llvm/flang/test/Fir/target-rewrite-complex.fir

// RUN: fir-opt --target-rewrite="target=i386-unknown-linux-gnu" %s | FileCheck %s --check-prefix=I32
// RUN: fir-opt --target-rewrite="target=i386-w64-windows-gnu" %s | FileCheck %s --check-prefix=I32_MINGW
// RUN: fir-opt --target-rewrite="target=x86_64-unknown-linux-gnu" %s | FileCheck %s --check-prefix=X64
// RUN: fir-opt --target-rewrite="target=x86_64-w64-windows-gnu" %s | FileCheck %s --check-prefix=X64_MINGW
// RUN: fir-opt --target-rewrite="target=aarch64-unknown-linux-gnu" %s | FileCheck %s --check-prefix=AARCH64
// RUN: fir-opt --target-rewrite="target=powerpc64le-unknown-linux-gnu" %s | FileCheck %s --check-prefix=PPC64le
// RUN: fir-opt --target-rewrite="target=sparc64-unknown-linux-gnu" %s | FileCheck %s --check-prefix=SPARCV9
// RUN: fir-opt --target-rewrite="target=sparcv9-sun-solaris2.11" %s | FileCheck %s --check-prefix=SPARCV9
// RUN: fir-opt --target-rewrite="target=riscv64-unknown-linux-gnu" %s | FileCheck %s --check-prefix=RISCV64
// RUN: fir-opt --target-rewrite="target=powerpc64-ibm-aix7.2.0.0" %s | FileCheck %s --check-prefix=PPC64
// RUN: fir-opt --target-rewrite="target=loongarch64-unknown-linux-gnu" %s | FileCheck %s --check-prefix=LOONGARCH64

// Test that we rewrite the signature and body of a function that returns a
// complex<4>.
// I32-LABEL: func @returncomplex4() -> i64
// I32_MINGW-LABEL: func @returncomplex4() -> i64
// X64-LABEL: func @returncomplex4() -> !fir.vector<2:f32>
// X64_MINGW-LABEL: func @returncomplex4() -> i64
// AARCH64-LABEL: func @returncomplex4() -> tuple<f32, f32>
// PPC64le-LABEL: func @returncomplex4() -> tuple<f32, f32>
// SPARCV9-LABEL: func @returncomplex4() -> tuple<f32, f32>
// RISCV64-LABEL: func @returncomplex4() -> tuple<f32, f32>
// PPC64-LABEL: func @returncomplex4() -> tuple<f32, f32>
// LOONGARCH64-LABEL: func @returncomplex4() -> tuple<f32, f32>
func.func @returncomplex4() -> complex<f32> {
  // I32: fir.insert_value
  // I32: [[VAL:%[0-9A-Za-z]+]] = fir.insert_value
  // I32_MINGW: fir.insert_value
  // I32_MINGW: [[VAL:%[0-9A-Za-z]+]] = fir.insert_value
  // X64: fir.insert_value
  // X64: [[VAL:%[0-9A-Za-z]+]] = fir.insert_value
  // X64_MINGW: fir.insert_value
  // X64_MINGW: [[VAL:%[0-9A-Za-z]+]] = fir.insert_value
  // AARCH64: fir.insert_value
  // AARCH64: [[VAL:%[0-9A-Za-z]+]] = fir.insert_value
  // PPC64le: fir.insert_value
  // PPC64le: [[VAL:%[0-9A-Za-z]+]] = fir.insert_value
  // SPARCV9: fir.insert_value
  // SPARCV9: [[VAL:%[0-9A-Za-z]+]] = fir.insert_value
  // RISCV64: fir.insert_value
  // RISCV64: [[VAL:%[0-9A-Za-z]+]] = fir.insert_value
  // PPC64: fir.insert_value
  // PPC64: [[VAL:%[0-9A-Za-z]+]] = fir.insert_value
  // LOONGARCH64: fir.insert_value
  // LOONGARCH64: [[VAL:%[0-9A-Za-z]+]] = fir.insert_value
  %1 = fir.undefined complex<f32>
  %2 = arith.constant 2.0 : f32
  %3 = fir.convert %2 : (f32) -> f32
  %c0 = arith.constant 0 : i32
  %4 = fir.insert_value %1, %3, [0 : i32] : (complex<f32>, f32) -> complex<f32>
  %c1 = arith.constant 1 : i32
  %5 = arith.constant -42.0 : f32
  %6 = fir.insert_value %4, %5, [1 : i32] : (complex<f32>, f32) -> complex<f32>

  // I32: [[ADDRI64:%[0-9A-Za-z]+]] = fir.alloca i64
  // I32: [[ADDRC:%[0-9A-Za-z]+]] = fir.convert [[ADDRI64]] : (!fir.ref<i64>) -> !fir.ref<complex<f32>>
  // I32: fir.store [[VAL]] to [[ADDRC]] : !fir.ref<complex<f32>>
  // I32: [[RES:%[0-9A-Za-z]+]] = fir.load [[ADDRI64]] : !fir.ref<i64>
  // I32: return [[RES]] : i64
  // I32_MINGW: [[ADDRV:%[0-9A-Za-z]+]] = fir.alloca i64
  // I32_MINGW: [[ADDRC:%[0-9A-Za-z]+]] = fir.convert [[ADDRV]] : (!fir.ref<i64>) -> !fir.ref<complex<f32>>
  // I32_MINGW: fir.store [[VAL]] to [[ADDRC]] : !fir.ref<complex<f32>>
  // I32_MINGW: [[RES:%[0-9A-Za-z]+]] = fir.load [[ADDRV]] : !fir.ref<i64>
  // I32_MINGW: return [[RES]] : i64
  // X64: [[ADDRV:%[0-9A-Za-z]+]] = fir.alloca !fir.vector<2:f32>
  // X64: [[ADDRC:%[0-9A-Za-z]+]] = fir.convert [[ADDRV]] : (!fir.ref<!fir.vector<2:f32>>) -> !fir.ref<complex<f32>>
  // X64: fir.store [[VAL]] to [[ADDRC]] : !fir.ref<complex<f32>>
  // X64: [[RES:%[0-9A-Za-z]+]] = fir.load [[ADDRV]] : !fir.ref<!fir.vector<2:f32>>
  // X64: return [[RES]] : !fir.vector<2:f32>
  // X64_MINGW: [[ADDRV:%[0-9A-Za-z]+]] = fir.alloca i64
  // X64_MINGW: [[ADDRC:%[0-9A-Za-z]+]] = fir.convert [[ADDRV]] : (!fir.ref<i64>) -> !fir.ref<complex<f32>>
  // X64_MINGW: fir.store [[VAL]] to [[ADDRC]] : !fir.ref<complex<f32>>
  // X64_MINGW: [[RES:%[0-9A-Za-z]+]] = fir.load [[ADDRV]] : !fir.ref<i64>
  // X64_MINGW: return [[RES]] : i64
  // AARCH64: [[ADDRT:%[0-9A-Za-z]+]] = fir.alloca tuple<f32, f32>
  // AARCH64: [[ADDRC:%[0-9A-Za-z]+]] = fir.convert [[ADDRT]] : (!fir.ref<tuple<f32, f32>>) -> !fir.ref<complex<f32>>
  // AARCH64: fir.store [[VAL]] to [[ADDRC]] : !fir.ref<complex<f32>>
  // AARCH64: [[RES:%[0-9A-Za-z]+]] = fir.load [[ADDRT]] : !fir.ref<tuple<f32, f32>>
  // AARCH64: return [[RES]] : tuple<f32, f32>
  // PPC64le: [[ADDRT:%[0-9A-Za-z]+]] = fir.alloca tuple<f32, f32>
  // PPC64le: [[ADDRC:%[0-9A-Za-z]+]] = fir.convert [[ADDRT]] : (!fir.ref<tuple<f32, f32>>) -> !fir.ref<complex<f32>>
  // PPC64le: fir.store [[VAL]] to [[ADDRC]] : !fir.ref<complex<f32>>
  // PPC64le: [[RES:%[0-9A-Za-z]+]] = fir.load [[ADDRT]] : !fir.ref<tuple<f32, f32>>
  // PPC64le: return [[RES]] : tuple<f32, f32>
  // SPARCV9: [[ADDRT:%[0-9A-Za-z]+]] = fir.alloca tuple<f32, f32>
  // SPARCV9: [[ADDRC:%[0-9A-Za-z]+]] = fir.convert [[ADDRT]] : (!fir.ref<tuple<f32, f32>>) -> !fir.ref<complex<f32>>
  // SPARCV9: fir.store [[VAL]] to [[ADDRC]] : !fir.ref<complex<f32>>
  // SPARCV9: [[RES:%[0-9A-Za-z]+]] = fir.load [[ADDRT]] : !fir.ref<tuple<f32, f32>>
  // SPARCV9: return [[RES]] : tuple<f32, f32>
  // RISCV64: [[ADDRT:%[0-9A-Za-z]+]] = fir.alloca tuple<f32, f32>
  // RISCV64: [[ADDRC:%[0-9A-Za-z]+]] = fir.convert [[ADDRT]] : (!fir.ref<tuple<f32, f32>>) -> !fir.ref<complex<f32>>
  // PPC64: [[ADDRT:%[0-9A-Za-z]+]] = fir.alloca tuple<f32, f32>
  // PPC64: [[ADDRC:%[0-9A-Za-z]+]] = fir.convert [[ADDRT]] : (!fir.ref<tuple<f32, f32>>) -> !fir.ref<complex<f32>>
  // PPC64: fir.store [[VAL]] to [[ADDRC]] : !fir.ref<complex<f32>>
  // PPC64: [[RES:%[0-9A-Za-z]+]] = fir.load [[ADDRT]] : !fir.ref<tuple<f32, f32>>
  // PPC64: return [[RES]] : tuple<f32, f32>
  // LOONGARCH64: [[ADDRT:%[0-9A-Za-z]+]] = fir.alloca tuple<f32, f32>
  // LOONGARCH64: [[ADDRC:%[0-9A-Za-z]+]] = fir.convert [[ADDRT]] : (!fir.ref<tuple<f32, f32>>) -> !fir.ref<complex<f32>>
  return %6 : complex<f32>
}

// Test that we rewrite the signature and body of a function that returns a
// complex<8>.
// I32-LABEL:func @returncomplex8
// I32-SAME: ([[ARG0:%[0-9A-Za-z]+]]: !fir.ref<tuple<f64, f64>>  {llvm.align = 4 : i32, llvm.sret = tuple<f64, f64>})
// I32_MINGW-LABEL: func @returncomplex8
// I32_MINGW-SAME: ([[ARG0:%[0-9A-Za-z]+]]: !fir.ref<tuple<f64, f64>>  {llvm.align = 8 : i32, llvm.sret = tuple<f64, f64>})
// X64-LABEL: func @returncomplex8() -> tuple<f64, f64>
// X64_MINGW-LABEL: func @returncomplex8
// X64_MINGW-SAME: ([[ARG0:%[0-9A-Za-z]+]]: !fir.ref<tuple<f64, f64>>  {llvm.align = 8 : i32, llvm.sret = tuple<f64, f64>})
// AARCH64-LABEL: func @returncomplex8() -> tuple<f64, f64>
// PPC64le-LABEL: func @returncomplex8() -> tuple<f64, f64>
// SPARCV9-LABEL: func @returncomplex8() -> tuple<f64, f64>
// RISCV64-LABEL: func @returncomplex8() -> tuple<f64, f64>
// PPC64-LABEL: func @returncomplex8() -> tuple<f64, f64>
// LOONGARCH64-LABEL: func @returncomplex8() -> tuple<f64, f64>
func.func @returncomplex8() -> complex<f64> {
  // I32: fir.insert_value
  // I32: [[VAL:%[0-9A-Za-z]+]] = fir.insert_value {{.*}}
  // I32_MINGW: fir.insert_value
  // I32_MINGW: [[VAL:%[0-9A-Za-z]+]] = fir.insert_value {{.*}}
  // X64: fir.insert_value
  // X64: [[VAL:%[0-9A-Za-z]+]] = fir.insert_value {{.*}}
  // X64_MINGW: fir.insert_value
  // X64_MINGW: [[VAL:%[0-9A-Za-z]+]] = fir.insert_value {{.*}}
  // AARCH64: fir.insert_value
  // AARCH64: [[VAL:%[0-9A-Za-z]+]] = fir.insert_value {{.*}}
  // PPC64le: fir.insert_value
  // PPC64le: [[VAL:%[0-9A-Za-z]+]] = fir.insert_value {{.*}}
  // SPARCV9: fir.insert_value
  // SPARCV9: [[VAL:%[0-9A-Za-z]+]] = fir.insert_value {{.*}}
  // RISCV64: fir.insert_value
  // RISCV64: [[VAL:%[0-9A-Za-z]+]] = fir.insert_value {{.*}}
  // PPC64: fir.insert_value
  // PPC64: [[VAL:%[0-9A-Za-z]+]] = fir.insert_value {{.*}}
  // LOONGARCH64: fir.insert_value
  // LOONGARCH64: [[VAL:%[0-9A-Za-z]+]] = fir.insert_value {{.*}}
  %1 = fir.undefined complex<f64>
  %2 = arith.constant 1.0 : f64
  %3 = arith.constant -4.0 : f64
  %c0 = arith.constant 0 : i32
  %4 = fir.insert_value %1, %3, [0 : i32] : (complex<f64>, f64) -> complex<f64>
  %c1 = arith.constant 1 : i32
  %5 = fir.insert_value %4, %2, [1 : i32] : (complex<f64>, f64) -> complex<f64>

  // I32: [[ADDR:%[0-9A-Za-z]+]] = fir.convert [[ARG0]] : (!fir.ref<tuple<f64, f64>>) -> !fir.ref<complex<f64>>
  // I32: fir.store [[VAL]] to [[ADDR]] : !fir.ref<complex<f64>>
  // I32: return{{ *$}}
  // I32_MINGW: [[ADDRC:%[0-9A-Za-z]+]] = fir.convert [[ARG0]] : (!fir.ref<tuple<f64, f64>>) -> !fir.ref<complex<f64>>
  // I32_MINGW: fir.store [[VAL]] to [[ADDRC]] : !fir.ref<complex<f64>>
  // I32_MINGW: return
  // X64: [[ADDRT:%[0-9A-Za-z]+]] = fir.alloca tuple<f64, f64>
  // X64: [[ADDRC:%[0-9A-Za-z]+]] = fir.convert [[ADDRT]] : (!fir.ref<tuple<f64, f64>>) -> !fir.ref<complex<f64>>
  // X64: fir.store [[VAL]] to [[ADDRC]] : !fir.ref<complex<f64>>
  // X64: [[RES:%[0-9A-Za-z]+]] = fir.load [[ADDRT]] : !fir.ref<tuple<f64, f64>>
  // X64: return [[RES]] : tuple<f64, f64>
  // X64_MINGW: [[ADDRC:%[0-9A-Za-z]+]] = fir.convert [[ARG0]] : (!fir.ref<tuple<f64, f64>>) -> !fir.ref<complex<f64>>
  // X64_MINGW: fir.store [[VAL]] to [[ADDRC]] : !fir.ref<complex<f64>>
  // X64_MINGW: return
  // AARCH64: [[ADDRT:%[0-9A-Za-z]+]] = fir.alloca tuple<f64, f64>
  // AARCH64: [[ADDRC:%[0-9A-Za-z]+]] = fir.convert [[ADDRT]] : (!fir.ref<tuple<f64, f64>>) -> !fir.ref<complex<f64>>
  // AARCH64: fir.store [[VAL]] to [[ADDRC]] : !fir.ref<complex<f64>>
  // AARCH64: [[RES:%[0-9A-Za-z]+]] = fir.load [[ADDRT]] : !fir.ref<tuple<f64, f64>>
  // AARCH64: return [[RES]] : tuple<f64, f64>
  // PPC64le: [[ADDRT:%[0-9A-Za-z]+]] = fir.alloca tuple<f64, f64>
  // PPC64le: [[ADDRC:%[0-9A-Za-z]+]] = fir.convert [[ADDRT]] : (!fir.ref<tuple<f64, f64>>) -> !fir.ref<complex<f64>>
  // PPC64le: fir.store [[VAL]] to [[ADDRC]] : !fir.ref<complex<f64>>
  // PPC64le: [[RES:%[0-9A-Za-z]+]] = fir.load [[ADDRT]] : !fir.ref<tuple<f64, f64>>
  // PPC64le: return [[RES]] : tuple<f64, f64>
  // SPARCV9: [[ADDRT:%[0-9A-Za-z]+]] = fir.alloca tuple<f64, f64>
  // SPARCV9: [[ADDRC:%[0-9A-Za-z]+]] = fir.convert [[ADDRT]] : (!fir.ref<tuple<f64, f64>>) -> !fir.ref<complex<f64>>
  // SPARCV9: fir.store [[VAL]] to [[ADDRC]] : !fir.ref<complex<f64>>
  // SPARCV9: [[RES:%[0-9A-Za-z]+]] = fir.load [[ADDRT]] : !fir.ref<tuple<f64, f64>>
  // SPARCV9: return [[RES]] : tuple<f64, f64>
  // RISCV64: [[ADDRT:%[0-9A-Za-z]+]] = fir.alloca tuple<f64, f64>
  // RISCV64: [[ADDRC:%[0-9A-Za-z]+]] = fir.convert [[ADDRT]] : (!fir.ref<tuple<f64, f64>>) -> !fir.ref<complex<f64>>
  // RISCV64: fir.store [[VAL]] to [[ADDRC]] : !fir.ref<complex<f64>>
  // RISCV64: [[RES:%[0-9A-Za-z]+]] = fir.load [[ADDRT]] : !fir.ref<tuple<f64, f64>>
  // RISCV64: return [[RES]] : tuple<f64, f64>
  // PPC64: [[ADDRT:%[0-9A-Za-z]+]] = fir.alloca tuple<f64, f64>
  // PPC64: [[ADDRC:%[0-9A-Za-z]+]] = fir.convert [[ADDRT]] : (!fir.ref<tuple<f64, f64>>) -> !fir.ref<complex<f64>>
  // PPC64: fir.store [[VAL]] to [[ADDRC]] : !fir.ref<complex<f64>>
  // PPC64: [[RES:%[0-9A-Za-z]+]] = fir.load [[ADDRT]] : !fir.ref<tuple<f64, f64>>
  // PPC64: return [[RES]] : tuple<f64, f64>
  // LOONGARCH64: [[ADDRT:%[0-9A-Za-z]+]] = fir.alloca tuple<f64, f64>
  // LOONGARCH64: [[ADDRC:%[0-9A-Za-z]+]] = fir.convert [[ADDRT]] : (!fir.ref<tuple<f64, f64>>) -> !fir.ref<complex<f64>>
  // LOONGARCH64: fir.store [[VAL]] to [[ADDRC]] : !fir.ref<complex<f64>>
  // LOONGARCH64: [[RES:%[0-9A-Za-z]+]] = fir.load [[ADDRT]] : !fir.ref<tuple<f64, f64>>
  // LOONGARCH64: return [[RES]] : tuple<f64, f64>
  return %5 : complex<f64>
}

