src/crypto/hmac_drbg.c - ipxe - Git at Google

 /*
  * Copyright (C) 2012 Michael Brown <mbrown@fensystems.co.uk>.
  *
  * This program is free software; you can redistribute it and/or
  * modify it under the terms of the GNU General Public License as
  * published by the Free Software Foundation; either version 2 of the
  * License, or any later version.
  *
  * This program is distributed in the hope that it will be useful, but
  * WITHOUT ANY WARRANTY; without even the implied warranty of
  * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE.  See the GNU
  * General Public License for more details.
  *
  * You should have received a copy of the GNU General Public License
  * along with this program; if not, write to the Free Software
  * Foundation, Inc., 51 Franklin Street, Fifth Floor, Boston, MA
  * 02110-1301, USA.
  *
  * You can also choose to distribute this program under the terms of
  * the Unmodified Binary Distribution Licence (as given in the file
  * COPYING.UBDL), provided that you have satisfied its requirements.
  *
  * Alternatively, you may distribute this code in source or binary
  * form, with or without modification, provided that the following
  * conditions are met:
  *
  *  1. Redistributions of source code must retain the above copyright
  *     notice, this list of conditions and the above disclaimer.
  *
  *  2. Redistributions in binary form must reproduce the above
  *     copyright notice, this list of conditions and the above
  *     disclaimer in the documentation and/or other materials provided
  *     with the distribution.
  */

 FILE_LICENCE ( GPL2_OR_LATER_OR_UBDL );

 /** @file
  *
  * HMAC_DRBG algorithm
  *
  * This algorithm is designed to comply with ANS X9.82 Part 3-2007
  * Section 10.2.2.2.  This standard is not freely available, but most
  * of the text appears to be shared with NIST SP 800-90, which can be
  * downloaded from
  *
  *     http://csrc.nist.gov/publications/nistpubs/800-90/SP800-90revised_March2007.pdf
  *
  * Where possible, references are given to both documents.  In the
  * case of any disagreement, ANS X9.82 takes priority over NIST SP
  * 800-90.  (In particular, note that some algorithms that are
  * Approved by NIST SP 800-90 are not Approved by ANS X9.82.)
  */

 #include <stdint.h>
 #include <string.h>
 #include <errno.h>
 #include <assert.h>
 #include <ipxe/crypto.h>
 #include <ipxe/hmac.h>
 #include <ipxe/hmac_drbg.h>

 /**
  * Update the HMAC_DRBG key
  *
  * @v hash		Underlying hash algorithm
  * @v state		HMAC_DRBG internal state
  * @v data		Provided data
  * @v len		Length of provided data
  * @v single		Single byte used in concatenation
  *
  * This function carries out the operation
  *
  *     K = HMAC ( K, V || single || provided_data )
  *
  * as used by hmac_drbg_update()
  */
 static void hmac_drbg_update_key ( struct digest_algorithm *hash,
 				   struct hmac_drbg_state *state,
 				   const void *data, size_t len,
 				   const uint8_t single ) {
 	uint8_t context[ hmac_ctxsize ( hash ) ];
 	size_t out_len = hash->digestsize;

 	DBGC ( state, "HMAC_DRBG_%s %p provided data :\n", hash->name, state );
 	DBGC_HDA ( state, 0, data, len );

 	/* Sanity checks */
 	assert ( hash != NULL );
 	assert ( state != NULL );
 	assert ( ( data != NULL ) || ( len == 0 ) );
 	assert ( ( single == 0x00 ) || ( single == 0x01 ) );

 	/* K = HMAC ( K, V || single || provided_data ) */
 	hmac_init ( hash, context, state->key, out_len );
 	hmac_update ( hash, context, state->value, out_len );
 	hmac_update ( hash, context, &single, sizeof ( single ) );
 	hmac_update ( hash, context, data, len );
 	hmac_final ( hash, context, state->key );

 	DBGC ( state, "HMAC_DRBG_%s %p K = HMAC ( K, V || %#02x || "
 	       "provided_data ) :\n", hash->name, state, single );
 	DBGC_HDA ( state, 0, state->key, out_len );
 }

