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Diff: TARGET_KL82Z/TOOLCHAIN_IAR/fsl_ltc.h
- Revision:
- 171:3a7713b1edbc
- Parent:
- 145:64910690c574
--- /dev/null Thu Jan 01 00:00:00 1970 +0000 +++ b/TARGET_KL82Z/TOOLCHAIN_IAR/fsl_ltc.h Thu Nov 08 11:45:42 2018 +0000 @@ -0,0 +1,1575 @@ +/* + * Copyright (c) 2015-2016, Freescale Semiconductor, Inc. + * All rights reserved. + * + * Redistribution and use in source and binary forms, with or without modification, + * are permitted provided that the following conditions are met: + * + * o Redistributions of source code must retain the above copyright notice, this list + * of conditions and the following disclaimer. + * + * o 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. + * + * o Neither the name of Freescale Semiconductor, Inc. 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 HOLDER 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. + */ +#ifndef _FSL_LTC_H_ +#define _FSL_LTC_H_ + +#include "fsl_common.h" + +/******************************************************************************* + * Definitions + *******************************************************************************/ + +/*! + * @addtogroup ltc + * @{ + */ +/*! @name Driver version */ +/*@{*/ +/*! @brief LTC driver version. Version 2.0.1. + * + * Current version: 2.0.1 + * + * Change log: + * - Version 2.0.1 + * - fixed warning during g++ compilation + */ +#define FSL_LTC_DRIVER_VERSION (MAKE_VERSION(2, 0, 1)) +/*@}*/ +/*! @} */ + +/******************************************************************************* + * AES Definitions + *******************************************************************************/ +/*! + * @addtogroup ltc_driver_aes + * @{ + */ +/*! AES block size in bytes */ +#define LTC_AES_BLOCK_SIZE 16 +/*! AES Input Vector size in bytes */ +#define LTC_AES_IV_SIZE 16 + +/*! @brief Type of AES key for ECB and CBC decrypt operations. */ +typedef enum _ltc_aes_key_t +{ + kLTC_EncryptKey = 0U, /*!< Input key is an encrypt key */ + kLTC_DecryptKey = 1U, /*!< Input key is a decrypt key */ +} ltc_aes_key_t; + +/*! + *@} + */ + +/******************************************************************************* + * DES Definitions + *******************************************************************************/ +/*! + * @addtogroup ltc_driver_des + * @{ + */ + +/*! @brief LTC DES key size - 64 bits. */ +#define LTC_DES_KEY_SIZE 8 + +/*! @brief LTC DES IV size - 8 bytes */ +#define LTC_DES_IV_SIZE 8 + +/*! + *@} + */ + +/******************************************************************************* + * HASH Definitions + ******************************************************************************/ +/*! + * @addtogroup ltc_driver_hash + * @{ + */ +/*! Supported cryptographic block cipher functions for HASH creation */ +typedef enum _ltc_hash_algo_t +{ + kLTC_XcbcMac = 0, /*!< XCBC-MAC (AES engine) */ + kLTC_Cmac, /*!< CMAC (AES engine) */ +#if defined(FSL_FEATURE_LTC_HAS_SHA) && FSL_FEATURE_LTC_HAS_SHA + kLTC_Sha1, /*!< SHA_1 (MDHA engine) */ + kLTC_Sha224, /*!< SHA_224 (MDHA engine) */ + kLTC_Sha256, /*!< SHA_256 (MDHA engine) */ +#endif /* FSL_FEATURE_LTC_HAS_SHA */ +} ltc_hash_algo_t; + +/*! @brief LTC HASH Context size. */ +#if defined(FSL_FEATURE_LTC_HAS_SHA) && FSL_FEATURE_LTC_HAS_SHA +#define LTC_HASH_CTX_SIZE 41 +#else +#define LTC_HASH_CTX_SIZE 29 +#endif /* FSL_FEATURE_LTC_HAS_SHA */ + +/*! @brief Storage type used to save hash context. */ +typedef uint32_t ltc_hash_ctx_t[LTC_HASH_CTX_SIZE]; + +/*! + *@} + */ +/******************************************************************************* + * PKHA Definitions + ******************************************************************************/ +/*! + * @addtogroup ltc_driver_pkha + * @{ + */ +/*! PKHA ECC point structure */ +typedef struct _ltc_pkha_ecc_point_t +{ + uint8_t *X; /*!< X coordinate (affine) */ + uint8_t *Y; /*!< Y coordinate (affine) */ +} ltc_pkha_ecc_point_t; + +/*! @brief Use of timing equalized version of a PKHA function. */ +typedef enum _ltc_pkha_timing_t +{ + kLTC_PKHA_NoTimingEqualized = 0U, /*!< Normal version of a PKHA operation */ + kLTC_PKHA_TimingEqualized = 1U /*!< Timing-equalized version of a PKHA operation */ +} ltc_pkha_timing_t; + +/*! @brief Integer vs binary polynomial arithmetic selection. */ +typedef enum _ltc_pkha_f2m_t +{ + kLTC_PKHA_IntegerArith = 0U, /*!< Use integer arithmetic */ + kLTC_PKHA_F2mArith = 1U /*!< Use binary polynomial arithmetic */ +} ltc_pkha_f2m_t; + +/*! @brief Montgomery or normal PKHA input format. */ +typedef enum _ltc_pkha_montgomery_form_t +{ + kLTC_PKHA_NormalValue = 0U, /*!< PKHA number is normal integer */ + kLTC_PKHA_MontgomeryFormat = 1U /*!< PKHA number is in montgomery format */ +} ltc_pkha_montgomery_form_t; + +/*! + *@} + */ + +/******************************************************************************* + * API + ******************************************************************************/ + +#if defined(__cplusplus) +extern "C" { +#endif + +/*! + * @addtogroup ltc + * @{ + */ + +/*! + * @brief Initializes the LTC driver. + * This function initializes the LTC driver. + * @param base LTC peripheral base address + */ +void LTC_Init(LTC_Type *base); + +/*! + * @brief Deinitializes the LTC driver. + * This function deinitializes the LTC driver. + * @param base LTC peripheral base address + */ +void LTC_Deinit(LTC_Type *base); + +#if defined(FSL_FEATURE_LTC_HAS_DPAMS) && FSL_FEATURE_LTC_HAS_DPAMS +/*! + * @brief Sets the DPA Mask Seed register. + * + * The DPA Mask Seed register reseeds the mask that provides resistance against DPA (differential power analysis) + * attacks on AES or DES keys. + * + * Differential Power Analysis Mask (DPA) resistance uses a randomly changing mask that introduces + * "noise" into the power consumed by the AES or DES. This reduces the signal-to-noise ratio that differential + * power analysis attacks use to "guess" bits of the key. This randomly changing mask should be + * seeded at POR, and continues to provide DPA resistance from that point on. However, to provide even more + * DPA protection it is recommended that the DPA mask be reseeded after every 50,000 blocks have + * been processed. At that time, software can opt to write a new seed (preferably obtained from an RNG) + * into the DPA Mask Seed register (DPAMS), or software can opt to provide the new seed earlier or + * later, or not at all. DPA resistance continues even if the DPA mask is never reseeded. + * + * @param base LTC peripheral base address + * @param mask The DPA mask seed. + */ +void LTC_SetDpaMaskSeed(LTC_Type *base, uint32_t mask); +#endif /* FSL_FEATURE_LTC_HAS_DPAMS */ + +/*! + *@} + */ + +/******************************************************************************* + * AES API + ******************************************************************************/ + +/*! + * @addtogroup ltc_driver_aes + * @{ + */ + +/*! + * @brief