mlir/test/Transforms/normalize-memrefs.mlir - llvm-project - Git at Google

 // RUN: mlir-opt -normalize-memrefs -allow-unregistered-dialect %s | FileCheck %s

 // This file tests whether the memref type having non-trivial map layouts
 // are normalized to trivial (identity) layouts.

 // CHECK-LABEL: func @permute()
 func @permute() {
   %A = memref.alloc() : memref<64x256xf32, affine_map<(d0, d1) -> (d1, d0)>>
   affine.for %i = 0 to 64 {
     affine.for %j = 0 to 256 {
       %1 = affine.load %A[%i, %j] : memref<64x256xf32, affine_map<(d0, d1) -> (d1, d0)>>
       "prevent.dce"(%1) : (f32) -> ()
     }
   }
   memref.dealloc %A : memref<64x256xf32, affine_map<(d0, d1) -> (d1, d0)>>
   return
 }
 // The old memref alloc should disappear.
 // CHECK-NOT:  memref<64x256xf32>
 // CHECK:      [[MEM:%[0-9]+]] = memref.alloc() : memref<256x64xf32>
 // CHECK-NEXT: affine.for %[[I:arg[0-9]+]] = 0 to 64 {
 // CHECK-NEXT:   affine.for %[[J:arg[0-9]+]] = 0 to 256 {
 // CHECK-NEXT:     affine.load [[MEM]][%[[J]], %[[I]]] : memref<256x64xf32>
 // CHECK-NEXT:     "prevent.dce"
 // CHECK-NEXT:   }
 // CHECK-NEXT: }
 // CHECK-NEXT: memref.dealloc [[MEM]]
 // CHECK-NEXT: return

 // CHECK-LABEL: func @shift
 func @shift(%idx : index) {
   // CHECK-NEXT: memref.alloc() : memref<65xf32>
   %A = memref.alloc() : memref<64xf32, affine_map<(d0) -> (d0 + 1)>>
   // CHECK-NEXT: affine.load %{{.*}}[symbol(%arg0) + 1] : memref<65xf32>
   affine.load %A[%idx] : memref<64xf32, affine_map<(d0) -> (d0 + 1)>>
   affine.for %i = 0 to 64 {
     %1 = affine.load %A[%i] : memref<64xf32, affine_map<(d0) -> (d0 + 1)>>
     "prevent.dce"(%1) : (f32) -> ()
     // CHECK: %{{.*}} = affine.load %{{.*}}[%arg{{.*}} + 1] : memref<65xf32>
   }
   return
 }

 // CHECK-LABEL: func @high_dim_permute()
 func @high_dim_permute() {
   // CHECK-NOT: memref<64x128x256xf32,
   %A = memref.alloc() : memref<64x128x256xf32, affine_map<(d0, d1, d2) -> (d2, d0, d1)>>
   // CHECK: %[[I:arg[0-9]+]]
   affine.for %i = 0 to 64 {
     // CHECK: %[[J:arg[0-9]+]]
     affine.for %j = 0 to 128 {
       // CHECK: %[[K:arg[0-9]+]]
       affine.for %k = 0 to 256 {
         %1 = affine.load %A[%i, %j, %k] : memref<64x128x256xf32, affine_map<(d0, d1, d2) -> (d2, d0, d1)>>
         // CHECK: %{{.*}} = affine.load %{{.*}}[%[[K]], %[[I]], %[[J]]] : memref<256x64x128xf32>
         "prevent.dce"(%1) : (f32) -> ()
       }
     }
   }
   return
 }

 // CHECK-LABEL: func @invalid_map
 func @invalid_map() {
   %A = memref.alloc() : memref<64x128xf32, affine_map<(d0, d1) -> (d0, -d1 - 10)>>
   // CHECK: %{{.*}} = memref.alloc() : memref<64x128xf32,
   return
 }

 // A tiled layout.
 // CHECK-LABEL: func @data_tiling
 func @data_tiling(%idx : index) {
   // CHECK: memref.alloc() : memref<8x32x8x16xf32>
   %A = memref.alloc() : memref<64x512xf32, affine_map<(d0, d1) -> (d0 floordiv 8, d1 floordiv 16, d0 mod 8, d1 mod 16)>>
   // CHECK: affine.load %{{.*}}[symbol(%arg0) floordiv 8, symbol(%arg0) floordiv 16, symbol(%arg0) mod 8, symbol(%arg0) mod 16]
   %1 = affine.load %A[%idx, %idx] : memref<64x512xf32, affine_map<(d0, d1) -> (d0 floordiv 8, d1 floordiv 16, d0 mod 8, d1 mod 16)>>
   "prevent.dce"(%1) : (f32) -> ()
   return
 }

 // Strides 2 and 4 along respective dimensions.
 // CHECK-LABEL: func @strided
 func @strided() {
   %A = memref.alloc() : memref<64x128xf32, affine_map<(d0, d1) -> (2*d0, 4*d1)>>
   // CHECK: affine.for %[[IV0:.*]] =
   affine.for %i = 0 to 64 {
     // CHECK: affine.for %[[IV1:.*]] =
     affine.for %j = 0 to 128 {
       // CHECK: affine.load %{{.*}}[%[[IV0]] * 2, %[[IV1]] * 4] : memref<127x509xf32>
       %1 = affine.load %A[%i, %j] : memref<64x128xf32, affine_map<(d0, d1) -> (2*d0, 4*d1)>>
       "prevent.dce"(%1) : (f32) -> ()
     }
   }
   return
 }

