clang/test/OpenMP/parallel_master_ast_print.cpp - llvm-project - Git at Google

 // RUN: %clang_cc1 -verify -fopenmp -ast-print %s | FileCheck %s
 // RUN: %clang_cc1 -fopenmp -x c++ -std=c++11 -emit-pch -o %t %s
 // RUN: %clang_cc1 -fopenmp -std=c++11 -include-pch %t -fsyntax-only -verify %s -ast-print | FileCheck %s

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

 #ifndef HEADER
 #define HEADER

 void foo() {}

 struct S1 {
   S1(): a(0) {}
   S1(int v) : a(v) {}
   int a;
   typedef int type;
   S1& operator +(const S1&);
   S1& operator *(const S1&);
   S1& operator &&(const S1&);
   S1& operator ^(const S1&);
 };

 template <typename T>
 class S7 : public T {
 protected:
   T a;
   T b[100];
   S7() : a(0) {}

 public:
   S7(typename T::type v) : a(v) {
 #pragma omp parallel master private(a) private(this->a) private(T::a)
     for (int k = 0; k < a.a; ++k)
       ++this->a.a;
 #pragma omp parallel master firstprivate(a) firstprivate(this->a) firstprivate(T::a)
     for (int k = 0; k < a.a; ++k)
       ++this->a.a;
 #pragma omp parallel master shared(a) shared(this->a) shared(T::a)
     for (int k = 0; k < a.a; ++k)
       ++this->a.a;
 #pragma omp parallel master reduction(+ : a) reduction(*: b[:])
     for (int k = 0; k < a.a; ++k)
       ++this->a.a;
   }
   S7 &operator=(S7 &s) {
 #pragma omp parallel master private(a) private(this->a)
     for (int k = 0; k < s.a.a; ++k)
       ++s.a.a;
 #pragma omp parallel master firstprivate(a) firstprivate(this->a)
     for (int k = 0; k < s.a.a; ++k)
       ++s.a.a;
 #pragma omp parallel master shared(a) shared(this->a)
     for (int k = 0; k < s.a.a; ++k)
       ++s.a.a;
 #pragma omp parallel master reduction(&& : this->a) reduction(^: b[s.a.a])
     for (int k = 0; k < s.a.a; ++k)
       ++s.a.a;
     return *this;
   }
 };

 // CHECK: #pragma omp parallel master private(this->a) private(this->a) private(T::a)
 // CHECK: #pragma omp parallel master firstprivate(this->a) firstprivate(this->a) firstprivate(T::a)
 // CHECK: #pragma omp parallel master shared(this->a) shared(this->a) shared(T::a)
 // CHECK: #pragma omp parallel master reduction(+: this->a) reduction(*: this->b[:])
 // CHECK: #pragma omp parallel master private(this->a) private(this->a)
 // CHECK: #pragma omp parallel master firstprivate(this->a) firstprivate(this->a)
 // CHECK: #pragma omp parallel master shared(this->a) shared(this->a)
 // CHECK: #pragma omp parallel master reduction(&&: this->a) reduction(^: this->b[s.a.a])
 // CHECK: #pragma omp parallel master private(this->a) private(this->a) private(this->S1::a)
 // CHECK: #pragma omp parallel master firstprivate(this->a) firstprivate(this->a) firstprivate(this->S1::a)
 // CHECK: #pragma omp parallel master shared(this->a) shared(this->a) shared(this->S1::a)
 // CHECK: #pragma omp parallel master reduction(+: this->a) reduction(*: this->b[:])

