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diff --git a/target/linux/generic-2.4/files/crypto/ocf/ep80579/icp_asym.c b/target/linux/generic-2.4/files/crypto/ocf/ep80579/icp_asym.c
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+/***************************************************************************
+ *
+ * This file is provided under a dual BSD/GPLv2 license. When using or
+ * redistributing this file, you may do so under either license.
+ *
+ * GPL LICENSE SUMMARY
+ *
+ * Copyright(c) 2007,2008,2009 Intel Corporation. All rights reserved.
+ *
+ * This program is free software; you can redistribute it and/or modify
+ * it under the terms of version 2 of the GNU General Public License as
+ * published by the Free Software Foundation.
+ *
+ * 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 St - Fifth Floor, Boston, MA 02110-1301 USA.
+ * The full GNU General Public License is included in this distribution
+ * in the file called LICENSE.GPL.
+ *
+ * Contact Information:
+ * Intel Corporation
+ *
+ * BSD LICENSE
+ *
+ * Copyright(c) 2007,2008,2009 Intel Corporation. All rights reserved.
+ * All rights reserved.
+ *
+ * Redistribution and use in source and binary forms, with or without
+ * modification, are permitted provided that the following conditions
+ * are met:
+ *
+ * * Redistributions of source code must retain the above copyright
+ * notice, this list of conditions and the following disclaimer.
+ * * 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.
+ * * Neither the name of Intel Corporation nor the names of its
+ * contributors may be used to endorse or promote products derived
+ * from this software without specific prior written permission.
+ *
+ * THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS
+ * "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 COPYRIGHT
+ * OWNER 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.
+ *
+ *
+ * version: Security.L.1.0.2-229
+ *
+ ***************************************************************************/
+
+#include "icp_ocf.h"
+
+/*The following define values (containing the word 'INDEX') are used to find
+the index of each input buffer of the crypto_kop struct (see OCF cryptodev.h).
+These values were found through analysis of the OCF OpenSSL patch. If the
+calling program uses different input buffer positions, these defines will have
+to be changed.*/
+
+/*DIFFIE HELLMAN buffer index values*/
+#define ICP_DH_KRP_PARAM_PRIME_INDEX (0)
+#define ICP_DH_KRP_PARAM_BASE_INDEX (1)
+#define ICP_DH_KRP_PARAM_PRIVATE_VALUE_INDEX (2)
+#define ICP_DH_KRP_PARAM_RESULT_INDEX (3)
+
+/*MOD EXP buffer index values*/
+#define ICP_MOD_EXP_KRP_PARAM_BASE_INDEX (0)
+#define ICP_MOD_EXP_KRP_PARAM_EXPONENT_INDEX (1)
+#define ICP_MOD_EXP_KRP_PARAM_MODULUS_INDEX (2)
+#define ICP_MOD_EXP_KRP_PARAM_RESULT_INDEX (3)
+
+/*MOD EXP CRT buffer index values*/
+#define ICP_MOD_EXP_CRT_KRP_PARAM_PRIME_P_INDEX (0)
+#define ICP_MOD_EXP_CRT_KRP_PARAM_PRIME_Q_INDEX (1)
+#define ICP_MOD_EXP_CRT_KRP_PARAM_I_INDEX (2)
+#define ICP_MOD_EXP_CRT_KRP_PARAM_EXPONENT_DP_INDEX (3)
+#define ICP_MOD_EXP_CRT_KRP_PARAM_EXPONENT_DQ_INDEX (4)
+#define ICP_MOD_EXP_CRT_KRP_PARAM_COEFF_QINV_INDEX (5)
+#define ICP_MOD_EXP_CRT_KRP_PARAM_RESULT_INDEX (6)
+
+/*DSA sign buffer index values*/
+#define ICP_DSA_SIGN_KRP_PARAM_DGST_INDEX (0)
+#define ICP_DSA_SIGN_KRP_PARAM_PRIME_P_INDEX (1)
+#define ICP_DSA_SIGN_KRP_PARAM_PRIME_Q_INDEX (2)
+#define ICP_DSA_SIGN_KRP_PARAM_G_INDEX (3)
+#define ICP_DSA_SIGN_KRP_PARAM_X_INDEX (4)
+#define ICP_DSA_SIGN_KRP_PARAM_R_RESULT_INDEX (5)
+#define ICP_DSA_SIGN_KRP_PARAM_S_RESULT_INDEX (6)
+
+/*DSA verify buffer index values*/
+#define ICP_DSA_VERIFY_KRP_PARAM_DGST_INDEX (0)
+#define ICP_DSA_VERIFY_KRP_PARAM_PRIME_P_INDEX (1)
+#define ICP_DSA_VERIFY_KRP_PARAM_PRIME_Q_INDEX (2)
+#define ICP_DSA_VERIFY_KRP_PARAM_G_INDEX (3)
+#define ICP_DSA_VERIFY_KRP_PARAM_PUBKEY_INDEX (4)
+#define ICP_DSA_VERIFY_KRP_PARAM_SIG_R_INDEX (5)
+#define ICP_DSA_VERIFY_KRP_PARAM_SIG_S_INDEX (6)
+
+/*DSA sign prime Q vs random number K size check values*/
+#define DONT_RUN_LESS_THAN_CHECK (0)
+#define FAIL_A_IS_GREATER_THAN_B (1)
+#define FAIL_A_IS_EQUAL_TO_B (1)
+#define SUCCESS_A_IS_LESS_THAN_B (0)
+#define DSA_SIGN_RAND_GEN_VAL_CHECK_MAX_ITERATIONS (500)
+
+/* We need to set a cryptokp success value just in case it is set or allocated
+ and not set to zero outside of this module */
+#define CRYPTO_OP_SUCCESS (0)
+
+/*Function to compute Diffie Hellman (DH) phase 1 or phase 2 key values*/
+static int icp_ocfDrvDHComputeKey(struct cryptkop *krp);
+
+/*Function to compute a Modular Exponentiation (Mod Exp)*/
+static int icp_ocfDrvModExp(struct cryptkop *krp);
+
+/*Function to compute a Mod Exp using the Chinease Remainder Theorem*/
+static int icp_ocfDrvModExpCRT(struct cryptkop *krp);
+
+/*Helper function to compute whether the first big number argument is less than
+ the second big number argument */
+static int
+icp_ocfDrvCheckALessThanB(CpaFlatBuffer * pK, CpaFlatBuffer * pQ, int *doCheck);
+
+/*Function to sign an input with DSA R and S keys*/
+static int icp_ocfDrvDsaSign(struct cryptkop *krp);
+
+/*Function to Verify a DSA buffer signature*/
+static int icp_ocfDrvDsaVerify(struct cryptkop *krp);
+
+/*Callback function for DH operation*/
+static void
+icp_ocfDrvDhP1CallBack(void *callbackTag,
+ CpaStatus status,
+ void *pOpData, CpaFlatBuffer * pLocalOctetStringPV);
+
+/*Callback function for ME operation*/
+static void
+icp_ocfDrvModExpCallBack(void *callbackTag,
+ CpaStatus status,
+ void *pOpData, CpaFlatBuffer * pResult);
+
+/*Callback function for ME CRT operation*/
+static void
+icp_ocfDrvModExpCRTCallBack(void *callbackTag,
+ CpaStatus status,
+ void *pOpData, CpaFlatBuffer * pOutputData);
+
+/*Callback function for DSA sign operation*/
+static void
+icp_ocfDrvDsaRSSignCallBack(void *callbackTag,
+ CpaStatus status,
+ void *pOpData,
+ CpaBoolean protocolStatus,
+ CpaFlatBuffer * pR, CpaFlatBuffer * pS);
+
+/*Callback function for DSA Verify operation*/
