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|
/*-------------------------------------------------------------------------
*
* sysv_shmem.c
* Implement shared memory using SysV facilities
*
* These routines used to be a fairly thin layer on top of SysV shared
* memory functionality. With the addition of anonymous-shmem logic,
* they're a bit fatter now. We still require a SysV shmem block to
* exist, though, because mmap'd shmem provides no way to find out how
* many processes are attached, which we need for interlocking purposes.
*
* Portions Copyright (c) 1996-2022, PostgreSQL Global Development Group
* Portions Copyright (c) 1994, Regents of the University of California
*
* IDENTIFICATION
* src/backend/port/sysv_shmem.c
*
*-------------------------------------------------------------------------
*/
#include "postgres.h"
#include <signal.h>
#include <unistd.h>
#include <sys/file.h>
#include <sys/mman.h>
#include <sys/stat.h>
#ifdef HAVE_SYS_IPC_H
#include <sys/ipc.h>
#endif
#ifdef HAVE_SYS_SHM_H
#include <sys/shm.h>
#endif
#include "miscadmin.h"
#include "port/pg_bitutils.h"
#include "portability/mem.h"
#include "storage/dsm.h"
#include "storage/fd.h"
#include "storage/ipc.h"
#include "storage/pg_shmem.h"
#include "utils/guc.h"
#include "utils/pidfile.h"
/*
* As of PostgreSQL 9.3, we normally allocate only a very small amount of
* System V shared memory, and only for the purposes of providing an
* interlock to protect the data directory. The real shared memory block
* is allocated using mmap(). This works around the problem that many
* systems have very low limits on the amount of System V shared memory
* that can be allocated. Even a limit of a few megabytes will be enough
* to run many copies of PostgreSQL without needing to adjust system settings.
*
* We assume that no one will attempt to run PostgreSQL 9.3 or later on
* systems that are ancient enough that anonymous shared memory is not
* supported, such as pre-2.4 versions of Linux. If that turns out to be
* false, we might need to add compile and/or run-time tests here and do this
* only if the running kernel supports it.
*
* However, we must always disable this logic in the EXEC_BACKEND case, and
* fall back to the old method of allocating the entire segment using System V
* shared memory, because there's no way to attach an anonymous mmap'd segment
* to a process after exec(). Since EXEC_BACKEND is intended only for
* developer use, this shouldn't be a big problem. Because of this, we do
* not worry about supporting anonymous shmem in the EXEC_BACKEND cases below.
*
* As of PostgreSQL 12, we regained the ability to use a large System V shared
* memory region even in non-EXEC_BACKEND builds, if shared_memory_type is set
* to sysv (though this is not the default).
*/
typedef key_t IpcMemoryKey; /* shared memory key passed to shmget(2) */
typedef int IpcMemoryId; /* shared memory ID returned by shmget(2) */
/*
* How does a given IpcMemoryId relate to this PostgreSQL process?
*
* One could recycle unattached segments of different data directories if we
* distinguished that case from other SHMSTATE_FOREIGN cases. Doing so would
* cause us to visit less of the key space, making us less likely to detect a
* SHMSTATE_ATTACHED key. It would also complicate the concurrency analysis,
* in that postmasters of different data directories could simultaneously
* attempt to recycle a given key. We'll waste keys longer in some cases, but
* avoiding the problems of the alternative justifies that loss.
*/
typedef enum
{
SHMSTATE_ANALYSIS_FAILURE, /* unexpected failure to analyze the ID */
SHMSTATE_ATTACHED, /* pertinent to DataDir, has attached PIDs */
SHMSTATE_ENOENT, /* no segment of that ID */
SHMSTATE_FOREIGN, /* exists, but not pertinent to DataDir */
SHMSTATE_UNATTACHED /* pertinent to DataDir, no attached PIDs */
} IpcMemoryState;
unsigned long UsedShmemSegID = 0;
void *UsedShmemSegAddr = NULL;
static Size AnonymousShmemSize;
static void *AnonymousShmem = NULL;
static void *InternalIpcMemoryCreate(IpcMemoryKey memKey, Size size);
static void IpcMemoryDetach(int status, Datum shmaddr);
static void IpcMemoryDelete(int status, Datum shmId);
static IpcMemoryState PGSharedMemoryAttach(IpcMemoryId shmId,
void *attachAt,
PGShmemHeader **addr);
/*
* InternalIpcMemoryCreate(memKey, size)
*
* Attempt to create a new shared memory segment with the specified key.