// Test that we rewrite the signature of a function that accepts a complex<4>.
// I32-LABEL: func private @paramcomplex4(!fir.ref<tuple<f32, f32>> {llvm.align = 4 : i32, llvm.byval = tuple<f32, f32>})
// I32_MINGW-LABEL: func private @paramcomplex4(!fir.ref<tuple<f32, f32>> {llvm.align = 4 : i32, llvm.byval = tuple<f32, f32>})
// X64-LABEL: func private @paramcomplex4(!fir.vector<2:f32>)
// X64_MINGW-LABEL: func private @paramcomplex4(i64)
// AARCH64-LABEL: func private @paramcomplex4(!fir.array<2xf32>)
// PPC64le-LABEL: func private @paramcomplex4(f32, f32)
// SPARCV9-LABEL: func private @paramcomplex4(f32, f32)
// RISCV64-LABEL: func private @paramcomplex4(f32, f32)
// PPC64-LABEL: func private @paramcomplex4(f32, f32)
// LOONGARCH64-LABEL: func private @paramcomplex4(f32, f32)
func.func private @paramcomplex4(complex<f32>) -> ()

// Test that we rewrite calls to functions that return or accept complex<4>.
// I32-LABEL: func @callcomplex4
// I32_MINGW-LABEL: func @callcomplex4
// X64-LABEL: func @callcomplex4
// X64_MINGW-LABEL: func @callcomplex4
// AARCH64-LABEL: func @callcomplex4
// PPC64le-LABEL: func @callcomplex4
// SPARCV9-LABEL: func @callcomplex4
// RISCV64-LABEL: func @callcomplex4
// PPC64-LABEL: func @callcomplex4
// LOONGARCH64-LABEL: func @callcomplex4
func.func @callcomplex4(%arg0 : !fir.class<!fir.type<_QMpolymorphic_testTp1{a:i32,b:i32}>>) {

  // I32: [[RES:%[0-9A-Za-z]+]] = fir.call @returncomplex4() : () -> i64
  // I32_MINGW: [[RES:%[0-9A-Za-z]+]] = fir.call @returncomplex4() : () -> i64
  // X64: [[RES:%[0-9A-Za-z]+]] = fir.call @returncomplex4() : () -> !fir.vector<2:f32>
  // X64_MINGW: [[RES:%[0-9A-Za-z]+]] = fir.call @returncomplex4() : () -> i64
  // AARCH64: [[RES:%[0-9A-Za-z]+]] = fir.call @returncomplex4() : () -> tuple<f32, f32>
  // PPC64le: [[RES:%[0-9A-Za-z]+]] = fir.call @returncomplex4() : () -> tuple<f32, f32>
  // SPARCV9: [[RES:%[0-9A-Za-z]+]] = fir.call @returncomplex4() : () -> tuple<f32, f32>
  // RISCV64: [[RES:%[0-9A-Za-z]+]] = fir.call @returncomplex4() : () -> tuple<f32, f32>
  // PPC64: [[RES:%[0-9A-Za-z]+]] = fir.call @returncomplex4() : () -> tuple<f32, f32>
  // LOONGARCH64: [[RES:%[0-9A-Za-z]+]] = fir.call @returncomplex4() : () -> tuple<f32, f32>
  %1 = fir.call @returncomplex4() : () -> complex<f32>

  // I32: [[ADDRI64:%[0-9A-Za-z]+]] = fir.alloca i64
  // I32: fir.store [[RES]] to [[ADDRI64]] : !fir.ref<i64>
  // I32: [[ADDRC:%[0-9A-Za-z]+]] = fir.convert [[ADDRI64]] : (!fir.ref<i64>) -> !fir.ref<complex<f32>>
  // I32: [[C:%[0-9A-Za-z]+]] = fir.load [[ADDRC]] : !fir.ref<complex<f32>>
  // I32: [[ADDRC2:%[0-9A-Za-z]+]] = fir.alloca complex<f32>
  // I32: fir.store [[C]] to [[ADDRC2]] : !fir.ref<complex<f32>>
  // I32: [[T:%[0-9A-Za-z]+]] = fir.convert [[ADDRC2]] : (!fir.ref<complex<f32>>) -> !fir.ref<tuple<f32, f32>>
  // I32: fir.call @paramcomplex4([[T]]) : (!fir.ref<tuple<f32, f32>>) -> ()

  // I32_MINGW: [[ADDRI64:%[0-9A-Za-z]+]] = fir.alloca i64
  // I32_MINGW: fir.store [[RES]] to [[ADDRI64]] : !fir.ref<i64>
  // I32_MINGW: [[ADDRC:%[0-9A-Za-z]+]] = fir.convert [[ADDRI64]] : (!fir.ref<i64>) -> !fir.ref<complex<f32>>
  // I32_MINGW: [[C:%[0-9A-Za-z]+]] = fir.load [[ADDRC]] : !fir.ref<complex<f32>>
  // I32_MINGW: [[ADDRC2:%[0-9A-Za-z]+]] = fir.alloca complex<f32>
  // I32_MINGW: fir.store [[C]] to [[ADDRC2]] : !fir.ref<complex<f32>>
  // I32_MINGW: [[T:%[0-9A-Za-z]+]] = fir.convert [[ADDRC2]] : (!fir.ref<complex<f32>>) -> !fir.ref<tuple<f32, f32>>
  // I32_MINGW: fir.call @paramcomplex4([[T]]) : (!fir.ref<tuple<f32, f32>>) -> ()

  // X64: [[ADDRV:%[0-9A-Za-z]+]] = fir.alloca !fir.vector<2:f32>
  // X64: fir.store [[RES]] to [[ADDRV]] : !fir.ref<!fir.vector<2:f32>>
  // X64: [[ADDRC:%[0-9A-Za-z]+]] = fir.convert [[ADDRV]] : (!fir.ref<!fir.vector<2:f32>>) -> !fir.ref<complex<f32>>
  // X64: [[V:%[0-9A-Za-z]+]] = fir.load [[ADDRC]] : !fir.ref<complex<f32>>
  // X64: [[ADDRV2:%[0-9A-Za-z]+]] = fir.alloca !fir.vector<2:f32>
  // X64: [[ADDRC2:%[0-9A-Za-z]+]] = fir.convert [[ADDRV2]] : (!fir.ref<!fir.vector<2:f32>>) -> !fir.ref<complex<f32>>
  // X64: fir.store [[V]] to [[ADDRC2]] : !fir.ref<complex<f32>>
  // X64: [[VRELOADED:%[0-9A-Za-z]+]] = fir.load [[ADDRV2]] : !fir.ref<!fir.vector<2:f32>>
  // X64: fir.call @paramcomplex4([[VRELOADED]]) : (!fir.vector<2:f32>) -> ()

  // X64_MINGW: [[ADDRV:%[0-9A-Za-z]+]] = fir.alloca i64
  // X64_MINGW: fir.store [[RES]] to [[ADDRV]] : !fir.ref<i64>
  // X64_MINGW: [[ADDRC:%[0-9A-Za-z]+]] = fir.convert [[ADDRV]] :  (!fir.ref<i64>) -> !fir.ref<complex<f32>>
  // X64_MINGW: [[V:%[0-9A-Za-z]+]] = fir.load [[ADDRC]] : !fir.ref<complex<f32>>
  // X64_MINGW: [[ADDRV2:%[0-9A-Za-z]+]] = fir.alloca i64
  // X64_MINGW: [[ADDRC2:%[0-9A-Za-z]+]] = fir.convert [[ADDRV2]] : (!fir.ref<i64>) -> !fir.ref<complex<f32>>
  // X64_MINGW: fir.store [[V]] to [[ADDRC2]] : !fir.ref<complex<f32>>
  // X64_MINGW: [[VRELOADED:%[0-9A-Za-z]+]] = fir.load [[ADDRV2]] : !fir.ref<i64>
  // X64_MINGW: fir.call @paramcomplex4([[VRELOADED]]) : (i64) -> ()

  // AARCH64: [[ADDRT:%[0-9A-Za-z]+]] = fir.alloca tuple<f32, f32>
  // AARCH64: fir.store [[RES]] to [[ADDRT]] : !fir.ref<tuple<f32, f32>>
  // AARCH64: [[ADDRC:%[0-9A-Za-z]+]] = fir.convert [[ADDRT]] : (!fir.ref<tuple<f32, f32>>) -> !fir.ref<complex<f32>>
  // AARCH64: [[V:%[0-9A-Za-z]+]] = fir.load [[ADDRC]] : !fir.ref<complex<f32>>
  // AARCH64: [[ADDRARR:%[0-9A-Za-z]+]] = fir.alloca !fir.array<2xf32>
  // AARCH64: [[ADDRC2:%[0-9A-Za-z]+]] = fir.convert [[ADDRARR]] : (!fir.ref<!fir.array<2xf32>>) -> !fir.ref<complex<f32>>
  // AARCH64: fir.store [[V]] to [[ADDRC2]] : !fir.ref<complex<f32>>
  // AARCH64: [[ARR:%[0-9A-Za-z]+]] = fir.load [[ADDRARR]] : !fir.ref<!fir.array<2xf32>>
  // AARCH64: fir.call @paramcomplex4([[ARR]]) : (!fir.array<2xf32>) -> ()

  // PPC64le: [[ADDRT:%[0-9A-Za-z]+]] = fir.alloca tuple<f32, f32>
  // PPC64le: fir.store [[RES]] to [[ADDRT]] : !fir.ref<tuple<f32, f32>>
  // PPC64le: [[ADDRC:%[0-9A-Za-z]+]] = fir.convert [[ADDRT]] : (!fir.ref<tuple<f32, f32>>) -> !fir.ref<complex<f32>>
  // PPC64le: [[V:%[0-9A-Za-z]+]] = fir.load [[ADDRC]] : !fir.ref<complex<f32>>
  // PPC64le: [[A:%[0-9A-Za-z]+]] = fir.extract_value [[V]], [0 : i32] : (complex<f32>) -> f32
  // PPC64le: [[B:%[0-9A-Za-z]+]] = fir.extract_value [[V]], [1 : i32] : (complex<f32>) -> f32
  // PPC64le: fir.call @paramcomplex4([[A]], [[B]]) : (f32, f32) -> ()

  // SPARCV9: [[ADDRT:%[0-9A-Za-z]+]] = fir.alloca tuple<f32, f32>
  // SPARCV9: fir.store [[RES]] to [[ADDRT]] : !fir.ref<tuple<f32, f32>>
  // SPARCV9: [[ADDRC:%[0-9A-Za-z]+]] = fir.convert [[ADDRT]] : (!fir.ref<tuple<f32, f32>>) -> !fir.ref<complex<f32>>
  // SPARCV9: [[V:%[0-9A-Za-z]+]] = fir.load [[ADDRC]] : !fir.ref<complex<f32>>
  // SPARCV9: [[A:%[0-9A-Za-z]+]] = fir.extract_value [[V]], [0 : i32] : (complex<f32>) -> f32
  // SPARCV9: [[B:%[0-9A-Za-z]+]] = fir.extract_value [[V]], [1 : i32] : (complex<f32>) -> f32
  // SPARCV9: fir.call @paramcomplex4([[A]], [[B]]) : (f32, f32) -> ()

  // RISCV64: [[ADDRT:%[0-9A-Za-z]+]] = fir.alloca tuple<f32, f32>
  // RISCV64: fir.store [[RES]] to [[ADDRT]] : !fir.ref<tuple<f32, f32>>
  // RISCV64: [[ADDRC:%[0-9A-Za-z]+]] = fir.convert [[ADDRT]] : (!fir.ref<tuple<f32, f32>>) -> !fir.ref<complex<f32>>
  // RISCV64: [[V:%[0-9A-Za-z]+]] = fir.load [[ADDRC]] : !fir.ref<complex<f32>>
  // RISCV64: [[A:%[0-9A-Za-z]+]] = fir.extract_value [[V]], [0 : i32] : (complex<f32>) -> f32
  // RISCV64: [[B:%[0-9A-Za-z]+]] = fir.extract_value [[V]], [1 : i32] : (complex<f32>) -> f32
  // RISCV64: fir.call @paramcomplex4([[A]], [[B]]) : (f32, f32) -> ()
 
  // PPC64: [[ADDRT:%[0-9A-Za-z]+]] = fir.alloca tuple<f32, f32>
  // PPC64: fir.store [[RES]] to [[ADDRT]] : !fir.ref<tuple<f32, f32>>
  // PPC64: [[ADDRC:%[0-9A-Za-z]+]] = fir.convert [[ADDRT]] : (!fir.ref<tuple<f32, f32>>) -> !fir.ref<complex<f32>>
  // PPC64: [[V:%[0-9A-Za-z]+]] = fir.load [[ADDRC]] : !fir.ref<complex<f32>>
  // PPC64: [[A:%[0-9A-Za-z]+]] = fir.extract_value [[V]], [0 : i32] : (complex<f32>) -> f32
  // PPC64: [[B:%[0-9A-Za-z]+]] = fir.extract_value [[V]], [1 : i32] : (complex<f32>) -> f32
  // PPC64: fir.call @paramcomplex4([[A]], [[B]]) : (f32, f32) -> ()

  // LOONGARCH64: [[ADDRT:%[0-9A-Za-z]+]] = fir.alloca tuple<f32, f32>
  // LOONGARCH64: fir.store [[RES]] to [[ADDRT]] : !fir.ref<tuple<f32, f32>>
  // LOONGARCH64: [[ADDRC:%[0-9A-Za-z]+]] = fir.convert [[ADDRT]] : (!fir.ref<tuple<f32, f32>>) -> !fir.ref<complex<f32>>
  // LOONGARCH64: [[V:%[0-9A-Za-z]+]] = fir.load [[ADDRC]] : !fir.ref<complex<f32>>
  // LOONGARCH64: [[A:%[0-9A-Za-z]+]] = fir.extract_value [[V]], [0 : i32] : (complex<f32>) -> f32
  // LOONGARCH64: [[B:%[0-9A-Za-z]+]] = fir.extract_value [[V]], [1 : i32] : (complex<f32>) -> f32
  // LOONGARCH64: fir.call @paramcomplex4([[A]], [[B]]) : (f32, f32) -> ()
  fir.call @paramcomplex4(%1) : (complex<f32>) -> ()

  // I32: [[RES:%[0-9A-Za-z]+]] = fir.dispatch "ret_complex"(%{{.*}} : !fir.class<!fir.type<_QMpolymorphic_testTp1{a:i32,b:i32}>>) (%{{.*}} : !fir.class<!fir.type<_QMpolymorphic_testTp1{a:i32,b:i32}>>) -> i64 {pass_arg_pos = 0 : i32}
  // I32_MINGW: [[RES:%[0-9A-Za-z]+]] = fir.dispatch "ret_complex"(%{{.*}} : !fir.class<!fir.type<_QMpolymorphic_testTp1{a:i32,b:i32}>>) (%{{.*}} : !fir.class<!fir.type<_QMpolymorphic_testTp1{a:i32,b:i32}>>) -> i64 {pass_arg_pos = 0 : i32}
  // X64: [[RES:%[0-9A-Za-z]+]] = fir.dispatch "ret_complex"(%{{.*}} : !fir.class<!fir.type<_QMpolymorphic_testTp1{a:i32,b:i32}>>) (%{{.*}} : !fir.class<!fir.type<_QMpolymorphic_testTp1{a:i32,b:i32}>>) -> !fir.vector<2:f32> {pass_arg_pos = 0 : i32}
  // X64_MINGW: [[RES:%[0-9A-Za-z]+]] = fir.dispatch "ret_complex"(%{{.*}} : !fir.class<!fir.type<_QMpolymorphic_testTp1{a:i32,b:i32}>>) (%{{.*}} : !fir.class<!fir.type<_QMpolymorphic_testTp1{a:i32,b:i32}>>) -> i64 {pass_arg_pos = 0 : i32}
  // AARCH64: [[RES:%[0-9A-Za-z]+]] = fir.dispatch "ret_complex"(%{{.*}} : !fir.class<!fir.type<_QMpolymorphic_testTp1{a:i32,b:i32}>>) (%{{.*}} : !fir.class<!fir.type<_QMpolymorphic_testTp1{a:i32,b:i32}>>) -> tuple<f32, f32> {pass_arg_pos = 0 : i32}
  // PPC64le: [[RES:%[0-9A-Za-z]+]] = fir.dispatch "ret_complex"(%{{.*}} : !fir.class<!fir.type<_QMpolymorphic_testTp1{a:i32,b:i32}>>) (%{{.*}} : !fir.class<!fir.type<_QMpolymorphic_testTp1{a:i32,b:i32}>>) -> tuple<f32, f32> {pass_arg_pos = 0 : i32}
  // SPARCV9: [[RES:%[0-9A-Za-z]+]] = fir.dispatch "ret_complex"(%{{.*}} : !fir.class<!fir.type<_QMpolymorphic_testTp1{a:i32,b:i32}>>) (%{{.*}} : !fir.class<!fir.type<_QMpolymorphic_testTp1{a:i32,b:i32}>>) -> tuple<f32, f32> {pass_arg_pos = 0 : i32}
  // PPC64: [[RES:%[0-9A-Za-z]+]] = fir.dispatch "ret_complex"(%{{.*}} : !fir.class<!fir.type<_QMpolymorphic_testTp1{a:i32,b:i32}>>) (%{{.*}} : !fir.class<!fir.type<_QMpolymorphic_testTp1{a:i32,b:i32}>>) -> tuple<f32, f32> {pass_arg_pos = 0 : i32}
  %2 = fir.dispatch "ret_complex"(%arg0 : !fir.class<!fir.type<_QMpolymorphic_testTp1{a:i32,b:i32}>>) (%arg0 : !fir.class<!fir.type<_QMpolymorphic_testTp1{a:i32,b:i32}>>) -> complex<f32> {pass_arg_pos = 0 : i32}

  // I32: [[ADDRI64:%[0-9A-Za-z]+]] = fir.alloca i64
  // I32: fir.store [[RES]] to [[ADDRI64]] : !fir.ref<i64>
  // I32: [[ADDRC:%[0-9A-Za-z]+]] = fir.convert [[ADDRI64]] : (!fir.ref<i64>) -> !fir.ref<complex<f32>>
  // I32: [[C:%[0-9A-Za-z]+]] = fir.load [[ADDRC]] : !fir.ref<complex<f32>>
  // I32: [[ADDRC2:%[0-9A-Za-z]+]] = fir.alloca complex<f32>
  // I32: fir.store [[C]] to [[ADDRC2]] : !fir.ref<complex<f32>>
  // I32: [[T:%[0-9A-Za-z]+]] = fir.convert [[ADDRC2]] : (!fir.ref<complex<f32>>) -> !fir.ref<tuple<f32, f32>>
  // I32: fir.dispatch "with_complex"(%{{.*}} : !fir.class<!fir.type<_QMpolymorphic_testTp1{a:i32,b:i32}>>) (%{{.*}}, [[T]] : !fir.class<!fir.type<_QMpolymorphic_testTp1{a:i32,b:i32}>>, !fir.ref<tuple<f32, f32>>) {pass_arg_pos = 0 : i32}

