mlir/test/Transforms/pipeline-data-transfer.mlir - llvm-project - Git at Google

 // RUN: mlir-opt -allow-unregistered-dialect %s -split-input-file -affine-pipeline-data-transfer | FileCheck %s

 // -----

 // CHECK-DAG: [[$MOD_2:#map[0-9]+]] = affine_map<(d0) -> (d0 mod 2)>
 // CHECK-DAG: [[$MAP_MINUS_1:#map[0-9]+]] = affine_map<(d0) -> (d0 - 1)>

 // CHECK-LABEL: func @loop_nest_dma() {
 func @loop_nest_dma() {

   %A = memref.alloc() : memref<256 x f32, affine_map<(d0) -> (d0)>, 0>
   %Ah = memref.alloc() : memref<32 x f32, affine_map<(d0) -> (d0)>, 1>

   %tag = memref.alloc() : memref<1 x f32>

   %zero = arith.constant 0 : index
   %num_elts = arith.constant 32 : index

   affine.for %i = 0 to 8 {
     affine.dma_start %A[%i], %Ah[%i], %tag[%zero], %num_elts : memref<256 x f32>, memref<32 x f32, 1>, memref<1 x f32>
     affine.dma_wait %tag[%zero], %num_elts : memref<1 x f32>
     %v = affine.load %Ah[%i] : memref<32 x f32, affine_map<(d0) -> (d0)>, 1>
     %r = "compute"(%v) : (f32) -> (f32)
     affine.store %r, %Ah[%i] : memref<32 x f32, affine_map<(d0) -> (d0)>, 1>
     affine.for %j = 0 to 32 {
       "do_more_compute"(%i, %j) : (index, index) -> ()
     }
   }
   memref.dealloc %tag : memref<1 x f32>
   memref.dealloc %Ah : memref<32 x f32, affine_map<(d0) -> (d0)>, 1>
   return
 }
 // CHECK:       %{{.*}} = memref.alloc() : memref<256xf32>
 // CHECK:       %{{.*}} = memref.alloc() : memref<2x32xf32, 1>
 // CHECK-NEXT:  %{{.*}} = memref.alloc() : memref<2x1xf32>
 // CHECK-NEXT:  affine.dma_start %{{.*}}[%{{.*}}], %{{.*}}[%{{.*}} mod 2, %{{.*}}], %{{.*}}[%{{.*}} mod 2, 0], %{{.*}} : memref<256xf32>, memref<2x32xf32, 1>, memref<2x1xf32>
 // CHECK-NEXT:  affine.for %{{.*}} = 1 to 8 {
 // CHECK-NEXT:    affine.dma_start %{{.*}}[%{{.*}}], %{{.*}}[%{{.*}} mod 2, %{{.*}}], %{{.*}}[%{{.*}} mod 2, 0], %{{.*}} : memref<256xf32>, memref<2x32xf32, 1>, memref<2x1xf32>
 // CHECK-NEXT:    affine.apply [[$MAP_MINUS_1]](%{{.*}})
 // CHECK-NEXT:    affine.apply [[$MOD_2]](%{{.*}})
 // CHECK-NEXT:    affine.apply [[$MOD_2]](%{{.*}})
 // CHECK-NEXT:    affine.dma_wait %{{.*}}[%{{.*}} mod 2, 0], %{{.*}} : memref<2x1xf32>
 // CHECK-NEXT:    affine.load %{{.*}}[%{{.*}} mod 2, %{{.*}}] : memref<2x32xf32, 1>
 // CHECK-NEXT:    "compute"(%{{.*}}) : (f32) -> f32
 // CHECK-NEXT:    affine.store %{{.*}}, %{{.*}}[%{{.*}} mod 2, %{{.*}}] : memref<2x32xf32, 1>
 // CHECK-NEXT:    affine.for %{{.*}} = 0 to 32 {
 // CHECK-NEXT:      "do_more_compute"(%{{.*}}, %{{.*}}) : (index, index) -> ()
 // CHECK-NEXT:    }
 // CHECK-NEXT:  }
 // CHECK-NEXT:  affine.apply [[$MAP_MINUS_1]](%{{.*}})
 // CHECK-NEXT:  affine.apply [[$MOD_2]](%{{.*}})
 // CHECK-NEXT:  affine.apply [[$MOD_2]](%{{.*}})
 // CHECK-NEXT:  affine.dma_wait %{{.*}}[%{{.*}} mod 2, 0], %{{.*}} : memref<2x1xf32>
 // CHECK-NEXT:  affine.load %{{.*}}[%{{.*}} mod 2, %{{.*}}] : memref<2x32xf32, 1>
 // CHECK-NEXT:  "compute"(%{{.*}}) : (f32) -> f32
 // CHECK-NEXT:  affine.store %{{.*}}, %{{.*}}[%{{.*}} mod 2, %{{.*}}] : memref<2x32xf32, 1>
 // CHECK-NEXT:  affine.for %{{.*}} = 0 to 32 {
 // CHECK-NEXT:    "do_more_compute"(%{{.*}}, %{{.*}}) : (index, index) -> ()
 // CHECK-NEXT:  }
 // CHECK-NEXT:  memref.dealloc %{{.*}} : memref<2x1xf32>
 // CHECK-NEXT:  memref.dealloc %{{.*}} : memref<2x32xf32, 1>
 // CHECK-NEXT:  return
 // CHECK-NEXT:}

 // -----

 // CHECK-DAG: [[$FLOOR_MOD_2:#map[0-9]+]] = affine_map<(d0) -> ((d0 floordiv 4) mod 2)>
 // CHECK-DAG: [[$REMAP_SHIFT_MINUS_4:#map[0-9]+]] = affine_map<(d0) -> (d0 - 4)>

