Google Git
Sign in
chromium / v8 / v8 / cf138bd3d4499f01574a4007c5cfeb873012cd26 / . / src / wasm / c-api.cc
blob: 229c6142e48185ee27cf65e7ae8fd0c07d5dc073 [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.
// This implementation is originally from
// https://github.com/WebAssembly/wasm-c-api/:
// Copyright 2019 Andreas Rossberg
//
// Licensed under the Apache License, Version 2.0 (the "License");
// you may not use this file except in compliance with the License.
// You may obtain a copy of the License at
//
// http://www.apache.org/licenses/LICENSE-2.0
//
// Unless required by applicable law or agreed to in writing, software
// distributed under the License is distributed on an "AS IS" BASIS,
// WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
// See the License for the specific language governing permissions and
// limitations under the License.
#include <cstring>
#include <iostream>
#include "third_party/wasm-api/wasm.h"
#include "third_party/wasm-api/wasm.hh"
#include "include/libplatform/libplatform.h"
#include "include/v8.h"
#include "src/api/api-inl.h"
#include "src/wasm/leb-helper.h"
#include "src/wasm/module-instantiate.h"
#include "src/wasm/wasm-constants.h"
#include "src/wasm/wasm-objects.h"
#include "src/wasm/wasm-result.h"
#include "src/wasm/wasm-serialization.h"
// BEGIN FILE wasm-bin.cc
namespace wasm {
namespace bin {
////////////////////////////////////////////////////////////////////////////////
// Encoding
void encode_header(char*& ptr) {
std::memcpy(ptr,
"\x00"
"asm\x01\x00\x00\x00",
8);
ptr += 8;
}
void encode_size32(char*& ptr, size_t n) {
assert(n <= 0xffffffff);
for (int i = 0; i < 5; ++i) {
*ptr++ = (n & 0x7f) | (i == 4 ? 0x00 : 0x80);
n = n >> 7;
}
}
void encode_valtype(char*& ptr, const ValType* type) {
switch (type->kind()) {
case I32:
*ptr++ = 0x7f;
break;
case I64:
*ptr++ = 0x7e;
break;
case F32:
*ptr++ = 0x7d;
break;
case F64:
*ptr++ = 0x7c;
break;
case FUNCREF:
*ptr++ = 0x70;
break;
case ANYREF:
*ptr++ = 0x6f;
break;
default:
UNREACHABLE();
}
}
auto zero_size(const ValType* type) -> size_t {
switch (type->kind()) {
case I32:
return 1;
case I64:
return 1;
case F32:
return 4;
case F64:
return 8;
case FUNCREF:
return 0;
case ANYREF:
return 0;
default:
UNREACHABLE();
}
}
void encode_const_zero(char*& ptr, const ValType* type) {
switch (type->kind()) {
case I32:
*ptr++ = 0x41;
break;
case I64:
*ptr++ = 0x42;
break;
case F32:
*ptr++ = 0x43;
break;
case F64:
*ptr++ = 0x44;
break;
default:
UNREACHABLE();
}
for (size_t i = 0; i < zero_size(type); ++i) *ptr++ = 0;
}
auto wrapper(const FuncType* type) -> vec<byte_t> {
auto in_arity = type->params().size();
auto out_arity = type->results().size();
auto size = 39 + in_arity + out_arity;
auto binary = vec<byte_t>::make_uninitialized(size);
auto ptr = binary.get();
encode_header(ptr);
*ptr++ = i::wasm::kTypeSectionCode;
encode_size32(ptr, 12 + in_arity + out_arity); // size
*ptr++ = 1; // length
*ptr++ = i::wasm::kWasmFunctionTypeCode;
encode_size32(ptr, in_arity);
for (size_t i = 0; i < in_arity; ++i) {
encode_valtype(ptr, type->params()[i].get());
}
encode_size32(ptr, out_arity);
for (size_t i = 0; i < out_arity; ++i) {
encode_valtype(ptr, type->results()[i].get());
}
*ptr++ = i::wasm::kImportSectionCode;
*ptr++ = 5; // size
*ptr++ = 1; // length
*ptr++ = 0; // module length
*ptr++ = 0; // name length
*ptr++ = i::wasm::kExternalFunction;
*ptr++ = 0; // type index
*ptr++ = i::wasm::kExportSectionCode;
*ptr++ = 4; // size
*ptr++ = 1; // length
*ptr++ = 0; // name length
*ptr++ = i::wasm::kExternalFunction;
*ptr++ = 0; // func index
assert(ptr - binary.get() == static_cast<ptrdiff_t>(size));
return binary;
}
////////////////////////////////////////////////////////////////////////////////
// Decoding
// Numbers
auto u32(const byte_t*& pos) -> uint32_t {
uint32_t n = 0;
uint32_t shift = 0;
byte_t b;
do {
b = *pos++;
n += (b & 0x7f) << shift;
shift += 7;
} while ((b & 0x80) != 0);
return n;
}
auto u64(const byte_t*& pos) -> uint64_t {
uint64_t n = 0;
uint64_t shift = 0;
byte_t b;
do {
b = *pos++;
n += (b & 0x7f) << shift;
shift += 7;
} while ((b & 0x80) != 0);
return n;
}
void u32_skip(const byte_t*& pos) { bin::u32(pos); }
// Names
auto name(const byte_t*& pos) -> Name {
auto size = bin::u32(pos);
auto start = pos;
auto name = Name::make_uninitialized(size);
std::memcpy(name.get(), start, size);
pos += size;
return name;
}
// Types
auto valtype(const byte_t*& pos) -> own<wasm::ValType*> {
switch (*pos++) {
case i::wasm::kLocalI32:
return ValType::make(I32);
case i::wasm::kLocalI64:
return ValType::make(I64);
case i::wasm::kLocalF32:
return ValType::make(F32);
case i::wasm::kLocalF64:
return ValType::make(F64);
case i::wasm::kLocalAnyFunc:
return ValType::make(FUNCREF);
case i::wasm::kLocalAnyRef:
return ValType::make(ANYREF);
default:
// TODO(wasm+): support new value types
UNREACHABLE();
}
return {};
}
auto mutability(const byte_t*& pos) -> Mutability {
return *pos++ ? VAR : CONST;
}
auto limits(const byte_t*& pos) -> Limits {
auto tag = *pos++;
auto min = bin::u32(pos);
if ((tag & 0x01) == 0) {
return Limits(min);
} else {
auto max = bin::u32(pos);
return Limits(min, max);
}
}
auto stacktype(const byte_t*& pos) -> vec<ValType*> {
size_t size = bin::u32(pos);
auto v = vec<ValType*>::make_uninitialized(size);
for (uint32_t i = 0; i < size; ++i) v[i] = bin::valtype(pos);
return v;
}
auto functype(const byte_t*& pos) -> own<FuncType*> {
assert(*pos == i::wasm::kWasmFunctionTypeCode);
++pos;
auto params = bin::stacktype(pos);
auto results = bin::stacktype(pos);
return FuncType::make(std::move(params), std::move(results));
}
auto globaltype(const byte_t*& pos) -> own<GlobalType*> {
auto content = bin::valtype(pos);
auto mutability = bin::mutability(pos);
return GlobalType::make(std::move(content), mutability);
}
auto tabletype(const byte_t*& pos) -> own<TableType*> {
auto elem = bin::valtype(pos);
auto limits = bin::limits(pos);
return TableType::make(std::move(elem), limits);
}
auto memorytype(const byte_t*& pos) -> own<MemoryType*> {
auto limits = bin::limits(pos);
return MemoryType::make(limits);
}
// Expressions
void expr_skip(const byte_t*& pos) {
switch (*pos++) {
case i::wasm::kExprI32Const:
case i::wasm::kExprI64Const:
case i::wasm::kExprGetGlobal: {
bin::u32_skip(pos);
} break;
case i::wasm::kExprF32Const: {
pos += 4;
} break;
case i::wasm::kExprF64Const: {
pos += 8;
} break;
default: {
// TODO(wasm+): support new expression forms
UNREACHABLE();
}
}
++pos; // end
}
// Sections
auto section(const vec<const byte_t>& binary, i::wasm::SectionCode sec)
-> const byte_t* {
const byte_t* end = binary.get() + binary.size();
const byte_t* pos = binary.get() + 8; // skip header
while (pos < end && *pos++ != sec) {
auto size = bin::u32(pos);
pos += size;
}
if (pos == end) return nullptr;
bin::u32_skip(pos);
return pos;
}
// Only for asserts/DCHECKs.
auto section_end(const vec<const byte_t>& binary, i::wasm::SectionCode sec)
-> const byte_t* {
const byte_t* end = binary.get() + binary.size();
const byte_t* pos = binary.get() + 8; // skip header
while (pos < end && *pos != sec) {
++pos;
auto size = bin::u32(pos);
pos += size;
}
if (pos == end) return nullptr;
++pos;
auto size = bin::u32(pos);
return pos + size;
}
// Type section
auto types(const vec<const byte_t>& binary) -> vec<FuncType*> {
auto pos = bin::section(binary, i::wasm::kTypeSectionCode);
if (pos == nullptr) return vec<FuncType*>::make();
size_t size = bin::u32(pos);
// TODO(wasm+): support new deftypes
auto v = vec<FuncType*>::make_uninitialized(size);
for (uint32_t i = 0; i < size; ++i) {
v[i] = bin::functype(pos);
}
assert(pos == bin::section_end(binary, i::wasm::kTypeSectionCode));
return v;
}
// Import section
auto imports(const vec<const byte_t>& binary, const vec<FuncType*>& types)
-> vec<ImportType*> {
auto pos = bin::section(binary, i::wasm::kImportSectionCode);
if (pos == nullptr) return vec<ImportType*>::make();
size_t size = bin::u32(pos);
auto v = vec<ImportType*>::make_uninitialized(size);
for (uint32_t i = 0; i < size; ++i) {
auto module = bin::name(pos);
auto name = bin::name(pos);
own<ExternType*> type;
switch (*pos++) {
case i::wasm::kExternalFunction:
type = types[bin::u32(pos)]->copy();
break;
case i::wasm::kExternalTable:
type = bin::tabletype(pos);
break;
case i::wasm::kExternalMemory:
type = bin::memorytype(pos);
break;
case i::wasm::kExternalGlobal:
type = bin::globaltype(pos);
break;
default:
UNREACHABLE();
}
v[i] =
ImportType::make(std::move(module), std::move(name), std::move(type));
}
assert(pos == bin::section_end(binary, i::wasm::kImportSectionCode));
return v;
}
auto count(const vec<ImportType*>& imports, ExternKind kind) -> uint32_t {
uint32_t n = 0;
for (uint32_t i = 0; i < imports.size(); ++i) {
if (imports[i]->type()->kind() == kind) ++n;
}
return n;
}
// Function section
auto funcs(const vec<const byte_t>& binary, const vec<ImportType*>& imports,
const vec<FuncType*>& types) -> vec<FuncType*> {
auto pos = bin::section(binary, i::wasm::kFunctionSectionCode);
size_t size = pos != nullptr ? bin::u32(pos) : 0;
auto v =
vec<FuncType*>::make_uninitialized(size + count(imports, EXTERN_FUNC));
size_t j = 0;
for (uint32_t i = 0; i < imports.size(); ++i) {
auto et = imports[i]->type();
if (et->kind() == EXTERN_FUNC) {
v[j++] = et->func()->copy();
}
}
if (pos != nullptr) {
for (; j < v.size(); ++j) {
v[j] = types[bin::u32(pos)]->copy();
}
assert(pos == bin::section_end(binary, i::wasm::kFunctionSectionCode));
}
return v;
}
// Global section
auto globals(const vec<const byte_t>& binary, const vec<ImportType*>& imports)
-> vec<GlobalType*> {
auto pos = bin::section(binary, i::wasm::kGlobalSectionCode);
size_t size = pos != nullptr ? bin::u32(pos) : 0;
auto v = vec<GlobalType*>::make_uninitialized(size +
count(imports, EXTERN_GLOBAL));
size_t j = 0;
for (uint32_t i = 0; i < imports.size(); ++i) {
auto et = imports[i]->type();
if (et->kind() == EXTERN_GLOBAL) {
v[j++] = et->global()->copy();
}
}
if (pos != nullptr) {
for (; j < v.size(); ++j) {
v[j] = bin::globaltype(pos);
expr_skip(pos);
}
assert(pos == bin::section_end(binary, i::wasm::kGlobalSectionCode));
}
return v;
}
// Table section
auto tables(const vec<const byte_t>& binary, const vec<ImportType*>& imports)
-> vec<TableType*> {
auto pos = bin::section(binary, i::wasm::kTableSectionCode);
size_t size = pos != nullptr ? bin::u32(pos) : 0;
auto v =
vec<TableType*>::make_uninitialized(size + count(imports, EXTERN_TABLE));
size_t j = 0;
for (uint32_t i = 0; i < imports.size(); ++i) {
