mlir/test/Dialect/Linalg/fusion-pattern.mlir - llvm-project - Git at Google

 // RUN: mlir-opt %s -test-linalg-fusion-transform-patterns -canonicalize -cse -split-input-file | FileCheck %s

 module {
   func @basic_fusion(%arg0: memref<?x?xf32>, %arg1: memref<?x?xf32>,
                      %arg2: memref<?x?xf32>) {
     %cst = constant 0.000000e+00 : f32
     linalg.fill(%arg2, %cst) : memref<?x?xf32>, f32
     linalg.matmul {__internal_linalg_transform__ = "basic_fusion"}
       ins(%arg0, %arg1 : memref<?x?xf32>, memref<?x?xf32>)
       outs(%arg2 : memref<?x?xf32>)
     return
   }
 }

 //  CHECK-DAG: #[[MAP0:.+]] = affine_map<(d0)[s0] -> (32, -d0 + s0)>
 //  CHECK-DAG: #[[MAP1:.+]] = affine_map<(d0, d1)[s0, s1] -> (d0 * s1 + s0 + d1)>
 //  CHECK-DAG: #[[MAP2:.+]] = affine_map<(d0)[s0] -> (64, -d0 + s0)>
 //  CHECK-DAG: #[[MAP3:.+]] = affine_map<(d0)[s0] -> (16, -d0 + s0)>
 //      CHECK: func @basic_fusion
 // CHECK-SAME:   %[[ARG0:[a-zA-Z0-9_]+]]: memref<?x?xf32>
 // CHECK-SAME:   %[[ARG1:[a-zA-Z0-9_]+]]: memref<?x?xf32>
 // CHECK-SAME:   %[[ARG2:[a-zA-Z0-9_]+]]: memref<?x?xf32>
 //  CHECK-DAG:   %[[C0:.+]] = constant 0 : index
 //  CHECK-DAG:   %[[C1:.+]] = constant 1 : index
 //  CHECK-DAG:   %[[C32:.+]] = constant 32 : index
 //  CHECK-DAG:   %[[C64:.+]] = constant 64 : index
 //  CHECK-DAG:   %[[C16:.+]] = constant 16 : index
 //  CHECK-DAG:   %[[CST:.+]] = constant 0.0{{.*}} : f32
 //  CHECK-DAG:   linalg.fill(%[[ARG2]], %[[CST]])
 // CHECK-SAME:   __internal_linalg_transform__ = "after_basic_fusion_original"
 //  CHECK-DAG:   %[[M:.+]] = dim %[[ARG0]], %[[C0]]
 //  CHECK-DAG:   %[[N:.+]] = dim %[[ARG1]], %[[C1]]
 //      CHECK:   scf.parallel (%[[IV0:.+]], %[[IV1:.+]]) =
 // CHECK-SAME:     to (%[[M]], %[[N]])
 // CHECK-SAME:     step (%[[C32]], %[[C64]]) {
 //      CHECK:     %[[TILE_M:.+]] = affine.min #[[MAP0]](%[[IV0]])[%[[M]]]
 //      CHECK:     %[[K:.+]] = dim %[[ARG0]], %[[C1]]
 //      CHECK:     %[[SV1:.+]] = subview %[[ARG0]][%[[IV0]], 0]
 // CHECK-SAME:       [%[[TILE_M]], %[[K]]]
 //      CHECK:     %[[K_2:.+]] = dim %[[ARG1]], %[[C0]]
 //      CHECK:     %[[TILE_N:.+]] = affine.min #[[MAP2]](%[[IV1]])[%[[N]]]
 //      CHECK:     %[[SV2:.+]] = subview %[[ARG1]][0, %[[IV1]]]
 // CHECK-SAME:       %[[K_2]], %[[TILE_N]]
 //      CHECK:     %[[M_2:.+]] = dim %[[ARG2]], %[[C0]]
 //      CHECK:     %[[TILE_M_2:.+]] = affine.min #[[MAP0]](%[[IV0]])[%[[M_2]]]
 //      CHECK:     %[[N_2:.+]] = dim %[[ARG2]], %[[C1]]
 //      CHECK:     %[[TILE_N_2:.+]] = affine.min #[[MAP2]](%[[IV1]])[%[[N_2]]]
 //      CHECK:     %[[SV3:.+]] = subview %[[ARG2]][%[[IV0]], %[[IV1]]]
 // CHECK-SAME:       [%[[TILE_M_2]], %[[TILE_N_2]]]
 //      CHECK:     %[[SV3_2:.+]] = subview %[[ARG2]][%[[IV0]], %[[IV1]]]
 // CHECK-SAME:       [%[[TILE_M]], %[[TILE_N]]]
 //      CHECK:     linalg.fill(%[[SV3_2]], %[[CST]])
 // CHECK-SAME:       __internal_linalg_transform__ = "after_basic_fusion_producer"
 //      CHECK:     scf.for %[[IV2:.+]] = %[[C0]] to %[[K]] step %[[C16]] {
 //      CHECK:       %[[TILE_K:.+]] = affine.min #[[MAP3]](%[[IV2]])[%[[K]]]
 //      CHECK:       %[[SV4:.+]] = subview %[[SV1]][0, %[[IV2]]]
 // CHECK-SAME:         [%[[TILE_M]], %[[TILE_K]]]
 //      CHECK:       %[[TILE_K_2:.+]] = affine.min #[[MAP3]](%[[IV2]])[%[[K_2]]]
 //      CHECK:       %[[SV5:.+]] = subview %[[SV2]][%[[IV2]], 0]
 // CHECK-SAME:         [%[[TILE_K_2]], %[[TILE_N]]]
 //      CHECK:       linalg.matmul
 // CHECK-SAME:         __internal_linalg_transform__ = "after_basic_fusion"
 // CHECK-SAME:         ins(%[[SV4]], %[[SV5]]
 // CHECK-SAME:           : memref<?x?xf32, #[[MAP1]]>, memref<?x?xf32, #[[MAP1]]>)
 // CHECK-SAME:         outs(%[[SV3]] : memref<?x?xf32, #[[MAP1]]>)
 //      CHECK:     }
 //      CHECK:   }
 //      CHECK:   linalg.matmul
 // CHECK-SAME:     __internal_linalg_transform__ = "after_basic_fusion_original"

