Stowage/ladybird
2
0
Fork 0
mirror of https://github.com/LadybirdBrowser/ladybird.git synced 2025-11-03 23:00:58 +00:00
Code Issues Projects Releases Packages Wiki Activity
ladybird/Userland/Libraries/LibJS/Runtime/VM.cpp
Ali Mohammad Pur 5e1499d104 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')
2023-12-17 18:25:10 +03:30

1043 lines
45 KiB
C++
Raw Blame History

This file contains ambiguous Unicode characters

This file contains Unicode characters that might be confused with other characters. If you think that this is intentional, you can safely ignore this warning. Use the Escape button to reveal them.

/*
* Copyright (c) 2020-2023, Andreas Kling <kling@serenityos.org>
* Copyright (c) 2020-2023, Linus Groh <linusg@serenityos.org>
* Copyright (c) 2021-2022, David Tuin <davidot@serenityos.org>
*
* SPDX-License-Identifier: BSD-2-Clause
*/
#include <AK/Array.h>
#include <AK/Debug.h>
#include <AK/LexicalPath.h>
#include <AK/ScopeGuard.h>
#include <AK/String.h>
#include <AK/StringBuilder.h>
#include <LibFileSystem/FileSystem.h>
#include <LibJS/AST.h>
#include <LibJS/Bytecode/Interpreter.h>
#include <LibJS/JIT/NativeExecutable.h>
#include <LibJS/Runtime/AbstractOperations.h>
#include <LibJS/Runtime/Array.h>
#include <LibJS/Runtime/BoundFunction.h>
#include <LibJS/Runtime/Completion.h>
#include <LibJS/Runtime/ECMAScriptFunctionObject.h>
#include <LibJS/Runtime/Error.h>
#include <LibJS/Runtime/FinalizationRegistry.h>
#include <LibJS/Runtime/FunctionEnvironment.h>
#include <LibJS/Runtime/Iterator.h>
#include <LibJS/Runtime/NativeFunction.h>
#include <LibJS/Runtime/PromiseCapability.h>
#include <LibJS/Runtime/Reference.h>
#include <LibJS/Runtime/Symbol.h>
#include <LibJS/Runtime/VM.h>
#include <LibJS/SourceTextModule.h>
#include <LibJS/SyntheticModule.h>
namespace JS {
ErrorOr<NonnullRefPtr<VM>> VM::create(OwnPtr<CustomData> custom_data)
{
ErrorMessages error_messages {};
error_messages[to_underlying(ErrorMessage::OutOfMemory)] = TRY(String::from_utf8(ErrorType::OutOfMemory.message()));
auto vm = adopt_ref(*new VM(move(custom_data), move(error_messages)));
WellKnownSymbols well_known_symbols {
#define __JS_ENUMERATE(SymbolName, snake_name) \
Symbol::create(*vm, "Symbol." #SymbolName##_string, false),
JS_ENUMERATE_WELL_KNOWN_SYMBOLS
#undef __JS_ENUMERATE
};
vm->set_well_known_symbols(move(well_known_symbols));
return vm;
}
template<u32... code_points>
static constexpr auto make_single_ascii_character_strings(IndexSequence<code_points...>)
{
return AK::Array { (String::from_code_point(code_points))... };
}
static constexpr auto single_ascii_character_strings = make_single_ascii_character_strings(MakeIndexSequence<128>());
VM::VM(OwnPtr<CustomData> custom_data, ErrorMessages error_messages)
: m_heap(*this)
, m_error_messages(move(error_messages))
, m_custom_data(move(custom_data))
{
m_bytecode_interpreter = make<Bytecode::Interpreter>(*this);
m_empty_string = m_heap.allocate_without_realm<PrimitiveString>(String {});
for (size_t i = 0; i < single_ascii_character_strings.size(); ++i)
m_single_ascii_character_strings[i] = m_heap.allocate_without_realm<PrimitiveString>(single_ascii_character_strings[i]);
// Default hook implementations. These can be overridden by the host, for example, LibWeb overrides the default hooks to place promise jobs on the microtask queue.
host_promise_rejection_tracker = [this](Promise& promise, Promise::RejectionOperation operation) {
promise_rejection_tracker(promise, operation);
};
host_call_job_callback = [this](JobCallback& job_callback, Value this_value, ReadonlySpan<Value> arguments) {
return call_job_callback(*this, job_callback, this_value, arguments);
};
host_enqueue_finalization_registry_cleanup_job = [this](FinalizationRegistry& finalization_registry) {
enqueue_finalization_registry_cleanup_job(finalization_registry);
};
host_enqueue_promise_job = [this](Function<ThrowCompletionOr<Value>()> job, Realm* realm) {
enqueue_promise_job(move(job), realm);
};
host_make_job_callback = [](FunctionObject& function_object) {
return make_job_callback(function_object);
};
host_load_imported_module = [this](ImportedModuleReferrer referrer, ModuleRequest const& module_request, GCPtr<GraphLoadingState::HostDefined> load_state, ImportedModulePayload payload) -> void {
return load_imported_module(referrer, module_request, load_state, move(payload));
};
host_get_import_meta_properties = [&](SourceTextModule const&) -> HashMap<PropertyKey, Value> {
return {};
};
host_finalize_import_meta = [&](Object*, SourceTextModule const&) {
};
host_get_supported_import_attributes = [&] {
return Vector<ByteString> { "type" };
};
// 19.2.1.2 HostEnsureCanCompileStrings ( callerRealm, calleeRealm ), https://tc39.es/ecma262/#sec-hostensurecancompilestrings
host_ensure_can_compile_strings = [](Realm&) -> ThrowCompletionOr<void> {
// The host-defined abstract operation HostEnsureCanCompileStrings takes argument calleeRealm (a Realm Record)
// and returns either a normal completion containing unused or a throw completion.
