crypto/apr_sha1.c - apr-util - Git at Google

 /* Licensed to the Apache Software Foundation (ASF) under one or more
  * contributor license agreements.  See the NOTICE file distributed with
  * this work for additional information regarding copyright ownership.
  * The ASF licenses this file to You under the Apache License, Version 2.0
  * (the "License"); you may not use this file except in compliance with
  * the License.  You may obtain a copy of the License at
  *
  *     http://www.apache.org/licenses/LICENSE-2.0
  *
  * Unless required by applicable law or agreed to in writing, software
  * distributed under the License is distributed on an "AS IS" BASIS,
  * WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
  * See the License for the specific language governing permissions and
  * limitations under the License.
  */

 /*
  * The exported function:
  *
  * 	 apr_sha1_base64(const char *clear, int len, char *out);
  *
  * provides a means to SHA1 crypt/encode a plaintext password in
  * a way which makes password files compatible with those commonly
  * used in netscape web and ldap installations. It was put together
  * by Clinton Wong <clintdw@netcom.com>, who also notes that:
  *
  * Note: SHA1 support is useful for migration purposes, but is less
  *     secure than Apache's password format, since Apache's (MD5)
  *     password format uses a random eight character salt to generate
  *     one of many possible hashes for the same password.  Netscape
  *     uses plain SHA1 without a salt, so the same password
  *     will always generate the same hash, making it easier
  *     to break since the search space is smaller.
  *
  * See also the documentation in support/SHA1 as to hints on how to
  * migrate an existing netscape installation and other supplied utitlites.
  *
  * This software also makes use of the following component:
  *
  * NIST Secure Hash Algorithm
  *  	heavily modified by Uwe Hollerbach uh@alumni.caltech edu
  *	from Peter C. Gutmann's implementation as found in
  *	Applied Cryptography by Bruce Schneier
  *	This code is hereby placed in the public domain
  */

 #include "apr_sha1.h"
 #include "apr_base64.h"
 #include "apr_strings.h"
 #include "apr_lib.h"
 #if APR_CHARSET_EBCDIC
 #include "apr_xlate.h"
 #endif /*APR_CHARSET_EBCDIC*/
 #include <string.h>

 /* a bit faster & bigger, if defined */
 #define UNROLL_LOOPS

 /* NIST's proposed modification to SHA, 7/11/94 */
 #define USE_MODIFIED_SHA

 /* SHA f()-functions */
 #define f1(x,y,z)	((x & y) | (~x & z))
 #define f2(x,y,z)	(x ^ y ^ z)
 #define f3(x,y,z)	((x & y) | (x & z) | (y & z))
 #define f4(x,y,z)	(x ^ y ^ z)

 /* SHA constants */
 #define CONST1		0x5a827999L
 #define CONST2		0x6ed9eba1L
 #define CONST3		0x8f1bbcdcL
 #define CONST4		0xca62c1d6L

 /* 32-bit rotate */

 #define ROT32(x,n)	((x << n) | (x >> (32 - n)))

 #define FUNC(n,i)						\
     temp = ROT32(A,5) + f##n(B,C,D) + E + W[i] + CONST##n;	\
     E = D; D = C; C = ROT32(B,30); B = A; A = temp

 #define SHA_BLOCKSIZE           64

 #if APR_CHARSET_EBCDIC
 static apr_xlate_t *ebcdic2ascii_xlate;

 APU_DECLARE(apr_status_t) apr_SHA1InitEBCDIC(apr_xlate_t *x)
 {
     apr_status_t rv;
     int onoff;

     /* Only single-byte conversion is supported.
      */
     rv = apr_xlate_sb_get(x, &onoff);
     if (rv) {
         return rv;
     }
     if (!onoff) { /* If conversion is not single-byte-only */
         return APR_EINVAL;
     }
     ebcdic2ascii_xlate = x;
     return APR_SUCCESS;
 }
 #endif

