test/OpenMP/declare_simd_ast_print.cpp - third_party/swift-clang - Git at Google

 // RUN: %clang_cc1 -verify -fopenmp -x c++ -std=c++11 -ast-print %s | FileCheck %s
 // RUN: %clang_cc1 -fopenmp -x c++ -std=c++11 -emit-pch -o %t %s
 // RUN: %clang_cc1 -fopenmp -x c++ -std=c++11 -include-pch %t -fsyntax-only -verify %s -ast-print | FileCheck %s
 // expected-no-diagnostics

 #ifndef HEADER
 #define HEADER

 #pragma omp declare simd linear(d: 8)
 #pragma omp declare simd inbranch simdlen(32)
 #pragma omp declare simd notinbranch
 void add_1(float *d) __attribute__((cold));

 // CHECK: #pragma omp declare simd notinbranch
 // CHECK-NEXT: #pragma omp declare simd inbranch simdlen(32)
 // CHECK-NEXT: #pragma omp declare simd linear(val(d): 8)
 // CHECK-NEXT: void add_1(float *d) __attribute__((cold));
 //

 #pragma omp declare simd aligned(hp, hp2)
 template <class C> void h(C *hp, C *hp2, C *hq, C *lin) {
 }

 // CHECK: #pragma omp declare simd aligned(hp) aligned(hp2)
 // CHECK-NEXT: template <class C = int> void h(int *hp, int *hp2, int *hq, int *lin) {
 // CHECK-NEXT: h((float *)hp, (float *)hp2, (float *)hq, (float *)lin);
 // CHECK-NEXT: }

 // CHECK: #pragma omp declare simd  aligned(hp) aligned(hp2)
 // CHECK-NEXT: template <class C = float> void h(float *hp, float *hp2, float *hq, float *lin) {
 // CHECK-NEXT: }

 // CHECK: #pragma omp declare simd aligned(hp) aligned(hp2)
 // CHECK: template <class C> void h(C *hp, C *hp2, C *hq, C *lin) {
 // CHECK-NEXT: }
 //

 // Explicit specialization with <C=int>.
 // Pragmas need to be same, otherwise standard says that's undefined behavior.
 #pragma omp declare simd aligned(hp, hp2)
 template <>
 void h(int *hp, int *hp2, int *hq, int *lin)
 {
   // Implicit specialization with <C=float>.
   // This is special case where the directive is stored by Sema and is
   // generated together with the (pending) function instatiation.
   h((float*) hp, (float*) hp2, (float*) hq, (float*) lin);
 }

 class VV {
   // CHECK: #pragma omp declare simd uniform(this, a) linear(val(b): a)
   // CHECK-NEXT: int add(int a, int b) __attribute__((cold))    {
   // CHECK-NEXT: return a + b;
   // CHECK-NEXT: }
   #pragma omp declare simd uniform(this, a) linear(val(b): a)
   int add(int a, int b) __attribute__((cold)) { return a + b; }

   // CHECK: #pragma omp declare simd aligned(b: 4) aligned(a) linear(ref(b): 4) linear(val(this)) linear(val(a))
   // CHECK-NEXT: float taddpf(float *a, float *&b)     {
   // CHECK-NEXT: return *a + *b;
   // CHECK-NEXT: }
   #pragma omp declare simd aligned (b: 4) aligned(a) linear(ref(b): 4) linear(this, a)
   float taddpf(float *a, float *&b) { return *a + *b; }

 // CHECK: #pragma omp declare simd aligned(b: 8)
 // CHECK-NEXT: #pragma omp declare simd linear(uval(c): 8)
 // CHECK-NEXT: int tadd(int (&b)[], int &c) {
 // CHECK-NEXT: return this->x[b[0]] + b[0];
 // CHECK-NEXT: }
   #pragma omp declare simd linear(uval(c): 8)
   #pragma omp declare simd aligned(b : 8)
   int tadd(int (&b)[], int &c) { return x[b[0]] + b[0]; }

 private:
   int x[10];
 };

 // CHECK: template <int X = 16, typename T = float> class TVV {
 // CHECK: #pragma omp declare simd
 // CHECK-NEXT: int tadd(int a, int b);
 // CHECK: #pragma omp declare simd aligned(a: 16 * 2) aligned(b) linear(ref(b): 16)
 // CHECK-NEXT: float taddpf(float *a, float *&b) {
 // CHECK-NEXT: return *a + *b;
 // CHECK-NEXT: }
 // CHECK: #pragma omp declare simd
 // CHECK-NEXT: #pragma omp declare simd
 // CHECK-NEXT: int tadd(int b) {
 // CHECK-NEXT: return this->x[b] + b;
 // CHECK-NEXT: }
 // CHECK: }
 template <int X, typename T>
 class TVV {
 public:
 // CHECK: template <int X, typename T> class TVV {
   #pragma omp declare simd simdlen(X)
   int tadd(int a, int b) { return a + b; }