 // CHECK-LABEL: @loop_step
 func @loop_step(%arg0: memref<512xf32>,
                   %arg1: memref<512xf32>) {
   %c0 = arith.constant 0 : index
   %c4 = arith.constant 4 : index
   affine.for %i0 = 0 to 512 step 4 {
     %1 = memref.alloc() : memref<4xf32, 1>
     %2 = memref.alloc() : memref<1xi32>
     affine.dma_start %arg0[%i0], %1[%c0], %2[%c0], %c4,
               : memref<512xf32>, memref<4xf32, 1>, memref<1xi32>
     affine.dma_wait %2[%c0], %c4 : memref<1xi32>
     "compute"(%i0) : (index) -> ()
     memref.dealloc %2 : memref<1xi32>
     memref.dealloc %1 : memref<4xf32, 1>
   }
   return
 }
 // CHECK:        [[BUF:%[0-9]+]] = memref.alloc() : memref<2x4xf32, 1>
 // CHECK:        [[TAG:%[0-9]+]] = memref.alloc() : memref<2x1xi32>
 // CHECK-NEXT:   affine.dma_start %{{.*}}[%{{.*}}], %{{.*}}[(%{{.*}} floordiv 4) mod 2, 0], [[TAG]][(%{{.*}} floordiv 4) mod 2, 0], %{{.*}} : memref<512xf32>, memref<2x4xf32, 1>, memref<2x1xi32>
 // CHECK-NEXT:   affine.for %{{.*}} = 4 to 512 step 4 {
 // CHECK-NEXT:     affine.dma_start %{{.*}}[%{{.*}}], %{{.*}}[(%{{.*}} floordiv 4) mod 2, 0], [[TAG]][(%{{.*}} floordiv 4) mod 2, 0], %{{.*}} : memref<512xf32>, memref<2x4xf32, 1>, memref<2x1xi32>
 // CHECK-NEXT:     affine.apply [[$REMAP_SHIFT_MINUS_4]](%{{.*}})
 // CHECK-NEXT:     affine.apply [[$FLOOR_MOD_2]](%{{.*}})
 // CHECK:          affine.dma_wait [[TAG]][(%{{.*}} floordiv 4) mod 2, 0], %{{.*}} : memref<2x1xi32>
 // CHECK-NEXT:     "compute"(%{{.*}}) : (index) -> ()
 // CHECK-NEXT:   }
 // CHECK-NEXT:   [[SHIFTED:%[0-9]+]] = affine.apply [[$REMAP_SHIFT_MINUS_4]](%{{.*}})
 // CHECK-NEXT:   %{{.*}} = affine.apply [[$FLOOR_MOD_2]]([[SHIFTED]])
 // CHECK:        affine.dma_wait [[TAG]][(%{{.*}} floordiv 4) mod 2, 0], %{{.*}} : memref<2x1xi32>
 // CHECK-NEXT:   "compute"(%{{.*}}) : (index) -> ()
 // CHECK-NEXT:   memref.dealloc [[TAG]] : memref<2x1xi32>
 // CHECK-NEXT:   memref.dealloc [[BUF]] : memref<2x4xf32, 1>
 // CHECK-NEXT:   return
 // CHECK-NEXT: }

 // -----

 #map1 = affine_map<(d0, d1) -> ((d0 * 2048 + d1 * 256) floordiv 32)>
 #map2 = affine_map<(d0) -> ((d0 * 2048) floordiv 32)>
 // CHECK-LABEL: func @loop_dma_nested(%{{.*}}: memref<512x32xvector<8xf32>
 func @loop_dma_nested(%arg0: memref<512x32xvector<8xf32>>, %arg1: memref<512x32xvector<8xf32>>, %arg2: memref<512x32xvector<8xf32>>) {
   %num_elts = arith.constant 256 : index
   %c0 = arith.constant 0 : index
   %0 = memref.alloc() : memref<64x4xvector<8xf32>, 2>
   %1 = memref.alloc() : memref<64x4xvector<8xf32>, 2>
   %2 = memref.alloc() : memref<64x4xvector<8xf32>, 2>
   %3 = memref.alloc() : memref<2xi32>
   %4 = memref.alloc() : memref<2xi32>
   %5 = memref.alloc() : memref<2xi32>
   // Prologue for DMA overlap on arg2.
   // CHECK-DAG: [[BUF_ARG2:%[0-9]+]] = memref.alloc() : memref<2x64x4xvector<8xf32>, 2>
   // CHECK-DAG: [[TAG_ARG2:%[0-9]+]] = memref.alloc() : memref<2x2xi32>
   // CHECK: affine.dma_start %{{.*}}[
   // CHECK: affine.for %{{.*}} = 1 to 8 {
   affine.for %i0 = 0 to 8 {
     %6 = affine.apply #map2(%i0)
     affine.dma_start %arg2[%6, %c0], %2[%c0, %c0], %5[%c0], %num_elts : memref<512x32xvector<8xf32>>, memref<64x4xvector<8xf32>, 2>, memref<2xi32>
     affine.dma_wait %5[%c0], %num_elts : memref<2xi32>
     // Steady state for DMA overlap on arg2
     // CHECK: affine.dma_start %{{.*}}[
     // CHECK: affine.dma_wait [[TAG_ARG2]]
     // Prologue for DMA overlap on arg0, arg1 nested within i0
     // CHECK: [[BUF_ARG0:%[0-9]+]] = memref.alloc() : memref<2x64x4xvector<8xf32>, 2>
     // CHECK: [[BUF_ARG1:%[0-9]+]] = memref.alloc() : memref<2x64x4xvector<8xf32>, 2>
     // CHECK: [[TAG_ARG0:%[0-9]+]] = memref.alloc() : memref<2x2xi32>
     // CHECK: [[TAG_ARG1:%[0-9]+]] = memref.alloc() : memref<2x2xi32>
     // CHECK: affine.dma_start %{{.*}}[
     // CHECK: affine.dma_start %{{.*}}[
     // CHECK-NEXT: affine.for %{{.*}} = 1 to 8 {
     affine.for %i1 = 0 to 8 {
       %7 = affine.apply #map1(%i0, %i1)
       %8 = affine.apply #map2(%i1)
       affine.dma_start %arg0[%7, %c0], %0[%c0, %c0], %3[%c0], %num_elts : memref<512x32xvector<8xf32>>, memref<64x4xvector<8xf32>, 2>, memref<2xi32>
       affine.dma_start %arg1[%8, %c0], %1[%c0, %c0], %4[%c0], %num_elts : memref<512x32xvector<8xf32>>, memref<64x4xvector<8xf32>, 2>, memref<2xi32>
       affine.dma_wait %3[%c0], %num_elts : memref<2xi32>
       affine.dma_wait %4[%c0], %num_elts : memref<2xi32>
       // Steady state for DMA overlap on arg0, arg1
       // CHECK: affine.dma_start %{{.*}}[
       // CHECK: affine.dma_start %{{.*}}[
       // CHECK: affine.dma_wait [[TAG_ARG0]]
       // CHECK: affine.dma_wait [[TAG_ARG1]]
       // CHECK-NEXT: affine.for %{{.*}} = 0 to 4 {
       affine.for %i2 = 0 to 4 {
         "foo"() : () -> ()
       }
     }
     // epilogue for arg0, arg1
     // CHECK: affine.dma_wait [[TAG_ARG0]]
     // CHECK: affine.dma_wait [[TAG_ARG1]]
     // CHECK-DAG:    memref.dealloc [[TAG_ARG1]] : memref<2x2xi32>
     // CHECK-DAG:    memref.dealloc [[TAG_ARG0]] : memref<2x2xi32>
     // CHECK-DAG:    memref.dealloc [[BUF_ARG1]] : memref<2x64x4xvector<8xf32>, 2>
     // CHECK-DAG:    memref.dealloc [[BUF_ARG0]] : memref<2x64x4xvector<8xf32>, 2>
   // epilogue for DMA overlap on %arg2
   // CHECK:  affine.dma_wait [[TAG_ARG2]]
   // Within the epilogue for arg2's DMA, we have the DMAs on %arg1, %arg2 nested.
   // CHECK: [[BUF_ARG0_NESTED:%[0-9]+]] = memref.alloc() : memref<2x64x4xvector<8xf32>, 2>
   // CHECK: [[BUF_ARG1_NESTED:%[0-9]+]] = memref.alloc() : memref<2x64x4xvector<8xf32>, 2>
   // CHECK: [[TAG_ARG0_NESTED:%[0-9]+]] = memref.alloc() : memref<2x2xi32>
   // CHECK: [[TAG_ARG1_NESTED:%[0-9]+]] = memref.alloc() : memref<2x2xi32>
   // CHECK:  affine.dma_start %{{.*}}[
   // CHECK:  affine.dma_start %{{.*}}[
   // CHECK:  affine.for %{{.*}} = 1 to 8 {
   // CHECK:    affine.dma_start %{{.*}}[
   // CHECK:    affine.dma_start %{{.*}}[
   // CHECK:    affine.dma_wait [[TAG_ARG0_NESTED]]
   // CHECK:    affine.dma_wait [[TAG_ARG1_NESTED]]
   // CHECK:    affine.for %{{.*}} = 0 to 4 {
   // CHECK:      "foo"() : () -> ()
   // CHECK:  affine.dma_wait [[TAG_ARG0_NESTED]]
   // CHECK:  affine.dma_wait [[TAG_ARG1_NESTED]]
   // CHECK:  affine.for %{{.*}} = 0 to 4 {
   }
   memref.dealloc %5 : memref<2xi32>
   memref.dealloc %4 : memref<2xi32>
   memref.dealloc %3 : memref<2xi32>
   memref.dealloc %2 : memref<64x4xvector<8xf32>, 2>
   memref.dealloc %1 : memref<64x4xvector<8xf32>, 2>
   memref.dealloc %0 : memref<64x4xvector<8xf32>, 2>
   return
 // CHECK: }
 // CHECK-DAG:  memref.dealloc [[TAG_ARG1_NESTED]] : memref<2x2xi32>
 // CHECK-DAG:  memref.dealloc [[TAG_ARG0_NESTED]] : memref<2x2xi32>
 // CHECK-DAG:  memref.dealloc [[BUF_ARG1_NESTED]] : memref<2x64x4xvector<8xf32>, 2>
 // CHECK-DAG:  memref.dealloc [[BUF_ARG0_NESTED]] : memref<2x64x4xvector<8xf32>, 2>
 // CHECK-DAG:  memref.dealloc [[TAG_ARG2]] : memref<2x2xi32>
 // CHECK-DAG:  memref.dealloc [[BUF_ARG2]] : memref<2x64x4xvector<8xf32>, 2>
 // CHECK-NEXT: return
 }