* Will fail (return NULL) if such a segment already exists. If successful,
* attach the segment to the current process and return its attached address.
* On success, callbacks are registered with on_shmem_exit to detach and
* delete the segment when on_shmem_exit is called.
*
* If we fail with a failure code other than collision-with-existing-segment,
* print out an error and abort. Other types of errors are not recoverable.
*/
static void *
InternalIpcMemoryCreate(IpcMemoryKey memKey, Size size)
{
IpcMemoryId shmid;
void *requestedAddress = NULL;
void *memAddress;
/*
* Normally we just pass requestedAddress = NULL to shmat(), allowing the
* system to choose where the segment gets mapped. But in an EXEC_BACKEND
* build, it's possible for whatever is chosen in the postmaster to not
* work for backends, due to variations in address space layout. As a
* rather klugy workaround, allow the user to specify the address to use
* via setting the environment variable PG_SHMEM_ADDR. (If this were of
* interest for anything except debugging, we'd probably create a cleaner
* and better-documented way to set it, such as a GUC.)
*/
#ifdef EXEC_BACKEND
{
char *pg_shmem_addr = getenv("PG_SHMEM_ADDR");
if (pg_shmem_addr)
requestedAddress = (void *) strtoul(pg_shmem_addr, NULL, 0);
else
{
#if defined(__darwin__) && SIZEOF_VOID_P == 8
/*
* Provide a default value that is believed to avoid problems with
* ASLR on the current macOS release.
*/
requestedAddress = (void *) 0x80000000000;
#endif
}
}
#endif
shmid = shmget(memKey, size, IPC_CREAT | IPC_EXCL | IPCProtection);
if (shmid < 0)
{
int shmget_errno = errno;
/*
* Fail quietly if error indicates a collision with existing segment.
* One would expect EEXIST, given that we said IPC_EXCL, but perhaps
* we could get a permission violation instead? Also, EIDRM might
* occur if an old seg is slated for destruction but not gone yet.
*/
if (shmget_errno == EEXIST || shmget_errno == EACCES
#ifdef EIDRM
|| shmget_errno == EIDRM
#endif
)
return NULL;
/*
* Some BSD-derived kernels are known to return EINVAL, not EEXIST, if
* there is an existing segment but it's smaller than "size" (this is
* a result of poorly-thought-out ordering of error tests). To
* distinguish between collision and invalid size in such cases, we
* make a second try with size = 0. These kernels do not test size
* against SHMMIN in the preexisting-segment case, so we will not get
* EINVAL a second time if there is such a segment.
*/
if (shmget_errno == EINVAL)
{
shmid = shmget(memKey, 0, IPC_CREAT | IPC_EXCL | IPCProtection);
if (shmid < 0)
{
/* As above, fail quietly if we verify a collision */
if (errno == EEXIST || errno == EACCES
#ifdef EIDRM
|| errno == EIDRM
#endif
)
return NULL;
/* Otherwise, fall through to report the original error */
}
else
{
/*
* On most platforms we cannot get here because SHMMIN is
* greater than zero. However, if we do succeed in creating a
* zero-size segment, free it and then fall through to report
* the original error.
*/
if (shmctl(shmid, IPC_RMID, NULL) < 0)
elog(LOG, "shmctl(%d, %d, 0) failed: %m",
(int) shmid, IPC_RMID);
}
}
/*
* Else complain and abort.
*
* Note: at this point EINVAL should mean that either SHMMIN or SHMMAX
* is violated. SHMALL violation might be reported as either ENOMEM
* (BSDen) or ENOSPC (Linux); the Single Unix Spec fails to say which
* it should be. SHMMNI violation is ENOSPC, per spec. Just plain
* not-enough-RAM is ENOMEM.
