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|
/*-------------------------------------------------------------------------
*
* dsm_impl.c
* manage dynamic shared memory segments
*
* This file provides low-level APIs for creating and destroying shared
* memory segments using several different possible techniques. We refer
* to these segments as dynamic because they can be created, altered, and
* destroyed at any point during the server life cycle. This is unlike
* the main shared memory segment, of which there is always exactly one
* and which is always mapped at a fixed address in every PostgreSQL
* background process.
*
* Because not all systems provide the same primitives in this area, nor
* do all primitives behave the same way on all systems, we provide
* several implementations of this facility. Many systems implement
* POSIX shared memory (shm_open etc.), which is well-suited to our needs
* in this area, with the exception that shared memory identifiers live
* in a flat system-wide namespace, raising the uncomfortable prospect of
* name collisions with other processes (including other copies of
* PostgreSQL) running on the same system. Some systems only support
* the older System V shared memory interface (shmget etc.) which is
* also usable; however, the default allocation limits are often quite
* small, and the namespace is even more restricted.
*
* We also provide an mmap-based shared memory implementation. This may
* be useful on systems that provide shared memory via a special-purpose
* filesystem; by opting for this implementation, the user can even
* control precisely where their shared memory segments are placed. It
* can also be used as a fallback for systems where shm_open and shmget
* are not available or can't be used for some reason. Of course,
* mapping a file residing on an actual spinning disk is a fairly poor
* approximation for shared memory because writeback may hurt performance
* substantially, but there should be few systems where we must make do
* with such poor tools.
*
* As ever, Windows requires its own implementation.
*
* Portions Copyright (c) 1996-2023, PostgreSQL Global Development Group
* Portions Copyright (c) 1994, Regents of the University of California
*
*
* IDENTIFICATION
* src/backend/storage/ipc/dsm_impl.c
*
*-------------------------------------------------------------------------
*/
#include "postgres.h"
#include <fcntl.h>
#include <signal.h>
#include <unistd.h>
#ifndef WIN32
#include <sys/mman.h>
#include <sys/ipc.h>
#include <sys/shm.h>
#include <sys/stat.h>
#endif
#include "common/file_perm.h"
#include "libpq/pqsignal.h"
#include "miscadmin.h"
#include "pgstat.h"
#include "portability/mem.h"
#include "postmaster/postmaster.h"
#include "storage/dsm_impl.h"
#include "storage/fd.h"
#include "utils/guc.h"
#include "utils/memutils.h"
#ifdef USE_DSM_POSIX
static bool dsm_impl_posix(dsm_op op, dsm_handle handle, Size request_size,
void **impl_private, void **mapped_address,
Size *mapped_size, int elevel);
static int dsm_impl_posix_resize(int fd, off_t size);
#endif
#ifdef USE_DSM_SYSV
static bool dsm_impl_sysv(dsm_op op, dsm_handle handle, Size request_size,
void **impl_private, void **mapped_address,
Size *mapped_size, int elevel);
#endif
#ifdef USE_DSM_WINDOWS
static bool dsm_impl_windows(dsm_op op, dsm_handle handle, Size request_size,
void **impl_private, void **mapped_address,
Size *mapped_size, int elevel);
#endif
#ifdef USE_DSM_MMAP
static bool dsm_impl_mmap(dsm_op op, dsm_handle handle, Size request_size,
void **impl_private, void **mapped_address,
Size *mapped_size, int elevel);
#endif
static int errcode_for_dynamic_shared_memory(void);
const struct config_enum_entry dynamic_shared_memory_options[] = {
#ifdef USE_DSM_POSIX
{"posix", DSM_IMPL_POSIX, false},
#endif
#ifdef USE_DSM_SYSV
{"sysv", DSM_IMPL_SYSV, false},
#endif
#ifdef USE_DSM_WINDOWS
{"windows", DSM_IMPL_WINDOWS, false},
#endif
#ifdef USE_DSM_MMAP
{"mmap", DSM_IMPL_MMAP, false},
#endif
{NULL, 0, false}
};
/* Implementation selector. */
int dynamic_shared_memory_type = DEFAULT_DYNAMIC_SHARED_MEMORY_TYPE;
/* Amount of space reserved for DSM segments in the main area. */
int min_dynamic_shared_memory;
/* Size of buffer to be used for zero-filling. */
#define ZBUFFER_SIZE 8192
#define SEGMENT_NAME_PREFIX "Global/PostgreSQL"
/*------
* Perform a low-level shared memory operation in a platform-specific way,
* as dictated by the selected implementation. Each implementation is
* required to implement the following primitives.