 // Strided, but the strides are in the linearized space.
 // CHECK-LABEL: func @strided_cumulative
 func @strided_cumulative() {
   %A = memref.alloc() : memref<2x5xf32, affine_map<(d0, d1) -> (3*d0 + 17*d1)>>
   // CHECK: affine.for %[[IV0:.*]] =
   affine.for %i = 0 to 2 {
     // CHECK: affine.for %[[IV1:.*]] =
     affine.for %j = 0 to 5 {
       // CHECK: affine.load %{{.*}}[%[[IV0]] * 3 + %[[IV1]] * 17] : memref<72xf32>
       %1 = affine.load %A[%i, %j]  : memref<2x5xf32, affine_map<(d0, d1) -> (3*d0 + 17*d1)>>
       "prevent.dce"(%1) : (f32) -> ()
     }
   }
   return
 }

 // Symbolic operand for alloc, although unused. Tests replaceAllMemRefUsesWith
 // when the index remap has symbols.
 // CHECK-LABEL: func @symbolic_operands
 func @symbolic_operands(%s : index) {
   // CHECK: memref.alloc() : memref<100xf32>
   %A = memref.alloc()[%s] : memref<10x10xf32, affine_map<(d0,d1)[s0] -> (10*d0 + d1)>>
   affine.for %i = 0 to 10 {
     affine.for %j = 0 to 10 {
       // CHECK: affine.load %{{.*}}[%{{.*}} * 10 + %{{.*}}] : memref<100xf32>
       %1 = affine.load %A[%i, %j] : memref<10x10xf32, affine_map<(d0,d1)[s0] -> (10*d0 + d1)>>
       "prevent.dce"(%1) : (f32) -> ()
     }
   }
   return
 }

 // Semi-affine maps, normalization not implemented yet.
 // CHECK-LABEL: func @semi_affine_layout_map
 func @semi_affine_layout_map(%s0: index, %s1: index) {
   %A = memref.alloc()[%s0, %s1] : memref<256x1024xf32, affine_map<(d0, d1)[s0, s1] -> (d0*s0 + d1*s1)>>
   affine.for %i = 0 to 256 {
     affine.for %j = 0 to 1024 {
       // CHECK: memref<256x1024xf32, #map{{[0-9]+}}>
       affine.load %A[%i, %j] : memref<256x1024xf32, affine_map<(d0, d1)[s0, s1] -> (d0*s0 + d1*s1)>>
     }
   }
   return
 }

 // CHECK-LABEL: func @alignment
 func @alignment() {
   %A = memref.alloc() {alignment = 32 : i64}: memref<64x128x256xf32, affine_map<(d0, d1, d2) -> (d2, d0, d1)>>
   // CHECK-NEXT: memref.alloc() {alignment = 32 : i64} : memref<256x64x128xf32>
   return
 }

 #tile = affine_map < (i)->(i floordiv 4, i mod 4) >

 // Following test cases check the inter-procedural memref normalization.

 // Test case 1: Check normalization for multiple memrefs in a function argument list.
 // CHECK-LABEL: func @multiple_argument_type
 // CHECK-SAME:  (%[[A:arg[0-9]+]]: memref<4x4xf64>, %[[B:arg[0-9]+]]: f64, %[[C:arg[0-9]+]]: memref<2x4xf64>, %[[D:arg[0-9]+]]: memref<24xf64>) -> f64
 func @multiple_argument_type(%A: memref<16xf64, #tile>, %B: f64, %C: memref<8xf64, #tile>, %D: memref<24xf64>) -> f64 {
   %a = affine.load %A[0] : memref<16xf64, #tile>
   %p = arith.mulf %a, %a : f64
   affine.store %p, %A[10] : memref<16xf64, #tile>
   call @single_argument_type(%C): (memref<8xf64, #tile>) -> ()
   return %B : f64
 }

 // CHECK: %[[a:[0-9]+]] = affine.load %[[A]][0, 0] : memref<4x4xf64>
 // CHECK: %[[p:[0-9]+]] = arith.mulf %[[a]], %[[a]] : f64
 // CHECK: affine.store %[[p]], %[[A]][2, 2] : memref<4x4xf64>
 // CHECK: call @single_argument_type(%[[C]]) : (memref<2x4xf64>) -> ()
 // CHECK: return %[[B]] : f64

 // Test case 2: Check normalization for single memref argument in a function.
 // CHECK-LABEL: func @single_argument_type
 // CHECK-SAME: (%[[C:arg[0-9]+]]: memref<2x4xf64>)
 func @single_argument_type(%C : memref<8xf64, #tile>) {
   %a = memref.alloc(): memref<8xf64, #tile>
   %b = memref.alloc(): memref<16xf64, #tile>
   %d = arith.constant 23.0 : f64
   %e = memref.alloc(): memref<24xf64>
   call @single_argument_type(%a): (memref<8xf64, #tile>) -> ()
   call @single_argument_type(%C): (memref<8xf64, #tile>) -> ()
   call @multiple_argument_type(%b, %d, %a, %e): (memref<16xf64, #tile>, f64, memref<8xf64, #tile>, memref<24xf64>) -> f64
   return
 }