// It allows host environments to block certain ECMAScript functions which allow developers to compile strings into ECMAScript code.
// An implementation of HostEnsureCanCompileStrings must conform to the following requirements:
// - If the returned Completion Record is a normal completion, it must be a normal completion containing unused.
// The default implementation of HostEnsureCanCompileStrings is to return NormalCompletion(unused).
return {};
};
host_ensure_can_add_private_element = [](Object&) -> ThrowCompletionOr<void> {
// The host-defined abstract operation HostEnsureCanAddPrivateElement takes argument O (an Object)
// and returns either a normal completion containing unused or a throw completion.
// It allows host environments to prevent the addition of private elements to particular host-defined exotic objects.
// An implementation of HostEnsureCanAddPrivateElement must conform to the following requirements:
// - If O is not a host-defined exotic object, this abstract operation must return NormalCompletion(unused) and perform no other steps.
// - Any two calls of this abstract operation with the same argument must return the same kind of Completion Record.
// The default implementation of HostEnsureCanAddPrivateElement is to return NormalCompletion(unused).
return {};
// This abstract operation is only invoked by ECMAScript hosts that are web browsers.
// NOTE: Since LibJS has no way of knowing whether the current environment is a browser we always
// call HostEnsureCanAddPrivateElement when needed.
};
}
VM::~VM() = default;
String const& VM::error_message(ErrorMessage type) const
{
VERIFY(type < ErrorMessage::__Count);
auto const& message = m_error_messages[to_underlying(type)];
VERIFY(!message.is_empty());
return message;
}
Bytecode::Interpreter& VM::bytecode_interpreter()
{
return *m_bytecode_interpreter;
}
struct ExecutionContextRootsCollector : public Cell::Visitor {
virtual void visit_impl(Cell& cell) override
{
roots.set(&cell);
}
virtual void visit_possible_values(ReadonlyBytes) override
{
VERIFY_NOT_REACHED();
}
HashTable<Cell*> roots;
};
void VM::gather_roots(HashMap<Cell*, HeapRoot>& roots)
{
roots.set(m_empty_string, HeapRoot { .type = HeapRoot::Type::VM });
for (auto string : m_single_ascii_character_strings)
roots.set(string, HeapRoot { .type = HeapRoot::Type::VM });
#define __JS_ENUMERATE(SymbolName, snake_name) \
roots.set(m_well_known_symbols.snake_name, HeapRoot { .type = HeapRoot::Type::VM });
JS_ENUMERATE_WELL_KNOWN_SYMBOLS
#undef __JS_ENUMERATE
for (auto& symbol : m_global_symbol_registry)
roots.set(symbol.value, HeapRoot { .type = HeapRoot::Type::VM });
for (auto finalization_registry : m_finalization_registry_cleanup_jobs)
roots.set(finalization_registry, HeapRoot { .type = HeapRoot::Type::VM });
auto gather_roots_from_execution_context_stack = [&roots](Vector<ExecutionContext*> const& stack) {
for (auto const& execution_context : stack) {
ExecutionContextRootsCollector visitor;
execution_context->visit_edges(visitor);
for (auto* cell : visitor.roots)
roots.set(cell, HeapRoot { .type = HeapRoot::Type::VM });
}
};
gather_roots_from_execution_context_stack(m_execution_context_stack);
for (auto& saved_stack : m_saved_execution_context_stacks)
gather_roots_from_execution_context_stack(saved_stack);
}
ThrowCompletionOr<Value> VM::named_evaluation_if_anonymous_function(ASTNode const& expression, DeprecatedFlyString const& name)
{
// 8.3.3 Static Semantics: IsAnonymousFunctionDefinition ( expr ), https://tc39.es/ecma262/#sec-isanonymousfunctiondefinition
// And 8.3.5 Runtime Semantics: NamedEvaluation, https://tc39.es/ecma262/#sec-runtime-semantics-namedevaluation
if (is<FunctionExpression>(expression)) {
auto& function = static_cast<FunctionExpression const&>(expression);
if (!function.has_name()) {
return function.instantiate_ordinary_function_expression(*this, name);
}
} else if (is<ClassExpression>(expression)) {
auto& class_expression = static_cast<ClassExpression const&>(expression);
if (!class_expression.has_name()) {
return TRY(class_expression.class_definition_evaluation(*this, {}, name));
}
}
return execute_ast_node(expression);
}
// 8.5.2 Runtime Semantics: BindingInitialization, https://tc39.es/ecma262/#sec-runtime-semantics-bindinginitialization
ThrowCompletionOr<void> VM::binding_initialization(DeprecatedFlyString const& target, Value value, Environment* environment)
{
// 1. Let name be StringValue of Identifier.
// 2. Return ? InitializeBoundName(name, value, environment).
return initialize_bound_name(*this, target, value, environment);
}
// 8.5.2 Runtime Semantics: BindingInitialization, https://tc39.es/ecma262/#sec-runtime-semantics-bindinginitialization
ThrowCompletionOr<void> VM::binding_initialization(NonnullRefPtr<BindingPattern const> const& target, Value value, Environment* environment)
{
auto& vm = *this;
// BindingPattern : ObjectBindingPattern
if (target->kind == BindingPattern::Kind::Object) {
// 1. Perform ? RequireObjectCoercible(value).
