// SPDX-License-Identifier: GPL-2.0-or-later /* * Copyright (C) 2021 LG Electronics. * * Author(s): Hyunchul Lee */ #include #include #include #include #include #include #include "exfat_ondisk.h" #include "libexfat.h" #include "exfat_fs.h" #include "exfat_dir.h" static struct path_resolve_ctx path_resolve_ctx; #define fsck_err(parent, inode, fmt, ...) \ ({ \ exfat_resolve_path_parent(&path_resolve_ctx, \ parent, inode); \ exfat_err("ERROR: %s: " fmt, \ path_resolve_ctx.local_path, \ ##__VA_ARGS__); \ }) static ssize_t write_block(struct exfat_de_iter *iter, unsigned int block) { off_t device_offset; struct exfat *exfat = iter->exfat; struct buffer_desc *desc; unsigned int i; desc = &iter->buffer_desc[block & 0x01]; for (i = 0; i < iter->read_size / iter->write_size; i++) { if (desc->dirty[i]) { device_offset = exfat_c2o(exfat, desc->p_clus) + desc->offset; if (exfat_write(exfat->blk_dev->dev_fd, desc->buffer + i * iter->write_size, iter->write_size, device_offset + i * iter->write_size) != (ssize_t)iter->write_size) return -EIO; desc->dirty[i] = 0; } } return 0; } static int read_ahead_first_blocks(struct exfat_de_iter *iter) { #ifdef POSIX_FADV_WILLNEED struct exfat *exfat = iter->exfat; clus_t clus_count; unsigned int size; clus_count = iter->parent->size / exfat->clus_size; if (clus_count > 1) { iter->ra_begin_offset = 0; iter->ra_next_clus = 1; size = exfat->clus_size; } else { iter->ra_begin_offset = 0; iter->ra_next_clus = 0; size = iter->ra_partial_size; } return posix_fadvise(exfat->blk_dev->dev_fd, exfat_c2o(exfat, iter->parent->first_clus), size, POSIX_FADV_WILLNEED); #else return -ENOTSUP; #endif } /** * read the next fragment in advance, and assume the fragment * which covers @clus is already read. */ static int read_ahead_next_blocks(struct exfat_de_iter *iter, clus_t clus, unsigned int offset, clus_t p_clus) { #ifdef POSIX_FADV_WILLNEED struct exfat *exfat = iter->exfat; off_t device_offset; clus_t clus_count, ra_clus, ra_p_clus; unsigned int size; int ret = 0; clus_count = iter->parent->size / exfat->clus_size; if (clus + 1 < clus_count) { ra_clus = clus + 1; if (ra_clus == iter->ra_next_clus && offset >= iter->ra_begin_offset) { ret = exfat_get_inode_next_clus(exfat, iter->parent, p_clus, &ra_p_clus); if (ret) return ret; if (ra_p_clus == EXFAT_EOF_CLUSTER) return -EIO; device_offset = exfat_c2o(exfat, ra_p_clus); size = ra_clus + 1 < clus_count ? exfat->clus_size : iter->ra_partial_size; ret = posix_fadvise(exfat->blk_dev->dev_fd, device_offset, size, POSIX_FADV_WILLNEED); iter->ra_next_clus = ra_clus + 1; iter->ra_begin_offset = 0; } } else { if (offset >= iter->ra_begin_offset && offset + iter->ra_partial_size <= exfat->clus_size) { device_offset = exfat_c2o(exfat, p_clus) + offset + iter->ra_partial_size; ret = posix_fadvise(exfat->blk_dev->dev_fd, device_offset, iter->ra_partial_size, POSIX_FADV_WILLNEED); iter->ra_begin_offset = offset + iter->ra_partial_size; } } return ret; #else return -ENOTSUP; #endif } static int read_ahead_next_dir_blocks(struct exfat_de_iter *iter) { #ifdef POSIX_FADV_WILLNEED struct exfat *exfat = iter->exfat; struct