mlir/test/Dialect/Affine/loop-tiling-parametric.mlir - llvm-project - Git at Google

 // RUN: mlir-opt %s -split-input-file -test-affine-parametric-tile | FileCheck %s
 // Test cases to test the utility introduced to tile affine for loops using
 // SSA values as tiling parameters(tile sizes). The tile sizes are expected
 // to be passed as input arguments(before any other argument) to the function
 // enclosing the loop nest. Currently hyper-rectangular loop nests with constant
 // lower bounds are supported.

 // -----

 // CHECK-DAG: [[LBI:#map[0-9]+]] = affine_map<(d0)[s0] -> (d0 * s0)>
 // CHECK-DAG: [[UBI0:#map[0-9]+]] = affine_map<(d0)[s0] -> (d0 * s0 + s0, 256)>
 // CHECK-DAG: [[UBI1:#map[0-9]+]] = affine_map<(d0)[s0] -> (d0 * s0 + s0, 512)>
 // CHECK-DAG: [[UBI2:#map[0-9]+]] = affine_map<(d0)[s0] -> (d0 * s0 + s0, 1024)>
 // CHECK-DAG: [[UBO0:#map[0-9]+]] = affine_map<()[s0] -> (256 ceildiv s0)>
 // CHECK-DAG: [[UBO1:#map[0-9]+]] = affine_map<()[s0] -> (512 ceildiv s0)>
 // CHECK-DAG: [[UBO2:#map[0-9]+]] = affine_map<()[s0] -> (1024 ceildiv s0)>

 // CHECK: func @loop_tiling_3d([[ARG0:%arg[0-9]+]]: index, [[ARG1:%arg[0-9]+]]: index, [[ARG2:%arg[0-9]+]]: index)
 // CHECK-NEXT:   affine.for [[ARG3:%arg[0-9]+]] = 0 to [[UBO0]](){{.*}}[[ARG0]]
 // CHECK-NEXT:     affine.for [[ARG4:%arg[0-9]+]] = 0 to [[UBO1]](){{.*}}[[ARG1]]
 // CHECK-NEXT:       affine.for [[ARG5:%arg[0-9]+]] = 0 to [[UBO2]](){{.*}}[[ARG2]]
 // CHECK-NEXT:         affine.for %[[I:.*]] = [[LBI]]{{.*}}[[ARG3]]{{.*}}[[ARG0]]{{.*}} to min [[UBI0]]{{.*}}[[ARG3]]{{.*}}[[ARG0]]
 // CHECK-NEXT:          affine.for %[[J:.*]] = [[LBI]]{{.*}}[[ARG4]]{{.*}}[[ARG1]]{{.*}} to min [[UBI1]]{{.*}}[[ARG4]]{{.*}}[[ARG1]]
 // CHECK-NEXT:            affine.for %[[K:.*]] = [[LBI]]{{.*}}[[ARG5]]{{.*}}[[ARG2]]{{.*}} to min [[UBI2]]{{.*}}[[ARG5]]{{.*}}[[ARG2]]
 // CHECK-NEXT:              "test.foo"(%[[I]], %[[J]], %[[K]])
 func @loop_tiling_3d(%t0 : index, %t1 : index, %t2 : index) {
   affine.for %i = 0 to 256 {
     affine.for %j = 0 to 512 {
       affine.for %k = 0 to 1024 {
         "test.foo"(%i, %j, %k) : (index, index, index) -> ()
       }
     }
   }
   return
 }

 // -----

 // CHECK-DAG: [[LBI:#map[0-9]+]] = affine_map<(d0)[s0] -> (d0 * s0)>
 // CHECK-DAG: [[UBI0:#map[0-9]+]] = affine_map<(d0)[s0] -> (d0 * s0 + s0 * 4, 256)>
 // CHECK-DAG: [[UBI1:#map[0-9]+]] = affine_map<(d0)[s0] -> (d0 * s0 + s0 * 3, 512)>
 // CHECK-DAG: [[UBI2:#map[0-9]+]] = affine_map<(d0)[s0] -> (d0 * s0 + s0 * 2, 1024)>
 // CHECK-DAG: [[UBO0:#map[0-9]+]] = affine_map<()[s0] -> (256 ceildiv s0)>
 // CHECK-DAG: [[UBO1:#map[0-9]+]] = affine_map<()[s0] -> (512 ceildiv s0)>
 // CHECK-DAG: [[UBO2:#map[0-9]+]] = affine_map<()[s0] -> (1024 ceildiv s0)>

 // CHECK: func @loop_tiling_non_unit_step([[ARG0:%arg[0-9]+]]: index, [[ARG1:%arg[0-9]+]]: index, [[ARG2:%arg[0-9]+]]: index)
 // CHECK-NEXT:  affine.for [[ARG3:%arg[0-9]+]] = 0 to [[UBO0]](){{.*}}[[ARG0]]{{.*}}step 4
 // CHECK-NEXT:    affine.for [[ARG4:%arg[0-9]+]] = 0 to [[UBO1]](){{.*}}[[ARG1]]{{.*}} step 3
 // CHECK-NEXT:       affine.for [[ARG5:%arg[0-9]+]] = 0 to [[UBO2]](){{.*}}[[ARG2]]{{.*}} step 2
 // CHECK-NEXT:         affine.for %[[I:.*]] = [[LBI]]{{.*}}[[ARG3]]{{.*}}[[ARG0]]{{.*}} to min [[UBI0]]{{.*}}[[ARG3]]{{.*}}[[ARG0]]{{.*}} step 4
 // CHECK-NEXT:          affine.for %[[J:.*]] = [[LBI]]{{.*}}[[ARG4]]{{.*}}[[ARG1]]{{.*}} to min [[UBI1]]{{.*}}[[ARG4]]{{.*}}[[ARG1]]{{.*}} step 3
 // CHECK-NEXT:            affine.for %[[K:.*]] = [[LBI]]{{.*}}[[ARG5]]{{.*}}[[ARG2]]{{.*}} to min [[UBI2]]{{.*}}[[ARG5]]{{.*}}[[ARG2]]{{.*}} step 2
 // CHECK-NEXT:              "test.foo"(%[[I]], %[[J]], %[[K]])
 func @loop_tiling_non_unit_step(%t0: index, %t1: index, %t2: index){
   affine.for %i = 0 to 256 step 4 {
     affine.for %j = 0 to 512  step 3 {
       affine.for %k = 0 to 1024 step 2 {
         "test.foo"(%i, %j, %k) : (index, index, index) -> ()
       }
     }
   }
   return
 }

