Bug Summary

File:src/lib/libcrypto/bf/bf_enc.c
Warning:line 302, column 2
Value stored to 'tin0' is never read

Annotated Source Code

Press '?' to see keyboard shortcuts

clang -cc1 -cc1 -triple amd64-unknown-openbsd7.0 -analyze -disable-free -disable-llvm-verifier -discard-value-names -main-file-name bf_enc.c -analyzer-store=region -analyzer-opt-analyze-nested-blocks -analyzer-checker=core -analyzer-checker=apiModeling -analyzer-checker=unix -analyzer-checker=deadcode -analyzer-checker=security.insecureAPI.UncheckedReturn -analyzer-checker=security.insecureAPI.getpw -analyzer-checker=security.insecureAPI.gets -analyzer-checker=security.insecureAPI.mktemp -analyzer-checker=security.insecureAPI.mkstemp -analyzer-checker=security.insecureAPI.vfork -analyzer-checker=nullability.NullPassedToNonnull -analyzer-checker=nullability.NullReturnedFromNonnull -analyzer-output plist -w -setup-static-analyzer -mrelocation-model pic -pic-level 1 -fhalf-no-semantic-interposition -mframe-pointer=all -relaxed-aliasing -fno-rounding-math -mconstructor-aliases -munwind-tables -target-cpu x86-64 -target-feature +retpoline-indirect-calls -target-feature +retpoline-indirect-branches -tune-cpu generic -debugger-tuning=gdb -fcoverage-compilation-dir=/usr/src/lib/libcrypto/obj -resource-dir /usr/local/lib/clang/13.0.0 -D LIBRESSL_INTERNAL -D LIBRESSL_CRYPTO_INTERNAL -D DSO_DLFCN -D HAVE_DLFCN_H -D HAVE_FUNOPEN -D OPENSSL_NO_HW_PADLOCK -I /usr/src/lib/libcrypto -I /usr/src/lib/libcrypto/asn1 -I /usr/src/lib/libcrypto/bio -I /usr/src/lib/libcrypto/bn -I /usr/src/lib/libcrypto/bytestring -I /usr/src/lib/libcrypto/dh -I /usr/src/lib/libcrypto/dsa -I /usr/src/lib/libcrypto/ec -I /usr/src/lib/libcrypto/ecdh -I /usr/src/lib/libcrypto/ecdsa -I /usr/src/lib/libcrypto/evp -I /usr/src/lib/libcrypto/hmac -I /usr/src/lib/libcrypto/modes -I /usr/src/lib/libcrypto/ocsp -I /usr/src/lib/libcrypto/rsa -I /usr/src/lib/libcrypto/x509 -I /usr/src/lib/libcrypto/obj -D AES_ASM -D BSAES_ASM -D VPAES_ASM -D OPENSSL_IA32_SSE2 -D RSA_ASM -D OPENSSL_BN_ASM_MONT -D OPENSSL_BN_ASM_MONT5 -D OPENSSL_BN_ASM_GF2m -D MD5_ASM -D GHASH_ASM -D RC4_MD5_ASM -D SHA1_ASM -D SHA256_ASM -D SHA512_ASM -D WHIRLPOOL_ASM -D OPENSSL_CPUID_OBJ -D PIC -internal-isystem /usr/local/lib/clang/13.0.0/include -internal-externc-isystem /usr/include -O2 -fdebug-compilation-dir=/usr/src/lib/libcrypto/obj -ferror-limit 19 -fwrapv -D_RET_PROTECTOR -ret-protector -fgnuc-version=4.2.1 -vectorize-loops -vectorize-slp -fno-builtin-malloc -fno-builtin-calloc -fno-builtin-realloc -fno-builtin-valloc -fno-builtin-free -fno-builtin-strdup -fno-builtin-strndup -analyzer-output=html -faddrsig -D__GCC_HAVE_DWARF2_CFI_ASM=1 -o /home/ben/Projects/vmm/scan-build/2022-01-12-194120-40624-1 -x c /usr/src/lib/libcrypto/bf/bf_enc.c
1/* $OpenBSD: bf_enc.c,v 1.6 2014/10/28 07:35:58 jsg Exp $ */
2/* Copyright (C) 1995-1998 Eric Young (eay@cryptsoft.com)
3 * All rights reserved.
4 *
5 * This package is an SSL implementation written
6 * by Eric Young (eay@cryptsoft.com).
7 * The implementation was written so as to conform with Netscapes SSL.
8 *
9 * This library is free for commercial and non-commercial use as long as
10 * the following conditions are aheared to. The following conditions
11 * apply to all code found in this distribution, be it the RC4, RSA,
12 * lhash, DES, etc., code; not just the SSL code. The SSL documentation
13 * included with this distribution is covered by the same copyright terms
14 * except that the holder is Tim Hudson (tjh@cryptsoft.com).
15 *
16 * Copyright remains Eric Young's, and as such any Copyright notices in
17 * the code are not to be removed.
18 * If this package is used in a product, Eric Young should be given attribution
19 * as the author of the parts of the library used.
20 * This can be in the form of a textual message at program startup or
21 * in documentation (online or textual) provided with the package.
22 *
23 * Redistribution and use in source and binary forms, with or without
24 * modification, are permitted provided that the following conditions
25 * are met:
26 * 1. Redistributions of source code must retain the copyright
27 * notice, this list of conditions and the following disclaimer.
28 * 2. Redistributions in binary form must reproduce the above copyright
29 * notice, this list of conditions and the following disclaimer in the
30 * documentation and/or other materials provided with the distribution.
31 * 3. All advertising materials mentioning features or use of this software
32 * must display the following acknowledgement:
33 * "This product includes cryptographic software written by
34 * Eric Young (eay@cryptsoft.com)"
35 * The word 'cryptographic' can be left out if the rouines from the library
36 * being used are not cryptographic related :-).