 /**
  * Update the HMAC_DRBG value
  *
  * @v hash		Underlying hash algorithm
  * @v state		HMAC_DRBG internal state
  * @v data		Provided data
  * @v len		Length of provided data
  * @v single		Single byte used in concatenation
  *
  * This function carries out the operation
  *
  *     V = HMAC ( K, V )
  *
  * as used by hmac_drbg_update() and hmac_drbg_generate()
  */
 static void hmac_drbg_update_value ( struct digest_algorithm *hash,
 				     struct hmac_drbg_state *state ) {
 	uint8_t context[ hmac_ctxsize ( hash ) ];
 	size_t out_len = hash->digestsize;

 	/* Sanity checks */
 	assert ( hash != NULL );
 	assert ( state != NULL );

 	/* V = HMAC ( K, V ) */
 	hmac_init ( hash, context, state->key, out_len );
 	hmac_update ( hash, context, state->value, out_len );
 	hmac_final ( hash, context, state->value );

 	DBGC ( state, "HMAC_DRBG_%s %p V = HMAC ( K, V ) :\n",
 	       hash->name, state );
 	DBGC_HDA ( state, 0, state->value, out_len );
 }

 /**
  * Update HMAC_DRBG internal state
  *
  * @v hash		Underlying hash algorithm
  * @v state		HMAC_DRBG internal state
  * @v data		Provided data
  * @v len		Length of provided data
  *
  * This is the HMAC_DRBG_Update function defined in ANS X9.82 Part
  * 3-2007 Section 10.2.2.2.2 (NIST SP 800-90 Section 10.1.2.2).
  *
  * The key and value are updated in-place within the HMAC_DRBG
  * internal state.
  */
 static void hmac_drbg_update ( struct digest_algorithm *hash,
 			       struct hmac_drbg_state *state,
 			       const void *data, size_t len ) {

 	DBGC ( state, "HMAC_DRBG_%s %p update\n", hash->name, state );

 	/* Sanity checks */
 	assert ( hash != NULL );
 	assert ( state != NULL );
 	assert ( ( data != NULL ) || ( len == 0 ) );

 	/* 1.  K = HMAC ( K, V || 0x00 || provided_data ) */
 	hmac_drbg_update_key ( hash, state, data, len, 0x00 );

 	/* 2.  V = HMAC ( K, V ) */
 	hmac_drbg_update_value ( hash, state );

 	/* 3.  If ( provided_data = Null ), then return K and V */
 	if ( ! len )
 		return;

 	/* 4.  K = HMAC ( K, V || 0x01 || provided_data ) */
 	hmac_drbg_update_key ( hash, state, data, len, 0x01 );

 	/* 5.  V = HMAC ( K, V ) */
 	hmac_drbg_update_value ( hash, state );

 	/* 6.  Return K and V */
 }

 /**
  * Instantiate HMAC_DRBG
  *
  * @v hash		Underlying hash algorithm
  * @v state		HMAC_DRBG internal state to be initialised
  * @v entropy		Entropy input
  * @v entropy_len	Length of entropy input
  * @v personal		Personalisation string
  * @v personal_len	Length of personalisation string
  *
  * This is the HMAC_DRBG_Instantiate_algorithm function defined in ANS
  * X9.82 Part 3-2007 Section 10.2.2.2.3 (NIST SP 800-90 Section
  * 10.1.2.3).
  *
  * The nonce must be included within the entropy input (i.e. the
  * entropy input must contain at least 3/2 * security_strength bits of
  * entropy, as per ANS X9.82 Part 3-2007 Section 8.4.2 (NIST SP 800-90
  * Section 8.6.7).
  *
  * The key, value and reseed counter are updated in-place within the
  * HMAC_DRBG internal state.
  */
 void hmac_drbg_instantiate ( struct digest_algorithm *hash,
 			     struct hmac_drbg_state *state,
 			     const void *entropy, size_t entropy_len,
 			     const void *personal, size_t personal_len ){
 	size_t out_len = hash->digestsize;