 // -----
 #map2 = affine_map<(d0) -> ((d0 * 2048) floordiv 32)>

 // CHECK: func @loop_dma_dependent
 func @loop_dma_dependent(%arg2: memref<512x32xvector<8xf32>>) {
   %num_elts = arith.constant 256 : index
   %c0 = arith.constant 0 : index
   %0 = memref.alloc() : memref<64x4xvector<8xf32>, 2>
   %1 = memref.alloc() : memref<64x4xvector<8xf32>, 2>
   %2 = memref.alloc() : memref<64x4xvector<8xf32>, 2>
   %3 = memref.alloc() : memref<2xi32>
   %4 = memref.alloc() : memref<2xi32>
   %5 = memref.alloc() : memref<2xi32>

   // The two DMAs below are dependent (incoming and outgoing on the same
   // memref) in the same iteration; so no pipelining here.
   // CHECK-NOT: affine.dma_start
   // CHECK: affine.for %{{.*}} = 0 to 8 {
   affine.for %i0 = 0 to 8 {
     %6 = affine.apply #map2(%i0)
     affine.dma_start %arg2[%6, %c0], %2[%c0, %c0], %5[%c0], %num_elts : memref<512x32xvector<8xf32>>, memref<64x4xvector<8xf32>, 2>, memref<2xi32>
     affine.dma_wait %5[%c0], %num_elts : memref<2xi32>

     affine.dma_start %2[%c0, %c0], %arg2[%6, %c0], %5[%c0], %num_elts : memref<64x4xvector<8xf32>, 2>, memref<512x32xvector<8xf32>>, memref<2xi32>
     affine.dma_wait %5[%c0], %num_elts : memref<2xi32>
   }
   memref.dealloc %5 : memref<2xi32>
   memref.dealloc %4 : memref<2xi32>
   memref.dealloc %3 : memref<2xi32>
   memref.dealloc %2 : memref<64x4xvector<8xf32>, 2>
   memref.dealloc %1 : memref<64x4xvector<8xf32>, 2>
   memref.dealloc %0 : memref<64x4xvector<8xf32>, 2>
   return
 }

 // -----

 // CHECK-LABEL: func @escaping_use
 func @escaping_use(%arg0: memref<512 x 32 x f32>) {
   %c32 = arith.constant 32 : index
   %num_elt = arith.constant 512 : index
   %zero = arith.constant 0 : index
   %Av = memref.alloc() : memref<32 x 32 x f32, 2>
   %tag = memref.alloc() : memref<1 x i32>

   // CHECK-NOT: affine.dma_start
   // CHECK: affine.for %{{.*}} = 0 to 16 {
   affine.for %kTT = 0 to 16 {
     affine.dma_start %arg0[%zero, %zero], %Av[%zero, %zero], %tag[%zero], %num_elt :
       memref<512 x 32 x f32>,
       memref<32 x 32 x f32, 2>, memref<1 x i32>
     affine.dma_wait %tag[%zero], %num_elt : memref<1 x i32>
     // escaping use; no DMA pipelining / double buffering will be done.
     "foo"(%Av) : (memref<32 x 32 x f32, 2>) -> ()
   }
   memref.dealloc %tag : memref<1 x i32>
   memref.dealloc %Av : memref<32 x 32 x f32, 2>
   return
 // CHECK:        "foo"(%{{[0-9]+}}) : (memref<32x32xf32, 2>) -> ()
 // CHECK:      }
 // CHECK:      return
 }

 // -----

 // CHECK-LABEL: func @escaping_tag
 func @escaping_tag(%arg0: memref<512 x 32 x f32>) {
   %c32 = arith.constant 32 : index
   %num_elt = arith.constant 512 : index
   %zero = arith.constant 0 : index
   %Av = memref.alloc() : memref<32 x 32 x f32, 2>
   %tag = memref.alloc() : memref<1 x i32>

