v8/test/cctest/wasm/wasm-run-utils.cc
Clemens Backes e0433f7dd0 [wasm][debug] Store "for debugging" flag on compilation unit
Before the "debug" flag was stored on the {CompilationEnv}. But each
background compilation task only gets the {CompilationEnv} once when
starting compilation, so by the time it picks up the "Liftoff for
debugging" compilation jobs, it might still compile them without the
debug flag being set. This leads to flakes in the "debug-step-into-wasm"
test, because we won't stop in the function prologue when stepping in
(because the function prologue does not check the "hook on function
call" flag if debug mode was not enabled).

This CL does not increase the size of a compilation unit, since both the
tier and the debug flag only need a single byte each.

As a nice side effect, this change allows us to remove the lock in
{CreateCompilationEnv}, because no modifyable flag is read any more.

R=thibaudm@chromium.org

Bug: v8:10410
Change-Id: Ic296ea0c4dd1d4dedde119f0536e87e5d301b5a1
Reviewed-on: https://chromium-review.googlesource.com/c/v8/v8/+/2144116
Reviewed-by: Thibaud Michaud <thibaudm@chromium.org>
Commit-Queue: Clemens Backes <clemensb@chromium.org>
Cr-Commit-Position: refs/heads/master@{#67115}
2020-04-14 13:58:59 +00:00

635 lines
25 KiB
C++

// Copyright 2017 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 "test/cctest/wasm/wasm-run-utils.h"
#include "src/codegen/assembler-inl.h"
#include "src/diagnostics/code-tracer.h"
#include "src/heap/heap-inl.h"
#include "src/wasm/graph-builder-interface.h"
#include "src/wasm/leb-helper.h"
#include "src/wasm/module-compiler.h"
#include "src/wasm/wasm-import-wrapper-cache.h"
#include "src/wasm/wasm-objects-inl.h"
#include "src/wasm/wasm-opcodes.h"
namespace v8 {
namespace internal {
namespace wasm {
template <>
void AppendSingle(std::vector<byte>* code, WasmOpcode op) {
// We do not yet have opcodes that take up more than 2 byte (decoded). But if
// that changes, this will need to be updated.
DCHECK_EQ(0, op >> 16);
byte prefix = (op >> 8) & 0xff;
byte opcode = op & 0xff;
if (!prefix) {
code->push_back(opcode);
return;
}
// Ensure the prefix is really one of the supported prefixed opcodes.
DCHECK(WasmOpcodes::IsPrefixOpcode(static_cast<WasmOpcode>(prefix)));
code->push_back(prefix);
// Decoded opcodes fit in a byte (0x00-0xff).
DCHECK_LE(LEBHelper::sizeof_u32v(opcode), 2);
// Therefore, the encoding needs max 2 bytes.
uint8_t encoded[2];
uint8_t* d = encoded;
// d is updated to after the last uint8_t written.
LEBHelper::write_u32v(&d, opcode);
for (uint8_t* p = encoded; p < d; p++) {
code->push_back(*p);
}
}
TestingModuleBuilder::TestingModuleBuilder(
Zone* zone, ManuallyImportedJSFunction* maybe_import, ExecutionTier tier,
RuntimeExceptionSupport exception_support, LowerSimd lower_simd)
: test_module_(std::make_shared<WasmModule>()),
test_module_ptr_(test_module_.get()),
isolate_(CcTest::InitIsolateOnce()),
enabled_features_(WasmFeatures::FromIsolate(isolate_)),
execution_tier_(tier),
runtime_exception_support_(exception_support),
lower_simd_(lower_simd) {
WasmJs::Install(isolate_, true);
test_module_->untagged_globals_buffer_size = kMaxGlobalsSize;
memset(globals_data_, 0, sizeof(globals_data_));
uint32_t maybe_import_index = 0;
if (maybe_import) {
// Manually add an imported function before any other functions.
