FreeCalypso > hg > fc-selenite
view src/cs/drivers/drv_app/ffs/board/reclaim.c @ 134:7d50d8d13711
FFS code sync with Magnetite + gcc version fix
This change brings the new flash autodetection for FC and Pirelli targets
from Magnetite, and should also fix the gcc version for C1xx and gtamodem
targets, which were previously broken because they used TI's original
flash autodetect code (which operates at address 0) while the boot ROM
is mapped there.
| author | Mychaela Falconia <falcon@freecalypso.org> |
|---|---|
| date | Tue, 11 Dec 2018 08:43:25 +0000 |
| parents | b6a5e36de839 |
| children |
line wrap: on
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/****************************************************************************** * Flash File System (ffs) * Idea, design and coding by Mads Meisner-Jensen, mmj@ti.com * * FFS core reclaim functionality * * $Id: reclaim.c 1.4.1.28 Thu, 08 Jan 2004 15:05:23 +0100 tsj $ * ******************************************************************************/ #ifndef TARGET #include "ffs.cfg" #endif #include "ffs/ffs.h" #include "ffs/board/core.h" #include "ffs/board/drv.h" #include "ffs/board/ffstrace.h" #include <stdlib.h> // rand() /****************************************************************************** * Inodes Reclaim ******************************************************************************/ void inodes_recurse(iref_t i) { iref_t pi; struct inode_s *ip, *newip; tw(tr(TR_BEGIN, TrReclaimLow, "inodes_recurse(%d) {\n", i)); ip = inode_addr(i); newip = (struct inode_s *) offset2addr(dev.binfo[fs.newinodes].offset) + i; // copy inode dir to new block, except child, sibling and copied ffsdrv.write((uint32*) &newip->location, (uint32*) &ip->location, sizeof(location_t)); ffsdrv.write_halfword((uint16*) &newip->size, ip->size); ffsdrv_write_byte (&newip->flags, ip->flags); ffsdrv.write_halfword((uint16*) &newip->sequence, ip->sequence); ffsdrv.write_halfword((uint16*) &newip->updates, ip->updates); bstat[fs.newinodes].used++; // if no children of this dir, we have no more work to do if (ip->child == (iref_t) IREF_NULL) { tw(tr(TR_END, TrReclaimLow, "}\n")); return; } pi = -i; i = ip->child; ip = inode_addr(i); do { tw(tr(TR_FUNC, TrReclaimLow, "pi = %d, i = %d", pi, i)); tw(tr(TR_NULL, TrReclaimLow, ", size = %d, location = 0x%x", ip->size, ip->location)); tw(tr(TR_NULL, TrReclaimLow, ", name_addr = 0x%x", addr2name(offset2addr(location2offset(ip->location))))); if (is_object(ip, OT_SEGMENT)) tw(tr(TR_NULL, TrReclaimLow, ", (segment)\n")); else tw(tr(TR_NULL, TrReclaimLow, ", '%s'\n", (ip->size ? addr2name(offset2addr(location2offset(ip->location))) : "(cleaned)"))); if (is_object_valid(ip)) { if (is_object(ip, OT_DIR)) { tw(tr(TR_NULL, TrReclaimLow, "recursing...\n", i)); inodes_recurse(i); } else { tw(tr(TR_NULL, TrReclaimLow, "copying...