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cobalt / cobalt / ef837fa448402e2ada2fb3821210cc20d850164b / . / src / v8 / src / wasm / wasm-module-builder.cc
blob: 997496bb2916465289bc0bdbc6123f6f8dcffbfc [file] [log] [blame]
// Copyright 2015 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/signature.h"
#include "src/handles.h"
#include "src/objects-inl.h"
#include "src/v8.h"
#include "src/zone/zone-containers.h"
#include "src/wasm/function-body-decoder.h"
#include "src/wasm/leb-helper.h"
#include "src/wasm/module-decoder.h"
#include "src/wasm/wasm-module-builder.h"
#include "src/wasm/wasm-module.h"
#include "src/wasm/wasm-opcodes.h"
#include "src/v8memory.h"
namespace v8 {
namespace internal {
namespace wasm {
namespace {
// Emit a section code and the size as a padded varint that can be patched
// later.
size_t EmitSection(SectionCode code, ZoneBuffer& buffer) {
// Emit the section code.
buffer.write_u8(code);
// Emit a placeholder for the length.
return buffer.reserve_u32v();
}
// Patch the size of a section after it's finished.
void FixupSection(ZoneBuffer& buffer, size_t start) {
buffer.patch_u32v(start, static_cast<uint32_t>(buffer.offset() - start -
kPaddedVarInt32Size));
}
} // namespace
WasmFunctionBuilder::WasmFunctionBuilder(WasmModuleBuilder* builder)
: builder_(builder),
locals_(builder->zone()),
signature_index_(0),
func_index_(static_cast<uint32_t>(builder->functions_.size())),
body_(builder->zone(), 256),
i32_temps_(builder->zone()),
i64_temps_(builder->zone()),
f32_temps_(builder->zone()),
f64_temps_(builder->zone()),
direct_calls_(builder->zone()),
asm_offsets_(builder->zone(), 8) {}
void WasmFunctionBuilder::EmitI32V(int32_t val) { body_.write_i32v(val); }
void WasmFunctionBuilder::EmitU32V(uint32_t val) { body_.write_u32v(val); }
void WasmFunctionBuilder::SetSignature(FunctionSig* sig) {
DCHECK(!locals_.has_sig());
locals_.set_sig(sig);
signature_index_ = builder_->AddSignature(sig);
}
uint32_t WasmFunctionBuilder::AddLocal(ValueType type) {
DCHECK(locals_.has_sig());
return locals_.AddLocals(1, type);
}
void WasmFunctionBuilder::EmitGetLocal(uint32_t local_index) {
EmitWithU32V(kExprGetLocal, local_index);
}
void WasmFunctionBuilder::EmitSetLocal(uint32_t local_index) {
EmitWithU32V(kExprSetLocal, local_index);
}
void WasmFunctionBuilder::EmitTeeLocal(uint32_t local_index) {
EmitWithU32V(kExprTeeLocal, local_index);
}
void WasmFunctionBuilder::EmitCode(const byte* code, uint32_t code_size) {
body_.write(code, code_size);
}
void WasmFunctionBuilder::Emit(WasmOpcode opcode) { body_.write_u8(opcode); }
void WasmFunctionBuilder::EmitWithU8(WasmOpcode opcode, const byte immediate) {
body_.write_u8(opcode);
body_.write_u8(immediate);
}
void WasmFunctionBuilder::EmitWithU8U8(WasmOpcode opcode, const byte imm1,
const byte imm2) {
body_.write_u8(opcode);
body_.write_u8(imm1);
body_.write_u8(imm2);
}
void WasmFunctionBuilder::EmitWithI32V(WasmOpcode opcode, int32_t immediate) {
body_.write_u8(opcode);
body_.write_i32v(immediate);
}
void WasmFunctionBuilder::EmitWithU32V(WasmOpcode opcode, uint32_t immediate) {
body_.write_u8(opcode);
body_.write_u32v(immediate);
}
void WasmFunctionBuilder::EmitI32Const(int32_t value) {
EmitWithI32V(kExprI32Const, value);
}
void WasmFunctionBuilder::EmitI64Const(int64_t value) {
body_.write_u8(kExprI64Const);
body_.write_i64v(value);
}
void WasmFunctionBuilder::EmitF32Const(float value) {
body_.write_u8(kExprF32Const);
body_.write_f32(value);
}
void WasmFunctionBuilder::EmitF64Const(double value) {
body_.write_u8(kExprF64Const);
body_.write_f64(value);
}
void WasmFunctionBuilder::EmitDirectCallIndex(uint32_t index) {
DirectCallIndex call;
call.offset = body_.size();
call.direct_index = index;
direct_calls_.push_back(call);
byte placeholder_bytes[kMaxVarInt32Size] = {0};
EmitCode(placeholder_bytes, arraysize(placeholder_bytes));
}
void WasmFunctionBuilder::SetName(Vector<const char> name) { name_ = name; }
void WasmFunctionBuilder::AddAsmWasmOffset(int call_position,
int to_number_position) {
// We only want to emit one mapping per byte offset.
