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|
/*-------------------------------------------------------------------------
*
* slru.c
* Simple LRU buffering for transaction status logfiles
*
* We use a simple least-recently-used scheme to manage a pool of page
* buffers. Under ordinary circumstances we expect that write
* traffic will occur mostly to the latest page (and to the just-prior
* page, soon after a page transition). Read traffic will probably touch
* a larger span of pages, but in any case a fairly small number of page
* buffers should be sufficient. So, we just search the buffers using plain
* linear search; there's no need for a hashtable or anything fancy.
* The management algorithm is straight LRU except that we will never swap
* out the latest page (since we know it's going to be hit again eventually).
*
* We use a control LWLock to protect the shared data structures, plus
* per-buffer LWLocks that synchronize I/O for each buffer. The control lock
* must be held to examine or modify any shared state. A process that is
* reading in or writing out a page buffer does not hold the control lock,
* only the per-buffer lock for the buffer it is working on.
*
* "Holding the control lock" means exclusive lock in all cases except for
* SimpleLruReadPage_ReadOnly(); see comments for SlruRecentlyUsed() for
* the implications of that.
*
* When initiating I/O on a buffer, we acquire the per-buffer lock exclusively
* before releasing the control lock. The per-buffer lock is released after
* completing the I/O, re-acquiring the control lock, and updating the shared
* state. (Deadlock is not possible here, because we never try to initiate
* I/O when someone else is already doing I/O on the same buffer.)
* To wait for I/O to complete, release the control lock, acquire the
* per-buffer lock in shared mode, immediately release the per-buffer lock,
* reacquire the control lock, and then recheck state (since arbitrary things
* could have happened while we didn't have the lock).
*
* As with the regular buffer manager, it is possible for another process
* to re-dirty a page that is currently being written out. This is handled
* by re-setting the page's page_dirty flag.
*
*
* Portions Copyright (c) 1996-2021, PostgreSQL Global Development Group
* Portions Copyright (c) 1994, Regents of the University of California
*
* src/backend/access/transam/slru.c
*
*-------------------------------------------------------------------------
*/
#include "postgres.h"
#include <fcntl.h>
#include <sys/stat.h>
#include <unistd.h>
#include "access/slru.h"
#include "access/transam.h"
#include "access/xlog.h"
#include "miscadmin.h"
#include "pgstat.h"
#include "storage/fd.h"
#include "storage/shmem.h"
#define SlruFileName(ctl, path, seg) \
snprintf(path, MAXPGPATH, "%s/%04X", (ctl)->Dir, seg)
/*
* During SimpleLruWriteAll(), we will usually not need to write more than one
* or two physical files, but we may need to write several pages per file. We
* can consolidate the I/O requests by leaving files open until control returns
* to SimpleLruWriteAll(). This data structure remembers which files are open.
*/
#define MAX_WRITEALL_BUFFERS 16
typedef struct SlruWriteAllData
{
int num_files; /* # files actually open */
int fd[MAX_WRITEALL_BUFFERS]; /* their FD's */
int segno[MAX_WRITEALL_BUFFERS]; /* their log seg#s */
} SlruWriteAllData;
typedef struct SlruWriteAllData *SlruWriteAll;
/*
* Populate a file tag describing a segment file. We only use the segment
* number, since we can derive everything else we need by having separate
* sync handler functions for clog, multixact etc.
*/
#define INIT_SLRUFILETAG(a,xx_handler,xx_segno) \
( \
memset(&(a), 0, sizeof(FileTag)), \
(a).handler = (xx_handler), \
(a).segno = (xx_segno) \
)
/*
* Macro to mark a buffer slot "most recently used". Note multiple evaluation
* of arguments!
*
* The reason for the if-test is that there are often many consecutive
* accesses to the same page (particularly the latest page). By suppressing
* useless increments of cur_lru_count, we reduce the probability that old
* pages' counts will "wrap around" and make them appear recently used.
*
* We allow this code to be executed concurrently by multiple processes within
* SimpleLruReadPage_ReadOnly(). As long as int reads and writes are atomic,
* this should not cause any completely-bogus values to enter the computation.
* However, it is possible for either cur_lru_count or individual
* page_lru_count entries to be "reset" to lower values than they should have,
* in case a process is delayed while it executes this macro. With care in
* SlruSelectLRUPage(), this does little harm, and in any case the absolute
* worst possible consequence is a nonoptimal choice of page to evict. The
* gain from allowing concurrent reads of SLRU pages seems worth it.
*/
#define SlruRecentlyUsed(shared, slotno) \
do { \
int new_lru_count = (shared)->cur_lru_count; \
if (new_lru_count != (shared)->page_lru_count[slotno]) { \
(shared)->cur_lru_count = ++new_lru_count; \
(shared)->page_lru_count[slotno] = new_lru_count; \
} \
} while (0)
/* Saved info for SlruReportIOError */
typedef enum
{
SLRU_OPEN_FAILED,
SLRU_SEEK_FAILED,
SLRU_READ_FAILED,
SLRU_WRITE_FAILED,
SLRU_FSYNC_FAILED,
SLRU_CLOSE_FAILED
} SlruErrorCause;
static SlruErrorCause slru_errcause;
static int slru_errno;
static void SimpleLruZeroLSNs(SlruCtl ctl, int slotno);
static void SimpleLruWaitIO(SlruCtl ctl, int slotno);
static void SlruInternalWritePage(SlruCtl ctl, int slotno, SlruWriteAll fdata);
static bool SlruPhysicalReadPage(SlruCtl ctl, int pageno, int slotno);
static bool SlruPhysicalWritePage(SlruCtl ctl, int pageno, int slotno,
SlruWriteAll fdata);
static void SlruReportIOError(SlruCtl ctl, int pageno, TransactionId xid);
static int SlruSelectLRUPage(SlruCtl ctl, int pageno);
static bool SlruScanDirCbDeleteCutoff(SlruCtl ctl, char *filename,
int segpage, void *data);
static void SlruInternalDeleteSegment(SlruCtl ctl, int segno);
/*
* Initialization of shared memory
*/
Size
SimpleLruShmemSize(int nslots, int nlsns)
{
Size sz;
/* we assume nslots isn't so large as to risk overflow */
sz = MAXALIGN(sizeof(SlruSharedData));
sz += MAXALIGN(nslots * sizeof(char *)); /* page_buffer[] */
sz += MAXALIGN(nslots * sizeof(SlruPageStatus)); /* page_status[] */
sz += MAXALIGN(nslots * sizeof(bool)); /* page_dirty[] */
sz += MAXALIGN(nslots * sizeof(int)); /* page_number[] */
sz += MAXALIGN(nslots * sizeof(int)); /* page_lru_count[] */
sz += MAXALIGN(nslots * sizeof(LWLockPadded)); /* buffer_locks[] */
if (nlsns > 0)
sz += MAXALIGN(nslots * nlsns * sizeof(XLogRecPtr)); /* group_lsn[] */
return BUFFERALIGN(sz) + BLCKSZ * nslots;
}
/*
* Initialize, or attach to, a simple LRU cache in shared memory.
