/** \ingroup rpmio * \file rpmio/rpmio.c */ #include "system.h" #include #include #include #if defined(__linux__) #include #endif #include #include #include #include #include #include #include "rpmio/rpmio_internal.h" #include "debug.h" typedef struct FDSTACK_s * FDSTACK_t; struct FDSTACK_s { FDIO_t io; void * fp; int fdno; int syserrno; /* last system errno encountered */ const char *errcookie; /* pointer to custom error string */ FDSTACK_t prev; }; /** \ingroup rpmio * Cumulative statistics for a descriptor. */ typedef struct { struct rpmop_s ops[FDSTAT_MAX]; /*!< Cumulative statistics. */ } * FDSTAT_t; /** \ingroup rpmio * The FD_t File Handle data structure. */ struct _FD_s { int nrefs; int flags; #define RPMIO_DEBUG_IO 0x40000000 int magic; #define FDMAGIC 0x04463138 FDSTACK_t fps; int urlType; /* ufdio: */ char *descr; /* file name (or other description) */ FDSTAT_t stats; /* I/O statistics */ rpmDigestBundle digests; }; #define DBG(_f, _m, _x) \ \ if ((_rpmio_debug | ((_f) ? ((FD_t)(_f))->flags : 0)) & (_m)) fprintf _x \ #define DBGIO(_f, _x) DBG((_f), RPMIO_DEBUG_IO, _x) static FDSTACK_t fdGetFps(FD_t fd) { return (fd != NULL) ? fd->fps : NULL; } static void fdSetFdno(FD_t fd, int fdno) { if (fd) fd->fps->fdno = fdno; } static void fdPush(FD_t fd, FDIO_t io, void * fp, int fdno) { FDSTACK_t fps = xcalloc(1, sizeof(*fps)); fps->io = io; fps->fp = fp; fps->fdno = fdno; fps->prev = fd->fps; fd->fps = fps; fdLink(fd); } static FDSTACK_t fdPop(FD_t fd) { FDSTACK_t fps = fd->fps; fd->fps = fps->prev; free(fps); fps = fd->fps; fdFree(fd); return fps; } void fdSetBundle(FD_t fd, rpmDigestBundle bundle) { if (fd) fd->digests = bundle; } rpmDigestBundle fdGetBundle(FD_t fd, int create) { rpmDigestBundle bundle = NULL; if (fd) { if (fd->digests == NULL && create) fd->digests = rpmDigestBundleNew(); bundle = fd->digests; } return bundle; } /** \ingroup rpmio * \name RPMIO Vectors. */ typedef ssize_t (*fdio_read_function_t) (FDSTACK_t fps, void *buf, size_t nbytes); typedef ssize_t (*fdio_write_function_t) (FDSTACK_t fps, const void *buf, size_t nbytes); typedef int (*fdio_seek_function_t) (FDSTACK_t fps, off_t pos, int whence); typedef int (*fdio_close_function_t) (FDSTACK_t fps); typedef FD_t (*fdio_open_function_t) (const char * path, int flags, mode_t mode); typedef FD_t (*fdio_fdopen_function_t) (FD_t fd, int fdno, const char * fmode); typedef int (*fdio_fflush_function_t) (FDSTACK_t fps); typedef off_t (*fdio_ftell_function_t) (FDSTACK_t fps); typedef int (*fdio_ferror_function_t) (FDSTACK_t fps); typedef const char * (*fdio_fstrerr_function_t)(FDSTACK_t fps); struct FDIO_s { const char * ioname; const char * name; fdio_read_function_t read; fdio_write_function_t write; fdio_seek_function_t seek; fdio_close_function_t close; fdio_open_function_t _open; fdio_fdopen_function_t _fdopen; fdio_fflush_function_t _fflush; fdio_ftell_function_t _ftell; fdio_ferror_function_t _ferror; fdio_fstrerr_function_t _fstrerr; }; /* forward refs */ static const FDIO_t fdio; static const FDIO_t ufdio; static const FDIO_t gzdio; #if HAVE_BZLIB_H static const FDIO_t bzdio; #endif #ifdef HAVE_LZMA_H static const FDIO_t xzdio; static const FDIO_t lzdio; #endif #ifdef HAVE_ZSTD static const FDIO_t zstdio; #endif /** \ingroup rpmio * Update digest(s) attached to fd. */ static void fdUpdateDigests(FD_t fd, const void * buf, size_t buflen); static FD_t fdNew(int fdno, const char *descr); /** */ int _rpmio_debug = 0; /* =============================================================== */ static const char * fdbg(FD_t fd) { static char buf[BUFSIZ]; char *be = buf; buf[0] = '\0'; if (fd == NULL) return buf; *be++ = '\t'; for (FDSTACK_t fps = fd->fps; fps != NULL; fps = fps->prev) { FDIO_t iot = fps->io; if (fps != fd->fps) *be++ = ' '; *be++ = '|'; *be++ = ' '; /* plain fd io types dont have _fopen() method */ if (iot->_fdopen == NULL) { sprintf(be, "%s %d fp %p", iot->ioname, fps->fdno, fps->fp); } else { sprintf(be, "%s %p fp %d", iot->ioname, fps->fp, fps->fdno); } be += strlen(be); *be = '\0'; } return buf; } static void fdstat_enter(FD_t fd, fdOpX opx) { if (fd->stats != NULL) (void) rpmswEnter(fdOp(fd, opx), (ssize_t) 0); } static void fdstat_exit(FD_t fd, fdOpX opx, ssize_t rc) { if (rc == -1) { FDSTACK_t fps = fdGetFps(fd); fps->syserrno = errno; } if (fd->stats != NULL) (void) rpmswExit(fdOp(fd, opx), rc); } static void fdstat_print(FD_t fd, const char * msg, FILE * fp) { static const int usec_scale = (1000*1000); int opx; if (fd == NULL || fd->stats == NULL) return; for (opx = 0; opx < 4; opx++) { rpmop op = &fd->stats->ops[opx]; if (op->count <= 0) continue; switch (opx) { case FDSTAT_READ: if (msg) fprintf(fp, "%s:", msg); fprintf(fp, "%8d reads, %8ld total bytes in %d.