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dawn / dawn / refs/heads/chromium/4825 / . / src / dawn_node / interop / Core.h
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// Copyright 2021 The Dawn Authors
//
// 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.
// This file provides core interop helpers used by the code generated by the
// templates.
#ifndef DAWN_NODE_INTEROP_CORE_WEBGPU_H_
#define DAWN_NODE_INTEROP_CORE_WEBGPU_H_
#include <cstdint>
#include <optional>
#include <string>
#include <type_traits>
#include <unordered_map>
#include <variant>
#include <vector>
#include "napi.h"
#include "src/dawn_node/utils/Debug.h"
#define ENABLE_INTEROP_LOGGING 0 // Enable for verbose interop logging
#if ENABLE_INTEROP_LOGGING
# define INTEROP_LOG(...) LOG(__VA_ARGS__)
#else
# define INTEROP_LOG(...)
#endif
// A helper macro for constructing a PromiseInfo with the current file, function and line.
// See PromiseInfo
#define PROMISE_INFO \
::wgpu::interop::PromiseInfo { \
__FILE__, __FUNCTION__, __LINE__ \
}
namespace wgpu::interop {
////////////////////////////////////////////////////////////////////////////////
// Primitive JavaScript types
////////////////////////////////////////////////////////////////////////////////
using Object = Napi::Object;
using ArrayBuffer = Napi::ArrayBuffer;
using Int8Array = Napi::TypedArrayOf<int8_t>;
using Int16Array = Napi::TypedArrayOf<int16_t>;
using Int32Array = Napi::TypedArrayOf<int32_t>;
using Uint8Array = Napi::TypedArrayOf<uint8_t>;
using Uint16Array = Napi::TypedArrayOf<uint16_t>;
using Uint32Array = Napi::TypedArrayOf<uint32_t>;
using Float32Array = Napi::TypedArrayOf<float>;
using Float64Array = Napi::TypedArrayOf<double>;
using DataView = Napi::TypedArray;
template <typename T>
using FrozenArray = std::vector<T>;
////////////////////////////////////////////////////////////////////////////////
// Result
////////////////////////////////////////////////////////////////////////////////
// Result is used to hold an success / error state by functions that perform JS <-> C++
// conversion
struct [[nodiscard]] Result {
// Returns true if the operation succeeded, false if there was an error
inline operator bool() const {
return error.empty();
}
// If Result is an error, then a new Error is returned with the
// stringified values append to the error message.
// If Result is a success, then a success Result is returned.
template <typename... VALUES>
Result Append(VALUES && ... values) {
if (*this) {
return *this;
}
std::stringstream ss;
ss << error << "\n";
utils::Write(ss, std::forward<VALUES>(values)...);
return {ss.str()};
}
// The error message, if the operation failed.
std::string error;
};
// A successful result
extern Result Success;
// Returns a Result with the given error message
Result Error(std::string msg);
////////////////////////////////////////////////////////////////////////////////
// Interface<T>
////////////////////////////////////////////////////////////////////////////////
// Interface<T> is a templated wrapper around a JavaScript object, which
// implements the template-generated interface type T. Interfaces are returned
// by either calling T::Bind() or T::Create().
template <typename T>
class Interface {
public:
// Constructs an Interface with no JS object.
inline Interface() {
}
// Constructs an Interface wrapping the given JS object.
// The JS object must have been created with a call to T::Bind().
explicit inline Interface(Napi::Object o) : object(o) {
}
// Implicit conversion operators to Napi objects.
inline operator napi_value() const {
return object;
}
inline operator const Napi::Value &() const {
return object;
}
inline operator const Napi::Object &() const {
return object;
}
// Member and dereference operators
inline T* operator->() const {
return T::Unwrap(object);
}
inline T* operator*() const {
return T::Unwrap(object);
}
// As<IMPL>() returns the unwrapped object cast to the implementation type.
// The interface implementation *must* be of the template type IMPL.
template <typename IMPL>
inline IMPL* As() const {
return static_cast<IMPL*>(T::Unwrap(object));
}
private:
Napi::Object object;
};
////////////////////////////////////////////////////////////////////////////////
// Promise<T>
////////////////////////////////////////////////////////////////////////////////
// Info holds details about where the promise was constructed.
