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- /*
- * Copyright (C) 2011-2016 Intel Corporation. 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.
- *
- */
- /*
- * Do NOT use this library in your actual product.
- * The purpose of this sample library is to aid the debugging of a
- * remote attestation service.
- * To achieve that goal, the sample remote attestation application
- * will use this sample library to generate reproducible messages.
- * If you have still not decided on whether you should use this library in a
- * released product, please refer to the implementation of __do_get_rand32.
- **/
- #include <string.h>
- #include <stdlib.h>
- #include <stdint.h>
- #include "ippcp.h"
- #include "sgx_memset_s.h"
- #include "se_memcpy.h"
- #include "sample_libcrypto.h"
- #include <errno.h>
- #ifdef __linux__
- /*
- * __memset_vp is a volatile pointer to a function.
- * It is initialised to point to memset, and should never be changed.
- */
- static void * (* const volatile __memset_vp)(void *, int, size_t)
- = (memset);
- #undef memset_s /* in case it was defined as a macro */
- extern "C" int memset_s(void *s, size_t smax, int c, size_t n)
- {
- int err = 0;
- if (s == NULL) {
- err = EINVAL;
- goto out;
- }
- if (n > smax) {
- err = EOVERFLOW;
- n = smax;
- }
- /* Calling through a volatile pointer should never be optimised away. */
- (*__memset_vp)(s, c, n);
- out:
- if (err == 0)
- return 0;
- else {
- errno = err;
- /* XXX call runtime-constraint handler */
- return err;
- }
- }
- #endif
- #ifndef ERROR_BREAK
- #define ERROR_BREAK(x) if(x){break;}
- #endif
- #ifndef SAFE_FREE
- #define SAFE_FREE(ptr) {if (NULL != (ptr)) {free(ptr); (ptr) = NULL;}}
- #endif
- #ifndef ROUND_TO
- #define ROUND_TO(x, align) (((x) + (align-1)) & ~(align-1))
- #endif
- #ifndef UNUSED
- #define UNUSED(val) (void)(val)
- #endif
- static uint32_t seed = (uint32_t)(9);
- // We are using this very non-random definition for reproducibility / debugging purposes.
- static inline sample_status_t __do_get_rand32(uint32_t* rand_num)
- {
- *rand_num = seed;
- return SAMPLE_SUCCESS;
- }
- static inline IppStatus check_copy_size(size_t target_size, size_t source_size)
- {
- if(target_size < source_size)
- return ippStsSizeErr;
- return ippStsNoErr;
- }
- /* The function should generate a random number properly, and the pseudo-rand
- implementation is only for demo purpose. */
- sample_status_t sample_read_rand(unsigned char *rand, size_t length_in_bytes)
- {
- // check parameters
- if(!rand || !length_in_bytes)
- {
- return SAMPLE_ERROR_INVALID_PARAMETER;
- }
- // loop to rdrand
- while(length_in_bytes > 0)
- {
- uint32_t rand_num = 0;
- sample_status_t status = __do_get_rand32(&rand_num);
- if(status != SAMPLE_SUCCESS)
- {
- return status;
- }
- size_t size = (length_in_bytes < sizeof(rand_num))
- ? length_in_bytes : sizeof(rand_num);
- if(memcpy_s(rand, size, &rand_num, size))
- {
- return status;
- }
- rand += size;
- length_in_bytes -= size;
- }
- return SAMPLE_SUCCESS;
- }
- static IppStatus sgx_ipp_newBN(const Ipp32u *p_data, int size_in_bytes, IppsBigNumState **p_new_BN)
- {
- IppsBigNumState *pBN=0;
- int bn_size = 0;
- if(p_new_BN == NULL || (size_in_bytes <= 0) || ((size_in_bytes % sizeof(Ipp32u)) != 0))
- return ippStsBadArgErr;
- // Get the size of the IppsBigNumState context in bytes
- IppStatus error_code = ippsBigNumGetSize(size_in_bytes/(int)sizeof(Ipp32u), &bn_size);
- if(error_code != ippStsNoErr)
- {
- *p_new_BN = 0;
- return error_code;
- }
- pBN = (IppsBigNumState *) malloc(bn_size);
- if(!pBN)
- {
- error_code = ippStsMemAllocErr;
- *p_new_BN = 0;
- return error_code;
- }
- // Initialize context and partition allocated buffer
- error_code = ippsBigNumInit(size_in_bytes/(int)sizeof(Ipp32u), pBN);
- if(error_code != ippStsNoErr)
- {
- free(pBN);
- *p_new_BN = 0;
- return error_code;
- }
- if(p_data)
- {
- error_code = ippsSet_BN(IppsBigNumPOS, size_in_bytes/(int)sizeof(Ipp32u), p_data, pBN);
- if(error_code != ippStsNoErr)
- {
- *p_new_BN = 0;
- free(pBN);
- return error_code;
- }
- }
- *p_new_BN = pBN;
- return error_code;
- }
- static void sample_ipp_secure_free_BN(IppsBigNumState *pBN, int size_in_bytes)
- {
- if(pBN == NULL || size_in_bytes <= 0 || size_in_bytes/sizeof(Ipp32u) <= 0)
- {
- if(pBN)
- {
- free(pBN);
- }
- return;
- }
- int bn_size = 0;
- // Get the size of the IppsBigNumState context in bytes
- // Since we have checked the size_in_bytes before and the &bn_size is not NULL, ippsBigNumGetSize never returns failure
- ippsBigNumGetSize(size_in_bytes/(int)sizeof(Ipp32u), &bn_size);
- if (bn_size <= 0)
- {
- free(pBN);
- return;
- }
- // Clear the buffer before free.