 // CHECK: %[[a:[0-9]+]] = memref.alloc() : memref<2x4xf64>
 // CHECK: %[[b:[0-9]+]] = memref.alloc() : memref<4x4xf64>
 // CHECK: %cst = arith.constant 2.300000e+01 : f64
 // CHECK: %[[e:[0-9]+]] = memref.alloc() : memref<24xf64>
 // CHECK: call @single_argument_type(%[[a]]) : (memref<2x4xf64>) -> ()
 // CHECK: call @single_argument_type(%[[C]]) : (memref<2x4xf64>) -> ()
 // CHECK: call @multiple_argument_type(%[[b]], %cst, %[[a]], %[[e]]) : (memref<4x4xf64>, f64, memref<2x4xf64>, memref<24xf64>) -> f64

 // Test case 3: Check function returning any other type except memref.
 // CHECK-LABEL: func @non_memref_ret
 // CHECK-SAME: (%[[C:arg[0-9]+]]: memref<2x4xf64>) -> i1
 func @non_memref_ret(%A: memref<8xf64, #tile>) -> i1 {
   %d = arith.constant 1 : i1
   return %d : i1
 }

 // Test cases here onwards deal with normalization of memref in function signature, caller site.

 // Test case 4: Check successful memref normalization in case of inter/intra-recursive calls.
 // CHECK-LABEL: func @ret_multiple_argument_type
 // CHECK-SAME: (%[[A:arg[0-9]+]]: memref<4x4xf64>, %[[B:arg[0-9]+]]: f64, %[[C:arg[0-9]+]]: memref<2x4xf64>) -> (memref<2x4xf64>, f64)
 func @ret_multiple_argument_type(%A: memref<16xf64, #tile>, %B: f64, %C: memref<8xf64, #tile>) -> (memref<8xf64, #tile>, f64) {
   %a = affine.load %A[0] : memref<16xf64, #tile>
   %p = arith.mulf %a, %a : f64
   %cond = arith.constant 1 : i1
   cond_br %cond, ^bb1, ^bb2
   ^bb1:
     %res1, %res2 = call @ret_single_argument_type(%C) : (memref<8xf64, #tile>) -> (memref<16xf64, #tile>, memref<8xf64, #tile>)
     return %res2, %p: memref<8xf64, #tile>, f64
   ^bb2:
     return %C, %p: memref<8xf64, #tile>, f64
 }

 // CHECK:   %[[a:[0-9]+]] = affine.load %[[A]][0, 0] : memref<4x4xf64>
 // CHECK:   %[[p:[0-9]+]] = arith.mulf %[[a]], %[[a]] : f64
 // CHECK:   %true = arith.constant true
 // CHECK:   cond_br %true, ^bb1, ^bb2
 // CHECK: ^bb1:  // pred: ^bb0
 // CHECK:   %[[res:[0-9]+]]:2 = call @ret_single_argument_type(%[[C]]) : (memref<2x4xf64>) -> (memref<4x4xf64>, memref<2x4xf64>)
 // CHECK:   return %[[res]]#1, %[[p]] : memref<2x4xf64>, f64
 // CHECK: ^bb2:  // pred: ^bb0
 // CHECK:   return %{{.*}}, %{{.*}} : memref<2x4xf64>, f64

 // CHECK-LABEL: func @ret_single_argument_type
 // CHECK-SAME: (%[[C:arg[0-9]+]]: memref<2x4xf64>) -> (memref<4x4xf64>, memref<2x4xf64>)
 func @ret_single_argument_type(%C: memref<8xf64, #tile>) -> (memref<16xf64, #tile>, memref<8xf64, #tile>){
   %a = memref.alloc() : memref<8xf64, #tile>
   %b = memref.alloc() : memref<16xf64, #tile>
   %d = arith.constant 23.0 : f64
   call @ret_single_argument_type(%a) : (memref<8xf64, #tile>) -> (memref<16xf64, #tile>, memref<8xf64, #tile>)
   call @ret_single_argument_type(%C) : (memref<8xf64, #tile>) -> (memref<16xf64, #tile>, memref<8xf64, #tile>)
   %res1, %res2 = call @ret_multiple_argument_type(%b, %d, %a) : (memref<16xf64, #tile>, f64, memref<8xf64, #tile>) -> (memref<8xf64, #tile>, f64)
   %res3, %res4 = call @ret_single_argument_type(%res1) : (memref<8xf64, #tile>) -> (memref<16xf64, #tile>, memref<8xf64, #tile>)
   return %b, %a: memref<16xf64, #tile>, memref<8xf64, #tile>
 }

 // CHECK: %[[a:[0-9]+]] = memref.alloc() : memref<2x4xf64>
 // CHECK: %[[b:[0-9]+]] = memref.alloc() : memref<4x4xf64>
 // CHECK: %cst = arith.constant 2.300000e+01 : f64
 // CHECK: %[[resA:[0-9]+]]:2 = call @ret_single_argument_type(%[[a]]) : (memref<2x4xf64>) -> (memref<4x4xf64>, memref<2x4xf64>)
 // CHECK: %[[resB:[0-9]+]]:2 = call @ret_single_argument_type(%[[C]]) : (memref<2x4xf64>) -> (memref<4x4xf64>, memref<2x4xf64>)
 // CHECK: %[[resC:[0-9]+]]:2 = call @ret_multiple_argument_type(%[[b]], %cst, %[[a]]) : (memref<4x4xf64>, f64, memref<2x4xf64>) -> (memref<2x4xf64>, f64)
 // CHECK: %[[resD:[0-9]+]]:2 = call @ret_single_argument_type(%[[resC]]#0) : (memref<2x4xf64>) -> (memref<4x4xf64>, memref<2x4xf64>)
 // CHECK: return %{{.*}}, %{{.*}} : memref<4x4xf64>, memref<2x4xf64>

