ctr_eFuse/cr_hsm_code.c

/* ====================================================================
 * Copyright (c) 1998-2008 The OpenSSL Project.  All rights reserved.
 *
 * Redistribution and use in source and binary forms, with or without
 * modification, are permitted provided that the following conditions
 * are met:
 *
 * 1. Redistributions of source code must retain the above copyright
 *    notice, this list of conditions and the following disclaimer. 
 *
 * 2. Redistributions in binary form must reproduce the above copyright
 *    notice, this list of conditions and the following disclaimer in
 *    the documentation and/or other materials provided with the
 *    distribution.
 *
 * 3. All advertising materials mentioning features or use of this
 *    software must display the following acknowledgment:
 *    "This product includes software developed by the OpenSSL Project
 *    for use in the OpenSSL Toolkit. (http://www.openssl.org/)"
 *
 * 4. The names "OpenSSL Toolkit" and "OpenSSL Project" must not be used to
 *    endorse or promote products derived from this software without
 *    prior written permission. For written permission, please contact
 *    openssl-core@openssl.org.
 *
 * 5. Products derived from this software may not be called "OpenSSL"
 *    nor may "OpenSSL" appear in their names without prior written
 *    permission of the OpenSSL Project.
 *
 * 6. Redistributions of any form whatsoever must retain the following
 *    acknowledgment:
 *    "This product includes software developed by the OpenSSL Project
 *    for use in the OpenSSL Toolkit (http://www.openssl.org/)"
 *
 * THIS SOFTWARE IS PROVIDED BY THE OpenSSL PROJECT ``AS IS'' AND ANY
 * EXPRESSED OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE
 * IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR
 * PURPOSE ARE DISCLAIMED.  IN NO EVENT SHALL THE OpenSSL PROJECT OR
 * ITS CONTRIBUTORS BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL,
 * SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT
 * NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES;
 * LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION)
 * HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT,
 * STRICT LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE)
 * ARISING IN ANY WAY OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED
 * OF THE POSSIBILITY OF SUCH DAMAGE.
 * ====================================================================
 *
 * This product includes cryptographic software written by Eric Young
 * (eay@cryptsoft.com).  This product includes software written by Tim
 * Hudson (tjh@cryptsoft.com).
 *
 */

/* Copyright (C) 1995-1998 Eric Young (eay@cryptsoft.com)
 * All rights reserved.
 *
 * This package is an SSL implementation written
 * by Eric Young (eay@cryptsoft.com).
 * The implementation was written so as to conform with Netscapes SSL.
 * 
 * This library is free for commercial and non-commercial use as long as
 * the following conditions are aheared to.  The following conditions
 * apply to all code found in this distribution, be it the RC4, RSA,
 * lhash, DES, etc., code; not just the SSL code.  The SSL documentation
 * included with this distribution is covered by the same copyright terms
 * except that the holder is Tim Hudson (tjh@cryptsoft.com).
 * 
 * Copyright remains Eric Young's, and as such any Copyright notices in
 * the code are not to be removed.
 * If this package is used in a product, Eric Young should be given attribution
 * as the author of the parts of the library used.
 * This can be in the form of a textual message at program startup or
 * in documentation (online or textual) provided with the package.
 * 
 * Redistribution and use in source and binary forms, with or without
 * modification, are permitted provided that the following conditions
 * are met:
 * 1. Redistributions of source code must retain the copyright
 *    notice, this list of conditions and the following disclaimer.
 * 2. Redistributions in binary form must reproduce the above copyright
 *    notice, this list of conditions and the following disclaimer in the
 *    documentation and/or other materials provided with the distribution.
 * 3. All advertising materials mentioning features or use of this software
 *    must display the following acknowledgement:
 *    "This product includes cryptographic software written by
 *     Eric Young (eay@cryptsoft.com)"
 *    The word 'cryptographic' can be left out if the rouines from the library
 *    being used are not cryptographic related :-).
 * 4. If you include any Windows specific code (or a derivative thereof) from 
 *    the apps directory (application code) you must include an acknowledgement:
 *    "This product includes software written by Tim Hudson (tjh@cryptsoft.com)"
 * 
 * THIS SOFTWARE IS PROVIDED BY ERIC YOUNG ``AS IS'' AND
 * ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE
 * IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE
 * ARE DISCLAIMED.  IN NO EVENT SHALL THE AUTHOR OR CONTRIBUTORS BE LIABLE
 * FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL
 * DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS
 * OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION)
 * HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT
 * LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY
 * OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF
 * SUCH DAMAGE.
 * 
 * The licence and distribution terms for any publically available version or
 * derivative of this code cannot be changed.  i.e. this code cannot simply be
 * copied and put under another distribution licence
 * [including the GNU Public Licence.]
 */

#include <assert.h>
#include <stdio.h>
#include <stdlib.h>
#include <limits.h>
#include <time.h>
#include <sys/time.h>
#include <string.h>
#include <cr_alloc.h>

#ifdef USE_HSM
#include "cr_hsm_code.h"
#include "cr_hsm_alloc.h"
#include "cr_hsm_bignum.h"
#include "cr_generate_id.h"
#include "cr_generate_id_private.h"

// nShield
#include "nfastapp.h"
#include "nfkm.h"
#include "rqcard-applic.h"
#include "rqcard-fips.h"

// nFast variables
NFast_AppHandle hsmHandle;
NFastApp_Connection hsmConnection;
NFKM_WorldInfo *hsmWorld = NULL;	// allocate

