llvm-for-llvmta/tools/clang/test/CodeGen/fp-floatcontrol-pragma.cpp

// RUN: %clang_cc1 -fexperimental-strict-floating-point -DEXCEPT=1 -fcxx-exceptions -triple x86_64-linux-gnu -emit-llvm -o - %s | FileCheck -check-prefix=CHECK-NS %s
// RUN: %clang_cc1 -fexperimental-strict-floating-point -triple x86_64-linux-gnu -emit-llvm -o - %s | FileCheck %s
// RUN: %clang_cc1 -fexperimental-strict-floating-point -DFENV_ON=1 -triple x86_64-linux-gnu -emit-llvm -o - %s | FileCheck -check-prefix=CHECK-FENV %s
// RUN: %clang_cc1 -fexperimental-strict-floating-point -triple %itanium_abi_triple -O3 -emit-llvm -o - %s | FileCheck -check-prefix=CHECK-O3 %s

// Verify float_control(precise, off) enables fast math flags on fp operations.
float fp_precise_1(float a, float b, float c) {
// CHECK-O3: _Z12fp_precise_1fff
// CHECK-O3: %[[M:.+]] = fmul fast float{{.*}}
// CHECK-O3: fadd fast float %[[M]], %c
#pragma float_control(precise, off)
  return a * b + c;
}

// Is float_control state cleared on exiting compound statements?
float fp_precise_2(float a, float b, float c) {
  // CHECK-O3: _Z12fp_precise_2fff
  // CHECK-O3: %[[M:.+]] = fmul float{{.*}}
  // CHECK-O3: fadd float %[[M]], %c
  {
#pragma float_control(precise, off)
  }
  return a * b + c;
}

// Does float_control survive template instantiation?
class Foo {};
Foo operator+(Foo, Foo);

template <typename T>
T template_muladd(T a, T b, T c) {
#pragma float_control(precise, off)
  return a * b + c;
}

float fp_precise_3(float a, float b, float c) {
  // CHECK-O3: _Z12fp_precise_3fff
  // CHECK-O3: %[[M:.+]] = fmul fast float{{.*}}
  // CHECK-O3: fadd fast float %[[M]], %c
  return template_muladd<float>(a, b, c);
}

template <typename T>
class fp_precise_4 {
  float method(float a, float b, float c) {
#pragma float_control(precise, off)
    return a * b + c;
  }
};

template class fp_precise_4<int>;
// CHECK-O3: _ZN12fp_precise_4IiE6methodEfff
// CHECK-O3: %[[M:.+]] = fmul fast float{{.*}}
// CHECK-O3: fadd fast float %[[M]], %c

// Check file-scoped float_control
#pragma float_control(push)
#pragma float_control(precise, off)
float fp_precise_5(float a, float b, float c) {
  // CHECK-O3: _Z12fp_precise_5fff
  // CHECK-O3: %[[M:.+]] = fmul fast float{{.*}}
  // CHECK-O3: fadd fast float %[[M]], %c
  return a * b + c;
}
#pragma float_control(pop)

float fff(float x, float y) {
// CHECK-LABEL: define{{.*}} float @_Z3fffff{{.*}}
// CHECK: entry
#pragma float_control(except, on)
  float z;
  z = z * z;
  //CHECK: llvm.experimental.constrained.fmul{{.*}}
  {
    z = x * y;
    //CHECK: llvm.experimental.constrained.fmul{{.*}}
  }
  {
// This pragma has no effect since if there are any fp intrin in the
// function then all the operations need to be fp intrin
#pragma float_control(except, off)
    z = z + x * y;
    //CHECK: llvm.experimental.constrained.fmul{{.*}}
  }
  z = z * z;
  //CHECK: llvm.experimental.constrained.fmul{{.*}}
  return z;
}
float check_precise(float x, float y) {
  // CHECK-LABEL: define{{.*}} float @_Z13check_preciseff{{.*}}
  float z;
  {
#pragma float_control(precise, on)
    z = x * y + z;
    //CHECK: llvm.fmuladd{{.*}}
  }
  {
#pragma float_control(precise, off)
    z = x * y + z;
    //CHECK: fmul fast float
    //CHECK: fadd fast float
  }
  return z;
}

float fma_test2(float a, float b, float c) {
// CHECK-LABEL define{{.*}} float @_Z9fma_test2fff{{.*}}
#pragma float_control(precise, off)
  float x = a * b + c;
  //CHECK: fmuladd
  return x;
}

float fma_test1(float a, float b, float c) {
// CHECK-LABEL define{{.*}} float @_Z9fma_test1fff{{.*}}
#pragma float_control(precise, on)
  float x = a * b + c;
  //CHECK: fmuladd
  return x;
}