 // Test case set #5: To check normalization in a chain of interconnected functions.
 // CHECK-LABEL: func @func_A
 // CHECK-SAME: (%[[A:arg[0-9]+]]: memref<2x4xf64>)
 func @func_A(%A: memref<8xf64, #tile>) {
   call @func_B(%A) : (memref<8xf64, #tile>) -> ()
   return
 }
 // CHECK: call @func_B(%[[A]]) : (memref<2x4xf64>) -> ()

 // CHECK-LABEL: func @func_B
 // CHECK-SAME: (%[[A:arg[0-9]+]]: memref<2x4xf64>)
 func @func_B(%A: memref<8xf64, #tile>) {
   call @func_C(%A) : (memref<8xf64, #tile>) -> ()
   return
 }
 // CHECK: call @func_C(%[[A]]) : (memref<2x4xf64>) -> ()

 // CHECK-LABEL: func @func_C
 // CHECK-SAME: (%[[A:arg[0-9]+]]: memref<2x4xf64>)
 func @func_C(%A: memref<8xf64, #tile>) {
   return
 }

 // Test case set #6: Checking if no normalization takes place in a scenario: A -> B -> C and B has an unsupported type.
 // CHECK-LABEL: func @some_func_A
 // CHECK-SAME: (%[[A:arg[0-9]+]]: memref<8xf64, #map{{[0-9]+}}>)
 func @some_func_A(%A: memref<8xf64, #tile>) {
   call @some_func_B(%A) : (memref<8xf64, #tile>) -> ()
   return
 }
 // CHECK: call @some_func_B(%[[A]]) : (memref<8xf64, #map{{[0-9]+}}>) -> ()

 // CHECK-LABEL: func @some_func_B
 // CHECK-SAME: (%[[A:arg[0-9]+]]: memref<8xf64, #map{{[0-9]+}}>)
 func @some_func_B(%A: memref<8xf64, #tile>) {
   "test.test"(%A) : (memref<8xf64, #tile>) -> ()
   call @some_func_C(%A) : (memref<8xf64, #tile>) -> ()
   return
 }
 // CHECK: call @some_func_C(%[[A]]) : (memref<8xf64, #map{{[0-9]+}}>) -> ()

 // CHECK-LABEL: func @some_func_C
 // CHECK-SAME: (%[[A:arg[0-9]+]]: memref<8xf64, #map{{[0-9]+}}>)
 func @some_func_C(%A: memref<8xf64, #tile>) {
   return
 }

 // Test case set #7: Check normalization in case of external functions.
 // CHECK-LABEL: func private @external_func_A
 // CHECK-SAME: (memref<4x4xf64>)
 func private @external_func_A(memref<16xf64, #tile>) -> ()

 // CHECK-LABEL: func private @external_func_B
 // CHECK-SAME: (memref<4x4xf64>, f64) -> memref<2x4xf64>
 func private @external_func_B(memref<16xf64, #tile>, f64) -> (memref<8xf64, #tile>)

 // CHECK-LABEL: func @simply_call_external()
 func @simply_call_external() {
   %a = memref.alloc() : memref<16xf64, #tile>
   call @external_func_A(%a) : (memref<16xf64, #tile>) -> ()
   return
 }
 // CHECK: %[[a:[0-9]+]] = memref.alloc() : memref<4x4xf64>
 // CHECK: call @external_func_A(%[[a]]) : (memref<4x4xf64>) -> ()

 // CHECK-LABEL: func @use_value_of_external
 // CHECK-SAME: (%[[A:arg[0-9]+]]: memref<4x4xf64>, %[[B:arg[0-9]+]]: f64) -> memref<2x4xf64>
 func @use_value_of_external(%A: memref<16xf64, #tile>, %B: f64) -> (memref<8xf64, #tile>) {
   %res = call @external_func_B(%A, %B) : (memref<16xf64, #tile>, f64) -> (memref<8xf64, #tile>)
   return %res : memref<8xf64, #tile>
 }
 // CHECK: %[[res:[0-9]+]] = call @external_func_B(%[[A]], %[[B]]) : (memref<4x4xf64>, f64) -> memref<2x4xf64>
 // CHECK: return %{{.*}} : memref<2x4xf64>

 // CHECK-LABEL: func @affine_parallel_norm
 func @affine_parallel_norm() ->  memref<8xf32, #tile> {
   %c = arith.constant 23.0 : f32
   %a = memref.alloc() : memref<8xf32, #tile>
   // CHECK: affine.parallel (%{{.*}}) = (0) to (8) reduce ("assign") -> (memref<2x4xf32>)
   %1 = affine.parallel (%i) = (0) to (8) reduce ("assign") ->  memref<8xf32, #tile> {
     affine.store %c, %a[%i] : memref<8xf32, #tile>
     // CHECK: affine.yield %{{.*}} : memref<2x4xf32>
     affine.yield %a : memref<8xf32, #tile>
   }
   return %1 : memref<8xf32, #tile>
 }
	// RUN: mlir-opt -normalize-memrefs -allow-unregistered-dialect %s \| FileCheck %s

	// This file tests whether the memref type having non-trivial map layouts
	// are normalized to trivial (identity) layouts.

