/* * $Id: store_dir_ufs.c,v 1.65.2.1 2008/01/02 15:49:37 hno Exp $ * * DEBUG: section 47 Store Directory Routines * AUTHOR: Duane Wessels * * SQUID Web Proxy Cache http://www.squid-cache.org/ * ---------------------------------------------------------- * * Squid is the result of efforts by numerous individuals from * the Internet community; see the CONTRIBUTORS file for full * details. Many organizations have provided support for Squid's * development; see the SPONSORS file for full details. Squid is * Copyrighted (C) 2001 by the Regents of the University of * California; see the COPYRIGHT file for full details. Squid * incorporates software developed and/or copyrighted by other * sources; see the CREDITS file for full details. * * This program is free software; you can redistribute it and/or modify * it under the terms of the GNU General Public License as published by * the Free Software Foundation; either version 2 of the License, or * (at your option) any later version. * * This program is distributed in the hope that it will be useful, * but WITHOUT ANY WARRANTY; without even the implied warranty of * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the * GNU General Public License for more details. * * You should have received a copy of the GNU General Public License * along with this program; if not, write to the Free Software * Foundation, Inc., 59 Temple Place, Suite 330, Boston, MA 02111, USA. * */ #include "squid.h" #include "store_ufs.h" #define DefaultLevelOneDirs 16 #define DefaultLevelTwoDirs 256 #define STORE_META_BUFSZ 4096 typedef struct _RebuildState RebuildState; struct _RebuildState { SwapDir *sd; int n_read; FILE *log; int speed; int curlvl1; int curlvl2; struct { unsigned int clean:1; unsigned int init:1; } flags; int done; int in_dir; int fn; struct dirent *entry; DIR *td; char fullpath[SQUID_MAXPATHLEN]; char fullfilename[SQUID_MAXPATHLEN]; struct _store_rebuild_data counts; }; static int n_ufs_dirs = 0; static int *ufs_dir_index = NULL; MemPool *ufs_state_pool = NULL; static int ufs_initialised = 0; static char *storeUfsDirSwapSubDir(SwapDir *, int subdirn); static int storeUfsDirCreateDirectory(const char *path, int); static int storeUfsDirVerifyCacheDirs(SwapDir *); static int storeUfsDirVerifyDirectory(const char *path); static void storeUfsDirCreateSwapSubDirs(SwapDir *); static char *storeUfsDirSwapLogFile(SwapDir *, const char *); static EVH storeUfsDirRebuildFromDirectory; static EVH storeUfsDirRebuildFromSwapLog; static int storeUfsDirGetNextFile(RebuildState *, sfileno *, int *size); static StoreEntry *storeUfsDirAddDiskRestore(SwapDir * SD, const cache_key * key, int file_number, squid_file_sz swap_file_sz, time_t expires, time_t timestamp, time_t lastref, time_t lastmod, u_num32 refcount, u_short flags, int clean); static void storeUfsDirRebuild(SwapDir * sd); static void storeUfsDirCloseTmpSwapLog(SwapDir * sd); static FILE *storeUfsDirOpenTmpSwapLog(SwapDir *, int *, int *); static STLOGOPEN storeUfsDirOpenSwapLog; static STINIT storeUfsDirInit; static STFREE storeUfsDirFree; static STLOGCLEANSTART storeUfsDirWriteCleanStart; static STLOGCLEANNEXTENTRY storeUfsDirCleanLogNextEntry; static STLOGCLEANWRITE storeUfsDirWriteCleanEntry; static STLOGCLEANDONE storeUfsDirWriteCleanDone; static STLOGCLOSE storeUfsDirCloseSwapLog; static STLOGWRITE storeUfsDirSwapLog; static STNEWFS storeUfsDirNewfs; static STDUMP storeUfsDirDump; static STMAINTAINFS storeUfsDirMaintain; static STCHECKOBJ storeUfsDirCheckObj; static STCHECKLOADAV storeUfsDirCheckLoadAv; static STREFOBJ storeUfsDirRefObj; static STUNREFOBJ storeUfsDirUnrefObj; static QS rev_int_sort; static int storeUfsDirClean(int swap_index); static EVH storeUfsDirCleanEvent; static int storeUfsDirIs(SwapDir * sd); static int storeUfsFilenoBelongsHere(int fn, int F0, int F1, int F2); static int storeUfsCleanupDoubleCheck(SwapDir *, StoreEntry *); static void storeUfsDirStats(SwapDir *, StoreEntry *); static void storeUfsDirInitBitmap(SwapDir *); static int storeUfsDirValidFileno(SwapDir *, sfileno, int); STSETUP storeFsSetup_ufs; /* * These functions were ripped straight out of the heart of store_dir.c. * They assume that the given filenum is on a ufs partiton, which may or * may not be true.. * XXX this evilness should be tidied up at a later date! */ static int storeUfsDirMapBitTest(SwapDir * SD, sfileno filn) { ufsinfo_t *ufsinfo; ufsinfo = (ufsinfo_t *) SD->fsdata; return file_map_bit_test(ufsinfo->map, filn); } static void storeUfsDirMapBitSet(SwapDir * SD, int fn) { sfileno filn = fn; ufsinfo_t *ufsinfo; ufsinfo = (ufsinfo_t *) SD->fsdata; file_map_bit_set(ufsinfo->map, filn); } void storeUfsDirMapBitReset(SwapDir * SD, int fn) { sfileno filn = fn; ufsinfo_t *ufsinfo; ufsinfo = (ufsinfo_t *) SD->fsdata; /* * We have to test the bit before calling file_map_bit_reset. * file_map_bit_reset doesn't do bounds checking. It assumes * filn is a valid file number, but it might not be because * the map is dynamic in size. Also clearing an already clear * bit puts the map counter of-of-whack. */ if (file_map_bit_test(ufsinfo->map, filn)) file_map_bit_reset(ufsinfo->map, filn); } int storeUfsDirMapBitAllocate(SwapDir * SD) { ufsinfo_t *ufsinfo = (ufsinfo_t *) SD->fsdata; int fn; fn = file_map_allocate(ufsinfo->map, ufsinfo->suggest); file_map_bit_set(ufsinfo->map, fn); ufsinfo->suggest = fn + 1; return fn; } /* * Initialise the ufs bitmap * * If there already is a bitmap, and the numobjects is larger than currently * configured, we allocate a new bitmap and 'grow' the old one into it. */ static void storeUfsDirInitBitmap(SwapDir * sd) { ufsinfo_t *ufsinfo = (ufsinfo_t *) sd->fsdata; if (ufsinfo->map == NULL) { /* First time */ ufsinfo->map = file_map_create(); } else if (ufsinfo->map->max_n_files) { /* it grew, need to expand */ /* XXX We don't need it anymore .. */ } /* else it shrunk, and we leave the old one in place */ } static char * storeUfsDirSwapSubDir(SwapDir * sd, int subdirn) { ufsinfo_t *ufsinfo = (ufsinfo_t *) sd->fsdata; LOCAL_ARRAY(char, fullfilename, SQUID_MAXPATHLEN); assert(0 <= subdirn && subdirn < ufsinfo->l1); snprintf(fullfilename, SQUID_MAXPATHLEN, "%s/%02X", sd->path, subdirn); return fullfilename; } static int storeUfsDirCreateDirectory(const char *path, int should_exist) { int created = 0; struct stat st; getCurrentTime(); if (0 == stat(path, &st)) { if (S_ISDIR(st.st_mode)) { debug(47, should_exist ? 3 : 1) ("%s exists\n", path); } else { fatalf("Swap directory %s is not a directory.", path); } #ifdef _SQUID_MSWIN_ } else if (0 == mkdir(path)) { #else } else if (0 == mkdir(path, 0755)) { #endif debug(47, should_exist ? 