+static void
+icp_ocfDrvDsaVerifyCallBack(void *callbackTag,
+ CpaStatus status,
+ void *pOpData, CpaBoolean verifyStatus);
+
+/* Name : icp_ocfDrvPkeProcess
+ *
+ * Description : This function will choose which PKE process to follow
+ * based on the input arguments
+ */
+int icp_ocfDrvPkeProcess(icp_device_t dev, struct cryptkop *krp, int hint)
+{
+ CpaStatus lacStatus = CPA_STATUS_SUCCESS;
+
+ if (NULL == krp) {
+ DPRINTK("%s(): Invalid input parameters, cryptkop = %p\n",
+ __FUNCTION__, krp);
+ return EINVAL;
+ }
+
+ if (CPA_TRUE == icp_atomic_read(&icp_ocfDrvIsExiting)) {
+ krp->krp_status = ECANCELED;
+ return ECANCELED;
+ }
+
+ switch (krp->krp_op) {
+ case CRK_DH_COMPUTE_KEY:
+ DPRINTK("%s() doing DH_COMPUTE_KEY\n", __FUNCTION__);
+ lacStatus = icp_ocfDrvDHComputeKey(krp);
+ if (CPA_STATUS_SUCCESS != lacStatus) {
+ EPRINTK("%s(): icp_ocfDrvDHComputeKey failed "
+ "(%d).\n", __FUNCTION__, lacStatus);
+ krp->krp_status = ECANCELED;
+ return ECANCELED;
+ }
+
+ break;
+
+ case CRK_MOD_EXP:
+ DPRINTK("%s() doing MOD_EXP \n", __FUNCTION__);
+ lacStatus = icp_ocfDrvModExp(krp);
+ if (CPA_STATUS_SUCCESS != lacStatus) {
+ EPRINTK("%s(): icp_ocfDrvModExp failed (%d).\n",
+ __FUNCTION__, lacStatus);
+ krp->krp_status = ECANCELED;
+ return ECANCELED;
+ }
+
+ break;
+
+ case CRK_MOD_EXP_CRT:
+ DPRINTK("%s() doing MOD_EXP_CRT \n", __FUNCTION__);
+ lacStatus = icp_ocfDrvModExpCRT(krp);
+ if (CPA_STATUS_SUCCESS != lacStatus) {
+ EPRINTK("%s(): icp_ocfDrvModExpCRT "
+ "failed (%d).\n", __FUNCTION__, lacStatus);
+ krp->krp_status = ECANCELED;
+ return ECANCELED;
+ }
+
+ break;
+
+ case CRK_DSA_SIGN:
+ DPRINTK("%s() doing DSA_SIGN \n", __FUNCTION__);
+ lacStatus = icp_ocfDrvDsaSign(krp);
+ if (CPA_STATUS_SUCCESS != lacStatus) {
+ EPRINTK("%s(): icp_ocfDrvDsaSign "
+ "failed (%d).\n", __FUNCTION__, lacStatus);
+ krp->krp_status = ECANCELED;
+ return ECANCELED;
+ }
+
+ break;
+
+ case CRK_DSA_VERIFY:
+ DPRINTK("%s() doing DSA_VERIFY \n", __FUNCTION__);
+ lacStatus = icp_ocfDrvDsaVerify(krp);
+ if (CPA_STATUS_SUCCESS != lacStatus) {
+ EPRINTK("%s(): icp_ocfDrvDsaVerify "
+ "failed (%d).\n", __FUNCTION__, lacStatus);
+ krp->krp_status = ECANCELED;
+ return ECANCELED;
+ }
+
+ break;
+
+ default:
+ EPRINTK("%s(): Asymettric function not "
+ "supported (%d).\n", __FUNCTION__, krp->krp_op);
+ krp->krp_status = EOPNOTSUPP;
+ return EOPNOTSUPP;
+ }
+
+ return ICP_OCF_DRV_STATUS_SUCCESS;
+}
+
+/* Name : icp_ocfDrvSwapBytes
+ *
+ * Description : This function is used to swap the byte order of a buffer.
+ * It has been seen that in general we are passed little endian byte order
+ * buffers, but LAC only accepts big endian byte order buffers.
+ */
+static void inline icp_ocfDrvSwapBytes(u_int8_t * num, u_int32_t buff_len_bytes)
+{
+
+ int i;
+ u_int8_t *end_ptr;
+ u_int8_t hold_val;
+
+ end_ptr = num + (buff_len_bytes - 1);
+ buff_len_bytes = buff_len_bytes >> 1;
+ for (i = 0; i < buff_len_bytes; i++) {
+ hold_val = *num;
+ *num = *end_ptr;
+ num++;
+ *end_ptr = hold_val;
+ end_ptr--;
+ }
+}
+
+/* Name : icp_ocfDrvDHComputeKey
+ *
+ * Description : This function will map Diffie Hellman calls from OCF
+ * to the LAC API. OCF uses this function for Diffie Hellman Phase1 and
+ * Phase2. LAC has a separate Diffie Hellman Phase2 call, however both phases
+ * break down to a modular exponentiation.
+ */
+static int icp_ocfDrvDHComputeKey(struct cryptkop *krp)
+{
+ CpaStatus lacStatus = CPA_STATUS_SUCCESS;
+ void *callbackTag = NULL;
+ CpaCyDhPhase1KeyGenOpData *pPhase1OpData = NULL;
+ CpaFlatBuffer *pLocalOctetStringPV = NULL;
+ uint32_t dh_prime_len_bytes = 0, dh_prime_len_bits = 0;
+
+ /* Input checks - check prime is a multiple of 8 bits to allow for
+ allocation later */
+ dh_prime_len_bits =
+ (krp->krp_param[ICP_DH_KRP_PARAM_PRIME_INDEX].crp_nbits);
+
+ /* LAC can reject prime lengths based on prime key sizes, we just
+ need to make sure we can allocate space for the base and
+ exponent buffers correctly */
+ if ((dh_prime_len_bits % NUM_BITS_IN_BYTE) != 0) {
+ APRINTK("%s(): Warning Prime number buffer size is not a "
+ "multiple of 8 bits\n", __FUNCTION__);
+ }
+
+ /* Result storage space should be the same size as the prime as this
+ value can take up the same amount of storage space */
+ if (dh_prime_len_bits !=
+ krp->krp_param[ICP_DH_KRP_PARAM_RESULT_INDEX].crp_nbits) {
+ DPRINTK("%s(): Return Buffer must be the same size "
+ "as the Prime buffer\n", __FUNCTION__);
+ krp->krp_status = EINVAL;
+ return EINVAL;
+ }
+ /* Switch to size in bytes */
+ BITS_TO_BYTES(dh_prime_len_bytes, dh_prime_len_bits);
+
+ callbackTag = krp;
+
+/*All allocations are set to ICP_M_NOWAIT due to the possibility of getting
+called in interrupt context*/
+ pPhase1OpData = icp_kmem_cache_zalloc(drvDH_zone, ICP_M_NOWAIT);
+ if (NULL == pPhase1OpData) {
+ APRINTK("%s():Failed to get memory for key gen data\n",
+ __FUNCTION__);
+ krp->krp_status = ENOMEM;
+ return ENOMEM;
+ }
+
+ pLocalOctetStringPV =
+ icp_kmem_cache_zalloc(drvFlatBuffer_zone, ICP_M_NOWAIT);
+ if (NULL == pLocalOctetStringPV) {
+ APRINTK("%s():Failed to get memory for pLocalOctetStringPV\n",
+ __FUNCTION__);
+ ICP_CACHE_FREE(drvDH_zone, pPhase1OpData);
+ krp->krp_status = ENOMEM;
+ return ENOMEM;
+ }
+
+ /* Link parameters */
+ pPhase1OpData->primeP.pData =
+ krp->krp_param[ICP_DH_KRP_PARAM_PRIME_INDEX].crp_p;
+
+ pPhase1OpData->primeP.dataLenInBytes = dh_prime_len_bytes;
+
+ icp_ocfDrvSwapBytes(pPhase1OpData->primeP.pData, dh_prime_len_bytes);
+
+ pPhase1OpData->baseG.pData =
+ krp->krp_param[ICP_DH_KRP_PARAM_BASE_INDEX].crp_p;
+
+ BITS_TO_BYTES(pPhase1OpData->baseG.dataLenInBytes,
+ krp->krp_param[ICP_DH_KRP_PARAM_BASE_INDEX].crp_nbits);
+
+ icp_ocfDrvSwapBytes(pPhase1OpData->baseG.pData,
+ pPhase1OpData->baseG.dataLenInBytes);
+
+ pPhase1OpData->privateValueX.pData =
+ krp->krp_param[ICP_DH_KRP_PARAM_PRIVATE_VALUE_INDEX].crp_p;
+
+ BITS_TO_BYTES(pPhase1OpData->privateValueX.dataLenInBytes,
+ krp->krp_param[ICP_DH_KRP_PARAM_PRIVATE_VALUE_INDEX].
