/**************************************************************************//** * * @copyright (C) 2020 Nuvoton Technology Corp. All rights reserved. * * SPDX-License-Identifier: Apache-2.0 * * Change Logs: * Date Author Notes * 2021-7-15 Wayne First version * ******************************************************************************/ #include #if defined(BSP_USING_PDMA) #include #include #include #include #include "drv_sys.h" /* Private define ---------------------------------------------------------------*/ // RT_DEV_NAME_PREFIX pdma #ifndef NU_PDMA_MEMFUN_ACTOR_MAX #define NU_PDMA_MEMFUN_ACTOR_MAX (4) #endif /* To select the first PDMA base */ #if !defined(USE_MA35D1_SUBM) #define DEF_PDMA_BASE_START PDMA0_BASE #else #define DEF_PDMA_BASE_START PDMA2_BASE #endif enum { PDMA_START = -1, #if defined(BSP_USING_PDMA0) PDMA0_IDX, #endif #if defined(BSP_USING_PDMA1) PDMA1_IDX, #endif #if defined(BSP_USING_PDMA2) PDMA2_IDX, #endif #if defined(BSP_USING_PDMA3) PDMA3_IDX, #endif PDMA_CNT }; #define NU_PDMA_SG_TBL_MAXSIZE (NU_PDMA_SG_LIMITED_DISTANCE/sizeof(DSCT_T)) #define NU_PDMA_CH_MAX (PDMA_CNT*PDMA_CH_MAX) /* Specify maximum channels of PDMA */ #define NU_PDMA_CH_Pos (0) /* Specify first channel number of PDMA */ #define NU_PDMA_CH_Msk (PDMA_CH_Msk << NU_PDMA_CH_Pos) #define NU_PDMA_GET_BASE(ch) (PDMA_T *)((((ch)/PDMA_CH_MAX)*0x10000UL) + DEF_PDMA_BASE_START) #define NU_PDMA_GET_MOD_IDX(ch) ((ch)/PDMA_CH_MAX) #define NU_PDMA_GET_MOD_CHIDX(ch) ((ch)%PDMA_CH_MAX) /* Private typedef --------------------------------------------------------------*/ struct nu_pdma_periph_ctl { uint32_t m_u32Peripheral; nu_pdma_memctrl_t m_eMemCtl; }; typedef struct nu_pdma_periph_ctl nu_pdma_periph_ctl_t; struct nu_pdma_chn { struct nu_pdma_chn_cb m_sCB_Event; struct nu_pdma_chn_cb m_sCB_Trigger; struct nu_pdma_chn_cb m_sCB_Disable; nu_pdma_desc_t *m_ppsSgtbl; uint32_t m_u32WantedSGTblNum; uint32_t m_u32EventFilter; uint32_t m_u32IdleTimeout_us; nu_pdma_periph_ctl_t m_spPeripCtl; }; typedef struct nu_pdma_chn nu_pdma_chn_t; struct nu_pdma_memfun_actor { int m_i32ChannID; uint32_t m_u32Result; rt_sem_t m_psSemMemFun; } ; typedef struct nu_pdma_memfun_actor *nu_pdma_memfun_actor_t; /* Private functions ------------------------------------------------------------*/ static int nu_pdma_peripheral_set(uint32_t u32PeriphType); static void nu_pdma_init(void); static void nu_pdma_channel_enable(int i32ChannID); static void nu_pdma_channel_disable(int i32ChannID); static void nu_pdma_channel_reset(int i32ChannID); static rt_err_t nu_pdma_timeout_set(int i32ChannID, int i32Timeout_us); static void nu_pdma_periph_ctrl_fill(int i32ChannID, int i32CtlPoolIdx); static rt_size_t nu_pdma_memfun(void *dest, void *src, uint32_t u32DataWidth, unsigned int u32TransferCnt, nu_pdma_memctrl_t eMemCtl); static void nu_pdma_memfun_cb(void *pvUserData, uint32_t u32Events); static void nu_pdma_memfun_actor_init(void); static int nu_pdma_memfun_employ(void); static int nu_pdma_non_transfer_count_get(int32_t i32ChannID); /* Public functions -------------------------------------------------------------*/ /* Private variables ------------------------------------------------------------*/ static volatile int nu_pdma_inited = 0; static volatile uint32_t nu_pdma_chn_mask_arr[PDMA_CNT] = {0}; static nu_pdma_chn_t nu_pdma_chn_arr[NU_PDMA_CH_MAX]; static volatile uint32_t nu_pdma_memfun_actor_mask = 0; static volatile uint32_t nu_pdma_memfun_actor_maxnum = 0; static rt_sem_t nu_pdma_memfun_actor_pool_sem = RT_NULL; static rt_mutex_t nu_pdma_memfun_actor_pool_lock = RT_NULL; static void nu_pdma_isr(int vector, void *pvdata); const static struct nu_module nu_pdma_arr[] = { #if defined(BSP_USING_PDMA0) { .name = "pdma0", .m_pvBase = (void *)PDMA0, .u32RstId = PDMA0_RST, .eIRQn = PDMA0_IRQn }, #endif #if defined(BSP_USING_PDMA1) { .name = "pdma1", .m_pvBase = (void *)PDMA1, .u32RstId = PDMA1_RST, .eIRQn = PDMA1_IRQn }, #endif #if defined(BSP_USING_PDMA2) { .name = "pdma2", .m_pvBase = (void *)PDMA2, .u32RstId = PDMA2_RST, .eIRQn = PDMA2_IRQn }, #endif #if defined(BSP_USING_PDMA3) { .name = "pdma3", .m_pvBase = (void *)PDMA3, .u32RstId = PDMA3_RST, .eIRQn = PDMA3_IRQn } #endif }; static const nu_pdma_periph_ctl_t g_nu_pdma_peripheral_ctl_pool[ ] = { // M2M { PDMA_MEM, eMemCtl_SrcInc_DstInc }, // M2P { PDMA_UART0_TX, eMemCtl_SrcInc_DstFix }, { PDMA_UART1_TX, eMemCtl_SrcInc_DstFix }, { PDMA_UART2_TX, eMemCtl_SrcInc_DstFix }, { PDMA_UART3_TX, eMemCtl_SrcInc_DstFix }, { PDMA_UART4_TX, eMemCtl_SrcInc_DstFix }, { PDMA_UART5_TX, eMemCtl_SrcInc_DstFix }, { PDMA_UART6_TX, eMemCtl_SrcInc_DstFix }, { PDMA_UART7_TX, eMemCtl_SrcInc_DstFix }, { PDMA_UART8_TX, eMemCtl_SrcInc_DstFix }, { PDMA_UART9_TX, eMemCtl_SrcInc_DstFix }, { PDMA_UART10_TX, eMemCtl_SrcInc_DstFix }, { PDMA_UART11_TX, eMemCtl_SrcInc_DstFix }, { PDMA_UART12_TX, eMemCtl_SrcInc_DstFix }, { PDMA_UART13_TX, eMemCtl_SrcInc_DstFix }, { PDMA_UART14_TX, eMemCtl_SrcInc_DstFix }, { PDMA_UART15_TX, eMemCtl_SrcInc_DstFix }, { PDMA_UART16_TX, eMemCtl_SrcInc_DstFix }, { PDMA_QSPI0_TX, eMemCtl_SrcInc_DstFix }, { PDMA_QSPI1_TX, eMemCtl_SrcInc_DstFix }, { PDMA_SPI0_TX, eMemCtl_SrcInc_DstFix }, { PDMA_SPI1_TX, eMemCtl_SrcInc_DstFix }, { PDMA_SPI2_TX, eMemCtl_SrcInc_DstFix }, { PDMA_SPI3_TX, eMemCtl_SrcInc_DstFix }, { PDMA_I2C0_TX, eMemCtl_SrcInc_DstFix }, { PDMA_I2C1_TX, eMemCtl_SrcInc_DstFix }, { PDMA_I2C2_TX, eMemCtl_SrcInc_DstFix }, { PDMA_I2C3_TX, eMemCtl_SrcInc_DstFix }, { PDMA_I2C4_TX, eMemCtl_SrcInc_DstFix }, { PDMA_I2C5_TX, eMemCtl_SrcInc_DstFix }, { PDMA_I2S0_TX, eMemCtl_SrcInc_DstFix }, { PDMA_I2S1_TX, eMemCtl_SrcInc_DstFix }, // P2M { PDMA_UART0_RX, eMemCtl_SrcFix_DstInc }, { PDMA_UART1_RX, eMemCtl_SrcFix_DstInc }, { PDMA_UART2_RX, eMemCtl_SrcFix_DstInc }, { PDMA_UART3_RX, eMemCtl_SrcFix_DstInc }, { PDMA_UART4_RX, eMemCtl_SrcFix_DstInc }, { PDMA_UART5_RX, eMemCtl_SrcFix_DstInc }, { PDMA_UART6_RX, eMemCtl_SrcFix_DstInc }, { PDMA_UART7_RX, eMemCtl_SrcFix_DstInc }, { PDMA_UART8_RX, eMemCtl_SrcFix_DstInc }, { PDMA_UART9_RX, eMemCtl_SrcFix_DstInc }, { PDMA_UART10_RX, eMemCtl_SrcFix_DstInc }, { PDMA_UART11_RX, eMemCtl_SrcFix_DstInc }, { PDMA_UART12_RX, eMemCtl_SrcFix_DstInc }, { PDMA_UART13_RX, eMemCtl_SrcFix_DstInc }, { PDMA_UART14_RX, eMemCtl_SrcFix_DstInc }, { PDMA_UART15_RX, eMemCtl_SrcFix_DstInc }, { PDMA_UART16_RX, eMemCtl_SrcFix_DstInc }, { PDMA_QSPI0_RX, eMemCtl_SrcFix_DstInc }, { PDMA_QSPI1_RX, eMemCtl_SrcFix_DstInc }, { PDMA_SPI0_RX, eMemCtl_SrcFix_DstInc }, { PDMA_SPI1_RX, eMemCtl_SrcFix_DstInc }, { PDMA_SPI2_RX, eMemCtl_SrcFix_DstInc }, { PDMA_SPI3_RX, eMemCtl_SrcFix_DstInc }, { PDMA_I2C0_RX, eMemCtl_SrcFix_DstInc }, { PDMA_I2C1_RX, eMemCtl_SrcFix_DstInc }, { PDMA_I2C2_RX, eMemCtl_SrcFix_DstInc }, { PDMA_I2C3_RX, eMemCtl_SrcFix_DstInc }, { PDMA_I2C4_RX, eMemCtl_SrcFix_DstInc }, { PDMA_I2C5_RX, eMemCtl_SrcFix_DstInc }, { PDMA_I2S0_RX, eMemCtl_SrcFix_DstInc }, { PDMA_I2S1_RX, eMemCtl_SrcFix_DstInc }, }; #define NU_PERIPHERAL_SIZE ( sizeof(g_nu_pdma_peripheral_ctl_pool) / sizeof(g_nu_pdma_peripheral_ctl_pool[0]) ) static struct nu_pdma_memfun_actor nu_pdma_memfun_actor_arr[NU_PDMA_MEMFUN_ACTOR_MAX]; static int nu_pdma_check_is_nonallocated(uint32_t u32ChnId) { uint32_t mod_idx = NU_PDMA_GET_MOD_IDX(u32ChnId); RT_ASSERT(mod_idx < PDMA_CNT); return !(nu_pdma_chn_mask_arr[mod_idx] & (1 << NU_PDMA_GET_MOD_CHIDX(u32ChnId))); } static int nu_pdma_peripheral_set(uint32_t u32PeriphType) { int idx = 0; while (idx < NU_PERIPHERAL_SIZE) { if (g_nu_pdma_peripheral_ctl_pool[idx].m_u32Peripheral == u32PeriphType) return idx; idx++; } // Not such peripheral return -1; } static void nu_pdma_periph_ctrl_fill(int i32ChannID, int i32CtlPoolIdx) { nu_pdma_chn_t *psPdmaChann = &nu_pdma_chn_arr[i32ChannID - NU_PDMA_CH_Pos]; psPdmaChann->m_spPeripCtl.m_u32Peripheral = g_nu_pdma_peripheral_ctl_pool[i32CtlPoolIdx].m_u32Peripheral; psPdmaChann->m_spPeripCtl.m_eMemCtl = g_nu_pdma_peripheral_ctl_pool[i32CtlPoolIdx].m_eMemCtl; } /** * Hardware PDMA Initialization */ static void nu_pdma_init(void) { int i; if (nu_pdma_inited) return; rt_memset(nu_pdma_chn_arr, 0x00, NU_PDMA_CH_MAX * sizeof(nu_pdma_chn_t)); for (i = (PDMA_START + 1); i < PDMA_CNT; i++) { nu_pdma_chn_mask_arr[i] = ~(NU_PDMA_CH_Msk); nu_sys_ip_reset(nu_pdma_arr[i].u32RstId); /* Initialize PDMA setting */ PDMA_Open((PDMA_T *)nu_pdma_arr[i].m_pvBase, PDMA_CH_Msk); PDMA_Close((PDMA_T *)nu_pdma_arr[i].m_pvBase); /* Register PDMA ISR */ rt_hw_interrupt_install(nu_pdma_arr[i].eIRQn, nu_pdma_isr, nu_pdma_arr[i].m_pvBase, nu_pdma_arr[i].name); rt_hw_interrupt_umask(nu_pdma_arr[i].eIRQn); } nu_pdma_inited = 1; } static inline void nu_pdma_channel_enable(int i32ChannID) { PDMA_T *PDMA = NU_PDMA_GET_BASE(i32ChannID); int u32ModChannId = NU_PDMA_GET_MOD_CHIDX(i32ChannID); /* Clean descriptor table control register. */ PDMA->DSCT[u32ModChannId].CTL = 0UL; /* Enable the channel */ PDMA->CHCTL |= (1 << u32ModChannId); } static inline void nu_pdma_channel_disable(int i32ChannID) { PDMA_T *PDMA = NU_PDMA_GET_BASE(i32ChannID); PDMA->CHCTL &= ~(1 << NU_PDMA_GET_MOD_CHIDX(i32ChannID)); } static inline void nu_pdma_channel_reset(int i32ChannID) { PDMA_T *PDMA = NU_PDMA_GET_BASE(i32ChannID); int u32ModChannId = NU_PDMA_GET_MOD_CHIDX(i32ChannID); PDMA->CHRST = (1 << u32ModChannId); /* Wait for cleared channel CHCTL. */ while ((PDMA->CHCTL & (1 << u32ModChannId))); } void nu_pdma_channel_terminate(int i32ChannID) { if (nu_pdma_check_is_nonallocated(i32ChannID)) goto exit_pdma_channel_terminate; /* Reset specified channel. */ nu_pdma_channel_reset(i32ChannID); /* Enable specified channel after reset. */ nu_pdma_channel_enable(i32ChannID); exit_pdma_channel_terminate: return; } static rt_err_t nu_pdma_timeout_set(int i32ChannID, int i32Timeout_us) { rt_err_t ret = RT_EINVAL; PDMA_T *PDMA = NULL; uint32_t u32ModChannId; if (nu_pdma_check_is_nonallocated(i32ChannID)) goto exit_nu_pdma_timeout_set; PDMA = NU_PDMA_GET_BASE(i32ChannID); u32ModChannId = NU_PDMA_GET_MOD_CHIDX(i32ChannID); nu_pdma_chn_arr[i32ChannID - NU_PDMA_CH_Pos].m_u32IdleTimeout_us = i32Timeout_us; if (i32Timeout_us) { uint32_t u32ToClk_Max = 1000000ul / (CLK_GetSYSCLK1Freq() / (1 << 8)); uint32_t u32Divider = (i32Timeout_us / u32ToClk_Max) / (1 << 16); uint32_t u32TOutCnt = (i32Timeout_us / u32ToClk_Max) % (1 << 16); PDMA_DisableTimeout(PDMA, 1 << u32ModChannId); PDMA_EnableInt(PDMA, u32ModChannId, PDMA_INT_TIMEOUT); // Interrupt type if (u32Divider > 7) { u32Divider = 7; u32TOutCnt = (1 << 16) - 1; } if (u32ModChannId < 8) PDMA->TOUTPSC = (PDMA->TOUTPSC & ~(0x7ul << (PDMA_TOUTPSC_TOUTPSC1_Pos * u32ModChannId))) | (u32Divider << (PDMA_TOUTPSC_TOUTPSC1_Pos * u32ModChannId)); else PDMA->TOUTPSC1 = (PDMA->TOUTPSC1 & ~(0x7ul << (PDMA_TOUTPSC_TOUTPSC1_Pos * u32ModChannId))) | (u32Divider << (PDMA_TOUTPSC_TOUTPSC1_Pos * u32ModChannId)); //rt_kprintf("[%d]HCLK=%d, u32Divider=%d, u32TOutCnt=%d\n", i32Timeout_us, CLK_GetSYSCLK1Freq(), u32Divider, u32TOutCnt ); PDMA_SetTimeOut(PDMA, u32ModChannId, 1, u32TOutCnt); ret = RT_EOK; } else { PDMA_DisableInt(PDMA, u32ModChannId, PDMA_INT_TIMEOUT); // Interrupt type PDMA_DisableTimeout(PDMA, 1 << u32ModChannId); } exit_nu_pdma_timeout_set: return -(ret); } int nu_pdma_channel_allocate(int32_t i32PeripType) { int ChnId, i32PeripCtlIdx, j; nu_pdma_init(); if ((i32PeripCtlIdx = nu_pdma_peripheral_set(i32PeripType)) < 0) goto exit_nu_pdma_channel_allocate; for (j = (PDMA_START + 1); j < PDMA_CNT; j++) { /* Find the position of first '0' in nu_pdma_chn_mask_arr[j]. */ ChnId = nu_cto(nu_pdma_chn_mask_arr[j]); if (ChnId < PDMA_CH_MAX) { nu_pdma_chn_mask_arr[j] |= (1 << ChnId); ChnId += (j * PDMA_CH_MAX); rt_memset(nu_pdma_chn_arr + ChnId - NU_PDMA_CH_Pos, 0x00, sizeof(nu_pdma_chn_t)); /* Set idx number of g_nu_pdma_peripheral_ctl_pool */ nu_pdma_periph_ctrl_fill(ChnId, i32PeripCtlIdx); /* Reset channel */ nu_pdma_channel_terminate(ChnId); return ChnId; } } exit_nu_pdma_channel_allocate: // No channel available return -(RT_ERROR); } rt_err_t nu_pdma_channel_free(int i32ChannID) { rt_err_t ret = RT_EINVAL; if (! nu_pdma_inited) goto exit_nu_pdma_channel_free; if (nu_pdma_check_is_nonallocated(i32ChannID)) goto exit_nu_pdma_channel_free; if ((i32ChannID < NU_PDMA_CH_MAX) && (i32ChannID >= NU_PDMA_CH_Pos)) { nu_pdma_chn_mask_arr[NU_PDMA_GET_MOD_IDX(i32ChannID)] &= ~(1 << NU_PDMA_GET_MOD_CHIDX(i32ChannID)); nu_pdma_channel_disable(i32ChannID); ret = RT_EOK; } exit_nu_pdma_channel_free: return -(ret); } rt_err_t nu_pdma_filtering_set(int i32ChannID, uint32_t u32EventFilter) { rt_err_t ret = RT_EINVAL; if (nu_pdma_check_is_nonallocated(i32ChannID)) goto exit_nu_pdma_filtering_set; nu_pdma_chn_arr[i32ChannID - NU_PDMA_CH_Pos].m_u32EventFilter = u32EventFilter; ret = RT_EOK; exit_nu_pdma_filtering_set: return -(ret) ; } uint32_t nu_pdma_filtering_get(int i32ChannID) { if (nu_pdma_check_is_nonallocated(i32ChannID)) goto exit_nu_pdma_filtering_get; return nu_pdma_chn_arr[i32ChannID - NU_PDMA_CH_Pos].m_u32EventFilter; exit_nu_pdma_filtering_get: return 0; } rt_err_t nu_pdma_callback_register(int i32ChannID, nu_pdma_chn_cb_t psChnCb) { rt_err_t ret = RT_EINVAL; nu_pdma_chn_cb_t psChnCb_Current = RT_NULL; RT_ASSERT(psChnCb != RT_NULL); if (nu_pdma_check_is_nonallocated(i32ChannID)) goto exit_nu_pdma_callback_register; switch (psChnCb->m_eCBType) { case eCBType_Event: psChnCb_Current = &nu_pdma_chn_arr[i32ChannID - NU_PDMA_CH_Pos].m_sCB_Event; break; case eCBType_Trigger: psChnCb_Current = &nu_pdma_chn_arr[i32ChannID - NU_PDMA_CH_Pos].m_sCB_Trigger; break; case eCBType_Disable: psChnCb_Current = &nu_pdma_chn_arr[i32ChannID - NU_PDMA_CH_Pos].m_sCB_Disable; break; default: goto exit_nu_pdma_callback_register; } psChnCb_Current->m_pfnCBHandler = psChnCb->m_pfnCBHandler; psChnCb_Current->m_pvUserData = psChnCb->m_pvUserData; ret = RT_EOK; exit_nu_pdma_callback_register: return -(ret) ; } nu_pdma_cb_handler_t nu_pdma_callback_hijack(int i32ChannID, nu_pdma_cbtype_t eCBType, nu_pdma_chn_cb_t psChnCb_Hijack) { nu_pdma_chn_cb_t psChnCb_Current = RT_NULL; struct nu_pdma_chn_cb sChnCB_Tmp; RT_ASSERT(psChnCb_Hijack != NULL); sChnCB_Tmp.m_pfnCBHandler = RT_NULL; if (nu_pdma_check_is_nonallocated(i32ChannID)) goto exit_nu_pdma_callback_hijack; switch (eCBType) { case eCBType_Event: psChnCb_Current = &nu_pdma_chn_arr[i32ChannID - NU_PDMA_CH_Pos].m_sCB_Event; break; case eCBType_Trigger: psChnCb_Current = &nu_pdma_chn_arr[i32ChannID - NU_PDMA_CH_Pos].m_sCB_Trigger; break; case eCBType_Disable: psChnCb_Current = &nu_pdma_chn_arr[i32ChannID - NU_PDMA_CH_Pos].m_sCB_Disable; break; default: goto exit_nu_pdma_callback_hijack; } /* Backup */ sChnCB_Tmp.m_pfnCBHandler = psChnCb_Current->m_pfnCBHandler; sChnCB_Tmp.m_pvUserData = psChnCb_Current->m_pvUserData; /* Update */ psChnCb_Current->m_pfnCBHandler = psChnCb_Hijack->m_pfnCBHandler; psChnCb_Current->m_pvUserData = psChnCb_Hijack->m_pvUserData; /* Restore */ psChnCb_Hijack->m_pfnCBHandler = sChnCB_Tmp.m_pfnCBHandler; psChnCb_Hijack->m_pvUserData = sChnCB_Tmp.m_pvUserData; exit_nu_pdma_callback_hijack: return sChnCB_Tmp.m_pfnCBHandler; } static int nu_pdma_non_transfer_count_get(int32_t i32ChannID) { PDMA_T *PDMA = NU_PDMA_GET_BASE(i32ChannID); return ((PDMA->DSCT[NU_PDMA_GET_MOD_CHIDX(i32ChannID)].CTL & PDMA_DSCT_CTL_TXCNT_Msk) >> PDMA_DSCT_CTL_TXCNT_Pos) + 1; } int nu_pdma_transferred_byte_get(int32_t i32ChannID, int32_t i32TriggerByteLen) { int i32BitWidth = 0; int cur_txcnt = 0; PDMA_T *PDMA; if (nu_pdma_check_is_nonallocated(i32ChannID)) goto exit_nu_pdma_transferred_byte_get; PDMA = NU_PDMA_GET_BASE(i32ChannID); if ((PDMA->DSCT[NU_PDMA_GET_MOD_CHIDX(i32ChannID)].CTL & PDMA_DSCT_CTL_OPMODE_Msk) != PDMA_OP_SCATTER) { i32BitWidth = PDMA->DSCT[NU_PDMA_GET_MOD_CHIDX(i32ChannID)].CTL & PDMA_DSCT_CTL_TXWIDTH_Msk; i32BitWidth = (i32BitWidth == PDMA_WIDTH_8) ? 1 : (i32BitWidth == PDMA_WIDTH_16) ? 2 : (i32BitWidth == PDMA_WIDTH_32) ? 4 : 0; cur_txcnt = nu_pdma_non_transfer_count_get(i32ChannID); // rt_kprintf("\n[%s] %d %d %02x\n", __func__, i32ChannID, cur_txcnt, (PDMA->DSCT[NU_PDMA_GET_MOD_CHIDX(i32ChannID)].CTL & PDMA_DSCT_CTL_OPMODE_Msk) ); return (i32TriggerByteLen - (cur_txcnt) * i32BitWidth); } // rt_kprintf("\n@@@@ %d %02x @@@@\n", i32ChannID, PDMA->DSCT[NU_PDMA_GET_MOD_CHIDX(i32ChannID)].CTL & PDMA_DSCT_CTL_OPMODE_Msk); return 0; exit_nu_pdma_transferred_byte_get: return -1; } nu_pdma_memctrl_t nu_pdma_channel_memctrl_get(int i32ChannID) { nu_pdma_memctrl_t eMemCtrl = eMemCtl_Undefined; if (nu_pdma_check_is_nonallocated(i32ChannID)) goto exit_nu_pdma_channel_memctrl_get; eMemCtrl = nu_pdma_chn_arr[i32ChannID - NU_PDMA_CH_Pos].m_spPeripCtl.m_eMemCtl; exit_nu_pdma_channel_memctrl_get: return eMemCtrl; } rt_err_t nu_pdma_channel_memctrl_set(int i32ChannID, nu_pdma_memctrl_t eMemCtrl) { rt_err_t ret = RT_EINVAL; nu_pdma_chn_t *psPdmaChann = &nu_pdma_chn_arr[i32ChannID - NU_PDMA_CH_Pos]; if (nu_pdma_check_is_nonallocated(i32ChannID)) goto exit_nu_pdma_channel_memctrl_set; else if ((eMemCtrl < eMemCtl_SrcFix_DstFix) || (eMemCtrl > eMemCtl_SrcInc_DstInc)) goto