libgomp/testsuite/libgomp.oacc-c-c++-common/subset-subarray-mappings-1-r-p.c - gcc - Git at Google

 /* Test "subset" subarray mappings
    { dg-additional-options "-DOPENACC_RUNTIME" } using OpenACC Runtime Library routines,
    { dg-additional-options "-DPOINTERS" } using pointers.  */

 /* { dg-skip-if "" { *-*-* } { "-DACC_MEM_SHARED=1" } } */

 #if OPENACC_RUNTIME
 #elif OPENACC_DIRECTIVES
 #else
 # error
 #endif

 #if POINTERS
 #elif ARRAYS
 #else
 # error
 #endif


 #include <openacc.h>
 #include <acc_prof.h>
 #include <stdlib.h>
 #include <string.h>
 #include <assert.h>
 #include <stdint.h>
 #include <stdbool.h>


 static bool cb_ev_alloc_expected;
 static size_t cb_ev_alloc_bytes;
 static const void *cb_ev_alloc_device_ptr;
 static void
 cb_ev_alloc (acc_prof_info *prof_info, acc_event_info *event_info, acc_api_info *api_info)
 {
   assert (cb_ev_alloc_expected);
   cb_ev_alloc_expected = false;

   cb_ev_alloc_bytes = event_info->data_event.bytes;
   cb_ev_alloc_device_ptr = event_info->data_event.device_ptr;
 }

 static bool cb_ev_free_expected;
 static const void *cb_ev_free_device_ptr;
 static void
 cb_ev_free (acc_prof_info *prof_info, acc_event_info *event_info, acc_api_info *api_info)
 {
   assert (cb_ev_free_expected);
   cb_ev_free_expected = false;

   cb_ev_free_device_ptr = event_info->data_event.device_ptr;
 }


 /* Match the alignment processing that
    'libgomp/target.c:gomp_map_vars_internal' is doing; simplified, not
    considering special alignment requirements of certain data types.  */

 static size_t
 aligned_size (size_t tgt_size)
 {
   size_t tgt_align = sizeof (void *);
   return tgt_size + tgt_align - 1;
 }

 static const void *
 aligned_address (const void *tgt_start)
 {
   size_t tgt_align = sizeof (void *);
   return (void *) (((uintptr_t) tgt_start + tgt_align - 1) & ~(tgt_align - 1));
 }


 #define SIZE 1024
 #define SUBSET 32


 static void
 f1 (void)
 {
   cb_ev_alloc_expected = false;
   cb_ev_free_expected = false;
   acc_prof_register (acc_ev_alloc, cb_ev_alloc, acc_reg);
   acc_prof_register (acc_ev_free, cb_ev_free, acc_reg);

 #if POINTERS
   char* myblock = (char *) malloc (SIZE);
 #else
   char myblock[SIZE];
 #endif
   int i;
   void *dst;
   for (i = 0; i < SIZE; i++)
     myblock[i] = i;

   cb_ev_alloc_expected = true;
 #if OPENACC_RUNTIME
   dst = acc_copyin (myblock, SIZE);
 #else
 # if POINTERS
 #  pragma acc enter data copyin (myblock[0:SIZE])
 # else
 #  pragma acc enter data copyin (myblock)
 # endif
   dst = acc_deviceptr (myblock);
 #endif
   assert (dst);
   assert (!cb_ev_alloc_expected);
   assert (cb_ev_alloc_bytes == aligned_size (SIZE));
   assert (aligned_address (cb_ev_alloc_device_ptr) == dst);
   for (i = 0; i < SIZE; i += SUBSET)
     {
       void *partdst = acc_deviceptr (&myblock[i]);
       assert ((uintptr_t) partdst == (uintptr_t) dst + i);
       assert (acc_hostptr (partdst) == &myblock[i]);
     }
   for (i = 0; i < SIZE; i += SUBSET)
     {
       void *partdst;
 #if OPENACC_RUNTIME
       partdst = acc_pcopyin (&myblock[i], SUBSET);
 #else
 # pragma acc enter data pcopyin (myblock[i:SUBSET])
       partdst = acc_deviceptr (&myblock[i]);
 #endif
       assert ((uintptr_t) partdst == (uintptr_t) dst + i);
     }
   /* Dereference first half.  */
   for (i = 0; i < 512; i += SUBSET)
     {
       assert (acc_is_present (&myblock[i], SUBSET));
       assert (acc_is_present (myblock, SIZE));
 #if OPENACC_RUNTIME
       acc_delete (&myblock[i], SUBSET);
 #else
 # pragma acc exit data delete (myblock[i:SUBSET])
 #endif
       assert (acc_is_present (&myblock[i], SUBSET));
       assert (acc_is_present (myblock, SIZE));
     }
   /* Dereference all.  */
 #if OPENACC_RUNTIME
   acc_delete (myblock, SIZE);
 #else
 # if POINTERS
 #  pragma acc exit data delete (myblock[0:SIZE])
 # else
 #  pragma acc exit data delete (myblock)
 # endif
 #endif
   /* Expect it's still present.  */
   assert (acc_is_present (myblock, SIZE));
   /* Dereference second half.  */
   for (i = 512; i < SIZE; i += SUBSET)
     {
       bool last = i >= SIZE - SUBSET;

