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|
// Copyright 2020 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/objects/shared-function-info.h"
#include "src/ast/ast.h"
#include "src/ast/scopes.h"
#include "src/codegen/compilation-cache.h"
#include "src/codegen/compiler.h"
#include "src/diagnostics/code-tracer.h"
#include "src/objects/shared-function-info-inl.h"
#include "src/strings/string-builder-inl.h"
namespace v8 {
namespace internal {
V8_EXPORT_PRIVATE constexpr Smi SharedFunctionInfo::kNoSharedNameSentinel;
uint32_t SharedFunctionInfo::Hash() {
// Hash SharedFunctionInfo based on its start position and script id. Note: we
// don't use the function's literal id since getting that is slow for compiled
// funcitons.
int start_pos = StartPosition();
int script_id = script().IsScript() ? Script::cast(script()).id() : 0;
return static_cast<uint32_t>(base::hash_combine(start_pos, script_id));
}
void SharedFunctionInfo::Init(ReadOnlyRoots ro_roots, int unique_id) {
DisallowGarbageCollection no_gc;
// Set the function data to the "illegal" builtin. Ideally we'd use some sort
// of "uninitialized" marker here, but it's cheaper to use a valid buitin and
// avoid having to do uninitialized checks elsewhere.
set_builtin_id(Builtins::kIllegal);
// Set the name to the no-name sentinel, this can be updated later.
set_name_or_scope_info(SharedFunctionInfo::kNoSharedNameSentinel,
kReleaseStore, SKIP_WRITE_BARRIER);
// Generally functions won't have feedback, unless they have been created
// from a FunctionLiteral. Those can just reset this field to keep the
// SharedFunctionInfo in a consistent state.
set_raw_outer_scope_info_or_feedback_metadata(ro_roots.the_hole_value(),
SKIP_WRITE_BARRIER);
set_script_or_debug_info(ro_roots.undefined_value(), kReleaseStore,
SKIP_WRITE_BARRIER);
set_function_literal_id(kFunctionLiteralIdInvalid);
#if V8_SFI_HAS_UNIQUE_ID
set_unique_id(unique_id);
#endif
// Set integer fields (smi or int, depending on the architecture).
set_length(0);
set_internal_formal_parameter_count(0);
set_expected_nof_properties(0);
set_raw_function_token_offset(0);
// All flags default to false or 0, except ConstructAsBuiltinBit just because
// we're using the kIllegal builtin.
set_flags(ConstructAsBuiltinBit::encode(true));
set_flags2(0);
UpdateFunctionMapIndex();
clear_padding();
}
Code SharedFunctionInfo::GetCode() const {
// ======
// NOTE: This chain of checks MUST be kept in sync with the equivalent CSA
// GetSharedFunctionInfoCode method in code-stub-assembler.cc.
// ======
Isolate* isolate = GetIsolate();
Object data = function_data(kAcquireLoad);
if (data.IsSmi()) {
// Holding a Smi means we are a builtin.
DCHECK(HasBuiltinId());
return isolate->builtins()->builtin(builtin_id());
} else if (data.IsBytecodeArray()) {
// Having a bytecode array means we are a compiled, interpreted function.
DCHECK(HasBytecodeArray());
return isolate->builtins()->builtin(Builtins::kInterpreterEntryTrampoline);
} else if (data.IsAsmWasmData()) {
// Having AsmWasmData means we are an asm.js/wasm function.
DCHECK(HasAsmWasmData());
return isolate->builtins()->builtin(Builtins::kInstantiateAsmJs);
} else if (data.IsUncompiledData()) {
// Having uncompiled data (with or without scope) means we need to compile.
DCHECK(HasUncompiledData());
return isolate->builtins()->builtin(Builtins::kCompileLazy);
} else if (data.IsFunctionTemplateInfo()) {
// Having a function template info means we are an API function.