   // CHECK-NOT: affine.dma_start
   // CHECK: affine.for %{{.*}} = 0 to 16 {
   affine.for %kTT = 0 to 16 {
     affine.dma_start %arg0[%zero, %zero], %Av[%zero, %zero], %tag[%zero], %num_elt :
       memref<512 x 32 x f32>,
       memref<32 x 32 x f32, 2>, memref<1 x i32>
     affine.dma_wait %tag[%zero], %num_elt : memref<1 x i32>
     // escaping use; no DMA pipelining / double buffering will be done.
     "foo"(%tag) : (memref<1 x i32>) -> ()
   }
   memref.dealloc %tag : memref<1 x i32>
   memref.dealloc %Av : memref<32 x 32 x f32, 2>
   return
 // CHECK:        "foo"(%{{[0-9]+}}) : (memref<1xi32>) -> ()
 // CHECK:      }
 // CHECK:      return
 }


 // -----

 // CHECK-LABEL: func @live_out_use
 func @live_out_use(%arg0: memref<512 x 32 x f32>) -> f32 {
   %c32 = arith.constant 32 : index
   %num_elt = arith.constant 512 : index
   %zero = arith.constant 0 : index
   %Av = memref.alloc() : memref<32 x 32 x f32, 2>
   %tag = memref.alloc() : memref<1 x i32>

   // CHECK-NOT: affine.dma_start
   // CHECK: affine.for %{{.*}} = 0 to 16 {
   affine.for %kTT = 0 to 16 {
     affine.dma_start %arg0[%zero, %zero], %Av[%zero, %zero], %tag[%zero], %num_elt :
       memref<512 x 32 x f32>,
       memref<32 x 32 x f32, 2>, memref<1 x i32>
     affine.dma_wait %tag[%zero], %num_elt : memref<1 x i32>
   }
   // Use live out of 'affine.for' op; no DMA pipelining will be done.
   %v = affine.load %Av[%zero, %zero] : memref<32 x 32 x f32, 2>
   memref.dealloc %tag : memref<1 x i32>
   memref.dealloc %Av : memref<32 x 32 x f32, 2>
   return %v : f32
 // CHECK:      affine.load %{{[0-9]+}}[%{{.*}}, %{{.*}}] : memref<32x32xf32, 2>
 // CHECK:      return
 }

 // -----

 // CHECK-LABEL: func @dynamic_shape_dma_buffer
 func @dynamic_shape_dma_buffer(%arg0: memref<512 x 32 x f32>, %Av: memref<? x ? x f32, 2>) {
   %num_elt = arith.constant 512 : index
   %zero = arith.constant 0 : index
   %tag = memref.alloc() : memref<1 x i32>

 // Double buffering for dynamic shaped buffer.
 // Note: Cannot capture C0 because there are multiple C0 constants in the IR.
 // CHECK:       memref.dim %{{.*}}, %{{.*}} : memref<?x?xf32, 2>
 // CHECK-NEXT:  %[[C1:.*]] = arith.constant 1 : index
 // CHECK-NEXT:  memref.dim %{{.*}}, %[[C1]] : memref<?x?xf32, 2>
 // CHECK-NEXT:  memref.alloc(%{{.*}}, %{{.*}}) : memref<2x?x?xf32, 2>
 // CHECK:       affine.dma_start %{{.*}}[%{{.*}}, %{{.*}}], %{{.*}}[%{{.*}} mod 2, 0, 0], %{{.*}}[%{{.*}} mod 2, 0], %{{.*}}
   affine.for %kTT = 0 to 16 {
     affine.dma_start %arg0[%zero, %zero], %Av[%zero, %zero], %tag[%zero], %num_elt :
       memref<512 x 32 x f32>,
       memref<? x ? x f32, 2>, memref<1 x i32>
     affine.dma_wait %tag[%zero], %num_elt : memref<1 x i32>
   }
   return
 // CHECK-NEXT:  affine.for %{{.*}} = 1 to 16 {
 // CHECK:         affine.dma_start %{{.*}}[%{{.*}}, %{{.*}}], %{{.*}}[%{{.*}} mod 2, 0, 0], %{{.*}}[%{{.*}} mod 2, 0], %{{.*}}
 // CHECK:         affine.dma_wait %{{.*}}[%{{.*}} mod 2, 0], %{{.*}} : memref<2x1xi32>
 // CHECK:       }
 // CHECK:       affine.dma_wait %{{.*}}[%{{.*}} mod 2, 0], %{{.*}} : memref<2x1xi32>
 // CHECK:       return
 }

 // Memref replacement will fail here due to a non-dereferencing use. However,
 // no incorrect transformation is performed in spite of one of the uses being a
 // dereferencing one since replaceAllMemRefUsesWith checks for escaping uses
 // before performing any replacement.
 // CHECK-LABEL: func @escaping_and_indexed_use_mix
 func @escaping_and_indexed_use_mix() {
   %A = memref.alloc() : memref<256 x f32, affine_map<(d0) -> (d0)>, 0>
   %Ah = memref.alloc() : memref<32 x f32, affine_map<(d0) -> (d0)>, 1>
   %tag = memref.alloc() : memref<1 x f32>
   %zero = arith.constant 0 : index
   %num_elts = arith.constant 32 : index

   // alloc for the buffer is created but no replacement should happen.
   affine.for %i = 0 to 8 {
     affine.dma_start %A[%i], %Ah[%i], %tag[%zero], %num_elts : memref<256 x f32>, memref<32 x f32, 1>, memref<1 x f32>
     affine.dma_wait %tag[%zero], %num_elts : memref<1 x f32>
     "compute"(%Ah) : (memref<32 x f32, 1>) -> ()
     %v = affine.load %Ah[%i] : memref<32 x f32, affine_map<(d0) -> (d0)>, 1>
     "foo"(%v) : (f32) -> ()
   }
   memref.dealloc %A : memref<256 x f32, affine_map<(d0) -> (d0)>, 0>
   memref.dealloc %Ah : memref<32 x f32, affine_map<(d0) -> (d0)>, 1>
   return
 }
 // No replacement.
 // CHECK: affine.for %{{.*}} = 0 to 8 {
 // CHECK-NEXT:   affine.dma_start %{{.*}}[%{{.*}}], %{{.*}}[%{{.*}}], %{{.*}}[%{{.*}}], %{{.*}}
 // CHECK-NEXT:   affine.dma_wait %{{.*}}[%{{.*}}], %{{.*}} : memref<1xf32>
 // CHECK-NEXT:   "compute"(%{{.*}}) : (memref<32xf32, 1>) -> ()
 // CHECK-NEXT:   [[VAL:%[0-9]+]] = affine.load %{{.*}}[%{{.*}}] : memref<32xf32, 1>
 // CHECK-NEXT:   "foo"([[VAL]]) : (f32) -> ()
	// RUN: mlir-opt -allow-unregistered-dialect %s -split-input-file -affine-pipeline-data-transfer \| FileCheck %s

