[u/mdw/putty] / sshcrc.c

/*
 * CRC32 implementation.
 *
 * The basic concept of a CRC is that you treat your bit-string
 * abcdefg... as a ludicrously long polynomial M=a+bx+cx^2+dx^3+...
 * over Z[2]. You then take a modulus polynomial P, and compute the
 * remainder of M on division by P. Thus, an erroneous message N
 * will only have the same CRC if the difference E = M-N is an
 * exact multiple of P. (Note that as we are working over Z[2], M-N
 * = N-M = M+N; but that's not very important.)
 *
 * What makes the CRC good is choosing P to have good properties:
 *
 *  - If its first and last terms are both nonzero then it cannot
 *    be a factor of any single term x^i. Therefore if M and N
 *    differ by exactly one bit their CRCs will guaranteeably
 *    be distinct.
 *
 *  - If it has a prime (irreducible) factor with three terms then
 *    it cannot divide a polynomial of the form x^i(1+x^j).
 *    Therefore if M and N differ by exactly _two_ bits they will
 *    have different CRCs.
 *
 *  - If it has a factor (x+1) then it cannot divide a polynomial
 *    with an odd number of terms. Therefore if M and N differ by
 *    _any odd_ number of bits they will have different CRCs.
 *
 *  - If the error term E is of the form x^i*B(x) where B(x) has
 *    order less than P (i.e. a short _burst_ of errors) then P
 *    cannot divide E (since no polynomial can divide a shorter
 *    one), so any such error burst will be spotted.
 *
 * The CRC32 standard polynomial is
 *   x^32+x^26+x^23+x^22+x^16+x^12+x^11+x^10+x^8+x^7+x^5+x^4+x^2+x^1+x^0
 *
 * In fact, we don't compute M mod P; we compute M*x^32 mod P.
 *
 * The concrete implementation of the CRC is this: we maintain at
 * all times a 32-bit word which is the current remainder of the
 * polynomial mod P. Whenever we receive an extra bit, we multiply
 * the existing remainder by x, add (XOR) the x^32 term thus
 * generated to the new x^32 term caused by the incoming bit, and
 * remove the resulting combined x^32 term if present by replacing
 * it with (P-x^32).
 *
 * Bit 0 of the word is the x^31 term and bit 31 is the x^0 term.
 * Thus, multiplying by x means shifting right. So the actual
 * algorithm goes like this:
 *
 *   x32term = (crcword & 1) ^ newbit;
 *   crcword = (crcword >> 1) ^ (x32term * 0xEDB88320);
 *
 * In practice, we pre-compute what will happen to crcword on any
 * given sequence of eight incoming bits, and store that in a table
 * which we then use at run-time to do the job:
 * 
 *   outgoingplusnew = (crcword & 0xFF) ^ newbyte;
 *   crcword = (crcword >> 8) ^ table[outgoingplusnew];
 *
 * where table[outgoingplusnew] is computed by setting crcword=0
 * and then iterating the first code fragment eight times (taking
 * the incoming byte low bit first).
 *
 * Note that all shifts are rightward and thus no assumption is
 * made about exact word length! (Although word length must be at
 * _least_ 32 bits, but ANSI C guarantees this for `unsigned long'
 * anyway.)
 */

#include <stdlib.h>

#include "ssh.h"

/* ----------------------------------------------------------------------
 * Multi-function module. Can be compiled three ways.
 *
 *  - Compile with no special #defines. Will generate a table
 *    that's already initialised at compile time, and one function
 *    crc32_compute(buf,len) that uses it. Normal usage.
 *
 *  - Compile with INITFUNC defined. Will generate an uninitialised
 *    array as the table, and as well as crc32_compute(buf,len) it
 *    will also generate void crc32_init(void) which sets up the
 *    table at run time. Useful if binary size is important.
 *
 *  - Compile with GENPROGRAM defined. Will create a standalone
 *    program that does the initialisation and outputs the table as
 *    C code.
 */