exit_nu_pdma_channel_memctrl_set; /* PDMA_MEM/SAR_FIX/BURST mode is not supported. */ if ((psPdmaChann->m_spPeripCtl.m_u32Peripheral == PDMA_MEM) && ((eMemCtrl == eMemCtl_SrcFix_DstInc) || (eMemCtrl == eMemCtl_SrcFix_DstFix))) goto exit_nu_pdma_channel_memctrl_set; nu_pdma_chn_arr[i32ChannID - NU_PDMA_CH_Pos].m_spPeripCtl.m_eMemCtl = eMemCtrl; ret = RT_EOK; exit_nu_pdma_channel_memctrl_set: return -(ret); } static void nu_pdma_channel_memctrl_fill(nu_pdma_memctrl_t eMemCtl, uint32_t *pu32SrcCtl, uint32_t *pu32DstCtl) { switch ((int)eMemCtl) { case eMemCtl_SrcFix_DstFix: *pu32SrcCtl = PDMA_SAR_FIX; *pu32DstCtl = PDMA_DAR_FIX; break; case eMemCtl_SrcFix_DstInc: *pu32SrcCtl = PDMA_SAR_FIX; *pu32DstCtl = PDMA_DAR_INC; break; case eMemCtl_SrcInc_DstFix: *pu32SrcCtl = PDMA_SAR_INC; *pu32DstCtl = PDMA_DAR_FIX; break; case eMemCtl_SrcInc_DstInc: *pu32SrcCtl = PDMA_SAR_INC; *pu32DstCtl = PDMA_DAR_INC; break; default: break; } } /* This is for Scatter-gather DMA. */ rt_err_t nu_pdma_desc_setup(int i32ChannID, nu_pdma_desc_t dma_desc, uint32_t u32DataWidth, uint32_t u32AddrSrc, uint32_t u32AddrDst, int32_t i32TransferCnt, nu_pdma_desc_t next, uint32_t u32BeSilent) { nu_pdma_periph_ctl_t *psPeriphCtl = NULL; uint32_t u32SrcCtl = 0; uint32_t u32DstCtl = 0; rt_err_t ret = RT_EINVAL; if (!dma_desc) goto exit_nu_pdma_desc_setup; else if (nu_pdma_check_is_nonallocated(i32ChannID)) goto exit_nu_pdma_desc_setup; else if (!(u32DataWidth == 8 || u32DataWidth == 16 || u32DataWidth == 32)) goto exit_nu_pdma_desc_setup; else if ((u32AddrSrc % (u32DataWidth / 8)) || (u32AddrDst % (u32DataWidth / 8))) goto exit_nu_pdma_desc_setup; else if (i32TransferCnt > NU_PDMA_MAX_TXCNT) goto exit_nu_pdma_desc_setup; psPeriphCtl = &nu_pdma_chn_arr[i32ChannID - NU_PDMA_CH_Pos].m_spPeripCtl; nu_pdma_channel_memctrl_fill(psPeriphCtl->m_eMemCtl, &u32SrcCtl, &u32DstCtl); dma_desc->CTL = ((i32TransferCnt - 1) << PDMA_DSCT_CTL_TXCNT_Pos) | ((u32DataWidth == 8) ? PDMA_WIDTH_8 : (u32DataWidth == 16) ? PDMA_WIDTH_16 : PDMA_WIDTH_32) | u32SrcCtl | u32DstCtl | PDMA_OP_BASIC; dma_desc->SA = u32AddrSrc; dma_desc->DA = u32AddrDst; dma_desc->NEXT = 0; /* Terminating node by default. */ if (psPeriphCtl->m_u32Peripheral == PDMA_MEM) { /* For M2M transfer */ dma_desc->CTL |= (PDMA_REQ_BURST | PDMA_BURST_32); } else { /* For P2M and M2P transfer */ dma_desc->CTL |= (PDMA_REQ_SINGLE); } if (next) { /* Link to Next and modify to scatter-gather DMA mode. */ dma_desc->CTL = (dma_desc->CTL & ~PDMA_DSCT_CTL_OPMODE_Msk) | PDMA_OP_SCATTER; dma_desc->NEXT = (uint32_t)next; } /* Be silent */ if (u32BeSilent) dma_desc->CTL |= PDMA_DSCT_CTL_TBINTDIS_Msk; ret = RT_EOK; exit_nu_pdma_desc_setup: return -(ret); } rt_err_t nu_pdma_sgtbls_allocate(nu_pdma_desc_t *ppsSgtbls, int num) { int i; nu_pdma_desc_t psSgTblHead; RT_ASSERT(ppsSgtbls != NULL); RT_ASSERT(num > 0); psSgTblHead = (nu_pdma_desc_t) rt_malloc_align(RT_ALIGN(sizeof(DSCT_T) * num, 64), 64); RT_ASSERT(psSgTblHead != RT_NULL); rt_memset((void *)psSgTblHead, 0, sizeof(DSCT_T) * num); for (i = 0; i < num; i++) ppsSgtbls[i] = &psSgTblHead[i]; return RT_EOK; } void nu_pdma_sgtbls_free(nu_pdma_desc_t *ppsSgtbls, int num) { nu_pdma_desc_t psSgTblHead; RT_ASSERT(ppsSgtbls != NULL); psSgTblHead = *ppsSgtbls; RT_ASSERT(psSgTblHead != NULL); rt_free_align(psSgTblHead); } static void _nu_pdma_transfer(int i32ChannID, uint32_t u32Peripheral, nu_pdma_desc_t head, uint32_t u32IdleTimeout_us) { PDMA_T *PDMA = NU_PDMA_GET_BASE(i32ChannID); nu_pdma_chn_t *psPdmaChann = &nu_pdma_chn_arr[i32ChannID - NU_PDMA_CH_Pos]; #if !defined(USE_MA35D1_SUBM) /* Writeback data in dcache to memory before transferring. */ { static uint32_t bNonCacheAlignedWarning = 1; nu_pdma_desc_t next = head; int CACHE_LINE_SIZE = nu_cpu_dcache_line_size(); while (next != RT_NULL) { uint32_t u32TxCnt = ((next->CTL & PDMA_DSCT_CTL_TXCNT_Msk) >> PDMA_DSCT_CTL_TXCNT_Pos) + 1; uint32_t u32DataWidth = (1 << ((next->CTL & PDMA_DSCT_CTL_TXWIDTH_Msk) >> PDMA_DSCT_CTL_TXWIDTH_Pos)); uint32_t u32SrcCtl = (next->CTL & PDMA_DSCT_CTL_SAINC_Msk); uint32_t u32DstCtl = (next->CTL & PDMA_DSCT_CTL_DAINC_Msk); uint32_t u32FlushLen = u32TxCnt * u32DataWidth; #if 0 