src/backend/storage/ipc/pmsignal.c - hawq - Git at Google

 /*-------------------------------------------------------------------------
  *
  * pmsignal.c
  *	  routines for signaling the postmaster from its child processes
  *
  *
  * Portions Copyright (c) 1996-2009, PostgreSQL Global Development Group
  * Portions Copyright (c) 1994, Regents of the University of California
  *
  * IDENTIFICATION
  *	  $PostgreSQL: pgsql/src/backend/storage/ipc/pmsignal.c,v 1.28 2009/06/11 14:49:01 momjian Exp $
  *
  *-------------------------------------------------------------------------
  */
 #include "postgres.h"

 #include <signal.h>
 #include <unistd.h>

 #include "miscadmin.h"
 #include "postmaster/postmaster.h"
 #include "storage/pmsignal.h"
 #include "storage/shmem.h"


 /*
  * The postmaster is signaled by its children by sending SIGUSR1.  The
  * specific reason is communicated via flags in shared memory.	We keep
  * a boolean flag for each possible "reason", so that different reasons
  * can be signaled by different backends at the same time.	(However,
  * if the same reason is signaled more than once simultaneously, the
  * postmaster will observe it only once.)
  *
  * The flags are actually declared as "volatile sig_atomic_t" for maximum
  * portability.  This should ensure that loads and stores of the flag
  * values are atomic, allowing us to dispense with any explicit locking.
  *
  * In addition to the per-reason flags, we store a set of per-child-process
  * flags that are currently used only for detecting whether a backend has
  * exited without performing proper shutdown.  The per-child-process flags
  * have three possible states: UNUSED, ASSIGNED, ACTIVE.  An UNUSED slot is
  * available for assignment.  An ASSIGNED slot is associated with a postmaster
  * child process, but either the process has not touched shared memory yet,
  * or it has successfully cleaned up after itself.	A ACTIVE slot means the
  * process is actively using shared memory.  The slots are assigned to
  * child processes at random, and postmaster.c is responsible for tracking
  * which one goes with which PID.
  */

 #define PM_CHILD_UNUSED		0	/* these values must fit in sig_atomic_t */
 #define PM_CHILD_ASSIGNED	1
 #define PM_CHILD_ACTIVE		2

 /* "typedef struct PMSignalData PMSignalData" appears in pmsignal.h */
 struct PMSignalData
 {
 	/* per-reason flags */
 	sig_atomic_t PMSignalFlags[NUM_PMSIGNALS];
 	/* per-child-process flags */
 	int			num_child_flags;	/* # of entries in PMChildFlags[] */
 	int			next_child_flag;	/* next slot to try to assign */
 	sig_atomic_t PMChildFlags[1];		/* VARIABLE LENGTH ARRAY */
 };

 NON_EXEC_STATIC volatile PMSignalData *PMSignalState = NULL;


 /*
  * PMSignalShmemSize
  *		Compute space needed for pmsignal.c's shared memory
  */
 Size
 PMSignalShmemSize(void)
 {
 	Size		size;

 	size = offsetof(PMSignalData, PMChildFlags);
 	size = add_size(size, mul_size(MaxLivePostmasterChildren(),
 								   sizeof(sig_atomic_t)));

 	return size;
 }

 /*
  * PMSignalShmemInit - initialize during shared-memory creation
  */
 void
 PMSignalShmemInit(void)
 {
 	bool		found;

 	PMSignalState = (PMSignalData *)
 		ShmemInitStruct("PMSignalState", PMSignalShmemSize(), &found);

 	if (!found)
 	{
 		MemSet(PMSignalState, 0, PMSignalShmemSize());
 		PMSignalState->num_child_flags = MaxLivePostmasterChildren();
 	}
 }

 /*
  * SendPostmasterSignal - signal the postmaster from a child process
  */
 void
 SendPostmasterSignal(PMSignalReason reason)
 {
 	/* If called in a standalone backend, do nothing */
 	if (!IsUnderPostmaster)
 		return;
 	/* Atomically set the proper flag */
 	PMSignalState->PMSignalFlags[reason] = true;
 	/* Send signal to postmaster */
 	kill(PostmasterPid, SIGUSR1);
 }

 /*
  * CheckPostmasterSignal - check to see if a particular reason has been
  * signaled, and clear the signal flag.  Should be called by postmaster
  * after receiving SIGUSR1.
  */
 bool
 CheckPostmasterSignal(PMSignalReason reason)
 {
 	/* Careful here --- don't clear flag if we haven't seen it set */
 	if (PMSignalState->PMSignalFlags[reason])
 	{
 		PMSignalState->PMSignalFlags[reason] = false;
 		return true;
 	}
 	return false;
 }


