/* The MIT License Copyright (c) 2008 Broad Institute / Massachusetts Institute of Technology 2011, 2012 Attractive Chaos Copyright (C) 2009, 2013-2016 Genome Research Ltd Permission is hereby granted, free of charge, to any person obtaining a copy of this software and associated documentation files (the "Software"), to deal in the Software without restriction, including without limitation the rights to use, copy, modify, merge, publish, distribute, sublicense, and/or sell copies of the Software, and to permit persons to whom the Software is furnished to do so, subject to the following conditions: The above copyright notice and this permission notice shall be included in all copies or substantial portions of the Software. THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, EXPRESS OR IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF MERCHANTABILITY, FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT. IN NO EVENT SHALL THE AUTHORS OR COPYRIGHT HOLDERS BE LIABLE FOR ANY CLAIM, DAMAGES OR OTHER LIABILITY, WHETHER IN AN ACTION OF CONTRACT, TORT OR OTHERWISE, ARISING FROM, OUT OF OR IN CONNECTION WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS IN THE SOFTWARE. */ #include #include #include #include #include #include #include #include #include #include #include "htslib/hts.h" #include "htslib/bgzf.h" #include "htslib/hfile.h" #define BGZF_CACHE #define BGZF_MT #define BLOCK_HEADER_LENGTH 18 #define BLOCK_FOOTER_LENGTH 8 /* BGZF/GZIP header (speciallized from RFC 1952; little endian): +---+---+---+---+---+---+---+---+---+---+---+---+---+---+---+---+---+---+ | 31|139| 8| 4| 0| 0|255| 6| 66| 67| 2|BLK_LEN| +---+---+---+---+---+---+---+---+---+---+---+---+---+---+---+---+---+---+ BGZF extension: ^ ^ ^ ^ | | | | FLG.EXTRA XLEN B C BGZF format is compatible with GZIP. It limits the size of each compressed block to 2^16 bytes and adds and an extra "BC" field in the gzip header which records the size. */ static const uint8_t g_magic[19] = "\037\213\010\4\0\0\0\0\0\377\6\0\102\103\2\0\0\0"; #ifdef BGZF_CACHE typedef struct { int size; uint8_t *block; int64_t end_offset; } cache_t; #include "htslib/khash.h" KHASH_MAP_INIT_INT64(cache, cache_t) #endif typedef struct { uint64_t uaddr; // offset w.r.t. uncompressed data uint64_t caddr; // offset w.r.t. compressed data } bgzidx1_t; struct __bgzidx_t { int noffs, moffs; // the size of the index, n:used, m:allocated bgzidx1_t *offs; // offsets uint64_t ublock_addr; // offset of the current block (uncompressed data) }; void bgzf_index_destroy(BGZF *fp); int bgzf_index_add_block(BGZF *fp); static inline void packInt16(uint8_t *buffer, uint16_t value) { buffer[0] = value; buffer[1] = value >> 8; } static inline int unpackInt16(const uint8_t *buffer) { return buffer[0] | buffer[1] << 8; } static inline void packInt32(uint8_t *buffer, uint32_t value) { buffer[0] = value; buffer[1] = value >> 8; buffer[2] = value >> 16; buffer[3] = value >> 24; } static const char *bgzf_zerr(int errnum, z_stream *zs) { static char buffer[32]; /* Return zs->msg if available. zlib doesn't set this very reliably. Looking at the source suggests that it may get set to a useful message for deflateInit2, inflateInit2 and inflate when it returns Z_DATA_ERROR. For inflate with other return codes, deflate, deflateEnd and inflateEnd it doesn't appear to be useful. For the likely non-useful cases, the caller should pass NULL into zs. */ if (zs && zs->msg) return zs->msg; // gzerror OF((gzFile file, int *errnum) switch (errnum) { case Z_ERRNO: return strerror(errno); case Z_STREAM_ERROR: return "invalid parameter/compression level, or inconsistent stream state"; case Z_DATA_ERROR: return "invalid or incomplete IO"; case Z_MEM_ERROR: return "out of memory"; case Z_BUF_ERROR: return "progress temporarily not possible, or in() / out() returned an error"; case Z_VERSION_ERROR: return "zlib version mismatch"; case Z_OK: // 0: maybe gzgets error Z_NULL default: snprintf(buffer, sizeof(buffer), "[%d] unknown", errnum); return buffer; // FIXME: Not thread-safe. } } static BGZF *bgzf_read_init(hFILE *hfpr) { BGZF *fp; uint8_t magic[18]; ssize_t n = hpeek(hfpr, magic, 18); if (n < 0) return NULL; fp = (BGZF*)calloc(1, sizeof(BGZF)); if (fp == NULL) return NULL; fp->is_write = 0; fp->is_compressed = (n==2 && magic[0]==0x1f && magic[1]==0x8b); fp->uncompressed_block = malloc(BGZF_MAX_BLOCK_SIZE); fp->compressed_block = malloc(BGZF_MAX_BLOCK_SIZE); fp->is_compressed = (n==18 && magic[0]==0x1f && magic[1]==0x8b) ? 