1 : 3) ("%s created\n", path); created = 1; } else { fatalf("Failed to make swap directory %s: %s", path, xstrerror()); } return created; } static int storeUfsDirVerifyDirectory(const char *path) { struct stat sb; if (stat(path, &sb) < 0) { debug(47, 0) ("%s: %s\n", path, xstrerror()); return -1; } if (S_ISDIR(sb.st_mode) == 0) { debug(47, 0) ("%s is not a directory\n", path); return -1; } return 0; } /* * This function is called by storeUfsDirInit(). If this returns < 0, * then Squid exits, complains about swap directories not * existing, and instructs the admin to run 'squid -z' */ static int storeUfsDirVerifyCacheDirs(SwapDir * sd) { ufsinfo_t *ufsinfo = (ufsinfo_t *) sd->fsdata; int j; const char *path = sd->path; if (storeUfsDirVerifyDirectory(path) < 0) return -1; for (j = 0; j < ufsinfo->l1; j++) { path = storeUfsDirSwapSubDir(sd, j); if (storeUfsDirVerifyDirectory(path) < 0) return -1; } return 0; } static void storeUfsDirCreateSwapSubDirs(SwapDir * sd) { ufsinfo_t *ufsinfo = (ufsinfo_t *) sd->fsdata; int i, k; int should_exist; LOCAL_ARRAY(char, name, MAXPATHLEN); for (i = 0; i < ufsinfo->l1; i++) { snprintf(name, MAXPATHLEN, "%s/%02X", sd->path, i); if (storeUfsDirCreateDirectory(name, 0)) should_exist = 0; else should_exist = 1; debug(47, 1) ("Making directories in %s\n", name); for (k = 0; k < ufsinfo->l2; k++) { snprintf(name, MAXPATHLEN, "%s/%02X/%02X", sd->path, i, k); storeUfsDirCreateDirectory(name, should_exist); } } } static char * storeUfsDirSwapLogFile(SwapDir * sd, const char *ext) { LOCAL_ARRAY(char, path, SQUID_MAXPATHLEN); LOCAL_ARRAY(char, pathtmp, SQUID_MAXPATHLEN); LOCAL_ARRAY(char, digit, 32); char *pathtmp2; if (Config.Log.swap) { xstrncpy(pathtmp, sd->path, SQUID_MAXPATHLEN - 64); pathtmp2 = pathtmp; while ((pathtmp2 = strchr(pathtmp2, '/')) != NULL) *pathtmp2 = '.'; while (strlen(pathtmp) && pathtmp[strlen(pathtmp) - 1] == '.') pathtmp[strlen(pathtmp) - 1] = '\0'; for (pathtmp2 = pathtmp; *pathtmp2 == '.'; pathtmp2++); snprintf(path, SQUID_MAXPATHLEN - 64, Config.Log.swap, pathtmp2); if (strncmp(path, Config.Log.swap, SQUID_MAXPATHLEN - 64) == 0) { strcat(path, "."); snprintf(digit, 32, "%02d", sd->index); strncat(path, digit, 3); } } else { xstrncpy(path, sd->path, SQUID_MAXPATHLEN - 64); strcat(path, "/swap.state"); } if (ext) strncat(path, ext, 16); return path; } static void storeUfsDirOpenSwapLog(SwapDir * sd) { ufsinfo_t *ufsinfo = (ufsinfo_t *) sd->fsdata; char *path; int fd; path = storeUfsDirSwapLogFile(sd, NULL); if (ufsinfo->swaplog_fd >= 0) { debug(50, 1) ("storeUfsDirOpenSwapLog: %s already open\n", path); return; } fd = file_open(path, O_WRONLY | O_CREAT | O_BINARY); if (fd < 0) { debug(50, 1) ("%s: %s\n", path, xstrerror()); fatal("storeUfsDirOpenSwapLog: Failed to open swap log."); } debug(50, 3) ("Cache Dir #%d log opened on FD %d\n", sd->index, fd); ufsinfo->swaplog_fd = fd; if (0 == n_ufs_dirs) assert(NULL == ufs_dir_index); n_ufs_dirs++; assert(n_ufs_dirs <= Config.cacheSwap.n_configured); } static void storeUfsDirCloseSwapLog(SwapDir * sd) { ufsinfo_t *ufsinfo = (ufsinfo_t *) sd->fsdata; if (ufsinfo->swaplog_fd < 0) /* not open */ return; file_close(ufsinfo->swaplog_fd); debug(47, 3) ("Cache Dir #%d log closed on FD %d\n", sd->index, ufsinfo->swaplog_fd); ufsinfo->swaplog_fd = -1; n_ufs_dirs--; assert(n_ufs_dirs >= 0); if (0 == n_ufs_dirs) safe_free(ufs_dir_index); } static void storeUfsCheckConfig(SwapDir * sd) { if (!opt_create_swap_dirs) requirePathnameExists("cache_dir", sd->path); } static void storeUfsDirInit(SwapDir * sd) { static int started_clean_event = 0; static const char *errmsg = "\tFailed to verify one of the swap directories, Check cache.log\n" "\tfor details. Run 'squid -z' to create swap directories\n" "\tif needed, or if running Squid for the first time."; storeUfsDirInitBitmap(sd); if (storeUfsDirVerifyCacheDirs(sd) < 0) fatal(errmsg); storeUfsDirOpenSwapLog(sd); storeUfsDirRebuild(sd); if (!started_clean_event) { eventAdd("storeDirClean", storeUfsDirCleanEvent, NULL, 15.0, 1); started_clean_event = 1; } (void) storeDirGetBlkSize(sd->path, &sd->fs.blksize); } static void storeUfsDirRebuildComplete(RebuildState * rb) { if (rb->log) { debug(47, 1) ("Done reading %s swaplog (%d entries)\n", rb->sd->path, rb->n_read); fclose(rb->log); rb->log = NULL; } else { debug(47, 1) ("Done scanning %s (%d entries)\n", rb->sd->path, rb->counts.scancount); } store_dirs_rebuilding--; storeUfsDirCloseTmpSwapLog(rb->sd); storeRebuildComplete(&rb->counts); cbdataFree(rb); } static void storeUfsDirRebuildFromDirectory(void *data) { RebuildState *rb = data; SwapDir *SD = rb->sd; LOCAL_ARRAY(char, hdr_buf, SM_PAGE_SIZE); StoreEntry *e = NULL; StoreEntry tmpe; cache_key key[SQUID_MD5_DIGEST_LENGTH]; sfileno filn = 0; int count; int size; struct stat sb; int swap_hdr_len; int fd = -1; tlv *tlv_list; tlv *t; assert(rb != NULL); debug(47, 3) ("storeUfsDirRebuildFromDirectory: DIR #%d\n", rb->sd->index); for (count = 0; count < rb->speed; count++) { assert(fd == -1); fd = storeUfsDirGetNextFile(rb, &filn, &size); if (fd == -2) { storeUfsDirRebuildComplete(rb); return; } else if (fd < 0) { continue; } assert(fd > -1); /* lets get file stats here */ if (fstat(fd, &sb) < 0) { debug(47, 1) ("storeUfsDirRebuildFromDirectory: fstat(FD %d): %s\n", fd, xstrerror()); file_close(fd); store_open_disk_fd--; fd = -1; continue; } if ((++rb->counts.scancount & 0xFFFF) == 0) debug(47, 3) (" %s %7d files opened so far.\n", rb->sd->path, rb->counts.scancount); debug(47, 9) ("file_in: fd=%d %08X\n", fd, filn); statCounter.syscalls.disk.reads++; if (FD_READ_METHOD(fd, hdr_buf, SM_PAGE_SIZE) < 0) { debug(47, 1) ("storeUfsDirRebuildFromDirectory: read(FD %d): %s\n", fd, xstrerror()); file_close(fd); store_open_disk_fd--; fd = -1; continue; } file_close(fd); store_open_disk_fd--; fd = -1; swap_hdr_len = 0; #if USE_TRUNCATE if (sb.st_size == 0) continue; #endif tlv_list = storeSwapMetaUnpack(hdr_buf, &swap_hdr_len); if (tlv_list == NULL) { debug(47, 1) ("storeUfsDirRebuildFromDirectory: failed to get meta data\n"); /* XXX shouldn't this be a call to storeUfsUnlink ? */ storeUfsDirUnlinkFile(SD, filn); continue; } debug(47, 3) ("storeUfsDirRebuildFromDirectory: successful swap meta unpacking\n"); memset(key, '\0', SQUID_MD5_DIGEST_LENGTH); memset(&tmpe, '\0', sizeof(StoreEntry)); for (t = tlv_list; t; t = t->next) { switch (t->type) { case STORE_META_KEY: assert(t->length == SQUID_MD5_DIGEST_LENGTH); xmemcpy(key, t->value, SQUID_MD5_DIGEST_LENGTH); break; #if