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1422 1423 1424 1425 1426 1427 1428 1429 1430 1431 1432 1433 1434 1435 1436 1437 1438 1439 1440 1441 1442 1443 1444 1445 1446 1447 1448 1449 1450 1451 1452 1453 1454 1455 1456 1457 1458 1459 1460 1461 1462 1463 1464 1465 1466 1467 1468 1469 1470 1471 1472 1473 1474 1475 1476 1477 1478 1479 1480 1481 1482 1483 1484 1485 1486 1487 1488 1489 1490 1491 1492 1493 1494 1495 1496 1497 1498 1499 1500 1501 1502 1503 1504 1505 1506 1507 1508 1509 1510 1511 1512 1513 1514 1515 1516 1517 1518 1519 1520 1521 1522 1523 1524 1525 1526 1527 1528 1529 1530 1531 1532 1533 1534 1535 1536 1537 1538 1539 1540 1541 1542 1543 1544 1545 1546 1547 1548 1549 1550 1551 1552 1553 1554 1555 1556 1557 1558 1559 1560 1561 1562 1563 1564 1565 1566 1567 1568 1569 1570 1571 1572 1573 1574 1575 1576 1577 1578 1579 1580 1581 1582 1583 1584 1585 1586 1587 1588 1589 1590 1591 1592 1593 | /* * Swap block device support for MTDs * Turns an MTD device into a swap device with block wear leveling * * Copyright © 2007,2011 Nokia Corporation. All rights reserved. * * Authors: Jarkko Lavinen <jarkko.lavinen@nokia.com> * * Based on Richard Purdie's earlier implementation in 2007. Background * support and lock-less operation written by Adrian Hunter. * * This program is free software; you can redistribute it and/or * modify it under the terms of the GNU General Public License * version 2 as published by the Free Software Foundation. * * 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., 51 Franklin St, Fifth Floor, Boston, MA * 02110-1301 USA */ #include <linux/kernel.h> #include <linux/module.h> #include <linux/mtd/mtd.h> #include <linux/mtd/blktrans.h> #include <linux/rbtree.h> #include <linux/sched.h> #include <linux/slab.h> #include <linux/vmalloc.h> #include <linux/genhd.h> #include <linux/swap.h> #include <linux/debugfs.h> #include <linux/seq_file.h> #include <linux/device.h> #include <linux/math64.h> #define MTDSWAP_PREFIX "mtdswap" /* * The number of free eraseblocks when GC should stop */ #define CLEAN_BLOCK_THRESHOLD 20 /* * Number of free eraseblocks below which GC can also collect low frag * blocks. */ #define LOW_FRAG_GC_TRESHOLD 5 /* * Wear level cost amortization. We want to do wear leveling on the background * without disturbing gc too much. This is made by defining max GC frequency. * Frequency value 6 means 1/6 of the GC passes will pick an erase block based * on the biggest wear difference rather than the biggest dirtiness. * * The lower freq2 should be chosen so that it makes sure the maximum erase * difference will decrease even if a malicious application is deliberately * trying to make erase differences large. */ #define MAX_ERASE_DIFF 4000 #define COLLECT_NONDIRTY_BASE MAX_ERASE_DIFF #define COLLECT_NONDIRTY_FREQ1 6 #define COLLECT_NONDIRTY_FREQ2 4 #define PAGE_UNDEF UINT_MAX #define BLOCK_UNDEF UINT_MAX #define BLOCK_ERROR (UINT_MAX - 1) #define BLOCK_MAX (UINT_MAX - 2) #define EBLOCK_BAD (1 << 0) #define EBLOCK_NOMAGIC (1 << 1) #define EBLOCK_BITFLIP (1 << 2) #define EBLOCK_FAILED (1 << 3) #define EBLOCK_READERR (1 << 4) #define EBLOCK_IDX_SHIFT 5 struct swap_eb { struct rb_node rb; struct rb_root *root; unsigned int flags; unsigned int active_count; unsigned int erase_count; unsigned int pad; /* speeds up pointer decremtnt */ }; #define MTDSWAP_ECNT_MIN(rbroot) (rb_entry(rb_first(rbroot), struct swap_eb, \ rb)->erase_count) #define MTDSWAP_ECNT_MAX(rbroot) (rb_entry(rb_last(rbroot), struct swap_eb, \ rb)->erase_count) struct mtdswap_tree { struct rb_root root; unsigned int count; }; enum { MTDSWAP_CLEAN, MTDSWAP_USED, MTDSWAP_LOWFRAG, MTDSWAP_HIFRAG, MTDSWAP_DIRTY, MTDSWAP_BITFLIP, MTDSWAP_FAILING, MTDSWAP_TREE_CNT, }; struct mtdswap_dev { struct mtd_blktrans_dev *mbd_dev; struct mtd_info *mtd; struct device *dev; unsigned int *page_data; unsigned int *revmap; unsigned int eblks; unsigned int spare_eblks; unsigned int pages_per_eblk; unsigned int max_erase_count; struct swap_eb *eb_data; struct mtdswap_tree trees[MTDSWAP_TREE_CNT]; unsigned long long sect_read_count; unsigned long long sect_write_count; unsigned long long mtd_write_count; unsigned long long mtd_read_count; unsigned long long discard_count; unsigned long long discard_page_count; unsigned int curr_write_pos; struct swap_eb *curr_write; char *page_buf; char *oob_buf; struct dentry *debugfs_root; }; struct