 	DBGC ( state, "HMAC_DRBG_%s %p instantiate\n", hash->name, state );

 	/* Sanity checks */
 	assert ( hash != NULL );
 	assert ( state != NULL );
 	assert ( entropy != NULL );
 	assert ( ( personal != NULL ) || ( personal_len == 0 ) );

 	/* 1.  seed_material = entropy_input || nonce ||
 	 *     personalisation_string
 	 */

 	/* 2.  Key = 0x00 00..00 */
 	memset ( state->key, 0x00, out_len );

 	/* 3.  V = 0x01 01...01 */
 	memset ( state->value, 0x01, out_len );

 	/* 4.  ( Key, V ) = HMAC_DBRG_Update ( seed_material, Key, V )
 	 * 5.  reseed_counter = 1
 	 * 6.  Return V, Key and reseed_counter as the
 	 *     initial_working_state
 	 */
 	hmac_drbg_reseed ( hash, state, entropy, entropy_len,
 			   personal, personal_len );
 }

 /**
  * Reseed HMAC_DRBG
  *
  * @v hash		Underlying hash algorithm
  * @v state		HMAC_DRBG internal state
  * @v entropy		Entropy input
  * @v entropy_len	Length of entropy input
  * @v additional	Additional input
  * @v additional_len	Length of additional input
  *
  * This is the HMAC_DRBG_Reseed_algorithm function defined in ANS X9.82
  * Part 3-2007 Section 10.2.2.2.4 (NIST SP 800-90 Section 10.1.2.4).
  *
  * The key, value and reseed counter are updated in-place within the
  * HMAC_DRBG internal state.
  */
 void hmac_drbg_reseed ( struct digest_algorithm *hash,
 			struct hmac_drbg_state *state,
 			const void *entropy, size_t entropy_len,
 			const void *additional, size_t additional_len ) {
 	uint8_t seed_material[ entropy_len + additional_len ];

 	DBGC ( state, "HMAC_DRBG_%s %p (re)seed\n", hash->name, state );

 	/* Sanity checks */
 	assert ( hash != NULL );
 	assert ( state != NULL );
 	assert ( entropy != NULL );
 	assert ( ( additional != NULL ) || ( additional_len == 0 ) );

 	/* 1.  seed_material = entropy_input || additional_input */
 	memcpy ( seed_material, entropy, entropy_len );
 	memcpy ( ( seed_material + entropy_len ), additional, additional_len );
 	DBGC ( state, "HMAC_DRBG_%s %p seed material :\n", hash->name, state );
 	DBGC_HDA ( state, 0, seed_material, sizeof ( seed_material ) );

 	/* 2.  ( Key, V ) = HMAC_DBRG_Update ( seed_material, Key, V ) */
 	hmac_drbg_update ( hash, state, seed_material,
 			   sizeof ( seed_material ) );

 	/* 3.  reseed_counter = 1 */
 	state->reseed_counter = 1;

 	/* 4.  Return V, Key and reseed_counter as the new_working_state */
 }

 /**
  * Generate pseudorandom bits using HMAC_DRBG
  *
  * @v hash		Underlying hash algorithm
  * @v state		HMAC_DRBG internal state
  * @v additional	Additional input
  * @v additional_len	Length of additional input
  * @v data		Output buffer
  * @v len		Length of output buffer
  * @ret rc		Return status code
  *
  * This is the HMAC_DRBG_Generate_algorithm function defined in ANS X9.82
  * Part 3-2007 Section 10.2.2.2.5 (NIST SP 800-90 Section 10.1.2.5).
  *
  * Requests must be for an integral number of bytes.
  *
  * The key, value and reseed counter are updated in-place within the
  * HMAC_DRBG internal state.
  *
  * Note that the only permitted error is "reseed required".
  */
 int hmac_drbg_generate ( struct digest_algorithm *hash,
 			 struct hmac_drbg_state *state,
 			 const void *additional, size_t additional_len,
 			 void *data, size_t len ) {
 	size_t out_len = hash->digestsize;
 	void *orig_data = data;
 	size_t orig_len = len;
 	size_t frag_len;

