NAME
SHA512_Init,
SHA512_Update, SHA512_Final,
SHA512_End, SHA512_File,
SHA512_FileChunk,
SHA512_Data, SHA384_Init,
SHA384_Update, SHA384_Final,
SHA384_End, SHA384_File,
SHA384_FileChunk,
SHA384_Data,
SHA512_256_Init,
SHA512_256_Update,
SHA512_256_Final,
SHA512_256_End,
SHA512_256_File,
SHA512_256_FileChunk,
SHA512_256_Data —
calculate the FIPS 180-4 ``SHA-512''
family of message digests
LIBRARY
library “libmd”
SYNOPSIS
#include
<sys/types.h>
#include <sha512.h>
void
SHA512_Init(SHA512_CTX
*context);
void
SHA512_Update(SHA512_CTX
*context, const unsigned
char *data, size_t
len);
void
SHA512_Final(unsigned
char digest[64],
SHA512_CTX *context);
char *
SHA512_End(SHA512_CTX
*context, char
*buf);
char *
SHA512_File(const
char *filename, char
*buf);
char *
SHA512_FileChunk(const
char *filename, char
*buf, off_t offset,
off_t length);
char *
SHA512_Data(const
unsigned char *data,
unsigned int len,
char *buf);
#include
<sha384.h>
void
SHA384_Init(SHA384_CTX
*context);
void
SHA384_Update(SHA384_CTX
*context, const unsigned
char *data, size_t
len);
void
SHA384_Final(unsigned
char digest[48],
SHA384_CTX *context);
char *
SHA384_End(SHA384_CTX
*context, char
*buf);
char *
SHA384_File(const
char *filename, char
*buf);
char *
SHA384_FileChunk(const
char *filename, char
*buf, off_t offset,
off_t length);
char *
SHA384_Data(const
unsigned char *data,
unsigned int len,
char *buf);
#include
<sha512t.h>
void
SHA512_256_Init(SHA512_CTX
*context);
void
SHA512_256_Update(SHA512_CTX
*context, const unsigned
char *data, size_t
len);
void
SHA512_256_Final(unsigned
char digest[32],
SHA512_CTX *context);
char *
SHA512_256_End(SHA512_CTX
*context, char
*buf);
char *
SHA512_256_File(const
char *filename, char
*buf);
char *
SHA512_256_FileChunk(const
char *filename, char
*buf, off_t offset,
off_t length);
char *
SHA512_256_Data(const
unsigned char *data,
unsigned int len,
char *buf);
DESCRIPTION
TheSHA512_ functions calculate a 512-bit cryptographic
checksum (digest) for any number of input bytes. A cryptographic checksum is a
one-way hash function; that is, it is computationally impractical to find the
input corresponding to a particular output. This net result is a
“fingerprint” of the input-data, which does not disclose the
actual input.
The
SHA512_Init(),
SHA512_Update(),
and SHA512_Final() functions are the core functions.
Allocate an SHA512_CTX, initialize it with
SHA512_Init(), run over the data with
SHA512_Update(), and finally extract the result
using SHA512_Final(), which will also erase the
SHA512_CTX.
SHA512_End()
is a wrapper for
SHA512_Final()
which converts the return value to a 129-character (including the
terminating '\0') ASCII string which represents the 512 bits in
hexadecimal.
SHA512_File()
calculates the digest of a file, and uses
SHA512_End() to return the result. If the file
cannot be opened, a null pointer is returned.
SHA512_FileChunk()
is similar to SHA512_File(), but it only calculates
the digest over a byte-range of the file specified, starting at
offset and spanning length
bytes. If the length parameter is specified as 0, or
more than the length of the remaining part of the file,
SHA512_FileChunk() calculates the digest from
offset to the end of file.
SHA512_Data() calculates the digest of a chunk of
data in memory, and uses SHA512_End() to return the
result.
When using
SHA512_End(),
SHA512_File(), or
SHA512_Data(),
the buf argument can be a null pointer, in which case
the returned string is allocated with
malloc(3) and subsequently must be explicitly deallocated using
free(3) after use. If the buf argument is
non-null it must point to at least 129 characters of buffer space.
The SHA384_ and
SHA512_256_ functions are identical to the
SHA512_ functions except they use a different
initial hash value and the output is truncated to 384 bits and 256 bits
respectively.
SHA384_End()
is a wrapper for
SHA384_Final()
which converts the return value to a 97-character (including the terminating
'\0') ASCII string which represents the 384 bits in hexadecimal.
SHA512_256_End()
is a wrapper for
SHA512_Final()
which converts the return value to a 65-character (including the terminating
'\0') ASCII string which represents the 256 bits in hexadecimal.
SEE ALSO
md4(3), md5(3), ripemd(3), sha(3), sha256(3), sha512(3), skein(3)
HISTORY
These functions appeared in FreeBSD 9.0.
AUTHORS
The core hash routines were implemented by Colin Percival based on the published FIPS 180-2 standard.
BUGS
No method is known to exist which finds two files having the same hash value, nor to find a file with a specific hash value. There is on the other hand no guarantee that such a method does not exist.