mlir/test/Transforms/loop-coalescing.mlir - llvm-project - Git at Google

 // RUN: mlir-opt -split-input-file -allow-unregistered-dialect -loop-coalescing %s | FileCheck %s

 // CHECK-LABEL: @one_3d_nest
 func @one_3d_nest() {
   // Capture original bounds.  Note that for zero-based step-one loops, the
   // upper bound is also the number of iterations.
   // CHECK: %[[orig_lb:.*]] = arith.constant 0
   // CHECK: %[[orig_step:.*]] = arith.constant 1
   // CHECK: %[[orig_ub_k:.*]] = arith.constant 3
   // CHECK: %[[orig_ub_i:.*]] = arith.constant 42
   // CHECK: %[[orig_ub_j:.*]] = arith.constant 56
   %c0 = arith.constant 0 : index
   %c1 = arith.constant 1 : index
   %c2 = arith.constant 2 : index
   %c3 = arith.constant 3 : index
   %c42 = arith.constant 42 : index
   %c56 = arith.constant 56 : index
   // The range of the new scf.
   // CHECK:     %[[partial_range:.*]] = arith.muli %[[orig_ub_i]], %[[orig_ub_j]]
   // CHECK-NEXT:%[[range:.*]] = arith.muli %[[partial_range]], %[[orig_ub_k]]

   // Updated loop bounds.
   // CHECK: scf.for %[[i:.*]] = %[[orig_lb]] to %[[range]] step %[[orig_step]]
   scf.for %i = %c0 to %c42 step %c1 {
     // Inner loops must have been removed.
     // CHECK-NOT: scf.for

     // Reconstruct original IVs from the linearized one.
     // CHECK: %[[orig_k:.*]] = arith.remsi %[[i]], %[[orig_ub_k]]
     // CHECK: %[[div:.*]] = arith.divsi %[[i]], %[[orig_ub_k]]
     // CHECK: %[[orig_j:.*]] = arith.remsi %[[div]], %[[orig_ub_j]]
     // CHECK: %[[orig_i:.*]] = arith.divsi %[[div]], %[[orig_ub_j]]
     scf.for %j = %c0 to %c56 step %c1 {
       scf.for %k = %c0 to %c3 step %c1 {
         // CHECK: "use"(%[[orig_i]], %[[orig_j]], %[[orig_k]])
         "use"(%i, %j, %k) : (index, index, index) -> ()
       }
     }
   }
   return
 }

 // Check that there is no chasing the replacement of value uses by ensuring
 // multiple uses of loop induction variables get rewritten to the same values.

 // CHECK-LABEL: @multi_use
 func @multi_use() {
   %c0 = arith.constant 0 : index
   %c1 = arith.constant 1 : index
   %c10 = arith.constant 10 : index
   // CHECK: scf.for %[[iv:.*]] =
   scf.for %i = %c1 to %c10 step %c1 {
     scf.for %j = %c1 to %c10 step %c1 {
       scf.for %k = %c1 to %c10 step %c1 {
         // CHECK: %[[k_unshifted:.*]] = arith.remsi %[[iv]], %[[k_extent:.*]]
         // CHECK: %[[ij:.*]] = arith.divsi %[[iv]], %[[k_extent]]
         // CHECK: %[[j_unshifted:.*]] = arith.remsi %[[ij]], %[[j_extent:.*]]
         // CHECK: %[[i_unshifted:.*]] = arith.divsi %[[ij]], %[[j_extent]]
         // CHECK: %[[k:.*]] = arith.addi %[[k_unshifted]]
         // CHECK: %[[j:.*]] = arith.addi %[[j_unshifted]]
         // CHECK: %[[i:.*]] = arith.addi %[[i_unshifted]]

         // CHECK: "use1"(%[[i]], %[[j]], %[[k]])
         "use1"(%i,%j,%k) : (index,index,index) -> ()
         // CHECK: "use2"(%[[i]], %[[k]], %[[j]])
         "use2"(%i,%k,%j) : (index,index,index) -> ()
         // CHECK: "use3"(%[[k]], %[[j]], %[[i]])
         "use3"(%k,%j,%i) : (index,index,index) -> ()
       }
     }
   }
   return
 }

 func @unnormalized_loops() {
   // CHECK: %[[orig_step_i:.*]] = arith.constant 2
   // CHECK: %[[orig_step_j:.*]] = arith.constant 3
   // CHECK: %[[orig_lb_i:.*]] = arith.constant 5
   // CHECK: %[[orig_lb_j:.*]] = arith.constant 7
   // CHECK: %[[orig_ub_i:.*]] = arith.constant 10
   // CHECK: %[[orig_ub_j:.*]] = arith.constant 17
   %c2 = arith.constant 2 : index
   %c3 = arith.constant 3 : index
   %c5 = arith.constant 5 : index
   %c7 = arith.constant 7 : index
   %c10 = arith.constant 10 : index
   %c17 = arith.constant 17 : index

   // Number of iterations in the outer scf.
   // CHECK: %[[diff_i:.*]] = arith.subi %[[orig_ub_i]], %[[orig_lb_i]]
   // CHECK: %[[c1:.*]] = arith.constant 1
   // CHECK: %[[step_minus_c1:.*]] = arith.subi %[[orig_step_i]], %[[c1]]
   // CHECK: %[[dividend:.*]] = arith.addi %[[diff_i]], %[[step_minus_c1]]
   // CHECK: %[[numiter_i:.*]] = arith.divsi %[[dividend]], %[[orig_step_i]]

   // Normalized lower bound and step for the outer scf.
   // CHECK: %[[lb_i:.*]] = arith.constant 0
   // CHECK: %[[step_i:.*]] = arith.constant 1

   // Number of iterations in the inner loop, the pattern is the same as above,
   // only capture the final result.
   // CHECK: %[[numiter_j:.*]] = arith.divsi {{.*}}, %[[orig_step_j]]

