test/tint/bug/tint/914.wgsl.expected.fxc.hlsl - dawn - Git at Google

 groupshared float mm_Asub[64][64];
 groupshared float mm_Bsub[64][64];

 void tint_zero_workgroup_memory(uint local_idx) {
   {
     for(uint idx = local_idx; (idx < 4096u); idx = (idx + 256u)) {
       uint i = (idx / 64u);
       uint i_1 = (idx % 64u);
       mm_Asub[i][i_1] = 0.0f;
       mm_Bsub[i][i_1] = 0.0f;
     }
   }
   GroupMemoryBarrierWithGroupSync();
 }

 ByteAddressBuffer firstMatrix : register(t0);
 ByteAddressBuffer secondMatrix : register(t1);
 RWByteAddressBuffer resultMatrix : register(u2);
 cbuffer cbuffer_uniforms : register(b3) {
   uint4 uniforms[1];
 };

 float mm_readA(uint row, uint col) {
   bool tint_tmp = (row < uniforms[0].x);
   if (tint_tmp) {
     tint_tmp = (col < uniforms[0].y);
   }
   if ((tint_tmp)) {
     float result = asfloat(firstMatrix.Load((4u * ((row * uniforms[0].y) + col))));
     return result;
   }
   return 0.0f;
 }

 float mm_readB(uint row, uint col) {
   bool tint_tmp_1 = (row < uniforms[0].y);
   if (tint_tmp_1) {
     tint_tmp_1 = (col < uniforms[0].z);
   }
   if ((tint_tmp_1)) {
     float result = asfloat(secondMatrix.Load((4u * ((row * uniforms[0].z) + col))));
     return result;
   }
   return 0.0f;
 }

 void mm_write(uint row, uint col, float value) {
   bool tint_tmp_2 = (row < uniforms[0].x);
   if (tint_tmp_2) {
     tint_tmp_2 = (col < uniforms[0].z);
   }
   if ((tint_tmp_2)) {
     uint index = (col + (row * uniforms[0].z));
     resultMatrix.Store((4u * index), asuint(value));
   }
 }

 uint tint_div(uint lhs, uint rhs) {
   return (lhs / ((rhs == 0u) ? 1u : rhs));
 }

 struct tint_symbol_5 {
   uint3 local_id : SV_GroupThreadID;
   uint local_invocation_index : SV_GroupIndex;
   uint3 global_id : SV_DispatchThreadID;
 };