*/
errno = shmget_errno;
ereport(FATAL,
(errmsg("could not create shared memory segment: %m"),
errdetail("Failed system call was shmget(key=%lu, size=%zu, 0%o).",
(unsigned long) memKey, size,
IPC_CREAT | IPC_EXCL | IPCProtection),
(shmget_errno == EINVAL) ?
errhint("This error usually means that PostgreSQL's request for a shared memory "
"segment exceeded your kernel's SHMMAX parameter, or possibly that "
"it is less than "
"your kernel's SHMMIN parameter.\n"
"The PostgreSQL documentation contains more information about shared "
"memory configuration.") : 0,
(shmget_errno == ENOMEM) ?
errhint("This error usually means that PostgreSQL's request for a shared "
"memory segment exceeded your kernel's SHMALL parameter. You might need "
"to reconfigure the kernel with larger SHMALL.\n"
"The PostgreSQL documentation contains more information about shared "
"memory configuration.") : 0,
(shmget_errno == ENOSPC) ?
errhint("This error does *not* mean that you have run out of disk space. "
"It occurs either if all available shared memory IDs have been taken, "
"in which case you need to raise the SHMMNI parameter in your kernel, "
"or because the system's overall limit for shared memory has been "
"reached.\n"
"The PostgreSQL documentation contains more information about shared "
"memory configuration.") : 0));
}
/* Register on-exit routine to delete the new segment */
on_shmem_exit(IpcMemoryDelete, Int32GetDatum(shmid));
/* OK, should be able to attach to the segment */
memAddress = shmat(shmid, requestedAddress, PG_SHMAT_FLAGS);
if (memAddress == (void *) -1)
elog(FATAL, "shmat(id=%d, addr=%p, flags=0x%x) failed: %m",
shmid, requestedAddress, PG_SHMAT_FLAGS);
/* Register on-exit routine to detach new segment before deleting */
on_shmem_exit(IpcMemoryDetach, PointerGetDatum(memAddress));
/*
* Store shmem key and ID in data directory lockfile. Format to try to
* keep it the same length always (trailing junk in the lockfile won't
* hurt, but might confuse humans).
*/
{
char line[64];
sprintf(line, "%9lu %9lu",
(unsigned long) memKey, (unsigned long) shmid);
AddToDataDirLockFile(LOCK_FILE_LINE_SHMEM_KEY, line);
}
return memAddress;
}
/****************************************************************************/
/* IpcMemoryDetach(status, shmaddr) removes a shared memory segment */
/* from process' address space */
/* (called as an on_shmem_exit callback, hence funny argument list) */
/****************************************************************************/
static void
IpcMemoryDetach(int status, Datum shmaddr)
{
/* Detach System V shared memory block. */
if (shmdt((void *) DatumGetPointer(shmaddr)) < 0)
elog(LOG, "shmdt(%p) failed: %m", DatumGetPointer(shmaddr));
}
/****************************************************************************/
/* IpcMemoryDelete(status, shmId) deletes a shared memory segment */
/* (called as an on_shmem_exit callback, hence funny argument list) */
/****************************************************************************/
static void
IpcMemoryDelete(int status, Datum shmId)
{
if (shmctl(DatumGetInt32(shmId), IPC_RMID, NULL) < 0)
elog(LOG, "shmctl(%d, %d, 0) failed: %m",
DatumGetInt32(shmId), IPC_RMID);
}
/*
* PGSharedMemoryIsInUse
*
* Is a previously-existing shmem segment still existing and in use?
*
* The point of this exercise is to detect the case where a prior postmaster
* crashed, but it left child backends that are still running. Therefore
* we only care about shmem segments that are associated with the intended
* DataDir. This is an important consideration since accidental matches of
* shmem segment IDs are reasonably common.
*/
bool
PGSharedMemoryIsInUse(unsigned long id1, unsigned long id2)
{
PGShmemHeader *memAddress;
IpcMemoryState state;
state = PGSharedMemoryAttach((IpcMemoryId) id2, NULL, &memAddress);
if (memAddress && shmdt((void *) memAddress) < 0)
elog(LOG, "shmdt(%p) failed: %m", memAddress);
switch (state)
{
case SHMSTATE_ENOENT:
case SHMSTATE_FOREIGN:
case SHMSTATE_UNATTACHED:
return false;
case SHMSTATE_ANALYSIS_FAILURE:
case SHMSTATE_ATTACHED:
return true;
}
return true;
}
/*
* Test for a segment with id shmId; see comment at IpcMemoryState.
