libgomp/testsuite/libgomp.c-c++-common/allocate-1.c - gcc - Git at Google

 #include <omp.h>
 #include <stdlib.h>
 #include <stdint.h>

 struct S { int a, b; };

 void
 foo (int x, int *p, int *q, int px, omp_allocator_handle_t h, int fl)
 {
   int y = 0, r = 0, i, i1, l, l2[4], l3, n = 8;
   int i2, j2, n2 = 9, l4;
   int i3, j3, n3 = 10, l5;
   int i4, j4, n4 = 11, l6;
   int i5;
   int v[x], w[x];
   int r2[4] = { 0, 0, 0, 0 };
   int xo = x;
   struct S s = { 27, 29 };
   for (i = 0; i < 4; i++)
     p[i] = 0;
   for (i = 0; i < 3; i++)
     q[i] = 0;
   for (i = 0; i < x; i++)
     w[i] = i;
   #pragma omp parallel private (y, v) firstprivate (x) allocate (x, y, v)
   {
     int *volatile p1 = &x;
     int *volatile p2 = &y;
     if (x != 42)
       abort ();
     #pragma omp barrier
     *p2 = 1;
     p1[0]++;
     v[0] = 7;
     v[41] = 8;
     #pragma omp barrier
     if (x != 43 || y != 1)
       abort ();
     if (v[0] != 7 || v[41] != 8)
       abort ();
     if ((fl & 2) && (((uintptr_t) p1 | (uintptr_t) p2
 	| (uintptr_t) &v[0]) & 63) != 0)
       abort ();
   }
   x = xo;
   #pragma omp teams
   #pragma omp parallel private (y) firstprivate (x, w) allocate (h: x, y, w)
   {
     int *volatile p1 = &x;
     int *volatile p2 = &y;
     if (x != 42 || w[17] != 17 || w[41] != 41)
       abort ();
     #pragma omp barrier
     *p2 = 1;
     p1[0]++;
     w[19]++;
     #pragma omp barrier
     if (x != 43 || y != 1 || w[19] != 20)
       abort ();
     if ((fl & 1) && (((uintptr_t) p1 | (uintptr_t) p2
 		      | (uintptr_t) &w[0]) & 63) != 0)
       abort ();
   }
   x = xo;
   #pragma omp parallel for private (y) firstprivate (x) allocate (h: x, y, r, l, n) reduction(+: r) lastprivate (l) linear (n: 16)
   for (i = 0; i < 64; i++)
     {
       if (x != 42)
 	abort ();
       y = 1;
       l = i;
       n += y + 15;
       r += i;
       if ((fl & 1) && (((uintptr_t) &x | (uintptr_t) &y | (uintptr_t) &r
 			| (uintptr_t) &l | (uintptr_t) &n) & 63) != 0)
 	abort ();
     }
   x = xo;
   #pragma omp parallel
   {
     #pragma omp for lastprivate (l2) private (i1) allocate (h: l2, l3, i1) lastprivate (conditional: l3)
     for (i1 = 0; i1 < 64; i1++)
       {
 	l2[0] = i1;
 	l2[1] = i1 + 1;
 	l2[2] = i1 + 2;
 	l2[3] = i1 + 3;
 	if (i1 < 37)
 	  l3 = i1;
 	if ((fl & 1) && (((uintptr_t) &l2[0] | (uintptr_t) &l3 | (uintptr_t) &i1) & 63) != 0)
 	  abort ();
       }
     #pragma omp for collapse(2) lastprivate(l4, i2, j2) linear (n2:17) allocate (h: n2, l4, i2, j2)
     for (i2 = 3; i2 < 5; i2++)
       for (j2 = 17; j2 < 22; j2 += 2)
 	{
 	  n2 += 17;
 	  l4 = i2 * 31 + j2;
 	  if ((fl & 1) && (((uintptr_t) &l4 | (uintptr_t) &n2
 			    | (uintptr_t) &i2 | (uintptr_t) &j2) & 63) != 0)
 	    abort ();
 	}