 class S8 : public S7<S1> {
   S8() {}

 public:
   S8(int v) : S7<S1>(v){
 #pragma omp parallel master private(a) private(this->a) private(S7 < S1 > ::a)
     for (int k = 0; k < a.a; ++k)
       ++this->a.a;
 #pragma omp parallel master firstprivate(a) firstprivate(this->a) firstprivate(S7 < S1 > ::a)
     for (int k = 0; k < a.a; ++k)
       ++this->a.a;
 #pragma omp parallel master shared(a) shared(this->a) shared(S7 < S1 > ::a)
     for (int k = 0; k < a.a; ++k)
       ++this->a.a;
 #pragma omp parallel master reduction(^ : S7 < S1 > ::a) reduction(+ : S7 < S1 > ::b[ : S7 < S1 > ::a.a])
     for (int k = 0; k < a.a; ++k)
       ++this->a.a;
   }
   S8 &operator=(S8 &s) {
 #pragma omp parallel master private(a) private(this->a)
     for (int k = 0; k < s.a.a; ++k)
       ++s.a.a;
 #pragma omp parallel master firstprivate(a) firstprivate(this->a)
     for (int k = 0; k < s.a.a; ++k)
       ++s.a.a;
 #pragma omp parallel master shared(a) shared(this->a)
     for (int k = 0; k < s.a.a; ++k)
       ++s.a.a;
 #pragma omp parallel master reduction(* : this->a) reduction(&&:this->b[a.a:])
     for (int k = 0; k < s.a.a; ++k)
       ++s.a.a;
     return *this;
   }
 };

 // CHECK: #pragma omp parallel master private(this->a) private(this->a) private(this->S7<S1>::a)
 // CHECK: #pragma omp parallel master firstprivate(this->a) firstprivate(this->a) firstprivate(this->S7<S1>::a)
 // CHECK: #pragma omp parallel master shared(this->a) shared(this->a) shared(this->S7<S1>::a)
 // CHECK: #pragma omp parallel master reduction(^: this->S7<S1>::a) reduction(+: this->S7<S1>::b[:this->S7<S1>::a.a])
 // CHECK: #pragma omp parallel master private(this->a) private(this->a)
 // CHECK: #pragma omp parallel master firstprivate(this->a) firstprivate(this->a)
 // CHECK: #pragma omp parallel master shared(this->a) shared(this->a)
 // CHECK: #pragma omp parallel master reduction(*: this->a) reduction(&&: this->b[this->a.a:])

 template <class T>
 struct S {
   operator T() {return T();}
   static T TS;
   #pragma omp threadprivate(TS)
 };

 // CHECK:      template <class T> struct S {
 // CHECK:        static T TS;
 // CHECK-NEXT:   #pragma omp threadprivate(S::TS)
 // CHECK:      };
 // CHECK:      template<> struct S<int> {
 // CHECK:        static int TS;
 // CHECK-NEXT:   #pragma omp threadprivate(S<int>::TS)
 // CHECK-NEXT: }
 // CHECK:      template<> struct S<long> {
 // CHECK:        static long TS;
 // CHECK-NEXT:   #pragma omp threadprivate(S<long>::TS)
 // CHECK-NEXT: }

 int thrp;
 #pragma omp threadprivate(thrp)

 template <typename T, int C>
 T tmain(T argc, T *argv) {
   T b = argc, c, d, e, f, g;
   static T a;
   S<T> s;
   T arr[C][10], arr1[C];
 #pragma omp parallel master
   a=2;
 #pragma omp parallel master default(none), private(argc,b) firstprivate(argv) shared (d) if (parallel:argc > 0) num_threads(C) copyin(S<T>::TS, thrp) proc_bind(master) reduction(+:c, arr1[argc]) reduction(max:e, arr[:C][0:10])
   foo();
 #pragma omp parallel master if (C) num_threads(s) proc_bind(close) reduction(^:e, f, arr[0:C][:argc]) reduction(task, && : g)
   foo();
   return 0;
 }

