/* * Copyright (C) 2015 The Android Open Source Project * * Licensed under the Apache License, Version 2.0 (the "License"); * you may not use this file except in compliance with the License. * You may obtain a copy of the License at * * http://www.apache.org/licenses/LICENSE-2.0 * * Unless required by applicable law or agreed to in writing, software * distributed under the License is distributed on an "AS IS" BASIS, * WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied. * See the License for the specific language governing permissions and * limitations under the License. */ #include <stdlib.h> #include <sys/ioctl.h> #include <sys/stat.h> #include <ext4_utils/ext4_sb.h> extern "C" { #include <squashfs_utils.h> } #if defined(__linux__) #include <linux/fs.h> #elif defined(__APPLE__) #include <sys/disk.h> #define BLKGETSIZE64 DKIOCGETBLOCKCOUNT #define fdatasync(fd) fcntl((fd), F_FULLFSYNC) #endif #include "fec_private.h" /* used by `find_offset'; returns metadata size for a file size `size' and `roots' Reed-Solomon parity bytes */ using size_func = uint64_t (*)(uint64_t size, int roots); /* performs a binary search to find a metadata offset from a file so that the metadata size matches function `get_real_size(size, roots)', using the approximate size returned by `get_appr_size' as a starting point */ static int find_offset(uint64_t file_size, int roots, uint64_t *offset, size_func get_appr_size, size_func get_real_size) { check(offset); check(get_appr_size); check(get_real_size); if (file_size % FEC_BLOCKSIZE) { /* must be a multiple of block size */ error("file size not multiple of " stringify(FEC_BLOCKSIZE)); errno = EINVAL; return -1; } uint64_t mi = get_appr_size(file_size, roots); uint64_t lo = file_size - mi * 2; uint64_t hi = file_size - mi / 2; while (lo < hi) { mi = ((hi + lo) / (2 * FEC_BLOCKSIZE)) * FEC_BLOCKSIZE; uint64_t total = mi + get_real_size(mi, roots); if (total < file_size) { lo = mi + FEC_BLOCKSIZE; } else if (total > file_size) { hi = mi; } else { *offset = mi; debug("file_size = %" PRIu64 " -> offset = %" PRIu64, file_size, mi); return 0; } } warn("could not determine offset"); errno = ERANGE; return -1; } /* returns verity metadata size for a `size' byte file */ static uint64_t get_verity_size(uint64_t size, int) { return VERITY_METADATA_SIZE + verity_get_size(size, NULL, NULL); } /* computes the verity metadata offset for a file with size `f->size' */ static int find_verity_offset(fec_handle *f, uint64_t *offset) { check(f); check(offset); return find_offset(f->data_size, 0, offset, get_verity_size, get_verity_size); } /* attempts to read and validate an ecc header from file position `offset' */ static int parse_ecc_header(fec_handle *f, uint64_t offset) { check(f); check(f->ecc.rsn > 0 && f->ecc.rsn < FEC_RSM); check(f->size > sizeof(fec_header)); debug("offset = %" PRIu64, offset); if (offset > f->size - sizeof(fec_header)) { return -1; } fec_header header; /* there's obviously no ecc data at this point, so there is no need to call fec_pread to access this data */ if (!raw_pread(f, &header, sizeof(fec_header), offset)) { error("failed to read: %s", strerror(errno)); return -1; } /* move offset back to the beginning of the block for validating header */ offset -= offset % FEC_BLOCKSIZE; if (header.magic != FEC_MAGIC) { return -1; } if (header.version != FEC_VERSION) { error("unsupported ecc version: %u", header.version); return -1; } if (header.size != sizeof(fec_header)) { error("unexpected ecc header size: %u", header.size); return -1; } if (header.roots == 0 || header.roots >= FEC_RSM) { error("invalid ecc roots: %u", header.roots); return -1; } if (f->ecc.roots != (int)header.roots) { error("unexpected number of roots: %d vs %u", f->ecc.roots, header.roots); return -1; } if (header.fec_size % header.roots || header.fec_size % FEC_BLOCKSIZE) { error("inconsistent ecc size %u", header.fec_size); return -1; } f->data_size = header.inp_size; f->ecc.blocks = fec_div_round_up(f->data_size, FEC_BLOCKSIZE); f->ecc.rounds = fec_div_round_up(f->ecc.blocks, f->ecc.rsn); if (header.fec_size != (uint32_t)f->ecc.rounds * f->ecc.roots * FEC_BLOCKSIZE) { error("inconsistent ecc size %u", header.fec_size); return -1; } f->ecc.size = header.fec_size; f->ecc.start = header.inp_size; /* validate encoding data; caller may opt not to use it if invalid */ SHA256_CTX ctx; SHA256_Init(&ctx); uint8_t buf[FEC_BLOCKSIZE]; uint32_t n = 0; uint32_t len = FEC_BLOCKSIZE; while (n < f->ecc.size) { if (len > f->ecc.size - n) { len = f->ecc.size - n; } if (!raw_pread(f, buf, len, f->ecc.start + n)) { error("failed to read ecc: %s", strerror(errno)); return -1; } SHA256_Update(&ctx, buf, len); n += len; } uint8_t hash[SHA256_DIGEST_LENGTH]; SHA256_Final(hash, &ctx); f->ecc.valid = !memcmp(hash, header.hash, SHA256_DIGEST_LENGTH); if (!f->ecc.valid) { warn("ecc data not valid"); } return 0; } /* attempts to read an ecc header from `offset', and checks for a backup copy at the end of the block if the primary header is not valid */ static int parse_ecc(fec_handle *f, uint64_t offset) { check(f); check(offset % FEC_BLOCKSIZE == 0); check(offset < UINT64_MAX - FEC_BLOCKSIZE); /* check the primary header at the beginning of the block */ if (parse_ecc_header(f, offset) == 0) { return 0; } /* check the backup header at the end of the block */ if (parse_ecc_header(f, offset + FEC_BLOCKSIZE - sizeof(fec_header)) == 0) { warn("using backup ecc header"); return 0; } return -1; } /* reads the squashfs superblock and returns the size of the file system in `offset' */ static int get_squashfs_size(fec_handle *f, uint64_t *offset) { check(f); check(offset); size_t sb_size = squashfs_get_sb_size(); check(sb_size <= SSIZE_MAX); uint8_t buffer[sb_size]; if (fec_pread(f, buffer, sizeof(buffer), 0) != (ssize_t)sb_size) { error("failed to read superblock: %s", strerror(errno)); return -1; } squashfs_info sq; if (squashfs_parse_sb_buffer(buffer, &sq) < 0) { error("failed to parse superblock: %s", strerror(errno)); return -1; } *offset = sq.bytes_used_4K_padded; return 0; } /* reads the ext4 superblock and returns the size of the file system in `offset' */ static int get_ext4_size(fec_handle *f, uint64_t *offset) { check(f); check(f->size > 1024 + sizeof(ext4_super_block)); check(offset); ext4_super_block sb; if (fec_pread(f, &sb, sizeof(sb), 1024) != sizeof(sb)) { error("failed to read superblock: %s", strerror(errno)); return -1; } fs_info info; info.len = 0; /* only len is set to 0 to ask the device for real size. */ if (ext4_parse_sb(&sb, &info) != 0) { errno = EINVAL; return -1; } *offset = info.len; return 0; } /* attempts to determine file system size, if no fs type is specified in `f->flags', tries all supported types, and returns the size in `offset' */ static int get_fs_size(fec_handle *f, uint64_t *offset) { check(f); check(offset); if (f->flags & FEC_FS_EXT4) { return get_ext4_size(f, offset); } else if (f->flags & FEC_FS_SQUASH) { return get_squashfs_size(f, offset); } else { /* try all alternatives */ int rc = get_ext4_size(f, offset); if (rc == 0) { debug("found ext4fs"); return rc; } rc = get_squashfs_size(f, offset); if (rc == 0) { debug("found squashfs"); } return rc; } } /* locates, validates, and loads verity metadata from `f->fd' */ static int load_verity(fec_handle *f) { check(f); debug("size = %" PRIu64 ", flags = %d", f->data_size, f->flags); uint64_t offset = f->data_size - VERITY_METADATA_SIZE; /* verity header is at the end of the data area */ if (verity_parse_header(f, offset) == 0) { debug("found at %" PRIu64 " (start %" PRIu64 ")", offset, f->verity.hash_start); return 0; } debug("trying legacy formats"); /* legacy format at the end of the partition */ if (find_verity_offset(f, &offset) == 0 && verity_parse_header(f, offset) == 0) { debug("found at %" PRIu64 " (start %" PRIu64 ")", offset, f->verity.hash_start); return 0; } /* legacy format after the file system, but not at the end */ int rc = get_fs_size(f, &offset); if (rc == 0) { debug("file system size = %" PRIu64, offset); rc = verity_parse_header(f, offset); if (rc == 0) { debug("found at %" PRIu64 " (start %" PRIu64 ")", offset, f->verity.hash_start); } } return rc; } /* locates, validates, and loads ecc data from `f->fd' */ static int load_ecc(fec_handle *f) { check(f); debug("size = %" PRIu64, f->data_size); uint64_t offset = f->data_size - FEC_BLOCKSIZE; if (parse_ecc(f, offset) == 0) { debug("found at %" PRIu64 " (start %" PRIu64 ")", offset, f->ecc.start); return 0; } return -1; } /* sets `f->size' to the size