 	DBGC ( state, "HMAC_DRBG_%s %p generate\n", hash->name, state );

 	/* Sanity checks */
 	assert ( hash != NULL );
 	assert ( state != NULL );
 	assert ( data != NULL );
 	assert ( ( additional != NULL ) || ( additional_len == 0 ) );

 	/* 1.  If reseed_counter > reseed_interval, then return an
 	 *     indication that a reseed is required
 	 */
 	if ( state->reseed_counter > HMAC_DRBG_RESEED_INTERVAL ) {
 		DBGC ( state, "HMAC_DRBG_%s %p reseed interval exceeded\n",
 		       hash->name, state );
 		return -ESTALE;
 	}

 	/* 2.  If additional_input != Null, then
 	 *     ( Key, V ) = HMAC_DRBG_Update ( additional_input, Key, V )
 	 */
 	if ( additional_len )
 		hmac_drbg_update ( hash, state, additional, additional_len );

 	/* 3.  temp = Null
 	 * 4.  While ( len ( temp ) < requested_number_of_bits ) do:
 	 */
 	while ( len ) {

 		/* 4.1  V = HMAC ( Key, V ) */
 		hmac_drbg_update_value ( hash, state );

 		/* 4.2.  temp = temp || V
 		 * 5.    returned_bits = Leftmost requested_number_of_bits
 		 *       of temp
 		 */
 		frag_len = len;
 		if ( frag_len > out_len )
 			frag_len = out_len;
 		memcpy ( data, state->value, frag_len );
 		data += frag_len;
 		len -= frag_len;
 	}

 	/* 6.  ( Key, V ) = HMAC_DRBG_Update ( additional_input, Key, V ) */
 	hmac_drbg_update ( hash, state, additional, additional_len );

 	/* 7.  reseed_counter = reseed_counter + 1 */
 	state->reseed_counter++;

 	DBGC ( state, "HMAC_DRBG_%s %p generated :\n", hash->name, state );
 	DBGC_HDA ( state, 0, orig_data, orig_len );

 	/* 8.  Return SUCCESS, returned_bits, and the new values of
 	 *     Key, V and reseed_counter as the new_working_state
 	 */
 	return 0;
 }
	/*
	* Copyright (C) 2012 Michael Brown <mbrown@fensystems.co.uk>.
	*
	* This program is free software; you can redistribute it and/or
	* modify it under the terms of the GNU General Public License as
	* published by the Free Software Foundation; either version 2 of the
	* License, or any later version.
	*
	* This program is distributed in the hope that it will be useful, but
	* WITHOUT ANY WARRANTY; without even the implied warranty of
	* MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU
	* General Public License for more details.
	*
	* You should have received a copy of the GNU General Public License
	* along with this program; if not, write to the Free Software
	* Foundation, Inc., 51 Franklin Street, Fifth Floor, Boston, MA
	* 02110-1301, USA.
	*
	* You can also choose to distribute this program under the terms of
	* the Unmodified Binary Distribution Licence (as given in the file
	* COPYING.UBDL), provided that you have satisfied its requirements.
	*
	* Alternatively, you may distribute this code in source or binary
	* form, with or without modification, provided that the following
	* conditions are met:
	*
	* 1. Redistributions of source code must retain the above copyright
	* notice, this list of conditions and the above disclaimer.
	*
	* 2. Redistributions in binary form must reproduce the above
	* copyright notice, this list of conditions and the above
	* disclaimer in the documentation and/or other materials provided
	* with the distribution.
	*/

	FILE_LICENCE ( GPL2_OR_LATER_OR_UBDL );

	/** @file
	*
	* HMAC_DRBG algorithm
	*
	* This algorithm is designed to comply with ANS X9.82 Part 3-2007
	* Section 10.2.2.2. This standard is not freely available, but most
	* of the text appears to be shared with NIST SP 800-90, which can be
	* downloaded from
	*
	* http://csrc.nist.gov/publications/nistpubs/800-90/SP800-90revised_March2007.pdf
	*
	* Where possible, references are given to both documents. In the
	* case of any disagreement, ANS X9.82 takes priority over NIST SP
	* 800-90. (In particular, note that some algorithms that are
	* Approved by NIST SP 800-90 are not Approved by ANS X9.82.)
	*/