// Used for printing debug messages when a promise is finalized without being resolved
// or rejected.
// Use the PROMISE_INFO macro to populate this structure.
struct PromiseInfo {
const char* file = nullptr;
const char* function = nullptr;
int line = 0;
};
namespace detail {
// Base class for Promise<T> specializations.
class PromiseBase {
public:
// Implicit conversion operators to Napi promises.
inline operator napi_value() const {
return state->deferred.Promise();
}
inline operator Napi::Value() const {
return state->deferred.Promise();
}
inline operator Napi::Promise() const {
return state->deferred.Promise();
}
// Reject() rejects the promise with the given failure value.
void Reject(Napi::Value value) const {
state->deferred.Reject(value);
state->resolved_or_rejected = true;
}
void Reject(Napi::Error err) const {
Reject(err.Value());
}
void Reject(std::string err) const {
Reject(Napi::Error::New(state->deferred.Env(), err));
}
protected:
void Resolve(Napi::Value value) const {
state->deferred.Resolve(value);
state->resolved_or_rejected = true;
}
struct State {
Napi::Promise::Deferred deferred;
PromiseInfo info;
bool resolved_or_rejected = false;
};
PromiseBase(Napi::Env env, const PromiseInfo& info)
: state(new State{Napi::Promise::Deferred::New(env), info}) {
state->deferred.Promise().AddFinalizer(
[](Napi::Env, State* state) {
// TODO(https://github.com/gpuweb/cts/issues/784):
// Devices are never destroyed, so we always end up
// leaking the Device.lost promise. Enable this once
// fixed.
if ((false)) {
if (!state->resolved_or_rejected) {
::wgpu::utils::Fatal("Promise not resolved or rejected",
state->info.file, state->info.line,
state->info.function);
}
}
delete state;
},
state);
}
State* const state;
};
} // namespace detail
// Promise<T> is a templated wrapper around a JavaScript promise, which can
// resolve to the template type T.
template <typename T>
class Promise : public detail::PromiseBase {
public:
// Constructor
Promise(Napi::Env env, const PromiseInfo& info) : PromiseBase(env, info) {
}
// Resolve() fulfills the promise with the given value.
void Resolve(T&& value) const {
PromiseBase::Resolve(ToJS(state->deferred.Env(), std::forward<T>(value)));
}
};
// Specialization for Promises that resolve with no value
template <>
class Promise<void> : public detail::PromiseBase {
public:
// Constructor
Promise(Napi::Env env, const PromiseInfo& info) : PromiseBase(env, info) {
}
// Resolve() fulfills the promise.
void Resolve() const {
PromiseBase::Resolve(state->deferred.Env().Undefined());
}
};
////////////////////////////////////////////////////////////////////////////////
// Converter<T>
////////////////////////////////////////////////////////////////////////////////
// Converter<T> is specialized for each type T which can be converted from C++
// to JavaScript, or JavaScript to C++.
// Each specialization of Converter<T> is expected to have two static methods
// with the signatures:
//
// // FromJS() converts the JavaScript value 'in' to the C++ value 'out'.
// static Result FromJS(Napi::Env, Napi::Value in, T& out);
//
// // ToJS() converts the C++ value 'in' to a JavaScript value, and returns
// // this value.
