gdb/testsuite/gdb.base/watchpoint.c - binutils-gdb - Git at Google

 #include <stdio.h>
 #include <unistd.h>
 /*
  *	Since using watchpoints can be very slow, we have to take some pains to
  *	ensure that we don't run too long with them enabled or we run the risk
  *	of having the test timeout.  To help avoid this, we insert some marker
  *	functions in the execution stream so we can set breakpoints at known
  *	locations, without worrying about invalidating line numbers by changing
  *	this file.  We use null bodied functions are markers since gdb does
  *	not support breakpoints at labeled text points at this time.
  *
  *	One place we need is a marker for when we start executing our tests
  *	instructions rather than any process startup code, so we insert one
  *	right after entering main().  Another is right before we finish, before
  *	we start executing any process termination code.
  *
  *	Another problem we have to guard against, at least for the test
  *	suite, is that we need to ensure that the line that causes the
  *	watchpoint to be hit is still the current line when gdb notices
  *	the hit.  Depending upon the specific code generated by the compiler,
  *	the instruction after the one that triggers the hit may be part of
  *	the same line or part of the next line.  Thus we ensure that there
  *	are always some instructions to execute on the same line after the
  *	code that should trigger the hit.
  */

 int count = -1;
 int ival1 = -1;
 int ival2 = -1;
 int ival3 = -1;
 int ival4 = -1;
 int ival5 = -1;
 char buf[31] = "testtesttesttesttesttesttestte";
 struct foo
 {
   int val;
 };
 struct foo struct1, struct2, *ptr1, *ptr2;

 int doread = 0;

 char *global_ptr;
 char **global_ptr_ptr;

 struct foo2
 {
   int val[2];
 };
 struct foo2 foo2;

 struct foo4
 {
   int val[4];
 };
 struct foo4 foo4;

 struct foo5
 {
   struct { int x; } *p;
 };

 struct foo5 *null_ptr;

 void marker1 ()
 {
 }

 void marker2 ()
 {
 }

 void marker4 ()
 {
 }

 void marker5 ()
 {
 }

 void marker6 ()
 {
 }

 void recurser (int  x)
 {
   int  local_x = 0;

   if (x > 0)
     recurser (x-1);
   local_x = x;
 }

 void
 func2 ()
 {
   int  local_a = 0;
   static int  static_b;

   /* func2 breakpoint here */
   ival5++;
   local_a = ival5;
   static_b = local_a;
 }

 void
 func3 ()
 {
   int x;
   int y;

   x = 0;
   x = 1;				/* second x assignment */
   y = 1;
   y = 2;
   buf[26] = 3;
 }

 int
 func1 ()
 {
   /* The point of this is that we will set a breakpoint at this call.

      Then, if DECR_PC_AFTER_BREAK equals the size of a function call
      instruction (true on a sun3 if this is gcc-compiled--FIXME we
      should use asm() to make it work for any compiler, present or
      future), then we will end up branching to the location just after
      the breakpoint.  And we better not confuse that with hitting the
      breakpoint.  */
   func2 ();
   return 73;
 }

 void
 func4 ()
 {
   buf[0] = 3;
   global_ptr = buf;
   buf[0] = 7;
   buf[1] = 5;
   global_ptr_ptr = &global_ptr;
   buf[0] = 9;
   global_ptr++;
 }

 void
 func5 ()
 {
   int val = 0, val2 = 23;
   int *x = &val;

   /* func5 breakpoint here */
   x = &val2;
   val = 27;
 }

 void
 func6 (void)
 {
   /* func6 breakpoint here */
   foo2.val[1] = 0;
   foo2.val[1] = 11;
 }

 void
 func7 (void)
 {
   /* func7 breakpoint here */
   foo4.val[3] = 0;
   foo4.val[3] = 33;
 }

 int main ()
 {
   struct1.val = 1;
   struct2.val = 2;
   ptr1 = &struct1;
   ptr2 = &struct2;
   marker1 ();
   func1 ();
   for (count = 0; count < 4; count++) {
     ival1 = count;
     ival3 = count; ival4 = count;
   }
   ival1 = count; /* Outside loop */
   ival2 = count;
   ival3 = count; ival4 = count;
   marker2 ();
   if (doread)
     {
       static char msg[] = "type stuff for buf now:";
       write (1, msg, sizeof (msg) - 1);
       read (0, &buf[0], 5);
     }
   marker4 ();

   /* We have a watchpoint on ptr1->val.  It should be triggered if
      ptr1's value changes.  */
   ptr1 = ptr2;

   /* This should not trigger the watchpoint.  If it does, then we
      used the wrong value chain to re-insert the watchpoints or we
      are not evaluating the watchpoint expression correctly.  */
   struct1.val = 5;
   marker5 ();

   /* We have a watchpoint on ptr1->val.  It should be triggered if
      ptr1's value changes.  */
   ptr1 = ptr2;

   /* This should not trigger the watchpoint.  If it does, then we
      used the wrong value chain to re-insert the watchpoints or we
      are not evaluating the watchpoint expression correctly.  */
   struct1.val = 5;
   marker5 ();

   /* We're going to watch locals of func2, to see that out-of-scope
      watchpoints are detected and properly deleted.
      */
   marker6 ();

   /* This invocation is used for watches of a single
      local variable. */
   func2 ();

   /* This invocation is used for watches of an expression
      involving a local variable. */
   func2 ();

   /* This invocation is used for watches of a static
      (non-stack-based) local variable. */
   func2 ();

   /* This invocation is used for watches of a local variable
      when recursion happens.
      */
   marker6 ();
   recurser (2);