	// -----

	// CHECK-DAG: [[$MOD_2:#map[0-9]+]] = affine_map<(d0) -> (d0 mod 2)>
	// CHECK-DAG: [[$MAP_MINUS_1:#map[0-9]+]] = affine_map<(d0) -> (d0 - 1)>

	// CHECK-LABEL: func @loop_nest_dma() {
	func @loop_nest_dma() {

	%A = memref.alloc() : memref<256 x f32, affine_map<(d0) -> (d0)>, 0>
	%Ah = memref.alloc() : memref<32 x f32, affine_map<(d0) -> (d0)>, 1>

	%tag = memref.alloc() : memref<1 x f32>

	%zero = arith.constant 0 : index
	%num_elts = arith.constant 32 : index

	affine.for %i = 0 to 8 {
	affine.dma_start %A[%i], %Ah[%i], %tag[%zero], %num_elts : memref<256 x f32>, memref<32 x f32, 1>, memref<1 x f32>
	affine.dma_wait %tag[%zero], %num_elts : memref<1 x f32>
	%v = affine.load %Ah[%i] : memref<32 x f32, affine_map<(d0) -> (d0)>, 1>
	%r = "compute"(%v) : (f32) -> (f32)
	affine.store %r, %Ah[%i] : memref<32 x f32, affine_map<(d0) -> (d0)>, 1>
	affine.for %j = 0 to 32 {
	"do_more_compute"(%i, %j) : (index, index) -> ()
	}
	}
	memref.dealloc %tag : memref<1 x f32>
	memref.dealloc %Ah : memref<32 x f32, affine_map<(d0) -> (d0)>, 1>
	return
	}
	// CHECK: %{{.*}} = memref.alloc() : memref<256xf32>
	// CHECK: %{{.*}} = memref.alloc() : memref<2x32xf32, 1>
	// CHECK-NEXT: %{{.*}} = memref.alloc() : memref<2x1xf32>
	// CHECK-NEXT: affine.dma_start %{{.}}[%{{.}}], %{{.}}[%{{.}} mod 2, %{{.}}], %{{.}}[%{{.}} mod 2, 0], %{{.}} : memref<256xf32>, memref<2x32xf32, 1>, memref<2x1xf32>
	// CHECK-NEXT: affine.for %{{.*}} = 1 to 8 {
	// CHECK-NEXT: affine.dma_start %{{.}}[%{{.}}], %{{.}}[%{{.}} mod 2, %{{.}}], %{{.}}[%{{.}} mod 2, 0], %{{.}} : memref<256xf32>, memref<2x32xf32, 1>, memref<2x1xf32>
	// CHECK-NEXT: affine.apply [[$MAP_MINUS_1]](%{{.*}})
	// CHECK-NEXT: affine.apply [[$MOD_2]](%{{.*}})
	// CHECK-NEXT: affine.apply [[$MOD_2]](%{{.*}})
	// CHECK-NEXT: affine.dma_wait %{{.}}[%{{.}} mod 2, 0], %{{.*}} : memref<2x1xf32>
	// CHECK-NEXT: affine.load %{{.}}[%{{.}} mod 2, %{{.*}}] : memref<2x32xf32, 1>
	// CHECK-NEXT: "compute"(%{{.*}}) : (f32) -> f32
	// CHECK-NEXT: affine.store %{{.}}, %{{.}}[%{{.}} mod 2, %{{.}}] : memref<2x32xf32, 1>
	// CHECK-NEXT: affine.for %{{.*}} = 0 to 32 {
	// CHECK-NEXT: "do_more_compute"(%{{.}}, %{{.}}) : (index, index) -> ()
	// CHECK-NEXT: }
	// CHECK-NEXT: }
	// CHECK-NEXT: affine.apply [[$MAP_MINUS_1]](%{{.*}})
	// CHECK-NEXT: affine.apply [[$MOD_2]](%{{.*}})
	// CHECK-NEXT: affine.apply [[$MOD_2]](%{{.*}})
	// CHECK-NEXT: affine.dma_wait %{{.}}[%{{.}} mod 2, 0], %{{.*}} : memref<2x1xf32>
	// CHECK-NEXT: affine.load %{{.}}[%{{.}} mod 2, %{{.*}}] : memref<2x32xf32, 1>
	// CHECK-NEXT: "compute"(%{{.*}}) : (f32) -> f32
	// CHECK-NEXT: affine.store %{{.}}, %{{.}}[%{{.}} mod 2, %{{.}}] : memref<2x32xf32, 1>
	// CHECK-NEXT: affine.for %{{.*}} = 0 to 32 {
	// CHECK-NEXT: "do_more_compute"(%{{.}}, %{{.}}) : (index, index) -> ()
	// CHECK-NEXT: }
	// CHECK-NEXT: memref.dealloc %{{.*}} : memref<2x1xf32>
	// CHECK-NEXT: memref.dealloc %{{.*}} : memref<2x32xf32, 1>
	// CHECK-NEXT: return
	// CHECK-NEXT:}

	// -----

	// CHECK-DAG: [[$FLOOR_MOD_2:#map[0-9]+]] = affine_map<(d0) -> ((d0 floordiv 4) mod 2)>
	// CHECK-DAG: [[$REMAP_SHIFT_MINUS_4:#map[0-9]+]] = affine_map<(d0) -> (d0 - 4)>