       assert (acc_is_present (&myblock[i], SUBSET));
       assert (acc_is_present (myblock, SIZE));
       if (last)
 	cb_ev_free_expected = true;
 #if OPENACC_RUNTIME
       acc_delete (&myblock[i], SUBSET);
 #else
 # pragma acc exit data delete (myblock[i:SUBSET])
 #endif
       assert (!cb_ev_free_expected);
       if (last)
 	assert (cb_ev_free_device_ptr == cb_ev_alloc_device_ptr);
       assert (acc_is_present (&myblock[i], SUBSET) != last);
       assert (acc_is_present (myblock, SIZE) != last);
     }
   /* Expect it's all gone now.  */
   for (i = 512; i < SIZE; i += SUBSET)
     assert (!acc_is_present (&myblock[i], SUBSET));
   assert (!acc_is_present (myblock, SIZE));
   assert (!acc_is_present (myblock, 1));

 #if POINTERS
   free (myblock);
 #endif

   acc_prof_unregister (acc_ev_alloc, cb_ev_alloc, acc_reg);
   acc_prof_unregister (acc_ev_free, cb_ev_free, acc_reg);
 }


 static void
 f2 (void)
 {
   cb_ev_alloc_expected = false;
   cb_ev_free_expected = false;
   acc_prof_register (acc_ev_alloc, cb_ev_alloc, acc_reg);
   acc_prof_register (acc_ev_free, cb_ev_free, acc_reg);

 #if POINTERS
   char *block1 = (char *) malloc (SIZE);
   char *block2 = (char *) malloc (SIZE);
   char *block3 = (char *) malloc (SIZE);
 #else
   char block1[SIZE];
   char block2[SIZE];
   char block3[SIZE];
 #endif
   int i;
   for (i = 0; i < SIZE; i++)
     block1[i] = block2[i] = block3[i] = i;

   cb_ev_alloc_expected = true;
 #if POINTERS
 # pragma acc data copyin(block1[0:SIZE], block2[0:SIZE], block3[0:SIZE])
 #else
 # pragma acc data copyin(block1, block2, block3)
 #endif
   {
     void *block1_d = acc_deviceptr (block1);
     void *block2_d = acc_deviceptr (block2);
     void *block3_d = acc_deviceptr (block3);
     assert (!cb_ev_alloc_expected);
     /* 'block1', 'block2', 'block3' get mapped in one device memory object, in
        reverse order.  */
     assert (cb_ev_alloc_bytes == aligned_size (3 * SIZE));
     assert ((void *) ((uintptr_t) aligned_address (cb_ev_alloc_device_ptr) + 2 * SIZE) == block1_d);
     assert ((void *) ((uintptr_t) aligned_address (cb_ev_alloc_device_ptr) + 1 * SIZE) == block2_d);
     assert ((void *) ((uintptr_t) aligned_address (cb_ev_alloc_device_ptr) + 0 * SIZE) == block3_d);

     for (i = 0; i < SIZE; i += SUBSET)
       {
 	void *block2_part_d;
 #if OPENACC_RUNTIME
 	block2_part_d = acc_pcopyin (&block2[i], SUBSET);
 #else
 # pragma acc enter data pcopyin (block2[i:SUBSET])
 	block2_part_d = acc_deviceptr (&block2[i]);
 #endif
 	assert ((uintptr_t) block2_part_d == (uintptr_t) block2_d + i);
       }
   }
   /* The mappings have been removed, but the device memory object has not yet
      been 'free'd.  */
   assert (!acc_is_present (block1, SIZE));
   assert (acc_is_present (block2, SIZE));
   assert (!acc_is_present (block3, SIZE));
   for (i = 0; i < SIZE; i += SUBSET)
     {
       bool last = i >= SIZE - SUBSET;

