crypto/bf/bf_enc.c - third_party/openssl - Git at Google

 /*
  * Copyright 1995-2020 The OpenSSL Project Authors. All Rights Reserved.
  *
  * Licensed under the Apache License 2.0 (the "License").  You may not use
  * this file except in compliance with the License.  You can obtain a copy
  * in the file LICENSE in the source distribution or at
  * https://www.openssl.org/source/license.html
  */

 /*
  * BF low level APIs are deprecated for public use, but still ok for internal
  * use.
  */
 #include "internal/deprecated.h"

 #include <openssl/blowfish.h>
 #include "bf_local.h"

 /*
  * Blowfish as implemented from 'Blowfish: Springer-Verlag paper' (From
  * LECTURE NOTES IN COMPUTER SCIENCE 809, FAST SOFTWARE ENCRYPTION, CAMBRIDGE
  * SECURITY WORKSHOP, CAMBRIDGE, U.K., DECEMBER 9-11, 1993)
  */

 #if (BF_ROUNDS != 16) && (BF_ROUNDS != 20)
 # error If you set BF_ROUNDS to some value other than 16 or 20, you will have \
 to modify the code.
 #endif

 void BF_encrypt(BF_LONG *data, const BF_KEY *key)
 {
     register BF_LONG l, r;
     register const BF_LONG *p, *s;

     p = key->P;
     s = &(key->S[0]);
     l = data[0];
     r = data[1];

     l ^= p[0];
     BF_ENC(r, l, s, p[1]);
     BF_ENC(l, r, s, p[2]);
     BF_ENC(r, l, s, p[3]);
     BF_ENC(l, r, s, p[4]);
     BF_ENC(r, l, s, p[5]);
     BF_ENC(l, r, s, p[6]);
     BF_ENC(r, l, s, p[7]);
     BF_ENC(l, r, s, p[8]);
     BF_ENC(r, l, s, p[9]);
     BF_ENC(l, r, s, p[10]);
     BF_ENC(r, l, s, p[11]);
     BF_ENC(l, r, s, p[12]);
     BF_ENC(r, l, s, p[13]);
     BF_ENC(l, r, s, p[14]);
     BF_ENC(r, l, s, p[15]);
     BF_ENC(l, r, s, p[16]);
 # if BF_ROUNDS == 20
     BF_ENC(r, l, s, p[17]);
     BF_ENC(l, r, s, p[18]);
     BF_ENC(r, l, s, p[19]);
     BF_ENC(l, r, s, p[20]);
 # endif
     r ^= p[BF_ROUNDS + 1];

     data[1] = l & 0xffffffffU;
     data[0] = r & 0xffffffffU;
 }

 void BF_decrypt(BF_LONG *data, const BF_KEY *key)
 {
     register BF_LONG l, r;
     register const BF_LONG *p, *s;

     p = key->P;
     s = &(key->S[0]);
     l = data[0];
     r = data[1];

     l ^= p[BF_ROUNDS + 1];
 #  if BF_ROUNDS == 20
     BF_ENC(r, l, s, p[20]);
     BF_ENC(l, r, s, p[19]);
     BF_ENC(r, l, s, p[18]);
     BF_ENC(l, r, s, p[17]);
 #  endif
     BF_ENC(r, l, s, p[16]);
     BF_ENC(l, r, s, p[15]);
     BF_ENC(r, l, s, p[14]);
     BF_ENC(l, r, s, p[13]);
     BF_ENC(r, l, s, p[12]);
     BF_ENC(l, r, s, p[11]);
     BF_ENC(r, l, s, p[10]);
     BF_ENC(l, r, s, p[9]);
     BF_ENC(r, l, s, p[8]);
     BF_ENC(l, r, s, p[7]);
     BF_ENC(r, l, s, p[6]);
     BF_ENC(l, r, s, p[5]);
     BF_ENC(r, l, s, p[4]);
     BF_ENC(l, r, s, p[3]);
     BF_ENC(r, l, s, p[2]);
     BF_ENC(l, r, s, p[1]);
     r ^= p[0];

     data[1] = l & 0xffffffffU;
     data[0] = r & 0xffffffffU;
 }

 void BF_cbc_encrypt(const unsigned char *in, unsigned char *out, long length,
                     const BF_KEY *schedule, unsigned char *ivec, int encrypt)
 {
     register BF_LONG tin0, tin1;
     register BF_LONG tout0, tout1, xor0, xor1;
     register long l = length;
     BF_LONG tin[2];

