mlir/test/Transforms/cse.mlir - toolchain/llvm-project - Git at Google

 // RUN: mlir-opt -allow-unregistered-dialect %s -pass-pipeline='func(cse)' | FileCheck %s

 // CHECK-DAG: #[[$MAP:.*]] = affine_map<(d0) -> (d0 mod 2)>
 #map0 = affine_map<(d0) -> (d0 mod 2)>

 // CHECK-LABEL: @simple_constant
 func @simple_constant() -> (i32, i32) {
   // CHECK-NEXT: %c1_i32 = constant 1 : i32
   %0 = constant 1 : i32

   // CHECK-NEXT: return %c1_i32, %c1_i32 : i32, i32
   %1 = constant 1 : i32
   return %0, %1 : i32, i32
 }

 // CHECK-LABEL: @basic
 func @basic() -> (index, index) {
   // CHECK: %c0 = constant 0 : index
   %c0 = constant 0 : index
   %c1 = constant 0 : index

   // CHECK-NEXT: %0 = affine.apply #[[$MAP]](%c0)
   %0 = affine.apply #map0(%c0)
   %1 = affine.apply #map0(%c1)

   // CHECK-NEXT: return %0, %0 : index, index
   return %0, %1 : index, index
 }

 // CHECK-LABEL: @many
 func @many(f32, f32) -> (f32) {
 ^bb0(%a : f32, %b : f32):
   // CHECK-NEXT: %0 = addf %arg0, %arg1 : f32
   %c = addf %a, %b : f32
   %d = addf %a, %b : f32
   %e = addf %a, %b : f32
   %f = addf %a, %b : f32

   // CHECK-NEXT: %1 = addf %0, %0 : f32
   %g = addf %c, %d : f32
   %h = addf %e, %f : f32
   %i = addf %c, %e : f32

   // CHECK-NEXT: %2 = addf %1, %1 : f32
   %j = addf %g, %h : f32
   %k = addf %h, %i : f32

   // CHECK-NEXT: %3 = addf %2, %2 : f32
   %l = addf %j, %k : f32

   // CHECK-NEXT: return %3 : f32
   return %l : f32
 }

 /// Check that operations are not eliminated if they have different operands.
 // CHECK-LABEL: @different_ops
 func @different_ops() -> (i32, i32) {
   // CHECK: %c0_i32 = constant 0 : i32
   // CHECK: %c1_i32 = constant 1 : i32
   %0 = constant 0 : i32
   %1 = constant 1 : i32

   // CHECK-NEXT: return %c0_i32, %c1_i32 : i32, i32
   return %0, %1 : i32, i32
 }

 /// Check that operations are not eliminated if they have different result
 /// types.
 // CHECK-LABEL: @different_results
 func @different_results(%arg0: tensor<*xf32>) -> (tensor<?x?xf32>, tensor<4x?xf32>) {
   // CHECK: %0 = tensor_cast %arg0 : tensor<*xf32> to tensor<?x?xf32>
   // CHECK-NEXT: %1 = tensor_cast %arg0 : tensor<*xf32> to tensor<4x?xf32>
   %0 = tensor_cast %arg0 : tensor<*xf32> to tensor<?x?xf32>
   %1 = tensor_cast %arg0 : tensor<*xf32> to tensor<4x?xf32>

   // CHECK-NEXT: return %0, %1 : tensor<?x?xf32>, tensor<4x?xf32>
   return %0, %1 : tensor<?x?xf32>, tensor<4x?xf32>
 }

 /// Check that operations are not eliminated if they have different attributes.
 // CHECK-LABEL: @different_attributes
 func @different_attributes(index, index) -> (i1, i1, i1) {
 ^bb0(%a : index, %b : index):
   // CHECK: %0 = cmpi "slt", %arg0, %arg1 : index
   %0 = cmpi "slt", %a, %b : index

   // CHECK-NEXT: %1 = cmpi "ne", %arg0, %arg1 : index
   /// Predicate 1 means inequality comparison.
   %1 = cmpi "ne", %a, %b : index
   %2 = "std.cmpi"(%a, %b) {predicate = 1} : (index, index) -> i1

