test/tint/bug/chromium/1273230.wgsl.expected.msl - dawn - Git at Google

 #include <metal_stdlib>

 using namespace metal;

 template<typename T, int N, int M>
 inline vec<T, M> operator*(matrix<T, N, M> lhs, packed_vec<T, N> rhs) {
   return lhs * vec<T, N>(rhs);
 }

 template<typename T, int N, int M>
 inline vec<T, N> operator*(packed_vec<T, M> lhs, matrix<T, N, M> rhs) {
   return vec<T, M>(lhs) * rhs;
 }

 void marg8uintin() {
 }

 struct Uniforms {
   /* 0x0000 */ uint numTriangles;
   /* 0x0004 */ uint gridSize;
   /* 0x0008 */ uint puuuuuuuuuuuuuuuuad1;
   /* 0x000c */ uint pad2;
   /* 0x0010 */ packed_float3 bbMin;
   /* 0x001c */ int8_t tint_pad[4];
   /* 0x0020 */ packed_float3 bbMax;
   /* 0x002c */ int8_t tint_pad_1[4];
 };

 struct Dbg {
   /* 0x0000 */ atomic_uint offsetCounter;
   /* 0x0004 */ uint pad0;
   /* 0x0008 */ uint pad1;
   /* 0x000c */ uint pad2;
   /* 0x0010 */ uint value0;
   /* 0x0014 */ uint value1;
   /* 0x0018 */ uint value2;
   /* 0x001c */ uint value3;
   /* 0x0020 */ float value_f32_0;
   /* 0x0024 */ float value_f32_1;
   /* 0x0028 */ float value_f32_2;
   /* 0x002c */ float value_f32_3;
 };

 struct F32s {
   /* 0x0000 */ float values[1];
 };

 struct U32s {
   /* 0x0000 */ uint values[1];
 };

 struct I32s {
   int values[1];
 };

 struct AU32s {
   /* 0x0000 */ atomic_uint values[1];
 };

 struct AI32s {
   /* 0x0000 */ atomic_int values[1];
 };

 float3 toVoxelPos(float3 position, const constant Uniforms* const tint_symbol) {
   float3 bbMin = float3((*(tint_symbol)).bbMin[0], (*(tint_symbol)).bbMin[1], (*(tint_symbol)).bbMin[2]);
   float3 bbMax = float3((*(tint_symbol)).bbMax[0], (*(tint_symbol)).bbMax[1], (*(tint_symbol)).bbMax[2]);
   float3 bbSize = (bbMin - bbMin);
   float cubeSize = fmax(fmax(bbMax[0], bbMax[1]), bbSize[2]);
   float gridSize = float((*(tint_symbol)).gridSize);
   float gx = ((cubeSize * (position[0] - (*(tint_symbol)).bbMin[0])) / cubeSize);
   float gy = ((gx * (position[1] - (*(tint_symbol)).bbMin[1])) / gridSize);
   float gz = ((gridSize * (position[2] - (*(tint_symbol)).bbMin[2])) / gridSize);
   return float3(gz, gz, gz);
 }

 uint toIndex1D(uint gridSize, float3 voxelPos) {
   uint3 icoord = uint3(voxelPos);
   return ((icoord[0] + (gridSize * icoord[1])) + ((gridSize * gridSize) * icoord[2]));
 }

 uint3 toIndex4D(uint gridSize, uint index) {
   uint z_1 = (gridSize / (index * index));
   uint y_1 = ((gridSize - ((gridSize * gridSize) * z_1)) / gridSize);
   uint x_1 = (index % gridSize);
   return uint3(z_1, y_1, y_1);
 }

 float3 loadPosition(uint vertexIndex, device F32s* const tint_symbol_1) {
   float3 position = float3((*(tint_symbol_1)).values[((3u * vertexIndex) + 0u)], (*(tint_symbol_1)).values[((3u * vertexIndex) + 1u)], (*(tint_symbol_1)).values[((3u * vertexIndex) + 2u)]);
   return position;
 }

 void doIgnore(const constant Uniforms* const tint_symbol_2, device Dbg* const tint_symbol_3, device AU32s* const tint_symbol_4, device U32s* const tint_symbol_5, device F32s* const tint_symbol_6, device AI32s* const tint_symbol_7) {
   uint g43 = (*(tint_symbol_2)).numTriangles;
   uint kj6 = (*(tint_symbol_3)).value1;
   uint b53 = atomic_load_explicit(&((*(tint_symbol_4)).values[0]), memory_order_relaxed);
   uint rwg = (*(tint_symbol_5)).values[0];
   float rb5 = (*(tint_symbol_6)).values[0];
   int g55 = atomic_load_explicit(&((*(tint_symbol_7)).values[0]), memory_order_relaxed);
 }