+ crp_nbits);
+
+ icp_ocfDrvSwapBytes(pPhase1OpData->privateValueX.pData,
+ pPhase1OpData->privateValueX.dataLenInBytes);
+
+ /* Output parameters */
+ pLocalOctetStringPV->pData =
+ krp->krp_param[ICP_DH_KRP_PARAM_RESULT_INDEX].crp_p;
+
+ BITS_TO_BYTES(pLocalOctetStringPV->dataLenInBytes,
+ krp->krp_param[ICP_DH_KRP_PARAM_RESULT_INDEX].crp_nbits);
+
+ lacStatus = cpaCyDhKeyGenPhase1(CPA_INSTANCE_HANDLE_SINGLE,
+ icp_ocfDrvDhP1CallBack,
+ callbackTag, pPhase1OpData,
+ pLocalOctetStringPV);
+
+ if (CPA_STATUS_SUCCESS != lacStatus) {
+ EPRINTK("%s(): DH Phase 1 Key Gen failed (%d).\n",
+ __FUNCTION__, lacStatus);
+ icp_ocfDrvFreeFlatBuffer(pLocalOctetStringPV);
+ ICP_CACHE_FREE(drvDH_zone, pPhase1OpData);
+ }
+
+ return lacStatus;
+}
+
+/* Name : icp_ocfDrvModExp
+ *
+ * Description : This function will map ordinary Modular Exponentiation calls
+ * from OCF to the LAC API.
+ *
+ */
+static int icp_ocfDrvModExp(struct cryptkop *krp)
+{
+ CpaStatus lacStatus = CPA_STATUS_SUCCESS;
+ void *callbackTag = NULL;
+ CpaCyLnModExpOpData *pModExpOpData = NULL;
+ CpaFlatBuffer *pResult = NULL;
+
+ if ((krp->krp_param[ICP_MOD_EXP_KRP_PARAM_MODULUS_INDEX].crp_nbits %
+ NUM_BITS_IN_BYTE) != 0) {
+ DPRINTK("%s(): Warning - modulus buffer size (%d) is not a "
+ "multiple of 8 bits\n", __FUNCTION__,
+ krp->krp_param[ICP_MOD_EXP_KRP_PARAM_MODULUS_INDEX].
+ crp_nbits);
+ }
+
+ /* Result storage space should be the same size as the prime as this
+ value can take up the same amount of storage space */
+ if (krp->krp_param[ICP_MOD_EXP_KRP_PARAM_MODULUS_INDEX].crp_nbits >
+ krp->krp_param[ICP_MOD_EXP_KRP_PARAM_RESULT_INDEX].crp_nbits) {
+ APRINTK("%s(): Return Buffer size must be the same or"
+ " greater than the Modulus buffer\n", __FUNCTION__);
+ krp->krp_status = EINVAL;
+ return EINVAL;
+ }
+
+ callbackTag = krp;
+
+ pModExpOpData = icp_kmem_cache_zalloc(drvLnModExp_zone, ICP_M_NOWAIT);
+ if (NULL == pModExpOpData) {
+ APRINTK("%s():Failed to get memory for key gen data\n",
+ __FUNCTION__);
+ krp->krp_status = ENOMEM;
+ return ENOMEM;
+ }
+
+ pResult = icp_kmem_cache_zalloc(drvFlatBuffer_zone, ICP_M_NOWAIT);
+ if (NULL == pResult) {
+ APRINTK("%s():Failed to get memory for ModExp result\n",
+ __FUNCTION__);
+ ICP_CACHE_FREE(drvLnModExp_zone, pModExpOpData);
+ krp->krp_status = ENOMEM;
+ return ENOMEM;
+ }
+
+ /* Link parameters */
+ pModExpOpData->modulus.pData =
+ krp->krp_param[ICP_MOD_EXP_KRP_PARAM_MODULUS_INDEX].crp_p;
+ BITS_TO_BYTES(pModExpOpData->modulus.dataLenInBytes,
+ krp->krp_param[ICP_MOD_EXP_KRP_PARAM_MODULUS_INDEX].
+ crp_nbits);
+
+ icp_ocfDrvSwapBytes(pModExpOpData->modulus.pData,
+ pModExpOpData->modulus.dataLenInBytes);
+
+ DPRINTK("%s : base (%d)\n", __FUNCTION__, krp->
+ krp_param[ICP_MOD_EXP_KRP_PARAM_BASE_INDEX].crp_nbits);
+ pModExpOpData->base.pData =
+ krp->krp_param[ICP_MOD_EXP_KRP_PARAM_BASE_INDEX].crp_p;
+ BITS_TO_BYTES(pModExpOpData->base.dataLenInBytes,
+ krp->krp_param[ICP_MOD_EXP_KRP_PARAM_BASE_INDEX].
+ crp_nbits);
+ icp_ocfDrvSwapBytes(pModExpOpData->base.pData,
+ pModExpOpData->base.dataLenInBytes);
+
+ pModExpOpData->exponent.pData =
+ krp->krp_param[ICP_MOD_EXP_KRP_PARAM_EXPONENT_INDEX].crp_p;
+ BITS_TO_BYTES(pModExpOpData->exponent.dataLenInBytes,
+ krp->krp_param[ICP_MOD_EXP_KRP_PARAM_EXPONENT_INDEX].
+ crp_nbits);
+
+ icp_ocfDrvSwapBytes(pModExpOpData->exponent.pData,
+ pModExpOpData->exponent.dataLenInBytes);
+ /* Output parameters */
+ pResult->pData =
+ krp->krp_param[ICP_MOD_EXP_KRP_PARAM_RESULT_INDEX].crp_p,
+ BITS_TO_BYTES(pResult->dataLenInBytes,
+ krp->krp_param[ICP_MOD_EXP_KRP_PARAM_RESULT_INDEX].
+ crp_nbits);
+
+ lacStatus = cpaCyLnModExp(CPA_INSTANCE_HANDLE_SINGLE,
+ icp_ocfDrvModExpCallBack,
+ callbackTag, pModExpOpData, pResult);
+
+ if (CPA_STATUS_SUCCESS != lacStatus) {
+ EPRINTK("%s(): Mod Exp Operation failed (%d).\n",
+ __FUNCTION__, lacStatus);
+ krp->krp_status = ECANCELED;
+ icp_ocfDrvFreeFlatBuffer(pResult);
+ ICP_CACHE_FREE(drvLnModExp_zone, pModExpOpData);
+ }
+
+ return lacStatus;
+}
+
+/* Name : icp_ocfDrvModExpCRT
+ *
+ * Description : This function will map ordinary Modular Exponentiation Chinese
+ * Remainder Theorem implementaion calls from OCF to the LAC API.
+ *
+ * Note : Mod Exp CRT for this driver is accelerated through LAC RSA type 2
+ * decrypt operation. Therefore P and Q input values must always be prime
+ * numbers. Although basic primality checks are done in LAC, it is up to the
+ * user to do any correct prime number checking before passing the inputs.
