ladybird/Libraries/LibWeb/WebAssembly/Memory.cpp

/*
 * Copyright (c) 2021, Ali Mohammad Pur <mpfard@serenityos.org>
 * Copyright (c) 2023, Tim Flynn <trflynn89@serenityos.org>
 *
 * SPDX-License-Identifier: BSD-2-Clause
 */

#include <LibJS/Runtime/Realm.h>
#include <LibJS/Runtime/SharedArrayBufferConstructor.h>
#include <LibJS/Runtime/VM.h>
#include <LibWasm/Types.h>
#include <LibWeb/Bindings/Intrinsics.h>
#include <LibWeb/Bindings/MemoryPrototype.h>
#include <LibWeb/WebAssembly/Memory.h>
#include <LibWeb/WebAssembly/WebAssembly.h>

namespace Web::WebAssembly {

GC_DEFINE_ALLOCATOR(Memory);

WebIDL::ExceptionOr<GC::Ref<Memory>> Memory::construct_impl(JS::Realm& realm, MemoryDescriptor& descriptor)
{
    auto& vm = realm.vm();

    // https://webassembly.github.io/threads/js-api/index.html#dom-memory-memory
    // 4. Let share be shared if descriptor["shared"] is true and unshared otherwise.
    // 5. If share is shared and maximum is empty, throw a TypeError exception.
    auto shared = descriptor.shared.value_or(false);
    if (shared && !descriptor.maximum.has_value())
        return vm.throw_completion<JS::TypeError>("Maximum has to be specified for shared memory."sv);

    Wasm::Limits limits { descriptor.initial, move(descriptor.maximum) };
    Wasm::MemoryType memory_type { move(limits) };

    auto& cache = Detail::get_cache(realm);
    auto address = cache.abstract_machine().store().allocate(memory_type);
    if (!address.has_value())
        return vm.throw_completion<JS::TypeError>("Wasm Memory allocation failed"sv);

    auto memory_object = realm.create<Memory>(realm, *address, shared ? Shared::Yes : Shared::No);

    return memory_object;
}

Memory::Memory(JS::Realm& realm, Wasm::MemoryAddress address, Shared shared)
    : Bindings::PlatformObject(realm)
    , m_address(address)
    , m_shared(shared)
{
    auto& cache = Detail::get_cache(realm);

    cache.abstract_machine().store().get(address)->successful_grow_hook = [realm = GC::Ref(realm), address] {
        refresh_the_memory_buffer(realm->vm(), realm, address);
    };
}

// https://webassembly.github.io/spec/js-api/#initialize-a-memory-object
void Memory::initialize(JS::Realm& realm)
{
    WEB_SET_PROTOTYPE_FOR_INTERFACE_WITH_CUSTOM_NAME(Memory, WebAssembly.Memory);
    Base::initialize(realm);

    auto& vm = realm.vm();

    // https://webassembly.github.io/spec/js-api/#initialize-a-memory-object
    // 1. Let map be the surrounding agent’s associated Memory object cache.
    // 2. Assert: map[memaddr] doesn’t exist.
    auto& cache = Detail::get_cache(realm);
    auto exists = cache.memory_instances().contains(m_address);
    VERIFY(!exists);

    // 3. Let buffer be the result of creating a fixed length memory buffer from memaddr.
    auto buffer = create_a_fixed_length_memory_buffer(vm, realm, m_address, m_shared);

    // 4. Set memory.[[Memory]] to memaddr.
    // NOTE: This is already set by the Memory constructor.

    // 5. Set memory.[[BufferObject]] to buffer.
    m_buffer = buffer;

    // 6. Set map[memaddr] to memory.
    cache.add_memory_instance(m_address, *this);
}

void Memory::visit_edges(Visitor& visitor)
{
    Base::visit_edges(visitor);
    visitor.visit(m_buffer);
}

// https://webassembly.github.io/spec/js-api/#dom-memory-grow
WebIDL::ExceptionOr<u32> Memory::grow(u32 delta)
{
    auto& vm = this->vm();

    auto& context = Detail::get_cache(realm());
    auto* memory = context.abstract_machine().store().get(address());
    VERIFY(memory);

    auto previous_size = memory->size() / Wasm::Constants::page_size;
    if (!memory->grow(delta * Wasm::Constants::page_size, Wasm::MemoryInstance::GrowType::No, Wasm::MemoryInstance::InhibitGrowCallback::Yes))
        return vm.throw_completion<JS::RangeError>("Memory.grow() grows past the stated limit of the memory instance"sv);

    refresh_the_memory_buffer(vm, realm(), m_address);

    return previous_size;
}

// https://webassembly.github.io/spec/js-api/#refresh-the-memory-buffer
void Memory::refresh_the_memory_buffer(JS::VM& vm, JS::Realm& realm, Wasm::MemoryAddress address)
{
    // 1. Let map be the surrounding agent’s associated Memory object cache.
    // 2. Assert: map[memaddr] exists.
    // 3. Let memory be map[memaddr].
    auto& cache = Detail::get_cache(realm);
    auto memory = cache.get_memory_instance(address);
    VERIFY(memory.has_value());

    // 4. Let buffer be memory.[[BufferObject]].
    auto& buffer = memory.value()->m_buffer;