*
* ctl: address of local (unshared) control structure.
* name: name of SLRU. (This is user-visible, pick with care!)
* nslots: number of page slots to use.
* nlsns: number of LSN groups per page (set to zero if not relevant).
* ctllock: LWLock to use to control access to the shared control structure.
* subdir: PGDATA-relative subdirectory that will contain the files.
* tranche_id: LWLock tranche ID to use for the SLRU's per-buffer LWLocks.
*/
void
SimpleLruInit(SlruCtl ctl, const char *name, int nslots, int nlsns,
LWLock *ctllock, const char *subdir, int tranche_id,
SyncRequestHandler sync_handler)
{
SlruShared shared;
bool found;
shared = (SlruShared) ShmemInitStruct(name,
SimpleLruShmemSize(nslots, nlsns),
&found);
if (!IsUnderPostmaster)
{
/* Initialize locks and shared memory area */
char *ptr;
Size offset;
int slotno;
Assert(!found);
memset(shared, 0, sizeof(SlruSharedData));
shared->ControlLock = ctllock;
shared->num_slots = nslots;
shared->lsn_groups_per_page = nlsns;
shared->cur_lru_count = 0;
/* shared->latest_page_number will be set later */
shared->slru_stats_idx = pgstat_slru_index(name);
ptr = (char *) shared;
offset = MAXALIGN(sizeof(SlruSharedData));
shared->page_buffer = (char **) (ptr + offset);
offset += MAXALIGN(nslots * sizeof(char *));
shared->page_status = (SlruPageStatus *) (ptr + offset);
offset += MAXALIGN(nslots * sizeof(SlruPageStatus));
shared->page_dirty = (bool *) (ptr + offset);
offset += MAXALIGN(nslots * sizeof(bool));
shared->page_number = (int *) (ptr + offset);
offset += MAXALIGN(nslots * sizeof(int));
shared->page_lru_count = (int *) (ptr + offset);
offset += MAXALIGN(nslots * sizeof(int));
/* Initialize LWLocks */
shared->buffer_locks = (LWLockPadded *) (ptr + offset);
offset += MAXALIGN(nslots * sizeof(LWLockPadded));
if (nlsns > 0)
{
shared->group_lsn = (XLogRecPtr *) (ptr + offset);
offset += MAXALIGN(nslots * nlsns * sizeof(XLogRecPtr));
}
ptr += BUFFERALIGN(offset);
for (slotno = 0; slotno < nslots; slotno++)
{
LWLockInitialize(&shared->buffer_locks[slotno].lock,
tranche_id);
shared->page_buffer[slotno] = ptr;
shared->page_status[slotno] = SLRU_PAGE_EMPTY;
shared->page_dirty[slotno] = false;
shared->page_lru_count[slotno] = 0;
ptr += BLCKSZ;
}
/* Should fit to estimated shmem size */
Assert(ptr - (char *) shared <= SimpleLruShmemSize(nslots, nlsns));
}
else
Assert(found);
/*
* Initialize the unshared control struct, including directory path. We
* assume caller set PagePrecedes.
*/
ctl->shared = shared;
ctl->sync_handler = sync_handler;
strlcpy(ctl->Dir, subdir, sizeof(ctl->Dir));
}
/*
* Initialize (or reinitialize) a page to zeroes.
*
* The page is not actually written, just set up in shared memory.
* The slot number of the new page is returned.
*
* Control lock must be held at entry, and will be held at exit.
*/
int
SimpleLruZeroPage(SlruCtl ctl, int pageno)
{
SlruShared shared = ctl->shared;
int slotno;
/* Find a suitable buffer slot for the page */
slotno = SlruSelectLRUPage(ctl, pageno);
Assert(shared->page_status[slotno] == SLRU_PAGE_EMPTY ||
(shared->page_status[slotno] == SLRU_PAGE_VALID &&
!shared->page_dirty[slotno]) ||
shared->page_number[slotno] == pageno);
/* Mark the slot as containing this page */
shared->page_number[slotno] = pageno;
shared->page_status[slotno] = SLRU_PAGE_VALID;
shared->page_dirty[slotno] = true;
SlruRecentlyUsed(shared, slotno);
/* Set the buffer to zeroes */
MemSet(shared->page_buffer[slotno], 0, BLCKSZ);
/* Set the LSNs for this new page to zero */
SimpleLruZeroLSNs(ctl, slotno);
/* Assume this page is now the latest active page */
shared->latest_page_number = pageno;
/* update the stats counter of zeroed pages */
pgstat_count_slru_page_zeroed(shared->slru_stats_idx);
return slotno;
}
/*
* Zero all the LSNs we store for this slru page.
*
* This should be called each time we create a new page, and each time we read
* in a page from disk into an existing buffer. (Such an old page cannot
* have any interesting LSNs, since we'd have flushed them before writing
* the page in the first place.)
*
* This assumes that InvalidXLogRecPtr is bitwise-all-0.
*/
static void
SimpleLruZeroLSNs(SlruCtl ctl, int slotno)
{
SlruShared shared = ctl->shared;
if (shared->lsn_groups_per_page > 0)
MemSet(&shared->group_lsn[slotno * shared->lsn_groups_per_page], 0,
shared->lsn_groups_per_page * sizeof(XLogRecPtr));
}
/*
* Wait for any active I/O on a page slot to finish. (This does not
* guarantee that new I/O hasn't been started before we return, though.
* In fact the slot might not even contain the same page anymore.)
*
* Control lock must be held at entry, and will be held at exit.
*/
static void
SimpleLruWaitIO(SlruCtl ctl, int slotno)
{
SlruShared shared = ctl->shared;
/* See notes at top of file */
LWLockRelease(shared->ControlLock);
LWLockAcquire(&shared->buffer_locks[slotno].lock, LW_SHARED);
LWLockRelease(&shared->buffer_locks[slotno].lock);
LWLockAcquire(shared->ControlLock, LW_EXCLUSIVE);
/*
* If the slot is still in an io-in-progress state, then either someone
* already started a new I/O on the slot, or a previous I/O failed and
* neglected to reset the page state. That shouldn't happen, really, but
* it seems worth a few extra cycles to check and recover from it. We can
* cheaply test for failure by seeing if the buffer lock is still held (we
* assume that transaction abort would release the lock).
