mlir/test/Conversion/ComplexToLLVM/full-conversion.mlir - llvm-project - Git at Google

 // RUN: mlir-opt %s -convert-complex-to-llvm -convert-std-to-llvm -reconcile-unrealized-casts | FileCheck %s

 // CHECK-LABEL: llvm.func @complex_div
 // CHECK-SAME:    %[[LHS:.*]]: ![[C_TY:.*>]], %[[RHS:.*]]: ![[C_TY]]) -> ![[C_TY]]
 func @complex_div(%lhs: complex<f32>, %rhs: complex<f32>) -> complex<f32> {
   %div = complex.div %lhs, %rhs : complex<f32>
   return %div : complex<f32>
 }
 // CHECK: %[[LHS_RE:.*]] = llvm.extractvalue %[[LHS]][0] : ![[C_TY]]
 // CHECK: %[[LHS_IM:.*]] = llvm.extractvalue %[[LHS]][1] : ![[C_TY]]
 // CHECK: %[[RHS_RE:.*]] = llvm.extractvalue %[[RHS]][0] : ![[C_TY]]
 // CHECK: %[[RHS_IM:.*]] = llvm.extractvalue %[[RHS]][1] : ![[C_TY]]

 // CHECK: %[[RESULT_0:.*]] = llvm.mlir.undef : ![[C_TY]]

 // CHECK-DAG: %[[RHS_RE_SQ:.*]] = llvm.fmul %[[RHS_RE]], %[[RHS_RE]]  : f32
 // CHECK-DAG: %[[RHS_IM_SQ:.*]] = llvm.fmul %[[RHS_IM]], %[[RHS_IM]]  : f32
 // CHECK: %[[SQ_NORM:.*]] = llvm.fadd %[[RHS_RE_SQ]], %[[RHS_IM_SQ]]  : f32

 // CHECK-DAG: %[[REAL_TMP_0:.*]] = llvm.fmul %[[LHS_RE]], %[[RHS_RE]]  : f32
 // CHECK-DAG: %[[REAL_TMP_1:.*]] = llvm.fmul %[[LHS_IM]], %[[RHS_IM]]  : f32
 // CHECK: %[[REAL_TMP_2:.*]] = llvm.fadd %[[REAL_TMP_0]], %[[REAL_TMP_1]]  : f32

 // CHECK-DAG: %[[IMAG_TMP_0:.*]] = llvm.fmul %[[LHS_IM]], %[[RHS_RE]]  : f32
 // CHECK-DAG: %[[IMAG_TMP_1:.*]] = llvm.fmul %[[LHS_RE]], %[[RHS_IM]]  : f32
 // CHECK: %[[IMAG_TMP_2:.*]] = llvm.fsub %[[IMAG_TMP_0]], %[[IMAG_TMP_1]]  : f32

 // CHECK: %[[REAL:.*]] = llvm.fdiv %[[REAL_TMP_2]], %[[SQ_NORM]]  : f32
 // CHECK: %[[RESULT_1:.*]] = llvm.insertvalue %[[REAL]], %[[RESULT_0]][0] : ![[C_TY]]
 // CHECK: %[[IMAG:.*]] = llvm.fdiv %[[IMAG_TMP_2]], %[[SQ_NORM]]  : f32
 // CHECK: %[[RESULT_2:.*]] = llvm.insertvalue %[[IMAG]], %[[RESULT_1]][1] : ![[C_TY]]
 // CHECK: llvm.return %[[RESULT_2]] : ![[C_TY]]

 // CHECK-LABEL: llvm.func @complex_mul
 // CHECK-SAME:    %[[LHS:.*]]: ![[C_TY:.*>]], %[[RHS:.*]]: ![[C_TY]]) -> ![[C_TY]]
 func @complex_mul(%lhs: complex<f32>, %rhs: complex<f32>) -> complex<f32> {
   %mul = complex.mul %lhs, %rhs : complex<f32>
   return %mul : complex<f32>
 }
 // CHECK: %[[LHS_RE:.*]] = llvm.extractvalue %[[LHS]][0] : ![[C_TY]]
 // CHECK: %[[LHS_IM:.*]] = llvm.extractvalue %[[LHS]][1] : ![[C_TY]]
 // CHECK: %[[RHS_RE:.*]] = llvm.extractvalue %[[RHS]][0] : ![[C_TY]]
 // CHECK: %[[RHS_IM:.*]] = llvm.extractvalue %[[RHS]][1] : ![[C_TY]]
 // CHECK: %[[RESULT_0:.*]] = llvm.mlir.undef : ![[C_TY]]

