blob: 9169a315ea9a36bbfd6bf9f8251d4bd9783df580 [file] [log] [blame]
// Copyright 2019 the V8 project authors. All rights reserved.
// Use of this source code is governed by a BSD-style license that can be
// found in the LICENSE file.
#include "src/wasm/module-instantiate.h"
#include "src/api/api.h"
#include "src/asmjs/asm-js.h"
#include "src/logging/counters.h"
#include "src/logging/metrics.h"
#include "src/numbers/conversions-inl.h"
#include "src/objects/property-descriptor.h"
#include "src/tracing/trace-event.h"
#include "src/utils/utils.h"
#include "src/wasm/module-compiler.h"
#include "src/wasm/wasm-constants.h"
#include "src/wasm/wasm-external-refs.h"
#include "src/wasm/wasm-import-wrapper-cache.h"
#include "src/wasm/wasm-module.h"
#include "src/wasm/wasm-objects-inl.h"
#include "src/wasm/wasm-subtyping.h"
#define TRACE(...) \
do { \
if (FLAG_trace_wasm_instances) PrintF(__VA_ARGS__); \
} while (false)
namespace v8 {
namespace internal {
namespace wasm {
using base::ReadLittleEndianValue;
using base::WriteLittleEndianValue;
namespace {
byte* raw_buffer_ptr(MaybeHandle<JSArrayBuffer> buffer, int offset) {
return static_cast<byte*>(buffer.ToHandleChecked()->backing_store()) + offset;
}
uint32_t EvalUint32InitExpr(Handle<WasmInstanceObject> instance,
const WasmInitExpr& expr) {
switch (expr.kind()) {
case WasmInitExpr::kI32Const:
return expr.immediate().i32_const;
case WasmInitExpr::kGlobalGet: {
uint32_t offset =
instance->module()->globals[expr.immediate().index].offset;
auto raw_addr = reinterpret_cast<Address>(
instance->untagged_globals_buffer().backing_store()) +
offset;
return ReadLittleEndianValue<uint32_t>(raw_addr);
}
default:
UNREACHABLE();
}
}
using ImportWrapperQueue = WrapperQueue<WasmImportWrapperCache::CacheKey,
WasmImportWrapperCache::CacheKeyHash>;
class CompileImportWrapperJob final : public JobTask {
public:
CompileImportWrapperJob(
WasmEngine* engine, Counters* counters, NativeModule* native_module,
ImportWrapperQueue* queue,
WasmImportWrapperCache::ModificationScope* cache_scope)
: engine_(engine),
counters_(counters),
native_module_(native_module),
queue_(queue),
cache_scope_(cache_scope) {}
size_t GetMaxConcurrency(size_t worker_count) const override {
size_t flag_limit =
static_cast<size_t>(std::max(1, FLAG_wasm_num_compilation_tasks));
// Add {worker_count} to the queue size because workers might still be
// processing units that have already been popped from the queue.
return std::min(flag_limit, worker_count + queue_->size());
}
void Run(JobDelegate* delegate) override {
while (base::Optional<WasmImportWrapperCache::CacheKey> key =
queue_->pop()) {
CompileImportWrapper(engine_, native_module_, counters_, key->kind,
key->signature, key->expected_arity, cache_scope_);
if (delegate->ShouldYield()) return;
}
}
private:
WasmEngine* const engine_;
Counters* const counters_;
NativeModule* const native_module_;
ImportWrapperQueue* const queue_;
WasmImportWrapperCache::ModificationScope* const cache_scope_;
};
} // namespace
// TODO(jkummerow): Move these elsewhere.
Handle<Map> CreateStructMap(Isolate* isolate, const WasmModule* module,
int struct_index, Handle<Map> rtt_parent) {
const wasm::StructType* type = module->struct_type(struct_index);
const int inobject_properties = 0;
DCHECK_LE(type->total_fields_size(), kMaxInt - WasmStruct::kHeaderSize);
const int instance_size =
WasmStruct::kHeaderSize + static_cast<int>(type->total_fields_size());
const InstanceType instance_type = WASM_STRUCT_TYPE;
// TODO(jkummerow): If NO_ELEMENTS were supported, we could use that here.
const ElementsKind elements_kind = TERMINAL_FAST_ELEMENTS_KIND;
Handle<WasmTypeInfo> type_info = isolate->factory()->NewWasmTypeInfo(
reinterpret_cast<Address>(type), rtt_parent);
Handle<Map> map = isolate->factory()->NewMap(
instance_type, instance_size, elements_kind, inobject_properties);
map->set_wasm_type_info(*type_info);
return map;
}
Handle<Map> CreateArrayMap(Isolate* isolate, const WasmModule* module,
int array_index, Handle<Map> rtt_parent) {
const wasm::ArrayType* type = module->array_type(array_index);
const int inobject_properties = 0;
const int instance_size = kVariableSizeSentinel;
const InstanceType instance_type = WASM_ARRAY_TYPE;
const ElementsKind elements_kind = TERMINAL_FAST_ELEMENTS_KIND;
Handle<WasmTypeInfo> type_info = isolate->factory()->NewWasmTypeInfo(
reinterpret_cast<Address>(type), rtt_parent);
Handle<Map> map = isolate->factory()->NewMap(
instance_type, instance_size, elements_kind, inobject_properties);
map->set_wasm_type_info(*type_info);
return map;
}
Handle<Map> CreateGenericRtt(Isolate* isolate, const WasmModule* module,
Handle<Map> rtt_parent) {
const int inobject_properties = 0;
const int instance_size = 0;
const InstanceType instance_type = WASM_STRUCT_TYPE; // Fake; good enough.
const ElementsKind elements_kind = TERMINAL_FAST_ELEMENTS_KIND;
Handle<WasmTypeInfo> type_info =
isolate->factory()->NewWasmTypeInfo(0, rtt_parent);
Handle<Map> map = isolate->factory()->NewMap(
instance_type, instance_size, elements_kind, inobject_properties);
map->set_wasm_type_info(*type_info);
return map;
}
namespace {
// TODO(7748): Consider storing this array in Maps'
// "transitions_or_prototype_info" slot.
// Also consider being more memory-efficient, e.g. use inline storage for
// single entries, and/or adapt the growth strategy.
class RttSubtypes : public ArrayList {
public:
static Handle<ArrayList> Insert(Isolate* isolate, Handle<ArrayList> array,
uint32_t type_index, Handle<Map> sub_rtt) {
Handle<Smi> key = handle(Smi::FromInt(type_index), isolate);
return Add(isolate, array, key, sub_rtt);
}
static Map SearchSubtype(Handle<ArrayList> array, uint32_t type_index) {
// Linear search for now.
// TODO(7748): Consider keeping the array sorted and using binary search
// here, if empirical data indicates that that would be worthwhile.
int count = array->Length();
for (int i = 0; i < count; i += 2) {
if (Smi::cast(array->Get(i)).value() == static_cast<int>(type_index)) {
return Map::cast(array->Get(i + 1));
}
}
return {};
}
};
} // namespace
Handle<Map> AllocateSubRtt(Isolate* isolate,
Handle<WasmInstanceObject> instance, uint32_t type,
Handle<Map> parent) {
// Check for an existing RTT first.
DCHECK(parent->IsWasmStructMap() || parent->IsWasmArrayMap());
Handle<ArrayList> cache(parent->wasm_type_info().subtypes(), isolate);
Map maybe_cached = RttSubtypes::SearchSubtype(cache, type);
if (!maybe_cached.is_null()) return handle(maybe_cached, isolate);
// Allocate a fresh RTT otherwise.
const wasm::WasmModule* module = instance->module();
Handle<Map> rtt;
if (wasm::HeapType(type).is_generic()) {
rtt = wasm::CreateGenericRtt(isolate, module, parent);
} else if (module->has_struct(type)) {
rtt = wasm::CreateStructMap(isolate, module, type, parent);
} else if (module->has_array(type)) {
rtt = wasm::CreateArrayMap(isolate, module, type, parent);
} else {
DCHECK(module->has_signature(type));
// Currently, parent rtts for functions are meaningless,
// since (rtt.test func rtt) iff (func.map == rtt).
// Therefore, we simply create a fresh function map here.
// TODO(7748): Canonicalize rtts to make them work for identical function
// types.
rtt = Map::Copy(isolate, isolate->wasm_exported_function_map(),
"fresh function map for AllocateSubRtt");
}
cache = RttSubtypes::Insert(isolate, cache, type, rtt);
parent->wasm_type_info().set_subtypes(*cache);
return rtt;
}
// A helper class to simplify instantiating a module from a module object.
// It closes over the {Isolate}, the {ErrorThrower}, etc.
class InstanceBuilder {
public:
InstanceBuilder(Isolate* isolate, v8::metrics::Recorder::ContextId context_id,
ErrorThrower* thrower, Handle<WasmModuleObject> module_object,
MaybeHandle<JSReceiver> ffi,
MaybeHandle<JSArrayBuffer> memory_buffer);
// Build an instance, in all of its glory.
MaybeHandle<WasmInstanceObject> Build();
// Run the start function, if any.
bool ExecuteStartFunction();
private:
// A pre-evaluated value to use in import binding.
struct SanitizedImport {
Handle<String> module_name;
Handle<String> import_name;
Handle<Object> value;
};
Isolate* isolate_;
v8::metrics::Recorder::ContextId context_id_;
const WasmFeatures enabled_;
const WasmModule* const module_;
ErrorThrower* thrower_;
Handle<WasmModuleObject> module_object_;
MaybeHandle<JSReceiver> ffi_;
MaybeHandle<JSArrayBuffer> memory_buffer_;
Handle<WasmMemoryObject> memory_object_;
Handle<JSArrayBuffer> untagged_globals_;
Handle<FixedArray> tagged_globals_;
std::vector<Handle<WasmExceptionObject>> exception_wrappers_;
Handle<WasmExportedFunction> start_function_;
std::vector<SanitizedImport> sanitized_imports_;
// Helper routines to print out errors with imports.