SIZEOF_SQUID_FILE_SZ == SIZEOF_SIZE_T case STORE_META_STD: assert(t->length == STORE_HDR_METASIZE); xmemcpy(&tmpe.timestamp, t->value, STORE_HDR_METASIZE); break; #else case STORE_META_STD_LFS: assert(t->length == STORE_HDR_METASIZE); xmemcpy(&tmpe.timestamp, t->value, STORE_HDR_METASIZE); break; case STORE_META_STD: assert(t->length == STORE_HDR_METASIZE_OLD); { struct { time_t timestamp; time_t lastref; time_t expires; time_t lastmod; size_t swap_file_sz; u_short refcount; u_short flags; } *tmp = t->value; assert(sizeof(*tmp) == STORE_HDR_METASIZE_OLD); tmpe.timestamp = tmp->timestamp; tmpe.lastref = tmp->lastref; tmpe.expires = tmp->expires; tmpe.lastmod = tmp->lastmod; tmpe.swap_file_sz = tmp->swap_file_sz; tmpe.refcount = tmp->refcount; tmpe.flags = tmp->flags; } break; #endif default: break; } } storeSwapTLVFree(tlv_list); tlv_list = NULL; if (storeKeyNull(key)) { debug(47, 1) ("storeUfsDirRebuildFromDirectory: NULL key\n"); storeUfsDirUnlinkFile(SD, filn); continue; } tmpe.hash.key = key; /* check sizes */ if (tmpe.swap_file_sz == 0) { tmpe.swap_file_sz = sb.st_size; } else if (tmpe.swap_file_sz == sb.st_size - swap_hdr_len) { tmpe.swap_file_sz = sb.st_size; } else if (tmpe.swap_file_sz != sb.st_size) { debug(47, 1) ("storeUfsDirRebuildFromDirectory: SIZE MISMATCH %ld!=%ld\n", (long int) tmpe.swap_file_sz, (long int) sb.st_size); storeUfsDirUnlinkFile(SD, filn); continue; } if (EBIT_TEST(tmpe.flags, KEY_PRIVATE)) { storeUfsDirUnlinkFile(SD, filn); rb->counts.badflags++; continue; } e = storeGet(key); if (e && e->lastref >= tmpe.lastref) { /* key already exists, current entry is newer */ /* keep old, ignore new */ rb->counts.dupcount++; continue; } else if (NULL != e) { /* URL already exists, this swapfile not being used */ /* junk old, load new */ storeRelease(e); /* release old entry */ rb->counts.dupcount++; } rb->counts.objcount++; storeEntryDump(&tmpe, 5); e = storeUfsDirAddDiskRestore(SD, key, filn, tmpe.swap_file_sz, tmpe.expires, tmpe.timestamp, tmpe.lastref, tmpe.lastmod, tmpe.refcount, /* refcount */ tmpe.flags, /* flags */ (int) rb->flags.clean); storeDirSwapLog(e, SWAP_LOG_ADD); } eventAdd("storeRebuild", storeUfsDirRebuildFromDirectory, rb, 0.0, 1); } static void storeUfsDirRebuildFromSwapLog(void *data) { RebuildState *rb = data; SwapDir *SD = rb->sd; StoreEntry *e = NULL; storeSwapLogData s; size_t ss = sizeof(storeSwapLogData); int count; int used; /* is swapfile already in use? */ int disk_entry_newer; /* is the log entry newer than current entry? */ double x; assert(rb != NULL); /* load a number of objects per invocation */ for (count = 0; count < rb->speed; count++) { if (fread(&s, ss, 1, rb->log) != 1) { storeUfsDirRebuildComplete(rb); return; } rb->n_read++; /* * BC: during 2.4 development, we changed the way swap file * numbers are assigned and stored. The high 16 bits used * to encode the SD index number. There used to be a call * to storeDirProperFileno here that re-assigned the index * bits. Now, for backwards compatibility, we just need * to mask it off. */ s.swap_filen &= 0x00FFFFFF; debug(47, 3) ("storeUfsDirRebuildFromSwapLog: %s %s %08X\n", swap_log_op_str[(int) s.op], storeKeyText(s.key), s.swap_filen); if (s.op == SWAP_LOG_ADD) { (void) 0; } else if (s.op == SWAP_LOG_DEL) { /* Delete unless we already have a newer copy */ if ((e = storeGet(s.key)) != NULL && s.lastref >= e->lastref) { /* * Make sure we don't unlink the file, it might be * in use by a subsequent entry. Also note that * we don't have to subtract from store_swap_size * because adding to store_swap_size happens in * the cleanup procedure. */ storeRecycle(e); rb->counts.cancelcount++; } continue; } else { x = log(++rb->counts.bad_log_op) / log(10.0); if (0.0 == x - (double) (int) x) debug(47, 1) ("WARNING: %d invalid swap log entries found\n", rb->counts.bad_log_op); rb->counts.invalid++; continue; } if ((++rb->counts.scancount & 0xFFF) == 0) { struct stat sb; if (0 == fstat(fileno(rb->log), &sb)) storeRebuildProgress(SD->index, (int) sb.st_size / ss, rb->n_read); } if (!storeUfsDirValidFileno(SD, s.swap_filen, 0)) { rb->counts.invalid++; continue; } if (EBIT_TEST(s.flags, KEY_PRIVATE)) { rb->counts.badflags++; continue; } e = storeGet(s.key); used = storeUfsDirMapBitTest(SD, s.swap_filen); /* If this URL already exists in the cache, does the swap log * appear to have a newer entry? Compare 'lastref' from the * swap log to e->lastref. */ disk_entry_newer = e ? (s.lastref > e->lastref ? 1 : 0) : 0; if (used && !disk_entry_newer) { /* log entry is old, ignore it */ rb->counts.clashcount++; continue; } else if (used && e && e->swap_filen == s.swap_filen && e->swap_dirn == SD->index) { /* swapfile taken, same URL, newer, update meta */ if (e->store_status == STORE_OK) { e->lastref = s.timestamp; e->timestamp = s.timestamp; e->expires = s.expires; e->lastmod = s.lastmod; e->flags = s.flags; e->refcount += s.refcount; storeUfsDirUnrefObj(SD, e); } else { debug_trap("storeUfsDirRebuildFromSwapLog: bad condition"); debug(47, 1) ("\tSee %s:%d\n", __FILE__, __LINE__); } continue; } else if (used) { /* swapfile in use, not by this URL, log entry is newer */ /* This is sorta bad: the log entry should NOT be newer at this * point. If the log is dirty, the filesize check should have * caught this. If the log is clean, there should never be a * newer entry. */ debug(47, 1) ("WARNING: newer swaplog entry for dirno %d, fileno %08X\n", SD->index, s.swap_filen); /* I'm tempted to remove the swapfile here just to be safe, * but there is a bad race condition in the NOVM version if * the swapfile has recently been opened for writing, but * not yet opened for reading. Because we can't map * swapfiles back to StoreEntrys, we don't know the state * of the entry using that file. */ /* We'll assume the existing entry is valid, probably because * the swap file number got taken while we rebuild */ rb->counts.clashcount++; continue; } else if (e && !disk_entry_newer) { /* key already exists, current entry is newer */ /* keep old, ignore new */ rb->counts.dupcount++; continue; } else if (e) { /* key already exists, this swapfile not being used */ /* junk old, load new */ storeRecycle(e); rb->counts.dupcount++; } else { /* URL doesnt exist, swapfile not in use */ /* load new */ (void) 0; } /* update store_swap_size */ rb->counts.objcount++; e = storeUfsDirAddDiskRestore(SD, s.key, s.swap_filen, s.swap_file_sz, s.expires, s.timestamp, s.lastref, s.lastmod, s.refcount, s.flags, (int) rb->flags.clean); storeDirSwapLog(e, SWAP_LOG_ADD); } eventAdd("storeRebuild", storeUfsDirRebuildFromSwapLog, rb, 