test/tint/bug/tint/1739.wgsl.expected.msl - dawn - Git at Google

 #include <metal_stdlib>

 using namespace metal;

 template<typename T, size_t N>
 struct tint_array {
     const constant T& operator[](size_t i) const constant { return elements[i]; }
     device T& operator[](size_t i) device { return elements[i]; }
     const device T& operator[](size_t i) const device { return elements[i]; }
     thread T& operator[](size_t i) thread { return elements[i]; }
     const thread T& operator[](size_t i) const thread { return elements[i]; }
     threadgroup T& operator[](size_t i) threadgroup { return elements[i]; }
     const threadgroup T& operator[](size_t i) const threadgroup { return elements[i]; }
     T elements[N];
 };

 struct tint_packed_vec3_f32_array_element {
   /* 0x0000 */ packed_float3 elements;
   /* 0x000c */ tint_array<int8_t, 4> tint_pad;
 };

 struct GammaTransferParams {
   /* 0x0000 */ float G;
   /* 0x0004 */ float A;
   /* 0x0008 */ float B;
   /* 0x000c */ float C;
   /* 0x0010 */ float D;
   /* 0x0014 */ float E;
   /* 0x0018 */ float F;
   /* 0x001c */ uint padding;
 };

 struct ExternalTextureParams_tint_packed_vec3 {
   /* 0x0000 */ uint numPlanes;
   /* 0x0004 */ uint doYuvToRgbConversionOnly;
   /* 0x0008 */ tint_array<int8_t, 8> tint_pad_1;
   /* 0x0010 */ float3x4 yuvToRgbConversionMatrix;
   /* 0x0040 */ GammaTransferParams gammaDecodeParams;
   /* 0x0060 */ GammaTransferParams gammaEncodeParams;
   /* 0x0080 */ tint_array<tint_packed_vec3_f32_array_element, 3> gamutConversionMatrix;
   /* 0x00b0 */ float3x2 coordTransformationMatrix;
   /* 0x00c8 */ tint_array<int8_t, 8> tint_pad_2;
 };

 float3x3 tint_unpack_vec3_in_composite(tint_array<tint_packed_vec3_f32_array_element, 3> in) {
   float3x3 result = float3x3(0.0f);
   for(uint i = 0u; (i < 3u); i = (i + 1u)) {
     result[i] = float3(in[i].elements);
   }
   return result;
 }

 struct ExternalTextureParams {
   uint numPlanes;
   uint doYuvToRgbConversionOnly;
   float3x4 yuvToRgbConversionMatrix;
   GammaTransferParams gammaDecodeParams;
   GammaTransferParams gammaEncodeParams;
   float3x3 gamutConversionMatrix;
   float3x2 coordTransformationMatrix;
 };

 ExternalTextureParams tint_unpack_vec3_in_composite_1(ExternalTextureParams_tint_packed_vec3 in) {
   ExternalTextureParams result = {};
   result.numPlanes = in.numPlanes;
   result.doYuvToRgbConversionOnly = in.doYuvToRgbConversionOnly;
   result.yuvToRgbConversionMatrix = in.yuvToRgbConversionMatrix;
   result.gammaDecodeParams = in.gammaDecodeParams;
   result.gammaEncodeParams = in.gammaEncodeParams;
   result.gamutConversionMatrix = tint_unpack_vec3_in_composite(in.gamutConversionMatrix);
   result.coordTransformationMatrix = in.coordTransformationMatrix;
   return result;
 }

 int2 tint_clamp(int2 e, int2 low, int2 high) {
   return min(max(e, low), high);
 }

 float3 gammaCorrection(float3 v, GammaTransferParams params) {
   bool3 const cond = (fabs(v) < float3(params.D));
   float3 const t = (sign(v) * ((params.C * fabs(v)) + params.F));
   float3 const f = (sign(v) * (pow(((params.A * fabs(v)) + params.B), float3(params.G)) + params.E));
   return select(f, t, cond);
 }