 // -----

 // CHECK-DAG: [[LBI0:#map[0-9]+]] = affine_map<(d0)[s0] -> (d0 * s0)>
 // CHECK-DAG: [[UBI0:#map[0-9]+]] = affine_map<(d0)[s0, s1, s2] -> (d0 * s2 + s2, s0, 4096 floordiv s1)>
 // CHECK-DAG: [[UBO0:#map[0-9]+]] = affine_map<()[s0, s1, s2] -> (s0 ceildiv s2, (4096 floordiv s1) ceildiv s2)>

 // CHECK: func @tile_loop_with_div_in_upper_bound([[ARG0:%arg[0-9]+]]: index, %{{.*}}: memref<?xi32>, %{{.*}}: index, %{{.*}}: index)
 #ub = affine_map<()[s0, s1] -> (s0, 4096 floordiv s1)>
 func @tile_loop_with_div_in_upper_bound(%t5 : index, %A : memref<? x i32>, %L : index, %U : index) {
   %c0 = arith.constant 0 : index
   %M = memref.dim %A, %c0 : memref<? x i32>
   affine.for %i = 0 to min #ub()[%M, %U] {
     arith.addi %i, %i : index
   }
   // CHECK:  affine.for [[ARG1:%arg[0-9]+]] = 0 to min [[UBO0]]()[%{{.*}}, %{{.*}}, [[ARG0]]]
   // CHECK-NEXT:    affine.for %[[I:.*]] = [[LBI0]]([[ARG1]]){{.*}}[[ARG0]]{{.*}} to min [[UBI0]]({{.*}})[{{.*}}, {{.*}}, [[ARG0]]]
   // CHECK-NEXT:      arith.addi %[[I]], %[[I]]
   return
 }

 // -----

 // CHECK-DAG: [[LBI0:#map[0-9]+]] = affine_map<(d0)[s0] -> (d0 * s0)>
 // CHECK-DAG: [[UBI0:#map[0-9]+]] = affine_map<(d0)[s0, s1, s2] -> (d0 * s2 + s2 * 4, s0, 4096 floordiv s1)>
 // CHECK-DAG: [[UBO0:#map[0-9]+]] = affine_map<()[s0, s1, s2] -> (s0 ceildiv s2, (4096 floordiv s1) ceildiv s2)>

 // CHECK: func @tile_loop_with_div_in_upper_bound_non_unit_step([[ARG0:%arg[0-9]+]]: index, %{{.*}}: memref<?xi32>, %{{.*}}: index, %{{.*}}: index)
 #ub = affine_map<()[s0, s1] -> (s0, 4096 floordiv s1)>
 func @tile_loop_with_div_in_upper_bound_non_unit_step(%t5 : index, %A : memref<? x i32>, %L : index, %U : index) {
   %c0 = arith.constant 0 : index
   %M = memref.dim %A, %c0 : memref<? x i32>
   affine.for %i = 0 to min #ub()[%M, %U] step 4 {
     arith.addi %i, %i : index
   }
   // CHECK: affine.for [[ARG1:%arg[0-9]+]] = 0 to min [[UBO0]]()[%{{.*}}, %{{.*}}, [[ARG0]]]{{.*}} step 4{{.*}}
   // CHECK-NEXT:    affine.for %[[I:.*]] = [[LBI0]]([[ARG1]]){{.*}}[[ARG0]]{{.*}} to min [[UBI0]]({{.*}})[{{.*}}, {{.*}}, [[ARG0]]]{{.*}} step 4{{.*}}
   // CHECK-NEXT:      arith.addi %[[I]], %[[I]]
   return
 }

 // -----

 // CHECK-DAG: [[LBI0:#map[0-9]+]] = affine_map<(d0)[s0] -> ((d0 - 8) * s0 + 8)>
 // CHECK-DAG: [[UBI2:#map[0-9]+]] = affine_map<(d0)[s0, s1] -> ((d0 - 8) * s1 + s1 * 4 + 8, s0 + 16)>
 // CHECK-DAG: [[UBI1:#map[0-9]+]] = affine_map<(d0)[s0, s1] -> ((d0 - 8) * s1 + s1 + 8, s0 + 16)>
 // CHECK-DAG: [[UBI0:#map[0-9]+]] = affine_map<(d0)[s0] -> ((d0 - 8) * s0 + s0 + 8, 256)>
 // CHECK-DAG: [[UBO1:#map[0-9]+]] = affine_map<()[s0, s1] -> ((s0 + 8) ceildiv s1 + 8)>
 // CHECK-DAG: [[UBO0:#map[0-9]+]] = affine_map<()[s0] -> (248 ceildiv s0 + 8)>

 // CHECK: func @tile_loop_with_non_zero_lb([[ARG0:%arg[0-9]+]]: index, [[ARG1:%arg[0-9]+]]: index, [[ARG2:%arg[0-9]+]]: index, %{{.*}}: index)
 // CHECK-NEXT:  affine.for [[ARG3:%arg[0-9+]]] = 8 to [[UBO0]]{{.*}}[[ARG0]]{{.*}}
 // CHECK-NEXT:    affine.for [[ARG4:%arg[0-9+]]] = 8 to [[UBO1]]{{.*}}[[ARG1]]{{.*}}
 // CHECK-NEXT:      affine.for [[ARG5:%arg[0-9+]]] = 8 to [[UBO1]]{{.*}}[[ARG2]]{{.*}} step 4
 // CHECK-NEXT:        affine.for %[[I:.*]] = [[LBI0]]([[ARG3]]){{.*}}[[ARG0]]{{.*}} to min [[UBI0]]([[ARG3]]){{.*}}[[ARG0]]{{.*}}
 // CHECK-NEXT:          affine.for %[[J:.*]] = [[LBI0]]([[ARG4]]){{.*}}[[ARG1]]{{.*}} to min [[UBI1]]([[ARG4]]){{.*}}[[ARG1]]{{.*}}
 // CHECK-NEXT:            affine.for %[[K:.*]] = [[LBI0]]([[ARG5]]){{.*}}[[ARG2]]{{.*}} to min [[UBI2]]([[ARG5]]){{.*}}[[ARG2]]{{.*}}step 4{{.*}}
 // CHECK-NEXT:              "test.foo"(%[[I]], %[[J]], %[[K]]) : (index, index, index) -> ()
 #ubi = affine_map<()[s0] -> (s0 + 16)>
 func @tile_loop_with_non_zero_lb(%t0: index, %t1: index, %t2: index, %U: index){
   affine.for %i = 8 to 256 {
     affine.for %j = 8 to #ubi()[%U] {
       affine.for %k = 8 to #ubi()[%U] step 4 {
         "test.foo"(%i, %j, %k) : (index, index, index) -> ()
       }
     }
   }
   return
 }

