bool AES_KW_Encrypt(COSE_RecipientInfo * pcose, const byte * pbKeyIn, int cbitKey, const byte * pbContent, int cbContent, cose_errback * perr)
{
byte *pbOut = NULL;
AES_KEY key;
#ifdef USE_CBOR_CONTEXT
cn_cbor_context * context = &pcose->m_encrypt.m_message.m_allocContext;
#endif
cn_cbor * cnTmp = NULL;
pbOut = COSE_CALLOC(cbContent + 8, 1, context);
CHECK_CONDITION(AES_set_encrypt_key(pbKeyIn, cbitKey, &key) == 0, COSE_ERR_CRYPTO_FAIL);
CHECK_CONDITION(AES_wrap_key(&key, NULL, pbOut, pbContent, cbContent), COSE_ERR_CRYPTO_FAIL);
cnTmp = cn_cbor_data_create(pbOut, (int)cbContent + 8, CBOR_CONTEXT_PARAM_COMMA NULL);
CHECK_CONDITION(cnTmp != NULL, COSE_ERR_CBOR);
pbOut = NULL;
CHECK_CONDITION(_COSE_array_replace(&pcose->m_encrypt.m_message, cnTmp, INDEX_BODY, CBOR_CONTEXT_PARAM_COMMA NULL), COSE_ERR_CBOR);
cnTmp = NULL;
return true;
errorReturn:
COSE_FREE(cnTmp, context);
if (pbOut != NULL) COSE_FREE(pbOut, context);
return false;
}
bool AES_CBC_MAC_Create(COSE_MacMessage * pcose, int TSize, const byte * pbKey, size_t cbKey, const byte * pbAuthData, size_t cbAuthData, cose_errback * perr)
{
const EVP_CIPHER * pcipher = NULL;
EVP_CIPHER_CTX ctx;
int cbOut;
byte rgbIV[16] = { 0 };
byte * rgbOut = NULL;
bool f = false;
unsigned int i;
cn_cbor * cn = NULL;
#ifdef USE_CBOR_CONTEXT
cn_cbor_context * context = &pcose->m_message.m_allocContext;
#endif
rgbOut = COSE_CALLOC(16, 1, context);
CHECK_CONDITION(rgbOut != NULL, COSE_ERR_OUT_OF_MEMORY);
switch (cbKey*8) {
case 128:
pcipher = EVP_aes_128_cbc();
break;
case 256:
pcipher = EVP_aes_256_cbc();
break;
default:
FAIL_CONDITION(COSE_ERR_INVALID_PARAMETER);
}
// Setup and run the OpenSSL code
EVP_CIPHER_CTX_init(&ctx);
CHECK_CONDITION(EVP_EncryptInit_ex(&ctx, pcipher, NULL, pbKey, rgbIV), COSE_ERR_CRYPTO_FAIL);
for (i = 0; i < (unsigned int)cbAuthData / 16; i++) {
CHECK_CONDITION(EVP_EncryptUpdate(&ctx, rgbOut, &cbOut, pbAuthData + (i * 16), 16), COSE_ERR_CRYPTO_FAIL);
}
if (cbAuthData % 16 != 0) {
CHECK_CONDITION(EVP_EncryptUpdate(&ctx, rgbOut, &cbOut, pbAuthData + (i * 16), cbAuthData % 16), COSE_ERR_CRYPTO_FAIL);
CHECK_CONDITION(EVP_EncryptUpdate(&ctx, rgbOut, &cbOut, rgbIV, 16 - (cbAuthData % 16)), COSE_ERR_CRYPTO_FAIL);
}
cn = cn_cbor_data_create(rgbOut, TSize / 8, CBOR_CONTEXT_PARAM_COMMA NULL);
CHECK_CONDITION(cn != NULL, COSE_ERR_OUT_OF_MEMORY);
rgbOut = NULL;
CHECK_CONDITION(_COSE_array_replace(&pcose->m_message, cn, INDEX_MAC_TAG, CBOR_CONTEXT_PARAM_COMMA NULL), COSE_ERR_CBOR);
cn = NULL;
EVP_CIPHER_CTX_cleanup(&ctx);
return !f;
errorReturn:
if (rgbOut != NULL) COSE_FREE(rgbOut, context);
if (cn != NULL) CN_CBOR_FREE(cn, context);
EVP_CIPHER_CTX_cleanup(&ctx);
return false;
}
bool ECDSA_Sign(COSE * pSigner, int index, const cn_cbor * pKey, int cbitDigest, const byte * rgbToSign, size_t cbToSign, cose_errback * perr)
{
EC_KEY * eckey = NULL;
byte rgbDigest[EVP_MAX_MD_SIZE];
unsigned int cbDigest = sizeof(rgbDigest);
byte * pbSig = NULL;