#define POLY (0xEDB88320L)

#ifdef GENPROGRAM
#define INITFUNC		       /* the gen program needs the init func :-) */
#endif

#ifdef INITFUNC

/*
 * This variant of the code generates the table at run-time from an
 * init function.
 */
static unsigned long crc32_table[256];

void crc32_init(void)
{
    unsigned long crcword;
    int i;

    for (i = 0; i < 256; i++) {
	unsigned long newbyte, x32term;
	int j;
	crcword = 0;
	newbyte = i;
	for (j = 0; j < 8; j++) {
	    x32term = (crcword ^ newbyte) & 1;
	    crcword = (crcword >> 1) ^ (x32term * POLY);
	    newbyte >>= 1;
	}
	crc32_table[i] = crcword;
    }
}

#else

/*
 * This variant of the code has the data already prepared.
 */
static const unsigned long crc32_table[256] = {
    0x00000000L, 0x77073096L, 0xEE0E612CL, 0x990951BAL,
    0x076DC419L, 0x706AF48FL, 0xE963A535L, 0x9E6495A3L,
    0x0EDB8832L, 0x79DCB8A4L, 0xE0D5E91EL, 0x97D2D988L,
    0x09B64C2BL, 0x7EB17CBDL, 0xE7B82D07L, 0x90BF1D91L,
    0x1DB71064L, 0x6AB020F2L, 0xF3B97148L, 0x84BE41DEL,
    0x1ADAD47DL, 0x6DDDE4EBL, 0xF4D4B551L, 0x83D385C7L,
    0x136C9856L, 0x646BA8C0L, 0xFD62F97AL, 0x8A65C9ECL,
    0x14015C4FL, 0x63066CD9L, 0xFA0F3D63L, 0x8D080DF5L,
    0x3B6E20C8L, 0x4C69105EL, 0xD56041E4L, 0xA2677172L,
    0x3C03E4D1L, 0x4B04D447L, 0xD20D85FDL, 0xA50AB56BL,
    0x35B5A8FAL, 0x42B2986CL, 0xDBBBC9D6L, 0xACBCF940L,
    0x32D86CE3L, 0x45DF5C75L, 0xDCD60DCFL, 0xABD13D59L,
    0x26D930ACL, 0x51DE003AL, 0xC8D75180L, 0xBFD06116L,
    0x21B4F4B5L, 0x56B3C423L, 0xCFBA9599L, 0xB8BDA50FL,
    0x2802B89EL, 0x5F058808L, 0xC60CD9B2L, 0xB10BE924L,
    0x2F6F7C87L, 0x58684C11L, 0xC1611DABL, 0xB6662D3DL,
    0x76DC4190L, 0x01DB7106L, 0x98D220BCL, 0xEFD5102AL,
    0x71B18589L, 0x06B6B51FL, 0x9FBFE4A5L, 0xE8B8D433L,
    0x7807C9A2L, 0x0F00F934L, 0x9609A88EL, 0xE10E9818L,
    0x7F6A0DBBL, 0x086D3D2DL, 0x91646C97L, 0xE6635C01L,
    0x6B6B51F4L, 0x1C6C6162L, 0x856530D8L, 0xF262004EL,
    0x6C0695EDL, 0x1B01A57BL, 0x8208F4C1L, 0xF50FC457L,
    0x65B0D9C6L, 0x12B7E950L, 0x8BBEB8EAL, 0xFCB9887CL,
    0x62DD1DDFL, 0x15DA2D49L, 0x8CD37CF3L, 0xFBD44C65L,
    0x4DB26158L, 0x3AB551CEL, 0xA3BC0074L, 0xD4BB30E2L,