DCHECK(IsApiFunction());
return isolate->builtins()->builtin(Builtins::kHandleApiCall);
} else if (data.IsWasmExportedFunctionData()) {
// Having a WasmExportedFunctionData means the code is in there.
DCHECK(HasWasmExportedFunctionData());
return wasm_exported_function_data().wrapper_code();
} else if (data.IsInterpreterData()) {
Code code = InterpreterTrampoline();
DCHECK(code.IsCode());
DCHECK(code.is_interpreter_trampoline_builtin());
return code;
} else if (data.IsWasmJSFunctionData()) {
return wasm_js_function_data().wrapper_code();
} else if (data.IsWasmCapiFunctionData()) {
return wasm_capi_function_data().wrapper_code();
}
UNREACHABLE();
}
WasmExportedFunctionData SharedFunctionInfo::wasm_exported_function_data()
const {
DCHECK(HasWasmExportedFunctionData());
return WasmExportedFunctionData::cast(function_data(kAcquireLoad));
}
WasmJSFunctionData SharedFunctionInfo::wasm_js_function_data() const {
DCHECK(HasWasmJSFunctionData());
return WasmJSFunctionData::cast(function_data(kAcquireLoad));
}
WasmCapiFunctionData SharedFunctionInfo::wasm_capi_function_data() const {
DCHECK(HasWasmCapiFunctionData());
return WasmCapiFunctionData::cast(function_data(kAcquireLoad));
}
SharedFunctionInfo::ScriptIterator::ScriptIterator(Isolate* isolate,
Script script)
: ScriptIterator(handle(script.shared_function_infos(), isolate)) {}
SharedFunctionInfo::ScriptIterator::ScriptIterator(
Handle<WeakFixedArray> shared_function_infos)
: shared_function_infos_(shared_function_infos), index_(0) {}
SharedFunctionInfo SharedFunctionInfo::ScriptIterator::Next() {
while (index_ < shared_function_infos_->length()) {
MaybeObject raw = shared_function_infos_->Get(index_++);
HeapObject heap_object;
if (!raw->GetHeapObject(&heap_object) || heap_object.IsUndefined()) {
continue;
}
return SharedFunctionInfo::cast(heap_object);
}
return SharedFunctionInfo();
}
void SharedFunctionInfo::ScriptIterator::Reset(Isolate* isolate,
Script script) {
shared_function_infos_ = handle(script.shared_function_infos(), isolate);
index_ = 0;
}
void SharedFunctionInfo::SetScript(ReadOnlyRoots roots,
HeapObject script_object,
int function_literal_id,
bool reset_preparsed_scope_data) {
DisallowGarbageCollection no_gc;
if (script() == script_object) return;
if (reset_preparsed_scope_data && HasUncompiledDataWithPreparseData()) {
ClearPreparseData();
}
// Add shared function info to new script's list. If a collection occurs,
// the shared function info may be temporarily in two lists.
// This is okay because the gc-time processing of these lists can tolerate
// duplicates.
if (script_object.IsScript()) {
DCHECK(!script().IsScript());
Script script = Script::cast(script_object);
WeakFixedArray list = script.shared_function_infos();
#ifdef DEBUG
DCHECK_LT(function_literal_id, list.length());
MaybeObject maybe_object = list.Get(function_literal_id);
HeapObject heap_object;
if (maybe_object->GetHeapObjectIfWeak(&heap_object)) {
DCHECK_EQ(heap_object, *this);
}
#endif
list.Set(function_literal_id, HeapObjectReference::Weak(*this));
} else {
DCHECK(script().IsScript());
// Remove shared function info from old script's list.
Script old_script = Script::cast(script());
// Due to liveedit, it might happen that the old_script doesn't know
// about the SharedFunctionInfo, so we have to guard against that.