   // New bounds of the outer scf.
   // CHECK: %[[range:.*]] = arith.muli %[[numiter_i]], %[[numiter_j]]
   // CHECK: scf.for %[[i:.*]] = %[[lb_i]] to %[[range]] step %[[step_i]]
   scf.for %i = %c5 to %c10 step %c2 {
     // The inner loop has been removed.
     // CHECK-NOT: scf.for
     scf.for %j = %c7 to %c17 step %c3 {
       // The IVs are rewritten.
       // CHECK: %[[normalized_j:.*]] = arith.remsi %[[i]], %[[numiter_j]]
       // CHECK: %[[normalized_i:.*]] = arith.divsi %[[i]], %[[numiter_j]]
       // CHECK: %[[scaled_j:.*]] = arith.muli %[[normalized_j]], %[[orig_step_j]]
       // CHECK: %[[orig_j:.*]] = arith.addi %[[scaled_j]], %[[orig_lb_j]]
       // CHECK: %[[scaled_i:.*]] = arith.muli %[[normalized_i]], %[[orig_step_i]]
       // CHECK: %[[orig_i:.*]] = arith.addi %[[scaled_i]], %[[orig_lb_i]]
       // CHECK: "use"(%[[orig_i]], %[[orig_j]])
       "use"(%i, %j) : (index, index) -> ()
     }
   }
   return
 }

 // Check with parametric loop bounds and steps, capture the bounds here.
 // CHECK-LABEL: @parametric
 // CHECK-SAME: %[[orig_lb1:[A-Za-z0-9]+]]:
 // CHECK-SAME: %[[orig_ub1:[A-Za-z0-9]+]]:
 // CHECK-SAME: %[[orig_step1:[A-Za-z0-9]+]]:
 // CHECK-SAME: %[[orig_lb2:[A-Za-z0-9]+]]:
 // CHECK-SAME: %[[orig_ub2:[A-Za-z0-9]+]]:
 // CHECK-SAME: %[[orig_step2:[A-Za-z0-9]+]]:
 func @parametric(%lb1 : index, %ub1 : index, %step1 : index,
                  %lb2 : index, %ub2 : index, %step2 : index) {
   // Compute the number of iterations for each of the loops and the total
   // number of iterations.
   // CHECK: %[[range1:.*]] = arith.subi %[[orig_ub1]], %[[orig_lb1]]
   // CHECK: %[[orig_step1_minus_1:.*]] = arith.subi %[[orig_step1]], %c1
   // CHECK: %[[dividend1:.*]] = arith.addi %[[range1]], %[[orig_step1_minus_1]]
   // CHECK: %[[numiter1:.*]] = arith.divsi %[[dividend1]], %[[orig_step1]]
   // CHECK: %[[range2:.*]] = arith.subi %[[orig_ub2]], %[[orig_lb2]]
   // CHECK: %[[orig_step2_minus_1:.*]] = arith.subi %arg5, %c1
   // CHECK: %[[dividend2:.*]] = arith.addi %[[range2]], %[[orig_step2_minus_1]]
   // CHECK: %[[numiter2:.*]] = arith.divsi %[[dividend2]], %[[orig_step2]]
   // CHECK: %[[range:.*]] = arith.muli %[[numiter1]], %[[numiter2]] : index

   // Check that the outer loop is updated.
   // CHECK: scf.for %[[i:.*]] = %c0{{.*}} to %[[range]] step %c1
   scf.for %i = %lb1 to %ub1 step %step1 {
     // Check that the inner loop is removed.
     // CHECK-NOT: scf.for
     scf.for %j = %lb2 to %ub2 step %step2 {
       // Remapping of the induction variables.
       // CHECK: %[[normalized_j:.*]] = arith.remsi %[[i]], %[[numiter2]] : index
       // CHECK: %[[normalized_i:.*]] = arith.divsi %[[i]], %[[numiter2]] : index
       // CHECK: %[[scaled_j:.*]] = arith.muli %[[normalized_j]], %[[orig_step2]]
       // CHECK: %[[orig_j:.*]] = arith.addi %[[scaled_j]], %[[orig_lb2]]
       // CHECK: %[[scaled_i:.*]] = arith.muli %[[normalized_i]], %[[orig_step1]]
       // CHECK: %[[orig_i:.*]] = arith.addi %[[scaled_i]], %[[orig_lb1]]

       // CHECK: "foo"(%[[orig_i]], %[[orig_j]])
       "foo"(%i, %j) : (index, index) -> ()
     }
   }
   return
 }

 // CHECK-LABEL: @two_bands
 func @two_bands() {
   %c0 = arith.constant 0 : index
   %c1 = arith.constant 1 : index
   %c10 = arith.constant 10 : index
   // CHECK: %[[outer_range:.*]] = arith.muli
   // CHECK: scf.for %{{.*}} = %{{.*}} to %[[outer_range]]
   scf.for %i = %c0 to %c10 step %c1 {
     // Check that the "j" loop was removed and that the inner loops were
     // coalesced as well.  The preparation step for coalescing will inject the
     // subtraction operation unlike the IV remapping.
     // CHECK-NOT: scf.for
     // CHECK: arith.subi
     scf.for %j = %c0 to %c10 step %c1 {
       // The inner pair of loops is coalesced separately.
       // CHECK: scf.for
       scf.for %k = %i to %j step %c1 {
         // CHECK_NOT: scf.for
         scf.for %l = %i to %j step %c1 {
           "foo"() : () -> ()
         }
       }
     }
   }
   return
 }