	// CHECK-LABEL: @loop_step
	func @loop_step(%arg0: memref<512xf32>,
	%arg1: memref<512xf32>) {
	%c0 = arith.constant 0 : index
	%c4 = arith.constant 4 : index
	affine.for %i0 = 0 to 512 step 4 {
	%1 = memref.alloc() : memref<4xf32, 1>
	%2 = memref.alloc() : memref<1xi32>
	affine.dma_start %arg0[%i0], %1[%c0], %2[%c0], %c4,
	: memref<512xf32>, memref<4xf32, 1>, memref<1xi32>
	affine.dma_wait %2[%c0], %c4 : memref<1xi32>
	"compute"(%i0) : (index) -> ()
	memref.dealloc %2 : memref<1xi32>
	memref.dealloc %1 : memref<4xf32, 1>
	}
	return
	}
	// CHECK: [[BUF:%[0-9]+]] = memref.alloc() : memref<2x4xf32, 1>
	// CHECK: [[TAG:%[0-9]+]] = memref.alloc() : memref<2x1xi32>
	// CHECK-NEXT: affine.dma_start %{{.}}[%{{.}}], %{{.}}[(%{{.}} floordiv 4) mod 2, 0], [[TAG]][(%{{.}} floordiv 4) mod 2, 0], %{{.}} : memref<512xf32>, memref<2x4xf32, 1>, memref<2x1xi32>
	// CHECK-NEXT: affine.for %{{.*}} = 4 to 512 step 4 {
	// CHECK-NEXT: affine.dma_start %{{.}}[%{{.}}], %{{.}}[(%{{.}} floordiv 4) mod 2, 0], [[TAG]][(%{{.}} floordiv 4) mod 2, 0], %{{.}} : memref<512xf32>, memref<2x4xf32, 1>, memref<2x1xi32>
	// CHECK-NEXT: affine.apply [[$REMAP_SHIFT_MINUS_4]](%{{.*}})
	// CHECK-NEXT: affine.apply [[$FLOOR_MOD_2]](%{{.*}})
	// CHECK: affine.dma_wait [[TAG]][(%{{.}} floordiv 4) mod 2, 0], %{{.}} : memref<2x1xi32>
	// CHECK-NEXT: "compute"(%{{.*}}) : (index) -> ()
	// CHECK-NEXT: }
	// CHECK-NEXT: [[SHIFTED:%[0-9]+]] = affine.apply [[$REMAP_SHIFT_MINUS_4]](%{{.*}})
	// CHECK-NEXT: %{{.*}} = affine.apply [[$FLOOR_MOD_2]]([[SHIFTED]])
	// CHECK: affine.dma_wait [[TAG]][(%{{.}} floordiv 4) mod 2, 0], %{{.}} : memref<2x1xi32>
	// CHECK-NEXT: "compute"(%{{.*}}) : (index) -> ()
	// CHECK-NEXT: memref.dealloc [[TAG]] : memref<2x1xi32>
	// CHECK-NEXT: memref.dealloc [[BUF]] : memref<2x4xf32, 1>
	// CHECK-NEXT: return
	// CHECK-NEXT: }

	// -----

	#map1 = affine_map<(d0, d1) -> ((d0 * 2048 + d1 * 256) floordiv 32)>
	#map2 = affine_map<(d0) -> ((d0 * 2048) floordiv 32)>
	// CHECK-LABEL: func @loop_dma_nested(%{{.*}}: memref<512x32xvector<8xf32>
	func @loop_dma_nested(%arg0: memref<512x32xvector<8xf32>>, %arg1: memref<512x32xvector<8xf32>>, %arg2: memref<512x32xvector<8xf32>>) {
	%num_elts = arith.constant 256 : index
	%c0 = arith.constant 0 : index
	%0 = memref.alloc() : memref<64x4xvector<8xf32>, 2>
	%1 = memref.alloc() : memref<64x4xvector<8xf32>, 2>
	%2 = memref.alloc() : memref<64x4xvector<8xf32>, 2>
	%3 = memref.alloc() : memref<2xi32>
	%4 = memref.alloc() : memref<2xi32>
	%5 = memref.alloc() : memref<2xi32>
	// Prologue for DMA overlap on arg2.
	// CHECK-DAG: [[BUF_ARG2:%[0-9]+]] = memref.alloc() : memref<2x64x4xvector<8xf32>, 2>
	// CHECK-DAG: [[TAG_ARG2:%[0-9]+]] = memref.alloc() : memref<2x2xi32>
	// CHECK: affine.dma_start %{{.*}}[
	// CHECK: affine.for %{{.*}} = 1 to 8 {
	affine.for %i0 = 0 to 8 {
	%6 = affine.apply #map2(%i0)
	affine.dma_start %arg2[%6, %c0], %2[%c0, %c0], %5[%c0], %num_elts : memref<512x32xvector<8xf32>>, memref<64x4xvector<8xf32>, 2>, memref<2xi32>
	affine.dma_wait %5[%c0], %num_elts : memref<2xi32>
	// Steady state for DMA overlap on arg2
	// CHECK: affine.dma_start %{{.*}}[
	// CHECK: affine.dma_wait [[TAG_ARG2]]
	// Prologue for DMA overlap on arg0, arg1 nested within i0
	// CHECK: [[BUF_ARG0:%[0-9]+]] = memref.alloc() : memref<2x64x4xvector<8xf32>, 2>
	// CHECK: [[BUF_ARG1:%[0-9]+]] = memref.alloc() : memref<2x64x4xvector<8xf32>, 2>
	// CHECK: [[TAG_ARG0:%[0-9]+]] = memref.alloc() : memref<2x2xi32>
	// CHECK: [[TAG_ARG1:%[0-9]+]] = memref.alloc() : memref<2x2xi32>
	// CHECK: affine.dma_start %{{.*}}[
	// CHECK: affine.dma_start %{{.*}}[
	// CHECK-NEXT: affine.for %{{.*}} = 1 to 8 {
	affine.for %i1 = 0 to 8 {
	%7 = affine.apply #map1(%i0, %i1)
	%8 = affine.apply #map2(%i1)
	affine.dma_start %arg0[%7, %c0], %0[%c0, %c0], %3[%c0], %num_elts : memref<512x32xvector<8xf32>>, memref<64x4xvector<8xf32>, 2>, memref<2xi32>
	affine.dma_start %arg1[%8, %c0], %1[%c0, %c0], %4[%c0], %num_elts : memref<512x32xvector<8xf32>>, memref<64x4xvector<8xf32>, 2>, memref<2xi32>
	affine.dma_wait %3[%c0], %num_elts : memref<2xi32>
	affine.dma_wait %4[%c0], %num_elts : memref<2xi32>
	// Steady state for DMA overlap on arg0, arg1
	// CHECK: affine.dma_start %{{.*}}[
	// CHECK: affine.dma_start %{{.*}}[
	// CHECK: affine.dma_wait [[TAG_ARG0]]
	// CHECK: affine.dma_wait [[TAG_ARG1]]
	// CHECK-NEXT: affine.for %{{.*}} = 0 to 4 {
	affine.for %i2 = 0 to 4 {
	"foo"() : () -> ()
	}
	}
	// epilogue for arg0, arg1
	// CHECK: affine.dma_wait [[TAG_ARG0]]
	// CHECK: affine.dma_wait [[TAG_ARG1]]
	// CHECK-DAG: memref.dealloc [[TAG_ARG1]] : memref<2x2xi32>
	// CHECK-DAG: memref.dealloc [[TAG_ARG0]] : memref<2x2xi32>
	// CHECK-DAG: memref.dealloc [[BUF_ARG1]] : memref<2x64x4xvector<8xf32>, 2>
	// CHECK-DAG: memref.dealloc [[BUF_ARG0]] : memref<2x64x4xvector<8xf32>, 2>
	// epilogue for DMA overlap on %arg2
	// CHECK: affine.dma_wait [[TAG_ARG2]]
	// Within the epilogue for arg2's DMA, we have the DMAs on %arg1, %arg2 nested.
	// CHECK: [[BUF_ARG0_NESTED:%[0-9]+]] = memref.alloc() : memref<2x64x4xvector<8xf32>, 2>
	// CHECK: [[BUF_ARG1_NESTED:%[0-9]+]] = memref.alloc() : memref<2x64x4xvector<8xf32>, 2>
	// CHECK: [[TAG_ARG0_NESTED:%[0-9]+]] = memref.alloc() : memref<2x2xi32>
	// CHECK: [[TAG_ARG1_NESTED:%[0-9]+]] = memref.alloc() : memref<2x2xi32>
	// CHECK: affine.dma_start %{{.*}}[
	// CHECK: affine.dma_start %{{.*}}[
	// CHECK: affine.for %{{.*}} = 1 to 8 {
	// CHECK: affine.dma_start %{{.*}}[
	// CHECK: affine.dma_start %{{.*}}[
	// CHECK: affine.dma_wait [[TAG_ARG0_NESTED]]
	// CHECK: affine.dma_wait [[TAG_ARG1_NESTED]]
	// CHECK: affine.for %{{.*}} = 0 to 4 {
	// CHECK: "foo"() : () -> ()
	// CHECK: affine.dma_wait [[TAG_ARG0_NESTED]]
	// CHECK: affine.dma_wait [[TAG_ARG1_NESTED]]
	// CHECK: affine.for %{{.*}} = 0 to 4 {
	}
	memref.dealloc %5 : memref<2xi32>
	memref.dealloc %4 : memref<2xi32>
	memref.dealloc %3 : memref<2xi32>
	memref.dealloc %2 : memref<64x4xvector<8xf32>, 2>
	memref.dealloc %1 : memref<64x4xvector<8xf32>, 2>
	memref.dealloc %0 : memref<64x4xvector<8xf32>, 2>
	return
	// CHECK: }
	// CHECK-DAG: memref.dealloc [[TAG_ARG1_NESTED]] : memref<2x2xi32>
	// CHECK-DAG: memref.dealloc [[TAG_ARG0_NESTED]] : memref<2x2xi32>
	// CHECK-DAG: memref.dealloc [[BUF_ARG1_NESTED]] : memref<2x64x4xvector<8xf32>, 2>
	// CHECK-DAG: memref.dealloc [[BUF_ARG0_NESTED]] : memref<2x64x4xvector<8xf32>, 2>
	// CHECK-DAG: memref.dealloc [[TAG_ARG2]] : memref<2x2xi32>
	// CHECK-DAG: memref.dealloc [[BUF_ARG2]] : memref<2x64x4xvector<8xf32>, 2>
	// CHECK-NEXT: return
	}