auto et = imports[i]->type();
if (et->kind() == EXTERN_TABLE) {
v[j++] = et->table()->copy();
}
}
if (pos != nullptr) {
for (; j < v.size(); ++j) {
v[j] = bin::tabletype(pos);
}
assert(pos == bin::section_end(binary, i::wasm::kTableSectionCode));
}
return v;
}
// Memory section
auto memories(const vec<const byte_t>& binary, const vec<ImportType*>& imports)
-> vec<MemoryType*> {
auto pos = bin::section(binary, i::wasm::kMemorySectionCode);
size_t size = pos != nullptr ? bin::u32(pos) : 0;
auto v = vec<MemoryType*>::make_uninitialized(size +
count(imports, EXTERN_MEMORY));
size_t j = 0;
for (uint32_t i = 0; i < imports.size(); ++i) {
auto et = imports[i]->type();
if (et->kind() == EXTERN_MEMORY) {
v[j++] = et->memory()->copy();
}
}
if (pos != nullptr) {
for (; j < v.size(); ++j) {
v[j] = bin::memorytype(pos);
}
assert(pos == bin::section_end(binary, i::wasm::kMemorySectionCode));
}
return v;
}
// Export section
auto exports(const vec<const byte_t>& binary, const vec<FuncType*>& funcs,
const vec<GlobalType*>& globals, const vec<TableType*>& tables,
const vec<MemoryType*>& memories) -> vec<ExportType*> {
auto pos = bin::section(binary, i::wasm::kExportSectionCode);
if (pos == nullptr) return vec<ExportType*>::make();
size_t size = bin::u32(pos);
auto exports = vec<ExportType*>::make_uninitialized(size);
for (uint32_t i = 0; i < size; ++i) {
auto name = bin::name(pos);
auto tag = *pos++;
auto index = bin::u32(pos);
own<ExternType*> type;
switch (tag) {
case i::wasm::kExternalFunction:
type = funcs[index]->copy();
break;
case i::wasm::kExternalTable:
type = tables[index]->copy();
break;
case i::wasm::kExternalMemory:
type = memories[index]->copy();
break;
case i::wasm::kExternalGlobal:
type = globals[index]->copy();
break;
default:
UNREACHABLE();
}
exports[i] = ExportType::make(std::move(name), std::move(type));
}
assert(pos == bin::section_end(binary, i::wasm::kExportSectionCode));
return exports;
}
auto imports(const vec<const byte_t>& binary) -> vec<ImportType*> {
return bin::imports(binary, bin::types(binary));
}
auto exports(const vec<const byte_t>& binary) -> vec<ExportType*> {
auto types = bin::types(binary);
auto imports = bin::imports(binary, types);
auto funcs = bin::funcs(binary, imports, types);
auto globals = bin::globals(binary, imports);
auto tables = bin::tables(binary, imports);
auto memories = bin::memories(binary, imports);
return bin::exports(binary, funcs, globals, tables, memories);
}
} // namespace bin
} // namespace wasm
// BEGIN FILE wasm-v8-lowlevel.cc
namespace v8 {
namespace wasm {
// Foreign pointers
auto foreign_new(v8::Isolate* isolate, void* ptr) -> v8::Local<v8::Value> {
auto foreign = v8::FromCData(reinterpret_cast<i::Isolate*>(isolate),
reinterpret_cast<i::Address>(ptr));
return v8::Utils::ToLocal(foreign);
}
auto foreign_get(v8::Local<v8::Value> val) -> void* {
auto foreign = v8::Utils::OpenHandle(*val);
if (!foreign->IsForeign()) return nullptr;
auto addr = v8::ToCData<i::Address>(*foreign);
return reinterpret_cast<void*>(addr);
}
// Types
auto v8_valtype_to_wasm(i::wasm::ValueType v8_valtype) -> ::wasm::ValKind {
switch (v8_valtype) {
case i::wasm::kWasmI32:
return ::wasm::I32;
case i::wasm::kWasmI64:
return ::wasm::I64;
case i::wasm::kWasmF32:
return ::wasm::F32;
case i::wasm::kWasmF64:
return ::wasm::F64;
default:
// TODO(wasm+): support new value types
UNREACHABLE();
}
}
i::wasm::ValueType wasm_valtype_to_v8(::wasm::ValKind type) {
switch (type) {
case ::wasm::I32:
return i::wasm::kWasmI32;
case ::wasm::I64:
return i::wasm::kWasmI64;
case ::wasm::F32:
return i::wasm::kWasmF32;
case ::wasm::F64:
return i::wasm::kWasmF64;
default:
// TODO(wasm+): support new value types
UNREACHABLE();
}
}
} // namespace wasm
} // namespace v8
/// BEGIN FILE wasm-v8.cc
namespace wasm {
///////////////////////////////////////////////////////////////////////////////
// Auxiliaries
[[noreturn]] void WASM_UNIMPLEMENTED(const char* s) {
std::cerr << "Wasm API: " << s << " not supported yet!\n";
exit(1);
}
template <class T>
void ignore(T) {}
template <class C>
struct implement;
template <class C>
auto impl(C* x) -> typename implement<C>::type* {
return reinterpret_cast<typename implement<C>::type*>(x);
}
template <class C>
auto impl(const C* x) -> const typename implement<C>::type* {
return reinterpret_cast<const typename implement<C>::type*>(x);
}
template <class C>
auto seal(typename implement<C>::type* x) -> C* {
return reinterpret_cast<C*>(x);
}
template <class C>
auto seal(const typename implement<C>::type* x) -> const C* {
return reinterpret_cast<const C*>(x);
}
#ifdef DEBUG
template <class T>
void vec<T>::make_data() {}
template <class T>
void vec<T>::free_data() {}
#endif
///////////////////////////////////////////////////////////////////////////////
// Runtime Environment
// Configuration
struct ConfigImpl {
ConfigImpl() {}
~ConfigImpl() {}
};
template <>
struct implement<Config> {
using type = ConfigImpl;
};
Config::~Config() { impl(this)->~ConfigImpl(); }
void Config::operator delete(void* p) { ::operator delete(p); }
auto Config::make() -> own<Config*> {
return own<Config*>(seal<Config>(new (std::nothrow) ConfigImpl()));
}
// Engine
struct EngineImpl {
static bool created;
std::unique_ptr<v8::Platform> platform;
EngineImpl() {
assert(!created);
created = true;
}
~EngineImpl() {
v8::V8::Dispose();
v8::V8::ShutdownPlatform();
}
};
bool EngineImpl::created = false;
template <>
struct implement<Engine> {
using type = EngineImpl;
};
Engine::~Engine() { impl(this)->~EngineImpl(); }
void Engine::operator delete(void* p) { ::operator delete(p); }
auto Engine::make(own<Config*>&& config) -> own<Engine*> {
i::FLAG_expose_gc = true;
i::FLAG_experimental_wasm_bigint = true;
i::FLAG_experimental_wasm_mv = true;
auto engine = new (std::nothrow) EngineImpl;
if (!engine) return own<Engine*>();
engine->platform = v8::platform::NewDefaultPlatform();
v8::V8::InitializePlatform(engine->platform.get());
v8::V8::Initialize();
return make_own(seal<Engine>(engine));
}
// Stores
class StoreImpl {
friend own<Store*> Store::make(Engine*);
v8::Isolate::CreateParams create_params_;
v8::Isolate* isolate_;
v8::Eternal<v8::Context> context_;
public:
StoreImpl() {}
~StoreImpl() {
#ifdef DEBUG
reinterpret_cast<i::Isolate*>(isolate_)->heap()->PreciseCollectAllGarbage(
i::Heap::kNoGCFlags, i::GarbageCollectionReason::kTesting,
v8::kGCCallbackFlagForced);
#endif
context()->Exit();
isolate_->Exit();
isolate_->Dispose();
delete create_params_.array_buffer_allocator;
}
auto isolate() const -> v8::Isolate* { return isolate_; }
i::Isolate* i_isolate() const {
return reinterpret_cast<i::Isolate*>(isolate_);
}
auto context() const -> v8::Local<v8::Context> {
return context_.Get(isolate_);
}
static auto get(i::Isolate* isolate) -> StoreImpl* {
return static_cast<StoreImpl*>(
reinterpret_cast<v8::Isolate*>(isolate)->GetData(0));
}
};
template <>
struct implement<Store> {
using type = StoreImpl;
};
Store::~Store() { impl(this)->~StoreImpl(); }
void Store::operator delete(void* p) { ::operator delete(p); }
auto Store::make(Engine*) -> own<Store*> {
auto store = make_own(new (std::nothrow) StoreImpl());
if (!store) return own<Store*>();
// Create isolate.
store->create_params_.array_buffer_allocator =
v8::ArrayBuffer::Allocator::NewDefaultAllocator();
auto isolate = v8::Isolate::New(store->create_params_);
if (!isolate) return own<Store*>();
{
v8::Isolate::Scope isolate_scope(isolate);
v8::HandleScope handle_scope(isolate);
// Create context.
auto context = v8::Context::New(isolate);
if (context.IsEmpty()) return own<Store*>();
v8::Context::Scope context_scope(context);
store->isolate_ = isolate;
store->context_ = v8::Eternal<v8::Context>(isolate, context);
}
store->isolate()->Enter();
store->context()->Enter();
isolate->SetData(0, store.get());
return make_own(seal<Store>(store.release()));
}
///////////////////////////////////////////////////////////////////////////////
// Type Representations
// Value Types
struct ValTypeImpl {
ValKind kind;
explicit ValTypeImpl(ValKind kind) : kind(kind) {}
};
template <>
struct implement<ValType> {
using type = ValTypeImpl;
};
ValTypeImpl* valtypes[] = {
new ValTypeImpl(I32), new ValTypeImpl(I64), new ValTypeImpl(F32),
new ValTypeImpl(F64), new ValTypeImpl(ANYREF), new ValTypeImpl(FUNCREF),
};
ValType::~ValType() {}
void ValType::operator delete(void*) {}
auto ValType::make(ValKind k) -> own<ValType*> {
auto result = seal<ValType>(valtypes[k]);
return own<ValType*>(result);
}
auto ValType::copy() const -> own<ValType*> { return make(kind()); }
auto ValType::kind() const -> ValKind { return impl(this)->kind; }
// Extern Types
struct ExternTypeImpl {
ExternKind kind;
explicit ExternTypeImpl(ExternKind kind) : kind(kind) {}
virtual ~ExternTypeImpl() {}
};
template <>
struct implement<ExternType> {
using type = ExternTypeImpl;
};
ExternType::~ExternType() { impl(this)->~ExternTypeImpl(); }
void ExternType::operator delete(void* p) { ::operator delete(p); }
auto ExternType::copy() const -> own<ExternType*> {
switch (kind()) {
case EXTERN_FUNC:
return func()->copy();
case EXTERN_GLOBAL:
return global()->copy();
case EXTERN_TABLE:
return table()->copy();
case EXTERN_MEMORY:
return memory()->copy();
}
}
auto ExternType::kind() const -> ExternKind { return impl(this)->kind; }
// Function Types
struct FuncTypeImpl : ExternTypeImpl {
vec<ValType*> params;
vec<ValType*> results;
FuncTypeImpl(vec<ValType*>& params, vec<ValType*>& results)
: ExternTypeImpl(EXTERN_FUNC),
params(std::move(params)),
results(std::move(results)) {}
~FuncTypeImpl() {}
};
template <>
struct implement<FuncType> {
using type = FuncTypeImpl;
};
FuncType::~FuncType() {}
auto FuncType::make(vec<ValType*>&& params, vec<ValType*>&& results)
-> own<FuncType*> {
return params && results
? own<FuncType*>(seal<FuncType>(new (std::nothrow)
FuncTypeImpl(params, results)))
: own<FuncType*>();
}
auto FuncType::copy() const -> own<FuncType*> {
return make(params().copy(), results().copy());
}
auto FuncType::params() const -> const vec<ValType*>& {
return impl(this)->params;
}
auto FuncType::results() const -> const vec<ValType*>& {
return impl(this)->results;
}
auto ExternType::func() -> FuncType* {
return kind() == EXTERN_FUNC
? seal<FuncType>(static_cast<FuncTypeImpl*>(impl(this)))
: nullptr;
}
auto ExternType::func() const -> const FuncType* {
return kind() == EXTERN_FUNC
? seal<FuncType>(static_cast<const FuncTypeImpl*>(impl(this)))
: nullptr;
}
// Global Types
struct GlobalTypeImpl : ExternTypeImpl {
