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191 lines
6.2 KiB
C
191 lines
6.2 KiB
C
/* crypt.c -- implements crypt.h */
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#include "crypt.h"
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/* CRYPT.C
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*
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* Encryption routines
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*
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* written by Dana Hoggatt and Daniel Lawrence
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*/
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#if CRYPT
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#include <stdio.h>
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static int mod95(int);
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/**********
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*
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* myencrypt - in place encryption/decryption of a buffer
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*
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* (C) Copyright 1986, Dana L. Hoggatt
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* 1216, Beck Lane, Lafayette, IN
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*
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* When consulting directly with the author of this routine,
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* please refer to this routine as the "DLH-POLY-86-B CIPHER".
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*
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* This routine was written for Dan Lawrence, for use in V3.8 of
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* MicroEMACS, a public domain text/program editor.
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*
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* I kept the following goals in mind when preparing this function:
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*
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* 1. All printable characters were to be encrypted back
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* into the printable range, control characters and
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* high-bit characters were to remain unaffected. this
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* way, encrypted would still be just as cheap to
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* transmit down a 7-bit data path as they were before.
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*
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* 2. The encryption had to be portable. The encrypted
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* file from one computer should be able to be decrypted
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* on another computer.
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*
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* 3. The encryption had to be inexpensive, both in terms
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* of speed and space.
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*
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* 4. The system needed to be secure against all but the
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* most determined of attackers.
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*
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* For encryption of a block of data, one calls myencrypt passing
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* a pointer to the data block and its length. The data block is
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* encrypted in place, that is, the encrypted output overwrites
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* the input. Decryption is totally isomorphic, and is performed
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* in the same manner by the same routine.
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*
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* Before using this routine for encrypting data, you are expected
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* to specify an encryption key. This key is an arbitrary string,
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* to be supplied by the user. To set the key takes two calls to
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* myencrypt(). First, you call
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*
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* myencrypt(NULL, vector)
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*
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* This resets all internal control information. Typically (and
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* specifically in the case on MICRO-emacs) you would use a "vector"
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* of 0. Other values can be used to customize your editor to be
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* "incompatable" with the normally distributed version. For
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* this purpose, the best results will be obtained by avoiding
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* multiples of 95.
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*
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* Then, you "encrypt" your password by calling
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*
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* myencrypt(pass, strlen(pass))
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*
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* where "pass" is your password string. Myencrypt() will destroy
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* the original copy of the password (it becomes encrypted),
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* which is good. You do not want someone on a multiuser system
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* to peruse your memory space and bump into your password.
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* Still, it is a better idea to erase the password buffer to
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* defeat memory perusal by a more technical snooper.
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*
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* For the interest of cryptologists, at the heart of this
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* function is a Beaufort Cipher. The cipher alphabet is the
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* range of printable characters (' ' to '~'), all "control"
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* and "high-bit" characters are left unaltered.
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*
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* The key is a variant autokey, derived from a wieghted sum
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* of all the previous clear text and cipher text. A counter
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* is used as salt to obiterate any simple cyclic behavior
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* from the clear text, and key feedback is used to assure
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* that the entire message is based on the original key,
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* preventing attacks on the last part of the message as if
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* it were a pure autokey system.
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*
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* Overall security of encrypted data depends upon three
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* factors: the fundamental cryptographic system must be
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* difficult to compromise; exhaustive searching of the key
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* space must be computationally expensive; keys and plaintext
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* must remain out of sight. This system satisfies this set
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* of conditions to within the degree desired for MicroEMACS.
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*
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* Though direct methods of attack (against systems such as
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* this) do exist, they are not well known and will consume
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* considerable amounts of computing time. An exhaustive
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* search requires over a billion investigations, on average.
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*
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* The choice, entry, storage, manipulation, alteration,
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* protection and security of the keys themselves are the
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* responsiblity of the user.
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*
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*
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* char *bptr; buffer of characters to be encrypted
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* unsigned len; number of characters in the buffer
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*
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**********/
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void myencrypt(char *bptr, unsigned len)
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{
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int cc; /* current character being considered */
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static long key = 0; /* 29 bit encipherment key */
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static int salt = 0; /* salt to spice up key with */
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if (!bptr) { /* is there anything here to encrypt? */
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key = len; /* set the new key */
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salt = len; /* set the new salt */
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return;
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}
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while (len--) { /* for every character in the buffer */
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cc = *bptr; /* get a character out of the buffer */
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/* only encipher printable characters */
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if ((cc >= ' ') && (cc <= '~')) {
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/** If the upper bit (bit 29) is set, feed it back into the key. This
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assures us that the starting key affects the entire message. **/
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key &= 0x1FFFFFFFL; /* strip off overflow */
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if (key & 0x10000000L) {
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key ^= 0x0040A001L; /* feedback */
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}
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/** Down-bias the character, perform a Beaufort encipherment, and
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up-bias the character again. We want key to be positive
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so that the left shift here will be more portable and the
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mod95() faster **/
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cc = mod95((int) (key % 95) - (cc - ' ')) + ' ';
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/** the salt will spice up the key a little bit, helping to obscure
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any patterns in the clear text, particularly when all the
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characters (or long sequences of them) are the same. We do
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not want the salt to go negative, or it will affect the key
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too radically. It is always a good idea to chop off cyclics
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to prime values. **/
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if (++salt >= 20857) { /* prime modulus */
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salt = 0;
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}
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/** our autokey (a special case of the running key) is being
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generated by a wieghted checksum of clear text, cipher
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text, and salt. **/
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key = key + key + cc + *bptr + salt;
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}
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*bptr++ = cc; /* put character back into buffer */
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}
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return;
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}
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static int mod95(int val)
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{
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/* The mathematical MOD does not match the computer MOD */
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/* Yes, what I do here may look strange, but it gets the
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job done, and portably at that. */
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while (val >= 9500)
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val -= 9500;
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while (val >= 950)
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val -= 950;
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while (val >= 95)
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val -= 95;
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while (val < 0)
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val += 95;
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return val;
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}
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#endif
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