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https://github.com/KolibriOS/kolibrios.git
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e9b1c1bac6
git-svn-id: svn://kolibrios.org@6725 a494cfbc-eb01-0410-851d-a64ba20cac60
654 lines
22 KiB
C
654 lines
22 KiB
C
/*
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Copyright (c) 1990-2007 Info-ZIP. All rights reserved.
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See the accompanying file LICENSE, version 2005-Feb-10 or later
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(the contents of which are also included in (un)zip.h) for terms of use.
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If, for some reason, all these files are missing, the Info-ZIP license
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also may be found at: ftp://ftp.info-zip.org/pub/infozip/license.html
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*/
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/*
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crypt.c (full version) by Info-ZIP. Last revised: [see crypt.h]
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The main encryption/decryption source code for Info-Zip software was
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originally written in Europe. To the best of our knowledge, it can
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be freely distributed in both source and object forms from any country,
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including the USA under License Exception TSU of the U.S. Export
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Administration Regulations (section 740.13(e)) of 6 June 2002.
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NOTE on copyright history:
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Previous versions of this source package (up to version 2.8) were
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not copyrighted and put in the public domain. If you cannot comply
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with the Info-Zip LICENSE, you may want to look for one of those
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public domain versions.
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*/
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/*
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This encryption code is a direct transcription of the algorithm from
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Roger Schlafly, described by Phil Katz in the file appnote.txt. This
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file (appnote.txt) is distributed with the PKZIP program (even in the
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version without encryption capabilities).
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*/
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#define ZCRYPT_INTERNAL
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#include "zip.h"
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#include "crypt.h"
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#include "ttyio.h"
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#if CRYPT
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#ifndef FALSE
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# define FALSE 0
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#endif
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#ifdef ZIP
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/* For the encoding task used in Zip (and ZipCloak), we want to initialize
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the crypt algorithm with some reasonably unpredictable bytes, see
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the crypthead() function. The standard rand() library function is
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used to supply these `random' bytes, which in turn is initialized by
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a srand() call. The srand() function takes an "unsigned" (at least 16bit)
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seed value as argument to determine the starting point of the rand()
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pseudo-random number generator.
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This seed number is constructed as "Seed = Seed1 .XOR. Seed2" with
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Seed1 supplied by the current time (= "(unsigned)time()") and Seed2
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as some (hopefully) nondeterministic bitmask. On many (most) systems,
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we use some "process specific" number, as the PID or something similar,
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but when nothing unpredictable is available, a fixed number may be
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sufficient.
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NOTE:
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1.) This implementation requires the availability of the following
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standard UNIX C runtime library functions: time(), rand(), srand().
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On systems where some of them are missing, the environment that
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incorporates the crypt routines must supply suitable replacement
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functions.
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2.) It is a very bad idea to use a second call to time() to set the
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"Seed2" number! In this case, both "Seed1" and "Seed2" would be
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(almost) identical, resulting in a (mostly) "zero" constant seed
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number passed to srand().
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The implementation environment defined in the "zip.h" header should
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supply a reasonable definition for ZCR_SEED2 (an unsigned number; for
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most implementations of rand() and srand(), only the lower 16 bits are
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significant!). An example that works on many systems would be
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"#define ZCR_SEED2 (unsigned)getpid()".
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The default definition for ZCR_SEED2 supplied below should be regarded
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as a fallback to allow successful compilation in "beta state"
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environments.