0.0, 1); } #if SIZEOF_SQUID_FILE_SZ != SIZEOF_SIZE_T /* This is an exact copy of the above, but using storeSwapLogDataOld entry type */ static void storeUfsDirRebuildFromSwapLogOld(void *data) { RebuildState *rb = data; SwapDir *SD = rb->sd; StoreEntry *e = NULL; storeSwapLogDataOld s; size_t ss = sizeof(storeSwapLogDataOld); int count; int used; /* is swapfile already in use? */ int disk_entry_newer; /* is the log entry newer than current entry? */ double x; assert(rb != NULL); /* load a number of objects per invocation */ for (count = 0; count < rb->speed; count++) { if (fread(&s, ss, 1, rb->log) != 1) { storeUfsDirRebuildComplete(rb); return; } rb->n_read++; /* * BC: during 2.4 development, we changed the way swap file * numbers are assigned and stored. The high 16 bits used * to encode the SD index number. There used to be a call * to storeDirProperFileno here that re-assigned the index * bits. Now, for backwards compatibility, we just need * to mask it off. */ s.swap_filen &= 0x00FFFFFF; debug(47, 3) ("storeUfsDirRebuildFromSwapLog: %s %s %08X\n", swap_log_op_str[(int) s.op], storeKeyText(s.key), s.swap_filen); if (s.op == SWAP_LOG_ADD) { (void) 0; } else if (s.op == SWAP_LOG_DEL) { /* Delete unless we already have a newer copy */ if ((e = storeGet(s.key)) != NULL && s.lastref >= e->lastref) { /* * Make sure we don't unlink the file, it might be * in use by a subsequent entry. Also note that * we don't have to subtract from store_swap_size * because adding to store_swap_size happens in * the cleanup procedure. */ storeRecycle(e); rb->counts.cancelcount++; } continue; } else { x = log(++rb->counts.bad_log_op) / log(10.0); if (0.0 == x - (double) (int) x) debug(47, 1) ("WARNING: %d invalid swap log entries found\n", rb->counts.bad_log_op); rb->counts.invalid++; continue; } if ((++rb->counts.scancount & 0xFFF) == 0) { struct stat sb; if (0 == fstat(fileno(rb->log), &sb)) storeRebuildProgress(SD->index, (int) sb.st_size / ss, rb->n_read); } if (!storeUfsDirValidFileno(SD, s.swap_filen, 0)) { rb->counts.invalid++; continue; } if (EBIT_TEST(s.flags, KEY_PRIVATE)) { rb->counts.badflags++; continue; } e = storeGet(s.key); used = storeUfsDirMapBitTest(SD, s.swap_filen); /* If this URL already exists in the cache, does the swap log * appear to have a newer entry? Compare 'lastref' from the * swap log to e->lastref. */ disk_entry_newer = e ? (s.lastref > e->lastref ? 1 : 0) : 0; if (used && !disk_entry_newer) { /* log entry is old, ignore it */ rb->counts.clashcount++; continue; } else if (used && e && e->swap_filen == s.swap_filen && e->swap_dirn == SD->index) { /* swapfile taken, same URL, newer, update meta */ if (e->store_status == STORE_OK) { e->lastref = s.timestamp; e->timestamp = s.timestamp; e->expires = s.expires; e->lastmod = s.lastmod; e->flags = s.flags; e->refcount += s.refcount; storeUfsDirUnrefObj(SD, e); } else { debug_trap("storeUfsDirRebuildFromSwapLog: bad condition"); debug(47, 1) ("\tSee %s:%d\n", __FILE__, __LINE__); } continue; } else if (used) { /* swapfile in use, not by this URL, log entry is newer */ /* This is sorta bad: the log entry should NOT be newer at this * point. If the log is dirty, the filesize check should have * caught this. If the log is clean, there should never be a * newer entry. */ debug(47, 1) ("WARNING: newer swaplog entry for dirno %d, fileno %08X\n", SD->index, s.swap_filen); /* I'm tempted to remove the swapfile here just to be safe, * but there is a bad race condition in the NOVM version if * the swapfile has recently been opened for writing, but * not yet opened for reading. Because we can't map * swapfiles back to StoreEntrys, we don't know the state * of the entry using that file. */ /* We'll assume the existing entry is valid, probably because * the swap file number got taken while we rebuild */ rb->counts.clashcount++; continue; } else if (e && !disk_entry_newer) { /* key already exists, current entry is newer */ /* keep old, ignore new */ rb->counts.dupcount++; continue; } else if (e) { /* key already exists, this swapfile not being used */ /* junk old, load new */ storeRecycle(e); rb->counts.dupcount++; } else { /* URL doesnt exist, swapfile not in use */ /* load new */ (void) 0; } /* update store_swap_size */ rb->counts.objcount++; e = storeUfsDirAddDiskRestore(SD, s.key, s.swap_filen, s.swap_file_sz, s.expires, s.timestamp, s.lastref, s.lastmod, s.refcount, s.flags, (int) rb->flags.clean); storeDirSwapLog(e, SWAP_LOG_ADD); } eventAdd("storeRebuild", storeUfsDirRebuildFromSwapLogOld, rb, 0.0, 1); } #endif static void storeUfsDirRebuildFromSwapLogCheckVersion(void *data) { RebuildState *rb = data; storeSwapLogHeader hdr; if (fread(&hdr, sizeof(hdr), 1, rb->log) != 1) { storeUfsDirRebuildComplete(rb); return; } if (hdr.op == SWAP_LOG_VERSION) { if (fseek(rb->log, hdr.record_size, SEEK_SET) != 0) { storeUfsDirRebuildComplete(rb); return; } if (hdr.version == 1 && hdr.record_size == sizeof(storeSwapLogData)) { eventAdd("storeRebuild", storeUfsDirRebuildFromSwapLog, rb, 0.0, 1); return; } #if SIZEOF_SQUID_FILE_SZ != SIZEOF_SIZE_T if (hdr.version == 1 && hdr.record_size == sizeof(storeSwapLogDataOld)) { debug(47, 1) ("storeUfsDirRebuildFromSwapLog: Found current version but without large file support. Upgrading\n"); eventAdd("storeRebuild", storeUfsDirRebuildFromSwapLogOld, rb, 0.0, 1); return; } #endif debug(47, 1) ("storeUfsDirRebuildFromSwapLog: Unsupported swap.state version %d size %d\n", hdr.version, hdr.record_size); storeUfsDirRebuildComplete(rb); return; } rewind(rb->log); debug(47, 1) ("storeUfsDirRebuildFromSwapLog: Old version detected. Upgrading\n"); #if SIZEOF_SQUID_FILE_SZ == SIZEOF_SIZE_T eventAdd("storeRebuild", storeUfsDirRebuildFromSwapLog, rb, 0.0, 1); #else eventAdd("storeRebuild", storeUfsDirRebuildFromSwapLogOld, rb, 0.0, 1); #endif } static int storeUfsDirGetNextFile(RebuildState * rb, sfileno * filn_p, int *size) { SwapDir *SD = rb->sd; ufsinfo_t *ufsinfo = (ufsinfo_t *) SD->fsdata; int fd = -1; int used = 0; int dirs_opened = 0; debug(47, 3) ("storeUfsDirGetNextFile: flag=%d, %d: /%02X/%02X\n", rb->flags.init, rb->sd->index, rb->curlvl1, rb->curlvl2); if (rb->done) return -2; while (fd < 0 && rb->done == 0) { fd = -1; if (0 == rb->flags.init) { /* initialize, open first file */ rb->done = 0; rb->curlvl1 = 0; rb->curlvl2 = 0; rb->in_dir = 0; rb->flags.init = 1; assert(Config.cacheSwap.n_configured > 0); } if (0 == rb->in_dir) { /* we need to read in a new directory */ snprintf(rb->fullpath, SQUID_MAXPATHLEN, "%s/%02X/%02X", rb->sd->path, rb->curlvl1, rb->curlvl2); if (dirs_opened) return -1; rb->td = opendir(rb->fullpath); dirs_opened++; if (rb->td == NULL) { debug(47, 1) ("storeUfsDirGetNextFile: opendir: %s: %s\n", rb->fullpath, xstrerror()); } else { rb->entry = readdir(rb->td); /* skip . and .. */ rb->entry = readdir(rb->td); if (rb->entry == NULL && errno == ENOENT) debug(47, 1) ("storeUfsDirGetNextFile: directory does not exist!.