 // CHECK: template <typename T, int C> T tmain(T argc, T *argv) {
 // CHECK-NEXT: T b = argc, c, d, e, f, g;
 // CHECK-NEXT: static T a;
 // CHECK-NEXT: S<T> s;
 // CHECK-NEXT: T arr[C][10], arr1[C];
 // CHECK-NEXT: #pragma omp parallel master{{$}}
 // CHECK-NEXT: a = 2;
 // CHECK-NEXT: #pragma omp parallel master default(none) private(argc,b) firstprivate(argv) shared(d) if(parallel: argc > 0) num_threads(C) copyin(S<T>::TS,thrp) proc_bind(master) reduction(+: c,arr1[argc]) reduction(max: e,arr[:C][0:10])
 // CHECK-NEXT: foo()
 // CHECK-NEXT: #pragma omp parallel master if(C) num_threads(s) proc_bind(close) reduction(^: e,f,arr[0:C][:argc]) reduction(task, &&: g)
 // CHECK-NEXT: foo()
 // CHECK: template<> int tmain<int, 5>(int argc, int *argv) {
 // CHECK-NEXT: int b = argc, c, d, e, f, g;
 // CHECK-NEXT: static int a;
 // CHECK-NEXT: S<int> s;
 // CHECK-NEXT: int arr[5][10], arr1[5];
 // CHECK-NEXT: #pragma omp parallel master
 // CHECK-NEXT: a = 2;
 // CHECK-NEXT: #pragma omp parallel master default(none) private(argc,b) firstprivate(argv) shared(d) if(parallel: argc > 0) num_threads(5) copyin(S<int>::TS,thrp) proc_bind(master) reduction(+: c,arr1[argc]) reduction(max: e,arr[:5][0:10])
 // CHECK-NEXT: foo()
 // CHECK-NEXT: #pragma omp parallel master if(5) num_threads(s) proc_bind(close) reduction(^: e,f,arr[0:5][:argc]) reduction(task, &&: g)
 // CHECK-NEXT: foo()
 // CHECK: template<> long tmain<long, 1>(long argc, long *argv) {
 // CHECK-NEXT: long b = argc, c, d, e, f, g;
 // CHECK-NEXT: static long a;
 // CHECK-NEXT: S<long> s;
 // CHECK-NEXT: long arr[1][10], arr1[1];
 // CHECK-NEXT: #pragma omp parallel master
 // CHECK-NEXT: a = 2;
 // CHECK-NEXT: #pragma omp parallel master default(none) private(argc,b) firstprivate(argv) shared(d) if(parallel: argc > 0) num_threads(1) copyin(S<long>::TS,thrp) proc_bind(master) reduction(+: c,arr1[argc]) reduction(max: e,arr[:1][0:10])
 // CHECK-NEXT: foo()
 // CHECK-NEXT: #pragma omp parallel master if(1) num_threads(s) proc_bind(close) reduction(^: e,f,arr[0:1][:argc]) reduction(task, &&: g)
 // CHECK-NEXT: foo()

 enum Enum { };

 int main (int argc, char **argv) {
   long x;
   int b = argc, c, d, e, f, g;
   static int a;
   #pragma omp threadprivate(a)
   int arr[10][argc], arr1[2];
   Enum ee;
 // CHECK: Enum ee;
 #pragma omp parallel master
 // CHECK-NEXT: #pragma omp parallel master
   a=2;
 // CHECK-NEXT: a = 2;
 #pragma omp parallel master default(none), private(argc,b) firstprivate(argv) if (parallel: argc > 0) num_threads(ee) copyin(a) proc_bind(spread) reduction(| : c, d, arr1[argc]) reduction(* : e, arr[:10][0:argc]) allocate(e)
 // CHECK-NEXT: #pragma omp parallel master default(none) private(argc,b) firstprivate(argv) if(parallel: argc > 0) num_threads(ee) copyin(a) proc_bind(spread) reduction(|: c,d,arr1[argc]) reduction(*: e,arr[:10][0:argc]) allocate(e)
   foo();
 // CHECK-NEXT: foo();
 // CHECK-NEXT: #pragma omp parallel master allocate(e) if(b) num_threads(c) proc_bind(close) reduction(^: e,f) reduction(&&: g,arr[0:argc][:10])
 // CHECK-NEXT: foo()
 #pragma omp parallel master allocate(e) if (b) num_threads(c) proc_bind(close) reduction(^:e, f) reduction(&& : g, arr[0:argc][:10])
   foo();
   return tmain<int, 5>(b, &b) + tmain<long, 1>(x, &x);
 }

 template<typename T>
 T S<T>::TS = 0;

