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

 struct Uniforms {
   dimAOuter : u32;
   dimInner : u32;
   dimBOuter : u32;
 };

 struct Matrix {
   numbers : array<f32>;
 };

 [[group(0), binding(0)]] var<storage, read> firstMatrix : Matrix;

 [[group(0), binding(1)]] var<storage, read> secondMatrix : Matrix;

 [[group(0), binding(2)]] var<storage, write> resultMatrix : Matrix;

 [[group(0), binding(3)]] var<uniform> uniforms : Uniforms;

 fn mm_readA(row : u32, col : u32) -> f32 {
   if (((row < uniforms.dimAOuter) && (col < uniforms.dimInner))) {
     let result : f32 = firstMatrix.numbers[((row * uniforms.dimInner) + col)];
     return result;
   }
   return 0.0;
 }

 fn mm_readB(row : u32, col : u32) -> f32 {
   if (((row < uniforms.dimInner) && (col < uniforms.dimBOuter))) {
     let result : f32 = secondMatrix.numbers[((row * uniforms.dimBOuter) + col)];
     return result;
   }
   return 0.0;
 }

 fn mm_write(row : u32, col : u32, value : f32) {
   if (((row < uniforms.dimAOuter) && (col < uniforms.dimBOuter))) {
     let index : u32 = (col + (row * uniforms.dimBOuter));
     resultMatrix.numbers[index] = value;
   }
 }

 let RowPerThread : u32 = 4u;

 let ColPerThread : u32 = 4u;

 let TileAOuter : u32 = 64u;

 let TileBOuter : u32 = 64u;

 let TileInner : u32 = 64u;

 var<workgroup> mm_Asub : array<array<f32, 64>, 64>;

 var<workgroup> mm_Bsub : array<array<f32, 64>, 64>;

 [[stage(compute), workgroup_size(16, 16, 1)]]
 fn main([[builtin(local_invocation_id)]] local_id : vec3<u32>, [[builtin(global_invocation_id)]] global_id : vec3<u32>) {
   let tileRow : u32 = (local_id.y * RowPerThread);
   let tileCol : u32 = (local_id.x * ColPerThread);
   let globalRow : u32 = (global_id.y * RowPerThread);
   let globalCol : u32 = (global_id.x * ColPerThread);
   let numTiles : u32 = (((uniforms.dimInner - 1u) / TileInner) + 1u);
   var acc : array<f32, 16>;
   var ACached : f32;
   var BCached : array<f32, 4>;
   for(var index : u32 = 0u; (index < (RowPerThread * ColPerThread)); index = (index + 1u)) {
     acc[index] = 0.0;
   }
   let ColPerThreadA : u32 = (TileInner / 16u);
   let tileColA : u32 = (local_id.x * ColPerThreadA);
   let RowPerThreadB : u32 = (TileInner / 16u);
   let tileRowB : u32 = (local_id.y * RowPerThreadB);
   for(var t : u32 = 0u; (t < numTiles); t = (t + 1u)) {
     for(var innerRow : u32 = 0u; (innerRow < RowPerThread); innerRow = (innerRow + 1u)) {
       for(var innerCol : u32 = 0u; (innerCol < ColPerThreadA); innerCol = (innerCol + 1u)) {
         let inputRow : u32 = (tileRow + innerRow);
         let inputCol : u32 = (tileColA + innerCol);
         mm_Asub[inputRow][inputCol] = mm_readA((globalRow + innerRow), ((t * TileInner) + inputCol));
       }
     }
     for(var innerRow : u32 = 0u; (innerRow < RowPerThreadB); innerRow = (innerRow + 1u)) {
       for(var innerCol : u32 = 0u; (innerCol < ColPerThread); innerCol = (innerCol + 1u)) {
         let inputRow : u32 = (tileRowB + innerRow);
         let inputCol : u32 = (tileCol + innerCol);
         mm_Bsub[innerCol][inputCol] = mm_readB(((t * TileInner) + inputRow), (globalCol + innerCol));
       }
     }
     workgroupBarrier();
     for(var k : u32 = 0u; (k < TileInner); k = (k + 1u)) {
       for(var inner : u32 = 0u; (inner < ColPerThread); inner = (inner + 1u)) {
         BCached[inner] = mm_Bsub[k][(tileCol + inner)];
       }
       for(var innerRow : u32 = 0u; (innerRow < RowPerThread); innerRow = (innerRow + 1u)) {
         ACached = mm_Asub[(tileRow + innerRow)][k];
         for(var innerCol : u32 = 0u; (innerCol < ColPerThread); innerCol = (innerCol + 1u)) {
           let index : u32 = ((innerRow * ColPerThread) + innerCol);
           acc[index] = (acc[index] + (ACached * BCached[innerCol]));
         }
       }
     }
     workgroupBarrier();
   }
   for(var innerRow : u32 = 0u; (innerRow < RowPerThread); innerRow = (innerRow + 1u)) {
     for(var innerCol : u32 = 0u; (innerCol < ColPerThread); innerCol = (innerCol + 1u)) {
       let index : u32 = ((innerRow * ColPerThread) + innerCol);
       mm_write((globalRow + innerRow), (globalCol + innerCol), acc[index]);
     }
   }
 }
	struct Uniforms {
	dimAOuter : u32;
	dimInner : u32;
	dimBOuter : u32;
	};

	struct Matrix {
	numbers : array<f32>;
	};