own<ValType*> content;
Mutability mutability;
GlobalTypeImpl(own<ValType*>& content, Mutability mutability)
: ExternTypeImpl(EXTERN_GLOBAL),
content(std::move(content)),
mutability(mutability) {}
~GlobalTypeImpl() {}
};
template <>
struct implement<GlobalType> {
using type = GlobalTypeImpl;
};
GlobalType::~GlobalType() {}
auto GlobalType::make(own<ValType*>&& content, Mutability mutability)
-> own<GlobalType*> {
return content ? own<GlobalType*>(seal<GlobalType>(
new (std::nothrow) GlobalTypeImpl(content, mutability)))
: own<GlobalType*>();
}
auto GlobalType::copy() const -> own<GlobalType*> {
return make(content()->copy(), mutability());
}
auto GlobalType::content() const -> const ValType* {
return impl(this)->content.get();
}
auto GlobalType::mutability() const -> Mutability {
return impl(this)->mutability;
}
auto ExternType::global() -> GlobalType* {
return kind() == EXTERN_GLOBAL
? seal<GlobalType>(static_cast<GlobalTypeImpl*>(impl(this)))
: nullptr;
}
auto ExternType::global() const -> const GlobalType* {
return kind() == EXTERN_GLOBAL
? seal<GlobalType>(static_cast<const GlobalTypeImpl*>(impl(this)))
: nullptr;
}
// Table Types
struct TableTypeImpl : ExternTypeImpl {
own<ValType*> element;
Limits limits;
TableTypeImpl(own<ValType*>& element, Limits limits)
: ExternTypeImpl(EXTERN_TABLE),
element(std::move(element)),
limits(limits) {}
~TableTypeImpl() {}
};
template <>
struct implement<TableType> {
using type = TableTypeImpl;
};
TableType::~TableType() {}
auto TableType::make(own<ValType*>&& element, Limits limits)
-> own<TableType*> {
return element ? own<TableType*>(seal<TableType>(
new (std::nothrow) TableTypeImpl(element, limits)))
: own<TableType*>();
}
auto TableType::copy() const -> own<TableType*> {
return make(element()->copy(), limits());
}
auto TableType::element() const -> const ValType* {
return impl(this)->element.get();
}
auto TableType::limits() const -> const Limits& { return impl(this)->limits; }
auto ExternType::table() -> TableType* {
return kind() == EXTERN_TABLE
? seal<TableType>(static_cast<TableTypeImpl*>(impl(this)))
: nullptr;
}
auto ExternType::table() const -> const TableType* {
return kind() == EXTERN_TABLE
? seal<TableType>(static_cast<const TableTypeImpl*>(impl(this)))
: nullptr;
}
// Memory Types
struct MemoryTypeImpl : ExternTypeImpl {
Limits limits;
explicit MemoryTypeImpl(Limits limits)
: ExternTypeImpl(EXTERN_MEMORY), limits(limits) {}
~MemoryTypeImpl() {}
};
template <>
struct implement<MemoryType> {
using type = MemoryTypeImpl;
};
MemoryType::~MemoryType() {}
auto MemoryType::make(Limits limits) -> own<MemoryType*> {
return own<MemoryType*>(
seal<MemoryType>(new (std::nothrow) MemoryTypeImpl(limits)));
}
auto MemoryType::copy() const -> own<MemoryType*> {
return MemoryType::make(limits());
}
auto MemoryType::limits() const -> const Limits& { return impl(this)->limits; }
auto ExternType::memory() -> MemoryType* {
return kind() == EXTERN_MEMORY
? seal<MemoryType>(static_cast<MemoryTypeImpl*>(impl(this)))
: nullptr;
}
auto ExternType::memory() const -> const MemoryType* {
return kind() == EXTERN_MEMORY
? seal<MemoryType>(static_cast<const MemoryTypeImpl*>(impl(this)))
: nullptr;
}
// Import Types
struct ImportTypeImpl {
Name module;
Name name;
own<ExternType*> type;
ImportTypeImpl(Name& module, Name& name, own<ExternType*>& type)
: module(std::move(module)),
name(std::move(name)),
type(std::move(type)) {}
~ImportTypeImpl() {}
};
template <>
struct implement<ImportType> {
using type = ImportTypeImpl;
};
ImportType::~ImportType() { impl(this)->~ImportTypeImpl(); }
void ImportType::operator delete(void* p) { ::operator delete(p); }
auto ImportType::make(Name&& module, Name&& name, own<ExternType*>&& type)
-> own<ImportType*> {
return module && name && type
? own<ImportType*>(seal<ImportType>(
new (std::nothrow) ImportTypeImpl(module, name, type)))
: own<ImportType*>();
}
auto ImportType::copy() const -> own<ImportType*> {
return make(module().copy(), name().copy(), type()->copy());
}
auto ImportType::module() const -> const Name& { return impl(this)->module; }
auto ImportType::name() const -> const Name& { return impl(this)->name; }
auto ImportType::type() const -> const ExternType* {
return impl(this)->type.get();
}
// Export Types
struct ExportTypeImpl {
Name name;
own<ExternType*> type;
ExportTypeImpl(Name& name, own<ExternType*>& type)
: name(std::move(name)), type(std::move(type)) {}
~ExportTypeImpl() {}
};
template <>
struct implement<ExportType> {
using type = ExportTypeImpl;
};
ExportType::~ExportType() { impl(this)->~ExportTypeImpl(); }
void ExportType::operator delete(void* p) { ::operator delete(p); }
auto ExportType::make(Name&& name, own<ExternType*>&& type)
-> own<ExportType*> {
return name && type ? own<ExportType*>(seal<ExportType>(
new (std::nothrow) ExportTypeImpl(name, type)))
: own<ExportType*>();
}
auto ExportType::copy() const -> own<ExportType*> {
return make(name().copy(), type()->copy());
}
auto ExportType::name() const -> const Name& { return impl(this)->name; }
auto ExportType::type() const -> const ExternType* {
return impl(this)->type.get();
}
///////////////////////////////////////////////////////////////////////////////
// Conversions of values from and to V8 objects
auto val_to_v8(StoreImpl* store, const Val& v) -> v8::Local<v8::Value> {
auto isolate = store->isolate();
switch (v.kind()) {
case I32:
return v8::Integer::NewFromUnsigned(isolate, v.i32());
case I64:
return v8::BigInt::New(isolate, v.i64());
case F32:
return v8::Number::New(isolate, v.f32());
case F64:
return v8::Number::New(isolate, v.f64());
case ANYREF:
case FUNCREF: {
if (v.ref() == nullptr) {
return v8::Null(isolate);
} else {
WASM_UNIMPLEMENTED("ref value");
}
}
default:
UNREACHABLE();
}
}
own<Val> v8_to_val(i::Isolate* isolate, i::Handle<i::Object> value,
ValKind kind) {
switch (kind) {
case I32:
do {
if (value->IsSmi()) return Val(i::Smi::ToInt(*value));
if (value->IsHeapNumber()) {
return Val(i::DoubleToInt32(i::HeapNumber::cast(*value).value()));
}
value = i::Object::ToInt32(isolate, value).ToHandleChecked();
// This will loop back at most once.
} while (true);
UNREACHABLE();
case I64:
if (value->IsBigInt()) return Val(i::BigInt::cast(*value).AsInt64());
return Val(
i::BigInt::FromObject(isolate, value).ToHandleChecked()->AsInt64());
case F32:
do {
if (value->IsSmi()) {
return Val(static_cast<float32_t>(i::Smi::ToInt(*value)));
}
if (value->IsHeapNumber()) {
return Val(i::DoubleToFloat32(i::HeapNumber::cast(*value).value()));
}
value = i::Object::ToNumber(isolate, value).ToHandleChecked();
// This will loop back at most once.
} while (true);
UNREACHABLE();
case F64:
do {
if (value->IsSmi()) {
return Val(static_cast<float64_t>(i::Smi::ToInt(*value)));
}
if (value->IsHeapNumber()) {
return Val(i::HeapNumber::cast(*value).value());
}
value = i::Object::ToNumber(isolate, value).ToHandleChecked();
// This will loop back at most once.
} while (true);
UNREACHABLE();
case ANYREF:
case FUNCREF: {
if (value->IsNull(isolate)) {
return Val(nullptr);
} else {
WASM_UNIMPLEMENTED("ref value");
}
}
}
}
i::Handle<i::String> VecToString(i::Isolate* isolate,
const vec<byte_t>& chars) {
return isolate->factory()
->NewStringFromUtf8({chars.get(), chars.size()})
.ToHandleChecked();
}
// References
template <class Ref, class JSType>
class RefImpl {
public:
static own<Ref*> make(StoreImpl* store, i::Handle<JSType> obj) {
RefImpl* self = new (std::nothrow) RefImpl();
if (!self) return nullptr;
i::Isolate* isolate = store->i_isolate();
self->val_ = isolate->global_handles()->Create(*obj);
return make_own(seal<Ref>(self));
}
void Reset() {
i::GlobalHandles::Destroy(location());
if (host_data_) {
if (host_data_->finalizer) {
host_data_->finalizer(host_data_->info);
}
delete host_data_;
}
}
own<Ref*> copy() const { return make(store(), v8_object()); }
StoreImpl* store() const { return StoreImpl::get(isolate()); }
i::Isolate* isolate() const { return val_->GetIsolate(); }
i::Handle<JSType> v8_object() const { return i::Handle<JSType>::cast(val_); }
void* get_host_info() const {
if (host_data_ == nullptr) return nullptr;
return host_data_->info;
}
void set_host_info(void* info, void (*finalizer)(void*)) {
host_data_ = new HostData(location(), info, finalizer);
i::GlobalHandles::MakeWeak(host_data_->location, host_data_, &v8_finalizer,
v8::WeakCallbackType::kParameter);
}
private:
struct HostData {
HostData(i::Address* location, void* info, void (*finalizer)(void*))
: location(location), info(info), finalizer(finalizer) {}
i::Address* location;
void* info;
void (*finalizer)(void*);
};
RefImpl() {}
static void v8_finalizer(const v8::WeakCallbackInfo<void>& info) {
HostData* data = reinterpret_cast<HostData*>(info.GetParameter());
i::GlobalHandles::Destroy(data->location);
if (data->finalizer) (*data->finalizer)(data->info);
delete data;
}
i::Address* location() const {
return reinterpret_cast<i::Address*>(val_.address());
}
i::Handle<i::JSReceiver> val_;
HostData* host_data_ = nullptr;
};
template <>
struct implement<Ref> {
using type = RefImpl<Ref, i::JSReceiver>;
};
Ref::~Ref() {
impl(this)->Reset();
delete impl(this);
}
void Ref::operator delete(void* p) {}
auto Ref::copy() const -> own<Ref*> { return impl(this)->copy(); }
auto Ref::get_host_info() const -> void* { return impl(this)->get_host_info(); }
void Ref::set_host_info(void* info, void (*finalizer)(void*)) {
impl(this)->set_host_info(info, finalizer);
}
///////////////////////////////////////////////////////////////////////////////
// Runtime Objects
// Traps
template <>
struct implement<Trap> {
using type = RefImpl<Trap, i::JSReceiver>;
};
Trap::~Trap() {}
auto Trap::copy() const -> own<Trap*> { return impl(this)->copy(); }
auto Trap::make(Store* store_abs, const Message& message) -> own<Trap*> {
auto store = impl(store_abs);
i::Isolate* isolate = store->i_isolate();
i::HandleScope handle_scope(isolate);
i::Handle<i::String> string = VecToString(isolate, message);
i::Handle<i::JSReceiver> exception = i::Handle<i::JSReceiver>::cast(
isolate->factory()->NewError(isolate->error_function(), string));
return implement<Trap>::type::make(store, exception);
}
auto Trap::message() const -> Message {
auto isolate = impl(this)->isolate();
i::HandleScope handle_scope(isolate);
i::Handle<i::JSMessageObject> message =
isolate->CreateMessage(impl(this)->v8_object(), nullptr);
i::Handle<i::String> result = i::MessageHandler::GetMessage(isolate, message);
result = i::String::Flatten(isolate, result); // For performance.