   // CHECK-NEXT: return %0, %1, %1 : i1, i1, i1
   return %0, %1, %2 : i1, i1, i1
 }

 /// Check that operations with side effects are not eliminated.
 // CHECK-LABEL: @side_effect
 func @side_effect() -> (memref<2x1xf32>, memref<2x1xf32>) {
   // CHECK: %0 = alloc() : memref<2x1xf32>
   %0 = alloc() : memref<2x1xf32>

   // CHECK-NEXT: %1 = alloc() : memref<2x1xf32>
   %1 = alloc() : memref<2x1xf32>

   // CHECK-NEXT: return %0, %1 : memref<2x1xf32>, memref<2x1xf32>
   return %0, %1 : memref<2x1xf32>, memref<2x1xf32>
 }

 /// Check that operation definitions are properly propagated down the dominance
 /// tree.
 // CHECK-LABEL: @down_propagate_for
 func @down_propagate_for() {
   // CHECK: %c1_i32 = constant 1 : i32
   %0 = constant 1 : i32

   // CHECK-NEXT: affine.for {{.*}} = 0 to 4 {
   affine.for %i = 0 to 4 {
     // CHECK-NEXT: "foo"(%c1_i32, %c1_i32) : (i32, i32) -> ()
     %1 = constant 1 : i32
     "foo"(%0, %1) : (i32, i32) -> ()
   }
   return
 }

 // CHECK-LABEL: @down_propagate
 func @down_propagate() -> i32 {
   // CHECK-NEXT: %c1_i32 = constant 1 : i32
   %0 = constant 1 : i32

   // CHECK-NEXT: %true = constant true
   %cond = constant true

   // CHECK-NEXT: cond_br %true, ^bb1, ^bb2(%c1_i32 : i32)
   cond_br %cond, ^bb1, ^bb2(%0 : i32)

 ^bb1: // CHECK: ^bb1:
   // CHECK-NEXT: br ^bb2(%c1_i32 : i32)
   %1 = constant 1 : i32
   br ^bb2(%1 : i32)

 ^bb2(%arg : i32):
   return %arg : i32
 }

 /// Check that operation definitions are NOT propagated up the dominance tree.
 // CHECK-LABEL: @up_propagate_for
 func @up_propagate_for() -> i32 {
   // CHECK: affine.for {{.*}} = 0 to 4 {
   affine.for %i = 0 to 4 {
     // CHECK-NEXT: %c1_i32_0 = constant 1 : i32
     // CHECK-NEXT: "foo"(%c1_i32_0) : (i32) -> ()
     %0 = constant 1 : i32
     "foo"(%0) : (i32) -> ()
   }

   // CHECK: %c1_i32 = constant 1 : i32
   // CHECK-NEXT: return %c1_i32 : i32
   %1 = constant 1 : i32
   return %1 : i32
 }

 // CHECK-LABEL: func @up_propagate
 func @up_propagate() -> i32 {
   // CHECK-NEXT:  %c0_i32 = constant 0 : i32
   %0 = constant 0 : i32

   // CHECK-NEXT: %true = constant true
   %cond = constant true

   // CHECK-NEXT: cond_br %true, ^bb1, ^bb2(%c0_i32 : i32)
   cond_br %cond, ^bb1, ^bb2(%0 : i32)

 ^bb1: // CHECK: ^bb1:
   // CHECK-NEXT: %c1_i32 = constant 1 : i32
   %1 = constant 1 : i32

   // CHECK-NEXT: br ^bb2(%c1_i32 : i32)
   br ^bb2(%1 : i32)

 ^bb2(%arg : i32): // CHECK: ^bb2
   // CHECK-NEXT: %c1_i32_0 = constant 1 : i32
   %2 = constant 1 : i32

