FreeCalypso > hg > fc-magnetite
view src/cs/drivers/drv_app/ffs/board/fsck.c @ 624:012028896cfb
FFS dev.c, Leonardo target: Fujitsu MB84VF5F5F4J2 #if 0'ed out
The FFS code we got from TI/Openmoko had a stanza for "Fujitsu MB84VF5F5F4J2
stacked device", using a fake device ID code that would need to be patched
manually into cfgffs.c (suppressing and overriding autodetection) and using
an FFS base address in the nCS2 bank, indicating that this FFS config was
probably meant for the MCP version of Leonardo which allows for 16 MiB flash
with a second bank on nCS2.
We previously had this FFS config stanza conditionalized under
CONFIG_TARGET_LEONARDO because the base address contained therein is invalid
for other targets, but now that we actually have a Leonardo build target in
FC Magnetite, I realize that the better approach is to #if 0 out this stanza
altogether: it is already non-functional because it uses a fake device ID
code, thus it is does not add support for more Leonardo board variants,
instead it is just noise.
| author | Mychaela Falconia <falcon@freecalypso.org> |
|---|---|
| date | Sun, 22 Dec 2019 21:24:29 +0000 |
| parents | 945cf7f506b2 |
| children | ba45f6514fb1 |
line wrap: on
line source
/****************************************************************************** * Flash File System (ffs) * Idea, design and coding by Mads Meisner-Jensen, mmj@ti.com * * FFS file system integrity checking, journalling, init and exit * * $Id: fsck.c 1.3.1.1.1.33 Thu, 08 Jan 2004 15:05:23 +0100 tsj $ * ******************************************************************************/ #ifndef TARGET #include "ffs.cfg" #endif #include <string.h> #include <assert.h> #include "ffs/ffs.h" #include "ffs/board/core.h" #include "ffs/board/drv.h" #include "ffs/board/ffstrace.h" /****************************************************************************** * Functions ******************************************************************************/ bref_t blocks_fsck(void); iref_t inodes_fsck(void); /****************************************************************************** * Init and Exit ******************************************************************************/ effs_t ffs_initialize(void) { bref_t b; struct inode_s *ip; int i; tlw(led_set(0)); tlw(led_on(LED_INIT)); ttw(str(TTrInit, "initialize {" NL)); tw(tr(TR_BEGIN, TrFsck, "ffs_initialize() {\n")); // default to non-initialized ffs fs.root = 0; fs.debug[0] = fs.debug[1] = fs.debug[2] = fs.debug[3] = 0; fs.testflags = 0; tlw(led_on(LED_DRV_INIT)); fs.initerror = ffsdrv_init(); // read manufacturer and device ID tlw(led_off(LED_DRV_INIT)); if (fs.initerror < 0) { tlw(led_off(0)); tw(tr(TR_END, TrFsck, "} %d\n", fs.initerror)); ttw(ttr(TTrInit, "} %d" NL, fs.initerror)); return fs.initerror; } for (i = 0; i < 2; i++) { tlw(led_on(LED_BLOCKS_FSCK)); fs.initerror = EFFS_INVALID; fs.initerror = b = blocks_fsck(); tlw(led_off(LED_BLOCKS_FSCK)); if (fs.initerror < 0) { tlw(led_off(0)); tw(tr(TR_END, TrFsck, "} %d\n", fs.initerror)); ttw(ttr(TTrInit, "} %d" NL, fs.initerror)); return fs.initerror; } tlw(led_on(LED_INODES_FSCK)); fs.initerror = EFFS_INVALID; fs.initerror = inodes_fsck(); tlw(led_off(LED_INODES_FSCK)); if (fs.initerror < 0) { tlw(led_off(0)); tw(tr(TR_END, TrFsck, "} %d\n", fs.initerror)); ttw(ttr(TTrInit, "} %d" NL, fs.initerror)); return fs.initerror; } // parse the fs options in the root inode's name ip = inode_addr(fs.root); fs_params_init(addr2name(offset2addr(location2offset(ip->location)))); if ((fs.initerror = journal_init(fs.ijournal)) == 0) break; } // Init all file_descriptors to zero memset(fs.fd, 0, sizeof(struct file_descriptor_s) * fs.fd_max); // If blocks_fsck() found a block that needs cleaning, we do it, now // that all the file system has been initialized. if (b > 0) { block_clean(b - 1); block_free(b - 1); } statistics_init(); // In target, we do this before entering the task event loop... // Otherwise we would in some cases impose a long reboot delay if we did // it here. If we test in target it is nessesary to call // blocks_reclaim() anyway because we re-init ffs. #if (TARGET == 1) //NOTEME: can this be done in another/better way? #if (WITH_TFFS == 1) blocks_reclaim(); #endif #else blocks_reclaim(); #endif tlw(led_off(LED_INIT)); tw(tr(TR_END, TrFsck, "} %d\n", EFFS_OK)); ttw(str(TTrInit, "} 0" NL)); return EFFS_OK; } void fs_params_init(const char *p) { uint8 opt, digit; uint32 n; int numdatablocks; tw(tr(TR_BEGIN, TrFsck, "fsparams_init('%s') {\n", p)); // Compiled default values fs.filename_max = FFS_FILENAME_MAX; fs.path_depth_max = FFS_PATH_DEPTH_MAX; fs.fd_max = FFS_FD_MAX; fs.journal_size = FFS_JOURNAL_SIZE_IN256THS; fs.flags = 0; fs.testflags = 0; // Flag that it not has been changed by an input arg. fs.block_files_max = 0; // The default lost bytes percentage of a block before it is reclaimed // is approx. 90%. fs.lost_threshold = (256 - 256/10); // If we only have two blocks, we cannot make any reclaims and thus we // have a write-once FFS system. fs.blocks_free_min = (dev.numblocks > 2 ? 