    // 5. If IsFixedLengthArrayBuffer(buffer) is true,
    if (buffer->is_fixed_length()) {
        // https://webassembly.github.io/threads/js-api/index.html#refresh-the-memory-buffer
        // 1. If IsSharedArrayBuffer(buffer) is false,
        if (!buffer->is_shared_array_buffer()) {
            // 1. Perform ! DetachArrayBuffer(buffer, "WebAssembly.Memory").
            MUST(JS::detach_array_buffer(vm, *buffer, JS::PrimitiveString::create(vm, "WebAssembly.Memory"_string)));
        }

        // 2. Let newBuffer be the result of creating a fixed length memory buffer from memaddr.
        // 3. Set memory.[[BufferObject]] to newBuffer.
    }

    buffer = create_a_fixed_length_memory_buffer(vm, realm, address, memory.value()->m_shared);
}

// https://webassembly.github.io/spec/js-api/#dom-memory-buffer
WebIDL::ExceptionOr<GC::Ref<JS::ArrayBuffer>> Memory::buffer() const
{
    return GC::Ref(*m_buffer);
}

// https://webassembly.github.io/spec/js-api/#create-a-fixed-length-memory-buffer
GC::Ref<JS::ArrayBuffer> Memory::create_a_fixed_length_memory_buffer(JS::VM& vm, JS::Realm& realm, Wasm::MemoryAddress address, Shared shared)
{
    auto& context = Detail::get_cache(realm);
    auto* memory = context.abstract_machine().store().get(address);
    VERIFY(memory);

    JS::ArrayBuffer* array_buffer;
    // https://webassembly.github.io/threads/js-api/index.html#create-a-fixed-length-memory-buffer
    // 3. If share is shared,
    if (shared == Shared::Yes) {
        // 1. Let block be a Shared Data Block which is identified with the underlying memory of memaddr.
        // 2. Let buffer be a new SharedArrayBuffer with the internal slots [[ArrayBufferData]] and [[ArrayBufferByteLength]].
        // 3. Set buffer.[[ArrayBufferData]] to block.
        array_buffer = JS::ArrayBuffer::create(realm, &memory->data(), JS::DataBlock::Shared::Yes);

        // 4. Set buffer.[[ArrayBufferByteLength]] to the length of block.
        VERIFY(array_buffer->byte_length() == memory->size());

        // 5. Perform ! SetIntegrityLevel(buffer, "frozen").
        MUST(array_buffer->set_integrity_level(JS::Object::IntegrityLevel::Frozen));
    }

    // 4. Otherwise,
    else {
        array_buffer = JS::ArrayBuffer::create(realm, &memory->data());
        array_buffer->set_detach_key(JS::PrimitiveString::create(vm, "WebAssembly.Memory"_string));
    }

    return GC::Ref(*array_buffer);
}

}
-												LibWeb: Port WebAssembly.Memory to IDL

											
										
										
											2023-03-15 19:29:57 -04:00
+								/*
 								 * Copyright (c) 2021, Ali Mohammad Pur <mpfard@serenityos.org>
 								 * Copyright (c) 2023, Tim Flynn <trflynn89@serenityos.org>
 								 *
 								 * SPDX-License-Identifier: BSD-2-Clause
 								 */
 								#include <LibJS/Runtime/Realm.h>
-												LibWeb: Support creation of shared memory in WebAssembly API

Add support for shared memory creation in WebAssembly memory API.
This API is needed for WPT tests that use shared array buffers.

Import related WPT tests.

											
										
										
											2024-12-07 21:17:20 +01:00
+								#include <LibJS/Runtime/SharedArrayBufferConstructor.h>
-												LibWeb: Port WebAssembly.Memory to IDL

											
										
										
											2023-03-15 19:29:57 -04:00
+								#include <LibJS/Runtime/VM.h>
 								#include <LibWasm/Types.h>
 								#include <LibWeb/Bindings/Intrinsics.h>
-												LibWeb: Remove Bindings/Forward.h from LibWeb/Forward.h

This was resulting in a whole lot of rebuilding whenever a new IDL
interface was added.

Instead, just directly include the prototype in every C++ file which
needs it. While we only really need a forward declaration in each cpp
file; including the full prototype header (which itself only includes
LibJS/Object.h, which is already transitively brought in by
PlatformObject) - it seems like a small price to pay compared to what
feels like a full rebuild of LibWeb whenever a new IDL file is added.

Given all of these includes are only needed for the ::initialize
method, there is probably a smart way of avoiding this problem
altogether. I've considered both using some macro trickery or generating
these functions somehow instead.

											
										
										
											2024-04-27 12:09:58 +12:00
+								#include <LibWeb/Bindings/MemoryPrototype.h>
-												LibWeb: Port WebAssembly.Memory to IDL

											
										
										
											2023-03-15 19:29:57 -04:00
+								#include <LibWeb/WebAssembly/Memory.h>
-												LibWeb: Remove remaining WebAssemblyObject data to the namespace file

											
										
										
											2023-03-16 14:11:21 -04:00
+								#include <LibWeb/WebAssembly/WebAssembly.h>
-												LibWeb: Port WebAssembly.Memory to IDL

											
										
										
											2023-03-15 19:29:57 -04:00
 								namespace Web::WebAssembly {
-												LibGC+Everywhere: Factor out a LibGC from LibJS

Resulting in a massive rename across almost everywhere! Alongside the
namespace change, we now have the following names:

 * JS::NonnullGCPtr -> GC::Ref
 * JS::GCPtr -> GC::Ptr
 * JS::HeapFunction -> GC::Function
 * JS::CellImpl -> GC::Cell
 * JS::Handle -> GC::Root

											
										
										
											2024-11-15 04:01:23 +13:00
+								GC_DEFINE_ALLOCATOR(Memory);
-												LibWeb: Put most LibWeb GC objects in type-specific heap blocks

With this change, we now have ~1200 CellAllocators across both LibJS and
LibWeb in a normal WebContent instance.