WeakFixedArray infos = old_script.shared_function_infos();
if (function_literal_id < infos.length()) {
MaybeObject raw =
old_script.shared_function_infos().Get(function_literal_id);
HeapObject heap_object;
if (raw->GetHeapObjectIfWeak(&heap_object) && heap_object == *this) {
old_script.shared_function_infos().Set(
function_literal_id,
HeapObjectReference::Strong(roots.undefined_value()));
}
}
}
// Finally set new script.
set_script(script_object);
}
bool SharedFunctionInfo::HasBreakInfo() const {
if (!HasDebugInfo()) return false;
DebugInfo info = GetDebugInfo();
bool has_break_info = info.HasBreakInfo();
return has_break_info;
}
bool SharedFunctionInfo::BreakAtEntry() const {
if (!HasDebugInfo()) return false;
DebugInfo info = GetDebugInfo();
bool break_at_entry = info.BreakAtEntry();
return break_at_entry;
}
bool SharedFunctionInfo::HasCoverageInfo() const {
if (!HasDebugInfo()) return false;
DebugInfo info = GetDebugInfo();
bool has_coverage_info = info.HasCoverageInfo();
return has_coverage_info;
}
CoverageInfo SharedFunctionInfo::GetCoverageInfo() const {
DCHECK(HasCoverageInfo());
return CoverageInfo::cast(GetDebugInfo().coverage_info());
}
std::unique_ptr<char[]> SharedFunctionInfo::DebugNameCStr() {
if (HasWasmExportedFunctionData()) {
return WasmExportedFunction::GetDebugName(
wasm_exported_function_data().sig());
}
DisallowGarbageCollection no_gc;
String function_name = Name();
if (function_name.length() == 0) function_name = inferred_name();
return function_name.ToCString();
}
// static
Handle<String> SharedFunctionInfo::DebugName(
Handle<SharedFunctionInfo> shared) {
if (shared->HasWasmExportedFunctionData()) {
return shared->GetIsolate()
->factory()
->NewStringFromUtf8(CStrVector(shared->DebugNameCStr().get()))
.ToHandleChecked();
}
DisallowHeapAllocation no_gc;
String function_name = shared->Name();
if (function_name.length() == 0) function_name = shared->inferred_name();
return handle(function_name, shared->GetIsolate());
}
bool SharedFunctionInfo::PassesFilter(const char* raw_filter) {
Vector<const char> filter = CStrVector(raw_filter);
return v8::internal::PassesFilter(CStrVector(DebugNameCStr().get()), filter);
}
bool SharedFunctionInfo::HasSourceCode() const {
ReadOnlyRoots roots = GetReadOnlyRoots();
return !script().IsUndefined(roots) &&
!Script::cast(script()).source().IsUndefined(roots) &&
String::cast(Script::cast(script()).source()).length() > 0;
}
void SharedFunctionInfo::DiscardCompiledMetadata(
Isolate* isolate,
std::function<void(HeapObject object, ObjectSlot slot, HeapObject target)>
gc_notify_updated_slot) {
DisallowGarbageCollection no_gc;
if (is_compiled()) {
if (FLAG_trace_flush_bytecode) {
CodeTracer::Scope scope(GetIsolate()->GetCodeTracer());
PrintF(scope.file(), "[discarding compiled metadata for ");
ShortPrint(scope.file());
PrintF(scope.file(), "]\n");
}
HeapObject outer_scope_info;
if (scope_info().HasOuterScopeInfo()) {
outer_scope_info = scope_info().OuterScopeInfo();
} else {
outer_scope_info = ReadOnlyRoots(isolate).the_hole_value();
}
// Raw setter to avoid validity checks, since we're performing the unusual
// task of decompiling.
set_raw_outer_scope_info_or_feedback_metadata(outer_scope_info);
gc_notify_updated_slot(
*this,
RawField(SharedFunctionInfo::kOuterScopeInfoOrFeedbackMetadataOffset),
outer_scope_info);
} else {
DCHECK(outer_scope_info().IsScopeInfo() || outer_scope_info().IsTheHole());
}
// TODO(rmcilroy): Possibly discard ScopeInfo here as well.
