Mercurial > hg > orthanc
comparison OrthancFramework/Resources/ThirdParty/minizip/crypt.h @ 4044:d25f4c0fa160 framework
splitting code into OrthancFramework and OrthancServer
| author | Sebastien Jodogne <s.jodogne@gmail.com> |
|---|---|
| date | Wed, 10 Jun 2020 20:30:34 +0200 |
| parents | Resources/ThirdParty/minizip/crypt.h@e583bbf6ec6c |
| children | 8174e45f48d8 |
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| 4043:6c6239aec462 | 4044:d25f4c0fa160 |
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| 1 /* crypt.h -- base code for crypt/uncrypt ZIPfile | |
| 2 | |
| 3 | |
| 4 Version 1.01e, February 12th, 2005 | |
| 5 | |
| 6 Copyright (C) 1998-2005 Gilles Vollant | |
| 7 | |
| 8 This code is a modified version of crypting code in Infozip distribution | |
| 9 | |
| 10 The encryption/decryption parts of this source code (as opposed to the | |
| 11 non-echoing password parts) were originally written in Europe. The | |
| 12 whole source package can be freely distributed, including from the USA. | |
| 13 (Prior to January 2000, re-export from the US was a violation of US law.) | |
| 14 | |
| 15 This encryption code is a direct transcription of the algorithm from | |
| 16 Roger Schlafly, described by Phil Katz in the file appnote.txt. This | |
| 17 file (appnote.txt) is distributed with the PKZIP program (even in the | |
| 18 version without encryption capabilities). | |
| 19 | |
| 20 If you don't need crypting in your application, just define symbols | |
| 21 NOCRYPT and NOUNCRYPT. | |
| 22 | |
| 23 This code support the "Traditional PKWARE Encryption". | |
| 24 | |
| 25 The new AES encryption added on Zip format by Winzip (see the page | |
| 26 http://www.winzip.com/aes_info.htm ) and PKWare PKZip 5.x Strong | |
| 27 Encryption is not supported. | |
| 28 */ | |
| 29 | |
| 30 #define CRC32(c, b) ((*(pcrc_32_tab+(((int)(c) ^ (b)) & 0xff))) ^ ((c) >> 8)) | |
| 31 | |
| 32 /*********************************************************************** | |
| 33 * Return the next byte in the pseudo-random sequence | |
| 34 */ | |
| 35 static int decrypt_byte(unsigned long* pkeys, const z_crc_t* pcrc_32_tab) | |
| 36 { | |
| 37 unsigned temp; /* POTENTIAL BUG: temp*(temp^1) may overflow in an | |
| 38 * unpredictable manner on 16-bit systems; not a problem | |
| 39 * with any known compiler so far, though */ | |
| 40 | |
| 41 temp = ((unsigned)(*(pkeys+2)) & 0xffff) | 2; | |
| 42 return (int)(((temp * (temp ^ 1)) >> 8) & 0xff); | |
| 43 } | |
| 44 | |
| 45 /*********************************************************************** | |
| 46 * Update the encryption keys with the next byte of plain text | |
| 47 */ | |
| 48 static int update_keys(unsigned long* pkeys,const z_crc_t* pcrc_32_tab,int c) | |
| 49 { | |
| 50 (*(pkeys+0)) = CRC32((*(pkeys+0)), c); | |
| 51 (*(pkeys+1)) += (*(pkeys+0)) & 0xff; | |
| 52 (*(pkeys+1)) = (*(pkeys+1)) * 134775813L + 1; | |
| 53 { | |
| 54 register int keyshift = (int)((*(pkeys+1)) >> 24); | |