 float4 textureLoadExternal(texture2d<float, access::sample> plane0, texture2d<float, access::sample> plane1, int2 coord, ExternalTextureParams params) {
   int2 const coord1 = (coord >> uint2(1u));
   float3 color = 0.0f;
   if ((params.numPlanes == 1u)) {
     color = plane0.read(uint2(coord), 0).rgb;
   } else {
     color = (float4(plane0.read(uint2(coord), 0)[0], plane1.read(uint2(coord1), 0).rg, 1.0f) * params.yuvToRgbConversionMatrix);
   }
   if ((params.doYuvToRgbConversionOnly == 0u)) {
     color = gammaCorrection(color, params.gammaDecodeParams);
     color = (params.gamutConversionMatrix * color);
     color = gammaCorrection(color, params.gammaEncodeParams);
   }
   return float4(color, 1.0f);
 }

 kernel void tint_symbol(texture2d<float, access::sample> tint_symbol_1 [[texture(1)]], texture2d<float, access::sample> tint_symbol_2 [[texture(2)]], const constant ExternalTextureParams_tint_packed_vec3* tint_symbol_3 [[buffer(3)]], texture2d<float, access::write> tint_symbol_4 [[texture(0)]]) {
   float4 red = textureLoadExternal(tint_symbol_1, tint_symbol_2, tint_clamp(int2(10), int2(0), int2((uint2(tint_symbol_1.get_width(), tint_symbol_1.get_height()) - uint2(1u)))), tint_unpack_vec3_in_composite_1(*(tint_symbol_3)));
   tint_symbol_4.write(red, uint2(tint_clamp(int2(0), int2(0), int2((uint2(tint_symbol_4.get_width(), tint_symbol_4.get_height()) - uint2(1u))))));
   float4 green = textureLoadExternal(tint_symbol_1, tint_symbol_2, tint_clamp(int2(70, 118), int2(0), int2((uint2(tint_symbol_1.get_width(), tint_symbol_1.get_height()) - uint2(1u)))), tint_unpack_vec3_in_composite_1(*(tint_symbol_3)));
   tint_symbol_4.write(green, uint2(tint_clamp(int2(1, 0), int2(0), int2((uint2(tint_symbol_4.get_width(), tint_symbol_4.get_height()) - uint2(1u))))));
   return;
 }
	#include <metal_stdlib>

	using namespace metal;

	template<typename T, size_t N>
	struct tint_array {
	const constant T& operator[](size_t i) const constant { return elements[i]; }
	device T& operator[](size_t i) device { return elements[i]; }
	const device T& operator[](size_t i) const device { return elements[i]; }
	thread T& operator[](size_t i) thread { return elements[i]; }
	const thread T& operator[](size_t i) const thread { return elements[i]; }
	threadgroup T& operator[](size_t i) threadgroup { return elements[i]; }
	const threadgroup T& operator[](size_t i) const threadgroup { return elements[i]; }
	T elements[N];
	};

	struct tint_packed_vec3_f32_array_element {
	/* 0x0000 */ packed_float3 elements;
	/* 0x000c */ tint_array<int8_t, 4> tint_pad;
	};

	struct GammaTransferParams {
	/* 0x0000 */ float G;
	/* 0x0004 */ float A;
	/* 0x0008 */ float B;
	/* 0x000c */ float C;
	/* 0x0010 */ float D;
	/* 0x0014 */ float E;
	/* 0x0018 */ float F;
	/* 0x001c */ uint padding;
	};

	struct ExternalTextureParams_tint_packed_vec3 {
	/* 0x0000 */ uint numPlanes;
	/* 0x0004 */ uint doYuvToRgbConversionOnly;
	/* 0x0008 */ tint_array<int8_t, 8> tint_pad_1;
	/* 0x0010 */ float3x4 yuvToRgbConversionMatrix;
	/* 0x0040 */ GammaTransferParams gammaDecodeParams;
	/* 0x0060 */ GammaTransferParams gammaEncodeParams;
	/* 0x0080 */ tint_array<tint_packed_vec3_f32_array_element, 3> gamutConversionMatrix;
	/* 0x00b0 */ float3x2 coordTransformationMatrix;
	/* 0x00c8 */ tint_array<int8_t, 8> tint_pad_2;
	};

	float3x3 tint_unpack_vec3_in_composite(tint_array<tint_packed_vec3_f32_array_element, 3> in) {
	float3x3 result = float3x3(0.0f);
	for(uint i = 0u; (i < 3u); i = (i + 1u)) {
	result[i] = float3(in[i].elements);
	}
	return result;
	}

	struct ExternalTextureParams {
	uint numPlanes;
	uint doYuvToRgbConversionOnly;
	float3x4 yuvToRgbConversionMatrix;
	GammaTransferParams gammaDecodeParams;
	GammaTransferParams gammaEncodeParams;
	float3x3 gamutConversionMatrix;
	float3x2 coordTransformationMatrix;
	};