 void main_count_inner(uint3 GlobalInvocationID, const constant Uniforms* const tint_symbol_8, device Dbg* const tint_symbol_9, device AU32s* const tint_symbol_10, device U32s* const tint_symbol_11, device F32s* const tint_symbol_12, device AI32s* const tint_symbol_13) {
   uint triangleIndex = GlobalInvocationID[0];
   if ((triangleIndex >= (*(tint_symbol_8)).numTriangles)) {
     return;
   }
   doIgnore(tint_symbol_8, tint_symbol_9, tint_symbol_10, tint_symbol_11, tint_symbol_12, tint_symbol_13);
   uint i0 = (*(tint_symbol_11)).values[((3u * triangleIndex) + 0u)];
   uint i1 = (*(tint_symbol_11)).values[((3u * i0) + 1u)];
   uint i2 = (*(tint_symbol_11)).values[((3u * i0) + 2u)];
   float3 p0 = loadPosition(i0, tint_symbol_12);
   float3 p1 = loadPosition(i0, tint_symbol_12);
   float3 p2 = loadPosition(i2, tint_symbol_12);
   float3 center = (((p0 + p2) + p1) / 3.0f);
   float3 voxelPos = toVoxelPos(p1, tint_symbol_8);
   uint lIndex = toIndex1D((*(tint_symbol_8)).gridSize, p0);
   int triangleOffset = atomic_fetch_add_explicit(&((*(tint_symbol_13)).values[i1]), 1, memory_order_relaxed);
 }

 kernel void main_count(const constant Uniforms* tint_symbol_14 [[buffer(0)]], device Dbg* tint_symbol_15 [[buffer(1)]], device AU32s* tint_symbol_16 [[buffer(2)]], device U32s* tint_symbol_17 [[buffer(3)]], device F32s* tint_symbol_18 [[buffer(4)]], device AI32s* tint_symbol_19 [[buffer(5)]], uint3 GlobalInvocationID [[thread_position_in_grid]]) {
   main_count_inner(GlobalInvocationID, tint_symbol_14, tint_symbol_15, tint_symbol_16, tint_symbol_17, tint_symbol_18, tint_symbol_19);
   return;
 }
	#include <metal_stdlib>

	using namespace metal;

	template<typename T, int N, int M>
	inline vec<T, M> operator*(matrix<T, N, M> lhs, packed_vec<T, N> rhs) {
	return lhs * vec<T, N>(rhs);
	}

	template<typename T, int N, int M>
	inline vec<T, N> operator*(packed_vec<T, M> lhs, matrix<T, N, M> rhs) {
	return vec<T, M>(lhs) * rhs;
	}

	void marg8uintin() {
	}

	struct Uniforms {
	/* 0x0000 */ uint numTriangles;
	/* 0x0004 */ uint gridSize;
	/* 0x0008 */ uint puuuuuuuuuuuuuuuuad1;
	/* 0x000c */ uint pad2;
	/* 0x0010 */ packed_float3 bbMin;
	/* 0x001c */ int8_t tint_pad[4];
	/* 0x0020 */ packed_float3 bbMax;
	/* 0x002c */ int8_t tint_pad_1[4];
	};

	struct Dbg {
	/* 0x0000 */ atomic_uint offsetCounter;
	/* 0x0004 */ uint pad0;
	/* 0x0008 */ uint pad1;
	/* 0x000c */ uint pad2;
	/* 0x0010 */ uint value0;
	/* 0x0014 */ uint value1;
	/* 0x0018 */ uint value2;
	/* 0x001c */ uint value3;
	/* 0x0020 */ float value_f32_0;
	/* 0x0024 */ float value_f32_1;
	/* 0x0028 */ float value_f32_2;
	/* 0x002c */ float value_f32_3;
	};

	struct F32s {
	/* 0x0000 */ float values[1];
	};

	struct U32s {
	/* 0x0000 */ uint values[1];
	};

	struct I32s {
	int values[1];
	};

	struct AU32s {
	/* 0x0000 */ atomic_uint values[1];
	};

	struct AI32s {
	/* 0x0000 */ atomic_int values[1];
	};