 // -----

 // Check coalescing of affine.for loops when all the loops have constant upper bound.
 // CHECK-DAG: #[[SIXTEEN:.*]] = affine_map<() -> (16)>
 // CHECK-DAG: #[[SIXTY_FOUR:.*]] = affine_map<() -> (64)>
 // CHECK-DAG: #[[PRODUCT:.*]] = affine_map<(d0)[s0] -> (d0 * s0)>
 // CHECK-DAG: #[[EIGHT:.*]] = affine_map<() -> (8)>
 // CHECK-DAG: #[[MOD:.*]] = affine_map<(d0)[s0] -> (d0 mod s0)>
 // CHECK-DAG: #[[DIV:.*]] = affine_map<(d0)[s0] -> (d0 floordiv s0)>
 func @coalesce_affine_for() {
   affine.for %i = 0 to 16 {
     affine.for %j = 0 to 64 {
       affine.for %k = 0 to 8 {
         "test.foo"(%i, %j, %k) : (index, index, index) -> ()
       }
     }
   }
   return
 }
 // CHECK-DAG: %[[T0:.*]] = affine.apply #[[SIXTEEN]]()
 // CHECK-DAG: %[[T1:.*]] = affine.apply #[[SIXTY_FOUR]]()
 // CHECK-DAG: %[[T2:.*]] = affine.apply #[[PRODUCT]](%[[T0]])[%[[T1]]]
 // CHECK-DAG: %[[T3:.*]] = affine.apply #[[EIGHT]]()
 // CHECK-DAG: %[[T4:.*]] = affine.apply #[[PRODUCT]](%[[T2]])[%[[T3]]]
 // CHECK:       affine.for %[[IV:.*]] = 0 to %[[T4]]
 // CHECK-DAG:    %[[K:.*]] =  affine.apply #[[MOD]](%[[IV]])[%[[T3]]]
 // CHECK-DAG:    %[[T6:.*]] = affine.apply #[[DIV]](%[[IV]])[%[[T3]]]
 // CHECK-DAG:    %[[J:.*]] =  affine.apply #[[MOD]](%[[T6]])[%[[T1]]]
 // CHECK-DAG:    %[[I:.*]] =  affine.apply #[[DIV]](%[[T6]])[%[[T1]]]
 // CHECK-NEXT:    "test.foo"(%[[I]], %[[J]], %[[K]])
 // CHECK-NEXT:  }
 // CHECK-NEXT:  return

 // -----

 // Check coalescing of affine.for loops when all the loops have non constant upper bounds.
 // CHECK-DAG: #[[IDENTITY:.*]] = affine_map<()[s0] -> (s0)>
 // CHECK-DAG: #[[PRODUCT:.*]] = affine_map<(d0)[s0] -> (d0 * s0)>
 // CHECK-DAG: #[[MOD:.*]] = affine_map<(d0)[s0] -> (d0 mod s0)>
 // CHECK-DAG: #[[FLOOR:.*]] = affine_map<(d0)[s0] -> (d0 floordiv s0)>
 func @coalesce_affine_for(%arg0: memref<?x?xf32>) {
   %c0 = arith.constant 0 : index
   %M = memref.dim %arg0, %c0 : memref<?x?xf32>
   %N = memref.dim %arg0, %c0 : memref<?x?xf32>
   %K = memref.dim %arg0, %c0 : memref<?x?xf32>
   affine.for %i = 0 to %M {
     affine.for %j = 0 to %N {
       affine.for %k = 0 to %K {
       "test.foo"(%i, %j, %k) : (index, index, index) -> ()
       }
     }
   }
   return
 }
 // CHECK: %[[T0:.*]] = memref.dim %arg{{.*}}, %c{{.*}} : memref<?x?xf32>
 // CHECK: %[[T1:.*]] = memref.dim %arg{{.*}}, %c{{.*}} : memref<?x?xf32>
 // CHECK: %[[T2:.*]] = memref.dim %arg{{.*}}, %c{{.*}} : memref<?x?xf32>
 // CHECK-DAG: %[[T3:.*]] = affine.apply #[[IDENTITY]]()[%[[T0]]]
 // CHECK-DAG: %[[T4:.*]] = affine.apply #[[IDENTITY]]()[%[[T1]]]
 // CHECK-DAG: %[[T5:.*]] = affine.apply #[[PRODUCT]](%[[T3]])[%[[T4]]]
 // CHECK-DAG: %[[T6:.*]] = affine.apply #[[IDENTITY]]()[%[[T2]]]
 // CHECK-DAG: %[[T7:.*]] = affine.apply #[[PRODUCT]](%[[T5]])[%[[T6]]]
 // CHECK: affine.for %[[IV:.*]] = 0 to %[[T7]]
 // CHECK-DAG:    %[[K:.*]] = affine.apply #[[MOD]](%[[IV]])[%[[T6]]]
 // CHECK-DAG:    %[[T9:.*]] = affine.apply #[[FLOOR]](%[[IV]])[%[[T6]]]
 // CHECK-DAG:    %[[J:.*]] = affine.apply #[[MOD]](%[[T9]])[%[[T4]]]
 // CHECK-DAG:    %[[I:.*]] = affine.apply #[[FLOOR]](%[[T9]])[%[[T4]]]
 // CHECK-NEXT:    "test.foo"(%[[I]], %[[J]], %[[K]])
 // CHECK-NEXT:  }
 // CHECK-NEXT:  return

