PeripheralDriver_Flagchip_F.../Src/module_driver_hsm_level3.c

1443 lines
64 KiB
C

/**
* @file Crypto_Level2Api.c
* @version 0.8.0
*
* @brief AUTOSAR Crypto - Low level part of CRY driver.
* @details Hardware security module (HSM) provides several standards based cryptographic
* services and security services.
*
* @addtogroup CRYPTO
* @{
*/
/*==================================================================================================
* PERIPHERAL : CRYPTO,MAILBOX
* PLATFORM : Flagchip FC7300
* AUTOSAR VERSION : 4.6.0
* AUTOSAR REVISION : ASR_REL_R20-11
* SOFTWARE VERSION : 0.8.0
* VENDOR : Flagchip Semiconductors
*
* Copyright 2020-2023 Flagchip Semiconductors Co., Ltd.
* All Rights Reserved.
==================================================================================================*/
/*==================================================================================================
* Revision History:
*
* Version Date Initials CR# Descriptions
* --------- ---------- ------------- ---------- ---------------
* 0.1.0 15/02/2024 QXW0051 N/A CRYPTO Initial Version
* 0.6.0 23/03/2024 QXW0071 N/A Add Support For FC7240
==================================================================================================*/
#include "module_driver_hsm.h"
#include "module_driver_hsm_level1_leveln.h"
/********************************************* Level1 function *********************************************************/
HSM_StatusType hsm_1B4B_convert_from_idx(HSM_DataFormatType eDstFmt, void *pDst, hsm_uint32_t u32DstStartIdx, hsm_uint32_t u32DstBufByteSize,
HSM_DataFormatType eSrcFmt, const void *pSrc, hsm_uint32_t u32SrcStartIdx, hsm_uint32_t u32SrcStopIdx);
void hsm_bidi_memcpy(void *pDstMem, const void *pSrcMem, hsm_uint32_t u32OpCnt, hsm_int32_t sOpDirection);
void hsm_memcpy(void *pDstMem, const void *pSrcMem, hsm_uint32_t u32Cnt);
void hsm_memset(void *pDstMem, hsm_uint8_t u8Val, hsm_uint32_t u32Cnt);
hsm_int32_t hsm_memcmp(const void *pDst, const void *pSrc, hsm_uint32_t u32OpCnt);
HSM_StatusType hsm_hash_get_result_byte_count(HFAM_MODE_E eMode, hsm_uint32_t *pRetByteCnt);
void hsm_u32_array_swap(hsm_uint32_t *pData, hsm_uint32_t u32WordCnt);
void hsm_u32_array_swap_to(hsm_uint32_t *pData, const hsm_uint32_t *pSrc, hsm_uint32_t u32WordCnt);
void hsm_rm_prefix_zeros(
HSM_DataFormatType eInputFmt, const hsm_uint8_t *pData, hsm_uint32_t u32ByteCount, const hsm_uint8_t **ppActualData, hsm_uint32_t *pActualByteCnt);
void hsm_core_swap_u32_array_pad(
hsm_uint32_t *pAlignedDest, hsm_uint32_t u32DestWordCnt, const hsm_uint8_t *pSrc,
hsm_uint32_t u32SrcOpByteCnt, hsm_uint8_t u8PadByte, HSM_BoolType bPadFromMSB, HSM_BoolType bSwap);
void HSM_L1_CleanEnv(HSM_L1_RtCtxType *pCtx);
HSM_StatusType HSM_L1_CommonExitEnv(HSM_L1_RtCtxType *pCtx);
HSM_StatusType HSM_L1_Abort(HSM_L1_RtCtxType *pCtx);
void HSM_L1_Init(HSM_L1_RtCtxType *pCtx, HSM_L1_InitParmType *pParm);
HSM_StatusType HSM_L1_Md5SetupEnv(HSM_L1_RtCtxType *pCtx);
HSM_StatusType HSM_L1_Md5Reset(HSM_L1_RtCtxType *pCtx);
HSM_StatusType HSM_L1_Md5ExitEnv(HSM_L1_RtCtxType *pCtx);
HSM_StatusType HSM_L1_Md5(HSM_L1_RtCtxType *pCtx, const HSM_Ln_Md5Type *pCfg, hsm_uint32_t u32TimeoutMs);
HSM_StatusType HSM_L1_Md5_Isr(HSM_L1_RtCtxType *pCtx);
HSM_StatusType HSM_L1_Md5Poll(HSM_L1_RtCtxType *pCtx);
HSM_StatusType HSM_L1_Sm3SetupEnv(HSM_L1_RtCtxType *pCtx);
HSM_StatusType HSM_L1_Sm3Reset(HSM_L1_RtCtxType *pCtx);
HSM_StatusType HSM_L1_Sm3ExitEnv(HSM_L1_RtCtxType *pCtx);
HSM_StatusType HSM_L1_Sm3(HSM_L1_RtCtxType *pCtx, const HSM_Ln_Sm3Type *pCfg, hsm_uint32_t u32TimeoutMs);
HSM_StatusType HSM_L1_Sm3_Isr(HSM_L1_RtCtxType *pCtx);
HSM_StatusType HSM_L1_Sm3Poll(HSM_L1_RtCtxType *pCtx);
HSM_StatusType HSM_L1_ShaSetupEnv(HSM_L1_RtCtxType *pCtx);
HSM_StatusType HSM_L1_ShaReset(HSM_L1_RtCtxType *pCtx);
HSM_StatusType HSM_L1_ShaExitEnv(HSM_L1_RtCtxType *pCtx);
HSM_StatusType HSM_L1_Sha(HSM_L1_RtCtxType *pCtx, const HSM_Ln_ShaType *pCfg, hsm_uint32_t u32TimeoutMs);
HSM_StatusType HSM_L1_Sha_Isr(HSM_L1_RtCtxType *pCtx);
HSM_StatusType HSM_L1_ShaPoll(HSM_L1_RtCtxType *pCtx);
HSM_StatusType HSM_L1_RngSetupEnv(HSM_L1_RtCtxType *pCtx);
HSM_StatusType HSM_L1_RngReset(HSM_L1_RtCtxType *pCtx);
HSM_StatusType HSM_L1_RngExitEnv(HSM_L1_RtCtxType *pCtx);
HSM_StatusType HSM_L1_Rng(HSM_L1_RtCtxType *pCtx, const HSM_Ln_RngType *pCfg, hsm_uint32_t u32TimeoutMs);
HSM_StatusType HSM_L1_Rng_Isr(HSM_L1_RtCtxType *pCtx);
HSM_StatusType HSM_L1_RngPoll(HSM_L1_RtCtxType *pCtx);
HSM_StatusType HSM_L1_EccVerifySetupEnv(HSM_L1_RtCtxType *pCtx, hsm_uint32_t u32BitCnt);
HSM_StatusType HSM_L1_EccVerifyExitEnv(HSM_L1_RtCtxType *pCtx);
HSM_StatusType HSM_L1_EccVerify(HSM_L1_RtCtxType *pCtx, const HSM_L1_EccVerifyType *pCfg, hsm_uint32_t u32TimeoutMs);
HSM_StatusType HSM_L1_EccVerify_Isr(HSM_L1_RtCtxType *pCtx);
HSM_StatusType HSM_L1_EccVerifyPoll(HSM_L1_RtCtxType *pCtx);
HSM_StatusType HSM_L1_EccVerifyReset(HSM_L1_RtCtxType *pCtx);
HSM_StatusType HSM_L1_EccDecryptSetupEnv(HSM_L1_RtCtxType *pCtx, hsm_uint32_t u32BitCnt);
HSM_StatusType HSM_L1_EccDecryptExitEnv(HSM_L1_RtCtxType *pCtx);
HSM_StatusType HSM_L1_EccDecrypt(HSM_L1_RtCtxType *pCtx, const HSM_Ln_EccDecryptType *pCfg, hsm_uint32_t u32TimeoutMs);
HSM_StatusType HSM_L1_EccDecrypt_Isr(HSM_L1_RtCtxType *pCtx);
HSM_StatusType HSM_L1_EccDecryptPoll(HSM_L1_RtCtxType *pCtx);
HSM_StatusType HSM_L1_EccDecryptReset(HSM_L1_RtCtxType *pCtx);
HSM_StatusType HSM_L1_EccCalculateSetupEnv(HSM_L1_RtCtxType *pCtx, hsm_uint32_t u32BitCnt);
HSM_StatusType HSM_L1_EccCalculateExitEnv(HSM_L1_RtCtxType *pCtx);
HSM_StatusType HSM_L1_EccCalculateKP(HSM_L1_RtCtxType *pCtx, const HSM_Ln_EccKPType *pCfg, hsm_uint32_t u32TimeoutMs);
HSM_StatusType HSM_L1_EccCalculate_Isr(HSM_L1_RtCtxType *pCtx);
HSM_StatusType HSM_L1_EccCalculatePoll(HSM_L1_RtCtxType *pCtx);
HSM_StatusType HSM_L1_EccCalculateReset(HSM_L1_RtCtxType *pCtx);
HSM_StatusType HSM_L1_CMacSetupEnv(HSM_L1_RtCtxType *pCtx);
HSM_StatusType HSM_L1_CMacReset(HSM_L1_RtCtxType *pCtx);
HSM_StatusType HSM_L1_CMacExitEnv(HSM_L1_RtCtxType *pCtx);
HSM_StatusType HSM_L1_CMac(HSM_L1_RtCtxType *pCtx, const HSM_Ln_CMacType *pCfg, hsm_uint32_t u32TimeoutMs);
HSM_StatusType HSM_L1_CMac_Isr(HSM_L1_RtCtxType *pCtx);
HSM_StatusType HSM_L1_CMacPoll(HSM_L1_RtCtxType *pCtx);
HSM_StatusType HSM_L1_AesEncryptSetupEnv(HSM_L1_RtCtxType *pCtx);
HSM_StatusType HSM_L1_AesEncryptReset(HSM_L1_RtCtxType *pCtx);
HSM_StatusType HSM_L1_AesEncryptExitEnv(HSM_L1_RtCtxType *pCtx);
HSM_StatusType HSM_L1_AesEncrypt(HSM_L1_RtCtxType *pCtx, const HSM_Ln_AesEncryptType *pCfg, hsm_uint32_t u32TimeoutMs);
HSM_StatusType HSM_L1_AesEncrypt_Isr(HSM_L1_RtCtxType *pCtx);
HSM_StatusType HSM_L1_AesEncryptPoll(HSM_L1_RtCtxType *pCtx);