*/
if (shared->page_status[slotno] == SLRU_PAGE_READ_IN_PROGRESS ||
shared->page_status[slotno] == SLRU_PAGE_WRITE_IN_PROGRESS)
{
if (LWLockConditionalAcquire(&shared->buffer_locks[slotno].lock, LW_SHARED))
{
/* indeed, the I/O must have failed */
if (shared->page_status[slotno] == SLRU_PAGE_READ_IN_PROGRESS)
shared->page_status[slotno] = SLRU_PAGE_EMPTY;
else /* write_in_progress */
{
shared->page_status[slotno] = SLRU_PAGE_VALID;
shared->page_dirty[slotno] = true;
}
LWLockRelease(&shared->buffer_locks[slotno].lock);
}
}
}
/*
* Find a page in a shared buffer, reading it in if necessary.
* The page number must correspond to an already-initialized page.
*
* If write_ok is true then it is OK to return a page that is in
* WRITE_IN_PROGRESS state; it is the caller's responsibility to be sure
* that modification of the page is safe. If write_ok is false then we
* will not return the page until it is not undergoing active I/O.
*
* The passed-in xid is used only for error reporting, and may be
* InvalidTransactionId if no specific xid is associated with the action.
*
* Return value is the shared-buffer slot number now holding the page.
* The buffer's LRU access info is updated.
*
* Control lock must be held at entry, and will be held at exit.
*/
int
SimpleLruReadPage(SlruCtl ctl, int pageno, bool write_ok,
TransactionId xid)
{
SlruShared shared = ctl->shared;
/* Outer loop handles restart if we must wait for someone else's I/O */
for (;;)
{
int slotno;
bool ok;
/* See if page already is in memory; if not, pick victim slot */
slotno = SlruSelectLRUPage(ctl, pageno);
/* Did we find the page in memory? */
if (shared->page_number[slotno] == pageno &&
shared->page_status[slotno] != SLRU_PAGE_EMPTY)
{
/*
* If page is still being read in, we must wait for I/O. Likewise
* if the page is being written and the caller said that's not OK.
*/
if (shared->page_status[slotno] == SLRU_PAGE_READ_IN_PROGRESS ||
(shared->page_status[slotno] == SLRU_PAGE_WRITE_IN_PROGRESS &&
!write_ok))
{
SimpleLruWaitIO(ctl, slotno);
/* Now we must recheck state from the top */
continue;
}
/* Otherwise, it's ready to use */
SlruRecentlyUsed(shared, slotno);
/* update the stats counter of pages found in the SLRU */
pgstat_count_slru_page_hit(shared->slru_stats_idx);
return slotno;
}
/* We found no match; assert we selected a freeable slot */
Assert(shared->page_status[slotno] == SLRU_PAGE_EMPTY ||
(shared->page_status[slotno] == SLRU_PAGE_VALID &&
!shared->page_dirty[slotno]));
/* Mark the slot read-busy */
shared->page_number[slotno] = pageno;
shared->page_status[slotno] = SLRU_PAGE_READ_IN_PROGRESS;
shared->page_dirty[slotno] = false;
/* Acquire per-buffer lock (cannot deadlock, see notes at top) */
LWLockAcquire(&shared->buffer_locks[slotno].lock, LW_EXCLUSIVE);
/* Release control lock while doing I/O */
LWLockRelease(shared->ControlLock);
/* Do the read */
ok = SlruPhysicalReadPage(ctl, pageno, slotno);
/* Set the LSNs for this newly read-in page to zero */
SimpleLruZeroLSNs(ctl, slotno);
/* Re-acquire control lock and update page state */
LWLockAcquire(shared->ControlLock, LW_EXCLUSIVE);
Assert(shared->page_number[slotno] == pageno &&
shared->page_status[slotno] == SLRU_PAGE_READ_IN_PROGRESS &&
!shared->page_dirty[slotno]);
shared->page_status[slotno] = ok ? SLRU_PAGE_VALID : SLRU_PAGE_EMPTY;
LWLockRelease(&shared->buffer_locks[slotno].lock);
/* Now it's okay to ereport if we failed */
if (!ok)
SlruReportIOError(ctl, pageno, xid);
SlruRecentlyUsed(shared, slotno);
/* update the stats counter of pages not found in SLRU */
pgstat_count_slru_page_read(shared->slru_stats_idx);
return slotno;
}
}
/*
* Find a page in a shared buffer, reading it in if necessary.
* The page number must correspond to an already-initialized page.
* The caller must intend only read-only access to the page.
*
* The passed-in xid is used only for error reporting, and may be
* InvalidTransactionId if no specific xid is associated with the action.
*
* Return value is the shared-buffer slot number now holding the page.
* The buffer's LRU access info is updated.
*
* Control lock must NOT be held at entry, but will be held at exit.
* It is unspecified whether the lock will be shared or exclusive.
*/
int
SimpleLruReadPage_ReadOnly(SlruCtl ctl, int pageno, TransactionId xid)
{
SlruShared shared = ctl->shared;
int slotno;
/* Try to find the page while holding only shared lock */
LWLockAcquire(shared->ControlLock, LW_SHARED);
/* See if page is already in a buffer */
for (slotno = 0; slotno < shared->num_slots; slotno++)
{
if (shared->page_number[slotno] == pageno &&
shared->page_status[slotno] != SLRU_PAGE_EMPTY &&
shared->page_status[slotno] != SLRU_PAGE_READ_IN_PROGRESS)
{
/* See comments for SlruRecentlyUsed macro */
SlruRecentlyUsed(shared, slotno);
/* update the stats counter of pages found in the SLRU */
pgstat_count_slru_page_hit(shared->slru_stats_idx);
return slotno;
}
}
/* No luck, so switch to normal exclusive lock and do regular read */
LWLockRelease(shared->ControlLock);
LWLockAcquire(shared->ControlLock, LW_EXCLUSIVE);
return SimpleLruReadPage(ctl, pageno, true, xid);
}
/*
* Write a page from a shared buffer, if necessary.
* Does nothing if the specified slot is not dirty.
*
* NOTE: only one write attempt is made here. Hence, it is possible that
* the page is still dirty at exit (if someone else re-dirtied it during
* the write). However, we *do* attempt a fresh write even if the page
* is already being written; this is for checkpoints.
*
* Control lock must be held at entry, and will be held at exit.
*/
static void
SlruInternalWritePage(SlruCtl ctl, int slotno, SlruWriteAll fdata)
{
SlruShared shared = ctl->shared;
int pageno = shared->page_number[slotno];
bool ok;
/* If a write is in progress, wait for it to finish */
while (shared->page_status[slotno] == SLRU_PAGE_WRITE_IN_PROGRESS &&
shared->page_number[slotno] == pageno)
{
SimpleLruWaitIO(ctl, slotno);
}
/*
* Do nothing if page is not dirty, or if buffer no longer contains the
* same page we were called for.