+ */
+static int icp_ocfDrvModExpCRT(struct cryptkop *krp)
+{
+ CpaStatus lacStatus = CPA_STATUS_SUCCESS;
+ CpaCyRsaDecryptOpData *rsaDecryptOpData = NULL;
+ void *callbackTag = NULL;
+ CpaFlatBuffer *pOutputData = NULL;
+
+ /*Parameter input checks are all done by LAC, no need to repeat
+ them here. */
+ callbackTag = krp;
+
+ rsaDecryptOpData =
+ icp_kmem_cache_zalloc(drvRSADecrypt_zone, ICP_M_NOWAIT);
+ if (NULL == rsaDecryptOpData) {
+ APRINTK("%s():Failed to get memory"
+ " for MOD EXP CRT Op data struct\n", __FUNCTION__);
+ krp->krp_status = ENOMEM;
+ return ENOMEM;
+ }
+
+ rsaDecryptOpData->pRecipientPrivateKey
+ = icp_kmem_cache_zalloc(drvRSAPrivateKey_zone, ICP_M_NOWAIT);
+ if (NULL == rsaDecryptOpData->pRecipientPrivateKey) {
+ APRINTK("%s():Failed to get memory for MOD EXP CRT"
+ " private key values struct\n", __FUNCTION__);
+ ICP_CACHE_FREE(drvRSADecrypt_zone, rsaDecryptOpData);
+ krp->krp_status = ENOMEM;
+ return ENOMEM;
+ }
+
+ rsaDecryptOpData->pRecipientPrivateKey->
+ version = CPA_CY_RSA_VERSION_TWO_PRIME;
+ rsaDecryptOpData->pRecipientPrivateKey->
+ privateKeyRepType = CPA_CY_RSA_PRIVATE_KEY_REP_TYPE_2;
+
+ pOutputData = icp_kmem_cache_zalloc(drvFlatBuffer_zone, ICP_M_NOWAIT);
+ if (NULL == pOutputData) {
+ APRINTK("%s():Failed to get memory"
+ " for MOD EXP CRT output data\n", __FUNCTION__);
+ ICP_CACHE_FREE(drvRSAPrivateKey_zone,
+ rsaDecryptOpData->pRecipientPrivateKey);
+ ICP_CACHE_FREE(drvRSADecrypt_zone, rsaDecryptOpData);
+ krp->krp_status = ENOMEM;
+ return ENOMEM;
+ }
+
+ rsaDecryptOpData->pRecipientPrivateKey->
+ version = CPA_CY_RSA_VERSION_TWO_PRIME;
+ rsaDecryptOpData->pRecipientPrivateKey->
+ privateKeyRepType = CPA_CY_RSA_PRIVATE_KEY_REP_TYPE_2;
+
+ /* Link parameters */
+ rsaDecryptOpData->inputData.pData =
+ krp->krp_param[ICP_MOD_EXP_CRT_KRP_PARAM_I_INDEX].crp_p;
+ BITS_TO_BYTES(rsaDecryptOpData->inputData.dataLenInBytes,
+ krp->krp_param[ICP_MOD_EXP_CRT_KRP_PARAM_I_INDEX].
+ crp_nbits);
+
+ icp_ocfDrvSwapBytes(rsaDecryptOpData->inputData.pData,
+ rsaDecryptOpData->inputData.dataLenInBytes);
+
+ rsaDecryptOpData->pRecipientPrivateKey->privateKeyRep2.prime1P.pData =
+ krp->krp_param[ICP_MOD_EXP_CRT_KRP_PARAM_PRIME_P_INDEX].crp_p;
+ BITS_TO_BYTES(rsaDecryptOpData->pRecipientPrivateKey->privateKeyRep2.
+ prime1P.dataLenInBytes,
+ krp->krp_param[ICP_MOD_EXP_CRT_KRP_PARAM_PRIME_P_INDEX].
+ crp_nbits);
+
+ icp_ocfDrvSwapBytes(rsaDecryptOpData->pRecipientPrivateKey->
+ privateKeyRep2.prime1P.pData,
+ rsaDecryptOpData->pRecipientPrivateKey->
+ privateKeyRep2.prime1P.dataLenInBytes);
+
+ rsaDecryptOpData->pRecipientPrivateKey->privateKeyRep2.prime2Q.pData =
+ krp->krp_param[ICP_MOD_EXP_CRT_KRP_PARAM_PRIME_Q_INDEX].crp_p;
+ BITS_TO_BYTES(rsaDecryptOpData->pRecipientPrivateKey->privateKeyRep2.
+ prime2Q.dataLenInBytes,
+ krp->krp_param[ICP_MOD_EXP_CRT_KRP_PARAM_PRIME_Q_INDEX].
+ crp_nbits);
+
+ icp_ocfDrvSwapBytes(rsaDecryptOpData->pRecipientPrivateKey->
+ privateKeyRep2.prime2Q.pData,
+ rsaDecryptOpData->pRecipientPrivateKey->
+ privateKeyRep2.prime2Q.dataLenInBytes);
+
+ rsaDecryptOpData->pRecipientPrivateKey->
+ privateKeyRep2.exponent1Dp.pData =
+ krp->krp_param[ICP_MOD_EXP_CRT_KRP_PARAM_EXPONENT_DP_INDEX].crp_p;
+ BITS_TO_BYTES(rsaDecryptOpData->pRecipientPrivateKey->privateKeyRep2.
+ exponent1Dp.dataLenInBytes,
+ krp->
+ krp_param[ICP_MOD_EXP_CRT_KRP_PARAM_EXPONENT_DP_INDEX].
+ crp_nbits);
+
+ icp_ocfDrvSwapBytes(rsaDecryptOpData->pRecipientPrivateKey->
+ privateKeyRep2.exponent1Dp.pData,
+ rsaDecryptOpData->pRecipientPrivateKey->
+ privateKeyRep2.exponent1Dp.dataLenInBytes);
+
+ rsaDecryptOpData->pRecipientPrivateKey->
+ privateKeyRep2.exponent2Dq.pData =
+ krp->krp_param[ICP_MOD_EXP_CRT_KRP_PARAM_EXPONENT_DQ_INDEX].crp_p;
+ BITS_TO_BYTES(rsaDecryptOpData->pRecipientPrivateKey->
+ privateKeyRep2.exponent2Dq.dataLenInBytes,
+ krp->
+ krp_param[ICP_MOD_EXP_CRT_KRP_PARAM_EXPONENT_DQ_INDEX].
+ crp_nbits);
+
+ icp_ocfDrvSwapBytes(rsaDecryptOpData->pRecipientPrivateKey->
+ privateKeyRep2.exponent2Dq.pData,
+ rsaDecryptOpData->pRecipientPrivateKey->
+ privateKeyRep2.exponent2Dq.dataLenInBytes);
+
+ rsaDecryptOpData->pRecipientPrivateKey->
+ privateKeyRep2.coefficientQInv.pData =
+ krp->krp_param[ICP_MOD_EXP_CRT_KRP_PARAM_COEFF_QINV_INDEX].crp_p;
+ BITS_TO_BYTES(rsaDecryptOpData->pRecipientPrivateKey->
+ privateKeyRep2.coefficientQInv.dataLenInBytes,
+ krp->
+ krp_param[ICP_MOD_EXP_CRT_KRP_PARAM_COEFF_QINV_INDEX].
+ crp_nbits);
+
+ icp_ocfDrvSwapBytes(rsaDecryptOpData->pRecipientPrivateKey->
+ privateKeyRep2.coefficientQInv.pData,
+ rsaDecryptOpData->pRecipientPrivateKey->
+ privateKeyRep2.coefficientQInv.dataLenInBytes);
+
+ /* Output Parameter */
+ pOutputData->pData =
+ krp->krp_param[ICP_MOD_EXP_CRT_KRP_PARAM_RESULT_INDEX].crp_p;
+ BITS_TO_BYTES(pOutputData->dataLenInBytes,
+ krp->krp_param[ICP_MOD_EXP_CRT_KRP_PARAM_RESULT_INDEX].