   /* This invocation is used for watches of a local variable with explicitly
      specified scope when recursion happens.
      */
   marker6 ();
   recurser (2);

   marker6 ();

   func3 ();

   func4 ();

   func5 ();

   func6 ();

   func7 ();

   return 0;
 }
	#include <stdio.h>
	#include <unistd.h>
	/*
	* Since using watchpoints can be very slow, we have to take some pains to
	* ensure that we don't run too long with them enabled or we run the risk
	* of having the test timeout. To help avoid this, we insert some marker
	* functions in the execution stream so we can set breakpoints at known
	* locations, without worrying about invalidating line numbers by changing
	* this file. We use null bodied functions are markers since gdb does
	* not support breakpoints at labeled text points at this time.
	*
	* One place we need is a marker for when we start executing our tests
	* instructions rather than any process startup code, so we insert one
	* right after entering main(). Another is right before we finish, before
	* we start executing any process termination code.
	*
	* Another problem we have to guard against, at least for the test
	* suite, is that we need to ensure that the line that causes the
	* watchpoint to be hit is still the current line when gdb notices
	* the hit. Depending upon the specific code generated by the compiler,
	* the instruction after the one that triggers the hit may be part of
	* the same line or part of the next line. Thus we ensure that there
	* are always some instructions to execute on the same line after the
	* code that should trigger the hit.
	*/

	int count = -1;
	int ival1 = -1;
	int ival2 = -1;
	int ival3 = -1;
	int ival4 = -1;
	int ival5 = -1;
	char buf[31] = "testtesttesttesttesttesttestte";
	struct foo
	{
	int val;
	};
	struct foo struct1, struct2, ptr1, ptr2;

	int doread = 0;

	char *global_ptr;
	char **global_ptr_ptr;

	struct foo2
	{
	int val[2];
	};
	struct foo2 foo2;

	struct foo4
	{
	int val[4];
	};
	struct foo4 foo4;

	struct foo5
	{
	struct { int x; } *p;
	};

	struct foo5 *null_ptr;

	void marker1 ()
	{
	}

	void marker2 ()
	{
	}

	void marker4 ()
	{
	}

	void marker5 ()
	{
	}

	void marker6 ()
	{
	}

	void recurser (int x)
	{
	int local_x = 0;

	if (x > 0)
	recurser (x-1);
	local_x = x;
	}

	void
	func2 ()
	{
	int local_a = 0;
	static int static_b;

	/* func2 breakpoint here */
	ival5++;
	local_a = ival5;
	static_b = local_a;
	}

	void
	func3 ()
	{
	int x;
	int y;

	x = 0;
	x = 1; /* second x assignment */
	y = 1;
	y = 2;
	buf[26] = 3;
	}

	int
	func1 ()
	{
	/* The point of this is that we will set a breakpoint at this call.

	Then, if DECR_PC_AFTER_BREAK equals the size of a function call
	instruction (true on a sun3 if this is gcc-compiled--FIXME we
	should use asm() to make it work for any compiler, present or
	future), then we will end up branching to the location just after
	the breakpoint. And we better not confuse that with hitting the
	breakpoint. */
	func2 ();
	return 73;
	}

	void
	func4 ()
	{
	buf[0] = 3;
	global_ptr = buf;
	buf[0] = 7;
	buf[1] = 5;
	global_ptr_ptr = &global_ptr;
	buf[0] = 9;
	global_ptr++;
	}

	void
	func5 ()
	{
	int val = 0, val2 = 23;
	int *x = &val;

	/* func5 breakpoint here */
	x = &val2;
	val = 27;
	}

	void
	func6 (void)
	{
	/* func6 breakpoint here */
	foo2.val[1] = 0;
	foo2.val[1] = 11;
	}

	void
	func7 (void)
	{
	/* func7 breakpoint here */
	foo4.val[3] = 0;
	foo4.val[3] = 33;
	}

	int main ()
	{
	struct1.val = 1;
	struct2.val = 2;
	ptr1 = &struct1;
	ptr2 = &struct2;
	marker1 ();
	func1 ();
	for (count = 0; count < 4; count++) {
	ival1 = count;
	ival3 = count; ival4 = count;
	}
	ival1 = count; /* Outside loop */
	ival2 = count;
	ival3 = count; ival4 = count;
	marker2 ();
	if (doread)
	{
	static char msg[] = "type stuff for buf now:";
	write (1, msg, sizeof (msg) - 1);
	read (0, &buf[0], 5);
	}
	marker4 ();

	/* We have a watchpoint on ptr1->val. It should be triggered if
	ptr1's value changes. */
	ptr1 = ptr2;

	/* This should not trigger the watchpoint. If it does, then we
	used the wrong value chain to re-insert the watchpoints or we
	are not evaluating the watchpoint expression correctly. */
	struct1.val = 5;
	marker5 ();

	/* We have a watchpoint on ptr1->val. It should be triggered if
	ptr1's value changes. */
	ptr1 = ptr2;

	/* This should not trigger the watchpoint. If it does, then we
	used the wrong value chain to re-insert the watchpoints or we
	are not evaluating the watchpoint expression correctly. */
	struct1.val = 5;
	marker5 ();

	/* We're going to watch locals of func2, to see that out-of-scope
	watchpoints are detected and properly deleted.
	*/
	marker6 ();

	/* This invocation is used for watches of a single
	local variable. */
	func2 ();

	/* This invocation is used for watches of an expression
	involving a local variable. */
	func2 ();

	/* This invocation is used for watches of a static
	(non-stack-based) local variable. */
	func2 ();

	/* This invocation is used for watches of a local variable
	when recursion happens.
	*/
	marker6 ();
	recurser (2);

	/* This invocation is used for watches of a local variable with explicitly
	specified scope when recursion happens.
	*/
	marker6 ();
	recurser (2);

	marker6 ();

	func3 ();

	func4 ();

	func5 ();

	func6 ();

	func7 ();

	return 0;
	}