list_head *current; struct exfat_inode *next_inode; off_t offset; if (list_empty(&exfat->dir_list)) return -EINVAL; current = exfat->dir_list.next; if (iter->parent == list_entry(current, struct exfat_inode, list) && current->next != &exfat->dir_list) { next_inode = list_entry(current->next, struct exfat_inode, list); offset = exfat_c2o(exfat, next_inode->first_clus); return posix_fadvise(exfat->blk_dev->dev_fd, offset, iter->ra_partial_size, POSIX_FADV_WILLNEED); } return 0; #else return -ENOTSUP; #endif } static ssize_t read_block(struct exfat_de_iter *iter, unsigned int block) { struct exfat *exfat = iter->exfat; struct buffer_desc *desc, *prev_desc; off_t device_offset; ssize_t ret; desc = &iter->buffer_desc[block & 0x01]; if (block == 0) { desc->p_clus = iter->parent->first_clus; desc->offset = 0; } /* if the buffer already contains dirty dentries, write it */ if (write_block(iter, block)) return -EIO; if (block > 0) { if (block > iter->parent->size / iter->read_size) return EOF; prev_desc = &iter->buffer_desc[(block-1) & 0x01]; if (prev_desc->offset + 2 * iter->read_size <= exfat->clus_size) { desc->p_clus = prev_desc->p_clus; desc->offset = prev_desc->offset + iter->read_size; } else { ret = exfat_get_inode_next_clus(exfat, iter->parent, prev_desc->p_clus, &desc->p_clus); desc->offset = 0; if (ret) return ret; else if (desc->p_clus == EXFAT_EOF_CLUSTER) return EOF; } } device_offset = exfat_c2o(exfat, desc->p_clus) + desc->offset; ret = exfat_read(exfat->blk_dev->dev_fd, desc->buffer, iter->read_size, device_offset); if (ret <= 0) return ret; /* * if a buffer is filled with dentries, read blocks ahead of time, * otherwise read blocks of the next directory in advance. */ if (desc->buffer[iter->read_size - 32] != EXFAT_LAST) read_ahead_next_blocks(iter, (block * iter->read_size) / exfat->clus_size, (block * iter->read_size) % exfat->clus_size, desc->p_clus); else read_ahead_next_dir_blocks(iter); return ret; } int exfat_de_iter_init(struct exfat_de_iter *iter, struct exfat *exfat, struct exfat_inode *dir, struct buffer_desc *bd) { iter->exfat = exfat; iter->parent = dir; iter->write_size = exfat->sect_size; iter->read_size = exfat->clus_size <= 4*KB ? exfat->clus_size : 4*KB; if (exfat->clus_size <= 32 * KB) iter->ra_partial_size = MAX(4 * KB, exfat->clus_size / 2); else iter->ra_partial_size = exfat->clus_size / 4; iter->ra_partial_size = MIN(iter->ra_partial_size, 8 * KB); iter->buffer_desc = bd; iter->de_file_offset = 0; iter->next_read_offset = iter->read_size; iter->max_skip_dentries = 0; iter->dot_name_num = 0; if (iter->parent->size == 0) return EOF; read_ahead_first_blocks(iter); if (read_block(iter, 0) != (ssize_t)iter->read_size) { exfat_err("failed to read directory entries.