 // CHECK: #pragma omp declare simd simdlen(X)
 // CHECK-NEXT: int tadd(int a, int b) {
 // CHECK-NEXT: return a + b;
 // CHECK-NEXT: }

   #pragma omp declare simd aligned(a : X * 2) aligned(b) linear(ref(b): X)
   float taddpf(float *a, T *&b) { return *a + *b; }

 // CHECK: #pragma omp declare simd aligned(a: X * 2) aligned(b)
 // CHECK-NEXT: float taddpf(float *a, T *&b) {
 // CHECK-NEXT: return *a + *b;
 // CHECK-NEXT: }

   #pragma omp declare simd
   #pragma omp declare simd uniform(this, b)
   int tadd(int b) { return x[b] + b; }

 // CHECK: #pragma omp declare simd uniform(this, b)
 // CHECK-NEXT: #pragma omp declare simd
 // CHECK-NEXT: int tadd(int b) {
 // CHECK-NEXT: return this->x[b] + b;
 // CHECK-NEXT: }

 private:
   int x[X];
 };
 // CHECK: };

 // CHECK: #pragma omp declare simd simdlen(64) aligned(b: 64 * 2) linear(uval(c): 64)
 // CHECK: template <int N = 64> void foo(int (&b)[64], float *&c)
 // CHECK: #pragma omp declare simd simdlen(N) aligned(b: N * 2) linear(uval(c): N)
 // CHECK: template <int N> void foo(int (&b)[N], float *&c)
 #pragma omp declare simd simdlen(N) aligned(b : N * 2) linear(uval(c): N)
 template <int N>
 void foo(int (&b)[N], float *&c);

 // CHECK: TVV<16, float> t16;
 TVV<16, float> t16;

 void f() {
   float a = 1.0f, b = 2.0f;
   float *p = &b;
   float r = t16.taddpf(&a, p);
   int res = t16.tadd(b);
   int c[64];
   foo(c, p);
 }

 #endif
	// RUN: %clang_cc1 -verify -fopenmp -x c++ -std=c++11 -ast-print %s \| FileCheck %s
	// RUN: %clang_cc1 -fopenmp -x c++ -std=c++11 -emit-pch -o %t %s
	// RUN: %clang_cc1 -fopenmp -x c++ -std=c++11 -include-pch %t -fsyntax-only -verify %s -ast-print \| FileCheck %s
	// expected-no-diagnostics

	#ifndef HEADER
	#define HEADER

	#pragma omp declare simd linear(d: 8)
	#pragma omp declare simd inbranch simdlen(32)
	#pragma omp declare simd notinbranch
	void add_1(float *d) __attribute__((cold));

	// CHECK: #pragma omp declare simd notinbranch
	// CHECK-NEXT: #pragma omp declare simd inbranch simdlen(32)
	// CHECK-NEXT: #pragma omp declare simd linear(val(d): 8)
	// CHECK-NEXT: void add_1(float *d) __attribute__((cold));
	//

	#pragma omp declare simd aligned(hp, hp2)
	template <class C> void h(C hp, C hp2, C hq, C lin) {
	}

	// CHECK: #pragma omp declare simd aligned(hp) aligned(hp2)
	// CHECK-NEXT: template <class C = int> void h(int hp, int hp2, int hq, int lin) {
	// CHECK-NEXT: h((float )hp, (float )hp2, (float )hq, (float )lin);
	// CHECK-NEXT: }

	// CHECK: #pragma omp declare simd aligned(hp) aligned(hp2)
	// CHECK-NEXT: template <class C = float> void h(float hp, float hp2, float hq, float lin) {
	// CHECK-NEXT: }

	// CHECK: #pragma omp declare simd aligned(hp) aligned(hp2)
	// CHECK: template <class C> void h(C hp, C hp2, C hq, C lin) {
	// CHECK-NEXT: }
	//