HSM_StatusType HSM_L1_AesDecryptSetupEnv(HSM_L1_RtCtxType *pCtx);
HSM_StatusType HSM_L1_AesDecryptReset(HSM_L1_RtCtxType *pCtx);
HSM_StatusType HSM_L1_AesDecryptExitEnv(HSM_L1_RtCtxType *pCtx);
HSM_StatusType HSM_L1_AesDecrypt(HSM_L1_RtCtxType *pCtx, const HSM_Ln_AesDecryptType *pCfg, hsm_uint32_t u32TimeoutMs);
HSM_StatusType HSM_L1_AesDecrypt_Isr(HSM_L1_RtCtxType *pCtx);
HSM_StatusType HSM_L1_AesDecryptPoll(HSM_L1_RtCtxType *pCtx);
HSM_StatusType HSM_L1_Sm4EncryptSetupEnv(HSM_L1_RtCtxType *pCtx);
HSM_StatusType HSM_L1_Sm4EncryptReset(HSM_L1_RtCtxType *pCtx);
HSM_StatusType HSM_L1_Sm4EncryptExitEnv(HSM_L1_RtCtxType *pCtx);
HSM_StatusType HSM_L1_Sm4Encrypt(HSM_L1_RtCtxType *pCtx, const HSM_Ln_Sm4EncryptType *pCfg, hsm_uint32_t u32TimeoutMs);
HSM_StatusType HSM_L1_Sm4Encrypt_Isr(HSM_L1_RtCtxType *pCtx);
HSM_StatusType HSM_L1_Sm4EncryptPoll(HSM_L1_RtCtxType *pCtx);
HSM_StatusType HSM_L1_Sm4DecryptSetupEnv(HSM_L1_RtCtxType *pCtx);
HSM_StatusType HSM_L1_Sm4DecryptReset(HSM_L1_RtCtxType *pCtx);
HSM_StatusType HSM_L1_Sm4DecryptExitEnv(HSM_L1_RtCtxType *pCtx);
HSM_StatusType HSM_L1_Sm4Decrypt(HSM_L1_RtCtxType *pCtx, const HSM_Ln_Sm4DecryptType *pCfg, hsm_uint32_t u32TimeoutMs);
HSM_StatusType HSM_L1_Sm4Decrypt_Isr(HSM_L1_RtCtxType *pCtx);
HSM_StatusType HSM_L1_Sm4DecryptPoll(HSM_L1_RtCtxType *pCtx);
HSM_StatusType HSM_L1_BnCalcSetupEnv(HSM_L1_RtCtxType *pCtx);
HSM_StatusType HSM_L1_BnCalcExitEnv(HSM_L1_RtCtxType *pCtx);
hsm_uint32_t hsm_pkam_get_actual_size(HSM_DataFormatType eDataFormat, const void *pData, hsm_uint32_t u32ByteCount, const hsm_uint8_t **ppLastNonZero);
HSM_StatusType hsm_pkam_get_bn_bit_count(HSM_DataFormatType eFmt, const hsm_uint8_t *pData, hsm_uint32_t u32ByteCnt, hsm_uint32_t *pBitCnt);
HSM_StatusType HSM_L1_BnCalc(HSM_L1_RtCtxType *pCtx, const HSM_L1_BnCalcType *pCfg, hsm_uint32_t u32TimeoutMs);
HSM_StatusType HSM_L1_BnCalc_Isr(HSM_L1_RtCtxType *pCtx);
HSM_StatusType HSM_L1_BnCalcPoll(HSM_L1_RtCtxType *pCtx);
HSM_StatusType HSM_L1_BnCalcReset(HSM_L1_RtCtxType *pCtx);
HSM_StatusType HSM_L1_ScatterHashSetupEnv(HSM_L1_RtCtxType *pCtx);
HSM_StatusType HSM_L1_ScatterHashSetMacCfg(HSM_L1_RtCtxType *pCtx, HSM_Ln_HashMacCfgType *ptCfg);
HSM_StatusType HSM_L1_ScatterHashInit(HSM_L1_RtCtxType *pCtx, const HSM_ShaAlgType eAlg, const HSM_Ln_ScatterHashType *pCfg, hsm_uint32_t u32TimeoutMs);
HSM_StatusType HSM_L1_ScatterHashUpdate(HSM_L1_RtCtxType *pCtx, const HSM_Ln_ScatterHashType *pCfg, hsm_uint32_t u32TimeoutMs);
HSM_StatusType hsm_aux_get_empty_data_hash(HSM_ShaAlgType eHash, const hsm_uint8_t **ppHashData, hsm_uint32_t *pByteCnt);
HSM_StatusType HSM_L1_ScatterHashFinal(HSM_L1_RtCtxType *pCtx, const HSM_Ln_ScatterHashType *pCfg, const HSM_Ln_ResultBufInfoType *pResult, hsm_uint32_t u32TimeoutMs);
HSM_StatusType HSM_L1_ScatterHash_Isr(HSM_L1_RtCtxType *pCtx);
HSM_StatusType HSM_L1_ScatterHashPoll(HSM_L1_RtCtxType *pCtx);
HSM_StatusType HSM_L1_ScatterHashExitEnv(HSM_L1_RtCtxType *pCtx);
HSM_StatusType HSM_L1_ScatterCMacSetupEnv(HSM_L1_RtCtxType *pCtx);
HSM_StatusType HSM_L1_ScatterCMacInit(HSM_L1_RtCtxType *pCtx, const HSM_Ln_CMacCfgParmsType *pKeyCfg, const HSM_Ln_ScatterCMacType *pCfg, hsm_uint32_t u32TimeoutMs);
HSM_StatusType HSM_L1_ScatterCMacUpdate(HSM_L1_RtCtxType *pCtx, const HSM_Ln_ScatterCMacType *pCfg, hsm_uint32_t u32TimeoutMs);
HSM_StatusType HSM_L1_ScatterCMacFinal(HSM_L1_RtCtxType *pCtx, const HSM_Ln_ScatterCMacType *pCfg, const HSM_Ln_ResultBufInfoType *pResult, hsm_uint32_t u32TimeoutMs);
HSM_StatusType HSM_L1_ScatterCMac_Isr(HSM_L1_RtCtxType *pCtx);
HSM_StatusType HSM_L1_ScatterCMacPoll(HSM_L1_RtCtxType *pCtx);
HSM_StatusType HSM_L1_ScatterCMacExitEnv(HSM_L1_RtCtxType *pCtx);
HSM_StatusType HSM_L1_EccSignSetupEnv(HSM_L1_RtCtxType *pCtx, hsm_uint32_t u32BitCnt);
HSM_StatusType HSM_L1_EccSignExitEnv(HSM_L1_RtCtxType *pCtx);
HSM_StatusType HSM_L1_EccSign(HSM_L1_RtCtxType *pCtx, const HSM_Ln_EccSignType *pCfg, hsm_uint32_t u32TimeoutMs);
HSM_StatusType HSM_L1_EccSign_Isr(HSM_L1_RtCtxType *pCtx);
HSM_StatusType HSM_L1_EccSignPoll(HSM_L1_RtCtxType *pCtx);
HSM_StatusType HSM_L1_EccSignReset(HSM_L1_RtCtxType *pCtx);
HSM_StatusType HSM_L1_RsaSsaPssVerifySetupEnv(HSM_L1_RtCtxType *pCtx, hsm_uint32_t u32RsaBitCnt);
HSM_StatusType HSM_L1_RsaSsaPssVerify(HSM_L1_RtCtxType *pCtx, const HSM_Ln_RsaSsaPssVerifyType *pCfg, hsm_uint32_t u32TimeoutMs);
HSM_StatusType HSM_L1_RsaSsaPssVerifyPoll(HSM_L1_RtCtxType *pCtx);
HSM_StatusType HSM_L1_RsaSsaPssVerifyReset(HSM_L1_RtCtxType *pCtx);
HSM_StatusType HSM_L1_RsaSsaPssVerify_Isr(HSM_L1_RtCtxType *pCtx);
HSM_StatusType HSM_L1_RsaSsaPssVerifyExitEnv(HSM_L1_RtCtxType *pCtx);
HSM_StatusType HSM_L1_RsaSsaPkcs1V15VerifySetupEnv(HSM_L1_RtCtxType *pCtx, hsm_uint32_t u32RsaBitCnt);
HSM_StatusType HSM_L1_RsaSsaPkcs1V15Verify(HSM_L1_RtCtxType *pCtx, const HSM_Ln_RsaSsaPkcs1v15VerifyType *pCfg, hsm_uint32_t u32TimeoutMs);
HSM_StatusType HSM_L1_RsaSsaPkcs1V15VerifyPoll(HSM_L1_RtCtxType *pCtx);
HSM_StatusType HSM_L1_RsaSsaPkcs1V15VerifyReset(HSM_L1_RtCtxType *pCtx);
HSM_StatusType HSM_L1_RsaSsaPkcs1V15Verify_Isr(HSM_L1_RtCtxType *pCtx);
HSM_StatusType HSM_L1_RsaSsaPkcs1V15VerifyExitEnv(HSM_L1_RtCtxType *pCtx);
HSM_StatusType HSM_L1_KeyImportSetupEnv(HSM_L1_RtCtxType *pCtx);
HSM_StatusType HSM_L1_KeyImport(HSM_L1_RtCtxType *pCtx, const HSM_Ln_ImportUserKeyExtType *pCfg, hsm_uint32_t u32TimeoutMs);
HSM_StatusType HSM_L1_KeyImportPoll(HSM_L1_RtCtxType *pCtx);
HSM_StatusType HSM_L1_KeyImportReset(HSM_L1_RtCtxType *pCtx);
HSM_StatusType HSM_L1_KeyImportExitEnv(HSM_L1_RtCtxType *pCtx);
HSM_StatusType HSM_L1_KeyImport_Isr(HSM_L1_RtCtxType *pCtx);
#if ((FC7XXX_HSM_SUBSYSTEM_TYPE == FC7240_HSM_SUBSYSTEM) || (FC7XXX_HSM_SUBSYSTEM_TYPE == FC7300_HSM_SUBSYSTEM))
HSM_StatusType HSM_L1_KeyValidateSetupEnv(HSM_L1_RtCtxType *pCtx);
HSM_StatusType HSM_L1_KeyValidate(HSM_L1_RtCtxType *pCtx, hsm_uint32_t u32KeyId, hsm_uint32_t u32TimeoutMs);
HSM_StatusType HSM_L1_KeyValidatePoll(HSM_L1_RtCtxType *pCtx);
HSM_StatusType HSM_L1_KeyValidateReset(HSM_L1_RtCtxType *pCtx);
HSM_StatusType HSM_L1_KeyValidateExitEnv(HSM_L1_RtCtxType *pCtx);
HSM_StatusType HSM_L1_KeyValidate_Isr(HSM_L1_RtCtxType *pCtx);
#endif
#if ((FC7XXX_HSM_SUBSYSTEM_TYPE == FC7240_HSM_SUBSYSTEM) || (FC7XXX_HSM_SUBSYSTEM_TYPE == FC7300_HSM_SUBSYSTEM))
#else
HSM_StatusType HSM_L1_UpdateKeyIdContentSetupEnv(HSM_L1_RtCtxType *pCtx);
HSM_StatusType HSM_L1_UpdateKeyIdContent(HSM_L1_RtCtxType *pCtx, const HSM_Ln_KeyManagerUpdateUserKeyType *pCfg, hsm_uint32_t u32TimeoutMs);
HSM_StatusType HSM_L1_UpdateKeyIdContentPoll(HSM_L1_RtCtxType *pCtx);
HSM_StatusType HSM_L1_UpdateKeyIdContentReset(HSM_L1_RtCtxType *pCtx);
HSM_StatusType HSM_L1_UpdateKeyIdContentExitEnv(HSM_L1_RtCtxType *pCtx);
HSM_StatusType HSM_L1_UpdateKeyIdContent_Isr(HSM_L1_RtCtxType *pCtx);