- memset_s(pBN, bn_size, 0, bn_size);
- free(pBN);
- return;
- }
- IppStatus __STDCALL sample_ipp_DRNGen(Ipp32u* pRandBNU, int nBits, void* pCtx_unused)
- {
- sample_status_t sample_ret;
- UNUSED(pCtx_unused);
- if(0 != nBits%8)
- {
- // Must be byte aligned
- return ippStsSizeErr;
- }
- if(!pRandBNU)
- {
- return ippStsNullPtrErr;
- }
- sample_ret = sample_read_rand((uint8_t*)pRandBNU, (uint32_t)nBits/8);
- if(SAMPLE_SUCCESS != sample_ret)
- {
- return ippStsErr;
- }
- return ippStsNoErr;
- }
- /* Rijndael AES-GCM
- * Parameters:
- * Return: sample_status_t - SAMPLE_SUCCESS on success, error code otherwise.
- * Inputs: sample_aes_gcm_128bit_key_t *p_key - Pointer to key used in encryption/decryption operation
- * uint8_t *p_src - Pointer to input stream to be encrypted/decrypted
- * uint32_t src_len - Length of input stream to be encrypted/decrypted
- * uint8_t *p_iv - Pointer to initialization vector to use
- * uint32_t iv_len - Length of initialization vector
- * uint8_t *p_aad - Pointer to input stream of additional authentication data
- * uint32_t aad_len - Length of additional authentication data stream
- * sample_aes_gcm_128bit_tag_t *p_in_mac - Pointer to expected MAC in decryption process
- * Output: uint8_t *p_dst - Pointer to cipher text. Size of buffer should be >= src_len.
- * sample_aes_gcm_128bit_tag_t *p_out_mac - Pointer to MAC generated from encryption process
- * NOTE: Wrapper is responsible for confirming decryption tag matches encryption tag */
- sample_status_t sample_rijndael128GCM_encrypt(const sample_aes_gcm_128bit_key_t *p_key, const uint8_t *p_src, uint32_t src_len,
- uint8_t *p_dst, const uint8_t *p_iv, uint32_t iv_len, const uint8_t *p_aad, uint32_t aad_len,
- sample_aes_gcm_128bit_tag_t *p_out_mac)
- {
- IppStatus error_code = ippStsNoErr;
- IppsAES_GCMState* pState = NULL;
- int ippStateSize = 0;
- if ((p_key == NULL) || ((src_len > 0) && (p_dst == NULL)) || ((src_len > 0) && (p_src == NULL))
- || (p_out_mac == NULL) || (iv_len != SAMPLE_AESGCM_IV_SIZE) || ((aad_len > 0) && (p_aad == NULL))
- || (p_iv == NULL) || ((p_src == NULL) && (p_aad == NULL)))
- {
- return SAMPLE_ERROR_INVALID_PARAMETER;
- }
- error_code = ippsAES_GCMGetSize(&ippStateSize);
- if (error_code != ippStsNoErr)
- {
- return SAMPLE_ERROR_UNEXPECTED;
- }
- pState = (IppsAES_GCMState*)malloc(ippStateSize);
- if(pState == NULL)
- {
- return SAMPLE_ERROR_OUT_OF_MEMORY;
- }
- error_code = ippsAES_GCMInit((const Ipp8u *)p_key, SAMPLE_AESGCM_KEY_SIZE, pState, ippStateSize);
- if (error_code != ippStsNoErr)
- {
- // Clear temp State before free.
- memset_s(pState, ippStateSize, 0, ippStateSize);
- free(pState);
- switch (error_code)
- {
- case ippStsMemAllocErr: return SAMPLE_ERROR_OUT_OF_MEMORY;
- case ippStsNullPtrErr:
- case ippStsLengthErr: return SAMPLE_ERROR_INVALID_PARAMETER;
- default: return SAMPLE_ERROR_UNEXPECTED;
- }
- }
- error_code = ippsAES_GCMStart(p_iv, SAMPLE_AESGCM_IV_SIZE, p_aad, aad_len, pState);
- if (error_code != ippStsNoErr)
- {
- // Clear temp State before free.
- memset_s(pState, ippStateSize, 0, ippStateSize);
- free(pState);
- switch (error_code)
- {
- case ippStsNullPtrErr:
- case ippStsLengthErr: return SAMPLE_ERROR_INVALID_PARAMETER;
- default: return SAMPLE_ERROR_UNEXPECTED;
- }
- }
- if (src_len > 0) {
- error_code = ippsAES_GCMEncrypt(p_src, p_dst, src_len, pState);
- if (error_code != ippStsNoErr)
- {
- // Clear temp State before free.