\n"); debug(47, 3) ("storeUfsDirGetNextFile: Directory %s\n", rb->fullpath); } } if (rb->td != NULL && (rb->entry = readdir(rb->td)) != NULL) { rb->in_dir++; if (sscanf(rb->entry->d_name, "%x", &rb->fn) != 1) { debug(47, 3) ("storeUfsDirGetNextFile: invalid %s\n", rb->entry->d_name); continue; } if (!storeUfsFilenoBelongsHere(rb->fn, rb->sd->index, rb->curlvl1, rb->curlvl2)) { debug(47, 3) ("storeUfsDirGetNextFile: %08X does not belong in %d/%d/%d\n", rb->fn, rb->sd->index, rb->curlvl1, rb->curlvl2); continue; } used = storeUfsDirMapBitTest(SD, rb->fn); if (used) { debug(47, 3) ("storeUfsDirGetNextFile: Locked, continuing with next.\n"); continue; } snprintf(rb->fullfilename, SQUID_MAXPATHLEN, "%s/%s", rb->fullpath, rb->entry->d_name); debug(47, 3) ("storeUfsDirGetNextFile: Opening %s\n", rb->fullfilename); fd = file_open(rb->fullfilename, O_RDONLY | O_BINARY); if (fd < 0) debug(47, 1) ("storeUfsDirGetNextFile: %s: %s\n", rb->fullfilename, xstrerror()); else store_open_disk_fd++; continue; } if (rb->td != NULL) closedir(rb->td); rb->td = NULL; rb->in_dir = 0; if (++rb->curlvl2 < ufsinfo->l2) continue; rb->curlvl2 = 0; if (++rb->curlvl1 < ufsinfo->l1) continue; rb->curlvl1 = 0; rb->done = 1; } *filn_p = rb->fn; return fd; } /* Add a new object to the cache with empty memory copy and pointer to disk * use to rebuild store from disk. */ static StoreEntry * storeUfsDirAddDiskRestore(SwapDir * SD, const cache_key * key, int file_number, squid_file_sz swap_file_sz, time_t expires, time_t timestamp, time_t lastref, time_t lastmod, u_num32 refcount, u_short flags, int clean) { StoreEntry *e = NULL; debug(47, 5) ("storeUfsAddDiskRestore: %s, fileno=%08X\n", storeKeyText(key), file_number); /* if you call this you'd better be sure file_number is not * already in use! */ e = new_StoreEntry(STORE_ENTRY_WITHOUT_MEMOBJ, NULL); e->store_status = STORE_OK; storeSetMemStatus(e, NOT_IN_MEMORY); e->swap_status = SWAPOUT_DONE; e->swap_filen = file_number; e->swap_dirn = SD->index; e->swap_file_sz = swap_file_sz; e->lock_count = 0; e->lastref = lastref; e->timestamp = timestamp; e->expires = expires; e->lastmod = lastmod; e->refcount = refcount; e->flags = flags; EBIT_SET(e->flags, ENTRY_CACHABLE); EBIT_CLR(e->flags, RELEASE_REQUEST); EBIT_CLR(e->flags, KEY_PRIVATE); e->ping_status = PING_NONE; EBIT_CLR(e->flags, ENTRY_VALIDATED); storeUfsDirMapBitSet(SD, e->swap_filen); storeHashInsert(e, key); /* do it after we clear KEY_PRIVATE */ storeUfsDirReplAdd(SD, e); return e; } CBDATA_TYPE(RebuildState); static void storeUfsDirRebuild(SwapDir * sd) { RebuildState *rb; int clean = 0; int zero = 0; FILE *fp; EVH *func = NULL; CBDATA_INIT_TYPE(RebuildState); rb = cbdataAlloc(RebuildState); rb->sd = sd; rb->speed = opt_foreground_rebuild ? 1 << 30 : 50; /* * If the swap.state file exists in the cache_dir, then * we'll use storeUfsDirRebuildFromSwapLog(), otherwise we'll * use storeUfsDirRebuildFromDirectory() to open up each file * and suck in the meta data. */ fp = storeUfsDirOpenTmpSwapLog(sd, &clean, &zero); if (fp == NULL || zero) { if (fp != NULL) fclose(fp); func = storeUfsDirRebuildFromDirectory; } else { func = storeUfsDirRebuildFromSwapLogCheckVersion; rb->log = fp; rb->flags.clean = (unsigned int) clean; } debug(47, 1) ("Rebuilding storage in %s (%s)\n", sd->path, clean ? "CLEAN" : "DIRTY"); store_dirs_rebuilding++; eventAdd("storeRebuild", func, rb, 0.0, 1); } static void storeUfsDirCloseTmpSwapLog(SwapDir * sd) { ufsinfo_t *ufsinfo = (ufsinfo_t *) sd->fsdata; char *swaplog_path = xstrdup(storeUfsDirSwapLogFile(sd, NULL)); char *new_path = xstrdup(storeUfsDirSwapLogFile(sd, ".new")); int fd; file_close(ufsinfo->swaplog_fd); if (xrename(new_path, swaplog_path) < 0) { fatal("storeUfsDirCloseTmpSwapLog: rename failed"); } fd = file_open(swaplog_path, O_WRONLY | O_CREAT | O_BINARY); if (fd < 0) { debug(50, 1) ("%s: %s\n", swaplog_path, xstrerror()); fatal("storeUfsDirCloseTmpSwapLog: Failed to open swap log."); } safe_free(swaplog_path); safe_free(new_path); ufsinfo->swaplog_fd = fd; debug(47, 3) ("Cache Dir #%d log opened on FD %d\n", sd->index, fd); } static void storeSwapLogDataFree(void *s) { memFree(s, MEM_SWAP_LOG_DATA); } static void storeUfsWriteSwapLogheader(int fd) { storeSwapLogHeader *hdr = memAllocate(MEM_SWAP_LOG_DATA); hdr->op = SWAP_LOG_VERSION; hdr->version = 1; hdr->record_size = sizeof(storeSwapLogData); /* The header size is a full log record to keep some level of backward * compatibility even if the actual header is smaller */ file_write(fd, -1, hdr, sizeof(storeSwapLogData), NULL, NULL, (FREE *) storeSwapLogDataFree); } static FILE * storeUfsDirOpenTmpSwapLog(SwapDir * sd, int *clean_flag, int *zero_flag) { ufsinfo_t *ufsinfo = (ufsinfo_t *) sd->fsdata; char *swaplog_path = xstrdup(storeUfsDirSwapLogFile(sd, NULL)); char *clean_path = xstrdup(storeUfsDirSwapLogFile(sd, ".last-clean")); char *new_path = xstrdup(storeUfsDirSwapLogFile(sd, ".new")); struct stat log_sb; struct stat clean_sb; FILE *fp; int fd; if (stat(swaplog_path, &log_sb) < 0) { debug(47, 1) ("Cache Dir #%d: No log file\n", sd->index); safe_free(swaplog_path); safe_free(clean_path); safe_free(new_path); return NULL; } *zero_flag = log_sb.st_size == 0 ? 