#endif
HSM_StatusType HSM_L1_KeyCopySetupEnv(HSM_L1_RtCtxType *pCtx);
HSM_StatusType HSM_L1_KeyCopy(HSM_L1_RtCtxType *pCtx, const HSM_Ln_CopyUserKeyType *pCfg, hsm_uint32_t u32TimeoutMs);
HSM_StatusType HSM_L1_KeyCopyPoll(HSM_L1_RtCtxType *pCtx);
HSM_StatusType HSM_L1_KeyCopyReset(HSM_L1_RtCtxType *pCtx);
HSM_StatusType HSM_L1_KeyCopyExitEnv(HSM_L1_RtCtxType *pCtx);
HSM_StatusType HSM_L1_KeyCopy_Isr(HSM_L1_RtCtxType *pCtx);
HSM_StatusType HSM_L1_KeyRevokeSetupEnv(HSM_L1_RtCtxType *pCtx);
HSM_StatusType HSM_L1_KeyRevoke(HSM_L1_RtCtxType *pCtx, hsm_uint32_t u32KeyId, hsm_uint32_t u32TimeoutMs);
HSM_StatusType HSM_L1_KeyRevokePoll(HSM_L1_RtCtxType *pCtx);
HSM_StatusType HSM_L1_KeyRevokeReset(HSM_L1_RtCtxType *pCtx);
HSM_StatusType HSM_L1_KeyRevokeExitEnv(HSM_L1_RtCtxType *pCtx);
HSM_StatusType HSM_L1_KeyRevoke_Isr(HSM_L1_RtCtxType *pCtx);
HSM_StatusType HSM_L1_KeySpaceTidyUpSetupEnv(HSM_L1_RtCtxType *pCtx);
HSM_StatusType HSM_L1_KeySpaceTidyUp(HSM_L1_RtCtxType *pCtx, HSM_Ln_KeySpaceStatusType *pCfg, hsm_uint32_t u32TimeoutMs);
HSM_StatusType HSM_L1_KeySpaceTidyUpPoll(HSM_L1_RtCtxType *pCtx);
HSM_StatusType HSM_L1_KeySpaceTidyUpReset(HSM_L1_RtCtxType *pCtx);
HSM_StatusType HSM_L1_KeySpaceTidyUpExitEnv(HSM_L1_RtCtxType *pCtx);
HSM_StatusType HSM_L1_KeySpaceTidyup_Isr(HSM_L1_RtCtxType *pCtx);
HSM_StatusType HSM_L1_KeySpaceGetStatusSetupEnv(HSM_L1_RtCtxType *pCtx);
HSM_StatusType HSM_L1_KeySpaceGetStatus(HSM_L1_RtCtxType *pCtx, HSM_Ln_KeySpaceStatusType *pCfg, hsm_uint32_t u32TimeoutMs);
HSM_StatusType HSM_L1_KeySpaceGetStatusPoll(HSM_L1_RtCtxType *pCtx);
HSM_StatusType HSM_L1_KeySpaceGetStatusReset(HSM_L1_RtCtxType *pCtx);
HSM_StatusType HSM_L1_KeySpaceGetStatusExitEnv(HSM_L1_RtCtxType *pCtx);
HSM_StatusType HSM_L1_KeySpaceGetStatus_Isr(HSM_L1_RtCtxType *pCtx);
#if ((FC7XXX_HSM_SUBSYSTEM_TYPE == FC7240_HSM_SUBSYSTEM) || (FC7XXX_HSM_SUBSYSTEM_TYPE == FC7300_HSM_SUBSYSTEM))
HSM_StatusType HSM_L1_GetKeyIdStatusSetupEnv(HSM_L1_RtCtxType *pCtx);
HSM_StatusType HSM_L1_GetKeyIdStatus(HSM_L1_RtCtxType *pCtx, hsm_uint32_t u32KeyId, hsm_uint32_t u32TimeoutMs);
HSM_StatusType HSM_L1_GetKeyIdStatusPoll(HSM_L1_RtCtxType *pCtx);
HSM_StatusType HSM_L1_GetKeyIdStatusReset(HSM_L1_RtCtxType *pCtx);
HSM_StatusType HSM_L1_GetKeyIdStatusExitEnv(HSM_L1_RtCtxType *pCtx);
HSM_StatusType HSM_L1_GetKeyIdStatus_Isr(HSM_L1_RtCtxType *pCtx);
#endif
HSM_StatusType HSM_L1_RsaSsaPkcs1V15SignSetupEnv(HSM_L1_RtCtxType *pCtx);
HSM_StatusType HSM_L1_RsaSsaPkcs1V15SignHash(HSM_L1_RtCtxType *pCtx, const HSM_Ln_RsaSsaPkcs1V15SignHashType *pCfg, hsm_uint32_t u32TimeoutMs);
HSM_StatusType HSM_L1_RsaSsaPkcs1V15SignData(HSM_L1_RtCtxType *pCtx, const HSM_Ln_RsaSsaPkcs1V15SignDataType *pCfg, hsm_uint32_t u32TimeoutMs);
HSM_StatusType HSM_L1_RsaSsaPkcs1V15SignPoll(HSM_L1_RtCtxType *pCtx);
HSM_StatusType HSM_L1_RsaSsaPkcs1V15SignReset(HSM_L1_RtCtxType *pCtx);
HSM_StatusType HSM_L1_RsaSsaPkcs1V15SignExitEnv(HSM_L1_RtCtxType *pCtx);
HSM_StatusType HSM_L1_RsaSsaPkcs1V15Sign_Isr(HSM_L1_RtCtxType *pCtx);
HSM_StatusType HSM_L1_RsaSsaPssSignSetupEnv(HSM_L1_RtCtxType *pCtx);
HSM_StatusType HSM_L1_RsaSsaPssSignData(HSM_L1_RtCtxType *pCtx, const HSM_Ln_RsaSsaPssSignDataType *pCfg, hsm_uint32_t u32TimeoutMs);
HSM_StatusType HSM_L1_RsaSsaPssSignHash(HSM_L1_RtCtxType *pCtx, const HSM_Ln_RsaSsaPssSignHashType *pCfg, hsm_uint32_t u32TimeoutMs);
HSM_StatusType HSM_L1_RsaSsaPssSignPoll(HSM_L1_RtCtxType *pCtx);
HSM_StatusType HSM_L1_RsaSsaPssSignReset(HSM_L1_RtCtxType *pCtx);
HSM_StatusType HSM_L1_RsaSsaPssSignExitEnv(HSM_L1_RtCtxType *pCtx);
HSM_StatusType HSM_L1_RsaSsaPssSign_Isr(HSM_L1_RtCtxType *pCtx);
HSM_StatusType HSM_L1_PKCS1_GetRsaPrivateKeyInfFromDer(const hsm_uint8_t *pDer, HSM_L1_PKCS_RsaPrivateKeyInfType *pInf);
HSM_StatusType HSM_L1_PKCS1_GetEccPrivateKeyInfFromDer(const hsm_uint8_t *pDer, HSM_L1_PKCS_EccPrivateKeyInfType *pInf);
HSM_StatusType HSM_L1_PKCS8_GetPrivateKeyInfFromDer(const hsm_uint8_t *pDer, HSM_L1_PKCS8_PrivateKeyInfType *pInf);
HSM_StatusType HSM_L1_PKCS1_GetRsaPublicKeyInfFromDer(const hsm_uint8_t *pDer, HSM_L1_PKCS_RsaPublicKeyInfType *pInf);
HSM_StatusType hsm_l1_subjectpublicinfo_bitstring_geteccpublickeyinf(const hsm_uint8_t *pDer, HSM_L1_PKCS_EccPublicKeyInfType *pInf);
HSM_StatusType HSM_L1_SubjectPublicInfo_GetPublicKeyInfFromDer(const hsm_uint8_t *pDer, HSM_L1_PublicKeyInfType *pInf);
HSM_StatusType HSM_L1_GetPoll(HSM_L1_RtCtxType *pCtx);
void HSM_L1_Ack_IrqHandler(void *pUpperCtx, HSM_StatusType eRet);
/********************************************* Level2 function *********************************************************/
HSM_StatusType hsm_l2_cmac_empty_process(HSM_L2_RtCtxType *pL2Ctx, HSM_L1_RtCtxType *pL1Ctx, hsm_uint32_t u32TimeoutMs, HSM_L2_DrvCMacEmptyInfType *pCfg,
HSM_StatusType eRetFromPrevious, HSM_TriggerSrcType bTriggerMode);
HSM_StatusType hsm_l2_revoke_key_process(HSM_L2_RtCtxType *pL2Ctx, HSM_L1_RtCtxType *pL1Ctx, hsm_uint32_t u32TimeoutMs, HSM_L2_DrvRevokeKeyInfType *pCfg,
HSM_StatusType eRetFromPrevious, HSM_TriggerSrcType bTriggerMode);
HSM_StatusType hsm_l2_ecc_verify_process(HSM_L2_RtCtxType *pL2Ctx, HSM_L1_RtCtxType *pL1Ctx, hsm_uint32_t u32TimeoutMs, HSM_L2_DrvEccVerifyInfType *pCfg,
HSM_StatusType eRetFromPrevious, HSM_TriggerSrcType bTriggerMode);
HSM_StatusType HSM_L2_CMacEmptySetupEnv(HSM_L2_RtCtxType *pL2Ctx, HSM_L1_RtCtxType *pL1Ctx);
HSM_StatusType HSM_L2_CMacEmptyReset(HSM_L2_RtCtxType *pL2Ctx, HSM_L1_RtCtxType *pL1Ctx);
HSM_StatusType HSM_L2_CMacEmptyExitEnv(HSM_L2_RtCtxType *pL2Ctx, HSM_L1_RtCtxType *pL1Ctx);
HSM_StatusType hsm_l2_cmac_empty_process(HSM_L2_RtCtxType *pL2Ctx, HSM_L1_RtCtxType *pL1Ctx, hsm_uint32_t u32TimeoutMs,
HSM_L2_DrvCMacEmptyInfType *pCfg, HSM_StatusType eRetFromPrevious, HSM_TriggerSrcType bTriggerMode);
HSM_StatusType HSM_L2_CMacEmpty(HSM_L2_RtCtxType *pL2Ctx, HSM_L1_RtCtxType *pL1Ctx, const HSM_Ln_CMacCfgParmsType *pKeyCfg, const HSM_Ln_ResultBufInfoType *pResult,
hsm_uint32_t u32TimeoutMs);
HSM_StatusType HSM_L2_CMacEmptyPoll(HSM_L2_RtCtxType *pL2Ctx, HSM_L1_RtCtxType *pL1Ctx, hsm_uint32_t u32TimeoutMs);
#if (FC7XXX_HSM_SUBSYSTEM_TYPE == FC7240_HSM_SUBSYSTEM) || (FC7XXX_HSM_SUBSYSTEM_TYPE == FC7300_HSM_SUBSYSTEM)
HSM_StatusType hsm_l2_update_key_process(HSM_L2_RtCtxType *pL2Ctx, HSM_L1_RtCtxType *pL1Ctx, hsm_uint32_t u32TimeoutMs,
HSM_L2_DrvUpdateKeyInfType *pCfg, HSM_StatusType eRetFromPrevious, HSM_TriggerSrcType bTriggerMode);
#else
HSM_StatusType hsm_l2_update_key_process(HSM_L2_RtCtxType *pL2Ctx, HSM_L1_RtCtxType *pL1Ctx, hsm_uint32_t u32TimeoutMs,
HSM_L2_DrvUpdateKeyInfType *pCfg, HSM_StatusType eRetFromPrevious, HSM_TriggerSrcType bTriggerMode);
#endif
HSM_StatusType HSM_L2_UpdateKeySetupEnv(HSM_L2_RtCtxType *pL2Ctx, HSM_L1_RtCtxType *pL1Ctx);