 // -----

 // CHECK-DAG: [[LBI:#map[0-9]+]] = affine_map<(d0)[s0] -> (d0 * s0)>
 // CHECK-DAG: [[UBI0:#map[0-9]+]] = affine_map<(d0)[s0] -> (d0 * s0 + s0, 256)>
 // CHECK-DAG: [[UBI1:#map[0-9]+]] = affine_map<(d0)[s0] -> (d0 * s0 + s0, 250)>
 // CHECK-DAG: [[UBO0:#map[0-9]+]] = affine_map<()[s0] -> (256 ceildiv s0)>
 // CHECK-DAG: [[UBO1:#map[0-9]+]] = affine_map<()[s0] -> (250 ceildiv s0)>

 // CHECK: func @simple_matmul([[ARG0:%arg[0-9]+]]: index, [[ARG1:%arg[0-9]+]]: index, [[ARG2:%arg[0-9]+]]: index{{.*}})
 // CHECK-NEXT:   affine.for [[ARG3:%arg[0-9]+]] = 0 to [[UBO0]](){{.*}}[[ARG0]]{{.*}}
 // CHECK-NEXT:     affine.for [[ARG4:%arg[0-9]+]] = 0 to [[UBO0]](){{.*}}[[ARG1]]{{.*}}
 // CHECK-NEXT:       affine.for [[ARG5:%arg[0-9]+]] = 0 to [[UBO1]](){{.*}}[[ARG2]]{{.*}}
 // CHECK-NEXT:         affine.for %[[I:.*]] = [[LBI]]{{.*}}[[ARG3]]{{.*}}[[ARG0]]{{.*}} to min [[UBI0]]{{.*}}[[ARG3]]{{.*}}[[ARG0]]{{.*}}
 // CHECK-NEXT:          affine.for %[[J:.*]] = [[LBI]]{{.*}}[[ARG4]]{{.*}}[[ARG1]]{{.*}} to min [[UBI0]]{{.*}}[[ARG4]]{{.*}}[[ARG1]]{{.*}}
 // CHECK-NEXT:            affine.for %[[K:.*]] = [[LBI]]{{.*}}[[ARG5]]{{.*}}[[ARG2]]{{.*}} to min [[UBI1]]{{.*}}[[ARG5]]{{.*}}[[ARG2]]{{.*}}
 // CHECK-NEXT:                 affine.load %{{.*}}[%[[I]], %[[K]]]
 // CHECK-NEXT:                 affine.load %{{.*}}[%[[K]], %[[J]]]
 // CHECK-NEXT:                 affine.load %{{.*}}[%[[I]], %[[J]]]
 // CHECK-NEXT:                 arith.mulf %{{.*}}
 // CHECK-NEXT:                 arith.addf %{{.*}}
 // CHECK-NEXT:                 affine.store %{{.*}}[%[[I]], %[[J]]]
 func @simple_matmul(%t6 : index, %t7 : index, %t8 : index, %arg0: memref<256x256xvector<64xf32>>, %arg1: memref<256x256xvector<64xf32>>, %arg2: memref<256x256xvector<64xf32>>) -> memref<256x256xvector<64xf32>> {
   affine.for %i = 0 to 256 {
     affine.for %j = 0 to 256 {
       affine.for %k = 0 to 250 {
         %l = affine.load %arg0[%i, %k] : memref<256x256xvector<64xf32>>
         %r = affine.load %arg1[%k, %j] : memref<256x256xvector<64xf32>>
         %o = affine.load %arg2[%i, %j] : memref<256x256xvector<64xf32>>
         %m = arith.mulf %l, %r : vector<64xf32>
         %a = arith.addf %o, %m : vector<64xf32>
         affine.store %a, %arg2[%i, %j] : memref<256x256xvector<64xf32>>
       }
     }
   }
   return %arg2 : memref<256x256xvector<64xf32>>
 }

 // -----

 // CHECK-DAG: [[LBI0:#map[0-9]+]] = affine_map<(d0)[s0] -> (d0 * s0)>
 // CHECK-DAG: [[UBI0:#map[0-9]+]] = affine_map<(d0)[s0, s1] -> (d0 * s1 + s1, s0)>
 // CHECK-DAG: [[UBO0:#map[0-9]+]] = affine_map<()[s0, s1] -> (s0 ceildiv s1)>

 // CHECK: func @tile_with_symbolic_loop_upper_bounds([[ARG0:%arg[0-9]+]]: index, [[ARG1:%arg[0-9]+]]: index{{.*}}){{.*}}
 // CHECK:        affine.for [[ARG2:%arg[0-9]+]] = 0 to [[UBO0]](){{.*}}[[ARG0]]{{.*}}
 // CHECK-NEXT:     affine.for [[ARG3:%arg[0-9]+]] = 0 to [[UBO0]](){{.*}}[[ARG1]]{{.*}}
 // CHECK-NEXT:       affine.for %[[I0:.*]] = [[LBI0]]{{.*}}[[ARG2]]{{.*}}[[ARG0]]{{.*}} to min [[UBI0]]{{.*}}[[ARG2]]{{.*}}[[ARG0]]{{.*}}
 // CHECK-NEXT:         affine.for %[[I1:.*]] = [[LBI0]]{{.*}}[[ARG3]]{{.*}}[[ARG1]]{{.*}} to min [[UBI0]]{{.*}}[[ARG3]]{{.*}}[[ARG1]]{{.*}}
 // CHECK-NEXT:           affine.store %{{.*}}, %{{.*}}[%[[I0]], %[[I1]]] : memref<?x?xf32>
 // CHECK-NEXT:           affine.for %[[I2:.*]] = 0 to %{{.*}} {
 // CHECK-NEXT:             affine.load %{{.*}}%[[I0]], %[[I2]]
 // CHECK-NEXT:             affine.load %{{.*}}%[[I2]], %[[I1]]
 // CHECK-NEXT:             arith.mulf
 // CHECK-NEXT:             affine.load %{{.*}}%[[I0]], %[[I1]]
 // CHECK-NEXT:             arith.addf
 // CHECK-NEXT:             affine.store %{{.*}}%[[I0]], %[[I1]]
 func @tile_with_symbolic_loop_upper_bounds(%t9 : index, %t10: index, %arg0: memref<?x?xf32>, %arg1: memref<?x?xf32>, %arg2: memref<?x?xf32>) {
   %cst = arith.constant 0.000000e+00 : f32
   %c0 = arith.constant 0 : index
   %0 = memref.dim %arg0, %c0 : memref<?x?xf32>
   affine.for %i0 = 0 to %0 {
     affine.for %i1 = 0 to %0 {
       affine.store %cst, %arg2[%i0, %i1] : memref<?x?xf32>
       affine.for %i2 = 0 to %0 {
         %1 = affine.load %arg0[%i0, %i2] : memref<?x?xf32>
         %2 = affine.load %arg1[%i2, %i1] : memref<?x?xf32>
         %3 = arith.mulf %1, %2 : f32
         %4 = affine.load %arg2[%i0, %i1] : memref<?x?xf32>
         %5 = arith.addf %4, %3 : f32
         affine.store %5, %arg2[%i0, %i1] : memref<?x?xf32>
       }
     }
   }
   return
 }