// This must happen before the instance object is created, since the
// instance object allocates import entries.
maybe_import_index = AddFunction(maybe_import->sig, nullptr, kImport);
DCHECK_EQ(0, maybe_import_index);
}
instance_object_ = InitInstanceObject();
Handle<FixedArray> tables(isolate_->factory()->NewFixedArray(0));
instance_object_->set_tables(*tables);
if (maybe_import) {
// Manually compile an import wrapper and insert it into the instance.
CodeSpaceMemoryModificationScope modification_scope(isolate_->heap());
auto resolved = compiler::ResolveWasmImportCall(
maybe_import->js_function, maybe_import->sig, enabled_features_);
compiler::WasmImportCallKind kind = resolved.first;
Handle<JSReceiver> callable = resolved.second;
WasmImportWrapperCache::ModificationScope cache_scope(
native_module_->import_wrapper_cache());
WasmImportWrapperCache::CacheKey key(kind, maybe_import->sig);
auto import_wrapper = cache_scope[key];
if (import_wrapper == nullptr) {
import_wrapper = CompileImportWrapper(
isolate_->wasm_engine(), native_module_, isolate_->counters(), kind,
maybe_import->sig, &cache_scope);
}
ImportedFunctionEntry(instance_object_, maybe_import_index)
.SetWasmToJs(isolate_, callable, import_wrapper);
}
if (tier == ExecutionTier::kInterpreter) {
interpreter_ = WasmDebugInfo::SetupForTesting(instance_object_);
}
}
TestingModuleBuilder::~TestingModuleBuilder() {
// When the native module dies and is erased from the cache, it is expected to
// have either valid bytes or no bytes at all.
native_module_->SetWireBytes({});
}
byte* TestingModuleBuilder::AddMemory(uint32_t size, SharedFlag shared) {
CHECK(!test_module_->has_memory);
CHECK_NULL(mem_start_);
CHECK_EQ(0, mem_size_);
DCHECK(!instance_object_->has_memory_object());
uint32_t initial_pages = RoundUp(size, kWasmPageSize) / kWasmPageSize;
uint32_t maximum_pages = (test_module_->maximum_pages != 0)
? test_module_->maximum_pages
: initial_pages;
test_module_->has_memory = true;
// Create the WasmMemoryObject.
Handle<WasmMemoryObject> memory_object =
WasmMemoryObject::New(isolate_, initial_pages, maximum_pages, shared)
.ToHandleChecked();
instance_object_->set_memory_object(*memory_object);
mem_start_ =
reinterpret_cast<byte*>(memory_object->array_buffer().backing_store());
mem_size_ = size;
CHECK(size == 0 || mem_start_);
WasmMemoryObject::AddInstance(isolate_, memory_object, instance_object_);
// TODO(wasm): Delete the following two lines when test-run-wasm will use a
// multiple of kPageSize as memory size. At the moment, the effect of these
// two lines is used to shrink the memory for testing purposes.
instance_object_->SetRawMemory(mem_start_, mem_size_);
return mem_start_;
}
uint32_t TestingModuleBuilder::AddFunction(const FunctionSig* sig,
const char* name,
FunctionType type) {
if (test_module_->functions.size() == 0) {
// TODO(titzer): Reserving space here to avoid the underlying WasmFunction
// structs from moving.
test_module_->functions.reserve(kMaxFunctions);
}
uint32_t index = static_cast<uint32_t>(test_module_->functions.size());
test_module_->functions.push_back({sig, // sig
index, // func_index
0, // sig_index
{0, 0}, // code
false, // imported
false, // exported
false}); // declared
if (type == kImport) {
DCHECK_EQ(0, test_module_->num_declared_functions);
++test_module_->num_imported_functions;
test_module_->functions.back().imported = true;
} else {
++test_module_->num_declared_functions;
}
DCHECK_EQ(test_module_->functions.size(),
test_module_->num_imported_functions +
test_module_->num_declared_functions);
if (name) {
Vector<const byte> name_vec = Vector<const byte>::cast(CStrVector(name));
test_module_->lazily_generated_names.AddForTesting(
index, {AddBytes(name_vec), static_cast<uint32_t>(name_vec.length())});
}
if (interpreter_) {
interpreter_->AddFunctionForTesting(&test_module_->functions.back());
// Patch the jump table to call the interpreter for this function.
