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README.org
- libkhash - kana-hash
libkhash - kana-hash
Kana mnemonic hashes
Example output
Input is uguu~
using the default salt.
Algorithm | Output |
---|---|
SHA256 | おシソまツアでぅせツモァだゅノびヲろぢォセつマぶけぁユねハァがゅ |
CRC32 | わぼぢァ |
CRC64 | づやワえぼちレこ |
SHA256 (truncated) | おシソまツアで |
Installation
The dynamic library is built with Cargo
and Rust
, and the cli example program is built with gcc
.
Build and install
The default build configuration builds both the dynamic library and the cli example program, and copies them to /usr/lib/libkhash.so
and /usr/bin/kana-hash
respectively.
$ make && sudo make install
The install path can be changed by editing the INSTALL
and INSTALL-BIN
paths in the Makefile.
Uninstall
To remove installed binaries, run:
$ sudo make uninstall
Other build configurations
The Makefile contains some other build directives.
Native code optimisations
By default libkhash
builds the shared library with native architecture optimisations enabled.
If you are intending to move the binary to another architecture, this might not be desireable.
To build without such optimisations, run:
$ make khash-nonative
Tests
To build and run all tests, run:
$ make test
Building the CLI
The default make
directive builds both the library and the CLI example program.
To build just the CLI example program, run:
$ cd cli && make
TODO Rust crate
C header
A header file is provided for C programs wanting to use the khash interface.
Documented more fully in ./include/khash.h.
All symbols defined here begin with either KHASH_
(for macros) or khash_
.
Example
To create a context
#include <khash.h>
const char* input_salt = "salt!";
const char* input_data = "some data to hash".
khash_context ctx;
assert(khash_new_context(KHASH_ALGO_SHA256, KHASH_SALT_TYPE_SPECIFIC, input_salt, strlen(input_salt), &ctx) == KHASH_SUCCESS, "khash_new_context() failed.");
Find the buffer length we need and allocate a buffer.
size_t length;
assert(khash_length(&ctx, input_data, strlen(input_data), &length) == KHASH_SUCCESS, "khash_length() failed.");
Create the buffer and hash, then print the result to stdout
.
char* buffer = alloca(length+1);
assert(khash_do(&ctx, input_data, strlen(input_data), buffer, length) == KHASH_SUCCESS, "khash_do() failed.");
buffer[length] = 0; // Ensure we have a NUL terminator.
setlocale(LC_ALL, ""); //Ensure we can print UTF-8.
printf("Kana hash: %s\n", buffer);
Alternatively, we can allocate the max length needed instead of calculating it.
size_t length;
assert(khash_max_length(KHASH_ALGO_SHA256, strlen(input_data), &length) == KHASH_SUCCESS, "khash_max_length() failed.");
char* buffer = alloca(length+1);
memset(buffer, 0, length+1); //Ensure NUL terminators.
Definitions
Macros
All macros defined are for options.
They cannot be combied as flags.
The KHASH_ALGO_
prefixed ones are for use as the algo parameter in the khash_new_context()
function.
The KHASH_SALT_TYPE_
prefixed ones are for use as the salt_type parameter.
The KHASH_ERROR_
prefixed ones each indicate an error code returned by all of the functions.
Name | Description |
---|---|
KHASH_ALGO_DEFAULT |
The default algorithm used by the library (truncated SHA256) |
KHASH_ALGO_CRC32 |
CRC32 checksum algorithm |
KHASH_ALGO_CRC64 |
CRC64 checksum algorithm |
KHASH_ALGO_SHA256 |
SHA256 hash algorithm |
KHSAH_ALGO_SHA256_TRUNCATED |
SHA256 truncated to 64-bits |
KHASH_SALT_TYPE_NONE |
No salt |
KHASH_SALT_TYPE_DEFAULT |
The default static salt used by the library |
KHASH_SALT_TYPE_SPECIFIC |
A provided salt, as the data and of the size parameter passed to khash_new_context() |
KHASH_SALT_TYPE_RANDOM |
A randomly generated salt |
KHASH_SUCCESS |
The code returned by all of the functions when the operation was successful |
KHASH_ERROR_IO |
There was an IO error |
KHASH_ERROR_FORMAT |
The was a text formatting related error |
KHASH_ERROR_LENGTH |
There was a hash length mismatch |
KHASH_ERROR_RNG |
The random number generator failed |
KHASH_ERROR_UNKNOWN |
There was an unknown error or the stack attempted to unwind past the FFI boundary. |
Types
There are 2 exported structs, although you will rarely need to access their members directly.