rt_kprintf("[%s] i32ChannID=%d\n", __func__, i32ChannID); rt_kprintf("[%s] PDMA=0x%08x\n", __func__, (uint32_t)PDMA); rt_kprintf("[%s] u32TxCnt=%d\n", __func__, u32TxCnt); rt_kprintf("[%s] u32DataWidth=%d\n", __func__, u32DataWidth); rt_kprintf("[%s] u32SrcCtl=0x%08x\n", __func__, u32SrcCtl); rt_kprintf("[%s] u32DstCtl=0x%08x\n", __func__, u32DstCtl); rt_kprintf("[%s] u32FlushLen=%d\n", __func__, u32FlushLen); #endif /* Flush Src buffer into memory. */ if ((u32SrcCtl == PDMA_SAR_INC)) // for M2P, M2M rt_hw_cpu_dcache_clean_inv((void *)next->SA, u32FlushLen); /* Flush Dst buffer into memory. */ if ((u32DstCtl == PDMA_DAR_INC)) // for P2M, M2M rt_hw_cpu_dcache_clean_inv((void *)next->DA, u32FlushLen); /* Flush descriptor into memory */ rt_hw_cpu_dcache_clean_inv((void *)next, sizeof(DSCT_T)); if (bNonCacheAlignedWarning) { if ((u32FlushLen & (CACHE_LINE_SIZE - 1)) || (next->SA & (CACHE_LINE_SIZE - 1)) || (next->DA & (CACHE_LINE_SIZE - 1)) || ((rt_uint32_t)next & (CACHE_LINE_SIZE - 1))) { /* Race-condition avoidance between DMA-transferring and DCache write-back: Source, destination, DMA descriptor address and length should be aligned at len(CACHE_LINE_SIZE) */ bNonCacheAlignedWarning = 0; rt_kprintf("[PDMA-W]\n"); } } next = (nu_pdma_desc_t)next->NEXT; if (next == head) break; } } #endif PDMA_DisableTimeout(PDMA, 1 << NU_PDMA_GET_MOD_CHIDX(i32ChannID)); PDMA_EnableInt(PDMA, NU_PDMA_GET_MOD_CHIDX(i32ChannID), PDMA_INT_TRANS_DONE); nu_pdma_timeout_set(i32ChannID, u32IdleTimeout_us); /* Set scatter-gather mode and head */ /* Take care the head structure, you should make sure cache-coherence. */ PDMA_SetTransferMode(PDMA, NU_PDMA_GET_MOD_CHIDX(i32ChannID), u32Peripheral, (head->NEXT != 0) ? 1 : 0, (uint32_t)head); /* If peripheral is M2M, trigger it. */ if (u32Peripheral == PDMA_MEM) { PDMA_Trigger(PDMA, NU_PDMA_GET_MOD_CHIDX(i32ChannID)); } else if (psPdmaChann->m_sCB_Trigger.m_pfnCBHandler) { psPdmaChann->m_sCB_Trigger.m_pfnCBHandler(psPdmaChann->m_sCB_Trigger.m_pvUserData, psPdmaChann->m_sCB_Trigger.m_u32Reserved); } } static void _nu_pdma_free_sgtbls(nu_pdma_chn_t *psPdmaChann) { if (psPdmaChann->m_ppsSgtbl) { nu_pdma_sgtbls_free(psPdmaChann->m_ppsSgtbl, psPdmaChann->m_u32WantedSGTblNum); rt_free_align((void *)psPdmaChann->m_ppsSgtbl); psPdmaChann->m_ppsSgtbl = RT_NULL; psPdmaChann->m_u32WantedSGTblNum = 0; } } static rt_err_t _nu_pdma_transfer_chain(int i32ChannID, uint32_t u32DataWidth, uint32_t u32AddrSrc, uint32_t u32AddrDst, uint32_t u32TransferCnt, uint32_t u32IdleTimeout_us) { int i = 0; rt_err_t ret = RT_ERROR; nu_pdma_periph_ctl_t *psPeriphCtl = NULL; nu_pdma_chn_t *psPdmaChann = &nu_pdma_chn_arr[i32ChannID - NU_PDMA_CH_Pos]; nu_pdma_memctrl_t eMemCtl = nu_pdma_channel_memctrl_get(i32ChannID); rt_uint32_t u32Offset = 0; rt_uint32_t u32TxCnt = 0; psPeriphCtl = &psPdmaChann->m_spPeripCtl; if (psPdmaChann->m_u32WantedSGTblNum != (u32TransferCnt / NU_PDMA_MAX_TXCNT + 1)) { if (psPdmaChann->m_u32WantedSGTblNum > 0) _nu_pdma_free_sgtbls(psPdmaChann); psPdmaChann->m_u32WantedSGTblNum = u32TransferCnt / NU_PDMA_MAX_TXCNT + 1; psPdmaChann->m_ppsSgtbl = (nu_pdma_desc_t *)rt_malloc_align(sizeof(nu_pdma_desc_t) * psPdmaChann->m_u32WantedSGTblNum, 4); if (!psPdmaChann->m_ppsSgtbl) goto exit__nu_pdma_transfer_chain; ret = nu_pdma_sgtbls_allocate(psPdmaChann->m_ppsSgtbl, psPdmaChann->m_u32WantedSGTblNum); if (ret != RT_EOK) goto exit__nu_pdma_transfer_chain; } for (i = 0; i < psPdmaChann->m_u32WantedSGTblNum; i++) { u32TxCnt = (u32TransferCnt > NU_PDMA_MAX_TXCNT) ? NU_PDMA_MAX_TXCNT : u32TransferCnt; ret = nu_pdma_desc_setup(i32ChannID, psPdmaChann->m_ppsSgtbl[i], u32DataWidth, (eMemCtl & 0x2ul) ? u32AddrSrc + u32Offset : u32AddrSrc, /* Src address is Inc or not. */ (eMemCtl & 0x1ul) ? u32AddrDst + u32Offset : u32AddrDst, /* Dst address is Inc or not. */ u32TxCnt, ((i + 1) == psPdmaChann->m_u32WantedSGTblNum) ? RT_NULL : psPdmaChann->m_ppsSgtbl[i + 1], ((i + 1) == psPdmaChann->m_u32WantedSGTblNum) ? 