int length = 0;
std::unique_ptr<char[]> utf8 =
result->ToCString(i::DISALLOW_NULLS, i::FAST_STRING_TRAVERSAL, &length);
return vec<byte_t>::adopt(length, utf8.release());
}
// Foreign Objects
template <>
struct implement<Foreign> {
using type = RefImpl<Foreign, i::JSReceiver>;
};
Foreign::~Foreign() {}
auto Foreign::copy() const -> own<Foreign*> { return impl(this)->copy(); }
auto Foreign::make(Store* store_abs) -> own<Foreign*> {
auto store = impl(store_abs);
auto isolate = store->i_isolate();
i::HandleScope handle_scope(isolate);
auto obj = i::Handle<i::JSReceiver>();
return implement<Foreign>::type::make(store, obj);
}
// Modules
template <>
struct implement<Module> {
using type = RefImpl<Module, i::WasmModuleObject>;
};
Module::~Module() {}
auto Module::copy() const -> own<Module*> { return impl(this)->copy(); }
auto Module::validate(Store* store_abs, const vec<byte_t>& binary) -> bool {
i::wasm::ModuleWireBytes bytes(
{reinterpret_cast<const uint8_t*>(binary.get()), binary.size()});
i::Isolate* isolate = impl(store_abs)->i_isolate();
i::wasm::WasmFeatures features = i::wasm::WasmFeaturesFromIsolate(isolate);
return isolate->wasm_engine()->SyncValidate(isolate, features, bytes);
}
class NopErrorThrower : public i::wasm::ErrorThrower {
public:
explicit NopErrorThrower(i::Isolate* isolate)
: i::wasm::ErrorThrower(isolate, "ignored") {}
~NopErrorThrower() { Reset(); }
};
auto Module::make(Store* store_abs, const vec<byte_t>& binary) -> own<Module*> {
StoreImpl* store = impl(store_abs);
i::Isolate* isolate = store->i_isolate();
i::HandleScope scope(isolate);
i::wasm::ModuleWireBytes bytes(
{reinterpret_cast<const uint8_t*>(binary.get()), binary.size()});
i::wasm::WasmFeatures features = i::wasm::WasmFeaturesFromIsolate(isolate);
NopErrorThrower thrower(isolate);
i::Handle<i::WasmModuleObject> module;
if (!isolate->wasm_engine()
->SyncCompile(isolate, features, &thrower, bytes)
.ToHandle(&module)) {
return nullptr;
}
return implement<Module>::type::make(store, module);
}
auto Module::imports() const -> vec<ImportType*> {
i::Vector<const uint8_t> wire_bytes =
impl(this)->v8_object()->native_module()->wire_bytes();
vec<const byte_t> binary = vec<const byte_t>::adopt(
wire_bytes.size(), reinterpret_cast<const byte_t*>(wire_bytes.begin()));
auto imports = wasm::bin::imports(binary);
binary.release();
return imports;
}
vec<ExportType*> ExportsImpl(i::Handle<i::WasmModuleObject> module_obj) {
i::Vector<const uint8_t> wire_bytes =
module_obj->native_module()->wire_bytes();
vec<const byte_t> binary = vec<const byte_t>::adopt(
wire_bytes.size(), reinterpret_cast<const byte_t*>(wire_bytes.begin()));
auto exports = wasm::bin::exports(binary);
binary.release();
return exports;
}
auto Module::exports() const -> vec<ExportType*> {
return ExportsImpl(impl(this)->v8_object());
}
auto Module::serialize() const -> vec<byte_t> {
i::wasm::NativeModule* native_module =
impl(this)->v8_object()->native_module();
i::Vector<const uint8_t> wire_bytes = native_module->wire_bytes();
size_t binary_size = wire_bytes.size();
i::wasm::WasmSerializer serializer(native_module);
size_t serial_size = serializer.GetSerializedNativeModuleSize();
size_t size_size = i::wasm::LEBHelper::sizeof_u64v(binary_size);
vec<byte_t> buffer =
vec<byte_t>::make_uninitialized(size_size + binary_size + serial_size);
byte_t* ptr = buffer.get();
i::wasm::LEBHelper::write_u64v(reinterpret_cast<uint8_t**>(&ptr),
binary_size);
std::memcpy(ptr, wire_bytes.begin(), binary_size);
ptr += binary_size;
if (!serializer.SerializeNativeModule(
{reinterpret_cast<uint8_t*>(ptr), serial_size})) {
buffer.reset();
}
return std::move(buffer);
}
auto Module::deserialize(Store* store_abs, const vec<byte_t>& serialized)
-> own<Module*> {
StoreImpl* store = impl(store_abs);
i::Isolate* isolate = store->i_isolate();
i::HandleScope handle_scope(isolate);
const byte_t* ptr = serialized.get();
uint64_t binary_size = wasm::bin::u64(ptr);
ptrdiff_t size_size = ptr - serialized.get();
size_t serial_size = serialized.size() - size_size - binary_size;
i::Handle<i::WasmModuleObject> module_obj;
size_t data_size = static_cast<size_t>(binary_size);
if (!i::wasm::DeserializeNativeModule(
isolate,
{reinterpret_cast<const uint8_t*>(ptr + data_size), serial_size},
{reinterpret_cast<const uint8_t*>(ptr), data_size})
.ToHandle(&module_obj)) {
return nullptr;
}
return implement<Module>::type::make(store, module_obj);
}
// TODO(v8): do better when V8 can do better.
template <>
struct implement<Shared<Module>> {
using type = vec<byte_t>;
};
template <>
Shared<Module>::~Shared() {
impl(this)->~vec();
}
template <>
void Shared<Module>::operator delete(void* p) {
::operator delete(p);
}
auto Module::share() const -> own<Shared<Module>*> {
auto shared = seal<Shared<Module>>(new vec<byte_t>(serialize()));
return make_own(shared);
}
auto Module::obtain(Store* store, const Shared<Module>* shared)
-> own<Module*> {
return Module::deserialize(store, *impl(shared));
}
// Externals
template <>
struct implement<Extern> {
using type = RefImpl<Extern, i::JSReceiver>;
};
Extern::~Extern() {}
auto Extern::copy() const -> own<Extern*> { return impl(this)->copy(); }
auto Extern::kind() const -> ExternKind {
i::Handle<i::JSReceiver> obj = impl(this)->v8_object();
if (i::WasmExportedFunction::IsWasmExportedFunction(*obj)) {
return wasm::EXTERN_FUNC;
}
if (obj->IsWasmGlobalObject()) return wasm::EXTERN_GLOBAL;
if (obj->IsWasmTableObject()) return wasm::EXTERN_TABLE;
if (obj->IsWasmMemoryObject()) return wasm::EXTERN_MEMORY;
UNREACHABLE();
}
auto Extern::type() const -> own<ExternType*> {
switch (kind()) {
case EXTERN_FUNC:
return func()->type();
case EXTERN_GLOBAL:
return global()->type();
case EXTERN_TABLE:
return table()->type();
case EXTERN_MEMORY:
return memory()->type();
}
}
auto Extern::func() -> Func* {
return kind() == EXTERN_FUNC ? static_cast<Func*>(this) : nullptr;
}
auto Extern::global() -> Global* {
return kind() == EXTERN_GLOBAL ? static_cast<Global*>(this) : nullptr;
}
auto Extern::table() -> Table* {
return kind() == EXTERN_TABLE ? static_cast<Table*>(this) : nullptr;
}
auto Extern::memory() -> Memory* {
return kind() == EXTERN_MEMORY ? static_cast<Memory*>(this) : nullptr;
}
auto Extern::func() const -> const Func* {
return kind() == EXTERN_FUNC ? static_cast<const Func*>(this) : nullptr;
}
auto Extern::global() const -> const Global* {
return kind() == EXTERN_GLOBAL ? static_cast<const Global*>(this) : nullptr;
}
auto Extern::table() const -> const Table* {
return kind() == EXTERN_TABLE ? static_cast<const Table*>(this) : nullptr;
}
auto Extern::memory() const -> const Memory* {
return kind() == EXTERN_MEMORY ? static_cast<const Memory*>(this) : nullptr;
}
auto extern_to_v8(const Extern* ex) -> i::Handle<i::JSReceiver> {
return impl(ex)->v8_object();
}
// Function Instances
template <>
struct implement<Func> {
using type = RefImpl<Func, i::JSFunction>;
};
Func::~Func() {}
auto Func::copy() const -> own<Func*> { return impl(this)->copy(); }
struct FuncData {
Store* store;
own<FuncType*> type;
enum Kind { kCallback, kCallbackWithEnv } kind;
union {
Func::callback callback;
Func::callback_with_env callback_with_env;
};
void (*finalizer)(void*);
void* env;
FuncData(Store* store, const FuncType* type, Kind kind)
: store(store),
type(type->copy()),
kind(kind),
finalizer(nullptr),
env(nullptr) {}
~FuncData() {
if (finalizer) (*finalizer)(env);
}
static i::Address v8_callback(void* data, i::Address argv);
static void finalize_func_data(void* data);
};
namespace {
// TODO(jkummerow): Generalize for WasmExportedFunction and WasmCapiFunction.
class SignatureHelper : public i::AllStatic {
public:
// Use an invalid type as a marker separating params and results.
static const i::wasm::ValueType kMarker = i::wasm::kWasmStmt;
static i::Handle<i::PodArray<i::wasm::ValueType>> Serialize(
i::Isolate* isolate, FuncType* type) {
int sig_size =
static_cast<int>(type->params().size() + type->results().size() + 1);
i::Handle<i::PodArray<i::wasm::ValueType>> sig =
i::PodArray<i::wasm::ValueType>::New(isolate, sig_size,
i::AllocationType::kOld);
int index = 0;
// TODO(jkummerow): Consider making vec<> range-based for-iterable.
for (size_t i = 0; i < type->results().size(); i++) {
sig->set(index++,
v8::wasm::wasm_valtype_to_v8(type->results()[i]->kind()));
}
// {sig->set} needs to take the address of its second parameter,
// so we can't pass in the static const kMarker directly.
i::wasm::ValueType marker = kMarker;
sig->set(index++, marker);
for (size_t i = 0; i < type->params().size(); i++) {
sig->set(index++,
v8::wasm::wasm_valtype_to_v8(type->params()[i]->kind()));
}
return sig;
}
static own<FuncType*> Deserialize(i::PodArray<i::wasm::ValueType> sig) {
int result_arity = ResultArity(sig);
int param_arity = sig.length() - result_arity - 1;
vec<ValType*> results = vec<ValType*>::make_uninitialized(result_arity);
vec<ValType*> params = vec<ValType*>::make_uninitialized(param_arity);
int i = 0;
for (; i < sig.length(); ++i) {
results[i] = ValType::make(v8::wasm::v8_valtype_to_wasm(sig.get(i)));
}
i++;
for (; i < param_arity; ++i) {
params[i] = ValType::make(v8::wasm::v8_valtype_to_wasm(sig.get(i)));
}
return FuncType::make(std::move(params), std::move(results));
}
static int ResultArity(i::PodArray<i::wasm::ValueType> sig) {
int count = 0;
for (; count < sig.length(); count++) {
if (sig.get(count) == kMarker) return count;
}
UNREACHABLE();
}
static int ParamArity(i::PodArray<i::wasm::ValueType> sig) {
return sig.length() - ResultArity(sig) - 1;
}
static i::PodArray<i::wasm::ValueType> GetSig(
i::Handle<i::JSFunction> function) {
return i::WasmCapiFunction::cast(*function).GetSerializedSignature();
}
};
auto make_func(Store* store_abs, FuncData* data) -> own<Func*> {
auto store = impl(store_abs);
i::Isolate* isolate = store->i_isolate();
i::HandleScope handle_scope(isolate);
i::Handle<i::WasmCapiFunction> function = i::WasmCapiFunction::New(
isolate, reinterpret_cast<i::Address>(&FuncData::v8_callback), data,
SignatureHelper::Serialize(isolate, data->type.get()));
auto func = implement<Func>::type::make(store, function);
func->set_host_info(data, &FuncData::finalize_func_data);
return func;
}
} // namespace
auto Func::make(Store* store, const FuncType* type, Func::callback callback)
-> own<Func*> {
auto data = new FuncData(store, type, FuncData::kCallback);
data->callback = callback;
return make_func(store, data);
}
auto Func::make(Store* store, const FuncType* type, callback_with_env callback,
void* env, void (*finalizer)(void*)) -> own<Func*> {
auto data = new FuncData(store, type, FuncData::kCallbackWithEnv);
data->callback_with_env = callback;
data->env = env;
data->finalizer = finalizer;
return make_func(store, data);
}
auto Func::type() const -> own<FuncType*> {
i::Handle<i::JSFunction> func = impl(this)->v8_object();
if (i::WasmCapiFunction::IsWasmCapiFunction(*func)) {
return SignatureHelper::Deserialize(SignatureHelper::GetSig(func));
}
DCHECK(i::WasmExportedFunction::IsWasmExportedFunction(*func));
i::Handle<i::WasmExportedFunction> function =
i::Handle<i::WasmExportedFunction>::cast(func);
i::wasm::FunctionSig* sig =
function->instance().module()->functions[function->function_index()].sig;
uint32_t param_arity = static_cast<uint32_t>(sig->parameter_count());
uint32_t result_arity = static_cast<uint32_t>(sig->return_count());
auto params = vec<ValType*>::make_uninitialized(param_arity);
auto results = vec<ValType*>::make_uninitialized(result_arity);
for (size_t i = 0; i < params.size(); ++i) {
auto kind = v8::wasm::v8_valtype_to_wasm(sig->GetParam(i));
params[i] = ValType::make(kind);
}
for (size_t i = 0; i < results.size(); ++i) {
auto kind = v8::wasm::v8_valtype_to_wasm(sig->GetReturn(i));
results[i] = ValType::make(kind);
}
return FuncType::make(std::move(params), std::move(results));
}
auto Func::param_arity() const -> size_t {
i::Handle<i::JSFunction> func = impl(this)->v8_object();
if (i::WasmCapiFunction::IsWasmCapiFunction(*func)) {
return SignatureHelper::ParamArity(SignatureHelper::GetSig(func));
}
DCHECK(i::WasmExportedFunction::IsWasmExportedFunction(*func));
i::Handle<i::WasmExportedFunction> function =
i::Handle<i::WasmExportedFunction>::cast(func);
i::wasm::FunctionSig* sig =
function->instance().module()->functions[function->function_index()].sig;
return sig->parameter_count();
}
auto Func::result_arity() const -> size_t {
i::Handle<i::JSFunction> func = impl(this)->v8_object();
if (i::WasmCapiFunction::IsWasmCapiFunction(*func)) {
return SignatureHelper::ResultArity(SignatureHelper::GetSig(func));
}
DCHECK(i::WasmExportedFunction::IsWasmExportedFunction(*func));
i::Handle<i::WasmExportedFunction> function =
i::Handle<i::WasmExportedFunction>::cast(func);
i::wasm::FunctionSig* sig =
function->instance().module()->functions[function->function_index()].sig;
return sig->return_count();
}
auto Func::call(const Val args[], Val results[]) const -> own<Trap*> {
auto func = impl(this);
auto store = func->store();
auto isolate = store->isolate();
auto i_isolate = store->i_isolate();
v8::HandleScope handle_scope(isolate);
int num_params;
int num_results;
ValKind result_kind;
i::Handle<i::JSFunction> v8_func = func->v8_object();
if (i::WasmExportedFunction::IsWasmExportedFunction(*v8_func)) {
i::WasmExportedFunction wef = i::WasmExportedFunction::cast(*v8_func);
i::wasm::FunctionSig* sig =
wef.instance().module()->functions[wef.function_index()].sig;
num_params = static_cast<int>(sig->parameter_count());
num_results = static_cast<int>(sig->return_count());
if (num_results > 0) {
result_kind = v8::wasm::v8_valtype_to_wasm(sig->GetReturn(0));
}
#if DEBUG
for (int i = 0; i < num_params; i++) {
DCHECK_EQ(args[i].kind(), v8::wasm::v8_valtype_to_wasm(sig->GetParam(i)));
}
#endif
} else {
DCHECK(i::WasmCapiFunction::IsWasmCapiFunction(*v8_func));
UNIMPLEMENTED();
}
// TODO(rossberg): cache v8_args array per thread.
