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ladybird/Userland/Libraries/LibJS/Bytecode/Interpreter.cpp

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LibJS: Start fleshing out a bytecode for the JavaScript engine :^) This patch begins the work of implementing JavaScript execution in a bytecode VM instead of an AST tree-walk interpreter. It's probably quite naive, but we have to start somewhere. The basic idea is that you call Bytecode::Generator::generate() on an AST node and it hands you back a Bytecode::Block filled with instructions that can then be interpreted by a Bytecode::Interpreter. This first version only implements two instructions: Load and Add. :^) Each bytecode block has infinity registers, and the interpreter resizes its register file to fit the block being executed. Two new `js` options are added in this patch as well: `-d` will dump the generated bytecode `-b` will execute the generated bytecode Note that unless `-d` and/or `-b` are specified, none of the bytecode related stuff in LibJS runs at all. This is implemented in parallel with the existing AST interpreter. :^)
2021-06-03 10:46:30 +02:00
/*
LibJS: Fast path for Increment of Int32 value in bytecode interpreter 5% speed-up on Kraken/ai-astar.js in interpreter mode. :^)
2024-01-27 20:51:11 +01:00
* Copyright (c) 2021-2024, Andreas Kling <kling@serenityos.org>
LibJS: Start fleshing out a bytecode for the JavaScript engine :^) This patch begins the work of implementing JavaScript execution in a bytecode VM instead of an AST tree-walk interpreter. It's probably quite naive, but we have to start somewhere. The basic idea is that you call Bytecode::Generator::generate() on an AST node and it hands you back a Bytecode::Block filled with instructions that can then be interpreted by a Bytecode::Interpreter. This first version only implements two instructions: Load and Add. :^) Each bytecode block has infinity registers, and the interpreter resizes its register file to fit the block being executed. Two new `js` options are added in this patch as well: `-d` will dump the generated bytecode `-b` will execute the generated bytecode Note that unless `-d` and/or `-b` are specified, none of the bytecode related stuff in LibJS runs at all. This is implemented in parallel with the existing AST interpreter. :^)
2021-06-03 10:46:30 +02:00
*
* SPDX-License-Identifier: BSD-2-Clause
*/
LibJS: Move bytecode debug spam behind JS_BYTECODE_DEBUG :^)
2021-06-07 15:17:37 +02:00
#include <AK/Debug.h>
LibJS: Move all bytecode instruction implementations to Interpreter.cpp This allows aggressive inlining without LTO.
2023-09-27 10:10:00 +02:00
#include <AK/HashTable.h>
LibJS: Store strings in a string table Instead of using Strings in the bytecode ops this adds a global string table to the Executable struct which individual operations can refer to using indices. This brings bytecode ops one step closer to being pointer free.
2021-06-09 10:02:01 +02:00
#include <AK/TemporaryChange.h>
LibJS/Bytecode: Leave GlobalDeclarationInstantiation in C++ Don't try to implement this AO in bytecode. Instead, the bytecode Interpreter class now has a run() API with the same inputs as the AST interpreter. It sets up the necessary environments etc, including invoking the GlobalDeclarationInstantiation AO.
2023-06-15 12:36:57 +02:00
#include <LibJS/AST.h>
LibJS: Generate bytecode in basic blocks instead of one big block This limits the size of each block (currently set to 1K), and gets us closer to a canonical, more easily analysable bytecode format. As a result of this, "Labels" are now simply entries to basic blocks. Since there is no more 'conditional' jump (as all jumps are always taken), JumpIf{True,False} are unified to JumpConditional, and JumpIfNullish is renamed to JumpNullish. Also fixes #7914 as a result of reimplementing the loop logic.
2021-06-09 06:49:58 +04:30
#include <LibJS/Bytecode/BasicBlock.h>
LibJS/Bytecode: Begin moving shareable (JIT+Interpreter) stuff somewhere There are a lot of native C++ functions that will be used by both the bytecode interpreter and jitted code. Let's put them in their own file instead of having them in Interpreter.cpp.
2023-10-18 13:26:47 +02:00
#include <LibJS/Bytecode/CommonImplementations.h>
Ladybird+LibJS: Add CLI option to run browser with LibJS bytecode VM This required quite a bit of plumbing, but now you can run ladybird --use-bytecode
2023-06-17 13:16:35 +02:00
#include <LibJS/Bytecode/Generator.h>
LibJS: Start fleshing out a bytecode for the JavaScript engine :^) This patch begins the work of implementing JavaScript execution in a bytecode VM instead of an AST tree-walk interpreter. It's probably quite naive, but we have to start somewhere. The basic idea is that you call Bytecode::Generator::generate() on an AST node and it hands you back a Bytecode::Block filled with instructions that can then be interpreted by a Bytecode::Interpreter. This first version only implements two instructions: Load and Add. :^) Each bytecode block has infinity registers, and the interpreter resizes its register file to fit the block being executed. Two new `js` options are added in this patch as well: `-d` will dump the generated bytecode `-b` will execute the generated bytecode Note that unless `-d` and/or `-b` are specified, none of the bytecode related stuff in LibJS runs at all. This is implemented in parallel with the existing AST interpreter. :^)
2021-06-03 10:46:30 +02:00
#include <LibJS/Bytecode/Instruction.h>
#include <LibJS/Bytecode/Interpreter.h>
LibJS: Use static unwind mappings for unwind related functions
2023-10-20 00:33:51 +02:00
#include <LibJS/Bytecode/Label.h>
LibJS: Move Bytecode::Instruction::execute() to the Op.h header ..and make sure it always gets inlined in the interpreter loop.
2021-06-09 09:19:34 +02:00
#include <LibJS/Bytecode/Op.h>
LibJS: Move all bytecode instruction implementations to Interpreter.cpp This allows aggressive inlining without LTO.
2023-09-27 10:10:00 +02:00
#include <LibJS/Runtime/AbstractOperations.h>
#include <LibJS/Runtime/Array.h>
#include <LibJS/Runtime/BigInt.h>
#include <LibJS/Runtime/DeclarativeEnvironment.h>
#include <LibJS/Runtime/ECMAScriptFunctionObject.h>
#include <LibJS/Runtime/Environment.h>
#include <LibJS/Runtime/FunctionEnvironment.h>
LibJS: Drop "Record" suffix from all the *Environment record classes "Records" in the spec are basically C++ classes, so let's drop this mouthful of a suffix.
2021-07-01 12:24:46 +02:00
#include <LibJS/Runtime/GlobalEnvironment.h>
LibJS: Add a VM accessor to Bytecode::Interpreter :^)
2021-06-03 18:26:13 +02:00
#include <LibJS/Runtime/GlobalObject.h>
LibJS: Move all bytecode instruction implementations to Interpreter.cpp This allows aggressive inlining without LTO.
2023-09-27 10:10:00 +02:00
#include <LibJS/Runtime/Iterator.h>
LibJS: Call builtins directly in the bytecode interpreter Allows the bytecode interpreter to call the builtins c++ implementation directly without making a javascript call just as the JIT. Kraken test speedups: imaging-gaussian-blur.js (1.5x) and audio-oscillator.js (1.2x)
2023-11-30 19:49:29 +01:00
#include <LibJS/Runtime/MathObject.h>
LibJS: Move all bytecode instruction implementations to Interpreter.cpp This allows aggressive inlining without LTO.
2023-09-27 10:10:00 +02:00
#include <LibJS/Runtime/NativeFunction.h>
#include <LibJS/Runtime/ObjectEnvironment.h>
LibJS: Move the GlobalEnvironment from GlobalObject to Realm This is where the spec wants to have it. Requires a couple of hacks as currently everything that needs a Realm actually has a GlobalObject, so we need to go via the Interpreter.
2021-09-11 20:27:36 +01:00
#include <LibJS/Runtime/Realm.h>
LibJS: Move all bytecode instruction implementations to Interpreter.cpp This allows aggressive inlining without LTO.
2023-09-27 10:10:00 +02:00
#include <LibJS/Runtime/Reference.h>
#include <LibJS/Runtime/RegExpObject.h>
#include <LibJS/Runtime/Value.h>
LibJS: Inline fast case for Value::to_{boolean,number,numeric,primitive} These functions all have a very common case that can be dealt with a very simple inline check, often avoiding the need to call an out-of-line function. This patch moves the common case to inline functions in a new ValueInlines.h header (necessary due to header dependency issues..) 8% speed-up on the entire Kraken benchmark :^)
2023-10-06 17:54:21 +02:00
#include <LibJS/Runtime/ValueInlines.h>
LibJS: Move all bytecode instruction implementations to Interpreter.cpp This allows aggressive inlining without LTO.
2023-09-27 10:10:00 +02:00
#include <LibJS/SourceTextModule.h>
LibJS: Start fleshing out a bytecode for the JavaScript engine :^) This patch begins the work of implementing JavaScript execution in a bytecode VM instead of an AST tree-walk interpreter. It's probably quite naive, but we have to start somewhere. The basic idea is that you call Bytecode::Generator::generate() on an AST node and it hands you back a Bytecode::Block filled with instructions that can then be interpreted by a Bytecode::Interpreter. This first version only implements two instructions: Load and Add. :^) Each bytecode block has infinity registers, and the interpreter resizes its register file to fit the block being executed. Two new `js` options are added in this patch as well: `-d` will dump the generated bytecode `-b` will execute the generated bytecode Note that unless `-d` and/or `-b` are specified, none of the bytecode related stuff in LibJS runs at all. This is implemented in parallel with the existing AST interpreter. :^)
2021-06-03 10:46:30 +02:00
namespace JS::Bytecode {
LibJS: Move global "should dump bytecode" flag into LibJS This will allow us to trigger bytecode executable dumps when generating bytecode inside LibJS as well, not just in clients like js and test-js.
2021-10-24 13:34:46 +02:00
bool g_dump_bytecode = false;
LibJS: Compile ScriptFunctions into bytecode and run them that way :^) If there's a current Bytecode::Interpreter in action, ScriptFunction will now compile itself into bytecode and execute in that context. This patch also adds the Return bytecode instruction so that we can actually return values from called functions. :^) Return values are propagated from callee to caller via the caller's $0 register. Bytecode::Interpreter now keeps a stack of register "windows". These are not very efficient, but it should be pretty straightforward to convert them to e.g a sliding register window architecture later on. This is pretty dang cool! :^)
2021-06-05 15:53:36 +02:00
LibJS/Bytecode: Move to a new bytecode format This patch moves us away from the accumulator-based bytecode format to one with explicit source and destination registers. The new format has multiple benefits: - ~25% faster on the Kraken and Octane benchmarks :^) - Fewer instructions to accomplish the same thing - Much easier for humans to read(!) Because this change requires a fundamental shift in how bytecode is generated, it is quite comprehensive. Main implementation mechanism: generate_bytecode() virtual function now takes an optional "preferred dst" operand, which allows callers to communicate when they have an operand that would be optimal for the result to go into. It also returns an optional "actual dst" operand, which is where the completion value (if any) of the AST node is stored after the node has "executed". One thing of note that's new: because instructions can now take locals as operands, this means we got rid of the GetLocal instruction. A side-effect of that is we have to think about the temporal deadzone (TDZ) a bit differently for locals (GetLocal would previously check for empty values and interpret that as a TDZ access and throw). We now insert special ThrowIfTDZ instructions in places where a local access may be in the TDZ, to maintain the correct behavior. There are a number of progressions and regressions from this test: A number of async generator tests have been accidentally fixed while converting the implementation to the new bytecode format. It didn't seem useful to preserve bugs in the original code when converting it. Some "does eval() return the correct completion value" tests have regressed, in particular ones related to propagating the appropriate completion after control flow statements like continue and break. These are all fairly obscure issues, and I believe we can continue working on them separately. The net test262 result is a progression though. :^)
2024-02-04 08:00:54 +01:00
static ByteString format_operand(StringView name, Operand operand, Bytecode::Executable const& executable)
{
StringBuilder builder;
LibJS/Bytecode: Put arguments directly in the Call instruction Instead of having Call refer to a range of VM registers, it now has a trailing list of argument operands as part of the instruction. This means we no longer have to shuffle every argument value into a register before making a call, making bytecode smaller & faster. :^)
2024-02-20 15:59:45 +01:00
if (!name.is_empty())
builder.appendff("\033[32m{}\033[0m:", name);
LibJS/Bytecode: Move to a new bytecode format This patch moves us away from the accumulator-based bytecode format to one with explicit source and destination registers. The new format has multiple benefits: - ~25% faster on the Kraken and Octane benchmarks :^) - Fewer instructions to accomplish the same thing - Much easier for humans to read(!) Because this change requires a fundamental shift in how bytecode is generated, it is quite comprehensive. Main implementation mechanism: generate_bytecode() virtual function now takes an optional "preferred dst" operand, which allows callers to communicate when they have an operand that would be optimal for the result to go into. It also returns an optional "actual dst" operand, which is where the completion value (if any) of the AST node is stored after the node has "executed". One thing of note that's new: because instructions can now take locals as operands, this means we got rid of the GetLocal instruction. A side-effect of that is we have to think about the temporal deadzone (TDZ) a bit differently for locals (GetLocal would previously check for empty values and interpret that as a TDZ access and throw). We now insert special ThrowIfTDZ instructions in places where a local access may be in the TDZ, to maintain the correct behavior. There are a number of progressions and regressions from this test: A number of async generator tests have been accidentally fixed while converting the implementation to the new bytecode format. It didn't seem useful to preserve bugs in the original code when converting it. Some "does eval() return the correct completion value" tests have regressed, in particular ones related to propagating the appropriate completion after control flow statements like continue and break. These are all fairly obscure issues, and I believe we can continue working on them separately. The net test262 result is a progression though. :^)
2024-02-04 08:00:54 +01:00
switch (operand.type()) {
case Operand::Type::Register:
builder.appendff("\033[33mreg{}\033[0m", operand.index());
break;
case Operand::Type::Local:
// FIXME: Show local name.
builder.appendff("\033[34mloc{}\033[0m", operand.index());
break;
case Operand::Type::Constant: {
builder.append("\033[36m"sv);
auto value = executable.constants[operand.index()];
if (value.is_empty())
builder.append("<Empty>"sv);
else if (value.is_boolean())
builder.appendff("Bool({})", value.as_bool() ? "true"sv : "false"sv);
else if (value.is_int32())
builder.appendff("Int32({})", value.as_i32());
else if (value.is_double())
builder.appendff("Double({})", value.as_double());
LibJS/Bytecode: Make primitive bigints be constants Instead of emitting a NewBigInt instruction to construct a primitive bigint from a parsed literal, we now instantiate the BigInt on the heap during codegen.
2024-03-03 11:40:00 +01:00
else if (value.is_bigint())
builder.appendff("BigInt({})", value.as_bigint().to_byte_string());
LibJS/Bytecode: Make primitive strings be constants Instead of emitting a NewString instruction to construct a primitive string from a parsed literal, we now instantiate the PrimitiveString on the heap during codegen.
2024-03-03 11:34:36 +01:00
else if (value.is_string())
builder.appendff("String(\"{}\")", value.as_string().utf8_string_view());
LibJS/Bytecode: Move to a new bytecode format This patch moves us away from the accumulator-based bytecode format to one with explicit source and destination registers. The new format has multiple benefits: - ~25% faster on the Kraken and Octane benchmarks :^) - Fewer instructions to accomplish the same thing - Much easier for humans to read(!) Because this change requires a fundamental shift in how bytecode is generated, it is quite comprehensive. Main implementation mechanism: generate_bytecode() virtual function now takes an optional "preferred dst" operand, which allows callers to communicate when they have an operand that would be optimal for the result to go into. It also returns an optional "actual dst" operand, which is where the completion value (if any) of the AST node is stored after the node has "executed". One thing of note that's new: because instructions can now take locals as operands, this means we got rid of the GetLocal instruction. A side-effect of that is we have to think about the temporal deadzone (TDZ) a bit differently for locals (GetLocal would previously check for empty values and interpret that as a TDZ access and throw). We now insert special ThrowIfTDZ instructions in places where a local access may be in the TDZ, to maintain the correct behavior. There are a number of progressions and regressions from this test: A number of async generator tests have been accidentally fixed while converting the implementation to the new bytecode format. It didn't seem useful to preserve bugs in the original code when converting it. Some "does eval() return the correct completion value" tests have regressed, in particular ones related to propagating the appropriate completion after control flow statements like continue and break. These are all fairly obscure issues, and I believe we can continue working on them separately. The net test262 result is a progression though. :^)
2024-02-04 08:00:54 +01:00
else if (value.is_undefined())
builder.append("Undefined"sv);
else if (value.is_null())
builder.append("Null"sv);
else
builder.appendff("Value: {}", value);
builder.append("\033[0m"sv);
break;
}
default:
VERIFY_NOT_REACHED();
}
return builder.to_byte_string();
}
LibJS/Bytecode: Put arguments directly in the Call instruction Instead of having Call refer to a range of VM registers, it now has a trailing list of argument operands as part of the instruction. This means we no longer have to shuffle every argument value into a register before making a call, making bytecode smaller & faster. :^)
2024-02-20 15:59:45 +01:00
static ByteString format_operand_list(StringView name, ReadonlySpan<Operand> operands, Bytecode::Executable const& executable)
{
StringBuilder builder;
if (!name.is_empty())
LibJS/Bytecode: Fix formatting of operand lists in bytecode dumps There was an unterminated color escape sequence which caused "args" to look like "rgs" when dumping Call instructions.
2024-02-27 07:43:35 +01:00
builder.appendff(", \033[32m{}\033[0m:[", name);
LibJS/Bytecode: Put arguments directly in the Call instruction Instead of having Call refer to a range of VM registers, it now has a trailing list of argument operands as part of the instruction. This means we no longer have to shuffle every argument value into a register before making a call, making bytecode smaller & faster. :^)
2024-02-20 15:59:45 +01:00
for (size_t i = 0; i < operands.size(); ++i) {
if (i != 0)
builder.append(", "sv);
builder.appendff("{}", format_operand(""sv, operands[i], executable));
}
builder.append("]"sv);
return builder.to_byte_string();
}
LibJS/Bytecode: Make NewPrimitiveArray a variable-length instruction Instead of having a FixedArray with a separate heap allocation, we can just bake the primitive values into the instruction itself.
2024-03-03 12:37:28 +01:00
static ByteString format_value_list(StringView name, ReadonlySpan<Value> values)
{
StringBuilder builder;
if (!name.is_empty())
builder.appendff(", \033[32m{}\033[0m:[", name);
builder.join(", "sv, values);
builder.append("]"sv);
return builder.to_byte_string();
}
LibJS/Bytecode: Add fast paths for equality checks with same-tag values
2024-03-04 09:34:30 +01:00
ALWAYS_INLINE static ThrowCompletionOr<Value> loosely_inequals(VM& vm, Value src1, Value src2)
LibJS/Bytecode: Add peephole optimization pass and fuse compare+jump This patch adds a new "Peephole" pass for performing small, local optimizations to bytecode. We also introduce the first such optimization, fusing a sequence of some comparison instruction FooCompare followed by a JumpIf into a new set of JumpFooCompare instructions. This gives a ~50% speed-up on the following microbenchmark: for (let i = 0; i < 10_000_000; ++i) { } But more traditional benchmarks see a pretty sizable speed-up as well, for example 15% on Kraken/ai-astar.js and 16% on Kraken/audio-dft.js :^)
2024-03-03 14:56:33 +01:00
{
LibJS/Bytecode: Add fast paths for equality checks with same-tag values
2024-03-04 09:34:30 +01:00
if (src1.tag() == src2.tag()) {
if (src1.is_int32() || src1.is_object() || src1.is_boolean() || src1.is_nullish())
return Value(src1.encoded() != src2.encoded());
}
LibJS/Bytecode: Add peephole optimization pass and fuse compare+jump This patch adds a new "Peephole" pass for performing small, local optimizations to bytecode. We also introduce the first such optimization, fusing a sequence of some comparison instruction FooCompare followed by a JumpIf into a new set of JumpFooCompare instructions. This gives a ~50% speed-up on the following microbenchmark: for (let i = 0; i < 10_000_000; ++i) { } But more traditional benchmarks see a pretty sizable speed-up as well, for example 15% on Kraken/ai-astar.js and 16% on Kraken/audio-dft.js :^)
2024-03-03 14:56:33 +01:00
return Value(!TRY(is_loosely_equal(vm, src1, src2)));
}
LibJS/Bytecode: Add fast paths for equality checks with same-tag values
2024-03-04 09:34:30 +01:00
ALWAYS_INLINE static ThrowCompletionOr<Value> loosely_equals(VM& vm, Value src1, Value src2)
LibJS/Bytecode: Add peephole optimization pass and fuse compare+jump This patch adds a new "Peephole" pass for performing small, local optimizations to bytecode. We also introduce the first such optimization, fusing a sequence of some comparison instruction FooCompare followed by a JumpIf into a new set of JumpFooCompare instructions. This gives a ~50% speed-up on the following microbenchmark: for (let i = 0; i < 10_000_000; ++i) { } But more traditional benchmarks see a pretty sizable speed-up as well, for example 15% on Kraken/ai-astar.js and 16% on Kraken/audio-dft.js :^)
2024-03-03 14:56:33 +01:00
{
LibJS/Bytecode: Add fast paths for equality checks with same-tag values
2024-03-04 09:34:30 +01:00
if (src1.tag() == src2.tag()) {
if (src1.is_int32() || src1.is_object() || src1.is_boolean() || src1.is_nullish())
return Value(src1.encoded() == src2.encoded());
}
LibJS/Bytecode: Add peephole optimization pass and fuse compare+jump This patch adds a new "Peephole" pass for performing small, local optimizations to bytecode. We also introduce the first such optimization, fusing a sequence of some comparison instruction FooCompare followed by a JumpIf into a new set of JumpFooCompare instructions. This gives a ~50% speed-up on the following microbenchmark: for (let i = 0; i < 10_000_000; ++i) { } But more traditional benchmarks see a pretty sizable speed-up as well, for example 15% on Kraken/ai-astar.js and 16% on Kraken/audio-dft.js :^)
2024-03-03 14:56:33 +01:00
return Value(TRY(is_loosely_equal(vm, src1, src2)));
}
LibJS/Bytecode: Add fast paths for equality checks with same-tag values
2024-03-04 09:34:30 +01:00
ALWAYS_INLINE static ThrowCompletionOr<Value> strict_inequals(VM&, Value src1, Value src2)
LibJS/Bytecode: Add peephole optimization pass and fuse compare+jump This patch adds a new "Peephole" pass for performing small, local optimizations to bytecode. We also introduce the first such optimization, fusing a sequence of some comparison instruction FooCompare followed by a JumpIf into a new set of JumpFooCompare instructions. This gives a ~50% speed-up on the following microbenchmark: for (let i = 0; i < 10_000_000; ++i) { } But more traditional benchmarks see a pretty sizable speed-up as well, for example 15% on Kraken/ai-astar.js and 16% on Kraken/audio-dft.js :^)
2024-03-03 14:56:33 +01:00
{
LibJS/Bytecode: Add fast paths for equality checks with same-tag values
2024-03-04 09:34:30 +01:00
if (src1.tag() == src2.tag()) {
if (src1.is_int32() || src1.is_object() || src1.is_boolean() || src1.is_nullish())
return Value(src1.encoded() != src2.encoded());
}
LibJS/Bytecode: Add peephole optimization pass and fuse compare+jump This patch adds a new "Peephole" pass for performing small, local optimizations to bytecode. We also introduce the first such optimization, fusing a sequence of some comparison instruction FooCompare followed by a JumpIf into a new set of JumpFooCompare instructions. This gives a ~50% speed-up on the following microbenchmark: for (let i = 0; i < 10_000_000; ++i) { } But more traditional benchmarks see a pretty sizable speed-up as well, for example 15% on Kraken/ai-astar.js and 16% on Kraken/audio-dft.js :^)
2024-03-03 14:56:33 +01:00
return Value(!is_strictly_equal(src1, src2));
}
LibJS/Bytecode: Add fast paths for equality checks with same-tag values
2024-03-04 09:34:30 +01:00
ALWAYS_INLINE static ThrowCompletionOr<Value> strict_equals(VM&, Value src1, Value src2)
LibJS/Bytecode: Add peephole optimization pass and fuse compare+jump This patch adds a new "Peephole" pass for performing small, local optimizations to bytecode. We also introduce the first such optimization, fusing a sequence of some comparison instruction FooCompare followed by a JumpIf into a new set of JumpFooCompare instructions. This gives a ~50% speed-up on the following microbenchmark: for (let i = 0; i < 10_000_000; ++i) { } But more traditional benchmarks see a pretty sizable speed-up as well, for example 15% on Kraken/ai-astar.js and 16% on Kraken/audio-dft.js :^)
2024-03-03 14:56:33 +01:00
{
LibJS/Bytecode: Add fast paths for equality checks with same-tag values
2024-03-04 09:34:30 +01:00
if (src1.tag() == src2.tag()) {
if (src1.is_int32() || src1.is_object() || src1.is_boolean() || src1.is_nullish())
return Value(src1.encoded() == src2.encoded());
}
LibJS/Bytecode: Add peephole optimization pass and fuse compare+jump This patch adds a new "Peephole" pass for performing small, local optimizations to bytecode. We also introduce the first such optimization, fusing a sequence of some comparison instruction FooCompare followed by a JumpIf into a new set of JumpFooCompare instructions. This gives a ~50% speed-up on the following microbenchmark: for (let i = 0; i < 10_000_000; ++i) { } But more traditional benchmarks see a pretty sizable speed-up as well, for example 15% on Kraken/ai-astar.js and 16% on Kraken/audio-dft.js :^)
2024-03-03 14:56:33 +01:00
return Value(is_strictly_equal(src1, src2));
}
LibJS/Bytecode: Simplify Bytecode::Interpreter lifetime model The JS::VM now owns the one Bytecode::Interpreter. We no longer have multiple bytecode interpreters, and there is no concept of a "current" bytecode interpreter. If you ask for VM::bytecode_interpreter_if_exists(), it will return null if we're not running the program in "bytecode enabled" mode. If you ask for VM::bytecode_interpreter(), it will return a bytecode interpreter in all modes. This is used for situations where even the AST interpreter switches to bytecode mode (generators, etc.)
2023-06-22 15:59:18 +02:00
Interpreter::Interpreter(VM& vm)
: m_vm(vm)
LibJS: Compile ScriptFunctions into bytecode and run them that way :^) If there's a current Bytecode::Interpreter in action, ScriptFunction will now compile itself into bytecode and execute in that context. This patch also adds the Return bytecode instruction so that we can actually return values from called functions. :^) Return values are propagated from callee to caller via the caller's $0 register. Bytecode::Interpreter now keeps a stack of register "windows". These are not very efficient, but it should be pretty straightforward to convert them to e.g a sliding register window architecture later on. This is pretty dang cool! :^)
2021-06-05 15:53:36 +02:00
{
LibJS: Start fleshing out a bytecode for the JavaScript engine :^) This patch begins the work of implementing JavaScript execution in a bytecode VM instead of an AST tree-walk interpreter. It's probably quite naive, but we have to start somewhere. The basic idea is that you call Bytecode::Generator::generate() on an AST node and it hands you back a Bytecode::Block filled with instructions that can then be interpreted by a Bytecode::Interpreter. This first version only implements two instructions: Load and Add. :^) Each bytecode block has infinity registers, and the interpreter resizes its register file to fit the block being executed. Two new `js` options are added in this patch as well: `-d` will dump the generated bytecode `-b` will execute the generated bytecode Note that unless `-d` and/or `-b` are specified, none of the bytecode related stuff in LibJS runs at all. This is implemented in parallel with the existing AST interpreter. :^)
2021-06-03 10:46:30 +02:00
}
Interpreter::~Interpreter()
{
}
LibJS/Bytecode: Move to a new bytecode format This patch moves us away from the accumulator-based bytecode format to one with explicit source and destination registers. The new format has multiple benefits: - ~25% faster on the Kraken and Octane benchmarks :^) - Fewer instructions to accomplish the same thing - Much easier for humans to read(!) Because this change requires a fundamental shift in how bytecode is generated, it is quite comprehensive. Main implementation mechanism: generate_bytecode() virtual function now takes an optional "preferred dst" operand, which allows callers to communicate when they have an operand that would be optimal for the result to go into. It also returns an optional "actual dst" operand, which is where the completion value (if any) of the AST node is stored after the node has "executed". One thing of note that's new: because instructions can now take locals as operands, this means we got rid of the GetLocal instruction. A side-effect of that is we have to think about the temporal deadzone (TDZ) a bit differently for locals (GetLocal would previously check for empty values and interpret that as a TDZ access and throw). We now insert special ThrowIfTDZ instructions in places where a local access may be in the TDZ, to maintain the correct behavior. There are a number of progressions and regressions from this test: A number of async generator tests have been accidentally fixed while converting the implementation to the new bytecode format. It didn't seem useful to preserve bugs in the original code when converting it. Some "does eval() return the correct completion value" tests have regressed, in particular ones related to propagating the appropriate completion after control flow statements like continue and break. These are all fairly obscure issues, and I believe we can continue working on them separately. The net test262 result is a progression though. :^)
2024-02-04 08:00:54 +01:00
ALWAYS_INLINE Value Interpreter::get(Operand op) const
LibJS/Bytecode: Add Bytecode::Operand An Operand is either a register, a local, or a constant (index into the executable's constant table)
2024-02-02 10:19:17 +01:00
{
switch (op.type()) {
case Operand::Type::Register:
return reg(Register { op.index() });
case Operand::Type::Local:
LibJS/Bytecode: Flatten bytecode to a contiguous representation Instead of keeping bytecode as a set of disjoint basic blocks on the malloc heap, bytecode is now a contiguous sequence of bytes(!) The transformation happens at the end of Bytecode::Generator::generate() and the only really hairy part is rerouting jump labels. This required solving a few problems: - The interpreter execution loop had to change quite a bit, since we were storing BasicBlock pointers all over the place, and control transfer was done by redirecting the interpreter's current block. - Exception handlers & finalizers are now stored per-bytecode-range in a side table in Executable. - The interpreter now has a plain program counter instead of a stream iterator. This actually makes error stack generation a bit nicer since we just have to deal with a number instead of reaching into the iterator. This yields a 25% performance improvement on this microbenchmark: for (let i = 0; i < 1_000_000; ++i) { } But basically everything gets faster. :^)
2024-05-06 06:44:08 +02:00
return m_locals.data()[op.index()];
LibJS/Bytecode: Add Bytecode::Operand An Operand is either a register, a local, or a constant (index into the executable's constant table)
2024-02-02 10:19:17 +01:00
case Operand::Type::Constant:
return current_executable().constants[op.index()];
}
LibJS/Bytecode: Move to a new bytecode format This patch moves us away from the accumulator-based bytecode format to one with explicit source and destination registers. The new format has multiple benefits: - ~25% faster on the Kraken and Octane benchmarks :^) - Fewer instructions to accomplish the same thing - Much easier for humans to read(!) Because this change requires a fundamental shift in how bytecode is generated, it is quite comprehensive. Main implementation mechanism: generate_bytecode() virtual function now takes an optional "preferred dst" operand, which allows callers to communicate when they have an operand that would be optimal for the result to go into. It also returns an optional "actual dst" operand, which is where the completion value (if any) of the AST node is stored after the node has "executed". One thing of note that's new: because instructions can now take locals as operands, this means we got rid of the GetLocal instruction. A side-effect of that is we have to think about the temporal deadzone (TDZ) a bit differently for locals (GetLocal would previously check for empty values and interpret that as a TDZ access and throw). We now insert special ThrowIfTDZ instructions in places where a local access may be in the TDZ, to maintain the correct behavior. There are a number of progressions and regressions from this test: A number of async generator tests have been accidentally fixed while converting the implementation to the new bytecode format. It didn't seem useful to preserve bugs in the original code when converting it. Some "does eval() return the correct completion value" tests have regressed, in particular ones related to propagating the appropriate completion after control flow statements like continue and break. These are all fairly obscure issues, and I believe we can continue working on them separately. The net test262 result is a progression though. :^)
2024-02-04 08:00:54 +01:00
__builtin_unreachable();
LibJS/Bytecode: Add Bytecode::Operand An Operand is either a register, a local, or a constant (index into the executable's constant table)
2024-02-02 10:19:17 +01:00
}
LibJS/Bytecode: Move to a new bytecode format This patch moves us away from the accumulator-based bytecode format to one with explicit source and destination registers. The new format has multiple benefits: - ~25% faster on the Kraken and Octane benchmarks :^) - Fewer instructions to accomplish the same thing - Much easier for humans to read(!) Because this change requires a fundamental shift in how bytecode is generated, it is quite comprehensive. Main implementation mechanism: generate_bytecode() virtual function now takes an optional "preferred dst" operand, which allows callers to communicate when they have an operand that would be optimal for the result to go into. It also returns an optional "actual dst" operand, which is where the completion value (if any) of the AST node is stored after the node has "executed". One thing of note that's new: because instructions can now take locals as operands, this means we got rid of the GetLocal instruction. A side-effect of that is we have to think about the temporal deadzone (TDZ) a bit differently for locals (GetLocal would previously check for empty values and interpret that as a TDZ access and throw). We now insert special ThrowIfTDZ instructions in places where a local access may be in the TDZ, to maintain the correct behavior. There are a number of progressions and regressions from this test: A number of async generator tests have been accidentally fixed while converting the implementation to the new bytecode format. It didn't seem useful to preserve bugs in the original code when converting it. Some "does eval() return the correct completion value" tests have regressed, in particular ones related to propagating the appropriate completion after control flow statements like continue and break. These are all fairly obscure issues, and I believe we can continue working on them separately. The net test262 result is a progression though. :^)
2024-02-04 08:00:54 +01:00
ALWAYS_INLINE void Interpreter::set(Operand op, Value value)
LibJS/Bytecode: Add Bytecode::Operand An Operand is either a register, a local, or a constant (index into the executable's constant table)
2024-02-02 10:19:17 +01:00
{
switch (op.type()) {
case Operand::Type::Register:
reg(Register { op.index() }) = value;
return;
case Operand::Type::Local:
LibJS/Bytecode: Flatten bytecode to a contiguous representation Instead of keeping bytecode as a set of disjoint basic blocks on the malloc heap, bytecode is now a contiguous sequence of bytes(!) The transformation happens at the end of Bytecode::Generator::generate() and the only really hairy part is rerouting jump labels. This required solving a few problems: - The interpreter execution loop had to change quite a bit, since we were storing BasicBlock pointers all over the place, and control transfer was done by redirecting the interpreter's current block. - Exception handlers & finalizers are now stored per-bytecode-range in a side table in Executable. - The interpreter now has a plain program counter instead of a stream iterator. This actually makes error stack generation a bit nicer since we just have to deal with a number instead of reaching into the iterator. This yields a 25% performance improvement on this microbenchmark: for (let i = 0; i < 1_000_000; ++i) { } But basically everything gets faster. :^)
2024-05-06 06:44:08 +02:00
m_locals.data()[op.index()] = value;
LibJS/Bytecode: Add Bytecode::Operand An Operand is either a register, a local, or a constant (index into the executable's constant table)
2024-02-02 10:19:17 +01:00
return;
case Operand::Type::Constant:
VERIFY_NOT_REACHED();
}
LibJS/Bytecode: Move to a new bytecode format This patch moves us away from the accumulator-based bytecode format to one with explicit source and destination registers. The new format has multiple benefits: - ~25% faster on the Kraken and Octane benchmarks :^) - Fewer instructions to accomplish the same thing - Much easier for humans to read(!) Because this change requires a fundamental shift in how bytecode is generated, it is quite comprehensive. Main implementation mechanism: generate_bytecode() virtual function now takes an optional "preferred dst" operand, which allows callers to communicate when they have an operand that would be optimal for the result to go into. It also returns an optional "actual dst" operand, which is where the completion value (if any) of the AST node is stored after the node has "executed". One thing of note that's new: because instructions can now take locals as operands, this means we got rid of the GetLocal instruction. A side-effect of that is we have to think about the temporal deadzone (TDZ) a bit differently for locals (GetLocal would previously check for empty values and interpret that as a TDZ access and throw). We now insert special ThrowIfTDZ instructions in places where a local access may be in the TDZ, to maintain the correct behavior. There are a number of progressions and regressions from this test: A number of async generator tests have been accidentally fixed while converting the implementation to the new bytecode format. It didn't seem useful to preserve bugs in the original code when converting it. Some "does eval() return the correct completion value" tests have regressed, in particular ones related to propagating the appropriate completion after control flow statements like continue and break. These are all fairly obscure issues, and I believe we can continue working on them separately. The net test262 result is a progression though. :^)
2024-02-04 08:00:54 +01:00
__builtin_unreachable();
LibJS/Bytecode: Add Bytecode::Operand An Operand is either a register, a local, or a constant (index into the executable's constant table)
2024-02-02 10:19:17 +01:00
}
LibJS/Bytecode: Leave GlobalDeclarationInstantiation in C++ Don't try to implement this AO in bytecode. Instead, the bytecode Interpreter class now has a run() API with the same inputs as the AST interpreter. It sets up the necessary environments etc, including invoking the GlobalDeclarationInstantiation AO.
2023-06-15 12:36:57 +02:00
// 16.1.6 ScriptEvaluation ( scriptRecord ), https://tc39.es/ecma262/#sec-runtime-semantics-scriptevaluation
ThrowCompletionOr<Value> Interpreter::run(Script& script_record, JS::GCPtr<Environment> lexical_environment_override)
{
auto& vm = this->vm();
// 1. Let globalEnv be scriptRecord.[[Realm]].[[GlobalEnv]].
auto& global_environment = script_record.realm().global_environment();
// 2. Let scriptContext be a new ECMAScript code execution context.
LibJS: Always allocate ExecutionContext objects on the malloc heap Instead of allocating these in a mixture of ways, we now always put them on the malloc heap, and keep an intrusive linked list of them that we can iterate for GC marking purposes.
2023-11-27 16:45:45 +01:00
auto script_context = ExecutionContext::create(vm.heap());
LibJS/Bytecode: Leave GlobalDeclarationInstantiation in C++ Don't try to implement this AO in bytecode. Instead, the bytecode Interpreter class now has a run() API with the same inputs as the AST interpreter. It sets up the necessary environments etc, including invoking the GlobalDeclarationInstantiation AO.
2023-06-15 12:36:57 +02:00
// 3. Set the Function of scriptContext to null.
// NOTE: This was done during execution context construction.
// 4. Set the Realm of scriptContext to scriptRecord.[[Realm]].
LibJS: Always allocate ExecutionContext objects on the malloc heap Instead of allocating these in a mixture of ways, we now always put them on the malloc heap, and keep an intrusive linked list of them that we can iterate for GC marking purposes.
2023-11-27 16:45:45 +01:00
script_context->realm = &script_record.realm();
LibJS/Bytecode: Leave GlobalDeclarationInstantiation in C++ Don't try to implement this AO in bytecode. Instead, the bytecode Interpreter class now has a run() API with the same inputs as the AST interpreter. It sets up the necessary environments etc, including invoking the GlobalDeclarationInstantiation AO.
2023-06-15 12:36:57 +02:00
// 5. Set the ScriptOrModule of scriptContext to scriptRecord.
LibJS: Always allocate ExecutionContext objects on the malloc heap Instead of allocating these in a mixture of ways, we now always put them on the malloc heap, and keep an intrusive linked list of them that we can iterate for GC marking purposes.
2023-11-27 16:45:45 +01:00
script_context->script_or_module = NonnullGCPtr<Script>(script_record);
LibJS/Bytecode: Leave GlobalDeclarationInstantiation in C++ Don't try to implement this AO in bytecode. Instead, the bytecode Interpreter class now has a run() API with the same inputs as the AST interpreter. It sets up the necessary environments etc, including invoking the GlobalDeclarationInstantiation AO.
2023-06-15 12:36:57 +02:00
// 6. Set the VariableEnvironment of scriptContext to globalEnv.
LibJS: Always allocate ExecutionContext objects on the malloc heap Instead of allocating these in a mixture of ways, we now always put them on the malloc heap, and keep an intrusive linked list of them that we can iterate for GC marking purposes.
2023-11-27 16:45:45 +01:00
script_context->variable_environment = &global_environment;
LibJS/Bytecode: Leave GlobalDeclarationInstantiation in C++ Don't try to implement this AO in bytecode. Instead, the bytecode Interpreter class now has a run() API with the same inputs as the AST interpreter. It sets up the necessary environments etc, including invoking the GlobalDeclarationInstantiation AO.
2023-06-15 12:36:57 +02:00
// 7. Set the LexicalEnvironment of scriptContext to globalEnv.
LibJS: Always allocate ExecutionContext objects on the malloc heap Instead of allocating these in a mixture of ways, we now always put them on the malloc heap, and keep an intrusive linked list of them that we can iterate for GC marking purposes.
2023-11-27 16:45:45 +01:00
script_context->lexical_environment = &global_environment;
LibJS/Bytecode: Leave GlobalDeclarationInstantiation in C++ Don't try to implement this AO in bytecode. Instead, the bytecode Interpreter class now has a run() API with the same inputs as the AST interpreter. It sets up the necessary environments etc, including invoking the GlobalDeclarationInstantiation AO.
2023-06-15 12:36:57 +02:00
// Non-standard: Override the lexical environment if requested.
if (lexical_environment_override)
LibJS: Always allocate ExecutionContext objects on the malloc heap Instead of allocating these in a mixture of ways, we now always put them on the malloc heap, and keep an intrusive linked list of them that we can iterate for GC marking purposes.
2023-11-27 16:45:45 +01:00
script_context->lexical_environment = lexical_environment_override;
LibJS/Bytecode: Leave GlobalDeclarationInstantiation in C++ Don't try to implement this AO in bytecode. Instead, the bytecode Interpreter class now has a run() API with the same inputs as the AST interpreter. It sets up the necessary environments etc, including invoking the GlobalDeclarationInstantiation AO.
2023-06-15 12:36:57 +02:00
// 8. Set the PrivateEnvironment of scriptContext to null.
// NOTE: This isn't in the spec, but we require it.
LibJS: Always allocate ExecutionContext objects on the malloc heap Instead of allocating these in a mixture of ways, we now always put them on the malloc heap, and keep an intrusive linked list of them that we can iterate for GC marking purposes.
2023-11-27 16:45:45 +01:00
script_context->is_strict_mode = script_record.parse_node().is_strict_mode();
LibJS/Bytecode: Leave GlobalDeclarationInstantiation in C++ Don't try to implement this AO in bytecode. Instead, the bytecode Interpreter class now has a run() API with the same inputs as the AST interpreter. It sets up the necessary environments etc, including invoking the GlobalDeclarationInstantiation AO.
2023-06-15 12:36:57 +02:00
// FIXME: 9. Suspend the currently running execution context.
// 10. Push scriptContext onto the execution context stack; scriptContext is now the running execution context.
LibJS: Always allocate ExecutionContext objects on the malloc heap Instead of allocating these in a mixture of ways, we now always put them on the malloc heap, and keep an intrusive linked list of them that we can iterate for GC marking purposes.
2023-11-27 16:45:45 +01:00
TRY(vm.push_execution_context(*script_context, {}));
LibJS/Bytecode: Leave GlobalDeclarationInstantiation in C++ Don't try to implement this AO in bytecode. Instead, the bytecode Interpreter class now has a run() API with the same inputs as the AST interpreter. It sets up the necessary environments etc, including invoking the GlobalDeclarationInstantiation AO.
2023-06-15 12:36:57 +02:00
// 11. Let script be scriptRecord.[[ECMAScriptCode]].
auto& script = script_record.parse_node();
// 12. Let result be Completion(GlobalDeclarationInstantiation(script, globalEnv)).
auto instantiation_result = script.global_declaration_instantiation(vm, global_environment);
Completion result = instantiation_result.is_throw_completion() ? instantiation_result.throw_completion() : normal_completion({});
// 13. If result.[[Type]] is normal, then
if (result.type() == Completion::Type::Normal) {
LibJS/Bytecode: Move to a new bytecode format This patch moves us away from the accumulator-based bytecode format to one with explicit source and destination registers. The new format has multiple benefits: - ~25% faster on the Kraken and Octane benchmarks :^) - Fewer instructions to accomplish the same thing - Much easier for humans to read(!) Because this change requires a fundamental shift in how bytecode is generated, it is quite comprehensive. Main implementation mechanism: generate_bytecode() virtual function now takes an optional "preferred dst" operand, which allows callers to communicate when they have an operand that would be optimal for the result to go into. It also returns an optional "actual dst" operand, which is where the completion value (if any) of the AST node is stored after the node has "executed". One thing of note that's new: because instructions can now take locals as operands, this means we got rid of the GetLocal instruction. A side-effect of that is we have to think about the temporal deadzone (TDZ) a bit differently for locals (GetLocal would previously check for empty values and interpret that as a TDZ access and throw). We now insert special ThrowIfTDZ instructions in places where a local access may be in the TDZ, to maintain the correct behavior. There are a number of progressions and regressions from this test: A number of async generator tests have been accidentally fixed while converting the implementation to the new bytecode format. It didn't seem useful to preserve bugs in the original code when converting it. Some "does eval() return the correct completion value" tests have regressed, in particular ones related to propagating the appropriate completion after control flow statements like continue and break. These are all fairly obscure issues, and I believe we can continue working on them separately. The net test262 result is a progression though. :^)
2024-02-04 08:00:54 +01:00
auto executable_result = JS::Bytecode::Generator::generate(vm, script, {});
LibJS/Bytecode: Leave GlobalDeclarationInstantiation in C++ Don't try to implement this AO in bytecode. Instead, the bytecode Interpreter class now has a run() API with the same inputs as the AST interpreter. It sets up the necessary environments etc, including invoking the GlobalDeclarationInstantiation AO.
2023-06-15 12:36:57 +02:00
if (executable_result.is_error()) {
if (auto error_string = executable_result.error().to_string(); error_string.is_error())
result = vm.template throw_completion<JS::InternalError>(vm.error_message(JS::VM::ErrorMessage::OutOfMemory));
else if (error_string = String::formatted("TODO({})", error_string.value()); error_string.is_error())
result = vm.template throw_completion<JS::InternalError>(vm.error_message(JS::VM::ErrorMessage::OutOfMemory));
else
result = JS::throw_completion(JS::InternalError::create(realm(), error_string.release_value()));
} else {
auto executable = executable_result.release_value();
if (g_dump_bytecode)
executable->dump();
// a. Set result to the result of evaluating script.
LibJS/Bytecode: Flatten bytecode to a contiguous representation Instead of keeping bytecode as a set of disjoint basic blocks on the malloc heap, bytecode is now a contiguous sequence of bytes(!) The transformation happens at the end of Bytecode::Generator::generate() and the only really hairy part is rerouting jump labels. This required solving a few problems: - The interpreter execution loop had to change quite a bit, since we were storing BasicBlock pointers all over the place, and control transfer was done by redirecting the interpreter's current block. - Exception handlers & finalizers are now stored per-bytecode-range in a side table in Executable. - The interpreter now has a plain program counter instead of a stream iterator. This actually makes error stack generation a bit nicer since we just have to deal with a number instead of reaching into the iterator. This yields a 25% performance improvement on this microbenchmark: for (let i = 0; i < 1_000_000; ++i) { } But basically everything gets faster. :^)
2024-05-06 06:44:08 +02:00
auto result_or_error = run_executable(*executable, {}, {});
LibJS/Bytecode: Leave GlobalDeclarationInstantiation in C++ Don't try to implement this AO in bytecode. Instead, the bytecode Interpreter class now has a run() API with the same inputs as the AST interpreter. It sets up the necessary environments etc, including invoking the GlobalDeclarationInstantiation AO.
2023-06-15 12:36:57 +02:00
if (result_or_error.value.is_error())
result = result_or_error.value.release_error();
else
LibJS: Merge CallFrame into ExecutionContext Before this change both ExecutionContext and CallFrame were created before executing function/module/script with a couple exceptions: - executable created for default function argument evaluation has to run in function's execution context. - `execute_ast_node()` where executable compiled for ASTNode has to be executed in running execution context. This change moves all members previously owned by CallFrame into ExecutionContext, and makes two exceptions where an executable that does not have a corresponding execution context saves and restores registers before running. Now, all execution state lives in a single entity, which makes it a bit easier to reason about and opens opportunities for optimizations, such as moving registers and local variables into a single array.
2024-05-01 19:33:49 +02:00
result = result_or_error.return_register_value;
LibJS/Bytecode: Leave GlobalDeclarationInstantiation in C++ Don't try to implement this AO in bytecode. Instead, the bytecode Interpreter class now has a run() API with the same inputs as the AST interpreter. It sets up the necessary environments etc, including invoking the GlobalDeclarationInstantiation AO.
2023-06-15 12:36:57 +02:00
}
}
// 14. If result.[[Type]] is normal and result.[[Value]] is empty, then
if (result.type() == Completion::Type::Normal && !result.value().has_value()) {
// a. Set result to NormalCompletion(undefined).
result = normal_completion(js_undefined());
}
// FIXME: 15. Suspend scriptContext and remove it from the execution context stack.
vm.pop_execution_context();
// 16. Assert: The execution context stack is not empty.
VERIFY(!vm.execution_context_stack().is_empty());
// FIXME: 17. Resume the context that is now on the top of the execution context stack as the running execution context.
// At this point we may have already run any queued promise jobs via on_call_stack_emptied,
// in which case this is a no-op.
// FIXME: These three should be moved out of Interpreter::run and give the host an option to run these, as it's up to the host when these get run.
// https://tc39.es/ecma262/#sec-jobs for jobs and https://tc39.es/ecma262/#_ref_3508 for ClearKeptObjects
// finish_execution_generation is particularly an issue for LibWeb, as the HTML spec wants to run it specifically after performing a microtask checkpoint.
// The promise and registry cleanup queues don't cause LibWeb an issue, as LibWeb overrides the hooks that push onto these queues.
vm.run_queued_promise_jobs();
vm.run_queued_finalization_registry_cleanup_jobs();
vm.finish_execution_generation();
// 18. Return ? result.
if (result.is_abrupt()) {
VERIFY(result.type() == Completion::Type::Throw);
return result.release_error();
}
VERIFY(result.value().has_value());
return *result.value();
}
ThrowCompletionOr<Value> Interpreter::run(SourceTextModule& module)
{
// FIXME: This is not a entry point as defined in the spec, but is convenient.
// To avoid work we use link_and_eval_module however that can already be
// dangerous if the vm loaded other modules.
auto& vm = this->vm();
TRY(vm.link_and_eval_module(Badge<Bytecode::Interpreter> {}, module));
vm.run_queued_promise_jobs();
vm.run_queued_finalization_registry_cleanup_jobs();
return js_undefined();
}
LibJS/Bytecode: Flatten bytecode to a contiguous representation Instead of keeping bytecode as a set of disjoint basic blocks on the malloc heap, bytecode is now a contiguous sequence of bytes(!) The transformation happens at the end of Bytecode::Generator::generate() and the only really hairy part is rerouting jump labels. This required solving a few problems: - The interpreter execution loop had to change quite a bit, since we were storing BasicBlock pointers all over the place, and control transfer was done by redirecting the interpreter's current block. - Exception handlers & finalizers are now stored per-bytecode-range in a side table in Executable. - The interpreter now has a plain program counter instead of a stream iterator. This actually makes error stack generation a bit nicer since we just have to deal with a number instead of reaching into the iterator. This yields a 25% performance improvement on this microbenchmark: for (let i = 0; i < 1_000_000; ++i) { } But basically everything gets faster. :^)
2024-05-06 06:44:08 +02:00
Interpreter::HandleExceptionResponse Interpreter::handle_exception(size_t& program_counter, Value exception)
LibJS: Start fleshing out a bytecode for the JavaScript engine :^) This patch begins the work of implementing JavaScript execution in a bytecode VM instead of an AST tree-walk interpreter. It's probably quite naive, but we have to start somewhere. The basic idea is that you call Bytecode::Generator::generate() on an AST node and it hands you back a Bytecode::Block filled with instructions that can then be interpreted by a Bytecode::Interpreter. This first version only implements two instructions: Load and Add. :^) Each bytecode block has infinity registers, and the interpreter resizes its register file to fit the block being executed. Two new `js` options are added in this patch as well: `-d` will dump the generated bytecode `-b` will execute the generated bytecode Note that unless `-d` and/or `-b` are specified, none of the bytecode related stuff in LibJS runs at all. This is implemented in parallel with the existing AST interpreter. :^)
2021-06-03 10:46:30 +02:00
{
LibJS/Bytecode: Flatten bytecode to a contiguous representation Instead of keeping bytecode as a set of disjoint basic blocks on the malloc heap, bytecode is now a contiguous sequence of bytes(!) The transformation happens at the end of Bytecode::Generator::generate() and the only really hairy part is rerouting jump labels. This required solving a few problems: - The interpreter execution loop had to change quite a bit, since we were storing BasicBlock pointers all over the place, and control transfer was done by redirecting the interpreter's current block. - Exception handlers & finalizers are now stored per-bytecode-range in a side table in Executable. - The interpreter now has a plain program counter instead of a stream iterator. This actually makes error stack generation a bit nicer since we just have to deal with a number instead of reaching into the iterator. This yields a 25% performance improvement on this microbenchmark: for (let i = 0; i < 1_000_000; ++i) { } But basically everything gets faster. :^)
2024-05-06 06:44:08 +02:00
reg(Register::exception()) = exception;
m_scheduled_jump = {};
auto handlers = current_executable().exception_handlers_for_offset(program_counter);
if (!handlers.has_value()) {
return HandleExceptionResponse::ExitFromExecutable;
}
auto& handler = handlers->handler_offset;
auto& finalizer = handlers->finalizer_offset;
VERIFY(!vm().running_execution_context().unwind_contexts.is_empty());
auto& unwind_context = vm().running_execution_context().unwind_contexts.last();
VERIFY(unwind_context.executable == m_current_executable);
if (handler.has_value()) {
program_counter = handler.value();
return HandleExceptionResponse::ContinueInThisExecutable;
}
if (finalizer.has_value()) {
program_counter = finalizer.value();
return HandleExceptionResponse::ContinueInThisExecutable;
}
VERIFY_NOT_REACHED();
}
#define NEXT_INSTRUCTION() \
program_counter += instruction.length(); \
goto start;
void Interpreter::run_bytecode(size_t entry_point)
{
auto& running_execution_context = vm().running_execution_context();
auto* locals = running_execution_context.locals.data();
LibJS: Inline bytecode ops for direct local/register access These can do a lot less stuff if we put them directly in the interpreter loop and allow them to access the locals/registers arrays directly.
2023-09-27 10:31:07 +02:00
auto& accumulator = this->accumulator();
LibJS/Bytecode: Flatten bytecode to a contiguous representation Instead of keeping bytecode as a set of disjoint basic blocks on the malloc heap, bytecode is now a contiguous sequence of bytes(!) The transformation happens at the end of Bytecode::Generator::generate() and the only really hairy part is rerouting jump labels. This required solving a few problems: - The interpreter execution loop had to change quite a bit, since we were storing BasicBlock pointers all over the place, and control transfer was done by redirecting the interpreter's current block. - Exception handlers & finalizers are now stored per-bytecode-range in a side table in Executable. - The interpreter now has a plain program counter instead of a stream iterator. This actually makes error stack generation a bit nicer since we just have to deal with a number instead of reaching into the iterator. This yields a 25% performance improvement on this microbenchmark: for (let i = 0; i < 1_000_000; ++i) { } But basically everything gets faster. :^)
2024-05-06 06:44:08 +02:00
auto& executable = current_executable();
auto const* bytecode = executable.bytecode.data();
size_t program_counter = entry_point;
TemporaryChange change(m_program_counter, Optional<size_t&>(program_counter));
LibJS: Generate bytecode in basic blocks instead of one big block This limits the size of each block (currently set to 1K), and gets us closer to a canonical, more easily analysable bytecode format. As a result of this, "Labels" are now simply entries to basic blocks. Since there is no more 'conditional' jump (as all jumps are always taken), JumpIf{True,False} are unified to JumpConditional, and JumpIfNullish is renamed to JumpNullish. Also fixes #7914 as a result of reimplementing the loop logic.
2021-06-09 06:49:58 +04:30
for (;;) {
LibJS: Use `goto` instead of `bool will_jump` in interpreter loop This is honestly less spaghetti-ish.
2023-09-26 16:45:55 +02:00
start:
LibJS: Generate bytecode in basic blocks instead of one big block This limits the size of each block (currently set to 1K), and gets us closer to a canonical, more easily analysable bytecode format. As a result of this, "Labels" are now simply entries to basic blocks. Since there is no more 'conditional' jump (as all jumps are always taken), JumpIf{True,False} are unified to JumpConditional, and JumpIfNullish is renamed to JumpNullish. Also fixes #7914 as a result of reimplementing the loop logic.
2021-06-09 06:49:58 +04:30
bool will_return = false;
LibJS: Don't enter finally blocks upon `yield` in bytecode mode
2022-12-06 20:45:38 +01:00
bool will_yield = false;
LibJS: Move bytecode interpreter's inner loop to its own function
2023-09-26 16:41:42 +02:00
LibJS/Bytecode: Flatten bytecode to a contiguous representation Instead of keeping bytecode as a set of disjoint basic blocks on the malloc heap, bytecode is now a contiguous sequence of bytes(!) The transformation happens at the end of Bytecode::Generator::generate() and the only really hairy part is rerouting jump labels. This required solving a few problems: - The interpreter execution loop had to change quite a bit, since we were storing BasicBlock pointers all over the place, and control transfer was done by redirecting the interpreter's current block. - Exception handlers & finalizers are now stored per-bytecode-range in a side table in Executable. - The interpreter now has a plain program counter instead of a stream iterator. This actually makes error stack generation a bit nicer since we just have to deal with a number instead of reaching into the iterator. This yields a 25% performance improvement on this microbenchmark: for (let i = 0; i < 1_000_000; ++i) { } But basically everything gets faster. :^)
2024-05-06 06:44:08 +02:00
for (;;) {
auto& instruction = *reinterpret_cast<Instruction const*>(&bytecode[program_counter]);
LibJS: Return early from Interpreter on unhandled exception If we don't have a local unwind context to handle the exception, we can just return right away. This allows us to remove one check from the inner loop.
2023-09-26 17:14:59 +02:00
LibJS: Inline flow control ops in the bytecode interpreter loop Instead of calling out to helper functions for flow control (and then checking control flags on every iteration), we now simply inline those ops in the interpreter loop directly.
2023-09-26 19:43:44 +02:00
switch (instruction.type()) {
LibJS: Inline bytecode ops for direct local/register access These can do a lot less stuff if we put them directly in the interpreter loop and allow them to access the locals/registers arrays directly.
2023-09-27 10:31:07 +02:00
case Instruction::Type::SetLocal:
LibJS/Bytecode: Move to a new bytecode format This patch moves us away from the accumulator-based bytecode format to one with explicit source and destination registers. The new format has multiple benefits: - ~25% faster on the Kraken and Octane benchmarks :^) - Fewer instructions to accomplish the same thing - Much easier for humans to read(!) Because this change requires a fundamental shift in how bytecode is generated, it is quite comprehensive. Main implementation mechanism: generate_bytecode() virtual function now takes an optional "preferred dst" operand, which allows callers to communicate when they have an operand that would be optimal for the result to go into. It also returns an optional "actual dst" operand, which is where the completion value (if any) of the AST node is stored after the node has "executed". One thing of note that's new: because instructions can now take locals as operands, this means we got rid of the GetLocal instruction. A side-effect of that is we have to think about the temporal deadzone (TDZ) a bit differently for locals (GetLocal would previously check for empty values and interpret that as a TDZ access and throw). We now insert special ThrowIfTDZ instructions in places where a local access may be in the TDZ, to maintain the correct behavior. There are a number of progressions and regressions from this test: A number of async generator tests have been accidentally fixed while converting the implementation to the new bytecode format. It didn't seem useful to preserve bugs in the original code when converting it. Some "does eval() return the correct completion value" tests have regressed, in particular ones related to propagating the appropriate completion after control flow statements like continue and break. These are all fairly obscure issues, and I believe we can continue working on them separately. The net test262 result is a progression though. :^)
2024-02-04 08:00:54 +01:00
locals[static_cast<Op::SetLocal const&>(instruction).index()] = get(static_cast<Op::SetLocal const&>(instruction).src());
LibJS/Bytecode: Flatten bytecode to a contiguous representation Instead of keeping bytecode as a set of disjoint basic blocks on the malloc heap, bytecode is now a contiguous sequence of bytes(!) The transformation happens at the end of Bytecode::Generator::generate() and the only really hairy part is rerouting jump labels. This required solving a few problems: - The interpreter execution loop had to change quite a bit, since we were storing BasicBlock pointers all over the place, and control transfer was done by redirecting the interpreter's current block. - Exception handlers & finalizers are now stored per-bytecode-range in a side table in Executable. - The interpreter now has a plain program counter instead of a stream iterator. This actually makes error stack generation a bit nicer since we just have to deal with a number instead of reaching into the iterator. This yields a 25% performance improvement on this microbenchmark: for (let i = 0; i < 1_000_000; ++i) { } But basically everything gets faster. :^)
2024-05-06 06:44:08 +02:00
NEXT_INSTRUCTION();
LibJS/Bytecode: Move to a new bytecode format This patch moves us away from the accumulator-based bytecode format to one with explicit source and destination registers. The new format has multiple benefits: - ~25% faster on the Kraken and Octane benchmarks :^) - Fewer instructions to accomplish the same thing - Much easier for humans to read(!) Because this change requires a fundamental shift in how bytecode is generated, it is quite comprehensive. Main implementation mechanism: generate_bytecode() virtual function now takes an optional "preferred dst" operand, which allows callers to communicate when they have an operand that would be optimal for the result to go into. It also returns an optional "actual dst" operand, which is where the completion value (if any) of the AST node is stored after the node has "executed". One thing of note that's new: because instructions can now take locals as operands, this means we got rid of the GetLocal instruction. A side-effect of that is we have to think about the temporal deadzone (TDZ) a bit differently for locals (GetLocal would previously check for empty values and interpret that as a TDZ access and throw). We now insert special ThrowIfTDZ instructions in places where a local access may be in the TDZ, to maintain the correct behavior. There are a number of progressions and regressions from this test: A number of async generator tests have been accidentally fixed while converting the implementation to the new bytecode format. It didn't seem useful to preserve bugs in the original code when converting it. Some "does eval() return the correct completion value" tests have regressed, in particular ones related to propagating the appropriate completion after control flow statements like continue and break. These are all fairly obscure issues, and I believe we can continue working on them separately. The net test262 result is a progression though. :^)
2024-02-04 08:00:54 +01:00
case Instruction::Type::Mov:
set(static_cast<Op::Mov const&>(instruction).dst(), get(static_cast<Op::Mov const&>(instruction).src()));
LibJS/Bytecode: Flatten bytecode to a contiguous representation Instead of keeping bytecode as a set of disjoint basic blocks on the malloc heap, bytecode is now a contiguous sequence of bytes(!) The transformation happens at the end of Bytecode::Generator::generate() and the only really hairy part is rerouting jump labels. This required solving a few problems: - The interpreter execution loop had to change quite a bit, since we were storing BasicBlock pointers all over the place, and control transfer was done by redirecting the interpreter's current block. - Exception handlers & finalizers are now stored per-bytecode-range in a side table in Executable. - The interpreter now has a plain program counter instead of a stream iterator. This actually makes error stack generation a bit nicer since we just have to deal with a number instead of reaching into the iterator. This yields a 25% performance improvement on this microbenchmark: for (let i = 0; i < 1_000_000; ++i) { } But basically everything gets faster. :^)
2024-05-06 06:44:08 +02:00
NEXT_INSTRUCTION();
LibJS/Bytecode: Move to a new bytecode format This patch moves us away from the accumulator-based bytecode format to one with explicit source and destination registers. The new format has multiple benefits: - ~25% faster on the Kraken and Octane benchmarks :^) - Fewer instructions to accomplish the same thing - Much easier for humans to read(!) Because this change requires a fundamental shift in how bytecode is generated, it is quite comprehensive. Main implementation mechanism: generate_bytecode() virtual function now takes an optional "preferred dst" operand, which allows callers to communicate when they have an operand that would be optimal for the result to go into. It also returns an optional "actual dst" operand, which is where the completion value (if any) of the AST node is stored after the node has "executed". One thing of note that's new: because instructions can now take locals as operands, this means we got rid of the GetLocal instruction. A side-effect of that is we have to think about the temporal deadzone (TDZ) a bit differently for locals (GetLocal would previously check for empty values and interpret that as a TDZ access and throw). We now insert special ThrowIfTDZ instructions in places where a local access may be in the TDZ, to maintain the correct behavior. There are a number of progressions and regressions from this test: A number of async generator tests have been accidentally fixed while converting the implementation to the new bytecode format. It didn't seem useful to preserve bugs in the original code when converting it. Some "does eval() return the correct completion value" tests have regressed, in particular ones related to propagating the appropriate completion after control flow statements like continue and break. These are all fairly obscure issues, and I believe we can continue working on them separately. The net test262 result is a progression though. :^)
2024-02-04 08:00:54 +01:00
case Instruction::Type::End:
accumulator = get(static_cast<Op::End const&>(instruction).value());
return;
LibJS: Inline flow control ops in the bytecode interpreter loop Instead of calling out to helper functions for flow control (and then checking control flags on every iteration), we now simply inline those ops in the interpreter loop directly.
2023-09-26 19:43:44 +02:00
case Instruction::Type::Jump:
LibJS/Bytecode: Flatten bytecode to a contiguous representation Instead of keeping bytecode as a set of disjoint basic blocks on the malloc heap, bytecode is now a contiguous sequence of bytes(!) The transformation happens at the end of Bytecode::Generator::generate() and the only really hairy part is rerouting jump labels. This required solving a few problems: - The interpreter execution loop had to change quite a bit, since we were storing BasicBlock pointers all over the place, and control transfer was done by redirecting the interpreter's current block. - Exception handlers & finalizers are now stored per-bytecode-range in a side table in Executable. - The interpreter now has a plain program counter instead of a stream iterator. This actually makes error stack generation a bit nicer since we just have to deal with a number instead of reaching into the iterator. This yields a 25% performance improvement on this microbenchmark: for (let i = 0; i < 1_000_000; ++i) { } But basically everything gets faster. :^)
2024-05-06 06:44:08 +02:00
program_counter = static_cast<Op::Jump const&>(instruction).target().address();
LibJS: Inline flow control ops in the bytecode interpreter loop Instead of calling out to helper functions for flow control (and then checking control flags on every iteration), we now simply inline those ops in the interpreter loop directly.
2023-09-26 19:43:44 +02:00
goto start;
LibJS/Bytecode: Make each Jump instruction inherit Instruction directly Before this change, all JumpFoo instructions inherited from Jump, which forced the unconditional Jump to have an unusued "false target" member. Also, labels were unnecessarily wrapped in Optional<>. By defining each jump instruction separately, they all shrink in size, and all ambiguity is removed.
2024-05-05 11:52:14 +02:00
case Instruction::Type::JumpIf: {
auto& jump = static_cast<Op::JumpIf const&>(instruction);
if (get(jump.condition()).to_boolean())
LibJS/Bytecode: Flatten bytecode to a contiguous representation Instead of keeping bytecode as a set of disjoint basic blocks on the malloc heap, bytecode is now a contiguous sequence of bytes(!) The transformation happens at the end of Bytecode::Generator::generate() and the only really hairy part is rerouting jump labels. This required solving a few problems: - The interpreter execution loop had to change quite a bit, since we were storing BasicBlock pointers all over the place, and control transfer was done by redirecting the interpreter's current block. - Exception handlers & finalizers are now stored per-bytecode-range in a side table in Executable. - The interpreter now has a plain program counter instead of a stream iterator. This actually makes error stack generation a bit nicer since we just have to deal with a number instead of reaching into the iterator. This yields a 25% performance improvement on this microbenchmark: for (let i = 0; i < 1_000_000; ++i) { } But basically everything gets faster. :^)
2024-05-06 06:44:08 +02:00
program_counter = jump.true_target().address();
LibJS: Inline flow control ops in the bytecode interpreter loop Instead of calling out to helper functions for flow control (and then checking control flags on every iteration), we now simply inline those ops in the interpreter loop directly.
2023-09-26 19:43:44 +02:00
else
LibJS/Bytecode: Flatten bytecode to a contiguous representation Instead of keeping bytecode as a set of disjoint basic blocks on the malloc heap, bytecode is now a contiguous sequence of bytes(!) The transformation happens at the end of Bytecode::Generator::generate() and the only really hairy part is rerouting jump labels. This required solving a few problems: - The interpreter execution loop had to change quite a bit, since we were storing BasicBlock pointers all over the place, and control transfer was done by redirecting the interpreter's current block. - Exception handlers & finalizers are now stored per-bytecode-range in a side table in Executable. - The interpreter now has a plain program counter instead of a stream iterator. This actually makes error stack generation a bit nicer since we just have to deal with a number instead of reaching into the iterator. This yields a 25% performance improvement on this microbenchmark: for (let i = 0; i < 1_000_000; ++i) { } But basically everything gets faster. :^)
2024-05-06 06:44:08 +02:00
program_counter = jump.false_target().address();
LibJS: Inline flow control ops in the bytecode interpreter loop Instead of calling out to helper functions for flow control (and then checking control flags on every iteration), we now simply inline those ops in the interpreter loop directly.
2023-09-26 19:43:44 +02:00
goto start;
LibJS/Bytecode: Make each Jump instruction inherit Instruction directly Before this change, all JumpFoo instructions inherited from Jump, which forced the unconditional Jump to have an unusued "false target" member. Also, labels were unnecessarily wrapped in Optional<>. By defining each jump instruction separately, they all shrink in size, and all ambiguity is removed.
2024-05-05 11:52:14 +02:00
}
LibJS/Bytecode: Turn JumpIf condition,@a,@next into JumpTrue/JumpFalse If one of the jump targets is the very next block, we can convert the jump instruction into a smaller JumpTrue or JumpFalse.
2024-05-06 10:15:17 +02:00
case Instruction::Type::JumpTrue: {
auto& jump = static_cast<Op::JumpTrue const&>(instruction);
if (get(jump.condition()).to_boolean()) {
program_counter = jump.target().address();
goto start;
}
NEXT_INSTRUCTION();
}
case Instruction::Type::JumpFalse: {
auto& jump = static_cast<Op::JumpFalse const&>(instruction);
if (!get(jump.condition()).to_boolean()) {
program_counter = jump.target().address();
goto start;
}
NEXT_INSTRUCTION();
}
LibJS/Bytecode: Make each Jump instruction inherit Instruction directly Before this change, all JumpFoo instructions inherited from Jump, which forced the unconditional Jump to have an unusued "false target" member. Also, labels were unnecessarily wrapped in Optional<>. By defining each jump instruction separately, they all shrink in size, and all ambiguity is removed.
2024-05-05 11:52:14 +02:00
case Instruction::Type::JumpNullish: {
auto& jump = static_cast<Op::JumpNullish const&>(instruction);
if (get(jump.condition()).is_nullish())
LibJS/Bytecode: Flatten bytecode to a contiguous representation Instead of keeping bytecode as a set of disjoint basic blocks on the malloc heap, bytecode is now a contiguous sequence of bytes(!) The transformation happens at the end of Bytecode::Generator::generate() and the only really hairy part is rerouting jump labels. This required solving a few problems: - The interpreter execution loop had to change quite a bit, since we were storing BasicBlock pointers all over the place, and control transfer was done by redirecting the interpreter's current block. - Exception handlers & finalizers are now stored per-bytecode-range in a side table in Executable. - The interpreter now has a plain program counter instead of a stream iterator. This actually makes error stack generation a bit nicer since we just have to deal with a number instead of reaching into the iterator. This yields a 25% performance improvement on this microbenchmark: for (let i = 0; i < 1_000_000; ++i) { } But basically everything gets faster. :^)
2024-05-06 06:44:08 +02:00
program_counter = jump.true_target().address();
LibJS: Inline flow control ops in the bytecode interpreter loop Instead of calling out to helper functions for flow control (and then checking control flags on every iteration), we now simply inline those ops in the interpreter loop directly.
2023-09-26 19:43:44 +02:00
else
LibJS/Bytecode: Flatten bytecode to a contiguous representation Instead of keeping bytecode as a set of disjoint basic blocks on the malloc heap, bytecode is now a contiguous sequence of bytes(!) The transformation happens at the end of Bytecode::Generator::generate() and the only really hairy part is rerouting jump labels. This required solving a few problems: - The interpreter execution loop had to change quite a bit, since we were storing BasicBlock pointers all over the place, and control transfer was done by redirecting the interpreter's current block. - Exception handlers & finalizers are now stored per-bytecode-range in a side table in Executable. - The interpreter now has a plain program counter instead of a stream iterator. This actually makes error stack generation a bit nicer since we just have to deal with a number instead of reaching into the iterator. This yields a 25% performance improvement on this microbenchmark: for (let i = 0; i < 1_000_000; ++i) { } But basically everything gets faster. :^)
2024-05-06 06:44:08 +02:00
program_counter = jump.false_target().address();
LibJS: Inline flow control ops in the bytecode interpreter loop Instead of calling out to helper functions for flow control (and then checking control flags on every iteration), we now simply inline those ops in the interpreter loop directly.
2023-09-26 19:43:44 +02:00
goto start;
LibJS/Bytecode: Make each Jump instruction inherit Instruction directly Before this change, all JumpFoo instructions inherited from Jump, which forced the unconditional Jump to have an unusued "false target" member. Also, labels were unnecessarily wrapped in Optional<>. By defining each jump instruction separately, they all shrink in size, and all ambiguity is removed.