 // -----

 // Check coalescing of affine.for loops when some of the loop has constant upper bounds while others have nin constant upper bounds.
 // CHECK-DAG: #[[IDENTITY:.*]] = affine_map<()[s0] -> (s0)>
 // CHECK-DAG: #[[PRODUCT:.*]] = affine_map<(d0)[s0] -> (d0 * s0)>
 // CHECK-DAG: #[[SIXTY_FOUR:.*]] = affine_map<() -> (64)>
 // CHECK-DAG: #[[MOD:.*]] = affine_map<(d0)[s0] -> (d0 mod s0)>
 // CHECK-DAG: #[[DIV:.*]] = affine_map<(d0)[s0] -> (d0 floordiv s0)>
 func @coalesce_affine_for(%arg0: memref<?x?xf32>) {
   %c0 = arith.constant 0 : index
   %M = memref.dim %arg0, %c0 : memref<?x?xf32>
   %N = memref.dim %arg0, %c0 : memref<?x?xf32>
   affine.for %i = 0 to %M {
     affine.for %j = 0 to %N {
       affine.for %k = 0 to 64 {
       "test.foo"(%i, %j, %k) : (index, index, index) -> ()
       }
     }
   }
   return
 }
 // CHECK: %[[T0:.*]] = memref.dim %arg{{.*}}, %c{{.*}} : memref<?x?xf32>
 // CHECK: %[[T1:.*]] = memref.dim %arg{{.*}}, %c{{.*}} : memref<?x?xf32>
 // CHECK-DAG: %[[T2:.*]] = affine.apply #[[IDENTITY]]()[%[[T0]]]
 // CHECK-DAG: %[[T3:.*]] = affine.apply #[[IDENTITY]]()[%[[T1]]]
 // CHECK-DAG: %[[T4:.*]] = affine.apply #[[PRODUCT]](%[[T2]])[%[[T3]]]
 // CHECK-DAG: %[[T5:.*]] = affine.apply #[[SIXTY_FOUR]]()
 // CHECK-DAG: %[[T6:.*]] = affine.apply #[[PRODUCT]](%[[T4]])[%[[T5]]]
 // CHECK: affine.for %[[IV:.*]] = 0 to %[[T6]]
 // CHECK-DAG:    %[[K:.*]] = affine.apply #[[MOD]](%[[IV]])[%[[T5]]]
 // CHECK-DAG:    %[[T8:.*]] = affine.apply #[[DIV]](%[[IV]])[%[[T5]]]
 // CHECK-DAG:    %[[J:.*]] = affine.apply #[[MOD]](%[[T8]])[%[[T3]]]
 // CHECK-DAG:    %[[I:.*]] = affine.apply #[[DIV]](%[[T8]])[%[[T3]]]
 // CHECK-NEXT:    "test.foo"(%[[I]], %[[J]], %[[K]])
 // CHECK-NEXT:  }
 // CHECK-NEXT:  return

 // -----

 // Check coalescing of affine.for loops when upper bound contains multi result upper bound map.
 // CHECK-DAG: #[[MAP0:.*]] = affine_map<()[s0] -> (s0, -s0)>
 // CHECK-DAG: #[[IDENTITY:.*]] = affine_map<()[s0] -> (s0)>
 // CHECK-DAG: #[[PRODUCT:.*]] = affine_map<(d0)[s0] -> (d0 * s0)>
 // CHECK-DAG: #[[MOD:.*]] = affine_map<(d0)[s0] -> (d0 mod s0)>
 // CHECK-DAG: #[[DIV:.*]] = affine_map<(d0)[s0] -> (d0 floordiv s0)>
 #myMap = affine_map<()[s1] -> (s1, -s1)>
 func @coalesce_affine_for(%arg0: memref<?x?xf32>) {
  %c0 = arith.constant 0 : index
  %M = memref.dim %arg0, %c0 : memref<?x?xf32>
  %N = memref.dim %arg0, %c0 : memref<?x?xf32>
  %K = memref.dim %arg0, %c0 : memref<?x?xf32>
  affine.for %i = 0 to min #myMap()[%M] {
    affine.for %j = 0 to %N {
      affine.for %k = 0 to %K {
      "test.foo"(%i, %j, %k) : (index, index, index) -> ()
      }
    }
  }
  return
 }
 // CHECK: %[[T0:.*]] = memref.dim %arg{{.*}}, %c{{.*}} : memref<?x?xf32>
 // CHECK: %[[T1:.*]] = memref.dim %arg{{.*}}, %c{{.*}} : memref<?x?xf32>
 // CHECK: %[[T2:.*]] = memref.dim %arg{{.*}}, %c{{.*}} : memref<?x?xf32>
 // CHECK-DAG: %[[T3:.*]] = affine.min #[[MAP0]]()[%[[T0]]]
 // CHECK-DAG: %[[T4:.*]] = affine.apply #[[IDENTITY]]()[%[[T1]]]
 // CHECK-DAG: %[[T5:.*]] = affine.apply #[[PRODUCT]](%[[T3]])[%[[T4]]]
 // CHECK-DAG: %[[T6:.*]] = affine.apply #[[IDENTITY]]()[%[[T2]]]
 // CHECK-DAG: %[[T7:.*]] = affine.apply #[[PRODUCT]](%[[T5]])[%[[T6]]]
 // CHECK: affine.for %[[IV:.*]] = 0 to %[[T7]]
 // CHECK-DAG:    %[[K:.*]] = affine.apply #[[MOD]](%[[IV]])[%[[T6]]]
 // CHECK-DAG:    %[[T9:.*]] = affine.apply #[[DIV]](%[[IV]])[%[[T6]]]
 // CHECK-DAG:    %[[J:.*]] = affine.apply #[[MOD]](%[[T9]])[%[[T4]]]
 // CHECK-DAG:    %[[I:.*]] = affine.apply #[[DIV]](%[[T9]])[%[[T4]]]
 // CHECK-NEXT:    "test.foo"(%[[I]], %[[J]], %[[K]])
 // CHECK-NEXT:  }
 // CHECK-NEXT:  return

 // -----

 // CHECK-DAG: #[[MAP0:.*]] = affine_map<(d0) -> (d0 * 110)>
 // CHECK-DAG: #[[MAP1:.*]] = affine_map<(d0) -> (696, d0 * 110 + 110)>
 #map0 = affine_map<(d0) -> (d0 * 110)>
 #map1 = affine_map<(d0) -> (696, d0 * 110 + 110)>
 func @test_loops_do_not_get_coalesced() {
   affine.for %i = 0 to 7 {
     affine.for %j = #map0(%i) to min #map1(%i) {
     }
   }
   return
 }
 // CHECK: affine.for %[[IV0:.*]] = 0 to 7
 // CHECK-NEXT: affine.for %[[IV1:.*]] = #[[MAP0]](%[[IV0]]) to min #[[MAP1]](%[[IV0]])
 // CHECK-NEXT: }
 // CHECK-NEXT: }
 // CHECK-NEXT: return
	// RUN: mlir-opt -split-input-file -allow-unregistered-dialect -loop-coalescing %s \| FileCheck %s