1 : 0); // Don't count free and inodes blocks numdatablocks = dev.numblocks - fs.blocks_free_min - 1; // Abselute max number of inodes. fs.inodes_max = dev.blocksize / sizeof(struct inode_s); if (fs.inodes_max > FFS_INODES_MAX) fs.inodes_max = FFS_INODES_MAX; // MUST be true: objects_max <= inodes_max - block_files_max, this is do // to the fact that we always need to have block_files_max number of // inodes left when we run a data reclaim. fs.objects_max = fs.inodes_max / 2; // Find a suitable chunk_size if (dev.numblocks*dev.blocksize > 1024*1024) fs.chunk_size_max = 8192; else fs.chunk_size_max = (2048 > (dev.blocksize / 8) ? (dev.blocksize / 8) : 2048); fs.fd_buf_size = fs.chunk_size_max; fs.journal_size = fs.journal_size * dev.blocksize / 256; if (fs.journal_size < FFS_JOURNAL_SIZE_MIN) fs.journal_size = FFS_JOURNAL_SIZE_MIN; // Set it just below the same amount as entries in one journal file fs.block_files_max = (fs.journal_size / sizeof(struct journal_s) - FFS_JOURNAL_MARGIN - 2); // MUST be true: block_files_max < objects_max / 2. But if we want // to reach objects_max must block_files_max >= objects_max / number // of datablocks, however a big block_files_max require higher // reserved_space. if (fs.block_files_max > fs.objects_max / 2) fs.block_files_max = fs.objects_max / 2 - 4; // Are we able to reach objects_max? If not then lower the number if (fs.objects_max > numdatablocks * fs.block_files_max) fs.objects_max = numdatablocks * fs.block_files_max + 10; // Absolute minimum is RESERVED_LOW the rest is 'workspace' which is // needed to have a reasonable performance. fs.reserved_space = dev.blocksize / 2 + numdatablocks * dev.blocksize / 16 + RESERVED_LOW; // skip to first char following second slash in name n = 0; while (*p) { if (*p++ == '/') { n++; if (n == 2) break; } } if (n == 2) { // while still options to process... while (*p) { opt = *p++; // save option letter for later // collect option value... n = 0; while ((digit = *p)) { if (digit >= '0' && digit <= '9') { n = 10 * n + digit - '0'; p++; } else break; } switch (opt) { case 'b': dev.numblocks = n; break; case 'm': fs.blocks_free_min = n; break; case 'i': fs.inodes_max = n; break; case 'o': fs.objects_max = n; break; case 'n': fs.filename_max = n; break; case 'f': fs.block_files_max = n; break; case 'd': fs.fd_max = n; break; case 's': fs.fd_buf_size = n; break; case 't': fs.lost_threshold = n; break; case 'z': fs.flags = n; break; case 'j': fs.journal_size = n; break; case 'c': fs.chunk_size_max = n; break; case 'r': fs.reserved_space = n; break; // d = &fs.path_depth_max; // really necessary? default: break; } } } // Now recompute a few parameters based on adjusted values. // No journal file thuse no reserved space. if (fs.journal_size == 0) { fs.block_files_max = fs.objects_max / 2; fs.reserved_space = 0; fs.block_files_reserved = 0; } else { // If journal size is less than minimum must it have been changed by an // input arg, recalculate. if (fs.journal_size < FFS_JOURNAL_SIZE_MIN) fs.journal_size = fs.journal_size * dev.blocksize / 256; if (fs.reserved_space < RESERVED_LOW) fs.reserved_space = fs.reserved_space * dev.blocksize / 256; // Only one reserved is needed however we want a margin and set it to two fs.block_files_reserved = 2; } // Don't count free blocks, inode block, reserved space, block headers // and the size of one filename. fs.filesize_max = numdatablocks * dev.blocksize - fs.reserved_space - numdatablocks * BHEADER_SIZE - FFS_FILENAME_MAX; // Furthermore don't count the overhead from each chunk (alignment) fs.filesize_max -= ((fs.filesize_max / fs.chunk_size_max) * dev.atomsize + dev.atomsize); // NOTEME: chunk_size_min is never used fs.chunk_size_min = numdatablocks / fs.objects_max; tw(tr(TR_FUNC, TrFsck, "dev.numblocks = %d\n", dev.numblocks)); tw(tr(TR_FUNC, TrFsck, "fs.blocks_free_min = %d\n", fs.blocks_free_min)); tw(tr(TR_FUNC, TrFsck, "fs.inodes_max = %d\n", fs.inodes_max)); tw(tr(TR_FUNC, TrFsck, "fs.objects_max = %d\n", fs.objects_max)); tw(tr(TR_FUNC, TrFsck, "fs.block_files_max = %d\n", fs.block_files_max)); tw(tr(TR_FUNC, TrFsck, "fs.block_files_reserved = %d\n", fs.block_files_reserved)); tw(tr(TR_FUNC, TrFsck, "fs.chunk_size_max = %d\n", fs.chunk_size_max)); tw(tr(TR_FUNC, TrFsck, "fs.filename_max = %d\n", fs.filename_max)); tw(tr(TR_FUNC, TrFsck, "fs.lost_threshold = %d\n", fs.lost_threshold)); tw(tr(TR_FUNC, TrFsck, "fs.path_depth_max = %d\n", fs.path_depth_max)); tw(tr(TR_FUNC, TrFsck, "fs.journal_size = %d\n", fs.journal_size)); tw(tr(TR_FUNC, TrFsck, "fs.reserved_space = %d\n", fs.reserved_space)); tw(tr(TR_FUNC, TrFsck, "fs.fd_max = %d\n", fs.fd_max)); tw(tr(TR_FUNC, TrFsck, "fs.fd_buf_size = 0x%02x\n", fs.fd_buf_size)); tw(tr(TR_FUNC, TrFsck, "fs.flags = 0x%02x\n", fs.flags)); tw(tr(TR_END, TrFsck, "}\n")); } // TODO: Finish pending commits/writes. effs_t ffs_exit(void) { tw(tr(TR_FUNC, TrFsck, "exit() 0\n")); return EFFS_OK; } #if 0 // Not used in this version // Purely for core internal use; Read a file. effs_t file_read_int(const char *path, void *src, int size) { if (fs.initerror != EFFS_OK) return fs.initerror; return object_read(path, src, size, 0); } // Purely for core internal use; Update a file. effs_t file_update(const char *path, void *src, int size) { char *name; iref_t i, dir; if (fs.initerror != EFFS_OK) return fs.initerror; if ((i = object_lookup(path, &name, &dir)) < 0) return i; journal_begin(i); if ((i = object_create(name, src, size, -dir)) < 0) return i; journal_end(0); return EFFS_OK; } #endif /****************************************************************************** * blocks_fsck() ******************************************************************************/ blocksize_t block_used(bref_t b) { blocksize_t used; uint32 *p, *q; tlw(led_toggle(LED_BLOCKS_FSCK)); // We search backwards through block to find the last used byte and // thus the total number of used bytes. Note that this code depends // on the fact that an erased flash location is 0xFF! p = (uint32 *) offset2addr(dev.binfo[b].offset); for (q = p + dev.blocksize/4 - 4; q > p; q -= 