     #pragma omp for collapse(2) lastprivate(l5, i3, j3) linear (n3:17) schedule (static, 3) allocate (n3, l5, i3, j3)
     for (i3 = 3; i3 < 5; i3++)
       for (j3 = 17; j3 < 23; j3 += 2)
 	{
 	  n3 += 17;
 	  l5 = i3 * 31 + j3;
 	  if ((fl & 2) && (((uintptr_t) &l5 | (uintptr_t) &n3
 			    | (uintptr_t) &i3 | (uintptr_t) &j3) & 63) != 0)
 	    abort ();
 	}
     #pragma omp for collapse(2) lastprivate(l6, i4, j4) linear (n4:17) schedule (dynamic) allocate (h: n4, l6, i4, j4)
     for (i4 = 3; i4 < 5; i4++)
       for (j4 = 17; j4 < 22; j4 += 2)
 	{
 	  n4 += 17;
 	  l6 = i4 * 31 + j4;
 	  if ((fl & 1) && (((uintptr_t) &l6 | (uintptr_t) &n4
 			    | (uintptr_t) &i4 | (uintptr_t) &j4) & 63) != 0)
 	    abort ();
 	}
     #pragma omp for lastprivate (i5) allocate (i5)
     for (i5 = 1; i5 < 17; i5 += 3)
       {
 	if ((fl & 2) && (((uintptr_t) &i5) & 63) != 0)
 	  abort ();
       }
     #pragma omp for reduction(+:p[2:px], q[:3], r2) allocate(h: p, q, r2)
     for (i = 0; i < 32; i++)
       {
 	p[2] += i;
 	p[3] += 2 * i;
 	q[0] += 3 * i;
 	q[2] += 4 * i;
 	r2[0] += 5 * i;
 	r2[3] += 6 * i;
 	/* Can't really rely on alignment of &p[0], the implementation could
 	   allocate the whole array or do what GCC does and allocate only part
 	   of it.  */
 	if ((fl & 1) && (((uintptr_t) &q[0] | (uintptr_t) &r2[0]) & 63) != 0)
 	  abort ();
       }
     #pragma omp task private(y) firstprivate(x) allocate(x, y)
     {
       int *volatile p1 = &x;
       int *volatile p2 = &y;
       if (x != 42)
 	abort ();
       p1[0]++;
       p2[0] = 21;
       if (x != 43 || y != 21)
 	abort ();
       if ((fl & 2) && (((uintptr_t) p1 | (uintptr_t) p2) & 63) != 0)
 	abort ();
     }
     #pragma omp task private(y) firstprivate(x) allocate(h: x, y)
     {
       int *volatile p1 = &x;
       int *volatile p2 = &y;
       if (x != 42)
 	abort ();
       p1[0]++;
       p2[0] = 21;
       if (x != 43 || y != 21)
 	abort ();
       if ((fl & 1) && (((uintptr_t) p1 | (uintptr_t) p2) & 63) != 0)
 	abort ();
     }
     #pragma omp task private(y) firstprivate(s) allocate(s, y)
     {
       int *volatile p1 = &s.a;
       int *volatile p2 = &s.b;
       int *volatile p3 = &y;
       if (s.a != 27 || s.b != 29)
 	abort ();
       p1[0]++;
       p2[0]++;
       p3[0] = 21;
       if (s.a != 28 || s.b != 30 || y != 21)
 	abort ();
       if ((fl & 2) && (((uintptr_t) p1 | (uintptr_t) p3) & 63) != 0)
 	abort ();
     }
     #pragma omp task private(y) firstprivate(s) allocate(h: s, y)
     {
       int *volatile p1 = &s.a;
       int *volatile p2 = &s.b;
       int *volatile p3 = &y;
       if (s.a != 27 || s.b != 29)
 	abort ();
       p1[0]++;
       p2[0]++;
       p3[0] = 21;
       if (s.a != 28 || s.b != 30 || y != 21)
 	abort ();