1 : 0; /* close the existing write-only FD */ if (ufsinfo->swaplog_fd >= 0) file_close(ufsinfo->swaplog_fd); /* open a write-only FD for the new log */ fd = file_open(new_path, O_WRONLY | O_CREAT | O_TRUNC | O_BINARY); if (fd < 0) { debug(50, 1) ("%s: %s\n", new_path, xstrerror()); fatal("storeDirOpenTmpSwapLog: Failed to open swap log."); } ufsinfo->swaplog_fd = fd; storeUfsWriteSwapLogheader(fd); /* open a read-only stream of the old log */ fp = fopen(swaplog_path, "rb"); if (fp == NULL) { debug(50, 0) ("%s: %s\n", swaplog_path, xstrerror()); fatal("Failed to open swap log for reading"); } memset(&clean_sb, '\0', sizeof(struct stat)); if (stat(clean_path, &clean_sb) < 0) *clean_flag = 0; else if (clean_sb.st_mtime < log_sb.st_mtime) *clean_flag = 0; else *clean_flag = 1; safeunlink(clean_path, 1); safe_free(swaplog_path); safe_free(clean_path); safe_free(new_path); return fp; } struct _clean_state { char *cur; char *new; char *cln; char *outbuf; int outbuf_offset; int fd; RemovalPolicyWalker *walker; }; #define CLEAN_BUF_SZ 16384 /* * Begin the process to write clean cache state. For UFS this means * opening some log files and allocating write buffers. Return 0 if * we succeed, and assign the 'func' and 'data' return pointers. */ static int storeUfsDirWriteCleanStart(SwapDir * sd) { struct _clean_state *state = xcalloc(1, sizeof(*state)); #if HAVE_FCHMOD struct stat sb; #endif sd->log.clean.write = NULL; sd->log.clean.state = NULL; state->new = xstrdup(storeUfsDirSwapLogFile(sd, ".clean")); state->fd = file_open(state->new, O_WRONLY | O_CREAT | O_TRUNC | O_BINARY); if (state->fd < 0) { debug(50, 0) ("storeDirWriteCleanStart: %s: open: %s\n", state->new, xstrerror()); debug(50, 0) ("storeDirWriteCleanStart: Current swap logfile " "not replaced.\n"); xfree(state->new); xfree(state); return -1; } storeUfsWriteSwapLogheader(state->fd); state->cur = xstrdup(storeUfsDirSwapLogFile(sd, NULL)); state->cln = xstrdup(storeUfsDirSwapLogFile(sd, ".last-clean")); state->outbuf = xcalloc(CLEAN_BUF_SZ, 1); state->outbuf_offset = 0; state->walker = sd->repl->WalkInit(sd->repl); unlink(state->cln); debug(47, 3) ("storeDirWriteCleanLogs: opened %s, FD %d\n", state->new, state->fd); #if HAVE_FCHMOD if (stat(state->cur, &sb) == 0) fchmod(state->fd, sb.st_mode); #endif sd->log.clean.write = storeUfsDirWriteCleanEntry; sd->log.clean.state = state; return 0; } /* * Get the next entry that is a candidate for clean log writing */ const StoreEntry * storeUfsDirCleanLogNextEntry(SwapDir * sd) { const StoreEntry *entry = NULL; struct _clean_state *state = sd->log.clean.state; if (state->walker) entry = state->walker->Next(state->walker); return entry; } /* * "write" an entry to the clean log file. */ static void storeUfsDirWriteCleanEntry(SwapDir * sd, const StoreEntry * e) { storeSwapLogData s; static size_t ss = sizeof(storeSwapLogData); struct _clean_state *state = sd->log.clean.state; memset(&s, '\0', ss); s.op = (char) SWAP_LOG_ADD; s.swap_filen = e->swap_filen; s.timestamp = e->timestamp; s.lastref = e->lastref; s.expires = e->expires; s.lastmod = e->lastmod; s.swap_file_sz = e->swap_file_sz; s.refcount = e->refcount; s.flags = e->flags; xmemcpy(&s.key, e->hash.key, SQUID_MD5_DIGEST_LENGTH); xmemcpy(state->outbuf + state->outbuf_offset, &s, ss); state->outbuf_offset += ss; /* buffered write */ if (state->outbuf_offset + ss > CLEAN_BUF_SZ) { if (FD_WRITE_METHOD(state->fd, state->outbuf, state->outbuf_offset) < 0) { debug(50, 0) ("storeDirWriteCleanLogs: %s: write: %s\n", state->new, xstrerror()); debug(50, 0) ("storeDirWriteCleanLogs: Current swap logfile not replaced.\n"); file_close(state->fd); state->fd = -1; unlink(state->new); safe_free(state); sd->log.clean.state = NULL; sd->log.clean.write = NULL; return; } state->outbuf_offset = 0; } } static void storeUfsDirWriteCleanDone(SwapDir * sd) { int fd; struct _clean_state *state = sd->log.clean.state; if (NULL == state) return; if (state->fd < 0) return; state->walker->Done(state->walker); if (FD_WRITE_METHOD(state->fd, state->outbuf, state->outbuf_offset) < 0) { debug(50, 0) ("storeDirWriteCleanLogs: %s: write: %s\n", state->new, xstrerror()); debug(50, 0) ("storeDirWriteCleanLogs: Current swap logfile " "not replaced.\n"); file_close(state->fd); state->fd = -1; unlink(state->new); } safe_free(state->outbuf); /* * You can't rename open files on Microsoft "operating systems" * so we have to close before renaming. */ storeUfsDirCloseSwapLog(sd); /* save the fd value for a later test */ fd = state->fd; /* rename */ if (state->fd >= 0) { #if defined(_SQUID_OS2_) || defined(_SQUID_WIN32_) file_close(state->fd); state->fd = -1; #endif xrename(state->new, state->cur); } /* touch a timestamp file if we're not still validating */ if (store_dirs_rebuilding) (void) 0; else if (fd < 0) (void) 0; else file_close(file_open(state->cln, O_WRONLY | O_CREAT | O_TRUNC | O_BINARY)); /* close */ safe_free(state->cur); safe_free(state->new); safe_free(state->cln); if (state->fd >= 0) file_close(state->fd); state->fd = -1; safe_free(state); sd->log.clean.state = NULL; sd->log.clean.write = NULL; } static void storeUfsDirSwapLog(const SwapDir * sd, const StoreEntry * e, int op) { ufsinfo_t *ufsinfo = (ufsinfo_t *) sd->fsdata; storeSwapLogData *s = memAllocate(MEM_SWAP_LOG_DATA); s->op = (char) op; s->swap_filen = e->swap_filen; s->timestamp = e->timestamp; s->lastref = e->lastref; s->expires = e->expires; s->lastmod = e->lastmod; s->swap_file_sz = e->swap_file_sz; s->refcount = e->refcount; s->flags = e->flags; xmemcpy(s->key, e->hash.key, SQUID_MD5_DIGEST_LENGTH); file_write(ufsinfo->swaplog_fd, -1, s, sizeof(storeSwapLogData), NULL, NULL, (FREE *) storeSwapLogDataFree); } static void storeUfsDirNewfs(SwapDir * sd) { debug(47, 3) ("Creating swap space in %s\n", sd->path); storeUfsDirCreateDirectory(sd->path, 0); storeUfsDirCreateSwapSubDirs(sd); } static int rev_int_sort(const void *A, const void *B) { const int *i1 = A; const int *i2 = B; return *i2 - *i1; } static int storeUfsDirClean(int swap_index) { DIR *dp = NULL; struct dirent *de = NULL; LOCAL_ARRAY(char, p1, MAXPATHLEN + 1); LOCAL_ARRAY(char, p2, MAXPATHLEN + 1); #if USE_TRUNCATE struct stat sb; #endif int files[20]; int swapfileno; int fn; /* same as swapfileno, but with dirn bits set */ int n = 0; int k = 0; int N0, N1, N2; int D0, D1, D2; SwapDir *SD; ufsinfo_t *ufsinfo; N0 = n_ufs_dirs; D0 = ufs_dir_index[swap_index % N0]; SD = &Config.cacheSwap.swapDirs[D0]; ufsinfo = (ufsinfo_t *) SD->fsdata; N1 = ufsinfo->l1; D1 = (swap_index / N0) % N1; N2 = ufsinfo->l2; D2 = ((swap_index / N0) / N1) % N2; snprintf(p1, SQUID_MAXPATHLEN, "%s/%02X/%02X", Config.cacheSwap.swapDirs[D0].path, D1, D2); debug(36, 3) ("storeDirClean: Cleaning directory %s\n", p1); dp = opendir(p1); if (dp == NULL) { if (errno == ENOENT) { debug(36, 0) ("storeDirClean: WARNING: Creating %s\n", p1); #ifdef _SQUID_MSWIN_ if (mkdir(p1) == 0) #else if (mkdir(p1, 0777) == 0) #endif return 0; } debug(50, 0) ("storeDirClean: %s: %s\n", p1, xstrerror()); safeunlink(p1, 1); return 0; } while ((de = readdir(dp)) != NULL && k < 20) { if (sscanf(de->d_name, "%X", &swapfileno) != 1) continue; fn = swapfileno; /* XXX should remove this cruft ! */ if (storeUfsDirValidFileno(SD, fn, 1)) if (storeUfsDirMapBitTest(SD, fn)) if (storeUfsFilenoBelongsHere(fn, D0, D1, D2)) continue; #if USE_TRUNCATE if (!stat(de->d_name, &sb)) if (sb.st_size == 0) continue; #endif