     if (encrypt) {
         n2l(ivec, tout0);
         n2l(ivec, tout1);
         ivec -= 8;
         for (l -= 8; l >= 0; l -= 8) {
             n2l(in, tin0);
             n2l(in, tin1);
             tin0 ^= tout0;
             tin1 ^= tout1;
             tin[0] = tin0;
             tin[1] = tin1;
             BF_encrypt(tin, schedule);
             tout0 = tin[0];
             tout1 = tin[1];
             l2n(tout0, out);
             l2n(tout1, out);
         }
         if (l != -8) {
             n2ln(in, tin0, tin1, l + 8);
             tin0 ^= tout0;
             tin1 ^= tout1;
             tin[0] = tin0;
             tin[1] = tin1;
             BF_encrypt(tin, schedule);
             tout0 = tin[0];
             tout1 = tin[1];
             l2n(tout0, out);
             l2n(tout1, out);
         }
         l2n(tout0, ivec);
         l2n(tout1, ivec);
     } else {
         n2l(ivec, xor0);
         n2l(ivec, xor1);
         ivec -= 8;
         for (l -= 8; l >= 0; l -= 8) {
             n2l(in, tin0);
             n2l(in, tin1);
             tin[0] = tin0;
             tin[1] = tin1;
             BF_decrypt(tin, schedule);
             tout0 = tin[0] ^ xor0;
             tout1 = tin[1] ^ xor1;
             l2n(tout0, out);
             l2n(tout1, out);
             xor0 = tin0;
             xor1 = tin1;
         }
         if (l != -8) {
             n2l(in, tin0);
             n2l(in, tin1);
             tin[0] = tin0;
             tin[1] = tin1;
             BF_decrypt(tin, schedule);
             tout0 = tin[0] ^ xor0;
             tout1 = tin[1] ^ xor1;
             l2nn(tout0, tout1, out, l + 8);
             xor0 = tin0;
             xor1 = tin1;
         }
         l2n(xor0, ivec);
         l2n(xor1, ivec);
     }
     tin0 = tin1 = tout0 = tout1 = xor0 = xor1 = 0;
     tin[0] = tin[1] = 0;
 }
	/*
	* Copyright 1995-2020 The OpenSSL Project Authors. All Rights Reserved.
	*
	* Licensed under the Apache License 2.0 (the "License"). You may not use
	* this file except in compliance with the License. You can obtain a copy
	* in the file LICENSE in the source distribution or at
	* https://www.openssl.org/source/license.html
	*/

	/*
	* BF low level APIs are deprecated for public use, but still ok for internal
	* use.
	*/
	#include "internal/deprecated.h"

	#include <openssl/blowfish.h>
	#include "bf_local.h"

	/*
	* Blowfish as implemented from 'Blowfish: Springer-Verlag paper' (From
	* LECTURE NOTES IN COMPUTER SCIENCE 809, FAST SOFTWARE ENCRYPTION, CAMBRIDGE
	* SECURITY WORKSHOP, CAMBRIDGE, U.K., DECEMBER 9-11, 1993)
	*/

	#if (BF_ROUNDS != 16) && (BF_ROUNDS != 20)
	# error If you set BF_ROUNDS to some value other than 16 or 20, you will have \
	to modify the code.
	#endif

	void BF_encrypt(BF_LONG data, const BF_KEY key)
	{
	register BF_LONG l, r;
	register const BF_LONG p, s;

	p = key->P;
	s = &(key->S[0]);
	l = data[0];
	r = data[1];

	l ^= p[0];
	BF_ENC(r, l, s, p[1]);
	BF_ENC(l, r, s, p[2]);
	BF_ENC(r, l, s, p[3]);
	BF_ENC(l, r, s, p[4]);
	BF_ENC(r, l, s, p[5]);
	BF_ENC(l, r, s, p[6]);
	BF_ENC(r, l, s, p[7]);
	BF_ENC(l, r, s, p[8]);
	BF_ENC(r, l, s, p[9]);
	BF_ENC(l, r, s, p[10]);
	BF_ENC(r, l, s, p[11]);
	BF_ENC(l, r, s, p[12]);
	BF_ENC(r, l, s, p[13]);
	BF_ENC(l, r, s, p[14]);
	BF_ENC(r, l, s, p[15]);
	BF_ENC(l, r, s, p[16]);
	# if BF_ROUNDS == 20
	BF_ENC(r, l, s, p[17]);
	BF_ENC(l, r, s, p[18]);
	BF_ENC(r, l, s, p[19]);
	BF_ENC(l, r, s, p[20]);
	# endif
	r ^= p[BF_ROUNDS + 1];