       if ((fl & 1) && (((uintptr_t) p1 | (uintptr_t) p3) & 63) != 0)
 	abort ();
     }
   }
   if (r != 64 * 63 / 2 || l != 63 || n != 8 + 16 * 64)
     abort ();
   if (l2[0] != 63 || l2[1] != 63 + 1 || l2[2] != 63 + 2 || l2[3] != 63 + 3 || l3 != 36)
     abort ();
   if (i2 != 5 || j2 != 23 || n2 != 9 + 6 * 17 || l4 != 4 * 31 + 21)
     abort ();
   if (i3 != 5 || j3 != 23 || n3 != 10 + 6 * 17 || l5 != 4 * 31 + 21)
     abort ();
   if (i4 != 5 || j4 != 23 || n4 != 11 + 6 * 17 || l6 != 4 * 31 + 21)
     abort ();
   if (i5 != 19)
     abort ();
   if (p[2] != (32 * 31) / 2 || p[3] != 2 * (32 * 31) / 2
       || q[0] != 3 * (32 * 31) / 2 || q[2] != 4 * (32 * 31) / 2
       || r2[0] != 5 * (32 * 31) / 2 || r2[3] != 6 * (32 * 31) / 2)
     abort ();
 }

 void
 bar (int x, omp_allocator_handle_t h)
 {
   int y = 0, r = 0, i, i1, l, l2[4], l3, n = 8;
   int i2, j2, n2 = 9, l4;
   int i3, j3, n3 = 10, l5;
   int i4, j4, n4 = 11, l6;
   int i5;
   struct S s = { 27, 29 };
   int xo = x;
   #pragma omp parallel private (y) firstprivate (x) allocate (x, y)
   {
     if (x != 42)
       abort ();
     #pragma omp barrier
     y = 1;
     x++;
     #pragma omp barrier
     if (x != 43 || y != 1)
       abort ();
   }
   x = xo;
   #pragma omp teams
   #pragma omp parallel private (y) firstprivate (x) allocate (h: x, y)
   {
     if (x != 42)
       abort ();
     #pragma omp barrier
     y = 1;
     x++;
     #pragma omp barrier
     if (x != 43 || y != 1)
       abort ();
   }
   x = xo;
   #pragma omp parallel for private (y) firstprivate (x) allocate (h: x, y, r, l, n) reduction(+: r) lastprivate (l) linear (n: 16)
   for (i = 0; i < 64; i++)
     {
       if (x != 42)
 	abort ();
       y = 1;
       l = i;
       n += y + 15;
       r += i;
     }
   x = xo;
   #pragma omp parallel
   {
     #pragma omp for lastprivate (l2) private (i1) allocate (h: l2, l3, i1) lastprivate (conditional: l3)
     for (i1 = 0; i1 < 64; i1++)
       {
 	l2[0] = i1;
 	l2[1] = i1 + 1;
 	l2[2] = i1 + 2;
 	l2[3] = i1 + 3;
 	if (i1 < 37)
 	  l3 = i1;
       }
     #pragma omp for collapse(2) lastprivate(l4, i2, j2) linear (n2:17) allocate (h: n2, l4, i2, j2)
     for (i2 = 3; i2 < 5; i2++)
       for (j2 = 17; j2 < 22; j2 += 2)
 	{
 	  n2 += 17;
 	  l4 = i2 * 31 + j2;
 	}
     #pragma omp for collapse(2) lastprivate(l5, i3, j3) linear (n3:17) schedule (static, 3) allocate (n3, l5, i3, j3)
     for (i3 = 3; i3 < 5; i3++)
       for (j3 = 17; j3 < 23; j3 += 2)
 	{
 	  n3 += 17;
 	  l5 = i3 * 31 + j3;
 	}
     #pragma omp for collapse(2) lastprivate(l6, i4, j4) linear (n4:17) schedule (dynamic) allocate (h: n4, l6, i4, j4)
     for (i4 = 3; i4 < 5; i4++)
       for (j4 = 17; j4 < 22; j4 += 2)
 	{
 	  n4 += 17;
 	  l6 = i4 * 31 + j4;
 	}
     #pragma omp for lastprivate (i5) allocate (i5)