const EVP_MD * digest;
#ifdef USE_CBOR_CONTEXT
cn_cbor_context * context = &pSigner->m_allocContext;
#endif
cn_cbor * p = NULL;
ECDSA_SIG * psig = NULL;
cn_cbor_errback cbor_error;
int cbR;
byte rgbSig[66];
int cb;
eckey = ECKey_From(pKey, &cbR, perr);
if (eckey == NULL) {
errorReturn:
if (p != NULL) CN_CBOR_FREE(p, context);
if (eckey != NULL) EC_KEY_free(eckey);
return false;
}
switch (cbitDigest) {
case 256: digest = EVP_sha256(); break;
case 512: digest = EVP_sha512(); break;
case 384: digest = EVP_sha384(); break;
default:
FAIL_CONDITION(COSE_ERR_INVALID_PARAMETER);
}
EVP_Digest(rgbToSign, cbToSign, rgbDigest, &cbDigest, digest, NULL);
psig = ECDSA_do_sign(rgbDigest, cbDigest, eckey);
CHECK_CONDITION(psig != NULL, COSE_ERR_CRYPTO_FAIL);
pbSig = COSE_CALLOC(cbR, 2, context);
CHECK_CONDITION(pbSig != NULL, COSE_ERR_OUT_OF_MEMORY);
cb = BN_bn2bin(psig->r, rgbSig);
CHECK_CONDITION(cb <= cbR, COSE_ERR_INVALID_PARAMETER);
memcpy(pbSig + cbR - cb, rgbSig, cb);
cb = BN_bn2bin(psig->s, rgbSig);
CHECK_CONDITION(cb <= cbR, COSE_ERR_INVALID_PARAMETER);
memcpy(pbSig + 2*cbR - cb, rgbSig, cb);
p = cn_cbor_data_create(pbSig, cbR*2, CBOR_CONTEXT_PARAM_COMMA &cbor_error);
CHECK_CONDITION_CBOR(p != NULL, cbor_error);
CHECK_CONDITION(_COSE_array_replace(pSigner, p, index, CBOR_CONTEXT_PARAM_COMMA NULL), COSE_ERR_CBOR);
return true;
}
bool COSE_Enveloped_AddRecipient(HCOSE_ENVELOPED hEnc, HCOSE_RECIPIENT hRecip, cose_errback * perr)
{
COSE_RecipientInfo * pRecip;
COSE_Enveloped * pEncrypt;
cn_cbor * pRecipients = NULL;
#ifdef USE_CBOR_CONTEXT
cn_cbor_context * context;
#endif
cn_cbor_errback cbor_error;
CHECK_CONDITION(IsValidEnvelopedHandle(hEnc), COSE_ERR_INVALID_HANDLE);
CHECK_CONDITION(IsValidRecipientHandle(hRecip), COSE_ERR_INVALID_HANDLE);
pEncrypt = (COSE_Enveloped *)hEnc;
pRecip = (COSE_RecipientInfo *)hRecip;
#ifdef USE_CBOR_CONTEXT
context = &pEncrypt->m_message.m_allocContext;
#endif // USE_CBOR_CONTEXT
pRecip->m_recipientNext = pEncrypt->m_recipientFirst;
pEncrypt->m_recipientFirst = pRecip;
pRecipients = _COSE_arrayget_int(&pEncrypt->m_message, INDEX_RECIPIENTS);
if (pRecipients == NULL) {
pRecipients = cn_cbor_array_create(CBOR_CONTEXT_PARAM_COMMA &cbor_error);
CHECK_CONDITION_CBOR(pRecipients != NULL, cbor_error);
if (!_COSE_array_replace(&pEncrypt->m_message, pRecipients, INDEX_RECIPIENTS, CBOR_CONTEXT_PARAM_COMMA &cbor_error)) {
CN_CBOR_FREE(pRecipients, context);
if (perr != NULL) perr->err = _MapFromCBOR(cbor_error);
goto errorReturn;
}
}
CHECK_CONDITION_CBOR(cn_cbor_array_append(pRecipients, pRecip->m_encrypt.m_message.m_cbor, &cbor_error), cbor_error);
pRecip->m_encrypt.m_message.m_refCount++;
return true;
errorReturn:
return false;
}
bool COSE_Mac_AddRecipient(HCOSE_MAC hMac, HCOSE_RECIPIENT hRecip, cose_errback * perr)
{
COSE_RecipientInfo * pRecip;
COSE_MacMessage * pMac;
cn_cbor * pRecipients = NULL;
cn_cbor * pRecipientsT = NULL;
#ifdef USE_CBOR_CONTEXT