37 * 4. If you include any Windows specific code (or a derivative thereof) from
38 * the apps directory (application code) you must include an acknowledgement:
39 * "This product includes software written by Tim Hudson (tjh@cryptsoft.com)"
40 *
41 * THIS SOFTWARE IS PROVIDED BY ERIC YOUNG ``AS IS'' AND
42 * ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE
43 * IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE
44 * ARE DISCLAIMED. IN NO EVENT SHALL THE AUTHOR OR CONTRIBUTORS BE LIABLE
45 * FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL
46 * DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS
47 * OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION)
48 * HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT
49 * LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY
50 * OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF
51 * SUCH DAMAGE.
52 *
53 * The licence and distribution terms for any publically available version or
54 * derivative of this code cannot be changed. i.e. this code cannot simply be
55 * copied and put under another distribution licence
56 * [including the GNU Public Licence.]
57 */
58
59#include <openssl/blowfish.h>
60#include "bf_locl.h"
61
62/* Blowfish as implemented from 'Blowfish: Springer-Verlag paper'
63 * (From LECTURE NOTES IN COMPUTER SCIENCE 809, FAST SOFTWARE ENCRYPTION,
64 * CAMBRIDGE SECURITY WORKSHOP, CAMBRIDGE, U.K., DECEMBER 9-11, 1993)
65 */
66
67#if (BF_ROUNDS16 != 16) && (BF_ROUNDS16 != 20)
68#error If you set BF_ROUNDS16 to some value other than 16 or 20, you will have \
69to modify the code.
70#endif
71
72void BF_encrypt(BF_LONGunsigned int *data, const BF_KEY *key)
73 {
74#ifndef BF_PTR2
75 BF_LONGunsigned int l,r;
76 const BF_LONGunsigned int *p,*s;
77
78 p=key->P;
79 s= &(key->S[0]);
80 l=data[0];
81 r=data[1];
82
83 l^=p[0];
84 BF_ENC(r,l,s,p[ 1])( r^=p[ 1], r^=((( s[ ((int)(l>>24)&0xff)] + s[0x0100
+((int)(l>>16)&0xff)])^ s[0x0200+((int)(l>> 8
)&0xff)])+ s[0x0300+((int)(l )&0xff)])&0xffffffffL
)
;
85 BF_ENC(l,r,s,p[ 2])( l^=p[ 2], l^=((( s[ ((int)(r>>24)&0xff)] + s[0x0100
+((int)(r>>16)&0xff)])^ s[0x0200+((int)(r>> 8
)&0xff)])+ s[0x0300+((int)(r )&0xff)])&0xffffffffL
)
;
86 BF_ENC(r,l,s,p[ 3])( r^=p[ 3], r^=((( s[ ((int)(l>>24)&0xff)] + s[0x0100
+((int)(l>>16)&0xff)])^ s[0x0200+((int)(l>> 8
)&0xff)])+ s[0x0300+((int)(l )&0xff)])&0xffffffffL
)
;
87 BF_ENC(l,r,s,p[ 4])( l^=p[ 4], l^=((( s[ ((int)(r>>24)&0xff)] + s[0x0100
+((int)(r>>16)&0xff)])^ s[0x0200+((int)(r>> 8
)&0xff)])+ s[0x0300+((int)(r )&0xff)])&0xffffffffL
)
;
88 BF_ENC(r,l,s,p[ 5])( r^=p[ 5], r^=((( s[ ((int)(l>>24)&0xff)] + s[0x0100
+((int)(l>>16)&0xff)])^ s[0x0200+((int)(l>> 8
)&0xff)])+ s[0x0300+((int)(l )&0xff)])&0xffffffffL
)
;
89 BF_ENC(l,r,s,p[ 6])( l^=p[ 6], l^=((( s[ ((int)(r>>24)&0xff)] + s[0x0100
+((int)(r>>16)&0xff)])^ s[0x0200+((int)(r>> 8
)&0xff)])+ s[0x0300+((int)(r )&0xff)])&0xffffffffL
)
;
90 BF_ENC(r,l,s,p[ 7])( r^=p[ 7], r^=((( s[ ((int)(l>>24)&0xff)] + s[0x0100
+((int)(l>>16)&0xff)])^ s[0x0200+((int)(l>> 8
)&0xff)])+ s[0x0300+((int)(l )&0xff)])&0xffffffffL
)
;
91 BF_ENC(l,r,s,p[ 8])( l^=p[ 8], l^=((( s[ ((int)(r>>24)&0xff)] + s[0x0100
+((int)(r>>16)&0xff)])^ s[0x0200+((int)(r>> 8
)&0xff)])+ s[0x0300+((int)(r )&0xff)])&0xffffffffL
)
;