Transforms an AES encrypt key (forward AES) into the decrypt key (inverse AES). + * + * Transforms the AES encrypt key (forward AES) into the decrypt key (inverse AES). + * The key derived by this function can be used as a direct load decrypt key + * for AES ECB and CBC decryption operations (keyType argument). + * + * @param base LTC peripheral base address + * @param encryptKey Input key for decrypt key transformation + * @param[out] decryptKey Output key, the decrypt form of the AES key. + * @param keySize Size of the input key and output key in bytes. Must be 16, 24, or 32. + * @return Status from key generation operation + */ +status_t LTC_AES_GenerateDecryptKey(LTC_Type *base, const uint8_t *encryptKey, uint8_t *decryptKey, uint32_t keySize); + +/*! + * @brief Encrypts AES using the ECB block mode. + * + * Encrypts AES using the ECB block mode. + * + * @param base LTC peripheral base address + * @param plaintext Input plain text to encrypt + * @param[out] ciphertext Output cipher text + * @param size Size of input and output data in bytes. Must be multiple of 16 bytes. + * @param key Input key to use for encryption + * @param keySize Size of the input key, in bytes. Must be 16, 24, or 32. + * @return Status from encrypt operation + */ +status_t LTC_AES_EncryptEcb( + LTC_Type *base, const uint8_t *plaintext, uint8_t *ciphertext, uint32_t size, const uint8_t *key, uint32_t keySize); + +/*! + * @brief Decrypts AES using ECB block mode. + * + * Decrypts AES using ECB block mode. + * + * @param base LTC peripheral base address + * @param ciphertext Input cipher text to decrypt + * @param[out] plaintext Output plain text + * @param size Size of input and output data in bytes. Must be multiple of 16 bytes. + * @param key Input key. + * @param keySize Size of the input key, in bytes. Must be 16, 24, or 32. + * @param keyType Input type of the key (allows to directly load decrypt key for AES ECB decrypt operation.) + * @return Status from decrypt operation + */ +status_t LTC_AES_DecryptEcb(LTC_Type *base, + const uint8_t *ciphertext, + uint8_t *plaintext, + uint32_t size, + const uint8_t *key, + uint32_t keySize, + ltc_aes_key_t keyType); + +/*! + * @brief Encrypts AES using CBC block mode. + * + * @param base LTC peripheral base address + * @param plaintext Input plain text to encrypt + * @param[out] ciphertext Output cipher text + * @param size Size of input and output data in bytes. Must be multiple of 16 bytes. + * @param iv Input initial vector to combine with the first input block. + * @param key Input key to use for encryption + * @param keySize Size of the input key, in bytes. Must be 16, 24, or 32. + * @return Status from encrypt operation + */ +status_t LTC_AES_EncryptCbc(LTC_Type *base, + const uint8_t *plaintext, + uint8_t *ciphertext, + uint32_t size, + const uint8_t iv[LTC_AES_IV_SIZE], + const uint8_t *key, + uint32_t keySize); + +/*! + * @brief Decrypts AES using CBC block mode. + * + * @param base LTC peripheral base address + * @param ciphertext Input cipher text to decrypt + * @param[out] plaintext Output plain text + * @param size Size of input and output data in bytes. Must be multiple of 16 bytes. + * @param iv Input initial vector to combine with the first input block. + * @param key Input key to use for decryption + * @param keySize Size of the input key, in bytes. Must be 16, 24, or 32. + * @param keyType Input type of the key (allows to directly load decrypt key for AES CBC decrypt operation.) + * @return Status from decrypt operation + */ +status_t LTC_AES_DecryptCbc(LTC_Type *base, + const uint8_t *ciphertext, + uint8_t *plaintext, + uint32_t size, + const uint8_t iv[LTC_AES_IV_SIZE], + const uint8_t *key, + uint32_t keySize, + ltc_aes_key_t keyType); + +/*! + * @brief Encrypts or decrypts AES using CTR block mode. + * + * Encrypts or decrypts AES using CTR block mode. + * AES CTR mode uses only forward AES cipher and same algorithm for encryption and decryption. + * The only difference between encryption and decryption is that, for encryption, the input argument + * is plain text and the output argument is cipher text. For decryption, the input argument is cipher text + * and the output argument is plain text. + * + * @param base LTC peripheral base address + * @param input Input data for CTR block mode + * @param[out] output Output data for CTR block mode + * @param size Size of input and output data in bytes + * @param[in,out] counter Input counter (updates on return) + * @param key Input key to use for forward AES cipher + * @param keySize Size of the input key, in bytes. Must be 16, 24, or 32. + * @param[out] counterlast Output cipher of last counter, for chained CTR calls. NULL can be passed if chained calls are + * not used. + * @param[out] szLeft Output number of bytes in left unused in counterlast block. NULL can be passed if chained calls + * are not used. + * @return Status from encrypt operation + */ +status_t LTC_AES_CryptCtr(LTC_Type *base, + const uint8_t *input, + uint8_t *output, + uint32_t size, + uint8_t counter[LTC_AES_BLOCK_SIZE], + const uint8_t *key, + uint32_t keySize, + uint8_t counterlast[LTC_AES_BLOCK_SIZE], + uint32_t *szLeft); + +/*! AES CTR decrypt is mapped to the AES CTR generic operation */ +#define LTC_AES_DecryptCtr(base, input, output, size, counter, key, keySize, counterlast, szLeft) \ + LTC_AES_CryptCtr(base, input, output, size, counter, key, keySize, counterlast, szLeft) + +/*! AES CTR encrypt is mapped to the AES CTR generic operation */ +#define LTC_AES_EncryptCtr(base, input, output, size, counter, key, keySize, counterlast, szLeft) \ + LTC_AES_CryptCtr(base, input, output, size, counter, key, keySize, counterlast, szLeft) + +#if defined(FSL_FEATURE_LTC_HAS_GCM) && FSL_FEATURE_LTC_HAS_GCM +/*! + * @brief Encrypts AES and tags using GCM block mode. + * + * Encrypts AES and optionally tags using GCM block mode. If plaintext is NULL, only the GHASH is calculated and output + * in the 'tag' field. + * + * @param base LTC peripheral base address + * @param plaintext Input plain text to encrypt + * @param[out] ciphertext Output cipher text. + * @param size Size of input and output data in bytes + * @param iv Input initial vector + * @param ivSize Size of the IV + * @param aad Input additional authentication data + * @param aadSize Input size in bytes of AAD + * @param key Input key to use for encryption + * @param keySize Size of the input key, in bytes. Must be 16, 24, or 32. + * @param[out] tag Output hash tag. Set to NULL to skip tag processing. + * @param tagSize Input size of the tag to generate, in bytes. Must be 4,8,12,13,14,15 or 16. + * @return Status from encrypt operation + */ +status_t LTC_AES_EncryptTagGcm(LTC_Type *base, + const uint8_t *plaintext, + uint8_t *ciphertext, + uint32_t size, + const uint8_t *iv, + uint32_t ivSize, + const uint8_t *aad, + uint32_t aadSize, + const uint8_t *key, + uint32_t keySize, + uint8_t *tag, + uint32_t