 // -----

 // CHECK-DAG: [[LBI0:#map[0-9]+]] = affine_map<(d0)[s0] -> (d0 * s0)>
 // CHECK-DAG: [[UBI0:#map[0-9]+]] = affine_map<(d0)[s0, s1, s2] -> (d0 * s2 + s2, s0 + s1)>
 // CHECK-DAG: [[UBO0:#map[0-9]+]] = affine_map<()[s0, s1, s2] -> ((s0 + s1) ceildiv s2)>

 // CHECK: func @tile_with_loop_upper_bounds_in_two_symbols([[ARG0:%arg[0-9]+]]: index{{.*}}){{.*}}
 func @tile_with_loop_upper_bounds_in_two_symbols(%t11 : index, %arg0: memref<?xf32>, %limit: index) {
   %c0 = arith.constant 0 : index
   %dim0 = memref.dim %arg0, %c0 : memref<?xf32>
   affine.for %i0 = 0 to affine_map<()[s0, s1] -> (s0 + s1)> ()[%dim0, %limit] {
     %v0 = affine.load %arg0[%i0] : memref<?xf32>
   }
   // CHECK:  affine.for [[ARG1:%arg[0-9]+]] = 0 to [[UBO0]]()[%{{.*}}, %{{.*}}, [[ARG0]]]
   // CHECK-NEXT:    affine.for %[[I:.*]] = [[LBI0]]([[ARG1]]){{.*}}[[ARG0]]{{.*}} to min [[UBI0]]([[ARG1]])[{{.*}}, {{.*}}, [[ARG0]]]
   // CHECK-NEXT:      affine.load %{{.*}}[%[[I]]]
   return
 }

 // -----

 // CHECK-DAG: [[LBI0:#map[0-9]+]] = affine_map<(d0)[s0] -> (d0 * s0)>
 // CHECK-DAG: [[UBI1:#map[0-9]+]] = affine_map<(d0, d1)[s0, s1] -> (d1 * s1 + s1, d0 + s0 + 4)>
 // CHECK-DAG: [[UBI0:#map[0-9]+]] = affine_map<(d0, d1)[s0, s1] -> (d1 * s1 + s1, d0 + s0 + 2)>
 // CHECK-DAG: [[UBO1:#map[0-9]+]] = affine_map<(d0)[s0, s1] -> ((d0 + s0 + 4) ceildiv s1)>
 // CHECK-DAG: [[UBO0:#map[0-9]+]] = affine_map<(d0)[s0, s1] -> ((d0 + s0 + 2) ceildiv s1)>

 // CHECK: func @tile_with_upper_bounds_in_dimensions_and_symbols([[ARG0:%arg[0-9]+]]: index, [[ARG1:%arg[0-9]+]]: index, [[ARG2:%arg[0-9]+]]: index, [[ARG3:%arg[0-9]+]]: index{{.*}}){{.*}}
 // CHECK-NEXT: affine.for [[ARG4:%arg[0-9]+]] = 0 to [[UBO0]]({{.*}}){{.*}}[[ARG0]]
 // CHECK-NEXT:   affine.for [[ARG5:%arg[0-9]+]] = 0 to [[UBO1]]({{.*}}){{.*}}[[ARG1]]
 // CHECK-NEXT:     affine.for {{.*}} = [[LBI0]]([[ARG4]]){{.*}}[[ARG0]]{{.*}} to min [[UBI0]]({{.*}}, [[ARG4]]){{.*}}[[ARG0]]{{.*}}
 // CHECK-NEXT:       affine.for {{.*}} = [[LBI0]]([[ARG5]]){{.*}}[[ARG1]]{{.*}} to min [[UBI1]]({{.*}}, [[ARG5]]){{.*}}[[ARG1]]{{.*}}
 func @tile_with_upper_bounds_in_dimensions_and_symbols(%t12 : index, %t13 :index, %M: index, %N:  index, %K: index) {
   affine.for %i = 0 to affine_map<(d0)[s0] -> (d0 + s0 + 2)>(%M)[%K] {
     affine.for %j = 0 to affine_map<(d0)[s0] -> (d0 + s0 + 4)>(%N)[%K] {
       "test.foo" () : () -> ()
     }
   }
   return
 }

 // -----

 // CHECK-DAG: [[LBI0:#map[0-9]+]] = affine_map<(d0)[s0] -> (d0 * s0)>
 // CHECK-DAG: [[UBI1:#map[0-9]+]] = affine_map<(d0, d1)[s0, s1] -> (d1 * s1 + s1 * 4, d0 + s0 + 4)>
 // CHECK-DAG: [[UBI0:#map[0-9]+]] = affine_map<(d0, d1)[s0, s1] -> (d1 * s1 + s1 * 2, d0 + s0 + 2)>
 // CHECK-DAG: [[UBO1:#map[0-9]+]] = affine_map<(d0)[s0, s1] -> ((d0 + s0 + 4) ceildiv s1)>
 // CHECK-DAG: [[UBO0:#map[0-9]+]] = affine_map<(d0)[s0, s1] -> ((d0 + s0 + 2) ceildiv s1)>

 // CHECK: func @tile_with_upper_bounds_in_dimensions_and_symbols_non_unit_steps
 // CHECK-SAME: ([[ARG0:%arg[0-9]+]]: index, [[ARG1:%arg[0-9]+]]: index, [[ARG2:%arg[0-9]+]]: index, [[ARG3:%arg[0-9]+]]: index{{.*}}){{.*}}
 // CHECK-NEXT: affine.for [[ARG4:%arg[0-9]+]] = 0 to [[UBO0]]({{.*}}){{.*}}[[ARG0]]{{.*}} step 2{{.*}}
 // CHECK-NEXT:   affine.for [[ARG5:%arg[0-9]+]] = 0 to [[UBO1]]({{.*}}){{.*}}[[ARG1]]{{.*}} step 4{{.*}}
 // CHECK-NEXT:     affine.for {{.*}} = [[LBI0]]([[ARG4]]){{.*}}[[ARG0]]{{.*}} to min [[UBI0]]({{.*}}, [[ARG4]]){{.*}}[[ARG0]]{{.*}} step 2{{.*}}
 // CHECK-NEXT:       affine.for {{.*}} = [[LBI0]]([[ARG5]]){{.*}}[[ARG1]]{{.*}} to min [[UBI1]]({{.*}}, [[ARG5]]){{.*}}[[ARG1]]{{.*}} step 4{{.*}}
 func @tile_with_upper_bounds_in_dimensions_and_symbols_non_unit_steps(%t12 : index, %t13 :index, %M: index, %N :  index, %K: index) {
   affine.for %i = 0 to affine_map<(d0)[s0] -> (d0 + s0 + 2)>(%M)[%K] step 2 {
     affine.for %j = 0 to affine_map<(d0)[s0] -> (d0 + s0 + 4)>(%N)[%K] step 4 {
       "test.foo" () : () -> ()
     }
   }
   return
 }
	// RUN: mlir-opt %s -split-input-file -test-affine-parametric-tile \| FileCheck %s
	// Test cases to test the utility introduced to tile affine for loops using
	// SSA values as tiling parameters(tile sizes). The tile sizes are expected
	// to be passed as input arguments(before any other argument) to the function
	// enclosing the loop nest. Currently hyper-rectangular loop nests with constant
	// lower bounds are supported.