4) { if ( ~(q[0] & q[1] & q[2] & q[3]) ) break; } if ( ~(q[0] & q[1] & q[2] & q[3]) ) q += 4; used = atomalign((char *) q - (char *) p); tw(tr(TR_FUNC, TrFsckLow, "ffs_block_used(%d) %d\n", b, used)); return used; } age_t age_distance(age_t x, age_t y) { age_t a = x - y; if (a > 0x8000) a = -a; tw(tr(TR_FUNC, TrFsckLow, "age_distance(%d, %d) %d\n", x, y, a)); return a; } // For each ffs block, we initialise the basic bstat array information, // namely the number of used bytes. Also, we locate the inodes block and if // a previous operation was interrupted by a powerfail, we clean it up. // // We return EFFS_OK if all is fine. If a positive integer is returned, it // denotes a block that needs to be cleaned by block_clean() once FFS // has been properly intialized (we actually return the block number + 1 // because otherwise it would clash with EFFS_OK return code). If no inodes // block is found or another error occurs, we return the error code. bref_t blocks_fsck(void) { bref_t b, b_to_clean, b_inode_lost; int age_valid; age_t age_min, age_max, age_dist, age_dist_min, age_dist_max; struct block_header_s *bhp; struct block_header_old_s *obhp; ttw(str(TTrInitLow, "blocks_fsck {" NL)); tw(tr(TR_BEGIN, TrFsck, "blocks_fsck() {\n")); // initialize ages to the illegal/unset value age_min = age_max = age_dist = 0; fs.format = 0; fs.inodes = -1; fs.newinodes = -1; b_inode_lost = -1; b_to_clean = EFFS_OK; for (b = 0; b < dev.numblocks; b++) { tlw(led_toggle(LED_DRV_INIT)); // read block flags from flash bhp = (struct block_header_s *) offset2addr(dev.binfo[b].offset); obhp = (struct block_header_old_s *) bhp; bstat[b].used = dev.blocksize; bstat[b].lost = bstat[b].used; bstat[b].flags = bhp->flags; bstat[b].objects = 0; age_valid = 0; if (bhp->magic_low != BLOCK_MAGIC_LOW || bhp->magic_high != BLOCK_MAGIC_HIGH) { // The block magic as bad! It *could* be because the flash // memory map is incorrect or because another application has // spuriously written to the flash or ... who knows what. First // we check to see if the reason is that we are dealing with a // (really) old ffs format version. if (obhp->magic_low == OLD_BLOCK_MAGIC_LOW && obhp->magic_high == OLD_FFS_FORMAT_VERSION) { tw(tr(TR_FUNC, TrFsck, "OLD ")); fs.format = obhp->magic_high; // We simulate that all the blocks are data blocks, in order // to have some well-defined state that preformat() can work // on. Later we will return EFFS_BADFORMAT and otherwise // leave everything as it is, *without* modifying anything! bstat[b].flags = BF_IS_DATA; } else { // Quickly test if block is in empty state. We do not make a // full check with block_used() because that takes too // long --- we let preformat() do that. if (bhp->magic_low == FLASH_NULL16 && bhp->magic_high == FLASH_NULL16 && bhp->age == FLASH_NULL16 && bhp->version == FLASH_NULL16 && bhp->flags == FLASH_NULL16) { bstat[b].used = 0; bstat[b].lost = 0; bstat[b].flags = BF_IS_EMPTY; tw(tr(TR_FUNC, TrFsck, "EMPTY ")); } else { // If the block is not free, it is probably corrupted. // Thus we reset its age and free it. tw(tr(TR_FUNC, TrFsck, "magic = 0x%08x\n", bhp->magic_low | (bhp->magic_high << 16))); ffsdrv.write_halfword(&bhp->age, 0); block_free(b); tw(tr(TR_FUNC, TrFsck, "BAD ")); } } } else { fs.format = bhp->version; age_valid = 1; if (!is_block(b, BF_IS_FREE)) { bstat[b].used = block_used(b); bstat[b].lost = bstat[b].used - BHEADER_SIZE; } if (is_block(b, BF_IS_FREE)) { // The only case where we do not call block_used() is // when the block is truly free. bstat[b].used = 0; bstat[b].lost = 0; tw(tr(TR_FUNC, TrFsck, "FREE ")); ttw(ttr(TTrInitLow, "FREE" NL)); } else if (is_block(b, BF_IS_DATA)) { tw(tr(TR_FUNC, TrFsck, "DATA ")); ttw(ttr(TTrInitLow, "DATA" NL)); } else if (is_block(b, BF_IS_CLEANING)) { // Here we schedule a block_clean(). Note that we can // and do not execute the block cleaning now, as the info // that block_clean() needs is not at all ready at this // point in the initialization. So we set a flag and then // clean the block at the end of ffs_initialize() tw(tr(TR_FUNC, TrFsck, "CLEANING ")); ttw(ttr(TTrInitLow, "CLEANING" NL)); b_to_clean = b + 1; } else if (is_block(b, BF_IS_COPYING)) { tw(tr(TR_FUNC, TrFsck, "COPYING ")); ttw(ttr(TTrInitLow, "COPYING" NL)); fs.newinodes = b; } else if (is_block(b, BF_IS_INODES)) { tw(tr(TR_FUNC, TrFsck, "INODES ")); ttw(ttr(TTrInitLow, "INODES" NL)); fs.inodes = b; } else if (is_block(b, BF_IS_INODES_LOST)) { tw(tr(TR_FUNC, TrFsck, "INODESLOST")); ttw(ttr(TTrInitLow, "INODESLOST" NL)); b_inode_lost = b; } else { block_free(b); tw(tr(TR_FUNC, TrFsck, "INVALID ")); ttw(ttr(TTrInitLow, "INVALID" NL)); } } tw(tr(TR_NULL, TrFsck, " %2d: (0x%05x) %02x, used = %6d\n", b, dev.binfo[b].offset, bstat[b].flags & 0xFF, bstat[b].used)); if (age_valid) { if (age_min == 0) { // Initialize minimum and maximum block ages age_min = age_max = bhp->age; tw(tr(TR_FUNC, TrFsckLow, "age_min/max = %d\n", age_min)); } else { age_dist_min = age_distance(bhp->age, age_min); age_dist_max = age_distance(bhp->age, age_max); if (age_dist_min > age_dist || age_dist_max > age_dist) { if (age_dist_max > age_dist_min) { age_dist = age_dist_max; age_min = bhp->age; tw(tr(TR_FUNC, TrFsckLow, "age_min = %d (dist = %d)\n", age_min, age_dist)); } else { age_dist = age_dist_min; age_max = bhp->age; tw(tr(TR_FUNC, TrFsckLow, "age_max = %d (dist = %d)\n", age_max, age_dist)); } } } } } tlw(led_off(LED_DRV_INIT)); tw(tr(TR_FUNC, TrFsck, "age min, max, max-min = %d, %d, %d\n", age_min, age_max, (uint16) (age_max-age_min))); // If age_max is untouched is is