	ExternalTextureParams tint_unpack_vec3_in_composite_1(ExternalTextureParams_tint_packed_vec3 in) {
	ExternalTextureParams result = {};
	result.numPlanes = in.numPlanes;
	result.doYuvToRgbConversionOnly = in.doYuvToRgbConversionOnly;
	result.yuvToRgbConversionMatrix = in.yuvToRgbConversionMatrix;
	result.gammaDecodeParams = in.gammaDecodeParams;
	result.gammaEncodeParams = in.gammaEncodeParams;
	result.gamutConversionMatrix = tint_unpack_vec3_in_composite(in.gamutConversionMatrix);
	result.coordTransformationMatrix = in.coordTransformationMatrix;
	return result;
	}

	int2 tint_clamp(int2 e, int2 low, int2 high) {
	return min(max(e, low), high);
	}

	float3 gammaCorrection(float3 v, GammaTransferParams params) {
	bool3 const cond = (fabs(v) < float3(params.D));
	float3 const t = (sign(v) * ((params.C * fabs(v)) + params.F));
	float3 const f = (sign(v) * (pow(((params.A * fabs(v)) + params.B), float3(params.G)) + params.E));
	return select(f, t, cond);
	}

	float4 textureLoadExternal(texture2d<float, access::sample> plane0, texture2d<float, access::sample> plane1, int2 coord, ExternalTextureParams params) {
	int2 const coord1 = (coord >> uint2(1u));
	float3 color = 0.0f;
	if ((params.numPlanes == 1u)) {
	color = plane0.read(uint2(coord), 0).rgb;
	} else {
	color = (float4(plane0.read(uint2(coord), 0)[0], plane1.read(uint2(coord1), 0).rg, 1.0f) * params.yuvToRgbConversionMatrix);
	}
	if ((params.doYuvToRgbConversionOnly == 0u)) {
	color = gammaCorrection(color, params.gammaDecodeParams);
	color = (params.gamutConversionMatrix * color);
	color = gammaCorrection(color, params.gammaEncodeParams);
	}
	return float4(color, 1.0f);
	}

	kernel void tint_symbol(texture2d<float, access::sample> tint_symbol_1 [[texture(1)]], texture2d<float, access::sample> tint_symbol_2 [[texture(2)]], const constant ExternalTextureParams_tint_packed_vec3* tint_symbol_3 [[buffer(3)]], texture2d<float, access::write> tint_symbol_4 [[texture(0)]]) {
	float4 red = textureLoadExternal(tint_symbol_1, tint_symbol_2, tint_clamp(int2(10), int2(0), int2((uint2(tint_symbol_1.get_width(), tint_symbol_1.get_height()) - uint2(1u)))), tint_unpack_vec3_in_composite_1(*(tint_symbol_3)));
	tint_symbol_4.write(red, uint2(tint_clamp(int2(0), int2(0), int2((uint2(tint_symbol_4.get_width(), tint_symbol_4.get_height()) - uint2(1u))))));
	float4 green = textureLoadExternal(tint_symbol_1, tint_symbol_2, tint_clamp(int2(70, 118), int2(0), int2((uint2(tint_symbol_1.get_width(), tint_symbol_1.get_height()) - uint2(1u)))), tint_unpack_vec3_in_composite_1(*(tint_symbol_3)));
	tint_symbol_4.write(green, uint2(tint_clamp(int2(1, 0), int2(0), int2((uint2(tint_symbol_4.get_width(), tint_symbol_4.get_height()) - uint2(1u))))));
	return;
	}