92 BF_ENC(r,l,s,p[ 9])( r^=p[ 9], r^=((( s[ ((int)(l>>24)&0xff)] + s[0x0100
+((int)(l>>16)&0xff)])^ s[0x0200+((int)(l>> 8
)&0xff)])+ s[0x0300+((int)(l )&0xff)])&0xffffffffL
)
;
93 BF_ENC(l,r,s,p[10])( l^=p[10], l^=((( s[ ((int)(r>>24)&0xff)] + s[0x0100
+((int)(r>>16)&0xff)])^ s[0x0200+((int)(r>> 8
)&0xff)])+ s[0x0300+((int)(r )&0xff)])&0xffffffffL
)
;
94 BF_ENC(r,l,s,p[11])( r^=p[11], r^=((( s[ ((int)(l>>24)&0xff)] + s[0x0100
+((int)(l>>16)&0xff)])^ s[0x0200+((int)(l>> 8
)&0xff)])+ s[0x0300+((int)(l )&0xff)])&0xffffffffL
)
;
95 BF_ENC(l,r,s,p[12])( l^=p[12], l^=((( s[ ((int)(r>>24)&0xff)] + s[0x0100
+((int)(r>>16)&0xff)])^ s[0x0200+((int)(r>> 8
)&0xff)])+ s[0x0300+((int)(r )&0xff)])&0xffffffffL
)
;
96 BF_ENC(r,l,s,p[13])( r^=p[13], r^=((( s[ ((int)(l>>24)&0xff)] + s[0x0100
+((int)(l>>16)&0xff)])^ s[0x0200+((int)(l>> 8
)&0xff)])+ s[0x0300+((int)(l )&0xff)])&0xffffffffL
)
;
97 BF_ENC(l,r,s,p[14])( l^=p[14], l^=((( s[ ((int)(r>>24)&0xff)] + s[0x0100
+((int)(r>>16)&0xff)])^ s[0x0200+((int)(r>> 8
)&0xff)])+ s[0x0300+((int)(r )&0xff)])&0xffffffffL
)
;
98 BF_ENC(r,l,s,p[15])( r^=p[15], r^=((( s[ ((int)(l>>24)&0xff)] + s[0x0100
+((int)(l>>16)&0xff)])^ s[0x0200+((int)(l>> 8
)&0xff)])+ s[0x0300+((int)(l )&0xff)])&0xffffffffL
)
;
99 BF_ENC(l,r,s,p[16])( l^=p[16], l^=((( s[ ((int)(r>>24)&0xff)] + s[0x0100
+((int)(r>>16)&0xff)])^ s[0x0200+((int)(r>> 8
)&0xff)])+ s[0x0300+((int)(r )&0xff)])&0xffffffffL
)
;
100#if BF_ROUNDS16 == 20
101 BF_ENC(r,l,s,p[17])( r^=p[17], r^=((( s[ ((int)(l>>24)&0xff)] + s[0x0100
+((int)(l>>16)&0xff)])^ s[0x0200+((int)(l>> 8
)&0xff)])+ s[0x0300+((int)(l )&0xff)])&0xffffffffL
)
;
102 BF_ENC(l,r,s,p[18])( l^=p[18], l^=((( s[ ((int)(r>>24)&0xff)] + s[0x0100
+((int)(r>>16)&0xff)])^ s[0x0200+((int)(r>> 8
)&0xff)])+ s[0x0300+((int)(r )&0xff)])&0xffffffffL
)
;
103 BF_ENC(r,l,s,p[19])( r^=p[19], r^=((( s[ ((int)(l>>24)&0xff)] + s[0x0100
+((int)(l>>16)&0xff)])^ s[0x0200+((int)(l>> 8
)&0xff)])+ s[0x0300+((int)(l )&0xff)])&0xffffffffL
)
;
104 BF_ENC(l,r,s,p[20])( l^=p[20], l^=((( s[ ((int)(r>>24)&0xff)] + s[0x0100
+((int)(r>>16)&0xff)])^ s[0x0200+((int)(r>> 8
)&0xff)])+ s[0x0300+((int)(r )&0xff)])&0xffffffffL
)
;
105#endif
106 r^=p[BF_ROUNDS16+1];
107
108 data[1]=l&0xffffffffL;
109 data[0]=r&0xffffffffL;
110#else
111 BF_LONGunsigned int l,r,t,*k;
112
113 l=data[0];
114 r=data[1];
115 k=(BF_LONGunsigned int*)key;
116
117 l^=k[0];
118 BF_ENC(r,l,k, 1)( r^=1, r^=((( k[ ((int)(l>>24)&0xff)] + k[0x0100+(
(int)(l>>16)&0xff)])^ k[0x0200+((int)(l>> 8)&
0xff)])+ k[0x0300+((int)(l )&0xff)])&0xffffffffL )
;
119 BF_ENC(l,r,k, 2)( l^=2, l^=((( k[ ((int)(r>>24)&0xff)] + k[0x0100+(
(int)(r>>16)&0xff)])^ k[0x0200+((int)(r>> 8)&
0xff)])+ k[0x0300+((int)(r )&0xff)])&0xffffffffL )
;
120 BF_ENC(r,l,k, 3)( r^=3, r^=((( k[ ((int)(l>>24)&0xff)] + k[0x0100+(
(int)(l>>16)&0xff)])^ k[0x0200+((int)(l>> 8)&
0xff)])+ k[0x0300+((int)(l )&0xff)])&0xffffffffL )
;
121 BF_ENC(l,r,k, 4)( l^=4, l^=((( k[ ((int)(r>>24)&0xff)] + k[0x0100+(
(int)(r>>16)&0xff)])^ k[0x0200+((int)(r>> 8)&
0xff)])+ k[0x0300+((int)(r )&0xff)])&0xffffffffL )
;
122 BF_ENC(r,l,k, 5)( r^=5, r^=((( k[ ((int)(l>>24)&0xff)] + k[0x0100+(
(int)(l>>16)&0xff)])^ k[0x0200+((int)(l>> 8)&
0xff)])+ k[0x0300+((int)(l )&0xff)])&0xffffffffL )
;
123 BF_ENC(l,r,k, 6)( l^=6, l^=((( k[ ((int)(r>>24)&0xff)] + k[0x0100+(