1 : 0; fp->is_gzip = ( !fp->is_compressed || ((magic[3]&4) && memcmp(&magic[12], "BC\2\0",4)==0) ) ? 0 : 1; #ifdef BGZF_CACHE fp->cache = kh_init(cache); #endif return fp; } // get the compress level from the mode string: compress_level==-1 for the default level, -2 plain uncompressed static int mode2level(const char *__restrict mode) { int i, compress_level = -1; for (i = 0; mode[i]; ++i) if (mode[i] >= '0' && mode[i] <= '9') break; if (mode[i]) compress_level = (int)mode[i] - '0'; if (strchr(mode, 'u')) compress_level = -2; return compress_level; } static BGZF *bgzf_write_init(const char *mode) { BGZF *fp; fp = (BGZF*)calloc(1, sizeof(BGZF)); if (fp == NULL) goto mem_fail; fp->is_write = 1; int compress_level = mode2level(mode); if ( compress_level==-2 ) { fp->is_compressed = 0; return fp; } fp->is_compressed = 1; fp->uncompressed_block = malloc(BGZF_MAX_BLOCK_SIZE); if (fp->uncompressed_block == NULL) goto mem_fail; fp->compressed_block = malloc(BGZF_MAX_BLOCK_SIZE); if (fp->compressed_block == NULL) goto mem_fail; fp->compress_level = compress_level < 0? Z_DEFAULT_COMPRESSION : compress_level; // Z_DEFAULT_COMPRESSION==-1 if (fp->compress_level > 9) fp->compress_level = Z_DEFAULT_COMPRESSION; if ( strchr(mode,'g') ) { // gzip output fp->is_gzip = 1; fp->gz_stream = (z_stream*)calloc(1,sizeof(z_stream)); if (fp->gz_stream == NULL) goto mem_fail; fp->gz_stream->zalloc = NULL; fp->gz_stream->zfree = NULL; fp->gz_stream->msg = NULL; int ret = deflateInit2(fp->gz_stream, fp->compress_level, Z_DEFLATED, 15|16, 8, Z_DEFAULT_STRATEGY); if (ret!=Z_OK) { if (hts_verbose >= 1) { fprintf(stderr, "[E::%s] deflateInit2 failed: %s\n", __func__, bgzf_zerr(ret, fp->gz_stream)); } goto fail; } } return fp; mem_fail: if (hts_verbose >= 1) { fprintf(stderr, "[E::%s] %s\n", __func__, strerror(errno)); } fail: if (fp != NULL) { free(fp->uncompressed_block); free(fp->compressed_block); free(fp->gz_stream); free(fp); } return NULL; } BGZF *bgzf_open(const char *path, const char *mode) { BGZF *fp = 0; assert(compressBound(BGZF_BLOCK_SIZE) < BGZF_MAX_BLOCK_SIZE); if (strchr(mode, 'r')) { hFILE *fpr; if ((fpr = hopen(path, mode)) == 0) return 0; fp = bgzf_read_init(fpr); if (fp == 0) { hclose_abruptly(fpr); return NULL; } fp->fp = fpr; } else if (strchr(mode, 'w') || strchr(mode, 'a')) { hFILE *fpw; if ((fpw = hopen(path, mode)) == 0) return 0; fp = bgzf_write_init(mode); if (fp == NULL) return NULL; fp->fp = fpw; } else { errno = EINVAL; return 0; } fp->is_be = ed_is_big(); return fp; } BGZF *bgzf_dopen(int fd, const char *mode) { BGZF *fp = 0; assert(compressBound(BGZF_BLOCK_SIZE) < BGZF_MAX_BLOCK_SIZE); if (strchr(mode, 'r')) { hFILE *fpr; if ((fpr = hdopen(fd, mode)) == 0) return 0; fp = bgzf_read_init(fpr); if (fp == 0) { hclose_abruptly(fpr); return NULL; } // FIXME this closes fd fp->fp = fpr; } else if (strchr(mode, 'w') || strchr(mode, 'a')) { hFILE *fpw; if ((fpw = hdopen(fd, mode)) == 0) return 0; fp = bgzf_write_init(mode); if (fp == NULL) return NULL; fp->fp = fpw; } else { errno = EINVAL; return 0; } fp->is_be = ed_is_big(); return fp; } BGZF *bgzf_hopen(hFILE *hfp, const char *mode) { BGZF *fp = NULL; assert(compressBound(BGZF_BLOCK_SIZE) < BGZF_MAX_BLOCK_SIZE); if (strchr(mode, 'r')) { fp = bgzf_read_init(hfp); if (fp == NULL) return NULL; } else if (strchr(mode, 'w') || strchr(mode, 'a')) { fp = bgzf_write_init(mode); if (fp == NULL) return NULL; } else { errno = EINVAL; return 0; } fp->fp = hfp; fp->is_be = ed_is_big(); return fp; } int bgzf_compress(void *_dst, size_t *dlen, const void *src, size_t slen, int level) { uint32_t crc; z_stream zs; uint8_t *dst = (uint8_t*)_dst; // compress the body zs.zalloc = NULL; zs.zfree = NULL; zs.msg = NULL; zs.next_in = (Bytef*)src; zs.avail_in = slen; zs.next_out = dst + BLOCK_HEADER_LENGTH; zs.avail_out = *dlen - BLOCK_HEADER_LENGTH - BLOCK_FOOTER_LENGTH; int ret = deflateInit2(&zs, level, Z_DEFLATED, -15, 8, Z_DEFAULT_STRATEGY); // -15 to disable zlib header/footer if (ret!