DCHECK(asm_offsets_.size() == 0 || body_.size() > last_asm_byte_offset_);
DCHECK_LE(body_.size(), kMaxUInt32);
uint32_t byte_offset = static_cast<uint32_t>(body_.size());
asm_offsets_.write_u32v(byte_offset - last_asm_byte_offset_);
last_asm_byte_offset_ = byte_offset;
DCHECK_GE(call_position, 0);
asm_offsets_.write_i32v(call_position - last_asm_source_position_);
DCHECK_GE(to_number_position, 0);
asm_offsets_.write_i32v(to_number_position - call_position);
last_asm_source_position_ = to_number_position;
}
void WasmFunctionBuilder::SetAsmFunctionStartPosition(int position) {
DCHECK_EQ(0, asm_func_start_source_position_);
DCHECK_LE(0, position);
// Must be called before emitting any asm.js source position.
DCHECK_EQ(0, asm_offsets_.size());
asm_func_start_source_position_ = position;
last_asm_source_position_ = position;
}
void WasmFunctionBuilder::DeleteCodeAfter(size_t position) {
DCHECK_LE(position, body_.size());
body_.Truncate(position);
}
void WasmFunctionBuilder::WriteSignature(ZoneBuffer& buffer) const {
buffer.write_u32v(signature_index_);
}
void WasmFunctionBuilder::WriteBody(ZoneBuffer& buffer) const {
size_t locals_size = locals_.Size();
buffer.write_size(locals_size + body_.size());
buffer.EnsureSpace(locals_size);
byte** ptr = buffer.pos_ptr();
locals_.Emit(*ptr);
(*ptr) += locals_size; // UGLY: manual bump of position pointer
if (body_.size() > 0) {
size_t base = buffer.offset();
buffer.write(body_.begin(), body_.size());
for (DirectCallIndex call : direct_calls_) {
buffer.patch_u32v(
base + call.offset,
call.direct_index +
static_cast<uint32_t>(builder_->function_imports_.size()));
}
}
}
void WasmFunctionBuilder::WriteAsmWasmOffsetTable(ZoneBuffer& buffer) const {
if (asm_func_start_source_position_ == 0 && asm_offsets_.size() == 0) {
buffer.write_size(0);
return;
}
size_t locals_enc_size = LEBHelper::sizeof_u32v(locals_.Size());
size_t func_start_size =
LEBHelper::sizeof_u32v(asm_func_start_source_position_);
buffer.write_size(asm_offsets_.size() + locals_enc_size + func_start_size);
// Offset of the recorded byte offsets.
DCHECK_GE(kMaxUInt32, locals_.Size());
buffer.write_u32v(static_cast<uint32_t>(locals_.Size()));
// Start position of the function.
buffer.write_u32v(asm_func_start_source_position_);
buffer.write(asm_offsets_.begin(), asm_offsets_.size());
}
WasmModuleBuilder::WasmModuleBuilder(Zone* zone)
: zone_(zone),
signatures_(zone),
function_imports_(zone),
function_exports_(zone),
global_imports_(zone),
functions_(zone),
data_segments_(zone),
indirect_functions_(zone),
globals_(zone),
signature_map_(zone),
start_function_index_(-1),
min_memory_size_(16),
max_memory_size_(0),
has_max_memory_size_(false),
has_shared_memory_(false) {}
WasmFunctionBuilder* WasmModuleBuilder::AddFunction(FunctionSig* sig) {
functions_.push_back(new (zone_) WasmFunctionBuilder(this));
// Add the signature if one was provided here.