HSM_StatusType HSM_L2_UpdateKeyReset(HSM_L2_RtCtxType *pL2Ctx, HSM_L1_RtCtxType *pL1Ctx);
HSM_StatusType HSM_L2_UpdateKey(HSM_L2_RtCtxType *pL2Ctx, HSM_L1_RtCtxType *pL1Ctx, const HSM_Ln_ImportUserKeyExtType *pKeyCfg, hsm_uint32_t u32TimeoutMs);
HSM_StatusType HSM_L2_UpdateKeyPoll(HSM_L2_RtCtxType *pL2Ctx, HSM_L1_RtCtxType *pL1Ctx, hsm_uint32_t u32TimeoutMs);
HSM_StatusType HSM_L2_UpdateKeyExitEnv(HSM_L2_RtCtxType *pL2Ctx, HSM_L1_RtCtxType *pL1Ctx);
HSM_StatusType HSM_L2_RevokeKeySetupEnv(HSM_L2_RtCtxType *pL2Ctx, HSM_L1_RtCtxType *pL1Ctx);
HSM_StatusType HSM_L2_RevokeKeyReset(HSM_L2_RtCtxType *pL2Ctx, HSM_L1_RtCtxType *pL1Ctx);
HSM_StatusType HSM_L2_RevokeKey(HSM_L2_RtCtxType *pL2Ctx, HSM_L1_RtCtxType *pL1Ctx, hsm_uint32_t u32KeyId, hsm_uint32_t u32TimeoutMs);
HSM_StatusType HSM_L2_RevokeKeyPoll(HSM_L2_RtCtxType *pL2Ctx, HSM_L1_RtCtxType *pL1Ctx, hsm_uint32_t u32TimeoutMs);
HSM_StatusType HSM_L2_RevokeKeyExitEnv(HSM_L2_RtCtxType *pL2Ctx, HSM_L1_RtCtxType *pL1Ctx);
HSM_StatusType hsm_l2_ecc_verify_process(HSM_L2_RtCtxType *pL2Ctx, HSM_L1_RtCtxType *pL1Ctx, hsm_uint32_t u32TimeoutMs,
HSM_L2_DrvEccVerifyInfType *pCfg, HSM_StatusType eRetFromPrevious, HSM_TriggerSrcType bTriggerMode);
HSM_StatusType HSM_L2_EccVerifySetupEnv(HSM_L2_RtCtxType *pL2Ctx, HSM_L1_RtCtxType *pL1Ctx, hsm_uint32_t u32BitCnt);
HSM_StatusType HSM_L2_EccVerifyReset(HSM_L2_RtCtxType *pL2Ctx, HSM_L1_RtCtxType *pL1Ctx);
HSM_StatusType HSM_L2_EccVerify(HSM_L2_RtCtxType *pL2Ctx, HSM_L1_RtCtxType *pL1Ctx, const HSM_Ln_EccVerifyType *pCfg, hsm_uint32_t u32TimeoutMs);
HSM_StatusType HSM_L2_EccVerifyPoll(HSM_L2_RtCtxType *pL2Ctx, HSM_L1_RtCtxType *pL1Ctx, hsm_uint32_t u32TimeoutMs);
HSM_StatusType HSM_L2_EccVerifyExitEnv(HSM_L2_RtCtxType *pL2Ctx, HSM_L1_RtCtxType *pL1Ctx);
HSM_StatusType HSM_L2_Sm2VerifySetupEnv(HSM_L2_RtCtxType *pL2Ctx, HSM_L1_RtCtxType *pL1Ctx);
HSM_StatusType HSM_L2_Sm2VerifyReset(HSM_L2_RtCtxType *pL2Ctx, HSM_L1_RtCtxType *pL1Ctx);
HSM_StatusType HSM_L2_Sm2Verify(HSM_L2_RtCtxType *pL2Ctx, HSM_L1_RtCtxType *pL1Ctx, const HSM_Ln_Sm2VerifyType *pCfg, hsm_uint32_t u32TimeoutMs);
HSM_StatusType HSM_L2_Sm2VerifyPoll(HSM_L2_RtCtxType *pL2Ctx, HSM_L1_RtCtxType *pL1Ctx, hsm_uint32_t u32TimeoutMs);
HSM_StatusType HSM_L2_Sm2VerifyExitEnv(HSM_L2_RtCtxType *pL2Ctx, HSM_L1_RtCtxType *pL1Ctx);
void HSM_L2_Ack_IrqHandler(void *pUpperCtx, HSM_BoolType bIsErrorHappen, HSM_StatusType eRet);
void HSM_L2_Init(HSM_L2_RtCtxType *pCtx, HSM_L2_InitParmType *pParm);
void HSM_L2_CleanEnv(HSM_L2_RtCtxType *pCtx);
void HSM_L2_Abort(HSM_L2_RtCtxType *pCtx);
void HSM_L2_CommonExitEnv(HSM_L2_RtCtxType *pCtx);
HSM_StatusType HSM_L2_GetPoll(HSM_L2_RtCtxType *pL2Ctx, HSM_L1_RtCtxType *pL1Ctx, hsm_uint32_t u32TimeoutMs);
HSM_StatusType hsm_l2_revoke_key_process(HSM_L2_RtCtxType *pL2Ctx, HSM_L1_RtCtxType *pL1Ctx, hsm_uint32_t u32TimeoutMs,
HSM_L2_DrvRevokeKeyInfType *pCfg, HSM_StatusType eRetFromPrevious, HSM_TriggerSrcType bTriggerMode);
/****************************************** Local function declarations ***********************************************/
HSM_StatusType HSM_L3_ScatterCMacSetupEnv(HSM_L3_RtCtxType *pL3Ctx, HSM_L2_RtCtxType *pL2Ctx, HSM_L1_RtCtxType *pL1Ctx);
HSM_StatusType HSM_L3_ScatterCMacReset(HSM_L3_RtCtxType *pL3Ctx, HSM_L2_RtCtxType *pL2Ctx, HSM_L1_RtCtxType *pL1Ctx);
HSM_StatusType HSM_L3_ScatterCMacExitEnv(HSM_L3_RtCtxType *pL3Ctx, HSM_L2_RtCtxType *pL2Ctx, HSM_L1_RtCtxType *pL1Ctx);
HSM_StatusType HSM_L3_ScatterCMacInit(HSM_L3_RtCtxType *pL3Ctx, HSM_L2_RtCtxType *pL2Ctx, HSM_L1_RtCtxType *pL1Ctx, const HSM_Ln_CMacCfgParmsType *pKeyCfg,
const HSM_Ln_ScatterCMacType *pCfg, hsm_uint32_t u32TimeoutMs);
HSM_StatusType HSM_L3_ScatterCMacUpdate(HSM_L3_RtCtxType *pL3Ctx, HSM_L2_RtCtxType *pL2Ctx, HSM_L1_RtCtxType *pL1Ctx, const HSM_Ln_ScatterCMacType *pCfg,
hsm_uint32_t u32TimeoutMs);
HSM_StatusType HSM_L3_ScatterCMacFinal(HSM_L3_RtCtxType *pL3Ctx, HSM_L2_RtCtxType *pL2Ctx, HSM_L1_RtCtxType *pL1Ctx, const HSM_Ln_ScatterCMacType *pCfg,
const HSM_Ln_ResultBufInfoType *pResult, hsm_uint32_t u32TimeoutMs);
HSM_StatusType HSM_L3_ScatterCMacPoll(HSM_L3_RtCtxType *pL3Ctx, HSM_L2_RtCtxType *pL2Ctx, HSM_L1_RtCtxType *pL1Ctx, hsm_uint32_t u32TimeoutMs);
HSM_StatusType HSM_L3_UpdateKeySetupEnv(HSM_L3_RtCtxType *pL3Ctx, HSM_L2_RtCtxType *pL2Ctx, HSM_L1_RtCtxType *pL1Ctx);
HSM_StatusType HSM_L3_UpdateKeyReset(HSM_L3_RtCtxType *pL3Ctx, HSM_L2_RtCtxType *pL2Ctx, HSM_L1_RtCtxType *pL1Ctx);
HSM_StatusType HSM_L3_UpdateKeyExitEnv(HSM_L3_RtCtxType *pL3Ctx, HSM_L2_RtCtxType *pL2Ctx, HSM_L1_RtCtxType *pL1Ctx);
void hsm_core_padding_and_swap_array(
hsm_uint32_t *pAlignedDest, hsm_uint32_t u32DestOpWordCnt, const void *pSrcData,
hsm_uint32_t u32SrcOpByteCnt, HSM_DataFormatType eSrcFmt, hsm_uint8_t u8PadByte, HSM_BoolType bPadFromMSB, HSM_BoolType bSwap);
void hsm_pkam_u32_array_append_zero_from_left(hsm_uint8_t *pDest, const hsm_uint8_t *pSrc, hsm_uint32_t u32SrcByteCnt, hsm_uint32_t u32ZeroByteCnt);
const hsm_uint32_t *hsm_pkam_get_loadable_buf(HSM_DataFormatType eInputFmt, hsm_uint32_t *pCacheBufferMayUse,
hsm_uint32_t u32LastCacheByteCnt, const hsm_uint32_t *pSrc, hsm_uint32_t u32SrcByteCnt, hsm_uint32_t u32LoadByteCount);
HSM_StatusType HSM_L3_UpdatePlainKey(HSM_L3_RtCtxType *pL3Ctx, HSM_L2_RtCtxType *pL2Ctx, HSM_L1_RtCtxType *pL1Ctx,
const HSM_Ln_PlainKeyImport *pPlainKey, hsm_uint32_t u32TimeoutMs);
HSM_StatusType HSM_L3_UpdateKeyPoll(HSM_L3_RtCtxType *pL3Ctx, HSM_L2_RtCtxType *pL2Ctx, HSM_L1_RtCtxType *pL1Ctx, hsm_uint32_t u32TimeoutMs);
void HSM_L3_Ack_IrqHandler(void *pUpperCtx, HSM_BoolType bErrorHappen, HSM_StatusType eRet);
void HSM_L3_Init(HSM_L3_RtCtxType *pCtx, HSM_L3_InitParmType *pParm);
void HSM_L3_CleanEnv(HSM_L3_RtCtxType *pCtx);
void HSM_L3_Abort(HSM_L3_RtCtxType *pCtx);
void HSM_L3_CommonExitEnv(HSM_L3_RtCtxType *pCtx);
HSM_StatusType HSM_L3_GetPoll(HSM_L3_RtCtxType *pL3Ctx, HSM_L2_RtCtxType *pL2Ctx, HSM_L1_RtCtxType *pL1Ctx, hsm_uint32_t u32TimeoutMs);
static HSM_StatusType hsm_scatter_cmac_process(HSM_L3_RtCtxType *pL3Ctx, HSM_L2_RtCtxType *pL2Ctx, HSM_L1_RtCtxType *pL1Ctx, hsm_uint32_t u32TimeoutMs,
HSM_L3_DrvScatterCMacInfType *pCfg, HSM_StatusType eRetFromPrevious, HSM_TriggerSrcType bTriggerMode);
/********************************************* Global function *********************************************************/
HSM_StatusType HSM_L3_ScatterCMacSetupEnv(HSM_L3_RtCtxType *pL3Ctx, HSM_L2_RtCtxType *pL2Ctx, HSM_L1_RtCtxType *pL1Ctx)
{
HSM_StatusType eRet = HSM_STATUS_SUCCESS;
(void)pL2Ctx;
(void)pL1Ctx;
if (HSM_LEVEL_3RD_OP_NONE == pL3Ctx->eOperation)
{
pL3Ctx->eOperation = HSM_LEVEL_3RD_OP_SCATTER_CMAC;
pL3Ctx->tL3AlgCtx.tScatterCMac.eState = HSM_L3_SCATTER_CMAC_READY;
pL3Ctx->tL3AlgCtx.tScatterCMac.u32InputTotalSize = 0u;