 /* do SHA transformation */
 static void sha_transform(apr_sha1_ctx_t *sha_info)
 {
     int i;
     apr_uint32_t temp, A, B, C, D, E, W[80];

     for (i = 0; i < 16; ++i) {
 	W[i] = sha_info->data[i];
     }
     for (i = 16; i < 80; ++i) {
 	W[i] = W[i-3] ^ W[i-8] ^ W[i-14] ^ W[i-16];
 #ifdef USE_MODIFIED_SHA
 	W[i] = ROT32(W[i], 1);
 #endif /* USE_MODIFIED_SHA */
     }
     A = sha_info->digest[0];
     B = sha_info->digest[1];
     C = sha_info->digest[2];
     D = sha_info->digest[3];
     E = sha_info->digest[4];
 #ifdef UNROLL_LOOPS
     FUNC(1, 0);  FUNC(1, 1);  FUNC(1, 2);  FUNC(1, 3);  FUNC(1, 4);
     FUNC(1, 5);  FUNC(1, 6);  FUNC(1, 7);  FUNC(1, 8);  FUNC(1, 9);
     FUNC(1,10);  FUNC(1,11);  FUNC(1,12);  FUNC(1,13);  FUNC(1,14);
     FUNC(1,15);  FUNC(1,16);  FUNC(1,17);  FUNC(1,18);  FUNC(1,19);

     FUNC(2,20);  FUNC(2,21);  FUNC(2,22);  FUNC(2,23);  FUNC(2,24);
     FUNC(2,25);  FUNC(2,26);  FUNC(2,27);  FUNC(2,28);  FUNC(2,29);
     FUNC(2,30);  FUNC(2,31);  FUNC(2,32);  FUNC(2,33);  FUNC(2,34);
     FUNC(2,35);  FUNC(2,36);  FUNC(2,37);  FUNC(2,38);  FUNC(2,39);

     FUNC(3,40);  FUNC(3,41);  FUNC(3,42);  FUNC(3,43);  FUNC(3,44);
     FUNC(3,45);  FUNC(3,46);  FUNC(3,47);  FUNC(3,48);  FUNC(3,49);
     FUNC(3,50);  FUNC(3,51);  FUNC(3,52);  FUNC(3,53);  FUNC(3,54);
     FUNC(3,55);  FUNC(3,56);  FUNC(3,57);  FUNC(3,58);  FUNC(3,59);

     FUNC(4,60);  FUNC(4,61);  FUNC(4,62);  FUNC(4,63);  FUNC(4,64);
     FUNC(4,65);  FUNC(4,66);  FUNC(4,67);  FUNC(4,68);  FUNC(4,69);
     FUNC(4,70);  FUNC(4,71);  FUNC(4,72);  FUNC(4,73);  FUNC(4,74);
     FUNC(4,75);  FUNC(4,76);  FUNC(4,77);  FUNC(4,78);  FUNC(4,79);
 #else /* !UNROLL_LOOPS */
     for (i = 0; i < 20; ++i) {
 	FUNC(1,i);
     }
     for (i = 20; i < 40; ++i) {
 	FUNC(2,i);
     }
     for (i = 40; i < 60; ++i) {
 	FUNC(3,i);
     }
     for (i = 60; i < 80; ++i) {
 	FUNC(4,i);
     }
 #endif /* !UNROLL_LOOPS */
     sha_info->digest[0] += A;
     sha_info->digest[1] += B;
     sha_info->digest[2] += C;
     sha_info->digest[3] += D;
     sha_info->digest[4] += E;
 }

 union endianTest {
     long Long;
     char Char[sizeof(long)];
 };

 static char isLittleEndian(void)
 {
     static union endianTest u;
     u.Long = 1;
     return (u.Char[0] == 1);
 }

 /* change endianness of data */

 /* count is the number of bytes to do an endian flip */
 static void maybe_byte_reverse(apr_uint32_t *buffer, int count)
 {
     int i;
     apr_byte_t ct[4], *cp;

     if (isLittleEndian()) {	/* do the swap only if it is little endian */
 	count /= sizeof(apr_uint32_t);
 	cp = (apr_byte_t *) buffer;
 	for (i = 0; i < count; ++i) {
 	    ct[0] = cp[0];
 	    ct[1] = cp[1];
 	    ct[2] = cp[2];
 	    ct[3] = cp[3];
 	    cp[0] = ct[3];
 	    cp[1] = ct[2];
 	    cp[2] = ct[1];
 	    cp[3] = ct[0];
 	    cp += sizeof(apr_uint32_t);
 	}
     }
 }