tagSize); + +/*! + * @brief Decrypts AES and authenticates using GCM block mode. + * + * Decrypts AES and optionally authenticates using GCM block mode. If ciphertext is NULL, only the GHASH is calculated + * and compared with the received GHASH in 'tag' field. + * + * @param base LTC peripheral base address + * @param ciphertext Input cipher text to decrypt + * @param[out] plaintext Output plain text. + * @param size Size of input and output data in bytes + * @param iv Input initial vector + * @param ivSize Size of the IV + * @param aad Input additional authentication data + * @param aadSize Input size in bytes of AAD + * @param key Input key to use for encryption + * @param keySize Size of the input key, in bytes. Must be 16, 24, or 32. + * @param tag Input hash tag to compare. Set to NULL to skip tag processing. + * @param tagSize Input size of the tag, in bytes. Must be 4, 8, 12, 13, 14, 15, or 16. + * @return Status from decrypt operation + */ +status_t LTC_AES_DecryptTagGcm(LTC_Type *base, + const uint8_t *ciphertext, + uint8_t *plaintext, + uint32_t size, + const uint8_t *iv, + uint32_t ivSize, + const uint8_t *aad, + uint32_t aadSize, + const uint8_t *key, + uint32_t keySize, + const uint8_t *tag, + uint32_t tagSize); +#endif /* FSL_FEATURE_LTC_HAS_GCM */ + +/*! + * @brief Encrypts AES and tags using CCM block mode. + * + * Encrypts AES and optionally tags using CCM block mode. + * + * @param base LTC peripheral base address + * @param plaintext Input plain text to encrypt + * @param[out] ciphertext Output cipher text. + * @param size Size of input and output data in bytes. Zero means authentication only. + * @param iv Nonce + * @param ivSize Length of the Nonce in bytes. Must be 7, 8, 9, 10, 11, 12, or 13. + * @param aad Input additional authentication data. Can be NULL if aadSize is zero. + * @param aadSize Input size in bytes of AAD. Zero means data mode only (authentication skipped). + * @param key Input key to use for encryption + * @param keySize Size of the input key, in bytes. Must be 16, 24, or 32. + * @param[out] tag Generated output tag. Set to NULL to skip tag processing. + * @param tagSize Input size of the tag to generate, in bytes. Must be 4, 6, 8, 10, 12, 14, or 16. + * @return Status from encrypt operation + */ +status_t LTC_AES_EncryptTagCcm(LTC_Type *base, + const uint8_t *plaintext, + uint8_t *ciphertext, + uint32_t size, + const uint8_t *iv, + uint32_t ivSize, + const uint8_t *aad, + uint32_t aadSize, + const uint8_t *key, + uint32_t keySize, + uint8_t *tag, + uint32_t tagSize); + +/*! + * @brief Decrypts AES and authenticates using CCM block mode. + * + * Decrypts AES and optionally authenticates using CCM block mode. + * + * @param base LTC peripheral base address + * @param ciphertext Input cipher text to decrypt + * @param[out] plaintext Output plain text. + * @param size Size of input and output data in bytes. Zero means authentication only. + * @param iv Nonce + * @param ivSize Length of the Nonce in bytes. Must be 7, 8, 9, 10, 11, 12, or 13. + * @param aad Input additional authentication data. Can be NULL if aadSize is zero. + * @param aadSize Input size in bytes of AAD. Zero means data mode only (authentication skipped). + * @param key Input key to use for decryption + * @param keySize Size of the input key, in bytes. Must be 16, 24, or 32. + * @param tag Received tag. Set to NULL to skip tag processing. + * @param tagSize Input size of the received tag to compare with the computed tag, in bytes. Must be 4, 6, 8, 10, 12, + * 14, or 16. + * @return Status from decrypt operation + */ +status_t LTC_AES_DecryptTagCcm(LTC_Type *base, + const uint8_t *ciphertext, + uint8_t *plaintext, + uint32_t size, + const uint8_t *iv, + uint32_t ivSize, + const uint8_t *aad, + uint32_t aadSize, + const uint8_t *key, + uint32_t keySize, + const uint8_t *tag, + uint32_t tagSize); + +/*! + *@} + */ + +/******************************************************************************* + * DES API + ******************************************************************************/ +/*! + * @addtogroup ltc_driver_des + * @{ + */ +/*! + * @brief Encrypts DES using ECB block mode. + * + * Encrypts DES using ECB block mode. + * + * @param base LTC peripheral base address + * @param plaintext Input plaintext to encrypt + * @param[out] ciphertext Output ciphertext + * @param size Size of input and output data in bytes. Must be multiple of 8 bytes. + * @param key Input key to use for encryption + * @return Status from encrypt/decrypt operation + */ +status_t LTC_DES_EncryptEcb( + LTC_Type *base, const uint8_t *plaintext, uint8_t *ciphertext, uint32_t size, const uint8_t key[LTC_DES_KEY_SIZE]); + +/*! + * @brief Decrypts DES using ECB block mode. + * + * Decrypts DES using ECB block mode. + * + * @param base LTC peripheral base address + * @param ciphertext Input ciphertext to decrypt + * @param[out] plaintext Output plaintext + * @param size Size of input and output data in bytes. Must be multiple of 8 bytes. + * @param key Input key to use for decryption + * @return Status from encrypt/decrypt operation + */ +status_t LTC_DES_DecryptEcb( + LTC_Type *base, const uint8_t *ciphertext, uint8_t *plaintext, uint32_t size, const uint8_t key[LTC_DES_KEY_SIZE]); + +/*! + * @brief Encrypts DES using CBC block mode. + * + * Encrypts DES using CBC block mode. + * + * @param base LTC peripheral base address + * @param plaintext Input plaintext to encrypt + * @param[out] ciphertext Ouput ciphertext + * @param size Size of input and output data in bytes + * @param iv Input initial vector to combine with the first plaintext block. + * The iv does not need to be secret, but it must be unpredictable. + * @param key Input key to use for encryption + * @return Status from encrypt/decrypt operation + */ +status_t LTC_DES_EncryptCbc(LTC_Type *base, + const uint8_t *plaintext, + uint8_t *ciphertext, + uint32_t size, + const uint8_t iv[LTC_DES_IV_SIZE], + const uint8_t key[LTC_DES_KEY_SIZE]); + +/*! + * @brief Decrypts DES using CBC block mode. + * + * Decrypts DES using CBC block mode. + * + * @param base LTC peripheral base address + * @param ciphertext Input ciphertext to decrypt + * @param[out] plaintext Output plaintext + * @param size Size of input data in bytes + * @param iv Input initial vector to combine with the first plaintext block. + * The iv does not need to be secret, but it must be unpredictable. + * @param key Input key to use for decryption + * @return Status from encrypt/decrypt operation + */ +status_t LTC_DES_DecryptCbc(LTC_Type *base, + const uint8_t *ciphertext, + uint8_t *plaintext, + uint32_t size, + const uint8_t iv[LTC_DES_IV_SIZE], + const uint8_t key[LTC_DES_KEY_SIZE]); + +/*! + * @brief Encrypts DES using CFB block mode. + * + * Encrypts DES using CFB block mode. + * + * @param base LTC peripheral base address + * @param plaintext Input plaintext to encrypt + * @param size Size of input data in bytes + * @param