mtdswap_oobdata { __le16 magic; __le32 count; } __attribute__((packed)); #define MTDSWAP_MAGIC_CLEAN 0x2095 #define MTDSWAP_MAGIC_DIRTY (MTDSWAP_MAGIC_CLEAN + 1) #define MTDSWAP_TYPE_CLEAN 0 #define MTDSWAP_TYPE_DIRTY 1 #define MTDSWAP_OOBSIZE sizeof(struct mtdswap_oobdata) #define MTDSWAP_ERASE_RETRIES 3 /* Before marking erase block bad */ #define MTDSWAP_IO_RETRIES 3 enum { MTDSWAP_SCANNED_CLEAN, MTDSWAP_SCANNED_DIRTY, MTDSWAP_SCANNED_BITFLIP, MTDSWAP_SCANNED_BAD, }; /* * In the worst case mtdswap_writesect() has allocated the last clean * page from the current block and is then pre-empted by the GC * thread. The thread can consume a full erase block when moving a * block. */ #define MIN_SPARE_EBLOCKS 2 #define MIN_ERASE_BLOCKS (MIN_SPARE_EBLOCKS + 1) #define TREE_ROOT(d, name) (&d->trees[MTDSWAP_ ## name].root) #define TREE_EMPTY(d, name) (TREE_ROOT(d, name)->rb_node == NULL) #define TREE_NONEMPTY(d, name) (!TREE_EMPTY(d, name)) #define TREE_COUNT(d, name) (d->trees[MTDSWAP_ ## name].count) #define MTDSWAP_MBD_TO_MTDSWAP(dev) ((struct mtdswap_dev *)dev->priv) static char partitions[128] = ""; module_param_string(partitions, partitions, sizeof(partitions), 0444); MODULE_PARM_DESC(partitions, "MTD partition numbers to use as swap " "partitions=\"1,3,5\""); static unsigned int spare_eblocks = 10; module_param(spare_eblocks, uint, 0444); MODULE_PARM_DESC(spare_eblocks, "Percentage of spare erase blocks for " "garbage collection (default 10%)"); static bool header; /* false */ module_param(header, bool, 0444); MODULE_PARM_DESC(header, "Include builtin swap header (default 0, without header)"); static int mtdswap_gc(struct mtdswap_dev *d, unsigned int background); static loff_t mtdswap_eb_offset(struct mtdswap_dev *d, struct swap_eb *eb) { return (loff_t)(eb - d->eb_data) * d->mtd->erasesize; } static void mtdswap_eb_detach(struct mtdswap_dev *d, struct swap_eb *eb) { unsigned int oldidx; struct mtdswap_tree *tp; if (eb->root) { tp = container_of(eb->root, struct mtdswap_tree, root); oldidx = tp - &d->trees[0]; d->trees[oldidx].count--; rb_erase(&eb->rb, eb->root); } } static void __mtdswap_rb_add(struct rb_root *root, struct swap_eb *eb) { struct rb_node **p, *parent = NULL; struct swap_eb *cur; p = &root->rb_node; while (*p) { parent = *p; cur = rb_entry(parent, struct swap_eb, rb); if (eb->erase_count > cur->erase_count) p = &(*p)->rb_right; else p = &(*p)->rb_left; } rb_link_node(&eb->rb, parent, p); rb_insert_color(&eb->rb, root); } static void mtdswap_rb_add(struct mtdswap_dev *d, struct swap_eb *eb, int idx) { struct rb_root *root; if (eb->root == &d->trees[idx].root) return; mtdswap_eb_detach(d, eb); root = &d->trees[idx].root; __mtdswap_rb_add(root, eb); eb->root = root; d->trees[idx].count++; } static struct rb_node *mtdswap_rb_index(struct rb_root *root, unsigned int idx) { struct rb_node *p; unsigned int i; p = rb_first(root); i = 0; while (i < idx && p) { p = rb_next(p); i++; } return p; } static int mtdswap_handle_badblock(struct mtdswap_dev *d, struct swap_eb *eb) { int ret; loff_t offset; d->spare_eblks--; eb->flags |= EBLOCK_BAD; mtdswap_eb_detach(d, eb); eb->root = NULL; /* badblocks not supported */ if (!d->mtd->block_markbad) return 1; offset = mtdswap_eb_offset(d, eb); dev_warn(d->dev, "Marking bad block at %08llx\n", offset); ret = d->mtd->block_markbad(d->mtd, offset); if (ret) { dev_warn(d->dev, "Mark block bad failed for block at %08llx " "error %d\n", offset, ret); return ret; } return 1; } static int mtdswap_handle_write_error(struct mtdswap_dev *d, struct swap_eb *eb) { unsigned int marked = eb->flags & EBLOCK_FAILED; struct swap_eb *curr_write = d->curr_write; eb->flags |= EBLOCK_FAILED; if (curr_write == eb) { d->curr_write = NULL; if (!marked && d->curr_write_pos != 0) { mtdswap_rb_add(d, eb, MTDSWAP_FAILING); return 0; } } return mtdswap_handle_badblock(d, eb); } static int mtdswap_read_oob(struct mtdswap_dev *d, loff_t from, struct mtd_oob_ops *ops) { int ret = d->mtd->read_oob(d->mtd, from, ops); if (ret == -EUCLEAN) return ret; if (ret) { dev_warn(d->dev, "Read OOB failed %d for block at %08llx\n", ret, from); return ret; } if (ops->oobretlen < ops->ooblen) { dev_warn(d->dev, "Read OOB return short read (%zd bytes not " "%zd) for block at %08llx\n", ops->oobretlen, ops->ooblen, from); return -EIO; } return 0; } static int mtdswap_read_markers(struct mtdswap_dev *d, struct swap_eb *eb) { struct mtdswap_oobdata *data, *data2; int ret; loff_t offset; struct mtd_oob_ops ops; offset = mtdswap_eb_offset(d, eb); /* Check first if the block is bad. */ if (d->mtd->block_isbad && d->mtd->block_isbad(d->mtd, offset)) return MTDSWAP_SCANNED_BAD; ops.ooblen = 2 * d->mtd->ecclayout->oobavail; ops.oobbuf = d->oob_buf; ops.ooboffs = 0; ops.datbuf = NULL; ops.mode = MTD_OOB_AUTO; ret = mtdswap_read_oob(d, offset, &ops); if (ret && ret != -EUCLEAN) return ret; data = (struct mtdswap_oobdata *)d->oob_buf; data2 = (struct mtdswap_oobdata *) (d->oob_buf + d->mtd->ecclayout->oobavail); if (le16_to_cpu(data->magic) == MTDSWAP_MAGIC_CLEAN) { eb->erase_count = le32_to_cpu(data->count); if (ret == -EUCLEAN) ret = MTDSWAP_SCANNED_BITFLIP; else { if (le16_to_cpu(data2->magic) == MTDSWAP_MAGIC_DIRTY) ret = MTDSWAP_SCANNED_DIRTY; else ret = MTDSWAP_SCANNED_CLEAN; } } else { eb->flags |= EBLOCK_NOMAGIC; ret = MTDSWAP_SCANNED_DIRTY; } return ret; } static int mtdswap_write_marker(struct mtdswap_dev *d, struct swap_eb *eb, u16 marker) { struct mtdswap_oobdata n; int ret; loff_t offset; struct mtd_oob_ops ops; ops.ooboffs = 0; ops.oobbuf = (uint8_t *)&n; ops.mode = MTD_OOB_AUTO; ops.datbuf = NULL; if (marker == MTDSWAP_TYPE_CLEAN) { n.magic = cpu_to_le16(MTDSWAP_MAGIC_CLEAN); n.count = cpu_to_le32(eb->erase_count); ops.ooblen = MTDSWAP_OOBSIZE; offset = mtdswap_eb_offset(d, eb); } else { n.magic = cpu_to_le16(MTDSWAP_MAGIC_DIRTY); ops.ooblen = sizeof(n.magic); offset = mtdswap_eb_offset(d, eb) + d->mtd->writesize; } ret = d->mtd->write_oob(d->mtd, offset , &ops); if (ret) { dev_warn(d->dev, "Write OOB failed for block at %08llx " "error %d\n", offset, ret); if (ret == -EIO || ret == -EBADMSG) mtdswap_handle_write_error(d, eb); return ret; } if (ops.oobretlen != ops.ooblen) { dev_warn(d->dev, "Short OOB write for block at %08llx: " "%zd not %zd\n", offset, ops.oobretlen, ops.ooblen); return ret; } return 0; } /* * Are there any erase blocks without MAGIC_CLEAN header, presumably * because power was cut off after erase but before header write? We * need to guestimate the erase count. */ static void mtdswap_check_counts(struct mtdswap_dev *d) { struct rb_root hist_root = RB_ROOT; struct rb_node *medrb; struct swap_eb *eb; unsigned int i, cnt, median; cnt = 0; for (i = 0; i < d->eblks; i++) { eb = d->eb_data + i; if (eb->flags & (EBLOCK_NOMAGIC | EBLOCK_BAD | EBLOCK_READERR)) continue; __mtdswap_rb_add(&hist_root, eb); cnt++; } if (cnt == 0) return; medrb = mtdswap_rb_index(&hist_root, cnt / 2); median = rb_entry(medrb, struct swap_eb, rb)->erase_count; d->max_erase_count = MTDSWAP_ECNT_MAX(&hist_root); for (i = 0; i < d->eblks; i++) { eb = d->eb_data + i; if (eb->flags & (EBLOCK_NOMAGIC | EBLOCK_READERR)) eb->erase_count = median; if (eb->flags & (EBLOCK_NOMAGIC | EBLOCK_BAD | EBLOCK_READERR)) continue; rb_erase(&eb->rb, &hist_root); } } static void mtdswap_scan_eblks(struct mtdswap_dev *d) { int status; unsigned int i, idx; struct swap_eb *eb; for (i = 0; i < d->eblks; i++) { eb = d->eb_data + i; status = mtdswap_read_markers(d, eb); if (status < 0) eb->flags |= EBLOCK_READERR; else if (status == MTDSWAP_SCANNED_BAD) { eb->flags |= EBLOCK_BAD; continue; } switch (status) { case MTDSWAP_SCANNED_CLEAN: idx = MTDSWAP_CLEAN; break; case MTDSWAP_SCANNED_DIRTY: case MTDSWAP_SCANNED_BITFLIP: idx = MTDSWAP_DIRTY; break; default: idx = MTDSWAP_FAILING; } eb->flags |= (idx << EBLOCK_IDX_SHIFT); } mtdswap_check_counts(d); for (i = 0; i < d->eblks; i++) { eb = d->eb_data + i; if (eb->flags & EBLOCK_BAD) continue; idx = eb->flags >> EBLOCK_IDX_SHIFT; mtdswap_rb_add(d, eb, idx); } } /* * Place eblk into a tree corresponding to its number of active blocks * it contains. */ static void mtdswap_store_eb(struct mtdswap_dev *d, struct swap_eb *eb) { unsigned int weight = eb->active_count; unsigned int maxweight = d->pages_per_eblk; if (eb == d->curr_write) return; if (eb->flags & EBLOCK_BITFLIP) mtdswap_rb_add(d, eb, MTDSWAP_BITFLIP); else if (eb->flags & (EBLOCK_READERR | EBLOCK_FAILED)) mtdswap_rb_add(d, eb, MTDSWAP_FAILING); if (weight == maxweight) mtdswap_rb_add(d, eb, MTDSWAP_USED); else if (weight == 0) mtdswap_rb_add(d, eb, MTDSWAP_DIRTY); else if (weight > (maxweight/2)) mtdswap_rb_add(d, eb, MTDSWAP_LOWFRAG); else mtdswap_rb_add(d, eb, MTDSWAP_HIFRAG); } static void mtdswap_erase_callback(struct erase_info *done) { wait_queue_head_t *wait_q = (wait_queue_head_t *)done->priv; wake_up(wait_q); } static int mtdswap_erase_block(struct mtdswap_dev *d, struct swap_eb *eb) { struct mtd_info *mtd = d->mtd; struct erase_info erase; wait_queue_head_t wq; unsigned int retries = 0; int ret; eb->erase_count++; if (eb->erase_count > d->max_erase_count) d->max_erase_count = eb->erase_count; retry: init_waitqueue_head(&wq); memset(&erase, 0, sizeof(struct erase_info)); erase.mtd = mtd; erase.callback = mtdswap_erase_callback; erase.addr = mtdswap_eb_offset(d, eb); erase.len = mtd->erasesize; erase.priv = (u_long)&wq; ret = mtd->erase(mtd, &erase); if (ret) { if (retries++ < MTDSWAP_ERASE_RETRIES) { dev_warn(d->dev, "erase of erase block %#llx on %s failed", erase.addr, mtd->name); yield(); goto retry; } dev_err(d->dev, "Cannot erase erase block %#llx on %s\n", erase.addr, mtd->name); mtdswap_handle_badblock(d, eb); return -EIO; } ret = wait_event_interruptible(wq, erase.state == MTD_ERASE_DONE || erase.state == MTD_ERASE_FAILED); if (ret) { dev_err(d->dev, "Interrupted erase block %#llx erassure on %s", erase.addr, mtd->name); return -EINTR; } if (erase.state == MTD_ERASE_FAILED) { if (retries++ < MTDSWAP_ERASE_RETRIES) { dev_warn(d->dev, "erase of erase block %#llx on %s failed", erase.addr, mtd->name); yield(); goto retry; } mtdswap_handle_badblock(d, eb); return -EIO; } return 0; } static int mtdswap_map_free_block(struct mtdswap_dev *d, unsigned int page, unsigned int *block) { int ret; struct swap_eb *old_eb = d->curr_write; struct rb_root *clean_root; struct swap_eb *eb; if (old_eb == NULL || d->curr_write_pos >= d->pages_per_eblk) { do { if (TREE_EMPTY(d, CLEAN)) return -ENOSPC; clean_root = TREE_ROOT(d, CLEAN); eb = rb_entry(rb_first(clean_root), struct swap_eb, rb); rb_erase(&eb->rb, clean_root); eb->root = NULL; TREE_COUNT(d, CLEAN)--; ret = mtdswap_write_marker(d, eb, MTDSWAP_TYPE_DIRTY); } while (ret == -EIO || ret == -EBADMSG); if (ret) return ret; d->curr_write_pos = 0; d->curr_write = eb; if (old_eb) mtdswap_store_eb(d, old_eb); } *block = (d->curr_write - d->eb_data) * d->pages_per_eblk + d->curr_write_pos; d->curr_write->active_count++; d->revmap[*block] = page; d->curr_write_pos++; return 0; } static unsigned int mtdswap_free_page_cnt(struct mtdswap_dev *d) { return TREE_COUNT(d, CLEAN) * d->pages_per_eblk + d->pages_per_eblk - d->curr_write_pos; } static unsigned int mtdswap_enough_free_pages(struct mtdswap_dev *d) { return mtdswap_free_page_cnt(d) > d->pages_per_eblk; } static int mtdswap_write_block(struct mtdswap_dev *d, char *buf, unsigned int page, unsigned int *bp, int gc_context) { struct mtd_info *mtd = d->mtd; struct swap_eb *eb; size_t retlen; loff_t writepos; int ret; retry: if (!gc_context) while (!mtdswap_enough_free_pages(d)) if (mtdswap_gc(d, 0) > 0) return -ENOSPC; ret = mtdswap_map_free_block(d, page, bp); eb = d->eb_data + (*bp / d->pages_per_eblk); if (ret == -EIO || ret == -EBADMSG) { d->curr_write = NULL; eb->active_count--; d->revmap[*bp] = PAGE_UNDEF; goto retry; } if (ret < 0) return ret; writepos = (loff_t)*bp << PAGE_SHIFT; ret = mtd->write(mtd, writepos, PAGE_SIZE, &retlen, buf); if (ret == -EIO || ret == -EBADMSG) { d->curr_write_pos--; eb->active_count--; d->revmap[*bp] = PAGE_UNDEF; mtdswap_handle_write_error(d, eb); goto retry; } if (ret < 0) { dev_err(d->dev, "Write to MTD device failed: %d (%zd written)", ret, retlen); goto err; } if (retlen != PAGE_SIZE) { dev_err(d->dev, "Short write to MTD device: %zd written", retlen); ret = -EIO; goto err; } return ret; err: d->curr_write_pos--; eb->active_count--; d->revmap[*bp] = PAGE_UNDEF; return ret; } static int mtdswap_move_block(struct mtdswap_dev *d, unsigned int oldblock, unsigned int *newblock) { struct mtd_info *mtd = d->mtd; struct swap_eb *eb, *oldeb; int ret; size_t retlen; unsigned int page, retries; loff_t readpos; page = d->revmap[oldblock]; readpos = (loff_t) oldblock << PAGE_SHIFT; retries = 0; retry: ret = mtd->read(mtd, readpos, PAGE_SIZE, &retlen, d->page_buf); if (ret < 0 && ret != -EUCLEAN) { oldeb = d->eb_data + oldblock / d->pages_per_eblk; oldeb->flags |= EBLOCK_READERR; dev_err(d->dev, "Read Error: %d (block %u)\n", ret, oldblock); retries++; if (retries < MTDSWAP_IO_RETRIES) goto retry; goto read_error; } if (retlen != PAGE_SIZE) { dev_err(d->dev, "Short read: %zd (block %u)\n", retlen, oldblock); ret = -EIO; goto read_error; } ret = mtdswap_write_block(d, d->page_buf, page, newblock, 1); if (ret < 0) { d->page_data[page] = BLOCK_ERROR; dev_err(d->dev, "Write error: %d\n", ret); return ret; } eb = d->eb_data + *newblock / d->pages_per_eblk; d->page_data[page] = *newblock; d->revmap[oldblock] = PAGE_UNDEF; eb = d->eb_data + oldblock / d->pages_per_eblk; eb->active_count--; return 0; read_error: d->page_data[page] = BLOCK_ERROR; d->revmap[oldblock] = PAGE_UNDEF; return ret; } static int mtdswap_gc_eblock(struct mtdswap_dev *d, struct swap_eb *eb) { unsigned int i, block, eblk_base, newblock; int ret, errcode; errcode = 0; eblk_base = (eb - d->eb_data) * d->pages_per_eblk; for (i = 0; i < d->pages_per_eblk; i++) { if (d->spare_eblks < MIN_SPARE_EBLOCKS) return -ENOSPC; block = eblk_base + i; if (d->revmap[block] == PAGE_UNDEF) continue; ret = mtdswap_move_block(d, block, &newblock); if (ret < 0 && !errcode) errcode = ret; } return errcode; } static int __mtdswap_choose_gc_tree(struct mtdswap_dev *d) { int idx, stopat; if (TREE_COUNT(d, CLEAN) < LOW_FRAG_GC_TRESHOLD) stopat = MTDSWAP_LOWFRAG; else stopat = MTDSWAP_HIFRAG; for (idx = MTDSWAP_BITFLIP; idx >= stopat; idx--) if (d->trees[idx].root.rb_node != NULL) return idx; return -1; } static int mtdswap_wlfreq(unsigned int maxdiff) { unsigned int h, x, y, dist, base; /* * Calculate linear ramp down from f1 to f2 when maxdiff goes from * MAX_ERASE_DIFF to MAX_ERASE_DIFF + COLLECT_NONDIRTY_BASE. Similar * to triangle with height f1 - f1 and width COLLECT_NONDIRTY_BASE. */ dist = maxdiff - MAX_ERASE_DIFF; if (dist > COLLECT_NONDIRTY_BASE) dist = COLLECT_NONDIRTY_BASE; /* * Modelling the slop as right angular triangle with base * COLLECT_NONDIRTY_BASE and height freq1 - freq2. The ratio y/x is * equal to the ratio h/base. */ h = COLLECT_NONDIRTY_FREQ1 - COLLECT_NONDIRTY_FREQ2; base = COLLECT_NONDIRTY_BASE; x = dist - base; y = (x * h + base / 2) / base; return COLLECT_NONDIRTY_FREQ2 + y; } static int mtdswap_choose_wl_tree(struct mtdswap_dev *d) { static unsigned int pick_cnt; unsigned int i, idx = -1, wear, max; struct rb_root *root; max = 0; for (i = 0; i <= MTDSWAP_DIRTY; i++) { root = &d->trees[i].root; if (root->rb_node == NULL) continue; wear = d->max_erase_count - MTDSWAP_ECNT_MIN(root); if (wear > max) { max = wear; idx = i; } } if (max > MAX_ERASE_DIFF && pick_cnt >= mtdswap_wlfreq(max) - 1) { pick_cnt = 0; return idx; } pick_cnt++; return -1; } static int mtdswap_choose_gc_tree(struct mtdswap_dev *d, unsigned int background) { int idx; if (TREE_NONEMPTY(d, FAILING) && (background || (TREE_EMPTY(d, CLEAN) && TREE_EMPTY(d, DIRTY)))) return MTDSWAP_FAILING; idx = mtdswap_choose_wl_tree(d); if (idx >= MTDSWAP_CLEAN) return idx; return __mtdswap_choose_gc_tree(d); } static struct swap_eb *mtdswap_pick_gc_eblk(struct mtdswap_dev *d, unsigned int background) { struct rb_root *rp = NULL; struct swap_eb *eb = NULL; int idx; if (background && TREE_COUNT(d, CLEAN) > CLEAN_BLOCK_THRESHOLD && TREE_EMPTY(d, DIRTY) && TREE_EMPTY(d, FAILING)) return NULL; idx = mtdswap_choose_gc_tree(d, background); if (idx < 0) return NULL; rp = &d->trees[idx].root; eb = rb_entry(rb_first(rp), struct swap_eb, rb); rb_erase(&eb->rb, rp); eb->root = NULL; d->trees[idx].count--; return eb; } static unsigned int mtdswap_test_patt(unsigned int i) { return i % 2 ? 0x55555555 : 0xAAAAAAAA; } static unsigned int mtdswap_eblk_passes(struct mtdswap_dev *d, struct swap_eb *eb) { struct mtd_info *mtd = d->mtd; unsigned int test, i, j, patt, mtd_pages; loff_t base, pos; unsigned int *p1 = (unsigned int *)d->page_buf; unsigned char *p2 = (unsigned char *)d->oob_buf; struct mtd_oob_ops ops; int ret; ops.mode = MTD_OOB_AUTO; ops.len = mtd->writesize; ops.ooblen = mtd->ecclayout->oobavail; ops.ooboffs = 0; ops.datbuf = d->page_buf; ops.oobbuf = d->oob_buf; base = mtdswap_eb_offset(d, eb); mtd_pages = d->pages_per_eblk * PAGE_SIZE / mtd->writesize; for (test = 0; test < 2; test++) { pos = base; for (i = 0; i < mtd_pages; i++) { patt = mtdswap_test_patt(test + i); memset(d->page_buf, patt, mtd->writesize); memset(d->oob_buf, patt, mtd->ecclayout->oobavail); ret = mtd->write_oob(mtd, pos, &ops); if (ret) goto error; pos += mtd->writesize; } pos = base; for (i = 0; i < mtd_pages; i++) { ret = mtd->read_oob(mtd, pos, &ops); if (ret) goto error; patt = mtdswap_test_patt(test + i); for (j = 0; j < mtd->writesize/sizeof(int); j++) if (p1[j] != patt) goto error; for (j = 0; j < mtd->ecclayout->oobavail; j++) if (p2[j] != (unsigned char)patt) goto error; pos += mtd->writesize; } ret = mtdswap_erase_block(d, eb); if (ret) goto error; } eb->flags &= ~EBLOCK_READERR; return 1; error: mtdswap_handle_badblock(d, eb); return 0; } static int mtdswap_gc(struct mtdswap_dev *d, unsigned int background) { struct swap_eb *eb; int ret; if (d->spare_eblks < MIN_SPARE_EBLOCKS) return 1; eb = mtdswap_pick_gc_eblk(d, background); if (!eb) return 1; ret = mtdswap_gc_eblock(d, eb); if (ret == -ENOSPC) return 1; if (eb->flags & EBLOCK_FAILED) { mtdswap_handle_badblock(d, eb); return 0; } eb->flags &= ~EBLOCK_BITFLIP; ret = mtdswap_erase_block(d, eb); if ((eb->flags & EBLOCK_READERR) && (ret || !mtdswap_eblk_passes(d, eb))) return 0; if (ret == 0) ret = mtdswap_write_marker(d, eb, MTDSWAP_TYPE_CLEAN); if (ret == 0) mtdswap_rb_add(d, eb, MTDSWAP_CLEAN); else if (ret != -EIO && ret != -EBADMSG) mtdswap_rb_add(d, eb, MTDSWAP_DIRTY); return 0; } static void mtdswap_background(struct mtd_blktrans_dev *dev) { struct mtdswap_dev *d = MTDSWAP_MBD_TO_MTDSWAP(dev); int ret; while (1) { ret = mtdswap_gc(d, 1); if (ret || mtd_blktrans_cease_background(dev)) return; } } static void mtdswap_cleanup(struct mtdswap_dev *d) { vfree(d->eb_data); vfree(d->revmap); vfree(d->page_data); kfree(d->oob_buf); kfree(d->page_buf); } static int mtdswap_flush(struct mtd_blktrans_dev *dev) { struct mtdswap_dev *d = MTDSWAP_MBD_TO_MTDSWAP(dev); if (d->mtd->sync) d->mtd->sync(d->mtd); return 0; } static unsigned int mtdswap_badblocks(struct mtd_info *mtd, uint64_t size) { loff_t offset; unsigned int badcnt; badcnt = 0; if (mtd->block_isbad) for (offset = 0; offset < size; offset += mtd->erasesize) if (mtd->block_isbad(mtd, offset)) badcnt++; return badcnt; } static int mtdswap_writesect(struct mtd_blktrans_dev *dev, unsigned long page, char *buf) { struct mtdswap_dev *d = MTDSWAP_MBD_TO_MTDSWAP(dev); unsigned int newblock, mapped; struct swap_eb *eb; int ret; d->sect_write_count++; if (d->spare_eblks < MIN_SPARE_EBLOCKS) return -ENOSPC; if (header) { /* Ignore writes to the header page */ if (unlikely(page == 0)) return 0; page--; } mapped = d->page_data[page]; if (mapped <= BLOCK_MAX) { eb = d->eb_data + (mapped / d->pages_per_eblk); eb->active_count--; mtdswap_store_eb(d, eb); d->page_data[page] = BLOCK_UNDEF; d->revmap[mapped] = PAGE_UNDEF; } ret = mtdswap_write_block(d, buf, page, &newblock, 0); d->mtd_write_count++; if (ret < 0) return ret; eb = d->eb_data + (newblock / d->pages_per_eblk); d->page_data[page] = newblock; return 0; } /* Provide a dummy swap header for the kernel */ static int mtdswap_auto_header(struct mtdswap_dev *d, char *buf) { union swap_header *hd = (union swap_header *)(buf); memset(buf, 0, PAGE_SIZE - 10); hd->info.version = 1; hd->info.last_page = d->mbd_dev->size - 1; hd->info.nr_badpages = 0; memcpy(buf + PAGE_SIZE - 10, "SWAPSPACE2", 10); return 0; } static int mtdswap_readsect(struct mtd_blktrans_dev *dev, unsigned long page, char *buf) { struct mtdswap_dev *d = MTDSWAP_MBD_TO_MTDSWAP(dev); struct mtd_info *mtd = d->mtd; unsigned int realblock, retries; loff_t readpos; struct swap_eb *eb; size_t retlen; int ret; d->sect_read_count++; if (header) { if (unlikely(page == 0)) return mtdswap_auto_header(d, buf); page--; } realblock = d->page_data[page]; if (realblock > BLOCK_MAX) { memset(buf, 0x0, PAGE_SIZE); if (realblock == BLOCK_UNDEF) return 0; else return -EIO; } eb = d->eb_data + (realblock / d->pages_per_eblk); BUG_ON(d->revmap[realblock] == PAGE_UNDEF); readpos = (loff_t)realblock << PAGE_SHIFT; retries = 0; retry: ret = mtd->read(mtd, readpos, PAGE_SIZE, &retlen, buf); d->mtd_read_count++; if (ret == -EUCLEAN) { eb->flags |= EBLOCK_BITFLIP; mtdswap_rb_add(d, eb, MTDSWAP_BITFLIP); ret = 0; } if (ret < 0) { dev_err(d->dev, "Read error %d\n", ret); eb->flags |= EBLOCK_READERR; mtdswap_rb_add(d, eb, MTDSWAP_FAILING); retries++; if (retries < MTDSWAP_IO_RETRIES) goto retry; return ret; } if (retlen != PAGE_SIZE) { dev_err(d->dev, "Short read %zd\n", retlen); return -EIO; } return 0; } static int mtdswap_discard(struct mtd_blktrans_dev *dev, unsigned long first, unsigned nr_pages) { struct mtdswap_dev *d = MTDSWAP_MBD_TO_MTDSWAP(dev); unsigned long page; struct swap_eb *eb; unsigned int mapped; d->discard_count++; for (page = first; page < first + nr_pages; page++) { mapped = d->page_data[page]; if (mapped <= BLOCK_MAX) { eb = d->eb_data + (mapped / d->pages_per_eblk); eb->active_count--; mtdswap_store_eb(d, eb); d->page_data[page] = BLOCK_UNDEF; d->revmap[mapped] = PAGE_UNDEF; d->discard_page_count++; } else if (mapped == BLOCK_ERROR) { d->page_data[page] = BLOCK_UNDEF; d->discard_page_count++; } } return 0; } static int mtdswap_show(struct seq_file *s, void *data) { struct mtdswap_dev *d = (struct mtdswap_dev *) s->private; unsigned long sum; unsigned int count[MTDSWAP_TREE_CNT]; unsigned int min[MTDSWAP_TREE_CNT]; unsigned int max[MTDSWAP_TREE_CNT]; unsigned int i, cw = 0, cwp = 0, cwecount = 0, bb_cnt, mapped, pages; uint64_t use_size; char *name[] = {"clean", "used", "low", "high", "dirty", "bitflip", "failing"}; mutex_lock(&d->mbd_dev->lock); for (i = 0; i < MTDSWAP_TREE_CNT; i++) { struct rb_root *root = &d->trees[i].root; if (root->rb_node) { count[i] = d->trees[i].count; min[i] = rb_entry(rb_first(root), struct swap_eb, rb)->erase_count; max[i] = rb_entry(rb_last(root), struct swap_eb, rb)->erase_count; } else count[i] = 0; } if (d->curr_write) { cw = 1; cwp = d->curr_write_pos; cwecount = d->curr_write->erase_count; } sum = 0; for (i = 0; i < d->eblks; i++) sum += d->eb_data[i].erase_count; use_size = (uint64_t)d->eblks * d->mtd->erasesize; bb_cnt = mtdswap_badblocks(d->mtd, use_size); mapped = 0; pages = d->mbd_dev->size; for (i = 0; i < pages; i++) if (d->page_data[i] != BLOCK_UNDEF) mapped++; mutex_unlock(&d->mbd_dev->lock); for (i = 0; i < MTDSWAP_TREE_CNT; i++) { if (!count[i]) continue; if (min[i] != max[i]) seq_printf(s, "%s:\t%5d erase blocks, erased min %d, " "max %d times\n", name[i], count[i], min[i], max[i]); else seq_printf(s, "%s:\t%5d erase blocks, all erased %d " "times\n", name[i], count[i], min[i]); } if (bb_cnt) seq_printf(s, "bad:\t%5u erase blocks\n", bb_cnt); if (cw) seq_printf(s, "current erase block: %u pages used, %u free, " "erased %u times\n", cwp, d->pages_per_eblk - cwp, cwecount); seq_printf(s, "total erasures: %lu\n", sum); seq_printf(s, "\n"); seq_printf(s, "mtdswap_readsect count: %llu\n", d->sect_read_count); seq_printf(s, "mtdswap_writesect count: %llu\n", d->sect_write_count); seq_printf(s, "mtdswap_discard count: %llu\n", d->discard_count); seq_printf(s, "mtd read count: %llu\n", d->mtd_read_count); seq_printf(s, "mtd write count: %llu\n", d->mtd_write_count); seq_printf(s, "discarded pages count: %llu\n", d->discard_page_count); seq_printf(s, "\n"); seq_printf(s, "total pages: %u\n", pages); seq_printf(s, "pages mapped: %u\n", mapped); return 0; } static int mtdswap_open(struct inode *inode, struct file *file) { return single_open(file, mtdswap_show, inode->i_private); } static const struct file_operations mtdswap_fops = { .open = mtdswap_open, .read = seq_read, .llseek = seq_lseek, .release = single_release, }; static int mtdswap_add_debugfs(struct mtdswap_dev *d) { struct gendisk *gd = d->mbd_dev->disk; struct device *dev = disk_to_dev(gd); struct dentry *root; struct dentry *dent; root = debugfs_create_dir(gd->disk_name, NULL); if (IS_ERR(root)) return 0; if (!root) { dev_err(dev, "failed to initialize debugfs\n"); return -1; } d->debugfs_root = root; dent = debugfs_create_file("stats", S_IRUSR, root, d, &mtdswap_fops); if (!dent) { dev_err(d->dev, "debugfs_create_file failed\n"); debugfs_remove_recursive(root); d->debugfs_root = NULL; return -1; } return 0; } static int mtdswap_init(struct mtdswap_dev *d, unsigned int eblocks, unsigned int spare_cnt) { struct mtd_info *mtd = d->mbd_dev->mtd; unsigned int i, eblk_bytes, pages, blocks; int ret = -ENOMEM; d->mtd = mtd; d->eblks = eblocks; d->spare_eblks = spare_cnt; d->pages_per_eblk = mtd->erasesize >> PAGE_SHIFT; pages = d->mbd_dev->size; blocks = eblocks * d->pages_per_eblk; for (i = 0; i < MTDSWAP_TREE_CNT; i++) d->trees[i].root = RB_ROOT; d->page_data = vmalloc(sizeof(int)*pages); if (!d->page_data) goto page_data_fail; d->revmap = vmalloc(sizeof(int)*blocks); if (!d->revmap) goto revmap_fail; eblk_bytes = sizeof(struct swap_eb)*d->eblks; d->eb_data = vmalloc(eblk_bytes); if (!d->eb_data) goto eb_data_fail; memset(d->eb_data, 0, eblk_bytes); for (i = 0; i < pages; i++) d->page_data[i] = BLOCK_UNDEF; for (i = 0; i < blocks; i++) d->revmap[i] = PAGE_UNDEF; d->page_buf = kmalloc(PAGE_SIZE, GFP_KERNEL); if (!d->page_buf) goto page_buf_fail; d->oob_buf = kmalloc(2 * mtd->ecclayout->oobavail, GFP_KERNEL); if (!d->oob_buf) goto oob_buf_fail; mtdswap_scan_eblks(d); return 0; oob_buf_fail: kfree(d->page_buf); page_buf_fail: vfree(d->eb_data); eb_data_fail: vfree(d->revmap); revmap_fail: vfree(d->page_data); page_data_fail: printk(KERN_ERR "%s: init failed (%d)\n", MTDSWAP_PREFIX, ret); return ret; } static void mtdswap_add_mtd(struct mtd_blktrans_ops *tr, struct mtd_info *mtd) { struct mtdswap_dev *d; struct mtd_blktrans_dev *mbd_dev; char *parts; char *this_opt; unsigned long part; unsigned int eblocks, eavailable, bad_blocks, spare_cnt; uint64_t swap_size, use_size, size_limit; struct nand_ecclayout *oinfo; int ret; parts = &partitions[0]; if (!*parts) return; while ((this_opt = strsep(&parts, ",")) != NULL) { if (strict_strtoul(this_opt, 0, &part) < 0) return; if (mtd->index == part) break; } if (mtd->index != part) return; if (mtd->erasesize < PAGE_SIZE || mtd->erasesize % PAGE_SIZE) { printk(KERN_ERR "%s: Erase size %u not multiple of PAGE_SIZE " "%lu\n", MTDSWAP_PREFIX, mtd->erasesize, PAGE_SIZE); return; } if (PAGE_SIZE % mtd->writesize || mtd->writesize > PAGE_SIZE) { printk(KERN_ERR "%s: PAGE_SIZE %lu not multiple of write size" " %u\n", MTDSWAP_PREFIX, PAGE_SIZE, mtd->writesize); return; } oinfo = mtd->ecclayout; if (!oinfo) { printk(KERN_ERR "%s: mtd%d does not have OOB\n", MTDSWAP_PREFIX, mtd->index); return; } if (!mtd->oobsize || oinfo->oobavail < MTDSWAP_OOBSIZE) { printk(KERN_ERR "%s: Not enough free bytes in OOB, " "%d available, %zu needed.\n", MTDSWAP_PREFIX, oinfo->oobavail, MTDSWAP_OOBSIZE); return; } if (spare_eblocks > 100) spare_eblocks = 100; use_size = mtd->size; size_limit = (uint64_t) BLOCK_MAX * PAGE_SIZE; if (mtd->size > size_limit) { printk(KERN_WARNING "%s: Device too large. Limiting size to " "%llu bytes\n", MTDSWAP_PREFIX, size_limit); use_size = size_limit; } eblocks = mtd_div_by_eb(use_size, mtd); use_size = eblocks * mtd->erasesize; bad_blocks = mtdswap_badblocks(mtd, use_size); eavailable = eblocks - bad_blocks; if (eavailable < MIN_ERASE_BLOCKS) { printk(KERN_ERR "%s: Not enough erase blocks. %u available, " "%d needed\n", MTDSWAP_PREFIX, eavailable, MIN_ERASE_BLOCKS); return; } spare_cnt = div_u64((uint64_t)eavailable * spare_eblocks, 100); if (spare_cnt < MIN_SPARE_EBLOCKS) spare_cnt = MIN_SPARE_EBLOCKS; if (spare_cnt > eavailable - 1) spare_cnt = eavailable - 1; swap_size = (uint64_t)(eavailable - spare_cnt) * mtd->erasesize + (header ? PAGE_SIZE : 0); printk(KERN_INFO "%s: Enabling MTD swap on device %lu, size %llu KB, " "%u spare, %u bad blocks\n", MTDSWAP_PREFIX, part, swap_size / 1024, spare_cnt, bad_blocks); d = kzalloc(sizeof(struct mtdswap_dev), GFP_KERNEL); if (!d) return; mbd_dev = kzalloc(sizeof(struct mtd_blktrans_dev), GFP_KERNEL); if (!mbd_dev) { kfree(d); return; } d->mbd_dev = mbd_dev; mbd_dev->priv = d; mbd_dev->mtd = mtd; mbd_dev->devnum = mtd->index; mbd_dev->size = swap_size >> PAGE_SHIFT; mbd_dev->tr = tr; if (!(mtd->flags & MTD_WRITEABLE)) mbd_dev->readonly = 1; if (mtdswap_init(d, eblocks, spare_cnt) < 0) goto init_failed; if (add_mtd_blktrans_dev(mbd_dev) < 0) goto cleanup; d->dev = disk_to_dev(mbd_dev->disk); ret = mtdswap_add_debugfs(d); if (ret < 0) goto debugfs_failed; return; debugfs_failed: del_mtd_blktrans_dev(mbd_dev); cleanup: mtdswap_cleanup(d); init_failed: kfree(mbd_dev); kfree(d); } static void mtdswap_remove_dev(struct mtd_blktrans_dev *dev) { struct mtdswap_dev *d = MTDSWAP_MBD_TO_MTDSWAP(dev); debugfs_remove_recursive(d->debugfs_root); del_mtd_blktrans_dev(dev); mtdswap_cleanup(d); kfree(d); } static struct mtd_blktrans_ops mtdswap_ops = { .name = "mtdswap", .major = 0, .part_bits = 0, .blksize = PAGE_SIZE, .flush = mtdswap_flush, .readsect = mtdswap_readsect, .writesect = mtdswap_writesect, .discard = mtdswap_discard, .background = mtdswap_background, .add_mtd = mtdswap_add_mtd, .remove_dev = mtdswap_remove_dev, .owner = THIS_MODULE, }; static int __init mtdswap_modinit(void) { return register_mtd_blktrans(&mtdswap_ops); } static void __exit mtdswap_modexit(void) { deregister_mtd_blktrans(&mtdswap_ops); } module_init(mtdswap_modinit); module_exit(mtdswap_modexit); MODULE_LICENSE("GPL"); MODULE_AUTHOR("Jarkko Lavinen <jarkko.lavinen@nokia.com>"); MODULE_DESCRIPTION("Block device access to an MTD suitable for using as " "swap space"); |