	[[group(0), binding(0)]] var<storage, read> firstMatrix : Matrix;

	[[group(0), binding(1)]] var<storage, read> secondMatrix : Matrix;

	[[group(0), binding(2)]] var<storage, write> resultMatrix : Matrix;

	[[group(0), binding(3)]] var<uniform> uniforms : Uniforms;

	fn mm_readA(row : u32, col : u32) -> f32 {
	if (((row < uniforms.dimAOuter) && (col < uniforms.dimInner))) {
	let result : f32 = firstMatrix.numbers[((row * uniforms.dimInner) + col)];
	return result;
	}
	return 0.0;
	}

	fn mm_readB(row : u32, col : u32) -> f32 {
	if (((row < uniforms.dimInner) && (col < uniforms.dimBOuter))) {
	let result : f32 = secondMatrix.numbers[((row * uniforms.dimBOuter) + col)];
	return result;
	}
	return 0.0;
	}

	fn mm_write(row : u32, col : u32, value : f32) {
	if (((row < uniforms.dimAOuter) && (col < uniforms.dimBOuter))) {
	let index : u32 = (col + (row * uniforms.dimBOuter));
	resultMatrix.numbers[index] = value;
	}
	}

	let RowPerThread : u32 = 4u;

	let ColPerThread : u32 = 4u;

	let TileAOuter : u32 = 64u;

	let TileBOuter : u32 = 64u;

	let TileInner : u32 = 64u;

	var<workgroup> mm_Asub : array<array<f32, 64>, 64>;

	var<workgroup> mm_Bsub : array<array<f32, 64>, 64>;

	[[stage(compute), workgroup_size(16, 16, 1)]]
	fn main([[builtin(local_invocation_id)]] local_id : vec3<u32>, [[builtin(global_invocation_id)]] global_id : vec3<u32>) {
	let tileRow : u32 = (local_id.y * RowPerThread);
	let tileCol : u32 = (local_id.x * ColPerThread);
	let globalRow : u32 = (global_id.y * RowPerThread);
	let globalCol : u32 = (global_id.x * ColPerThread);
	let numTiles : u32 = (((uniforms.dimInner - 1u) / TileInner) + 1u);
	var acc : array<f32, 16>;
	var ACached : f32;
	var BCached : array<f32, 4>;
	for(var index : u32 = 0u; (index < (RowPerThread * ColPerThread)); index = (index + 1u)) {
	acc[index] = 0.0;
	}
	let ColPerThreadA : u32 = (TileInner / 16u);
	let tileColA : u32 = (local_id.x * ColPerThreadA);
	let RowPerThreadB : u32 = (TileInner / 16u);
	let tileRowB : u32 = (local_id.y * RowPerThreadB);
	for(var t : u32 = 0u; (t < numTiles); t = (t + 1u)) {
	for(var innerRow : u32 = 0u; (innerRow < RowPerThread); innerRow = (innerRow + 1u)) {
	for(var innerCol : u32 = 0u; (innerCol < ColPerThreadA); innerCol = (innerCol + 1u)) {
	let inputRow : u32 = (tileRow + innerRow);
	let inputCol : u32 = (tileColA + innerCol);
	mm_Asub[inputRow][inputCol] = mm_readA((globalRow + innerRow), ((t * TileInner) + inputCol));
	}
	}
	for(var innerRow : u32 = 0u; (innerRow < RowPerThreadB); innerRow = (innerRow + 1u)) {
	for(var innerCol : u32 = 0u; (innerCol < ColPerThread); innerCol = (innerCol + 1u)) {
	let inputRow : u32 = (tileRowB + innerRow);
	let inputCol : u32 = (tileCol + innerCol);
	mm_Bsub[innerCol][inputCol] = mm_readB(((t * TileInner) + inputRow), (globalCol + innerCol));
	}
	}
	workgroupBarrier();
	for(var k : u32 = 0u; (k < TileInner); k = (k + 1u)) {
	for(var inner : u32 = 0u; (inner < ColPerThread); inner = (inner + 1u)) {
	BCached[inner] = mm_Bsub[k][(tileCol + inner)];
	}
	for(var innerRow : u32 = 0u; (innerRow < RowPerThread); innerRow = (innerRow + 1u)) {
	ACached = mm_Asub[(tileRow + innerRow)][k];
	for(var innerCol : u32 = 0u; (innerCol < ColPerThread); innerCol = (innerCol + 1u)) {
	let index : u32 = ((innerRow * ColPerThread) + innerCol);
	acc[index] = (acc[index] + (ACached * BCached[innerCol]));
	}
	}
	}
	workgroupBarrier();
	}
	for(var innerRow : u32 = 0u; (innerRow < RowPerThread); innerRow = (innerRow + 1u)) {
	for(var innerCol : u32 = 0u; (innerCol < ColPerThread); innerCol = (innerCol + 1u)) {
	let index : u32 = ((innerRow * ColPerThread) + innerCol);
	mm_write((globalRow + innerRow), (globalCol + innerCol), acc[index]);
	}
	}
	}