iv Input initial block. + * @param key Input key to use for encryption + * @param[out] ciphertext Output ciphertext + * @return Status from encrypt/decrypt operation + */ +status_t LTC_DES_EncryptCfb(LTC_Type *base, + const uint8_t *plaintext, + uint8_t *ciphertext, + uint32_t size, + const uint8_t iv[LTC_DES_IV_SIZE], + const uint8_t key[LTC_DES_KEY_SIZE]); + +/*! + * @brief Decrypts DES using CFB block mode. + * + * Decrypts DES using CFB block mode. + * + * @param base LTC peripheral base address + * @param ciphertext Input ciphertext to decrypt + * @param[out] plaintext Output plaintext + * @param size Size of input and output data in bytes + * @param iv Input initial block. + * @param key Input key to use for decryption + * @return Status from encrypt/decrypt operation + */ +status_t LTC_DES_DecryptCfb(LTC_Type *base, + const uint8_t *ciphertext, + uint8_t *plaintext, + uint32_t size, + const uint8_t iv[LTC_DES_IV_SIZE], + const uint8_t key[LTC_DES_KEY_SIZE]); + +/*! + * @brief Encrypts DES using OFB block mode. + * + * Encrypts DES using OFB block mode. + * + * @param base LTC peripheral base address + * @param plaintext Input plaintext to encrypt + * @param[out] ciphertext Output ciphertext + * @param size Size of input and output data in bytes + * @param iv Input unique input vector. The OFB mode requires that the IV be unique + * for each execution of the mode under the given key. + * @param key Input key to use for encryption + * @return Status from encrypt/decrypt operation + */ +status_t LTC_DES_EncryptOfb(LTC_Type *base, + const uint8_t *plaintext, + uint8_t *ciphertext, + uint32_t size, + const uint8_t iv[LTC_DES_IV_SIZE], + const uint8_t key[LTC_DES_KEY_SIZE]); + +/*! + * @brief Decrypts DES using OFB block mode. + * + * Decrypts DES using OFB block mode. + * + * @param base LTC peripheral base address + * @param ciphertext Input ciphertext to decrypt + * @param[out] plaintext Output plaintext + * @param size Size of input and output data in bytes. Must be multiple of 8 bytes. + * @param iv Input unique input vector. The OFB mode requires that the IV be unique + * for each execution of the mode under the given key. + * @param key Input key to use for decryption + * @return Status from encrypt/decrypt operation + */ +status_t LTC_DES_DecryptOfb(LTC_Type *base, + const uint8_t *ciphertext, + uint8_t *plaintext, + uint32_t size, + const uint8_t iv[LTC_DES_IV_SIZE], + const uint8_t key[LTC_DES_KEY_SIZE]); + +/*! + * @brief Encrypts triple DES using ECB block mode with two keys. + * + * Encrypts triple DES using ECB block mode with two keys. + * + * @param base LTC peripheral base address + * @param plaintext Input plaintext to encrypt + * @param[out] ciphertext Output ciphertext + * @param size Size of input and output data in bytes. Must be multiple of 8 bytes. + * @param key1 First input key for key bundle + * @param key2 Second input key for key bundle + * @return Status from encrypt/decrypt operation + */ +status_t LTC_DES2_EncryptEcb(LTC_Type *base, + const uint8_t *plaintext, + uint8_t *ciphertext, + uint32_t size, + const uint8_t key1[LTC_DES_KEY_SIZE], + const uint8_t key2[LTC_DES_KEY_SIZE]); + +/*! + * @brief Decrypts triple DES using ECB block mode with two keys. + * + * Decrypts triple DES using ECB block mode with two keys. + * + * @param base LTC peripheral base address + * @param ciphertext Input ciphertext to decrypt + * @param[out] plaintext Output plaintext + * @param size Size of input and output data in bytes. Must be multiple of 8 bytes. + * @param key1 First input key for key bundle + * @param key2 Second input key for key bundle + * @return Status from encrypt/decrypt operation + */ +status_t LTC_DES2_DecryptEcb(LTC_Type *base, + const uint8_t *ciphertext, + uint8_t *plaintext, + uint32_t size, + const uint8_t key1[LTC_DES_KEY_SIZE], + const uint8_t key2[LTC_DES_KEY_SIZE]); + +/*! + * @brief Encrypts triple DES using CBC block mode with two keys. + * + * Encrypts triple DES using CBC block mode with two keys. + * + * @param base LTC peripheral base address + * @param plaintext Input plaintext to encrypt + * @param[out] ciphertext Output ciphertext + * @param size Size of input and output data in bytes + * @param iv Input initial vector to combine with the first plaintext block. + * The iv does not need to be secret, but it must be unpredictable. + * @param key1 First input key for key bundle + * @param key2 Second input key for key bundle + * @return Status from encrypt/decrypt operation + */ +status_t LTC_DES2_EncryptCbc(LTC_Type *base, + const uint8_t *plaintext, + uint8_t *ciphertext, + uint32_t size, + const uint8_t iv[LTC_DES_IV_SIZE], + const uint8_t key1[LTC_DES_KEY_SIZE], + const uint8_t key2[LTC_DES_KEY_SIZE]); + +/*! + * @brief Decrypts triple DES using CBC block mode with two keys. + * + * Decrypts triple DES using CBC block mode with two keys. + * + * @param base LTC peripheral base address + * @param ciphertext Input ciphertext to decrypt + * @param[out] plaintext Output plaintext + * @param size Size of input and output data in bytes + * @param iv Input initial vector to combine with the first plaintext block. + * The iv does not need to be secret, but it must be unpredictable. + * @param key1 First input key for key bundle + * @param key2 Second input key for key bundle + * @return Status from encrypt/decrypt operation + */ +status_t LTC_DES2_DecryptCbc(LTC_Type *base, + const uint8_t *ciphertext, + uint8_t *plaintext, + uint32_t size, + const uint8_t iv[LTC_DES_IV_SIZE], + const uint8_t key1[LTC_DES_KEY_SIZE], + const uint8_t key2[LTC_DES_KEY_SIZE]); + +/*! + * @brief Encrypts triple DES using CFB block mode with two keys. + * + * Encrypts triple DES using CFB block mode with two keys. + * + * @param base LTC peripheral base address + * @param plaintext Input plaintext to encrypt + * @param[out] ciphertext Output ciphertext + * @param size Size of input and output data in bytes + * @param iv Input initial block. + * @param key1 First input key for key bundle + * @param key2 Second input key for key bundle + * @return Status from encrypt/decrypt operation + */ +status_t LTC_DES2_EncryptCfb(LTC_Type *base, + const uint8_t *plaintext, + uint8_t *ciphertext, + uint32_t size, + const uint8_t iv[LTC_DES_IV_SIZE], + const uint8_t key1[LTC_DES_KEY_SIZE], + const uint8_t key2[LTC_DES_KEY_SIZE]); + +/*! + * @brief Decrypts triple DES using CFB block mode with two keys. + * + * Decrypts triple DES using CFB block mode with two keys. + * + * @param base LTC peripheral base address + * @param ciphertext Input ciphertext to decrypt + * @param[out] plaintext Output plaintext + * @param size Size of input and output data in bytes + * @param iv Input initial block. + * @param key1 First input key for key bundle + * @param key2 Second input key for key bundle + * @return Status from encrypt/decrypt operation + */ +status_t LTC_DES2_DecryptCfb(LTC_Type *base, + const uint8_t *ciphertext, + uint8_t *plaintext, + uint32_t size, + const uint8_t iv[LTC_DES_IV_SIZE], + const uint8_t key1[LTC_DES_KEY_SIZE], + const uint8_t key2[LTC_DES_KEY_SIZE]); + +/*! + * @brief Encrypts triple DES using OFB block mode with two keys. + * + * Encrypts triple DES using OFB block mode with two keys. + * + * @param base LTC peripheral base address + * @param plaintext Input plaintext to encrypt + * @param[out] ciphertext Output ciphertext + * @param size Size of input and output data in bytes + * @param iv Input unique input vector. The OFB mode requires that the IV be unique + * for each execution of the mode under the given key. + * @param key1 First input key for key bundle + * @param key2 Second input key for key bundle + * @return Status from encrypt/decrypt operation + */ +status_t LTC_DES2_EncryptOfb(LTC_Type *base, + const uint8_t *plaintext, + uint8_t *ciphertext, + uint32_t size, + const uint8_t iv[LTC_DES_IV_SIZE], + const uint8_t key1[LTC_DES_KEY_SIZE], + const uint8_t key2[LTC_DES_KEY_SIZE]); + +/*! + * @brief Decrypts triple DES using OFB block mode with two keys. + * + * Decrypts triple DES using OFB block mode with two keys. + * + * @param base LTC peripheral base address + * @param ciphertext Input ciphertext to decrypt + * @param[out] plaintext Output plaintext + * @param size Size of input and output data in bytes + * @param iv Input unique input vector. The OFB mode requires that the IV be unique + * for each execution of the mode under the given key. + * @param key1 First input key for key bundle + * @param key2 Second input key for key bundle + * @return Status from encrypt/decrypt operation + */ +status_t LTC_DES2_DecryptOfb(LTC_Type *base, + const uint8_t *ciphertext, + uint8_t *plaintext, + uint32_t size, + const uint8_t iv[LTC_DES_IV_SIZE], + const uint8_t key1[LTC_DES_KEY_SIZE], + const uint8_t key2[LTC_DES_KEY_SIZE]); + +/*! + * @brief Encrypts triple DES using ECB block mode with three keys. + * + * Encrypts triple DES using ECB block mode with three keys. + * + * @param base LTC peripheral base address + * @param plaintext Input plaintext to encrypt + * @param[out] ciphertext Output ciphertext + * @param size Size of input and output data in bytes. Must be multiple of 8 bytes. + * @param key1 First input key for key bundle + * @param key2 Second input key for key bundle + * @param key3 Third input key for key bundle + * @return Status from encrypt/decrypt operation + */ +status_t LTC_DES3_EncryptEcb(LTC_Type *base, + const uint8_t *plaintext, + uint8_t *ciphertext, + uint32_t size, + const uint8_t key1[LTC_DES_KEY_SIZE], + const uint8_t key2[LTC_DES_KEY_SIZE], + const uint8_t key3[LTC_DES_KEY_SIZE]); + +/*! + * @brief Decrypts triple DES using ECB block mode with three keys. + * + * Decrypts triple DES using ECB block mode with three keys. + * + * @param base LTC peripheral base address + * @param ciphertext Input ciphertext to decrypt + * @param[out] plaintext Output plaintext + * @param size Size of input and output data in bytes. Must be multiple of 8 bytes. + * @param key1 First input key for key bundle + * @param key2 Second input key for key bundle + * @param key3 Third input key for key bundle + * @return Status from encrypt/decrypt operation + */ +status_t LTC_DES3_DecryptEcb(LTC_Type *base, + const uint8_t *ciphertext, + uint8_t *plaintext, + uint32_t size, + const uint8_t key1[LTC_DES_KEY_SIZE], + const uint8_t key2[LTC_DES_KEY_SIZE], + const uint8_t key3[LTC_DES_KEY_SIZE]); + +/*! + * @brief Encrypts triple DES using CBC block mode with three keys. + * + * Encrypts triple DES using CBC block mode with three keys. + * + * @param base LTC peripheral base address + * @param plaintext Input plaintext to encrypt + * @param[out] ciphertext Output ciphertext + * @param size Size of input data in bytes + * @param iv Input initial vector to combine with the first plaintext block. + * The iv does not need to be secret, but it must be unpredictable. + * @param key1 First input key for key bundle + * @param key2 Second input key for key bundle + * @param key3 Third input key for key bundle + * @return Status from encrypt/decrypt operation + */ +status_t LTC_DES3_EncryptCbc(LTC_Type *base, + const uint8_t *plaintext, + uint8_t *ciphertext, + uint32_t size, + const uint8_t iv[LTC_DES_IV_SIZE], + const uint8_t key1[LTC_DES_KEY_SIZE], + const uint8_t key2[LTC_DES_KEY_SIZE], + const uint8_t key3[LTC_DES_KEY_SIZE]); + +/*! + * @brief Decrypts triple DES using CBC block mode with three keys. + * + * Decrypts triple DES using CBC block mode with three keys. + * + * @param base LTC peripheral base address + * @param ciphertext Input ciphertext to decrypt + * @param[out] plaintext Output plaintext + * @param size Size of input and output data in bytes + * @param iv Input initial vector to combine with the first plaintext block. + * The iv does not need to be secret, but it must be unpredictable. + * @param key1 First input key for key bundle + * @param key2 Second input key for key bundle + * @param key3 Third input key for key bundle + * @return Status from encrypt/decrypt operation + */ +status_t LTC_DES3_DecryptCbc(LTC_Type *base, + const uint8_t *ciphertext, + uint8_t *plaintext, + uint32_t size, + const uint8_t iv[LTC_DES_IV_SIZE], + const uint8_t key1[LTC_DES_KEY_SIZE], + const uint8_t key2[LTC_DES_KEY_SIZE], + const uint8_t key3[LTC_DES_KEY_SIZE]); + +/*! + * @brief Encrypts triple DES using CFB block mode with three keys. + * + * Encrypts triple DES using CFB block mode with three keys. + * + * @param base LTC peripheral base address + * @param plaintext Input plaintext to encrypt + * @param[out] ciphertext Output ciphertext + * @param size Size of input and ouput data in bytes + * @param iv Input initial block. + * @param key1 First input key for key bundle + * @param key2 Second input key for key bundle + * @param key3 Third input key for key bundle + * @return Status from encrypt/decrypt operation + */ +status_t LTC_DES3_EncryptCfb(LTC_Type *base, + const uint8_t *plaintext, + uint8_t *ciphertext, + uint32_t size, + const uint8_t iv[LTC_DES_IV_SIZE], + const uint8_t key1[LTC_DES_KEY_SIZE], + const uint8_t key2[LTC_DES_KEY_SIZE], + const uint8_t key3[LTC_DES_KEY_SIZE]); + +/*! + * @brief Decrypts triple DES using CFB block mode with three keys. + * + * Decrypts triple DES using CFB block mode with three keys. + * + * @param base LTC peripheral base address + * @param ciphertext Input ciphertext to decrypt + * @param[out] plaintext Output plaintext + * @param size Size of input data in bytes + * @param iv Input initial block. + * @param key1 First input key for key bundle + * @param key2 Second input key for key bundle + * @param key3 Third input key for key bundle + * @return Status from encrypt/decrypt operation + */ +status_t LTC_DES3_DecryptCfb(LTC_Type *base, + const uint8_t *ciphertext, + uint8_t *plaintext, + uint32_t size, + const uint8_t iv[LTC_DES_IV_SIZE], + const uint8_t