	#include <stdint.h>
	#include <string.h>
	#include <errno.h>
	#include <assert.h>
	#include <ipxe/crypto.h>
	#include <ipxe/hmac.h>
	#include <ipxe/hmac_drbg.h>

	/**
	* Update the HMAC_DRBG key
	*
	* @v hash Underlying hash algorithm
	* @v state HMAC_DRBG internal state
	* @v data Provided data
	* @v len Length of provided data
	* @v single Single byte used in concatenation
	*
	* This function carries out the operation
	*
	* K = HMAC ( K, V \|\| single \|\| provided_data )
	*
	* as used by hmac_drbg_update()
	*/
	static void hmac_drbg_update_key ( struct digest_algorithm *hash,
	struct hmac_drbg_state *state,
	const void *data, size_t len,
	const uint8_t single ) {
	uint8_t context[ hmac_ctxsize ( hash ) ];
	size_t out_len = hash->digestsize;

	DBGC ( state, "HMAC_DRBG_%s %p provided data :\n", hash->name, state );
	DBGC_HDA ( state, 0, data, len );

	/* Sanity checks */
	assert ( hash != NULL );
	assert ( state != NULL );
	assert ( ( data != NULL ) \|\| ( len == 0 ) );
	assert ( ( single == 0x00 ) \|\| ( single == 0x01 ) );

	/* K = HMAC ( K, V \|\| single \|\| provided_data ) */
	hmac_init ( hash, context, state->key, out_len );
	hmac_update ( hash, context, state->value, out_len );
	hmac_update ( hash, context, &single, sizeof ( single ) );
	hmac_update ( hash, context, data, len );
	hmac_final ( hash, context, state->key );

	DBGC ( state, "HMAC_DRBG_%s %p K = HMAC ( K, V \|\| %#02x \|\| "
	"provided_data ) :\n", hash->name, state, single );
	DBGC_HDA ( state, 0, state->key, out_len );
	}

	/**
	* Update the HMAC_DRBG value
	*
	* @v hash Underlying hash algorithm
	* @v state HMAC_DRBG internal state
	* @v data Provided data
	* @v len Length of provided data
	* @v single Single byte used in concatenation
	*
	* This function carries out the operation
	*
	* V = HMAC ( K, V )
	*
	* as used by hmac_drbg_update() and hmac_drbg_generate()
	*/
	static void hmac_drbg_update_value ( struct digest_algorithm *hash,
	struct hmac_drbg_state *state ) {
	uint8_t context[ hmac_ctxsize ( hash ) ];
	size_t out_len = hash->digestsize;

	/* Sanity checks */
	assert ( hash != NULL );
	assert ( state != NULL );

	/* V = HMAC ( K, V ) */
	hmac_init ( hash, context, state->key, out_len );
	hmac_update ( hash, context, state->value, out_len );
	hmac_final ( hash, context, state->value );

	DBGC ( state, "HMAC_DRBG_%s %p V = HMAC ( K, V ) :\n",
	hash->name, state );
	DBGC_HDA ( state, 0, state->value, out_len );
	}

	/**
	* Update HMAC_DRBG internal state
	*
	* @v hash Underlying hash algorithm
	* @v state HMAC_DRBG internal state
	* @v data Provided data
	* @v len Length of provided data
	*
	* This is the HMAC_DRBG_Update function defined in ANS X9.82 Part
	* 3-2007 Section 10.2.2.2.2 (NIST SP 800-90 Section 10.1.2.2).
	*
	* The key and value are updated in-place within the HMAC_DRBG
	* internal state.
	*/
	static void hmac_drbg_update ( struct digest_algorithm *hash,
	struct hmac_drbg_state *state,
	const void *data, size_t len ) {