 /* initialize the SHA digest */

 APU_DECLARE(void) apr_sha1_init(apr_sha1_ctx_t *sha_info)
 {
     sha_info->digest[0] = 0x67452301L;
     sha_info->digest[1] = 0xefcdab89L;
     sha_info->digest[2] = 0x98badcfeL;
     sha_info->digest[3] = 0x10325476L;
     sha_info->digest[4] = 0xc3d2e1f0L;
     sha_info->count_lo = 0L;
     sha_info->count_hi = 0L;
     sha_info->local = 0;
 }

 /* update the SHA digest */

 APU_DECLARE(void) apr_sha1_update_binary(apr_sha1_ctx_t *sha_info,
                                      const unsigned char *buffer,
                                      unsigned int count)
 {
     unsigned int i;

     if ((sha_info->count_lo + ((apr_uint32_t) count << 3)) < sha_info->count_lo) {
 	++sha_info->count_hi;
     }
     sha_info->count_lo += (apr_uint32_t) count << 3;
     sha_info->count_hi += (apr_uint32_t) count >> 29;
     if (sha_info->local) {
 	i = SHA_BLOCKSIZE - sha_info->local;
 	if (i > count) {
 	    i = count;
 	}
 	memcpy(((apr_byte_t *) sha_info->data) + sha_info->local, buffer, i);
 	count -= i;
 	buffer += i;
 	sha_info->local += i;
 	if (sha_info->local == SHA_BLOCKSIZE) {
 	    maybe_byte_reverse(sha_info->data, SHA_BLOCKSIZE);
 	    sha_transform(sha_info);
 	}
 	else {
 	    return;
 	}
     }
     while (count >= SHA_BLOCKSIZE) {
 	memcpy(sha_info->data, buffer, SHA_BLOCKSIZE);
 	buffer += SHA_BLOCKSIZE;
 	count -= SHA_BLOCKSIZE;
 	maybe_byte_reverse(sha_info->data, SHA_BLOCKSIZE);
 	sha_transform(sha_info);
     }
     memcpy(sha_info->data, buffer, count);
     sha_info->local = count;
 }

 APU_DECLARE(void) apr_sha1_update(apr_sha1_ctx_t *sha_info, const char *buf,
                               unsigned int count)
 {
 #if APR_CHARSET_EBCDIC
     int i;
     const apr_byte_t *buffer = (const apr_byte_t *) buf;
     apr_size_t inbytes_left, outbytes_left;

     if ((sha_info->count_lo + ((apr_uint32_t) count << 3)) < sha_info->count_lo) {
 	++sha_info->count_hi;
     }
     sha_info->count_lo += (apr_uint32_t) count << 3;
     sha_info->count_hi += (apr_uint32_t) count >> 29;
     /* Is there a remainder of the previous Update operation? */
     if (sha_info->local) {
 	i = SHA_BLOCKSIZE - sha_info->local;
 	if (i > count) {
 	    i = count;
 	}
         inbytes_left = outbytes_left = i;
         apr_xlate_conv_buffer(ebcdic2ascii_xlate, buffer, &inbytes_left,
                               ((apr_byte_t *) sha_info->data) + sha_info->local,
                               &outbytes_left);
 	count -= i;
 	buffer += i;
 	sha_info->local += i;
 	if (sha_info->local == SHA_BLOCKSIZE) {
 	    maybe_byte_reverse(sha_info->data, SHA_BLOCKSIZE);
 	    sha_transform(sha_info);
 	}
 	else {
 	    return;
 	}
     }
     while (count >= SHA_BLOCKSIZE) {
         inbytes_left = outbytes_left = SHA_BLOCKSIZE;
         apr_xlate_conv_buffer(ebcdic2ascii_xlate, buffer, &inbytes_left,
                               (apr_byte_t *) sha_info->data, &outbytes_left);
 	buffer += SHA_BLOCKSIZE;
 	count -= SHA_BLOCKSIZE;
 	maybe_byte_reverse(sha_info->data, SHA_BLOCKSIZE);
 	sha_transform(sha_info);
     }
     inbytes_left = outbytes_left = count;
     apr_xlate_conv_buffer(ebcdic2ascii_xlate, buffer, &inbytes_left,
                           (apr_byte_t *) sha_info->data, &outbytes_left);
     sha_info->local = count;
 #else
     apr_sha1_update_binary(sha_info, (const unsigned char *) buf, count);
 #endif
 }

