[dragonfly.git] / secure / lib / libcrypto / man / blowfish.3

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.\" ========================================================================
.\"
.IX Title "blowfish 3"
.TH blowfish 3 "2012-01-04" "1.0.0f" "OpenSSL"
.\" For nroff, turn off justification.  Always turn off hyphenation; it makes
.\" way too many mistakes in technical documents.
.if n .ad l
.nh
.SH "NAME"
blowfish, BF_set_key, BF_encrypt, BF_decrypt, BF_ecb_encrypt, BF_cbc_encrypt,
BF_cfb64_encrypt, BF_ofb64_encrypt, BF_options \- Blowfish encryption
.SH "SYNOPSIS"
.IX Header "SYNOPSIS"
.Vb 1
\& #include <openssl/blowfish.h>
\&
\& void BF_set_key(BF_KEY *key, int len, const unsigned char *data);
\&
\& void BF_ecb_encrypt(const unsigned char *in, unsigned char *out,
\&         BF_KEY *key, int enc);
\& void BF_cbc_encrypt(const unsigned char *in, unsigned char *out,
\&         long length, BF_KEY *schedule, unsigned char *ivec, int enc);
\& void BF_cfb64_encrypt(const unsigned char *in, unsigned char *out,
\&         long length, BF_KEY *schedule, unsigned char *ivec, int *num,
\&         int enc);
\& void BF_ofb64_encrypt(const unsigned char *in, unsigned char *out,
\&         long length, BF_KEY *schedule, unsigned char *ivec, int *num);
\& const char *BF_options(void);
\&
\& void BF_encrypt(BF_LONG *data,const BF_KEY *key);
\& void BF_decrypt(BF_LONG *data,const BF_KEY *key);
.Ve
.SH "DESCRIPTION"
.IX Header "DESCRIPTION"
This library implements the Blowfish cipher, which was invented and described
by Counterpane (see http://www.counterpane.com/blowfish.html ).
.PP
Blowfish is a block cipher that operates on 64 bit (8 byte) blocks of data.
It uses a variable size key, but typically, 128 bit (16 byte) keys are
considered good for strong encryption.  Blowfish can be used in the same
modes as \s-1DES\s0 (see \fIdes_modes\fR\|(7)).  Blowfish is currently one
of the faster block ciphers.  It is quite a bit faster than \s-1DES\s0, and much
faster than \s-1IDEA\s0 or \s-1RC2\s0.
.PP
Blowfish consists of a key setup phase and the actual encryption or decryption
phase.
.PP
\&\fIBF_set_key()\fR sets up the \fB\s-1BF_KEY\s0\fR \fBkey\fR using the \fBlen\fR bytes long key
at \fBdata\fR.
.PP
\&\fIBF_ecb_encrypt()\fR is the basic Blowfish encryption and decryption function.
It encrypts or decrypts the first 64 bits of \fBin\fR using the key \fBkey\fR,
putting the result in \fBout\fR.  \fBenc\fR decides if encryption (\fB\s-1BF_ENCRYPT\s0\fR)
or decryption (\fB\s-1BF_DECRYPT\s0\fR) shall be performed.  The vector pointed at by
\&\fBin\fR and \fBout\fR must be 64 bits in length, no less.  If they are larger,
everything after the first 64 bits is ignored.
.PP
The mode functions \fIBF_cbc_encrypt()\fR, \fIBF_cfb64_encrypt()\fR and \fIBF_ofb64_encrypt()\fR
all operate on variable length data.  They all take an initialization vector
\&\fBivec\fR which needs to be passed along into the next call of the same function 
for the same message.  \fBivec\fR may be initialized with anything, but the
recipient needs to know what it was initialized with, or it won't be able
to decrypt.  Some programs and protocols simplify this, like \s-1SSH\s0, where
\&\fBivec\fR is simply initialized to zero.
\&\fIBF_cbc_encrypt()\fR operates on data that is a multiple of 8 bytes long, while
\&\fIBF_cfb64_encrypt()\fR and \fIBF_ofb64_encrypt()\fR are used to encrypt an variable
number of bytes (the amount does not have to be an exact multiple of 8).  The
purpose of the latter two is to simulate stream ciphers, and therefore, they
need the parameter \fBnum\fR, which is a pointer to an integer where the current
offset in \fBivec\fR is stored between calls.  This integer must be initialized
to zero when \fBivec\fR is initialized.
.PP
\&\fIBF_cbc_encrypt()\fR is the Cipher Block Chaining function for Blowfish.  It
encrypts or decrypts the 64 bits chunks of \fBin\fR using the key \fBschedule\fR,
putting the result in \fBout\fR.  \fBenc\fR decides if encryption (\s-1BF_ENCRYPT\s0) or
decryption (\s-1BF_DECRYPT\s0) shall be performed.  \fBivec\fR must point at an 8 byte
long initialization vector.
.PP
\&\fIBF_cfb64_encrypt()\fR is the \s-1CFB\s0 mode for Blowfish with 64 bit feedback.