*/
if (!shared->page_dirty[slotno] ||
shared->page_status[slotno] != SLRU_PAGE_VALID ||
shared->page_number[slotno] != pageno)
return;
/*
* Mark the slot write-busy, and clear the dirtybit. After this point, a
* transaction status update on this page will mark it dirty again.
*/
shared->page_status[slotno] = SLRU_PAGE_WRITE_IN_PROGRESS;
shared->page_dirty[slotno] = false;
/* Acquire per-buffer lock (cannot deadlock, see notes at top) */
LWLockAcquire(&shared->buffer_locks[slotno].lock, LW_EXCLUSIVE);
/* Release control lock while doing I/O */
LWLockRelease(shared->ControlLock);
/* Do the write */
ok = SlruPhysicalWritePage(ctl, pageno, slotno, fdata);
/* If we failed, and we're in a flush, better close the files */
if (!ok && fdata)
{
int i;
for (i = 0; i < fdata->num_files; i++)
CloseTransientFile(fdata->fd[i]);
}
/* Re-acquire control lock and update page state */
LWLockAcquire(shared->ControlLock, LW_EXCLUSIVE);
Assert(shared->page_number[slotno] == pageno &&
shared->page_status[slotno] == SLRU_PAGE_WRITE_IN_PROGRESS);
/* If we failed to write, mark the page dirty again */
if (!ok)
shared->page_dirty[slotno] = true;
shared->page_status[slotno] = SLRU_PAGE_VALID;
LWLockRelease(&shared->buffer_locks[slotno].lock);
/* Now it's okay to ereport if we failed */
if (!ok)
SlruReportIOError(ctl, pageno, InvalidTransactionId);
/* If part of a checkpoint, count this as a buffer written. */
if (fdata)
CheckpointStats.ckpt_bufs_written++;
}
/*
* Wrapper of SlruInternalWritePage, for external callers.
* fdata is always passed a NULL here.
*/
void
SimpleLruWritePage(SlruCtl ctl, int slotno)
{
SlruInternalWritePage(ctl, slotno, NULL);
}
/*
* Return whether the given page exists on disk.
*
* A false return means that either the file does not exist, or that it's not
* large enough to contain the given page.
*/
bool
SimpleLruDoesPhysicalPageExist(SlruCtl ctl, int pageno)
{
int segno = pageno / SLRU_PAGES_PER_SEGMENT;
int rpageno = pageno % SLRU_PAGES_PER_SEGMENT;
int offset = rpageno * BLCKSZ;
char path[MAXPGPATH];
int fd;
bool result;
off_t endpos;
/* update the stats counter of checked pages */
pgstat_count_slru_page_exists(ctl->shared->slru_stats_idx);
SlruFileName(ctl, path, segno);
fd = OpenTransientFile(path, O_RDONLY | PG_BINARY);
if (fd < 0)
{
/* expected: file doesn't exist */
if (errno == ENOENT)
return false;
/* report error normally */
slru_errcause = SLRU_OPEN_FAILED;
slru_errno = errno;
SlruReportIOError(ctl, pageno, 0);
}
if ((endpos = lseek(fd, 0, SEEK_END)) < 0)
{
slru_errcause = SLRU_SEEK_FAILED;
slru_errno = errno;
SlruReportIOError(ctl, pageno, 0);
}
result = endpos >= (off_t) (offset + BLCKSZ);
if (CloseTransientFile(fd) != 0)
{
slru_errcause = SLRU_CLOSE_FAILED;
slru_errno = errno;
return false;
}
return result;
}
/*
* Physical read of a (previously existing) page into a buffer slot
*
* On failure, we cannot just ereport(ERROR) since caller has put state in
* shared memory that must be undone. So, we return false and save enough
* info in static variables to let SlruReportIOError make the report.
*
* For now, assume it's not worth keeping a file pointer open across
* read/write operations. We could cache one virtual file pointer ...
*/
static bool
SlruPhysicalReadPage(SlruCtl ctl, int pageno, int slotno)
{
SlruShared shared = ctl->shared;
int segno = pageno / SLRU_PAGES_PER_SEGMENT;
int rpageno = pageno % SLRU_PAGES_PER_SEGMENT;
off_t offset = rpageno * BLCKSZ;
char path[MAXPGPATH];
int fd;
SlruFileName(ctl, path, segno);
/*
* In a crash-and-restart situation, it's possible for us to receive
* commands to set the commit status of transactions whose bits are in
* already-truncated segments of the commit log (see notes in
* SlruPhysicalWritePage). Hence, if we are InRecovery, allow the case
* where the file doesn't exist, and return zeroes instead.
*/
fd = OpenTransientFile(path, O_RDONLY | PG_BINARY);
if (fd < 0)
{
if (errno != ENOENT || !InRecovery)
{
slru_errcause = SLRU_OPEN_FAILED;
slru_errno = errno;
return false;
}
ereport(LOG,
(errmsg("file \"%s\" doesn't exist, reading as zeroes",
path)));
MemSet(shared->page_buffer[slotno], 0, BLCKSZ);
return true;
}
errno = 0;
pgstat_report_wait_start(WAIT_EVENT_SLRU_READ);
if (pg_pread(fd, shared->page_buffer[slotno], BLCKSZ, offset) != BLCKSZ)
{
pgstat_report_wait_end();
slru_errcause = SLRU_READ_FAILED;
slru_errno = errno;
CloseTransientFile(fd);
return false;
}
pgstat_report_wait_end();
if (CloseTransientFile(fd) != 0)
{
slru_errcause = SLRU_CLOSE_FAILED;
slru_errno = errno;
return false;
}
return true;
}
/*
* Physical write of a page from a buffer slot
*
* On failure, we cannot just ereport(ERROR) since caller has put state in
* shared memory that must be undone. So, we return false and save enough
* info in static variables to let SlruReportIOError make the report.
*
* For now, assume it's not worth keeping a file pointer open across
* independent read/write operations. We do batch operations during
* SimpleLruWriteAll, though.
*
* fdata is NULL for a standalone write, pointer to open-file info during
* SimpleLruWriteAll.
*/
static bool
SlruPhysicalWritePage(SlruCtl ctl, int pageno, int slotno, SlruWriteAll fdata)
{
SlruShared shared = ctl->shared;
int segno = pageno / SLRU_PAGES_PER_SEGMENT;
int rpageno = pageno % SLRU_PAGES_PER_SEGMENT;
off_t offset = rpageno * BLCKSZ;
char path[MAXPGPATH];
int fd = -1;
/* update the stats counter of written pages */
pgstat_count_slru_page_written(shared->slru_stats_idx);
/*
* Honor the write-WAL-before-data rule, if appropriate, so that we do not
* write out data before associated WAL records. This is the same action
* performed during FlushBuffer() in the main buffer manager.