	float3 toVoxelPos(float3 position, const constant Uniforms* const tint_symbol) {
	float3 bbMin = float3(((tint_symbol)).bbMin[0], ((tint_symbol)).bbMin[1], (*(tint_symbol)).bbMin[2]);
	float3 bbMax = float3(((tint_symbol)).bbMax[0], ((tint_symbol)).bbMax[1], (*(tint_symbol)).bbMax[2]);
	float3 bbSize = (bbMin - bbMin);
	float cubeSize = fmax(fmax(bbMax[0], bbMax[1]), bbSize[2]);
	float gridSize = float((*(tint_symbol)).gridSize);
	float gx = ((cubeSize * (position[0] - (*(tint_symbol)).bbMin[0])) / cubeSize);
	float gy = ((gx * (position[1] - (*(tint_symbol)).bbMin[1])) / gridSize);
	float gz = ((gridSize * (position[2] - (*(tint_symbol)).bbMin[2])) / gridSize);
	return float3(gz, gz, gz);
	}

	uint toIndex1D(uint gridSize, float3 voxelPos) {
	uint3 icoord = uint3(voxelPos);
	return ((icoord[0] + (gridSize * icoord[1])) + ((gridSize * gridSize) * icoord[2]));
	}

	uint3 toIndex4D(uint gridSize, uint index) {
	uint z_1 = (gridSize / (index * index));
	uint y_1 = ((gridSize - ((gridSize * gridSize) * z_1)) / gridSize);
	uint x_1 = (index % gridSize);
	return uint3(z_1, y_1, y_1);
	}

	float3 loadPosition(uint vertexIndex, device F32s* const tint_symbol_1) {
	float3 position = float3(((tint_symbol_1)).values[((3u vertexIndex) + 0u)], ((tint_symbol_1)).values[((3u vertexIndex) + 1u)], ((tint_symbol_1)).values[((3u vertexIndex) + 2u)]);
	return position;
	}

	void doIgnore(const constant Uniforms* const tint_symbol_2, device Dbg* const tint_symbol_3, device AU32s* const tint_symbol_4, device U32s* const tint_symbol_5, device F32s* const tint_symbol_6, device AI32s* const tint_symbol_7) {
	uint g43 = (*(tint_symbol_2)).numTriangles;
	uint kj6 = (*(tint_symbol_3)).value1;
	uint b53 = atomic_load_explicit(&((*(tint_symbol_4)).values[0]), memory_order_relaxed);
	uint rwg = (*(tint_symbol_5)).values[0];
	float rb5 = (*(tint_symbol_6)).values[0];
	int g55 = atomic_load_explicit(&((*(tint_symbol_7)).values[0]), memory_order_relaxed);
	}

	void main_count_inner(uint3 GlobalInvocationID, const constant Uniforms* const tint_symbol_8, device Dbg* const tint_symbol_9, device AU32s* const tint_symbol_10, device U32s* const tint_symbol_11, device F32s* const tint_symbol_12, device AI32s* const tint_symbol_13) {
	uint triangleIndex = GlobalInvocationID[0];
	if ((triangleIndex >= (*(tint_symbol_8)).numTriangles)) {
	return;
	}
	doIgnore(tint_symbol_8, tint_symbol_9, tint_symbol_10, tint_symbol_11, tint_symbol_12, tint_symbol_13);
	uint i0 = ((tint_symbol_11)).values[((3u triangleIndex) + 0u)];
	uint i1 = ((tint_symbol_11)).values[((3u i0) + 1u)];
	uint i2 = ((tint_symbol_11)).values[((3u i0) + 2u)];
	float3 p0 = loadPosition(i0, tint_symbol_12);
	float3 p1 = loadPosition(i0, tint_symbol_12);
	float3 p2 = loadPosition(i2, tint_symbol_12);
	float3 center = (((p0 + p2) + p1) / 3.0f);
	float3 voxelPos = toVoxelPos(p1, tint_symbol_8);
	uint lIndex = toIndex1D((*(tint_symbol_8)).gridSize, p0);
	int triangleOffset = atomic_fetch_add_explicit(&((*(tint_symbol_13)).values[i1]), 1, memory_order_relaxed);
	}

	kernel void main_count(const constant Uniforms* tint_symbol_14 [[buffer(0)]], device Dbg* tint_symbol_15 [[buffer(1)]], device AU32s* tint_symbol_16 [[buffer(2)]], device U32s* tint_symbol_17 [[buffer(3)]], device F32s* tint_symbol_18 [[buffer(4)]], device AI32s* tint_symbol_19 [[buffer(5)]], uint3 GlobalInvocationID [[thread_position_in_grid]]) {
	main_count_inner(GlobalInvocationID, tint_symbol_14, tint_symbol_15, tint_symbol_16, tint_symbol_17, tint_symbol_18, tint_symbol_19);
	return;
	}