	// CHECK-LABEL: func @permute()
	func @permute() {
	%A = memref.alloc() : memref<64x256xf32, affine_map<(d0, d1) -> (d1, d0)>>
	affine.for %i = 0 to 64 {
	affine.for %j = 0 to 256 {
	%1 = affine.load %A[%i, %j] : memref<64x256xf32, affine_map<(d0, d1) -> (d1, d0)>>
	"prevent.dce"(%1) : (f32) -> ()
	}
	}
	memref.dealloc %A : memref<64x256xf32, affine_map<(d0, d1) -> (d1, d0)>>
	return
	}
	// The old memref alloc should disappear.
	// CHECK-NOT: memref<64x256xf32>
	// CHECK: [[MEM:%[0-9]+]] = memref.alloc() : memref<256x64xf32>
	// CHECK-NEXT: affine.for %[[I:arg[0-9]+]] = 0 to 64 {
	// CHECK-NEXT: affine.for %[[J:arg[0-9]+]] = 0 to 256 {
	// CHECK-NEXT: affine.load [[MEM]][%[[J]], %[[I]]] : memref<256x64xf32>
	// CHECK-NEXT: "prevent.dce"
	// CHECK-NEXT: }
	// CHECK-NEXT: }
	// CHECK-NEXT: memref.dealloc [[MEM]]
	// CHECK-NEXT: return

	// CHECK-LABEL: func @shift
	func @shift(%idx : index) {
	// CHECK-NEXT: memref.alloc() : memref<65xf32>
	%A = memref.alloc() : memref<64xf32, affine_map<(d0) -> (d0 + 1)>>
	// CHECK-NEXT: affine.load %{{.*}}[symbol(%arg0) + 1] : memref<65xf32>
	affine.load %A[%idx] : memref<64xf32, affine_map<(d0) -> (d0 + 1)>>
	affine.for %i = 0 to 64 {
	%1 = affine.load %A[%i] : memref<64xf32, affine_map<(d0) -> (d0 + 1)>>
	"prevent.dce"(%1) : (f32) -> ()
	// CHECK: %{{.}} = affine.load %{{.}}[%arg{{.*}} + 1] : memref<65xf32>
	}
	return
	}

	// CHECK-LABEL: func @high_dim_permute()
	func @high_dim_permute() {
	// CHECK-NOT: memref<64x128x256xf32,
	%A = memref.alloc() : memref<64x128x256xf32, affine_map<(d0, d1, d2) -> (d2, d0, d1)>>
	// CHECK: %[[I:arg[0-9]+]]
	affine.for %i = 0 to 64 {
	// CHECK: %[[J:arg[0-9]+]]
	affine.for %j = 0 to 128 {
	// CHECK: %[[K:arg[0-9]+]]
	affine.for %k = 0 to 256 {
	%1 = affine.load %A[%i, %j, %k] : memref<64x128x256xf32, affine_map<(d0, d1, d2) -> (d2, d0, d1)>>
	// CHECK: %{{.}} = affine.load %{{.}}[%[[K]], %[[I]], %[[J]]] : memref<256x64x128xf32>
	"prevent.dce"(%1) : (f32) -> ()
	}
	}
	}
	return
	}

	// CHECK-LABEL: func @invalid_map
	func @invalid_map() {
	%A = memref.alloc() : memref<64x128xf32, affine_map<(d0, d1) -> (d0, -d1 - 10)>>
	// CHECK: %{{.*}} = memref.alloc() : memref<64x128xf32,
	return
	}

	// A tiled layout.
	// CHECK-LABEL: func @data_tiling
	func @data_tiling(%idx : index) {
	// CHECK: memref.alloc() : memref<8x32x8x16xf32>
	%A = memref.alloc() : memref<64x512xf32, affine_map<(d0, d1) -> (d0 floordiv 8, d1 floordiv 16, d0 mod 8, d1 mod 16)>>
	// CHECK: affine.load %{{.*}}[symbol(%arg0) floordiv 8, symbol(%arg0) floordiv 16, symbol(%arg0) mod 8, symbol(%arg0) mod 16]
	%1 = affine.load %A[%idx, %idx] : memref<64x512xf32, affine_map<(d0, d1) -> (d0 floordiv 8, d1 floordiv 16, d0 mod 8, d1 mod 16)>>
	"prevent.dce"(%1) : (f32) -> ()
	return
	}

	// Strides 2 and 4 along respective dimensions.
	// CHECK-LABEL: func @strided
	func @strided() {
	%A = memref.alloc() : memref<64x128xf32, affine_map<(d0, d1) -> (2d0, 4d1)>>
	// CHECK: affine.for %[[IV0:.*]] =
	affine.for %i = 0 to 64 {
	// CHECK: affine.for %[[IV1:.*]] =
	affine.for %j = 0 to 128 {
	// CHECK: affine.load %{{.}}[%[[IV0]] 2, %[[IV1]] * 4] : memref<127x509xf32>
	%1 = affine.load %A[%i, %j] : memref<64x128xf32, affine_map<(d0, d1) -> (2d0, 4d1)>>
	"prevent.dce"(%1) : (f32) -> ()
	}
	}
	return
	}

