/* * FreeRTOS V202212.00 * Copyright (C) 2020 Amazon.com, Inc. or its affiliates. All Rights Reserved. * * Permission is hereby granted, free of charge, to any person obtaining a copy of * this software and associated documentation files (the "Software"), to deal in * the Software without restriction, including without limitation the rights to * use, copy, modify, merge, publish, distribute, sublicense, and/or sell copies of * the Software, and to permit persons to whom the Software is furnished to do so, * subject to the following conditions: * * The above copyright notice and this permission notice shall be included in all * copies or substantial portions of the Software. * * THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, EXPRESS OR * IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF MERCHANTABILITY, FITNESS * FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT. IN NO EVENT SHALL THE AUTHORS OR * COPYRIGHT HOLDERS BE LIABLE FOR ANY CLAIM, DAMAGES OR OTHER LIABILITY, WHETHER * IN AN ACTION OF CONTRACT, TORT OR OTHERWISE, ARISING FROM, OUT OF OR IN * CONNECTION WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS IN THE SOFTWARE. * * https://www.FreeRTOS.org * https://github.com/FreeRTOS * */ /** * @file transport_mbedtls_pkcs11.c * @brief TLS transport interface implementations. This implementation uses * mbedTLS. */ #include "logging_levels.h" #define LIBRARY_LOG_NAME "PkcsTlsTransport" #define LIBRARY_LOG_LEVEL LOG_INFO #include "logging_stack.h" #define MBEDTLS_ALLOW_PRIVATE_ACCESS #include "mbedtls/private_access.h" /* Standard includes. */ #include /* FreeRTOS includes. */ #include "FreeRTOS.h" /* MbedTLS Bio TCP sockets wrapper include. */ #include "mbedtls_bio_tcp_sockets_wrapper.h" /* TLS transport header. */ #include "transport_mbedtls_pkcs11.h" #include "mbedtls_pkcs11.h" /* PKCS #11 includes. */ #include "core_pkcs11_config.h" #include "core_pkcs11.h" #include "pkcs11.h" #include "core_pki_utils.h" /*-----------------------------------------------------------*/ /** * @brief Each compilation unit that consumes the NetworkContext must define it. * It should contain a single pointer as seen below whenever the header file * of this transport implementation is included to your project. * * @note When using multiple transports in the same compilation unit, * define this pointer as void *. */ struct NetworkContext { TlsTransportParams_t * pParams; }; /*-----------------------------------------------------------*/ /** * @brief Represents string to be logged when mbedTLS returned error * does not contain a high-level code. */ static const char * pNoHighLevelMbedTlsCodeStr = ""; /** * @brief Represents string to be logged when mbedTLS returned error * does not contain a low-level code. */ static const char * pNoLowLevelMbedTlsCodeStr = ""; /** * @brief Utility for converting the high-level code in an mbedTLS error to string, * if the code-contains a high-level code; otherwise, using a default string. */ #define mbedtlsHighLevelCodeOrDefault( mbedTlsCode ) \ ( mbedtls_high_level_strerr( mbedTlsCode ) != NULL ) ? \ mbedtls_high_level_strerr( mbedTlsCode ) : pNoHighLevelMbedTlsCodeStr /** * @brief Utility for converting the level-level code in an mbedTLS error to string, * if the code-contains a level-level code; otherwise, using a default string. */ #define mbedtlsLowLevelCodeOrDefault( mbedTlsCode ) \ ( mbedtls_low_level_strerr( mbedTlsCode ) != NULL ) ? \ mbedtls_low_level_strerr( mbedTlsCode ) : pNoLowLevelMbedTlsCodeStr /*-----------------------------------------------------------*/ /** * @brief Initialize the mbed TLS structures in a network connection. * * @param[in] pSslContext The SSL context to initialize. */ static void sslContextInit( SSLContext_t * pSslContext ); /** * @brief Free the mbed TLS structures in a network connection. * * @param[in] pSslContext The SSL context to free. */ static void sslContextFree( SSLContext_t * pSslContext ); /** * @brief Set up TLS on a TCP connection. * * @param[in] pNetworkContext Network context. * @param[in] pHostName Remote host name, used for server name indication. * @param[in] pNetworkCredentials TLS setup parameters. * * @return #TLS_TRANSPORT_SUCCESS, #TLS_TRANSPORT_INSUFFICIENT_MEMORY, #TLS_TRANSPORT_INVALID_CREDENTIALS, * #TLS_TRANSPORT_HANDSHAKE_FAILED, or #TLS_TRANSPORT_INTERNAL_ERROR. */ static TlsTransportStatus_t tlsSetup( NetworkContext_t * pNetworkContext, const char * pHostName, const NetworkCredentials_t * pNetworkCredentials ); /*-----------------------------------------------------------*/ /** * @brief Callback that wraps PKCS#11 for pseudo-random number generation. * * @param[in] pvCtx Caller context. * @param[in] pucRandom Byte array to fill with random data. * @param[in] xRandomLength Length of byte array. * * @return Zero on success. */ static int32_t generateRandomBytes( void * pvCtx, unsigned char * pucRandom, size_t xRandomLength ); /** * @brief Helper for reading the specified certificate object, if present, * out of storage, into RAM, and then into an mbedTLS certificate context * object. * * @param[in] pSslContext Caller TLS context. * @param[in] pcLabelName PKCS #11 certificate object label. * @param[in] xClass PKCS #11 certificate object class. * @param[out] pxCertificateContext Certificate context. * * @return Zero on success. */ static CK_RV readCertificateIntoContext( SSLContext_t * pSslContext, const char * pcLabelName, CK_OBJECT_CLASS xClass, mbedtls_x509_crt * pxCertificateContext ); /** * @brief Helper for setting up potentially hardware-based cryptographic context * for the client TLS certificate and private key. * * @param[in] Caller context. * @param[in] PKCS11 label which contains the desired private key. * * @return Zero on success. */ static CK_RV initializeClientKeys( SSLContext_t * pxCtx, const char * pcLabelName ); /** * @brief Sign a cryptographic hash with the private key. * * @param[in] pvContext Crypto context. * @param[in] xMdAlg Unused. * @param[in] pucHash Length in bytes of hash to be signed. * @param[in] uiHashLen Byte array of hash to be signed. * @param[out] pucSig RSA signature bytes. * @param[in] pxSigLen Length in bytes of signature buffer. * @param[in] piRng Unused. * @param[in] pvRng Unused. * * @return Zero on success. */ static int32_t