affine.mlir
8.39 KB
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// RUN: mlir-opt %s -convert-linalg-to-affine-loops | FileCheck %s
// Test that we can lower all the way to LLVM without crashing, don't check results here.
// RUN: mlir-opt %s -convert-linalg-to-affine-loops -convert-linalg-to-llvm -o=/dev/null 2>&1
// CHECK-DAG: #[[$strided3D:.*]] = affine_map<(d0, d1, d2)[s0, s1, s2] -> (d0 * s1 + s0 + d1 * s2 + d2)>
// CHECK-DAG: #[[$stride2Dilation1:.*]] = affine_map<(d0, d1) -> (d0 * 2 + d1)>
// CHECK-DAG: #[[$clampMinMap:.*]] = affine_map<(d0) -> (d0, 0)>
func @matmul(%arg0: memref<?xi8>, %M: index, %N: index, %K: index) {
%c0 = constant 0 : index
%c1 = constant 1 : index
%A = view %arg0[%c0][%M, %K] : memref<?xi8> to memref<?x?xf32>
%B = view %arg0[%c0][%K, %N] : memref<?xi8> to memref<?x?xf32>
%C = view %arg0[%c0][%M, %N] : memref<?xi8> to memref<?x?xf32>
linalg.matmul %A, %B, %C : (memref<?x?xf32>, memref<?x?xf32>, memref<?x?xf32>)
return
}
// CHECK-LABEL: func @matmul(%{{.*}}: memref<?xi8>,
// CHECK-SAME: [[M:arg[0-9]+]]: index
// CHECK-SAME: [[N:arg[0-9]+]]: index
// CHECK-SAME: [[K:arg[0-9]+]]: index
// CHECK: %[[A:.*]] = std.view %{{.*}}[{{.*}}] : memref<?xi8> to memref<?x?xf32>
// CHECK: %[[B:.*]] = std.view %{{.*}}[{{.*}}] : memref<?xi8> to memref<?x?xf32>
// CHECK: %[[C:.*]] = std.view %{{.*}}[{{.*}}] : memref<?xi8> to memref<?x?xf32>
// CHECK: affine.for %{{.*}} = 0 to %{{.*}} {
// CHECK: affine.for %{{.*}} = 0 to %{{.*}} {
// CHECK: affine.for %{{.*}} = 0 to %{{.*}} {
// CHECK-DAG: %[[a:.*]] = affine.load %[[A]][%{{.*}}, %{{.*}}] : memref<?x?xf32>
// CHECK-DAG: %[[b:.*]] = affine.load %[[B]][%{{.*}}, %{{.*}}] : memref<?x?xf32>
// CHECK-DAG: %[[inc:.*]] = mulf %[[a]], %[[b]] : f32
// CHECK-DAG: %[[c:.*]] = affine.load %[[C]][%{{.*}}, %{{.*}}] : memref<?x?xf32>
// CHECK-DAG: %[[res:.*]] = addf %[[c]], %[[inc]] : f32
// CHECK: affine.store %[[res]], %[[C]][%{{.*}}, %{{.*}}] : memref<?x?xf32>
func @conv_view3(%arg0: memref<?x?x?xf32, offset: ?, strides: [?, ?, 1]>, %arg1: memref<?x?x?xf32, offset: ?, strides: [?, ?, 1]>, %arg2: memref<?x?x?xf32, offset: ?, strides: [?, ?, 1]>) {
linalg.conv(%arg0, %arg1, %arg2) {strides = [2]}: memref<?x?x?xf32, offset: ?, strides: [?, ?, 1]>, memref<?x?x?xf32, offset: ?, strides: [?, ?, 1]>, memref<?x?x?xf32, offset: ?, strides: [?, ?, 1]>
return
}
// CHECK-LABEL: func @conv_view3(
// CHECK: %{{.*}}: memref<?x?x?xf32, #[[$strided3D]]>, %{{.*}}: memref<?x?x?xf32, #[[$strided3D]]>, %{{.*}}: memref<?x?x?xf32, #[[$strided3D]]>) {
// CHECK: %[[Z0:.*]] = dim %arg0, %c0 : memref<?x?x?xf32, #[[$strided3D]]>
// CHECK: %[[Q:.*]] = dim %arg0, %c1 : memref<?x?x?xf32, #[[$strided3D]]>
// CHECK: %[[K:.*]] = dim %arg0, %c2 : memref<?x?x?xf32, #[[$strided3D]]>
// CHECK: %[[B:.*]] = dim %arg1, %c0 : memref<?x?x?xf32, #[[$strided3D]]>
// CHECK: %[[X0:.*]] = dim %arg2, %c1 : memref<?x?x?xf32, #[[$strided3D]]>
// CHECK: affine.for %{{.*}} = 0 to %[[B]] {
// CHECK: affine.for %{{.*}} = 0 to %[[X0]] {
// CHECK: affine.for %{{.*}} = 0 to %[[K]] {
// CHECK: affine.for %{{.*}} = 0 to %[[Q]] {
// CHECK: affine.for %{{.*}} = 0 to %[[Z0]] {
// CHECK: %[[SUM:.*]] = affine.apply #[[$stride2Dilation1]](%{{.*}}, %{{.*}})
// No padding needed here; only affine loads.