 /* finish computing the SHA digest */

 APU_DECLARE(void) apr_sha1_final(unsigned char digest[APR_SHA1_DIGESTSIZE],
                              apr_sha1_ctx_t *sha_info)
 {
     int count, i, j;
     apr_uint32_t lo_bit_count, hi_bit_count, k;

     lo_bit_count = sha_info->count_lo;
     hi_bit_count = sha_info->count_hi;
     count = (int) ((lo_bit_count >> 3) & 0x3f);
     ((apr_byte_t *) sha_info->data)[count++] = 0x80;
     if (count > SHA_BLOCKSIZE - 8) {
 	memset(((apr_byte_t *) sha_info->data) + count, 0, SHA_BLOCKSIZE - count);
 	maybe_byte_reverse(sha_info->data, SHA_BLOCKSIZE);
 	sha_transform(sha_info);
 	memset((apr_byte_t *) sha_info->data, 0, SHA_BLOCKSIZE - 8);
     }
     else {
 	memset(((apr_byte_t *) sha_info->data) + count, 0,
 	       SHA_BLOCKSIZE - 8 - count);
     }
     maybe_byte_reverse(sha_info->data, SHA_BLOCKSIZE);
     sha_info->data[14] = hi_bit_count;
     sha_info->data[15] = lo_bit_count;
     sha_transform(sha_info);

     for (i = 0, j = 0; j < APR_SHA1_DIGESTSIZE; i++) {
 	k = sha_info->digest[i];
 	digest[j++] = (unsigned char) ((k >> 24) & 0xff);
 	digest[j++] = (unsigned char) ((k >> 16) & 0xff);
 	digest[j++] = (unsigned char) ((k >> 8) & 0xff);
 	digest[j++] = (unsigned char) (k & 0xff);
     }
 }


 APU_DECLARE(void) apr_sha1_base64(const char *clear, int len, char *out)
 {
     int l;
     apr_sha1_ctx_t context;
     apr_byte_t digest[APR_SHA1_DIGESTSIZE];

     apr_sha1_init(&context);
     apr_sha1_update(&context, clear, len);
     apr_sha1_final(digest, &context);

     /* private marker. */
     apr_cpystrn(out, APR_SHA1PW_ID, APR_SHA1PW_IDLEN + 1);

     /* SHA1 hash is always 20 chars */
     l = apr_base64_encode_binary(out + APR_SHA1PW_IDLEN, digest, sizeof(digest));
     out[l + APR_SHA1PW_IDLEN] = '\0';

     /*
      * output of base64 encoded SHA1 is always 28 chars + APR_SHA1PW_IDLEN
      */
 }
	/* Licensed to the Apache Software Foundation (ASF) under one or more
	* contributor license agreements. See the NOTICE file distributed with
	* this work for additional information regarding copyright ownership.
	* The ASF licenses this file to You under the Apache License, Version 2.0
	* (the "License"); you may not use this file except in compliance with
	* the License. You may obtain a copy of the License at
	*
	* http://www.apache.org/licenses/LICENSE-2.0
	*
	* Unless required by applicable law or agreed to in writing, software
	* distributed under the License is distributed on an "AS IS" BASIS,
	* WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
	* See the License for the specific language governing permissions and
	* limitations under the License.
	*/

	/*
	* The exported function:
	*
	* apr_sha1_base64(const char clear, int len, char out);
	*
	* provides a means to SHA1 crypt/encode a plaintext password in
	* a way which makes password files compatible with those commonly
	* used in netscape web and ldap installations. It was put together
	* by Clinton Wong <clintdw@netcom.com>, who also notes that:
	*
	* Note: SHA1 support is useful for migration purposes, but is less
	* secure than Apache's password format, since Apache's (MD5)
	* password format uses a random eight character salt to generate
	* one of many possible hashes for the same password. Netscape
	* uses plain SHA1 without a salt, so the same password
	* will always generate the same hash, making it easier
	* to break since the search space is smaller.
	*
	* See also the documentation in support/SHA1 as to hints on how to
	* migrate an existing netscape installation and other supplied utitlites.
	*
	* This software also makes use of the following component:
	*
	* NIST Secure Hash Algorithm
	* heavily modified by Uwe Hollerbach uh@alumni.caltech edu
	* from Peter C. Gutmann's implementation as found in
	* Applied Cryptography by Bruce Schneier
	* This code is hereby placed in the public domain
	*/

