/*- * Copyright (c) 2008 Anselm Strauss * Copyright (c) 2009 Joerg Sonnenberger * Copyright (c) 2011-2012,2014 Michihiro NAKAJIMA * All rights reserved. * * 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. * * THIS SOFTWARE IS PROVIDED BY THE AUTHOR(S) ``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 AUTHOR(S) 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. */ /* * Development supported by Google Summer of Code 2008. */ #include "archive_platform.h" __FBSDID("$FreeBSD: head/lib/libarchive/archive_write_set_format_zip.c 201168 2009-12-29 06:15:32Z kientzle $"); #ifdef HAVE_ERRNO_H #include #endif #ifdef HAVE_LANGINFO_H #include #endif #ifdef HAVE_STDLIB_H #include #endif #ifdef HAVE_STRING_H #include #endif #ifdef HAVE_ZLIB_H #include #endif #include "archive.h" #include "archive_cryptor_private.h" #include "archive_endian.h" #include "archive_entry.h" #include "archive_entry_locale.h" #include "archive_hmac_private.h" #include "archive_private.h" #include "archive_random_private.h" #include "archive_write_private.h" #ifndef HAVE_ZLIB_H #include "archive_crc32.h" #endif #define ZIP_ENTRY_FLAG_ENCRYPTED (1<<0) #define ZIP_ENTRY_FLAG_LENGTH_AT_END (1<<3) #define ZIP_ENTRY_FLAG_UTF8_NAME (1 << 11) enum compression { COMPRESSION_UNSPECIFIED = -1, COMPRESSION_STORE = 0, COMPRESSION_DEFLATE = 8 }; #ifdef HAVE_ZLIB_H #define COMPRESSION_DEFAULT COMPRESSION_DEFLATE #else #define COMPRESSION_DEFAULT COMPRESSION_STORE #endif enum encryption { ENCRYPTION_NONE = 0, ENCRYPTION_TRADITIONAL, /* Traditional PKWARE encryption. */ ENCRYPTION_WINZIP_AES128, /* WinZIP AES-128 encryption. */ ENCRYPTION_WINZIP_AES256, /* WinZIP AES-256 encryption. */ }; #define TRAD_HEADER_SIZE 12 /* * See "WinZip - AES Encryption Information" * http://www.winzip.com/aes_info.htm */ /* Value used in compression method. */ #define WINZIP_AES_ENCRYPTION 99 /* A WinZip AES header size which is stored at the beginning of * file contents. */ #define WINZIP_AES128_HEADER_SIZE (8 + 2) #define WINZIP_AES256_HEADER_SIZE (16 + 2) /* AES vendor version. */ #define AES_VENDOR_AE_1 0x0001 #define AES_VENDOR_AE_2 0x0002 /* Authentication code size. */ #define AUTH_CODE_SIZE 10 /**/ #define MAX_DERIVED_KEY_BUF_SIZE (AES_MAX_KEY_SIZE * 2 + 2) struct cd_segment { struct cd_segment *next; size_t buff_size; unsigned char *buff; unsigned char *p; }; struct trad_enc_ctx { uint32_t keys[3]; }; struct zip { int64_t entry_offset; int64_t entry_compressed_size; int64_t entry_uncompressed_size; int64_t entry_compressed_written; int64_t entry_uncompressed_written; int64_t entry_uncompressed_limit; struct archive_entry *entry; uint32_t entry_crc32; enum compression entry_compression; enum encryption entry_encryption; int entry_flags; int entry_uses_zip64; int experiments; struct trad_enc_ctx tctx; char tctx_valid; unsigned char trad_chkdat; unsigned aes_vendor; archive_crypto_ctx cctx; char cctx_valid; archive_hmac_sha1_ctx hctx; char hctx_valid; unsigned char *file_header; size_t file_header_extra_offset; unsigned long (*crc32func)(unsigned long crc, const void *buff, size_t len); struct cd_segment *central_directory; struct cd_segment *central_directory_last; size_t central_directory_bytes; size_t central_directory_entries; int64_t written_bytes; /* Overall position in file. */ struct archive_string_conv *opt_sconv; struct archive_string_conv *sconv_default; enum compression requested_compression; int deflate_compression_level; int init_default_conversion; enum encryption encryption_type; #define ZIP_FLAG_AVOID_ZIP64 1 #define ZIP_FLAG_FORCE_ZIP64 2 #define ZIP_FLAG_EXPERIMENT_xl 4 int flags; #ifdef HAVE_ZLIB_H z_stream stream; #endif size_t len_buf; unsigned char *buf; }; /* Don't call this min or MIN, since those are already defined on lots of platforms (but not all). */ #define zipmin(a, b) ((a) > (b) ? (b) : (a)) static ssize_t archive_write_zip_data(struct archive_write *, const void *buff, size_t s); static int archive_write_zip_close(struct archive_write *); static int archive_write_zip_free(struct archive_write *); static int archive_write_zip_finish_entry(struct archive_write *); static int archive_write_zip_header(struct archive_write *, struct archive_entry *); static int archive_write_zip_options(struct archive_write *, const char *, const char *); static unsigned int dos_time(const time_t); static size_t path_length(struct archive_entry *); static int write_path(struct archive_entry *, struct archive_write *); static void copy_path(struct archive_entry *, unsigned char *); static struct archive_string_conv *get_sconv(struct archive_write *, struct zip *); static int trad_enc_init(struct trad_enc_ctx *, const char *, size_t); static unsigned trad_enc_encrypt_update(struct trad_enc_ctx *, const uint8_t *, size_t, uint8_t *, size_t); static int init_traditional_pkware_encryption(struct archive_write *); static int is_traditional_pkware_encryption_supported(void); static int init_winzip_aes_encryption(struct archive_write *); static int is_winzip_aes_encryption_supported(int encryption); static unsigned char * cd_alloc(struct zip *zip, size_t length) { unsigned char *p; if (zip->central_directory == NULL || (zip->central_directory_last->p + length > zip->central_directory_last->buff + zip->central_directory_last->buff_size)) { struct cd_segment *segment = calloc(1, sizeof(*segment)); if (segment == NULL) return NULL; segment->buff_size = 64 * 1024; segment->buff = malloc(segment->buff_size); if (segment->buff == NULL) { free(segment); return NULL; } segment->p = segment->buff; if (zip->central_directory == NULL) { zip->central_directory = zip->central_directory_last = segment; } else { zip->central_directory_last->next = segment; zip->central_directory_last = segment; } } p = zip->central_directory_last->p; zip->central_directory_last->p += length; zip->central_directory_bytes += length; return (p); } static unsigned long real_crc32(unsigned long crc, const void *buff, size_t len) { return crc32(crc, buff, (unsigned int)len); } static unsigned long fake_crc32(unsigned long crc, const void *buff, size_t len) { (void)crc; /* UNUSED */ (void)buff; /* UNUSED */ (void)len; /* UNUSED */ return 0; } static int archive_write_zip_options(struct archive_write *a, const char *key, const char *val) { struct zip *zip = a->format_data; int ret = ARCHIVE_FAILED; if (strcmp(key, "compression") == 0) { /* * Set compression to use on all future entries. * This only affects regular files. */ if (val == NULL || val[0] == 0) { archive_set_error(&a->archive, ARCHIVE_ERRNO_MISC, "%s: compression option needs a compression name", a->format_name); } else if (strcmp(val, "deflate") == 0) { #ifdef HAVE_ZLIB_H zip->requested_compression = COMPRESSION_DEFLATE; ret = ARCHIVE_OK; #else archive_set_error(&a->archive, ARCHIVE_ERRNO_MISC, "deflate compression not supported"); #endif } else if (strcmp(val, "store") == 0) { zip->requested_compression = COMPRESSION_STORE; ret = ARCHIVE_OK; } return (ret); } else if (strcmp(key, "compression-level") == 0) { if (val == NULL || !(val[0] >= '0' && val[0] <= '9') || val[1] != '\0') { return ARCHIVE_WARN; } if (val[0] == '0') { zip->requested_compression = COMPRESSION_STORE; return ARCHIVE_OK; } else { #ifdef HAVE_ZLIB_H zip->requested_compression = COMPRESSION_DEFLATE; zip->deflate_compression_level = val[0] - '0'; return ARCHIVE_OK; #else archive_set_error(&a->archive, ARCHIVE_ERRNO_MISC, "deflate compression not supported"); #endif } } else if (strcmp(key, "encryption") == 0) { if (val == NULL) { zip->encryption_type = ENCRYPTION_NONE; ret = ARCHIVE_OK; } else if (val[0] == '1' || strcmp(val, "traditional") == 0 || strcmp(val, "zipcrypt") == 0 || strcmp(val, "ZipCrypt") == 0) { if (is_traditional_pkware_encryption_supported()) { zip->encryption_type = ENCRYPTION_TRADITIONAL; ret = ARCHIVE_OK; } else { archive_set_error(&a->archive, ARCHIVE_ERRNO_MISC, "encryption not supported"); } } else if (strcmp(val, "aes128") == 0) { if (is_winzip_aes_encryption_supported( ENCRYPTION_WINZIP_AES128)) { zip->encryption_type = ENCRYPTION_WINZIP_AES128; ret = ARCHIVE_OK; } else { archive_set_error(&a->archive, ARCHIVE_ERRNO_MISC, "encryption not supported"); } } else if (strcmp(val, "aes256") == 0) { if (is_winzip_aes_encryption_supported( ENCRYPTION_WINZIP_AES256)) { zip->encryption_type = ENCRYPTION_WINZIP_AES256; ret = ARCHIVE_OK; } else { archive_set_error(&a->archive, ARCHIVE_ERRNO_MISC, "encryption not supported"); } } else { archive_set_error(&a->archive, ARCHIVE_ERRNO_MISC, "%s: unknown encryption '%s'", a->format_name, val); } return (ret); } else if (strcmp(key, "experimental") == 0) { if (val == NULL || val[0] == 0) { zip->flags &= ~ ZIP_FLAG_EXPERIMENT_xl; } else { zip->flags |= ZIP_FLAG_EXPERIMENT_xl; } return (ARCHIVE_OK); } else if (strcmp(key, "fakecrc32") == 0) { /* * FOR TESTING ONLY: disable CRC calculation to speed up * certain complex tests. */ if (val == NULL || val[0] == 0) { zip->crc32func = real_crc32; } else { zip->crc32func = fake_crc32; } return (ARCHIVE_OK); } else if (strcmp(key, "hdrcharset") == 0) { /* * Set the character set used in translating filenames. */ if (val == NULL || val[0] == 0) { archive_set_error(&a->archive, ARCHIVE_ERRNO_MISC, "%s: hdrcharset option needs a character-set name", a->format_name); } else { zip->opt_sconv = archive_string_conversion_to_charset( &a->archive, val, 0); if (zip->opt_sconv != NULL) ret = ARCHIVE_OK; else ret = ARCHIVE_FATAL; } return (ret); } else if (strcmp(key, "zip64") == 0) { /* * Bias decisions about Zip64: force them to be * generated in certain cases where they are not * forbidden or avoid them in certain cases where they * are not strictly required. */ if (val != NULL && *val != '\0') { zip->flags |= ZIP_FLAG_FORCE_ZIP64; zip->flags &= ~ZIP_FLAG_AVOID_ZIP64; } else { zip->flags &= ~ZIP_FLAG_FORCE_ZIP64; zip->flags |= ZIP_FLAG_AVOID_ZIP64; } return (ARCHIVE_OK); } /* Note: The "warn" return is just to inform the options * supervisor that we didn't handle it. It will generate * a suitable error if no one used this option. */ return (ARCHIVE_WARN); } int archive_write_zip_set_compression_deflate(struct archive *_a) { struct archive_write *a = (struct archive_write *)_a; int ret = ARCHIVE_FAILED; archive_check_magic(_a, ARCHIVE_WRITE_MAGIC, ARCHIVE_STATE_NEW | ARCHIVE_STATE_HEADER | ARCHIVE_STATE_DATA, "archive_write_zip_set_compression_deflate"); if (a->archive.archive_format != ARCHIVE_FORMAT_ZIP) { archive_set_error(&a->archive, ARCHIVE_ERRNO_MISC, "Can only use archive_write_zip_set_compression_deflate" " with zip format"); ret = ARCHIVE_FATAL; } else { #ifdef HAVE_ZLIB_H struct zip *zip = a->format_data; zip->requested_compression = COMPRESSION_DEFLATE; ret = ARCHIVE_OK; #else archive_set_error(&a->archive, ARCHIVE_ERRNO_MISC, "deflate compression not supported"); ret = ARCHIVE_FAILED; #endif } return (ret); } int archive_write_zip_set_compression_store(struct archive *_a) { struct archive_write *a = (struct archive_write *)_a; struct zip *zip = a->format_data; int ret = ARCHIVE_FAILED; archive_check_magic(_a, ARCHIVE_WRITE_MAGIC, ARCHIVE_STATE_NEW | ARCHIVE_STATE_HEADER | ARCHIVE_STATE_DATA, "archive_write_zip_set_compression_deflate"); if (a->archive.archive_format != ARCHIVE_FORMAT_ZIP) { archive_set_error(&a->archive, ARCHIVE_ERRNO_MISC, "Can only use archive_write_zip_set_compression_store" " with zip format"); ret = ARCHIVE_FATAL; } else { zip->requested_compression = COMPRESSION_STORE; ret = ARCHIVE_OK; } return (ret); } int archive_write_set_format_zip(struct archive *_a) { struct archive_write *a = (struct archive_write *)_a; struct zip *zip; archive_check_magic(_a, ARCHIVE_WRITE_MAGIC, ARCHIVE_STATE_NEW, "archive_write_set_format_zip"); /* If another format was already registered, unregister it. */ if (a->format_free != NULL) (a->format_free)(a); zip = (struct zip *) calloc(1, sizeof(*zip)); if (zip == NULL) { archive_set_error(&a->archive, ENOMEM, "Can't allocate zip data"); return (ARCHIVE_FATAL); } /* "Unspecified" lets us choose the appropriate compression. */ zip->requested_compression = COMPRESSION_UNSPECIFIED; #ifdef HAVE_ZLIB_H zip->deflate_compression_level = Z_DEFAULT_COMPRESSION; #endif zip->crc32func = real_crc32; /* A buffer used for both compression and encryption. */ zip->len_buf = 65536; zip->buf = malloc(zip->len_buf); if (zip->buf == NULL) { free(zip); archive_set_error(&a->archive, ENOMEM, "Can't allocate compression buffer"); return (ARCHIVE_FATAL); } a->format_data = zip; a->format_name = "zip"; a->format_options = archive_write_zip_options; a->format_write_header = archive_write_zip_header; a->format_write_data = archive_write_zip_data; a->format_finish_entry = archive_write_zip_finish_entry; a->format_close = archive_write_zip_close; a->format_free = archive_write_zip_free; a->archive.archive_format = ARCHIVE_FORMAT_ZIP; a->archive.archive_format_name = "ZIP"; return (ARCHIVE_OK); } static int is_all_ascii(const char *p) { const unsigned char *pp = (const unsigned char *)p; while (*pp) { if (*pp++ > 127) return (0); } return (1); } static int archive_write_zip_header(struct archive_write *a, struct archive_entry *entry) { unsigned char local_header[32]; unsigned char local_extra[144]; struct zip *zip = a->format_data; unsigned char *e; unsigned char *cd_extra; size_t filename_length; const char *slink = NULL; size_t slink_size = 0; struct archive_string_conv *sconv = get_sconv(a, zip); int ret, ret2 = ARCHIVE_OK; mode_t type; int version_needed = 10; /* Ignore types of entries that we don't support. */ type = archive_entry_filetype(entry); if (type != AE_IFREG && type != AE_IFDIR && type != AE_IFLNK) { archive_set_error(&a->archive, ARCHIVE_ERRNO_MISC, "Filetype not supported"); return ARCHIVE_FAILED; }; /* If we're not using Zip64, reject large files. */ if (zip->flags & ZIP_FLAG_AVOID_ZIP64) { /* Reject entries over 4GB. */ if (archive_entry_size_is_set(entry) && (archive_entry_size(entry) > 0xffffffff)) { archive_set_error(&a->archive, ARCHIVE_ERRNO_MISC, "Files > 4GB require Zip64 extensions"); return ARCHIVE_FAILED; } /* Reject entries if archive is > 4GB. */ if (zip->written_bytes > 0xffffffff) { archive_set_error(&a->archive, ARCHIVE_ERRNO_MISC, "Archives > 4GB require Zip64 extensions"); return ARCHIVE_FAILED; } } /* Only regular files can have size > 0. */ if (type != AE_IFREG) archive_entry_set_size(entry, 0); /* Reset information from last entry. */ zip->entry_offset = zip->written_bytes; zip->entry_uncompressed_limit = INT64_MAX; zip->entry_compressed_size = 0; zip->entry_uncompressed_size = 0; zip->entry_compressed_written = 0; zip->entry_uncompressed_written = 0; zip->entry_flags = 0; zip->entry_uses_zip64 = 0; zip->entry_crc32 = zip->crc32func(0, NULL, 0); zip->entry_encryption = 0; if (zip->entry != NULL) { archive_entry_free(zip->entry); zip->entry = NULL; } if (zip->cctx_valid) archive_encrypto_aes_ctr_release(&zip->cctx); if (zip->hctx_valid) archive_hmac_sha1_cleanup(&zip->hctx); zip->tctx_valid = zip->cctx_valid = zip->hctx_valid = 0; if (type == AE_IFREG &&(!archive_entry_size_is_set(entry) || archive_entry_size(entry) > 0)) { switch (zip->encryption_type) { case ENCRYPTION_TRADITIONAL: case ENCRYPTION_WINZIP_AES128: case ENCRYPTION_WINZIP_AES256: zip->entry_flags |= ZIP_ENTRY_FLAG_ENCRYPTED; zip->entry_encryption = zip->encryption_type; break; default: break; } } #if defined(_WIN32) && !defined(__CYGWIN__) /* Make sure the path separators in pahtname, hardlink and symlink * are all slash '/', not the Windows path separator '\'. */ zip->entry = __la_win_entry_in_posix_pathseparator(entry); if (zip->entry == entry) zip->entry = archive_entry_clone(entry); #else zip->entry = archive_entry_clone(entry); #endif if (zip->entry == NULL) { archive_set_error(&a->archive, ENOMEM, "Can't allocate zip header data"); return (ARCHIVE_FATAL); } if (sconv != NULL) { const char *p; size_t len; if (archive_entry_pathname_l(entry, &p, &len, sconv) != 0) { if (errno == ENOMEM) { archive_set_error(&a->archive, ENOMEM, "Can't allocate memory for Pathname"); return (ARCHIVE_FATAL); } archive_set_error(&a->archive, ARCHIVE_ERRNO_FILE_FORMAT, "Can't translate Pathname '%s' to %s", archive_entry_pathname(entry), archive_string_conversion_charset_name(sconv)); ret2 = ARCHIVE_WARN; } if (len > 0) archive_entry_set_pathname(zip->entry, p); /* * There is no standard for symlink handling; we convert * it using the same character-set translation that we use * for filename. */ if (type == AE_IFLNK) { if (archive_entry_symlink_l(entry, &p, &len, sconv)) { if (errno == ENOMEM) { archive_set_error(&a->archive, ENOMEM, "Can't allocate memory " " for Symlink"); return (ARCHIVE_FATAL); } /* No error if we can't convert. */ } else if (len > 0) archive_entry_set_symlink(zip->entry, p); } } /* If filename isn't ASCII and we can use UTF-8, set the UTF-8 flag. */ if (!is_all_ascii(archive_entry_pathname(zip->entry))) { if (zip->opt_sconv != NULL) { if (strcmp(archive_string_conversion_charset_name( zip->opt_sconv), "UTF-8") == 0) zip->entry_flags |= ZIP_ENTRY_FLAG_UTF8_NAME; #if HAVE_NL_LANGINFO } else if (strcmp(nl_langinfo(CODESET), "UTF-8") == 0) { zip->entry_flags |= ZIP_ENTRY_FLAG_UTF8_NAME; #endif } } filename_length = path_length(zip->entry); /* Determine appropriate compression and size for this entry. */ if (type == AE_IFLNK) { slink = archive_entry_symlink(zip->entry); if (slink != NULL) slink_size = strlen(slink); else slink_size = 0; zip->entry_uncompressed_limit = slink_size; zip->entry_compressed_size = slink_size; zip->entry_uncompressed_size = slink_size; zip->entry_crc32 = zip->crc32func(zip->entry_crc32, (const unsigned char *)slink, slink_size); zip->entry_compression = COMPRESSION_STORE; version_needed = 20; } else if (type != AE_IFREG) { zip->entry_compression = COMPRESSION_STORE; zip->entry_uncompressed_limit = 0; version_needed = 20; } else if (archive_entry_size_is_set(zip->entry)) { int64_t size = archive_entry_size(zip->entry); int64_t additional_size = 0; zip->entry_uncompressed_limit = size; zip->entry_compression = zip->requested_compression; if (zip->entry_compression == COMPRESSION_UNSPECIFIED) { zip->entry_compression = COMPRESSION_DEFAULT; } if (zip->entry_compression == COMPRESSION_STORE) { zip->entry_compressed_size = size; zip->entry_uncompressed_size = size; version_needed = 10; } else { zip->entry_uncompressed_size = size; version_needed = 20; } if (zip->entry_flags & ZIP_ENTRY_FLAG_ENCRYPTED) { switch (zip->entry_encryption) { case ENCRYPTION_TRADITIONAL: additional_size = TRAD_HEADER_SIZE; version_needed = 20; break; case ENCRYPTION_WINZIP_AES128: additional_size = WINZIP_AES128_HEADER_SIZE + AUTH_CODE_SIZE; version_needed = 20; break; case ENCRYPTION_WINZIP_AES256: additional_size = WINZIP_AES256_HEADER_SIZE + AUTH_CODE_SIZE; version_needed = 20; break; default: break; } if (zip->entry_compression == COMPRESSION_STORE) zip->entry_compressed_size += additional_size; } /* * Set Zip64 extension in any of the following cases * (this was suggested by discussion on info-zip-dev * mailing list): * = Zip64 is being forced by user * = File is over 4GiB uncompressed * (including encryption header, if any) * = File is close to 4GiB and is being compressed * (compression might make file larger) */ if ((zip->flags & ZIP_FLAG_FORCE_ZIP64) || (zip->entry_uncompressed_size + additional_size > 0xffffffffLL) || (zip->entry_uncompressed_size > 0xff000000LL && zip->entry_compression != COMPRESSION_STORE)) { zip->entry_uses_zip64 = 1; version_needed = 45; } /* We may know the size, but never the CRC. */ zip->entry_flags |= ZIP_ENTRY_FLAG_LENGTH_AT_END; } else { /* We don't know the size. In this case, we prefer * deflate (it has a clear end-of-data marker which * makes length-at-end more reliable) and will * enable Zip64 extensions unless we're told not to. */ zip->entry_compression = COMPRESSION_DEFAULT; zip->entry_flags |= ZIP_ENTRY_FLAG_LENGTH_AT_END; if ((zip->flags & ZIP_FLAG_AVOID_ZIP64) == 0) { zip->entry_uses_zip64 = 1; version_needed = 45; } else if (zip->entry_compression == COMPRESSION_STORE) { version_needed = 10; } else { version_needed = 20; } if (zip->entry_flags & ZIP_ENTRY_FLAG_ENCRYPTED) { switch (zip->entry_encryption) { case ENCRYPTION_TRADITIONAL: case ENCRYPTION_WINZIP_AES128: case ENCRYPTION_WINZIP_AES256: if (version_needed < 20) version_needed = 20; break; default: break; } } } /* Format the local header. */ memset(local_header, 0, sizeof(local_header)); memcpy(local_header, "PK\003\004", 4); archive_le16enc(local_header + 4, version_needed); archive_le16enc(local_header + 6, zip->entry_flags); if (zip->entry_encryption == ENCRYPTION_WINZIP_AES128 || zip->entry_encryption == ENCRYPTION_WINZIP_AES256) archive_le16enc(local_header + 8, WINZIP_AES_ENCRYPTION); else archive_le16enc(local_header + 8, zip->entry_compression); archive_le32enc(local_header + 10, dos_time(archive_entry_mtime(zip->entry))); archive_le32enc(local_header + 14, zip->entry_crc32); if (zip->entry_uses_zip64) { /* Zip64 data in the local header "must" include both * compressed and uncompressed sizes AND those fields * are included only if these are 0xffffffff; * THEREFORE these must be set this way, even if we * know one of them is smaller. */ archive_le32enc(local_header + 18, 0xffffffffLL); archive_le32enc(local_header + 22, 0xffffffffLL); } else { archive_le32enc(local_header + 18, (uint32_t)zip->entry_compressed_size); archive_le32enc(local_header + 22, (uint32_t)zip->entry_uncompressed_size); } archive_le16enc(local_header + 26, (uint16_t)filename_length); if (zip->entry_encryption == ENCRYPTION_TRADITIONAL) { if (zip->entry_flags & ZIP_ENTRY_FLAG_LENGTH_AT_END) zip->trad_chkdat = local_header[11]; else zip->trad_chkdat = local_header[17]; } /* Format as much of central directory file header as we can: */ zip->file_header = cd_alloc(zip, 46); /* If (zip->file_header == NULL) XXXX */ ++zip->central_directory_entries; memset(zip->file_header, 0, 46); memcpy(zip->file_header, "PK\001\002", 4); /* "Made by PKZip 2.0 on Unix." */ archive_le16enc(zip->file_header + 4, 3 * 256 + version_needed); archive_le16enc(zip->file_header + 6, version_needed); archive_le16enc(zip->file_header + 8, zip->entry_flags); if (zip->entry_encryption == ENCRYPTION_WINZIP_AES128 || zip->entry_encryption == ENCRYPTION_WINZIP_AES256) archive_le16enc(zip->file_header + 10, WINZIP_AES_ENCRYPTION); else archive_le16enc(zip->file_header + 10, zip->entry_compression); archive_le32enc(zip->file_header + 12, dos_time(archive_entry_mtime(zip->entry))); archive_le16enc(zip->file_header + 28, (uint16_t)filename_length); /* Following Info-Zip, store mode in the "external attributes" field. */ archive_le32enc(zip->file_header + 38, archive_entry_mode(zip->entry) << 16); e = cd_alloc(zip, filename_length); /* If (e == NULL) XXXX */ copy_path(zip->entry, e); /* Format extra data. */ memset(local_extra, 0, sizeof(local_extra)); e = local_extra; /* First, extra blocks that are the same between * the local file header and the central directory. * We format them once and then duplicate them. */ /* UT timestamp, length depends on what timestamps are set. */ memcpy(e, "UT", 2); archive_le16enc(e + 2, 1 + (archive_entry_mtime_is_set(entry) ? 