#define ERROR_THROWER_WITH_MESSAGE(TYPE) \
void Report##TYPE(const char* error, uint32_t index, \
Handle<String> module_name, Handle<String> import_name) { \
thrower_->TYPE("Import #%d module=\"%s\" function=\"%s\" error: %s", \
index, module_name->ToCString().get(), \
import_name->ToCString().get(), error); \
} \
\
MaybeHandle<Object> Report##TYPE(const char* error, uint32_t index, \
Handle<String> module_name) { \
thrower_->TYPE("Import #%d module=\"%s\" error: %s", index, \
module_name->ToCString().get(), error); \
return MaybeHandle<Object>(); \
}
ERROR_THROWER_WITH_MESSAGE(LinkError)
ERROR_THROWER_WITH_MESSAGE(TypeError)
#undef ERROR_THROWER_WITH_MESSAGE
// Look up an import value in the {ffi_} object.
MaybeHandle<Object> LookupImport(uint32_t index, Handle<String> module_name,
Handle<String> import_name);
// Look up an import value in the {ffi_} object specifically for linking an
// asm.js module. This only performs non-observable lookups, which allows
// falling back to JavaScript proper (and hence re-executing all lookups) if
// module instantiation fails.
MaybeHandle<Object> LookupImportAsm(uint32_t index,
Handle<String> import_name);
// Load data segments into the memory.
void LoadDataSegments(Handle<WasmInstanceObject> instance);
void WriteGlobalValue(const WasmGlobal& global, double value);
void WriteGlobalValue(const WasmGlobal& global, int64_t num);
void WriteGlobalValue(const WasmGlobal& global,
Handle<WasmGlobalObject> value);
void WriteGlobalExternRef(const WasmGlobal& global, Handle<Object> value);
void SanitizeImports();
// Find the imported memory if there is one.
bool FindImportedMemory();
// Allocate the memory.
bool AllocateMemory();
// Processes a single imported function.
bool ProcessImportedFunction(Handle<WasmInstanceObject> instance,
int import_index, int func_index,
Handle<String> module_name,
Handle<String> import_name,
Handle<Object> value);
// Initialize imported tables of type funcref.
bool InitializeImportedIndirectFunctionTable(
Handle<WasmInstanceObject> instance, int table_index, int import_index,
Handle<WasmTableObject> table_object);
// Process a single imported table.
bool ProcessImportedTable(Handle<WasmInstanceObject> instance,
int import_index, int table_index,
Handle<String> module_name,
Handle<String> import_name, Handle<Object> value);
// Process a single imported memory.
bool ProcessImportedMemory(Handle<WasmInstanceObject> instance,
int import_index, Handle<String> module_name,
Handle<String> import_name, Handle<Object> value);
// Process a single imported global.
bool ProcessImportedGlobal(Handle<WasmInstanceObject> instance,
int import_index, int global_index,
Handle<String> module_name,
Handle<String> import_name, Handle<Object> value);
// Process a single imported WasmGlobalObject.
bool ProcessImportedWasmGlobalObject(Handle<WasmInstanceObject> instance,
int import_index,
Handle<String> module_name,
Handle<String> import_name,
const WasmGlobal& global,
Handle<WasmGlobalObject> global_object);
// Compile import wrappers in parallel. The result goes into the native
// module's import_wrapper_cache.
void CompileImportWrappers(Handle<WasmInstanceObject> instance);
// Process the imports, including functions, tables, globals, and memory, in
// order, loading them from the {ffi_} object. Returns the number of imported
// functions.
int ProcessImports(Handle<WasmInstanceObject> instance);
template <typename T>
T* GetRawGlobalPtr(const WasmGlobal& global);
// Process initialization of globals.
void InitGlobals(Handle<WasmInstanceObject> instance);
Handle<Object> RecursivelyEvaluateGlobalInitializer(
const WasmInitExpr& init, Handle<WasmInstanceObject> instance);
// Process the exports, creating wrappers for functions, tables, memories,
// and globals.
void ProcessExports(Handle<WasmInstanceObject> instance);
void InitializeIndirectFunctionTables(Handle<WasmInstanceObject> instance);
void LoadTableSegments(Handle<WasmInstanceObject> instance);
// Creates new exception tags for all exceptions. Note that some tags might
// already exist if they were imported, those tags will be re-used.
void InitializeExceptions(Handle<WasmInstanceObject> instance);
};
MaybeHandle<WasmInstanceObject> InstantiateToInstanceObject(
Isolate* isolate, ErrorThrower* thrower,
Handle<WasmModuleObject> module_object, MaybeHandle<JSReceiver> imports,
MaybeHandle<JSArrayBuffer> memory_buffer) {
v8::metrics::Recorder::ContextId context_id =
isolate->GetOrRegisterRecorderContextId(isolate->native_context());
InstanceBuilder builder(isolate, context_id, thrower, module_object, imports,
memory_buffer);
auto instance = builder.Build();
if (!instance.is_null() && builder.ExecuteStartFunction()) {
return instance;
}
DCHECK(isolate->has_pending_exception() || thrower->error());
return {};
}
InstanceBuilder::InstanceBuilder(Isolate* isolate,
v8::metrics::Recorder::ContextId context_id,
ErrorThrower* thrower,
Handle<WasmModuleObject> module_object,
MaybeHandle<JSReceiver> ffi,
MaybeHandle<JSArrayBuffer> memory_buffer)
: isolate_(isolate),
context_id_(context_id),
enabled_(module_object->native_module()->enabled_features()),
module_(module_object->module()),
thrower_(thrower),
module_object_(module_object),
ffi_(ffi),
memory_buffer_(memory_buffer) {
sanitized_imports_.reserve(module_->import_table.size());
}
// Build an instance, in all of its glory.
MaybeHandle<WasmInstanceObject> InstanceBuilder::Build() {
TRACE_EVENT0(TRACE_DISABLED_BY_DEFAULT("v8.wasm.detailed"),
"wasm.InstanceBuilder.Build");
// Check that an imports argument was provided, if the module requires it.
// No point in continuing otherwise.
if (!module_->import_table.empty() && ffi_.is_null()) {
thrower_->TypeError(
"Imports argument must be present and must be an object");
return {};
}
SanitizeImports();
if (thrower_->error()) return {};
// From here on, we expect the build pipeline to run without exiting to JS.
DisallowJavascriptExecution no_js(isolate_);
// Record build time into correct bucket, then build instance.
TimedHistogramScope wasm_instantiate_module_time_scope(SELECT_WASM_COUNTER(
isolate_->counters(), module_->origin, wasm_instantiate, module_time));
v8::metrics::WasmModuleInstantiated wasm_module_instantiated;
base::ElapsedTimer timer;
timer.Start();
NativeModule* native_module = module_object_->native_module();
//--------------------------------------------------------------------------
// Set up the memory buffer and memory objects.
//--------------------------------------------------------------------------
uint32_t initial_pages = module_->initial_pages;
auto initial_pages_counter = SELECT_WASM_COUNTER(
isolate_->counters(), module_->origin, wasm, min_mem_pages_count);
initial_pages_counter->AddSample(initial_pages);
if (module_->has_maximum_pages) {
DCHECK_EQ(kWasmOrigin, module_->origin);
auto max_pages_counter =
isolate_->counters()->wasm_wasm_max_mem_pages_count();
max_pages_counter->AddSample(module_->maximum_pages);
}
if (is_asmjs_module(module_)) {
Handle<JSArrayBuffer> buffer;
if (memory_buffer_.ToHandle(&buffer)) {
// asm.js instantiation should have changed the state of the buffer.
CHECK(!buffer->is_detachable());
CHECK(buffer->is_asmjs_memory());
} else {
// Use an empty JSArrayBuffer for degenerate asm.js modules.
memory_buffer_ = isolate_->factory()->NewJSArrayBufferAndBackingStore(
0, InitializedFlag::kUninitialized);
if (!memory_buffer_.ToHandle(&buffer)) {
thrower_->RangeError("Out of memory: asm.js memory");
return {};
}
buffer->set_is_asmjs_memory(true);
buffer->set_is_detachable(false);
}
// The maximum number of pages isn't strictly necessary for memory
// objects used for asm.js, as they are never visible, but we might
// as well make it accurate.
auto maximum_pages = static_cast<uint32_t>(
RoundUp(buffer->byte_length(), wasm::kWasmPageSize) /
wasm::kWasmPageSize);
memory_object_ =
WasmMemoryObject::New(isolate_, memory_buffer_, maximum_pages);
} else {
// Actual wasm module must have either imported or created memory.
CHECK(memory_buffer_.is_null());
if (!FindImportedMemory()) {
if (module_->has_memory && !AllocateMemory()) {
DCHECK(isolate_->has_pending_exception() || thrower_->error());
return {};
}
}
}
//--------------------------------------------------------------------------
// Create the WebAssembly.Instance object.
//--------------------------------------------------------------------------
TRACE("New module instantiation for %p\n", native_module);
Handle<WasmInstanceObject> instance =
WasmInstanceObject::New(isolate_, module_object_);
//--------------------------------------------------------------------------
// Attach the memory to the instance.
//--------------------------------------------------------------------------
if (module_->has_memory) {
DCHECK(!memory_object_.is_null());
if (!instance->has_memory_object()) {
instance->set_memory_object(*memory_object_);
}
// Add the instance object to the list of instances for this memory.