    0x4ADFA541L, 0x3DD895D7L, 0xA4D1C46DL, 0xD3D6F4FBL,
    0x4369E96AL, 0x346ED9FCL, 0xAD678846L, 0xDA60B8D0L,
    0x44042D73L, 0x33031DE5L, 0xAA0A4C5FL, 0xDD0D7CC9L,
    0x5005713CL, 0x270241AAL, 0xBE0B1010L, 0xC90C2086L,
    0x5768B525L, 0x206F85B3L, 0xB966D409L, 0xCE61E49FL,
    0x5EDEF90EL, 0x29D9C998L, 0xB0D09822L, 0xC7D7A8B4L,
    0x59B33D17L, 0x2EB40D81L, 0xB7BD5C3BL, 0xC0BA6CADL,
    0xEDB88320L, 0x9ABFB3B6L, 0x03B6E20CL, 0x74B1D29AL,
    0xEAD54739L, 0x9DD277AFL, 0x04DB2615L, 0x73DC1683L,
    0xE3630B12L, 0x94643B84L, 0x0D6D6A3EL, 0x7A6A5AA8L,
    0xE40ECF0BL, 0x9309FF9DL, 0x0A00AE27L, 0x7D079EB1L,
    0xF00F9344L, 0x8708A3D2L, 0x1E01F268L, 0x6906C2FEL,
    0xF762575DL, 0x806567CBL, 0x196C3671L, 0x6E6B06E7L,
    0xFED41B76L, 0x89D32BE0L, 0x10DA7A5AL, 0x67DD4ACCL,
    0xF9B9DF6FL, 0x8EBEEFF9L, 0x17B7BE43L, 0x60B08ED5L,
    0xD6D6A3E8L, 0xA1D1937EL, 0x38D8C2C4L, 0x4FDFF252L,
    0xD1BB67F1L, 0xA6BC5767L, 0x3FB506DDL, 0x48B2364BL,
    0xD80D2BDAL, 0xAF0A1B4CL, 0x36034AF6L, 0x41047A60L,
    0xDF60EFC3L, 0xA867DF55L, 0x316E8EEFL, 0x4669BE79L,
    0xCB61B38CL, 0xBC66831AL, 0x256FD2A0L, 0x5268E236L,
    0xCC0C7795L, 0xBB0B4703L, 0x220216B9L, 0x5505262FL,
    0xC5BA3BBEL, 0xB2BD0B28L, 0x2BB45A92L, 0x5CB36A04L,
    0xC2D7FFA7L, 0xB5D0CF31L, 0x2CD99E8BL, 0x5BDEAE1DL,
    0x9B64C2B0L, 0xEC63F226L, 0x756AA39CL, 0x026D930AL,
    0x9C0906A9L, 0xEB0E363FL, 0x72076785L, 0x05005713L,
    0x95BF4A82L, 0xE2B87A14L, 0x7BB12BAEL, 0x0CB61B38L,
    0x92D28E9BL, 0xE5D5BE0DL, 0x7CDCEFB7L, 0x0BDBDF21L,
    0x86D3D2D4L, 0xF1D4E242L, 0x68DDB3F8L, 0x1FDA836EL,
    0x81BE16CDL, 0xF6B9265BL, 0x6FB077E1L, 0x18B74777L,
    0x88085AE6L, 0xFF0F6A70L, 0x66063BCAL, 0x11010B5CL,
    0x8F659EFFL, 0xF862AE69L, 0x616BFFD3L, 0x166CCF45L,
    0xA00AE278L, 0xD70DD2EEL, 0x4E048354L, 0x3903B3C2L,
    0xA7672661L, 0xD06016F7L, 0x4969474DL, 0x3E6E77DBL,
    0xAED16A4AL, 0xD9D65ADCL, 0x40DF0B66L, 0x37D83BF0L,
    0xA9BCAE53L, 0xDEBB9EC5L, 0x47B2CF7FL, 0x30B5FFE9L,
    0xBDBDF21CL, 0xCABAC28AL, 0x53B39330L, 0x24B4A3A6L,
    0xBAD03605L, 0xCDD70693L, 0x54DE5729L, 0x23D967BFL,
    0xB3667A2EL, 0xC4614AB8L, 0x5D681B02L, 0x2A6F2B94L,
    0xB40BBE37L, 0xC30C8EA1L, 0x5A05DF1BL, 0x2D02EF8DL
};