	// CHECK-LABEL: @one_3d_nest
	func @one_3d_nest() {
	// Capture original bounds. Note that for zero-based step-one loops, the
	// upper bound is also the number of iterations.
	// CHECK: %[[orig_lb:.*]] = arith.constant 0
	// CHECK: %[[orig_step:.*]] = arith.constant 1
	// CHECK: %[[orig_ub_k:.*]] = arith.constant 3
	// CHECK: %[[orig_ub_i:.*]] = arith.constant 42
	// CHECK: %[[orig_ub_j:.*]] = arith.constant 56
	%c0 = arith.constant 0 : index
	%c1 = arith.constant 1 : index
	%c2 = arith.constant 2 : index
	%c3 = arith.constant 3 : index
	%c42 = arith.constant 42 : index
	%c56 = arith.constant 56 : index
	// The range of the new scf.
	// CHECK: %[[partial_range:.*]] = arith.muli %[[orig_ub_i]], %[[orig_ub_j]]
	// CHECK-NEXT:%[[range:.*]] = arith.muli %[[partial_range]], %[[orig_ub_k]]

	// Updated loop bounds.
	// CHECK: scf.for %[[i:.*]] = %[[orig_lb]] to %[[range]] step %[[orig_step]]
	scf.for %i = %c0 to %c42 step %c1 {
	// Inner loops must have been removed.
	// CHECK-NOT: scf.for

	// Reconstruct original IVs from the linearized one.
	// CHECK: %[[orig_k:.*]] = arith.remsi %[[i]], %[[orig_ub_k]]
	// CHECK: %[[div:.*]] = arith.divsi %[[i]], %[[orig_ub_k]]
	// CHECK: %[[orig_j:.*]] = arith.remsi %[[div]], %[[orig_ub_j]]
	// CHECK: %[[orig_i:.*]] = arith.divsi %[[div]], %[[orig_ub_j]]
	scf.for %j = %c0 to %c56 step %c1 {
	scf.for %k = %c0 to %c3 step %c1 {
	// CHECK: "use"(%[[orig_i]], %[[orig_j]], %[[orig_k]])
	"use"(%i, %j, %k) : (index, index, index) -> ()
	}
	}
	}
	return
	}

	// Check that there is no chasing the replacement of value uses by ensuring
	// multiple uses of loop induction variables get rewritten to the same values.

	// CHECK-LABEL: @multi_use
	func @multi_use() {
	%c0 = arith.constant 0 : index
	%c1 = arith.constant 1 : index
	%c10 = arith.constant 10 : index
	// CHECK: scf.for %[[iv:.*]] =
	scf.for %i = %c1 to %c10 step %c1 {
	scf.for %j = %c1 to %c10 step %c1 {
	scf.for %k = %c1 to %c10 step %c1 {
	// CHECK: %[[k_unshifted:.]] = arith.remsi %[[iv]], %[[k_extent:.]]
	// CHECK: %[[ij:.*]] = arith.divsi %[[iv]], %[[k_extent]]
	// CHECK: %[[j_unshifted:.]] = arith.remsi %[[ij]], %[[j_extent:.]]
	// CHECK: %[[i_unshifted:.*]] = arith.divsi %[[ij]], %[[j_extent]]
	// CHECK: %[[k:.*]] = arith.addi %[[k_unshifted]]
	// CHECK: %[[j:.*]] = arith.addi %[[j_unshifted]]
	// CHECK: %[[i:.*]] = arith.addi %[[i_unshifted]]

	// CHECK: "use1"(%[[i]], %[[j]], %[[k]])
	"use1"(%i,%j,%k) : (index,index,index) -> ()
	// CHECK: "use2"(%[[i]], %[[k]], %[[j]])
	"use2"(%i,%k,%j) : (index,index,index) -> ()
	// CHECK: "use3"(%[[k]], %[[j]], %[[i]])
	"use3"(%k,%j,%i) : (index,index,index) -> ()
	}
	}
	}
	return
	}

	func @unnormalized_loops() {
	// CHECK: %[[orig_step_i:.*]] = arith.constant 2
	// CHECK: %[[orig_step_j:.*]] = arith.constant 3
	// CHECK: %[[orig_lb_i:.*]] = arith.constant 5
	// CHECK: %[[orig_lb_j:.*]] = arith.constant 7
	// CHECK: %[[orig_ub_i:.*]] = arith.constant 10
	// CHECK: %[[orig_ub_j:.*]] = arith.constant 17
	%c2 = arith.constant 2 : index
	%c3 = arith.constant 3 : index
	%c5 = arith.constant 5 : index
	%c7 = arith.constant 7 : index
	%c10 = arith.constant 10 : index
	%c17 = arith.constant 17 : index

	// Number of iterations in the outer scf.
	// CHECK: %[[diff_i:.*]] = arith.subi %[[orig_ub_i]], %[[orig_lb_i]]
	// CHECK: %[[c1:.*]] = arith.constant 1
	// CHECK: %[[step_minus_c1:.*]] = arith.subi %[[orig_step_i]], %[[c1]]
	// CHECK: %[[dividend:.*]] = arith.addi %[[diff_i]], %[[step_minus_c1]]
	// CHECK: %[[numiter_i:.*]] = arith.divsi %[[dividend]], %[[orig_step_i]]

	// Normalized lower bound and step for the outer scf.
	// CHECK: %[[lb_i:.*]] = arith.constant 0
	// CHECK: %[[step_i:.*]] = arith.constant 1

	// Number of iterations in the inner loop, the pattern is the same as above,
	// only capture the final result.
	// CHECK: %[[numiter_j:.]] = arith.divsi {{.}}, %[[orig_step_j]]