WasmMemoryObject::AddInstance(isolate_, memory_object_, instance);
// Double-check the {memory} array buffer matches the instance.
Handle<JSArrayBuffer> memory = memory_buffer_.ToHandleChecked();
CHECK_EQ(instance->memory_size(), memory->byte_length());
CHECK_EQ(instance->memory_start(), memory->backing_store());
}
//--------------------------------------------------------------------------
// Set up the globals for the new instance.
//--------------------------------------------------------------------------
uint32_t untagged_globals_buffer_size = module_->untagged_globals_buffer_size;
if (untagged_globals_buffer_size > 0) {
MaybeHandle<JSArrayBuffer> result =
isolate_->factory()->NewJSArrayBufferAndBackingStore(
untagged_globals_buffer_size, InitializedFlag::kZeroInitialized,
AllocationType::kOld);
if (!result.ToHandle(&untagged_globals_)) {
thrower_->RangeError("Out of memory: wasm globals");
return {};
}
instance->set_untagged_globals_buffer(*untagged_globals_);
instance->set_globals_start(
reinterpret_cast<byte*>(untagged_globals_->backing_store()));
}
uint32_t tagged_globals_buffer_size = module_->tagged_globals_buffer_size;
if (tagged_globals_buffer_size > 0) {
tagged_globals_ = isolate_->factory()->NewFixedArray(
static_cast<int>(tagged_globals_buffer_size));
instance->set_tagged_globals_buffer(*tagged_globals_);
}
//--------------------------------------------------------------------------
// Set up the array of references to imported globals' array buffers.
//--------------------------------------------------------------------------
if (module_->num_imported_mutable_globals > 0) {
// TODO(binji): This allocates one slot for each mutable global, which is
// more than required if multiple globals are imported from the same
// module.
Handle<FixedArray> buffers_array = isolate_->factory()->NewFixedArray(
module_->num_imported_mutable_globals, AllocationType::kOld);
instance->set_imported_mutable_globals_buffers(*buffers_array);
}
//--------------------------------------------------------------------------
// Set up the exception table used for exception tag checks.
//--------------------------------------------------------------------------
int exceptions_count = static_cast<int>(module_->exceptions.size());
if (exceptions_count > 0) {
Handle<FixedArray> exception_table = isolate_->factory()->NewFixedArray(
exceptions_count, AllocationType::kOld);
instance->set_exceptions_table(*exception_table);
exception_wrappers_.resize(exceptions_count);
}
//--------------------------------------------------------------------------
// Set up table storage space.
//--------------------------------------------------------------------------
int table_count = static_cast<int>(module_->tables.size());
{
for (int i = 0; i < table_count; i++) {
const WasmTable& table = module_->tables[i];
if (table.initial_size > FLAG_wasm_max_table_size) {
thrower_->RangeError(
"initial table size (%u elements) is larger than implementation "
"limit (%u elements)",
table.initial_size, FLAG_wasm_max_table_size);
return {};
}
}
Handle<FixedArray> tables = isolate_->factory()->NewFixedArray(table_count);
for (int i = module_->num_imported_tables; i < table_count; i++) {
const WasmTable& table = module_->tables[i];
Handle<WasmTableObject> table_obj = WasmTableObject::New(
isolate_, instance, table.type, table.initial_size,
table.has_maximum_size, table.maximum_size, nullptr);
tables->set(i, *table_obj);
}
instance->set_tables(*tables);
}
{
Handle<FixedArray> tables = isolate_->factory()->NewFixedArray(table_count);
// Table 0 is handled specially. See {InitializeIndirectFunctionTable} for
// the initilization. All generated and runtime code will use this optimized
// shortcut in the instance. Hence it is safe to start with table 1 in the
// iteration below.
for (int i = 1; i < table_count; ++i) {
const WasmTable& table = module_->tables[i];
if (IsSubtypeOf(table.type, kWasmFuncRef, module_)) {
Handle<WasmIndirectFunctionTable> table_obj =
WasmIndirectFunctionTable::New(isolate_, table.initial_size);
tables->set(i, *table_obj);
}
}
instance->set_indirect_function_tables(*tables);
}
NativeModuleModificationScope native_modification_scope(native_module);
//--------------------------------------------------------------------------
// Process the imports for the module.
//--------------------------------------------------------------------------
int num_imported_functions = ProcessImports(instance);
if (num_imported_functions < 0) return {};
wasm_module_instantiated.imported_function_count = num_imported_functions;
//--------------------------------------------------------------------------
// Create maps for managed objects (GC proposal).
// Must happen before {InitGlobals} because globals can refer to these maps.
//--------------------------------------------------------------------------
if (enabled_.has_gc()) {
Handle<FixedArray> maps = isolate_->factory()->NewUninitializedFixedArray(
static_cast<int>(module_->type_kinds.size()));
// TODO(7748): Do we want a different sentinel here?
Handle<Map> anyref_sentinel_map = isolate_->factory()->null_map();
for (int map_index = 0;
map_index < static_cast<int>(module_->type_kinds.size());
map_index++) {
Handle<Map> map;
switch (module_->type_kinds[map_index]) {
case kWasmStructTypeCode:
map = CreateStructMap(isolate_, module_, map_index,
anyref_sentinel_map);
break;
case kWasmArrayTypeCode:
map =
CreateArrayMap(isolate_, module_, map_index, anyref_sentinel_map);
break;
case kWasmFunctionTypeCode:
// TODO(7748): Think about canonicalizing rtts to make them work for
// identical function types.
map = Map::Copy(isolate_, isolate_->wasm_exported_function_map(),
"fresh function map for function type canonical rtt "
"initialization");
break;
}
maps->set(map_index, *map);
}
instance->set_managed_object_maps(*maps);
}
//--------------------------------------------------------------------------
// Process the initialization for the module's globals.
//--------------------------------------------------------------------------
InitGlobals(instance);
//--------------------------------------------------------------------------
// Initialize the indirect tables.
//--------------------------------------------------------------------------
if (table_count > 0) {
InitializeIndirectFunctionTables(instance);
}
//--------------------------------------------------------------------------
// Initialize the exceptions table.
//--------------------------------------------------------------------------
if (exceptions_count > 0) {
InitializeExceptions(instance);
}
// The bulk memory proposal changes the MVP behavior here; the segments are
// written as if `memory.init` and `table.init` are executed directly, and
// not bounds checked ahead of time.
if (!enabled_.has_bulk_memory()) {
//--------------------------------------------------------------------------
// Check that indirect function table segments are within bounds.
//--------------------------------------------------------------------------
for (const WasmElemSegment& elem_segment : module_->elem_segments) {
if (elem_segment.status != WasmElemSegment::kStatusActive) continue;
DCHECK_LT(elem_segment.table_index, table_count);
uint32_t base = EvalUint32InitExpr(instance, elem_segment.offset);
// Because of imported tables, {table_size} has to come from the table
// object itself.
auto table_object = handle(WasmTableObject::cast(instance->tables().get(
elem_segment.table_index)),
isolate_);
uint32_t table_size = table_object->current_length();
if (!base::IsInBounds<uint32_t>(
base, static_cast<uint32_t>(elem_segment.entries.size()),
table_size)) {
thrower_->LinkError("table initializer is out of bounds");
return {};
}
}
//--------------------------------------------------------------------------
// Check that memory segments are within bounds.
//--------------------------------------------------------------------------
for (const WasmDataSegment& seg : module_->data_segments) {
if (!seg.active) continue;
uint32_t base = EvalUint32InitExpr(instance, seg.dest_addr);
if (!base::IsInBounds<uint64_t>(base, seg.source.length(),
instance->memory_size())) {
thrower_->LinkError("data segment is out of bounds");
return {};
}
}
}
//--------------------------------------------------------------------------
// Set up the exports object for the new instance.
//--------------------------------------------------------------------------
ProcessExports(instance);
if (thrower_->error()) return {};
//--------------------------------------------------------------------------
// Initialize the indirect function tables.
//--------------------------------------------------------------------------
if (table_count > 0) {
LoadTableSegments(instance);
if (thrower_->error()) return {};
}
//--------------------------------------------------------------------------
// Initialize the memory by loading data segments.
//--------------------------------------------------------------------------
if (module_->data_segments.size() > 0) {
LoadDataSegments(instance);
if (thrower_->error()) return {};
}
//--------------------------------------------------------------------------
// Create a wrapper for the start function.
//--------------------------------------------------------------------------
if (module_->start_function_index >= 0) {
int start_index = module_->start_function_index;
auto& function = module_->functions[start_index];
Handle<Code> wrapper_code =
JSToWasmWrapperCompilationUnit::CompileJSToWasmWrapper(
isolate_, function.sig, module_, function.imported);
// TODO(clemensb): Don't generate an exported function for the start
// function. Use CWasmEntry instead.
start_function_ = WasmExportedFunction::New(
isolate_, instance, start_index,
static_cast<int>(function.sig->parameter_count()), wrapper_code);
if (function.imported) {
ImportedFunctionEntry entry(instance, module_->start_function_index);
Object callable = entry.maybe_callable();
if (callable.IsJSFunction()) {
// If the start function was imported and calls into Blink, we have
// to pretend that the V8 API was used to enter its correct context.