       assert (acc_is_present (block2, SIZE));
       if (last)
 	cb_ev_free_expected = true;
 #if OPENACC_RUNTIME
       acc_delete (&block2[i], SUBSET);
 #else
 # pragma acc exit data delete (block2[i:SUBSET])
 #endif
       assert (!cb_ev_free_expected);
       if (last)
 	assert (cb_ev_free_device_ptr == cb_ev_alloc_device_ptr);
     }
   assert (!acc_is_present (block1, SIZE));
   assert (!acc_is_present (block2, SIZE));
   assert (!acc_is_present (block3, SIZE));

 #if POINTERS
   free (block1);
   free (block2);
   free (block3);
 #endif

   acc_prof_unregister (acc_ev_alloc, cb_ev_alloc, acc_reg);
   acc_prof_unregister (acc_ev_free, cb_ev_free, acc_reg);
 }


 static void
 f3 ()
 {
   cb_ev_alloc_expected = false;
   cb_ev_free_expected = false;
   acc_prof_register (acc_ev_alloc, cb_ev_alloc, acc_reg);
   acc_prof_register (acc_ev_free, cb_ev_free, acc_reg);

 #if POINTERS
   char *h = (char *) malloc (SIZE);
 #else
   char h[SIZE];
 #endif

   char *d1;
   cb_ev_alloc_expected = true;
 #if OPENACC_RUNTIME
   d1 = (char *) acc_present_or_create (h, SIZE);
 #else
 # if POINTERS
 #  pragma acc enter data present_or_create (h[0:SIZE])
 # else
 #  pragma acc enter data present_or_create (h)
 # endif
   d1 = (char *) acc_deviceptr (h);
 #endif
   assert (d1);
   assert (!cb_ev_alloc_expected);
   assert (cb_ev_alloc_bytes == aligned_size (SIZE));
   assert (aligned_address (cb_ev_alloc_device_ptr) == d1);
   assert (acc_is_present (h, SIZE));
   assert (acc_is_present (&h[2], SIZE - 2));

   char *d2;
 #if OPENACC_RUNTIME
   d2 = (char *) acc_present_or_create (&h[2], SIZE - 2);
 #else
 # pragma acc enter data present_or_create (h[2:SIZE - 2])
   d2 = (char *) acc_deviceptr (&h[2]);
 #endif
   assert (d2);
   assert (d1 == d2 - 2);
   assert (acc_is_present (h, SIZE));
   assert (acc_is_present (&h[2], SIZE - 2));

   d2 = (char *) acc_deviceptr (&h[2]);
   assert (d1 == d2 - 2);

 #if OPENACC_RUNTIME
   acc_delete (&h[2], SIZE - 2);
 #else
 # pragma acc exit data delete (h[2:SIZE - 2])
 #endif
   assert (acc_is_present (h, SIZE));
   assert (acc_is_present (&h[2], SIZE - 2));

   cb_ev_free_expected = true;
 #if OPENACC_RUNTIME
   acc_delete (h, SIZE);
 #else
 # if POINTERS
 #  pragma acc exit data delete (h[0:SIZE])
 # else
 #  pragma acc exit data delete (h)
 # endif
 #endif
   assert (!cb_ev_free_expected);
   assert (cb_ev_free_device_ptr == cb_ev_alloc_device_ptr);

   assert (!acc_is_present (h, SIZE));
   assert (!acc_is_present (&h[2], SIZE - 2));
   assert (!acc_is_present (h, 1));

 # if POINTERS
   free (h);
 #endif

   acc_prof_unregister (acc_ev_alloc, cb_ev_alloc, acc_reg);
   acc_prof_unregister (acc_ev_free, cb_ev_free, acc_reg);
 }


 /* Based on what used to be 'libgomp.oacc-c-c++-common/lib-22.c'.  */

 static void
 f_lib_22 (void)
 {
   cb_ev_alloc_expected = false;
   cb_ev_free_expected = false;
   acc_prof_register (acc_ev_alloc, cb_ev_alloc, acc_reg);
   acc_prof_register (acc_ev_free, cb_ev_free, acc_reg);

   const int c0 = 0;
   const int c1 = 1;