*
* If the segment exists, we'll attempt to attach to it, using attachAt
* if that's not NULL (but it's best to pass NULL if possible).
*
* *addr is set to the segment memory address if we attached to it, else NULL.
*/
static IpcMemoryState
PGSharedMemoryAttach(IpcMemoryId shmId,
void *attachAt,
PGShmemHeader **addr)
{
struct shmid_ds shmStat;
struct stat statbuf;
PGShmemHeader *hdr;
*addr = NULL;
/*
* First, try to stat the shm segment ID, to see if it exists at all.
*/
if (shmctl(shmId, IPC_STAT, &shmStat) < 0)
{
/*
* EINVAL actually has multiple possible causes documented in the
* shmctl man page, but we assume it must mean the segment no longer
* exists.
*/
if (errno == EINVAL)
return SHMSTATE_ENOENT;
/*
* EACCES implies we have no read permission, which means it is not a
* Postgres shmem segment (or at least, not one that is relevant to
* our data directory).
*/
if (errno == EACCES)
return SHMSTATE_FOREIGN;
/*
* Some Linux kernel versions (in fact, all of them as of July 2007)
* sometimes return EIDRM when EINVAL is correct. The Linux kernel
* actually does not have any internal state that would justify
* returning EIDRM, so we can get away with assuming that EIDRM is
* equivalent to EINVAL on that platform.
*/
#ifdef HAVE_LINUX_EIDRM_BUG
if (errno == EIDRM)
return SHMSTATE_ENOENT;
#endif
/*
* Otherwise, we had better assume that the segment is in use. The
* only likely case is (non-Linux, assumed spec-compliant) EIDRM,
* which implies that the segment has been IPC_RMID'd but there are
* still processes attached to it.
*/
return SHMSTATE_ANALYSIS_FAILURE;
}
/*
* Try to attach to the segment and see if it matches our data directory.
* This avoids any risk of duplicate-shmem-key conflicts on machines that
* are running several postmasters under the same userid.
*
* (When we're called from PGSharedMemoryCreate, this stat call is
* duplicative; but since this isn't a high-traffic case it's not worth
* trying to optimize.)
*/
if (stat(DataDir, &statbuf) < 0)
return SHMSTATE_ANALYSIS_FAILURE; /* can't stat; be conservative */
hdr = (PGShmemHeader *) shmat(shmId, attachAt, PG_SHMAT_FLAGS);
if (hdr == (PGShmemHeader *) -1)
{
/*
* Attachment failed. The cases we're interested in are the same as
* for the shmctl() call above. In particular, note that the owning
* postmaster could have terminated and removed the segment between
* shmctl() and shmat().
*
* If attachAt isn't NULL, it's possible that EINVAL reflects a
* problem with that address not a vanished segment, so it's best to
* pass NULL when probing for conflicting segments.
*/
if (errno == EINVAL)
return SHMSTATE_ENOENT; /* segment disappeared */
if (errno == EACCES)
return SHMSTATE_FOREIGN; /* must be non-Postgres */
#ifdef HAVE_LINUX_EIDRM_BUG
if (errno == EIDRM)
return SHMSTATE_ENOENT; /* segment disappeared */
#endif
/* Otherwise, be conservative. */
return SHMSTATE_ANALYSIS_FAILURE;
}
*addr = hdr;
if (hdr->magic != PGShmemMagic ||
hdr->device != statbuf.st_dev ||
hdr->inode != statbuf.st_ino)
{
/*
* It's either not a Postgres segment, or not one for my data
* directory.
*/
return SHMSTATE_FOREIGN;
}
/*
* It does match our data directory, so now test whether any processes are
* still attached to it. (We are, now, but the shm_nattch result is from
* before we attached to it.)
*/
return shmStat.shm_nattch == 0 ? SHMSTATE_UNATTACHED : SHMSTATE_ATTACHED;
}
/*
* Identify the huge page size to use, and compute the related mmap flags.