files[k++] = swapfileno; } closedir(dp); if (k == 0) return 0; qsort(files, k, sizeof(int), rev_int_sort); if (k > 10) k = 10; for (n = 0; n < k; n++) { debug(36, 3) ("storeDirClean: Cleaning file %08X\n", files[n]); snprintf(p2, MAXPATHLEN + 1, "%s/%08X", p1, files[n]); #if USE_TRUNCATE truncate(p2, 0); #else safeunlink(p2, 0); #endif statCounter.swap.files_cleaned++; } debug(36, 3) ("Cleaned %d unused files from %s\n", k, p1); return k; } static void storeUfsDirCleanEvent(void *unused) { static int swap_index = 0; int i; int j = 0; int n = 0; /* * Assert that there are UFS cache_dirs configured, otherwise * we should never be called. */ assert(n_ufs_dirs); if (NULL == ufs_dir_index) { SwapDir *sd; ufsinfo_t *ufsinfo; /* * Initialize the little array that translates UFS cache_dir * number into the Config.cacheSwap.swapDirs array index. */ ufs_dir_index = xcalloc(n_ufs_dirs, sizeof(*ufs_dir_index)); for (i = 0, n = 0; i < Config.cacheSwap.n_configured; i++) { sd = &Config.cacheSwap.swapDirs[i]; if (!storeUfsDirIs(sd)) continue; ufs_dir_index[n++] = i; ufsinfo = (ufsinfo_t *) sd->fsdata; j += (ufsinfo->l1 * ufsinfo->l2); } assert(n == n_ufs_dirs); /* * Start the storeUfsDirClean() swap_index with a random * value. j equals the total number of UFS level 2 * swap directories */ swap_index = (int) (squid_random() % j); } if (0 == store_dirs_rebuilding) { n = storeUfsDirClean(swap_index); swap_index++; } eventAdd("storeDirClean", storeUfsDirCleanEvent, NULL, 15.0 * exp(-0.25 * n), 1); } static int storeUfsDirIs(SwapDir * sd) { if (strncmp(sd->type, "ufs", 3) == 0) return 1; return 0; } /* * Does swapfile number 'fn' belong in cachedir #F0, * level1 dir #F1, level2 dir #F2? */ static int storeUfsFilenoBelongsHere(int fn, int F0, int F1, int F2) { int D1, D2; int L1, L2; int filn = fn; ufsinfo_t *ufsinfo; assert(F0 < Config.cacheSwap.n_configured); ufsinfo = (ufsinfo_t *) Config.cacheSwap.swapDirs[F0].fsdata; L1 = ufsinfo->l1; L2 = ufsinfo->l2; D1 = ((filn / L2) / L2) % L1; if (F1 != D1) return 0; D2 = (filn / L2) % L2; if (F2 != D2) return 0; return 1; } int storeUfsDirValidFileno(SwapDir * SD, sfileno filn, int flag) { ufsinfo_t *ufsinfo = (ufsinfo_t *) SD->fsdata; if (filn < 0) return 0; /* * If flag is set it means out-of-range file number should * be considered invalid. */ if (flag) if (filn > ufsinfo->map->max_n_files) return 0; return 1; } void storeUfsDirMaintain(SwapDir * SD) { ufsinfo_t *ufsinfo = SD->fsdata; StoreEntry *e = NULL; int removed = 0; int max_scan; int max_remove; double f; RemovalPurgeWalker *walker; /* We can't delete objects while rebuilding swap */ if (store_dirs_rebuilding) { return; } else { f = (double) (SD->cur_size - SD->low_size) / (SD->max_size - SD->low_size); f = f < 0.0 ? 0.0 : f > 1.0 ? 1.0 : f; max_scan = (int) (f * 400.0 + 100.0); max_remove = (int) (f * 70.0 + 10.0); /* * This is kinda cheap, but so we need this priority hack? */ } debug(47, 3) ("storeMaintainSwapSpace: f=%f, max_scan=%d, max_remove=%d\n", f, max_scan, max_remove); walker = SD->repl->PurgeInit(SD->repl, max_scan); while (1) { if (SD->cur_size < SD->low_size && ufsinfo->map->n_files_in_map < FILEMAP_MAX) break; if (removed >= max_remove) break; e = walker->Next(walker); if (!e) break; /* no more objects */ removed++; storeRelease(e); } walker->Done(walker); debug(47, (removed ? 2 : 3)) ("storeUfsDirMaintain: %s removed %d/%d f=%.03f max_scan=%d\n", SD->path, removed, max_remove, f, max_scan); } /* * storeUfsDirCheckObj * * This routine is called by storeDirSelectSwapDir to see if the given * object is able to be stored on this filesystem. UFS filesystems will * happily store anything as long as the LRU time isn't too small. */ int storeUfsDirCheckObj(SwapDir * SD, const StoreEntry * e) { return 1; } /* * storeUfsDirCheckLoadAv * * Return load average from 0 to 1000. */ int storeUfsDirCheckLoadAv(SwapDir * SD, store_op_t op) { ufsinfo_t *ufsinfo = SD->fsdata; return UFS_LOAD_BASE + ufsinfo->open_files / 2; } /* * storeUfsDirRefObj * * This routine is called whenever an object is referenced, so we can * maintain replacement information within the storage fs. */ void storeUfsDirRefObj(SwapDir * SD, StoreEntry * e) { debug(47, 3) ("storeUfsDirRefObj: referencing %p %d/%d\n", e, e->swap_dirn, e->swap_filen); if (SD->repl->Referenced) SD->repl->Referenced(SD->repl, e, &e->repl); } /* * storeUfsDirUnrefObj * This routine is called whenever the last reference to an object is * removed, to maintain replacement information within the storage fs. */ void storeUfsDirUnrefObj(SwapDir * SD, StoreEntry * e) { debug(47, 3) ("storeUfsDirUnrefObj: referencing %p %d/%d\n", e, e->swap_dirn, e->swap_filen); if (SD->repl->Dereferenced) SD->repl->Dereferenced(SD->repl, e, &e->repl); } /* * storeUfsDirUnlinkFile * * This routine unlinks a file and pulls it out of the bitmap. * It used to be in storeUfsUnlink(), however an interface change * forced this bit of code here. Eeek. */ void storeUfsDirUnlinkFile(SwapDir * SD, sfileno f) { debug(79, 3) ("storeUfsDirUnlinkFile: unlinking fileno %08X\n", f); /* storeUfsDirMapBitReset(SD, f); */ #if USE_UNLINKD unlinkdUnlink(storeUfsDirFullPath(SD, f, NULL)); #elif USE_TRUNCATE truncate(storeUfsDirFullPath(SD, f, NULL), 0); #else unlink(storeUfsDirFullPath(SD, f, NULL)); #endif } /* * Add and remove the given StoreEntry from the replacement policy in * use. */ void storeUfsDirReplAdd(SwapDir * SD, StoreEntry * e) { debug(47, 4) ("storeUfsDirReplAdd: added node %p to dir %d\n", e, SD->index); SD->repl->Add(SD->repl, e, &e->repl); } void storeUfsDirReplRemove(StoreEntry * e) { SwapDir *SD = INDEXSD(e->swap_dirn); debug(47, 4) ("storeUfsDirReplRemove: remove node %p from dir %d\n", e, SD->index); SD->repl->Remove(SD->repl, e, &e->repl); } /* ========== LOCAL FUNCTIONS ABOVE, GLOBAL FUNCTIONS BELOW ========== */ void storeUfsDirStats(SwapDir * SD, StoreEntry * sentry) { ufsinfo_t *ufsinfo = SD->fsdata; #ifdef HAVE_STATVFS fsblkcnt_t totl_kb = 0; fsblkcnt_t free_kb = 0; fsfilcnt_t totl_in = 0; fsfilcnt_t free_in = 0; #else int totl_kb = 0; int free_kb = 0; int totl_in = 0; int free_in = 0; #endif int x; storeAppendPrintf(sentry, "First level subdirectories: %d\n", ufsinfo->l1); storeAppendPrintf(sentry, "Second level subdirectories: %d\n", ufsinfo->l2); storeAppendPrintf(sentry, "Maximum Size: %d KB\n", SD->max_size); storeAppendPrintf(sentry, "Current Size: %d KB\n", SD->cur_size); storeAppendPrintf(sentry, "Percent Used: %0.2f%%\n", 100.0 * SD->cur_size / SD->max_size); storeAppendPrintf(sentry, "Current load metric: %d / %d\n", storeUfsDirCheckLoadAv(SD, ST_OP_CREATE), MAX_LOAD_VALUE); storeAppendPrintf(sentry, "Filemap bits in use: %d of %d (%d%%)\n", ufsinfo->map->n_files_in_map, ufsinfo->map->max_n_files, percent(ufsinfo->map->n_files_in_map, ufsinfo->map->max_n_files)); x = storeDirGetUFSStats(SD->path, &totl_kb, &free_kb, &totl_in, &free_in); if (0 == x) { #ifdef HAVE_STATVFS storeAppendPrintf(sentry, "Filesystem Space in use: %" PRIu64 "/%" PRIu64 " KB (%.0f%%)\n", (uint64_t) (totl_kb - free_kb), (uint64_t) totl_kb, dpercent(totl_kb - free_kb, totl_kb)); storeAppendPrintf(sentry, "Filesystem Inodes in use: %" PRIu64 "/%" PRIu64 " (%.0f%%)\n", (uint64_t) (totl_in - free_in), (uint64_t) totl_in, dpercent(totl_in - free_in, totl_in)); #else storeAppendPrintf(sentry, "Filesystem Space in use: %d/%d KB (%d%%)\n", totl_kb - free_kb, totl_kb, percent(totl_kb - free_kb, totl_kb)); storeAppendPrintf(sentry, "Filesystem Inodes in use: %d/%d (%d%%)\n", totl_in - free_in, totl_in, percent(totl_in - free_in, totl_in)); #endif } storeAppendPrintf(sentry, "Flags:"); if (SD->flags.selected) storeAppendPrintf(sentry, " SELECTED"); if (SD->flags.read_only) storeAppendPrintf(sentry, " READ-ONLY"); storeAppendPrintf(sentry, "\n"); } static struct cache_dir_option options[] = { #if NOT_YET_DONE {"L1", storeUfsDirParseL1, storeUfsDirDumpL1}, {"L2", storeUfsDirParseL2, storeUfsDirDumpL2}, #endif {NULL, NULL} }; /* * storeUfsDirReconfigure * * This routine is called when the given swapdir needs reconfiguring */ static void storeUfsDirReconfigure(SwapDir * sd, int index, char *path) { int i; int size; int l1; int l2; i = GetInteger(); size = i << 10; /* Mbytes to kbytes */ if (size <= 0) fatal("storeUfsDirReconfigure: invalid size value"); i = GetInteger(); l1 = i; if (l1 <= 0) fatal("storeUfsDirReconfigure: invalid level 1 directories value"); i = GetInteger(); l2 = i; if (l2 <= 0) fatal("storeUfsDirReconfigure: invalid level 2 directories value"); /* just reconfigure it */ if (size == sd->max_size) debug(3, 1) ("Cache dir '%s' size remains unchanged at %d KB\n", path, size); else debug(3, 1) ("Cache dir '%s' size changed to %d KB\n", path, size); sd->max_size = size; parse_cachedir_options(sd, options, 1); } void storeUfsDirDump(StoreEntry * entry, SwapDir * s) { ufsinfo_t *ufsinfo = (ufsinfo_t *) s->fsdata; storeAppendPrintf(entry, " %d %d %d", s->max_size >> 10, ufsinfo->l1, ufsinfo->l2); dump_cachedir_options(entry, options, s); } /* * Only "free" the filesystem specific stuff here */ static void storeUfsDirFree(SwapDir * s) { ufsinfo_t *ufsinfo = (ufsinfo_t *) s->fsdata; if (ufsinfo->swaplog_fd > -1) { file_close(ufsinfo->swaplog_fd); ufsinfo->swaplog_fd = -1; } filemapFreeMemory(ufsinfo->map); xfree(ufsinfo); s->fsdata = NULL; /* Will aid debugging... */ } char * storeUfsDirFullPath(SwapDir * SD, sfileno filn, char *fullpath) { LOCAL_ARRAY(char, fullfilename, SQUID_MAXPATHLEN); ufsinfo_t *ufsinfo = (ufsinfo_t *) SD->fsdata; int L1 = ufsinfo->l1; int L2 = ufsinfo->l2; if (!fullpath) fullpath = fullfilename; fullpath[0] = '\0'; snprintf(fullpath, SQUID_MAXPATHLEN, "%s/%02X/%02X/%08X", SD->path, ((filn / L2) / L2) % L1, (filn / L2) % L2, filn); return fullpath; } /* * storeUfsCleanupDoubleCheck * * This is called by storeCleanup() if -S was given on the command line. */ static int storeUfsCleanupDoubleCheck(SwapDir * sd, StoreEntry * e) { struct stat sb; if (stat(storeUfsDirFullPath(sd, e->swap_filen, NULL), &sb) < 0) { debug(47, 0) ("storeUfsCleanupDoubleCheck: MISSING SWAP FILE\n"); debug(47, 0) ("storeUfsCleanupDoubleCheck: FILENO %08X\n", e->swap_filen); debug(47, 0) ("storeUfsCleanupDoubleCheck: PATH %s\n", storeUfsDirFullPath(sd, e->swap_filen, NULL)); storeEntryDump(e, 0); return -1; } if (e->swap_file_sz != sb.st_size) { debug(47, 0) ("storeUfsCleanupDoubleCheck: SIZE MISMATCH\n"); debug(47, 0) ("storeUfsCleanupDoubleCheck: FILENO %08X\n", e->swap_filen); debug(47, 0) ("storeUfsCleanupDoubleCheck: PATH %s\n", storeUfsDirFullPath(sd, e->swap_filen, NULL)); debug(47, 0) ("storeUfsCleanupDoubleCheck: ENTRY SIZE: %ld, FILE SIZE: %ld\n", (long int) e->swap_file_sz, (long int) sb.st_size); storeEntryDump(e, 0); return -1; } return 0; } /* * storeUfsDirParse * * Called when a *new* fs is being setup. */ static void storeUfsDirParse(SwapDir * sd, int index, char *path) { int i; int size; int l1; int l2; ufsinfo_t *ufsinfo; i = GetInteger(); size = i << 10; /* Mbytes to kbytes */ if (size <= 0) fatal("storeUfsDirParse: invalid size value"); i = GetInteger(); l1 = i; if (l1 <= 0) fatal("storeUfsDirParse: invalid level 1 directories value"); i = GetInteger(); l2 = i; if (l2 <= 0) fatal("storeUfsDirParse: invalid level 2 directories value"); ufsinfo = xmalloc(sizeof(ufsinfo_t)); if (ufsinfo == NULL) fatal("storeUfsDirParse: couldn't xmalloc() ufsinfo_t!\n"); sd->index = index; sd->path = xstrdup(path); sd->max_size = size; sd->fsdata = ufsinfo; ufsinfo->l1 = l1; ufsinfo->l2 = l2; ufsinfo->swaplog_fd = -1; ufsinfo->map = NULL; /* Debugging purposes */ ufsinfo->suggest = 0; ufsinfo->open_files = 0; sd->checkconfig = storeUfsCheckConfig; sd->init = storeUfsDirInit; sd->newfs = storeUfsDirNewfs; sd->dump = storeUfsDirDump; sd->freefs = storeUfsDirFree; sd->dblcheck = storeUfsCleanupDoubleCheck; sd->statfs = storeUfsDirStats; sd->maintainfs = storeUfsDirMaintain; sd->checkobj = storeUfsDirCheckObj; sd->checkload = storeUfsDirCheckLoadAv; sd->refobj = storeUfsDirRefObj; sd->unrefobj = storeUfsDirUnrefObj; sd->callback = NULL; sd->sync = NULL; sd->obj.create = storeUfsCreate; sd->obj.open = storeUfsOpen; sd->obj.close = storeUfsClose; sd->obj.read = storeUfsRead; sd->obj.write = storeUfsWrite; sd->obj.unlink = storeUfsUnlink; sd->obj.recycle = storeUfsRecycle; sd->log.open = storeUfsDirOpenSwapLog; sd->log.close = storeUfsDirCloseSwapLog; sd->log.write = storeUfsDirSwapLog; sd->log.clean.start = storeUfsDirWriteCleanStart; sd->log.clean.nextentry = storeUfsDirCleanLogNextEntry; sd->log.clean.done = storeUfsDirWriteCleanDone; parse_cachedir_options(sd, options, 1); /* Initialise replacement policy stuff */ sd->repl = createRemovalPolicy(Config.replPolicy); } /* * Initial setup / end destruction */ static void storeUfsDirDone(void) { memPoolDestroy(ufs_state_pool); ufs_initialised = 0; } void storeFsSetup_ufs(storefs_entry_t * storefs) { assert(!ufs_initialised); storefs->parsefunc = storeUfsDirParse; storefs->reconfigurefunc = storeUfsDirReconfigure; storefs->donefunc = storeUfsDirDone; ufs_state_pool = memPoolCreate("UFS IO State data", sizeof(ufsstate_t)); ufs_initialised = 1; }