	// Explicit specialization with <C=int>.
	// Pragmas need to be same, otherwise standard says that's undefined behavior.
	#pragma omp declare simd aligned(hp, hp2)
	template <>
	void h(int hp, int hp2, int hq, int lin)
	{
	// Implicit specialization with <C=float>.
	// This is special case where the directive is stored by Sema and is
	// generated together with the (pending) function instatiation.
	h((float) hp, (float) hp2, (float) hq, (float) lin);
	}

	class VV {
	// CHECK: #pragma omp declare simd uniform(this, a) linear(val(b): a)
	// CHECK-NEXT: int add(int a, int b) __attribute__((cold)) {
	// CHECK-NEXT: return a + b;
	// CHECK-NEXT: }
	#pragma omp declare simd uniform(this, a) linear(val(b): a)
	int add(int a, int b) __attribute__((cold)) { return a + b; }

	// CHECK: #pragma omp declare simd aligned(b: 4) aligned(a) linear(ref(b): 4) linear(val(this)) linear(val(a))
	// CHECK-NEXT: float taddpf(float a, float &b) {
	// CHECK-NEXT: return a + b;
	// CHECK-NEXT: }
	#pragma omp declare simd aligned (b: 4) aligned(a) linear(ref(b): 4) linear(this, a)
	float taddpf(float a, float &b) { return a + b; }

	// CHECK: #pragma omp declare simd aligned(b: 8)
	// CHECK-NEXT: #pragma omp declare simd linear(uval(c): 8)
	// CHECK-NEXT: int tadd(int (&b)[], int &c) {
	// CHECK-NEXT: return this->x[b[0]] + b[0];
	// CHECK-NEXT: }
	#pragma omp declare simd linear(uval(c): 8)
	#pragma omp declare simd aligned(b : 8)
	int tadd(int (&b)[], int &c) { return x[b[0]] + b[0]; }

	private:
	int x[10];
	};

	// CHECK: template <int X = 16, typename T = float> class TVV {
	// CHECK: #pragma omp declare simd
	// CHECK-NEXT: int tadd(int a, int b);
	// CHECK: #pragma omp declare simd aligned(a: 16 * 2) aligned(b) linear(ref(b): 16)
	// CHECK-NEXT: float taddpf(float a, float &b) {
	// CHECK-NEXT: return a + b;
	// CHECK-NEXT: }
	// CHECK: #pragma omp declare simd
	// CHECK-NEXT: #pragma omp declare simd
	// CHECK-NEXT: int tadd(int b) {
	// CHECK-NEXT: return this->x[b] + b;
	// CHECK-NEXT: }
	// CHECK: }
	template <int X, typename T>
	class TVV {
	public:
	// CHECK: template <int X, typename T> class TVV {
	#pragma omp declare simd simdlen(X)
	int tadd(int a, int b) { return a + b; }

	// CHECK: #pragma omp declare simd simdlen(X)
	// CHECK-NEXT: int tadd(int a, int b) {
	// CHECK-NEXT: return a + b;
	// CHECK-NEXT: }

	#pragma omp declare simd aligned(a : X * 2) aligned(b) linear(ref(b): X)
	float taddpf(float a, T &b) { return a + b; }

	// CHECK: #pragma omp declare simd aligned(a: X * 2) aligned(b)
	// CHECK-NEXT: float taddpf(float a, T &b) {
	// CHECK-NEXT: return a + b;
	// CHECK-NEXT: }

	#pragma omp declare simd
	#pragma omp declare simd uniform(this, b)
	int tadd(int b) { return x[b] + b; }

	// CHECK: #pragma omp declare simd uniform(this, b)
	// CHECK-NEXT: #pragma omp declare simd
	// CHECK-NEXT: int tadd(int b) {
	// CHECK-NEXT: return this->x[b] + b;
	// CHECK-NEXT: }

	private:
	int x[X];
	};
	// CHECK: };

	// CHECK: #pragma omp declare simd simdlen(64) aligned(b: 64 * 2) linear(uval(c): 64)
	// CHECK: template <int N = 64> void foo(int (&b)[64], float *&c)
	// CHECK: #pragma omp declare simd simdlen(N) aligned(b: N * 2) linear(uval(c): N)
	// CHECK: template <int N> void foo(int (&b)[N], float *&c)
	#pragma omp declare simd simdlen(N) aligned(b : N * 2) linear(uval(c): N)
	template <int N>
	void foo(int (&b)[N], float *&c);

	// CHECK: TVV<16, float> t16;
	TVV<16, float> t16;

	void f() {
	float a = 1.0f, b = 2.0f;
	float *p = &b;
	float r = t16.taddpf(&a, p);
	int res = t16.tadd(b);
	int c[64];
	foo(c, p);
	}

	#endif