}
// static
void SharedFunctionInfo::DiscardCompiled(
Isolate* isolate, Handle<SharedFunctionInfo> shared_info) {
DCHECK(shared_info->CanDiscardCompiled());
Handle<String> inferred_name_val =
handle(shared_info->inferred_name(), isolate);
int start_position = shared_info->StartPosition();
int end_position = shared_info->EndPosition();
shared_info->DiscardCompiledMetadata(isolate);
// Replace compiled data with a new UncompiledData object.
if (shared_info->HasUncompiledDataWithPreparseData()) {
// If this is uncompiled data with a pre-parsed scope data, we can just
// clear out the scope data and keep the uncompiled data.
shared_info->ClearPreparseData();
} else {
// Create a new UncompiledData, without pre-parsed scope, and update the
// function data to point to it. Use the raw function data setter to avoid
// validity checks, since we're performing the unusual task of decompiling.
Handle<UncompiledData> data =
isolate->factory()->NewUncompiledDataWithoutPreparseData(
inferred_name_val, start_position, end_position);
shared_info->set_function_data(*data, kReleaseStore);
}
}
// static
Handle<Object> SharedFunctionInfo::GetSourceCode(
Handle<SharedFunctionInfo> shared) {
Isolate* isolate = shared->GetIsolate();
if (!shared->HasSourceCode()) return isolate->factory()->undefined_value();
Handle<String> source(String::cast(Script::cast(shared->script()).source()),
isolate);
return isolate->factory()->NewSubString(source, shared->StartPosition(),
shared->EndPosition());
}
// static
Handle<Object> SharedFunctionInfo::GetSourceCodeHarmony(
Handle<SharedFunctionInfo> shared) {
Isolate* isolate = shared->GetIsolate();
if (!shared->HasSourceCode()) return isolate->factory()->undefined_value();
Handle<String> script_source(
String::cast(Script::cast(shared->script()).source()), isolate);
int start_pos = shared->function_token_position();
DCHECK_NE(start_pos, kNoSourcePosition);
Handle<String> source = isolate->factory()->NewSubString(
script_source, start_pos, shared->EndPosition());
if (!shared->is_wrapped()) return source;
DCHECK(!shared->name_should_print_as_anonymous());
IncrementalStringBuilder builder(isolate);
builder.AppendCString("function ");
builder.AppendString(Handle<String>(shared->Name(), isolate));
builder.AppendCString("(");
Handle<FixedArray> args(Script::cast(shared->script()).wrapped_arguments(),
isolate);
int argc = args->length();
for (int i = 0; i < argc; i++) {
if (i > 0) builder.AppendCString(", ");
builder.AppendString(Handle<String>(String::cast(args->get(i)), isolate));
}
builder.AppendCString(") {\n");
builder.AppendString(source);
builder.AppendCString("\n}");
return builder.Finish().ToHandleChecked();
}
int SharedFunctionInfo::SourceSize() { return EndPosition() - StartPosition(); }
// Output the source code without any allocation in the heap.
std::ostream& operator<<(std::ostream& os, const SourceCodeOf& v) {
const SharedFunctionInfo s = v.value;
// For some native functions there is no source.
if (!s.HasSourceCode()) return os << "<No Source>";
// Get the source for the script which this function came from.
// Don't use String::cast because we don't want more assertion errors while
// we are already creating a stack dump.
String script_source =
String::unchecked_cast(Script::cast(s.script()).source());
if (!script_source.LooksValid()) return os << "<Invalid Source>";
if (!s.is_toplevel()) {
os << "function ";
String name = s.Name();
if (name.length() > 0) {
name.PrintUC16(os);
}
}
int len = s.EndPosition() - s.StartPosition();
if (len <= v.max_length || v.max_length < 0) {
script_source.PrintUC16(os, s.StartPosition(), s.EndPosition());
return os;
} else {
script_source.PrintUC16(os, s.StartPosition(),
s.StartPosition() + v.max_length);
return os << "...\n";
}
}
MaybeHandle<Code> SharedFunctionInfo::TryGetCachedCode(Isolate* isolate) {
if (!may_have_cached_code()) return {};
Handle<SharedFunctionInfo> zis(*this, isolate);
return isolate->compilation_cache()->LookupCode(zis);
}
void SharedFunctionInfo::DisableOptimization(BailoutReason reason) {
DCHECK_NE(reason, BailoutReason::kNoReason);
set_flags(DisabledOptimizationReasonBits::update(flags(), reason));
// Code should be the lazy compilation stub or else interpreted.