  // I32_MINGW: [[ADDRI64:%[0-9A-Za-z]+]] = fir.alloca i64
  // I32_MINGW: fir.store [[RES]] to [[ADDRI64]] : !fir.ref<i64>
  // I32_MINGW: [[ADDRC:%[0-9A-Za-z]+]] = fir.convert [[ADDRI64]] : (!fir.ref<i64>) -> !fir.ref<complex<f32>>
  // I32_MINGW: [[C:%[0-9A-Za-z]+]] = fir.load [[ADDRC]] : !fir.ref<complex<f32>>
  // I32_MINGW: [[ADDRC2:%[0-9A-Za-z]+]] = fir.alloca complex<f32>
  // I32_MINGW: fir.store [[C]] to [[ADDRC2]] : !fir.ref<complex<f32>>
  // I32_MINGW: [[T:%[0-9A-Za-z]+]] = fir.convert [[ADDRC2]] : (!fir.ref<complex<f32>>) -> !fir.ref<tuple<f32, f32>>
  // I32_MINGW: fir.dispatch "with_complex"(%{{.*}} : !fir.class<!fir.type<_QMpolymorphic_testTp1{a:i32,b:i32}>>) (%{{.*}}, [[T]] : !fir.class<!fir.type<_QMpolymorphic_testTp1{a:i32,b:i32}>>, !fir.ref<tuple<f32, f32>>) {pass_arg_pos = 0 : i32}

  // X64: [[ADDRV:%[0-9A-Za-z]+]] = fir.alloca !fir.vector<2:f32>
  // X64: fir.store [[RES]] to [[ADDRV]] : !fir.ref<!fir.vector<2:f32>>
  // X64: [[ADDRC:%[0-9A-Za-z]+]] = fir.convert [[ADDRV]] : (!fir.ref<!fir.vector<2:f32>>) -> !fir.ref<complex<f32>>
  // X64: [[V:%[0-9A-Za-z]+]] = fir.load [[ADDRC]] : !fir.ref<complex<f32>>
  // X64: [[ADDRV2:%[0-9A-Za-z]+]] = fir.alloca !fir.vector<2:f32>
  // X64: [[ADDRC2:%[0-9A-Za-z]+]] = fir.convert [[ADDRV2]] : (!fir.ref<!fir.vector<2:f32>>) -> !fir.ref<complex<f32>>
  // X64: fir.store [[V]] to [[ADDRC2]] : !fir.ref<complex<f32>>
  // X64: [[VRELOADED:%[0-9A-Za-z]+]] = fir.load [[ADDRV2]] : !fir.ref<!fir.vector<2:f32>>
  // X64: fir.dispatch "with_complex"(%{{.*}} : !fir.class<!fir.type<_QMpolymorphic_testTp1{a:i32,b:i32}>>) (%{{.*}}, [[VRELOADED]] : !fir.class<!fir.type<_QMpolymorphic_testTp1{a:i32,b:i32}>>, !fir.vector<2:f32>) {pass_arg_pos = 0 : i32}

  // X64_MINGW: [[ADDRV:%[0-9A-Za-z]+]] = fir.alloca i64
  // X64_MINGW: fir.store [[RES]] to [[ADDRV]] : !fir.ref<i64>
  // X64_MINGW: [[ADDRC:%[0-9A-Za-z]+]] = fir.convert [[ADDRV]] : (!fir.ref<i64>) -> !fir.ref<complex<f32>>
  // X64_MINGW: [[V:%[0-9A-Za-z]+]] = fir.load [[ADDRC]] : !fir.ref<complex<f32>>
  // X64_MINGW: [[ADDRV2:%[0-9A-Za-z]+]] = fir.alloca i64
  // X64_MINGW: [[ADDRC2:%[0-9A-Za-z]+]] = fir.convert [[ADDRV2]] : (!fir.ref<i64>) -> !fir.ref<complex<f32>>
  // X64_MINGW: fir.store [[V]] to [[ADDRC2]] : !fir.ref<complex<f32>>
  // X64_MINGW: [[VRELOADED:%[0-9A-Za-z]+]] = fir.load [[ADDRV2]] : !fir.ref<i64>
  // X64_MINGW: fir.dispatch "with_complex"(%{{.*}} : !fir.class<!fir.type<_QMpolymorphic_testTp1{a:i32,b:i32}>>) (%{{.*}}, [[VRELOADED]] : !fir.class<!fir.type<_QMpolymorphic_testTp1{a:i32,b:i32}>>, i64) {pass_arg_pos = 0 : i32}

  // AARCH64: [[ADDRT:%[0-9A-Za-z]+]] = fir.alloca tuple<f32, f32>
  // AARCH64: fir.store [[RES]] to [[ADDRT]] : !fir.ref<tuple<f32, f32>>
  // AARCH64: [[ADDRC:%[0-9A-Za-z]+]] = fir.convert [[ADDRT]] : (!fir.ref<tuple<f32, f32>>) -> !fir.ref<complex<f32>>
  // AARCH64: [[V:%[0-9A-Za-z]+]] = fir.load [[ADDRC]] : !fir.ref<complex<f32>>
  // AARCH64: [[ADDRARR:%[0-9A-Za-z]+]] = fir.alloca !fir.array<2xf32>
  // AARCH64: [[ADDRC2:%[0-9A-Za-z]+]] = fir.convert [[ADDRARR]] : (!fir.ref<!fir.array<2xf32>>) -> !fir.ref<complex<f32>>
  // AARCH64: fir.store [[V]] to [[ADDRC2]] : !fir.ref<complex<f32>>
  // AARCH64: [[ARR:%[0-9A-Za-z]+]] = fir.load [[ADDRARR]] : !fir.ref<!fir.array<2xf32>>
  // AARCH64: fir.dispatch "with_complex"(%{{.*}} : !fir.class<!fir.type<_QMpolymorphic_testTp1{a:i32,b:i32}>>) (%{{.*}}, [[ARR]] : !fir.class<!fir.type<_QMpolymorphic_testTp1{a:i32,b:i32}>>, !fir.array<2xf32>) {pass_arg_pos = 0 : i32}

  // PPC64le: [[ADDRT:%[0-9A-Za-z]+]] = fir.alloca tuple<f32, f32>
  // PPC64le: fir.store [[RES]] to [[ADDRT]] : !fir.ref<tuple<f32, f32>>
  // PPC64le: [[ADDRC:%[0-9A-Za-z]+]] = fir.convert [[ADDRT]] : (!fir.ref<tuple<f32, f32>>) -> !fir.ref<complex<f32>>
  // PPC64le: [[V:%[0-9A-Za-z]+]] = fir.load [[ADDRC]] : !fir.ref<complex<f32>>
  // PPC64le: [[A:%[0-9A-Za-z]+]] = fir.extract_value [[V]], [0 : i32] : (complex<f32>) -> f32
  // PPC64le: [[B:%[0-9A-Za-z]+]] = fir.extract_value [[V]], [1 : i32] : (complex<f32>) -> f32
  // PPC64le: fir.dispatch "with_complex"(%{{.*}} : !fir.class<!fir.type<_QMpolymorphic_testTp1{a:i32,b:i32}>>) (%{{.*}}, [[A]], [[B]] : !fir.class<!fir.type<_QMpolymorphic_testTp1{a:i32,b:i32}>>, f32, f32) {pass_arg_pos = 0 : i32}

  // SPARCV9: [[ADDRT:%[0-9A-Za-z]+]] = fir.alloca tuple<f32, f32>
  // SPARCV9: fir.store [[RES]] to [[ADDRT]] : !fir.ref<tuple<f32, f32>>
  // SPARCV9: [[ADDRC:%[0-9A-Za-z]+]] = fir.convert [[ADDRT]] : (!fir.ref<tuple<f32, f32>>) -> !fir.ref<complex<f32>>
  // SPARCV9: [[V:%[0-9A-Za-z]+]] = fir.load [[ADDRC]] : !fir.ref<complex<f32>>
  // SPARCV9: [[A:%[0-9A-Za-z]+]] = fir.extract_value [[V]], [0 : i32] : (complex<f32>) -> f32
  // SPARCV9: [[B:%[0-9A-Za-z]+]] = fir.extract_value [[V]], [1 : i32] : (complex<f32>) -> f32
  // SPARCV9: fir.dispatch "with_complex"(%{{.*}} : !fir.class<!fir.type<_QMpolymorphic_testTp1{a:i32,b:i32}>>) (%{{.*}}, [[A]], [[B]] : !fir.class<!fir.type<_QMpolymorphic_testTp1{a:i32,b:i32}>>, f32, f32) {pass_arg_pos = 0 : i32}

  // PPC64: [[ADDRT:%[0-9A-Za-z]+]] = fir.alloca tuple<f32, f32>
  // PPC64: fir.store [[RES]] to [[ADDRT]] : !fir.ref<tuple<f32, f32>>
  // PPC64: [[ADDRC:%[0-9A-Za-z]+]] = fir.convert [[ADDRT]] : (!fir.ref<tuple<f32, f32>>) -> !fir.ref<complex<f32>>
  // PPC64: [[V:%[0-9A-Za-z]+]] = fir.load [[ADDRC]] : !fir.ref<complex<f32>>
  // PPC64: [[A:%[0-9A-Za-z]+]] = fir.extract_value [[V]], [0 : i32] : (complex<f32>) -> f32
  // PPC64: [[B:%[0-9A-Za-z]+]] = fir.extract_value [[V]], [1 : i32] : (complex<f32>) -> f32
  // PPC64: fir.dispatch "with_complex"(%{{.*}} : !fir.class<!fir.type<_QMpolymorphic_testTp1{a:i32,b:i32}>>) (%{{.*}}, [[A]], [[B]] : !fir.class<!fir.type<_QMpolymorphic_testTp1{a:i32,b:i32}>>, f32, f32) {pass_arg_pos = 0 : i32}
  fir.dispatch "with_complex"(%arg0 : !fir.class<!fir.type<_QMpolymorphic_testTp1{a:i32,b:i32}>>) (%arg0, %2 : !fir.class<!fir.type<_QMpolymorphic_testTp1{a:i32,b:i32}>>, complex<f32>) {pass_arg_pos = 0 : i32}


  // I32: fir.dispatch "with_complex2"(%{{.*}} : !fir.class<!fir.type<_QMpolymorphic_testTp1{a:i32,b:i32}>>) (%{{.*}}, %{{.*}} : !fir.ref<tuple<f32, f32>>, !fir.class<!fir.type<_QMpolymorphic_testTp1{a:i32,b:i32}>>) {pass_arg_pos = 1 : i32}
  // I32_MINGW: fir.dispatch "with_complex2"(%{{.*}} : !fir.class<!fir.type<_QMpolymorphic_testTp1{a:i32,b:i32}>>) (%{{.*}}, %{{.*}} : !fir.ref<tuple<f32, f32>>, !fir.class<!fir.type<_QMpolymorphic_testTp1{a:i32,b:i32}>>) {pass_arg_pos = 1 : i32}
  // X64: fir.dispatch "with_complex2"(%{{.*}} : !fir.class<!fir.type<_QMpolymorphic_testTp1{a:i32,b:i32}>>) (%{{.*}}, %{{.*}} : !fir.vector<2:f32>, !fir.class<!fir.type<_QMpolymorphic_testTp1{a:i32,b:i32}>>) {pass_arg_pos = 1 : i32}
  // X64_MINGW: fir.dispatch "with_complex2"(%{{.*}} : !fir.class<!fir.type<_QMpolymorphic_testTp1{a:i32,b:i32}>>) (%{{.*}}, %{{.*}} : i64, !fir.class<!fir.type<_QMpolymorphic_testTp1{a:i32,b:i32}>>) {pass_arg_pos = 1 : i32}
  // AARCH64: fir.dispatch "with_complex2"(%{{.*}} : !fir.class<!fir.type<_QMpolymorphic_testTp1{a:i32,b:i32}>>) (%{{.*}}, %{{.*}} : !fir.array<2xf32>, !fir.class<!fir.type<_QMpolymorphic_testTp1{a:i32,b:i32}>>) {pass_arg_pos = 1 : i32}
  // PPC64le: fir.dispatch "with_complex2"(%{{.*}} : !fir.class<!fir.type<_QMpolymorphic_testTp1{a:i32,b:i32}>>) (%{{.*}}, %{{.*}}, %{{.*}} : f32, f32, !fir.class<!fir.type<_QMpolymorphic_testTp1{a:i32,b:i32}>>) {pass_arg_pos = 2 : i32}
  // SPARCV9: fir.dispatch "with_complex2"(%{{.*}} : !fir.class<!fir.type<_QMpolymorphic_testTp1{a:i32,b:i32}>>) (%{{.*}}, %{{.*}}, %{{.*}} : f32, f32, !fir.class<!fir.type<_QMpolymorphic_testTp1{a:i32,b:i32}>>) {pass_arg_pos = 2 : i32}
  // RISCV64: fir.dispatch "with_complex2"(%{{.*}} : !fir.class<!fir.type<_QMpolymorphic_testTp1{a:i32,b:i32}>>) (%{{.*}}, %{{.*}}, %{{.*}} : f32, f32, !fir.class<!fir.type<_QMpolymorphic_testTp1{a:i32,b:i32}>>) {pass_arg_pos = 2 : i32}
  // PPC64: fir.dispatch "with_complex2"(%{{.*}} : !fir.class<!fir.type<_QMpolymorphic_testTp1{a:i32,b:i32}>>) (%{{.*}}, %{{.*}}, %{{.*}} : f32, f32, !fir.class<!fir.type<_QMpolymorphic_testTp1{a:i32,b:i32}>>) {pass_arg_pos = 2 : i32}
  // LOONGARCH64: fir.dispatch "with_complex2"(%{{.*}} : !fir.class<!fir.type<_QMpolymorphic_testTp1{a:i32,b:i32}>>) (%{{.*}}, %{{.*}}, %{{.*}} : f32, f32, !fir.class<!fir.type<_QMpolymorphic_testTp1{a:i32,b:i32}>>) {pass_arg_pos = 2 : i32}
  fir.dispatch "with_complex2"(%arg0 : !fir.class<!fir.type<_QMpolymorphic_testTp1{a:i32,b:i32}>>) (%2, %arg0 : complex<f32>, !fir.class<!fir.type<_QMpolymorphic_testTp1{a:i32,b:i32}>>) {pass_arg_pos = 1 : i32}

  return
}

// Test that we rewrite the signature of a function that accepts a complex<8>.
// I32-LABEL: func private @paramcomplex8(!fir.ref<tuple<f64, f64>> {llvm.align = 4 : i32, llvm.byval = tuple<f64, f64>})
// I32_MINGW-LABEL: func private @paramcomplex8(!fir.ref<tuple<f64, f64>> {llvm.align = 4 : i32, llvm.byval = tuple<f64, f64>})
// X64-LABEL: func private @paramcomplex8(f64, f64)
// X64_MINGW-LABEL: func private @paramcomplex8(!fir.ref<tuple<f64, f64>> {llvm.align = 8 : i32, llvm.byval = tuple<f64, f64>})
// AARCH64-LABEL: func private @paramcomplex8(!fir.array<2xf64>)
// PPC64le-LABEL: func private @paramcomplex8(f64, f64)
// SPARCV9-LABEL: func private @paramcomplex8(f64, f64)
// RISCV64-LABEL: func private @paramcomplex8(f64, f64)
// PPC64-LABEL: func private @paramcomplex8(f64, f64)
// LOONGARCH64-LABEL: func private @paramcomplex8(f64, f64)
func.func private @paramcomplex8(complex<f64>) -> ()

// Test that we rewrite calls to functions that return or accept complex<8>.
// I32-LABEL: func @callcomplex8()
// I32_MINGW-LABEL: func @callcomplex8()
// X64-LABEL: func @callcomplex8()
// X64_MINGW-LABEL: func @callcomplex8()
// AARCH64-LABEL: func @callcomplex8()
// PPC64le-LABEL: func @callcomplex8()
// SPARCV9-LABEL: func @callcomplex8()
// RISCV64-LABEL: func @callcomplex8()
// PPC64-LABEL: func @callcomplex8()
// LOONGARCH64-LABEL: func @callcomplex8()
func.func @callcomplex8() {
  // I32: [[RES:%[0-9A-Za-z]+]] = fir.alloca tuple<f64, f64>
  // I32: fir.call @returncomplex8([[RES]]) : (!fir.ref<tuple<f64, f64>>) -> ()
  // I32_MINGW: [[RES:%[0-9A-Za-z]+]] = fir.alloca tuple<f64, f64>
  // I32_MINGW: fir.call @returncomplex8([[RES]]) : (!fir.ref<tuple<f64, f64>>) -> ()
  // X64: [[RES:%[0-9A-Za-z]+]] = fir.call @returncomplex8() : () -> tuple<f64, f64>
  // X64_MINGW: [[RES:%[0-9A-Za-z]+]] = fir.alloca tuple<f64, f64>
  // X64_MINGW: fir.call @returncomplex8([[RES]]) : (!fir.ref<tuple<f64, f64>>) -> ()
  // AARCH64: [[RES:%[0-9A-Za-z]+]] = fir.call @returncomplex8() : () -> tuple<f64, f64>
  // PPC64le: [[RES:%[0-9A-Za-z]+]] = fir.call @returncomplex8() : () -> tuple<f64, f64>
  // SPARCV9: [[RES:%[0-9A-Za-z]+]] = fir.call @returncomplex8() : () -> tuple<f64, f64>
  // RISCV64: [[RES:%[0-9A-Za-z]+]] = fir.call @returncomplex8() : () -> tuple<f64, f64>
  // PPC64: [[RES:%[0-9A-Za-z]+]] = fir.call @returncomplex8() : () -> tuple<f64, f64>
  // LOONGARCH64: [[RES:%[0-9A-Za-z]+]] = fir.call @returncomplex8() : () -> tuple<f64, f64>
  %1 = fir.call @returncomplex8() : () -> complex<f64>

