/* file_wrappers.c * * Wiretap Library * Copyright (c) 1998 by Gilbert Ramirez * * SPDX-License-Identifier: GPL-2.0-or-later */ /* file_access interface based heavily on zlib gzread.c and gzlib.c from zlib * Copyright (C) 1995-2010 Jean-loup Gailly and Mark Adler * under licence: * * SPDX-License-Identifier: Zlib * */ #include #include #include #include "wtap-int.h" #include "file_wrappers.h" #include #ifdef HAVE_ZLIB #define ZLIB_CONST #include #endif /* HAVE_ZLIB */ /* * See RFC 1952: * * https://tools.ietf.org/html/rfc1952 * * for a description of the gzip file format. * * Some other compressed file formats we might want to support: * * XZ format: http://tukaani.org/xz/ * * Bzip2 format: http://bzip.org/ * * Lzip format: http://www.nongnu.org/lzip/ */ /* * List of compression types supported. */ static struct compression_type { wtap_compression_type type; const char *extension; const char *description; } compression_types[] = { #ifdef HAVE_ZLIB { WTAP_GZIP_COMPRESSED, "gz", "gzip compressed" }, #endif { WTAP_UNCOMPRESSED, NULL, NULL } }; wtap_compression_type wtap_get_compression_type(wtap *wth) { gboolean is_compressed; is_compressed = file_iscompressed((wth->fh == NULL) ? wth->random_fh : wth->fh); return is_compressed ? WTAP_GZIP_COMPRESSED : WTAP_UNCOMPRESSED; } const char * wtap_compression_type_description(wtap_compression_type compression_type) { for (struct compression_type *p = compression_types; p->type != WTAP_UNCOMPRESSED; p++) { if (p->type == compression_type) return p->description; } return NULL; } const char * wtap_compression_type_extension(wtap_compression_type compression_type) { for (struct compression_type *p = compression_types; p->type != WTAP_UNCOMPRESSED; p++) { if (p->type == compression_type) return p->extension; } return NULL; } GSList * wtap_get_all_compression_type_extensions_list(void) { GSList *extensions; extensions = NULL; /* empty list, to start with */ for (struct compression_type *p = compression_types; p->type != WTAP_UNCOMPRESSED; p++) extensions = g_slist_prepend(extensions, (gpointer)p->extension); return extensions; } /* #define GZBUFSIZE 8192 */ #define GZBUFSIZE 4096 /* values for wtap_reader compression */ typedef enum { UNKNOWN, /* unknown - look for a gzip header */ UNCOMPRESSED, /* uncompressed - copy input directly */ #ifdef HAVE_ZLIB ZLIB, /* decompress a zlib stream */ GZIP_AFTER_HEADER #endif } compression_t; struct wtap_reader_buf { guint8 *buf; /* buffer */ guint8 *next; /* next byte to deliver from buffer */ guint avail; /* number of bytes available to deliver at next */ }; struct wtap_reader { int fd; /* file descriptor */ gint64 raw_pos; /* current position in file (just to not call lseek()) */ gint64 pos; /* current position in uncompressed data */ guint size; /* buffer size */ struct wtap_reader_buf in; /* input buffer, containing compressed data */ struct wtap_reader_buf out; /* output buffer, containing uncompressed data */ gboolean eof; /* TRUE if end of input file reached */ gint64 start; /* where the gzip data started, for rewinding */ gint64 raw; /* where the raw data started, for seeking */ compression_t compression; /* type of compression, if any */ gboolean is_compressed; /* FALSE if completely uncompressed, TRUE otherwise */ /* seek request */ gint64 skip; /* amount to skip (already rewound if backwards) */ gboolean seek_pending; /* TRUE if seek request pending */ /* error information */ int err; /* error code */ const char *err_info; /* additional error information string for some errors */ #ifdef HAVE_ZLIB /* zlib inflate stream */ z_stream strm; /* stream structure in-place (not a pointer) */ gboolean dont_check_crc; /* TRUE if we aren't supposed to check the CRC */ #endif /* fast seeking */ GPtrArray *fast_seek; void *fast_seek_cur; }; /* Current read offset within a buffer. */ static guint offset_in_buffer(struct wtap_reader_buf *buf) { /* buf->next points to the next byte to read, and buf->buf points to the first byte in the buffer, so the difference between them is the offset. This will fit in an unsigned int, because it can't be bigger than the size of the buffer, which is an unsigned int. */ return (guint)(buf->next - buf->buf); } /* Number of bytes of data that are in a buffer. */ static guint bytes_in_buffer(struct wtap_reader_buf *buf) { /* buf->next + buf->avail points just past the last byte of data in the buffer. Thus, (buf->next + buf->avail) - buf->buf is the number of bytes of data in the buffer. This will fit in an unsigned int, because it can't be bigger than the size of the buffer, which is an unsigned int. */ return (guint)((buf->next + buf->avail) - buf->buf); } /* Reset a buffer, discarding all data in the buffer, so we read into it starting at the beginning. */ static void buf_reset(struct wtap_reader_buf *buf) { buf->next = buf->buf; buf->avail = 0; } static int buf_read(FILE_T state, struct wtap_reader_buf *buf) { guint space_left, to_read; unsigned char *read_ptr; ssize_t ret; /* How much space is left at the end of the buffer? XXX - the output buffer actually has state->size * 2 bytes. */ space_left = state->size - bytes_in_buffer(buf); if (space_left == 0) { /* There's no space left, so we start fresh at the beginning of the buffer. */ buf_reset(buf); read_ptr = buf->buf; to_read = state->size; } else { /* There's some space left; try to read as much data as we can into that space. We may get less than that if we're reading from a pipe or if we're near the end of the file. */ read_ptr = buf->next + buf->avail; to_read = space_left; } ret = ws_read(state->fd, read_ptr, to_read); if (ret < 0) { state->err = errno; state->err_info = NULL; return -1; } if (ret == 0) state->eof = TRUE; state->raw_pos += ret; buf->avail += ret; return 0; } static int /* gz_avail */ fill_in_buffer(FILE_T state) { if (state->err != 0) return -1; if (!state->eof) { if (buf_read(state, &state->in) < 0) return -1; } return 0; } #define ZLIB_WINSIZE 32768 struct fast_seek_point { gint64 out; /* corresponding offset in uncompressed data */ gint64 in; /* offset in input file of first full byte */ compression_t compression; union { struct { #ifdef HAVE_INFLATEPRIME int bits; /* number of bits (1-7) from byte at in - 1, or 0 */ #endif unsigned char window[ZLIB_WINSIZE]; /* preceding 32K of uncompressed data */ /* be gentle with Z_STREAM_END, 8 bytes more... Another solution would be to comment checks out */ guint32 adler; guint32 total_out; } zlib; } data; }; struct zlib_cur_seek_point { unsigned char window[ZLIB_WINSIZE]; /* preceding 32K of uncompressed data */ unsigned int pos; unsigned int have; }; #define SPAN G_GINT64_CONSTANT(1048576) static struct fast_seek_point * fast_seek_find(FILE_T file, gint64 pos) { struct fast_seek_point *smallest = NULL; struct fast_seek_point *item; guint low, i, max; if (!file->fast_seek) return NULL; for (low = 0, max = file->fast_seek->len; low < max; ) { i = (low + max) / 2; item = (struct fast_seek_point *)file->fast_seek->pdata[i]; if (pos < item->out) max = i; else if (pos > item->out) { smallest = item; low = i + 1; } else { return item; } } return smallest; } static void fast_seek_header(FILE_T file, gint64 in_pos, gint64 out_pos, compression_t compression) { struct fast_seek_point *item = NULL; if (file->fast_seek->len != 0) item = (struct fast_seek_point *)file->fast_seek->pdata[file->fast_seek->len - 1]; if (!item || item->out < out_pos) { struct fast_seek_point *val = g_new(struct fast_seek_point,1); val->in = in_pos; val->out = out_pos; val->compression = compression; g_ptr_array_add(file->fast_seek, val); } } static void fast_seek_reset( #ifdef HAVE_ZLIB FILE_T state) #else FILE_T state _U_) #endif { #ifdef HAVE_ZLIB if (state->compression == ZLIB && state->fast_seek_cur != NULL) { struct zlib_cur_seek_point *cur = (struct zlib_cur_seek_point *) state->fast_seek_cur; cur->have = 0; } #endif } #ifdef HAVE_ZLIB /* Get next byte from input, or -1 if end or error. * * Note: * * 1) errors from buf_read(), and thus from fill_in_buffer(), are * "sticky", and fill_in_buffer() won't do any reading if there's * an error; * * 2) GZ_GETC() returns -1 on an EOF; * * so it's safe to make multiple GZ_GETC() calls and only check the * last one for an error. */ #define GZ_GETC() ((state->in.avail == 0 && fill_in_buffer(state) == -1) ? -1 : \ (state->in.avail == 0 ? -1 : \ (state->in.avail--, *(state->in.next)++))) /* Get a one-byte integer and return 0 on success and the value in *ret. Otherwise -1 is returned, state->err is set, and *ret is not modified. */ static int gz_next1(FILE_T state, guint8 *ret) { int ch; ch = GZ_GETC(); if (ch == -1) { if (state->err == 0) { /* EOF */ state->err = WTAP_ERR_SHORT_READ; state->err_info = NULL; } return -1; } *ret = ch; return 0; } /* Get a two-byte little-endian integer and return 0 on success and the value in *ret. Otherwise -1 is returned, state->err is set, and *ret is not modified. */ static int gz_next2(FILE_T state, guint16 *ret) { guint16 val; int ch; val = GZ_GETC(); ch = GZ_GETC(); if (ch == -1) { if (state->err == 0) { /* EOF */ state->err = WTAP_ERR_SHORT_READ; state->err_info = NULL; } return -1; } val += (guint16)ch << 8; *ret = val; return 0; } /* Get a four-byte little-endian integer and return 0 on success and the value in *ret. Otherwise -1 is returned, state->err is set, and *ret is not modified. */ static int gz_next4(FILE_T state, guint32 *ret) { guint32 val; int ch; val = GZ_GETC(); val += (unsigned)GZ_GETC() << 8; val += (guint32)GZ_GETC() << 16; ch = GZ_GETC(); if (ch == -1) { if (state->err == 0) { /* EOF */ state->err = WTAP_ERR_SHORT_READ; state->err_info = NULL; } return -1; } val += (guint32)ch << 24; *ret = val; return 0; } /* Skip the specified number of bytes and return 0 on success. Otherwise -1 is returned. */ static int gz_skipn(FILE_T state, size_t n) { while (n != 0) { if (GZ_GETC() == -1) { if (state->err == 0) { /* EOF */ state->err = WTAP_ERR_SHORT_READ; state->err_info = NULL; } return -1; } n--; } return 0; } /* Skip a null-terminated string and return 0 on success. Otherwise -1 is returned. */ static int gz_skipzstr(FILE_T state) { int ch; /* It's null-terminated, so scan until we read a byte with the value 0 or get an error. */ while ((ch = GZ_GETC()) > 0) ; if (ch == -1) { if (state->err == 0) { /* EOF */ state->err = WTAP_ERR_SHORT_READ; state->err_info = NULL; } return -1; } return 0; } static void zlib_fast_seek_add(FILE_T file, struct zlib_cur_seek_point *point, int bits, gint64 in_pos, gint64 out_pos) { /* it's for sure after gzip header, so file->fast_seek->len != 0 */ struct fast_seek_point *item = (struct fast_seek_point *)file->fast_seek->pdata[file->fast_seek->len - 1]; #ifndef HAVE_INFLATEPRIME if (bits) return; #endif /* Glib has got Balanced Binary Trees (GTree) but I couldn't find a way to do quick search for nearest (and smaller) value to seek (It's what fast_seek_find() do) * Inserting value in middle of sorted array is expensive, so we want to add only in the end. * It's not big deal, cause first-read don't usually invoke seeking */ if (item->out + SPAN < out_pos) { struct fast_seek_point *val = g_new(struct fast_seek_point,1); val->in = in_pos; val->out = out_pos; val->compression = ZLIB; #ifdef HAVE_INFLATEPRIME val->data.zlib.bits = bits; #endif if (point->pos != 