TRY(require_object_coercible(vm, value));
// 2. Return ? BindingInitialization of ObjectBindingPattern with arguments value and environment.
// BindingInitialization of ObjectBindingPattern
// 1. Perform ? PropertyBindingInitialization of BindingPropertyList with arguments value and environment.
TRY(property_binding_initialization(*target, value, environment));
// 2. Return unused.
return {};
}
// BindingPattern : ArrayBindingPattern
else {
// 1. Let iteratorRecord be ? GetIterator(value, sync).
auto iterator_record = TRY(get_iterator(vm, value, IteratorHint::Sync));
// 2. Let result be Completion(IteratorBindingInitialization of ArrayBindingPattern with arguments iteratorRecord and environment).
auto result = iterator_binding_initialization(*target, iterator_record, environment);
// 3. If iteratorRecord.[[Done]] is false, return ? IteratorClose(iteratorRecord, result).
if (!iterator_record->done) {
// iterator_close() always returns a Completion, which ThrowCompletionOr will interpret as a throw
// completion. So only return the result of iterator_close() if it is indeed a throw completion.
auto completion = result.is_throw_completion() ? result.release_error() : normal_completion({});
if (completion = iterator_close(vm, iterator_record, move(completion)); completion.is_error())
return completion.release_error();
}
// 4. Return ? result.
return result;
}
}
ThrowCompletionOr<Value> VM::execute_ast_node(ASTNode const& node)
{
auto executable = TRY(Bytecode::compile(*this, node, FunctionKind::Normal, ""sv));
auto result_or_error = bytecode_interpreter().run_and_return_frame(*executable, nullptr);
if (result_or_error.value.is_error())
return result_or_error.value.release_error();
return result_or_error.frame->registers()[0];
}
// 13.15.5.3 Runtime Semantics: PropertyDestructuringAssignmentEvaluation, https://tc39.es/ecma262/#sec-runtime-semantics-propertydestructuringassignmentevaluation
// 14.3.3.1 Runtime Semantics: PropertyBindingInitialization, https://tc39.es/ecma262/#sec-destructuring-binding-patterns-runtime-semantics-propertybindinginitialization
ThrowCompletionOr<void> VM::property_binding_initialization(BindingPattern const& binding, Value value, Environment* environment)
{
auto& vm = *this;
auto& realm = *vm.current_realm();
auto object = TRY(value.to_object(vm));
HashTable<PropertyKey> seen_names;
for (auto& property : binding.entries) {
VERIFY(!property.is_elision());
if (property.is_rest) {
Reference assignment_target;
if (auto identifier_ptr = property.name.get_pointer<NonnullRefPtr<Identifier const>>()) {
assignment_target = TRY(resolve_binding((*identifier_ptr)->string(), environment));
} else {
VERIFY_NOT_REACHED();
}
auto rest_object = Object::create(realm, realm.intrinsics().object_prototype());
VERIFY(rest_object);
TRY(rest_object->copy_data_properties(vm, object, seen_names));
if (!environment)
return assignment_target.put_value(vm, rest_object);
else
return assignment_target.initialize_referenced_binding(vm, rest_object);
}
auto name = TRY(property.name.visit(
[&](Empty) -> ThrowCompletionOr<PropertyKey> { VERIFY_NOT_REACHED(); },
[&](NonnullRefPtr<Identifier const> const& identifier) -> ThrowCompletionOr<PropertyKey> {
return identifier->string();
},
[&](NonnullRefPtr<Expression const> const& expression) -> ThrowCompletionOr<PropertyKey> {
auto result = TRY(execute_ast_node(*expression));
return result.to_property_key(vm);
}));
seen_names.set(name);
if (property.name.has<NonnullRefPtr<Identifier const>>() && property.alias.has<Empty>()) {
// FIXME: this branch and not taking this have a lot in common we might want to unify it more (like it was before).
auto& identifier = *property.name.get<NonnullRefPtr<Identifier const>>();
auto reference = TRY(resolve_binding(identifier.string(), environment));
auto value_to_assign = TRY(object->get(name));
if (property.initializer && value_to_assign.is_undefined()) {
value_to_assign = TRY(named_evaluation_if_anonymous_function(*property.initializer, identifier.string()));
}
if (!environment)
TRY(reference.put_value(vm, value_to_assign));
else
TRY(reference.initialize_referenced_binding(vm, value_to_assign));
continue;
}
auto reference_to_assign_to = TRY(property.alias.visit(
[&](Empty) -> ThrowCompletionOr<Optional<Reference>> { return Optional<Reference> {}; },
[&](NonnullRefPtr<Identifier const> const& identifier) -> ThrowCompletionOr<Optional<Reference>> {
return TRY(resolve_binding(identifier->string(), environment));
},
[&](NonnullRefPtr<BindingPattern const> const&) -> ThrowCompletionOr<Optional<Reference>> { return Optional<Reference> {}; },
[&](NonnullRefPtr<MemberExpression const> const&) -> ThrowCompletionOr<Optional<Reference>> {
VERIFY_NOT_REACHED();
}));
auto value_to_assign = TRY(object->get(name));
if (property.initializer && value_to_assign.is_undefined()) {
if (auto* identifier_ptr = property.alias.get_pointer<NonnullRefPtr<Identifier const>>())
value_to_assign = TRY(named_evaluation_if_anonymous_function(*property.initializer, (*identifier_ptr)->string()));
else
value_to_assign = TRY(execute_ast_node(*property.initializer));
}
if (auto* binding_ptr = property.alias.get_pointer<NonnullRefPtr<BindingPattern const>>()) {
TRY(binding_initialization(*binding_ptr, value_to_assign, environment));
} else {
VERIFY(reference_to_assign_to.has_value());
if (!environment)
TRY(reference_to_assign_to->put_value(vm, value_to_assign));
else
TRY(reference_to_assign_to->initialize_referenced_binding(vm, value_to_assign));
}
}
return {};
}
// 13.15.5.5 Runtime Semantics: IteratorDestructuringAssignmentEvaluation, https://tc39.es/ecma262/#sec-runtime-semantics-iteratordestructuringassignmentevaluation
// 8.5.3 Runtime Semantics: IteratorBindingInitialization, https://tc39.es/ecma262/#sec-runtime-semantics-iteratorbindinginitialization
ThrowCompletionOr<void> VM::iterator_binding_initialization(BindingPattern const& binding, IteratorRecord& iterator_record, Environment* environment)
{
auto& vm = *this;
auto& realm = *vm.current_realm();
// FIXME: this method is nearly identical to destructuring assignment!