because all blocks were in the 'Empty' // state. In this case we let the age be as it is (0xFFFF). if (age_max == 0) age_max = age_min = BLOCK_AGE_MAX; // Handle age wrap around thus ensuring fs.age_max is set correctly. We // have to type-cast the whole computation, otherwise it will be // incorrect. if ((age_t) (age_max - age_min) > 0x8000) { age_dist = age_max; age_max = age_min; age_min = age_dist; } // save maximum age found for the case of a bad block that is going to // be reclaimed later on by blocks_reclaim() fs.age_max = age_max; tw(tr(TR_FUNC, TrFsck, "fs.format = 0x%04x\n", fs.format)); tw(tr(TR_FUNC, TrFsck, "fs.inodes, newinodes = %d, %d\n", fs.inodes, fs.newinodes)); ttw(ttr(TTrInit, "fs.inodes, newinodes = %d, %d" NL, fs.inodes, fs.newinodes)); tw(tr(TR_FUNC, TrFsck, "age min, max = %d, %d\n", age_min, age_max)); // If any blocks were in the EMPTY state, now is the time to bring them // into the FREE state. Note that we must only do this *after* // fs.age_max has been initialized. for (b = 0; b < dev.numblocks; b++) { if (is_block(b, BF_IS_EMPTY)) { if ((bstat[b].used = block_used(b)) == 0) block_preformat(b, 0); else block_free(b); } } if (fs.inodes >= 0) { // The 'old' inode block is still valid thus we keep it. if (fs.newinodes >= 0) // The copying of inodes to the new block was not finished thus // we free the block block_free(fs.newinodes); inodes_set(fs.inodes); } else { // Copying must have been finished if (fs.newinodes >= 0 && b_inode_lost >= 0) { // The inode reclaim did finish but currently there is no valid // inode block thus the operation must be finished by committing // the new block as the valid inode block. fs.inodes = b_inode_lost; block_commit(); } else { // No old or new Inode block! tw(tr(TR_END, TrFsck, "} %d\n", EFFS_NOFORMAT)); ttw(ttr(TTrInitLow, "} %d" NL, EFFS_NOFORMAT)); return EFFS_NOFORMAT; } } if ((fs.format >> 8) != (FFS_FORMAT_VERSION >> 8)) { tw(tr(TR_END, TrFsck, "} %d\n", EFFS_BADFORMAT)); ttw(ttr(TTrInitLow, "} %d" NL, EFFS_BADFORMAT)); return EFFS_BADFORMAT; } // FIXME: Insert age sanity check; age distance must not be too big (> 2 // * FFS_AGE_DISTANCE)? tw(tr(TR_END, TrFsck, "} %d\n", b_to_clean)); ttw(ttr(TTrInitLow, "} %d" NL, b_to_clean)); return b_to_clean; } // Set fs.inodes and fs.inodes_addr void inodes_set(iref_t i) { fs.inodes = i; fs.inodes_addr = (struct inode_s *) (offset2addr(dev.binfo[fs.inodes].offset) + dev.atomsize - sizeof(struct inode_s)); } /****************************************************************************** * inodes_fsck() ******************************************************************************/ // Now for each inode in the inodes block, update the bstat array // information: free, used, objects. Also, locate the root inode. We could // optimize this a little, because bstat[binodes].used gives an inidication // of how many inodes are actually present in the system. iref_t inodes_fsck(void) { iref_t i; struct inode_s *ip; char *addr; bref_t block; ttw(str(TTrInitLow, "inodes_fsck {" NL)); tw(tr(TR_BEGIN, TrFsck, "inodes_fsck() {\n")); tw(tr(TR_FUNC, TrFsck, "inodes in block %d:\n", fs.inodes)); // the fields of the bstat entry for the inodes have the meaning: // used = total number of used inodes (valid, erased, invalid) // lost = total number of lost inodes (erased, invalid) // objects = index of first free inode (used by inode_alloc()) fs.root = 0; // default to root inode not found fs.ijournal = 0; // default to journal file inode not found bstat[fs.inodes].objects = 1; bstat[fs.inodes].used = 0; bstat[fs.inodes].lost = 0; fs.sequence = 0; // just for debug (fun) // we must set some default value for this, so we set it to max possible! fs.inodes_max = dev.blocksize / sizeof(struct inode_s); ip = inode_addr(1); tw(tr(TR_FUNC, TrFsck, " i addr cld sib seq upd flag size name\n")); for (i = 1; i < fs.inodes_max; i++, ip++) { // just for debug (fun) if (ip->sequence > fs.sequence) fs.sequence = ip->sequence; // compute block index and total data space occupied block = offset2block(location2offset(ip->location)); // Only scan used inodes. blocks_fsck() accounted all used space as // also being lost space, so now we subtract from the lost space, // the space used by valid objects if (ip->location != FLASH_NULL32) { bstat[fs.inodes].used++; tw(tr(TR_FUNC, TrFsck, "%3d 0x%05X %3d %3d %4d %3d %s%s%s%s%s%s %6d %s\n", i, location2offset(ip->location), ip->child, ip->sibling, ip->sequence, ip->updates, is_object(ip, OT_DIR) ? "d" : "", is_object(ip, OT_LINK) ? "l" : "", is_object(ip, OT_FILE) ? "f" : "", is_object(ip, OT_SEGMENT) ? "s" : "", is_object(ip, OT_ERASED) ? " " : "", IS_BIT_SET(ip->flags, OF_READONLY) && !is_object(ip, OT_ERASED) ? "r" : " ", ip->size, // Erased chunks do not have any name so we can not trace erased objects! (ip->size && !is_object(ip, OT_SEGMENT) && !is_object(ip, OT_ERASED) ? addr2name(offset2addr(location2offset(ip->location))) : "") )); if (is_object_valid(ip)) { // This inode is valid, so we account the data space as used // and the inode as used too. bstat[block].lost -= ip->size; bstat[block].objects++; // test if this is the root inode. store index if it is. if (!is_object(ip, OT_SEGMENT)) { addr = addr2name(offset2addr(location2offset(ip->location))); if (*addr == '/') fs.root = i; else if (*addr == '.' && ffs_strcmp(addr, FFS_JOURNAL_NAME) == 0) { fs.ijournal = i; } } } else if (is_object(ip, OT_ERASED)) { // this inode's data is deleted, so we account the data // space as used and lost and the inode as lost too. bstat[fs.inodes].lost++; } else { // This is an