2024-05-05 11:52:14 +02:00
}
case Instruction::Type::JumpUndefined: {
auto& jump = static_cast<Op::JumpUndefined const&>(instruction);
if (get(jump.condition()).is_undefined())
LibJS/Bytecode: Flatten bytecode to a contiguous representation Instead of keeping bytecode as a set of disjoint basic blocks on the malloc heap, bytecode is now a contiguous sequence of bytes(!) The transformation happens at the end of Bytecode::Generator::generate() and the only really hairy part is rerouting jump labels. This required solving a few problems: - The interpreter execution loop had to change quite a bit, since we were storing BasicBlock pointers all over the place, and control transfer was done by redirecting the interpreter's current block. - Exception handlers & finalizers are now stored per-bytecode-range in a side table in Executable. - The interpreter now has a plain program counter instead of a stream iterator. This actually makes error stack generation a bit nicer since we just have to deal with a number instead of reaching into the iterator. This yields a 25% performance improvement on this microbenchmark: for (let i = 0; i < 1_000_000; ++i) { } But basically everything gets faster. :^)
2024-05-06 06:44:08 +02:00
program_counter = jump.true_target().address();
LibJS: Inline flow control ops in the bytecode interpreter loop Instead of calling out to helper functions for flow control (and then checking control flags on every iteration), we now simply inline those ops in the interpreter loop directly.
2023-09-26 19:43:44 +02:00
else
LibJS/Bytecode: Flatten bytecode to a contiguous representation Instead of keeping bytecode as a set of disjoint basic blocks on the malloc heap, bytecode is now a contiguous sequence of bytes(!) The transformation happens at the end of Bytecode::Generator::generate() and the only really hairy part is rerouting jump labels. This required solving a few problems: - The interpreter execution loop had to change quite a bit, since we were storing BasicBlock pointers all over the place, and control transfer was done by redirecting the interpreter's current block. - Exception handlers & finalizers are now stored per-bytecode-range in a side table in Executable. - The interpreter now has a plain program counter instead of a stream iterator. This actually makes error stack generation a bit nicer since we just have to deal with a number instead of reaching into the iterator. This yields a 25% performance improvement on this microbenchmark: for (let i = 0; i < 1_000_000; ++i) { } But basically everything gets faster. :^)
2024-05-06 06:44:08 +02:00
program_counter = jump.false_target().address();
LibJS: Inline flow control ops in the bytecode interpreter loop Instead of calling out to helper functions for flow control (and then checking control flags on every iteration), we now simply inline those ops in the interpreter loop directly.
2023-09-26 19:43:44 +02:00
goto start;
LibJS/Bytecode: Make each Jump instruction inherit Instruction directly Before this change, all JumpFoo instructions inherited from Jump, which forced the unconditional Jump to have an unusued "false target" member. Also, labels were unnecessarily wrapped in Optional<>. By defining each jump instruction separately, they all shrink in size, and all ambiguity is removed.
2024-05-05 11:52:14 +02:00
}
LibJS: Inline flow control ops in the bytecode interpreter loop Instead of calling out to helper functions for flow control (and then checking control flags on every iteration), we now simply inline those ops in the interpreter loop directly.
2023-09-26 19:43:44 +02:00
case Instruction::Type::EnterUnwindContext:
LibJS: Use static unwind mappings for unwind related functions
2023-10-20 00:33:51 +02:00
enter_unwind_context();
LibJS/Bytecode: Flatten bytecode to a contiguous representation Instead of keeping bytecode as a set of disjoint basic blocks on the malloc heap, bytecode is now a contiguous sequence of bytes(!) The transformation happens at the end of Bytecode::Generator::generate() and the only really hairy part is rerouting jump labels. This required solving a few problems: - The interpreter execution loop had to change quite a bit, since we were storing BasicBlock pointers all over the place, and control transfer was done by redirecting the interpreter's current block. - Exception handlers & finalizers are now stored per-bytecode-range in a side table in Executable. - The interpreter now has a plain program counter instead of a stream iterator. This actually makes error stack generation a bit nicer since we just have to deal with a number instead of reaching into the iterator. This yields a 25% performance improvement on this microbenchmark: for (let i = 0; i < 1_000_000; ++i) { } But basically everything gets faster. :^)
2024-05-06 06:44:08 +02:00
program_counter = static_cast<Op::EnterUnwindContext const&>(instruction).entry_point().address();
LibJS: Inline flow control ops in the bytecode interpreter loop Instead of calling out to helper functions for flow control (and then checking control flags on every iteration), we now simply inline those ops in the interpreter loop directly.
2023-09-26 19:43:44 +02:00
goto start;
LibJS: Save scheduled jumps when entering unwind contexts These are then restored upon `ContinuePendingUnwind`. This stops us from forgetting where we needed to jump when we do extra try-catches in finally blocks. Co-Authored-By: Jesús "gsus" Lapastora <cyber.gsuscode@gmail.com>
2023-10-21 22:46:40 +02:00
case Instruction::Type::ContinuePendingUnwind: {
LibJS: Inline flow control ops in the bytecode interpreter loop Instead of calling out to helper functions for flow control (and then checking control flags on every iteration), we now simply inline those ops in the interpreter loop directly.
2023-09-26 19:43:44 +02:00
if (auto exception = reg(Register::exception()); !exception.is_empty()) {
LibJS/Bytecode: Flatten bytecode to a contiguous representation Instead of keeping bytecode as a set of disjoint basic blocks on the malloc heap, bytecode is now a contiguous sequence of bytes(!) The transformation happens at the end of Bytecode::Generator::generate() and the only really hairy part is rerouting jump labels. This required solving a few problems: - The interpreter execution loop had to change quite a bit, since we were storing BasicBlock pointers all over the place, and control transfer was done by redirecting the interpreter's current block. - Exception handlers & finalizers are now stored per-bytecode-range in a side table in Executable. - The interpreter now has a plain program counter instead of a stream iterator. This actually makes error stack generation a bit nicer since we just have to deal with a number instead of reaching into the iterator. This yields a 25% performance improvement on this microbenchmark: for (let i = 0; i < 1_000_000; ++i) { } But basically everything gets faster. :^)
2024-05-06 06:44:08 +02:00
if (handle_exception(program_counter, exception) == HandleExceptionResponse::ExitFromExecutable)
return;
goto start;
LibJS: Inline flow control ops in the bytecode interpreter loop Instead of calling out to helper functions for flow control (and then checking control flags on every iteration), we now simply inline those ops in the interpreter loop directly.
2023-09-26 19:43:44 +02:00
}
if (!saved_return_value().is_empty()) {
do_return(saved_return_value());
LibJS/Bytecode: Flatten bytecode to a contiguous representation Instead of keeping bytecode as a set of disjoint basic blocks on the malloc heap, bytecode is now a contiguous sequence of bytes(!) The transformation happens at the end of Bytecode::Generator::generate() and the only really hairy part is rerouting jump labels. This required solving a few problems: - The interpreter execution loop had to change quite a bit, since we were storing BasicBlock pointers all over the place, and control transfer was done by redirecting the interpreter's current block. - Exception handlers & finalizers are now stored per-bytecode-range in a side table in Executable. - The interpreter now has a plain program counter instead of a stream iterator. This actually makes error stack generation a bit nicer since we just have to deal with a number instead of reaching into the iterator. This yields a 25% performance improvement on this microbenchmark: for (let i = 0; i < 1_000_000; ++i) { } But basically everything gets faster. :^)
2024-05-06 06:44:08 +02:00
goto may_return;
LibJS: Inline flow control ops in the bytecode interpreter loop Instead of calling out to helper functions for flow control (and then checking control flags on every iteration), we now simply inline those ops in the interpreter loop directly.
2023-09-26 19:43:44 +02:00
}
LibJS/Bytecode: Flatten bytecode to a contiguous representation Instead of keeping bytecode as a set of disjoint basic blocks on the malloc heap, bytecode is now a contiguous sequence of bytes(!) The transformation happens at the end of Bytecode::Generator::generate() and the only really hairy part is rerouting jump labels. This required solving a few problems: - The interpreter execution loop had to change quite a bit, since we were storing BasicBlock pointers all over the place, and control transfer was done by redirecting the interpreter's current block. - Exception handlers & finalizers are now stored per-bytecode-range in a side table in Executable. - The interpreter now has a plain program counter instead of a stream iterator. This actually makes error stack generation a bit nicer since we just have to deal with a number instead of reaching into the iterator. This yields a 25% performance improvement on this microbenchmark: for (let i = 0; i < 1_000_000; ++i) { } But basically everything gets faster. :^)
2024-05-06 06:44:08 +02:00
auto const old_scheduled_jump = running_execution_context.previously_scheduled_jumps.take_last();
if (m_scheduled_jump.has_value()) {
program_counter = m_scheduled_jump.value();
m_scheduled_jump = {};
LibJS: Inline flow control ops in the bytecode interpreter loop Instead of calling out to helper functions for flow control (and then checking control flags on every iteration), we now simply inline those ops in the interpreter loop directly.
2023-09-26 19:43:44 +02:00
} else {
LibJS/Bytecode: Flatten bytecode to a contiguous representation Instead of keeping bytecode as a set of disjoint basic blocks on the malloc heap, bytecode is now a contiguous sequence of bytes(!) The transformation happens at the end of Bytecode::Generator::generate() and the only really hairy part is rerouting jump labels. This required solving a few problems: - The interpreter execution loop had to change quite a bit, since we were storing BasicBlock pointers all over the place, and control transfer was done by redirecting the interpreter's current block. - Exception handlers & finalizers are now stored per-bytecode-range in a side table in Executable. - The interpreter now has a plain program counter instead of a stream iterator. This actually makes error stack generation a bit nicer since we just have to deal with a number instead of reaching into the iterator. This yields a 25% performance improvement on this microbenchmark: for (let i = 0; i < 1_000_000; ++i) { } But basically everything gets faster. :^)
2024-05-06 06:44:08 +02:00
program_counter = static_cast<Op::ContinuePendingUnwind const&>(instruction).resume_target().address();
LibJS: Save scheduled jumps when entering unwind contexts These are then restored upon `ContinuePendingUnwind`. This stops us from forgetting where we needed to jump when we do extra try-catches in finally blocks. Co-Authored-By: Jesús "gsus" Lapastora <cyber.gsuscode@gmail.com>
2023-10-21 22:46:40 +02:00
// set the scheduled jump to the old value if we continue
// where we left it
m_scheduled_jump = old_scheduled_jump;
LibJS: Inline flow control ops in the bytecode interpreter loop Instead of calling out to helper functions for flow control (and then checking control flags on every iteration), we now simply inline those ops in the interpreter loop directly.
2023-09-26 19:43:44 +02:00
}
goto start;
LibJS: Save scheduled jumps when entering unwind contexts These are then restored upon `ContinuePendingUnwind`. This stops us from forgetting where we needed to jump when we do extra try-catches in finally blocks. Co-Authored-By: Jesús "gsus" Lapastora <cyber.gsuscode@gmail.com>
2023-10-21 22:46:40 +02:00
}
LibJS: Use static unwind mappings for unwind related functions
2023-10-20 00:33:51 +02:00
case Instruction::Type::ScheduleJump: {
LibJS/Bytecode: Flatten bytecode to a contiguous representation Instead of keeping bytecode as a set of disjoint basic blocks on the malloc heap, bytecode is now a contiguous sequence of bytes(!) The transformation happens at the end of Bytecode::Generator::generate() and the only really hairy part is rerouting jump labels. This required solving a few problems: - The interpreter execution loop had to change quite a bit, since we were storing BasicBlock pointers all over the place, and control transfer was done by redirecting the interpreter's current block. - Exception handlers & finalizers are now stored per-bytecode-range in a side table in Executable. - The interpreter now has a plain program counter instead of a stream iterator. This actually makes error stack generation a bit nicer since we just have to deal with a number instead of reaching into the iterator. This yields a 25% performance improvement on this microbenchmark: for (let i = 0; i < 1_000_000; ++i) { } But basically everything gets faster. :^)
2024-05-06 06:44:08 +02:00
m_scheduled_jump = static_cast<Op::ScheduleJump const&>(instruction).target().address();
auto finalizer = executable.exception_handlers_for_offset(program_counter).value().finalizer_offset;
VERIFY(finalizer.has_value());
program_counter = finalizer.value();
LibJS: Inline flow control ops in the bytecode interpreter loop Instead of calling out to helper functions for flow control (and then checking control flags on every iteration), we now simply inline those ops in the interpreter loop directly.
2023-09-26 19:43:44 +02:00
goto start;
LibJS: Use static unwind mappings for unwind related functions
2023-10-20 00:33:51 +02:00
}
LibJS: Inline flow control ops in the bytecode interpreter loop Instead of calling out to helper functions for flow control (and then checking control flags on every iteration), we now simply inline those ops in the interpreter loop directly.
2023-09-26 19:43:44 +02:00
default:
break;
}
LibJS/Bytecode: Flatten bytecode to a contiguous representation Instead of keeping bytecode as a set of disjoint basic blocks on the malloc heap, bytecode is now a contiguous sequence of bytes(!) The transformation happens at the end of Bytecode::Generator::generate() and the only really hairy part is rerouting jump labels. This required solving a few problems: - The interpreter execution loop had to change quite a bit, since we were storing BasicBlock pointers all over the place, and control transfer was done by redirecting the interpreter's current block. - Exception handlers & finalizers are now stored per-bytecode-range in a side table in Executable. - The interpreter now has a plain program counter instead of a stream iterator. This actually makes error stack generation a bit nicer since we just have to deal with a number instead of reaching into the iterator. This yields a 25% performance improvement on this microbenchmark: for (let i = 0; i < 1_000_000; ++i) { } But basically everything gets faster. :^)
2024-05-06 06:44:08 +02:00
{
auto result = instruction.execute(*this);
LibJS: Use static unwind mappings for unwind related functions
2023-10-20 00:33:51 +02:00
LibJS/Bytecode: Flatten bytecode to a contiguous representation Instead of keeping bytecode as a set of disjoint basic blocks on the malloc heap, bytecode is now a contiguous sequence of bytes(!) The transformation happens at the end of Bytecode::Generator::generate() and the only really hairy part is rerouting jump labels. This required solving a few problems: - The interpreter execution loop had to change quite a bit, since we were storing BasicBlock pointers all over the place, and control transfer was done by redirecting the interpreter's current block. - Exception handlers & finalizers are now stored per-bytecode-range in a side table in Executable. - The interpreter now has a plain program counter instead of a stream iterator. This actually makes error stack generation a bit nicer since we just have to deal with a number instead of reaching into the iterator. This yields a 25% performance improvement on this microbenchmark: for (let i = 0; i < 1_000_000; ++i) { } But basically everything gets faster. :^)
2024-05-06 06:44:08 +02:00
if (result.is_error()) {
if (handle_exception(program_counter, *result.throw_completion().value()) == HandleExceptionResponse::ExitFromExecutable)
return;
LibJS: Use `goto` instead of `bool will_jump` in interpreter loop This is honestly less spaghetti-ish.
2023-09-26 16:45:55 +02:00
goto start;
LibJS: Implement bytecode generation for try..catch..finally EnterUnwindContext pushes an unwind context (exception handler and/or finalizer) onto a stack. LeaveUnwindContext pops the unwind context from that stack. Upon return to the interpreter loop we check whether the VM has an exception pending. If no unwind context is available we return from the loop. If an exception handler is available we clear the VM's exception, put the exception value into the accumulator register, clear the unwind context's handler and jump to the handler. If no handler is available but a finalizer is available we save the exception value + metadata (for later use by ContinuePendingUnwind), clear the VM's exception, pop the unwind context and jump to the finalizer. ContinuePendingUnwind checks whether a saved exception is available. If no saved exception is available it jumps to the resume label. Otherwise it stores the exception into the VM. The Jump after LeaveUnwindContext could be integrated into the LeaveUnwindContext instruction. I've kept them separate for now to make the bytecode more readable. > try { 1; throw "x" } catch (e) { 2 } finally { 3 }; 4 1: [ 0] EnterScope [ 10] EnterUnwindContext handler:@4 finalizer:@3 [ 38] EnterScope [ 48] LoadImmediate 1 [ 60] NewString 1 ("x") [ 70] Throw <for non-terminated blocks: insert LeaveUnwindContext + Jump @3 here> 2: [ 0] LoadImmediate 4 3: [ 0] EnterScope [ 10] LoadImmediate 3 [ 28] ContinuePendingUnwind resume:@2 4: [ 0] SetVariable 0 (e) [ 10] EnterScope [ 20] LoadImmediate 2 [ 38] LeaveUnwindContext [ 3c] Jump @3 String Table: 0: e 1: x
2021-06-10 15:04:38 +02:00
}
}
LibJS: Inline flow control ops in the bytecode interpreter loop Instead of calling out to helper functions for flow control (and then checking control flags on every iteration), we now simply inline those ops in the interpreter loop directly.
2023-09-26 19:43:44 +02:00
LibJS/Bytecode: Flatten bytecode to a contiguous representation Instead of keeping bytecode as a set of disjoint basic blocks on the malloc heap, bytecode is now a contiguous sequence of bytes(!) The transformation happens at the end of Bytecode::Generator::generate() and the only really hairy part is rerouting jump labels. This required solving a few problems: - The interpreter execution loop had to change quite a bit, since we were storing BasicBlock pointers all over the place, and control transfer was done by redirecting the interpreter's current block. - Exception handlers & finalizers are now stored per-bytecode-range in a side table in Executable. - The interpreter now has a plain program counter instead of a stream iterator. This actually makes error stack generation a bit nicer since we just have to deal with a number instead of reaching into the iterator. This yields a 25% performance improvement on this microbenchmark: for (let i = 0; i < 1_000_000; ++i) { } But basically everything gets faster. :^)
2024-05-06 06:44:08 +02:00
may_return:
LibJS: Keep return value in a call frame register
2023-09-26 15:32:46 +02:00
if (!reg(Register::return_value()).is_empty()) {
LibJS: Generate bytecode in basic blocks instead of one big block This limits the size of each block (currently set to 1K), and gets us closer to a canonical, more easily analysable bytecode format. As a result of this, "Labels" are now simply entries to basic blocks. Since there is no more 'conditional' jump (as all jumps are always taken), JumpIf{True,False} are unified to JumpConditional, and JumpIfNullish is renamed to JumpNullish. Also fixes #7914 as a result of reimplementing the loop logic.
2021-06-09 06:49:58 +04:30
will_return = true;
LibJS: Don't enter finally blocks upon `yield` in bytecode mode
2022-12-06 20:45:38 +01:00
// Note: A `yield` statement will not go through a finally statement,
// hence we need to set a flag to not do so,
// but we generate a Yield Operation in the case of returns in
// generators as well, so we need to check if it will actually
// continue or is a `return` in disguise
LibJS/Bytecode: Do not unwind eagerly after throwing `Await` If an exception was thrown while evaluating the argument of an `await` expression, we should jump to the continuation block instead of eagerly rejecting the caller async function. This restores the behavior prior to the addition of the separate `Await` instruction in d66eb4e3.
2023-07-15 09:59:19 +02:00
will_yield = (instruction.type() == Instruction::Type::Yield && static_cast<Op::Yield const&>(instruction).continuation().has_value()) || instruction.type() == Instruction::Type::Await;
LibJS: Generate bytecode in basic blocks instead of one big block This limits the size of each block (currently set to 1K), and gets us closer to a canonical, more easily analysable bytecode format. As a result of this, "Labels" are now simply entries to basic blocks. Since there is no more 'conditional' jump (as all jumps are always taken), JumpIf{True,False} are unified to JumpConditional, and JumpIfNullish is renamed to JumpNullish. Also fixes #7914 as a result of reimplementing the loop logic.
2021-06-09 06:49:58 +04:30
break;
}
LibJS/Bytecode: Flatten bytecode to a contiguous representation Instead of keeping bytecode as a set of disjoint basic blocks on the malloc heap, bytecode is now a contiguous sequence of bytes(!) The transformation happens at the end of Bytecode::Generator::generate() and the only really hairy part is rerouting jump labels. This required solving a few problems: - The interpreter execution loop had to change quite a bit, since we were storing BasicBlock pointers all over the place, and control transfer was done by redirecting the interpreter's current block. - Exception handlers & finalizers are now stored per-bytecode-range in a side table in Executable. - The interpreter now has a plain program counter instead of a stream iterator. This actually makes error stack generation a bit nicer since we just have to deal with a number instead of reaching into the iterator. This yields a 25% performance improvement on this microbenchmark: for (let i = 0; i < 1_000_000; ++i) { } But basically everything gets faster. :^)
2024-05-06 06:44:08 +02:00
NEXT_INSTRUCTION();
LibJS: Intercept returns through finally blocks in Bytecode This is still not perfect, as we now actually crash in the `try-finally-continue` tests, while we now succeed all `try-catch-finally-*` tests. Note that we do not yet go through the finally block when exiting the unwind context through a break or continue.
2022-11-13 20:56:53 +01:00
}
LibJS: Generate bytecode in basic blocks instead of one big block This limits the size of each block (currently set to 1K), and gets us closer to a canonical, more easily analysable bytecode format. As a result of this, "Labels" are now simply entries to basic blocks. Since there is no more 'conditional' jump (as all jumps are always taken), JumpIf{True,False} are unified to JumpConditional, and JumpIfNullish is renamed to JumpNullish. Also fixes #7914 as a result of reimplementing the loop logic.
2021-06-09 06:49:58 +04:30
LibJS/Bytecode: Flatten bytecode to a contiguous representation Instead of keeping bytecode as a set of disjoint basic blocks on the malloc heap, bytecode is now a contiguous sequence of bytes(!) The transformation happens at the end of Bytecode::Generator::generate() and the only really hairy part is rerouting jump labels. This required solving a few problems: - The interpreter execution loop had to change quite a bit, since we were storing BasicBlock pointers all over the place, and control transfer was done by redirecting the interpreter's current block. - Exception handlers & finalizers are now stored per-bytecode-range in a side table in Executable. - The interpreter now has a plain program counter instead of a stream iterator. This actually makes error stack generation a bit nicer since we just have to deal with a number instead of reaching into the iterator. This yields a 25% performance improvement on this microbenchmark: for (let i = 0; i < 1_000_000; ++i) { } But basically everything gets faster. :^)
2024-05-06 06:44:08 +02:00
if (!will_yield) {
if (auto handlers = executable.exception_handlers_for_offset(program_counter); handlers.has_value()) {
if (auto finalizer = handlers.value().finalizer_offset; finalizer.has_value()) {
VERIFY(!running_execution_context.unwind_contexts.is_empty());
auto& unwind_context = running_execution_context.unwind_contexts.last();
VERIFY(unwind_context.executable == m_current_executable);
reg(Register::saved_return_value()) = reg(Register::return_value());
reg(Register::return_value()) = {};
program_counter = finalizer.value();
// the unwind_context will be pop'ed when entering the finally block
continue;
}
}
}
LibJS: Stop bytecode execution after we've encountered an exception
2021-06-09 18:19:11 +02:00
LibJS: Intercept returns through finally blocks in Bytecode This is still not perfect, as we now actually crash in the `try-finally-continue` tests, while we now succeed all `try-catch-finally-*` tests. Note that we do not yet go through the finally block when exiting the unwind context through a break or continue.
2022-11-13 20:56:53 +01:00
if (will_return)
break;
LibJS: Add basic support for while loops in the bytecode engine This introduces two new instructions: Jump and JumpIfFalse. Jumps are made to a Bytecode::Label, which is a simple object that represents a location in the bytecode stream. Note that you may not always know the target of a jump when adding the jump instruction itself, but we can just update the instruction later on during codegen once we know where the jump target is. The Bytecode::Interpreter now implements jumping via a jump slot that gets checked after each instruction to see if a jump is pending. If not, we just increment the PC as usual.
2021-06-04 12:07:38 +02:00
}
LibJS: Move bytecode interpreter's inner loop to its own function
2023-09-26 16:41:42 +02:00
}
LibJS/Bytecode: Flatten bytecode to a contiguous representation Instead of keeping bytecode as a set of disjoint basic blocks on the malloc heap, bytecode is now a contiguous sequence of bytes(!) The transformation happens at the end of Bytecode::Generator::generate() and the only really hairy part is rerouting jump labels. This required solving a few problems: - The interpreter execution loop had to change quite a bit, since we were storing BasicBlock pointers all over the place, and control transfer was done by redirecting the interpreter's current block. - Exception handlers & finalizers are now stored per-bytecode-range in a side table in Executable. - The interpreter now has a plain program counter instead of a stream iterator. This actually makes error stack generation a bit nicer since we just have to deal with a number instead of reaching into the iterator. This yields a 25% performance improvement on this microbenchmark: for (let i = 0; i < 1_000_000; ++i) { } But basically everything gets faster. :^)
2024-05-06 06:44:08 +02:00
Interpreter::ResultAndReturnRegister Interpreter::run_executable(Executable& executable, Optional<size_t> entry_point, Value initial_accumulator_value)
LibJS: Move bytecode interpreter's inner loop to its own function
2023-09-26 16:41:42 +02:00
{
dbgln_if(JS_BYTECODE_DEBUG, "Bytecode::Interpreter will run unit {:p}", &executable);
LibJS: Fix some GCVerifier warnings
2024-04-05 13:47:41 -07:00
TemporaryChange restore_executable { m_current_executable, GCPtr { executable } };
LibJS/Bytecode: Flatten bytecode to a contiguous representation Instead of keeping bytecode as a set of disjoint basic blocks on the malloc heap, bytecode is now a contiguous sequence of bytes(!) The transformation happens at the end of Bytecode::Generator::generate() and the only really hairy part is rerouting jump labels. This required solving a few problems: - The interpreter execution loop had to change quite a bit, since we were storing BasicBlock pointers all over the place, and control transfer was done by redirecting the interpreter's current block. - Exception handlers & finalizers are now stored per-bytecode-range in a side table in Executable. - The interpreter now has a plain program counter instead of a stream iterator. This actually makes error stack generation a bit nicer since we just have to deal with a number instead of reaching into the iterator. This yields a 25% performance improvement on this microbenchmark: for (let i = 0; i < 1_000_000; ++i) { } But basically everything gets faster. :^)
2024-05-06 06:44:08 +02:00
TemporaryChange restore_saved_jump { m_scheduled_jump, Optional<size_t> {} };
LibJS: Fix some GCVerifier warnings
2024-04-05 13:47:41 -07:00
TemporaryChange restore_realm { m_realm, GCPtr { vm().current_realm() } };
TemporaryChange restore_global_object { m_global_object, GCPtr { m_realm->global_object() } };
TemporaryChange restore_global_declarative_environment { m_global_declarative_environment, GCPtr { m_realm->global_environment().declarative_record() } };
LibJS: Move bytecode interpreter's inner loop to its own function
2023-09-26 16:41:42 +02:00
VERIFY(!vm().execution_context_stack().is_empty());
LibJS: Merge CallFrame into ExecutionContext Before this change both ExecutionContext and CallFrame were created before executing function/module/script with a couple exceptions: - executable created for default function argument evaluation has to run in function's execution context. - `execute_ast_node()` where executable compiled for ASTNode has to be executed in running execution context. This change moves all members previously owned by CallFrame into ExecutionContext, and makes two exceptions where an executable that does not have a corresponding execution context saves and restores registers before running. Now, all execution state lives in a single entity, which makes it a bit easier to reason about and opens opportunities for optimizations, such as moving registers and local variables into a single array.
2024-05-01 19:33:49 +02:00
auto& running_execution_context = vm().running_execution_context();
if (running_execution_context.registers.size() < executable.number_of_registers)
running_execution_context.registers.resize(executable.number_of_registers);
LibJS: Move bytecode interpreter's inner loop to its own function
2023-09-26 16:41:42 +02:00
LibJS/Bytecode: Flatten bytecode to a contiguous representation Instead of keeping bytecode as a set of disjoint basic blocks on the malloc heap, bytecode is now a contiguous sequence of bytes(!) The transformation happens at the end of Bytecode::Generator::generate() and the only really hairy part is rerouting jump labels. This required solving a few problems: - The interpreter execution loop had to change quite a bit, since we were storing BasicBlock pointers all over the place, and control transfer was done by redirecting the interpreter's current block. - Exception handlers & finalizers are now stored per-bytecode-range in a side table in Executable. - The interpreter now has a plain program counter instead of a stream iterator. This actually makes error stack generation a bit nicer since we just have to deal with a number instead of reaching into the iterator. This yields a 25% performance improvement on this microbenchmark: for (let i = 0; i < 1_000_000; ++i) { } But basically everything gets faster. :^)
2024-05-06 06:44:08 +02:00
TemporaryChange restore_registers { m_registers, running_execution_context.registers.span() };
TemporaryChange restore_locals { m_locals, running_execution_context.locals.span() };
reg(Register::accumulator()) = initial_accumulator_value;
LibJS: Merge CallFrame into ExecutionContext Before this change both ExecutionContext and CallFrame were created before executing function/module/script with a couple exceptions: - executable created for default function argument evaluation has to run in function's execution context. - `execute_ast_node()` where executable compiled for ASTNode has to be executed in running execution context. This change moves all members previously owned by CallFrame into ExecutionContext, and makes two exceptions where an executable that does not have a corresponding execution context saves and restores registers before running. Now, all execution state lives in a single entity, which makes it a bit easier to reason about and opens opportunities for optimizations, such as moving registers and local variables into a single array.
2024-05-01 19:33:49 +02:00
reg(Register::return_value()) = {};
running_execution_context.executable = &executable;
LibJS: Lazily collect stack trace information The previous implementation was calling `backtrace()` for every function call, which is quite slow. Instead, this implementation provides VM::stack_trace() which unwinds the native stack, maps it through NativeExecutable::get_source_range and combines it with source ranges from interpreted call frames.
2023-11-01 00:39:28 +01:00
LibJS/Bytecode: Flatten bytecode to a contiguous representation Instead of keeping bytecode as a set of disjoint basic blocks on the malloc heap, bytecode is now a contiguous sequence of bytes(!) The transformation happens at the end of Bytecode::Generator::generate() and the only really hairy part is rerouting jump labels. This required solving a few problems: - The interpreter execution loop had to change quite a bit, since we were storing BasicBlock pointers all over the place, and control transfer was done by redirecting the interpreter's current block. - Exception handlers & finalizers are now stored per-bytecode-range in a side table in Executable. - The interpreter now has a plain program counter instead of a stream iterator. This actually makes error stack generation a bit nicer since we just have to deal with a number instead of reaching into the iterator. This yields a 25% performance improvement on this microbenchmark: for (let i = 0; i < 1_000_000; ++i) { } But basically everything gets faster. :^)
2024-05-06 06:44:08 +02:00
run_bytecode(entry_point.value_or(0));
LibJS: Start fleshing out a bytecode for the JavaScript engine :^) This patch begins the work of implementing JavaScript execution in a bytecode VM instead of an AST tree-walk interpreter. It's probably quite naive, but we have to start somewhere. The basic idea is that you call Bytecode::Generator::generate() on an AST node and it hands you back a Bytecode::Block filled with instructions that can then be interpreted by a Bytecode::Interpreter. This first version only implements two instructions: Load and Add. :^) Each bytecode block has infinity registers, and the interpreter resizes its register file to fit the block being executed. Two new `js` options are added in this patch as well: `-d` will dump the generated bytecode `-b` will execute the generated bytecode Note that unless `-d` and/or `-b` are specified, none of the bytecode related stuff in LibJS runs at all. This is implemented in parallel with the existing AST interpreter. :^)
2021-06-03 10:46:30 +02:00
LibJS: Rename Bytecode::ExecutionUnit => Bytecode::Executable
2021-06-09 09:11:20 +02:00
dbgln_if(JS_BYTECODE_DEBUG, "Bytecode::Interpreter did run unit {:p}", &executable);
LibJS: Move bytecode debug spam behind JS_BYTECODE_DEBUG :^)
2021-06-07 15:17:37 +02:00
if constexpr (JS_BYTECODE_DEBUG) {
for (size_t i = 0; i < registers().size(); ++i) {
LibJS: Convert remaining usages of Value::TDSWOSE to Value::TSWOSE Note the couple of cases using MUST are just debugging statements.
2023-02-12 21:54:02 -05:00
String value_string;
LibJS: Move bytecode debug spam behind JS_BYTECODE_DEBUG :^)
2021-06-07 15:17:37 +02:00
if (registers()[i].is_empty())
AK: Make "foo"_string infallible Stop worrying about tiny OOMs. Work towards #20405.
2023-08-07 11:12:38 +02:00
value_string = "(empty)"_string;
LibJS: Move bytecode debug spam behind JS_BYTECODE_DEBUG :^)
2021-06-07 15:17:37 +02:00
else
LibJS: Make Value::to_string_without_side_effects() infallible Work towards #20449.
2023-08-09 08:49:02 +02:00
value_string = registers()[i].to_string_without_side_effects();
LibJS: Move bytecode debug spam behind JS_BYTECODE_DEBUG :^)
2021-06-07 15:17:37 +02:00
dbgln("[{:3}] {}", i, value_string);
}
LibJS: Start fleshing out a bytecode for the JavaScript engine :^) This patch begins the work of implementing JavaScript execution in a bytecode VM instead of an AST tree-walk interpreter. It's probably quite naive, but we have to start somewhere. The basic idea is that you call Bytecode::Generator::generate() on an AST node and it hands you back a Bytecode::Block filled with instructions that can then be interpreted by a Bytecode::Interpreter. This first version only implements two instructions: Load and Add. :^) Each bytecode block has infinity registers, and the interpreter resizes its register file to fit the block being executed. Two new `js` options are added in this patch as well: `-d` will dump the generated bytecode `-b` will execute the generated bytecode Note that unless `-d` and/or `-b` are specified, none of the bytecode related stuff in LibJS runs at all. This is implemented in parallel with the existing AST interpreter. :^)
2021-06-03 10:46:30 +02:00
}
LibJS: Compile ScriptFunctions into bytecode and run them that way :^) If there's a current Bytecode::Interpreter in action, ScriptFunction will now compile itself into bytecode and execute in that context. This patch also adds the Return bytecode instruction so that we can actually return values from called functions. :^) Return values are propagated from callee to caller via the caller's $0 register. Bytecode::Interpreter now keeps a stack of register "windows". These are not very efficient, but it should be pretty straightforward to convert them to e.g a sliding register window architecture later on. This is pretty dang cool! :^)
2021-06-05 15:53:36 +02:00
LibJS: Keep return value in a call frame register
2023-09-26 15:32:46 +02:00
auto return_value = js_undefined();
if (!reg(Register::return_value()).is_empty())
return_value = reg(Register::return_value());
else if (!reg(Register::saved_return_value()).is_empty())
return_value = reg(Register::saved_return_value());
LibJS: Keep current exception in a call frame register Instead of keeping it in a Bytecode::Interpreter member, move it into a dedicated call frame register.
2023-09-26 11:57:42 +02:00
auto exception = reg(Register::exception());
LibJS/Bytecode: Keep saved return value in call frame register This fixes an issue where returning inside a `try` block and then calling a function inside `finally` would clobber the saved return value from the `try` block. Note that we didn't need to change the base of register allocation, since it was already 1 too high. With this fixed, https://microsoft.com/edge loads in bytecode mode. :^) Thanks to Luke for reducing the issue!
2023-07-21 17:30:07 +02:00
LibJS: Run the queued promise reaction jobs on bytecode interpreter exit This is the same as what the AST interpreter does.
2021-11-11 00:44:56 +03:30
// At this point we may have already run any queued promise jobs via on_call_stack_emptied,
// in which case this is a no-op.
vm().run_queued_promise_jobs();
LibJS: Store and maintain an "execution generation" counter This counter is increased each time a synchronous execution sequence completes, and will allow us to emulate the abstract operations AddToKeptObjects & ClearKeptObjects efficiently.
2021-06-12 17:32:54 +03:00
vm().finish_execution_generation();
LibJS: Merge CallFrame into ExecutionContext Before this change both ExecutionContext and CallFrame were created before executing function/module/script with a couple exceptions: - executable created for default function argument evaluation has to run in function's execution context. - `execute_ast_node()` where executable compiled for ASTNode has to be executed in running execution context. This change moves all members previously owned by CallFrame into ExecutionContext, and makes two exceptions where an executable that does not have a corresponding execution context saves and restores registers before running. Now, all execution state lives in a single entity, which makes it a bit easier to reason about and opens opportunities for optimizations, such as moving registers and local variables into a single array.
2024-05-01 19:33:49 +02:00
if (!exception.is_empty())
return { throw_completion(exception), vm().running_execution_context().registers[0] };
return { return_value, vm().running_execution_context().registers[0] };
LibJS: Start fleshing out a bytecode for the JavaScript engine :^) This patch begins the work of implementing JavaScript execution in a bytecode VM instead of an AST tree-walk interpreter. It's probably quite naive, but we have to start somewhere. The basic idea is that you call Bytecode::Generator::generate() on an AST node and it hands you back a Bytecode::Block filled with instructions that can then be interpreted by a Bytecode::Interpreter. This first version only implements two instructions: Load and Add. :^) Each bytecode block has infinity registers, and the interpreter resizes its register file to fit the block being executed. Two new `js` options are added in this patch as well: `-d` will dump the generated bytecode `-b` will execute the generated bytecode Note that unless `-d` and/or `-b` are specified, none of the bytecode related stuff in LibJS runs at all. This is implemented in parallel with the existing AST interpreter. :^)
2021-06-03 10:46:30 +02:00
}
LibJS: Use static unwind mappings for unwind related functions
2023-10-20 00:33:51 +02:00
void Interpreter::enter_unwind_context()
LibJS: Implement bytecode generation for try..catch..finally EnterUnwindContext pushes an unwind context (exception handler and/or finalizer) onto a stack. LeaveUnwindContext pops the unwind context from that stack. Upon return to the interpreter loop we check whether the VM has an exception pending. If no unwind context is available we return from the loop. If an exception handler is available we clear the VM's exception, put the exception value into the accumulator register, clear the unwind context's handler and jump to the handler. If no handler is available but a finalizer is available we save the exception value + metadata (for later use by ContinuePendingUnwind), clear the VM's exception, pop the unwind context and jump to the finalizer. ContinuePendingUnwind checks whether a saved exception is available. If no saved exception is available it jumps to the resume label. Otherwise it stores the exception into the VM. The Jump after LeaveUnwindContext could be integrated into the LeaveUnwindContext instruction. I've kept them separate for now to make the bytecode more readable. > try { 1; throw "x" } catch (e) { 2 } finally { 3 }; 4 1: [ 0] EnterScope [ 10] EnterUnwindContext handler:@4 finalizer:@3 [ 38] EnterScope [ 48] LoadImmediate 1 [ 60] NewString 1 ("x") [ 70] Throw <for non-terminated blocks: insert LeaveUnwindContext + Jump @3 here> 2: [ 0] LoadImmediate 4 3: [ 0] EnterScope [ 10] LoadImmediate 3 [ 28] ContinuePendingUnwind resume:@2 4: [ 0] SetVariable 0 (e) [ 10] EnterScope [ 20] LoadImmediate 2 [ 38] LeaveUnwindContext [ 3c] Jump @3 String Table: 0: e 1: x
2021-06-10 15:04:38 +02:00
{
LibJS: Merge CallFrame into ExecutionContext Before this change both ExecutionContext and CallFrame were created before executing function/module/script with a couple exceptions: - executable created for default function argument evaluation has to run in function's execution context. - `execute_ast_node()` where executable compiled for ASTNode has to be executed in running execution context. This change moves all members previously owned by CallFrame into ExecutionContext, and makes two exceptions where an executable that does not have a corresponding execution context saves and restores registers before running. Now, all execution state lives in a single entity, which makes it a bit easier to reason about and opens opportunities for optimizations, such as moving registers and local variables into a single array.
2024-05-01 19:33:49 +02:00
auto& running_execution_context = vm().running_execution_context();
running_execution_context.unwind_contexts.empend(
LibJS/Bytecode: Restore old environments when an exception is caught Unwind contexts now remember the lexical and variable environments in effect when they were created. If an exception is caught, we revert to those environments in the running execution context.
2023-05-13 18:53:14 +02:00
m_current_executable,
LibJS/Bytecode: Remove unnecessary variable environment stack The var environments will unwind as needed with the ExecutionContext and there's no need to include it in the unwind info. We still need to do this for lexical environments though, since they can have short local lifetimes inside a function.
2023-07-02 15:05:17 +02:00
vm().running_execution_context().lexical_environment);
LibJS: Merge CallFrame into ExecutionContext Before this change both ExecutionContext and CallFrame were created before executing function/module/script with a couple exceptions: - executable created for default function argument evaluation has to run in function's execution context. - `execute_ast_node()` where executable compiled for ASTNode has to be executed in running execution context. This change moves all members previously owned by CallFrame into ExecutionContext, and makes two exceptions where an executable that does not have a corresponding execution context saves and restores registers before running. Now, all execution state lives in a single entity, which makes it a bit easier to reason about and opens opportunities for optimizations, such as moving registers and local variables into a single array.
2024-05-01 19:33:49 +02:00
running_execution_context.previously_scheduled_jumps.append(m_scheduled_jump);
LibJS/Bytecode: Flatten bytecode to a contiguous representation Instead of keeping bytecode as a set of disjoint basic blocks on the malloc heap, bytecode is now a contiguous sequence of bytes(!) The transformation happens at the end of Bytecode::Generator::generate() and the only really hairy part is rerouting jump labels. This required solving a few problems: - The interpreter execution loop had to change quite a bit, since we were storing BasicBlock pointers all over the place, and control transfer was done by redirecting the interpreter's current block. - Exception handlers & finalizers are now stored per-bytecode-range in a side table in Executable. - The interpreter now has a plain program counter instead of a stream iterator. This actually makes error stack generation a bit nicer since we just have to deal with a number instead of reaching into the iterator. This yields a 25% performance improvement on this microbenchmark: for (let i = 0; i < 1_000_000; ++i) { } But basically everything gets faster. :^)
2024-05-06 06:44:08 +02:00
m_scheduled_jump = {};
LibJS: Implement bytecode generation for try..catch..finally EnterUnwindContext pushes an unwind context (exception handler and/or finalizer) onto a stack. LeaveUnwindContext pops the unwind context from that stack. Upon return to the interpreter loop we check whether the VM has an exception pending. If no unwind context is available we return from the loop. If an exception handler is available we clear the VM's exception, put the exception value into the accumulator register, clear the unwind context's handler and jump to the handler. If no handler is available but a finalizer is available we save the exception value + metadata (for later use by ContinuePendingUnwind), clear the VM's exception, pop the unwind context and jump to the finalizer. ContinuePendingUnwind checks whether a saved exception is available. If no saved exception is available it jumps to the resume label. Otherwise it stores the exception into the VM. The Jump after LeaveUnwindContext could be integrated into the LeaveUnwindContext instruction. I've kept them separate for now to make the bytecode more readable. > try { 1; throw "x" } catch (e) { 2 } finally { 3 }; 4 1: [ 0] EnterScope [ 10] EnterUnwindContext handler:@4 finalizer:@3 [ 38] EnterScope [ 48] LoadImmediate 1 [ 60] NewString 1 ("x") [ 70] Throw <for non-terminated blocks: insert LeaveUnwindContext + Jump @3 here> 2: [ 0] LoadImmediate 4 3: [ 0] EnterScope [ 10] LoadImmediate 3 [ 28] ContinuePendingUnwind resume:@2 4: [ 0] SetVariable 0 (e) [ 10] EnterScope [ 20] LoadImmediate 2 [ 38] LeaveUnwindContext [ 3c] Jump @3 String Table: 0: e 1: x
2021-06-10 15:04:38 +02:00
}
void Interpreter::leave_unwind_context()
{
LibJS: Merge CallFrame into ExecutionContext Before this change both ExecutionContext and CallFrame were created before executing function/module/script with a couple exceptions: - executable created for default function argument evaluation has to run in function's execution context. - `execute_ast_node()` where executable compiled for ASTNode has to be executed in running execution context. This change moves all members previously owned by CallFrame into ExecutionContext, and makes two exceptions where an executable that does not have a corresponding execution context saves and restores registers before running. Now, all execution state lives in a single entity, which makes it a bit easier to reason about and opens opportunities for optimizations, such as moving registers and local variables into a single array.
2024-05-01 19:33:49 +02:00
auto& running_execution_context = vm().running_execution_context();
running_execution_context.unwind_contexts.take_last();
LibJS: Implement bytecode generation for try..catch..finally EnterUnwindContext pushes an unwind context (exception handler and/or finalizer) onto a stack. LeaveUnwindContext pops the unwind context from that stack. Upon return to the interpreter loop we check whether the VM has an exception pending. If no unwind context is available we return from the loop. If an exception handler is available we clear the VM's exception, put the exception value into the accumulator register, clear the unwind context's handler and jump to the handler. If no handler is available but a finalizer is available we save the exception value + metadata (for later use by ContinuePendingUnwind), clear the VM's exception, pop the unwind context and jump to the finalizer. ContinuePendingUnwind checks whether a saved exception is available. If no saved exception is available it jumps to the resume label. Otherwise it stores the exception into the VM. The Jump after LeaveUnwindContext could be integrated into the LeaveUnwindContext instruction. I've kept them separate for now to make the bytecode more readable. > try { 1; throw "x" } catch (e) { 2 } finally { 3 }; 4 1: [ 0] EnterScope [ 10] EnterUnwindContext handler:@4 finalizer:@3 [ 38] EnterScope [ 48] LoadImmediate 1 [ 60] NewString 1 ("x") [ 70] Throw <for non-terminated blocks: insert LeaveUnwindContext + Jump @3 here> 2: [ 0] LoadImmediate 4 3: [ 0] EnterScope [ 10] LoadImmediate 3 [ 28] ContinuePendingUnwind resume:@2 4: [ 0] SetVariable 0 (e) [ 10] EnterScope [ 20] LoadImmediate 2 [ 38] LeaveUnwindContext [ 3c] Jump @3 String Table: 0: e 1: x
2021-06-10 15:04:38 +02:00
}
LibJS/Bytecode: Move to a new bytecode format This patch moves us away from the accumulator-based bytecode format to one with explicit source and destination registers. The new format has multiple benefits: - ~25% faster on the Kraken and Octane benchmarks :^) - Fewer instructions to accomplish the same thing - Much easier for humans to read(!) Because this change requires a fundamental shift in how bytecode is generated, it is quite comprehensive. Main implementation mechanism: generate_bytecode() virtual function now takes an optional "preferred dst" operand, which allows callers to communicate when they have an operand that would be optimal for the result to go into. It also returns an optional "actual dst" operand, which is where the completion value (if any) of the AST node is stored after the node has "executed". One thing of note that's new: because instructions can now take locals as operands, this means we got rid of the GetLocal instruction. A side-effect of that is we have to think about the temporal deadzone (TDZ) a bit differently for locals (GetLocal would previously check for empty values and interpret that as a TDZ access and throw). We now insert special ThrowIfTDZ instructions in places where a local access may be in the TDZ, to maintain the correct behavior. There are a number of progressions and regressions from this test: A number of async generator tests have been accidentally fixed while converting the implementation to the new bytecode format. It didn't seem useful to preserve bugs in the original code when converting it. Some "does eval() return the correct completion value" tests have regressed, in particular ones related to propagating the appropriate completion after control flow statements like continue and break. These are all fairly obscure issues, and I believe we can continue working on them separately. The net test262 result is a progression though. :^)
2024-02-04 08:00:54 +01:00
void Interpreter::catch_exception(Operand dst)
LibJS/JIT: Update "unwind context" stack in JIT code Until now, the unwind context stack has not been maintained by jitted code, which meant we were unable to support the `with` statement. This is a first step towards supporting that by making jitted code call out to C++ to update the unwind context stack when entering/leaving unwind contexts. We also introduce a new "Catch" bytecode instruction that moves the current exception into the accumulator. It's always emitted at the start of a "catch" block.
2023-11-11 23:19:46 +01:00
{
LibJS/Bytecode: Move to a new bytecode format This patch moves us away from the accumulator-based bytecode format to one with explicit source and destination registers. The new format has multiple benefits: - ~25% faster on the Kraken and Octane benchmarks :^) - Fewer instructions to accomplish the same thing - Much easier for humans to read(!) Because this change requires a fundamental shift in how bytecode is generated, it is quite comprehensive. Main implementation mechanism: generate_bytecode() virtual function now takes an optional "preferred dst" operand, which allows callers to communicate when they have an operand that would be optimal for the result to go into. It also returns an optional "actual dst" operand, which is where the completion value (if any) of the AST node is stored after the node has "executed". One thing of note that's new: because instructions can now take locals as operands, this means we got rid of the GetLocal instruction. A side-effect of that is we have to think about the temporal deadzone (TDZ) a bit differently for locals (GetLocal would previously check for empty values and interpret that as a TDZ access and throw). We now insert special ThrowIfTDZ instructions in places where a local access may be in the TDZ, to maintain the correct behavior. There are a number of progressions and regressions from this test: A number of async generator tests have been accidentally fixed while converting the implementation to the new bytecode format. It didn't seem useful to preserve bugs in the original code when converting it. Some "does eval() return the correct completion value" tests have regressed, in particular ones related to propagating the appropriate completion after control flow statements like continue and break. These are all fairly obscure issues, and I believe we can continue working on them separately. The net test262 result is a progression though. :^)
2024-02-04 08:00:54 +01:00
set(dst, reg(Register::exception()));
LibJS/JIT: Update "unwind context" stack in JIT code Until now, the unwind context stack has not been maintained by jitted code, which meant we were unable to support the `with` statement. This is a first step towards supporting that by making jitted code call out to C++ to update the unwind context stack when entering/leaving unwind contexts. We also introduce a new "Catch" bytecode instruction that moves the current exception into the accumulator. It's always emitted at the start of a "catch" block.
2023-11-11 23:19:46 +01:00
reg(Register::exception()) = {};
LibJS: Merge CallFrame into ExecutionContext Before this change both ExecutionContext and CallFrame were created before executing function/module/script with a couple exceptions: - executable created for default function argument evaluation has to run in function's execution context. - `execute_ast_node()` where executable compiled for ASTNode has to be executed in running execution context. This change moves all members previously owned by CallFrame into ExecutionContext, and makes two exceptions where an executable that does not have a corresponding execution context saves and restores registers before running. Now, all execution state lives in a single entity, which makes it a bit easier to reason about and opens opportunities for optimizations, such as moving registers and local variables into a single array.
2024-05-01 19:33:49 +02:00
auto& running_execution_context = vm().running_execution_context();
auto& context = running_execution_context.unwind_contexts.last();
LibJS/JIT: Update "unwind context" stack in JIT code Until now, the unwind context stack has not been maintained by jitted code, which meant we were unable to support the `with` statement. This is a first step towards supporting that by making jitted code call out to C++ to update the unwind context stack when entering/leaving unwind contexts. We also introduce a new "Catch" bytecode instruction that moves the current exception into the accumulator. It's always emitted at the start of a "catch" block.
2023-11-11 23:19:46 +01:00
VERIFY(!context.handler_called);
VERIFY(context.executable == &current_executable());
context.handler_called = true;
vm().running_execution_context().lexical_environment = context.lexical_environment;
}
LibJS: Restore scheduled jumps in catch blocks without finalizers
2024-04-11 11:07:35 +02:00
void Interpreter::restore_scheduled_jump()
{
LibJS: Fix build after merging CallFrame removal and finally fixes
2024-05-02 07:42:09 +02:00
m_scheduled_jump = vm().running_execution_context().previously_scheduled_jumps.take_last();
LibJS: Restore scheduled jumps in catch blocks without finalizers
2024-04-11 11:07:35 +02:00
}
LibJS: Cleanup unwind state when transferring control out of a finalizer This does two things: * Clear exceptions when transferring control out of a finalizer Otherwise they would resurface at the end of the next finalizer (see test the new test case), or at the end of a function * Pop one scheduled jump when transferring control out of a finalizer This removes one old FIXME
2024-04-11 11:58:18 +02:00
void Interpreter::leave_finally()
{
reg(Register::exception()) = {};
LibJS: Fix build after merging CallFrame removal and finally fixes
2024-05-02 07:42:09 +02:00
m_scheduled_jump = vm().running_execution_context().previously_scheduled_jumps.take_last();
LibJS: Cleanup unwind state when transferring control out of a finalizer This does two things: * Clear exceptions when transferring control out of a finalizer Otherwise they would resurface at the end of the next finalizer (see test the new test case), or at the end of a function * Pop one scheduled jump when transferring control out of a finalizer This removes one old FIXME
2024-04-11 11:58:18 +02:00
}
LibJS/JIT: Support the EnterObjectEnvironment bytecode instruction We can now use `with` statements in jitted code. :^)
2023-11-12 00:12:21 +01:00
void Interpreter::enter_object_environment(Object& object)
{
LibJS: Merge CallFrame into ExecutionContext Before this change both ExecutionContext and CallFrame were created before executing function/module/script with a couple exceptions: - executable created for default function argument evaluation has to run in function's execution context. - `execute_ast_node()` where executable compiled for ASTNode has to be executed in running execution context. This change moves all members previously owned by CallFrame into ExecutionContext, and makes two exceptions where an executable that does not have a corresponding execution context saves and restores registers before running. Now, all execution state lives in a single entity, which makes it a bit easier to reason about and opens opportunities for optimizations, such as moving registers and local variables into a single array.
2024-05-01 19:33:49 +02:00
auto& running_execution_context = vm().running_execution_context();
auto& old_environment = running_execution_context.lexical_environment;
running_execution_context.saved_lexical_environments.append(old_environment);
running_execution_context.lexical_environment = new_object_environment(object, true, old_environment);
LibJS/JIT: Support the EnterObjectEnvironment bytecode instruction We can now use `with` statements in jitted code. :^)
2023-11-12 00:12:21 +01:00
}
LibJS/Bytecode: Move to a new bytecode format This patch moves us away from the accumulator-based bytecode format to one with explicit source and destination registers. The new format has multiple benefits: - ~25% faster on the Kraken and Octane benchmarks :^) - Fewer instructions to accomplish the same thing - Much easier for humans to read(!) Because this change requires a fundamental shift in how bytecode is generated, it is quite comprehensive. Main implementation mechanism: generate_bytecode() virtual function now takes an optional "preferred dst" operand, which allows callers to communicate when they have an operand that would be optimal for the result to go into. It also returns an optional "actual dst" operand, which is where the completion value (if any) of the AST node is stored after the node has "executed". One thing of note that's new: because instructions can now take locals as operands, this means we got rid of the GetLocal instruction. A side-effect of that is we have to think about the temporal deadzone (TDZ) a bit differently for locals (GetLocal would previously check for empty values and interpret that as a TDZ access and throw). We now insert special ThrowIfTDZ instructions in places where a local access may be in the TDZ, to maintain the correct behavior. There are a number of progressions and regressions from this test: A number of async generator tests have been accidentally fixed while converting the implementation to the new bytecode format. It didn't seem useful to preserve bugs in the original code when converting it. Some "does eval() return the correct completion value" tests have regressed, in particular ones related to propagating the appropriate completion after control flow statements like continue and break. These are all fairly obscure issues, and I believe we can continue working on them separately. The net test262 result is a progression though. :^)
2024-02-04 08:00:54 +01:00
ThrowCompletionOr<NonnullGCPtr<Bytecode::Executable>> compile(VM& vm, ASTNode const& node, ReadonlySpan<FunctionParameter> parameters, FunctionKind kind, DeprecatedFlyString const& name)
LibJS/Bytecode: Simplify Bytecode::Interpreter lifetime model The JS::VM now owns the one Bytecode::Interpreter. We no longer have multiple bytecode interpreters, and there is no concept of a "current" bytecode interpreter. If you ask for VM::bytecode_interpreter_if_exists(), it will return null if we're not running the program in "bytecode enabled" mode. If you ask for VM::bytecode_interpreter(), it will return a bytecode interpreter in all modes. This is used for situations where even the AST interpreter switches to bytecode mode (generators, etc.)
2023-06-22 15:59:18 +02:00
{
LibJS/Bytecode: Move to a new bytecode format This patch moves us away from the accumulator-based bytecode format to one with explicit source and destination registers. The new format has multiple benefits: - ~25% faster on the Kraken and Octane benchmarks :^) - Fewer instructions to accomplish the same thing - Much easier for humans to read(!) Because this change requires a fundamental shift in how bytecode is generated, it is quite comprehensive. Main implementation mechanism: generate_bytecode() virtual function now takes an optional "preferred dst" operand, which allows callers to communicate when they have an operand that would be optimal for the result to go into. It also returns an optional "actual dst" operand, which is where the completion value (if any) of the AST node is stored after the node has "executed". One thing of note that's new: because instructions can now take locals as operands, this means we got rid of the GetLocal instruction. A side-effect of that is we have to think about the temporal deadzone (TDZ) a bit differently for locals (GetLocal would previously check for empty values and interpret that as a TDZ access and throw). We now insert special ThrowIfTDZ instructions in places where a local access may be in the TDZ, to maintain the correct behavior. There are a number of progressions and regressions from this test: A number of async generator tests have been accidentally fixed while converting the implementation to the new bytecode format. It didn't seem useful to preserve bugs in the original code when converting it. Some "does eval() return the correct completion value" tests have regressed, in particular ones related to propagating the appropriate completion after control flow statements like continue and break. These are all fairly obscure issues, and I believe we can continue working on them separately. The net test262 result is a progression though. :^)
2024-02-04 08:00:54 +01:00
auto executable_result = Bytecode::Generator::generate(vm, node, parameters, kind);
LibJS/Bytecode: Simplify Bytecode::Interpreter lifetime model The JS::VM now owns the one Bytecode::Interpreter. We no longer have multiple bytecode interpreters, and there is no concept of a "current" bytecode interpreter. If you ask for VM::bytecode_interpreter_if_exists(), it will return null if we're not running the program in "bytecode enabled" mode. If you ask for VM::bytecode_interpreter(), it will return a bytecode interpreter in all modes. This is used for situations where even the AST interpreter switches to bytecode mode (generators, etc.)
2023-06-22 15:59:18 +02:00
if (executable_result.is_error())
return vm.throw_completion<InternalError>(ErrorType::NotImplemented, TRY_OR_THROW_OOM(vm, executable_result.error().to_string()));
auto bytecode_executable = executable_result.release_value();
bytecode_executable->name = name;
LibJS: Remove the concept of bytecode optimization levels While this would be useful in the future for implementing a multi-tiered optimization strategy, currently a binary on/off is enough for us. This removes the confusingly on-by-default `OptimizationLevel::None` option which made the optimization pipeline a no-op even if `Bytecode::Interpreter::set_optimizations_enabled` had been called. Fixes #15982
2023-06-26 20:10:11 +02:00
LibJS/Bytecode: Simplify Bytecode::Interpreter lifetime model The JS::VM now owns the one Bytecode::Interpreter. We no longer have multiple bytecode interpreters, and there is no concept of a "current" bytecode interpreter. If you ask for VM::bytecode_interpreter_if_exists(), it will return null if we're not running the program in "bytecode enabled" mode. If you ask for VM::bytecode_interpreter(), it will return a bytecode interpreter in all modes. This is used for situations where even the AST interpreter switches to bytecode mode (generators, etc.)
2023-06-22 15:59:18 +02:00
if (Bytecode::g_dump_bytecode)
bytecode_executable->dump();
return bytecode_executable;
}
LibJS: Start fleshing out a bytecode for the JavaScript engine :^) This patch begins the work of implementing JavaScript execution in a bytecode VM instead of an AST tree-walk interpreter. It's probably quite naive, but we have to start somewhere. The basic idea is that you call Bytecode::Generator::generate() on an AST node and it hands you back a Bytecode::Block filled with instructions that can then be interpreted by a Bytecode::Interpreter. This first version only implements two instructions: Load and Add. :^) Each bytecode block has infinity registers, and the interpreter resizes its register file to fit the block being executed. Two new `js` options are added in this patch as well: `-d` will dump the generated bytecode `-b` will execute the generated bytecode Note that unless `-d` and/or `-b` are specified, none of the bytecode related stuff in LibJS runs at all. This is implemented in parallel with the existing AST interpreter. :^)
2021-06-03 10:46:30 +02:00
}
LibJS: Move all bytecode instruction implementations to Interpreter.cpp This allows aggressive inlining without LTO.
2023-09-27 10:10:00 +02:00
namespace JS::Bytecode {
Everywhere: Rename {Deprecated => Byte}String This commit un-deprecates DeprecatedString, and repurposes it as a byte string. As the null state has already been removed, there are no other particularly hairy blockers in repurposing this type as a byte string (what it _really_ is). This commit is auto-generated: $ xs=$(ack -l \bDeprecatedString\b\|deprecated_string AK Userland \ Meta Ports Ladybird Tests Kernel) $ perl -pie 's/\bDeprecatedString\b/ByteString/g; s/deprecated_string/byte_string/g' $xs $ clang-format --style=file -i \ $(git diff --name-only | grep \.cpp\|\.h) $ gn format $(git ls-files '*.gn' '*.gni')
2023-12-16 17:49:34 +03:30
ByteString Instruction::to_byte_string(Bytecode::Executable const& executable) const
LibJS: Move all bytecode instruction implementations to Interpreter.cpp This allows aggressive inlining without LTO.
2023-09-27 10:10:00 +02:00
{
#define __BYTECODE_OP(op) \
case Instruction::Type::op: \
Everywhere: Rename {Deprecated => Byte}String This commit un-deprecates DeprecatedString, and repurposes it as a byte string. As the null state has already been removed, there are no other particularly hairy blockers in repurposing this type as a byte string (what it _really_ is). This commit is auto-generated: $ xs=$(ack -l \bDeprecatedString\b\|deprecated_string AK Userland \ Meta Ports Ladybird Tests Kernel) $ perl -pie 's/\bDeprecatedString\b/ByteString/g; s/deprecated_string/byte_string/g' $xs $ clang-format --style=file -i \ $(git diff --name-only | grep \.cpp\|\.h) $ gn format $(git ls-files '*.gn' '*.gni')
2023-12-16 17:49:34 +03:30
return static_cast<Bytecode::Op::op const&>(*this).to_byte_string_impl(executable);
LibJS: Move all bytecode instruction implementations to Interpreter.cpp This allows aggressive inlining without LTO.
2023-09-27 10:10:00 +02:00
switch (type()) {
ENUMERATE_BYTECODE_OPS(__BYTECODE_OP)
default:
VERIFY_NOT_REACHED();
}
#undef __BYTECODE_OP
}
}
namespace JS::Bytecode::Op {
LibJS/Bytecode: Move to a new bytecode format This patch moves us away from the accumulator-based bytecode format to one with explicit source and destination registers. The new format has multiple benefits: - ~25% faster on the Kraken and Octane benchmarks :^) - Fewer instructions to accomplish the same thing - Much easier for humans to read(!) Because this change requires a fundamental shift in how bytecode is generated, it is quite comprehensive. Main implementation mechanism: generate_bytecode() virtual function now takes an optional "preferred dst" operand, which allows callers to communicate when they have an operand that would be optimal for the result to go into. It also returns an optional "actual dst" operand, which is where the completion value (if any) of the AST node is stored after the node has "executed". One thing of note that's new: because instructions can now take locals as operands, this means we got rid of the GetLocal instruction. A side-effect of that is we have to think about the temporal deadzone (TDZ) a bit differently for locals (GetLocal would previously check for empty values and interpret that as a TDZ access and throw). We now insert special ThrowIfTDZ instructions in places where a local access may be in the TDZ, to maintain the correct behavior. There are a number of progressions and regressions from this test: A number of async generator tests have been accidentally fixed while converting the implementation to the new bytecode format. It didn't seem useful to preserve bugs in the original code when converting it. Some "does eval() return the correct completion value" tests have regressed, in particular ones related to propagating the appropriate completion after control flow statements like continue and break. These are all fairly obscure issues, and I believe we can continue working on them separately. The net test262 result is a progression though. :^)
2024-02-04 08:00:54 +01:00
static void dump_object(Object& o, HashTable<Object const*>& seen, int indent = 0)
LibJS: Move all bytecode instruction implementations to Interpreter.cpp This allows aggressive inlining without LTO.
2023-09-27 10:10:00 +02:00
{
LibJS/Bytecode: Move to a new bytecode format This patch moves us away from the accumulator-based bytecode format to one with explicit source and destination registers. The new format has multiple benefits: - ~25% faster on the Kraken and Octane benchmarks :^) - Fewer instructions to accomplish the same thing - Much easier for humans to read(!) Because this change requires a fundamental shift in how bytecode is generated, it is quite comprehensive. Main implementation mechanism: generate_bytecode() virtual function now takes an optional "preferred dst" operand, which allows callers to communicate when they have an operand that would be optimal for the result to go into. It also returns an optional "actual dst" operand, which is where the completion value (if any) of the AST node is stored after the node has "executed". One thing of note that's new: because instructions can now take locals as operands, this means we got rid of the GetLocal instruction. A side-effect of that is we have to think about the temporal deadzone (TDZ) a bit differently for locals (GetLocal would previously check for empty values and interpret that as a TDZ access and throw). We now insert special ThrowIfTDZ instructions in places where a local access may be in the TDZ, to maintain the correct behavior. There are a number of progressions and regressions from this test: A number of async generator tests have been accidentally fixed while converting the implementation to the new bytecode format. It didn't seem useful to preserve bugs in the original code when converting it. Some "does eval() return the correct completion value" tests have regressed, in particular ones related to propagating the appropriate completion after control flow statements like continue and break. These are all fairly obscure issues, and I believe we can continue working on them separately. The net test262 result is a progression though. :^)
2024-02-04 08:00:54 +01:00
if (seen.contains(&o))
return;
seen.set(&o);
for (auto& it : o.shape().property_table()) {
auto value = o.get_direct(it.value.offset);
dbgln("{} {} -> {}", String::repeated(' ', indent).release_value(), it.key.to_display_string(), value);
if (value.is_object()) {
dump_object(value.as_object(), seen, indent + 2);
}
}
LibJS: Move all bytecode instruction implementations to Interpreter.cpp This allows aggressive inlining without LTO.
2023-09-27 10:10:00 +02:00
}
LibJS/Bytecode: Move to a new bytecode format This patch moves us away from the accumulator-based bytecode format to one with explicit source and destination registers. The new format has multiple benefits: - ~25% faster on the Kraken and Octane benchmarks :^) - Fewer instructions to accomplish the same thing - Much easier for humans to read(!) Because this change requires a fundamental shift in how bytecode is generated, it is quite comprehensive. Main implementation mechanism: generate_bytecode() virtual function now takes an optional "preferred dst" operand, which allows callers to communicate when they have an operand that would be optimal for the result to go into. It also returns an optional "actual dst" operand, which is where the completion value (if any) of the AST node is stored after the node has "executed". One thing of note that's new: because instructions can now take locals as operands, this means we got rid of the GetLocal instruction. A side-effect of that is we have to think about the temporal deadzone (TDZ) a bit differently for locals (GetLocal would previously check for empty values and interpret that as a TDZ access and throw). We now insert special ThrowIfTDZ instructions in places where a local access may be in the TDZ, to maintain the correct behavior. There are a number of progressions and regressions from this test: A number of async generator tests have been accidentally fixed while converting the implementation to the new bytecode format. It didn't seem useful to preserve bugs in the original code when converting it. Some "does eval() return the correct completion value" tests have regressed, in particular ones related to propagating the appropriate completion after control flow statements like continue and break. These are all fairly obscure issues, and I believe we can continue working on them separately. The net test262 result is a progression though. :^)
2024-02-04 08:00:54 +01:00
ThrowCompletionOr<void> Dump::execute_impl(Bytecode::Interpreter& interpreter) const
LibJS: Move all bytecode instruction implementations to Interpreter.cpp This allows aggressive inlining without LTO.
2023-09-27 10:10:00 +02:00
{
LibJS/Bytecode: Move to a new bytecode format This patch moves us away from the accumulator-based bytecode format to one with explicit source and destination registers. The new format has multiple benefits: - ~25% faster on the Kraken and Octane benchmarks :^) - Fewer instructions to accomplish the same thing - Much easier for humans to read(!) Because this change requires a fundamental shift in how bytecode is generated, it is quite comprehensive. Main implementation mechanism: generate_bytecode() virtual function now takes an optional "preferred dst" operand, which allows callers to communicate when they have an operand that would be optimal for the result to go into. It also returns an optional "actual dst" operand, which is where the completion value (if any) of the AST node is stored after the node has "executed". One thing of note that's new: because instructions can now take locals as operands, this means we got rid of the GetLocal instruction. A side-effect of that is we have to think about the temporal deadzone (TDZ) a bit differently for locals (GetLocal would previously check for empty values and interpret that as a TDZ access and throw). We now insert special ThrowIfTDZ instructions in places where a local access may be in the TDZ, to maintain the correct behavior. There are a number of progressions and regressions from this test: A number of async generator tests have been accidentally fixed while converting the implementation to the new bytecode format. It didn't seem useful to preserve bugs in the original code when converting it. Some "does eval() return the correct completion value" tests have regressed, in particular ones related to propagating the appropriate completion after control flow statements like continue and break. These are all fairly obscure issues, and I believe we can continue working on them separately. The net test262 result is a progression though. :^)
2024-02-04 08:00:54 +01:00
auto value = interpreter.get(m_value);
dbgln("(DUMP) {}: {}", m_text, value);
if (value.is_object()) {
HashTable<Object const*> seen;
dump_object(value.as_object(), seen);
}
return {};
LibJS: Move all bytecode instruction implementations to Interpreter.cpp This allows aggressive inlining without LTO.
2023-09-27 10:10:00 +02:00
}
LibJS/Bytecode: Move to a new bytecode format This patch moves us away from the accumulator-based bytecode format to one with explicit source and destination registers. The new format has multiple benefits: - ~25% faster on the Kraken and Octane benchmarks :^) - Fewer instructions to accomplish the same thing - Much easier for humans to read(!) Because this change requires a fundamental shift in how bytecode is generated, it is quite comprehensive. Main implementation mechanism: generate_bytecode() virtual function now takes an optional "preferred dst" operand, which allows callers to communicate when they have an operand that would be optimal for the result to go into. It also returns an optional "actual dst" operand, which is where the completion value (if any) of the AST node is stored after the node has "executed". One thing of note that's new: because instructions can now take locals as operands, this means we got rid of the GetLocal instruction. A side-effect of that is we have to think about the temporal deadzone (TDZ) a bit differently for locals (GetLocal would previously check for empty values and interpret that as a TDZ access and throw). We now insert special ThrowIfTDZ instructions in places where a local access may be in the TDZ, to maintain the correct behavior. There are a number of progressions and regressions from this test: A number of async generator tests have been accidentally fixed while converting the implementation to the new bytecode format. It didn't seem useful to preserve bugs in the original code when converting it. Some "does eval() return the correct completion value" tests have regressed, in particular ones related to propagating the appropriate completion after control flow statements like continue and break. These are all fairly obscure issues, and I believe we can continue working on them separately. The net test262 result is a progression though. :^)
2024-02-04 08:00:54 +01:00
ThrowCompletionOr<void> End::execute_impl(Bytecode::Interpreter&) const
LibJS: Move all bytecode instruction implementations to Interpreter.cpp This allows aggressive inlining without LTO.
2023-09-27 10:10:00 +02:00
{
LibJS: Put __builtin_unreachable() in unused bytecode opcode handlers For the opcodes that are handled directly in the interpreter loop, we want the compiler to know that there's nothing to inline here.
2023-09-27 11:31:23 +02:00
// Handled in the interpreter loop.
__builtin_unreachable();
LibJS: Move all bytecode instruction implementations to Interpreter.cpp This allows aggressive inlining without LTO.
2023-09-27 10:10:00 +02:00
}
LibJS/Bytecode: Add fast paths for many binary expression instructions By handling common cases like Int32 arithmetic directly in the instruction handler, we can avoid the cost of calling the generic helper functions in Value.cpp.
2024-02-20 11:59:46 +01:00
#define JS_DEFINE_EXECUTE_FOR_COMMON_BINARY_OP(OpTitleCase, op_snake_case) \
LibJS: Move all bytecode instruction implementations to Interpreter.cpp This allows aggressive inlining without LTO.
2023-09-27 10:10:00 +02:00
ThrowCompletionOr<void> OpTitleCase::execute_impl(Bytecode::Interpreter& interpreter) const \
{ \
auto& vm = interpreter.vm(); \
LibJS/Bytecode: Move to a new bytecode format This patch moves us away from the accumulator-based bytecode format to one with explicit source and destination registers. The new format has multiple benefits: - ~25% faster on the Kraken and Octane benchmarks :^) - Fewer instructions to accomplish the same thing - Much easier for humans to read(!) Because this change requires a fundamental shift in how bytecode is generated, it is quite comprehensive. Main implementation mechanism: generate_bytecode() virtual function now takes an optional "preferred dst" operand, which allows callers to communicate when they have an operand that would be optimal for the result to go into. It also returns an optional "actual dst" operand, which is where the completion value (if any) of the AST node is stored after the node has "executed". One thing of note that's new: because instructions can now take locals as operands, this means we got rid of the GetLocal instruction. A side-effect of that is we have to think about the temporal deadzone (TDZ) a bit differently for locals (GetLocal would previously check for empty values and interpret that as a TDZ access and throw). We now insert special ThrowIfTDZ instructions in places where a local access may be in the TDZ, to maintain the correct behavior. There are a number of progressions and regressions from this test: A number of async generator tests have been accidentally fixed while converting the implementation to the new bytecode format. It didn't seem useful to preserve bugs in the original code when converting it. Some "does eval() return the correct completion value" tests have regressed, in particular ones related to propagating the appropriate completion after control flow statements like continue and break. These are all fairly obscure issues, and I believe we can continue working on them separately. The net test262 result is a progression though. :^)
2024-02-04 08:00:54 +01:00
auto lhs = interpreter.get(m_lhs); \
auto rhs = interpreter.get(m_rhs); \
interpreter.set(m_dst, TRY(op_snake_case(vm, lhs, rhs))); \
LibJS: Move all bytecode instruction implementations to Interpreter.cpp This allows aggressive inlining without LTO.