wasm::WasmCompilationResult result = compiler::CompileWasmInterpreterEntry(
isolate_->wasm_engine(), native_module_->enabled_features(), index,
sig);
std::unique_ptr<wasm::WasmCode> code = native_module_->AddCode(
index, result.code_desc, result.frame_slot_count,
result.tagged_parameter_slots,
result.protected_instructions_data.as_vector(),
result.source_positions.as_vector(), wasm::WasmCode::kInterpreterEntry,
wasm::ExecutionTier::kInterpreter);
native_module_->PublishCode(std::move(code));
}
DCHECK_LT(index, kMaxFunctions); // limited for testing.
return index;
}
void TestingModuleBuilder::FreezeSignatureMapAndInitializeWrapperCache() {
if (test_module_->signature_map.is_frozen()) return;
test_module_->signature_map.Freeze();
size_t max_num_sigs = MaxNumExportWrappers(test_module_.get());
Handle<FixedArray> export_wrappers =
isolate_->factory()->NewFixedArray(static_cast<int>(max_num_sigs));
instance_object_->module_object().set_export_wrappers(*export_wrappers);
}
Handle<JSFunction> TestingModuleBuilder::WrapCode(uint32_t index) {
FreezeSignatureMapAndInitializeWrapperCache();
SetExecutable();
return WasmInstanceObject::GetOrCreateWasmExternalFunction(
isolate_, instance_object(), index);
}
void TestingModuleBuilder::AddIndirectFunctionTable(
const uint16_t* function_indexes, uint32_t table_size) {
auto instance = instance_object();
uint32_t table_index = static_cast<uint32_t>(test_module_->tables.size());
test_module_->tables.emplace_back();
WasmTable& table = test_module_->tables.back();
table.initial_size = table_size;
table.maximum_size = table_size;
table.has_maximum_size = true;
table.type = kWasmFuncRef;
{
// Allocate the indirect function table.
Handle<FixedArray> old_tables =
table_index == 0
? isolate_->factory()->empty_fixed_array()
: handle(instance_object_->indirect_function_tables(), isolate_);
Handle<FixedArray> new_tables =
isolate_->factory()->CopyFixedArrayAndGrow(old_tables, 1);
Handle<WasmIndirectFunctionTable> table_obj =
WasmIndirectFunctionTable::New(isolate_, table.initial_size);
new_tables->set(table_index, *table_obj);
instance_object_->set_indirect_function_tables(*new_tables);
}
WasmInstanceObject::EnsureIndirectFunctionTableWithMinimumSize(
instance_object(), table_index, table_size);
Handle<WasmTableObject> table_obj =
WasmTableObject::New(isolate_, table.type, table.initial_size,
table.has_maximum_size, table.maximum_size, nullptr);
WasmTableObject::AddDispatchTable(isolate_, table_obj, instance_object_,
table_index);
if (function_indexes) {
for (uint32_t i = 0; i < table_size; ++i) {
WasmFunction& function = test_module_->functions[function_indexes[i]];
int sig_id = test_module_->signature_map.Find(*function.sig);
IndirectFunctionTableEntry(instance, table_index, i)
.Set(sig_id, instance, function.func_index);
WasmTableObject::SetFunctionTablePlaceholder(
isolate_, table_obj, i, instance_object_, function_indexes[i]);
}
}
Handle<FixedArray> old_tables(instance_object_->tables(), isolate_);
Handle<FixedArray> new_tables =
isolate_->factory()->CopyFixedArrayAndGrow(old_tables, 1);
new_tables->set(old_tables->length(), *table_obj);
instance_object_->set_tables(*new_tables);
}
uint32_t TestingModuleBuilder::AddBytes(Vector<const byte> bytes) {
Vector<const uint8_t> old_bytes = native_module_->wire_bytes();
uint32_t old_size = static_cast<uint32_t>(old_bytes.size());
// Avoid placing strings at offset 0, this might be interpreted as "not
// set", e.g. for function names.