#pragma float_control(push)
#pragma float_control(precise, on)
struct Distance {};
Distance operator+(Distance, Distance);

template <class T>
T add(T lhs, T rhs) {
#pragma float_control(except, on)
  return lhs + rhs;
}
#pragma float_control(pop)

float test_OperatorCall() {
  return add(1.0f, 2.0f);
  //CHECK: llvm.experimental.constrained.fadd{{.*}}fpexcept.strict
}
// CHECK-LABEL define{{.*}} float  {{.*}}test_OperatorCall{{.*}}

#if FENV_ON
#pragma STDC FENV_ACCESS ON
#endif
// CHECK-LABEL: define {{.*}}callt{{.*}}

void callt() {
  volatile float z;
  z = z * z;
  //CHECK-FENV: llvm.experimental.constrained.fmul{{.*}}
}

// CHECK-LABEL: define {{.*}}myAdd{{.*}}
float myAdd(int i, float f) {
  if (i<0)
  return 1.0 + 2.0;
  // Check that floating point constant folding doesn't occur if
  // #pragma STC FENV_ACCESS is enabled.
  //CHECK-FENV: llvm.experimental.constrained.fadd{{.*}}double 1.0{{.*}}double 2.0{{.*}}
  //CHECK: store float 3.0{{.*}}retval{{.*}}
  static double v = 1.0 / 3.0;
  //CHECK-FENV: llvm.experimental.constrained.fptrunc.f32.f64{{.*}}
  //CHECK-NOT: fdiv
  return v;
}

#if EXCEPT
namespace ns {
// Check that pragma float_control can appear in namespace.
#pragma float_control(except, on, push)
float exc_on(double x, float zero) {
// CHECK-NS: define {{.*}}exc_on{{.*}}
  {} try {
    x = 1.0 / zero; /* division by zero, the result unused */
//CHECK-NS: llvm.experimental.constrained.fdiv{{.*}}
  } catch (...) {}
  return zero;
}
}

// Check pragma is still effective after namespace closes
float exc_still_on(double x, float zero) {
// CHECK-NS: define {{.*}}exc_still_on{{.*}}
  {} try {
    x = 1.0 / zero; /* division by zero, the result unused */
//CHECK-NS: llvm.experimental.constrained.fdiv{{.*}}
  } catch (...) {}
  return zero;
}

#pragma float_control(pop)
float exc_off(double x, float zero) {
// CHECK-NS: define {{.*}}exc_off{{.*}}
  {} try {
    x = 1.0 / zero; /* division by zero, the result unused */
//CHECK-NS: fdiv double
  } catch (...) {}
  return zero;
}

namespace fc_template_namespace {
#pragma float_control(except, on, push)
template <class T>
T exc_on(double x, T zero) {
// CHECK-NS: define {{.*}}fc_template_namespace{{.*}}
  {} try {
    x = 1.0 / zero; /* division by zero, the result unused */
//CHECK-NS: llvm.experimental.constrained.fdiv{{.*}}
  } catch (...) {}
  return zero;
}
}

#pragma float_control(pop)
float xx(double x, float z) {
  return fc_template_namespace::exc_on<float>(x, z);
}
#endif // EXCEPT

float try_lam(float x, unsigned n) {
// CHECK: define {{.*}}try_lam{{.*}}class.anon{{.*}}
  float result;
  auto t =
        // Lambda expression begins
        [](float a, float b) {
#pragma float_control( except, on)
            return a * b;
//CHECK: llvm.experimental.constrained.fmul{{.*}}fpexcept.strict
        } // end of lambda expression
  (1.0f,2.0f);
  result = x + t;
  return result;
}
added clang 2022-04-25 13:02:35 +02:00			`// RUN: %clang_cc1 -fexperimental-strict-floating-point -DEXCEPT=1 -fcxx-exceptions -triple x86_64-linux-gnu -emit-llvm -o - %s \| FileCheck -check-prefix=CHECK-NS %s`
			`// RUN: %clang_cc1 -fexperimental-strict-floating-point -triple x86_64-linux-gnu -emit-llvm -o - %s \| FileCheck %s`
			`// RUN: %clang_cc1 -fexperimental-strict-floating-point -DFENV_ON=1 -triple x86_64-linux-gnu -emit-llvm -o - %s \| FileCheck -check-prefix=CHECK-FENV %s`
			`// RUN: %clang_cc1 -fexperimental-strict-floating-point -triple %itanium_abi_triple -O3 -emit-llvm -o - %s \| FileCheck -check-prefix=CHECK-O3 %s`