	// New bounds of the outer scf.
	// CHECK: %[[range:.*]] = arith.muli %[[numiter_i]], %[[numiter_j]]
	// CHECK: scf.for %[[i:.*]] = %[[lb_i]] to %[[range]] step %[[step_i]]
	scf.for %i = %c5 to %c10 step %c2 {
	// The inner loop has been removed.
	// CHECK-NOT: scf.for
	scf.for %j = %c7 to %c17 step %c3 {
	// The IVs are rewritten.
	// CHECK: %[[normalized_j:.*]] = arith.remsi %[[i]], %[[numiter_j]]
	// CHECK: %[[normalized_i:.*]] = arith.divsi %[[i]], %[[numiter_j]]
	// CHECK: %[[scaled_j:.*]] = arith.muli %[[normalized_j]], %[[orig_step_j]]
	// CHECK: %[[orig_j:.*]] = arith.addi %[[scaled_j]], %[[orig_lb_j]]
	// CHECK: %[[scaled_i:.*]] = arith.muli %[[normalized_i]], %[[orig_step_i]]
	// CHECK: %[[orig_i:.*]] = arith.addi %[[scaled_i]], %[[orig_lb_i]]
	// CHECK: "use"(%[[orig_i]], %[[orig_j]])
	"use"(%i, %j) : (index, index) -> ()
	}
	}
	return
	}

	// Check with parametric loop bounds and steps, capture the bounds here.
	// CHECK-LABEL: @parametric
	// CHECK-SAME: %[[orig_lb1:[A-Za-z0-9]+]]:
	// CHECK-SAME: %[[orig_ub1:[A-Za-z0-9]+]]:
	// CHECK-SAME: %[[orig_step1:[A-Za-z0-9]+]]:
	// CHECK-SAME: %[[orig_lb2:[A-Za-z0-9]+]]:
	// CHECK-SAME: %[[orig_ub2:[A-Za-z0-9]+]]:
	// CHECK-SAME: %[[orig_step2:[A-Za-z0-9]+]]:
	func @parametric(%lb1 : index, %ub1 : index, %step1 : index,
	%lb2 : index, %ub2 : index, %step2 : index) {
	// Compute the number of iterations for each of the loops and the total
	// number of iterations.
	// CHECK: %[[range1:.*]] = arith.subi %[[orig_ub1]], %[[orig_lb1]]
	// CHECK: %[[orig_step1_minus_1:.*]] = arith.subi %[[orig_step1]], %c1
	// CHECK: %[[dividend1:.*]] = arith.addi %[[range1]], %[[orig_step1_minus_1]]
	// CHECK: %[[numiter1:.*]] = arith.divsi %[[dividend1]], %[[orig_step1]]
	// CHECK: %[[range2:.*]] = arith.subi %[[orig_ub2]], %[[orig_lb2]]
	// CHECK: %[[orig_step2_minus_1:.*]] = arith.subi %arg5, %c1
	// CHECK: %[[dividend2:.*]] = arith.addi %[[range2]], %[[orig_step2_minus_1]]
	// CHECK: %[[numiter2:.*]] = arith.divsi %[[dividend2]], %[[orig_step2]]
	// CHECK: %[[range:.*]] = arith.muli %[[numiter1]], %[[numiter2]] : index

	// Check that the outer loop is updated.
	// CHECK: scf.for %[[i:.]] = %c0{{.}} to %[[range]] step %c1
	scf.for %i = %lb1 to %ub1 step %step1 {
	// Check that the inner loop is removed.
	// CHECK-NOT: scf.for
	scf.for %j = %lb2 to %ub2 step %step2 {
	// Remapping of the induction variables.
	// CHECK: %[[normalized_j:.*]] = arith.remsi %[[i]], %[[numiter2]] : index
	// CHECK: %[[normalized_i:.*]] = arith.divsi %[[i]], %[[numiter2]] : index
	// CHECK: %[[scaled_j:.*]] = arith.muli %[[normalized_j]], %[[orig_step2]]
	// CHECK: %[[orig_j:.*]] = arith.addi %[[scaled_j]], %[[orig_lb2]]
	// CHECK: %[[scaled_i:.*]] = arith.muli %[[normalized_i]], %[[orig_step1]]
	// CHECK: %[[orig_i:.*]] = arith.addi %[[scaled_i]], %[[orig_lb1]]

	// CHECK: "foo"(%[[orig_i]], %[[orig_j]])
	"foo"(%i, %j) : (index, index) -> ()
	}
	}
	return
	}

	// CHECK-LABEL: @two_bands
	func @two_bands() {
	%c0 = arith.constant 0 : index
	%c1 = arith.constant 1 : index
	%c10 = arith.constant 10 : index
	// CHECK: %[[outer_range:.*]] = arith.muli
	// CHECK: scf.for %{{.}} = %{{.}} to %[[outer_range]]
	scf.for %i = %c0 to %c10 step %c1 {
	// Check that the "j" loop was removed and that the inner loops were
	// coalesced as well. The preparation step for coalescing will inject the
	// subtraction operation unlike the IV remapping.
	// CHECK-NOT: scf.for
	// CHECK: arith.subi
	scf.for %j = %c0 to %c10 step %c1 {
	// The inner pair of loops is coalesced separately.
	// CHECK: scf.for
	scf.for %k = %i to %j step %c1 {
	// CHECK_NOT: scf.for
	scf.for %l = %i to %j step %c1 {
	"foo"() : () -> ()
	}
	}
	}
	}
	return
	}