     for (i5 = 1; i5 < 17; i5 += 3)
       ;
     #pragma omp task private(y) firstprivate(x) allocate(x, y)
     {
       if (x != 42)
 	abort ();
       x++;
       y = 21;
       if (x != 43 || y != 21)
 	abort ();
     }
     #pragma omp task private(y) firstprivate(x) allocate(h: x, y)
     {
       if (x != 42)
 	abort ();
       x++;
       y = 21;
       if (x != 43 || y != 21)
 	abort ();
     }
     #pragma omp task private(y) firstprivate(s) allocate(s, y)
     {
       if (s.a != 27 || s.b != 29)
 	abort ();
       s.a++;
       s.b++;
       y = 21;
       if (s.a != 28 || s.b != 30 || y != 21)
 	abort ();
     }
     #pragma omp task private(y) firstprivate(s) allocate(h: s, y)
     {
       if (s.a != 27 || s.b != 29)
 	abort ();
       s.a++;
       s.b++;
       y = 21;
       if (s.a != 28 || s.b != 30 || y != 21)
 	abort ();
     }
   }
   if (r != 64 * 63 / 2 || l != 63 || n != 8 + 16 * 64)
     abort ();
   if (l2[0] != 63 || l2[1] != 63 + 1 || l2[2] != 63 + 2 || l2[3] != 63 + 3 || l3 != 36)
     abort ();
   if (i2 != 5 || j2 != 23 || n2 != 9 + 6 * 17 || l4 != 4 * 31 + 21)
     abort ();
   if (i3 != 5 || j3 != 23 || n3 != 10 + 6 * 17 || l5 != 4 * 31 + 21)
     abort ();
   if (i4 != 5 || j4 != 23 || n4 != 11 + 6 * 17 || l6 != 4 * 31 + 21)
     abort ();
   if (i5 != 19)
     abort ();
 }

 int
 main ()
 {
   omp_alloctrait_t traits[3]
     = { { omp_atk_alignment, 64 },
 	{ omp_atk_fallback, omp_atv_null_fb } };
   omp_allocator_handle_t a
     = omp_init_allocator (omp_default_mem_space, 2, traits);
   int p[4], q[3];
   if (a == omp_null_allocator)
     abort ();
   omp_set_default_allocator (omp_default_mem_alloc);
   foo (42, p, q, 2, omp_null_allocator, 0);
   foo (42, p, q, 2, omp_default_mem_alloc, 0);
   foo (42, p, q, 2, a, 1);
   omp_set_default_allocator (a);
   foo (42, p, q, 2, omp_null_allocator, 3);
   foo (42, p, q, 2, omp_default_mem_alloc, 2);
   bar (42, a);
   omp_destroy_allocator (a);
   return 0;
 }
	#include <omp.h>
	#include <stdlib.h>
	#include <stdint.h>

	struct S { int a, b; };

	void
	foo (int x, int p, int q, int px, omp_allocator_handle_t h, int fl)
	{
	int y = 0, r = 0, i, i1, l, l2[4], l3, n = 8;
	int i2, j2, n2 = 9, l4;
	int i3, j3, n3 = 10, l5;
	int i4, j4, n4 = 11, l6;
	int i5;
	int v[x], w[x];
	int r2[4] = { 0, 0, 0, 0 };
	int xo = x;
	struct S s = { 27, 29 };
	for (i = 0; i < 4; i++)
	p[i] = 0;
	for (i = 0; i < 3; i++)
	q[i] = 0;
	for (i = 0; i < x; i++)
	w[i] = i;
	#pragma omp parallel private (y, v) firstprivate (x) allocate (x, y, v)
	{
	int *volatile p1 = &x;
	int *volatile p2 = &y;
	if (x != 42)
	abort ();
	#pragma omp barrier
	*p2 = 1;
	p1[0]++;
	v[0] = 7;
	v[41] = 8;
	#pragma omp barrier
	if (x != 43 \|\| y != 1)
	abort ();
	if (v[0] != 7 \|\| v[41] != 8)