*
* DSM_OP_CREATE. Create a segment whose size is the request_size and
* map it.
*
* DSM_OP_ATTACH. Map the segment, whose size must be the request_size.
*
* DSM_OP_DETACH. Unmap the segment.
*
* DSM_OP_DESTROY. Unmap the segment, if it is mapped. Destroy the
* segment.
*
* Arguments:
* op: The operation to be performed.
* handle: The handle of an existing object, or for DSM_OP_CREATE, the
* a new handle the caller wants created.
* request_size: For DSM_OP_CREATE, the requested size. Otherwise, 0.
* impl_private: Private, implementation-specific data. Will be a pointer
* to NULL for the first operation on a shared memory segment within this
* backend; thereafter, it will point to the value to which it was set
* on the previous call.
* mapped_address: Pointer to start of current mapping; pointer to NULL
* if none. Updated with new mapping address.
* mapped_size: Pointer to size of current mapping; pointer to 0 if none.
* Updated with new mapped size.
* elevel: Level at which to log errors.
*
* Return value: true on success, false on failure. When false is returned,
* a message should first be logged at the specified elevel, except in the
* case where DSM_OP_CREATE experiences a name collision, which should
* silently return false.
*-----
*/
bool
dsm_impl_op(dsm_op op, dsm_handle handle, Size request_size,
void **impl_private, void **mapped_address, Size *mapped_size,
int elevel)
{
Assert(op == DSM_OP_CREATE || request_size == 0);
Assert((op != DSM_OP_CREATE && op != DSM_OP_ATTACH) ||
(*mapped_address == NULL && *mapped_size == 0));
switch (dynamic_shared_memory_type)
{
#ifdef USE_DSM_POSIX
case DSM_IMPL_POSIX:
return dsm_impl_posix(op, handle, request_size, impl_private,
mapped_address, mapped_size, elevel);
#endif
#ifdef USE_DSM_SYSV
case DSM_IMPL_SYSV:
return dsm_impl_sysv(op, handle, request_size, impl_private,
mapped_address, mapped_size, elevel);
#endif
#ifdef USE_DSM_WINDOWS
case DSM_IMPL_WINDOWS:
return dsm_impl_windows(op, handle, request_size, impl_private,
mapped_address, mapped_size, elevel);
#endif
#ifdef USE_DSM_MMAP
case DSM_IMPL_MMAP:
return dsm_impl_mmap(op, handle, request_size, impl_private,
mapped_address, mapped_size, elevel);
#endif
default:
elog(ERROR, "unexpected dynamic shared memory type: %d",
dynamic_shared_memory_type);
return false;
}
}
#ifdef USE_DSM_POSIX
/*
* Operating system primitives to support POSIX shared memory.
*
* POSIX shared memory segments are created and attached using shm_open()
* and shm_unlink(); other operations, such as sizing or mapping the
* segment, are performed as if the shared memory segments were files.
*
* Indeed, on some platforms, they may be implemented that way. While
* POSIX shared memory segments seem intended to exist in a flat namespace,
* some operating systems may implement them as files, even going so far
* to treat a request for /xyz as a request to create a file by that name
* in the root directory. Users of such broken platforms should select
* a different shared memory implementation.