 /*
  * AssignPostmasterChildSlot - select an unused slot for a new postmaster
  * child process, and set its state to ASSIGNED.  Returns a slot number
  * (one to N).
  *
  * Only the postmaster is allowed to execute this routine, so we need no
  * special locking.
  */
 int
 AssignPostmasterChildSlot(void)
 {
 	int			slot = PMSignalState->next_child_flag;
 	int			n;

 	/*
 	 * Scan for a free slot.  We track the last slot assigned so as not to
 	 * waste time repeatedly rescanning low-numbered slots.
 	 */
 	for (n = PMSignalState->num_child_flags; n > 0; n--)
 	{
 		if (--slot < 0)
 			slot = PMSignalState->num_child_flags - 1;
 		if (PMSignalState->PMChildFlags[slot] == PM_CHILD_UNUSED)
 		{
 			PMSignalState->PMChildFlags[slot] = PM_CHILD_ASSIGNED;
 			PMSignalState->next_child_flag = slot;
 			return slot + 1;
 		}
 	}

 	/* Out of slots ... should never happen, else postmaster.c messed up */
 	elog(FATAL, "no free slots in PMChildFlags array");
 	return 0;					/* keep compiler quiet */
 }

 /*
  * ReleasePostmasterChildSlot - release a slot after death of a postmaster
  * child process.  This must be called in the postmaster process.
  *
  * Returns true if the slot had been in ASSIGNED state (the expected case),
  * false otherwise (implying that the child failed to clean itself up).
  */
 bool
 ReleasePostmasterChildSlot(int slot)
 {
 	bool		result;

 	Assert(slot > 0 && slot <= PMSignalState->num_child_flags);
 	slot--;

 	/*
 	 * Note: the slot state might already be unused, because the logic in
 	 * postmaster.c is such that this might get called twice when a child
 	 * crashes.  So we don't try to Assert anything about the state.
 	 */
 	result = (PMSignalState->PMChildFlags[slot] == PM_CHILD_ASSIGNED);
 	PMSignalState->PMChildFlags[slot] = PM_CHILD_UNUSED;
 	return result;
 }

 /*
  * MarkPostmasterChildActive - mark a postmaster child as about to begin
  * actively using shared memory.  This is called in the child process.
  */
 void
 MarkPostmasterChildActive(void)
 {
 	int			slot = MyPMChildSlot;

 	Assert(slot > 0 && slot <= PMSignalState->num_child_flags);
 	slot--;
 	Assert(PMSignalState->PMChildFlags[slot] == PM_CHILD_ASSIGNED);
 	PMSignalState->PMChildFlags[slot] = PM_CHILD_ACTIVE;
 }

 /*
  * MarkPostmasterChildInactive - mark a postmaster child as done using
  * shared memory.  This is called in the child process.
  */
 void
 MarkPostmasterChildInactive(void)
 {
 	int			slot = MyPMChildSlot;

 	Assert(slot > 0 && slot <= PMSignalState->num_child_flags);
 	slot--;
 	Assert(PMSignalState->PMChildFlags[slot] == PM_CHILD_ACTIVE);
 	PMSignalState->PMChildFlags[slot] = PM_CHILD_ASSIGNED;
 }


 /*
  * PostmasterIsAlive - check whether postmaster process is still alive
  *
  * amDirectChild should be passed as "true" by code that knows it is
  * executing in a direct child process of the postmaster; pass "false"
  * if an indirect child or not sure.  The "true" case uses a faster and
  * more reliable test, so use it when possible.
  */
 bool
 PostmasterIsAlive(bool amDirectChild)
 {
 #ifndef WIN32
 	if (amDirectChild)
 	{
 		/*
 		 * If the postmaster is alive, we'll still be its child.  If it's
 		 * died, we'll be reassigned as a child of the init process.
 		 */
 #ifdef __darwin__
 		/*
 		 * When attached w/gdb on OSX, gdb becomes parent of debugged process!
 		 * If we are direct child of postmaster and end up as child of
 		 * init, the postmaster musta died. This, of course, fails to detect
 		 * death of postmaster while this process is attached to gdb - but
 		 * that's easier to deal w/than being difficult to use gdb in the
 		 * normal case.
 		 */
 		return(getppid() != 1 /* init's pid */);
 #else  /* __darwin__ */
 		return (getppid() == PostmasterPid);
 #endif /* __darwin__ */
 	}
 	else
 	{
 		/*
 		 * Use kill() to see if the postmaster is still alive.	This can
 		 * sometimes give a false positive result, since the postmaster's PID
 		 * may get recycled, but it is good enough for existing uses by
 		 * indirect children.
 		 */
 		return (kill(PostmasterPid, 0) == 0);
 	}
 #else							/* WIN32 */
 	return (WaitForSingleObject(PostmasterHandle, 0) == WAIT_TIMEOUT);
 #endif   /* WIN32 */
 }