 #endif
	// RUN: %clang_cc1 -verify -fopenmp -ast-print %s \| FileCheck %s
	// RUN: %clang_cc1 -fopenmp -x c++ -std=c++11 -emit-pch -o %t %s
	// RUN: %clang_cc1 -fopenmp -std=c++11 -include-pch %t -fsyntax-only -verify %s -ast-print \| FileCheck %s

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

	#ifndef HEADER
	#define HEADER

	void foo() {}

	struct S1 {
	S1(): a(0) {}
	S1(int v) : a(v) {}
	int a;
	typedef int type;
	S1& operator +(const S1&);
	S1& operator *(const S1&);
	S1& operator &&(const S1&);
	S1& operator ^(const S1&);
	};

	template <typename T>
	class S7 : public T {
	protected:
	T a;
	T b[100];
	S7() : a(0) {}

	public:
	S7(typename T::type v) : a(v) {
	#pragma omp parallel master private(a) private(this->a) private(T::a)
	for (int k = 0; k < a.a; ++k)
	++this->a.a;
	#pragma omp parallel master firstprivate(a) firstprivate(this->a) firstprivate(T::a)
	for (int k = 0; k < a.a; ++k)
	++this->a.a;
	#pragma omp parallel master shared(a) shared(this->a) shared(T::a)
	for (int k = 0; k < a.a; ++k)
	++this->a.a;
	#pragma omp parallel master reduction(+ : a) reduction(*: b[:])
	for (int k = 0; k < a.a; ++k)
	++this->a.a;
	}
	S7 &operator=(S7 &s) {
	#pragma omp parallel master private(a) private(this->a)
	for (int k = 0; k < s.a.a; ++k)
	++s.a.a;
	#pragma omp parallel master firstprivate(a) firstprivate(this->a)
	for (int k = 0; k < s.a.a; ++k)
	++s.a.a;
	#pragma omp parallel master shared(a) shared(this->a)
	for (int k = 0; k < s.a.a; ++k)
	++s.a.a;
	#pragma omp parallel master reduction(&& : this->a) reduction(^: b[s.a.a])
	for (int k = 0; k < s.a.a; ++k)
	++s.a.a;
	return *this;
	}
	};

	// CHECK: #pragma omp parallel master private(this->a) private(this->a) private(T::a)
	// CHECK: #pragma omp parallel master firstprivate(this->a) firstprivate(this->a) firstprivate(T::a)
	// CHECK: #pragma omp parallel master shared(this->a) shared(this->a) shared(T::a)
	// CHECK: #pragma omp parallel master reduction(+: this->a) reduction(*: this->b[:])
	// CHECK: #pragma omp parallel master private(this->a) private(this->a)
	// CHECK: #pragma omp parallel master firstprivate(this->a) firstprivate(this->a)
	// CHECK: #pragma omp parallel master shared(this->a) shared(this->a)
	// CHECK: #pragma omp parallel master reduction(&&: this->a) reduction(^: this->b[s.a.a])
	// CHECK: #pragma omp parallel master private(this->a) private(this->a) private(this->S1::a)
	// CHECK: #pragma omp parallel master firstprivate(this->a) firstprivate(this->a) firstprivate(this->S1::a)
	// CHECK: #pragma omp parallel master shared(this->a) shared(this->a) shared(this->S1::a)
	// CHECK: #pragma omp parallel master reduction(+: this->a) reduction(*: this->b[:])