}
else
{
eRet = HSM_STATUS_BUSY;
}
return eRet;
}
HSM_StatusType HSM_L3_ScatterCMacReset(HSM_L3_RtCtxType *pL3Ctx, HSM_L2_RtCtxType *pL2Ctx, HSM_L1_RtCtxType *pL1Ctx)
{
HSM_StatusType eRet = HSM_STATUS_SUCCESS;
(void)pL2Ctx;
(void)pL1Ctx;
if (HSM_LEVEL_3RD_OP_SCATTER_CMAC == pL3Ctx->eOperation)
{
eRet = HSM_L1_Abort(pL1Ctx);
HSM_L2_Abort(pL2Ctx);
pL3Ctx->tL3AlgCtx.tScatterCMac.eState = HSM_L3_SCATTER_CMAC_READY;
}
else
{
eRet = HSM_STATUS_ERROR;
}
return eRet;
}
HSM_StatusType HSM_L3_ScatterCMacExitEnv(HSM_L3_RtCtxType *pL3Ctx, HSM_L2_RtCtxType *pL2Ctx, HSM_L1_RtCtxType *pL1Ctx)
{
HSM_StatusType eRet = HSM_STATUS_SUCCESS;
if (HSM_LEVEL_3RD_OP_SCATTER_CMAC == pL3Ctx->eOperation)
{
eRet = HSM_L1_Abort(pL1Ctx);
HSM_L2_Abort(pL2Ctx);
pL3Ctx->eOperation = HSM_LEVEL_3RD_OP_NONE;
}
else
{
eRet = HSM_STATUS_ERROR;
}
return eRet;
}
HSM_StatusType HSM_L3_ScatterCMacInit(HSM_L3_RtCtxType *pL3Ctx, HSM_L2_RtCtxType *pL2Ctx, HSM_L1_RtCtxType *pL1Ctx, const HSM_Ln_CMacCfgParmsType *pKeyCfg,
const HSM_Ln_ScatterCMacType *pCfg, hsm_uint32_t u32TimeoutMs)
{
HSM_StatusType eRet;
(void)pL2Ctx;
if (HSM_LEVEL_3RD_OP_SCATTER_CMAC == pL3Ctx->eOperation)
{
if (pL3Ctx->tL3AlgCtx.tScatterCMac.eState == HSM_L3_SCATTER_CMAC_READY)
{
pL3Ctx->tL3AlgCtx.tScatterCMac.u32TimeoutMs = u32TimeoutMs;
if (pCfg->u32DataSize > 0)
{
eRet = HSM_L1_ScatterCMacSetupEnv(pL1Ctx);
if (HSM_STATUS_SUCCESS == eRet)
{
pL3Ctx->tL3AlgCtx.tScatterCMac.eState = HSM_L3_SCATTER_CMAC_INIT;
pL3Ctx->tL3AlgCtx.tScatterCMac.u32InputTotalSize = pCfg->u32DataSize;
eRet = HSM_L1_ScatterCMacInit(pL1Ctx, pKeyCfg, pCfg, u32TimeoutMs);
if (HSM_STATUS_SUCCESS == eRet)
{
;
}
else if (HSM_STATUS_AGAIN == eRet)
{
pL3Ctx->tL3AlgCtx.tScatterCMac.eState = HSM_L3_SCATTER_CMAC_NEED_MORE_AFTER_INIT;
}
else
{
HSM_L1_ScatterCMacExitEnv(pL1Ctx);
pL3Ctx->tL3AlgCtx.tScatterCMac.eState = HSM_L3_SCATTER_CMAC_STOP;
}
}
else
{
pL3Ctx->tL3AlgCtx.tScatterCMac.eState = HSM_L3_SCATTER_CMAC_STOP;
}
}
else
{
pL3Ctx->tL3AlgCtx.tScatterCMac.u32InputTotalSize = 0u;
hsm_memcpy(&(pL3Ctx->tL3AlgCtx.tScatterCMac.tCfgParm), pKeyCfg, sizeof(pL3Ctx->tL3AlgCtx.tScatterCMac.tCfgParm));
pL3Ctx->tL3AlgCtx.tScatterCMac.eState = HSM_L3_SCATTER_CMAC_EMPTY_INPUT;
eRet = HSM_STATUS_AGAIN;
}
}
else
{
eRet = HSM_STATUS_LOGIC_ERR;
}
}
else
{
eRet = HSM_STATUS_BUSY;
}
return eRet;
}
HSM_StatusType HSM_L3_ScatterCMacUpdate(HSM_L3_RtCtxType *pL3Ctx, HSM_L2_RtCtxType *pL2Ctx, HSM_L1_RtCtxType *pL1Ctx, const HSM_Ln_ScatterCMacType *pCfg, hsm_uint32_t u32TimeoutMs)
{
HSM_StatusType eRet;
(void)pL2Ctx;
if (HSM_LEVEL_3RD_OP_SCATTER_CMAC == pL3Ctx->eOperation)
{
if ((pL3Ctx->tL3AlgCtx.tScatterCMac.eState == HSM_L3_SCATTER_CMAC_NEED_MORE_AFTER_INIT) ||
(pL3Ctx->tL3AlgCtx.tScatterCMac.eState == HSM_L3_SCATTER_CMAC_INIT_OK) ||
(pL3Ctx->tL3AlgCtx.tScatterCMac.eState == HSM_L3_SCATTER_CMAC_NEED_MORE_AFTER_UPDATE) ||
(pL3Ctx->tL3AlgCtx.tScatterCMac.eState == HSM_L3_SCATTER_CMAC_UPDATE_OK))
{
pL3Ctx->tL3AlgCtx.tScatterCMac.u32TimeoutMs = u32TimeoutMs;
pL3Ctx->tL3AlgCtx.tScatterCMac.eState = HSM_L3_SCATTER_CMAC_UPDATE;
pL3Ctx->tL3AlgCtx.tScatterCMac.u32InputTotalSize += pCfg->u32DataSize;
eRet = HSM_L1_ScatterCMacUpdate(pL1Ctx, pCfg, u32TimeoutMs);
if (HSM_STATUS_SUCCESS == eRet)
{
;
}
else if (HSM_STATUS_AGAIN == eRet)
{
pL3Ctx->tL3AlgCtx.tScatterCMac.eState = HSM_L3_SCATTER_CMAC_NEED_MORE_AFTER_UPDATE;
}
else
{
HSM_L1_ScatterCMacExitEnv(pL1Ctx);
pL3Ctx->tL3AlgCtx.tScatterCMac.eState = HSM_L3_SCATTER_CMAC_STOP;
}
}
else if (pL3Ctx->tL3AlgCtx.tScatterCMac.eState == HSM_L3_SCATTER_CMAC_EMPTY_INPUT)
{
pL3Ctx->tL3AlgCtx.tScatterCMac.u32TimeoutMs = u32TimeoutMs;
if (pCfg->u32DataSize > 0)
{
eRet = HSM_L1_ScatterCMacSetupEnv(pL1Ctx);
if (HSM_STATUS_SUCCESS == eRet)
{
pL3Ctx->tL3AlgCtx.tScatterCMac.eState = HSM_L3_SCATTER_CMAC_INIT;
pL3Ctx->tL3AlgCtx.tScatterCMac.u32InputTotalSize = pCfg->u32DataSize;
eRet = HSM_L1_ScatterCMacInit(pL1Ctx, &(pL3Ctx->tL3AlgCtx.tScatterCMac.tCfgParm), pCfg, u32TimeoutMs);
if (HSM_STATUS_SUCCESS == eRet)
{
;
}
else if (HSM_STATUS_AGAIN == eRet)
{
pL3Ctx->tL3AlgCtx.tScatterCMac.eState = HSM_L3_SCATTER_CMAC_NEED_MORE_AFTER_INIT;
}
else
{
HSM_L1_ScatterCMacExitEnv(pL1Ctx);
pL3Ctx->tL3AlgCtx.tScatterCMac.eState = HSM_L3_SCATTER_CMAC_STOP;
}
}
else
{
pL3Ctx->tL3AlgCtx.tScatterCMac.eState = HSM_L3_SCATTER_CMAC_STOP;
}
}
else
{
eRet = HSM_STATUS_AGAIN;
}
}
else
{
eRet = HSM_STATUS_LOGIC_ERR;
}
}
else
{
eRet = HSM_STATUS_BUSY;
}
return eRet;
}
HSM_StatusType HSM_L3_ScatterCMacFinal(HSM_L3_RtCtxType *pL3Ctx, HSM_L2_RtCtxType *pL2Ctx, HSM_L1_RtCtxType *pL1Ctx, const HSM_Ln_ScatterCMacType *pCfg,
const HSM_Ln_ResultBufInfoType *pResult, hsm_uint32_t u32TimeoutMs)
{
HSM_StatusType eRet;
if (HSM_LEVEL_3RD_OP_SCATTER_CMAC == pL3Ctx->eOperation)
{
if ((pL3Ctx->tL3AlgCtx.tScatterCMac.eState == HSM_L3_SCATTER_CMAC_NEED_MORE_AFTER_INIT) ||
(pL3Ctx->tL3AlgCtx.tScatterCMac.eState == HSM_L3_SCATTER_CMAC_INIT_OK) ||
(pL3Ctx->tL3AlgCtx.tScatterCMac.eState == HSM_L3_SCATTER_CMAC_NEED_MORE_AFTER_UPDATE) ||
(pL3Ctx->tL3AlgCtx.tScatterCMac.eState == HSM_L3_SCATTER_CMAC_UPDATE_OK))
{
pL3Ctx->tL3AlgCtx.tScatterCMac.u32TimeoutMs = u32TimeoutMs;
pL3Ctx->tL3AlgCtx.tScatterCMac.eState = HSM_L3_SCATTER_CMAC_FINAL;
pL3Ctx->tL3AlgCtx.tScatterCMac.u32InputTotalSize += pCfg->u32DataSize;
eRet = HSM_L1_ScatterCMacFinal(pL1Ctx, pCfg, pResult, u32TimeoutMs);
if (HSM_STATUS_SUCCESS == eRet)
{
;
}
else
{
HSM_L1_ScatterCMacExitEnv(pL1Ctx);
pL3Ctx->tL3AlgCtx.tScatterCMac.eState = HSM_L3_SCATTER_CMAC_STOP;
}
}
else if (pL3Ctx->tL3AlgCtx.tScatterCMac.eState == HSM_L3_SCATTER_CMAC_EMPTY_INPUT)
{
pL3Ctx->tL3AlgCtx.tScatterCMac.u32TimeoutMs = u32TimeoutMs;
if (pCfg->u32DataSize > 0)
{
eRet = HSM_L1_ScatterCMacSetupEnv(pL1Ctx);
if (HSM_STATUS_SUCCESS == eRet)
{
pL3Ctx->tL3AlgCtx.tScatterCMac.eState = HSM_L3_SCATTER_CMAC_FINAL;
pL3Ctx->tL3AlgCtx.tScatterCMac.u32InputTotalSize = pCfg->u32DataSize;
eRet = HSM_L1_ScatterCMacInit(pL1Ctx, &(pL3Ctx->tL3AlgCtx.tScatterCMac.tCfgParm), NULL_PTR, u32TimeoutMs);
if (HSM_STATUS_AGAIN == eRet)
{
eRet = HSM_L1_ScatterCMacFinal(pL1Ctx, pCfg, pResult, u32TimeoutMs);
if (HSM_STATUS_SUCCESS == eRet)
{
;
}
else
{
HSM_L1_ScatterCMacExitEnv(pL1Ctx);
pL3Ctx->tL3AlgCtx.tScatterCMac.eState = HSM_L3_SCATTER_CMAC_STOP;
}
}
else
{
HSM_L1_ScatterCMacExitEnv(pL1Ctx);
pL3Ctx->tL3AlgCtx.tScatterCMac.eState = HSM_L3_SCATTER_CMAC_STOP;
}
}
else
{
pL3Ctx->tL3AlgCtx.tScatterCMac.eState = HSM_L3_SCATTER_CMAC_STOP;
}
}
else
{
eRet = HSM_L2_CMacEmptySetupEnv(pL2Ctx, pL1Ctx);
if (HSM_STATUS_SUCCESS == eRet)
{
pL3Ctx->tL3AlgCtx.tScatterCMac.eState = HSM_L3_SCATTER_CMAC_FINAL;
pL3Ctx->tL3AlgCtx.tScatterCMac.u32InputTotalSize = pCfg->u32DataSize;
eRet = HSM_L2_CMacEmpty(pL2Ctx, pL1Ctx, &(pL3Ctx->tL3AlgCtx.tScatterCMac.tCfgParm), pResult, u32TimeoutMs);