cn_cbor_context * context = NULL;
#endif
cn_cbor_errback cbor_error;
CHECK_CONDITION(IsValidMacHandle(hMac), COSE_ERR_INVALID_PARAMETER);
CHECK_CONDITION(IsValidRecipientHandle(hRecip), COSE_ERR_INVALID_PARAMETER);
pMac = (COSE_MacMessage *)hMac;
pRecip = (COSE_RecipientInfo *)hRecip;
pRecip->m_recipientNext = pMac->m_recipientFirst;
pMac->m_recipientFirst = pRecip;
#ifdef USE_CBOR_CONTEXT
context = &pMac->m_message.m_allocContext;
#endif // USE_CBOR_CONTEXT
pRecipients = _COSE_arrayget_int(&pMac->m_message, INDEX_MAC_RECIPIENTS);
if (pRecipients == NULL) {
pRecipientsT = cn_cbor_array_create(CBOR_CONTEXT_PARAM_COMMA &cbor_error);
CHECK_CONDITION_CBOR(pRecipientsT != NULL, cbor_error);
CHECK_CONDITION_CBOR(_COSE_array_replace(&pMac->m_message, pRecipientsT, INDEX_MAC_RECIPIENTS, CBOR_CONTEXT_PARAM_COMMA &cbor_error), cbor_error);
pRecipients = pRecipientsT;
pRecipientsT = NULL;
}
CHECK_CONDITION_CBOR(cn_cbor_array_append(pRecipients, pRecip->m_encrypt.m_message.m_cbor, &cbor_error), cbor_error);
pRecip->m_encrypt.m_message.m_refCount++;
return true;
errorReturn:
if (pRecipientsT == NULL) CN_CBOR_FREE(pRecipientsT, context);
return false;
}
bool HMAC_Create(COSE_MacMessage * pcose, int HSize, int TSize, const byte * pbKey, size_t cbKey, const byte * pbAuthData, size_t cbAuthData, cose_errback * perr)
{
byte * rgbOut = NULL;
// unsigned int cbOut;
mbedtls_md_context_t contx;
const char* md_name;
const struct mbedtls_md_info_t * info;
#ifdef USE_CBOR_CONTEXT
cn_cbor_context * context = &pcose->m_message.m_allocContext;
#endif
switch (HSize) {
case 256: md_name = "SHA256"; break;
case 384: md_name = "SHA384"; break;
case 512: md_name = "SHA512"; break;
default: FAIL_CONDITION(COSE_ERR_INVALID_PARAMETER); break;
}
if (0) {
errorReturn:
COSE_FREE(rgbOut, context);
mbedtls_md_free(&contx);
return false;
}
mbedtls_md_init(&contx);
info = mbedtls_md_info_from_string (md_name);
mbedtls_md_setup( &contx, info, 1 );
rgbOut = COSE_CALLOC(mbedtls_md_get_size(info), 1, context);
CHECK_CONDITION(rgbOut != NULL, COSE_ERR_OUT_OF_MEMORY);
CHECK_CONDITION(!(mbedtls_md_hmac_starts (&contx, (char*)pbKey, cbKey)), COSE_ERR_CRYPTO_FAIL);
CHECK_CONDITION(!(mbedtls_md_hmac_update (&contx, pbAuthData, cbAuthData)), COSE_ERR_CRYPTO_FAIL);
CHECK_CONDITION(!(mbedtls_md_hmac_finish (&contx, rgbOut)), COSE_ERR_CRYPTO_FAIL);
CHECK_CONDITION(_COSE_array_replace(&pcose->m_message, cn_cbor_data_create(rgbOut, TSize / 8, CBOR_CONTEXT_PARAM_COMMA NULL), INDEX_MAC_TAG, CBOR_CONTEXT_PARAM_COMMA NULL), COSE_ERR_CBOR);
mbedtls_md_free(&contx);
return true;
}
bool _COSE_Init(COSE* pobj, int msgType, CBOR_CONTEXT_COMMA cose_errback * perr)
{
cn_cbor_errback errState;;
#ifdef USE_CBOR_CONTEXT
if (context != NULL) pobj->m_allocContext = *context;
#endif
pobj->m_protectedMap = cn_cbor_map_create(CBOR_CONTEXT_PARAM_COMMA &errState);
CHECK_CONDITION_CBOR(pobj->m_protectedMap != NULL, errState);
