/* * Copyright (C) 2010 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. */ #define _FILE_OFFSET_BITS 64 #define _LARGEFILE64_SOURCE 1 #include #include #include #include #include #include #include #include #include #include "output_file.h" #include "sparse_format.h" #include "sparse_crc32.h" #ifndef USE_MINGW #include #define O_BINARY 0 #else #define ftruncate64 ftruncate #endif #if defined(__APPLE__) && defined(__MACH__) #define lseek64 lseek #define ftruncate64 ftruncate #define mmap64 mmap #define off64_t off_t #endif #ifdef __BIONIC__ extern void* __mmap2(void *, size_t, int, int, int, off_t); static inline void *mmap64(void *addr, size_t length, int prot, int flags, int fd, off64_t offset) { return __mmap2(addr, length, prot, flags, fd, offset >> 12); } #endif #define min(a, b) \ ({ typeof(a) _a = (a); typeof(b) _b = (b); (_a < _b) ? _a : _b; }) #define SPARSE_HEADER_MAJOR_VER 1 #define SPARSE_HEADER_MINOR_VER 0 #define SPARSE_HEADER_LEN (sizeof(sparse_header_t)) #define CHUNK_HEADER_LEN (sizeof(chunk_header_t)) #define container_of(inner, outer_t, elem) \ ((outer_t *)((char *)inner - offsetof(outer_t, elem))) struct output_file_ops { int (*open)(struct output_file *, int fd); int (*skip)(struct output_file *, int64_t); int (*pad)(struct output_file *, int64_t); int (*write)(struct output_file *, void *, int); void (*close)(struct output_file *); }; struct sparse_file_ops { int (*write_data_chunk)(struct output_file *out, unsigned int len, void *data); int (*write_fill_chunk)(struct output_file *out, unsigned int len, uint32_t fill_val); int (*write_skip_chunk)(struct output_file *out, int64_t len); int (*write_end_chunk)(struct output_file *out); }; struct output_file { int64_t cur_out_ptr; unsigned int chunk_cnt; uint32_t crc32; struct output_file_ops *ops; struct sparse_file_ops *sparse_ops; int use_crc; unsigned int block_size; int64_t len; char *zero_buf; uint32_t *fill_buf; char *buf; }; struct output_file_gz { struct output_file out; gzFile gz_fd; }; #define to_output_file_gz(_o) \ container_of((_o), struct output_file_gz, out) struct output_file_normal { struct output_file out; int fd; }; #define to_output_file_normal(_o) \ container_of((_o), struct output_file_normal, out) static int file_open(struct output_file *out, int fd) { struct output_file_normal *outn = to_output_file_normal(out); outn->fd = fd; return 0; } static int file_skip(struct output_file *out, int64_t cnt) { off64_t ret; struct output_file_normal *outn = to_output_file_normal(out); ret = lseek64(outn->fd, cnt, SEEK_CUR); if (ret < 0) { error_errno("lseek64"); return -1; } return 0; } static int file_pad(struct output_file *out, int64_t len) { int ret; struct output_file_normal *outn = to_output_file_normal(out); ret = ftruncate64(outn->fd, len); if (ret < 0) { return -errno; } return 0; } static int file_write(struct output_file *out, void *data, int len) { int ret; struct output_file_normal *outn = to_output_file_normal(out); ret = write(outn->fd, data, len); if (ret < 0) { error_errno("write"); return -1; } else if (ret < len) { error("incomplete write"); return -1; } return 0; } static void file_close(struct output_file *out) { struct output_file_normal *outn = to_output_file_normal(out); free(outn); } static struct output_file_ops file_ops = { .open = file_open, .skip = file_skip, .pad = file_pad, .write = file_write, .close = file_close, }; static int gz_file_open(struct output_file *out, int fd) { struct output_file_gz *outgz = to_output_file_gz(out); outgz->gz_fd = gzdopen(fd, "wb9"); if (!outgz->gz_fd) { error_errno("gzopen"); return -errno; } return 0; } static int gz_file_skip(struct output_file *out, int64_t cnt) { off64_t ret; struct output_file_gz *outgz = to_output_file_gz(out); ret = gzseek(outgz->gz_fd, cnt, SEEK_CUR); if (ret < 0) { error_errno("gzseek"); return -1; } return 0; } static int gz_file_pad(struct output_file *out, int64_t len) { off64_t ret; struct output_file_gz *outgz = to_output_file_gz(out); ret = gztell(outgz->gz_fd); if (ret < 0) { return -1; } if (ret >= len) { return 0; } ret = gzseek(outgz->gz_fd, len - 1, SEEK_SET); if (ret < 0) { return -1; } gzwrite(outgz->gz_fd, "", 1); return 0; } static int gz_file_write(struct output_file *out, void *data, int len) { int ret; struct output_file_gz *outgz = to_output_file_gz(out); ret = gzwrite(outgz->gz_fd, data, len); if (ret < 0) { error_errno("gzwrite"); return -1; } else if (ret < len) { error("incomplete gzwrite"); return -1; } return 0; } static void gz_file_close(struct output_file *out) { struct output_file_gz *outgz = to_output_file_gz(out); gzclose(outgz->gz_fd); free(outgz); } static struct output_file_ops gz_file_ops = { .open = gz_file_open, .skip = gz_file_skip, .pad = gz_file_pad, .write = gz_file_write, .close = gz_file_close, }; int read_all(int fd, void *buf, size_t len) { size_t total = 0; int ret; char *ptr = buf; while (total < len) { ret = read(fd, ptr, len - total); if (ret < 0) return -errno; if (ret == 0) return -EINVAL; ptr += ret; total += ret; } return 0; } static int write_sparse_skip_chunk(struct output_file *out, int64_t skip_len) { chunk_header_t chunk_header; int ret, chunk; if (skip_len % out->block_size) { error("don't care size %llu is not a multiple of the block size %u", skip_len, out->block_size); return -1; } /* We are skipping data, so emit a don't care chunk. */ chunk_header.chunk_type = CHUNK_TYPE_DONT_CARE; chunk_header.reserved1 = 0; chunk_header.chunk_sz = skip_len / out->block_size; chunk_header.total_sz = CHUNK_HEADER_LEN; ret = out->ops->write(out, &chunk_header, sizeof(chunk_header)); if (ret < 0) return -1; out->cur_out_ptr += skip_len; out->chunk_cnt++; return 0; } static int write_sparse_fill_chunk(struct output_file *out, unsigned int len, uint32_t fill_val) { chunk_header_t chunk_header; int rnd_up_len, zero_len, count; int ret; unsigned int i; /* Round up the fill length to a multiple of the block size */ rnd_up_len = ALIGN(len, out->block_size); /* Finally we can safely emit a chunk of data */ chunk_header.chunk_type = CHUNK_TYPE_FILL; chunk_header.reserved1 = 0; chunk_header.chunk_sz = rnd_up_len / out->block_size; chunk_header.total_sz = CHUNK_HEADER_LEN + sizeof(fill_val); ret = out->ops->write(out, &chunk_header, sizeof(chunk_header)); if (ret < 0) return -1; ret = out->ops->write(out, &fill_val, sizeof(fill_val)); if (ret < 0) return -1; if (out->use_crc) { count = out->block_size / sizeof(uint32_t); while (count--) out->crc32 = sparse_crc32(out->crc32, &fill_val, sizeof(uint32_t)); } out->cur_out_ptr += rnd_up_len; out->chunk_cnt++; return 0; } static int write_sparse_data_chunk(struct output_file *out, unsigned int len, void *data) { chunk_header_t chunk_header; int rnd_up_len, zero_len; int ret; /* Round up the data length to a multiple of the block size */ rnd_up_len = ALIGN(len, out->block_size); zero_len = rnd_up_len - len; /* Finally we can safely emit a chunk of data */ chunk_header.chunk_type = CHUNK_TYPE_RAW; chunk_header.reserved1 = 0; chunk_header.chunk_sz = rnd_up_len / out->block_size; chunk_header.total_sz = CHUNK_HEADER_LEN + rnd_up_len; ret = out->ops->write(out, &chunk_header, sizeof(chunk_header)); if (ret < 0) return -1; ret = out->ops->write(out, data, len); if (ret < 0) return -1; if (zero_len) { ret = out->ops->write(out, out->zero_buf, zero_len); if (ret < 0) return -1; } if (out->use_crc) { out->crc32 = sparse_crc32(out->crc32, data, len); if (zero_len) out->crc32 = sparse_crc32(out->crc32, out->zero_buf, zero_len); } out->cur_out_ptr += rnd_up_len; out->chunk_cnt++; return 0; } int write_sparse_end_chunk(struct output_file *out) { chunk_header_t chunk_header; int ret; if (out->use_crc) { chunk_header.chunk_type = CHUNK_TYPE_CRC32; chunk_header.reserved1 = 0; chunk_header.chunk_sz = 0; chunk_header.total_sz = CHUNK_HEADER_LEN + 4; ret = out->ops->write(out, &chunk_header, sizeof(chunk_header)); if (ret < 0) { return ret; } out->ops->write(out, &out->crc32, 4); if (ret < 0) { return ret; } out->chunk_cnt++; } return 0; } static struct sparse_file_ops sparse_file_ops = { .write_data_chunk = write_sparse_data_chunk, .write_fill_chunk = write_sparse_fill_chunk, .write_skip_chunk = write_sparse_skip_chunk, .write_end_chunk = write_sparse_end_chunk, }; static int write_normal_data_chunk(struct output_file *out, unsigned int len, void *data) { int ret; unsigned int rnd_up_len = ALIGN(len, out->block_size); ret = out->ops->write(out, data, len); if (ret < 0) { return ret; } if (rnd_up_len > len) { ret = out->ops->skip(out, rnd_up_len - len); } return ret; } static int write_normal_fill_chunk(struct output_file *out, unsigned int len, uint32_t fill_val) { int ret; unsigned int i; unsigned int write_len; /* Initialize fill_buf with the fill_val */ for (i = 0; i < out->block_size / sizeof(uint32_t); i++) { out->fill_buf[i] = fill_val; } while (len) { write_len = min(len, out->block_size); ret = out->ops->write(out, out->fill_buf, write_len); if (ret < 0) { return ret; } len -= write_len; } return 0; } static int write_normal_skip_chunk(struct output_file *out, int64_t len) { return out->ops->skip(out, len); } int write_normal_end_chunk(struct output_file *out) { return out->ops->pad(out, out->len); } static struct sparse_file_ops normal_file_ops = { .write_data_chunk = write_normal_data_chunk, .write_fill_chunk = write_normal_fill_chunk, .write_skip_chunk = write_normal_skip_chunk, .write_end_chunk = write_normal_end_chunk, }; void close_output_file(struct output_file *out) { int ret; out->sparse_ops->write_end_chunk(out); out->ops->close(out); } static int output_file_init(struct output_file *out, int block_size, int64_t len, bool sparse, int chunks, bool crc) { int ret; out->len = len; out->block_size = block_size; out->cur_out_ptr = 0ll; out->chunk_cnt = 0; out->crc32 = 0; out->use_crc = crc; out->zero_buf = calloc(block_size, 1); if (!out->zero_buf) { error_errno("malloc zero_buf"); return -ENOMEM; } out->fill_buf = calloc(block_size, 1); if (!out->fill_buf) { error_errno("malloc fill_buf"); ret = -ENOMEM; goto err_fill_buf; } if (sparse) { out->sparse_ops = &sparse_file_ops; } else { out->sparse_ops = &normal_file_ops; } if (sparse) { sparse_header_t sparse_header = { .magic = SPARSE_HEADER_MAGIC, .major_version = SPARSE_HEADER_MAJOR_VER, .minor_version = SPARSE_HEADER_MINOR_VER, .file_hdr_sz = SPARSE_HEADER_LEN, .chunk_hdr_sz = CHUNK_HEADER_LEN, .blk_sz = out->block_size, .total_blks = out->len / out->block_size, .total_chunks = chunks, .image_checksum = 0 }; if (out->use_crc) { sparse_header.total_chunks++; } ret = out->ops->write(out, &sparse_header, sizeof(sparse_header)); if (ret < 0) { goto err_write; } } return 0; err_write: free(out->fill_buf); err_fill_buf: free(out->zero_buf); return ret; } static struct output_file *output_file_new_gz(void) { struct output_file_gz *outgz = calloc(1, sizeof(struct output_file_gz)); if (!outgz) { error_errno("malloc struct outgz"); return NULL; } outgz->out.ops = &gz_file_ops; return &outgz->out; } static struct output_file *output_file_new_normal(void) { struct output_file_normal *outn = calloc(1, sizeof(struct output_file_normal)); if (!outn) { error_errno("malloc struct outn"); return NULL; } outn->out.ops = &file_ops; return &outn->out; } struct output_file *open_output_fd(int fd, unsigned int block_size, int64_t len, int gz, int sparse, int chunks, int crc) { int ret; struct output_file *out; if (gz) { out = output_file_new_gz(); } else { out = output_file_new_normal(); } out->ops->open(out, fd); ret = output_file_init(out, block_size, len, sparse, chunks, crc); if (ret < 0) { free(out); return NULL; } return out; } /* Write a contiguous region of data blocks from a memory buffer */ int write_data_chunk(struct output_file *out, unsigned int len, void *data) { return out->sparse_ops->write_data_chunk(out, len, data); } /* Write a contiguous region of data blocks with a fill value */ int write_fill_chunk(struct output_file *out, unsigned int len, uint32_t fill_val) { return out->sparse_ops->write_fill_chunk(out, len, fill_val); } int write_fd_chunk(struct output_file *out, unsigned int len, int fd, int64_t offset) { int ret; int64_t aligned_offset; int aligned_diff; int buffer_size; char *ptr; aligned_offset = offset & ~(4096 - 1); aligned_diff = offset - aligned_offset; buffer_size = len + aligned_diff; #ifndef USE_MINGW char *data = mmap64(NULL, buffer_size, PROT_READ, MAP_SHARED, fd, aligned_offset); if (data == MAP_FAILED) { return -errno; } ptr = data + aligned_diff; #else off64_t pos; char *data = malloc(len); if (!data) { return -errno; } pos = lseek64(fd, offset, SEEK_SET); if (pos < 0) { return -errno; } ret = read_all(fd, data, len); if (ret < 0) { return ret; } ptr = data; #endif ret = out->sparse_ops->write_data_chunk(out, len, ptr); #ifndef USE_MINGW munmap(data, buffer_size); #else free(data); #endif return ret; } /* Write a contiguous region of data blocks from a file */ int write_file_chunk(struct output_file *out, unsigned int len, const char *file, int64_t offset) { int ret; int file_fd = open(file, O_RDONLY | O_BINARY); if (file_fd < 0) { return -errno; } ret = write_fd_chunk(out, len, file_fd, offset); close(file_fd); return ret; } int write_skip_chunk(struct output_file *out, int64_t len) { return out->sparse_ops->write_skip_chunk(out, len); }