blob: 2ba01a4e8cb85b256265f1113736334f75ba129f [file] [log] [blame] [edit]
// Copyright 2021 The Dawn & Tint Authors
//
// Redistribution and use in source and binary forms, with or without
// modification, are permitted provided that the following conditions are met:
//
// 1. Redistributions of source code must retain the above copyright notice, this
// list of conditions and the following disclaimer.
//
// 2. Redistributions in binary form must reproduce the above copyright notice,
// this list of conditions and the following disclaimer in the documentation
// and/or other materials provided with the distribution.
//
// 3. Neither the name of the copyright holder nor the names of its
// contributors may be used to endorse or promote products derived from
// this software without specific prior written permission.
//
// THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS "AS IS"
// AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE
// IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE ARE
// DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT HOLDER OR CONTRIBUTORS BE LIABLE
// FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL
// DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR
// SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER
// CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY,
// OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE
// OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE.
#include "src/dawn/node/binding/Converter.h"
#include <cassert>
#include "src/dawn/node/binding/GPUBuffer.h"
#include "src/dawn/node/binding/GPUPipelineLayout.h"
#include "src/dawn/node/binding/GPUQuerySet.h"
#include "src/dawn/node/binding/GPUSampler.h"
#include "src/dawn/node/binding/GPUShaderModule.h"
#include "src/dawn/node/binding/GPUTexture.h"
#include "src/dawn/node/binding/GPUTextureView.h"
#include "src/dawn/node/utils/Debug.h"
namespace wgpu::binding {
Converter::~Converter() {
for (auto& free : free_) {
free();
}
}
bool Converter::HasFeature(wgpu::FeatureName feature) {
// Not all uses of the converter will have a device (for example for adapter-related
// conversions).
assert(device.Get() != nullptr);
return device.HasFeature(feature);
}
bool Converter::Convert(wgpu::Extent3D& out, const interop::GPUExtent3D& in) {
out = {};
if (auto* dict = std::get_if<interop::GPUExtent3DDict>(&in)) {
out.depthOrArrayLayers = dict->depthOrArrayLayers;
out.width = dict->width;
out.height = dict->height;
return true;
}
if (auto* vec = std::get_if<std::vector<interop::GPUIntegerCoordinate>>(&in)) {
switch (vec->size()) {
default:
case 3:
out.depthOrArrayLayers = (*vec)[2];
case 2: // fallthrough
out.height = (*vec)[1];
case 1: // fallthrough
out.width = (*vec)[0];
return true;
case 0:
break;
}
}
Napi::Error::New(env, "invalid value for GPUExtent3D").ThrowAsJavaScriptException();
return false;
}
bool Converter::Convert(wgpu::Origin3D& out, const interop::GPUOrigin3DDict& in) {
out = {};
out.x = in.x;
out.y = in.y;
out.z = in.z;
return true;
}
bool Converter::Convert(wgpu::Color& out, const interop::GPUColor& in) {
out = {};
if (auto* dict = std::get_if<interop::GPUColorDict>(&in)) {
out.r = dict->r;
out.g = dict->g;
out.b = dict->b;
out.a = dict->a;
return true;
}
if (auto* vec = std::get_if<std::vector<double>>(&in)) {
switch (vec->size()) {
default:
case 4:
out.a = (*vec)[3];
case 3: // fallthrough
out.b = (*vec)[2];
case 2: // fallthrough
out.g = (*vec)[1];
case 1: // fallthrough
out.r = (*vec)[0];
return true;
case 0:
break;
}
}
Napi::Error::New(env, "invalid value for GPUColor").ThrowAsJavaScriptException();
return false;
}
bool Converter::Convert(wgpu::Origin3D& out, const std::vector<interop::GPUIntegerCoordinate>& in) {
out = {};
switch (in.size()) {
default:
case 3:
out.z = in[2];
case 2: // fallthrough
out.y = in[1];
case 1: // fallthrough
out.x = in[0];
case 0:
break;
}
return true;
}
bool Converter::Convert(wgpu::TextureAspect& out, const interop::GPUTextureAspect& in) {
out = wgpu::TextureAspect::All;
switch (in) {
case interop::GPUTextureAspect::kAll:
out = wgpu::TextureAspect::All;
return true;
case interop::GPUTextureAspect::kStencilOnly:
out = wgpu::TextureAspect::StencilOnly;
return true;
case interop::GPUTextureAspect::kDepthOnly:
out = wgpu::TextureAspect::DepthOnly;
return true;
}
Napi::Error::New(env, "invalid value for GPUTextureAspect").ThrowAsJavaScriptException();
return false;
}
bool Converter::Convert(wgpu::ImageCopyTexture& out, const interop::GPUImageCopyTexture& in) {
out = {};
return Convert(out.texture, in.texture) && Convert(out.mipLevel, in.mipLevel) &&
Convert(out.origin, in.origin) && Convert(out.aspect, in.aspect);
}
bool Converter::Convert(wgpu::ImageCopyBuffer& out, const interop::GPUImageCopyBuffer& in) {
out = {};
out.buffer = *in.buffer.As<GPUBuffer>();
return Convert(out.layout.offset, in.offset) &&
Convert(out.layout.bytesPerRow, in.bytesPerRow) &&
Convert(out.layout.rowsPerImage, in.rowsPerImage);
}
bool Converter::Convert(BufferSource& out, interop::BufferSource in) {
out = {};
if (auto* view = std::get_if<interop::ArrayBufferView>(&in)) {
std::visit(
[&](auto&& v) {
auto arr = v.ArrayBuffer();
out.data = static_cast<uint8_t*>(arr.Data()) + v.ByteOffset();
out.size = v.ByteLength();
out.bytesPerElement = v.ElementSize();
},
*view);
return true;
}
if (auto* arr = std::get_if<interop::ArrayBuffer>(&in)) {
out.data = arr->Data();
out.size = arr->ByteLength();
out.bytesPerElement = 1;
return true;
}
Napi::Error::New(env, "invalid value for BufferSource").ThrowAsJavaScriptException();
return false;
}
bool Converter::Convert(wgpu::TextureDataLayout& out, const interop::GPUImageDataLayout& in) {
out = {};
return Convert(out.bytesPerRow, in.bytesPerRow) && Convert(out.offset, in.offset) &&
Convert(out.rowsPerImage, in.rowsPerImage);
}
bool Converter::Convert(wgpu::TextureFormat& out, const interop::GPUTextureFormat& in) {
out = wgpu::TextureFormat::Undefined;
wgpu::FeatureName requiredFeature = wgpu::FeatureName::Undefined;
switch (in) {
case interop::GPUTextureFormat::kR8Unorm:
out = wgpu::TextureFormat::R8Unorm;
return true;
case interop::GPUTextureFormat::kR8Snorm:
out = wgpu::TextureFormat::R8Snorm;
return true;
case interop::GPUTextureFormat::kR8Uint:
out = wgpu::TextureFormat::R8Uint;
return true;
case interop::GPUTextureFormat::kR8Sint:
out = wgpu::TextureFormat::R8Sint;
return true;
case interop::GPUTextureFormat::kR16Uint:
out = wgpu::TextureFormat::R16Uint;
return true;
case interop::GPUTextureFormat::kR16Sint:
out = wgpu::TextureFormat::R16Sint;
return true;
case interop::GPUTextureFormat::kR16Float:
out = wgpu::TextureFormat::R16Float;
return true;
case interop::GPUTextureFormat::kRg8Unorm:
out = wgpu::TextureFormat::RG8Unorm;
return true;
case interop::GPUTextureFormat::kRg8Snorm:
out = wgpu::TextureFormat::RG8Snorm;
return true;
case interop::GPUTextureFormat::kRg8Uint:
out = wgpu::TextureFormat::RG8Uint;
return true;
case interop::GPUTextureFormat::kRg8Sint:
out = wgpu::TextureFormat::RG8Sint;
return true;
case interop::GPUTextureFormat::kR32Uint:
out = wgpu::TextureFormat::R32Uint;
return true;
case interop::GPUTextureFormat::kR32Sint:
out = wgpu::TextureFormat::R32Sint;
return true;
case interop::GPUTextureFormat::kR32Float:
out = wgpu::TextureFormat::R32Float;
return true;
case interop::GPUTextureFormat::kRg16Uint:
out = wgpu::TextureFormat::RG16Uint;
return true;
case interop::GPUTextureFormat::kRg16Sint:
out = wgpu::TextureFormat::RG16Sint;
return true;
case interop::GPUTextureFormat::kRg16Float:
out = wgpu::TextureFormat::RG16Float;
return true;
case interop::GPUTextureFormat::kRgba8Unorm:
out = wgpu::TextureFormat::RGBA8Unorm;
return true;
case interop::GPUTextureFormat::kRgba8UnormSrgb:
out = wgpu::TextureFormat::RGBA8UnormSrgb;
return true;
case interop::GPUTextureFormat::kRgba8Snorm:
out = wgpu::TextureFormat::RGBA8Snorm;
return true;
case interop::GPUTextureFormat::kRgba8Uint:
out = wgpu::TextureFormat::RGBA8Uint;
return true;
case interop::GPUTextureFormat::kRgba8Sint:
out = wgpu::TextureFormat::RGBA8Sint;
return true;
case interop::GPUTextureFormat::kBgra8Unorm:
out = wgpu::TextureFormat::BGRA8Unorm;
return true;
case interop::GPUTextureFormat::kBgra8UnormSrgb:
out = wgpu::TextureFormat::BGRA8UnormSrgb;
return true;
case interop::GPUTextureFormat::kRgb9E5Ufloat:
out = wgpu::TextureFormat::RGB9E5Ufloat;
return true;
case interop::GPUTextureFormat::kRgb10A2Uint:
out = wgpu::TextureFormat::RGB10A2Uint;
return true;
case interop::GPUTextureFormat::kRgb10A2Unorm:
out = wgpu::TextureFormat::RGB10A2Unorm;
return true;
case interop::GPUTextureFormat::kRg11B10Ufloat:
out = wgpu::TextureFormat::RG11B10Ufloat;
return true;
case interop::GPUTextureFormat::kRg32Uint:
out = wgpu::TextureFormat::RG32Uint;
return true;
case interop::GPUTextureFormat::kRg32Sint:
out = wgpu::TextureFormat::RG32Sint;
return true;
case interop::GPUTextureFormat::kRg32Float:
out = wgpu::TextureFormat::RG32Float;
return true;
case interop::GPUTextureFormat::kRgba16Uint:
out = wgpu::TextureFormat::RGBA16Uint;
return true;
case interop::GPUTextureFormat::kRgba16Sint:
out = wgpu::TextureFormat::RGBA16Sint;
return true;
case interop::GPUTextureFormat::kRgba16Float:
out = wgpu::TextureFormat::RGBA16Float;
return true;
case interop::GPUTextureFormat::kRgba32Uint:
out = wgpu::TextureFormat::RGBA32Uint;
return true;
case interop::GPUTextureFormat::kRgba32Sint:
out = wgpu::TextureFormat::RGBA32Sint;
return true;
case interop::GPUTextureFormat::kRgba32Float:
out = wgpu::TextureFormat::RGBA32Float;
return true;
case interop::GPUTextureFormat::kStencil8:
out = wgpu::TextureFormat::Stencil8;
return true;
case interop::GPUTextureFormat::kDepth16Unorm:
out = wgpu::TextureFormat::Depth16Unorm;
return true;
case interop::GPUTextureFormat::kDepth24Plus:
out = wgpu::TextureFormat::Depth24Plus;
return true;
case interop::GPUTextureFormat::kDepth24PlusStencil8:
out = wgpu::TextureFormat::Depth24PlusStencil8;
return true;
case interop::GPUTextureFormat::kDepth32Float:
out = wgpu::TextureFormat::Depth32Float;
return true;
case interop::GPUTextureFormat::kDepth32FloatStencil8:
out = wgpu::TextureFormat::Depth32FloatStencil8;
requiredFeature = wgpu::FeatureName::Depth32FloatStencil8;
break;
case interop::GPUTextureFormat::kBc1RgbaUnorm:
out = wgpu::TextureFormat::BC1RGBAUnorm;
requiredFeature = wgpu::FeatureName::TextureCompressionBC;
break;
case interop::GPUTextureFormat::kBc1RgbaUnormSrgb:
out = wgpu::TextureFormat::BC1RGBAUnormSrgb;
requiredFeature = wgpu::FeatureName::TextureCompressionBC;
break;
case interop::GPUTextureFormat::kBc2RgbaUnorm:
out = wgpu::TextureFormat::BC2RGBAUnorm;
requiredFeature = wgpu::FeatureName::TextureCompressionBC;
break;
case interop::GPUTextureFormat::kBc2RgbaUnormSrgb:
out = wgpu::TextureFormat::BC2RGBAUnormSrgb;
requiredFeature = wgpu::FeatureName::TextureCompressionBC;
break;
case interop::GPUTextureFormat::kBc3RgbaUnorm:
out = wgpu::TextureFormat::BC3RGBAUnorm;
requiredFeature = wgpu::FeatureName::TextureCompressionBC;
break;
case interop::GPUTextureFormat::kBc3RgbaUnormSrgb:
out = wgpu::TextureFormat::BC3RGBAUnormSrgb;
requiredFeature = wgpu::FeatureName::TextureCompressionBC;
break;
case interop::GPUTextureFormat::kBc4RUnorm:
out = wgpu::TextureFormat::BC4RUnorm;
requiredFeature = wgpu::FeatureName::TextureCompressionBC;
break;
case interop::GPUTextureFormat::kBc4RSnorm:
out = wgpu::TextureFormat::BC4RSnorm;
requiredFeature = wgpu::FeatureName::TextureCompressionBC;
break;
case interop::GPUTextureFormat::kBc5RgUnorm:
out = wgpu::TextureFormat::BC5RGUnorm;
requiredFeature = wgpu::FeatureName::TextureCompressionBC;
break;
case interop::GPUTextureFormat::kBc5RgSnorm:
out = wgpu::TextureFormat::BC5RGSnorm;
requiredFeature = wgpu::FeatureName::TextureCompressionBC;
break;
case interop::GPUTextureFormat::kBc6HRgbUfloat:
out = wgpu::TextureFormat::BC6HRGBUfloat;
requiredFeature = wgpu::FeatureName::TextureCompressionBC;
break;
case interop::GPUTextureFormat::kBc6HRgbFloat:
out = wgpu::TextureFormat::BC6HRGBFloat;
requiredFeature = wgpu::FeatureName::TextureCompressionBC;
break;
case interop::GPUTextureFormat::kBc7RgbaUnorm:
out = wgpu::TextureFormat::BC7RGBAUnorm;
requiredFeature = wgpu::FeatureName::TextureCompressionBC;
break;
case interop::GPUTextureFormat::kBc7RgbaUnormSrgb:
out = wgpu::TextureFormat::BC7RGBAUnormSrgb;
requiredFeature = wgpu::FeatureName::TextureCompressionBC;
break;
case interop::GPUTextureFormat::kEtc2Rgb8Unorm:
out = wgpu::TextureFormat::ETC2RGB8Unorm;
requiredFeature = wgpu::FeatureName::TextureCompressionETC2;
break;
case interop::GPUTextureFormat::kEtc2Rgb8UnormSrgb:
out = wgpu::TextureFormat::ETC2RGB8UnormSrgb;
requiredFeature = wgpu::FeatureName::TextureCompressionETC2;
break;
case interop::GPUTextureFormat::kEtc2Rgb8A1Unorm:
out = wgpu::TextureFormat::ETC2RGB8A1Unorm;
requiredFeature = wgpu::FeatureName::TextureCompressionETC2;
break;
case interop::GPUTextureFormat::kEtc2Rgb8A1UnormSrgb:
out = wgpu::TextureFormat::ETC2RGB8A1UnormSrgb;
requiredFeature = wgpu::FeatureName::TextureCompressionETC2;