+ crp_nbits);
+
+ lacStatus = cpaCyRsaDecrypt(CPA_INSTANCE_HANDLE_SINGLE,
+ icp_ocfDrvModExpCRTCallBack,
+ callbackTag, rsaDecryptOpData, pOutputData);
+
+ if (CPA_STATUS_SUCCESS != lacStatus) {
+ EPRINTK("%s(): Mod Exp CRT Operation failed (%d).\n",
+ __FUNCTION__, lacStatus);
+ krp->krp_status = ECANCELED;
+ icp_ocfDrvFreeFlatBuffer(pOutputData);
+ ICP_CACHE_FREE(drvRSAPrivateKey_zone,
+ rsaDecryptOpData->pRecipientPrivateKey);
+ ICP_CACHE_FREE(drvRSADecrypt_zone, rsaDecryptOpData);
+ }
+
+ return lacStatus;
+}
+
+/* Name : icp_ocfDrvCheckALessThanB
+ *
+ * Description : This function will check whether the first argument is less
+ * than the second. It is used to check whether the DSA RS sign Random K
+ * value is less than the Prime Q value (as defined in the specification)
+ *
+ */
+static int
+icp_ocfDrvCheckALessThanB(CpaFlatBuffer * pK, CpaFlatBuffer * pQ, int *doCheck)
+{
+
+ uint8_t *MSB_K = pK->pData;
+ uint8_t *MSB_Q = pQ->pData;
+ uint32_t buffer_lengths_in_bytes = pQ->dataLenInBytes;
+
+ if (DONT_RUN_LESS_THAN_CHECK == *doCheck) {
+ return FAIL_A_IS_GREATER_THAN_B;
+ }
+
+/*Check MSBs
+if A == B, check next MSB
+if A > B, return A_IS_GREATER_THAN_B
+if A < B, return A_IS_LESS_THAN_B (success)
+*/
+ while (*MSB_K == *MSB_Q) {
+ MSB_K++;
+ MSB_Q++;
+
+ buffer_lengths_in_bytes--;
+ if (0 == buffer_lengths_in_bytes) {
+ DPRINTK("%s() Buffers have equal value!!\n",
+ __FUNCTION__);
+ return FAIL_A_IS_EQUAL_TO_B;
+ }
+
+ }
+
+ if (*MSB_K < *MSB_Q) {
+ return SUCCESS_A_IS_LESS_THAN_B;
+ } else {
+ return FAIL_A_IS_GREATER_THAN_B;
+ }
+
+}
+
+/* Name : icp_ocfDrvDsaSign
+ *
+ * Description : This function will map DSA RS Sign from OCF to the LAC API.
+ *
+ * NOTE: From looking at OCF patch to OpenSSL and even the number of input
+ * parameters, OCF expects us to generate the random seed value. This value
+ * is generated and passed to LAC, however the number is discared in the
+ * callback and not returned to the user.
+ */
+static int icp_ocfDrvDsaSign(struct cryptkop *krp)
+{
+ CpaStatus lacStatus = CPA_STATUS_SUCCESS;
+ CpaCyDsaRSSignOpData *dsaRsSignOpData = NULL;
+ void *callbackTag = NULL;
+ CpaCyRandGenOpData randGenOpData;
+ int primeQSizeInBytes = 0;
+ int doCheck = 0;
+ CpaFlatBuffer randData;
+ CpaBoolean protocolStatus = CPA_FALSE;
+ CpaFlatBuffer *pR = NULL;
+ CpaFlatBuffer *pS = NULL;
+
+ callbackTag = krp;
+
+ BITS_TO_BYTES(primeQSizeInBytes,
+ krp->krp_param[ICP_DSA_SIGN_KRP_PARAM_PRIME_Q_INDEX].
+ crp_nbits);
+
+ if (DSA_RS_SIGN_PRIMEQ_SIZE_IN_BYTES != primeQSizeInBytes) {
+ APRINTK("%s(): DSA PRIME Q size not equal to the "
+ "FIPS defined 20bytes, = %d\n",
+ __FUNCTION__, primeQSizeInBytes);
+ krp->krp_status = EDOM;
+ return EDOM;
+ }
+
+ dsaRsSignOpData =
+ icp_kmem_cache_zalloc(drvDSARSSign_zone, ICP_M_NOWAIT);
+ if (NULL == dsaRsSignOpData) {
+ APRINTK("%s():Failed to get memory"
+ " for DSA RS Sign Op data struct\n", __FUNCTION__);
+ krp->krp_status = ENOMEM;
+ return ENOMEM;
+ }
+
+ dsaRsSignOpData->K.pData =
+ icp_kmem_cache_alloc(drvDSARSSignKValue_zone, ICP_M_NOWAIT);
+
+ if (NULL == dsaRsSignOpData->K.pData) {
+ APRINTK("%s():Failed to get memory"
+ " for DSA RS Sign Op Random value\n", __FUNCTION__);
+ ICP_CACHE_FREE(drvDSARSSign_zone, dsaRsSignOpData);
+ krp->krp_status = ENOMEM;
+ return ENOMEM;
+ }
+
+ pR = icp_kmem_cache_zalloc(drvFlatBuffer_zone, ICP_M_NOWAIT);
+ if (NULL == pR) {
+ APRINTK("%s():Failed to get memory"
+ " for DSA signature R\n", __FUNCTION__);
+ ICP_CACHE_FREE(drvDSARSSignKValue_zone,
+ dsaRsSignOpData->K.pData);
+ ICP_CACHE_FREE(drvDSARSSign_zone, dsaRsSignOpData);
+ krp->krp_status = ENOMEM;
+ return ENOMEM;
+ }
+
+ pS = icp_kmem_cache_zalloc(drvFlatBuffer_zone, ICP_M_NOWAIT);
+ if (NULL == pS) {
+ APRINTK("%s():Failed to get memory"
+ " for DSA signature S\n", __FUNCTION__);
+ icp_ocfDrvFreeFlatBuffer(pR);
+ ICP_CACHE_FREE(drvDSARSSignKValue_zone,
+ dsaRsSignOpData->K.pData);
+ ICP_CACHE_FREE(drvDSARSSign_zone, dsaRsSignOpData);
+ krp->krp_status = ENOMEM;
+ return ENOMEM;
+ }
+
+ /*link prime number parameter for ease of processing */
+ dsaRsSignOpData->P.pData =
+ krp->krp_param[ICP_DSA_SIGN_KRP_PARAM_PRIME_P_INDEX].crp_p;
+ BITS_TO_BYTES(dsaRsSignOpData->P.dataLenInBytes,
+ krp->krp_param[ICP_DSA_SIGN_KRP_PARAM_PRIME_P_INDEX].
+ crp_nbits);
+
+ icp_ocfDrvSwapBytes(dsaRsSignOpData->P.pData,
+ dsaRsSignOpData->P.dataLenInBytes);
+
+ dsaRsSignOpData->Q.pData =
+ krp->krp_param[ICP_DSA_SIGN_KRP_PARAM_PRIME_Q_INDEX].crp_p;
+ BITS_TO_BYTES(dsaRsSignOpData->Q.dataLenInBytes,
+ krp->krp_param[ICP_DSA_SIGN_KRP_PARAM_PRIME_Q_INDEX].