- memset_s(pState, ippStateSize, 0, ippStateSize);
- free(pState);
- switch (error_code)
- {
- case ippStsNullPtrErr: return SAMPLE_ERROR_INVALID_PARAMETER;
- default: return SAMPLE_ERROR_UNEXPECTED;
- }
- }
- }
- error_code = ippsAES_GCMGetTag((Ipp8u *)p_out_mac, SAMPLE_AESGCM_MAC_SIZE, pState);
- if (error_code != ippStsNoErr)
- {
- // Clear temp State before free.
- memset_s(pState, ippStateSize, 0, ippStateSize);
- free(pState);
- switch (error_code)
- {
- case ippStsNullPtrErr:
- case ippStsLengthErr: return SAMPLE_ERROR_INVALID_PARAMETER;
- default: return SAMPLE_ERROR_UNEXPECTED;
- }
- }
- // Clear temp State before free.
- memset_s(pState, ippStateSize, 0, ippStateSize);
- free(pState);
- return SAMPLE_SUCCESS;
- }
- /* Message Authentication - Rijndael 128 CMAC
- * Parameters:
- * Return: sample_status_t - SAMPLE_SUCCESS on success, error code otherwise.
- * Inputs: sample_cmac_128bit_key_t *p_key - Pointer to key used in encryption/decryption operation
- * uint8_t *p_src - Pointer to input stream to be MACed
- * uint32_t src_len - Length of input stream to be MACed
- * Output: sample_cmac_gcm_128bit_tag_t *p_mac - Pointer to resultant MAC */
- sample_status_t sample_rijndael128_cmac_msg(const sample_cmac_128bit_key_t *p_key, const uint8_t *p_src,
- uint32_t src_len, sample_cmac_128bit_tag_t *p_mac)
- {
- IppsAES_CMACState* pState = NULL;
- int ippStateSize = 0;
- IppStatus error_code = ippStsNoErr;
- if ((p_key == NULL) || (p_src == NULL) || (p_mac == NULL))
- {
- return SAMPLE_ERROR_INVALID_PARAMETER;
- }
- error_code = ippsAES_CMACGetSize(&ippStateSize);
- if (error_code != ippStsNoErr)
- {
- return SAMPLE_ERROR_UNEXPECTED;
- }
- pState = (IppsAES_CMACState*)malloc(ippStateSize);
- if(pState == NULL)
- {
- return SAMPLE_ERROR_OUT_OF_MEMORY;
- }
- error_code = ippsAES_CMACInit((const Ipp8u *)p_key, SAMPLE_CMAC_KEY_SIZE, pState, ippStateSize);
- if (error_code != ippStsNoErr)
- {
- // Clear temp State before free.
- memset_s(pState, ippStateSize, 0, ippStateSize);
- free(pState);
- switch (error_code)
- {
- case ippStsMemAllocErr: return SAMPLE_ERROR_OUT_OF_MEMORY;
- case ippStsNullPtrErr:
- case ippStsLengthErr: return SAMPLE_ERROR_INVALID_PARAMETER;
- default: return SAMPLE_ERROR_UNEXPECTED;
- }
- }
- error_code = ippsAES_CMACUpdate((const Ipp8u *)p_src, src_len, pState);
- if (error_code != ippStsNoErr)
- {
- // Clear temp State before free.
- memset_s(pState, ippStateSize, 0, ippStateSize);
- free(pState);
- switch (error_code)
- {
- case ippStsNullPtrErr:
- case ippStsLengthErr: return SAMPLE_ERROR_INVALID_PARAMETER;
- default: return SAMPLE_ERROR_UNEXPECTED;
- }
- }
- error_code = ippsAES_CMACFinal((Ipp8u *)p_mac, SAMPLE_CMAC_MAC_SIZE, pState);
- if (error_code != ippStsNoErr)
- {
- // Clear temp State before free.
- memset_s(pState, ippStateSize, 0, ippStateSize);
- free(pState);
- switch (error_code)
- {
- case ippStsNullPtrErr:
- case ippStsLengthErr: return SAMPLE_ERROR_INVALID_PARAMETER;
- default: return SAMPLE_ERROR_UNEXPECTED;
- }
- }
- // Clear temp State before free.
- memset_s(pState, ippStateSize, 0, ippStateSize);
- free(pState);
- return SAMPLE_SUCCESS;
- }
- extern "C" int some_function()
- {
- return 1234;
- }
- /*
- * Elliptic Curve Crytpography - Based on GF(p), 256 bit
- */
- /* Allocates and initializes ecc context
- * Parameters:
- * Return: sample_status_t - SAMPLE_SUCCESS on success, error code otherwise.