pobj->m_dontSendMap = cn_cbor_map_create(CBOR_CONTEXT_PARAM_COMMA &errState);
CHECK_CONDITION_CBOR(pobj->m_dontSendMap != NULL, errState);
pobj->m_cbor = cn_cbor_array_create(CBOR_CONTEXT_PARAM_COMMA &errState);
CHECK_CONDITION_CBOR(pobj->m_cbor != NULL, errState);
pobj->m_ownMsg = 1;
#ifdef TAG_IN_ARRAY
if (msgType > 0) {
cn_cbor * cn = cn_cbor_int_create(msgType, CBOR_CONTEXT_PARAM_COMMA &errState);
CHECK_CONDITION_CBOR(cn != NULL, errState);
CHECK_CONDITION_CBOR(cn_cbor_array_append(pobj->m_cbor, cn, &errState), errState);
pobj->m_msgType = msgType;
}
#else
pobj->m_msgType = msgType;
#endif
pobj->m_unprotectMap = cn_cbor_map_create(CBOR_CONTEXT_PARAM_COMMA &errState);
CHECK_CONDITION_CBOR(pobj->m_unprotectMap != NULL, errState);
CHECK_CONDITION_CBOR(_COSE_array_replace(pobj, pobj->m_unprotectMap, INDEX_UNPROTECTED, CBOR_CONTEXT_PARAM_COMMA &errState), errState);
pobj->m_ownUnprotectedMap = false;
pobj->m_refCount = 1;
return true;
errorReturn:
_COSE_Release(pobj);
return false;
}
cn_cbor * _COSE_encode_protected(COSE * pMessage, cose_errback * perr)
{
cn_cbor * pProtected;
int cbProtected;
byte * pbProtected = NULL;
#ifdef USE_CBOR_CONTEXT
cn_cbor_context * context = &pMessage->m_allocContext;
#endif // USE_CBOR_CONTEXT
#ifdef TAG_IN_ARRAY
pProtected = cn_cbor_index(pMessage->m_cbor, INDEX_PROTECTED + (pMessage->m_msgType == 0 ? 0 : 1));
#else
pProtected = cn_cbor_index(pMessage->m_cbor, INDEX_PROTECTED);
#endif
if ((pProtected != NULL) &&(pProtected->type != CN_CBOR_INVALID)) {
errorReturn:
if (pbProtected != NULL) COSE_FREE(pbProtected, context);
return pProtected;
}
if (pMessage->m_protectedMap->length > 0) {
cbProtected = cn_cbor_encoder_write(RgbDontUse3, 0, sizeof(RgbDontUse3), pMessage->m_protectedMap);
pbProtected = (byte *)COSE_CALLOC(cbProtected, 1, context);
CHECK_CONDITION(pbProtected != NULL, COSE_ERR_OUT_OF_MEMORY);
CHECK_CONDITION(cn_cbor_encoder_write(pbProtected, 0, cbProtected, pMessage->m_protectedMap) == cbProtected, COSE_ERR_CBOR);
}
else {
cbProtected = 0;
}
pProtected = cn_cbor_data_create(pbProtected, cbProtected, CBOR_CONTEXT_PARAM_COMMA NULL);
CHECK_CONDITION(pProtected != NULL, COSE_ERR_OUT_OF_MEMORY);
pbProtected = NULL;
CHECK_CONDITION(_COSE_array_replace(pMessage, pProtected, INDEX_PROTECTED, CBOR_CONTEXT_PARAM_COMMA NULL), COSE_ERR_CBOR);
return pProtected;
}
bool HMAC_Create(COSE_MacMessage * pcose, int HSize, int TSize, const byte * pbKey, size_t cbKey, const byte * pbAuthData, size_t cbAuthData, cose_errback * perr)
{
HMAC_CTX ctx;
const EVP_MD * pmd = NULL;
byte * rgbOut = NULL;
unsigned int cbOut;
#ifdef USE_CBOR_CONTEXT
cn_cbor_context * context = &pcose->m_message.m_allocContext;
#endif
HMAC_CTX_init(&ctx);
if (0) {
errorReturn:
COSE_FREE(rgbOut, context);
HMAC_cleanup(&ctx);
return false;
}
switch (HSize) {
case 256: pmd = EVP_sha256(); break;
case 384: pmd = EVP_sha384(); break;
case 512: pmd = EVP_sha512(); break;
default: FAIL_CONDITION(COSE_ERR_INVALID_PARAMETER); break;
