SHA224_Init man page on NetBSD

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SHA2(3)			 BSD Library Functions Manual		       SHA2(3)

NAME
     SHA256_Init, SHA256_Update, SHA256_Pad, SHA256_Final, SHA256_Transform,
     SHA256_End, SHA256_File, SHA256_FileChunk, SHA256_Data — calculate the
     NIST Secure Hash Standard (version 2)

SYNOPSIS
     #include <sys/types.h>
     #include <sha2.h>

     void
     SHA224_Init(SHA224_CTX *context);

     void
     SHA224_Update(SHA224_CTX *context, const uint8_t *data, size_t len);

     void
     SHA224_Pad(SHA224_CTX *context);

     void
     SHA224_Final(uint8_t digest[SHA224_DIGEST_LENGTH], SHA224_CTX *context);

     void
     SHA224_Transform(uint32_t state[8],
	 const uint8_t buffer[SHA224_BLOCK_LENGTH]);

     char *
     SHA224_End(SHA224_CTX *context, char *buf);

     char *
     SHA224_File(const char *filename, char *buf);

     char *
     SHA224_FileChunk(const char *filename, char *buf, off_t offset,
	 off_t length);

     char *
     SHA224_Data(uint8_t *data, size_t len, char *buf);

     void
     SHA256_Init(SHA256_CTX *context);

     void
     SHA256_Update(SHA256_CTX *context, const uint8_t *data, size_t len);

     void
     SHA256_Pad(SHA256_CTX *context);

     void
     SHA256_Final(uint8_t digest[SHA256_DIGEST_LENGTH], SHA256_CTX *context);

     void
     SHA256_Transform(uint32_t state[8],
	 const uint8_t buffer[SHA256_BLOCK_LENGTH]);

     char *
     SHA256_End(SHA256_CTX *context, char *buf);

     char *
     SHA256_File(const char *filename, char *buf);

     char *
     SHA256_FileChunk(const char *filename, char *buf, off_t offset,
	 off_t length);

     char *
     SHA256_Data(uint8_t *data, size_t len, char *buf);

     void
     SHA384_Init(SHA384_CTX *context);

     void
     SHA384_Update(SHA384_CTX *context, const uint8_t *data, size_t len);

     void
     SHA384_Pad(SHA384_CTX *context);

     void
     SHA384_Final(uint8_t digest[SHA384_DIGEST_LENGTH], SHA384_CTX *context);

     void
     SHA384_Transform(uint64_t state[8],
	 const uint8_t buffer[SHA384_BLOCK_LENGTH]);

     char *
     SHA384_End(SHA384_CTX *context, char *buf);

     char *
     SHA384_File(char *filename, char *buf);

     char *
     SHA384_FileChunk(char *filename, char *buf, off_t offset, off_t length);

     char *
     SHA384_Data(uint8_t *data, size_t len, char *buf);

     void
     SHA512_Init(SHA512_CTX *context);

     void
     SHA512_Update(SHA512_CTX *context, const uint8_t *data, size_t len);

     void
     SHA512_Pad(SHA512_CTX *context);

     void
     SHA512_Final(uint8_t digest[SHA512_DIGEST_LENGTH], SHA512_CTX *context);

     void
     SHA512_Transform(uint64_t state[8],
	 const uint8_t buffer[SHA512_BLOCK_LENGTH]);

     char *
     SHA512_End(SHA512_CTX *context, char *buf);

     char *
     SHA512_File(char *filename, char *buf);

     char *
     SHA512_FileChunk(char *filename, char *buf, off_t offset, off_t length);

     char *
     SHA512_Data(uint8_t *data, size_t len, char *buf);

DESCRIPTION
     The SHA2 functions implement the NIST Secure Hash Standard, FIPS PUB
     180-2.  The SHA2 functions are used to generate a condensed representa‐
     tion of a message called a message digest, suitable for use as a digital
     signature.	 There are four families of functions, with names correspond‐
     ing to the number of bits in the resulting message digest.	 The SHA-224
     and SHA-256 functions are limited to processing a message of less than
     2^64 bits as input.  The SHA-384 and SHA-512 functions can process a mes‐
     sage of at most 2^128 - 1 bits as input.