	DBGC ( state, "HMAC_DRBG_%s %p update\n", hash->name, state );

	/* Sanity checks */
	assert ( hash != NULL );
	assert ( state != NULL );
	assert ( ( data != NULL ) \|\| ( len == 0 ) );

	/* 1. K = HMAC ( K, V \|\| 0x00 \|\| provided_data ) */
	hmac_drbg_update_key ( hash, state, data, len, 0x00 );

	/* 2. V = HMAC ( K, V ) */
	hmac_drbg_update_value ( hash, state );

	/* 3. If ( provided_data = Null ), then return K and V */
	if ( ! len )
	return;

	/* 4. K = HMAC ( K, V \|\| 0x01 \|\| provided_data ) */
	hmac_drbg_update_key ( hash, state, data, len, 0x01 );

	/* 5. V = HMAC ( K, V ) */
	hmac_drbg_update_value ( hash, state );

	/* 6. Return K and V */
	}

	/**
	* Instantiate HMAC_DRBG
	*
	* @v hash Underlying hash algorithm
	* @v state HMAC_DRBG internal state to be initialised
	* @v entropy Entropy input
	* @v entropy_len Length of entropy input
	* @v personal Personalisation string
	* @v personal_len Length of personalisation string
	*
	* This is the HMAC_DRBG_Instantiate_algorithm function defined in ANS
	* X9.82 Part 3-2007 Section 10.2.2.2.3 (NIST SP 800-90 Section
	* 10.1.2.3).
	*
	* The nonce must be included within the entropy input (i.e. the
	* entropy input must contain at least 3/2 * security_strength bits of
	* entropy, as per ANS X9.82 Part 3-2007 Section 8.4.2 (NIST SP 800-90
	* Section 8.6.7).
	*
	* The key, value and reseed counter are updated in-place within the
	* HMAC_DRBG internal state.
	*/
	void hmac_drbg_instantiate ( struct digest_algorithm *hash,
	struct hmac_drbg_state *state,
	const void *entropy, size_t entropy_len,
	const void *personal, size_t personal_len ){
	size_t out_len = hash->digestsize;

	DBGC ( state, "HMAC_DRBG_%s %p instantiate\n", hash->name, state );

	/* Sanity checks */
	assert ( hash != NULL );
	assert ( state != NULL );
	assert ( entropy != NULL );
	assert ( ( personal != NULL ) \|\| ( personal_len == 0 ) );

	/* 1. seed_material = entropy_input \|\| nonce \|\|
	* personalisation_string
	*/

	/* 2. Key = 0x00 00..00 */
	memset ( state->key, 0x00, out_len );

	/* 3. V = 0x01 01...01 */
	memset ( state->value, 0x01, out_len );

	/* 4. ( Key, V ) = HMAC_DBRG_Update ( seed_material, Key, V )
	* 5. reseed_counter = 1
	* 6. Return V, Key and reseed_counter as the
	* initial_working_state
	*/
	hmac_drbg_reseed ( hash, state, entropy, entropy_len,
	personal, personal_len );
	}

	/**
	* Reseed HMAC_DRBG
	*
	* @v hash Underlying hash algorithm
	* @v state HMAC_DRBG internal state
	* @v entropy Entropy input
	* @v entropy_len Length of entropy input
	* @v additional Additional input
	* @v additional_len Length of additional input
	*
	* This is the HMAC_DRBG_Reseed_algorithm function defined in ANS X9.82
	* Part 3-2007 Section 10.2.2.2.4 (NIST SP 800-90 Section 10.1.2.4).
	*
	* The key, value and reseed counter are updated in-place within the
	* HMAC_DRBG internal state.
	*/
	void hmac_drbg_reseed ( struct digest_algorithm *hash,
	struct hmac_drbg_state *state,
	const void *entropy, size_t entropy_len,
	const void *additional, size_t additional_len ) {
	uint8_t seed_material[ entropy_len + additional_len ];

	DBGC ( state, "HMAC_DRBG_%s %p (re)seed\n", hash->name, state );