}
rgbOut = COSE_CALLOC(EVP_MAX_MD_SIZE, 1, context);
CHECK_CONDITION(rgbOut != NULL, COSE_ERR_OUT_OF_MEMORY);
CHECK_CONDITION(HMAC_Init(&ctx, pbKey, (int) cbKey, pmd), COSE_ERR_CRYPTO_FAIL);
CHECK_CONDITION(HMAC_Update(&ctx, pbAuthData, cbAuthData), COSE_ERR_CRYPTO_FAIL);
CHECK_CONDITION(HMAC_Final(&ctx, rgbOut, &cbOut), COSE_ERR_CRYPTO_FAIL);
CHECK_CONDITION(_COSE_array_replace(&pcose->m_message, cn_cbor_data_create(rgbOut, TSize / 8, CBOR_CONTEXT_PARAM_COMMA NULL), INDEX_MAC_TAG, CBOR_CONTEXT_PARAM_COMMA NULL), COSE_ERR_CBOR);
HMAC_cleanup(&ctx);
return true;
}
bool COSE_Mac0_SetContent(HCOSE_MAC0 cose, const byte * rgbContent, size_t cbContent, cose_errback * perr)
{
COSE_Mac0Message * p = (COSE_Mac0Message *)cose;
#ifdef USE_CBOR_CONTEXT
cn_cbor_context * context = &p->m_message.m_allocContext;
#endif
cn_cbor * ptmp = NULL;
cn_cbor_errback cbor_error;
CHECK_CONDITION(IsValidMac0Handle(cose), COSE_ERR_INVALID_PARAMETER);
ptmp = cn_cbor_data_create(rgbContent, (int) cbContent, CBOR_CONTEXT_PARAM_COMMA &cbor_error);
CHECK_CONDITION_CBOR(ptmp != NULL, cbor_error);
CHECK_CONDITION_CBOR(_COSE_array_replace(&p->m_message, ptmp, INDEX_BODY, CBOR_CONTEXT_PARAM_COMMA &cbor_error), cbor_error);
ptmp = NULL;
return true;
errorReturn:
if (ptmp != NULL) CN_CBOR_FREE(ptmp, context);
return false;
}
HCOSE_RECIPIENT COSE_Mac_add_shared_secret(HCOSE_MAC hcose, COSE_Algorithms alg, byte * rgbKey, int cbKey, byte * rgbKid, int cbKid, cose_errback * perr)
{
#ifdef USE_CBOR_CONTEXT
cn_cbor_context * context = NULL;
#endif // USE_CBOR_CONTEXT
COSE_RecipientInfo * pobj;
COSE_MacMessage * pcose = (COSE_MacMessage *)hcose;
cn_cbor * cn_Temp = NULL;
cn_cbor * pRecipients = NULL;
cn_cbor * pRecipientsNew = NULL;
byte * pbKey = NULL;
byte * pbTemp = NULL;
cn_cbor * cnTemp = NULL;
cn_cbor_errback cbor_error;
CHECK_CONDITION(IsValidMacHandle(hcose) && (rgbKey != NULL), COSE_ERR_INVALID_PARAMETER);
#ifdef USE_CBOR_CONTEXT
context = &pcose->m_message.m_allocContext;
#endif // USE_CBOR_CONTEXT
switch (alg) {
case COSE_Algorithm_Direct:
break;
default:
FAIL_CONDITION(COSE_ERR_INVALID_PARAMETER);
}
pobj = (COSE_RecipientInfo *)COSE_CALLOC(1, sizeof(COSE_RecipientInfo), context);
CHECK_CONDITION(pobj != NULL, COSE_ERR_OUT_OF_MEMORY);
if (!_COSE_Init(&pobj->m_encrypt.m_message, COSE_unknown_object, CBOR_CONTEXT_PARAM_COMMA perr)) {
goto errorReturn;
}
cn_Temp = cn_cbor_int_create(alg, CBOR_CONTEXT_PARAM_COMMA &cbor_error);
CHECK_CONDITION_CBOR(cn_Temp != NULL, cbor_error);
CHECK_CONDITION_CBOR(cn_cbor_mapput_int(pobj->m_encrypt.m_message.m_unprotectMap, COSE_Header_Algorithm, cn_Temp, CBOR_CONTEXT_PARAM_COMMA &cbor_error), cbor_error);
cn_Temp = NULL;
if (cbKid > 0) {
pbTemp = (byte *)COSE_CALLOC(cbKid, 1, context);
CHECK_CONDITION(pbTemp != NULL, COSE_ERR_OUT_OF_MEMORY);
memcpy(pbTemp, rgbKid, cbKid);
cnTemp = cn_cbor_data_create(pbTemp, cbKid, CBOR_CONTEXT_PARAM_COMMA &cbor_error);