  // I32: [[RESC:%[0-9A-Za-z]+]] = fir.convert [[RES]] : (!fir.ref<tuple<f64, f64>>) -> !fir.ref<complex<f64>>
  // I32: [[V:%[0-9A-Za-z]+]]  = fir.load [[RESC]] : !fir.ref<complex<f64>>
  // I32: [[ADDRC:%[0-9A-Za-z]+]] = fir.alloca complex<f64>
  // I32: fir.store [[V]] to [[ADDRC]] : !fir.ref<complex<f64>>
  // I32: [[ADDRT:%[0-9A-Za-z]+]] = fir.convert [[ADDRC]] : (!fir.ref<complex<f64>>) -> !fir.ref<tuple<f64, f64>>
  // I32: fir.call @paramcomplex8([[ADDRT]]) : (!fir.ref<tuple<f64, f64>>) -> ()

  // I32_MINGW: [[RESC:%[0-9A-Za-z]+]] = fir.convert [[RES]] : (!fir.ref<tuple<f64, f64>>) -> !fir.ref<complex<f64>>
  // I32_MINGW: [[V:%[0-9A-Za-z]+]]  = fir.load [[RESC]] : !fir.ref<complex<f64>>
  // I32_MINGW: [[ADDRC:%[0-9A-Za-z]+]] = fir.alloca complex<f64>
  // I32_MINGW: fir.store [[V]] to [[ADDRC]] : !fir.ref<complex<f64>>
  // I32_MINGW: [[ADDRT:%[0-9A-Za-z]+]] = fir.convert [[ADDRC]] : (!fir.ref<complex<f64>>) -> !fir.ref<tuple<f64, f64>>
  // I32_MINGW: fir.call @paramcomplex8([[ADDRT]]) : (!fir.ref<tuple<f64, f64>>) -> ()

  // X64: [[ADDRT:%[0-9A-Za-z]+]] = fir.alloca tuple<f64, f64>
  // X64: fir.store [[RES]] to [[ADDRT]] : !fir.ref<tuple<f64, f64>>
  // X64: [[ADDRC:%[0-9A-Za-z]+]] = fir.convert [[ADDRT]] : (!fir.ref<tuple<f64, f64>>) -> !fir.ref<complex<f64>>
  // X64: [[V:%[0-9A-Za-z]+]] = fir.load [[ADDRC]] : !fir.ref<complex<f64>>
  // X64: [[A:%[0-9A-Za-z]+]] = fir.extract_value [[V]], [0 : i32] : (complex<f64>) -> f64
  // X64: [[B:%[0-9A-Za-z]+]] = fir.extract_value [[V]], [1 : i32] : (complex<f64>) -> f64
  // X64: fir.call @paramcomplex8([[A]], [[B]]) : (f64, f64) -> ()

  // X64_MINGW: [[RESC:%[0-9A-Za-z]+]] = fir.convert [[RES]] : (!fir.ref<tuple<f64, f64>>) -> !fir.ref<complex<f64>>
  // X64_MINGW: [[V:%[0-9A-Za-z]+]]  = fir.load [[RESC]] : !fir.ref<complex<f64>>
  // X64_MINGW: [[ADDRC:%[0-9A-Za-z]+]] = fir.alloca complex<f64>
  // X64_MINGW: fir.store [[V]] to [[ADDRC]] : !fir.ref<complex<f64>>
  // X64_MINGW: [[ADDRT:%[0-9A-Za-z]+]] = fir.convert [[ADDRC]] : (!fir.ref<complex<f64>>) -> !fir.ref<tuple<f64, f64>>
  // X64_MINGW: fir.call @paramcomplex8([[ADDRT]]) : (!fir.ref<tuple<f64, f64>>) -> ()

  // AARCH64: [[ADDRT:%[0-9A-Za-z]+]] = fir.alloca tuple<f64, f64>
  // AARCH64: fir.store [[RES]] to [[ADDRT]] : !fir.ref<tuple<f64, f64>>
  // AARCH64: [[ADDRV:%[0-9A-Za-z]+]] = fir.convert [[ADDRT]] : (!fir.ref<tuple<f64, f64>>) -> !fir.ref<complex<f64>>
  // AARCH64: [[V:%[0-9A-Za-z]+]] = fir.load [[ADDRV]] : !fir.ref<complex<f64>>
  // AARCH64: [[ADDRARR:%[0-9A-Za-z]+]] = fir.alloca !fir.array<2xf64>
  // AARCH64: [[ADDRC:%[0-9A-Za-z]+]] = fir.convert [[ADDRARR]] : (!fir.ref<!fir.array<2xf64>>) -> !fir.ref<complex<f64>>
  // AARCH64: fir.store [[V]] to [[ADDRC]] : !fir.ref<complex<f64>>
  // AARCH64: [[ARR:%[0-9A-Za-z]+]] = fir.load [[ADDRARR]] : !fir.ref<!fir.array<2xf64>>
  // AARCH64: fir.call @paramcomplex8([[ARR]]) : (!fir.array<2xf64>) -> ()

  // PPC64le: [[ADDRT:%[0-9A-Za-z]+]] = fir.alloca tuple<f64, f64>
  // PPC64le: fir.store [[RES]] to [[ADDRT]] : !fir.ref<tuple<f64, f64>>
  // PPC64le: [[ADDRC:%[0-9A-Za-z]+]] = fir.convert [[ADDRT]] : (!fir.ref<tuple<f64, f64>>) -> !fir.ref<complex<f64>>
  // PPC64le: [[V:%[0-9A-Za-z]+]] = fir.load [[ADDRC]] : !fir.ref<complex<f64>>
  // PPC64le: [[A:%[0-9A-Za-z]+]] = fir.extract_value [[V]], [0 : i32] : (complex<f64>) -> f64
  // PPC64le: [[B:%[0-9A-Za-z]+]] = fir.extract_value [[V]], [1 : i32] : (complex<f64>) -> f64
  // PPC64le: fir.call @paramcomplex8([[A]], [[B]]) : (f64, f64) -> ()

  // SPARCV9: [[ADDRT:%[0-9A-Za-z]+]] = fir.alloca tuple<f64, f64>
  // SPARCV9: fir.store [[RES]] to [[ADDRT]] : !fir.ref<tuple<f64, f64>>
  // SPARCV9: [[ADDRC:%[0-9A-Za-z]+]] = fir.convert [[ADDRT]] : (!fir.ref<tuple<f64, f64>>) -> !fir.ref<complex<f64>>
  // SPARCV9: [[V:%[0-9A-Za-z]+]] = fir.load [[ADDRC]] : !fir.ref<complex<f64>>
  // SPARCV9: [[A:%[0-9A-Za-z]+]] = fir.extract_value [[V]], [0 : i32] : (complex<f64>) -> f64
  // SPARCV9: [[B:%[0-9A-Za-z]+]] = fir.extract_value [[V]], [1 : i32] : (complex<f64>) -> f64
  // SPARCV9: fir.call @paramcomplex8([[A]], [[B]]) : (f64, f64) -> ()

  // RISCV64: [[ADDRT:%[0-9A-Za-z]+]] = fir.alloca tuple<f64, f64>
  // RISCV64: fir.store [[RES]] to [[ADDRT]] : !fir.ref<tuple<f64, f64>>
  // RISCV64: [[ADDRC:%[0-9A-Za-z]+]] = fir.convert [[ADDRT]] : (!fir.ref<tuple<f64, f64>>) -> !fir.ref<complex<f64>>
  // RISCV64: [[V:%[0-9A-Za-z]+]] = fir.load [[ADDRC]] : !fir.ref<complex<f64>>
  // RISCV64: [[A:%[0-9A-Za-z]+]] = fir.extract_value [[V]], [0 : i32] : (complex<f64>) -> f64
  // RISCV64: [[B:%[0-9A-Za-z]+]] = fir.extract_value [[V]], [1 : i32] : (complex<f64>) -> f64
  // RISCV64: fir.call @paramcomplex8([[A]], [[B]]) : (f64, f64) -> ()

  // PPC64: [[ADDRT:%[0-9A-Za-z]+]] = fir.alloca tuple<f64, f64>
  // PPC64: fir.store [[RES]] to [[ADDRT]] : !fir.ref<tuple<f64, f64>>
  // PPC64: [[ADDRC:%[0-9A-Za-z]+]] = fir.convert [[ADDRT]] : (!fir.ref<tuple<f64, f64>>) -> !fir.ref<complex<f64>>
  // PPC64: [[V:%[0-9A-Za-z]+]] = fir.load [[ADDRC]] : !fir.ref<complex<f64>>
  // PPC64: [[A:%[0-9A-Za-z]+]] = fir.extract_value [[V]], [0 : i32] : (complex<f64>) -> f64
  // PPC64: [[B:%[0-9A-Za-z]+]] = fir.extract_value [[V]], [1 : i32] : (complex<f64>) -> f64
  // PPC64: fir.call @paramcomplex8([[A]], [[B]]) : (f64, f64) -> ()

  // LOONGARCH64: [[ADDRT:%[0-9A-Za-z]+]] = fir.alloca tuple<f64, f64>
  // LOONGARCH64: fir.store [[RES]] to [[ADDRT]] : !fir.ref<tuple<f64, f64>>
  // LOONGARCH64: [[ADDRC:%[0-9A-Za-z]+]] = fir.convert [[ADDRT]] : (!fir.ref<tuple<f64, f64>>) -> !fir.ref<complex<f64>>
  // LOONGARCH64: [[V:%[0-9A-Za-z]+]] = fir.load [[ADDRC]] : !fir.ref<complex<f64>>
  // LOONGARCH64: [[A:%[0-9A-Za-z]+]] = fir.extract_value [[V]], [0 : i32] : (complex<f64>) -> f64
  // LOONGARCH64: [[B:%[0-9A-Za-z]+]] = fir.extract_value [[V]], [1 : i32] : (complex<f64>) -> f64
  // LOONGARCH64: fir.call @paramcomplex8([[A]], [[B]]) : (f64, f64) -> ()
  
  fir.call @paramcomplex8(%1) : (complex<f64>) -> ()
  return
}

// Test multiple complex<4> parameters and arguments
// I32-LABEL: func private @calleemultipleparamscomplex4(!fir.ref<tuple<f32, f32>> {llvm.align = 4 : i32, llvm.byval = tuple<f32, f32>}, !fir.ref<tuple<f32, f32>> {llvm.align = 4 : i32, llvm.byval = tuple<f32, f32>}, !fir.ref<tuple<f32, f32>> {llvm.align = 4 : i32, llvm.byval = tuple<f32, f32>})
// I32_MINGW-LABEL: func private @calleemultipleparamscomplex4(!fir.ref<tuple<f32, f32>> {llvm.align = 4 : i32, llvm.byval = tuple<f32, f32>}, !fir.ref<tuple<f32, f32>> {llvm.align = 4 : i32, llvm.byval = tuple<f32, f32>}, !fir.ref<tuple<f32, f32>> {llvm.align = 4 : i32, llvm.byval = tuple<f32, f32>})
// X64-LABEL: func private @calleemultipleparamscomplex4(!fir.vector<2:f32>, !fir.vector<2:f32>, !fir.vector<2:f32>)
// X64_MINGW-LABEL: func private @calleemultipleparamscomplex4(i64, i64, i64)
// AARCH64-LABEL: func private @calleemultipleparamscomplex4(!fir.array<2xf32>, !fir.array<2xf32>, !fir.array<2xf32>)
// PPC64le-LABEL: func private @calleemultipleparamscomplex4(f32, f32, f32, f32, f32, f32)
// SPARCV9-LABEL: func private @calleemultipleparamscomplex4(f32, f32, f32, f32, f32, f32)
// RISCV64-LABEL: func private @calleemultipleparamscomplex4(f32, f32, f32, f32, f32, f32)
// PPC64-LABEL: func private @calleemultipleparamscomplex4(f32, f32, f32, f32, f32, f32)
// LOONGARCH64-LABEL: func private @calleemultipleparamscomplex4(f32, f32, f32, f32, f32, f32)
func.func private @calleemultipleparamscomplex4(complex<f32>, complex<f32>, complex<f32>) -> ()

// I32-LABEL: func @multipleparamscomplex4
// I32-SAME: ([[Z1:%[0-9A-Za-z]+]]: !fir.ref<tuple<f32, f32>> {llvm.align = 4 : i32, llvm.byval = tuple<f32, f32>}, [[Z2:%[0-9A-Za-z]+]]: !fir.ref<tuple<f32, f32>> {llvm.align = 4 : i32, llvm.byval = tuple<f32, f32>}, [[Z3:%[0-9A-Za-z]+]]: !fir.ref<tuple<f32, f32>> {llvm.align = 4 : i32, llvm.byval = tuple<f32, f32>})
// I32_MINGW-LABEL: func @multipleparamscomplex4
// I32_MINGW-SAME: ([[Z1:%[0-9A-Za-z]+]]: !fir.ref<tuple<f32, f32>> {llvm.align = 4 : i32, llvm.byval = tuple<f32, f32>}, [[Z2:%[0-9A-Za-z]+]]: !fir.ref<tuple<f32, f32>> {llvm.align = 4 : i32, llvm.byval = tuple<f32, f32>}, [[Z3:%[0-9A-Za-z]+]]: !fir.ref<tuple<f32, f32>> {llvm.align = 4 : i32, llvm.byval = tuple<f32, f32>})
// X64-LABEL: func @multipleparamscomplex4
// X64-SAME: ([[Z1:%[0-9A-Za-z]+]]: !fir.vector<2:f32>, [[Z2:%[0-9A-Za-z]+]]: !fir.vector<2:f32>, [[Z3:%[0-9A-Za-z]+]]: !fir.vector<2:f32>)
// X64_MINGW-LABEL: func @multipleparamscomplex4
// X64_MINGW-SAME: ([[Z1:%[0-9A-Za-z]+]]: i64, [[Z2:%[0-9A-Za-z]+]]: i64, [[Z3:%[0-9A-Za-z]+]]: i64)
// AARCH64-LABEL: func @multipleparamscomplex4
// AARCH64-SAME: ([[Z1:%[0-9A-Za-z]+]]: !fir.array<2xf32>, [[Z2:%[0-9A-Za-z]+]]: !fir.array<2xf32>, [[Z3:%[0-9A-Za-z]+]]: !fir.array<2xf32>)
// PPC64le-LABEL: func @multipleparamscomplex4
// PPC64le-SAME: ([[A1:%[0-9A-Za-z]+]]: f32, [[B1:%[0-9A-Za-z]+]]: f32, [[A2:%[0-9A-Za-z]+]]: f32, [[B2:%[0-9A-Za-z]+]]: f32, [[A3:%[0-9A-Za-z]+]]: f32, [[B3:%[0-9A-Za-z]+]]: f32)
// SPARCV9-LABEL: func @multipleparamscomplex4
// SPARCV9-SAME: ([[A1:%[0-9A-Za-z]+]]: f32, [[B1:%[0-9A-Za-z]+]]: f32, [[A2:%[0-9A-Za-z]+]]: f32, [[B2:%[0-9A-Za-z]+]]: f32, [[A3:%[0-9A-Za-z]+]]: f32, [[B3:%[0-9A-Za-z]+]]: f32)
// RISCV64-LABEL: func @multipleparamscomplex4
// RISCV64-SAME: ([[A1:%[0-9A-Za-z]+]]: f32, [[B1:%[0-9A-Za-z]+]]: f32, [[A2:%[0-9A-Za-z]+]]: f32, [[B2:%[0-9A-Za-z]+]]: f32, [[A3:%[0-9A-Za-z]+]]: f32, [[B3:%[0-9A-Za-z]+]]: f32)
// PPC64-LABEL: func @multipleparamscomplex4
// PPC64-SAME: ([[A1:%[0-9A-Za-z]+]]: f32, [[B1:%[0-9A-Za-z]+]]: f32, [[A2:%[0-9A-Za-z]+]]: f32, [[B2:%[0-9A-Za-z]+]]: f32, [[A3:%[0-9A-Za-z]+]]: f32, [[B3:%[0-9A-Za-z]+]]: f32)
// LOONGARCH64-LABEL: func @multipleparamscomplex4
// LOONGARCH64-SAME: ([[A1:%[0-9A-Za-z]+]]: f32, [[B1:%[0-9A-Za-z]+]]: f32, [[A2:%[0-9A-Za-z]+]]: f32, [[B2:%[0-9A-Za-z]+]]: f32, [[A3:%[0-9A-Za-z]+]]: f32, [[B3:%[0-9A-Za-z]+]]: f32)
func.func @multipleparamscomplex4(%z1 : complex<f32>, %z2 : complex<f32>, %z3 : complex<f32>) {
  // I32-DAG: [[Z1_ADDR:%[0-9A-Za-z]+]] = fir.convert [[Z1]] : (!fir.ref<tuple<f32, f32>>) -> !fir.ref<complex<f32>>
  // I32-DAG: [[Z1_VAL:%[0-9A-Za-z]+]] = fir.load [[Z1_ADDR]] : !fir.ref<complex<f32>>
  // I32-DAG: [[Z2_ADDR:%[0-9A-Za-z]+]] = fir.convert [[Z2]] : (!fir.ref<tuple<f32, f32>>) -> !fir.ref<complex<f32>>
  // I32-DAG: [[Z2_VAL:%[0-9A-Za-z]+]] = fir.load [[Z2_ADDR]] : !fir.ref<complex<f32>>
  // I32-DAG: [[Z3_ADDR:%[0-9A-Za-z]+]] = fir.convert [[Z3]] : (!fir.ref<tuple<f32, f32>>) -> !fir.ref<complex<f32>>
  // I32-DAG: [[Z3_VAL:%[0-9A-Za-z]+]] = fir.load [[Z3_ADDR]] : !fir.ref<complex<f32>>

  // I32-DAG: [[Z1_ADDRC:%[0-9A-Za-z]+]] = fir.alloca complex<f32>
  // I32-DAG: fir.store [[Z1_VAL]] to [[Z1_ADDRC]] : !fir.ref<complex<f32>>
  // I32-DAG: [[Z1_ADDRT:%[0-9A-Za-z]+]] = fir.convert [[Z1_ADDRC]] : (!fir.ref<complex<f32>>) -> !fir.ref<tuple<f32, f32>>
  // I32-DAG: [[Z2_ADDRC:%[0-9A-Za-z]+]] = fir.alloca complex<f32>
  // I32-DAG: fir.store [[Z2_VAL]] to [[Z2_ADDRC]] : !fir.ref<complex<f32>>
  // I32-DAG: [[Z2_ADDRT:%[0-9A-Za-z]+]] = fir.convert [[Z2_ADDRC]] : (!fir.ref<complex<f32>>) -> !fir.ref<tuple<f32, f32>>
  // I32-DAG: [[Z3_ADDRC:%[0-9A-Za-z]+]] = fir.alloca complex<f32>
  // I32-DAG: fir.store [[Z3_VAL]] to [[Z3_ADDRC]] : !fir.ref<complex<f32>>
  // I32-DAG: [[Z3_ADDRT:%[0-9A-Za-z]+]] = fir.convert [[Z3_ADDRC]] : (!fir.ref<complex<f32>>) -> !fir.ref<tuple<f32, f32>>