	// -----

	// CHECK-DAG: [[LBI:#map[0-9]+]] = affine_map<(d0)[s0] -> (d0 * s0)>
	// CHECK-DAG: [[UBI0:#map[0-9]+]] = affine_map<(d0)[s0] -> (d0 * s0 + s0, 256)>
	// CHECK-DAG: [[UBI1:#map[0-9]+]] = affine_map<(d0)[s0] -> (d0 * s0 + s0, 512)>
	// CHECK-DAG: [[UBI2:#map[0-9]+]] = affine_map<(d0)[s0] -> (d0 * s0 + s0, 1024)>
	// CHECK-DAG: [[UBO0:#map[0-9]+]] = affine_map<()[s0] -> (256 ceildiv s0)>
	// CHECK-DAG: [[UBO1:#map[0-9]+]] = affine_map<()[s0] -> (512 ceildiv s0)>
	// CHECK-DAG: [[UBO2:#map[0-9]+]] = affine_map<()[s0] -> (1024 ceildiv s0)>

	// CHECK: func @loop_tiling_3d([[ARG0:%arg[0-9]+]]: index, [[ARG1:%arg[0-9]+]]: index, [[ARG2:%arg[0-9]+]]: index)
	// CHECK-NEXT: affine.for [[ARG3:%arg[0-9]+]] = 0 to [[UBO0]](){{.*}}[[ARG0]]
	// CHECK-NEXT: affine.for [[ARG4:%arg[0-9]+]] = 0 to [[UBO1]](){{.*}}[[ARG1]]
	// CHECK-NEXT: affine.for [[ARG5:%arg[0-9]+]] = 0 to [[UBO2]](){{.*}}[[ARG2]]
	// CHECK-NEXT: affine.for %[[I:.]] = [[LBI]]{{.}}[[ARG3]]{{.}}[[ARG0]]{{.}} to min [[UBI0]]{{.}}[[ARG3]]{{.}}[[ARG0]]
	// CHECK-NEXT: affine.for %[[J:.]] = [[LBI]]{{.}}[[ARG4]]{{.}}[[ARG1]]{{.}} to min [[UBI1]]{{.}}[[ARG4]]{{.}}[[ARG1]]
	// CHECK-NEXT: affine.for %[[K:.]] = [[LBI]]{{.}}[[ARG5]]{{.}}[[ARG2]]{{.}} to min [[UBI2]]{{.}}[[ARG5]]{{.}}[[ARG2]]
	// CHECK-NEXT: "test.foo"(%[[I]], %[[J]], %[[K]])
	func @loop_tiling_3d(%t0 : index, %t1 : index, %t2 : index) {
	affine.for %i = 0 to 256 {
	affine.for %j = 0 to 512 {
	affine.for %k = 0 to 1024 {
	"test.foo"(%i, %j, %k) : (index, index, index) -> ()
	}
	}
	}
	return
	}

	// -----

	// CHECK-DAG: [[LBI:#map[0-9]+]] = affine_map<(d0)[s0] -> (d0 * s0)>
	// CHECK-DAG: [[UBI0:#map[0-9]+]] = affine_map<(d0)[s0] -> (d0 * s0 + s0 * 4, 256)>
	// CHECK-DAG: [[UBI1:#map[0-9]+]] = affine_map<(d0)[s0] -> (d0 * s0 + s0 * 3, 512)>
	// CHECK-DAG: [[UBI2:#map[0-9]+]] = affine_map<(d0)[s0] -> (d0 * s0 + s0 * 2, 1024)>
	// CHECK-DAG: [[UBO0:#map[0-9]+]] = affine_map<()[s0] -> (256 ceildiv s0)>
	// CHECK-DAG: [[UBO1:#map[0-9]+]] = affine_map<()[s0] -> (512 ceildiv s0)>
	// CHECK-DAG: [[UBO2:#map[0-9]+]] = affine_map<()[s0] -> (1024 ceildiv s0)>

	// CHECK: func @loop_tiling_non_unit_step([[ARG0:%arg[0-9]+]]: index, [[ARG1:%arg[0-9]+]]: index, [[ARG2:%arg[0-9]+]]: index)
	// CHECK-NEXT: affine.for [[ARG3:%arg[0-9]+]] = 0 to [[UBO0]](){{.}}[[ARG0]]{{.}}step 4
	// CHECK-NEXT: affine.for [[ARG4:%arg[0-9]+]] = 0 to [[UBO1]](){{.}}[[ARG1]]{{.}} step 3
	// CHECK-NEXT: affine.for [[ARG5:%arg[0-9]+]] = 0 to [[UBO2]](){{.}}[[ARG2]]{{.}} step 2
	// CHECK-NEXT: affine.for %[[I:.]] = [[LBI]]{{.}}[[ARG3]]{{.}}[[ARG0]]{{.}} to min [[UBI0]]{{.}}[[ARG3]]{{.}}[[ARG0]]{{.*}} step 4
	// CHECK-NEXT: affine.for %[[J:.]] = [[LBI]]{{.}}[[ARG4]]{{.}}[[ARG1]]{{.}} to min [[UBI1]]{{.}}[[ARG4]]{{.}}[[ARG1]]{{.*}} step 3
	// CHECK-NEXT: affine.for %[[K:.]] = [[LBI]]{{.}}[[ARG5]]{{.}}[[ARG2]]{{.}} to min [[UBI2]]{{.}}[[ARG5]]{{.}}[[ARG2]]{{.*}} step 2
	// CHECK-NEXT: "test.foo"(%[[I]], %[[J]], %[[K]])
	func @loop_tiling_non_unit_step(%t0: index, %t1: index, %t2: index){
	affine.for %i = 0 to 256 step 4 {
	affine.for %j = 0 to 512 step 3 {
	affine.for %k = 0 to 1024 step 2 {
	"test.foo"(%i, %j, %k) : (index, index, index) -> ()
	}
	}
	}
	return
	}