Name | Field | Description |
---|---|---|
khash_salt |
A salt allocated into a context by khash_new_context() and released by khash_free_context() . You shouldn't mess with its field directly. |
|
salt_type | The type of the salt. | |
size | The size of the salt. | |
body | A pointer to the body of the salt. (The memory allocated here is not guaranteed to be of the provided size.) | |
khash_context |
A context for the khash_ functions. Allocated by khash_new_context() . You can modify its fields if you want. |
|
algo | The algorithm for this context. | |
flags | Placeholder for potential flags added in the future. Currently unused. | |
salt | The allocated salt. You shouldn't directly mess with this field. |
Functions
All defined functions return either KHASH_SUCCESS
or one of the KHASH_ERROR_
values above.
Name | Parameters | Description |
---|---|---|
khash_new_context |
algo, salt_type, data, size, output | Creates a new context for use with other libkhash functions. algo is expected to be one of the KHASH_ALGO_ macros listed above. Likewise salt_type is expected to be one of the KHASH_SALT_TYPE_ macros. data can be NULL unless salt_type is set to KHASH_SALT_TYPE_SPECIFIC , in which exactly size bytes are read from data. output is expected to be a valid pointer to a currently unused `khash_context` structure. |
khash_free_context |
ctx | Free a context allocated with khash_new_context() . ctx is expected to be a valid pointer to a currently allocated context. |
khash_clone_context |
src, dst | Clone a context allocated with khash_new_context() into another. The newly allocated dst must be properly released (with khash_free_context() or khash_do() ) as well as the source. src is expected to be a valid pointer to an allocated context, and dst is expected to be a valid pointer to an unallocated context. |
khash_length |
ctx, data, size, length | Compute the length required to hold the output string for khash_do() for a given input. Will read exactly size bytes from data and compute the value into what is pointed to by length (which is expected to be a valid pointer to a type of size_t .) The resulting length does not include a NUL terminator for the string. |
khash_do |
ctx, data, size, output, output_size | Compute the kana-hash of size bytes from data and store no more than output_size of the the result into the string pointed to by output. Each pointer is expected to be valid. This function frees the supplied ctx after the hash has been computed, and thus ctx is no longer valid afterwards. |
khash_max_length |
algo, input_len, output_len | Calculate the max possible size for the given algorithm (expected to be one of the KHASH_ALGO_ macros) and input length, and store this result in output_len (expected to be a valid non-NULL pointer.) input_len is not required unless the algorithm is dynamically sized (all currently implemented ones are not.) |
Node FFI bindings
NPM package in ./node
Installation (npm)
Follow the /flanchan/libkhash/src/commit/4ed44555f3cc0642c3091a215d01bb82a6377cab/installation section first.
$ npm install --save /path/to/repo/node
Examples
Import the package
const hash = require('kana-hash');
Create a context
Create the context by specifying an algorithm identifier, and an optional salt.