// static Napi::Value ToJS(Napi::Env, T in);
template <typename T>
class Converter {};
template <>
class Converter<Napi::Object> {
public:
static inline Result FromJS(Napi::Env, Napi::Value value, Napi::Object& out) {
if (value.IsObject()) {
out = value.ToObject();
return Success;
}
return Error("value is not an object");
}
static inline Napi::Value ToJS(Napi::Env, Napi::Object value) {
return value;
}
};
template <>
class Converter<ArrayBuffer> {
public:
static inline Result FromJS(Napi::Env, Napi::Value value, ArrayBuffer& out) {
if (value.IsArrayBuffer()) {
out = value.As<ArrayBuffer>();
return Success;
}
return Error("value is not a ArrayBuffer");
};
static inline Napi::Value ToJS(Napi::Env, ArrayBuffer value) {
return value;
}
};
template <>
class Converter<Napi::TypedArray> {
public:
static inline Result FromJS(Napi::Env, Napi::Value value, Napi::TypedArray& out) {
if (value.IsTypedArray()) {
out = value.As<Napi::TypedArray>();
return Success;
}
return Error("value is not a TypedArray");
};
static inline Napi::Value ToJS(Napi::Env, ArrayBuffer value) {
return value;
}
};
template <typename T>
class Converter<Napi::TypedArrayOf<T>> {
public:
// clang-format off
// The Napi element type of T
static constexpr napi_typedarray_type element_type =
std::is_same<T, int8_t>::value ? napi_int8_array
: std::is_same<T, uint8_t>::value ? napi_uint8_array
: std::is_same<T, int16_t>::value ? napi_int16_array
: std::is_same<T, uint16_t>::value ? napi_uint16_array
: std::is_same<T, int32_t>::value ? napi_int32_array
: std::is_same<T, uint32_t>::value ? napi_uint32_array
: std::is_same<T, float>::value ? napi_float32_array
: std::is_same<T, double>::value ? napi_float64_array
: std::is_same<T, int64_t>::value ? napi_bigint64_array
: std::is_same<T, uint64_t>::value ? napi_biguint64_array
: static_cast<napi_typedarray_type>(-1);
// clang-format on
static_assert(static_cast<int>(element_type) >= 0,
"unsupported T type for Napi::TypedArrayOf<T>");
static inline Result FromJS(Napi::Env, Napi::Value value, Napi::TypedArrayOf<T>& out) {
if (value.IsTypedArray()) {
auto arr = value.As<Napi::TypedArrayOf<T>>();
if (arr.TypedArrayType() == element_type) {
out = arr;
return Success;
}
return Error("value is not a TypedArray of the correct element type");
}
return Error("value is not a TypedArray");
};
static inline Napi::Value ToJS(Napi::Env, ArrayBuffer value) {
return value;
}
};
template <>
class Converter<std::string> {
public:
static Result FromJS(Napi::Env, Napi::Value, std::string&);
static Napi::Value ToJS(Napi::Env, std::string);
};
template <>
class Converter<bool> {
public:
static Result FromJS(Napi::Env, Napi::Value, bool&);
static Napi::Value ToJS(Napi::Env, bool);
};
template <>
class Converter<int8_t> {
public:
static Result FromJS(Napi::Env, Napi::Value, int8_t&);
static Napi::Value ToJS(Napi::Env, int8_t);
};
template <>
class Converter<uint8_t> {
public:
static Result FromJS(Napi::Env, Napi::Value, uint8_t&);
static Napi::Value ToJS(Napi::Env, uint8_t);
};
template <>
class Converter<int16_t> {
public:
static Result FromJS(Napi::Env, Napi::Value, int16_t&);
static Napi::Value ToJS(Napi::Env, int16_t);
};
template <>
class Converter<uint16_t> {
public:
static Result FromJS(Napi::Env, Napi::Value, uint16_t&);
static Napi::Value ToJS(Napi::Env, uint16_t);
};
template <>
class Converter<int32_t> {
public:
static Result FromJS(Napi::Env, Napi::Value, int32_t&);
static Napi::Value ToJS(Napi::Env, int32_t);
};
template <>
class Converter<uint32_t> {
public:
static Result FromJS(Napi::Env, Napi::Value, uint32_t&);
static Napi::Value ToJS(Napi::Env, uint32_t);
};
template <>
class Converter<int64_t> {
public:
static Result FromJS(Napi::Env, Napi::Value, int64_t&);
static Napi::Value ToJS(Napi::Env, int64_t);