0) { unsigned int left = ZLIB_WINSIZE - point->pos; memcpy(val->data.zlib.window, point->window + point->pos, left); memcpy(val->data.zlib.window + left, point->window, point->pos); } else memcpy(val->data.zlib.window, point->window, ZLIB_WINSIZE); /* * XXX - strm.adler is a uLong in at least some versions * of zlib, and uLong is an unsigned long in at least * some of those versions, which means it's 64-bit * on LP64 platforms, even though the checksum is * 32-bit. We assume the actual Adler checksum * is in the lower 32 bits of strm.adler; as the * checksum in the file is only 32 bits, we save only * those lower 32 bits, and cast away any additional * bits to squelch warnings. * * The same applies to strm.total_out. */ val->data.zlib.adler = (guint32) file->strm.adler; val->data.zlib.total_out = (guint32) file->strm.total_out; g_ptr_array_add(file->fast_seek, val); } } static void /* gz_decomp */ zlib_read(FILE_T state, unsigned char *buf, unsigned int count) { int ret = 0; /* XXX */ guint32 crc, len; z_streamp strm = &(state->strm); unsigned char *buf2 = buf; unsigned int count2 = count; strm->avail_out = count; strm->next_out = buf; /* fill output buffer up to end of deflate stream or error */ do { /* get more input for inflate() */ if (state->in.avail == 0 && fill_in_buffer(state) == -1) break; if (state->in.avail == 0) { /* EOF */ state->err = WTAP_ERR_SHORT_READ; state->err_info = NULL; break; } strm->avail_in = state->in.avail; strm->next_in = state->in.next; /* decompress and handle errors */ #ifdef Z_BLOCK ret = inflate(strm, Z_BLOCK); #else ret = inflate(strm, Z_NO_FLUSH); #endif state->in.avail = strm->avail_in; #ifdef z_const DIAG_OFF(cast-qual) state->in.next = (unsigned char *)strm->next_in; DIAG_ON(cast-qual) #else state->in.next = strm->next_in; #endif if (ret == Z_STREAM_ERROR) { state->err = WTAP_ERR_DECOMPRESS; state->err_info = strm->msg; break; } if (ret == Z_NEED_DICT) { state->err = WTAP_ERR_DECOMPRESS; state->err_info = "preset dictionary needed"; break; } if (ret == Z_MEM_ERROR) { /* This means "not enough memory". */ state->err = ENOMEM; state->err_info = NULL; break; } if (ret == Z_DATA_ERROR) { /* deflate stream invalid */ state->err = WTAP_ERR_DECOMPRESS; state->err_info = strm->msg; break; } /* * XXX - Z_BUF_ERROR? */ strm->adler = crc32(strm->adler, buf2, count2 - strm->avail_out); #ifdef Z_BLOCK if (state->fast_seek_cur != NULL) { struct zlib_cur_seek_point *cur = (struct zlib_cur_seek_point *) state->fast_seek_cur; unsigned int ready = count2 - strm->avail_out; if (ready < ZLIB_WINSIZE) { guint left = ZLIB_WINSIZE - cur->pos; if (ready >= left) { memcpy(cur->window + cur->pos, buf2, left); if (ready != left) memcpy(cur->window, buf2 + left, ready - left); cur->pos = ready - left; cur->have += ready; } else { memcpy(cur->window + cur->pos, buf2, ready); cur->pos += ready; cur->have += ready; } if (cur->have >= ZLIB_WINSIZE) cur->have = ZLIB_WINSIZE; } else { memcpy(cur->window, buf2 + (ready - ZLIB_WINSIZE), ZLIB_WINSIZE); cur->pos = 0; cur->have = ZLIB_WINSIZE; } if (cur->have >= ZLIB_WINSIZE && ret != Z_STREAM_END && (strm->data_type & 128) && !(strm->data_type & 64)) zlib_fast_seek_add(state, cur, (strm->data_type & 7), state->raw_pos - strm->avail_in, state->pos + (count - strm->avail_out)); } #endif buf2 = (buf2 + count2 - strm->avail_out); count2 = strm->avail_out; } while (strm->avail_out && ret != Z_STREAM_END); /* update available output and crc check value */ state->out.next = buf; state->out.avail = count - strm->avail_out; /* Check gzip trailer if at end of deflate stream. We don't fail immediately here, we just set an error indication, so that we try to process what data we got before the error. The next attempt to read something past that data will get the error. */ if (ret == Z_STREAM_END) { if (gz_next4(state, &crc) != -1 && gz_next4(state, &len) != -1) { if (crc != strm->adler && !state->dont_check_crc) { state->err = WTAP_ERR_DECOMPRESS; state->err_info = "bad CRC"; } else if (len != (strm->total_out & 0xffffffffUL)) { state->err = WTAP_ERR_DECOMPRESS; state->err_info = "length field wrong"; } } state->compression = UNKNOWN; /* ready for next stream, once have is 0 */ g_free(state->fast_seek_cur); state->fast_seek_cur = NULL; } } #endif static int gz_head(FILE_T state) { guint already_read; /* get some data in the input buffer */ if (state->in.avail == 0) { if (fill_in_buffer(state) == -1) return -1; if (state->in.avail == 0) return 0; } /* look for the gzip magic header bytes 31 and 139 */ if (state->in.next[0] == 31) { state->in.avail--; state->in.next++; if (state->in.avail == 0 && fill_in_buffer(state) == -1) return -1; if (state->in.avail != 0 && state->in.next[0] == 139) { #ifdef HAVE_ZLIB guint8 cm; guint8 flags; guint16 len; guint16 hcrc; /* we have a gzip header, woo hoo! */ state->in.avail--; state->in.next++; /* read rest of header */ /* compression method (CM) */ if (gz_next1(state, &cm) == -1) return -1; if (cm != 8) { state->err = WTAP_ERR_DECOMPRESS; state->err_info = "unknown compression method"; return -1; } /* flags (FLG) */ if (gz_next1(state, &flags) == -1) return -1; if (flags & 0xe0) { /* reserved flag bits */ state->err = WTAP_ERR_DECOMPRESS; state->err_info = "reserved flag bits set"; return -1; } /* modification time (MTIME) */ if (gz_skipn(state, 4) == -1) return -1; /* extra flags (XFL) */ if (gz_skipn(state, 1) == -1) return -1; /* operating system (OS) */ if (gz_skipn(state, 1) == -1) return -1; if (flags & 4) { /* extra field - get XLEN */ if (gz_next2(state, &len) == -1) return -1; /* skip the extra field */ if (gz_skipn(state, len) == -1) return -1; } if (flags & 8) { /* file name */ if (gz_skipzstr(state) == -1) return -1; } if (flags & 16) { /* comment */ if (gz_skipzstr(state) == -1) return -1; } if (flags & 2) { /* header crc */ if (gz_next2(state, &hcrc) == -1) return -1; /* XXX - check the CRC? */ } /* set up for decompression */ inflateReset(&(state->strm)); state->strm.adler = crc32(0L, Z_NULL, 0); state->compression = ZLIB; state->is_compressed = TRUE; #ifdef Z_BLOCK if (state->fast_seek) { struct zlib_cur_seek_point *cur = g_new(struct zlib_cur_seek_point,1); cur->pos = cur->have = 0; g_free(state->fast_seek_cur); state->fast_seek_cur = cur; fast_seek_header(state, state->raw_pos - state->in.avail, state->pos, GZIP_AFTER_HEADER); } #endif /* Z_BLOCK */ return 0; #else /* HAVE_ZLIB */ state->err = WTAP_ERR_DECOMPRESSION_NOT_SUPPORTED; state->err_info = "reading gzip-compressed files isn't supported"; return -1; #endif /* HAVE_ZLIB */ } } #ifdef HAVE_LIBXZ /* { 0xFD, '7', 'z', 'X', 'Z', 0x00 } */ /* FD 37 7A 58 5A 00 */ #endif if (state->fast_seek) fast_seek_header(state, state->raw_pos - state->in.avail - state->out.avail, state->pos, UNCOMPRESSED); /* doing raw i/o, save start of raw data for seeking, copy any leftover input to output -- this assumes that the output buffer is larger than the input buffer, which also assures space for gzungetc() */ state->raw = state->pos; state->out.next = state->out.buf; /* not a compressed file -- copy everything we've read into the input buffer to the output buffer and fall to raw i/o */ already_read = bytes_in_buffer(&state->in); if (already_read != 0) { memcpy(state->out.buf, state->in.buf, already_read); state->out.avail = already_read; /* Now discard everything in the input buffer */ buf_reset(&state->in); } state->compression = UNCOMPRESSED; return 0; } static int /* gz_make */ fill_out_buffer(FILE_T state) { if (state->compression == UNKNOWN) { /* look for gzip header */ if (gz_head(state) == -1) return -1; if (state->out.avail != 0) /* got some data from gz_head() */ return 0; } if (state->compression == UNCOMPRESSED) { /* straight copy */ if (buf_read(state, &state->out) < 0) return -1; } #ifdef HAVE_ZLIB else if (state->compression == ZLIB) { /* decompress */ zlib_read(state, state->out.buf, state->size << 1); } #endif return 0; } static int gz_skip(FILE_T state, gint64 len) { guint n; /* skip over len bytes or reach end-of-file, whichever comes first */ while (len) if (state->out.avail != 0) { /* We have stuff in the output buffer; skip over it. */ n = (gint64)state->out.avail > len ? (unsigned)len : state->out.avail; state->out.avail -= n; state->out.next += n; state->pos += n; len -= n; } else if (state->err != 0) { /* We have nothing in the output buffer, and we have an error that may not have been reported yet; that means we can't generate any more data into the output buffer, so return an error indication. */ return -1; } else if (state->eof && state->in.avail == 0) { /* We have nothing in the output buffer, and we're at the end of the input; just return. */ break; } else { /* We have nothing in the output buffer, and we can generate more data; get more output, looking for header if required. */ if (fill_out_buffer(state) == -1) return -1; } return 0; } static void gz_reset(FILE_T state) { buf_reset(&state->out); /* no output data available */ state->eof = FALSE; /* not at end of file */ state->compression = UNKNOWN; /* look for gzip header */ state->seek_pending = FALSE; /* no seek request pending */ state->err = 0; /* clear error */ state->err_info = NULL; state->pos = 0; /* no uncompressed data yet */ buf_reset(&state->in); /* no input data yet */ } FILE_T file_fdopen(int fd) { /* * XXX - we now check whether we have st_blksize in struct stat; * it's not available on all platforms. * * I'm not sure why we're testing _STATBUF_ST_BLKSIZE; it's not * set on all platforms that have st_blksize in struct stat. * (Not all platforms have st_blksize in struct stat.) * * Is there some reason *not* to make the buffer size the maximum * of GBUFSIZE and st_blksize? On most UN*Xes, the standard I/O * library does I/O with st_blksize as the buffer size; on others, * and on Windows, it's a 4K buffer size. If st_blksize is bigger * than GBUFSIZE (which is currently 4KB), that's probably a * hint that reading in st_blksize chunks is considered a good * idea (e.g., an 8K/1K Berkeley fast file system with st_blksize * being 8K, or APFS, where st_blksize is big on at least some * versions of macOS). */ #ifdef _STATBUF_ST_BLKSIZE ws_statb64 st; #endif int want = GZBUFSIZE; FILE_T state; if (fd == -1) return NULL; /* allocate FILE_T structure to return */ state = (FILE_T)g_try_malloc0(sizeof *state); if (state == NULL) return NULL; state->fast_seek_cur = NULL; state->fast_seek = NULL; /* open the file with the appropriate mode (or just use fd) */ state->fd = fd; /* we don't yet know whether it's compressed */ state->is_compressed = FALSE; /* save the current position for rewinding (only if reading) */ state->start = ws_lseek64(state->fd, 0, SEEK_CUR); if (state->start == -1) state->start = 0; state->raw_pos = state->start; /* initialize stream */ gz_reset(state); #ifdef _STATBUF_ST_BLKSIZE if (ws_fstat64(fd, &st) >= 0) { /* * Yes, st_blksize can be bigger than an int; apparently, * it's a long on LP64 Linux, for example. * * If the value is too big to fit into an int, just * use the default. */ if (st.st_blksize <= G_MAXINT) want = (int)st.st_blksize; /* XXX, verify result? */ } #endif /* allocate buffers */ state->in.buf = (unsigned char *)g_try_malloc((gsize)want); state->in.next = state->in.buf; state->in.avail = 0; state->out.buf = (unsigned