2023-09-27 10:10:00 +02:00
return {}; \
}
LibJS/Bytecode: Add fast paths for many binary expression instructions By handling common cases like Int32 arithmetic directly in the instruction handler, we can avoid the cost of calling the generic helper functions in Value.cpp.
2024-02-20 11:59:46 +01:00
#define JS_DEFINE_TO_BYTE_STRING_FOR_COMMON_BINARY_OP(OpTitleCase, op_snake_case) \
ByteString OpTitleCase::to_byte_string_impl(Bytecode::Executable const& executable) const \
{ \
return ByteString::formatted(#OpTitleCase " {}, {}, {}", \
format_operand("dst"sv, m_dst, executable), \
format_operand("lhs"sv, m_lhs, executable), \
format_operand("rhs"sv, m_rhs, executable)); \
}
JS_ENUMERATE_COMMON_BINARY_OPS_WITHOUT_FAST_PATH(JS_DEFINE_EXECUTE_FOR_COMMON_BINARY_OP)
JS_ENUMERATE_COMMON_BINARY_OPS_WITHOUT_FAST_PATH(JS_DEFINE_TO_BYTE_STRING_FOR_COMMON_BINARY_OP)
JS_ENUMERATE_COMMON_BINARY_OPS_WITH_FAST_PATH(JS_DEFINE_TO_BYTE_STRING_FOR_COMMON_BINARY_OP)
ThrowCompletionOr<void> Add::execute_impl(Bytecode::Interpreter& interpreter) const
{
auto& vm = interpreter.vm();
auto const lhs = interpreter.get(m_lhs);
auto const rhs = interpreter.get(m_rhs);
if (lhs.is_number() && rhs.is_number()) {
if (lhs.is_int32() && rhs.is_int32()) {
if (!Checked<i32>::addition_would_overflow(lhs.as_i32(), rhs.as_i32())) {
interpreter.set(m_dst, Value(lhs.as_i32() + rhs.as_i32()));
return {};
}
}
interpreter.set(m_dst, Value(lhs.as_double() + rhs.as_double()));
return {};
}
interpreter.set(m_dst, TRY(add(vm, lhs, rhs)));
return {};
}
ThrowCompletionOr<void> Mul::execute_impl(Bytecode::Interpreter& interpreter) const
{
auto& vm = interpreter.vm();
auto const lhs = interpreter.get(m_lhs);
auto const rhs = interpreter.get(m_rhs);
if (lhs.is_number() && rhs.is_number()) {
if (lhs.is_int32() && rhs.is_int32()) {
if (!Checked<i32>::multiplication_would_overflow(lhs.as_i32(), rhs.as_i32())) {
interpreter.set(m_dst, Value(lhs.as_i32() * rhs.as_i32()));
return {};
}
}
interpreter.set(m_dst, Value(lhs.as_double() * rhs.as_double()));
return {};
}
interpreter.set(m_dst, TRY(mul(vm, lhs, rhs)));
return {};
}
ThrowCompletionOr<void> Sub::execute_impl(Bytecode::Interpreter& interpreter) const
{
auto& vm = interpreter.vm();
auto const lhs = interpreter.get(m_lhs);
auto const rhs = interpreter.get(m_rhs);
if (lhs.is_number() && rhs.is_number()) {
if (lhs.is_int32() && rhs.is_int32()) {
if (!Checked<i32>::addition_would_overflow(lhs.as_i32(), -rhs.as_i32())) {
interpreter.set(m_dst, Value(lhs.as_i32() - rhs.as_i32()));
return {};
}
}
interpreter.set(m_dst, Value(lhs.as_double() - rhs.as_double()));
return {};
}
interpreter.set(m_dst, TRY(sub(vm, lhs, rhs)));
return {};
}
ThrowCompletionOr<void> BitwiseXor::execute_impl(Bytecode::Interpreter& interpreter) const
{
auto& vm = interpreter.vm();
auto const lhs = interpreter.get(m_lhs);
auto const rhs = interpreter.get(m_rhs);
if (lhs.is_int32() && rhs.is_int32()) {
interpreter.set(m_dst, Value(lhs.as_i32() ^ rhs.as_i32()));
return {};
}
interpreter.set(m_dst, TRY(bitwise_xor(vm, lhs, rhs)));
return {};
}
ThrowCompletionOr<void> BitwiseAnd::execute_impl(Bytecode::Interpreter& interpreter) const
{
auto& vm = interpreter.vm();
auto const lhs = interpreter.get(m_lhs);
auto const rhs = interpreter.get(m_rhs);
if (lhs.is_int32() && rhs.is_int32()) {
interpreter.set(m_dst, Value(lhs.as_i32() & rhs.as_i32()));
return {};
}
interpreter.set(m_dst, TRY(bitwise_and(vm, lhs, rhs)));
return {};
}
ThrowCompletionOr<void> BitwiseOr::execute_impl(Bytecode::Interpreter& interpreter) const
{
auto& vm = interpreter.vm();
auto const lhs = interpreter.get(m_lhs);
auto const rhs = interpreter.get(m_rhs);
if (lhs.is_int32() && rhs.is_int32()) {
interpreter.set(m_dst, Value(lhs.as_i32() | rhs.as_i32()));
return {};
}
interpreter.set(m_dst, TRY(bitwise_or(vm, lhs, rhs)));
return {};
}
ThrowCompletionOr<void> UnsignedRightShift::execute_impl(Bytecode::Interpreter& interpreter) const
{
auto& vm = interpreter.vm();
auto const lhs = interpreter.get(m_lhs);
auto const rhs = interpreter.get(m_rhs);
LibJS/Bytecode: Increase coverage of left/shift expression fast paths As long as the inputs are Int32, we can convert them to UInt32 in a spec-compliant way with a simple static_cast<u32>. This allows calculations like `-3 >>> 2` to take the fast path as well, which is extremely valuable for stuff like crypto code. While we're doing this, also remove the fast paths from the generic shift functions in Value.cpp, since we only end up there if we *didn't* take the same fast path in the interpreter.
2024-03-04 10:56:21 +01:00
if (lhs.is_int32() && rhs.is_int32()) {
LibJS/Bytecode: Add fast paths for many binary expression instructions By handling common cases like Int32 arithmetic directly in the instruction handler, we can avoid the cost of calling the generic helper functions in Value.cpp.
2024-02-20 11:59:46 +01:00
auto const shift_count = static_cast<u32>(rhs.as_i32()) % 32;
interpreter.set(m_dst, Value(static_cast<u32>(lhs.as_i32()) >> shift_count));
return {};
}
interpreter.set(m_dst, TRY(unsigned_right_shift(vm, lhs, rhs)));
return {};
}
ThrowCompletionOr<void> RightShift::execute_impl(Bytecode::Interpreter& interpreter) const
{
auto& vm = interpreter.vm();
auto const lhs = interpreter.get(m_lhs);
auto const rhs = interpreter.get(m_rhs);
LibJS/Bytecode: Increase coverage of left/shift expression fast paths As long as the inputs are Int32, we can convert them to UInt32 in a spec-compliant way with a simple static_cast<u32>. This allows calculations like `-3 >>> 2` to take the fast path as well, which is extremely valuable for stuff like crypto code. While we're doing this, also remove the fast paths from the generic shift functions in Value.cpp, since we only end up there if we *didn't* take the same fast path in the interpreter.
2024-03-04 10:56:21 +01:00
if (lhs.is_int32() && rhs.is_int32()) {
LibJS/Bytecode: Add fast paths for many binary expression instructions By handling common cases like Int32 arithmetic directly in the instruction handler, we can avoid the cost of calling the generic helper functions in Value.cpp.
2024-02-20 11:59:46 +01:00
auto const shift_count = static_cast<u32>(rhs.as_i32()) % 32;
interpreter.set(m_dst, Value(lhs.as_i32() >> shift_count));
return {};
}
interpreter.set(m_dst, TRY(right_shift(vm, lhs, rhs)));
return {};
}
LibJS/Bytecode: Add fast path for LeftShift with Int32 operands
2024-03-04 10:01:40 +01:00
ThrowCompletionOr<void> LeftShift::execute_impl(Bytecode::Interpreter& interpreter) const
{
auto& vm = interpreter.vm();
auto const lhs = interpreter.get(m_lhs);
auto const rhs = interpreter.get(m_rhs);
LibJS/Bytecode: Increase coverage of left/shift expression fast paths As long as the inputs are Int32, we can convert them to UInt32 in a spec-compliant way with a simple static_cast<u32>. This allows calculations like `-3 >>> 2` to take the fast path as well, which is extremely valuable for stuff like crypto code. While we're doing this, also remove the fast paths from the generic shift functions in Value.cpp, since we only end up there if we *didn't* take the same fast path in the interpreter.
2024-03-04 10:56:21 +01:00
if (lhs.is_int32() && rhs.is_int32()) {
LibJS/Bytecode: Add fast path for LeftShift with Int32 operands
2024-03-04 10:01:40 +01:00
auto const shift_count = static_cast<u32>(rhs.as_i32()) % 32;
interpreter.set(m_dst, Value(lhs.as_i32() << shift_count));
return {};
}
interpreter.set(m_dst, TRY(left_shift(vm, lhs, rhs)));
return {};
}
LibJS/Bytecode: Add fast paths for many binary expression instructions By handling common cases like Int32 arithmetic directly in the instruction handler, we can avoid the cost of calling the generic helper functions in Value.cpp.
2024-02-20 11:59:46 +01:00
ThrowCompletionOr<void> LessThan::execute_impl(Bytecode::Interpreter& interpreter) const
{
auto& vm = interpreter.vm();
auto const lhs = interpreter.get(m_lhs);
auto const rhs = interpreter.get(m_rhs);
if (lhs.is_int32() && rhs.is_int32()) {
interpreter.set(m_dst, Value(lhs.as_i32() < rhs.as_i32()));
return {};
}
interpreter.set(m_dst, TRY(less_than(vm, lhs, rhs)));
return {};
}
ThrowCompletionOr<void> LessThanEquals::execute_impl(Bytecode::Interpreter& interpreter) const
{
auto& vm = interpreter.vm();
auto const lhs = interpreter.get(m_lhs);
auto const rhs = interpreter.get(m_rhs);
if (lhs.is_int32() && rhs.is_int32()) {
interpreter.set(m_dst, Value(lhs.as_i32() <= rhs.as_i32()));
return {};
}
interpreter.set(m_dst, TRY(less_than_equals(vm, lhs, rhs)));
return {};
}
ThrowCompletionOr<void> GreaterThan::execute_impl(Bytecode::Interpreter& interpreter) const
{
auto& vm = interpreter.vm();
auto const lhs = interpreter.get(m_lhs);
auto const rhs = interpreter.get(m_rhs);
if (lhs.is_int32() && rhs.is_int32()) {
interpreter.set(m_dst, Value(lhs.as_i32() > rhs.as_i32()));
return {};
}
interpreter.set(m_dst, TRY(greater_than(vm, lhs, rhs)));
return {};
}
ThrowCompletionOr<void> GreaterThanEquals::execute_impl(Bytecode::Interpreter& interpreter) const
{
auto& vm = interpreter.vm();
auto const lhs = interpreter.get(m_lhs);
auto const rhs = interpreter.get(m_rhs);
if (lhs.is_int32() && rhs.is_int32()) {
interpreter.set(m_dst, Value(lhs.as_i32() >= rhs.as_i32()));
return {};
}
interpreter.set(m_dst, TRY(greater_than_equals(vm, lhs, rhs)));
return {};
}
LibJS: Move all bytecode instruction implementations to Interpreter.cpp This allows aggressive inlining without LTO.
2023-09-27 10:10:00 +02:00
static ThrowCompletionOr<Value> not_(VM&, Value value)
{
return Value(!value.to_boolean());
}
static ThrowCompletionOr<Value> typeof_(VM& vm, Value value)
{
return PrimitiveString::create(vm, value.typeof());
}
#define JS_DEFINE_COMMON_UNARY_OP(OpTitleCase, op_snake_case) \
ThrowCompletionOr<void> OpTitleCase::execute_impl(Bytecode::Interpreter& interpreter) const \
{ \
auto& vm = interpreter.vm(); \
LibJS/Bytecode: Move to a new bytecode format This patch moves us away from the accumulator-based bytecode format to one with explicit source and destination registers. The new format has multiple benefits: - ~25% faster on the Kraken and Octane benchmarks :^) - Fewer instructions to accomplish the same thing - Much easier for humans to read(!) Because this change requires a fundamental shift in how bytecode is generated, it is quite comprehensive. Main implementation mechanism: generate_bytecode() virtual function now takes an optional "preferred dst" operand, which allows callers to communicate when they have an operand that would be optimal for the result to go into. It also returns an optional "actual dst" operand, which is where the completion value (if any) of the AST node is stored after the node has "executed". One thing of note that's new: because instructions can now take locals as operands, this means we got rid of the GetLocal instruction. A side-effect of that is we have to think about the temporal deadzone (TDZ) a bit differently for locals (GetLocal would previously check for empty values and interpret that as a TDZ access and throw). We now insert special ThrowIfTDZ instructions in places where a local access may be in the TDZ, to maintain the correct behavior. There are a number of progressions and regressions from this test: A number of async generator tests have been accidentally fixed while converting the implementation to the new bytecode format. It didn't seem useful to preserve bugs in the original code when converting it. Some "does eval() return the correct completion value" tests have regressed, in particular ones related to propagating the appropriate completion after control flow statements like continue and break. These are all fairly obscure issues, and I believe we can continue working on them separately. The net test262 result is a progression though. :^)
2024-02-04 08:00:54 +01:00
interpreter.set(dst(), TRY(op_snake_case(vm, interpreter.get(src())))); \
LibJS: Move all bytecode instruction implementations to Interpreter.cpp This allows aggressive inlining without LTO.
2023-09-27 10:10:00 +02:00
return {}; \
} \
LibJS/Bytecode: Move to a new bytecode format This patch moves us away from the accumulator-based bytecode format to one with explicit source and destination registers. The new format has multiple benefits: - ~25% faster on the Kraken and Octane benchmarks :^) - Fewer instructions to accomplish the same thing - Much easier for humans to read(!) Because this change requires a fundamental shift in how bytecode is generated, it is quite comprehensive. Main implementation mechanism: generate_bytecode() virtual function now takes an optional "preferred dst" operand, which allows callers to communicate when they have an operand that would be optimal for the result to go into. It also returns an optional "actual dst" operand, which is where the completion value (if any) of the AST node is stored after the node has "executed". One thing of note that's new: because instructions can now take locals as operands, this means we got rid of the GetLocal instruction. A side-effect of that is we have to think about the temporal deadzone (TDZ) a bit differently for locals (GetLocal would previously check for empty values and interpret that as a TDZ access and throw). We now insert special ThrowIfTDZ instructions in places where a local access may be in the TDZ, to maintain the correct behavior. There are a number of progressions and regressions from this test: A number of async generator tests have been accidentally fixed while converting the implementation to the new bytecode format. It didn't seem useful to preserve bugs in the original code when converting it. Some "does eval() return the correct completion value" tests have regressed, in particular ones related to propagating the appropriate completion after control flow statements like continue and break. These are all fairly obscure issues, and I believe we can continue working on them separately. The net test262 result is a progression though. :^)
2024-02-04 08:00:54 +01:00
ByteString OpTitleCase::to_byte_string_impl(Bytecode::Executable const& executable) const \
LibJS: Move all bytecode instruction implementations to Interpreter.cpp This allows aggressive inlining without LTO.
2023-09-27 10:10:00 +02:00
{ \
LibJS/Bytecode: Move to a new bytecode format This patch moves us away from the accumulator-based bytecode format to one with explicit source and destination registers. The new format has multiple benefits: - ~25% faster on the Kraken and Octane benchmarks :^) - Fewer instructions to accomplish the same thing - Much easier for humans to read(!) Because this change requires a fundamental shift in how bytecode is generated, it is quite comprehensive. Main implementation mechanism: generate_bytecode() virtual function now takes an optional "preferred dst" operand, which allows callers to communicate when they have an operand that would be optimal for the result to go into. It also returns an optional "actual dst" operand, which is where the completion value (if any) of the AST node is stored after the node has "executed". One thing of note that's new: because instructions can now take locals as operands, this means we got rid of the GetLocal instruction. A side-effect of that is we have to think about the temporal deadzone (TDZ) a bit differently for locals (GetLocal would previously check for empty values and interpret that as a TDZ access and throw). We now insert special ThrowIfTDZ instructions in places where a local access may be in the TDZ, to maintain the correct behavior. There are a number of progressions and regressions from this test: A number of async generator tests have been accidentally fixed while converting the implementation to the new bytecode format. It didn't seem useful to preserve bugs in the original code when converting it. Some "does eval() return the correct completion value" tests have regressed, in particular ones related to propagating the appropriate completion after control flow statements like continue and break. These are all fairly obscure issues, and I believe we can continue working on them separately. The net test262 result is a progression though. :^)
2024-02-04 08:00:54 +01:00
return ByteString::formatted(#OpTitleCase " {}, {}", \
format_operand("dst"sv, dst(), executable), \
format_operand("src"sv, src(), executable)); \
LibJS: Move all bytecode instruction implementations to Interpreter.cpp This allows aggressive inlining without LTO.
2023-09-27 10:10:00 +02:00
}
JS_ENUMERATE_COMMON_UNARY_OPS(JS_DEFINE_COMMON_UNARY_OP)
ThrowCompletionOr<void> NewArray::execute_impl(Bytecode::Interpreter& interpreter) const
{
auto array = MUST(Array::create(interpreter.realm(), 0));
for (size_t i = 0; i < m_element_count; i++) {
auto& value = interpreter.reg(Register(m_elements[0].index() + i));
array->indexed_properties().put(i, value, default_attributes);
}
LibJS/Bytecode: Move to a new bytecode format This patch moves us away from the accumulator-based bytecode format to one with explicit source and destination registers. The new format has multiple benefits: - ~25% faster on the Kraken and Octane benchmarks :^) - Fewer instructions to accomplish the same thing - Much easier for humans to read(!) Because this change requires a fundamental shift in how bytecode is generated, it is quite comprehensive. Main implementation mechanism: generate_bytecode() virtual function now takes an optional "preferred dst" operand, which allows callers to communicate when they have an operand that would be optimal for the result to go into. It also returns an optional "actual dst" operand, which is where the completion value (if any) of the AST node is stored after the node has "executed". One thing of note that's new: because instructions can now take locals as operands, this means we got rid of the GetLocal instruction. A side-effect of that is we have to think about the temporal deadzone (TDZ) a bit differently for locals (GetLocal would previously check for empty values and interpret that as a TDZ access and throw). We now insert special ThrowIfTDZ instructions in places where a local access may be in the TDZ, to maintain the correct behavior. There are a number of progressions and regressions from this test: A number of async generator tests have been accidentally fixed while converting the implementation to the new bytecode format. It didn't seem useful to preserve bugs in the original code when converting it. Some "does eval() return the correct completion value" tests have regressed, in particular ones related to propagating the appropriate completion after control flow statements like continue and break. These are all fairly obscure issues, and I believe we can continue working on them separately. The net test262 result is a progression though. :^)
2024-02-04 08:00:54 +01:00
interpreter.set(dst(), array);
LibJS: Move all bytecode instruction implementations to Interpreter.cpp This allows aggressive inlining without LTO.
2023-09-27 10:10:00 +02:00
return {};
}
LibJS: Instantiate primitive array expressions using a single operation This will not meaningfully affect short array literals, but it does give us a bit of extra perf when evaluating huge array expressions like in Kraken/imaging-darkroom.js
2023-11-17 22:07:23 +02:00
ThrowCompletionOr<void> NewPrimitiveArray::execute_impl(Bytecode::Interpreter& interpreter) const
{
auto array = MUST(Array::create(interpreter.realm(), 0));
LibJS/Bytecode: Make NewPrimitiveArray a variable-length instruction Instead of having a FixedArray with a separate heap allocation, we can just bake the primitive values into the instruction itself.
2024-03-03 12:37:28 +01:00
for (size_t i = 0; i < m_element_count; i++)
array->indexed_properties().put(i, m_elements[i], default_attributes);
LibJS/Bytecode: Move to a new bytecode format This patch moves us away from the accumulator-based bytecode format to one with explicit source and destination registers. The new format has multiple benefits: - ~25% faster on the Kraken and Octane benchmarks :^) - Fewer instructions to accomplish the same thing - Much easier for humans to read(!) Because this change requires a fundamental shift in how bytecode is generated, it is quite comprehensive. Main implementation mechanism: generate_bytecode() virtual function now takes an optional "preferred dst" operand, which allows callers to communicate when they have an operand that would be optimal for the result to go into. It also returns an optional "actual dst" operand, which is where the completion value (if any) of the AST node is stored after the node has "executed". One thing of note that's new: because instructions can now take locals as operands, this means we got rid of the GetLocal instruction. A side-effect of that is we have to think about the temporal deadzone (TDZ) a bit differently for locals (GetLocal would previously check for empty values and interpret that as a TDZ access and throw). We now insert special ThrowIfTDZ instructions in places where a local access may be in the TDZ, to maintain the correct behavior. There are a number of progressions and regressions from this test: A number of async generator tests have been accidentally fixed while converting the implementation to the new bytecode format. It didn't seem useful to preserve bugs in the original code when converting it. Some "does eval() return the correct completion value" tests have regressed, in particular ones related to propagating the appropriate completion after control flow statements like continue and break. These are all fairly obscure issues, and I believe we can continue working on them separately. The net test262 result is a progression though. :^)
2024-02-04 08:00:54 +01:00
interpreter.set(dst(), array);
LibJS: Instantiate primitive array expressions using a single operation This will not meaningfully affect short array literals, but it does give us a bit of extra perf when evaluating huge array expressions like in Kraken/imaging-darkroom.js
2023-11-17 22:07:23 +02:00
return {};
}
LibJS/Bytecode: Move to a new bytecode format This patch moves us away from the accumulator-based bytecode format to one with explicit source and destination registers. The new format has multiple benefits: - ~25% faster on the Kraken and Octane benchmarks :^) - Fewer instructions to accomplish the same thing - Much easier for humans to read(!) Because this change requires a fundamental shift in how bytecode is generated, it is quite comprehensive. Main implementation mechanism: generate_bytecode() virtual function now takes an optional "preferred dst" operand, which allows callers to communicate when they have an operand that would be optimal for the result to go into. It also returns an optional "actual dst" operand, which is where the completion value (if any) of the AST node is stored after the node has "executed". One thing of note that's new: because instructions can now take locals as operands, this means we got rid of the GetLocal instruction. A side-effect of that is we have to think about the temporal deadzone (TDZ) a bit differently for locals (GetLocal would previously check for empty values and interpret that as a TDZ access and throw). We now insert special ThrowIfTDZ instructions in places where a local access may be in the TDZ, to maintain the correct behavior. There are a number of progressions and regressions from this test: A number of async generator tests have been accidentally fixed while converting the implementation to the new bytecode format. It didn't seem useful to preserve bugs in the original code when converting it. Some "does eval() return the correct completion value" tests have regressed, in particular ones related to propagating the appropriate completion after control flow statements like continue and break. These are all fairly obscure issues, and I believe we can continue working on them separately. The net test262 result is a progression though. :^)
2024-02-04 08:00:54 +01:00
ThrowCompletionOr<void> ArrayAppend::execute_impl(Bytecode::Interpreter& interpreter) const
LibJS: Move all bytecode instruction implementations to Interpreter.cpp This allows aggressive inlining without LTO.
2023-09-27 10:10:00 +02:00
{
LibJS/Bytecode: Move to a new bytecode format This patch moves us away from the accumulator-based bytecode format to one with explicit source and destination registers. The new format has multiple benefits: - ~25% faster on the Kraken and Octane benchmarks :^) - Fewer instructions to accomplish the same thing - Much easier for humans to read(!) Because this change requires a fundamental shift in how bytecode is generated, it is quite comprehensive. Main implementation mechanism: generate_bytecode() virtual function now takes an optional "preferred dst" operand, which allows callers to communicate when they have an operand that would be optimal for the result to go into. It also returns an optional "actual dst" operand, which is where the completion value (if any) of the AST node is stored after the node has "executed". One thing of note that's new: because instructions can now take locals as operands, this means we got rid of the GetLocal instruction. A side-effect of that is we have to think about the temporal deadzone (TDZ) a bit differently for locals (GetLocal would previously check for empty values and interpret that as a TDZ access and throw). We now insert special ThrowIfTDZ instructions in places where a local access may be in the TDZ, to maintain the correct behavior. There are a number of progressions and regressions from this test: A number of async generator tests have been accidentally fixed while converting the implementation to the new bytecode format. It didn't seem useful to preserve bugs in the original code when converting it. Some "does eval() return the correct completion value" tests have regressed, in particular ones related to propagating the appropriate completion after control flow statements like continue and break. These are all fairly obscure issues, and I believe we can continue working on them separately. The net test262 result is a progression though. :^)
2024-02-04 08:00:54 +01:00
return append(interpreter.vm(), interpreter.get(dst()), interpreter.get(src()), m_is_spread);
LibJS: Move all bytecode instruction implementations to Interpreter.cpp This allows aggressive inlining without LTO.
2023-09-27 10:10:00 +02:00
}
ThrowCompletionOr<void> ImportCall::execute_impl(Bytecode::Interpreter& interpreter) const
{
auto& vm = interpreter.vm();
LibJS/Bytecode: Move to a new bytecode format This patch moves us away from the accumulator-based bytecode format to one with explicit source and destination registers. The new format has multiple benefits: - ~25% faster on the Kraken and Octane benchmarks :^) - Fewer instructions to accomplish the same thing - Much easier for humans to read(!) Because this change requires a fundamental shift in how bytecode is generated, it is quite comprehensive. Main implementation mechanism: generate_bytecode() virtual function now takes an optional "preferred dst" operand, which allows callers to communicate when they have an operand that would be optimal for the result to go into. It also returns an optional "actual dst" operand, which is where the completion value (if any) of the AST node is stored after the node has "executed". One thing of note that's new: because instructions can now take locals as operands, this means we got rid of the GetLocal instruction. A side-effect of that is we have to think about the temporal deadzone (TDZ) a bit differently for locals (GetLocal would previously check for empty values and interpret that as a TDZ access and throw). We now insert special ThrowIfTDZ instructions in places where a local access may be in the TDZ, to maintain the correct behavior. There are a number of progressions and regressions from this test: A number of async generator tests have been accidentally fixed while converting the implementation to the new bytecode format. It didn't seem useful to preserve bugs in the original code when converting it. Some "does eval() return the correct completion value" tests have regressed, in particular ones related to propagating the appropriate completion after control flow statements like continue and break. These are all fairly obscure issues, and I believe we can continue working on them separately. The net test262 result is a progression though. :^)
2024-02-04 08:00:54 +01:00
auto specifier = interpreter.get(m_specifier);
auto options_value = interpreter.get(m_options);
interpreter.set(dst(), TRY(perform_import_call(vm, specifier, options_value)));
LibJS: Move all bytecode instruction implementations to Interpreter.cpp This allows aggressive inlining without LTO.
2023-09-27 10:10:00 +02:00
return {};
}
ThrowCompletionOr<void> IteratorToArray::execute_impl(Bytecode::Interpreter& interpreter) const
{
LibJS/Bytecode: Move to a new bytecode format This patch moves us away from the accumulator-based bytecode format to one with explicit source and destination registers. The new format has multiple benefits: - ~25% faster on the Kraken and Octane benchmarks :^) - Fewer instructions to accomplish the same thing - Much easier for humans to read(!) Because this change requires a fundamental shift in how bytecode is generated, it is quite comprehensive. Main implementation mechanism: generate_bytecode() virtual function now takes an optional "preferred dst" operand, which allows callers to communicate when they have an operand that would be optimal for the result to go into. It also returns an optional "actual dst" operand, which is where the completion value (if any) of the AST node is stored after the node has "executed". One thing of note that's new: because instructions can now take locals as operands, this means we got rid of the GetLocal instruction. A side-effect of that is we have to think about the temporal deadzone (TDZ) a bit differently for locals (GetLocal would previously check for empty values and interpret that as a TDZ access and throw). We now insert special ThrowIfTDZ instructions in places where a local access may be in the TDZ, to maintain the correct behavior. There are a number of progressions and regressions from this test: A number of async generator tests have been accidentally fixed while converting the implementation to the new bytecode format. It didn't seem useful to preserve bugs in the original code when converting it. Some "does eval() return the correct completion value" tests have regressed, in particular ones related to propagating the appropriate completion after control flow statements like continue and break. These are all fairly obscure issues, and I believe we can continue working on them separately. The net test262 result is a progression though. :^)
2024-02-04 08:00:54 +01:00
interpreter.set(dst(), TRY(iterator_to_array(interpreter.vm(), interpreter.get(iterator()))));
LibJS: Move all bytecode instruction implementations to Interpreter.cpp This allows aggressive inlining without LTO.
2023-09-27 10:10:00 +02:00
return {};
}
ThrowCompletionOr<void> NewObject::execute_impl(Bytecode::Interpreter& interpreter) const
{
auto& vm = interpreter.vm();
auto& realm = *vm.current_realm();
LibJS/Bytecode: Move to a new bytecode format This patch moves us away from the accumulator-based bytecode format to one with explicit source and destination registers. The new format has multiple benefits: - ~25% faster on the Kraken and Octane benchmarks :^) - Fewer instructions to accomplish the same thing - Much easier for humans to read(!) Because this change requires a fundamental shift in how bytecode is generated, it is quite comprehensive. Main implementation mechanism: generate_bytecode() virtual function now takes an optional "preferred dst" operand, which allows callers to communicate when they have an operand that would be optimal for the result to go into. It also returns an optional "actual dst" operand, which is where the completion value (if any) of the AST node is stored after the node has "executed". One thing of note that's new: because instructions can now take locals as operands, this means we got rid of the GetLocal instruction. A side-effect of that is we have to think about the temporal deadzone (TDZ) a bit differently for locals (GetLocal would previously check for empty values and interpret that as a TDZ access and throw). We now insert special ThrowIfTDZ instructions in places where a local access may be in the TDZ, to maintain the correct behavior. There are a number of progressions and regressions from this test: A number of async generator tests have been accidentally fixed while converting the implementation to the new bytecode format. It didn't seem useful to preserve bugs in the original code when converting it. Some "does eval() return the correct completion value" tests have regressed, in particular ones related to propagating the appropriate completion after control flow statements like continue and break. These are all fairly obscure issues, and I believe we can continue working on them separately. The net test262 result is a progression though. :^)
2024-02-04 08:00:54 +01:00
interpreter.set(dst(), Object::create(realm, realm.intrinsics().object_prototype()));
LibJS: Move all bytecode instruction implementations to Interpreter.cpp This allows aggressive inlining without LTO.
2023-09-27 10:10:00 +02:00
return {};
}
ThrowCompletionOr<void> NewRegExp::execute_impl(Bytecode::Interpreter& interpreter) const
{
LibJS/Bytecode: Move to a new bytecode format This patch moves us away from the accumulator-based bytecode format to one with explicit source and destination registers. The new format has multiple benefits: - ~25% faster on the Kraken and Octane benchmarks :^) - Fewer instructions to accomplish the same thing - Much easier for humans to read(!) Because this change requires a fundamental shift in how bytecode is generated, it is quite comprehensive. Main implementation mechanism: generate_bytecode() virtual function now takes an optional "preferred dst" operand, which allows callers to communicate when they have an operand that would be optimal for the result to go into. It also returns an optional "actual dst" operand, which is where the completion value (if any) of the AST node is stored after the node has "executed". One thing of note that's new: because instructions can now take locals as operands, this means we got rid of the GetLocal instruction. A side-effect of that is we have to think about the temporal deadzone (TDZ) a bit differently for locals (GetLocal would previously check for empty values and interpret that as a TDZ access and throw). We now insert special ThrowIfTDZ instructions in places where a local access may be in the TDZ, to maintain the correct behavior. There are a number of progressions and regressions from this test: A number of async generator tests have been accidentally fixed while converting the implementation to the new bytecode format. It didn't seem useful to preserve bugs in the original code when converting it. Some "does eval() return the correct completion value" tests have regressed, in particular ones related to propagating the appropriate completion after control flow statements like continue and break. These are all fairly obscure issues, and I believe we can continue working on them separately. The net test262 result is a progression though. :^)
2024-02-04 08:00:54 +01:00
interpreter.set(dst(),
new_regexp(
interpreter.vm(),
interpreter.current_executable().regex_table->get(m_regex_index),
interpreter.current_executable().get_string(m_source_index),
interpreter.current_executable().get_string(m_flags_index)));
return {};
}
#define JS_DEFINE_NEW_BUILTIN_ERROR_OP(ErrorName) \
ThrowCompletionOr<void> New##ErrorName::execute_impl(Bytecode::Interpreter& interpreter) const \
{ \
auto& vm = interpreter.vm(); \
auto& realm = *vm.current_realm(); \
interpreter.set(dst(), ErrorName::create(realm, interpreter.current_executable().get_string(m_error_string))); \
return {}; \
} \
ByteString New##ErrorName::to_byte_string_impl(Bytecode::Executable const& executable) const \
{ \
return ByteString::formatted("New" #ErrorName " {}, {}", \
format_operand("dst"sv, m_dst, executable), \
executable.string_table->get(m_error_string)); \
LibJS: Move all bytecode instruction implementations to Interpreter.cpp This allows aggressive inlining without LTO.
2023-09-27 10:10:00 +02:00
}
JS_ENUMERATE_NEW_BUILTIN_ERROR_OPS(JS_DEFINE_NEW_BUILTIN_ERROR_OP)
ThrowCompletionOr<void> CopyObjectExcludingProperties::execute_impl(Bytecode::Interpreter& interpreter) const
{
auto& vm = interpreter.vm();
auto& realm = *vm.current_realm();
LibJS/Bytecode: Move to a new bytecode format This patch moves us away from the accumulator-based bytecode format to one with explicit source and destination registers. The new format has multiple benefits: - ~25% faster on the Kraken and Octane benchmarks :^) - Fewer instructions to accomplish the same thing - Much easier for humans to read(!) Because this change requires a fundamental shift in how bytecode is generated, it is quite comprehensive. Main implementation mechanism: generate_bytecode() virtual function now takes an optional "preferred dst" operand, which allows callers to communicate when they have an operand that would be optimal for the result to go into. It also returns an optional "actual dst" operand, which is where the completion value (if any) of the AST node is stored after the node has "executed". One thing of note that's new: because instructions can now take locals as operands, this means we got rid of the GetLocal instruction. A side-effect of that is we have to think about the temporal deadzone (TDZ) a bit differently for locals (GetLocal would previously check for empty values and interpret that as a TDZ access and throw). We now insert special ThrowIfTDZ instructions in places where a local access may be in the TDZ, to maintain the correct behavior. There are a number of progressions and regressions from this test: A number of async generator tests have been accidentally fixed while converting the implementation to the new bytecode format. It didn't seem useful to preserve bugs in the original code when converting it. Some "does eval() return the correct completion value" tests have regressed, in particular ones related to propagating the appropriate completion after control flow statements like continue and break. These are all fairly obscure issues, and I believe we can continue working on them separately. The net test262 result is a progression though. :^)
2024-02-04 08:00:54 +01:00
auto from_object = interpreter.get(m_from_object);
LibJS: Move all bytecode instruction implementations to Interpreter.cpp This allows aggressive inlining without LTO.
2023-09-27 10:10:00 +02:00
auto to_object = Object::create(realm, realm.intrinsics().object_prototype());
HashTable<PropertyKey> excluded_names;
for (size_t i = 0; i < m_excluded_names_count; ++i) {
LibJS/Bytecode: Move to a new bytecode format This patch moves us away from the accumulator-based bytecode format to one with explicit source and destination registers. The new format has multiple benefits: - ~25% faster on the Kraken and Octane benchmarks :^) - Fewer instructions to accomplish the same thing - Much easier for humans to read(!) Because this change requires a fundamental shift in how bytecode is generated, it is quite comprehensive. Main implementation mechanism: generate_bytecode() virtual function now takes an optional "preferred dst" operand, which allows callers to communicate when they have an operand that would be optimal for the result to go into. It also returns an optional "actual dst" operand, which is where the completion value (if any) of the AST node is stored after the node has "executed". One thing of note that's new: because instructions can now take locals as operands, this means we got rid of the GetLocal instruction. A side-effect of that is we have to think about the temporal deadzone (TDZ) a bit differently for locals (GetLocal would previously check for empty values and interpret that as a TDZ access and throw). We now insert special ThrowIfTDZ instructions in places where a local access may be in the TDZ, to maintain the correct behavior. There are a number of progressions and regressions from this test: A number of async generator tests have been accidentally fixed while converting the implementation to the new bytecode format. It didn't seem useful to preserve bugs in the original code when converting it. Some "does eval() return the correct completion value" tests have regressed, in particular ones related to propagating the appropriate completion after control flow statements like continue and break. These are all fairly obscure issues, and I believe we can continue working on them separately. The net test262 result is a progression though. :^)
2024-02-04 08:00:54 +01:00
excluded_names.set(TRY(interpreter.get(m_excluded_names[i]).to_property_key(vm)));
LibJS: Move all bytecode instruction implementations to Interpreter.cpp This allows aggressive inlining without LTO.
2023-09-27 10:10:00 +02:00
}
TRY(to_object->copy_data_properties(vm, from_object, excluded_names));
LibJS/Bytecode: Move to a new bytecode format This patch moves us away from the accumulator-based bytecode format to one with explicit source and destination registers. The new format has multiple benefits: - ~25% faster on the Kraken and Octane benchmarks :^) - Fewer instructions to accomplish the same thing - Much easier for humans to read(!) Because this change requires a fundamental shift in how bytecode is generated, it is quite comprehensive. Main implementation mechanism: generate_bytecode() virtual function now takes an optional "preferred dst" operand, which allows callers to communicate when they have an operand that would be optimal for the result to go into. It also returns an optional "actual dst" operand, which is where the completion value (if any) of the AST node is stored after the node has "executed". One thing of note that's new: because instructions can now take locals as operands, this means we got rid of the GetLocal instruction. A side-effect of that is we have to think about the temporal deadzone (TDZ) a bit differently for locals (GetLocal would previously check for empty values and interpret that as a TDZ access and throw). We now insert special ThrowIfTDZ instructions in places where a local access may be in the TDZ, to maintain the correct behavior. There are a number of progressions and regressions from this test: A number of async generator tests have been accidentally fixed while converting the implementation to the new bytecode format. It didn't seem useful to preserve bugs in the original code when converting it. Some "does eval() return the correct completion value" tests have regressed, in particular ones related to propagating the appropriate completion after control flow statements like continue and break. These are all fairly obscure issues, and I believe we can continue working on them separately. The net test262 result is a progression though. :^)
2024-02-04 08:00:54 +01:00
interpreter.set(dst(), to_object);
LibJS: Move all bytecode instruction implementations to Interpreter.cpp This allows aggressive inlining without LTO.
2023-09-27 10:10:00 +02:00
return {};
}
ThrowCompletionOr<void> ConcatString::execute_impl(Bytecode::Interpreter& interpreter) const
{
auto& vm = interpreter.vm();
LibJS/Bytecode: Move to a new bytecode format This patch moves us away from the accumulator-based bytecode format to one with explicit source and destination registers. The new format has multiple benefits: - ~25% faster on the Kraken and Octane benchmarks :^) - Fewer instructions to accomplish the same thing - Much easier for humans to read(!) Because this change requires a fundamental shift in how bytecode is generated, it is quite comprehensive. Main implementation mechanism: generate_bytecode() virtual function now takes an optional "preferred dst" operand, which allows callers to communicate when they have an operand that would be optimal for the result to go into. It also returns an optional "actual dst" operand, which is where the completion value (if any) of the AST node is stored after the node has "executed". One thing of note that's new: because instructions can now take locals as operands, this means we got rid of the GetLocal instruction. A side-effect of that is we have to think about the temporal deadzone (TDZ) a bit differently for locals (GetLocal would previously check for empty values and interpret that as a TDZ access and throw). We now insert special ThrowIfTDZ instructions in places where a local access may be in the TDZ, to maintain the correct behavior. There are a number of progressions and regressions from this test: A number of async generator tests have been accidentally fixed while converting the implementation to the new bytecode format. It didn't seem useful to preserve bugs in the original code when converting it. Some "does eval() return the correct completion value" tests have regressed, in particular ones related to propagating the appropriate completion after control flow statements like continue and break. These are all fairly obscure issues, and I believe we can continue working on them separately. The net test262 result is a progression though. :^)
2024-02-04 08:00:54 +01:00
auto string = TRY(interpreter.get(src()).to_primitive_string(vm));
interpreter.set(dst(), PrimitiveString::create(vm, interpreter.get(dst()).as_string(), string));
LibJS: Move all bytecode instruction implementations to Interpreter.cpp This allows aggressive inlining without LTO.
2023-09-27 10:10:00 +02:00
return {};
}
ThrowCompletionOr<void> GetVariable::execute_impl(Bytecode::Interpreter& interpreter) const
{
LibJS/Bytecode: Move to a new bytecode format This patch moves us away from the accumulator-based bytecode format to one with explicit source and destination registers. The new format has multiple benefits: - ~25% faster on the Kraken and Octane benchmarks :^) - Fewer instructions to accomplish the same thing - Much easier for humans to read(!) Because this change requires a fundamental shift in how bytecode is generated, it is quite comprehensive. Main implementation mechanism: generate_bytecode() virtual function now takes an optional "preferred dst" operand, which allows callers to communicate when they have an operand that would be optimal for the result to go into. It also returns an optional "actual dst" operand, which is where the completion value (if any) of the AST node is stored after the node has "executed". One thing of note that's new: because instructions can now take locals as operands, this means we got rid of the GetLocal instruction. A side-effect of that is we have to think about the temporal deadzone (TDZ) a bit differently for locals (GetLocal would previously check for empty values and interpret that as a TDZ access and throw). We now insert special ThrowIfTDZ instructions in places where a local access may be in the TDZ, to maintain the correct behavior. There are a number of progressions and regressions from this test: A number of async generator tests have been accidentally fixed while converting the implementation to the new bytecode format. It didn't seem useful to preserve bugs in the original code when converting it. Some "does eval() return the correct completion value" tests have regressed, in particular ones related to propagating the appropriate completion after control flow statements like continue and break. These are all fairly obscure issues, and I believe we can continue working on them separately. The net test262 result is a progression though. :^)
2024-02-04 08:00:54 +01:00
interpreter.set(dst(), TRY(get_variable(interpreter, interpreter.current_executable().get_identifier(m_identifier), interpreter.current_executable().environment_variable_caches[m_cache_index])));
LibJS: Move all bytecode instruction implementations to Interpreter.cpp This allows aggressive inlining without LTO.
2023-09-27 10:10:00 +02:00
return {};
}
ThrowCompletionOr<void> GetCalleeAndThisFromEnvironment::execute_impl(Bytecode::Interpreter& interpreter) const
{
LibJS/JIT: Resolve the GetCalleeAndThisFromEnvironment cache at JIT time
2023-11-10 13:00:36 +01:00
auto callee_and_this = TRY(get_callee_and_this_from_environment(
interpreter,
interpreter.current_executable().get_identifier(m_identifier),
interpreter.current_executable().environment_variable_caches[m_cache_index]));
LibJS/Bytecode: Move to a new bytecode format This patch moves us away from the accumulator-based bytecode format to one with explicit source and destination registers. The new format has multiple benefits: - ~25% faster on the Kraken and Octane benchmarks :^) - Fewer instructions to accomplish the same thing - Much easier for humans to read(!) Because this change requires a fundamental shift in how bytecode is generated, it is quite comprehensive. Main implementation mechanism: generate_bytecode() virtual function now takes an optional "preferred dst" operand, which allows callers to communicate when they have an operand that would be optimal for the result to go into. It also returns an optional "actual dst" operand, which is where the completion value (if any) of the AST node is stored after the node has "executed". One thing of note that's new: because instructions can now take locals as operands, this means we got rid of the GetLocal instruction. A side-effect of that is we have to think about the temporal deadzone (TDZ) a bit differently for locals (GetLocal would previously check for empty values and interpret that as a TDZ access and throw). We now insert special ThrowIfTDZ instructions in places where a local access may be in the TDZ, to maintain the correct behavior. There are a number of progressions and regressions from this test: A number of async generator tests have been accidentally fixed while converting the implementation to the new bytecode format. It didn't seem useful to preserve bugs in the original code when converting it. Some "does eval() return the correct completion value" tests have regressed, in particular ones related to propagating the appropriate completion after control flow statements like continue and break. These are all fairly obscure issues, and I believe we can continue working on them separately. The net test262 result is a progression though. :^)
2024-02-04 08:00:54 +01:00
interpreter.set(m_callee, callee_and_this.callee);
interpreter.set(m_this_value, callee_and_this.this_value);
LibJS: Move all bytecode instruction implementations to Interpreter.cpp This allows aggressive inlining without LTO.
2023-09-27 10:10:00 +02:00
return {};
}
ThrowCompletionOr<void> GetGlobal::execute_impl(Bytecode::Interpreter& interpreter) const
{
LibJS/Bytecode: Move to a new bytecode format This patch moves us away from the accumulator-based bytecode format to one with explicit source and destination registers. The new format has multiple benefits: - ~25% faster on the Kraken and Octane benchmarks :^) - Fewer instructions to accomplish the same thing - Much easier for humans to read(!) Because this change requires a fundamental shift in how bytecode is generated, it is quite comprehensive. Main implementation mechanism: generate_bytecode() virtual function now takes an optional "preferred dst" operand, which allows callers to communicate when they have an operand that would be optimal for the result to go into. It also returns an optional "actual dst" operand, which is where the completion value (if any) of the AST node is stored after the node has "executed". One thing of note that's new: because instructions can now take locals as operands, this means we got rid of the GetLocal instruction. A side-effect of that is we have to think about the temporal deadzone (TDZ) a bit differently for locals (GetLocal would previously check for empty values and interpret that as a TDZ access and throw). We now insert special ThrowIfTDZ instructions in places where a local access may be in the TDZ, to maintain the correct behavior. There are a number of progressions and regressions from this test: A number of async generator tests have been accidentally fixed while converting the implementation to the new bytecode format. It didn't seem useful to preserve bugs in the original code when converting it. Some "does eval() return the correct completion value" tests have regressed, in particular ones related to propagating the appropriate completion after control flow statements like continue and break. These are all fairly obscure issues, and I believe we can continue working on them separately. The net test262 result is a progression though. :^)
2024-02-04 08:00:54 +01:00
interpreter.set(dst(), TRY(get_global(interpreter, interpreter.current_executable().get_identifier(m_identifier), interpreter.current_executable().global_variable_caches[m_cache_index])));
LibJS/JIT: Compile the GetGlobal bytecode instruction
2023-10-20 12:56:12 +02:00
return {};
LibJS: Move all bytecode instruction implementations to Interpreter.cpp This allows aggressive inlining without LTO.
2023-09-27 10:10:00 +02:00
}
ThrowCompletionOr<void> DeleteVariable::execute_impl(Bytecode::Interpreter& interpreter) const
{
auto& vm = interpreter.vm();
auto const& string = interpreter.current_executable().get_identifier(m_identifier);
auto reference = TRY(vm.resolve_binding(string));
LibJS/Bytecode: Move to a new bytecode format This patch moves us away from the accumulator-based bytecode format to one with explicit source and destination registers. The new format has multiple benefits: - ~25% faster on the Kraken and Octane benchmarks :^) - Fewer instructions to accomplish the same thing - Much easier for humans to read(!) Because this change requires a fundamental shift in how bytecode is generated, it is quite comprehensive. Main implementation mechanism: generate_bytecode() virtual function now takes an optional "preferred dst" operand, which allows callers to communicate when they have an operand that would be optimal for the result to go into. It also returns an optional "actual dst" operand, which is where the completion value (if any) of the AST node is stored after the node has "executed". One thing of note that's new: because instructions can now take locals as operands, this means we got rid of the GetLocal instruction. A side-effect of that is we have to think about the temporal deadzone (TDZ) a bit differently for locals (GetLocal would previously check for empty values and interpret that as a TDZ access and throw). We now insert special ThrowIfTDZ instructions in places where a local access may be in the TDZ, to maintain the correct behavior. There are a number of progressions and regressions from this test: A number of async generator tests have been accidentally fixed while converting the implementation to the new bytecode format. It didn't seem useful to preserve bugs in the original code when converting it. Some "does eval() return the correct completion value" tests have regressed, in particular ones related to propagating the appropriate completion after control flow statements like continue and break. These are all fairly obscure issues, and I believe we can continue working on them separately. The net test262 result is a progression though. :^)
2024-02-04 08:00:54 +01:00
interpreter.set(dst(), Value(TRY(reference.delete_(vm))));
LibJS: Move all bytecode instruction implementations to Interpreter.cpp This allows aggressive inlining without LTO.
2023-09-27 10:10:00 +02:00
return {};
}
ThrowCompletionOr<void> CreateLexicalEnvironment::execute_impl(Bytecode::Interpreter& interpreter) const
{
auto make_and_swap_envs = [&](auto& old_environment) {
GCPtr<Environment> environment = new_declarative_environment(*old_environment).ptr();
swap(old_environment, environment);
return environment;
};
LibJS: Merge CallFrame into ExecutionContext Before this change both ExecutionContext and CallFrame were created before executing function/module/script with a couple exceptions: - executable created for default function argument evaluation has to run in function's execution context. - `execute_ast_node()` where executable compiled for ASTNode has to be executed in running execution context. This change moves all members previously owned by CallFrame into ExecutionContext, and makes two exceptions where an executable that does not have a corresponding execution context saves and restores registers before running. Now, all execution state lives in a single entity, which makes it a bit easier to reason about and opens opportunities for optimizations, such as moving registers and local variables into a single array.
2024-05-01 19:33:49 +02:00
auto& running_execution_context = interpreter.vm().running_execution_context();
running_execution_context.saved_lexical_environments.append(make_and_swap_envs(running_execution_context.lexical_environment));
LibJS: Move all bytecode instruction implementations to Interpreter.cpp This allows aggressive inlining without LTO.
2023-09-27 10:10:00 +02:00
return {};
}
ThrowCompletionOr<void> EnterObjectEnvironment::execute_impl(Bytecode::Interpreter& interpreter) const
{
LibJS/Bytecode: Move to a new bytecode format This patch moves us away from the accumulator-based bytecode format to one with explicit source and destination registers. The new format has multiple benefits: - ~25% faster on the Kraken and Octane benchmarks :^) - Fewer instructions to accomplish the same thing - Much easier for humans to read(!) Because this change requires a fundamental shift in how bytecode is generated, it is quite comprehensive. Main implementation mechanism: generate_bytecode() virtual function now takes an optional "preferred dst" operand, which allows callers to communicate when they have an operand that would be optimal for the result to go into. It also returns an optional "actual dst" operand, which is where the completion value (if any) of the AST node is stored after the node has "executed". One thing of note that's new: because instructions can now take locals as operands, this means we got rid of the GetLocal instruction. A side-effect of that is we have to think about the temporal deadzone (TDZ) a bit differently for locals (GetLocal would previously check for empty values and interpret that as a TDZ access and throw). We now insert special ThrowIfTDZ instructions in places where a local access may be in the TDZ, to maintain the correct behavior. There are a number of progressions and regressions from this test: A number of async generator tests have been accidentally fixed while converting the implementation to the new bytecode format. It didn't seem useful to preserve bugs in the original code when converting it. Some "does eval() return the correct completion value" tests have regressed, in particular ones related to propagating the appropriate completion after control flow statements like continue and break. These are all fairly obscure issues, and I believe we can continue working on them separately. The net test262 result is a progression though. :^)
2024-02-04 08:00:54 +01:00
auto object = TRY(interpreter.get(m_object).to_object(interpreter.vm()));
LibJS/JIT: Support the EnterObjectEnvironment bytecode instruction We can now use `with` statements in jitted code. :^)
2023-11-12 00:12:21 +01:00
interpreter.enter_object_environment(*object);
LibJS: Move all bytecode instruction implementations to Interpreter.cpp This allows aggressive inlining without LTO.
2023-09-27 10:10:00 +02:00
return {};
}
LibJS/JIT: Update "unwind context" stack in JIT code Until now, the unwind context stack has not been maintained by jitted code, which meant we were unable to support the `with` statement. This is a first step towards supporting that by making jitted code call out to C++ to update the unwind context stack when entering/leaving unwind contexts. We also introduce a new "Catch" bytecode instruction that moves the current exception into the accumulator. It's always emitted at the start of a "catch" block.
2023-11-11 23:19:46 +01:00
ThrowCompletionOr<void> Catch::execute_impl(Bytecode::Interpreter& interpreter) const
{
LibJS/Bytecode: Move to a new bytecode format This patch moves us away from the accumulator-based bytecode format to one with explicit source and destination registers. The new format has multiple benefits: - ~25% faster on the Kraken and Octane benchmarks :^) - Fewer instructions to accomplish the same thing - Much easier for humans to read(!) Because this change requires a fundamental shift in how bytecode is generated, it is quite comprehensive. Main implementation mechanism: generate_bytecode() virtual function now takes an optional "preferred dst" operand, which allows callers to communicate when they have an operand that would be optimal for the result to go into. It also returns an optional "actual dst" operand, which is where the completion value (if any) of the AST node is stored after the node has "executed". One thing of note that's new: because instructions can now take locals as operands, this means we got rid of the GetLocal instruction. A side-effect of that is we have to think about the temporal deadzone (TDZ) a bit differently for locals (GetLocal would previously check for empty values and interpret that as a TDZ access and throw). We now insert special ThrowIfTDZ instructions in places where a local access may be in the TDZ, to maintain the correct behavior. There are a number of progressions and regressions from this test: A number of async generator tests have been accidentally fixed while converting the implementation to the new bytecode format. It didn't seem useful to preserve bugs in the original code when converting it. Some "does eval() return the correct completion value" tests have regressed, in particular ones related to propagating the appropriate completion after control flow statements like continue and break. These are all fairly obscure issues, and I believe we can continue working on them separately. The net test262 result is a progression though. :^)
2024-02-04 08:00:54 +01:00
interpreter.catch_exception(dst());
LibJS/JIT: Update "unwind context" stack in JIT code Until now, the unwind context stack has not been maintained by jitted code, which meant we were unable to support the `with` statement. This is a first step towards supporting that by making jitted code call out to C++ to update the unwind context stack when entering/leaving unwind contexts. We also introduce a new "Catch" bytecode instruction that moves the current exception into the accumulator. It's always emitted at the start of a "catch" block.
2023-11-11 23:19:46 +01:00
return {};
}
LibJS: Cleanup unwind state when transferring control out of a finalizer This does two things: * Clear exceptions when transferring control out of a finalizer Otherwise they would resurface at the end of the next finalizer (see test the new test case), or at the end of a function * Pop one scheduled jump when transferring control out of a finalizer This removes one old FIXME
2024-04-11 11:58:18 +02:00
ThrowCompletionOr<void> LeaveFinally::execute_impl(Bytecode::Interpreter& interpreter) const
{
interpreter.leave_finally();
return {};
}
LibJS: Restore scheduled jumps in catch blocks without finalizers
2024-04-11 11:07:35 +02:00
ThrowCompletionOr<void> RestoreScheduledJump::execute_impl(Bytecode::Interpreter& interpreter) const
{
interpreter.restore_scheduled_jump();
return {};
}
LibJS: Move all bytecode instruction implementations to Interpreter.cpp This allows aggressive inlining without LTO.
2023-09-27 10:10:00 +02:00
ThrowCompletionOr<void> CreateVariable::execute_impl(Bytecode::Interpreter& interpreter) const
{
auto const& name = interpreter.current_executable().get_identifier(m_identifier);
LibJS/Bytecode: Move CreateVariable impl to CommonImplementations
2023-10-29 00:21:43 +02:00
return create_variable(interpreter.vm(), name, m_mode, m_is_global, m_is_immutable, m_is_strict);
LibJS: Move all bytecode instruction implementations to Interpreter.cpp This allows aggressive inlining without LTO.
2023-09-27 10:10:00 +02:00
}
ThrowCompletionOr<void> SetVariable::execute_impl(Bytecode::Interpreter& interpreter) const
{
auto& vm = interpreter.vm();
auto const& name = interpreter.current_executable().get_identifier(m_identifier);
LibJS/JIT: Add fastpath for set variable
2023-11-16 07:13:35 +01:00
TRY(set_variable(vm,
name,
LibJS/Bytecode: Move to a new bytecode format This patch moves us away from the accumulator-based bytecode format to one with explicit source and destination registers. The new format has multiple benefits: - ~25% faster on the Kraken and Octane benchmarks :^) - Fewer instructions to accomplish the same thing - Much easier for humans to read(!) Because this change requires a fundamental shift in how bytecode is generated, it is quite comprehensive. Main implementation mechanism: generate_bytecode() virtual function now takes an optional "preferred dst" operand, which allows callers to communicate when they have an operand that would be optimal for the result to go into. It also returns an optional "actual dst" operand, which is where the completion value (if any) of the AST node is stored after the node has "executed". One thing of note that's new: because instructions can now take locals as operands, this means we got rid of the GetLocal instruction. A side-effect of that is we have to think about the temporal deadzone (TDZ) a bit differently for locals (GetLocal would previously check for empty values and interpret that as a TDZ access and throw). We now insert special ThrowIfTDZ instructions in places where a local access may be in the TDZ, to maintain the correct behavior. There are a number of progressions and regressions from this test: A number of async generator tests have been accidentally fixed while converting the implementation to the new bytecode format. It didn't seem useful to preserve bugs in the original code when converting it. Some "does eval() return the correct completion value" tests have regressed, in particular ones related to propagating the appropriate completion after control flow statements like continue and break. These are all fairly obscure issues, and I believe we can continue working on them separately. The net test262 result is a progression though. :^)
2024-02-04 08:00:54 +01:00
interpreter.get(src()),
LibJS/JIT: Add fastpath for set variable
2023-11-16 07:13:35 +01:00
m_mode,
m_initialization_mode,
interpreter.current_executable().environment_variable_caches[m_cache_index]));
LibJS: Move all bytecode instruction implementations to Interpreter.cpp This allows aggressive inlining without LTO.
2023-09-27 10:10:00 +02:00
return {};
}
LibJS: Put __builtin_unreachable() in unused bytecode opcode handlers For the opcodes that are handled directly in the interpreter loop, we want the compiler to know that there's nothing to inline here.
2023-09-27 11:31:23 +02:00
ThrowCompletionOr<void> SetLocal::execute_impl(Bytecode::Interpreter&) const
LibJS: Move all bytecode instruction implementations to Interpreter.cpp This allows aggressive inlining without LTO.
2023-09-27 10:10:00 +02:00
{
LibJS: Put __builtin_unreachable() in unused bytecode opcode handlers For the opcodes that are handled directly in the interpreter loop, we want the compiler to know that there's nothing to inline here.
2023-09-27 11:31:23 +02:00
// Handled in the interpreter loop.
__builtin_unreachable();
LibJS: Move all bytecode instruction implementations to Interpreter.cpp This allows aggressive inlining without LTO.
2023-09-27 10:10:00 +02:00
}
ThrowCompletionOr<void> GetById::execute_impl(Bytecode::Interpreter& interpreter) const
{
LibJS: Include identifier information in nullish property read access When a GetById / GetByValue bytecode operation results in accessing a nullish object, we now include the name of the property and the object being accessed in the exception message (if available). This should make it easier to debug live websites. For example, the following errors would all previously produce a generic error message of "ToObject on null or undefined": > foo = null > foo.bar Uncaught exception: [TypeError] Cannot access property "bar" on null object "foo" at <unknown> > foo = { bar: undefined } > foo.bar.baz Uncaught exception: [TypeError] Cannot access property "baz" on undefined object "foo.bar" at <unknown> Note we certainly don't capture all possible nullish property read accesses here. This just covers cases I've seen most on live websites; we can cover more cases as they arise.
2024-03-29 11:26:10 -04:00
auto base_identifier = interpreter.current_executable().get_identifier(m_base_identifier);
auto const& property_identifier = interpreter.current_executable().get_identifier(m_property);
LibJS/Bytecode: Move to a new bytecode format This patch moves us away from the accumulator-based bytecode format to one with explicit source and destination registers. The new format has multiple benefits: - ~25% faster on the Kraken and Octane benchmarks :^) - Fewer instructions to accomplish the same thing - Much easier for humans to read(!) Because this change requires a fundamental shift in how bytecode is generated, it is quite comprehensive. Main implementation mechanism: generate_bytecode() virtual function now takes an optional "preferred dst" operand, which allows callers to communicate when they have an operand that would be optimal for the result to go into. It also returns an optional "actual dst" operand, which is where the completion value (if any) of the AST node is stored after the node has "executed". One thing of note that's new: because instructions can now take locals as operands, this means we got rid of the GetLocal instruction. A side-effect of that is we have to think about the temporal deadzone (TDZ) a bit differently for locals (GetLocal would previously check for empty values and interpret that as a TDZ access and throw). We now insert special ThrowIfTDZ instructions in places where a local access may be in the TDZ, to maintain the correct behavior. There are a number of progressions and regressions from this test: A number of async generator tests have been accidentally fixed while converting the implementation to the new bytecode format. It didn't seem useful to preserve bugs in the original code when converting it. Some "does eval() return the correct completion value" tests have regressed, in particular ones related to propagating the appropriate completion after control flow statements like continue and break. These are all fairly obscure issues, and I believe we can continue working on them separately. The net test262 result is a progression though. :^)
2024-02-04 08:00:54 +01:00
auto base_value = interpreter.get(base());
LibJS/JIT: Resolve the PropertyLookupCache pointers at JIT time We know where the lookup cache is by the time we're jitting code, so let's put the pointer directly into the instruction stream.
2023-11-05 14:33:54 +01:00
auto& cache = interpreter.current_executable().property_lookup_caches[m_cache_index];
LibJS: Include identifier information in nullish property read access When a GetById / GetByValue bytecode operation results in accessing a nullish object, we now include the name of the property and the object being accessed in the exception message (if available). This should make it easier to debug live websites. For example, the following errors would all previously produce a generic error message of "ToObject on null or undefined": > foo = null > foo.bar Uncaught exception: [TypeError] Cannot access property "bar" on null object "foo" at <unknown> > foo = { bar: undefined } > foo.bar.baz Uncaught exception: [TypeError] Cannot access property "baz" on undefined object "foo.bar" at <unknown> Note we certainly don't capture all possible nullish property read accesses here. This just covers cases I've seen most on live websites; we can cover more cases as they arise.
2024-03-29 11:26:10 -04:00
interpreter.set(dst(), TRY(get_by_id(interpreter.vm(), base_identifier, property_identifier, base_value, base_value, cache)));
LibJS/Bytecode: Begin moving shareable (JIT+Interpreter) stuff somewhere There are a lot of native C++ functions that will be used by both the bytecode interpreter and jitted code. Let's put them in their own file instead of having them in Interpreter.cpp.
2023-10-18 13:26:47 +02:00
return {};
LibJS: Move all bytecode instruction implementations to Interpreter.cpp This allows aggressive inlining without LTO.
2023-09-27 10:10:00 +02:00
}
ThrowCompletionOr<void> GetByIdWithThis::execute_impl(Bytecode::Interpreter& interpreter) const
{
LibJS/Bytecode: Move to a new bytecode format This patch moves us away from the accumulator-based bytecode format to one with explicit source and destination registers. The new format has multiple benefits: - ~25% faster on the Kraken and Octane benchmarks :^) - Fewer instructions to accomplish the same thing - Much easier for humans to read(!) Because this change requires a fundamental shift in how bytecode is generated, it is quite comprehensive. Main implementation mechanism: generate_bytecode() virtual function now takes an optional "preferred dst" operand, which allows callers to communicate when they have an operand that would be optimal for the result to go into. It also returns an optional "actual dst" operand, which is where the completion value (if any) of the AST node is stored after the node has "executed". One thing of note that's new: because instructions can now take locals as operands, this means we got rid of the GetLocal instruction. A side-effect of that is we have to think about the temporal deadzone (TDZ) a bit differently for locals (GetLocal would previously check for empty values and interpret that as a TDZ access and throw). We now insert special ThrowIfTDZ instructions in places where a local access may be in the TDZ, to maintain the correct behavior. There are a number of progressions and regressions from this test: A number of async generator tests have been accidentally fixed while converting the implementation to the new bytecode format. It didn't seem useful to preserve bugs in the original code when converting it. Some "does eval() return the correct completion value" tests have regressed, in particular ones related to propagating the appropriate completion after control flow statements like continue and break. These are all fairly obscure issues, and I believe we can continue working on them separately. The net test262 result is a progression though. :^)
2024-02-04 08:00:54 +01:00
auto base_value = interpreter.get(m_base);
auto this_value = interpreter.get(m_this_value);
LibJS/JIT: Resolve the PropertyLookupCache pointers at JIT time We know where the lookup cache is by the time we're jitting code, so let's put the pointer directly into the instruction stream.
2023-11-05 14:33:54 +01:00
auto& cache = interpreter.current_executable().property_lookup_caches[m_cache_index];
LibJS: Include identifier information in nullish property read access When a GetById / GetByValue bytecode operation results in accessing a nullish object, we now include the name of the property and the object being accessed in the exception message (if available). This should make it easier to debug live websites. For example, the following errors would all previously produce a generic error message of "ToObject on null or undefined": > foo = null > foo.bar Uncaught exception: [TypeError] Cannot access property "bar" on null object "foo" at <unknown> > foo = { bar: undefined } > foo.bar.baz Uncaught exception: [TypeError] Cannot access property "baz" on undefined object "foo.bar" at <unknown> Note we certainly don't capture all possible nullish property read accesses here. This just covers cases I've seen most on live websites; we can cover more cases as they arise.
2024-03-29 11:26:10 -04:00
interpreter.set(dst(), TRY(get_by_id(interpreter.vm(), {}, interpreter.current_executable().get_identifier(m_property), base_value, this_value, cache)));
LibJS/Bytecode: Begin moving shareable (JIT+Interpreter) stuff somewhere There are a lot of native C++ functions that will be used by both the bytecode interpreter and jitted code. Let's put them in their own file instead of having them in Interpreter.cpp.
2023-10-18 13:26:47 +02:00
return {};
LibJS: Move all bytecode instruction implementations to Interpreter.cpp This allows aggressive inlining without LTO.
2023-09-27 10:10:00 +02:00
}
ThrowCompletionOr<void> GetPrivateById::execute_impl(Bytecode::Interpreter& interpreter) const
{
auto& vm = interpreter.vm();
auto const& name = interpreter.current_executable().get_identifier(m_property);
LibJS/Bytecode: Move to a new bytecode format This patch moves us away from the accumulator-based bytecode format to one with explicit source and destination registers. The new format has multiple benefits: - ~25% faster on the Kraken and Octane benchmarks :^) - Fewer instructions to accomplish the same thing - Much easier for humans to read(!) Because this change requires a fundamental shift in how bytecode is generated, it is quite comprehensive. Main implementation mechanism: generate_bytecode() virtual function now takes an optional "preferred dst" operand, which allows callers to communicate when they have an operand that would be optimal for the result to go into. It also returns an optional "actual dst" operand, which is where the completion value (if any) of the AST node is stored after the node has "executed". One thing of note that's new: because instructions can now take locals as operands, this means we got rid of the GetLocal instruction. A side-effect of that is we have to think about the temporal deadzone (TDZ) a bit differently for locals (GetLocal would previously check for empty values and interpret that as a TDZ access and throw). We now insert special ThrowIfTDZ instructions in places where a local access may be in the TDZ, to maintain the correct behavior. There are a number of progressions and regressions from this test: A number of async generator tests have been accidentally fixed while converting the implementation to the new bytecode format. It didn't seem useful to preserve bugs in the original code when converting it. Some "does eval() return the correct completion value" tests have regressed, in particular ones related to propagating the appropriate completion after control flow statements like continue and break. These are all fairly obscure issues, and I believe we can continue working on them separately. The net test262 result is a progression though. :^)
2024-02-04 08:00:54 +01:00
auto base_value = interpreter.get(m_base);
LibJS: Move all bytecode instruction implementations to Interpreter.cpp This allows aggressive inlining without LTO.
2023-09-27 10:10:00 +02:00
auto private_reference = make_private_reference(vm, base_value, name);
LibJS/Bytecode: Move to a new bytecode format This patch moves us away from the accumulator-based bytecode format to one with explicit source and destination registers. The new format has multiple benefits: - ~25% faster on the Kraken and Octane benchmarks :^) - Fewer instructions to accomplish the same thing - Much easier for humans to read(!) Because this change requires a fundamental shift in how bytecode is generated, it is quite comprehensive. Main implementation mechanism: generate_bytecode() virtual function now takes an optional "preferred dst" operand, which allows callers to communicate when they have an operand that would be optimal for the result to go into. It also returns an optional "actual dst" operand, which is where the completion value (if any) of the AST node is stored after the node has "executed". One thing of note that's new: because instructions can now take locals as operands, this means we got rid of the GetLocal instruction. A side-effect of that is we have to think about the temporal deadzone (TDZ) a bit differently for locals (GetLocal would previously check for empty values and interpret that as a TDZ access and throw). We now insert special ThrowIfTDZ instructions in places where a local access may be in the TDZ, to maintain the correct behavior. There are a number of progressions and regressions from this test: A number of async generator tests have been accidentally fixed while converting the implementation to the new bytecode format. It didn't seem useful to preserve bugs in the original code when converting it. Some "does eval() return the correct completion value" tests have regressed, in particular ones related to propagating the appropriate completion after control flow statements like continue and break. These are all fairly obscure issues, and I believe we can continue working on them separately. The net test262 result is a progression though. :^)
2024-02-04 08:00:54 +01:00
interpreter.set(dst(), TRY(private_reference.get_value(vm)));
LibJS: Move all bytecode instruction implementations to Interpreter.cpp This allows aggressive inlining without LTO.
2023-09-27 10:10:00 +02:00
return {};
}
ThrowCompletionOr<void> HasPrivateId::execute_impl(Bytecode::Interpreter& interpreter) const
{
auto& vm = interpreter.vm();
LibJS/Bytecode: Move to a new bytecode format This patch moves us away from the accumulator-based bytecode format to one with explicit source and destination registers. The new format has multiple benefits: - ~25% faster on the Kraken and Octane benchmarks :^) - Fewer instructions to accomplish the same thing - Much easier for humans to read(!) Because this change requires a fundamental shift in how bytecode is generated, it is quite comprehensive. Main implementation mechanism: generate_bytecode() virtual function now takes an optional "preferred dst" operand, which allows callers to communicate when they have an operand that would be optimal for the result to go into. It also returns an optional "actual dst" operand, which is where the completion value (if any) of the AST node is stored after the node has "executed". One thing of note that's new: because instructions can now take locals as operands, this means we got rid of the GetLocal instruction. A side-effect of that is we have to think about the temporal deadzone (TDZ) a bit differently for locals (GetLocal would previously check for empty values and interpret that as a TDZ access and throw). We now insert special ThrowIfTDZ instructions in places where a local access may be in the TDZ, to maintain the correct behavior. There are a number of progressions and regressions from this test: A number of async generator tests have been accidentally fixed while converting the implementation to the new bytecode format. It didn't seem useful to preserve bugs in the original code when converting it. Some "does eval() return the correct completion value" tests have regressed, in particular ones related to propagating the appropriate completion after control flow statements like continue and break. These are all fairly obscure issues, and I believe we can continue working on them separately. The net test262 result is a progression though. :^)
2024-02-04 08:00:54 +01:00
auto base = interpreter.get(m_base);
if (!base.is_object())
LibJS: Move all bytecode instruction implementations to Interpreter.cpp This allows aggressive inlining without LTO.
2023-09-27 10:10:00 +02:00
return vm.throw_completion<TypeError>(ErrorType::InOperatorWithObject);
auto private_environment = vm.running_execution_context().private_environment;
VERIFY(private_environment);
auto private_name = private_environment->resolve_private_identifier(interpreter.current_executable().get_identifier(m_property));
LibJS/Bytecode: Move to a new bytecode format This patch moves us away from the accumulator-based bytecode format to one with explicit source and destination registers. The new format has multiple benefits: - ~25% faster on the Kraken and Octane benchmarks :^) - Fewer instructions to accomplish the same thing - Much easier for humans to read(!) Because this change requires a fundamental shift in how bytecode is generated, it is quite comprehensive. Main implementation mechanism: generate_bytecode() virtual function now takes an optional "preferred dst" operand, which allows callers to communicate when they have an operand that would be optimal for the result to go into. It also returns an optional "actual dst" operand, which is where the completion value (if any) of the AST node is stored after the node has "executed". One thing of note that's new: because instructions can now take locals as operands, this means we got rid of the GetLocal instruction. A side-effect of that is we have to think about the temporal deadzone (TDZ) a bit differently for locals (GetLocal would previously check for empty values and interpret that as a TDZ access and throw). We now insert special ThrowIfTDZ instructions in places where a local access may be in the TDZ, to maintain the correct behavior. There are a number of progressions and regressions from this test: A number of async generator tests have been accidentally fixed while converting the implementation to the new bytecode format. It didn't seem useful to preserve bugs in the original code when converting it. Some "does eval() return the correct completion value" tests have regressed, in particular ones related to propagating the appropriate completion after control flow statements like continue and break. These are all fairly obscure issues, and I believe we can continue working on them separately. The net test262 result is a progression though. :^)
2024-02-04 08:00:54 +01:00
interpreter.set(dst(), Value(base.as_object().private_element_find(private_name) != nullptr));
LibJS: Move all bytecode instruction implementations to Interpreter.cpp This allows aggressive inlining without LTO.