	// Strided, but the strides are in the linearized space.
	// CHECK-LABEL: func @strided_cumulative
	func @strided_cumulative() {
	%A = memref.alloc() : memref<2x5xf32, affine_map<(d0, d1) -> (3d0 + 17d1)>>
	// CHECK: affine.for %[[IV0:.*]] =
	affine.for %i = 0 to 2 {
	// CHECK: affine.for %[[IV1:.*]] =
	affine.for %j = 0 to 5 {
	// CHECK: affine.load %{{.}}[%[[IV0]] 3 + %[[IV1]] * 17] : memref<72xf32>
	%1 = affine.load %A[%i, %j] : memref<2x5xf32, affine_map<(d0, d1) -> (3d0 + 17d1)>>
	"prevent.dce"(%1) : (f32) -> ()
	}
	}
	return
	}

	// Symbolic operand for alloc, although unused. Tests replaceAllMemRefUsesWith
	// when the index remap has symbols.
	// CHECK-LABEL: func @symbolic_operands
	func @symbolic_operands(%s : index) {
	// CHECK: memref.alloc() : memref<100xf32>
	%A = memref.alloc()[%s] : memref<10x10xf32, affine_map<(d0,d1)[s0] -> (10*d0 + d1)>>
	affine.for %i = 0 to 10 {
	affine.for %j = 0 to 10 {
	// CHECK: affine.load %{{.}}[%{{.}} * 10 + %{{.*}}] : memref<100xf32>
	%1 = affine.load %A[%i, %j] : memref<10x10xf32, affine_map<(d0,d1)[s0] -> (10*d0 + d1)>>
	"prevent.dce"(%1) : (f32) -> ()
	}
	}
	return
	}

	// Semi-affine maps, normalization not implemented yet.
	// CHECK-LABEL: func @semi_affine_layout_map
	func @semi_affine_layout_map(%s0: index, %s1: index) {
	%A = memref.alloc()[%s0, %s1] : memref<256x1024xf32, affine_map<(d0, d1)[s0, s1] -> (d0s0 + d1s1)>>
	affine.for %i = 0 to 256 {
	affine.for %j = 0 to 1024 {
	// CHECK: memref<256x1024xf32, #map{{[0-9]+}}>
	affine.load %A[%i, %j] : memref<256x1024xf32, affine_map<(d0, d1)[s0, s1] -> (d0s0 + d1s1)>>
	}
	}
	return
	}

	// CHECK-LABEL: func @alignment
	func @alignment() {
	%A = memref.alloc() {alignment = 32 : i64}: memref<64x128x256xf32, affine_map<(d0, d1, d2) -> (d2, d0, d1)>>
	// CHECK-NEXT: memref.alloc() {alignment = 32 : i64} : memref<256x64x128xf32>
	return
	}

	#tile = affine_map < (i)->(i floordiv 4, i mod 4) >

	// Following test cases check the inter-procedural memref normalization.

	// Test case 1: Check normalization for multiple memrefs in a function argument list.
	// CHECK-LABEL: func @multiple_argument_type
	// CHECK-SAME: (%[[A:arg[0-9]+]]: memref<4x4xf64>, %[[B:arg[0-9]+]]: f64, %[[C:arg[0-9]+]]: memref<2x4xf64>, %[[D:arg[0-9]+]]: memref<24xf64>) -> f64
	func @multiple_argument_type(%A: memref<16xf64, #tile>, %B: f64, %C: memref<8xf64, #tile>, %D: memref<24xf64>) -> f64 {
	%a = affine.load %A[0] : memref<16xf64, #tile>
	%p = arith.mulf %a, %a : f64
	affine.store %p, %A[10] : memref<16xf64, #tile>
	call @single_argument_type(%C): (memref<8xf64, #tile>) -> ()
	return %B : f64
	}

	// CHECK: %[[a:[0-9]+]] = affine.load %[[A]][0, 0] : memref<4x4xf64>
	// CHECK: %[[p:[0-9]+]] = arith.mulf %[[a]], %[[a]] : f64
	// CHECK: affine.store %[[p]], %[[A]][2, 2] : memref<4x4xf64>
	// CHECK: call @single_argument_type(%[[C]]) : (memref<2x4xf64>) -> ()
	// CHECK: return %[[B]] : f64

	// Test case 2: Check normalization for single memref argument in a function.
	// CHECK-LABEL: func @single_argument_type
	// CHECK-SAME: (%[[C:arg[0-9]+]]: memref<2x4xf64>)
	func @single_argument_type(%C : memref<8xf64, #tile>) {
	%a = memref.alloc(): memref<8xf64, #tile>
	%b = memref.alloc(): memref<16xf64, #tile>
	%d = arith.constant 23.0 : f64
	%e = memref.alloc(): memref<24xf64>
	call @single_argument_type(%a): (memref<8xf64, #tile>) -> ()
	call @single_argument_type(%C): (memref<8xf64, #tile>) -> ()
	call @multiple_argument_type(%b, %d, %a, %e): (memref<16xf64, #tile>, f64, memref<8xf64, #tile>, memref<24xf64>) -> f64
	return
	}