4 : 0) + (archive_entry_atime_is_set(entry) ? 4 : 0) + (archive_entry_ctime_is_set(entry) ? 4 : 0)); e += 4; *e++ = (archive_entry_mtime_is_set(entry) ? 1 : 0) | (archive_entry_atime_is_set(entry) ? 2 : 0) | (archive_entry_ctime_is_set(entry) ? 4 : 0); if (archive_entry_mtime_is_set(entry)) { archive_le32enc(e, (uint32_t)archive_entry_mtime(entry)); e += 4; } if (archive_entry_atime_is_set(entry)) { archive_le32enc(e, (uint32_t)archive_entry_atime(entry)); e += 4; } if (archive_entry_ctime_is_set(entry)) { archive_le32enc(e, (uint32_t)archive_entry_ctime(entry)); e += 4; } /* ux Unix extra data, length 11, version 1 */ /* TODO: If uid < 64k, use 2 bytes, ditto for gid. */ memcpy(e, "ux\013\000\001", 5); e += 5; *e++ = 4; /* Length of following UID */ archive_le32enc(e, (uint32_t)archive_entry_uid(entry)); e += 4; *e++ = 4; /* Length of following GID */ archive_le32enc(e, (uint32_t)archive_entry_gid(entry)); e += 4; /* AES extra data field: WinZIP AES information, ID=0x9901 */ if ((zip->entry_flags & ZIP_ENTRY_FLAG_ENCRYPTED) && (zip->entry_encryption == ENCRYPTION_WINZIP_AES128 || zip->entry_encryption == ENCRYPTION_WINZIP_AES256)) { memcpy(e, "\001\231\007\000\001\000AE", 8); /* AES vendoer version AE-2 does not store a CRC. * WinZip 11 uses AE-1, which does store the CRC, * but it does not store the CRC when the file size * is less than 20 bytes. So we simulate what * WinZip 11 does. * NOTE: WinZip 9.0 and 10.0 uses AE-2 by default. */ if (archive_entry_size_is_set(zip->entry) && archive_entry_size(zip->entry) < 20) { archive_le16enc(e+4, AES_VENDOR_AE_2); zip->aes_vendor = AES_VENDOR_AE_2;/* no CRC. */ } else zip->aes_vendor = AES_VENDOR_AE_1; e += 8; /* AES encryption strength. */ *e++ = (zip->entry_encryption == ENCRYPTION_WINZIP_AES128)?1:3; /* Actual compression method. */ archive_le16enc(e, zip->entry_compression); e += 2; } /* Copy UT ,ux, and AES-extra into central directory as well. */ zip->file_header_extra_offset = zip->central_directory_bytes; cd_extra = cd_alloc(zip, e - local_extra); memcpy(cd_extra, local_extra, e - local_extra); /* * Following extra blocks vary between local header and * central directory. These are the local header versions. * Central directory versions get formatted in * archive_write_zip_finish_entry() below. */ /* "[Zip64 entry] in the local header MUST include BOTH * original [uncompressed] and compressed size fields." */ if (zip->entry_uses_zip64) { unsigned char *zip64_start = e; memcpy(e, "\001\000\020\000", 4); e += 4; archive_le64enc(e, zip->entry_uncompressed_size); e += 8; archive_le64enc(e, zip->entry_compressed_size); e += 8; archive_le16enc(zip64_start + 2, (uint16_t)(e - (zip64_start + 4))); } if (zip->flags & ZIP_FLAG_EXPERIMENT_xl) { /* Experimental 'xl' extension to improve streaming. */ unsigned char *external_info = e; int included = 7; memcpy(e, "xl\000\000", 4); // 0x6c65 + 2-byte length e += 4; e[0] = included; /* bitmap of included fields */ e += 1; if (included & 1) { archive_le16enc(e, /* "Version created by" */ 3 * 256 + version_needed); e += 2; } if (included & 2) { archive_le16enc(e, 0); /* internal file attributes */ e += 2; } if (included & 4) { archive_le32enc(e, /* external file attributes */ archive_entry_mode(zip->entry) << 16); e += 4; } if (included & 8) { // Libarchive does not currently support file comments. } archive_le16enc(external_info + 2, (uint16_t)(e - (external_info + 4))); } /* Update local header with size of extra data and write it all out: */ archive_le16enc(local_header + 28, (uint16_t)(e - local_extra)); ret = __archive_write_output(a, local_header, 30); if (ret != ARCHIVE_OK) return (ARCHIVE_FATAL); zip->written_bytes += 30; ret = write_path(zip->entry, a); if (ret <= ARCHIVE_OK) return (ARCHIVE_FATAL); zip->written_bytes += ret; ret = __archive_write_output(a, local_extra, e - local_extra); if (ret != ARCHIVE_OK) return (ARCHIVE_FATAL); zip->written_bytes += e - local_extra; /* For symlinks, write the body now. */ if (slink != NULL) { ret = __archive_write_output(a, slink, slink_size); if (ret != ARCHIVE_OK) return (ARCHIVE_FATAL); zip->entry_compressed_written += slink_size; zip->entry_uncompressed_written += slink_size; zip->written_bytes += slink_size; } #ifdef HAVE_ZLIB_H if (zip->entry_compression == COMPRESSION_DEFLATE) { zip->stream.zalloc = Z_NULL; zip->stream.zfree = Z_NULL; zip->stream.opaque = Z_NULL; zip->stream.next_out = zip->buf; zip->stream.avail_out = (uInt)zip->len_buf; if (deflateInit2(&zip->stream, zip->deflate_compression_level, Z_DEFLATED, -15, 8, Z_DEFAULT_STRATEGY) != Z_OK) { archive_set_error(&a->archive, ENOMEM, "Can't init deflate compressor"); return (ARCHIVE_FATAL); } } #endif return (ret2); } static ssize_t archive_write_zip_data(struct archive_write *a, const void *buff, size_t s) { int ret; struct zip *zip = a->format_data; if ((int64_t)s > zip->entry_uncompressed_limit) s = (size_t)zip->entry_uncompressed_limit; zip->entry_uncompressed_written += s; if (s == 0) return 0; if (zip->entry_flags & ZIP_ENTRY_FLAG_ENCRYPTED) { switch (zip->entry_encryption) { case ENCRYPTION_TRADITIONAL: /* Initialize traditoinal PKWARE encryption context. */ if (!zip->tctx_valid) { ret = init_traditional_pkware_encryption(a); if (ret != ARCHIVE_OK) return (ret); zip->tctx_valid = 1; } break; case ENCRYPTION_WINZIP_AES128: case ENCRYPTION_WINZIP_AES256: if (!zip->cctx_valid) { ret = init_winzip_aes_encryption(a); if (ret != ARCHIVE_OK) return (ret); zip->cctx_valid = zip->hctx_valid = 1; } break; default: break; } } switch (zip->entry_compression) { case COMPRESSION_STORE: if (zip->tctx_valid || zip->cctx_valid) { const uint8_t *rb = (const uint8_t *)buff; const uint8_t * const re = rb + s; while (rb < re) { size_t l; if (zip->tctx_valid) { l = trad_enc_encrypt_update(&zip->tctx, rb, re - rb, zip->buf, zip->len_buf); } else { l = zip->len_buf; ret = archive_encrypto_aes_ctr_update( &zip->cctx, rb, re - rb, zip->buf, &l); if (ret < 0) { archive_set_error(&a->archive, ARCHIVE_ERRNO_MISC, "Failed to encrypt file"); return (ARCHIVE_FAILED); } archive_hmac_sha1_update(&zip->hctx, zip->buf, l); } ret = __archive_write_output(a, zip->buf, l); if (ret != ARCHIVE_OK) return (ret); zip->entry_compressed_written += l; zip->written_bytes += l; rb += l; } } else { ret = __archive_write_output(a, buff, s); if (ret != ARCHIVE_OK) return (ret); zip->written_bytes += s; zip->entry_compressed_written += s; } break; #if HAVE_ZLIB_H case COMPRESSION_DEFLATE: zip->stream.next_in = (unsigned char*)(uintptr_t)buff; zip->stream.avail_in = (uInt)s; do { ret = deflate(&zip->stream, Z_NO_FLUSH); if (ret == Z_STREAM_ERROR) return (ARCHIVE_FATAL); if (zip->stream.avail_out == 0) { if (zip->tctx_valid) { trad_enc_encrypt_update(&zip->tctx, zip->buf, zip->len_buf, zip->buf, zip->len_buf); } else if (zip->cctx_valid) { size_t outl = zip->len_buf; ret = archive_encrypto_aes_ctr_update( &zip->cctx, zip->buf, zip->len_buf, zip->buf, &outl); if (ret < 0) { archive_set_error(&a->archive, ARCHIVE_ERRNO_MISC, "Failed to encrypt file"); return (ARCHIVE_FAILED); } archive_hmac_sha1_update(&zip->hctx, zip->buf, zip->len_buf); } ret = __archive_write_output(a, zip->buf, zip->len_buf); if (ret != ARCHIVE_OK) return (ret); zip->entry_compressed_written += zip->len_buf; zip->written_bytes += zip->len_buf; zip->stream.next_out = zip->buf; zip->stream.avail_out = (uInt)zip->len_buf; } } while (zip->stream.avail_in != 0); break; #endif default: archive_set_error(&a->archive, ARCHIVE_ERRNO_MISC, "Invalid ZIP compression type"); return ARCHIVE_FATAL; } zip->entry_uncompressed_limit -= s; if (!zip->cctx_valid || zip->aes_vendor != AES_VENDOR_AE_2) zip->entry_crc32 = zip->crc32func(zip->entry_crc32, buff, (unsigned)s); return (s); } static int archive_write_zip_finish_entry(struct archive_write *a) { struct zip *zip = a->format_data; int ret; #if HAVE_ZLIB_H if (zip->entry_compression == COMPRESSION_DEFLATE) { for (;;) { size_t remainder; ret = deflate(&zip->stream, Z_FINISH); if (ret == Z_STREAM_ERROR) return (ARCHIVE_FATAL); remainder = zip->len_buf - zip->stream.avail_out; if (zip->tctx_valid) { trad_enc_encrypt_update(&zip->tctx, zip->buf, remainder, zip->buf, remainder); } else if (zip->cctx_valid) { size_t outl = remainder; ret = archive_encrypto_aes_ctr_update( &zip->cctx, zip->buf, remainder, zip->buf, &outl); if (ret < 0) { archive_set_error(&a->archive, ARCHIVE_ERRNO_MISC, "Failed to encrypt file"); return (ARCHIVE_FAILED); } archive_hmac_sha1_update(&zip->hctx, zip->buf, remainder); } ret = __archive_write_output(a, zip->buf, remainder); if (ret != ARCHIVE_OK) return (ret); zip->entry_compressed_written += remainder; zip->written_bytes += remainder; zip->stream.next_out = zip->buf; if (zip->stream.avail_out != 0) break; zip->stream.avail_out = (uInt)zip->len_buf; } deflateEnd(&zip->stream); } #endif if (zip->hctx_valid) { uint8_t hmac[20]; size_t hmac_len = 20; archive_hmac_sha1_final(&zip->hctx, hmac, &hmac_len); ret = __archive_write_output(a, hmac, AUTH_CODE_SIZE); if (ret != ARCHIVE_OK) return (ret); zip->entry_compressed_written += AUTH_CODE_SIZE; zip->written_bytes += AUTH_CODE_SIZE; } /* Write trailing data descriptor. */ if ((zip->entry_flags & ZIP_ENTRY_FLAG_LENGTH_AT_END) != 0) { char d[24]; memcpy(d, "PK\007\010", 4); if (zip->cctx_valid && zip->aes_vendor == AES_VENDOR_AE_2) archive_le32enc(d + 4, 0);/* no CRC.*/ else archive_le32enc(d + 4, zip->entry_crc32); if (zip->entry_uses_zip64) { archive_le64enc(d + 8, (uint64_t)zip->entry_compressed_written); archive_le64enc(d + 16, (uint64_t)zip->entry_uncompressed_written); ret = __archive_write_output(a, d, 24); zip->written_bytes += 24; } else { archive_le32enc(d + 8, (uint32_t)zip->entry_compressed_written); archive_le32enc(d + 12, (uint32_t)zip->entry_uncompressed_written); ret = __archive_write_output(a, d, 16); zip->written_bytes += 16; } if (ret != ARCHIVE_OK) return (ARCHIVE_FATAL); } /* Append Zip64 extra data to central directory information. */ if (zip->entry_compressed_written > 0xffffffffLL || zip->entry_uncompressed_written > 0xffffffffLL || zip->entry_offset > 0xffffffffLL) { unsigned char zip64[32]; unsigned char *z = zip64, *zd; memcpy(z, "\001\000\000\000", 4); z += 4; if (zip->entry_uncompressed_written >= 0xffffffffLL) { archive_le64enc(z, zip->entry_uncompressed_written); z += 8; } if (zip->entry_compressed_written >= 0xffffffffLL) { archive_le64enc(z, zip->entry_compressed_written); z += 8; } if (zip->entry_offset >= 0xffffffffLL) { archive_le64enc(z, zip->entry_offset); z += 8; } archive_le16enc(zip64 + 2, (uint16_t)(z - (zip64 + 4))); zd = cd_alloc(zip, z - zip64); if (zd == NULL) { archive_set_error(&a->archive, ENOMEM, "Can't allocate zip data"); return (ARCHIVE_FATAL); } memcpy(zd, zip64, z - zip64); /* Zip64 means version needs to be set to at least 4.5 */ if (archive_le16dec(zip->file_header + 6) < 45) archive_le16enc(zip->file_header + 6, 45); } /* Fix up central directory file header. */ if (zip->cctx_valid && zip->aes_vendor == AES_VENDOR_AE_2) archive_le32enc(zip->file_header + 16, 0);/* no CRC.