for (size_t i = 0; i < binding.entries.size(); i++) {
auto& entry = binding.entries[i];
Value value;
auto assignment_target = TRY(entry.alias.visit(
[&](Empty) -> ThrowCompletionOr<Optional<Reference>> { return Optional<Reference> {}; },
[&](NonnullRefPtr<Identifier const> const& identifier) -> ThrowCompletionOr<Optional<Reference>> {
return TRY(resolve_binding(identifier->string(), environment));
},
[&](NonnullRefPtr<BindingPattern const> const&) -> ThrowCompletionOr<Optional<Reference>> { return Optional<Reference> {}; },
[&](NonnullRefPtr<MemberExpression const> const&) -> ThrowCompletionOr<Optional<Reference>> {
VERIFY_NOT_REACHED();
}));
// BindingRestElement : ... BindingIdentifier
// BindingRestElement : ... BindingPattern
if (entry.is_rest) {
VERIFY(i == binding.entries.size() - 1);
// 2. Let A be ! ArrayCreate(0).
auto array = MUST(Array::create(realm, 0));
// 3. Let n be 0.
// 4. Repeat,
while (true) {
ThrowCompletionOr<GCPtr<Object>> next { nullptr };
// a. If iteratorRecord.[[Done]] is false, then
if (!iterator_record.done) {
// i. Let next be Completion(IteratorStep(iteratorRecord)).
next = iterator_step(vm, iterator_record);
// ii. If next is an abrupt completion, set iteratorRecord.[[Done]] to true.
// iii. ReturnIfAbrupt(next).
if (next.is_error()) {
iterator_record.done = true;
return next.release_error();
}
// iv. If next is false, set iteratorRecord.[[Done]] to true.
if (!next.value())
iterator_record.done = true;
}
// b. If iteratorRecord.[[Done]] is true, then
if (iterator_record.done) {
// NOTE: Step i. and ii. are handled below.
break;
}
// c. Let nextValue be Completion(IteratorValue(next)).
auto next_value = iterator_value(vm, *next.value());
// d. If nextValue is an abrupt completion, set iteratorRecord.[[Done]] to true.
// e. ReturnIfAbrupt(nextValue).
if (next_value.is_error()) {
iterator_record.done = true;
return next_value.release_error();
}
// f. Perform ! CreateDataPropertyOrThrow(A, ! ToString(𝔽(n)), nextValue).
array->indexed_properties().append(next_value.value());
// g. Set n to n + 1.
}
value = array;
}
// SingleNameBinding : BindingIdentifier Initializer[opt]
// BindingElement : BindingPattern Initializer[opt]
else {
// 1. Let v be undefined.
value = js_undefined();
// 2. If iteratorRecord.[[Done]] is false, then
if (!iterator_record.done) {
// a. Let next be Completion(IteratorStep(iteratorRecord)).
auto next = iterator_step(vm, iterator_record);
// b. If next is an abrupt completion, set iteratorRecord.[[Done]] to true.
// c. ReturnIfAbrupt(next).
if (next.is_error()) {
iterator_record.done = true;
return next.release_error();
}
// d. If next is false, set iteratorRecord.[[Done]] to true.
if (!next.value()) {
iterator_record.done = true;
}
// e. Else,
else {
// i. Set v to Completion(IteratorValue(next)).
auto value_or_error = iterator_value(vm, *next.value());
// ii. If v is an abrupt completion, set iteratorRecord.[[Done]] to true.
// iii. ReturnIfAbrupt(v).
if (value_or_error.is_throw_completion()) {
iterator_record.done = true;
return value_or_error.release_error();
}
value = value_or_error.release_value();
}
}
// NOTE: Step 3. and 4. are handled below.
}
if (value.is_undefined() && entry.initializer) {
VERIFY(!entry.is_rest);
if (auto* identifier_ptr = entry.alias.get_pointer<NonnullRefPtr<Identifier const>>())
value = TRY(named_evaluation_if_anonymous_function(*entry.initializer, (*identifier_ptr)->string()));
else
value = TRY(execute_ast_node(*entry.initializer));
}
if (auto* binding_ptr = entry.alias.get_pointer<NonnullRefPtr<BindingPattern const>>()) {
TRY(binding_initialization(*binding_ptr, value, environment));
} else if (!entry.alias.has<Empty>()) {
VERIFY(assignment_target.has_value());
if (!environment)
TRY(assignment_target->put_value(vm, value));
else
TRY(assignment_target->initialize_referenced_binding(vm, value));
}
}
return {};
}
// 9.1.2.1 GetIdentifierReference ( env, name, strict ), https://tc39.es/ecma262/#sec-getidentifierreference
ThrowCompletionOr<Reference> VM::get_identifier_reference(Environment* environment, DeprecatedFlyString name, bool strict, size_t hops)
{
// 1. If env is the value null, then
if (!environment) {
// a. Return the Reference Record { [[Base]]: unresolvable, [[ReferencedName]]: name, [[Strict]]: strict, [[ThisValue]]: empty }.
return Reference { Reference::BaseType::Unresolvable, move(name), strict };
}
// 2. Let exists be ? env.HasBinding(name).