- * Output: sample_ecc_state_handle_t ecc_handle - Handle to ECC crypto system */
- sample_status_t sample_ecc256_open_context(sample_ecc_state_handle_t* ecc_handle)
- {
- IppStatus ipp_ret = ippStsNoErr;
- IppsECCPState* p_ecc_state = NULL;
- // default use 256r1 parameter
- int ctx_size = 0;
- if (ecc_handle == NULL)
- return SAMPLE_ERROR_INVALID_PARAMETER;
- ipp_ret = ippsECCPGetSize(256, &ctx_size);
- if (ipp_ret != ippStsNoErr)
- return SAMPLE_ERROR_UNEXPECTED;
- p_ecc_state = (IppsECCPState*)(malloc(ctx_size));
- if (p_ecc_state == NULL)
- return SAMPLE_ERROR_OUT_OF_MEMORY;
- ipp_ret = ippsECCPInit(256, p_ecc_state);
- if (ipp_ret != ippStsNoErr)
- {
- SAFE_FREE(p_ecc_state);
- *ecc_handle = NULL;
- return SAMPLE_ERROR_UNEXPECTED;
- }
- ipp_ret = ippsECCPSetStd(IppECCPStd256r1, p_ecc_state);
- if (ipp_ret != ippStsNoErr)
- {
- SAFE_FREE(p_ecc_state);
- *ecc_handle = NULL;
- return SAMPLE_ERROR_UNEXPECTED;
- }
- *ecc_handle = p_ecc_state;
- return SAMPLE_SUCCESS;
- }
- /* Cleans up ecc context
- * Parameters:
- * Return: sample_status_t - SAMPLE_SUCCESS on success, error code otherwise.
- * Output: sample_ecc_state_handle_t ecc_handle - Handle to ECC crypto system */
- sample_status_t sample_ecc256_close_context(sample_ecc_state_handle_t ecc_handle)
- {
- if (ecc_handle == NULL)
- {
- return SAMPLE_ERROR_INVALID_PARAMETER;
- }
- IppsECCPState* p_ecc_state = (IppsECCPState*)ecc_handle;
- int ctx_size = 0;
- IppStatus ipp_ret = ippsECCPGetSize(256, &ctx_size);
- if (ipp_ret != ippStsNoErr)
- {
- free(p_ecc_state);
- return SAMPLE_SUCCESS;
- }
- memset_s(p_ecc_state, ctx_size, 0, ctx_size);
- free(p_ecc_state);
- return SAMPLE_SUCCESS;
- }
- /* Populates private/public key pair - caller code allocates memory
- * Parameters:
- * Return: sample_status_t - SAMPLE_SUCCESS on success, error code otherwise.
- * Inputs: sample_ecc_state_handle_t ecc_handle - Handle to ECC crypto system
- * Outputs: sample_ec256_private_t *p_private - Pointer to the private key
- * sample_ec256_public_t *p_public - Pointer to the public key */
- sample_status_t sample_ecc256_create_key_pair(sample_ec256_private_t *p_private,
- sample_ec256_public_t *p_public,
- sample_ecc_state_handle_t ecc_handle)
- {
- if ((ecc_handle == NULL) || (p_private == NULL) || (p_public == NULL))
- {
- return SAMPLE_ERROR_INVALID_PARAMETER;
- }
- IppsBigNumState* dh_priv_BN = NULL;
- IppsECCPPointState* point_pub = NULL;
- IppsBigNumState* pub_gx = NULL;
- IppsBigNumState* pub_gy = NULL;
- IppStatus ipp_ret = ippStsNoErr;
- int ecPointSize = 0;
- IppsECCPState* p_ecc_state = (IppsECCPState*)ecc_handle;
- do
- {
- //init eccp point
- ipp_ret = ippsECCPPointGetSize(256, &ecPointSize);
- ERROR_BREAK(ipp_ret);
- point_pub = (IppsECCPPointState*)( malloc(ecPointSize) );
- if(!point_pub)
- {
- ipp_ret = ippStsNoMemErr;
- break;
- }
- ipp_ret = ippsECCPPointInit(256, point_pub);
- ERROR_BREAK(ipp_ret);
- ipp_ret = sgx_ipp_newBN(NULL, SAMPLE_ECP256_KEY_SIZE, &dh_priv_BN);
- ERROR_BREAK(ipp_ret);
- // Use the true random number (DRNG)
- ipp_ret = ippsECCPGenKeyPair(dh_priv_BN, point_pub, p_ecc_state, (IppBitSupplier)sample_ipp_DRNGen, NULL);
- ERROR_BREAK(ipp_ret);
- //convert point_result to oct string
- ipp_ret = sgx_ipp_newBN(NULL, SAMPLE_ECP256_KEY_SIZE, &pub_gx);
- ERROR_BREAK(ipp_ret);
- ipp_ret = sgx_ipp_newBN(NULL, SAMPLE_ECP256_KEY_SIZE, &pub_gy);
- ERROR_BREAK(ipp_ret);
- ipp_ret = ippsECCPGetPoint(pub_gx, pub_gy, point_pub, p_ecc_state);
- ERROR_BREAK(ipp_ret);
- IppsBigNumSGN sgn = IppsBigNumPOS;
- Ipp32u *pdata = NULL;
- // ippsRef_BN is in bits not bytes (versus old ippsGet_BN)
- int length = 0;
- ipp_ret = ippsRef_BN(&sgn, &length, &pdata, pub_gx);
- ERROR_BREAK(ipp_ret);
- memset(p_public->gx, 0, sizeof(p_public->gx));
- ipp_ret = check_copy_size(sizeof(p_public->gx), ROUND_TO(length, 8)/8);
- ERROR_BREAK(ipp_ret);
- memcpy(p_public->gx, pdata, ROUND_TO(length, 8)/8);
- ipp_ret = ippsRef_BN(&sgn, &length, &pdata, pub_gy);
- ERROR_BREAK(ipp_ret);
- memset(p_public->gy, 0, sizeof(p_public->gy));
- ipp_ret = check_copy_size(sizeof(p_public->gy), ROUND_TO(length, 8)/8);
- ERROR_BREAK(ipp_ret);
- memcpy(p_public->gy, pdata, ROUND_TO(length, 8)/8);
- ipp_ret = ippsRef_BN(&sgn, &length, &pdata, dh_priv_BN);
- ERROR_BREAK(ipp_ret);
- memset(p_private->r, 0, sizeof(p_private->r));
- ipp_ret = check_copy_size(sizeof(p_private->r), ROUND_TO(length, 8)/8);
- ERROR_BREAK(ipp_ret);
- memcpy(p_private->r, pdata, ROUND_TO(length, 8)/8);
- }while(0);
- //Clear temp buffer before free.