   // CHECK-NEXT: %1 = addi %0, %c1_i32_0 : i32
   %add = addi %arg, %2 : i32

   // CHECK-NEXT: return %1 : i32
   return %add : i32
 }

 /// The same test as above except that we are testing on a cfg embedded within
 /// an operation region.
 // CHECK-LABEL: func @up_propagate_region
 func @up_propagate_region() -> i32 {
   // CHECK-NEXT: %0 = "foo.region"
   %0 = "foo.region"() ({
     // CHECK-NEXT:  %c0_i32 = constant 0 : i32
     // CHECK-NEXT: %true = constant true
     // CHECK-NEXT: cond_br

     %1 = constant 0 : i32
     %true = constant true
     cond_br %true, ^bb1, ^bb2(%1 : i32)

   ^bb1: // CHECK: ^bb1:
     // CHECK-NEXT: %c1_i32 = constant 1 : i32
     // CHECK-NEXT: br

     %c1_i32 = constant 1 : i32
     br ^bb2(%c1_i32 : i32)

   ^bb2(%arg : i32): // CHECK: ^bb2(%1: i32):
     // CHECK-NEXT: %c1_i32_0 = constant 1 : i32
     // CHECK-NEXT: %2 = addi %1, %c1_i32_0 : i32
     // CHECK-NEXT: "foo.yield"(%2) : (i32) -> ()

     %c1_i32_0 = constant 1 : i32
     %2 = addi %arg, %c1_i32_0 : i32
     "foo.yield" (%2) : (i32) -> ()
   }) : () -> (i32)
   return %0 : i32
 }

 /// This test checks that nested regions that are isolated from above are
 /// properly handled.
 // CHECK-LABEL: @nested_isolated
 func @nested_isolated() -> i32 {
   // CHECK-NEXT: constant 1
   %0 = constant 1 : i32

   // CHECK-NEXT: @nested_func
   func @nested_func() {
     // CHECK-NEXT: constant 1
     %foo = constant 1 : i32
     "foo.yield"(%foo) : (i32) -> ()
   }

   // CHECK: "foo.region"
   "foo.region"() ({
     // CHECK-NEXT: constant 1
     %foo = constant 1 : i32
     "foo.yield"(%foo) : (i32) -> ()
   }) : () -> ()

   return %0 : i32
 }
	// RUN: mlir-opt -allow-unregistered-dialect %s -pass-pipeline='func(cse)' \| FileCheck %s

	// CHECK-DAG: #[[$MAP:.*]] = affine_map<(d0) -> (d0 mod 2)>
	#map0 = affine_map<(d0) -> (d0 mod 2)>

	// CHECK-LABEL: @simple_constant
	func @simple_constant() -> (i32, i32) {
	// CHECK-NEXT: %c1_i32 = constant 1 : i32
	%0 = constant 1 : i32

	// CHECK-NEXT: return %c1_i32, %c1_i32 : i32, i32
	%1 = constant 1 : i32
	return %0, %1 : i32, i32
	}

	// CHECK-LABEL: @basic
	func @basic() -> (index, index) {
	// CHECK: %c0 = constant 0 : index
	%c0 = constant 0 : index
	%c1 = constant 0 : index

	// CHECK-NEXT: %0 = affine.apply #[[$MAP]](%c0)
	%0 = affine.apply #map0(%c0)
	%1 = affine.apply #map0(%c1)

	// CHECK-NEXT: return %0, %0 : index, index
	return %0, %1 : index, index
	}

	// CHECK-LABEL: @many
	func @many(f32, f32) -> (f32) {
	^bb0(%a : f32, %b : f32):
	// CHECK-NEXT: %0 = addf %arg0, %arg1 : f32
	%c = addf %a, %b : f32
	%d = addf %a, %b : f32
	%e = addf %a, %b : f32
	%f = addf %a, %b : f32

	// CHECK-NEXT: %1 = addf %0, %0 : f32
	%g = addf %c, %d : f32
	%h = addf %e, %f : f32
	%i = addf %c, %e : f32

	// CHECK-NEXT: %2 = addf %1, %1 : f32
	%j = addf %g, %h : f32
	%k = addf %h, %i : f32