This gives us a minimum heap size of 4.7 MiB in the scenario where we
only have one cell allocated per type. Of course, in practice there will
be many more of each type, so the effective overhead is quite a bit
smaller than that in practice.

I left a few types unconverted to this mechanism because I got tired of
doing this. :^)

											
										
										
											2023-11-19 19:47:52 +01:00
-												LibGC+Everywhere: Factor out a LibGC from LibJS

Resulting in a massive rename across almost everywhere! Alongside the
namespace change, we now have the following names:

 * JS::NonnullGCPtr -> GC::Ref
 * JS::GCPtr -> GC::Ptr
 * JS::HeapFunction -> GC::Function
 * JS::CellImpl -> GC::Cell
 * JS::Handle -> GC::Root

											
										
										
											2024-11-15 04:01:23 +13:00
+								WebIDL::ExceptionOr<GC::Ref<Memory>> Memory::construct_impl(JS::Realm& realm, MemoryDescriptor& descriptor)
-												LibWeb: Port WebAssembly.Memory to IDL

											
										
										
											2023-03-15 19:29:57 -04:00
+								{
 								    auto& vm = realm.vm();
-												LibWeb: Support creation of shared memory in WebAssembly API

Add support for shared memory creation in WebAssembly memory API.
This API is needed for WPT tests that use shared array buffers.

Import related WPT tests.

											
										
										
											2024-12-07 21:17:20 +01:00
+								    // https://webassembly.github.io/threads/js-api/index.html#dom-memory-memory
 								    // 4. Let share be shared if descriptor["shared"] is true and unshared otherwise.
 								    // 5. If share is shared and maximum is empty, throw a TypeError exception.
 								    auto shared = descriptor.shared.value_or(false);
 								    if (shared && !descriptor.maximum.has_value())
 								        return vm.throw_completion<JS::TypeError>("Maximum has to be specified for shared memory."sv);
-												LibWeb: Port WebAssembly.Memory to IDL

											
										
										
											2023-03-15 19:29:57 -04:00
+								    Wasm::Limits limits { descriptor.initial, move(descriptor.maximum) };
 								    Wasm::MemoryType memory_type { move(limits) };
-												LibWeb: Isolate WebAssembly cache by global object

This change moves WebAssembly related data that was previously globally
accessible into the `WebAssemblyCache` object and creates one of these
per global object. This ensures that WebAssembly data cannot be
accessed across realms.

											
										
										
											2024-04-25 19:09:34 +01:00
+								    auto& cache = Detail::get_cache(realm);
 								    auto address = cache.abstract_machine().store().allocate(memory_type);
-												LibWeb: Port WebAssembly.Memory to IDL

											
										
										
											2023-03-15 19:29:57 -04:00
+								    if (!address.has_value())
 								        return vm.throw_completion<JS::TypeError>("Wasm Memory allocation failed"sv);
-												LibWeb: Support creation of shared memory in WebAssembly API

Add support for shared memory creation in WebAssembly memory API.
This API is needed for WPT tests that use shared array buffers.

Import related WPT tests.

											
										
										
											2024-12-07 21:17:20 +01:00
+								    auto memory_object = realm.create<Memory>(realm, *address, shared ? Shared::Yes : Shared::No);
-												LibWeb+LibWasm: Implement and use the "reset the Memory buffer" steps

This implements the memory object cache and its "reset on grow"
semantics, as the web depends on the exact behaviour.

											
										
										
											2023-03-29 01:31:51 +03:30
+								    return memory_object;
-												LibWeb: Port WebAssembly.Memory to IDL

											
										
										
											2023-03-15 19:29:57 -04:00
+								}
-												LibWeb: Support creation of shared memory in WebAssembly API

Add support for shared memory creation in WebAssembly memory API.
This API is needed for WPT tests that use shared array buffers.

Import related WPT tests.

											
										
										
											2024-12-07 21:17:20 +01:00
+								Memory::Memory(JS::Realm& realm, Wasm::MemoryAddress address, Shared shared)
-												LibWeb: Port WebAssembly.Memory to IDL

											
										
										
											2023-03-15 19:29:57 -04:00
+								    : Bindings::PlatformObject(realm)
 								    , m_address(address)
-												LibWeb: Support creation of shared memory in WebAssembly API

Add support for shared memory creation in WebAssembly memory API.
This API is needed for WPT tests that use shared array buffers.

Import related WPT tests.

											
										
										
											2024-12-07 21:17:20 +01:00
+								    , m_shared(shared)
-												LibWeb: Port WebAssembly.Memory to IDL

											
										
										
											2023-03-15 19:29:57 -04:00
+								{
-												LibWeb: Register Wasm memory grow hook in constructor of Memory objects

Previously it would only register the hook for JavaScript constructed
Memory objects. This allows Ruffle to load again.

											
										
										
											2024-12-10 13:29:37 +00:00
+								    auto& cache = Detail::get_cache(realm);
-												LibWeb: Implement the WebAssembly "Memory object cache" + other changes

This cache is referenced by a few parts of the JS API spec, including
the threads spec (such as in toFixedLengthBuffer), as well as the
"refresh the Memory buffer" algorithm, which was implemented as a method
of Memory before this change.