- if(point_pub) memset_s(point_pub, ecPointSize, 0, ecPointSize);
- SAFE_FREE(point_pub);
- sample_ipp_secure_free_BN(pub_gx, SAMPLE_ECP256_KEY_SIZE);
- sample_ipp_secure_free_BN(pub_gy, SAMPLE_ECP256_KEY_SIZE);
- sample_ipp_secure_free_BN(dh_priv_BN, SAMPLE_ECP256_KEY_SIZE);
- switch (ipp_ret)
- {
- case ippStsNoErr: return SAMPLE_SUCCESS;
- case ippStsNoMemErr:
- case ippStsMemAllocErr: return SAMPLE_ERROR_OUT_OF_MEMORY;
- case ippStsNullPtrErr:
- case ippStsLengthErr:
- case ippStsOutOfRangeErr:
- case ippStsSizeErr:
- case ippStsBadArgErr: return SAMPLE_ERROR_INVALID_PARAMETER;
- default: return SAMPLE_ERROR_UNEXPECTED;
- }
- }
- /* Computes DH shared key based on private B key (local) and remote public Ga Key
- * Parameters:
- * Return: sample_status_t - SAMPLE_SUCCESS on success, error code otherwise.
- * Inputs: sample_ecc_state_handle_t ecc_handle - Handle to ECC crypto system
- * sample_ec256_private_t *p_private_b - Pointer to the local private key - LITTLE ENDIAN
- * sample_ec256_public_t *p_public_ga - Pointer to the remote public key - LITTLE ENDIAN
- * Output: sample_ec256_dh_shared_t *p_shared_key - Pointer to the shared DH key - LITTLE ENDIAN
- *x-coordinate of (privKeyB - pubKeyA) */
- sample_status_t sample_ecc256_compute_shared_dhkey(sample_ec256_private_t *p_private_b,
- sample_ec256_public_t *p_public_ga,
- sample_ec256_dh_shared_t *p_shared_key,
- sample_ecc_state_handle_t ecc_handle)
- {
- if ((ecc_handle == NULL) || (p_private_b == NULL) || (p_public_ga == NULL) || (p_shared_key == NULL))
- {
- return SAMPLE_ERROR_INVALID_PARAMETER;
- }
- IppsBigNumState* BN_dh_privB = NULL;
- IppsBigNumState* BN_dh_share = NULL;
- IppsBigNumState* pubA_gx = NULL;
- IppsBigNumState* pubA_gy = NULL;
- IppsECCPPointState* point_pubA = NULL;
- IppStatus ipp_ret = ippStsNoErr;
- int ecPointSize = 0;
- IppsECCPState* p_ecc_state = (IppsECCPState*)ecc_handle;
- IppECResult ipp_result = ippECValid;
- do
- {
- ipp_ret = sgx_ipp_newBN((Ipp32u*)p_private_b->r, sizeof(sample_ec256_private_t), &BN_dh_privB);
- ERROR_BREAK(ipp_ret);
- ipp_ret = sgx_ipp_newBN((uint32_t*)p_public_ga->gx, sizeof(p_public_ga->gx), &pubA_gx);
- ERROR_BREAK(ipp_ret);
- ipp_ret = sgx_ipp_newBN((uint32_t*)p_public_ga->gy, sizeof(p_public_ga->gy), &pubA_gy);
- ERROR_BREAK(ipp_ret);
- ipp_ret = ippsECCPPointGetSize(256, &ecPointSize);
- ERROR_BREAK(ipp_ret);
- point_pubA = (IppsECCPPointState*)( malloc(ecPointSize) );
- if(!point_pubA)
- {
- ipp_ret = ippStsNoMemErr;
- break;
- }
- ipp_ret = ippsECCPPointInit(256, point_pubA);
- ERROR_BREAK(ipp_ret);
- ipp_ret = ippsECCPSetPoint(pubA_gx, pubA_gy, point_pubA, p_ecc_state);
- ERROR_BREAK(ipp_ret);
- // Check to see if the point is a valid point on the Elliptic curve and is not infinity
- ipp_ret = ippsECCPCheckPoint(point_pubA, &ipp_result, p_ecc_state);
- if (ipp_result != ippECValid)
- {
- break;
- }
- ERROR_BREAK(ipp_ret);
- ipp_ret = sgx_ipp_newBN(NULL, sizeof(sample_ec256_dh_shared_t), &BN_dh_share);
- ERROR_BREAK(ipp_ret);
- /* This API generates shareA = x-coordinate of (privKeyB - pubKeyA) */