};
template <>
class Converter<uint64_t> {
public:
static Result FromJS(Napi::Env, Napi::Value, uint64_t&);
static Napi::Value ToJS(Napi::Env, uint64_t);
};
template <>
class Converter<float> {
public:
static Result FromJS(Napi::Env, Napi::Value, float&);
static Napi::Value ToJS(Napi::Env, float);
};
template <>
class Converter<double> {
public:
static Result FromJS(Napi::Env, Napi::Value, double&);
static Napi::Value ToJS(Napi::Env, double);
};
template <typename T>
class Converter<Interface<T>> {
public:
static Result FromJS(Napi::Env env, Napi::Value value, Interface<T>& out) {
if (!value.IsObject()) {
return Error("value is not object");
}
auto obj = value.As<Napi::Object>();
if (!T::Unwrap(obj)) {
return Error("object is not of the correct interface type");
}
out = Interface<T>(obj);
return Success;
}
static Napi::Value ToJS(Napi::Env env, const Interface<T>& value) {
return {env, value};
}
};
template <typename T>
class Converter<std::optional<T>> {
public:
static Result FromJS(Napi::Env env, Napi::Value value, std::optional<T>& out) {
if (value.IsNull() || value.IsUndefined()) {
out.reset();
return Success;
}
T v{};
auto res = Converter<T>::FromJS(env, value, v);
if (!res) {
return res;
}
out = std::move(v);
return Success;
}
static Napi::Value ToJS(Napi::Env env, std::optional<T> value) {
if (value.has_value()) {
return Converter<T>::ToJS(env, value.value());
}
return env.Null();
}
};
template <typename T>
class Converter<std::vector<T>> {
public:
static inline Result FromJS(Napi::Env env, Napi::Value value, std::vector<T>& out) {
if (!value.IsArray()) {
return Error("value is not an array");
}
auto arr = value.As<Napi::Array>();
std::vector<T> vec(arr.Length());
for (size_t i = 0; i < vec.size(); i++) {
auto res = Converter<T>::FromJS(env, arr[static_cast<uint32_t>(i)], vec[i]);
if (!res) {
return res.Append("for array element ", i);
}
}
out = std::move(vec);
return Success;
}
static inline Napi::Value ToJS(Napi::Env env, const std::vector<T>& vec) {
auto arr = Napi::Array::New(env, vec.size());
for (size_t i = 0; i < vec.size(); i++) {
arr.Set(static_cast<uint32_t>(i), Converter<T>::ToJS(env, vec[i]));
}
return arr;
}
};
template <typename K, typename V>
class Converter<std::unordered_map<K, V>> {
public:
static inline Result FromJS(Napi::Env env,
Napi::Value value,
std::unordered_map<K, V>& out) {
if (!value.IsObject()) {
return Error("value is not an object");
}
auto obj = value.ToObject();
auto keys = obj.GetPropertyNames();
std::unordered_map<K, V> map(keys.Length());
for (uint32_t i = 0; i < static_cast<uint32_t>(keys.Length()); i++) {
K key{};
V value{};
auto key_res = Converter<K>::FromJS(env, keys[i], key);
if (!key_res) {
return key_res.Append("for object key");
}
auto value_res = Converter<V>::FromJS(env, obj.Get(keys[i]), value);
if (!value_res) {
return value_res.Append("for object value of key: ", key);
}
map[key] = value;
}
out = std::move(map);
return Success;
}
static inline Napi::Value ToJS(Napi::Env env, std::unordered_map<K, V> value) {
auto obj = Napi::Object::New(env);
for (auto it : value) {
obj.Set(Converter<K>::ToJS(env, it.first), Converter<V>::ToJS(env, it.second));
}
return obj;
}
};
template <typename... TYPES>
class Converter<std::variant<TYPES...>> {
template <typename TY>
static inline Result TryFromJS(Napi::Env env,
Napi::Value value,
std::variant<TYPES...>& out) {
TY v{};
auto res = Converter<TY>::FromJS(env, value, v);
if (!res) {
return Error("no possible types matched");
}
out = std::move(v);
return Success;
}
template <typename T0, typename T1, typename... TN>
static inline Result TryFromJS(Napi::Env env,
Napi::Value value,
std::variant<TYPES...>& out) {
if (TryFromJS<T0>(env, value, out)) {
return Success;
}