 // -----

 module {
   func @rhs_fusion(%arg0: memref<?x?xf32>, %arg1: memref<?x?xf32>,
                               %arg2: memref<?x?xf32>, %arg3: memref<?x?xf32>) {
     %cst = constant 0.000000e+00 : f32
     linalg.copy(%arg1, %arg2) : memref<?x?xf32>, memref<?x?xf32>
     linalg.fill(%arg3, %cst) : memref<?x?xf32>, f32
     linalg.matmul {__internal_linalg_transform__ = "rhs_fusion"}
       ins(%arg0, %arg2 : memref<?x?xf32>, memref<?x?xf32>)
       outs(%arg3 : memref<?x?xf32>)
     return
   }
 }
 //  CHECK-DAG: #[[MAP0:.+]] = affine_map<(d0)[s0] -> (64, -d0 + s0)>
 //  CHECK-DAG: #[[MAP1:.+]] = affine_map<(d0, d1)[s0, s1] -> (d0 * s1 + s0 + d1)>
 //  CHECK-DAG: #[[MAP2:.+]] = affine_map<(d0)[s0] -> (32, -d0 + s0)>
 //  CHECK-DAG: #[[MAP3:.+]] = affine_map<(d0)[s0] -> (16, -d0 + s0)>
 //      CHECK: func @rhs_fusion
 // CHECK-SAME:   %[[ARG0:[a-zA-Z0-9_]+]]: memref<?x?xf32>
 // CHECK-SAME:   %[[ARG1:[a-zA-Z0-9_]+]]: memref<?x?xf32>
 // CHECK-SAME:   %[[ARG2:[a-zA-Z0-9_]+]]: memref<?x?xf32>
 // CHECK-SAME:   %[[ARG3:[a-zA-Z0-9_]+]]: memref<?x?xf32>
 //  CHECK-DAG:   %[[C0:.+]] = constant 0 : index
 //  CHECK-DAG:   %[[C1:.+]] = constant 1 : index
 //  CHECK-DAG:   %[[C32:.+]] = constant 32 : index
 //  CHECK-DAG:   %[[C64:.+]] = constant 64 : index
 //  CHECK-DAG:   %[[C16:.+]] = constant 16 : index
 //  CHECK-DAG:   %[[CST:.+]] = constant 0.0{{.*}} : f32
 //  CHECK-DAG:   linalg.copy(%[[ARG1]], %[[ARG2]])
 // CHECK-SAME:   __internal_linalg_transform__ = "after_rhs_fusion_original"
 //  CHECK-DAG:   %[[N:.+]] = dim %[[ARG2]], %[[C1]]
 //      CHECK:   scf.parallel (%[[IV0:.+]]) =
 // CHECK-SAME:     (%[[C0]]) to (%[[N]]) step (%[[C64]]) {
 //      CHECK:     %[[K:.+]] = dim %[[ARG2]], %[[C0]]
 //      CHECK:     %[[TILE_N:.+]] = affine.min #[[MAP0]](%[[IV0]])[%[[N]]]
 //      CHECK:     %[[SV1:.+]] = subview %[[ARG2]][0, %[[IV0]]]
 // CHECK-SAME:       [%[[K]], %[[TILE_N]]]
 //      CHECK:     %[[M:.+]] = dim %[[ARG3]], %[[C0]]
 //      CHECK:     %[[N_2:.+]] = dim %[[ARG3]], %[[C1]]
 //      CHECK:     %[[TILE_N_2:.+]] = affine.min #[[MAP0]](%[[IV0]])[%[[N_2]]]
 //      CHECK:     %[[SV2:.+]] = subview %[[ARG3]][0, %[[IV0]]]
 // CHECK-SAME:       [%[[M]], %[[TILE_N_2]]]
 //      CHECK:     %[[K_2:.+]] = dim %[[ARG1]], %[[C0]]
 //      CHECK:     %[[SV3:.+]] = subview %[[ARG1]][0, %[[IV0]]]
 // CHECK-SAME:       [%[[K_2]], %[[TILE_N]]]
 //      CHECK:     %[[SV3_2:.+]] = subview %[[ARG2]][0, %[[IV0]]]
 // CHECK-SAME:       [%[[K_2]], %[[TILE_N]]]
 //      CHECK:     linalg.copy(%[[SV3]], %[[SV3_2]])
 // CHECK-SAME:       __internal_linalg_transform__ = "after_rhs_fusion_producer"
 //  CHECK-NOT:     linalg.fill
 //  CHECK-DAG:     %[[M_2:.+]] = dim %[[ARG0]], %[[C0]]
 //  CHECK-DAG:     %[[K_2:.+]] = dim %[[ARG0]], %[[C1]]
 //      CHECK:     scf.parallel (%[[IV1:.+]]) =
 // CHECK-SAME:       (%[[C0]]) to (%[[M_2]]) step (%[[C32]]) {
 // CHECK-NEXT:       scf.for %[[IV2:.+]] = %[[C0]] to %[[K_2]] step %[[C16]] {
 //      CHECK:         %[[TILE_M:.+]] = affine.min #[[MAP2]](%[[IV1]])[%[[M_2]]]
 //      CHECK:         %[[TILE_K:.+]] = affine.min #[[MAP3]](%[[IV2]])[%[[K_2]]]
 //      CHECK:         %[[SV4:.+]] = subview %[[ARG0]][%[[IV1]], %[[IV2]]]
 // CHECK-SAME:           [%[[TILE_M]], %[[TILE_K]]]
 //      CHECK:         %[[TILE_K_2:.+]] = affine.min #[[MAP3]](%[[IV2]])[%[[K]]]
 //      CHECK:         %[[SV5:.+]] = subview %[[SV1]][%[[IV2]], 0]
 // CHECK-SAME:           [%[[TILE_K_2]], %[[TILE_N]]]
 //      CHECK:         %[[TILE_M_2:.+]] = affine.min #[[MAP2]](%[[IV1]])[%[[M]]]
 //      CHECK:         %[[SV6:.+]] = subview %[[SV2]][%[[IV1]], 0]
 // CHECK-SAME:           [%[[TILE_M_2]], %[[TILE_N_2]]]
 //      CHECK:         linalg.matmul
 // CHECK-SAME:           __internal_linalg_transform__ = "after_rhs_fusion"
 // CHECK-SAME:           ins(%[[SV4]], %[[SV5]]
 // CHECK-SAME:             : memref<?x?xf32, #[[MAP1]]>, memref<?x?xf32, #[[MAP1]]>)
 // CHECK-SAME:           outs(%[[SV6]] : memref<?x?xf32, #[[MAP1]]>)
 //      CHECK:       }
 //      CHECK:     }
 //      CHECK:   }
 //      CHECK:   linalg.matmul
 // CHECK-SAME:     __internal_linalg_transform__ = "after_rhs_fusion_original"


 // -----

 module {
   func @two_operand_fusion(%arg0: memref<?x?xf32>, %arg1: memref<?x?xf32>,
                               %arg2: memref<?x?xf32>, %arg3: memref<?x?xf32>) {
     %cst = constant 0.000000e+00 : f32
     linalg.copy(%arg0, %arg1) : memref<?x?xf32>, memref<?x?xf32>
     linalg.fill(%arg3, %cst) : memref<?x?xf32>, f32
     linalg.matmul {__internal_linalg_transform__ = "two_operand_fusion"}
       ins(%arg1, %arg2 : memref<?x?xf32>, memref<?x?xf32>)
       outs(%arg3 : memref<?x?xf32>)
     return
   }
 }
 //  CHECK-DAG: #[[MAP0:.+]] = affine_map<(d0)[s0] -> (32, -d0 + s0)>
 //  CHECK-DAG: #[[MAP1:.+]] = affine_map<(d0, d1)[s0, s1] -> (d0 * s1 + s0 + d1)>
 //  CHECK-DAG: #[[MAP2:.+]] = affine_map<(d0)[s0] -> (16, -d0 + s0)>
 //  CHECK-DAG: #[[MAP3:.+]] = affine_map<(d0)[s0] -> (64, -d0 + s0)>
 //      CHECK: func @two_operand_fusion
 // CHECK-SAME:   %[[ARG0:[a-zA-Z0-9_]+]]: memref<?x?xf32>
 // CHECK-SAME:   %[[ARG1:[a-zA-Z0-9_]+]]: memref<?x?xf32>
 // CHECK-SAME:   %[[ARG2:[a-zA-Z0-9_]+]]: memref<?x?xf32>
 // CHECK-SAME:   %[[ARG3:[a-zA-Z0-9_]+]]: memref<?x?xf32>
 //  CHECK-DAG:   %[[C0:.+]] = constant 0 : index
 //  CHECK-DAG:   %[[C1:.+]] = constant 1 : index
 //  CHECK-DAG:   %[[C32:.+]] = constant 32 : index
 //  CHECK-DAG:   %[[C64:.+]] = constant 64 : index
 //  CHECK-DAG:   %[[C16:.+]] = constant 16 : index
 //  CHECK-DAG:   %[[CST:.+]] = constant 0.0{{.*}} : f32
 //      CHECK:   linalg.copy(%[[ARG0]], %[[ARG1]])
 // CHECK-SAME:     __internal_linalg_transform__ = "after_two_operand_fusion_original"
 //      CHECK:   linalg.fill(%[[ARG3]], %[[CST]])
 // CHECK-SAME:     __internal_linalg_transform__ = "after_two_operand_fusion_original"
 //  CHECK-DAG:   %[[M:.+]] = dim %[[ARG1]], %[[C0]]
 //      CHECK:   scf.parallel (%[[IV0:.+]]) =
 // CHECK-SAME:     (%[[C0]]) to (%[[M]]) step (%[[C32]]) {
 //      CHECK:     %[[TILE_M:.+]] = affine.min #[[MAP0]](%[[IV0]])[%[[M]]]
 //      CHECK:     %[[K:.+]] = dim %[[ARG1]], %[[C1]]
 //      CHECK:     %[[SV1:.+]] = subview %[[ARG1]][%[[IV0]], 0]
 // CHECK-SAME:       [%[[TILE_M]], %[[K]]]
 //      CHECK:     %[[M_2:.+]] = dim %[[ARG3]], %[[C0]]
 //      CHECK:     %[[TILE_M_2:.+]] = affine.min #[[MAP0]](%[[IV0]])[%[[M_2]]]
 //      CHECK:     %[[N:.+]] = dim %[[ARG3]], %[[C1]]
 //      CHECK:     %[[SV2:.+]] = subview %[[ARG3]][%[[IV0]], 0]
 // CHECK-SAME:       [%[[TILE_M_2]], %[[N]]]
 //      CHECK:     %[[SV2_2:.+]] = subview %[[ARG3]][%[[IV0]], 0]
 // CHECK-SAME:       [%[[TILE_M]], %[[N]]]
 //      CHECK:     %[[K_2:.+]] = dim %[[ARG0]], %[[C1]]
 //      CHECK:     %[[SV3:.+]] = subview %[[ARG0]][%[[IV0]], 0]
 // CHECK-SAME:       [%[[TILE_M]], %[[K_2]]]
 //      CHECK:     %[[SV3_2:.+]] = subview %[[ARG1]][%[[IV0]], 0]
 // CHECK-SAME:       [%[[TILE_M]], %[[K_2]]]
 //      CHECK:     linalg.copy(%[[SV3]], %[[SV3_2]])
 // CHECK-SAME:       __internal_linalg_transform__ = "after_two_operand_fusion_producer"
 //      CHECK:     linalg.fill(%[[SV2_2]], %[[CST]])
 // CHECK-SAME:       __internal_linalg_transform__ = "after_two_operand_fusion_producer"
 //  CHECK-DAG:     %[[N_2:.+]] = dim %[[ARG2]], %[[C1]]
 //      CHECK:     scf.parallel (%[[IV1:.+]]) =
 // CHECK-SAME:       (%[[C0]]) to (%[[N_2]]) step (%[[C64]]) {
 // CHECK-NEXT:       scf.for %[[IV2:.+]] = %[[C0]] to %[[K]] step %[[C16]] {
 //      CHECK:         %[[TILE_K:.+]] = affine.min #[[MAP2]](%[[IV2]])[%[[K]]]
 //      CHECK:         %[[SV4:.+]] = subview %[[SV1]][0, %[[IV2]]]
 // CHECK-SAME:           [%[[TILE_M]], %[[TILE_K]]]
 //      CHECK:         %[[K_2:.+]] = dim %[[ARG2]], %[[C0]]
 //      CHECK:         %[[TILE_K_2:.+]] = affine.min #[[MAP2]](%[[IV2]])[%[[K_2]]]
 //      CHECK:         %[[TILE_N:.+]] = affine.min #[[MAP3]](%[[IV1]])[%[[N_2]]]
 //      CHECK:         %[[SV5:.+]] = subview %[[ARG2]][%[[IV2]], %[[IV1]]]
 // CHECK-SAME:           [%[[TILE_K_2]], %[[TILE_N]]]
 //      CHECK:         %[[TILE_N_2:.+]] = affine.min #[[MAP3]](%[[IV1]])[%[[N]]]
 //      CHECK:         %[[SV6:.+]] = subview %[[SV2]][0, %[[IV1]]]
 // CHECK-SAME:           [%[[TILE_M_2]], %[[TILE_N_2]]]
 //      CHECK:         linalg.matmul
 // CHECK-SAME:           __internal_linalg_transform__ = "after_two_operand_fusion"
 // CHECK-SAME:           ins(%[[SV4]], %[[SV5]]
 // CHECK-SAME:             : memref<?x?xf32, #[[MAP1]]>, memref<?x?xf32, #[[MAP1]]>)
 // CHECK-SAME:           outs(%[[SV6]] : memref<?x?xf32, #[[MAP1]]>)
 //      CHECK:       }
 //      CHECK:     }
 //      CHECK:   }
 //      CHECK:   linalg.matmul
 // CHECK-SAME:     __internal_linalg_transform__ = "after_two_operand_fusion_original"

