Author | Tokens | Token Proportion | Commits | Commit Proportion |
---|---|---|---|---|
Konstantin Komarov | 7134 | 95.54% | 9 | 47.37% |
Thomas Kühnel | 219 | 2.93% | 2 | 10.53% |
Kari Argillander | 110 | 1.47% | 5 | 26.32% |
Kenneth Lee | 2 | 0.03% | 1 | 5.26% |
Abdun Nihaal | 1 | 0.01% | 1 | 5.26% |
Tetsuo Handa | 1 | 0.01% | 1 | 5.26% |
Total | 7467 | 19 |
// SPDX-License-Identifier: GPL-2.0 /* * * Copyright (C) 2019-2021 Paragon Software GmbH, All rights reserved. * * This code builds two trees of free clusters extents. * Trees are sorted by start of extent and by length of extent. * NTFS_MAX_WND_EXTENTS defines the maximum number of elements in trees. * In extreme case code reads on-disk bitmap to find free clusters. * */ #include <linux/buffer_head.h> #include <linux/fs.h> #include <linux/kernel.h> #include "ntfs.h" #include "ntfs_fs.h" /* * Maximum number of extents in tree. */ #define NTFS_MAX_WND_EXTENTS (32u * 1024u) struct rb_node_key { struct rb_node node; size_t key; }; struct e_node { struct rb_node_key start; /* Tree sorted by start. */ struct rb_node_key count; /* Tree sorted by len. */ }; static int wnd_rescan(struct wnd_bitmap *wnd); static struct buffer_head *wnd_map(struct wnd_bitmap *wnd, size_t iw); static bool wnd_is_free_hlp(struct wnd_bitmap *wnd, size_t bit, size_t bits); static struct kmem_cache *ntfs_enode_cachep; int __init ntfs3_init_bitmap(void) { ntfs_enode_cachep = kmem_cache_create("ntfs3_enode_cache", sizeof(struct e_node), 0, SLAB_RECLAIM_ACCOUNT, NULL); return ntfs_enode_cachep ? 0 : -ENOMEM; } void ntfs3_exit_bitmap(void) { kmem_cache_destroy(ntfs_enode_cachep); } /* * wnd_scan * * b_pos + b_len - biggest fragment. * Scan range [wpos wbits) window @buf. * * Return: -1 if not found. */ static size_t wnd_scan(const void *buf, size_t wbit, u32 wpos, u32 wend, size_t to_alloc, size_t *prev_tail, size_t *b_pos, size_t *b_len) { while (wpos < wend) { size_t free_len; u32 free_bits, end; u32 used = find_next_zero_bit_le(buf, wend, wpos); if (used >= wend) { if (*b_len < *prev_tail) { *b_pos = wbit - *prev_tail; *b_len = *prev_tail; } *prev_tail = 0; return -1; } if (used > wpos) { wpos = used; if (*b_len < *prev_tail) { *b_pos = wbit - *prev_tail; *b_len = *prev_tail; } *prev_tail = 0; } /* * Now we have a fragment [wpos, wend) staring with 0. */ end = wpos + to_alloc - *prev_tail; free_bits = find_next_bit_le(buf, min(end, wend), wpos); free_len = *prev_tail + free_bits - wpos; if (*b_len < free_len) { *b_pos = wbit + wpos - *prev_tail; *b_len = free_len; } if (free_len >= to_alloc) return wbit + wpos - *prev_tail; if (free_bits >= wend) { *prev_tail += free_bits - wpos; return -1; } wpos = free_bits + 1; *prev_tail = 0; } return -1; } /* * wnd_close - Frees all resources. */ void wnd_close(struct wnd_bitmap *wnd) { struct rb_node *node, *next; kvfree(wnd->free_bits); wnd->free_bits = NULL; run_close(&wnd->run); node = rb_first(&wnd->start_tree); while (node) { next = rb_next(node); rb_erase(node, &wnd->start_tree); kmem_cache_free(ntfs_enode_cachep, rb_entry(node, struct e_node, start.node)); node = next; } } static struct rb_node *rb_lookup(struct rb_root *root, size_t v) { struct rb_node **p = &root->rb_node; struct rb_node *r = NULL; while (*p) { struct rb_node_key *k; k = rb_entry(*p, struct rb_node_key, node); if (v < k->key) { p = &(*p)->rb_left; } else if (v > k->key) { r = &k->node; p = &(*p)->rb_right; } else { return &k->node; } } return r; } /* * rb_insert_count - Helper function to insert special kind of 'count' tree. */ static inline bool rb_insert_count(struct rb_root *root, struct e_node *e) { struct rb_node **p = &root->rb_node; struct rb_node *parent = NULL; size_t e_ckey = e->count.key; size_t e_skey = e->start.key; while (*p) { struct e_node *k = rb_entry(parent = *p, struct