test/Dialect/MemRef/emulate-wide-int.mlir - llvm-project/mlir - Git at Google

 // RUN: mlir-opt --memref-emulate-wide-int="widest-int-supported=32" %s | FileCheck %s

 // Expect no conversions, i32 is supported.
 // CHECK-LABEL: func @memref_i32
 // CHECK:         [[M:%.+]] = memref.alloc() : memref<4xi32, 1>
 // CHECK-NEXT:    [[V:%.+]] = memref.load [[M]][{{%.+}}] : memref<4xi32, 1>
 // CHECK-NEXT:    memref.store {{%.+}}, [[M]][{{%.+}}] : memref<4xi32, 1>
 // CHECK-NEXT:    return
 func.func @memref_i32() {
     %c0 = arith.constant 0 : index
     %c1 = arith.constant 1 : i32
     %m = memref.alloc() : memref<4xi32, 1>
     %v = memref.load %m[%c0] : memref<4xi32, 1>
     memref.store %c1, %m[%c0] : memref<4xi32, 1>
     return
 }

 // Expect no conversions, f64 is not an integer type.
 // CHECK-LABEL: func @memref_f32
 // CHECK:         [[M:%.+]] = memref.alloc() : memref<4xf32, 1>
 // CHECK-NEXT:    [[V:%.+]] = memref.load [[M]][{{%.+}}] : memref<4xf32, 1>
 // CHECK-NEXT:    memref.store {{%.+}}, [[M]][{{%.+}}] : memref<4xf32, 1>
 // CHECK-NEXT:    return
 func.func @memref_f32() {
     %c0 = arith.constant 0 : index
     %c1 = arith.constant 1.0 : f32
     %m = memref.alloc() : memref<4xf32, 1>
     %v = memref.load %m[%c0] : memref<4xf32, 1>
     memref.store %c1, %m[%c0] : memref<4xf32, 1>
     return
 }

 // CHECK-LABEL: func @alloc_load_store_i64
 // CHECK:         [[C1:%.+]] = arith.constant dense<[1, 0]> : vector<2xi32>
 // CHECK-NEXT:    [[M:%.+]]  = memref.alloc() : memref<4xvector<2xi32>, 1>
 // CHECK-NEXT:    [[V:%.+]]  = memref.load [[M]][{{%.+}}] : memref<4xvector<2xi32>, 1>
 // CHECK-NEXT:    memref.store [[C1]], [[M]][{{%.+}}] : memref<4xvector<2xi32>, 1>
 // CHECK-NEXT:    return
 func.func @alloc_load_store_i64() {
     %c0 = arith.constant 0 : index
     %c1 = arith.constant 1 : i64
     %m = memref.alloc() : memref<4xi64, 1>
     %v = memref.load %m[%c0] : memref<4xi64, 1>
     memref.store %c1, %m[%c0] : memref<4xi64, 1>
     return
 }


 // CHECK-LABEL: func @alloc_load_store_i64_nontemporal
 // CHECK:         [[C1:%.+]] = arith.constant dense<[1, 0]> : vector<2xi32>
 // CHECK-NEXT:    [[M:%.+]]  = memref.alloc() : memref<4xvector<2xi32>, 1>
 // CHECK-NEXT:    [[V:%.+]]  = memref.load [[M]][{{%.+}}] {nontemporal = true} : memref<4xvector<2xi32>, 1>
 // CHECK-NEXT:    memref.store [[C1]], [[M]][{{%.+}}] {nontemporal = true} : memref<4xvector<2xi32>, 1>
 // CHECK-NEXT:    return
 func.func @alloc_load_store_i64_nontemporal() {
     %c0 = arith.constant 0 : index
     %c1 = arith.constant 1 : i64
     %m = memref.alloc() : memref<4xi64, 1>
     %v = memref.load %m[%c0] {nontemporal = true} : memref<4xi64, 1>
     memref.store %c1, %m[%c0] {nontemporal = true} : memref<4xi64, 1>
     return
 }
	// RUN: mlir-opt --memref-emulate-wide-int="widest-int-supported=32" %s \| FileCheck %s