2023-09-27 10:10:00 +02:00
return {};
}
ThrowCompletionOr<void> PutById::execute_impl(Bytecode::Interpreter& interpreter) const
{
auto& vm = interpreter.vm();
LibJS/Bytecode: Move to a new bytecode format This patch moves us away from the accumulator-based bytecode format to one with explicit source and destination registers. The new format has multiple benefits: - ~25% faster on the Kraken and Octane benchmarks :^) - Fewer instructions to accomplish the same thing - Much easier for humans to read(!) Because this change requires a fundamental shift in how bytecode is generated, it is quite comprehensive. Main implementation mechanism: generate_bytecode() virtual function now takes an optional "preferred dst" operand, which allows callers to communicate when they have an operand that would be optimal for the result to go into. It also returns an optional "actual dst" operand, which is where the completion value (if any) of the AST node is stored after the node has "executed". One thing of note that's new: because instructions can now take locals as operands, this means we got rid of the GetLocal instruction. A side-effect of that is we have to think about the temporal deadzone (TDZ) a bit differently for locals (GetLocal would previously check for empty values and interpret that as a TDZ access and throw). We now insert special ThrowIfTDZ instructions in places where a local access may be in the TDZ, to maintain the correct behavior. There are a number of progressions and regressions from this test: A number of async generator tests have been accidentally fixed while converting the implementation to the new bytecode format. It didn't seem useful to preserve bugs in the original code when converting it. Some "does eval() return the correct completion value" tests have regressed, in particular ones related to propagating the appropriate completion after control flow statements like continue and break. These are all fairly obscure issues, and I believe we can continue working on them separately. The net test262 result is a progression though. :^)
2024-02-04 08:00:54 +01:00
auto value = interpreter.get(m_src);
auto base = interpreter.get(m_base);
LibJS: Include identifier information in nullish property write access When a PutById / PutByValue bytecode operation results in accessing a nullish object, we now include the name of the property and the object being accessed in the exception message (if available). This should make it easier to debug live websites. For example, the following errors would all previously produce a generic error message of "ToObject on null or undefined": > foo = null > foo.bar = 1 Uncaught exception: [TypeError] Cannot access property "bar" on null object "foo" at <unknown> > foo = { bar: undefined } > foo.bar.baz = 1 Uncaught exception: [TypeError] Cannot access property "baz" on undefined object "foo.bar" at <unknown> Note we certainly don't capture all possible nullish property write accesses here. This just covers cases I've seen most on live websites; we can cover more cases as they arise.
2024-03-29 12:10:52 -04:00
auto base_identifier = interpreter.current_executable().get_identifier(m_base_identifier);
LibJS: Move all bytecode instruction implementations to Interpreter.cpp This allows aggressive inlining without LTO.
2023-09-27 10:10:00 +02:00
PropertyKey name = interpreter.current_executable().get_identifier(m_property);
LibJS: Add basic monomorphic caching for PutById property access This patch makes it possible for JS::Object::internal_set() to populate a CacheablePropertyMetadata, and uses this to implement a basic monomorphic cache for the most common form of property write access.
2023-11-08 20:51:26 +01:00
auto& cache = interpreter.current_executable().property_lookup_caches[m_cache_index];
LibJS: Include identifier information in nullish property write access When a PutById / PutByValue bytecode operation results in accessing a nullish object, we now include the name of the property and the object being accessed in the exception message (if available). This should make it easier to debug live websites. For example, the following errors would all previously produce a generic error message of "ToObject on null or undefined": > foo = null > foo.bar = 1 Uncaught exception: [TypeError] Cannot access property "bar" on null object "foo" at <unknown> > foo = { bar: undefined } > foo.bar.baz = 1 Uncaught exception: [TypeError] Cannot access property "baz" on undefined object "foo.bar" at <unknown> Note we certainly don't capture all possible nullish property write accesses here. This just covers cases I've seen most on live websites; we can cover more cases as they arise.
2024-03-29 12:10:52 -04:00
TRY(put_by_property_key(vm, base, base, value, base_identifier, name, m_kind, &cache));
LibJS: Move all bytecode instruction implementations to Interpreter.cpp This allows aggressive inlining without LTO.
2023-09-27 10:10:00 +02:00
return {};
}
ThrowCompletionOr<void> PutByIdWithThis::execute_impl(Bytecode::Interpreter& interpreter) const
{
auto& vm = interpreter.vm();
LibJS/Bytecode: Move to a new bytecode format This patch moves us away from the accumulator-based bytecode format to one with explicit source and destination registers. The new format has multiple benefits: - ~25% faster on the Kraken and Octane benchmarks :^) - Fewer instructions to accomplish the same thing - Much easier for humans to read(!) Because this change requires a fundamental shift in how bytecode is generated, it is quite comprehensive. Main implementation mechanism: generate_bytecode() virtual function now takes an optional "preferred dst" operand, which allows callers to communicate when they have an operand that would be optimal for the result to go into. It also returns an optional "actual dst" operand, which is where the completion value (if any) of the AST node is stored after the node has "executed". One thing of note that's new: because instructions can now take locals as operands, this means we got rid of the GetLocal instruction. A side-effect of that is we have to think about the temporal deadzone (TDZ) a bit differently for locals (GetLocal would previously check for empty values and interpret that as a TDZ access and throw). We now insert special ThrowIfTDZ instructions in places where a local access may be in the TDZ, to maintain the correct behavior. There are a number of progressions and regressions from this test: A number of async generator tests have been accidentally fixed while converting the implementation to the new bytecode format. It didn't seem useful to preserve bugs in the original code when converting it. Some "does eval() return the correct completion value" tests have regressed, in particular ones related to propagating the appropriate completion after control flow statements like continue and break. These are all fairly obscure issues, and I believe we can continue working on them separately. The net test262 result is a progression though. :^)
2024-02-04 08:00:54 +01:00
auto value = interpreter.get(m_src);
auto base = interpreter.get(m_base);
LibJS: Move all bytecode instruction implementations to Interpreter.cpp This allows aggressive inlining without LTO.
2023-09-27 10:10:00 +02:00
PropertyKey name = interpreter.current_executable().get_identifier(m_property);
LibJS: Add basic monomorphic caching for PutById property access This patch makes it possible for JS::Object::internal_set() to populate a CacheablePropertyMetadata, and uses this to implement a basic monomorphic cache for the most common form of property write access.
2023-11-08 20:51:26 +01:00
auto& cache = interpreter.current_executable().property_lookup_caches[m_cache_index];
LibJS: Include identifier information in nullish property write access When a PutById / PutByValue bytecode operation results in accessing a nullish object, we now include the name of the property and the object being accessed in the exception message (if available). This should make it easier to debug live websites. For example, the following errors would all previously produce a generic error message of "ToObject on null or undefined": > foo = null > foo.bar = 1 Uncaught exception: [TypeError] Cannot access property "bar" on null object "foo" at <unknown> > foo = { bar: undefined } > foo.bar.baz = 1 Uncaught exception: [TypeError] Cannot access property "baz" on undefined object "foo.bar" at <unknown> Note we certainly don't capture all possible nullish property write accesses here. This just covers cases I've seen most on live websites; we can cover more cases as they arise.
2024-03-29 12:10:52 -04:00
TRY(put_by_property_key(vm, base, interpreter.get(m_this_value), value, {}, name, m_kind, &cache));
LibJS: Move all bytecode instruction implementations to Interpreter.cpp This allows aggressive inlining without LTO.
2023-09-27 10:10:00 +02:00
return {};
}
ThrowCompletionOr<void> PutPrivateById::execute_impl(Bytecode::Interpreter& interpreter) const
{
auto& vm = interpreter.vm();
LibJS/Bytecode: Move to a new bytecode format This patch moves us away from the accumulator-based bytecode format to one with explicit source and destination registers. The new format has multiple benefits: - ~25% faster on the Kraken and Octane benchmarks :^) - Fewer instructions to accomplish the same thing - Much easier for humans to read(!) Because this change requires a fundamental shift in how bytecode is generated, it is quite comprehensive. Main implementation mechanism: generate_bytecode() virtual function now takes an optional "preferred dst" operand, which allows callers to communicate when they have an operand that would be optimal for the result to go into. It also returns an optional "actual dst" operand, which is where the completion value (if any) of the AST node is stored after the node has "executed". One thing of note that's new: because instructions can now take locals as operands, this means we got rid of the GetLocal instruction. A side-effect of that is we have to think about the temporal deadzone (TDZ) a bit differently for locals (GetLocal would previously check for empty values and interpret that as a TDZ access and throw). We now insert special ThrowIfTDZ instructions in places where a local access may be in the TDZ, to maintain the correct behavior. There are a number of progressions and regressions from this test: A number of async generator tests have been accidentally fixed while converting the implementation to the new bytecode format. It didn't seem useful to preserve bugs in the original code when converting it. Some "does eval() return the correct completion value" tests have regressed, in particular ones related to propagating the appropriate completion after control flow statements like continue and break. These are all fairly obscure issues, and I believe we can continue working on them separately. The net test262 result is a progression though. :^)
2024-02-04 08:00:54 +01:00
auto value = interpreter.get(m_src);
auto object = TRY(interpreter.get(m_base).to_object(vm));
LibJS: Move all bytecode instruction implementations to Interpreter.cpp This allows aggressive inlining without LTO.
2023-09-27 10:10:00 +02:00
auto name = interpreter.current_executable().get_identifier(m_property);
auto private_reference = make_private_reference(vm, object, name);
TRY(private_reference.put_value(vm, value));
return {};
}
ThrowCompletionOr<void> DeleteById::execute_impl(Bytecode::Interpreter& interpreter) const
{
LibJS/Bytecode: Move to a new bytecode format This patch moves us away from the accumulator-based bytecode format to one with explicit source and destination registers. The new format has multiple benefits: - ~25% faster on the Kraken and Octane benchmarks :^) - Fewer instructions to accomplish the same thing - Much easier for humans to read(!) Because this change requires a fundamental shift in how bytecode is generated, it is quite comprehensive. Main implementation mechanism: generate_bytecode() virtual function now takes an optional "preferred dst" operand, which allows callers to communicate when they have an operand that would be optimal for the result to go into. It also returns an optional "actual dst" operand, which is where the completion value (if any) of the AST node is stored after the node has "executed". One thing of note that's new: because instructions can now take locals as operands, this means we got rid of the GetLocal instruction. A side-effect of that is we have to think about the temporal deadzone (TDZ) a bit differently for locals (GetLocal would previously check for empty values and interpret that as a TDZ access and throw). We now insert special ThrowIfTDZ instructions in places where a local access may be in the TDZ, to maintain the correct behavior. There are a number of progressions and regressions from this test: A number of async generator tests have been accidentally fixed while converting the implementation to the new bytecode format. It didn't seem useful to preserve bugs in the original code when converting it. Some "does eval() return the correct completion value" tests have regressed, in particular ones related to propagating the appropriate completion after control flow statements like continue and break. These are all fairly obscure issues, and I believe we can continue working on them separately. The net test262 result is a progression though. :^)
2024-02-04 08:00:54 +01:00
auto base_value = interpreter.get(m_base);
interpreter.set(dst(), TRY(Bytecode::delete_by_id(interpreter, base_value, m_property)));
LibJS: Move all bytecode instruction implementations to Interpreter.cpp This allows aggressive inlining without LTO.
2023-09-27 10:10:00 +02:00
return {};
}
ThrowCompletionOr<void> DeleteByIdWithThis::execute_impl(Bytecode::Interpreter& interpreter) const
{
auto& vm = interpreter.vm();
LibJS/Bytecode: Move to a new bytecode format This patch moves us away from the accumulator-based bytecode format to one with explicit source and destination registers. The new format has multiple benefits: - ~25% faster on the Kraken and Octane benchmarks :^) - Fewer instructions to accomplish the same thing - Much easier for humans to read(!) Because this change requires a fundamental shift in how bytecode is generated, it is quite comprehensive. Main implementation mechanism: generate_bytecode() virtual function now takes an optional "preferred dst" operand, which allows callers to communicate when they have an operand that would be optimal for the result to go into. It also returns an optional "actual dst" operand, which is where the completion value (if any) of the AST node is stored after the node has "executed". One thing of note that's new: because instructions can now take locals as operands, this means we got rid of the GetLocal instruction. A side-effect of that is we have to think about the temporal deadzone (TDZ) a bit differently for locals (GetLocal would previously check for empty values and interpret that as a TDZ access and throw). We now insert special ThrowIfTDZ instructions in places where a local access may be in the TDZ, to maintain the correct behavior. There are a number of progressions and regressions from this test: A number of async generator tests have been accidentally fixed while converting the implementation to the new bytecode format. It didn't seem useful to preserve bugs in the original code when converting it. Some "does eval() return the correct completion value" tests have regressed, in particular ones related to propagating the appropriate completion after control flow statements like continue and break. These are all fairly obscure issues, and I believe we can continue working on them separately. The net test262 result is a progression though. :^)
2024-02-04 08:00:54 +01:00
auto base_value = interpreter.get(m_base);
LibJS: Move all bytecode instruction implementations to Interpreter.cpp This allows aggressive inlining without LTO.
2023-09-27 10:10:00 +02:00
auto const& identifier = interpreter.current_executable().get_identifier(m_property);
bool strict = vm.in_strict_mode();
LibJS/Bytecode: Move to a new bytecode format This patch moves us away from the accumulator-based bytecode format to one with explicit source and destination registers. The new format has multiple benefits: - ~25% faster on the Kraken and Octane benchmarks :^) - Fewer instructions to accomplish the same thing - Much easier for humans to read(!) Because this change requires a fundamental shift in how bytecode is generated, it is quite comprehensive. Main implementation mechanism: generate_bytecode() virtual function now takes an optional "preferred dst" operand, which allows callers to communicate when they have an operand that would be optimal for the result to go into. It also returns an optional "actual dst" operand, which is where the completion value (if any) of the AST node is stored after the node has "executed". One thing of note that's new: because instructions can now take locals as operands, this means we got rid of the GetLocal instruction. A side-effect of that is we have to think about the temporal deadzone (TDZ) a bit differently for locals (GetLocal would previously check for empty values and interpret that as a TDZ access and throw). We now insert special ThrowIfTDZ instructions in places where a local access may be in the TDZ, to maintain the correct behavior. There are a number of progressions and regressions from this test: A number of async generator tests have been accidentally fixed while converting the implementation to the new bytecode format. It didn't seem useful to preserve bugs in the original code when converting it. Some "does eval() return the correct completion value" tests have regressed, in particular ones related to propagating the appropriate completion after control flow statements like continue and break. These are all fairly obscure issues, and I believe we can continue working on them separately. The net test262 result is a progression though. :^)
2024-02-04 08:00:54 +01:00
auto reference = Reference { base_value, identifier, interpreter.get(m_this_value), strict };
interpreter.set(dst(), Value(TRY(reference.delete_(vm))));
LibJS: Move all bytecode instruction implementations to Interpreter.cpp This allows aggressive inlining without LTO.
2023-09-27 10:10:00 +02:00
return {};
}
ThrowCompletionOr<void> Jump::execute_impl(Bytecode::Interpreter&) const
{
// Handled in the interpreter loop.
LibJS: Put __builtin_unreachable() in unused bytecode opcode handlers For the opcodes that are handled directly in the interpreter loop, we want the compiler to know that there's nothing to inline here.
2023-09-27 11:31:23 +02:00
__builtin_unreachable();
LibJS: Move all bytecode instruction implementations to Interpreter.cpp This allows aggressive inlining without LTO.
2023-09-27 10:10:00 +02:00
}
ThrowCompletionOr<void> ResolveThisBinding::execute_impl(Bytecode::Interpreter& interpreter) const
{
auto& cached_this_value = interpreter.reg(Register::this_value());
if (cached_this_value.is_empty()) {
// OPTIMIZATION: Because the value of 'this' cannot be reassigned during a function execution, it's
// resolved once and then saved for subsequent use.
auto& vm = interpreter.vm();
cached_this_value = TRY(vm.resolve_this_binding());
}
LibJS/Bytecode: Move to a new bytecode format This patch moves us away from the accumulator-based bytecode format to one with explicit source and destination registers. The new format has multiple benefits: - ~25% faster on the Kraken and Octane benchmarks :^) - Fewer instructions to accomplish the same thing - Much easier for humans to read(!) Because this change requires a fundamental shift in how bytecode is generated, it is quite comprehensive. Main implementation mechanism: generate_bytecode() virtual function now takes an optional "preferred dst" operand, which allows callers to communicate when they have an operand that would be optimal for the result to go into. It also returns an optional "actual dst" operand, which is where the completion value (if any) of the AST node is stored after the node has "executed". One thing of note that's new: because instructions can now take locals as operands, this means we got rid of the GetLocal instruction. A side-effect of that is we have to think about the temporal deadzone (TDZ) a bit differently for locals (GetLocal would previously check for empty values and interpret that as a TDZ access and throw). We now insert special ThrowIfTDZ instructions in places where a local access may be in the TDZ, to maintain the correct behavior. There are a number of progressions and regressions from this test: A number of async generator tests have been accidentally fixed while converting the implementation to the new bytecode format. It didn't seem useful to preserve bugs in the original code when converting it. Some "does eval() return the correct completion value" tests have regressed, in particular ones related to propagating the appropriate completion after control flow statements like continue and break. These are all fairly obscure issues, and I believe we can continue working on them separately. The net test262 result is a progression though. :^)
2024-02-04 08:00:54 +01:00
interpreter.set(dst(), cached_this_value);
LibJS: Move all bytecode instruction implementations to Interpreter.cpp This allows aggressive inlining without LTO.
2023-09-27 10:10:00 +02:00
return {};
}
// https://tc39.es/ecma262/#sec-makesuperpropertyreference
ThrowCompletionOr<void> ResolveSuperBase::execute_impl(Bytecode::Interpreter& interpreter) const
{
auto& vm = interpreter.vm();
// 1. Let env be GetThisEnvironment().
auto& env = verify_cast<FunctionEnvironment>(*get_this_environment(vm));
// 2. Assert: env.HasSuperBinding() is true.
VERIFY(env.has_super_binding());
// 3. Let baseValue be ? env.GetSuperBase().
LibJS/Bytecode: Move to a new bytecode format This patch moves us away from the accumulator-based bytecode format to one with explicit source and destination registers. The new format has multiple benefits: - ~25% faster on the Kraken and Octane benchmarks :^) - Fewer instructions to accomplish the same thing - Much easier for humans to read(!) Because this change requires a fundamental shift in how bytecode is generated, it is quite comprehensive. Main implementation mechanism: generate_bytecode() virtual function now takes an optional "preferred dst" operand, which allows callers to communicate when they have an operand that would be optimal for the result to go into. It also returns an optional "actual dst" operand, which is where the completion value (if any) of the AST node is stored after the node has "executed". One thing of note that's new: because instructions can now take locals as operands, this means we got rid of the GetLocal instruction. A side-effect of that is we have to think about the temporal deadzone (TDZ) a bit differently for locals (GetLocal would previously check for empty values and interpret that as a TDZ access and throw). We now insert special ThrowIfTDZ instructions in places where a local access may be in the TDZ, to maintain the correct behavior. There are a number of progressions and regressions from this test: A number of async generator tests have been accidentally fixed while converting the implementation to the new bytecode format. It didn't seem useful to preserve bugs in the original code when converting it. Some "does eval() return the correct completion value" tests have regressed, in particular ones related to propagating the appropriate completion after control flow statements like continue and break. These are all fairly obscure issues, and I believe we can continue working on them separately. The net test262 result is a progression though. :^)
2024-02-04 08:00:54 +01:00
interpreter.set(dst(), TRY(env.get_super_base()));
LibJS: Move all bytecode instruction implementations to Interpreter.cpp This allows aggressive inlining without LTO.
2023-09-27 10:10:00 +02:00
return {};
}
ThrowCompletionOr<void> GetNewTarget::execute_impl(Bytecode::Interpreter& interpreter) const
{
LibJS/Bytecode: Move to a new bytecode format This patch moves us away from the accumulator-based bytecode format to one with explicit source and destination registers. The new format has multiple benefits: - ~25% faster on the Kraken and Octane benchmarks :^) - Fewer instructions to accomplish the same thing - Much easier for humans to read(!) Because this change requires a fundamental shift in how bytecode is generated, it is quite comprehensive. Main implementation mechanism: generate_bytecode() virtual function now takes an optional "preferred dst" operand, which allows callers to communicate when they have an operand that would be optimal for the result to go into. It also returns an optional "actual dst" operand, which is where the completion value (if any) of the AST node is stored after the node has "executed". One thing of note that's new: because instructions can now take locals as operands, this means we got rid of the GetLocal instruction. A side-effect of that is we have to think about the temporal deadzone (TDZ) a bit differently for locals (GetLocal would previously check for empty values and interpret that as a TDZ access and throw). We now insert special ThrowIfTDZ instructions in places where a local access may be in the TDZ, to maintain the correct behavior. There are a number of progressions and regressions from this test: A number of async generator tests have been accidentally fixed while converting the implementation to the new bytecode format. It didn't seem useful to preserve bugs in the original code when converting it. Some "does eval() return the correct completion value" tests have regressed, in particular ones related to propagating the appropriate completion after control flow statements like continue and break. These are all fairly obscure issues, and I believe we can continue working on them separately. The net test262 result is a progression though. :^)
2024-02-04 08:00:54 +01:00
interpreter.set(dst(), interpreter.vm().get_new_target());
LibJS: Move all bytecode instruction implementations to Interpreter.cpp This allows aggressive inlining without LTO.
2023-09-27 10:10:00 +02:00
return {};
}
ThrowCompletionOr<void> GetImportMeta::execute_impl(Bytecode::Interpreter& interpreter) const
{
LibJS/Bytecode: Move to a new bytecode format This patch moves us away from the accumulator-based bytecode format to one with explicit source and destination registers. The new format has multiple benefits: - ~25% faster on the Kraken and Octane benchmarks :^) - Fewer instructions to accomplish the same thing - Much easier for humans to read(!) Because this change requires a fundamental shift in how bytecode is generated, it is quite comprehensive. Main implementation mechanism: generate_bytecode() virtual function now takes an optional "preferred dst" operand, which allows callers to communicate when they have an operand that would be optimal for the result to go into. It also returns an optional "actual dst" operand, which is where the completion value (if any) of the AST node is stored after the node has "executed". One thing of note that's new: because instructions can now take locals as operands, this means we got rid of the GetLocal instruction. A side-effect of that is we have to think about the temporal deadzone (TDZ) a bit differently for locals (GetLocal would previously check for empty values and interpret that as a TDZ access and throw). We now insert special ThrowIfTDZ instructions in places where a local access may be in the TDZ, to maintain the correct behavior. There are a number of progressions and regressions from this test: A number of async generator tests have been accidentally fixed while converting the implementation to the new bytecode format. It didn't seem useful to preserve bugs in the original code when converting it. Some "does eval() return the correct completion value" tests have regressed, in particular ones related to propagating the appropriate completion after control flow statements like continue and break. These are all fairly obscure issues, and I believe we can continue working on them separately. The net test262 result is a progression though. :^)
2024-02-04 08:00:54 +01:00
interpreter.set(dst(), interpreter.vm().get_import_meta());
LibJS: Move all bytecode instruction implementations to Interpreter.cpp This allows aggressive inlining without LTO.
2023-09-27 10:10:00 +02:00
return {};
}
LibJS/Bytecode: Move to a new bytecode format This patch moves us away from the accumulator-based bytecode format to one with explicit source and destination registers. The new format has multiple benefits: - ~25% faster on the Kraken and Octane benchmarks :^) - Fewer instructions to accomplish the same thing - Much easier for humans to read(!) Because this change requires a fundamental shift in how bytecode is generated, it is quite comprehensive. Main implementation mechanism: generate_bytecode() virtual function now takes an optional "preferred dst" operand, which allows callers to communicate when they have an operand that would be optimal for the result to go into. It also returns an optional "actual dst" operand, which is where the completion value (if any) of the AST node is stored after the node has "executed". One thing of note that's new: because instructions can now take locals as operands, this means we got rid of the GetLocal instruction. A side-effect of that is we have to think about the temporal deadzone (TDZ) a bit differently for locals (GetLocal would previously check for empty values and interpret that as a TDZ access and throw). We now insert special ThrowIfTDZ instructions in places where a local access may be in the TDZ, to maintain the correct behavior. There are a number of progressions and regressions from this test: A number of async generator tests have been accidentally fixed while converting the implementation to the new bytecode format. It didn't seem useful to preserve bugs in the original code when converting it. Some "does eval() return the correct completion value" tests have regressed, in particular ones related to propagating the appropriate completion after control flow statements like continue and break. These are all fairly obscure issues, and I believe we can continue working on them separately. The net test262 result is a progression though. :^)
2024-02-04 08:00:54 +01:00
ThrowCompletionOr<void> JumpIf::execute_impl(Bytecode::Interpreter&) const
{
// Handled in the interpreter loop.
__builtin_unreachable();
}
LibJS/Bytecode: Turn JumpIf condition,@a,@next into JumpTrue/JumpFalse If one of the jump targets is the very next block, we can convert the jump instruction into a smaller JumpTrue or JumpFalse.
2024-05-06 10:15:17 +02:00
ThrowCompletionOr<void> JumpTrue::execute_impl(Bytecode::Interpreter&) const
{
// Handled in the interpreter loop.
__builtin_unreachable();
}
ThrowCompletionOr<void> JumpFalse::execute_impl(Bytecode::Interpreter&) const
{
// Handled in the interpreter loop.
__builtin_unreachable();
}
LibJS/Bytecode: Move to a new bytecode format This patch moves us away from the accumulator-based bytecode format to one with explicit source and destination registers. The new format has multiple benefits: - ~25% faster on the Kraken and Octane benchmarks :^) - Fewer instructions to accomplish the same thing - Much easier for humans to read(!) Because this change requires a fundamental shift in how bytecode is generated, it is quite comprehensive. Main implementation mechanism: generate_bytecode() virtual function now takes an optional "preferred dst" operand, which allows callers to communicate when they have an operand that would be optimal for the result to go into. It also returns an optional "actual dst" operand, which is where the completion value (if any) of the AST node is stored after the node has "executed". One thing of note that's new: because instructions can now take locals as operands, this means we got rid of the GetLocal instruction. A side-effect of that is we have to think about the temporal deadzone (TDZ) a bit differently for locals (GetLocal would previously check for empty values and interpret that as a TDZ access and throw). We now insert special ThrowIfTDZ instructions in places where a local access may be in the TDZ, to maintain the correct behavior. There are a number of progressions and regressions from this test: A number of async generator tests have been accidentally fixed while converting the implementation to the new bytecode format. It didn't seem useful to preserve bugs in the original code when converting it. Some "does eval() return the correct completion value" tests have regressed, in particular ones related to propagating the appropriate completion after control flow statements like continue and break. These are all fairly obscure issues, and I believe we can continue working on them separately. The net test262 result is a progression though. :^)
2024-02-04 08:00:54 +01:00
ThrowCompletionOr<void> JumpUndefined::execute_impl(Bytecode::Interpreter&) const
LibJS: Move all bytecode instruction implementations to Interpreter.cpp This allows aggressive inlining without LTO.
2023-09-27 10:10:00 +02:00
{
// Handled in the interpreter loop.
LibJS: Put __builtin_unreachable() in unused bytecode opcode handlers For the opcodes that are handled directly in the interpreter loop, we want the compiler to know that there's nothing to inline here.
2023-09-27 11:31:23 +02:00
__builtin_unreachable();
LibJS: Move all bytecode instruction implementations to Interpreter.cpp This allows aggressive inlining without LTO.
2023-09-27 10:10:00 +02:00
}
ThrowCompletionOr<void> JumpNullish::execute_impl(Bytecode::Interpreter&) const
{
// Handled in the interpreter loop.
LibJS: Put __builtin_unreachable() in unused bytecode opcode handlers For the opcodes that are handled directly in the interpreter loop, we want the compiler to know that there's nothing to inline here.
2023-09-27 11:31:23 +02:00
__builtin_unreachable();
LibJS: Move all bytecode instruction implementations to Interpreter.cpp This allows aggressive inlining without LTO.
2023-09-27 10:10:00 +02:00
}
LibJS/Bytecode: Move to a new bytecode format This patch moves us away from the accumulator-based bytecode format to one with explicit source and destination registers. The new format has multiple benefits: - ~25% faster on the Kraken and Octane benchmarks :^) - Fewer instructions to accomplish the same thing - Much easier for humans to read(!) Because this change requires a fundamental shift in how bytecode is generated, it is quite comprehensive. Main implementation mechanism: generate_bytecode() virtual function now takes an optional "preferred dst" operand, which allows callers to communicate when they have an operand that would be optimal for the result to go into. It also returns an optional "actual dst" operand, which is where the completion value (if any) of the AST node is stored after the node has "executed". One thing of note that's new: because instructions can now take locals as operands, this means we got rid of the GetLocal instruction. A side-effect of that is we have to think about the temporal deadzone (TDZ) a bit differently for locals (GetLocal would previously check for empty values and interpret that as a TDZ access and throw). We now insert special ThrowIfTDZ instructions in places where a local access may be in the TDZ, to maintain the correct behavior. There are a number of progressions and regressions from this test: A number of async generator tests have been accidentally fixed while converting the implementation to the new bytecode format. It didn't seem useful to preserve bugs in the original code when converting it. Some "does eval() return the correct completion value" tests have regressed, in particular ones related to propagating the appropriate completion after control flow statements like continue and break. These are all fairly obscure issues, and I believe we can continue working on them separately. The net test262 result is a progression though. :^)
2024-02-04 08:00:54 +01:00
ThrowCompletionOr<void> Mov::execute_impl(Bytecode::Interpreter&) const
LibJS: Move all bytecode instruction implementations to Interpreter.cpp This allows aggressive inlining without LTO.
2023-09-27 10:10:00 +02:00
{
// Handled in the interpreter loop.
LibJS: Put __builtin_unreachable() in unused bytecode opcode handlers For the opcodes that are handled directly in the interpreter loop, we want the compiler to know that there's nothing to inline here.
2023-09-27 11:31:23 +02:00
__builtin_unreachable();
LibJS: Move all bytecode instruction implementations to Interpreter.cpp This allows aggressive inlining without LTO.
2023-09-27 10:10:00 +02:00
}
LibJS/Bytecode: Put arguments directly in the Call instruction Instead of having Call refer to a range of VM registers, it now has a trailing list of argument operands as part of the instruction. This means we no longer have to shuffle every argument value into a register before making a call, making bytecode smaller & faster. :^)
2024-02-20 15:59:45 +01:00
static ThrowCompletionOr<Value> dispatch_builtin_call(Bytecode::Interpreter& interpreter, Bytecode::Builtin builtin, ReadonlySpan<Operand> arguments)
LibJS: Call builtins directly in the bytecode interpreter Allows the bytecode interpreter to call the builtins c++ implementation directly without making a javascript call just as the JIT. Kraken test speedups: imaging-gaussian-blur.js (1.5x) and audio-oscillator.js (1.2x)
2023-11-30 19:49:29 +01:00
{
switch (builtin) {
case Builtin::MathAbs:
LibJS/Bytecode: Put arguments directly in the Call instruction Instead of having Call refer to a range of VM registers, it now has a trailing list of argument operands as part of the instruction. This means we no longer have to shuffle every argument value into a register before making a call, making bytecode smaller & faster. :^)
2024-02-20 15:59:45 +01:00
return TRY(MathObject::abs_impl(interpreter.vm(), interpreter.get(arguments[0])));
LibJS: Call builtins directly in the bytecode interpreter Allows the bytecode interpreter to call the builtins c++ implementation directly without making a javascript call just as the JIT. Kraken test speedups: imaging-gaussian-blur.js (1.5x) and audio-oscillator.js (1.2x)
2023-11-30 19:49:29 +01:00
case Builtin::MathLog:
LibJS/Bytecode: Put arguments directly in the Call instruction Instead of having Call refer to a range of VM registers, it now has a trailing list of argument operands as part of the instruction. This means we no longer have to shuffle every argument value into a register before making a call, making bytecode smaller & faster. :^)
2024-02-20 15:59:45 +01:00
return TRY(MathObject::log_impl(interpreter.vm(), interpreter.get(arguments[0])));
case Builtin::MathPow:
return TRY(MathObject::pow_impl(interpreter.vm(), interpreter.get(arguments[0]), interpreter.get(arguments[1])));
LibJS: Call builtins directly in the bytecode interpreter Allows the bytecode interpreter to call the builtins c++ implementation directly without making a javascript call just as the JIT. Kraken test speedups: imaging-gaussian-blur.js (1.5x) and audio-oscillator.js (1.2x)
2023-11-30 19:49:29 +01:00
case Builtin::MathExp:
LibJS/Bytecode: Put arguments directly in the Call instruction Instead of having Call refer to a range of VM registers, it now has a trailing list of argument operands as part of the instruction. This means we no longer have to shuffle every argument value into a register before making a call, making bytecode smaller & faster. :^)
2024-02-20 15:59:45 +01:00
return TRY(MathObject::exp_impl(interpreter.vm(), interpreter.get(arguments[0])));
LibJS: Call builtins directly in the bytecode interpreter Allows the bytecode interpreter to call the builtins c++ implementation directly without making a javascript call just as the JIT. Kraken test speedups: imaging-gaussian-blur.js (1.5x) and audio-oscillator.js (1.2x)
2023-11-30 19:49:29 +01:00
case Builtin::MathCeil:
LibJS/Bytecode: Put arguments directly in the Call instruction Instead of having Call refer to a range of VM registers, it now has a trailing list of argument operands as part of the instruction. This means we no longer have to shuffle every argument value into a register before making a call, making bytecode smaller & faster. :^)
2024-02-20 15:59:45 +01:00
return TRY(MathObject::ceil_impl(interpreter.vm(), interpreter.get(arguments[0])));
LibJS: Call builtins directly in the bytecode interpreter Allows the bytecode interpreter to call the builtins c++ implementation directly without making a javascript call just as the JIT. Kraken test speedups: imaging-gaussian-blur.js (1.5x) and audio-oscillator.js (1.2x)
2023-11-30 19:49:29 +01:00
case Builtin::MathFloor:
LibJS/Bytecode: Put arguments directly in the Call instruction Instead of having Call refer to a range of VM registers, it now has a trailing list of argument operands as part of the instruction. This means we no longer have to shuffle every argument value into a register before making a call, making bytecode smaller & faster. :^)
2024-02-20 15:59:45 +01:00
return TRY(MathObject::floor_impl(interpreter.vm(), interpreter.get(arguments[0])));
LibJS: Call builtins directly in the bytecode interpreter Allows the bytecode interpreter to call the builtins c++ implementation directly without making a javascript call just as the JIT. Kraken test speedups: imaging-gaussian-blur.js (1.5x) and audio-oscillator.js (1.2x)
2023-11-30 19:49:29 +01:00
case Builtin::MathRound:
LibJS/Bytecode: Put arguments directly in the Call instruction Instead of having Call refer to a range of VM registers, it now has a trailing list of argument operands as part of the instruction. This means we no longer have to shuffle every argument value into a register before making a call, making bytecode smaller & faster. :^)
2024-02-20 15:59:45 +01:00
return TRY(MathObject::round_impl(interpreter.vm(), interpreter.get(arguments[0])));
LibJS: Call builtins directly in the bytecode interpreter Allows the bytecode interpreter to call the builtins c++ implementation directly without making a javascript call just as the JIT. Kraken test speedups: imaging-gaussian-blur.js (1.5x) and audio-oscillator.js (1.2x)
2023-11-30 19:49:29 +01:00
case Builtin::MathSqrt:
LibJS/Bytecode: Put arguments directly in the Call instruction Instead of having Call refer to a range of VM registers, it now has a trailing list of argument operands as part of the instruction. This means we no longer have to shuffle every argument value into a register before making a call, making bytecode smaller & faster. :^)
2024-02-20 15:59:45 +01:00
return TRY(MathObject::sqrt_impl(interpreter.vm(), interpreter.get(arguments[0])));
LibJS: Call builtins directly in the bytecode interpreter Allows the bytecode interpreter to call the builtins c++ implementation directly without making a javascript call just as the JIT. Kraken test speedups: imaging-gaussian-blur.js (1.5x) and audio-oscillator.js (1.2x)
2023-11-30 19:49:29 +01:00
case Bytecode::Builtin::__Count:
VERIFY_NOT_REACHED();
}
VERIFY_NOT_REACHED();
}
LibJS: Move all bytecode instruction implementations to Interpreter.cpp This allows aggressive inlining without LTO.
2023-09-27 10:10:00 +02:00
ThrowCompletionOr<void> Call::execute_impl(Bytecode::Interpreter& interpreter) const
{
LibJS/Bytecode: Move to a new bytecode format This patch moves us away from the accumulator-based bytecode format to one with explicit source and destination registers. The new format has multiple benefits: - ~25% faster on the Kraken and Octane benchmarks :^) - Fewer instructions to accomplish the same thing - Much easier for humans to read(!) Because this change requires a fundamental shift in how bytecode is generated, it is quite comprehensive. Main implementation mechanism: generate_bytecode() virtual function now takes an optional "preferred dst" operand, which allows callers to communicate when they have an operand that would be optimal for the result to go into. It also returns an optional "actual dst" operand, which is where the completion value (if any) of the AST node is stored after the node has "executed". One thing of note that's new: because instructions can now take locals as operands, this means we got rid of the GetLocal instruction. A side-effect of that is we have to think about the temporal deadzone (TDZ) a bit differently for locals (GetLocal would previously check for empty values and interpret that as a TDZ access and throw). We now insert special ThrowIfTDZ instructions in places where a local access may be in the TDZ, to maintain the correct behavior. There are a number of progressions and regressions from this test: A number of async generator tests have been accidentally fixed while converting the implementation to the new bytecode format. It didn't seem useful to preserve bugs in the original code when converting it. Some "does eval() return the correct completion value" tests have regressed, in particular ones related to propagating the appropriate completion after control flow statements like continue and break. These are all fairly obscure issues, and I believe we can continue working on them separately. The net test262 result is a progression though. :^)
2024-02-04 08:00:54 +01:00
auto callee = interpreter.get(m_callee);
LibJS: Move all bytecode instruction implementations to Interpreter.cpp This allows aggressive inlining without LTO.
2023-09-27 10:10:00 +02:00
LibJS/Bytecode: Un-templatize throw_if_needed_for_call()
2023-10-26 15:13:08 +02:00
TRY(throw_if_needed_for_call(interpreter, callee, call_type(), expression_string()));
LibJS: Move all bytecode instruction implementations to Interpreter.cpp This allows aggressive inlining without LTO.
2023-09-27 10:10:00 +02:00
LibJS/Bytecode: Avoid Value==Value in Call built-in fast path Comparing two Values has to call the generic same_value() helper, and we can avoid this by simply using a stronger type for built-in native function handlers.
2024-02-20 21:29:58 +01:00
if (m_builtin.has_value()
&& m_argument_count == Bytecode::builtin_argument_count(m_builtin.value())
&& callee.is_object()
&& interpreter.realm().get_builtin_value(m_builtin.value()) == &callee.as_object()) {
LibJS/Bytecode: Put arguments directly in the Call instruction Instead of having Call refer to a range of VM registers, it now has a trailing list of argument operands as part of the instruction. This means we no longer have to shuffle every argument value into a register before making a call, making bytecode smaller & faster. :^)
2024-02-20 15:59:45 +01:00
interpreter.set(dst(), TRY(dispatch_builtin_call(interpreter, m_builtin.value(), { m_arguments, m_argument_count })));
LibJS: Call builtins directly in the bytecode interpreter Allows the bytecode interpreter to call the builtins c++ implementation directly without making a javascript call just as the JIT. Kraken test speedups: imaging-gaussian-blur.js (1.5x) and audio-oscillator.js (1.2x)
2023-11-30 19:49:29 +01:00
return {};
}
LibJS/Bytecode: Put arguments directly in the Call instruction Instead of having Call refer to a range of VM registers, it now has a trailing list of argument operands as part of the instruction. This means we no longer have to shuffle every argument value into a register before making a call, making bytecode smaller & faster. :^)
2024-02-20 15:59:45 +01:00
Vector<Value> argument_values;
argument_values.ensure_capacity(m_argument_count);
for (size_t i = 0; i < m_argument_count; ++i)
argument_values.unchecked_append(interpreter.get(m_arguments[i]));
interpreter.set(dst(), TRY(perform_call(interpreter, interpreter.get(m_this_value), call_type(), callee, argument_values)));
LibJS/Bytecode: Move perform_call helper to CommonImplementations
2023-10-20 13:20:28 +02:00
return {};
LibJS: Move all bytecode instruction implementations to Interpreter.cpp This allows aggressive inlining without LTO.
2023-09-27 10:10:00 +02:00
}
ThrowCompletionOr<void> CallWithArgumentArray::execute_impl(Bytecode::Interpreter& interpreter) const
{
LibJS/Bytecode: Move to a new bytecode format This patch moves us away from the accumulator-based bytecode format to one with explicit source and destination registers. The new format has multiple benefits: - ~25% faster on the Kraken and Octane benchmarks :^) - Fewer instructions to accomplish the same thing - Much easier for humans to read(!) Because this change requires a fundamental shift in how bytecode is generated, it is quite comprehensive. Main implementation mechanism: generate_bytecode() virtual function now takes an optional "preferred dst" operand, which allows callers to communicate when they have an operand that would be optimal for the result to go into. It also returns an optional "actual dst" operand, which is where the completion value (if any) of the AST node is stored after the node has "executed". One thing of note that's new: because instructions can now take locals as operands, this means we got rid of the GetLocal instruction. A side-effect of that is we have to think about the temporal deadzone (TDZ) a bit differently for locals (GetLocal would previously check for empty values and interpret that as a TDZ access and throw). We now insert special ThrowIfTDZ instructions in places where a local access may be in the TDZ, to maintain the correct behavior. There are a number of progressions and regressions from this test: A number of async generator tests have been accidentally fixed while converting the implementation to the new bytecode format. It didn't seem useful to preserve bugs in the original code when converting it. Some "does eval() return the correct completion value" tests have regressed, in particular ones related to propagating the appropriate completion after control flow statements like continue and break. These are all fairly obscure issues, and I believe we can continue working on them separately. The net test262 result is a progression though. :^)
2024-02-04 08:00:54 +01:00
auto callee = interpreter.get(m_callee);
LibJS/Bytecode: Un-templatize throw_if_needed_for_call()
2023-10-26 15:13:08 +02:00
TRY(throw_if_needed_for_call(interpreter, callee, call_type(), expression_string()));
LibJS/Bytecode: Move to a new bytecode format This patch moves us away from the accumulator-based bytecode format to one with explicit source and destination registers. The new format has multiple benefits: - ~25% faster on the Kraken and Octane benchmarks :^) - Fewer instructions to accomplish the same thing - Much easier for humans to read(!) Because this change requires a fundamental shift in how bytecode is generated, it is quite comprehensive. Main implementation mechanism: generate_bytecode() virtual function now takes an optional "preferred dst" operand, which allows callers to communicate when they have an operand that would be optimal for the result to go into. It also returns an optional "actual dst" operand, which is where the completion value (if any) of the AST node is stored after the node has "executed". One thing of note that's new: because instructions can now take locals as operands, this means we got rid of the GetLocal instruction. A side-effect of that is we have to think about the temporal deadzone (TDZ) a bit differently for locals (GetLocal would previously check for empty values and interpret that as a TDZ access and throw). We now insert special ThrowIfTDZ instructions in places where a local access may be in the TDZ, to maintain the correct behavior. There are a number of progressions and regressions from this test: A number of async generator tests have been accidentally fixed while converting the implementation to the new bytecode format. It didn't seem useful to preserve bugs in the original code when converting it. Some "does eval() return the correct completion value" tests have regressed, in particular ones related to propagating the appropriate completion after control flow statements like continue and break. These are all fairly obscure issues, and I believe we can continue working on them separately. The net test262 result is a progression though. :^)
2024-02-04 08:00:54 +01:00
auto argument_values = argument_list_evaluation(interpreter.vm(), interpreter.get(arguments()));
interpreter.set(dst(), TRY(perform_call(interpreter, interpreter.get(m_this_value), call_type(), callee, move(argument_values))));
LibJS/Bytecode: Move perform_call helper to CommonImplementations
2023-10-20 13:20:28 +02:00
return {};
LibJS: Move all bytecode instruction implementations to Interpreter.cpp This allows aggressive inlining without LTO.
2023-09-27 10:10:00 +02:00
}
// 13.3.7.1 Runtime Semantics: Evaluation, https://tc39.es/ecma262/#sec-super-keyword-runtime-semantics-evaluation
ThrowCompletionOr<void> SuperCallWithArgumentArray::execute_impl(Bytecode::Interpreter& interpreter) const
{
LibJS/Bytecode: Move to a new bytecode format This patch moves us away from the accumulator-based bytecode format to one with explicit source and destination registers. The new format has multiple benefits: - ~25% faster on the Kraken and Octane benchmarks :^) - Fewer instructions to accomplish the same thing - Much easier for humans to read(!) Because this change requires a fundamental shift in how bytecode is generated, it is quite comprehensive. Main implementation mechanism: generate_bytecode() virtual function now takes an optional "preferred dst" operand, which allows callers to communicate when they have an operand that would be optimal for the result to go into. It also returns an optional "actual dst" operand, which is where the completion value (if any) of the AST node is stored after the node has "executed". One thing of note that's new: because instructions can now take locals as operands, this means we got rid of the GetLocal instruction. A side-effect of that is we have to think about the temporal deadzone (TDZ) a bit differently for locals (GetLocal would previously check for empty values and interpret that as a TDZ access and throw). We now insert special ThrowIfTDZ instructions in places where a local access may be in the TDZ, to maintain the correct behavior. There are a number of progressions and regressions from this test: A number of async generator tests have been accidentally fixed while converting the implementation to the new bytecode format. It didn't seem useful to preserve bugs in the original code when converting it. Some "does eval() return the correct completion value" tests have regressed, in particular ones related to propagating the appropriate completion after control flow statements like continue and break. These are all fairly obscure issues, and I believe we can continue working on them separately. The net test262 result is a progression though. :^)
2024-02-04 08:00:54 +01:00
interpreter.set(dst(), TRY(super_call_with_argument_array(interpreter.vm(), interpreter.get(arguments()), m_is_synthetic)));
LibJS: Move all bytecode instruction implementations to Interpreter.cpp This allows aggressive inlining without LTO.
2023-09-27 10:10:00 +02:00
return {};
}
ThrowCompletionOr<void> NewFunction::execute_impl(Bytecode::Interpreter& interpreter) const
{
auto& vm = interpreter.vm();
LibJS/Bytecode: Move to a new bytecode format This patch moves us away from the accumulator-based bytecode format to one with explicit source and destination registers. The new format has multiple benefits: - ~25% faster on the Kraken and Octane benchmarks :^) - Fewer instructions to accomplish the same thing - Much easier for humans to read(!) Because this change requires a fundamental shift in how bytecode is generated, it is quite comprehensive. Main implementation mechanism: generate_bytecode() virtual function now takes an optional "preferred dst" operand, which allows callers to communicate when they have an operand that would be optimal for the result to go into. It also returns an optional "actual dst" operand, which is where the completion value (if any) of the AST node is stored after the node has "executed". One thing of note that's new: because instructions can now take locals as operands, this means we got rid of the GetLocal instruction. A side-effect of that is we have to think about the temporal deadzone (TDZ) a bit differently for locals (GetLocal would previously check for empty values and interpret that as a TDZ access and throw). We now insert special ThrowIfTDZ instructions in places where a local access may be in the TDZ, to maintain the correct behavior. There are a number of progressions and regressions from this test: A number of async generator tests have been accidentally fixed while converting the implementation to the new bytecode format. It didn't seem useful to preserve bugs in the original code when converting it. Some "does eval() return the correct completion value" tests have regressed, in particular ones related to propagating the appropriate completion after control flow statements like continue and break. These are all fairly obscure issues, and I believe we can continue working on them separately. The net test262 result is a progression though. :^)
2024-02-04 08:00:54 +01:00
interpreter.set(dst(), new_function(vm, m_function_node, m_lhs_name, m_home_object));
LibJS: Move all bytecode instruction implementations to Interpreter.cpp This allows aggressive inlining without LTO.
2023-09-27 10:10:00 +02:00
return {};
}
ThrowCompletionOr<void> Return::execute_impl(Bytecode::Interpreter& interpreter) const
{
LibJS/Bytecode: Move to a new bytecode format This patch moves us away from the accumulator-based bytecode format to one with explicit source and destination registers. The new format has multiple benefits: - ~25% faster on the Kraken and Octane benchmarks :^) - Fewer instructions to accomplish the same thing - Much easier for humans to read(!) Because this change requires a fundamental shift in how bytecode is generated, it is quite comprehensive. Main implementation mechanism: generate_bytecode() virtual function now takes an optional "preferred dst" operand, which allows callers to communicate when they have an operand that would be optimal for the result to go into. It also returns an optional "actual dst" operand, which is where the completion value (if any) of the AST node is stored after the node has "executed". One thing of note that's new: because instructions can now take locals as operands, this means we got rid of the GetLocal instruction. A side-effect of that is we have to think about the temporal deadzone (TDZ) a bit differently for locals (GetLocal would previously check for empty values and interpret that as a TDZ access and throw). We now insert special ThrowIfTDZ instructions in places where a local access may be in the TDZ, to maintain the correct behavior. There are a number of progressions and regressions from this test: A number of async generator tests have been accidentally fixed while converting the implementation to the new bytecode format. It didn't seem useful to preserve bugs in the original code when converting it. Some "does eval() return the correct completion value" tests have regressed, in particular ones related to propagating the appropriate completion after control flow statements like continue and break. These are all fairly obscure issues, and I believe we can continue working on them separately. The net test262 result is a progression though. :^)
2024-02-04 08:00:54 +01:00
if (m_value.has_value())
interpreter.do_return(interpreter.get(*m_value));
else
interpreter.do_return(js_undefined());
LibJS: Move all bytecode instruction implementations to Interpreter.cpp This allows aggressive inlining without LTO.
2023-09-27 10:10:00 +02:00
return {};
}
ThrowCompletionOr<void> Increment::execute_impl(Bytecode::Interpreter& interpreter) const
{
auto& vm = interpreter.vm();
LibJS/Bytecode: Move to a new bytecode format This patch moves us away from the accumulator-based bytecode format to one with explicit source and destination registers. The new format has multiple benefits: - ~25% faster on the Kraken and Octane benchmarks :^) - Fewer instructions to accomplish the same thing - Much easier for humans to read(!) Because this change requires a fundamental shift in how bytecode is generated, it is quite comprehensive. Main implementation mechanism: generate_bytecode() virtual function now takes an optional "preferred dst" operand, which allows callers to communicate when they have an operand that would be optimal for the result to go into. It also returns an optional "actual dst" operand, which is where the completion value (if any) of the AST node is stored after the node has "executed". One thing of note that's new: because instructions can now take locals as operands, this means we got rid of the GetLocal instruction. A side-effect of that is we have to think about the temporal deadzone (TDZ) a bit differently for locals (GetLocal would previously check for empty values and interpret that as a TDZ access and throw). We now insert special ThrowIfTDZ instructions in places where a local access may be in the TDZ, to maintain the correct behavior. There are a number of progressions and regressions from this test: A number of async generator tests have been accidentally fixed while converting the implementation to the new bytecode format. It didn't seem useful to preserve bugs in the original code when converting it. Some "does eval() return the correct completion value" tests have regressed, in particular ones related to propagating the appropriate completion after control flow statements like continue and break. These are all fairly obscure issues, and I believe we can continue working on them separately. The net test262 result is a progression though. :^)
2024-02-04 08:00:54 +01:00
auto old_value = interpreter.get(dst());
LibJS: Fast path for Increment of Int32 value in bytecode interpreter 5% speed-up on Kraken/ai-astar.js in interpreter mode. :^)
2024-01-27 20:51:11 +01:00
// OPTIMIZATION: Fast path for Int32 values.
if (old_value.is_int32()) {
auto integer_value = old_value.as_i32();
if (integer_value != NumericLimits<i32>::max()) [[likely]] {
LibJS/Bytecode: Move to a new bytecode format This patch moves us away from the accumulator-based bytecode format to one with explicit source and destination registers. The new format has multiple benefits: - ~25% faster on the Kraken and Octane benchmarks :^) - Fewer instructions to accomplish the same thing - Much easier for humans to read(!) Because this change requires a fundamental shift in how bytecode is generated, it is quite comprehensive. Main implementation mechanism: generate_bytecode() virtual function now takes an optional "preferred dst" operand, which allows callers to communicate when they have an operand that would be optimal for the result to go into. It also returns an optional "actual dst" operand, which is where the completion value (if any) of the AST node is stored after the node has "executed". One thing of note that's new: because instructions can now take locals as operands, this means we got rid of the GetLocal instruction. A side-effect of that is we have to think about the temporal deadzone (TDZ) a bit differently for locals (GetLocal would previously check for empty values and interpret that as a TDZ access and throw). We now insert special ThrowIfTDZ instructions in places where a local access may be in the TDZ, to maintain the correct behavior. There are a number of progressions and regressions from this test: A number of async generator tests have been accidentally fixed while converting the implementation to the new bytecode format. It didn't seem useful to preserve bugs in the original code when converting it. Some "does eval() return the correct completion value" tests have regressed, in particular ones related to propagating the appropriate completion after control flow statements like continue and break. These are all fairly obscure issues, and I believe we can continue working on them separately. The net test262 result is a progression though. :^)
2024-02-04 08:00:54 +01:00
interpreter.set(dst(), Value { integer_value + 1 });
LibJS: Fast path for Increment of Int32 value in bytecode interpreter 5% speed-up on Kraken/ai-astar.js in interpreter mode. :^)
2024-01-27 20:51:11 +01:00
return {};
}
}
old_value = TRY(old_value.to_numeric(vm));
LibJS: Move all bytecode instruction implementations to Interpreter.cpp This allows aggressive inlining without LTO.
2023-09-27 10:10:00 +02:00
if (old_value.is_number())
LibJS/Bytecode: Move to a new bytecode format This patch moves us away from the accumulator-based bytecode format to one with explicit source and destination registers. The new format has multiple benefits: - ~25% faster on the Kraken and Octane benchmarks :^) - Fewer instructions to accomplish the same thing - Much easier for humans to read(!) Because this change requires a fundamental shift in how bytecode is generated, it is quite comprehensive. Main implementation mechanism: generate_bytecode() virtual function now takes an optional "preferred dst" operand, which allows callers to communicate when they have an operand that would be optimal for the result to go into. It also returns an optional "actual dst" operand, which is where the completion value (if any) of the AST node is stored after the node has "executed". One thing of note that's new: because instructions can now take locals as operands, this means we got rid of the GetLocal instruction. A side-effect of that is we have to think about the temporal deadzone (TDZ) a bit differently for locals (GetLocal would previously check for empty values and interpret that as a TDZ access and throw). We now insert special ThrowIfTDZ instructions in places where a local access may be in the TDZ, to maintain the correct behavior. There are a number of progressions and regressions from this test: A number of async generator tests have been accidentally fixed while converting the implementation to the new bytecode format. It didn't seem useful to preserve bugs in the original code when converting it. Some "does eval() return the correct completion value" tests have regressed, in particular ones related to propagating the appropriate completion after control flow statements like continue and break. These are all fairly obscure issues, and I believe we can continue working on them separately. The net test262 result is a progression though. :^)
2024-02-04 08:00:54 +01:00
interpreter.set(dst(), Value(old_value.as_double() + 1));
LibJS: Move all bytecode instruction implementations to Interpreter.cpp This allows aggressive inlining without LTO.
2023-09-27 10:10:00 +02:00
else
LibJS/Bytecode: Move to a new bytecode format This patch moves us away from the accumulator-based bytecode format to one with explicit source and destination registers. The new format has multiple benefits: - ~25% faster on the Kraken and Octane benchmarks :^) - Fewer instructions to accomplish the same thing - Much easier for humans to read(!) Because this change requires a fundamental shift in how bytecode is generated, it is quite comprehensive. Main implementation mechanism: generate_bytecode() virtual function now takes an optional "preferred dst" operand, which allows callers to communicate when they have an operand that would be optimal for the result to go into. It also returns an optional "actual dst" operand, which is where the completion value (if any) of the AST node is stored after the node has "executed". One thing of note that's new: because instructions can now take locals as operands, this means we got rid of the GetLocal instruction. A side-effect of that is we have to think about the temporal deadzone (TDZ) a bit differently for locals (GetLocal would previously check for empty values and interpret that as a TDZ access and throw). We now insert special ThrowIfTDZ instructions in places where a local access may be in the TDZ, to maintain the correct behavior. There are a number of progressions and regressions from this test: A number of async generator tests have been accidentally fixed while converting the implementation to the new bytecode format. It didn't seem useful to preserve bugs in the original code when converting it. Some "does eval() return the correct completion value" tests have regressed, in particular ones related to propagating the appropriate completion after control flow statements like continue and break. These are all fairly obscure issues, and I believe we can continue working on them separately. The net test262 result is a progression though. :^)
2024-02-04 08:00:54 +01:00
interpreter.set(dst(), BigInt::create(vm, old_value.as_bigint().big_integer().plus(Crypto::SignedBigInteger { 1 })));
LibJS: Move all bytecode instruction implementations to Interpreter.cpp This allows aggressive inlining without LTO.
2023-09-27 10:10:00 +02:00
return {};
}
LibJS/Bytecode: Dedicated instructions for postfix increment/decrement Instead of splitting the postfix variants into ToNumeric + Inc/Dec, we now have dedicated PostfixIncrement and PostfixDecrement instructions that handle both outputs in one go.
2024-02-20 11:45:01 +01:00
ThrowCompletionOr<void> PostfixIncrement::execute_impl(Bytecode::Interpreter& interpreter) const
{
auto& vm = interpreter.vm();
auto old_value = interpreter.get(m_src);
// OPTIMIZATION: Fast path for Int32 values.
if (old_value.is_int32()) {
auto integer_value = old_value.as_i32();
if (integer_value != NumericLimits<i32>::max()) [[likely]] {
interpreter.set(m_dst, old_value);
interpreter.set(m_src, Value { integer_value + 1 });
return {};
}
}
old_value = TRY(old_value.to_numeric(vm));
interpreter.set(m_dst, old_value);
if (old_value.is_number())
interpreter.set(m_src, Value(old_value.as_double() + 1));
else
interpreter.set(m_src, BigInt::create(vm, old_value.as_bigint().big_integer().plus(Crypto::SignedBigInteger { 1 })));
return {};
}
LibJS: Move all bytecode instruction implementations to Interpreter.cpp This allows aggressive inlining without LTO.
2023-09-27 10:10:00 +02:00
ThrowCompletionOr<void> Decrement::execute_impl(Bytecode::Interpreter& interpreter) const
{
auto& vm = interpreter.vm();
LibJS/Bytecode: Move to a new bytecode format This patch moves us away from the accumulator-based bytecode format to one with explicit source and destination registers. The new format has multiple benefits: - ~25% faster on the Kraken and Octane benchmarks :^) - Fewer instructions to accomplish the same thing - Much easier for humans to read(!) Because this change requires a fundamental shift in how bytecode is generated, it is quite comprehensive. Main implementation mechanism: generate_bytecode() virtual function now takes an optional "preferred dst" operand, which allows callers to communicate when they have an operand that would be optimal for the result to go into. It also returns an optional "actual dst" operand, which is where the completion value (if any) of the AST node is stored after the node has "executed". One thing of note that's new: because instructions can now take locals as operands, this means we got rid of the GetLocal instruction. A side-effect of that is we have to think about the temporal deadzone (TDZ) a bit differently for locals (GetLocal would previously check for empty values and interpret that as a TDZ access and throw). We now insert special ThrowIfTDZ instructions in places where a local access may be in the TDZ, to maintain the correct behavior. There are a number of progressions and regressions from this test: A number of async generator tests have been accidentally fixed while converting the implementation to the new bytecode format. It didn't seem useful to preserve bugs in the original code when converting it. Some "does eval() return the correct completion value" tests have regressed, in particular ones related to propagating the appropriate completion after control flow statements like continue and break. These are all fairly obscure issues, and I believe we can continue working on them separately. The net test262 result is a progression though. :^)
2024-02-04 08:00:54 +01:00
auto old_value = interpreter.get(dst());
old_value = TRY(old_value.to_numeric(vm));
LibJS: Move all bytecode instruction implementations to Interpreter.cpp This allows aggressive inlining without LTO.
2023-09-27 10:10:00 +02:00
if (old_value.is_number())
LibJS/Bytecode: Move to a new bytecode format This patch moves us away from the accumulator-based bytecode format to one with explicit source and destination registers. The new format has multiple benefits: - ~25% faster on the Kraken and Octane benchmarks :^) - Fewer instructions to accomplish the same thing - Much easier for humans to read(!) Because this change requires a fundamental shift in how bytecode is generated, it is quite comprehensive. Main implementation mechanism: generate_bytecode() virtual function now takes an optional "preferred dst" operand, which allows callers to communicate when they have an operand that would be optimal for the result to go into. It also returns an optional "actual dst" operand, which is where the completion value (if any) of the AST node is stored after the node has "executed". One thing of note that's new: because instructions can now take locals as operands, this means we got rid of the GetLocal instruction. A side-effect of that is we have to think about the temporal deadzone (TDZ) a bit differently for locals (GetLocal would previously check for empty values and interpret that as a TDZ access and throw). We now insert special ThrowIfTDZ instructions in places where a local access may be in the TDZ, to maintain the correct behavior. There are a number of progressions and regressions from this test: A number of async generator tests have been accidentally fixed while converting the implementation to the new bytecode format. It didn't seem useful to preserve bugs in the original code when converting it. Some "does eval() return the correct completion value" tests have regressed, in particular ones related to propagating the appropriate completion after control flow statements like continue and break. These are all fairly obscure issues, and I believe we can continue working on them separately. The net test262 result is a progression though. :^)
2024-02-04 08:00:54 +01:00
interpreter.set(dst(), Value(old_value.as_double() - 1));
LibJS: Move all bytecode instruction implementations to Interpreter.cpp This allows aggressive inlining without LTO.
2023-09-27 10:10:00 +02:00
else
LibJS/Bytecode: Move to a new bytecode format This patch moves us away from the accumulator-based bytecode format to one with explicit source and destination registers. The new format has multiple benefits: - ~25% faster on the Kraken and Octane benchmarks :^) - Fewer instructions to accomplish the same thing - Much easier for humans to read(!) Because this change requires a fundamental shift in how bytecode is generated, it is quite comprehensive. Main implementation mechanism: generate_bytecode() virtual function now takes an optional "preferred dst" operand, which allows callers to communicate when they have an operand that would be optimal for the result to go into. It also returns an optional "actual dst" operand, which is where the completion value (if any) of the AST node is stored after the node has "executed". One thing of note that's new: because instructions can now take locals as operands, this means we got rid of the GetLocal instruction. A side-effect of that is we have to think about the temporal deadzone (TDZ) a bit differently for locals (GetLocal would previously check for empty values and interpret that as a TDZ access and throw). We now insert special ThrowIfTDZ instructions in places where a local access may be in the TDZ, to maintain the correct behavior. There are a number of progressions and regressions from this test: A number of async generator tests have been accidentally fixed while converting the implementation to the new bytecode format. It didn't seem useful to preserve bugs in the original code when converting it. Some "does eval() return the correct completion value" tests have regressed, in particular ones related to propagating the appropriate completion after control flow statements like continue and break. These are all fairly obscure issues, and I believe we can continue working on them separately. The net test262 result is a progression though. :^)
2024-02-04 08:00:54 +01:00
interpreter.set(dst(), BigInt::create(vm, old_value.as_bigint().big_integer().minus(Crypto::SignedBigInteger { 1 })));
LibJS: Move all bytecode instruction implementations to Interpreter.cpp This allows aggressive inlining without LTO.
2023-09-27 10:10:00 +02:00
return {};
}
LibJS/Bytecode: Dedicated instructions for postfix increment/decrement Instead of splitting the postfix variants into ToNumeric + Inc/Dec, we now have dedicated PostfixIncrement and PostfixDecrement instructions that handle both outputs in one go.
2024-02-20 11:45:01 +01:00
ThrowCompletionOr<void> PostfixDecrement::execute_impl(Bytecode::Interpreter& interpreter) const
{
auto& vm = interpreter.vm();
auto old_value = interpreter.get(m_src);
old_value = TRY(old_value.to_numeric(vm));
interpreter.set(m_dst, old_value);
if (old_value.is_number())
interpreter.set(m_src, Value(old_value.as_double() - 1));
else
interpreter.set(m_src, BigInt::create(vm, old_value.as_bigint().big_integer().minus(Crypto::SignedBigInteger { 1 })));
return {};
}
LibJS: Move all bytecode instruction implementations to Interpreter.cpp This allows aggressive inlining without LTO.
2023-09-27 10:10:00 +02:00
ThrowCompletionOr<void> Throw::execute_impl(Bytecode::Interpreter& interpreter) const
{
LibJS/Bytecode: Move to a new bytecode format This patch moves us away from the accumulator-based bytecode format to one with explicit source and destination registers. The new format has multiple benefits: - ~25% faster on the Kraken and Octane benchmarks :^) - Fewer instructions to accomplish the same thing - Much easier for humans to read(!) Because this change requires a fundamental shift in how bytecode is generated, it is quite comprehensive. Main implementation mechanism: generate_bytecode() virtual function now takes an optional "preferred dst" operand, which allows callers to communicate when they have an operand that would be optimal for the result to go into. It also returns an optional "actual dst" operand, which is where the completion value (if any) of the AST node is stored after the node has "executed". One thing of note that's new: because instructions can now take locals as operands, this means we got rid of the GetLocal instruction. A side-effect of that is we have to think about the temporal deadzone (TDZ) a bit differently for locals (GetLocal would previously check for empty values and interpret that as a TDZ access and throw). We now insert special ThrowIfTDZ instructions in places where a local access may be in the TDZ, to maintain the correct behavior. There are a number of progressions and regressions from this test: A number of async generator tests have been accidentally fixed while converting the implementation to the new bytecode format. It didn't seem useful to preserve bugs in the original code when converting it. Some "does eval() return the correct completion value" tests have regressed, in particular ones related to propagating the appropriate completion after control flow statements like continue and break. These are all fairly obscure issues, and I believe we can continue working on them separately. The net test262 result is a progression though. :^)
2024-02-04 08:00:54 +01:00
return throw_completion(interpreter.get(src()));
LibJS: Move all bytecode instruction implementations to Interpreter.cpp This allows aggressive inlining without LTO.
2023-09-27 10:10:00 +02:00
}
ThrowCompletionOr<void> ThrowIfNotObject::execute_impl(Bytecode::Interpreter& interpreter) const
{
auto& vm = interpreter.vm();
LibJS/Bytecode: Move to a new bytecode format This patch moves us away from the accumulator-based bytecode format to one with explicit source and destination registers. The new format has multiple benefits: - ~25% faster on the Kraken and Octane benchmarks :^) - Fewer instructions to accomplish the same thing - Much easier for humans to read(!) Because this change requires a fundamental shift in how bytecode is generated, it is quite comprehensive. Main implementation mechanism: generate_bytecode() virtual function now takes an optional "preferred dst" operand, which allows callers to communicate when they have an operand that would be optimal for the result to go into. It also returns an optional "actual dst" operand, which is where the completion value (if any) of the AST node is stored after the node has "executed". One thing of note that's new: because instructions can now take locals as operands, this means we got rid of the GetLocal instruction. A side-effect of that is we have to think about the temporal deadzone (TDZ) a bit differently for locals (GetLocal would previously check for empty values and interpret that as a TDZ access and throw). We now insert special ThrowIfTDZ instructions in places where a local access may be in the TDZ, to maintain the correct behavior. There are a number of progressions and regressions from this test: A number of async generator tests have been accidentally fixed while converting the implementation to the new bytecode format. It didn't seem useful to preserve bugs in the original code when converting it. Some "does eval() return the correct completion value" tests have regressed, in particular ones related to propagating the appropriate completion after control flow statements like continue and break. These are all fairly obscure issues, and I believe we can continue working on them separately. The net test262 result is a progression though. :^)
2024-02-04 08:00:54 +01:00
auto src = interpreter.get(m_src);
if (!src.is_object())
return vm.throw_completion<TypeError>(ErrorType::NotAnObject, src.to_string_without_side_effects());
LibJS: Move all bytecode instruction implementations to Interpreter.cpp This allows aggressive inlining without LTO.
2023-09-27 10:10:00 +02:00
return {};
}
ThrowCompletionOr<void> ThrowIfNullish::execute_impl(Bytecode::Interpreter& interpreter) const
{
auto& vm = interpreter.vm();
LibJS/Bytecode: Move to a new bytecode format This patch moves us away from the accumulator-based bytecode format to one with explicit source and destination registers. The new format has multiple benefits: - ~25% faster on the Kraken and Octane benchmarks :^) - Fewer instructions to accomplish the same thing - Much easier for humans to read(!) Because this change requires a fundamental shift in how bytecode is generated, it is quite comprehensive. Main implementation mechanism: generate_bytecode() virtual function now takes an optional "preferred dst" operand, which allows callers to communicate when they have an operand that would be optimal for the result to go into. It also returns an optional "actual dst" operand, which is where the completion value (if any) of the AST node is stored after the node has "executed". One thing of note that's new: because instructions can now take locals as operands, this means we got rid of the GetLocal instruction. A side-effect of that is we have to think about the temporal deadzone (TDZ) a bit differently for locals (GetLocal would previously check for empty values and interpret that as a TDZ access and throw). We now insert special ThrowIfTDZ instructions in places where a local access may be in the TDZ, to maintain the correct behavior. There are a number of progressions and regressions from this test: A number of async generator tests have been accidentally fixed while converting the implementation to the new bytecode format. It didn't seem useful to preserve bugs in the original code when converting it. Some "does eval() return the correct completion value" tests have regressed, in particular ones related to propagating the appropriate completion after control flow statements like continue and break. These are all fairly obscure issues, and I believe we can continue working on them separately. The net test262 result is a progression though. :^)
2024-02-04 08:00:54 +01:00
auto value = interpreter.get(m_src);
LibJS: Move all bytecode instruction implementations to Interpreter.cpp This allows aggressive inlining without LTO.
2023-09-27 10:10:00 +02:00
if (value.is_nullish())
return vm.throw_completion<TypeError>(ErrorType::NotObjectCoercible, value.to_string_without_side_effects());
return {};
}
LibJS/Bytecode: Move to a new bytecode format This patch moves us away from the accumulator-based bytecode format to one with explicit source and destination registers. The new format has multiple benefits: - ~25% faster on the Kraken and Octane benchmarks :^) - Fewer instructions to accomplish the same thing - Much easier for humans to read(!) Because this change requires a fundamental shift in how bytecode is generated, it is quite comprehensive. Main implementation mechanism: generate_bytecode() virtual function now takes an optional "preferred dst" operand, which allows callers to communicate when they have an operand that would be optimal for the result to go into. It also returns an optional "actual dst" operand, which is where the completion value (if any) of the AST node is stored after the node has "executed". One thing of note that's new: because instructions can now take locals as operands, this means we got rid of the GetLocal instruction. A side-effect of that is we have to think about the temporal deadzone (TDZ) a bit differently for locals (GetLocal would previously check for empty values and interpret that as a TDZ access and throw). We now insert special ThrowIfTDZ instructions in places where a local access may be in the TDZ, to maintain the correct behavior. There are a number of progressions and regressions from this test: A number of async generator tests have been accidentally fixed while converting the implementation to the new bytecode format. It didn't seem useful to preserve bugs in the original code when converting it. Some "does eval() return the correct completion value" tests have regressed, in particular ones related to propagating the appropriate completion after control flow statements like continue and break. These are all fairly obscure issues, and I believe we can continue working on them separately. The net test262 result is a progression though. :^)
2024-02-04 08:00:54 +01:00
ThrowCompletionOr<void> ThrowIfTDZ::execute_impl(Bytecode::Interpreter& interpreter) const
{
auto& vm = interpreter.vm();
auto value = interpreter.get(m_src);
if (value.is_empty())
return vm.throw_completion<ReferenceError>(ErrorType::BindingNotInitialized, value.to_string_without_side_effects());
return {};
}
LibJS: Move all bytecode instruction implementations to Interpreter.cpp This allows aggressive inlining without LTO.
2023-09-27 10:10:00 +02:00
ThrowCompletionOr<void> EnterUnwindContext::execute_impl(Bytecode::Interpreter&) const
{
// Handled in the interpreter loop.
LibJS: Put __builtin_unreachable() in unused bytecode opcode handlers For the opcodes that are handled directly in the interpreter loop, we want the compiler to know that there's nothing to inline here.
2023-09-27 11:31:23 +02:00
__builtin_unreachable();
LibJS: Move all bytecode instruction implementations to Interpreter.cpp This allows aggressive inlining without LTO.
2023-09-27 10:10:00 +02:00
}
ThrowCompletionOr<void> ScheduleJump::execute_impl(Bytecode::Interpreter&) const
{
// Handled in the interpreter loop.
LibJS: Put __builtin_unreachable() in unused bytecode opcode handlers For the opcodes that are handled directly in the interpreter loop, we want the compiler to know that there's nothing to inline here.
2023-09-27 11:31:23 +02:00
__builtin_unreachable();
LibJS: Move all bytecode instruction implementations to Interpreter.cpp This allows aggressive inlining without LTO.
