mlir/test/Integration/Dialect/SparseTensor/GPU/CUDA/sparse-matvec.mlir - llvm-project - Git at Google

 //
 // NOTE: this test requires gpu-sm80
 //
 // RUN: mlir-opt %s \
 // RUN:   --sparsifier="enable-runtime-library=false parallelization-strategy=dense-outer-loop gpu-triple=nvptx64-nvidia-cuda gpu-chip=sm_80 gpu-features=+ptx71 gpu-format=%gpu_compilation_format" \
 // RUN: | mlir-cpu-runner \
 // RUN:   --shared-libs=%mlir_cuda_runtime \
 // RUN:   --shared-libs=%mlir_c_runner_utils \
 // RUN:   --e main --entry-point-result=void \
 // RUN: | FileCheck %s

 #CSR = #sparse_tensor.encoding<{ map = (d0, d1) -> (d0 : dense, d1 : compressed) }>

 module {
   // Compute matrix vector y = Ax
   func.func @matvec(%A: tensor<?x?xf64, #CSR>, %x: tensor<?xf64>, %y_in: tensor<?xf64>) -> tensor<?xf64> {
     %y_out = linalg.matvec
       ins(%A, %x: tensor<?x?xf64, #CSR>, tensor<?xf64>)
       outs(%y_in: tensor<?xf64>) -> tensor<?xf64>
     return %y_out : tensor<?xf64>
   }

   func.func @main() {
     %f0 = arith.constant 0.0 : f64
     %c0 = arith.constant 0 : index
     %c1 = arith.constant 1 : index

     // Stress test with a dense matrix DA.
     %DA = tensor.generate {
     ^bb0(%i: index, %j: index):
       %k = arith.addi %i, %j : index
       %l = arith.index_cast %k : index to i64
       %f = arith.uitofp %l : i64 to f64
       tensor.yield %f : f64
     } : tensor<1024x64xf64>

     // Convert to a "sparse" m x n matrix A.
     %A = sparse_tensor.convert %DA : tensor<1024x64xf64> to tensor<?x?xf64, #CSR>

     // Initialize dense vector with n elements:
     //   (1, 2, 3, 4, ..., n)
     %d1 = tensor.dim %A, %c1 : tensor<?x?xf64, #CSR>
     %x = tensor.generate %d1 {
     ^bb0(%i : index):
       %k = arith.addi %i, %c1 : index
       %j = arith.index_cast %k : index to i64
       %f = arith.uitofp %j : i64 to f64
       tensor.yield %f : f64
     } : tensor<?xf64>

     // Initialize dense vector to m zeros.
     %d0 = tensor.dim %A, %c0 : tensor<?x?xf64, #CSR>
     %y = tensor.generate %d0 {
     ^bb0(%i : index):
       tensor.yield %f0 : f64
     } : tensor<?xf64>

     // Call the kernel.
     %0 = call @matvec(%A, %x, %y) : (tensor<?x?xf64, #CSR>, tensor<?xf64>, tensor<?xf64>) -> tensor<?xf64>

     //
     // Sanity check on results.
     //
     // CHECK: ( 87360, 89440, 91520, 93600, 95680, 97760, 99840, 101920, 104000, 106080, 108160, 110240, 112320, 114400, 116480, 118560, 120640, 122720, 124800, 126880, 128960, 131040, 133120, 135200, 137280, 139360, 141440, 143520, 145600, 147680, 149760, 151840, 153920, 156000, 158080, 160160, 162240, 164320, 166400, 168480, 170560, 172640, 174720, 176800, 178880, 180960, 183040, 185120, 187200, 189280, 191360, 193440, 195520, 197600, 199680, 201760, 203840, 205920, 208000, 210080, 212160, 214240, 216320, 218400 )
     //
     %pb0 = vector.transfer_read %0[%c0], %f0 : tensor<?xf64>, vector<64xf64>
     vector.print %pb0 : vector<64xf64>