Now, this algorithm can be implemented in a spec-like fashion (though it
mostly seems to add extra complexity). This change also fixes a bug
where memories that were re-exported from an imported WebAssembly.Memory
were given a distinct WebAssembly.Memory object, since the caching that
existed in Instance.cpp was instance-local, not global to the realm.

We also make Memory::m_buffer non-lazy, since we have to implement
"initialize a memory object" correctly anyway.

											
										
										
											2025-08-18 21:13:58 -07:00
+								    cache.abstract_machine().store().get(address)->successful_grow_hook = [realm = GC::Ref(realm), address] {
 								        refresh_the_memory_buffer(realm->vm(), realm, address);
-												LibWeb: Register Wasm memory grow hook in constructor of Memory objects

Previously it would only register the hook for JavaScript constructed
Memory objects. This allows Ruffle to load again.

											
										
										
											2024-12-10 13:29:37 +00:00
+								    };
-												LibWeb: Port WebAssembly.Memory to IDL

											
										
										
											2023-03-15 19:29:57 -04:00
+								}
-												LibWeb: Implement the WebAssembly "Memory object cache" + other changes

This cache is referenced by a few parts of the JS API spec, including
the threads spec (such as in toFixedLengthBuffer), as well as the
"refresh the Memory buffer" algorithm, which was implemented as a method
of Memory before this change.

Now, this algorithm can be implemented in a spec-like fashion (though it
mostly seems to add extra complexity). This change also fixes a bug
where memories that were re-exported from an imported WebAssembly.Memory
were given a distinct WebAssembly.Memory object, since the caching that
existed in Instance.cpp was instance-local, not global to the realm.

We also make Memory::m_buffer non-lazy, since we have to implement
"initialize a memory object" correctly anyway.

											
										
										
											2025-08-18 21:13:58 -07:00
+								// https://webassembly.github.io/spec/js-api/#initialize-a-memory-object
-												LibJS: Make Cell::initialize() return void

Stop worrying about tiny OOMs.

Work towards #20405

											
										
										
											2023-08-07 08:41:28 +02:00
+								void Memory::initialize(JS::Realm& realm)
-												LibWeb: Port WebAssembly.Memory to IDL

											
										
										
											2023-03-15 19:29:57 -04:00
+								{
-												LibWeb: Avoid FlyString lookups when setting IDL interface prototypes

This commit introduces a WEB_SET_PROTOTYPE_FOR_INTERFACE macro that
caches the interface name in a local static FlyString. This means that
we only pay for FlyString-from-literal lookup once per browser lifetime
instead of every time the interface is instantiated.

											
										
										
											2024-03-16 13:13:08 +01:00
+								    WEB_SET_PROTOTYPE_FOR_INTERFACE_WITH_CUSTOM_NAME(Memory, WebAssembly.Memory);
-												LibWeb: Only set prototype once for object with IDL interface

Before this change, we were going through the chain of base classes for
each IDL interface object and having them set the prototype to their
prototype.

Instead of doing that, reorder things so that we set the right prototype
immediately in Foo::initialize(), and then don't bother in all the base
class overrides.

This knocks off a ~1% profile item on Speedometer 3.

											
										
										
											2025-04-20 16:22:57 +02:00
+								    Base::initialize(realm);
-												LibWeb: Implement the WebAssembly "Memory object cache" + other changes

This cache is referenced by a few parts of the JS API spec, including
the threads spec (such as in toFixedLengthBuffer), as well as the
"refresh the Memory buffer" algorithm, which was implemented as a method
of Memory before this change.

Now, this algorithm can be implemented in a spec-like fashion (though it
mostly seems to add extra complexity). This change also fixes a bug
where memories that were re-exported from an imported WebAssembly.Memory
were given a distinct WebAssembly.Memory object, since the caching that
existed in Instance.cpp was instance-local, not global to the realm.

We also make Memory::m_buffer non-lazy, since we have to implement
"initialize a memory object" correctly anyway.

											
										
										
											2025-08-18 21:13:58 -07:00
 								    auto& vm = realm.vm();
 								    // https://webassembly.github.io/spec/js-api/#initialize-a-memory-object
 								    // 1. Let map be the surrounding agent’s associated Memory object cache.
 								    // 2. Assert: map[memaddr] doesn’t exist.
 								    auto& cache = Detail::get_cache(realm);
 								    auto exists = cache.memory_instances().contains(m_address);
 								    VERIFY(!exists);
 								    // 3. Let buffer be the result of creating a fixed length memory buffer from memaddr.
 								    auto buffer = create_a_fixed_length_memory_buffer(vm, realm, m_address, m_shared);
 								    // 4. Set memory.[[Memory]] to memaddr.
 								    // NOTE: This is already set by the Memory constructor.
 								    // 5. Set memory.[[BufferObject]] to buffer.
 								    m_buffer = buffer;
 								    // 6. Set map[memaddr] to memory.
 								    cache.add_memory_instance(m_address, *this);
-												LibWeb: Port WebAssembly.Memory to IDL

											
										
										
											2023-03-15 19:29:57 -04:00
+								}
-												LibWeb/WebAssembly: Add missing visit of WebAssembly::Memory::m_buffer

											
										
										
											2024-04-05 15:22:02 +02:00
+								void Memory::visit_edges(Visitor& visitor)
 								{
 								    Base::visit_edges(visitor);
 								    visitor.visit(m_buffer);
 								}
-												LibWeb: Port WebAssembly.Memory to IDL

											
										
										
											2023-03-15 19:29:57 -04:00
+								// https://webassembly.github.io/spec/js-api/#dom-memory-grow
 								WebIDL::ExceptionOr<u32> Memory::grow(u32 delta)
 								{
 								    auto& vm = this->vm();
-												LibWeb: Isolate WebAssembly cache by global object

This change moves WebAssembly related data that was previously globally
accessible into the `WebAssemblyCache` object and creates one of these
per global object. This ensures that WebAssembly data cannot be
accessed across realms.