	// -----
	#map2 = affine_map<(d0) -> ((d0 * 2048) floordiv 32)>

	// CHECK: func @loop_dma_dependent
	func @loop_dma_dependent(%arg2: memref<512x32xvector<8xf32>>) {
	%num_elts = arith.constant 256 : index
	%c0 = arith.constant 0 : index
	%0 = memref.alloc() : memref<64x4xvector<8xf32>, 2>
	%1 = memref.alloc() : memref<64x4xvector<8xf32>, 2>
	%2 = memref.alloc() : memref<64x4xvector<8xf32>, 2>
	%3 = memref.alloc() : memref<2xi32>
	%4 = memref.alloc() : memref<2xi32>
	%5 = memref.alloc() : memref<2xi32>

	// The two DMAs below are dependent (incoming and outgoing on the same
	// memref) in the same iteration; so no pipelining here.
	// CHECK-NOT: affine.dma_start
	// CHECK: affine.for %{{.*}} = 0 to 8 {
	affine.for %i0 = 0 to 8 {
	%6 = affine.apply #map2(%i0)
	affine.dma_start %arg2[%6, %c0], %2[%c0, %c0], %5[%c0], %num_elts : memref<512x32xvector<8xf32>>, memref<64x4xvector<8xf32>, 2>, memref<2xi32>
	affine.dma_wait %5[%c0], %num_elts : memref<2xi32>

	affine.dma_start %2[%c0, %c0], %arg2[%6, %c0], %5[%c0], %num_elts : memref<64x4xvector<8xf32>, 2>, memref<512x32xvector<8xf32>>, memref<2xi32>
	affine.dma_wait %5[%c0], %num_elts : memref<2xi32>
	}
	memref.dealloc %5 : memref<2xi32>
	memref.dealloc %4 : memref<2xi32>
	memref.dealloc %3 : memref<2xi32>
	memref.dealloc %2 : memref<64x4xvector<8xf32>, 2>
	memref.dealloc %1 : memref<64x4xvector<8xf32>, 2>
	memref.dealloc %0 : memref<64x4xvector<8xf32>, 2>
	return
	}

	// -----

	// CHECK-LABEL: func @escaping_use
	func @escaping_use(%arg0: memref<512 x 32 x f32>) {
	%c32 = arith.constant 32 : index
	%num_elt = arith.constant 512 : index
	%zero = arith.constant 0 : index
	%Av = memref.alloc() : memref<32 x 32 x f32, 2>
	%tag = memref.alloc() : memref<1 x i32>

	// CHECK-NOT: affine.dma_start
	// CHECK: affine.for %{{.*}} = 0 to 16 {
	affine.for %kTT = 0 to 16 {
	affine.dma_start %arg0[%zero, %zero], %Av[%zero, %zero], %tag[%zero], %num_elt :
	memref<512 x 32 x f32>,
	memref<32 x 32 x f32, 2>, memref<1 x i32>
	affine.dma_wait %tag[%zero], %num_elt : memref<1 x i32>
	// escaping use; no DMA pipelining / double buffering will be done.
	"foo"(%Av) : (memref<32 x 32 x f32, 2>) -> ()
	}
	memref.dealloc %tag : memref<1 x i32>
	memref.dealloc %Av : memref<32 x 32 x f32, 2>
	return
	// CHECK: "foo"(%{{[0-9]+}}) : (memref<32x32xf32, 2>) -> ()
	// CHECK: }
	// CHECK: return
	}

	// -----

	// CHECK-LABEL: func @escaping_tag
	func @escaping_tag(%arg0: memref<512 x 32 x f32>) {
	%c32 = arith.constant 32 : index
	%num_elt = arith.constant 512 : index
	%zero = arith.constant 0 : index
	%Av = memref.alloc() : memref<32 x 32 x f32, 2>
	%tag = memref.alloc() : memref<1 x i32>