	// -----

	// Check coalescing of affine.for loops when all the loops have constant upper bound.
	// CHECK-DAG: #[[SIXTEEN:.*]] = affine_map<() -> (16)>
	// CHECK-DAG: #[[SIXTY_FOUR:.*]] = affine_map<() -> (64)>
	// CHECK-DAG: #[[PRODUCT:.]] = affine_map<(d0)[s0] -> (d0 s0)>
	// CHECK-DAG: #[[EIGHT:.*]] = affine_map<() -> (8)>
	// CHECK-DAG: #[[MOD:.*]] = affine_map<(d0)[s0] -> (d0 mod s0)>
	// CHECK-DAG: #[[DIV:.*]] = affine_map<(d0)[s0] -> (d0 floordiv s0)>
	func @coalesce_affine_for() {
	affine.for %i = 0 to 16 {
	affine.for %j = 0 to 64 {
	affine.for %k = 0 to 8 {
	"test.foo"(%i, %j, %k) : (index, index, index) -> ()
	}
	}
	}
	return
	}
	// CHECK-DAG: %[[T0:.*]] = affine.apply #[[SIXTEEN]]()
	// CHECK-DAG: %[[T1:.*]] = affine.apply #[[SIXTY_FOUR]]()
	// CHECK-DAG: %[[T2:.*]] = affine.apply #[[PRODUCT]](%[[T0]])[%[[T1]]]
	// CHECK-DAG: %[[T3:.*]] = affine.apply #[[EIGHT]]()
	// CHECK-DAG: %[[T4:.*]] = affine.apply #[[PRODUCT]](%[[T2]])[%[[T3]]]
	// CHECK: affine.for %[[IV:.*]] = 0 to %[[T4]]
	// CHECK-DAG: %[[K:.*]] = affine.apply #[[MOD]](%[[IV]])[%[[T3]]]
	// CHECK-DAG: %[[T6:.*]] = affine.apply #[[DIV]](%[[IV]])[%[[T3]]]
	// CHECK-DAG: %[[J:.*]] = affine.apply #[[MOD]](%[[T6]])[%[[T1]]]
	// CHECK-DAG: %[[I:.*]] = affine.apply #[[DIV]](%[[T6]])[%[[T1]]]
	// CHECK-NEXT: "test.foo"(%[[I]], %[[J]], %[[K]])
	// CHECK-NEXT: }
	// CHECK-NEXT: return

	// -----

	// Check coalescing of affine.for loops when all the loops have non constant upper bounds.
	// CHECK-DAG: #[[IDENTITY:.*]] = affine_map<()[s0] -> (s0)>
	// CHECK-DAG: #[[PRODUCT:.]] = affine_map<(d0)[s0] -> (d0 s0)>
	// CHECK-DAG: #[[MOD:.*]] = affine_map<(d0)[s0] -> (d0 mod s0)>
	// CHECK-DAG: #[[FLOOR:.*]] = affine_map<(d0)[s0] -> (d0 floordiv s0)>
	func @coalesce_affine_for(%arg0: memref<?x?xf32>) {
	%c0 = arith.constant 0 : index
	%M = memref.dim %arg0, %c0 : memref<?x?xf32>
	%N = memref.dim %arg0, %c0 : memref<?x?xf32>
	%K = memref.dim %arg0, %c0 : memref<?x?xf32>
	affine.for %i = 0 to %M {
	affine.for %j = 0 to %N {
	affine.for %k = 0 to %K {
	"test.foo"(%i, %j, %k) : (index, index, index) -> ()
	}
	}
	}
	return
	}
	// CHECK: %[[T0:.]] = memref.dim %arg{{.}}, %c{{.*}} : memref<?x?xf32>
	// CHECK: %[[T1:.]] = memref.dim %arg{{.}}, %c{{.*}} : memref<?x?xf32>
	// CHECK: %[[T2:.]] = memref.dim %arg{{.}}, %c{{.*}} : memref<?x?xf32>
	// CHECK-DAG: %[[T3:.*]] = affine.apply #[[IDENTITY]]()[%[[T0]]]
	// CHECK-DAG: %[[T4:.*]] = affine.apply #[[IDENTITY]]()[%[[T1]]]
	// CHECK-DAG: %[[T5:.*]] = affine.apply #[[PRODUCT]](%[[T3]])[%[[T4]]]
	// CHECK-DAG: %[[T6:.*]] = affine.apply #[[IDENTITY]]()[%[[T2]]]
	// CHECK-DAG: %[[T7:.*]] = affine.apply #[[PRODUCT]](%[[T5]])[%[[T6]]]
	// CHECK: affine.for %[[IV:.*]] = 0 to %[[T7]]
	// CHECK-DAG: %[[K:.*]] = affine.apply #[[MOD]](%[[IV]])[%[[T6]]]
	// CHECK-DAG: %[[T9:.*]] = affine.apply #[[FLOOR]](%[[IV]])[%[[T6]]]
	// CHECK-DAG: %[[J:.*]] = affine.apply #[[MOD]](%[[T9]])[%[[T4]]]
	// CHECK-DAG: %[[I:.*]] = affine.apply #[[FLOOR]](%[[T9]])[%[[T4]]]
	// CHECK-NEXT: "test.foo"(%[[I]], %[[J]], %[[K]])
	// CHECK-NEXT: }
	// CHECK-NEXT: return