Optional<size_t> index;
auto exists = TRY(environment->has_binding(name, &index));
// Note: This is an optimization for looking up the same reference.
Optional<EnvironmentCoordinate> environment_coordinate;
if (index.has_value()) {
VERIFY(hops <= NumericLimits<u32>::max());
VERIFY(index.value() <= NumericLimits<u32>::max());
environment_coordinate = EnvironmentCoordinate { .hops = static_cast<u32>(hops), .index = static_cast<u32>(index.value()) };
}
// 3. If exists is true, then
if (exists) {
// a. Return the Reference Record { [[Base]]: env, [[ReferencedName]]: name, [[Strict]]: strict, [[ThisValue]]: empty }.
return Reference { *environment, move(name), strict, environment_coordinate };
}
// 4. Else,
else {
// a. Let outer be env.[[OuterEnv]].
// b. Return ? GetIdentifierReference(outer, name, strict).
return get_identifier_reference(environment->outer_environment(), move(name), strict, hops + 1);
}
}
// 9.4.2 ResolveBinding ( name [ , env ] ), https://tc39.es/ecma262/#sec-resolvebinding
ThrowCompletionOr<Reference> VM::resolve_binding(DeprecatedFlyString const& name, Environment* environment)
{
// 1. If env is not present or if env is undefined, then
if (!environment) {
// a. Set env to the running execution context's LexicalEnvironment.
environment = running_execution_context().lexical_environment;
}
// 2. Assert: env is an Environment Record.
VERIFY(environment);
// 3. If the source text matched by the syntactic production that is being evaluated is contained in strict mode code, let strict be true; else let strict be false.
bool strict = in_strict_mode();
// 4. Return ? GetIdentifierReference(env, name, strict).
return get_identifier_reference(environment, name, strict);
// NOTE: The spec says:
// Note: The result of ResolveBinding is always a Reference Record whose [[ReferencedName]] field is name.
// But this is not actually correct as GetIdentifierReference (or really the methods it calls) can throw.
}
// 9.4.4 ResolveThisBinding ( ), https://tc39.es/ecma262/#sec-resolvethisbinding
ThrowCompletionOr<Value> VM::resolve_this_binding()
{
auto& vm = *this;
// 1. Let envRec be GetThisEnvironment().
auto environment = get_this_environment(vm);
// 2. Return ? envRec.GetThisBinding().
return TRY(environment->get_this_binding(vm));
}
// 9.4.5 GetNewTarget ( ), https://tc39.es/ecma262/#sec-getnewtarget
Value VM::get_new_target()
{
// 1. Let envRec be GetThisEnvironment().
auto env = get_this_environment(*this);
// 2. Assert: envRec has a [[NewTarget]] field.
// 3. Return envRec.[[NewTarget]].
return verify_cast<FunctionEnvironment>(*env).new_target();
}
// 13.3.12.1 Runtime Semantics: Evaluation, https://tc39.es/ecma262/#sec-meta-properties-runtime-semantics-evaluation
// ImportMeta branch only
Object* VM::get_import_meta()
{
// 1. Let module be GetActiveScriptOrModule().
auto script_or_module = get_active_script_or_module();
// 2. Assert: module is a Source Text Module Record.
auto& module = verify_cast<SourceTextModule>(*script_or_module.get<NonnullGCPtr<Module>>());
// 3. Let importMeta be module.[[ImportMeta]].
auto* import_meta = module.import_meta();
// 4. If importMeta is empty, then
if (import_meta == nullptr) {
// a. Set importMeta to OrdinaryObjectCreate(null).
import_meta = Object::create(*current_realm(), nullptr);
// b. Let importMetaValues be HostGetImportMetaProperties(module).
auto import_meta_values = host_get_import_meta_properties(module);
// c. For each Record { [[Key]], [[Value]] } p of importMetaValues, do
for (auto& entry : import_meta_values) {
// i. Perform ! CreateDataPropertyOrThrow(importMeta, p.[[Key]], p.[[Value]]).
MUST(import_meta->create_data_property_or_throw(entry.key, entry.value));
}
// d. Perform HostFinalizeImportMeta(importMeta, module).
host_finalize_import_meta(import_meta, module);
// e. Set module.[[ImportMeta]] to importMeta.
module.set_import_meta({}, import_meta);
// f. Return importMeta.
return import_meta;
}
// 5. Else,
else {
// a. Assert: Type(importMeta) is Object.
// Note: This is always true by the type.