	class S8 : public S7<S1> {
	S8() {}

	public:
	S8(int v) : S7<S1>(v){
	#pragma omp parallel master private(a) private(this->a) private(S7 < S1 > ::a)
	for (int k = 0; k < a.a; ++k)
	++this->a.a;
	#pragma omp parallel master firstprivate(a) firstprivate(this->a) firstprivate(S7 < S1 > ::a)
	for (int k = 0; k < a.a; ++k)
	++this->a.a;
	#pragma omp parallel master shared(a) shared(this->a) shared(S7 < S1 > ::a)
	for (int k = 0; k < a.a; ++k)
	++this->a.a;
	#pragma omp parallel master reduction(^ : S7 < S1 > ::a) reduction(+ : S7 < S1 > ::b[ : S7 < S1 > ::a.a])
	for (int k = 0; k < a.a; ++k)
	++this->a.a;
	}
	S8 &operator=(S8 &s) {
	#pragma omp parallel master private(a) private(this->a)
	for (int k = 0; k < s.a.a; ++k)
	++s.a.a;
	#pragma omp parallel master firstprivate(a) firstprivate(this->a)
	for (int k = 0; k < s.a.a; ++k)
	++s.a.a;
	#pragma omp parallel master shared(a) shared(this->a)
	for (int k = 0; k < s.a.a; ++k)
	++s.a.a;
	#pragma omp parallel master reduction(* : this->a) reduction(&&:this->b[a.a:])
	for (int k = 0; k < s.a.a; ++k)
	++s.a.a;
	return *this;
	}
	};

	// CHECK: #pragma omp parallel master private(this->a) private(this->a) private(this->S7<S1>::a)
	// CHECK: #pragma omp parallel master firstprivate(this->a) firstprivate(this->a) firstprivate(this->S7<S1>::a)
	// CHECK: #pragma omp parallel master shared(this->a) shared(this->a) shared(this->S7<S1>::a)
	// CHECK: #pragma omp parallel master reduction(^: this->S7<S1>::a) reduction(+: this->S7<S1>::b[:this->S7<S1>::a.a])
	// CHECK: #pragma omp parallel master private(this->a) private(this->a)
	// CHECK: #pragma omp parallel master firstprivate(this->a) firstprivate(this->a)
	// CHECK: #pragma omp parallel master shared(this->a) shared(this->a)
	// CHECK: #pragma omp parallel master reduction(*: this->a) reduction(&&: this->b[this->a.a:])

	template <class T>
	struct S {
	operator T() {return T();}
	static T TS;
	#pragma omp threadprivate(TS)
	};

	// CHECK: template <class T> struct S {
	// CHECK: static T TS;
	// CHECK-NEXT: #pragma omp threadprivate(S::TS)
	// CHECK: };
	// CHECK: template<> struct S<int> {
	// CHECK: static int TS;
	// CHECK-NEXT: #pragma omp threadprivate(S<int>::TS)
	// CHECK-NEXT: }
	// CHECK: template<> struct S<long> {
	// CHECK: static long TS;
	// CHECK-NEXT: #pragma omp threadprivate(S<long>::TS)
	// CHECK-NEXT: }

	int thrp;
	#pragma omp threadprivate(thrp)

	template <typename T, int C>
	T tmain(T argc, T *argv) {
	T b = argc, c, d, e, f, g;
	static T a;
	S<T> s;
	T arr[C][10], arr1[C];
	#pragma omp parallel master
	a=2;
	#pragma omp parallel master default(none), private(argc,b) firstprivate(argv) shared (d) if (parallel:argc > 0) num_threads(C) copyin(S<T>::TS, thrp) proc_bind(master) reduction(+:c, arr1[argc]) reduction(max:e, arr[:C][0:10])
	foo();
	#pragma omp parallel master if (C) num_threads(s) proc_bind(close) reduction(^:e, f, arr[0:C][:argc]) reduction(task, && : g)
	foo();
	return 0;
	}