	// CHECK-NEXT: %3 = addf %2, %2 : f32
	%l = addf %j, %k : f32

	// CHECK-NEXT: return %3 : f32
	return %l : f32
	}

	/// Check that operations are not eliminated if they have different operands.
	// CHECK-LABEL: @different_ops
	func @different_ops() -> (i32, i32) {
	// CHECK: %c0_i32 = constant 0 : i32
	// CHECK: %c1_i32 = constant 1 : i32
	%0 = constant 0 : i32
	%1 = constant 1 : i32

	// CHECK-NEXT: return %c0_i32, %c1_i32 : i32, i32
	return %0, %1 : i32, i32
	}

	/// Check that operations are not eliminated if they have different result
	/// types.
	// CHECK-LABEL: @different_results
	func @different_results(%arg0: tensor<*xf32>) -> (tensor<?x?xf32>, tensor<4x?xf32>) {
	// CHECK: %0 = tensor_cast %arg0 : tensor<*xf32> to tensor<?x?xf32>
	// CHECK-NEXT: %1 = tensor_cast %arg0 : tensor<*xf32> to tensor<4x?xf32>
	%0 = tensor_cast %arg0 : tensor<*xf32> to tensor<?x?xf32>
	%1 = tensor_cast %arg0 : tensor<*xf32> to tensor<4x?xf32>

	// CHECK-NEXT: return %0, %1 : tensor<?x?xf32>, tensor<4x?xf32>
	return %0, %1 : tensor<?x?xf32>, tensor<4x?xf32>
	}

	/// Check that operations are not eliminated if they have different attributes.
	// CHECK-LABEL: @different_attributes
	func @different_attributes(index, index) -> (i1, i1, i1) {
	^bb0(%a : index, %b : index):
	// CHECK: %0 = cmpi "slt", %arg0, %arg1 : index
	%0 = cmpi "slt", %a, %b : index

	// CHECK-NEXT: %1 = cmpi "ne", %arg0, %arg1 : index
	/// Predicate 1 means inequality comparison.
	%1 = cmpi "ne", %a, %b : index
	%2 = "std.cmpi"(%a, %b) {predicate = 1} : (index, index) -> i1

	// CHECK-NEXT: return %0, %1, %1 : i1, i1, i1
	return %0, %1, %2 : i1, i1, i1
	}

	/// Check that operations with side effects are not eliminated.
	// CHECK-LABEL: @side_effect
	func @side_effect() -> (memref<2x1xf32>, memref<2x1xf32>) {
	// CHECK: %0 = alloc() : memref<2x1xf32>
	%0 = alloc() : memref<2x1xf32>

	// CHECK-NEXT: %1 = alloc() : memref<2x1xf32>
	%1 = alloc() : memref<2x1xf32>

	// CHECK-NEXT: return %0, %1 : memref<2x1xf32>, memref<2x1xf32>
	return %0, %1 : memref<2x1xf32>, memref<2x1xf32>
	}

	/// Check that operation definitions are properly propagated down the dominance
	/// tree.
	// CHECK-LABEL: @down_propagate_for
	func @down_propagate_for() {
	// CHECK: %c1_i32 = constant 1 : i32
	%0 = constant 1 : i32

	// CHECK-NEXT: affine.for {{.*}} = 0 to 4 {
	affine.for %i = 0 to 4 {
	// CHECK-NEXT: "foo"(%c1_i32, %c1_i32) : (i32, i32) -> ()
	%1 = constant 1 : i32
	"foo"(%0, %1) : (i32, i32) -> ()
	}
	return
	}

	// CHECK-LABEL: @down_propagate
	func @down_propagate() -> i32 {
	// CHECK-NEXT: %c1_i32 = constant 1 : i32
	%0 = constant 1 : i32

	// CHECK-NEXT: %true = constant true
	%cond = constant true

	// CHECK-NEXT: cond_br %true, ^bb1, ^bb2(%c1_i32 : i32)
	cond_br %cond, ^bb1, ^bb2(%0 : i32)

	^bb1: // CHECK: ^bb1:
	// CHECK-NEXT: br ^bb2(%c1_i32 : i32)
	%1 = constant 1 : i32
	br ^bb2(%1 : i32)

