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.TH LIBHASHSUM_INIT_KECCAK_HASHER 3 libhashsum
.SH NAME
libhashsum_init_keccak_hasher - initialise state for Keccak hashing
.SH SYNOPSIS
.nf
#include <libhashsum.h>
\fBstruct libhashsum_hasher\fP {
enum libhashsum_algorithm \fIalgorithm\fP;
const char *\fIalgorithm_string\fP;
size_t \fIinput_block_size\fP;
size_t \fIhash_size\fP;
unsigned char *\fIhash_output\fP;
unsigned char \fIsupports_non_whole_bytes\fP;
unsigned char \fIstandard_partial_byte_input_encoding\fP;
unsigned char \fIstandard_partial_byte_output_encoding\fP;
unsigned char \fIhash_excess_bits\fP;
size_t (*\fIprocess\fP)(struct libhashsum_hasher *\fPthis\fP, const void *\fPdata\fP, size_t \fPbytes\fP);
int (*\fIfinalise_const\fP)(struct libhashsum_hasher *\fPthis\fP, const void *\fPdata\fP, size_t \fPbytes\fP, unsigned \fPextra_bits\fP);
int (*\fIfinalise\fP)(struct libhashsum_hasher *\fPthis\fP, void *\fPdata\fP, size_t \fPbytes\fP, unsigned \fPextra_bits\fP, size_t \fPsize\fP);
void (*\fIstretch\fP)(struct libhashsum_hasher *\fPthis\fP, int \fPskip\fP, void *\fPbuffer\fP);
void (*\fIdestroy\fP)(struct libhashsum_hasher *\fPthis\fP);
union libhashsum_state { /* definition omitted */ } \fIstate\fP;
};
int \fBlibhashsum_init_keccak_hasher\fP(struct libhashsum_hasher *\fIhasher\fP, size_t \fIratebits\fP,
size_t \fIcapbits\fP, size_t \fIhashbits\fP, size_t \fIsqueezes\fP);
.fi
.PP
Link with
.I -lhashsum
.IR "-lkeccak" .
.SH DESCRIPTION
The
.B libhashsum_init_keccak_hasher
function initialises
.I *hasher
for hashing using the cryptographic hash function Keccak,
and stores hash function information and hashing functions
for Keccak in
.IR *hasher .
.PP
.I ratebit
shall be the rate, in bits per \(dqabsorption\(dq, of the hash function,
or 0 if it shall be resolved to an automatically determined value.
.PP
.I capbits
shall be the capacity, in bits, of the hash function's \(dqsponge\(dq,
or 0 if it shall be resolved to an automatically determined value.
.PP
.I hashbits
shall be the hash size, in bits or 0 if it shall be resolved to
an automatically determined value.
.PP
.I squeezes
shall be the number of \(dqsponge squeezes\(dq to perform at the
end phase when producing the hash, or 0 if it shall be resolved
to an automatically determined value (which will always be 1).
.PP
.I hasher->algorithm
will be set to
.I LIBHASHSUM_KECCAK_224
(if
.I (ratebits, capbits, hashbits, squeezes)
have the values (1152, 448, 224, 1)
after zeroes have been resolved),
.I LIBHASHSUM_KECCAK_256
(if
.I (ratebits, capbits, hashbits, squeezes)
have the values (1088, 512, 256, 1)
after zeroes have been resolved),
.I LIBHASHSUM_KECCAK_384
(if
.I (ratebits, capbits, hashbits, squeezes)
have the values (832, 768, 384, 1)
after zeroes have been resolved),
.I LIBHASHSUM_KECCAK_512
(if
.I (ratebits, capbits, hashbits, squeezes)
have the values (576, 1024, 512, 1)
after zeroes have been resolved), or
.I LIBHASHSUM_KECCAK
(otherwise).
.PP
.I hasher->algorithm_string
will be set to
.RB \(dq Keccak-224 \(dq
if
.I hasher->algorithm
was set to
.IR LIBHASHSUM_KECCAK_224 ,
.RB \(dq Keccak-256 \(dq
if
.I hasher->algorithm
was set to
.IR LIBHASHSUM_KECCAK_256 ,
.RB \(dq Keccak-384 \(dq
if
.I hasher->algorithm
was set to
.IR LIBHASHSUM_KECCAK_384 ,
.RB \(dq Keccak-512 \(dq
if
.I hasher->algorithm
was set to
.IR LIBHASHSUM_KECCAK_512 ,
and otherwise to
.RB \(dq Keccak[r= \fIratebits\fP ,c= \fIcapbits\fP ,n= \fIhashbits\fP ] \(dq
if
.I squeezes<2
or
.RB \(dq Keccak[r= \fIratebits\fP ,c= \fIcapbits\fP ,n= \fIhashbits\fP z= \fIsqueezes\fP ] \(dq
(if
.IR squeezes>1 ),
where
.IR ratebits ,
.IR capbits ,
and
.I hashbits
have their resolved non-zero values.
For the later two cases,
.I hasher->algorithm_string
will be a pointer to a buffer in
.IR hasher->state .
.PP
.I hasher->input_block_size
will be set to the block size, in bytes
.RI ( ratebits/8
unless
.IR ratebits==0 ).
.PP
.I hasher->hash_size
will be set to the hash size, in bytes
.RI ( (hashbits+7)/8
unless
.IR hashbits==0 ).
.PP
.I hasher->hash_excess_bits
will be set to number of bits the last byte in
the hash is padded with (it will be padded with
cleared bits in its most significant part). As
long as
.I hashbits
is a multiple of 8, this number will be 0 (the
entire last byte is used), otherwise, it will be
.IR 8-(hashbits&7) .
.PP
.I hasher->hash_output
will be set to
.IR NULL .