0 : 1); // Silent, w/o TD interrupt if (ret != RT_EOK) goto exit__nu_pdma_transfer_chain; u32TransferCnt -= u32TxCnt; u32Offset += (u32TxCnt * u32DataWidth / 8); } _nu_pdma_transfer(i32ChannID, psPeriphCtl->m_u32Peripheral, psPdmaChann->m_ppsSgtbl[0], u32IdleTimeout_us); ret = RT_EOK; return ret; exit__nu_pdma_transfer_chain: _nu_pdma_free_sgtbls(psPdmaChann); return -(ret); } rt_err_t nu_pdma_transfer(int i32ChannID, uint32_t u32DataWidth, uint32_t u32AddrSrc, uint32_t u32AddrDst, uint32_t u32TransferCnt, uint32_t u32IdleTimeout_us) { rt_err_t ret = RT_EINVAL; PDMA_T *PDMA = NU_PDMA_GET_BASE(i32ChannID); nu_pdma_desc_t head; nu_pdma_chn_t *psPdmaChann; nu_pdma_periph_ctl_t *psPeriphCtl = NULL; if (nu_pdma_check_is_nonallocated(i32ChannID)) goto exit_nu_pdma_transfer; else if (!u32TransferCnt) goto exit_nu_pdma_transfer; else if (u32TransferCnt > NU_PDMA_MAX_TXCNT) return _nu_pdma_transfer_chain(i32ChannID, u32DataWidth, u32AddrSrc, u32AddrDst, u32TransferCnt, u32IdleTimeout_us); psPdmaChann = &nu_pdma_chn_arr[i32ChannID - NU_PDMA_CH_Pos]; psPeriphCtl = &psPdmaChann->m_spPeripCtl; head = &PDMA->DSCT[NU_PDMA_GET_MOD_CHIDX(i32ChannID)]; ret = nu_pdma_desc_setup(i32ChannID, head, u32DataWidth, u32AddrSrc, u32AddrDst, u32TransferCnt, RT_NULL, 0); if (ret != RT_EOK) goto exit_nu_pdma_transfer; _nu_pdma_transfer(i32ChannID, psPeriphCtl->m_u32Peripheral, head, u32IdleTimeout_us); ret = RT_EOK; exit_nu_pdma_transfer: return -(ret); } rt_err_t nu_pdma_sg_transfer(int i32ChannID, nu_pdma_desc_t head, uint32_t u32IdleTimeout_us) { rt_err_t ret = RT_EINVAL; nu_pdma_periph_ctl_t *psPeriphCtl = NULL; if (!head) goto exit_nu_pdma_sg_transfer; else if (nu_pdma_check_is_nonallocated(i32ChannID)) goto exit_nu_pdma_sg_transfer; psPeriphCtl = &nu_pdma_chn_arr[i32ChannID - NU_PDMA_CH_Pos].m_spPeripCtl; _nu_pdma_transfer(i32ChannID, psPeriphCtl->m_u32Peripheral, head, u32IdleTimeout_us); ret = RT_EOK; exit_nu_pdma_sg_transfer: return -(ret); } static void nu_pdma_isr(int vector, void *pvdata) { int i; PDMA_T *PDMA = (void *)pvdata; uint32_t intsts = PDMA_GET_INT_STATUS(PDMA); uint32_t abtsts = PDMA_GET_ABORT_STS(PDMA); uint32_t tdsts = PDMA_GET_TD_STS(PDMA); uint32_t unalignsts = PDMA_GET_ALIGN_STS(PDMA); uint32_t reqto = intsts & PDMA_INTSTS_REQTOFn_Msk; uint32_t reqto_ch = (reqto >> PDMA_INTSTS_REQTOFn_Pos); int allch_sts = (reqto_ch | tdsts | abtsts | unalignsts); // Abort if (intsts & PDMA_INTSTS_ABTIF_Msk) { // Clear all Abort flags PDMA_CLR_ABORT_FLAG(PDMA, abtsts); } // Transfer done if (intsts & PDMA_INTSTS_TDIF_Msk) { // Clear all transfer done flags PDMA_CLR_TD_FLAG(PDMA, tdsts); } // Unaligned if (intsts & PDMA_INTSTS_ALIGNF_Msk) { // Clear all Unaligned flags PDMA_CLR_ALIGN_FLAG(PDMA, unalignsts); } // Timeout if (reqto) { // Clear all Timeout flags PDMA->INTSTS = reqto; } // Find the position of first '1' in allch_sts. while ((i = nu_ctz(allch_sts)) < PDMA_CH_MAX) { int module_id = ((uint32_t)PDMA - DEF_PDMA_BASE_START) / 0x10000UL; int j = i + (module_id * PDMA_CH_MAX); int ch_mask = (1 << i); if (nu_pdma_chn_mask_arr[module_id] & ch_mask) { int ch_event = 0; nu_pdma_chn_t *dma_chn = nu_pdma_chn_arr + j - NU_PDMA_CH_Pos; if (dma_chn->m_sCB_Event.m_pfnCBHandler) { if (abtsts & ch_mask) { ch_event |= NU_PDMA_EVENT_ABORT; } if (tdsts & ch_mask) { ch_event |= NU_PDMA_EVENT_TRANSFER_DONE; } if (unalignsts & ch_mask) { ch_event |= NU_PDMA_EVENT_ALIGNMENT; } if (reqto_ch & ch_mask) { PDMA_DisableTimeout(PDMA, ch_mask); ch_event |= NU_PDMA_EVENT_TIMEOUT; } if (dma_chn->m_sCB_Disable.m_pfnCBHandler) dma_chn->m_sCB_Disable.m_pfnCBHandler(dma_chn->m_sCB_Disable.m_pvUserData, dma_chn->m_sCB_Disable.m_u32Reserved); if ((dma_chn->m_u32EventFilter & ch_event) && dma_chn->m_sCB_Event.m_pfnCBHandler) dma_chn->m_sCB_Event.m_pfnCBHandler(dma_chn->m_sCB_Event.m_pvUserData, ch_event); if (reqto_ch & ch_mask) nu_pdma_timeout_set(j, nu_pdma_chn_arr[j - NU_PDMA_CH_Pos].m_u32IdleTimeout_us); }//if(dma_chn->handler) } //if (nu_pdma_chn_mask & ch_mask) // Clear the served bit. allch_sts &= ~ch_mask; } //while } static void nu_pdma_memfun_actor_init(void) { int i = 0 ; nu_pdma_init(); for (i = 0; i < NU_PDMA_MEMFUN_ACTOR_MAX; i++) { rt_memset(&nu_pdma_memfun_actor_arr[i], 0, sizeof(struct nu_pdma_memfun_actor)); if (-(RT_ERROR) != (nu_pdma_memfun_actor_arr[i].m_i32ChannID = nu_pdma_channel_allocate(PDMA_MEM))) { nu_pdma_memfun_actor_arr[i].m_psSemMemFun = rt_sem_create("memactor_sem", 0, RT_IPC_FLAG_FIFO); RT_ASSERT(nu_pdma_memfun_actor_arr[i].m_psSemMemFun != RT_NULL); } else break; } if (i) { nu_pdma_memfun_actor_maxnum = i; nu_pdma_memfun_actor_mask = ~(((1 << i) - 1)); nu_pdma_memfun_actor_pool_sem = rt_sem_create("mempool_sem", nu_pdma_memfun_actor_maxnum, RT_IPC_FLAG_FIFO); RT_ASSERT(nu_pdma_memfun_actor_pool_sem != RT_NULL); nu_pdma_memfun_actor_pool_lock = rt_mutex_create("mempool_lock", RT_IPC_FLAG_PRIO); RT_ASSERT(nu_pdma_memfun_actor_pool_lock != RT_NULL); } } static void nu_pdma_memfun_cb(void *pvUserData, uint32_t u32Events) { rt_err_t result = RT_EOK; nu_pdma_memfun_actor_t psMemFunActor = (nu_pdma_memfun_actor_t)pvUserData; psMemFunActor->m_u32Result = u32Events; result = rt_sem_release(psMemFunActor->m_psSemMemFun); RT_ASSERT(result == RT_EOK); } static int nu_pdma_memfun_employ(void) { int idx = -1 ; rt_err_t result = RT_EOK; /* Headhunter */ if (nu_pdma_memfun_actor_pool_sem && ((result = rt_sem_take(nu_pdma_memfun_actor_pool_sem, RT_WAITING_FOREVER)) == RT_EOK)) { RT_ASSERT(result == RT_EOK); result = rt_mutex_take(nu_pdma_memfun_actor_pool_lock, RT_WAITING_FOREVER); RT_ASSERT(result == RT_EOK); /* Find the position of first '0' in nu_pdma_memfun_actor_mask. */ idx = nu_cto(nu_pdma_memfun_actor_mask); if (idx != 32) { nu_pdma_memfun_actor_mask |= (1 << idx); } else { idx = -1; } result = rt_mutex_release(nu_pdma_memfun_actor_pool_lock); RT_ASSERT(result == RT_EOK); } return idx; } static rt_size_t nu_pdma_memfun(void *dest, void *src, uint32_t u32DataWidth, unsigned int u32TransferCnt, nu_pdma_memctrl_t eMemCtl) { nu_pdma_memfun_actor_t psMemFunActor = NULL; struct nu_pdma_chn_cb sChnCB; rt_err_t result = RT_ERROR; int idx; rt_size_t ret = 0; /* Employ actor */ while ((idx = nu_pdma_memfun_employ()) < 0); psMemFunActor = &nu_pdma_memfun_actor_arr[idx]; /* Set PDMA memory control to eMemCtl. */ nu_pdma_channel_memctrl_set(psMemFunActor->m_i32ChannID, eMemCtl); /* Register ISR callback function */ sChnCB.m_eCBType = eCBType_Event; sChnCB.m_pfnCBHandler = nu_pdma_memfun_cb; sChnCB.m_pvUserData = (void *)psMemFunActor; nu_pdma_filtering_set(psMemFunActor->m_i32ChannID, NU_PDMA_EVENT_ABORT | NU_PDMA_EVENT_TRANSFER_DONE); nu_pdma_callback_register(psMemFunActor->m_i32ChannID, &sChnCB); psMemFunActor->m_u32Result = 0; /* Trigger it */ nu_pdma_transfer(psMemFunActor->m_i32ChannID, u32DataWidth, (uint32_t)src, (uint32_t)dest, u32TransferCnt, 0); /* Wait it done. */ result = rt_sem_take(psMemFunActor->m_psSemMemFun, RT_WAITING_FOREVER); RT_ASSERT(result == RT_EOK); /* Give result if get NU_PDMA_EVENT_TRANSFER_DONE.*/ if (psMemFunActor->m_u32Result & NU_PDMA_EVENT_TRANSFER_DONE) { ret += u32TransferCnt; } else { ret += (u32TransferCnt - nu_pdma_non_transfer_count_get(psMemFunActor->m_i32ChannID)); } /* Terminate it if get ABORT event */ if (psMemFunActor->m_u32Result & NU_PDMA_EVENT_ABORT) { nu_pdma_channel_terminate(psMemFunActor->m_i32ChannID); } result = rt_mutex_take(nu_pdma_memfun_actor_pool_lock, RT_WAITING_FOREVER); RT_ASSERT(result == RT_EOK); nu_pdma_memfun_actor_mask &= ~(1 << idx); result = rt_mutex_release(nu_pdma_memfun_actor_pool_lock); RT_ASSERT(result == RT_EOK); /* Fire actor */ result = rt_sem_release(nu_pdma_memfun_actor_pool_sem); RT_ASSERT(result == RT_EOK); return ret; } rt_size_t nu_pdma_mempush(void *dest, void *src, uint32_t data_width, unsigned int transfer_count) { if (data_width == 8 || data_width == 16 || data_width == 32) return nu_pdma_memfun(dest, src, data_width, transfer_count, eMemCtl_SrcInc_DstFix); return 0; } void *nu_pdma_memcpy(void *dest, void *src, unsigned int count) { int i = 0; uint32_t u32Offset = 0; uint32_t u32Remaining = count; for (i = 4; (i > 0) && (u32Remaining > 0) ; i >>= 1) { uint32_t u32src = (uint32_t)src + u32Offset; uint32_t u32dest = (uint32_t)dest + u32Offset; if (((u32src % i) == (u32dest % i)) && ((u32src % i) == 0) && (RT_ALIGN_DOWN(u32Remaining, i) >= i)) { uint32_t u32TXCnt = u32Remaining / i; if (u32TXCnt != nu_pdma_memfun((void *)u32dest, (void *)u32src, i * 8, u32TXCnt, eMemCtl_SrcInc_DstInc)) goto exit_nu_pdma_memcpy; u32Offset += (u32TXCnt * i); u32Remaining -= (u32TXCnt * i); } } if (count == u32Offset) return dest; exit_nu_pdma_memcpy: return NULL; } /** * PDMA memfun actor initialization */ int rt_hw_pdma_memfun_init(void) { nu_pdma_memfun_actor_init(); return 0; } INIT_DEVICE_EXPORT(rt_hw_pdma_memfun_init); #endif // #if defined(BSP_USING_PDMA)