											
										
										
											2024-04-25 19:09:34 +01:00
+								    auto& context = Detail::get_cache(realm());
 								    auto* memory = context.abstract_machine().store().get(address());
-												LibWeb: Implement the WebAssembly "Memory object cache" + other changes

This cache is referenced by a few parts of the JS API spec, including
the threads spec (such as in toFixedLengthBuffer), as well as the
"refresh the Memory buffer" algorithm, which was implemented as a method
of Memory before this change.

Now, this algorithm can be implemented in a spec-like fashion (though it
mostly seems to add extra complexity). This change also fixes a bug
where memories that were re-exported from an imported WebAssembly.Memory
were given a distinct WebAssembly.Memory object, since the caching that
existed in Instance.cpp was instance-local, not global to the realm.

We also make Memory::m_buffer non-lazy, since we have to implement
"initialize a memory object" correctly anyway.

											
										
										
											2025-08-18 21:13:58 -07:00
+								    VERIFY(memory);
-												LibWeb: Port WebAssembly.Memory to IDL

											
										
										
											2023-03-15 19:29:57 -04:00
 								    auto previous_size = memory->size() / Wasm::Constants::page_size;
-												LibWasm: Make `memory.grow` grow the memory's type

After a `memory.grow`, the type of the memory instance should be
updated so potential memory imports on the boundary are unlinkable.

											
										
										
											2024-07-10 15:05:20 -07:00
+								    if (!memory->grow(delta * Wasm::Constants::page_size, Wasm::MemoryInstance::GrowType::No, Wasm::MemoryInstance::InhibitGrowCallback::Yes))
-												LibWeb: Port WebAssembly.Memory to IDL

											
										
										
											2023-03-15 19:29:57 -04:00
+								        return vm.throw_completion<JS::RangeError>("Memory.grow() grows past the stated limit of the memory instance"sv);
-												LibWeb: Implement the WebAssembly "Memory object cache" + other changes

This cache is referenced by a few parts of the JS API spec, including
the threads spec (such as in toFixedLengthBuffer), as well as the
"refresh the Memory buffer" algorithm, which was implemented as a method
of Memory before this change.

Now, this algorithm can be implemented in a spec-like fashion (though it
mostly seems to add extra complexity). This change also fixes a bug
where memories that were re-exported from an imported WebAssembly.Memory
were given a distinct WebAssembly.Memory object, since the caching that
existed in Instance.cpp was instance-local, not global to the realm.

We also make Memory::m_buffer non-lazy, since we have to implement
"initialize a memory object" correctly anyway.

											
										
										
											2025-08-18 21:13:58 -07:00
+								    refresh_the_memory_buffer(vm, realm(), m_address);
-												LibWeb+LibWasm: Implement and use the "reset the Memory buffer" steps

This implements the memory object cache and its "reset on grow"
semantics, as the web depends on the exact behaviour.

											
										
										
											2023-03-29 01:31:51 +03:30
-												LibWeb: Port WebAssembly.Memory to IDL

											
										
										
											2023-03-15 19:29:57 -04:00
+								    return previous_size;
 								}
-												LibWeb: Support creation of shared memory in WebAssembly API

Add support for shared memory creation in WebAssembly memory API.
This API is needed for WPT tests that use shared array buffers.

Import related WPT tests.

											
										
										
											2024-12-07 21:17:20 +01:00
+								// https://webassembly.github.io/spec/js-api/#refresh-the-memory-buffer
-												LibWeb: Implement the WebAssembly "Memory object cache" + other changes

This cache is referenced by a few parts of the JS API spec, including
the threads spec (such as in toFixedLengthBuffer), as well as the
"refresh the Memory buffer" algorithm, which was implemented as a method
of Memory before this change.

Now, this algorithm can be implemented in a spec-like fashion (though it
mostly seems to add extra complexity). This change also fixes a bug
where memories that were re-exported from an imported WebAssembly.Memory
were given a distinct WebAssembly.Memory object, since the caching that
existed in Instance.cpp was instance-local, not global to the realm.

We also make Memory::m_buffer non-lazy, since we have to implement
"initialize a memory object" correctly anyway.

											
										
										
											2025-08-18 21:13:58 -07:00
+								void Memory::refresh_the_memory_buffer(JS::VM& vm, JS::Realm& realm, Wasm::MemoryAddress address)
-												LibWeb+LibWasm: Implement and use the "reset the Memory buffer" steps

This implements the memory object cache and its "reset on grow"
semantics, as the web depends on the exact behaviour.

											
										
										
											2023-03-29 01:31:51 +03:30
+								{
-												LibWeb: Implement the WebAssembly "Memory object cache" + other changes

This cache is referenced by a few parts of the JS API spec, including
the threads spec (such as in toFixedLengthBuffer), as well as the
"refresh the Memory buffer" algorithm, which was implemented as a method
of Memory before this change.