 // -----

 module {
   func @matmul_fusion(%arg0: memref<?x?xf32>, %arg1: memref<?x?xf32>,
                       %arg2: memref<?x?xf32>, %arg3: memref<?x?xf32>,
                       %arg4: memref<?x?xf32>) {
     linalg.matmul ins(%arg0, %arg1 : memref<?x?xf32>, memref<?x?xf32>)
       outs(%arg2 : memref<?x?xf32>)
     linalg.matmul {__internal_linalg_transform__ = "lhs_fusion"}
       ins(%arg2, %arg3 : memref<?x?xf32>, memref<?x?xf32>)
       outs(%arg4 : memref<?x?xf32>)
     return
   }
 }
 //  CHECK-DAG: #[[MAP0:.+]] = affine_map<(d0)[s0] -> (32, -d0 + s0)>
 //  CHECK-DAG: #[[MAP1:.+]] = affine_map<(d0, d1)[s0, s1] -> (d0 * s1 + s0 + d1)>
 //  CHECK-DAG: #[[MAP2:.+]] = affine_map<(d0)[s0] -> (16, -d0 + s0)>
 //  CHECK-DAG: #[[MAP3:.+]] = affine_map<(d0)[s0] -> (64, -d0 + s0)>
 //      CHECK: func @matmul_fusion
 // CHECK-SAME:   %[[ARG0:[a-zA-Z0-9_]+]]: memref<?x?xf32>
 // CHECK-SAME:   %[[ARG1:[a-zA-Z0-9_]+]]: memref<?x?xf32>
 // CHECK-SAME:   %[[ARG2:[a-zA-Z0-9_]+]]: memref<?x?xf32>
 // CHECK-SAME:   %[[ARG3:[a-zA-Z0-9_]+]]: memref<?x?xf32>
 // CHECK-SAME:   %[[ARG4:[a-zA-Z0-9_]+]]: memref<?x?xf32>
 //  CHECK-DAG:   %[[C0:.+]] = constant 0 : index
 //  CHECK-DAG:   %[[C1:.+]] = constant 1 : index
 //  CHECK-DAG:   %[[C32:.+]] = constant 32 : index
 //  CHECK-DAG:   %[[C64:.+]] = constant 64 : index
 //  CHECK-DAG:   %[[C16:.+]] = constant 16 : index
 //      CHECK:   linalg.matmul
 // CHECK-SAME:     __internal_linalg_transform__ = "after_lhs_fusion_original"
 //  CHECK-DAG:   %[[M:.+]] = dim %[[ARG2]], %[[C0]]
 //      CHECK:   scf.parallel (%[[IV0:.+]]) =
 // CHECK-SAME:     (%[[C0]]) to (%[[M]]) step (%[[C32]]) {
 //      CHECK:     %[[TILE_M:.+]] = affine.min #[[MAP0]](%[[IV0]])[%[[M]]]
 //      CHECK:     %[[K2:.+]] = dim %[[ARG2]], %[[C1]]
 //      CHECK:     %[[SV1:.+]] = subview %[[ARG2]][%[[IV0]], 0]
 // CHECK-SAME:       [%[[TILE_M]], %[[K2]]]
 //      CHECK:     %[[M_2:.+]] = dim %[[ARG4]], %[[C0]]
 //      CHECK:     %[[TILE_M_2:.+]] = affine.min #[[MAP0]](%[[IV0]])[%[[M_2]]]
 //      CHECK:     %[[N:.+]] = dim %[[ARG4]], %[[C1]]
 //      CHECK:     %[[SV2:.+]] = subview %[[ARG4]][%[[IV0]], 0]
 // CHECK-SAME:       [%[[TILE_M_2]], %[[N]]]
 //      CHECK:     %[[K2_2:.+]] = dim %[[ARG1]], %[[C1]]
 //      CHECK:     %[[K1:.+]] = dim %[[ARG0]], %[[C1]]
 //      CHECK:     %[[SV3:.+]] = subview %[[ARG0]][%[[IV0]], 0]
 // CHECK-SAME:       [%[[TILE_M]], %[[K1]]]
 //      CHECK:     %[[SV4:.+]] = subview %[[ARG1]][0, 0] [%[[K1]], %[[K2_2]]]
 //      CHECK:     %[[SV1_2:.+]] = subview %[[ARG2]][%[[IV0]], 0]
 // CHECK-SAME:       [%[[TILE_M]], %[[K2_2]]]
 //      CHECK:     linalg.matmul
 // CHECK-SAME:         __internal_linalg_transform__ = "after_lhs_fusion_producer"
 // CHECK-SAME:         ins(%[[SV3]], %[[SV4]]
 // CHECK-SAME:           : memref<?x?xf32, #[[MAP1]]>, memref<?x?xf32, #[[MAP1]]>)
 // CHECK-SAME:         outs(%[[SV1_2]] : memref<?x?xf32, #[[MAP1]]>)
 //  CHECK-DAG:     %[[N_2:.+]] = dim %[[ARG3]], %[[C1]]
 //      CHECK:     scf.parallel (%[[IV1:.+]]) =
 // CHECK-SAME:       (%[[C0]]) to (%[[N_2]]) step (%[[C64]]) {
 // CHECK-NEXT:       scf.for %[[IV2:.+]] = %[[C0]] to %[[K]] step %[[C16]] {
 //      CHECK:         %[[TILE_K:.+]] = affine.min #[[MAP2]](%[[IV2]])[%[[K]]]
 //      CHECK:         %[[SV6:.+]] = subview %[[SV1]][0, %[[IV2]]]
 // CHECK-SAME:           [%[[TILE_M]], %[[TILE_K]]]
 //      CHECK:         %[[K_2:.+]] = dim %[[ARG3]], %[[C0]]
 //      CHECK:         %[[TILE_K_2:.+]] = affine.min #[[MAP2]](%[[IV2]])[%[[K_2]]]
 //      CHECK:         %[[TILE_N:.+]] = affine.min #[[MAP3]](%[[IV1]])[%[[N_2]]]
 //      CHECK:         %[[SV7:.+]] = subview %[[ARG3]][%[[IV2]], %[[IV1]]]
 // CHECK-SAME:           [%[[TILE_K_2]], %[[TILE_N]]]
 //      CHECK:         %[[TILE_N_2:.+]] = affine.min #[[MAP3]](%[[IV1]])[%[[N]]]
 //      CHECK:         %[[SV8:.+]] = subview %[[SV2]][0, %[[IV1]]]
 // CHECK-SAME:           [%[[TILE_M_2]], %[[TILE_N_2]]]
 //      CHECK:         linalg.matmul
 // CHECK-SAME:           __internal_linalg_transform__ = "after_lhs_fusion"
 // CHECK-SAME:           ins(%[[SV6]], %[[SV7]]
 // CHECK-SAME:             : memref<?x?xf32, #[[MAP1]]>, memref<?x?xf32, #[[MAP1]]>)
 // CHECK-SAME:           outs(%[[SV8]] : memref<?x?xf32, #[[MAP1]]>)
 //      CHECK:       }
 //      CHECK:     }
 //      CHECK:   }
 //      CHECK:   linalg.matmul
 // CHECK-SAME:     __internal_linalg_transform__ = "after_lhs_fusion_original"