(int)(r>>16)&0xff)])^ k[0x0200+((int)(r>> 8)&
0xff)])+ k[0x0300+((int)(r )&0xff)])&0xffffffffL )
;
124 BF_ENC(r,l,k, 7)( r^=7, r^=((( k[ ((int)(l>>24)&0xff)] + k[0x0100+(
(int)(l>>16)&0xff)])^ k[0x0200+((int)(l>> 8)&
0xff)])+ k[0x0300+((int)(l )&0xff)])&0xffffffffL )
;
125 BF_ENC(l,r,k, 8)( l^=8, l^=((( k[ ((int)(r>>24)&0xff)] + k[0x0100+(
(int)(r>>16)&0xff)])^ k[0x0200+((int)(r>> 8)&
0xff)])+ k[0x0300+((int)(r )&0xff)])&0xffffffffL )
;
126 BF_ENC(r,l,k, 9)( r^=9, r^=((( k[ ((int)(l>>24)&0xff)] + k[0x0100+(
(int)(l>>16)&0xff)])^ k[0x0200+((int)(l>> 8)&
0xff)])+ k[0x0300+((int)(l )&0xff)])&0xffffffffL )
;
127 BF_ENC(l,r,k,10)( l^=10, l^=((( k[ ((int)(r>>24)&0xff)] + k[0x0100+
((int)(r>>16)&0xff)])^ k[0x0200+((int)(r>> 8)
&0xff)])+ k[0x0300+((int)(r )&0xff)])&0xffffffffL
)
;
128 BF_ENC(r,l,k,11)( r^=11, r^=((( k[ ((int)(l>>24)&0xff)] + k[0x0100+
((int)(l>>16)&0xff)])^ k[0x0200+((int)(l>> 8)
&0xff)])+ k[0x0300+((int)(l )&0xff)])&0xffffffffL
)
;
129 BF_ENC(l,r,k,12)( l^=12, l^=((( k[ ((int)(r>>24)&0xff)] + k[0x0100+
((int)(r>>16)&0xff)])^ k[0x0200+((int)(r>> 8)
&0xff)])+ k[0x0300+((int)(r )&0xff)])&0xffffffffL
)
;
130 BF_ENC(r,l,k,13)( r^=13, r^=((( k[ ((int)(l>>24)&0xff)] + k[0x0100+
((int)(l>>16)&0xff)])^ k[0x0200+((int)(l>> 8)
&0xff)])+ k[0x0300+((int)(l )&0xff)])&0xffffffffL
)
;
131 BF_ENC(l,r,k,14)( l^=14, l^=((( k[ ((int)(r>>24)&0xff)] + k[0x0100+
((int)(r>>16)&0xff)])^ k[0x0200+((int)(r>> 8)
&0xff)])+ k[0x0300+((int)(r )&0xff)])&0xffffffffL
)
;
132 BF_ENC(r,l,k,15)( r^=15, r^=((( k[ ((int)(l>>24)&0xff)] + k[0x0100+
((int)(l>>16)&0xff)])^ k[0x0200+((int)(l>> 8)
&0xff)])+ k[0x0300+((int)(l )&0xff)])&0xffffffffL
)
;
133 BF_ENC(l,r,k,16)( l^=16, l^=((( k[ ((int)(r>>24)&0xff)] + k[0x0100+
((int)(r>>16)&0xff)])^ k[0x0200+((int)(r>> 8)
&0xff)])+ k[0x0300+((int)(r )&0xff)])&0xffffffffL
)
;
134#if BF_ROUNDS16 == 20
135 BF_ENC(r,l,k,17)( r^=17, r^=((( k[ ((int)(l>>24)&0xff)] + k[0x0100+
((int)(l>>16)&0xff)])^ k[0x0200+((int)(l>> 8)
&0xff)])+ k[0x0300+((int)(l )&0xff)])&0xffffffffL
)
;
136 BF_ENC(l,r,k,18)( l^=18, l^=((( k[ ((int)(r>>24)&0xff)] + k[0x0100+
((int)(r>>16)&0xff)])^ k[0x0200+((int)(r>> 8)
&0xff)])+ k[0x0300+((int)(r )&0xff)])&0xffffffffL
)
;
137 BF_ENC(r,l,k,19)( r^=19, r^=((( k[ ((int)(l>>24)&0xff)] + k[0x0100+
((int)(l>>16)&0xff)])^ k[0x0200+((int)(l>> 8)
&0xff)])+ k[0x0300+((int)(l )&0xff)])&0xffffffffL
)
;
138 BF_ENC(l,r,k,20)( l^=20, l^=((( k[ ((int)(r>>24)&0xff)] + k[0x0100+
((int)(r>>16)&0xff)])^ k[0x0200+((int)(r>> 8)
&0xff)])+ k[0x0300+((int)(r )&0xff)])&0xffffffffL
)
;
139#endif
140 r^=k[BF_ROUNDS16+1];
141
142 data[1]=l&0xffffffffL;
143 data[0]=r&0xffffffffL;
144#endif
145 }
146
147#ifndef BF_DEFAULT_OPTIONS
148
149void BF_decrypt(BF_LONGunsigned int *data, const BF_KEY *key)
150 {
151#ifndef BF_PTR2
152 BF_LONGunsigned int l,r;
153 const BF_LONGunsigned int *p,*s;
154
155 p=key->P;
156 s= &(key->S[0]);
157 l=data[0];
158 r=data[1];
159
160 l^=p[BF_ROUNDS16+1];
161#if BF_ROUNDS16 == 20
162 BF_ENC(r,l,s,p[20])( r^=p[20], r^=((( s[ ((int)(l>>24)&0xff)] + s[0x0100
+((int)(l>>16)&0xff)])^ s[0x0200+((int)(l>> 8
)&0xff)])+ s[0x0300+((int)(l )&0xff)])&0xffffffffL
)
;
163 BF_ENC(l,r,s,p[19])( l^=p[19], l^=((( s[ ((int)(r>>24)&0xff)] + s[0x0100
+((int)(r>>16)&0xff)])^ s[0x0200+((int)(r>> 8
)&0xff)])+ s[0x0300+((int)(r )&0xff)])&0xffffffffL