	^bb2(%arg : i32):
	return %arg : i32
	}

	/// Check that operation definitions are NOT propagated up the dominance tree.
	// CHECK-LABEL: @up_propagate_for
	func @up_propagate_for() -> i32 {
	// CHECK: affine.for {{.*}} = 0 to 4 {
	affine.for %i = 0 to 4 {
	// CHECK-NEXT: %c1_i32_0 = constant 1 : i32
	// CHECK-NEXT: "foo"(%c1_i32_0) : (i32) -> ()
	%0 = constant 1 : i32
	"foo"(%0) : (i32) -> ()
	}

	// CHECK: %c1_i32 = constant 1 : i32
	// CHECK-NEXT: return %c1_i32 : i32
	%1 = constant 1 : i32
	return %1 : i32
	}

	// CHECK-LABEL: func @up_propagate
	func @up_propagate() -> i32 {
	// CHECK-NEXT: %c0_i32 = constant 0 : i32
	%0 = constant 0 : i32

	// CHECK-NEXT: %true = constant true
	%cond = constant true

	// CHECK-NEXT: cond_br %true, ^bb1, ^bb2(%c0_i32 : i32)
	cond_br %cond, ^bb1, ^bb2(%0 : i32)

	^bb1: // CHECK: ^bb1:
	// CHECK-NEXT: %c1_i32 = constant 1 : i32
	%1 = constant 1 : i32

	// CHECK-NEXT: br ^bb2(%c1_i32 : i32)
	br ^bb2(%1 : i32)

	^bb2(%arg : i32): // CHECK: ^bb2
	// CHECK-NEXT: %c1_i32_0 = constant 1 : i32
	%2 = constant 1 : i32

	// CHECK-NEXT: %1 = addi %0, %c1_i32_0 : i32
	%add = addi %arg, %2 : i32

	// CHECK-NEXT: return %1 : i32
	return %add : i32
	}

	/// The same test as above except that we are testing on a cfg embedded within
	/// an operation region.
	// CHECK-LABEL: func @up_propagate_region
	func @up_propagate_region() -> i32 {
	// CHECK-NEXT: %0 = "foo.region"
	%0 = "foo.region"() ({
	// CHECK-NEXT: %c0_i32 = constant 0 : i32
	// CHECK-NEXT: %true = constant true
	// CHECK-NEXT: cond_br

	%1 = constant 0 : i32
	%true = constant true
	cond_br %true, ^bb1, ^bb2(%1 : i32)

	^bb1: // CHECK: ^bb1:
	// CHECK-NEXT: %c1_i32 = constant 1 : i32
	// CHECK-NEXT: br

	%c1_i32 = constant 1 : i32
	br ^bb2(%c1_i32 : i32)

	^bb2(%arg : i32): // CHECK: ^bb2(%1: i32):
	// CHECK-NEXT: %c1_i32_0 = constant 1 : i32
	// CHECK-NEXT: %2 = addi %1, %c1_i32_0 : i32
	// CHECK-NEXT: "foo.yield"(%2) : (i32) -> ()

	%c1_i32_0 = constant 1 : i32
	%2 = addi %arg, %c1_i32_0 : i32
	"foo.yield" (%2) : (i32) -> ()
	}) : () -> (i32)
	return %0 : i32
	}

	/// This test checks that nested regions that are isolated from above are
	/// properly handled.
	// CHECK-LABEL: @nested_isolated
	func @nested_isolated() -> i32 {
	// CHECK-NEXT: constant 1
	%0 = constant 1 : i32

	// CHECK-NEXT: @nested_func
	func @nested_func() {
	// CHECK-NEXT: constant 1
	%foo = constant 1 : i32
	"foo.yield"(%foo) : (i32) -> ()
	}

	// CHECK: "foo.region"
	"foo.region"() ({
	// CHECK-NEXT: constant 1
	%foo = constant 1 : i32
	"foo.yield"(%foo) : (i32) -> ()
	}) : () -> ()

	return %0 : i32
	}