libitm/testsuite/libitm.c/priv-1.c - gcc - Git at Google

 /* Quick stress test for proxy privatization.  */

 /* We need to use a TM method that has to enforce privatization safety
    explicitly.  */
 /* { dg-set-target-env-var ITM_DEFAULT_METHOD "ml_wt" } */

 #include <stdlib.h>
 #include <stdio.h>
 #include <pthread.h>

 /* Make them likely to be mapped to different orecs.  */
 #define ALIGN __attribute__((aligned (256)))
 /* Don't make these static to work around PR 68591.  */
 int x ALIGN;
 int *ptr ALIGN;
 int *priv_ptr ALIGN;
 int priv_value ALIGN;
 int barrier ALIGN = 0;
 const int iters = 100;

 static void arrive_and_wait (int expected_value)
 {
   int now = __atomic_add_fetch (&barrier, 1, __ATOMIC_ACQ_REL);
   while (now < expected_value)
     __atomic_load (&barrier, &now, __ATOMIC_ACQUIRE);
 }

 static void __attribute__((transaction_pure,noinline)) delay (int i)
 {
   for (volatile int v = 0; v < i; v++);
 }

 /* This tries to catch a case in which proxy privatization safety is not
    ensured by privatization_user.  Specifically, it's access to the value
    of it's transactional snapshot of ptr must read from an uncommitted write
    by writer; thus, writer must still be active but must have read ptr before
    proxy can privatize *ptr by assigning to ptr.
    We try to make this interleaving more likely by delaying the commit of
    writer and the start of proxy.  */
 static void *writer (void *dummy __attribute__((unused)))
 {
   for (int i = 0; i < iters; i++)
     {
       /* Initialize state in each round.  */
       x = 0;
       ptr = &x;
       priv_ptr = NULL;
       int wrote = 1;
       arrive_and_wait (i * 6 + 3);
       /* Interference by another writer.  Has a conflict with the proxy
 	 privatizer.  */
       __transaction_atomic
 	{
 	  if (ptr != NULL)
 	    *ptr = 1;
 	  else
 	    wrote = 0;
 	  delay (2000000);
 	}
       arrive_and_wait (i * 6 + 6);
       /* If the previous transaction committed first, wrote == 1 and x == 1;
 	 otherwise, if the proxy came first, wrote == 0 and priv_value == 0.
        */
       if (wrote != priv_value)
 	abort ();
     }
   return NULL;
 }

 static void *proxy (void *dummy __attribute__((unused)))
 {
   for (int i = 0; i < iters; i++)
     {
       arrive_and_wait (i * 6 + 3);
       delay(1000000);
       __transaction_atomic
 	{
 	  /* Hand-off to privatization-user and its read-only transaction and
 	     subsequent use of privatization.  */
 	  priv_ptr = ptr;
 	  ptr = NULL;
 	}
       arrive_and_wait (i * 6 + 6);
     }
   return NULL;
 }

 static void *privatization_user (void *dummy __attribute__((unused)))
 {
   for (int i = 0; i < iters; i++)
     {
       arrive_and_wait (i * 6 + 3);
       /* Spin until we have gotten a pointer from the proxy.  Then access
 	 the value pointed to nontransactionally.  */
       int *p = NULL;
       while (p == NULL)
 	__transaction_atomic { p = priv_ptr; }
       priv_value = *p;
       arrive_and_wait (i * 6 + 6);
     }
   return NULL;
 }

 int main()
 {
   pthread_t p[3];

   pthread_create (p+0, NULL, writer, NULL);
   pthread_create (p+1, NULL, proxy, NULL);
   pthread_create (p+2, NULL, privatization_user, NULL);

   for (int i = 0; i < 3; ++i)
     pthread_join  (p[i], NULL);

   return 0;
 }
	/* Quick stress test for proxy privatization. */

	/* We need to use a TM method that has to enforce privatization safety
	explicitly. */
	/* { dg-set-target-env-var ITM_DEFAULT_METHOD "ml_wt" } */

	#include <stdlib.h>
	#include <stdio.h>
	#include <pthread.h>

	/* Make them likely to be mapped to different orecs. */
	#define ALIGN __attribute__((aligned (256)))
	/* Don't make these static to work around PR 68591. */
	int x ALIGN;
	int *ptr ALIGN;
	int *priv_ptr ALIGN;
	int priv_value ALIGN;
	int barrier ALIGN = 0;
	const int iters = 100;

	static void arrive_and_wait (int expected_value)
	{
	int now = __atomic_add_fetch (&barrier, 1, __ATOMIC_ACQ_REL);
	while (now < expected_value)
	__atomic_load (&barrier, &now, __ATOMIC_ACQUIRE);
	}

	static void __attribute__((transaction_pure,noinline)) delay (int i)
	{
	for (volatile int v = 0; v < i; v++);
	}

	/* This tries to catch a case in which proxy privatization safety is not
	ensured by privatization_user. Specifically, it's access to the value
	of it's transactional snapshot of ptr must read from an uncommitted write
	by writer; thus, writer must still be active but must have read ptr before
	proxy can privatize *ptr by assigning to ptr.
	We try to make this interleaving more likely by delaying the commit of
	writer and the start of proxy. */
	static void writer (void dummy __attribute__((unused)))
	{
	for (int i = 0; i < iters; i++)
	{
	/* Initialize state in each round. */
	x = 0;
	ptr = &x;
	priv_ptr = NULL;
	int wrote = 1;
	arrive_and_wait (i * 6 + 3);
	/* Interference by another writer. Has a conflict with the proxy
	privatizer. */
	__transaction_atomic
	{
	if (ptr != NULL)
	*ptr = 1;
	else
	wrote = 0;
	delay (2000000);
	}
	arrive_and_wait (i * 6 + 6);
	/* If the previous transaction committed first, wrote == 1 and x == 1;
	otherwise, if the proxy came first, wrote == 0 and priv_value == 0.
	*/
	if (wrote != priv_value)
	abort ();
	}
	return NULL;
	}

	static void proxy (void dummy __attribute__((unused)))
	{
	for (int i = 0; i < iters; i++)
	{
	arrive_and_wait (i * 6 + 3);
	delay(1000000);
	__transaction_atomic
	{
	/* Hand-off to privatization-user and its read-only transaction and
	subsequent use of privatization. */
	priv_ptr = ptr;
	ptr = NULL;
	}
	arrive_and_wait (i * 6 + 6);
	}
	return NULL;
	}

	static void privatization_user (void dummy __attribute__((unused)))
	{
	for (int i = 0; i < iters; i++)
	{
	arrive_and_wait (i * 6 + 3);
	/* Spin until we have gotten a pointer from the proxy. Then access
	the value pointed to nontransactionally. */
	int *p = NULL;
	while (p == NULL)
	__transaction_atomic { p = priv_ptr; }
	priv_value = *p;
	arrive_and_wait (i * 6 + 6);
	}
	return NULL;
	}

	int main()
	{
	pthread_t p[3];

	pthread_create (p+0, NULL, writer, NULL);
	pthread_create (p+1, NULL, proxy, NULL);
	pthread_create (p+2, NULL, privatization_user, NULL);

	for (int i = 0; i < 3; ++i)
	pthread_join (p[i], NULL);

	return 0;
	}