char *)g_try_malloc(((gsize)want) << 1); state->out.next = state->out.buf; state->out.avail = 0; state->size = want; if (state->in.buf == NULL || state->out.buf == NULL) { g_free(state->out.buf); g_free(state->in.buf); g_free(state); errno = ENOMEM; return NULL; } #ifdef HAVE_ZLIB /* allocate inflate memory */ state->strm.zalloc = Z_NULL; state->strm.zfree = Z_NULL; state->strm.opaque = Z_NULL; state->strm.avail_in = 0; state->strm.next_in = Z_NULL; if (inflateInit2(&(state->strm), -15) != Z_OK) { /* raw inflate */ g_free(state->out.buf); g_free(state->in.buf); g_free(state); errno = ENOMEM; return NULL; } /* for now, assume we should check the crc */ state->dont_check_crc = FALSE; #endif /* return stream */ return state; } FILE_T file_open(const char *path) { int fd; FILE_T ft; #ifdef HAVE_ZLIB const char *suffixp; #endif /* open file and do correct filename conversions. XXX - do we need O_LARGEFILE? On UN*X, if we need to do something special to get large file support, the configure script should have set us up with the appropriate #defines, so we should be getting a large-file-enabled file descriptor here. Pre-Large File Summit UN*Xes, and possibly even some post-LFS UN*Xes, might require O_LARGEFILE here, though. If so, we should probably handle that in ws_open(). */ if ((fd = ws_open(path, O_RDONLY|O_BINARY, 0000)) == -1) return NULL; /* open file handle */ ft = file_fdopen(fd); if (ft == NULL) { ws_close(fd); return NULL; } #ifdef HAVE_ZLIB /* * If this file's name ends in ".caz", it's probably a compressed * Windows Sniffer file. The compression is gzip, but if we * process the CRC as specified by RFC 1952, the computed CRC * doesn't match the stored CRC. * * Compressed Windows Sniffer files don't all have the same CRC * value; is it just random crap, or are they running the CRC on * a different set of data than you're supposed to (e.g., not * CRCing some of the data), or something such as that? * * For now, we just set a flag to ignore CRC errors. */ suffixp = strrchr(path, '.'); if (suffixp != NULL) { if (g_ascii_strcasecmp(suffixp, ".caz") == 0) ft->dont_check_crc = TRUE; } #endif return ft; } void file_set_random_access(FILE_T stream, gboolean random_flag _U_, GPtrArray *seek) { stream->fast_seek = seek; } gint64 file_seek(FILE_T file, gint64 offset, int whence, int *err) { struct fast_seek_point *here; guint n; if (whence != SEEK_SET && whence != SEEK_CUR && whence != SEEK_END) { g_assert_not_reached(); /* *err = EINVAL; return -1; */ } /* Normalize offset to a SEEK_CUR specification */ if (whence == SEEK_END) { /* Seek relative to the end of the file; given that we might be reading from a compressed file, we do that by seeking to the end of the file, making an offset relative to the end of the file an offset relative to the current position. XXX - we don't actually use this yet, but, for uncompressed files, we could optimize it, if desired, by directly using ws_lseek64(). */ if (gz_skip(file, G_MAXINT64) == -1) { *err = file->err; return -1; } if (offset == 0) { /* We are done */ return file->pos; } } else if (whence == SEEK_SET) offset -= file->pos; else if (file->seek_pending) { /* There's a forward-skip pending, so file->pos doesn't reflect the actual file position, it represents the position from which we're skipping; update the offset to include that. */ offset += file->skip; } file->seek_pending = FALSE; /* * Are we moving at all? */ if (offset == 0) { /* No. Just return the current position. */ return file->pos; } /* * Are we seeking backwards? */ if (offset < 0) { /* * Yes. * * Do we have enough data before the current position in the * buffer that we can seek backwards within the buffer? */ if (-offset <= offset_in_buffer(&file->out)) { /* * Yes. Adjust appropriately. * * offset is negative, so -offset is non-negative, and * -offset is <= an unsigned and thus fits in an unsigned. * Get that value and adjust appropriately. * * (Casting offset to unsigned makes it positive, which * is not what we would want, so we cast -offset instead.) * * XXX - this won't work with -offset = 2^63, as its * negative isn't a valid 64-bit integer, but we are * not at all likely to see files big enough to ever * see a negative offset that large. */ guint adjustment = (unsigned)(-offset); file->out.avail += adjustment; file->out.next -= adjustment; file->pos -= adjustment; return file->pos; } } else { /* * No. Offset is positive; we're seeking forwards. * * Do we have enough data after the current position in the * buffer that we can seek forwards within the buffer? */ if (offset < file->out.avail) { /* * Yes. Adjust appropriately. * * offset is < an unsigned and thus fits in an unsigned, * so we can cast it to guint safely. */ file->out.avail -= (guint)offset; file->out.next += offset; file->pos += offset; return file->pos; } } /* * We're not seeking within the buffer. Do we have "fast seek" data * for the location to which we will be seeking, and is the offset * outside the span for compressed files or is this an uncompressed * file? * * XXX, profile */ if ((here = fast_seek_find(file, file->pos + offset)) && (offset < 0 || offset > SPAN || here->compression == UNCOMPRESSED)) { gint64 off, off2; /* * Yes. Use that data to do the seek. * Note that this will be true only if file_set_random_access() * has been called on this file, which should never be the case * for a pipe. */ #ifdef HAVE_ZLIB if (here->compression == ZLIB) { #ifdef HAVE_INFLATEPRIME off = here->in - (here->data.zlib.bits ? 