 // -----

 module {
   func @matmul_plus_matmul(%arg0: memref<?x?xf32>, %arg1: memref<?x?xf32>,
                            %arg2: memref<?x?xf32>) {
     %c0 = constant 0 : index
     %c1 = constant 1 : index
     %0 = dim %arg2, %c0 : memref<?x?xf32>
     %1 = dim %arg2, %c1 : memref<?x?xf32>
     %2 = alloc(%0, %1) : memref<?x?xf32>
     linalg.matmul ins(%arg0, %arg1 : memref<?x?xf32>, memref<?x?xf32>)
       outs(%2 : memref<?x?xf32>)
     linalg.generic
       {indexing_maps = [affine_map<(d0, d1) -> (d0, d1)>,
                         affine_map<(d0, d1) -> (d0, d1)>,
                         affine_map<(d0, d1) -> (d0, d1)>],
        iterator_types = ["parallel", "parallel"],
        __internal_linalg_transform__ = "transpose_fusion"}
       ins(%2, %2 : memref<?x?xf32>, memref<?x?xf32>)
       outs(%arg2 : memref<?x?xf32>) {
       ^bb0(%arg3 : f32, %arg4 : f32, %arg5 : f32) :
         %3 = addf %arg3, %arg4 : f32
         linalg.yield %3 : f32
       }
     return
   }
 }
 //       CHECK: func @matmul_plus_matmul
 //  CHECK-SAME:   %[[ARG0:[a-zA-Z0-9_]+]]: memref<?x?xf32>
 //  CHECK-SAME:   %[[ARG1:[a-zA-Z0-9_]+]]: memref<?x?xf32>
 //  CHECK-SAME:   %[[ARG2:[a-zA-Z0-9_]+]]: memref<?x?xf32>
 //       CHECK:   %[[T2:.+]] = alloc(%{{.*}}, %{{.*}}) : memref<?x?xf32>
 //       CHECK:   linalg.matmul
 //  CHECK-SAME:     after_transpose_fusion_original
 //       CHECK:   scf.parallel (%[[ARG3:[a-zA-Z0-9_]+]], %[[ARG4:.[a-zA-Z0-9_]+]])
 //       CHECK:     %[[T5:.+]] = subview %[[T2]][%[[ARG3]], %[[ARG4]]]
 //       CHECK:     %[[T6:.+]] = subview %[[ARG2]][%[[ARG3]], %[[ARG4]]]
 //       CHECK:     %[[T8:.+]] = subview %[[ARG0]][%[[ARG3]], 0]
 //       CHECK:     %[[T9:.+]] = subview %[[ARG1]][0, %[[ARG4]]]
 //       CHECK:     linalg.matmul
 //  CHECK-SAME:       after_transpose_fusion_producer
 //  CHECK-SAME:       ins(%[[T8]], %[[T9]]
 //  CHECK-SAME:       outs(%[[T5]]
 //   CHECK-NOT:     linalg.matmul
 //       CHECK:     linalg.generic
 //  CHECK-SAME:       ins(%[[T5]], %[[T5]]
 //  CHECK-SAME:       outs(%[[T6]]
 //  CHECK-SAME:       after_transpose_fusion

 // -----

 module {
   func @matmul_plus_transpose_matmul(%arg0: memref<?x?xf32>,
                                      %arg1: memref<?x?xf32>,
                                      %arg2: memref<?x?xf32>) {
     %c0 = constant 0 : index
     %c1 = constant 1 : index
     %0 = dim %arg2, %c0 : memref<?x?xf32>
     %1 = dim %arg2, %c1 : memref<?x?xf32>
     %2 = alloc(%0, %1) : memref<?x?xf32>
     linalg.matmul ins(%arg0, %arg1 : memref<?x?xf32>, memref<?x?xf32>)
       outs(%2 : memref<?x?xf32>)
     linalg.generic
       {indexing_maps = [affine_map<(d0, d1) -> (d0, d1)>,
                         affine_map<(d0, d1) -> (d1, d0)>,
                         affine_map<(d0, d1) -> (d0, d1)>],
        iterator_types = ["parallel", "parallel"],
        __internal_linalg_transform__ = "transpose_fusion"}
       ins(%2, %2 : memref<?x?xf32>, memref<?x?xf32>)
       outs(%arg2 : memref<?x?xf32>) {
       ^bb0(%arg3 : f32, %arg4 : f32, %arg5 : f32) :
         %3 = addf %arg3, %arg4 : f32
         linalg.yield %3 : f32
       }
     return
   }
 }
 // CHECK-LABEL: func @matmul_plus_transpose_matmul
 //   CHECK-NOT:   scf.parallel
 //   CHECK-NOT:   scf.for
 //       CHECK:   linalg.matmul
 //   CHECK-NOT:   scf.parallel
 //   CHECK-NOT:   scf.for
 //       CHECK:   linalg.generic
 //   CHECK-NOT:   scf.parallel
 //   CHECK-NOT:   scf.for

 // -----

 #map0 = affine_map<(d0)[s0] -> (32, -d0 + s0)>
 #map1 = affine_map<(d0)[s0] -> (64, -d0 + s0)>
 #map2 = affine_map<(d0)[s0] -> (16, -d0 + s0)>
 #map3 = affine_map<(d0, d1)[s0, s1] -> (d0 * s1 + s0 + d1)>
 module {
   func @basic_no_fusion(%arg0: memref<?x?xf32>, %arg1: memref<?x?xf32>,
                         %arg2: memref<?x?xf32>) {
     %c0 = constant 0 : index
     %c1 = constant 1 : index
     %c2 = constant 2 : index
     %c32 = constant 32 : index
     %c64 = constant 64 : index
     %c16 = constant 16 : index
     %cst = constant 0.000000e+00 : f32
     linalg.fill(%arg2, %cst) : memref<?x?xf32>, f32
     %0 = dim %arg0, %c0 : memref<?x?xf32>
     %1 = dim %arg1, %c1 : memref<?x?xf32>
     %2 = dim %arg0, %c1 : memref<?x?xf32>
     scf.parallel (%arg3, %arg4) = (%c0, %c0) to (%0, %1) step (%c32, %c64) {
       scf.for %arg5 = %c0 to %2 step %c16 {
         %3 = affine.min #map0(%arg3)[%0]
         %4 = affine.min #map1(%arg4)[%1]
         %5 = affine.min #map2(%arg5)[%2]
         %6 = subview %arg0[%arg3, %arg5] [%3, %5] [1, 1] : memref<?x?xf32> to memref<?x?xf32, #map3>
         %7 = subview %arg1[%arg5, %arg4] [%5, %4] [1, 1] : memref<?x?xf32> to memref<?x?xf32, #map3>
         %8 = subview %arg2[%arg3, %arg4] [%3, %4] [1, 1] : memref<?x?xf32> to memref<?x?xf32, #map3>
         linalg.matmul {__internal_linalg_transform__ = "basic_fusion"}
           ins(%6, %7 : memref<?x?xf32, #map3>, memref<?x?xf32, #map3>)
           outs(%8 : memref<?x?xf32, #map3>)
       }
       scf.yield
     }
     return
   }
 }
 // CHECK-LABEL: func @basic_no_fusion
 //   CHECK-NOT:   scf.parallel
 //       CHECK:   linalg.fill
 //       CHECK:   scf.parallel
 //       CHECK:     scf.for
 //   CHECK-NOT:     linalg.fill
 //       CHECK:     linalg.matmul