// To get that context to {ExecuteStartFunction} below, we install it
// as the context of the wrapper we just compiled. That's a bit of a
// hack because it's not really the wrapper's context, only its wrapped
// target's context, but the end result is the same, and since the
// start function wrapper doesn't leak, neither does this
// implementation detail.
start_function_->set_context(JSFunction::cast(callable).context());
}
}
}
DCHECK(!isolate_->has_pending_exception());
TRACE("Successfully built instance for module %p\n",
module_object_->native_module());
wasm_module_instantiated.success = true;
wasm_module_instantiated.wall_clock_duration_in_us =
timer.Elapsed().InMicroseconds();
timer.Stop();
isolate_->metrics_recorder()->DelayMainThreadEvent(wasm_module_instantiated,
context_id_);
return instance;
}
bool InstanceBuilder::ExecuteStartFunction() {
TRACE_EVENT0(TRACE_DISABLED_BY_DEFAULT("v8.wasm.detailed"),
"wasm.ExecuteStartFunction");
if (start_function_.is_null()) return true; // No start function.
HandleScope scope(isolate_);
// In case the start function calls out to Blink, we have to make sure that
// the correct "entered context" is available. This is the equivalent of
// v8::Context::Enter() and must happen in addition to the function call
// sequence doing the compiled version of "isolate->set_context(...)".
HandleScopeImplementer* hsi = isolate_->handle_scope_implementer();
hsi->EnterContext(start_function_->context());
// Call the JS function.
Handle<Object> undefined = isolate_->factory()->undefined_value();
MaybeHandle<Object> retval =
Execution::Call(isolate_, start_function_, undefined, 0, nullptr);
hsi->LeaveContext();
if (retval.is_null()) {
DCHECK(isolate_->has_pending_exception());
return false;
}
return true;
}
// Look up an import value in the {ffi_} object.
MaybeHandle<Object> InstanceBuilder::LookupImport(uint32_t index,
Handle<String> module_name,
Handle<String> import_name) {
// We pre-validated in the js-api layer that the ffi object is present, and
// a JSObject, if the module has imports.
DCHECK(!ffi_.is_null());
// Look up the module first.
MaybeHandle<Object> result = Object::GetPropertyOrElement(
isolate_, ffi_.ToHandleChecked(), module_name);
if (result.is_null()) {
return ReportTypeError("module not found", index, module_name);
}
Handle<Object> module = result.ToHandleChecked();
// Look up the value in the module.
if (!module->IsJSReceiver()) {
return ReportTypeError("module is not an object or function", index,
module_name);
}
result = Object::GetPropertyOrElement(isolate_, module, import_name);
if (result.is_null()) {
ReportLinkError("import not found", index, module_name, import_name);
return MaybeHandle<JSFunction>();
}
return result;
}
// Look up an import value in the {ffi_} object specifically for linking an
// asm.js module. This only performs non-observable lookups, which allows
// falling back to JavaScript proper (and hence re-executing all lookups) if
// module instantiation fails.
MaybeHandle<Object> InstanceBuilder::LookupImportAsm(
uint32_t index, Handle<String> import_name) {
// Check that a foreign function interface object was provided.
if (ffi_.is_null()) {
return ReportLinkError("missing imports object", index, import_name);
}
// Perform lookup of the given {import_name} without causing any observable
// side-effect. We only accept accesses that resolve to data properties,
// which is indicated by the asm.js spec in section 7 ("Linking") as well.
Handle<Object> result;
LookupIterator::Key key(isolate_, Handle<Name>::cast(import_name));
LookupIterator it(isolate_, ffi_.ToHandleChecked(), key);
switch (it.state()) {
case LookupIterator::ACCESS_CHECK:
case LookupIterator::INTEGER_INDEXED_EXOTIC:
case LookupIterator::INTERCEPTOR:
case LookupIterator::JSPROXY:
case LookupIterator::ACCESSOR:
case LookupIterator::TRANSITION:
return ReportLinkError("not a data property", index, import_name);
case LookupIterator::NOT_FOUND:
// Accepting missing properties as undefined does not cause any
// observable difference from JavaScript semantics, we are lenient.
result = isolate_->factory()->undefined_value();
break;
case LookupIterator::DATA:
result = it.GetDataValue();
break;
}
return result;
}
// Load data segments into the memory.
void InstanceBuilder::LoadDataSegments(Handle<WasmInstanceObject> instance) {
Vector<const uint8_t> wire_bytes =
module_object_->native_module()->wire_bytes();
for (const WasmDataSegment& segment : module_->data_segments) {
uint32_t size = segment.source.length();
if (enabled_.has_bulk_memory()) {
// Passive segments are not copied during instantiation.
if (!segment.active) continue;
uint32_t dest_offset = EvalUint32InitExpr(instance, segment.dest_addr);
bool ok = base::ClampToBounds(
dest_offset, &size, static_cast<uint32_t>(instance->memory_size()));
if (!ok) {
thrower_->RuntimeError("data segment is out of bounds");
return;
}
// No need to copy empty segments.
if (size == 0) continue;
std::memcpy(instance->memory_start() + dest_offset,
wire_bytes.begin() + segment.source.offset(), size);
} else {
DCHECK(segment.active);
// Segments of size == 0 are just nops.
if (size == 0) continue;
uint32_t dest_offset = EvalUint32InitExpr(instance, segment.dest_addr);
DCHECK(base::IsInBounds<uint64_t>(dest_offset, size,
instance->memory_size()));
byte* dest = instance->memory_start() + dest_offset;
const byte* src = wire_bytes.begin() + segment.source.offset();
memcpy(dest, src, size);
}
}
}
void InstanceBuilder::WriteGlobalValue(const WasmGlobal& global, double num) {
TRACE("init [globals_start=%p + %u] = %lf, type = %s\n",
raw_buffer_ptr(untagged_globals_, 0), global.offset, num,
global.type.name().c_str());
switch (global.type.kind()) {
case ValueType::kI32:
WriteLittleEndianValue<int32_t>(GetRawGlobalPtr<int32_t>(global),
DoubleToInt32(num));
break;
case ValueType::kI64:
// The Wasm-BigInt proposal currently says that i64 globals may
// only be initialized with BigInts. See:
// https://github.com/WebAssembly/JS-BigInt-integration/issues/12
UNREACHABLE();
case ValueType::kF32:
WriteLittleEndianValue<float>(GetRawGlobalPtr<float>(global),
DoubleToFloat32(num));
break;
case ValueType::kF64:
WriteLittleEndianValue<double>(GetRawGlobalPtr<double>(global), num);
break;
default:
UNREACHABLE();
}
}
void InstanceBuilder::WriteGlobalValue(const WasmGlobal& global, int64_t num) {
TRACE("init [globals_start=%p + %u] = %" PRId64 ", type = %s\n",
raw_buffer_ptr(untagged_globals_, 0), global.offset, num,
global.type.name().c_str());
DCHECK_EQ(kWasmI64, global.type);
WriteLittleEndianValue<int64_t>(GetRawGlobalPtr<int64_t>(global), num);
}
void InstanceBuilder::WriteGlobalValue(const WasmGlobal& global,
Handle<WasmGlobalObject> value) {
TRACE("init [globals_start=%p + %u] = ", raw_buffer_ptr(untagged_globals_, 0),
global.offset);
switch (global.type.kind()) {
case ValueType::kI32: {
int32_t num = value->GetI32();
WriteLittleEndianValue<int32_t>(GetRawGlobalPtr<int32_t>(global), num);
TRACE("%d", num);
break;
}
case ValueType::kI64: {
int64_t num = value->GetI64();
WriteLittleEndianValue<int64_t>(GetRawGlobalPtr<int64_t>(global), num);
TRACE("%" PRId64, num);
break;
}
case ValueType::kF32: {
float num = value->GetF32();
WriteLittleEndianValue<float>(GetRawGlobalPtr<float>(global), num);
TRACE("%f", num);
break;
}
case ValueType::kF64: {
double num = value->GetF64();
WriteLittleEndianValue<double>(GetRawGlobalPtr<double>(global), num);
TRACE("%lf", num);
break;
}
case ValueType::kRtt:
case ValueType::kRef:
case ValueType::kOptRef: {
tagged_globals_->set(global.offset, *value->GetRef());
break;
}
case ValueType::kStmt:
case ValueType::kS128:
case ValueType::kBottom:
case ValueType::kI8:
case ValueType::kI16:
UNREACHABLE();
}
TRACE(", type = %s (from WebAssembly.Global)\n", global.type.name().c_str());
}
void InstanceBuilder::WriteGlobalExternRef(const WasmGlobal& global,
Handle<Object> value) {
tagged_globals_->set(global.offset, *value, UPDATE_WRITE_BARRIER);
}
void InstanceBuilder::SanitizeImports() {
Vector<const uint8_t> wire_bytes =
module_object_->native_module()->wire_bytes();
for (size_t index = 0; index < module_->import_table.size(); ++index) {
const WasmImport& import = module_->import_table[index];
Handle<String> module_name =
WasmModuleObject::ExtractUtf8StringFromModuleBytes(
isolate_, wire_bytes, import.module_name, kInternalize);
Handle<String> import_name =
WasmModuleObject::ExtractUtf8StringFromModuleBytes(
isolate_, wire_bytes, import.field_name, kInternalize);
int int_index = static_cast<int>(index);
MaybeHandle<Object> result =
is_asmjs_module(module_)
? LookupImportAsm(int_index, import_name)
: LookupImport(int_index, module_name, import_name);
if (thrower_->error()) {
thrower_->LinkError("Could not find value for import %zu", index);
return;
}
Handle<Object> value = result.ToHandleChecked();
sanitized_imports_.push_back({module_name, import_name, value});
}
}
bool InstanceBuilder::FindImportedMemory() {
DCHECK_EQ(module_->import_table.size(), sanitized_imports_.size());
for (size_t index = 0; index < module_->import_table.size(); index++) {
WasmImport import = module_->import_table[index];
if (import.kind == kExternalMemory) {
auto& value = sanitized_imports_[index].value;
if (!value->IsWasmMemoryObject()) return false;
memory_object_ = Handle<WasmMemoryObject>::cast(value);
memory_buffer_ =
Handle<JSArrayBuffer>(memory_object_->array_buffer(), isolate_);
return true;
}
}
return false;
}
bool InstanceBuilder::ProcessImportedFunction(
Handle<WasmInstanceObject> instance, int import_index, int func_index,
Handle<String> module_name, Handle<String> import_name,
Handle<Object> value) {
// Function imports must be callable.