+ crp_nbits);
+
+ icp_ocfDrvSwapBytes(dsaRsSignOpData->Q.pData,
+ dsaRsSignOpData->Q.dataLenInBytes);
+
+ /*generate random number with equal buffer size to Prime value Q,
+ but value less than Q */
+ dsaRsSignOpData->K.dataLenInBytes = dsaRsSignOpData->Q.dataLenInBytes;
+
+ randGenOpData.generateBits = CPA_TRUE;
+ randGenOpData.lenInBytes = dsaRsSignOpData->K.dataLenInBytes;
+
+ icp_ocfDrvPtrAndLenToFlatBuffer(dsaRsSignOpData->K.pData,
+ dsaRsSignOpData->K.dataLenInBytes,
+ &randData);
+
+ doCheck = 0;
+ while (icp_ocfDrvCheckALessThanB(&(dsaRsSignOpData->K),
+ &(dsaRsSignOpData->Q), &doCheck)) {
+
+ if (CPA_STATUS_SUCCESS
+ != cpaCyRandGen(CPA_INSTANCE_HANDLE_SINGLE,
+ NULL, NULL, &randGenOpData, &randData)) {
+ APRINTK("%s(): ERROR - Failed to generate DSA RS Sign K"
+ "value\n", __FUNCTION__);
+ icp_ocfDrvFreeFlatBuffer(pS);
+ icp_ocfDrvFreeFlatBuffer(pR);
+ ICP_CACHE_FREE(drvDSARSSignKValue_zone,
+ dsaRsSignOpData->K.pData);
+ ICP_CACHE_FREE(drvDSARSSign_zone, dsaRsSignOpData);
+ krp->krp_status = EAGAIN;
+ return EAGAIN;
+ }
+
+ doCheck++;
+ if (DSA_SIGN_RAND_GEN_VAL_CHECK_MAX_ITERATIONS == doCheck) {
+ APRINTK("%s(): ERROR - Failed to find DSA RS Sign K "
+ "value less than Q value\n", __FUNCTION__);
+ icp_ocfDrvFreeFlatBuffer(pS);
+ icp_ocfDrvFreeFlatBuffer(pR);
+ ICP_CACHE_FREE(drvDSARSSignKValue_zone,
+ dsaRsSignOpData->K.pData);
+ ICP_CACHE_FREE(drvDSARSSign_zone, dsaRsSignOpData);
+ krp->krp_status = EAGAIN;
+ return EAGAIN;
+ }
+
+ }
+ /*Rand Data - no need to swap bytes for pK */
+
+ /* Link parameters */
+ dsaRsSignOpData->G.pData =
+ krp->krp_param[ICP_DSA_SIGN_KRP_PARAM_G_INDEX].crp_p;
+ BITS_TO_BYTES(dsaRsSignOpData->G.dataLenInBytes,
+ krp->krp_param[ICP_DSA_SIGN_KRP_PARAM_G_INDEX].crp_nbits);
+
+ icp_ocfDrvSwapBytes(dsaRsSignOpData->G.pData,
+ dsaRsSignOpData->G.dataLenInBytes);
+
+ dsaRsSignOpData->X.pData =
+ krp->krp_param[ICP_DSA_SIGN_KRP_PARAM_X_INDEX].crp_p;
+ BITS_TO_BYTES(dsaRsSignOpData->X.dataLenInBytes,
+ krp->krp_param[ICP_DSA_SIGN_KRP_PARAM_X_INDEX].crp_nbits);
+ icp_ocfDrvSwapBytes(dsaRsSignOpData->X.pData,
+ dsaRsSignOpData->X.dataLenInBytes);
+
+ /*OpenSSL dgst parameter is left in big endian byte order,
+ therefore no byte swap is required */
+ dsaRsSignOpData->M.pData =
+ krp->krp_param[ICP_DSA_SIGN_KRP_PARAM_DGST_INDEX].crp_p;
+ BITS_TO_BYTES(dsaRsSignOpData->M.dataLenInBytes,
+ krp->krp_param[ICP_DSA_SIGN_KRP_PARAM_DGST_INDEX].
+ crp_nbits);
+
+ /* Output Parameters */
+ pS->pData = krp->krp_param[ICP_DSA_SIGN_KRP_PARAM_S_RESULT_INDEX].crp_p;
+ BITS_TO_BYTES(pS->dataLenInBytes,
+ krp->krp_param[ICP_DSA_SIGN_KRP_PARAM_S_RESULT_INDEX].
+ crp_nbits);
+
+ pR->pData = krp->krp_param[ICP_DSA_SIGN_KRP_PARAM_R_RESULT_INDEX].crp_p;
+ BITS_TO_BYTES(pR->dataLenInBytes,
+ krp->krp_param[ICP_DSA_SIGN_KRP_PARAM_R_RESULT_INDEX].
+ crp_nbits);
+
+ lacStatus = cpaCyDsaSignRS(CPA_INSTANCE_HANDLE_SINGLE,
+ icp_ocfDrvDsaRSSignCallBack,
+ callbackTag, dsaRsSignOpData,
+ &protocolStatus, pR, pS);
+
+ if (CPA_STATUS_SUCCESS != lacStatus) {
+ EPRINTK("%s(): DSA RS Sign Operation failed (%d).\n",
+ __FUNCTION__, lacStatus);
+ krp->krp_status = ECANCELED;
+ icp_ocfDrvFreeFlatBuffer(pS);
+ icp_ocfDrvFreeFlatBuffer(pR);
+ ICP_CACHE_FREE(drvDSARSSignKValue_zone,
+ dsaRsSignOpData->K.pData);
+ ICP_CACHE_FREE(drvDSARSSign_zone, dsaRsSignOpData);
+ }
+
+ return lacStatus;
+}
+
+/* Name : icp_ocfDrvDsaVerify
+ *
+ * Description : This function will map DSA RS Verify from OCF to the LAC API.
+ *
+ */
+static int icp_ocfDrvDsaVerify(struct cryptkop *krp)
+{
+ CpaStatus lacStatus = CPA_STATUS_SUCCESS;
+ CpaCyDsaVerifyOpData *dsaVerifyOpData = NULL;
+ void *callbackTag = NULL;
+ CpaBoolean verifyStatus = CPA_FALSE;
+
+ callbackTag = krp;
+
+ dsaVerifyOpData =
+ icp_kmem_cache_zalloc(drvDSAVerify_zone, ICP_M_NOWAIT);
+ if (NULL == dsaVerifyOpData) {
+ APRINTK("%s():Failed to get memory"
+ " for DSA Verify Op data struct\n", __FUNCTION__);
+ krp->krp_status = ENOMEM;
+ return ENOMEM;
+ }
+
+ /* Link parameters */
+ dsaVerifyOpData->P.pData =
+ krp->krp_param[ICP_DSA_VERIFY_KRP_PARAM_PRIME_P_INDEX].crp_p;
+ BITS_TO_BYTES(dsaVerifyOpData->P.dataLenInBytes,
+ krp->krp_param[ICP_DSA_VERIFY_KRP_PARAM_PRIME_P_INDEX].
+ crp_nbits);
+ icp_ocfDrvSwapBytes(dsaVerifyOpData->P.pData,
+ dsaVerifyOpData->P.dataLenInBytes);
+
+ dsaVerifyOpData->Q.pData =
+ krp->krp_param[ICP_DSA_VERIFY_KRP_PARAM_PRIME_Q_INDEX].crp_p;
+ BITS_TO_BYTES(dsaVerifyOpData->Q.dataLenInBytes,
+ krp->krp_param[ICP_DSA_VERIFY_KRP_PARAM_PRIME_Q_INDEX].
+ crp_nbits);
+ icp_ocfDrvSwapBytes(dsaVerifyOpData->Q.pData,
+ dsaVerifyOpData->Q.dataLenInBytes);
+
+ dsaVerifyOpData->G.pData =
+ krp->krp_param[ICP_DSA_VERIFY_KRP_PARAM_G_INDEX].crp_p;
+ BITS_TO_BYTES(dsaVerifyOpData->G.dataLenInBytes,
+ krp->krp_param[ICP_DSA_VERIFY_KRP_PARAM_G_INDEX].
+ crp_nbits);
+ icp_ocfDrvSwapBytes(dsaVerifyOpData->G.pData,
+ dsaVerifyOpData->G.dataLenInBytes);
+
+ dsaVerifyOpData->Y.pData =
+ krp->krp_param[ICP_DSA_VERIFY_KRP_PARAM_PUBKEY_INDEX].crp_p;
+ BITS_TO_BYTES(dsaVerifyOpData->Y.dataLenInBytes,
+ krp->krp_param[ICP_DSA_VERIFY_KRP_PARAM_PUBKEY_INDEX].