	// CHECK: %[[a:[0-9]+]] = memref.alloc() : memref<2x4xf64>
	// CHECK: %[[b:[0-9]+]] = memref.alloc() : memref<4x4xf64>
	// CHECK: %cst = arith.constant 2.300000e+01 : f64
	// CHECK: %[[e:[0-9]+]] = memref.alloc() : memref<24xf64>
	// CHECK: call @single_argument_type(%[[a]]) : (memref<2x4xf64>) -> ()
	// CHECK: call @single_argument_type(%[[C]]) : (memref<2x4xf64>) -> ()
	// CHECK: call @multiple_argument_type(%[[b]], %cst, %[[a]], %[[e]]) : (memref<4x4xf64>, f64, memref<2x4xf64>, memref<24xf64>) -> f64

	// Test case 3: Check function returning any other type except memref.
	// CHECK-LABEL: func @non_memref_ret
	// CHECK-SAME: (%[[C:arg[0-9]+]]: memref<2x4xf64>) -> i1
	func @non_memref_ret(%A: memref<8xf64, #tile>) -> i1 {
	%d = arith.constant 1 : i1
	return %d : i1
	}

	// Test cases here onwards deal with normalization of memref in function signature, caller site.

	// Test case 4: Check successful memref normalization in case of inter/intra-recursive calls.
	// CHECK-LABEL: func @ret_multiple_argument_type
	// CHECK-SAME: (%[[A:arg[0-9]+]]: memref<4x4xf64>, %[[B:arg[0-9]+]]: f64, %[[C:arg[0-9]+]]: memref<2x4xf64>) -> (memref<2x4xf64>, f64)
	func @ret_multiple_argument_type(%A: memref<16xf64, #tile>, %B: f64, %C: memref<8xf64, #tile>) -> (memref<8xf64, #tile>, f64) {
	%a = affine.load %A[0] : memref<16xf64, #tile>
	%p = arith.mulf %a, %a : f64
	%cond = arith.constant 1 : i1
	cond_br %cond, ^bb1, ^bb2
	^bb1:
	%res1, %res2 = call @ret_single_argument_type(%C) : (memref<8xf64, #tile>) -> (memref<16xf64, #tile>, memref<8xf64, #tile>)
	return %res2, %p: memref<8xf64, #tile>, f64
	^bb2:
	return %C, %p: memref<8xf64, #tile>, f64
	}

	// CHECK: %[[a:[0-9]+]] = affine.load %[[A]][0, 0] : memref<4x4xf64>
	// CHECK: %[[p:[0-9]+]] = arith.mulf %[[a]], %[[a]] : f64
	// CHECK: %true = arith.constant true
	// CHECK: cond_br %true, ^bb1, ^bb2
	// CHECK: ^bb1: // pred: ^bb0
	// CHECK: %[[res:[0-9]+]]:2 = call @ret_single_argument_type(%[[C]]) : (memref<2x4xf64>) -> (memref<4x4xf64>, memref<2x4xf64>)
	// CHECK: return %[[res]]#1, %[[p]] : memref<2x4xf64>, f64
	// CHECK: ^bb2: // pred: ^bb0
	// CHECK: return %{{.}}, %{{.}} : memref<2x4xf64>, f64

	// CHECK-LABEL: func @ret_single_argument_type
	// CHECK-SAME: (%[[C:arg[0-9]+]]: memref<2x4xf64>) -> (memref<4x4xf64>, memref<2x4xf64>)
	func @ret_single_argument_type(%C: memref<8xf64, #tile>) -> (memref<16xf64, #tile>, memref<8xf64, #tile>){
	%a = memref.alloc() : memref<8xf64, #tile>
	%b = memref.alloc() : memref<16xf64, #tile>
	%d = arith.constant 23.0 : f64
	call @ret_single_argument_type(%a) : (memref<8xf64, #tile>) -> (memref<16xf64, #tile>, memref<8xf64, #tile>)
	call @ret_single_argument_type(%C) : (memref<8xf64, #tile>) -> (memref<16xf64, #tile>, memref<8xf64, #tile>)
	%res1, %res2 = call @ret_multiple_argument_type(%b, %d, %a) : (memref<16xf64, #tile>, f64, memref<8xf64, #tile>) -> (memref<8xf64, #tile>, f64)
	%res3, %res4 = call @ret_single_argument_type(%res1) : (memref<8xf64, #tile>) -> (memref<16xf64, #tile>, memref<8xf64, #tile>)
	return %b, %a: memref<16xf64, #tile>, memref<8xf64, #tile>
	}

	// CHECK: %[[a:[0-9]+]] = memref.alloc() : memref<2x4xf64>
	// CHECK: %[[b:[0-9]+]] = memref.alloc() : memref<4x4xf64>
	// CHECK: %cst = arith.constant 2.300000e+01 : f64
	// CHECK: %[[resA:[0-9]+]]:2 = call @ret_single_argument_type(%[[a]]) : (memref<2x4xf64>) -> (memref<4x4xf64>, memref<2x4xf64>)
	// CHECK: %[[resB:[0-9]+]]:2 = call @ret_single_argument_type(%[[C]]) : (memref<2x4xf64>) -> (memref<4x4xf64>, memref<2x4xf64>)
	// CHECK: %[[resC:[0-9]+]]:2 = call @ret_multiple_argument_type(%[[b]], %cst, %[[a]]) : (memref<4x4xf64>, f64, memref<2x4xf64>) -> (memref<2x4xf64>, f64)
	// CHECK: %[[resD:[0-9]+]]:2 = call @ret_single_argument_type(%[[resC]]#0) : (memref<2x4xf64>) -> (memref<4x4xf64>, memref<2x4xf64>)
	// CHECK: return %{{.}}, %{{.}} : memref<4x4xf64>, memref<2x4xf64>