if (!value->IsCallable()) {
ReportLinkError("function import requires a callable", import_index,
module_name, import_name);
return false;
}
// Store any {WasmExternalFunction} callable in the instance before the call
// is resolved to preserve its identity. This handles exported functions as
// well as functions constructed via other means (e.g. WebAssembly.Function).
if (WasmExternalFunction::IsWasmExternalFunction(*value)) {
WasmInstanceObject::SetWasmExternalFunction(
isolate_, instance, func_index,
Handle<WasmExternalFunction>::cast(value));
}
auto js_receiver = Handle<JSReceiver>::cast(value);
const FunctionSig* expected_sig = module_->functions[func_index].sig;
auto resolved = compiler::ResolveWasmImportCall(js_receiver, expected_sig,
module_, enabled_);
compiler::WasmImportCallKind kind = resolved.first;
js_receiver = resolved.second;
switch (kind) {
case compiler::WasmImportCallKind::kLinkError:
ReportLinkError("imported function does not match the expected type",
import_index, module_name, import_name);
return false;
case compiler::WasmImportCallKind::kWasmToWasm: {
// The imported function is a Wasm function from another instance.
auto imported_function = Handle<WasmExportedFunction>::cast(js_receiver);
Handle<WasmInstanceObject> imported_instance(
imported_function->instance(), isolate_);
// The import reference is the instance object itself.
Address imported_target = imported_function->GetWasmCallTarget();
ImportedFunctionEntry entry(instance, func_index);
entry.SetWasmToWasm(*imported_instance, imported_target);
break;
}
case compiler::WasmImportCallKind::kWasmToCapi: {
NativeModule* native_module = instance->module_object().native_module();
Address host_address =
WasmCapiFunction::cast(*js_receiver).GetHostCallTarget();
WasmCodeRefScope code_ref_scope;
WasmCode* wasm_code = compiler::CompileWasmCapiCallWrapper(
isolate_->wasm_engine(), native_module, expected_sig, host_address);
isolate_->counters()->wasm_generated_code_size()->Increment(
wasm_code->instructions().length());
isolate_->counters()->wasm_reloc_size()->Increment(
wasm_code->reloc_info().length());
ImportedFunctionEntry entry(instance, func_index);
// We re-use the SetWasmToJs infrastructure because it passes the
// callable to the wrapper, which we need to get the function data.
entry.SetWasmToJs(isolate_, js_receiver, wasm_code);
break;
}
default: {
// The imported function is a callable.
int expected_arity = static_cast<int>(expected_sig->parameter_count());
if (kind == compiler::WasmImportCallKind::kJSFunctionArityMismatch) {
Handle<JSFunction> function = Handle<JSFunction>::cast(js_receiver);
SharedFunctionInfo shared = function->shared();
expected_arity = shared.internal_formal_parameter_count();
}
NativeModule* native_module = instance->module_object().native_module();
WasmCode* wasm_code = native_module->import_wrapper_cache()->Get(
kind, expected_sig, expected_arity);
DCHECK_NOT_NULL(wasm_code);
ImportedFunctionEntry entry(instance, func_index);
if (wasm_code->kind() == WasmCode::kWasmToJsWrapper) {
// Wasm to JS wrappers are treated specially in the import table.
entry.SetWasmToJs(isolate_, js_receiver, wasm_code);
} else {
// Wasm math intrinsics are compiled as regular Wasm functions.
DCHECK(kind >= compiler::WasmImportCallKind::kFirstMathIntrinsic &&
kind <= compiler::WasmImportCallKind::kLastMathIntrinsic);
entry.SetWasmToWasm(*instance, wasm_code->instruction_start());
}
break;
}
}
return true;
}
bool InstanceBuilder::InitializeImportedIndirectFunctionTable(
Handle<WasmInstanceObject> instance, int table_index, int import_index,
Handle<WasmTableObject> table_object) {
int imported_table_size = table_object->current_length();
// Allocate a new dispatch table.
WasmInstanceObject::EnsureIndirectFunctionTableWithMinimumSize(
instance, table_index, imported_table_size);
// Initialize the dispatch table with the (foreign) JS functions
// that are already in the table.
for (int i = 0; i < imported_table_size; ++i) {
bool is_valid;
bool is_null;
MaybeHandle<WasmInstanceObject> maybe_target_instance;
int function_index;
MaybeHandle<WasmJSFunction> maybe_js_function;
WasmTableObject::GetFunctionTableEntry(
isolate_, module_, table_object, i, &is_valid, &is_null,
&maybe_target_instance, &function_index, &maybe_js_function);
if (!is_valid) {
thrower_->LinkError("table import %d[%d] is not a wasm function",
import_index, i);
return false;
}
if (is_null) continue;
Handle<WasmJSFunction> js_function;
if (maybe_js_function.ToHandle(&js_function)) {
WasmInstanceObject::ImportWasmJSFunctionIntoTable(
isolate_, instance, table_index, i, js_function);
continue;
}
Handle<WasmInstanceObject> target_instance =
maybe_target_instance.ToHandleChecked();
const FunctionSig* sig = target_instance->module_object()
.module()
->functions[function_index]
.sig;
// Look up the signature's canonical id. If there is no canonical
// id, then the signature does not appear at all in this module,
// so putting {-1} in the table will cause checks to always fail.
IndirectFunctionTableEntry(instance, table_index, i)
.Set(module_->signature_map.Find(*sig), target_instance,
function_index);
}
return true;
}
bool InstanceBuilder::ProcessImportedTable(Handle<WasmInstanceObject> instance,
int import_index, int table_index,
Handle<String> module_name,
Handle<String> import_name,
Handle<Object> value) {
if (!value->IsWasmTableObject()) {
ReportLinkError("table import requires a WebAssembly.Table", import_index,
module_name, import_name);
return false;
}
const WasmTable& table = module_->tables[table_index];
auto table_object = Handle<WasmTableObject>::cast(value);
uint32_t imported_table_size =
static_cast<uint32_t>(table_object->current_length());
if (imported_table_size < table.initial_size) {
thrower_->LinkError("table import %d is smaller than initial %u, got %u",
import_index, table.initial_size, imported_table_size);
return false;
}
if (table.has_maximum_size) {
if (table_object->maximum_length().IsUndefined(isolate_)) {
thrower_->LinkError("table import %d has no maximum length, expected %u",
import_index, table.maximum_size);
return false;
}
int64_t imported_maximum_size = table_object->maximum_length().Number();
if (imported_maximum_size < 0) {
thrower_->LinkError("table import %d has no maximum length, expected %u",
import_index, table.maximum_size);
return false;
}
if (imported_maximum_size > table.maximum_size) {
thrower_->LinkError("table import %d has a larger maximum size %" PRIx64
" than the module's declared maximum %u",
import_index, imported_maximum_size,
table.maximum_size);
return false;
}
}
const WasmModule* table_type_module =
!table_object->instance().IsUndefined()
? WasmInstanceObject::cast(table_object->instance()).module()
: instance->module();
if (!EquivalentTypes(table.type, table_object->type(), module_,
table_type_module)) {
ReportLinkError("imported table does not match the expected type",
import_index, module_name, import_name);
return false;
}
if (IsSubtypeOf(table.type, kWasmFuncRef, module_) &&
!InitializeImportedIndirectFunctionTable(instance, table_index,
import_index, table_object)) {
return false;
}
instance->tables().set(table_index, *value);
return true;
}
bool InstanceBuilder::ProcessImportedMemory(Handle<WasmInstanceObject> instance,
int import_index,
Handle<String> module_name,
Handle<String> import_name,
Handle<Object> value) {
if (!value->IsWasmMemoryObject()) {
ReportLinkError("memory import must be a WebAssembly.Memory object",
import_index, module_name, import_name);
return false;
}
auto memory_object = Handle<WasmMemoryObject>::cast(value);
// The imported memory should have been already set up early.
CHECK_EQ(instance->memory_object(), *memory_object);
Handle<JSArrayBuffer> buffer(memory_object_->array_buffer(), isolate_);
// memory_ should have already been assigned in Build().