invalid object, so we account the data space // as used and lost and the inode as lost too. NOTEME: error // what should we do? Perhaps we should record semi-lost // inodes? Can we safely account for it here if this is an // object to be recovered because another inode.copied is // referring to this? Will used/lost etc. be updated // correctly then? bstat[fs.inodes].lost++; tw(tr(TR_NULL, TrFsck, "(invalid = %d)\n", ip->flags & OT_MASK)); } } } ttw(ttr(TTrInit, "fs.root=%d, journal=%d" NL, fs.root, fs.ijournal)); tw(tr(TR_END, TrFsck, "} used: %d, lost: %d, root: %d, journal: %d\n", bstat[fs.inodes].used, bstat[fs.inodes].lost, fs.root, fs.ijournal)); fs.sequence++; tw(tr_bstat()); if (fs.root == 0) { ttw(ttr(TTrInitLow, "} %d" NL, EFFS_NOFORMAT)); return EFFS_NOFORMAT; } ttw(str(TTrInitLow, "} 0" NL)); return EFFS_OK; } /****************************************************************************** * Preformat and format ******************************************************************************/ // Prepare all blocks for fs_format(). Because ffs_is_formattable() has // already been called prior to this function, we know that no sector erase // is in progress! The blocks are prepared by putting them into the 'Free' // state. effs_t fs_preformat(void) { bref_t b; ttw(str(TTrFormat, "preformat {" NL)); tw(tr(TR_BEGIN, TrFormat, "fs_preformat() {\n")); // Mark ffs as being non-formatted from now on. fs.root = 0; // We must initialize bstat[fs.inodes].used and inodes_high, such that // inodes_reclaim() isn't triggered in reclaim() on the following // fs_format(). inodes_set(0); bstat[fs.inodes].used = 0; bstat[fs.inodes].lost = 0; bstat[fs.inodes].objects = 0; // While format is in progress, we make FFS inaccessible to other // functions... fs.initerror = EFFS_NOFORMAT; if (dev.manufact == 0) { b = EFFS_NODEVICE; } else { for (b = 0; b < dev.numblocks; b++) { if (is_block(b, BF_IS_EMPTY)) { if ((bstat[b].used = block_used(b)) == 0) block_preformat(b, 0); else block_free(b); } else if (!is_block(b, BF_IS_FREE)) { block_free(b); } } b = EFFS_OK; } tw(tr(TR_END, TrFormat, "} %d\n", b)); ttw(ttr(TTrFormat, "} %d" NL, b)); return b; } // Preformat a single block thus taking it from the 'Empty' state into // 'Free' state. void block_preformat(bref_t b, age_t age) { int set_age_max; struct block_header_s *bhp = (struct block_header_s *) offset2addr(dev.binfo[b].offset); tw(tr(TR_BEGIN, TrFormat, "fs_block_preformat(%d, %d)\n", b, age)); if (age == 0) { age = fs.age_max; } else { // We schedule an update of fs.age_max. Due to proper handling of // age wrap-around, we can not actually set it now. set_age_max = (age == fs.age_max); age++; if (age == 0) age++; if (set_age_max) { fs.age_max = age; tw(tr(TR_FUNC, TrFormat, "new fs.age_max = %d\n", fs.age_max)); } } ffsdrv.write_halfword(&bhp->age, age); ffsdrv.write_halfword(&bhp->version, FFS_FORMAT_VERSION); ffsdrv.write_halfword(&bhp->magic_low, BLOCK_MAGIC_LOW); ffsdrv.write_halfword(&bhp->magic_high, BLOCK_MAGIC_HIGH); bstat[b].flags = BF_IS_EMPTY; bstat[b].used = 0; bstat[b].lost = 0; bstat[b].objects = 0; block_flags_write(b, BF_FREE); tw(tr(TR_END, TrFormat, "")); } // After preformat() has erased two blocks, this function can be called to // initialize ffs by writing fs data and metadata. Note that ffs_begin() is // *not* called before this function in ffs.c. Otherwise we would never // enter this function because fs.root is zero. NOTEME: this is also a bug // as this means we risk that this operation is started while an erase (or a // write) is in progress! How the flash device reacts to this is currently // unknown. effs_t fs_format(const char *name) { bref_t i, b; ttw(str(TTrFormat, "format {" NL)); tw(tr(TR_BEGIN, TrFormat, "fs_format('%s') {\n", name)); // Initialize file system parameters. It should be safe to change these // now, as the format cannot fail at this point onwards. fs_params_init(name); // Make the first block be the inodes block if ((fs.inodes = block_alloc(1, BF_COPYING)) < 0) return EFFS_AGAIN; block_flags_write(fs.inodes, BF_INODES); inodes_set(fs.inodes); // Make all block as data blocks except from the free_min and inode block for (i = 0; i < dev.numblocks - fs.blocks_free_min - 1; i++) if ((b = block_alloc(0, BF_DATA)) < 0) return EFFS_AGAIN; // Restart object sequencing (debug feature only) fs.sequence = 0; // Create root directory journal_begin(0); if ((fs.root = object_create(name, 0, 0, 0)) < 0) { tw(tr(TR_END, TrFormat, "} %d\n", fs.root)); return fs.root; } journal_commit(OT_DIR); if ((fs.ijournal = journal_create(0)) < 0) { tw(tr(TR_END, TrFormat, "} %d\n", fs.ijournal)); return fs.ijournal; } fs.initerror = ffs_initialize(); ttw(ttr(TTrFormat, "} %d" NL, fs.initerror)); tw(tr(TR_END, TrFormat, "} %d\n", fs.initerror)); return fs.initerror; } // Check if we are ready to preformat (flag = 0) or format (flag = 1) // // For a format, we must first ensure no blocks are valid e.g. a preformat // has already been run. Next, we must ensure we have preformatted all // blocks e.g. all blocks are in the 'Free' state. This is actually the same // thing but it sure helps the user because it yields a more precise error // code when the format fails. In future we might be able to start a format // when only two blocks have been preformatted, but this is harder because // we have to make sure not to read from the physical sector that we are // erasing, and this is exactly what ffs_ffs_initialize() currently does // (when it is called at the end of format()). // // For a preformat, we must ensure an erase is not in