 /*
  * ParentIsAlive - check whether parent process is still alive;
  */
 bool
 ParentProcIsAlive()
 {
 	/* if parent exits, init process (PID 1) is reported as parent */
 	return (getppid() != 1);
 }
	/*-------------------------------------------------------------------------
	*
	* pmsignal.c
	* routines for signaling the postmaster from its child processes
	*
	*
	* Portions Copyright (c) 1996-2009, PostgreSQL Global Development Group
	* Portions Copyright (c) 1994, Regents of the University of California
	*
	* IDENTIFICATION
	* $PostgreSQL: pgsql/src/backend/storage/ipc/pmsignal.c,v 1.28 2009/06/11 14:49:01 momjian Exp $
	*
	*-------------------------------------------------------------------------
	*/
	#include "postgres.h"

	#include <signal.h>
	#include <unistd.h>

	#include "miscadmin.h"
	#include "postmaster/postmaster.h"
	#include "storage/pmsignal.h"
	#include "storage/shmem.h"


	/*
	* The postmaster is signaled by its children by sending SIGUSR1. The
	* specific reason is communicated via flags in shared memory. We keep
	* a boolean flag for each possible "reason", so that different reasons
	* can be signaled by different backends at the same time. (However,
	* if the same reason is signaled more than once simultaneously, the
	* postmaster will observe it only once.)
	*
	* The flags are actually declared as "volatile sig_atomic_t" for maximum
	* portability. This should ensure that loads and stores of the flag
	* values are atomic, allowing us to dispense with any explicit locking.
	*
	* In addition to the per-reason flags, we store a set of per-child-process
	* flags that are currently used only for detecting whether a backend has
	* exited without performing proper shutdown. The per-child-process flags
	* have three possible states: UNUSED, ASSIGNED, ACTIVE. An UNUSED slot is
	* available for assignment. An ASSIGNED slot is associated with a postmaster
	* child process, but either the process has not touched shared memory yet,
	* or it has successfully cleaned up after itself. A ACTIVE slot means the
	* process is actively using shared memory. The slots are assigned to
	* child processes at random, and postmaster.c is responsible for tracking
	* which one goes with which PID.
	*/

	#define PM_CHILD_UNUSED 0 /* these values must fit in sig_atomic_t */
	#define PM_CHILD_ASSIGNED 1
	#define PM_CHILD_ACTIVE 2

	/* "typedef struct PMSignalData PMSignalData" appears in pmsignal.h */
	struct PMSignalData
	{
	/* per-reason flags */
	sig_atomic_t PMSignalFlags[NUM_PMSIGNALS];
	/* per-child-process flags */
	int num_child_flags; /* # of entries in PMChildFlags[] */
	int next_child_flag; /* next slot to try to assign */
	sig_atomic_t PMChildFlags[1]; /* VARIABLE LENGTH ARRAY */
	};

	NON_EXEC_STATIC volatile PMSignalData *PMSignalState = NULL;


	/*
	* PMSignalShmemSize
	* Compute space needed for pmsignal.c's shared memory
	*/
	Size
	PMSignalShmemSize(void)
	{
	Size size;

	size = offsetof(PMSignalData, PMChildFlags);
	size = add_size(size, mul_size(MaxLivePostmasterChildren(),
	sizeof(sig_atomic_t)));

	return size;
	}

	/*
	* PMSignalShmemInit - initialize during shared-memory creation
	*/
	void
	PMSignalShmemInit(void)
	{
	bool found;

	PMSignalState = (PMSignalData *)
	ShmemInitStruct("PMSignalState", PMSignalShmemSize(), &found);

	if (!found)
	{
	MemSet(PMSignalState, 0, PMSignalShmemSize());
	PMSignalState->num_child_flags = MaxLivePostmasterChildren();
	}
	}

	/*
	* SendPostmasterSignal - signal the postmaster from a child process
	*/
	void
	SendPostmasterSignal(PMSignalReason reason)
	{
	/* If called in a standalone backend, do nothing */
	if (!IsUnderPostmaster)
	return;
	/* Atomically set the proper flag */
	PMSignalState->PMSignalFlags[reason] = true;
	/* Send signal to postmaster */
	kill(PostmasterPid, SIGUSR1);
	}

	/*
	* CheckPostmasterSignal - check to see if a particular reason has been
	* signaled, and clear the signal flag. Should be called by postmaster
	* after receiving SIGUSR1.
	*/
	bool
	CheckPostmasterSignal(PMSignalReason reason)
	{
	/* Careful here --- don't clear flag if we haven't seen it set */
	if (PMSignalState->PMSignalFlags[reason])
	{
	PMSignalState->PMSignalFlags[reason] = false;
	return true;
	}
	return false;
	}