\n")); // copy inode to new block, except child, sibling and copied newip = (struct inode_s *) offset2addr(dev.binfo[fs.newinodes].offset) + i; ffsdrv.write((uint32*) &newip->location, (uint32*) &ip->location, sizeof(location_t)); ffsdrv.write_halfword((uint16*) &newip->size, ip->size); ffsdrv_write_byte (&newip->flags, ip->flags); ffsdrv.write_halfword((uint16*) &newip->sequence, ip->sequence); ffsdrv.write_halfword((uint16*) &newip->updates, ip->updates); bstat[fs.newinodes].used++; } tw(tr(TR_FUNC, TrReclaimLow, "Linking: %d->%d\n",pi, i)); // now write the child or sibling link of previous inode newip = (struct inode_s *) offset2addr(dev.binfo[fs.newinodes].offset); if (pi > 0) ffsdrv.write_halfword((uint16*) &(newip + pi)->sibling, i); else ffsdrv.write_halfword((uint16*) &(newip + (-pi))->child, i); pi = i; // save index of previous inode if (ip->child != (iref_t) IREF_NULL && is_object(ip, OT_FILE)) { iref_t pis, is; struct inode_s *ips; pis = i; ips = ip; tw(tr(TR_FUNC, TrReclaimLow, "Follow segment head\n")); // While child is valid while ((is = ips->child) != (iref_t) IREF_NULL) { // Get child is = ips->child; ips = inode_addr(is); tw(tr(TR_FUNC, TrReclaimLow, "Child ok, got new child i = %d\n", is)); // While object not is valid while (!is_object_valid(ips)) { tw(tr(TR_FUNC, TrReclaimLow, "pi = %d, i = %d c(cleaned)\n", pis, is)); // If sibling are valid if (ips->sibling != (iref_t) IREF_NULL) { // Get sibling is = ips->sibling; ips = inode_addr(is); tw(tr(TR_FUNC, TrReclaimLow, "Sibling ok, got new sibling i = %d\n", is)); } else { tw(tr(TR_FUNC, TrReclaimLow, "Sibling = FF (%d)\n", ips->sibling)); break; // Nothing more todo, child and sibling = FF } } // If object is valid if (is_object_valid(ips)) { tw(tr(TR_NULL, TrReclaimLow, "copying...\n")); // copy inode to new block, except child, sibling and copied newip = (struct inode_s *) offset2addr(dev.binfo[fs.newinodes].offset) + is; ffsdrv.write((uint32*) &newip->location, (uint32*) &ips->location, sizeof(location_t)); ffsdrv.write_halfword((uint16*) &newip->size, ips->size); ffsdrv_write_byte (&newip->flags, ips->flags); ffsdrv.write_halfword((uint16*) &newip->sequence, ips->sequence); ffsdrv.write_halfword((uint16*) &newip->updates, ips->updates); bstat[fs.newinodes].used++; tw(tr(TR_FUNC, TrReclaimLow, "Linking child: %d->%d\n",pis, is)); // now write the child link of previous inode newip = (struct inode_s *) offset2addr(dev.binfo[fs.newinodes].offset); ffsdrv.write_halfword((uint16*) &(newip + (pis))->child, is); pis = is; // save index of previous inode } else { tw(tr(TR_FUNC, TrReclaimLow, "Sibling = FF (%d, %d)\n", ips->sibling, ips->child)); } } } } else { tw(tr(TR_NULL, TrReclaimLow, "(ignoring)\n")); } i = ip->sibling; ip = inode_addr(i); } while (i != (iref_t) IREF_NULL); tw(tr(TR_END, TrReclaimLow, "}\n")); } // Reclaim inodes, eg. move inodes to another block and erase old one. effs_t inodes_reclaim(void) { tw(tr(TR_BEGIN, TrIReclaim, "inodes_reclaim() {\n")); ttw(str(TTrRec, "irec{")); if (fs.initerror != EFFS_OK) { tw(tr(TR_END, TrIReclaim, "} %d\n", fs.initerror)); ttw(ttr(TTrRec, "} %d" NL, fs.initerror)); return fs.initerror; } if ((fs.newinodes = block_alloc(1, BF_COPYING)) < 0) { tw(tr(TR_END, TrIReclaim, "} %d\n", EFFS_NOBLOCKS)); ttw(ttr(TTrRec, "} %d" NL, EFFS_NOBLOCKS)); return EFFS_NOBLOCKS; } statistics_update_irec(bstat[fs.inodes].used - bstat[fs.inodes].lost, bstat[fs.inodes].lost); // copy all inodes... bstat[fs.newinodes].used = 0; inodes_recurse(fs.root); block_commit(); tw(tr(TR_END, TrIReclaim, "} 0\n")); ttw(str(TTrRec, "} 0" NL)); return EFFS_OK; } #if (FFS_TEST == 0) #define BLOCK_COMMIT_TEST(testcase, text) #else #if (TARGET == 0) // 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. #define