key1[LTC_DES_KEY_SIZE], + const uint8_t key2[LTC_DES_KEY_SIZE], + const uint8_t key3[LTC_DES_KEY_SIZE]); + +/*! + * @brief Encrypts triple DES using OFB block mode with three keys. + * + * Encrypts triple DES using OFB block mode with three keys. + * + * @param base LTC peripheral base address + * @param plaintext Input plaintext to encrypt + * @param[out] ciphertext Output ciphertext + * @param size Size of input and output data in bytes + * @param iv Input unique input vector. The OFB mode requires that the IV be unique + * for each execution of the mode under the given key. + * @param key1 First input key for key bundle + * @param key2 Second input key for key bundle + * @param key3 Third input key for key bundle + * @return Status from encrypt/decrypt operation + */ +status_t LTC_DES3_EncryptOfb(LTC_Type *base, + const uint8_t *plaintext, + uint8_t *ciphertext, + uint32_t size, + const uint8_t iv[LTC_DES_IV_SIZE], + const uint8_t key1[LTC_DES_KEY_SIZE], + const uint8_t key2[LTC_DES_KEY_SIZE], + const uint8_t key3[LTC_DES_KEY_SIZE]); + +/*! + * @brief Decrypts triple DES using OFB block mode with three keys. + * + * Decrypts triple DES using OFB block mode with three keys. + * + * @param base LTC peripheral base address + * @param ciphertext Input ciphertext to decrypt + * @param[out] plaintext Output plaintext + * @param size Size of input and output data in bytes + * @param iv Input unique input vector. The OFB mode requires that the IV be unique + * for each execution of the mode under the given key. + * @param key1 First input key for key bundle + * @param key2 Second input key for key bundle + * @param key3 Third input key for key bundle + * @return Status from encrypt/decrypt operation + */ +status_t LTC_DES3_DecryptOfb(LTC_Type *base, + const uint8_t *ciphertext, + uint8_t *plaintext, + uint32_t size, + const uint8_t iv[LTC_DES_IV_SIZE], + const uint8_t key1[LTC_DES_KEY_SIZE], + const uint8_t key2[LTC_DES_KEY_SIZE], + const uint8_t key3[LTC_DES_KEY_SIZE]); + +/*! + *@} + */ + +/******************************************************************************* + * HASH API + ******************************************************************************/ + +/*! + * @addtogroup ltc_driver_hash + * @{ + */ +/*! + * @brief Initialize HASH context + * + * This function initialize the HASH. + * Key shall be supplied if the underlaying algoritm is AES XCBC-MAC or CMAC. + * Key shall be NULL if the underlaying algoritm is SHA. + * + * For XCBC-MAC, the key length must be 16. For CMAC, the key length can be + * the AES key lengths supported by AES engine. For MDHA the key length argument + * is ignored. + * + * @param base LTC peripheral base address + * @param[out] ctx Output hash context + * @param algo Underlaying algorithm to use for hash computation. + * @param key Input key (NULL if underlaying algorithm is SHA) + * @param keySize Size of input key in bytes + * @return Status of initialization + */ +status_t LTC_HASH_Init(LTC_Type *base, ltc_hash_ctx_t *ctx, ltc_hash_algo_t algo, const uint8_t *key, uint32_t keySize); + +/*! + * @brief Add data to current HASH + * + * Add data to current HASH. This can be called repeatedly with an arbitrary amount of data to be + * hashed. + * + * @param[in,out] ctx HASH context + * @param input Input data + * @param inputSize Size of input data in bytes + * @return Status of the hash update operation + */ +status_t LTC_HASH_Update(ltc_hash_ctx_t *ctx, const uint8_t *input, uint32_t inputSize); + +/*! + * @brief Finalize hashing + * + * Outputs the final hash and erases the context. + * + * @param[in,out] ctx Input hash context + * @param[out] output Output hash data + * @param[out] outputSize Output parameter storing the size of the output hash in bytes + * @return Status of the hash finish operation + */ +status_t LTC_HASH_Finish(ltc_hash_ctx_t *ctx, uint8_t *output, uint32_t *outputSize); + +/*! + * @brief Create HASH on given data + * + * Perform the full keyed HASH in one function call. + * + * @param base LTC peripheral base address + * @param algo Block cipher algorithm to use for CMAC creation + * @param input Input data + * @param inputSize Size of input data in bytes + * @param key Input key + * @param keySize Size of input key in bytes + * @param[out] output Output hash data + * @param[out] outputSize Output parameter storing the size of the output hash in bytes + * @return Status of the one call hash operation. + */ +status_t LTC_HASH(LTC_Type *base, + ltc_hash_algo_t algo, + const uint8_t *input, + uint32_t inputSize, + const uint8_t *key, + uint32_t keySize, + uint8_t *output, + uint32_t *outputSize); +/*! + *@} + */ + +/******************************************************************************* + * PKHA API + ******************************************************************************/ +/*! + * @addtogroup ltc_driver_pkha + * @{ + */ + +/*! + * @brief Compare two PKHA big numbers. + * + * Compare two PKHA big numbers. Return 1 for a > b, -1 for a < b and 0 if they are same. + * PKHA big number is lsbyte first. Thus the comparison starts at msbyte which is the last member of tested arrays. + * + * @param a First integer represented as an array of bytes, lsbyte first. + * @param sizeA Size in bytes of the first integer. + * @param b Second integer represented as an array of bytes, lsbyte first. + * @param sizeB Size in bytes of the second integer. + * @return 1 if a > b. + * @return -1 if a < b. + * @return 0 if a = b. + */ +int LTC_PKHA_CompareBigNum(const uint8_t *a, size_t sizeA, const uint8_t *b, size_t sizeB); + +/*! + * @brief Converts from integer to Montgomery format. + * + * This function computes R2 mod N and optionally converts A or B into Montgomery format of A or B. + * + * @param base LTC peripheral base address + * @param N modulus + * @param sizeN size of N in bytes + * @param[in,out] A The first input in non-Montgomery format. Output Montgomery format of the first input. + * @param[in,out] sizeA pointer to size variable. On input it holds size of input A in bytes. On output it holds size of + * Montgomery format of A in bytes. + * @param[in,out] B Second input in non-Montgomery format. Output Montgomery format of the second input. + * @param[in,out] sizeB pointer to size variable. On input it holds size of input B in bytes. On output it holds size of + * Montgomery format of B in bytes. + * @param[out] R2 Output Montgomery factor R2 mod N. + * @param[out] sizeR2 pointer to size variable. On output it holds size of Montgomery factor R2 mod N in bytes. + * @param equalTime Run the function time equalized or no timing equalization. + * @param arithType Type of arithmetic to perform (integer or F2m) + * @return Operation status. + */ +status_t LTC_PKHA_NormalToMontgomery(LTC_Type *base, + const uint8_t *N, + uint16_t sizeN, + uint8_t *A, + uint16_t *sizeA, + uint8_t *B, + uint16_t *sizeB, + uint8_t *R2, + uint16_t *sizeR2, + ltc_pkha_timing_t