Isolate* isolate = GetIsolate();
DCHECK(abstract_code(isolate).kind() == CodeKind::INTERPRETED_FUNCTION ||
abstract_code(isolate).kind() == CodeKind::BUILTIN);
PROFILE(isolate, CodeDisableOptEvent(handle(abstract_code(isolate), isolate),
handle(*this, isolate)));
if (FLAG_trace_opt) {
CodeTracer::Scope scope(isolate->GetCodeTracer());
PrintF(scope.file(), "[disabled optimization for ");
ShortPrint(scope.file());
PrintF(scope.file(), ", reason: %s]\n", GetBailoutReason(reason));
}
}
// static
template <typename LocalIsolate>
void SharedFunctionInfo::InitFromFunctionLiteral(
LocalIsolate* isolate, Handle<SharedFunctionInfo> shared_info,
FunctionLiteral* lit, bool is_toplevel) {
DCHECK(!shared_info->name_or_scope_info(kAcquireLoad).IsScopeInfo());
// When adding fields here, make sure DeclarationScope::AnalyzePartially is
// updated accordingly.
shared_info->set_internal_formal_parameter_count(lit->parameter_count());
shared_info->SetFunctionTokenPosition(lit->function_token_position(),
lit->start_position());
shared_info->set_syntax_kind(lit->syntax_kind());
shared_info->set_allows_lazy_compilation(lit->AllowsLazyCompilation());
shared_info->set_language_mode(lit->language_mode());
shared_info->set_function_literal_id(lit->function_literal_id());
// FunctionKind must have already been set.
DCHECK(lit->kind() == shared_info->kind());
shared_info->set_needs_home_object(lit->scope()->NeedsHomeObject());
DCHECK_IMPLIES(lit->requires_instance_members_initializer(),
IsClassConstructor(lit->kind()));
shared_info->set_requires_instance_members_initializer(
lit->requires_instance_members_initializer());
DCHECK_IMPLIES(lit->class_scope_has_private_brand(),
IsClassConstructor(lit->kind()));
shared_info->set_class_scope_has_private_brand(
lit->class_scope_has_private_brand());
DCHECK_IMPLIES(lit->has_static_private_methods_or_accessors(),
IsClassConstructor(lit->kind()));
shared_info->set_has_static_private_methods_or_accessors(
lit->has_static_private_methods_or_accessors());
shared_info->set_is_toplevel(is_toplevel);
DCHECK(shared_info->outer_scope_info().IsTheHole());
if (!is_toplevel) {
Scope* outer_scope = lit->scope()->GetOuterScopeWithContext();
if (outer_scope) {
shared_info->set_outer_scope_info(*outer_scope->scope_info());
shared_info->set_private_name_lookup_skips_outer_class(
lit->scope()->private_name_lookup_skips_outer_class());
}
}
shared_info->set_length(lit->function_length());
// For lazy parsed functions, the following flags will be inaccurate since we
// don't have the information yet. They're set later in
// SetSharedFunctionFlagsFromLiteral (compiler.cc), when the function is
// really parsed and compiled.
if (lit->ShouldEagerCompile()) {
shared_info->set_has_duplicate_parameters(lit->has_duplicate_parameters());
shared_info->UpdateAndFinalizeExpectedNofPropertiesFromEstimate(lit);
DCHECK_NULL(lit->produced_preparse_data());
// If we're about to eager compile, we'll have the function literal
// available, so there's no need to wastefully allocate an uncompiled data.