progress (because we // don't know how the device will react to a new erase when an erase is // currently suspended). effs_t is_formattable(int8 flag) { bref_t i, free, valid; effs_t error = EFFS_OK; tw(tr(TR_FUNC, TrFormat, "is_formattable() ")); // Count the number of valid and free blocks. These numbers will later // be checked to see if we are really ready for a (pre)format(). Note // that we *only* read block flags from the bstat[] array. We must not // read directly from the flash sectors because an erase might be in // progress! for (i = 0, free = 0, valid = 0; i < dev.numblocks; i++) { if (is_block(i, BF_IS_DATA) || is_block(i, BF_IS_INODES)) valid++; if (is_block(i, BF_IS_FREE)) free++; } if (flag == 0) { // In the case of a preformat, ensure an erase is not in // progress (because we don't know how the device will react to a new // erase when an erase is currently suspended). if (dev.state == DEV_ERASE || dev.state == DEV_ERASE_SUSPEND) { tw(tr(TR_NULL, TrFormat, "(%d)\n", EFFS_AGAIN)); return EFFS_AGAIN; } } else { if (valid > 0) // Ensure we have preformatted prior to a format. error = EFFS_NOPREFORMAT; else if (free < dev.numblocks) // Ensure all blocks are free before a format(). If not, a // preformat() is currently in progress. error = EFFS_AGAIN; } tw(tr(TR_NULL, TrFormat, "(%d)\n", error)); return error; } /****************************************************************************** * Journalling ******************************************************************************/ // The following matrix illustrates how the members of an inode change for // the various (journalled) operations: // // | flags | size | loc | child | siblg | dir | oldi | updates // ---------+-------+------+-----+-------+-------+-----+------+-------- // create | new | new | new | - | - | ins | n/a | 0 // fupdate | o | new | new | o | - | ins | del | old+1 // relocate | o | o | new | o | - | ins | del | old+1 // fctrl | new | o | o | o | - | ins | del | old+1 // remove | n/a | n/a | n/a | n/a | n/a | n/a | del | n/a // // - = leave empty (0xFFFF) // ins = insert/append into directory // o = old value // // We don't have to store child member in the journal entry because either // it is EMPTY (fs.journal.oldi = 0) or it is retrieved from oldip->child. // NOTEME: With journalling implemented, object_relocate might be able just // to make a simple data copy! // block_clean() is safe (without journalling), now that only ip->size is // set to zero. // Begin a new journal. Either a fresh object create (oldi == 0) or an // update of an existing object (oldi == iref of old object) void journal_begin(iref_t oldi) { tw(tr(TR_FUNC, TrJournal, "journal_begin(%d)\n", oldi)); fs.journal.i = 0; fs.journal.state = JOURNAL_IS_EMPTY; fs.journal.repli = 0; fs.link_child = 1; //Default link child in journal_commit() if (oldi == 0) { fs.journal.flags = 0xFF; fs.journal.diri = 0; fs.journal.oldi = 0; fs.journal.location = 0; fs.journal.size = 0; } else { struct inode_s *oldip = inode_addr(oldi); fs.journal.flags = oldip->flags; fs.journal.diri = oldi; fs.journal.oldi = oldi; fs.journal.location = oldip->location; fs.journal.size = oldip->size; } } // NOTEME: We have compressed the macro code because it will NOT compile on // Unix otherwise. So until we find out why, we use this as a work-around. #if (FFS_TEST == 1) #define JOURNAL_TEST(testcase, text) if (fs.testflags == testcase) { tw(tr(TR_END, TrJournal, "} (" text ")\n")); return; } #else #define JOURNAL_TEST(testcase, text) #endif // NOTEME: Should we empty journal file when we are anyway relocating it in // data_reclaim()? void journal_end(uint8 type) { struct inode_s *ip = inode_addr(fs.ijournal); struct journal_s *addr = (struct journal_s *) offset2addr(location2offset(ip->location) + fs.journal_pos); tw(tr(TR_BEGIN, TrJournal, "journal_end(0x%x) {\n", type)); tw(tr(TR_FUNC, TrJournal, "journal_pos = 0x%04x (%d)\n", fs.journal_pos, (fs.journal_pos - JOURNAL_POS_INITIAL) / sizeof(struct journal_s))); // If this is a create, set the object type if (type != 0 && fs.journal.oldi == 0) fs.journal.flags = (fs.journal.flags & OF_MASK) | type; // If there is no journal file, we can do without it, although we // certainly don't like it! if (fs.ijournal == 0) { journal_commit(0); tw(tr(TR_END, TrJournal, "} No jounal file\n")); return; } JOURNAL_TEST(JOURNAL_TEST_EMPTY, "Oops in JOURNAL_IS_EMPTY"); // Write RAM journal to journal file. if (fs.journal.state == (uint8) JOURNAL_IS_EMPTY) { fs.journal.state = JOURNAL_IS_WRITING; ffsdrv.write(addr, &fs.journal, sizeof(fs.journal)); } JOURNAL_TEST(JOURNAL_TEST_WRITING, "Oops in JOURNAL_IS_WRITING"); // Advance journal file's state if (fs.journal.state == (uint8) JOURNAL_IS_WRITING) { fs.journal.state = JOURNAL_IS_READY; ffsdrv_write_byte(&addr->state, fs.journal.state); } JOURNAL_TEST(JOURNAL_TEST_READY, "Oops in JOURNAL_IS_READY"); journal_commit(0); JOURNAL_TEST(JOURNAL_TEST_COMMITTING, "Oops in JOURNAL_TEST_COMMITTING"); JOURNAL_TEST(JOURNAL_TEST_COMMITTED, "Oops in JOURNAL_COMMITTED"); // Advance journal file's state ffsdrv_write_byte(&addr->state, JOURNAL_IS_DONE); JOURNAL_TEST(JOURNAL_TEST_DONE, "Oops in JOURNAL_IS_DONE"); // Advance journal fs.journal_pos += sizeof(struct journal_s); // Unless we are currently relocating the journal file itself, check if // journal file is near full and relocate it if it is. if (fs.journal_pos >= fs.journal_size - FFS_JOURNAL_MARGIN * sizeof(struct journal_s) && fs.journal.oldi != fs.ijournal) { tw(tr(TR_FUNC, TrJournal, "Journal file (near) full!