  // I32: fir.call @calleemultipleparamscomplex4([[Z1_ADDRT]], [[Z2_ADDRT]], [[Z3_ADDRT]]) : (!fir.ref<tuple<f32, f32>>, !fir.ref<tuple<f32, f32>>, !fir.ref<tuple<f32, f32>>) -> ()

  // I32_MINGW-DAG: [[Z1_ADDR:%[0-9A-Za-z]+]] = fir.convert [[Z1]] : (!fir.ref<tuple<f32, f32>>) -> !fir.ref<complex<f32>>
  // I32_MINGW-DAG: [[Z1_VAL:%[0-9A-Za-z]+]] = fir.load [[Z1_ADDR]] : !fir.ref<complex<f32>>
  // I32_MINGW-DAG: [[Z2_ADDR:%[0-9A-Za-z]+]] = fir.convert [[Z2]] : (!fir.ref<tuple<f32, f32>>) -> !fir.ref<complex<f32>>
  // I32_MINGW-DAG: [[Z2_VAL:%[0-9A-Za-z]+]] = fir.load [[Z2_ADDR]] : !fir.ref<complex<f32>>
  // I32_MINGW-DAG: [[Z3_ADDR:%[0-9A-Za-z]+]] = fir.convert [[Z3]] : (!fir.ref<tuple<f32, f32>>) -> !fir.ref<complex<f32>>
  // I32_MINGW-DAG: [[Z3_VAL:%[0-9A-Za-z]+]] = fir.load [[Z3_ADDR]] : !fir.ref<complex<f32>>

  // I32_MINGW-DAG: [[Z1_ADDRC:%[0-9A-Za-z]+]] = fir.alloca complex<f32>
  // I32_MINGW-DAG: fir.store [[Z1_VAL]] to [[Z1_ADDRC]] : !fir.ref<complex<f32>>
  // I32_MINGW-DAG: [[Z1_ADDRT:%[0-9A-Za-z]+]] = fir.convert [[Z1_ADDRC]] : (!fir.ref<complex<f32>>) -> !fir.ref<tuple<f32, f32>>
  // I32_MINGW-DAG: [[Z2_ADDRC:%[0-9A-Za-z]+]] = fir.alloca complex<f32>
  // I32_MINGW-DAG: fir.store [[Z2_VAL]] to [[Z2_ADDRC]] : !fir.ref<complex<f32>>
  // I32_MINGW-DAG: [[Z2_ADDRT:%[0-9A-Za-z]+]] = fir.convert [[Z2_ADDRC]] : (!fir.ref<complex<f32>>) -> !fir.ref<tuple<f32, f32>>
  // I32_MINGW-DAG: [[Z3_ADDRC:%[0-9A-Za-z]+]] = fir.alloca complex<f32>
  // I32_MINGW-DAG: fir.store [[Z3_VAL]] to [[Z3_ADDRC]] : !fir.ref<complex<f32>>
  // I32_MINGW-DAG: [[Z3_ADDRT:%[0-9A-Za-z]+]] = fir.convert [[Z3_ADDRC]] : (!fir.ref<complex<f32>>) -> !fir.ref<tuple<f32, f32>>

  // I32_MINGW: fir.call @calleemultipleparamscomplex4([[Z1_ADDRT]], [[Z2_ADDRT]], [[Z3_ADDRT]]) : (!fir.ref<tuple<f32, f32>>, !fir.ref<tuple<f32, f32>>, !fir.ref<tuple<f32, f32>>) -> ()

  // X64-DAG: [[Z3_ADDR:%[0-9A-Za-z]+]] = fir.alloca !fir.vector<2:f32>
  // X64-DAG: fir.store [[Z3]] to [[Z3_ADDR]] : !fir.ref<!fir.vector<2:f32>>
  // X64-DAG: [[Z3_ADDRC:%[0-9A-Za-z]+]] = fir.convert [[Z3_ADDR]] : (!fir.ref<!fir.vector<2:f32>>) -> !fir.ref<complex<f32>>
  // X64-DAG: [[Z3_VAL:%[0-9A-Za-z]+]] = fir.load [[Z3_ADDRC]] : !fir.ref<complex<f32>>
  // X64-DAG: [[Z2_ADDR:%[0-9A-Za-z]+]] = fir.alloca !fir.vector<2:f32>
  // X64-DAG: fir.store [[Z2]] to [[Z2_ADDR]] : !fir.ref<!fir.vector<2:f32>>
  // X64-DAG: [[Z2_ADDRC:%[0-9A-Za-z]+]] = fir.convert [[Z2_ADDR]] : (!fir.ref<!fir.vector<2:f32>>) -> !fir.ref<complex<f32>>
  // X64-DAG: [[Z2_VAL:%[0-9A-Za-z]+]] = fir.load [[Z2_ADDRC]] : !fir.ref<complex<f32>>
  // X64-DAG: [[Z1_ADDR:%[0-9A-Za-z]+]] = fir.alloca !fir.vector<2:f32>
  // X64-DAG: fir.store [[Z1]] to [[Z1_ADDR]] : !fir.ref<!fir.vector<2:f32>>
  // X64-DAG: [[Z1_ADDRC:%[0-9A-Za-z]+]] = fir.convert [[Z1_ADDR]] : (!fir.ref<!fir.vector<2:f32>>) -> !fir.ref<complex<f32>>
  // X64-DAG: [[Z1_VAL:%[0-9A-Za-z]+]] = fir.load [[Z1_ADDRC]] : !fir.ref<complex<f32>>

  // X64-DAG: [[Z1_ADDRV:%[0-9A-Za-z]+]] = fir.alloca !fir.vector<2:f32>
  // X64-DAG: [[Z1_ADDRC2:%[0-9A-Za-z]+]] = fir.convert [[Z1_ADDRV]] : (!fir.ref<!fir.vector<2:f32>>) -> !fir.ref<complex<f32>>
  // X64-DAG: fir.store [[Z1_VAL]] to [[Z1_ADDRC2]] : !fir.ref<complex<f32>>
  // X64-DAG: [[Z1_RELOADED:%[0-9A-Za-z]+]] = fir.load [[Z1_ADDRV]] : !fir.ref<!fir.vector<2:f32>>
  // X64-DAG: [[Z2_ADDRV:%[0-9A-Za-z]+]] = fir.alloca !fir.vector<2:f32>
  // X64-DAG: [[Z2_ADDRC2:%[0-9A-Za-z]+]] = fir.convert [[Z2_ADDRV]] : (!fir.ref<!fir.vector<2:f32>>) -> !fir.ref<complex<f32>>
  // X64-DAG: fir.store [[Z2_VAL]] to [[Z2_ADDRC2]] : !fir.ref<complex<f32>>
  // X64-DAG: [[Z2_RELOADED:%[0-9A-Za-z]+]] = fir.load [[Z2_ADDRV]] : !fir.ref<!fir.vector<2:f32>>
  // X64-DAG: [[Z3_ADDRV:%[0-9A-Za-z]+]] = fir.alloca !fir.vector<2:f32>
  // X64-DAG: [[Z3_ADDRC2:%[0-9A-Za-z]+]] = fir.convert [[Z3_ADDRV]] : (!fir.ref<!fir.vector<2:f32>>) -> !fir.ref<complex<f32>>
  // X64-DAG: fir.store [[Z3_VAL]] to [[Z3_ADDRC2]] : !fir.ref<complex<f32>>
  // X64-DAG: [[Z3_RELOADED:%[0-9A-Za-z]+]] = fir.load [[Z3_ADDRV]] : !fir.ref<!fir.vector<2:f32>>

  // X64: fir.call @calleemultipleparamscomplex4([[Z1_RELOADED]], [[Z2_RELOADED]], [[Z3_RELOADED]]) : (!fir.vector<2:f32>, !fir.vector<2:f32>, !fir.vector<2:f32>) -> ()

  // X64_MINGW-DAG: [[Z3_ADDR:%[0-9A-Za-z]+]] = fir.alloca i64
  // X64_MINGW-DAG: fir.store [[Z3]] to [[Z3_ADDR]] : !fir.ref<i64>
  // X64_MINGW-DAG: [[Z3_ADDRC:%[0-9A-Za-z]+]] = fir.convert [[Z3_ADDR]] : (!fir.ref<i64>) -> !fir.ref<complex<f32>>
  // X64_MINGW-DAG: [[Z3_VAL:%[0-9A-Za-z]+]] = fir.load [[Z3_ADDRC]] : !fir.ref<complex<f32>>
  // X64_MINGW-DAG: [[Z2_ADDR:%[0-9A-Za-z]+]] = fir.alloca i64
  // X64_MINGW-DAG: fir.store [[Z2]] to [[Z2_ADDR]] : !fir.ref<i64>
  // X64_MINGW-DAG: [[Z2_ADDRC:%[0-9A-Za-z]+]] = fir.convert [[Z2_ADDR]] : (!fir.ref<i64>) -> !fir.ref<complex<f32>>
  // X64_MINGW-DAG: [[Z2_VAL:%[0-9A-Za-z]+]] = fir.load [[Z2_ADDRC]] : !fir.ref<complex<f32>>
  // X64_MINGW-DAG: [[Z1_ADDR:%[0-9A-Za-z]+]] = fir.alloca i64
  // X64_MINGW-DAG: fir.store [[Z1]] to [[Z1_ADDR]] : !fir.ref<i64>
  // X64_MINGW-DAG: [[Z1_ADDRC:%[0-9A-Za-z]+]] = fir.convert [[Z1_ADDR]] : (!fir.ref<i64>) -> !fir.ref<complex<f32>>
  // X64_MINGW-DAG: [[Z1_VAL:%[0-9A-Za-z]+]] = fir.load [[Z1_ADDRC]] : !fir.ref<complex<f32>>

  // X64_MINGW-DAG: [[Z1_ADDRV:%[0-9A-Za-z]+]] = fir.alloca i64
  // X64_MINGW-DAG: [[Z1_ADDRC2:%[0-9A-Za-z]+]] = fir.convert [[Z1_ADDRV]] : (!fir.ref<i64>) -> !fir.ref<complex<f32>>
  // X64_MINGW-DAG: fir.store [[Z1_VAL]] to [[Z1_ADDRC2]] : !fir.ref<complex<f32>>
  // X64_MINGW-DAG: [[Z1_RELOADED:%[0-9A-Za-z]+]] = fir.load [[Z1_ADDRV]] : !fir.ref<i64>
  // X64_MINGW-DAG: [[Z2_ADDRV:%[0-9A-Za-z]+]] = fir.alloca i64
  // X64_MINGW-DAG: [[Z2_ADDRC2:%[0-9A-Za-z]+]] = fir.convert [[Z2_ADDRV]] : (!fir.ref<i64>) -> !fir.ref<complex<f32>>
  // X64_MINGW-DAG: fir.store [[Z2_VAL]] to [[Z2_ADDRC2]] : !fir.ref<complex<f32>>
  // X64_MINGW-DAG: [[Z2_RELOADED:%[0-9A-Za-z]+]] = fir.load [[Z2_ADDRV]] : !fir.ref<i64>
  // X64_MINGW-DAG: [[Z3_ADDRV:%[0-9A-Za-z]+]] = fir.alloca i64
  // X64_MINGW-DAG: [[Z3_ADDRC2:%[0-9A-Za-z]+]] = fir.convert [[Z3_ADDRV]] : (!fir.ref<i64>) -> !fir.ref<complex<f32>>
  // X64_MINGW-DAG: fir.store [[Z3_VAL]] to [[Z3_ADDRC2]] : !fir.ref<complex<f32>>
  // X64_MINGW-DAG: [[Z3_RELOADED:%[0-9A-Za-z]+]] = fir.load [[Z3_ADDRV]] : !fir.ref<i64>

  // X64_MINGW: fir.call @calleemultipleparamscomplex4([[Z1_RELOADED]], [[Z2_RELOADED]], [[Z3_RELOADED]]) : (i64, i64, i64) -> ()

  // AARCH64-DAG: [[Z3_ARR:%[0-9A-Za-z]+]] = fir.alloca !fir.array<2xf32>
  // AARCH64-DAG: fir.store [[Z3]] to [[Z3_ARR]] : !fir.ref<!fir.array<2xf32>>
  // AARCH64-DAG: [[Z3_ADDRC:%[0-9A-Za-z]+]] = fir.convert [[Z3_ARR]] : (!fir.ref<!fir.array<2xf32>>) -> !fir.ref<complex<f32>>
  // AARCH64-DAG: [[Z3_VAL:%[0-9A-Za-z]+]] = fir.load [[Z3_ADDRC]] : !fir.ref<complex<f32>>
  // AARCH64-DAG: [[Z2_ARR:%[0-9A-Za-z]+]] = fir.alloca !fir.array<2xf32>
  // AARCH64-DAG: fir.store [[Z2]] to [[Z2_ARR]] : !fir.ref<!fir.array<2xf32>>
  // AARCH64-DAG: [[Z2_ADDRC:%[0-9A-Za-z]+]] = fir.convert [[Z2_ARR]] : (!fir.ref<!fir.array<2xf32>>) -> !fir.ref<complex<f32>>
  // AARCH64-DAG: [[Z2_VAL:%[0-9A-Za-z]+]] = fir.load [[Z2_ADDRC]] : !fir.ref<complex<f32>>
  // AARCH64-DAG: [[Z1_ARR:%[0-9A-Za-z]+]] = fir.alloca !fir.array<2xf32>
  // AARCH64-DAG: fir.store [[Z1]] to [[Z1_ARR]] : !fir.ref<!fir.array<2xf32>>
  // AARCH64-DAG: [[Z1_ADDRC:%[0-9A-Za-z]+]] = fir.convert [[Z1_ARR]] : (!fir.ref<!fir.array<2xf32>>) -> !fir.ref<complex<f32>>
  // AARCH64-DAG: [[Z1_VAL:%[0-9A-Za-z]+]] = fir.load [[Z1_ADDRC]] : !fir.ref<complex<f32>>

  // AARCH64-DAG: [[Z1_ARR2:%[0-9A-Za-z]+]] = fir.alloca !fir.array<2xf32>
  // AARCH64-DAG: [[Z1_ADDRC2:%[0-9A-Za-z]+]] = fir.convert [[Z1_ARR2]] : (!fir.ref<!fir.array<2xf32>>) -> !fir.ref<complex<f32>>
  // AARCH64-DAG: fir.store [[Z1_VAL]] to [[Z1_ADDRC2]] : !fir.ref<complex<f32>>
  // AARCH64-DAG: [[Z1_RELOADED:%[0-9A-Za-z]+]] = fir.load [[Z1_ARR2]] : !fir.ref<!fir.array<2xf32>>
  // AARCH64-DAG: [[Z2_ARR2:%[0-9A-Za-z]+]] = fir.alloca !fir.array<2xf32>
  // AARCH64-DAG: [[Z2_ADDRC2:%[0-9A-Za-z]+]] = fir.convert [[Z2_ARR2]] : (!fir.ref<!fir.array<2xf32>>) -> !fir.ref<complex<f32>>
  // AARCH64-DAG: fir.store [[Z2_VAL]] to [[Z2_ADDRC2]] : !fir.ref<complex<f32>>
  // AARCH64-DAG: [[Z2_RELOADED:%[0-9A-Za-z]+]] = fir.load [[Z2_ARR2]] : !fir.ref<!fir.array<2xf32>>
  // AARCH64-DAG: [[Z3_ARR2:%[0-9A-Za-z]+]] = fir.alloca !fir.array<2xf32>
  // AARCH64-DAG: [[Z3_ADDRC2:%[0-9A-Za-z]+]] = fir.convert [[Z3_ARR2]] : (!fir.ref<!fir.array<2xf32>>) -> !fir.ref<complex<f32>>
  // AARCH64-DAG: fir.store [[Z3_VAL]] to [[Z3_ADDRC2]] : !fir.ref<complex<f32>>
  // AARCH64-DAG: [[Z3_RELOADED:%[0-9A-Za-z]+]] = fir.load [[Z3_ARR2]] : !fir.ref<!fir.array<2xf32>>

  // AARCH64: fir.call @calleemultipleparamscomplex4([[Z1_RELOADED]], [[Z2_RELOADED]], [[Z3_RELOADED]]) : (!fir.array<2xf32>, !fir.array<2xf32>, !fir.array<2xf32>) -> ()

  // PPC64le-DAG: [[Z3_EMPTY:%[0-9A-Za-z]+]] = fir.undefined complex<f32>
  // PPC64le-DAG: [[Z3_PARTIAL:%[0-9A-Za-z]+]] = fir.insert_value [[Z3_EMPTY]], [[A3]], [0 : i32] : (complex<f32>, f32) -> complex<f32>
  // PPC64le-DAG: [[Z3:%[0-9A-Za-z]+]] = fir.insert_value [[Z3_PARTIAL]], [[B3]], [1 : i32] : (complex<f32>, f32) -> complex<f32>
  // PPC64le-DAG: [[Z2_EMPTY:%[0-9A-Za-z]+]] = fir.undefined complex<f32>
  // PPC64le-DAG: [[Z2_PARTIAL:%[0-9A-Za-z]+]] = fir.insert_value [[Z2_EMPTY]], [[A2]], [0 : i32] : (complex<f32>, f32) -> complex<f32>
  // PPC64le-DAG: [[Z2:%[0-9A-Za-z]+]] = fir.insert_value [[Z2_PARTIAL]], [[B2]], [1 : i32] : (complex<f32>, f32) -> complex<f32>
  // PPC64le-DAG: [[Z1_EMPTY:%[0-9A-Za-z]+]] = fir.undefined complex<f32>
  // PPC64le-DAG: [[Z1_PARTIAL:%[0-9A-Za-z]+]] = fir.insert_value [[Z1_EMPTY]], [[A1]], [0 : i32] : (complex<f32>, f32) -> complex<f32>
  // PPC64le-DAG: [[Z1:%[0-9A-Za-z]+]] = fir.insert_value [[Z1_PARTIAL]], [[B1]], [1 : i32] : (complex<f32>, f32) -> complex<f32>

  // PPC64le-DAG: [[A1_EXTR:%[0-9A-Za-z]+]] = fir.extract_value [[Z1]], [0 : i32] : (complex<f32>) -> f32
  // PPC64le-DAG: [[B1_EXTR:%[0-9A-Za-z]+]] = fir.extract_value [[Z1]], [1 : i32] : (complex<f32>) -> f32
  // PPC64le-DAG: [[A2_EXTR:%[0-9A-Za-z]+]] = fir.extract_value [[Z2]], [0 : i32] : (complex<f32>) -> f32
  // PPC64le-DAG: [[B2_EXTR:%[0-9A-Za-z]+]] = fir.extract_value [[Z2]], [1 : i32] : (complex<f32>) -> f32
  // PPC64le-DAG: [[A3_EXTR:%[0-9A-Za-z]+]] = fir.extract_value [[Z3]], [0 : i32] : (complex<f32>) -> f32
  // PPC64le-DAG: [[B3_EXTR:%[0-9A-Za-z]+]] = fir.extract_value [[Z3]], [1 : i32] : (complex<f32>) -> f32