)
;
164 BF_ENC(r,l,s,p[18])( r^=p[18], r^=((( s[ ((int)(l>>24)&0xff)] + s[0x0100
+((int)(l>>16)&0xff)])^ s[0x0200+((int)(l>> 8
)&0xff)])+ s[0x0300+((int)(l )&0xff)])&0xffffffffL
)
;
165 BF_ENC(l,r,s,p[17])( l^=p[17], l^=((( s[ ((int)(r>>24)&0xff)] + s[0x0100
+((int)(r>>16)&0xff)])^ s[0x0200+((int)(r>> 8
)&0xff)])+ s[0x0300+((int)(r )&0xff)])&0xffffffffL
)
;
166#endif
167 BF_ENC(r,l,s,p[16])( r^=p[16], r^=((( s[ ((int)(l>>24)&0xff)] + s[0x0100
+((int)(l>>16)&0xff)])^ s[0x0200+((int)(l>> 8
)&0xff)])+ s[0x0300+((int)(l )&0xff)])&0xffffffffL
)
;
168 BF_ENC(l,r,s,p[15])( l^=p[15], l^=((( s[ ((int)(r>>24)&0xff)] + s[0x0100
+((int)(r>>16)&0xff)])^ s[0x0200+((int)(r>> 8
)&0xff)])+ s[0x0300+((int)(r )&0xff)])&0xffffffffL
)
;
169 BF_ENC(r,l,s,p[14])( r^=p[14], r^=((( s[ ((int)(l>>24)&0xff)] + s[0x0100
+((int)(l>>16)&0xff)])^ s[0x0200+((int)(l>> 8
)&0xff)])+ s[0x0300+((int)(l )&0xff)])&0xffffffffL
)
;
170 BF_ENC(l,r,s,p[13])( l^=p[13], l^=((( s[ ((int)(r>>24)&0xff)] + s[0x0100
+((int)(r>>16)&0xff)])^ s[0x0200+((int)(r>> 8
)&0xff)])+ s[0x0300+((int)(r )&0xff)])&0xffffffffL
)
;
171 BF_ENC(r,l,s,p[12])( r^=p[12], r^=((( s[ ((int)(l>>24)&0xff)] + s[0x0100
+((int)(l>>16)&0xff)])^ s[0x0200+((int)(l>> 8
)&0xff)])+ s[0x0300+((int)(l )&0xff)])&0xffffffffL
)
;
172 BF_ENC(l,r,s,p[11])( l^=p[11], l^=((( s[ ((int)(r>>24)&0xff)] + s[0x0100
+((int)(r>>16)&0xff)])^ s[0x0200+((int)(r>> 8
)&0xff)])+ s[0x0300+((int)(r )&0xff)])&0xffffffffL
)
;
173 BF_ENC(r,l,s,p[10])( r^=p[10], r^=((( s[ ((int)(l>>24)&0xff)] + s[0x0100
+((int)(l>>16)&0xff)])^ s[0x0200+((int)(l>> 8
)&0xff)])+ s[0x0300+((int)(l )&0xff)])&0xffffffffL
)
;
174 BF_ENC(l,r,s,p[ 9])( l^=p[ 9], l^=((( s[ ((int)(r>>24)&0xff)] + s[0x0100
+((int)(r>>16)&0xff)])^ s[0x0200+((int)(r>> 8
)&0xff)])+ s[0x0300+((int)(r )&0xff)])&0xffffffffL
)
;
175 BF_ENC(r,l,s,p[ 8])( r^=p[ 8], r^=((( s[ ((int)(l>>24)&0xff)] + s[0x0100
+((int)(l>>16)&0xff)])^ s[0x0200+((int)(l>> 8
)&0xff)])+ s[0x0300+((int)(l )&0xff)])&0xffffffffL
)
;
176 BF_ENC(l,r,s,p[ 7])( l^=p[ 7], l^=((( s[ ((int)(r>>24)&0xff)] + s[0x0100
+((int)(r>>16)&0xff)])^ s[0x0200+((int)(r>> 8
)&0xff)])+ s[0x0300+((int)(r )&0xff)])&0xffffffffL
)
;
177 BF_ENC(r,l,s,p[ 6])( r^=p[ 6], r^=((( s[ ((int)(l>>24)&0xff)] + s[0x0100
+((int)(l>>16)&0xff)])^ s[0x0200+((int)(l>> 8
)&0xff)])+ s[0x0300+((int)(l )&0xff)])&0xffffffffL
)
;
178 BF_ENC(l,r,s,p[ 5])( l^=p[ 5], l^=((( s[ ((int)(r>>24)&0xff)] + s[0x0100
+((int)(r>>16)&0xff)])^ s[0x0200+((int)(r>> 8
)&0xff)])+ s[0x0300+((int)(r )&0xff)])&0xffffffffL
)
;
179 BF_ENC(r,l,s,p[ 4])( r^=p[ 4], r^=((( s[ ((int)(l>>24)&0xff)] + s[0x0100
+((int)(l>>16)&0xff)])^ s[0x0200+((int)(l>> 8
)&0xff)])+ s[0x0300+((int)(l )&0xff)])&0xffffffffL
)
;
180 BF_ENC(l,r,s,p[ 3])( l^=p[ 3], l^=((( s[ ((int)(r>>24)&0xff)] + s[0x0100
+((int)(r>>16)&0xff)])^ s[0x0200+((int)(r>> 8
)&0xff)])+ s[0x0300+((int)(r )&0xff)])&0xffffffffL
)
;
181 BF_ENC(r,l,s,p[ 2])( r^=p[ 2], r^=((( s[ ((int)(l>>24)&0xff)] + s[0x0100
+((int)(l>>16)&0xff)])^ s[0x0200+((int)(l>> 8
)&0xff)])+ s[0x0300+((int)(l )&0xff)])&0xffffffffL
)
;
182 BF_ENC(l,r,s,p[ 1])( l^=p[ 1], l^=((( s[ ((int)(r>>24)&0xff)] + s[0x0100
+((int)(r>>16)&0xff)])^ s[0x0200+((int)(r>> 8
)&0xff)])+ s[0x0300+((int)(r )&0xff)])&0xffffffffL
)
;
183 r^=p[0];
184
185 data[1]=l&0xffffffffL;