	// Test case set #5: To check normalization in a chain of interconnected functions.
	// CHECK-LABEL: func @func_A
	// CHECK-SAME: (%[[A:arg[0-9]+]]: memref<2x4xf64>)
	func @func_A(%A: memref<8xf64, #tile>) {
	call @func_B(%A) : (memref<8xf64, #tile>) -> ()
	return
	}
	// CHECK: call @func_B(%[[A]]) : (memref<2x4xf64>) -> ()

	// CHECK-LABEL: func @func_B
	// CHECK-SAME: (%[[A:arg[0-9]+]]: memref<2x4xf64>)
	func @func_B(%A: memref<8xf64, #tile>) {
	call @func_C(%A) : (memref<8xf64, #tile>) -> ()
	return
	}
	// CHECK: call @func_C(%[[A]]) : (memref<2x4xf64>) -> ()

	// CHECK-LABEL: func @func_C
	// CHECK-SAME: (%[[A:arg[0-9]+]]: memref<2x4xf64>)
	func @func_C(%A: memref<8xf64, #tile>) {
	return
	}

	// Test case set #6: Checking if no normalization takes place in a scenario: A -> B -> C and B has an unsupported type.
	// CHECK-LABEL: func @some_func_A
	// CHECK-SAME: (%[[A:arg[0-9]+]]: memref<8xf64, #map{{[0-9]+}}>)
	func @some_func_A(%A: memref<8xf64, #tile>) {
	call @some_func_B(%A) : (memref<8xf64, #tile>) -> ()
	return
	}
	// CHECK: call @some_func_B(%[[A]]) : (memref<8xf64, #map{{[0-9]+}}>) -> ()

	// CHECK-LABEL: func @some_func_B
	// CHECK-SAME: (%[[A:arg[0-9]+]]: memref<8xf64, #map{{[0-9]+}}>)
	func @some_func_B(%A: memref<8xf64, #tile>) {
	"test.test"(%A) : (memref<8xf64, #tile>) -> ()
	call @some_func_C(%A) : (memref<8xf64, #tile>) -> ()
	return
	}
	// CHECK: call @some_func_C(%[[A]]) : (memref<8xf64, #map{{[0-9]+}}>) -> ()

	// CHECK-LABEL: func @some_func_C
	// CHECK-SAME: (%[[A:arg[0-9]+]]: memref<8xf64, #map{{[0-9]+}}>)
	func @some_func_C(%A: memref<8xf64, #tile>) {
	return
	}

	// Test case set #7: Check normalization in case of external functions.
	// CHECK-LABEL: func private @external_func_A
	// CHECK-SAME: (memref<4x4xf64>)
	func private @external_func_A(memref<16xf64, #tile>) -> ()

	// CHECK-LABEL: func private @external_func_B
	// CHECK-SAME: (memref<4x4xf64>, f64) -> memref<2x4xf64>
	func private @external_func_B(memref<16xf64, #tile>, f64) -> (memref<8xf64, #tile>)

	// CHECK-LABEL: func @simply_call_external()
	func @simply_call_external() {
	%a = memref.alloc() : memref<16xf64, #tile>
	call @external_func_A(%a) : (memref<16xf64, #tile>) -> ()
	return
	}
	// CHECK: %[[a:[0-9]+]] = memref.alloc() : memref<4x4xf64>
	// CHECK: call @external_func_A(%[[a]]) : (memref<4x4xf64>) -> ()

	// CHECK-LABEL: func @use_value_of_external
	// CHECK-SAME: (%[[A:arg[0-9]+]]: memref<4x4xf64>, %[[B:arg[0-9]+]]: f64) -> memref<2x4xf64>
	func @use_value_of_external(%A: memref<16xf64, #tile>, %B: f64) -> (memref<8xf64, #tile>) {
	%res = call @external_func_B(%A, %B) : (memref<16xf64, #tile>, f64) -> (memref<8xf64, #tile>)
	return %res : memref<8xf64, #tile>
	}
	// CHECK: %[[res:[0-9]+]] = call @external_func_B(%[[A]], %[[B]]) : (memref<4x4xf64>, f64) -> memref<2x4xf64>
	// CHECK: return %{{.*}} : memref<2x4xf64>

	// CHECK-LABEL: func @affine_parallel_norm
	func @affine_parallel_norm() -> memref<8xf32, #tile> {
	%c = arith.constant 23.0 : f32
	%a = memref.alloc() : memref<8xf32, #tile>
	// CHECK: affine.parallel (%{{.*}}) = (0) to (8) reduce ("assign") -> (memref<2x4xf32>)
	%1 = affine.parallel (%i) = (0) to (8) reduce ("assign") -> memref<8xf32, #tile> {
	affine.store %c, %a[%i] : memref<8xf32, #tile>
	// CHECK: affine.yield %{{.*}} : memref<2x4xf32>
	affine.yield %a : memref<8xf32, #tile>
	}
	return %1 : memref<8xf32, #tile>
	}