*/
static bool
dsm_impl_posix(dsm_op op, dsm_handle handle, Size request_size,
void **impl_private, void **mapped_address, Size *mapped_size,
int elevel)
{
char name[64];
int flags;
int fd;
char *address;
snprintf(name, 64, "/PostgreSQL.%u", handle);
/* Handle teardown cases. */
if (op == DSM_OP_DETACH || op == DSM_OP_DESTROY)
{
if (*mapped_address != NULL
&& munmap(*mapped_address, *mapped_size) != 0)
{
ereport(elevel,
(errcode_for_dynamic_shared_memory(),
errmsg("could not unmap shared memory segment \"%s\": %m",
name)));
return false;
}
*mapped_address = NULL;
*mapped_size = 0;
if (op == DSM_OP_DESTROY && shm_unlink(name) != 0)
{
ereport(elevel,
(errcode_for_dynamic_shared_memory(),
errmsg("could not remove shared memory segment \"%s\": %m",
name)));
return false;
}
return true;
}
/*
* Create new segment or open an existing one for attach.
*
* Even though we will close the FD before returning, it seems desirable
* to use Reserve/ReleaseExternalFD, to reduce the probability of EMFILE
* failure. The fact that we won't hold the FD open long justifies using
* ReserveExternalFD rather than AcquireExternalFD, though.
*/
ReserveExternalFD();
flags = O_RDWR | (op == DSM_OP_CREATE ? O_CREAT | O_EXCL : 0);
if ((fd = shm_open(name, flags, PG_FILE_MODE_OWNER)) == -1)
{
ReleaseExternalFD();
if (op == DSM_OP_ATTACH || errno != EEXIST)
ereport(elevel,
(errcode_for_dynamic_shared_memory(),
errmsg("could not open shared memory segment \"%s\": %m",
name)));
return false;
}
/*
* If we're attaching the segment, determine the current size; if we are
* creating the segment, set the size to the requested value.
*/
if (op == DSM_OP_ATTACH)
{
struct stat st;
if (fstat(fd, &st) != 0)
{
int save_errno;
/* Back out what's already been done. */
save_errno = errno;
close(fd);
ReleaseExternalFD();
errno = save_errno;
ereport(elevel,
(errcode_for_dynamic_shared_memory(),
errmsg("could not stat shared memory segment \"%s\": %m",
name)));
return false;
}
request_size = st.st_size;
}
else if (dsm_impl_posix_resize(fd, request_size) != 0)
{
int save_errno;
/* Back out what's already been done. */
save_errno = errno;
close(fd);
ReleaseExternalFD();
shm_unlink(name);
errno = save_errno;
ereport(elevel,
(errcode_for_dynamic_shared_memory(),
errmsg("could not resize shared memory segment \"%s\" to %zu bytes: %m",
name, request_size)));
return false;
}
/* Map it. */
address = mmap(NULL, request_size, PROT_READ | PROT_WRITE,
MAP_SHARED | MAP_HASSEMAPHORE | MAP_NOSYNC, fd, 0);
if (address == MAP_FAILED)
{
int save_errno;
/* Back out what's already been done. */
save_errno = errno;
close(fd);
ReleaseExternalFD();
if (op == DSM_OP_CREATE)
shm_unlink(name);
errno = save_errno;
ereport(elevel,
(errcode_for_dynamic_shared_memory(),
errmsg("could not map shared memory segment \"%s\": %m",
name)));
return false;
}
*mapped_address = address;
*mapped_size = request_size;
close(fd);
ReleaseExternalFD();
return true;
}
/*
* Set the size of a virtual memory region associated with a file descriptor.
* If necessary, also ensure that virtual memory is actually allocated by the
* operating system, to avoid nasty surprises later.
*
* Returns non-zero if either truncation or allocation fails, and sets errno.
*/
static int
dsm_impl_posix_resize(int fd, off_t size)
{
int rc;
int save_errno;
sigset_t save_sigmask;
/*
* Block all blockable signals, except SIGQUIT. posix_fallocate() can run
* for quite a long time, and is an all-or-nothing operation. If we
* allowed SIGUSR1 to interrupt us repeatedly (for example, due to
* recovery conflicts), the retry loop might never succeed.