 // -----

 module {
   func @basic_conv_fusion(%arg0: memref<?x?x?x?xf32>, %arg1: memref<?x?x?x?xf32>,
                           %arg2: memref<?x?x?x?xf32>) {
     %cst = constant 0.000000e+00 : f32
     linalg.fill(%arg2, %cst) : memref<?x?x?x?xf32>, f32
     linalg.conv(%arg0, %arg1, %arg2) {
       dilations = [1, 1], strides = [1, 1],
       __internal_linalg_transform__ = "basic_fusion"} :
       memref<?x?x?x?xf32>, memref<?x?x?x?xf32>, memref<?x?x?x?xf32>
     return
   }
 }
 //      CHECK: func @basic_conv_fusion
 //      CHECK:   linalg.fill
 // CHECK-SAME:     __internal_linalg_transform__ = "after_basic_fusion_original"
 //      CHECK:  scf.parallel (%{{.+}}, %{{.+}}, %{{.+}})
 // CHECK-SAME:  {
 //      CHECK:    linalg.fill
 // CHECK-SAME:      __internal_linalg_transform__ = "after_basic_fusion_producer"
 //      CHECK:    linalg.conv
 // CHECK-SAME:      __internal_linalg_transform__ = "after_basic_fusion"
 //      CHECK:  }
 //      CHECK:  linalg.conv
 // CHECK-SAME:    __internal_linalg_transform__ = "after_basic_fusion_original"
	// RUN: mlir-opt %s -test-linalg-fusion-transform-patterns -canonicalize -cse -split-input-file \| FileCheck %s

	module {
	func @basic_fusion(%arg0: memref<?x?xf32>, %arg1: memref<?x?xf32>,
	%arg2: memref<?x?xf32>) {
	%cst = constant 0.000000e+00 : f32
	linalg.fill(%arg2, %cst) : memref<?x?xf32>, f32
	linalg.matmul {__internal_linalg_transform__ = "basic_fusion"}
	ins(%arg0, %arg1 : memref<?x?xf32>, memref<?x?xf32>)
	outs(%arg2 : memref<?x?xf32>)
	return
	}
	}

	// CHECK-DAG: #[[MAP0:.+]] = affine_map<(d0)[s0] -> (32, -d0 + s0)>
	// CHECK-DAG: #[[MAP1:.+]] = affine_map<(d0, d1)[s0, s1] -> (d0 * s1 + s0 + d1)>
	// CHECK-DAG: #[[MAP2:.+]] = affine_map<(d0)[s0] -> (64, -d0 + s0)>
	// CHECK-DAG: #[[MAP3:.+]] = affine_map<(d0)[s0] -> (16, -d0 + s0)>
	// CHECK: func @basic_fusion
	// CHECK-SAME: %[[ARG0:[a-zA-Z0-9_]+]]: memref<?x?xf32>
	// CHECK-SAME: %[[ARG1:[a-zA-Z0-9_]+]]: memref<?x?xf32>
	// CHECK-SAME: %[[ARG2:[a-zA-Z0-9_]+]]: memref<?x?xf32>
	// CHECK-DAG: %[[C0:.+]] = constant 0 : index
	// CHECK-DAG: %[[C1:.+]] = constant 1 : index
	// CHECK-DAG: %[[C32:.+]] = constant 32 : index
	// CHECK-DAG: %[[C64:.+]] = constant 64 : index
	// CHECK-DAG: %[[C16:.+]] = constant 16 : index
	// CHECK-DAG: %[[CST:.+]] = constant 0.0{{.*}} : f32
	// CHECK-DAG: linalg.fill(%[[ARG2]], %[[CST]])
	// CHECK-SAME: __internal_linalg_transform__ = "after_basic_fusion_original"
	// CHECK-DAG: %[[M:.+]] = dim %[[ARG0]], %[[C0]]
	// CHECK-DAG: %[[N:.+]] = dim %[[ARG1]], %[[C1]]
	// CHECK: scf.parallel (%[[IV0:.+]], %[[IV1:.+]]) =
	// CHECK-SAME: to (%[[M]], %[[N]])
	// CHECK-SAME: step (%[[C32]], %[[C64]]) {
	// CHECK: %[[TILE_M:.+]] = affine.min #[[MAP0]](%[[IV0]])[%[[M]]]
	// CHECK: %[[K:.+]] = dim %[[ARG0]], %[[C1]]
	// CHECK: %[[SV1:.+]] = subview %[[ARG0]][%[[IV0]], 0]
	// CHECK-SAME: [%[[TILE_M]], %[[K]]]
	// CHECK: %[[K_2:.+]] = dim %[[ARG1]], %[[C0]]
	// CHECK: %[[TILE_N:.+]] = affine.min #[[MAP2]](%[[IV1]])[%[[N]]]
	// CHECK: %[[SV2:.+]] = subview %[[ARG1]][0, %[[IV1]]]
	// CHECK-SAME: %[[K_2]], %[[TILE_N]]
	// CHECK: %[[M_2:.+]] = dim %[[ARG2]], %[[C0]]
	// CHECK: %[[TILE_M_2:.+]] = affine.min #[[MAP0]](%[[IV0]])[%[[M_2]]]
	// CHECK: %[[N_2:.+]] = dim %[[ARG2]], %[[C1]]
	// CHECK: %[[TILE_N_2:.+]] = affine.min #[[MAP2]](%[[IV1]])[%[[N_2]]]
	// CHECK: %[[SV3:.+]] = subview %[[ARG2]][%[[IV0]], %[[IV1]]]
	// CHECK-SAME: [%[[TILE_M_2]], %[[TILE_N_2]]]
	// CHECK: %[[SV3_2:.+]] = subview %[[ARG2]][%[[IV0]], %[[IV1]]]
	// CHECK-SAME: [%[[TILE_M]], %[[TILE_N]]]
	// CHECK: linalg.fill(%[[SV3_2]], %[[CST]])
	// CHECK-SAME: __internal_linalg_transform__ = "after_basic_fusion_producer"
	// CHECK: scf.for %[[IV2:.+]] = %[[C0]] to %[[K]] step %[[C16]] {
	// CHECK: %[[TILE_K:.+]] = affine.min #[[MAP3]](%[[IV2]])[%[[K]]]
	// CHECK: %[[SV4:.+]] = subview %[[SV1]][0, %[[IV2]]]
	// CHECK-SAME: [%[[TILE_M]], %[[TILE_K]]]
	// CHECK: %[[TILE_K_2:.+]] = affine.min #[[MAP3]](%[[IV2]])[%[[K_2]]]
	// CHECK: %[[SV5:.+]] = subview %[[SV2]][%[[IV2]], 0]
	// CHECK-SAME: [%[[TILE_K_2]], %[[TILE_N]]]
	// CHECK: linalg.matmul
	// CHECK-SAME: __internal_linalg_transform__ = "after_basic_fusion"
	// CHECK-SAME: ins(%[[SV4]], %[[SV5]]
	// CHECK-SAME: : memref<?x?xf32, #[[MAP1]]>, memref<?x?xf32, #[[MAP1]]>)
	// CHECK-SAME: outs(%[[SV3]] : memref<?x?xf32, #[[MAP1]]>)
	// CHECK: }
	// CHECK: }
	// CHECK: linalg.matmul
	// CHECK-SAME: __internal_linalg_transform__ = "after_basic_fusion_original"