  // PPC64le: fir.call @calleemultipleparamscomplex4([[A1_EXTR]], [[B1_EXTR]], [[A2_EXTR]], [[B2_EXTR]], [[A3_EXTR]], [[B3_EXTR]]) : (f32, f32, f32, f32, f32, f32) -> ()

  // SPARCV9-DAG: [[Z3_EMPTY:%[0-9A-Za-z]+]] = fir.undefined complex<f32>
  // SPARCV9-DAG: [[Z3_PARTIAL:%[0-9A-Za-z]+]] = fir.insert_value [[Z3_EMPTY]], [[A3]], [0 : i32] : (complex<f32>, f32) -> complex<f32>
  // SPARCV9-DAG: [[Z3:%[0-9A-Za-z]+]] = fir.insert_value [[Z3_PARTIAL]], [[B3]], [1 : i32] : (complex<f32>, f32) -> complex<f32>
  // SPARCV9-DAG: [[Z2_EMPTY:%[0-9A-Za-z]+]] = fir.undefined complex<f32>
  // SPARCV9-DAG: [[Z2_PARTIAL:%[0-9A-Za-z]+]] = fir.insert_value [[Z2_EMPTY]], [[A2]], [0 : i32] : (complex<f32>, f32) -> complex<f32>
  // SPARCV9-DAG: [[Z2:%[0-9A-Za-z]+]] = fir.insert_value [[Z2_PARTIAL]], [[B2]], [1 : i32] : (complex<f32>, f32) -> complex<f32>
  // SPARCV9-DAG: [[Z1_EMPTY:%[0-9A-Za-z]+]] = fir.undefined complex<f32>
  // SPARCV9-DAG: [[Z1_PARTIAL:%[0-9A-Za-z]+]] = fir.insert_value [[Z1_EMPTY]], [[A1]], [0 : i32] : (complex<f32>, f32) -> complex<f32>
  // SPARCV9-DAG: [[Z1:%[0-9A-Za-z]+]] = fir.insert_value [[Z1_PARTIAL]], [[B1]], [1 : i32] : (complex<f32>, f32) -> complex<f32>

  // SPARCV9-DAG: [[A1_EXTR:%[0-9A-Za-z]+]] = fir.extract_value [[Z1]], [0 : i32] : (complex<f32>) -> f32
  // SPARCV9-DAG: [[B1_EXTR:%[0-9A-Za-z]+]] = fir.extract_value [[Z1]], [1 : i32] : (complex<f32>) -> f32
  // SPARCV9-DAG: [[A2_EXTR:%[0-9A-Za-z]+]] = fir.extract_value [[Z2]], [0 : i32] : (complex<f32>) -> f32
  // SPARCV9-DAG: [[B2_EXTR:%[0-9A-Za-z]+]] = fir.extract_value [[Z2]], [1 : i32] : (complex<f32>) -> f32
  // SPARCV9-DAG: [[A3_EXTR:%[0-9A-Za-z]+]] = fir.extract_value [[Z3]], [0 : i32] : (complex<f32>) -> f32
  // SPARCV9-DAG: [[B3_EXTR:%[0-9A-Za-z]+]] = fir.extract_value [[Z3]], [1 : i32] : (complex<f32>) -> f32

  // SPARCV9: fir.call @calleemultipleparamscomplex4([[A1_EXTR]], [[B1_EXTR]], [[A2_EXTR]], [[B2_EXTR]], [[A3_EXTR]], [[B3_EXTR]]) : (f32, f32, f32, f32, f32, f32) -> ()

  // RISCV64-DAG: [[Z3_EMPTY:%[0-9A-Za-z]+]] = fir.undefined complex<f32>
  // RISCV64-DAG: [[Z3_PARTIAL:%[0-9A-Za-z]+]] = fir.insert_value [[Z3_EMPTY]], [[A3]], [0 : i32] : (complex<f32>, f32) -> complex<f32>
  // RISCV64-DAG: [[Z3:%[0-9A-Za-z]+]] = fir.insert_value [[Z3_PARTIAL]], [[B3]], [1 : i32] : (complex<f32>, f32) -> complex<f32>
  // RISCV64-DAG: [[Z2_EMPTY:%[0-9A-Za-z]+]] = fir.undefined complex<f32>
  // RISCV64-DAG: [[Z2_PARTIAL:%[0-9A-Za-z]+]] = fir.insert_value [[Z2_EMPTY]], [[A2]], [0 : i32] : (complex<f32>, f32) -> complex<f32>
  // RISCV64-DAG: [[Z2:%[0-9A-Za-z]+]] = fir.insert_value [[Z2_PARTIAL]], [[B2]], [1 : i32] : (complex<f32>, f32) -> complex<f32>
  // RISCV64-DAG: [[Z1_EMPTY:%[0-9A-Za-z]+]] = fir.undefined complex<f32>
  // RISCV64-DAG: [[Z1_PARTIAL:%[0-9A-Za-z]+]] = fir.insert_value [[Z1_EMPTY]], [[A1]], [0 : i32] : (complex<f32>, f32) -> complex<f32>
  // RISCV64-DAG: [[Z1:%[0-9A-Za-z]+]] = fir.insert_value [[Z1_PARTIAL]], [[B1]], [1 : i32] : (complex<f32>, f32) -> complex<f32>

  // RISCV64-DAG: [[A1_EXTR:%[0-9A-Za-z]+]] = fir.extract_value [[Z1]], [0 : i32] : (complex<f32>) -> f32
  // RISCV64-DAG: [[B1_EXTR:%[0-9A-Za-z]+]] = fir.extract_value [[Z1]], [1 : i32] : (complex<f32>) -> f32
  // RISCV64-DAG: [[A2_EXTR:%[0-9A-Za-z]+]] = fir.extract_value [[Z2]], [0 : i32] : (complex<f32>) -> f32
  // RISCV64-DAG: [[B2_EXTR:%[0-9A-Za-z]+]] = fir.extract_value [[Z2]], [1 : i32] : (complex<f32>) -> f32
  // RISCV64-DAG: [[A3_EXTR:%[0-9A-Za-z]+]] = fir.extract_value [[Z3]], [0 : i32] : (complex<f32>) -> f32
  // RISCV64-DAG: [[B3_EXTR:%[0-9A-Za-z]+]] = fir.extract_value [[Z3]], [1 : i32] : (complex<f32>) -> f32

  // RISCV64: fir.call @calleemultipleparamscomplex4([[A1_EXTR]], [[B1_EXTR]], [[A2_EXTR]], [[B2_EXTR]], [[A3_EXTR]], [[B3_EXTR]]) : (f32, f32, f32, f32, f32, f32) -> ()
  // PPC64-DAG: [[Z3_EMPTY:%[0-9A-Za-z]+]] = fir.undefined complex<f32>
  // PPC64-DAG: [[Z3_PARTIAL:%[0-9A-Za-z]+]] = fir.insert_value [[Z3_EMPTY]], [[A3]], [0 : i32] : (complex<f32>, f32) -> complex<f32>
  // PPC64-DAG: [[Z3:%[0-9A-Za-z]+]] = fir.insert_value [[Z3_PARTIAL]], [[B3]], [1 : i32] : (complex<f32>, f32) -> complex<f32>
  // PPC64-DAG: [[Z2_EMPTY:%[0-9A-Za-z]+]] = fir.undefined complex<f32>
  // PPC64-DAG: [[Z2_PARTIAL:%[0-9A-Za-z]+]] = fir.insert_value [[Z2_EMPTY]], [[A2]], [0 : i32] : (complex<f32>, f32) -> complex<f32>
  // PPC64-DAG: [[Z2:%[0-9A-Za-z]+]] = fir.insert_value [[Z2_PARTIAL]], [[B2]], [1 : i32] : (complex<f32>, f32) -> complex<f32>
  // PPC64-DAG: [[Z1_EMPTY:%[0-9A-Za-z]+]] = fir.undefined complex<f32>
  // PPC64-DAG: [[Z1_PARTIAL:%[0-9A-Za-z]+]] = fir.insert_value [[Z1_EMPTY]], [[A1]], [0 : i32] : (complex<f32>, f32) -> complex<f32>
  // PPC64-DAG: [[Z1:%[0-9A-Za-z]+]] = fir.insert_value [[Z1_PARTIAL]], [[B1]], [1 : i32] : (complex<f32>, f32) -> complex<f32>

  // PPC64-DAG: [[A1_EXTR:%[0-9A-Za-z]+]] = fir.extract_value [[Z1]], [0 : i32] : (complex<f32>) -> f32
  // PPC64-DAG: [[B1_EXTR:%[0-9A-Za-z]+]] = fir.extract_value [[Z1]], [1 : i32] : (complex<f32>) -> f32
  // PPC64-DAG: [[A2_EXTR:%[0-9A-Za-z]+]] = fir.extract_value [[Z2]], [0 : i32] : (complex<f32>) -> f32
  // PPC64-DAG: [[B2_EXTR:%[0-9A-Za-z]+]] = fir.extract_value [[Z2]], [1 : i32] : (complex<f32>) -> f32
  // PPC64-DAG: [[A3_EXTR:%[0-9A-Za-z]+]] = fir.extract_value [[Z3]], [0 : i32] : (complex<f32>) -> f32
  // PPC64-DAG: [[B3_EXTR:%[0-9A-Za-z]+]] = fir.extract_value [[Z3]], [1 : i32] : (complex<f32>) -> f32

  // PPC64: fir.call @calleemultipleparamscomplex4([[A1_EXTR]], [[B1_EXTR]], [[A2_EXTR]], [[B2_EXTR]], [[A3_EXTR]], [[B3_EXTR]]) : (f32, f32, f32, f32, f32, f32) -> ()
  // LOONGARCH64-DAG: [[Z3_EMPTY:%[0-9A-Za-z]+]] = fir.undefined complex<f32>
  // LOONGARCH64-DAG: [[Z3_PARTIAL:%[0-9A-Za-z]+]] = fir.insert_value [[Z3_EMPTY]], [[A3]], [0 : i32] : (complex<f32>, f32) -> complex<f32>
  // LOONGARCH64-DAG: [[Z3:%[0-9A-Za-z]+]] = fir.insert_value [[Z3_PARTIAL]], [[B3]], [1 : i32] : (complex<f32>, f32) -> complex<f32>
  // LOONGARCH64-DAG: [[Z2_EMPTY:%[0-9A-Za-z]+]] = fir.undefined complex<f32>
  // LOONGARCH64-DAG: [[Z2_PARTIAL:%[0-9A-Za-z]+]] = fir.insert_value [[Z2_EMPTY]], [[A2]], [0 : i32] : (complex<f32>, f32) -> complex<f32>
  // LOONGARCH64-DAG: [[Z2:%[0-9A-Za-z]+]] = fir.insert_value [[Z2_PARTIAL]], [[B2]], [1 : i32] : (complex<f32>, f32) -> complex<f32>
  // LOONGARCH64-DAG: [[Z1_EMPTY:%[0-9A-Za-z]+]] = fir.undefined complex<f32>
  // LOONGARCH64-DAG: [[Z1_PARTIAL:%[0-9A-Za-z]+]] = fir.insert_value [[Z1_EMPTY]], [[A1]], [0 : i32] : (complex<f32>, f32) -> complex<f32>
  // LOONGARCH64-DAG: [[Z1:%[0-9A-Za-z]+]] = fir.insert_value [[Z1_PARTIAL]], [[B1]], [1 : i32] : (complex<f32>, f32) -> complex<f32>

  // LOONGARCH64-DAG: [[A1_EXTR:%[0-9A-Za-z]+]] = fir.extract_value [[Z1]], [0 : i32] : (complex<f32>) -> f32
  // LOONGARCH64-DAG: [[B1_EXTR:%[0-9A-Za-z]+]] = fir.extract_value [[Z1]], [1 : i32] : (complex<f32>) -> f32
  // LOONGARCH64-DAG: [[A2_EXTR:%[0-9A-Za-z]+]] = fir.extract_value [[Z2]], [0 : i32] : (complex<f32>) -> f32
  // LOONGARCH64-DAG: [[B2_EXTR:%[0-9A-Za-z]+]] = fir.extract_value [[Z2]], [1 : i32] : (complex<f32>) -> f32
  // LOONGARCH64-DAG: [[A3_EXTR:%[0-9A-Za-z]+]] = fir.extract_value [[Z3]], [0 : i32] : (complex<f32>) -> f32
  // LOONGARCH64-DAG: [[B3_EXTR:%[0-9A-Za-z]+]] = fir.extract_value [[Z3]], [1 : i32] : (complex<f32>) -> f32

  // LOONGARCH64: fir.call @calleemultipleparamscomplex4([[A1_EXTR]], [[B1_EXTR]], [[A2_EXTR]], [[B2_EXTR]], [[A3_EXTR]], [[B3_EXTR]]) : (f32, f32, f32, f32, f32, f32) -> ()
  fir.call @calleemultipleparamscomplex4(%z1, %z2, %z3) : (complex<f32>, complex<f32>, complex<f32>) -> ()
  return
}

// Test that we rewrite the signature of and calls to a function that accepts
// and returns MLIR complex<f32>.

// I32-LABEL: func private @mlircomplexf32
// I32-SAME: ([[Z1:%[0-9A-Za-z]+]]: !fir.ref<tuple<f32, f32>> {llvm.align = 4 : i32, llvm.byval = tuple<f32, f32>}, [[Z2:%[0-9A-Za-z]+]]: !fir.ref<tuple<f32, f32>> {llvm.align = 4 : i32, llvm.byval = tuple<f32, f32>})
// I32-SAME: -> i64
// I32_MINGW-LABEL: func private @mlircomplexf32
// I32_MINGW-SAME: ([[Z1:%[0-9A-Za-z]+]]: !fir.ref<tuple<f32, f32>> {llvm.align = 4 : i32, llvm.byval = tuple<f32, f32>}, [[Z2:%[0-9A-Za-z]+]]: !fir.ref<tuple<f32, f32>> {llvm.align = 4 : i32, llvm.byval = tuple<f32, f32>})
// I32_MINGW-SAME: -> i64
// X64-LABEL: func private @mlircomplexf32
// X64-SAME: ([[Z1:%[0-9A-Za-z]+]]: !fir.vector<2:f32>, [[Z2:%[0-9A-Za-z]+]]: !fir.vector<2:f32>)
// X64-SAME: -> !fir.vector<2:f32>
// X64_MINGW-LABEL: func private @mlircomplexf32
// X64_MINGW-SAME: ([[Z1:%[0-9A-Za-z]+]]: i64, [[Z2:%[0-9A-Za-z]+]]: i64)
// X64_MINGW-SAME: -> i64
// AARCH64-LABEL: func private @mlircomplexf32
// AARCH64-SAME: ([[Z1:%[0-9A-Za-z]+]]: !fir.array<2xf32>, [[Z2:%[0-9A-Za-z]+]]: !fir.array<2xf32>)
// AARCH64-SAME: -> tuple<f32, f32>
// PPC64le-LABEL: func private @mlircomplexf32
// PPC64le-SAME: ([[A1:%[0-9A-Za-z]+]]: f32, [[B1:%[0-9A-Za-z]+]]: f32, [[A2:%[0-9A-Za-z]+]]: f32, [[B2:%[0-9A-Za-z]+]]: f32)
// PPC64le-SAME: -> tuple<f32, f32>
// SPARCV9-LABEL: func private @mlircomplexf32
// SPARCV9-SAME: ([[A1:%[0-9A-Za-z]+]]: f32, [[B1:%[0-9A-Za-z]+]]: f32, [[A2:%[0-9A-Za-z]+]]: f32, [[B2:%[0-9A-Za-z]+]]: f32)
// SPARCV9-SAME: -> tuple<f32, f32>
// RISCV64-LABEL: func private @mlircomplexf32
// RISCV64-SAME: ([[A1:%[0-9A-Za-z]+]]: f32, [[B1:%[0-9A-Za-z]+]]: f32, [[A2:%[0-9A-Za-z]+]]: f32, [[B2:%[0-9A-Za-z]+]]: f32)
// RISCV64-SAME: -> tuple<f32, f32>
// PPC64-LABEL: func private @mlircomplexf32
// PPC64-SAME: ([[A1:%[0-9A-Za-z]+]]: f32, [[B1:%[0-9A-Za-z]+]]: f32, [[A2:%[0-9A-Za-z]+]]: f32, [[B2:%[0-9A-Za-z]+]]: f32)
// PPC64-SAME: -> tuple<f32, f32>
// LOONGARCH64-LABEL: func private @mlircomplexf32
// LOONGARCH64-SAME: ([[A1:%[0-9A-Za-z]+]]: f32, [[B1:%[0-9A-Za-z]+]]: f32, [[A2:%[0-9A-Za-z]+]]: f32, [[B2:%[0-9A-Za-z]+]]: f32)
// LOONGARCH64-SAME: -> tuple<f32, f32>
func.func private @mlircomplexf32(%z1: complex<f32>, %z2: complex<f32>) -> complex<f32> {

  // I32-DAG: [[Z1_ADDR:%[0-9A-Za-z]+]] = fir.convert [[Z1]] : (!fir.ref<tuple<f32, f32>>) -> !fir.ref<complex<f32>>
  // I32-DAG: [[Z1_VAL:%[0-9A-Za-z]+]] = fir.load [[Z1_ADDR]] : !fir.ref<complex<f32>>
  // I32-DAG: [[Z2_ADDR:%[0-9A-Za-z]+]] = fir.convert [[Z2]] : (!fir.ref<tuple<f32, f32>>) -> !fir.ref<complex<f32>>
  // I32-DAG: [[Z2_VAL:%[0-9A-Za-z]+]] = fir.load [[Z2_ADDR]] : !fir.ref<complex<f32>>

  // I32-DAG: [[Z1_ADDRC:%[0-9A-Za-z]+]] = fir.alloca complex<f32>
  // I32-DAG: fir.store [[Z1_VAL]] to [[Z1_ADDRC]] : !fir.ref<complex<f32>>
  // I32-DAG: [[Z1_ADDRT:%[0-9A-Za-z]+]] = fir.convert [[Z1_ADDRC]] : (!fir.ref<complex<f32>>) -> !fir.ref<tuple<f32, f32>>
  // I32-DAG: [[Z2_ADDRC:%[0-9A-Za-z]+]] = fir.alloca complex<f32>
  // I32-DAG: fir.store [[Z2_VAL]] to [[Z2_ADDRC]] : !fir.ref<complex<f32>>
  // I32-DAG: [[Z2_ADDRT:%[0-9A-Za-z]+]] = fir.convert [[Z2_ADDRC]] : (!fir.ref<complex<f32>>) -> !fir.ref<tuple<f32, f32>>