%06d secs\n", op->count, (long)op->bytes, (int)(op->usecs/usec_scale), (int)(op->usecs%usec_scale)); break; case FDSTAT_WRITE: if (msg) fprintf(fp, "%s:", msg); fprintf(fp, "%8d writes, %8ld total bytes in %d.%06d secs\n", op->count, (long)op->bytes, (int)(op->usecs/usec_scale), (int)(op->usecs%usec_scale)); break; case FDSTAT_SEEK: break; case FDSTAT_CLOSE: break; } } } off_t fdSize(FD_t fd) { struct stat sb; off_t rc = -1; if (fd != NULL && fstat(Fileno(fd), &sb) == 0) rc = sb.st_size; return rc; } FD_t fdDup(int fdno) { FD_t fd; int nfdno; if ((nfdno = dup(fdno)) < 0) return NULL; fd = fdNew(nfdno, NULL); DBGIO(fd, (stderr, "==> fdDup(%d) fd %p %s\n", fdno, (fd ? fd : NULL), fdbg(fd))); return fd; } /* Regular fd doesn't have fflush() equivalent but its not an error either */ static int fdFlush(FDSTACK_t fps) { return 0; } static int fdError(FDSTACK_t fps) { return fps->syserrno; } static int zfdError(FDSTACK_t fps) { return (fps->syserrno || fps->errcookie != NULL) ? -1 : 0; } static const char * fdStrerr(FDSTACK_t fps) { return (fps->syserrno != 0) ? strerror(fps->syserrno) : ""; } static const char * zfdStrerr(FDSTACK_t fps) { return (fps->errcookie != NULL) ? fps->errcookie : ""; } const char * Fdescr(FD_t fd) { if (fd == NULL) return _("[none]"); /* Lazy lookup if description is not set (eg dupped fd) */ if (fd->descr == NULL) { int fdno = fd->fps->fdno; #if defined(__linux__) /* Grab the path from /proc if we can */ char *procpath = NULL; char buf[PATH_MAX]; ssize_t llen; rasprintf(&procpath, "/proc/self/fd/%d", fdno); llen = readlink(procpath, buf, sizeof(buf)-1); free(procpath); if (llen >= 1) { buf[llen] = '\0'; /* Real paths in /proc are always absolute */ if (buf[0] == '/') fd->descr = xstrdup(buf); else fd->descr = rstrscat(NULL, "[", buf, "]", NULL); } #endif /* Still no description, base it on fdno which is always there */ if (fd->descr == NULL) rasprintf(&(fd->descr), "[fd %d]", fdno); } return fd->descr; } FD_t fdLink(FD_t fd) { if (fd) fd->nrefs++; return fd; } FD_t fdFree( FD_t fd) { if (fd) { if (--fd->nrefs > 0) return fd; fd->stats = _free(fd->stats); if (fd->digests) { fd->digests = rpmDigestBundleFree(fd->digests); } free(fd->fps); free(fd->descr); free(fd); } return NULL; } static FD_t fdNew(int fdno, const char *descr) { FD_t fd = xcalloc(1, sizeof(*fd)); fd->nrefs = 0; fd->flags = 0; fd->magic = FDMAGIC; fd->urlType = URL_IS_UNKNOWN; fd->stats = xcalloc(1, sizeof(*fd->stats)); fd->digests = NULL; fd->descr = descr ? xstrdup(descr) : NULL; fdPush(fd, fdio, NULL, fdno); return fd; } static ssize_t fdRead(FDSTACK_t fps, void * buf, size_t count) { return read(fps->fdno, buf, count); } static ssize_t fdWrite(FDSTACK_t fps, const void * buf, size_t count) { if (count == 0) return 0; return write(fps->fdno, buf, count); } static int fdSeek(FDSTACK_t fps, off_t pos, int whence) { return lseek(fps->fdno, pos, whence); } static int fdClose(FDSTACK_t fps) { int fdno = fps->fdno; int rc; fps->fdno = -1; rc = ((fdno >= 0) ? close(fdno) : -2); return rc; } static FD_t fdOpen(const char *path, int flags, mode_t mode) { FD_t fd; int fdno; fdno = open(path, flags, mode); if (fdno < 0) return NULL; if (fcntl(fdno, F_SETFD, FD_CLOEXEC)) { (void) close(fdno); return NULL; } fd = fdNew(fdno, path); fd->flags = flags; return fd; } static off_t fdTell(FDSTACK_t fps) { return lseek(fps->fdno, 0, SEEK_CUR); } static const struct FDIO_s fdio_s = { "fdio", NULL, fdRead, fdWrite, fdSeek, fdClose, fdOpen, NULL, fdFlush, fdTell, fdError, fdStrerr, }; static const FDIO_t fdio = &fdio_s ; off_t ufdCopy(FD_t sfd, FD_t tfd) { char buf[BUFSIZ]; ssize_t rdbytes, wrbytes; off_t total = 0; while (1) { rdbytes = Fread(buf, sizeof(buf[0]), sizeof(buf), sfd); if (rdbytes > 0) { wrbytes = Fwrite(buf, sizeof(buf[0]), rdbytes, tfd); if (wrbytes != rdbytes) { total = -1; break; } total += wrbytes; } else { if (rdbytes < 0) total = -1; break; } } return total; } /* * Deal with remote url's