	/* Sanity checks */
	assert ( hash != NULL );
	assert ( state != NULL );
	assert ( entropy != NULL );
	assert ( ( additional != NULL ) \|\| ( additional_len == 0 ) );

	/* 1. seed_material = entropy_input \|\| additional_input */
	memcpy ( seed_material, entropy, entropy_len );
	memcpy ( ( seed_material + entropy_len ), additional, additional_len );
	DBGC ( state, "HMAC_DRBG_%s %p seed material :\n", hash->name, state );
	DBGC_HDA ( state, 0, seed_material, sizeof ( seed_material ) );

	/* 2. ( Key, V ) = HMAC_DBRG_Update ( seed_material, Key, V ) */
	hmac_drbg_update ( hash, state, seed_material,
	sizeof ( seed_material ) );

	/* 3. reseed_counter = 1 */
	state->reseed_counter = 1;

	/* 4. Return V, Key and reseed_counter as the new_working_state */
	}

	/**
	* Generate pseudorandom bits using HMAC_DRBG
	*
	* @v hash Underlying hash algorithm
	* @v state HMAC_DRBG internal state
	* @v additional Additional input
	* @v additional_len Length of additional input
	* @v data Output buffer
	* @v len Length of output buffer
	* @ret rc Return status code
	*
	* This is the HMAC_DRBG_Generate_algorithm function defined in ANS X9.82
	* Part 3-2007 Section 10.2.2.2.5 (NIST SP 800-90 Section 10.1.2.5).
	*
	* Requests must be for an integral number of bytes.
	*
	* The key, value and reseed counter are updated in-place within the
	* HMAC_DRBG internal state.
	*
	* Note that the only permitted error is "reseed required".
	*/
	int hmac_drbg_generate ( struct digest_algorithm *hash,
	struct hmac_drbg_state *state,
	const void *additional, size_t additional_len,
	void *data, size_t len ) {
	size_t out_len = hash->digestsize;
	void *orig_data = data;
	size_t orig_len = len;
	size_t frag_len;

	DBGC ( state, "HMAC_DRBG_%s %p generate\n", hash->name, state );

	/* Sanity checks */
	assert ( hash != NULL );
	assert ( state != NULL );
	assert ( data != NULL );
	assert ( ( additional != NULL ) \|\| ( additional_len == 0 ) );

	/* 1. If reseed_counter > reseed_interval, then return an
	* indication that a reseed is required
	*/
	if ( state->reseed_counter > HMAC_DRBG_RESEED_INTERVAL ) {
	DBGC ( state, "HMAC_DRBG_%s %p reseed interval exceeded\n",
	hash->name, state );
	return -ESTALE;
	}

	/* 2. If additional_input != Null, then
	* ( Key, V ) = HMAC_DRBG_Update ( additional_input, Key, V )
	*/
	if ( additional_len )
	hmac_drbg_update ( hash, state, additional, additional_len );

	/* 3. temp = Null
	* 4. While ( len ( temp ) < requested_number_of_bits ) do:
	*/
	while ( len ) {

	/* 4.1 V = HMAC ( Key, V ) */
	hmac_drbg_update_value ( hash, state );

	/* 4.2. temp = temp \|\| V
	* 5. returned_bits = Leftmost requested_number_of_bits
	* of temp
	*/
	frag_len = len;
	if ( frag_len > out_len )
	frag_len = out_len;
	memcpy ( data, state->value, frag_len );
	data += frag_len;
	len -= frag_len;
	}

	/* 6. ( Key, V ) = HMAC_DRBG_Update ( additional_input, Key, V ) */
	hmac_drbg_update ( hash, state, additional, additional_len );

	/* 7. reseed_counter = reseed_counter + 1 */
	state->reseed_counter++;

	DBGC ( state, "HMAC_DRBG_%s %p generated :\n", hash->name, state );
	DBGC_HDA ( state, 0, orig_data, orig_len );

	/* 8. Return SUCCESS, returned_bits, and the new values of
	* Key, V and reseed_counter as the new_working_state
	*/
	return 0;
	}