  // I32: [[VAL:%[0-9A-Za-z]+]] = fir.call @mlircomplexf32([[Z1_ADDRT]], [[Z2_ADDRT]]) : (!fir.ref<tuple<f32, f32>>, !fir.ref<tuple<f32, f32>>) -> i64

  // I32_MINGW-DAG: [[Z1_ADDR:%[0-9A-Za-z]+]] = fir.convert [[Z1]] : (!fir.ref<tuple<f32, f32>>) -> !fir.ref<complex<f32>>
  // I32_MINGW-DAG: [[Z1_VAL:%[0-9A-Za-z]+]] = fir.load [[Z1_ADDR]] : !fir.ref<complex<f32>>
  // I32_MINGW-DAG: [[Z2_ADDR:%[0-9A-Za-z]+]] = fir.convert [[Z2]] : (!fir.ref<tuple<f32, f32>>) -> !fir.ref<complex<f32>>
  // I32_MINGW-DAG: [[Z2_VAL:%[0-9A-Za-z]+]] = fir.load [[Z2_ADDR]] : !fir.ref<complex<f32>>

  // I32_MINGW-DAG: [[Z1_ADDRC:%[0-9A-Za-z]+]] = fir.alloca complex<f32>
  // I32_MINGW-DAG: fir.store [[Z1_VAL]] to [[Z1_ADDRC]] : !fir.ref<complex<f32>>
  // I32_MINGW-DAG: [[Z1_ADDRT:%[0-9A-Za-z]+]] = fir.convert [[Z1_ADDRC]] : (!fir.ref<complex<f32>>) -> !fir.ref<tuple<f32, f32>>
  // I32_MINGW-DAG: [[Z2_ADDRC:%[0-9A-Za-z]+]] = fir.alloca complex<f32>
  // I32_MINGW-DAG: fir.store [[Z2_VAL]] to [[Z2_ADDRC]] : !fir.ref<complex<f32>>
  // I32_MINGW-DAG: [[Z2_ADDRT:%[0-9A-Za-z]+]] = fir.convert [[Z2_ADDRC]] : (!fir.ref<complex<f32>>) -> !fir.ref<tuple<f32, f32>>

  // I32_MINGW: [[VAL:%[0-9A-Za-z]+]] = fir.call @mlircomplexf32([[Z1_ADDRT]], [[Z2_ADDRT]]) : (!fir.ref<tuple<f32, f32>>, !fir.ref<tuple<f32, f32>>) -> i64

  // X64-DAG: [[Z2_ADDR:%[0-9A-Za-z]+]] = fir.alloca !fir.vector<2:f32>
  // X64-DAG: fir.store [[Z2]] to [[Z2_ADDR]] : !fir.ref<!fir.vector<2:f32>>
  // X64-DAG: [[Z2_ADDRC:%[0-9A-Za-z]+]] = fir.convert [[Z2_ADDR]] : (!fir.ref<!fir.vector<2:f32>>) -> !fir.ref<complex<f32>>
  // X64-DAG: [[Z2_VAL:%[0-9A-Za-z]+]] = fir.load [[Z2_ADDRC]] : !fir.ref<complex<f32>>
  // X64-DAG: [[Z1_ADDR:%[0-9A-Za-z]+]] = fir.alloca !fir.vector<2:f32>
  // X64-DAG: fir.store [[Z1]] to [[Z1_ADDR]] : !fir.ref<!fir.vector<2:f32>>
  // X64-DAG: [[Z1_ADDRC:%[0-9A-Za-z]+]] = fir.convert [[Z1_ADDR]] : (!fir.ref<!fir.vector<2:f32>>) -> !fir.ref<complex<f32>>
  // X64-DAG: [[Z1_VAL:%[0-9A-Za-z]+]] = fir.load [[Z1_ADDRC]] : !fir.ref<complex<f32>>

  // X64-DAG: [[Z1_ADDRV:%[0-9A-Za-z]+]] = fir.alloca !fir.vector<2:f32>
  // X64-DAG: [[Z1_ADDRC2:%[0-9A-Za-z]+]] = fir.convert [[Z1_ADDRV]] : (!fir.ref<!fir.vector<2:f32>>) -> !fir.ref<complex<f32>>
  // X64-DAG: fir.store [[Z1_VAL]] to [[Z1_ADDRC2]] : !fir.ref<complex<f32>>
  // X64-DAG: [[Z1_RELOADED:%[0-9A-Za-z]+]] = fir.load [[Z1_ADDRV]] : !fir.ref<!fir.vector<2:f32>>
  // X64-DAG: [[Z2_ADDRV:%[0-9A-Za-z]+]] = fir.alloca !fir.vector<2:f32>
  // X64-DAG: [[Z2_ADDRC2:%[0-9A-Za-z]+]] = fir.convert [[Z2_ADDRV]] : (!fir.ref<!fir.vector<2:f32>>) -> !fir.ref<complex<f32>>
  // X64-DAG: fir.store [[Z2_VAL]] to [[Z2_ADDRC2]] : !fir.ref<complex<f32>>
  // X64-DAG: [[Z2_RELOADED:%[0-9A-Za-z]+]] = fir.load [[Z2_ADDRV]] : !fir.ref<!fir.vector<2:f32>>

  // X64: [[VAL:%[0-9A-Za-z]+]] = fir.call @mlircomplexf32([[Z1_RELOADED]], [[Z2_RELOADED]]) : (!fir.vector<2:f32>, !fir.vector<2:f32>) -> !fir.vector<2:f32>

  // X64_MINGW-DAG: [[Z2_ADDR:%[0-9A-Za-z]+]] = fir.alloca i64
  // X64_MINGW-DAG: fir.store [[Z2]] to [[Z2_ADDR]] : !fir.ref<i64>
  // X64_MINGW-DAG: [[Z2_ADDRC:%[0-9A-Za-z]+]] = fir.convert [[Z2_ADDR]] : (!fir.ref<i64>) -> !fir.ref<complex<f32>>
  // X64_MINGW-DAG: [[Z2_VAL:%[0-9A-Za-z]+]] = fir.load [[Z2_ADDRC]] : !fir.ref<complex<f32>>
  // X64_MINGW-DAG: [[Z1_ADDR:%[0-9A-Za-z]+]] = fir.alloca i64
  // X64_MINGW-DAG: fir.store [[Z1]] to [[Z1_ADDR]] : !fir.ref<i64>
  // X64_MINGW-DAG: [[Z1_ADDRC:%[0-9A-Za-z]+]] = fir.convert [[Z1_ADDR]] : (!fir.ref<i64>) -> !fir.ref<complex<f32>>
  // X64_MINGW-DAG: [[Z1_VAL:%[0-9A-Za-z]+]] = fir.load [[Z1_ADDRC]] : !fir.ref<complex<f32>>

  // X64_MINGW-DAG: [[Z1_ADDRV:%[0-9A-Za-z]+]] = fir.alloca i64
  // X64_MINGW-DAG: [[Z1_ADDRC2:%[0-9A-Za-z]+]] = fir.convert [[Z1_ADDRV]] : (!fir.ref<i64>) -> !fir.ref<complex<f32>>
  // X64_MINGW-DAG: fir.store [[Z1_VAL]] to [[Z1_ADDRC2]] : !fir.ref<complex<f32>>
  // X64_MINGW-DAG: [[Z1_RELOADED:%[0-9A-Za-z]+]] = fir.load [[Z1_ADDRV]] : !fir.ref<i64>
  // X64_MINGW-DAG: [[Z2_ADDRV:%[0-9A-Za-z]+]] = fir.alloca i64
  // X64_MINGW-DAG: [[Z2_ADDRC2:%[0-9A-Za-z]+]] = fir.convert [[Z2_ADDRV]] : (!fir.ref<i64>) -> !fir.ref<complex<f32>>
  // X64_MINGW-DAG: fir.store [[Z2_VAL]] to [[Z2_ADDRC2]] : !fir.ref<complex<f32>>
  // X64_MINGW-DAG: [[Z2_RELOADED:%[0-9A-Za-z]+]] = fir.load [[Z2_ADDRV]] : !fir.ref<i64>

  // X64_MINGW: [[VAL:%[0-9A-Za-z]+]] = fir.call @mlircomplexf32([[Z1_RELOADED]], [[Z2_RELOADED]]) : (i64, i64) -> i64

  // AARCH64-DAG: [[Z2_ARR:%[0-9A-Za-z]+]] = fir.alloca !fir.array<2xf32>
  // AARCH64-DAG: fir.store [[Z2]] to [[Z2_ARR]] : !fir.ref<!fir.array<2xf32>>
  // AARCH64-DAG: [[Z2_ADDRC:%[0-9A-Za-z]+]] = fir.convert [[Z2_ARR]] : (!fir.ref<!fir.array<2xf32>>) -> !fir.ref<complex<f32>>
  // AARCH64-DAG: [[Z2_VAL:%[0-9A-Za-z]+]] = fir.load [[Z2_ADDRC]] : !fir.ref<complex<f32>>
  // AARCH64-DAG: [[Z1_ARR:%[0-9A-Za-z]+]] = fir.alloca !fir.array<2xf32>
  // AARCH64-DAG: fir.store [[Z1]] to [[Z1_ARR]] : !fir.ref<!fir.array<2xf32>>
  // AARCH64-DAG: [[Z1_ADDRC:%[0-9A-Za-z]+]] = fir.convert [[Z1_ARR]] : (!fir.ref<!fir.array<2xf32>>) -> !fir.ref<complex<f32>>
  // AARCH64-DAG: [[Z1_VAL:%[0-9A-Za-z]+]] = fir.load [[Z1_ADDRC]] : !fir.ref<complex<f32>>

  // AARCH64-DAG: [[Z1_ARR2:%[0-9A-Za-z]+]] = fir.alloca !fir.array<2xf32>
  // AARCH64-DAG: [[Z1_ADDRC2:%[0-9A-Za-z]+]] = fir.convert [[Z1_ARR2]] : (!fir.ref<!fir.array<2xf32>>) -> !fir.ref<complex<f32>>
  // AARCH64-DAG: fir.store [[Z1_VAL]] to [[Z1_ADDRC2]] : !fir.ref<complex<f32>>
  // AARCH64-DAG: [[Z1_RELOADED:%[0-9A-Za-z]+]] = fir.load [[Z1_ARR2]] : !fir.ref<!fir.array<2xf32>>
  // AARCH64-DAG: [[Z2_ARR2:%[0-9A-Za-z]+]] = fir.alloca !fir.array<2xf32>
  // AARCH64-DAG: [[Z2_ADDRC2:%[0-9A-Za-z]+]] = fir.convert [[Z2_ARR2]] : (!fir.ref<!fir.array<2xf32>>) -> !fir.ref<complex<f32>>
  // AARCH64-DAG: fir.store [[Z2_VAL]] to [[Z2_ADDRC2]] : !fir.ref<complex<f32>>
  // AARCH64-DAG: [[Z2_RELOADED:%[0-9A-Za-z]+]] = fir.load [[Z2_ARR2]] : !fir.ref<!fir.array<2xf32>>

  // AARCH64: [[VAL:%[0-9A-Za-z]+]] = fir.call @mlircomplexf32([[Z1_RELOADED]], [[Z2_RELOADED]]) : (!fir.array<2xf32>, !fir.array<2xf32>) -> tuple<f32, f32>

  // PPC64le-DAG: [[Z2_EMPTY:%[0-9A-Za-z]+]] = fir.undefined complex<f32>
  // PPC64le-DAG: [[Z2_PARTIAL:%[0-9A-Za-z]+]] = fir.insert_value [[Z2_EMPTY]], [[A2]], [0 : i32] : (complex<f32>, f32) -> complex<f32>
  // PPC64le-DAG: [[Z2:%[0-9A-Za-z]+]] = fir.insert_value [[Z2_PARTIAL]], [[B2]], [1 : i32] : (complex<f32>, f32) -> complex<f32>
  // PPC64le-DAG: [[Z1_EMPTY:%[0-9A-Za-z]+]] = fir.undefined complex<f32>
  // PPC64le-DAG: [[Z1_PARTIAL:%[0-9A-Za-z]+]] = fir.insert_value [[Z1_EMPTY]], [[A1]], [0 : i32] : (complex<f32>, f32) -> complex<f32>
  // PPC64le-DAG: [[Z1:%[0-9A-Za-z]+]] = fir.insert_value [[Z1_PARTIAL]], [[B1]], [1 : i32] : (complex<f32>, f32) -> complex<f32>

  // PPC64le-DAG: [[A1_EXTR:%[0-9A-Za-z]+]] = fir.extract_value [[Z1]], [0 : i32] : (complex<f32>) -> f32
  // PPC64le-DAG: [[B1_EXTR:%[0-9A-Za-z]+]] = fir.extract_value [[Z1]], [1 : i32] : (complex<f32>) -> f32
  // PPC64le-DAG: [[A2_EXTR:%[0-9A-Za-z]+]] = fir.extract_value [[Z2]], [0 : i32] : (complex<f32>) -> f32
  // PPC64le-DAG: [[B2_EXTR:%[0-9A-Za-z]+]] = fir.extract_value [[Z2]], [1 : i32] : (complex<f32>) -> f32

  // PPC64le: [[VAL:%[0-9A-Za-z]+]] = fir.call @mlircomplexf32([[A1_EXTR]], [[B1_EXTR]], [[A2_EXTR]], [[B2_EXTR]]) : (f32, f32, f32, f32) -> tuple<f32, f32>

  // SPARCV9-DAG: [[Z2_EMPTY:%[0-9A-Za-z]+]] = fir.undefined complex<f32>
  // SPARCV9-DAG: [[Z2_PARTIAL:%[0-9A-Za-z]+]] = fir.insert_value [[Z2_EMPTY]], [[A2]], [0 : i32] : (complex<f32>, f32) -> complex<f32>
  // SPARCV9-DAG: [[Z2:%[0-9A-Za-z]+]] = fir.insert_value [[Z2_PARTIAL]], [[B2]], [1 : i32] : (complex<f32>, f32) -> complex<f32>
  // SPARCV9-DAG: [[Z1_EMPTY:%[0-9A-Za-z]+]] = fir.undefined complex<f32>
  // SPARCV9-DAG: [[Z1_PARTIAL:%[0-9A-Za-z]+]] = fir.insert_value [[Z1_EMPTY]], [[A1]], [0 : i32] : (complex<f32>, f32) -> complex<f32>
  // SPARCV9-DAG: [[Z1:%[0-9A-Za-z]+]] = fir.insert_value [[Z1_PARTIAL]], [[B1]], [1 : i32] : (complex<f32>, f32) -> complex<f32>

  // SPARCV9-DAG: [[A1_EXTR:%[0-9A-Za-z]+]] = fir.extract_value [[Z1]], [0 : i32] : (complex<f32>) -> f32
  // SPARCV9-DAG: [[B1_EXTR:%[0-9A-Za-z]+]] = fir.extract_value [[Z1]], [1 : i32] : (complex<f32>) -> f32
  // SPARCV9-DAG: [[A2_EXTR:%[0-9A-Za-z]+]] = fir.extract_value [[Z2]], [0 : i32] : (complex<f32>) -> f32
  // SPARCV9-DAG: [[B2_EXTR:%[0-9A-Za-z]+]] = fir.extract_value [[Z2]], [1 : i32] : (complex<f32>) -> f32

  // SPARCV9: [[VAL:%[0-9A-Za-z]+]] = fir.call @mlircomplexf32([[A1_EXTR]], [[B1_EXTR]], [[A2_EXTR]], [[B2_EXTR]]) : (f32, f32, f32, f32) -> tuple<f32, f32>

  // RISCV64-DAG: [[Z2_EMPTY:%[0-9A-Za-z]+]] = fir.undefined complex<f32>
  // RISCV64-DAG: [[Z2_PARTIAL:%[0-9A-Za-z]+]] = fir.insert_value [[Z2_EMPTY]], [[A2]], [0 : i32] : (complex<f32>, f32) -> complex<f32>
  // RISCV64-DAG: [[Z2:%[0-9A-Za-z]+]] = fir.insert_value [[Z2_PARTIAL]], [[B2]], [1 : i32] : (complex<f32>, f32) -> complex<f32>
  // RISCV64-DAG: [[Z1_EMPTY:%[0-9A-Za-z]+]] = fir.undefined complex<f32>
  // RISCV64-DAG: [[Z1_PARTIAL:%[0-9A-Za-z]+]] = fir.insert_value [[Z1_EMPTY]], [[A1]], [0 : i32] : (complex<f32>, f32) -> complex<f32>
  // RISCV64-DAG: [[Z1:%[0-9A-Za-z]+]] = fir.insert_value [[Z1_PARTIAL]], [[B1]], [1 : i32] : (complex<f32>, f32) -> complex<f32>

  // RISCV64-DAG: [[A1_EXTR:%[0-9A-Za-z]+]] = fir.extract_value [[Z1]], [0 : i32] : (complex<f32>) -> f32
  // RISCV64-DAG: [[B1_EXTR:%[0-9A-Za-z]+]] = fir.extract_value [[Z1]], [1 : i32] : (complex<f32>) -> f32
  // RISCV64-DAG: [[A2_EXTR:%[0-9A-Za-z]+]] = fir.extract_value [[Z2]], [0 : i32] : (complex<f32>) -> f32
  // RISCV64-DAG: [[B2_EXTR:%[0-9A-Za-z]+]] = fir.extract_value [[Z2]], [1 : i32] : (complex<f32>) -> f32

  // RISCV64: [[VAL:%[0-9A-Za-z]+]] = fir.call @mlircomplexf32([[A1_EXTR]], [[B1_EXTR]], [[A2_EXTR]], [[B2_EXTR]]) : (f32, f32, f32, f32) -> tuple<f32, f32>
  
  // PPC64-DAG: [[Z2_EMPTY:%[0-9A-Za-z]+]] = fir.undefined complex<f32>
  // PPC64-DAG: [[Z2_PARTIAL:%[0-9A-Za-z]+]] = fir.insert_value [[Z2_EMPTY]], [[A2]], [0 : i32] : (complex<f32>, f32) -> complex<f32>
  // PPC64-DAG: [[Z2:%[0-9A-Za-z]+]] = fir.insert_value [[Z2_PARTIAL]], [[B2]], [1 : i32] : (complex<f32>, f32) -> complex<f32>
  // PPC64-DAG: [[Z1_EMPTY:%[0-9A-Za-z]+]] = fir.undefined complex<f32>
  // PPC64-DAG: [[Z1_PARTIAL:%[0-9A-Za-z]+]] = fir.insert_value [[Z1_EMPTY]], [[A1]], [0 : i32] : (complex<f32>, f32) -> complex<f32>
  // PPC64-DAG: [[Z1:%[0-9A-Za-z]+]] = fir.insert_value [[Z1_PARTIAL]], [[B1]], [1 : i32] : (complex<f32>, f32) -> complex<f32>