uint32_t bytes_offset = old_size ? old_size : 1;
size_t new_size = bytes_offset + bytes.size();
OwnedVector<uint8_t> new_bytes = OwnedVector<uint8_t>::New(new_size);
if (old_size > 0) {
memcpy(new_bytes.start(), old_bytes.begin(), old_size);
} else {
// Set the unused byte. It is never decoded, but the bytes are used as the
// key in the native module cache.
new_bytes[0] = 0;
}
memcpy(new_bytes.start() + bytes_offset, bytes.begin(), bytes.length());
native_module_->SetWireBytes(std::move(new_bytes));
return bytes_offset;
}
uint32_t TestingModuleBuilder::AddException(const FunctionSig* sig) {
DCHECK_EQ(0, sig->return_count());
uint32_t index = static_cast<uint32_t>(test_module_->exceptions.size());
test_module_->exceptions.push_back(WasmException{sig});
Handle<WasmExceptionTag> tag = WasmExceptionTag::New(isolate_, index);
Handle<FixedArray> table(instance_object_->exceptions_table(), isolate_);
table = isolate_->factory()->CopyFixedArrayAndGrow(table, 1);
instance_object_->set_exceptions_table(*table);
table->set(index, *tag);
return index;
}
uint32_t TestingModuleBuilder::AddPassiveDataSegment(Vector<const byte> bytes) {
uint32_t index = static_cast<uint32_t>(test_module_->data_segments.size());
DCHECK_EQ(index, test_module_->data_segments.size());
DCHECK_EQ(index, data_segment_starts_.size());
DCHECK_EQ(index, data_segment_sizes_.size());
// Add a passive data segment. This isn't used by function compilation, but
// but it keeps the index in sync. The data segment's source will not be
// correct, since we don't store data in the module wire bytes.
test_module_->data_segments.emplace_back();
// The num_declared_data_segments (from the DataCount section) is used
// to validate the segment index, during function compilation.
test_module_->num_declared_data_segments = index + 1;
Address old_data_address =
reinterpret_cast<Address>(data_segment_data_.data());
size_t old_data_size = data_segment_data_.size();
data_segment_data_.resize(old_data_size + bytes.length());
Address new_data_address =
reinterpret_cast<Address>(data_segment_data_.data());
memcpy(data_segment_data_.data() + old_data_size, bytes.begin(),
bytes.length());
// The data_segment_data_ offset may have moved, so update all the starts.
for (Address& start : data_segment_starts_) {
start += new_data_address - old_data_address;
}
data_segment_starts_.push_back(new_data_address + old_data_size);
data_segment_sizes_.push_back(bytes.length());
// The vector pointers may have moved, so update the instance object.
instance_object_->set_data_segment_starts(data_segment_starts_.data());
instance_object_->set_data_segment_sizes(data_segment_sizes_.data());
return index;
}
uint32_t TestingModuleBuilder::AddPassiveElementSegment(
const std::vector<uint32_t>& entries) {
uint32_t index = static_cast<uint32_t>(test_module_->elem_segments.size());
DCHECK_EQ(index, dropped_elem_segments_.size());
test_module_->elem_segments.emplace_back(false);
auto& elem_segment = test_module_->elem_segments.back();
elem_segment.entries = entries;
// The vector pointers may have moved, so update the instance object.
dropped_elem_segments_.push_back(0);
instance_object_->set_dropped_elem_segments(dropped_elem_segments_.data());
return index;
}
CompilationEnv TestingModuleBuilder::CreateCompilationEnv() {
// This is a hack so we don't need to call
// trap_handler::IsTrapHandlerEnabled().