return;
}
shared_info->UpdateExpectedNofPropertiesFromEstimate(lit);
Handle<UncompiledData> data;
ProducedPreparseData* scope_data = lit->produced_preparse_data();
if (scope_data != nullptr) {
Handle<PreparseData> preparse_data = scope_data->Serialize(isolate);
data = isolate->factory()->NewUncompiledDataWithPreparseData(
lit->GetInferredName(isolate), lit->start_position(),
lit->end_position(), preparse_data);
} else {
data = isolate->factory()->NewUncompiledDataWithoutPreparseData(
lit->GetInferredName(isolate), lit->start_position(),
lit->end_position());
}
shared_info->set_uncompiled_data(*data);
}
template EXPORT_TEMPLATE_DEFINE(V8_EXPORT_PRIVATE) void SharedFunctionInfo::
InitFromFunctionLiteral<Isolate>(Isolate* isolate,
Handle<SharedFunctionInfo> shared_info,
FunctionLiteral* lit, bool is_toplevel);
template EXPORT_TEMPLATE_DEFINE(V8_EXPORT_PRIVATE) void SharedFunctionInfo::
InitFromFunctionLiteral<LocalIsolate>(
LocalIsolate* isolate, Handle<SharedFunctionInfo> shared_info,
FunctionLiteral* lit, bool is_toplevel);
uint16_t SharedFunctionInfo::get_property_estimate_from_literal(
FunctionLiteral* literal) {
int estimate = literal->expected_property_count();
// If this is a class constructor, we may have already parsed fields.
if (is_class_constructor()) {
estimate += expected_nof_properties();
}
return estimate;
}
void SharedFunctionInfo::UpdateExpectedNofPropertiesFromEstimate(
FunctionLiteral* literal) {
// Limit actual estimate to fit in a 8 bit field, we will never allocate
// more than this in any case.
STATIC_ASSERT(JSObject::kMaxInObjectProperties <= kMaxUInt8);
int estimate = get_property_estimate_from_literal(literal);
set_expected_nof_properties(std::min(estimate, kMaxUInt8));
}
void SharedFunctionInfo::UpdateAndFinalizeExpectedNofPropertiesFromEstimate(
FunctionLiteral* literal) {
DCHECK(literal->ShouldEagerCompile());
if (are_properties_final()) {
return;
}
int estimate = get_property_estimate_from_literal(literal);
// If no properties are added in the constructor, they are more likely
// to be added later.
if (estimate == 0) estimate = 2;
// Limit actual estimate to fit in a 8 bit field, we will never allocate
// more than this in any case.
STATIC_ASSERT(JSObject::kMaxInObjectProperties <= kMaxUInt8);
estimate = std::min(estimate, kMaxUInt8);
set_expected_nof_properties(estimate);
set_are_properties_final(true);
}
void SharedFunctionInfo::SetFunctionTokenPosition(int function_token_position,
int start_position) {
int offset;
if (function_token_position == kNoSourcePosition) {
offset = 0;
} else {
offset = start_position - function_token_position;
}
if (offset > kMaximumFunctionTokenOffset) {
offset = kFunctionTokenOutOfRange;
}
set_raw_function_token_offset(offset);
}
int SharedFunctionInfo::StartPosition() const {
Object maybe_scope_info = name_or_scope_info(kAcquireLoad);
if (maybe_scope_info.IsScopeInfo()) {
ScopeInfo info = ScopeInfo::cast(maybe_scope_info);
if (info.HasPositionInfo()) {
return info.StartPosition();
}
}
if (HasUncompiledData()) {
// Works with or without scope.