	#include "apr_sha1.h"
	#include "apr_base64.h"
	#include "apr_strings.h"
	#include "apr_lib.h"
	#if APR_CHARSET_EBCDIC
	#include "apr_xlate.h"
	#endif /APR_CHARSET_EBCDIC/
	#include <string.h>

	/* a bit faster & bigger, if defined */
	#define UNROLL_LOOPS

	/* NIST's proposed modification to SHA, 7/11/94 */
	#define USE_MODIFIED_SHA

	/* SHA f()-functions */
	#define f1(x,y,z) ((x & y) \| (~x & z))
	#define f2(x,y,z) (x ^ y ^ z)
	#define f3(x,y,z) ((x & y) \| (x & z) \| (y & z))
	#define f4(x,y,z) (x ^ y ^ z)

	/* SHA constants */
	#define CONST1 0x5a827999L
	#define CONST2 0x6ed9eba1L
	#define CONST3 0x8f1bbcdcL
	#define CONST4 0xca62c1d6L

	/* 32-bit rotate */

	#define ROT32(x,n) ((x << n) \| (x >> (32 - n)))

	#define FUNC(n,i) \
	temp = ROT32(A,5) + f##n(B,C,D) + E + W[i] + CONST##n; \
	E = D; D = C; C = ROT32(B,30); B = A; A = temp

	#define SHA_BLOCKSIZE 64

	#if APR_CHARSET_EBCDIC
	static apr_xlate_t *ebcdic2ascii_xlate;

	APU_DECLARE(apr_status_t) apr_SHA1InitEBCDIC(apr_xlate_t *x)
	{
	apr_status_t rv;
	int onoff;

	/* Only single-byte conversion is supported.
	*/
	rv = apr_xlate_sb_get(x, &onoff);
	if (rv) {
	return rv;
	}
	if (!onoff) { /* If conversion is not single-byte-only */
	return APR_EINVAL;
	}
	ebcdic2ascii_xlate = x;
	return APR_SUCCESS;
	}
	#endif

	/* do SHA transformation */
	static void sha_transform(apr_sha1_ctx_t *sha_info)
	{
	int i;
	apr_uint32_t temp, A, B, C, D, E, W[80];

	for (i = 0; i < 16; ++i) {
	W[i] = sha_info->data[i];
	}
	for (i = 16; i < 80; ++i) {
	W[i] = W[i-3] ^ W[i-8] ^ W[i-14] ^ W[i-16];
	#ifdef USE_MODIFIED_SHA
	W[i] = ROT32(W[i], 1);
	#endif /* USE_MODIFIED_SHA */
	}
	A = sha_info->digest[0];
	B = sha_info->digest[1];
	C = sha_info->digest[2];
	D = sha_info->digest[3];
	E = sha_info->digest[4];
	#ifdef UNROLL_LOOPS
	FUNC(1, 0); FUNC(1, 1); FUNC(1, 2); FUNC(1, 3); FUNC(1, 4);
	FUNC(1, 5); FUNC(1, 6); FUNC(1, 7); FUNC(1, 8); FUNC(1, 9);
	FUNC(1,10); FUNC(1,11); FUNC(1,12); FUNC(1,13); FUNC(1,14);
	FUNC(1,15); FUNC(1,16); FUNC(1,17); FUNC(1,18); FUNC(1,19);

	FUNC(2,20); FUNC(2,21); FUNC(2,22); FUNC(2,23); FUNC(2,24);
	FUNC(2,25); FUNC(2,26); FUNC(2,27); FUNC(2,28); FUNC(2,29);
	FUNC(2,30); FUNC(2,31); FUNC(2,32); FUNC(2,33); FUNC(2,34);
	FUNC(2,35); FUNC(2,36); FUNC(2,37); FUNC(2,38); FUNC(2,39);

	FUNC(3,40); FUNC(3,41); FUNC(3,42); FUNC(3,43); FUNC(3,44);
	FUNC(3,45); FUNC(3,46); FUNC(3,47); FUNC(3,48); FUNC(3,49);
	FUNC(3,50); FUNC(3,51); FUNC(3,52); FUNC(3,53); FUNC(3,54);
	FUNC(3,55); FUNC(3,56); FUNC(3,57); FUNC(3,58); FUNC(3,59);