If provided, the salt must be of type Salt
.
const ctx = new hash.Kana(hash.Kana.ALGO_DEFAULT, new hash.Salt("optional salt~"));
Create a hash
The once()
function consumes the context and outputs a hash string.
const output = ctx.once("input string");
Creating a hash without consuming
If you want to reuse the context, use the hash()
function.
const output = ctx.hash("input string");
Freeing the context
The context must be release after use if you have not called once()
.
ctx.finish();
Cloning an existing context
The new context must also be freed with either once()
or finish()
.
const new_ctx = ctx.clone();
Alternatively
To create a hash in one line you can do one of the following.
const hash1 = new Kana(Kana.ALGO_DEFAULT, new Salt("salt~")).once("input string~"); //Allocates the exact space required for the output string.
const hash2 = Kana.single(Kana.ALGO_DEFAULT, new Salt("salt~")).once("input string~"); //Allocates the max space required for the output string, instead of the exact. Might be faster.
Interface documentation
The 2 exported objects are Kana
and Salt
.
Kana
's constructor expects between 0 and 2 arguments.
- The first is either an algorithm definition or empty, if empty
Kana
uses the default algorithm (truncated SHA256). - The second is either an instance of
Salt
or empty, if emptyKana
uses the default library salt.
Salt
's constructor expects 0 or 1 argument.
- Either a string to use as the specific salt or empty, if empty there is no salt.
Kana
also has a static function single(algo, salt, input)
which automatically creates a context, computes the hash, frees the context, and then returns the computed hash as a JavaScript string.
Defined constants
Name | Type | Description |
---|---|---|
Kana.ALGO_DEFAULT |
Algorithm definition | The default algorithm specified by the library (set to sha256 truncated) |
Kana.ALGO_CRC32 |
Algorithm definition | CRC32 checksum algorithm |
Kana.ALGO_CRC64 |
Algorithm definition | CRC64 checksum algorithm |
Kana.ALGO_SHA256 |
Algorithm definition | SHA256 hashing algorithm |
Kana.ALGO_SHA256_TRUNCATED |
Algorithm definition | Truncated SHA256 algorithm, to 64-bits |
Salt.None |
Salt | No salt |
Salt.Random |
Salt | A cryptographically secure random salt |
Salt.Default |
Salt | The library's default static salt |
Notes
The strings generated by this library are meant to be pretty, not secure. It is not a secure way of representing a hash as many collisions are possible.
Digest algorithm
The kana algorithm is a 16-bit block digest that works as follows:
- The most and least significant 8 bits are each seperated into Stage 0 and Stage 1 each operating on the first and second byte respectively.
-
Stage 0:
- The byte is sign tested (bitwise
AND
0x80
), store this as a boolean in sign0. - The valid first character range is looked up using the result of the sign test (either 0 or 1), store the range in range, and the slice
KANA
taken from the range in kana. - The first index is calculated as the unsigned first byte modulo the size (exclusive) of range. Store this as index0.
- The swap table is checked to see if index0 has an entry. Then each following step is checked in order:
- The byte is sign tested (bitwise
- If the swap entry exists and the first byte bitwise
AND
0x2
is not 0, set the first character of the output to the value found in the swap table. - If the swap entry exists and the first byte bitwise
AND
0x8
is not 0 and the index has an entry in the 2nd swap table, set the first character of the output to the value found in the 2nd swap table. -
In any other case, set the first character of the output to the value found in the kana slice at the index.
-
Stage 1:
- Compute a sub table for index plus the start of range using the ranges defined in
KANA_SUB_VALID_FOR
and store it in sub. If there is no sub table possible, skip to step 3. - If there is an entry in sub for the index of the 2nd byte modulo the size of
KANA_SUB
, set the second output character to be that character. - If there was no value set from the sub table, the 2nd output character becomes the first output character from inputting the 2nd byte back through Stage 0 as the first byte.
- Compute a sub table for index plus the start of range using the ranges defined in
- Concatenate both characters and move to the next 16-bit block.
Notes:
- It is valid for a single iterator to produce between 0 and 2 characters but no more.
- If an input given to the algorithm that cannot be divided exactly into 16-bit blocks (i.e. one byte is left over), a padding byte of 0 is added as the 2nd byte to make it fit.
For more information see mnemonic.rs.
-
License
GPL'd with love <3