return TryFromJS<T1, TN...>(env, value, out);
}
public:
static inline Result FromJS(Napi::Env env, Napi::Value value, std::variant<TYPES...>& out) {
return TryFromJS<TYPES...>(env, value, out);
}
static inline Napi::Value ToJS(Napi::Env env, std::variant<TYPES...> value) {
return std::visit(
[&](auto&& v) {
using T = std::remove_cv_t<std::remove_reference_t<decltype(v)>>;
return Converter<T>::ToJS(env, v);
},
value);
}
};
template <typename T>
class Converter<Promise<T>> {
public:
static inline Result FromJS(Napi::Env, Napi::Value, Promise<T>&) {
UNIMPLEMENTED();
}
static inline Napi::Value ToJS(Napi::Env, Promise<T> promise) {
return promise;
}
};
////////////////////////////////////////////////////////////////////////////////
// Helpers
////////////////////////////////////////////////////////////////////////////////
// FromJS() is a helper function which delegates to
// Converter<T>::FromJS()
template <typename T>
inline Result FromJS(Napi::Env env, Napi::Value value, T& out) {
return Converter<T>::FromJS(env, value, out);
}
// FromJSOptional() is similar to FromJS(), but if 'value' is either null
// or undefined then 'out' is left unassigned.
template <typename T>
inline Result FromJSOptional(Napi::Env env, Napi::Value value, T& out) {
if (value.IsNull() || value.IsUndefined()) {
return Success;
}
return Converter<T>::FromJS(env, value, out);
}
// ToJS() is a helper function which delegates to Converter<T>::ToJS()
template <typename T>
inline Napi::Value ToJS(Napi::Env env, T&& value) {
return Converter<std::remove_cv_t<std::remove_reference_t<T>>>::ToJS(
env, std::forward<T>(value));
}
// DefaultedParameter can be used in the tuple parameter types passed to
// FromJS(const Napi::CallbackInfo& info, PARAM_TYPES& args), for parameters
// that have a default value. If the argument is omitted in the call, then
// DefaultedParameter::default_value will be assigned to
// DefaultedParameter::value.
template <typename T>
struct DefaultedParameter {
T value; // The argument value assigned by FromJS()
T default_value; // The default value if no argument supplied
// Implicit conversion operator. Returns value.
inline operator const T&() const {
return value;
}
};
// IsDefaultedParameter<T>::value is true iff T is of type DefaultedParameter.
template <typename T>
struct IsDefaultedParameter {
static constexpr bool value = false;
};
template <typename T>
struct IsDefaultedParameter<DefaultedParameter<T>> {
static constexpr bool value = true;
};
// FromJS() is a helper function for bulk converting the arguments of 'info'.
// PARAM_TYPES is a std::tuple<> describing the C++ function parameter types.
// Parameters may be of the templated DefaultedParameter type, in which case
// the parameter will default to the default-value if omitted.
template <typename PARAM_TYPES, int BASE_INDEX = 0>
inline Result FromJS(const Napi::CallbackInfo& info, PARAM_TYPES& args) {
if constexpr (BASE_INDEX < std::tuple_size_v<PARAM_TYPES>) {
using T = std::tuple_element_t<BASE_INDEX, PARAM_TYPES>;
auto& value = info[BASE_INDEX];
auto& out = std::get<BASE_INDEX>(args);
if constexpr (IsDefaultedParameter<T>::value) {
// Parameter has a default value.
// Check whether the argument was provided.
if (value.IsNull() || value.IsUndefined()) {
// Use default value for this parameter
out.value = out.default_value;
} else {
// Argument was provided
auto res = FromJS(info.Env(), value, out.value);
if (!res) {
return res;
}
}
} else {
// Parameter does not have a default value.
auto res = FromJS(info.Env(), value, out);
if (!res) {
return res;
}
}
// Convert the rest of the arguments
return FromJS<PARAM_TYPES, BASE_INDEX + 1>(info, args);
} else {
return Success;
}
}
} // namespace wgpu::interop
#endif // DAWN_NODE_INTEROP_CORE_WEBGPU_H_