*/
if (shared->group_lsn != NULL)
{
/*
* We must determine the largest async-commit LSN for the page. This
* is a bit tedious, but since this entire function is a slow path
* anyway, it seems better to do this here than to maintain a per-page
* LSN variable (which'd need an extra comparison in the
* transaction-commit path).
*/
XLogRecPtr max_lsn;
int lsnindex,
lsnoff;
lsnindex = slotno * shared->lsn_groups_per_page;
max_lsn = shared->group_lsn[lsnindex++];
for (lsnoff = 1; lsnoff < shared->lsn_groups_per_page; lsnoff++)
{
XLogRecPtr this_lsn = shared->group_lsn[lsnindex++];
if (max_lsn < this_lsn)
max_lsn = this_lsn;
}
if (!XLogRecPtrIsInvalid(max_lsn))
{
/*
* As noted above, elog(ERROR) is not acceptable here, so if
* XLogFlush were to fail, we must PANIC. This isn't much of a
* restriction because XLogFlush is just about all critical
* section anyway, but let's make sure.
*/
START_CRIT_SECTION();
XLogFlush(max_lsn);
END_CRIT_SECTION();
}
}
/*
* During a WriteAll, we may already have the desired file open.
*/
if (fdata)
{
int i;
for (i = 0; i < fdata->num_files; i++)
{
if (fdata->segno[i] == segno)
{
fd = fdata->fd[i];
break;
}
}
}
if (fd < 0)
{
/*
* If the file doesn't already exist, we should create it. It is
* possible for this to need to happen when writing a page that's not
* first in its segment; we assume the OS can cope with that. (Note:
* it might seem that it'd be okay to create files only when
* SimpleLruZeroPage is called for the first page of a segment.
* However, if after a crash and restart the REDO logic elects to
* replay the log from a checkpoint before the latest one, then it's
* possible that we will get commands to set transaction status of
* transactions that have already been truncated from the commit log.
* Easiest way to deal with that is to accept references to
* nonexistent files here and in SlruPhysicalReadPage.)
*
* Note: it is possible for more than one backend to be executing this
* code simultaneously for different pages of the same file. Hence,
* don't use O_EXCL or O_TRUNC or anything like that.
*/
SlruFileName(ctl, path, segno);
fd = OpenTransientFile(path, O_RDWR | O_CREAT | PG_BINARY);
if (fd < 0)
{
slru_errcause = SLRU_OPEN_FAILED;
slru_errno = errno;
return false;
}
if (fdata)
{
if (fdata->num_files < MAX_WRITEALL_BUFFERS)
{
fdata->fd[fdata->num_files] = fd;
fdata->segno[fdata->num_files] = segno;
fdata->num_files++;
}
else
{
/*
* In the unlikely event that we exceed MAX_FLUSH_BUFFERS,
* fall back to treating it as a standalone write.
*/
fdata = NULL;
}
}
}
errno = 0;
pgstat_report_wait_start(WAIT_EVENT_SLRU_WRITE);
if (pg_pwrite(fd, shared->page_buffer[slotno], BLCKSZ, offset) != BLCKSZ)
{
pgstat_report_wait_end();
/* if write didn't set errno, assume problem is no disk space */
if (errno == 0)
errno = ENOSPC;
slru_errcause = SLRU_WRITE_FAILED;
slru_errno = errno;
if (!fdata)
CloseTransientFile(fd);
return false;
}
pgstat_report_wait_end();
/* Queue up a sync request for the checkpointer. */
if (ctl->sync_handler != SYNC_HANDLER_NONE)
{
FileTag tag;
INIT_SLRUFILETAG(tag, ctl->sync_handler, segno);
if (!RegisterSyncRequest(&tag, SYNC_REQUEST, false))
{
/* No space to enqueue sync request. Do it synchronously. */
pgstat_report_wait_start(WAIT_EVENT_SLRU_SYNC);
if (pg_fsync(fd) != 0)
{
pgstat_report_wait_end();
slru_errcause = SLRU_FSYNC_FAILED;
slru_errno = errno;
CloseTransientFile(fd);
return false;
}
pgstat_report_wait_end();
}
}
/* Close file, unless part of flush request. */
if (!fdata)
{
if (CloseTransientFile(fd) != 0)
{
slru_errcause = SLRU_CLOSE_FAILED;
slru_errno = errno;
return false;
}
}
return true;
}
/*
* Issue the error message after failure of SlruPhysicalReadPage or
* SlruPhysicalWritePage. Call this after cleaning up shared-memory state.
*/
static void
SlruReportIOError(SlruCtl ctl, int pageno, TransactionId xid)
{
int segno = pageno / SLRU_PAGES_PER_SEGMENT;
int rpageno = pageno % SLRU_PAGES_PER_SEGMENT;
int offset = rpageno * BLCKSZ;
char path[MAXPGPATH];
SlruFileName(ctl, path, segno);
errno = slru_errno;
switch (slru_errcause)
{
case SLRU_OPEN_FAILED:
ereport(ERROR,
(errcode_for_file_access(),
errmsg("could not access status of transaction %u", xid),
errdetail("Could not open file \"%s\": %m.", path)));
break;
case SLRU_SEEK_FAILED:
ereport(ERROR,
(errcode_for_file_access(),
errmsg("could not access status of transaction %u", xid),
errdetail("Could not seek in file \"%s\" to offset %u: %m.",
path, offset)));
break;
case SLRU_READ_FAILED:
if (errno)
ereport(ERROR,
(errcode_for_file_access(),
errmsg("could not access status of transaction %u", xid),
errdetail("Could not read from file \"%s\" at offset %u: %m.",
path, offset)));
else
ereport(ERROR,
(errmsg("could not access status of transaction %u", xid),
errdetail("Could not read from file \"%s\" at offset %u: read too few bytes.", path, offset)));
break;
case SLRU_WRITE_FAILED:
if (errno)
ereport(ERROR,
(errcode_for_file_access(),
errmsg("could not access status of transaction %u", xid),
errdetail("Could not write to file \"%s\" at offset %u: %m.",
path, offset)));
else
ereport(ERROR,
(errmsg("could not access status of transaction %u", xid),
errdetail("Could not write to file \"%s\" at offset %u: wrote too few bytes.",
path, offset)));
break;
case SLRU_FSYNC_FAILED:
ereport(data_sync_elevel(ERROR),
(errcode_for_file_access(),
errmsg("could not access status of transaction %u", xid),
errdetail("Could not fsync file \"%s\": %m.",
path)));
break;
case SLRU_CLOSE_FAILED:
ereport(ERROR,
(errcode_for_file_access(),
errmsg("could not access status of transaction %u", xid),
errdetail("Could not close file \"%s\": %m.",
path)));
break;
default:
/* can't get here, we trust */
elog(ERROR, "unrecognized SimpleLru error cause: %d",
(int) slru_errcause);
break;
}
}
/*
* Select the slot to re-use when we need a free slot.