*/ else archive_le32enc(zip->file_header + 16, zip->entry_crc32); archive_le32enc(zip->file_header + 20, (uint32_t)zipmin(zip->entry_compressed_written, ARCHIVE_LITERAL_LL(0xffffffff))); archive_le32enc(zip->file_header + 24, (uint32_t)zipmin(zip->entry_uncompressed_written, ARCHIVE_LITERAL_LL(0xffffffff))); archive_le16enc(zip->file_header + 30, (uint16_t)(zip->central_directory_bytes - zip->file_header_extra_offset)); archive_le32enc(zip->file_header + 42, (uint32_t)zipmin(zip->entry_offset, ARCHIVE_LITERAL_LL(0xffffffff))); return (ARCHIVE_OK); } static int archive_write_zip_close(struct archive_write *a) { uint8_t buff[64]; int64_t offset_start, offset_end; struct zip *zip = a->format_data; struct cd_segment *segment; int ret; offset_start = zip->written_bytes; segment = zip->central_directory; while (segment != NULL) { ret = __archive_write_output(a, segment->buff, segment->p - segment->buff); if (ret != ARCHIVE_OK) return (ARCHIVE_FATAL); zip->written_bytes += segment->p - segment->buff; segment = segment->next; } offset_end = zip->written_bytes; /* If central dir info is too large, write Zip64 end-of-cd */ if (offset_end - offset_start > ARCHIVE_LITERAL_LL(0xffffffff) || offset_start > ARCHIVE_LITERAL_LL(0xffffffff) || zip->central_directory_entries > 0xffffUL || (zip->flags & ZIP_FLAG_FORCE_ZIP64)) { /* Zip64 end-of-cd record */ memset(buff, 0, 56); memcpy(buff, "PK\006\006", 4); archive_le64enc(buff + 4, 44); archive_le16enc(buff + 12, 45); archive_le16enc(buff + 14, 45); /* This is disk 0 of 0. */ archive_le64enc(buff + 24, zip->central_directory_entries); archive_le64enc(buff + 32, zip->central_directory_entries); archive_le64enc(buff + 40, offset_end - offset_start); archive_le64enc(buff + 48, offset_start); ret = __archive_write_output(a, buff, 56); if (ret != ARCHIVE_OK) return (ARCHIVE_FATAL); zip->written_bytes += 56; /* Zip64 end-of-cd locator record. */ memset(buff, 0, 20); memcpy(buff, "PK\006\007", 4); archive_le32enc(buff + 4, 0); archive_le64enc(buff + 8, offset_end); archive_le32enc(buff + 16, 1); ret = __archive_write_output(a, buff, 20); if (ret != ARCHIVE_OK) return (ARCHIVE_FATAL); zip->written_bytes += 20; } /* Format and write end of central directory. */ memset(buff, 0, sizeof(buff)); memcpy(buff, "PK\005\006", 4); archive_le16enc(buff + 8, (uint16_t)zipmin(0xffffU, zip->central_directory_entries)); archive_le16enc(buff + 10, (uint16_t)zipmin(0xffffU, zip->central_directory_entries)); archive_le32enc(buff + 12, (uint32_t)zipmin(0xffffffffLL, (offset_end - offset_start))); archive_le32enc(buff + 16, (uint32_t)zipmin(0xffffffffLL, offset_start)); ret = __archive_write_output(a, buff, 22); if (ret != ARCHIVE_OK) return (ARCHIVE_FATAL); zip->written_bytes += 22; return (ARCHIVE_OK); } static int archive_write_zip_free(struct archive_write *a) { struct zip *zip; struct cd_segment *segment; zip = a->format_data; while (zip->central_directory != NULL) { segment = zip->central_directory; zip->central_directory = segment->next; free(segment->buff); free(segment); } free(zip->buf); archive_entry_free(zip->entry); if (zip->cctx_valid) archive_encrypto_aes_ctr_release(&zip->cctx); if (zip->hctx_valid) archive_hmac_sha1_cleanup(&zip->hctx); /* TODO: Free opt_sconv, sconv_default */ free(zip); a->format_data = NULL; return (ARCHIVE_OK); } /* Convert into MSDOS-style date/time. */ static unsigned int dos_time(const time_t unix_time) { struct tm *t; unsigned int dt; /* This will not preserve time when creating/extracting the archive * on two systems with different time zones. */ t = localtime(&unix_time); /* MSDOS-style date/time is only between 1980-01-01 and 2107-12-31 */ if (t->tm_year < 1980 - 1900) /* Set minimum date/time '1980-01-01 00:00:00'. */ dt = 0x00210000U; else if (t->tm_year > 2107 - 1900) /* Set maximum date/time '2107-12-31 23:59:58'. */ dt = 0xff9fbf7dU; else { dt = 0; dt += ((t->tm_year - 80) & 0x7f) << 9; dt += ((t->tm_mon + 1) & 0x0f) << 5; dt += (t->tm_mday & 0x1f); dt <<= 16; dt += (t->tm_hour & 0x1f) << 11; dt += (t->tm_min & 0x3f) << 5; dt += (t->tm_sec & 0x3e) >> 1; /* Only counting every 2 seconds. */ } return dt; } static size_t path_length(struct archive_entry *entry) { mode_t type; const char *path; type = archive_entry_filetype(entry); path = archive_entry_pathname(entry); if (path == NULL) return (0); if (type == AE_IFDIR && (path[0] == '\0' || path[strlen(path) - 1] != '/')) { return strlen(path) + 1; } else { return strlen(path); } } static int write_path(struct archive_entry *entry, struct archive_write *archive) { int ret; const char *path; mode_t type; size_t written_bytes; path = archive_entry_pathname(entry); type = archive_entry_filetype(entry); written_bytes = 0; ret = __archive_write_output(archive, path, strlen(path)); if (ret != ARCHIVE_OK) return (ARCHIVE_FATAL); written_bytes += strlen(path); /* Folders are recognized by a trailing slash. */ if ((type == AE_IFDIR) & (path[strlen(path) - 1] != '/')) { ret = __archive_write_output(archive, "/", 1); if (ret != ARCHIVE_OK) return (ARCHIVE_FATAL); written_bytes += 1; } return ((int)written_bytes); } static void copy_path(struct archive_entry *entry, unsigned char *p) { const char *path; size_t pathlen; mode_t type; path = archive_entry_pathname(entry); pathlen = strlen(path); type = archive_entry_filetype(entry); memcpy(p, path, pathlen); /* Folders are recognized by a trailing slash. */ if ((type == AE_IFDIR) & (path[pathlen - 1] != '/')) { p[pathlen] = '/'; p[pathlen + 1] = '\0'; } } static struct archive_string_conv * get_sconv(struct archive_write *a, struct zip *zip) { if (zip->opt_sconv != NULL) return (zip->opt_sconv); if (!zip->init_default_conversion) { zip->sconv_default = archive_string_default_conversion_for_write(&(a->archive)); zip->init_default_conversion = 1; } return (zip->sconv_default); } /* Traditional PKWARE Decryption functions. */ static void trad_enc_update_keys(struct trad_enc_ctx *ctx, uint8_t c) { uint8_t t; #define CRC32(c, b) (crc32(c ^ 0xffffffffUL, &b, 1) ^ 0xffffffffUL) ctx->keys[0] = CRC32(ctx->keys[0], c); ctx->keys[1] = (ctx->keys[1] + (ctx->keys[0] & 0xff)) * 134775813L + 1; t = (ctx->keys[1] >> 24) & 0xff; ctx->keys[2] = CRC32(ctx->keys[2], t); #undef CRC32 } static uint8_t trad_enc_decypt_byte(struct trad_enc_ctx *ctx) { unsigned temp = ctx->keys[2] | 2; return (uint8_t)((temp * (temp ^ 1)) >> 8) & 0xff; } static unsigned trad_enc_encrypt_update(struct trad_enc_ctx *ctx, const uint8_t *in, size_t in_len, uint8_t *out, size_t out_len) { unsigned i, max; max = (unsigned)((in_len < out_len)? in_len: out_len); for (i = 0; i < max; i++) { uint8_t t = in[i]; out[i] = t ^ trad_enc_decypt_byte(ctx); trad_enc_update_keys(ctx, t); } return i; } static int trad_enc_init(struct trad_enc_ctx *ctx, const char *pw, size_t pw_len) { ctx->keys[0] = 305419896L; ctx->keys[1] = 591751049L; ctx->keys[2] = 878082192L; for (;pw_len; --pw_len) trad_enc_update_keys(ctx, *pw++); return 0; } static int is_traditional_pkware_encryption_supported(void) { uint8_t key[TRAD_HEADER_SIZE]; if (archive_random(key, sizeof(key)-1) != ARCHIVE_OK) return (0); return (1); } static int init_traditional_pkware_encryption(struct archive_write *a) { struct zip *zip = a->format_data; const char *passphrase; uint8_t key[TRAD_HEADER_SIZE]; uint8_t key_encrypted[TRAD_HEADER_SIZE]; int ret; passphrase = __archive_write_get_passphrase(a); if (passphrase == NULL) { archive_set_error(&a->archive, ARCHIVE_ERRNO_MISC, "Encryption needs passphrase"); return ARCHIVE_FAILED; } if (archive_random(key, sizeof(key)-1) != ARCHIVE_OK) { archive_set_error(&a->archive, ARCHIVE_ERRNO_MISC, "Can't generate random number for encryption"); return ARCHIVE_FATAL; } trad_enc_init(&zip->tctx, passphrase, strlen(passphrase)); /* Set the last key code which will be used as a check code * for verifying passphrase in decryption. */ key[TRAD_HEADER_SIZE-1] = zip->trad_chkdat; trad_enc_encrypt_update(&zip->tctx, key, TRAD_HEADER_SIZE, key_encrypted, TRAD_HEADER_SIZE); /* Write encrypted keys in the top of the file content. */ ret = __archive_write_output(a, key_encrypted, TRAD_HEADER_SIZE); if (ret != ARCHIVE_OK) return (ret); zip->written_bytes += TRAD_HEADER_SIZE; zip->entry_compressed_written += TRAD_HEADER_SIZE; return (ret); } static int init_winzip_aes_encryption(struct archive_write *a) { struct zip *zip = a->format_data; const char *passphrase; size_t key_len, salt_len; uint8_t salt[16 + 2]; uint8_t derived_key[MAX_DERIVED_KEY_BUF_SIZE]; int ret; passphrase = __archive_write_get_passphrase(a); if (passphrase == NULL) { archive_set_error(&a->archive, ARCHIVE_ERRNO_MISC, "Encryption needs passphrase"); return (ARCHIVE_FAILED); } if (zip->entry_encryption == ENCRYPTION_WINZIP_AES128) { salt_len = 8; key_len = 16; } else { /* AES 256 */ salt_len = 16; key_len = 32; } if (archive_random(salt, salt_len) != ARCHIVE_OK) { archive_set_error(&a->archive, ARCHIVE_ERRNO_MISC, "Can't generate random number for encryption"); return (ARCHIVE_FATAL); } archive_pbkdf2_sha1(passphrase, strlen(passphrase), salt, salt_len, 1000, derived_key, key_len * 2 + 2); ret = archive_encrypto_aes_ctr_init(&zip->cctx, derived_key, key_len); if (ret != 0) { archive_set_error(&a->archive, ARCHIVE_ERRNO_MISC, "Decryption is unsupported due to lack of crypto library"); return (ARCHIVE_FAILED); } ret = archive_hmac_sha1_init(&zip->hctx, derived_key + key_len, key_len); if (ret != 0) { archive_encrypto_aes_ctr_release(&zip->cctx); archive_set_error(&a->archive, ARCHIVE_ERRNO_MISC, "Failed to initialize HMAC-SHA1"); return (ARCHIVE_FAILED); } /* Set a passowrd verification value after the 'salt'. */ salt[salt_len] = derived_key[key_len * 2]; salt[salt_len + 1] = derived_key[key_len * 2 + 1]; /* Write encrypted keys in the top of the file content. */ ret = __archive_write_output(a, salt, salt_len + 2); if (ret != ARCHIVE_OK) return (ret); zip->written_bytes += salt_len + 2; zip->entry_compressed_written += salt_len + 2; return (ARCHIVE_OK); } static int is_winzip_aes_encryption_supported(int encryption) { size_t key_len, salt_len; uint8_t salt[16 + 2]; uint8_t derived_key[MAX_DERIVED_KEY_BUF_SIZE]; archive_crypto_ctx cctx; archive_hmac_sha1_ctx hctx; int ret; if (encryption == ENCRYPTION_WINZIP_AES128) { salt_len = 8; key_len = 16; } else { /* AES 256 */ salt_len = 16; key_len = 32; } if (archive_random(salt, salt_len) != ARCHIVE_OK) return (0); ret = archive_pbkdf2_sha1("p", 1, salt, salt_len, 1000, derived_key, key_len * 2 + 2); if (ret != 0) return (0); ret = archive_encrypto_aes_ctr_init(&cctx, derived_key, key_len); if (ret != 0) return (0); ret = archive_hmac_sha1_init(&hctx, derived_key + key_len, key_len); archive_encrypto_aes_ctr_release(&cctx); if (ret != 0) return (0); archive_hmac_sha1_cleanup(&hctx); return (1); }