2023-09-27 10:10:00 +02:00
}
ThrowCompletionOr<void> LeaveLexicalEnvironment::execute_impl(Bytecode::Interpreter& interpreter) const
{
LibJS: Merge CallFrame into ExecutionContext Before this change both ExecutionContext and CallFrame were created before executing function/module/script with a couple exceptions: - executable created for default function argument evaluation has to run in function's execution context. - `execute_ast_node()` where executable compiled for ASTNode has to be executed in running execution context. This change moves all members previously owned by CallFrame into ExecutionContext, and makes two exceptions where an executable that does not have a corresponding execution context saves and restores registers before running. Now, all execution state lives in a single entity, which makes it a bit easier to reason about and opens opportunities for optimizations, such as moving registers and local variables into a single array.
2024-05-01 19:33:49 +02:00
auto& running_execution_context = interpreter.vm().running_execution_context();
running_execution_context.lexical_environment = running_execution_context.saved_lexical_environments.take_last();
LibJS: Move all bytecode instruction implementations to Interpreter.cpp This allows aggressive inlining without LTO.
2023-09-27 10:10:00 +02:00
return {};
}
ThrowCompletionOr<void> LeaveUnwindContext::execute_impl(Bytecode::Interpreter& interpreter) const
{
interpreter.leave_unwind_context();
return {};
}
ThrowCompletionOr<void> ContinuePendingUnwind::execute_impl(Bytecode::Interpreter&) const
{
// Handled in the interpreter loop.
LibJS: Put __builtin_unreachable() in unused bytecode opcode handlers For the opcodes that are handled directly in the interpreter loop, we want the compiler to know that there's nothing to inline here.
2023-09-27 11:31:23 +02:00
__builtin_unreachable();
LibJS: Move all bytecode instruction implementations to Interpreter.cpp This allows aggressive inlining without LTO.
2023-09-27 10:10:00 +02:00
}
ThrowCompletionOr<void> Yield::execute_impl(Bytecode::Interpreter& interpreter) const
{
LibJS/Bytecode: Move to a new bytecode format This patch moves us away from the accumulator-based bytecode format to one with explicit source and destination registers. The new format has multiple benefits: - ~25% faster on the Kraken and Octane benchmarks :^) - Fewer instructions to accomplish the same thing - Much easier for humans to read(!) Because this change requires a fundamental shift in how bytecode is generated, it is quite comprehensive. Main implementation mechanism: generate_bytecode() virtual function now takes an optional "preferred dst" operand, which allows callers to communicate when they have an operand that would be optimal for the result to go into. It also returns an optional "actual dst" operand, which is where the completion value (if any) of the AST node is stored after the node has "executed". One thing of note that's new: because instructions can now take locals as operands, this means we got rid of the GetLocal instruction. A side-effect of that is we have to think about the temporal deadzone (TDZ) a bit differently for locals (GetLocal would previously check for empty values and interpret that as a TDZ access and throw). We now insert special ThrowIfTDZ instructions in places where a local access may be in the TDZ, to maintain the correct behavior. There are a number of progressions and regressions from this test: A number of async generator tests have been accidentally fixed while converting the implementation to the new bytecode format. It didn't seem useful to preserve bugs in the original code when converting it. Some "does eval() return the correct completion value" tests have regressed, in particular ones related to propagating the appropriate completion after control flow statements like continue and break. These are all fairly obscure issues, and I believe we can continue working on them separately. The net test262 result is a progression though. :^)
2024-02-04 08:00:54 +01:00
auto yielded_value = interpreter.get(m_value).value_or(js_undefined());
LibJS: Move all bytecode instruction implementations to Interpreter.cpp This allows aggressive inlining without LTO.
2023-09-27 10:10:00 +02:00
auto object = Object::create(interpreter.realm(), nullptr);
object->define_direct_property("result", yielded_value, JS::default_attributes);
if (m_continuation_label.has_value())
// FIXME: If we get a pointer, which is not accurately representable as a double
// will cause this to explode
LibJS/Bytecode: Flatten bytecode to a contiguous representation Instead of keeping bytecode as a set of disjoint basic blocks on the malloc heap, bytecode is now a contiguous sequence of bytes(!) The transformation happens at the end of Bytecode::Generator::generate() and the only really hairy part is rerouting jump labels. This required solving a few problems: - The interpreter execution loop had to change quite a bit, since we were storing BasicBlock pointers all over the place, and control transfer was done by redirecting the interpreter's current block. - Exception handlers & finalizers are now stored per-bytecode-range in a side table in Executable. - The interpreter now has a plain program counter instead of a stream iterator. This actually makes error stack generation a bit nicer since we just have to deal with a number instead of reaching into the iterator. This yields a 25% performance improvement on this microbenchmark: for (let i = 0; i < 1_000_000; ++i) { } But basically everything gets faster. :^)
2024-05-06 06:44:08 +02:00
object->define_direct_property("continuation", Value(m_continuation_label->address()), JS::default_attributes);
LibJS: Move all bytecode instruction implementations to Interpreter.cpp This allows aggressive inlining without LTO.
2023-09-27 10:10:00 +02:00
else
LibJS/Bytecode: Flatten bytecode to a contiguous representation Instead of keeping bytecode as a set of disjoint basic blocks on the malloc heap, bytecode is now a contiguous sequence of bytes(!) The transformation happens at the end of Bytecode::Generator::generate() and the only really hairy part is rerouting jump labels. This required solving a few problems: - The interpreter execution loop had to change quite a bit, since we were storing BasicBlock pointers all over the place, and control transfer was done by redirecting the interpreter's current block. - Exception handlers & finalizers are now stored per-bytecode-range in a side table in Executable. - The interpreter now has a plain program counter instead of a stream iterator. This actually makes error stack generation a bit nicer since we just have to deal with a number instead of reaching into the iterator. This yields a 25% performance improvement on this microbenchmark: for (let i = 0; i < 1_000_000; ++i) { } But basically everything gets faster. :^)
2024-05-06 06:44:08 +02:00
object->define_direct_property("continuation", js_null(), JS::default_attributes);
LibJS: Move all bytecode instruction implementations to Interpreter.cpp This allows aggressive inlining without LTO.
2023-09-27 10:10:00 +02:00
object->define_direct_property("isAwait", Value(false), JS::default_attributes);
interpreter.do_return(object);
LibJS/Bytecode: Move to a new bytecode format This patch moves us away from the accumulator-based bytecode format to one with explicit source and destination registers. The new format has multiple benefits: - ~25% faster on the Kraken and Octane benchmarks :^) - Fewer instructions to accomplish the same thing - Much easier for humans to read(!) Because this change requires a fundamental shift in how bytecode is generated, it is quite comprehensive. Main implementation mechanism: generate_bytecode() virtual function now takes an optional "preferred dst" operand, which allows callers to communicate when they have an operand that would be optimal for the result to go into. It also returns an optional "actual dst" operand, which is where the completion value (if any) of the AST node is stored after the node has "executed". One thing of note that's new: because instructions can now take locals as operands, this means we got rid of the GetLocal instruction. A side-effect of that is we have to think about the temporal deadzone (TDZ) a bit differently for locals (GetLocal would previously check for empty values and interpret that as a TDZ access and throw). We now insert special ThrowIfTDZ instructions in places where a local access may be in the TDZ, to maintain the correct behavior. There are a number of progressions and regressions from this test: A number of async generator tests have been accidentally fixed while converting the implementation to the new bytecode format. It didn't seem useful to preserve bugs in the original code when converting it. Some "does eval() return the correct completion value" tests have regressed, in particular ones related to propagating the appropriate completion after control flow statements like continue and break. These are all fairly obscure issues, and I believe we can continue working on them separately. The net test262 result is a progression though. :^)
2024-02-04 08:00:54 +01:00
LibJS: Move all bytecode instruction implementations to Interpreter.cpp This allows aggressive inlining without LTO.
2023-09-27 10:10:00 +02:00
return {};
}
ThrowCompletionOr<void> Await::execute_impl(Bytecode::Interpreter& interpreter) const
{
LibJS/Bytecode: Move to a new bytecode format This patch moves us away from the accumulator-based bytecode format to one with explicit source and destination registers. The new format has multiple benefits: - ~25% faster on the Kraken and Octane benchmarks :^) - Fewer instructions to accomplish the same thing - Much easier for humans to read(!) Because this change requires a fundamental shift in how bytecode is generated, it is quite comprehensive. Main implementation mechanism: generate_bytecode() virtual function now takes an optional "preferred dst" operand, which allows callers to communicate when they have an operand that would be optimal for the result to go into. It also returns an optional "actual dst" operand, which is where the completion value (if any) of the AST node is stored after the node has "executed". One thing of note that's new: because instructions can now take locals as operands, this means we got rid of the GetLocal instruction. A side-effect of that is we have to think about the temporal deadzone (TDZ) a bit differently for locals (GetLocal would previously check for empty values and interpret that as a TDZ access and throw). We now insert special ThrowIfTDZ instructions in places where a local access may be in the TDZ, to maintain the correct behavior. There are a number of progressions and regressions from this test: A number of async generator tests have been accidentally fixed while converting the implementation to the new bytecode format. It didn't seem useful to preserve bugs in the original code when converting it. Some "does eval() return the correct completion value" tests have regressed, in particular ones related to propagating the appropriate completion after control flow statements like continue and break. These are all fairly obscure issues, and I believe we can continue working on them separately. The net test262 result is a progression though. :^)
2024-02-04 08:00:54 +01:00
auto yielded_value = interpreter.get(m_argument).value_or(js_undefined());
LibJS: Move all bytecode instruction implementations to Interpreter.cpp This allows aggressive inlining without LTO.
2023-09-27 10:10:00 +02:00
auto object = Object::create(interpreter.realm(), nullptr);
object->define_direct_property("result", yielded_value, JS::default_attributes);
// FIXME: If we get a pointer, which is not accurately representable as a double
// will cause this to explode
LibJS/Bytecode: Flatten bytecode to a contiguous representation Instead of keeping bytecode as a set of disjoint basic blocks on the malloc heap, bytecode is now a contiguous sequence of bytes(!) The transformation happens at the end of Bytecode::Generator::generate() and the only really hairy part is rerouting jump labels. This required solving a few problems: - The interpreter execution loop had to change quite a bit, since we were storing BasicBlock pointers all over the place, and control transfer was done by redirecting the interpreter's current block. - Exception handlers & finalizers are now stored per-bytecode-range in a side table in Executable. - The interpreter now has a plain program counter instead of a stream iterator. This actually makes error stack generation a bit nicer since we just have to deal with a number instead of reaching into the iterator. This yields a 25% performance improvement on this microbenchmark: for (let i = 0; i < 1_000_000; ++i) { } But basically everything gets faster. :^)
2024-05-06 06:44:08 +02:00
object->define_direct_property("continuation", Value(m_continuation_label.address()), JS::default_attributes);
LibJS: Move all bytecode instruction implementations to Interpreter.cpp This allows aggressive inlining without LTO.
2023-09-27 10:10:00 +02:00
object->define_direct_property("isAwait", Value(true), JS::default_attributes);
interpreter.do_return(object);
return {};
}
ThrowCompletionOr<void> GetByValue::execute_impl(Bytecode::Interpreter& interpreter) const
{
LibJS: Include identifier information in nullish property read access When a GetById / GetByValue bytecode operation results in accessing a nullish object, we now include the name of the property and the object being accessed in the exception message (if available). This should make it easier to debug live websites. For example, the following errors would all previously produce a generic error message of "ToObject on null or undefined": > foo = null > foo.bar Uncaught exception: [TypeError] Cannot access property "bar" on null object "foo" at <unknown> > foo = { bar: undefined } > foo.bar.baz Uncaught exception: [TypeError] Cannot access property "baz" on undefined object "foo.bar" at <unknown> Note we certainly don't capture all possible nullish property read accesses here. This just covers cases I've seen most on live websites; we can cover more cases as they arise.
2024-03-29 11:26:10 -04:00
auto base_identifier = interpreter.current_executable().get_identifier(m_base_identifier);
interpreter.set(dst(), TRY(get_by_value(interpreter.vm(), base_identifier, interpreter.get(m_base), interpreter.get(m_property))));
LibJS: Move all bytecode instruction implementations to Interpreter.cpp This allows aggressive inlining without LTO.
2023-09-27 10:10:00 +02:00
return {};
}
ThrowCompletionOr<void> GetByValueWithThis::execute_impl(Bytecode::Interpreter& interpreter) const
{
auto& vm = interpreter.vm();
LibJS/Bytecode: Move to a new bytecode format This patch moves us away from the accumulator-based bytecode format to one with explicit source and destination registers. The new format has multiple benefits: - ~25% faster on the Kraken and Octane benchmarks :^) - Fewer instructions to accomplish the same thing - Much easier for humans to read(!) Because this change requires a fundamental shift in how bytecode is generated, it is quite comprehensive. Main implementation mechanism: generate_bytecode() virtual function now takes an optional "preferred dst" operand, which allows callers to communicate when they have an operand that would be optimal for the result to go into. It also returns an optional "actual dst" operand, which is where the completion value (if any) of the AST node is stored after the node has "executed". One thing of note that's new: because instructions can now take locals as operands, this means we got rid of the GetLocal instruction. A side-effect of that is we have to think about the temporal deadzone (TDZ) a bit differently for locals (GetLocal would previously check for empty values and interpret that as a TDZ access and throw). We now insert special ThrowIfTDZ instructions in places where a local access may be in the TDZ, to maintain the correct behavior. There are a number of progressions and regressions from this test: A number of async generator tests have been accidentally fixed while converting the implementation to the new bytecode format. It didn't seem useful to preserve bugs in the original code when converting it. Some "does eval() return the correct completion value" tests have regressed, in particular ones related to propagating the appropriate completion after control flow statements like continue and break. These are all fairly obscure issues, and I believe we can continue working on them separately. The net test262 result is a progression though. :^)
2024-02-04 08:00:54 +01:00
auto property_key_value = interpreter.get(m_property);
auto object = TRY(interpreter.get(m_base).to_object(vm));
LibJS: Move all bytecode instruction implementations to Interpreter.cpp This allows aggressive inlining without LTO.
2023-09-27 10:10:00 +02:00
auto property_key = TRY(property_key_value.to_property_key(vm));
LibJS/Bytecode: Move to a new bytecode format This patch moves us away from the accumulator-based bytecode format to one with explicit source and destination registers. The new format has multiple benefits: - ~25% faster on the Kraken and Octane benchmarks :^) - Fewer instructions to accomplish the same thing - Much easier for humans to read(!) Because this change requires a fundamental shift in how bytecode is generated, it is quite comprehensive. Main implementation mechanism: generate_bytecode() virtual function now takes an optional "preferred dst" operand, which allows callers to communicate when they have an operand that would be optimal for the result to go into. It also returns an optional "actual dst" operand, which is where the completion value (if any) of the AST node is stored after the node has "executed". One thing of note that's new: because instructions can now take locals as operands, this means we got rid of the GetLocal instruction. A side-effect of that is we have to think about the temporal deadzone (TDZ) a bit differently for locals (GetLocal would previously check for empty values and interpret that as a TDZ access and throw). We now insert special ThrowIfTDZ instructions in places where a local access may be in the TDZ, to maintain the correct behavior. There are a number of progressions and regressions from this test: A number of async generator tests have been accidentally fixed while converting the implementation to the new bytecode format. It didn't seem useful to preserve bugs in the original code when converting it. Some "does eval() return the correct completion value" tests have regressed, in particular ones related to propagating the appropriate completion after control flow statements like continue and break. These are all fairly obscure issues, and I believe we can continue working on them separately. The net test262 result is a progression though. :^)
2024-02-04 08:00:54 +01:00
interpreter.set(dst(), TRY(object->internal_get(property_key, interpreter.get(m_this_value))));
LibJS: Move all bytecode instruction implementations to Interpreter.cpp This allows aggressive inlining without LTO.
2023-09-27 10:10:00 +02:00
return {};
}
ThrowCompletionOr<void> PutByValue::execute_impl(Bytecode::Interpreter& interpreter) const
{
auto& vm = interpreter.vm();
LibJS/Bytecode: Move to a new bytecode format This patch moves us away from the accumulator-based bytecode format to one with explicit source and destination registers. The new format has multiple benefits: - ~25% faster on the Kraken and Octane benchmarks :^) - Fewer instructions to accomplish the same thing - Much easier for humans to read(!) Because this change requires a fundamental shift in how bytecode is generated, it is quite comprehensive. Main implementation mechanism: generate_bytecode() virtual function now takes an optional "preferred dst" operand, which allows callers to communicate when they have an operand that would be optimal for the result to go into. It also returns an optional "actual dst" operand, which is where the completion value (if any) of the AST node is stored after the node has "executed". One thing of note that's new: because instructions can now take locals as operands, this means we got rid of the GetLocal instruction. A side-effect of that is we have to think about the temporal deadzone (TDZ) a bit differently for locals (GetLocal would previously check for empty values and interpret that as a TDZ access and throw). We now insert special ThrowIfTDZ instructions in places where a local access may be in the TDZ, to maintain the correct behavior. There are a number of progressions and regressions from this test: A number of async generator tests have been accidentally fixed while converting the implementation to the new bytecode format. It didn't seem useful to preserve bugs in the original code when converting it. Some "does eval() return the correct completion value" tests have regressed, in particular ones related to propagating the appropriate completion after control flow statements like continue and break. These are all fairly obscure issues, and I believe we can continue working on them separately. The net test262 result is a progression though. :^)
2024-02-04 08:00:54 +01:00
auto value = interpreter.get(m_src);
LibJS: Include identifier information in nullish property write access When a PutById / PutByValue bytecode operation results in accessing a nullish object, we now include the name of the property and the object being accessed in the exception message (if available). This should make it easier to debug live websites. For example, the following errors would all previously produce a generic error message of "ToObject on null or undefined": > foo = null > foo.bar = 1 Uncaught exception: [TypeError] Cannot access property "bar" on null object "foo" at <unknown> > foo = { bar: undefined } > foo.bar.baz = 1 Uncaught exception: [TypeError] Cannot access property "baz" on undefined object "foo.bar" at <unknown> Note we certainly don't capture all possible nullish property write accesses here. This just covers cases I've seen most on live websites; we can cover more cases as they arise.
2024-03-29 12:10:52 -04:00
auto base_identifier = interpreter.current_executable().get_identifier(m_base_identifier);
TRY(put_by_value(vm, interpreter.get(m_base), base_identifier, interpreter.get(m_property), value, m_kind));
LibJS: Move all bytecode instruction implementations to Interpreter.cpp This allows aggressive inlining without LTO.
2023-09-27 10:10:00 +02:00
return {};
}
ThrowCompletionOr<void> PutByValueWithThis::execute_impl(Bytecode::Interpreter& interpreter) const
{
auto& vm = interpreter.vm();
LibJS/Bytecode: Move to a new bytecode format This patch moves us away from the accumulator-based bytecode format to one with explicit source and destination registers. The new format has multiple benefits: - ~25% faster on the Kraken and Octane benchmarks :^) - Fewer instructions to accomplish the same thing - Much easier for humans to read(!) Because this change requires a fundamental shift in how bytecode is generated, it is quite comprehensive. Main implementation mechanism: generate_bytecode() virtual function now takes an optional "preferred dst" operand, which allows callers to communicate when they have an operand that would be optimal for the result to go into. It also returns an optional "actual dst" operand, which is where the completion value (if any) of the AST node is stored after the node has "executed". One thing of note that's new: because instructions can now take locals as operands, this means we got rid of the GetLocal instruction. A side-effect of that is we have to think about the temporal deadzone (TDZ) a bit differently for locals (GetLocal would previously check for empty values and interpret that as a TDZ access and throw). We now insert special ThrowIfTDZ instructions in places where a local access may be in the TDZ, to maintain the correct behavior. There are a number of progressions and regressions from this test: A number of async generator tests have been accidentally fixed while converting the implementation to the new bytecode format. It didn't seem useful to preserve bugs in the original code when converting it. Some "does eval() return the correct completion value" tests have regressed, in particular ones related to propagating the appropriate completion after control flow statements like continue and break. These are all fairly obscure issues, and I believe we can continue working on them separately. The net test262 result is a progression though. :^)
2024-02-04 08:00:54 +01:00
auto value = interpreter.get(m_src);
auto base = interpreter.get(m_base);
auto property_key = m_kind != PropertyKind::Spread ? TRY(interpreter.get(m_property).to_property_key(vm)) : PropertyKey {};
LibJS: Include identifier information in nullish property write access When a PutById / PutByValue bytecode operation results in accessing a nullish object, we now include the name of the property and the object being accessed in the exception message (if available). This should make it easier to debug live websites. For example, the following errors would all previously produce a generic error message of "ToObject on null or undefined": > foo = null > foo.bar = 1 Uncaught exception: [TypeError] Cannot access property "bar" on null object "foo" at <unknown> > foo = { bar: undefined } > foo.bar.baz = 1 Uncaught exception: [TypeError] Cannot access property "baz" on undefined object "foo.bar" at <unknown> Note we certainly don't capture all possible nullish property write accesses here. This just covers cases I've seen most on live websites; we can cover more cases as they arise.
2024-03-29 12:10:52 -04:00
TRY(put_by_property_key(vm, base, interpreter.get(m_this_value), value, {}, property_key, m_kind));
LibJS: Move all bytecode instruction implementations to Interpreter.cpp This allows aggressive inlining without LTO.
2023-09-27 10:10:00 +02:00
return {};
}
ThrowCompletionOr<void> DeleteByValue::execute_impl(Bytecode::Interpreter& interpreter) const
{
LibJS/Bytecode: Move to a new bytecode format This patch moves us away from the accumulator-based bytecode format to one with explicit source and destination registers. The new format has multiple benefits: - ~25% faster on the Kraken and Octane benchmarks :^) - Fewer instructions to accomplish the same thing - Much easier for humans to read(!) Because this change requires a fundamental shift in how bytecode is generated, it is quite comprehensive. Main implementation mechanism: generate_bytecode() virtual function now takes an optional "preferred dst" operand, which allows callers to communicate when they have an operand that would be optimal for the result to go into. It also returns an optional "actual dst" operand, which is where the completion value (if any) of the AST node is stored after the node has "executed". One thing of note that's new: because instructions can now take locals as operands, this means we got rid of the GetLocal instruction. A side-effect of that is we have to think about the temporal deadzone (TDZ) a bit differently for locals (GetLocal would previously check for empty values and interpret that as a TDZ access and throw). We now insert special ThrowIfTDZ instructions in places where a local access may be in the TDZ, to maintain the correct behavior. There are a number of progressions and regressions from this test: A number of async generator tests have been accidentally fixed while converting the implementation to the new bytecode format. It didn't seem useful to preserve bugs in the original code when converting it. Some "does eval() return the correct completion value" tests have regressed, in particular ones related to propagating the appropriate completion after control flow statements like continue and break. These are all fairly obscure issues, and I believe we can continue working on them separately. The net test262 result is a progression though. :^)
2024-02-04 08:00:54 +01:00
auto base_value = interpreter.get(m_base);
auto property_key_value = interpreter.get(m_property);
interpreter.set(dst(), TRY(delete_by_value(interpreter, base_value, property_key_value)));
LibJS: Move all bytecode instruction implementations to Interpreter.cpp This allows aggressive inlining without LTO.
2023-09-27 10:10:00 +02:00
return {};
}
ThrowCompletionOr<void> DeleteByValueWithThis::execute_impl(Bytecode::Interpreter& interpreter) const
{
LibJS/Bytecode: Move to a new bytecode format This patch moves us away from the accumulator-based bytecode format to one with explicit source and destination registers. The new format has multiple benefits: - ~25% faster on the Kraken and Octane benchmarks :^) - Fewer instructions to accomplish the same thing - Much easier for humans to read(!) Because this change requires a fundamental shift in how bytecode is generated, it is quite comprehensive. Main implementation mechanism: generate_bytecode() virtual function now takes an optional "preferred dst" operand, which allows callers to communicate when they have an operand that would be optimal for the result to go into. It also returns an optional "actual dst" operand, which is where the completion value (if any) of the AST node is stored after the node has "executed". One thing of note that's new: because instructions can now take locals as operands, this means we got rid of the GetLocal instruction. A side-effect of that is we have to think about the temporal deadzone (TDZ) a bit differently for locals (GetLocal would previously check for empty values and interpret that as a TDZ access and throw). We now insert special ThrowIfTDZ instructions in places where a local access may be in the TDZ, to maintain the correct behavior. There are a number of progressions and regressions from this test: A number of async generator tests have been accidentally fixed while converting the implementation to the new bytecode format. It didn't seem useful to preserve bugs in the original code when converting it. Some "does eval() return the correct completion value" tests have regressed, in particular ones related to propagating the appropriate completion after control flow statements like continue and break. These are all fairly obscure issues, and I believe we can continue working on them separately. The net test262 result is a progression though. :^)
2024-02-04 08:00:54 +01:00
auto property_key_value = interpreter.get(m_property);
auto base_value = interpreter.get(m_base);
auto this_value = interpreter.get(m_this_value);
interpreter.set(dst(), TRY(delete_by_value_with_this(interpreter, base_value, property_key_value, this_value)));
LibJS/JIT: Compile the DeleteByValueWithThis instruction
2023-10-29 21:37:52 +01:00
LibJS: Move all bytecode instruction implementations to Interpreter.cpp This allows aggressive inlining without LTO.
2023-09-27 10:10:00 +02:00
return {};
}
ThrowCompletionOr<void> GetIterator::execute_impl(Bytecode::Interpreter& interpreter) const
{
auto& vm = interpreter.vm();
LibJS/Bytecode: Move to a new bytecode format This patch moves us away from the accumulator-based bytecode format to one with explicit source and destination registers. The new format has multiple benefits: - ~25% faster on the Kraken and Octane benchmarks :^) - Fewer instructions to accomplish the same thing - Much easier for humans to read(!) Because this change requires a fundamental shift in how bytecode is generated, it is quite comprehensive. Main implementation mechanism: generate_bytecode() virtual function now takes an optional "preferred dst" operand, which allows callers to communicate when they have an operand that would be optimal for the result to go into. It also returns an optional "actual dst" operand, which is where the completion value (if any) of the AST node is stored after the node has "executed". One thing of note that's new: because instructions can now take locals as operands, this means we got rid of the GetLocal instruction. A side-effect of that is we have to think about the temporal deadzone (TDZ) a bit differently for locals (GetLocal would previously check for empty values and interpret that as a TDZ access and throw). We now insert special ThrowIfTDZ instructions in places where a local access may be in the TDZ, to maintain the correct behavior. There are a number of progressions and regressions from this test: A number of async generator tests have been accidentally fixed while converting the implementation to the new bytecode format. It didn't seem useful to preserve bugs in the original code when converting it. Some "does eval() return the correct completion value" tests have regressed, in particular ones related to propagating the appropriate completion after control flow statements like continue and break. These are all fairly obscure issues, and I believe we can continue working on them separately. The net test262 result is a progression though. :^)
2024-02-04 08:00:54 +01:00
interpreter.set(dst(), TRY(get_iterator(vm, interpreter.get(iterable()), m_hint)));
LibJS: Stop converting between Object <-> IteratorRecord all the time This patch makes IteratorRecord an Object. Although it's not exposed to author code, this does allow us to store it in a VM register. Now that we can store it in a VM register, we don't need to convert it back and forth between IteratorRecord and Object when accessing it from bytecode. The big win here is avoiding 3 [[Get]] accesses on every iteration step of for..of loops. There are also a bunch of smaller efficiencies gained. 20% speed-up on this microbenchmark: function go(a) { for (const p of a) { } } const a = []; a.length = 1_000_000; go(a);
2023-12-07 10:44:41 +01:00
return {};
}
ThrowCompletionOr<void> GetObjectFromIteratorRecord::execute_impl(Bytecode::Interpreter& interpreter) const
{
LibJS/Bytecode: Move to a new bytecode format This patch moves us away from the accumulator-based bytecode format to one with explicit source and destination registers. The new format has multiple benefits: - ~25% faster on the Kraken and Octane benchmarks :^) - Fewer instructions to accomplish the same thing - Much easier for humans to read(!) Because this change requires a fundamental shift in how bytecode is generated, it is quite comprehensive. Main implementation mechanism: generate_bytecode() virtual function now takes an optional "preferred dst" operand, which allows callers to communicate when they have an operand that would be optimal for the result to go into. It also returns an optional "actual dst" operand, which is where the completion value (if any) of the AST node is stored after the node has "executed". One thing of note that's new: because instructions can now take locals as operands, this means we got rid of the GetLocal instruction. A side-effect of that is we have to think about the temporal deadzone (TDZ) a bit differently for locals (GetLocal would previously check for empty values and interpret that as a TDZ access and throw). We now insert special ThrowIfTDZ instructions in places where a local access may be in the TDZ, to maintain the correct behavior. There are a number of progressions and regressions from this test: A number of async generator tests have been accidentally fixed while converting the implementation to the new bytecode format. It didn't seem useful to preserve bugs in the original code when converting it. Some "does eval() return the correct completion value" tests have regressed, in particular ones related to propagating the appropriate completion after control flow statements like continue and break. These are all fairly obscure issues, and I believe we can continue working on them separately. The net test262 result is a progression though. :^)
2024-02-04 08:00:54 +01:00
auto& iterator_record = verify_cast<IteratorRecord>(interpreter.get(m_iterator_record).as_object());
interpreter.set(m_object, iterator_record.iterator);
LibJS: Stop converting between Object <-> IteratorRecord all the time This patch makes IteratorRecord an Object. Although it's not exposed to author code, this does allow us to store it in a VM register. Now that we can store it in a VM register, we don't need to convert it back and forth between IteratorRecord and Object when accessing it from bytecode. The big win here is avoiding 3 [[Get]] accesses on every iteration step of for..of loops. There are also a bunch of smaller efficiencies gained. 20% speed-up on this microbenchmark: function go(a) { for (const p of a) { } } const a = []; a.length = 1_000_000; go(a);
2023-12-07 10:44:41 +01:00
return {};
}
ThrowCompletionOr<void> GetNextMethodFromIteratorRecord::execute_impl(Bytecode::Interpreter& interpreter) const
{
LibJS/Bytecode: Move to a new bytecode format This patch moves us away from the accumulator-based bytecode format to one with explicit source and destination registers. The new format has multiple benefits: - ~25% faster on the Kraken and Octane benchmarks :^) - Fewer instructions to accomplish the same thing - Much easier for humans to read(!) Because this change requires a fundamental shift in how bytecode is generated, it is quite comprehensive. Main implementation mechanism: generate_bytecode() virtual function now takes an optional "preferred dst" operand, which allows callers to communicate when they have an operand that would be optimal for the result to go into. It also returns an optional "actual dst" operand, which is where the completion value (if any) of the AST node is stored after the node has "executed". One thing of note that's new: because instructions can now take locals as operands, this means we got rid of the GetLocal instruction. A side-effect of that is we have to think about the temporal deadzone (TDZ) a bit differently for locals (GetLocal would previously check for empty values and interpret that as a TDZ access and throw). We now insert special ThrowIfTDZ instructions in places where a local access may be in the TDZ, to maintain the correct behavior. There are a number of progressions and regressions from this test: A number of async generator tests have been accidentally fixed while converting the implementation to the new bytecode format. It didn't seem useful to preserve bugs in the original code when converting it. Some "does eval() return the correct completion value" tests have regressed, in particular ones related to propagating the appropriate completion after control flow statements like continue and break. These are all fairly obscure issues, and I believe we can continue working on them separately. The net test262 result is a progression though. :^)
2024-02-04 08:00:54 +01:00
auto& iterator_record = verify_cast<IteratorRecord>(interpreter.get(m_iterator_record).as_object());
interpreter.set(m_next_method, iterator_record.next_method);
LibJS: Move all bytecode instruction implementations to Interpreter.cpp This allows aggressive inlining without LTO.
2023-09-27 10:10:00 +02:00
return {};
}
ThrowCompletionOr<void> GetMethod::execute_impl(Bytecode::Interpreter& interpreter) const
{
auto& vm = interpreter.vm();
auto identifier = interpreter.current_executable().get_identifier(m_property);
LibJS/Bytecode: Move to a new bytecode format This patch moves us away from the accumulator-based bytecode format to one with explicit source and destination registers. The new format has multiple benefits: - ~25% faster on the Kraken and Octane benchmarks :^) - Fewer instructions to accomplish the same thing - Much easier for humans to read(!) Because this change requires a fundamental shift in how bytecode is generated, it is quite comprehensive. Main implementation mechanism: generate_bytecode() virtual function now takes an optional "preferred dst" operand, which allows callers to communicate when they have an operand that would be optimal for the result to go into. It also returns an optional "actual dst" operand, which is where the completion value (if any) of the AST node is stored after the node has "executed". One thing of note that's new: because instructions can now take locals as operands, this means we got rid of the GetLocal instruction. A side-effect of that is we have to think about the temporal deadzone (TDZ) a bit differently for locals (GetLocal would previously check for empty values and interpret that as a TDZ access and throw). We now insert special ThrowIfTDZ instructions in places where a local access may be in the TDZ, to maintain the correct behavior. There are a number of progressions and regressions from this test: A number of async generator tests have been accidentally fixed while converting the implementation to the new bytecode format. It didn't seem useful to preserve bugs in the original code when converting it. Some "does eval() return the correct completion value" tests have regressed, in particular ones related to propagating the appropriate completion after control flow statements like continue and break. These are all fairly obscure issues, and I believe we can continue working on them separately. The net test262 result is a progression though. :^)
2024-02-04 08:00:54 +01:00
auto method = TRY(interpreter.get(m_object).get_method(vm, identifier));
interpreter.set(dst(), method ?: js_undefined());
LibJS: Move all bytecode instruction implementations to Interpreter.cpp This allows aggressive inlining without LTO.
2023-09-27 10:10:00 +02:00
return {};
}
ThrowCompletionOr<void> GetObjectPropertyIterator::execute_impl(Bytecode::Interpreter& interpreter) const
{
LibJS/Bytecode: Move to a new bytecode format This patch moves us away from the accumulator-based bytecode format to one with explicit source and destination registers. The new format has multiple benefits: - ~25% faster on the Kraken and Octane benchmarks :^) - Fewer instructions to accomplish the same thing - Much easier for humans to read(!) Because this change requires a fundamental shift in how bytecode is generated, it is quite comprehensive. Main implementation mechanism: generate_bytecode() virtual function now takes an optional "preferred dst" operand, which allows callers to communicate when they have an operand that would be optimal for the result to go into. It also returns an optional "actual dst" operand, which is where the completion value (if any) of the AST node is stored after the node has "executed". One thing of note that's new: because instructions can now take locals as operands, this means we got rid of the GetLocal instruction. A side-effect of that is we have to think about the temporal deadzone (TDZ) a bit differently for locals (GetLocal would previously check for empty values and interpret that as a TDZ access and throw). We now insert special ThrowIfTDZ instructions in places where a local access may be in the TDZ, to maintain the correct behavior. There are a number of progressions and regressions from this test: A number of async generator tests have been accidentally fixed while converting the implementation to the new bytecode format. It didn't seem useful to preserve bugs in the original code when converting it. Some "does eval() return the correct completion value" tests have regressed, in particular ones related to propagating the appropriate completion after control flow statements like continue and break. These are all fairly obscure issues, and I believe we can continue working on them separately. The net test262 result is a progression though. :^)
2024-02-04 08:00:54 +01:00
interpreter.set(dst(), TRY(get_object_property_iterator(interpreter.vm(), interpreter.get(object()))));
LibJS: Move all bytecode instruction implementations to Interpreter.cpp This allows aggressive inlining without LTO.
2023-09-27 10:10:00 +02:00
return {};
}
ThrowCompletionOr<void> IteratorClose::execute_impl(Bytecode::Interpreter& interpreter) const
{
auto& vm = interpreter.vm();
LibJS/Bytecode: Move to a new bytecode format This patch moves us away from the accumulator-based bytecode format to one with explicit source and destination registers. The new format has multiple benefits: - ~25% faster on the Kraken and Octane benchmarks :^) - Fewer instructions to accomplish the same thing - Much easier for humans to read(!) Because this change requires a fundamental shift in how bytecode is generated, it is quite comprehensive. Main implementation mechanism: generate_bytecode() virtual function now takes an optional "preferred dst" operand, which allows callers to communicate when they have an operand that would be optimal for the result to go into. It also returns an optional "actual dst" operand, which is where the completion value (if any) of the AST node is stored after the node has "executed". One thing of note that's new: because instructions can now take locals as operands, this means we got rid of the GetLocal instruction. A side-effect of that is we have to think about the temporal deadzone (TDZ) a bit differently for locals (GetLocal would previously check for empty values and interpret that as a TDZ access and throw). We now insert special ThrowIfTDZ instructions in places where a local access may be in the TDZ, to maintain the correct behavior. There are a number of progressions and regressions from this test: A number of async generator tests have been accidentally fixed while converting the implementation to the new bytecode format. It didn't seem useful to preserve bugs in the original code when converting it. Some "does eval() return the correct completion value" tests have regressed, in particular ones related to propagating the appropriate completion after control flow statements like continue and break. These are all fairly obscure issues, and I believe we can continue working on them separately. The net test262 result is a progression though. :^)
2024-02-04 08:00:54 +01:00
auto& iterator = verify_cast<IteratorRecord>(interpreter.get(m_iterator_record).as_object());
LibJS: Move all bytecode instruction implementations to Interpreter.cpp This allows aggressive inlining without LTO.
2023-09-27 10:10:00 +02:00
// FIXME: Return the value of the resulting completion. (Note that m_completion_value can be empty!)
TRY(iterator_close(vm, iterator, Completion { m_completion_type, m_completion_value, {} }));
return {};
}
ThrowCompletionOr<void> AsyncIteratorClose::execute_impl(Bytecode::Interpreter& interpreter) const
{
auto& vm = interpreter.vm();
LibJS/Bytecode: Move to a new bytecode format This patch moves us away from the accumulator-based bytecode format to one with explicit source and destination registers. The new format has multiple benefits: - ~25% faster on the Kraken and Octane benchmarks :^) - Fewer instructions to accomplish the same thing - Much easier for humans to read(!) Because this change requires a fundamental shift in how bytecode is generated, it is quite comprehensive. Main implementation mechanism: generate_bytecode() virtual function now takes an optional "preferred dst" operand, which allows callers to communicate when they have an operand that would be optimal for the result to go into. It also returns an optional "actual dst" operand, which is where the completion value (if any) of the AST node is stored after the node has "executed". One thing of note that's new: because instructions can now take locals as operands, this means we got rid of the GetLocal instruction. A side-effect of that is we have to think about the temporal deadzone (TDZ) a bit differently for locals (GetLocal would previously check for empty values and interpret that as a TDZ access and throw). We now insert special ThrowIfTDZ instructions in places where a local access may be in the TDZ, to maintain the correct behavior. There are a number of progressions and regressions from this test: A number of async generator tests have been accidentally fixed while converting the implementation to the new bytecode format. It didn't seem useful to preserve bugs in the original code when converting it. Some "does eval() return the correct completion value" tests have regressed, in particular ones related to propagating the appropriate completion after control flow statements like continue and break. These are all fairly obscure issues, and I believe we can continue working on them separately. The net test262 result is a progression though. :^)
2024-02-04 08:00:54 +01:00
auto& iterator = verify_cast<IteratorRecord>(interpreter.get(m_iterator_record).as_object());
LibJS: Move all bytecode instruction implementations to Interpreter.cpp This allows aggressive inlining without LTO.
2023-09-27 10:10:00 +02:00
// FIXME: Return the value of the resulting completion. (Note that m_completion_value can be empty!)
TRY(async_iterator_close(vm, iterator, Completion { m_completion_type, m_completion_value, {} }));
return {};
}
ThrowCompletionOr<void> IteratorNext::execute_impl(Bytecode::Interpreter& interpreter) const
{
auto& vm = interpreter.vm();
LibJS/Bytecode: Move to a new bytecode format This patch moves us away from the accumulator-based bytecode format to one with explicit source and destination registers. The new format has multiple benefits: - ~25% faster on the Kraken and Octane benchmarks :^) - Fewer instructions to accomplish the same thing - Much easier for humans to read(!) Because this change requires a fundamental shift in how bytecode is generated, it is quite comprehensive. Main implementation mechanism: generate_bytecode() virtual function now takes an optional "preferred dst" operand, which allows callers to communicate when they have an operand that would be optimal for the result to go into. It also returns an optional "actual dst" operand, which is where the completion value (if any) of the AST node is stored after the node has "executed". One thing of note that's new: because instructions can now take locals as operands, this means we got rid of the GetLocal instruction. A side-effect of that is we have to think about the temporal deadzone (TDZ) a bit differently for locals (GetLocal would previously check for empty values and interpret that as a TDZ access and throw). We now insert special ThrowIfTDZ instructions in places where a local access may be in the TDZ, to maintain the correct behavior. There are a number of progressions and regressions from this test: A number of async generator tests have been accidentally fixed while converting the implementation to the new bytecode format. It didn't seem useful to preserve bugs in the original code when converting it. Some "does eval() return the correct completion value" tests have regressed, in particular ones related to propagating the appropriate completion after control flow statements like continue and break. These are all fairly obscure issues, and I believe we can continue working on them separately. The net test262 result is a progression though. :^)
2024-02-04 08:00:54 +01:00
auto& iterator_record = verify_cast<IteratorRecord>(interpreter.get(m_iterator_record).as_object());
interpreter.set(dst(), TRY(iterator_next(vm, iterator_record)));
LibJS: Move all bytecode instruction implementations to Interpreter.cpp This allows aggressive inlining without LTO.
2023-09-27 10:10:00 +02:00
return {};
}
ThrowCompletionOr<void> NewClass::execute_impl(Bytecode::Interpreter& interpreter) const
{
LibJS/Bytecode: Move to a new bytecode format This patch moves us away from the accumulator-based bytecode format to one with explicit source and destination registers. The new format has multiple benefits: - ~25% faster on the Kraken and Octane benchmarks :^) - Fewer instructions to accomplish the same thing - Much easier for humans to read(!) Because this change requires a fundamental shift in how bytecode is generated, it is quite comprehensive. Main implementation mechanism: generate_bytecode() virtual function now takes an optional "preferred dst" operand, which allows callers to communicate when they have an operand that would be optimal for the result to go into. It also returns an optional "actual dst" operand, which is where the completion value (if any) of the AST node is stored after the node has "executed". One thing of note that's new: because instructions can now take locals as operands, this means we got rid of the GetLocal instruction. A side-effect of that is we have to think about the temporal deadzone (TDZ) a bit differently for locals (GetLocal would previously check for empty values and interpret that as a TDZ access and throw). We now insert special ThrowIfTDZ instructions in places where a local access may be in the TDZ, to maintain the correct behavior. There are a number of progressions and regressions from this test: A number of async generator tests have been accidentally fixed while converting the implementation to the new bytecode format. It didn't seem useful to preserve bugs in the original code when converting it. Some "does eval() return the correct completion value" tests have regressed, in particular ones related to propagating the appropriate completion after control flow statements like continue and break. These are all fairly obscure issues, and I believe we can continue working on them separately. The net test262 result is a progression though. :^)
2024-02-04 08:00:54 +01:00
Value super_class;
if (m_super_class.has_value())
super_class = interpreter.get(m_super_class.value());
interpreter.set(dst(), TRY(new_class(interpreter.vm(), super_class, m_class_expression, m_lhs_name)));
LibJS: Move all bytecode instruction implementations to Interpreter.cpp This allows aggressive inlining without LTO.
2023-09-27 10:10:00 +02:00
return {};
}
// 13.5.3.1 Runtime Semantics: Evaluation, https://tc39.es/ecma262/#sec-typeof-operator-runtime-semantics-evaluation
ThrowCompletionOr<void> TypeofVariable::execute_impl(Bytecode::Interpreter& interpreter) const
{
auto& vm = interpreter.vm();
LibJS/Bytecode: Move to a new bytecode format This patch moves us away from the accumulator-based bytecode format to one with explicit source and destination registers. The new format has multiple benefits: - ~25% faster on the Kraken and Octane benchmarks :^) - Fewer instructions to accomplish the same thing - Much easier for humans to read(!) Because this change requires a fundamental shift in how bytecode is generated, it is quite comprehensive. Main implementation mechanism: generate_bytecode() virtual function now takes an optional "preferred dst" operand, which allows callers to communicate when they have an operand that would be optimal for the result to go into. It also returns an optional "actual dst" operand, which is where the completion value (if any) of the AST node is stored after the node has "executed". One thing of note that's new: because instructions can now take locals as operands, this means we got rid of the GetLocal instruction. A side-effect of that is we have to think about the temporal deadzone (TDZ) a bit differently for locals (GetLocal would previously check for empty values and interpret that as a TDZ access and throw). We now insert special ThrowIfTDZ instructions in places where a local access may be in the TDZ, to maintain the correct behavior. There are a number of progressions and regressions from this test: A number of async generator tests have been accidentally fixed while converting the implementation to the new bytecode format. It didn't seem useful to preserve bugs in the original code when converting it. Some "does eval() return the correct completion value" tests have regressed, in particular ones related to propagating the appropriate completion after control flow statements like continue and break. These are all fairly obscure issues, and I believe we can continue working on them separately. The net test262 result is a progression though. :^)
2024-02-04 08:00:54 +01:00
interpreter.set(dst(), TRY(typeof_variable(vm, interpreter.current_executable().get_identifier(m_identifier))));
LibJS: Move all bytecode instruction implementations to Interpreter.cpp This allows aggressive inlining without LTO.
2023-09-27 10:10:00 +02:00
return {};
}
ThrowCompletionOr<void> BlockDeclarationInstantiation::execute_impl(Bytecode::Interpreter& interpreter) const
{
auto& vm = interpreter.vm();
auto old_environment = vm.running_execution_context().lexical_environment;
LibJS: Merge CallFrame into ExecutionContext Before this change both ExecutionContext and CallFrame were created before executing function/module/script with a couple exceptions: - executable created for default function argument evaluation has to run in function's execution context. - `execute_ast_node()` where executable compiled for ASTNode has to be executed in running execution context. This change moves all members previously owned by CallFrame into ExecutionContext, and makes two exceptions where an executable that does not have a corresponding execution context saves and restores registers before running. Now, all execution state lives in a single entity, which makes it a bit easier to reason about and opens opportunities for optimizations, such as moving registers and local variables into a single array.
2024-05-01 19:33:49 +02:00
auto& running_execution_context = vm.running_execution_context();
running_execution_context.saved_lexical_environments.append(old_environment);
running_execution_context.lexical_environment = new_declarative_environment(*old_environment);
m_scope_node.block_declaration_instantiation(vm, running_execution_context.lexical_environment);
LibJS: Move all bytecode instruction implementations to Interpreter.cpp This allows aggressive inlining without LTO.
2023-09-27 10:10:00 +02:00
return {};
}
LibJS/Bytecode: Move to a new bytecode format This patch moves us away from the accumulator-based bytecode format to one with explicit source and destination registers. The new format has multiple benefits: - ~25% faster on the Kraken and Octane benchmarks :^) - Fewer instructions to accomplish the same thing - Much easier for humans to read(!) Because this change requires a fundamental shift in how bytecode is generated, it is quite comprehensive. Main implementation mechanism: generate_bytecode() virtual function now takes an optional "preferred dst" operand, which allows callers to communicate when they have an operand that would be optimal for the result to go into. It also returns an optional "actual dst" operand, which is where the completion value (if any) of the AST node is stored after the node has "executed". One thing of note that's new: because instructions can now take locals as operands, this means we got rid of the GetLocal instruction. A side-effect of that is we have to think about the temporal deadzone (TDZ) a bit differently for locals (GetLocal would previously check for empty values and interpret that as a TDZ access and throw). We now insert special ThrowIfTDZ instructions in places where a local access may be in the TDZ, to maintain the correct behavior. There are a number of progressions and regressions from this test: A number of async generator tests have been accidentally fixed while converting the implementation to the new bytecode format. It didn't seem useful to preserve bugs in the original code when converting it. Some "does eval() return the correct completion value" tests have regressed, in particular ones related to propagating the appropriate completion after control flow statements like continue and break. These are all fairly obscure issues, and I believe we can continue working on them separately. The net test262 result is a progression though. :^)
2024-02-04 08:00:54 +01:00
ByteString Mov::to_byte_string_impl(Bytecode::Executable const& executable) const
LibJS: Move all bytecode instruction implementations to Interpreter.cpp This allows aggressive inlining without LTO.
2023-09-27 10:10:00 +02:00
{
LibJS/Bytecode: Move to a new bytecode format This patch moves us away from the accumulator-based bytecode format to one with explicit source and destination registers. The new format has multiple benefits: - ~25% faster on the Kraken and Octane benchmarks :^) - Fewer instructions to accomplish the same thing - Much easier for humans to read(!) Because this change requires a fundamental shift in how bytecode is generated, it is quite comprehensive. Main implementation mechanism: generate_bytecode() virtual function now takes an optional "preferred dst" operand, which allows callers to communicate when they have an operand that would be optimal for the result to go into. It also returns an optional "actual dst" operand, which is where the completion value (if any) of the AST node is stored after the node has "executed". One thing of note that's new: because instructions can now take locals as operands, this means we got rid of the GetLocal instruction. A side-effect of that is we have to think about the temporal deadzone (TDZ) a bit differently for locals (GetLocal would previously check for empty values and interpret that as a TDZ access and throw). We now insert special ThrowIfTDZ instructions in places where a local access may be in the TDZ, to maintain the correct behavior. There are a number of progressions and regressions from this test: A number of async generator tests have been accidentally fixed while converting the implementation to the new bytecode format. It didn't seem useful to preserve bugs in the original code when converting it. Some "does eval() return the correct completion value" tests have regressed, in particular ones related to propagating the appropriate completion after control flow statements like continue and break. These are all fairly obscure issues, and I believe we can continue working on them separately. The net test262 result is a progression though. :^)
2024-02-04 08:00:54 +01:00
return ByteString::formatted("Mov {}, {}",
format_operand("dst"sv, m_dst, executable),
format_operand("src"sv, m_src, executable));
LibJS: Move all bytecode instruction implementations to Interpreter.cpp This allows aggressive inlining without LTO.
2023-09-27 10:10:00 +02:00
}
LibJS/Bytecode: Move to a new bytecode format This patch moves us away from the accumulator-based bytecode format to one with explicit source and destination registers. The new format has multiple benefits: - ~25% faster on the Kraken and Octane benchmarks :^) - Fewer instructions to accomplish the same thing - Much easier for humans to read(!) Because this change requires a fundamental shift in how bytecode is generated, it is quite comprehensive. Main implementation mechanism: generate_bytecode() virtual function now takes an optional "preferred dst" operand, which allows callers to communicate when they have an operand that would be optimal for the result to go into. It also returns an optional "actual dst" operand, which is where the completion value (if any) of the AST node is stored after the node has "executed". One thing of note that's new: because instructions can now take locals as operands, this means we got rid of the GetLocal instruction. A side-effect of that is we have to think about the temporal deadzone (TDZ) a bit differently for locals (GetLocal would previously check for empty values and interpret that as a TDZ access and throw). We now insert special ThrowIfTDZ instructions in places where a local access may be in the TDZ, to maintain the correct behavior. There are a number of progressions and regressions from this test: A number of async generator tests have been accidentally fixed while converting the implementation to the new bytecode format. It didn't seem useful to preserve bugs in the original code when converting it. Some "does eval() return the correct completion value" tests have regressed, in particular ones related to propagating the appropriate completion after control flow statements like continue and break. These are all fairly obscure issues, and I believe we can continue working on them separately. The net test262 result is a progression though. :^)
2024-02-04 08:00:54 +01:00
ByteString NewArray::to_byte_string_impl(Bytecode::Executable const& executable) const
LibJS: Move all bytecode instruction implementations to Interpreter.cpp This allows aggressive inlining without LTO.
2023-09-27 10:10:00 +02:00
{
StringBuilder builder;
LibJS/Bytecode: Move to a new bytecode format This patch moves us away from the accumulator-based bytecode format to one with explicit source and destination registers. The new format has multiple benefits: - ~25% faster on the Kraken and Octane benchmarks :^) - Fewer instructions to accomplish the same thing - Much easier for humans to read(!) Because this change requires a fundamental shift in how bytecode is generated, it is quite comprehensive. Main implementation mechanism: generate_bytecode() virtual function now takes an optional "preferred dst" operand, which allows callers to communicate when they have an operand that would be optimal for the result to go into. It also returns an optional "actual dst" operand, which is where the completion value (if any) of the AST node is stored after the node has "executed". One thing of note that's new: because instructions can now take locals as operands, this means we got rid of the GetLocal instruction. A side-effect of that is we have to think about the temporal deadzone (TDZ) a bit differently for locals (GetLocal would previously check for empty values and interpret that as a TDZ access and throw). We now insert special ThrowIfTDZ instructions in places where a local access may be in the TDZ, to maintain the correct behavior. There are a number of progressions and regressions from this test: A number of async generator tests have been accidentally fixed while converting the implementation to the new bytecode format. It didn't seem useful to preserve bugs in the original code when converting it. Some "does eval() return the correct completion value" tests have regressed, in particular ones related to propagating the appropriate completion after control flow statements like continue and break. These are all fairly obscure issues, and I believe we can continue working on them separately. The net test262 result is a progression though. :^)
2024-02-04 08:00:54 +01:00
builder.appendff("NewArray {}", format_operand("dst"sv, dst(), executable));
LibJS: Move all bytecode instruction implementations to Interpreter.cpp This allows aggressive inlining without LTO.
2023-09-27 10:10:00 +02:00
if (m_element_count != 0) {
LibJS/Bytecode: Move to a new bytecode format This patch moves us away from the accumulator-based bytecode format to one with explicit source and destination registers. The new format has multiple benefits: - ~25% faster on the Kraken and Octane benchmarks :^) - Fewer instructions to accomplish the same thing - Much easier for humans to read(!) Because this change requires a fundamental shift in how bytecode is generated, it is quite comprehensive. Main implementation mechanism: generate_bytecode() virtual function now takes an optional "preferred dst" operand, which allows callers to communicate when they have an operand that would be optimal for the result to go into. It also returns an optional "actual dst" operand, which is where the completion value (if any) of the AST node is stored after the node has "executed". One thing of note that's new: because instructions can now take locals as operands, this means we got rid of the GetLocal instruction. A side-effect of that is we have to think about the temporal deadzone (TDZ) a bit differently for locals (GetLocal would previously check for empty values and interpret that as a TDZ access and throw). We now insert special ThrowIfTDZ instructions in places where a local access may be in the TDZ, to maintain the correct behavior. There are a number of progressions and regressions from this test: A number of async generator tests have been accidentally fixed while converting the implementation to the new bytecode format. It didn't seem useful to preserve bugs in the original code when converting it. Some "does eval() return the correct completion value" tests have regressed, in particular ones related to propagating the appropriate completion after control flow statements like continue and break. These are all fairly obscure issues, and I believe we can continue working on them separately. The net test262 result is a progression though. :^)
2024-02-04 08:00:54 +01:00
builder.appendff(", [{}-{}]", format_operand("from"sv, m_elements[0], executable), format_operand("to"sv, m_elements[1], executable));
LibJS: Move all bytecode instruction implementations to Interpreter.cpp This allows aggressive inlining without LTO.
2023-09-27 10:10:00 +02:00
}
Everywhere: Rename {Deprecated => Byte}String This commit un-deprecates DeprecatedString, and repurposes it as a byte string. As the null state has already been removed, there are no other particularly hairy blockers in repurposing this type as a byte string (what it _really_ is). This commit is auto-generated: $ xs=$(ack -l \bDeprecatedString\b\|deprecated_string AK Userland \ Meta Ports Ladybird Tests Kernel) $ perl -pie 's/\bDeprecatedString\b/ByteString/g; s/deprecated_string/byte_string/g' $xs $ clang-format --style=file -i \ $(git diff --name-only | grep \.cpp\|\.h) $ gn format $(git ls-files '*.gn' '*.gni')
2023-12-16 17:49:34 +03:30
return builder.to_byte_string();
LibJS: Move all bytecode instruction implementations to Interpreter.cpp This allows aggressive inlining without LTO.
2023-09-27 10:10:00 +02:00
}
LibJS/Bytecode: Move to a new bytecode format This patch moves us away from the accumulator-based bytecode format to one with explicit source and destination registers. The new format has multiple benefits: - ~25% faster on the Kraken and Octane benchmarks :^) - Fewer instructions to accomplish the same thing - Much easier for humans to read(!) Because this change requires a fundamental shift in how bytecode is generated, it is quite comprehensive. Main implementation mechanism: generate_bytecode() virtual function now takes an optional "preferred dst" operand, which allows callers to communicate when they have an operand that would be optimal for the result to go into. It also returns an optional "actual dst" operand, which is where the completion value (if any) of the AST node is stored after the node has "executed". One thing of note that's new: because instructions can now take locals as operands, this means we got rid of the GetLocal instruction. A side-effect of that is we have to think about the temporal deadzone (TDZ) a bit differently for locals (GetLocal would previously check for empty values and interpret that as a TDZ access and throw). We now insert special ThrowIfTDZ instructions in places where a local access may be in the TDZ, to maintain the correct behavior. There are a number of progressions and regressions from this test: A number of async generator tests have been accidentally fixed while converting the implementation to the new bytecode format. It didn't seem useful to preserve bugs in the original code when converting it. Some "does eval() return the correct completion value" tests have regressed, in particular ones related to propagating the appropriate completion after control flow statements like continue and break. These are all fairly obscure issues, and I believe we can continue working on them separately. The net test262 result is a progression though. :^)
2024-02-04 08:00:54 +01:00
ByteString NewPrimitiveArray::to_byte_string_impl(Bytecode::Executable const& executable) const
LibJS: Instantiate primitive array expressions using a single operation This will not meaningfully affect short array literals, but it does give us a bit of extra perf when evaluating huge array expressions like in Kraken/imaging-darkroom.js
2023-11-17 22:07:23 +02:00
{
LibJS/Bytecode: Move to a new bytecode format This patch moves us away from the accumulator-based bytecode format to one with explicit source and destination registers. The new format has multiple benefits: - ~25% faster on the Kraken and Octane benchmarks :^) - Fewer instructions to accomplish the same thing - Much easier for humans to read(!) Because this change requires a fundamental shift in how bytecode is generated, it is quite comprehensive. Main implementation mechanism: generate_bytecode() virtual function now takes an optional "preferred dst" operand, which allows callers to communicate when they have an operand that would be optimal for the result to go into. It also returns an optional "actual dst" operand, which is where the completion value (if any) of the AST node is stored after the node has "executed". One thing of note that's new: because instructions can now take locals as operands, this means we got rid of the GetLocal instruction. A side-effect of that is we have to think about the temporal deadzone (TDZ) a bit differently for locals (GetLocal would previously check for empty values and interpret that as a TDZ access and throw). We now insert special ThrowIfTDZ instructions in places where a local access may be in the TDZ, to maintain the correct behavior. There are a number of progressions and regressions from this test: A number of async generator tests have been accidentally fixed while converting the implementation to the new bytecode format. It didn't seem useful to preserve bugs in the original code when converting it. Some "does eval() return the correct completion value" tests have regressed, in particular ones related to propagating the appropriate completion after control flow statements like continue and break. These are all fairly obscure issues, and I believe we can continue working on them separately. The net test262 result is a progression though. :^)
2024-02-04 08:00:54 +01:00
return ByteString::formatted("NewPrimitiveArray {}, {}"sv,
format_operand("dst"sv, dst(), executable),
LibJS/Bytecode: Make NewPrimitiveArray a variable-length instruction Instead of having a FixedArray with a separate heap allocation, we can just bake the primitive values into the instruction itself.
2024-03-03 12:37:28 +01:00
format_value_list("elements"sv, elements()));
LibJS: Instantiate primitive array expressions using a single operation This will not meaningfully affect short array literals, but it does give us a bit of extra perf when evaluating huge array expressions like in Kraken/imaging-darkroom.js
2023-11-17 22:07:23 +02:00
}
LibJS/Bytecode: Move to a new bytecode format This patch moves us away from the accumulator-based bytecode format to one with explicit source and destination registers. The new format has multiple benefits: - ~25% faster on the Kraken and Octane benchmarks :^) - Fewer instructions to accomplish the same thing - Much easier for humans to read(!) Because this change requires a fundamental shift in how bytecode is generated, it is quite comprehensive. Main implementation mechanism: generate_bytecode() virtual function now takes an optional "preferred dst" operand, which allows callers to communicate when they have an operand that would be optimal for the result to go into. It also returns an optional "actual dst" operand, which is where the completion value (if any) of the AST node is stored after the node has "executed". One thing of note that's new: because instructions can now take locals as operands, this means we got rid of the GetLocal instruction. A side-effect of that is we have to think about the temporal deadzone (TDZ) a bit differently for locals (GetLocal would previously check for empty values and interpret that as a TDZ access and throw). We now insert special ThrowIfTDZ instructions in places where a local access may be in the TDZ, to maintain the correct behavior. There are a number of progressions and regressions from this test: A number of async generator tests have been accidentally fixed while converting the implementation to the new bytecode format. It didn't seem useful to preserve bugs in the original code when converting it. Some "does eval() return the correct completion value" tests have regressed, in particular ones related to propagating the appropriate completion after control flow statements like continue and break. These are all fairly obscure issues, and I believe we can continue working on them separately. The net test262 result is a progression though. :^)
2024-02-04 08:00:54 +01:00
ByteString ArrayAppend::to_byte_string_impl(Bytecode::Executable const& executable) const
LibJS: Move all bytecode instruction implementations to Interpreter.cpp This allows aggressive inlining without LTO.
2023-09-27 10:10:00 +02:00
{
LibJS/Bytecode: Move to a new bytecode format This patch moves us away from the accumulator-based bytecode format to one with explicit source and destination registers. The new format has multiple benefits: - ~25% faster on the Kraken and Octane benchmarks :^) - Fewer instructions to accomplish the same thing - Much easier for humans to read(!) Because this change requires a fundamental shift in how bytecode is generated, it is quite comprehensive. Main implementation mechanism: generate_bytecode() virtual function now takes an optional "preferred dst" operand, which allows callers to communicate when they have an operand that would be optimal for the result to go into. It also returns an optional "actual dst" operand, which is where the completion value (if any) of the AST node is stored after the node has "executed". One thing of note that's new: because instructions can now take locals as operands, this means we got rid of the GetLocal instruction. A side-effect of that is we have to think about the temporal deadzone (TDZ) a bit differently for locals (GetLocal would previously check for empty values and interpret that as a TDZ access and throw). We now insert special ThrowIfTDZ instructions in places where a local access may be in the TDZ, to maintain the correct behavior. There are a number of progressions and regressions from this test: A number of async generator tests have been accidentally fixed while converting the implementation to the new bytecode format. It didn't seem useful to preserve bugs in the original code when converting it. Some "does eval() return the correct completion value" tests have regressed, in particular ones related to propagating the appropriate completion after control flow statements like continue and break. These are all fairly obscure issues, and I believe we can continue working on them separately. The net test262 result is a progression though. :^)
2024-02-04 08:00:54 +01:00
return ByteString::formatted("Append {}, {}{}",
format_operand("dst"sv, dst(), executable),
format_operand("src"sv, src(), executable),
m_is_spread ? " **"sv : ""sv);
LibJS: Move all bytecode instruction implementations to Interpreter.cpp This allows aggressive inlining without LTO.
2023-09-27 10:10:00 +02:00
}
LibJS/Bytecode: Move to a new bytecode format This patch moves us away from the accumulator-based bytecode format to one with explicit source and destination registers. The new format has multiple benefits: - ~25% faster on the Kraken and Octane benchmarks :^) - Fewer instructions to accomplish the same thing - Much easier for humans to read(!) Because this change requires a fundamental shift in how bytecode is generated, it is quite comprehensive. Main implementation mechanism: generate_bytecode() virtual function now takes an optional "preferred dst" operand, which allows callers to communicate when they have an operand that would be optimal for the result to go into. It also returns an optional "actual dst" operand, which is where the completion value (if any) of the AST node is stored after the node has "executed". One thing of note that's new: because instructions can now take locals as operands, this means we got rid of the GetLocal instruction. A side-effect of that is we have to think about the temporal deadzone (TDZ) a bit differently for locals (GetLocal would previously check for empty values and interpret that as a TDZ access and throw). We now insert special ThrowIfTDZ instructions in places where a local access may be in the TDZ, to maintain the correct behavior. There are a number of progressions and regressions from this test: A number of async generator tests have been accidentally fixed while converting the implementation to the new bytecode format. It didn't seem useful to preserve bugs in the original code when converting it. Some "does eval() return the correct completion value" tests have regressed, in particular ones related to propagating the appropriate completion after control flow statements like continue and break. These are all fairly obscure issues, and I believe we can continue working on them separately. The net test262 result is a progression though. :^)
2024-02-04 08:00:54 +01:00
ByteString IteratorToArray::to_byte_string_impl(Bytecode::Executable const& executable) const
LibJS: Move all bytecode instruction implementations to Interpreter.cpp This allows aggressive inlining without LTO.
2023-09-27 10:10:00 +02:00
{
LibJS/Bytecode: Move to a new bytecode format This patch moves us away from the accumulator-based bytecode format to one with explicit source and destination registers. The new format has multiple benefits: - ~25% faster on the Kraken and Octane benchmarks :^) - Fewer instructions to accomplish the same thing - Much easier for humans to read(!) Because this change requires a fundamental shift in how bytecode is generated, it is quite comprehensive. Main implementation mechanism: generate_bytecode() virtual function now takes an optional "preferred dst" operand, which allows callers to communicate when they have an operand that would be optimal for the result to go into. It also returns an optional "actual dst" operand, which is where the completion value (if any) of the AST node is stored after the node has "executed". One thing of note that's new: because instructions can now take locals as operands, this means we got rid of the GetLocal instruction. A side-effect of that is we have to think about the temporal deadzone (TDZ) a bit differently for locals (GetLocal would previously check for empty values and interpret that as a TDZ access and throw). We now insert special ThrowIfTDZ instructions in places where a local access may be in the TDZ, to maintain the correct behavior. There are a number of progressions and regressions from this test: A number of async generator tests have been accidentally fixed while converting the implementation to the new bytecode format. It didn't seem useful to preserve bugs in the original code when converting it. Some "does eval() return the correct completion value" tests have regressed, in particular ones related to propagating the appropriate completion after control flow statements like continue and break. These are all fairly obscure issues, and I believe we can continue working on them separately. The net test262 result is a progression though. :^)
2024-02-04 08:00:54 +01:00
return ByteString::formatted("IteratorToArray {}, {}",
format_operand("dst"sv, dst(), executable),
format_operand("iterator"sv, iterator(), executable));
LibJS: Move all bytecode instruction implementations to Interpreter.cpp This allows aggressive inlining without LTO.
2023-09-27 10:10:00 +02:00
}
LibJS/Bytecode: Move to a new bytecode format This patch moves us away from the accumulator-based bytecode format to one with explicit source and destination registers. The new format has multiple benefits: - ~25% faster on the Kraken and Octane benchmarks :^) - Fewer instructions to accomplish the same thing - Much easier for humans to read(!) Because this change requires a fundamental shift in how bytecode is generated, it is quite comprehensive. Main implementation mechanism: generate_bytecode() virtual function now takes an optional "preferred dst" operand, which allows callers to communicate when they have an operand that would be optimal for the result to go into. It also returns an optional "actual dst" operand, which is where the completion value (if any) of the AST node is stored after the node has "executed". One thing of note that's new: because instructions can now take locals as operands, this means we got rid of the GetLocal instruction. A side-effect of that is we have to think about the temporal deadzone (TDZ) a bit differently for locals (GetLocal would previously check for empty values and interpret that as a TDZ access and throw). We now insert special ThrowIfTDZ instructions in places where a local access may be in the TDZ, to maintain the correct behavior. There are a number of progressions and regressions from this test: A number of async generator tests have been accidentally fixed while converting the implementation to the new bytecode format. It didn't seem useful to preserve bugs in the original code when converting it. Some "does eval() return the correct completion value" tests have regressed, in particular ones related to propagating the appropriate completion after control flow statements like continue and break. These are all fairly obscure issues, and I believe we can continue working on them separately. The net test262 result is a progression though. :^)
2024-02-04 08:00:54 +01:00
ByteString NewObject::to_byte_string_impl(Bytecode::Executable const& executable) const
LibJS: Move all bytecode instruction implementations to Interpreter.cpp This allows aggressive inlining without LTO.
2023-09-27 10:10:00 +02:00
{
LibJS/Bytecode: Move to a new bytecode format This patch moves us away from the accumulator-based bytecode format to one with explicit source and destination registers. The new format has multiple benefits: - ~25% faster on the Kraken and Octane benchmarks :^) - Fewer instructions to accomplish the same thing - Much easier for humans to read(!) Because this change requires a fundamental shift in how bytecode is generated, it is quite comprehensive. Main implementation mechanism: generate_bytecode() virtual function now takes an optional "preferred dst" operand, which allows callers to communicate when they have an operand that would be optimal for the result to go into. It also returns an optional "actual dst" operand, which is where the completion value (if any) of the AST node is stored after the node has "executed". One thing of note that's new: because instructions can now take locals as operands, this means we got rid of the GetLocal instruction. A side-effect of that is we have to think about the temporal deadzone (TDZ) a bit differently for locals (GetLocal would previously check for empty values and interpret that as a TDZ access and throw). We now insert special ThrowIfTDZ instructions in places where a local access may be in the TDZ, to maintain the correct behavior. There are a number of progressions and regressions from this test: A number of async generator tests have been accidentally fixed while converting the implementation to the new bytecode format. It didn't seem useful to preserve bugs in the original code when converting it. Some "does eval() return the correct completion value" tests have regressed, in particular ones related to propagating the appropriate completion after control flow statements like continue and break. These are all fairly obscure issues, and I believe we can continue working on them separately. The net test262 result is a progression though. :^)
2024-02-04 08:00:54 +01:00
return ByteString::formatted("NewObject {}", format_operand("dst"sv, dst(), executable));
LibJS: Move all bytecode instruction implementations to Interpreter.cpp This allows aggressive inlining without LTO.
2023-09-27 10:10:00 +02:00
}
Everywhere: Rename {Deprecated => Byte}String This commit un-deprecates DeprecatedString, and repurposes it as a byte string. As the null state has already been removed, there are no other particularly hairy blockers in repurposing this type as a byte string (what it _really_ is). This commit is auto-generated: $ xs=$(ack -l \bDeprecatedString\b\|deprecated_string AK Userland \ Meta Ports Ladybird Tests Kernel) $ perl -pie 's/\bDeprecatedString\b/ByteString/g; s/deprecated_string/byte_string/g' $xs $ clang-format --style=file -i \ $(git diff --name-only | grep \.cpp\|\.h) $ gn format $(git ls-files '*.gn' '*.gni')
2023-12-16 17:49:34 +03:30
ByteString NewRegExp::to_byte_string_impl(Bytecode::Executable const& executable) const
LibJS: Move all bytecode instruction implementations to Interpreter.cpp This allows aggressive inlining without LTO.
2023-09-27 10:10:00 +02:00
{
LibJS/Bytecode: Move to a new bytecode format This patch moves us away from the accumulator-based bytecode format to one with explicit source and destination registers. The new format has multiple benefits: - ~25% faster on the Kraken and Octane benchmarks :^) - Fewer instructions to accomplish the same thing - Much easier for humans to read(!) Because this change requires a fundamental shift in how bytecode is generated, it is quite comprehensive. Main implementation mechanism: generate_bytecode() virtual function now takes an optional "preferred dst" operand, which allows callers to communicate when they have an operand that would be optimal for the result to go into. It also returns an optional "actual dst" operand, which is where the completion value (if any) of the AST node is stored after the node has "executed". One thing of note that's new: because instructions can now take locals as operands, this means we got rid of the GetLocal instruction. A side-effect of that is we have to think about the temporal deadzone (TDZ) a bit differently for locals (GetLocal would previously check for empty values and interpret that as a TDZ access and throw). We now insert special ThrowIfTDZ instructions in places where a local access may be in the TDZ, to maintain the correct behavior. There are a number of progressions and regressions from this test: A number of async generator tests have been accidentally fixed while converting the implementation to the new bytecode format. It didn't seem useful to preserve bugs in the original code when converting it. Some "does eval() return the correct completion value" tests have regressed, in particular ones related to propagating the appropriate completion after control flow statements like continue and break. These are all fairly obscure issues, and I believe we can continue working on them separately. The net test262 result is a progression though. :^)
2024-02-04 08:00:54 +01:00
return ByteString::formatted("NewRegExp {}, source:{} (\"{}\") flags:{} (\"{}\")",
format_operand("dst"sv, dst(), executable),
m_source_index, executable.get_string(m_source_index), m_flags_index, executable.get_string(m_flags_index));
LibJS: Move all bytecode instruction implementations to Interpreter.cpp This allows aggressive inlining without LTO.
2023-09-27 10:10:00 +02:00
}
LibJS/Bytecode: Move to a new bytecode format This patch moves us away from the accumulator-based bytecode format to one with explicit source and destination registers. The new format has multiple benefits: - ~25% faster on the Kraken and Octane benchmarks :^) - Fewer instructions to accomplish the same thing - Much easier for humans to read(!) Because this change requires a fundamental shift in how bytecode is generated, it is quite comprehensive. Main implementation mechanism: generate_bytecode() virtual function now takes an optional "preferred dst" operand, which allows callers to communicate when they have an operand that would be optimal for the result to go into. It also returns an optional "actual dst" operand, which is where the completion value (if any) of the AST node is stored after the node has "executed". One thing of note that's new: because instructions can now take locals as operands, this means we got rid of the GetLocal instruction. A side-effect of that is we have to think about the temporal deadzone (TDZ) a bit differently for locals (GetLocal would previously check for empty values and interpret that as a TDZ access and throw). We now insert special ThrowIfTDZ instructions in places where a local access may be in the TDZ, to maintain the correct behavior. There are a number of progressions and regressions from this test: A number of async generator tests have been accidentally fixed while converting the implementation to the new bytecode format. It didn't seem useful to preserve bugs in the original code when converting it. Some "does eval() return the correct completion value" tests have regressed, in particular ones related to propagating the appropriate completion after control flow statements like continue and break. These are all fairly obscure issues, and I believe we can continue working on them separately. The net test262 result is a progression though. :^)
2024-02-04 08:00:54 +01:00
ByteString CopyObjectExcludingProperties::to_byte_string_impl(Bytecode::Executable const& executable) const
LibJS: Move all bytecode instruction implementations to Interpreter.cpp This allows aggressive inlining without LTO.