// CHECK-NEXT: affine.load
// CHECK-NEXT: affine.load
func @conv_padding(%arg0: memref<?x?x?x?xf32>,
%arg1: memref<?x?x?x?xf32>,
%arg2: memref<?x?x?x?xf32>) {
linalg.conv(%arg0, %arg1, %arg2) {dilations = [1, 1],
padding = dense<[[0, 1], [1, 1]]> : tensor<2x2xi64>,
strides = [1, 1]} :
memref<?x?x?x?xf32>, memref<?x?x?x?xf32>, memref<?x?x?x?xf32>
return
}
// CHECK-LABEL: func @conv_padding
// CHECK: %{{.*}}: memref<?x?x?x?xf32>, %{{.*}}: memref<?x?x?x?xf32>, %{{.*}}: memref<?x?x?x?xf32>) {
// CHECK: %[[ZERO:.*]] = constant 0.000000e+00 : f32
// CHECK: %[[Z0:.*]] = dim %arg0, %c0 : memref<?x?x?x?xf32>
// CHECK: %[[Z1:.*]] = dim %arg0, %c1 : memref<?x?x?x?xf32>
// CHECK: %[[Q:.*]] = dim %arg0, %c2 : memref<?x?x?x?xf32>
// CHECK: %[[K:.*]] = dim %arg0, %c3 : memref<?x?x?x?xf32>
// CHECK: %[[B:.*]] = dim %arg1, %c0 : memref<?x?x?x?xf32>
// CHECK: %[[X0:.*]] = dim %arg2, %c1 : memref<?x?x?x?xf32>
// CHECK: %[[X1:.*]] = dim %arg2, %c2 : memref<?x?x?x?xf32>
// CHECK: affine.for %{{.*}} = 0 to %[[B]] {
// CHECK: affine.for %{{.*}} = 0 to %[[X0]] {
// CHECK: affine.for %{{.*}} = 0 to %[[X1]] {
// CHECK: affine.for %{{.*}} = 0 to %[[K]] {
// CHECK: affine.for %{{.*}} = 0 to %[[Q]] {
// CHECK: affine.for %{{.*}} = 0 to %[[Z0]] {
// CHECK: affine.for %{{.*}} = 0 to %[[Z1]] {
// CHECK: %[[SUM0:.*]] = affine.apply #{{.*}}(%{{.*}}, %{{.*}})
// CHECK: %[[SUM1:.*]] = affine.apply #{{.*}}(%{{.*}}, %{{.*}})
// CHECK: %[[IDX:.*]] = affine.max #[[$clampMinMap]](%[[SUM0]])
// CHECK: %[[IDY:.*]] = affine.max #[[$clampMinMap]](%[[SUM1]])
// Padded conv involves an affine.max in the memory access and this is not
// allowed by affine.load. Use std.load in such cases.