	// -----

	// CHECK-DAG: [[LBI0:#map[0-9]+]] = affine_map<(d0)[s0] -> (d0 * s0)>
	// CHECK-DAG: [[UBI0:#map[0-9]+]] = affine_map<(d0)[s0, s1, s2] -> (d0 * s2 + s2, s0, 4096 floordiv s1)>
	// CHECK-DAG: [[UBO0:#map[0-9]+]] = affine_map<()[s0, s1, s2] -> (s0 ceildiv s2, (4096 floordiv s1) ceildiv s2)>

	// CHECK: func @tile_loop_with_div_in_upper_bound([[ARG0:%arg[0-9]+]]: index, %{{.}}: memref<?xi32>, %{{.}}: index, %{{.*}}: index)
	#ub = affine_map<()[s0, s1] -> (s0, 4096 floordiv s1)>
	func @tile_loop_with_div_in_upper_bound(%t5 : index, %A : memref<? x i32>, %L : index, %U : index) {
	%c0 = arith.constant 0 : index
	%M = memref.dim %A, %c0 : memref<? x i32>
	affine.for %i = 0 to min #ub()[%M, %U] {
	arith.addi %i, %i : index
	}
	// CHECK: affine.for [[ARG1:%arg[0-9]+]] = 0 to min [[UBO0]]()[%{{.}}, %{{.}}, [[ARG0]]]
	// CHECK-NEXT: affine.for %[[I:.]] = [[LBI0]]([[ARG1]]){{.}}[[ARG0]]{{.}} to min [[UBI0]]({{.}})[{{.}}, {{.}}, [[ARG0]]]
	// CHECK-NEXT: arith.addi %[[I]], %[[I]]
	return
	}

	// -----

	// CHECK-DAG: [[LBI0:#map[0-9]+]] = affine_map<(d0)[s0] -> (d0 * s0)>
	// CHECK-DAG: [[UBI0:#map[0-9]+]] = affine_map<(d0)[s0, s1, s2] -> (d0 * s2 + s2 * 4, s0, 4096 floordiv s1)>
	// CHECK-DAG: [[UBO0:#map[0-9]+]] = affine_map<()[s0, s1, s2] -> (s0 ceildiv s2, (4096 floordiv s1) ceildiv s2)>

	// CHECK: func @tile_loop_with_div_in_upper_bound_non_unit_step([[ARG0:%arg[0-9]+]]: index, %{{.}}: memref<?xi32>, %{{.}}: index, %{{.*}}: index)
	#ub = affine_map<()[s0, s1] -> (s0, 4096 floordiv s1)>
	func @tile_loop_with_div_in_upper_bound_non_unit_step(%t5 : index, %A : memref<? x i32>, %L : index, %U : index) {
	%c0 = arith.constant 0 : index
	%M = memref.dim %A, %c0 : memref<? x i32>
	affine.for %i = 0 to min #ub()[%M, %U] step 4 {
	arith.addi %i, %i : index
	}
	// CHECK: affine.for [[ARG1:%arg[0-9]+]] = 0 to min [[UBO0]]()[%{{.}}, %{{.}}, [[ARG0]]]{{.}} step 4{{.}}
	// CHECK-NEXT: affine.for %[[I:.]] = [[LBI0]]([[ARG1]]){{.}}[[ARG0]]{{.}} to min [[UBI0]]({{.}})[{{.}}, {{.}}, [[ARG0]]]{{.}} step 4{{.}}
	// CHECK-NEXT: arith.addi %[[I]], %[[I]]
	return
	}

	// -----

	// CHECK-DAG: [[LBI0:#map[0-9]+]] = affine_map<(d0)[s0] -> ((d0 - 8) * s0 + 8)>
	// CHECK-DAG: [[UBI2:#map[0-9]+]] = affine_map<(d0)[s0, s1] -> ((d0 - 8) * s1 + s1 * 4 + 8, s0 + 16)>
	// CHECK-DAG: [[UBI1:#map[0-9]+]] = affine_map<(d0)[s0, s1] -> ((d0 - 8) * s1 + s1 + 8, s0 + 16)>
	// CHECK-DAG: [[UBI0:#map[0-9]+]] = affine_map<(d0)[s0] -> ((d0 - 8) * s0 + s0 + 8, 256)>
	// CHECK-DAG: [[UBO1:#map[0-9]+]] = affine_map<()[s0, s1] -> ((s0 + 8) ceildiv s1 + 8)>
	// CHECK-DAG: [[UBO0:#map[0-9]+]] = affine_map<()[s0] -> (248 ceildiv s0 + 8)>

	// CHECK: func @tile_loop_with_non_zero_lb([[ARG0:%arg[0-9]+]]: index, [[ARG1:%arg[0-9]+]]: index, [[ARG2:%arg[0-9]+]]: index, %{{.*}}: index)
	// CHECK-NEXT: affine.for [[ARG3:%arg[0-9+]]] = 8 to [[UBO0]]{{.}}[[ARG0]]{{.}}
	// CHECK-NEXT: affine.for [[ARG4:%arg[0-9+]]] = 8 to [[UBO1]]{{.}}[[ARG1]]{{.}}
	// CHECK-NEXT: affine.for [[ARG5:%arg[0-9+]]] = 8 to [[UBO1]]{{.}}[[ARG2]]{{.}} step 4
	// CHECK-NEXT: affine.for %[[I:.]] = [[LBI0]]([[ARG3]]){{.}}[[ARG0]]{{.}} to min [[UBI0]]([[ARG3]]){{.}}[[ARG0]]{{.*}}
	// CHECK-NEXT: affine.for %[[J:.]] = [[LBI0]]([[ARG4]]){{.}}[[ARG1]]{{.}} to min [[UBI1]]([[ARG4]]){{.}}[[ARG1]]{{.*}}
	// CHECK-NEXT: affine.for %[[K:.]] = [[LBI0]]([[ARG5]]){{.}}[[ARG2]]{{.}} to min [[UBI2]]([[ARG5]]){{.}}[[ARG2]]{{.}}step 4{{.}}
	// CHECK-NEXT: "test.foo"(%[[I]], %[[J]], %[[K]]) : (index, index, index) -> ()
	#ubi = affine_map<()[s0] -> (s0 + 16)>
	func @tile_loop_with_non_zero_lb(%t0: index, %t1: index, %t2: index, %U: index){
	affine.for %i = 8 to 256 {
	affine.for %j = 8 to #ubi()[%U] {
	affine.for %k = 8 to #ubi()[%U] step 4 {
	"test.foo"(%i, %j, %k) : (index, index, index) -> ()
	}
	}
	}
	return
	}