*
* Some Linux kernel versions have a bug causing mmap() to fail on requests
* that are not a multiple of the hugepage size. Versions without that bug
* instead silently round the request up to the next hugepage multiple ---
* and then munmap() fails when we give it a size different from that.
* So we have to round our request up to a multiple of the actual hugepage
* size to avoid trouble.
*
* Doing the round-up ourselves also lets us make use of the extra memory,
* rather than just wasting it. Currently, we just increase the available
* space recorded in the shmem header, which will make the extra usable for
* purposes such as additional locktable entries. Someday, for very large
* hugepage sizes, we might want to think about more invasive strategies,
* such as increasing shared_buffers to absorb the extra space.
*
* Returns the (real, assumed or config provided) page size into
* *hugepagesize, and the hugepage-related mmap flags to use into
* *mmap_flags if requested by the caller. If huge pages are not supported,
* *hugepagesize and *mmap_flags are set to 0.
*/
void
GetHugePageSize(Size *hugepagesize, int *mmap_flags)
{
#ifdef MAP_HUGETLB
Size default_hugepagesize = 0;
Size hugepagesize_local = 0;
int mmap_flags_local = 0;
/*
* System-dependent code to find out the default huge page size.
*
* On Linux, read /proc/meminfo looking for a line like "Hugepagesize:
* nnnn kB". Ignore any failures, falling back to the preset default.
*/
#ifdef __linux__
{
FILE *fp = AllocateFile("/proc/meminfo", "r");
char buf[128];
unsigned int sz;
char ch;
if (fp)
{
while (fgets(buf, sizeof(buf), fp))
{
if (sscanf(buf, "Hugepagesize: %u %c", &sz, &ch) == 2)
{
if (ch == 'k')
{
default_hugepagesize = sz * (Size) 1024;
break;
}
/* We could accept other units besides kB, if needed */
}
}
FreeFile(fp);
}
}
#endif /* __linux__ */
if (huge_page_size != 0)
{
/* If huge page size is requested explicitly, use that. */
hugepagesize_local = (Size) huge_page_size * 1024;
}
else if (default_hugepagesize != 0)
{
/* Otherwise use the system default, if we have it. */
hugepagesize_local = default_hugepagesize;
}
else
{
/*
* If we fail to find out the system's default huge page size, or no
* huge page size is requested explicitly, assume it is 2MB. This will
* work fine when the actual size is less. If it's more, we might get
* mmap() or munmap() failures due to unaligned requests; but at this
* writing, there are no reports of any non-Linux systems being picky
* about that.
*/
hugepagesize_local = 2 * 1024 * 1024;
}
mmap_flags_local = MAP_HUGETLB;
/*
* On recent enough Linux, also include the explicit page size, if
* necessary.
*/
#if defined(MAP_HUGE_MASK) && defined(MAP_HUGE_SHIFT)
if (hugepagesize_local != default_hugepagesize)
{
int shift = pg_ceil_log2_64(hugepagesize_local);
mmap_flags_local |= (shift & MAP_HUGE_MASK) << MAP_HUGE_SHIFT;
}
#endif
/* assign the results found */
if (mmap_flags)
*mmap_flags = mmap_flags_local;
if (hugepagesize)
*hugepagesize = hugepagesize_local;
#else
if (hugepagesize)
*hugepagesize = 0;
if (mmap_flags)
*mmap_flags = 0;
#endif /* MAP_HUGETLB */
}
/*
* Creates an anonymous mmap()ed shared memory segment.
*
* Pass the requested size in *size. This function will modify *size to the
* actual size of the allocation, if it ends up allocating a segment that is
* larger than requested.
*/
static void *
CreateAnonymousSegment(Size *size)
{
Size allocsize = *size;
void *ptr = MAP_FAILED;
int mmap_errno = 0;
#ifndef MAP_HUGETLB
/* PGSharedMemoryCreate should have dealt with this case */
Assert(huge_pages != HUGE_PAGES_ON);
#else
if (huge_pages == HUGE_PAGES_ON || huge_pages == HUGE_PAGES_TRY)
{
/*
* Round up the request size to a suitable large value.