break;
case interop::GPUTextureFormat::kEtc2Rgba8Unorm:
out = wgpu::TextureFormat::ETC2RGBA8Unorm;
requiredFeature = wgpu::FeatureName::TextureCompressionETC2;
break;
case interop::GPUTextureFormat::kEtc2Rgba8UnormSrgb:
out = wgpu::TextureFormat::ETC2RGBA8UnormSrgb;
requiredFeature = wgpu::FeatureName::TextureCompressionETC2;
break;
case interop::GPUTextureFormat::kEacR11Unorm:
out = wgpu::TextureFormat::EACR11Unorm;
requiredFeature = wgpu::FeatureName::TextureCompressionETC2;
break;
case interop::GPUTextureFormat::kEacR11Snorm:
out = wgpu::TextureFormat::EACR11Snorm;
requiredFeature = wgpu::FeatureName::TextureCompressionETC2;
break;
case interop::GPUTextureFormat::kEacRg11Unorm:
out = wgpu::TextureFormat::EACRG11Unorm;
requiredFeature = wgpu::FeatureName::TextureCompressionETC2;
break;
case interop::GPUTextureFormat::kEacRg11Snorm:
out = wgpu::TextureFormat::EACRG11Snorm;
requiredFeature = wgpu::FeatureName::TextureCompressionETC2;
break;
case interop::GPUTextureFormat::kAstc4X4Unorm:
out = wgpu::TextureFormat::ASTC4x4Unorm;
requiredFeature = wgpu::FeatureName::TextureCompressionASTC;
break;
case interop::GPUTextureFormat::kAstc4X4UnormSrgb:
out = wgpu::TextureFormat::ASTC4x4UnormSrgb;
requiredFeature = wgpu::FeatureName::TextureCompressionASTC;
break;
case interop::GPUTextureFormat::kAstc5X4Unorm:
out = wgpu::TextureFormat::ASTC5x4Unorm;
requiredFeature = wgpu::FeatureName::TextureCompressionASTC;
break;
case interop::GPUTextureFormat::kAstc5X4UnormSrgb:
out = wgpu::TextureFormat::ASTC5x4UnormSrgb;
requiredFeature = wgpu::FeatureName::TextureCompressionASTC;
break;
case interop::GPUTextureFormat::kAstc5X5Unorm:
out = wgpu::TextureFormat::ASTC5x5Unorm;
requiredFeature = wgpu::FeatureName::TextureCompressionASTC;
break;
case interop::GPUTextureFormat::kAstc5X5UnormSrgb:
out = wgpu::TextureFormat::ASTC5x5UnormSrgb;
requiredFeature = wgpu::FeatureName::TextureCompressionASTC;
break;
case interop::GPUTextureFormat::kAstc6X5Unorm:
out = wgpu::TextureFormat::ASTC6x5Unorm;
requiredFeature = wgpu::FeatureName::TextureCompressionASTC;
break;
case interop::GPUTextureFormat::kAstc6X5UnormSrgb:
out = wgpu::TextureFormat::ASTC6x5UnormSrgb;
requiredFeature = wgpu::FeatureName::TextureCompressionASTC;
break;
case interop::GPUTextureFormat::kAstc6X6Unorm:
out = wgpu::TextureFormat::ASTC6x6Unorm;
requiredFeature = wgpu::FeatureName::TextureCompressionASTC;
break;
case interop::GPUTextureFormat::kAstc6X6UnormSrgb:
out = wgpu::TextureFormat::ASTC6x6UnormSrgb;
requiredFeature = wgpu::FeatureName::TextureCompressionASTC;
break;
case interop::GPUTextureFormat::kAstc8X5Unorm:
out = wgpu::TextureFormat::ASTC8x5Unorm;
requiredFeature = wgpu::FeatureName::TextureCompressionASTC;
break;
case interop::GPUTextureFormat::kAstc8X5UnormSrgb:
out = wgpu::TextureFormat::ASTC8x5UnormSrgb;
requiredFeature = wgpu::FeatureName::TextureCompressionASTC;
break;
case interop::GPUTextureFormat::kAstc8X6Unorm:
out = wgpu::TextureFormat::ASTC8x6Unorm;
requiredFeature = wgpu::FeatureName::TextureCompressionASTC;
break;
case interop::GPUTextureFormat::kAstc8X6UnormSrgb:
out = wgpu::TextureFormat::ASTC8x6UnormSrgb;
requiredFeature = wgpu::FeatureName::TextureCompressionASTC;
break;
case interop::GPUTextureFormat::kAstc8X8Unorm:
out = wgpu::TextureFormat::ASTC8x8Unorm;
requiredFeature = wgpu::FeatureName::TextureCompressionASTC;
break;
case interop::GPUTextureFormat::kAstc8X8UnormSrgb:
out = wgpu::TextureFormat::ASTC8x8UnormSrgb;
requiredFeature = wgpu::FeatureName::TextureCompressionASTC;
break;
case interop::GPUTextureFormat::kAstc10X5Unorm:
out = wgpu::TextureFormat::ASTC10x5Unorm;
requiredFeature = wgpu::FeatureName::TextureCompressionASTC;
break;
case interop::GPUTextureFormat::kAstc10X5UnormSrgb:
out = wgpu::TextureFormat::ASTC10x5UnormSrgb;
requiredFeature = wgpu::FeatureName::TextureCompressionASTC;
break;
case interop::GPUTextureFormat::kAstc10X6Unorm:
out = wgpu::TextureFormat::ASTC10x6Unorm;
requiredFeature = wgpu::FeatureName::TextureCompressionASTC;
break;
case interop::GPUTextureFormat::kAstc10X6UnormSrgb:
out = wgpu::TextureFormat::ASTC10x6UnormSrgb;
requiredFeature = wgpu::FeatureName::TextureCompressionASTC;
break;
case interop::GPUTextureFormat::kAstc10X8Unorm:
out = wgpu::TextureFormat::ASTC10x8Unorm;
requiredFeature = wgpu::FeatureName::TextureCompressionASTC;
break;
case interop::GPUTextureFormat::kAstc10X8UnormSrgb:
out = wgpu::TextureFormat::ASTC10x8UnormSrgb;
requiredFeature = wgpu::FeatureName::TextureCompressionASTC;
break;
case interop::GPUTextureFormat::kAstc10X10Unorm:
out = wgpu::TextureFormat::ASTC10x10Unorm;
requiredFeature = wgpu::FeatureName::TextureCompressionASTC;
break;
case interop::GPUTextureFormat::kAstc10X10UnormSrgb:
out = wgpu::TextureFormat::ASTC10x10UnormSrgb;
requiredFeature = wgpu::FeatureName::TextureCompressionASTC;
break;
case interop::GPUTextureFormat::kAstc12X10Unorm:
out = wgpu::TextureFormat::ASTC12x10Unorm;
requiredFeature = wgpu::FeatureName::TextureCompressionASTC;
break;
case interop::GPUTextureFormat::kAstc12X10UnormSrgb:
out = wgpu::TextureFormat::ASTC12x10UnormSrgb;
requiredFeature = wgpu::FeatureName::TextureCompressionASTC;
break;
case interop::GPUTextureFormat::kAstc12X12Unorm:
out = wgpu::TextureFormat::ASTC12x12Unorm;
requiredFeature = wgpu::FeatureName::TextureCompressionASTC;
break;
case interop::GPUTextureFormat::kAstc12X12UnormSrgb:
out = wgpu::TextureFormat::ASTC12x12UnormSrgb;
requiredFeature = wgpu::FeatureName::TextureCompressionASTC;
break;
default:
Napi::Error::New(env, "invalid value for GPUTextureFormat")
.ThrowAsJavaScriptException();
return false;
}
assert(requiredFeature != wgpu::FeatureName::Undefined);
if (!HasFeature(requiredFeature)) {
Napi::TypeError::New(env, "invalid value for GPUTextureFormat")
.ThrowAsJavaScriptException();
return false;
}
return true;
}
bool Converter::Convert(interop::GPUTextureFormat& out, wgpu::TextureFormat in) {
#define CASE(WGPU, INTEROP) \
case wgpu::TextureFormat::WGPU: \
out = interop::GPUTextureFormat::INTEROP; \
return true
switch (in) {
CASE(ASTC10x10Unorm, kAstc10X10Unorm);
CASE(ASTC10x10UnormSrgb, kAstc10X10UnormSrgb);
CASE(ASTC10x5Unorm, kAstc10X5Unorm);
CASE(ASTC10x5UnormSrgb, kAstc10X5UnormSrgb);
CASE(ASTC10x6Unorm, kAstc10X6Unorm);
CASE(ASTC10x6UnormSrgb, kAstc10X6UnormSrgb);
CASE(ASTC10x8Unorm, kAstc10X8Unorm);
CASE(ASTC10x8UnormSrgb, kAstc10X8UnormSrgb);
CASE(ASTC12x10Unorm, kAstc12X10Unorm);
CASE(ASTC12x10UnormSrgb, kAstc12X10UnormSrgb);
CASE(ASTC12x12Unorm, kAstc12X12Unorm);