	// -----

	// CHECK-DAG: [[LBI:#map[0-9]+]] = affine_map<(d0)[s0] -> (d0 * s0)>
	// CHECK-DAG: [[UBI0:#map[0-9]+]] = affine_map<(d0)[s0] -> (d0 * s0 + s0, 256)>
	// CHECK-DAG: [[UBI1:#map[0-9]+]] = affine_map<(d0)[s0] -> (d0 * s0 + s0, 250)>
	// CHECK-DAG: [[UBO0:#map[0-9]+]] = affine_map<()[s0] -> (256 ceildiv s0)>
	// CHECK-DAG: [[UBO1:#map[0-9]+]] = affine_map<()[s0] -> (250 ceildiv s0)>

	// CHECK: func @simple_matmul([[ARG0:%arg[0-9]+]]: index, [[ARG1:%arg[0-9]+]]: index, [[ARG2:%arg[0-9]+]]: index{{.*}})
	// CHECK-NEXT: affine.for [[ARG3:%arg[0-9]+]] = 0 to [[UBO0]](){{.}}[[ARG0]]{{.}}
	// CHECK-NEXT: affine.for [[ARG4:%arg[0-9]+]] = 0 to [[UBO0]](){{.}}[[ARG1]]{{.}}
	// CHECK-NEXT: affine.for [[ARG5:%arg[0-9]+]] = 0 to [[UBO1]](){{.}}[[ARG2]]{{.}}
	// CHECK-NEXT: affine.for %[[I:.]] = [[LBI]]{{.}}[[ARG3]]{{.}}[[ARG0]]{{.}} to min [[UBI0]]{{.}}[[ARG3]]{{.}}[[ARG0]]{{.*}}
	// CHECK-NEXT: affine.for %[[J:.]] = [[LBI]]{{.}}[[ARG4]]{{.}}[[ARG1]]{{.}} to min [[UBI0]]{{.}}[[ARG4]]{{.}}[[ARG1]]{{.*}}
	// CHECK-NEXT: affine.for %[[K:.]] = [[LBI]]{{.}}[[ARG5]]{{.}}[[ARG2]]{{.}} to min [[UBI1]]{{.}}[[ARG5]]{{.}}[[ARG2]]{{.*}}
	// CHECK-NEXT: affine.load %{{.*}}[%[[I]], %[[K]]]
	// CHECK-NEXT: affine.load %{{.*}}[%[[K]], %[[J]]]
	// CHECK-NEXT: affine.load %{{.*}}[%[[I]], %[[J]]]
	// CHECK-NEXT: arith.mulf %{{.*}}
	// CHECK-NEXT: arith.addf %{{.*}}
	// CHECK-NEXT: affine.store %{{.*}}[%[[I]], %[[J]]]
	func @simple_matmul(%t6 : index, %t7 : index, %t8 : index, %arg0: memref<256x256xvector<64xf32>>, %arg1: memref<256x256xvector<64xf32>>, %arg2: memref<256x256xvector<64xf32>>) -> memref<256x256xvector<64xf32>> {
	affine.for %i = 0 to 256 {
	affine.for %j = 0 to 256 {
	affine.for %k = 0 to 250 {
	%l = affine.load %arg0[%i, %k] : memref<256x256xvector<64xf32>>
	%r = affine.load %arg1[%k, %j] : memref<256x256xvector<64xf32>>
	%o = affine.load %arg2[%i, %j] : memref<256x256xvector<64xf32>>
	%m = arith.mulf %l, %r : vector<64xf32>
	%a = arith.addf %o, %m : vector<64xf32>
	affine.store %a, %arg2[%i, %j] : memref<256x256xvector<64xf32>>
	}
	}
	}
	return %arg2 : memref<256x256xvector<64xf32>>
	}

	// -----

	// CHECK-DAG: [[LBI0:#map[0-9]+]] = affine_map<(d0)[s0] -> (d0 * s0)>
	// CHECK-DAG: [[UBI0:#map[0-9]+]] = affine_map<(d0)[s0, s1] -> (d0 * s1 + s1, s0)>
	// CHECK-DAG: [[UBO0:#map[0-9]+]] = affine_map<()[s0, s1] -> (s0 ceildiv s1)>

	// CHECK: func @tile_with_symbolic_loop_upper_bounds([[ARG0:%arg[0-9]+]]: index, [[ARG1:%arg[0-9]+]]: index{{.}}){{.}}
	// CHECK: affine.for [[ARG2:%arg[0-9]+]] = 0 to [[UBO0]](){{.}}[[ARG0]]{{.}}
	// CHECK-NEXT: affine.for [[ARG3:%arg[0-9]+]] = 0 to [[UBO0]](){{.}}[[ARG1]]{{.}}
	// CHECK-NEXT: affine.for %[[I0:.]] = [[LBI0]]{{.}}[[ARG2]]{{.}}[[ARG0]]{{.}} to min [[UBI0]]{{.}}[[ARG2]]{{.}}[[ARG0]]{{.*}}
	// CHECK-NEXT: affine.for %[[I1:.]] = [[LBI0]]{{.}}[[ARG3]]{{.}}[[ARG1]]{{.}} to min [[UBI0]]{{.}}[[ARG3]]{{.}}[[ARG1]]{{.*}}
	// CHECK-NEXT: affine.store %{{.}}, %{{.}}[%[[I0]], %[[I1]]] : memref<?x?xf32>
	// CHECK-NEXT: affine.for %[[I2:.]] = 0 to %{{.}} {
	// CHECK-NEXT: affine.load %{{.*}}%[[I0]], %[[I2]]
	// CHECK-NEXT: affine.load %{{.*}}%[[I2]], %[[I1]]
	// CHECK-NEXT: arith.mulf
	// CHECK-NEXT: affine.load %{{.*}}%[[I0]], %[[I1]]
	// CHECK-NEXT: arith.addf
	// CHECK-NEXT: affine.store %{{.*}}%[[I0]], %[[I1]]
	func @tile_with_symbolic_loop_upper_bounds(%t9 : index, %t10: index, %arg0: memref<?x?xf32>, %arg1: memref<?x?xf32>, %arg2: memref<?x?xf32>) {
	%cst = arith.constant 0.000000e+00 : f32
	%c0 = arith.constant 0 : index
	%0 = memref.dim %arg0, %c0 : memref<?x?xf32>
	affine.for %i0 = 0 to %0 {
	affine.for %i1 = 0 to %0 {
	affine.store %cst, %arg2[%i0, %i1] : memref<?x?xf32>
	affine.for %i2 = 0 to %0 {
	%1 = affine.load %arg0[%i0, %i2] : memref<?x?xf32>
	%2 = affine.load %arg1[%i2, %i1] : memref<?x?xf32>
	%3 = arith.mulf %1, %2 : f32
	%4 = affine.load %arg2[%i0, %i1] : memref<?x?xf32>
	%5 = arith.addf %4, %3 : f32
	affine.store %5, %arg2[%i0, %i1] : memref<?x?xf32>
	}
	}
	}
	return
	}