const bool is_trap_handler_enabled =
V8_TRAP_HANDLER_SUPPORTED && i::FLAG_wasm_trap_handler;
return {test_module_ptr_,
is_trap_handler_enabled ? kUseTrapHandler : kNoTrapHandler,
runtime_exception_support_, enabled_features_, lower_simd()};
}
const WasmGlobal* TestingModuleBuilder::AddGlobal(ValueType type) {
byte size = type.element_size_bytes();
global_offset = (global_offset + size - 1) & ~(size - 1); // align
test_module_->globals.push_back(
{type, true, WasmInitExpr(), {global_offset}, false, false});
global_offset += size;
// limit number of globals.
CHECK_LT(global_offset, kMaxGlobalsSize);
return &test_module_->globals.back();
}
Handle<WasmInstanceObject> TestingModuleBuilder::InitInstanceObject() {
const bool kUsesLiftoff = true;
size_t code_size_estimate =
wasm::WasmCodeManager::EstimateNativeModuleCodeSize(test_module_.get(),
kUsesLiftoff);
auto native_module = isolate_->wasm_engine()->NewNativeModule(
isolate_, enabled_features_, test_module_, code_size_estimate);
native_module->SetWireBytes(OwnedVector<const uint8_t>());
Handle<Script> script =
isolate_->wasm_engine()->GetOrCreateScript(isolate_, native_module);
Handle<WasmModuleObject> module_object =
WasmModuleObject::New(isolate_, std::move(native_module), script);
// This method is called when we initialize TestEnvironment. We don't
// have a memory yet, so we won't create it here. We'll update the
// interpreter when we get a memory. We do have globals, though.
native_module_ = module_object->native_module();
native_module_->ReserveCodeTableForTesting(kMaxFunctions);
auto instance = WasmInstanceObject::New(isolate_, module_object);
instance->set_exceptions_table(*isolate_->factory()->empty_fixed_array());
instance->set_globals_start(globals_data_);
return instance;
}
void TestBuildingGraphWithBuilder(compiler::WasmGraphBuilder* builder,
Zone* zone, const FunctionSig* sig,
const byte* start, const byte* end) {
WasmFeatures unused_detected_features;
FunctionBody body(sig, 0, start, end);
DecodeResult result =
BuildTFGraph(zone->allocator(), WasmFeatures::All(), nullptr, builder,
&unused_detected_features, body, nullptr);
if (result.failed()) {
#ifdef DEBUG
if (!FLAG_trace_wasm_decoder) {
// Retry the compilation with the tracing flag on, to help in debugging.
FLAG_trace_wasm_decoder = true;
result = BuildTFGraph(zone->allocator(), WasmFeatures::All(), nullptr,
builder, &unused_detected_features, body, nullptr);
}
#endif
FATAL("Verification failed; pc = +%x, msg = %s", result.error().offset(),
result.error().message().c_str());
}
builder->LowerInt64(compiler::WasmGraphBuilder::kCalledFromWasm);
if (!CpuFeatures::SupportsWasmSimd128()) {
builder->SimdScalarLoweringForTesting();
}
}
void TestBuildingGraph(Zone* zone, compiler::JSGraph* jsgraph,
CompilationEnv* module, const FunctionSig* sig,
compiler::SourcePositionTable* source_position_table,
const byte* start, const byte* end) {
compiler::WasmGraphBuilder builder(module, zone, jsgraph, sig,
source_position_table);
TestBuildingGraphWithBuilder(&builder, zone, sig, start, end);
}
WasmFunctionWrapper::WasmFunctionWrapper(Zone* zone, int num_params)
: GraphAndBuilders(zone),
inner_code_node_(nullptr),
context_address_(nullptr),
signature_(nullptr) {
// One additional parameter for the pointer to the return value memory.