+ crp_nbits);
+ icp_ocfDrvSwapBytes(dsaVerifyOpData->Y.pData,
+ dsaVerifyOpData->Y.dataLenInBytes);
+
+ /*OpenSSL dgst parameter is left in big endian byte order,
+ therefore no byte swap is required */
+ dsaVerifyOpData->M.pData =
+ krp->krp_param[ICP_DSA_VERIFY_KRP_PARAM_DGST_INDEX].crp_p;
+ BITS_TO_BYTES(dsaVerifyOpData->M.dataLenInBytes,
+ krp->krp_param[ICP_DSA_VERIFY_KRP_PARAM_DGST_INDEX].
+ crp_nbits);
+
+ dsaVerifyOpData->R.pData =
+ krp->krp_param[ICP_DSA_VERIFY_KRP_PARAM_SIG_R_INDEX].crp_p;
+ BITS_TO_BYTES(dsaVerifyOpData->R.dataLenInBytes,
+ krp->krp_param[ICP_DSA_VERIFY_KRP_PARAM_SIG_R_INDEX].
+ crp_nbits);
+ icp_ocfDrvSwapBytes(dsaVerifyOpData->R.pData,
+ dsaVerifyOpData->R.dataLenInBytes);
+
+ dsaVerifyOpData->S.pData =
+ krp->krp_param[ICP_DSA_VERIFY_KRP_PARAM_SIG_S_INDEX].crp_p;
+ BITS_TO_BYTES(dsaVerifyOpData->S.dataLenInBytes,
+ krp->krp_param[ICP_DSA_VERIFY_KRP_PARAM_SIG_S_INDEX].
+ crp_nbits);
+ icp_ocfDrvSwapBytes(dsaVerifyOpData->S.pData,
+ dsaVerifyOpData->S.dataLenInBytes);
+
+ lacStatus = cpaCyDsaVerify(CPA_INSTANCE_HANDLE_SINGLE,
+ icp_ocfDrvDsaVerifyCallBack,
+ callbackTag, dsaVerifyOpData, &verifyStatus);
+
+ if (CPA_STATUS_SUCCESS != lacStatus) {
+ EPRINTK("%s(): DSA Verify Operation failed (%d).\n",
+ __FUNCTION__, lacStatus);
+ ICP_CACHE_FREE(drvDSAVerify_zone, dsaVerifyOpData);
+ krp->krp_status = ECANCELED;
+ }
+
+ return lacStatus;
+}
+
+/* Name : icp_ocfDrvDhP1Callback
+ *
+ * Description : When this function returns it signifies that the LAC
+ * component has completed the DH operation.
+ */
+static void
+icp_ocfDrvDhP1CallBack(void *callbackTag,
+ CpaStatus status,
+ void *pOpData, CpaFlatBuffer * pLocalOctetStringPV)
+{
+ struct cryptkop *krp = NULL;
+ CpaCyDhPhase1KeyGenOpData *pPhase1OpData = NULL;
+
+ if (NULL == callbackTag) {
+ DPRINTK("%s(): Invalid input parameters - "
+ "callbackTag data is NULL\n", __FUNCTION__);
+ return;
+ }
+ krp = (struct cryptkop *)callbackTag;
+
+ if (NULL == pOpData) {
+ DPRINTK("%s(): Invalid input parameters - "
+ "Operation Data is NULL\n", __FUNCTION__);
+ krp->krp_status = ECANCELED;
+ crypto_kdone(krp);
+ return;
+ }
+ pPhase1OpData = (CpaCyDhPhase1KeyGenOpData *) pOpData;
+
+ if (NULL == pLocalOctetStringPV) {
+ DPRINTK("%s(): Invalid input parameters - "
+ "pLocalOctetStringPV Data is NULL\n", __FUNCTION__);
+ memset(pPhase1OpData, 0, sizeof(CpaCyDhPhase1KeyGenOpData));
+ ICP_CACHE_FREE(drvDH_zone, pPhase1OpData);
+ krp->krp_status = ECANCELED;
+ crypto_kdone(krp);
+ return;
+ }
+
+ if (CPA_STATUS_SUCCESS == status) {
+ krp->krp_status = CRYPTO_OP_SUCCESS;
+ } else {
+ APRINTK("%s(): Diffie Hellman Phase1 Key Gen failed - "
+ "Operation Status = %d\n", __FUNCTION__, status);
+ krp->krp_status = ECANCELED;
+ }
+
+ icp_ocfDrvSwapBytes(pLocalOctetStringPV->pData,
+ pLocalOctetStringPV->dataLenInBytes);
+
+ icp_ocfDrvFreeFlatBuffer(pLocalOctetStringPV);
+ memset(pPhase1OpData, 0, sizeof(CpaCyDhPhase1KeyGenOpData));
+ ICP_CACHE_FREE(drvDH_zone, pPhase1OpData);
+
+ crypto_kdone(krp);
+
+ return;
+}
+
+/* Name : icp_ocfDrvModExpCallBack
+ *
+ * Description : When this function returns it signifies that the LAC
+ * component has completed the Mod Exp operation.
+ */
+static void
+icp_ocfDrvModExpCallBack(void *callbackTag,
+ CpaStatus status,
+ void *pOpdata, CpaFlatBuffer * pResult)
+{
+ struct cryptkop *krp = NULL;
+ CpaCyLnModExpOpData *pLnModExpOpData = NULL;
+
+ if (NULL == callbackTag) {
+ DPRINTK("%s(): Invalid input parameters - "
+ "callbackTag data is NULL\n", __FUNCTION__);
+ return;
+ }
+ krp = (struct cryptkop *)callbackTag;
+
+ if (NULL == pOpdata) {
+ DPRINTK("%s(): Invalid Mod Exp input parameters - "
+ "Operation Data is NULL\n", __FUNCTION__);
+ krp->krp_status = ECANCELED;
+ crypto_kdone(krp);
+ return;
+ }
+ pLnModExpOpData = (CpaCyLnModExpOpData *) pOpdata;
+
+ if (NULL == pResult) {
+ DPRINTK("%s(): Invalid input parameters - "
+ "pResult data is NULL\n", __FUNCTION__);
+ krp->krp_status = ECANCELED;
+ memset(pLnModExpOpData, 0, sizeof(CpaCyLnModExpOpData));
+ ICP_CACHE_FREE(drvLnModExp_zone, pLnModExpOpData);
+ crypto_kdone(krp);
+ return;
+ }
+
+ if (CPA_STATUS_SUCCESS == status) {
+ krp->krp_status = CRYPTO_OP_SUCCESS;
+ } else {
+ APRINTK("%s(): LAC Mod Exp Operation failed - "
+ "Operation Status = %d\n", __FUNCTION__, status);
+ krp->krp_status = ECANCELED;
+ }
+
+ icp_ocfDrvSwapBytes(pResult->pData, pResult->dataLenInBytes);
+
+ /*switch base size value back to original */
+ if (pLnModExpOpData->base.pData ==
+ (uint8_t *) & (krp->
+ krp_param[ICP_MOD_EXP_KRP_PARAM_BASE_INDEX].
+ crp_nbits)) {
+ *((uint32_t *) pLnModExpOpData->base.pData) =
+ ntohl(*((uint32_t *) pLnModExpOpData->base.pData));
+ }
+ icp_ocfDrvFreeFlatBuffer(pResult);
+ memset(pLnModExpOpData, 0, sizeof(CpaCyLnModExpOpData));
+ ICP_CACHE_FREE(drvLnModExp_zone, pLnModExpOpData);
+
+ crypto_kdone(krp);
+
+ return;
+
+}
+
+/* Name : icp_ocfDrvModExpCRTCallBack
+ *
+ * Description : When this function returns it signifies that the LAC
+ * component has completed the Mod Exp CRT operation.