			`// Verify float_control(precise, off) enables fast math flags on fp operations.`
			`float fp_precise_1(float a, float b, float c) {`
			`// CHECK-O3: _Z12fp_precise_1fff`
			`// CHECK-O3: %[[M:.+]] = fmul fast float{{.*}}`
			`// CHECK-O3: fadd fast float %[[M]], %c`
			`#pragma float_control(precise, off)`
			`return a * b + c;`
			`}`

			`// Is float_control state cleared on exiting compound statements?`
			`float fp_precise_2(float a, float b, float c) {`
			`// CHECK-O3: _Z12fp_precise_2fff`
			`// CHECK-O3: %[[M:.+]] = fmul float{{.*}}`
			`// CHECK-O3: fadd float %[[M]], %c`
			`{`
			`#pragma float_control(precise, off)`
			`}`
			`return a * b + c;`
			`}`

			`// Does float_control survive template instantiation?`
			`class Foo {};`
			`Foo operator+(Foo, Foo);`

			`template <typename T>`
			`T template_muladd(T a, T b, T c) {`
			`#pragma float_control(precise, off)`
			`return a * b + c;`
			`}`

			`float fp_precise_3(float a, float b, float c) {`
			`// CHECK-O3: _Z12fp_precise_3fff`
			`// CHECK-O3: %[[M:.+]] = fmul fast float{{.*}}`
			`// CHECK-O3: fadd fast float %[[M]], %c`
			`return template_muladd<float>(a, b, c);`
			`}`

			`template <typename T>`
			`class fp_precise_4 {`
			`float method(float a, float b, float c) {`
			`#pragma float_control(precise, off)`
			`return a * b + c;`
			`}`
			`};`

			`template class fp_precise_4<int>;`
			`// CHECK-O3: _ZN12fp_precise_4IiE6methodEfff`
			`// CHECK-O3: %[[M:.+]] = fmul fast float{{.*}}`
			`// CHECK-O3: fadd fast float %[[M]], %c`

			`// Check file-scoped float_control`
			`#pragma float_control(push)`
			`#pragma float_control(precise, off)`
			`float fp_precise_5(float a, float b, float c) {`
			`// CHECK-O3: _Z12fp_precise_5fff`
			`// CHECK-O3: %[[M:.+]] = fmul fast float{{.*}}`
			`// CHECK-O3: fadd fast float %[[M]], %c`
			`return a * b + c;`
			`}`
			`#pragma float_control(pop)`

			`float fff(float x, float y) {`
			`// CHECK-LABEL: define{{.}} float @_Z3fffff{{.}}`
			`// CHECK: entry`
			`#pragma float_control(except, on)`
			`float z;`
			`z = z * z;`
			`//CHECK: llvm.experimental.constrained.fmul{{.*}}`
			`{`
			`z = x * y;`
			`//CHECK: llvm.experimental.constrained.fmul{{.*}}`
			`}`
			`{`
			`// This pragma has no effect since if there are any fp intrin in the`
			`// function then all the operations need to be fp intrin`
			`#pragma float_control(except, off)`
			`z = z + x * y;`
			`//CHECK: llvm.experimental.constrained.fmul{{.*}}`
			`}`
			`z = z * z;`
			`//CHECK: llvm.experimental.constrained.fmul{{.*}}`
			`return z;`
			`}`
			`float check_precise(float x, float y) {`
			`// CHECK-LABEL: define{{.}} float @_Z13check_preciseff{{.}}`
			`float z;`
			`{`
			`#pragma float_control(precise, on)`
			`z = x * y + z;`
			`//CHECK: llvm.fmuladd{{.*}}`
			`}`
			`{`
			`#pragma float_control(precise, off)`
			`z = x * y + z;`
			`//CHECK: fmul fast float`
			`//CHECK: fadd fast float`
			`}`
			`return z;`
			`}`

			`float fma_test2(float a, float b, float c) {`
			`// CHECK-LABEL define{{.}} float @_Z9fma_test2fff{{.}}`
			`#pragma float_control(precise, off)`
			`float x = a * b + c;`
			`//CHECK: fmuladd`
			`return x;`
			`}`