186 data[0]=r&0xffffffffL;
187#else
188 BF_LONGunsigned int l,r,t,*k;
189
190 l=data[0];
191 r=data[1];
192 k=(BF_LONGunsigned int *)key;
193
194 l^=k[BF_ROUNDS16+1];
195#if BF_ROUNDS16 == 20
196 BF_ENC(r,l,k,20)( r^=20, r^=((( k[ ((int)(l>>24)&0xff)] + k[0x0100+
((int)(l>>16)&0xff)])^ k[0x0200+((int)(l>> 8)
&0xff)])+ k[0x0300+((int)(l )&0xff)])&0xffffffffL
)
;
197 BF_ENC(l,r,k,19)( l^=19, l^=((( k[ ((int)(r>>24)&0xff)] + k[0x0100+
((int)(r>>16)&0xff)])^ k[0x0200+((int)(r>> 8)
&0xff)])+ k[0x0300+((int)(r )&0xff)])&0xffffffffL
)
;
198 BF_ENC(r,l,k,18)( r^=18, r^=((( k[ ((int)(l>>24)&0xff)] + k[0x0100+
((int)(l>>16)&0xff)])^ k[0x0200+((int)(l>> 8)
&0xff)])+ k[0x0300+((int)(l )&0xff)])&0xffffffffL
)
;
199 BF_ENC(l,r,k,17)( l^=17, l^=((( k[ ((int)(r>>24)&0xff)] + k[0x0100+
((int)(r>>16)&0xff)])^ k[0x0200+((int)(r>> 8)
&0xff)])+ k[0x0300+((int)(r )&0xff)])&0xffffffffL
)
;
200#endif
201 BF_ENC(r,l,k,16)( r^=16, r^=((( k[ ((int)(l>>24)&0xff)] + k[0x0100+
((int)(l>>16)&0xff)])^ k[0x0200+((int)(l>> 8)
&0xff)])+ k[0x0300+((int)(l )&0xff)])&0xffffffffL
)
;
202 BF_ENC(l,r,k,15)( l^=15, l^=((( k[ ((int)(r>>24)&0xff)] + k[0x0100+
((int)(r>>16)&0xff)])^ k[0x0200+((int)(r>> 8)
&0xff)])+ k[0x0300+((int)(r )&0xff)])&0xffffffffL
)
;
203 BF_ENC(r,l,k,14)( r^=14, r^=((( k[ ((int)(l>>24)&0xff)] + k[0x0100+
((int)(l>>16)&0xff)])^ k[0x0200+((int)(l>> 8)
&0xff)])+ k[0x0300+((int)(l )&0xff)])&0xffffffffL
)
;
204 BF_ENC(l,r,k,13)( l^=13, l^=((( k[ ((int)(r>>24)&0xff)] + k[0x0100+
((int)(r>>16)&0xff)])^ k[0x0200+((int)(r>> 8)
&0xff)])+ k[0x0300+((int)(r )&0xff)])&0xffffffffL
)
;
205 BF_ENC(r,l,k,12)( r^=12, r^=((( k[ ((int)(l>>24)&0xff)] + k[0x0100+
((int)(l>>16)&0xff)])^ k[0x0200+((int)(l>> 8)
&0xff)])+ k[0x0300+((int)(l )&0xff)])&0xffffffffL
)
;
206 BF_ENC(l,r,k,11)( l^=11, l^=((( k[ ((int)(r>>24)&0xff)] + k[0x0100+
((int)(r>>16)&0xff)])^ k[0x0200+((int)(r>> 8)
&0xff)])+ k[0x0300+((int)(r )&0xff)])&0xffffffffL
)
;
207 BF_ENC(r,l,k,10)( r^=10, r^=((( k[ ((int)(l>>24)&0xff)] + k[0x0100+
((int)(l>>16)&0xff)])^ k[0x0200+((int)(l>> 8)
&0xff)])+ k[0x0300+((int)(l )&0xff)])&0xffffffffL
)
;
208 BF_ENC(l,r,k, 9)( l^=9, l^=((( k[ ((int)(r>>24)&0xff)] + k[0x0100+(
(int)(r>>16)&0xff)])^ k[0x0200+((int)(r>> 8)&
0xff)])+ k[0x0300+((int)(r )&0xff)])&0xffffffffL )
;
209 BF_ENC(r,l,k, 8)( r^=8, r^=((( k[ ((int)(l>>24)&0xff)] + k[0x0100+(
(int)(l>>16)&0xff)])^ k[0x0200+((int)(l>> 8)&
0xff)])+ k[0x0300+((int)(l )&0xff)])&0xffffffffL )
;
210 BF_ENC(l,r,k, 7)( l^=7, l^=((( k[ ((int)(r>>24)&0xff)] + k[0x0100+(
(int)(r>>16)&0xff)])^ k[0x0200+((int)(r>> 8)&
0xff)])+ k[0x0300+((int)(r )&0xff)])&0xffffffffL )
;
211 BF_ENC(r,l,k, 6)( r^=6, r^=((( k[ ((int)(l>>24)&0xff)] + k[0x0100+(
(int)(l>>16)&0xff)])^ k[0x0200+((int)(l>> 8)&
0xff)])+ k[0x0300+((int)(l )&0xff)])&0xffffffffL )
;
212 BF_ENC(l,r,k, 5)( l^=5, l^=((( k[ ((int)(r>>24)&0xff)] + k[0x0100+(
(int)(r>>16)&0xff)])^ k[0x0200+((int)(r>> 8)&
0xff)])+ k[0x0300+((int)(r )&0xff)])&0xffffffffL )
;
213 BF_ENC(r,l,k, 4)( r^=4, r^=((( k[ ((int)(l>>24)&0xff)] + k[0x0100+(
(int)(l>>16)&0xff)])^ k[0x0200+((int)(l>> 8)&
0xff)])+ k[0x0300+((int)(l )&0xff)])&0xffffffffL )
;
214 BF_ENC(l,r,k, 3)( l^=3, l^=((( k[ ((int)(r>>24)&0xff)] + k[0x0100+(
(int)(r>>16)&0xff)])^ k[0x0200+((int)(r>> 8)&
0xff)])+ k[0x0300+((int)(r )&0xff)])&0xffffffffL )
;