*/
if (IsUnderPostmaster)
sigprocmask(SIG_SETMASK, &BlockSig, &save_sigmask);
pgstat_report_wait_start(WAIT_EVENT_DSM_ALLOCATE);
#if defined(HAVE_POSIX_FALLOCATE) && defined(__linux__)
/*
* On Linux, a shm_open fd is backed by a tmpfs file. If we were to use
* ftruncate, the file would contain a hole. Accessing memory backed by a
* hole causes tmpfs to allocate pages, which fails with SIGBUS if there
* is no more tmpfs space available. So we ask tmpfs to allocate pages
* here, so we can fail gracefully with ENOSPC now rather than risking
* SIGBUS later.
*
* We still use a traditional EINTR retry loop to handle SIGCONT.
* posix_fallocate() doesn't restart automatically, and we don't want this
* to fail if you attach a debugger.
*/
do
{
rc = posix_fallocate(fd, 0, size);
} while (rc == EINTR);
/*
* The caller expects errno to be set, but posix_fallocate() doesn't set
* it. Instead it returns error numbers directly. So set errno, even
* though we'll also return rc to indicate success or failure.
*/
errno = rc;
#else
/* Extend the file to the requested size. */
do
{
rc = ftruncate(fd, size);
} while (rc < 0 && errno == EINTR);
#endif
pgstat_report_wait_end();
if (IsUnderPostmaster)
{
save_errno = errno;
sigprocmask(SIG_SETMASK, &save_sigmask, NULL);
errno = save_errno;
}
return rc;
}
#endif /* USE_DSM_POSIX */
#ifdef USE_DSM_SYSV
/*
* Operating system primitives to support System V shared memory.
*
* System V shared memory segments are manipulated using shmget(), shmat(),
* shmdt(), and shmctl(). As the default allocation limits for System V
* shared memory are usually quite low, the POSIX facilities may be
* preferable; but those are not supported everywhere.
*/
static bool
dsm_impl_sysv(dsm_op op, dsm_handle handle, Size request_size,
void **impl_private, void **mapped_address, Size *mapped_size,
int elevel)
{
key_t key;
int ident;
char *address;
char name[64];
int *ident_cache;
/*
* POSIX shared memory and mmap-based shared memory identify segments with
* names. To avoid needless error message variation, we use the handle as
* the name.
*/
snprintf(name, 64, "%u", handle);
/*
* The System V shared memory namespace is very restricted; names are of
* type key_t, which is expected to be some sort of integer data type, but
* not necessarily the same one as dsm_handle. Since we use dsm_handle to
* identify shared memory segments across processes, this might seem like
* a problem, but it's really not. If dsm_handle is bigger than key_t,
* the cast below might truncate away some bits from the handle the
* user-provided, but it'll truncate exactly the same bits away in exactly
* the same fashion every time we use that handle, which is all that
* really matters. Conversely, if dsm_handle is smaller than key_t, we
* won't use the full range of available key space, but that's no big deal
* either.
*
* We do make sure that the key isn't negative, because that might not be
* portable.
*/
key = (key_t) handle;
if (key < 1) /* avoid compiler warning if type is unsigned */
key = -key;
/*
* There's one special key, IPC_PRIVATE, which can't be used. If we end
* up with that value by chance during a create operation, just pretend it
* already exists, so that caller will retry. If we run into it anywhere
* else, the caller has passed a handle that doesn't correspond to
* anything we ever created, which should not happen.
*/
if (key == IPC_PRIVATE)
{
if (op != DSM_OP_CREATE)
elog(DEBUG4, "System V shared memory key may not be IPC_PRIVATE");
errno = EEXIST;
return false;
}
/*
* Before we can do anything with a shared memory segment, we have to map
* the shared memory key to a shared memory identifier using shmget(). To
* avoid repeated lookups, we store the key using impl_private.