Now, this algorithm can be implemented in a spec-like fashion (though it
mostly seems to add extra complexity). This change also fixes a bug
where memories that were re-exported from an imported WebAssembly.Memory
were given a distinct WebAssembly.Memory object, since the caching that
existed in Instance.cpp was instance-local, not global to the realm.

We also make Memory::m_buffer non-lazy, since we have to implement
"initialize a memory object" correctly anyway.

											
										
										
											2025-08-18 21:13:58 -07:00
+								    // 1. Let map be the surrounding agent’s associated Memory object cache.
 								    // 2. Assert: map[memaddr] exists.
 								    // 3. Let memory be map[memaddr].
 								    auto& cache = Detail::get_cache(realm);
 								    auto memory = cache.get_memory_instance(address);
 								    VERIFY(memory.has_value());
-												LibWeb+LibWasm: Implement and use the "reset the Memory buffer" steps

This implements the memory object cache and its "reset on grow"
semantics, as the web depends on the exact behaviour.

											
										
										
											2023-03-29 01:31:51 +03:30
-												LibWeb: Implement the WebAssembly "Memory object cache" + other changes

This cache is referenced by a few parts of the JS API spec, including
the threads spec (such as in toFixedLengthBuffer), as well as the
"refresh the Memory buffer" algorithm, which was implemented as a method
of Memory before this change.

Now, this algorithm can be implemented in a spec-like fashion (though it
mostly seems to add extra complexity). This change also fixes a bug
where memories that were re-exported from an imported WebAssembly.Memory
were given a distinct WebAssembly.Memory object, since the caching that
existed in Instance.cpp was instance-local, not global to the realm.

We also make Memory::m_buffer non-lazy, since we have to implement
"initialize a memory object" correctly anyway.

											
										
										
											2025-08-18 21:13:58 -07:00
+								    // 4. Let buffer be memory.[[BufferObject]].
 								    auto& buffer = memory.value()->m_buffer;
-												LibWeb+LibWasm: Implement and use the "reset the Memory buffer" steps

This implements the memory object cache and its "reset on grow"
semantics, as the web depends on the exact behaviour.

											
										
										
											2023-03-29 01:31:51 +03:30
-												LibWeb: Implement the WebAssembly "Memory object cache" + other changes

This cache is referenced by a few parts of the JS API spec, including
the threads spec (such as in toFixedLengthBuffer), as well as the
"refresh the Memory buffer" algorithm, which was implemented as a method
of Memory before this change.

Now, this algorithm can be implemented in a spec-like fashion (though it
mostly seems to add extra complexity). This change also fixes a bug
where memories that were re-exported from an imported WebAssembly.Memory
were given a distinct WebAssembly.Memory object, since the caching that
existed in Instance.cpp was instance-local, not global to the realm.

We also make Memory::m_buffer non-lazy, since we have to implement
"initialize a memory object" correctly anyway.

											
										
										
											2025-08-18 21:13:58 -07:00
+								    // 5. If IsFixedLengthArrayBuffer(buffer) is true,
 								    if (buffer->is_fixed_length()) {
-												LibWeb: Support creation of shared memory in WebAssembly API

Add support for shared memory creation in WebAssembly memory API.
This API is needed for WPT tests that use shared array buffers.

Import related WPT tests.

											
										
										
											2024-12-07 21:17:20 +01:00
+								        // https://webassembly.github.io/threads/js-api/index.html#refresh-the-memory-buffer
 								        // 1. If IsSharedArrayBuffer(buffer) is false,
-												LibWeb: Implement the WebAssembly "Memory object cache" + other changes

This cache is referenced by a few parts of the JS API spec, including
the threads spec (such as in toFixedLengthBuffer), as well as the
"refresh the Memory buffer" algorithm, which was implemented as a method
of Memory before this change.

Now, this algorithm can be implemented in a spec-like fashion (though it
mostly seems to add extra complexity). This change also fixes a bug
where memories that were re-exported from an imported WebAssembly.Memory
were given a distinct WebAssembly.Memory object, since the caching that
existed in Instance.cpp was instance-local, not global to the realm.

We also make Memory::m_buffer non-lazy, since we have to implement
"initialize a memory object" correctly anyway.

											
										
										
											2025-08-18 21:13:58 -07:00
+								        if (!buffer->is_shared_array_buffer()) {
-												LibWeb: Support creation of shared memory in WebAssembly API

Add support for shared memory creation in WebAssembly memory API.
This API is needed for WPT tests that use shared array buffers.

Import related WPT tests.

											
										
										
											2024-12-07 21:17:20 +01:00
+								            // 1. Perform ! DetachArrayBuffer(buffer, "WebAssembly.Memory").
-												LibWeb: Implement the WebAssembly "Memory object cache" + other changes

This cache is referenced by a few parts of the JS API spec, including
the threads spec (such as in toFixedLengthBuffer), as well as the
"refresh the Memory buffer" algorithm, which was implemented as a method
of Memory before this change.

Now, this algorithm can be implemented in a spec-like fashion (though it
mostly seems to add extra complexity). This change also fixes a bug
where memories that were re-exported from an imported WebAssembly.Memory
were given a distinct WebAssembly.Memory object, since the caching that
existed in Instance.cpp was instance-local, not global to the realm.