equalTime, + ltc_pkha_f2m_t arithType); + +/*! + * @brief Converts from Montgomery format to int. + * + * This function converts Montgomery format of A or B into int A or B. + * + * @param base LTC peripheral base address + * @param N modulus. + * @param sizeN size of N modulus in bytes. + * @param[in,out] A Input first number in Montgomery format. Output is non-Montgomery format. + * @param[in,out] sizeA pointer to size variable. On input it holds size of the input A in bytes. On output it holds + * size of non-Montgomery A in bytes. + * @param[in,out] B Input first number in Montgomery format. Output is non-Montgomery format. + * @param[in,out] sizeB pointer to size variable. On input it holds size of the input B in bytes. On output it holds + * size of non-Montgomery B in bytes. + * @param equalTime Run the function time equalized or no timing equalization. + * @param arithType Type of arithmetic to perform (integer or F2m) + * @return Operation status. + */ +status_t LTC_PKHA_MontgomeryToNormal(LTC_Type *base, + const uint8_t *N, + uint16_t sizeN, + uint8_t *A, + uint16_t *sizeA, + uint8_t *B, + uint16_t *sizeB, + ltc_pkha_timing_t equalTime, + ltc_pkha_f2m_t arithType); + +/*! + * @brief Performs modular addition - (A + B) mod N. + * + * This function performs modular addition of (A + B) mod N, with either + * integer or binary polynomial (F2m) inputs. In the F2m form, this function is + * equivalent to a bitwise XOR and it is functionally the same as subtraction. + * + * @param base LTC peripheral base address + * @param A first addend (integer or binary polynomial) + * @param sizeA Size of A in bytes + * @param B second addend (integer or binary polynomial) + * @param sizeB Size of B in bytes + * @param N modulus. For F2m operation this can be NULL, as N is ignored during F2m polynomial addition. + * @param sizeN Size of N in bytes. This must be given for both integer and F2m polynomial additions. + * @param[out] result Output array to store result of operation + * @param[out] resultSize Output size of operation in bytes + * @param arithType Type of arithmetic to perform (integer or F2m) + * @return Operation status. + */ +status_t LTC_PKHA_ModAdd(LTC_Type *base, + const uint8_t *A, + uint16_t sizeA, + const uint8_t *B, + uint16_t sizeB, + const uint8_t *N, + uint16_t sizeN, + uint8_t *result, + uint16_t *resultSize, + ltc_pkha_f2m_t arithType); + +/*! + * @brief Performs modular subtraction - (A - B) mod N. + * + * This function performs modular subtraction of (A - B) mod N with + * integer inputs. + * + * @param base LTC peripheral base address + * @param A first addend (integer or binary polynomial) + * @param sizeA Size of A in bytes + * @param B second addend (integer or binary polynomial) + * @param sizeB Size of B in bytes + * @param N modulus + * @param sizeN Size of N in bytes + * @param[out] result Output array to store result of operation + * @param[out] resultSize Output size of operation in bytes + * @return Operation status. + */ +status_t LTC_PKHA_ModSub1(LTC_Type *base, + const uint8_t *A, + uint16_t sizeA, + const uint8_t *B, + uint16_t sizeB, + const uint8_t *N, + uint16_t sizeN, + uint8_t *result, + uint16_t *resultSize); + +/*! + * @brief Performs modular subtraction - (B - A) mod N. + * + * This function performs modular subtraction of (B - A) mod N, + * with integer inputs. + * + * @param base LTC peripheral base address + * @param A first addend (integer or binary polynomial) + * @param sizeA Size of A in bytes + * @param B second addend (integer or binary polynomial) + * @param sizeB Size of B in bytes + * @param N modulus + * @param sizeN Size of N in bytes + * @param[out] result Output array to store result of operation + * @param[out] resultSize Output size of operation in bytes + * @return Operation status. + */ +status_t LTC_PKHA_ModSub2(LTC_Type *base, + const uint8_t *A, + uint16_t sizeA, + const uint8_t *B, + uint16_t sizeB, + const uint8_t *N, + uint16_t sizeN, + uint8_t *result, + uint16_t *resultSize); + +/*! + * @brief Performs modular multiplication - (A x B) mod N. + * + * This function performs modular multiplication with either integer or + * binary polynomial (F2m) inputs. It can optionally specify whether inputs + * and/or outputs will be in Montgomery form or not. + * + * @param base LTC peripheral base address + * @param A first addend (integer or binary polynomial) + * @param sizeA Size of A in bytes + * @param B second addend (integer or binary polynomial) + * @param sizeB Size of B in bytes + * @param N modulus. + * @param sizeN Size of N in bytes + * @param[out] result Output array to store result of operation + * @param[out] resultSize Output size of operation in bytes + * @param arithType Type of arithmetic to perform (integer or F2m) + * @param montIn Format of inputs + * @param montOut Format of output + * @param equalTime Run the function time equalized or no timing equalization. This argument is ignored for F2m modular + * multiplication. + * @return Operation status. + */ +status_t LTC_PKHA_ModMul(LTC_Type *base, + const uint8_t *A, + uint16_t sizeA, + const uint8_t *B, + uint16_t sizeB, + const uint8_t *N, + uint16_t sizeN, + uint8_t *result, + uint16_t *resultSize, + ltc_pkha_f2m_t arithType, + ltc_pkha_montgomery_form_t montIn, + ltc_pkha_montgomery_form_t montOut, + ltc_pkha_timing_t equalTime); + +/*! + * @brief Performs modular exponentiation - (A^E) mod N. + * + * This function performs modular exponentiation with either integer or + * binary polynomial (F2m) inputs. + * + * @param base LTC peripheral base address + * @param A first addend (integer or binary polynomial) + * @param sizeA Size of A in bytes + * @param N modulus + * @param sizeN Size of N in bytes + * @param E exponent + * @param sizeE Size of E in bytes + * @param[out] result Output array to store result of operation + * @param[out] resultSize Output size of operation in bytes + * @param montIn Format of A input (normal or Montgomery) + * @param arithType Type of arithmetic to perform (integer or F2m) + * @param equalTime Run the function time equalized or no timing equalization. + * @return Operation status. + */ +status_t LTC_PKHA_ModExp(LTC_Type *base, + const uint8_t *A, + uint16_t sizeA, + const uint8_t *N, + uint16_t sizeN, + const uint8_t *E, + uint16_t sizeE, + uint8_t *result, + uint16_t *resultSize, + ltc_pkha_f2m_t arithType, + ltc_pkha_montgomery_form_t montIn, + ltc_pkha_timing_t equalTime); + +/*! + * @brief Performs modular reduction - (A) mod N. + * + * This function performs modular reduction with either integer or + * binary polynomial (F2m) inputs. + * + * @param base LTC peripheral base address + * @param A first addend (integer or binary polynomial) + * @param sizeA Size of A in bytes + * @param N modulus + * @param sizeN Size of N in bytes + * @param[out] result Output array to store result of operation + * @param[out] resultSize Output size of operation