	// -----

	module {
	func @rhs_fusion(%arg0: memref<?x?xf32>, %arg1: memref<?x?xf32>,
	%arg2: memref<?x?xf32>, %arg3: memref<?x?xf32>) {
	%cst = constant 0.000000e+00 : f32
	linalg.copy(%arg1, %arg2) : memref<?x?xf32>, memref<?x?xf32>
	linalg.fill(%arg3, %cst) : memref<?x?xf32>, f32
	linalg.matmul {__internal_linalg_transform__ = "rhs_fusion"}
	ins(%arg0, %arg2 : memref<?x?xf32>, memref<?x?xf32>)
	outs(%arg3 : memref<?x?xf32>)
	return
	}
	}
	// CHECK-DAG: #[[MAP0:.+]] = affine_map<(d0)[s0] -> (64, -d0 + s0)>
	// CHECK-DAG: #[[MAP1:.+]] = affine_map<(d0, d1)[s0, s1] -> (d0 * s1 + s0 + d1)>
	// CHECK-DAG: #[[MAP2:.+]] = affine_map<(d0)[s0] -> (32, -d0 + s0)>
	// CHECK-DAG: #[[MAP3:.+]] = affine_map<(d0)[s0] -> (16, -d0 + s0)>
	// CHECK: func @rhs_fusion
	// CHECK-SAME: %[[ARG0:[a-zA-Z0-9_]+]]: memref<?x?xf32>
	// CHECK-SAME: %[[ARG1:[a-zA-Z0-9_]+]]: memref<?x?xf32>
	// CHECK-SAME: %[[ARG2:[a-zA-Z0-9_]+]]: memref<?x?xf32>
	// CHECK-SAME: %[[ARG3:[a-zA-Z0-9_]+]]: memref<?x?xf32>
	// CHECK-DAG: %[[C0:.+]] = constant 0 : index
	// CHECK-DAG: %[[C1:.+]] = constant 1 : index
	// CHECK-DAG: %[[C32:.+]] = constant 32 : index
	// CHECK-DAG: %[[C64:.+]] = constant 64 : index
	// CHECK-DAG: %[[C16:.+]] = constant 16 : index
	// CHECK-DAG: %[[CST:.+]] = constant 0.0{{.*}} : f32
	// CHECK-DAG: linalg.copy(%[[ARG1]], %[[ARG2]])
	// CHECK-SAME: __internal_linalg_transform__ = "after_rhs_fusion_original"
	// CHECK-DAG: %[[N:.+]] = dim %[[ARG2]], %[[C1]]
	// CHECK: scf.parallel (%[[IV0:.+]]) =
	// CHECK-SAME: (%[[C0]]) to (%[[N]]) step (%[[C64]]) {
	// CHECK: %[[K:.+]] = dim %[[ARG2]], %[[C0]]
	// CHECK: %[[TILE_N:.+]] = affine.min #[[MAP0]](%[[IV0]])[%[[N]]]
	// CHECK: %[[SV1:.+]] = subview %[[ARG2]][0, %[[IV0]]]
	// CHECK-SAME: [%[[K]], %[[TILE_N]]]
	// CHECK: %[[M:.+]] = dim %[[ARG3]], %[[C0]]
	// CHECK: %[[N_2:.+]] = dim %[[ARG3]], %[[C1]]
	// CHECK: %[[TILE_N_2:.+]] = affine.min #[[MAP0]](%[[IV0]])[%[[N_2]]]
	// CHECK: %[[SV2:.+]] = subview %[[ARG3]][0, %[[IV0]]]
	// CHECK-SAME: [%[[M]], %[[TILE_N_2]]]
	// CHECK: %[[K_2:.+]] = dim %[[ARG1]], %[[C0]]
	// CHECK: %[[SV3:.+]] = subview %[[ARG1]][0, %[[IV0]]]
	// CHECK-SAME: [%[[K_2]], %[[TILE_N]]]
	// CHECK: %[[SV3_2:.+]] = subview %[[ARG2]][0, %[[IV0]]]
	// CHECK-SAME: [%[[K_2]], %[[TILE_N]]]
	// CHECK: linalg.copy(%[[SV3]], %[[SV3_2]])
	// CHECK-SAME: __internal_linalg_transform__ = "after_rhs_fusion_producer"
	// CHECK-NOT: linalg.fill
	// CHECK-DAG: %[[M_2:.+]] = dim %[[ARG0]], %[[C0]]
	// CHECK-DAG: %[[K_2:.+]] = dim %[[ARG0]], %[[C1]]
	// CHECK: scf.parallel (%[[IV1:.+]]) =
	// CHECK-SAME: (%[[C0]]) to (%[[M_2]]) step (%[[C32]]) {
	// CHECK-NEXT: scf.for %[[IV2:.+]] = %[[C0]] to %[[K_2]] step %[[C16]] {
	// CHECK: %[[TILE_M:.+]] = affine.min #[[MAP2]](%[[IV1]])[%[[M_2]]]
	// CHECK: %[[TILE_K:.+]] = affine.min #[[MAP3]](%[[IV2]])[%[[K_2]]]
	// CHECK: %[[SV4:.+]] = subview %[[ARG0]][%[[IV1]], %[[IV2]]]
	// CHECK-SAME: [%[[TILE_M]], %[[TILE_K]]]
	// CHECK: %[[TILE_K_2:.+]] = affine.min #[[MAP3]](%[[IV2]])[%[[K]]]
	// CHECK: %[[SV5:.+]] = subview %[[SV1]][%[[IV2]], 0]
	// CHECK-SAME: [%[[TILE_K_2]], %[[TILE_N]]]
	// CHECK: %[[TILE_M_2:.+]] = affine.min #[[MAP2]](%[[IV1]])[%[[M]]]
	// CHECK: %[[SV6:.+]] = subview %[[SV2]][%[[IV1]], 0]
	// CHECK-SAME: [%[[TILE_M_2]], %[[TILE_N_2]]]
	// CHECK: linalg.matmul
	// CHECK-SAME: __internal_linalg_transform__ = "after_rhs_fusion"
	// CHECK-SAME: ins(%[[SV4]], %[[SV5]]
	// CHECK-SAME: : memref<?x?xf32, #[[MAP1]]>, memref<?x?xf32, #[[MAP1]]>)
	// CHECK-SAME: outs(%[[SV6]] : memref<?x?xf32, #[[MAP1]]>)
	// CHECK: }
	// CHECK: }
	// CHECK: }
	// CHECK: linalg.matmul
	// CHECK-SAME: __internal_linalg_transform__ = "after_rhs_fusion_original"


	// -----

	module {
	func @two_operand_fusion(%arg0: memref<?x?xf32>, %arg1: memref<?x?xf32>,
	%arg2: memref<?x?xf32>, %arg3: memref<?x?xf32>) {
	%cst = constant 0.000000e+00 : f32
	linalg.copy(%arg0, %arg1) : memref<?x?xf32>, memref<?x?xf32>
	linalg.fill(%arg3, %cst) : memref<?x?xf32>, f32
	linalg.matmul {__internal_linalg_transform__ = "two_operand_fusion"}
	ins(%arg1, %arg2 : memref<?x?xf32>, memref<?x?xf32>)
	outs(%arg3 : memref<?x?xf32>)
	return
	}
	}
	// CHECK-DAG: #[[MAP0:.+]] = affine_map<(d0)[s0] -> (32, -d0 + s0)>
	// CHECK-DAG: #[[MAP1:.+]] = affine_map<(d0, d1)[s0, s1] -> (d0 * s1 + s0 + d1)>
	// CHECK-DAG: #[[MAP2:.+]] = affine_map<(d0)[s0] -> (16, -d0 + s0)>
	// CHECK-DAG: #[[MAP3:.+]] = affine_map<(d0)[s0] -> (64, -d0 + s0)>
	// CHECK: func @two_operand_fusion
	// CHECK-SAME: %[[ARG0:[a-zA-Z0-9_]+]]: memref<?x?xf32>
	// CHECK-SAME: %[[ARG1:[a-zA-Z0-9_]+]]: memref<?x?xf32>
	// CHECK-SAME: %[[ARG2:[a-zA-Z0-9_]+]]: memref<?x?xf32>
	// CHECK-SAME: %[[ARG3:[a-zA-Z0-9_]+]]: memref<?x?xf32>
	// CHECK-DAG: %[[C0:.+]] = constant 0 : index
	// CHECK-DAG: %[[C1:.+]] = constant 1 : index
	// CHECK-DAG: %[[C32:.+]] = constant 32 : index
	// CHECK-DAG: %[[C64:.+]] = constant 64 : index
	// CHECK-DAG: %[[C16:.+]] = constant 16 : index
	// CHECK-DAG: %[[CST:.+]] = constant 0.0{{.*}} : f32
	// CHECK: linalg.copy(%[[ARG0]], %[[ARG1]])
	// CHECK-SAME: __internal_linalg_transform__ = "after_two_operand_fusion_original"
	// CHECK: linalg.fill(%[[ARG3]], %[[CST]])
	// CHECK-SAME: __internal_linalg_transform__ = "after_two_operand_fusion_original"
	// CHECK-DAG: %[[M:.+]] = dim %[[ARG1]], %[[C0]]
	// CHECK: scf.parallel (%[[IV0:.+]]) =
	// CHECK-SAME: (%[[C0]]) to (%[[M]]) step (%[[C32]]) {
	// CHECK: %[[TILE_M:.+]] = affine.min #[[MAP0]](%[[IV0]])[%[[M]]]
	// CHECK: %[[K:.+]] = dim %[[ARG1]], %[[C1]]
	// CHECK: %[[SV1:.+]] = subview %[[ARG1]][%[[IV0]], 0]
	// CHECK-SAME: [%[[TILE_M]], %[[K]]]
	// CHECK: %[[M_2:.+]] = dim %[[ARG3]], %[[C0]]
	// CHECK: %[[TILE_M_2:.+]] = affine.min #[[MAP0]](%[[IV0]])[%[[M_2]]]
	// CHECK: %[[N:.+]] = dim %[[ARG3]], %[[C1]]
	// CHECK: %[[SV2:.+]] = subview %[[ARG3]][%[[IV0]], 0]
	// CHECK-SAME: [%[[TILE_M_2]], %[[N]]]
	// CHECK: %[[SV2_2:.+]] = subview %[[ARG3]][%[[IV0]], 0]
	// CHECK-SAME: [%[[TILE_M]], %[[N]]]
	// CHECK: %[[K_2:.+]] = dim %[[ARG0]], %[[C1]]
	// CHECK: %[[SV3:.+]] = subview %[[ARG0]][%[[IV0]], 0]
	// CHECK-SAME: [%[[TILE_M]], %[[K_2]]]
	// CHECK: %[[SV3_2:.+]] = subview %[[ARG1]][%[[IV0]], 0]
	// CHECK-SAME: [%[[TILE_M]], %[[K_2]]]
	// CHECK: linalg.copy(%[[SV3]], %[[SV3_2]])
	// CHECK-SAME: __internal_linalg_transform__ = "after_two_operand_fusion_producer"
	// CHECK: linalg.fill(%[[SV2_2]], %[[CST]])
	// CHECK-SAME: __internal_linalg_transform__ = "after_two_operand_fusion_producer"
	// CHECK-DAG: %[[N_2:.+]] = dim %[[ARG2]], %[[C1]]
	// CHECK: scf.parallel (%[[IV1:.+]]) =
	// CHECK-SAME: (%[[C0]]) to (%[[N_2]]) step (%[[C64]]) {
	// CHECK-NEXT: scf.for %[[IV2:.+]] = %[[C0]] to %[[K]] step %[[C16]] {
	// CHECK: %[[TILE_K:.+]] = affine.min #[[MAP2]](%[[IV2]])[%[[K]]]
	// CHECK: %[[SV4:.+]] = subview %[[SV1]][0, %[[IV2]]]
	// CHECK-SAME: [%[[TILE_M]], %[[TILE_K]]]
	// CHECK: %[[K_2:.+]] = dim %[[ARG2]], %[[C0]]
	// CHECK: %[[TILE_K_2:.+]] = affine.min #[[MAP2]](%[[IV2]])[%[[K_2]]]
	// CHECK: %[[TILE_N:.+]] = affine.min #[[MAP3]](%[[IV1]])[%[[N_2]]]
	// CHECK: %[[SV5:.+]] = subview %[[ARG2]][%[[IV2]], %[[IV1]]]
	// CHECK-SAME: [%[[TILE_K_2]], %[[TILE_N]]]
	// CHECK: %[[TILE_N_2:.+]] = affine.min #[[MAP3]](%[[IV1]])[%[[N]]]
	// CHECK: %[[SV6:.+]] = subview %[[SV2]][0, %[[IV1]]]
	// CHECK-SAME: [%[[TILE_M_2]], %[[TILE_N_2]]]
	// CHECK: linalg.matmul
	// CHECK-SAME: __internal_linalg_transform__ = "after_two_operand_fusion"
	// CHECK-SAME: ins(%[[SV4]], %[[SV5]]
	// CHECK-SAME: : memref<?x?xf32, #[[MAP1]]>, memref<?x?xf32, #[[MAP1]]>)
	// CHECK-SAME: outs(%[[SV6]] : memref<?x?xf32, #[[MAP1]]>)
	// CHECK: }
	// CHECK: }
	// CHECK: }
	// CHECK: linalg.matmul
	// CHECK-SAME: __internal_linalg_transform__ = "after_two_operand_fusion_original"