#ifdef ENCRYPT_AES
M_KeyID hsmAesKeyidDev, hsmAesKeyidProd;
const NFKM_KeyIdent hsmAesKeyidentDev = { (char*)"simple", (char*)"efuse-aes-dev" };
const NFKM_KeyIdent hsmAesKeyidentProd = { (char*)"simple", (char*)"efuse-aes-prod" };

static int hsm_aes_load_key( NFKM_KeyIdent keyident, M_KeyID *keyid );
#else	// !ENCRYPT_AES
M_KeyID hsmRsaPrivkeyidDev, hsmRsaPubkeyidDev, hsmRsaPrivkeyidProd, hsmRsaPubkeyidProd;
const NFKM_KeyIdent hsmRsaKeyidentDev = { (char*)"simple", (char*)"efuse-rsa-priv-dev" };
const NFKM_KeyIdent hsmRsaKeyidentProd = { (char*)"simple", (char*)"efuse-rsa-priv-prod" };

static int hsm_rsa_load_keypair( NFKM_KeyIdent keyident, M_KeyID *privKeyid, M_KeyID *pubKeyid );
#endif	// ENCRYPT_AES

// ECDSA key
M_KeyID hsmEcdsaPrivkeyidDev, hsmEcdsaPubkeyidDev;
M_KeyID hsmEcdsaPrivkeyidProd, hsmEcdsaPubkeyidProd;

const NFKM_KeyIdent hsmEcdsaPrivkeyidentDev = { (char*)"simple", (char*)"nct2-priv-dev" };
const NFKM_KeyIdent hsmEcdsaPubkeyidentDev = { (char*)"simple", (char*)"nct2-pub-dev" };
const NFKM_KeyIdent hsmEcdsaPrivkeyidentProd = { (char*)"simple", (char*)"nct2-priv-prod" };
const NFKM_KeyIdent hsmEcdsaPubkeyidentProd = { (char*)"simple", (char*)"nct2-pub-prod" };
int hsm_ecdsa_load_keypair( NFKM_KeyIdent privKeyident, M_KeyID *privKeyid,
								NFKM_KeyIdent pubKeyident, M_KeyID *pubKeyid );

// init HSM
int hsm_initialize( void )
{
	int ret_code = CR_GENID_SUCCESS;
	
	// HSM <20>̃<EFBFBD><CC83>Z<EFBFBD>b<EFBFBD>g<EFBFBD><67><EFBFBD><EFBFBD>
#ifdef EXE_AUTH_OK
	ret_code = hsm_reset_module();
	if ( ret_code != CR_GENID_SUCCESS )
	{
		SetErrorInfo( __FUNCTION__, __LINE__ );
		return ret_code;
	}
#endif
		
	// init HSM
	ret_code = NFastApp_Init( &hsmHandle, my_hsm_malloc, my_hsm_realloc, my_hsm_free, NULL );
	if ( ret_code != CR_GENID_SUCCESS )
	{
		SetErrorInfo( __FUNCTION__, __LINE__ );
		return ret_code;
	}
	
	// set BigNum upcalls for HSM
	ret_code = NFastApp_SetBignumUpcalls(
					hsmHandle,
					my_bignumreceiveupcall,
					my_bignumsendlenupcall,
					my_bignumsendupcall,
					my_bignumfreeupcall,
					my_bignumformatupcall,
					NULL );
	if ( ret_code != CR_GENID_SUCCESS )
	{
		SetErrorInfo( __FUNCTION__, __LINE__ );
		return ret_code;
	}
	
	// connect HSM
	ret_code = NFastApp_Connect( hsmHandle, &hsmConnection, 0 /* flag */, NULL );
	if ( ret_code != CR_GENID_SUCCESS )
	{
		SetErrorInfo( __FUNCTION__, __LINE__ );
		return ret_code;
	}
	
	// get NFKM info
	ret_code = NFKM_getinfo( hsmHandle, &hsmWorld, NULL );
	if ( ret_code != CR_GENID_SUCCESS )
	{
		SetErrorInfo( __FUNCTION__, __LINE__ );
		return ret_code;
	}

#ifdef ENCRYPT_AES
	// load aes dev key
	ret_code = hsm_aes_load_key( hsmAesKeyidentDev, &hsmAesKeyidDev );
	if ( ret_code != CR_GENID_SUCCESS )
	{
		SetErrorInfo( __FUNCTION__, __LINE__ );
		return ret_code;
	}
	
	// load aes prod key
	ret_code = hsm_aes_load_key( hsmAesKeyidentProd, &hsmAesKeyidProd );
	if ( ret_code != CR_GENID_SUCCESS )
	{
		SetErrorInfo( __FUNCTION__, __LINE__ );
		return ret_code;
	}
#else	// !ENCRYPT_AES
	// load rsa dev keypair
	ret_code = hsm_rsa_load_keypair( hsmRsaKeyidentDev, &hsmRsaPrivkeyidDev, &hsmRsaPubkeyidDev );
	if ( ret_code != CR_GENID_SUCCESS )
	{
		SetErrorInfo( __FUNCTION__, __LINE__ );
		return ret_code;
	}
	
	// load rsa prod keypair
	ret_code = hsm_rsa_load_keypair( hsmRsaKeyidentProd, &hsmRsaPrivkeyidProd, &hsmRsaPubkeyidProd );
	if ( ret_code != CR_GENID_SUCCESS )
	{
		SetErrorInfo( __FUNCTION__, __LINE__ );
		return ret_code;
	}
#endif	// ENCRYPT_AES