*
* The target page number is passed because we need to consider the
* possibility that some other process reads in the target page while
* we are doing I/O to free a slot. Hence, check or recheck to see if
* any slot already holds the target page, and return that slot if so.
* Thus, the returned slot is *either* a slot already holding the pageno
* (could be any state except EMPTY), *or* a freeable slot (state EMPTY
* or CLEAN).
*
* Control lock must be held at entry, and will be held at exit.
*/
static int
SlruSelectLRUPage(SlruCtl ctl, int pageno)
{
SlruShared shared = ctl->shared;
/* Outer loop handles restart after I/O */
for (;;)
{
int slotno;
int cur_count;
int bestvalidslot = 0; /* keep compiler quiet */
int best_valid_delta = -1;
int best_valid_page_number = 0; /* keep compiler quiet */
int bestinvalidslot = 0; /* keep compiler quiet */
int best_invalid_delta = -1;
int best_invalid_page_number = 0; /* keep compiler quiet */
/* See if page already has a buffer assigned */
for (slotno = 0; slotno < shared->num_slots; slotno++)
{
if (shared->page_number[slotno] == pageno &&
shared->page_status[slotno] != SLRU_PAGE_EMPTY)
return slotno;
}
/*
* If we find any EMPTY slot, just select that one. Else choose a
* victim page to replace. We normally take the least recently used
* valid page, but we will never take the slot containing
* latest_page_number, even if it appears least recently used. We
* will select a slot that is already I/O busy only if there is no
* other choice: a read-busy slot will not be least recently used once
* the read finishes, and waiting for an I/O on a write-busy slot is
* inferior to just picking some other slot. Testing shows the slot
* we pick instead will often be clean, allowing us to begin a read at
* once.
*
* Normally the page_lru_count values will all be different and so
* there will be a well-defined LRU page. But since we allow
* concurrent execution of SlruRecentlyUsed() within
* SimpleLruReadPage_ReadOnly(), it is possible that multiple pages
* acquire the same lru_count values. In that case we break ties by
* choosing the furthest-back page.
*
* Notice that this next line forcibly advances cur_lru_count to a
* value that is certainly beyond any value that will be in the
* page_lru_count array after the loop finishes. This ensures that
* the next execution of SlruRecentlyUsed will mark the page newly
* used, even if it's for a page that has the current counter value.
* That gets us back on the path to having good data when there are
* multiple pages with the same lru_count.
*/
cur_count = (shared->cur_lru_count)++;
for (slotno = 0; slotno < shared->num_slots; slotno++)
{
int this_delta;
int this_page_number;
if (shared->page_status[slotno] == SLRU_PAGE_EMPTY)
return slotno;
this_delta = cur_count - shared->page_lru_count[slotno];
if (this_delta < 0)
{
/*
* Clean up in case shared updates have caused cur_count
* increments to get "lost". We back off the page counts,
* rather than trying to increase cur_count, to avoid any
* question of infinite loops or failure in the presence of
* wrapped-around counts.
*/
shared->page_lru_count[slotno] = cur_count;
this_delta = 0;
}
this_page_number = shared->page_number[slotno];
if (this_page_number == shared->latest_page_number)
continue;
if (shared->page_status[slotno] == SLRU_PAGE_VALID)
{
if (this_delta > best_valid_delta ||
(this_delta == best_valid_delta &&
ctl->PagePrecedes(this_page_number,
best_valid_page_number)))
{
bestvalidslot = slotno;
best_valid_delta = this_delta;
best_valid_page_number = this_page_number;
}
}
else
{
if (this_delta > best_invalid_delta ||
(this_delta == best_invalid_delta &&
ctl->PagePrecedes(this_page_number,
best_invalid_page_number)))
{
bestinvalidslot = slotno;
best_invalid_delta = this_delta;
best_invalid_page_number = this_page_number;
}
}
}
/*
* If all pages (except possibly the latest one) are I/O busy, we'll
* have to wait for an I/O to complete and then retry. In that
* unhappy case, we choose to wait for the I/O on the least recently
* used slot, on the assumption that it was likely initiated first of
* all the I/Os in progress and may therefore finish first.
*/
if (best_valid_delta < 0)
{
SimpleLruWaitIO(ctl, bestinvalidslot);
continue;
}
/*
* If the selected page is clean, we're set.
*/
if (!shared->page_dirty[bestvalidslot])
return bestvalidslot;
/*
* Write the page.
*/
SlruInternalWritePage(ctl, bestvalidslot, NULL);
/*
* Now loop back and try again. This is the easiest way of dealing
* with corner cases such as the victim page being re-dirtied while we
* wrote it.
*/
}
}
/*
* Write dirty pages to disk during checkpoint or database shutdown. Flushing
* is deferred until the next call to ProcessSyncRequests(), though we do fsync
* the containing directory here to make sure that newly created directory
* entries are on disk.
*/
void
SimpleLruWriteAll(SlruCtl ctl, bool allow_redirtied)
{
SlruShared shared = ctl->shared;
SlruWriteAllData fdata;
int slotno;
int pageno = 0;
int i;
bool ok;
/* update the stats counter of flushes */
pgstat_count_slru_flush(shared->slru_stats_idx);
/*
* Find and write dirty pages
*/
fdata.num_files = 0;
LWLockAcquire(shared->ControlLock, LW_EXCLUSIVE);
for (slotno = 0; slotno < shared->num_slots; slotno++)
{
SlruInternalWritePage(ctl, slotno, &fdata);
/*
* In some places (e.g. checkpoints), we cannot assert that the slot
* is clean now, since another process might have re-dirtied it
* already. That's okay.
*/
Assert(allow_redirtied ||
shared->page_status[slotno] == SLRU_PAGE_EMPTY ||
(shared->page_status[slotno] == SLRU_PAGE_VALID &&
!shared->page_dirty[slotno]));
}
LWLockRelease(shared->ControlLock);
/*
* Now close any files that were open
*/
ok = true;
for (i = 0; i < fdata.num_files; i++)
{
if (CloseTransientFile(fdata.fd[i]) != 0)
{
slru_errcause = SLRU_CLOSE_FAILED;
slru_errno = errno;
pageno = fdata.segno[i] * SLRU_PAGES_PER_SEGMENT;
ok = false;
}
}
if (!ok)
SlruReportIOError(ctl, pageno, InvalidTransactionId);
/* Ensure that directory entries for new files are on disk. */
if (ctl->sync_handler != SYNC_HANDLER_NONE)
fsync_fname(ctl->Dir, true);
}
/*
* Remove all segments before the one holding the passed page number
*
* All SLRUs prevent concurrent calls to this function, either with an LWLock
* or by calling it only as part of a checkpoint. Mutual exclusion must begin
* before computing cutoffPage. Mutual exclusion must end after any limit
* update that would permit other backends to write fresh data into the
* segment immediately preceding the one containing cutoffPage. Otherwise,
* when the SLRU is quite full, SimpleLruTruncate() might delete that segment
* after it has accrued freshly-written data.