if (HSM_STATUS_SUCCESS == eRet)
{
;
}
else
{
HSM_L2_CMacEmptyExitEnv(pL2Ctx, pL1Ctx);
pL3Ctx->tL3AlgCtx.tScatterCMac.eState = HSM_L3_SCATTER_CMAC_STOP;
}
}
else
{
pL3Ctx->tL3AlgCtx.tScatterCMac.eState = HSM_L3_SCATTER_CMAC_STOP;
}
}
}
else
{
eRet = HSM_STATUS_LOGIC_ERR;
}
}
else
{
eRet = HSM_STATUS_BUSY;
}
return eRet;
}
static HSM_StatusType hsm_scatter_cmac_process(HSM_L3_RtCtxType *pL3Ctx, HSM_L2_RtCtxType *pL2Ctx, HSM_L1_RtCtxType *pL1Ctx, hsm_uint32_t u32TimeoutMs,
HSM_L3_DrvScatterCMacInfType *pCfg, HSM_StatusType eRetFromPrevious, HSM_TriggerSrcType bTriggerMode)
{
HSM_StatusType eRet;
HSM_StatusType eTempRetFromPrevious = eRetFromPrevious;
switch (pCfg->eState)
{
case HSM_L3_SCATTER_CMAC_INIT:
{
if (HSM_TRIGGER_SRC_ISR == bTriggerMode)
{
; /* nothing to do */
}
else
{
eTempRetFromPrevious = HSM_L1_ScatterCMacPoll(pL1Ctx);
if ((HSM_STATUS_AGAIN != eTempRetFromPrevious) && (HSM_STATUS_SUCCESS != eTempRetFromPrevious))
{
HSM_L1_ScatterCMacExitEnv(pL1Ctx);
}
}
if (HSM_STATUS_SUCCESS == eTempRetFromPrevious)
{
pL3Ctx->tL3AlgCtx.tScatterCMac.eState = HSM_L3_SCATTER_CMAC_INIT_OK;
eRet = HSM_STATUS_SUCCESS;
}
else if ((HSM_TRIGGER_SRC_ISR != bTriggerMode) && (HSM_STATUS_AGAIN == eTempRetFromPrevious))
{
eRet = HSM_STATUS_AGAIN;
}
else
{
pL3Ctx->tL3AlgCtx.tScatterCMac.eState = HSM_L3_SCATTER_CMAC_STOP;
eRet = HSM_STATUS_ERROR;
}
}
break;
case HSM_L3_SCATTER_CMAC_UPDATE:
{
if (HSM_TRIGGER_SRC_ISR == bTriggerMode)
{
;
}
else
{
eTempRetFromPrevious = HSM_L1_ScatterCMacPoll(pL1Ctx);
if ((HSM_STATUS_AGAIN != eTempRetFromPrevious) && (HSM_STATUS_SUCCESS != eTempRetFromPrevious))
{
HSM_L1_ScatterCMacExitEnv(pL1Ctx);
}
}
if (HSM_STATUS_SUCCESS == eTempRetFromPrevious)
{
pL3Ctx->tL3AlgCtx.tScatterCMac.eState = HSM_L3_SCATTER_CMAC_UPDATE_OK;
eRet = HSM_STATUS_SUCCESS;
}
else if ((HSM_TRIGGER_SRC_ISR != bTriggerMode) && (HSM_STATUS_AGAIN == eTempRetFromPrevious))
{
eRet = HSM_STATUS_AGAIN;
}
else
{
pL3Ctx->tL3AlgCtx.tScatterCMac.eState = HSM_L3_SCATTER_CMAC_STOP;
eRet = HSM_STATUS_ERROR;
}
}
break;
case HSM_L3_SCATTER_CMAC_FINAL:
{
if (HSM_TRIGGER_SRC_ISR == bTriggerMode)
{
HSM_L1_CommonExitEnv(pL1Ctx);
HSM_L2_CommonExitEnv(pL2Ctx);
}
else
{
if (pL3Ctx->tL3AlgCtx.tScatterCMac.u32InputTotalSize > 0u)
{
eTempRetFromPrevious = HSM_L1_ScatterCMacPoll(pL1Ctx);
if (HSM_STATUS_AGAIN != eTempRetFromPrevious)
{
HSM_L1_ScatterCMacExitEnv(pL1Ctx);
}
}
else
{
eTempRetFromPrevious = HSM_L2_CMacEmptyPoll(pL2Ctx, pL1Ctx, u32TimeoutMs);
if (HSM_STATUS_AGAIN != eTempRetFromPrevious)
{
HSM_L2_CMacEmptyExitEnv(pL2Ctx, pL1Ctx);
}
}
}
if (HSM_STATUS_SUCCESS == eTempRetFromPrevious)
{
pL3Ctx->tL3AlgCtx.tScatterCMac.eState = HSM_L3_SCATTER_CMAC_STOP;
eRet = HSM_STATUS_SUCCESS;
}
else if ((HSM_TRIGGER_SRC_ISR != bTriggerMode) && (HSM_STATUS_AGAIN == eTempRetFromPrevious))
{
eRet = HSM_STATUS_AGAIN;
}
else
{
pL3Ctx->tL3AlgCtx.tScatterCMac.eState = HSM_L3_SCATTER_CMAC_STOP;
eRet = HSM_STATUS_ERROR;
}
}
break;
default:
eRet = HSM_STATUS_LOGIC_ERR;
break;
}
return eRet;
}
HSM_StatusType HSM_L3_ScatterCMacPoll(HSM_L3_RtCtxType *pL3Ctx, HSM_L2_RtCtxType *pL2Ctx, HSM_L1_RtCtxType *pL1Ctx, hsm_uint32_t u32TimeoutMs)
{
HSM_StatusType eRet;
if (HSM_LEVEL_3RD_OP_SCATTER_CMAC == pL3Ctx->eOperation)
{
eRet = hsm_scatter_cmac_process(pL3Ctx, pL2Ctx, pL1Ctx, u32TimeoutMs, &(pL3Ctx->tL3AlgCtx.tScatterCMac), HSM_STATUS_SUCCESS, pL1Ctx->eTriggerSrc);
}
else
{
eRet = HSM_STATUS_ERROR;
}
return eRet;
}
/* --------------------------------------------------------------------------- */
/* --------------------------------------------------------------------------- */
HSM_StatusType HSM_L3_UpdateKeySetupEnv(HSM_L3_RtCtxType *pL3Ctx, HSM_L2_RtCtxType *pL2Ctx, HSM_L1_RtCtxType *pL1Ctx)
{
HSM_StatusType eRet = HSM_STATUS_SUCCESS;
(void)pL2Ctx;
(void)pL1Ctx;
if (HSM_LEVEL_3RD_OP_NONE == pL3Ctx->eOperation)
{
pL3Ctx->eOperation = HSM_LEVEL_3RD_OP_UPDATE_KEY;
pL3Ctx->tL3AlgCtx.tUpdateKey.eState = HSM_L3_UPDATE_KEY_READY;
}
else
{
eRet = HSM_STATUS_BUSY;
}
return eRet;
}
HSM_StatusType HSM_L3_UpdateKeyReset(HSM_L3_RtCtxType *pL3Ctx, HSM_L2_RtCtxType *pL2Ctx, HSM_L1_RtCtxType *pL1Ctx)
{
HSM_StatusType eRet = HSM_STATUS_SUCCESS;
(void)pL2Ctx;
(void)pL1Ctx;
if (HSM_LEVEL_3RD_OP_UPDATE_KEY == pL3Ctx->eOperation)
{
eRet = HSM_L1_Abort(pL1Ctx);
HSM_L2_Abort(pL2Ctx);
pL3Ctx->tL3AlgCtx.tUpdateKey.eState = HSM_L3_UPDATE_KEY_READY;
}
else
{
eRet = HSM_STATUS_ERROR;
}
return eRet;
}
HSM_StatusType HSM_L3_UpdateKeyExitEnv(HSM_L3_RtCtxType *pL3Ctx, HSM_L2_RtCtxType *pL2Ctx, HSM_L1_RtCtxType *pL1Ctx)
{
HSM_StatusType eRet = HSM_STATUS_SUCCESS;
if (HSM_LEVEL_3RD_OP_UPDATE_KEY == pL3Ctx->eOperation)
{
eRet = HSM_L1_Abort(pL1Ctx);
HSM_L2_Abort(pL2Ctx);
pL3Ctx->eOperation = HSM_LEVEL_3RD_OP_NONE;
}
else
{
eRet = HSM_STATUS_ERROR;
}
return eRet;
}
void hsm_core_padding_and_swap_array(
hsm_uint32_t *pAlignedDest, hsm_uint32_t u32DestOpWordCnt, const void *pSrcData,
hsm_uint32_t u32SrcOpByteCnt, HSM_DataFormatType eSrcFmt, hsm_uint8_t u8PadByte, HSM_BoolType bPadFromMSB, HSM_BoolType bSwap)
{
hsm_uint32_t u32Idx = 0;
hsm_uint32_t u32Temp;
hsm_uint32_t u32Data;
hsm_uint32_t u32DestIdx;
const hsm_uint32_t *pSrc = (const hsm_uint32_t *)pSrcData;
hsm_uint32_t u32DestWordCnt = u32DestOpWordCnt;
hsm_uint32_t u32SrcByteCnt = u32SrcOpByteCnt;
if ((u32DestWordCnt << 2u) < u32SrcByteCnt)
{
u32SrcByteCnt = (u32DestWordCnt << 2u);
}
u32Temp = u32SrcByteCnt >> 2u; /* the word cnt, remove the extra bytes */
if (0u == (((hsm_uint32_t)pSrc) & 0x3u))
{
if (HSM_FALSE != bSwap)
{
for (; u32Idx < u32Temp; ++u32Idx)
{
pAlignedDest[u32Idx] = hsm_hw_swap_u32(pSrc[u32Idx]);
}
}
else
{
for (; u32Idx < u32Temp; ++u32Idx)
{
pAlignedDest[u32Idx] = pSrc[u32Idx];
}
}
}
else
{
if (HSM_FALSE != bSwap)
{
for (; u32Idx < u32Temp; ++u32Idx)
{
u32DestIdx = (hsm_uint32_t)pSrc + (u32Idx * 4);
u32Data = *((hsm_uint8_t *)u32DestIdx + 3);
u32Data = (u32Data << 8u) | (*((hsm_uint8_t *)u32DestIdx + 2));
u32Data = (u32Data << 8u) | (*((hsm_uint8_t *)u32DestIdx + 1));
u32Data = (u32Data << 8u) | (*((hsm_uint8_t *)u32DestIdx + 0));
pAlignedDest[u32Idx] = hsm_hw_swap_u32(u32Data);
}
}
else
{
for (; u32Idx < u32Temp; ++u32Idx)
{
u32DestIdx = (hsm_uint32_t)pSrc + (u32Idx * 4);
u32Data = *((hsm_uint8_t *)u32DestIdx + 3);
u32Data = (u32Data << 8u) | (*((hsm_uint8_t *)u32DestIdx + 2));
u32Data = (u32Data << 8u) | (*((hsm_uint8_t *)u32DestIdx + 1));
u32Data = (u32Data << 8u) | (*((hsm_uint8_t *)u32DestIdx + 0));
pAlignedDest[u32Idx] = (u32Data);
}
}
}
u32DestIdx = u32Idx;
u32Temp = (u32SrcByteCnt % 4u);
if (0u != u32Temp)
{
u32Temp = 4u - u32Temp; /* 1-3 -> 3-1, get the pad byte cnt */
u32SrcByteCnt = (hsm_uint32_t)pSrc + (u32Idx * 4);
u32Data = 0u;
if (HSM_DATA_FORMAT_1B == eSrcFmt)
{
/* be careful to not read exceed the border */