	// load ecdsa dev keypair
	ret_code = hsm_ecdsa_load_keypair( hsmEcdsaPrivkeyidentDev, &hsmEcdsaPrivkeyidDev,
											hsmEcdsaPubkeyidentDev, &hsmEcdsaPubkeyidDev );
	if ( ret_code != CR_GENID_SUCCESS )
	{
		SetErrorInfo( __FUNCTION__, __LINE__ );
		return ret_code;
	}
	
	// load ecdsa prod keypair
	ret_code = hsm_ecdsa_load_keypair( hsmEcdsaPrivkeyidentProd, &hsmEcdsaPrivkeyidProd,
											hsmEcdsaPubkeyidentProd, &hsmEcdsaPubkeyidProd );
	if ( ret_code != CR_GENID_SUCCESS )
	{
		SetErrorInfo( __FUNCTION__, __LINE__ );
		return ret_code;
	}

	return ret_code;
}	// hsm_initialize

int hsm_finalize( void )
{
	int ret_code = CR_GENID_SUCCESS;
			
	// void
	NFKM_freeinfo( hsmHandle, &hsmWorld, NULL );
	
	ret_code = NFastApp_Disconnect( hsmConnection, NULL );
	if ( ret_code != CR_GENID_SUCCESS )
	{
		SetErrorInfo( __FUNCTION__, __LINE__ );
	}
	
	// void
	NFastApp_Finish( hsmHandle, NULL );
	
	return ret_code;
}	// hsm_finalize

int hsm_reset_module( void )
{
	int ret_code = CR_GENID_SUCCESS;
	NFast_AppHandle handle;
	NFastApp_Connection connection;
	M_Command cmd;
	M_Reply reply;
	
	memset( &cmd, 0, sizeof( cmd ) );
	memset( &reply, 0, sizeof( reply ) );
	
	// init HSM
	ret_code = NFastApp_InitEx( &handle, NULL, NULL );
	if ( ret_code != CR_GENID_SUCCESS )
	{
		SetErrorInfo( __FUNCTION__, __LINE__ );
		return ret_code;
	}
	
	// <20><><EFBFBD><EFBFBD><EFBFBD><EFBFBD><EFBFBD>[<5B>h<EFBFBD>Őڑ<C590><DA91><EFBFBD><EFBFBD>Ȃ<EFBFBD><C882>ƁAClerUnit, RetryFailedModule<6C>R<EFBFBD>}<7D><><EFBFBD>h<EFBFBD><68><EFBFBD><EFBFBD><EFBFBD>s<EFBFBD>ł<EFBFBD><C582>Ȃ<EFBFBD>
	ret_code = NFastApp_Connect( handle, &connection, NFastApp_ConnectionFlags_Privileged, NULL );
	if ( ret_code != CR_GENID_SUCCESS )
	{
		SetErrorInfo( __FUNCTION__, __LINE__ );
		return ret_code;
	}
	
	// <20><><EFBFBD>W<EFBFBD><57><EFBFBD>[<5B><><EFBFBD>̏<EFBFBD><CC8F>Ԋm<D48A>F
	cmd.cmd = Cmd_NewEnquiry;
	cmd.args.newenquiry.module = HSM_MODULE_ID;
	cmd.args.newenquiry.version = EnqVer_Six;
	ret_code = NFastApp_Transact( connection, NULL, &cmd, &reply, NULL );
	if ( ret_code != CR_GENID_SUCCESS )
	{
		SetErrorInfo( __FUNCTION__, __LINE__ );
		return ret_code;
	}
	ret_code = reply.status;
	if ( ret_code != CR_GENID_SUCCESS )
	{
		SetErrorInfo( __FUNCTION__, __LINE__ );
		return ret_code;
	}
	
	// <20><><EFBFBD>W<EFBFBD><57><EFBFBD>[<5B><><EFBFBD><EFBFBD> failed state <20>łȂ<C582><C882>Ȃ<EFBFBD><C882>ȉ<EFBFBD><C889>͕K<CD95>v<EFBFBD>Ȃ<EFBFBD><C882>̂ő<CC82><C591>I<EFBFBD><49>
	if ( reply.reply.newenquiry.flags & Cmd_NewEnquiry_Reply_flags_Failed )
	{
		NFastApp_Free_Command( handle, NULL, NULL, &cmd );
		NFastApp_Free_Reply( handle, NULL, NULL, &reply );
		
		memset( &cmd, 0, sizeof( cmd ) );
		memset( &reply, 0, sizeof( reply ) );
		
		// failed state <20><><EFBFBD><EFBFBD><EFBFBD>̕<EFBFBD><CC95><EFBFBD><EFBFBD>v<EFBFBD><76>
		// <20>K<EFBFBD><4B> Status_OK <20><><EFBFBD>Ԃ<EFBFBD><D482>Ă<EFBFBD><C482><EFBFBD><EFBFBD>̂ŐM<C590>p<EFBFBD>ł<EFBFBD><C582>Ȃ<EFBFBD>
		cmd.cmd = Cmd_RetryFailedModule;
		cmd.args.retryfailedmodule.module = HSM_MODULE_ID;
		ret_code = NFastApp_Transact( connection, NULL, &cmd, &reply, NULL );
		if ( ret_code != CR_GENID_SUCCESS )
		{
			SetErrorInfo( __FUNCTION__, __LINE__ );
			return ret_code;
		}
		ret_code = reply.status;
		if ( ret_code != CR_GENID_SUCCESS )
		{
			SetErrorInfo( __FUNCTION__, __LINE__ );
			return ret_code;
		}
		