privateKeySigningCallback( void * pvContext, mbedtls_md_type_t xMdAlg, const unsigned char * pucHash, size_t xHashLen, unsigned char * pucSig, size_t * pxSigLen, int32_t ( * piRng )( void *, unsigned char *, size_t ), void * pvRng ); /*-----------------------------------------------------------*/ static void sslContextInit( SSLContext_t * pSslContext ) { configASSERT( pSslContext != NULL ); mbedtls_ssl_config_init( &( pSslContext->config ) ); mbedtls_x509_crt_init( &( pSslContext->rootCa ) ); mbedtls_x509_crt_init( &( pSslContext->clientCert ) ); mbedtls_ssl_init( &( pSslContext->context ) ); xInitializePkcs11Session( &( pSslContext->xP11Session ) ); C_GetFunctionList( &( pSslContext->pxP11FunctionList ) ); } /*-----------------------------------------------------------*/ static void sslContextFree( SSLContext_t * pSslContext ) { configASSERT( pSslContext != NULL ); mbedtls_ssl_free( &( pSslContext->context ) ); mbedtls_x509_crt_free( &( pSslContext->rootCa ) ); mbedtls_x509_crt_free( &( pSslContext->clientCert ) ); mbedtls_ssl_config_free( &( pSslContext->config ) ); mbedtls_pk_free( &( pSslContext->privKey ) ); pSslContext->pxP11FunctionList->C_CloseSession( pSslContext->xP11Session ); } /*-----------------------------------------------------------*/ static TlsTransportStatus_t tlsSetup( NetworkContext_t * pNetworkContext, const char * pHostName, const NetworkCredentials_t * pNetworkCredentials ) { TlsTransportParams_t * pTlsTransportParams = NULL; TlsTransportStatus_t returnStatus = TLS_TRANSPORT_SUCCESS; int32_t mbedtlsError = 0; CK_RV xResult = CKR_OK; configASSERT( pNetworkContext != NULL ); configASSERT( pNetworkContext->pParams != NULL ); configASSERT( pHostName != NULL ); configASSERT( pNetworkCredentials != NULL ); configASSERT( pNetworkCredentials->pRootCa != NULL ); configASSERT( pNetworkCredentials->pClientCertLabel != NULL ); configASSERT( pNetworkCredentials->pPrivateKeyLabel != NULL ); pTlsTransportParams = pNetworkContext->pParams; /* Initialize the mbed TLS context structures. */ sslContextInit( &( pTlsTransportParams->sslContext ) ); mbedtlsError = mbedtls_ssl_config_defaults( &( pTlsTransportParams->sslContext.config ), MBEDTLS_SSL_IS_CLIENT, MBEDTLS_SSL_TRANSPORT_STREAM, MBEDTLS_SSL_PRESET_DEFAULT ); if( mbedtlsError != 0 ) { LogError( ( "Failed to set default SSL configuration: mbedTLSError= %s : %s.", mbedtlsHighLevelCodeOrDefault( mbedtlsError ), mbedtlsLowLevelCodeOrDefault( mbedtlsError ) ) ); /* Per mbed TLS docs, mbedtls_ssl_config_defaults only fails on memory allocation. */ returnStatus = TLS_TRANSPORT_INSUFFICIENT_MEMORY; } if( returnStatus == TLS_TRANSPORT_SUCCESS ) { /* Set up the certificate security profile, starting from the default value. */ pTlsTransportParams->sslContext.certProfile = mbedtls_x509_crt_profile_default; /* test.mosquitto.org only provides a 1024-bit RSA certificate, which is * not acceptable by the default mbed TLS certificate security profile. * For the purposes of this demo, allow the use of 1024-bit RSA certificates. * This block should be removed otherwise. */ if( strncmp( pHostName, "test.mosquitto.org", strlen( pHostName ) ) == 