if (u32Temp == 1u) /* pad 1 byte, so can read 3bytes */
{
u32Data = (u32Data << 8u) | (*((hsm_uint8_t *)u32SrcByteCnt + 2));
u32Data = (u32Data << 8u) | (*((hsm_uint8_t *)u32SrcByteCnt + 1));
u32Data = (u32Data << 8u) | (*((hsm_uint8_t *)u32SrcByteCnt + 0));
}
else if (u32Temp == 2u)
{
u32Data = (u32Data << 8u) | (*((hsm_uint8_t *)u32SrcByteCnt + 1));
u32Data = (u32Data << 8u) | (*((hsm_uint8_t *)u32SrcByteCnt + 0));
}
else
{
u32Data = (u32Data << 8u) | (*((hsm_uint8_t *)u32SrcByteCnt + 0));
}
}
else /* source is 4B format */
{
/* be careful to not read exceed the border */
if (u32Temp == 1u) /* pad 1 byte, so can read 3bytes */
{
u32Data = (u32Data << 8u) | (*((hsm_uint8_t *)u32SrcByteCnt + 3));
u32Data = (u32Data << 8u) | (*((hsm_uint8_t *)u32SrcByteCnt + 2));
u32Data = (u32Data << 8u) | (*((hsm_uint8_t *)u32SrcByteCnt + 1));
u32Data = (u32Data << 8u); /* & 0xFFFFFF00u */
}
else if (u32Temp == 2u)
{
u32Data = (u32Data << 8u) | (*((hsm_uint8_t *)u32SrcByteCnt + 3));
u32Data = (u32Data << 8u) | (*((hsm_uint8_t *)u32SrcByteCnt + 2));
u32Data = (u32Data << 16u); /* & 0xFFFF0000u */
}
else
{
u32Data = (u32Data << 8u) | (*((hsm_uint8_t *)u32SrcByteCnt + 3));
u32Data = (u32Data << 24u); /* & 0xFF000000u */
}
}
if (HSM_FALSE != bPadFromMSB) /* pad data at the high address of the last word of the input buffer */
{
u32Data = u32Data << (u32Temp * 8u);
for (u32Idx = 0; u32Idx < u32Temp; ++u32Idx)
{
u32Data = (u32Data >> 8u) | (((hsm_uint32_t)u8PadByte) << 24u);
}
}
else
{
u32Data = u32Data >> (u32Temp * 8u);
for (u32Idx = 0; u32Idx < u32Temp; ++u32Idx)
{
u32Data = (u32Data << 8u) | (((hsm_uint32_t)u8PadByte));
}
}
if (HSM_FALSE != bSwap)
{
pAlignedDest[u32DestIdx] = hsm_hw_swap_u32(u32Data);
}
else
{
pAlignedDest[u32DestIdx] = (u32Data);
}
u32DestIdx++;
}
hsm_memset(pAlignedDest + u32DestIdx, u8PadByte, (u32DestWordCnt << 2u) - (u32DestIdx << 2u));
}
void hsm_pkam_u32_array_append_zero_from_left(hsm_uint8_t *pDest, const hsm_uint8_t *pSrc, hsm_uint32_t u32SrcByteCnt, hsm_uint32_t u32ZeroByteCnt)
{
hsm_uint32_t u32PadZeroTailCnt;
hsm_uint32_t u32Left;
hsm_uint8_t *pDestInter;
const hsm_uint8_t *pSrcInter;
hsm_uint8_t u8Data;
if (0u == u32ZeroByteCnt)
{
if (pDest != pSrc)
{
hsm_bidi_memcpy(pDest, pSrc, u32SrcByteCnt, 1);
}
else
{
; /* nothing to do */
}
}
else
{
pSrcInter = pSrc;
u32Left = u32SrcByteCnt;
pDestInter = pDest + u32ZeroByteCnt;
hsm_memset(pDest, 0, u32ZeroByteCnt);
while (u32Left > 3u)
{
pDestInter[0] = pSrcInter[3];
pDestInter[1] = pSrcInter[2];
pDestInter[2] = pSrcInter[1];
pDestInter[3] = pSrcInter[0];
u32Left -= 4u;
pDestInter += 4u;
pSrcInter += 4u;
}
if (3u == u32Left)
{
pDestInter[0] = pSrcInter[3];
pDestInter[1] = pSrcInter[2];
pDestInter[2] = pSrcInter[1];
pDestInter += 3u;
}
else if (2u == u32Left)
{
pDestInter[0] = pSrcInter[3];
pDestInter[1] = pSrcInter[2];
pDestInter += 2u;
}
else if (1u == u32Left)
{
pDestInter[0] = pSrcInter[3];
pDestInter += 1u;
}
else
{
; /* nothing to do */
}
u32PadZeroTailCnt = 4u - ((u32SrcByteCnt + u32ZeroByteCnt) % 4u);
hsm_memset(pDestInter, 0, u32PadZeroTailCnt);
u32Left = u32ZeroByteCnt + u32SrcByteCnt + u32PadZeroTailCnt;
pDestInter = pDest;
while (u32Left > 3u)
{
u8Data = pDestInter[3];
pDestInter[3] = pDestInter[0];
pDestInter[0] = u8Data;
u8Data = pDestInter[2];
pDestInter[2] = pDestInter[1];
pDestInter[1] = u8Data;
u32Left -= 4u;
pDestInter += 4u;
}
}
}
const hsm_uint32_t *hsm_pkam_get_loadable_buf(HSM_DataFormatType eInputFmt, hsm_uint32_t *pCacheBufferMayUse,
hsm_uint32_t u32LastCacheByteCnt, const hsm_uint32_t *pSrc, hsm_uint32_t u32SrcByteCnt, hsm_uint32_t u32LoadByteCount)
{
const hsm_uint32_t *pRet;
hsm_uint32_t u32WordCnt = u32LoadByteCount >> 2U;
hsm_uint32_t u32Temp;
hsm_uint32_t u32CacheByteCnt = u32LastCacheByteCnt;
hsm_uint32_t *pCacheMayUse = pCacheBufferMayUse;
hsm_uint32_t *pAlignedCache = (hsm_uint32_t *)(((((hsm_uint32_t)pCacheMayUse) + 3u) >> 2u) << 2u);
u32CacheByteCnt = u32CacheByteCnt - (((hsm_uint32_t)pAlignedCache) - ((hsm_uint32_t)pCacheMayUse));
pCacheMayUse = pAlignedCache; /* make sure the buffer start address is 4bytes aligned */
if (((((u32LoadByteCount + 7u) >> 3u) << 3u) <= u32CacheByteCnt) && /* require load cache size is enough for load data 8byte aligned */
(0 == (u32LoadByteCount % 4)) &&
(u32LoadByteCount >= u32SrcByteCnt))
{
if (u32SrcByteCnt == u32LoadByteCount)
{
if (HSM_DATA_FORMAT_1B == eInputFmt) /* 1bytes unit format */
{
hsm_core_padding_and_swap_array(pCacheMayUse, u32WordCnt, pSrc, u32LoadByteCount, eInputFmt, 0, HSM_TRUE, HSM_TRUE);
if (0u != (u32LoadByteCount % 8u))
{
pCacheMayUse[u32WordCnt] = 0u;
}
/* else nothing */
pRet = pCacheMayUse;
}
/* 4byte format, if input start address not 4bytes aligned, or load byte cnt not 8bytes aligned, need pad 0, these two case should use cache */
else if (((((hsm_uint32_t)pSrc) & 0x3u) != 0u) || (0u != (u32LoadByteCount % 8u))) /* && (0u != pSrc[u32LoadByteCount/4u]))) not read more to trigger MPU protect */
{
hsm_core_padding_and_swap_array(pCacheMayUse, u32WordCnt, pSrc, u32LoadByteCount, eInputFmt, 0, HSM_FALSE, HSM_FALSE);
if (0u != (u32LoadByteCount % 8u))
{
pCacheMayUse[u32WordCnt] = 0u;
}
/* else nothing */
pRet = pCacheMayUse;
}
else
{
pRet = pSrc;
}
}
else
{
pRet = pCacheMayUse;
if (HSM_DATA_FORMAT_1B == eInputFmt) /* 1bytes unit format */
{
u32Temp = u32LoadByteCount - u32SrcByteCnt;
hsm_memset(pCacheMayUse, 0U, u32Temp);
hsm_bidi_memcpy(((hsm_uint8_t *)pCacheMayUse) + u32Temp, pSrc, u32SrcByteCnt, 1);
hsm_core_padding_and_swap_array(pCacheMayUse, u32WordCnt, pCacheMayUse, u32LoadByteCount, eInputFmt, 0, HSM_TRUE,
HSM_TRUE); /* the data size has patched to u32LoadByteCount size */
if (0u != (u32LoadByteCount % 8u))
{
pCacheMayUse[u32WordCnt] = 0u;
}
}
else /* 4bytes unit format */
{
u32Temp = u32LoadByteCount - u32SrcByteCnt;
hsm_pkam_u32_array_append_zero_from_left((hsm_uint8_t *)pCacheMayUse, (const hsm_uint8_t *)pSrc, u32SrcByteCnt, u32Temp);
if (0u != (u32LoadByteCount % 8u))
{
pCacheMayUse[u32WordCnt] = 0u;
}
/* else nothing */
}
}
}
else
{
pRet = pSrc; /* error case, make sure the caller not trigger this */
}
return pRet;
}
HSM_StatusType HSM_L3_UpdatePlainKey(HSM_L3_RtCtxType *pL3Ctx, HSM_L2_RtCtxType *pL2Ctx, HSM_L1_RtCtxType *pL1Ctx,
const HSM_Ln_PlainKeyImport *pPlainKey, hsm_uint32_t u32TimeoutMs)
{
HSM_StatusType eRet;
HSM_Ln_ImportUserKeyExtType tCfg;
hsm_uint32_t u32ActualStoreSize;
if (HSM_LEVEL_3RD_OP_UPDATE_KEY == pL3Ctx->eOperation)
{
if (pL3Ctx->tL3AlgCtx.tUpdateKey.eState == HSM_L3_UPDATE_KEY_READY)
{
if ((pPlainKey->u32KeyId) &&
(!((HSM_LN_KEY_DATA_STORE_FMT_SPLIT_BN_LOADABLE == pPlainKey->eKeyStoreFmt) && (pPlainKey->u32KeyDataByteCnt & 0x1u))))
{
pL3Ctx->tL3AlgCtx.tUpdateKey.u32TimeoutMs = u32TimeoutMs;