		NFastApp_Free_Command( handle, NULL, NULL, &cmd );
		NFastApp_Free_Reply( handle, NULL, NULL, &reply );
		
		memset( &cmd, 0, sizeof( cmd ) );
		memset( &reply, 0, sizeof( reply ) );
		
		// <20><><EFBFBD>W<EFBFBD><57><EFBFBD>[<5B><><EFBFBD>̃<EFBFBD><CC83>Z<EFBFBD>b<EFBFBD>g
		cmd.cmd = Cmd_ClearUnit;
		cmd.args.clearunit.module = HSM_MODULE_ID;
		ret_code = NFastApp_Transact( connection, NULL, &cmd, &reply, NULL );
		if ( ret_code != CR_GENID_SUCCESS )
		{
			SetErrorInfo( __FUNCTION__, __LINE__ );
			return ret_code;
		}
		ret_code = reply.status;
		if ( ret_code != CR_GENID_SUCCESS )
		{
			SetErrorInfo( __FUNCTION__, __LINE__ );
			return ret_code;
		}
		
		NFastApp_Free_Command( handle, NULL, NULL, &cmd );
		NFastApp_Free_Reply( handle, NULL, NULL, &reply );
		
		memset( &cmd, 0, sizeof( cmd ) );
		memset( &reply, 0, sizeof( reply ) );
		
		// <20><><EFBFBD>W<EFBFBD><57><EFBFBD>[<5B><><EFBFBD>̏<EFBFBD><CC8F>Ԃ<EFBFBD><D482>ēx<C493>m<EFBFBD>F
		cmd.cmd = Cmd_NewEnquiry;
		cmd.args.newenquiry.module = HSM_MODULE_ID;
		cmd.args.newenquiry.version = EnqVer_Six;
		ret_code = NFastApp_Transact( connection, NULL, &cmd, &reply, NULL );
		if ( ret_code != CR_GENID_SUCCESS )
		{
			SetErrorInfo( __FUNCTION__, __LINE__ );
			return ret_code;
		}
		ret_code = reply.status;
		if ( ret_code != CR_GENID_SUCCESS )
		{
			SetErrorInfo( __FUNCTION__, __LINE__ );
			return ret_code;
		}
		
		// <20><><EFBFBD><EFBFBD><EFBFBD><EFBFBD><EFBFBD>Ȃ<EFBFBD><C882>悤<EFBFBD>Ȃ<EFBFBD><C882>I<EFBFBD><49><EFBFBD><EFBFBD><EFBFBD>邵<EFBFBD><E982B5><EFBFBD>Ȃ<EFBFBD>
		if ( reply.reply.newenquiry.flags & Cmd_NewEnquiry_Reply_flags_Failed )
		{
			SetErrorInfo( __FUNCTION__, __LINE__ );
			return Status_HardwareFailed;
		}
	}	// <20><><EFBFBD><EFBFBD><EFBFBD><EFBFBD><EFBFBD><EFBFBD>
	
	// <20>ؒf
	ret_code = NFastApp_Disconnect( hsmConnection, NULL );
	if ( ret_code != CR_GENID_SUCCESS )
	{
		SetErrorInfo( __FUNCTION__, __LINE__ );
		return ret_code;
	}
	
	// <20>n<EFBFBD><6E><EFBFBD>h<EFBFBD><68><EFBFBD>j<EFBFBD><6A>
	NFastApp_Finish( handle, NULL );

	return ret_code;
}	// hsm_reset_module

int hsm_generate_random( unsigned char *buf, int bytes )
{
	int ret_code = CR_GENID_SUCCESS;
	M_Command cmd;
	M_Reply reply;
	
	memset( &cmd, 0, sizeof( cmd ) );
	memset( &reply, 0, sizeof( reply ) );
	
	// <20>R<EFBFBD>}<7D><><EFBFBD>h<EFBFBD>ɒl<C992><6C><EFBFBD>Z<EFBFBD>b<EFBFBD>g<EFBFBD><67><EFBFBD><EFBFBD>
	cmd.cmd = Cmd_GenerateRandom;
	cmd.args.generaterandom.lenbytes = bytes;
	
	// <20><><EFBFBD>ߔ<EFBFBD><DF94>s
	ret_code = NFastApp_Transact( hsmConnection, NULL, &cmd, &reply, NULL );
	if ( ret_code != CR_GENID_SUCCESS )
	{
		SetErrorInfo( __FUNCTION__, __LINE__ );
		return ret_code;
	}
	ret_code = reply.status;
	if ( ret_code != CR_GENID_SUCCESS )
	{
		SetErrorInfo( __FUNCTION__, __LINE__ );
		return ret_code;
	}
	
	// buffer copy
	memcpy( buf, reply.reply.generaterandom.data.ptr, bytes );
	
	NFastApp_Free_Command( hsmHandle, NULL, NULL, &cmd );
	NFastApp_Free_Reply( hsmHandle, NULL, NULL, &reply );

	return CR_GENID_SUCCESS;
}	// hsm_generate_rand

int hsm_get_rtc( time_t *time )
{
	int ret_code = CR_GENID_SUCCESS;
	
	M_Command cmd;
	M_Reply reply;
	
	memset( &cmd, 0, sizeof( cmd ) );
	memset( &reply, 0, sizeof( reply ) );

	// <20>R<EFBFBD>}<7D><><EFBFBD>h<EFBFBD>ɒl<C992><6C><EFBFBD>Z<EFBFBD>b<EFBFBD>g<EFBFBD><67><EFBFBD><EFBFBD>
	cmd.cmd = Cmd_GetRTC;
	cmd.args.getrtc.module = HSM_MODULE_ID;
	