0 ) { pTlsTransportParams->sslContext.certProfile.rsa_min_bitlen = 1024; } /* Set SSL authmode and the RNG context. */ mbedtls_ssl_conf_authmode( &( pTlsTransportParams->sslContext.config ), MBEDTLS_SSL_VERIFY_REQUIRED ); mbedtls_ssl_conf_rng( &( pTlsTransportParams->sslContext.config ), generateRandomBytes, &pTlsTransportParams->sslContext ); mbedtls_ssl_conf_cert_profile( &( pTlsTransportParams->sslContext.config ), &( pTlsTransportParams->sslContext.certProfile ) ); /* Parse the server root CA certificate into the SSL context. */ mbedtlsError = mbedtls_x509_crt_parse( &( pTlsTransportParams->sslContext.rootCa ), pNetworkCredentials->pRootCa, pNetworkCredentials->rootCaSize ); if( mbedtlsError != 0 ) { LogError( ( "Failed to parse server root CA certificate: mbedTLSError= %s : %s.", mbedtlsHighLevelCodeOrDefault( mbedtlsError ), mbedtlsLowLevelCodeOrDefault( mbedtlsError ) ) ); returnStatus = TLS_TRANSPORT_INVALID_CREDENTIALS; } else { mbedtls_ssl_conf_ca_chain( &( pTlsTransportParams->sslContext.config ), &( pTlsTransportParams->sslContext.rootCa ), NULL ); } } if( returnStatus == TLS_TRANSPORT_SUCCESS ) { /* Setup the client private key. */ xResult = initializeClientKeys( &( pTlsTransportParams->sslContext ), pNetworkCredentials->pPrivateKeyLabel ); if( xResult != CKR_OK ) { LogError( ( "Failed to setup key handling by PKCS #11." ) ); returnStatus = TLS_TRANSPORT_INVALID_CREDENTIALS; } else { /* Setup the client certificate. */ xResult = readCertificateIntoContext( &( pTlsTransportParams->sslContext ), pNetworkCredentials->pClientCertLabel, CKO_CERTIFICATE, &( pTlsTransportParams->sslContext.clientCert ) ); if( xResult != CKR_OK ) { LogError( ( "Failed to get certificate from PKCS #11 module." ) ); returnStatus = TLS_TRANSPORT_INVALID_CREDENTIALS; } else { ( void ) mbedtls_ssl_conf_own_cert( &( pTlsTransportParams->sslContext.config ), &( pTlsTransportParams->sslContext.clientCert ), &( pTlsTransportParams->sslContext.privKey ) ); } } } if( ( returnStatus == TLS_TRANSPORT_SUCCESS ) && ( pNetworkCredentials->pAlpnProtos != NULL ) ) { /* Include an application protocol list in the TLS ClientHello * message. */ mbedtlsError = mbedtls_ssl_conf_alpn_protocols( &( pTlsTransportParams->sslContext.config ), pNetworkCredentials->pAlpnProtos ); if( mbedtlsError != 0 ) { LogError( ( "Failed to configure ALPN protocol in mbed TLS: mbedTLSError= %s : %s.", mbedtlsHighLevelCodeOrDefault( mbedtlsError ), mbedtlsLowLevelCodeOrDefault( mbedtlsError ) ) ); returnStatus = TLS_TRANSPORT_INTERNAL_ERROR; } } if( returnStatus == TLS_TRANSPORT_SUCCESS ) { /* Initialize the mbed TLS secured connection context. */ mbedtlsError = mbedtls_ssl_setup( &( pTlsTransportParams->sslContext.context ), &( pTlsTransportParams->sslContext.config ) ); if( mbedtlsError != 0 ) { LogError( ( "Failed to set up mbed TLS SSL context: mbedTLSError= %s : %s.", mbedtlsHighLevelCodeOrDefault( mbedtlsError ), mbedtlsLowLevelCodeOrDefault( mbedtlsError ) ) ); returnStatus = TLS_TRANSPORT_INTERNAL_ERROR; } else { /* Set the underlying IO for the TLS connection. */ /* MISRA Rule 11.2 flags the following line for casting the second * parameter to void *. This rule is suppressed because * #mbedtls_ssl_set_bio requires the second parameter as void *. */ /* coverity[misra_c_2012_rule_11_2_violation] */ mbedtls_ssl_set_bio( &( pTlsTransportParams->sslContext.context ), ( void * ) pTlsTransportParams->tcpSocket, xMbedTLSBioTCPSocketsWrapperSend, xMbedTLSBioTCPSocketsWrapperRecv, NULL ); } } if( returnStatus == TLS_TRANSPORT_SUCCESS ) { /* Enable SNI if requested. */ if( pNetworkCredentials->disableSni == pdFALSE ) { mbedtlsError = mbedtls_ssl_set_hostname( &( pTlsTransportParams->sslContext.context ), pHostName ); if( mbedtlsError != 0 ) { LogError( ( "Failed to set server name: mbedTLSError= %s : %s.", mbedtlsHighLevelCodeOrDefault( mbedtlsError ), mbedtlsLowLevelCodeOrDefault( mbedtlsError ) ) ); returnStatus = TLS_TRANSPORT_INTERNAL_ERROR; } } } /* Set Maximum Fragment Length if enabled. */ #ifdef MBEDTLS_SSL_MAX_FRAGMENT_LENGTH if( returnStatus == TLS_TRANSPORT_SUCCESS ) { /* Enable the max fragment extension. 4096 bytes is currently the largest fragment size permitted. * See RFC 8449 https://tools.ietf.org/html/rfc8449 for more information. * * Smaller values can be found in "mbedtls/include/ssl.h". */ mbedtlsError = mbedtls_ssl_conf_max_frag_len( &( pTlsTransportParams->sslContext.config ), MBEDTLS_SSL_MAX_FRAG_LEN_4096 ); if( mbedtlsError != 0 ) { LogError( ( "Failed to maximum fragment length extension: mbedTLSError= %s : %s.", mbedtlsHighLevelCodeOrDefault( mbedtlsError ), mbedtlsLowLevelCodeOrDefault( mbedtlsError ) ) ); returnStatus = TLS_TRANSPORT_INTERNAL_ERROR; } } #endif /* ifdef MBEDTLS_SSL_MAX_FRAGMENT_LENGTH */ if( returnStatus == TLS_TRANSPORT_SUCCESS ) { /* Perform the TLS handshake. */ do { mbedtlsError = mbedtls_ssl_handshake( &( pTlsTransportParams->sslContext.context ) ); } while( ( mbedtlsError == MBEDTLS_ERR_SSL_WANT_READ ) || ( mbedtlsError == MBEDTLS_ERR_SSL_WANT_WRITE ) ); if( mbedtlsError != 0 ) { LogError( ( "Failed to perform TLS handshake: mbedTLSError= %s : %s.", mbedtlsHighLevelCodeOrDefault( mbedtlsError ), mbedtlsLowLevelCodeOrDefault( mbedtlsError ) ) ); returnStatus = TLS_TRANSPORT_HANDSHAKE_FAILED; } } if( returnStatus != TLS_TRANSPORT_SUCCESS ) { sslContextFree( &( pTlsTransportParams->sslContext ) ); } else { LogInfo( ( "(Network connection %p) TLS handshake successful.", pNetworkContext ) ); } return returnStatus; } /*-----------------------------------------------------------*/ static int32_t generateRandomBytes( void * pvCtx, unsigned char * pucRandom, size_t xRandomLength ) { /* Must cast from void pointer to conform to mbed TLS API. */ SSLContext_t * pxCtx = ( SSLContext_t * ) pvCtx; CK_RV xResult; xResult = pxCtx->pxP11FunctionList->C_GenerateRandom( pxCtx->xP11Session, pucRandom, xRandomLength ); if( xResult != CKR_OK ) { LogError( ( "Failed to generate random bytes from the PKCS #11 module." ) ); } return xResult; } /*-----------------------------------------------------------*/ static CK_RV readCertificateIntoContext( SSLContext_t * pSslContext, const char * pcLabelName, CK_OBJECT_CLASS xClass, mbedtls_x509_crt * pxCertificateContext ) { CK_RV xResult = CKR_OK; CK_ATTRIBUTE