BLOCK_COMMIT_TEST(testcase, text) if (fs.testflags == testcase) { tw(tr(TR_FUNC, TrData, "} (" text ")\n")); return; } #else #define BLOCK_COMMIT_TEST(testcase, text) if (fs.testflags == testcase) { ttw(ttr(TTrData, "} (" text ")\n")); return; } #endif #endif // Inode -> Lost, Copying -> Inode, Lost -> Free void block_commit(void) { int oldinodes = fs.inodes; tw(tr(TR_BEGIN, TrIReclaim, "block_commit(%d -> %d) {\n", oldinodes, fs.newinodes)); ttw(ttr(TTrRec, "block_commit(%d -> %d) {\n" NL, oldinodes, fs.newinodes)); BLOCK_COMMIT_TEST(BLOCK_COMMIT_BEFORE, "Oops before commit"); block_flags_write(oldinodes, BF_LOST); BLOCK_COMMIT_TEST(BLOCK_COMMIT_NO_VALID, "Oops no valid inode block"); // Validate new block as an inodes block block_flags_write(fs.newinodes, BF_INODES); bstat[fs.newinodes].lost = 0; bstat[fs.newinodes].objects = 1; inodes_set(fs.newinodes); // Free old inodes block block_free(oldinodes); BLOCK_COMMIT_TEST(BLOCK_COMMIT_OLD_FREE, "Oops after freeing old block"); BLOCK_COMMIT_TEST(BLOCK_COMMIT_AFTER, "Oops after commit"); ttw(str(TTrRec, "} 0" NL)); tw(tr(TR_END, TrIReclaim, "}\n")); } /****************************************************************************** * Data Reclaim ******************************************************************************/ // Important note: We must NOT perform a data reclaim when we are in the // process of creating the journal file! // Reclaim a data block, eg. move files to other blocks and erase old one. // When the reclaim is done, we must completely delete the old inodes which // are pointing into the old data sector which is going to be erased now. iref_t data_reclaim(int space) { iref_t error; tw(tr(TR_BEGIN, TrDReclaim, "data_reclaim(%d) {\n", space)); if (fs.initerror != EFFS_OK) { tw(tr(TR_END, TrDReclaim, "} %d\n", fs.initerror)); return fs.initerror; } error = data_reclaim_try(space); tw(tr(TR_END, TrDReclaim, "} (data_reclaim) %d\n", error)); return error; } int dage_max_reached(int dage_blk, int agegain) { int reclaim, early, log2, mask; tw(tr(TR_BEGIN, TrDReclaim, "young(%d, %d) {\n", dage_blk, agegain)); // Simple algorithm reclaim = (dage_blk + agegain - 2 * FFS_DAGE_MAX >= 0); // Early exponential probability based reclaim early = FFS_DAGE_MAX - dage_blk; if (agegain > dage_blk - 4 && 0 < early && early <= FFS_DAGE_EARLY_WIDTH) { if (early < 4) early = 2; if (early < FFS_DAGE_EARLY_WIDTH) { // Now make an exponential probability distributon by // generating a bitmask of a size relative to (dage_blk // - DAGE_EARLY_WIDTH) log2 = -1; while (early > 0) { early >>= 1; log2++; } reclaim = log2; mask = (1 << (log2 + 1)) - 1; reclaim = ((rand() & mask) == 0); } } // Do not perform a reclaim unless we gain a certain minimum if (agegain < FFS_DAGE_GAIN_MIN) reclaim = 0; tw(tr(TR_END, TrDReclaim, "} (%d)\n", reclaim)); return reclaim; } // Try to reclaim at least <space> bytes of data space. On success, return // the number of bytes actually reclaimed. Otherwise, on failure, return a // (negative) error. int data_reclaim_try(int space) { // 1. Find a suitable block to reclaim. // // 2. Relocate each valid object from old block (to another block). An // object relocation is similar to a normal file update, e.g. similar to // fupdate(). // // 3. If