\n"); return -EIO; } return 0; } int exfat_de_iter_get(struct exfat_de_iter *iter, int ith, struct exfat_dentry **dentry) { off_t next_de_file_offset; ssize_t ret; unsigned int block; next_de_file_offset = iter->de_file_offset + ith * sizeof(struct exfat_dentry); block = (unsigned int)(next_de_file_offset / iter->read_size); if (next_de_file_offset + sizeof(struct exfat_dentry) > iter->parent->size) return EOF; /* the dentry must be in current, or next block which will be read */ if (block > iter->de_file_offset / iter->read_size + 1) return -ERANGE; /* read next cluster if needed */ if (next_de_file_offset >= iter->next_read_offset) { ret = read_block(iter, block); if (ret != (ssize_t)iter->read_size) return ret; iter->next_read_offset += iter->read_size; } if (ith + 1 > iter->max_skip_dentries) iter->max_skip_dentries = ith + 1; *dentry = (struct exfat_dentry *) (iter->buffer_desc[block & 0x01].buffer + next_de_file_offset % iter->read_size); return 0; } int exfat_de_iter_get_dirty(struct exfat_de_iter *iter, int ith, struct exfat_dentry **dentry) { off_t next_file_offset; unsigned int block; int ret, sect_idx; ret = exfat_de_iter_get(iter, ith, dentry); if (!ret) { next_file_offset = iter->de_file_offset + ith * sizeof(struct exfat_dentry); block = (unsigned int)(next_file_offset / iter->read_size); sect_idx = (int)((next_file_offset % iter->read_size) / iter->write_size); iter->buffer_desc[block & 0x01].dirty[sect_idx] = 1; } return ret; } int exfat_de_iter_flush(struct exfat_de_iter *iter) { if (write_block(iter, 0) || write_block(iter, 1)) return -EIO; return 0; } int exfat_de_iter_advance(struct exfat_de_iter *iter, int skip_dentries) { if (skip_dentries > iter->max_skip_dentries) return -EINVAL; iter->max_skip_dentries = 0; iter->de_file_offset = iter->de_file_offset + skip_dentries * sizeof(struct exfat_dentry); return 0; } off_t exfat_de_iter_device_offset(struct exfat_de_iter *iter) { struct buffer_desc *bd; unsigned int block; if ((uint64_t)iter->de_file_offset >= iter->parent->size) return EOF; block = iter->de_file_offset / iter->read_size; bd = &iter->buffer_desc[block & 0x01]; return exfat_c2o(iter->exfat, bd->p_clus) + bd->offset + iter->de_file_offset % iter->read_size; } off_t exfat_de_iter_file_offset(struct exfat_de_iter *iter) { return iter->de_file_offset; } /* * try to find the dentry set matched with @filter. this function * doesn't verify the dentry set. * * if found, return 0. if not found, return EOF. otherwise return errno. */ int exfat_lookup_dentry_set(struct exfat *exfat, struct exfat_inode *parent, struct exfat_lookup_filter *filter) { struct buffer_desc *bd = NULL; struct exfat_dentry *dentry = NULL; off_t free_file_offset = 0, free_dev_offset = 0; struct exfat_de_iter de_iter; int dentry_count; int retval; bool last_is_free = false; bd = exfat_alloc_buffer(2, exfat->clus_size, exfat->sect_size); if (!bd) return -ENOMEM; retval = exfat_de_iter_init(&de_iter, exfat, parent, bd); if (retval == EOF || retval) goto out; filter->out.dentry_set = NULL; while (1) { retval = exfat_de_iter_get(&de_iter, 0, &dentry); if (retval == EOF) { break; } else if (retval) { fsck_err(parent->parent, parent, "failed to get a dentry. %d\n", retval); goto out; } dentry_count = 1; if (dentry->type == filter->in.type) { retval = 0; if (filter->in.filter) retval = filter->in.filter(&de_iter, filter->in.param, &dentry_count); if (retval == 0) { struct exfat_dentry *d; int i; filter->out.dentry_set = calloc(dentry_count, sizeof(struct