 #if POINTERS
   char *h = (char *) malloc (SIZE);
 #else
   char h[SIZE];
 #endif

   memset (h, c0, SIZE);
   void *d;
   cb_ev_alloc_expected = true;
 #if OPENACC_RUNTIME
   d = acc_copyin (h, SIZE);
 #else
 # if POINTERS
 #  pragma acc enter data copyin (h[0:SIZE])
 # else
 #  pragma acc enter data copyin (h)
 # endif
   d = acc_deviceptr (h);
 #endif
   assert (d);
   assert (!cb_ev_alloc_expected);
   assert (cb_ev_alloc_bytes == aligned_size (SIZE));
   assert (aligned_address (cb_ev_alloc_device_ptr) == d);
   /* Overwrite the local memory.  */
   memset (h, c1, SIZE);
   /* Now 'copyout' not the whole but only a "subset" subarray, missing one
      SUBSET at the beginning, and half a SUBSET at the end...  */
   cb_ev_free_expected = true;
 #if OPENACC_RUNTIME
   acc_copyout (h + SUBSET, SIZE - SUBSET - SUBSET / 2);
 #else
 # pragma acc exit data copyout (h[SUBSET:SIZE - SUBSET - SUBSET / 2])
 #endif
   /* ..., yet, expect the device memory object to be 'free'd...  */
   assert (!cb_ev_free_expected);
   assert (cb_ev_free_device_ptr == cb_ev_alloc_device_ptr);
   /* ..., and the mapping to be removed...  */
   assert (!acc_is_present (h, SIZE));
   assert (!acc_is_present (&h[SUBSET], SIZE - SUBSET - SUBSET / 2));
   assert (!acc_is_present (h, 1));
   /* ..., but the 'copyout'ed device memory to correspond to just the "subset"
      subarray.  */
   for (size_t i = 0; i < SIZE; ++i)
     {
       if (i < SUBSET)
 	assert (h[i] == c1);
       else if (i < SIZE - SUBSET / 2)
 	assert (h[i] == c0);
       else if (i < SIZE)
 	assert (h[i] == c1);
     }

 #if POINTERS
   free (h);
 #endif

   acc_prof_unregister (acc_ev_alloc, cb_ev_alloc, acc_reg);
   acc_prof_unregister (acc_ev_free, cb_ev_free, acc_reg);
 }


 /* Based on what used to be 'libgomp.oacc-c-c++-common/lib-30.c'.  */

 static void
 f_lib_30 (void)
 {
   cb_ev_alloc_expected = false;
   cb_ev_free_expected = false;
   acc_prof_register (acc_ev_alloc, cb_ev_alloc, acc_reg);
   acc_prof_register (acc_ev_free, cb_ev_free, acc_reg);

 #if POINTERS
   char *h = (char *) malloc (SIZE);
 #else
   char h[SIZE];
 #endif
   memset (h, 0, SIZE);

   void *d;
   cb_ev_alloc_expected = true;
 #if OPENACC_RUNTIME
   d = acc_create (h, SIZE);
 #else
 # if POINTERS
 #  pragma acc enter data create (h[0:SIZE])
 # else
 #  pragma acc enter data create (h)
 # endif
   d = acc_deviceptr (h);
 #endif
   assert (d);
   assert (!cb_ev_alloc_expected);
   assert (cb_ev_alloc_bytes == aligned_size (SIZE));
   assert (aligned_address (cb_ev_alloc_device_ptr) == d);

   /* We 'delete' not the whole but only a "subset" subarray...  */
   cb_ev_free_expected = true;
 #if OPENACC_RUNTIME
   acc_delete (h, SIZE - SUBSET);
 #else
 # pragma acc exit data delete (h[0:SIZE - SUBSET])
 #endif
   /* ..., yet, expect the device memory object to be 'free'd...  */
   assert (!cb_ev_free_expected);
   assert (cb_ev_free_device_ptr == cb_ev_alloc_device_ptr);
   /* ..., and the mapping to be removed.  */
   assert (!acc_is_present (h, SIZE));
   assert (!acc_is_present (h, SIZE - SUBSET));
   assert (!acc_is_present (h, 1));