	abort ();
	if ((fl & 2) && (((uintptr_t) p1 \| (uintptr_t) p2
	\| (uintptr_t) &v[0]) & 63) != 0)
	abort ();
	}
	x = xo;
	#pragma omp teams
	#pragma omp parallel private (y) firstprivate (x, w) allocate (h: x, y, w)
	{
	int *volatile p1 = &x;
	int *volatile p2 = &y;
	if (x != 42 \|\| w[17] != 17 \|\| w[41] != 41)
	abort ();
	#pragma omp barrier
	*p2 = 1;
	p1[0]++;
	w[19]++;
	#pragma omp barrier
	if (x != 43 \|\| y != 1 \|\| w[19] != 20)
	abort ();
	if ((fl & 1) && (((uintptr_t) p1 \| (uintptr_t) p2
	\| (uintptr_t) &w[0]) & 63) != 0)
	abort ();
	}
	x = xo;
	#pragma omp parallel for private (y) firstprivate (x) allocate (h: x, y, r, l, n) reduction(+: r) lastprivate (l) linear (n: 16)
	for (i = 0; i < 64; i++)
	{
	if (x != 42)
	abort ();
	y = 1;
	l = i;
	n += y + 15;
	r += i;
	if ((fl & 1) && (((uintptr_t) &x \| (uintptr_t) &y \| (uintptr_t) &r
	\| (uintptr_t) &l \| (uintptr_t) &n) & 63) != 0)
	abort ();
	}
	x = xo;
	#pragma omp parallel
	{
	#pragma omp for lastprivate (l2) private (i1) allocate (h: l2, l3, i1) lastprivate (conditional: l3)
	for (i1 = 0; i1 < 64; i1++)
	{
	l2[0] = i1;
	l2[1] = i1 + 1;
	l2[2] = i1 + 2;
	l2[3] = i1 + 3;
	if (i1 < 37)
	l3 = i1;
	if ((fl & 1) && (((uintptr_t) &l2[0] \| (uintptr_t) &l3 \| (uintptr_t) &i1) & 63) != 0)
	abort ();
	}
	#pragma omp for collapse(2) lastprivate(l4, i2, j2) linear (n2:17) allocate (h: n2, l4, i2, j2)
	for (i2 = 3; i2 < 5; i2++)
	for (j2 = 17; j2 < 22; j2 += 2)
	{
	n2 += 17;
	l4 = i2 * 31 + j2;
	if ((fl & 1) && (((uintptr_t) &l4 \| (uintptr_t) &n2
	\| (uintptr_t) &i2 \| (uintptr_t) &j2) & 63) != 0)
	abort ();
	}
	#pragma omp for collapse(2) lastprivate(l5, i3, j3) linear (n3:17) schedule (static, 3) allocate (n3, l5, i3, j3)
	for (i3 = 3; i3 < 5; i3++)
	for (j3 = 17; j3 < 23; j3 += 2)
	{
	n3 += 17;
	l5 = i3 * 31 + j3;
	if ((fl & 2) && (((uintptr_t) &l5 \| (uintptr_t) &n3
	\| (uintptr_t) &i3 \| (uintptr_t) &j3) & 63) != 0)
	abort ();
	}
	#pragma omp for collapse(2) lastprivate(l6, i4, j4) linear (n4:17) schedule (dynamic) allocate (h: n4, l6, i4, j4)
	for (i4 = 3; i4 < 5; i4++)
	for (j4 = 17; j4 < 22; j4 += 2)
	{
	n4 += 17;
	l6 = i4 * 31 + j4;
	if ((fl & 1) && (((uintptr_t) &l6 \| (uintptr_t) &n4
	\| (uintptr_t) &i4 \| (uintptr_t) &j4) & 63) != 0)
	abort ();
	}
	#pragma omp for lastprivate (i5) allocate (i5)
	for (i5 = 1; i5 < 17; i5 += 3)
	{
	if ((fl & 2) && (((uintptr_t) &i5) & 63) != 0)
	abort ();
	}
	#pragma omp for reduction(+:p[2:px], q[:3], r2) allocate(h: p, q, r2)
	for (i = 0; i < 32; i++)
	{
	p[2] += i;
	p[3] += 2 * i;
	q[0] += 3 * i;
	q[2] += 4 * i;
	r2[0] += 5 * i;
	r2[3] += 6 * i;
	/* Can't really rely on alignment of &p[0], the implementation could
	allocate the whole array or do what GCC does and allocate only part
	of it. */