	// -----

	module {
	func @matmul_fusion(%arg0: memref<?x?xf32>, %arg1: memref<?x?xf32>,
	%arg2: memref<?x?xf32>, %arg3: memref<?x?xf32>,
	%arg4: memref<?x?xf32>) {
	linalg.matmul ins(%arg0, %arg1 : memref<?x?xf32>, memref<?x?xf32>)
	outs(%arg2 : memref<?x?xf32>)
	linalg.matmul {__internal_linalg_transform__ = "lhs_fusion"}
	ins(%arg2, %arg3 : memref<?x?xf32>, memref<?x?xf32>)
	outs(%arg4 : memref<?x?xf32>)
	return
	}
	}
	// CHECK-DAG: #[[MAP0:.+]] = affine_map<(d0)[s0] -> (32, -d0 + s0)>
	// CHECK-DAG: #[[MAP1:.+]] = affine_map<(d0, d1)[s0, s1] -> (d0 * s1 + s0 + d1)>
	// CHECK-DAG: #[[MAP2:.+]] = affine_map<(d0)[s0] -> (16, -d0 + s0)>
	// CHECK-DAG: #[[MAP3:.+]] = affine_map<(d0)[s0] -> (64, -d0 + s0)>
	// CHECK: func @matmul_fusion
	// CHECK-SAME: %[[ARG0:[a-zA-Z0-9_]+]]: memref<?x?xf32>
	// CHECK-SAME: %[[ARG1:[a-zA-Z0-9_]+]]: memref<?x?xf32>
	// CHECK-SAME: %[[ARG2:[a-zA-Z0-9_]+]]: memref<?x?xf32>
	// CHECK-SAME: %[[ARG3:[a-zA-Z0-9_]+]]: memref<?x?xf32>
	// CHECK-SAME: %[[ARG4:[a-zA-Z0-9_]+]]: memref<?x?xf32>
	// CHECK-DAG: %[[C0:.+]] = constant 0 : index
	// CHECK-DAG: %[[C1:.+]] = constant 1 : index
	// CHECK-DAG: %[[C32:.+]] = constant 32 : index
	// CHECK-DAG: %[[C64:.+]] = constant 64 : index
	// CHECK-DAG: %[[C16:.+]] = constant 16 : index
	// CHECK: linalg.matmul
	// CHECK-SAME: __internal_linalg_transform__ = "after_lhs_fusion_original"
	// CHECK-DAG: %[[M:.+]] = dim %[[ARG2]], %[[C0]]
	// CHECK: scf.parallel (%[[IV0:.+]]) =
	// CHECK-SAME: (%[[C0]]) to (%[[M]]) step (%[[C32]]) {
	// CHECK: %[[TILE_M:.+]] = affine.min #[[MAP0]](%[[IV0]])[%[[M]]]
	// CHECK: %[[K2:.+]] = dim %[[ARG2]], %[[C1]]
	// CHECK: %[[SV1:.+]] = subview %[[ARG2]][%[[IV0]], 0]
	// CHECK-SAME: [%[[TILE_M]], %[[K2]]]
	// CHECK: %[[M_2:.+]] = dim %[[ARG4]], %[[C0]]
	// CHECK: %[[TILE_M_2:.+]] = affine.min #[[MAP0]](%[[IV0]])[%[[M_2]]]
	// CHECK: %[[N:.+]] = dim %[[ARG4]], %[[C1]]
	// CHECK: %[[SV2:.+]] = subview %[[ARG4]][%[[IV0]], 0]
	// CHECK-SAME: [%[[TILE_M_2]], %[[N]]]
	// CHECK: %[[K2_2:.+]] = dim %[[ARG1]], %[[C1]]
	// CHECK: %[[K1:.+]] = dim %[[ARG0]], %[[C1]]
	// CHECK: %[[SV3:.+]] = subview %[[ARG0]][%[[IV0]], 0]
	// CHECK-SAME: [%[[TILE_M]], %[[K1]]]
	// CHECK: %[[SV4:.+]] = subview %[[ARG1]][0, 0] [%[[K1]], %[[K2_2]]]
	// CHECK: %[[SV1_2:.+]] = subview %[[ARG2]][%[[IV0]], 0]
	// CHECK-SAME: [%[[TILE_M]], %[[K2_2]]]
	// CHECK: linalg.matmul
	// CHECK-SAME: __internal_linalg_transform__ = "after_lhs_fusion_producer"
	// CHECK-SAME: ins(%[[SV3]], %[[SV4]]
	// CHECK-SAME: : memref<?x?xf32, #[[MAP1]]>, memref<?x?xf32, #[[MAP1]]>)
	// CHECK-SAME: outs(%[[SV1_2]] : memref<?x?xf32, #[[MAP1]]>)
	// CHECK-DAG: %[[N_2:.+]] = dim %[[ARG3]], %[[C1]]
	// CHECK: scf.parallel (%[[IV1:.+]]) =
	// CHECK-SAME: (%[[C0]]) to (%[[N_2]]) step (%[[C64]]) {
	// CHECK-NEXT: scf.for %[[IV2:.+]] = %[[C0]] to %[[K]] step %[[C16]] {
	// CHECK: %[[TILE_K:.+]] = affine.min #[[MAP2]](%[[IV2]])[%[[K]]]
	// CHECK: %[[SV6:.+]] = subview %[[SV1]][0, %[[IV2]]]
	// CHECK-SAME: [%[[TILE_M]], %[[TILE_K]]]
	// CHECK: %[[K_2:.+]] = dim %[[ARG3]], %[[C0]]
	// CHECK: %[[TILE_K_2:.+]] = affine.min #[[MAP2]](%[[IV2]])[%[[K_2]]]
	// CHECK: %[[TILE_N:.+]] = affine.min #[[MAP3]](%[[IV1]])[%[[N_2]]]
	// CHECK: %[[SV7:.+]] = subview %[[ARG3]][%[[IV2]], %[[IV1]]]
	// CHECK-SAME: [%[[TILE_K_2]], %[[TILE_N]]]
	// CHECK: %[[TILE_N_2:.+]] = affine.min #[[MAP3]](%[[IV1]])[%[[N]]]
	// CHECK: %[[SV8:.+]] = subview %[[SV2]][0, %[[IV1]]]
	// CHECK-SAME: [%[[TILE_M_2]], %[[TILE_N_2]]]
	// CHECK: linalg.matmul
	// CHECK-SAME: __internal_linalg_transform__ = "after_lhs_fusion"
	// CHECK-SAME: ins(%[[SV6]], %[[SV7]]
	// CHECK-SAME: : memref<?x?xf32, #[[MAP1]]>, memref<?x?xf32, #[[MAP1]]>)
	// CHECK-SAME: outs(%[[SV8]] : memref<?x?xf32, #[[MAP1]]>)
	// CHECK: }
	// CHECK: }
	// CHECK: }
	// CHECK: linalg.matmul
	// CHECK-SAME: __internal_linalg_transform__ = "after_lhs_fusion_original"