// b. Return importMeta.
return import_meta;
}
}
// 9.4.5 GetGlobalObject ( ), https://tc39.es/ecma262/#sec-getglobalobject
Object& VM::get_global_object()
{
// 1. Let currentRealm be the current Realm Record.
auto& current_realm = *this->current_realm();
// 2. Return currentRealm.[[GlobalObject]].
return current_realm.global_object();
}
bool VM::in_strict_mode() const
{
if (execution_context_stack().is_empty())
return false;
return running_execution_context().is_strict_mode;
}
void VM::run_queued_promise_jobs()
{
dbgln_if(PROMISE_DEBUG, "Running queued promise jobs");
while (!m_promise_jobs.is_empty()) {
auto job = m_promise_jobs.take_first();
dbgln_if(PROMISE_DEBUG, "Calling promise job function");
[[maybe_unused]] auto result = job();
}
}
// 9.5.4 HostEnqueuePromiseJob ( job, realm ), https://tc39.es/ecma262/#sec-hostenqueuepromisejob
void VM::enqueue_promise_job(Function<ThrowCompletionOr<Value>()> job, Realm*)
{
// An implementation of HostEnqueuePromiseJob must conform to the requirements in 9.5 as well as the following:
// - FIXME: If realm is not null, each time job is invoked the implementation must perform implementation-defined steps such that execution is prepared to evaluate ECMAScript code at the time of job's invocation.
// - FIXME: Let scriptOrModule be GetActiveScriptOrModule() at the time HostEnqueuePromiseJob is invoked. If realm is not null, each time job is invoked the implementation must perform implementation-defined steps
// such that scriptOrModule is the active script or module at the time of job's invocation.
// - Jobs must run in the same order as the HostEnqueuePromiseJob invocations that scheduled them.
m_promise_jobs.append(move(job));
}
void VM::run_queued_finalization_registry_cleanup_jobs()
{
while (!m_finalization_registry_cleanup_jobs.is_empty()) {
auto registry = m_finalization_registry_cleanup_jobs.take_first();
// FIXME: Handle any uncatched exceptions here.
(void)registry->cleanup();
}
}
// 9.10.4.1 HostEnqueueFinalizationRegistryCleanupJob ( finalizationRegistry ), https://tc39.es/ecma262/#sec-host-cleanup-finalization-registry
void VM::enqueue_finalization_registry_cleanup_job(FinalizationRegistry& registry)
{
m_finalization_registry_cleanup_jobs.append(&registry);
}
// 27.2.1.9 HostPromiseRejectionTracker ( promise, operation ), https://tc39.es/ecma262/#sec-host-promise-rejection-tracker
void VM::promise_rejection_tracker(Promise& promise, Promise::RejectionOperation operation) const
{
switch (operation) {
case Promise::RejectionOperation::Reject:
// A promise was rejected without any handlers
if (on_promise_unhandled_rejection)
on_promise_unhandled_rejection(promise);
break;
case Promise::RejectionOperation::Handle:
// A handler was added to an already rejected promise
if (on_promise_rejection_handled)
on_promise_rejection_handled(promise);
break;
default:
VERIFY_NOT_REACHED();
}
}
void VM::dump_backtrace() const
{
for (ssize_t i = m_execution_context_stack.size() - 1; i >= 0; --i) {
auto& frame = m_execution_context_stack[i];
if (frame->instruction_stream_iterator.has_value() && frame->instruction_stream_iterator->source_code()) {
auto source_range = frame->instruction_stream_iterator->source_range().realize();
dbgln("-> {} @ {}:{},{}", frame->function_name ? frame->function_name->utf8_string() : ""_string, source_range.filename(), source_range.start.line, source_range.start.column);
} else {
dbgln("-> {}", frame->function_name ? frame->function_name->utf8_string() : ""_string);
}
}
}
void VM::save_execution_context_stack()
{
m_saved_execution_context_stacks.append(move(m_execution_context_stack));
}
void VM::restore_execution_context_stack()
{
m_execution_context_stack = m_saved_execution_context_stacks.take_last();
}
// 9.4.1 GetActiveScriptOrModule ( ), https://tc39.es/ecma262/#sec-getactivescriptormodule
ScriptOrModule VM::get_active_script_or_module() const
{
// 1. If the execution context stack is empty, return null.
if (m_execution_context_stack.is_empty())
return Empty {};
// 2. Let ec be the topmost execution context on the execution context stack whose ScriptOrModule component is not null.
for (auto i = m_execution_context_stack.size() - 1; i > 0; i--) {
if (!m_execution_context_stack[i]->script_or_module.has<Empty>())
return m_execution_context_stack[i]->script_or_module;
}
// 3. If no such execution context exists, return null. Otherwise, return ec's ScriptOrModule.
// Note: Since it is not empty we have 0 and since we got here all the
// above contexts don't have a non-null ScriptOrModule
return m_execution_context_stack[0]->script_or_module;
}
VM::StoredModule* VM::get_stored_module(ImportedModuleReferrer const&, ByteString const& filename, ByteString const&)
{
// Note the spec says:
// If this operation is called multiple times with the same (referrer, specifier) pair and it performs
// FinishLoadingImportedModule(referrer, specifier, payload, result) where result is a normal completion,
// then it must perform FinishLoadingImportedModule(referrer, specifier, payload, result) with the same result each time.
// Editor's Note from https://tc39.es/proposal-json-modules/#sec-hostresolveimportedmodule
// The above text implies that is recommended but not required that hosts do not use moduleRequest.[[Assertions]]
// as part of the module cache key. In either case, an exception thrown from an import with a given assertion list
// does not rule out success of another import with the same specifier but a different assertion list.