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*/
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# include <time.h> /* time() function supplies first part of crypt seed */
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/* "last resort" source for second part of crypt seed pattern */
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# ifndef ZCR_SEED2
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# define ZCR_SEED2 (unsigned)3141592654L /* use PI as default pattern */
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# endif
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# ifdef GLOBAL /* used in Amiga system headers, maybe others too */
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# undef GLOBAL
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# endif
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# define GLOBAL(g) g
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#else /* !ZIP */
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# define GLOBAL(g) G.g
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#endif /* ?ZIP */
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#ifdef UNZIP
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/* char *key = (char *)NULL; moved to globals.h */
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# ifndef FUNZIP
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local int testp OF((__GPRO__ ZCONST uch *h));
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local int testkey OF((__GPRO__ ZCONST uch *h, ZCONST char *key));
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# endif
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#endif /* UNZIP */
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#ifndef UNZIP /* moved to globals.h for UnZip */
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# ifndef Z_UINT4_DEFINED
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# if !defined(NO_LIMITS_H)
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# if (defined(UINT_MAX) && (UINT_MAX == 0xffffffffUL))
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typedef unsigned int z_uint4;
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# define Z_UINT4_DEFINED
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# else
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# if (defined(ULONG_MAX) && (ULONG_MAX == 0xffffffffUL))
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typedef unsigned long z_uint4;
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# define Z_UINT4_DEFINED
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# else
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# if (defined(USHRT_MAX) && (USHRT_MAX == 0xffffffffUL))
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typedef unsigned short z_uint4;
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# define Z_UINT4_DEFINED
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# endif
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# endif
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# endif
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# endif /* !NO_LIMITS_H */
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# endif /* !Z_UINT4_DEFINED */
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# ifndef Z_UINT4_DEFINED
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typedef ulg z_uint4;
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# define Z_UINT4_DEFINED
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# endif
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local z_uint4 keys[3]; /* keys defining the pseudo-random sequence */
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#endif /* !UNZIP */
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#ifndef Trace
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# ifdef CRYPT_DEBUG
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# define Trace(x) fprintf x
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# else
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# define Trace(x)
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# endif
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#endif
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#include "crc32.h"
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#ifdef IZ_CRC_BE_OPTIMIZ
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local z_uint4 near crycrctab[256];
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local z_uint4 near *cry_crctb_p = NULL;
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local z_uint4 near *crytab_init OF((__GPRO));
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# define CRY_CRC_TAB cry_crctb_p
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# undef CRC32
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# define CRC32(c, b, crctab) (crctab[((int)(c) ^ (b)) & 0xff] ^ ((c) >> 8))
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#else
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# define CRY_CRC_TAB CRC_32_TAB
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#endif /* ?IZ_CRC_BE_OPTIMIZ */
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/***********************************************************************
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* Return the next byte in the pseudo-random sequence
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*/
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int decrypt_byte(__G)
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__GDEF
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{
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unsigned temp; /* POTENTIAL BUG: temp*(temp^1) may overflow in an
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* unpredictable manner on 16-bit systems; not a problem
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* with any known compiler so far, though */
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temp = ((unsigned)GLOBAL(keys[2]) & 0xffff) | 2;
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return (int)(((temp * (temp ^ 1)) >> 8) & 0xff);
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}
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/***********************************************************************
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* Update the encryption keys with the next byte of plain text
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*/
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int update_keys(__G__ c)
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__GDEF
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int c; /* byte of plain text */
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{
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GLOBAL(keys[0]) = CRC32(GLOBAL(keys[0]), c, CRY_CRC_TAB);
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GLOBAL(keys[1]) = (GLOBAL(keys[1])
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+ (GLOBAL(keys[0]) & 0xff))
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* 134775813L + 1;
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{
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register int keyshift = (int)(GLOBAL(keys[1]) >> 24);
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GLOBAL(keys[2]) = CRC32(GLOBAL(keys[2]), keyshift, CRY_CRC_TAB);
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}
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return c;
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}
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/***********************************************************************
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* Initialize the encryption keys and the random header according to
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* the given password.
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*/
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void init_keys(__G__ passwd)
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__GDEF
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ZCONST char *passwd; /* password string with which to modify keys */
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{
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#ifdef IZ_CRC_BE_OPTIMIZ
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if (cry_crctb_p == NULL) {
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cry_crctb_p = crytab_init(__G);
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}
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#endif
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GLOBAL(keys[0]) = 305419896L;
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GLOBAL(keys[1]) = 591751049L;
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GLOBAL(keys[2]) = 878082192L;
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while (*passwd != '\0') {
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update_keys(__G__ (int)*passwd);
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passwd++;
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}
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}
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/***********************************************************************
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* Initialize the local copy of the table of precomputed crc32 values.
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* Whereas the public crc32-table is optimized for crc32 calculations
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* on arrays of bytes, the crypt code needs the crc32 values in an
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* byte-order-independent form as 32-bit unsigned numbers. On systems
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* with Big-Endian byte order using the optimized crc32 code, this
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* requires inverting the byte-order of the values in the
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* crypt-crc32-table.
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*/
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#ifdef IZ_CRC_BE_OPTIMIZ
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local z_uint4 near *crytab_init(__G)
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__GDEF
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{
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int i;
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for (i = 0; i < 256; i++) {
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crycrctab[i] = REV_BE(CRC_32_TAB[i]);
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}
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return crycrctab;
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}
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#endif
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#ifdef ZIP
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/***********************************************************************
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* Write encryption header to file zfile using the password passwd
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* and the cyclic redundancy check crc.
