test/Integration/Dialect/Linalg/CPU/test-conv-1d-call.mlir - llvm-project/mlir - Git at Google

 // RUN: mlir-opt %s -test-transform-dialect-erase-schedule -convert-linalg-to-loops -convert-scf-to-cf  -expand-strided-metadata -lower-affine -convert-arith-to-llvm -convert-scf-to-cf --finalize-memref-to-llvm -convert-func-to-llvm -reconcile-unrealized-casts | \
 // RUN: mlir-cpu-runner -e main -entry-point-result=void \
 // RUN:   -shared-libs=%mlir_runner_utils \
 // RUN: | FileCheck %s

 // RUN: mlir-opt %s -transform-interpreter -test-transform-dialect-erase-schedule -convert-linalg-to-loops -convert-scf-to-cf \
 // RUN:    -expand-strided-metadata -lower-affine -convert-arith-to-llvm -convert-scf-to-cf --finalize-memref-to-llvm -convert-func-to-llvm -reconcile-unrealized-casts | \
 // RUN: mlir-cpu-runner -e main -entry-point-result=void \
 // RUN:   -shared-libs=%mlir_runner_utils \
 // RUN: | FileCheck %s

 func.func private @printMemrefF32(memref<*xf32>)

 // Creates and returns a 1-D buffer of size %s1 filled with the value %f
 func.func @alloc_1d_filled_f32(%s1 : index, %f : f32) -> memref<?xf32> {
   %buf = memref.alloc(%s1) : memref<?xf32>
   linalg.fill ins(%f : f32) outs(%buf : memref<?xf32>)
   return %buf : memref<?xf32>
 }

 func.func @conv_1d(%arg0: memref<?xf32>, %arg1: memref<?xf32>, %arg2: memref<?xf32>) {
   linalg.conv_1d ins (%arg0, %arg1: memref<?xf32>, memref<?xf32>)
                 outs (%arg2: memref<?xf32>)
   return
 }

 module attributes {transform.with_named_sequence} {
   transform.named_sequence @__transform_main(%arg1: !transform.any_op {transform.readonly}) {
     %0 = transform.structured.match ops{["linalg.conv_1d"]} in %arg1 : (!transform.any_op) -> !transform.any_op
     %1, %loop = transform.structured.tile_using_for %0 [4] : (!transform.any_op) -> (!transform.any_op, !transform.any_op)
     transform.yield
   }
 }

 func.func @main() {
   %c3 = arith.constant 3 : index
   %c6 = arith.constant 6 : index
   %c8 = arith.constant 8 : index
   %f10 = arith.constant 10.00000e+00 : f32
   %val = arith.constant 2.00000e+00 : f32
   %zero = arith.constant 0.00000e+00 : f32

   %filter1D = call @alloc_1d_filled_f32(%c3, %val) : (index, f32) -> (memref<?xf32>)
   %in1D = call @alloc_1d_filled_f32(%c8, %val) : (index, f32) -> (memref<?xf32>)
   %out1D = call @alloc_1d_filled_f32(%c6, %zero) : (index, f32) -> (memref<?xf32>)

   memref.store %f10, %in1D[%c3] : memref<?xf32>
   call @conv_1d(%in1D, %filter1D, %out1D) : (memref<?xf32>, memref<?xf32>, memref<?xf32>) -> ()
   %out1D_ = memref.cast %out1D : memref<?xf32> to memref<*xf32>
   call @printMemrefF32(%out1D_): (memref<*xf32>) -> ()

   memref.dealloc %filter1D : memref<?xf32>
   memref.dealloc %in1D : memref<?xf32>
   memref.dealloc %out1D : memref<?xf32>
   return
 }

 // CHECK:       Unranked Memref {{.*}}
 // CHECK-NEXT:  [12, 28, 28, 28, 12, 12]
	// RUN: mlir-opt %s -test-transform-dialect-erase-schedule -convert-linalg-to-loops -convert-scf-to-cf -expand-strided-metadata -lower-affine -convert-arith-to-llvm -convert-scf-to-cf --finalize-memref-to-llvm -convert-func-to-llvm -reconcile-unrealized-casts \| \
	// RUN: mlir-cpu-runner -e main -entry-point-result=void \
	// RUN: -shared-libs=%mlir_runner_utils \
	// RUN: \| FileCheck %s

	// RUN: mlir-opt %s -transform-interpreter -test-transform-dialect-erase-schedule -convert-linalg-to-loops -convert-scf-to-cf \
	// RUN: -expand-strided-metadata -lower-affine -convert-arith-to-llvm -convert-scf-to-cf --finalize-memref-to-llvm -convert-func-to-llvm -reconcile-unrealized-casts \| \
	// RUN: mlir-cpu-runner -e main -entry-point-result=void \
	// RUN: -shared-libs=%mlir_runner_utils \
	// RUN: \| FileCheck %s

	func.func private @printMemrefF32(memref<*xf32>)

	// Creates and returns a 1-D buffer of size %s1 filled with the value %f
	func.func @alloc_1d_filled_f32(%s1 : index, %f : f32) -> memref<?xf32> {
	%buf = memref.alloc(%s1) : memref<?xf32>
	linalg.fill ins(%f : f32) outs(%buf : memref<?xf32>)
	return %buf : memref<?xf32>
	}

	func.func @conv_1d(%arg0: memref<?xf32>, %arg1: memref<?xf32>, %arg2: memref<?xf32>) {
	linalg.conv_1d ins (%arg0, %arg1: memref<?xf32>, memref<?xf32>)
	outs (%arg2: memref<?xf32>)
	return
	}

	module attributes {transform.with_named_sequence} {
	transform.named_sequence @__transform_main(%arg1: !transform.any_op {transform.readonly}) {
	%0 = transform.structured.match ops{["linalg.conv_1d"]} in %arg1 : (!transform.any_op) -> !transform.any_op
	%1, %loop = transform.structured.tile_using_for %0 [4] : (!transform.any_op) -> (!transform.any_op, !transform.any_op)
	transform.yield
	}
	}

	func.func @main() {
	%c3 = arith.constant 3 : index
	%c6 = arith.constant 6 : index
	%c8 = arith.constant 8 : index
	%f10 = arith.constant 10.00000e+00 : f32
	%val = arith.constant 2.00000e+00 : f32
	%zero = arith.constant 0.00000e+00 : f32

	%filter1D = call @alloc_1d_filled_f32(%c3, %val) : (index, f32) -> (memref<?xf32>)
	%in1D = call @alloc_1d_filled_f32(%c8, %val) : (index, f32) -> (memref<?xf32>)
	%out1D = call @alloc_1d_filled_f32(%c6, %zero) : (index, f32) -> (memref<?xf32>)

	memref.store %f10, %in1D[%c3] : memref<?xf32>
	call @conv_1d(%in1D, %filter1D, %out1D) : (memref<?xf32>, memref<?xf32>, memref<?xf32>) -> ()
	%out1D_ = memref.cast %out1D : memref<?xf32> to memref<*xf32>
	call @printMemrefF32(%out1D_): (memref<*xf32>) -> ()

	memref.dealloc %filter1D : memref<?xf32>
	memref.dealloc %in1D : memref<?xf32>
	memref.dealloc %out1D : memref<?xf32>
	return
	}

	// CHECK: Unranked Memref {{.*}}
	// CHECK-NEXT: [12, 28, 28, 28, 12, 12]