DCHECK_EQ(*memory_buffer_.ToHandleChecked(), *buffer);
uint32_t imported_cur_pages =
static_cast<uint32_t>(buffer->byte_length() / kWasmPageSize);
if (imported_cur_pages < module_->initial_pages) {
thrower_->LinkError("memory import %d is smaller than initial %u, got %u",
import_index, module_->initial_pages,
imported_cur_pages);
return false;
}
int32_t imported_maximum_pages = memory_object_->maximum_pages();
if (module_->has_maximum_pages) {
if (imported_maximum_pages < 0) {
thrower_->LinkError(
"memory import %d has no maximum limit, expected at most %u",
import_index, imported_maximum_pages);
return false;
}
if (static_cast<uint32_t>(imported_maximum_pages) >
module_->maximum_pages) {
thrower_->LinkError(
"memory import %d has a larger maximum size %u than the "
"module's declared maximum %u",
import_index, imported_maximum_pages, module_->maximum_pages);
return false;
}
}
if (module_->has_shared_memory != buffer->is_shared()) {
thrower_->LinkError(
"mismatch in shared state of memory, declared = %d, imported = %d",
module_->has_shared_memory, buffer->is_shared());
return false;
}
return true;
}
bool InstanceBuilder::ProcessImportedWasmGlobalObject(
Handle<WasmInstanceObject> instance, int import_index,
Handle<String> module_name, Handle<String> import_name,
const WasmGlobal& global, Handle<WasmGlobalObject> global_object) {
if (static_cast<bool>(global_object->is_mutable()) != global.mutability) {
ReportLinkError("imported global does not match the expected mutability",
import_index, module_name, import_name);
return false;
}
const WasmModule* global_type_module =
!global_object->instance().IsUndefined()
? WasmInstanceObject::cast(global_object->instance()).module()
: instance->module();
bool valid_type =
global.mutability
? EquivalentTypes(global_object->type(), global.type,
global_type_module, instance->module())
: IsSubtypeOf(global_object->type(), global.type, global_type_module,
instance->module());
if (!valid_type) {
ReportLinkError("imported global does not match the expected type",
import_index, module_name, import_name);
return false;
}
if (global.mutability) {
DCHECK_LT(global.index, module_->num_imported_mutable_globals);
Handle<Object> buffer;
Address address_or_offset;
if (global.type.is_reference_type()) {
static_assert(sizeof(global_object->offset()) <= sizeof(Address),
"The offset into the globals buffer does not fit into "
"the imported_mutable_globals array");
buffer = handle(global_object->tagged_buffer(), isolate_);
// For externref globals we use a relative offset, not an absolute
// address.
address_or_offset = static_cast<Address>(global_object->offset());
} else {
buffer = handle(global_object->untagged_buffer(), isolate_);
// It is safe in this case to store the raw pointer to the buffer
// since the backing store of the JSArrayBuffer will not be
// relocated.
address_or_offset = reinterpret_cast<Address>(raw_buffer_ptr(
Handle<JSArrayBuffer>::cast(buffer), global_object->offset()));
}
instance->imported_mutable_globals_buffers().set(global.index, *buffer);
instance->imported_mutable_globals()[global.index] = address_or_offset;
return true;
}
WriteGlobalValue(global, global_object);
return true;
}
bool InstanceBuilder::ProcessImportedGlobal(Handle<WasmInstanceObject> instance,
int import_index, int global_index,
Handle<String> module_name,
Handle<String> import_name,
Handle<Object> value) {
// Immutable global imports are converted to numbers and written into
// the {untagged_globals_} array buffer.
//
// Mutable global imports instead have their backing array buffers
// referenced by this instance, and store the address of the imported
// global in the {imported_mutable_globals_} array.
const WasmGlobal& global = module_->globals[global_index];
// The mutable-global proposal allows importing i64 values, but only if
// they are passed as a WebAssembly.Global object.
//
// However, the bigint proposal allows importing constant i64 values,
// as non WebAssembly.Global object.
if (global.type == kWasmI64 && !enabled_.has_bigint() &&
!value->IsWasmGlobalObject()) {
ReportLinkError("global import cannot have type i64", import_index,
module_name, import_name);
return false;
}
// SIMD proposal allows modules to define an imported v128 global, and only
// supports importing a WebAssembly.Global object for this global, but also
// defines constructing a WebAssembly.Global of v128 to be a TypeError.
// We *should* never hit this case in the JS API, but the module should should
// be allowed to declare such a global (no validation error).
if (global.type == kWasmS128 && !value->IsWasmGlobalObject()) {
ReportLinkError("global import of type v128 must be a WebAssembly.Global",
import_index, module_name, import_name);
return false;
}
if (is_asmjs_module(module_)) {
// Accepting {JSFunction} on top of just primitive values here is a
// workaround to support legacy asm.js code with broken binding. Note
// that using {NaN} (or Smi::zero()) here is what using the observable
// conversion via {ToPrimitive} would produce as well.
// TODO(wasm): Still observable if Function.prototype.valueOf or friends
// are patched, we might need to check for that as well.
if (value->IsJSFunction()) value = isolate_->factory()->nan_value();
if (value->IsPrimitive() && !value->IsSymbol()) {
if (global.type == kWasmI32) {
value = Object::ToInt32(isolate_, value).ToHandleChecked();
} else {
value = Object::ToNumber(isolate_, value).ToHandleChecked();
}
}
}
if (value->IsWasmGlobalObject()) {
auto global_object = Handle<WasmGlobalObject>::cast(value);
return ProcessImportedWasmGlobalObject(instance, import_index, module_name,
import_name, global, global_object);
}
if (global.mutability) {
ReportLinkError(
"imported mutable global must be a WebAssembly.Global object",
import_index, module_name, import_name);
return false;
}
if (global.type.is_reference_type()) {
const char* error_message;
if (!wasm::TypecheckJSObject(isolate_, module_, value, global.type,
&error_message)) {
ReportLinkError(error_message, global_index, module_name, import_name);
return false;
}
WriteGlobalExternRef(global, value);
return true;
}
if (value->IsNumber() && global.type != kWasmI64) {
WriteGlobalValue(global, value->Number());
return true;
}
if (enabled_.has_bigint() && global.type == kWasmI64 && value->IsBigInt()) {
WriteGlobalValue(global, BigInt::cast(*value).AsInt64());
return true;
}
ReportLinkError(
"global import must be a number, valid Wasm reference, or "
"WebAssembly.Global object",
import_index, module_name, import_name);
return false;
}
void InstanceBuilder::CompileImportWrappers(
Handle<WasmInstanceObject> instance) {
int num_imports = static_cast<int>(module_->import_table.size());
NativeModule* native_module = instance->module_object().native_module();
WasmImportWrapperCache::ModificationScope cache_scope(
native_module->import_wrapper_cache());
// Compilation is done in two steps:
// 1) Insert nullptr entries in the cache for wrappers that need to be
// compiled. 2) Compile wrappers in background tasks using the
// ImportWrapperQueue. This way the cache won't invalidate other iterators
// when inserting a new WasmCode, since the key will already be there.
ImportWrapperQueue import_wrapper_queue;
for (int index = 0; index < num_imports; ++index) {
Handle<Object> value = sanitized_imports_[index].value;
if (module_->import_table[index].kind != kExternalFunction ||
!value->IsCallable()) {
continue;
}
auto js_receiver = Handle<JSReceiver>::cast(value);
uint32_t func_index = module_->import_table[index].index;
const FunctionSig* sig = module_->functions[func_index].sig;
auto resolved =
compiler::ResolveWasmImportCall(js_receiver, sig, module_, enabled_);
compiler::WasmImportCallKind kind = resolved.first;
if (kind == compiler::WasmImportCallKind::kWasmToWasm ||
kind == compiler::WasmImportCallKind::kLinkError ||
kind == compiler::WasmImportCallKind::kWasmToCapi) {
continue;
}
int expected_arity = static_cast<int>(sig->parameter_count());
if (resolved.first ==
compiler::WasmImportCallKind::kJSFunctionArityMismatch) {
Handle<JSFunction> function = Handle<JSFunction>::cast(resolved.second);
SharedFunctionInfo shared = function->shared();
expected_arity = shared.internal_formal_parameter_count();
}
WasmImportWrapperCache::CacheKey key(kind, sig, expected_arity);
if (cache_scope[key] != nullptr) {
// Cache entry already exists, no need to compile it again.
continue;
}
import_wrapper_queue.insert(key);
}
auto compile_job_task = std::make_unique<CompileImportWrapperJob>(
isolate_->wasm_engine(), isolate_->counters(), native_module,
&import_wrapper_queue, &cache_scope);
auto compile_job = V8::GetCurrentPlatform()->PostJob(
TaskPriority::kUserVisible, std::move(compile_job_task));
// Wait for the job to finish, while contributing in this thread.
compile_job->Join();
}
// Process the imports, including functions, tables, globals, and memory, in
// order, loading them from the {ffi_} object. Returns the number of imported
// functions.
int InstanceBuilder::ProcessImports(Handle<WasmInstanceObject> instance) {
int num_imported_functions = 0;
int num_imported_tables = 0;
DCHECK_EQ(module_->import_table.size(), sanitized_imports_.size());
CompileImportWrappers(instance);
int num_imports = static_cast<int>(module_->import_table.size());
for (int index = 0; index < num_imports; ++index) {
const WasmImport& import = module_->import_table[index];
Handle<String> module_name = sanitized_imports_[index].module_name;
Handle<String> import_name = sanitized_imports_[index].import_name;
Handle<Object> value = sanitized_imports_[index].value;
switch (import.kind) {
case kExternalFunction: {
uint32_t func_index = import.index;
DCHECK_EQ(num_imported_functions, func_index);
if (!ProcessImportedFunction(instance, index, func_index, module_name,
import_name, value)) {
return -1;
}
num_imported_functions++;
break;
}
case kExternalTable: {
uint32_t table_index = import.index;
DCHECK_EQ(table_index, num_imported_tables);
if (!ProcessImportedTable(instance, index, table_index, module_name,
import_name, value)) {
return -1;
}
num_imported_tables++;
break;
}
case kExternalMemory: {
if (!ProcessImportedMemory(instance, index, module_name, import_name,
value)) {
return -1;
}
break;
}
case kExternalGlobal: {
if (!ProcessImportedGlobal(instance, index, import.index, module_name,
import_name, value)) {
return -1;
}
break;
}
case kExternalException: {
if (!value->IsWasmExceptionObject()) {
ReportLinkError("exception import requires a WebAssembly.Exception",
index, module_name, import_name);
return -1;
}
Handle<WasmExceptionObject> imported_exception =
Handle<WasmExceptionObject>::cast(value);
if (!imported_exception->MatchesSignature(
module_->exceptions[import.index].sig)) {
ReportLinkError("imported exception does not match the expected type",
index, module_name, import_name);
return -1;
}
Object exception_tag = imported_exception->exception_tag();
DCHECK(instance->exceptions_table().get(import.index).IsUndefined());
instance->exceptions_table().set(import.index, exception_tag);
exception_wrappers_[import.index] = imported_exception;
break;
}
default:
UNREACHABLE();
break;
}
}
return num_imported_functions;
}
template <typename T>
T* InstanceBuilder::GetRawGlobalPtr(const WasmGlobal& global) {
return reinterpret_cast<T*>(raw_buffer_ptr(untagged_globals_, global.offset));
}
Handle<Object> InstanceBuilder::RecursivelyEvaluateGlobalInitializer(
const WasmInitExpr& init, Handle<WasmInstanceObject> instance) {
switch (init.kind()) {
case WasmInitExpr::kI32Const:
case WasmInitExpr::kI64Const:
case WasmInitExpr::kF32Const:
case WasmInitExpr::kF64Const:
case WasmInitExpr::kS128Const:
case WasmInitExpr::kRefNullConst:
case WasmInitExpr::kRefFuncConst:
case WasmInitExpr::kNone:
// Handled directly by {InitGlobals()}, can't occur as recursive case.