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*/
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void crypthead(passwd, crc, zfile)
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ZCONST char *passwd; /* password string */
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ulg crc; /* crc of file being encrypted */
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FILE *zfile; /* where to write header */
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{
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int n; /* index in random header */
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int t; /* temporary */
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int c; /* random byte */
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uch header[RAND_HEAD_LEN]; /* random header */
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static unsigned calls = 0; /* ensure different random header each time */
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/* First generate RAND_HEAD_LEN-2 random bytes. We encrypt the
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* output of rand() to get less predictability, since rand() is
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* often poorly implemented.
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*/
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if (++calls == 1) {
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srand((unsigned)time(NULL) ^ ZCR_SEED2);
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}
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init_keys(passwd);
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for (n = 0; n < RAND_HEAD_LEN-2; n++) {
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c = (rand() >> 7) & 0xff;
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header[n] = (uch)zencode(c, t);
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}
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/* Encrypt random header (last two bytes is high word of crc) */
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init_keys(passwd);
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for (n = 0; n < RAND_HEAD_LEN-2; n++) {
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header[n] = (uch)zencode(header[n], t);
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}
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header[RAND_HEAD_LEN-2] = (uch)zencode((int)(crc >> 16) & 0xff, t);
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header[RAND_HEAD_LEN-1] = (uch)zencode((int)(crc >> 24) & 0xff, t);
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fwrite(header, 1, RAND_HEAD_LEN, f);
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}
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#ifdef UTIL
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/***********************************************************************
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* Encrypt the zip entry described by z from file source to file dest
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* using the password passwd. Return an error code in the ZE_ class.
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*/
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int zipcloak(z, source, dest, passwd)
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struct zlist far *z; /* zip entry to encrypt */
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FILE *source, *dest; /* source and destination files */
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ZCONST char *passwd; /* password string */
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{
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int c; /* input byte */
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int res; /* result code */
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ulg n; /* holds offset and counts size */
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ush flag; /* previous flags */
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int t; /* temporary */
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int ztemp; /* temporary storage for zencode value */
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/* Set encrypted bit, clear extended local header bit and write local
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header to output file */
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if ((n = (ulg)ftell(dest)) == (ulg)-1L) return ZE_TEMP;
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z->off = n;
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flag = z->flg;
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z->flg |= 1, z->flg &= ~8;
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z->lflg |= 1, z->lflg &= ~8;
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z->siz += RAND_HEAD_LEN;
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if ((res = putlocal(z, dest)) != ZE_OK) return res;
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/* Initialize keys with password and write random header */
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crypthead(passwd, z->crc, dest);
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/* Skip local header in input file */
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if (fseek(source, (long)((4 + LOCHEAD) + (ulg)z->nam + (ulg)z->ext),
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SEEK_CUR)) {
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return ferror(source) ? ZE_READ : ZE_EOF;
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}
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/* Encrypt data */
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for (n = z->siz - RAND_HEAD_LEN; n; n--) {
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if ((c = getc(source)) == EOF) {
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return ferror(source) ? ZE_READ : ZE_EOF;
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}
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ztemp = zencode(c, t);
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putc(ztemp, dest);
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}
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/* Skip extended local header in input file if there is one */
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if ((flag & 8) != 0 && fseek(source, 16L, SEEK_CUR)) {
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return ferror(source) ? ZE_READ : ZE_EOF;
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}
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if (fflush(dest) == EOF) return ZE_TEMP;
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/* Update number of bytes written to output file */
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tempzn += (4 + LOCHEAD) + z->nam + z->ext + z->siz;
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return ZE_OK;
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}
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/***********************************************************************
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* Decrypt the zip entry described by z from file source to file dest
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* using the password passwd. Return an error code in the ZE_ class.