CHECK_CONDITION_CBOR(cnTemp != NULL, cbor_error);
pbTemp = NULL;
CHECK_CONDITION_CBOR(cn_cbor_mapput_int(pobj->m_encrypt.m_message.m_unprotectMap, COSE_Header_KID, cnTemp, CBOR_CONTEXT_PARAM_COMMA &cbor_error), cbor_error);
}
pobj->m_encrypt.pbKey = pbKey = (byte *)COSE_CALLOC(cbKey, 1, context);
CHECK_CONDITION(pobj->m_encrypt.pbKey != NULL, COSE_ERR_OUT_OF_MEMORY);
memcpy(pbKey, rgbKey, cbKey);
pobj->m_encrypt.cbKey = cbKey;
pobj->m_recipientNext = pcose->m_recipientFirst;
pcose->m_recipientFirst = pobj;
pRecipients = _COSE_arrayget_int(&pcose->m_message, INDEX_MAC_RECIPIENTS);
if (pRecipients == NULL) {
pRecipients = pRecipientsNew = cn_cbor_array_create(CBOR_CONTEXT_PARAM_COMMA &cbor_error);
CHECK_CONDITION_CBOR(pRecipients != NULL, cbor_error);
pRecipientsNew = NULL;
CHECK_CONDITION_CBOR(_COSE_array_replace(&pcose->m_message, pRecipients, INDEX_MAC_RECIPIENTS, CBOR_CONTEXT_PARAM_COMMA &cbor_error), cbor_error);
}
CHECK_CONDITION_CBOR(cn_cbor_array_append(pRecipients, pobj->m_encrypt.m_message.m_cbor, &cbor_error), cbor_error);
pobj->m_encrypt.m_message.m_flags |= 1;
return (HCOSE_RECIPIENT)pobj;
errorReturn:
if (cn_Temp != NULL) CN_CBOR_FREE(cn_Temp, context);
if (pRecipientsNew != NULL) CN_CBOR_FREE(pRecipientsNew, context);
// if (pobj != NULL) COSE_Recipient_Free(pobj);
return NULL;
}
bool AES_CCM_Encrypt(COSE_Enveloped * pcose, int TSize, int LSize, const byte * pbKey, size_t cbKey, const byte * pbAuthData, size_t cbAuthData, cose_errback * perr)
{
mbedtls_ccm_context ctx;
int cbOut;
byte * rgbOut = NULL;
int NSize = 15 - (LSize/8);
const cn_cbor * cbor_iv = NULL;
cn_cbor * cbor_iv_t = NULL;
#ifdef USE_CBOR_CONTEXT
cn_cbor_context * context = &pcose->m_message.m_allocContext;
#endif
cn_cbor * cnTmp = NULL;
mbedtls_cipher_id_t cipher;
byte rgbIV[16];
byte * pbIV = NULL;
cn_cbor_errback cbor_error;
mbedtls_ccm_init(&ctx);
cipher = MBEDTLS_CIPHER_ID_AES;
// Setup the IV/Nonce and put it into the message
cbor_iv = _COSE_map_get_int(&pcose->m_message, COSE_Header_IV, COSE_BOTH, perr);
if (cbor_iv == NULL) {
pbIV = COSE_CALLOC(NSize, 1, context);
CHECK_CONDITION(pbIV != NULL, COSE_ERR_OUT_OF_MEMORY);
rand_bytes(pbIV, NSize);
memcpy(rgbIV, pbIV, NSize);
cbor_iv_t = cn_cbor_data_create(pbIV, NSize, CBOR_CONTEXT_PARAM_COMMA &cbor_error);
CHECK_CONDITION_CBOR(cbor_iv_t != NULL, cbor_error);
pbIV = NULL;
if (!_COSE_map_put(&pcose->m_message, COSE_Header_IV, cbor_iv_t, COSE_UNPROTECT_ONLY, perr)) goto errorReturn;
cbor_iv_t = NULL;
}
else {
CHECK_CONDITION(cbor_iv->type == CN_CBOR_BYTES, COSE_ERR_INVALID_PARAMETER);
CHECK_CONDITION(cbor_iv->length == NSize, COSE_ERR_INVALID_PARAMETER);
memcpy(rgbIV, cbor_iv->v.str, cbor_iv->length);
}
// Setup and run the mbedTLS code
//cbKey comes in bytes not bits
CHECK_CONDITION(!mbedtls_ccm_setkey(&ctx, cipher, pbKey, cbKey*8), COSE_ERR_CRYPTO_FAIL);
TSize /= 8; // Comes in in bits not bytes.
cbOut = pcose->cbContent; // M00BUG - This is a missing call?