 #if POINTERS
   free (h);
 #endif

   acc_prof_unregister (acc_ev_alloc, cb_ev_alloc, acc_reg);
   acc_prof_unregister (acc_ev_free, cb_ev_free, acc_reg);
 }


 int
 main ()
 {
   f1 ();
   f2 ();
   f3 ();
   f_lib_22 ();
   f_lib_30 ();

   return 0;
 }
	/* Test "subset" subarray mappings
	{ dg-additional-options "-DOPENACC_RUNTIME" } using OpenACC Runtime Library routines,
	{ dg-additional-options "-DPOINTERS" } using pointers. */

	/* { dg-skip-if "" { --* } { "-DACC_MEM_SHARED=1" } } */

	#if OPENACC_RUNTIME
	#elif OPENACC_DIRECTIVES
	#else
	# error
	#endif

	#if POINTERS
	#elif ARRAYS
	#else
	# error
	#endif


	#include <openacc.h>
	#include <acc_prof.h>
	#include <stdlib.h>
	#include <string.h>
	#include <assert.h>
	#include <stdint.h>
	#include <stdbool.h>


	static bool cb_ev_alloc_expected;
	static size_t cb_ev_alloc_bytes;
	static const void *cb_ev_alloc_device_ptr;
	static void
	cb_ev_alloc (acc_prof_info prof_info, acc_event_info event_info, acc_api_info *api_info)
	{
	assert (cb_ev_alloc_expected);
	cb_ev_alloc_expected = false;

	cb_ev_alloc_bytes = event_info->data_event.bytes;
	cb_ev_alloc_device_ptr = event_info->data_event.device_ptr;
	}

	static bool cb_ev_free_expected;
	static const void *cb_ev_free_device_ptr;
	static void
	cb_ev_free (acc_prof_info prof_info, acc_event_info event_info, acc_api_info *api_info)
	{
	assert (cb_ev_free_expected);
	cb_ev_free_expected = false;

	cb_ev_free_device_ptr = event_info->data_event.device_ptr;
	}


	/* Match the alignment processing that
	'libgomp/target.c:gomp_map_vars_internal' is doing; simplified, not
	considering special alignment requirements of certain data types. */

	static size_t
	aligned_size (size_t tgt_size)
	{
	size_t tgt_align = sizeof (void *);
	return tgt_size + tgt_align - 1;
	}

	static const void *
	aligned_address (const void *tgt_start)
	{
	size_t tgt_align = sizeof (void *);
	return (void *) (((uintptr_t) tgt_start + tgt_align - 1) & ~(tgt_align - 1));
	}


	#define SIZE 1024
	#define SUBSET 32


	static void
	f1 (void)
	{
	cb_ev_alloc_expected = false;
	cb_ev_free_expected = false;
	acc_prof_register (acc_ev_alloc, cb_ev_alloc, acc_reg);
	acc_prof_register (acc_ev_free, cb_ev_free, acc_reg);

	#if POINTERS
	char* myblock = (char *) malloc (SIZE);
	#else
	char myblock[SIZE];
	#endif
	int i;
	void *dst;
	for (i = 0; i < SIZE; i++)
	myblock[i] = i;

	cb_ev_alloc_expected = true;
	#if OPENACC_RUNTIME
	dst = acc_copyin (myblock, SIZE);
	#else
	# if POINTERS
	# pragma acc enter data copyin (myblock[0:SIZE])
	# else
	# pragma acc enter data copyin (myblock)
	# endif
	dst = acc_deviceptr (myblock);
	#endif
	assert (dst);
	assert (!cb_ev_alloc_expected);
	assert (cb_ev_alloc_bytes == aligned_size (SIZE));
	assert (aligned_address (cb_ev_alloc_device_ptr) == dst);
	for (i = 0; i < SIZE; i += SUBSET)
	{
	void *partdst = acc_deviceptr (&myblock[i]);
	assert ((uintptr_t) partdst == (uintptr_t) dst + i);
	assert (acc_hostptr (partdst) == &myblock[i]);
	}
	for (i = 0; i < SIZE; i += SUBSET)
	{
	void *partdst;
	#if OPENACC_RUNTIME
	partdst = acc_pcopyin (&myblock[i], SUBSET);
	#else
	# pragma acc enter data pcopyin (myblock[i:SUBSET])
	partdst = acc_deviceptr (&myblock[i]);
	#endif
	assert ((uintptr_t) partdst == (uintptr_t) dst + i);
	}
	/* Dereference first half. */
	for (i = 0; i < 512; i += SUBSET)
	{
	assert (acc_is_present (&myblock[i], SUBSET));
	assert (acc_is_present (myblock, SIZE));
	#if OPENACC_RUNTIME
	acc_delete (&myblock[i], SUBSET);
	#else
	# pragma acc exit data delete (myblock[i:SUBSET])
	#endif
	assert (acc_is_present (&myblock[i], SUBSET));
	assert (acc_is_present (myblock, SIZE));
	}
	/* Dereference all. */
	#if OPENACC_RUNTIME
	acc_delete (myblock, SIZE);
	#else
	# if POINTERS
	# pragma acc exit data delete (myblock[0:SIZE])
	# else
	# pragma acc exit data delete (myblock)
	# endif
	#endif
	/* Expect it's still present. */
	assert (acc_is_present (myblock, SIZE));
	/* Dereference second half. */
	for (i = 512; i < SIZE; i += SUBSET)
	{
	bool last = i >= SIZE - SUBSET;