CASE(ASTC12x12UnormSrgb, kAstc12X12UnormSrgb);
CASE(ASTC4x4Unorm, kAstc4X4Unorm);
CASE(ASTC4x4UnormSrgb, kAstc4X4UnormSrgb);
CASE(ASTC5x4Unorm, kAstc5X4Unorm);
CASE(ASTC5x4UnormSrgb, kAstc5X4UnormSrgb);
CASE(ASTC5x5Unorm, kAstc5X5Unorm);
CASE(ASTC5x5UnormSrgb, kAstc5X5UnormSrgb);
CASE(ASTC6x5Unorm, kAstc6X5Unorm);
CASE(ASTC6x5UnormSrgb, kAstc6X5UnormSrgb);
CASE(ASTC6x6Unorm, kAstc6X6Unorm);
CASE(ASTC6x6UnormSrgb, kAstc6X6UnormSrgb);
CASE(ASTC8x5Unorm, kAstc8X5Unorm);
CASE(ASTC8x5UnormSrgb, kAstc8X5UnormSrgb);
CASE(ASTC8x6Unorm, kAstc8X6Unorm);
CASE(ASTC8x6UnormSrgb, kAstc8X6UnormSrgb);
CASE(ASTC8x8Unorm, kAstc8X8Unorm);
CASE(ASTC8x8UnormSrgb, kAstc8X8UnormSrgb);
CASE(BC1RGBAUnorm, kBc1RgbaUnorm);
CASE(BC1RGBAUnormSrgb, kBc1RgbaUnormSrgb);
CASE(BC2RGBAUnorm, kBc2RgbaUnorm);
CASE(BC2RGBAUnormSrgb, kBc2RgbaUnormSrgb);
CASE(BC3RGBAUnorm, kBc3RgbaUnorm);
CASE(BC3RGBAUnormSrgb, kBc3RgbaUnormSrgb);
CASE(BC4RSnorm, kBc4RSnorm);
CASE(BC4RUnorm, kBc4RUnorm);
CASE(BC5RGSnorm, kBc5RgSnorm);
CASE(BC5RGUnorm, kBc5RgUnorm);
CASE(BC6HRGBFloat, kBc6HRgbFloat);
CASE(BC6HRGBUfloat, kBc6HRgbUfloat);
CASE(BC7RGBAUnorm, kBc7RgbaUnorm);
CASE(BC7RGBAUnormSrgb, kBc7RgbaUnormSrgb);
CASE(BGRA8Unorm, kBgra8Unorm);
CASE(BGRA8UnormSrgb, kBgra8UnormSrgb);
CASE(Depth16Unorm, kDepth16Unorm);
CASE(Depth24Plus, kDepth24Plus);
CASE(Depth24PlusStencil8, kDepth24PlusStencil8);
CASE(Depth32Float, kDepth32Float);
CASE(Depth32FloatStencil8, kDepth32FloatStencil8);
CASE(EACR11Snorm, kEacR11Snorm);
CASE(EACR11Unorm, kEacR11Unorm);
CASE(EACRG11Snorm, kEacRg11Snorm);
CASE(EACRG11Unorm, kEacRg11Unorm);
CASE(ETC2RGB8A1Unorm, kEtc2Rgb8A1Unorm);
CASE(ETC2RGB8A1UnormSrgb, kEtc2Rgb8A1UnormSrgb);
CASE(ETC2RGB8Unorm, kEtc2Rgb8Unorm);
CASE(ETC2RGB8UnormSrgb, kEtc2Rgb8UnormSrgb);
CASE(ETC2RGBA8Unorm, kEtc2Rgba8Unorm);
CASE(ETC2RGBA8UnormSrgb, kEtc2Rgba8UnormSrgb);
CASE(R16Float, kR16Float);
CASE(R16Sint, kR16Sint);
CASE(R16Uint, kR16Uint);
CASE(R32Float, kR32Float);
CASE(R32Sint, kR32Sint);
CASE(R32Uint, kR32Uint);
CASE(R8Sint, kR8Sint);
CASE(R8Snorm, kR8Snorm);
CASE(R8Uint, kR8Uint);
CASE(R8Unorm, kR8Unorm);
CASE(RG11B10Ufloat, kRg11B10Ufloat);
CASE(RG16Float, kRg16Float);
CASE(RG16Sint, kRg16Sint);
CASE(RG16Uint, kRg16Uint);
CASE(RG32Float, kRg32Float);
CASE(RG32Sint, kRg32Sint);
CASE(RG32Uint, kRg32Uint);
CASE(RG8Sint, kRg8Sint);
CASE(RG8Snorm, kRg8Snorm);
CASE(RG8Uint, kRg8Uint);
CASE(RG8Unorm, kRg8Unorm);
CASE(RGB10A2Uint, kRgb10A2Uint);
CASE(RGB10A2Unorm, kRgb10A2Unorm);
CASE(RGB9E5Ufloat, kRgb9E5Ufloat);
CASE(RGBA16Float, kRgba16Float);
CASE(RGBA16Sint, kRgba16Sint);
CASE(RGBA16Uint, kRgba16Uint);
CASE(RGBA32Float, kRgba32Float);
CASE(RGBA32Sint, kRgba32Sint);
CASE(RGBA32Uint, kRgba32Uint);
CASE(RGBA8Sint, kRgba8Sint);
CASE(RGBA8Snorm, kRgba8Snorm);
CASE(RGBA8Uint, kRgba8Uint);
CASE(RGBA8Unorm, kRgba8Unorm);
CASE(RGBA8UnormSrgb, kRgba8UnormSrgb);
CASE(Stencil8, kStencil8);
#undef CASE
case wgpu::TextureFormat::R10X6BG10X6Biplanar420Unorm:
case wgpu::TextureFormat::R16Snorm:
case wgpu::TextureFormat::R16Unorm:
case wgpu::TextureFormat::R8BG8Biplanar420Unorm:
case wgpu::TextureFormat::RG16Snorm:
case wgpu::TextureFormat::RG16Unorm:
case wgpu::TextureFormat::RGBA16Snorm:
case wgpu::TextureFormat::RGBA16Unorm:
case wgpu::TextureFormat::Undefined:
return false;
}
return false;
}
bool Converter::Convert(wgpu::TextureUsage& out, const interop::GPUTextureUsageFlags& in) {
out = static_cast<wgpu::TextureUsage>(in.value);
return true;
}
bool Converter::Convert(interop::GPUTextureUsageFlags& out, wgpu::TextureUsage in) {
out = interop::GPUTextureUsageFlags(static_cast<uint32_t>(out));
return true;
}
bool Converter::Convert(wgpu::ColorWriteMask& out, const interop::GPUColorWriteFlags& in) {
out = static_cast<wgpu::ColorWriteMask>(in.value);
return true;
}
bool Converter::Convert(wgpu::BufferUsage& out, const interop::GPUBufferUsageFlags& in) {
out = static_cast<wgpu::BufferUsage>(in.value);
return true;
}
bool Converter::Convert(interop::GPUBufferUsageFlags& out, wgpu::BufferUsage in) {
out = interop::GPUBufferUsageFlags(static_cast<uint32_t>(out));
return true;
}
bool Converter::Convert(wgpu::MapMode& out, const interop::GPUMapModeFlags& in) {
out = static_cast<wgpu::MapMode>(in.value);
return true;
}
bool Converter::Convert(wgpu::ShaderStage& out, const interop::GPUShaderStageFlags& in) {
out = static_cast<wgpu::ShaderStage>(in.value);
return true;
}
bool Converter::Convert(wgpu::TextureDimension& out, const interop::GPUTextureDimension& in) {
out = wgpu::TextureDimension::e1D;
switch (in) {
case interop::GPUTextureDimension::k1D:
out = wgpu::TextureDimension::e1D;
return true;
case interop::GPUTextureDimension::k2D:
out = wgpu::TextureDimension::e2D;
return true;
case interop::GPUTextureDimension::k3D:
out = wgpu::TextureDimension::e3D;
return true;
}
Napi::Error::New(env, "invalid value for GPUTextureDimension").ThrowAsJavaScriptException();
return false;
}
bool Converter::Convert(interop::GPUTextureDimension& out, wgpu::TextureDimension in) {
switch (in) {
case wgpu::TextureDimension::e1D:
out = interop::GPUTextureDimension::k1D;
return true;
case wgpu::TextureDimension::e2D:
out = interop::GPUTextureDimension::k2D;
return true;
case wgpu::TextureDimension::e3D:
out = interop::GPUTextureDimension::k3D;
return true;
}
return false;
}
bool Converter::Convert(wgpu::TextureViewDimension& out,
const interop::GPUTextureViewDimension& in) {
out = wgpu::TextureViewDimension::Undefined;
switch (in) {
case interop::GPUTextureViewDimension::k1D:
out = wgpu::TextureViewDimension::e1D;
return true;
case interop::GPUTextureViewDimension::k2D:
out = wgpu::TextureViewDimension::e2D;
return true;
case interop::GPUTextureViewDimension::k2DArray:
out = wgpu::TextureViewDimension::e2DArray;
return true;
case interop::GPUTextureViewDimension::kCube:
out = wgpu::TextureViewDimension::Cube;
return true;
case interop::GPUTextureViewDimension::kCubeArray:
out = wgpu::TextureViewDimension::CubeArray;
return true;
case interop::GPUTextureViewDimension::k3D:
out = wgpu::TextureViewDimension::e3D;
return true;
default:
break;
}
Napi::Error::New(env, "invalid value for GPUTextureViewDimension").ThrowAsJavaScriptException();
return false;
}
bool Converter::Convert(wgpu::ProgrammableStageDescriptor& out,
const interop::GPUProgrammableStage& in) {
out = {};
out.module = *in.module.As<GPUShaderModule>();
// Replace nulls in the entryPoint name with another character that's disallowed in
// identifiers. This is so that using "main\0" doesn't match an entryPoint named "main".