auto v8_args = std::unique_ptr<i::Handle<i::Object>[]>(
new (std::nothrow) i::Handle<i::Object>[num_params]);
for (int i = 0; i < num_params; ++i) {
v8_args[i] = v8::Utils::OpenHandle(*val_to_v8(store, args[i]));
}
// TODO(jkummerow): Use Execution::TryCall instead of manual TryCatch.
v8::TryCatch handler(isolate);
i::MaybeHandle<i::Object> maybe_val = i::Execution::Call(
i_isolate, func->v8_object(), i_isolate->factory()->undefined_value(),
num_params, v8_args.get());
if (handler.HasCaught()) {
i_isolate->OptionalRescheduleException(true);
i::Handle<i::Object> exception =
v8::Utils::OpenHandle(*handler.Exception());
if (!exception->IsJSReceiver()) {
i::MaybeHandle<i::String> maybe_string =
i::Object::ToString(i_isolate, exception);
i::Handle<i::String> string = maybe_string.is_null()
? i_isolate->factory()->empty_string()
: maybe_string.ToHandleChecked();
exception =
i_isolate->factory()->NewError(i_isolate->error_function(), string);
}
return implement<Trap>::type::make(
store, i::Handle<i::JSReceiver>::cast(exception));
}
auto val = maybe_val.ToHandleChecked();
if (num_results == 0) {
assert(val->IsUndefined(i_isolate));
} else if (num_results == 1) {
assert(!val->IsUndefined(i_isolate));
new (&results[0]) Val(v8_to_val(i_isolate, val, result_kind));
} else {
WASM_UNIMPLEMENTED("multiple results");
}
return nullptr;
}
i::Address FuncData::v8_callback(void* data, i::Address argv) {
FuncData* self = reinterpret_cast<FuncData*>(data);
const vec<ValType*>& param_types = self->type->params();
const vec<ValType*>& result_types = self->type->results();
int num_param_types = static_cast<int>(param_types.size());
int num_result_types = static_cast<int>(result_types.size());
std::unique_ptr<Val[]> params(new Val[num_param_types]);
std::unique_ptr<Val[]> results(new Val[num_result_types]);
i::Address p = argv;
for (int i = 0; i < num_param_types; ++i) {
switch (param_types[i]->kind()) {
case I32:
params[i] = Val(i::ReadUnalignedValue<int32_t>(p));
p += 4;
break;
case I64:
params[i] = Val(i::ReadUnalignedValue<int64_t>(p));
p += 8;
break;
case F32:
params[i] = Val(i::ReadUnalignedValue<float32_t>(p));
p += 4;
break;
case F64:
params[i] = Val(i::ReadUnalignedValue<float64_t>(p));
p += 8;
break;
case ANYREF:
case FUNCREF: {
i::Address raw = i::ReadUnalignedValue<i::Address>(p);
p += sizeof(raw);
if (raw == i::kNullAddress) {
params[i] = Val(nullptr);
} else {
i::JSReceiver raw_obj = i::JSReceiver::cast(i::Object(raw));
i::Handle<i::JSReceiver> obj(raw_obj, raw_obj.GetIsolate());
params[i] = Val(implement<Ref>::type::make(impl(self->store), obj));
}
break;
}
}
}
own<Trap*> trap;
if (self->kind == kCallbackWithEnv) {
trap = self->callback_with_env(self->env, params.get(), results.get());
} else {
trap = self->callback(params.get(), results.get());
}
if (trap) {
i::Isolate* isolate = impl(self->store)->i_isolate();
isolate->Throw(*impl(trap.get())->v8_object());
i::Object ex = isolate->pending_exception();
isolate->clear_pending_exception();
return ex.ptr();
}
p = argv;
for (int i = 0; i < num_result_types; ++i) {
switch (result_types[i]->kind()) {
case I32:
i::WriteUnalignedValue(p, results[i].i32());
p += 4;
break;
case I64:
i::WriteUnalignedValue(p, results[i].i64());
p += 8;
break;
case F32:
i::WriteUnalignedValue(p, results[i].f32());
p += 4;
break;
case F64:
i::WriteUnalignedValue(p, results[i].f64());
p += 8;
break;
case ANYREF:
case FUNCREF: {
if (results[i].ref() == nullptr) {
i::WriteUnalignedValue(p, i::kNullAddress);
} else {
i::WriteUnalignedValue(p, impl(results[i].ref())->v8_object()->ptr());
}
p += sizeof(i::Address);
break;
}
}
}
return i::kNullAddress;
}
void FuncData::finalize_func_data(void* data) {
delete reinterpret_cast<FuncData*>(data);
}
// Global Instances
template <>
struct implement<Global> {
using type = RefImpl<Global, i::WasmGlobalObject>;
};
Global::~Global() {}
auto Global::copy() const -> own<Global*> { return impl(this)->copy(); }
auto Global::make(Store* store_abs, const GlobalType* type, const Val& val)
-> own<Global*> {
StoreImpl* store = impl(store_abs);
i::Isolate* isolate = store->i_isolate();
i::HandleScope handle_scope(isolate);
DCHECK_EQ(type->content()->kind(), val.kind());
i::wasm::ValueType i_type =
v8::wasm::wasm_valtype_to_v8(type->content()->kind());
bool is_mutable = (type->mutability() == VAR);
const int32_t offset = 0;
i::Handle<i::WasmGlobalObject> obj =
i::WasmGlobalObject::New(isolate, i::MaybeHandle<i::JSArrayBuffer>(),
i::MaybeHandle<i::FixedArray>(), i_type, offset,
is_mutable)
.ToHandleChecked();
auto global = implement<Global>::type::make(store, obj);
assert(global);
global->set(val);
return global;
}
auto Global::type() const -> own<GlobalType*> {
i::Handle<i::WasmGlobalObject> v8_global = impl(this)->v8_object();
ValKind kind = v8::wasm::v8_valtype_to_wasm(v8_global->type());
Mutability mutability = v8_global->is_mutable() ? VAR : CONST;
return GlobalType::make(ValType::make(kind), mutability);
}
auto Global::get() const -> Val {
i::Handle<i::WasmGlobalObject> v8_global = impl(this)->v8_object();
switch (type()->content()->kind()) {
case I32:
return Val(v8_global->GetI32());
case I64:
return Val(v8_global->GetI64());
case F32:
return Val(v8_global->GetF32());
case F64:
return Val(v8_global->GetF64());
case ANYREF:
case FUNCREF:
WASM_UNIMPLEMENTED("globals of reference type");
default:
// TODO(wasm+): support new value types
UNREACHABLE();
}
}
void Global::set(const Val& val) {
i::Handle<i::WasmGlobalObject> v8_global = impl(this)->v8_object();
switch (val.kind()) {
case I32:
return v8_global->SetI32(val.i32());
case I64:
return v8_global->SetI64(val.i64());
case F32:
return v8_global->SetF32(val.f32());
case F64:
return v8_global->SetF64(val.f64());
case ANYREF:
case FUNCREF:
WASM_UNIMPLEMENTED("globals of reference type");
default:
// TODO(wasm+): support new value types
UNREACHABLE();
}
}
// Table Instances
template <>
struct implement<Table> {
using type = RefImpl<Table, i::WasmTableObject>;
};
Table::~Table() {}
auto Table::copy() const -> own<Table*> { return impl(this)->copy(); }
auto Table::make(Store* store_abs, const TableType* type, const Ref* ref)
-> own<Table*> {
StoreImpl* store = impl(store_abs);
i::Isolate* isolate = store->i_isolate();
i::HandleScope scope(isolate);
auto enabled_features = i::wasm::WasmFeaturesFromFlags();
// Get "element".
i::wasm::ValueType i_type;
switch (type->element()->kind()) {
case FUNCREF:
i_type = i::wasm::kWasmAnyFunc;
break;
case ANYREF:
if (enabled_features.anyref) {
i_type = i::wasm::kWasmAnyRef;
break;
} // Else fall through.
V8_FALLTHROUGH;
default:
UNREACHABLE(); // 'element' must be 'FUNCREF'.
return nullptr;
}
const Limits& limits = type->limits();
uint32_t minimum = limits.min;
if (minimum > i::wasm::max_table_init_entries()) return nullptr;
uint32_t maximum = limits.max;
bool has_maximum = false;
if (maximum != Limits(0).max) {
has_maximum = true;
if (maximum < minimum) return nullptr;
if (maximum > i::wasm::max_table_init_entries()) return nullptr;
}
i::Handle<i::FixedArray> backing_store;
i::Handle<i::WasmTableObject> table_obj = i::WasmTableObject::New(
isolate, i_type, minimum, has_maximum, maximum, &backing_store);
if (ref) {
i::Handle<i::JSReceiver> init = impl(ref)->v8_object();
DCHECK(i::wasm::max_table_init_entries() <= i::kMaxInt);
for (int i = 0; i < static_cast<int>(minimum); i++) {
// This doesn't call WasmTableObject::Set because the table has
// just been created, so it can't be imported by any instances
// yet that might require updating.
DCHECK_EQ(table_obj->dispatch_tables().length(), 0);
backing_store->set(i, *init);
}
}
return implement<Table>::type::make(store, table_obj);
}
auto Table::type() const -> own<TableType*> {
i::Handle<i::WasmTableObject> table = impl(this)->v8_object();
uint32_t min = table->current_length();
uint32_t max;
if (!table->maximum_length().ToUint32(&max)) max = 0xFFFFFFFFu;
// TODO(wasm+): support new element types.
return TableType::make(ValType::make(FUNCREF), Limits(min, max));
}
auto Table::get(size_t index) const -> own<Ref*> {
i::Handle<i::WasmTableObject> table = impl(this)->v8_object();
if (index >= table->current_length()) return own<Ref*>();
i::Isolate* isolate = table->GetIsolate();
i::HandleScope handle_scope(isolate);
i::Handle<i::Object> result =
i::WasmTableObject::Get(isolate, table, static_cast<uint32_t>(index));
if (!result->IsJSFunction()) return own<Ref*>();
DCHECK(i::WasmExportedFunction::IsWasmExportedFunction(*result) ||
i::WasmCapiFunction::IsWasmCapiFunction(*result));
// TODO(wasm+): other references
return implement<Func>::type::make(impl(this)->store(),
i::Handle<i::JSFunction>::cast(result));
}
auto Table::set(size_t index, const Ref* ref) -> bool {
if (ref && !impl(ref)->v8_object()->IsFunction()) {
WASM_UNIMPLEMENTED("non-function table elements");
}
i::Handle<i::WasmTableObject> table = impl(this)->v8_object();
if (index >= table->current_length()) return false;
i::Isolate* isolate = table->GetIsolate();
i::HandleScope handle_scope(isolate);
i::Handle<i::Object> obj =
ref ? i::Handle<i::Object>::cast(impl(ref)->v8_object())
: i::Handle<i::Object>::cast(
i::ReadOnlyRoots(isolate).null_value_handle());
i::WasmTableObject::Set(isolate, table, static_cast<uint32_t>(index), obj);
return true;
}
// TODO(jkummerow): Having Table::size_t shadowing "std" size_t is ugly.