rgbOut = (byte *)COSE_CALLOC(cbOut+TSize, 1, context);
CHECK_CONDITION(rgbOut != NULL, COSE_ERR_OUT_OF_MEMORY);
CHECK_CONDITION(!mbedtls_ccm_encrypt_and_tag(&ctx, pcose->cbContent, rgbIV, NSize, pbAuthData, cbAuthData, pcose->pbContent, rgbOut, &rgbOut[pcose->cbContent], TSize), COSE_ERR_CRYPTO_FAIL);
cnTmp = cn_cbor_data_create(rgbOut, (int)pcose->cbContent + TSize, CBOR_CONTEXT_PARAM_COMMA NULL);
CHECK_CONDITION(cnTmp != NULL, COSE_ERR_CBOR);
rgbOut = NULL;
CHECK_CONDITION(_COSE_array_replace(&pcose->m_message, cnTmp, INDEX_BODY, CBOR_CONTEXT_PARAM_COMMA NULL), COSE_ERR_CBOR);
cnTmp = NULL;
mbedtls_ccm_free(&ctx);
return true;
errorReturn:
if (pbIV != NULL) COSE_FREE(pbIV, context);
if (cbor_iv_t != NULL) COSE_FREE(cbor_iv_t, context);
if (rgbOut != NULL) COSE_FREE(rgbOut, context);
if (cnTmp != NULL) COSE_FREE(cnTmp, context);
printf("errorReturn from OPENSSL\n");
mbedtls_ccm_free(&ctx);
return false;
}
bool ECDSA_Sign(COSE * pSigner, int index, const cn_cbor * pKey, int cbitDigest, const byte * rgbToSign, size_t cbToSign, cose_errback * perr)
{
#if defined(MBEDTLS_ECDSA_DETERMINISTIC)
byte rgbDigest[MBEDTLS_MD_MAX_SIZE];
uint8_t * pbSig = NULL;
cn_cbor_errback cbor_error;
int cbR;
mbedtls_md_type_t mdType;
const mbedtls_md_info_t *pmdInfo;
mbedtls_ecp_keypair keypair;
mbedtls_mpi r;
mbedtls_mpi s;
#ifdef USE_CBOR_CONTEXT
cn_cbor_context * context = &pSigner->m_allocContext;
#endif
cn_cbor * p = NULL;
bool result = false;
mbedtls_ecp_keypair_init(&keypair);
mbedtls_mpi_init(&r);
mbedtls_mpi_init(&s);
if(!ECKey_From(pKey, &keypair, perr)) goto errorReturn;
CHECK_CONDITION(keypair.d.n != 0, COSE_ERR_INVALID_PARAMETER);
switch(cbitDigest)
{
case 256:
mdType = MBEDTLS_MD_SHA256;
break;
case 384:
mdType = MBEDTLS_MD_SHA384;
break;
case 512:
mdType = MBEDTLS_MD_SHA512;
break;
default:
FAIL_CONDITION(COSE_ERR_INVALID_PARAMETER);
}
pmdInfo = mbedtls_md_info_from_type(mdType);
CHECK_CONDITION(pmdInfo != NULL, COSE_ERR_INVALID_PARAMETER);
CHECK_CONDITION(mbedtls_md(pmdInfo, rgbToSign, cbToSign, rgbDigest) == 0, COSE_ERR_INVALID_PARAMETER);
CHECK_CONDITION(mbedtls_ecdsa_sign_det(&keypair.grp, &r, &s, &keypair.d, rgbDigest, mbedtls_md_get_size(pmdInfo), mdType) == 0, COSE_ERR_CRYPTO_FAIL);
cbR = (keypair.grp.nbits + 7) / 8;
pbSig = COSE_CALLOC(cbR, 2, context);
CHECK_CONDITION(pbSig != NULL, COSE_ERR_OUT_OF_MEMORY);
CHECK_CONDITION(mbedtls_mpi_write_binary(&r, pbSig, cbR) == 0, COSE_ERR_INTERNAL);
CHECK_CONDITION(mbedtls_mpi_write_binary(&s, pbSig + cbR, cbR) == 0, COSE_ERR_INTERNAL);
p = cn_cbor_data_create(pbSig, cbR*2, CBOR_CONTEXT_PARAM_COMMA &cbor_error);
CHECK_CONDITION_CBOR(p != NULL, cbor_error);
CHECK_CONDITION(_COSE_array_replace(pSigner, p, index, CBOR_CONTEXT_PARAM_COMMA NULL), COSE_ERR_CBOR);
p = NULL;
pbSig = NULL;
result = true;
errorReturn:
cn_cbor_free(p CBOR_CONTEXT_PARAM);
COSE_FREE(pbSig, context);
mbedtls_mpi_free(&r);
mbedtls_mpi_free(&s);
mbedtls_ecp_keypair_free(&keypair);
return result;
#else
return false;
#endif
}
bool AES_CCM_Encrypt(COSE_Enveloped * pcose, int TSize, int LSize, const byte * pbKey, size_t cbKey, const byte * pbAuthData, size_t cbAuthData, cose_errback * perr)
{
EVP_CIPHER_CTX ctx;
int cbOut;