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*/
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int zipbare(z, source, dest, passwd)
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struct zlist far *z; /* zip entry to encrypt */
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FILE *source, *dest; /* source and destination files */
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ZCONST char *passwd; /* password string */
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{
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#ifdef ZIP10
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int c0 /* byte preceding the last input byte */
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#endif
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int c1; /* last input byte */
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ulg offset; /* used for file offsets */
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ulg size; /* size of input data */
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int r; /* size of encryption header */
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int res; /* return code */
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ush flag; /* previous flags */
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/* Save position and skip local header in input file */
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if ((offset = (ulg)ftell(source)) == (ulg)-1L ||
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fseek(source, (long)((4 + LOCHEAD) + (ulg)z->nam + (ulg)z->ext),
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SEEK_CUR)) {
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return ferror(source) ? ZE_READ : ZE_EOF;
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}
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/* Initialize keys with password */
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init_keys(passwd);
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/* Decrypt encryption header, save last two bytes */
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c1 = 0;
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for (r = RAND_HEAD_LEN; r; r--) {
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#ifdef ZIP10
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c0 = c1;
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#endif
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if ((c1 = getc(source)) == EOF) {
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return ferror(source) ? ZE_READ : ZE_EOF;
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}
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Trace((stdout, " (%02x)", c1));
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zdecode(c1);
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Trace((stdout, " %02x", c1));
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}
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Trace((stdout, "\n"));
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/* If last two bytes of header don't match crc (or file time in the
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* case of an extended local header), back up and just copy. For
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* pkzip 2.0, the check has been reduced to one byte only.
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*/
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#ifdef ZIP10
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if ((ush)(c0 | (c1<<8)) !=
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(z->flg & 8 ? (ush) z->tim & 0xffff : (ush)(z->crc >> 16))) {
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#else
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if ((ush)c1 != (z->flg & 8 ? (ush) z->tim >> 8 : (ush)(z->crc >> 24))) {
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#endif
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if (fseek(source, offset, SEEK_SET)) {
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return ferror(source) ? ZE_READ : ZE_EOF;
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}
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if ((res = zipcopy(z, source, dest)) != ZE_OK) return res;
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return ZE_MISS;
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}
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/* Clear encrypted bit and local header bit, and write local header to
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output file */
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if ((offset = (ulg)ftell(dest)) == (ulg)-1L) return ZE_TEMP;
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z->off = offset;
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flag = z->flg;
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z->flg &= ~9;
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z->lflg &= ~9;
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z->siz -= RAND_HEAD_LEN;
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if ((res = putlocal(z, dest)) != ZE_OK) return res;
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/* Decrypt data */
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for (size = z->siz; size; size--) {
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if ((c1 = getc(source)) == EOF) {
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return ferror(source) ? ZE_READ : ZE_EOF;
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}
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zdecode(c1);
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putc(c1, dest);
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}
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/* Skip extended local header in input file if there is one */
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if ((flag & 8) != 0 && fseek(source, 16L, SEEK_CUR)) {
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return ferror(source) ? ZE_READ : ZE_EOF;
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}
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if (fflush(dest) == EOF) return ZE_TEMP;
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/* Update number of bytes written to output file */
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tempzn += (4 + LOCHEAD) + z->nam + z->ext + z->siz;
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return ZE_OK;
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}
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#else /* !UTIL */
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/***********************************************************************
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* If requested, encrypt the data in buf, and in any case call fwrite()
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* with the arguments to zfwrite(). Return what fwrite() returns.
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*
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* A bug has been found when encrypting large files. See trees.c
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* for details and the fix.
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*/
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unsigned zfwrite(buf, item_size, nb, f)
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zvoid *buf; /* data buffer */
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extent item_size; /* size of each item in bytes */
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extent nb; /* number of items */
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FILE *f; /* file to write to */
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{
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int t; /* temporary */
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if (key != (char *)NULL) { /* key is the global password pointer */
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ulg size; /* buffer size */
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char *p = (char*)buf; /* steps through buffer */
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/* Encrypt data in buffer */
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for (size = item_size*(ulg)nb; size != 0; p++, size--) {
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*p = (char)zencode(*p, t);
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}
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}
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/* Write the buffer out */
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return fwrite(buf, item_size, nb, f);
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}
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#endif /* ?UTIL */
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#endif /* ZIP */
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#if (defined(UNZIP) && !defined(FUNZIP))
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/***********************************************************************
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* Get the password and set up keys for current zipfile member.
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* Return PK_ class error.