auto Table::size() const -> size_t {
return impl(this)->v8_object()->current_length();
}
auto Table::grow(size_t delta, const Ref* ref) -> bool {
i::Handle<i::WasmTableObject> table = impl(this)->v8_object();
i::Isolate* isolate = table->GetIsolate();
i::HandleScope scope(isolate);
i::Handle<i::Object> init_value =
ref == nullptr
? i::Handle<i::Object>::cast(isolate->factory()->null_value())
: i::Handle<i::Object>::cast(impl(ref)->v8_object());
int result = i::WasmTableObject::Grow(
isolate, table, static_cast<uint32_t>(delta), init_value);
return result >= 0;
}
// Memory Instances
template <>
struct implement<Memory> {
using type = RefImpl<Memory, i::WasmMemoryObject>;
};
Memory::~Memory() {}
auto Memory::copy() const -> own<Memory*> { return impl(this)->copy(); }
auto Memory::make(Store* store_abs, const MemoryType* type) -> own<Memory*> {
StoreImpl* store = impl(store_abs);
i::Isolate* isolate = store->i_isolate();
i::HandleScope scope(isolate);
const Limits& limits = type->limits();
uint32_t minimum = limits.min;
if (minimum > i::wasm::max_mem_pages()) return nullptr;
uint32_t maximum = limits.max;
if (maximum != Limits(0).max) {
if (maximum < minimum) return nullptr;
if (maximum > i::wasm::kSpecMaxWasmMemoryPages) return nullptr;
}
bool is_shared = false; // TODO(wasm+): Support shared memory.
i::Handle<i::WasmMemoryObject> memory_obj;
if (!i::WasmMemoryObject::New(isolate, minimum, maximum, is_shared)
.ToHandle(&memory_obj)) {
return own<Memory*>();
}
return implement<Memory>::type::make(store, memory_obj);
}
auto Memory::type() const -> own<MemoryType*> {
i::Handle<i::WasmMemoryObject> memory = impl(this)->v8_object();
uint32_t min = static_cast<uint32_t>(memory->array_buffer().byte_length() /
i::wasm::kWasmPageSize);
uint32_t max =
memory->has_maximum_pages() ? memory->maximum_pages() : 0xFFFFFFFFu;
return MemoryType::make(Limits(min, max));
}
auto Memory::data() const -> byte_t* {
return reinterpret_cast<byte_t*>(
impl(this)->v8_object()->array_buffer().backing_store());
}
auto Memory::data_size() const -> size_t {
return impl(this)->v8_object()->array_buffer().byte_length();
}
auto Memory::size() const -> pages_t {
return static_cast<pages_t>(
impl(this)->v8_object()->array_buffer().byte_length() /
i::wasm::kWasmPageSize);
}
auto Memory::grow(pages_t delta) -> bool {
i::Handle<i::WasmMemoryObject> memory = impl(this)->v8_object();
i::Isolate* isolate = memory->GetIsolate();
i::HandleScope handle_scope(isolate);
int32_t old = i::WasmMemoryObject::Grow(isolate, memory, delta);
return old != -1;
}
// Module Instances
template <>
struct implement<Instance> {
using type = RefImpl<Instance, i::WasmInstanceObject>;
};
Instance::~Instance() {}
auto Instance::copy() const -> own<Instance*> { return impl(this)->copy(); }
auto Instance::make(Store* store_abs, const Module* module_abs,
const Extern* const imports[]) -> own<Instance*> {
StoreImpl* store = impl(store_abs);
const implement<Module>::type* module = impl(module_abs);
i::Isolate* isolate = store->i_isolate();
i::HandleScope handle_scope(isolate);
DCHECK_EQ(module->v8_object()->GetIsolate(), isolate);
vec<ImportType*> import_types = module_abs->imports();
i::Handle<i::JSObject> imports_obj =
isolate->factory()->NewJSObject(isolate->object_function());
for (size_t i = 0; i < import_types.size(); ++i) {
auto type = import_types[i];
i::Handle<i::String> module_str = VecToString(isolate, type->module());
i::Handle<i::String> name_str = VecToString(isolate, type->name());
i::Handle<i::JSObject> module_obj;
i::LookupIterator module_it(isolate, imports_obj, module_str,
i::LookupIterator::OWN_SKIP_INTERCEPTOR);
if (i::JSObject::HasProperty(&module_it).ToChecked()) {
module_obj = i::Handle<i::JSObject>::cast(
i::Object::GetProperty(&module_it).ToHandleChecked());
} else {
module_obj = isolate->factory()->NewJSObject(isolate->object_function());
ignore(
i::Object::SetProperty(isolate, imports_obj, module_str, module_obj));
}
ignore(i::Object::SetProperty(isolate, module_obj, name_str,
impl(imports[i])->v8_object()));
}
NopErrorThrower thrower(isolate);
i::Handle<i::WasmInstanceObject> instance_obj =
isolate->wasm_engine()
->SyncInstantiate(isolate, &thrower, module->v8_object(), imports_obj,
i::MaybeHandle<i::JSArrayBuffer>())
.ToHandleChecked();
return implement<Instance>::type::make(store, instance_obj);
}
auto Instance::exports() const -> vec<Extern*> {
const implement<Instance>::type* instance = impl(this);
StoreImpl* store = instance->store();
i::Isolate* isolate = store->i_isolate();
i::HandleScope handle_scope(isolate);
i::Handle<i::WasmInstanceObject> instance_obj = instance->v8_object();
i::Handle<i::WasmModuleObject> module_obj(instance_obj->module_object(),
isolate);
i::Handle<i::JSObject> exports_obj(instance_obj->exports_object(), isolate);
vec<ExportType*> export_types = ExportsImpl(module_obj);
vec<Extern*> exports = vec<Extern*>::make_uninitialized(export_types.size());
if (!exports) return vec<Extern*>::invalid();
for (size_t i = 0; i < export_types.size(); ++i) {
auto& name = export_types[i]->name();
i::Handle<i::String> name_str = VecToString(isolate, name);
i::Handle<i::Object> obj =
i::Object::GetProperty(isolate, exports_obj, name_str)
.ToHandleChecked();
const ExternType* type = export_types[i]->type();
switch (type->kind()) {
case EXTERN_FUNC: {
DCHECK(i::WasmExportedFunction::IsWasmExportedFunction(*obj));
exports[i].reset(implement<Func>::type::make(
store, i::Handle<i::WasmExportedFunction>::cast(obj)));
} break;
case EXTERN_GLOBAL: {
exports[i].reset(implement<Global>::type::make(
store, i::Handle<i::WasmGlobalObject>::cast(obj)));
} break;
case EXTERN_TABLE: {
exports[i].reset(implement<Table>::type::make(
store, i::Handle<i::WasmTableObject>::cast(obj)));
} break;
case EXTERN_MEMORY: {
exports[i].reset(implement<Memory>::type::make(
store, i::Handle<i::WasmMemoryObject>::cast(obj)));
} break;
}
}
return exports;
}
///////////////////////////////////////////////////////////////////////////////
} // namespace wasm
// BEGIN FILE wasm-c.cc
extern "C" {
///////////////////////////////////////////////////////////////////////////////
// Auxiliaries
// Backing implementation
extern "C++" {
template <class T>
struct borrowed_vec {
wasm::vec<T> it;
explicit borrowed_vec(wasm::vec<T>&& v) : it(std::move(v)) {}
borrowed_vec(borrowed_vec<T>&& that) : it(std::move(that.it)) {}
~borrowed_vec() { it.release(); }
};
} // extern "C++"
#define WASM_DEFINE_OWN(name, Name) \
struct wasm_##name##_t : Name {}; \
\
void wasm_##name##_delete(wasm_##name##_t* x) { delete x; } \
\
extern "C++" inline auto hide(Name* x)->wasm_##name##_t* { \
return static_cast<wasm_##name##_t*>(x); \
} \
extern "C++" inline auto hide(const Name* x)->const wasm_##name##_t* { \
return static_cast<const wasm_##name##_t*>(x); \
} \
extern "C++" inline auto reveal(wasm_##name##_t* x)->Name* { return x; } \
extern "C++" inline auto reveal(const wasm_##name##_t* x)->const Name* { \
return x; \
} \
extern "C++" inline auto get(wasm::own<Name*>& x)->wasm_##name##_t* { \
return hide(x.get()); \
} \
extern "C++" inline auto get(const wasm::own<Name*>& x) \
->const wasm_##name##_t* { \
return hide(x.get()); \
} \
extern "C++" inline auto release(wasm::own<Name*>&& x)->wasm_##name##_t* { \
return hide(x.release()); \
} \
extern "C++" inline auto adopt(wasm_##name##_t* x)->wasm::own<Name*> { \
return make_own(x); \
}
// Vectors
#define WASM_DEFINE_VEC_BASE(name, Name, ptr_or_none) \
extern "C++" inline auto hide(wasm::vec<Name ptr_or_none>& v) \
->wasm_##name##_vec_t* { \
static_assert(sizeof(wasm_##name##_vec_t) == sizeof(wasm::vec<Name>), \
"C/C++ incompatibility"); \
return reinterpret_cast<wasm_##name##_vec_t*>(&v); \
} \
extern "C++" inline auto hide(const wasm::vec<Name ptr_or_none>& v) \
->const wasm_##name##_vec_t* { \
static_assert(sizeof(wasm_##name##_vec_t) == sizeof(wasm::vec<Name>), \
"C/C++ incompatibility"); \
return reinterpret_cast<const wasm_##name##_vec_t*>(&v); \
} \
extern "C++" inline auto hide(Name ptr_or_none* v) \
->wasm_##name##_t ptr_or_none* { \
static_assert( \
sizeof(wasm_##name##_t ptr_or_none) == sizeof(Name ptr_or_none), \
"C/C++ incompatibility"); \
return reinterpret_cast<wasm_##name##_t ptr_or_none*>(v); \
} \
extern "C++" inline auto hide(Name ptr_or_none const* v) \
->wasm_##name##_t ptr_or_none const* { \
static_assert( \
sizeof(wasm_##name##_t ptr_or_none) == sizeof(Name ptr_or_none), \
"C/C++ incompatibility"); \
return reinterpret_cast<wasm_##name##_t ptr_or_none const*>(v); \
} \
extern "C++" inline auto reveal(wasm_##name##_t ptr_or_none* v) \
->Name ptr_or_none* { \
static_assert( \
sizeof(wasm_##name##_t ptr_or_none) == sizeof(Name ptr_or_none), \
"C/C++ incompatibility"); \
return reinterpret_cast<Name ptr_or_none*>(v); \
} \
extern "C++" inline auto reveal(wasm_##name##_t ptr_or_none const* v) \
->Name ptr_or_none const* { \
static_assert( \
sizeof(wasm_##name##_t ptr_or_none) == sizeof(Name ptr_or_none), \
"C/C++ incompatibility"); \
return reinterpret_cast<Name ptr_or_none const*>(v); \
} \
extern "C++" inline auto get(wasm::vec<Name ptr_or_none>& v) \
->wasm_##name##_vec_t { \
wasm_##name##_vec_t v2 = {v.size(), hide(v.get())}; \
return v2; \
} \
extern "C++" inline auto get(const wasm::vec<Name ptr_or_none>& v) \
->const wasm_##name##_vec_t { \
wasm_##name##_vec_t v2 = { \
v.size(), const_cast<wasm_##name##_t ptr_or_none*>(hide(v.get()))}; \
return v2; \
} \
extern "C++" inline auto release(wasm::vec<Name ptr_or_none>&& v) \
->wasm_##name##_vec_t { \
wasm_##name##_vec_t v2 = {v.size(), hide(v.release())}; \
return v2; \
} \
extern "C++" inline auto adopt(wasm_##name##_vec_t* v) \
->wasm::vec<Name ptr_or_none> { \
return wasm::vec<Name ptr_or_none>::adopt(v->size, reveal(v->data)); \
} \
extern "C++" inline auto borrow(const wasm_##name##_vec_t* v) \
->borrowed_vec<Name ptr_or_none> { \
return borrowed_vec<Name ptr_or_none>( \
wasm::vec<Name ptr_or_none>::adopt(v->size, reveal(v->data))); \
} \
\
void wasm_##name##_vec_new_uninitialized(wasm_##name##_vec_t* out, \
size_t size) { \
*out = release(wasm::vec<Name ptr_or_none>::make_uninitialized(size)); \
} \
void wasm_##name##_vec_new_empty(wasm_##name##_vec_t* out) { \
wasm_##name##_vec_new_uninitialized(out, 0); \
} \
\
void wasm_##name##_vec_delete(wasm_##name##_vec_t* v) { adopt(v); }
// Vectors with no ownership management of elements
#define WASM_DEFINE_VEC_PLAIN(name, Name, ptr_or_none) \
WASM_DEFINE_VEC_BASE(name, Name, ptr_or_none) \
\
void wasm_##name##_vec_new(wasm_##name##_vec_t* out, size_t size, \
wasm_##name##_t ptr_or_none const data[]) { \