	assert (acc_is_present (&myblock[i], SUBSET));
	assert (acc_is_present (myblock, SIZE));
	if (last)
	cb_ev_free_expected = true;
	#if OPENACC_RUNTIME
	acc_delete (&myblock[i], SUBSET);
	#else
	# pragma acc exit data delete (myblock[i:SUBSET])
	#endif
	assert (!cb_ev_free_expected);
	if (last)
	assert (cb_ev_free_device_ptr == cb_ev_alloc_device_ptr);
	assert (acc_is_present (&myblock[i], SUBSET) != last);
	assert (acc_is_present (myblock, SIZE) != last);
	}
	/* Expect it's all gone now. */
	for (i = 512; i < SIZE; i += SUBSET)
	assert (!acc_is_present (&myblock[i], SUBSET));
	assert (!acc_is_present (myblock, SIZE));
	assert (!acc_is_present (myblock, 1));

	#if POINTERS
	free (myblock);
	#endif

	acc_prof_unregister (acc_ev_alloc, cb_ev_alloc, acc_reg);
	acc_prof_unregister (acc_ev_free, cb_ev_free, acc_reg);
	}


	static void
	f2 (void)
	{
	cb_ev_alloc_expected = false;
	cb_ev_free_expected = false;
	acc_prof_register (acc_ev_alloc, cb_ev_alloc, acc_reg);
	acc_prof_register (acc_ev_free, cb_ev_free, acc_reg);

	#if POINTERS
	char block1 = (char ) malloc (SIZE);
	char block2 = (char ) malloc (SIZE);
	char block3 = (char ) malloc (SIZE);
	#else
	char block1[SIZE];
	char block2[SIZE];
	char block3[SIZE];
	#endif
	int i;
	for (i = 0; i < SIZE; i++)
	block1[i] = block2[i] = block3[i] = i;

	cb_ev_alloc_expected = true;
	#if POINTERS
	# pragma acc data copyin(block1[0:SIZE], block2[0:SIZE], block3[0:SIZE])
	#else
	# pragma acc data copyin(block1, block2, block3)
	#endif
	{
	void *block1_d = acc_deviceptr (block1);
	void *block2_d = acc_deviceptr (block2);
	void *block3_d = acc_deviceptr (block3);
	assert (!cb_ev_alloc_expected);
	/* 'block1', 'block2', 'block3' get mapped in one device memory object, in
	reverse order. */
	assert (cb_ev_alloc_bytes == aligned_size (3 * SIZE));
	assert ((void ) ((uintptr_t) aligned_address (cb_ev_alloc_device_ptr) + 2 SIZE) == block1_d);
	assert ((void ) ((uintptr_t) aligned_address (cb_ev_alloc_device_ptr) + 1 SIZE) == block2_d);
	assert ((void ) ((uintptr_t) aligned_address (cb_ev_alloc_device_ptr) + 0 SIZE) == block3_d);

	for (i = 0; i < SIZE; i += SUBSET)
	{
	void *block2_part_d;
	#if OPENACC_RUNTIME
	block2_part_d = acc_pcopyin (&block2[i], SUBSET);
	#else
	# pragma acc enter data pcopyin (block2[i:SUBSET])
	block2_part_d = acc_deviceptr (&block2[i]);
	#endif
	assert ((uintptr_t) block2_part_d == (uintptr_t) block2_d + i);
	}
	}
	/* The mappings have been removed, but the device memory object has not yet
	been 'free'd. */
	assert (!acc_is_present (block1, SIZE));
	assert (acc_is_present (block2, SIZE));
	assert (!acc_is_present (block3, SIZE));
	for (i = 0; i < SIZE; i += SUBSET)
	{
	bool last = i >= SIZE - SUBSET;