	if ((fl & 1) && (((uintptr_t) &q[0] \| (uintptr_t) &r2[0]) & 63) != 0)
	abort ();
	}
	#pragma omp task private(y) firstprivate(x) allocate(x, y)
	{
	int *volatile p1 = &x;
	int *volatile p2 = &y;
	if (x != 42)
	abort ();
	p1[0]++;
	p2[0] = 21;
	if (x != 43 \|\| y != 21)
	abort ();
	if ((fl & 2) && (((uintptr_t) p1 \| (uintptr_t) p2) & 63) != 0)
	abort ();
	}
	#pragma omp task private(y) firstprivate(x) allocate(h: x, y)
	{
	int *volatile p1 = &x;
	int *volatile p2 = &y;
	if (x != 42)
	abort ();
	p1[0]++;
	p2[0] = 21;
	if (x != 43 \|\| y != 21)
	abort ();
	if ((fl & 1) && (((uintptr_t) p1 \| (uintptr_t) p2) & 63) != 0)
	abort ();
	}
	#pragma omp task private(y) firstprivate(s) allocate(s, y)
	{
	int *volatile p1 = &s.a;
	int *volatile p2 = &s.b;
	int *volatile p3 = &y;
	if (s.a != 27 \|\| s.b != 29)
	abort ();
	p1[0]++;
	p2[0]++;
	p3[0] = 21;
	if (s.a != 28 \|\| s.b != 30 \|\| y != 21)
	abort ();
	if ((fl & 2) && (((uintptr_t) p1 \| (uintptr_t) p3) & 63) != 0)
	abort ();
	}
	#pragma omp task private(y) firstprivate(s) allocate(h: s, y)
	{
	int *volatile p1 = &s.a;
	int *volatile p2 = &s.b;
	int *volatile p3 = &y;
	if (s.a != 27 \|\| s.b != 29)
	abort ();
	p1[0]++;
	p2[0]++;
	p3[0] = 21;
	if (s.a != 28 \|\| s.b != 30 \|\| y != 21)
	abort ();
	if ((fl & 1) && (((uintptr_t) p1 \| (uintptr_t) p3) & 63) != 0)
	abort ();
	}
	}
	if (r != 64 * 63 / 2 \|\| l != 63 \|\| n != 8 + 16 * 64)
	abort ();
	if (l2[0] != 63 \|\| l2[1] != 63 + 1 \|\| l2[2] != 63 + 2 \|\| l2[3] != 63 + 3 \|\| l3 != 36)
	abort ();
	if (i2 != 5 \|\| j2 != 23 \|\| n2 != 9 + 6 * 17 \|\| l4 != 4 * 31 + 21)
	abort ();
	if (i3 != 5 \|\| j3 != 23 \|\| n3 != 10 + 6 * 17 \|\| l5 != 4 * 31 + 21)
	abort ();
	if (i4 != 5 \|\| j4 != 23 \|\| n4 != 11 + 6 * 17 \|\| l6 != 4 * 31 + 21)
	abort ();
	if (i5 != 19)
	abort ();
	if (p[2] != (32 * 31) / 2 \|\| p[3] != 2 * (32 * 31) / 2
	\|\| q[0] != 3 * (32 * 31) / 2 \|\| q[2] != 4 * (32 * 31) / 2
	\|\| r2[0] != 5 * (32 * 31) / 2 \|\| r2[3] != 6 * (32 * 31) / 2)
	abort ();
	}

	void
	bar (int x, omp_allocator_handle_t h)
	{
	int y = 0, r = 0, i, i1, l, l2[4], l3, n = 8;
	int i2, j2, n2 = 9, l4;
	int i3, j3, n3 = 10, l5;
	int i4, j4, n4 = 11, l6;
	int i5;
	struct S s = { 27, 29 };
	int xo = x;
	#pragma omp parallel private (y) firstprivate (x) allocate (x, y)
	{
	if (x != 42)
	abort ();
	#pragma omp barrier
	y = 1;
	x++;
	#pragma omp barrier
	if (x != 43 \|\| y != 1)
	abort ();
	}
	x = xo;
	#pragma omp teams
	#pragma omp parallel private (y) firstprivate (x) allocate (h: x, y)
	{
	if (x != 42)
	abort ();
	#pragma omp barrier
	y = 1;
	x++;
	#pragma omp barrier
	if (x != 43 \|\| y != 1)
	abort ();
	}
	x = xo;
	#pragma omp parallel for private (y) firstprivate (x) allocate (h: x, y, r, l, n) reduction(+: r) lastprivate (l) linear (n: 16)
	for (i = 0; i < 64; i++)