auto v2 = wasm::vec<Name ptr_or_none>::make_uninitialized(size); \
if (v2.size() != 0) { \
memcpy(v2.get(), data, size * sizeof(wasm_##name##_t ptr_or_none)); \
} \
*out = release(std::move(v2)); \
} \
\
void wasm_##name##_vec_copy(wasm_##name##_vec_t* out, \
wasm_##name##_vec_t* v) { \
wasm_##name##_vec_new(out, v->size, v->data); \
}
// Vectors who own their elements
#define WASM_DEFINE_VEC(name, Name, ptr_or_none) \
WASM_DEFINE_VEC_BASE(name, Name, ptr_or_none) \
\
void wasm_##name##_vec_new(wasm_##name##_vec_t* out, size_t size, \
wasm_##name##_t ptr_or_none const data[]) { \
auto v2 = wasm::vec<Name ptr_or_none>::make_uninitialized(size); \
for (size_t i = 0; i < v2.size(); ++i) { \
v2[i] = adopt(data[i]); \
} \
*out = release(std::move(v2)); \
} \
\
void wasm_##name##_vec_copy(wasm_##name##_vec_t* out, \
wasm_##name##_vec_t* v) { \
auto v2 = wasm::vec<Name ptr_or_none>::make_uninitialized(v->size); \
for (size_t i = 0; i < v2.size(); ++i) { \
v2[i] = adopt(wasm_##name##_copy(v->data[i])); \
} \
*out = release(std::move(v2)); \
}
extern "C++" {
template <class T>
inline auto is_empty(T* p) -> bool {
return !p;
}
}
// Byte vectors
using byte = byte_t;
WASM_DEFINE_VEC_PLAIN(byte, byte, )
///////////////////////////////////////////////////////////////////////////////
// Runtime Environment
// Configuration
WASM_DEFINE_OWN(config, wasm::Config)
wasm_config_t* wasm_config_new() { return release(wasm::Config::make()); }
// Engine
WASM_DEFINE_OWN(engine, wasm::Engine)
wasm_engine_t* wasm_engine_new() { return release(wasm::Engine::make()); }
wasm_engine_t* wasm_engine_new_with_config(wasm_config_t* config) {
return release(wasm::Engine::make(adopt(config)));
}
// Stores
WASM_DEFINE_OWN(store, wasm::Store)
wasm_store_t* wasm_store_new(wasm_engine_t* engine) {
return release(wasm::Store::make(engine));
}
///////////////////////////////////////////////////////////////////////////////
// Type Representations
// Type attributes
extern "C++" inline auto hide(wasm::Mutability mutability)
-> wasm_mutability_t {
return static_cast<wasm_mutability_t>(mutability);
}
extern "C++" inline auto reveal(wasm_mutability_t mutability)
-> wasm::Mutability {
return static_cast<wasm::Mutability>(mutability);
}
extern "C++" inline auto hide(const wasm::Limits& limits)
-> const wasm_limits_t* {
return reinterpret_cast<const wasm_limits_t*>(&limits);
}
extern "C++" inline auto reveal(wasm_limits_t limits) -> wasm::Limits {
return wasm::Limits(limits.min, limits.max);
}
extern "C++" inline auto hide(wasm::ValKind kind) -> wasm_valkind_t {
return static_cast<wasm_valkind_t>(kind);
}
extern "C++" inline auto reveal(wasm_valkind_t kind) -> wasm::ValKind {
return static_cast<wasm::ValKind>(kind);
}
extern "C++" inline auto hide(wasm::ExternKind kind) -> wasm_externkind_t {
return static_cast<wasm_externkind_t>(kind);
}
extern "C++" inline auto reveal(wasm_externkind_t kind) -> wasm::ExternKind {
return static_cast<wasm::ExternKind>(kind);
}
// Generic
#define WASM_DEFINE_TYPE(name, Name) \
WASM_DEFINE_OWN(name, Name) \
WASM_DEFINE_VEC(name, Name, *) \
\
wasm_##name##_t* wasm_##name##_copy(wasm_##name##_t* t) { \
return release(t->copy()); \
}
// Value Types
WASM_DEFINE_TYPE(valtype, wasm::ValType)
wasm_valtype_t* wasm_valtype_new(wasm_valkind_t k) {
return release(wasm::ValType::make(reveal(k)));
}
wasm_valkind_t wasm_valtype_kind(const wasm_valtype_t* t) {
return hide(t->kind());
}
// Function Types
WASM_DEFINE_TYPE(functype, wasm::FuncType)
wasm_functype_t* wasm_functype_new(wasm_valtype_vec_t* params,
wasm_valtype_vec_t* results) {
return release(wasm::FuncType::make(adopt(params), adopt(results)));
}
const wasm_valtype_vec_t* wasm_functype_params(const wasm_functype_t* ft) {
return hide(ft->params());
}
const wasm_valtype_vec_t* wasm_functype_results(const wasm_functype_t* ft) {
return hide(ft->results());
}
// Global Types
WASM_DEFINE_TYPE(globaltype, wasm::GlobalType)
wasm_globaltype_t* wasm_globaltype_new(wasm_valtype_t* content,
wasm_mutability_t mutability) {
return release(wasm::GlobalType::make(adopt(content), reveal(mutability)));
}
const wasm_valtype_t* wasm_globaltype_content(const wasm_globaltype_t* gt) {
return hide(gt->content());
}
wasm_mutability_t wasm_globaltype_mutability(const wasm_globaltype_t* gt) {
return hide(gt->mutability());
}
// Table Types
WASM_DEFINE_TYPE(tabletype, wasm::TableType)
wasm_tabletype_t* wasm_tabletype_new(wasm_valtype_t* element,
const wasm_limits_t* limits) {
return release(wasm::TableType::make(adopt(element), reveal(*limits)));
}
const wasm_valtype_t* wasm_tabletype_element(const wasm_tabletype_t* tt) {
return hide(tt->element());
}
const wasm_limits_t* wasm_tabletype_limits(const wasm_tabletype_t* tt) {
return hide(tt->limits());
}
// Memory Types
WASM_DEFINE_TYPE(memorytype, wasm::MemoryType)
wasm_memorytype_t* wasm_memorytype_new(const wasm_limits_t* limits) {
return release(wasm::MemoryType::make(reveal(*limits)));
}
const wasm_limits_t* wasm_memorytype_limits(const wasm_memorytype_t* mt) {
return hide(mt->limits());
}
// Extern Types
WASM_DEFINE_TYPE(externtype, wasm::ExternType)
wasm_externkind_t wasm_externtype_kind(const wasm_externtype_t* et) {
return hide(et->kind());
}
wasm_externtype_t* wasm_functype_as_externtype(wasm_functype_t* ft) {
return hide(static_cast<wasm::ExternType*>(ft));
}
wasm_externtype_t* wasm_globaltype_as_externtype(wasm_globaltype_t* gt) {
return hide(static_cast<wasm::ExternType*>(gt));
}
wasm_externtype_t* wasm_tabletype_as_externtype(wasm_tabletype_t* tt) {
return hide(static_cast<wasm::ExternType*>(tt));
}
wasm_externtype_t* wasm_memorytype_as_externtype(wasm_memorytype_t* mt) {
return hide(static_cast<wasm::ExternType*>(mt));
}
const wasm_externtype_t* wasm_functype_as_externtype_const(
const wasm_functype_t* ft) {
return hide(static_cast<const wasm::ExternType*>(ft));
}
const wasm_externtype_t* wasm_globaltype_as_externtype_const(
const wasm_globaltype_t* gt) {
return hide(static_cast<const wasm::ExternType*>(gt));
}
const wasm_externtype_t* wasm_tabletype_as_externtype_const(
const wasm_tabletype_t* tt) {
return hide(static_cast<const wasm::ExternType*>(tt));
}
const wasm_externtype_t* wasm_memorytype_as_externtype_const(
const wasm_memorytype_t* mt) {
return hide(static_cast<const wasm::ExternType*>(mt));
}
wasm_functype_t* wasm_externtype_as_functype(wasm_externtype_t* et) {
return et->kind() == wasm::EXTERN_FUNC
? hide(static_cast<wasm::FuncType*>(reveal(et)))
: nullptr;
}
wasm_globaltype_t* wasm_externtype_as_globaltype(wasm_externtype_t* et) {
return et->kind() == wasm::EXTERN_GLOBAL
? hide(static_cast<wasm::GlobalType*>(reveal(et)))
: nullptr;
}
wasm_tabletype_t* wasm_externtype_as_tabletype(wasm_externtype_t* et) {
return et->kind() == wasm::EXTERN_TABLE
? hide(static_cast<wasm::TableType*>(reveal(et)))
: nullptr;
}
wasm_memorytype_t* wasm_externtype_as_memorytype(wasm_externtype_t* et) {
return et->kind() == wasm::EXTERN_MEMORY
? hide(static_cast<wasm::MemoryType*>(reveal(et)))
: nullptr;
}
const wasm_functype_t* wasm_externtype_as_functype_const(
const wasm_externtype_t* et) {
return et->kind() == wasm::EXTERN_FUNC
? hide(static_cast<const wasm::FuncType*>(reveal(et)))
: nullptr;
}
const wasm_globaltype_t* wasm_externtype_as_globaltype_const(
const wasm_externtype_t* et) {
return et->kind() == wasm::EXTERN_GLOBAL
? hide(static_cast<const wasm::GlobalType*>(reveal(et)))
: nullptr;
}
const wasm_tabletype_t* wasm_externtype_as_tabletype_const(
const wasm_externtype_t* et) {
return et->kind() == wasm::EXTERN_TABLE
? hide(static_cast<const wasm::TableType*>(reveal(et)))
: nullptr;
}
const wasm_memorytype_t* wasm_externtype_as_memorytype_const(
const wasm_externtype_t* et) {
return et->kind() == wasm::EXTERN_MEMORY
? hide(static_cast<const wasm::MemoryType*>(reveal(et)))
: nullptr;
}
// Import Types
WASM_DEFINE_TYPE(importtype, wasm::ImportType)
wasm_importtype_t* wasm_importtype_new(wasm_name_t* module, wasm_name_t* name,
wasm_externtype_t* type) {
return release(
wasm::ImportType::make(adopt(module), adopt(name), adopt(type)));
}
const wasm_name_t* wasm_importtype_module(const wasm_importtype_t* it) {
return hide(it->module());
}
const wasm_name_t* wasm_importtype_name(const wasm_importtype_t* it) {
return hide(it->name());
}
const wasm_externtype_t* wasm_importtype_type(const wasm_importtype_t* it) {
return hide(it->type());
}
// Export Types
WASM_DEFINE_TYPE(exporttype, wasm::ExportType)
wasm_exporttype_t* wasm_exporttype_new(wasm_name_t* name,
wasm_externtype_t* type) {
return release(wasm::ExportType::make(adopt(name), adopt(type)));
}
const wasm_name_t* wasm_exporttype_name(const wasm_exporttype_t* et) {
return hide(et->name());
}
const wasm_externtype_t* wasm_exporttype_type(const wasm_exporttype_t* et) {
return hide(et->type());
}
///////////////////////////////////////////////////////////////////////////////
// Runtime Values
// References
#define WASM_DEFINE_REF_BASE(name, Name) \
WASM_DEFINE_OWN(name, Name) \
\
wasm_##name##_t* wasm_##name##_copy(const wasm_##name##_t* t) { \
return release(t->copy()); \
} \
\
void* wasm_##name##_get_host_info(const wasm_##name##_t* r) { \
return r->get_host_info(); \
} \
void wasm_##name##_set_host_info(wasm_##name##_t* r, void* info) { \
r->set_host_info(info); \
} \
void wasm_##name##_set_host_info_with_finalizer( \
wasm_##name##_t* r, void* info, void (*finalizer)(void*)) { \
r->set_host_info(info, finalizer); \
}
#define WASM_DEFINE_REF(name, Name) \
WASM_DEFINE_REF_BASE(name, Name) \
\
wasm_ref_t* wasm_##name##_as_ref(wasm_##name##_t* r) { \
return hide(static_cast<wasm::Ref*>(reveal(r))); \
} \
wasm_##name##_t* wasm_ref_as_##name(wasm_ref_t* r) { \
return hide(static_cast<Name*>(reveal(r))); \
} \
\
const wasm_ref_t* wasm_##name##_as_ref_const(const wasm_##name##_t* r) { \
return hide(static_cast<const wasm::Ref*>(reveal(r))); \
} \
const wasm_##name##_t* wasm_ref_as_##name##_const(const wasm_ref_t* r) { \
return hide(static_cast<const Name*>(reveal(r))); \
}
#define WASM_DEFINE_SHARABLE_REF(name, Name) \
WASM_DEFINE_REF(name, Name) \
WASM_DEFINE_OWN(shared_##name, wasm::Shared<Name>)
WASM_DEFINE_REF_BASE(ref, wasm::Ref)
// Values
extern "C++" {
inline auto is_empty(wasm_val_t v) -> bool {
return !is_ref(reveal(v.kind)) || !v.of.ref;
}
inline auto hide(wasm::Val v) -> wasm_val_t {
wasm_val_t v2 = {hide(v.kind()), {}};
switch (v.kind()) {
case wasm::I32:
v2.of.i32 = v.i32();
break;
case wasm::I64:
v2.of.i64 = v.i64();
break;
case wasm::F32:
v2.of.f32 = v.f32();
break;
case wasm::F64:
v2.of.f64 = v.f64();
break;
case wasm::ANYREF:
case wasm::FUNCREF:
v2.of.ref = hide(v.ref());
break;
default:
UNREACHABLE();
}
return v2;