*/
Size hugepagesize;
int mmap_flags;
GetHugePageSize(&hugepagesize, &mmap_flags);
if (allocsize % hugepagesize != 0)
allocsize += hugepagesize - (allocsize % hugepagesize);
ptr = mmap(NULL, allocsize, PROT_READ | PROT_WRITE,
PG_MMAP_FLAGS | mmap_flags, -1, 0);
mmap_errno = errno;
if (huge_pages == HUGE_PAGES_TRY && ptr == MAP_FAILED)
elog(DEBUG1, "mmap(%zu) with MAP_HUGETLB failed, huge pages disabled: %m",
allocsize);
}
#endif
if (ptr == MAP_FAILED && huge_pages != HUGE_PAGES_ON)
{
/*
* Use the original size, not the rounded-up value, when falling back
* to non-huge pages.
*/
allocsize = *size;
ptr = mmap(NULL, allocsize, PROT_READ | PROT_WRITE,
PG_MMAP_FLAGS, -1, 0);
mmap_errno = errno;
}
if (ptr == MAP_FAILED)
{
errno = mmap_errno;
ereport(FATAL,
(errmsg("could not map anonymous shared memory: %m"),
(mmap_errno == ENOMEM) ?
errhint("This error usually means that PostgreSQL's request "
"for a shared memory segment exceeded available memory, "
"swap space, or huge pages. To reduce the request size "
"(currently %zu bytes), reduce PostgreSQL's shared "
"memory usage, perhaps by reducing shared_buffers or "
"max_connections.",
allocsize) : 0));
}
*size = allocsize;
return ptr;
}
/*
* AnonymousShmemDetach --- detach from an anonymous mmap'd block
* (called as an on_shmem_exit callback, hence funny argument list)
*/
static void
AnonymousShmemDetach(int status, Datum arg)
{
/* Release anonymous shared memory block, if any. */
if (AnonymousShmem != NULL)
{
if (munmap(AnonymousShmem, AnonymousShmemSize) < 0)
elog(LOG, "munmap(%p, %zu) failed: %m",
AnonymousShmem, AnonymousShmemSize);
AnonymousShmem = NULL;
}
}
/*
* PGSharedMemoryCreate
*
* Create a shared memory segment of the given size and initialize its
* standard header. Also, register an on_shmem_exit callback to release
* the storage.
*
* Dead Postgres segments pertinent to this DataDir are recycled if found, but
* we do not fail upon collision with foreign shmem segments. The idea here
* is to detect and re-use keys that may have been assigned by a crashed
* postmaster or backend.
*/
PGShmemHeader *
PGSharedMemoryCreate(Size size,
PGShmemHeader **shim)
{
IpcMemoryKey NextShmemSegID;
void *memAddress;
PGShmemHeader *hdr;
struct stat statbuf;
Size sysvsize;
/*
* We use the data directory's ID info (inode and device numbers) to
* positively identify shmem segments associated with this data dir, and
* also as seeds for searching for a free shmem key.
*/
if (stat(DataDir, &statbuf) < 0)
ereport(FATAL,
(errcode_for_file_access(),
errmsg("could not stat data directory \"%s\": %m",
DataDir)));
/* Complain if hugepages demanded but we can't possibly support them */
#if !defined(MAP_HUGETLB)
if (huge_pages == HUGE_PAGES_ON)
ereport(ERROR,
(errcode(ERRCODE_FEATURE_NOT_SUPPORTED),
errmsg("huge pages not supported on this platform")));
#endif
/* For now, we don't support huge pages in SysV memory */
if (huge_pages == HUGE_PAGES_ON && shared_memory_type != SHMEM_TYPE_MMAP)
ereport(ERROR,
(errcode(ERRCODE_FEATURE_NOT_SUPPORTED),
errmsg("huge pages not supported with the current shared_memory_type setting")));
/* Room for a header? */
Assert(size > MAXALIGN(sizeof(PGShmemHeader)));
if (shared_memory_type == SHMEM_TYPE_MMAP)
{
AnonymousShmem = CreateAnonymousSegment(&size);
AnonymousShmemSize = size;
/* Register on-exit routine to unmap the anonymous segment */
on_shmem_exit(AnonymousShmemDetach, (Datum) 0);
/* Now we need only allocate a minimal-sized SysV shmem block. */
sysvsize = sizeof(PGShmemHeader);
}
else
sysvsize = size;
/*
* Loop till we find a free IPC key. Trust CreateDataDirLockFile() to
* ensure no more than one postmaster per data directory can enter this
* loop simultaneously. (CreateDataDirLockFile() does not entirely ensure
* that, but prefer fixing it over coping here.)