	// CHECK: template <typename T, int C> T tmain(T argc, T *argv) {
	// CHECK-NEXT: T b = argc, c, d, e, f, g;
	// CHECK-NEXT: static T a;
	// CHECK-NEXT: S<T> s;
	// CHECK-NEXT: T arr[C][10], arr1[C];
	// CHECK-NEXT: #pragma omp parallel master{{$}}
	// CHECK-NEXT: a = 2;
	// CHECK-NEXT: #pragma omp parallel master default(none) private(argc,b) firstprivate(argv) shared(d) if(parallel: argc > 0) num_threads(C) copyin(S<T>::TS,thrp) proc_bind(master) reduction(+: c,arr1[argc]) reduction(max: e,arr[:C][0:10])
	// CHECK-NEXT: foo()
	// CHECK-NEXT: #pragma omp parallel master if(C) num_threads(s) proc_bind(close) reduction(^: e,f,arr[0:C][:argc]) reduction(task, &&: g)
	// CHECK-NEXT: foo()
	// CHECK: template<> int tmain<int, 5>(int argc, int *argv) {
	// CHECK-NEXT: int b = argc, c, d, e, f, g;
	// CHECK-NEXT: static int a;
	// CHECK-NEXT: S<int> s;
	// CHECK-NEXT: int arr[5][10], arr1[5];
	// CHECK-NEXT: #pragma omp parallel master
	// CHECK-NEXT: a = 2;
	// CHECK-NEXT: #pragma omp parallel master default(none) private(argc,b) firstprivate(argv) shared(d) if(parallel: argc > 0) num_threads(5) copyin(S<int>::TS,thrp) proc_bind(master) reduction(+: c,arr1[argc]) reduction(max: e,arr[:5][0:10])
	// CHECK-NEXT: foo()
	// CHECK-NEXT: #pragma omp parallel master if(5) num_threads(s) proc_bind(close) reduction(^: e,f,arr[0:5][:argc]) reduction(task, &&: g)
	// CHECK-NEXT: foo()
	// CHECK: template<> long tmain<long, 1>(long argc, long *argv) {
	// CHECK-NEXT: long b = argc, c, d, e, f, g;
	// CHECK-NEXT: static long a;
	// CHECK-NEXT: S<long> s;
	// CHECK-NEXT: long arr[1][10], arr1[1];
	// CHECK-NEXT: #pragma omp parallel master
	// CHECK-NEXT: a = 2;
	// CHECK-NEXT: #pragma omp parallel master default(none) private(argc,b) firstprivate(argv) shared(d) if(parallel: argc > 0) num_threads(1) copyin(S<long>::TS,thrp) proc_bind(master) reduction(+: c,arr1[argc]) reduction(max: e,arr[:1][0:10])
	// CHECK-NEXT: foo()
	// CHECK-NEXT: #pragma omp parallel master if(1) num_threads(s) proc_bind(close) reduction(^: e,f,arr[0:1][:argc]) reduction(task, &&: g)
	// CHECK-NEXT: foo()

	enum Enum { };

	int main (int argc, char **argv) {
	long x;
	int b = argc, c, d, e, f, g;
	static int a;
	#pragma omp threadprivate(a)
	int arr[10][argc], arr1[2];
	Enum ee;
	// CHECK: Enum ee;
	#pragma omp parallel master
	// CHECK-NEXT: #pragma omp parallel master
	a=2;
	// CHECK-NEXT: a = 2;
	#pragma omp parallel master default(none), private(argc,b) firstprivate(argv) if (parallel: argc > 0) num_threads(ee) copyin(a) proc_bind(spread) reduction(\| : c, d, arr1[argc]) reduction(* : e, arr[:10][0:argc]) allocate(e)
	// CHECK-NEXT: #pragma omp parallel master default(none) private(argc,b) firstprivate(argv) if(parallel: argc > 0) num_threads(ee) copyin(a) proc_bind(spread) reduction(\|: c,d,arr1[argc]) reduction(*: e,arr[:10][0:argc]) allocate(e)
	foo();
	// CHECK-NEXT: foo();
	// CHECK-NEXT: #pragma omp parallel master allocate(e) if(b) num_threads(c) proc_bind(close) reduction(^: e,f) reduction(&&: g,arr[0:argc][:10])
	// CHECK-NEXT: foo()
	#pragma omp parallel master allocate(e) if (b) num_threads(c) proc_bind(close) reduction(^:e, f) reduction(&& : g, arr[0:argc][:10])
	foo();
	return tmain<int, 5>(b, &b) + tmain<long, 1>(x, &x);
	}

	template<typename T>
	T S<T>::TS = 0;

	#endif