\n")); journal_create(fs.ijournal); } // Check if we have just committed the journal file itself if (fs.journal.oldi == fs.ijournal) { fs.journal_pos = JOURNAL_POS_INITIAL; fs.ijournal = fs.journal.i; tw(tr(TR_FUNC, TrJournal, "Journal file re-created, fs.ijournal = %d\n", fs.ijournal)); } tw(tr(TR_END, TrJournal, "}\n")); } // Write contents of fs.journal to FFS meta data (inodes). Note that we do // NOT traverse ip->copied as we used to do in the old // object_update_commit(). Also, we do not check if object has been // erased after traversing ip->copied. All this code has been removed // because we will very soon have full callback functionality and thus the // code is redundant. void journal_commit(uint8 type) { struct inode_s *ip = inode_addr(fs.journal.i); struct inode_s *oldip = inode_addr(fs.journal.oldi); struct inode_s *dp; bref_t b; tw(tr(TR_BEGIN, TrJournal, "journal_commit(%d) {\n", type)); tw(tr(TR_FUNC, TrJournal, "i = %d\n", fs.journal.i)); ttw(ttr(TTrObj, "jc(){" NL)); if (fs.journal.i) { // If this is a create, set the object type if (type != 0 && fs.journal.oldi == 0) fs.journal.flags = (fs.journal.flags & OF_MASK) | type; tw(tr(TR_FUNC, TrJournal, "loc = 0x%04x, size = %d\n", fs.journal.location, fs.journal.size)); ffsdrv.write((uint32 *) &ip->location, (uint32 *) &fs.journal.location, sizeof(location_t)); ffsdrv.write_halfword((uint16 *) &ip->size, fs.journal.size); if (fs.journal.oldi != 0 && fs.link_child != 0) // If this is an update, we copy the child member from old // inode. We must do this before we validate the new object, // otherwise an intermediate readdir() will detect an empty // directory! ffsdrv.write_halfword((uint16*) &ip->child, oldip->child); tw(tr(TR_FUNC, TrJournal, "seq = %d\n", fs.sequence)); // We must check if sequence is already written because if this // commit was inititiated by journal_init(), we don't know exactly // what was written if (ip->sequence == FLASH_NULL16) ffsdrv.write_halfword(&ip->sequence, fs.sequence++); if (fs.journal.oldi == 0) ffsdrv.write_halfword(&ip->updates, 0); else ffsdrv.write_halfword(&ip->updates, oldip->updates + 1); JOURNAL_TEST(JOURNAL_TEST_COMMITTING, "Oops in JOURNAL_TEST_COMMITTING") // Insert object into directory structure. We must do this before // deleting old object, otherwise an intermediate readdir() will // fail with EFFS_NOTFOUND. Note that when the root directory is // created, fs.journal.diri is zero --- thus the test! if (fs.journal.diri != 0) { tw(tr(TR_FUNC, TrJournal, "diri = %d ", fs.journal.diri)); if (fs.journal.diri < 0) { tw(tr(TR_NULL, TrJournal, "child\n")); dp = inode_addr(-fs.journal.diri); ffsdrv.write_halfword((uint16 *) &dp->child, fs.journal.i); } else { tw(tr(TR_NULL, TrJournal, "sibling\n")); dp = inode_addr(fs.journal.diri); ffsdrv.write_halfword((uint16 *) &dp->sibling, fs.journal.i); } } // The new object is validated before the old object is deleted. // This is in order to avoid an interrupting stat or read operation // to fail with EFFS_NOTFOUND tw(tr(TR_FUNC, TrJournal, "flags = 0x%02x\n", fs.journal.flags)); ffsdrv_write_byte(&ip->flags, fs.journal.flags); // Update bstat[] appropriately b = offset2block(location2offset(ip->location)); bstat[b].objects++; tw(tr(TR_FUNC, TrJournal, "bstat[%d].objects = %d\n", b, bstat[b].objects)); } tw(tr(TR_FUNC, TrJournal, "oldi = %d\n", fs.journal.oldi)); if (fs.journal.oldi != 0) { // If this is an update or an erase, we erase the old object ffsdrv_write_byte(&oldip->flags, OT_ERASED); // Update bstat according to deletion of the old object. b = offset2block(location2offset(oldip->location)); bstat[b].objects--; tw(tr(TR_FUNC, TrJournal, "bstat[%d].objects = %d\n", b, bstat[b].objects)); // If we moved the data (all cases, except fcontrol), update lost if (fs.journal.location != oldip->location) bstat[b].lost += oldip->size; bstat[fs.inodes].lost++; // If we renamed a file to an existing filename, remove the replaced file. if (fs.journal.repli > 0) object_remove(fs.journal.repli); // Ignore error! } tw(tr(TR_END, TrJournal, "}\n")); ttw(ttr(TTrObj, "}" NL)); } // Save the current journal into "old" journal. We need this because an // object_create() can call data_reclaim() which can call object_relocate() // which uses the journal system. int journal_push(void) { memcpy(&fs.ojournal, &fs.journal, sizeof(struct journal_s)); fs.journal_depth++; if (fs.journal_depth > 1) { tw(tr(TR_FUNC, TrAll, "FATAL: journal_push() to depth %d\n", fs.journal_depth)); return -1; } tw(tr(TR_FUNC, TrJournal, "journal_push() to depth %d\n", fs.journal_depth)); return EFFS_OK; } // Recall "old" journal into current journal int journal_pop(void) { tw(tr(TR_FUNC, TrJournal, "journal_pop() from depth %d\n", fs.journal_depth)); fs.journal_depth--; if (fs.journal_depth < 0) { tw(tr(TR_FUNC, TrAll, "FATAL: journal_pop() to depth %d\n", fs.journal_depth)); return -1; } memcpy(&fs.journal, &fs.ojournal, sizeof(struct journal_s)); return EFFS_OK; } // Initialize the journalling system. Create journal file if it not already // exist. Commit/write pending journal if such exists --- return 1 in that // case. Otherwise, if journal file is clean (no journals pending) and all // is fine, return EFFS_OK. effs_t journal_init(iref_t i) { int j; struct inode_s *ip = inode_addr(i); struct journal_s *addr; if (i == 0) { // Journal file does not exist, so create it if ((i = journal_create(0)) <= 0) { fs.ijournal = 0; return i; } } fs.journal_depth = 0; fs.journal_pos = JOURNAL_POS_INITIAL; addr = (struct journal_s *) offset2addr(location2offset(ip->location) + fs.journal_pos); tw(tr(TR_BEGIN, TrJournal, "journal_init(%d) {\n", i)); fs.ijournal = i; // Search for first non-completed journal entry. for (j = 0; /* FIXME: limit to end of journal */; j++, addr++) { if (addr->state != (uint8) JOURNAL_IS_DONE) break; } tw(tr(TR_FUNC, TrJournal, "entry %d is in state 0x%x\n", j, addr->state)); fs.journal_pos += j * sizeof(fs.journal); i = EFFS_OK; if (addr->state == (uint8) JOURNAL_IS_EMPTY) { tw(tr(TR_FUNC, TrJournal, "Last journal is in EMPTY state\n")); // Journal file is proper, so just record position } else if (addr->state == (uint8) JOURNAL_IS_READY) { // Copy the entry into fs.journal. tw(tr(TR_FUNC, TrJournal, "Last journal is in READY state\n")); memcpy(&fs.journal, addr, sizeof(fs.journal)); journal_end(0); i = 1; } else { // Journal entry wasn't finished, so just ignore it after updating // its state to JOURNAL_IS_DONE. tw(tr(TR_FUNC, TrJournal, "Last journal is between EMPTY and READY\n")); ffsdrv_write_byte(&addr->state, JOURNAL_IS_DONE); fs.journal_pos += sizeof(fs.journal); } if (ip->size != fs.journal_size + atomalign(sizeof(FFS_JOURNAL_NAME) + 1)) { tw(tr(TR_FUNC, TrJournal, "Wrong journal size, create new\n")); // Journal size do not match default size, so create new. This // should only happen if we use an old FFS image with a newer FFS // version. if ((i = journal_create(fs.ijournal)) <= 0) { fs.ijournal = 0; return i; } } tw(tr(TR_FUNC, TrJournal, "journal_pos = 0x%04x\n", fs.journal_pos)); tw(tr(TR_END, TrJournal, "} %d\n", i)); return i; } // Create the journal file from scratch or relocate an existing one. It is // marked read-only just for clarity --- it cannot be deleted anyway! // fs_format() calls this function. Note that no data are written in // object_create() because the journal file is handled specially in that // function. iref_t journal_create(iref_t oldi) { iref_t i; tw(tr(TR_BEGIN, TrJournal, "journal_create(%d) {\n", oldi)); tw(tr(TR_FUNC, TrJournal, "journal file size = %d\n", fs.journal_size)); if (fs.journal_size == 0) { tw(tr(TR_FUNC, TrJournal, "Journal file creation aborted because fs.journal_size = 0 (No journal file wanted)\n")); tw(tr(TR_END, TrJournal, "} %d\n", 0)); return 0; } // If we are working on a write-once file system, we do not need a // journal. if (fs.blocks_free_min == 0) { tw(tr(TR_FUNC, TrJournal, "Journal file creation aborted because fs.blocks_free_min = 0 (write-once system)\n")); tw(tr(TR_END, TrJournal, "} %d\n", 0)); return 0; } journal_begin(oldi); i = object_create(FFS_JOURNAL_NAME, 0, fs.journal_size, -fs.root); if (i < 0) { tw(tr(TR_END, TrJournal, "} %d\n", i)); return i; } fs.journal.flags = BIT_SET(fs.journal.flags, OF_READONLY); // commit the creation or relocation if (oldi != 0) journal_end(0); else { journal_commit(OT_FILE); fs.journal_pos = JOURNAL_POS_INITIAL; } tw(tr(TR_END, TrJournal, "} %d\n", i)); return i; } /****************************************************************************** * FFS Begin and End ******************************************************************************/ // The following two functions should surround the code of every API // function in ffs.c (except preformat and format). The functions // ensures that the operation about to be executed can be made without // race-conditions or other problems. #if (TARGET == 0) int debug_suspend = 0; #endif // Check if ffs has been initialized. Suspend an erase operation. effs_t ffs_begin(void) { #if (TARGET == 0) if (debug_suspend > 0) { tw(tr(TR_FUNC, TrAll, "FATAL: Previous erase_suspend was not resumed\n")); return EFFS_CORRUPTED; } // tw(tr(TR_FUNC, TrHelper, "Set debug_suspend\n")); debug_suspend = 1; #endif if (fs.initerror != EFFS_OK) return fs.initerror; // Suspend an erase in progress (only applicable if we are using a // multi-bank device driver) if (dev.state == DEV_ERASE) { ffsdrv.erase_suspend(); } else if (dev.state == DEV_WRITE) { ffsdrv.write_end(); } return EFFS_OK; } // Resume an erase operation that was in progress. int ffs_end(int error) { #if (TARGET == 1) // Resume an erase in progress (only applicable if we are using a // multi-bank device driver) if (dev.state == DEV_ERASE_SUSPEND) { ffsdrv.erase_resume(); } #else debug_suspend = 0; #endif return error; } /****************************************************************************** * FFS Statistics functions ******************************************************************************/ // Not implemented: int statistics_file_create(void) { return 0; } // Not implemented: // Rewrite the statistics file if it exists. Otherwise return error // code. The function is called after each data and inodes reclaim (after // writing the file that provoked the reclaim). int statistics_write(void) { return 0; } // Read the statistics file if it exists. Otherwise reset all statistics to // zero and set the magic. This function is called from ffs_init(). void statistics_init(void) { memset(&stats, 0, sizeof(struct ffs_stats_s)); } void statistics_update_drec(int valid, int lost, int candidate) { unsigned int old; switch (candidate) { case MOST_LOST: stats.drec.most_lost++; break; case MOST_UNUSED: stats.drec.most_unused++; break; case YOUNGEST: stats.drec.youngest++; break; } // Increment Most Significant Word if overflow is detected old = stats.drec.valid[0]; stats.drec.valid[0] += valid; if (old > stats.drec.valid[0]) stats.drec.valid[1]++; old = stats.drec.lost[0]; stats.drec.lost[0] += lost; if (old > stats.drec.lost[0]) stats.drec.lost[1]++; } void statistics_update_irec(int valid, int lost) { stats.irec.num++; stats.irec.valid += valid; stats.irec.lost += lost; }