there is not enough space to relocate a file, we must alloc a // new block then data_format() it. // // 4. set BF_CLEANING flag of old block. // // 5. ALL inodes (also invalid an erased ones) referring into reclaimed // block must now be totally wiped out. // // 6. Free (invalidate) old block. int result = 0, reserved_ok = 0; bref_t b, blocks_free; bref_t brc_young_b, brc_lost_b, brc_unused_b; blocksize_t brc_lost_lost, brc_lost_unused; blocksize_t brc_unused_unused; blocksize_t unused, unused_total, lost, lost_total, free; age_t brc_young_dage, free_dage, dage; struct block_header_s *bhp; // Note gain can be negative if the free block is younger than the youngest data block int age_gain; tw(tr(TR_BEGIN, TrDReclaim, "data_reclaim_try(%d) {\n", space)); ttw(str(TTrRec, "drec{" NL)); // While searching for a block to reclaim, we maintain three block // reclaim candidates (brc): One with the maximum number of lost bytes, // one with the maximum number of unused bytes and another for the // youngest block, e.g. the one with the largest age distance to // fs.age_max. The candidates are tried in the order mentioned. // This counts free blocks, so we initialize to number of blocks minus // one for inodes. blocks_free = dev.numblocks - 1; // Initialize Block Reclaim Candidate (brc) variables brc_lost_b = -1; brc_lost_unused = 0; brc_lost_lost = 0; brc_unused_b = -1; brc_unused_unused = 0; brc_young_b = -1; brc_young_dage = 0; free_dage = 0; lost_total = 0; unused_total = 0; tw(tr(TR_FUNC, TrDReclaim, "blk unused lost w/age age dist objs\n")); for (b = 0; b < dev.numblocks; b++) { bhp = (struct block_header_s *) offset2addr(dev.binfo[b].offset); if (is_block(b, BF_IS_DATA)) { // Record number of lost bytes and number of unused bytes, // eg. total space that would be freed if this block was // reclaimed lost = bstat[b].lost; unused = dev.blocksize - (bstat[b].used - bstat[b].lost); free = dev.blocksize - bstat[b].used; lost_total += lost; unused_total += unused; if (free >= RESERVED_LOW) reserved_ok = 1; if (lost > brc_lost_lost) { brc_lost_b = b; brc_lost_lost = lost; brc_lost_unused = unused; } if (unused > brc_unused_unused) { brc_unused_b = b; brc_unused_unused = unused; } tw(tr(TR_FUNC, TrDReclaim, "%3d %7d %7d ", b, unused, lost)); dage = saturate_dage(fs.age_max - bhp->age); tw(tr(TR_NULL, TrDReclaim, "%6d %5d %4d %3d\n", lost, bhp->age, dage, bstat[b].objects)); if (dage >= brc_young_dage) { brc_young_b = b; brc_young_dage = dage; } blocks_free--; } else if (is_block(b, BF_IS_FREE)) { unused_total += dev.blocksize; // Find youngest free block (in must cases we will only have one free b) dage = saturate_dage(fs.age_max - bhp->age); if (dage >= free_dage) free_dage = dage; // Delta age of youngest free block } } tw(tr(TR_FUNC, TrDReclaim, "sum %7d %7d\n", unused_total, lost_total)); tw(tr(TR_FUNC, TrDReclaim, "blocks_free = %d, fs.age_max = %d\n", blocks_free, fs.age_max)); age_gain = brc_young_dage - free_dage; // Same as free - block age if (space > unused_total) { // We will never be able to reclaim this amount... result = 0; } else { // No additional blocks (apart from spare block) are free... tw(tr(TR_FUNC, TrDReclaim, "brc_young_dage = %d, brc_lost_unused = %d, brc_unused_unused = %d\n", brc_young_dage, brc_lost_unused, brc_unused_unused)); if (reserved_ok == 0) { tw(tr(TR_FUNC, TrDReclaim, "No reserved, reclaim most-lost block (%d)\n", brc_unused_b)); result = data_block_reclaim(brc_lost_b, MOST_LOST); } else if (dage_max_reached(brc_young_dage, age_gain) > 0 ) { tw(tr(TR_FUNC, TrDReclaim, "Reclaiming youngest block (%d)\n", brc_young_b)); result = data_block_reclaim(brc_young_b, YOUNGEST); } else if (brc_lost_unused >= space) { tw(tr(TR_FUNC, TrDReclaim, "Reclaiming most-lost block (%d)\n", brc_lost_b)); result = data_block_reclaim(brc_lost_b, MOST_LOST); } else if (brc_unused_unused >= space) { tw(tr(TR_FUNC, TrDReclaim, "Reclaiming most-unused block (%d)\n", brc_unused_b)); result = data_block_reclaim(brc_unused_b, MOST_UNUSED); } else { tw(tr(TR_FUNC, TrDReclaim, "Reclaiming most-lost blockx (%d)\n", brc_lost_b)); result = data_block_reclaim(brc_lost_b, MOST_LOST); if (result >= 0) result = 0; // We reclaimed a block but we still need more space } } tw(tr(TR_END, TrDReclaim, "} (data_reclaim_try) %d\n", result)); return result; } #if (FFS_TEST == 0) #define BLOCK_RECLAIM_TEST(testcase, text) #else #if (TARGET == 0) // 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. #define BLOCK_RECLAIM_TEST(testcase, text) if (fs.testflags == testcase) { tw(tr(TR_FUNC, TrTestHigh, "(" text ")\n")); tw(tr(TR_END, TrDReclaim, "} (Test) -100\n", result));return -100; } #else #define BLOCK_RECLAIM_TEST(testcase, text) if (fs.testflags == testcase) { ttw(ttr(TTrData, "} (" text ")"NL)); ttw(ttr(TTrRec, "} (Test) -100" NL));return -100; } #endif #endif #if (FFS_TEST == 0) #define BLOCK_RECOVER_TEST_INIT(testcase, text) #define BLOCK_RECOVER_TEST(testcase, text) #else #if (TARGET == 0) #define BLOCK_RECOVER_TEST_INIT(testcase, text) int rand_object; if (fs.testflags == testcase) { rand_object = rand() % bstat[b].objects; tw(tr(TR_FUNC, TrTestHigh, "Fail when object nr %d is relocated\n", rand_object)); } #define BLOCK_RECOVER_TEST(testcase, text) if (fs.testflags == testcase) {if (rand_object == n) { tw(tr(TR_FUNC, TrTestHigh, "(" text ")\n")); tw(tr(TR_END, TrDReclaim, "} (Test) -101\n", result)); return -101; } } #else #define BLOCK_RECOVER_TEST_INIT(testcase, text) int rand_object; if (fs.testflags == testcase) { rand_object = rand() % bstat[b].objects; ttw(ttr(TTrData, "Fail when object nr %d is relocated" NL, rand_object)); } #define BLOCK_RECOVER_TEST(testcase, text) if (fs.testflags == testcase) {if (rand_object == n) { ttw(ttr(TTrData, "(" text ")" NL)); ttw(ttr(TTrRec, "} (Test) -101" NL, result)); return -101; } } #endif #endif iref_t data_block_reclaim(bref_t b, int candidate) { iref_t i, n, j; blocksize_t used_old, lost_old; int org_res_space, result = 0; iref_t org_block_files_reserved; offset_t lower, upper; struct inode_s *ip; static int is_reclaim_running = 0; tw(tr(TR_BEGIN, TrDReclaim, "data_block_reclaim(%d) {\n", b)); // In case of no free blocks (after sudden power off) or if the file // system is near full we risk to be reentered (infinity recursively // loop) and we can not allow that, so just return. if (is_reclaim_running == 1) { tw(tr(TR_END, TrDReclaim, "} (reenteret skip reclaim) 0\n")); return EFFS_RECLAIMLOOP; } is_reclaim_running = 1; // If there are more objects in this block than there are remaining // free inodes, we have to make an inodes_reclaim() first. tw(tr(TR_FUNC, TrDReclaim, "block_objects, fs.inodes_max, inodes: used, free\n")); tw(tr(TR_FUNC, TrDReclaim, "%10d, %13d, %15d, %4d\n", bstat[b].objects, fs.inodes_max, bstat[fs.inodes].used, fs.inodes_max - (bstat[fs.inodes].used + bstat[fs.inodes].lost))); if (bstat[b].objects >= (fs.inodes_max - (bstat[fs.inodes].used + bstat[fs.inodes].lost + FFS_INODES_MARGIN))) { tw(tr(TR_FUNC, TrInode, "NOTE: Will run out of free inodes...