It encrypts or decrypts the bytes in \fBin\fR using the key \fBschedule\fR,
putting the result in \fBout\fR.  \fBenc\fR decides if encryption (\fB\s-1BF_ENCRYPT\s0\fR)
or decryption (\fB\s-1BF_DECRYPT\s0\fR) shall be performed.  \fBivec\fR must point at an
8 byte long initialization vector. \fBnum\fR must point at an integer which must
be initially zero.
.PP
\&\fIBF_ofb64_encrypt()\fR is the \s-1OFB\s0 mode for Blowfish with 64 bit feedback.
It uses the same parameters as \fIBF_cfb64_encrypt()\fR, which must be initialized
the same way.
.PP
\&\fIBF_encrypt()\fR and \fIBF_decrypt()\fR are the lowest level functions for Blowfish
encryption.  They encrypt/decrypt the first 64 bits of the vector pointed by
\&\fBdata\fR, using the key \fBkey\fR.  These functions should not be used unless you
implement 'modes' of Blowfish.  The alternative is to use \fIBF_ecb_encrypt()\fR.
If you still want to use these functions, you should be aware that they take
each 32\-bit chunk in host-byte order, which is little-endian on little-endian
platforms and big-endian on big-endian ones.
.SH "RETURN VALUES"
.IX Header "RETURN VALUES"
None of the functions presented here return any value.
.SH "NOTE"
.IX Header "NOTE"
Applications should use the higher level functions
\&\fIEVP_EncryptInit\fR\|(3) etc. instead of calling the
blowfish functions directly.
.SH "SEE ALSO"
.IX Header "SEE ALSO"
\&\fIdes_modes\fR\|(7)
.SH "HISTORY"
.IX Header "HISTORY"
The Blowfish functions are available in all versions of SSLeay and OpenSSL.
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8b0cefbb JR	124	.\" ========================================================================
	125	.\"
	126	.IX Title "blowfish 3"
e3261593	127	.TH blowfish 3 "2012-01-04" "1.0.0f" "OpenSSL"
e257b235 PA	128	.\" For nroff, turn off justification. Always turn off hyphenation; it makes
	129	.\" way too many mistakes in technical documents.
	130	.if n .ad l
	131	.nh
984263bc MD	132	.SH "NAME"
	133	blowfish, BF_set_key, BF_encrypt, BF_decrypt, BF_ecb_encrypt, BF_cbc_encrypt,
	134	BF_cfb64_encrypt, BF_ofb64_encrypt, BF_options \- Blowfish encryption
	135	.SH "SYNOPSIS"
8b0cefbb	136	.IX Header "SYNOPSIS"
984263bc MD	137	.Vb 1
984263bc MD	138	\& #include <openssl/blowfish.h>
e257b235	139	\&
984263bc	140	\& void BF_set_key(BF_KEY key, int len, const unsigned char data);
e257b235	141	\&
984263bc MD	142	\& void BF_ecb_encrypt(const unsigned char in, unsigned char out,
	143	\& BF_KEY *key, int enc);
	144	\& void BF_cbc_encrypt(const unsigned char in, unsigned char out,
	145	\& long length, BF_KEY schedule, unsigned char ivec, int enc);
	146	\& void BF_cfb64_encrypt(const unsigned char in, unsigned char out,
	147	\& long length, BF_KEY schedule, unsigned char ivec, int *num,
	148	\& int enc);
	149	\& void BF_ofb64_encrypt(const unsigned char in, unsigned char out,
	150	\& long length, BF_KEY schedule, unsigned char ivec, int *num);
	151	\& const char *BF_options(void);
e257b235	152	\&
984263bc MD	153	\& void BF_encrypt(BF_LONG data,const BF_KEY key);
	154	\& void BF_decrypt(BF_LONG data,const BF_KEY key);
	155	.Ve
	156	.SH "DESCRIPTION"
8b0cefbb	157	.IX Header "DESCRIPTION"
984263bc MD	158	This library implements the Blowfish cipher, which was invented and described
	159	by Counterpane (see http://www.counterpane.com/blowfish.html ).
	160	.PP
	161	Blowfish is a block cipher that operates on 64 bit (8 byte) blocks of data.
	162	It uses a variable size key, but typically, 128 bit (16 byte) keys are
a561f9ff	163	considered good for strong encryption. Blowfish can be used in the same
8b0cefbb JR	164	modes as \s-1DES\s0 (see \fIdes_modes\fR\\|(7)). Blowfish is currently one
	165	of the faster block ciphers. It is quite a bit faster than \s-1DES\s0, and much
	166	faster than \s-1IDEA\s0 or \s-1RC2\s0.
984263bc MD	167	.PP
	168	Blowfish consists of a key setup phase and the actual encryption or decryption
	169	phase.
	170	.PP
8b0cefbb	171	\&\fIBF_set_key()\fR sets up the \fB\s-1BF_KEY\s0\fR \fBkey\fR using the \fBlen\fR bytes long key
984263bc MD	172	at \fBdata\fR.
984263bc MD	173	.PP
8b0cefbb	174	\&\fIBF_ecb_encrypt()\fR is the basic Blowfish encryption and decryption function.