// TODO(dawn:1345): Replace with a way to size strings explicitly in webgpu.h
char* entryPoint = Allocate<char>(in.entryPoint.size() + 1);
entryPoint[in.entryPoint.size()] = '\0';
for (size_t i = 0; i < in.entryPoint.size(); i++) {
if (in.entryPoint[i] == '\0') {
entryPoint[i] = '#';
} else {
entryPoint[i] = in.entryPoint[i];
}
}
out.entryPoint = entryPoint;
return Convert(out.constants, out.constantCount, in.constants);
}
bool Converter::Convert(wgpu::ConstantEntry& out,
const std::string& in_name,
wgpu::interop::GPUPipelineConstantValue in_value) {
out.key = in_name.c_str();
out.value = in_value;
return true;
}
bool Converter::Convert(wgpu::BlendComponent& out, const interop::GPUBlendComponent& in) {
out = {};
return Convert(out.operation, in.operation) && Convert(out.dstFactor, in.dstFactor) &&
Convert(out.srcFactor, in.srcFactor);
}
bool Converter::Convert(wgpu::BlendFactor& out, const interop::GPUBlendFactor& in) {
out = wgpu::BlendFactor::Zero;
switch (in) {
case interop::GPUBlendFactor::kZero:
out = wgpu::BlendFactor::Zero;
return true;
case interop::GPUBlendFactor::kOne:
out = wgpu::BlendFactor::One;
return true;
case interop::GPUBlendFactor::kSrc:
out = wgpu::BlendFactor::Src;
return true;
case interop::GPUBlendFactor::kOneMinusSrc:
out = wgpu::BlendFactor::OneMinusSrc;
return true;
case interop::GPUBlendFactor::kSrcAlpha:
out = wgpu::BlendFactor::SrcAlpha;
return true;
case interop::GPUBlendFactor::kOneMinusSrcAlpha:
out = wgpu::BlendFactor::OneMinusSrcAlpha;
return true;
case interop::GPUBlendFactor::kDst:
out = wgpu::BlendFactor::Dst;
return true;
case interop::GPUBlendFactor::kOneMinusDst:
out = wgpu::BlendFactor::OneMinusDst;
return true;
case interop::GPUBlendFactor::kDstAlpha:
out = wgpu::BlendFactor::DstAlpha;
return true;
case interop::GPUBlendFactor::kOneMinusDstAlpha:
out = wgpu::BlendFactor::OneMinusDstAlpha;
return true;
case interop::GPUBlendFactor::kSrcAlphaSaturated:
out = wgpu::BlendFactor::SrcAlphaSaturated;
return true;
case interop::GPUBlendFactor::kConstant:
out = wgpu::BlendFactor::Constant;
return true;
case interop::GPUBlendFactor::kOneMinusConstant:
out = wgpu::BlendFactor::OneMinusConstant;
return true;
default:
break;
}
Napi::Error::New(env, "invalid value for GPUBlendFactor").ThrowAsJavaScriptException();
return false;
}
bool Converter::Convert(wgpu::BlendOperation& out, const interop::GPUBlendOperation& in) {
out = wgpu::BlendOperation::Add;
switch (in) {
case interop::GPUBlendOperation::kAdd:
out = wgpu::BlendOperation::Add;
return true;
case interop::GPUBlendOperation::kSubtract:
out = wgpu::BlendOperation::Subtract;
return true;
case interop::GPUBlendOperation::kReverseSubtract:
out = wgpu::BlendOperation::ReverseSubtract;
return true;
case interop::GPUBlendOperation::kMin:
out = wgpu::BlendOperation::Min;
return true;
case interop::GPUBlendOperation::kMax:
out = wgpu::BlendOperation::Max;
return true;
default:
break;
}
Napi::Error::New(env, "invalid value for GPUBlendOperation").ThrowAsJavaScriptException();
return false;
}
bool Converter::Convert(wgpu::BlendState& out, const interop::GPUBlendState& in) {
out = {};
return Convert(out.alpha, in.alpha) && Convert(out.color, in.color);
}
bool Converter::Convert(wgpu::PrimitiveState& out, const interop::GPUPrimitiveState& in) {
out = {};
if (in.unclippedDepth) {
wgpu::PrimitiveDepthClipControl* depthClip = Allocate<wgpu::PrimitiveDepthClipControl>();
depthClip->unclippedDepth = true;
out.nextInChain = depthClip;
}
return Convert(out.topology, in.topology) &&
Convert(out.stripIndexFormat, in.stripIndexFormat) &&
Convert(out.frontFace, in.frontFace) && Convert(out.cullMode, in.cullMode);
}
bool Converter::Convert(wgpu::ColorTargetState& out, const interop::GPUColorTargetState& in) {
out = {};
return Convert(out.format, in.format) && Convert(out.blend, in.blend) &&
Convert(out.writeMask, in.writeMask);
}
bool Converter::Convert(wgpu::DepthStencilState& out, const interop::GPUDepthStencilState& in) {
out = {};
auto depthWriteDefined = Allocate<wgpu::DepthStencilStateDepthWriteDefinedDawn>();
depthWriteDefined->depthWriteDefined = in.depthWriteEnabled.has_value();
out.nextInChain = depthWriteDefined;
return Convert(out.format, in.format) && Convert(out.depthWriteEnabled, in.depthWriteEnabled) &&
Convert(out.depthCompare, in.depthCompare) &&
Convert(out.stencilFront, in.stencilFront) && Convert(out.stencilBack, in.stencilBack) &&
Convert(out.stencilReadMask, in.stencilReadMask) &&
Convert(out.stencilWriteMask, in.stencilWriteMask) &&
Convert(out.depthBias, in.depthBias) &&
Convert(out.depthBiasSlopeScale, in.depthBiasSlopeScale) &&
Convert(out.depthBiasClamp, in.depthBiasClamp);
}
bool Converter::Convert(wgpu::MultisampleState& out, const interop::GPUMultisampleState& in) {
out = {};
return Convert(out.count, in.count) && Convert(out.mask, in.mask) &&
Convert(out.alphaToCoverageEnabled, in.alphaToCoverageEnabled);
}
bool Converter::Convert(wgpu::FragmentState& out, const interop::GPUFragmentState& in) {
out = {};
return Convert(out.targets, out.targetCount, in.targets) && //
Convert(out.module, in.module) && //
Convert(out.entryPoint, in.entryPoint) && //
Convert(out.constants, out.constantCount, in.constants);
}
bool Converter::Convert(wgpu::PrimitiveTopology& out, const interop::GPUPrimitiveTopology& in) {
out = wgpu::PrimitiveTopology::LineList;
switch (in) {
case interop::GPUPrimitiveTopology::kPointList:
out = wgpu::PrimitiveTopology::PointList;
return true;
case interop::GPUPrimitiveTopology::kLineList:
out = wgpu::PrimitiveTopology::LineList;
return true;
case interop::GPUPrimitiveTopology::kLineStrip:
out = wgpu::PrimitiveTopology::LineStrip;
return true;
case interop::GPUPrimitiveTopology::kTriangleList:
out = wgpu::PrimitiveTopology::TriangleList;
return true;
case interop::GPUPrimitiveTopology::kTriangleStrip:
out = wgpu::PrimitiveTopology::TriangleStrip;
return true;
}
Napi::Error::New(env, "invalid value for GPUPrimitiveTopology").ThrowAsJavaScriptException();
return false;
}
bool Converter::Convert(wgpu::FrontFace& out, const interop::GPUFrontFace& in) {
out = wgpu::FrontFace::CW;
switch (in) {
case interop::GPUFrontFace::kCw:
out = wgpu::FrontFace::CW;
return true;
case interop::GPUFrontFace::kCcw:
out = wgpu::FrontFace::CCW;
return true;
}
Napi::Error::New(env, "invalid value for GPUFrontFace").ThrowAsJavaScriptException();
return false;
}
bool Converter::Convert(wgpu::CullMode& out, const interop::GPUCullMode& in) {
out = wgpu::CullMode::None;
switch (in) {
case interop::GPUCullMode::kNone:
out = wgpu::CullMode::None;
return true;
case interop::GPUCullMode::kFront:
out = wgpu::CullMode::Front;
return true;
case interop::GPUCullMode::kBack:
out = wgpu::CullMode::Back;
return true;
}
Napi::Error::New(env, "invalid value for GPUCullMode").ThrowAsJavaScriptException();
return false;
}
bool Converter::Convert(wgpu::CompareFunction& out, const interop::GPUCompareFunction& in) {
out = wgpu::CompareFunction::Undefined;
switch (in) {
case interop::GPUCompareFunction::kNever:
out = wgpu::CompareFunction::Never;
return true;
case interop::GPUCompareFunction::kLess:
out = wgpu::CompareFunction::Less;
return true;
case interop::GPUCompareFunction::kLessEqual:
out = wgpu::CompareFunction::LessEqual;
return true;
case interop::GPUCompareFunction::kGreater:
out = wgpu::CompareFunction::Greater;
return true;