We also make Memory::m_buffer non-lazy, since we have to implement
"initialize a memory object" correctly anyway.

											
										
										
											2025-08-18 21:13:58 -07:00
+								            MUST(JS::detach_array_buffer(vm, *buffer, JS::PrimitiveString::create(vm, "WebAssembly.Memory"_string)));
-												LibWeb: Support creation of shared memory in WebAssembly API

Add support for shared memory creation in WebAssembly memory API.
This API is needed for WPT tests that use shared array buffers.

Import related WPT tests.

											
										
										
											2024-12-07 21:17:20 +01:00
+								        }
-												LibWeb+LibWasm: Implement and use the "reset the Memory buffer" steps

This implements the memory object cache and its "reset on grow"
semantics, as the web depends on the exact behaviour.

											
										
										
											2023-03-29 01:31:51 +03:30
-												LibWeb: Implement the WebAssembly "Memory object cache" + other changes

This cache is referenced by a few parts of the JS API spec, including
the threads spec (such as in toFixedLengthBuffer), as well as the
"refresh the Memory buffer" algorithm, which was implemented as a method
of Memory before this change.

Now, this algorithm can be implemented in a spec-like fashion (though it
mostly seems to add extra complexity). This change also fixes a bug
where memories that were re-exported from an imported WebAssembly.Memory
were given a distinct WebAssembly.Memory object, since the caching that
existed in Instance.cpp was instance-local, not global to the realm.

We also make Memory::m_buffer non-lazy, since we have to implement
"initialize a memory object" correctly anyway.

											
										
										
											2025-08-18 21:13:58 -07:00
+								        // 2. Let newBuffer be the result of creating a fixed length memory buffer from memaddr.
 								        // 3. Set memory.[[BufferObject]] to newBuffer.
 								    }
-												LibWeb+LibWasm: Implement and use the "reset the Memory buffer" steps

This implements the memory object cache and its "reset on grow"
semantics, as the web depends on the exact behaviour.

											
										
										
											2023-03-29 01:31:51 +03:30
-												LibWeb: Implement the WebAssembly "Memory object cache" + other changes

This cache is referenced by a few parts of the JS API spec, including
the threads spec (such as in toFixedLengthBuffer), as well as the
"refresh the Memory buffer" algorithm, which was implemented as a method
of Memory before this change.

Now, this algorithm can be implemented in a spec-like fashion (though it
mostly seems to add extra complexity). This change also fixes a bug
where memories that were re-exported from an imported WebAssembly.Memory
were given a distinct WebAssembly.Memory object, since the caching that
existed in Instance.cpp was instance-local, not global to the realm.

We also make Memory::m_buffer non-lazy, since we have to implement
"initialize a memory object" correctly anyway.

											
										
										
											2025-08-18 21:13:58 -07:00
+								    buffer = create_a_fixed_length_memory_buffer(vm, realm, address, memory.value()->m_shared);
-												LibWeb+LibWasm: Implement and use the "reset the Memory buffer" steps

This implements the memory object cache and its "reset on grow"
semantics, as the web depends on the exact behaviour.

											
										
										
											2023-03-29 01:31:51 +03:30
+								}
-												LibWeb: Port WebAssembly.Memory to IDL

											
										
										
											2023-03-15 19:29:57 -04:00
+								// https://webassembly.github.io/spec/js-api/#dom-memory-buffer
-												LibGC+Everywhere: Factor out a LibGC from LibJS

Resulting in a massive rename across almost everywhere! Alongside the
namespace change, we now have the following names:

 * JS::NonnullGCPtr -> GC::Ref
 * JS::GCPtr -> GC::Ptr
 * JS::HeapFunction -> GC::Function
 * JS::CellImpl -> GC::Cell
 * JS::Handle -> GC::Root

											
										
										
											2024-11-15 04:01:23 +13:00
+								WebIDL::ExceptionOr<GC::Ref<JS::ArrayBuffer>> Memory::buffer() const
-												LibWeb: Port WebAssembly.Memory to IDL

											
										
										
											2023-03-15 19:29:57 -04:00
+								{
-												LibGC+Everywhere: Factor out a LibGC from LibJS

Resulting in a massive rename across almost everywhere! Alongside the
namespace change, we now have the following names:

 * JS::NonnullGCPtr -> GC::Ref
 * JS::GCPtr -> GC::Ptr
 * JS::HeapFunction -> GC::Function
 * JS::CellImpl -> GC::Cell
 * JS::Handle -> GC::Root

											
										
										
											2024-11-15 04:01:23 +13:00
+								    return GC::Ref(*m_buffer);
-												LibWeb+LibWasm: Implement and use the "reset the Memory buffer" steps

This implements the memory object cache and its "reset on grow"
semantics, as the web depends on the exact behaviour.

											
										
										
											2023-03-29 01:31:51 +03:30
+								}
-												LibWeb: Support creation of shared memory in WebAssembly API

Add support for shared memory creation in WebAssembly memory API.
This API is needed for WPT tests that use shared array buffers.

Import related WPT tests.

											
										
										
											2024-12-07 21:17:20 +01:00
+								// https://webassembly.github.io/spec/js-api/#create-a-fixed-length-memory-buffer
-												LibWeb: Implement the WebAssembly "Memory object cache" + other changes

This cache is referenced by a few parts of the JS API spec, including
the threads spec (such as in toFixedLengthBuffer), as well as the
"refresh the Memory buffer" algorithm, which was implemented as a method
of Memory before this change.