- ipp_ret = ippsECCPSharedSecretDH(BN_dh_privB, point_pubA, BN_dh_share, p_ecc_state);
- ERROR_BREAK(ipp_ret);
- IppsBigNumSGN sgn = IppsBigNumPOS;
- int length = 0;
- Ipp32u * pdata = NULL;
- ipp_ret = ippsRef_BN(&sgn, &length, &pdata, BN_dh_share);
- ERROR_BREAK(ipp_ret);
- memset(p_shared_key->s, 0, sizeof(p_shared_key->s));
- ipp_ret = check_copy_size(sizeof(p_shared_key->s), ROUND_TO(length, 8)/8);
- ERROR_BREAK(ipp_ret);
- memcpy(p_shared_key->s, pdata, ROUND_TO(length, 8)/8);
- }while(0);
- // Clear temp buffer before free.
- if(point_pubA)
- memset_s(point_pubA, ecPointSize, 0, ecPointSize);
- SAFE_FREE(point_pubA);
- sample_ipp_secure_free_BN(pubA_gx, sizeof(p_public_ga->gx));
- sample_ipp_secure_free_BN(pubA_gy, sizeof(p_public_ga->gy));
- sample_ipp_secure_free_BN(BN_dh_privB, sizeof(sample_ec256_private_t));
- sample_ipp_secure_free_BN(BN_dh_share, sizeof(sample_ec256_dh_shared_t));
- if (ipp_result != ippECValid)
- {
- return SAMPLE_ERROR_INVALID_PARAMETER;
- }
- switch (ipp_ret)
- {
- case ippStsNoErr: return SAMPLE_SUCCESS;
- case ippStsNoMemErr:
- case ippStsMemAllocErr: return SAMPLE_ERROR_OUT_OF_MEMORY;
- case ippStsNullPtrErr:
- case ippStsLengthErr:
- case ippStsOutOfRangeErr:
- case ippStsSizeErr:
- case ippStsBadArgErr: return SAMPLE_ERROR_INVALID_PARAMETER;
- default: return SAMPLE_ERROR_UNEXPECTED;
- }
- }
- const uint32_t sample_nistp256_r[] = {
- 0xFC632551, 0xF3B9CAC2, 0xA7179E84, 0xBCE6FAAD, 0xFFFFFFFF, 0xFFFFFFFF,
- 0x00000000, 0xFFFFFFFF};
- #include <stdio.h>
- /* Computes signature for data based on private key
- * Parameters:
- * Return: sample_status_t - SAMPLE_SUCCESS, SAMPLE_SUCCESS on success, error code otherwise.
- * Inputs: sample_ecc_state_handle_t ecc_handle - Handle to ECC crypto system
- * sample_ec256_private_t *p_private - Pointer to the private key - LITTLE ENDIAN
- * sample_uint8_t *p_data - Pointer to the data to be signed
- * uint32_t data_size - Size of the data to be signed
- * Output: sample_ec256_signature_t *p_signature - Pointer to the signature - LITTLE ENDIAN */
- sample_status_t sample_ecdsa_sign(const uint8_t *p_data,
- uint32_t data_size,
- sample_ec256_private_t *p_private,
- sample_ec256_signature_t *p_signature,
- sample_ecc_state_handle_t ecc_handle)
- {
- if ((ecc_handle == NULL) || (p_private == NULL) || (p_signature == NULL) || (p_data == NULL) || (data_size < 1))
- {
- return SAMPLE_ERROR_INVALID_PARAMETER;
- }
- IppStatus ipp_ret = ippStsNoErr;
- IppsECCPState* p_ecc_state = (IppsECCPState*)ecc_handle;
- IppsBigNumState* p_ecp_order = NULL;
- IppsBigNumState* p_hash_bn = NULL;
- IppsBigNumState* p_msg_bn = NULL;
- IppsBigNumState* p_eph_priv_bn = NULL;
- IppsECCPPointState* p_eph_pub = NULL;
- IppsBigNumState* p_reg_priv_bn = NULL;
- IppsBigNumState* p_signx_bn = NULL;
- IppsBigNumState* p_signy_bn = NULL;
- Ipp32u *p_sigx = NULL;
- Ipp32u *p_sigy = NULL;
- int ecp_size = 0;
- const int order_size = sizeof(sample_nistp256_r);
- uint32_t hash[8] = {0};
- do
- {
- ipp_ret = sgx_ipp_newBN(sample_nistp256_r, order_size, &p_ecp_order);
- ERROR_BREAK(ipp_ret);
- // Prepare the message used to sign.