 // CHECK-DAG: %[[REAL_TMP_0:.*]] = llvm.fmul %[[RHS_RE]], %[[LHS_RE]]  : f32
 // CHECK-DAG: %[[REAL_TMP_1:.*]] = llvm.fmul %[[RHS_IM]], %[[LHS_IM]]  : f32
 // CHECK: %[[REAL:.*]] = llvm.fsub %[[REAL_TMP_0]], %[[REAL_TMP_1]]  : f32

 // CHECK-DAG: %[[IMAG_TMP_0:.*]] = llvm.fmul %[[LHS_IM]], %[[RHS_RE]]  : f32
 // CHECK-DAG: %[[IMAG_TMP_1:.*]] = llvm.fmul %[[LHS_RE]], %[[RHS_IM]]  : f32
 // CHECK: %[[IMAG:.*]] = llvm.fadd %[[IMAG_TMP_0]], %[[IMAG_TMP_1]]  : f32

 // CHECK: %[[RESULT_1:.*]] = llvm.insertvalue %[[REAL]], %[[RESULT_0]][0]
 // CHECK: %[[RESULT_2:.*]] = llvm.insertvalue %[[IMAG]], %[[RESULT_1]][1]
 // CHECK: llvm.return %[[RESULT_2]] : ![[C_TY]]

 // CHECK-LABEL: llvm.func @complex_abs
 // CHECK-SAME: %[[ARG:.*]]: ![[C_TY:.*]])
 func @complex_abs(%arg: complex<f32>) -> f32 {
   %abs = complex.abs %arg: complex<f32>
   return %abs : f32
 }
 // CHECK: %[[REAL:.*]] = llvm.extractvalue %[[ARG]][0] : ![[C_TY]]
 // CHECK: %[[IMAG:.*]] = llvm.extractvalue %[[ARG]][1] : ![[C_TY]]
 // CHECK-DAG: %[[REAL_SQ:.*]] = llvm.fmul %[[REAL]], %[[REAL]]  : f32
 // CHECK-DAG: %[[IMAG_SQ:.*]] = llvm.fmul %[[IMAG]], %[[IMAG]]  : f32
 // CHECK: %[[SQ_NORM:.*]] = llvm.fadd %[[REAL_SQ]], %[[IMAG_SQ]]  : f32
 // CHECK: %[[NORM:.*]] = "llvm.intr.sqrt"(%[[SQ_NORM]]) : (f32) -> f32
 // CHECK: llvm.return %[[NORM]] : f32
	// RUN: mlir-opt %s -convert-complex-to-llvm -convert-std-to-llvm -reconcile-unrealized-casts \| FileCheck %s

	// CHECK-LABEL: llvm.func @complex_div
	// CHECK-SAME: %[[LHS:.]]: ![[C_TY:.>]], %[[RHS:.*]]: ![[C_TY]]) -> ![[C_TY]]
	func @complex_div(%lhs: complex<f32>, %rhs: complex<f32>) -> complex<f32> {
	%div = complex.div %lhs, %rhs : complex<f32>
	return %div : complex<f32>
	}
	// CHECK: %[[LHS_RE:.*]] = llvm.extractvalue %[[LHS]][0] : ![[C_TY]]
	// CHECK: %[[LHS_IM:.*]] = llvm.extractvalue %[[LHS]][1] : ![[C_TY]]
	// CHECK: %[[RHS_RE:.*]] = llvm.extractvalue %[[RHS]][0] : ![[C_TY]]
	// CHECK: %[[RHS_IM:.*]] = llvm.extractvalue %[[RHS]][1] : ![[C_TY]]

	// CHECK: %[[RESULT_0:.*]] = llvm.mlir.undef : ![[C_TY]]

	// CHECK-DAG: %[[RHS_RE_SQ:.*]] = llvm.fmul %[[RHS_RE]], %[[RHS_RE]] : f32
	// CHECK-DAG: %[[RHS_IM_SQ:.*]] = llvm.fmul %[[RHS_IM]], %[[RHS_IM]] : f32
	// CHECK: %[[SQ_NORM:.*]] = llvm.fadd %[[RHS_RE_SQ]], %[[RHS_IM_SQ]] : f32

	// CHECK-DAG: %[[REAL_TMP_0:.*]] = llvm.fmul %[[LHS_RE]], %[[RHS_RE]] : f32
	// CHECK-DAG: %[[REAL_TMP_1:.*]] = llvm.fmul %[[LHS_IM]], %[[RHS_IM]] : f32
	// CHECK: %[[REAL_TMP_2:.*]] = llvm.fadd %[[REAL_TMP_0]], %[[REAL_TMP_1]] : f32