*/
void
SimpleLruTruncate(SlruCtl ctl, int cutoffPage)
{
SlruShared shared = ctl->shared;
int slotno;
/* update the stats counter of truncates */
pgstat_count_slru_truncate(shared->slru_stats_idx);
/*
* Scan shared memory and remove any pages preceding the cutoff page, to
* ensure we won't rewrite them later. (Since this is normally called in
* or just after a checkpoint, any dirty pages should have been flushed
* already ... we're just being extra careful here.)
*/
LWLockAcquire(shared->ControlLock, LW_EXCLUSIVE);
restart:;
/*
* While we are holding the lock, make an important safety check: the
* current endpoint page must not be eligible for removal.
*/
if (ctl->PagePrecedes(shared->latest_page_number, cutoffPage))
{
LWLockRelease(shared->ControlLock);
ereport(LOG,
(errmsg("could not truncate directory \"%s\": apparent wraparound",
ctl->Dir)));
return;
}
for (slotno = 0; slotno < shared->num_slots; slotno++)
{
if (shared->page_status[slotno] == SLRU_PAGE_EMPTY)
continue;
if (!ctl->PagePrecedes(shared->page_number[slotno], cutoffPage))
continue;
/*
* If page is clean, just change state to EMPTY (expected case).
*/
if (shared->page_status[slotno] == SLRU_PAGE_VALID &&
!shared->page_dirty[slotno])
{
shared->page_status[slotno] = SLRU_PAGE_EMPTY;
continue;
}
/*
* Hmm, we have (or may have) I/O operations acting on the page, so
* we've got to wait for them to finish and then start again. This is
* the same logic as in SlruSelectLRUPage. (XXX if page is dirty,
* wouldn't it be OK to just discard it without writing it?
* SlruMayDeleteSegment() uses a stricter qualification, so we might
* not delete this page in the end; even if we don't delete it, we
* won't have cause to read its data again. For now, keep the logic
* the same as it was.)
*/
if (shared->page_status[slotno] == SLRU_PAGE_VALID)
SlruInternalWritePage(ctl, slotno, NULL);
else
SimpleLruWaitIO(ctl, slotno);
goto restart;
}
LWLockRelease(shared->ControlLock);
/* Now we can remove the old segment(s) */
(void) SlruScanDirectory(ctl, SlruScanDirCbDeleteCutoff, &cutoffPage);
}
/*
* Delete an individual SLRU segment.
*
* NB: This does not touch the SLRU buffers themselves, callers have to ensure
* they either can't yet contain anything, or have already been cleaned out.
*/
static void
SlruInternalDeleteSegment(SlruCtl ctl, int segno)
{
char path[MAXPGPATH];
/* Forget any fsync requests queued for this segment. */
if (ctl->sync_handler != SYNC_HANDLER_NONE)
{
FileTag tag;
INIT_SLRUFILETAG(tag, ctl->sync_handler, segno);
RegisterSyncRequest(&tag, SYNC_FORGET_REQUEST, true);
}
/* Unlink the file. */
SlruFileName(ctl, path, segno);
ereport(DEBUG2, (errmsg_internal("removing file \"%s\"", path)));
unlink(path);
}
/*
* Delete an individual SLRU segment, identified by the segment number.
*/
void
SlruDeleteSegment(SlruCtl ctl, int segno)
{
SlruShared shared = ctl->shared;
int slotno;
bool did_write;
/* Clean out any possibly existing references to the segment. */
LWLockAcquire(shared->ControlLock, LW_EXCLUSIVE);
restart:
did_write = false;
for (slotno = 0; slotno < shared->num_slots; slotno++)
{
int pagesegno = shared->page_number[slotno] / SLRU_PAGES_PER_SEGMENT;
if (shared->page_status[slotno] == SLRU_PAGE_EMPTY)
continue;
/* not the segment we're looking for */
if (pagesegno != segno)
continue;
/* If page is clean, just change state to EMPTY (expected case). */
if (shared->page_status[slotno] == SLRU_PAGE_VALID &&
!shared->page_dirty[slotno])
{
shared->page_status[slotno] = SLRU_PAGE_EMPTY;
continue;
}
/* Same logic as SimpleLruTruncate() */
if (shared->page_status[slotno] == SLRU_PAGE_VALID)
SlruInternalWritePage(ctl, slotno, NULL);
else
SimpleLruWaitIO(ctl, slotno);
did_write = true;
}
/*
* Be extra careful and re-check. The IO functions release the control
* lock, so new pages could have been read in.
*/
if (did_write)
goto restart;
SlruInternalDeleteSegment(ctl, segno);
LWLockRelease(shared->ControlLock);
}
/*
* Determine whether a segment is okay to delete.
*
* segpage is the first page of the segment, and cutoffPage is the oldest (in
* PagePrecedes order) page in the SLRU containing still-useful data. Since
* every core PagePrecedes callback implements "wrap around", check the
* segment's first and last pages:
*
* first<cutoff && last<cutoff: yes
* first<cutoff && last>=cutoff: no; cutoff falls inside this segment
* first>=cutoff && last<cutoff: no; wrap point falls inside this segment
* first>=cutoff && last>=cutoff: no; every page of this segment is too young
*/
static bool
SlruMayDeleteSegment(SlruCtl ctl, int segpage, int cutoffPage)
{
int seg_last_page = segpage + SLRU_PAGES_PER_SEGMENT - 1;
Assert(segpage % SLRU_PAGES_PER_SEGMENT == 0);
return (ctl->PagePrecedes(segpage, cutoffPage) &&
ctl->PagePrecedes(seg_last_page, cutoffPage));
}
#ifdef USE_ASSERT_CHECKING
static void
SlruPagePrecedesTestOffset(SlruCtl ctl, int per_page, uint32 offset)
{
TransactionId lhs,
rhs;
int newestPage,
oldestPage;
TransactionId newestXact,
oldestXact;
/*
* Compare an XID pair having undefined order (see RFC 1982), a pair at
* "opposite ends" of the XID space. TransactionIdPrecedes() treats each
* as preceding the other. If RHS is oldestXact, LHS is the first XID we
* must not assign.