	// <20><><EFBFBD>ߔ<EFBFBD><DF94>s
	ret_code = NFastApp_Transact( hsmConnection, NULL, &cmd, &reply, NULL );
	if ( ret_code != CR_GENID_SUCCESS )
	{
		SetErrorInfo( __FUNCTION__, __LINE__ );
		return ret_code;
	}
	ret_code = reply.status;
	if ( ret_code != CR_GENID_SUCCESS )
	{
		SetErrorInfo( __FUNCTION__, __LINE__ );
		return ret_code;
	}
	
	*time = (int)reply.reply.getrtc.time.currenttimelow;
	
	NFastApp_Free_Command( hsmHandle, NULL, NULL, &cmd );
	NFastApp_Free_Reply( hsmHandle, NULL, NULL, &reply );
	
	return CR_GENID_SUCCESS;
}	// hsm_get_rtc

#ifdef ENCRYPT_AES

int hsm_aes_load_key( NFKM_KeyIdent keyident, M_KeyID *keyid )
{
	int ret_code = CR_GENID_SUCCESS;
	NFKM_Key *keyinfo = NULL;
	NFKM_ModuleInfo *moduleinfo = NULL;
	M_ByteBlock *blobPtr = NULL;
	
	// find key
	ret_code = NFKM_findkey( hsmHandle, keyident, &keyinfo, NULL );
	if ( ret_code != CR_GENID_SUCCESS )
	{
		SetErrorInfo( __FUNCTION__, __LINE__ );
		goto end;
	}

	// get usable Module
	moduleinfo = hsmWorld->modules[0];
	ret_code = NFKM_getusablemodule( hsmWorld, HSM_MODULE_ID, &moduleinfo );
	if ( ret_code != CR_GENID_SUCCESS )
	{
		SetErrorInfo( __FUNCTION__, __LINE__ );
		goto end;
	}

	// load key blob
	blobPtr = &keyinfo->privblob;
	ret_code = NFKM_cmd_loadblob( hsmHandle, hsmConnection,
								moduleinfo->module, blobPtr, 
								0, keyid, "loading aes key blob", NULL );
	if ( ret_code != CR_GENID_SUCCESS )
	{
		SetErrorInfo( __FUNCTION__, __LINE__ );
		goto end;
	}

end:
	if ( keyinfo != NULL )
		NFKM_freekey( hsmHandle, keyinfo, NULL );

	return ret_code;
}	// hsm_aes_load_key

int hsm_aes_encrypt( unsigned char *dst_buf, unsigned char *org_buf, int size, u8 bonding_option, u8 *pIV )
{
	int ret_code = CR_GENID_SUCCESS;
	
	M_KeyID keyid;
	M_Command cmd;
	M_Reply reply;
	M_IV enc_iv;
	
	memset( &cmd, 0, sizeof( cmd ) );
	memset( &reply, 0, sizeof( reply ) );
	
	// key set
	keyid = bonding_option ? hsmAesKeyidDev : hsmAesKeyidProd;
	
	// iv set
	enc_iv.mech = Mech_RijndaelmCBCpNONE;
	memcpy( enc_iv.iv.generic128.iv.bytes, pIV, sizeof( enc_iv.iv.generic128.iv.bytes ) );
	
	// encrypt command set
	cmd.cmd = Cmd_Encrypt;
	cmd.args.encrypt.key = keyid;
	cmd.args.encrypt.mech = Mech_RijndaelmCBCpNONE;
	cmd.args.encrypt.plain.type = PlainTextType_Bytes;
	cmd.args.encrypt.plain.data.bytes.data.len = size;
	cmd.args.encrypt.plain.data.bytes.data.ptr = org_buf;
	cmd.args.encrypt.flags = Cmd_Encrypt_Args_flags_given_iv_present;
	cmd.args.encrypt.given_iv = &enc_iv;
	
	// encrypt command issue
	ret_code = NFastApp_Transact( hsmConnection, NULL, &cmd, &reply, NULL );
	if ( ret_code != CR_GENID_SUCCESS )
	{
		SetErrorInfo( __FUNCTION__, __LINE__ );
		return ret_code;
	}
	ret_code = reply.status;
	if ( ret_code != CR_GENID_SUCCESS )
	{
		SetErrorInfo( __FUNCTION__, __LINE__ );
		return ret_code;
	}
	
	// buffer copy
	memcpy( dst_buf, reply.reply.encrypt.cipher.data.generic128.cipher.ptr, size );

	//NFastApp_Free_Command( hsmHandle, NULL, NULL, &cmd );	// <20><><EFBFBD>̂<EFBFBD><CC82>A<EFBFBD>{<7B>[<5B>g<EFBFBD><67><EFBFBD><EFBFBD>
	NFastApp_Free_Reply( hsmHandle, NULL, NULL, &reply );
	
	return CR_GENID_SUCCESS;
}	// hsm_aes_encrypt

int hsm_aes_decrypt( unsigned char *dst_buf, unsigned char *org_buf, int size, u8 bonding_option, u8 *pIV )
{
	int ret_code = CR_GENID_SUCCESS;
	
	M_KeyID keyid;
	M_Command cmd;
	M_Reply reply;
	M_IV dec_iv;
	
	memset( &cmd, 0, sizeof( cmd ) );
	memset( &reply, 0, sizeof( reply ) );
	
	// key set
	keyid = bonding_option ? hsmAesKeyidDev : hsmAesKeyidProd;
	
	// iv set
	dec_iv.mech = Mech_RijndaelmCBCpNONE;
	memcpy( dec_iv.iv.generic128.iv.bytes, pIV, sizeof( dec_iv.iv.generic128.iv.bytes ) );
	