}
inline auto release(wasm::Val v) -> wasm_val_t {
wasm_val_t v2 = {hide(v.kind()), {}};
switch (v.kind()) {
case wasm::I32:
v2.of.i32 = v.i32();
break;
case wasm::I64:
v2.of.i64 = v.i64();
break;
case wasm::F32:
v2.of.f32 = v.f32();
break;
case wasm::F64:
v2.of.f64 = v.f64();
break;
case wasm::ANYREF:
case wasm::FUNCREF:
v2.of.ref = release(v.release_ref());
break;
default:
UNREACHABLE();
}
return v2;
}
inline auto adopt(wasm_val_t v) -> wasm::Val {
switch (reveal(v.kind)) {
case wasm::I32:
return wasm::Val(v.of.i32);
case wasm::I64:
return wasm::Val(v.of.i64);
case wasm::F32:
return wasm::Val(v.of.f32);
case wasm::F64:
return wasm::Val(v.of.f64);
case wasm::ANYREF:
case wasm::FUNCREF:
return wasm::Val(adopt(v.of.ref));
default:
UNREACHABLE();
}
}
struct borrowed_val {
wasm::Val it;
explicit borrowed_val(wasm::Val&& v) : it(std::move(v)) {}
borrowed_val(borrowed_val&& that) : it(std::move(that.it)) {}
~borrowed_val() {
if (it.is_ref()) it.release_ref();
}
};
inline auto borrow(const wasm_val_t* v) -> borrowed_val {
wasm::Val v2;
switch (reveal(v->kind)) {
case wasm::I32:
v2 = wasm::Val(v->of.i32);
break;
case wasm::I64:
v2 = wasm::Val(v->of.i64);
break;
case wasm::F32:
v2 = wasm::Val(v->of.f32);
break;
case wasm::F64:
v2 = wasm::Val(v->of.f64);
break;
case wasm::ANYREF:
case wasm::FUNCREF:
v2 = wasm::Val(adopt(v->of.ref));
break;
default:
UNREACHABLE();
}
return borrowed_val(std::move(v2));
}
} // extern "C++"
WASM_DEFINE_VEC_BASE(val, wasm::Val, )
void wasm_val_vec_new(wasm_val_vec_t* out, size_t size,
wasm_val_t const data[]) {
auto v2 = wasm::vec<wasm::Val>::make_uninitialized(size);
for (size_t i = 0; i < v2.size(); ++i) {
v2[i] = adopt(data[i]);
}
*out = release(std::move(v2));
}
void wasm_val_vec_copy(wasm_val_vec_t* out, wasm_val_vec_t* v) {
auto v2 = wasm::vec<wasm::Val>::make_uninitialized(v->size);
for (size_t i = 0; i < v2.size(); ++i) {
wasm_val_t val;
wasm_val_copy(&v->data[i], &val);
v2[i] = adopt(val);
}
*out = release(std::move(v2));
}
void wasm_val_delete(wasm_val_t* v) {
if (is_ref(reveal(v->kind))) adopt(v->of.ref);
}
void wasm_val_copy(wasm_val_t* out, const wasm_val_t* v) {
*out = *v;
if (is_ref(reveal(v->kind))) {
out->of.ref = release(v->of.ref->copy());
}
}
///////////////////////////////////////////////////////////////////////////////
// Runtime Objects
// Traps
WASM_DEFINE_REF(trap, wasm::Trap)
wasm_trap_t* wasm_trap_new(wasm_store_t* store, const wasm_message_t* message) {
auto message_ = borrow(message);
return release(wasm::Trap::make(store, message_.it));
}
void wasm_trap_message(const wasm_trap_t* trap, wasm_message_t* out) {
*out = release(reveal(trap)->message());
}
// Foreign Objects
WASM_DEFINE_REF(foreign, wasm::Foreign)
wasm_foreign_t* wasm_foreign_new(wasm_store_t* store) {
return release(wasm::Foreign::make(store));
}
// Modules
WASM_DEFINE_SHARABLE_REF(module, wasm::Module)
bool wasm_module_validate(wasm_store_t* store, const wasm_byte_vec_t* binary) {
auto binary_ = borrow(binary);
return wasm::Module::validate(store, binary_.it);
}
wasm_module_t* wasm_module_new(wasm_store_t* store,
const wasm_byte_vec_t* binary) {
auto binary_ = borrow(binary);
return release(wasm::Module::make(store, binary_.it));
}
void wasm_module_imports(const wasm_module_t* module,
wasm_importtype_vec_t* out) {
*out = release(reveal(module)->imports());
}
void wasm_module_exports(const wasm_module_t* module,
wasm_exporttype_vec_t* out) {
*out = release(reveal(module)->exports());
}
void wasm_module_serialize(const wasm_module_t* module, wasm_byte_vec_t* out) {
*out = release(reveal(module)->serialize());
}
wasm_module_t* wasm_module_deserialize(wasm_store_t* store,
const wasm_byte_vec_t* binary) {
auto binary_ = borrow(binary);
return release(wasm::Module::deserialize(store, binary_.it));
}
wasm_shared_module_t* wasm_module_share(const wasm_module_t* module) {
return release(reveal(module)->share());
}
wasm_module_t* wasm_module_obtain(wasm_store_t* store,
const wasm_shared_module_t* shared) {
return release(wasm::Module::obtain(store, shared));
}
// Function Instances
WASM_DEFINE_REF(func, wasm::Func)
extern "C++" {
auto wasm_callback(void* env, const wasm::Val args[], wasm::Val results[])
-> wasm::own<wasm::Trap*> {
auto f = reinterpret_cast<wasm_func_callback_t>(env);
return adopt(f(hide(args), hide(results)));
}
struct wasm_callback_env_t {
wasm_func_callback_with_env_t callback;
void* env;
void (*finalizer)(void*);
};
auto wasm_callback_with_env(void* env, const wasm::Val args[],
wasm::Val results[]) -> wasm::own<wasm::Trap*> {
auto t = static_cast<wasm_callback_env_t*>(env);
return adopt(t->callback(t->env, hide(args), hide(results)));
}
void wasm_callback_env_finalizer(void* env) {
auto t = static_cast<wasm_callback_env_t*>(env);
if (t->finalizer) t->finalizer(t->env);
delete t;
}
} // extern "C++"
wasm_func_t* wasm_func_new(wasm_store_t* store, const wasm_functype_t* type,
wasm_func_callback_t callback) {
return release(wasm::Func::make(store, type, wasm_callback,
reinterpret_cast<void*>(callback)));
}
wasm_func_t* wasm_func_new_with_env(wasm_store_t* store,
const wasm_functype_t* type,
wasm_func_callback_with_env_t callback,
void* env, void (*finalizer)(void*)) {
auto env2 = new wasm_callback_env_t{callback, env, finalizer};
return release(wasm::Func::make(store, type, wasm_callback_with_env, env2,
wasm_callback_env_finalizer));
}
wasm_functype_t* wasm_func_type(const wasm_func_t* func) {
return release(func->type());
}
size_t wasm_func_param_arity(const wasm_func_t* func) {
return func->param_arity();
}
size_t wasm_func_result_arity(const wasm_func_t* func) {
return func->result_arity();
}
wasm_trap_t* wasm_func_call(const wasm_func_t* func, const wasm_val_t args[],
wasm_val_t results[]) {
return release(func->call(reveal(args), reveal(results)));
}
// Global Instances
WASM_DEFINE_REF(global, wasm::Global)
wasm_global_t* wasm_global_new(wasm_store_t* store,
const wasm_globaltype_t* type,
const wasm_val_t* val) {
auto val_ = borrow(val);
return release(wasm::Global::make(store, type, val_.it));
}
wasm_globaltype_t* wasm_global_type(const wasm_global_t* global) {
return release(global->type());
}
void wasm_global_get(const wasm_global_t* global, wasm_val_t* out) {
*out = release(global->get());
}
void wasm_global_set(wasm_global_t* global, const wasm_val_t* val) {
auto val_ = borrow(val);
global->set(val_.it);
}
// Table Instances
WASM_DEFINE_REF(table, wasm::Table)
wasm_table_t* wasm_table_new(wasm_store_t* store, const wasm_tabletype_t* type,
wasm_ref_t* ref) {
return release(wasm::Table::make(store, type, ref));
}
wasm_tabletype_t* wasm_table_type(const wasm_table_t* table) {
return release(table->type());
}
wasm_ref_t* wasm_table_get(const wasm_table_t* table, wasm_table_size_t index) {
return release(table->get(index));
}
bool wasm_table_set(wasm_table_t* table, wasm_table_size_t index,
wasm_ref_t* ref) {
return table->set(index, ref);
}
wasm_table_size_t wasm_table_size(const wasm_table_t* table) {
return table->size();
}
bool wasm_table_grow(wasm_table_t* table, wasm_table_size_t delta,
wasm_ref_t* ref) {
return table->grow(delta, ref);
}
// Memory Instances
WASM_DEFINE_REF(memory, wasm::Memory)
wasm_memory_t* wasm_memory_new(wasm_store_t* store,
const wasm_memorytype_t* type) {
return release(wasm::Memory::make(store, type));
}
wasm_memorytype_t* wasm_memory_type(const wasm_memory_t* memory) {
return release(memory->type());
}
wasm_byte_t* wasm_memory_data(wasm_memory_t* memory) { return memory->data(); }
size_t wasm_memory_data_size(const wasm_memory_t* memory) {
return memory->data_size();
}
wasm_memory_pages_t wasm_memory_size(const wasm_memory_t* memory) {
return memory->size();
}
bool wasm_memory_grow(wasm_memory_t* memory, wasm_memory_pages_t delta) {
return memory->grow(delta);
}
// Externals
WASM_DEFINE_REF(extern, wasm::Extern)
WASM_DEFINE_VEC(extern, wasm::Extern, *)
wasm_externkind_t wasm_extern_kind(const wasm_extern_t* external) {
return hide(external->kind());
}
wasm_externtype_t* wasm_extern_type(const wasm_extern_t* external) {
return release(external->type());
}
wasm_extern_t* wasm_func_as_extern(wasm_func_t* func) {
return hide(static_cast<wasm::Extern*>(reveal(func)));
}
wasm_extern_t* wasm_global_as_extern(wasm_global_t* global) {
return hide(static_cast<wasm::Extern*>(reveal(global)));
}
wasm_extern_t* wasm_table_as_extern(wasm_table_t* table) {
return hide(static_cast<wasm::Extern*>(reveal(table)));
}
wasm_extern_t* wasm_memory_as_extern(wasm_memory_t* memory) {
return hide(static_cast<wasm::Extern*>(reveal(memory)));
}
const wasm_extern_t* wasm_func_as_extern_const(const wasm_func_t* func) {
return hide(static_cast<const wasm::Extern*>(reveal(func)));
}
const wasm_extern_t* wasm_global_as_extern_const(const wasm_global_t* global) {
return hide(static_cast<const wasm::Extern*>(reveal(global)));
}
const wasm_extern_t* wasm_table_as_extern_const(const wasm_table_t* table) {
return hide(static_cast<const wasm::Extern*>(reveal(table)));
}
const wasm_extern_t* wasm_memory_as_extern_const(const wasm_memory_t* memory) {
return hide(static_cast<const wasm::Extern*>(reveal(memory)));
}
wasm_func_t* wasm_extern_as_func(wasm_extern_t* external) {
return hide(external->func());
}
wasm_global_t* wasm_extern_as_global(wasm_extern_t* external) {
return hide(external->global());
}
wasm_table_t* wasm_extern_as_table(wasm_extern_t* external) {
return hide(external->table());
}
wasm_memory_t* wasm_extern_as_memory(wasm_extern_t* external) {
return hide(external->memory());
}
const wasm_func_t* wasm_extern_as_func_const(const wasm_extern_t* external) {
return hide(external->func());
}
const wasm_global_t* wasm_extern_as_global_const(
const wasm_extern_t* external) {
return hide(external->global());
}
const wasm_table_t* wasm_extern_as_table_const(const wasm_extern_t* external) {
return hide(external->table());
}
const wasm_memory_t* wasm_extern_as_memory_const(
const wasm_extern_t* external) {
return hide(external->memory());
}
// Module Instances
WASM_DEFINE_REF(instance, wasm::Instance)
wasm_instance_t* wasm_instance_new(wasm_store_t* store,
const wasm_module_t* module,
const wasm_extern_t* const imports[]) {
return release(wasm::Instance::make(
store, module, reinterpret_cast<const wasm::Extern* const*>(imports)));
}
void wasm_instance_exports(const wasm_instance_t* instance,
wasm_extern_vec_t* out) {
*out = release(instance->exports());
}
#undef WASM_DEFINE_OWN
#undef WASM_DEFINE_VEC_BASE
#undef WASM_DEFINE_VEC_PLAIN
#undef WASM_DEFINE_VEC
#undef WASM_DEFINE_TYPE
#undef WASM_DEFINE_REF_BASE
#undef WASM_DEFINE_REF
#undef WASM_DEFINE_SHARABLE_REF
} // extern "C"