- ipp_ret = ippsHashMessage(p_data, data_size, (Ipp8u*)hash, IPP_ALG_HASH_SHA256);
- ERROR_BREAK(ipp_ret);
- /* Byte swap in creation of Big Number from SHA256 hash output */
- ipp_ret = sgx_ipp_newBN(NULL, sizeof(hash), &p_hash_bn);
- ERROR_BREAK(ipp_ret);
- ipp_ret = ippsSetOctString_BN((Ipp8u*)hash, sizeof(hash), p_hash_bn);
- ERROR_BREAK(ipp_ret);
- ipp_ret = sgx_ipp_newBN(NULL, order_size, &p_msg_bn);
- ERROR_BREAK(ipp_ret);
- ipp_ret = ippsMod_BN(p_hash_bn, p_ecp_order, p_msg_bn);
- ERROR_BREAK(ipp_ret);
- // Get ephemeral key pair.
- ipp_ret = sgx_ipp_newBN(NULL, order_size, &p_eph_priv_bn);
- ERROR_BREAK(ipp_ret);
- //init eccp point
- ipp_ret = ippsECCPPointGetSize(256, &ecp_size);
- ERROR_BREAK(ipp_ret);
- p_eph_pub = (IppsECCPPointState*)(malloc(ecp_size));
- if(!p_eph_pub)
- {
- ipp_ret = ippStsNoMemErr;
- break;
- }
- ipp_ret = ippsECCPPointInit(256, p_eph_pub);
- ERROR_BREAK(ipp_ret);
- // generate ephemeral key pair for signing operation
- ipp_ret = ippsECCPGenKeyPair(p_eph_priv_bn, p_eph_pub, p_ecc_state,
- (IppBitSupplier)sample_ipp_DRNGen, NULL);
- ERROR_BREAK(ipp_ret);
- ipp_ret = ippsECCPSetKeyPair(p_eph_priv_bn, p_eph_pub, ippFalse, p_ecc_state);
- ERROR_BREAK(ipp_ret);
- // Set the regular private key.
- ipp_ret = sgx_ipp_newBN((uint32_t *)p_private->r, sizeof(p_private->r),
- &p_reg_priv_bn);
- ERROR_BREAK(ipp_ret);
- ipp_ret = sgx_ipp_newBN(NULL, order_size, &p_signx_bn);
- ERROR_BREAK(ipp_ret);
- ipp_ret = sgx_ipp_newBN(NULL, order_size, &p_signy_bn);
- ERROR_BREAK(ipp_ret);
- // Sign the message.
- ipp_ret = ippsECCPSignDSA(p_msg_bn, p_reg_priv_bn, p_signx_bn, p_signy_bn,
- p_ecc_state);
- ERROR_BREAK(ipp_ret);
- IppsBigNumSGN sign;
- int length;
- ipp_ret = ippsRef_BN(&sign, &length,(Ipp32u**) &p_sigx, p_signx_bn);
- ERROR_BREAK(ipp_ret);
- memset(p_signature->x, 0, sizeof(p_signature->x));
- ipp_ret = check_copy_size(sizeof(p_signature->x), ROUND_TO(length, 8)/8);
- ERROR_BREAK(ipp_ret);
- memcpy(p_signature->x, p_sigx, ROUND_TO(length, 8)/8);
- memset_s(p_sigx, sizeof(p_signature->x), 0, ROUND_TO(length, 8)/8);
- ipp_ret = ippsRef_BN(&sign, &length,(Ipp32u**) &p_sigy, p_signy_bn);
- ERROR_BREAK(ipp_ret);
- memset(p_signature->y, 0, sizeof(p_signature->y));
- ipp_ret = check_copy_size(sizeof(p_signature->y), ROUND_TO(length, 8)/8);
- ERROR_BREAK(ipp_ret);
- memcpy(p_signature->y, p_sigy, ROUND_TO(length, 8)/8);
- memset_s(p_sigy, sizeof(p_signature->y), 0, ROUND_TO(length, 8)/8);
- }while(0);
- // Clear buffer before free.