| 55 (*(pkeys+2)) = CRC32((*(pkeys+2)), keyshift); | |
| 56 } | |
| 57 return c; | |
| 58 } | |
| 59 | |
| 60 | |
| 61 /*********************************************************************** | |
| 62 * Initialize the encryption keys and the random header according to | |
| 63 * the given password. | |
| 64 */ | |
| 65 static void init_keys(const char* passwd,unsigned long* pkeys,const z_crc_t* pcrc_32_tab) | |
| 66 { | |
| 67 *(pkeys+0) = 305419896L; | |
| 68 *(pkeys+1) = 591751049L; | |
| 69 *(pkeys+2) = 878082192L; | |
| 70 while (*passwd != '\0') { | |
| 71 update_keys(pkeys,pcrc_32_tab,(int)*passwd); | |
| 72 passwd++; | |
| 73 } | |
| 74 } | |
| 75 | |
| 76 #define zdecode(pkeys,pcrc_32_tab,c) \ | |
| 77 (update_keys(pkeys,pcrc_32_tab,c ^= decrypt_byte(pkeys,pcrc_32_tab))) | |
| 78 | |
| 79 #define zencode(pkeys,pcrc_32_tab,c,t) \ | |
| 80 (t=decrypt_byte(pkeys,pcrc_32_tab), update_keys(pkeys,pcrc_32_tab,c), t^(c)) | |
| 81 | |
| 82 #ifdef INCLUDECRYPTINGCODE_IFCRYPTALLOWED | |
| 83 | |
| 84 #define RAND_HEAD_LEN 12 | |
| 85 /* "last resort" source for second part of crypt seed pattern */ | |
| 86 # ifndef ZCR_SEED2 | |
| 87 # define ZCR_SEED2 3141592654UL /* use PI as default pattern */ | |
| 88 # endif | |
| 89 | |
| 90 static int crypthead(const char* passwd, /* password string */ | |
| 91 unsigned char* buf, /* where to write header */ | |
| 92 int bufSize, | |
| 93 unsigned long* pkeys, | |
| 94 const z_crc_t* pcrc_32_tab, | |
| 95 unsigned long crcForCrypting) | |
| 96 { | |
| 97 int n; /* index in random header */ | |
| 98 int t; /* temporary */ | |
| 99 int c; /* random byte */ | |
| 100 unsigned char header[RAND_HEAD_LEN-2]; /* random header */ | |
| 101 static unsigned calls = 0; /* ensure different random header each time */ | |
| 102 | |
| 103 if (bufSize<RAND_HEAD_LEN) | |
| 104 return 0; | |
| 105 | |
| 106 /* First generate RAND_HEAD_LEN-2 random bytes. We encrypt the | |
| 107 * output of rand() to get less predictability, since rand() is | |
| 108 * often poorly implemented. | |
| 109 */ | |
| 110 if (++calls == 1) | |
| 111 { | |
| 112 srand((unsigned)(time(NULL) ^ ZCR_SEED2)); | |
| 113 } | |
| 114 init_keys(passwd, pkeys, pcrc_32_tab); | |
| 115 for (n = 0; n < RAND_HEAD_LEN-2; n++) | |
| 116 { | |
| 117 c = (rand() >> 7) & 0xff; | |
| 118 header[n] = (unsigned char)zencode(pkeys, pcrc_32_tab, c, t); | |
| 119 } | |
| 120 /* Encrypt random header (last two bytes is high word of crc) */ | |
| 121 init_keys(passwd, pkeys, pcrc_32_tab); | |
| 122 for (n = 0; n < RAND_HEAD_LEN-2; n++) | |
| 123 { | |
| 124 buf[n] = (unsigned char)zencode(pkeys, pcrc_32_tab, header[n], t); | |
| 125 } | |
| 126 buf[n++] = (unsigned char)zencode(pkeys, pcrc_32_tab, (int)(crcForCrypting >> 16) & 0xff, t); | |
| 127 buf[n++] = (unsigned char)zencode(pkeys, pcrc_32_tab, (int)(crcForCrypting >> 24) & 0xff, t); | |
| 128 return n; | |
| 129 } | |
| 130 | |
| 131 #endif |