/* zip_dirent.c -- read directory entry (local or central), clean dirent Copyright (C) 1999-2013 Dieter Baron and Thomas Klausner This file is part of libzip, a library to manipulate ZIP archives. The authors can be contacted at Redistribution and use in source and binary forms, with or without modification, are permitted provided that the following conditions are met: 1. Redistributions of source code must retain the above copyright notice, this list of conditions and the following disclaimer. 2. Redistributions in binary form must reproduce the above copyright notice, this list of conditions and the following disclaimer in the documentation and/or other materials provided with the distribution. 3. The names of the authors may not be used to endorse or promote products derived from this software without specific prior written permission. THIS SOFTWARE IS PROVIDED BY THE AUTHORS ``AS IS'' AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL THE AUTHORS BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE. */ #include #include #include #include #include #include #include "zipint.h" static time_t _zip_d2u_time(zip_uint16_t, zip_uint16_t); static struct zip_string *_zip_read_string(const unsigned char **, FILE *, zip_uint16_t, int, struct zip_error *); static struct zip_string *_zip_dirent_process_ef_utf_8(const struct zip_dirent *, zip_uint16_t, struct zip_string *); static struct zip_extra_field *_zip_ef_utf8(zip_uint16_t, struct zip_string *, struct zip_error *); void _zip_cdir_free(struct zip_cdir *cd) { zip_uint64_t i; if (!cd) return; for (i=0; inentry; i++) _zip_entry_finalize(cd->entry+i); free(cd->entry); _zip_string_free(cd->comment); free(cd); } int _zip_cdir_grow(struct zip_cdir *cd, zip_uint64_t nentry, struct zip_error *error) { struct zip_entry *entry; zip_uint64_t i; if (nentry < cd->nentry_alloc) { _zip_error_set(error, ZIP_ER_INTERNAL, 0); return -1; } if (nentry == cd->nentry_alloc) return 0; if ((entry=((struct zip_entry *) realloc(cd->entry, sizeof(*(cd->entry))*nentry))) == NULL) { _zip_error_set(error, ZIP_ER_MEMORY, 0); return -1; } for (i=cd->nentry_alloc; inentry_alloc = nentry; cd->entry = entry; return 0; } struct zip_cdir * _zip_cdir_new(zip_uint64_t nentry, struct zip_error *error) { struct zip_cdir *cd; zip_uint64_t i; if ((cd=(struct zip_cdir *)malloc(sizeof(*cd))) == NULL) { _zip_error_set(error, ZIP_ER_MEMORY, 0); return NULL; } if (nentry == 0) cd->entry = NULL; else if ((cd->entry=(struct zip_entry *)malloc(sizeof(*(cd->entry))*nentry)) == NULL) { _zip_error_set(error, ZIP_ER_MEMORY, 0); free(cd); return NULL; } for (i=0; ientry+i); cd->nentry = cd->nentry_alloc = nentry; cd->size = cd->offset = 0; cd->comment = NULL; return cd; } zip_int64_t _zip_cdir_write(struct zip *za, const struct zip_filelist *filelist, zip_uint64_t survivors, FILE *fp) { off_t off; zip_uint64_t offset, size; struct zip_string *comment; zip_uint64_t i; int is_zip64; int ret; if ((off=ftello(fp)) < 0) { _zip_error_set(&za->error, ZIP_ER_READ, errno); return -1; } offset = (zip_uint64_t)off; is_zip64 = 0; for (i=0; ientry+filelist[i].idx; if ((ret=_zip_dirent_write(entry->changes ? entry->changes : entry->orig, fp, ZIP_FL_CENTRAL, &za->error)) < 0) return -1; if (ret) is_zip64 = 1; } if ((off=ftello(fp)) < 0) { _zip_error_set(&za->error, ZIP_ER_READ, errno); return -1; } size = (zip_uint64_t)off - offset; if (offset > ZIP_UINT32_MAX || survivors > ZIP_UINT16_MAX) is_zip64 = 1; if (is_zip64) { fwrite(EOCD64_MAGIC, 1, 4, fp); _zip_write8(EOCD64LEN-12, fp); _zip_write2(45, fp); _zip_write2(45, fp); _zip_write4(0, fp); _zip_write4(0, fp); _zip_write8(survivors, fp); _zip_write8(survivors, fp); _zip_write8(size, fp); _zip_write8(offset, fp); fwrite(EOCD64LOC_MAGIC, 1, 4, fp); _zip_write4(0, fp); _zip_write8(offset+size, fp); _zip_write4(1, fp); } /* clearerr(fp); */ fwrite(EOCD_MAGIC, 1, 4, fp); _zip_write4(0, fp); _zip_write2(survivors >= ZIP_UINT16_MAX ? ZIP_UINT16_MAX : (zip_uint16_t)survivors, fp); _zip_write2(survivors >= ZIP_UINT16_MAX ? ZIP_UINT16_MAX : (zip_uint16_t)survivors, fp); _zip_write4(size >= ZIP_UINT32_MAX ? ZIP_UINT32_MAX : (zip_uint32_t)size, fp); _zip_write4(offset >= ZIP_UINT32_MAX ? ZIP_UINT32_MAX : (zip_uint32_t)offset, fp); comment = za->comment_changed ? za->comment_changes : za->comment_orig; _zip_write2(comment ? comment->length : 0, fp); if (comment) fwrite(comment->raw, 1, comment->length, fp); if (ferror(fp)) { _zip_error_set(&za->error, ZIP_ER_WRITE, errno); return -1; } return (zip_int64_t)size; } struct zip_dirent * _zip_dirent_clone(const struct zip_dirent *sde) { struct zip_dirent *tde; if ((tde=(struct zip_dirent *)malloc(sizeof(*tde))) == NULL) return NULL; if (sde) memcpy(tde, sde, sizeof(*sde)); else _zip_dirent_init(tde); tde->changed = 0; tde->cloned = 1; return tde; } void _zip_dirent_finalize(struct zip_dirent *zde) { if (!zde->cloned || zde->changed & ZIP_DIRENT_FILENAME) _zip_string_free(zde->filename); if (!zde->cloned || zde->changed & ZIP_DIRENT_EXTRA_FIELD) _zip_ef_free(zde->extra_fields); if (!zde->cloned || zde->changed & ZIP_DIRENT_COMMENT) _zip_string_free(zde->comment); } void _zip_dirent_free(struct zip_dirent *zde) { if (zde == NULL) return; _zip_dirent_finalize(zde); free(zde); } void _zip_dirent_init(struct zip_dirent *de) { de->changed = 0; de->local_extra_fields_read = 0; de->cloned = 0; de->version_madeby = 20; de->version_needed = 20; /* 2.0 */ de->bitflags = 0; de->comp_method = ZIP_CM_DEFAULT; de->last_mod = 0; de->crc = 0; de->comp_size = 0; de->uncomp_size = 0; de->filename = NULL; de->extra_fields = NULL; de->comment = NULL; de->disk_number = 0; de->int_attrib = 0; de->ext_attrib = 0; de->offset = 0; } int _zip_dirent_needs_zip64(const struct zip_dirent *de, zip_flags_t flags) { if (de->uncomp_size >= ZIP_UINT32_MAX || de->comp_size >= ZIP_UINT32_MAX || ((flags & ZIP_FL_CENTRAL) && de->offset >= ZIP_UINT32_MAX)) return 1; return 0; } struct zip_dirent * _zip_dirent_new(void) { struct zip_dirent *de; if ((de=(struct zip_dirent *)malloc(sizeof(*de))) == NULL) return NULL; _zip_dirent_init(de); return de; } /* _zip_dirent_read(zde, fp, bufp, left, localp, error): Fills the zip directory entry zde. If bufp is non-NULL, data is taken from there and bufp is advanced by the amount of data used; otherwise data is read from fp as needed. if leftp is non-NULL, no more bytes than specified by it are used, and *leftp is reduced by the number of bytes used. If local != 0, it reads a local header instead of a central directory entry. Returns 0 if successful. On error, error is filled in and -1 is returned. XXX: leftp and file position undefined on error. */ int _zip_dirent_read(struct zip_dirent *zde, FILE *fp, const unsigned char **bufp, zip_uint64_t *leftp, int local, struct zip_error *error) { unsigned char buf[CDENTRYSIZE]; const unsigned char *cur; zip_uint16_t dostime, dosdate; zip_uint32_t size; zip_uint16_t filename_len, comment_len, ef_len; if (local) size = LENTRYSIZE; else size = CDENTRYSIZE; if (leftp && (*leftp < size)) { _zip_error_set(error, ZIP_ER_NOZIP, 0); return -1; } if (bufp) { /* use data from buffer */ cur = *bufp; } else { /* read entry from disk */ if ((fread(buf, 1, size, fp)version_madeby = _zip_read2(&cur); else zde->version_madeby = 0; zde->version_needed = _zip_read2(&cur); zde->bitflags = _zip_read2(&cur); zde->comp_method = _zip_read2(&cur); /* convert to time_t */ dostime = _zip_read2(&cur); dosdate = _zip_read2(&cur); zde->last_mod = _zip_d2u_time(dostime, dosdate); zde->crc = _zip_read4(&cur); zde->comp_size = _zip_read4(&cur); zde->uncomp_size = _zip_read4(&cur); filename_len = _zip_read2(&cur); ef_len = _zip_read2(&cur); if (local) { comment_len = 0; zde->disk_number = 0; zde->int_attrib = 0; zde->ext_attrib = 0; zde->offset = 0; } else { comment_len = _zip_read2(&cur); zde->disk_number = _zip_read2(&cur); zde->int_attrib = _zip_read2(&cur); zde->ext_attrib = _zip_read4(&cur); zde->offset = _zip_read4(&cur); } zde->filename = NULL; zde->extra_fields = NULL; zde->comment = NULL; size += filename_len+ef_len+comment_len; if (leftp && (*leftp < size)) { _zip_error_set(error, ZIP_ER_INCONS, 0); return -1; } if (filename_len) { zde->filename = _zip_read_string(bufp ? &cur : NULL, fp, filename_len, 1, error); if (!zde->filename) return -1; if (zde->bitflags & ZIP_GPBF_ENCODING_UTF_8) { if (_zip_guess_encoding(zde->filename, ZIP_ENCODING_UTF8_KNOWN) == ZIP_ENCODING_ERROR) { _zip_error_set(error, ZIP_ER_INCONS, 0); return -1; } } } if (ef_len) { zip_uint8_t *ef = _zip_read_data(bufp ? &cur : NULL, fp, ef_len, 0, error); if (ef == NULL) return -1; if ((zde->extra_fields=_zip_ef_parse(ef, ef_len, local ? ZIP_EF_LOCAL : ZIP_EF_CENTRAL, error)) == NULL) { free(ef); return -1; } free(ef); if (local) zde->local_extra_fields_read = 1; } if (comment_len) { zde->comment = _zip_read_string(bufp ? &cur : NULL, fp, comment_len, 0, error); if (!zde->comment) return -1; if (zde->bitflags & ZIP_GPBF_ENCODING_UTF_8) { if (_zip_guess_encoding(zde->comment, ZIP_ENCODING_UTF8_KNOWN) == ZIP_ENCODING_ERROR) { _zip_error_set(error, ZIP_ER_INCONS, 0); return -1; } } } zde->filename = _zip_dirent_process_ef_utf_8(zde, ZIP_EF_UTF_8_NAME, zde->filename); zde->comment = _zip_dirent_process_ef_utf_8(zde, ZIP_EF_UTF_8_COMMENT, zde->comment); /* Zip64 */ if (zde->uncomp_size == ZIP_UINT32_MAX || zde->comp_size == ZIP_UINT32_MAX || zde->offset == ZIP_UINT32_MAX) { zip_uint16_t got_len, needed_len; const zip_uint8_t *ef = _zip_ef_get_by_id(zde->extra_fields, &got_len, ZIP_EF_ZIP64, 0, local ? ZIP_EF_LOCAL : ZIP_EF_CENTRAL, error); /* XXX: if got_len == 0 && !ZIP64_EOCD: no error, 0xffffffff is valid value */ if (ef == NULL) return -1; if (local) needed_len = 16; else needed_len = ((zde->uncomp_size == ZIP_UINT32_MAX) + (zde->comp_size == ZIP_UINT32_MAX) + (zde->offset == ZIP_UINT32_MAX)) * 8 + (zde->disk_number == ZIP_UINT16_MAX) * 4; if (got_len != needed_len) { _zip_error_set(error, ZIP_ER_INCONS, 0); return -1; } if (zde->uncomp_size == ZIP_UINT32_MAX) zde->uncomp_size = _zip_read8(&ef); else if (local) ef += 8; if (zde->comp_size == ZIP_UINT32_MAX) zde->comp_size = _zip_read8(&ef); if (!local) { if (zde->offset == ZIP_UINT32_MAX) zde->offset = _zip_read8(&ef); if (zde->disk_number == ZIP_UINT16_MAX) zde->disk_number = _zip_read4(&ef); } } if (!local) { if (zde->offset > ZIP_OFF_MAX) { _zip_error_set(error, ZIP_ER_SEEK, EFBIG); return -1; } } zde->extra_fields = _zip_ef_remove_internal(zde->extra_fields); if (bufp) *bufp = cur; if (leftp) *leftp -= size; return 0; } static struct zip_string * _zip_dirent_process_ef_utf_8(const struct zip_dirent *de, zip_uint16_t id, struct zip_string *str) { zip_uint16_t ef_len; zip_uint32_t ef_crc; const zip_uint8_t *ef = _zip_ef_get_by_id(de->extra_fields, &ef_len, id, 0, ZIP_EF_BOTH, NULL); if (ef == NULL || ef_len < 5 || ef[0] != 1) return str; ef++; ef_crc = _zip_read4(&ef); if (_zip_string_crc32(str) == ef_crc) { struct zip_string *ef_str = _zip_string_new(ef, ef_len-5, ZIP_ENCODING_UTF8_KNOWN, NULL); if (ef_str != NULL) { _zip_string_free(str); str = ef_str; } } return str; } zip_int32_t _zip_dirent_size(FILE *f, zip_uint16_t flags, struct zip_error *error) { zip_int32_t size; int local = (flags & ZIP_EF_LOCAL); int i; unsigned char b[6]; const unsigned char *p; size = local ? LENTRYSIZE : CDENTRYSIZE; if (fseek(f, local ? 26 : 28, SEEK_CUR) < 0) { _zip_error_set(error, ZIP_ER_SEEK, errno); return -1; } if (fread(b, (local ? 4 : 6), 1, f) != 1) { _zip_error_set(error, ZIP_ER_READ, errno); return -1; } p = b; for (i=0; i<(local ? 