	{
	if (x != 42)
	abort ();
	y = 1;
	l = i;
	n += y + 15;
	r += i;
	}
	x = xo;
	#pragma omp parallel
	{
	#pragma omp for lastprivate (l2) private (i1) allocate (h: l2, l3, i1) lastprivate (conditional: l3)
	for (i1 = 0; i1 < 64; i1++)
	{
	l2[0] = i1;
	l2[1] = i1 + 1;
	l2[2] = i1 + 2;
	l2[3] = i1 + 3;
	if (i1 < 37)
	l3 = i1;
	}
	#pragma omp for collapse(2) lastprivate(l4, i2, j2) linear (n2:17) allocate (h: n2, l4, i2, j2)
	for (i2 = 3; i2 < 5; i2++)
	for (j2 = 17; j2 < 22; j2 += 2)
	{
	n2 += 17;
	l4 = i2 * 31 + j2;
	}
	#pragma omp for collapse(2) lastprivate(l5, i3, j3) linear (n3:17) schedule (static, 3) allocate (n3, l5, i3, j3)
	for (i3 = 3; i3 < 5; i3++)
	for (j3 = 17; j3 < 23; j3 += 2)
	{
	n3 += 17;
	l5 = i3 * 31 + j3;
	}
	#pragma omp for collapse(2) lastprivate(l6, i4, j4) linear (n4:17) schedule (dynamic) allocate (h: n4, l6, i4, j4)
	for (i4 = 3; i4 < 5; i4++)
	for (j4 = 17; j4 < 22; j4 += 2)
	{
	n4 += 17;
	l6 = i4 * 31 + j4;
	}
	#pragma omp for lastprivate (i5) allocate (i5)
	for (i5 = 1; i5 < 17; i5 += 3)
	;
	#pragma omp task private(y) firstprivate(x) allocate(x, y)
	{
	if (x != 42)
	abort ();
	x++;
	y = 21;
	if (x != 43 \|\| y != 21)
	abort ();
	}
	#pragma omp task private(y) firstprivate(x) allocate(h: x, y)
	{
	if (x != 42)
	abort ();
	x++;
	y = 21;
	if (x != 43 \|\| y != 21)
	abort ();
	}
	#pragma omp task private(y) firstprivate(s) allocate(s, y)
	{
	if (s.a != 27 \|\| s.b != 29)
	abort ();
	s.a++;
	s.b++;
	y = 21;
	if (s.a != 28 \|\| s.b != 30 \|\| y != 21)
	abort ();
	}
	#pragma omp task private(y) firstprivate(s) allocate(h: s, y)
	{
	if (s.a != 27 \|\| s.b != 29)
	abort ();
	s.a++;
	s.b++;
	y = 21;
	if (s.a != 28 \|\| s.b != 30 \|\| y != 21)
	abort ();
	}
	}
	if (r != 64 * 63 / 2 \|\| l != 63 \|\| n != 8 + 16 * 64)
	abort ();
	if (l2[0] != 63 \|\| l2[1] != 63 + 1 \|\| l2[2] != 63 + 2 \|\| l2[3] != 63 + 3 \|\| l3 != 36)
	abort ();
	if (i2 != 5 \|\| j2 != 23 \|\| n2 != 9 + 6 * 17 \|\| l4 != 4 * 31 + 21)
	abort ();
	if (i3 != 5 \|\| j3 != 23 \|\| n3 != 10 + 6 * 17 \|\| l5 != 4 * 31 + 21)
	abort ();
	if (i4 != 5 \|\| j4 != 23 \|\| n4 != 11 + 6 * 17 \|\| l6 != 4 * 31 + 21)
	abort ();
	if (i5 != 19)
	abort ();
	}

	int
	main ()
	{
	omp_alloctrait_t traits[3]
	= { { omp_atk_alignment, 64 },
	{ omp_atk_fallback, omp_atv_null_fb } };
	omp_allocator_handle_t a
	= omp_init_allocator (omp_default_mem_space, 2, traits);
	int p[4], q[3];
	if (a == omp_null_allocator)
	abort ();
	omp_set_default_allocator (omp_default_mem_alloc);
	foo (42, p, q, 2, omp_null_allocator, 0);
	foo (42, p, q, 2, omp_default_mem_alloc, 0);
	foo (42, p, q, 2, a, 1);
	omp_set_default_allocator (a);
	foo (42, p, q, 2, omp_null_allocator, 3);
	foo (42, p, q, 2, omp_default_mem_alloc, 2);
	bar (42, a);
	omp_destroy_allocator (a);
	return 0;
	}