extern int omp_default_mem_alloc;
void foo() {
}
bool foobool(int argc) {
return argc;
}
struct S1; extern S1 a;
class S2 {
mutable int a;
public:
S2() : a(0) {}
};
const S2 b;
const S2 ba[5];
class S3 {
int a;
public:
S3() : a(0) {}
};
const S3 ca[5];
class S4 {
int a;
S4();
public:
S4(int v) : a(v) {
#pragma omp parallel master private(a) private(this->a)
{
for (int k = 0; k < v; ++k)
++this->a;
}
}
};
class S5 {
int a;
S5() : a(0) {}
public:
S5(int v) : a(v) {}
S5 &operator=(S5 &s) {
#pragma omp parallel master private(a) private(this->a) private(s.a)
{
for (int k = 0; k < s.a; ++k)
++s.a;
}
return *this;
}
};
template <typename T>
class S6 {
public:
T a;
S6() : a(0) {}
S6(T v) : a(v) {
#pragma omp parallel master private(a) private(this->a)
{
for (int k = 0; k < v; ++k)
++this->a;
}
}
S6 &operator=(S6 &s) {
#pragma omp parallel master private(a) private(this->a) private(s.a)
{
for (int k = 0; k < s.a; ++k)
++s.a;
}
return *this;
}
};
template <typename T>
class S7 : public T {
T a;
S7() : a(0) {}
public:
S7(T 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;
}
}
S7 &operator=(S7 &s) {
#pragma omp parallel master private(a) private(this->a) private(s.a) private(s.T::a)
{
for (int k = 0; k < s.a.a; ++k)
++s.a.a;
}
return *this;
}
};
S3 h;
#pragma omp threadprivate(h)
template <class I, class C>
int foomain(I argc, C **argv) {
I e(4);
I g(5);
int i, z;
int &j = i;
#pragma omp parallel master private
{
foo();
}
#pragma omp parallel master private(
{
foo();
}
#pragma omp parallel master private()
{
foo();
}
#pragma omp parallel master private(argc
{
foo();
}
#pragma omp parallel master private(argc,
{
foo();
}
#pragma omp parallel master private(argc > 0 ? argv[1] : argv[2])
{
foo();
}
#pragma omp parallel master private(argc) allocate , allocate(, allocate(omp_default , allocate(omp_default_mem_alloc, allocate(omp_default_mem_alloc:, allocate(omp_default_mem_alloc: argc, allocate(omp_default_mem_alloc: argv), allocate(argv)
{
foo();
}
#pragma omp parallel master private(S1)
{
foo();
}
#pragma omp parallel master private(a, b)
{
foo();
}
#pragma omp parallel master private(argv[1])
{
foo();
}
#pragma omp parallel master private(e, g, z)
{
foo();
}
#pragma omp parallel master private(h)
{
foo();
}
#pragma omp parallel master copyprivate(h)
{
foo();
}
#pragma omp parallel
{
int v = 0;
int i;
#pragma omp parallel master private(i)
{
foo();
}
v += i;
}
#pragma omp parallel shared(i)
#pragma omp parallel private(i)
#pragma omp parallel master private(j)
{
foo();
}
#pragma omp parallel master private(i)
{
foo();
}
return 0;
}
namespace A {
double x;
#pragma omp threadprivate(x)
}
namespace B {
using A::x;
}
int main(int argc, char **argv) {
S4 e(4);
S5 g(5);
S6<float> s6(0.0) , s6_0(1.0);
S7<S6<float> > s7(0.0) , s7_0(1.0);
int i, z;
int &j = i;
#pragma omp parallel master private
{
foo();
}
#pragma omp parallel master private(
{
foo();
}
#pragma omp parallel master private()
{
foo();
}
#pragma omp parallel master private(argc
{
foo();
}
#pragma omp parallel master private(argc,
{
foo();
}
#pragma omp parallel master private(argc > 0 ? argv[1] : argv[2])
{
foo();
}
#pragma omp parallel master private(argc, z)
{
foo();
}
#pragma omp parallel master private(S1)
{
foo();
}
#pragma omp parallel master private(a, b)
{
foo();
}
#pragma omp parallel master private(argv[1])
{
foo();
}
#pragma omp parallel master private(e, g)
{
foo();
}
#pragma omp parallel master private(h, B::x)
{
foo();
}
#pragma omp parallel master copyprivate(h)
{
foo();
}
#pragma omp parallel
{
int i;
#pragma omp parallel master private(i)
{
foo();
}
}
#pragma omp parallel shared(i)
#pragma omp parallel private(i)
#pragma omp parallel master private(j)
{
foo();
}
#pragma omp parallel master private(i)
{
foo();
}
static int m;
#pragma omp parallel master private(m)
{
foo();
}
s6 = s6_0; s7 = s7_0; return foomain(argc, argv); }