.PP
.I hasher->supports_non_whole_bytes
will be set to 1
to indicate that the
.I *hasher->finalise
and
.I *hasher->finalise_const
functions support non-zero values in their
.I extra_bits
parameter.
.PP
.I hasher->process
will be set to a pointer to the function to call
to feed, and process, data into the hash function.
Its parameter
.I this
shall be set to
.IR hasher .
Its parameter
.I data
parameter shall be set to the buffer of data to
process, and its parameter
.I bytes
shall set to the number of bytes to process from
.IR data .
.I *hasher->process
will return the number of bytes processed, which
will be a multiple of
.IR hasher->input_block_size
no greater than
.IR bytes .
.PP
.I hasher->finalise_const
will be set to a pointer to the function to call
once the entire text being hashed has been loaded,
and to get the hash of the text. Its parameter
.I this
shall be set to
.IR hasher .
Its parameter
.I data
shall be set to the beginning of any yet unprocessed
data, and its parameter
.I bytes
shall be set to the number of bytes to process from
.IR data .
Its parameter
.I extra_bits
shall be set to the number of bits to process from
the lower bits of the incomplete byte
.IR data[bytes] .
The
.I *hasher->finalise_const
function will return 0 upon successful completion,
and set
.I hasher->hash_output
to a pointer to a buffer in
.I hasher->state
containing the binary hash of the processed data.
Otherwise, the function will return -1, and set
.I errno
to indicate the error. However, if the user has
already set
.I hasher->hash_output
to a
.RI non- NULL
pointer, the function will output the binary hash
to that pointer instead without redirecting
.I hasher->hash_output
(the application must make sure this buffer is
sufficiently large). The function will failure if:
.RS
.TP
.B EINVAL
.I extra_bits
is 8 or greater.
.RE
.PP
.I hasher->finalise
will be set to the pointer to a function that
is an alternative to
.I *hasher->finalise_const
that can support zero-copy provided that the
buffer input as the argument
.I data
is sufficiently large. The
.I *hasher->finalise
function may rewrite
.I data
and shall is does not safe to use for multiple
hashers (if the same text is hashed using multiple
hashers,
.I *hasher->finalise_const
must be used). The
function's parameter
.I size
shall be set to the size of the buffer
.IR data .
.I *hasher->finalise
is otherwise identical to
.IR *hasher->finalise_const .
.PP
.I hasher->stretch
will be set to
.IR NULL ,
however upon successful completion of
.I *hasher->finalise
or
.IR *hasher->finalise_const ,
.I hasher->stretch
will be set to point to a function that can be
used to extend the hash by
.I hasher->hash_size
bytes, and can be called repeated without limitation.
The hash extent will be written to a buffer in
.I hasher->state
(which
.I *hasher->finalize
and
.I *hasher->finalize_const
also write the hash to), and
.I hasher->hash_output
will be set to point to this buffer.
.IR *hasher->stretch 's
parameter
.I this
shall be
.IR hasher .
Its parameter
.I skip
can be set to non-zero if the hash extent should
be discarded
.RI ( hasher->hash_output
will not be set in this case).
Its parameter
.I buffer
shall be
.I NULL
for the above described behaviour, or an sufficiently
large buffer the function shall output the hash extent
to. If
.I buffer
is
.RI non- NULL ,
.I hasher->hash_output
will be set to
.IR NULL ).
.PP
.I hasher->destroy
will be set to a pointer to a function to to
call, with
.I hasher
as the argument, deallocate dynamically
allocated data, which may invalidate any
pointer in
.IR *hasher .
.PP
.I hasher->state
will be initialised, it shall be treated as
internal to the library's implementation, and
may change between versions.
.PP
.I hasher
must not be
.IR NULL .
.SH RETURN VALUE
Upon successful completion, the
.B libhashsum_init_keccak_hasher
function returns 0. Otherwise,
the function returns -1 and sets
.I errno
to indicate the error. If -1
is returned, the state of
.I *hasher
is undefined.
.SH ERRORS
The
.B libhashsum_init_keccak_hasher
function fails if:
.TP
.B ENOSYS
Support was excluded at compile time.
.TP
.B ENOMEM
Insufficient memory available.
.TP
.B EINVAL
The combination of the values
.IR ratebits ,
.IR capbits ,
and
.I hashbits
is invalid (possibly any single value
is invalid).
.SH EXTENDED DESCRIPTION
libhashsum has normalises the all implemented hash
functions to always use the least significant bits
in non-whole octets, however each hash function has
its unstandarded. To make it easier to create an
application the use the same encoding of partial
octets as other application using any particular
hash function,
.B struct libhashsum_hasher
contains two fields:
.I standard_partial_byte_input_encoding
and
.IR standard_partial_byte_output_encoding ;
which are merely informtional. They are not set to
specify how libhashsum expects and encodes non-whole
octets, but rather specify how partial bytes are
encoded in the reference implementation or
specification of a hash function.
.PP
Keccak supports non-whole octet both in its
input and its output, and in its standard uses
the least significant bits of non-whole octets
both in the input and in the output, thus
.I this->standard_partial_byte_input_encoding
and
.I this->standard_partial_byte_output_encoding
will both be set to
.IR LIBHASHSUM_LEAST_SIGNIFICANT ,
which the same behaviour as libhashsum implements.
.SH HISTORY
Introduced in libhashsum 1.0.
.PP
The
.I hash_excess_bits
field was added in libhashsum 1.1.
.SH SEE ALSO
.BR libhashsum (7),
.BR libhashsum_init_keccak_224_hasher (3),
.BR libhashsum_init_keccak_256_hasher (3),
.BR libhashsum_init_keccak_384_hasher (3),
.BR libhashsum_init_keccak_512_hasher (3)
|