if (sig) functions_.back()->SetSignature(sig);
return functions_.back();
}
void WasmModuleBuilder::AddDataSegment(const byte* data, uint32_t size,
uint32_t dest) {
data_segments_.push_back({ZoneVector<byte>(zone()), dest});
ZoneVector<byte>& vec = data_segments_.back().data;
for (uint32_t i = 0; i < size; i++) {
vec.push_back(data[i]);
}
}
bool WasmModuleBuilder::CompareFunctionSigs::operator()(FunctionSig* a,
FunctionSig* b) const {
if (a->return_count() < b->return_count()) return true;
if (a->return_count() > b->return_count()) return false;
if (a->parameter_count() < b->parameter_count()) return true;
if (a->parameter_count() > b->parameter_count()) return false;
for (size_t r = 0; r < a->return_count(); r++) {
if (a->GetReturn(r) < b->GetReturn(r)) return true;
if (a->GetReturn(r) > b->GetReturn(r)) return false;
}
for (size_t p = 0; p < a->parameter_count(); p++) {
if (a->GetParam(p) < b->GetParam(p)) return true;
if (a->GetParam(p) > b->GetParam(p)) return false;
}
return false;
}
uint32_t WasmModuleBuilder::AddSignature(FunctionSig* sig) {
SignatureMap::iterator pos = signature_map_.find(sig);
if (pos != signature_map_.end()) {
return pos->second;
} else {
uint32_t index = static_cast<uint32_t>(signatures_.size());
signature_map_[sig] = index;
signatures_.push_back(sig);
return index;
}
}
uint32_t WasmModuleBuilder::AllocateIndirectFunctions(uint32_t count) {
uint32_t index = static_cast<uint32_t>(indirect_functions_.size());
DCHECK_GE(FLAG_wasm_max_table_size, index);
if (count > FLAG_wasm_max_table_size - index) {
return std::numeric_limits<uint32_t>::max();
}
indirect_functions_.resize(indirect_functions_.size() + count);
return index;
}
void WasmModuleBuilder::SetIndirectFunction(uint32_t indirect,
uint32_t direct) {
indirect_functions_[indirect] = direct;
}
uint32_t WasmModuleBuilder::AddImport(Vector<const char> name,
FunctionSig* sig) {
function_imports_.push_back({name, AddSignature(sig)});
return static_cast<uint32_t>(function_imports_.size() - 1);
}
uint32_t WasmModuleBuilder::AddGlobalImport(Vector<const char> name,
ValueType type) {
global_imports_.push_back({name, WasmOpcodes::ValueTypeCodeFor(type)});
return static_cast<uint32_t>(global_imports_.size() - 1);
}
void WasmModuleBuilder::MarkStartFunction(WasmFunctionBuilder* function) {
start_function_index_ = function->func_index();
}
void WasmModuleBuilder::AddExport(Vector<const char> name,
WasmFunctionBuilder* function) {
function_exports_.push_back({name, function->func_index()});
}
uint32_t WasmModuleBuilder::AddGlobal(ValueType type, bool exported,
bool mutability,
const WasmInitExpr& init) {
globals_.push_back({type, exported, mutability, init});
return static_cast<uint32_t>(globals_.size() - 1);
}
void WasmModuleBuilder::SetMinMemorySize(uint32_t value) {
min_memory_size_ = value;
}
void WasmModuleBuilder::SetMaxMemorySize(uint32_t value) {
has_max_memory_size_ = true;
max_memory_size_ = value;
}
void WasmModuleBuilder::SetHasSharedMemory() { has_shared_memory_ = true; }
void WasmModuleBuilder::WriteTo(ZoneBuffer& buffer) const {
// == Emit magic =============================================================
buffer.write_u32(kWasmMagic);
buffer.write_u32(kWasmVersion);
// == Emit signatures ========================================================
if (signatures_.size() > 0) {
size_t start = EmitSection(kTypeSectionCode, buffer);
buffer.write_size(signatures_.size());
for (FunctionSig* sig : signatures_) {
buffer.write_u8(kWasmFunctionTypeForm);
buffer.write_size(sig->parameter_count());
for (auto param : sig->parameters()) {
buffer.write_u8(WasmOpcodes::ValueTypeCodeFor(param));