case interop::GPUCompareFunction::kGreaterEqual:
out = wgpu::CompareFunction::GreaterEqual;
return true;
case interop::GPUCompareFunction::kEqual:
out = wgpu::CompareFunction::Equal;
return true;
case interop::GPUCompareFunction::kNotEqual:
out = wgpu::CompareFunction::NotEqual;
return true;
case interop::GPUCompareFunction::kAlways:
out = wgpu::CompareFunction::Always;
return true;
}
Napi::Error::New(env, "invalid value for GPUCompareFunction").ThrowAsJavaScriptException();
return false;
}
bool Converter::Convert(wgpu::IndexFormat& out, const interop::GPUIndexFormat& in) {
out = wgpu::IndexFormat::Undefined;
switch (in) {
case interop::GPUIndexFormat::kUint16:
out = wgpu::IndexFormat::Uint16;
return true;
case interop::GPUIndexFormat::kUint32:
out = wgpu::IndexFormat::Uint32;
return true;
}
Napi::Error::New(env, "invalid value for GPUIndexFormat").ThrowAsJavaScriptException();
return false;
}
bool Converter::Convert(wgpu::StencilOperation& out, const interop::GPUStencilOperation& in) {
out = wgpu::StencilOperation::Zero;
switch (in) {
case interop::GPUStencilOperation::kKeep:
out = wgpu::StencilOperation::Keep;
return true;
case interop::GPUStencilOperation::kZero:
out = wgpu::StencilOperation::Zero;
return true;
case interop::GPUStencilOperation::kReplace:
out = wgpu::StencilOperation::Replace;
return true;
case interop::GPUStencilOperation::kInvert:
out = wgpu::StencilOperation::Invert;
return true;
case interop::GPUStencilOperation::kIncrementClamp:
out = wgpu::StencilOperation::IncrementClamp;
return true;
case interop::GPUStencilOperation::kDecrementClamp:
out = wgpu::StencilOperation::DecrementClamp;
return true;
case interop::GPUStencilOperation::kIncrementWrap:
out = wgpu::StencilOperation::IncrementWrap;
return true;
case interop::GPUStencilOperation::kDecrementWrap:
out = wgpu::StencilOperation::DecrementWrap;
return true;
}
Napi::Error::New(env, "invalid value for GPUStencilOperation").ThrowAsJavaScriptException();
return false;
}
bool Converter::Convert(wgpu::StencilFaceState& out, const interop::GPUStencilFaceState& in) {
return Convert(out.compare, in.compare) && Convert(out.failOp, in.failOp) &&
Convert(out.depthFailOp, in.depthFailOp) && Convert(out.passOp, in.passOp);
}
bool Converter::Convert(wgpu::VertexBufferLayout& out, const interop::GPUVertexBufferLayout& in) {
out = {};
return Convert(out.attributes, out.attributeCount, in.attributes) &&
Convert(out.arrayStride, in.arrayStride) && Convert(out.stepMode, in.stepMode);
}
bool Converter::Convert(wgpu::VertexState& out, const interop::GPUVertexState& in) {
out = {};
wgpu::VertexBufferLayout* outBuffers = nullptr;
if (!Convert(out.module, in.module) || //
!Convert(outBuffers, out.bufferCount, in.buffers) || //
!Convert(out.entryPoint, in.entryPoint) || //
!Convert(out.constants, out.constantCount, in.constants)) {
return false;
}
// Patch up the unused vertex buffer layouts to use wgpu::VertexStepMode::VertexBufferNotUsed.
// The converter for optional value will have put the default value of wgpu::VertexBufferLayout
// that has wgpu::VertexStepMode::Vertex.
out.buffers = outBuffers;
for (size_t i = 0; i < in.buffers.size(); i++) {
if (!in.buffers[i].has_value()) {
outBuffers[i].stepMode = wgpu::VertexStepMode::VertexBufferNotUsed;
}
}
return true;
}
bool Converter::Convert(wgpu::VertexStepMode& out, const interop::GPUVertexStepMode& in) {
out = wgpu::VertexStepMode::Instance;
switch (in) {
case interop::GPUVertexStepMode::kInstance:
out = wgpu::VertexStepMode::Instance;
return true;
case interop::GPUVertexStepMode::kVertex:
out = wgpu::VertexStepMode::Vertex;
return true;
default:
break;
}
Napi::Error::New(env, "invalid value for GPUVertexStepMode").ThrowAsJavaScriptException();
return false;
}
bool Converter::Convert(wgpu::VertexAttribute& out, const interop::GPUVertexAttribute& in) {
return Convert(out.format, in.format) && Convert(out.offset, in.offset) &&
Convert(out.shaderLocation, in.shaderLocation);
}
bool Converter::Convert(wgpu::VertexFormat& out, const interop::GPUVertexFormat& in) {
out = wgpu::VertexFormat::Undefined;
switch (in) {
case interop::GPUVertexFormat::kUint8X2:
out = wgpu::VertexFormat::Uint8x2;
return true;
case interop::GPUVertexFormat::kUint8X4:
out = wgpu::VertexFormat::Uint8x4;
return true;
case interop::GPUVertexFormat::kSint8X2:
out = wgpu::VertexFormat::Sint8x2;
return true;
case interop::GPUVertexFormat::kSint8X4:
out = wgpu::VertexFormat::Sint8x4;
return true;
case interop::GPUVertexFormat::kUnorm8X2:
out = wgpu::VertexFormat::Unorm8x2;
return true;
case interop::GPUVertexFormat::kUnorm8X4:
out = wgpu::VertexFormat::Unorm8x4;
return true;
case interop::GPUVertexFormat::kSnorm8X2:
out = wgpu::VertexFormat::Snorm8x2;
return true;
case interop::GPUVertexFormat::kSnorm8X4:
out = wgpu::VertexFormat::Snorm8x4;
return true;
case interop::GPUVertexFormat::kUint16X2:
out = wgpu::VertexFormat::Uint16x2;
return true;
case interop::GPUVertexFormat::kUint16X4:
out = wgpu::VertexFormat::Uint16x4;
return true;
case interop::GPUVertexFormat::kSint16X2:
out = wgpu::VertexFormat::Sint16x2;
return true;
case interop::GPUVertexFormat::kSint16X4:
out = wgpu::VertexFormat::Sint16x4;
return true;
case interop::GPUVertexFormat::kUnorm16X2:
out = wgpu::VertexFormat::Unorm16x2;
return true;
case interop::GPUVertexFormat::kUnorm16X4:
out = wgpu::VertexFormat::Unorm16x4;
return true;
case interop::GPUVertexFormat::kSnorm16X2:
out = wgpu::VertexFormat::Snorm16x2;
return true;
case interop::GPUVertexFormat::kSnorm16X4:
out = wgpu::VertexFormat::Snorm16x4;
return true;
case interop::GPUVertexFormat::kFloat16X2:
out = wgpu::VertexFormat::Float16x2;
return true;
case interop::GPUVertexFormat::kFloat16X4:
out = wgpu::VertexFormat::Float16x4;
return true;
case interop::GPUVertexFormat::kFloat32:
out = wgpu::VertexFormat::Float32;
return true;
case interop::GPUVertexFormat::kFloat32X2:
out = wgpu::VertexFormat::Float32x2;
return true;
case interop::GPUVertexFormat::kFloat32X3:
out = wgpu::VertexFormat::Float32x3;
return true;
case interop::GPUVertexFormat::kFloat32X4:
out = wgpu::VertexFormat::Float32x4;
return true;
case interop::GPUVertexFormat::kUint32:
out = wgpu::VertexFormat::Uint32;
return true;
case interop::GPUVertexFormat::kUint32X2:
out = wgpu::VertexFormat::Uint32x2;
return true;
case interop::GPUVertexFormat::kUint32X3:
out = wgpu::VertexFormat::Uint32x3;
return true;
case interop::GPUVertexFormat::kUint32X4:
out = wgpu::VertexFormat::Uint32x4;
return true;
case interop::GPUVertexFormat::kSint32:
out = wgpu::VertexFormat::Sint32;
return true;
case interop::GPUVertexFormat::kSint32X2:
out = wgpu::VertexFormat::Sint32x2;
return true;
case interop::GPUVertexFormat::kSint32X3:
out = wgpu::VertexFormat::Sint32x3;
return true;
case interop::GPUVertexFormat::kSint32X4:
out = wgpu::VertexFormat::Sint32x4;
return true;
case interop::GPUVertexFormat::kUnorm1010102:
out = wgpu::VertexFormat::Unorm10_10_10_2;
return true;
default:
break;
}
Napi::Error::New(env, "invalid value for GPUVertexFormat").ThrowAsJavaScriptException();
return false;
}
bool Converter::Convert(wgpu::RenderPassColorAttachment& out,
const interop::GPURenderPassColorAttachment& in) {
out = {};
return Convert(out.view, in.view) && //
Convert(out.depthSlice, in.depthSlice) && //
Convert(out.resolveTarget, in.resolveTarget) && //
Convert(out.clearValue, in.clearValue) && //