// CHECK: %{{.*}} = load %{{.*}}[%{{.*}}, %[[IDX]], %[[IDY]], %{{.*}}] : memref<?x?x?x?xf32>
// CHECK: %{{.*}} = select %{{.*}}, %{{.*}}, %{{.*}} : f32
// CHECK: %{{.*}} = affine.load %{{.*}}[%{{.*}}, %{{.*}}, %{{.*}}, %{{.*}}] : memref<?x?x?x?xf32>
// CHECK: %{{.*}} = mulf %{{.*}}, %{{.*}} : f32
// CHECK: %{{.*}} = affine.load %{{.*}}[%{{.*}}, %{{.*}}, %{{.*}}, %{{.*}}] : memref<?x?x?x?xf32>
// CHECK: %{{.*}} = addf %{{.*}}, %{{.*}} : f32
// CHECK: affine.store %{{.*}}, %{{.*}}[%{{.*}}, %{{.*}}, %{{.*}}, %{{.*}}] : memref<?x?x?x?xf32>
//----------------------------------------------------------------------------//
// Named ops to loops.
//----------------------------------------------------------------------------//
func @named_batch_matmul(%A: memref<?x?x?xf32>, %B: memref<?x?x?xf32>, %C: memref<?x?x?xf32>) {
linalg.batch_matmul %A, %B, %C : (memref<?x?x?xf32>, memref<?x?x?xf32>, memref<?x?x?xf32>) -> ()
return
}
// CHECK-LABEL: @named_batch_matmul
// CHECK-SAME: %[[mA:[a-zA-Z0-9]+]]: memref<?x?x?xf32>
// CHECK-SAME: %[[mB:[a-zA-Z0-9]+]]: memref<?x?x?xf32>
// CHECK-SAME: %[[mC:[a-zA-Z0-9]+]]: memref<?x?x?xf32>
// CHECK: %[[B:.*]] = dim %[[mA]], %c0 : memref<?x?x?xf32>
// CHECK: %[[M:.*]] = dim %[[mA]], %c1 : memref<?x?x?xf32>
// CHECK: %[[K:.*]] = dim %[[mA]], %c2 : memref<?x?x?xf32>
// CHECK: %[[N:.*]] = dim %[[mB]], %c2 : memref<?x?x?xf32>
// CHECK: affine.for %[[b:.*]] = 0 to %[[B]] {
// CHECK: affine.for %[[m:.*]] = 0 to %[[M]] {
// CHECK: affine.for %[[n:.*]] = 0 to %[[N]] {
// CHECK: affine.for %[[k:.*]] = 0 to %[[K]] {
// CHECK: %[[va:.*]] = affine.load %[[mA]][%[[b]], %[[m]], %[[k]]] : memref<?x?x?xf32>
// CHECK: %[[vb:.*]] = affine.load %[[mB]][%[[b]], %[[k]], %[[n]]] : memref<?x?x?xf32>
// CHECK: %[[vc:.*]] = affine.load %[[mC]][%[[b]], %[[m]], %[[n]]] : memref<?x?x?xf32>
// CHECK: %[[inc:.*]] = mulf %[[va]], %[[vb]] : f32
// CHECK: %[[res:.*]] = addf %[[vc]], %[[inc]] : f32
// CHECK: affine.store %[[res]], %[[mC]][%[[b]], %[[m]], %[[n]]] : memref<?x?x?xf32>
// CHECK-LABEL: func @pooling_max_min
func @pooling_max_min(%arg0: memref<?x?xf32>,
%arg1: memref<?x?xi32>,
%arg2: memref<?x?xf32>) {
linalg.pooling_max(%arg0, %arg1, %arg2) { strides = [2, 1] }:
memref<?x?xf32>, memref<?x?xi32>, memref<?x?xf32>
linalg.pooling_min(%arg0, %arg1, %arg2) { strides = [2, 1] }:
memref<?x?xf32>, memref<?x?xi32>, memref<?x?xf32>
return
}
// This is a basic check to make sure the right load/stores are used. loops.mlir
// checks for the rest.
// CHECK: affine.load
// CHECK-NEXT: affine.load
// CHECK-NEXT: cmpf
// CHECK-NEXT: select
// CHECK-NEXT: affine.store
// The min pooling body.
// CHECK: affine.load
// CHECK-NEXT: affine.load
// CHECK-NEXT: cmpf
// CHECK-NEXT: select
// CHECK-NEXT: affine.store