=Z_OK) { if (hts_verbose >= 1) { fprintf(stderr, "[E::%s] deflateInit2 failed: %s\n", __func__, bgzf_zerr(ret, &zs)); } return -1; } if ((ret = deflate(&zs, Z_FINISH)) != Z_STREAM_END) { if (hts_verbose >= 1) { fprintf(stderr, "[E::%s] deflate failed: %s\n", __func__, bgzf_zerr(ret, ret == Z_DATA_ERROR ? &zs : NULL)); } return -1; } if ((ret = deflateEnd(&zs)) != Z_OK) { if (hts_verbose >= 1) { fprintf(stderr, "[E::%s] deflateEnd failed: %s\n", __func__, bgzf_zerr(ret, NULL)); } return -1; } *dlen = zs.total_out + BLOCK_HEADER_LENGTH + BLOCK_FOOTER_LENGTH; // write the header memcpy(dst, g_magic, BLOCK_HEADER_LENGTH); // the last two bytes are a place holder for the length of the block packInt16(&dst[16], *dlen - 1); // write the compressed length; -1 to fit 2 bytes // write the footer crc = crc32(crc32(0L, NULL, 0L), (Bytef*)src, slen); packInt32((uint8_t*)&dst[*dlen - 8], crc); packInt32((uint8_t*)&dst[*dlen - 4], slen); return 0; } static int bgzf_gzip_compress(BGZF *fp, void *_dst, size_t *dlen, const void *src, size_t slen, int level) { uint8_t *dst = (uint8_t*)_dst; z_stream *zs = fp->gz_stream; int flush = slen ? Z_NO_FLUSH : Z_FINISH; zs->next_in = (Bytef*)src; zs->avail_in = slen; zs->next_out = dst; zs->avail_out = *dlen; int ret = deflate(zs, flush); if (ret == Z_STREAM_ERROR) { if (hts_verbose >= 1) { fprintf(stderr, "[E::%s] deflate failed: %s\n", __func__, bgzf_zerr(ret, NULL)); } return -1; } *dlen = *dlen - zs->avail_out; return 0; } // Deflate the block in fp->uncompressed_block into fp->compressed_block. Also adds an extra field that stores the compressed block length. static int deflate_block(BGZF *fp, int block_length) { size_t comp_size = BGZF_MAX_BLOCK_SIZE; int ret; if ( !fp->is_gzip ) ret = bgzf_compress(fp->compressed_block, &comp_size, fp->uncompressed_block, block_length, fp->compress_level); else ret = bgzf_gzip_compress(fp, fp->compressed_block, &comp_size, fp->uncompressed_block, block_length, fp->compress_level); if ( ret != 0 ) { if (hts_verbose >= 3) { fprintf(stderr, "[E::%s] compression error %d\n", __func__, ret); } fp->errcode |= BGZF_ERR_ZLIB; return -1; } fp->block_offset = 0; return comp_size; } // Inflate the block in fp->compressed_block into fp->uncompressed_block static int inflate_block(BGZF* fp, int block_length) { z_stream zs; zs.zalloc = NULL; zs.zfree = NULL; zs.msg = NULL; zs.next_in = (Bytef*)fp->compressed_block + 18; zs.avail_in = block_length - 16; zs.next_out = (Bytef*)fp->uncompressed_block; zs.avail_out = BGZF_MAX_BLOCK_SIZE; int ret = inflateInit2(&zs, -15); if (ret != Z_OK) { if (hts_verbose >= 1) { fprintf(stderr, "[E::%s] inflateInit2 failed: %s\n", __func__, bgzf_zerr(ret, &zs)); } fp->errcode |= BGZF_ERR_ZLIB; return -1; } if ((ret = inflate(&zs, Z_FINISH)) != Z_STREAM_END) { if (hts_verbose >= 1) { fprintf(stderr, "[E::%s] inflate failed: %s\n", __func__, bgzf_zerr(ret, ret == Z_DATA_ERROR ? &zs : NULL)); } if ((ret = inflateEnd(&zs)) != Z_OK) { if (hts_verbose >= 2) { fprintf(stderr, "[E::%s] inflateEnd failed: %s\n", __func__, bgzf_zerr(ret, NULL)); } } fp->errcode |= BGZF_ERR_ZLIB; return -1; } if ((ret = inflateEnd(&zs)) != Z_OK) { if (hts_verbose >= 1) { fprintf(stderr, "[E::%s] inflateEnd failed: %s\n", __func__, bgzf_zerr(ret, NULL)); } fp->errcode |= BGZF_ERR_ZLIB; return -1; } return zs.total_out; } static int inflate_gzip_block(BGZF *fp, int cached) { int ret = Z_OK; do { if ( !cached && fp->gz_stream->avail_out!=0 ) { fp->gz_stream->avail_in = hread(fp->fp, fp->compressed_block, BGZF_BLOCK_SIZE); if ( fp->gz_stream->avail_in<=0 ) return fp->gz_stream->avail_in; if ( fp->gz_stream->avail_in==0 ) break; fp->gz_stream->next_in = fp->compressed_block; } else cached = 0; do { fp->gz_stream->next_out = (Bytef*)fp->uncompressed_block + fp->block_offset; fp->gz_stream->avail_out = BGZF_MAX_BLOCK_SIZE - fp->block_offset; fp->gz_stream->msg = NULL; ret = inflate(fp->gz_stream, Z_NO_FLUSH); if ( ret==Z_BUF_ERROR ) continue; // non-critical error if ( ret<0 ) { if (hts_verbose >= 1) { fprintf(stderr, "[E::%s] inflate failed: %s\n", __func__, bgzf_zerr(ret, ret == Z_DATA_ERROR ? fp->gz_stream : NULL)); } fp->errcode |= BGZF_ERR_ZLIB; return -1; } unsigned int have = BGZF_MAX_BLOCK_SIZE - fp->gz_stream->avail_out; if ( have ) return have; } while ( fp->gz_stream->avail_out == 0 ); } while (ret != Z_STREAM_END); return BGZF_MAX_BLOCK_SIZE - fp->gz_stream->avail_out; } // Returns: 0 on success (BGZF header); -1 on non-BGZF GZIP header; -2 on error static int check_header(const uint8_t *header) { if ( header[0] != 31 || header[1] != 139 || header[2] != 8 ) return -2; return ((header[3] & 4) != 0 && unpackInt16((uint8_t*)&header[10]) == 6 && header[12] == 'B' && header[13] == 'C' && unpackInt16((uint8_t*)&header[14]) == 2) ? 