The Data Encryption Standard is described in the US Government Federal Information Processing Standards (FIPS) 46-3 published by the National Institute of Standards and Technology. The DES has been very thoroughly analyzed since it was developed in the late 1970s, and no new significant flaws have been found.
However, the DES uses only a 56-bit key (plus 8 parity bits), and a machine has been built in 1998 which can search through all possible keys in about 6 days, which cost about US$200000; faster searches would be possible with more money. This makes simple DES insecure for most purposes, and NIST no longer permits new US government systems to use simple DES.
For serious encryption functionality, it is recommended that one of the many free encryption libraries be used instead of these routines.
The DES is a reversible operation which takes a 64-bit block and a 64-bit key, and produces another 64-bit block. Usually the bits are numbered so that the most-significant bit, the first bit, of each block is numbered 1.
Under that numbering, every 8th bit of the key (the 8th, 16th, and so on) is not used by the encryption algorithm itself. But the key must have odd parity; that is, out of bits 1 through 8, and 9 through 16, and so on, there must be an odd number of `1' bits, and this completely specifies the unused bits.
The
setkeyfunction sets an internal data structure to be an expanded form of key. key is specified as an array of 64 bits each stored in achar, the first bit iskey[0]and the 64th bit iskey[63]. The key should have the correct parity.
The
encryptfunction encrypts block if edflag is 0, otherwise it decrypts block, using a key previously set bysetkey. The result is placed in block.Like
setkey, block is specified as an array of 64 bits each stored in achar, but there are no parity bits in block.
— Function: void encrypt_r (char *block, int edflag, struct crypt_data * data)
These are reentrant versions of
setkeyandencrypt. The only difference is the extra parameter, which stores the expanded version of key. Before callingsetkey_rthe first time,data->initializedmust be cleared to zero.
The setkey_r and encrypt_r functions are GNU extensions.
setkey, encrypt, setkey_r, and encrypt_r are
defined in crypt.h.
The function
ecb_cryptencrypts or decrypts one or more blocks using DES. Each block is encrypted independently.The blocks and the key are stored packed in 8-bit bytes, so that the first bit of the key is the most-significant bit of
key[0]and the 63rd bit of the key is stored as the least-significant bit ofkey[7]. The key should have the correct parity.len is the number of bytes in blocks. It should be a multiple of 8 (so that there is a whole number of blocks to encrypt). len is limited to a maximum of
DES_MAXDATAbytes.The result of the encryption replaces the input in blocks.
The mode parameter is the bitwise OR of two of the following:
DES_ENCRYPT- This constant, used in the mode parameter, specifies that blocks is to be encrypted.
DES_DECRYPT- This constant, used in the mode parameter, specifies that blocks is to be decrypted.
DES_HW- This constant, used in the mode parameter, asks to use a hardware device. If no hardware device is available, encryption happens anyway, but in software.
DES_SW- This constant, used in the mode parameter, specifies that no hardware device is to be used.
The result of the function will be one of these values:
DESERR_NONE- The encryption succeeded.
DESERR_NOHWDEVICE- The encryption succeeded, but there was no hardware device available.
DESERR_HWERROR- The encryption failed because of a hardware problem.
DESERR_BADPARAM- The encryption failed because of a bad parameter, for instance len is not a multiple of 8 or len is larger than
DES_MAXDATA.
This macro returns 1 if err is a `success' result code from
ecb_cryptorcbc_crypt, and 0 otherwise.
The function
cbc_cryptencrypts or decrypts one or more blocks using DES in Cipher Block Chaining mode.For encryption in CBC mode, each block is exclusive-ored with ivec before being encrypted, then ivec is replaced with the result of the encryption, then the next block is processed. Decryption is the reverse of this process.
This has the advantage that blocks which are the same before being encrypted are very unlikely to be the same after being encrypted, making it much harder to detect patterns in the data.
Usually, ivec is set to 8 random bytes before encryption starts. Then the 8 random bytes are transmitted along with the encrypted data (without themselves being encrypted), and passed back in as ivec for decryption. Another possibility is to set ivec to 8 zeroes initially, and have the first the block encrypted consist of 8 random bytes.
Otherwise, all the parameters are similar to those for
ecb_crypt.
The function
des_setparitychanges the 64-bit key, stored packed in 8-bit bytes, to have odd parity by altering the low bits of each byte.
The ecb_crypt, cbc_crypt, and des_setparity
functions and their accompanying macros are all defined in the header
rpc/des_crypt.h.