by fetching them with a helper application * and treat as local file afterwards. * TODO: * - better error checking + reporting * - curl & friends don't know about hkp://, transform to http? */ static FD_t urlOpen(const char * url, int flags, mode_t mode) { FD_t fd; char *dest = NULL; int rc = 1; /* assume failure */ fd = rpmMkTempFile(NULL, &dest); if (fd == NULL) { return NULL; } Fclose(fd); rc = urlGetFile(url, dest); if (rc == 0) { fd = fdOpen(dest, flags, mode); unlink(dest); } else { fd = NULL; } dest = _free(dest); return fd; } static FD_t ufdOpen(const char * url, int flags, mode_t mode) { FD_t fd = NULL; const char * path; urltype urlType = urlPath(url, &path); if (_rpmio_debug) fprintf(stderr, "*** ufdOpen(%s,0x%x,0%o)\n", url, (unsigned)flags, (unsigned)mode); switch (urlType) { case URL_IS_FTP: case URL_IS_HTTPS: case URL_IS_HTTP: case URL_IS_HKP: fd = urlOpen(url, flags, mode); /* we're dealing with local file when urlOpen() returns */ urlType = URL_IS_UNKNOWN; break; case URL_IS_DASH: if ((flags & O_ACCMODE) == O_RDWR) { fd = NULL; } else { fd = fdDup((flags & O_ACCMODE) == O_WRONLY ? STDOUT_FILENO : STDIN_FILENO); } break; case URL_IS_PATH: case URL_IS_UNKNOWN: default: fd = fdOpen(path, flags, mode); break; } if (fd != NULL) { fd->fps->io = ufdio; fd->urlType = urlType; } return fd; } static const struct FDIO_s ufdio_s = { "ufdio", NULL, fdRead, fdWrite, fdSeek, fdClose, ufdOpen, NULL, fdFlush, fdTell, fdError, fdStrerr }; static const FDIO_t ufdio = &ufdio_s ; /* =============================================================== */ /* Support for GZIP library. */ #include static FD_t gzdFdopen(FD_t fd, int fdno, const char *fmode) { gzFile gzfile = gzdopen(fdno, fmode); if (gzfile == NULL) return NULL; fdSetFdno(fd, -1); /* XXX skip the fdio close */ fdPush(fd, gzdio, gzfile, fdno); /* Push gzdio onto stack */ return fd; } static int gzdFlush(FDSTACK_t fps) { gzFile gzfile = fps->fp; if (gzfile == NULL) return -2; return gzflush(gzfile, Z_SYNC_FLUSH); /* XXX W2DO? */ } static void gzdSetError(FDSTACK_t fps) { gzFile gzfile = fps->fp; int zerror = 0; fps->errcookie = gzerror(gzfile, &zerror); if (zerror == Z_ERRNO) { fps->syserrno = errno; fps->errcookie = strerror(fps->syserrno); } } static ssize_t gzdRead(FDSTACK_t fps, void * buf, size_t count) { gzFile gzfile = fps->fp; ssize_t rc; if (gzfile == NULL) return -2; /* XXX can't happen */ rc = gzread(gzfile, buf, count); if (rc < 0) gzdSetError(fps); return rc; } static ssize_t gzdWrite(FDSTACK_t fps, const void * buf, size_t count) { gzFile gzfile; ssize_t rc; gzfile = fps->fp; if (gzfile == NULL) return -2; /* XXX can't happen */ rc = gzwrite(gzfile, (void *)buf, count); if (rc < 0) gzdSetError(fps); return rc; } /* XXX zlib-1.0.4 has not */ static int gzdSeek(FDSTACK_t fps, off_t pos, int whence) { off_t p = pos; int rc; #if HAVE_GZSEEK gzFile gzfile = fps->fp; if (gzfile == NULL) return -2; /* XXX can't happen */ rc = gzseek(gzfile, p, whence); if (rc < 0) gzdSetError(fps); #else rc = -2; #endif return rc; } static int gzdClose(FDSTACK_t fps) { gzFile gzfile = fps->fp; int rc; if (gzfile == NULL) return -2; /* XXX can't happen */ rc = gzclose(gzfile); return (rc != 0) ? -1 : 0; } static off_t gzdTell(FDSTACK_t fps) { off_t pos = -1; gzFile gzfile = fps->fp; if (gzfile != NULL) { #if HAVE_GZSEEK pos = gztell(gzfile); if (pos < 0) gzdSetError(fps); #else pos = -2; #endif } return pos; } static const struct FDIO_s gzdio_s = { "gzdio", "gzip", gzdRead, gzdWrite, gzdSeek, gzdClose, NULL, gzdFdopen, gzdFlush, gzdTell, zfdError, zfdStrerr }; static const FDIO_t gzdio = &gzdio_s ; /* =============================================================== */ /* Support for BZIP2 library. */ #if HAVE_BZLIB_H #include static FD_t bzdFdopen(FD_t fd, int fdno, const char * fmode) { BZFILE *bzfile = BZ2_bzdopen(fdno, fmode); if (bzfile == NULL) return NULL; fdSetFdno(fd, -1); /* XXX skip the fdio close */ fdPush(fd, bzdio, bzfile, fdno); /* Push bzdio onto stack */ return fd; } static int bzdFlush(FDSTACK_t fps) { return BZ2_bzflush(fps->fp); } static ssize_t bzdRead(FDSTACK_t fps, void * buf, size_t count) { BZFILE *bzfile = fps->fp; ssize_t rc = 0; if (bzfile) rc = BZ2_bzread(bzfile, buf, count); if (rc == -1) { int zerror = 0; if (bzfile) { fps->errcookie = BZ2_bzerror(bzfile, &zerror); } } return rc; } static