xTemplate = { 0 }; CK_OBJECT_HANDLE xCertObj = 0; /* Get the handle of the certificate. */ xResult = xFindObjectWithLabelAndClass( pSslContext->xP11Session, pcLabelName, strnlen( pcLabelName, pkcs11configMAX_LABEL_LENGTH ), xClass, &xCertObj ); if( ( CKR_OK == xResult ) && ( xCertObj == CK_INVALID_HANDLE ) ) { xResult = CKR_OBJECT_HANDLE_INVALID; } /* Query the certificate size. */ if( CKR_OK == xResult ) { xTemplate.type = CKA_VALUE; xTemplate.ulValueLen = 0; xTemplate.pValue = NULL; xResult = pSslContext->pxP11FunctionList->C_GetAttributeValue( pSslContext->xP11Session, xCertObj, &xTemplate, 1 ); } /* Create a buffer for the certificate. */ if( CKR_OK == xResult ) { xTemplate.pValue = pvPortMalloc( xTemplate.ulValueLen ); if( NULL == xTemplate.pValue ) { xResult = CKR_HOST_MEMORY; } } /* Export the certificate. */ if( CKR_OK == xResult ) { xResult = pSslContext->pxP11FunctionList->C_GetAttributeValue( pSslContext->xP11Session, xCertObj, &xTemplate, 1 ); } /* Decode the certificate. */ if( CKR_OK == xResult ) { xResult = mbedtls_x509_crt_parse( pxCertificateContext, ( const unsigned char * ) xTemplate.pValue, xTemplate.ulValueLen ); } /* Free memory. */ vPortFree( xTemplate.pValue ); return xResult; } /*-----------------------------------------------------------*/ /** * @brief Helper for setting up potentially hardware-based cryptographic context * for the client TLS certificate and private key. * * @param[in] Caller context. * @param[in] PKCS11 label which contains the desired private key. * * @return Zero on success. */ static CK_RV initializeClientKeys( SSLContext_t * pxCtx, const char * pcLabelName ) { CK_RV xResult = CKR_OK; CK_SLOT_ID * pxSlotIds = NULL; CK_ULONG xCount = 0; CK_ATTRIBUTE xTemplate[ 2 ]; mbedtls_pk_type_t xKeyAlgo = ( mbedtls_pk_type_t ) ~0; /* Get the PKCS #11 module/token slot count. */ if( CKR_OK == xResult ) { xResult = ( BaseType_t ) pxCtx->pxP11FunctionList->C_GetSlotList( CK_TRUE, NULL, &xCount ); } /* Allocate memory to store the token slots. */ if( CKR_OK == xResult ) { pxSlotIds = ( CK_SLOT_ID * ) pvPortMalloc( sizeof( CK_SLOT_ID ) * xCount ); if( NULL == pxSlotIds ) { xResult = CKR_HOST_MEMORY; } } /* Get all of the available private key slot identities. */ if( CKR_OK == xResult ) { xResult = ( BaseType_t ) pxCtx->pxP11FunctionList->C_GetSlotList( CK_TRUE, pxSlotIds, &xCount ); } /* Put the module in authenticated mode. */ if( CKR_OK == xResult ) { xResult = ( BaseType_t ) pxCtx->pxP11FunctionList->C_Login( pxCtx->xP11Session, CKU_USER, ( CK_UTF8CHAR_PTR ) configPKCS11_DEFAULT_USER_PIN, sizeof( configPKCS11_DEFAULT_USER_PIN ) - 1 ); } if( CKR_OK == xResult ) { /* Get the handle of the device private key. */ xResult = xFindObjectWithLabelAndClass( pxCtx->xP11Session, pcLabelName, strnlen( pcLabelName, pkcs11configMAX_LABEL_LENGTH ), CKO_PRIVATE_KEY, &pxCtx->xP11PrivateKey ); } if( ( CKR_OK == xResult ) && ( pxCtx->xP11PrivateKey == CK_INVALID_HANDLE ) ) { xResult = CK_INVALID_HANDLE; LogError( ( "Could not find private key." ) ); } if( xResult == CKR_OK ) { xResult = xPKCS11_initMbedtlsPkContext( &( pxCtx->privKey ), pxCtx->xP11Session, pxCtx->xP11PrivateKey ); } /* Free memory. */ vPortFree( pxSlotIds ); return xResult; } /*-----------------------------------------------------------*/ TlsTransportStatus_t TLS_FreeRTOS_Connect( NetworkContext_t * pNetworkContext, const char * pHostName, uint16_t port, const NetworkCredentials_t * pNetworkCredentials, uint32_t receiveTimeoutMs, uint32_t sendTimeoutMs ) { TlsTransportParams_t * pTlsTransportParams = NULL; TlsTransportStatus_t returnStatus = TLS_TRANSPORT_SUCCESS; BaseType_t socketStatus = 0; BaseType_t isSocketConnected = pdFALSE; if( ( pNetworkContext == NULL ) || ( pNetworkContext->pParams == NULL ) || ( pHostName == NULL ) || ( pNetworkCredentials == NULL ) ) { LogError( ( "Invalid input parameter(s): Arguments cannot be NULL. pNetworkContext=%p, " "pHostName=%p, pNetworkCredentials=%p.", pNetworkContext, pHostName, pNetworkCredentials ) ); returnStatus = TLS_TRANSPORT_INVALID_PARAMETER; } else if( ( pNetworkCredentials->pRootCa == NULL ) ) { LogError( ( "pRootCa cannot be NULL." ) ); returnStatus = TLS_TRANSPORT_INVALID_PARAMETER; } else { /* Empty else for MISRA 15.7 compliance. */ } /* Establish a TCP connection with the server. */ if( returnStatus == TLS_TRANSPORT_SUCCESS ) { pTlsTransportParams = pNetworkContext->pParams; /* Initialize tcpSocket. */ pTlsTransportParams->tcpSocket = NULL; socketStatus = TCP_Sockets_Connect( &( pTlsTransportParams->tcpSocket ), pHostName, port, receiveTimeoutMs, sendTimeoutMs ); if( socketStatus != 0 ) { LogError( ( "Failed to connect to %s with error %d.", pHostName, socketStatus ) ); returnStatus = TLS_TRANSPORT_CONNECT_FAILURE; } } /* Perform TLS handshake. */ if( returnStatus == TLS_TRANSPORT_SUCCESS ) { isSocketConnected = pdTRUE; returnStatus = tlsSetup( pNetworkContext, pHostName, pNetworkCredentials ); } /* Clean up on failure. */ if( returnStatus != TLS_TRANSPORT_SUCCESS ) { if( isSocketConnected == pdTRUE ) { TCP_Sockets_Disconnect( pTlsTransportParams->tcpSocket ); pTlsTransportParams->tcpSocket = NULL; } } else { LogInfo( ( "(Network connection %p) Connection to %s established.", pNetworkContext, pHostName ) ); } return returnStatus; } /*-----------------------------------------------------------*/ void TLS_FreeRTOS_Disconnect( NetworkContext_t * pNetworkContext ) { TlsTransportParams_t * pTlsTransportParams = NULL; BaseType_t tlsStatus = 0; if( ( pNetworkContext != NULL ) && ( pNetworkContext->pParams != NULL ) ) { pTlsTransportParams = pNetworkContext->pParams; /* Attempting to terminate TLS connection. */ tlsStatus = ( BaseType_t ) mbedtls_ssl_close_notify( &( pTlsTransportParams->sslContext.context ) ); /* Ignore the WANT_READ and WANT_WRITE return values. */ if( ( tlsStatus != ( BaseType_t ) MBEDTLS_ERR_SSL_WANT_READ ) && ( tlsStatus != ( BaseType_t ) MBEDTLS_ERR_SSL_WANT_WRITE ) ) { if( tlsStatus == 0 ) { LogInfo( ( "(Network connection %p) TLS close-notify sent.", pNetworkContext ) ); } else { LogError( ( "(Network connection %p) Failed to send TLS close-notify: mbedTLSError= %s : %s.", pNetworkContext, mbedtlsHighLevelCodeOrDefault( tlsStatus ), mbedtlsLowLevelCodeOrDefault( tlsStatus ) ) ); } } /* Call socket shutdown function to