/* --COPYRIGHT--,BSD * Copyright (c) 2014, Texas Instruments Incorporated * 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 Texas Instruments Incorporated 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. * --/COPYRIGHT--*/ //***************************************************************************** // // aes256.c - Driver for the aes256 Module. // //***************************************************************************** //***************************************************************************** // //! \addtogroup aes256_api aes256 //! @{ // //***************************************************************************** #include "inc/hw_regaccess.h" #include "inc/hw_memmap.h" #ifdef __MSP430_HAS_AES256__ #include "aes256.h" #include uint8_t AES256_setCipherKey(uint16_t baseAddress, const uint8_t * cipherKey, uint16_t keyLength) { uint8_t i; uint16_t sCipherKey; HWREG16(baseAddress + OFS_AESACTL0) &= (~(AESKL_1 + AESKL_2)); switch(keyLength) { case AES256_KEYLENGTH_128BIT: HWREG16(baseAddress + OFS_AESACTL0) |= AESKL__128; break; case AES256_KEYLENGTH_192BIT: HWREG16(baseAddress + OFS_AESACTL0) |= AESKL__192; break; case AES256_KEYLENGTH_256BIT: HWREG16(baseAddress + OFS_AESACTL0) |= AESKL__256; break; default: return(STATUS_FAIL); } keyLength = keyLength / 8; for(i = 0; i < keyLength; i = i + 2) { sCipherKey = (uint16_t)(cipherKey[i]); sCipherKey = sCipherKey | ((uint16_t)(cipherKey[i + 1]) << 8); HWREG16(baseAddress + OFS_AESAKEY) = sCipherKey; } // Wait until key is written while(0x00 == (HWREG16(baseAddress + OFS_AESASTAT) & AESKEYWR)) { ; } return(STATUS_SUCCESS); } void AES256_encryptData(uint16_t baseAddress, const uint8_t * data, uint8_t * encryptedData) { uint8_t i; uint16_t tempData = 0; uint16_t tempVariable = 0; // Set module to encrypt mode HWREG16(baseAddress + OFS_AESACTL0) &= ~AESOP_3; // Write data to encrypt to module for(i = 0; i < 16; i = i + 2) { tempVariable = (uint16_t)(data[i]); tempVariable = tempVariable | ((uint16_t)(data[i + 1]) << 8); HWREG16(baseAddress + OFS_AESADIN) = tempVariable; } // Key that is already written shall be used // Encryption is initialized by setting AESKEYWR to 1 HWREG16(baseAddress + OFS_AESASTAT) |= AESKEYWR; // Wait unit finished ~167 MCLK while(AESBUSY == (HWREG16(baseAddress + OFS_AESASTAT) & AESBUSY)) { ; } // Write encrypted data back to variable for(i = 0; i < 16; i = i + 2) { tempData = HWREG16(baseAddress + OFS_AESADOUT); *(encryptedData + i) = (uint8_t)tempData; *(encryptedData + i + 1) = (uint8_t)(tempData >> 8); } } void AES256_decryptData(uint16_t baseAddress, const uint8_t * data, uint8_t * decryptedData) { uint8_t i; uint16_t tempData = 0; uint16_t tempVariable = 0; // Set module to decrypt mode HWREG16(baseAddress + OFS_AESACTL0) |= (AESOP_3); // Write data to decrypt to module for(i = 0; i < 16; i = i + 2) { tempVariable = (uint16_t)(data[i + 1] << 8); tempVariable = tempVariable | ((uint16_t)(data[i])); HWREG16(baseAddress + OFS_AESADIN) = tempVariable; } // Key that is already written shall be used // Now decryption starts HWREG16(baseAddress + OFS_AESASTAT) |= AESKEYWR; // Wait unit finished ~167 MCLK while(AESBUSY == (HWREG16(baseAddress + OFS_AESASTAT) & AESBUSY)) { ; } // Write encrypted data back to variable for(i = 0; i < 16; i = i + 2) { tempData = HWREG16(baseAddress + OFS_AESADOUT); *(decryptedData + i) = (uint8_t)tempData; *(decryptedData + i + 1) = (uint8_t)(tempData >> 8); } } uint8_t AES256_setDecipherKey(uint16_t baseAddress, const uint8_t * cipherKey, uint16_t keyLength) { uint8_t i; uint16_t tempVariable = 0; // Set module to decrypt mode HWREG16(baseAddress + OFS_AESACTL0) &= ~(AESOP0); HWREG16(baseAddress + OFS_AESACTL0) |= AESOP1; switch(keyLength) { case AES256_KEYLENGTH_128BIT: HWREG16(baseAddress + OFS_AESACTL0) |= AESKL__128; break; case AES256_KEYLENGTH_192BIT: HWREG16(baseAddress + OFS_AESACTL0) |= AESKL__192; break; case AES256_KEYLENGTH_256BIT: HWREG16(baseAddress + OFS_AESACTL0) |= AESKL__256; break; default: return(STATUS_FAIL); } keyLength = keyLength / 8; // Write cipher key to key register for(i = 0; i < keyLength; i = i + 2) { tempVariable = (uint16_t)(cipherKey[i]); tempVariable = tempVariable | ((uint16_t)(cipherKey[i + 1]) << 8); HWREG16(baseAddress + OFS_AESAKEY) = tempVariable; } // Wait until key is processed ~52 MCLK while((HWREG16(baseAddress + OFS_AESASTAT) & AESBUSY) == AESBUSY) { ; } return(STATUS_SUCCESS); } void AES256_clearInterrupt(uint16_t baseAddress) { HWREG16(baseAddress + OFS_AESACTL0) &= ~AESRDYIFG; } uint32_t AES256_getInterruptStatus(uint16_t baseAddress) { return ((HWREG16(baseAddress + OFS_AESACTL0) & AESRDYIFG) << 0x04); } void AES256_enableInterrupt(uint16_t baseAddress) { HWREG16(baseAddress + OFS_AESACTL0) |= AESRDYIE; } void AES256_disableInterrupt(uint16_t baseAddress) { HWREG16(baseAddress + OFS_AESACTL0) &= ~AESRDYIE; } void AES256_reset(uint16_t baseAddress) { HWREG16(baseAddress + OFS_AESACTL0) |= AESSWRST; } void AES256_startEncryptData(uint16_t baseAddress, const uint8_t * data) { uint8_t i; uint16_t tempVariable = 0; // Set module to encrypt mode HWREG16(baseAddress + OFS_AESACTL0) &= ~AESOP_3; // Write data to encrypt to module for(i = 0; i < 16; i = i + 2) { tempVariable = (uint16_t)(data[i]); tempVariable = tempVariable | ((uint16_t)(data[i + 1 ]) << 8); HWREG16(baseAddress + OFS_AESADIN) = tempVariable; } // Key that is already written shall be used // Encryption is initialized by setting AESKEYWR to 1 HWREG16(baseAddress + OFS_AESASTAT) |= AESKEYWR; } void AES256_startDecryptData(uint16_t baseAddress, const uint8_t * data) { uint8_t i; uint16_t tempVariable = 0; // Set module to decrypt mode HWREG16(baseAddress + OFS_AESACTL0) |= (AESOP_3); // Write data to decrypt to module for(i = 0; i < 16; i = i + 2) { tempVariable = (uint16_t)(data[i + 1] << 8); tempVariable = tempVariable | ((uint16_t)(data[i])); HWREG16(baseAddress + OFS_AESADIN) = tempVariable; } // Key that is already written shall be used // Now decryption starts HWREG16(baseAddress + OFS_AESASTAT) |= AESKEYWR; } uint8_t AES256_startSetDecipherKey(uint16_t baseAddress, const uint8_t * cipherKey, uint16_t keyLength) { uint8_t i; uint16_t tempVariable = 0; HWREG16(baseAddress + OFS_AESACTL0) &= ~(AESOP0); HWREG16(baseAddress + OFS_AESACTL0) |= AESOP1; switch(keyLength) { case AES256_KEYLENGTH_128BIT: HWREG16(baseAddress + OFS_AESACTL0) |= AESKL__128; break; case AES256_KEYLENGTH_192BIT: HWREG16(baseAddress + OFS_AESACTL0) |= AESKL__192; break; case AES256_KEYLENGTH_256BIT: HWREG16(baseAddress + OFS_AESACTL0) |= AESKL__256; break; default: return(STATUS_FAIL); } keyLength = keyLength / 8; // Write cipher key to key register for(i = 0; i < keyLength; i = i + 2) { tempVariable = (uint16_t)(cipherKey[i]); tempVariable = tempVariable | ((uint16_t)(cipherKey[i + 1]) << 8); HWREG16(baseAddress + OFS_AESAKEY) = tempVariable; } return(STATUS_SUCCESS); } uint8_t AES256_getDataOut(uint16_t baseAddress, uint8_t *outputData) { uint8_t i; uint16_t tempData = 0; // If module is busy, exit and return failure if(AESBUSY == (HWREG16(baseAddress + OFS_AESASTAT) & AESBUSY)) { return(STATUS_FAIL); } // Write encrypted data back to variable for(i = 0; i < 16; i = i + 2) { tempData = HWREG16(baseAddress + OFS_AESADOUT); *(outputData + i) = (uint8_t)tempData; *(outputData + i + 1) = (uint8_t)(tempData >> 8); } return(STATUS_SUCCESS); } uint16_t AES256_isBusy(uint16_t baseAddress) { return (HWREG16(baseAddress + OFS_AESASTAT) & AESBUSY); } void AES256_clearErrorFlag(uint16_t baseAddress) { HWREG16(baseAddress + OFS_AESACTL0) &= ~AESERRFG; } uint32_t AES256_getErrorFlagStatus(uint16_t baseAddress) { return (HWREG16(baseAddress + OFS_AESACTL0) & AESERRFG); } #endif //***************************************************************************** // //! Close the doxygen group for aes256_api //! @} // //*****************************************************************************