*/
if (*impl_private != NULL)
{
ident_cache = *impl_private;
ident = *ident_cache;
}
else
{
int flags = IPCProtection;
size_t segsize;
/*
* Allocate the memory BEFORE acquiring the resource, so that we don't
* leak the resource if memory allocation fails.
*/
ident_cache = MemoryContextAlloc(TopMemoryContext, sizeof(int));
/*
* When using shmget to find an existing segment, we must pass the
* size as 0. Passing a non-zero size which is greater than the
* actual size will result in EINVAL.
*/
segsize = 0;
if (op == DSM_OP_CREATE)
{
flags |= IPC_CREAT | IPC_EXCL;
segsize = request_size;
}
if ((ident = shmget(key, segsize, flags)) == -1)
{
if (op == DSM_OP_ATTACH || errno != EEXIST)
{
int save_errno = errno;
pfree(ident_cache);
errno = save_errno;
ereport(elevel,
(errcode_for_dynamic_shared_memory(),
errmsg("could not get shared memory segment: %m")));
}
return false;
}
*ident_cache = ident;
*impl_private = ident_cache;
}
/* Handle teardown cases. */
if (op == DSM_OP_DETACH || op == DSM_OP_DESTROY)
{
pfree(ident_cache);
*impl_private = NULL;
if (*mapped_address != NULL && shmdt(*mapped_address) != 0)
{
ereport(elevel,
(errcode_for_dynamic_shared_memory(),
errmsg("could not unmap shared memory segment \"%s\": %m",
name)));
return false;
}
*mapped_address = NULL;
*mapped_size = 0;
if (op == DSM_OP_DESTROY && shmctl(ident, IPC_RMID, NULL) < 0)
{
ereport(elevel,
(errcode_for_dynamic_shared_memory(),
errmsg("could not remove shared memory segment \"%s\": %m",
name)));
return false;
}
return true;
}
/* If we're attaching it, we must use IPC_STAT to determine the size. */
if (op == DSM_OP_ATTACH)
{
struct shmid_ds shm;
if (shmctl(ident, IPC_STAT, &shm) != 0)
{
ereport(elevel,
(errcode_for_dynamic_shared_memory(),
errmsg("could not stat shared memory segment \"%s\": %m",
name)));
return false;
}
request_size = shm.shm_segsz;
}
/* Map it. */
address = shmat(ident, NULL, PG_SHMAT_FLAGS);
if (address == (void *) -1)
{
int save_errno;
/* Back out what's already been done. */
save_errno = errno;
if (op == DSM_OP_CREATE)
shmctl(ident, IPC_RMID, NULL);
errno = save_errno;
ereport(elevel,
(errcode_for_dynamic_shared_memory(),
errmsg("could not map shared memory segment \"%s\": %m",
name)));
return false;
}
*mapped_address = address;
*mapped_size = request_size;
return true;
}
#endif
#ifdef USE_DSM_WINDOWS
/*
* Operating system primitives to support Windows shared memory.
*
* Windows shared memory implementation is done using file mapping
* which can be backed by either physical file or system paging file.
* Current implementation uses system paging file as other effects
* like performance are not clear for physical file and it is used in similar
* way for main shared memory in windows.
*
* A memory mapping object is a kernel object - they always get deleted when
* the last reference to them goes away, either explicitly via a CloseHandle or
* when the process containing the reference exits.
*/
static bool
dsm_impl_windows(dsm_op op, dsm_handle handle, Size request_size,
void **impl_private, void **mapped_address,
Size *mapped_size, int elevel)
{
char *address;
HANDLE hmap;
char name[64];
MEMORY_BASIC_INFORMATION info;
/*
* Storing the shared memory segment in the Global\ namespace, can allow
* any process running in any session to access that file mapping object
* provided that the caller has the required access rights. But to avoid
* issues faced in main shared memory, we are using the naming convention
* similar to main shared memory. We can change here once issue mentioned
* in GetSharedMemName is resolved.