0 : -1; } #ifdef BGZF_CACHE static void free_cache(BGZF *fp) { khint_t k; khash_t(cache) *h = (khash_t(cache)*)fp->cache; if (fp->is_write) return; for (k = kh_begin(h); k < kh_end(h); ++k) if (kh_exist(h, k)) free(kh_val(h, k).block); kh_destroy(cache, h); } static int load_block_from_cache(BGZF *fp, int64_t block_address) { khint_t k; cache_t *p; khash_t(cache) *h = (khash_t(cache)*)fp->cache; k = kh_get(cache, h, block_address); if (k == kh_end(h)) return 0; p = &kh_val(h, k); if (fp->block_length != 0) fp->block_offset = 0; fp->block_address = block_address; fp->block_length = p->size; memcpy(fp->uncompressed_block, p->block, BGZF_MAX_BLOCK_SIZE); if ( hseek(fp->fp, p->end_offset, SEEK_SET) < 0 ) { // todo: move the error up fprintf(stderr,"Could not hseek to %"PRId64"\n", p->end_offset); exit(1); } return p->size; } static void cache_block(BGZF *fp, int size) { int ret; khint_t k; cache_t *p; khash_t(cache) *h = (khash_t(cache)*)fp->cache; if (BGZF_MAX_BLOCK_SIZE >= fp->cache_size) return; if ((kh_size(h) + 1) * BGZF_MAX_BLOCK_SIZE > (uint32_t)fp->cache_size) { /* A better way would be to remove the oldest block in the * cache, but here we remove a random one for simplicity. This * should not have a big impact on performance. */ for (k = kh_begin(h); k < kh_end(h); ++k) if (kh_exist(h, k)) break; if (k < kh_end(h)) { free(kh_val(h, k).block); kh_del(cache, h, k); } } k = kh_put(cache, h, fp->block_address, &ret); if (ret == 0) return; // if this happens, a bug! p = &kh_val(h, k); p->size = fp->block_length; p->end_offset = fp->block_address + size; p->block = (uint8_t*)malloc(BGZF_MAX_BLOCK_SIZE); memcpy(kh_val(h, k).block, fp->uncompressed_block, BGZF_MAX_BLOCK_SIZE); } #else static void free_cache(BGZF *fp) {} static int load_block_from_cache(BGZF *fp, int64_t block_address) {return 0;} static void cache_block(BGZF *fp, int size) {} #endif int bgzf_read_block(BGZF *fp) { uint8_t header[BLOCK_HEADER_LENGTH], *compressed_block; int count, size = 0, block_length, remaining; // Reading an uncompressed file if ( !fp->is_compressed ) { count = hread(fp->fp, fp->uncompressed_block, BGZF_MAX_BLOCK_SIZE); if (count < 0) // Error { fp->errcode |= BGZF_ERR_IO; return -1; } else if (count == 0) // EOF { fp->block_length = 0; return 0; } if (fp->block_length != 0) fp->block_offset = 0; fp->block_address += count; fp->block_length = count; return 0; } // Reading compressed file int64_t block_address; block_address = htell(fp->fp); if ( fp->is_gzip && fp->gz_stream ) // is this is a initialized gzip stream? { count = inflate_gzip_block(fp, 0); if ( count<0 ) { fp->errcode |= BGZF_ERR_ZLIB; return -1; } fp->block_length = count; fp->block_address = block_address; return 0; } if (fp->cache_size && load_block_from_cache(fp, block_address)) return 0; count = hread(fp->fp, header, sizeof(header)); if (count == 0) { // no data read fp->block_length = 0; return 0; } int ret; if ( count != sizeof(header) || (ret=check_header(header))==-2 ) { fp->errcode |= BGZF_ERR_HEADER; return -1; } if ( ret==-1 ) { // GZIP, not BGZF uint8_t *cblock = (uint8_t*)fp->compressed_block; memcpy(cblock, header, sizeof(header)); count = hread(fp->fp, cblock+sizeof(header), BGZF_BLOCK_SIZE - sizeof(header)) + sizeof(header); int nskip = 10; // Check optional fields to skip: FLG.FNAME,FLG.FCOMMENT,FLG.FHCRC,FLG.FEXTRA // Note: Some of these fields are untested, I did not have appropriate data available if ( header[3] & 0x4 ) // FLG.FEXTRA { nskip += unpackInt16(&cblock[nskip]) + 2; } if ( header[3] & 0x8 ) // FLG.FNAME { while ( nskip= count ) { fp->errcode |= BGZF_ERR_HEADER; return -1; } fp->is_gzip = 1; fp->gz_stream = (z_stream*) calloc(1,sizeof(z_stream)); int ret = inflateInit2(fp->gz_stream, -15); if (ret != Z_OK) { if (hts_verbose >= 1) { fprintf(stderr, "[E::%s] inflateInit2 failed: %s", __func__, bgzf_zerr(ret, fp->gz_stream)); } fp->errcode |= BGZF_ERR_ZLIB; return -1; } fp->gz_stream->avail_in = count - nskip; fp->gz_stream->next_in = cblock + nskip; count = inflate_gzip_block(fp, 1); if ( count<0 ) { fp->errcode |= BGZF_ERR_ZLIB; return -1; } fp->block_length = count; fp->block_address = block_address; if ( fp->idx_build_otf ) return -1; // cannot build index for gzip return 0; } size = count; block_length = unpackInt16((uint8_t*)&header[16]) + 1; // +1 because when writing this number, we used "-1" compressed_block = (uint8_t*)fp->compressed_block; memcpy(compressed_block, header, BLOCK_HEADER_LENGTH); remaining = block_length - BLOCK_HEADER_LENGTH; count = hread(fp->fp, &compressed_block[BLOCK_HEADER_LENGTH], remaining); if (count != remaining) { fp->errcode |= BGZF_ERR_IO; return -1; } size += count; if ((count = inflate_block(fp, block_length)) < 0) { if (hts_verbose >= 2) fprintf(stderr, "[E::%s] inflate_block error %d\n", __func__, count); fp->errcode |= BGZF_ERR_ZLIB; return -1; } if (fp->block_length != 0) fp->block_offset = 0; // Do not reset offset if this read follows a seek. fp->block_address = block_address; fp->block_length = count; if ( fp->idx_build_otf ) { bgzf_index_add_block(fp); fp->idx->ublock_addr += count; } cache_block(fp, size); return 0; } ssize_t bgzf_read(BGZF *fp, void *data, size_t length) { ssize_t bytes_read = 0; uint8_t *output = (uint8_t*)data; if (length <= 0) return 0; assert(fp->is_write == 0); while (bytes_read < length) { int copy_length, available = fp->block_length - fp->block_offset; uint8_t *buffer; if (available <= 0) { int ret = bgzf_read_block(fp); if (ret != 0) { if (hts_verbose >= 2) { fprintf(stderr, "[E::%s] bgzf_read_block error %d after %zd of %zu bytes\n", __func__, ret, bytes_read, length); } fp->errcode |= BGZF_ERR_ZLIB; return -1; } available = fp->block_length - fp->block_offset; if (available <= 0) break; } copy_length = length - bytes_read < available? length - bytes_read : available; buffer = (uint8_t*)fp->uncompressed_block; memcpy(output, buffer + fp->block_offset, copy_length); fp->block_offset += copy_length; output += copy_length; bytes_read += copy_length; } if (fp->block_offset == fp->block_length) { fp->block_address = htell(fp->fp); fp->block_offset = fp->block_length = 0; } fp->uncompressed_address += bytes_read; return bytes_read; } ssize_t bgzf_raw_read(BGZF *fp, void *data, size_t length) { return hread(fp->fp, data, length); } #ifdef BGZF_MT typedef struct { struct bgzf_mtaux_t *mt; void *buf; int i, errcode, toproc, compress_level; } worker_t; typedef struct bgzf_mtaux_t { int n_threads, n_blks, curr, done; volatile int proc_cnt; void **blk; int *len; worker_t *w; pthread_t *tid; pthread_mutex_t lock; pthread_cond_t cv; } mtaux_t; static int worker_aux(worker_t *w) { int i, stop = 0; // wait for condition: to process or all done pthread_mutex_lock(&w->mt->lock); while (!w->toproc && !w->mt->done) pthread_cond_wait(&w->mt->cv, &w->mt->lock); if (w->mt->done) stop = 1; w->toproc = 0; pthread_mutex_unlock(&w->mt->lock); if (stop) return 1; // to quit the thread w->errcode = 0; for (i = w->i; i < w->mt->curr; i += w->mt->n_threads) { size_t clen = BGZF_MAX_BLOCK_SIZE; int ret = bgzf_compress(w->buf, &clen, w->mt->blk[i], w->mt->len[i], w->compress_level); if (ret != 0) { if (hts_verbose >= 2) fprintf(stderr, "[E::%s] bgzf_compress error %d\n", __func__, ret); w->errcode |= BGZF_ERR_ZLIB; // Report error // We're not going to do any more, so set remaining lengths to 0 for (; i < w->mt->curr; i += w->mt->n_threads) w->mt->len[i] = 0; break; // Give up } else { memcpy(w->mt->blk[i], w->buf, clen); w->mt->len[i] = clen; } } __sync_fetch_and_add(&w->mt->proc_cnt, 1); return 0; } static void *mt_worker(void *data) { while (worker_aux((worker_t*)data) == 0); return 0; } int bgzf_mt(BGZF *fp, int n_threads, int n_sub_blks) { int i; mtaux_t *mt; pthread_attr_t attr; if (!fp->is_write || fp->mt || n_threads <= 1) return -1; mt = (mtaux_t*)calloc(1, sizeof(mtaux_t)); mt->n_threads = n_threads; mt->n_blks = n_threads * n_sub_blks; mt->len = (int*)calloc(mt->n_blks, sizeof(int)); mt->blk = (void**)calloc(mt->n_blks, sizeof(void*)); for (i = 0; i < mt->n_blks; ++i) mt->blk[i] = malloc(BGZF_MAX_BLOCK_SIZE); mt->tid = (pthread_t*)calloc(mt->n_threads, sizeof(pthread_t)); // tid[0] is not used, as the worker 0 is launched by the master mt->w = (worker_t*)calloc(mt->n_threads, sizeof(worker_t)); for (i = 0; i < mt->n_threads; ++i) { mt->w[i].i = i; mt->w[i].mt = mt; mt->w[i].compress_level = fp->compress_level; mt->w[i].buf = malloc(BGZF_MAX_BLOCK_SIZE); } pthread_attr_init(&attr); pthread_attr_setdetachstate(&attr, PTHREAD_CREATE_JOINABLE); pthread_mutex_init(&mt->lock, 0); pthread_cond_init(&mt->cv, 0); for (i = 1; i < mt->n_threads; ++i) // worker 0 is effectively launched by the master thread pthread_create(&mt->tid[i], &attr, mt_worker, &mt->w[i]); fp->mt = mt; return 0; } static void mt_destroy(mtaux_t *mt) { int i; // signal all workers to quit pthread_mutex_lock(&mt->lock); mt->done = 1; mt->proc_cnt = 0; pthread_cond_broadcast(&mt->cv); pthread_mutex_unlock(&mt->lock); for (i = 1; i < mt->n_threads; ++i) pthread_join(mt->tid[i], 0); // worker 0 is effectively launched by the master thread // free other data allocated on heap for (i = 0; i < mt->n_blks; ++i) free(mt->blk[i]); for (i = 0; i < mt->n_threads; ++i) free(mt->w[i].buf); free(mt->blk); free(mt->len); free(mt->w); free(mt->tid); pthread_cond_destroy(&mt->cv); pthread_mutex_destroy(&mt->lock); free(mt); } static void mt_queue(BGZF *fp) { mtaux_t *mt = fp->mt; assert(mt->curr < mt->n_blks); // guaranteed by the caller memcpy(mt->blk[mt->curr], fp->uncompressed_block, fp->block_offset); mt->len[mt->curr] = fp->block_offset; fp->block_offset = 0; ++mt->curr; } static int mt_flush_queue(BGZF *fp) { int i; mtaux_t *mt = fp->mt; // signal all the workers to compress pthread_mutex_lock(&mt->lock); for (i = 0; i < mt->n_threads; ++i) mt->w[i].toproc = 1; mt->proc_cnt = 0; pthread_cond_broadcast(&mt->cv); pthread_mutex_unlock(&mt->lock); // worker 0 is doing things here worker_aux(&mt->w[0]); // wait for all the threads to complete while (mt->proc_cnt < mt->n_threads); // dump data to disk for (i = 0; i < mt->n_threads; ++i) fp->errcode |= mt->w[i].errcode; if (fp->errcode == 0) { /* Only try to write if all the threads worked, as otherwise we could get a file with holes in it */ for (i = 0; i < mt->curr; ++i) { if (hwrite(fp->fp, mt->blk[i], mt->len[i]) != mt->len[i]) { fp->errcode |= BGZF_ERR_IO; break; } } } mt->curr = 0; return (fp->errcode == 0)? 0 : -1; } static int lazy_flush(BGZF *fp) { if (fp->mt) { if (fp->block_offset) mt_queue(fp); return (fp->mt->curr < fp->mt->n_blks)? 0 : mt_flush_queue(fp); } else return bgzf_flush(fp); } #else // ~ #ifdef BGZF_MT int bgzf_mt(BGZF *fp, int n_threads, int n_sub_blks) { return 0; } static inline int lazy_flush(BGZF *fp) { return bgzf_flush(fp); } #endif // ~ #ifdef BGZF_MT int bgzf_flush(BGZF *fp) { if (!fp->is_write) return 0; #ifdef BGZF_MT if (fp->mt) { if (fp->block_offset) mt_queue(fp); // guaranteed that assertion does not fail return mt_flush_queue(fp); } #endif while (fp->block_offset > 0) { int block_length; if ( fp->idx_build_otf ) { bgzf_index_add_block(fp); fp->idx->ublock_addr += fp->block_offset; } block_length = deflate_block(fp, fp->block_offset); if (block_length < 0) { if (hts_verbose >= 3) fprintf(stderr, "[E::%s] deflate_block error %d\n", __func__, block_length); return -1; } if (hwrite(fp->fp, fp->compressed_block, block_length) != block_length) { if (hts_verbose >= 1) fprintf(stderr, "[E::%s] hwrite error (wrong size)\n", __func__); fp->errcode |= BGZF_ERR_IO; // possibly truncated file return -1; } fp->block_address += block_length; } return 0; } int bgzf_flush_try(BGZF *fp, ssize_t size) { if (fp->block_offset + size > BGZF_BLOCK_SIZE) return lazy_flush(fp); return 0; } ssize_t bgzf_write(BGZF *fp, const void *data, size_t length) { if ( !fp->is_compressed ) return hwrite(fp->fp, data, length); const uint8_t *input = (const uint8_t*)data; ssize_t remaining = length; assert(fp->is_write); while (remaining > 0) { uint8_t* buffer = (uint8_t*)fp->uncompressed_block; int copy_length = BGZF_BLOCK_SIZE - fp->block_offset; if (copy_length > remaining) copy_length = remaining; memcpy(buffer + fp->block_offset, input, copy_length); fp->block_offset += copy_length; input += copy_length; remaining -= copy_length; if (fp->block_offset == BGZF_BLOCK_SIZE) { if (lazy_flush(fp) != 0) return -1; } } return length - remaining; } ssize_t bgzf_raw_write(BGZF *fp, const void *data, size_t length) { return hwrite(fp->fp, data, length); } int bgzf_close(BGZF* fp) { int ret, block_length; if (fp == 0) return -1; if (fp->is_write && fp->is_compressed) { if (bgzf_flush(fp) != 0) return -1; fp->compress_level = -1; block_length = deflate_block(fp, 0); // write an empty block if (block_length < 0) { if (hts_verbose >= 3) fprintf(stderr, "[E::%s] deflate_block error %d\n", __func__, block_length); return -1; } if (hwrite(fp->fp, fp->compressed_block, block_length) < 0 || hflush(fp->fp) != 0) { if (hts_verbose >= 1) fprintf(stderr, "[E::%s] file write error\n", __func__); fp->errcode |= BGZF_ERR_IO; return -1; } #ifdef BGZF_MT if (fp->mt) mt_destroy(fp->mt); #endif } if ( fp->is_gzip ) { if (!fp->is_write) ret = inflateEnd(fp->gz_stream); else ret = deflateEnd(fp->gz_stream); if (ret != Z_OK && hts_verbose >= 1) fprintf(stderr, "[E::%s] inflateEnd/deflateEnd failed: %s\n", __func__, bgzf_zerr(ret, NULL)); free(fp->gz_stream); } ret = hclose(fp->fp); if (ret != 0) return -1; bgzf_index_destroy(fp); free(fp->uncompressed_block); free(fp->compressed_block); free_cache(fp); free(fp); return 0; } void bgzf_set_cache_size(BGZF *fp, int cache_size) { if (fp) fp->cache_size = cache_size; } int bgzf_check_EOF(BGZF *fp) { uint8_t buf[28]; off_t offset = htell(fp->fp); if (hseek(fp->fp, -28, SEEK_END) < 0) { if (errno == ESPIPE) { hclearerr(fp->fp); return 2; } else return -1; } if ( hread(fp->fp, buf, 28) != 28 ) return -1; if ( hseek(fp->fp, offset, SEEK_SET) < 0 ) return -1; return (memcmp("\037\213\010\4\0\0\0\0\0\377\6\0\102\103\2\0\033\0\3\0\0\0\0\0\0\0\0\0", buf, 28) == 0)? 1 : 0; } int64_t bgzf_seek(BGZF* fp, int64_t pos, int where) { int block_offset; int64_t block_address; if (fp->is_write || where != SEEK_SET) { fp->errcode |= BGZF_ERR_MISUSE; return -1; } block_offset = pos & 0xFFFF; block_address = pos >> 16; if (hseek(fp->fp, block_address, SEEK_SET) < 0) { fp->errcode |= BGZF_ERR_IO; return -1; } fp->block_length = 0; // indicates current block has not been loaded fp->block_address = block_address; fp->block_offset = block_offset; return 0; } int bgzf_is_bgzf(const char *fn) { uint8_t buf[16]; int n; hFILE *fp; if ((fp = hopen(fn, "r")) == 0) return 0; n = hread(fp, buf, 16); if ( hclose(fp) < 0 ) return -1; if (n != 16) return 0; return memcmp(g_magic, buf, 16) == 0? 1 : 0; } int bgzf_getc(BGZF *fp) { int c; if (fp->block_offset >= fp->block_length) { if (bgzf_read_block(fp) != 0) return -2; /* error */ if (fp->block_length == 0) return -1; /* end-of-file */ } c = ((unsigned char*)fp->uncompressed_block)[fp->block_offset++]; if (fp->block_offset == fp->block_length) { fp->block_address = htell(fp->fp); fp->block_offset = 0; fp->block_length = 0; } fp->uncompressed_address++; return c; } #ifndef kroundup32 #define kroundup32(x) (--(x), (x)|=(x)>>1, (x)|=(x)>>2, (x)|=(x)>>4, (x)|=(x)>>8, (x)|=(x)>>16, ++(x)) #endif int bgzf_getline(BGZF *fp, int delim, kstring_t *str) { int l, state = 0; unsigned char *buf = (unsigned char*)fp->uncompressed_block; str->l = 0; do { if (fp->block_offset >= fp->block_length) { if (bgzf_read_block(fp) != 0) { state = -2; break; } if (fp->block_length == 0) { state = -1; break; } } for (l = fp->block_offset; l < fp->block_length && buf[l] != delim; ++l); if (l < fp->block_length) state = 1; l -= fp->block_offset; if (str->l + l + 1 >= str->m) { str->m = str->l + l + 2; kroundup32(str->m); str->s = (char*)realloc(str->s, str->m); } memcpy(str->s + str->l, buf + fp->block_offset, l); str->l += l; fp->block_offset += l + 1; if (fp->block_offset >= fp->block_length) { fp->block_address = htell(fp->fp); fp->block_offset = 0; fp->block_length = 0; } } while (state == 0); if (str->l == 0 && state < 0) return state; fp->uncompressed_address += str->l; if ( delim=='\n' && str->l>0 && str->s[str->l-1]=='\r' ) str->l--; str->s[str->l] = 0; return str->l; } void bgzf_index_destroy(BGZF *fp) { if ( !fp->idx ) return; free(fp->idx->offs); free(fp->idx); fp->idx = NULL; fp->idx_build_otf = 0; } int bgzf_index_build_init(BGZF *fp) { bgzf_index_destroy(fp); fp->idx = (bgzidx_t*) calloc(1,sizeof(bgzidx_t)); if ( !fp->idx ) return -1; fp->idx_build_otf = 1; // build index on the fly return 0; } int bgzf_index_add_block(BGZF *fp) { fp->idx->noffs++; if ( fp->idx->noffs > fp->idx->moffs ) { fp->idx->moffs = fp->idx->noffs; kroundup32(fp->idx->moffs); fp->idx->offs = (bgzidx1_t*) realloc(fp->idx->offs, fp->idx->moffs*sizeof(bgzidx1_t)); if ( !fp->idx->offs ) return -1; } fp->idx->offs[ fp->idx->noffs-1 ].uaddr = fp->idx->ublock_addr; fp->idx->offs[ fp->idx->noffs-1 ].caddr = fp->block_address; return 0; } static inline int fwrite_uint64(uint64_t x, FILE *f) { if (ed_is_big()) x = ed_swap_8(x); if (fwrite(&x, sizeof x, 1, f) != 1) return -1; return 0; } int bgzf_index_dump(BGZF *fp, const char *bname, const char *suffix) { if (bgzf_flush(fp) != 0) return -1; assert(fp->idx); char *tmp = NULL; if ( suffix ) { int blen = strlen(bname); int slen = strlen(suffix); tmp = (char*) malloc(blen + slen + 1); if ( !tmp ) return -1; memcpy(tmp,bname,blen); memcpy(tmp+blen,suffix,slen+1); } FILE *idx = fopen(tmp?tmp:bname,"wb"); if ( tmp ) free(tmp); if ( !idx ) { if (hts_verbose > 1) { fprintf(stderr, "[E::%s] Error opening %s%s : %s\n", __func__, bname, suffix ? suffix : "", strerror(errno)); } return -1; } // Note that the index contains one extra record when indexing files opened // for reading. The terminating record is not present when opened for writing. // This is not a bug. int i; if (fwrite_uint64(fp->idx->noffs - 1, idx) < 0) goto fail; for (i=1; iidx->noffs; i++) { if (fwrite_uint64(fp->idx->offs[i].caddr, idx) < 0) goto fail; if (fwrite_uint64(fp->idx->offs[i].uaddr, idx) < 0) goto fail; } if (fclose(idx) < 0) { if (hts_verbose > 1) { fprintf(stderr, "[E::%s] Error on closing %s%s : %s\n", __func__, bname, suffix ? suffix : "", strerror(errno)); } return -1; } return 0; fail: if (hts_verbose > 1) { fprintf(stderr, "[E::%s] Error writing to %s%s : %s\n", __func__, bname, suffix ? suffix : "", strerror(errno)); } fclose(idx); return -1; } static inline int fread_uint64(uint64_t *xptr, FILE *f) { if (fread(xptr, sizeof *xptr, 1, f) != 1) return -1; if (ed_is_big()) ed_swap_8p(xptr); return 0; } int bgzf_index_load(BGZF *fp, const char *bname, const char *suffix) { char *tmp = NULL; if ( suffix ) { int blen = strlen(bname); int slen = strlen(suffix); tmp = (char*) malloc(blen + slen + 1); if ( !tmp ) return -1; memcpy(tmp,bname,blen); memcpy(tmp+blen,suffix,slen+1); } FILE *idx = fopen(tmp?tmp:bname,"rb"); if ( tmp ) free(tmp); if ( !idx ) { if (hts_verbose > 1) { fprintf(stderr, "[E::%s] Error opening %s%s : %s\n", __func__, bname, suffix ? suffix : "", strerror(errno)); } return -1; } fp->idx = (bgzidx_t*) calloc(1,sizeof(bgzidx_t)); if (fp->idx == NULL) goto fail; uint64_t x; if (fread_uint64(&x, idx) < 0) goto fail; fp->idx->noffs = fp->idx->moffs = x + 1; fp->idx->offs = (bgzidx1_t*) malloc(fp->idx->moffs*sizeof(bgzidx1_t)); if (fp->idx->offs == NULL) goto fail; fp->idx->offs[0].caddr = fp->idx->offs[0].uaddr = 0; int i; for (i=1; iidx->noffs; i++) { if (fread_uint64(&fp->idx->offs[i].caddr, idx) < 0) goto fail; if (fread_uint64(&fp->idx->offs[i].uaddr, idx) < 0) goto fail; } if (fclose(idx) != 0) goto fail; return 0; fail: if (hts_verbose > 1) { fprintf(stderr, "[E::%s] Error reading %s%s : %s\n", __func__, bname, suffix ? suffix : "", strerror(errno)); } fclose(idx); if (fp->idx) { free(fp->idx->offs); free(fp->idx); fp->idx = NULL; } return -1; } int bgzf_useek(BGZF *fp, long uoffset, int where) { if ( !fp->is_compressed ) { if (hseek(fp->fp, uoffset, SEEK_SET) < 0) { fp->errcode |= BGZF_ERR_IO; return -1; } fp->block_length = 0; // indicates current block has not been loaded fp->block_address = uoffset; fp->block_offset = 0; if (bgzf_read_block(fp) < 0) { fp->errcode |= BGZF_ERR_IO; return -1; } fp->uncompressed_address = uoffset; return 0; } if ( !fp->idx ) { fp->errcode |= BGZF_ERR_IO; return -1; } // binary search int ilo = 0, ihi = fp->idx->noffs - 1; while ( ilo<=ihi ) { int i = (ilo+ihi)*0.5; if ( uoffset < fp->idx->offs[i].uaddr ) ihi = i - 1; else if ( uoffset >= fp->idx->offs[i].uaddr ) ilo = i + 1; else break; } int i = ilo-1; if (hseek(fp->fp, fp->idx->offs[i].caddr, SEEK_SET) < 0) { fp->errcode |= BGZF_ERR_IO; return -1; } fp->block_length = 0; // indicates current block has not been loaded fp->block_address = fp->idx->offs[i].caddr; fp->block_offset = 0; if ( bgzf_read_block(fp) < 0 ) { fp->errcode |= BGZF_ERR_IO; return -1; } if ( uoffset - fp->idx->offs[i].uaddr > 0 ) { fp->block_offset = uoffset - fp->idx->offs[i].uaddr; assert( fp->block_offset <= fp->block_length ); // todo: skipped, unindexed, blocks } fp->uncompressed_address = uoffset; return 0; } long bgzf_utell(BGZF *fp) { return fp->uncompressed_address; // currently maintained only when reading }