exfat_dentry)); if (!filter->out.dentry_set) { retval = -ENOMEM; goto out; } for (i = 0; i < dentry_count; i++) { exfat_de_iter_get(&de_iter, i, &d); memcpy(filter->out.dentry_set + i, d, sizeof(struct exfat_dentry)); } filter->out.dentry_count = dentry_count; goto out; } else if (retval < 0) { goto out; } last_is_free = false; } else if ((dentry->type == EXFAT_LAST || IS_EXFAT_DELETED(dentry->type))) { if (!last_is_free) { free_file_offset = exfat_de_iter_file_offset(&de_iter); free_dev_offset = exfat_de_iter_device_offset(&de_iter); last_is_free = true; } } else { last_is_free = false; } exfat_de_iter_advance(&de_iter, dentry_count); } out: if (retval == 0) { filter->out.file_offset = exfat_de_iter_file_offset(&de_iter); filter->out.dev_offset = exfat_de_iter_device_offset(&de_iter); } else if (retval == EOF && last_is_free) { filter->out.file_offset = free_file_offset; filter->out.dev_offset = free_dev_offset; } else { filter->out.file_offset = exfat_de_iter_file_offset(&de_iter); filter->out.dev_offset = EOF; } if (bd) exfat_free_buffer(bd, 2); return retval; } static int filter_lookup_file(struct exfat_de_iter *de_iter, void *param, int *dentry_count) { struct exfat_dentry *file_de, *stream_de, *name_de; __le16 *name; int retval, name_len; int i; retval = exfat_de_iter_get(de_iter, 0, &file_de); if (retval || file_de->type != EXFAT_FILE) return 1; retval = exfat_de_iter_get(de_iter, 1, &stream_de); if (retval || stream_de->type != EXFAT_STREAM) return 1; name = (__le16 *)param; name_len = (int)exfat_utf16_len(name, PATH_MAX); if (file_de->dentry.file.num_ext < 1 + (name_len + ENTRY_NAME_MAX - 1) / ENTRY_NAME_MAX) return 1; for (i = 2; i <= file_de->dentry.file.num_ext && name_len > 0; i++) { int len; retval = exfat_de_iter_get(de_iter, i, &name_de); if (retval || name_de->type != EXFAT_NAME) return 1; len = MIN(name_len, ENTRY_NAME_MAX); if (memcmp(name_de->dentry.name.unicode_0_14, name, len * 2) != 0) return 1; name += len; name_len -= len; } *dentry_count = i; return 0; } int exfat_lookup_file(struct exfat *exfat, struct exfat_inode *parent, const char *name, struct exfat_lookup_filter *filter_out) { int retval; __le16 utf16_name[PATH_MAX + 2] = {0, }; retval = (int)exfat_utf16_enc(name, utf16_name, sizeof(utf16_name)); if (retval < 0) return retval; filter_out->in.type = EXFAT_FILE; filter_out->in.filter = filter_lookup_file; filter_out->in.param = utf16_name; retval = exfat_lookup_dentry_set(exfat, parent, filter_out); if (retval < 0) return retval; return 0; } void exfat_calc_dentry_checksum(struct exfat_dentry *dentry, uint16_t *checksum, bool primary) { unsigned int i; uint8_t *bytes; bytes = (uint8_t *)dentry; *checksum = ((*checksum << 15) | (*checksum >> 1)) + bytes[0]; *checksum = ((*checksum << 15) | (*checksum >> 1)) + bytes[1]; i = primary ? 