UNREACHABLE();
break;
case WasmInitExpr::kGlobalGet: {
// We can only get here for reference-type globals, but we don't have
// enough information to DCHECK that directly.
DCHECK(enabled_.has_reftypes() || enabled_.has_eh());
uint32_t old_offset = module_->globals[init.immediate().index].offset;
DCHECK(static_cast<int>(old_offset) < tagged_globals_->length());
return handle(tagged_globals_->get(old_offset), isolate_);
}
case WasmInitExpr::kRttCanon: {
switch (init.immediate().heap_type) {
case wasm::HeapType::kEq:
return isolate_->root_handle(RootIndex::kWasmRttEqrefMap);
case wasm::HeapType::kExtern:
return isolate_->root_handle(RootIndex::kWasmRttExternrefMap);
case wasm::HeapType::kFunc:
return isolate_->root_handle(RootIndex::kWasmRttFuncrefMap);
case wasm::HeapType::kI31:
return isolate_->root_handle(RootIndex::kWasmRttI31refMap);
case wasm::HeapType::kExn:
UNIMPLEMENTED(); // TODO(jkummerow): This is going away?
case wasm::HeapType::kBottom:
UNREACHABLE();
}
// Non-generic types fall through.
int map_index = init.immediate().heap_type;
return handle(instance->managed_object_maps().get(map_index), isolate_);
}
case WasmInitExpr::kRttSub: {
uint32_t type = static_cast<uint32_t>(init.immediate().heap_type);
Handle<Object> parent =
RecursivelyEvaluateGlobalInitializer(*init.operand(), instance);
return AllocateSubRtt(isolate_, instance, type,
Handle<Map>::cast(parent));
}
}
}
// Process initialization of globals.
void InstanceBuilder::InitGlobals(Handle<WasmInstanceObject> instance) {
for (const WasmGlobal& global : module_->globals) {
if (global.mutability && global.imported) {
continue;
}
switch (global.init.kind()) {
case WasmInitExpr::kI32Const:
WriteLittleEndianValue<int32_t>(GetRawGlobalPtr<int32_t>(global),
global.init.immediate().i32_const);
break;
case WasmInitExpr::kI64Const:
WriteLittleEndianValue<int64_t>(GetRawGlobalPtr<int64_t>(global),
global.init.immediate().i64_const);
break;
case WasmInitExpr::kF32Const:
WriteLittleEndianValue<float>(GetRawGlobalPtr<float>(global),
global.init.immediate().f32_const);
break;
case WasmInitExpr::kF64Const:
WriteLittleEndianValue<double>(GetRawGlobalPtr<double>(global),
global.init.immediate().f64_const);
break;
case WasmInitExpr::kS128Const:
DCHECK(enabled_.has_simd());
WriteLittleEndianValue<std::array<uint8_t, kSimd128Size>>(
GetRawGlobalPtr<std::array<uint8_t, kSimd128Size>>(global),
global.init.immediate().s128_const);
break;
case WasmInitExpr::kRefNullConst:
DCHECK(enabled_.has_reftypes() || enabled_.has_eh());
if (global.imported) break; // We already initialized imported globals.
tagged_globals_->set(global.offset,
ReadOnlyRoots(isolate_).null_value(),
SKIP_WRITE_BARRIER);
break;
case WasmInitExpr::kRefFuncConst: {
DCHECK(enabled_.has_reftypes());
auto function = WasmInstanceObject::GetOrCreateWasmExternalFunction(
isolate_, instance, global.init.immediate().index);
tagged_globals_->set(global.offset, *function);
break;
}
case WasmInitExpr::kGlobalGet: {
// Initialize with another global.
uint32_t new_offset = global.offset;
uint32_t old_offset =
module_->globals[global.init.immediate().index].offset;
TRACE("init [globals+%u] = [globals+%d]\n", global.offset, old_offset);
if (global.type.is_reference_type()) {
DCHECK(enabled_.has_reftypes() || enabled_.has_eh());
tagged_globals_->set(new_offset, tagged_globals_->get(old_offset));
} else {
size_t size = (global.type == kWasmI64 || global.type == kWasmF64)
? sizeof(double)
: sizeof(int32_t);
memcpy(raw_buffer_ptr(untagged_globals_, new_offset),
raw_buffer_ptr(untagged_globals_, old_offset), size);
}
break;
}
case WasmInitExpr::kRttCanon:
case WasmInitExpr::kRttSub:
tagged_globals_->set(
global.offset,
*RecursivelyEvaluateGlobalInitializer(global.init, instance));
break;
case WasmInitExpr::kNone:
// Happens with imported globals.
break;
}
}
}
// Allocate memory for a module instance as a new JSArrayBuffer.
bool InstanceBuilder::AllocateMemory() {
uint32_t initial_pages = module_->initial_pages;
uint32_t maximum_pages =
module_->has_maximum_pages ? module_->maximum_pages : max_mem_pages();
if (initial_pages > max_mem_pages()) {
thrower_->RangeError("Out of memory: wasm memory too large");
return false;
}
auto shared = (module_->has_shared_memory && enabled_.has_threads())
? SharedFlag::kShared
: SharedFlag::kNotShared;
MaybeHandle<WasmMemoryObject> result =
WasmMemoryObject::New(isolate_, initial_pages, maximum_pages, shared);
if (!result.ToHandle(&memory_object_)) {
thrower_->RangeError("Out of memory: wasm memory");
return false;
}
memory_buffer_ =
Handle<JSArrayBuffer>(memory_object_->array_buffer(), isolate_);
return true;
}
// Process the exports, creating wrappers for functions, tables, memories,
// globals, and exceptions.
void InstanceBuilder::ProcessExports(Handle<WasmInstanceObject> instance) {
std::unordered_map<int, Handle<Object>> imported_globals;
// If an imported WebAssembly function or global gets exported, the export
// has to be identical to to import. Therefore we cache all imported
// WebAssembly functions in the instance, and all imported globals in a map
// here.
for (int index = 0, end = static_cast<int>(module_->import_table.size());
index < end; ++index) {
const WasmImport& import = module_->import_table[index];
if (import.kind == kExternalFunction) {
Handle<Object> value = sanitized_imports_[index].value;
if (WasmExternalFunction::IsWasmExternalFunction(*value)) {
WasmInstanceObject::SetWasmExternalFunction(
isolate_, instance, import.index,
Handle<WasmExternalFunction>::cast(value));
}
} else if (import.kind == kExternalGlobal) {
Handle<Object> value = sanitized_imports_[index].value;
if (value->IsWasmGlobalObject()) {
imported_globals[import.index] = value;
}
}
}
Handle<JSObject> exports_object;
MaybeHandle<String> single_function_name;
bool is_asm_js = is_asmjs_module(module_);
if (is_asm_js) {
Handle<JSFunction> object_function = Handle<JSFunction>(
isolate_->native_context()->object_function(), isolate_);
exports_object = isolate_->factory()->NewJSObject(object_function);
single_function_name =
isolate_->factory()->InternalizeUtf8String(AsmJs::kSingleFunctionName);
} else {
exports_object = isolate_->factory()->NewJSObjectWithNullProto();
}
instance->set_exports_object(*exports_object);
PropertyDescriptor desc;
desc.set_writable(is_asm_js);
desc.set_enumerable(true);
desc.set_configurable(is_asm_js);
// Process each export in the export table.
for (const WasmExport& exp : module_->export_table) {
Handle<String> name = WasmModuleObject::ExtractUtf8StringFromModuleBytes(
isolate_, module_object_, exp.name, kInternalize);
Handle<JSObject> export_to = exports_object;
switch (exp.kind) {
case kExternalFunction: {
// Wrap and export the code as a JSFunction.
// TODO(wasm): reduce duplication with LoadElemSegment() further below
Handle<WasmExternalFunction> wasm_external_function =
WasmInstanceObject::GetOrCreateWasmExternalFunction(
isolate_, instance, exp.index);
desc.set_value(wasm_external_function);
if (is_asm_js &&
String::Equals(isolate_, name,
single_function_name.ToHandleChecked())) {
export_to = instance;
}
break;
}
case kExternalTable: {
desc.set_value(handle(instance->tables().get(exp.index), isolate_));
break;
}
case kExternalMemory: {
// Export the memory as a WebAssembly.Memory object. A WasmMemoryObject
// should already be available if the module has memory, since we always
// create or import it when building an WasmInstanceObject.
