/**************************************************************************//** * * @copyright (C) 2020 Nuvoton Technology Corp. All rights reserved. * * SPDX-License-Identifier: Apache-2.0 * * Change Logs: * Date Author Notes * 2020-7-4 YCHuang12 First version * ******************************************************************************/ #include #if (defined(BSP_USING_CRC) && defined(RT_HWCRYPTO_USING_CRC)) #include #include #include #include "NuMicro.h" #include "drv_pdma.h" /* Private define ---------------------------------------------------------------*/ #define NU_CRYPTO_CRC_NAME "nu_CRC" #define CRC_32_POLY 0x04C11DB7 #define CRC_CCITT_POLY 0x00001021 #define CRC_16_POLY 0x00008005 #define CRC_8_POLY 0x00000007 /* Private variables ------------------------------------------------------------*/ static struct rt_mutex s_CRC_mutex; static rt_uint32_t nu_crc_run( uint32_t u32OpMode, uint32_t u32Seed, uint32_t u32Attr, uint8_t *pu8InData, uint32_t u32DataLen ) { uint32_t u32CalChecksum = 0; uint32_t i = 0; rt_mutex_take(&s_CRC_mutex, RT_WAITING_FOREVER); /* Configure CRC controller */ CRC_Open(u32OpMode, u32Attr, u32Seed, CRC_CPU_WDATA_8); uint8_t *pu8InTempData = pu8InData; while (i < u32DataLen) { if (((((uint32_t)pu8InTempData) % 4) != 0) || (u32DataLen - i < 4)) { CRC->CTL &= ~CRC_CTL_DATLEN_Msk; CRC_WRITE_DATA(CRC, (*pu8InTempData) & 0xFF); pu8InTempData ++; i++; } else { CRC->CTL &= ~CRC_CTL_DATLEN_Msk; CRC->CTL |= CRC_CPU_WDATA_32; #if defined (NU_CRC_USE_PDMA) int32_t i32PDMATransCnt = (u32DataLen - i) / 4 ; i32PDMATransCnt = nu_pdma_mempush((void *)&CRC->DAT, pu8InTempData, 32, i32PDMATransCnt); if (i32PDMATransCnt > 0) { pu8InTempData += (i32PDMATransCnt * 4); i += (i32PDMATransCnt * 4); } #else CRC_WRITE_DATA(CRC, *(uint32_t *)pu8InTempData); pu8InTempData += 4; i += 4; #endif } } /* Get checksum value */ u32CalChecksum = CRC_GetChecksum(); rt_mutex_release(&s_CRC_mutex); return u32CalChecksum; } rt_err_t nu_crc_init(void) { SYS_ResetModule(CRC_RST); rt_mutex_init(&s_CRC_mutex, NU_CRYPTO_CRC_NAME, RT_IPC_FLAG_FIFO); return RT_EOK; } rt_uint32_t nu_crc_update(struct hwcrypto_crc *ctx, const rt_uint8_t *in, rt_size_t length) { uint32_t u32OpMode; uint32_t u32CRCAttr = 0; rt_uint32_t crc_result = 0; //select CRC operation mode switch (ctx->crc_cfg.poly) { case CRC_32_POLY: u32OpMode = CRC_32; break; case CRC_CCITT_POLY: u32OpMode = CRC_CCITT; break; case CRC_16_POLY: u32OpMode = CRC_16; break; case CRC_8_POLY: u32OpMode = CRC_8; break; default: return 0; } u32CRCAttr |= (ctx->crc_cfg.flags & CRC_FLAG_REFOUT) ? CRC_CHECKSUM_RVS : 0; //CRC Checksum Reverse u32CRCAttr |= (ctx->crc_cfg.flags & CRC_FLAG_REFIN) ? CRC_WDATA_RVS : 0; //CRC Write Data Reverse //Calculate CRC checksum, using config's last value as CRC seed crc_result = nu_crc_run(u32OpMode, ctx->crc_cfg.last_val, u32CRCAttr, (uint8_t *)in, length); //update CRC result to config's last value ctx->crc_cfg.last_val = crc_result; return crc_result ^ 0x00 ^ ctx->crc_cfg.xorout; } #endif //#if (defined(BSP_USING_CRC) && defined(RT_HWCRYPTO_USING_CRC))