2023-09-27 10:10:00 +02:00
{
StringBuilder builder;
LibJS/Bytecode: Move to a new bytecode format This patch moves us away from the accumulator-based bytecode format to one with explicit source and destination registers. The new format has multiple benefits: - ~25% faster on the Kraken and Octane benchmarks :^) - Fewer instructions to accomplish the same thing - Much easier for humans to read(!) Because this change requires a fundamental shift in how bytecode is generated, it is quite comprehensive. Main implementation mechanism: generate_bytecode() virtual function now takes an optional "preferred dst" operand, which allows callers to communicate when they have an operand that would be optimal for the result to go into. It also returns an optional "actual dst" operand, which is where the completion value (if any) of the AST node is stored after the node has "executed". One thing of note that's new: because instructions can now take locals as operands, this means we got rid of the GetLocal instruction. A side-effect of that is we have to think about the temporal deadzone (TDZ) a bit differently for locals (GetLocal would previously check for empty values and interpret that as a TDZ access and throw). We now insert special ThrowIfTDZ instructions in places where a local access may be in the TDZ, to maintain the correct behavior. There are a number of progressions and regressions from this test: A number of async generator tests have been accidentally fixed while converting the implementation to the new bytecode format. It didn't seem useful to preserve bugs in the original code when converting it. Some "does eval() return the correct completion value" tests have regressed, in particular ones related to propagating the appropriate completion after control flow statements like continue and break. These are all fairly obscure issues, and I believe we can continue working on them separately. The net test262 result is a progression though. :^)
2024-02-04 08:00:54 +01:00
builder.appendff("CopyObjectExcludingProperties {}, {}",
format_operand("dst"sv, dst(), executable),
format_operand("from"sv, m_from_object, executable));
LibJS: Move all bytecode instruction implementations to Interpreter.cpp This allows aggressive inlining without LTO.
2023-09-27 10:10:00 +02:00
if (m_excluded_names_count != 0) {
builder.append(" excluding:["sv);
LibJS/Bytecode: Move to a new bytecode format This patch moves us away from the accumulator-based bytecode format to one with explicit source and destination registers. The new format has multiple benefits: - ~25% faster on the Kraken and Octane benchmarks :^) - Fewer instructions to accomplish the same thing - Much easier for humans to read(!) Because this change requires a fundamental shift in how bytecode is generated, it is quite comprehensive. Main implementation mechanism: generate_bytecode() virtual function now takes an optional "preferred dst" operand, which allows callers to communicate when they have an operand that would be optimal for the result to go into. It also returns an optional "actual dst" operand, which is where the completion value (if any) of the AST node is stored after the node has "executed". One thing of note that's new: because instructions can now take locals as operands, this means we got rid of the GetLocal instruction. A side-effect of that is we have to think about the temporal deadzone (TDZ) a bit differently for locals (GetLocal would previously check for empty values and interpret that as a TDZ access and throw). We now insert special ThrowIfTDZ instructions in places where a local access may be in the TDZ, to maintain the correct behavior. There are a number of progressions and regressions from this test: A number of async generator tests have been accidentally fixed while converting the implementation to the new bytecode format. It didn't seem useful to preserve bugs in the original code when converting it. Some "does eval() return the correct completion value" tests have regressed, in particular ones related to propagating the appropriate completion after control flow statements like continue and break. These are all fairly obscure issues, and I believe we can continue working on them separately. The net test262 result is a progression though. :^)
2024-02-04 08:00:54 +01:00
for (size_t i = 0; i < m_excluded_names_count; ++i) {
if (i != 0)
builder.append(", "sv);
builder.append(format_operand("#"sv, m_excluded_names[i], executable));
}
LibJS: Move all bytecode instruction implementations to Interpreter.cpp This allows aggressive inlining without LTO.
2023-09-27 10:10:00 +02:00
builder.append(']');
}
Everywhere: Rename {Deprecated => Byte}String This commit un-deprecates DeprecatedString, and repurposes it as a byte string. As the null state has already been removed, there are no other particularly hairy blockers in repurposing this type as a byte string (what it _really_ is). This commit is auto-generated: $ xs=$(ack -l \bDeprecatedString\b\|deprecated_string AK Userland \ Meta Ports Ladybird Tests Kernel) $ perl -pie 's/\bDeprecatedString\b/ByteString/g; s/deprecated_string/byte_string/g' $xs $ clang-format --style=file -i \ $(git diff --name-only | grep \.cpp\|\.h) $ gn format $(git ls-files '*.gn' '*.gni')
2023-12-16 17:49:34 +03:30
return builder.to_byte_string();
LibJS: Move all bytecode instruction implementations to Interpreter.cpp This allows aggressive inlining without LTO.
2023-09-27 10:10:00 +02:00
}
LibJS/Bytecode: Move to a new bytecode format This patch moves us away from the accumulator-based bytecode format to one with explicit source and destination registers. The new format has multiple benefits: - ~25% faster on the Kraken and Octane benchmarks :^) - Fewer instructions to accomplish the same thing - Much easier for humans to read(!) Because this change requires a fundamental shift in how bytecode is generated, it is quite comprehensive. Main implementation mechanism: generate_bytecode() virtual function now takes an optional "preferred dst" operand, which allows callers to communicate when they have an operand that would be optimal for the result to go into. It also returns an optional "actual dst" operand, which is where the completion value (if any) of the AST node is stored after the node has "executed". One thing of note that's new: because instructions can now take locals as operands, this means we got rid of the GetLocal instruction. A side-effect of that is we have to think about the temporal deadzone (TDZ) a bit differently for locals (GetLocal would previously check for empty values and interpret that as a TDZ access and throw). We now insert special ThrowIfTDZ instructions in places where a local access may be in the TDZ, to maintain the correct behavior. There are a number of progressions and regressions from this test: A number of async generator tests have been accidentally fixed while converting the implementation to the new bytecode format. It didn't seem useful to preserve bugs in the original code when converting it. Some "does eval() return the correct completion value" tests have regressed, in particular ones related to propagating the appropriate completion after control flow statements like continue and break. These are all fairly obscure issues, and I believe we can continue working on them separately. The net test262 result is a progression though. :^)
2024-02-04 08:00:54 +01:00
ByteString ConcatString::to_byte_string_impl(Bytecode::Executable const& executable) const
LibJS: Move all bytecode instruction implementations to Interpreter.cpp This allows aggressive inlining without LTO.
2023-09-27 10:10:00 +02:00
{
LibJS/Bytecode: Move to a new bytecode format This patch moves us away from the accumulator-based bytecode format to one with explicit source and destination registers. The new format has multiple benefits: - ~25% faster on the Kraken and Octane benchmarks :^) - Fewer instructions to accomplish the same thing - Much easier for humans to read(!) Because this change requires a fundamental shift in how bytecode is generated, it is quite comprehensive. Main implementation mechanism: generate_bytecode() virtual function now takes an optional "preferred dst" operand, which allows callers to communicate when they have an operand that would be optimal for the result to go into. It also returns an optional "actual dst" operand, which is where the completion value (if any) of the AST node is stored after the node has "executed". One thing of note that's new: because instructions can now take locals as operands, this means we got rid of the GetLocal instruction. A side-effect of that is we have to think about the temporal deadzone (TDZ) a bit differently for locals (GetLocal would previously check for empty values and interpret that as a TDZ access and throw). We now insert special ThrowIfTDZ instructions in places where a local access may be in the TDZ, to maintain the correct behavior. There are a number of progressions and regressions from this test: A number of async generator tests have been accidentally fixed while converting the implementation to the new bytecode format. It didn't seem useful to preserve bugs in the original code when converting it. Some "does eval() return the correct completion value" tests have regressed, in particular ones related to propagating the appropriate completion after control flow statements like continue and break. These are all fairly obscure issues, and I believe we can continue working on them separately. The net test262 result is a progression though. :^)
2024-02-04 08:00:54 +01:00
return ByteString::formatted("ConcatString {}, {}",
format_operand("dst"sv, dst(), executable),
format_operand("src"sv, src(), executable));
LibJS: Move all bytecode instruction implementations to Interpreter.cpp This allows aggressive inlining without LTO.
2023-09-27 10:10:00 +02:00
}
Everywhere: Rename {Deprecated => Byte}String This commit un-deprecates DeprecatedString, and repurposes it as a byte string. As the null state has already been removed, there are no other particularly hairy blockers in repurposing this type as a byte string (what it _really_ is). This commit is auto-generated: $ xs=$(ack -l \bDeprecatedString\b\|deprecated_string AK Userland \ Meta Ports Ladybird Tests Kernel) $ perl -pie 's/\bDeprecatedString\b/ByteString/g; s/deprecated_string/byte_string/g' $xs $ clang-format --style=file -i \ $(git diff --name-only | grep \.cpp\|\.h) $ gn format $(git ls-files '*.gn' '*.gni')
2023-12-16 17:49:34 +03:30
ByteString GetCalleeAndThisFromEnvironment::to_byte_string_impl(Bytecode::Executable const& executable) const
LibJS: Move all bytecode instruction implementations to Interpreter.cpp This allows aggressive inlining without LTO.
2023-09-27 10:10:00 +02:00
{
LibJS/Bytecode: Move to a new bytecode format This patch moves us away from the accumulator-based bytecode format to one with explicit source and destination registers. The new format has multiple benefits: - ~25% faster on the Kraken and Octane benchmarks :^) - Fewer instructions to accomplish the same thing - Much easier for humans to read(!) Because this change requires a fundamental shift in how bytecode is generated, it is quite comprehensive. Main implementation mechanism: generate_bytecode() virtual function now takes an optional "preferred dst" operand, which allows callers to communicate when they have an operand that would be optimal for the result to go into. It also returns an optional "actual dst" operand, which is where the completion value (if any) of the AST node is stored after the node has "executed". One thing of note that's new: because instructions can now take locals as operands, this means we got rid of the GetLocal instruction. A side-effect of that is we have to think about the temporal deadzone (TDZ) a bit differently for locals (GetLocal would previously check for empty values and interpret that as a TDZ access and throw). We now insert special ThrowIfTDZ instructions in places where a local access may be in the TDZ, to maintain the correct behavior. There are a number of progressions and regressions from this test: A number of async generator tests have been accidentally fixed while converting the implementation to the new bytecode format. It didn't seem useful to preserve bugs in the original code when converting it. Some "does eval() return the correct completion value" tests have regressed, in particular ones related to propagating the appropriate completion after control flow statements like continue and break. These are all fairly obscure issues, and I believe we can continue working on them separately. The net test262 result is a progression though. :^)
2024-02-04 08:00:54 +01:00
return ByteString::formatted("GetCalleeAndThisFromEnvironment {}, {} <- {}",
format_operand("callee"sv, m_callee, executable),
format_operand("this"sv, m_this_value, executable),
executable.identifier_table->get(m_identifier));
LibJS: Move all bytecode instruction implementations to Interpreter.cpp This allows aggressive inlining without LTO.
2023-09-27 10:10:00 +02:00
}
Everywhere: Rename {Deprecated => Byte}String This commit un-deprecates DeprecatedString, and repurposes it as a byte string. As the null state has already been removed, there are no other particularly hairy blockers in repurposing this type as a byte string (what it _really_ is). This commit is auto-generated: $ xs=$(ack -l \bDeprecatedString\b\|deprecated_string AK Userland \ Meta Ports Ladybird Tests Kernel) $ perl -pie 's/\bDeprecatedString\b/ByteString/g; s/deprecated_string/byte_string/g' $xs $ clang-format --style=file -i \ $(git diff --name-only | grep \.cpp\|\.h) $ gn format $(git ls-files '*.gn' '*.gni')
2023-12-16 17:49:34 +03:30
ByteString GetVariable::to_byte_string_impl(Bytecode::Executable const& executable) const
LibJS: Move all bytecode instruction implementations to Interpreter.cpp This allows aggressive inlining without LTO.
2023-09-27 10:10:00 +02:00
{
LibJS/Bytecode: Move to a new bytecode format This patch moves us away from the accumulator-based bytecode format to one with explicit source and destination registers. The new format has multiple benefits: - ~25% faster on the Kraken and Octane benchmarks :^) - Fewer instructions to accomplish the same thing - Much easier for humans to read(!) Because this change requires a fundamental shift in how bytecode is generated, it is quite comprehensive. Main implementation mechanism: generate_bytecode() virtual function now takes an optional "preferred dst" operand, which allows callers to communicate when they have an operand that would be optimal for the result to go into. It also returns an optional "actual dst" operand, which is where the completion value (if any) of the AST node is stored after the node has "executed". One thing of note that's new: because instructions can now take locals as operands, this means we got rid of the GetLocal instruction. A side-effect of that is we have to think about the temporal deadzone (TDZ) a bit differently for locals (GetLocal would previously check for empty values and interpret that as a TDZ access and throw). We now insert special ThrowIfTDZ instructions in places where a local access may be in the TDZ, to maintain the correct behavior. There are a number of progressions and regressions from this test: A number of async generator tests have been accidentally fixed while converting the implementation to the new bytecode format. It didn't seem useful to preserve bugs in the original code when converting it. Some "does eval() return the correct completion value" tests have regressed, in particular ones related to propagating the appropriate completion after control flow statements like continue and break. These are all fairly obscure issues, and I believe we can continue working on them separately. The net test262 result is a progression though. :^)
2024-02-04 08:00:54 +01:00
return ByteString::formatted("GetVariable {}, {}",
format_operand("dst"sv, dst(), executable),
executable.identifier_table->get(m_identifier));
LibJS: Move all bytecode instruction implementations to Interpreter.cpp This allows aggressive inlining without LTO.
2023-09-27 10:10:00 +02:00
}
Everywhere: Rename {Deprecated => Byte}String This commit un-deprecates DeprecatedString, and repurposes it as a byte string. As the null state has already been removed, there are no other particularly hairy blockers in repurposing this type as a byte string (what it _really_ is). This commit is auto-generated: $ xs=$(ack -l \bDeprecatedString\b\|deprecated_string AK Userland \ Meta Ports Ladybird Tests Kernel) $ perl -pie 's/\bDeprecatedString\b/ByteString/g; s/deprecated_string/byte_string/g' $xs $ clang-format --style=file -i \ $(git diff --name-only | grep \.cpp\|\.h) $ gn format $(git ls-files '*.gn' '*.gni')
2023-12-16 17:49:34 +03:30
ByteString GetGlobal::to_byte_string_impl(Bytecode::Executable const& executable) const
LibJS: Move all bytecode instruction implementations to Interpreter.cpp This allows aggressive inlining without LTO.
2023-09-27 10:10:00 +02:00
{
LibJS/Bytecode: Move to a new bytecode format This patch moves us away from the accumulator-based bytecode format to one with explicit source and destination registers. The new format has multiple benefits: - ~25% faster on the Kraken and Octane benchmarks :^) - Fewer instructions to accomplish the same thing - Much easier for humans to read(!) Because this change requires a fundamental shift in how bytecode is generated, it is quite comprehensive. Main implementation mechanism: generate_bytecode() virtual function now takes an optional "preferred dst" operand, which allows callers to communicate when they have an operand that would be optimal for the result to go into. It also returns an optional "actual dst" operand, which is where the completion value (if any) of the AST node is stored after the node has "executed". One thing of note that's new: because instructions can now take locals as operands, this means we got rid of the GetLocal instruction. A side-effect of that is we have to think about the temporal deadzone (TDZ) a bit differently for locals (GetLocal would previously check for empty values and interpret that as a TDZ access and throw). We now insert special ThrowIfTDZ instructions in places where a local access may be in the TDZ, to maintain the correct behavior. There are a number of progressions and regressions from this test: A number of async generator tests have been accidentally fixed while converting the implementation to the new bytecode format. It didn't seem useful to preserve bugs in the original code when converting it. Some "does eval() return the correct completion value" tests have regressed, in particular ones related to propagating the appropriate completion after control flow statements like continue and break. These are all fairly obscure issues, and I believe we can continue working on them separately. The net test262 result is a progression though. :^)
2024-02-04 08:00:54 +01:00
return ByteString::formatted("GetGlobal {}, {}", format_operand("dst"sv, dst(), executable),
executable.identifier_table->get(m_identifier));
LibJS: Move all bytecode instruction implementations to Interpreter.cpp This allows aggressive inlining without LTO.
2023-09-27 10:10:00 +02:00
}
Everywhere: Rename {Deprecated => Byte}String This commit un-deprecates DeprecatedString, and repurposes it as a byte string. As the null state has already been removed, there are no other particularly hairy blockers in repurposing this type as a byte string (what it _really_ is). This commit is auto-generated: $ xs=$(ack -l \bDeprecatedString\b\|deprecated_string AK Userland \ Meta Ports Ladybird Tests Kernel) $ perl -pie 's/\bDeprecatedString\b/ByteString/g; s/deprecated_string/byte_string/g' $xs $ clang-format --style=file -i \ $(git diff --name-only | grep \.cpp\|\.h) $ gn format $(git ls-files '*.gn' '*.gni')
2023-12-16 17:49:34 +03:30
ByteString DeleteVariable::to_byte_string_impl(Bytecode::Executable const& executable) const
LibJS: Move all bytecode instruction implementations to Interpreter.cpp This allows aggressive inlining without LTO.
2023-09-27 10:10:00 +02:00
{
LibJS/Bytecode: Make IdentifierTableIndex a 32-bit index This makes a bunch of instructions smaller.
2024-05-06 10:12:02 +02:00
return ByteString::formatted("DeleteVariable {}", executable.identifier_table->get(m_identifier));
LibJS: Move all bytecode instruction implementations to Interpreter.cpp This allows aggressive inlining without LTO.
2023-09-27 10:10:00 +02:00
}
Everywhere: Rename {Deprecated => Byte}String This commit un-deprecates DeprecatedString, and repurposes it as a byte string. As the null state has already been removed, there are no other particularly hairy blockers in repurposing this type as a byte string (what it _really_ is). This commit is auto-generated: $ xs=$(ack -l \bDeprecatedString\b\|deprecated_string AK Userland \ Meta Ports Ladybird Tests Kernel) $ perl -pie 's/\bDeprecatedString\b/ByteString/g; s/deprecated_string/byte_string/g' $xs $ clang-format --style=file -i \ $(git diff --name-only | grep \.cpp\|\.h) $ gn format $(git ls-files '*.gn' '*.gni')
2023-12-16 17:49:34 +03:30
ByteString CreateLexicalEnvironment::to_byte_string_impl(Bytecode::Executable const&) const
LibJS: Move all bytecode instruction implementations to Interpreter.cpp This allows aggressive inlining without LTO.
2023-09-27 10:10:00 +02:00
{
return "CreateLexicalEnvironment"sv;
}
Everywhere: Rename {Deprecated => Byte}String This commit un-deprecates DeprecatedString, and repurposes it as a byte string. As the null state has already been removed, there are no other particularly hairy blockers in repurposing this type as a byte string (what it _really_ is). This commit is auto-generated: $ xs=$(ack -l \bDeprecatedString\b\|deprecated_string AK Userland \ Meta Ports Ladybird Tests Kernel) $ perl -pie 's/\bDeprecatedString\b/ByteString/g; s/deprecated_string/byte_string/g' $xs $ clang-format --style=file -i \ $(git diff --name-only | grep \.cpp\|\.h) $ gn format $(git ls-files '*.gn' '*.gni')
2023-12-16 17:49:34 +03:30
ByteString CreateVariable::to_byte_string_impl(Bytecode::Executable const& executable) const
LibJS: Move all bytecode instruction implementations to Interpreter.cpp This allows aggressive inlining without LTO.
2023-09-27 10:10:00 +02:00
{
auto mode_string = m_mode == EnvironmentMode::Lexical ? "Lexical" : "Variable";
LibJS/Bytecode: Make IdentifierTableIndex a 32-bit index This makes a bunch of instructions smaller.
2024-05-06 10:12:02 +02:00
return ByteString::formatted("CreateVariable env:{} immutable:{} global:{} {}", mode_string, m_is_immutable, m_is_global, executable.identifier_table->get(m_identifier));
LibJS: Move all bytecode instruction implementations to Interpreter.cpp This allows aggressive inlining without LTO.
2023-09-27 10:10:00 +02:00
}
LibJS/Bytecode: Move to a new bytecode format This patch moves us away from the accumulator-based bytecode format to one with explicit source and destination registers. The new format has multiple benefits: - ~25% faster on the Kraken and Octane benchmarks :^) - Fewer instructions to accomplish the same thing - Much easier for humans to read(!) Because this change requires a fundamental shift in how bytecode is generated, it is quite comprehensive. Main implementation mechanism: generate_bytecode() virtual function now takes an optional "preferred dst" operand, which allows callers to communicate when they have an operand that would be optimal for the result to go into. It also returns an optional "actual dst" operand, which is where the completion value (if any) of the AST node is stored after the node has "executed". One thing of note that's new: because instructions can now take locals as operands, this means we got rid of the GetLocal instruction. A side-effect of that is we have to think about the temporal deadzone (TDZ) a bit differently for locals (GetLocal would previously check for empty values and interpret that as a TDZ access and throw). We now insert special ThrowIfTDZ instructions in places where a local access may be in the TDZ, to maintain the correct behavior. There are a number of progressions and regressions from this test: A number of async generator tests have been accidentally fixed while converting the implementation to the new bytecode format. It didn't seem useful to preserve bugs in the original code when converting it. Some "does eval() return the correct completion value" tests have regressed, in particular ones related to propagating the appropriate completion after control flow statements like continue and break. These are all fairly obscure issues, and I believe we can continue working on them separately. The net test262 result is a progression though. :^)
2024-02-04 08:00:54 +01:00
ByteString EnterObjectEnvironment::to_byte_string_impl(Executable const& executable) const
LibJS: Move all bytecode instruction implementations to Interpreter.cpp This allows aggressive inlining without LTO.
2023-09-27 10:10:00 +02:00
{
LibJS/Bytecode: Move to a new bytecode format This patch moves us away from the accumulator-based bytecode format to one with explicit source and destination registers. The new format has multiple benefits: - ~25% faster on the Kraken and Octane benchmarks :^) - Fewer instructions to accomplish the same thing - Much easier for humans to read(!) Because this change requires a fundamental shift in how bytecode is generated, it is quite comprehensive. Main implementation mechanism: generate_bytecode() virtual function now takes an optional "preferred dst" operand, which allows callers to communicate when they have an operand that would be optimal for the result to go into. It also returns an optional "actual dst" operand, which is where the completion value (if any) of the AST node is stored after the node has "executed". One thing of note that's new: because instructions can now take locals as operands, this means we got rid of the GetLocal instruction. A side-effect of that is we have to think about the temporal deadzone (TDZ) a bit differently for locals (GetLocal would previously check for empty values and interpret that as a TDZ access and throw). We now insert special ThrowIfTDZ instructions in places where a local access may be in the TDZ, to maintain the correct behavior. There are a number of progressions and regressions from this test: A number of async generator tests have been accidentally fixed while converting the implementation to the new bytecode format. It didn't seem useful to preserve bugs in the original code when converting it. Some "does eval() return the correct completion value" tests have regressed, in particular ones related to propagating the appropriate completion after control flow statements like continue and break. These are all fairly obscure issues, and I believe we can continue working on them separately. The net test262 result is a progression though. :^)
2024-02-04 08:00:54 +01:00
return ByteString::formatted("EnterObjectEnvironment {}",
format_operand("object"sv, m_object, executable));
LibJS: Move all bytecode instruction implementations to Interpreter.cpp This allows aggressive inlining without LTO.
2023-09-27 10:10:00 +02:00
}
Everywhere: Rename {Deprecated => Byte}String This commit un-deprecates DeprecatedString, and repurposes it as a byte string. As the null state has already been removed, there are no other particularly hairy blockers in repurposing this type as a byte string (what it _really_ is). This commit is auto-generated: $ xs=$(ack -l \bDeprecatedString\b\|deprecated_string AK Userland \ Meta Ports Ladybird Tests Kernel) $ perl -pie 's/\bDeprecatedString\b/ByteString/g; s/deprecated_string/byte_string/g' $xs $ clang-format --style=file -i \ $(git diff --name-only | grep \.cpp\|\.h) $ gn format $(git ls-files '*.gn' '*.gni')
2023-12-16 17:49:34 +03:30
ByteString SetVariable::to_byte_string_impl(Bytecode::Executable const& executable) const
LibJS: Move all bytecode instruction implementations to Interpreter.cpp This allows aggressive inlining without LTO.
2023-09-27 10:10:00 +02:00
{
auto initialization_mode_name = m_initialization_mode == InitializationMode::Initialize ? "Initialize" : "Set";
auto mode_string = m_mode == EnvironmentMode::Lexical ? "Lexical" : "Variable";
LibJS/Bytecode: Move to a new bytecode format This patch moves us away from the accumulator-based bytecode format to one with explicit source and destination registers. The new format has multiple benefits: - ~25% faster on the Kraken and Octane benchmarks :^) - Fewer instructions to accomplish the same thing - Much easier for humans to read(!) Because this change requires a fundamental shift in how bytecode is generated, it is quite comprehensive. Main implementation mechanism: generate_bytecode() virtual function now takes an optional "preferred dst" operand, which allows callers to communicate when they have an operand that would be optimal for the result to go into. It also returns an optional "actual dst" operand, which is where the completion value (if any) of the AST node is stored after the node has "executed". One thing of note that's new: because instructions can now take locals as operands, this means we got rid of the GetLocal instruction. A side-effect of that is we have to think about the temporal deadzone (TDZ) a bit differently for locals (GetLocal would previously check for empty values and interpret that as a TDZ access and throw). We now insert special ThrowIfTDZ instructions in places where a local access may be in the TDZ, to maintain the correct behavior. There are a number of progressions and regressions from this test: A number of async generator tests have been accidentally fixed while converting the implementation to the new bytecode format. It didn't seem useful to preserve bugs in the original code when converting it. Some "does eval() return the correct completion value" tests have regressed, in particular ones related to propagating the appropriate completion after control flow statements like continue and break. These are all fairly obscure issues, and I believe we can continue working on them separately. The net test262 result is a progression though. :^)
2024-02-04 08:00:54 +01:00
return ByteString::formatted("SetVariable {}, {}, env:{} init:{}",
executable.identifier_table->get(m_identifier),
format_operand("src"sv, src(), executable),
mode_string, initialization_mode_name);
LibJS: Move all bytecode instruction implementations to Interpreter.cpp This allows aggressive inlining without LTO.
2023-09-27 10:10:00 +02:00
}
LibJS/Bytecode: Move to a new bytecode format This patch moves us away from the accumulator-based bytecode format to one with explicit source and destination registers. The new format has multiple benefits: - ~25% faster on the Kraken and Octane benchmarks :^) - Fewer instructions to accomplish the same thing - Much easier for humans to read(!) Because this change requires a fundamental shift in how bytecode is generated, it is quite comprehensive. Main implementation mechanism: generate_bytecode() virtual function now takes an optional "preferred dst" operand, which allows callers to communicate when they have an operand that would be optimal for the result to go into. It also returns an optional "actual dst" operand, which is where the completion value (if any) of the AST node is stored after the node has "executed". One thing of note that's new: because instructions can now take locals as operands, this means we got rid of the GetLocal instruction. A side-effect of that is we have to think about the temporal deadzone (TDZ) a bit differently for locals (GetLocal would previously check for empty values and interpret that as a TDZ access and throw). We now insert special ThrowIfTDZ instructions in places where a local access may be in the TDZ, to maintain the correct behavior. There are a number of progressions and regressions from this test: A number of async generator tests have been accidentally fixed while converting the implementation to the new bytecode format. It didn't seem useful to preserve bugs in the original code when converting it. Some "does eval() return the correct completion value" tests have regressed, in particular ones related to propagating the appropriate completion after control flow statements like continue and break. These are all fairly obscure issues, and I believe we can continue working on them separately. The net test262 result is a progression though. :^)
2024-02-04 08:00:54 +01:00
ByteString SetLocal::to_byte_string_impl(Bytecode::Executable const& executable) const
LibJS: Move all bytecode instruction implementations to Interpreter.cpp This allows aggressive inlining without LTO.
2023-09-27 10:10:00 +02:00
{
LibJS/Bytecode: Move to a new bytecode format This patch moves us away from the accumulator-based bytecode format to one with explicit source and destination registers. The new format has multiple benefits: - ~25% faster on the Kraken and Octane benchmarks :^) - Fewer instructions to accomplish the same thing - Much easier for humans to read(!) Because this change requires a fundamental shift in how bytecode is generated, it is quite comprehensive. Main implementation mechanism: generate_bytecode() virtual function now takes an optional "preferred dst" operand, which allows callers to communicate when they have an operand that would be optimal for the result to go into. It also returns an optional "actual dst" operand, which is where the completion value (if any) of the AST node is stored after the node has "executed". One thing of note that's new: because instructions can now take locals as operands, this means we got rid of the GetLocal instruction. A side-effect of that is we have to think about the temporal deadzone (TDZ) a bit differently for locals (GetLocal would previously check for empty values and interpret that as a TDZ access and throw). We now insert special ThrowIfTDZ instructions in places where a local access may be in the TDZ, to maintain the correct behavior. There are a number of progressions and regressions from this test: A number of async generator tests have been accidentally fixed while converting the implementation to the new bytecode format. It didn't seem useful to preserve bugs in the original code when converting it. Some "does eval() return the correct completion value" tests have regressed, in particular ones related to propagating the appropriate completion after control flow statements like continue and break. These are all fairly obscure issues, and I believe we can continue working on them separately. The net test262 result is a progression though. :^)
2024-02-04 08:00:54 +01:00
return ByteString::formatted("SetLocal {}, {}",
format_operand("dst"sv, dst(), executable),
format_operand("src"sv, src(), executable));
LibJS: Move all bytecode instruction implementations to Interpreter.cpp This allows aggressive inlining without LTO.
2023-09-27 10:10:00 +02:00
}
static StringView property_kind_to_string(PropertyKind kind)
{
switch (kind) {
case PropertyKind::Getter:
return "getter"sv;
case PropertyKind::Setter:
return "setter"sv;
case PropertyKind::KeyValue:
return "key-value"sv;
case PropertyKind::DirectKeyValue:
return "direct-key-value"sv;
case PropertyKind::Spread:
return "spread"sv;
case PropertyKind::ProtoSetter:
return "proto-setter"sv;
}
VERIFY_NOT_REACHED();
}
Everywhere: Rename {Deprecated => Byte}String This commit un-deprecates DeprecatedString, and repurposes it as a byte string. As the null state has already been removed, there are no other particularly hairy blockers in repurposing this type as a byte string (what it _really_ is). This commit is auto-generated: $ xs=$(ack -l \bDeprecatedString\b\|deprecated_string AK Userland \ Meta Ports Ladybird Tests Kernel) $ perl -pie 's/\bDeprecatedString\b/ByteString/g; s/deprecated_string/byte_string/g' $xs $ clang-format --style=file -i \ $(git diff --name-only | grep \.cpp\|\.h) $ gn format $(git ls-files '*.gn' '*.gni')
2023-12-16 17:49:34 +03:30
ByteString PutById::to_byte_string_impl(Bytecode::Executable const& executable) const
LibJS: Move all bytecode instruction implementations to Interpreter.cpp This allows aggressive inlining without LTO.
2023-09-27 10:10:00 +02:00
{
auto kind = property_kind_to_string(m_kind);
LibJS/Bytecode: Move to a new bytecode format This patch moves us away from the accumulator-based bytecode format to one with explicit source and destination registers. The new format has multiple benefits: - ~25% faster on the Kraken and Octane benchmarks :^) - Fewer instructions to accomplish the same thing - Much easier for humans to read(!) Because this change requires a fundamental shift in how bytecode is generated, it is quite comprehensive. Main implementation mechanism: generate_bytecode() virtual function now takes an optional "preferred dst" operand, which allows callers to communicate when they have an operand that would be optimal for the result to go into. It also returns an optional "actual dst" operand, which is where the completion value (if any) of the AST node is stored after the node has "executed". One thing of note that's new: because instructions can now take locals as operands, this means we got rid of the GetLocal instruction. A side-effect of that is we have to think about the temporal deadzone (TDZ) a bit differently for locals (GetLocal would previously check for empty values and interpret that as a TDZ access and throw). We now insert special ThrowIfTDZ instructions in places where a local access may be in the TDZ, to maintain the correct behavior. There are a number of progressions and regressions from this test: A number of async generator tests have been accidentally fixed while converting the implementation to the new bytecode format. It didn't seem useful to preserve bugs in the original code when converting it. Some "does eval() return the correct completion value" tests have regressed, in particular ones related to propagating the appropriate completion after control flow statements like continue and break. These are all fairly obscure issues, and I believe we can continue working on them separately. The net test262 result is a progression though. :^)
2024-02-04 08:00:54 +01:00
return ByteString::formatted("PutById {}, {}, {}, kind:{}",
format_operand("base"sv, m_base, executable),
executable.identifier_table->get(m_property),
format_operand("src"sv, m_src, executable),
kind);
LibJS: Move all bytecode instruction implementations to Interpreter.cpp This allows aggressive inlining without LTO.
2023-09-27 10:10:00 +02:00
}
Everywhere: Rename {Deprecated => Byte}String This commit un-deprecates DeprecatedString, and repurposes it as a byte string. As the null state has already been removed, there are no other particularly hairy blockers in repurposing this type as a byte string (what it _really_ is). This commit is auto-generated: $ xs=$(ack -l \bDeprecatedString\b\|deprecated_string AK Userland \ Meta Ports Ladybird Tests Kernel) $ perl -pie 's/\bDeprecatedString\b/ByteString/g; s/deprecated_string/byte_string/g' $xs $ clang-format --style=file -i \ $(git diff --name-only | grep \.cpp\|\.h) $ gn format $(git ls-files '*.gn' '*.gni')
2023-12-16 17:49:34 +03:30
ByteString PutByIdWithThis::to_byte_string_impl(Bytecode::Executable const& executable) const
LibJS: Move all bytecode instruction implementations to Interpreter.cpp This allows aggressive inlining without LTO.
2023-09-27 10:10:00 +02:00
{
auto kind = property_kind_to_string(m_kind);
LibJS/Bytecode: Move to a new bytecode format This patch moves us away from the accumulator-based bytecode format to one with explicit source and destination registers. The new format has multiple benefits: - ~25% faster on the Kraken and Octane benchmarks :^) - Fewer instructions to accomplish the same thing - Much easier for humans to read(!) Because this change requires a fundamental shift in how bytecode is generated, it is quite comprehensive. Main implementation mechanism: generate_bytecode() virtual function now takes an optional "preferred dst" operand, which allows callers to communicate when they have an operand that would be optimal for the result to go into. It also returns an optional "actual dst" operand, which is where the completion value (if any) of the AST node is stored after the node has "executed". One thing of note that's new: because instructions can now take locals as operands, this means we got rid of the GetLocal instruction. A side-effect of that is we have to think about the temporal deadzone (TDZ) a bit differently for locals (GetLocal would previously check for empty values and interpret that as a TDZ access and throw). We now insert special ThrowIfTDZ instructions in places where a local access may be in the TDZ, to maintain the correct behavior. There are a number of progressions and regressions from this test: A number of async generator tests have been accidentally fixed while converting the implementation to the new bytecode format. It didn't seem useful to preserve bugs in the original code when converting it. Some "does eval() return the correct completion value" tests have regressed, in particular ones related to propagating the appropriate completion after control flow statements like continue and break. These are all fairly obscure issues, and I believe we can continue working on them separately. The net test262 result is a progression though. :^)
2024-02-04 08:00:54 +01:00
return ByteString::formatted("PutByIdWithThis {}, {}, {}, {}, kind:{}",
format_operand("base"sv, m_base, executable),
executable.identifier_table->get(m_property),
format_operand("src"sv, m_src, executable),
format_operand("this"sv, m_this_value, executable),
kind);
LibJS: Move all bytecode instruction implementations to Interpreter.cpp This allows aggressive inlining without LTO.
2023-09-27 10:10:00 +02:00
}
Everywhere: Rename {Deprecated => Byte}String This commit un-deprecates DeprecatedString, and repurposes it as a byte string. As the null state has already been removed, there are no other particularly hairy blockers in repurposing this type as a byte string (what it _really_ is). This commit is auto-generated: $ xs=$(ack -l \bDeprecatedString\b\|deprecated_string AK Userland \ Meta Ports Ladybird Tests Kernel) $ perl -pie 's/\bDeprecatedString\b/ByteString/g; s/deprecated_string/byte_string/g' $xs $ clang-format --style=file -i \ $(git diff --name-only | grep \.cpp\|\.h) $ gn format $(git ls-files '*.gn' '*.gni')
2023-12-16 17:49:34 +03:30
ByteString PutPrivateById::to_byte_string_impl(Bytecode::Executable const& executable) const
LibJS: Move all bytecode instruction implementations to Interpreter.cpp This allows aggressive inlining without LTO.
2023-09-27 10:10:00 +02:00
{
auto kind = property_kind_to_string(m_kind);
LibJS/Bytecode: Move to a new bytecode format This patch moves us away from the accumulator-based bytecode format to one with explicit source and destination registers. The new format has multiple benefits: - ~25% faster on the Kraken and Octane benchmarks :^) - Fewer instructions to accomplish the same thing - Much easier for humans to read(!) Because this change requires a fundamental shift in how bytecode is generated, it is quite comprehensive. Main implementation mechanism: generate_bytecode() virtual function now takes an optional "preferred dst" operand, which allows callers to communicate when they have an operand that would be optimal for the result to go into. It also returns an optional "actual dst" operand, which is where the completion value (if any) of the AST node is stored after the node has "executed". One thing of note that's new: because instructions can now take locals as operands, this means we got rid of the GetLocal instruction. A side-effect of that is we have to think about the temporal deadzone (TDZ) a bit differently for locals (GetLocal would previously check for empty values and interpret that as a TDZ access and throw). We now insert special ThrowIfTDZ instructions in places where a local access may be in the TDZ, to maintain the correct behavior. There are a number of progressions and regressions from this test: A number of async generator tests have been accidentally fixed while converting the implementation to the new bytecode format. It didn't seem useful to preserve bugs in the original code when converting it. Some "does eval() return the correct completion value" tests have regressed, in particular ones related to propagating the appropriate completion after control flow statements like continue and break. These are all fairly obscure issues, and I believe we can continue working on them separately. The net test262 result is a progression though. :^)
2024-02-04 08:00:54 +01:00
return ByteString::formatted(
"PutPrivateById {}, {}, {}, kind:{} ",
format_operand("base"sv, m_base, executable),
executable.identifier_table->get(m_property),
format_operand("src"sv, m_src, executable),
kind);
LibJS: Move all bytecode instruction implementations to Interpreter.cpp This allows aggressive inlining without LTO.
2023-09-27 10:10:00 +02:00
}
Everywhere: Rename {Deprecated => Byte}String This commit un-deprecates DeprecatedString, and repurposes it as a byte string. As the null state has already been removed, there are no other particularly hairy blockers in repurposing this type as a byte string (what it _really_ is). This commit is auto-generated: $ xs=$(ack -l \bDeprecatedString\b\|deprecated_string AK Userland \ Meta Ports Ladybird Tests Kernel) $ perl -pie 's/\bDeprecatedString\b/ByteString/g; s/deprecated_string/byte_string/g' $xs $ clang-format --style=file -i \ $(git diff --name-only | grep \.cpp\|\.h) $ gn format $(git ls-files '*.gn' '*.gni')
2023-12-16 17:49:34 +03:30
ByteString GetById::to_byte_string_impl(Bytecode::Executable const& executable) const
LibJS: Move all bytecode instruction implementations to Interpreter.cpp This allows aggressive inlining without LTO.
2023-09-27 10:10:00 +02:00
{
LibJS/Bytecode: Move to a new bytecode format This patch moves us away from the accumulator-based bytecode format to one with explicit source and destination registers. The new format has multiple benefits: - ~25% faster on the Kraken and Octane benchmarks :^) - Fewer instructions to accomplish the same thing - Much easier for humans to read(!) Because this change requires a fundamental shift in how bytecode is generated, it is quite comprehensive. Main implementation mechanism: generate_bytecode() virtual function now takes an optional "preferred dst" operand, which allows callers to communicate when they have an operand that would be optimal for the result to go into. It also returns an optional "actual dst" operand, which is where the completion value (if any) of the AST node is stored after the node has "executed". One thing of note that's new: because instructions can now take locals as operands, this means we got rid of the GetLocal instruction. A side-effect of that is we have to think about the temporal deadzone (TDZ) a bit differently for locals (GetLocal would previously check for empty values and interpret that as a TDZ access and throw). We now insert special ThrowIfTDZ instructions in places where a local access may be in the TDZ, to maintain the correct behavior. There are a number of progressions and regressions from this test: A number of async generator tests have been accidentally fixed while converting the implementation to the new bytecode format. It didn't seem useful to preserve bugs in the original code when converting it. Some "does eval() return the correct completion value" tests have regressed, in particular ones related to propagating the appropriate completion after control flow statements like continue and break. These are all fairly obscure issues, and I believe we can continue working on them separately. The net test262 result is a progression though. :^)
2024-02-04 08:00:54 +01:00
return ByteString::formatted("GetById {}, {}, {}",
format_operand("dst"sv, m_dst, executable),
format_operand("base"sv, m_base, executable),
executable.identifier_table->get(m_property));
LibJS: Move all bytecode instruction implementations to Interpreter.cpp This allows aggressive inlining without LTO.
2023-09-27 10:10:00 +02:00
}
Everywhere: Rename {Deprecated => Byte}String This commit un-deprecates DeprecatedString, and repurposes it as a byte string. As the null state has already been removed, there are no other particularly hairy blockers in repurposing this type as a byte string (what it _really_ is). This commit is auto-generated: $ xs=$(ack -l \bDeprecatedString\b\|deprecated_string AK Userland \ Meta Ports Ladybird Tests Kernel) $ perl -pie 's/\bDeprecatedString\b/ByteString/g; s/deprecated_string/byte_string/g' $xs $ clang-format --style=file -i \ $(git diff --name-only | grep \.cpp\|\.h) $ gn format $(git ls-files '*.gn' '*.gni')
2023-12-16 17:49:34 +03:30
ByteString GetByIdWithThis::to_byte_string_impl(Bytecode::Executable const& executable) const
LibJS: Move all bytecode instruction implementations to Interpreter.cpp This allows aggressive inlining without LTO.
2023-09-27 10:10:00 +02:00
{
LibJS/Bytecode: Move to a new bytecode format This patch moves us away from the accumulator-based bytecode format to one with explicit source and destination registers. The new format has multiple benefits: - ~25% faster on the Kraken and Octane benchmarks :^) - Fewer instructions to accomplish the same thing - Much easier for humans to read(!) Because this change requires a fundamental shift in how bytecode is generated, it is quite comprehensive. Main implementation mechanism: generate_bytecode() virtual function now takes an optional "preferred dst" operand, which allows callers to communicate when they have an operand that would be optimal for the result to go into. It also returns an optional "actual dst" operand, which is where the completion value (if any) of the AST node is stored after the node has "executed". One thing of note that's new: because instructions can now take locals as operands, this means we got rid of the GetLocal instruction. A side-effect of that is we have to think about the temporal deadzone (TDZ) a bit differently for locals (GetLocal would previously check for empty values and interpret that as a TDZ access and throw). We now insert special ThrowIfTDZ instructions in places where a local access may be in the TDZ, to maintain the correct behavior. There are a number of progressions and regressions from this test: A number of async generator tests have been accidentally fixed while converting the implementation to the new bytecode format. It didn't seem useful to preserve bugs in the original code when converting it. Some "does eval() return the correct completion value" tests have regressed, in particular ones related to propagating the appropriate completion after control flow statements like continue and break. These are all fairly obscure issues, and I believe we can continue working on them separately. The net test262 result is a progression though. :^)
2024-02-04 08:00:54 +01:00
return ByteString::formatted("GetByIdWithThis {}, {}, {}, {}",
format_operand("dst"sv, m_dst, executable),
format_operand("base"sv, m_base, executable),
executable.identifier_table->get(m_property),
format_operand("this"sv, m_this_value, executable));
LibJS: Move all bytecode instruction implementations to Interpreter.cpp This allows aggressive inlining without LTO.
2023-09-27 10:10:00 +02:00
}
Everywhere: Rename {Deprecated => Byte}String This commit un-deprecates DeprecatedString, and repurposes it as a byte string. As the null state has already been removed, there are no other particularly hairy blockers in repurposing this type as a byte string (what it _really_ is). This commit is auto-generated: $ xs=$(ack -l \bDeprecatedString\b\|deprecated_string AK Userland \ Meta Ports Ladybird Tests Kernel) $ perl -pie 's/\bDeprecatedString\b/ByteString/g; s/deprecated_string/byte_string/g' $xs $ clang-format --style=file -i \ $(git diff --name-only | grep \.cpp\|\.h) $ gn format $(git ls-files '*.gn' '*.gni')
2023-12-16 17:49:34 +03:30
ByteString GetPrivateById::to_byte_string_impl(Bytecode::Executable const& executable) const
LibJS: Move all bytecode instruction implementations to Interpreter.cpp This allows aggressive inlining without LTO.
2023-09-27 10:10:00 +02:00
{
LibJS/Bytecode: Move to a new bytecode format This patch moves us away from the accumulator-based bytecode format to one with explicit source and destination registers. The new format has multiple benefits: - ~25% faster on the Kraken and Octane benchmarks :^) - Fewer instructions to accomplish the same thing - Much easier for humans to read(!) Because this change requires a fundamental shift in how bytecode is generated, it is quite comprehensive. Main implementation mechanism: generate_bytecode() virtual function now takes an optional "preferred dst" operand, which allows callers to communicate when they have an operand that would be optimal for the result to go into. It also returns an optional "actual dst" operand, which is where the completion value (if any) of the AST node is stored after the node has "executed". One thing of note that's new: because instructions can now take locals as operands, this means we got rid of the GetLocal instruction. A side-effect of that is we have to think about the temporal deadzone (TDZ) a bit differently for locals (GetLocal would previously check for empty values and interpret that as a TDZ access and throw). We now insert special ThrowIfTDZ instructions in places where a local access may be in the TDZ, to maintain the correct behavior. There are a number of progressions and regressions from this test: A number of async generator tests have been accidentally fixed while converting the implementation to the new bytecode format. It didn't seem useful to preserve bugs in the original code when converting it. Some "does eval() return the correct completion value" tests have regressed, in particular ones related to propagating the appropriate completion after control flow statements like continue and break. These are all fairly obscure issues, and I believe we can continue working on them separately. The net test262 result is a progression though. :^)
2024-02-04 08:00:54 +01:00
return ByteString::formatted("GetPrivateById {}, {}, {}",
format_operand("dst"sv, m_dst, executable),
format_operand("base"sv, m_base, executable),
executable.identifier_table->get(m_property));
LibJS: Move all bytecode instruction implementations to Interpreter.cpp This allows aggressive inlining without LTO.
2023-09-27 10:10:00 +02:00
}
Everywhere: Rename {Deprecated => Byte}String This commit un-deprecates DeprecatedString, and repurposes it as a byte string. As the null state has already been removed, there are no other particularly hairy blockers in repurposing this type as a byte string (what it _really_ is). This commit is auto-generated: $ xs=$(ack -l \bDeprecatedString\b\|deprecated_string AK Userland \ Meta Ports Ladybird Tests Kernel) $ perl -pie 's/\bDeprecatedString\b/ByteString/g; s/deprecated_string/byte_string/g' $xs $ clang-format --style=file -i \ $(git diff --name-only | grep \.cpp\|\.h) $ gn format $(git ls-files '*.gn' '*.gni')
2023-12-16 17:49:34 +03:30
ByteString HasPrivateId::to_byte_string_impl(Bytecode::Executable const& executable) const
LibJS: Move all bytecode instruction implementations to Interpreter.cpp This allows aggressive inlining without LTO.
2023-09-27 10:10:00 +02:00
{
LibJS/Bytecode: Move to a new bytecode format This patch moves us away from the accumulator-based bytecode format to one with explicit source and destination registers. The new format has multiple benefits: - ~25% faster on the Kraken and Octane benchmarks :^) - Fewer instructions to accomplish the same thing - Much easier for humans to read(!) Because this change requires a fundamental shift in how bytecode is generated, it is quite comprehensive. Main implementation mechanism: generate_bytecode() virtual function now takes an optional "preferred dst" operand, which allows callers to communicate when they have an operand that would be optimal for the result to go into. It also returns an optional "actual dst" operand, which is where the completion value (if any) of the AST node is stored after the node has "executed". One thing of note that's new: because instructions can now take locals as operands, this means we got rid of the GetLocal instruction. A side-effect of that is we have to think about the temporal deadzone (TDZ) a bit differently for locals (GetLocal would previously check for empty values and interpret that as a TDZ access and throw). We now insert special ThrowIfTDZ instructions in places where a local access may be in the TDZ, to maintain the correct behavior. There are a number of progressions and regressions from this test: A number of async generator tests have been accidentally fixed while converting the implementation to the new bytecode format. It didn't seem useful to preserve bugs in the original code when converting it. Some "does eval() return the correct completion value" tests have regressed, in particular ones related to propagating the appropriate completion after control flow statements like continue and break. These are all fairly obscure issues, and I believe we can continue working on them separately. The net test262 result is a progression though. :^)
2024-02-04 08:00:54 +01:00
return ByteString::formatted("HasPrivateId {}, {}, {}",
format_operand("dst"sv, m_dst, executable),
format_operand("base"sv, m_base, executable),
executable.identifier_table->get(m_property));
LibJS: Move all bytecode instruction implementations to Interpreter.cpp This allows aggressive inlining without LTO.
2023-09-27 10:10:00 +02:00
}
Everywhere: Rename {Deprecated => Byte}String This commit un-deprecates DeprecatedString, and repurposes it as a byte string. As the null state has already been removed, there are no other particularly hairy blockers in repurposing this type as a byte string (what it _really_ is). This commit is auto-generated: $ xs=$(ack -l \bDeprecatedString\b\|deprecated_string AK Userland \ Meta Ports Ladybird Tests Kernel) $ perl -pie 's/\bDeprecatedString\b/ByteString/g; s/deprecated_string/byte_string/g' $xs $ clang-format --style=file -i \ $(git diff --name-only | grep \.cpp\|\.h) $ gn format $(git ls-files '*.gn' '*.gni')
2023-12-16 17:49:34 +03:30
ByteString DeleteById::to_byte_string_impl(Bytecode::Executable const& executable) const
LibJS: Move all bytecode instruction implementations to Interpreter.cpp This allows aggressive inlining without LTO.
2023-09-27 10:10:00 +02:00
{
LibJS/Bytecode: Move to a new bytecode format This patch moves us away from the accumulator-based bytecode format to one with explicit source and destination registers. The new format has multiple benefits: - ~25% faster on the Kraken and Octane benchmarks :^) - Fewer instructions to accomplish the same thing - Much easier for humans to read(!) Because this change requires a fundamental shift in how bytecode is generated, it is quite comprehensive. Main implementation mechanism: generate_bytecode() virtual function now takes an optional "preferred dst" operand, which allows callers to communicate when they have an operand that would be optimal for the result to go into. It also returns an optional "actual dst" operand, which is where the completion value (if any) of the AST node is stored after the node has "executed". One thing of note that's new: because instructions can now take locals as operands, this means we got rid of the GetLocal instruction. A side-effect of that is we have to think about the temporal deadzone (TDZ) a bit differently for locals (GetLocal would previously check for empty values and interpret that as a TDZ access and throw). We now insert special ThrowIfTDZ instructions in places where a local access may be in the TDZ, to maintain the correct behavior. There are a number of progressions and regressions from this test: A number of async generator tests have been accidentally fixed while converting the implementation to the new bytecode format. It didn't seem useful to preserve bugs in the original code when converting it. Some "does eval() return the correct completion value" tests have regressed, in particular ones related to propagating the appropriate completion after control flow statements like continue and break. These are all fairly obscure issues, and I believe we can continue working on them separately. The net test262 result is a progression though. :^)
2024-02-04 08:00:54 +01:00
return ByteString::formatted("DeleteById {}, {}, {}",
format_operand("dst"sv, m_dst, executable),
format_operand("base"sv, m_base, executable),
executable.identifier_table->get(m_property));
LibJS: Move all bytecode instruction implementations to Interpreter.cpp This allows aggressive inlining without LTO.
2023-09-27 10:10:00 +02:00
}
Everywhere: Rename {Deprecated => Byte}String This commit un-deprecates DeprecatedString, and repurposes it as a byte string. As the null state has already been removed, there are no other particularly hairy blockers in repurposing this type as a byte string (what it _really_ is). This commit is auto-generated: $ xs=$(ack -l \bDeprecatedString\b\|deprecated_string AK Userland \ Meta Ports Ladybird Tests Kernel) $ perl -pie 's/\bDeprecatedString\b/ByteString/g; s/deprecated_string/byte_string/g' $xs $ clang-format --style=file -i \ $(git diff --name-only | grep \.cpp\|\.h) $ gn format $(git ls-files '*.gn' '*.gni')
2023-12-16 17:49:34 +03:30
ByteString DeleteByIdWithThis::to_byte_string_impl(Bytecode::Executable const& executable) const
LibJS: Move all bytecode instruction implementations to Interpreter.cpp This allows aggressive inlining without LTO.
2023-09-27 10:10:00 +02:00
{
LibJS/Bytecode: Move to a new bytecode format This patch moves us away from the accumulator-based bytecode format to one with explicit source and destination registers. The new format has multiple benefits: - ~25% faster on the Kraken and Octane benchmarks :^) - Fewer instructions to accomplish the same thing - Much easier for humans to read(!) Because this change requires a fundamental shift in how bytecode is generated, it is quite comprehensive. Main implementation mechanism: generate_bytecode() virtual function now takes an optional "preferred dst" operand, which allows callers to communicate when they have an operand that would be optimal for the result to go into. It also returns an optional "actual dst" operand, which is where the completion value (if any) of the AST node is stored after the node has "executed". One thing of note that's new: because instructions can now take locals as operands, this means we got rid of the GetLocal instruction. A side-effect of that is we have to think about the temporal deadzone (TDZ) a bit differently for locals (GetLocal would previously check for empty values and interpret that as a TDZ access and throw). We now insert special ThrowIfTDZ instructions in places where a local access may be in the TDZ, to maintain the correct behavior. There are a number of progressions and regressions from this test: A number of async generator tests have been accidentally fixed while converting the implementation to the new bytecode format. It didn't seem useful to preserve bugs in the original code when converting it. Some "does eval() return the correct completion value" tests have regressed, in particular ones related to propagating the appropriate completion after control flow statements like continue and break. These are all fairly obscure issues, and I believe we can continue working on them separately. The net test262 result is a progression though. :^)
2024-02-04 08:00:54 +01:00
return ByteString::formatted("DeleteByIdWithThis {}, {}, {}, {}",
format_operand("dst"sv, m_dst, executable),
format_operand("base"sv, m_base, executable),
executable.identifier_table->get(m_property),
format_operand("this"sv, m_this_value, executable));
LibJS: Move all bytecode instruction implementations to Interpreter.cpp This allows aggressive inlining without LTO.
2023-09-27 10:10:00 +02:00
}
Everywhere: Rename {Deprecated => Byte}String This commit un-deprecates DeprecatedString, and repurposes it as a byte string. As the null state has already been removed, there are no other particularly hairy blockers in repurposing this type as a byte string (what it _really_ is). This commit is auto-generated: $ xs=$(ack -l \bDeprecatedString\b\|deprecated_string AK Userland \ Meta Ports Ladybird Tests Kernel) $ perl -pie 's/\bDeprecatedString\b/ByteString/g; s/deprecated_string/byte_string/g' $xs $ clang-format --style=file -i \ $(git diff --name-only | grep \.cpp\|\.h) $ gn format $(git ls-files '*.gn' '*.gni')
2023-12-16 17:49:34 +03:30
ByteString Jump::to_byte_string_impl(Bytecode::Executable const&) const
LibJS: Move all bytecode instruction implementations to Interpreter.cpp This allows aggressive inlining without LTO.
2023-09-27 10:10:00 +02:00
{
LibJS/Bytecode: Make each Jump instruction inherit Instruction directly Before this change, all JumpFoo instructions inherited from Jump, which forced the unconditional Jump to have an unusued "false target" member. Also, labels were unnecessarily wrapped in Optional<>. By defining each jump instruction separately, they all shrink in size, and all ambiguity is removed.
2024-05-05 11:52:14 +02:00
return ByteString::formatted("Jump {}", m_target);
LibJS: Move all bytecode instruction implementations to Interpreter.cpp This allows aggressive inlining without LTO.
2023-09-27 10:10:00 +02:00
}
LibJS/Bytecode: Move to a new bytecode format This patch moves us away from the accumulator-based bytecode format to one with explicit source and destination registers. The new format has multiple benefits: - ~25% faster on the Kraken and Octane benchmarks :^) - Fewer instructions to accomplish the same thing - Much easier for humans to read(!) Because this change requires a fundamental shift in how bytecode is generated, it is quite comprehensive. Main implementation mechanism: generate_bytecode() virtual function now takes an optional "preferred dst" operand, which allows callers to communicate when they have an operand that would be optimal for the result to go into. It also returns an optional "actual dst" operand, which is where the completion value (if any) of the AST node is stored after the node has "executed". One thing of note that's new: because instructions can now take locals as operands, this means we got rid of the GetLocal instruction. A side-effect of that is we have to think about the temporal deadzone (TDZ) a bit differently for locals (GetLocal would previously check for empty values and interpret that as a TDZ access and throw). We now insert special ThrowIfTDZ instructions in places where a local access may be in the TDZ, to maintain the correct behavior. There are a number of progressions and regressions from this test: A number of async generator tests have been accidentally fixed while converting the implementation to the new bytecode format. It didn't seem useful to preserve bugs in the original code when converting it. Some "does eval() return the correct completion value" tests have regressed, in particular ones related to propagating the appropriate completion after control flow statements like continue and break. These are all fairly obscure issues, and I believe we can continue working on them separately. The net test262 result is a progression though. :^)
2024-02-04 08:00:54 +01:00
ByteString JumpIf::to_byte_string_impl(Bytecode::Executable const& executable) const
LibJS: Move all bytecode instruction implementations to Interpreter.cpp This allows aggressive inlining without LTO.
2023-09-27 10:10:00 +02:00
{
LibJS/Bytecode: Move to a new bytecode format This patch moves us away from the accumulator-based bytecode format to one with explicit source and destination registers. The new format has multiple benefits: - ~25% faster on the Kraken and Octane benchmarks :^) - Fewer instructions to accomplish the same thing - Much easier for humans to read(!) Because this change requires a fundamental shift in how bytecode is generated, it is quite comprehensive. Main implementation mechanism: generate_bytecode() virtual function now takes an optional "preferred dst" operand, which allows callers to communicate when they have an operand that would be optimal for the result to go into. It also returns an optional "actual dst" operand, which is where the completion value (if any) of the AST node is stored after the node has "executed". One thing of note that's new: because instructions can now take locals as operands, this means we got rid of the GetLocal instruction. A side-effect of that is we have to think about the temporal deadzone (TDZ) a bit differently for locals (GetLocal would previously check for empty values and interpret that as a TDZ access and throw). We now insert special ThrowIfTDZ instructions in places where a local access may be in the TDZ, to maintain the correct behavior. There are a number of progressions and regressions from this test: A number of async generator tests have been accidentally fixed while converting the implementation to the new bytecode format. It didn't seem useful to preserve bugs in the original code when converting it. Some "does eval() return the correct completion value" tests have regressed, in particular ones related to propagating the appropriate completion after control flow statements like continue and break. These are all fairly obscure issues, and I believe we can continue working on them separately. The net test262 result is a progression though. :^)
2024-02-04 08:00:54 +01:00
return ByteString::formatted("JumpIf {}, \033[32mtrue\033[0m:{} \033[32mfalse\033[0m:{}",
format_operand("condition"sv, m_condition, executable),
LibJS/Bytecode: Make each Jump instruction inherit Instruction directly Before this change, all JumpFoo instructions inherited from Jump, which forced the unconditional Jump to have an unusued "false target" member. Also, labels were unnecessarily wrapped in Optional<>. By defining each jump instruction separately, they all shrink in size, and all ambiguity is removed.
2024-05-05 11:52:14 +02:00
m_true_target,
m_false_target);
LibJS: Move all bytecode instruction implementations to Interpreter.cpp This allows aggressive inlining without LTO.
2023-09-27 10:10:00 +02:00
}
LibJS/Bytecode: Turn JumpIf condition,@a,@next into JumpTrue/JumpFalse If one of the jump targets is the very next block, we can convert the jump instruction into a smaller JumpTrue or JumpFalse.
2024-05-06 10:15:17 +02:00
ByteString JumpTrue::to_byte_string_impl(Bytecode::Executable const& executable) const
{
return ByteString::formatted("JumpTrue {}, {}",
format_operand("condition"sv, m_condition, executable),
m_target);
}
ByteString JumpFalse::to_byte_string_impl(Bytecode::Executable const& executable) const
{
return ByteString::formatted("JumpFalse {}, {}",
format_operand("condition"sv, m_condition, executable),
m_target);
}
LibJS/Bytecode: Move to a new bytecode format This patch moves us away from the accumulator-based bytecode format to one with explicit source and destination registers. The new format has multiple benefits: - ~25% faster on the Kraken and Octane benchmarks :^) - Fewer instructions to accomplish the same thing - Much easier for humans to read(!) Because this change requires a fundamental shift in how bytecode is generated, it is quite comprehensive. Main implementation mechanism: generate_bytecode() virtual function now takes an optional "preferred dst" operand, which allows callers to communicate when they have an operand that would be optimal for the result to go into. It also returns an optional "actual dst" operand, which is where the completion value (if any) of the AST node is stored after the node has "executed". One thing of note that's new: because instructions can now take locals as operands, this means we got rid of the GetLocal instruction. A side-effect of that is we have to think about the temporal deadzone (TDZ) a bit differently for locals (GetLocal would previously check for empty values and interpret that as a TDZ access and throw). We now insert special ThrowIfTDZ instructions in places where a local access may be in the TDZ, to maintain the correct behavior. There are a number of progressions and regressions from this test: A number of async generator tests have been accidentally fixed while converting the implementation to the new bytecode format. It didn't seem useful to preserve bugs in the original code when converting it. Some "does eval() return the correct completion value" tests have regressed, in particular ones related to propagating the appropriate completion after control flow statements like continue and break. These are all fairly obscure issues, and I believe we can continue working on them separately. The net test262 result is a progression though. :^)
2024-02-04 08:00:54 +01:00
ByteString JumpNullish::to_byte_string_impl(Bytecode::Executable const& executable) const
LibJS: Move all bytecode instruction implementations to Interpreter.cpp This allows aggressive inlining without LTO.
2023-09-27 10:10:00 +02:00
{
LibJS/Bytecode: Move to a new bytecode format This patch moves us away from the accumulator-based bytecode format to one with explicit source and destination registers. The new format has multiple benefits: - ~25% faster on the Kraken and Octane benchmarks :^) - Fewer instructions to accomplish the same thing - Much easier for humans to read(!) Because this change requires a fundamental shift in how bytecode is generated, it is quite comprehensive. Main implementation mechanism: generate_bytecode() virtual function now takes an optional "preferred dst" operand, which allows callers to communicate when they have an operand that would be optimal for the result to go into. It also returns an optional "actual dst" operand, which is where the completion value (if any) of the AST node is stored after the node has "executed". One thing of note that's new: because instructions can now take locals as operands, this means we got rid of the GetLocal instruction. A side-effect of that is we have to think about the temporal deadzone (TDZ) a bit differently for locals (GetLocal would previously check for empty values and interpret that as a TDZ access and throw). We now insert special ThrowIfTDZ instructions in places where a local access may be in the TDZ, to maintain the correct behavior. There are a number of progressions and regressions from this test: A number of async generator tests have been accidentally fixed while converting the implementation to the new bytecode format. It didn't seem useful to preserve bugs in the original code when converting it. Some "does eval() return the correct completion value" tests have regressed, in particular ones related to propagating the appropriate completion after control flow statements like continue and break. These are all fairly obscure issues, and I believe we can continue working on them separately. The net test262 result is a progression though. :^)
2024-02-04 08:00:54 +01:00
return ByteString::formatted("JumpNullish {}, null:{} nonnull:{}",
format_operand("condition"sv, m_condition, executable),
LibJS/Bytecode: Make each Jump instruction inherit Instruction directly Before this change, all JumpFoo instructions inherited from Jump, which forced the unconditional Jump to have an unusued "false target" member. Also, labels were unnecessarily wrapped in Optional<>. By defining each jump instruction separately, they all shrink in size, and all ambiguity is removed.
2024-05-05 11:52:14 +02:00
m_true_target,
m_false_target);
LibJS: Move all bytecode instruction implementations to Interpreter.cpp This allows aggressive inlining without LTO.
2023-09-27 10:10:00 +02:00
}
LibJS/Bytecode: Move to a new bytecode format This patch moves us away from the accumulator-based bytecode format to one with explicit source and destination registers. The new format has multiple benefits: - ~25% faster on the Kraken and Octane benchmarks :^) - Fewer instructions to accomplish the same thing - Much easier for humans to read(!) Because this change requires a fundamental shift in how bytecode is generated, it is quite comprehensive. Main implementation mechanism: generate_bytecode() virtual function now takes an optional "preferred dst" operand, which allows callers to communicate when they have an operand that would be optimal for the result to go into. It also returns an optional "actual dst" operand, which is where the completion value (if any) of the AST node is stored after the node has "executed". One thing of note that's new: because instructions can now take locals as operands, this means we got rid of the GetLocal instruction. A side-effect of that is we have to think about the temporal deadzone (TDZ) a bit differently for locals (GetLocal would previously check for empty values and interpret that as a TDZ access and throw). We now insert special ThrowIfTDZ instructions in places where a local access may be in the TDZ, to maintain the correct behavior. There are a number of progressions and regressions from this test: A number of async generator tests have been accidentally fixed while converting the implementation to the new bytecode format. It didn't seem useful to preserve bugs in the original code when converting it. Some "does eval() return the correct completion value" tests have regressed, in particular ones related to propagating the appropriate completion after control flow statements like continue and break. These are all fairly obscure issues, and I believe we can continue working on them separately. The net test262 result is a progression though. :^)
2024-02-04 08:00:54 +01:00
ByteString JumpUndefined::to_byte_string_impl(Bytecode::Executable const& executable) const
LibJS: Move all bytecode instruction implementations to Interpreter.cpp This allows aggressive inlining without LTO.
2023-09-27 10:10:00 +02:00
{
LibJS/Bytecode: Move to a new bytecode format This patch moves us away from the accumulator-based bytecode format to one with explicit source and destination registers. The new format has multiple benefits: - ~25% faster on the Kraken and Octane benchmarks :^) - Fewer instructions to accomplish the same thing - Much easier for humans to read(!) Because this change requires a fundamental shift in how bytecode is generated, it is quite comprehensive. Main implementation mechanism: generate_bytecode() virtual function now takes an optional "preferred dst" operand, which allows callers to communicate when they have an operand that would be optimal for the result to go into. It also returns an optional "actual dst" operand, which is where the completion value (if any) of the AST node is stored after the node has "executed". One thing of note that's new: because instructions can now take locals as operands, this means we got rid of the GetLocal instruction. A side-effect of that is we have to think about the temporal deadzone (TDZ) a bit differently for locals (GetLocal would previously check for empty values and interpret that as a TDZ access and throw). We now insert special ThrowIfTDZ instructions in places where a local access may be in the TDZ, to maintain the correct behavior. There are a number of progressions and regressions from this test: A number of async generator tests have been accidentally fixed while converting the implementation to the new bytecode format. It didn't seem useful to preserve bugs in the original code when converting it. Some "does eval() return the correct completion value" tests have regressed, in particular ones related to propagating the appropriate completion after control flow statements like continue and break. These are all fairly obscure issues, and I believe we can continue working on them separately. The net test262 result is a progression though. :^)
2024-02-04 08:00:54 +01:00
return ByteString::formatted("JumpUndefined {}, undefined:{} defined:{}",
format_operand("condition"sv, m_condition, executable),
LibJS/Bytecode: Make each Jump instruction inherit Instruction directly Before this change, all JumpFoo instructions inherited from Jump, which forced the unconditional Jump to have an unusued "false target" member. Also, labels were unnecessarily wrapped in Optional<>. By defining each jump instruction separately, they all shrink in size, and all ambiguity is removed.
2024-05-05 11:52:14 +02:00
m_true_target,
m_false_target);
LibJS: Move all bytecode instruction implementations to Interpreter.cpp This allows aggressive inlining without LTO.
2023-09-27 10:10:00 +02:00
}
static StringView call_type_to_string(CallType type)
{
switch (type) {
case CallType::Call:
return ""sv;
case CallType::Construct:
return " (Construct)"sv;
case CallType::DirectEval:
return " (DirectEval)"sv;
}
VERIFY_NOT_REACHED();
}
Everywhere: Rename {Deprecated => Byte}String This commit un-deprecates DeprecatedString, and repurposes it as a byte string. As the null state has already been removed, there are no other particularly hairy blockers in repurposing this type as a byte string (what it _really_ is). This commit is auto-generated: $ xs=$(ack -l \bDeprecatedString\b\|deprecated_string AK Userland \ Meta Ports Ladybird Tests Kernel) $ perl -pie 's/\bDeprecatedString\b/ByteString/g; s/deprecated_string/byte_string/g' $xs $ clang-format --style=file -i \ $(git diff --name-only | grep \.cpp\|\.h) $ gn format $(git ls-files '*.gn' '*.gni')
2023-12-16 17:49:34 +03:30
ByteString Call::to_byte_string_impl(Bytecode::Executable const& executable) const
LibJS: Move all bytecode instruction implementations to Interpreter.cpp This allows aggressive inlining without LTO.