#endif

#ifdef GENPROGRAM
int main(void)
{
    unsigned long crcword;
    int i;

    crc32_init();
    for (i = 0; i < 256; i++) {
	printf("%s0x%08XL%s",
	       (i % 4 == 0 ? "    " : " "),
	       crc32_table[i],
	       (i % 4 == 3 ? (i == 255 ? "\n" : ",\n") : ","));
    }

    return 0;
}
#endif

unsigned long crc32_update(unsigned long crcword, const void *buf, size_t len)
{
    const unsigned char *p = (const unsigned char *) buf;
    while (len--) {
	unsigned long newbyte = *p++;
	newbyte ^= crcword & 0xFFL;
	crcword = (crcword >> 8) ^ crc32_table[newbyte];
    }
    return crcword;
}

unsigned long crc32_compute(const void *buf, size_t len)
{
    return crc32_update(0L, buf, len);
}
Commit	Line	Data
8160fbfc	1	/*
	2	* CRC32 implementation.
	3	*
	4	* The basic concept of a CRC is that you treat your bit-string
	5	* abcdefg... as a ludicrously long polynomial M=a+bx+cx^2+dx^3+...
	6	* over Z[2]. You then take a modulus polynomial P, and compute the
	7	* remainder of M on division by P. Thus, an erroneous message N
	8	* will only have the same CRC if the difference E = M-N is an
	9	* exact multiple of P. (Note that as we are working over Z[2], M-N
	10	* = N-M = M+N; but that's not very important.)
	11	*
	12	* What makes the CRC good is choosing P to have good properties:
	13	*
	14	* - If its first and last terms are both nonzero then it cannot
	15	* be a factor of any single term x^i. Therefore if M and N
	16	* differ by exactly one bit their CRCs will guaranteeably
	17	* be distinct.
	18	*
	19	* - If it has a prime (irreducible) factor with three terms then
	20	* it cannot divide a polynomial of the form x^i(1+x^j).
	21	* Therefore if M and N differ by exactly _two_ bits they will
	22	* have different CRCs.
	23	*
	24	* - If it has a factor (x+1) then it cannot divide a polynomial
	25	* with an odd number of terms. Therefore if M and N differ by
	26	* _any odd_ number of bits they will have different CRCs.
	27	*
	28	* - If the error term E is of the form x^i*B(x) where B(x) has
	29	* order less than P (i.e. a short _burst_ of errors) then P
	30	* cannot divide E (since no polynomial can divide a shorter
	31	* one), so any such error burst will be spotted.
	32	*
	33	* The CRC32 standard polynomial is
	34	* x^32+x^26+x^23+x^22+x^16+x^12+x^11+x^10+x^8+x^7+x^5+x^4+x^2+x^1+x^0
	35	*
	36	* In fact, we don't compute M mod P; we compute M*x^32 mod P.
	37	*
	38	* The concrete implementation of the CRC is this: we maintain at
	39	* all times a 32-bit word which is the current remainder of the