  // PPC64-DAG: [[A1_EXTR:%[0-9A-Za-z]+]] = fir.extract_value [[Z1]], [0 : i32] : (complex<f32>) -> f32
  // PPC64-DAG: [[B1_EXTR:%[0-9A-Za-z]+]] = fir.extract_value [[Z1]], [1 : i32] : (complex<f32>) -> f32
  // PPC64-DAG: [[A2_EXTR:%[0-9A-Za-z]+]] = fir.extract_value [[Z2]], [0 : i32] : (complex<f32>) -> f32
  // PPC64-DAG: [[B2_EXTR:%[0-9A-Za-z]+]] = fir.extract_value [[Z2]], [1 : i32] : (complex<f32>) -> f32

  // PPC64: [[VAL:%[0-9A-Za-z]+]] = fir.call @mlircomplexf32([[A1_EXTR]], [[B1_EXTR]], [[A2_EXTR]], [[B2_EXTR]]) : (f32, f32, f32, f32) -> tuple<f32, f32>

  // LOONGARCH64-DAG: [[Z2_EMPTY:%[0-9A-Za-z]+]] = fir.undefined complex<f32>
  // LOONGARCH64-DAG: [[Z2_PARTIAL:%[0-9A-Za-z]+]] = fir.insert_value [[Z2_EMPTY]], [[A2]], [0 : i32] : (complex<f32>, f32) -> complex<f32>
  // LOONGARCH64-DAG: [[Z2:%[0-9A-Za-z]+]] = fir.insert_value [[Z2_PARTIAL]], [[B2]], [1 : i32] : (complex<f32>, f32) -> complex<f32>
  // LOONGARCH64-DAG: [[Z1_EMPTY:%[0-9A-Za-z]+]] = fir.undefined complex<f32>
  // LOONGARCH64-DAG: [[Z1_PARTIAL:%[0-9A-Za-z]+]] = fir.insert_value [[Z1_EMPTY]], [[A1]], [0 : i32] : (complex<f32>, f32) -> complex<f32>
  // LOONGARCH64-DAG: [[Z1:%[0-9A-Za-z]+]] = fir.insert_value [[Z1_PARTIAL]], [[B1]], [1 : i32] : (complex<f32>, f32) -> complex<f32>

  // LOONGARCH64-DAG: [[A1_EXTR:%[0-9A-Za-z]+]] = fir.extract_value [[Z1]], [0 : i32] : (complex<f32>) -> f32
  // LOONGARCH64-DAG: [[B1_EXTR:%[0-9A-Za-z]+]] = fir.extract_value [[Z1]], [1 : i32] : (complex<f32>) -> f32
  // LOONGARCH64-DAG: [[A2_EXTR:%[0-9A-Za-z]+]] = fir.extract_value [[Z2]], [0 : i32] : (complex<f32>) -> f32
  // LOONGARCH64-DAG: [[B2_EXTR:%[0-9A-Za-z]+]] = fir.extract_value [[Z2]], [1 : i32] : (complex<f32>) -> f32

  // LOONGARCH64: [[VAL:%[0-9A-Za-z]+]] = fir.call @mlircomplexf32([[A1_EXTR]], [[B1_EXTR]], [[A2_EXTR]], [[B2_EXTR]]) : (f32, f32, f32, f32) -> tuple<f32, f32>
  %0 = fir.call @mlircomplexf32(%z1, %z2) : (complex<f32>, complex<f32>) -> complex<f32>

  // I32: [[ADDRI64:%[0-9A-Za-z]+]] = fir.alloca i64
  // I32: fir.store [[VAL]] to [[ADDRI64]] : !fir.ref<i64>
  // I32: [[ADDRC:%[0-9A-Za-z]+]] = fir.convert [[ADDRI64]] : (!fir.ref<i64>) -> !fir.ref<complex<f32>>
  // I32: [[VAL_2:%[0-9A-Za-z]+]] = fir.load [[ADDRC]] : !fir.ref<complex<f32>>
  // I32: [[ADDRI64_2:%[0-9A-Za-z]+]] = fir.alloca i64
  // I32: [[ADDRC_2:%[0-9A-Za-z]+]] = fir.convert [[ADDRI64_2]] : (!fir.ref<i64>) -> !fir.ref<complex<f32>>
  // I32: fir.store [[VAL_2]] to [[ADDRC_2]] : !fir.ref<complex<f32>>
  // I32: [[RES:%[0-9A-Za-z]+]] = fir.load [[ADDRI64_2]] : !fir.ref<i64>
  // I32: return [[RES]] : i64

  // I32_MINGW: [[ADDRI64:%[0-9A-Za-z]+]] = fir.alloca i64
  // I32_MINGW: fir.store [[VAL]] to [[ADDRI64]] : !fir.ref<i64>
  // I32_MINGW: [[ADDRC:%[0-9A-Za-z]+]] = fir.convert [[ADDRI64]] : (!fir.ref<i64>) -> !fir.ref<complex<f32>>
  // I32_MINGW: [[VAL_2:%[0-9A-Za-z]+]] = fir.load [[ADDRC]] : !fir.ref<complex<f32>>
  // I32_MINGW: [[ADDRI64_2:%[0-9A-Za-z]+]] = fir.alloca i64
  // I32_MINGW: [[ADDRC_2:%[0-9A-Za-z]+]] = fir.convert [[ADDRI64_2]] : (!fir.ref<i64>) -> !fir.ref<complex<f32>>
  // I32_MINGW: fir.store [[VAL_2]] to [[ADDRC_2]] : !fir.ref<complex<f32>>
  // I32_MINGW: [[RES:%[0-9A-Za-z]+]] = fir.load [[ADDRI64_2]] : !fir.ref<i64>
  // I32_MINGW: return [[RES]] : i64

  // X64: [[ADDRV:%[0-9A-Za-z]+]] = fir.alloca !fir.vector<2:f32>
  // X64: fir.store [[VAL]] to [[ADDRV]] : !fir.ref<!fir.vector<2:f32>>
  // X64: [[ADDRC:%[0-9A-Za-z]+]] = fir.convert [[ADDRV]] : (!fir.ref<!fir.vector<2:f32>>) -> !fir.ref<complex<f32>>
  // X64: [[V:%[0-9A-Za-z]+]] = fir.load [[ADDRC]] : !fir.ref<complex<f32>>
  // X64: [[ADDRV_2:%[0-9A-Za-z]+]] = fir.alloca !fir.vector<2:f32>
  // X64: [[ADDRC_2:%[0-9A-Za-z]+]] = fir.convert [[ADDRV_2]] : (!fir.ref<!fir.vector<2:f32>>) -> !fir.ref<complex<f32>>
  // X64: fir.store [[V]] to [[ADDRC_2]] : !fir.ref<complex<f32>>
  // X64: [[RES:%[0-9A-Za-z]+]] = fir.load [[ADDRV_2]] : !fir.ref<!fir.vector<2:f32>>
  // X64: return [[RES]] : !fir.vector<2:f32>

  // X64_MINGW: [[ADDRV:%[0-9A-Za-z]+]] = fir.alloca i64
  // X64_MINGW: fir.store [[VAL]] to [[ADDRV]] : !fir.ref<i64>
  // X64_MINGW: [[ADDRC:%[0-9A-Za-z]+]] = fir.convert [[ADDRV]] : (!fir.ref<i64>) -> !fir.ref<complex<f32>>
  // X64_MINGW: [[V:%[0-9A-Za-z]+]] = fir.load [[ADDRC]] : !fir.ref<complex<f32>>
  // X64_MINGW: [[ADDRV_2:%[0-9A-Za-z]+]] = fir.alloca i64
  // X64_MINGW: [[ADDRC_2:%[0-9A-Za-z]+]] = fir.convert [[ADDRV_2]] : (!fir.ref<i64>) -> !fir.ref<complex<f32>>
  // X64_MINGW: fir.store [[V]] to [[ADDRC_2]] : !fir.ref<complex<f32>>
  // X64_MINGW: [[RES:%[0-9A-Za-z]+]] = fir.load [[ADDRV_2]] : !fir.ref<i64>
  // X64_MINGW: return [[RES]] : i64

  // AARCH64: [[ADDRT:%[0-9A-Za-z]+]] = fir.alloca tuple<f32, f32>
  // AARCH64: fir.store [[VAL]] to [[ADDRT]] : !fir.ref<tuple<f32, f32>>
  // AARCH64: [[ADDRC:%[0-9A-Za-z]+]] = fir.convert [[ADDRT]] : (!fir.ref<tuple<f32, f32>>) -> !fir.ref<complex<f32>>
  // AARCH64: [[V:%[0-9A-Za-z]+]] = fir.load [[ADDRC]] : !fir.ref<complex<f32>>
  // AARCH64: [[ADDRT_2:%[0-9A-Za-z]+]] = fir.alloca tuple<f32, f32>
  // AARCH64: [[ADDRC_2:%[0-9A-Za-z]+]] = fir.convert [[ADDRT_2]] : (!fir.ref<tuple<f32, f32>>) -> !fir.ref<complex<f32>>
  // AARCH64: fir.store [[V]] to [[ADDRC_2]] : !fir.ref<complex<f32>>
  // AARCH64: [[RES:%[0-9A-Za-z]+]] = fir.load [[ADDRT_2]] : !fir.ref<tuple<f32, f32>>
  // AARCH64: return [[RES]] : tuple<f32, f32>

  // PPC64le: [[ADDRT:%[0-9A-Za-z]+]] = fir.alloca tuple<f32, f32>
  // PPC64le: fir.store [[VAL]] to [[ADDRT]] : !fir.ref<tuple<f32, f32>>
  // PPC64le: [[ADDRC:%[0-9A-Za-z]+]] = fir.convert [[ADDRT]] : (!fir.ref<tuple<f32, f32>>) -> !fir.ref<complex<f32>>
  // PPC64le: [[V:%[0-9A-Za-z]+]] = fir.load [[ADDRC]] : !fir.ref<complex<f32>>
  // PPC64le: [[ADDRT_2:%[0-9A-Za-z]+]] = fir.alloca tuple<f32, f32>
  // PPC64le: [[ADDRC_2:%[0-9A-Za-z]+]] = fir.convert [[ADDRT_2]] : (!fir.ref<tuple<f32, f32>>) -> !fir.ref<complex<f32>>
  // PPC64le: fir.store [[V]] to [[ADDRC_2]] : !fir.ref<complex<f32>>
  // PPC64le: [[RES:%[0-9A-Za-z]+]] = fir.load [[ADDRT_2]] : !fir.ref<tuple<f32, f32>>
  // PPC64le: return [[RES]] : tuple<f32, f32>

  // SPARCV9: [[ADDRT:%[0-9A-Za-z]+]] = fir.alloca tuple<f32, f32>
  // SPARCV9: fir.store [[VAL]] to [[ADDRT]] : !fir.ref<tuple<f32, f32>>
  // SPARCV9: [[ADDRC:%[0-9A-Za-z]+]] = fir.convert [[ADDRT]] : (!fir.ref<tuple<f32, f32>>) -> !fir.ref<complex<f32>>
  // SPARCV9: [[V:%[0-9A-Za-z]+]] = fir.load [[ADDRC]] : !fir.ref<complex<f32>>
  // SPARCV9: [[ADDRT_2:%[0-9A-Za-z]+]] = fir.alloca tuple<f32, f32>
  // SPARCV9: [[ADDRC_2:%[0-9A-Za-z]+]] = fir.convert [[ADDRT_2]] : (!fir.ref<tuple<f32, f32>>) -> !fir.ref<complex<f32>>
  // SPARCV9: fir.store [[V]] to [[ADDRC_2]] : !fir.ref<complex<f32>>
  // SPARCV9: [[RES:%[0-9A-Za-z]+]] = fir.load [[ADDRT_2]] : !fir.ref<tuple<f32, f32>>
  // SPARCV9: return [[RES]] : tuple<f32, f32>

  // RISCV64: [[ADDRT:%[0-9A-Za-z]+]] = fir.alloca tuple<f32, f32>
  // RISCV64: fir.store [[VAL]] to [[ADDRT]] : !fir.ref<tuple<f32, f32>>
  // RISCV64: [[ADDRC:%[0-9A-Za-z]+]] = fir.convert [[ADDRT]] : (!fir.ref<tuple<f32, f32>>) -> !fir.ref<complex<f32>>
  // RISCV64: [[V:%[0-9A-Za-z]+]] = fir.load [[ADDRC]] : !fir.ref<complex<f32>>
  // RISCV64: [[ADDRT_2:%[0-9A-Za-z]+]] = fir.alloca tuple<f32, f32>
  // RISCV64: [[ADDRC_2:%[0-9A-Za-z]+]] = fir.convert [[ADDRT_2]] : (!fir.ref<tuple<f32, f32>>) -> !fir.ref<complex<f32>>
  // RISCV64: fir.store [[V]] to [[ADDRC_2]] : !fir.ref<complex<f32>>
  // RISCV64: [[RES:%[0-9A-Za-z]+]] = fir.load [[ADDRT_2]] : !fir.ref<tuple<f32, f32>>
  // RISCV64: return [[RES]] : tuple<f32, f32>
  
  // PPC64: [[ADDRT:%[0-9A-Za-z]+]] = fir.alloca tuple<f32, f32>
  // PPC64: fir.store [[VAL]] to [[ADDRT]] : !fir.ref<tuple<f32, f32>>
  // PPC64: [[ADDRC:%[0-9A-Za-z]+]] = fir.convert [[ADDRT]] : (!fir.ref<tuple<f32, f32>>) -> !fir.ref<complex<f32>>
  // PPC64: [[V:%[0-9A-Za-z]+]] = fir.load [[ADDRC]] : !fir.ref<complex<f32>>
  // PPC64: [[ADDRT_2:%[0-9A-Za-z]+]] = fir.alloca tuple<f32, f32>
  // PPC64: [[ADDRC_2:%[0-9A-Za-z]+]] = fir.convert [[ADDRT_2]] : (!fir.ref<tuple<f32, f32>>) -> !fir.ref<complex<f32>>
  // PPC64: fir.store [[V]] to [[ADDRC_2]] : !fir.ref<complex<f32>>
  // PPC64: [[RES:%[0-9A-Za-z]+]] = fir.load [[ADDRT_2]] : !fir.ref<tuple<f32, f32>>
  // PPC64: return [[RES]] : tuple<f32, f32>

  // LOONGARCH64: [[ADDRT:%[0-9A-Za-z]+]] = fir.alloca tuple<f32, f32>
  // LOONGARCH64: fir.store [[VAL]] to [[ADDRT]] : !fir.ref<tuple<f32, f32>>
  // LOONGARCH64: [[ADDRC:%[0-9A-Za-z]+]] = fir.convert [[ADDRT]] : (!fir.ref<tuple<f32, f32>>) -> !fir.ref<complex<f32>>
  // LOONGARCH64: [[V:%[0-9A-Za-z]+]] = fir.load [[ADDRC]] : !fir.ref<complex<f32>>
  // LOONGARCH64: [[ADDRT_2:%[0-9A-Za-z]+]] = fir.alloca tuple<f32, f32>
  // LOONGARCH64: [[ADDRC_2:%[0-9A-Za-z]+]] = fir.convert [[ADDRT_2]] : (!fir.ref<tuple<f32, f32>>) -> !fir.ref<complex<f32>>
  // LOONGARCH64: fir.store [[V]] to [[ADDRC_2]] : !fir.ref<complex<f32>>
  // LOONGARCH64: [[RES:%[0-9A-Za-z]+]] = fir.load [[ADDRT_2]] : !fir.ref<tuple<f32, f32>>
  // LOONGARCH64: return [[RES]] : tuple<f32, f32>
  return %0 : complex<f32>
}

// Test that we rewrite the fir.address_of operator.
// I32-LABEL: func @addrof()
// I32_MINGW-LABEL: func @addrof()
// X64-LABEL: func @addrof()
// X64_MINGW-LABEL: func @addrof()
// AARCH64-LABEL: func @addrof()
// PPC64le-LABEL: func @addrof()
// SPARCV9-LABEL: func @addrof()
// RISCV64-LABEL: func @addrof()
// PPC64-LABEL: func @addrof()
// LOONGARCH64-LABEL: func @addrof()
func.func @addrof() {
  // I32: {{%.*}} = fir.address_of(@returncomplex4) : () -> i64
  // I32_MINGW: {{%.*}} = fir.address_of(@returncomplex4) : () -> i64
  // X64: {{%.*}} = fir.address_of(@returncomplex4) : () -> !fir.vector<2:f32>
  // X64_MINGW: {{%.*}} = fir.address_of(@returncomplex4) : () -> i64
  // AARCH64: {{%.*}} = fir.address_of(@returncomplex4) : () -> tuple<f32, f32>
  // PPC64le: {{%.*}} = fir.address_of(@returncomplex4) : () -> tuple<f32, f32>
  // RISCV64: {{%.*}} = fir.address_of(@returncomplex4) : () -> tuple<f32, f32>
  // PPC64: {{%.*}} = fir.address_of(@returncomplex4) : () -> tuple<f32, f32>
  // LOONGARCH64: {{%.*}} = fir.address_of(@returncomplex4) : () -> tuple<f32, f32>
  %r = fir.address_of(@returncomplex4) : () -> complex<f32>

  // I32: {{%.*}} = fir.address_of(@paramcomplex4) : (!fir.ref<tuple<f32, f32>>) -> ()
  // I32_MINGW: {{%.*}} = fir.address_of(@paramcomplex4) : (!fir.ref<tuple<f32, f32>>) -> ()
  // X64: {{%.*}} = fir.address_of(@paramcomplex4) : (!fir.vector<2:f32>) -> ()
  // X64_MINGW: {{%.*}} = fir.address_of(@paramcomplex4) : (i64) -> ()
  // AARCH64: {{%.*}} = fir.address_of(@paramcomplex4) : (!fir.array<2xf32>) -> ()
  // PPC64le: {{%.*}} = fir.address_of(@paramcomplex4) : (f32, f32) -> ()
  // SPARCV9: {{%.*}} = fir.address_of(@paramcomplex4) : (f32, f32) -> ()
  // RISCV64: {{%.*}} = fir.address_of(@paramcomplex4) : (f32, f32) -> ()
  // PPC64: {{%.*}} = fir.address_of(@paramcomplex4) : (f32, f32) -> ()
  // LOONGARCH64: {{%.*}} = fir.address_of(@paramcomplex4) : (f32, f32) -> ()
  %p = fir.address_of(@paramcomplex4) : (complex<f32>) -> ()
  return
}