2023-09-27 10:10:00 +02:00
{
auto type = call_type_to_string(m_type);
LibJS/Bytecode: Put arguments directly in the Call instruction Instead of having Call refer to a range of VM registers, it now has a trailing list of argument operands as part of the instruction. This means we no longer have to shuffle every argument value into a register before making a call, making bytecode smaller & faster. :^)
2024-02-20 15:59:45 +01:00
StringBuilder builder;
builder.appendff("Call{} {}, {}, {}"sv,
type,
format_operand("dst"sv, m_dst, executable),
format_operand("callee"sv, m_callee, executable),
format_operand("this"sv, m_this_value, executable));
builder.append(format_operand_list("args"sv, { m_arguments, m_argument_count }, executable));
LibJS/Bytecode: Move to a new bytecode format This patch moves us away from the accumulator-based bytecode format to one with explicit source and destination registers. The new format has multiple benefits: - ~25% faster on the Kraken and Octane benchmarks :^) - Fewer instructions to accomplish the same thing - Much easier for humans to read(!) Because this change requires a fundamental shift in how bytecode is generated, it is quite comprehensive. Main implementation mechanism: generate_bytecode() virtual function now takes an optional "preferred dst" operand, which allows callers to communicate when they have an operand that would be optimal for the result to go into. It also returns an optional "actual dst" operand, which is where the completion value (if any) of the AST node is stored after the node has "executed". One thing of note that's new: because instructions can now take locals as operands, this means we got rid of the GetLocal instruction. A side-effect of that is we have to think about the temporal deadzone (TDZ) a bit differently for locals (GetLocal would previously check for empty values and interpret that as a TDZ access and throw). We now insert special ThrowIfTDZ instructions in places where a local access may be in the TDZ, to maintain the correct behavior. There are a number of progressions and regressions from this test: A number of async generator tests have been accidentally fixed while converting the implementation to the new bytecode format. It didn't seem useful to preserve bugs in the original code when converting it. Some "does eval() return the correct completion value" tests have regressed, in particular ones related to propagating the appropriate completion after control flow statements like continue and break. These are all fairly obscure issues, and I believe we can continue working on them separately. The net test262 result is a progression though. :^)
2024-02-04 08:00:54 +01:00
if (m_builtin.has_value()) {
LibJS/Bytecode: Put arguments directly in the Call instruction Instead of having Call refer to a range of VM registers, it now has a trailing list of argument operands as part of the instruction. This means we no longer have to shuffle every argument value into a register before making a call, making bytecode smaller & faster. :^)
2024-02-20 15:59:45 +01:00
builder.appendff(", (builtin:{})", m_builtin.value());
LibJS/Bytecode: Move to a new bytecode format This patch moves us away from the accumulator-based bytecode format to one with explicit source and destination registers. The new format has multiple benefits: - ~25% faster on the Kraken and Octane benchmarks :^) - Fewer instructions to accomplish the same thing - Much easier for humans to read(!) Because this change requires a fundamental shift in how bytecode is generated, it is quite comprehensive. Main implementation mechanism: generate_bytecode() virtual function now takes an optional "preferred dst" operand, which allows callers to communicate when they have an operand that would be optimal for the result to go into. It also returns an optional "actual dst" operand, which is where the completion value (if any) of the AST node is stored after the node has "executed". One thing of note that's new: because instructions can now take locals as operands, this means we got rid of the GetLocal instruction. A side-effect of that is we have to think about the temporal deadzone (TDZ) a bit differently for locals (GetLocal would previously check for empty values and interpret that as a TDZ access and throw). We now insert special ThrowIfTDZ instructions in places where a local access may be in the TDZ, to maintain the correct behavior. There are a number of progressions and regressions from this test: A number of async generator tests have been accidentally fixed while converting the implementation to the new bytecode format. It didn't seem useful to preserve bugs in the original code when converting it. Some "does eval() return the correct completion value" tests have regressed, in particular ones related to propagating the appropriate completion after control flow statements like continue and break. These are all fairly obscure issues, and I believe we can continue working on them separately. The net test262 result is a progression though. :^)
2024-02-04 08:00:54 +01:00
}
LibJS/Bytecode: Put arguments directly in the Call instruction Instead of having Call refer to a range of VM registers, it now has a trailing list of argument operands as part of the instruction. This means we no longer have to shuffle every argument value into a register before making a call, making bytecode smaller & faster. :^)
2024-02-20 15:59:45 +01:00
LibJS/Bytecode: Move to a new bytecode format This patch moves us away from the accumulator-based bytecode format to one with explicit source and destination registers. The new format has multiple benefits: - ~25% faster on the Kraken and Octane benchmarks :^) - Fewer instructions to accomplish the same thing - Much easier for humans to read(!) Because this change requires a fundamental shift in how bytecode is generated, it is quite comprehensive. Main implementation mechanism: generate_bytecode() virtual function now takes an optional "preferred dst" operand, which allows callers to communicate when they have an operand that would be optimal for the result to go into. It also returns an optional "actual dst" operand, which is where the completion value (if any) of the AST node is stored after the node has "executed". One thing of note that's new: because instructions can now take locals as operands, this means we got rid of the GetLocal instruction. A side-effect of that is we have to think about the temporal deadzone (TDZ) a bit differently for locals (GetLocal would previously check for empty values and interpret that as a TDZ access and throw). We now insert special ThrowIfTDZ instructions in places where a local access may be in the TDZ, to maintain the correct behavior. There are a number of progressions and regressions from this test: A number of async generator tests have been accidentally fixed while converting the implementation to the new bytecode format. It didn't seem useful to preserve bugs in the original code when converting it. Some "does eval() return the correct completion value" tests have regressed, in particular ones related to propagating the appropriate completion after control flow statements like continue and break. These are all fairly obscure issues, and I believe we can continue working on them separately. The net test262 result is a progression though. :^)
2024-02-04 08:00:54 +01:00
if (m_expression_string.has_value()) {
LibJS/Bytecode: Put arguments directly in the Call instruction Instead of having Call refer to a range of VM registers, it now has a trailing list of argument operands as part of the instruction. This means we no longer have to shuffle every argument value into a register before making a call, making bytecode smaller & faster. :^)
2024-02-20 15:59:45 +01:00
builder.appendff(", `{}`", executable.get_string(m_expression_string.value()));
LibJS/Bytecode: Move to a new bytecode format This patch moves us away from the accumulator-based bytecode format to one with explicit source and destination registers. The new format has multiple benefits: - ~25% faster on the Kraken and Octane benchmarks :^) - Fewer instructions to accomplish the same thing - Much easier for humans to read(!) Because this change requires a fundamental shift in how bytecode is generated, it is quite comprehensive. Main implementation mechanism: generate_bytecode() virtual function now takes an optional "preferred dst" operand, which allows callers to communicate when they have an operand that would be optimal for the result to go into. It also returns an optional "actual dst" operand, which is where the completion value (if any) of the AST node is stored after the node has "executed". One thing of note that's new: because instructions can now take locals as operands, this means we got rid of the GetLocal instruction. A side-effect of that is we have to think about the temporal deadzone (TDZ) a bit differently for locals (GetLocal would previously check for empty values and interpret that as a TDZ access and throw). We now insert special ThrowIfTDZ instructions in places where a local access may be in the TDZ, to maintain the correct behavior. There are a number of progressions and regressions from this test: A number of async generator tests have been accidentally fixed while converting the implementation to the new bytecode format. It didn't seem useful to preserve bugs in the original code when converting it. Some "does eval() return the correct completion value" tests have regressed, in particular ones related to propagating the appropriate completion after control flow statements like continue and break. These are all fairly obscure issues, and I believe we can continue working on them separately. The net test262 result is a progression though. :^)
2024-02-04 08:00:54 +01:00
}
LibJS/Bytecode: Put arguments directly in the Call instruction Instead of having Call refer to a range of VM registers, it now has a trailing list of argument operands as part of the instruction. This means we no longer have to shuffle every argument value into a register before making a call, making bytecode smaller & faster. :^)
2024-02-20 15:59:45 +01:00
return builder.to_byte_string();
LibJS: Move all bytecode instruction implementations to Interpreter.cpp This allows aggressive inlining without LTO.
2023-09-27 10:10:00 +02:00
}
Everywhere: Rename {Deprecated => Byte}String This commit un-deprecates DeprecatedString, and repurposes it as a byte string. As the null state has already been removed, there are no other particularly hairy blockers in repurposing this type as a byte string (what it _really_ is). This commit is auto-generated: $ xs=$(ack -l \bDeprecatedString\b\|deprecated_string AK Userland \ Meta Ports Ladybird Tests Kernel) $ perl -pie 's/\bDeprecatedString\b/ByteString/g; s/deprecated_string/byte_string/g' $xs $ clang-format --style=file -i \ $(git diff --name-only | grep \.cpp\|\.h) $ gn format $(git ls-files '*.gn' '*.gni')
2023-12-16 17:49:34 +03:30
ByteString CallWithArgumentArray::to_byte_string_impl(Bytecode::Executable const& executable) const
LibJS: Move all bytecode instruction implementations to Interpreter.cpp This allows aggressive inlining without LTO.
2023-09-27 10:10:00 +02:00
{
auto type = call_type_to_string(m_type);
LibJS/Bytecode: Move to a new bytecode format This patch moves us away from the accumulator-based bytecode format to one with explicit source and destination registers. The new format has multiple benefits: - ~25% faster on the Kraken and Octane benchmarks :^) - Fewer instructions to accomplish the same thing - Much easier for humans to read(!) Because this change requires a fundamental shift in how bytecode is generated, it is quite comprehensive. Main implementation mechanism: generate_bytecode() virtual function now takes an optional "preferred dst" operand, which allows callers to communicate when they have an operand that would be optimal for the result to go into. It also returns an optional "actual dst" operand, which is where the completion value (if any) of the AST node is stored after the node has "executed". One thing of note that's new: because instructions can now take locals as operands, this means we got rid of the GetLocal instruction. A side-effect of that is we have to think about the temporal deadzone (TDZ) a bit differently for locals (GetLocal would previously check for empty values and interpret that as a TDZ access and throw). We now insert special ThrowIfTDZ instructions in places where a local access may be in the TDZ, to maintain the correct behavior. There are a number of progressions and regressions from this test: A number of async generator tests have been accidentally fixed while converting the implementation to the new bytecode format. It didn't seem useful to preserve bugs in the original code when converting it. Some "does eval() return the correct completion value" tests have regressed, in particular ones related to propagating the appropriate completion after control flow statements like continue and break. These are all fairly obscure issues, and I believe we can continue working on them separately. The net test262 result is a progression though. :^)
2024-02-04 08:00:54 +01:00
StringBuilder builder;
builder.appendff("CallWithArgumentArray{} {}, {}, {}, {}",
type,
format_operand("dst"sv, m_dst, executable),
format_operand("callee"sv, m_callee, executable),
format_operand("this"sv, m_this_value, executable),
format_operand("arguments"sv, m_arguments, executable));
LibJS: Move all bytecode instruction implementations to Interpreter.cpp This allows aggressive inlining without LTO.
2023-09-27 10:10:00 +02:00
if (m_expression_string.has_value())
LibJS/Bytecode: Move to a new bytecode format This patch moves us away from the accumulator-based bytecode format to one with explicit source and destination registers. The new format has multiple benefits: - ~25% faster on the Kraken and Octane benchmarks :^) - Fewer instructions to accomplish the same thing - Much easier for humans to read(!) Because this change requires a fundamental shift in how bytecode is generated, it is quite comprehensive. Main implementation mechanism: generate_bytecode() virtual function now takes an optional "preferred dst" operand, which allows callers to communicate when they have an operand that would be optimal for the result to go into. It also returns an optional "actual dst" operand, which is where the completion value (if any) of the AST node is stored after the node has "executed". One thing of note that's new: because instructions can now take locals as operands, this means we got rid of the GetLocal instruction. A side-effect of that is we have to think about the temporal deadzone (TDZ) a bit differently for locals (GetLocal would previously check for empty values and interpret that as a TDZ access and throw). We now insert special ThrowIfTDZ instructions in places where a local access may be in the TDZ, to maintain the correct behavior. There are a number of progressions and regressions from this test: A number of async generator tests have been accidentally fixed while converting the implementation to the new bytecode format. It didn't seem useful to preserve bugs in the original code when converting it. Some "does eval() return the correct completion value" tests have regressed, in particular ones related to propagating the appropriate completion after control flow statements like continue and break. These are all fairly obscure issues, and I believe we can continue working on them separately. The net test262 result is a progression though. :^)
2024-02-04 08:00:54 +01:00
builder.appendff(" ({})", executable.get_string(m_expression_string.value()));
return builder.to_byte_string();
LibJS: Move all bytecode instruction implementations to Interpreter.cpp This allows aggressive inlining without LTO.
2023-09-27 10:10:00 +02:00
}
LibJS/Bytecode: Move to a new bytecode format This patch moves us away from the accumulator-based bytecode format to one with explicit source and destination registers. The new format has multiple benefits: - ~25% faster on the Kraken and Octane benchmarks :^) - Fewer instructions to accomplish the same thing - Much easier for humans to read(!) Because this change requires a fundamental shift in how bytecode is generated, it is quite comprehensive. Main implementation mechanism: generate_bytecode() virtual function now takes an optional "preferred dst" operand, which allows callers to communicate when they have an operand that would be optimal for the result to go into. It also returns an optional "actual dst" operand, which is where the completion value (if any) of the AST node is stored after the node has "executed". One thing of note that's new: because instructions can now take locals as operands, this means we got rid of the GetLocal instruction. A side-effect of that is we have to think about the temporal deadzone (TDZ) a bit differently for locals (GetLocal would previously check for empty values and interpret that as a TDZ access and throw). We now insert special ThrowIfTDZ instructions in places where a local access may be in the TDZ, to maintain the correct behavior. There are a number of progressions and regressions from this test: A number of async generator tests have been accidentally fixed while converting the implementation to the new bytecode format. It didn't seem useful to preserve bugs in the original code when converting it. Some "does eval() return the correct completion value" tests have regressed, in particular ones related to propagating the appropriate completion after control flow statements like continue and break. These are all fairly obscure issues, and I believe we can continue working on them separately. The net test262 result is a progression though. :^)
2024-02-04 08:00:54 +01:00
ByteString SuperCallWithArgumentArray::to_byte_string_impl(Bytecode::Executable const& executable) const
LibJS: Move all bytecode instruction implementations to Interpreter.cpp This allows aggressive inlining without LTO.
2023-09-27 10:10:00 +02:00
{
LibJS/Bytecode: Move to a new bytecode format This patch moves us away from the accumulator-based bytecode format to one with explicit source and destination registers. The new format has multiple benefits: - ~25% faster on the Kraken and Octane benchmarks :^) - Fewer instructions to accomplish the same thing - Much easier for humans to read(!) Because this change requires a fundamental shift in how bytecode is generated, it is quite comprehensive. Main implementation mechanism: generate_bytecode() virtual function now takes an optional "preferred dst" operand, which allows callers to communicate when they have an operand that would be optimal for the result to go into. It also returns an optional "actual dst" operand, which is where the completion value (if any) of the AST node is stored after the node has "executed". One thing of note that's new: because instructions can now take locals as operands, this means we got rid of the GetLocal instruction. A side-effect of that is we have to think about the temporal deadzone (TDZ) a bit differently for locals (GetLocal would previously check for empty values and interpret that as a TDZ access and throw). We now insert special ThrowIfTDZ instructions in places where a local access may be in the TDZ, to maintain the correct behavior. There are a number of progressions and regressions from this test: A number of async generator tests have been accidentally fixed while converting the implementation to the new bytecode format. It didn't seem useful to preserve bugs in the original code when converting it. Some "does eval() return the correct completion value" tests have regressed, in particular ones related to propagating the appropriate completion after control flow statements like continue and break. These are all fairly obscure issues, and I believe we can continue working on them separately. The net test262 result is a progression though. :^)
2024-02-04 08:00:54 +01:00
return ByteString::formatted("SuperCallWithArgumentArray {}, {}",
format_operand("dst"sv, m_dst, executable),
format_operand("arguments"sv, m_arguments, executable));
LibJS: Move all bytecode instruction implementations to Interpreter.cpp This allows aggressive inlining without LTO.
2023-09-27 10:10:00 +02:00
}
LibJS/Bytecode: Move to a new bytecode format This patch moves us away from the accumulator-based bytecode format to one with explicit source and destination registers. The new format has multiple benefits: - ~25% faster on the Kraken and Octane benchmarks :^) - Fewer instructions to accomplish the same thing - Much easier for humans to read(!) Because this change requires a fundamental shift in how bytecode is generated, it is quite comprehensive. Main implementation mechanism: generate_bytecode() virtual function now takes an optional "preferred dst" operand, which allows callers to communicate when they have an operand that would be optimal for the result to go into. It also returns an optional "actual dst" operand, which is where the completion value (if any) of the AST node is stored after the node has "executed". One thing of note that's new: because instructions can now take locals as operands, this means we got rid of the GetLocal instruction. A side-effect of that is we have to think about the temporal deadzone (TDZ) a bit differently for locals (GetLocal would previously check for empty values and interpret that as a TDZ access and throw). We now insert special ThrowIfTDZ instructions in places where a local access may be in the TDZ, to maintain the correct behavior. There are a number of progressions and regressions from this test: A number of async generator tests have been accidentally fixed while converting the implementation to the new bytecode format. It didn't seem useful to preserve bugs in the original code when converting it. Some "does eval() return the correct completion value" tests have regressed, in particular ones related to propagating the appropriate completion after control flow statements like continue and break. These are all fairly obscure issues, and I believe we can continue working on them separately. The net test262 result is a progression though. :^)
2024-02-04 08:00:54 +01:00
ByteString NewFunction::to_byte_string_impl(Bytecode::Executable const& executable) const
LibJS: Move all bytecode instruction implementations to Interpreter.cpp This allows aggressive inlining without LTO.
2023-09-27 10:10:00 +02:00
{
StringBuilder builder;
LibJS/Bytecode: Move to a new bytecode format This patch moves us away from the accumulator-based bytecode format to one with explicit source and destination registers. The new format has multiple benefits: - ~25% faster on the Kraken and Octane benchmarks :^) - Fewer instructions to accomplish the same thing - Much easier for humans to read(!) Because this change requires a fundamental shift in how bytecode is generated, it is quite comprehensive. Main implementation mechanism: generate_bytecode() virtual function now takes an optional "preferred dst" operand, which allows callers to communicate when they have an operand that would be optimal for the result to go into. It also returns an optional "actual dst" operand, which is where the completion value (if any) of the AST node is stored after the node has "executed". One thing of note that's new: because instructions can now take locals as operands, this means we got rid of the GetLocal instruction. A side-effect of that is we have to think about the temporal deadzone (TDZ) a bit differently for locals (GetLocal would previously check for empty values and interpret that as a TDZ access and throw). We now insert special ThrowIfTDZ instructions in places where a local access may be in the TDZ, to maintain the correct behavior. There are a number of progressions and regressions from this test: A number of async generator tests have been accidentally fixed while converting the implementation to the new bytecode format. It didn't seem useful to preserve bugs in the original code when converting it. Some "does eval() return the correct completion value" tests have regressed, in particular ones related to propagating the appropriate completion after control flow statements like continue and break. These are all fairly obscure issues, and I believe we can continue working on them separately. The net test262 result is a progression though. :^)
2024-02-04 08:00:54 +01:00
builder.appendff("NewFunction {}",
format_operand("dst"sv, m_dst, executable));
LibJS: Move all bytecode instruction implementations to Interpreter.cpp This allows aggressive inlining without LTO.
2023-09-27 10:10:00 +02:00
if (m_function_node.has_name())
builder.appendff(" name:{}"sv, m_function_node.name());
if (m_lhs_name.has_value())
LibJS/Bytecode: Move to a new bytecode format This patch moves us away from the accumulator-based bytecode format to one with explicit source and destination registers. The new format has multiple benefits: - ~25% faster on the Kraken and Octane benchmarks :^) - Fewer instructions to accomplish the same thing - Much easier for humans to read(!) Because this change requires a fundamental shift in how bytecode is generated, it is quite comprehensive. Main implementation mechanism: generate_bytecode() virtual function now takes an optional "preferred dst" operand, which allows callers to communicate when they have an operand that would be optimal for the result to go into. It also returns an optional "actual dst" operand, which is where the completion value (if any) of the AST node is stored after the node has "executed". One thing of note that's new: because instructions can now take locals as operands, this means we got rid of the GetLocal instruction. A side-effect of that is we have to think about the temporal deadzone (TDZ) a bit differently for locals (GetLocal would previously check for empty values and interpret that as a TDZ access and throw). We now insert special ThrowIfTDZ instructions in places where a local access may be in the TDZ, to maintain the correct behavior. There are a number of progressions and regressions from this test: A number of async generator tests have been accidentally fixed while converting the implementation to the new bytecode format. It didn't seem useful to preserve bugs in the original code when converting it. Some "does eval() return the correct completion value" tests have regressed, in particular ones related to propagating the appropriate completion after control flow statements like continue and break. These are all fairly obscure issues, and I believe we can continue working on them separately. The net test262 result is a progression though. :^)
2024-02-04 08:00:54 +01:00
builder.appendff(" lhs_name:{}"sv, executable.get_identifier(m_lhs_name.value()));
LibJS: Move all bytecode instruction implementations to Interpreter.cpp This allows aggressive inlining without LTO.
2023-09-27 10:10:00 +02:00
if (m_home_object.has_value())
LibJS/Bytecode: Move to a new bytecode format This patch moves us away from the accumulator-based bytecode format to one with explicit source and destination registers. The new format has multiple benefits: - ~25% faster on the Kraken and Octane benchmarks :^) - Fewer instructions to accomplish the same thing - Much easier for humans to read(!) Because this change requires a fundamental shift in how bytecode is generated, it is quite comprehensive. Main implementation mechanism: generate_bytecode() virtual function now takes an optional "preferred dst" operand, which allows callers to communicate when they have an operand that would be optimal for the result to go into. It also returns an optional "actual dst" operand, which is where the completion value (if any) of the AST node is stored after the node has "executed". One thing of note that's new: because instructions can now take locals as operands, this means we got rid of the GetLocal instruction. A side-effect of that is we have to think about the temporal deadzone (TDZ) a bit differently for locals (GetLocal would previously check for empty values and interpret that as a TDZ access and throw). We now insert special ThrowIfTDZ instructions in places where a local access may be in the TDZ, to maintain the correct behavior. There are a number of progressions and regressions from this test: A number of async generator tests have been accidentally fixed while converting the implementation to the new bytecode format. It didn't seem useful to preserve bugs in the original code when converting it. Some "does eval() return the correct completion value" tests have regressed, in particular ones related to propagating the appropriate completion after control flow statements like continue and break. These are all fairly obscure issues, and I believe we can continue working on them separately. The net test262 result is a progression though. :^)
2024-02-04 08:00:54 +01:00
builder.appendff(", {}"sv, format_operand("home_object"sv, m_home_object.value(), executable));
Everywhere: Rename {Deprecated => Byte}String This commit un-deprecates DeprecatedString, and repurposes it as a byte string. As the null state has already been removed, there are no other particularly hairy blockers in repurposing this type as a byte string (what it _really_ is). This commit is auto-generated: $ xs=$(ack -l \bDeprecatedString\b\|deprecated_string AK Userland \ Meta Ports Ladybird Tests Kernel) $ perl -pie 's/\bDeprecatedString\b/ByteString/g; s/deprecated_string/byte_string/g' $xs $ clang-format --style=file -i \ $(git diff --name-only | grep \.cpp\|\.h) $ gn format $(git ls-files '*.gn' '*.gni')
2023-12-16 17:49:34 +03:30
return builder.to_byte_string();
LibJS: Move all bytecode instruction implementations to Interpreter.cpp This allows aggressive inlining without LTO.
2023-09-27 10:10:00 +02:00
}
LibJS/Bytecode: Move to a new bytecode format This patch moves us away from the accumulator-based bytecode format to one with explicit source and destination registers. The new format has multiple benefits: - ~25% faster on the Kraken and Octane benchmarks :^) - Fewer instructions to accomplish the same thing - Much easier for humans to read(!) Because this change requires a fundamental shift in how bytecode is generated, it is quite comprehensive. Main implementation mechanism: generate_bytecode() virtual function now takes an optional "preferred dst" operand, which allows callers to communicate when they have an operand that would be optimal for the result to go into. It also returns an optional "actual dst" operand, which is where the completion value (if any) of the AST node is stored after the node has "executed". One thing of note that's new: because instructions can now take locals as operands, this means we got rid of the GetLocal instruction. A side-effect of that is we have to think about the temporal deadzone (TDZ) a bit differently for locals (GetLocal would previously check for empty values and interpret that as a TDZ access and throw). We now insert special ThrowIfTDZ instructions in places where a local access may be in the TDZ, to maintain the correct behavior. There are a number of progressions and regressions from this test: A number of async generator tests have been accidentally fixed while converting the implementation to the new bytecode format. It didn't seem useful to preserve bugs in the original code when converting it. Some "does eval() return the correct completion value" tests have regressed, in particular ones related to propagating the appropriate completion after control flow statements like continue and break. These are all fairly obscure issues, and I believe we can continue working on them separately. The net test262 result is a progression though. :^)
2024-02-04 08:00:54 +01:00
ByteString NewClass::to_byte_string_impl(Bytecode::Executable const& executable) const
LibJS: Move all bytecode instruction implementations to Interpreter.cpp This allows aggressive inlining without LTO.
2023-09-27 10:10:00 +02:00
{
StringBuilder builder;
auto name = m_class_expression.name();
LibJS/Bytecode: Move to a new bytecode format This patch moves us away from the accumulator-based bytecode format to one with explicit source and destination registers. The new format has multiple benefits: - ~25% faster on the Kraken and Octane benchmarks :^) - Fewer instructions to accomplish the same thing - Much easier for humans to read(!) Because this change requires a fundamental shift in how bytecode is generated, it is quite comprehensive. Main implementation mechanism: generate_bytecode() virtual function now takes an optional "preferred dst" operand, which allows callers to communicate when they have an operand that would be optimal for the result to go into. It also returns an optional "actual dst" operand, which is where the completion value (if any) of the AST node is stored after the node has "executed". One thing of note that's new: because instructions can now take locals as operands, this means we got rid of the GetLocal instruction. A side-effect of that is we have to think about the temporal deadzone (TDZ) a bit differently for locals (GetLocal would previously check for empty values and interpret that as a TDZ access and throw). We now insert special ThrowIfTDZ instructions in places where a local access may be in the TDZ, to maintain the correct behavior. There are a number of progressions and regressions from this test: A number of async generator tests have been accidentally fixed while converting the implementation to the new bytecode format. It didn't seem useful to preserve bugs in the original code when converting it. Some "does eval() return the correct completion value" tests have regressed, in particular ones related to propagating the appropriate completion after control flow statements like continue and break. These are all fairly obscure issues, and I believe we can continue working on them separately. The net test262 result is a progression though. :^)
2024-02-04 08:00:54 +01:00
builder.appendff("NewClass {}",
format_operand("dst"sv, m_dst, executable));
if (m_super_class.has_value())
builder.appendff(", {}", format_operand("super_class"sv, *m_super_class, executable));
if (!name.is_empty())
builder.appendff(", {}", name);
LibJS: Move all bytecode instruction implementations to Interpreter.cpp This allows aggressive inlining without LTO.
2023-09-27 10:10:00 +02:00
if (m_lhs_name.has_value())
LibJS/Bytecode: Make IdentifierTableIndex a 32-bit index This makes a bunch of instructions smaller.
2024-05-06 10:12:02 +02:00
builder.appendff(", lhs_name:{}"sv, executable.get_identifier(m_lhs_name.value()));
Everywhere: Rename {Deprecated => Byte}String This commit un-deprecates DeprecatedString, and repurposes it as a byte string. As the null state has already been removed, there are no other particularly hairy blockers in repurposing this type as a byte string (what it _really_ is). This commit is auto-generated: $ xs=$(ack -l \bDeprecatedString\b\|deprecated_string AK Userland \ Meta Ports Ladybird Tests Kernel) $ perl -pie 's/\bDeprecatedString\b/ByteString/g; s/deprecated_string/byte_string/g' $xs $ clang-format --style=file -i \ $(git diff --name-only | grep \.cpp\|\.h) $ gn format $(git ls-files '*.gn' '*.gni')
2023-12-16 17:49:34 +03:30
return builder.to_byte_string();
LibJS: Move all bytecode instruction implementations to Interpreter.cpp This allows aggressive inlining without LTO.
2023-09-27 10:10:00 +02:00
}
LibJS/Bytecode: Move to a new bytecode format This patch moves us away from the accumulator-based bytecode format to one with explicit source and destination registers. The new format has multiple benefits: - ~25% faster on the Kraken and Octane benchmarks :^) - Fewer instructions to accomplish the same thing - Much easier for humans to read(!) Because this change requires a fundamental shift in how bytecode is generated, it is quite comprehensive. Main implementation mechanism: generate_bytecode() virtual function now takes an optional "preferred dst" operand, which allows callers to communicate when they have an operand that would be optimal for the result to go into. It also returns an optional "actual dst" operand, which is where the completion value (if any) of the AST node is stored after the node has "executed". One thing of note that's new: because instructions can now take locals as operands, this means we got rid of the GetLocal instruction. A side-effect of that is we have to think about the temporal deadzone (TDZ) a bit differently for locals (GetLocal would previously check for empty values and interpret that as a TDZ access and throw). We now insert special ThrowIfTDZ instructions in places where a local access may be in the TDZ, to maintain the correct behavior. There are a number of progressions and regressions from this test: A number of async generator tests have been accidentally fixed while converting the implementation to the new bytecode format. It didn't seem useful to preserve bugs in the original code when converting it. Some "does eval() return the correct completion value" tests have regressed, in particular ones related to propagating the appropriate completion after control flow statements like continue and break. These are all fairly obscure issues, and I believe we can continue working on them separately. The net test262 result is a progression though. :^)
2024-02-04 08:00:54 +01:00
ByteString Return::to_byte_string_impl(Bytecode::Executable const& executable) const
LibJS: Move all bytecode instruction implementations to Interpreter.cpp This allows aggressive inlining without LTO.
2023-09-27 10:10:00 +02:00
{
LibJS/Bytecode: Move to a new bytecode format This patch moves us away from the accumulator-based bytecode format to one with explicit source and destination registers. The new format has multiple benefits: - ~25% faster on the Kraken and Octane benchmarks :^) - Fewer instructions to accomplish the same thing - Much easier for humans to read(!) Because this change requires a fundamental shift in how bytecode is generated, it is quite comprehensive. Main implementation mechanism: generate_bytecode() virtual function now takes an optional "preferred dst" operand, which allows callers to communicate when they have an operand that would be optimal for the result to go into. It also returns an optional "actual dst" operand, which is where the completion value (if any) of the AST node is stored after the node has "executed". One thing of note that's new: because instructions can now take locals as operands, this means we got rid of the GetLocal instruction. A side-effect of that is we have to think about the temporal deadzone (TDZ) a bit differently for locals (GetLocal would previously check for empty values and interpret that as a TDZ access and throw). We now insert special ThrowIfTDZ instructions in places where a local access may be in the TDZ, to maintain the correct behavior. There are a number of progressions and regressions from this test: A number of async generator tests have been accidentally fixed while converting the implementation to the new bytecode format. It didn't seem useful to preserve bugs in the original code when converting it. Some "does eval() return the correct completion value" tests have regressed, in particular ones related to propagating the appropriate completion after control flow statements like continue and break. These are all fairly obscure issues, and I believe we can continue working on them separately. The net test262 result is a progression though. :^)
2024-02-04 08:00:54 +01:00
if (m_value.has_value())
return ByteString::formatted("Return {}", format_operand("value"sv, m_value.value(), executable));
LibJS: Move all bytecode instruction implementations to Interpreter.cpp This allows aggressive inlining without LTO.
2023-09-27 10:10:00 +02:00
return "Return";
}
LibJS/Bytecode: Move to a new bytecode format This patch moves us away from the accumulator-based bytecode format to one with explicit source and destination registers. The new format has multiple benefits: - ~25% faster on the Kraken and Octane benchmarks :^) - Fewer instructions to accomplish the same thing - Much easier for humans to read(!) Because this change requires a fundamental shift in how bytecode is generated, it is quite comprehensive. Main implementation mechanism: generate_bytecode() virtual function now takes an optional "preferred dst" operand, which allows callers to communicate when they have an operand that would be optimal for the result to go into. It also returns an optional "actual dst" operand, which is where the completion value (if any) of the AST node is stored after the node has "executed". One thing of note that's new: because instructions can now take locals as operands, this means we got rid of the GetLocal instruction. A side-effect of that is we have to think about the temporal deadzone (TDZ) a bit differently for locals (GetLocal would previously check for empty values and interpret that as a TDZ access and throw). We now insert special ThrowIfTDZ instructions in places where a local access may be in the TDZ, to maintain the correct behavior. There are a number of progressions and regressions from this test: A number of async generator tests have been accidentally fixed while converting the implementation to the new bytecode format. It didn't seem useful to preserve bugs in the original code when converting it. Some "does eval() return the correct completion value" tests have regressed, in particular ones related to propagating the appropriate completion after control flow statements like continue and break. These are all fairly obscure issues, and I believe we can continue working on them separately. The net test262 result is a progression though. :^)
2024-02-04 08:00:54 +01:00
ByteString Increment::to_byte_string_impl(Bytecode::Executable const& executable) const
LibJS: Move all bytecode instruction implementations to Interpreter.cpp This allows aggressive inlining without LTO.
2023-09-27 10:10:00 +02:00
{
LibJS/Bytecode: Move to a new bytecode format This patch moves us away from the accumulator-based bytecode format to one with explicit source and destination registers. The new format has multiple benefits: - ~25% faster on the Kraken and Octane benchmarks :^) - Fewer instructions to accomplish the same thing - Much easier for humans to read(!) Because this change requires a fundamental shift in how bytecode is generated, it is quite comprehensive. Main implementation mechanism: generate_bytecode() virtual function now takes an optional "preferred dst" operand, which allows callers to communicate when they have an operand that would be optimal for the result to go into. It also returns an optional "actual dst" operand, which is where the completion value (if any) of the AST node is stored after the node has "executed". One thing of note that's new: because instructions can now take locals as operands, this means we got rid of the GetLocal instruction. A side-effect of that is we have to think about the temporal deadzone (TDZ) a bit differently for locals (GetLocal would previously check for empty values and interpret that as a TDZ access and throw). We now insert special ThrowIfTDZ instructions in places where a local access may be in the TDZ, to maintain the correct behavior. There are a number of progressions and regressions from this test: A number of async generator tests have been accidentally fixed while converting the implementation to the new bytecode format. It didn't seem useful to preserve bugs in the original code when converting it. Some "does eval() return the correct completion value" tests have regressed, in particular ones related to propagating the appropriate completion after control flow statements like continue and break. These are all fairly obscure issues, and I believe we can continue working on them separately. The net test262 result is a progression though. :^)
2024-02-04 08:00:54 +01:00
return ByteString::formatted("Increment {}", format_operand("dst"sv, m_dst, executable));
LibJS: Move all bytecode instruction implementations to Interpreter.cpp This allows aggressive inlining without LTO.
2023-09-27 10:10:00 +02:00
}
LibJS/Bytecode: Dedicated instructions for postfix increment/decrement Instead of splitting the postfix variants into ToNumeric + Inc/Dec, we now have dedicated PostfixIncrement and PostfixDecrement instructions that handle both outputs in one go.
2024-02-20 11:45:01 +01:00
ByteString PostfixIncrement::to_byte_string_impl(Bytecode::Executable const& executable) const
{
return ByteString::formatted("PostfixIncrement {}, {}",
format_operand("dst"sv, m_dst, executable),
LibJS/Bytecode: Fix bad serialization of Postfix{Increment,Decrement} We were serializing the dst operand twice in both instructions.
2024-03-03 09:04:30 +01:00
format_operand("src"sv, m_src, executable));
LibJS/Bytecode: Dedicated instructions for postfix increment/decrement Instead of splitting the postfix variants into ToNumeric + Inc/Dec, we now have dedicated PostfixIncrement and PostfixDecrement instructions that handle both outputs in one go.
2024-02-20 11:45:01 +01:00
}
ByteString Decrement::to_byte_string_impl(Bytecode::Executable const& executable) const
{
return ByteString::formatted("Decrement {}", format_operand("dst"sv, m_dst, executable));
}
ByteString PostfixDecrement::to_byte_string_impl(Bytecode::Executable const& executable) const
LibJS: Move all bytecode instruction implementations to Interpreter.cpp This allows aggressive inlining without LTO.
2023-09-27 10:10:00 +02:00
{
LibJS/Bytecode: Dedicated instructions for postfix increment/decrement Instead of splitting the postfix variants into ToNumeric + Inc/Dec, we now have dedicated PostfixIncrement and PostfixDecrement instructions that handle both outputs in one go.
2024-02-20 11:45:01 +01:00
return ByteString::formatted("PostfixDecrement {}, {}",
format_operand("dst"sv, m_dst, executable),
LibJS/Bytecode: Fix bad serialization of Postfix{Increment,Decrement} We were serializing the dst operand twice in both instructions.
2024-03-03 09:04:30 +01:00
format_operand("src"sv, m_src, executable));
LibJS: Move all bytecode instruction implementations to Interpreter.cpp This allows aggressive inlining without LTO.
2023-09-27 10:10:00 +02:00
}
LibJS/Bytecode: Move to a new bytecode format This patch moves us away from the accumulator-based bytecode format to one with explicit source and destination registers. The new format has multiple benefits: - ~25% faster on the Kraken and Octane benchmarks :^) - Fewer instructions to accomplish the same thing - Much easier for humans to read(!) Because this change requires a fundamental shift in how bytecode is generated, it is quite comprehensive. Main implementation mechanism: generate_bytecode() virtual function now takes an optional "preferred dst" operand, which allows callers to communicate when they have an operand that would be optimal for the result to go into. It also returns an optional "actual dst" operand, which is where the completion value (if any) of the AST node is stored after the node has "executed". One thing of note that's new: because instructions can now take locals as operands, this means we got rid of the GetLocal instruction. A side-effect of that is we have to think about the temporal deadzone (TDZ) a bit differently for locals (GetLocal would previously check for empty values and interpret that as a TDZ access and throw). We now insert special ThrowIfTDZ instructions in places where a local access may be in the TDZ, to maintain the correct behavior. There are a number of progressions and regressions from this test: A number of async generator tests have been accidentally fixed while converting the implementation to the new bytecode format. It didn't seem useful to preserve bugs in the original code when converting it. Some "does eval() return the correct completion value" tests have regressed, in particular ones related to propagating the appropriate completion after control flow statements like continue and break. These are all fairly obscure issues, and I believe we can continue working on them separately. The net test262 result is a progression though. :^)
2024-02-04 08:00:54 +01:00
ByteString Throw::to_byte_string_impl(Bytecode::Executable const& executable) const
LibJS: Move all bytecode instruction implementations to Interpreter.cpp This allows aggressive inlining without LTO.
2023-09-27 10:10:00 +02:00
{
LibJS/Bytecode: Move to a new bytecode format This patch moves us away from the accumulator-based bytecode format to one with explicit source and destination registers. The new format has multiple benefits: - ~25% faster on the Kraken and Octane benchmarks :^) - Fewer instructions to accomplish the same thing - Much easier for humans to read(!) Because this change requires a fundamental shift in how bytecode is generated, it is quite comprehensive. Main implementation mechanism: generate_bytecode() virtual function now takes an optional "preferred dst" operand, which allows callers to communicate when they have an operand that would be optimal for the result to go into. It also returns an optional "actual dst" operand, which is where the completion value (if any) of the AST node is stored after the node has "executed". One thing of note that's new: because instructions can now take locals as operands, this means we got rid of the GetLocal instruction. A side-effect of that is we have to think about the temporal deadzone (TDZ) a bit differently for locals (GetLocal would previously check for empty values and interpret that as a TDZ access and throw). We now insert special ThrowIfTDZ instructions in places where a local access may be in the TDZ, to maintain the correct behavior. There are a number of progressions and regressions from this test: A number of async generator tests have been accidentally fixed while converting the implementation to the new bytecode format. It didn't seem useful to preserve bugs in the original code when converting it. Some "does eval() return the correct completion value" tests have regressed, in particular ones related to propagating the appropriate completion after control flow statements like continue and break. These are all fairly obscure issues, and I believe we can continue working on them separately. The net test262 result is a progression though. :^)
2024-02-04 08:00:54 +01:00
return ByteString::formatted("Throw {}",
format_operand("src"sv, m_src, executable));
LibJS: Move all bytecode instruction implementations to Interpreter.cpp This allows aggressive inlining without LTO.
2023-09-27 10:10:00 +02:00
}
LibJS/Bytecode: Move to a new bytecode format This patch moves us away from the accumulator-based bytecode format to one with explicit source and destination registers. The new format has multiple benefits: - ~25% faster on the Kraken and Octane benchmarks :^) - Fewer instructions to accomplish the same thing - Much easier for humans to read(!) Because this change requires a fundamental shift in how bytecode is generated, it is quite comprehensive. Main implementation mechanism: generate_bytecode() virtual function now takes an optional "preferred dst" operand, which allows callers to communicate when they have an operand that would be optimal for the result to go into. It also returns an optional "actual dst" operand, which is where the completion value (if any) of the AST node is stored after the node has "executed". One thing of note that's new: because instructions can now take locals as operands, this means we got rid of the GetLocal instruction. A side-effect of that is we have to think about the temporal deadzone (TDZ) a bit differently for locals (GetLocal would previously check for empty values and interpret that as a TDZ access and throw). We now insert special ThrowIfTDZ instructions in places where a local access may be in the TDZ, to maintain the correct behavior. There are a number of progressions and regressions from this test: A number of async generator tests have been accidentally fixed while converting the implementation to the new bytecode format. It didn't seem useful to preserve bugs in the original code when converting it. Some "does eval() return the correct completion value" tests have regressed, in particular ones related to propagating the appropriate completion after control flow statements like continue and break. These are all fairly obscure issues, and I believe we can continue working on them separately. The net test262 result is a progression though. :^)
2024-02-04 08:00:54 +01:00
ByteString ThrowIfNotObject::to_byte_string_impl(Bytecode::Executable const& executable) const
LibJS: Move all bytecode instruction implementations to Interpreter.cpp This allows aggressive inlining without LTO.
2023-09-27 10:10:00 +02:00
{
LibJS/Bytecode: Move to a new bytecode format This patch moves us away from the accumulator-based bytecode format to one with explicit source and destination registers. The new format has multiple benefits: - ~25% faster on the Kraken and Octane benchmarks :^) - Fewer instructions to accomplish the same thing - Much easier for humans to read(!) Because this change requires a fundamental shift in how bytecode is generated, it is quite comprehensive. Main implementation mechanism: generate_bytecode() virtual function now takes an optional "preferred dst" operand, which allows callers to communicate when they have an operand that would be optimal for the result to go into. It also returns an optional "actual dst" operand, which is where the completion value (if any) of the AST node is stored after the node has "executed". One thing of note that's new: because instructions can now take locals as operands, this means we got rid of the GetLocal instruction. A side-effect of that is we have to think about the temporal deadzone (TDZ) a bit differently for locals (GetLocal would previously check for empty values and interpret that as a TDZ access and throw). We now insert special ThrowIfTDZ instructions in places where a local access may be in the TDZ, to maintain the correct behavior. There are a number of progressions and regressions from this test: A number of async generator tests have been accidentally fixed while converting the implementation to the new bytecode format. It didn't seem useful to preserve bugs in the original code when converting it. Some "does eval() return the correct completion value" tests have regressed, in particular ones related to propagating the appropriate completion after control flow statements like continue and break. These are all fairly obscure issues, and I believe we can continue working on them separately. The net test262 result is a progression though. :^)
2024-02-04 08:00:54 +01:00
return ByteString::formatted("ThrowIfNotObject {}",
format_operand("src"sv, m_src, executable));
LibJS: Move all bytecode instruction implementations to Interpreter.cpp This allows aggressive inlining without LTO.
2023-09-27 10:10:00 +02:00
}
LibJS/Bytecode: Move to a new bytecode format This patch moves us away from the accumulator-based bytecode format to one with explicit source and destination registers. The new format has multiple benefits: - ~25% faster on the Kraken and Octane benchmarks :^) - Fewer instructions to accomplish the same thing - Much easier for humans to read(!) Because this change requires a fundamental shift in how bytecode is generated, it is quite comprehensive. Main implementation mechanism: generate_bytecode() virtual function now takes an optional "preferred dst" operand, which allows callers to communicate when they have an operand that would be optimal for the result to go into. It also returns an optional "actual dst" operand, which is where the completion value (if any) of the AST node is stored after the node has "executed". One thing of note that's new: because instructions can now take locals as operands, this means we got rid of the GetLocal instruction. A side-effect of that is we have to think about the temporal deadzone (TDZ) a bit differently for locals (GetLocal would previously check for empty values and interpret that as a TDZ access and throw). We now insert special ThrowIfTDZ instructions in places where a local access may be in the TDZ, to maintain the correct behavior. There are a number of progressions and regressions from this test: A number of async generator tests have been accidentally fixed while converting the implementation to the new bytecode format. It didn't seem useful to preserve bugs in the original code when converting it. Some "does eval() return the correct completion value" tests have regressed, in particular ones related to propagating the appropriate completion after control flow statements like continue and break. These are all fairly obscure issues, and I believe we can continue working on them separately. The net test262 result is a progression though. :^)
2024-02-04 08:00:54 +01:00
ByteString ThrowIfNullish::to_byte_string_impl(Bytecode::Executable const& executable) const
LibJS: Move all bytecode instruction implementations to Interpreter.cpp This allows aggressive inlining without LTO.
2023-09-27 10:10:00 +02:00
{
LibJS/Bytecode: Move to a new bytecode format This patch moves us away from the accumulator-based bytecode format to one with explicit source and destination registers. The new format has multiple benefits: - ~25% faster on the Kraken and Octane benchmarks :^) - Fewer instructions to accomplish the same thing - Much easier for humans to read(!) Because this change requires a fundamental shift in how bytecode is generated, it is quite comprehensive. Main implementation mechanism: generate_bytecode() virtual function now takes an optional "preferred dst" operand, which allows callers to communicate when they have an operand that would be optimal for the result to go into. It also returns an optional "actual dst" operand, which is where the completion value (if any) of the AST node is stored after the node has "executed". One thing of note that's new: because instructions can now take locals as operands, this means we got rid of the GetLocal instruction. A side-effect of that is we have to think about the temporal deadzone (TDZ) a bit differently for locals (GetLocal would previously check for empty values and interpret that as a TDZ access and throw). We now insert special ThrowIfTDZ instructions in places where a local access may be in the TDZ, to maintain the correct behavior. There are a number of progressions and regressions from this test: A number of async generator tests have been accidentally fixed while converting the implementation to the new bytecode format. It didn't seem useful to preserve bugs in the original code when converting it. Some "does eval() return the correct completion value" tests have regressed, in particular ones related to propagating the appropriate completion after control flow statements like continue and break. These are all fairly obscure issues, and I believe we can continue working on them separately. The net test262 result is a progression though. :^)
2024-02-04 08:00:54 +01:00
return ByteString::formatted("ThrowIfNullish {}",
format_operand("src"sv, m_src, executable));
}
ByteString ThrowIfTDZ::to_byte_string_impl(Bytecode::Executable const& executable) const
{
return ByteString::formatted("ThrowIfTDZ {}",
format_operand("src"sv, m_src, executable));
LibJS: Move all bytecode instruction implementations to Interpreter.cpp This allows aggressive inlining without LTO.
2023-09-27 10:10:00 +02:00
}
Everywhere: Rename {Deprecated => Byte}String This commit un-deprecates DeprecatedString, and repurposes it as a byte string. As the null state has already been removed, there are no other particularly hairy blockers in repurposing this type as a byte string (what it _really_ is). This commit is auto-generated: $ xs=$(ack -l \bDeprecatedString\b\|deprecated_string AK Userland \ Meta Ports Ladybird Tests Kernel) $ perl -pie 's/\bDeprecatedString\b/ByteString/g; s/deprecated_string/byte_string/g' $xs $ clang-format --style=file -i \ $(git diff --name-only | grep \.cpp\|\.h) $ gn format $(git ls-files '*.gn' '*.gni')
2023-12-16 17:49:34 +03:30
ByteString EnterUnwindContext::to_byte_string_impl(Bytecode::Executable const&) const
LibJS: Move all bytecode instruction implementations to Interpreter.cpp This allows aggressive inlining without LTO.
2023-09-27 10:10:00 +02:00
{
Everywhere: Rename {Deprecated => Byte}String This commit un-deprecates DeprecatedString, and repurposes it as a byte string. As the null state has already been removed, there are no other particularly hairy blockers in repurposing this type as a byte string (what it _really_ is). This commit is auto-generated: $ xs=$(ack -l \bDeprecatedString\b\|deprecated_string AK Userland \ Meta Ports Ladybird Tests Kernel) $ perl -pie 's/\bDeprecatedString\b/ByteString/g; s/deprecated_string/byte_string/g' $xs $ clang-format --style=file -i \ $(git diff --name-only | grep \.cpp\|\.h) $ gn format $(git ls-files '*.gn' '*.gni')
2023-12-16 17:49:34 +03:30
return ByteString::formatted("EnterUnwindContext entry:{}", m_entry_point);
LibJS: Move all bytecode instruction implementations to Interpreter.cpp This allows aggressive inlining without LTO.
2023-09-27 10:10:00 +02:00
}
Everywhere: Rename {Deprecated => Byte}String This commit un-deprecates DeprecatedString, and repurposes it as a byte string. As the null state has already been removed, there are no other particularly hairy blockers in repurposing this type as a byte string (what it _really_ is). This commit is auto-generated: $ xs=$(ack -l \bDeprecatedString\b\|deprecated_string AK Userland \ Meta Ports Ladybird Tests Kernel) $ perl -pie 's/\bDeprecatedString\b/ByteString/g; s/deprecated_string/byte_string/g' $xs $ clang-format --style=file -i \ $(git diff --name-only | grep \.cpp\|\.h) $ gn format $(git ls-files '*.gn' '*.gni')
2023-12-16 17:49:34 +03:30
ByteString ScheduleJump::to_byte_string_impl(Bytecode::Executable const&) const
LibJS: Move all bytecode instruction implementations to Interpreter.cpp This allows aggressive inlining without LTO.
2023-09-27 10:10:00 +02:00
{
Everywhere: Rename {Deprecated => Byte}String This commit un-deprecates DeprecatedString, and repurposes it as a byte string. As the null state has already been removed, there are no other particularly hairy blockers in repurposing this type as a byte string (what it _really_ is). This commit is auto-generated: $ xs=$(ack -l \bDeprecatedString\b\|deprecated_string AK Userland \ Meta Ports Ladybird Tests Kernel) $ perl -pie 's/\bDeprecatedString\b/ByteString/g; s/deprecated_string/byte_string/g' $xs $ clang-format --style=file -i \ $(git diff --name-only | grep \.cpp\|\.h) $ gn format $(git ls-files '*.gn' '*.gni')
2023-12-16 17:49:34 +03:30
return ByteString::formatted("ScheduleJump {}", m_target);
LibJS: Move all bytecode instruction implementations to Interpreter.cpp This allows aggressive inlining without LTO.
2023-09-27 10:10:00 +02:00
}
Everywhere: Rename {Deprecated => Byte}String This commit un-deprecates DeprecatedString, and repurposes it as a byte string. As the null state has already been removed, there are no other particularly hairy blockers in repurposing this type as a byte string (what it _really_ is). This commit is auto-generated: $ xs=$(ack -l \bDeprecatedString\b\|deprecated_string AK Userland \ Meta Ports Ladybird Tests Kernel) $ perl -pie 's/\bDeprecatedString\b/ByteString/g; s/deprecated_string/byte_string/g' $xs $ clang-format --style=file -i \ $(git diff --name-only | grep \.cpp\|\.h) $ gn format $(git ls-files '*.gn' '*.gni')
2023-12-16 17:49:34 +03:30
ByteString LeaveLexicalEnvironment::to_byte_string_impl(Bytecode::Executable const&) const
LibJS: Move all bytecode instruction implementations to Interpreter.cpp This allows aggressive inlining without LTO.
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{
return "LeaveLexicalEnvironment"sv;
}
Everywhere: Rename {Deprecated => Byte}String This commit un-deprecates DeprecatedString, and repurposes it as a byte string. As the null state has already been removed, there are no other particularly hairy blockers in repurposing this type as a byte string (what it _really_ is). This commit is auto-generated: $ xs=$(ack -l \bDeprecatedString\b\|deprecated_string AK Userland \ Meta Ports Ladybird Tests Kernel) $ perl -pie 's/\bDeprecatedString\b/ByteString/g; s/deprecated_string/byte_string/g' $xs $ clang-format --style=file -i \ $(git diff --name-only | grep \.cpp\|\.h) $ gn format $(git ls-files '*.gn' '*.gni')
2023-12-16 17:49:34 +03:30
ByteString LeaveUnwindContext::to_byte_string_impl(Bytecode::Executable const&) const
LibJS: Move all bytecode instruction implementations to Interpreter.cpp This allows aggressive inlining without LTO.
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{
return "LeaveUnwindContext";
}
Everywhere: Rename {Deprecated => Byte}String This commit un-deprecates DeprecatedString, and repurposes it as a byte string. As the null state has already been removed, there are no other particularly hairy blockers in repurposing this type as a byte string (what it _really_ is). This commit is auto-generated: $ xs=$(ack -l \bDeprecatedString\b\|deprecated_string AK Userland \ Meta Ports Ladybird Tests Kernel) $ perl -pie 's/\bDeprecatedString\b/ByteString/g; s/deprecated_string/byte_string/g' $xs $ clang-format --style=file -i \ $(git diff --name-only | grep \.cpp\|\.h) $ gn format $(git ls-files '*.gn' '*.gni')
2023-12-16 17:49:34 +03:30
ByteString ContinuePendingUnwind::to_byte_string_impl(Bytecode::Executable const&) const
LibJS: Move all bytecode instruction implementations to Interpreter.cpp This allows aggressive inlining without LTO.
2023-09-27 10:10:00 +02:00
{
Everywhere: Rename {Deprecated => Byte}String This commit un-deprecates DeprecatedString, and repurposes it as a byte string. As the null state has already been removed, there are no other particularly hairy blockers in repurposing this type as a byte string (what it _really_ is). This commit is auto-generated: $ xs=$(ack -l \bDeprecatedString\b\|deprecated_string AK Userland \ Meta Ports Ladybird Tests Kernel) $ perl -pie 's/\bDeprecatedString\b/ByteString/g; s/deprecated_string/byte_string/g' $xs $ clang-format --style=file -i \ $(git diff --name-only | grep \.cpp\|\.h) $ gn format $(git ls-files '*.gn' '*.gni')
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return ByteString::formatted("ContinuePendingUnwind resume:{}", m_resume_target);
LibJS: Move all bytecode instruction implementations to Interpreter.cpp This allows aggressive inlining without LTO.
2023-09-27 10:10:00 +02:00
}
LibJS/Bytecode: Move to a new bytecode format This patch moves us away from the accumulator-based bytecode format to one with explicit source and destination registers. The new format has multiple benefits: - ~25% faster on the Kraken and Octane benchmarks :^) - Fewer instructions to accomplish the same thing - Much easier for humans to read(!) Because this change requires a fundamental shift in how bytecode is generated, it is quite comprehensive. Main implementation mechanism: generate_bytecode() virtual function now takes an optional "preferred dst" operand, which allows callers to communicate when they have an operand that would be optimal for the result to go into. It also returns an optional "actual dst" operand, which is where the completion value (if any) of the AST node is stored after the node has "executed". One thing of note that's new: because instructions can now take locals as operands, this means we got rid of the GetLocal instruction. A side-effect of that is we have to think about the temporal deadzone (TDZ) a bit differently for locals (GetLocal would previously check for empty values and interpret that as a TDZ access and throw). We now insert special ThrowIfTDZ instructions in places where a local access may be in the TDZ, to maintain the correct behavior. There are a number of progressions and regressions from this test: A number of async generator tests have been accidentally fixed while converting the implementation to the new bytecode format. It didn't seem useful to preserve bugs in the original code when converting it. Some "does eval() return the correct completion value" tests have regressed, in particular ones related to propagating the appropriate completion after control flow statements like continue and break. These are all fairly obscure issues, and I believe we can continue working on them separately. The net test262 result is a progression though. :^)
2024-02-04 08:00:54 +01:00
ByteString Yield::to_byte_string_impl(Bytecode::Executable const& executable) const
LibJS: Move all bytecode instruction implementations to Interpreter.cpp This allows aggressive inlining without LTO.
2023-09-27 10:10:00 +02:00
{
LibJS/Bytecode: Move to a new bytecode format This patch moves us away from the accumulator-based bytecode format to one with explicit source and destination registers. The new format has multiple benefits: - ~25% faster on the Kraken and Octane benchmarks :^) - Fewer instructions to accomplish the same thing - Much easier for humans to read(!) Because this change requires a fundamental shift in how bytecode is generated, it is quite comprehensive. Main implementation mechanism: generate_bytecode() virtual function now takes an optional "preferred dst" operand, which allows callers to communicate when they have an operand that would be optimal for the result to go into. It also returns an optional "actual dst" operand, which is where the completion value (if any) of the AST node is stored after the node has "executed". One thing of note that's new: because instructions can now take locals as operands, this means we got rid of the GetLocal instruction. A side-effect of that is we have to think about the temporal deadzone (TDZ) a bit differently for locals (GetLocal would previously check for empty values and interpret that as a TDZ access and throw). We now insert special ThrowIfTDZ instructions in places where a local access may be in the TDZ, to maintain the correct behavior. There are a number of progressions and regressions from this test: A number of async generator tests have been accidentally fixed while converting the implementation to the new bytecode format. It didn't seem useful to preserve bugs in the original code when converting it. Some "does eval() return the correct completion value" tests have regressed, in particular ones related to propagating the appropriate completion after control flow statements like continue and break. These are all fairly obscure issues, and I believe we can continue working on them separately. The net test262 result is a progression though. :^)
2024-02-04 08:00:54 +01:00
if (m_continuation_label.has_value()) {
LibJS/Bytecode: Flatten bytecode to a contiguous representation Instead of keeping bytecode as a set of disjoint basic blocks on the malloc heap, bytecode is now a contiguous sequence of bytes(!) The transformation happens at the end of Bytecode::Generator::generate() and the only really hairy part is rerouting jump labels. This required solving a few problems: - The interpreter execution loop had to change quite a bit, since we were storing BasicBlock pointers all over the place, and control transfer was done by redirecting the interpreter's current block. - Exception handlers & finalizers are now stored per-bytecode-range in a side table in Executable. - The interpreter now has a plain program counter instead of a stream iterator. This actually makes error stack generation a bit nicer since we just have to deal with a number instead of reaching into the iterator. This yields a 25% performance improvement on this microbenchmark: for (let i = 0; i < 1_000_000; ++i) { } But basically everything gets faster. :^)
2024-05-06 06:44:08 +02:00
return ByteString::formatted("Yield continuation:{}, {}",
m_continuation_label.value(),
LibJS/Bytecode: Move to a new bytecode format This patch moves us away from the accumulator-based bytecode format to one with explicit source and destination registers. The new format has multiple benefits: - ~25% faster on the Kraken and Octane benchmarks :^) - Fewer instructions to accomplish the same thing - Much easier for humans to read(!) Because this change requires a fundamental shift in how bytecode is generated, it is quite comprehensive. Main implementation mechanism: generate_bytecode() virtual function now takes an optional "preferred dst" operand, which allows callers to communicate when they have an operand that would be optimal for the result to go into. It also returns an optional "actual dst" operand, which is where the completion value (if any) of the AST node is stored after the node has "executed". One thing of note that's new: because instructions can now take locals as operands, this means we got rid of the GetLocal instruction. A side-effect of that is we have to think about the temporal deadzone (TDZ) a bit differently for locals (GetLocal would previously check for empty values and interpret that as a TDZ access and throw). We now insert special ThrowIfTDZ instructions in places where a local access may be in the TDZ, to maintain the correct behavior. There are a number of progressions and regressions from this test: A number of async generator tests have been accidentally fixed while converting the implementation to the new bytecode format. It didn't seem useful to preserve bugs in the original code when converting it. Some "does eval() return the correct completion value" tests have regressed, in particular ones related to propagating the appropriate completion after control flow statements like continue and break. These are all fairly obscure issues, and I believe we can continue working on them separately. The net test262 result is a progression though. :^)
2024-02-04 08:00:54 +01:00
format_operand("value"sv, m_value, executable));
}
return ByteString::formatted("Yield return {}",
format_operand("value"sv, m_value, executable));
LibJS: Move all bytecode instruction implementations to Interpreter.cpp This allows aggressive inlining without LTO.
2023-09-27 10:10:00 +02:00
}
LibJS/Bytecode: Move to a new bytecode format This patch moves us away from the accumulator-based bytecode format to one with explicit source and destination registers. The new format has multiple benefits: - ~25% faster on the Kraken and Octane benchmarks :^) - Fewer instructions to accomplish the same thing - Much easier for humans to read(!) Because this change requires a fundamental shift in how bytecode is generated, it is quite comprehensive. Main implementation mechanism: generate_bytecode() virtual function now takes an optional "preferred dst" operand, which allows callers to communicate when they have an operand that would be optimal for the result to go into. It also returns an optional "actual dst" operand, which is where the completion value (if any) of the AST node is stored after the node has "executed". One thing of note that's new: because instructions can now take locals as operands, this means we got rid of the GetLocal instruction. A side-effect of that is we have to think about the temporal deadzone (TDZ) a bit differently for locals (GetLocal would previously check for empty values and interpret that as a TDZ access and throw). We now insert special ThrowIfTDZ instructions in places where a local access may be in the TDZ, to maintain the correct behavior. There are a number of progressions and regressions from this test: A number of async generator tests have been accidentally fixed while converting the implementation to the new bytecode format. It didn't seem useful to preserve bugs in the original code when converting it. Some "does eval() return the correct completion value" tests have regressed, in particular ones related to propagating the appropriate completion after control flow statements like continue and break. These are all fairly obscure issues, and I believe we can continue working on them separately. The net test262 result is a progression though. :^)
2024-02-04 08:00:54 +01:00
ByteString Await::to_byte_string_impl(Bytecode::Executable const& executable) const
LibJS: Move all bytecode instruction implementations to Interpreter.cpp This allows aggressive inlining without LTO.
2023-09-27 10:10:00 +02:00
{
LibJS/Bytecode: Flatten bytecode to a contiguous representation Instead of keeping bytecode as a set of disjoint basic blocks on the malloc heap, bytecode is now a contiguous sequence of bytes(!) The transformation happens at the end of Bytecode::Generator::generate() and the only really hairy part is rerouting jump labels. This required solving a few problems: - The interpreter execution loop had to change quite a bit, since we were storing BasicBlock pointers all over the place, and control transfer was done by redirecting the interpreter's current block. - Exception handlers & finalizers are now stored per-bytecode-range in a side table in Executable. - The interpreter now has a plain program counter instead of a stream iterator. This actually makes error stack generation a bit nicer since we just have to deal with a number instead of reaching into the iterator. This yields a 25% performance improvement on this microbenchmark: for (let i = 0; i < 1_000_000; ++i) { } But basically everything gets faster. :^)
2024-05-06 06:44:08 +02:00
return ByteString::formatted("Await {}, continuation:{}",
LibJS/Bytecode: Move to a new bytecode format This patch moves us away from the accumulator-based bytecode format to one with explicit source and destination registers. The new format has multiple benefits: - ~25% faster on the Kraken and Octane benchmarks :^) - Fewer instructions to accomplish the same thing - Much easier for humans to read(!) Because this change requires a fundamental shift in how bytecode is generated, it is quite comprehensive. Main implementation mechanism: generate_bytecode() virtual function now takes an optional "preferred dst" operand, which allows callers to communicate when they have an operand that would be optimal for the result to go into. It also returns an optional "actual dst" operand, which is where the completion value (if any) of the AST node is stored after the node has "executed". One thing of note that's new: because instructions can now take locals as operands, this means we got rid of the GetLocal instruction. A side-effect of that is we have to think about the temporal deadzone (TDZ) a bit differently for locals (GetLocal would previously check for empty values and interpret that as a TDZ access and throw). We now insert special ThrowIfTDZ instructions in places where a local access may be in the TDZ, to maintain the correct behavior. There are a number of progressions and regressions from this test: A number of async generator tests have been accidentally fixed while converting the implementation to the new bytecode format. It didn't seem useful to preserve bugs in the original code when converting it. Some "does eval() return the correct completion value" tests have regressed, in particular ones related to propagating the appropriate completion after control flow statements like continue and break. These are all fairly obscure issues, and I believe we can continue working on them separately. The net test262 result is a progression though. :^)
2024-02-04 08:00:54 +01:00
format_operand("argument"sv, m_argument, executable),
LibJS/Bytecode: Flatten bytecode to a contiguous representation Instead of keeping bytecode as a set of disjoint basic blocks on the malloc heap, bytecode is now a contiguous sequence of bytes(!) The transformation happens at the end of Bytecode::Generator::generate() and the only really hairy part is rerouting jump labels. This required solving a few problems: - The interpreter execution loop had to change quite a bit, since we were storing BasicBlock pointers all over the place, and control transfer was done by redirecting the interpreter's current block. - Exception handlers & finalizers are now stored per-bytecode-range in a side table in Executable. - The interpreter now has a plain program counter instead of a stream iterator. This actually makes error stack generation a bit nicer since we just have to deal with a number instead of reaching into the iterator. This yields a 25% performance improvement on this microbenchmark: for (let i = 0; i < 1_000_000; ++i) { } But basically everything gets faster. :^)
2024-05-06 06:44:08 +02:00
m_continuation_label);
LibJS: Move all bytecode instruction implementations to Interpreter.cpp This allows aggressive inlining without LTO.
2023-09-27 10:10:00 +02:00
}
LibJS/Bytecode: Move to a new bytecode format This patch moves us away from the accumulator-based bytecode format to one with explicit source and destination registers. The new format has multiple benefits: - ~25% faster on the Kraken and Octane benchmarks :^) - Fewer instructions to accomplish the same thing - Much easier for humans to read(!) Because this change requires a fundamental shift in how bytecode is generated, it is quite comprehensive. Main implementation mechanism: generate_bytecode() virtual function now takes an optional "preferred dst" operand, which allows callers to communicate when they have an operand that would be optimal for the result to go into. It also returns an optional "actual dst" operand, which is where the completion value (if any) of the AST node is stored after the node has "executed". One thing of note that's new: because instructions can now take locals as operands, this means we got rid of the GetLocal instruction. A side-effect of that is we have to think about the temporal deadzone (TDZ) a bit differently for locals (GetLocal would previously check for empty values and interpret that as a TDZ access and throw). We now insert special ThrowIfTDZ instructions in places where a local access may be in the TDZ, to maintain the correct behavior. There are a number of progressions and regressions from this test: A number of async generator tests have been accidentally fixed while converting the implementation to the new bytecode format. It didn't seem useful to preserve bugs in the original code when converting it. Some "does eval() return the correct completion value" tests have regressed, in particular ones related to propagating the appropriate completion after control flow statements like continue and break. These are all fairly obscure issues, and I believe we can continue working on them separately. The net test262 result is a progression though. :^)
2024-02-04 08:00:54 +01:00
ByteString GetByValue::to_byte_string_impl(Bytecode::Executable const& executable) const
LibJS: Move all bytecode instruction implementations to Interpreter.cpp This allows aggressive inlining without LTO.
2023-09-27 10:10:00 +02:00
{
LibJS/Bytecode: Move to a new bytecode format This patch moves us away from the accumulator-based bytecode format to one with explicit source and destination registers. The new format has multiple benefits: - ~25% faster on the Kraken and Octane benchmarks :^) - Fewer instructions to accomplish the same thing - Much easier for humans to read(!) Because this change requires a fundamental shift in how bytecode is generated, it is quite comprehensive. Main implementation mechanism: generate_bytecode() virtual function now takes an optional "preferred dst" operand, which allows callers to communicate when they have an operand that would be optimal for the result to go into. It also returns an optional "actual dst" operand, which is where the completion value (if any) of the AST node is stored after the node has "executed". One thing of note that's new: because instructions can now take locals as operands, this means we got rid of the GetLocal instruction. A side-effect of that is we have to think about the temporal deadzone (TDZ) a bit differently for locals (GetLocal would previously check for empty values and interpret that as a TDZ access and throw). We now insert special ThrowIfTDZ instructions in places where a local access may be in the TDZ, to maintain the correct behavior. There are a number of progressions and regressions from this test: A number of async generator tests have been accidentally fixed while converting the implementation to the new bytecode format. It didn't seem useful to preserve bugs in the original code when converting it. Some "does eval() return the correct completion value" tests have regressed, in particular ones related to propagating the appropriate completion after control flow statements like continue and break. These are all fairly obscure issues, and I believe we can continue working on them separately. The net test262 result is a progression though. :^)
2024-02-04 08:00:54 +01:00
return ByteString::formatted("GetByValue {}, {}, {}",
format_operand("dst"sv, m_dst, executable),
format_operand("base"sv, m_base, executable),
format_operand("property"sv, m_property, executable));
LibJS: Move all bytecode instruction implementations to Interpreter.cpp This allows aggressive inlining without LTO.
2023-09-27 10:10:00 +02:00
}
LibJS/Bytecode: Move to a new bytecode format This patch moves us away from the accumulator-based bytecode format to one with explicit source and destination registers. The new format has multiple benefits: - ~25% faster on the Kraken and Octane benchmarks :^) - Fewer instructions to accomplish the same thing - Much easier for humans to read(!) Because this change requires a fundamental shift in how bytecode is generated, it is quite comprehensive. Main implementation mechanism: generate_bytecode() virtual function now takes an optional "preferred dst" operand, which allows callers to communicate when they have an operand that would be optimal for the result to go into. It also returns an optional "actual dst" operand, which is where the completion value (if any) of the AST node is stored after the node has "executed". One thing of note that's new: because instructions can now take locals as operands, this means we got rid of the GetLocal instruction. A side-effect of that is we have to think about the temporal deadzone (TDZ) a bit differently for locals (GetLocal would previously check for empty values and interpret that as a TDZ access and throw). We now insert special ThrowIfTDZ instructions in places where a local access may be in the TDZ, to maintain the correct behavior. There are a number of progressions and regressions from this test: A number of async generator tests have been accidentally fixed while converting the implementation to the new bytecode format. It didn't seem useful to preserve bugs in the original code when converting it. Some "does eval() return the correct completion value" tests have regressed, in particular ones related to propagating the appropriate completion after control flow statements like continue and break. These are all fairly obscure issues, and I believe we can continue working on them separately. The net test262 result is a progression though. :^)
2024-02-04 08:00:54 +01:00
ByteString GetByValueWithThis::to_byte_string_impl(Bytecode::Executable const& executable) const
LibJS: Move all bytecode instruction implementations to Interpreter.cpp This allows aggressive inlining without LTO.
2023-09-27 10:10:00 +02:00
{
LibJS/Bytecode: Move to a new bytecode format This patch moves us away from the accumulator-based bytecode format to one with explicit source and destination registers. The new format has multiple benefits: - ~25% faster on the Kraken and Octane benchmarks :^) - Fewer instructions to accomplish the same thing - Much easier for humans to read(!) Because this change requires a fundamental shift in how bytecode is generated, it is quite comprehensive. Main implementation mechanism: generate_bytecode() virtual function now takes an optional "preferred dst" operand, which allows callers to communicate when they have an operand that would be optimal for the result to go into. It also returns an optional "actual dst" operand, which is where the completion value (if any) of the AST node is stored after the node has "executed". One thing of note that's new: because instructions can now take locals as operands, this means we got rid of the GetLocal instruction. A side-effect of that is we have to think about the temporal deadzone (TDZ) a bit differently for locals (GetLocal would previously check for empty values and interpret that as a TDZ access and throw). We now insert special ThrowIfTDZ instructions in places where a local access may be in the TDZ, to maintain the correct behavior. There are a number of progressions and regressions from this test: A number of async generator tests have been accidentally fixed while converting the implementation to the new bytecode format. It didn't seem useful to preserve bugs in the original code when converting it. Some "does eval() return the correct completion value" tests have regressed, in particular ones related to propagating the appropriate completion after control flow statements like continue and break. These are all fairly obscure issues, and I believe we can continue working on them separately. The net test262 result is a progression though. :^)
2024-02-04 08:00:54 +01:00
return ByteString::formatted("GetByValueWithThis {}, {}, {}",
format_operand("dst"sv, m_dst, executable),
format_operand("base"sv, m_base, executable),
format_operand("property"sv, m_property, executable));
LibJS: Move all bytecode instruction implementations to Interpreter.cpp This allows aggressive inlining without LTO.
2023-09-27 10:10:00 +02:00
}
LibJS/Bytecode: Move to a new bytecode format This patch moves us away from the accumulator-based bytecode format to one with explicit source and destination registers. The new format has multiple benefits: - ~25% faster on the Kraken and Octane benchmarks :^) - Fewer instructions to accomplish the same thing - Much easier for humans to read(!) Because this change requires a fundamental shift in how bytecode is generated, it is quite comprehensive. Main implementation mechanism: generate_bytecode() virtual function now takes an optional "preferred dst" operand, which allows callers to communicate when they have an operand that would be optimal for the result to go into. It also returns an optional "actual dst" operand, which is where the completion value (if any) of the AST node is stored after the node has "executed". One thing of note that's new: because instructions can now take locals as operands, this means we got rid of the GetLocal instruction. A side-effect of that is we have to think about the temporal deadzone (TDZ) a bit differently for locals (GetLocal would previously check for empty values and interpret that as a TDZ access and throw). We now insert special ThrowIfTDZ instructions in places where a local access may be in the TDZ, to maintain the correct behavior. There are a number of progressions and regressions from this test: A number of async generator tests have been accidentally fixed while converting the implementation to the new bytecode format. It didn't seem useful to preserve bugs in the original code when converting it. Some "does eval() return the correct completion value" tests have regressed, in particular ones related to propagating the appropriate completion after control flow statements like continue and break. These are all fairly obscure issues, and I believe we can continue working on them separately. The net test262 result is a progression though. :^)
2024-02-04 08:00:54 +01:00
ByteString PutByValue::to_byte_string_impl(Bytecode::Executable const& executable) const
LibJS: Move all bytecode instruction implementations to Interpreter.cpp This allows aggressive inlining without LTO.
2023-09-27 10:10:00 +02:00
{
auto kind = property_kind_to_string(m_kind);
LibJS/Bytecode: Move to a new bytecode format This patch moves us away from the accumulator-based bytecode format to one with explicit source and destination registers. The new format has multiple benefits: - ~25% faster on the Kraken and Octane benchmarks :^) - Fewer instructions to accomplish the same thing - Much easier for humans to read(!) Because this change requires a fundamental shift in how bytecode is generated, it is quite comprehensive. Main implementation mechanism: generate_bytecode() virtual function now takes an optional "preferred dst" operand, which allows callers to communicate when they have an operand that would be optimal for the result to go into. It also returns an optional "actual dst" operand, which is where the completion value (if any) of the AST node is stored after the node has "executed". One thing of note that's new: because instructions can now take locals as operands, this means we got rid of the GetLocal instruction. A side-effect of that is we have to think about the temporal deadzone (TDZ) a bit differently for locals (GetLocal would previously check for empty values and interpret that as a TDZ access and throw). We now insert special ThrowIfTDZ instructions in places where a local access may be in the TDZ, to maintain the correct behavior. There are a number of progressions and regressions from this test: A number of async generator tests have been accidentally fixed while converting the implementation to the new bytecode format. It didn't seem useful to preserve bugs in the original code when converting it. Some "does eval() return the correct completion value" tests have regressed, in particular ones related to propagating the appropriate completion after control flow statements like continue and break. These are all fairly obscure issues, and I believe we can continue working on them separately. The net test262 result is a progression though. :^)
2024-02-04 08:00:54 +01:00
return ByteString::formatted("PutByValue {}, {}, {}, kind:{}",
format_operand("base"sv, m_base, executable),
format_operand("property"sv, m_property, executable),
format_operand("src"sv, m_src, executable),
kind);
LibJS: Move all bytecode instruction implementations to Interpreter.cpp This allows aggressive inlining without LTO.