*/
NextShmemSegID = statbuf.st_ino;
for (;;)
{
IpcMemoryId shmid;
PGShmemHeader *oldhdr;
IpcMemoryState state;
/* Try to create new segment */
memAddress = InternalIpcMemoryCreate(NextShmemSegID, sysvsize);
if (memAddress)
break; /* successful create and attach */
/* Check shared memory and possibly remove and recreate */
/*
* shmget() failure is typically EACCES, hence SHMSTATE_FOREIGN.
* ENOENT, a narrow possibility, implies SHMSTATE_ENOENT, but one can
* safely treat SHMSTATE_ENOENT like SHMSTATE_FOREIGN.
*/
shmid = shmget(NextShmemSegID, sizeof(PGShmemHeader), 0);
if (shmid < 0)
{
oldhdr = NULL;
state = SHMSTATE_FOREIGN;
}
else
state = PGSharedMemoryAttach(shmid, NULL, &oldhdr);
switch (state)
{
case SHMSTATE_ANALYSIS_FAILURE:
case SHMSTATE_ATTACHED:
ereport(FATAL,
(errcode(ERRCODE_LOCK_FILE_EXISTS),
errmsg("pre-existing shared memory block (key %lu, ID %lu) is still in use",
(unsigned long) NextShmemSegID,
(unsigned long) shmid),
errhint("Terminate any old server processes associated with data directory \"%s\".",
DataDir)));
break;
case SHMSTATE_ENOENT:
/*
* To our surprise, some other process deleted since our last
* InternalIpcMemoryCreate(). Moments earlier, we would have
* seen SHMSTATE_FOREIGN. Try that same ID again.
*/
elog(LOG,
"shared memory block (key %lu, ID %lu) deleted during startup",
(unsigned long) NextShmemSegID,
(unsigned long) shmid);
break;
case SHMSTATE_FOREIGN:
NextShmemSegID++;
break;
case SHMSTATE_UNATTACHED:
/*
* The segment pertains to DataDir, and every process that had
* used it has died or detached. Zap it, if possible, and any
* associated dynamic shared memory segments, as well. This
* shouldn't fail, but if it does, assume the segment belongs
* to someone else after all, and try the next candidate.
* Otherwise, try again to create the segment. That may fail
* if some other process creates the same shmem key before we
* do, in which case we'll try the next key.
*/
if (oldhdr->dsm_control != 0)
dsm_cleanup_using_control_segment(oldhdr->dsm_control);
if (shmctl(shmid, IPC_RMID, NULL) < 0)
NextShmemSegID++;
break;
}
if (oldhdr && shmdt((void *) oldhdr) < 0)
elog(LOG, "shmdt(%p) failed: %m", oldhdr);
}
/* Initialize new segment. */
hdr = (PGShmemHeader *) memAddress;
hdr->creatorPID = getpid();
hdr->magic = PGShmemMagic;
hdr->dsm_control = 0;
/* Fill in the data directory ID info, too */
hdr->device = statbuf.st_dev;
hdr->inode = statbuf.st_ino;
/*
* Initialize space allocation status for segment.
*/
hdr->totalsize = size;
hdr->freeoffset = MAXALIGN(sizeof(PGShmemHeader));
*shim = hdr;
/* Save info for possible future use */
UsedShmemSegAddr = memAddress;
UsedShmemSegID = (unsigned long) NextShmemSegID;
/*
* If AnonymousShmem is NULL here, then we're not using anonymous shared
* memory, and should return a pointer to the System V shared memory
* block. Otherwise, the System V shared memory block is only a shim, and
* we must return a pointer to the real block.