     // Release the resources.
     bufferization.dealloc_tensor %A : tensor<?x?xf64, #CSR>
     return
   }
 }
	//
	// NOTE: this test requires gpu-sm80
	//
	// RUN: mlir-opt %s \
	// RUN: --sparsifier="enable-runtime-library=false parallelization-strategy=dense-outer-loop gpu-triple=nvptx64-nvidia-cuda gpu-chip=sm_80 gpu-features=+ptx71 gpu-format=%gpu_compilation_format" \
	// RUN: \| mlir-cpu-runner \
	// RUN: --shared-libs=%mlir_cuda_runtime \
	// RUN: --shared-libs=%mlir_c_runner_utils \
	// RUN: --e main --entry-point-result=void \
	// RUN: \| FileCheck %s

	#CSR = #sparse_tensor.encoding<{ map = (d0, d1) -> (d0 : dense, d1 : compressed) }>

	module {
	// Compute matrix vector y = Ax
	func.func @matvec(%A: tensor<?x?xf64, #CSR>, %x: tensor<?xf64>, %y_in: tensor<?xf64>) -> tensor<?xf64> {
	%y_out = linalg.matvec
	ins(%A, %x: tensor<?x?xf64, #CSR>, tensor<?xf64>)
	outs(%y_in: tensor<?xf64>) -> tensor<?xf64>
	return %y_out : tensor<?xf64>
	}

	func.func @main() {
	%f0 = arith.constant 0.0 : f64
	%c0 = arith.constant 0 : index
	%c1 = arith.constant 1 : index

	// Stress test with a dense matrix DA.
	%DA = tensor.generate {
	^bb0(%i: index, %j: index):
	%k = arith.addi %i, %j : index
	%l = arith.index_cast %k : index to i64
	%f = arith.uitofp %l : i64 to f64
	tensor.yield %f : f64
	} : tensor<1024x64xf64>

	// Convert to a "sparse" m x n matrix A.
	%A = sparse_tensor.convert %DA : tensor<1024x64xf64> to tensor<?x?xf64, #CSR>

	// Initialize dense vector with n elements:
	// (1, 2, 3, 4, ..., n)
	%d1 = tensor.dim %A, %c1 : tensor<?x?xf64, #CSR>
	%x = tensor.generate %d1 {
	^bb0(%i : index):
	%k = arith.addi %i, %c1 : index
	%j = arith.index_cast %k : index to i64
	%f = arith.uitofp %j : i64 to f64
	tensor.yield %f : f64
	} : tensor<?xf64>

	// Initialize dense vector to m zeros.
	%d0 = tensor.dim %A, %c0 : tensor<?x?xf64, #CSR>
	%y = tensor.generate %d0 {
	^bb0(%i : index):
	tensor.yield %f0 : f64
	} : tensor<?xf64>

	// Call the kernel.
	%0 = call @matvec(%A, %x, %y) : (tensor<?x?xf64, #CSR>, tensor<?xf64>, tensor<?xf64>) -> tensor<?xf64>

	//
	// Sanity check on results.
	//
	// CHECK: ( 87360, 89440, 91520, 93600, 95680, 97760, 99840, 101920, 104000, 106080, 108160, 110240, 112320, 114400, 116480, 118560, 120640, 122720, 124800, 126880, 128960, 131040, 133120, 135200, 137280, 139360, 141440, 143520, 145600, 147680, 149760, 151840, 153920, 156000, 158080, 160160, 162240, 164320, 166400, 168480, 170560, 172640, 174720, 176800, 178880, 180960, 183040, 185120, 187200, 189280, 191360, 193440, 195520, 197600, 199680, 201760, 203840, 205920, 208000, 210080, 212160, 214240, 216320, 218400 )
	//
	%pb0 = vector.transfer_read %0[%c0], %f0 : tensor<?xf64>, vector<64xf64>
	vector.print %pb0 : vector<64xf64>

	// Release the resources.
	bufferization.dealloc_tensor %A : tensor<?x?xf64, #CSR>
	return
	}
	}