2023-09-27 10:10:00 +02:00
}
LibJS/Bytecode: Move to a new bytecode format This patch moves us away from the accumulator-based bytecode format to one with explicit source and destination registers. The new format has multiple benefits: - ~25% faster on the Kraken and Octane benchmarks :^) - Fewer instructions to accomplish the same thing - Much easier for humans to read(!) Because this change requires a fundamental shift in how bytecode is generated, it is quite comprehensive. Main implementation mechanism: generate_bytecode() virtual function now takes an optional "preferred dst" operand, which allows callers to communicate when they have an operand that would be optimal for the result to go into. It also returns an optional "actual dst" operand, which is where the completion value (if any) of the AST node is stored after the node has "executed". One thing of note that's new: because instructions can now take locals as operands, this means we got rid of the GetLocal instruction. A side-effect of that is we have to think about the temporal deadzone (TDZ) a bit differently for locals (GetLocal would previously check for empty values and interpret that as a TDZ access and throw). We now insert special ThrowIfTDZ instructions in places where a local access may be in the TDZ, to maintain the correct behavior. There are a number of progressions and regressions from this test: A number of async generator tests have been accidentally fixed while converting the implementation to the new bytecode format. It didn't seem useful to preserve bugs in the original code when converting it. Some "does eval() return the correct completion value" tests have regressed, in particular ones related to propagating the appropriate completion after control flow statements like continue and break. These are all fairly obscure issues, and I believe we can continue working on them separately. The net test262 result is a progression though. :^)
2024-02-04 08:00:54 +01:00
ByteString PutByValueWithThis::to_byte_string_impl(Bytecode::Executable const& executable) const
LibJS: Move all bytecode instruction implementations to Interpreter.cpp This allows aggressive inlining without LTO.
2023-09-27 10:10:00 +02:00
{
auto kind = property_kind_to_string(m_kind);
LibJS/Bytecode: Move to a new bytecode format This patch moves us away from the accumulator-based bytecode format to one with explicit source and destination registers. The new format has multiple benefits: - ~25% faster on the Kraken and Octane benchmarks :^) - Fewer instructions to accomplish the same thing - Much easier for humans to read(!) Because this change requires a fundamental shift in how bytecode is generated, it is quite comprehensive. Main implementation mechanism: generate_bytecode() virtual function now takes an optional "preferred dst" operand, which allows callers to communicate when they have an operand that would be optimal for the result to go into. It also returns an optional "actual dst" operand, which is where the completion value (if any) of the AST node is stored after the node has "executed". One thing of note that's new: because instructions can now take locals as operands, this means we got rid of the GetLocal instruction. A side-effect of that is we have to think about the temporal deadzone (TDZ) a bit differently for locals (GetLocal would previously check for empty values and interpret that as a TDZ access and throw). We now insert special ThrowIfTDZ instructions in places where a local access may be in the TDZ, to maintain the correct behavior. There are a number of progressions and regressions from this test: A number of async generator tests have been accidentally fixed while converting the implementation to the new bytecode format. It didn't seem useful to preserve bugs in the original code when converting it. Some "does eval() return the correct completion value" tests have regressed, in particular ones related to propagating the appropriate completion after control flow statements like continue and break. These are all fairly obscure issues, and I believe we can continue working on them separately. The net test262 result is a progression though. :^)
2024-02-04 08:00:54 +01:00
return ByteString::formatted("PutByValueWithThis {}, {}, {}, {}, kind:{}",
format_operand("base"sv, m_base, executable),
format_operand("property"sv, m_property, executable),
format_operand("src"sv, m_src, executable),
format_operand("this"sv, m_this_value, executable),
kind);
LibJS: Move all bytecode instruction implementations to Interpreter.cpp This allows aggressive inlining without LTO.
2023-09-27 10:10:00 +02:00
}
LibJS/Bytecode: Move to a new bytecode format This patch moves us away from the accumulator-based bytecode format to one with explicit source and destination registers. The new format has multiple benefits: - ~25% faster on the Kraken and Octane benchmarks :^) - Fewer instructions to accomplish the same thing - Much easier for humans to read(!) Because this change requires a fundamental shift in how bytecode is generated, it is quite comprehensive. Main implementation mechanism: generate_bytecode() virtual function now takes an optional "preferred dst" operand, which allows callers to communicate when they have an operand that would be optimal for the result to go into. It also returns an optional "actual dst" operand, which is where the completion value (if any) of the AST node is stored after the node has "executed". One thing of note that's new: because instructions can now take locals as operands, this means we got rid of the GetLocal instruction. A side-effect of that is we have to think about the temporal deadzone (TDZ) a bit differently for locals (GetLocal would previously check for empty values and interpret that as a TDZ access and throw). We now insert special ThrowIfTDZ instructions in places where a local access may be in the TDZ, to maintain the correct behavior. There are a number of progressions and regressions from this test: A number of async generator tests have been accidentally fixed while converting the implementation to the new bytecode format. It didn't seem useful to preserve bugs in the original code when converting it. Some "does eval() return the correct completion value" tests have regressed, in particular ones related to propagating the appropriate completion after control flow statements like continue and break. These are all fairly obscure issues, and I believe we can continue working on them separately. The net test262 result is a progression though. :^)
2024-02-04 08:00:54 +01:00
ByteString DeleteByValue::to_byte_string_impl(Bytecode::Executable const& executable) const
LibJS: Move all bytecode instruction implementations to Interpreter.cpp This allows aggressive inlining without LTO.
2023-09-27 10:10:00 +02:00
{
LibJS/Bytecode: Move to a new bytecode format This patch moves us away from the accumulator-based bytecode format to one with explicit source and destination registers. The new format has multiple benefits: - ~25% faster on the Kraken and Octane benchmarks :^) - Fewer instructions to accomplish the same thing - Much easier for humans to read(!) Because this change requires a fundamental shift in how bytecode is generated, it is quite comprehensive. Main implementation mechanism: generate_bytecode() virtual function now takes an optional "preferred dst" operand, which allows callers to communicate when they have an operand that would be optimal for the result to go into. It also returns an optional "actual dst" operand, which is where the completion value (if any) of the AST node is stored after the node has "executed". One thing of note that's new: because instructions can now take locals as operands, this means we got rid of the GetLocal instruction. A side-effect of that is we have to think about the temporal deadzone (TDZ) a bit differently for locals (GetLocal would previously check for empty values and interpret that as a TDZ access and throw). We now insert special ThrowIfTDZ instructions in places where a local access may be in the TDZ, to maintain the correct behavior. There are a number of progressions and regressions from this test: A number of async generator tests have been accidentally fixed while converting the implementation to the new bytecode format. It didn't seem useful to preserve bugs in the original code when converting it. Some "does eval() return the correct completion value" tests have regressed, in particular ones related to propagating the appropriate completion after control flow statements like continue and break. These are all fairly obscure issues, and I believe we can continue working on them separately. The net test262 result is a progression though. :^)
2024-02-04 08:00:54 +01:00
return ByteString::formatted("DeleteByValue {}, {}, {}",
format_operand("dst"sv, dst(), executable),
format_operand("base"sv, m_base, executable),
format_operand("property"sv, m_property, executable));
LibJS: Move all bytecode instruction implementations to Interpreter.cpp This allows aggressive inlining without LTO.
2023-09-27 10:10:00 +02:00
}
LibJS/Bytecode: Move to a new bytecode format This patch moves us away from the accumulator-based bytecode format to one with explicit source and destination registers. The new format has multiple benefits: - ~25% faster on the Kraken and Octane benchmarks :^) - Fewer instructions to accomplish the same thing - Much easier for humans to read(!) Because this change requires a fundamental shift in how bytecode is generated, it is quite comprehensive. Main implementation mechanism: generate_bytecode() virtual function now takes an optional "preferred dst" operand, which allows callers to communicate when they have an operand that would be optimal for the result to go into. It also returns an optional "actual dst" operand, which is where the completion value (if any) of the AST node is stored after the node has "executed". One thing of note that's new: because instructions can now take locals as operands, this means we got rid of the GetLocal instruction. A side-effect of that is we have to think about the temporal deadzone (TDZ) a bit differently for locals (GetLocal would previously check for empty values and interpret that as a TDZ access and throw). We now insert special ThrowIfTDZ instructions in places where a local access may be in the TDZ, to maintain the correct behavior. There are a number of progressions and regressions from this test: A number of async generator tests have been accidentally fixed while converting the implementation to the new bytecode format. It didn't seem useful to preserve bugs in the original code when converting it. Some "does eval() return the correct completion value" tests have regressed, in particular ones related to propagating the appropriate completion after control flow statements like continue and break. These are all fairly obscure issues, and I believe we can continue working on them separately. The net test262 result is a progression though. :^)
2024-02-04 08:00:54 +01:00
ByteString DeleteByValueWithThis::to_byte_string_impl(Bytecode::Executable const& executable) const
LibJS: Move all bytecode instruction implementations to Interpreter.cpp This allows aggressive inlining without LTO.
2023-09-27 10:10:00 +02:00
{
LibJS/Bytecode: Move to a new bytecode format This patch moves us away from the accumulator-based bytecode format to one with explicit source and destination registers. The new format has multiple benefits: - ~25% faster on the Kraken and Octane benchmarks :^) - Fewer instructions to accomplish the same thing - Much easier for humans to read(!) Because this change requires a fundamental shift in how bytecode is generated, it is quite comprehensive. Main implementation mechanism: generate_bytecode() virtual function now takes an optional "preferred dst" operand, which allows callers to communicate when they have an operand that would be optimal for the result to go into. It also returns an optional "actual dst" operand, which is where the completion value (if any) of the AST node is stored after the node has "executed". One thing of note that's new: because instructions can now take locals as operands, this means we got rid of the GetLocal instruction. A side-effect of that is we have to think about the temporal deadzone (TDZ) a bit differently for locals (GetLocal would previously check for empty values and interpret that as a TDZ access and throw). We now insert special ThrowIfTDZ instructions in places where a local access may be in the TDZ, to maintain the correct behavior. There are a number of progressions and regressions from this test: A number of async generator tests have been accidentally fixed while converting the implementation to the new bytecode format. It didn't seem useful to preserve bugs in the original code when converting it. Some "does eval() return the correct completion value" tests have regressed, in particular ones related to propagating the appropriate completion after control flow statements like continue and break. These are all fairly obscure issues, and I believe we can continue working on them separately. The net test262 result is a progression though. :^)
2024-02-04 08:00:54 +01:00
return ByteString::formatted("DeleteByValueWithThis {}, {}, {}, {}",
format_operand("dst"sv, dst(), executable),
format_operand("base"sv, m_base, executable),
format_operand("property"sv, m_property, executable),
format_operand("this"sv, m_this_value, executable));
LibJS: Move all bytecode instruction implementations to Interpreter.cpp This allows aggressive inlining without LTO.
2023-09-27 10:10:00 +02:00
}
LibJS/Bytecode: Move to a new bytecode format This patch moves us away from the accumulator-based bytecode format to one with explicit source and destination registers. The new format has multiple benefits: - ~25% faster on the Kraken and Octane benchmarks :^) - Fewer instructions to accomplish the same thing - Much easier for humans to read(!) Because this change requires a fundamental shift in how bytecode is generated, it is quite comprehensive. Main implementation mechanism: generate_bytecode() virtual function now takes an optional "preferred dst" operand, which allows callers to communicate when they have an operand that would be optimal for the result to go into. It also returns an optional "actual dst" operand, which is where the completion value (if any) of the AST node is stored after the node has "executed". One thing of note that's new: because instructions can now take locals as operands, this means we got rid of the GetLocal instruction. A side-effect of that is we have to think about the temporal deadzone (TDZ) a bit differently for locals (GetLocal would previously check for empty values and interpret that as a TDZ access and throw). We now insert special ThrowIfTDZ instructions in places where a local access may be in the TDZ, to maintain the correct behavior. There are a number of progressions and regressions from this test: A number of async generator tests have been accidentally fixed while converting the implementation to the new bytecode format. It didn't seem useful to preserve bugs in the original code when converting it. Some "does eval() return the correct completion value" tests have regressed, in particular ones related to propagating the appropriate completion after control flow statements like continue and break. These are all fairly obscure issues, and I believe we can continue working on them separately. The net test262 result is a progression though. :^)
2024-02-04 08:00:54 +01:00
ByteString GetIterator::to_byte_string_impl(Executable const& executable) const
LibJS: Move all bytecode instruction implementations to Interpreter.cpp This allows aggressive inlining without LTO.
2023-09-27 10:10:00 +02:00
{
auto hint = m_hint == IteratorHint::Sync ? "sync" : "async";
LibJS/Bytecode: Move to a new bytecode format This patch moves us away from the accumulator-based bytecode format to one with explicit source and destination registers. The new format has multiple benefits: - ~25% faster on the Kraken and Octane benchmarks :^) - Fewer instructions to accomplish the same thing - Much easier for humans to read(!) Because this change requires a fundamental shift in how bytecode is generated, it is quite comprehensive. Main implementation mechanism: generate_bytecode() virtual function now takes an optional "preferred dst" operand, which allows callers to communicate when they have an operand that would be optimal for the result to go into. It also returns an optional "actual dst" operand, which is where the completion value (if any) of the AST node is stored after the node has "executed". One thing of note that's new: because instructions can now take locals as operands, this means we got rid of the GetLocal instruction. A side-effect of that is we have to think about the temporal deadzone (TDZ) a bit differently for locals (GetLocal would previously check for empty values and interpret that as a TDZ access and throw). We now insert special ThrowIfTDZ instructions in places where a local access may be in the TDZ, to maintain the correct behavior. There are a number of progressions and regressions from this test: A number of async generator tests have been accidentally fixed while converting the implementation to the new bytecode format. It didn't seem useful to preserve bugs in the original code when converting it. Some "does eval() return the correct completion value" tests have regressed, in particular ones related to propagating the appropriate completion after control flow statements like continue and break. These are all fairly obscure issues, and I believe we can continue working on them separately. The net test262 result is a progression though. :^)
2024-02-04 08:00:54 +01:00
return ByteString::formatted("GetIterator {}, {}, hint:{}",
format_operand("dst"sv, m_dst, executable),
format_operand("iterable"sv, m_iterable, executable),
hint);
LibJS: Move all bytecode instruction implementations to Interpreter.cpp This allows aggressive inlining without LTO.
2023-09-27 10:10:00 +02:00
}
Everywhere: Rename {Deprecated => Byte}String This commit un-deprecates DeprecatedString, and repurposes it as a byte string. As the null state has already been removed, there are no other particularly hairy blockers in repurposing this type as a byte string (what it _really_ is). This commit is auto-generated: $ xs=$(ack -l \bDeprecatedString\b\|deprecated_string AK Userland \ Meta Ports Ladybird Tests Kernel) $ perl -pie 's/\bDeprecatedString\b/ByteString/g; s/deprecated_string/byte_string/g' $xs $ clang-format --style=file -i \ $(git diff --name-only | grep \.cpp\|\.h) $ gn format $(git ls-files '*.gn' '*.gni')
2023-12-16 17:49:34 +03:30
ByteString GetMethod::to_byte_string_impl(Bytecode::Executable const& executable) const
LibJS: Move all bytecode instruction implementations to Interpreter.cpp This allows aggressive inlining without LTO.
2023-09-27 10:10:00 +02:00
{
LibJS/Bytecode: Move to a new bytecode format This patch moves us away from the accumulator-based bytecode format to one with explicit source and destination registers. The new format has multiple benefits: - ~25% faster on the Kraken and Octane benchmarks :^) - Fewer instructions to accomplish the same thing - Much easier for humans to read(!) Because this change requires a fundamental shift in how bytecode is generated, it is quite comprehensive. Main implementation mechanism: generate_bytecode() virtual function now takes an optional "preferred dst" operand, which allows callers to communicate when they have an operand that would be optimal for the result to go into. It also returns an optional "actual dst" operand, which is where the completion value (if any) of the AST node is stored after the node has "executed". One thing of note that's new: because instructions can now take locals as operands, this means we got rid of the GetLocal instruction. A side-effect of that is we have to think about the temporal deadzone (TDZ) a bit differently for locals (GetLocal would previously check for empty values and interpret that as a TDZ access and throw). We now insert special ThrowIfTDZ instructions in places where a local access may be in the TDZ, to maintain the correct behavior. There are a number of progressions and regressions from this test: A number of async generator tests have been accidentally fixed while converting the implementation to the new bytecode format. It didn't seem useful to preserve bugs in the original code when converting it. Some "does eval() return the correct completion value" tests have regressed, in particular ones related to propagating the appropriate completion after control flow statements like continue and break. These are all fairly obscure issues, and I believe we can continue working on them separately. The net test262 result is a progression though. :^)
2024-02-04 08:00:54 +01:00
return ByteString::formatted("GetMethod {}, {}, {}",
format_operand("dst"sv, m_dst, executable),
format_operand("object"sv, m_object, executable),
executable.identifier_table->get(m_property));
LibJS: Move all bytecode instruction implementations to Interpreter.cpp This allows aggressive inlining without LTO.
2023-09-27 10:10:00 +02:00
}
LibJS/Bytecode: Move to a new bytecode format This patch moves us away from the accumulator-based bytecode format to one with explicit source and destination registers. The new format has multiple benefits: - ~25% faster on the Kraken and Octane benchmarks :^) - Fewer instructions to accomplish the same thing - Much easier for humans to read(!) Because this change requires a fundamental shift in how bytecode is generated, it is quite comprehensive. Main implementation mechanism: generate_bytecode() virtual function now takes an optional "preferred dst" operand, which allows callers to communicate when they have an operand that would be optimal for the result to go into. It also returns an optional "actual dst" operand, which is where the completion value (if any) of the AST node is stored after the node has "executed". One thing of note that's new: because instructions can now take locals as operands, this means we got rid of the GetLocal instruction. A side-effect of that is we have to think about the temporal deadzone (TDZ) a bit differently for locals (GetLocal would previously check for empty values and interpret that as a TDZ access and throw). We now insert special ThrowIfTDZ instructions in places where a local access may be in the TDZ, to maintain the correct behavior. There are a number of progressions and regressions from this test: A number of async generator tests have been accidentally fixed while converting the implementation to the new bytecode format. It didn't seem useful to preserve bugs in the original code when converting it. Some "does eval() return the correct completion value" tests have regressed, in particular ones related to propagating the appropriate completion after control flow statements like continue and break. These are all fairly obscure issues, and I believe we can continue working on them separately. The net test262 result is a progression though. :^)
2024-02-04 08:00:54 +01:00
ByteString GetObjectPropertyIterator::to_byte_string_impl(Bytecode::Executable const& executable) const
LibJS: Move all bytecode instruction implementations to Interpreter.cpp This allows aggressive inlining without LTO.
2023-09-27 10:10:00 +02:00
{
LibJS/Bytecode: Move to a new bytecode format This patch moves us away from the accumulator-based bytecode format to one with explicit source and destination registers. The new format has multiple benefits: - ~25% faster on the Kraken and Octane benchmarks :^) - Fewer instructions to accomplish the same thing - Much easier for humans to read(!) Because this change requires a fundamental shift in how bytecode is generated, it is quite comprehensive. Main implementation mechanism: generate_bytecode() virtual function now takes an optional "preferred dst" operand, which allows callers to communicate when they have an operand that would be optimal for the result to go into. It also returns an optional "actual dst" operand, which is where the completion value (if any) of the AST node is stored after the node has "executed". One thing of note that's new: because instructions can now take locals as operands, this means we got rid of the GetLocal instruction. A side-effect of that is we have to think about the temporal deadzone (TDZ) a bit differently for locals (GetLocal would previously check for empty values and interpret that as a TDZ access and throw). We now insert special ThrowIfTDZ instructions in places where a local access may be in the TDZ, to maintain the correct behavior. There are a number of progressions and regressions from this test: A number of async generator tests have been accidentally fixed while converting the implementation to the new bytecode format. It didn't seem useful to preserve bugs in the original code when converting it. Some "does eval() return the correct completion value" tests have regressed, in particular ones related to propagating the appropriate completion after control flow statements like continue and break. These are all fairly obscure issues, and I believe we can continue working on them separately. The net test262 result is a progression though. :^)
2024-02-04 08:00:54 +01:00
return ByteString::formatted("GetObjectPropertyIterator {}, {}",
format_operand("dst"sv, dst(), executable),
format_operand("object"sv, object(), executable));
LibJS: Move all bytecode instruction implementations to Interpreter.cpp This allows aggressive inlining without LTO.
2023-09-27 10:10:00 +02:00
}
LibJS/Bytecode: Move to a new bytecode format This patch moves us away from the accumulator-based bytecode format to one with explicit source and destination registers. The new format has multiple benefits: - ~25% faster on the Kraken and Octane benchmarks :^) - Fewer instructions to accomplish the same thing - Much easier for humans to read(!) Because this change requires a fundamental shift in how bytecode is generated, it is quite comprehensive. Main implementation mechanism: generate_bytecode() virtual function now takes an optional "preferred dst" operand, which allows callers to communicate when they have an operand that would be optimal for the result to go into. It also returns an optional "actual dst" operand, which is where the completion value (if any) of the AST node is stored after the node has "executed". One thing of note that's new: because instructions can now take locals as operands, this means we got rid of the GetLocal instruction. A side-effect of that is we have to think about the temporal deadzone (TDZ) a bit differently for locals (GetLocal would previously check for empty values and interpret that as a TDZ access and throw). We now insert special ThrowIfTDZ instructions in places where a local access may be in the TDZ, to maintain the correct behavior. There are a number of progressions and regressions from this test: A number of async generator tests have been accidentally fixed while converting the implementation to the new bytecode format. It didn't seem useful to preserve bugs in the original code when converting it. Some "does eval() return the correct completion value" tests have regressed, in particular ones related to propagating the appropriate completion after control flow statements like continue and break. These are all fairly obscure issues, and I believe we can continue working on them separately. The net test262 result is a progression though. :^)
2024-02-04 08:00:54 +01:00
ByteString IteratorClose::to_byte_string_impl(Bytecode::Executable const& executable) const
LibJS: Move all bytecode instruction implementations to Interpreter.cpp This allows aggressive inlining without LTO.
2023-09-27 10:10:00 +02:00
{
if (!m_completion_value.has_value())
LibJS/Bytecode: Move to a new bytecode format This patch moves us away from the accumulator-based bytecode format to one with explicit source and destination registers. The new format has multiple benefits: - ~25% faster on the Kraken and Octane benchmarks :^) - Fewer instructions to accomplish the same thing - Much easier for humans to read(!) Because this change requires a fundamental shift in how bytecode is generated, it is quite comprehensive. Main implementation mechanism: generate_bytecode() virtual function now takes an optional "preferred dst" operand, which allows callers to communicate when they have an operand that would be optimal for the result to go into. It also returns an optional "actual dst" operand, which is where the completion value (if any) of the AST node is stored after the node has "executed". One thing of note that's new: because instructions can now take locals as operands, this means we got rid of the GetLocal instruction. A side-effect of that is we have to think about the temporal deadzone (TDZ) a bit differently for locals (GetLocal would previously check for empty values and interpret that as a TDZ access and throw). We now insert special ThrowIfTDZ instructions in places where a local access may be in the TDZ, to maintain the correct behavior. There are a number of progressions and regressions from this test: A number of async generator tests have been accidentally fixed while converting the implementation to the new bytecode format. It didn't seem useful to preserve bugs in the original code when converting it. Some "does eval() return the correct completion value" tests have regressed, in particular ones related to propagating the appropriate completion after control flow statements like continue and break. These are all fairly obscure issues, and I believe we can continue working on them separately. The net test262 result is a progression though. :^)
2024-02-04 08:00:54 +01:00
return ByteString::formatted("IteratorClose {}, completion_type={} completion_value=<empty>",
format_operand("iterator_record"sv, m_iterator_record, executable),
to_underlying(m_completion_type));
LibJS: Move all bytecode instruction implementations to Interpreter.cpp This allows aggressive inlining without LTO.
2023-09-27 10:10:00 +02:00
auto completion_value_string = m_completion_value->to_string_without_side_effects();
LibJS/Bytecode: Move to a new bytecode format This patch moves us away from the accumulator-based bytecode format to one with explicit source and destination registers. The new format has multiple benefits: - ~25% faster on the Kraken and Octane benchmarks :^) - Fewer instructions to accomplish the same thing - Much easier for humans to read(!) Because this change requires a fundamental shift in how bytecode is generated, it is quite comprehensive. Main implementation mechanism: generate_bytecode() virtual function now takes an optional "preferred dst" operand, which allows callers to communicate when they have an operand that would be optimal for the result to go into. It also returns an optional "actual dst" operand, which is where the completion value (if any) of the AST node is stored after the node has "executed". One thing of note that's new: because instructions can now take locals as operands, this means we got rid of the GetLocal instruction. A side-effect of that is we have to think about the temporal deadzone (TDZ) a bit differently for locals (GetLocal would previously check for empty values and interpret that as a TDZ access and throw). We now insert special ThrowIfTDZ instructions in places where a local access may be in the TDZ, to maintain the correct behavior. There are a number of progressions and regressions from this test: A number of async generator tests have been accidentally fixed while converting the implementation to the new bytecode format. It didn't seem useful to preserve bugs in the original code when converting it. Some "does eval() return the correct completion value" tests have regressed, in particular ones related to propagating the appropriate completion after control flow statements like continue and break. These are all fairly obscure issues, and I believe we can continue working on them separately. The net test262 result is a progression though. :^)
2024-02-04 08:00:54 +01:00
return ByteString::formatted("IteratorClose {}, completion_type={} completion_value={}",
format_operand("iterator_record"sv, m_iterator_record, executable),
to_underlying(m_completion_type), completion_value_string);
LibJS: Move all bytecode instruction implementations to Interpreter.cpp This allows aggressive inlining without LTO.
2023-09-27 10:10:00 +02:00
}
LibJS/Bytecode: Move to a new bytecode format This patch moves us away from the accumulator-based bytecode format to one with explicit source and destination registers. The new format has multiple benefits: - ~25% faster on the Kraken and Octane benchmarks :^) - Fewer instructions to accomplish the same thing - Much easier for humans to read(!) Because this change requires a fundamental shift in how bytecode is generated, it is quite comprehensive. Main implementation mechanism: generate_bytecode() virtual function now takes an optional "preferred dst" operand, which allows callers to communicate when they have an operand that would be optimal for the result to go into. It also returns an optional "actual dst" operand, which is where the completion value (if any) of the AST node is stored after the node has "executed". One thing of note that's new: because instructions can now take locals as operands, this means we got rid of the GetLocal instruction. A side-effect of that is we have to think about the temporal deadzone (TDZ) a bit differently for locals (GetLocal would previously check for empty values and interpret that as a TDZ access and throw). We now insert special ThrowIfTDZ instructions in places where a local access may be in the TDZ, to maintain the correct behavior. There are a number of progressions and regressions from this test: A number of async generator tests have been accidentally fixed while converting the implementation to the new bytecode format. It didn't seem useful to preserve bugs in the original code when converting it. Some "does eval() return the correct completion value" tests have regressed, in particular ones related to propagating the appropriate completion after control flow statements like continue and break. These are all fairly obscure issues, and I believe we can continue working on them separately. The net test262 result is a progression though. :^)
2024-02-04 08:00:54 +01:00
ByteString AsyncIteratorClose::to_byte_string_impl(Bytecode::Executable const& executable) const
LibJS: Move all bytecode instruction implementations to Interpreter.cpp This allows aggressive inlining without LTO.
2023-09-27 10:10:00 +02:00
{
LibJS/Bytecode: Move to a new bytecode format This patch moves us away from the accumulator-based bytecode format to one with explicit source and destination registers. The new format has multiple benefits: - ~25% faster on the Kraken and Octane benchmarks :^) - Fewer instructions to accomplish the same thing - Much easier for humans to read(!) Because this change requires a fundamental shift in how bytecode is generated, it is quite comprehensive. Main implementation mechanism: generate_bytecode() virtual function now takes an optional "preferred dst" operand, which allows callers to communicate when they have an operand that would be optimal for the result to go into. It also returns an optional "actual dst" operand, which is where the completion value (if any) of the AST node is stored after the node has "executed". One thing of note that's new: because instructions can now take locals as operands, this means we got rid of the GetLocal instruction. A side-effect of that is we have to think about the temporal deadzone (TDZ) a bit differently for locals (GetLocal would previously check for empty values and interpret that as a TDZ access and throw). We now insert special ThrowIfTDZ instructions in places where a local access may be in the TDZ, to maintain the correct behavior. There are a number of progressions and regressions from this test: A number of async generator tests have been accidentally fixed while converting the implementation to the new bytecode format. It didn't seem useful to preserve bugs in the original code when converting it. Some "does eval() return the correct completion value" tests have regressed, in particular ones related to propagating the appropriate completion after control flow statements like continue and break. These are all fairly obscure issues, and I believe we can continue working on them separately. The net test262 result is a progression though. :^)
2024-02-04 08:00:54 +01:00
if (!m_completion_value.has_value()) {
return ByteString::formatted("AsyncIteratorClose {}, completion_type:{} completion_value:<empty>",
format_operand("iterator_record"sv, m_iterator_record, executable),
to_underlying(m_completion_type));
}
LibJS: Move all bytecode instruction implementations to Interpreter.cpp This allows aggressive inlining without LTO.
2023-09-27 10:10:00 +02:00
LibJS/Bytecode: Move to a new bytecode format This patch moves us away from the accumulator-based bytecode format to one with explicit source and destination registers. The new format has multiple benefits: - ~25% faster on the Kraken and Octane benchmarks :^) - Fewer instructions to accomplish the same thing - Much easier for humans to read(!) Because this change requires a fundamental shift in how bytecode is generated, it is quite comprehensive. Main implementation mechanism: generate_bytecode() virtual function now takes an optional "preferred dst" operand, which allows callers to communicate when they have an operand that would be optimal for the result to go into. It also returns an optional "actual dst" operand, which is where the completion value (if any) of the AST node is stored after the node has "executed". One thing of note that's new: because instructions can now take locals as operands, this means we got rid of the GetLocal instruction. A side-effect of that is we have to think about the temporal deadzone (TDZ) a bit differently for locals (GetLocal would previously check for empty values and interpret that as a TDZ access and throw). We now insert special ThrowIfTDZ instructions in places where a local access may be in the TDZ, to maintain the correct behavior. There are a number of progressions and regressions from this test: A number of async generator tests have been accidentally fixed while converting the implementation to the new bytecode format. It didn't seem useful to preserve bugs in the original code when converting it. Some "does eval() return the correct completion value" tests have regressed, in particular ones related to propagating the appropriate completion after control flow statements like continue and break. These are all fairly obscure issues, and I believe we can continue working on them separately. The net test262 result is a progression though. :^)
2024-02-04 08:00:54 +01:00
return ByteString::formatted("AsyncIteratorClose {}, completion_type:{}, completion_value:{}",
format_operand("iterator_record"sv, m_iterator_record, executable),
to_underlying(m_completion_type), m_completion_value);
LibJS: Move all bytecode instruction implementations to Interpreter.cpp This allows aggressive inlining without LTO.
2023-09-27 10:10:00 +02:00
}
LibJS/Bytecode: Move to a new bytecode format This patch moves us away from the accumulator-based bytecode format to one with explicit source and destination registers. The new format has multiple benefits: - ~25% faster on the Kraken and Octane benchmarks :^) - Fewer instructions to accomplish the same thing - Much easier for humans to read(!) Because this change requires a fundamental shift in how bytecode is generated, it is quite comprehensive. Main implementation mechanism: generate_bytecode() virtual function now takes an optional "preferred dst" operand, which allows callers to communicate when they have an operand that would be optimal for the result to go into. It also returns an optional "actual dst" operand, which is where the completion value (if any) of the AST node is stored after the node has "executed". One thing of note that's new: because instructions can now take locals as operands, this means we got rid of the GetLocal instruction. A side-effect of that is we have to think about the temporal deadzone (TDZ) a bit differently for locals (GetLocal would previously check for empty values and interpret that as a TDZ access and throw). We now insert special ThrowIfTDZ instructions in places where a local access may be in the TDZ, to maintain the correct behavior. There are a number of progressions and regressions from this test: A number of async generator tests have been accidentally fixed while converting the implementation to the new bytecode format. It didn't seem useful to preserve bugs in the original code when converting it. Some "does eval() return the correct completion value" tests have regressed, in particular ones related to propagating the appropriate completion after control flow statements like continue and break. These are all fairly obscure issues, and I believe we can continue working on them separately. The net test262 result is a progression though. :^)
2024-02-04 08:00:54 +01:00
ByteString IteratorNext::to_byte_string_impl(Executable const& executable) const
LibJS: Move all bytecode instruction implementations to Interpreter.cpp This allows aggressive inlining without LTO.
2023-09-27 10:10:00 +02:00
{
LibJS/Bytecode: Move to a new bytecode format This patch moves us away from the accumulator-based bytecode format to one with explicit source and destination registers. The new format has multiple benefits: - ~25% faster on the Kraken and Octane benchmarks :^) - Fewer instructions to accomplish the same thing - Much easier for humans to read(!) Because this change requires a fundamental shift in how bytecode is generated, it is quite comprehensive. Main implementation mechanism: generate_bytecode() virtual function now takes an optional "preferred dst" operand, which allows callers to communicate when they have an operand that would be optimal for the result to go into. It also returns an optional "actual dst" operand, which is where the completion value (if any) of the AST node is stored after the node has "executed". One thing of note that's new: because instructions can now take locals as operands, this means we got rid of the GetLocal instruction. A side-effect of that is we have to think about the temporal deadzone (TDZ) a bit differently for locals (GetLocal would previously check for empty values and interpret that as a TDZ access and throw). We now insert special ThrowIfTDZ instructions in places where a local access may be in the TDZ, to maintain the correct behavior. There are a number of progressions and regressions from this test: A number of async generator tests have been accidentally fixed while converting the implementation to the new bytecode format. It didn't seem useful to preserve bugs in the original code when converting it. Some "does eval() return the correct completion value" tests have regressed, in particular ones related to propagating the appropriate completion after control flow statements like continue and break. These are all fairly obscure issues, and I believe we can continue working on them separately. The net test262 result is a progression though. :^)
2024-02-04 08:00:54 +01:00
return ByteString::formatted("IteratorNext {}, {}",
format_operand("dst"sv, m_dst, executable),
format_operand("iterator_record"sv, m_iterator_record, executable));
LibJS: Move all bytecode instruction implementations to Interpreter.cpp This allows aggressive inlining without LTO.
2023-09-27 10:10:00 +02:00
}
LibJS/Bytecode: Move to a new bytecode format This patch moves us away from the accumulator-based bytecode format to one with explicit source and destination registers. The new format has multiple benefits: - ~25% faster on the Kraken and Octane benchmarks :^) - Fewer instructions to accomplish the same thing - Much easier for humans to read(!) Because this change requires a fundamental shift in how bytecode is generated, it is quite comprehensive. Main implementation mechanism: generate_bytecode() virtual function now takes an optional "preferred dst" operand, which allows callers to communicate when they have an operand that would be optimal for the result to go into. It also returns an optional "actual dst" operand, which is where the completion value (if any) of the AST node is stored after the node has "executed". One thing of note that's new: because instructions can now take locals as operands, this means we got rid of the GetLocal instruction. A side-effect of that is we have to think about the temporal deadzone (TDZ) a bit differently for locals (GetLocal would previously check for empty values and interpret that as a TDZ access and throw). We now insert special ThrowIfTDZ instructions in places where a local access may be in the TDZ, to maintain the correct behavior. There are a number of progressions and regressions from this test: A number of async generator tests have been accidentally fixed while converting the implementation to the new bytecode format. It didn't seem useful to preserve bugs in the original code when converting it. Some "does eval() return the correct completion value" tests have regressed, in particular ones related to propagating the appropriate completion after control flow statements like continue and break. These are all fairly obscure issues, and I believe we can continue working on them separately. The net test262 result is a progression though. :^)
2024-02-04 08:00:54 +01:00
ByteString ResolveThisBinding::to_byte_string_impl(Bytecode::Executable const& executable) const
LibJS: Move all bytecode instruction implementations to Interpreter.cpp This allows aggressive inlining without LTO.
2023-09-27 10:10:00 +02:00
{
LibJS/Bytecode: Move to a new bytecode format This patch moves us away from the accumulator-based bytecode format to one with explicit source and destination registers. The new format has multiple benefits: - ~25% faster on the Kraken and Octane benchmarks :^) - Fewer instructions to accomplish the same thing - Much easier for humans to read(!) Because this change requires a fundamental shift in how bytecode is generated, it is quite comprehensive. Main implementation mechanism: generate_bytecode() virtual function now takes an optional "preferred dst" operand, which allows callers to communicate when they have an operand that would be optimal for the result to go into. It also returns an optional "actual dst" operand, which is where the completion value (if any) of the AST node is stored after the node has "executed". One thing of note that's new: because instructions can now take locals as operands, this means we got rid of the GetLocal instruction. A side-effect of that is we have to think about the temporal deadzone (TDZ) a bit differently for locals (GetLocal would previously check for empty values and interpret that as a TDZ access and throw). We now insert special ThrowIfTDZ instructions in places where a local access may be in the TDZ, to maintain the correct behavior. There are a number of progressions and regressions from this test: A number of async generator tests have been accidentally fixed while converting the implementation to the new bytecode format. It didn't seem useful to preserve bugs in the original code when converting it. Some "does eval() return the correct completion value" tests have regressed, in particular ones related to propagating the appropriate completion after control flow statements like continue and break. These are all fairly obscure issues, and I believe we can continue working on them separately. The net test262 result is a progression though. :^)
2024-02-04 08:00:54 +01:00
return ByteString::formatted("ResolveThisBinding {}", format_operand("dst"sv, m_dst, executable));
LibJS: Move all bytecode instruction implementations to Interpreter.cpp This allows aggressive inlining without LTO.
2023-09-27 10:10:00 +02:00
}
LibJS/Bytecode: Move to a new bytecode format This patch moves us away from the accumulator-based bytecode format to one with explicit source and destination registers. The new format has multiple benefits: - ~25% faster on the Kraken and Octane benchmarks :^) - Fewer instructions to accomplish the same thing - Much easier for humans to read(!) Because this change requires a fundamental shift in how bytecode is generated, it is quite comprehensive. Main implementation mechanism: generate_bytecode() virtual function now takes an optional "preferred dst" operand, which allows callers to communicate when they have an operand that would be optimal for the result to go into. It also returns an optional "actual dst" operand, which is where the completion value (if any) of the AST node is stored after the node has "executed". One thing of note that's new: because instructions can now take locals as operands, this means we got rid of the GetLocal instruction. A side-effect of that is we have to think about the temporal deadzone (TDZ) a bit differently for locals (GetLocal would previously check for empty values and interpret that as a TDZ access and throw). We now insert special ThrowIfTDZ instructions in places where a local access may be in the TDZ, to maintain the correct behavior. There are a number of progressions and regressions from this test: A number of async generator tests have been accidentally fixed while converting the implementation to the new bytecode format. It didn't seem useful to preserve bugs in the original code when converting it. Some "does eval() return the correct completion value" tests have regressed, in particular ones related to propagating the appropriate completion after control flow statements like continue and break. These are all fairly obscure issues, and I believe we can continue working on them separately. The net test262 result is a progression though. :^)
2024-02-04 08:00:54 +01:00
ByteString ResolveSuperBase::to_byte_string_impl(Bytecode::Executable const& executable) const
LibJS: Move all bytecode instruction implementations to Interpreter.cpp This allows aggressive inlining without LTO.
2023-09-27 10:10:00 +02:00
{
LibJS/Bytecode: Move to a new bytecode format This patch moves us away from the accumulator-based bytecode format to one with explicit source and destination registers. The new format has multiple benefits: - ~25% faster on the Kraken and Octane benchmarks :^) - Fewer instructions to accomplish the same thing - Much easier for humans to read(!) Because this change requires a fundamental shift in how bytecode is generated, it is quite comprehensive. Main implementation mechanism: generate_bytecode() virtual function now takes an optional "preferred dst" operand, which allows callers to communicate when they have an operand that would be optimal for the result to go into. It also returns an optional "actual dst" operand, which is where the completion value (if any) of the AST node is stored after the node has "executed". One thing of note that's new: because instructions can now take locals as operands, this means we got rid of the GetLocal instruction. A side-effect of that is we have to think about the temporal deadzone (TDZ) a bit differently for locals (GetLocal would previously check for empty values and interpret that as a TDZ access and throw). We now insert special ThrowIfTDZ instructions in places where a local access may be in the TDZ, to maintain the correct behavior. There are a number of progressions and regressions from this test: A number of async generator tests have been accidentally fixed while converting the implementation to the new bytecode format. It didn't seem useful to preserve bugs in the original code when converting it. Some "does eval() return the correct completion value" tests have regressed, in particular ones related to propagating the appropriate completion after control flow statements like continue and break. These are all fairly obscure issues, and I believe we can continue working on them separately. The net test262 result is a progression though. :^)
2024-02-04 08:00:54 +01:00
return ByteString::formatted("ResolveSuperBase {}",
format_operand("dst"sv, m_dst, executable));
LibJS: Move all bytecode instruction implementations to Interpreter.cpp This allows aggressive inlining without LTO.
2023-09-27 10:10:00 +02:00
}
LibJS/Bytecode: Move to a new bytecode format This patch moves us away from the accumulator-based bytecode format to one with explicit source and destination registers. The new format has multiple benefits: - ~25% faster on the Kraken and Octane benchmarks :^) - Fewer instructions to accomplish the same thing - Much easier for humans to read(!) Because this change requires a fundamental shift in how bytecode is generated, it is quite comprehensive. Main implementation mechanism: generate_bytecode() virtual function now takes an optional "preferred dst" operand, which allows callers to communicate when they have an operand that would be optimal for the result to go into. It also returns an optional "actual dst" operand, which is where the completion value (if any) of the AST node is stored after the node has "executed". One thing of note that's new: because instructions can now take locals as operands, this means we got rid of the GetLocal instruction. A side-effect of that is we have to think about the temporal deadzone (TDZ) a bit differently for locals (GetLocal would previously check for empty values and interpret that as a TDZ access and throw). We now insert special ThrowIfTDZ instructions in places where a local access may be in the TDZ, to maintain the correct behavior. There are a number of progressions and regressions from this test: A number of async generator tests have been accidentally fixed while converting the implementation to the new bytecode format. It didn't seem useful to preserve bugs in the original code when converting it. Some "does eval() return the correct completion value" tests have regressed, in particular ones related to propagating the appropriate completion after control flow statements like continue and break. These are all fairly obscure issues, and I believe we can continue working on them separately. The net test262 result is a progression though. :^)
2024-02-04 08:00:54 +01:00
ByteString GetNewTarget::to_byte_string_impl(Bytecode::Executable const& executable) const
LibJS: Move all bytecode instruction implementations to Interpreter.cpp This allows aggressive inlining without LTO.
2023-09-27 10:10:00 +02:00
{
LibJS/Bytecode: Move to a new bytecode format This patch moves us away from the accumulator-based bytecode format to one with explicit source and destination registers. The new format has multiple benefits: - ~25% faster on the Kraken and Octane benchmarks :^) - Fewer instructions to accomplish the same thing - Much easier for humans to read(!) Because this change requires a fundamental shift in how bytecode is generated, it is quite comprehensive. Main implementation mechanism: generate_bytecode() virtual function now takes an optional "preferred dst" operand, which allows callers to communicate when they have an operand that would be optimal for the result to go into. It also returns an optional "actual dst" operand, which is where the completion value (if any) of the AST node is stored after the node has "executed". One thing of note that's new: because instructions can now take locals as operands, this means we got rid of the GetLocal instruction. A side-effect of that is we have to think about the temporal deadzone (TDZ) a bit differently for locals (GetLocal would previously check for empty values and interpret that as a TDZ access and throw). We now insert special ThrowIfTDZ instructions in places where a local access may be in the TDZ, to maintain the correct behavior. There are a number of progressions and regressions from this test: A number of async generator tests have been accidentally fixed while converting the implementation to the new bytecode format. It didn't seem useful to preserve bugs in the original code when converting it. Some "does eval() return the correct completion value" tests have regressed, in particular ones related to propagating the appropriate completion after control flow statements like continue and break. These are all fairly obscure issues, and I believe we can continue working on them separately. The net test262 result is a progression though. :^)
2024-02-04 08:00:54 +01:00
return ByteString::formatted("GetNewTarget {}", format_operand("dst"sv, m_dst, executable));
LibJS: Move all bytecode instruction implementations to Interpreter.cpp This allows aggressive inlining without LTO.
2023-09-27 10:10:00 +02:00
}
LibJS/Bytecode: Move to a new bytecode format This patch moves us away from the accumulator-based bytecode format to one with explicit source and destination registers. The new format has multiple benefits: - ~25% faster on the Kraken and Octane benchmarks :^) - Fewer instructions to accomplish the same thing - Much easier for humans to read(!) Because this change requires a fundamental shift in how bytecode is generated, it is quite comprehensive. Main implementation mechanism: generate_bytecode() virtual function now takes an optional "preferred dst" operand, which allows callers to communicate when they have an operand that would be optimal for the result to go into. It also returns an optional "actual dst" operand, which is where the completion value (if any) of the AST node is stored after the node has "executed". One thing of note that's new: because instructions can now take locals as operands, this means we got rid of the GetLocal instruction. A side-effect of that is we have to think about the temporal deadzone (TDZ) a bit differently for locals (GetLocal would previously check for empty values and interpret that as a TDZ access and throw). We now insert special ThrowIfTDZ instructions in places where a local access may be in the TDZ, to maintain the correct behavior. There are a number of progressions and regressions from this test: A number of async generator tests have been accidentally fixed while converting the implementation to the new bytecode format. It didn't seem useful to preserve bugs in the original code when converting it. Some "does eval() return the correct completion value" tests have regressed, in particular ones related to propagating the appropriate completion after control flow statements like continue and break. These are all fairly obscure issues, and I believe we can continue working on them separately. The net test262 result is a progression though. :^)
2024-02-04 08:00:54 +01:00
ByteString GetImportMeta::to_byte_string_impl(Bytecode::Executable const& executable) const
LibJS: Move all bytecode instruction implementations to Interpreter.cpp This allows aggressive inlining without LTO.
2023-09-27 10:10:00 +02:00
{
LibJS/Bytecode: Move to a new bytecode format This patch moves us away from the accumulator-based bytecode format to one with explicit source and destination registers. The new format has multiple benefits: - ~25% faster on the Kraken and Octane benchmarks :^) - Fewer instructions to accomplish the same thing - Much easier for humans to read(!) Because this change requires a fundamental shift in how bytecode is generated, it is quite comprehensive. Main implementation mechanism: generate_bytecode() virtual function now takes an optional "preferred dst" operand, which allows callers to communicate when they have an operand that would be optimal for the result to go into. It also returns an optional "actual dst" operand, which is where the completion value (if any) of the AST node is stored after the node has "executed". One thing of note that's new: because instructions can now take locals as operands, this means we got rid of the GetLocal instruction. A side-effect of that is we have to think about the temporal deadzone (TDZ) a bit differently for locals (GetLocal would previously check for empty values and interpret that as a TDZ access and throw). We now insert special ThrowIfTDZ instructions in places where a local access may be in the TDZ, to maintain the correct behavior. There are a number of progressions and regressions from this test: A number of async generator tests have been accidentally fixed while converting the implementation to the new bytecode format. It didn't seem useful to preserve bugs in the original code when converting it. Some "does eval() return the correct completion value" tests have regressed, in particular ones related to propagating the appropriate completion after control flow statements like continue and break. These are all fairly obscure issues, and I believe we can continue working on them separately. The net test262 result is a progression though. :^)
2024-02-04 08:00:54 +01:00
return ByteString::formatted("GetImportMeta {}", format_operand("dst"sv, m_dst, executable));
LibJS: Move all bytecode instruction implementations to Interpreter.cpp This allows aggressive inlining without LTO.
2023-09-27 10:10:00 +02:00
}
Everywhere: Rename {Deprecated => Byte}String This commit un-deprecates DeprecatedString, and repurposes it as a byte string. As the null state has already been removed, there are no other particularly hairy blockers in repurposing this type as a byte string (what it _really_ is). This commit is auto-generated: $ xs=$(ack -l \bDeprecatedString\b\|deprecated_string AK Userland \ Meta Ports Ladybird Tests Kernel) $ perl -pie 's/\bDeprecatedString\b/ByteString/g; s/deprecated_string/byte_string/g' $xs $ clang-format --style=file -i \ $(git diff --name-only | grep \.cpp\|\.h) $ gn format $(git ls-files '*.gn' '*.gni')
2023-12-16 17:49:34 +03:30
ByteString TypeofVariable::to_byte_string_impl(Bytecode::Executable const& executable) const
LibJS: Move all bytecode instruction implementations to Interpreter.cpp This allows aggressive inlining without LTO.
2023-09-27 10:10:00 +02:00
{
LibJS/Bytecode: Move to a new bytecode format This patch moves us away from the accumulator-based bytecode format to one with explicit source and destination registers. The new format has multiple benefits: - ~25% faster on the Kraken and Octane benchmarks :^) - Fewer instructions to accomplish the same thing - Much easier for humans to read(!) Because this change requires a fundamental shift in how bytecode is generated, it is quite comprehensive. Main implementation mechanism: generate_bytecode() virtual function now takes an optional "preferred dst" operand, which allows callers to communicate when they have an operand that would be optimal for the result to go into. It also returns an optional "actual dst" operand, which is where the completion value (if any) of the AST node is stored after the node has "executed". One thing of note that's new: because instructions can now take locals as operands, this means we got rid of the GetLocal instruction. A side-effect of that is we have to think about the temporal deadzone (TDZ) a bit differently for locals (GetLocal would previously check for empty values and interpret that as a TDZ access and throw). We now insert special ThrowIfTDZ instructions in places where a local access may be in the TDZ, to maintain the correct behavior. There are a number of progressions and regressions from this test: A number of async generator tests have been accidentally fixed while converting the implementation to the new bytecode format. It didn't seem useful to preserve bugs in the original code when converting it. Some "does eval() return the correct completion value" tests have regressed, in particular ones related to propagating the appropriate completion after control flow statements like continue and break. These are all fairly obscure issues, and I believe we can continue working on them separately. The net test262 result is a progression though. :^)
2024-02-04 08:00:54 +01:00
return ByteString::formatted("TypeofVariable {}, {}",
format_operand("dst"sv, m_dst, executable),
executable.identifier_table->get(m_identifier));
LibJS: Move all bytecode instruction implementations to Interpreter.cpp This allows aggressive inlining without LTO.
2023-09-27 10:10:00 +02:00
}
LibJS/Bytecode: Move to a new bytecode format This patch moves us away from the accumulator-based bytecode format to one with explicit source and destination registers. The new format has multiple benefits: - ~25% faster on the Kraken and Octane benchmarks :^) - Fewer instructions to accomplish the same thing - Much easier for humans to read(!) Because this change requires a fundamental shift in how bytecode is generated, it is quite comprehensive. Main implementation mechanism: generate_bytecode() virtual function now takes an optional "preferred dst" operand, which allows callers to communicate when they have an operand that would be optimal for the result to go into. It also returns an optional "actual dst" operand, which is where the completion value (if any) of the AST node is stored after the node has "executed". One thing of note that's new: because instructions can now take locals as operands, this means we got rid of the GetLocal instruction. A side-effect of that is we have to think about the temporal deadzone (TDZ) a bit differently for locals (GetLocal would previously check for empty values and interpret that as a TDZ access and throw). We now insert special ThrowIfTDZ instructions in places where a local access may be in the TDZ, to maintain the correct behavior. There are a number of progressions and regressions from this test: A number of async generator tests have been accidentally fixed while converting the implementation to the new bytecode format. It didn't seem useful to preserve bugs in the original code when converting it. Some "does eval() return the correct completion value" tests have regressed, in particular ones related to propagating the appropriate completion after control flow statements like continue and break. These are all fairly obscure issues, and I believe we can continue working on them separately. The net test262 result is a progression though. :^)
2024-02-04 08:00:54 +01:00
ByteString BlockDeclarationInstantiation::to_byte_string_impl(Bytecode::Executable const&) const
LibJS: Move all bytecode instruction implementations to Interpreter.cpp This allows aggressive inlining without LTO.
2023-09-27 10:10:00 +02:00
{
LibJS/Bytecode: Move to a new bytecode format This patch moves us away from the accumulator-based bytecode format to one with explicit source and destination registers. The new format has multiple benefits: - ~25% faster on the Kraken and Octane benchmarks :^) - Fewer instructions to accomplish the same thing - Much easier for humans to read(!) Because this change requires a fundamental shift in how bytecode is generated, it is quite comprehensive. Main implementation mechanism: generate_bytecode() virtual function now takes an optional "preferred dst" operand, which allows callers to communicate when they have an operand that would be optimal for the result to go into. It also returns an optional "actual dst" operand, which is where the completion value (if any) of the AST node is stored after the node has "executed". One thing of note that's new: because instructions can now take locals as operands, this means we got rid of the GetLocal instruction. A side-effect of that is we have to think about the temporal deadzone (TDZ) a bit differently for locals (GetLocal would previously check for empty values and interpret that as a TDZ access and throw). We now insert special ThrowIfTDZ instructions in places where a local access may be in the TDZ, to maintain the correct behavior. There are a number of progressions and regressions from this test: A number of async generator tests have been accidentally fixed while converting the implementation to the new bytecode format. It didn't seem useful to preserve bugs in the original code when converting it. Some "does eval() return the correct completion value" tests have regressed, in particular ones related to propagating the appropriate completion after control flow statements like continue and break. These are all fairly obscure issues, and I believe we can continue working on them separately. The net test262 result is a progression though. :^)
2024-02-04 08:00:54 +01:00
return "BlockDeclarationInstantiation"sv;
LibJS: Move all bytecode instruction implementations to Interpreter.cpp This allows aggressive inlining without LTO.
2023-09-27 10:10:00 +02:00
}
LibJS/Bytecode: Move to a new bytecode format This patch moves us away from the accumulator-based bytecode format to one with explicit source and destination registers. The new format has multiple benefits: - ~25% faster on the Kraken and Octane benchmarks :^) - Fewer instructions to accomplish the same thing - Much easier for humans to read(!) Because this change requires a fundamental shift in how bytecode is generated, it is quite comprehensive. Main implementation mechanism: generate_bytecode() virtual function now takes an optional "preferred dst" operand, which allows callers to communicate when they have an operand that would be optimal for the result to go into. It also returns an optional "actual dst" operand, which is where the completion value (if any) of the AST node is stored after the node has "executed". One thing of note that's new: because instructions can now take locals as operands, this means we got rid of the GetLocal instruction. A side-effect of that is we have to think about the temporal deadzone (TDZ) a bit differently for locals (GetLocal would previously check for empty values and interpret that as a TDZ access and throw). We now insert special ThrowIfTDZ instructions in places where a local access may be in the TDZ, to maintain the correct behavior. There are a number of progressions and regressions from this test: A number of async generator tests have been accidentally fixed while converting the implementation to the new bytecode format. It didn't seem useful to preserve bugs in the original code when converting it. Some "does eval() return the correct completion value" tests have regressed, in particular ones related to propagating the appropriate completion after control flow statements like continue and break. These are all fairly obscure issues, and I believe we can continue working on them separately. The net test262 result is a progression though. :^)
2024-02-04 08:00:54 +01:00
ByteString ImportCall::to_byte_string_impl(Bytecode::Executable const& executable) const
LibJS: Move all bytecode instruction implementations to Interpreter.cpp This allows aggressive inlining without LTO.
2023-09-27 10:10:00 +02:00
{
LibJS/Bytecode: Move to a new bytecode format This patch moves us away from the accumulator-based bytecode format to one with explicit source and destination registers. The new format has multiple benefits: - ~25% faster on the Kraken and Octane benchmarks :^) - Fewer instructions to accomplish the same thing - Much easier for humans to read(!) Because this change requires a fundamental shift in how bytecode is generated, it is quite comprehensive. Main implementation mechanism: generate_bytecode() virtual function now takes an optional "preferred dst" operand, which allows callers to communicate when they have an operand that would be optimal for the result to go into. It also returns an optional "actual dst" operand, which is where the completion value (if any) of the AST node is stored after the node has "executed". One thing of note that's new: because instructions can now take locals as operands, this means we got rid of the GetLocal instruction. A side-effect of that is we have to think about the temporal deadzone (TDZ) a bit differently for locals (GetLocal would previously check for empty values and interpret that as a TDZ access and throw). We now insert special ThrowIfTDZ instructions in places where a local access may be in the TDZ, to maintain the correct behavior. There are a number of progressions and regressions from this test: A number of async generator tests have been accidentally fixed while converting the implementation to the new bytecode format. It didn't seem useful to preserve bugs in the original code when converting it. Some "does eval() return the correct completion value" tests have regressed, in particular ones related to propagating the appropriate completion after control flow statements like continue and break. These are all fairly obscure issues, and I believe we can continue working on them separately. The net test262 result is a progression though. :^)
2024-02-04 08:00:54 +01:00
return ByteString::formatted("ImportCall {}, {}, {}",
format_operand("dst"sv, m_dst, executable),
format_operand("specifier"sv, m_specifier, executable),
format_operand("options"sv, m_options, executable));
}
ByteString Catch::to_byte_string_impl(Bytecode::Executable const& executable) const
{
return ByteString::formatted("Catch {}",
format_operand("dst"sv, m_dst, executable));
LibJS: Move all bytecode instruction implementations to Interpreter.cpp This allows aggressive inlining without LTO.
2023-09-27 10:10:00 +02:00
}
LibJS: Cleanup unwind state when transferring control out of a finalizer This does two things: * Clear exceptions when transferring control out of a finalizer Otherwise they would resurface at the end of the next finalizer (see test the new test case), or at the end of a function * Pop one scheduled jump when transferring control out of a finalizer This removes one old FIXME
2024-04-11 11:58:18 +02:00
ByteString LeaveFinally::to_byte_string_impl(Bytecode::Executable const&) const
{
return ByteString::formatted("LeaveFinally");
}
LibJS: Restore scheduled jumps in catch blocks without finalizers
2024-04-11 11:07:35 +02:00
ByteString RestoreScheduledJump::to_byte_string_impl(Bytecode::Executable const&) const
{
return ByteString::formatted("RestoreScheduledJump");
}
LibJS/Bytecode: Move to a new bytecode format This patch moves us away from the accumulator-based bytecode format to one with explicit source and destination registers. The new format has multiple benefits: - ~25% faster on the Kraken and Octane benchmarks :^) - Fewer instructions to accomplish the same thing - Much easier for humans to read(!) Because this change requires a fundamental shift in how bytecode is generated, it is quite comprehensive. Main implementation mechanism: generate_bytecode() virtual function now takes an optional "preferred dst" operand, which allows callers to communicate when they have an operand that would be optimal for the result to go into. It also returns an optional "actual dst" operand, which is where the completion value (if any) of the AST node is stored after the node has "executed". One thing of note that's new: because instructions can now take locals as operands, this means we got rid of the GetLocal instruction. A side-effect of that is we have to think about the temporal deadzone (TDZ) a bit differently for locals (GetLocal would previously check for empty values and interpret that as a TDZ access and throw). We now insert special ThrowIfTDZ instructions in places where a local access may be in the TDZ, to maintain the correct behavior. There are a number of progressions and regressions from this test: A number of async generator tests have been accidentally fixed while converting the implementation to the new bytecode format. It didn't seem useful to preserve bugs in the original code when converting it. Some "does eval() return the correct completion value" tests have regressed, in particular ones related to propagating the appropriate completion after control flow statements like continue and break. These are all fairly obscure issues, and I believe we can continue working on them separately. The net test262 result is a progression though. :^)
2024-02-04 08:00:54 +01:00
ByteString GetObjectFromIteratorRecord::to_byte_string_impl(Bytecode::Executable const& executable) const
LibJS: Move all bytecode instruction implementations to Interpreter.cpp This allows aggressive inlining without LTO.
2023-09-27 10:10:00 +02:00
{
LibJS/Bytecode: Move to a new bytecode format This patch moves us away from the accumulator-based bytecode format to one with explicit source and destination registers. The new format has multiple benefits: - ~25% faster on the Kraken and Octane benchmarks :^) - Fewer instructions to accomplish the same thing - Much easier for humans to read(!) Because this change requires a fundamental shift in how bytecode is generated, it is quite comprehensive. Main implementation mechanism: generate_bytecode() virtual function now takes an optional "preferred dst" operand, which allows callers to communicate when they have an operand that would be optimal for the result to go into. It also returns an optional "actual dst" operand, which is where the completion value (if any) of the AST node is stored after the node has "executed". One thing of note that's new: because instructions can now take locals as operands, this means we got rid of the GetLocal instruction. A side-effect of that is we have to think about the temporal deadzone (TDZ) a bit differently for locals (GetLocal would previously check for empty values and interpret that as a TDZ access and throw). We now insert special ThrowIfTDZ instructions in places where a local access may be in the TDZ, to maintain the correct behavior. There are a number of progressions and regressions from this test: A number of async generator tests have been accidentally fixed while converting the implementation to the new bytecode format. It didn't seem useful to preserve bugs in the original code when converting it. Some "does eval() return the correct completion value" tests have regressed, in particular ones related to propagating the appropriate completion after control flow statements like continue and break. These are all fairly obscure issues, and I believe we can continue working on them separately. The net test262 result is a progression though. :^)
2024-02-04 08:00:54 +01:00
return ByteString::formatted("GetObjectFromIteratorRecord {}, {}",
format_operand("object"sv, m_object, executable),
format_operand("iterator_record"sv, m_iterator_record, executable));
LibJS: Move all bytecode instruction implementations to Interpreter.cpp This allows aggressive inlining without LTO.
2023-09-27 10:10:00 +02:00
}
LibJS/Bytecode: Move to a new bytecode format This patch moves us away from the accumulator-based bytecode format to one with explicit source and destination registers. The new format has multiple benefits: - ~25% faster on the Kraken and Octane benchmarks :^) - Fewer instructions to accomplish the same thing - Much easier for humans to read(!) Because this change requires a fundamental shift in how bytecode is generated, it is quite comprehensive. Main implementation mechanism: generate_bytecode() virtual function now takes an optional "preferred dst" operand, which allows callers to communicate when they have an operand that would be optimal for the result to go into. It also returns an optional "actual dst" operand, which is where the completion value (if any) of the AST node is stored after the node has "executed". One thing of note that's new: because instructions can now take locals as operands, this means we got rid of the GetLocal instruction. A side-effect of that is we have to think about the temporal deadzone (TDZ) a bit differently for locals (GetLocal would previously check for empty values and interpret that as a TDZ access and throw). We now insert special ThrowIfTDZ instructions in places where a local access may be in the TDZ, to maintain the correct behavior. There are a number of progressions and regressions from this test: A number of async generator tests have been accidentally fixed while converting the implementation to the new bytecode format. It didn't seem useful to preserve bugs in the original code when converting it. Some "does eval() return the correct completion value" tests have regressed, in particular ones related to propagating the appropriate completion after control flow statements like continue and break. These are all fairly obscure issues, and I believe we can continue working on them separately. The net test262 result is a progression though. :^)
2024-02-04 08:00:54 +01:00
ByteString GetNextMethodFromIteratorRecord::to_byte_string_impl(Bytecode::Executable const& executable) const
LibJS/JIT: Update "unwind context" stack in JIT code Until now, the unwind context stack has not been maintained by jitted code, which meant we were unable to support the `with` statement. This is a first step towards supporting that by making jitted code call out to C++ to update the unwind context stack when entering/leaving unwind contexts. We also introduce a new "Catch" bytecode instruction that moves the current exception into the accumulator. It's always emitted at the start of a "catch" block.
2023-11-11 23:19:46 +01:00
{
LibJS/Bytecode: Move to a new bytecode format This patch moves us away from the accumulator-based bytecode format to one with explicit source and destination registers. The new format has multiple benefits: - ~25% faster on the Kraken and Octane benchmarks :^) - Fewer instructions to accomplish the same thing - Much easier for humans to read(!) Because this change requires a fundamental shift in how bytecode is generated, it is quite comprehensive. Main implementation mechanism: generate_bytecode() virtual function now takes an optional "preferred dst" operand, which allows callers to communicate when they have an operand that would be optimal for the result to go into. It also returns an optional "actual dst" operand, which is where the completion value (if any) of the AST node is stored after the node has "executed". One thing of note that's new: because instructions can now take locals as operands, this means we got rid of the GetLocal instruction. A side-effect of that is we have to think about the temporal deadzone (TDZ) a bit differently for locals (GetLocal would previously check for empty values and interpret that as a TDZ access and throw). We now insert special ThrowIfTDZ instructions in places where a local access may be in the TDZ, to maintain the correct behavior. There are a number of progressions and regressions from this test: A number of async generator tests have been accidentally fixed while converting the implementation to the new bytecode format. It didn't seem useful to preserve bugs in the original code when converting it. Some "does eval() return the correct completion value" tests have regressed, in particular ones related to propagating the appropriate completion after control flow statements like continue and break. These are all fairly obscure issues, and I believe we can continue working on them separately. The net test262 result is a progression though. :^)
2024-02-04 08:00:54 +01:00
return ByteString::formatted("GetNextMethodFromIteratorRecord {}, {}",
format_operand("next_method"sv, m_next_method, executable),
format_operand("iterator_record"sv, m_iterator_record, executable));
LibJS/JIT: Update "unwind context" stack in JIT code Until now, the unwind context stack has not been maintained by jitted code, which meant we were unable to support the `with` statement. This is a first step towards supporting that by making jitted code call out to C++ to update the unwind context stack when entering/leaving unwind contexts. We also introduce a new "Catch" bytecode instruction that moves the current exception into the accumulator. It's always emitted at the start of a "catch" block.
2023-11-11 23:19:46 +01:00
}
LibJS/Bytecode: Move to a new bytecode format This patch moves us away from the accumulator-based bytecode format to one with explicit source and destination registers. The new format has multiple benefits: - ~25% faster on the Kraken and Octane benchmarks :^) - Fewer instructions to accomplish the same thing - Much easier for humans to read(!) Because this change requires a fundamental shift in how bytecode is generated, it is quite comprehensive. Main implementation mechanism: generate_bytecode() virtual function now takes an optional "preferred dst" operand, which allows callers to communicate when they have an operand that would be optimal for the result to go into. It also returns an optional "actual dst" operand, which is where the completion value (if any) of the AST node is stored after the node has "executed". One thing of note that's new: because instructions can now take locals as operands, this means we got rid of the GetLocal instruction. A side-effect of that is we have to think about the temporal deadzone (TDZ) a bit differently for locals (GetLocal would previously check for empty values and interpret that as a TDZ access and throw). We now insert special ThrowIfTDZ instructions in places where a local access may be in the TDZ, to maintain the correct behavior. There are a number of progressions and regressions from this test: A number of async generator tests have been accidentally fixed while converting the implementation to the new bytecode format. It didn't seem useful to preserve bugs in the original code when converting it. Some "does eval() return the correct completion value" tests have regressed, in particular ones related to propagating the appropriate completion after control flow statements like continue and break. These are all fairly obscure issues, and I believe we can continue working on them separately. The net test262 result is a progression though. :^)
2024-02-04 08:00:54 +01:00
ByteString End::to_byte_string_impl(Bytecode::Executable const& executable) const
LibJS: Stop converting between Object <-> IteratorRecord all the time This patch makes IteratorRecord an Object. Although it's not exposed to author code, this does allow us to store it in a VM register. Now that we can store it in a VM register, we don't need to convert it back and forth between IteratorRecord and Object when accessing it from bytecode. The big win here is avoiding 3 [[Get]] accesses on every iteration step of for..of loops. There are also a bunch of smaller efficiencies gained. 20% speed-up on this microbenchmark: function go(a) { for (const p of a) { } } const a = []; a.length = 1_000_000; go(a);
2023-12-07 10:44:41 +01:00
{
LibJS/Bytecode: Move to a new bytecode format This patch moves us away from the accumulator-based bytecode format to one with explicit source and destination registers. The new format has multiple benefits: - ~25% faster on the Kraken and Octane benchmarks :^) - Fewer instructions to accomplish the same thing - Much easier for humans to read(!) Because this change requires a fundamental shift in how bytecode is generated, it is quite comprehensive. Main implementation mechanism: generate_bytecode() virtual function now takes an optional "preferred dst" operand, which allows callers to communicate when they have an operand that would be optimal for the result to go into. It also returns an optional "actual dst" operand, which is where the completion value (if any) of the AST node is stored after the node has "executed". One thing of note that's new: because instructions can now take locals as operands, this means we got rid of the GetLocal instruction. A side-effect of that is we have to think about the temporal deadzone (TDZ) a bit differently for locals (GetLocal would previously check for empty values and interpret that as a TDZ access and throw). We now insert special ThrowIfTDZ instructions in places where a local access may be in the TDZ, to maintain the correct behavior. There are a number of progressions and regressions from this test: A number of async generator tests have been accidentally fixed while converting the implementation to the new bytecode format. It didn't seem useful to preserve bugs in the original code when converting it. Some "does eval() return the correct completion value" tests have regressed, in particular ones related to propagating the appropriate completion after control flow statements like continue and break. These are all fairly obscure issues, and I believe we can continue working on them separately. The net test262 result is a progression though. :^)
2024-02-04 08:00:54 +01:00
return ByteString::formatted("End {}", format_operand("value"sv, m_value, executable));
LibJS: Stop converting between Object <-> IteratorRecord all the time This patch makes IteratorRecord an Object. Although it's not exposed to author code, this does allow us to store it in a VM register. Now that we can store it in a VM register, we don't need to convert it back and forth between IteratorRecord and Object when accessing it from bytecode. The big win here is avoiding 3 [[Get]] accesses on every iteration step of for..of loops. There are also a bunch of smaller efficiencies gained. 20% speed-up on this microbenchmark: function go(a) { for (const p of a) { } } const a = []; a.length = 1_000_000; go(a);
2023-12-07 10:44:41 +01:00
}
LibJS/Bytecode: Move to a new bytecode format This patch moves us away from the accumulator-based bytecode format to one with explicit source and destination registers. The new format has multiple benefits: - ~25% faster on the Kraken and Octane benchmarks :^) - Fewer instructions to accomplish the same thing - Much easier for humans to read(!) Because this change requires a fundamental shift in how bytecode is generated, it is quite comprehensive. Main implementation mechanism: generate_bytecode() virtual function now takes an optional "preferred dst" operand, which allows callers to communicate when they have an operand that would be optimal for the result to go into. It also returns an optional "actual dst" operand, which is where the completion value (if any) of the AST node is stored after the node has "executed". One thing of note that's new: because instructions can now take locals as operands, this means we got rid of the GetLocal instruction. A side-effect of that is we have to think about the temporal deadzone (TDZ) a bit differently for locals (GetLocal would previously check for empty values and interpret that as a TDZ access and throw). We now insert special ThrowIfTDZ instructions in places where a local access may be in the TDZ, to maintain the correct behavior. There are a number of progressions and regressions from this test: A number of async generator tests have been accidentally fixed while converting the implementation to the new bytecode format. It didn't seem useful to preserve bugs in the original code when converting it. Some "does eval() return the correct completion value" tests have regressed, in particular ones related to propagating the appropriate completion after control flow statements like continue and break. These are all fairly obscure issues, and I believe we can continue working on them separately. The net test262 result is a progression though. :^)
2024-02-04 08:00:54 +01:00
ByteString Dump::to_byte_string_impl(Bytecode::Executable const& executable) const
LibJS: Stop converting between Object <-> IteratorRecord all the time This patch makes IteratorRecord an Object. Although it's not exposed to author code, this does allow us to store it in a VM register. Now that we can store it in a VM register, we don't need to convert it back and forth between IteratorRecord and Object when accessing it from bytecode. The big win here is avoiding 3 [[Get]] accesses on every iteration step of for..of loops. There are also a bunch of smaller efficiencies gained. 20% speed-up on this microbenchmark: function go(a) { for (const p of a) { } } const a = []; a.length = 1_000_000; go(a);
2023-12-07 10:44:41 +01:00
{
LibJS/Bytecode: Move to a new bytecode format This patch moves us away from the accumulator-based bytecode format to one with explicit source and destination registers. The new format has multiple benefits: - ~25% faster on the Kraken and Octane benchmarks :^) - Fewer instructions to accomplish the same thing - Much easier for humans to read(!) Because this change requires a fundamental shift in how bytecode is generated, it is quite comprehensive. Main implementation mechanism: generate_bytecode() virtual function now takes an optional "preferred dst" operand, which allows callers to communicate when they have an operand that would be optimal for the result to go into. It also returns an optional "actual dst" operand, which is where the completion value (if any) of the AST node is stored after the node has "executed". One thing of note that's new: because instructions can now take locals as operands, this means we got rid of the GetLocal instruction. A side-effect of that is we have to think about the temporal deadzone (TDZ) a bit differently for locals (GetLocal would previously check for empty values and interpret that as a TDZ access and throw). We now insert special ThrowIfTDZ instructions in places where a local access may be in the TDZ, to maintain the correct behavior. There are a number of progressions and regressions from this test: A number of async generator tests have been accidentally fixed while converting the implementation to the new bytecode format. It didn't seem useful to preserve bugs in the original code when converting it. Some "does eval() return the correct completion value" tests have regressed, in particular ones related to propagating the appropriate completion after control flow statements like continue and break. These are all fairly obscure issues, and I believe we can continue working on them separately. The net test262 result is a progression though. :^)
2024-02-04 08:00:54 +01:00
return ByteString::formatted("Dump '{}', {}", m_text,
format_operand("value"sv, m_value, executable));
LibJS: Stop converting between Object <-> IteratorRecord all the time This patch makes IteratorRecord an Object. Although it's not exposed to author code, this does allow us to store it in a VM register. Now that we can store it in a VM register, we don't need to convert it back and forth between IteratorRecord and Object when accessing it from bytecode. The big win here is avoiding 3 [[Get]] accesses on every iteration step of for..of loops. There are also a bunch of smaller efficiencies gained. 20% speed-up on this microbenchmark: function go(a) { for (const p of a) { } } const a = []; a.length = 1_000_000; go(a);
2023-12-07 10:44:41 +01:00
}
LibJS: Move all bytecode instruction implementations to Interpreter.cpp This allows aggressive inlining without LTO.
2023-09-27 10:10:00 +02:00
}
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