u32ActualStoreSize = pPlainKey->u32KeyDataByteCnt;
tCfg.bStoreInFlash = (pPlainKey->u32KeyId & 0x1u) ? HSM_FALSE : HSM_TRUE;
tCfg.eExportType = pPlainKey->eExportType;
tCfg.pKeyID = NULL_PTR;
tCfg.eDecryType = KEYMANAGER_ENDECRY_NONE;
tCfg.u32DecryKeyID = 0U;
tCfg.eUserKeyType = KEYMANAGER_USER_KEY_TYPE_NONE; /* ignore the key type */
tCfg.eAlgType = KEYMANAGER_ENDECRY_ALG_CTR;
tCfg.pIV = NULL_PTR;
tCfg.u32KeyIdFix = pPlainKey->u32KeyId;
tCfg.u32Protect = 0u;
if (HSM_LN_KEY_DATA_STORE_FMT_BN_LOADABLE == pPlainKey->eKeyStoreFmt)
{
/* 4B format, 8bytes size aligned */
u32ActualStoreSize = ((pPlainKey->u32KeyDataByteCnt + 7u) >> 3u) << 3u;
tCfg.pDataAddr = hsm_pkam_get_loadable_buf(
pPlainKey->eKeyDataFmt, &(pL3Ctx->tL3AlgCtx.tUpdateKey.aKeyDataCache[0]),
sizeof(pL3Ctx->tL3AlgCtx.tUpdateKey.aKeyDataCache), (const hsm_uint32_t *)pPlainKey->pKeyData, pPlainKey->u32KeyDataByteCnt, u32ActualStoreSize);
tCfg.u32DataLength = u32ActualStoreSize;
}
else if (HSM_LN_KEY_DATA_STORE_FMT_SPLIT_BN_LOADABLE == pPlainKey->eKeyStoreFmt)
{
if (KEYMANAGER_USER_KEY_TYPE_SM2_PUBLIC == pPlainKey->eKeyUsage)
{
u32ActualStoreSize = 32u;
}
else
{
u32ActualStoreSize = (((pPlainKey->u32KeyDataByteCnt >> 1u) + 7u) >> 3u) << 3u;
}
tCfg.pDataAddr = hsm_pkam_get_loadable_buf(
pPlainKey->eKeyDataFmt, &(pL3Ctx->tL3AlgCtx.tUpdateKey.aKeyDataCache[0]),
u32ActualStoreSize, (const hsm_uint32_t *)pPlainKey->pKeyData, pPlainKey->u32KeyDataByteCnt >> 1u, u32ActualStoreSize);
if ((const void *)tCfg.pDataAddr != (const void *)pPlainKey->pKeyData)
{
hsm_pkam_get_loadable_buf(
pPlainKey->eKeyDataFmt, (hsm_uint32_t *)(((hsm_uint8_t *)tCfg.pDataAddr) + u32ActualStoreSize),
u32ActualStoreSize,
(const hsm_uint32_t *)((const hsm_uint8_t *)pPlainKey->pKeyData + (pPlainKey->u32KeyDataByteCnt >> 1u)),
pPlainKey->u32KeyDataByteCnt >> 1u, u32ActualStoreSize);
}
tCfg.u32DataLength = u32ActualStoreSize << 1u;
}
else if (HSM_LN_KEY_DATA_STORE_FMT_1B == pPlainKey->eKeyStoreFmt)
{
/* force 1B format */
if (HSM_DATA_FORMAT_4B == pPlainKey->eKeyDataFmt)
{
u32ActualStoreSize = ((pPlainKey->u32KeyDataByteCnt + 3u) >> 2u) << 2u;
hsm_core_padding_and_swap_array(&(pL3Ctx->tL3AlgCtx.tUpdateKey.aKeyDataCache[0]), u32ActualStoreSize >> 2u,
pPlainKey->pKeyData, pPlainKey->u32KeyDataByteCnt, pPlainKey->eKeyDataFmt, 0, HSM_FALSE, HSM_TRUE);
tCfg.pDataAddr = &(pL3Ctx->tL3AlgCtx.tUpdateKey.aKeyDataCache[0]);
tCfg.u32DataLength = pPlainKey->u32KeyDataByteCnt;
/* tCfg.u32DataLength NOT change */
}
else
{
hsm_memcpy((void*)(&(pL3Ctx->tL3AlgCtx.tUpdateKey.aKeyDataCache[0])),(const void *)pPlainKey->pKeyData,pPlainKey->u32KeyDataByteCnt);
tCfg.pDataAddr = &(pL3Ctx->tL3AlgCtx.tUpdateKey.aKeyDataCache[0]);
tCfg.u32DataLength = pPlainKey->u32KeyDataByteCnt;
}
}
else /* HSM_LN_KEY_DATA_STORE_FMT_4B */
{
if (HSM_DATA_FORMAT_1B == pPlainKey->eKeyDataFmt)
{
u32ActualStoreSize = ((pPlainKey->u32KeyDataByteCnt + 3u) >> 2u) << 2u; /* normal key data, size 4bytes aligned, force 4B format */
hsm_core_padding_and_swap_array(&(pL3Ctx->tL3AlgCtx.tUpdateKey.aKeyDataCache[0]), u32ActualStoreSize >> 2u,
pPlainKey->pKeyData, pPlainKey->u32KeyDataByteCnt, pPlainKey->eKeyDataFmt, 0, HSM_TRUE, HSM_TRUE);
tCfg.pDataAddr = (const hsm_uint32_t *)(&(pL3Ctx->tL3AlgCtx.tUpdateKey.aKeyDataCache[0]));
tCfg.u32DataLength = u32ActualStoreSize;
}
else
{
hsm_memcpy((void*)(&(pL3Ctx->tL3AlgCtx.tUpdateKey.aKeyDataCache[0])),(const void *)pPlainKey->pKeyData,pPlainKey->u32KeyDataByteCnt);
tCfg.pDataAddr = (const hsm_uint32_t *)(&(pL3Ctx->tL3AlgCtx.tUpdateKey.aKeyDataCache[0]));
tCfg.u32DataLength = pPlainKey->u32KeyDataByteCnt;
}
}
eRet = HSM_L2_UpdateKeySetupEnv(pL2Ctx, pL1Ctx);
if (HSM_STATUS_SUCCESS == eRet)
{
pL3Ctx->tL3AlgCtx.tUpdateKey.eState = HSM_L3_UPDATE_KEY_PROCESS;
eRet = HSM_L2_UpdateKey(pL2Ctx, pL1Ctx, &tCfg, u32TimeoutMs);
if (HSM_STATUS_SUCCESS == eRet)
{
;
}
else
{
HSM_L2_UpdateKeyExitEnv(pL2Ctx, pL1Ctx);
pL3Ctx->tL3AlgCtx.tUpdateKey.eState = HSM_L3_UPDATE_KEY_STOP;
}
}
else
{
pL3Ctx->tL3AlgCtx.tUpdateKey.eState = HSM_L3_UPDATE_KEY_STOP;
}
}
else
{
eRet = HSM_STATUS_PARAM_ERR;
}
}
else
{
eRet = HSM_STATUS_LOGIC_ERR;
}
}
else
{
eRet = HSM_STATUS_BUSY;
}
return eRet;
}
HSM_StatusType HSM_L3_UpdateKeyPoll(HSM_L3_RtCtxType *pL3Ctx, HSM_L2_RtCtxType *pL2Ctx, HSM_L1_RtCtxType *pL1Ctx, hsm_uint32_t u32TimeoutMs)
{
HSM_StatusType eRet;
if (HSM_LEVEL_3RD_OP_UPDATE_KEY == pL3Ctx->eOperation)
{
eRet = HSM_L2_UpdateKeyPoll(pL2Ctx, pL1Ctx, u32TimeoutMs);
}
else
{
eRet = HSM_STATUS_ERROR;
}
return eRet;
}
/* --------------------------------------------------------------------------- */
/* --------------------------------------------------------------------------- */
void HSM_L3_Ack_IrqHandler(void *pUpperCtx, HSM_BoolType bErrorHappen, HSM_StatusType eRet)
{
HSM_StatusType eCurStat = eRet;
HSM_BoolType bRunning = HSM_TRUE;
HSM_Ln_RtCtxType *pLnCtx = (HSM_Ln_RtCtxType *)pUpperCtx;
HSM_L3_RtCtxType *pL3Ctx = &(pLnCtx->tHsmL3Ctx);
HSM_L2_RtCtxType *pL2Ctx = &(pLnCtx->tHsmL2Ctx);
HSM_L1_RtCtxType *pL1Ctx = &(pLnCtx->tHsmL1Ctx);
HSM_BoolType bTempErrorHappen = bErrorHappen;
switch (pL3Ctx->eOperation)
{
case HSM_LEVEL_3RD_OP_SCATTER_CMAC:
{
eCurStat = hsm_scatter_cmac_process(pL3Ctx, pL2Ctx, pL1Ctx, pLnCtx->u32OpLimitMs, &(pL3Ctx->tL3AlgCtx.tScatterCMac), eRet, pL1Ctx->eTriggerSrc);
if (HSM_STATUS_AGAIN != eCurStat)
{
if (HSM_STATUS_SUCCESS != eCurStat)
{
bTempErrorHappen = HSM_TRUE;
}
else
{
bTempErrorHappen = HSM_FALSE;
}
}
/* else do nothing */
}
break;
case HSM_LEVEL_3RD_OP_UPDATE_KEY:
{
; /* nothing to do */
}
break;
default:
eCurStat = eRet;
bRunning = HSM_FALSE;
break;
}
if ((HSM_FALSE == bRunning) || (HSM_STATUS_AGAIN != eCurStat))
{
if (NULL_PTR != pL3Ctx->pStopCb)
{
pL3Ctx->pStopCb(pUpperCtx, bTempErrorHappen, eCurStat);
}
/* else nothing */
}
/* else do nothing */
}
void HSM_L3_Init(HSM_L3_RtCtxType *pCtx, HSM_L3_InitParmType *pParm)
{
pCtx->eOperation = HSM_LEVEL_3RD_OP_NONE;
pCtx->pStopCb = pParm->pStopCb;
}
void HSM_L3_CleanEnv(HSM_L3_RtCtxType *pCtx)
{
pCtx->eOperation = HSM_LEVEL_3RD_OP_NONE;
}
/* abort the second level operation, the operation goto none */
void HSM_L3_Abort(HSM_L3_RtCtxType *pCtx)
{
pCtx->eOperation = HSM_LEVEL_3RD_OP_NONE;
}
void HSM_L3_CommonExitEnv(HSM_L3_RtCtxType *pCtx)
{
pCtx->eOperation = HSM_LEVEL_3RD_OP_NONE;
}
HSM_StatusType HSM_L3_GetPoll(HSM_L3_RtCtxType *pL3Ctx, HSM_L2_RtCtxType *pL2Ctx, HSM_L1_RtCtxType *pL1Ctx, hsm_uint32_t u32TimeoutMs)
{
HSM_StatusType eRet;
if (HSM_LEVEL_3RD_OP_SCATTER_CMAC == pL3Ctx->eOperation)
{
eRet = HSM_L3_ScatterCMacPoll(pL3Ctx, pL2Ctx, pL1Ctx, u32TimeoutMs);
}
else if (HSM_LEVEL_3RD_OP_UPDATE_KEY == pL3Ctx->eOperation)
{
eRet = HSM_L3_UpdateKeyPoll(pL3Ctx, pL2Ctx, pL1Ctx, u32TimeoutMs);
}
else
{
eRet = HSM_STATUS_ERROR;
}
return eRet;
}