Now, this algorithm can be implemented in a spec-like fashion (though it
mostly seems to add extra complexity). This change also fixes a bug
where memories that were re-exported from an imported WebAssembly.Memory
were given a distinct WebAssembly.Memory object, since the caching that
existed in Instance.cpp was instance-local, not global to the realm.

We also make Memory::m_buffer non-lazy, since we have to implement
"initialize a memory object" correctly anyway.

											
										
										
											2025-08-18 21:13:58 -07:00
+								GC::Ref<JS::ArrayBuffer> Memory::create_a_fixed_length_memory_buffer(JS::VM& vm, JS::Realm& realm, Wasm::MemoryAddress address, Shared shared)
-												LibWeb+LibWasm: Implement and use the "reset the Memory buffer" steps

This implements the memory object cache and its "reset on grow"
semantics, as the web depends on the exact behaviour.

											
										
										
											2023-03-29 01:31:51 +03:30
+								{
-												LibWeb: Isolate WebAssembly cache by global object

This change moves WebAssembly related data that was previously globally
accessible into the `WebAssemblyCache` object and creates one of these
per global object. This ensures that WebAssembly data cannot be
accessed across realms.

											
										
										
											2024-04-25 19:09:34 +01:00
+								    auto& context = Detail::get_cache(realm);
 								    auto* memory = context.abstract_machine().store().get(address);
-												LibWeb: Implement the WebAssembly "Memory object cache" + other changes

This cache is referenced by a few parts of the JS API spec, including
the threads spec (such as in toFixedLengthBuffer), as well as the
"refresh the Memory buffer" algorithm, which was implemented as a method
of Memory before this change.

Now, this algorithm can be implemented in a spec-like fashion (though it
mostly seems to add extra complexity). This change also fixes a bug
where memories that were re-exported from an imported WebAssembly.Memory
were given a distinct WebAssembly.Memory object, since the caching that
existed in Instance.cpp was instance-local, not global to the realm.

We also make Memory::m_buffer non-lazy, since we have to implement
"initialize a memory object" correctly anyway.

											
										
										
											2025-08-18 21:13:58 -07:00
+								    VERIFY(memory);
-												LibWeb: Port WebAssembly.Memory to IDL

											
										
										
											2023-03-15 19:29:57 -04:00
-												LibWeb: Support creation of shared memory in WebAssembly API

Add support for shared memory creation in WebAssembly memory API.
This API is needed for WPT tests that use shared array buffers.

Import related WPT tests.

											
										
										
											2024-12-07 21:17:20 +01:00
+								    JS::ArrayBuffer* array_buffer;
 								    // https://webassembly.github.io/threads/js-api/index.html#create-a-fixed-length-memory-buffer
 								    // 3. If share is shared,
 								    if (shared == Shared::Yes) {
 								        // 1. Let block be a Shared Data Block which is identified with the underlying memory of memaddr.
 								        // 2. Let buffer be a new SharedArrayBuffer with the internal slots [[ArrayBufferData]] and [[ArrayBufferByteLength]].
-												LibWeb: Don't create a copy SharedArrayBuffer for shared Wasm memories

For whatever reason, the implementation of "create a fixed length memory
buffer" was borked for shared Wasm memories, in that a new
SharedArrayBuffer was created, with the contents of the Wasm memory
copied into it. This is incorrect, since the SharedArrayBuffer should be
a view into the Wasm memory's span, not a copy of it. This helps pass a
WPT subtest in wasm/jsapi/memory/grow.any.html.

											
										
										
											2025-08-17 12:19:55 -07:00
+								        // 3. Set buffer.[[ArrayBufferData]] to block.
 								        array_buffer = JS::ArrayBuffer::create(realm, &memory->data(), JS::DataBlock::Shared::Yes);
 								        // 4. Set buffer.[[ArrayBufferByteLength]] to the length of block.
 								        VERIFY(array_buffer->byte_length() == memory->size());
-												LibWeb: Support creation of shared memory in WebAssembly API

Add support for shared memory creation in WebAssembly memory API.
This API is needed for WPT tests that use shared array buffers.

Import related WPT tests.

											
										
										
											2024-12-07 21:17:20 +01:00
 								        // 5. Perform ! SetIntegrityLevel(buffer, "frozen").
 								        MUST(array_buffer->set_integrity_level(JS::Object::IntegrityLevel::Frozen));
 								    }
 								    // 4. Otherwise,
 								    else {
 								        array_buffer = JS::ArrayBuffer::create(realm, &memory->data());
 								        array_buffer->set_detach_key(JS::PrimitiveString::create(vm, "WebAssembly.Memory"_string));
 								    }
-												LibWeb: Port WebAssembly.Memory to IDL

											
										
										
											2023-03-15 19:29:57 -04:00
-												LibGC+Everywhere: Factor out a LibGC from LibJS

Resulting in a massive rename across almost everywhere! Alongside the
namespace change, we now have the following names:

 * JS::NonnullGCPtr -> GC::Ref
 * JS::GCPtr -> GC::Ptr
 * JS::HeapFunction -> GC::Function
 * JS::CellImpl -> GC::Cell
 * JS::Handle -> GC::Root

											
										
										
											2024-11-15 04:01:23 +13:00
+								    return GC::Ref(*array_buffer);
-												LibWeb: Port WebAssembly.Memory to IDL

											
										
										
											2023-03-15 19:29:57 -04:00
+								}
 								}