4 : 2; for (; i < sizeof(*dentry); i++) *checksum = ((*checksum << 15) | (*checksum >> 1)) + bytes[i]; } static uint16_t calc_dentry_set_checksum(struct exfat_dentry *dset, int dcount) { uint16_t checksum; int i; if (dcount < MIN_FILE_DENTRIES) return 0; checksum = 0; exfat_calc_dentry_checksum(&dset[0], &checksum, true); for (i = 1; i < dcount; i++) exfat_calc_dentry_checksum(&dset[i], &checksum, false); return checksum; } uint16_t exfat_calc_name_hash(struct exfat *exfat, __le16 *name, int len) { int i; __le16 ch; uint16_t chksum = 0; for (i = 0; i < len; i++) { ch = exfat->upcase_table[le16_to_cpu(name[i])]; ch = cpu_to_le16(ch); chksum = ((chksum << 15) | (chksum >> 1)) + (ch & 0xFF); chksum = ((chksum << 15) | (chksum >> 1)) + (ch >> 8); } return chksum; } static void unix_time_to_exfat_time(time_t unix_time, __u8 *tz, __le16 *date, __le16 *time, __u8 *time_ms) { struct tm tm; __u16 t, d; gmtime_r(&unix_time, &tm); d = ((tm.tm_year - 80) << 9) | ((tm.tm_mon + 1) << 5) | tm.tm_mday; t = (tm.tm_hour << 11) | (tm.tm_min << 5) | (tm.tm_sec >> 1); *tz = 0x80; *date = cpu_to_le16(d); *time = cpu_to_le16(t); if (time_ms) *time_ms = (tm.tm_sec & 1) * 100; } int exfat_build_file_dentry_set(struct exfat *exfat, const char *name, unsigned short attr, struct exfat_dentry **dentry_set, int *dentry_count) { struct exfat_dentry *dset; __le16 utf16_name[PATH_MAX + 2]; int retval; int dcount, name_len, i; __le16 e_date, e_time; __u8 tz, e_time_ms; memset(utf16_name, 0, sizeof(utf16_name)); retval = exfat_utf16_enc(name, utf16_name, sizeof(utf16_name)); if (retval < 0) return retval; name_len = retval / 2; dcount = 2 + DIV_ROUND_UP(name_len, ENTRY_NAME_MAX); dset = calloc(1, dcount * DENTRY_SIZE); if (!dset) return -ENOMEM; dset[0].type = EXFAT_FILE; dset[0].dentry.file.num_ext = dcount - 1; dset[0].dentry.file.attr = cpu_to_le16(attr); unix_time_to_exfat_time(time(NULL), &tz, &e_date, &e_time, &e_time_ms); dset[0].dentry.file.create_date = e_date; dset[0].dentry.file.create_time = e_time; dset[0].dentry.file.create_time_ms = e_time_ms; dset[0].dentry.file.create_tz = tz; dset[0].dentry.file.modify_date = e_date; dset[0].dentry.file.modify_time = e_time; dset[0].dentry.file.modify_time_ms = e_time_ms; dset[0].dentry.file.modify_tz = tz; dset[0].dentry.file.access_date = e_date; dset[0].dentry.file.access_time = e_time; dset[0].dentry.file.access_tz = tz; dset[1].type = EXFAT_STREAM; dset[1].dentry.stream.flags = 0x01; dset[1].dentry.stream.name_len = (__u8)name_len; dset[1].dentry.stream.name_hash = cpu_to_le16(exfat_calc_name_hash(exfat, utf16_name, name_len)); for (i = 2; i < dcount; i++) { dset[i].type = EXFAT_NAME; memcpy(dset[i].dentry.name.unicode_0_14, utf16_name + (i - 2) * ENTRY_NAME_MAX, ENTRY_NAME_MAX * 2); } dset[0].dentry.file.checksum = cpu_to_le16(calc_dentry_set_checksum(dset, dcount)); *dentry_set = dset; *dentry_count = dcount; return 0; } int exfat_update_file_dentry_set(struct exfat *exfat, struct exfat_dentry *dset, int dcount, const char *name, clus_t start_clu, clus_t ccount) { int i, name_len; __le16 utf16_name[PATH_MAX + 2]; if (dset[0].type != EXFAT_FILE || dcount < MIN_FILE_DENTRIES) return -EINVAL; if (name) { name_len = (int)exfat_utf16_enc(name, utf16_name, sizeof(utf16_name)); if (name_len < 0) return name_len; name_len /= 2; if (dcount != 2 + DIV_ROUND_UP(name_len, ENTRY_NAME_MAX)) return -EINVAL; dset[1].dentry.stream.name_len = (__u8)name_len; dset[1].dentry.stream.name_hash = exfat_calc_name_hash(exfat, utf16_name, name_len); for (i = 2; i < dcount; i++) { dset[i].type = EXFAT_NAME; memcpy(dset[i].dentry.name.unicode_0_14, utf16_name + (i - 2) * ENTRY_NAME_MAX, ENTRY_NAME_MAX * 2); } } dset[1].dentry.stream.valid_size = cpu_to_le64(ccount * exfat->clus_size); dset[1].dentry.stream.size = cpu_to_le64(ccount * exfat->clus_size); if (start_clu) dset[1].dentry.stream.start_clu = cpu_to_le32(start_clu); dset[0].dentry.file.checksum = cpu_to_le16(calc_dentry_set_checksum(dset, dcount)); return 0; } int exfat_find_free_cluster(struct exfat *exfat, clus_t start, clus_t *new_clu) { clus_t end = le32_to_cpu(exfat->bs->bsx.clu_count) + EXFAT_FIRST_CLUSTER; if (!exfat_heap_clus(exfat, start)) return -EINVAL; while (start < end) { if (exfat_bitmap_find_zero(exfat, exfat->alloc_bitmap, start, new_clu)) break; if (!exfat_bitmap_get(exfat->disk_bitmap, *new_clu)) return 0; start = *new_clu + 1; } end = start; start = EXFAT_FIRST_CLUSTER; while (start < end) { if (exfat_bitmap_find_zero(exfat, exfat->alloc_bitmap, start, new_clu)) goto out_nospc; if (!exfat_bitmap_get(exfat->disk_bitmap, *new_clu)) return 0; start = *new_clu + 1; } out_nospc: *new_clu = EXFAT_EOF_CLUSTER; return -ENOSPC; } static int exfat_map_cluster(struct exfat *exfat, struct exfat_inode *inode, off_t file_off, clus_t *mapped_clu) { clus_t clu, next, count, last_count; if (!exfat_heap_clus(exfat, inode->first_clus)) return -EINVAL; clu = inode->first_clus; next = EXFAT_EOF_CLUSTER; count = 1; if (file_off == EOF) last_count = DIV_ROUND_UP(inode->size, exfat->clus_size); else last_count = file_off / exfat->clus_size + 1; while (true) { if (count * exfat->clus_size > inode->size) return -EINVAL; if (count == last_count) { *mapped_clu = clu; return 0; } if (exfat_get_inode_next_clus(exfat, inode, clu, &next)) return -EINVAL; if (!exfat_heap_clus(exfat, clu)) return -EINVAL; clu = next; count++; } return -EINVAL; } static int exfat_write_dentry_set(struct exfat *exfat, struct exfat_dentry *dset, int dcount, off_t dev_off, off_t *next_dev_off) { clus_t clus; unsigned int clus_off, dent_len, first_half_len, sec_half_len; off_t first_half_off, sec_half_off = 0; if (exfat_o2c(exfat, dev_off, &clus, &clus_off)) return -ERANGE; dent_len = dcount * DENTRY_SIZE; first_half_len = MIN(dent_len, exfat->clus_size - clus_off); sec_half_len = dent_len - first_half_len; first_half_off = dev_off; if (sec_half_len) { clus_t next_clus; if (exfat_get_next_clus(exfat, clus, &next_clus)) return -EIO; if (!exfat_heap_clus(exfat, next_clus)) return -EINVAL; sec_half_off = exfat_c2o(exfat, next_clus); } if (exfat_write(exfat->blk_dev->dev_fd, dset, first_half_len, first_half_off) != (ssize_t)first_half_len) return -EIO; if (sec_half_len) { dset = (struct exfat_dentry *)((char *)dset + first_half_len); if (exfat_write(exfat->blk_dev->dev_fd, dset, sec_half_len, sec_half_off) != (ssize_t)sec_half_len) return -EIO; } if (next_dev_off) { if (sec_half_len) *next_dev_off = sec_half_off + sec_half_len; else *next_dev_off = first_half_off + first_half_len; } return 0; } static int