e_node, count.node); if (e_ckey > k->count.key) { p = &(*p)->rb_left; } else if (e_ckey < k->count.key) { p = &(*p)->rb_right; } else if (e_skey < k->start.key) { p = &(*p)->rb_left; } else if (e_skey > k->start.key) { p = &(*p)->rb_right; } else { WARN_ON(1); return false; } } rb_link_node(&e->count.node, parent, p); rb_insert_color(&e->count.node, root); return true; } /* * rb_insert_start - Helper function to insert special kind of 'count' tree. */ static inline bool rb_insert_start(struct rb_root *root, struct e_node *e) { struct rb_node **p = &root->rb_node; struct rb_node *parent = NULL; size_t e_skey = e->start.key; while (*p) { struct e_node *k; parent = *p; k = rb_entry(parent, struct e_node, start.node); if (e_skey < k->start.key) { p = &(*p)->rb_left; } else if (e_skey > k->start.key) { p = &(*p)->rb_right; } else { WARN_ON(1); return false; } } rb_link_node(&e->start.node, parent, p); rb_insert_color(&e->start.node, root); return true; } /* * wnd_add_free_ext - Adds a new extent of free space. * @build: 1 when building tree. */ static void wnd_add_free_ext(struct wnd_bitmap *wnd, size_t bit, size_t len, bool build) { struct e_node *e, *e0 = NULL; size_t ib, end_in = bit + len; struct rb_node *n; if (build) { /* Use extent_min to filter too short extents. */ if (wnd->count >= NTFS_MAX_WND_EXTENTS && len <= wnd->extent_min) { wnd->uptodated = -1; return; } } else { /* Try to find extent before 'bit'. */ n = rb_lookup(&wnd->start_tree, bit); if (!n) { n = rb_first(&wnd->start_tree); } else { e = rb_entry(n, struct e_node, start.node); n = rb_next(n); if (e->start.key + e->count.key == bit) { /* Remove left. */ bit = e->start.key; len += e->count.key; rb_erase(&e->start.node, &wnd->start_tree); rb_erase(&e->count.node, &wnd->count_tree); wnd->count -= 1; e0 = e; } } while (n) { size_t next_end; e = rb_entry(n, struct e_node, start.node); next_end = e->start.key + e->count.key; if (e->start.key > end_in) break; /* Remove right. */ n = rb_next(n); len += next_end - end_in; end_in = next_end; rb_erase(&e->start.node, &wnd->start_tree); rb_erase(&e->count.node, &wnd->count_tree); wnd->count -= 1; if (!e0) e0 = e; else kmem_cache_free(ntfs_enode_cachep, e); } if (wnd->uptodated != 1) { /* Check bits before 'bit'. */ ib = wnd->zone_bit == wnd->zone_end || bit < wnd->zone_end ? 0 : wnd->zone_end; while (bit > ib && wnd_is_free_hlp(wnd, bit - 1, 1)) { bit -= 1; len += 1; } /* Check bits after 'end_in'. */ ib = wnd->zone_bit == wnd->zone_end || end_in > wnd->zone_bit ? wnd->nbits : wnd->zone_bit; while (end_in < ib && wnd_is_free_hlp(wnd, end_in, 1)) { end_in += 1; len += 1; } } } /* Insert new fragment. */ if (wnd->count >= NTFS_MAX_WND_EXTENTS) { if (e0) kmem_cache_free(ntfs_enode_cachep, e0); wnd->uptodated = -1; /* Compare with smallest fragment. */ n = rb_last(&wnd->count_tree); e = rb_entry(n, struct e_node, count.node); if (len <= e->count.key) goto out; /* Do not insert small fragments. */ if (build) { struct e_node *e2; n = rb_prev(n); e2 = rb_entry(n, struct e_node, count.node); /* Smallest fragment will be 'e2->count.key'. */ wnd->extent_min = e2->count.key; } /* Replace smallest fragment by new one. */ rb_erase(&e->start.node, &wnd->start_tree); rb_erase(&e->count.node, &wnd->count_tree); wnd->count -= 1; } else { e = e0 ? e0 : kmem_cache_alloc(ntfs_enode_cachep, GFP_ATOMIC); if (!e) { wnd->uptodated = -1; goto out; } if (build && len <= wnd->extent_min) wnd->extent_min = len; } e->start.key = bit; e->count.key = len; if (len > wnd->extent_max) wnd->extent_max = len; rb_insert_start(&wnd->start_tree, e); rb_insert_count(&wnd->count_tree, e); wnd->count += 1; out:; } /* * wnd_remove_free_ext - Remove a run from the cached free space. */ static void wnd_remove_free_ext(struct wnd_bitmap *wnd, size_t bit, size_t len) { struct rb_node *n, *n3; struct e_node *e, *e3; size_t end_in = bit + len; size_t end3, end, new_key, new_len, max_new_len; /* Try to find extent before 'bit'. */ n = rb_lookup(&wnd->start_tree, bit); if (!n) return; e = rb_entry(n, struct e_node, start.node); end = e->start.key + e->count.key; new_key = new_len = 0; len = e->count.key; /* Range [bit,end_in) must be inside 'e' or outside 'e' and 'n'. */ if (e->start.key > bit) ; else if (end_in <= end) { /* Range [bit,end_in) inside 'e'. */ new_key = end_in; new_len = end - end_in; len = bit - e->start.key; } else if (bit > end) { bool bmax = false; n3 = rb_next(n); while (n3) { e3 = rb_entry(n3, struct e_node, start.node); if (e3->start.key >= end_in) break; if (e3->count.key == wnd->extent_max) bmax = true; end3 = e3->start.key + e3->count.key; if (end3 > end_in) { e3->start.key = end_in; rb_erase(&e3->count.node, &wnd->count_tree); e3->count.key = end3 - end_in; rb_insert_count(&wnd->count_tree, e3); break; } n3 = rb_next(n3); rb_erase(&e3->start.node, &wnd->start_tree); rb_erase(&e3->count.node, &wnd->count_tree); wnd->count -= 1; kmem_cache_free(ntfs_enode_cachep, e3); } if (!bmax) return; n3 = rb_first(&wnd->count_tree); wnd->extent_max = n3 ? rb_entry(n3, struct e_node, count.node)->count.key : 0; return; } if (e->count.key != wnd->extent_max) { ; } else if (rb_prev(&e->count.node)) { ; } else { n3 = rb_next(&e->count.node); max_new_len = max(len, new_len); if (!n3) { wnd->extent_max = max_new_len; } else { e3 = rb_entry(n3, struct e_node, count.node); wnd->extent_max = max(e3->count.key, max_new_len); } } if (!len) { if (new_len) { e->start.key = new_key; rb_erase(&e->count.node, &wnd->count_tree); e->count.key = new_len; rb_insert_count(&wnd->count_tree, e); } else { rb_erase(&e->start.node, &wnd->start_tree); rb_erase(&e->count.node, &wnd->count_tree); wnd->count -= 1; kmem_cache_free(ntfs_enode_cachep, e); } goto out; } rb_erase(&e->count.node, &wnd->count_tree); e->count.key = len; rb_insert_count(&wnd->count_tree, e); if (!new_len) goto out; if (wnd->count >= NTFS_MAX_WND_EXTENTS) { wnd->uptodated = -1; /* Get minimal extent. */ e = rb_entry(rb_last(&wnd->count_tree), struct e_node, count.node); if (e->count.key > new_len) goto out; /* Replace minimum. */ rb_erase(&e->start.node, &wnd->start_tree); rb_erase(&e->count.node, &wnd->count_tree); wnd->count -= 1; } else { e = kmem_cache_alloc(ntfs_enode_cachep, GFP_ATOMIC); if (!e) wnd->uptodated = -1; } if (e) { e->start.key = new_key; e->count.key = new_len; rb_insert_start(&wnd->start_tree, e); rb_insert_count(&wnd->count_tree, e); wnd->count += 1; } out: if (!wnd->count && 1 != wnd->uptodated) wnd_rescan(wnd); } /* * wnd_rescan - Scan all bitmap. Used while initialization. */ static int wnd_rescan(struct wnd_bitmap *wnd) { int err = 0; size_t prev_tail = 0; struct super_block *sb = wnd->sb; struct ntfs_sb_info *sbi = sb->s_fs_info; u64 lbo, len = 0; u32 blocksize = sb->s_blocksize; u8 cluster_bits = sbi->cluster_bits; u32 wbits = 8 * sb->s_blocksize; u32 used, frb; size_t wpos, wbit, iw, vbo; struct buffer_head *bh = NULL; CLST lcn, clen; wnd->uptodated = 0; wnd->extent_max = 0; wnd->extent_min = MINUS_ONE_T; wnd->total_zeroes = 0; vbo = 0; for (iw = 0; iw < wnd->nwnd; iw++) { if (iw + 1 == wnd->nwnd) wbits = wnd->bits_last; if (wnd->inited) { if (!wnd->free_bits[iw]) { /* All ones. */ if (prev_tail) { wnd_add_free_ext(wnd, vbo * 8 - prev_tail, prev_tail, true); prev_tail = 0; } goto next_wnd; } if (wbits == wnd->free_bits[iw]) { /* All zeroes. */ prev_tail += wbits; wnd->total_zeroes += wbits; goto next_wnd; } } if (!len) { u32 off = vbo & sbi->cluster_mask; if (!run_lookup_entry(&wnd->run, vbo >> cluster_bits, &lcn, &clen, NULL)) { err = -ENOENT; goto out; } lbo = ((u64)lcn << cluster_bits) + off; len = ((u64)clen << cluster_bits) - off; } bh = ntfs_bread(sb, lbo >> sb->s_blocksize_bits); if (!bh) { err = -EIO; goto out; } used = ntfs_bitmap_weight_le(bh->b_data, wbits); if (used < wbits) { frb = wbits - used; wnd->free_bits[iw] = frb; wnd->total_zeroes += frb; } wpos = 0; wbit = vbo * 8; if (wbit + wbits > wnd->nbits) wbits = wnd->nbits - wbit; do { used = find_next_zero_bit_le(bh->b_data, wbits, wpos); if (used > wpos && prev_tail) { wnd_add_free_ext(wnd, wbit + wpos - prev_tail, prev_tail, true); prev_tail = 0; } wpos = used; if (wpos >= wbits) { /* No free blocks. */ prev_tail = 0; break; } frb = find_next_bit_le(bh->b_data, wbits, wpos); if (frb >= wbits) { /* Keep last free block. */ prev_tail += frb - wpos; break; } wnd_add_free_ext(wnd, wbit + wpos - prev_tail, frb + prev_tail - wpos, true); /* Skip free block and first '1'. */ wpos = frb + 1; /* Reset previous tail. */ prev_tail = 0; } while (wpos < wbits); next_wnd: if (bh) put_bh(bh); bh = NULL; vbo += blocksize; if (len) { len -= blocksize; lbo += blocksize; } } /* Add last block. */ if (prev_tail) wnd_add_free_ext(wnd, wnd->nbits - prev_tail, prev_tail, true); /* * Before init cycle wnd->uptodated was 0. * If any errors or limits occurs while initialization then * wnd->uptodated will be -1. * If 'uptodated' is still 0 then Tree is really updated. */ if (!wnd->uptodated) wnd->uptodated = 1; if (wnd->zone_bit != wnd->zone_end) { size_t zlen = wnd->zone_end - wnd->zone_bit; wnd->zone_end = wnd->zone_bit; wnd_zone_set(wnd, wnd->zone_bit, zlen); } out: return err; } int wnd_init(struct wnd_bitmap *wnd, struct super_block *sb, size_t nbits) { int err; u32 blocksize = sb->s_blocksize; u32 wbits = blocksize * 8; init_rwsem(&wnd->rw_lock); wnd->sb = sb; wnd->nbits = nbits; wnd->total_zeroes = nbits; wnd->extent_max = MINUS_ONE_T; wnd->zone_bit = wnd->zone_end = 0; wnd->nwnd = bytes_to_block(sb, bitmap_size(nbits)); wnd->bits_last = nbits & (wbits - 1); if (!wnd->bits_last) wnd->bits_last = wbits; wnd->free_bits = kvmalloc_array(wnd->nwnd, sizeof(u16), GFP_KERNEL | __GFP_ZERO); if (!wnd->free_bits) return -ENOMEM; err = wnd_rescan(wnd); if (err) return err; wnd->inited = true; return 0; } /* * wnd_map - Call sb_bread for requested window. */ static struct buffer_head *wnd_map(struct wnd_bitmap *wnd, size_t iw) { size_t vbo; CLST lcn, clen; struct super_block *sb = wnd->sb; struct ntfs_sb_info *sbi; struct buffer_head *bh; u64 lbo; sbi = sb->s_fs_info; vbo = (u64)iw << sb->s_blocksize_bits; if (!run_lookup_entry(&wnd->run, vbo >> sbi->cluster_bits, &lcn, &clen, NULL)) { return ERR_PTR(-ENOENT); } lbo = ((u64)lcn << sbi->cluster_bits) + (vbo & sbi->cluster_mask); bh = ntfs_bread(wnd->sb, lbo >> sb->s_blocksize_bits); if (!bh) return ERR_PTR(-EIO); return bh; } /* * wnd_set_free - Mark the bits range from bit to bit + bits as free. */ int wnd_set_free(struct wnd_bitmap *wnd, size_t bit, size_t bits) { int err = 0; struct super_block *sb = wnd->sb; size_t bits0 = bits; u32 wbits = 8 * sb->s_blocksize; size_t iw = bit >> (sb->s_blocksize_bits + 3); u32 wbit = bit & (wbits - 1); struct buffer_head *bh; while (iw < wnd->nwnd && bits) { u32 tail, op; if (iw + 1 == wnd->nwnd) wbits = wnd->bits_last; tail = wbits - wbit; op = min_t(u32, tail, bits); bh = wnd_map(wnd, iw); if (IS_ERR(bh)) { err = PTR_ERR(bh); break; } lock_buffer(bh); ntfs_bitmap_clear_le(bh->b_data, wbit, op); wnd->free_bits[iw] += op; set_buffer_uptodate(bh); mark_buffer_dirty(bh); unlock_buffer(bh); put_bh(bh); wnd->total_zeroes += op; bits -= op; wbit = 0; iw += 1; } wnd_add_free_ext(wnd, bit, bits0, false); return err; } /* * wnd_set_used - Mark the bits range from bit to bit + bits as used. */ int wnd_set_used(struct wnd_bitmap *wnd, size_t bit, size_t bits) { int err = 0; struct super_block *sb = wnd->sb; size_t bits0 = bits; size_t iw = bit >> (sb->s_blocksize_bits + 3); u32 wbits = 8 * sb->s_blocksize; u32 wbit = bit & (wbits - 1); struct buffer_head *bh; while (iw < wnd->nwnd && bits) { u32 tail, op; if (unlikely(iw + 1 == wnd->nwnd)) wbits = wnd->bits_last; tail = wbits - wbit; op = min_t(u32, tail, bits); bh = wnd_map(wnd, iw); if (IS_ERR(bh)) { err = PTR_ERR(bh); break; } lock_buffer(bh); ntfs_bitmap_set_le(bh->b_data, wbit, op); wnd->free_bits[iw] -= op; set_buffer_uptodate(bh); mark_buffer_dirty(bh); unlock_buffer(bh); put_bh(bh); wnd->total_zeroes -= op; bits -= op; wbit = 0; iw += 1; } if (!RB_EMPTY_ROOT(&wnd->start_tree)) wnd_remove_free_ext(wnd, bit, bits0); return err; } /* * wnd_set_used_safe - Mark the bits range from bit to bit + bits as used. * * Unlikely wnd_set_used/wnd_set_free this function is not full trusted. * It scans every bit in bitmap and marks free bit as used. * @done - how many bits were marked as used. * * NOTE: normally *done should be 0. */ int wnd_set_used_safe(struct wnd_bitmap *wnd, size_t bit, size_t bits, size_t *done) { size_t i, from = 0, len = 0; int err = 0; *done = 0; for (i = 0; i < bits; i++) { if (wnd_is_free(wnd, bit + i, 1)) { if (!len) from = bit + i; len += 1; } else if (len) { err = wnd_set_used(wnd, from, len); *done += len; len = 0; if (err) break; } } if (len) { /* last fragment. */ err = wnd_set_used(wnd, from, len); *done += len; } return err; } /* * wnd_is_free_hlp * * Return: True if all clusters [bit, bit+bits) are free (bitmap only). */ static bool wnd_is_free_hlp(struct wnd_bitmap *wnd, size_t bit, size_t bits) { struct super_block *sb = wnd->sb; size_t iw = bit >> (sb->s_blocksize_bits + 3); u32 wbits = 8 * sb->s_blocksize; u32 wbit = bit & (wbits - 1); while (iw < wnd->nwnd && bits) { u32 tail, op; if (unlikely(iw + 1 == wnd->nwnd)) wbits = wnd->bits_last; tail = wbits - wbit; op = min_t(u32, tail, bits); if (wbits != wnd->free_bits[iw]) { bool ret; struct buffer_head *bh = wnd_map(wnd, iw); if (IS_ERR(bh)) return false; ret = are_bits_clear(bh->b_data, wbit, op); put_bh(bh); if (!ret) return false; } bits -= op; wbit = 0; iw += 1; } return true; } /* * wnd_is_free * * Return: True if all clusters [bit, bit+bits) are free. */ bool wnd_is_free(struct wnd_bitmap *wnd, size_t bit, size_t bits) { bool ret; struct rb_node *n; size_t end; struct e_node *e; if (RB_EMPTY_ROOT(&wnd->start_tree)) goto use_wnd; n = rb_lookup(&wnd->start_tree, bit); if (!n) goto use_wnd; e = rb_entry(n, struct e_node, start.node); end = e->start.key + e->count.key; if (bit < end && bit + bits <= end) return true; use_wnd: ret = wnd_is_free_hlp(wnd, bit, bits); return ret; } /* * wnd_is_used * * Return: True if all clusters [bit, bit+bits) are used. */ bool wnd_is_used(struct wnd_bitmap *wnd, size_t bit, size_t bits) { bool ret = false; struct super_block *sb = wnd->sb; size_t iw = bit >> (sb->s_blocksize_bits + 3); u32 wbits = 8 * sb->s_blocksize; u32 wbit = bit & (wbits - 1); size_t end; struct rb_node *n; struct e_node *e; if (RB_EMPTY_ROOT(&wnd->start_tree)) goto use_wnd; end = bit + bits; n = rb_lookup(&wnd->start_tree, end - 1); if (!n) goto use_wnd; e = rb_entry(n, struct e_node, start.node); if (e->start.key + e->count.key > bit) return false; use_wnd: while (iw < wnd->nwnd && bits) { u32 tail, op; if (unlikely(iw + 1 == wnd->nwnd)) wbits = wnd->bits_last; tail = wbits - wbit; op = min_t(u32, tail, bits); if (wnd->free_bits[iw]) { bool ret; struct buffer_head *bh = wnd_map(wnd, iw); if (IS_ERR(bh)) goto out; ret = are_bits_set(bh->b_data, wbit, op); put_bh(bh); if (!ret) goto out; } bits -= op; wbit = 0; iw += 1; } ret = true; out: return ret; } /* * wnd_find - Look for free space. * * - flags - BITMAP_FIND_XXX flags * * Return: 0 if not found. */ size_t wnd_find(struct wnd_bitmap *wnd, size_t to_alloc, size_t hint, size_t flags, size_t *allocated) { struct