	/*
	* AssignPostmasterChildSlot - select an unused slot for a new postmaster
	* child process, and set its state to ASSIGNED. Returns a slot number
	* (one to N).
	*
	* Only the postmaster is allowed to execute this routine, so we need no
	* special locking.
	*/
	int
	AssignPostmasterChildSlot(void)
	{
	int slot = PMSignalState->next_child_flag;
	int n;

	/*
	* Scan for a free slot. We track the last slot assigned so as not to
	* waste time repeatedly rescanning low-numbered slots.
	*/
	for (n = PMSignalState->num_child_flags; n > 0; n--)
	{
	if (--slot < 0)
	slot = PMSignalState->num_child_flags - 1;
	if (PMSignalState->PMChildFlags[slot] == PM_CHILD_UNUSED)
	{
	PMSignalState->PMChildFlags[slot] = PM_CHILD_ASSIGNED;
	PMSignalState->next_child_flag = slot;
	return slot + 1;
	}
	}

	/* Out of slots ... should never happen, else postmaster.c messed up */
	elog(FATAL, "no free slots in PMChildFlags array");
	return 0; /* keep compiler quiet */
	}

	/*
	* ReleasePostmasterChildSlot - release a slot after death of a postmaster
	* child process. This must be called in the postmaster process.
	*
	* Returns true if the slot had been in ASSIGNED state (the expected case),
	* false otherwise (implying that the child failed to clean itself up).
	*/
	bool
	ReleasePostmasterChildSlot(int slot)
	{
	bool result;

	Assert(slot > 0 && slot <= PMSignalState->num_child_flags);
	slot--;

	/*
	* Note: the slot state might already be unused, because the logic in
	* postmaster.c is such that this might get called twice when a child
	* crashes. So we don't try to Assert anything about the state.
	*/
	result = (PMSignalState->PMChildFlags[slot] == PM_CHILD_ASSIGNED);
	PMSignalState->PMChildFlags[slot] = PM_CHILD_UNUSED;
	return result;
	}

	/*
	* MarkPostmasterChildActive - mark a postmaster child as about to begin
	* actively using shared memory. This is called in the child process.
	*/
	void
	MarkPostmasterChildActive(void)
	{
	int slot = MyPMChildSlot;

	Assert(slot > 0 && slot <= PMSignalState->num_child_flags);
	slot--;
	Assert(PMSignalState->PMChildFlags[slot] == PM_CHILD_ASSIGNED);
	PMSignalState->PMChildFlags[slot] = PM_CHILD_ACTIVE;
	}

	/*
	* MarkPostmasterChildInactive - mark a postmaster child as done using
	* shared memory. This is called in the child process.
	*/
	void
	MarkPostmasterChildInactive(void)
	{
	int slot = MyPMChildSlot;

	Assert(slot > 0 && slot <= PMSignalState->num_child_flags);
	slot--;
	Assert(PMSignalState->PMChildFlags[slot] == PM_CHILD_ACTIVE);
	PMSignalState->PMChildFlags[slot] = PM_CHILD_ASSIGNED;
	}


	/*
	* PostmasterIsAlive - check whether postmaster process is still alive
	*
	* amDirectChild should be passed as "true" by code that knows it is
	* executing in a direct child process of the postmaster; pass "false"
	* if an indirect child or not sure. The "true" case uses a faster and
	* more reliable test, so use it when possible.
	*/
	bool
	PostmasterIsAlive(bool amDirectChild)
	{
	#ifndef WIN32
	if (amDirectChild)
	{
	/*
	* If the postmaster is alive, we'll still be its child. If it's
	* died, we'll be reassigned as a child of the init process.
	*/
	#ifdef __darwin__
	/*
	* When attached w/gdb on OSX, gdb becomes parent of debugged process!
	* If we are direct child of postmaster and end up as child of
	* init, the postmaster musta died. This, of course, fails to detect
	* death of postmaster while this process is attached to gdb - but
	* that's easier to deal w/than being difficult to use gdb in the
	* normal case.
	*/
	return(getppid() != 1 /* init's pid */);
	#else /* __darwin__ */
	return (getppid() == PostmasterPid);
	#endif /* __darwin__ */
	}
	else
	{
	/*
	* Use kill() to see if the postmaster is still alive. This can
	* sometimes give a false positive result, since the postmaster's PID
	* may get recycled, but it is good enough for existing uses by
	* indirect children.
	*/
	return (kill(PostmasterPid, 0) == 0);
	}
	#else /* WIN32 */
	return (WaitForSingleObject(PostmasterHandle, 0) == WAIT_TIMEOUT);
	#endif /* WIN32 */
	}


	/*
	* ParentIsAlive - check whether parent process is still alive;
	*/
	bool
	ParentProcIsAlive()
	{
	/* if parent exits, init process (PID 1) is reported as parent */
	return (getppid() != 1);
	}