	// -----

	// Check coalescing of affine.for loops when some of the loop has constant upper bounds while others have nin constant upper bounds.
	// CHECK-DAG: #[[IDENTITY:.*]] = affine_map<()[s0] -> (s0)>
	// CHECK-DAG: #[[PRODUCT:.]] = affine_map<(d0)[s0] -> (d0 s0)>
	// CHECK-DAG: #[[SIXTY_FOUR:.*]] = affine_map<() -> (64)>
	// CHECK-DAG: #[[MOD:.*]] = affine_map<(d0)[s0] -> (d0 mod s0)>
	// CHECK-DAG: #[[DIV:.*]] = affine_map<(d0)[s0] -> (d0 floordiv s0)>
	func @coalesce_affine_for(%arg0: memref<?x?xf32>) {
	%c0 = arith.constant 0 : index
	%M = memref.dim %arg0, %c0 : memref<?x?xf32>
	%N = memref.dim %arg0, %c0 : memref<?x?xf32>
	affine.for %i = 0 to %M {
	affine.for %j = 0 to %N {
	affine.for %k = 0 to 64 {
	"test.foo"(%i, %j, %k) : (index, index, index) -> ()
	}
	}
	}
	return
	}
	// CHECK: %[[T0:.]] = memref.dim %arg{{.}}, %c{{.*}} : memref<?x?xf32>
	// CHECK: %[[T1:.]] = memref.dim %arg{{.}}, %c{{.*}} : memref<?x?xf32>
	// CHECK-DAG: %[[T2:.*]] = affine.apply #[[IDENTITY]]()[%[[T0]]]
	// CHECK-DAG: %[[T3:.*]] = affine.apply #[[IDENTITY]]()[%[[T1]]]
	// CHECK-DAG: %[[T4:.*]] = affine.apply #[[PRODUCT]](%[[T2]])[%[[T3]]]
	// CHECK-DAG: %[[T5:.*]] = affine.apply #[[SIXTY_FOUR]]()
	// CHECK-DAG: %[[T6:.*]] = affine.apply #[[PRODUCT]](%[[T4]])[%[[T5]]]
	// CHECK: affine.for %[[IV:.*]] = 0 to %[[T6]]
	// CHECK-DAG: %[[K:.*]] = affine.apply #[[MOD]](%[[IV]])[%[[T5]]]
	// CHECK-DAG: %[[T8:.*]] = affine.apply #[[DIV]](%[[IV]])[%[[T5]]]
	// CHECK-DAG: %[[J:.*]] = affine.apply #[[MOD]](%[[T8]])[%[[T3]]]
	// CHECK-DAG: %[[I:.*]] = affine.apply #[[DIV]](%[[T8]])[%[[T3]]]
	// CHECK-NEXT: "test.foo"(%[[I]], %[[J]], %[[K]])
	// CHECK-NEXT: }
	// CHECK-NEXT: return

	// -----

	// Check coalescing of affine.for loops when upper bound contains multi result upper bound map.
	// CHECK-DAG: #[[MAP0:.*]] = affine_map<()[s0] -> (s0, -s0)>
	// CHECK-DAG: #[[IDENTITY:.*]] = affine_map<()[s0] -> (s0)>
	// CHECK-DAG: #[[PRODUCT:.]] = affine_map<(d0)[s0] -> (d0 s0)>
	// CHECK-DAG: #[[MOD:.*]] = affine_map<(d0)[s0] -> (d0 mod s0)>
	// CHECK-DAG: #[[DIV:.*]] = affine_map<(d0)[s0] -> (d0 floordiv s0)>
	#myMap = affine_map<()[s1] -> (s1, -s1)>
	func @coalesce_affine_for(%arg0: memref<?x?xf32>) {
	%c0 = arith.constant 0 : index
	%M = memref.dim %arg0, %c0 : memref<?x?xf32>
	%N = memref.dim %arg0, %c0 : memref<?x?xf32>
	%K = memref.dim %arg0, %c0 : memref<?x?xf32>
	affine.for %i = 0 to min #myMap()[%M] {
	affine.for %j = 0 to %N {
	affine.for %k = 0 to %K {
	"test.foo"(%i, %j, %k) : (index, index, index) -> ()
	}
	}
	}
	return
	}
	// CHECK: %[[T0:.]] = memref.dim %arg{{.}}, %c{{.*}} : memref<?x?xf32>
	// CHECK: %[[T1:.]] = memref.dim %arg{{.}}, %c{{.*}} : memref<?x?xf32>
	// CHECK: %[[T2:.]] = memref.dim %arg{{.}}, %c{{.*}} : memref<?x?xf32>
	// CHECK-DAG: %[[T3:.*]] = affine.min #[[MAP0]]()[%[[T0]]]
	// CHECK-DAG: %[[T4:.*]] = affine.apply #[[IDENTITY]]()[%[[T1]]]
	// CHECK-DAG: %[[T5:.*]] = affine.apply #[[PRODUCT]](%[[T3]])[%[[T4]]]
	// CHECK-DAG: %[[T6:.*]] = affine.apply #[[IDENTITY]]()[%[[T2]]]
	// CHECK-DAG: %[[T7:.*]] = affine.apply #[[PRODUCT]](%[[T5]])[%[[T6]]]
	// CHECK: affine.for %[[IV:.*]] = 0 to %[[T7]]
	// CHECK-DAG: %[[K:.*]] = affine.apply #[[MOD]](%[[IV]])[%[[T6]]]
	// CHECK-DAG: %[[T9:.*]] = affine.apply #[[DIV]](%[[IV]])[%[[T6]]]
	// CHECK-DAG: %[[J:.*]] = affine.apply #[[MOD]](%[[T9]])[%[[T4]]]
	// CHECK-DAG: %[[I:.*]] = affine.apply #[[DIV]](%[[T9]])[%[[T4]]]
	// CHECK-NEXT: "test.foo"(%[[I]], %[[J]], %[[K]])
	// CHECK-NEXT: }
	// CHECK-NEXT: return

	// -----

	// CHECK-DAG: #[[MAP0:.]] = affine_map<(d0) -> (d0 110)>
	// CHECK-DAG: #[[MAP1:.]] = affine_map<(d0) -> (696, d0 110 + 110)>
	#map0 = affine_map<(d0) -> (d0 * 110)>
	#map1 = affine_map<(d0) -> (696, d0 * 110 + 110)>
	func @test_loops_do_not_get_coalesced() {
	affine.for %i = 0 to 7 {
	affine.for %j = #map0(%i) to min #map1(%i) {
	}
	}
	return
	}
	// CHECK: affine.for %[[IV0:.*]] = 0 to 7
	// CHECK-NEXT: affine.for %[[IV1:.*]] = #[[MAP0]](%[[IV0]]) to min #[[MAP1]](%[[IV0]])
	// CHECK-NEXT: }
	// CHECK-NEXT: }
	// CHECK-NEXT: return