*/
if (AnonymousShmem == NULL)
return hdr;
memcpy(AnonymousShmem, hdr, sizeof(PGShmemHeader));
return (PGShmemHeader *) AnonymousShmem;
}
#ifdef EXEC_BACKEND
/*
* PGSharedMemoryReAttach
*
* This is called during startup of a postmaster child process to re-attach to
* an already existing shared memory segment. This is needed only in the
* EXEC_BACKEND case; otherwise postmaster children inherit the shared memory
* segment attachment via fork().
*
* UsedShmemSegID and UsedShmemSegAddr are implicit parameters to this
* routine. The caller must have already restored them to the postmaster's
* values.
*/
void
PGSharedMemoryReAttach(void)
{
IpcMemoryId shmid;
PGShmemHeader *hdr;
IpcMemoryState state;
void *origUsedShmemSegAddr = UsedShmemSegAddr;
Assert(UsedShmemSegAddr != NULL);
Assert(IsUnderPostmaster);
#ifdef __CYGWIN__
/* cygipc (currently) appears to not detach on exec. */
PGSharedMemoryDetach();
UsedShmemSegAddr = origUsedShmemSegAddr;
#endif
elog(DEBUG3, "attaching to %p", UsedShmemSegAddr);
shmid = shmget(UsedShmemSegID, sizeof(PGShmemHeader), 0);
if (shmid < 0)
state = SHMSTATE_FOREIGN;
else
state = PGSharedMemoryAttach(shmid, UsedShmemSegAddr, &hdr);
if (state != SHMSTATE_ATTACHED)
elog(FATAL, "could not reattach to shared memory (key=%d, addr=%p): %m",
(int) UsedShmemSegID, UsedShmemSegAddr);
if (hdr != origUsedShmemSegAddr)
elog(FATAL, "reattaching to shared memory returned unexpected address (got %p, expected %p)",
hdr, origUsedShmemSegAddr);
dsm_set_control_handle(hdr->dsm_control);
UsedShmemSegAddr = hdr; /* probably redundant */
}
/*
* PGSharedMemoryNoReAttach
*
* This is called during startup of a postmaster child process when we choose
* *not* to re-attach to the existing shared memory segment. We must clean up
* to leave things in the appropriate state. This is not used in the non
* EXEC_BACKEND case, either.
*
* The child process startup logic might or might not call PGSharedMemoryDetach
* after this; make sure that it will be a no-op if called.
*
* UsedShmemSegID and UsedShmemSegAddr are implicit parameters to this
* routine. The caller must have already restored them to the postmaster's
* values.
*/
void
PGSharedMemoryNoReAttach(void)
{
Assert(UsedShmemSegAddr != NULL);
Assert(IsUnderPostmaster);
#ifdef __CYGWIN__
/* cygipc (currently) appears to not detach on exec. */
PGSharedMemoryDetach();
#endif
/* For cleanliness, reset UsedShmemSegAddr to show we're not attached. */
UsedShmemSegAddr = NULL;
/* And the same for UsedShmemSegID. */
UsedShmemSegID = 0;
}
#endif /* EXEC_BACKEND */
/*
* PGSharedMemoryDetach
*
* Detach from the shared memory segment, if still attached. This is not
* intended to be called explicitly by the process that originally created the
* segment (it will have on_shmem_exit callback(s) registered to do that).
* Rather, this is for subprocesses that have inherited an attachment and want
* to get rid of it.
*
* UsedShmemSegID and UsedShmemSegAddr are implicit parameters to this
* routine, also AnonymousShmem and AnonymousShmemSize.
*/
void
PGSharedMemoryDetach(void)
{
if (UsedShmemSegAddr != NULL)
{
if ((shmdt(UsedShmemSegAddr) < 0)
#if defined(EXEC_BACKEND) && defined(__CYGWIN__)
/* Work-around for cygipc exec bug */
&& shmdt(NULL) < 0
#endif
)
elog(LOG, "shmdt(%p) failed: %m", UsedShmemSegAddr);
UsedShmemSegAddr = NULL;
}
if (AnonymousShmem != NULL)
{
if (munmap(AnonymousShmem, AnonymousShmemSize) < 0)
elog(LOG, "munmap(%p, %zu) failed: %m",
AnonymousShmem, AnonymousShmemSize);
AnonymousShmem = NULL;
}
}
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