*/
snprintf(name, 64, "%s.%u", SEGMENT_NAME_PREFIX, handle);
/*
* Handle teardown cases. Since Windows automatically destroys the object
* when no references remain, we can treat it the same as detach.
*/
if (op == DSM_OP_DETACH || op == DSM_OP_DESTROY)
{
if (*mapped_address != NULL
&& UnmapViewOfFile(*mapped_address) == 0)
{
_dosmaperr(GetLastError());
ereport(elevel,
(errcode_for_dynamic_shared_memory(),
errmsg("could not unmap shared memory segment \"%s\": %m",
name)));
return false;
}
if (*impl_private != NULL
&& CloseHandle(*impl_private) == 0)
{
_dosmaperr(GetLastError());
ereport(elevel,
(errcode_for_dynamic_shared_memory(),
errmsg("could not remove shared memory segment \"%s\": %m",
name)));
return false;
}
*impl_private = NULL;
*mapped_address = NULL;
*mapped_size = 0;
return true;
}
/* Create new segment or open an existing one for attach. */
if (op == DSM_OP_CREATE)
{
DWORD size_high;
DWORD size_low;
DWORD errcode;
/* Shifts >= the width of the type are undefined. */
#ifdef _WIN64
size_high = request_size >> 32;
#else
size_high = 0;
#endif
size_low = (DWORD) request_size;
/* CreateFileMapping might not clear the error code on success */
SetLastError(0);
hmap = CreateFileMapping(INVALID_HANDLE_VALUE, /* Use the pagefile */
NULL, /* Default security attrs */
PAGE_READWRITE, /* Memory is read/write */
size_high, /* Upper 32 bits of size */
size_low, /* Lower 32 bits of size */
name);
errcode = GetLastError();
if (errcode == ERROR_ALREADY_EXISTS || errcode == ERROR_ACCESS_DENIED)
{
/*
* On Windows, when the segment already exists, a handle for the
* existing segment is returned. We must close it before
* returning. However, if the existing segment is created by a
* service, then it returns ERROR_ACCESS_DENIED. We don't do
* _dosmaperr here, so errno won't be modified.
*/
if (hmap)
CloseHandle(hmap);
return false;
}
if (!hmap)
{
_dosmaperr(errcode);
ereport(elevel,
(errcode_for_dynamic_shared_memory(),
errmsg("could not create shared memory segment \"%s\": %m",
name)));
return false;
}
}
else
{
hmap = OpenFileMapping(FILE_MAP_WRITE | FILE_MAP_READ,
FALSE, /* do not inherit the name */
name); /* name of mapping object */
if (!hmap)
{
_dosmaperr(GetLastError());
ereport(elevel,
(errcode_for_dynamic_shared_memory(),
errmsg("could not open shared memory segment \"%s\": %m",
name)));
return false;
}
}
/* Map it. */
address = MapViewOfFile(hmap, FILE_MAP_WRITE | FILE_MAP_READ,
0, 0, 0);
if (!address)
{
int save_errno;
_dosmaperr(GetLastError());
/* Back out what's already been done. */
save_errno = errno;
CloseHandle(hmap);
errno = save_errno;
ereport(elevel,
(errcode_for_dynamic_shared_memory(),
errmsg("could not map shared memory segment \"%s\": %m",
name)));
return false;
}
/*
* VirtualQuery gives size in page_size units, which is 4K for Windows. We
* need size only when we are attaching, but it's better to get the size
* when creating new segment to keep size consistent both for
* DSM_OP_CREATE and DSM_OP_ATTACH.