	FUNC(4,60); FUNC(4,61); FUNC(4,62); FUNC(4,63); FUNC(4,64);
	FUNC(4,65); FUNC(4,66); FUNC(4,67); FUNC(4,68); FUNC(4,69);
	FUNC(4,70); FUNC(4,71); FUNC(4,72); FUNC(4,73); FUNC(4,74);
	FUNC(4,75); FUNC(4,76); FUNC(4,77); FUNC(4,78); FUNC(4,79);
	#else /* !UNROLL_LOOPS */
	for (i = 0; i < 20; ++i) {
	FUNC(1,i);
	}
	for (i = 20; i < 40; ++i) {
	FUNC(2,i);
	}
	for (i = 40; i < 60; ++i) {
	FUNC(3,i);
	}
	for (i = 60; i < 80; ++i) {
	FUNC(4,i);
	}
	#endif /* !UNROLL_LOOPS */
	sha_info->digest[0] += A;
	sha_info->digest[1] += B;
	sha_info->digest[2] += C;
	sha_info->digest[3] += D;
	sha_info->digest[4] += E;
	}

	union endianTest {
	long Long;
	char Char[sizeof(long)];
	};

	static char isLittleEndian(void)
	{
	static union endianTest u;
	u.Long = 1;
	return (u.Char[0] == 1);
	}

	/* change endianness of data */

	/* count is the number of bytes to do an endian flip */
	static void maybe_byte_reverse(apr_uint32_t *buffer, int count)
	{
	int i;
	apr_byte_t ct[4], *cp;

	if (isLittleEndian()) { /* do the swap only if it is little endian */
	count /= sizeof(apr_uint32_t);
	cp = (apr_byte_t *) buffer;
	for (i = 0; i < count; ++i) {
	ct[0] = cp[0];
	ct[1] = cp[1];
	ct[2] = cp[2];
	ct[3] = cp[3];
	cp[0] = ct[3];
	cp[1] = ct[2];
	cp[2] = ct[1];
	cp[3] = ct[0];
	cp += sizeof(apr_uint32_t);
	}
	}
	}

	/* initialize the SHA digest */

	APU_DECLARE(void) apr_sha1_init(apr_sha1_ctx_t *sha_info)
	{
	sha_info->digest[0] = 0x67452301L;
	sha_info->digest[1] = 0xefcdab89L;
	sha_info->digest[2] = 0x98badcfeL;
	sha_info->digest[3] = 0x10325476L;
	sha_info->digest[4] = 0xc3d2e1f0L;
	sha_info->count_lo = 0L;
	sha_info->count_hi = 0L;
	sha_info->local = 0;
	}

	/* update the SHA digest */

	APU_DECLARE(void) apr_sha1_update_binary(apr_sha1_ctx_t *sha_info,
	const unsigned char *buffer,
	unsigned int count)
	{
	unsigned int i;

	if ((sha_info->count_lo + ((apr_uint32_t) count << 3)) < sha_info->count_lo) {
	++sha_info->count_hi;
	}
	sha_info->count_lo += (apr_uint32_t) count << 3;
	sha_info->count_hi += (apr_uint32_t) count >> 29;
	if (sha_info->local) {
	i = SHA_BLOCKSIZE - sha_info->local;
	if (i > count) {
	i = count;
	}
	memcpy(((apr_byte_t *) sha_info->data) + sha_info->local, buffer, i);
	count -= i;
	buffer += i;
	sha_info->local += i;
	if (sha_info->local == SHA_BLOCKSIZE) {
	maybe_byte_reverse(sha_info->data, SHA_BLOCKSIZE);
	sha_transform(sha_info);
	}
	else {
	return;
	}
	}
	while (count >= SHA_BLOCKSIZE) {
	memcpy(sha_info->data, buffer, SHA_BLOCKSIZE);
	buffer += SHA_BLOCKSIZE;
	count -= SHA_BLOCKSIZE;
	maybe_byte_reverse(sha_info->data, SHA_BLOCKSIZE);
	sha_transform(sha_info);
	}
	memcpy(sha_info->data, buffer, count);
	sha_info->local = count;
	}