	assert (acc_is_present (block2, SIZE));
	if (last)
	cb_ev_free_expected = true;
	#if OPENACC_RUNTIME
	acc_delete (&block2[i], SUBSET);
	#else
	# pragma acc exit data delete (block2[i:SUBSET])
	#endif
	assert (!cb_ev_free_expected);
	if (last)
	assert (cb_ev_free_device_ptr == cb_ev_alloc_device_ptr);
	}
	assert (!acc_is_present (block1, SIZE));
	assert (!acc_is_present (block2, SIZE));
	assert (!acc_is_present (block3, SIZE));

	#if POINTERS
	free (block1);
	free (block2);
	free (block3);
	#endif

	acc_prof_unregister (acc_ev_alloc, cb_ev_alloc, acc_reg);
	acc_prof_unregister (acc_ev_free, cb_ev_free, acc_reg);
	}


	static void
	f3 ()
	{
	cb_ev_alloc_expected = false;
	cb_ev_free_expected = false;
	acc_prof_register (acc_ev_alloc, cb_ev_alloc, acc_reg);
	acc_prof_register (acc_ev_free, cb_ev_free, acc_reg);

	#if POINTERS
	char h = (char ) malloc (SIZE);
	#else
	char h[SIZE];
	#endif

	char *d1;
	cb_ev_alloc_expected = true;
	#if OPENACC_RUNTIME
	d1 = (char *) acc_present_or_create (h, SIZE);
	#else
	# if POINTERS
	# pragma acc enter data present_or_create (h[0:SIZE])
	# else
	# pragma acc enter data present_or_create (h)
	# endif
	d1 = (char *) acc_deviceptr (h);
	#endif
	assert (d1);
	assert (!cb_ev_alloc_expected);
	assert (cb_ev_alloc_bytes == aligned_size (SIZE));
	assert (aligned_address (cb_ev_alloc_device_ptr) == d1);
	assert (acc_is_present (h, SIZE));
	assert (acc_is_present (&h[2], SIZE - 2));

	char *d2;
	#if OPENACC_RUNTIME
	d2 = (char *) acc_present_or_create (&h[2], SIZE - 2);
	#else
	# pragma acc enter data present_or_create (h[2:SIZE - 2])
	d2 = (char *) acc_deviceptr (&h[2]);
	#endif
	assert (d2);
	assert (d1 == d2 - 2);
	assert (acc_is_present (h, SIZE));
	assert (acc_is_present (&h[2], SIZE - 2));

	d2 = (char *) acc_deviceptr (&h[2]);
	assert (d1 == d2 - 2);

	#if OPENACC_RUNTIME
	acc_delete (&h[2], SIZE - 2);
	#else
	# pragma acc exit data delete (h[2:SIZE - 2])
	#endif
	assert (acc_is_present (h, SIZE));
	assert (acc_is_present (&h[2], SIZE - 2));

	cb_ev_free_expected = true;
	#if OPENACC_RUNTIME
	acc_delete (h, SIZE);
	#else
	# if POINTERS
	# pragma acc exit data delete (h[0:SIZE])
	# else
	# pragma acc exit data delete (h)
	# endif
	#endif
	assert (!cb_ev_free_expected);
	assert (cb_ev_free_device_ptr == cb_ev_alloc_device_ptr);

	assert (!acc_is_present (h, SIZE));
	assert (!acc_is_present (&h[2], SIZE - 2));
	assert (!acc_is_present (h, 1));

	# if POINTERS
	free (h);
	#endif

	acc_prof_unregister (acc_ev_alloc, cb_ev_alloc, acc_reg);
	acc_prof_unregister (acc_ev_free, cb_ev_free, acc_reg);
	}


	/* Based on what used to be 'libgomp.oacc-c-c++-common/lib-22.c'. */

	static void
	f_lib_22 (void)
	{
	cb_ev_alloc_expected = false;
	cb_ev_free_expected = false;
	acc_prof_register (acc_ev_alloc, cb_ev_alloc, acc_reg);
	acc_prof_register (acc_ev_free, cb_ev_free, acc_reg);

	const int c0 = 0;
	const int c1 = 1;