	// CHECK-DAG: %[[IMAG_TMP_0:.*]] = llvm.fmul %[[LHS_IM]], %[[RHS_RE]] : f32
	// CHECK-DAG: %[[IMAG_TMP_1:.*]] = llvm.fmul %[[LHS_RE]], %[[RHS_IM]] : f32
	// CHECK: %[[IMAG_TMP_2:.*]] = llvm.fsub %[[IMAG_TMP_0]], %[[IMAG_TMP_1]] : f32

	// CHECK: %[[REAL:.*]] = llvm.fdiv %[[REAL_TMP_2]], %[[SQ_NORM]] : f32
	// CHECK: %[[RESULT_1:.*]] = llvm.insertvalue %[[REAL]], %[[RESULT_0]][0] : ![[C_TY]]
	// CHECK: %[[IMAG:.*]] = llvm.fdiv %[[IMAG_TMP_2]], %[[SQ_NORM]] : f32
	// CHECK: %[[RESULT_2:.*]] = llvm.insertvalue %[[IMAG]], %[[RESULT_1]][1] : ![[C_TY]]
	// CHECK: llvm.return %[[RESULT_2]] : ![[C_TY]]

	// CHECK-LABEL: llvm.func @complex_mul
	// CHECK-SAME: %[[LHS:.]]: ![[C_TY:.>]], %[[RHS:.*]]: ![[C_TY]]) -> ![[C_TY]]
	func @complex_mul(%lhs: complex<f32>, %rhs: complex<f32>) -> complex<f32> {
	%mul = complex.mul %lhs, %rhs : complex<f32>
	return %mul : complex<f32>
	}
	// CHECK: %[[LHS_RE:.*]] = llvm.extractvalue %[[LHS]][0] : ![[C_TY]]
	// CHECK: %[[LHS_IM:.*]] = llvm.extractvalue %[[LHS]][1] : ![[C_TY]]
	// CHECK: %[[RHS_RE:.*]] = llvm.extractvalue %[[RHS]][0] : ![[C_TY]]
	// CHECK: %[[RHS_IM:.*]] = llvm.extractvalue %[[RHS]][1] : ![[C_TY]]
	// CHECK: %[[RESULT_0:.*]] = llvm.mlir.undef : ![[C_TY]]

	// CHECK-DAG: %[[REAL_TMP_0:.*]] = llvm.fmul %[[RHS_RE]], %[[LHS_RE]] : f32
	// CHECK-DAG: %[[REAL_TMP_1:.*]] = llvm.fmul %[[RHS_IM]], %[[LHS_IM]] : f32
	// CHECK: %[[REAL:.*]] = llvm.fsub %[[REAL_TMP_0]], %[[REAL_TMP_1]] : f32

	// CHECK-DAG: %[[IMAG_TMP_0:.*]] = llvm.fmul %[[LHS_IM]], %[[RHS_RE]] : f32
	// CHECK-DAG: %[[IMAG_TMP_1:.*]] = llvm.fmul %[[LHS_RE]], %[[RHS_IM]] : f32
	// CHECK: %[[IMAG:.*]] = llvm.fadd %[[IMAG_TMP_0]], %[[IMAG_TMP_1]] : f32

	// CHECK: %[[RESULT_1:.*]] = llvm.insertvalue %[[REAL]], %[[RESULT_0]][0]
	// CHECK: %[[RESULT_2:.*]] = llvm.insertvalue %[[IMAG]], %[[RESULT_1]][1]
	// CHECK: llvm.return %[[RESULT_2]] : ![[C_TY]]

	// CHECK-LABEL: llvm.func @complex_abs
	// CHECK-SAME: %[[ARG:.]]: ![[C_TY:.]])
	func @complex_abs(%arg: complex<f32>) -> f32 {
	%abs = complex.abs %arg: complex<f32>
	return %abs : f32
	}
	// CHECK: %[[REAL:.*]] = llvm.extractvalue %[[ARG]][0] : ![[C_TY]]
	// CHECK: %[[IMAG:.*]] = llvm.extractvalue %[[ARG]][1] : ![[C_TY]]
	// CHECK-DAG: %[[REAL_SQ:.*]] = llvm.fmul %[[REAL]], %[[REAL]] : f32
	// CHECK-DAG: %[[IMAG_SQ:.*]] = llvm.fmul %[[IMAG]], %[[IMAG]] : f32
	// CHECK: %[[SQ_NORM:.*]] = llvm.fadd %[[REAL_SQ]], %[[IMAG_SQ]] : f32
	// CHECK: %[[NORM:.*]] = "llvm.intr.sqrt"(%[[SQ_NORM]]) : (f32) -> f32
	// CHECK: llvm.return %[[NORM]] : f32