	// Expect no conversions, i32 is supported.
	// CHECK-LABEL: func @memref_i32
	// CHECK: [[M:%.+]] = memref.alloc() : memref<4xi32, 1>
	// CHECK-NEXT: [[V:%.+]] = memref.load [[M]][{{%.+}}] : memref<4xi32, 1>
	// CHECK-NEXT: memref.store {{%.+}}, [[M]][{{%.+}}] : memref<4xi32, 1>
	// CHECK-NEXT: return
	func.func @memref_i32() {
	%c0 = arith.constant 0 : index
	%c1 = arith.constant 1 : i32
	%m = memref.alloc() : memref<4xi32, 1>
	%v = memref.load %m[%c0] : memref<4xi32, 1>
	memref.store %c1, %m[%c0] : memref<4xi32, 1>
	return
	}

	// Expect no conversions, f64 is not an integer type.
	// CHECK-LABEL: func @memref_f32
	// CHECK: [[M:%.+]] = memref.alloc() : memref<4xf32, 1>
	// CHECK-NEXT: [[V:%.+]] = memref.load [[M]][{{%.+}}] : memref<4xf32, 1>
	// CHECK-NEXT: memref.store {{%.+}}, [[M]][{{%.+}}] : memref<4xf32, 1>
	// CHECK-NEXT: return
	func.func @memref_f32() {
	%c0 = arith.constant 0 : index
	%c1 = arith.constant 1.0 : f32
	%m = memref.alloc() : memref<4xf32, 1>
	%v = memref.load %m[%c0] : memref<4xf32, 1>
	memref.store %c1, %m[%c0] : memref<4xf32, 1>
	return
	}

	// CHECK-LABEL: func @alloc_load_store_i64
	// CHECK: [[C1:%.+]] = arith.constant dense<[1, 0]> : vector<2xi32>
	// CHECK-NEXT: [[M:%.+]] = memref.alloc() : memref<4xvector<2xi32>, 1>
	// CHECK-NEXT: [[V:%.+]] = memref.load [[M]][{{%.+}}] : memref<4xvector<2xi32>, 1>
	// CHECK-NEXT: memref.store [[C1]], [[M]][{{%.+}}] : memref<4xvector<2xi32>, 1>
	// CHECK-NEXT: return
	func.func @alloc_load_store_i64() {
	%c0 = arith.constant 0 : index
	%c1 = arith.constant 1 : i64
	%m = memref.alloc() : memref<4xi64, 1>
	%v = memref.load %m[%c0] : memref<4xi64, 1>
	memref.store %c1, %m[%c0] : memref<4xi64, 1>
	return
	}


	// CHECK-LABEL: func @alloc_load_store_i64_nontemporal
	// CHECK: [[C1:%.+]] = arith.constant dense<[1, 0]> : vector<2xi32>
	// CHECK-NEXT: [[M:%.+]] = memref.alloc() : memref<4xvector<2xi32>, 1>
	// CHECK-NEXT: [[V:%.+]] = memref.load [[M]][{{%.+}}] {nontemporal = true} : memref<4xvector<2xi32>, 1>
	// CHECK-NEXT: memref.store [[C1]], [[M]][{{%.+}}] {nontemporal = true} : memref<4xvector<2xi32>, 1>
	// CHECK-NEXT: return
	func.func @alloc_load_store_i64_nontemporal() {
	%c0 = arith.constant 0 : index
	%c1 = arith.constant 1 : i64
	%m = memref.alloc() : memref<4xi64, 1>
	%v = memref.load %m[%c0] {nontemporal = true} : memref<4xi64, 1>
	memref.store %c1, %m[%c0] {nontemporal = true} : memref<4xi64, 1>
	return
	}