	// decyrpt
	cmd.cmd = Cmd_Decrypt;
	cmd.args.decrypt.flags = 0;
	cmd.args.decrypt.key = keyid;
	cmd.args.decrypt.mech = Mech_RijndaelmCBCpNONE;
	cmd.args.decrypt.cipher.mech = Mech_RijndaelmCBCpNONE;
	cmd.args.decrypt.cipher.data.generic128.cipher.len = size;
	cmd.args.decrypt.cipher.data.generic128.cipher.ptr = org_buf;
	cmd.args.decrypt.cipher.iv = dec_iv.iv;
	cmd.args.decrypt.reply_type = PlainTextType_Bytes;
	
	// decrypt command issue
	ret_code = NFastApp_Transact( hsmConnection, NULL, &cmd, &reply, NULL );
	if ( ret_code != CR_GENID_SUCCESS )
	{
		SetErrorInfo( __FUNCTION__, __LINE__ );
		return ret_code;
	}
	ret_code = reply.status;
	if ( ret_code != CR_GENID_SUCCESS )
	{
		SetErrorInfo( __FUNCTION__, __LINE__ );
		return ret_code;
	}
	
	// buffer copy
	memcpy( dst_buf, reply.reply.decrypt.plain.data.bytes.data.ptr, size );
	
	//NFastApp_Free_Command( hsmHandle, NULL, NULL, &cmd );	// <20><><EFBFBD>̂<EFBFBD><CC82>A<EFBFBD>{<7B>[<5B>g<EFBFBD><67><EFBFBD><EFBFBD>
	NFastApp_Free_Reply( hsmHandle, NULL, NULL, &reply );
	
	return CR_GENID_SUCCESS;
}	// hsm_aes_decrypt

#else	// !ENCRYPT_AES


int hsm_rsa_load_keypair( NFKM_KeyIdent keyident, M_KeyID *privKeyid, M_KeyID *pubKeyid )
{
	int ret_code = CR_GENID_SUCCESS;
	NFKM_Key *keyinfo = NULL;
	NFKM_ModuleInfo *moduleinfo = NULL;
	M_ByteBlock *blobPtr = NULL;
	
	// find key
	ret_code = NFKM_findkey( hsmHandle, keyident, &keyinfo, NULL );
	if ( ret_code != CR_GENID_SUCCESS )
	{
		SetErrorInfo( __FUNCTION__, __LINE__ );
		goto end;
	}

	// get usable Module
	moduleinfo = hsmWorld->modules[0];
	ret_code = NFKM_getusablemodule( hsmWorld, HSM_MODULE_ID, &moduleinfo );
	if ( ret_code != CR_GENID_SUCCESS )
	{
		SetErrorInfo( __FUNCTION__, __LINE__ );
		goto end;
	}

	// load private key blob
	blobPtr = &keyinfo->privblob;
	ret_code = NFKM_cmd_loadblob( hsmHandle, hsmConnection,
								moduleinfo->module, blobPtr, 
								0, privKeyid, 
								"loading priv key blob", NULL );
	if ( ret_code != CR_GENID_SUCCESS )
	{
		SetErrorInfo( __FUNCTION__, __LINE__ );
		goto end;
	}
	
	// load public key blob
	blobPtr = &keyinfo->pubblob;
	ret_code = NFKM_cmd_loadblob( hsmHandle, hsmConnection,
								moduleinfo->module, blobPtr, 
								0, pubKeyid, 
								"loading pub key blob", NULL );
	if ( ret_code != CR_GENID_SUCCESS )
	{
		SetErrorInfo( __FUNCTION__, __LINE__ );
		goto end;
	}

end:
	NFKM_freekey( hsmHandle, keyinfo, NULL );

	return ret_code;
}	// hsm_rsa_load_keypair

int hsm_rsa_encrypt( unsigned char *dst_buf, unsigned char *org_buf, int size, u8 bonding_option )
{
	int ret_code = CR_GENID_SUCCESS;
	
	M_KeyID keyid;
	M_Command cmd;
	M_Reply reply;
	
	memset( &cmd, 0, sizeof( cmd ) );
	memset( &reply, 0, sizeof( reply ) );
	
	// key set
	keyid = bonding_option ? hsmRsaPubkeyidDev : hsmRsaPubkeyidProd;
	
	// encrypt command set
	cmd.cmd = Cmd_Encrypt;
	cmd.args.encrypt.flags = 0;
	cmd.args.encrypt.key = keyid;
	cmd.args.encrypt.mech = Mech_RSApPKCS1;
	cmd.args.encrypt.plain.type = PlainTextType_Bytes;
	cmd.args.encrypt.plain.data.bytes.data.len = size;
	cmd.args.encrypt.plain.data.bytes.data.ptr = org_buf;
	
	// encrypt command issue
	ret_code = NFastApp_Transact( hsmConnection, NULL, &cmd, &reply, NULL );
	if ( ret_code != CR_GENID_SUCCESS )
	{
		SetErrorInfo( __FUNCTION__, __LINE__ );
		return ret_code;
	}
	ret_code = reply.status;
	if ( ret_code != CR_GENID_SUCCESS )
	{
		SetErrorInfo( __FUNCTION__, __LINE__ );
		return ret_code;
	}
	
	// buffer copy
	memcpy( dst_buf, reply.reply.decrypt.plain.data.bytes.data.ptr, size );
	