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*/
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int decrypt(__G__ passwrd)
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__GDEF
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ZCONST char *passwrd;
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{
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ush b;
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int n, r;
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uch h[RAND_HEAD_LEN];
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Trace((stdout, "\n[incnt = %d]: ", GLOBAL(incnt)));
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/* get header once (turn off "encrypted" flag temporarily so we don't
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* try to decrypt the same data twice) */
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GLOBAL(pInfo->encrypted) = FALSE;
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defer_leftover_input(__G);
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for (n = 0; n < RAND_HEAD_LEN; n++) {
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b = NEXTBYTE;
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h[n] = (uch)b;
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Trace((stdout, " (%02x)", h[n]));
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}
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undefer_input(__G);
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GLOBAL(pInfo->encrypted) = TRUE;
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if (GLOBAL(newzip)) { /* this is first encrypted member in this zipfile */
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GLOBAL(newzip) = FALSE;
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if (passwrd != (char *)NULL) { /* user gave password on command line */
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if (!GLOBAL(key)) {
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|
if ((GLOBAL(key) = (char *)malloc(strlen(passwrd)+1)) ==
|
|
(char *)NULL)
|
|
return PK_MEM2;
|
|
strcpy(GLOBAL(key), passwrd);
|
|
GLOBAL(nopwd) = TRUE; /* inhibit password prompting! */
|
|
}
|
|
} else if (GLOBAL(key)) { /* get rid of previous zipfile's key */
|
|
free(GLOBAL(key));
|
|
GLOBAL(key) = (char *)NULL;
|
|
}
|
|
}
|
|
|
|
/* if have key already, test it; else allocate memory for it */
|
|
if (GLOBAL(key)) {
|
|
if (!testp(__G__ h))
|
|
return PK_COOL; /* existing password OK (else prompt for new) */
|
|
else if (GLOBAL(nopwd))
|
|
return PK_WARN; /* user indicated no more prompting */
|
|
} else if ((GLOBAL(key) = (char *)malloc(IZ_PWLEN+1)) == (char *)NULL)
|
|
return PK_MEM2;
|
|
|
|
/* try a few keys */
|
|
n = 0;
|
|
do {
|
|
r = (*G.decr_passwd)((zvoid *)&G, &n, GLOBAL(key), IZ_PWLEN+1,
|
|
GLOBAL(zipfn), GLOBAL(filename));
|
|
if (r == IZ_PW_ERROR) { /* internal error in fetch of PW */
|
|
free (GLOBAL(key));
|
|
GLOBAL(key) = NULL;
|
|
return PK_MEM2;
|
|
}
|
|
if (r != IZ_PW_ENTERED) { /* user replied "skip" or "skip all" */
|
|
*GLOBAL(key) = '\0'; /* We try the NIL password, ... */
|
|
n = 0; /* and cancel fetch for this item. */
|
|
}
|
|
if (!testp(__G__ h))
|
|
return PK_COOL;
|
|
if (r == IZ_PW_CANCELALL) /* User replied "Skip all" */
|
|
GLOBAL(nopwd) = TRUE; /* inhibit any further PW prompt! */
|
|
} while (n > 0);
|
|
|
|
return PK_WARN;
|
|
|
|
} /* end function decrypt() */
|
|
|
|
|
|
|
|
/***********************************************************************
|
|
* Test the password. Return -1 if bad, 0 if OK.
|
|
*/
|
|
local int testp(__G__ h)
|
|
__GDEF
|
|
ZCONST uch *h;
|
|
{
|
|
int r;
|
|
char *key_translated;
|
|
|
|
/* On systems with "obscure" native character coding (e.g., EBCDIC),