+ */
+static void
+icp_ocfDrvModExpCRTCallBack(void *callbackTag,
+ CpaStatus status,
+ void *pOpData, CpaFlatBuffer * pOutputData)
+{
+ struct cryptkop *krp = NULL;
+ CpaCyRsaDecryptOpData *pDecryptData = NULL;
+
+ if (NULL == callbackTag) {
+ DPRINTK("%s(): Invalid input parameters - "
+ "callbackTag data is NULL\n", __FUNCTION__);
+ return;
+ }
+
+ krp = (struct cryptkop *)callbackTag;
+
+ if (NULL == pOpData) {
+ DPRINTK("%s(): Invalid input parameters - "
+ "Operation Data is NULL\n", __FUNCTION__);
+ krp->krp_status = ECANCELED;
+ crypto_kdone(krp);
+ return;
+ }
+ pDecryptData = (CpaCyRsaDecryptOpData *) pOpData;
+
+ if (NULL == pOutputData) {
+ DPRINTK("%s(): Invalid input parameter - "
+ "pOutputData is NULL\n", __FUNCTION__);
+ memset(pDecryptData->pRecipientPrivateKey, 0,
+ sizeof(CpaCyRsaPrivateKey));
+ ICP_CACHE_FREE(drvRSAPrivateKey_zone,
+ pDecryptData->pRecipientPrivateKey);
+ memset(pDecryptData, 0, sizeof(CpaCyRsaDecryptOpData));
+ ICP_CACHE_FREE(drvRSADecrypt_zone, pDecryptData);
+ krp->krp_status = ECANCELED;
+ crypto_kdone(krp);
+ return;
+ }
+
+ if (CPA_STATUS_SUCCESS == status) {
+ krp->krp_status = CRYPTO_OP_SUCCESS;
+ } else {
+ APRINTK("%s(): LAC Mod Exp CRT operation failed - "
+ "Operation Status = %d\n", __FUNCTION__, status);
+ krp->krp_status = ECANCELED;
+ }
+
+ icp_ocfDrvSwapBytes(pOutputData->pData, pOutputData->dataLenInBytes);
+
+ icp_ocfDrvFreeFlatBuffer(pOutputData);
+ memset(pDecryptData->pRecipientPrivateKey, 0,
+ sizeof(CpaCyRsaPrivateKey));
+ ICP_CACHE_FREE(drvRSAPrivateKey_zone,
+ pDecryptData->pRecipientPrivateKey);
+ memset(pDecryptData, 0, sizeof(CpaCyRsaDecryptOpData));
+ ICP_CACHE_FREE(drvRSADecrypt_zone, pDecryptData);
+
+ crypto_kdone(krp);
+
+ return;
+}
+
+/* Name : icp_ocfDrvDsaRSSignCallBack
+ *
+ * Description : When this function returns it signifies that the LAC
+ * component has completed the DSA RS sign operation.
+ */
+static void
+icp_ocfDrvDsaRSSignCallBack(void *callbackTag,
+ CpaStatus status,
+ void *pOpData,
+ CpaBoolean protocolStatus,
+ CpaFlatBuffer * pR, CpaFlatBuffer * pS)
+{
+ struct cryptkop *krp = NULL;
+ CpaCyDsaRSSignOpData *pSignData = NULL;
+
+ if (NULL == callbackTag) {
+ DPRINTK("%s(): Invalid input parameters - "
+ "callbackTag data is NULL\n", __FUNCTION__);
+ return;
+ }
+
+ krp = (struct cryptkop *)callbackTag;
+
+ if (NULL == pOpData) {
+ DPRINTK("%s(): Invalid input parameters - "
+ "Operation Data is NULL\n", __FUNCTION__);
+ krp->krp_status = ECANCELED;
+ crypto_kdone(krp);
+ return;
+ }
+ pSignData = (CpaCyDsaRSSignOpData *) pOpData;
+
+ if (NULL == pR) {
+ DPRINTK("%s(): Invalid input parameter - "
+ "pR sign is NULL\n", __FUNCTION__);
+ icp_ocfDrvFreeFlatBuffer(pS);
+ ICP_CACHE_FREE(drvDSARSSign_zone, pSignData);
+ krp->krp_status = ECANCELED;
+ crypto_kdone(krp);
+ return;
+ }
+
+ if (NULL == pS) {
+ DPRINTK("%s(): Invalid input parameter - "
+ "pS sign is NULL\n", __FUNCTION__);
+ icp_ocfDrvFreeFlatBuffer(pR);
+ ICP_CACHE_FREE(drvDSARSSign_zone, pSignData);
+ krp->krp_status = ECANCELED;
+ crypto_kdone(krp);
+ return;
+ }
+
+ if (CPA_STATUS_SUCCESS != status) {
+ APRINTK("%s(): LAC DSA RS Sign operation failed - "
+ "Operation Status = %d\n", __FUNCTION__, status);
+ krp->krp_status = ECANCELED;
+ } else {
+ krp->krp_status = CRYPTO_OP_SUCCESS;
+
+ if (CPA_TRUE != protocolStatus) {
+ DPRINTK("%s(): LAC DSA RS Sign operation failed due "
+ "to protocol error\n", __FUNCTION__);
+ krp->krp_status = EIO;
+ }
+ }
+
+ /* Swap bytes only when the callback status is successful and
+ protocolStatus is set to true */
+ if (CPA_STATUS_SUCCESS == status && CPA_TRUE == protocolStatus) {
+ icp_ocfDrvSwapBytes(pR->pData, pR->dataLenInBytes);
+ icp_ocfDrvSwapBytes(pS->pData, pS->dataLenInBytes);
+ }
+
+ icp_ocfDrvFreeFlatBuffer(pR);
+ icp_ocfDrvFreeFlatBuffer(pS);
+ memset(pSignData->K.pData, 0, pSignData->K.dataLenInBytes);
+ ICP_CACHE_FREE(drvDSARSSignKValue_zone, pSignData->K.pData);
+ memset(pSignData, 0, sizeof(CpaCyDsaRSSignOpData));
+ ICP_CACHE_FREE(drvDSARSSign_zone, pSignData);
+ crypto_kdone(krp);
+
+ return;
+}
+
+/* Name : icp_ocfDrvDsaVerifyCallback
+ *
+ * Description : When this function returns it signifies that the LAC
+ * component has completed the DSA Verify operation.
+ */
+static void
+icp_ocfDrvDsaVerifyCallBack(void *callbackTag,
+ CpaStatus status,
+ void *pOpData, CpaBoolean verifyStatus)
+{
+
+ struct cryptkop *krp = NULL;
+ CpaCyDsaVerifyOpData *pVerData = NULL;
+
+ if (NULL == callbackTag) {
+ DPRINTK("%s(): Invalid input parameters - "
+ "callbackTag data is NULL\n", __FUNCTION__);
+ return;
+ }
+
+ krp = (struct cryptkop *)callbackTag;
+
+ if (NULL == pOpData) {
+ DPRINTK("%s(): Invalid input parameters - "
+ "Operation Data is NULL\n", __FUNCTION__);
+ krp->krp_status = ECANCELED;
+ crypto_kdone(krp);
+ return;
+ }
+ pVerData = (CpaCyDsaVerifyOpData *) pOpData;
+
+ if (CPA_STATUS_SUCCESS != status) {
+ APRINTK("%s(): LAC DSA Verify operation failed - "
+ "Operation Status = %d\n", __FUNCTION__, status);
+ krp->krp_status = ECANCELED;
+ } else {
+ krp->krp_status = CRYPTO_OP_SUCCESS;
+
+ if (CPA_TRUE != verifyStatus) {
+ DPRINTK("%s(): DSA signature invalid\n", __FUNCTION__);
+ krp->krp_status = EIO;
+ }
+ }
+
+ /* Swap bytes only when the callback status is successful and
+ verifyStatus is set to true */
+ /*Just swapping back the key values for now. Possibly all
+ swapped buffers need to be reverted */
+ if (CPA_STATUS_SUCCESS == status && CPA_TRUE == verifyStatus) {
+ icp_ocfDrvSwapBytes(pVerData->R.pData,
+ pVerData->R.dataLenInBytes);
+ icp_ocfDrvSwapBytes(pVerData->S.pData,
+ pVerData->S.dataLenInBytes);
+ }
+
+ memset(pVerData, 0, sizeof(CpaCyDsaVerifyOpData));
+ ICP_CACHE_FREE(drvDSAVerify_zone, pVerData);
+ crypto_kdone(krp);
+
+ return;
+}