			`float fma_test1(float a, float b, float c) {`
			`// CHECK-LABEL define{{.}} float @_Z9fma_test1fff{{.}}`
			`#pragma float_control(precise, on)`
			`float x = a * b + c;`
			`//CHECK: fmuladd`
			`return x;`
			`}`

			`#pragma float_control(push)`
			`#pragma float_control(precise, on)`
			`struct Distance {};`
			`Distance operator+(Distance, Distance);`

			`template <class T>`
			`T add(T lhs, T rhs) {`
			`#pragma float_control(except, on)`
			`return lhs + rhs;`
			`}`
			`#pragma float_control(pop)`

			`float test_OperatorCall() {`
			`return add(1.0f, 2.0f);`
			`//CHECK: llvm.experimental.constrained.fadd{{.*}}fpexcept.strict`
			`}`
			`// CHECK-LABEL define{{.}} float {{.}}test_OperatorCall{{.*}}`

			`#if FENV_ON`
			`#pragma STDC FENV_ACCESS ON`
			`#endif`
			`// CHECK-LABEL: define {{.}}callt{{.}}`

			`void callt() {`
			`volatile float z;`
			`z = z * z;`
			`//CHECK-FENV: llvm.experimental.constrained.fmul{{.*}}`
			`}`

			`// CHECK-LABEL: define {{.}}myAdd{{.}}`
			`float myAdd(int i, float f) {`
			`if (i<0)`
			`return 1.0 + 2.0;`
			`// Check that floating point constant folding doesn't occur if`
			`// #pragma STC FENV_ACCESS is enabled.`
			`//CHECK-FENV: llvm.experimental.constrained.fadd{{.}}double 1.0{{.}}double 2.0{{.*}}`
			`//CHECK: store float 3.0{{.}}retval{{.}}`
			`static double v = 1.0 / 3.0;`
			`//CHECK-FENV: llvm.experimental.constrained.fptrunc.f32.f64{{.*}}`
			`//CHECK-NOT: fdiv`
			`return v;`
			`}`

			`#if EXCEPT`
			`namespace ns {`
			`// Check that pragma float_control can appear in namespace.`
			`#pragma float_control(except, on, push)`
			`float exc_on(double x, float zero) {`
			`// CHECK-NS: define {{.}}exc_on{{.}}`
			`{} try {`
			`x = 1.0 / zero; /* division by zero, the result unused */`
			`//CHECK-NS: llvm.experimental.constrained.fdiv{{.*}}`
			`} catch (...) {}`
			`return zero;`
			`}`
			`}`

			`// Check pragma is still effective after namespace closes`
			`float exc_still_on(double x, float zero) {`
			`// CHECK-NS: define {{.}}exc_still_on{{.}}`
			`{} try {`
			`x = 1.0 / zero; /* division by zero, the result unused */`
			`//CHECK-NS: llvm.experimental.constrained.fdiv{{.*}}`
			`} catch (...) {}`
			`return zero;`
			`}`

			`#pragma float_control(pop)`
			`float exc_off(double x, float zero) {`
			`// CHECK-NS: define {{.}}exc_off{{.}}`
			`{} try {`
			`x = 1.0 / zero; /* division by zero, the result unused */`
			`//CHECK-NS: fdiv double`
			`} catch (...) {}`
			`return zero;`
			`}`

			`namespace fc_template_namespace {`
			`#pragma float_control(except, on, push)`
			`template <class T>`
			`T exc_on(double x, T zero) {`
			`// CHECK-NS: define {{.}}fc_template_namespace{{.}}`
			`{} try {`
			`x = 1.0 / zero; /* division by zero, the result unused */`
			`//CHECK-NS: llvm.experimental.constrained.fdiv{{.*}}`
			`} catch (...) {}`
			`return zero;`
			`}`
			`}`

			`#pragma float_control(pop)`
			`float xx(double x, float z) {`
			`return fc_template_namespace::exc_on<float>(x, z);`
			`}`
			`#endif // EXCEPT`

			`float try_lam(float x, unsigned n) {`
			`// CHECK: define {{.}}try_lam{{.}}class.anon{{.*}}`
			`float result;`
			`auto t =`
			`// Lambda expression begins`
			`[](float a, float b) {`
			`#pragma float_control( except, on)`
			`return a * b;`
			`//CHECK: llvm.experimental.constrained.fmul{{.*}}fpexcept.strict`
			`} // end of lambda expression`
			`(1.0f,2.0f);`
			`result = x + t;`
			`return result;`
			`}`