*/
if (VirtualQuery(address, &info, sizeof(info)) == 0)
{
int save_errno;
_dosmaperr(GetLastError());
/* Back out what's already been done. */
save_errno = errno;
UnmapViewOfFile(address);
CloseHandle(hmap);
errno = save_errno;
ereport(elevel,
(errcode_for_dynamic_shared_memory(),
errmsg("could not stat shared memory segment \"%s\": %m",
name)));
return false;
}
*mapped_address = address;
*mapped_size = info.RegionSize;
*impl_private = hmap;
return true;
}
#endif
#ifdef USE_DSM_MMAP
/*
* Operating system primitives to support mmap-based shared memory.
*
* Calling this "shared memory" is somewhat of a misnomer, because what
* we're really doing is creating a bunch of files and mapping them into
* our address space. The operating system may feel obliged to
* synchronize the contents to disk even if nothing is being paged out,
* which will not serve us well. The user can relocate the pg_dynshmem
* directory to a ramdisk to avoid this problem, if available.
*/
static bool
dsm_impl_mmap(dsm_op op, dsm_handle handle, Size request_size,
void **impl_private, void **mapped_address, Size *mapped_size,
int elevel)
{
char name[64];
int flags;
int fd;
char *address;
snprintf(name, 64, PG_DYNSHMEM_DIR "/" PG_DYNSHMEM_MMAP_FILE_PREFIX "%u",
handle);
/* Handle teardown cases. */
if (op == DSM_OP_DETACH || op == DSM_OP_DESTROY)
{
if (*mapped_address != NULL
&& munmap(*mapped_address, *mapped_size) != 0)
{
ereport(elevel,
(errcode_for_dynamic_shared_memory(),
errmsg("could not unmap shared memory segment \"%s\": %m",
name)));
return false;
}
*mapped_address = NULL;
*mapped_size = 0;
if (op == DSM_OP_DESTROY && unlink(name) != 0)
{
ereport(elevel,
(errcode_for_dynamic_shared_memory(),
errmsg("could not remove shared memory segment \"%s\": %m",
name)));
return false;
}
return true;
}
/* Create new segment or open an existing one for attach. */
flags = O_RDWR | (op == DSM_OP_CREATE ? O_CREAT | O_EXCL : 0);
if ((fd = OpenTransientFile(name, flags)) == -1)
{
if (op == DSM_OP_ATTACH || errno != EEXIST)
ereport(elevel,
(errcode_for_dynamic_shared_memory(),
errmsg("could not open shared memory segment \"%s\": %m",
name)));
return false;
}
/*
* If we're attaching the segment, determine the current size; if we are
* creating the segment, set the size to the requested value.
*/
if (op == DSM_OP_ATTACH)
{
struct stat st;
if (fstat(fd, &st) != 0)
{
int save_errno;
/* Back out what's already been done. */
save_errno = errno;
CloseTransientFile(fd);
errno = save_errno;
ereport(elevel,
(errcode_for_dynamic_shared_memory(),
errmsg("could not stat shared memory segment \"%s\": %m",
name)));
return false;
}
request_size = st.st_size;
}
else
{
/*
* Allocate a buffer full of zeros.
*
* Note: palloc zbuffer, instead of just using a local char array, to
* ensure it is reasonably well-aligned; this may save a few cycles
* transferring data to the kernel.
*/
char *zbuffer = (char *) palloc0(ZBUFFER_SIZE);
uint32 remaining = request_size;
bool success = true;
/*
* Zero-fill the file. We have to do this the hard way to ensure that
* all the file space has really been allocated, so that we don't
* later seg fault when accessing the memory mapping. This is pretty
* pessimal.