- if(p_eph_pub)
- memset_s(p_eph_pub, ecp_size, 0, ecp_size);
- SAFE_FREE(p_eph_pub);
- sample_ipp_secure_free_BN(p_ecp_order, order_size);
- sample_ipp_secure_free_BN(p_hash_bn, sizeof(hash));
- sample_ipp_secure_free_BN(p_msg_bn, order_size);
- sample_ipp_secure_free_BN(p_eph_priv_bn, order_size);
- sample_ipp_secure_free_BN(p_reg_priv_bn, sizeof(p_private->r));
- sample_ipp_secure_free_BN(p_signx_bn, order_size);
- sample_ipp_secure_free_BN(p_signy_bn, order_size);
- switch (ipp_ret)
- {
- case ippStsNoErr: return SAMPLE_SUCCESS;
- case ippStsNoMemErr:
- case ippStsMemAllocErr: return SAMPLE_ERROR_OUT_OF_MEMORY;
- case ippStsNullPtrErr:
- case ippStsLengthErr:
- case ippStsOutOfRangeErr:
- case ippStsSizeErr:
- case ippStsBadArgErr: return SAMPLE_ERROR_INVALID_PARAMETER;
- default: return SAMPLE_ERROR_UNEXPECTED;
- }
- }
- /* Allocates and initializes sha256 state
- * Parameters:
- * Return: sample_status_t - SAMPLE_SUCCESS on success, error code otherwise.
- * Output: sample_sha_state_handle_t sha_handle - Handle to the SHA256 state */
- sample_status_t sample_sha256_init(sample_sha_state_handle_t* p_sha_handle)
- {
- IppStatus ipp_ret = ippStsNoErr;
- IppsHashState* p_temp_state = NULL;
- if (p_sha_handle == NULL)
- return SAMPLE_ERROR_INVALID_PARAMETER;
- int ctx_size = 0;
- ipp_ret = ippsHashGetSize(&ctx_size);
- if (ipp_ret != ippStsNoErr)
- return SAMPLE_ERROR_UNEXPECTED;
- p_temp_state = (IppsHashState*)(malloc(ctx_size));
- if (p_temp_state == NULL)
- return SAMPLE_ERROR_OUT_OF_MEMORY;
- ipp_ret = ippsHashInit(p_temp_state, IPP_ALG_HASH_SHA256);
- if (ipp_ret != ippStsNoErr)
- {
- SAFE_FREE(p_temp_state);
- *p_sha_handle = NULL;
- switch (ipp_ret)
- {
- case ippStsNullPtrErr:
- case ippStsLengthErr: return SAMPLE_ERROR_INVALID_PARAMETER;
- default: return SAMPLE_ERROR_UNEXPECTED;
- }
- }
- *p_sha_handle = p_temp_state;
- return SAMPLE_SUCCESS;
- }
- /* Updates sha256 has calculation based on the input message
- * Parameters:
- * Return: sample_status_t - SAMPLE_SUCCESS on success, error code otherwise.
- * Input: sample_sha_state_handle_t sha_handle - Handle to the SHA256 state
- * uint8_t *p_src - Pointer to the input stream to be hashed
- * uint32_t src_len - Length of the input stream to be hashed */
- sample_status_t sample_sha256_update(const uint8_t *p_src, uint32_t src_len, sample_sha_state_handle_t sha_handle)
- {
- if ((p_src == NULL) || (sha_handle == NULL))
- {
- return SAMPLE_ERROR_INVALID_PARAMETER;
- }
- IppStatus ipp_ret = ippStsNoErr;
- ipp_ret = ippsHashUpdate(p_src, src_len, (IppsHashState*)sha_handle);
- switch (ipp_ret)
- {
- case ippStsNoErr: return SAMPLE_SUCCESS;
- case ippStsNullPtrErr:
- case ippStsLengthErr: return SAMPLE_ERROR_INVALID_PARAMETER;
- default: return SAMPLE_ERROR_UNEXPECTED;
- }
- }
- /* Returns Hash calculation
- * Parameters:
- * Return: sample_status_t - SAMPLE_SUCCESS on success, error code otherwise.
- * Input: sample_sha_state_handle_t sha_handle - Handle to the SHA256 state
- * Output: sample_sha256_hash_t *p_hash - Resultant hash from operation */
- sample_status_t sample_sha256_get_hash(sample_sha_state_handle_t sha_handle, sample_sha256_hash_t *p_hash)
- {
- if ((sha_handle == NULL) || (p_hash == NULL))
- {
- return SAMPLE_ERROR_INVALID_PARAMETER;
- }
- IppStatus ipp_ret = ippStsNoErr;
- ipp_ret = ippsHashGetTag((Ipp8u*)p_hash, SAMPLE_SHA256_HASH_SIZE, (IppsHashState*)sha_handle);
- switch (ipp_ret)
- {
- case ippStsNoErr: return SAMPLE_SUCCESS;
- case ippStsNullPtrErr:
- case ippStsLengthErr: return SAMPLE_ERROR_INVALID_PARAMETER;
- default: return SAMPLE_ERROR_UNEXPECTED;
- }
- }
- /* Cleans up sha state
- * Parameters:
- * Return: sample_status_t - SAMPLE_SUCCESS on success, error code otherwise.
- * Input: sample_sha_state_handle_t sha_handle - Handle to the SHA256 state */
- sample_status_t sample_sha256_close(sample_sha_state_handle_t sha_handle)
- {
- if (sha_handle == NULL)
- {
- return SAMPLE_ERROR_INVALID_PARAMETER;
- }
- SAFE_FREE(sha_handle);
- return SAMPLE_SUCCESS;
- }
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