215 BF_ENC(r,l,k, 2)( r^=2, r^=((( k[ ((int)(l>>24)&0xff)] + k[0x0100+(
(int)(l>>16)&0xff)])^ k[0x0200+((int)(l>> 8)&
0xff)])+ k[0x0300+((int)(l )&0xff)])&0xffffffffL )
;
216 BF_ENC(l,r,k, 1)( l^=1, l^=((( k[ ((int)(r>>24)&0xff)] + k[0x0100+(
(int)(r>>16)&0xff)])^ k[0x0200+((int)(r>> 8)&
0xff)])+ k[0x0300+((int)(r )&0xff)])&0xffffffffL )
;
217 r^=k[0];
218
219 data[1]=l&0xffffffffL;
220 data[0]=r&0xffffffffL;
221#endif
222 }
223
224void BF_cbc_encrypt(const unsigned char *in, unsigned char *out, long length,
225 const BF_KEY *schedule, unsigned char *ivec, int encrypt)
226 {
227 BF_LONGunsigned int tin0,tin1;
228 BF_LONGunsigned int tout0,tout1,xor0,xor1;
229 long l=length;
230 BF_LONGunsigned int tin[2];
231
232 if (encrypt)
233 {
234 n2l(ivec,tout0)(tout0 =((unsigned long)(*((ivec)++)))<<24L, tout0|=((unsigned
long)(*((ivec)++)))<<16L, tout0|=((unsigned long)(*((ivec
)++)))<< 8L, tout0|=((unsigned long)(*((ivec)++))))
;
235 n2l(ivec,tout1)(tout1 =((unsigned long)(*((ivec)++)))<<24L, tout1|=((unsigned
long)(*((ivec)++)))<<16L, tout1|=((unsigned long)(*((ivec
)++)))<< 8L, tout1|=((unsigned long)(*((ivec)++))))
;
236 ivec-=8;
237 for (l-=8; l>=0; l-=8)
238 {
239 n2l(in,tin0)(tin0 =((unsigned long)(*((in)++)))<<24L, tin0|=((unsigned
long)(*((in)++)))<<16L, tin0|=((unsigned long)(*((in)++
)))<< 8L, tin0|=((unsigned long)(*((in)++))))
;
240 n2l(in,tin1)(tin1 =((unsigned long)(*((in)++)))<<24L, tin1|=((unsigned
long)(*((in)++)))<<16L, tin1|=((unsigned long)(*((in)++
)))<< 8L, tin1|=((unsigned long)(*((in)++))))
;
241 tin0^=tout0;
242 tin1^=tout1;
243 tin[0]=tin0;
244 tin[1]=tin1;
245 BF_encrypt(tin,schedule);
246 tout0=tin[0];
247 tout1=tin[1];
248 l2n(tout0,out)(*((out)++)=(unsigned char)(((tout0)>>24L)&0xff), *
((out)++)=(unsigned char)(((tout0)>>16L)&0xff), *((
out)++)=(unsigned char)(((tout0)>> 8L)&0xff), *((out
)++)=(unsigned char)(((tout0) )&0xff))
;
249 l2n(tout1,out)(*((out)++)=(unsigned char)(((tout1)>>24L)&0xff), *
((out)++)=(unsigned char)(((tout1)>>16L)&0xff), *((
out)++)=(unsigned char)(((tout1)>> 8L)&0xff), *((out
)++)=(unsigned char)(((tout1) )&0xff))
;
250 }
251 if (l != -8)
252 {
253 n2ln(in,tin0,tin1,l+8){ in+=l+8; tin0=tin1=0; switch (l+8) { case 8: tin1 =((unsigned
long)(*(--(in)))) ; case 7: tin1|=((unsigned long)(*(--(in))
))<< 8; case 6: tin1|=((unsigned long)(*(--(in))))<<
16; case 5: tin1|=((unsigned long)(*(--(in))))<<24; case
4: tin0 =((unsigned long)(*(--(in)))) ; case 3: tin0|=((unsigned
long)(*(--(in))))<< 8; case 2: tin0|=((unsigned long)(
*(--(in))))<<16; case 1: tin0|=((unsigned long)(*(--(in
))))<<24; } }
;
254 tin0^=tout0;
255 tin1^=tout1;
256 tin[0]=tin0;
257 tin[1]=tin1;
258 BF_encrypt(tin,schedule);
259 tout0=tin[0];
260 tout1=tin[1];
261 l2n(tout0,out)(*((out)++)=(unsigned char)(((tout0)>>24L)&0xff), *
((out)++)=(unsigned char)(((tout0)>>16L)&0xff), *((
out)++)=(unsigned char)(((tout0)>> 8L)&0xff), *((out
)++)=(unsigned char)(((tout0) )&0xff))
;
262 l2n(tout1,out)(*((out)++)=(unsigned char)(((tout1)>>24L)&0xff), *
((out)++)=(unsigned char)(((tout1)>>16L)&0xff), *((
out)++)=(unsigned char)(((tout1)>> 8L)&0xff), *((out
)++)=(unsigned char)(((tout1) )&0xff))
;
263 }
264 l2n(tout0,ivec)(*((ivec)++)=(unsigned char)(((tout0)>>24L)&0xff), *
((ivec)++)=(unsigned char)(((tout0)>>16L)&0xff), *(