ssize_t bzdWrite(FDSTACK_t fps, const void * buf, size_t count) { BZFILE *bzfile = fps->fp; ssize_t rc; rc = BZ2_bzwrite(bzfile, (void *)buf, count); if (rc == -1) { int zerror = 0; fps->errcookie = BZ2_bzerror(bzfile, &zerror); } return rc; } static int bzdClose(FDSTACK_t fps) { BZFILE *bzfile = fps->fp; if (bzfile == NULL) return -2; /* bzclose() doesn't return errors */ BZ2_bzclose(bzfile); return 0; } static const struct FDIO_s bzdio_s = { "bzdio", "bzip2", bzdRead, bzdWrite, NULL, bzdClose, NULL, bzdFdopen, bzdFlush, NULL, zfdError, zfdStrerr }; static const FDIO_t bzdio = &bzdio_s ; #endif /* HAVE_BZLIB_H */ /* =============================================================== */ /* Support for LZMA library. */ #ifdef HAVE_LZMA_H #include #include #include /* Multithreading support in stable API since xz 5.2.0 */ #if LZMA_VERSION >= 50020002 #define HAVE_LZMA_MT #endif #define kBufferSize (1 << 15) typedef struct lzfile { /* IO buffer */ uint8_t buf[kBufferSize]; lzma_stream strm; FILE *file; int encoding; int eof; } LZFILE; static LZFILE *lzopen_internal(const char *mode, int fd, int xz) { int level = LZMA_PRESET_DEFAULT; int encoding = 0; FILE *fp; LZFILE *lzfile; lzma_ret ret; lzma_stream init_strm = LZMA_STREAM_INIT; uint64_t mem_limit = rpmExpandNumeric("%{_xz_memlimit}"); #ifdef HAVE_LZMA_MT int threads = 0; #endif for (; *mode; mode++) { if (*mode == 'w') encoding = 1; else if (*mode == 'r') encoding = 0; else if (*mode >= '0' && *mode <= '9') level = *mode - '0'; else if (*mode == 'T') { if (isdigit(*(mode+1))) { #ifdef HAVE_LZMA_MT threads = atoi(++mode); #endif /* skip past rest of digits in string that atoi() * should've processed * */ while (isdigit(*++mode)); } #ifdef HAVE_LZMA_MT else threads = -1; #endif } } fp = fdopen(fd, encoding ? "w" : "r"); if (!fp) return NULL; lzfile = calloc(1, sizeof(*lzfile)); lzfile->file = fp; lzfile->encoding = encoding; lzfile->eof = 0; lzfile->strm = init_strm; if (encoding) { if (xz) { #ifdef HAVE_LZMA_MT if (!threads) { #endif ret = lzma_easy_encoder(&lzfile->strm, level, LZMA_CHECK_SHA256); #ifdef HAVE_LZMA_MT } else { if (threads == -1) threads = sysconf(_SC_NPROCESSORS_ONLN); lzma_mt mt_options = { .flags = 0, .threads = threads, .block_size = 0, .timeout = 0, .preset = level, .filters = NULL, .check = LZMA_CHECK_SHA256 }; #if __WORDSIZE == 32 /* In 32 bit environment, required memory easily exceeds memory address * space limit if compressing using multiple threads. * By setting a memory limit, liblzma will automatically adjust number * of threads to avoid exceeding memory. */ if (threads > 1) { struct utsname u; uint32_t memlimit = (SIZE_MAX>>1) + (SIZE_MAX>>3); uint64_t memory_usage; /* While a 32 bit linux kernel will have an address limit of 3GiB * for processes (which is why set the memory limit to 2.5GiB as a safety * margin), 64 bit kernels will have a limit of 4GiB for 32 bit binaries. * Therefore the memory limit should be higher if running on a 64 bit * kernel, so we increase it to 3,5GiB. */ uname(&u); if (strstr(u.machine, "64") || strstr(u.machine, "s390x") #if defined(__linux__) || ((personality(0xffffffff) & PER_MASK) == PER_LINUX32) #endif ) memlimit += (SIZE_MAX>>2); /* keep reducing the number of threads until memory usage gets below limit */ while ((memory_usage = lzma_stream_encoder_mt_memusage(&mt_options)) > memlimit) { /* number of threads shouldn't be able to hit zero with compression * settings aailable to set through rpm... */ assert(--mt_options.threads != 0); } lzma_memlimit_set(&lzfile->strm, memlimit); if (threads != (int)mt_options.threads) rpmlog(RPMLOG_NOTICE, "XZ: Adjusted the number of threads from %d to %d to not exceed the memory usage limit of %lu bytes", threads, mt_options.threads, memlimit); } #endif ret = lzma_stream_encoder_mt(&lzfile->strm, &mt_options); } #endif } else { lzma_options_lzma options; lzma_lzma_preset(&options, level); ret = lzma_alone_encoder(&lzfile->strm, &options); } } else { /* lzma_easy_decoder_memusage(level) is not ready yet, use hardcoded limit for now */ ret = lzma_auto_decoder(&lzfile->strm, mem_limit ? mem_limit : 100<<20, 0); } if (ret != LZMA_OK) { switch (ret) { case LZMA_MEM_ERROR: rpmlog(RPMLOG_ERR, "liblzma: Memory allocation failed"); break; case LZMA_DATA_ERROR: rpmlog(RPMLOG_ERR, "liblzma: File size limits exceeded"); break; default: rpmlog(RPMLOG_ERR, "liblzma: encoding) { for (;;) { lzfile->strm.avail_out = kBufferSize; lzfile->strm.next_out = lzfile->buf; ret = lzma_code(&lzfile->strm, LZMA_FINISH); if (ret != LZMA_OK && ret != LZMA_STREAM_END) return -1; n = kBufferSize - lzfile->strm.avail_out; if (n && fwrite(lzfile->buf, 1, n, lzfile->file) != n) return -1; if (ret == LZMA_STREAM_END) break; } } lzma_end(&lzfile->strm); rc = fclose(lzfile->file); free(lzfile); return rc; } static ssize_t lzread(LZFILE *lzfile, void *buf, size_t len) { lzma_ret ret; int eof = 0; if (!lzfile || lzfile->encoding) return -1; if (lzfile->eof) return 0; lzfile->strm.next_out = buf; lzfile->strm.avail_out = len; for (;;) { if (!lzfile->strm.avail_in) { lzfile->strm.next_in = lzfile->buf; lzfile->strm.avail_in = fread(lzfile->buf, 1, kBufferSize, lzfile->file); if (!lzfile->strm.avail_in) eof = 1; } ret = lzma_code(&lzfile->strm, LZMA_RUN); if (ret == LZMA_STREAM_END) { lzfile->eof = 1; return len - lzfile->strm.avail_out; } if (ret != LZMA_OK) return -1; if (!lzfile->strm.avail_out) return len; if (eof) return -1; } } static ssize_t lzwrite(LZFILE *lzfile, void *buf, size_t len) { lzma_ret ret; size_t n; if (!lzfile || !lzfile->encoding) return -1; if (!len) return 0; lzfile->strm.next_in = buf; lzfile->strm.avail_in = len; for (;;) { lzfile->strm.next_out = lzfile->buf; lzfile->strm.avail_out = kBufferSize; ret = lzma_code(&lzfile->strm, LZMA_RUN); if (ret != LZMA_OK) return -1; n = kBufferSize - lzfile->strm.avail_out; if (n && fwrite(lzfile->buf, 1, n, lzfile->file) != n) return -1; if (!lzfile->strm.avail_in) return len; } } static FD_t xzdFdopen(FD_t fd, int fdno, const char * fmode) { LZFILE *lzfile = lzopen_internal(fmode, fdno, 1); if (lzfile == NULL) return NULL; fdSetFdno(fd, -1); /* XXX skip the fdio close */ fdPush(fd, xzdio, lzfile, fdno); return fd; } static FD_t lzdFdopen(FD_t fd, int fdno, const char * fmode) { LZFILE *lzfile = lzopen_internal(fmode, fdno, 0); if (lzfile == NULL) return NULL; fdSetFdno(fd, -1); /* XXX skip the fdio close */ fdPush(fd, lzdio, lzfile, fdno); return fd; } static int lzdFlush(FDSTACK_t fps) { LZFILE *lzfile = fps->fp; return fflush(lzfile->file); } static ssize_t lzdRead(FDSTACK_t fps, void * buf, size_t count) { LZFILE *lzfile = fps->fp; ssize_t rc = 0; if (lzfile) rc = lzread(lzfile, buf, count); if (rc == -1) { fps->errcookie = "Lzma: decoding error"; } return rc; } static ssize_t lzdWrite(FDSTACK_t fps, const void * buf, size_t count) { LZFILE *lzfile = fps->fp; ssize_t rc = 0; rc = lzwrite(lzfile, (void *)buf, count); if (rc < 0) { fps->errcookie = "Lzma: encoding error"; } return rc; } static int lzdClose(FDSTACK_t fps) { LZFILE *lzfile = fps->fp; int rc; if (lzfile == NULL) return -2; rc = lzclose(lzfile); return rc; } static struct FDIO_s xzdio_s = { "xzdio", "xz", lzdRead, lzdWrite, NULL, lzdClose, NULL, xzdFdopen, lzdFlush, NULL, zfdError, zfdStrerr }; static const FDIO_t xzdio = &xzdio_s; static struct FDIO_s lzdio_s = { "lzdio", "lzma", lzdRead, lzdWrite, NULL, lzdClose, NULL, lzdFdopen, lzdFlush, NULL, zfdError, zfdStrerr }; static const FDIO_t lzdio = &lzdio_s; #endif /* HAVE_LZMA_H */ /* =============================================================== */ /* Support for ZSTD library. */ #ifdef HAVE_ZSTD #include typedef struct rpmzstd_s { int flags; /*!< open flags. */ int fdno; int level; /*!< compression level */ FILE * fp; void * _stream; /*!< ZSTD_{C,D}Stream */ size_t nb; void * b; ZSTD_inBuffer zib; /*!< ZSTD_inBuffer */ ZSTD_outBuffer zob; /*!< ZSTD_outBuffer */ } * rpmzstd; static rpmzstd rpmzstdNew(int fdno, const char *fmode) { int flags = 0; int level = 3; const char * s = fmode; char stdio[32]; char *t = stdio; char *te = t + sizeof(stdio) - 2; int c; switch ((c = *s++)) { case 'a': *t++ = (char)c; flags &= ~O_ACCMODE; flags |= O_WRONLY | O_CREAT | O_APPEND; break; case 'w': *t++ = (char)c; flags &= ~O_ACCMODE; flags |= O_WRONLY | O_CREAT | O_TRUNC; break; case 'r': *t++ = (char)c; flags &= ~O_ACCMODE; flags |= O_RDONLY; break; } while ((c = *s++) != 0) { switch (c) { case '.': break; case '+': if (t < te) *t++ = c; flags &= ~O_ACCMODE; flags |= O_RDWR; continue; break; default: if (c >= (int)'0' && c <= (int)'9') { level = strtol(s-1, (char **)&s, 10); if (level < 1){ level = 1; rpmlog(RPMLOG_WARNING, "Invalid compression level for zstd. Using %i instead.