	//NFastApp_Free_Command( hsmHandle, NULL, NULL, &cmd );	// <20><><EFBFBD>̂<EFBFBD><CC82>A<EFBFBD>{<7B>[<5B>g<EFBFBD><67><EFBFBD><EFBFBD>
	NFastApp_Free_Reply( hsmHandle, NULL, NULL, &reply );
	
	return CR_GENID_SUCCESS;
}	// hsm_rsa_encrypt

int hsm_rsa_decrypt( unsigned char *dst_buf, unsigned char *org_buf, int size, u8 bonding_option )
{
	int ret_code = CR_GENID_SUCCESS;
	
	M_KeyID keyid;
	M_Command cmd;
	M_Reply reply;
	
	memset( &cmd, 0, sizeof( cmd ) );
	memset( &reply, 0, sizeof( reply ) );
	
	// key set
	keyid = bonding_option ? hsmRsaPrivkeyidDev : hsmRsaPrivkeyidProd;
	
	// decyrpt command set
	cmd.cmd = Cmd_Decrypt;
	cmd.args.decrypt.flags = 0;
	cmd.args.decrypt.key = keyid;
	cmd.args.decrypt.mech = Mech_Any;
	cmd.args.decrypt.cipher.mech = Mech_RSApPKCS1;
	cmd.args.decrypt.cipher.data.generic128.cipher.len = size;
	cmd.args.decrypt.cipher.data.generic128.cipher.ptr = org_buf;
	cmd.args.decrypt.reply_type = PlainTextType_Bytes;
	
	// decrypt command issue
	ret_code = NFastApp_Transact( hsmConnection, NULL, &cmd, &reply, NULL );
	if ( ret_code != CR_GENID_SUCCESS )
	{
		SetErrorInfo( __FUNCTION__, __LINE__ );
		return ret_code;
	}
	ret_code = reply.status;
	if ( ret_code != CR_GENID_SUCCESS )
	{
		SetErrorInfo(  __FUNCTION__, __LINE__ );
		return ret_code;
	}
	
	// buffer copy
	memcpy( dst_buf, reply.reply.decrypt.plain.data.bytes.data.ptr, size );
	
	//NFastApp_Free_Command( hsmHandle, NULL, NULL, &cmd );	// <20><><EFBFBD>̂<EFBFBD><CC82>A<EFBFBD>{<7B>[<5B>g<EFBFBD><67><EFBFBD><EFBFBD>
	NFastApp_Free_Reply( hsmHandle, NULL, NULL, &reply );
	
	return CR_GENID_SUCCESS;
}	// hsm_rsa_decrypt

#endif	// !ENCRYPT_AES

int hsm_ecdsa_load_keypair( NFKM_KeyIdent privKeyident, M_KeyID *privKeyid, 
								NFKM_KeyIdent pubKeyident, M_KeyID *pubKeyid )
{
	int ret_code = CR_GENID_SUCCESS;
	NFKM_Key *keyinfo = NULL;
	NFKM_ModuleInfo *moduleinfo = NULL;
	M_ByteBlock *blobptr = NULL;

	// get usable Module
	moduleinfo = hsmWorld->modules[0];
	ret_code = NFKM_getusablemodule( hsmWorld, HSM_MODULE_ID, &moduleinfo );
	if ( ret_code != CR_GENID_SUCCESS )
	{
		SetErrorInfo( __FUNCTION__, __LINE__ );
		goto end;
	}
	
	// priv
	if ( &privKeyident != NULL )
	{
		// find key
		ret_code = NFKM_findkey( hsmHandle, privKeyident, &keyinfo, NULL );
		if ( ret_code != CR_GENID_SUCCESS )
		{	
			SetErrorInfo( __FUNCTION__, __LINE__ );
			goto end;
		}
		
		// load key blob
		blobptr = &(keyinfo->privblob);
		ret_code = NFKM_cmd_loadblob( hsmHandle, hsmConnection,
									moduleinfo->module, blobptr, 
									0, privKeyid, 
									"loading priv key blob", NULL );
		if ( ret_code != CR_GENID_SUCCESS )
		{
			SetErrorInfo( __FUNCTION__, __LINE__ );
			goto end;
		}
		
		NFKM_freekey( hsmHandle, keyinfo, NULL );
		keyinfo = NULL;
	}
	else
	{
		*privKeyid = 0;
	}	// priv

	// pub
	if ( &pubKeyident != NULL )
	{
		// find key
		ret_code = NFKM_findkey( hsmHandle, pubKeyident, &keyinfo, NULL );
		if ( ret_code != CR_GENID_SUCCESS )
		{	
			SetErrorInfo( __FUNCTION__, __LINE__ );
			goto end;
		}
		
		// load key blob
		blobptr = &(keyinfo->pubblob);
		ret_code = NFKM_cmd_loadblob( hsmHandle, hsmConnection,
									moduleinfo->module, blobptr, 
									0, pubKeyid, 
									"loading pub key blob", NULL );
		if ( ret_code != CR_GENID_SUCCESS )
		{
			SetErrorInfo( __FUNCTION__, __LINE__ );
			goto end;
		}
	}
	else
	{
		*pubKeyid = 0;
	}	// pub

end:
	NFKM_freekey( hsmHandle, keyinfo, NULL );

	return ret_code;
}	// hsm_ecdsa_load_keypair

int hsm_ecdsa_sign( unsigned char *sign_buf, unsigned char *data_buf, unsigned char bonding_option )
{
	int ret_code = CR_GENID_SUCCESS;
	
	M_KeyID privKeyid, pubKeyid;
	M_Command cmd;
	M_Reply reply;
	unsigned char *rPtr, *sPtr;
	int rLen, sLen;

	memset( &cmd, 0, sizeof( cmd ) );
	memset( &reply, 0, sizeof( reply ) );
	