return uncompiled_data().start_position();
}
if (IsApiFunction() || HasBuiltinId()) {
DCHECK_IMPLIES(HasBuiltinId(), builtin_id() != Builtins::kCompileLazy);
return 0;
}
if (HasWasmExportedFunctionData()) {
WasmInstanceObject instance = wasm_exported_function_data().instance();
int func_index = wasm_exported_function_data().function_index();
auto& function = instance.module()->functions[func_index];
return static_cast<int>(function.code.offset());
}
return kNoSourcePosition;
}
int SharedFunctionInfo::EndPosition() const {
Object maybe_scope_info = name_or_scope_info(kAcquireLoad);
if (maybe_scope_info.IsScopeInfo()) {
ScopeInfo info = ScopeInfo::cast(maybe_scope_info);
if (info.HasPositionInfo()) {
return info.EndPosition();
}
}
if (HasUncompiledData()) {
// Works with or without scope.
return uncompiled_data().end_position();
}
if (IsApiFunction() || HasBuiltinId()) {
DCHECK_IMPLIES(HasBuiltinId(), builtin_id() != Builtins::kCompileLazy);
return 0;
}
if (HasWasmExportedFunctionData()) {
WasmInstanceObject instance = wasm_exported_function_data().instance();
int func_index = wasm_exported_function_data().function_index();
auto& function = instance.module()->functions[func_index];
return static_cast<int>(function.code.end_offset());
}
return kNoSourcePosition;
}
void SharedFunctionInfo::SetPosition(int start_position, int end_position) {
Object maybe_scope_info = name_or_scope_info(kAcquireLoad);
if (maybe_scope_info.IsScopeInfo()) {
ScopeInfo info = ScopeInfo::cast(maybe_scope_info);
if (info.HasPositionInfo()) {
info.SetPositionInfo(start_position, end_position);
}
} else if (HasUncompiledData()) {
if (HasUncompiledDataWithPreparseData()) {
// Clear out preparsed scope data, since the position setter invalidates
// any scope data.
ClearPreparseData();
}
uncompiled_data().set_start_position(start_position);
uncompiled_data().set_end_position(end_position);
} else {
UNREACHABLE();
}
}
// static
void SharedFunctionInfo::EnsureSourcePositionsAvailable(
Isolate* isolate, Handle<SharedFunctionInfo> shared_info) {
if (FLAG_enable_lazy_source_positions && shared_info->HasBytecodeArray() &&
!shared_info->GetBytecodeArray(isolate).HasSourcePositionTable()) {
Compiler::CollectSourcePositions(isolate, shared_info);
}
}
// static
void SharedFunctionInfo::InstallDebugBytecode(Handle<SharedFunctionInfo> shared,
Isolate* isolate) {
DCHECK(shared->HasBytecodeArray());
Handle<BytecodeArray> original_bytecode_array(
shared->GetBytecodeArray(isolate), isolate);
Handle<BytecodeArray> debug_bytecode_array =
isolate->factory()->CopyBytecodeArray(original_bytecode_array);
{
DisallowGarbageCollection no_gc;
base::SharedMutexGuard<base::kExclusive> mutex_guard(
isolate->shared_function_info_access());
DebugInfo debug_info = shared->GetDebugInfo();
debug_info.set_original_bytecode_array(*original_bytecode_array,
kReleaseStore);
debug_info.set_debug_bytecode_array(*debug_bytecode_array, kReleaseStore);
shared->SetActiveBytecodeArray(*debug_bytecode_array);
}
}
// static
void SharedFunctionInfo::UninstallDebugBytecode(SharedFunctionInfo shared,
Isolate* isolate) {
DisallowGarbageCollection no_gc;
base::SharedMutexGuard<base::kExclusive> mutex_guard(
isolate->shared_function_info_access());
DebugInfo debug_info = shared.GetDebugInfo();
BytecodeArray original_bytecode_array = debug_info.OriginalBytecodeArray();
shared.SetActiveBytecodeArray(original_bytecode_array);
debug_info.set_original_bytecode_array(
ReadOnlyRoots(isolate).undefined_value(), kReleaseStore);
debug_info.set_debug_bytecode_array(ReadOnlyRoots(isolate).undefined_value(),
kReleaseStore);
}
} // namespace internal
} // namespace v8
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