of the file or block device */ static int get_size(fec_handle *f) { check(f); struct stat st; if (fstat(f->fd, &st) == -1) { error("fstat failed: %s", strerror(errno)); return -1; } if (S_ISBLK(st.st_mode)) { debug("block device"); if (ioctl(f->fd, BLKGETSIZE64, &f->size) == -1) { error("ioctl failed: %s", strerror(errno)); return -1; } } else if (S_ISREG(st.st_mode)) { debug("file"); f->size = st.st_size; } else { error("unsupported type %d", (int)st.st_mode); errno = EACCES; return -1; } return 0; } /* clears fec_handle fiels to safe values */ static void reset_handle(fec_handle *f) { f->fd = -1; f->flags = 0; f->mode = 0; f->errors = 0; f->data_size = 0; f->pos = 0; f->size = 0; memset(&f->ecc, 0, sizeof(f->ecc)); memset(&f->verity, 0, sizeof(f->verity)); } /* closes and flushes `f->fd' and releases any memory allocated for `f' */ int fec_close(struct fec_handle *f) { check(f); if (f->fd != -1) { if (f->mode & O_RDWR && fdatasync(f->fd) == -1) { warn("fdatasync failed: %s", strerror(errno)); } close(f->fd); } if (f->verity.hash) { delete[] f->verity.hash; } if (f->verity.salt) { delete[] f->verity.salt; } if (f->verity.table) { delete[] f->verity.table; } pthread_mutex_destroy(&f->mutex); reset_handle(f); delete f; return 0; } /* populates `data' from the internal data in `f', returns a value <0 if verity metadata is not available in `f->fd' */ int fec_verity_get_metadata(struct fec_handle *f, struct fec_verity_metadata *data) { check(f); check(data); if (!f->verity.metadata_start) { return -1; } check(f->data_size < f->size); check(f->data_size <= f->verity.hash_start); check(f->data_size <= f->verity.metadata_start); check(f->verity.table); data->disabled = f->verity.disabled; data->data_size = f->data_size; memcpy(data->signature, f->verity.header.signature, sizeof(data->signature)); memcpy(data->ecc_signature, f->verity.ecc_header.signature, sizeof(data->ecc_signature)); data->table = f->verity.table; data->table_length = f->verity.header.length; return 0; } /* populates `data' from the internal data in `f', returns a value <0 if ecc metadata is not available in `f->fd' */ int fec_ecc_get_metadata(struct fec_handle *f, struct fec_ecc_metadata *data) { check(f); check(data); if (!f->ecc.start) { return -1; } check(f->data_size < f->size); check(f->ecc.start >= f->data_size); check(f->ecc.start < f->size); check(f->ecc.start % FEC_BLOCKSIZE == 0) data->valid = f->ecc.valid; data->roots = f->ecc.roots; data->blocks = f->ecc.blocks; data->rounds = f->ecc.rounds; data->start = f->ecc.start; return 0; } /* populates `data' from the internal status in `f' */ int fec_get_status(struct fec_handle *f, struct fec_status *s) { check(f); check(s); s->flags = f->flags; s->mode = f->mode; s->errors = f->errors; s->data_size = f->data_size; s->size = f->size; return 0; } /* opens `path' using given options and returns a fec_handle in `handle' if successful */ int fec_open(struct fec_handle **handle, const char *path, int mode, int flags, int roots) { check(path); check(handle); check(roots > 0 && roots < FEC_RSM); debug("path = %s, mode = %d, flags = %d, roots = %d", path, mode, flags, roots); if (mode & (O_CREAT | O_TRUNC | O_EXCL | O_WRONLY)) { /* only reading and updating existing files is supported */ error("failed to open '%s': (unsupported mode %d)", path, mode); errno = EACCES; return -1; } fec::handle f(new (std::nothrow) fec_handle, fec_close); if (unlikely(!f)) { error("failed to allocate file handle"); errno = ENOMEM; return -1; } reset_handle(f.get()); f->mode = mode; f->ecc.roots = roots; f->ecc.rsn = FEC_RSM - roots; f->flags = flags; if (unlikely(pthread_mutex_init(&f->mutex, NULL) != 0)) { error("failed to create a mutex: %s", strerror(errno)); return -1; } f->fd = TEMP_FAILURE_RETRY(open(path, mode | O_CLOEXEC)); if (f->fd == -1) { error("failed to open '%s': %s", path, strerror(errno)); return -1; } if (get_size(f.get()) == -1) { error("failed to get size for '%s': %s", path, strerror(errno)); return -1; } f->data_size = f->size; /* until ecc and/or verity are loaded */ if (load_ecc(f.get()) == -1) { debug("error-correcting codes not found from '%s'", path); } if (load_verity(f.get()) == -1) { debug("verity metadata not found from '%s'", path); } *handle = f.release(); return 0; }