	40	* polynomial mod P. Whenever we receive an extra bit, we multiply
	41	* the existing remainder by x, add (XOR) the x^32 term thus
	42	* generated to the new x^32 term caused by the incoming bit, and
	43	* remove the resulting combined x^32 term if present by replacing
	44	* it with (P-x^32).
	45	*
	46	* Bit 0 of the word is the x^31 term and bit 31 is the x^0 term.
	47	* Thus, multiplying by x means shifting right. So the actual
	48	* algorithm goes like this:
	49	*
	50	* x32term = (crcword & 1) ^ newbit;
	51	* crcword = (crcword >> 1) ^ (x32term * 0xEDB88320);
	52	*
	53	* In practice, we pre-compute what will happen to crcword on any
	54	* given sequence of eight incoming bits, and store that in a table
	55	* which we then use at run-time to do the job:
	56	*
	57	* outgoingplusnew = (crcword & 0xFF) ^ newbyte;
	58	* crcword = (crcword >> 8) ^ table[outgoingplusnew];
	59	*
	60	* where table[outgoingplusnew] is computed by setting crcword=0
	61	* and then iterating the first code fragment eight times (taking
	62	* the incoming byte low bit first).
	63	*
	64	* Note that all shifts are rightward and thus no assumption is
65	* made about exact word length! (Although word length must be at
66	* _least_ 32 bits, but ANSI C guarantees this for `unsigned long'
67	* anyway.)
68	*/
374330e2	69
8160fbfc	70	#include <stdlib.h>
374330e2	71
fb3d9ab5	72	#include "ssh.h"
5451b83a	73
8160fbfc	74	/* ----------------------------------------------------------------------
	75	* Multi-function module. Can be compiled three ways.
	76	*
	77	* - Compile with no special #defines. Will generate a table
	78	* that's already initialised at compile time, and one function
71bedafe	79	* crc32_compute(buf,len) that uses it. Normal usage.
8160fbfc	80	*
8160fbfc	81	* - Compile with INITFUNC defined. Will generate an uninitialised
71bedafe	82	* array as the table, and as well as crc32_compute(buf,len) it
	83	* will also generate void crc32_init(void) which sets up the
	84	* table at run time. Useful if binary size is important.
8160fbfc	85	*
	86	* - Compile with GENPROGRAM defined. Will create a standalone
	87	* program that does the initialisation and outputs the table as
	88	* C code.
	89	*/
374330e2	90
8160fbfc	91	#define POLY (0xEDB88320L)
	92
	93	#ifdef GENPROGRAM
32874aea	94	#define INITFUNC /* the gen program needs the init func :-) */
8160fbfc	95	#endif
	96
	97	#ifdef INITFUNC
	98
	99	/*
	100	* This variant of the code generates the table at run-time from an
	101	* init function.
	102	*/
	103	static unsigned long crc32_table[256];
	104
32874aea	105	void crc32_init(void)