|
|
* the first test translates the password to the "main standard"
|
|
* character coding. */
|
|
|
|
#ifdef STR_TO_CP1
|
|
/* allocate buffer for translated password */
|
|
if ((key_translated = malloc(strlen(GLOBAL(key)) + 1)) == (char *)NULL)
|
|
return -1;
|
|
/* first try, test password translated "standard" charset */
|
|
r = testkey(__G__ h, STR_TO_CP1(key_translated, GLOBAL(key)));
|
|
#else /* !STR_TO_CP1 */
|
|
/* first try, test password as supplied on the extractor's host */
|
|
r = testkey(__G__ h, GLOBAL(key));
|
|
#endif /* ?STR_TO_CP1 */
|
|
|
|
#ifdef STR_TO_CP2
|
|
if (r != 0) {
|
|
#ifndef STR_TO_CP1
|
|
/* now prepare for second (and maybe third) test with translated pwd */
|
|
if ((key_translated = malloc(strlen(GLOBAL(key)) + 1)) == (char *)NULL)
|
|
return -1;
|
|
#endif
|
|
/* second try, password translated to alternate ("standard") charset */
|
|
r = testkey(__G__ h, STR_TO_CP2(key_translated, GLOBAL(key)));
|
|
#ifdef STR_TO_CP3
|
|
if (r != 0)
|
|
/* third try, password translated to another "standard" charset */
|
|
r = testkey(__G__ h, STR_TO_CP3(key_translated, GLOBAL(key)));
|
|
#endif
|
|
#ifndef STR_TO_CP1
|
|
free(key_translated);
|
|
#endif
|
|
}
|
|
#endif /* STR_TO_CP2 */
|
|
|
|
#ifdef STR_TO_CP1
|
|
free(key_translated);
|
|
if (r != 0) {
|
|
/* last resort, test password as supplied on the extractor's host */
|
|
r = testkey(__G__ h, GLOBAL(key));
|
|
}
|
|
#endif /* STR_TO_CP1 */
|
|
|
|
return r;
|
|
|
|
} /* end function testp() */
|
|
|
|
|
|
local int testkey(__G__ h, key)
|
|
__GDEF
|
|
ZCONST uch *h; /* decrypted header */
|
|
ZCONST char *key; /* decryption password to test */
|
|
{
|
|
ush b;
|
|
#ifdef ZIP10
|
|
ush c;
|
|
#endif
|
|
int n;
|
|
uch *p;
|
|
uch hh[RAND_HEAD_LEN]; /* decrypted header */
|
|
|
|
/* set keys and save the encrypted header */
|
|
init_keys(__G__ key);
|
|
memcpy(hh, h, RAND_HEAD_LEN);
|
|
|
|
/* check password */
|
|
for (n = 0; n < RAND_HEAD_LEN; n++) {
|
|
zdecode(hh[n]);
|
|
Trace((stdout, " %02x", hh[n]));
|
|
}
|
|
|
|
Trace((stdout,
|
|
"\n lrec.crc= %08lx crec.crc= %08lx pInfo->ExtLocHdr= %s\n",
|
|
GLOBAL(lrec.crc32), GLOBAL(pInfo->crc),
|
|
GLOBAL(pInfo->ExtLocHdr) ? "true":"false"));
|
|
Trace((stdout, " incnt = %d unzip offset into zipfile = %ld\n",
|
|
GLOBAL(incnt),
|
|
GLOBAL(cur_zipfile_bufstart)+(GLOBAL(inptr)-GLOBAL(inbuf))));
|
|
|
|
/* same test as in zipbare(): */
|
|
|
|
#ifdef ZIP10 /* check two bytes */
|
|
c = hh[RAND_HEAD_LEN-2], b = hh[RAND_HEAD_LEN-1];
|
|
Trace((stdout,
|
|
" (c | (b<<8)) = %04x (crc >> 16) = %04x lrec.time = %04x\n",
|
|
(ush)(c | (b<<8)), (ush)(GLOBAL(lrec.crc32) >> 16),
|
|
((ush)GLOBAL(lrec.last_mod_dos_datetime) & 0xffff))));
|
|
if ((ush)(c | (b<<8)) != (GLOBAL(pInfo->ExtLocHdr) ?
|
|
((ush)GLOBAL(lrec.last_mod_dos_datetime) & 0xffff) :
|
|
(ush)(GLOBAL(lrec.crc32) >> 16)))
|
|
return -1; /* bad */
|
|
#else
|
|
b = hh[RAND_HEAD_LEN-1];
|
|
Trace((stdout, " b = %02x (crc >> 24) = %02x (lrec.time >> 8) = %02x\n",
|
|
b, (ush)(GLOBAL(lrec.crc32) >> 24),
|
|
((ush)GLOBAL(lrec.last_mod_dos_datetime) >> 8) & 0xff));
|
|
if (b != (GLOBAL(pInfo->ExtLocHdr) ?
|
|
((ush)GLOBAL(lrec.last_mod_dos_datetime) >> 8) & 0xff :
|
|
(ush)(GLOBAL(lrec.crc32) >> 24)))
|
|
return -1; /* bad */
|
|
#endif
|
|
/* password OK: decrypt current buffer contents before leaving */
|
|
for (n = (long)GLOBAL(incnt) > GLOBAL(csize) ?
|
|
(int)GLOBAL(csize) : GLOBAL(incnt),
|
|
p = GLOBAL(inptr); n--; p++)
|
|
zdecode(*p);
|
|
return 0; /* OK */
|
|
|
|
} /* end function testkey() */
|
|
|
|
#endif /* UNZIP && !FUNZIP */
|
|
|
|
#else /* !CRYPT */
|
|
|
|
/* something "externally visible" to shut up compiler/linker warnings */
|
|
int zcr_dummy;
|
|
|
|
#endif /* ?CRYPT */
|