Signature<MachineType>::Builder sig_builder(zone, 1, num_params + 1);
sig_builder.AddReturn(MachineType::Int32());
for (int i = 0; i < num_params + 1; i++) {
sig_builder.AddParam(MachineType::Pointer());
}
signature_ = sig_builder.Build();
}
void WasmFunctionWrapper::Init(CallDescriptor* call_descriptor,
MachineType return_type,
Vector<MachineType> param_types) {
DCHECK_NOT_NULL(call_descriptor);
DCHECK_EQ(signature_->parameter_count(), param_types.length() + 1);
// Create the TF graph for the wrapper.
// Function, context_address, effect, and control.
Node** parameters = zone()->NewArray<Node*>(param_types.length() + 4);
int start_value_output_count =
static_cast<int>(signature_->parameter_count()) + 1;
graph()->SetStart(
graph()->NewNode(common()->Start(start_value_output_count)));
Node* effect = graph()->start();
int parameter_count = 0;
// Dummy node which gets replaced in SetInnerCode.
inner_code_node_ = graph()->NewNode(common()->Int32Constant(0));
parameters[parameter_count++] = inner_code_node_;
// Dummy node that gets replaced in SetContextAddress.
context_address_ = graph()->NewNode(IntPtrConstant(0));
parameters[parameter_count++] = context_address_;
int param_idx = 0;
for (MachineType t : param_types) {
DCHECK_NE(MachineType::None(), t);
parameters[parameter_count] = graph()->NewNode(
machine()->Load(t),
graph()->NewNode(common()->Parameter(param_idx++), graph()->start()),
graph()->NewNode(common()->Int32Constant(0)), effect, graph()->start());
effect = parameters[parameter_count++];
}
parameters[parameter_count++] = effect;
parameters[parameter_count++] = graph()->start();
Node* call = graph()->NewNode(common()->Call(call_descriptor),
parameter_count, parameters);
if (!return_type.IsNone()) {
effect = graph()->NewNode(
machine()->Store(compiler::StoreRepresentation(
return_type.representation(),
compiler::WriteBarrierKind::kNoWriteBarrier)),
graph()->NewNode(common()->Parameter(param_types.length()),
graph()->start()),
graph()->NewNode(common()->Int32Constant(0)), call, effect,
graph()->start());
}
Node* zero = graph()->NewNode(common()->Int32Constant(0));
Node* r = graph()->NewNode(
common()->Return(), zero,
graph()->NewNode(common()->Int32Constant(WASM_WRAPPER_RETURN_VALUE)),
effect, graph()->start());
graph()->SetEnd(graph()->NewNode(common()->End(1), r));
}
Handle<Code> WasmFunctionWrapper::GetWrapperCode() {
Handle<Code> code;
if (!code_.ToHandle(&code)) {
Isolate* isolate = CcTest::InitIsolateOnce();
auto call_descriptor = compiler::Linkage::GetSimplifiedCDescriptor(
zone(), signature_, CallDescriptor::kInitializeRootRegister);
if (kSystemPointerSize == 4) {
size_t num_params = signature_->parameter_count();
// One additional parameter for the pointer of the return value.
Signature<MachineRepresentation>::Builder rep_builder(zone(), 1,
num_params + 1);
rep_builder.AddReturn(MachineRepresentation::kWord32);
for (size_t i = 0; i < num_params + 1; i++) {
rep_builder.AddParam(MachineRepresentation::kWord32);
}
compiler::Int64Lowering r(graph(), machine(), common(), zone(),
rep_builder.Build());
r.LowerGraph();
}
OptimizedCompilationInfo info(ArrayVector("testing"), graph()->zone(),
Code::C_WASM_ENTRY);
code_ = compiler::Pipeline::GenerateCodeForTesting(
&info, isolate, call_descriptor, graph(),
AssemblerOptions::Default(isolate));
code = code_.ToHandleChecked();
#ifdef ENABLE_DISASSEMBLER
if (FLAG_print_opt_code) {
CodeTracer::Scope tracing_scope(isolate->GetCodeTracer());
OFStream os(tracing_scope.file());
code->Disassemble("wasm wrapper", os, isolate);
}
#endif
}
return code;
}
void WasmFunctionCompiler::Build(const byte* start, const byte* end) {
size_t locals_size = local_decls.Size();
size_t total_size = end - start + locals_size + 1;
byte* buffer = static_cast<byte*>(zone()->New(total_size));
// Prepend the local decls to the code.