*/
lhs = per_page + offset; /* skip first page to avoid non-normal XIDs */
rhs = lhs + (1U << 31);
Assert(TransactionIdPrecedes(lhs, rhs));
Assert(TransactionIdPrecedes(rhs, lhs));
Assert(!TransactionIdPrecedes(lhs - 1, rhs));
Assert(TransactionIdPrecedes(rhs, lhs - 1));
Assert(TransactionIdPrecedes(lhs + 1, rhs));
Assert(!TransactionIdPrecedes(rhs, lhs + 1));
Assert(!TransactionIdFollowsOrEquals(lhs, rhs));
Assert(!TransactionIdFollowsOrEquals(rhs, lhs));
Assert(!ctl->PagePrecedes(lhs / per_page, lhs / per_page));
Assert(!ctl->PagePrecedes(lhs / per_page, rhs / per_page));
Assert(!ctl->PagePrecedes(rhs / per_page, lhs / per_page));
Assert(!ctl->PagePrecedes((lhs - per_page) / per_page, rhs / per_page));
Assert(ctl->PagePrecedes(rhs / per_page, (lhs - 3 * per_page) / per_page));
Assert(ctl->PagePrecedes(rhs / per_page, (lhs - 2 * per_page) / per_page));
Assert(ctl->PagePrecedes(rhs / per_page, (lhs - 1 * per_page) / per_page)
|| (1U << 31) % per_page != 0); /* See CommitTsPagePrecedes() */
Assert(ctl->PagePrecedes((lhs + 1 * per_page) / per_page, rhs / per_page)
|| (1U << 31) % per_page != 0);
Assert(ctl->PagePrecedes((lhs + 2 * per_page) / per_page, rhs / per_page));
Assert(ctl->PagePrecedes((lhs + 3 * per_page) / per_page, rhs / per_page));
Assert(!ctl->PagePrecedes(rhs / per_page, (lhs + per_page) / per_page));
/*
* GetNewTransactionId() has assigned the last XID it can safely use, and
* that XID is in the *LAST* page of the second segment. We must not
* delete that segment.
*/
newestPage = 2 * SLRU_PAGES_PER_SEGMENT - 1;
newestXact = newestPage * per_page + offset;
Assert(newestXact / per_page == newestPage);
oldestXact = newestXact + 1;
oldestXact -= 1U << 31;
oldestPage = oldestXact / per_page;
Assert(!SlruMayDeleteSegment(ctl,
(newestPage -
newestPage % SLRU_PAGES_PER_SEGMENT),
oldestPage));
/*
* GetNewTransactionId() has assigned the last XID it can safely use, and
* that XID is in the *FIRST* page of the second segment. We must not
* delete that segment.
*/
newestPage = SLRU_PAGES_PER_SEGMENT;
newestXact = newestPage * per_page + offset;
Assert(newestXact / per_page == newestPage);
oldestXact = newestXact + 1;
oldestXact -= 1U << 31;
oldestPage = oldestXact / per_page;
Assert(!SlruMayDeleteSegment(ctl,
(newestPage -
newestPage % SLRU_PAGES_PER_SEGMENT),
oldestPage));
}
/*
* Unit-test a PagePrecedes function.
*
* This assumes every uint32 >= FirstNormalTransactionId is a valid key. It
* assumes each value occupies a contiguous, fixed-size region of SLRU bytes.
* (MultiXactMemberCtl separates flags from XIDs. AsyncCtl has
* variable-length entries, no keys, and no random access. These unit tests
* do not apply to them.)
*/
void
SlruPagePrecedesUnitTests(SlruCtl ctl, int per_page)
{
/* Test first, middle and last entries of a page. */
SlruPagePrecedesTestOffset(ctl, per_page, 0);
SlruPagePrecedesTestOffset(ctl, per_page, per_page / 2);
SlruPagePrecedesTestOffset(ctl, per_page, per_page - 1);
}
#endif
/*
* SlruScanDirectory callback
* This callback reports true if there's any segment wholly prior to the
* one containing the page passed as "data".
*/
bool
SlruScanDirCbReportPresence(SlruCtl ctl, char *filename, int segpage, void *data)
{
int cutoffPage = *(int *) data;
if (SlruMayDeleteSegment(ctl, segpage, cutoffPage))
return true; /* found one; don't iterate any more */
return false; /* keep going */
}
/*
* SlruScanDirectory callback.
* This callback deletes segments prior to the one passed in as "data".
*/
static bool
SlruScanDirCbDeleteCutoff(SlruCtl ctl, char *filename, int segpage, void *data)
{
int cutoffPage = *(int *) data;
if (SlruMayDeleteSegment(ctl, segpage, cutoffPage))
SlruInternalDeleteSegment(ctl, segpage / SLRU_PAGES_PER_SEGMENT);
return false; /* keep going */
}
/*
* SlruScanDirectory callback.
* This callback deletes all segments.
*/
bool
SlruScanDirCbDeleteAll(SlruCtl ctl, char *filename, int segpage, void *data)
{
SlruInternalDeleteSegment(ctl, segpage / SLRU_PAGES_PER_SEGMENT);
return false; /* keep going */
}
/*
* Scan the SimpleLru directory and apply a callback to each file found in it.
*
* If the callback returns true, the scan is stopped. The last return value
* from the callback is returned.
*
* The callback receives the following arguments: 1. the SlruCtl struct for the
* slru being truncated; 2. the filename being considered; 3. the page number
* for the first page of that file; 4. a pointer to the opaque data given to us
* by the caller.
*
* Note that the ordering in which the directory is scanned is not guaranteed.
*
* Note that no locking is applied.
*/
bool
SlruScanDirectory(SlruCtl ctl, SlruScanCallback callback, void *data)
{
bool retval = false;
DIR *cldir;
struct dirent *clde;
int segno;
int segpage;
cldir = AllocateDir(ctl->Dir);
while ((clde = ReadDir(cldir, ctl->Dir)) != NULL)
{
size_t len;
len = strlen(clde->d_name);
if ((len == 4 || len == 5 || len == 6) &&
strspn(clde->d_name, "0123456789ABCDEF") == len)
{
segno = (int) strtol(clde->d_name, NULL, 16);
segpage = segno * SLRU_PAGES_PER_SEGMENT;
elog(DEBUG2, "SlruScanDirectory invoking callback on %s/%s",
ctl->Dir, clde->d_name);
retval = callback(ctl, clde->d_name, segpage, data);
if (retval)
break;
}
}
FreeDir(cldir);
return retval;
}
/*
* Individual SLRUs (clog, ...) have to provide a sync.c handler function so
* that they can provide the correct "SlruCtl" (otherwise we don't know how to
* build the path), but they just forward to this common implementation that
* performs the fsync.
*/
int
SlruSyncFileTag(SlruCtl ctl, const FileTag *ftag, char *path)
{
int fd;
int save_errno;
int result;
SlruFileName(ctl, path, ftag->segno);
fd = OpenTransientFile(path, O_RDWR | PG_BINARY);
if (fd < 0)
return -1;
result = pg_fsync(fd);
save_errno = errno;
CloseTransientFile(fd);
errno = save_errno;
return result;
}
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