32874aea	106	{
8160fbfc	107	unsigned long crcword;
8160fbfc	108	int i;
32874aea	109
8160fbfc	110	for (i = 0; i < 256; i++) {
32874aea	111	unsigned long newbyte, x32term;
	112	int j;
	113	crcword = 0;
	114	newbyte = i;
	115	for (j = 0; j < 8; j++) {
	116	x32term = (crcword ^ newbyte) & 1;
	117	crcword = (crcword >> 1) ^ (x32term * POLY);
	118	newbyte >>= 1;
	119	}
	120	crc32_table[i] = crcword;
8160fbfc	121	}
	122	}
	123
	124	#else
	125
	126	/*
	127	* This variant of the code has the data already prepared.
	128	*/
	129	static const unsigned long crc32_table[256] = {
	130	0x00000000L, 0x77073096L, 0xEE0E612CL, 0x990951BAL,
	131	0x076DC419L, 0x706AF48FL, 0xE963A535L, 0x9E6495A3L,
	132	0x0EDB8832L, 0x79DCB8A4L, 0xE0D5E91EL, 0x97D2D988L,
	133	0x09B64C2BL, 0x7EB17CBDL, 0xE7B82D07L, 0x90BF1D91L,
	134	0x1DB71064L, 0x6AB020F2L, 0xF3B97148L, 0x84BE41DEL,
	135	0x1ADAD47DL, 0x6DDDE4EBL, 0xF4D4B551L, 0x83D385C7L,
	136	0x136C9856L, 0x646BA8C0L, 0xFD62F97AL, 0x8A65C9ECL,
	137	0x14015C4FL, 0x63066CD9L, 0xFA0F3D63L, 0x8D080DF5L,
	138	0x3B6E20C8L, 0x4C69105EL, 0xD56041E4L, 0xA2677172L,
	139	0x3C03E4D1L, 0x4B04D447L, 0xD20D85FDL, 0xA50AB56BL,
	140	0x35B5A8FAL, 0x42B2986CL, 0xDBBBC9D6L, 0xACBCF940L,
	141	0x32D86CE3L, 0x45DF5C75L, 0xDCD60DCFL, 0xABD13D59L,
	142	0x26D930ACL, 0x51DE003AL, 0xC8D75180L, 0xBFD06116L,
	143	0x21B4F4B5L, 0x56B3C423L, 0xCFBA9599L, 0xB8BDA50FL,
	144	0x2802B89EL, 0x5F058808L, 0xC60CD9B2L, 0xB10BE924L,
	145	0x2F6F7C87L, 0x58684C11L, 0xC1611DABL, 0xB6662D3DL,
	146	0x76DC4190L, 0x01DB7106L, 0x98D220BCL, 0xEFD5102AL,
	147	0x71B18589L, 0x06B6B51FL, 0x9FBFE4A5L, 0xE8B8D433L,
	148	0x7807C9A2L, 0x0F00F934L, 0x9609A88EL, 0xE10E9818L,
	149	0x7F6A0DBBL, 0x086D3D2DL, 0x91646C97L, 0xE6635C01L,
	150	0x6B6B51F4L, 0x1C6C6162L, 0x856530D8L, 0xF262004EL,
	151	0x6C0695EDL, 0x1B01A57BL, 0x8208F4C1L, 0xF50FC457L,
	152	0x65B0D9C6L, 0x12B7E950L, 0x8BBEB8EAL, 0xFCB9887CL,
	153	0x62DD1DDFL, 0x15DA2D49L, 0x8CD37CF3L, 0xFBD44C65L,
	154	0x4DB26158L, 0x3AB551CEL, 0xA3BC0074L, 0xD4BB30E2L,
	155	0x4ADFA541L, 0x3DD895D7L, 0xA4D1C46DL, 0xD3D6F4FBL,
	156	0x4369E96AL, 0x346ED9FCL, 0xAD678846L, 0xDA60B8D0L,
	157	0x44042D73L, 0x33031DE5L, 0xAA0A4C5FL, 0xDD0D7CC9L,
	158	0x5005713CL, 0x270241AAL, 0xBE0B1010L, 0xC90C2086L,
	159	0x5768B525L, 0x206F85B3L, 0xB966D409L, 0xCE61E49FL,
	160	0x5EDEF90EL, 0x29D9C998L, 0xB0D09822L, 0xC7D7A8B4L,
	161	0x59B33D17L, 0x2EB40D81L, 0xB7BD5C3BL, 0xC0BA6CADL,
	162	0xEDB88320L, 0x9ABFB3B6L, 0x03B6E20CL, 0x74B1D29AL,
	163	0xEAD54739L, 0x9DD277AFL, 0x04DB2615L, 0x73DC1683L,
	164	0xE3630B12L, 0x94643B84L, 0x0D6D6A3EL, 0x7A6A5AA8L,