1 : 0); #else off = here->in; #endif off2 = here->out; } else if (here->compression == GZIP_AFTER_HEADER) { off = here->in; off2 = here->out; } else #endif { off2 = (file->pos + offset); off = here->in + (off2 - here->out); } if (ws_lseek64(file->fd, off, SEEK_SET) == -1) { *err = errno; return -1; } fast_seek_reset(file); file->raw_pos = off; buf_reset(&file->out); file->eof = FALSE; file->seek_pending = FALSE; file->err = 0; file->err_info = NULL; buf_reset(&file->in); #ifdef HAVE_ZLIB if (here->compression == ZLIB) { z_stream *strm = &file->strm; inflateReset(strm); strm->adler = here->data.zlib.adler; strm->total_out = here->data.zlib.total_out; #ifdef HAVE_INFLATEPRIME if (here->data.zlib.bits) { FILE_T state = file; int ret = GZ_GETC(); if (ret == -1) { if (state->err == 0) { /* EOF */ *err = WTAP_ERR_SHORT_READ; } else *err = state->err; return -1; } (void)inflatePrime(strm, here->data.zlib.bits, ret >> (8 - here->data.zlib.bits)); } #endif (void)inflateSetDictionary(strm, here->data.zlib.window, ZLIB_WINSIZE); file->compression = ZLIB; } else if (here->compression == GZIP_AFTER_HEADER) { z_stream *strm = &file->strm; inflateReset(strm); strm->adler = crc32(0L, Z_NULL, 0); file->compression = ZLIB; } else #endif file->compression = here->compression; offset = (file->pos + offset) - off2; file->pos = off2; /* g_print("OK! %ld\n", offset); */ if (offset) { /* Don't skip forward yet, wait until we want to read from the file; that way, if we do multiple seeks in a row, all involving forward skips, they will be combined. */ file->seek_pending = TRUE; file->skip = offset; } return file->pos + offset; } /* * Is this an uncompressed file, are we within the raw area, * are we either seeking backwards or seeking past the end * of the buffer, and are we set up for random access with * file_set_random_access()? * * Again, note that this will never be true on a pipe, as * file_set_random_access() should never be called if we're * reading from a pipe. */ if (file->compression == UNCOMPRESSED && file->pos + offset >= file->raw && (offset < 0 || offset >= file->out.avail) && (file->fast_seek != NULL)) { /* * Yes. Just seek there within the file. */ if (ws_lseek64(file->fd, offset - file->out.avail, SEEK_CUR) == -1) { *err = errno; return -1; } file->raw_pos += (offset - file->out.avail); buf_reset(&file->out); file->eof = FALSE; file->seek_pending = FALSE; file->err = 0; file->err_info = NULL; buf_reset(&file->in); file->pos += offset; return file->pos; } /* * Are we seeking backwards? */ if (offset < 0) { /* * Yes. We have no fast seek data, so we have to rewind and * seek forward. * XXX - true only for compressed files. * * Calculate the amount to skip forward after rewinding. */ offset += file->pos; if (offset < 0) { /* before start of file! */ *err = EINVAL; return -1; } /* rewind, then skip to offset */ /* back up and start over */ if (ws_lseek64(file->fd, file->start, SEEK_SET) == -1) { *err = errno; return -1; } fast_seek_reset(file); file->raw_pos = file->start; gz_reset(file); } /* * Either we're seeking backwards, but have rewound and now need to * skip forwards, or we're seeking forwards. * * Skip what's in output buffer (one less gzgetc() check). */ n = (gint64)file->out.avail > offset ? (unsigned)offset : file->out.avail; file->out.avail -= n; file->out.next += n; file->pos += n; offset -= n; /* request skip (if not zero) */ if (offset) { /* Don't skip forward yet, wait until we want to read from the file; that way, if we do multiple seeks in a row, all involving forward skips, they will be combined. */ file->seek_pending = TRUE; file->skip = offset; } return file->pos + offset; } gint64 file_tell(FILE_T stream) { /* return position */ return stream->pos + (stream->seek_pending ? stream->skip : 0); } gint64 file_tell_raw(FILE_T stream) { return stream->raw_pos; } int file_fstat(FILE_T stream, ws_statb64 *statb, int *err) { if (ws_fstat64(stream->fd, statb) == -1) { if (err != NULL) *err = errno; return -1; } return 0; } gboolean file_iscompressed(FILE_T stream) { return stream->is_compressed; } int file_read(void *buf, unsigned int len, FILE_T file) { guint got, n; /* if len is zero, avoid unnecessary operations */ if (len == 0) return 0; /* process a skip request */ if (file->seek_pending) { file->seek_pending = FALSE; if (gz_skip(file, file->skip) == -1) return -1; } /* * Get len bytes to buf, or less than len if at the end; * if buf is null, just throw the bytes away. */ got = 0; do { if (file->out.avail != 0) { /* We have stuff in the output buffer; copy what we have. */ n = file->out.avail > len ? len : file->out.avail; if (buf != NULL) { memcpy(buf, file->out.next, n); buf = (char *)buf + n; } file->out.next += n; file->out.avail -= n; len -= n; got += n; file->pos += n; } else if (file->err != 0) { /* We have nothing in the output buffer, and we have an error that may not have been reported yet; that means we can't generate any more data into the output buffer, so return an error indication. */ return -1; } else if (file->eof && file->in.avail == 0) { /* We have nothing in the output buffer, and we're at the end of the input; just return with what we've gotten so far. */ break; } else { /* We have nothing in the output buffer, and we can generate more data; get more output, looking for header if required, and keep looping to process the new stuff in the output buffer. */ if (fill_out_buffer(file) == -1) return -1; } } while (len); return (int)got; } /* * XXX - this *peeks* at next byte, not a character. */ int file_peekc(FILE_T file) { int ret = 0; /* check that we're reading and that there's no error */ if (file->err != 0) return -1; /* try output buffer (no need to check for skip request) */ if (file->out.avail != 0) { return *(file->out.next); } /* process a skip request */ if (file->seek_pending) { file->seek_pending = FALSE; if (gz_skip(file, file->skip) == -1) return -1; } /* if we processed a skip request, there may be data in the buffer, * or an error could have occurred; likewise if we didn't do seek but * now call fill_out_buffer, the errors can occur. So we do this while * loop to check before and after - this is basically the logic from * file_read() but only for peeking not consuming a byte */ while (1) { if (file->out.avail != 0) { return *(file->out.next); } else if (file->err != 0) { return -1; } else if (file->eof && file->in.avail == 0) { return -1; } else if (fill_out_buffer(file) == -1) { return -1; } } /* it's actually impossible to get here */ return ret; } /* * XXX - this gets a byte, not a character. */ int file_getc(FILE_T file) { unsigned char buf[1]; int ret; /* check that we're reading and that there's no error */ if (file->err != 0) return -1; /* try output buffer (no need to check for skip request) */ if (file->out.avail != 0) { file->out.avail--; file->pos++; return *(file->out.next)++; } ret = file_read(buf, 1, file); return ret < 1 ? -1 : buf[0]; } /* Like file_gets, but returns a pointer to the terminating NUL. */ char * file_getsp(char *buf, int len, FILE_T file) { guint left, n; char *str; unsigned char *eol; /* check parameters */ if (buf == NULL || len < 1) return NULL; /* check that there's no error */ if (file->err != 0) return NULL; /* process a skip request */ if (file->seek_pending) { file->seek_pending = FALSE; if (gz_skip(file, file->skip) == -1) return NULL; } /* copy output bytes up to new line or len - 1, whichever comes first -- append a terminating zero to the string (we don't check for a zero in the contents, let the user worry about that) */ str = buf; left = (unsigned)len - 1; if (left) do { /* assure that something is in the output buffer */ if (file->out.avail == 0) { /* We have nothing in the output buffer. */ if (file->err != 0) { /* We have an error that may not have been reported yet; that means we can't generate any more data into the output buffer, so return an error indication. */ return NULL; } if (fill_out_buffer(file) == -1) return NULL; /* error */ if (file->out.avail == 0) { /* end of file */ if (buf == str) /* got bupkus */ return NULL; break; /* got something -- return it */ } } /* look for end-of-line in current output buffer */ n = file->out.avail > left ? left : file->out.avail; eol = (unsigned char *)memchr(file->out.next, '\n', n); if (eol != NULL) n = (unsigned)(eol - file->out.next) + 1; /* copy through end-of-line, or remainder if not found */ memcpy(buf, file->out.next, n); file->out.avail -= n; file->out.next += n; file->pos += n; left -= n; buf += n; } while (left && eol == NULL); /* found end-of-line or out of space -- add a terminator and return a pointer to it */ buf[0] = 0; return buf; } char * file_gets(char *buf, int len, FILE_T file) { if (!file_getsp(buf, len, file)) return NULL; return buf; } int file_eof(FILE_T file) { /* return end-of-file state */ return (file->eof && file->in.avail == 0 && file->out.avail == 0); } /* * Routine to return a Wiretap error code (0 for no error, an errno * for a file error, or a WTAP_ERR_ code for other errors) for an * I/O stream. Also returns an error string for some errors. */ int file_error(FILE_T fh, gchar **err_info) { if (fh->err!=0 && err_info) { /* g_strdup() returns NULL for NULL argument */ *err_info = g_strdup(fh->err_info); } return fh->err; } void file_clearerr(FILE_T stream) { /* clear error and end-of-file */ stream->err = 0; stream->err_info = NULL; stream->eof = FALSE; } void file_fdclose(FILE_T file) { ws_close(file->fd); file->fd = -1; } gboolean file_fdreopen(FILE_T file, const char *path) { int fd; if ((fd = ws_open(path, O_RDONLY|O_BINARY, 0000)) == -1) return FALSE; file->fd = fd; return TRUE; } void file_close(FILE_T file) { int fd = file->fd; /* free memory and close file */ if (file->size) { #ifdef HAVE_ZLIB inflateEnd(&(file->strm)); #endif g_free(file->out.buf); g_free(file->in.buf); } g_free(file->fast_seek_cur); file->err = 0; file->err_info = NULL; g_free(file); /* * If fd is -1, somebody's done a file_closefd() on us, so * we don't need to close the FD itself, and shouldn't do * so. */ if (fd != -1) ws_close(fd); } #ifdef HAVE_ZLIB /* internal gzip file state data structure for writing */ struct wtap_writer { int fd; /* file descriptor */ gint64 pos; /* current position in uncompressed data */ guint size; /* buffer size, zero if not allocated yet */ guint want; /* requested buffer size, default is GZBUFSIZE */ unsigned char *in; /* input buffer */ unsigned char *out; /* output buffer (double-sized when reading) */ unsigned char *next; /* next output data to deliver or write */ int level; /* compression level */ int strategy; /* compression strategy */ int err; /* error code */ /* zlib deflate stream */ z_stream strm; /* stream structure in-place (not a pointer) */ }; GZWFILE_T gzwfile_open(const char *path) { int fd; GZWFILE_T state; int save_errno; fd = ws_open(path, O_BINARY|O_WRONLY|O_CREAT|O_TRUNC, 0666); if (fd == -1) return NULL; state = gzwfile_fdopen(fd); if (state == NULL) { save_errno = errno; ws_close(fd); errno = save_errno; } return state; } GZWFILE_T gzwfile_fdopen(int fd) { GZWFILE_T state; /* allocate wtap_writer structure to return */ state = (GZWFILE_T)g_try_malloc(sizeof *state); if (state == NULL) return NULL; state->fd = fd; state->size = 0; /* no buffers allocated yet */ state->want = GZBUFSIZE; /* requested buffer size */ state->level = Z_DEFAULT_COMPRESSION; state->strategy = Z_DEFAULT_STRATEGY; /* initialize stream */ state->err = Z_OK; /* clear error */ state->pos = 0; /* no uncompressed data yet */ state->strm.avail_in = 0; /* no input data yet */ /* return stream */ return state; } /* Initialize state for writing a gzip file. Mark initialization by setting state->size to non-zero. Return -1, and set state->err, on failure; return 0 on success. */ static int gz_init(GZWFILE_T state) { int ret; z_streamp strm = &(state->strm); /* allocate input and output buffers */ state->in = (unsigned char *)g_try_malloc(state->want); state->out = (unsigned char *)g_try_malloc(state->want); if (state->in == NULL || state->out == NULL) { g_free(state->out); g_free(state->in); state->err = ENOMEM; return -1; } /* allocate deflate memory, set up for gzip compression */ strm->zalloc = Z_NULL; strm->zfree = Z_NULL; strm->opaque = Z_NULL; ret = deflateInit2(strm, state->level, Z_DEFLATED, 15 + 16, 8, state->strategy); if (ret != Z_OK) { g_free(state->out); g_free(state->in); if (ret == Z_MEM_ERROR) { /* This means "not enough memory". */ state->err = ENOMEM; } else { /* This "shouldn't happen". */ state->err = WTAP_ERR_INTERNAL; } return -1; } /* mark state as initialized */ state->size = state->want; /* initialize write buffer */ strm->avail_out = state->size; strm->next_out = state->out; state->next = strm->next_out; return 0; } /* Compress whatever is at avail_in and next_in and write to the output file. Return -1, and set state->err, if there is an error writing to the output file; return 0 on success. flush is assumed to be a valid deflate() flush value. If flush is Z_FINISH, then the deflate() state is reset to start a new gzip stream. */ static int gz_comp(GZWFILE_T state, int flush) { int ret; ssize_t got; ptrdiff_t have; z_streamp strm = &(state->strm); /* allocate memory if this is the first time through */ if (state->size == 0 && gz_init(state) == -1) return -1; /* run deflate() on provided input until it produces no more output */ ret = Z_OK; do { /* write out current buffer contents if full, or if flushing, but if doing Z_FINISH then don't write until we get to Z_STREAM_END */ if (strm->avail_out == 0 || (flush != Z_NO_FLUSH && (flush != Z_FINISH || ret == Z_STREAM_END))) { have = strm->next_out - state->next; if (have) { got = ws_write(state->fd, state->next, (unsigned int)have); if (got < 0) { state->err = errno; return -1; } if ((ptrdiff_t)got != have) { state->err = WTAP_ERR_SHORT_WRITE; return -1; } } if (strm->avail_out == 0) { strm->avail_out = state->size; strm->next_out = state->out; } state->next = strm->next_out; } /* compress */ have = strm->avail_out; ret = deflate(strm, flush); if (ret == Z_STREAM_ERROR) { /* This "shouldn't happen". */ state->err = WTAP_ERR_INTERNAL; return -1; } have -= strm->avail_out; } while (have); /* if that completed a deflate stream, allow another to start */ if (flush == Z_FINISH) deflateReset(strm); /* all done, no errors */ return 0; } /* Write out len bytes from buf. Return 0, and set state->err, on failure or on an attempt to write 0 bytes (in which case state->err is Z_OK); return the number of bytes written on success. */ unsigned gzwfile_write(GZWFILE_T state, const void *buf, guint len) { guint put = len; guint n; z_streamp strm; strm = &(state->strm); /* check that there's no error */ if (state->err != Z_OK) return 0; /* if len is zero, avoid unnecessary operations */ if (len == 0) return 0; /* allocate memory if this is the first time through */ if (state->size == 0 && gz_init(state) == -1) return 0; /* for small len, copy to input buffer, otherwise compress directly */ if (len < state->size) { /* copy to input buffer, compress when full */ do { if (strm->avail_in == 0) strm->next_in = state->in; n = state->size - strm->avail_in; if (n > len) n = len; #ifdef z_const DIAG_OFF(cast-qual) memcpy((Bytef *)strm->next_in + strm->avail_in, buf, n); DIAG_ON(cast-qual) #else memcpy(strm->next_in + strm->avail_in, buf, n); #endif strm->avail_in += n; state->pos += n; buf = (const char *)buf + n; len -= n; if (len && gz_comp(state, Z_NO_FLUSH) == -1) return 0; } while (len); } else { /* consume whatever's left in the input buffer */ if (strm->avail_in != 0 && gz_comp(state, Z_NO_FLUSH) == -1) return 0; /* directly compress user buffer to file */ strm->avail_in = len; #ifdef z_const strm->next_in = (z_const Bytef *)buf; #else DIAG_OFF(cast-qual) strm->next_in = (Bytef *)buf; DIAG_ON(cast-qual) #endif state->pos += len; if (gz_comp(state, Z_NO_FLUSH) == -1) return 0; } /* input was all buffered or compressed (put will fit in int) */ return (int)put; } /* Flush out what we've written so far. Returns -1, and sets state->err, on failure; returns 0 on success. */ int gzwfile_flush(GZWFILE_T state) { /* check that there's no error */ if (state->err != Z_OK) return -1; /* compress remaining data with Z_SYNC_FLUSH */ gz_comp(state, Z_SYNC_FLUSH); if (state->err != Z_OK) return -1; return 0; } /* Flush out all data written, and close the file. Returns a Wiretap error on failure; returns 0 on success. */ int gzwfile_close(GZWFILE_T state) { int ret = 0; /* flush, free memory, and close file */ if (gz_comp(state, Z_FINISH) == -1 && ret == 0) ret = state->err; (void)deflateEnd(&(state->strm)); g_free(state->out); g_free(state->in); state->err = Z_OK; if (ws_close(state->fd) == -1 && ret == 0) ret = errno; g_free(state); return ret; } int gzwfile_geterr(GZWFILE_T state) { return state->err; } #endif /* * Editor modelines - http://www.wireshark.org/tools/modelines.html * * Local variables: * c-basic-offset: 4 * tab-width: 8 * indent-tabs-mode: nil * End: * * vi: set shiftwidth=4 tabstop=8 expandtab: * :indentSize=4:tabSize=8:noTabs=true: */