	data[1] = l & 0xffffffffU;
	data[0] = r & 0xffffffffU;
	}

	void BF_decrypt(BF_LONG data, const BF_KEY key)
	{
	register BF_LONG l, r;
	register const BF_LONG p, s;

	p = key->P;
	s = &(key->S[0]);
	l = data[0];
	r = data[1];

	l ^= p[BF_ROUNDS + 1];
	# if BF_ROUNDS == 20
	BF_ENC(r, l, s, p[20]);
	BF_ENC(l, r, s, p[19]);
	BF_ENC(r, l, s, p[18]);
	BF_ENC(l, r, s, p[17]);
	# endif
	BF_ENC(r, l, s, p[16]);
	BF_ENC(l, r, s, p[15]);
	BF_ENC(r, l, s, p[14]);
	BF_ENC(l, r, s, p[13]);
	BF_ENC(r, l, s, p[12]);
	BF_ENC(l, r, s, p[11]);
	BF_ENC(r, l, s, p[10]);
	BF_ENC(l, r, s, p[9]);
	BF_ENC(r, l, s, p[8]);
	BF_ENC(l, r, s, p[7]);
	BF_ENC(r, l, s, p[6]);
	BF_ENC(l, r, s, p[5]);
	BF_ENC(r, l, s, p[4]);
	BF_ENC(l, r, s, p[3]);
	BF_ENC(r, l, s, p[2]);
	BF_ENC(l, r, s, p[1]);
	r ^= p[0];

	data[1] = l & 0xffffffffU;
	data[0] = r & 0xffffffffU;
	}

	void BF_cbc_encrypt(const unsigned char in, unsigned char out, long length,
	const BF_KEY schedule, unsigned char ivec, int encrypt)
	{
	register BF_LONG tin0, tin1;
	register BF_LONG tout0, tout1, xor0, xor1;
	register long l = length;
	BF_LONG tin[2];

	if (encrypt) {
	n2l(ivec, tout0);
	n2l(ivec, tout1);
	ivec -= 8;
	for (l -= 8; l >= 0; l -= 8) {
	n2l(in, tin0);
	n2l(in, tin1);
	tin0 ^= tout0;
	tin1 ^= tout1;
	tin[0] = tin0;
	tin[1] = tin1;
	BF_encrypt(tin, schedule);
	tout0 = tin[0];
	tout1 = tin[1];
	l2n(tout0, out);
	l2n(tout1, out);
	}
	if (l != -8) {
	n2ln(in, tin0, tin1, l + 8);
	tin0 ^= tout0;
	tin1 ^= tout1;
	tin[0] = tin0;
	tin[1] = tin1;
	BF_encrypt(tin, schedule);
	tout0 = tin[0];
	tout1 = tin[1];
	l2n(tout0, out);
	l2n(tout1, out);
	}
	l2n(tout0, ivec);
	l2n(tout1, ivec);
	} else {
	n2l(ivec, xor0);
	n2l(ivec, xor1);
	ivec -= 8;
	for (l -= 8; l >= 0; l -= 8) {
	n2l(in, tin0);
	n2l(in, tin1);
	tin[0] = tin0;
	tin[1] = tin1;
	BF_decrypt(tin, schedule);
	tout0 = tin[0] ^ xor0;
	tout1 = tin[1] ^ xor1;
	l2n(tout0, out);
	l2n(tout1, out);
	xor0 = tin0;
	xor1 = tin1;
	}
	if (l != -8) {
	n2l(in, tin0);
	n2l(in, tin1);
	tin[0] = tin0;
	tin[1] = tin1;
	BF_decrypt(tin, schedule);
	tout0 = tin[0] ^ xor0;
	tout1 = tin[1] ^ xor1;
	l2nn(tout0, tout1, out, l + 8);
	xor0 = tin0;
	xor1 = tin1;
	}
	l2n(xor0, ivec);
	l2n(xor1, ivec);
	}
	tin0 = tin1 = tout0 = tout1 = xor0 = xor1 = 0;
	tin[0] = tin[1] = 0;
	}