 void main_inner(uint3 local_id, uint3 global_id, uint local_invocation_index) {
   tint_zero_workgroup_memory(local_invocation_index);
   uint tileRow = (local_id.y * 4u);
   uint tileCol = (local_id.x * 4u);
   uint globalRow = (global_id.y * 4u);
   uint globalCol = (global_id.x * 4u);
   uint numTiles = (tint_div((uniforms[0].y - 1u), 64u) + 1u);
   float acc[16] = (float[16])0;
   float ACached = 0.0f;
   float BCached[4] = (float[4])0;
   {
     for(uint index = 0u; (index < 16u); index = (index + 1u)) {
       acc[index] = 0.0f;
     }
   }
   uint ColPerThreadA = 4u;
   uint tileColA = (local_id.x * ColPerThreadA);
   uint RowPerThreadB = 4u;
   uint tileRowB = (local_id.y * RowPerThreadB);
   {
     for(uint t = 0u; (t < numTiles); t = (t + 1u)) {
       {
         for(uint innerRow = 0u; (innerRow < 4u); innerRow = (innerRow + 1u)) {
           {
             for(uint innerCol = 0u; (innerCol < ColPerThreadA); innerCol = (innerCol + 1u)) {
               uint inputRow = (tileRow + innerRow);
               uint inputCol = (tileColA + innerCol);
               uint tint_symbol = inputRow;
               uint tint_symbol_1 = inputCol;
               mm_Asub[tint_symbol][tint_symbol_1] = mm_readA((globalRow + innerRow), ((t * 64u) + inputCol));
             }
           }
         }
       }
       {
         for(uint innerRow = 0u; (innerRow < RowPerThreadB); innerRow = (innerRow + 1u)) {
           {
             for(uint innerCol = 0u; (innerCol < 4u); innerCol = (innerCol + 1u)) {
               uint inputRow = (tileRowB + innerRow);
               uint inputCol = (tileCol + innerCol);
               uint tint_symbol_2 = innerCol;
               uint tint_symbol_3 = inputCol;
               mm_Bsub[tint_symbol_2][tint_symbol_3] = mm_readB(((t * 64u) + inputRow), (globalCol + innerCol));
             }
           }
         }
       }
       GroupMemoryBarrierWithGroupSync();
       {
         for(uint k = 0u; (k < 64u); k = (k + 1u)) {
           {
             for(uint inner = 0u; (inner < 4u); inner = (inner + 1u)) {
               BCached[inner] = mm_Bsub[k][(tileCol + inner)];
             }
           }
           {
             for(uint innerRow = 0u; (innerRow < 4u); innerRow = (innerRow + 1u)) {
               ACached = mm_Asub[(tileRow + innerRow)][k];
               {
                 for(uint innerCol = 0u; (innerCol < 4u); innerCol = (innerCol + 1u)) {
                   uint index = ((innerRow * 4u) + innerCol);
                   acc[index] = (acc[index] + (ACached * BCached[innerCol]));
                 }
               }
             }
           }
         }
       }
       GroupMemoryBarrierWithGroupSync();
     }
   }
   {
     for(uint innerRow = 0u; (innerRow < 4u); innerRow = (innerRow + 1u)) {
       {
         for(uint innerCol = 0u; (innerCol < 4u); innerCol = (innerCol + 1u)) {
           uint index = ((innerRow * 4u) + innerCol);
           mm_write((globalRow + innerRow), (globalCol + innerCol), acc[index]);
         }
       }
     }
   }
 }

 [numthreads(16, 16, 1)]
 void main(tint_symbol_5 tint_symbol_4) {
   main_inner(tint_symbol_4.local_id, tint_symbol_4.global_id, tint_symbol_4.local_invocation_index);
   return;
 }
	groupshared float mm_Asub[64][64];
	groupshared float mm_Bsub[64][64];

	void tint_zero_workgroup_memory(uint local_idx) {
	{
	for(uint idx = local_idx; (idx < 4096u); idx = (idx + 256u)) {
	uint i = (idx / 64u);
	uint i_1 = (idx % 64u);
	mm_Asub[i][i_1] = 0.0f;
	mm_Bsub[i][i_1] = 0.0f;
	}
	}
	GroupMemoryBarrierWithGroupSync();
	}

	ByteAddressBuffer firstMatrix : register(t0);
	ByteAddressBuffer secondMatrix : register(t1);
	RWByteAddressBuffer resultMatrix : register(u2);
	cbuffer cbuffer_uniforms : register(b3) {
	uint4 uniforms[1];
	};

	float mm_readA(uint row, uint col) {
	bool tint_tmp = (row < uniforms[0].x);
	if (tint_tmp) {
	tint_tmp = (col < uniforms[0].y);
	}
	if ((tint_tmp)) {
	float result = asfloat(firstMatrix.Load((4u * ((row * uniforms[0].y) + col))));
	return result;
	}
	return 0.0f;
	}

	float mm_readB(uint row, uint col) {
	bool tint_tmp_1 = (row < uniforms[0].y);
	if (tint_tmp_1) {
	tint_tmp_1 = (col < uniforms[0].z);
	}
	if ((tint_tmp_1)) {
	float result = asfloat(secondMatrix.Load((4u * ((row * uniforms[0].z) + col))));
	return result;
	}
	return 0.0f;
	}

	void mm_write(uint row, uint col, float value) {
	bool tint_tmp_2 = (row < uniforms[0].x);
	if (tint_tmp_2) {
	tint_tmp_2 = (col < uniforms[0].z);
	}
	if ((tint_tmp_2)) {
	uint index = (col + (row * uniforms[0].z));
	resultMatrix.Store((4u * index), asuint(value));
	}
	}