	165	0xE40ECF0BL, 0x9309FF9DL, 0x0A00AE27L, 0x7D079EB1L,
	166	0xF00F9344L, 0x8708A3D2L, 0x1E01F268L, 0x6906C2FEL,
	167	0xF762575DL, 0x806567CBL, 0x196C3671L, 0x6E6B06E7L,
	168	0xFED41B76L, 0x89D32BE0L, 0x10DA7A5AL, 0x67DD4ACCL,
	169	0xF9B9DF6FL, 0x8EBEEFF9L, 0x17B7BE43L, 0x60B08ED5L,
	170	0xD6D6A3E8L, 0xA1D1937EL, 0x38D8C2C4L, 0x4FDFF252L,
	171	0xD1BB67F1L, 0xA6BC5767L, 0x3FB506DDL, 0x48B2364BL,
	172	0xD80D2BDAL, 0xAF0A1B4CL, 0x36034AF6L, 0x41047A60L,
	173	0xDF60EFC3L, 0xA867DF55L, 0x316E8EEFL, 0x4669BE79L,
	174	0xCB61B38CL, 0xBC66831AL, 0x256FD2A0L, 0x5268E236L,
	175	0xCC0C7795L, 0xBB0B4703L, 0x220216B9L, 0x5505262FL,
	176	0xC5BA3BBEL, 0xB2BD0B28L, 0x2BB45A92L, 0x5CB36A04L,
	177	0xC2D7FFA7L, 0xB5D0CF31L, 0x2CD99E8BL, 0x5BDEAE1DL,
	178	0x9B64C2B0L, 0xEC63F226L, 0x756AA39CL, 0x026D930AL,
	179	0x9C0906A9L, 0xEB0E363FL, 0x72076785L, 0x05005713L,
	180	0x95BF4A82L, 0xE2B87A14L, 0x7BB12BAEL, 0x0CB61B38L,
	181	0x92D28E9BL, 0xE5D5BE0DL, 0x7CDCEFB7L, 0x0BDBDF21L,
	182	0x86D3D2D4L, 0xF1D4E242L, 0x68DDB3F8L, 0x1FDA836EL,
	183	0x81BE16CDL, 0xF6B9265BL, 0x6FB077E1L, 0x18B74777L,
	184	0x88085AE6L, 0xFF0F6A70L, 0x66063BCAL, 0x11010B5CL,
185	0x8F659EFFL, 0xF862AE69L, 0x616BFFD3L, 0x166CCF45L,
186	0xA00AE278L, 0xD70DD2EEL, 0x4E048354L, 0x3903B3C2L,
187	0xA7672661L, 0xD06016F7L, 0x4969474DL, 0x3E6E77DBL,
188	0xAED16A4AL, 0xD9D65ADCL, 0x40DF0B66L, 0x37D83BF0L,
189	0xA9BCAE53L, 0xDEBB9EC5L, 0x47B2CF7FL, 0x30B5FFE9L,
190	0xBDBDF21CL, 0xCABAC28AL, 0x53B39330L, 0x24B4A3A6L,
191	0xBAD03605L, 0xCDD70693L, 0x54DE5729L, 0x23D967BFL,
192	0xB3667A2EL, 0xC4614AB8L, 0x5D681B02L, 0x2A6F2B94L,
193	0xB40BBE37L, 0xC30C8EA1L, 0x5A05DF1BL, 0x2D02EF8DL
194	};
195
196	#endif
197
198	#ifdef GENPROGRAM
32874aea	199	int main(void)
32874aea	200	{
8160fbfc	201	unsigned long crcword;
	202	int i;
	203
	204	crc32_init();
	205	for (i = 0; i < 256; i++) {
32874aea	206	printf("%s0x%08XL%s",
	207	(i % 4 == 0 ? " " : " "),
	208	crc32_table[i],
	209	(i % 4 == 3 ? (i == 255 ? "\n" : ",\n") : ","));
8160fbfc	210	}
	211
	212	return 0;
	213	}
	214	#endif
	215
9a3a93a5	216	unsigned long crc32_update(unsigned long crcword, const void *buf, size_t len)
32874aea	217	{
8160fbfc	218	const unsigned char p = (const unsigned char ) buf;
8160fbfc	219	while (len--) {
32874aea	220	unsigned long newbyte = *p++;
	221	newbyte ^= crcword & 0xFFL;
	222	crcword = (crcword >> 8) ^ crc32_table[newbyte];
374330e2	223	}
8160fbfc	224	return crcword;
374330e2	225	}
9a3a93a5	226
71bedafe	227	unsigned long crc32_compute(const void *buf, size_t len)
9a3a93a5	228	{
	229	return crc32_update(0L, buf, len);
	230	}