*/
while (success && remaining > 0)
{
Size goal = remaining;
if (goal > ZBUFFER_SIZE)
goal = ZBUFFER_SIZE;
pgstat_report_wait_start(WAIT_EVENT_DSM_FILL_ZERO_WRITE);
if (write(fd, zbuffer, goal) == goal)
remaining -= goal;
else
success = false;
pgstat_report_wait_end();
}
if (!success)
{
int save_errno;
/* Back out what's already been done. */
save_errno = errno;
CloseTransientFile(fd);
unlink(name);
errno = save_errno ? save_errno : ENOSPC;
ereport(elevel,
(errcode_for_dynamic_shared_memory(),
errmsg("could not resize shared memory segment \"%s\" to %zu bytes: %m",
name, request_size)));
return false;
}
}
/* Map it. */
address = mmap(NULL, request_size, PROT_READ | PROT_WRITE,
MAP_SHARED | MAP_HASSEMAPHORE | MAP_NOSYNC, fd, 0);
if (address == MAP_FAILED)
{
int save_errno;
/* Back out what's already been done. */
save_errno = errno;
CloseTransientFile(fd);
if (op == DSM_OP_CREATE)
unlink(name);
errno = save_errno;
ereport(elevel,
(errcode_for_dynamic_shared_memory(),
errmsg("could not map shared memory segment \"%s\": %m",
name)));
return false;
}
*mapped_address = address;
*mapped_size = request_size;
if (CloseTransientFile(fd) != 0)
{
ereport(elevel,
(errcode_for_file_access(),
errmsg("could not close shared memory segment \"%s\": %m",
name)));
return false;
}
return true;
}
#endif
/*
* Implementation-specific actions that must be performed when a segment is to
* be preserved even when no backend has it attached.
*
* Except on Windows, we don't need to do anything at all. But since Windows
* cleans up segments automatically when no references remain, we duplicate
* the segment handle into the postmaster process. The postmaster needn't
* do anything to receive the handle; Windows transfers it automatically.
*/
void
dsm_impl_pin_segment(dsm_handle handle, void *impl_private,
void **impl_private_pm_handle)
{
switch (dynamic_shared_memory_type)
{
#ifdef USE_DSM_WINDOWS
case DSM_IMPL_WINDOWS:
if (IsUnderPostmaster)
{
HANDLE hmap;
if (!DuplicateHandle(GetCurrentProcess(), impl_private,
PostmasterHandle, &hmap, 0, FALSE,
DUPLICATE_SAME_ACCESS))
{
char name[64];
snprintf(name, 64, "%s.%u", SEGMENT_NAME_PREFIX, handle);
_dosmaperr(GetLastError());
ereport(ERROR,
(errcode_for_dynamic_shared_memory(),
errmsg("could not duplicate handle for \"%s\": %m",
name)));
}
/*
* Here, we remember the handle that we created in the
* postmaster process. This handle isn't actually usable in
* any process other than the postmaster, but that doesn't
* matter. We're just holding onto it so that, if the segment
* is unpinned, dsm_impl_unpin_segment can close it.
*/
*impl_private_pm_handle = hmap;
}
break;
#endif
default:
break;
}
}
/*
* Implementation-specific actions that must be performed when a segment is no
* longer to be preserved, so that it will be cleaned up when all backends
* have detached from it.
*
* Except on Windows, we don't need to do anything at all. For Windows, we
* close the extra handle that dsm_impl_pin_segment created in the
* postmaster's process space.
*/
void
dsm_impl_unpin_segment(dsm_handle handle, void **impl_private)
{
switch (dynamic_shared_memory_type)
{
#ifdef USE_DSM_WINDOWS
case DSM_IMPL_WINDOWS:
if (IsUnderPostmaster)
{
if (*impl_private &&
!DuplicateHandle(PostmasterHandle, *impl_private,
NULL, NULL, 0, FALSE,
DUPLICATE_CLOSE_SOURCE))
{
char name[64];
snprintf(name, 64, "%s.%u", SEGMENT_NAME_PREFIX, handle);
_dosmaperr(GetLastError());
ereport(ERROR,
(errcode_for_dynamic_shared_memory(),
errmsg("could not duplicate handle for \"%s\": %m",
name)));
}
*impl_private = NULL;
}
break;
#endif
default:
break;
}
}
static int
errcode_for_dynamic_shared_memory(void)
{
if (errno == EFBIG || errno == ENOMEM)
return errcode(ERRCODE_OUT_OF_MEMORY);
else
return errcode_for_file_access();
}
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