super_block *sb; u32 wbits, wpos, wzbit, wzend; size_t fnd, max_alloc, b_len, b_pos; size_t iw, prev_tail, nwnd, wbit, ebit, zbit, zend; size_t to_alloc0 = to_alloc; const struct e_node *e; const struct rb_node *pr, *cr; u8 log2_bits; bool fbits_valid; struct buffer_head *bh; /* Fast checking for available free space. */ if (flags & BITMAP_FIND_FULL) { size_t zeroes = wnd_zeroes(wnd); zeroes -= wnd->zone_end - wnd->zone_bit; if (zeroes < to_alloc0) goto no_space; if (to_alloc0 > wnd->extent_max) goto no_space; } else { if (to_alloc > wnd->extent_max) to_alloc = wnd->extent_max; } if (wnd->zone_bit <= hint && hint < wnd->zone_end) hint = wnd->zone_end; max_alloc = wnd->nbits; b_len = b_pos = 0; if (hint >= max_alloc) hint = 0; if (RB_EMPTY_ROOT(&wnd->start_tree)) { if (wnd->uptodated == 1) { /* Extents tree is updated -> No free space. */ goto no_space; } goto scan_bitmap; } e = NULL; if (!hint) goto allocate_biggest; /* Use hint: Enumerate extents by start >= hint. */ pr = NULL; cr = wnd->start_tree.rb_node; for (;;) { e = rb_entry(cr, struct e_node, start.node); if (e->start.key == hint) break; if (e->start.key < hint) { pr = cr; cr = cr->rb_right; if (!cr) break; continue; } cr = cr->rb_left; if (!cr) { e = pr ? rb_entry(pr, struct e_node, start.node) : NULL; break; } } if (!e) goto allocate_biggest; if (e->start.key + e->count.key > hint) { /* We have found extension with 'hint' inside. */ size_t len = e->start.key + e->count.key - hint; if (len >= to_alloc && hint + to_alloc <= max_alloc) { fnd = hint; goto found; } if (!(flags & BITMAP_FIND_FULL)) { if (len > to_alloc) len = to_alloc; if (hint + len <= max_alloc) { fnd = hint; to_alloc = len; goto found; } } } allocate_biggest: /* Allocate from biggest free extent. */ e = rb_entry(rb_first(&wnd->count_tree), struct e_node, count.node); if (e->count.key != wnd->extent_max) wnd->extent_max = e->count.key; if (e->count.key < max_alloc) { if (e->count.key >= to_alloc) { ; } else if (flags & BITMAP_FIND_FULL) { if (e->count.key < to_alloc0) { /* Biggest free block is less then requested. */ goto no_space; } to_alloc = e->count.key; } else if (-1 != wnd->uptodated) { to_alloc = e->count.key; } else { /* Check if we can use more bits. */ size_t op, max_check; struct rb_root start_tree; memcpy(&start_tree, &wnd->start_tree, sizeof(struct rb_root)); memset(&wnd->start_tree, 0, sizeof(struct rb_root)); max_check = e->start.key + to_alloc; if (max_check > max_alloc) max_check = max_alloc; for (op = e->start.key + e->count.key; op < max_check; op++) { if (!wnd_is_free(wnd, op, 1)) break; } memcpy(&wnd->start_tree, &start_tree, sizeof(struct rb_root)); to_alloc = op - e->start.key; } /* Prepare to return. */ fnd = e->start.key; if (e->start.key + to_alloc > max_alloc) to_alloc = max_alloc - e->start.key; goto found; } if (wnd->uptodated == 1) { /* Extents tree is updated -> no free space. */ goto no_space; } b_len = e->count.key; b_pos = e->start.key; scan_bitmap: sb = wnd->sb; log2_bits = sb->s_blocksize_bits + 3; /* At most two ranges [hint, max_alloc) + [0, hint). */ Again: /* TODO: Optimize request for case nbits > wbits. */ iw = hint >> log2_bits; wbits = sb->s_blocksize * 8; wpos = hint & (wbits - 1); prev_tail = 0; fbits_valid = true; if (max_alloc == wnd->nbits) { nwnd = wnd->nwnd; } else { size_t t = max_alloc + wbits - 1; nwnd = likely(t > max_alloc) ? (t >> log2_bits) : wnd->nwnd; } /* Enumerate all windows. */ for (; iw < nwnd; iw++) { wbit = iw << log2_bits; if (!wnd->free_bits[iw]) { if (prev_tail > b_len) { b_pos = wbit - prev_tail; b_len = prev_tail; } /* Skip full used window. */ prev_tail = 0; wpos = 0; continue; } if (unlikely(iw + 1 == nwnd)) { if (max_alloc == wnd->nbits) { wbits = wnd->bits_last; } else { size_t t = max_alloc & (wbits - 1); if (t) { wbits = t; fbits_valid = false; } } } if (wnd->zone_end > wnd->zone_bit) { ebit = wbit + wbits; zbit = max(wnd->zone_bit, wbit); zend = min(wnd->zone_end, ebit); /* Here we have a window [wbit, ebit) and zone [zbit, zend). */ if (zend <= zbit) { /* Zone does not overlap window. */ } else { wzbit = zbit - wbit; wzend = zend - wbit; /* Zone overlaps window. */ if (wnd->free_bits[iw] == wzend - wzbit) { prev_tail = 0; wpos = 0; continue; } /* Scan two ranges window: [wbit, zbit) and [zend, ebit). */ bh = wnd_map(wnd, iw); if (IS_ERR(bh)) { /* TODO: Error */ prev_tail = 0; wpos = 0; continue; } /* Scan range [wbit, zbit). */ if (wpos < wzbit) { /* Scan range [wpos, zbit). */ fnd = wnd_scan(bh->b_data, wbit, wpos, wzbit, to_alloc, &prev_tail, &b_pos, &b_len); if (fnd != MINUS_ONE_T) { put_bh(bh); goto found; } } prev_tail = 0; /* Scan range [zend, ebit). */ if (wzend < wbits) { fnd = wnd_scan(bh->b_data, wbit, max(wzend, wpos), wbits, to_alloc, &prev_tail, &b_pos, &b_len); if (fnd != MINUS_ONE_T) { put_bh(bh); goto found; } } wpos = 0; put_bh(bh); continue; } } /* Current window does not overlap zone. */ if (!wpos && fbits_valid && wnd->free_bits[iw] == wbits) { /* Window is empty. */ if (prev_tail + wbits >= to_alloc) { fnd = wbit + wpos - prev_tail; goto found; } /* Increase 'prev_tail' and process next window. */ prev_tail += wbits; wpos = 0; continue; } /* Read window. */ bh = wnd_map(wnd, iw); if (IS_ERR(bh)) { // TODO: Error. prev_tail = 0; wpos = 0; continue; } /* Scan range [wpos, eBits). */ fnd = wnd_scan(bh->b_data, wbit, wpos, wbits, to_alloc, &prev_tail, &b_pos, &b_len); put_bh(bh); if (fnd != MINUS_ONE_T) goto found; } if (b_len < prev_tail) { /* The last fragment. */ b_len = prev_tail; b_pos = max_alloc - prev_tail; } if (hint) { /* * We have scanned range [hint max_alloc). * Prepare to scan range [0 hint + to_alloc). */ size_t nextmax = hint + to_alloc; if (likely(nextmax >= hint) && nextmax < max_alloc) max_alloc = nextmax; hint = 0; goto Again; } if (!b_len) goto no_space; wnd->extent_max = b_len; if (flags & BITMAP_FIND_FULL) goto no_space; fnd = b_pos; to_alloc = b_len; found: if (flags & BITMAP_FIND_MARK_AS_USED) { /* TODO: Optimize remove extent (pass 'e'?). */ if (wnd_set_used(wnd, fnd, to_alloc)) goto no_space; } else if (wnd->extent_max != MINUS_ONE_T && to_alloc > wnd->extent_max) { wnd->extent_max = to_alloc; } *allocated = fnd; return to_alloc; no_space: return 0; } /* * wnd_extend - Extend bitmap ($MFT bitmap). */ int wnd_extend(struct wnd_bitmap *wnd, size_t new_bits) { int err; struct super_block *sb = wnd->sb; struct ntfs_sb_info *sbi = sb->s_fs_info; u32 blocksize = sb->s_blocksize; u32 wbits = blocksize * 8; u32 b0, new_last; size_t bits, iw, new_wnd; size_t old_bits = wnd->nbits; u16 *new_free; if (new_bits <= old_bits) return -EINVAL; /* Align to 8 byte boundary. */ new_wnd = bytes_to_block(sb, bitmap_size(new_bits)); new_last = new_bits & (wbits - 1); if (!new_last) new_last = wbits; if (new_wnd != wnd->nwnd) { new_free = kmalloc_array(new_wnd, sizeof(u16), GFP_NOFS); if (!new_free) return -ENOMEM; memcpy(new_free, wnd->free_bits, wnd->nwnd * sizeof(short)); memset(new_free + wnd->nwnd, 0, (new_wnd - wnd->nwnd) * sizeof(short)); kvfree(wnd->free_bits); wnd->free_bits = new_free; } /* Zero bits [old_bits,new_bits). */ bits = new_bits - old_bits; b0 = old_bits & (wbits - 1); for (iw = old_bits >> (sb->s_blocksize_bits + 3); bits; iw += 1) { u32 op; size_t frb; u64 vbo, lbo, bytes; struct buffer_head *bh; if (iw + 1 == new_wnd) wbits = new_last; op = b0 + bits > wbits ? wbits - b0 : bits; vbo = (u64)iw * blocksize; err = ntfs_vbo_to_lbo(sbi, &wnd->run, vbo, &lbo, &bytes); if (err) break; bh = ntfs_bread(sb, lbo >> sb->s_blocksize_bits); if (!bh) return -EIO; lock_buffer(bh); ntfs_bitmap_clear_le(bh->b_data, b0, blocksize * 8 - b0); frb = wbits - ntfs_bitmap_weight_le(bh->b_data, wbits); wnd->total_zeroes += frb - wnd->free_bits[iw]; wnd->free_bits[iw] = frb; set_buffer_uptodate(bh); mark_buffer_dirty(bh); unlock_buffer(bh); /* err = sync_dirty_buffer(bh); */ b0 = 0; bits -= op; } wnd->nbits = new_bits; wnd->nwnd = new_wnd; wnd->bits_last = new_last; wnd_add_free_ext(wnd, old_bits, new_bits - old_bits, false); return 0; } void wnd_zone_set(struct wnd_bitmap *wnd, size_t lcn, size_t len) { size_t zlen = wnd->zone_end - wnd->zone_bit; if (zlen) wnd_add_free_ext(wnd, wnd->zone_bit, zlen, false); if (!RB_EMPTY_ROOT(&wnd->start_tree) && len) wnd_remove_free_ext(wnd, lcn, len); wnd->zone_bit = lcn; wnd->zone_end = lcn + len; } int ntfs_trim_fs(struct ntfs_sb_info *sbi, struct fstrim_range *range) { int err = 0; struct super_block *sb = sbi->sb; struct wnd_bitmap *wnd = &sbi->used.bitmap; u32 wbits = 8 * sb->s_blocksize; CLST len = 0, lcn = 0, done = 0; CLST minlen = bytes_to_cluster(sbi, range->minlen); CLST lcn_from = bytes_to_cluster(sbi, range->start); size_t iw = lcn_from >> (sb->s_blocksize_bits + 3); u32 wbit = lcn_from & (wbits - 1); CLST lcn_to; if (!minlen) minlen = 1; if (range->len == (u64)-1) lcn_to = wnd->nbits; else lcn_to = bytes_to_cluster(sbi, range->start + range->len); down_read_nested(&wnd->rw_lock, BITMAP_MUTEX_CLUSTERS); for (; iw < wnd->nwnd; iw++, wbit = 0) { CLST lcn_wnd = iw * wbits; struct buffer_head *bh; if (lcn_wnd > lcn_to) break; if (!wnd->free_bits[iw]) continue; if (iw + 1 == wnd->nwnd) wbits = wnd->bits_last; if (lcn_wnd + wbits > lcn_to) wbits = lcn_to - lcn_wnd; bh = wnd_map(wnd, iw); if (IS_ERR(bh)) { err = PTR_ERR(bh); break; } for (; wbit < wbits; wbit++) { if (!test_bit_le(wbit, bh->b_data)) { if (!len) lcn = lcn_wnd + wbit; len += 1; continue; } if (len >= minlen) { err = ntfs_discard(sbi, lcn, len); if (err) goto out; done += len; } len = 0; } put_bh(bh); } /* Process the last fragment. */ if (len >= minlen) { err = ntfs_discard(sbi, lcn, len); if (err) goto out; done += len; } out: range->len = (u64)done << sbi->cluster_bits; up_read(&wnd->rw_lock); return err; } #if BITS_PER_LONG == 64 typedef __le64 bitmap_ulong; #define cpu_to_ul(x) cpu_to_le64(x) #define ul_to_cpu(x) le64_to_cpu(x) #else typedef __le32 bitmap_ulong; #define cpu_to_ul(x) cpu_to_le32(x) #define ul_to_cpu(x) le32_to_cpu(x) #endif void ntfs_bitmap_set_le(void *map, unsigned int start, int len) { bitmap_ulong *p = (bitmap_ulong *)map + BIT_WORD(start); const unsigned int size = start + len; int bits_to_set = BITS_PER_LONG - (start % BITS_PER_LONG); bitmap_ulong mask_to_set = cpu_to_ul(BITMAP_FIRST_WORD_MASK(start)); while (len - bits_to_set >= 0) { *p |= mask_to_set; len -= bits_to_set; bits_to_set = BITS_PER_LONG; mask_to_set = cpu_to_ul(~0UL); p++; } if (len) { mask_to_set &= cpu_to_ul(BITMAP_LAST_WORD_MASK(size)); *p |= mask_to_set; } } void ntfs_bitmap_clear_le(void *map, unsigned int start, int len) { bitmap_ulong *p = (bitmap_ulong *)map + BIT_WORD(start); const unsigned int size = start + len; int bits_to_clear = BITS_PER_LONG - (start % BITS_PER_LONG); bitmap_ulong mask_to_clear = cpu_to_ul(BITMAP_FIRST_WORD_MASK(start)); while (len - bits_to_clear >= 0) { *p &= ~mask_to_clear; len -= bits_to_clear; bits_to_clear = BITS_PER_LONG; mask_to_clear = cpu_to_ul(~0UL); p++; } if (len) { mask_to_clear &= cpu_to_ul(BITMAP_LAST_WORD_MASK(size)); *p &= ~mask_to_clear; } } unsigned int ntfs_bitmap_weight_le(const void *bitmap, int bits) { const ulong *bmp = bitmap; unsigned int k, lim = bits / BITS_PER_LONG; unsigned int w = 0; for (k = 0; k < lim; k++) w += hweight_long(bmp[k]); if (bits % BITS_PER_LONG) { w += hweight_long(ul_to_cpu(((bitmap_ulong *)bitmap)[k]) & BITMAP_LAST_WORD_MASK(bits)); } return w; }
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