	// -----

	// CHECK-DAG: [[LBI0:#map[0-9]+]] = affine_map<(d0)[s0] -> (d0 * s0)>
	// CHECK-DAG: [[UBI0:#map[0-9]+]] = affine_map<(d0)[s0, s1, s2] -> (d0 * s2 + s2, s0 + s1)>
	// CHECK-DAG: [[UBO0:#map[0-9]+]] = affine_map<()[s0, s1, s2] -> ((s0 + s1) ceildiv s2)>

	// CHECK: func @tile_with_loop_upper_bounds_in_two_symbols([[ARG0:%arg[0-9]+]]: index{{.}}){{.}}
	func @tile_with_loop_upper_bounds_in_two_symbols(%t11 : index, %arg0: memref<?xf32>, %limit: index) {
	%c0 = arith.constant 0 : index
	%dim0 = memref.dim %arg0, %c0 : memref<?xf32>
	affine.for %i0 = 0 to affine_map<()[s0, s1] -> (s0 + s1)> ()[%dim0, %limit] {
	%v0 = affine.load %arg0[%i0] : memref<?xf32>
	}
	// CHECK: affine.for [[ARG1:%arg[0-9]+]] = 0 to [[UBO0]]()[%{{.}}, %{{.}}, [[ARG0]]]
	// CHECK-NEXT: affine.for %[[I:.]] = [[LBI0]]([[ARG1]]){{.}}[[ARG0]]{{.}} to min [[UBI0]]([[ARG1]])[{{.}}, {{.*}}, [[ARG0]]]
	// CHECK-NEXT: affine.load %{{.*}}[%[[I]]]
	return
	}

	// -----

	// CHECK-DAG: [[LBI0:#map[0-9]+]] = affine_map<(d0)[s0] -> (d0 * s0)>
	// CHECK-DAG: [[UBI1:#map[0-9]+]] = affine_map<(d0, d1)[s0, s1] -> (d1 * s1 + s1, d0 + s0 + 4)>
	// CHECK-DAG: [[UBI0:#map[0-9]+]] = affine_map<(d0, d1)[s0, s1] -> (d1 * s1 + s1, d0 + s0 + 2)>
	// CHECK-DAG: [[UBO1:#map[0-9]+]] = affine_map<(d0)[s0, s1] -> ((d0 + s0 + 4) ceildiv s1)>
	// CHECK-DAG: [[UBO0:#map[0-9]+]] = affine_map<(d0)[s0, s1] -> ((d0 + s0 + 2) ceildiv s1)>

	// CHECK: func @tile_with_upper_bounds_in_dimensions_and_symbols([[ARG0:%arg[0-9]+]]: index, [[ARG1:%arg[0-9]+]]: index, [[ARG2:%arg[0-9]+]]: index, [[ARG3:%arg[0-9]+]]: index{{.}}){{.}}
	// CHECK-NEXT: affine.for [[ARG4:%arg[0-9]+]] = 0 to [[UBO0]]({{.}}){{.}}[[ARG0]]
	// CHECK-NEXT: affine.for [[ARG5:%arg[0-9]+]] = 0 to [[UBO1]]({{.}}){{.}}[[ARG1]]
	// CHECK-NEXT: affine.for {{.}} = [[LBI0]]([[ARG4]]){{.}}[[ARG0]]{{.}} to min [[UBI0]]({{.}}, [[ARG4]]){{.}}[[ARG0]]{{.}}
	// CHECK-NEXT: affine.for {{.}} = [[LBI0]]([[ARG5]]){{.}}[[ARG1]]{{.}} to min [[UBI1]]({{.}}, [[ARG5]]){{.}}[[ARG1]]{{.}}
	func @tile_with_upper_bounds_in_dimensions_and_symbols(%t12 : index, %t13 :index, %M: index, %N: index, %K: index) {
	affine.for %i = 0 to affine_map<(d0)[s0] -> (d0 + s0 + 2)>(%M)[%K] {
	affine.for %j = 0 to affine_map<(d0)[s0] -> (d0 + s0 + 4)>(%N)[%K] {
	"test.foo" () : () -> ()
	}
	}
	return
	}

	// -----

	// CHECK-DAG: [[LBI0:#map[0-9]+]] = affine_map<(d0)[s0] -> (d0 * s0)>
	// CHECK-DAG: [[UBI1:#map[0-9]+]] = affine_map<(d0, d1)[s0, s1] -> (d1 * s1 + s1 * 4, d0 + s0 + 4)>
	// CHECK-DAG: [[UBI0:#map[0-9]+]] = affine_map<(d0, d1)[s0, s1] -> (d1 * s1 + s1 * 2, d0 + s0 + 2)>
	// CHECK-DAG: [[UBO1:#map[0-9]+]] = affine_map<(d0)[s0, s1] -> ((d0 + s0 + 4) ceildiv s1)>
	// CHECK-DAG: [[UBO0:#map[0-9]+]] = affine_map<(d0)[s0, s1] -> ((d0 + s0 + 2) ceildiv s1)>

	// CHECK: func @tile_with_upper_bounds_in_dimensions_and_symbols_non_unit_steps
	// CHECK-SAME: ([[ARG0:%arg[0-9]+]]: index, [[ARG1:%arg[0-9]+]]: index, [[ARG2:%arg[0-9]+]]: index, [[ARG3:%arg[0-9]+]]: index{{.}}){{.}}
	// CHECK-NEXT: affine.for [[ARG4:%arg[0-9]+]] = 0 to [[UBO0]]({{.}}){{.}}[[ARG0]]{{.}} step 2{{.}}
	// CHECK-NEXT: affine.for [[ARG5:%arg[0-9]+]] = 0 to [[UBO1]]({{.}}){{.}}[[ARG1]]{{.}} step 4{{.}}
	// CHECK-NEXT: affine.for {{.}} = [[LBI0]]([[ARG4]]){{.}}[[ARG0]]{{.}} to min [[UBI0]]({{.}}, [[ARG4]]){{.}}[[ARG0]]{{.}} step 2{{.*}}
	// CHECK-NEXT: affine.for {{.}} = [[LBI0]]([[ARG5]]){{.}}[[ARG1]]{{.}} to min [[UBI1]]({{.}}, [[ARG5]]){{.}}[[ARG1]]{{.}} step 4{{.*}}
	func @tile_with_upper_bounds_in_dimensions_and_symbols_non_unit_steps(%t12 : index, %t13 :index, %M: index, %N : index, %K: index) {
	affine.for %i = 0 to affine_map<(d0)[s0] -> (d0 + s0 + 2)>(%M)[%K] step 2 {
	affine.for %j = 0 to affine_map<(d0)[s0] -> (d0 + s0 + 4)>(%N)[%K] step 4 {
	"test.foo" () : () -> ()
	}
	}
	return
	}