	// -----

	module {
	func @matmul_plus_matmul(%arg0: memref<?x?xf32>, %arg1: memref<?x?xf32>,
	%arg2: memref<?x?xf32>) {
	%c0 = constant 0 : index
	%c1 = constant 1 : index
	%0 = dim %arg2, %c0 : memref<?x?xf32>
	%1 = dim %arg2, %c1 : memref<?x?xf32>
	%2 = alloc(%0, %1) : memref<?x?xf32>
	linalg.matmul ins(%arg0, %arg1 : memref<?x?xf32>, memref<?x?xf32>)
	outs(%2 : memref<?x?xf32>)
	linalg.generic
	{indexing_maps = [affine_map<(d0, d1) -> (d0, d1)>,
	affine_map<(d0, d1) -> (d0, d1)>,
	affine_map<(d0, d1) -> (d0, d1)>],
	iterator_types = ["parallel", "parallel"],
	__internal_linalg_transform__ = "transpose_fusion"}
	ins(%2, %2 : memref<?x?xf32>, memref<?x?xf32>)
	outs(%arg2 : memref<?x?xf32>) {
	^bb0(%arg3 : f32, %arg4 : f32, %arg5 : f32) :
	%3 = addf %arg3, %arg4 : f32
	linalg.yield %3 : f32
	}
	return
	}
	}
	// CHECK: func @matmul_plus_matmul
	// CHECK-SAME: %[[ARG0:[a-zA-Z0-9_]+]]: memref<?x?xf32>
	// CHECK-SAME: %[[ARG1:[a-zA-Z0-9_]+]]: memref<?x?xf32>
	// CHECK-SAME: %[[ARG2:[a-zA-Z0-9_]+]]: memref<?x?xf32>
	// CHECK: %[[T2:.+]] = alloc(%{{.}}, %{{.}}) : memref<?x?xf32>
	// CHECK: linalg.matmul
	// CHECK-SAME: after_transpose_fusion_original
	// CHECK: scf.parallel (%[[ARG3:[a-zA-Z0-9_]+]], %[[ARG4:.[a-zA-Z0-9_]+]])
	// CHECK: %[[T5:.+]] = subview %[[T2]][%[[ARG3]], %[[ARG4]]]
	// CHECK: %[[T6:.+]] = subview %[[ARG2]][%[[ARG3]], %[[ARG4]]]
	// CHECK: %[[T8:.+]] = subview %[[ARG0]][%[[ARG3]], 0]
	// CHECK: %[[T9:.+]] = subview %[[ARG1]][0, %[[ARG4]]]
	// CHECK: linalg.matmul
	// CHECK-SAME: after_transpose_fusion_producer
	// CHECK-SAME: ins(%[[T8]], %[[T9]]
	// CHECK-SAME: outs(%[[T5]]
	// CHECK-NOT: linalg.matmul
	// CHECK: linalg.generic
	// CHECK-SAME: ins(%[[T5]], %[[T5]]
	// CHECK-SAME: outs(%[[T6]]
	// CHECK-SAME: after_transpose_fusion

	// -----

	module {
	func @matmul_plus_transpose_matmul(%arg0: memref<?x?xf32>,
	%arg1: memref<?x?xf32>,
	%arg2: memref<?x?xf32>) {
	%c0 = constant 0 : index
	%c1 = constant 1 : index
	%0 = dim %arg2, %c0 : memref<?x?xf32>
	%1 = dim %arg2, %c1 : memref<?x?xf32>
	%2 = alloc(%0, %1) : memref<?x?xf32>
	linalg.matmul ins(%arg0, %arg1 : memref<?x?xf32>, memref<?x?xf32>)
	outs(%2 : memref<?x?xf32>)
	linalg.generic
	{indexing_maps = [affine_map<(d0, d1) -> (d0, d1)>,
	affine_map<(d0, d1) -> (d1, d0)>,
	affine_map<(d0, d1) -> (d0, d1)>],
	iterator_types = ["parallel", "parallel"],
	__internal_linalg_transform__ = "transpose_fusion"}
	ins(%2, %2 : memref<?x?xf32>, memref<?x?xf32>)
	outs(%arg2 : memref<?x?xf32>) {
	^bb0(%arg3 : f32, %arg4 : f32, %arg5 : f32) :
	%3 = addf %arg3, %arg4 : f32
	linalg.yield %3 : f32
	}
	return
	}
	}
	// CHECK-LABEL: func @matmul_plus_transpose_matmul
	// CHECK-NOT: scf.parallel
	// CHECK-NOT: scf.for
	// CHECK: linalg.matmul
	// CHECK-NOT: scf.parallel
	// CHECK-NOT: scf.for
	// CHECK: linalg.generic
	// CHECK-NOT: scf.parallel
	// CHECK-NOT: scf.for

	// -----

	#map0 = affine_map<(d0)[s0] -> (32, -d0 + s0)>
	#map1 = affine_map<(d0)[s0] -> (64, -d0 + s0)>
	#map2 = affine_map<(d0)[s0] -> (16, -d0 + s0)>
	#map3 = affine_map<(d0, d1)[s0, s1] -> (d0 * s1 + s0 + d1)>
	module {
	func @basic_no_fusion(%arg0: memref<?x?xf32>, %arg1: memref<?x?xf32>,
	%arg2: memref<?x?xf32>) {
	%c0 = constant 0 : index
	%c1 = constant 1 : index
	%c2 = constant 2 : index
	%c32 = constant 32 : index
	%c64 = constant 64 : index
	%c16 = constant 16 : index
	%cst = constant 0.000000e+00 : f32
	linalg.fill(%arg2, %cst) : memref<?x?xf32>, f32
	%0 = dim %arg0, %c0 : memref<?x?xf32>
	%1 = dim %arg1, %c1 : memref<?x?xf32>
	%2 = dim %arg0, %c1 : memref<?x?xf32>
	scf.parallel (%arg3, %arg4) = (%c0, %c0) to (%0, %1) step (%c32, %c64) {
	scf.for %arg5 = %c0 to %2 step %c16 {
	%3 = affine.min #map0(%arg3)[%0]
	%4 = affine.min #map1(%arg4)[%1]
	%5 = affine.min #map2(%arg5)[%2]
	%6 = subview %arg0[%arg3, %arg5] [%3, %5] [1, 1] : memref<?x?xf32> to memref<?x?xf32, #map3>
	%7 = subview %arg1[%arg5, %arg4] [%5, %4] [1, 1] : memref<?x?xf32> to memref<?x?xf32, #map3>
	%8 = subview %arg2[%arg3, %arg4] [%3, %4] [1, 1] : memref<?x?xf32> to memref<?x?xf32, #map3>
	linalg.matmul {__internal_linalg_transform__ = "basic_fusion"}
	ins(%6, %7 : memref<?x?xf32, #map3>, memref<?x?xf32, #map3>)
	outs(%8 : memref<?x?xf32, #map3>)
	}
	scf.yield
	}
	return
	}
	}
	// CHECK-LABEL: func @basic_no_fusion
	// CHECK-NOT: scf.parallel
	// CHECK: linalg.fill
	// CHECK: scf.parallel
	// CHECK: scf.for
	// CHECK-NOT: linalg.fill
	// CHECK: linalg.matmul

	// -----

	module {
	func @basic_conv_fusion(%arg0: memref<?x?x?x?xf32>, %arg1: memref<?x?x?x?xf32>,
	%arg2: memref<?x?x?x?xf32>) {
	%cst = constant 0.000000e+00 : f32
	linalg.fill(%arg2, %cst) : memref<?x?x?x?xf32>, f32
	linalg.conv(%arg0, %arg1, %arg2) {
	dilations = [1, 1], strides = [1, 1],
	__internal_linalg_transform__ = "basic_fusion"} :
	memref<?x?x?x?xf32>, memref<?x?x?x?xf32>, memref<?x?x?x?xf32>
	return
	}
	}
	// CHECK: func @basic_conv_fusion
	// CHECK: linalg.fill
	// CHECK-SAME: __internal_linalg_transform__ = "after_basic_fusion_original"
	// CHECK: scf.parallel (%{{.+}}, %{{.+}}, %{{.+}})
	// CHECK-SAME: {
	// CHECK: linalg.fill
	// CHECK-SAME: __internal_linalg_transform__ = "after_basic_fusion_producer"
	// CHECK: linalg.conv
	// CHECK-SAME: __internal_linalg_transform__ = "after_basic_fusion"
	// CHECK: }
	// CHECK: linalg.conv
	// CHECK-SAME: __internal_linalg_transform__ = "after_basic_fusion_original"