     The SHA2 functions are considered to be more secure than the sha1(3)
     functions with which they share a similar interface.  The 224, 256, 384,
     and 512-bit versions of SHA2 share the same interface.  For brevity, only
     the 256-bit variants are described below.

     The SHA256_Init() function initializes a SHA256_CTX context for use with
     SHA256_Update(), and SHA256_Final().  The SHA256_Update() function adds
     data of length len to the SHA256_CTX specified by context.
     SHA256_Final() is called when all data has been added via SHA256_Update()
     and stores a message digest in the digest parameter.

     The SHA256_Pad() function can be used to apply padding to the message
     digest as in SHA256_Final(), but the current context can still be used
     with SHA256_Update().

     The SHA256_Transform() function is used by SHA256_Update() to hash
     512-bit blocks and forms the core of the algorithm.  Most programs should
     use the interface provided by SHA256_Init(), SHA256_Update(), and
     SHA256_Final() instead of calling SHA256_Transform() directly.

     The SHA256_End() function is a front end for SHA256_Final() which con‐
     verts the digest into an ASCII representation of the digest in hexadeci‐
     mal.

     The SHA256_File() function calculates the digest for a file and returns
     the result via SHA256_End().  If SHA256_File() is unable to open the
     file, a NULL pointer is returned.

     SHA256_FileChunk() behaves like SHA256_File() but calculates the digest
     only for that portion of the file starting at offset and continuing for
     length bytes or until end of file is reached, whichever comes first.  A
     zero length can be specified to read until end of file.  A negative
     length or offset will be ignored.

     The SHA256_Data() function calculates the digest of an arbitrary string
     and returns the result via SHA256_End().

     For each of the SHA256_End(), SHA256_File(), SHA256_FileChunk(), and
     SHA256_Data() functions the buf parameter should either be a string large
     enough to hold the resulting digest (e.g., SHA224_DIGEST_STRING_LENGTH,
     SHA256_DIGEST_STRING_LENGTH, SHA384_DIGEST_STRING_LENGTH, or
     SHA512_DIGEST_STRING_LENGTH, depending on the function being used) or a
     NULL pointer.  In the latter case, space will be dynamically allocated
     via malloc(3) and should be freed using free(3) when it is no longer
     needed.

EXAMPLES
     The following code fragment will calculate the SHA-256 digest for the
     string "abc", which is
     “0xba7816bf8f01cfea414140de5dae2223b00361a396177a9cb410ff61f20015ad”.

	   SHA256_CTX ctx;
	   uint8_t results[SHA256_DIGEST_LENGTH];
	   char *buf;
	   int n;

	   buf = "abc";
	   n = strlen(buf);
	   SHA256_Init(&ctx);
	   SHA256_Update(&ctx, (uint8_t *)buf, n);
	   SHA256_Final(results, &ctx);

	   /* Print the digest as one long hex value */
	   printf("0x");
	   for (n = 0; n < SHA256_DIGEST_LENGTH; n++)
		   printf("%02x", results[n]);
	   putchar('\n');

     Alternately, the helper functions could be used in the following way:

	   SHA256_CTX ctx;
	   uint8_t output[SHA256_DIGEST_STRING_LENGTH];
	   char *buf = "abc";

	   printf("0x%s\n", SHA256_Data(buf, strlen(buf), output));

SEE ALSO
     cksum(1), md4(3), md5(3), rmd160(3), sha1(3)

     Secure Hash Standard, FIPS PUB 180-2.

HISTORY
     The SHA2 functions appeared in OpenBSD 3.4 and NetBSD 3.0.

AUTHORS
     This implementation of the SHA functions was written by Aaron D. Gifford.

     The SHA256_End(), SHA256_File(), SHA256_FileChunk(), and SHA256_Data()
     helper functions are derived from code written by Poul-Henning Kamp.

CAVEATS
     This implementation of the Secure Hash Standard has not been validated by
     NIST and as such is not in official compliance with the standard.

     If a message digest is to be copied to a multi-byte type (i.e.: an array
     of five 32-bit integers) it will be necessary to perform byte swapping on
     little endian machines such as the i386, alpha, and vax.

BSD				 May 20, 2009				   BSD
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