	APU_DECLARE(void) apr_sha1_update(apr_sha1_ctx_t sha_info, const char buf,
	unsigned int count)
	{
	#if APR_CHARSET_EBCDIC
	int i;
	const apr_byte_t buffer = (const apr_byte_t ) buf;
	apr_size_t inbytes_left, outbytes_left;

	if ((sha_info->count_lo + ((apr_uint32_t) count << 3)) < sha_info->count_lo) {
	++sha_info->count_hi;
	}
	sha_info->count_lo += (apr_uint32_t) count << 3;
	sha_info->count_hi += (apr_uint32_t) count >> 29;
	/* Is there a remainder of the previous Update operation? */
	if (sha_info->local) {
	i = SHA_BLOCKSIZE - sha_info->local;
	if (i > count) {
	i = count;
	}
	inbytes_left = outbytes_left = i;
	apr_xlate_conv_buffer(ebcdic2ascii_xlate, buffer, &inbytes_left,
	((apr_byte_t *) sha_info->data) + sha_info->local,
	&outbytes_left);
	count -= i;
	buffer += i;
	sha_info->local += i;
	if (sha_info->local == SHA_BLOCKSIZE) {
	maybe_byte_reverse(sha_info->data, SHA_BLOCKSIZE);
	sha_transform(sha_info);
	}
	else {
	return;
	}
	}
	while (count >= SHA_BLOCKSIZE) {
	inbytes_left = outbytes_left = SHA_BLOCKSIZE;
	apr_xlate_conv_buffer(ebcdic2ascii_xlate, buffer, &inbytes_left,
	(apr_byte_t *) sha_info->data, &outbytes_left);
	buffer += SHA_BLOCKSIZE;
	count -= SHA_BLOCKSIZE;
	maybe_byte_reverse(sha_info->data, SHA_BLOCKSIZE);
	sha_transform(sha_info);
	}
	inbytes_left = outbytes_left = count;
	apr_xlate_conv_buffer(ebcdic2ascii_xlate, buffer, &inbytes_left,
	(apr_byte_t *) sha_info->data, &outbytes_left);
	sha_info->local = count;
	#else
	apr_sha1_update_binary(sha_info, (const unsigned char *) buf, count);
	#endif
	}

	/* finish computing the SHA digest */

	APU_DECLARE(void) apr_sha1_final(unsigned char digest[APR_SHA1_DIGESTSIZE],
	apr_sha1_ctx_t *sha_info)
	{
	int count, i, j;
	apr_uint32_t lo_bit_count, hi_bit_count, k;

	lo_bit_count = sha_info->count_lo;
	hi_bit_count = sha_info->count_hi;
	count = (int) ((lo_bit_count >> 3) & 0x3f);
	((apr_byte_t *) sha_info->data)[count++] = 0x80;
	if (count > SHA_BLOCKSIZE - 8) {
	memset(((apr_byte_t *) sha_info->data) + count, 0, SHA_BLOCKSIZE - count);
	maybe_byte_reverse(sha_info->data, SHA_BLOCKSIZE);
	sha_transform(sha_info);
	memset((apr_byte_t *) sha_info->data, 0, SHA_BLOCKSIZE - 8);
	}
	else {
	memset(((apr_byte_t *) sha_info->data) + count, 0,
	SHA_BLOCKSIZE - 8 - count);
	}
	maybe_byte_reverse(sha_info->data, SHA_BLOCKSIZE);
	sha_info->data[14] = hi_bit_count;
	sha_info->data[15] = lo_bit_count;
	sha_transform(sha_info);

	for (i = 0, j = 0; j < APR_SHA1_DIGESTSIZE; i++) {
	k = sha_info->digest[i];
	digest[j++] = (unsigned char) ((k >> 24) & 0xff);
	digest[j++] = (unsigned char) ((k >> 16) & 0xff);
	digest[j++] = (unsigned char) ((k >> 8) & 0xff);
	digest[j++] = (unsigned char) (k & 0xff);
	}
	}


	APU_DECLARE(void) apr_sha1_base64(const char clear, int len, char out)
	{
	int l;
	apr_sha1_ctx_t context;
	apr_byte_t digest[APR_SHA1_DIGESTSIZE];

	apr_sha1_init(&context);
	apr_sha1_update(&context, clear, len);
	apr_sha1_final(digest, &context);

	/* private marker. */
	apr_cpystrn(out, APR_SHA1PW_ID, APR_SHA1PW_IDLEN + 1);

	/* SHA1 hash is always 20 chars */
	l = apr_base64_encode_binary(out + APR_SHA1PW_IDLEN, digest, sizeof(digest));
	out[l + APR_SHA1PW_IDLEN] = '\0';

	/*
	* output of base64 encoded SHA1 is always 28 chars + APR_SHA1PW_IDLEN
	*/
	}