2 : 3); i++) { size += _zip_read2(&p); } return size; } /* _zip_dirent_torrent_normalize(de); Set values suitable for torrentzip. */ void _zip_dirent_torrent_normalize(struct zip_dirent *de) { static struct tm torrenttime; static time_t last_mod = 0; if (last_mod == 0) { #ifdef HAVE_STRUCT_TM_TM_ZONE time_t now; struct tm *l; #endif torrenttime.tm_sec = 0; torrenttime.tm_min = 32; torrenttime.tm_hour = 23; torrenttime.tm_mday = 24; torrenttime.tm_mon = 11; torrenttime.tm_year = 96; torrenttime.tm_wday = 0; torrenttime.tm_yday = 0; torrenttime.tm_isdst = 0; #ifdef HAVE_STRUCT_TM_TM_ZONE time(&now); l = localtime(&now); torrenttime.tm_gmtoff = l->tm_gmtoff; torrenttime.tm_zone = l->tm_zone; #endif last_mod = mktime(&torrenttime); } de->version_madeby = 0; de->version_needed = 20; /* 2.0 */ de->bitflags = 2; /* maximum compression */ de->comp_method = ZIP_CM_DEFLATE; de->last_mod = last_mod; de->disk_number = 0; de->int_attrib = 0; de->ext_attrib = 0; _zip_ef_free(de->extra_fields); de->extra_fields = NULL; _zip_string_free(de->comment); de->comment = NULL; } /* _zip_dirent_write(zde, fp, flags, error): Writes zip directory entry zde to file fp. If flags & ZIP_EF_LOCAL, it writes a local header instead of a central directory entry. If flags & ZIP_EF_FORCE_ZIP64, a ZIP64 extra field is written, even if not needed. Returns 0 if successful, 1 if successful and wrote ZIP64 extra field. On error, error is filled in and -1 is returned. */ int _zip_dirent_write(struct zip_dirent *de, FILE *fp, zip_flags_t flags, struct zip_error *error) { unsigned short dostime, dosdate; enum zip_encoding_type com_enc, name_enc; struct zip_extra_field *ef; zip_uint8_t ef_zip64[24], *ef_zip64_p; int is_zip64; int is_really_zip64; ef = NULL; is_zip64 = 0; fwrite((flags & ZIP_FL_LOCAL) ? LOCAL_MAGIC : CENTRAL_MAGIC, 1, 4, fp); name_enc = _zip_guess_encoding(de->filename, ZIP_ENCODING_UNKNOWN); com_enc = _zip_guess_encoding(de->comment, ZIP_ENCODING_UNKNOWN); if ((name_enc == ZIP_ENCODING_UTF8_KNOWN && com_enc == ZIP_ENCODING_ASCII) || (name_enc == ZIP_ENCODING_ASCII && com_enc == ZIP_ENCODING_UTF8_KNOWN) || (name_enc == ZIP_ENCODING_UTF8_KNOWN && com_enc == ZIP_ENCODING_UTF8_KNOWN)) de->bitflags |= ZIP_GPBF_ENCODING_UTF_8; else { de->bitflags &= ~ZIP_GPBF_ENCODING_UTF_8; if (name_enc == ZIP_ENCODING_UTF8_KNOWN) { ef = _zip_ef_utf8(ZIP_EF_UTF_8_NAME, de->filename, error); if (ef == NULL) return -1; } if ((flags & ZIP_FL_LOCAL) == 0 && com_enc == ZIP_ENCODING_UTF8_KNOWN){ struct zip_extra_field *ef2 = _zip_ef_utf8(ZIP_EF_UTF_8_COMMENT, de->comment, error); if (ef2 == NULL) { _zip_ef_free(ef); return -1; } ef2->next = ef; ef = ef2; } } ef_zip64_p = ef_zip64; if (flags & ZIP_FL_LOCAL) { if ((flags & ZIP_FL_FORCE_ZIP64) || de->comp_size > ZIP_UINT32_MAX || de->uncomp_size > ZIP_UINT32_MAX) { _zip_poke8(de->comp_size, &ef_zip64_p); _zip_poke8(de->uncomp_size, &ef_zip64_p); } } else { if ((flags & ZIP_FL_FORCE_ZIP64) || de->comp_size > ZIP_UINT32_MAX || de->uncomp_size > ZIP_UINT32_MAX || de->offset > ZIP_UINT32_MAX) { if (de->comp_size >= ZIP_UINT32_MAX) _zip_poke8(de->comp_size, &ef_zip64_p); if (de->uncomp_size >= ZIP_UINT32_MAX) _zip_poke8(de->uncomp_size, &ef_zip64_p); if (de->offset >= ZIP_UINT32_MAX) _zip_poke8(de->offset, &ef_zip64_p); } } if (ef_zip64_p != ef_zip64) { struct zip_extra_field *ef64 = _zip_ef_new(ZIP_EF_ZIP64, (zip_uint16_t)(ef_zip64_p-ef_zip64), ef_zip64, ZIP_EF_BOTH); ef64->next = ef; ef = ef64; is_zip64 = 1; } if ((flags & (ZIP_FL_LOCAL|ZIP_FL_FORCE_ZIP64)) == (ZIP_FL_LOCAL|ZIP_FL_FORCE_ZIP64)) is_really_zip64 = _zip_dirent_needs_zip64(de, flags); else is_really_zip64 = is_zip64; if ((flags & ZIP_FL_LOCAL) == 0) _zip_write2(is_really_zip64 ? 45 : de->version_madeby, fp); _zip_write2(is_really_zip64 ? 45 : de->version_needed, fp); _zip_write2(de->bitflags&0xfff9, fp); /* clear compression method specific flags */ _zip_write2((zip_uint16_t)de->comp_method, fp); /* XXX: can it be ZIP_CM_DEFAULT? */ _zip_u2d_time(de->last_mod, &dostime, &dosdate); _zip_write2(dostime, fp); _zip_write2(dosdate, fp); _zip_write4(de->crc, fp); if (de->comp_size < ZIP_UINT32_MAX) _zip_write4((zip_uint32_t)de->comp_size, fp); else _zip_write4(ZIP_UINT32_MAX, fp); if (de->uncomp_size < ZIP_UINT32_MAX) _zip_write4((zip_uint32_t)de->uncomp_size, fp); else _zip_write4(ZIP_UINT32_MAX, fp); _zip_write2(_zip_string_length(de->filename), fp); _zip_write2(_zip_ef_size(de->extra_fields, flags) + _zip_ef_size(ef, ZIP_EF_BOTH), fp); if ((flags & ZIP_FL_LOCAL) == 0) { _zip_write2(_zip_string_length(de->comment), fp); _zip_write2((zip_uint16_t)de->disk_number, fp); _zip_write2(de->int_attrib, fp); _zip_write4(de->ext_attrib, fp); if (de->offset < ZIP_UINT32_MAX) _zip_write4((zip_uint32_t)de->offset, fp); else _zip_write4(ZIP_UINT32_MAX, fp); } if (de->filename) _zip_string_write(de->filename, fp); if (ef) _zip_ef_write(ef, ZIP_EF_BOTH, fp); if (de->extra_fields) _zip_ef_write(de->extra_fields, flags, fp); if ((flags & ZIP_FL_LOCAL) == 0) { if (de->comment) _zip_string_write(de->comment, fp); } _zip_ef_free(ef); if (ferror(fp)) { _zip_error_set(error, ZIP_ER_WRITE, errno); return -1; } return is_zip64; } static time_t _zip_d2u_time(zip_uint16_t dtime, zip_uint16_t ddate) { struct tm tm; memset(&tm, 0, sizeof(tm)); /* let mktime decide if DST is in effect */ tm.tm_isdst = -1; tm.tm_year = ((ddate>>9)&127) + 1980 - 1900; tm.tm_mon = ((ddate>>5)&15) - 1; tm.tm_mday = ddate&31; tm.tm_hour = (dtime>>11)&31; tm.tm_min = (dtime>>5)&63; tm.tm_sec = (dtime<<1)&62; return mktime(&tm); } static struct zip_extra_field * _zip_ef_utf8(zip_uint16_t id, struct zip_string *str, struct zip_error *error) { const zip_uint8_t *raw; zip_uint8_t *data, *p; zip_uint32_t len; struct zip_extra_field *ef; raw = _zip_string_get(str, &len, ZIP_FL_ENC_RAW, NULL); if (len+5 > ZIP_UINT16_MAX) { /* XXX: error */ } if ((data=(zip_uint8_t *)malloc(len+5)) == NULL) { _zip_error_set(error, ZIP_ER_MEMORY, 0); return NULL; } p = data; *(p++) = 1; _zip_poke4(_zip_string_crc32(str), &p); memcpy(p, raw, len); p += len; ef = _zip_ef_new(id, (zip_uint16_t)(p-data), data, ZIP_EF_BOTH); free(data); return ef; } struct zip_dirent * _zip_get_dirent(struct zip *za, zip_uint64_t idx, zip_flags_t flags, struct zip_error *error) { if (error == NULL) error = &za->error; if (idx >= za->nentry) { _zip_error_set(error, ZIP_ER_INVAL, 0); return NULL; } if ((flags & ZIP_FL_UNCHANGED) || za->entry[idx].changes == NULL) { if (za->entry[idx].orig == NULL) { _zip_error_set(error, ZIP_ER_INVAL, 0); return NULL; } if (za->entry[idx].deleted && (flags & ZIP_FL_UNCHANGED) == 0) { _zip_error_set(error, ZIP_ER_DELETED, 0); return NULL; } return za->entry[idx].orig; } else return za->entry[idx].changes; } zip_uint16_t _zip_read2(const zip_uint8_t **a) { zip_uint16_t ret; ret = (zip_uint16_t)((*a)[0]+((*a)[1]<<8)); *a += 2; return ret; } zip_uint32_t _zip_read4(const zip_uint8_t **a) { zip_uint32_t ret; ret = ((((((zip_uint32_t)(*a)[3]<<8)+(*a)[2])<<8)+(*a)[1])<<8)+(*a)[0]; *a += 4; return ret; } zip_uint64_t _zip_read8(const zip_uint8_t **a) { zip_uint64_t x, y; x = ((((((zip_uint64_t)(*a)[3]<<8)+(*a)[2])<<8)+(*a)[1])<<8)+(*a)[0]; *a += 4; y = ((((((zip_uint64_t)(*a)[3]<<8)+(*a)[2])<<8)+(*a)[1])<<8)+(*a)[0]; *a += 4; return x+(y<<32); } zip_uint8_t * _zip_read_data(const zip_uint8_t **buf, FILE *fp, size_t len, int nulp, struct zip_error *error) { zip_uint8_t *r; if (len == 0 && nulp == 0) return NULL; r = (zip_uint8_t *)malloc(nulp ? len+1 : len); if (!r) { _zip_error_set(error, ZIP_ER_MEMORY, 0); return NULL; } if (buf) { memcpy(r, *buf, len); *buf += len; } else { if (fread(r, 1, len, fp)>8)&0xff; *((*p)++) = (i>>16)&0xff; *((*p)++) = (i>>24)&0xff; } void _zip_poke8(zip_uint64_t i, zip_uint8_t **p) { *((*p)++) = i&0xff; *((*p)++) = (i>>8)&0xff; *((*p)++) = (i>>16)&0xff; *((*p)++) = (i>>24)&0xff; *((*p)++) = (i>>32)&0xff; *((*p)++) = (i>>40)&0xff; *((*p)++) = (i>>48)&0xff; *((*p)++) = (i>>56)&0xff; } void _zip_write2(zip_uint16_t i, FILE *fp) { putc(i&0xff, fp); putc((i>>8)&0xff, fp); return; } void _zip_write4(zip_uint32_t i, FILE *fp) { putc(i&0xff, fp); putc((i>>8)&0xff, fp); putc((i>>16)&0xff, fp); putc((i>>24)&0xff, fp); return; } void _zip_write8(zip_uint64_t i, FILE *fp) { putc(i&0xff, fp); putc((i>>8)&0xff, fp); putc((i>>16)&0xff, fp); putc((i>>24)&0xff, fp); putc((i>>32)&0xff, fp); putc((i>>40)&0xff, fp); putc((i>>48)&0xff, fp); putc((i>>56)&0xff, fp); return; } void _zip_u2d_time(time_t time, zip_uint16_t *dtime, zip_uint16_t *ddate) { struct tm *tm; tm = localtime(&time); *ddate = (zip_uint16_t)(((tm->tm_year+1900-1980)<<9) + ((tm->tm_mon+1)<<5) + tm->tm_mday); *dtime = (zip_uint16_t)(((tm->tm_hour)<<11) + ((tm->tm_min)<<5) + ((tm->tm_sec)>>1)); return; }