local_decls.Emit(buffer);
// Emit the code.
memcpy(buffer + locals_size, start, end - start);
// Append an extra end opcode.
buffer[total_size - 1] = kExprEnd;
start = buffer;
end = buffer + total_size;
CHECK_GE(kMaxInt, end - start);
int len = static_cast<int>(end - start);
function_->code = {builder_->AddBytes(Vector<const byte>(start, len)),
static_cast<uint32_t>(len)};
if (interpreter_) {
// Add the code to the interpreter; do not generate compiled code.
interpreter_->SetFunctionCodeForTesting(function_, start, end);
return;
}
Vector<const uint8_t> wire_bytes = builder_->instance_object()
->module_object()
.native_module()
->wire_bytes();
CompilationEnv env = builder_->CreateCompilationEnv();
ScopedVector<uint8_t> func_wire_bytes(function_->code.length());
memcpy(func_wire_bytes.begin(), wire_bytes.begin() + function_->code.offset(),
func_wire_bytes.length());
FunctionBody func_body{function_->sig, function_->code.offset(),
func_wire_bytes.begin(), func_wire_bytes.end()};
NativeModule* native_module =
builder_->instance_object()->module_object().native_module();
WasmCompilationUnit unit(function_->func_index, builder_->execution_tier(),
kNoDebugging);
WasmFeatures unused_detected_features;
WasmCompilationResult result = unit.ExecuteCompilation(
isolate()->wasm_engine(), &env,
native_module->compilation_state()->GetWireBytesStorage(),
isolate()->counters(), &unused_detected_features);
WasmCode* code = native_module->PublishCode(
native_module->AddCompiledCode(std::move(result)));
DCHECK_NOT_NULL(code);
if (WasmCode::ShouldBeLogged(isolate())) code->LogCode(isolate());
}
WasmFunctionCompiler::WasmFunctionCompiler(Zone* zone, const FunctionSig* sig,
TestingModuleBuilder* builder,
const char* name)
: GraphAndBuilders(zone),
jsgraph(builder->isolate(), this->graph(), this->common(), nullptr,
nullptr, this->machine()),
sig(sig),
descriptor_(nullptr),
builder_(builder),
local_decls(zone, sig),
source_position_table_(this->graph()),
interpreter_(builder->interpreter()) {
// Get a new function from the testing module.
int index = builder->AddFunction(sig, name, TestingModuleBuilder::kWasm);
function_ = builder_->GetFunctionAt(index);
}
WasmFunctionCompiler::~WasmFunctionCompiler() = default;
/* static */
FunctionSig* WasmRunnerBase::CreateSig(Zone* zone, MachineType return_type,
Vector<MachineType> param_types) {
int return_count = return_type.IsNone() ? 0 : 1;
int param_count = param_types.length();
// Allocate storage array in zone.
ValueType* sig_types = zone->NewArray<ValueType>(return_count + param_count);
// Convert machine types to local types, and check that there are no
// MachineType::None()'s in the parameters.
int idx = 0;
if (return_count) sig_types[idx++] = ValueType::For(return_type);
for (MachineType param : param_types) {
CHECK_NE(MachineType::None(), param);
sig_types[idx++] = ValueType::For(param);
}
return new (zone) FunctionSig(return_count, param_count, sig_types);
}
// static
bool WasmRunnerBase::trap_happened;
} // namespace wasm
} // namespace internal
} // namespace v8