	#if POINTERS
	char h = (char ) malloc (SIZE);
	#else
	char h[SIZE];
	#endif

	memset (h, c0, SIZE);
	void *d;
	cb_ev_alloc_expected = true;
	#if OPENACC_RUNTIME
	d = acc_copyin (h, SIZE);
	#else
	# if POINTERS
	# pragma acc enter data copyin (h[0:SIZE])
	# else
	# pragma acc enter data copyin (h)
	# endif
	d = acc_deviceptr (h);
	#endif
	assert (d);
	assert (!cb_ev_alloc_expected);
	assert (cb_ev_alloc_bytes == aligned_size (SIZE));
	assert (aligned_address (cb_ev_alloc_device_ptr) == d);
	/* Overwrite the local memory. */
	memset (h, c1, SIZE);
	/* Now 'copyout' not the whole but only a "subset" subarray, missing one
	SUBSET at the beginning, and half a SUBSET at the end... */
	cb_ev_free_expected = true;
	#if OPENACC_RUNTIME
	acc_copyout (h + SUBSET, SIZE - SUBSET - SUBSET / 2);
	#else
	# pragma acc exit data copyout (h[SUBSET:SIZE - SUBSET - SUBSET / 2])
	#endif
	/* ..., yet, expect the device memory object to be 'free'd... */
	assert (!cb_ev_free_expected);
	assert (cb_ev_free_device_ptr == cb_ev_alloc_device_ptr);
	/* ..., and the mapping to be removed... */
	assert (!acc_is_present (h, SIZE));
	assert (!acc_is_present (&h[SUBSET], SIZE - SUBSET - SUBSET / 2));
	assert (!acc_is_present (h, 1));
	/* ..., but the 'copyout'ed device memory to correspond to just the "subset"
	subarray. */
	for (size_t i = 0; i < SIZE; ++i)
	{
	if (i < SUBSET)
	assert (h[i] == c1);
	else if (i < SIZE - SUBSET / 2)
	assert (h[i] == c0);
	else if (i < SIZE)
	assert (h[i] == c1);
	}

	#if POINTERS
	free (h);
	#endif

	acc_prof_unregister (acc_ev_alloc, cb_ev_alloc, acc_reg);
	acc_prof_unregister (acc_ev_free, cb_ev_free, acc_reg);
	}


	/* Based on what used to be 'libgomp.oacc-c-c++-common/lib-30.c'. */

	static void
	f_lib_30 (void)
	{
	cb_ev_alloc_expected = false;
	cb_ev_free_expected = false;
	acc_prof_register (acc_ev_alloc, cb_ev_alloc, acc_reg);
	acc_prof_register (acc_ev_free, cb_ev_free, acc_reg);

	#if POINTERS
	char h = (char ) malloc (SIZE);
	#else
	char h[SIZE];
	#endif
	memset (h, 0, SIZE);

	void *d;
	cb_ev_alloc_expected = true;
	#if OPENACC_RUNTIME
	d = acc_create (h, SIZE);
	#else
	# if POINTERS
	# pragma acc enter data create (h[0:SIZE])
	# else
	# pragma acc enter data create (h)
	# endif
	d = acc_deviceptr (h);
	#endif
	assert (d);
	assert (!cb_ev_alloc_expected);
	assert (cb_ev_alloc_bytes == aligned_size (SIZE));
	assert (aligned_address (cb_ev_alloc_device_ptr) == d);

	/* We 'delete' not the whole but only a "subset" subarray... */
	cb_ev_free_expected = true;
	#if OPENACC_RUNTIME
	acc_delete (h, SIZE - SUBSET);
	#else
	# pragma acc exit data delete (h[0:SIZE - SUBSET])
	#endif
	/* ..., yet, expect the device memory object to be 'free'd... */
	assert (!cb_ev_free_expected);
	assert (cb_ev_free_device_ptr == cb_ev_alloc_device_ptr);
	/* ..., and the mapping to be removed. */
	assert (!acc_is_present (h, SIZE));
	assert (!acc_is_present (h, SIZE - SUBSET));
	assert (!acc_is_present (h, 1));

	#if POINTERS
	free (h);
	#endif

	acc_prof_unregister (acc_ev_alloc, cb_ev_alloc, acc_reg);
	acc_prof_unregister (acc_ev_free, cb_ev_free, acc_reg);
	}


	int
	main ()
	{
	f1 ();
	f2 ();
	f3 ();
	f_lib_22 ();
	f_lib_30 ();

	return 0;
	}