984263bc	175	It encrypts or decrypts the first 64 bits of \fBin\fR using the key \fBkey\fR,
8b0cefbb JR	176	putting the result in \fBout\fR. \fBenc\fR decides if encryption (\fB\s-1BF_ENCRYPT\s0\fR)
	177	or decryption (\fB\s-1BF_DECRYPT\s0\fR) shall be performed. The vector pointed at by
	178	\&\fBin\fR and \fBout\fR must be 64 bits in length, no less. If they are larger,
984263bc MD	179	everything after the first 64 bits is ignored.
	180	.PP
	181	The mode functions \fIBF_cbc_encrypt()\fR, \fIBF_cfb64_encrypt()\fR and \fIBF_ofb64_encrypt()\fR
	182	all operate on variable length data. They all take an initialization vector
8b0cefbb	183	\&\fBivec\fR which needs to be passed along into the next call of the same function
984263bc MD	184	for the same message. \fBivec\fR may be initialized with anything, but the
984263bc MD	185	recipient needs to know what it was initialized with, or it won't be able
8b0cefbb JR	186	to decrypt. Some programs and protocols simplify this, like \s-1SSH\s0, where
	187	\&\fBivec\fR is simply initialized to zero.
	188	\&\fIBF_cbc_encrypt()\fR operates on data that is a multiple of 8 bytes long, while
	189	\&\fIBF_cfb64_encrypt()\fR and \fIBF_ofb64_encrypt()\fR are used to encrypt an variable
984263bc MD	190	number of bytes (the amount does not have to be an exact multiple of 8). The
	191	purpose of the latter two is to simulate stream ciphers, and therefore, they
	192	need the parameter \fBnum\fR, which is a pointer to an integer where the current
	193	offset in \fBivec\fR is stored between calls. This integer must be initialized
	194	to zero when \fBivec\fR is initialized.
	195	.PP
8b0cefbb	196	\&\fIBF_cbc_encrypt()\fR is the Cipher Block Chaining function for Blowfish. It
984263bc	197	encrypts or decrypts the 64 bits chunks of \fBin\fR using the key \fBschedule\fR,
8b0cefbb JR	198	putting the result in \fBout\fR. \fBenc\fR decides if encryption (\s-1BF_ENCRYPT\s0) or
8b0cefbb JR	199	decryption (\s-1BF_DECRYPT\s0) shall be performed. \fBivec\fR must point at an 8 byte
984263bc MD	200	long initialization vector.
984263bc MD	201	.PP
8b0cefbb	202	\&\fIBF_cfb64_encrypt()\fR is the \s-1CFB\s0 mode for Blowfish with 64 bit feedback.
984263bc	203	It encrypts or decrypts the bytes in \fBin\fR using the key \fBschedule\fR,
8b0cefbb JR	204	putting the result in \fBout\fR. \fBenc\fR decides if encryption (\fB\s-1BF_ENCRYPT\s0\fR)
8b0cefbb JR	205	or decryption (\fB\s-1BF_DECRYPT\s0\fR) shall be performed. \fBivec\fR must point at an
984263bc MD	206	8 byte long initialization vector. \fBnum\fR must point at an integer which must
	207	be initially zero.
	208	.PP
8b0cefbb	209	\&\fIBF_ofb64_encrypt()\fR is the \s-1OFB\s0 mode for Blowfish with 64 bit feedback.
984263bc MD	210	It uses the same parameters as \fIBF_cfb64_encrypt()\fR, which must be initialized
	211	the same way.
	212	.PP
8b0cefbb	213	\&\fIBF_encrypt()\fR and \fIBF_decrypt()\fR are the lowest level functions for Blowfish
984263bc	214	encryption. They encrypt/decrypt the first 64 bits of the vector pointed by
8b0cefbb JR	215	\&\fBdata\fR, using the key \fBkey\fR. These functions should not be used unless you
8b0cefbb JR	216	implement 'modes' of Blowfish. The alternative is to use \fIBF_ecb_encrypt()\fR.
984263bc	217	If you still want to use these functions, you should be aware that they take
8b0cefbb	218	each 32\-bit chunk in host-byte order, which is little-endian on little-endian
984263bc MD	219	platforms and big-endian on big-endian ones.
984263bc MD	220	.SH "RETURN VALUES"
8b0cefbb	221	.IX Header "RETURN VALUES"
984263bc MD	222	None of the functions presented here return any value.
984263bc MD	223	.SH "NOTE"
8b0cefbb	224	.IX Header "NOTE"
984263bc	225	Applications should use the higher level functions
8b0cefbb	226	\&\fIEVP_EncryptInit\fR\\|(3) etc. instead of calling the
984263bc MD	227	blowfish functions directly.
984263bc MD	228	.SH "SEE ALSO"
74dab6c2	229	.IX Header "SEE ALSO"
8b0cefbb JR	230	\&\fIdes_modes\fR\\|(7)
8b0cefbb JR	231	.SH "HISTORY"
74dab6c2	232	.IX Header "HISTORY"
8b0cefbb	233	The Blowfish functions are available in all versions of SSLeay and OpenSSL.