(ivec)++)=(unsigned char)(((tout0)>> 8L)&0xff), *((
ivec)++)=(unsigned char)(((tout0) )&0xff))
;
265 l2n(tout1,ivec)(*((ivec)++)=(unsigned char)(((tout1)>>24L)&0xff), *
((ivec)++)=(unsigned char)(((tout1)>>16L)&0xff), *(
(ivec)++)=(unsigned char)(((tout1)>> 8L)&0xff), *((
ivec)++)=(unsigned char)(((tout1) )&0xff))
;
266 }
267 else
268 {
269 n2l(ivec,xor0)(xor0 =((unsigned long)(*((ivec)++)))<<24L, xor0|=((unsigned
long)(*((ivec)++)))<<16L, xor0|=((unsigned long)(*((ivec
)++)))<< 8L, xor0|=((unsigned long)(*((ivec)++))))
;
270 n2l(ivec,xor1)(xor1 =((unsigned long)(*((ivec)++)))<<24L, xor1|=((unsigned
long)(*((ivec)++)))<<16L, xor1|=((unsigned long)(*((ivec
)++)))<< 8L, xor1|=((unsigned long)(*((ivec)++))))
;
271 ivec-=8;
272 for (l-=8; l>=0; l-=8)
273 {
274 n2l(in,tin0)(tin0 =((unsigned long)(*((in)++)))<<24L, tin0|=((unsigned
long)(*((in)++)))<<16L, tin0|=((unsigned long)(*((in)++
)))<< 8L, tin0|=((unsigned long)(*((in)++))))
;
275 n2l(in,tin1)(tin1 =((unsigned long)(*((in)++)))<<24L, tin1|=((unsigned
long)(*((in)++)))<<16L, tin1|=((unsigned long)(*((in)++
)))<< 8L, tin1|=((unsigned long)(*((in)++))))
;
276 tin[0]=tin0;
277 tin[1]=tin1;
278 BF_decrypt(tin,schedule);
279 tout0=tin[0]^xor0;
280 tout1=tin[1]^xor1;
281 l2n(tout0,out)(*((out)++)=(unsigned char)(((tout0)>>24L)&0xff), *
((out)++)=(unsigned char)(((tout0)>>16L)&0xff), *((
out)++)=(unsigned char)(((tout0)>> 8L)&0xff), *((out
)++)=(unsigned char)(((tout0) )&0xff))
;
282 l2n(tout1,out)(*((out)++)=(unsigned char)(((tout1)>>24L)&0xff), *
((out)++)=(unsigned char)(((tout1)>>16L)&0xff), *((
out)++)=(unsigned char)(((tout1)>> 8L)&0xff), *((out
)++)=(unsigned char)(((tout1) )&0xff))
;
283 xor0=tin0;
284 xor1=tin1;
285 }
286 if (l != -8)
287 {
288 n2l(in,tin0)(tin0 =((unsigned long)(*((in)++)))<<24L, tin0|=((unsigned
long)(*((in)++)))<<16L, tin0|=((unsigned long)(*((in)++
)))<< 8L, tin0|=((unsigned long)(*((in)++))))
;
289 n2l(in,tin1)(tin1 =((unsigned long)(*((in)++)))<<24L, tin1|=((unsigned
long)(*((in)++)))<<16L, tin1|=((unsigned long)(*((in)++
)))<< 8L, tin1|=((unsigned long)(*((in)++))))
;
290 tin[0]=tin0;
291 tin[1]=tin1;
292 BF_decrypt(tin,schedule);
293 tout0=tin[0]^xor0;
294 tout1=tin[1]^xor1;
295 l2nn(tout0,tout1,out,l+8){ out+=l+8; switch (l+8) { case 8: *(--(out))=(unsigned char)
(((tout1) )&0xff); case 7: *(--(out))=(unsigned char)(((tout1
)>> 8)&0xff); case 6: *(--(out))=(unsigned char)(((
tout1)>>16)&0xff); case 5: *(--(out))=(unsigned char
)(((tout1)>>24)&0xff); case 4: *(--(out))=(unsigned
char)(((tout0) )&0xff); case 3: *(--(out))=(unsigned char
)(((tout0)>> 8)&0xff); case 2: *(--(out))=(unsigned
char)(((tout0)>>16)&0xff); case 1: *(--(out))=(unsigned
char)(((tout0)>>24)&0xff); } }
;
296 xor0=tin0;
297 xor1=tin1;
298 }
299 l2n(xor0,ivec)(*((ivec)++)=(unsigned char)(((xor0)>>24L)&0xff), *
((ivec)++)=(unsigned char)(((xor0)>>16L)&0xff), *((
ivec)++)=(unsigned char)(((xor0)>> 8L)&0xff), *((ivec
)++)=(unsigned char)(((xor0) )&0xff))
;
300 l2n(xor1,ivec)(*((ivec)++)=(unsigned char)(((xor1)>>24L)&0xff), *
((ivec)++)=(unsigned char)(((xor1)>>16L)&0xff), *((
ivec)++)=(unsigned char)(((xor1)>> 8L)&0xff), *((ivec
)++)=(unsigned char)(((xor1) )&0xff))
;
301 }
302 tin0=tin1=tout0=tout1=xor0=xor1=0;
Value stored to 'tin0' is never read
303 tin[0]=tin[1]=0;
304 }
305
306#endif