close connection. */ TCP_Sockets_Disconnect( pTlsTransportParams->tcpSocket ); /* Free mbed TLS contexts. */ sslContextFree( &( pTlsTransportParams->sslContext ) ); } } /*-----------------------------------------------------------*/ int32_t TLS_FreeRTOS_recv( NetworkContext_t * pNetworkContext, void * pBuffer, size_t bytesToRecv ) { TlsTransportParams_t * pTlsTransportParams = NULL; int32_t tlsStatus = 0; if( ( pNetworkContext == NULL ) || ( pNetworkContext->pParams == NULL ) ) { LogError( ( "invalid input, pNetworkContext=%p", pNetworkContext ) ); tlsStatus = -1; } else if( pBuffer == NULL ) { LogError( ( "invalid input, pBuffer == NULL" ) ); tlsStatus = -1; } else if( bytesToRecv == 0 ) { LogError( ( "invalid input, bytesToRecv == 0" ) ); tlsStatus = -1; } else { pTlsTransportParams = pNetworkContext->pParams; tlsStatus = ( int32_t ) mbedtls_ssl_read( &( pTlsTransportParams->sslContext.context ), pBuffer, bytesToRecv ); if( ( tlsStatus == MBEDTLS_ERR_SSL_TIMEOUT ) || ( tlsStatus == MBEDTLS_ERR_SSL_WANT_READ ) || ( tlsStatus == MBEDTLS_ERR_SSL_WANT_WRITE ) ) { LogDebug( ( "Failed to read data. However, a read can be retried on this error. " "mbedTLSError= %s : %s.", mbedtlsHighLevelCodeOrDefault( tlsStatus ), mbedtlsLowLevelCodeOrDefault( tlsStatus ) ) ); /* Mark these set of errors as a timeout. The libraries may retry read * on these errors. */ tlsStatus = 0; } else if( tlsStatus < 0 ) { LogError( ( "Failed to read data: mbedTLSError= %s : %s.", mbedtlsHighLevelCodeOrDefault( tlsStatus ), mbedtlsLowLevelCodeOrDefault( tlsStatus ) ) ); } else { /* Empty else marker. */ } } return tlsStatus; } /*-----------------------------------------------------------*/ int32_t TLS_FreeRTOS_send( NetworkContext_t * pNetworkContext, const void * pBuffer, size_t bytesToSend ) { TlsTransportParams_t * pTlsTransportParams = NULL; int32_t tlsStatus = 0; if( ( pNetworkContext == NULL ) || ( pNetworkContext->pParams == NULL ) ) { LogError( ( "invalid input, pNetworkContext=%p", pNetworkContext ) ); tlsStatus = -1; } else if( pBuffer == NULL ) { LogError( ( "invalid input, pBuffer == NULL" ) ); tlsStatus = -1; } else if( bytesToSend == 0 ) { LogError( ( "invalid input, bytesToSend == 0" ) ); tlsStatus = -1; } else { pTlsTransportParams = pNetworkContext->pParams; tlsStatus = ( int32_t ) mbedtls_ssl_write( &( pTlsTransportParams->sslContext.context ), pBuffer, bytesToSend ); if( ( tlsStatus == MBEDTLS_ERR_SSL_TIMEOUT ) || ( tlsStatus == MBEDTLS_ERR_SSL_WANT_READ ) || ( tlsStatus == MBEDTLS_ERR_SSL_WANT_WRITE ) ) { LogDebug( ( "Failed to send data. However, send can be retried on this error. " "mbedTLSError= %s : %s.", mbedtlsHighLevelCodeOrDefault( tlsStatus ), mbedtlsLowLevelCodeOrDefault( tlsStatus ) ) ); /* Mark these set of errors as a timeout. The libraries may retry send * on these errors. */ tlsStatus = 0; } else if( tlsStatus < 0 ) { LogError( ( "Failed to send data: mbedTLSError= %s : %s.", mbedtlsHighLevelCodeOrDefault( tlsStatus ), mbedtlsLowLevelCodeOrDefault( tlsStatus ) ) ); } else { /* Empty else marker. */ } } return tlsStatus; } /*-----------------------------------------------------------*/