DCHECK(instance->has_memory_object());
desc.set_value(
Handle<WasmMemoryObject>(instance->memory_object(), isolate_));
break;
}
case kExternalGlobal: {
const WasmGlobal& global = module_->globals[exp.index];
if (global.imported) {
auto cached_global = imported_globals.find(exp.index);
if (cached_global != imported_globals.end()) {
desc.set_value(cached_global->second);
break;
}
}
Handle<JSArrayBuffer> untagged_buffer;
Handle<FixedArray> tagged_buffer;
uint32_t offset;
if (global.mutability && global.imported) {
Handle<FixedArray> buffers_array(
instance->imported_mutable_globals_buffers(), isolate_);
if (global.type.is_reference_type()) {
tagged_buffer = handle(
FixedArray::cast(buffers_array->get(global.index)), isolate_);
// For externref globals we store the relative offset in the
// imported_mutable_globals array instead of an absolute address.
Address addr = instance->imported_mutable_globals()[global.index];
DCHECK_LE(addr, static_cast<Address>(
std::numeric_limits<uint32_t>::max()));
offset = static_cast<uint32_t>(addr);
} else {
untagged_buffer =
handle(JSArrayBuffer::cast(buffers_array->get(global.index)),
isolate_);
Address global_addr =
instance->imported_mutable_globals()[global.index];
size_t buffer_size = untagged_buffer->byte_length();
Address backing_store =
reinterpret_cast<Address>(untagged_buffer->backing_store());
CHECK(global_addr >= backing_store &&
global_addr < backing_store + buffer_size);
offset = static_cast<uint32_t>(global_addr - backing_store);
}
} else {
if (global.type.is_reference_type()) {
tagged_buffer = handle(instance->tagged_globals_buffer(), isolate_);
} else {
untagged_buffer =
handle(instance->untagged_globals_buffer(), isolate_);
}
offset = global.offset;
}
// Since the global's array untagged_buffer is always provided,
// allocation should never fail.
Handle<WasmGlobalObject> global_obj =
WasmGlobalObject::New(isolate_, instance, untagged_buffer,
tagged_buffer, global.type, offset,
global.mutability)
.ToHandleChecked();
desc.set_value(global_obj);
break;
}
case kExternalException: {
const WasmException& exception = module_->exceptions[exp.index];
Handle<WasmExceptionObject> wrapper = exception_wrappers_[exp.index];
if (wrapper.is_null()) {
Handle<HeapObject> exception_tag(
HeapObject::cast(instance->exceptions_table().get(exp.index)),
isolate_);
wrapper =
WasmExceptionObject::New(isolate_, exception.sig, exception_tag);
exception_wrappers_[exp.index] = wrapper;
}
desc.set_value(wrapper);
break;
}
default:
UNREACHABLE();
break;
}
v8::Maybe<bool> status = JSReceiver::DefineOwnProperty(
isolate_, export_to, name, &desc, Just(kThrowOnError));
if (!status.IsJust()) {
DisallowHeapAllocation no_gc;
TruncatedUserString<> trunc_name(name->GetCharVector<uint8_t>(no_gc));
thrower_->LinkError("export of %.*s failed.", trunc_name.length(),
trunc_name.start());
return;
}
}
if (module_->origin == kWasmOrigin) {
v8::Maybe<bool> success =
JSReceiver::SetIntegrityLevel(exports_object, FROZEN, kDontThrow);
DCHECK(success.FromMaybe(false));
USE(success);
}
}
void InstanceBuilder::InitializeIndirectFunctionTables(
Handle<WasmInstanceObject> instance) {
for (int i = 0; i < static_cast<int>(module_->tables.size()); ++i) {
const WasmTable& table = module_->tables[i];
if (IsSubtypeOf(table.type, kWasmFuncRef, module_)) {
WasmInstanceObject::EnsureIndirectFunctionTableWithMinimumSize(
instance, i, table.initial_size);
}
}
}
bool LoadElemSegmentImpl(Isolate* isolate, Handle<WasmInstanceObject> instance,
Handle<WasmTableObject> table_object,
uint32_t table_index, uint32_t segment_index,
uint32_t dst, uint32_t src, size_t count) {
DCHECK_LT(segment_index, instance->module()->elem_segments.size());
auto& elem_segment = instance->module()->elem_segments[segment_index];
// TODO(wasm): Move this functionality into wasm-objects, since it is used
// for both instantiation and in the implementation of the table.init
// instruction.
if (!base::IsInBounds<uint64_t>(dst, count, table_object->current_length()) ||
!base::IsInBounds<uint64_t>(
src, count,
instance->dropped_elem_segments()[segment_index] == 0
? elem_segment.entries.size()
: 0)) {
return false;
}
const WasmModule* module = instance->module();
for (size_t i = 0; i < count; ++i) {
uint32_t func_index = elem_segment.entries[src + i];
int entry_index = static_cast<int>(dst + i);
if (func_index == WasmElemSegment::kNullIndex) {
if (IsSubtypeOf(table_object->type(), kWasmFuncRef, module)) {
IndirectFunctionTableEntry(instance, table_index, entry_index).clear();
}
WasmTableObject::Set(isolate, table_object, entry_index,
isolate->factory()->null_value());
continue;
}
const WasmFunction* function = &module->functions[func_index];
// Update the local dispatch table first if necessary.
if (IsSubtypeOf(table_object->type(), kWasmFuncRef, module)) {
uint32_t sig_id = module->canonicalized_type_ids[function->sig_index];
IndirectFunctionTableEntry(instance, table_index, entry_index)
.Set(sig_id, instance, func_index);
}
// For ExternRef tables, we have to generate the WasmExternalFunction
// eagerly. Later we cannot know if an entry is a placeholder or not.
if (table_object->type().is_reference_to(HeapType::kExtern)) {
Handle<WasmExternalFunction> wasm_external_function =
WasmInstanceObject::GetOrCreateWasmExternalFunction(isolate, instance,
func_index);
WasmTableObject::Set(isolate, table_object, entry_index,
wasm_external_function);
} else {
// Update the table object's other dispatch tables.
MaybeHandle<WasmExternalFunction> wasm_external_function =
WasmInstanceObject::GetWasmExternalFunction(isolate, instance,
func_index);
if (wasm_external_function.is_null()) {
// No JSFunction entry yet exists for this function. Create a {Tuple2}
// holding the information to lazily allocate one.
WasmTableObject::SetFunctionTablePlaceholder(
isolate, table_object, entry_index, instance, func_index);
} else {
table_object->entries().set(entry_index,
*wasm_external_function.ToHandleChecked());
}
// UpdateDispatchTables() updates all other dispatch tables, since
// we have not yet added the dispatch table we are currently building.
WasmTableObject::UpdateDispatchTables(isolate, table_object, entry_index,
function->sig, instance,
func_index);
}
}
return true;
}
void InstanceBuilder::LoadTableSegments(Handle<WasmInstanceObject> instance) {
for (uint32_t segment_index = 0;
segment_index < module_->elem_segments.size(); ++segment_index) {
auto& elem_segment = instance->module()->elem_segments[segment_index];
// Passive segments are not copied during instantiation.
if (elem_segment.status != WasmElemSegment::kStatusActive) continue;
uint32_t table_index = elem_segment.table_index;
uint32_t dst = EvalUint32InitExpr(instance, elem_segment.offset);
uint32_t src = 0;
size_t count = elem_segment.entries.size();
bool success = LoadElemSegmentImpl(
isolate_, instance,
handle(WasmTableObject::cast(
instance->tables().get(elem_segment.table_index)),
isolate_),
table_index, segment_index, dst, src, count);
// Set the active segments to being already dropped, since memory.init on
// a dropped passive segment and an active segment have the same
// behavior.
instance->dropped_elem_segments()[segment_index] = 1;
if (enabled_.has_bulk_memory()) {
if (!success) {
thrower_->RuntimeError("table initializer is out of bounds");
// Break out instead of returning; we don't want to continue to
// initialize any further element segments, but still need to add
// dispatch tables below.
break;
}
} else {
CHECK(success);
}
}
int table_count = static_cast<int>(module_->tables.size());
for (int index = 0; index < table_count; ++index) {
if (IsSubtypeOf(module_->tables[index].type, kWasmFuncRef, module_)) {
auto table_object = handle(
WasmTableObject::cast(instance->tables().get(index)), isolate_);
// Add the new dispatch table at the end to avoid redundant lookups.
WasmTableObject::AddDispatchTable(isolate_, table_object, instance,
index);
}
}
}
void InstanceBuilder::InitializeExceptions(
Handle<WasmInstanceObject> instance) {
Handle<FixedArray> exceptions_table(instance->exceptions_table(), isolate_);
for (int index = 0; index < exceptions_table->length(); ++index) {
if (!exceptions_table->get(index).IsUndefined(isolate_)) continue;
Handle<WasmExceptionTag> exception_tag =
WasmExceptionTag::New(isolate_, index);
exceptions_table->set(index, *exception_tag);
}
}
bool LoadElemSegment(Isolate* isolate, Handle<WasmInstanceObject> instance,
uint32_t table_index, uint32_t segment_index, uint32_t dst,
uint32_t src, uint32_t count) {
return LoadElemSegmentImpl(
isolate, instance,
handle(WasmTableObject::cast(instance->tables().get(table_index)),
isolate),
table_index, segment_index, dst, src, count);
}
} // namespace wasm
} // namespace internal
} // namespace v8
#undef TRACE