byte * rgbOut = NULL;
int NSize = 15 - (LSize/8);
int outl = 0;
const cn_cbor * cbor_iv = NULL;
cn_cbor * cbor_iv_t = NULL;
#ifdef USE_CBOR_CONTEXT
cn_cbor_context * context = &pcose->m_message.m_allocContext;
#endif
cn_cbor * cnTmp = NULL;
const EVP_CIPHER * cipher;
byte rgbIV[16];
byte * pbIV = NULL;
cn_cbor_errback cbor_error;
switch (cbKey*8) {
case 128:
cipher = EVP_aes_128_ccm();
break;
case 192:
cipher = EVP_aes_192_ccm();
break;
case 256:
cipher = EVP_aes_256_ccm();
break;
default:
FAIL_CONDITION(COSE_ERR_INVALID_PARAMETER);
}
// Setup the IV/Nonce and put it into the message
cbor_iv = _COSE_map_get_int(&pcose->m_message, COSE_Header_IV, COSE_BOTH, perr);
if (cbor_iv == NULL) {
pbIV = COSE_CALLOC(NSize, 1, context);
CHECK_CONDITION(pbIV != NULL, COSE_ERR_OUT_OF_MEMORY);
rand_bytes(pbIV, NSize);
memcpy(rgbIV, pbIV, NSize);
cbor_iv_t = cn_cbor_data_create(pbIV, NSize, CBOR_CONTEXT_PARAM_COMMA &cbor_error);
CHECK_CONDITION_CBOR(cbor_iv_t != NULL, cbor_error);
pbIV = NULL;
if (!_COSE_map_put(&pcose->m_message, COSE_Header_IV, cbor_iv_t, COSE_UNPROTECT_ONLY, perr)) goto errorReturn;
cbor_iv_t = NULL;
}
else {
CHECK_CONDITION(cbor_iv->type == CN_CBOR_BYTES, COSE_ERR_INVALID_PARAMETER);
CHECK_CONDITION(cbor_iv->length == NSize, COSE_ERR_INVALID_PARAMETER);
memcpy(rgbIV, cbor_iv->v.str, cbor_iv->length);
}
// Setup and run the OpenSSL code
EVP_CIPHER_CTX_init(&ctx);
CHECK_CONDITION(EVP_EncryptInit_ex(&ctx, cipher, NULL, NULL, NULL), COSE_ERR_CRYPTO_FAIL);
TSize /= 8; // Comes in in bits not bytes.
CHECK_CONDITION(EVP_CIPHER_CTX_ctrl(&ctx, EVP_CTRL_CCM_SET_L, (LSize/8), 0), COSE_ERR_CRYPTO_FAIL);
// CHECK_CONDITION(EVP_CIPHER_CTX_ctrl(&ctx, EVP_CTRL_CCM_SET_IVLEN, NSize, 0), COSE_ERR_CRYPTO_FAIL);
CHECK_CONDITION(EVP_CIPHER_CTX_ctrl(&ctx, EVP_CTRL_CCM_SET_TAG, TSize, NULL), COSE_ERR_CRYPTO_FAIL); // Say we are doing an 8 byte tag
CHECK_CONDITION(EVP_EncryptInit(&ctx, 0, pbKey, rgbIV), COSE_ERR_CRYPTO_FAIL);
CHECK_CONDITION(EVP_EncryptUpdate(&ctx, 0, &cbOut, 0, (int) pcose->cbContent), COSE_ERR_CRYPTO_FAIL);
CHECK_CONDITION(EVP_EncryptUpdate(&ctx, NULL, &outl, pbAuthData, (int) cbAuthData), COSE_ERR_CRYPTO_FAIL);
rgbOut = (byte *)COSE_CALLOC(cbOut+TSize, 1, context);
CHECK_CONDITION(rgbOut != NULL, COSE_ERR_OUT_OF_MEMORY);
CHECK_CONDITION(EVP_EncryptUpdate(&ctx, rgbOut, &cbOut, pcose->pbContent, (int) pcose->cbContent), COSE_ERR_CRYPTO_FAIL);
CHECK_CONDITION(EVP_EncryptFinal_ex(&ctx, &rgbOut[cbOut], &cbOut), COSE_ERR_CRYPTO_FAIL);
CHECK_CONDITION(EVP_CIPHER_CTX_ctrl(&ctx, EVP_CTRL_CCM_GET_TAG, TSize, &rgbOut[pcose->cbContent]), COSE_ERR_CRYPTO_FAIL);
cnTmp = cn_cbor_data_create(rgbOut, (int)pcose->cbContent + TSize, CBOR_CONTEXT_PARAM_COMMA NULL);
CHECK_CONDITION(cnTmp != NULL, COSE_ERR_CBOR);
rgbOut = NULL;
CHECK_CONDITION(_COSE_array_replace(&pcose->m_message, cnTmp, INDEX_BODY, CBOR_CONTEXT_PARAM_COMMA NULL), COSE_ERR_CBOR);
cnTmp = NULL;
EVP_CIPHER_CTX_cleanup(&ctx);
return true;
errorReturn:
if (pbIV != NULL) COSE_FREE(pbIV, context);
if (cbor_iv_t != NULL) COSE_FREE(cbor_iv_t, context);
if (rgbOut != NULL) COSE_FREE(rgbOut, context);
if (cnTmp != NULL) COSE_FREE(cnTmp, context);
EVP_CIPHER_CTX_cleanup(&ctx);
return false;
}