// FIXME: This should probably check referrer as well.
auto end_or_module = m_loaded_modules.find_if([&](StoredModule const& stored_module) {
return stored_module.filename == filename;
});
if (end_or_module.is_end())
return nullptr;
return &(*end_or_module);
}
ThrowCompletionOr<void> VM::link_and_eval_module(Badge<Bytecode::Interpreter>, SourceTextModule& module)
{
return link_and_eval_module(module);
}
ThrowCompletionOr<void> VM::link_and_eval_module(CyclicModule& module)
{
auto filename = module.filename();
module.load_requested_modules(nullptr);
dbgln_if(JS_MODULE_DEBUG, "[JS MODULE] Linking module {}", filename);
auto linked_or_error = module.link(*this);
if (linked_or_error.is_error())
return linked_or_error.throw_completion();
dbgln_if(JS_MODULE_DEBUG, "[JS MODULE] Linking passed, now evaluating module {}", filename);
auto evaluated_or_error = module.evaluate(*this);
if (evaluated_or_error.is_error())
return evaluated_or_error.throw_completion();
auto* evaluated_value = evaluated_or_error.value();
run_queued_promise_jobs();
VERIFY(m_promise_jobs.is_empty());
// FIXME: This will break if we start doing promises actually asynchronously.
VERIFY(evaluated_value->state() != Promise::State::Pending);
if (evaluated_value->state() == Promise::State::Rejected)
return JS::throw_completion(evaluated_value->result());
dbgln_if(JS_MODULE_DEBUG, "[JS MODULE] Evaluating passed for module {}", module.filename());
return {};
}
static ByteString resolve_module_filename(StringView filename, StringView module_type)
{
auto extensions = Vector<StringView, 2> { "js"sv, "mjs"sv };
if (module_type == "json"sv)
extensions = { "json"sv };
if (!FileSystem::exists(filename)) {
for (auto extension : extensions) {
// import "./foo" -> import "./foo.ext"
auto resolved_filepath = ByteString::formatted("{}.{}", filename, extension);
if (FileSystem::exists(resolved_filepath))
return resolved_filepath;
}
} else if (FileSystem::is_directory(filename)) {
for (auto extension : extensions) {
// import "./foo" -> import "./foo/index.ext"
auto resolved_filepath = LexicalPath::join(filename, ByteString::formatted("index.{}", extension)).string();
if (FileSystem::exists(resolved_filepath))
return resolved_filepath;
}
}
return filename;
}
// 16.2.1.8 HostLoadImportedModule ( referrer, specifier, hostDefined, payload ), https://tc39.es/ecma262/#sec-HostLoadImportedModule
void VM::load_imported_module(ImportedModuleReferrer referrer, ModuleRequest const& module_request, GCPtr<GraphLoadingState::HostDefined>, ImportedModulePayload payload)
{
// An implementation of HostLoadImportedModule must conform to the following requirements:
//
// - The host environment must perform FinishLoadingImportedModule(referrer, specifier, payload, result),
// where result is either a normal completion containing the loaded Module Record or a throw completion,
// either synchronously or asynchronously.
// - If this operation is called multiple times with the same (referrer, specifier) pair and it performs
// FinishLoadingImportedModule(referrer, specifier, payload, result) where result is a normal completion,
// then it must perform FinishLoadingImportedModule(referrer, specifier, payload, result) with the same result each time.
// - The operation must treat payload as an opaque value to be passed through to FinishLoadingImportedModule.
//
// The actual process performed is host-defined, but typically consists of performing whatever I/O operations are necessary to
// load the appropriate Module Record. Multiple different (referrer, specifier) pairs may map to the same Module Record instance.
// The actual mapping semantics is host-defined but typically a normalization process is applied to specifier as part of the
// mapping process. A typical normalization process would include actions such as expansion of relative and abbreviated path specifiers.
// Here we check, against the spec, if payload is a promise capability, meaning that this was called for a dynamic import
if (payload.has<NonnullGCPtr<PromiseCapability>>() && !m_dynamic_imports_allowed) {
// If you are here because you want to enable dynamic module importing make sure it won't be a security problem
// by checking the default implementation of HostImportModuleDynamically and creating your own hook or calling
// vm.allow_dynamic_imports().
finish_loading_imported_module(referrer, module_request, payload, throw_completion<InternalError>(ErrorType::DynamicImportNotAllowed, module_request.module_specifier));
return;
}
ByteString module_type;
for (auto& attribute : module_request.attributes) {
if (attribute.key == "type"sv) {
module_type = attribute.value;
break;
}
}
dbgln_if(JS_MODULE_DEBUG, "[JS MODULE] module at {} has type {}", module_request.module_specifier, module_type);
StringView const base_filename = referrer.visit(
[&](NonnullGCPtr<Realm> const&) {
// Generally within ECMA262 we always get a referencing_script_or_module. However, ShadowRealm gives an explicit null.
// To get around this is we attempt to get the active script_or_module otherwise we might start loading "random" files from the working directory.