in bytes + * @param arithType Type of arithmetic to perform (integer or F2m) + * @return Operation status. + */ +status_t LTC_PKHA_ModRed(LTC_Type *base, + const uint8_t *A, + uint16_t sizeA, + const uint8_t *N, + uint16_t sizeN, + uint8_t *result, + uint16_t *resultSize, + ltc_pkha_f2m_t arithType); + +/*! + * @brief Performs modular inversion - (A^-1) mod N. + * + * This function performs modular inversion with either integer or + * binary polynomial (F2m) inputs. + * + * @param base LTC peripheral base address + * @param A first addend (integer or binary polynomial) + * @param sizeA Size of A in bytes + * @param N modulus + * @param sizeN Size of N in bytes + * @param[out] result Output array to store result of operation + * @param[out] resultSize Output size of operation in bytes + * @param arithType Type of arithmetic to perform (integer or F2m) + * @return Operation status. + */ +status_t LTC_PKHA_ModInv(LTC_Type *base, + const uint8_t *A, + uint16_t sizeA, + const uint8_t *N, + uint16_t sizeN, + uint8_t *result, + uint16_t *resultSize, + ltc_pkha_f2m_t arithType); + +/*! + * @brief Computes integer Montgomery factor R^2 mod N. + * + * This function computes a constant to assist in converting operands + * into the Montgomery residue system representation. + * + * @param base LTC peripheral base address + * @param N modulus + * @param sizeN Size of N in bytes + * @param[out] result Output array to store result of operation + * @param[out] resultSize Output size of operation in bytes + * @param arithType Type of arithmetic to perform (integer or F2m) + * @return Operation status. + */ +status_t LTC_PKHA_ModR2( + LTC_Type *base, const uint8_t *N, uint16_t sizeN, uint8_t *result, uint16_t *resultSize, ltc_pkha_f2m_t arithType); + +/*! + * @brief Calculates the greatest common divisor - GCD (A, N). + * + * This function calculates the greatest common divisor of two inputs with + * either integer or binary polynomial (F2m) inputs. + * + * @param base LTC peripheral base address + * @param A first value (must be smaller than or equal to N) + * @param sizeA Size of A in bytes + * @param N second value (must be non-zero) + * @param sizeN Size of N in bytes + * @param[out] result Output array to store result of operation + * @param[out] resultSize Output size of operation in bytes + * @param arithType Type of arithmetic to perform (integer or F2m) + * @return Operation status. + */ +status_t LTC_PKHA_GCD(LTC_Type *base, + const uint8_t *A, + uint16_t sizeA, + const uint8_t *N, + uint16_t sizeN, + uint8_t *result, + uint16_t *resultSize, + ltc_pkha_f2m_t arithType); + +/*! + * @brief Executes Miller-Rabin primality test. + * + * This function calculates whether or not a candidate prime number is likely + * to be a prime. + * + * @param base LTC peripheral base address + * @param A initial random seed + * @param sizeA Size of A in bytes + * @param B number of trial runs + * @param sizeB Size of B in bytes + * @param N candidate prime integer + * @param sizeN Size of N in bytes + * @param[out] res True if the value is likely prime or false otherwise + * @return Operation status. + */ +status_t LTC_PKHA_PrimalityTest(LTC_Type *base, + const uint8_t *A, + uint16_t sizeA, + const uint8_t *B, + uint16_t sizeB, + const uint8_t *N, + uint16_t sizeN, + bool *res); + +/*! + * @brief Adds elliptic curve points - A + B. + * + * This function performs ECC point addition over a prime field (Fp) or binary field (F2m) using + * affine coordinates. + * + * @param base LTC peripheral base address + * @param A Left-hand point + * @param B Right-hand point + * @param N Prime modulus of the field + * @param R2modN NULL (the function computes R2modN internally) or pointer to pre-computed R2modN (obtained from + * LTC_PKHA_ModR2() function). + * @param aCurveParam A parameter from curve equation + * @param bCurveParam B parameter from curve equation (constant) + * @param size Size in bytes of curve points and parameters + * @param arithType Type of arithmetic to perform (integer or F2m) + * @param[out] result Result point + * @return Operation status. + */ +status_t LTC_PKHA_ECC_PointAdd(LTC_Type *base, + const ltc_pkha_ecc_point_t *A, + const ltc_pkha_ecc_point_t *B, + const uint8_t *N, + const uint8_t *R2modN, + const uint8_t *aCurveParam, + const uint8_t *bCurveParam, + uint8_t size, + ltc_pkha_f2m_t arithType, + ltc_pkha_ecc_point_t *result); + +/*! + * @brief Doubles elliptic curve points - B + B. + * + * This function performs ECC point doubling over a prime field (Fp) or binary field (F2m) using + * affine coordinates. + * + * @param base LTC peripheral base address + * @param B Point to double + * @param N Prime modulus of the field + * @param aCurveParam A parameter from curve equation + * @param bCurveParam B parameter from curve equation (constant) + * @param size Size in bytes of curve points and parameters + * @param arithType Type of arithmetic to perform (integer or F2m) + * @param[out] result Result point + * @return Operation status. + */ +status_t LTC_PKHA_ECC_PointDouble(LTC_Type *base, + const ltc_pkha_ecc_point_t *B, + const uint8_t *N, + const uint8_t *aCurveParam, + const uint8_t *bCurveParam, + uint8_t size, + ltc_pkha_f2m_t arithType, + ltc_pkha_ecc_point_t *result); + +/*! + * @brief Multiplies an elliptic curve point by a scalar - E x (A0, A1). + * + * This function performs ECC point multiplication to multiply an ECC point by + * a scalar integer multiplier over a prime field (Fp) or a binary field (F2m). + * + * @param base LTC peripheral base address + * @param A Point as multiplicand + * @param E Scalar multiple + * @param sizeE The size of E, in bytes + * @param N Modulus, a prime number for the Fp field or Irreducible polynomial for F2m field. + * @param R2modN NULL (the function computes R2modN internally) or pointer to pre-computed R2modN (obtained from + * LTC_PKHA_ModR2() function). + * @param aCurveParam A parameter from curve equation + * @param bCurveParam B parameter from curve equation (C parameter for operation over F2m). + * @param size Size in bytes of curve points and parameters + * @param equalTime Run the function time equalized or no timing equalization. + * @param arithType Type of arithmetic to perform (integer or F2m) + * @param[out] result Result point + * @param[out] infinity Output true if the result is point of infinity, and false otherwise. Writing of this output will + * be ignored if the argument is NULL. + * @return Operation status. + */ +status_t LTC_PKHA_ECC_PointMul(LTC_Type *base, + const ltc_pkha_ecc_point_t *A, + const uint8_t *E, + uint8_t sizeE, + const uint8_t *N, + const uint8_t *R2modN, + const uint8_t *aCurveParam, + const uint8_t *bCurveParam, + uint8_t size, + ltc_pkha_timing_t equalTime, + ltc_pkha_f2m_t arithType, + ltc_pkha_ecc_point_t *result, + bool *infinity); + +/*! + *@} + */ + +#if defined(__cplusplus) +} +#endif + +/*! + *@} + */ + +#endif /* _FSL_LTC_H_ */