Convert(out.loadOp, in.loadOp) && //
Convert(out.storeOp, in.storeOp);
}
bool Converter::Convert(wgpu::RenderPassDepthStencilAttachment& out,
const interop::GPURenderPassDepthStencilAttachment& in) {
out = {};
return Convert(out.view, in.view) && //
Convert(out.depthClearValue, in.depthClearValue) && //
Convert(out.depthLoadOp, in.depthLoadOp) && //
Convert(out.depthStoreOp, in.depthStoreOp) && //
Convert(out.depthReadOnly, in.depthReadOnly) && //
Convert(out.stencilClearValue, in.stencilClearValue) && //
Convert(out.stencilLoadOp, in.stencilLoadOp) && //
Convert(out.stencilStoreOp, in.stencilStoreOp) && //
Convert(out.stencilReadOnly, in.stencilReadOnly);
}
bool Converter::Convert(wgpu::RenderPassTimestampWrites& out,
const interop::GPURenderPassTimestampWrites& in) {
return Convert(out.querySet, in.querySet) && //
Convert(out.beginningOfPassWriteIndex, in.beginningOfPassWriteIndex) && //
Convert(out.endOfPassWriteIndex, in.endOfPassWriteIndex);
}
bool Converter::Convert(wgpu::ComputePassTimestampWrites& out,
const interop::GPUComputePassTimestampWrites& in) {
return Convert(out.querySet, in.querySet) && //
Convert(out.beginningOfPassWriteIndex, in.beginningOfPassWriteIndex) && //
Convert(out.endOfPassWriteIndex, in.endOfPassWriteIndex);
}
bool Converter::Convert(wgpu::LoadOp& out, const interop::GPULoadOp& in) {
out = wgpu::LoadOp::Clear;
switch (in) {
case interop::GPULoadOp::kLoad:
out = wgpu::LoadOp::Load;
return true;
case interop::GPULoadOp::kClear:
out = wgpu::LoadOp::Clear;
return true;
}
Napi::Error::New(env, "invalid value for GPULoadOp").ThrowAsJavaScriptException();
return false;
}
bool Converter::Convert(wgpu::StoreOp& out, const interop::GPUStoreOp& in) {
out = wgpu::StoreOp::Store;
switch (in) {
case interop::GPUStoreOp::kStore:
out = wgpu::StoreOp::Store;
return true;
case interop::GPUStoreOp::kDiscard:
out = wgpu::StoreOp::Discard;
return true;
}
Napi::Error::New(env, "invalid value for GPUStoreOp").ThrowAsJavaScriptException();
return false;
}
bool Converter::Convert(wgpu::BindGroupEntry& out, const interop::GPUBindGroupEntry& in) {
out = {};
if (!Convert(out.binding, in.binding)) {
return false;
}
if (auto* res = std::get_if<interop::Interface<interop::GPUSampler>>(&in.resource)) {
return Convert(out.sampler, *res);
}
if (auto* res = std::get_if<interop::Interface<interop::GPUTextureView>>(&in.resource)) {
return Convert(out.textureView, *res);
}
if (auto* res = std::get_if<interop::GPUBufferBinding>(&in.resource)) {
auto buffer = res->buffer.As<GPUBuffer>();
out.size = wgpu::kWholeSize;
if (!buffer || !Convert(out.offset, res->offset) || !Convert(out.size, res->size)) {
return false;
}
out.buffer = *buffer;
return true;
}
if (auto* res = std::get_if<interop::Interface<interop::GPUExternalTexture>>(&in.resource)) {
// TODO(crbug.com/dawn/1129): External textures
UNIMPLEMENTED(env, {});
}
Napi::Error::New(env, "invalid value for GPUBindGroupEntry.resource")
.ThrowAsJavaScriptException();
return false;
}
bool Converter::Convert(wgpu::BindGroupLayoutEntry& out,
const interop::GPUBindGroupLayoutEntry& in) {
// TODO(crbug.com/dawn/1129): External textures
return Convert(out.binding, in.binding) && Convert(out.visibility, in.visibility) &&
Convert(out.buffer, in.buffer) && Convert(out.sampler, in.sampler) &&
Convert(out.texture, in.texture) && Convert(out.storageTexture, in.storageTexture);
}
bool Converter::Convert(wgpu::BufferBindingLayout& out, const interop::GPUBufferBindingLayout& in) {
return Convert(out.type, in.type) && Convert(out.hasDynamicOffset, in.hasDynamicOffset) &&
Convert(out.minBindingSize, in.minBindingSize);
}
bool Converter::Convert(wgpu::SamplerBindingLayout& out,
const interop::GPUSamplerBindingLayout& in) {
return Convert(out.type, in.type);
}
bool Converter::Convert(wgpu::TextureBindingLayout& out,
const interop::GPUTextureBindingLayout& in) {
return Convert(out.sampleType, in.sampleType) && Convert(out.viewDimension, in.viewDimension) &&
Convert(out.multisampled, in.multisampled);
}
bool Converter::Convert(wgpu::StorageTextureBindingLayout& out,
const interop::GPUStorageTextureBindingLayout& in) {
return Convert(out.access, in.access) && Convert(out.format, in.format) &&
Convert(out.viewDimension, in.viewDimension);
}
bool Converter::Convert(wgpu::BufferBindingType& out, const interop::GPUBufferBindingType& in) {
out = wgpu::BufferBindingType::Undefined;
switch (in) {
case interop::GPUBufferBindingType::kUniform:
out = wgpu::BufferBindingType::Uniform;
return true;
case interop::GPUBufferBindingType::kStorage:
out = wgpu::BufferBindingType::Storage;
return true;
case interop::GPUBufferBindingType::kReadOnlyStorage:
out = wgpu::BufferBindingType::ReadOnlyStorage;
return true;
}
Napi::Error::New(env, "invalid value for GPUBufferBindingType").ThrowAsJavaScriptException();
return false;
}
bool Converter::Convert(wgpu::TextureSampleType& out, const interop::GPUTextureSampleType& in) {
out = wgpu::TextureSampleType::Undefined;
switch (in) {
case interop::GPUTextureSampleType::kFloat:
out = wgpu::TextureSampleType::Float;
return true;
case interop::GPUTextureSampleType::kUnfilterableFloat:
out = wgpu::TextureSampleType::UnfilterableFloat;
return true;
case interop::GPUTextureSampleType::kDepth:
out = wgpu::TextureSampleType::Depth;
return true;
case interop::GPUTextureSampleType::kSint:
out = wgpu::TextureSampleType::Sint;
return true;
case interop::GPUTextureSampleType::kUint:
out = wgpu::TextureSampleType::Uint;
return true;
}
Napi::Error::New(env, "invalid value for GPUTextureSampleType").ThrowAsJavaScriptException();
return false;
}
bool Converter::Convert(wgpu::SamplerBindingType& out, const interop::GPUSamplerBindingType& in) {
out = wgpu::SamplerBindingType::Undefined;
switch (in) {
case interop::GPUSamplerBindingType::kFiltering:
out = wgpu::SamplerBindingType::Filtering;
return true;
case interop::GPUSamplerBindingType::kNonFiltering:
out = wgpu::SamplerBindingType::NonFiltering;
return true;
case interop::GPUSamplerBindingType::kComparison:
out = wgpu::SamplerBindingType::Comparison;
return true;
}
Napi::Error::New(env, "invalid value for GPUSamplerBindingType").ThrowAsJavaScriptException();
return false;
}
bool Converter::Convert(wgpu::StorageTextureAccess& out,
const interop::GPUStorageTextureAccess& in) {
out = wgpu::StorageTextureAccess::Undefined;
switch (in) {
case interop::GPUStorageTextureAccess::kWriteOnly:
out = wgpu::StorageTextureAccess::WriteOnly;
return true;
case interop::GPUStorageTextureAccess::kReadOnly:
out = wgpu::StorageTextureAccess::ReadOnly;
return true;
case interop::GPUStorageTextureAccess::kReadWrite:
out = wgpu::StorageTextureAccess::ReadWrite;
return true;
}
Napi::Error::New(env, "invalid value for GPUStorageTextureAccess").ThrowAsJavaScriptException();
return false;
}
bool Converter::Convert(wgpu::QueryType& out, const interop::GPUQueryType& in) {
out = wgpu::QueryType::Occlusion;
switch (in) {
case interop::GPUQueryType::kOcclusion:
out = wgpu::QueryType::Occlusion;
return true;
case interop::GPUQueryType::kTimestamp:
if (HasFeature(wgpu::FeatureName::TimestampQuery)) {
out = wgpu::QueryType::Timestamp;
return true;
} else {
Napi::TypeError::New(env, "invalid value for GPUQueryType")
.ThrowAsJavaScriptException();
return false;
}
}
Napi::Error::New(env, "invalid value for GPUQueryType").ThrowAsJavaScriptException();