	// key set
	privKeyid = bonding_option ? hsmEcdsaPrivkeyidDev : hsmEcdsaPrivkeyidProd;
	pubKeyid = bonding_option ? hsmEcdsaPubkeyidDev : hsmEcdsaPubkeyidProd;
		
	// sign command set
	cmd.cmd = Cmd_Sign;
	cmd.args.sign.flags = 0;	// Cmd_Sign_Args_flags_given_iv_present;
	cmd.args.sign.key = privKeyid;
	cmd.args.sign.mech = HSM_SIGN_MECH;
#if 1
	cmd.args.sign.plain.type = PlainTextType_Hash32;
	cmd.args.sign.plain.data.hash32.data = *(M_Hash32*)data_buf;
#else
	cmd.args.sign.plain.type = PlainTextType_Hash;
	cmd.args.sign.plain.data.hash.data = *(M_Hash*)data_buf;
#endif

	// sign command issue
	ret_code = NFastApp_Transact( hsmConnection, NULL, &cmd, &reply, NULL );
	if ( ret_code != CR_GENID_SUCCESS )
	{
		SetErrorInfo( __FUNCTION__, __LINE__ );
		return ret_code;
	}
	ret_code = reply.status;
	if ( ret_code != CR_GENID_SUCCESS )
	{
		SetErrorInfo(  __FUNCTION__, __LINE__ );
		return ret_code;
	}

#if 1
	// signature bignum -> bin
	rLen = reply.reply.sign.sig.data.ecdsa.r->nbytes;
	rPtr = (unsigned char*)cr_mem_malloc( rLen );
	my_bignum2bin ( rPtr, rLen, hsmHandle, reply.reply.sign.sig.data.ecdsa.r );
	sLen = reply.reply.sign.sig.data.ecdsa.s->nbytes;
	sPtr = (unsigned char*)cr_mem_malloc( sLen );
	my_bignum2bin ( sPtr, sLen, hsmHandle, reply.reply.sign.sig.data.ecdsa.s );
#endif
		
#if 0
	DEBUG_PRINT_ARRAY( (char*)"sig r(HSM)", (const char *)rPtr, rLen );
	DEBUG_PRINT_ARRAY( (char*)"sig s(HSM)", (const char *)sPtr, sLen );
#endif
																												
	
	// verify
#if 1
	struct NFast_Bignum *rBn, *sBn;
	my_bignumCopy( &rBn, reply.reply.sign.sig.data.ecdsa.r, hsmHandle );
	my_bignumCopy( &sBn, reply.reply.sign.sig.data.ecdsa.s, hsmHandle );

	//NFastApp_Free_Command( handle, NULL, NULL, &cmd );
	NFastApp_Free_Reply( hsmHandle, NULL, NULL, &reply );
	memset( &cmd, 0, sizeof( cmd ) );
	memset( &reply, 0, sizeof( reply ) );

	cmd.cmd = Cmd_Verify;
	cmd.args.verify.flags = 0;
	cmd.args.verify.key = pubKeyid;
	cmd.args.verify.mech = HSM_SIGN_MECH;
#if 1
	cmd.args.verify.plain.type = PlainTextType_Hash32;
	cmd.args.verify.plain.data.hash32.data = *(M_Hash32*)data_buf;
#else
	cmd.args.verify.plain.type = PlainTextType_Hash;
	cmd.args.verify.plain.data.hash.data = *(M_Hash*)data_buf;
#endif

	cmd.args.verify.sig.mech = HSM_SIGN_MECH;
	cmd.args.verify.sig.data.ecdsa.r = rBn;
	cmd.args.verify.sig.data.ecdsa.s = sBn;
	ret_code = NFastApp_Transact( hsmConnection, NULL, &cmd, &reply, NULL );
	if ( ret_code != CR_GENID_SUCCESS )
	{
		SetErrorInfo( __FUNCTION__, __LINE__ );
		return ret_code;
	}
	ret_code = reply.status;
	if ( ret_code != CR_GENID_SUCCESS )
	{
		SetErrorInfo( __FUNCTION__, __LINE__ );
		return ret_code;
	}
	
	NFastApp_Free( hsmHandle, rBn, NULL, NULL );
	NFastApp_Free( hsmHandle, sBn, NULL, NULL );
#endif	// verify
		
	// copy sign
	int i;
	memset( sign_buf, 0, 60 );
	if ( rLen == 32 )
		memcpy( sign_buf, &rPtr[2], 0x1E );
	else
	{
		for ( i = 0; i < rLen; i++ )
			sign_buf[ 30 - i - 1 ] = rPtr[ rLen - i - 1 ];
	}
	
	if ( sLen == 32 )
		memcpy( &sign_buf[30], &sPtr[2], 0x1E );
	else
	{
		for ( i = 0; i < sLen; i++ )
			sign_buf[ 60 - i - 1 ] = sPtr[ sLen - i - 1 ];
	}

	//NFastApp_Free_Command( hsmHandle, NULL, NULL, &cmd );	// <20><><EFBFBD>̂<EFBFBD><CC82>A<EFBFBD>{<7B>[<5B>g<EFBFBD><67><EFBFBD><EFBFBD>
	NFastApp_Free_Reply( hsmHandle, NULL, NULL, &reply );	
	cr_mem_free( rPtr );
	cr_mem_free( sPtr );

	return CR_GENID_SUCCESS;
}	// hsm_ecdsa_sign

#endif // USE_HSM