return get_active_script_or_module().visit(
[](Empty) {
return "."sv;
},
[](auto const& script_or_module) {
return script_or_module->filename();
});
},
[&](auto const& script_or_module) {
return script_or_module->filename();
});
LexicalPath base_path { base_filename };
auto filename = LexicalPath::absolute_path(base_path.dirname(), module_request.module_specifier);
dbgln_if(JS_MODULE_DEBUG, "[JS MODULE] base path: '{}'", base_path);
dbgln_if(JS_MODULE_DEBUG, "[JS MODULE] initial filename: '{}'", filename);
filename = resolve_module_filename(filename, module_type);
dbgln_if(JS_MODULE_DEBUG, "[JS MODULE] resolved filename: '{}'", filename);
#if JS_MODULE_DEBUG
ByteString referencing_module_string = referrer.visit(
[&](Empty) -> ByteString {
return ".";
},
[&](auto& script_or_module) {
if constexpr (IsSame<Script*, decltype(script_or_module)>) {
return ByteString::formatted("Script @ {}", script_or_module.ptr());
}
return ByteString::formatted("Module @ {}", script_or_module.ptr());
});
dbgln_if(JS_MODULE_DEBUG, "[JS MODULE] load_imported_module({}, {})", referencing_module_string, filename);
dbgln_if(JS_MODULE_DEBUG, "[JS MODULE] resolved {} + {} -> {}", base_path, module_request.module_specifier, filename);
#endif
auto* loaded_module_or_end = get_stored_module(referrer, filename, module_type);
if (loaded_module_or_end != nullptr) {
dbgln_if(JS_MODULE_DEBUG, "[JS MODULE] load_imported_module({}) already loaded at {}", filename, loaded_module_or_end->module.ptr());
finish_loading_imported_module(referrer, module_request, payload, *loaded_module_or_end->module);
return;
}
dbgln_if(JS_MODULE_DEBUG, "[JS MODULE] reading and parsing module {}", filename);
auto file_or_error = Core::File::open(filename, Core::File::OpenMode::Read);
if (file_or_error.is_error()) {
finish_loading_imported_module(referrer, module_request, payload, throw_completion<SyntaxError>(ErrorType::ModuleNotFound, module_request.module_specifier));
return;
}
// FIXME: Don't read the file in one go.
auto file_content_or_error = file_or_error.value()->read_until_eof();
if (file_content_or_error.is_error()) {
if (file_content_or_error.error().code() == ENOMEM) {
finish_loading_imported_module(referrer, module_request, payload, throw_completion<JS::InternalError>(error_message(::JS::VM::ErrorMessage::OutOfMemory)));
return;
}
finish_loading_imported_module(referrer, module_request, payload, throw_completion<SyntaxError>(ErrorType::ModuleNotFound, module_request.module_specifier));
return;
}
StringView const content_view { file_content_or_error.value().bytes() };
auto module = [&]() -> ThrowCompletionOr<NonnullGCPtr<Module>> {
// If assertions has an entry entry such that entry.[[Key]] is "type", let type be entry.[[Value]]. The following requirements apply:
// If type is "json", then this algorithm must either invoke ParseJSONModule and return the resulting Completion Record, or throw an exception.
if (module_type == "json"sv) {
dbgln_if(JS_MODULE_DEBUG, "[JS MODULE] reading and parsing JSON module {}", filename);
return parse_json_module(content_view, *current_realm(), filename);
}
dbgln_if(JS_MODULE_DEBUG, "[JS MODULE] reading and parsing as SourceTextModule module {}", filename);
// Note: We treat all files as module, so if a script does not have exports it just runs it.
auto module_or_errors = SourceTextModule::parse(content_view, *current_realm(), filename);
if (module_or_errors.is_error()) {
VERIFY(module_or_errors.error().size() > 0);
return throw_completion<SyntaxError>(module_or_errors.error().first().to_byte_string());
}
auto module = module_or_errors.release_value();
m_loaded_modules.empend(
referrer,
module->filename(),
ByteString {}, // Null type
make_handle<Module>(*module),
true);
return module;
}();
finish_loading_imported_module(referrer, module_request, payload, module);
}
void VM::push_execution_context(ExecutionContext& context)
{
if (!m_execution_context_stack.is_empty())
m_execution_context_stack.last()->instruction_stream_iterator = bytecode_interpreter().instruction_stream_iterator();
m_execution_context_stack.append(&context);
}
void VM::pop_execution_context()
{
m_execution_context_stack.take_last();
if (m_execution_context_stack.is_empty() && on_call_stack_emptied)
on_call_stack_emptied();
}
#if ARCH(X86_64)
struct [[gnu::packed]] NativeStackFrame {
NativeStackFrame* prev;
FlatPtr return_address;
};
#endif
Vector<FlatPtr> VM::get_native_stack_trace() const
{
Vector<FlatPtr> buffer;
#if ARCH(X86_64)
// Manually walk the stack, because backtrace() does not traverse through JIT frames.
auto* frame = bit_cast<NativeStackFrame*>(__builtin_frame_address(0));
while (bit_cast<FlatPtr>(frame) < m_stack_info.top() && bit_cast<FlatPtr>(frame) >= m_stack_info.base()) {
buffer.append(frame->return_address);
frame = frame->prev;
}
#endif
return buffer;
}
static Optional<UnrealizedSourceRange> get_source_range(ExecutionContext const* context, Vector<FlatPtr> const& native_stack)
{
// native function
if (!context->executable)
return {};
auto const* native_executable = context->executable->native_executable();
if (!native_executable) {
// Interpreter frame
if (context->instruction_stream_iterator.has_value())
return context->instruction_stream_iterator->source_range();
return {};
}
// JIT frame
for (auto address : native_stack) {
auto range = native_executable->get_source_range(*context->executable, address);
if (range.has_value())
return range;
}
return {};
}
Vector<StackTraceElement> VM::stack_trace() const
{
auto native_stack = get_native_stack_trace();
Vector<StackTraceElement> stack_trace;
for (ssize_t i = m_execution_context_stack.size() - 1; i >= 0; i--) {
auto* context = m_execution_context_stack[i];
stack_trace.append({
.execution_context = context,
.source_range = get_source_range(context, native_stack).value_or({}),
});
}
return stack_trace;
}
}
Reference in a new issue View git blame Copy permalink