	uint tint_div(uint lhs, uint rhs) {
	return (lhs / ((rhs == 0u) ? 1u : rhs));
	}

	struct tint_symbol_5 {
	uint3 local_id : SV_GroupThreadID;
	uint local_invocation_index : SV_GroupIndex;
	uint3 global_id : SV_DispatchThreadID;
	};

	void main_inner(uint3 local_id, uint3 global_id, uint local_invocation_index) {
	tint_zero_workgroup_memory(local_invocation_index);
	uint tileRow = (local_id.y * 4u);
	uint tileCol = (local_id.x * 4u);
	uint globalRow = (global_id.y * 4u);
	uint globalCol = (global_id.x * 4u);
	uint numTiles = (tint_div((uniforms[0].y - 1u), 64u) + 1u);
	float acc[16] = (float[16])0;
	float ACached = 0.0f;
	float BCached[4] = (float[4])0;
	{
	for(uint index = 0u; (index < 16u); index = (index + 1u)) {
	acc[index] = 0.0f;
	}
	}
	uint ColPerThreadA = 4u;
	uint tileColA = (local_id.x * ColPerThreadA);
	uint RowPerThreadB = 4u;
	uint tileRowB = (local_id.y * RowPerThreadB);
	{
	for(uint t = 0u; (t < numTiles); t = (t + 1u)) {
	{
	for(uint innerRow = 0u; (innerRow < 4u); innerRow = (innerRow + 1u)) {
	{
	for(uint innerCol = 0u; (innerCol < ColPerThreadA); innerCol = (innerCol + 1u)) {
	uint inputRow = (tileRow + innerRow);
	uint inputCol = (tileColA + innerCol);
	uint tint_symbol = inputRow;
	uint tint_symbol_1 = inputCol;
	mm_Asub[tint_symbol][tint_symbol_1] = mm_readA((globalRow + innerRow), ((t * 64u) + inputCol));
	}
	}
	}
	}
	{
	for(uint innerRow = 0u; (innerRow < RowPerThreadB); innerRow = (innerRow + 1u)) {
	{
	for(uint innerCol = 0u; (innerCol < 4u); innerCol = (innerCol + 1u)) {
	uint inputRow = (tileRowB + innerRow);
	uint inputCol = (tileCol + innerCol);
	uint tint_symbol_2 = innerCol;
	uint tint_symbol_3 = inputCol;
	mm_Bsub[tint_symbol_2][tint_symbol_3] = mm_readB(((t * 64u) + inputRow), (globalCol + innerCol));
	}
	}
	}
	}
	GroupMemoryBarrierWithGroupSync();
	{
	for(uint k = 0u; (k < 64u); k = (k + 1u)) {
	{
	for(uint inner = 0u; (inner < 4u); inner = (inner + 1u)) {
	BCached[inner] = mm_Bsub[k][(tileCol + inner)];
	}
	}
	{
	for(uint innerRow = 0u; (innerRow < 4u); innerRow = (innerRow + 1u)) {
	ACached = mm_Asub[(tileRow + innerRow)][k];
	{
	for(uint innerCol = 0u; (innerCol < 4u); innerCol = (innerCol + 1u)) {
	uint index = ((innerRow * 4u) + innerCol);
	acc[index] = (acc[index] + (ACached * BCached[innerCol]));
	}
	}
	}
	}
	}
	}
	GroupMemoryBarrierWithGroupSync();
	}
	}
	{
	for(uint innerRow = 0u; (innerRow < 4u); innerRow = (innerRow + 1u)) {
	{
	for(uint innerCol = 0u; (innerCol < 4u); innerCol = (innerCol + 1u)) {
	uint index = ((innerRow * 4u) + innerCol);
	mm_write((globalRow + innerRow), (globalCol + innerCol), acc[index]);
	}
	}
	}
	}
	}

	[numthreads(16, 16, 1)]
	void main(tint_symbol_5 tint_symbol_4) {
	main_inner(tint_symbol_4.local_id, tint_symbol_4.global_id, tint_symbol_4.local_invocation_index);
	return;
	}