	// CHECK-NOT: affine.dma_start
	// CHECK: affine.for %{{.*}} = 0 to 16 {
	affine.for %kTT = 0 to 16 {
	affine.dma_start %arg0[%zero, %zero], %Av[%zero, %zero], %tag[%zero], %num_elt :
	memref<512 x 32 x f32>,
	memref<32 x 32 x f32, 2>, memref<1 x i32>
	affine.dma_wait %tag[%zero], %num_elt : memref<1 x i32>
	// escaping use; no DMA pipelining / double buffering will be done.
	"foo"(%tag) : (memref<1 x i32>) -> ()
	}
	memref.dealloc %tag : memref<1 x i32>
	memref.dealloc %Av : memref<32 x 32 x f32, 2>
	return
	// CHECK: "foo"(%{{[0-9]+}}) : (memref<1xi32>) -> ()
	// CHECK: }
	// CHECK: return
	}


	// -----

	// CHECK-LABEL: func @live_out_use
	func @live_out_use(%arg0: memref<512 x 32 x f32>) -> f32 {
	%c32 = arith.constant 32 : index
	%num_elt = arith.constant 512 : index
	%zero = arith.constant 0 : index
	%Av = memref.alloc() : memref<32 x 32 x f32, 2>
	%tag = memref.alloc() : memref<1 x i32>

	// CHECK-NOT: affine.dma_start
	// CHECK: affine.for %{{.*}} = 0 to 16 {
	affine.for %kTT = 0 to 16 {
	affine.dma_start %arg0[%zero, %zero], %Av[%zero, %zero], %tag[%zero], %num_elt :
	memref<512 x 32 x f32>,
	memref<32 x 32 x f32, 2>, memref<1 x i32>
	affine.dma_wait %tag[%zero], %num_elt : memref<1 x i32>
	}
	// Use live out of 'affine.for' op; no DMA pipelining will be done.
	%v = affine.load %Av[%zero, %zero] : memref<32 x 32 x f32, 2>
	memref.dealloc %tag : memref<1 x i32>
	memref.dealloc %Av : memref<32 x 32 x f32, 2>
	return %v : f32
	// CHECK: affine.load %{{[0-9]+}}[%{{.}}, %{{.}}] : memref<32x32xf32, 2>
	// CHECK: return
	}

	// -----

	// CHECK-LABEL: func @dynamic_shape_dma_buffer
	func @dynamic_shape_dma_buffer(%arg0: memref<512 x 32 x f32>, %Av: memref<? x ? x f32, 2>) {
	%num_elt = arith.constant 512 : index
	%zero = arith.constant 0 : index
	%tag = memref.alloc() : memref<1 x i32>

	// Double buffering for dynamic shaped buffer.
	// Note: Cannot capture C0 because there are multiple C0 constants in the IR.
	// CHECK: memref.dim %{{.}}, %{{.}} : memref<?x?xf32, 2>
	// CHECK-NEXT: %[[C1:.*]] = arith.constant 1 : index
	// CHECK-NEXT: memref.dim %{{.*}}, %[[C1]] : memref<?x?xf32, 2>
	// CHECK-NEXT: memref.alloc(%{{.}}, %{{.}}) : memref<2x?x?xf32, 2>
	// CHECK: affine.dma_start %{{.}}[%{{.}}, %{{.}}], %{{.}}[%{{.}} mod 2, 0, 0], %{{.}}[%{{.}} mod 2, 0], %{{.}}
	affine.for %kTT = 0 to 16 {
	affine.dma_start %arg0[%zero, %zero], %Av[%zero, %zero], %tag[%zero], %num_elt :
	memref<512 x 32 x f32>,
	memref<? x ? x f32, 2>, memref<1 x i32>
	affine.dma_wait %tag[%zero], %num_elt : memref<1 x i32>
	}
	return
	// CHECK-NEXT: affine.for %{{.*}} = 1 to 16 {
	// CHECK: affine.dma_start %{{.}}[%{{.}}, %{{.}}], %{{.}}[%{{.}} mod 2, 0, 0], %{{.}}[%{{.}} mod 2, 0], %{{.}}
	// CHECK: affine.dma_wait %{{.}}[%{{.}} mod 2, 0], %{{.*}} : memref<2x1xi32>
	// CHECK: }
	// CHECK: affine.dma_wait %{{.}}[%{{.}} mod 2, 0], %{{.*}} : memref<2x1xi32>
	// CHECK: return
	}

	// Memref replacement will fail here due to a non-dereferencing use. However,
	// no incorrect transformation is performed in spite of one of the uses being a
	// dereferencing one since replaceAllMemRefUsesWith checks for escaping uses
	// before performing any replacement.
	// CHECK-LABEL: func @escaping_and_indexed_use_mix
	func @escaping_and_indexed_use_mix() {
	%A = memref.alloc() : memref<256 x f32, affine_map<(d0) -> (d0)>, 0>
	%Ah = memref.alloc() : memref<32 x f32, affine_map<(d0) -> (d0)>, 1>
	%tag = memref.alloc() : memref<1 x f32>
	%zero = arith.constant 0 : index
	%num_elts = arith.constant 32 : index

	// alloc for the buffer is created but no replacement should happen.
	affine.for %i = 0 to 8 {
	affine.dma_start %A[%i], %Ah[%i], %tag[%zero], %num_elts : memref<256 x f32>, memref<32 x f32, 1>, memref<1 x f32>
	affine.dma_wait %tag[%zero], %num_elts : memref<1 x f32>
	"compute"(%Ah) : (memref<32 x f32, 1>) -> ()
	%v = affine.load %Ah[%i] : memref<32 x f32, affine_map<(d0) -> (d0)>, 1>
	"foo"(%v) : (f32) -> ()
	}
	memref.dealloc %A : memref<256 x f32, affine_map<(d0) -> (d0)>, 0>
	memref.dealloc %Ah : memref<32 x f32, affine_map<(d0) -> (d0)>, 1>
	return
	}
	// No replacement.
	// CHECK: affine.for %{{.*}} = 0 to 8 {
	// CHECK-NEXT: affine.dma_start %{{.}}[%{{.}}], %{{.}}[%{{.}}], %{{.}}[%{{.}}], %{{.*}}
	// CHECK-NEXT: affine.dma_wait %{{.}}[%{{.}}], %{{.*}} : memref<1xf32>
	// CHECK-NEXT: "compute"(%{{.*}}) : (memref<32xf32, 1>) -> ()
	// CHECK-NEXT: [[VAL:%[0-9]+]] = affine.load %{{.}}[%{{.}}] : memref<32xf32, 1>
	// CHECK-NEXT: "foo"([[VAL]]) : (f32) -> ()