}
buffer.write_size(sig->return_count());
for (auto ret : sig->returns()) {
buffer.write_u8(WasmOpcodes::ValueTypeCodeFor(ret));
}
}
FixupSection(buffer, start);
}
// == Emit imports ===========================================================
if (global_imports_.size() + function_imports_.size() > 0) {
size_t start = EmitSection(kImportSectionCode, buffer);
buffer.write_size(global_imports_.size() + function_imports_.size());
for (auto import : global_imports_) {
buffer.write_u32v(0); // module name (length)
buffer.write_string(import.name); // field name
buffer.write_u8(kExternalGlobal);
buffer.write_u8(import.type_code);
buffer.write_u8(0); // immutable
}
for (auto import : function_imports_) {
buffer.write_u32v(0); // module name (length)
buffer.write_string(import.name); // field name
buffer.write_u8(kExternalFunction);
buffer.write_u32v(import.sig_index);
}
FixupSection(buffer, start);
}
// == Emit function signatures ===============================================
uint32_t num_function_names = 0;
if (functions_.size() > 0) {
size_t start = EmitSection(kFunctionSectionCode, buffer);
buffer.write_size(functions_.size());
for (auto function : functions_) {
function->WriteSignature(buffer);
if (!function->name_.is_empty()) ++num_function_names;
}
FixupSection(buffer, start);
}
// == emit function table ====================================================
if (indirect_functions_.size() > 0) {
size_t start = EmitSection(kTableSectionCode, buffer);
buffer.write_u8(1); // table count
buffer.write_u8(kWasmAnyFunctionTypeForm);
buffer.write_u8(kResizableMaximumFlag);
buffer.write_size(indirect_functions_.size());
buffer.write_size(indirect_functions_.size());
FixupSection(buffer, start);
}
// == emit memory declaration ================================================
{
size_t start = EmitSection(kMemorySectionCode, buffer);
buffer.write_u8(1); // memory count
if (has_shared_memory_) {
buffer.write_u8(has_max_memory_size_ ? MemoryFlags::kSharedAndMaximum
: MemoryFlags::kSharedNoMaximum);
} else {
buffer.write_u8(has_max_memory_size_ ? MemoryFlags::kMaximum
: MemoryFlags::kNoMaximum);
}
buffer.write_u32v(min_memory_size_);
if (has_max_memory_size_) {
buffer.write_u32v(max_memory_size_);
}
FixupSection(buffer, start);
}
// == Emit globals ===========================================================
if (globals_.size() > 0) {
size_t start = EmitSection(kGlobalSectionCode, buffer);
buffer.write_size(globals_.size());
for (auto global : globals_) {
buffer.write_u8(WasmOpcodes::ValueTypeCodeFor(global.type));
buffer.write_u8(global.mutability ? 1 : 0);
switch (global.init.kind) {
case WasmInitExpr::kI32Const:
DCHECK_EQ(kWasmI32, global.type);
buffer.write_u8(kExprI32Const);
buffer.write_i32v(global.init.val.i32_const);
break;
case WasmInitExpr::kI64Const:
DCHECK_EQ(kWasmI64, global.type);
buffer.write_u8(kExprI64Const);
buffer.write_i64v(global.init.val.i64_const);
break;
case WasmInitExpr::kF32Const:
DCHECK_EQ(kWasmF32, global.type);
buffer.write_u8(kExprF32Const);
buffer.write_f32(global.init.val.f32_const);
break;
case WasmInitExpr::kF64Const:
DCHECK_EQ(kWasmF64, global.type);
buffer.write_u8(kExprF64Const);
buffer.write_f64(global.init.val.f64_const);
break;
case WasmInitExpr::kGlobalIndex:
buffer.write_u8(kExprGetGlobal);
buffer.write_u32v(global.init.val.global_index);
break;
default: {
// No initializer, emit a default value.
switch (global.type) {
case kWasmI32:
buffer.write_u8(kExprI32Const);
// LEB encoding of 0.
buffer.write_u8(0);
break;
case kWasmI64:
buffer.write_u8(kExprI64Const);
// LEB encoding of 0.