return false;
}
bool Converter::Convert(wgpu::FeatureName& out, interop::GPUFeatureName in) {
switch (in) {
case interop::GPUFeatureName::kTextureCompressionBc:
out = wgpu::FeatureName::TextureCompressionBC;
return true;
case interop::GPUFeatureName::kTextureCompressionEtc2:
out = wgpu::FeatureName::TextureCompressionETC2;
return true;
case interop::GPUFeatureName::kTextureCompressionAstc:
out = wgpu::FeatureName::TextureCompressionASTC;
return true;
case interop::GPUFeatureName::kTimestampQuery:
out = wgpu::FeatureName::TimestampQuery;
return true;
case interop::GPUFeatureName::kDepth32FloatStencil8:
out = wgpu::FeatureName::Depth32FloatStencil8;
return true;
case interop::GPUFeatureName::kDepthClipControl:
out = wgpu::FeatureName::DepthClipControl;
return true;
case interop::GPUFeatureName::kIndirectFirstInstance:
out = wgpu::FeatureName::IndirectFirstInstance;
return true;
case interop::GPUFeatureName::kShaderF16:
out = wgpu::FeatureName::ShaderF16;
return true;
case interop::GPUFeatureName::kRg11B10UfloatRenderable:
out = wgpu::FeatureName::RG11B10UfloatRenderable;
return true;
case interop::GPUFeatureName::kBgra8UnormStorage:
out = wgpu::FeatureName::BGRA8UnormStorage;
return true;
case interop::GPUFeatureName::kFloat32Filterable:
out = wgpu::FeatureName::Float32Filterable;
return true;
case interop::GPUFeatureName::kChromiumExperimentalSubgroups:
out = wgpu::FeatureName::ChromiumExperimentalSubgroups;
return true;
case interop::GPUFeatureName::kChromiumExperimentalSubgroupUniformControlFlow:
out = wgpu::FeatureName::ChromiumExperimentalSubgroupUniformControlFlow;
return true;
}
return false;
}
bool Converter::Convert(interop::GPUFeatureName& out, wgpu::FeatureName in) {
#define CASE(WGPU, INTEROP) \
case wgpu::FeatureName::WGPU: \
out = interop::GPUFeatureName::INTEROP; \
return true
switch (in) {
CASE(BGRA8UnormStorage, kBgra8UnormStorage);
CASE(ChromiumExperimentalSubgroups, kChromiumExperimentalSubgroups);
CASE(ChromiumExperimentalSubgroupUniformControlFlow,
kChromiumExperimentalSubgroupUniformControlFlow);
CASE(Depth32FloatStencil8, kDepth32FloatStencil8);
CASE(DepthClipControl, kDepthClipControl);
CASE(Float32Filterable, kFloat32Filterable);
CASE(IndirectFirstInstance, kIndirectFirstInstance);
CASE(RG11B10UfloatRenderable, kRg11B10UfloatRenderable);
CASE(ShaderF16, kShaderF16);
CASE(TextureCompressionASTC, kTextureCompressionAstc);
CASE(TextureCompressionBC, kTextureCompressionBc);
CASE(TextureCompressionETC2, kTextureCompressionEtc2);
CASE(TimestampQuery, kTimestampQuery);
#undef CASE
case wgpu::FeatureName::ANGLETextureSharing:
case wgpu::FeatureName::ChromiumExperimentalDp4a:
case wgpu::FeatureName::ChromiumExperimentalReadWriteStorageTexture:
case wgpu::FeatureName::D3D11MultithreadProtected:
case wgpu::FeatureName::DawnInternalUsages:
case wgpu::FeatureName::DawnMultiPlanarFormats:
case wgpu::FeatureName::DawnNative:
case wgpu::FeatureName::DualSourceBlending:
case wgpu::FeatureName::ImplicitDeviceSynchronization:
case wgpu::FeatureName::MSAARenderToSingleSampled:
case wgpu::FeatureName::MultiPlanarFormatExtendedUsages:
case wgpu::FeatureName::MultiPlanarFormatP010:
case wgpu::FeatureName::Norm16TextureFormats:
case wgpu::FeatureName::PixelLocalStorageCoherent:
case wgpu::FeatureName::PixelLocalStorageNonCoherent:
case wgpu::FeatureName::SharedFenceDXGISharedHandle:
case wgpu::FeatureName::SharedFenceMTLSharedEvent:
case wgpu::FeatureName::SharedFenceVkSemaphoreOpaqueFD:
case wgpu::FeatureName::SharedFenceVkSemaphoreSyncFD:
case wgpu::FeatureName::SharedFenceVkSemaphoreZirconHandle:
case wgpu::FeatureName::SharedTextureMemoryAHardwareBuffer:
case wgpu::FeatureName::SharedTextureMemoryD3D11Texture2D:
case wgpu::FeatureName::SharedTextureMemoryDmaBuf:
case wgpu::FeatureName::SharedTextureMemoryDXGISharedHandle:
case wgpu::FeatureName::SharedTextureMemoryEGLImage:
case wgpu::FeatureName::SharedTextureMemoryIOSurface:
case wgpu::FeatureName::SharedTextureMemoryOpaqueFD:
case wgpu::FeatureName::SharedTextureMemoryVkDedicatedAllocation:
case wgpu::FeatureName::SharedTextureMemoryZirconHandle:
case wgpu::FeatureName::SurfaceCapabilities:
case wgpu::FeatureName::ChromiumExperimentalTimestampQueryInsidePasses:
case wgpu::FeatureName::TransientAttachments:
case wgpu::FeatureName::HostMappedPointer:
case wgpu::FeatureName::MultiPlanarRenderTargets:
case wgpu::FeatureName::Undefined:
return false;
}
return false;
}
bool Converter::Convert(interop::GPUQueryType& out, wgpu::QueryType in) {
switch (in) {
case wgpu::QueryType::Occlusion:
out = interop::GPUQueryType::kOcclusion;
return true;
case wgpu::QueryType::Timestamp:
out = interop::GPUQueryType::kTimestamp;
return true;
}
return false;
}
bool Converter::Convert(interop::GPUBufferMapState& out, wgpu::BufferMapState in) {
switch (in) {
case wgpu::BufferMapState::Unmapped:
out = interop::GPUBufferMapState::kUnmapped;
return true;
case wgpu::BufferMapState::Pending:
out = interop::GPUBufferMapState::kPending;
return true;
case wgpu::BufferMapState::Mapped:
out = interop::GPUBufferMapState::kMapped;
return true;
}
return false;
}
bool Converter::Convert(wgpu::AddressMode& out, const interop::GPUAddressMode& in) {
out = wgpu::AddressMode::Repeat;
switch (in) {
case interop::GPUAddressMode::kClampToEdge:
out = wgpu::AddressMode::ClampToEdge;
return true;
case interop::GPUAddressMode::kRepeat:
out = wgpu::AddressMode::Repeat;
return true;
case interop::GPUAddressMode::kMirrorRepeat:
out = wgpu::AddressMode::MirrorRepeat;
return true;
}
Napi::Error::New(env, "invalid value for GPUAddressMode").ThrowAsJavaScriptException();
return false;
}
bool Converter::Convert(wgpu::FilterMode& out, const interop::GPUFilterMode& in) {
out = wgpu::FilterMode::Nearest;
switch (in) {
case interop::GPUFilterMode::kNearest:
out = wgpu::FilterMode::Nearest;
return true;
case interop::GPUFilterMode::kLinear:
out = wgpu::FilterMode::Linear;
return true;
}
Napi::Error::New(env, "invalid value for GPUFilterMode").ThrowAsJavaScriptException();
return false;
}
bool Converter::Convert(wgpu::MipmapFilterMode& out, const interop::GPUMipmapFilterMode& in) {
out = wgpu::MipmapFilterMode::Nearest;
switch (in) {
case interop::GPUMipmapFilterMode::kNearest:
out = wgpu::MipmapFilterMode::Nearest;
return true;
case interop::GPUMipmapFilterMode::kLinear:
out = wgpu::MipmapFilterMode::Linear;
return true;
}
Napi::Error::New(env, "invalid value for GPUMipmapFilterMode").ThrowAsJavaScriptException();
return false;
}
bool Converter::Convert(wgpu::ComputePipelineDescriptor& out,
const interop::GPUComputePipelineDescriptor& in) {
return Convert(out.label, in.label) && //
Convert(out.layout, in.layout) && //
Convert(out.compute, in.compute);
}
bool Converter::Convert(wgpu::RenderPipelineDescriptor& out,
const interop::GPURenderPipelineDescriptor& in) {
return Convert(out.label, in.label) && //
Convert(out.layout, in.layout) && //
Convert(out.vertex, in.vertex) && //
Convert(out.primitive, in.primitive) && //
Convert(out.depthStencil, in.depthStencil) && //
Convert(out.multisample, in.multisample) && //
Convert(out.fragment, in.fragment);
}
bool Converter::Convert(wgpu::PipelineLayout& out, const interop::GPUAutoLayoutMode& in) {
out = nullptr;
return true;
}
bool Converter::Convert(wgpu::Bool& out, const bool& in) {
out = in;
return true;
}
} // namespace wgpu::binding