\n")); inodes_reclaim(); } // Allocate a new block. NOTE: we don't return an error because if we // get in the situation where we don't have any free blocks this is the // only way to recover. if ((result = block_alloc(1, BF_DATA)) < 0) { tw(tr(TR_FUNC, TrAll, "WARNING: block_alloc failed\n")); } BLOCK_RECLAIM_TEST(BLOCK_RECLAIM_ALLOC, "Oops after ffs_block_alloc()"); // If there are any objects at all to reclaim... if (bstat[b].objects > 0) { BLOCK_RECOVER_TEST_INIT(BLOCK_RECOVER_OBJECTS, "Dummy") // Save the current journal state if (journal_push() != EFFS_OK) { is_reclaim_running = 0; // NOTEME: change to goto? return EFFS_CORRUPTED; } // We simulate that this block is completely full, such that we // don't relocate files to the end of the block used_old = bstat[b].used; lost_old = bstat[b].lost; // For statistics bstat[b].used = dev.blocksize - 1; // Compute lower (inclusive) and upper (exclusive) bounds of the // location of files in this block lower = offset2location(dev.binfo[b].offset); upper = offset2location(dev.binfo[b].offset + dev.blocksize); tw(tr(TR_FUNC, TrDReclaim, "Block addr range = 0x%X..0x%X\n", location2offset(lower), location2offset(upper))); // This is the only time we are allowed to use the reserved org_block_files_reserved= fs.block_files_reserved; fs.block_files_reserved = 0; org_res_space = fs.reserved_space; fs.reserved_space = RESERVED_NONE; ip = inode_addr(1); for (i = 1, n = 0; i < fs.inodes_max; i++, ip++) { BLOCK_RECOVER_TEST(BLOCK_RECOVER_OBJECTS, "Oops before relocate all objects"); // Ensure object is valid and within the block to be reclaimed if (is_object_valid(ip) && lower <= ip->location && ip->location < upper) { if ((result = object_relocate(i)) < 0) { tw(tr(TR_FUNC, TrAll, "FATAL object_relocate failed\n")); break; } // If we reclaim a segment head or wch that is in use we must // update the file descriptor as well for (j = 0; j < fs.fd_max; j++) { if (i == fs.fd[j].seghead) { tw(tr(TR_FUNC, TrDReclaim, "Updated seghead %d -> %d \n", fs.fd[j].seghead, result)); fs.fd[j].seghead = result; } if (i == fs.fd[j].wch) { tw(tr(TR_FUNC, TrDReclaim, "Updated wch %d -> %d \n", fs.fd[j].wch, result)); fs.fd[j].wch = result; } } // If we have just reclaimed an object which we started on // updating we must also update ojournal if (i == fs.ojournal.oldi) { struct inode_s *ip = inode_addr(result); tw(tr(TR_FUNC, TrDReclaim, "Updated ojournal oldi %d -> %d \n", fs.ojournal.oldi, result)); fs.ojournal.oldi = result; fs.ojournal.location = ip->location; } if (i == fs.ojournal.diri || i == -fs.ojournal.diri) { fs.ojournal.diri = (fs.ojournal.diri < 0 ? -result : result); tw(tr(TR_FUNC, TrDReclaim, "Updated ojournal: diri %d -> %d \n", i, fs.ojournal.diri)); } if (i == fs.ojournal.repli || i == -fs.ojournal.repli) { fs.ojournal.repli = (fs.ojournal.repli < 0 ? -result : result); tw(tr(TR_FUNC, TrDReclaim, "Updated ojournal: repli %d -> %d \n", i, fs.ojournal.repli)); } if (i == fs.i_backup || i == -fs.i_backup) { fs.i_backup = (fs.i_backup < 0 ? -result : result); tw(tr(TR_FUNC, TrDReclaim, "Updated i_backup: %d -> %d \n", i, fs.i_backup)); } n++; } } fs.block_files_reserved = org_block_files_reserved; // Restore fs.reserved_space = org_res_space; tw(tr(TR_FUNC, TrDReclaim, "Reclaimed %d objects\n", n)); if (result >= 0) result = n; // We return number of objects relocated if (i < fs.inodes_max) { // We did not finish, so restore the old bstat[].used of the block. bstat[b].used = used_old; tw(tr(TR_FUNC, TrAll, "WARNING: data_block_reclaim() not completed\n")); result = EFFS_DBR; } // Restore the saved journal state if (journal_pop() != EFFS_OK) { is_reclaim_running = 0; // NOTEME: change to goto? return EFFS_CORRUPTED; } } BLOCK_RECLAIM_TEST(BLOCK_RECLAIM_NO_CLEAN, "Oops before clean old data block"); if (result >= 0) { // Clean the block (remove all inodes that refer to this block) block_flags_write(b, BF_CLEANING); block_clean(b); statistics_update_drec(used_old - lost_old, lost_old, candidate); BLOCK_RECLAIM_TEST(BLOCK_RECLAIM_CLEANING, "Oops before free old data block"); // Free the old block block_free(b); } is_reclaim_running = 0; tw(tr(TR_END, TrDReclaim, "} (data_block_reclaim) %d\n", result)); ttw(ttr(TTrRec, "} %d" NL, result)); return result; } // Relocate object represented by inode reference <i>. iref_t object_relocate(iref_t oldi) { iref_t newi; struct inode_s *oldip; char *olddata, *oldname; int oldsize; tw(tr(TR_BEGIN, TrReclaimLow, "object_relocate(%d) {\n", oldi)); journal_begin(oldi); oldip = inode_addr(oldi); oldsize = segment_datasize(oldip); olddata = offset2addr(location2offset(oldip->location)); oldname = addr2name(olddata); olddata = addr2data(olddata, oldip); if (is_object(oldip, OT_SEGMENT)) newi = segment_create(olddata, oldsize, -oldi); else { // root inode is a special case if (*oldname == '/') newi = object_create(oldname, olddata, oldsize, 0); else newi = object_create(oldname, olddata, oldsize, oldi); } if (newi < 0) { tw(tr(TR_END, TrReclaimLow, "} %d\n", newi)); return newi; } // root inode is a special case if ((*oldname == '/') && !is_object(oldip, OT_SEGMENT)) { tw(tr(TR_FUNC, TrDReclaim, "Relocating fs.root: %d->%d\n", oldi, newi)); fs.root = newi; } journal_end(0); tw(tr(TR_END, TrReclaimLow, "} %d\n", newi)); return newi; } // Clean a block, eg. erase all inodes that refer to this block. iref_t block_clean(bref_t b) { iref_t i, n; struct inode_s *ip; offset_t lower, upper; tw(tr(TR_FUNC, TrDReclaim, "block_clean(%d) { ", b)); // Compute lower (inclusive) and upper (exclusive) bounds of the // location of files in this block lower = offset2location(dev.binfo[b].offset); upper = offset2location(dev.binfo[b].offset + dev.blocksize); tw(tr(TR_FUNC, TrDReclaim, "offset range = 0x%X..0x%X: ", lower, upper)); ip = inode_addr(1); for (i = 1, n = 0; i < fs.inodes_max; i++, ip++) { // Ensure object is within the block to be reclaimed. Note: if ffs // is conf. with 1MB or above will all not used inodes default have // the location to FFFF which will trigger a clean and make a error! if (lower <= ip->location && upper > ip->location) { tw(tr(TR_NULL, TrReclaimLow, "%d ", i)); // Set the size to zero so it won't be counted in ffs_initialize() ffsdrv.write_halfword((uint16 *) &ip->size, 0); n++; } } tw(tr(TR_NULL, TrDReclaim, "} %d\n", n)); return n; } /****************************************************************************** * Main and block reclaim ******************************************************************************/ // Reclaim (erase) all blocks that are marked as invalid/reclaimable. Each // time a block is erased, its age is incremented so as to support wear // levelling. Also, the global age limits are updated. FIXME: Should we // avoid having ffs_initialize() do a block_reclaim() because it delays reboot?. int blocks_reclaim(void) { bref_t b, n, b_lost_space; int blocks_free = 0, lost_space; int free_space, b_free_space; tw(tr(TR_BEGIN, TrBlock, "blocks_reclaim() {\n")); ttw(str(TTrRec, "blocks_reclaim() {" NL)); // Testing of fs.testflags is for the sake of testing block_commit() if ((fs.testflags & BLOCK_COMMIT_BASE) != 0) { tw(tr(TR_FUNC, TrBlock, "Bailing out because fs.testflags = 0x%X\n", fs.testflags)); } else { for (b = 0, n = 0; b < dev.numblocks; b++) { if (is_block_flag(b, BF_LOST)) { block_reclaim(b); n++; } if (is_block(b, BF_IS_FREE)) { blocks_free++; } } } // If the number of free blocks is less than fs.blocks_free_min we // call data_block_reclaim(). We will reclaim the block with most lost // space. This should only happend if we got a sudden power off/reset // while we reclaimed a block. if (blocks_free < fs.blocks_free_min) { lost_space = 0; free_space = 0; // We most never reclaim the block with most free space because this // is the only block we can relocate the objects to. for (b = 0; b < dev.numblocks; b++) { if (is_block_flag(b, BF_DATA)) { if ((dev.blocksize - bstat[b].used) > free_space) { free_space = dev.blocksize - bstat[b].used; b_free_space = b; } } } tw(tr(TR_FUNC, TrBlock, "most free space: %d in block: %d \n", free_space, b_free_space)); for (b = 0; b < dev.numblocks; b++) { if (is_block_flag(b, BF_DATA) && b != b_free_space) { if (bstat[b].lost > lost_space) { lost_space = bstat[b].lost; b_lost_space = b; } } } tw(tr(TR_FUNC, TrBlock, "most lost space: %d in block: %d \n", lost_space, b_lost_space)); data_block_reclaim(b_lost_space, MOST_LOST); } tw(tr(TR_END, TrBlock, "} %d\n", n)); ttw(ttr(TTrRec, "} %d" NL, n)); return n; } int block_reclaim(bref_t b) { age_t age; struct block_header_s *bhp; tw(tr(TR_BEGIN, TrBlock, "block_reclaim(%d) {\n", b)); // In ffs_initialize() we set fs.initerror = EFFS_INVALID while we call // blocks_fsck(). We test for that condition now, in order to avoid // doing sector erases that will delay the whole target boot process. if (fs.initerror == EFFS_INVALID) { tw(tr(TR_END, TrBlock, "} %d\n", fs.initerror)); return fs.initerror; } // Testing of fs.testflags is for the sake of testing block_commit() if ((fs.testflags & BLOCK_COMMIT_BASE) != 0 && fs.testflags != BLOCK_COMMIT_OLD_FREE) { tw(tr(TR_FUNC, TrBlock, "Bailing out because fs.testflags = 0x%X\n", fs.testflags)); } else { // We must read block's age before we erase it. bhp = (struct block_header_s *) offset2addr(dev.binfo[b].offset); age = bhp->age; ffsdrv.erase(b); block_preformat(b, age); } tw(tr(TR_END, TrBlock, "} %d\n", 0)); return 0; }