buffer.write_u8(0);
break;
case kWasmF32:
buffer.write_u8(kExprF32Const);
buffer.write_f32(0.f);
break;
case kWasmF64:
buffer.write_u8(kExprF64Const);
buffer.write_f64(0.);
break;
default:
UNREACHABLE();
}
}
}
buffer.write_u8(kExprEnd);
}
FixupSection(buffer, start);
}
// == emit exports ===========================================================
if (!function_exports_.empty()) {
size_t start = EmitSection(kExportSectionCode, buffer);
buffer.write_size(function_exports_.size());
for (auto function_export : function_exports_) {
buffer.write_string(function_export.name);
buffer.write_u8(kExternalFunction);
buffer.write_size(function_export.function_index +
function_imports_.size());
}
FixupSection(buffer, start);
}
// == emit start function index ==============================================
if (start_function_index_ >= 0) {
size_t start = EmitSection(kStartSectionCode, buffer);
buffer.write_size(start_function_index_ + function_imports_.size());
FixupSection(buffer, start);
}
// == emit function table elements ===========================================
if (indirect_functions_.size() > 0) {
size_t start = EmitSection(kElementSectionCode, buffer);
buffer.write_u8(1); // count of entries
buffer.write_u8(0); // table index
buffer.write_u8(kExprI32Const); // offset
buffer.write_u32v(0);
buffer.write_u8(kExprEnd);
buffer.write_size(indirect_functions_.size()); // element count
for (auto index : indirect_functions_) {
buffer.write_size(index + function_imports_.size());
}
FixupSection(buffer, start);
}
// == emit code ==============================================================
if (functions_.size() > 0) {
size_t start = EmitSection(kCodeSectionCode, buffer);
buffer.write_size(functions_.size());
for (auto function : functions_) {
function->WriteBody(buffer);
}
FixupSection(buffer, start);
}
// == emit data segments =====================================================
if (data_segments_.size() > 0) {
size_t start = EmitSection(kDataSectionCode, buffer);
buffer.write_size(data_segments_.size());
for (auto segment : data_segments_) {
buffer.write_u8(0); // linear memory segment
buffer.write_u8(kExprI32Const); // initializer expression for dest
buffer.write_u32v(segment.dest);
buffer.write_u8(kExprEnd);
buffer.write_u32v(static_cast<uint32_t>(segment.data.size()));
buffer.write(&segment.data[0], segment.data.size());
}
FixupSection(buffer, start);
}
// == Emit names =============================================================
if (num_function_names > 0 || !function_imports_.empty()) {
// Emit the section code.
buffer.write_u8(kUnknownSectionCode);
// Emit a placeholder for the length.
size_t start = buffer.reserve_u32v();
// Emit the section string.
buffer.write_size(4);
buffer.write(reinterpret_cast<const byte*>("name"), 4);
// Emit a subsection for the function names.
buffer.write_u8(NameSectionType::kFunction);
// Emit a placeholder for the subsection length.
size_t functions_start = buffer.reserve_u32v();
// Emit the function names.
// Imports are always named.
uint32_t num_imports = static_cast<uint32_t>(function_imports_.size());
buffer.write_size(num_imports + num_function_names);
uint32_t function_index = 0;
for (; function_index < num_imports; ++function_index) {
const WasmFunctionImport* import = &function_imports_[function_index];
DCHECK(!import->name.is_empty());
buffer.write_u32v(function_index);
buffer.write_string(import->name);
}
if (num_function_names > 0) {
for (auto function : functions_) {
DCHECK_EQ(function_index,
function->func_index() + function_imports_.size());
if (!function->name_.is_empty()) {
buffer.write_u32v(function_index);
buffer.write_string(function->name_);
}
++function_index;
}
}
FixupSection(buffer, functions_start);
FixupSection(buffer, start);
}
}
void WasmModuleBuilder::WriteAsmJsOffsetTable(ZoneBuffer& buffer) const {
// == Emit asm.js offset table ===============================================
buffer.write_size(functions_.size());
// Emit the offset table per function.
for (auto function : functions_) {
function->WriteAsmWasmOffsetTable(buffer);
}
// Append a 0 to indicate that this is an encoded table.
buffer.write_u8(0);
}
} // namespace wasm
} // namespace internal
} // namespace v8