\n", 1); } if (level > 19) { level = 19; rpmlog(RPMLOG_WARNING, "Invalid compression level for zstd. Using %i instead.\n", 19); } } continue; break; } break; } *t = '\0'; FILE * fp = fdopen(fdno, stdio); if (fp == NULL) return NULL; void * _stream = NULL; size_t nb = 0; if ((flags & O_ACCMODE) == O_RDONLY) { /* decompressing */ if ((_stream = (void *) ZSTD_createDStream()) == NULL || ZSTD_isError(ZSTD_initDStream(_stream))) { return NULL; } nb = ZSTD_DStreamInSize(); } else { /* compressing */ if ((_stream = (void *) ZSTD_createCStream()) == NULL || ZSTD_isError(ZSTD_initCStream(_stream, level))) { return NULL; } nb = ZSTD_CStreamOutSize(); } rpmzstd zstd = (rpmzstd) xcalloc(1, sizeof(*zstd)); zstd->flags = flags; zstd->fdno = fdno; zstd->level = level; zstd->fp = fp; zstd->_stream = _stream; zstd->nb = nb; zstd->b = xmalloc(nb); return zstd; } static FD_t zstdFdopen(FD_t fd, int fdno, const char * fmode) { rpmzstd zstd = rpmzstdNew(fdno, fmode); if (zstd == NULL) return NULL; fdSetFdno(fd, -1); /* XXX skip the fdio close */ fdPush(fd, zstdio, zstd, fdno); /* Push zstdio onto stack */ return fd; } static int zstdFlush(FDSTACK_t fps) { rpmzstd zstd = (rpmzstd) fps->fp; assert(zstd); int rc = -1; if ((zstd->flags & O_ACCMODE) == O_RDONLY) { /* decompressing */ rc = 0; } else { /* compressing */ /* close frame */ zstd->zob.dst = zstd->b; zstd->zob.size = zstd->nb; zstd->zob.pos = 0; int xx = ZSTD_flushStream(zstd->_stream, &zstd->zob); if (ZSTD_isError(xx)) fps->errcookie = ZSTD_getErrorName(xx); else if (zstd->zob.pos != fwrite(zstd->b, 1, zstd->zob.pos, zstd->fp)) fps->errcookie = "zstdFlush fwrite failed."; else rc = 0; } return rc; } static ssize_t zstdRead(FDSTACK_t fps, void * buf, size_t count) { rpmzstd zstd = (rpmzstd) fps->fp; assert(zstd); ZSTD_outBuffer zob = { buf, count, 0 }; while (zob.pos < zob.size) { /* Re-fill compressed data buffer. */ if (zstd->zib.pos >= zstd->zib.size) { zstd->zib.size = fread(zstd->b, 1, zstd->nb, zstd->fp); if (zstd->zib.size == 0) break; /* EOF */ zstd->zib.src = zstd->b; zstd->zib.pos = 0; } /* Decompress next chunk. */ int xx = ZSTD_decompressStream(zstd->_stream, &zob, &zstd->zib); if (ZSTD_isError(xx)) { fps->errcookie = ZSTD_getErrorName(xx); return -1; } } return zob.pos; } static ssize_t zstdWrite(FDSTACK_t fps, const void * buf, size_t count) { rpmzstd zstd = (rpmzstd) fps->fp; assert(zstd); ZSTD_inBuffer zib = { buf, count, 0 }; while (zib.pos < zib.size) { /* Reset to beginning of compressed data buffer. */ zstd->zob.dst = zstd->b; zstd->zob.size = zstd->nb; zstd->zob.pos = 0; /* Compress next chunk. */ int xx = ZSTD_compressStream(zstd->_stream, &zstd->zob, &zib); if (ZSTD_isError(xx)) { fps->errcookie = ZSTD_getErrorName(xx); return -1; } /* Write compressed data buffer. */ if (zstd->zob.pos > 0) { size_t nw = fwrite(zstd->b, 1, zstd->zob.pos, zstd->fp); if (nw != zstd->zob.pos) { fps->errcookie = "zstdWrite fwrite failed."; return -1; } } } return zib.pos; } static int zstdClose(FDSTACK_t fps) { rpmzstd zstd = (rpmzstd) fps->fp; assert(zstd); int rc = -2; if ((zstd->flags & O_ACCMODE) == O_RDONLY) { /* decompressing */ rc = 0; ZSTD_freeDStream(zstd->_stream); } else { /* compressing */ /* close frame */ zstd->zob.dst = zstd->b; zstd->zob.size = zstd->nb; zstd->zob.pos = 0; int xx = ZSTD_endStream(zstd->_stream, &zstd->zob); if (ZSTD_isError(xx)) fps->errcookie = ZSTD_getErrorName(xx); else if (zstd->zob.pos != fwrite(zstd->b, 1, zstd->zob.pos, zstd->fp)) fps->errcookie = "zstdClose fwrite failed."; else rc = 0; ZSTD_freeCStream(zstd->_stream); } if (zstd->fp && fileno(zstd->fp) > 2) (void) fclose(zstd->fp); if (zstd->b) free(zstd->b); free(zstd); return rc; } static const struct FDIO_s zstdio_s = { "zstdio", "zstd", zstdRead, zstdWrite, NULL, zstdClose, NULL, zstdFdopen, zstdFlush, NULL, zfdError, zfdStrerr }; static const FDIO_t zstdio = &zstdio_s ; #endif /* HAVE_ZSTD */ /* =============================================================== */ #define FDIOVEC(_fps, _vec) \ ((_fps) && (_fps)->io) ? (_fps)->io->_vec : NULL const char *Fstrerror(FD_t fd) { const char *err = ""; if (fd != NULL) { FDSTACK_t fps = fdGetFps(fd); fdio_fstrerr_function_t _fstrerr = FDIOVEC(fps, _fstrerr); if (_fstrerr) err = _fstrerr(fps); } else if (errno){ err = strerror(errno); } return err; } ssize_t Fread(void *buf, size_t size, size_t nmemb, FD_t fd) { ssize_t rc = -1; if (fd != NULL) { FDSTACK_t fps = fdGetFps(fd); fdio_read_function_t _read = FDIOVEC(fps, read); fdstat_enter(fd, FDSTAT_READ); do { rc = (_read ? (*_read) (fps, buf, size * nmemb) : -2); } while (rc == -1 && errno == EINTR); fdstat_exit(fd, FDSTAT_READ, rc); if (fd->digests && rc > 0) fdUpdateDigests(fd, buf, rc); } DBGIO(fd, (stderr, "==>\tFread(%p,%p,%ld) rc %ld %s\n", fd, buf, (long)size * nmemb, (long)rc, fdbg(fd))); return rc; } ssize_t Fwrite(const void *buf, size_t size, size_t nmemb, FD_t fd) { ssize_t rc = -1; if (fd != NULL) { FDSTACK_t fps = fdGetFps(fd); fdio_write_function_t _write = FDIOVEC(fps, write); fdstat_enter(fd, FDSTAT_WRITE); do { rc = (_write ? _write(fps, buf, size * nmemb) : -2); } while (rc == -1 && errno == EINTR); fdstat_exit(fd, FDSTAT_WRITE, rc); if (fd->digests && rc > 0) fdUpdateDigests(fd, buf, rc); } DBGIO(fd, (stderr, "==>\tFwrite(%p,%p,%ld) rc %ld %s\n", fd, buf, (long)size * nmemb, (long)rc, fdbg(fd))); return rc; } int Fseek(FD_t fd, off_t offset, int whence) { int rc = -1; if (fd != NULL) { FDSTACK_t fps = fdGetFps(fd); fdio_seek_function_t _seek = FDIOVEC(fps, seek); fdstat_enter(fd, FDSTAT_SEEK); rc = (_seek ? _seek(fps, offset, whence) : -2); fdstat_exit(fd, FDSTAT_SEEK, rc); } DBGIO(fd, (stderr, "==>\tFseek(%p,%ld,%d) rc %lx %s\n", fd, (long)offset, whence, (unsigned long)rc, fdbg(fd))); return rc; } int Fclose(FD_t fd) { int rc = 0, ec = 0; if (fd == NULL) return -1; fd = fdLink(fd); fdstat_enter(fd, FDSTAT_CLOSE); for (FDSTACK_t fps = fd->fps; fps != NULL; fps = fdPop(fd)) { if (fps->fdno >= 0) { fdio_close_function_t _close = FDIOVEC(fps, close); rc = _close ? _close(fps) : -2; if (ec == 0 && rc) ec = rc; } /* Debugging stats for compresed types */ if ((_rpmio_debug || rpmIsDebug()) && fps->fdno == -1) fdstat_print(fd, fps->io->ioname, stderr); /* Leave freeing the last one after stats */ if (fps->prev == NULL) break; } fdstat_exit(fd, FDSTAT_CLOSE, rc); DBGIO(fd, (stderr, "==>\tFclose(%p) rc %lx %s\n", (fd ? fd : NULL), (unsigned long)rc, fdbg(fd))); fdPop(fd); fdFree(fd); return ec; } /** * Convert stdio fmode to open(2) mode, filtering out zlib/bzlib flags. * returns stdio[0] = NUL on error. * * - gzopen: [0-9] is compression level * - gzopen: 'f' is filtered (Z_FILTERED) * - gzopen: 'h' is Huffman encoding (Z_HUFFMAN_ONLY) * - bzopen: [1-9] is block size (modulo 100K) * - bzopen: 's' is smallmode * - HACK: '.' terminates, rest is type of I/O */ static void cvtfmode (const char *m, char *stdio, size_t nstdio, char *other, size_t nother, const char **end, int * f) { int flags = 0; char c; switch (*m) { case 'a': flags &= ~O_ACCMODE; flags |= O_WRONLY | O_CREAT | O_APPEND; if (--nstdio > 0) *stdio++ = *m; break; case 'w': flags &= ~O_ACCMODE; flags |= O_WRONLY | O_CREAT | O_TRUNC; if (--nstdio > 0) *stdio++ = *m; break; case 'r': flags &= ~O_ACCMODE; flags |= O_RDONLY; if (--nstdio > 0) *stdio++ = *m; break; default: *stdio = '\0'; return; break; } m++; while ((c = *m++) != '\0') { switch (c) { case '.': break; case '+': flags &= ~O_ACCMODE; flags |= O_RDWR; if (--nstdio > 0) *stdio++ = c; continue; break; case 'b': if (--nstdio > 0) *stdio++ = c; continue; break; case 'x': flags |= O_EXCL; if (--nstdio > 0) *stdio++ = c; continue; break; case '?': flags |= RPMIO_DEBUG_IO; if (--nother > 0) *other++ = c; continue; break; default: if (--nother > 0) *other++ = c; continue; break; } break; } *stdio = *other = '\0'; if (end != NULL) *end = (*m != '\0' ? m : NULL); if (f != NULL) *f = flags; } static FDIO_t findIOT(const char *name) { static FDIO_t fdio_types[] = { &fdio_s, &ufdio_s, &gzdio_s, #if HAVE_BZLIB_H &bzdio_s, #endif #if HAVE_LZMA_H &xzdio_s, &lzdio_s, #endif #ifdef HAVE_ZSTD &zstdio_s, #endif NULL }; FDIO_t iot = NULL; for (FDIO_t *t = fdio_types; t && *t; t++) { if (rstreq(name, (*t)->ioname) || ((*t)->name && rstreq(name, (*t)->name))) { iot = (*t); break; } } return iot; } FD_t Fdopen(FD_t ofd, const char *fmode) { char stdio[20], other[20], zstdio[40]; const char *end = NULL; FDIO_t iot = NULL; FD_t fd = ofd; int fdno = Fileno(ofd); if (_rpmio_debug) fprintf(stderr, "*** Fdopen(%p,%s) %s\n", fd, fmode, fdbg(fd)); if (fd == NULL || fmode == NULL || fdno < 0) return NULL; cvtfmode(fmode, stdio, sizeof(stdio), other, sizeof(other), &end, NULL); if (stdio[0] == '\0') return NULL; zstdio[0] = '\0'; strncat(zstdio, stdio, sizeof(zstdio) - strlen(zstdio) - 1); strncat(zstdio, other, sizeof(zstdio) - strlen(zstdio) - 1); if (end == NULL && other[0] == '\0') return fd; if (end && *end) { iot = findIOT(end); } else if (other[0] != '\0') { for (end = other; *end && strchr("0123456789fh", *end); end++) {}; if (*end == '\0') iot = findIOT("gzdio"); } if (iot && iot->_fdopen) fd = iot->_fdopen(fd, fdno, zstdio); DBGIO(fd, (stderr, "==> Fdopen(%p,\"%s\") returns fd %p %s\n", ofd, fmode, (fd ? fd : NULL), fdbg(fd))); return fd; } FD_t Fopen(const char *path, const char *fmode) { char stdio[20], other[20]; const char *end = NULL; mode_t perms = 0666; int flags = 0; FD_t fd = NULL; if (path == NULL || fmode == NULL) return NULL; stdio[0] = '\0'; cvtfmode(fmode, stdio, sizeof(stdio), other, sizeof(other), &end, &flags); if (stdio[0] == '\0') return NULL; if (end == NULL || rstreq(end, "fdio")) { if (_rpmio_debug) fprintf(stderr, "*** Fopen fdio path %s fmode %s\n", path, fmode); fd = fdOpen(path, flags, perms); } else { if (_rpmio_debug) fprintf(stderr, "*** Fopen ufdio path %s fmode %s\n", path, fmode); fd = ufdOpen(path, flags, perms); } /* Open compressed stream if necessary */ if (fd) fd = Fdopen(fd, fmode); DBGIO(fd, (stderr, "==>\tFopen(\"%s\",%x,0%o) %s\n", path, (unsigned)flags, (unsigned)perms, fdbg(fd))); return fd; } int Fflush(FD_t fd) { int rc = -1; if (fd != NULL) { FDSTACK_t fps = fdGetFps(fd); fdio_fflush_function_t _fflush = FDIOVEC(fps, _fflush); rc = (_fflush ? _fflush(fps) : -2); } return rc; } off_t Ftell(FD_t fd) { off_t pos = -1; if (fd != NULL) { FDSTACK_t fps = fdGetFps(fd); fdio_ftell_function_t _ftell = FDIOVEC(fps, _ftell); pos = (_ftell ? _ftell(fps) : -2); } return pos; } int Ferror(FD_t fd) { int rc = 0; if (fd == NULL) return -1; for (FDSTACK_t fps = fd->fps; fps != NULL; fps = fps->prev) { fdio_ferror_function_t _ferror = FDIOVEC(fps, _ferror); rc = _ferror(fps); if (rc) break; } DBGIO(fd, (stderr, "==> Ferror(%p) rc %d %s\n", fd, rc, fdbg(fd))); return rc; } int Fileno(FD_t fd) { int rc = -1; if (fd == NULL) return -1; for (FDSTACK_t fps = fd->fps; fps != NULL; fps = fps->prev) { rc = fps->fdno; if (rc != -1) break; } DBGIO(fd, (stderr, "==> Fileno(%p) rc %d %s\n", (fd ? fd : NULL), rc, fdbg(fd))); return rc; } /* XXX this is naive */ int Fcntl(FD_t fd, int op, void *lip) { return fcntl(Fileno(fd), op, lip); } rpmop fdOp(FD_t fd, fdOpX opx) { rpmop op = NULL; if (fd != NULL && fd->stats != NULL && opx >= 0 && opx < FDSTAT_MAX) op = fd->stats->ops + opx; return op; } int rpmioSlurp(const char * fn, uint8_t ** bp, ssize_t * blenp) { static const ssize_t blenmax = (32 * BUFSIZ); ssize_t blen = 0; uint8_t * b = NULL; ssize_t size; FD_t fd; int rc = 0; fd = Fopen(fn, "r.ufdio"); if (fd == NULL || Ferror(fd)) { rc = 2; goto exit; } size = fdSize(fd); blen = (size >= 0 ? size : blenmax); if (blen) { int nb; b = xmalloc(blen+1); b[0] = '\0'; nb = Fread(b, sizeof(*b), blen, fd); if (Ferror(fd) || (size > 0 && nb != blen)) { rc = 1; goto exit; } if (blen == blenmax && nb < blen) { blen = nb; b = xrealloc(b, blen+1); } b[blen] = '\0'; } exit: if (fd) (void) Fclose(fd); if (rc) { if (b) free(b); b = NULL; blen = 0; } if (bp) *bp = b; else if (b) free(b); if (blenp) *blenp = blen; return rc; } void fdInitDigest(FD_t fd, int hashalgo, rpmDigestFlags flags) { return fdInitDigestID(fd, hashalgo, hashalgo, flags); } void fdInitDigestID(FD_t fd, int hashalgo, int id, rpmDigestFlags flags) { if (fd->digests == NULL) { fd->digests = rpmDigestBundleNew(); } fdstat_enter(fd, FDSTAT_DIGEST); rpmDigestBundleAddID(fd->digests, hashalgo, id, flags); fdstat_exit(fd, FDSTAT_DIGEST, (ssize_t) 0); } static void fdUpdateDigests(FD_t fd, const void * buf, size_t buflen) { if (fd && fd->digests) { fdstat_enter(fd, FDSTAT_DIGEST); rpmDigestBundleUpdate(fd->digests, buf, buflen); fdstat_exit(fd, FDSTAT_DIGEST, (ssize_t) buflen); } } void fdFiniDigest(FD_t fd, int id, void ** datap, size_t * lenp, int asAscii) { if (fd && fd->digests) { fdstat_enter(fd, FDSTAT_DIGEST); rpmDigestBundleFinal(fd->digests, id, datap, lenp, asAscii); fdstat_exit(fd, FDSTAT_DIGEST, (ssize_t) 0); } } DIGEST_CTX fdDupDigest(FD_t fd, int id) { DIGEST_CTX ctx = NULL; if (fd && fd->digests) ctx = rpmDigestBundleDupCtx(fd->digests, id); return ctx; }