exfat_alloc_cluster(struct exfat *exfat, struct exfat_inode *inode, clus_t *new_clu) { clus_t last_clu; int err; bool need_dset = inode != exfat->root; if ((need_dset && !inode->dentry_set) || inode->is_contiguous) return -EINVAL; err = exfat_find_free_cluster(exfat, exfat->start_clu, new_clu); if (err) { exfat->start_clu = EXFAT_FIRST_CLUSTER; exfat_err("failed to find an free cluster\n"); return -ENOSPC; } exfat->start_clu = *new_clu; if (exfat_set_fat(exfat, *new_clu, EXFAT_EOF_CLUSTER)) return -EIO; /* zero out the new cluster */ if (exfat_write(exfat->blk_dev->dev_fd, exfat->zero_cluster, exfat->clus_size, exfat_c2o(exfat, *new_clu)) != (ssize_t)exfat->clus_size) { exfat_err("failed to fill new cluster with zeroes\n"); return -EIO; } if (inode->size) { err = exfat_map_cluster(exfat, inode, EOF, &last_clu); if (err) { exfat_err("failed to get the last cluster\n"); return err; } if (exfat_set_fat(exfat, last_clu, *new_clu)) return -EIO; if (need_dset) { err = exfat_update_file_dentry_set(exfat, inode->dentry_set, inode->dentry_count, NULL, 0, DIV_ROUND_UP(inode->size, exfat->clus_size) + 1); if (err) return -EINVAL; } } else { if (need_dset) { err = exfat_update_file_dentry_set(exfat, inode->dentry_set, inode->dentry_count, NULL, *new_clu, 1); if (err) return -EINVAL; } } if (need_dset && exfat_write_dentry_set(exfat, inode->dentry_set, inode->dentry_count, inode->dev_offset, NULL)) return -EIO; exfat_bitmap_set(exfat->alloc_bitmap, *new_clu); if (inode->size == 0) inode->first_clus = *new_clu; inode->size += exfat->clus_size; return 0; } int exfat_add_dentry_set(struct exfat *exfat, struct exfat_dentry_loc *loc, struct exfat_dentry *dset, int dcount, bool need_next_loc) { struct exfat_inode *parent = loc->parent; off_t dev_off, next_dev_off; if (parent->is_contiguous || (uint64_t)loc->file_offset > parent->size || (unsigned int)dcount * DENTRY_SIZE > exfat->clus_size) return -EINVAL; dev_off = loc->dev_offset; if ((uint64_t)loc->file_offset + dcount * DENTRY_SIZE > parent->size) { clus_t new_clus; if (exfat_alloc_cluster(exfat, parent, &new_clus)) return -EIO; if ((uint64_t)loc->file_offset == parent->size - exfat->clus_size) dev_off = exfat_c2o(exfat, new_clus); } if (exfat_write_dentry_set(exfat, dset, dcount, dev_off, &next_dev_off)) return -EIO; if (need_next_loc) { loc->file_offset += dcount * DENTRY_SIZE; loc->dev_offset = next_dev_off; } return 0; } int exfat_create_file(struct exfat *exfat, struct exfat_inode *parent, const char *name, unsigned short attr) { struct exfat_dentry *dset; int err, dcount; struct exfat_lookup_filter filter; struct exfat_dentry_loc loc; err = exfat_lookup_file(exfat, parent, name, &filter); if (err == 0) { dset = filter.out.dentry_set; dcount = filter.out.dentry_count; if ((le16_to_cpu(dset->dentry.file.attr) & attr) != attr) err = -EEXIST; goto out; } err = exfat_build_file_dentry_set(exfat, name, attr, &dset, &dcount); if (err) return err; loc.parent = parent; loc.file_offset = filter.out.file_offset; loc.dev_offset = filter.out.dev_offset; err = exfat_add_dentry_set(exfat, &loc, dset, dcount, false); out: free(dset); return err; }