/*! \file gd32f4xx_dma.c \brief DMA driver */ /* Copyright (C) 2016 GigaDevice 2016-08-15, V1.0.0, firmware for GD32F4xx */ #include "gd32f4xx_dma.h" /* DMA register bit offset */ #define CHXCTL_PERIEN_OFFSET ((uint32_t)25U) /*! \brief deinitialize DMA a channel registers \param[in] dma_periph: DMAx(x=0,1) \arg DMAx(x=0,1) \param[in] channelx: specify which DMA channel is deinitialized \arg DMA_CHx(x=0..7) \param[out] none \retval none */ void dma_deinit(uint32_t dma_periph,dma_channel_enum channelx) { /* disable DMA a channel */ DMA_CHCTL(dma_periph,channelx) &= ~DMA_CHXCTL_CHEN; /* reset DMA channel registers */ DMA_CHCTL(dma_periph,channelx) = DMA_CHCTL_RESET_VALUE; DMA_CHCNT(dma_periph,channelx) = DMA_CHCNT_RESET_VALUE; DMA_CHPADDR(dma_periph,channelx) = DMA_CHPADDR_RESET_VALUE; DMA_CHM0ADDR(dma_periph,channelx) = DMA_CHMADDR_RESET_VALUE; DMA_CHM1ADDR(dma_periph,channelx) = DMA_CHMADDR_RESET_VALUE; DMA_CHFCTL(dma_periph,channelx) = DMA_CHFCTL_RESET_VALUE; if(channelx < DMA_CH4){ DMA_INTC0(dma_periph) |= DMA_FLAG_ADD(DMA_CHINTF_RESET_VALUE,channelx); }else{ DMA_INTC1(dma_periph) |= DMA_FLAG_ADD(DMA_CHINTF_RESET_VALUE,channelx); } } /*! \brief initialize DMA single data mode \param[in] dma_periph: DMAx(x=0,1) \arg DMAx(x=0,1) \param[in] channelx: specify which DMA channel is initialized \arg DMA_CHx(x=0..7) \param[in] init_struct: the data needed to initialize DMA single data mode periph_addr: peripheral base address periph_memory_width: DMA_PERIPH_WIDTH_8BIT,DMA_PERIPH_WIDTH_16BIT,DMA_PERIPH_WIDTH_32BIT periph_inc: DMA_PERIPH_INCREASE_ENABLE,DMA_PERIPH_INCREASE_DISABLE,DMA_PERIPH_INCREASE_FIX memory0_addr: memory base address memory_inc: DMA_MEMORY_INCREASE_ENABLE,DMA_MEMORY_INCREASE_DISABLE direction: DMA_PERIPH_TO_MEMORY,DMA_MEMORY_TO_PERIPH,DMA_MEMORY_TO_MEMORY number: the number of remaining data to be transferred by the DMA priority: DMA_PRIORITY_LOW,DMA_PRIORITY_MEDIUM,DMA_PRIORITY_HIGH,DMA_PRIORITY_ULTRA_HIGH circular_mode: DMA_CIRCULAR_MODE_ENABLE,DMA_CIRCULAR_MODE_DISABLE \param[out] none \retval none */ void dma_single_data_mode_init(uint32_t dma_periph,dma_channel_enum channelx,dma_single_data_parameter_struct init_struct) { uint32_t ctl; /* select single data mode */ DMA_CHFCTL(dma_periph,channelx) &= ~DMA_CHXFCTL_MDMEN; /* configure peripheral base address */ DMA_CHPADDR(dma_periph,channelx) = init_struct.periph_addr; /* configure memory base address */ DMA_CHM0ADDR(dma_periph,channelx) = init_struct.memory0_addr; /* configure the number of remaining data to be transferred */ DMA_CHCNT(dma_periph,channelx) = init_struct.number; /* configure peripheral and memory transfer width,channel priotity,transfer mode */ ctl = DMA_CHCTL(dma_periph,channelx); ctl &= ~(DMA_CHXCTL_PWIDTH | DMA_CHXCTL_MWIDTH | DMA_CHXCTL_PRIO | DMA_CHXCTL_TM); ctl |= (init_struct.periph_memory_width | (init_struct.periph_memory_width << 2) | init_struct.priority | init_struct.direction); DMA_CHCTL(dma_periph,channelx) = ctl; /* configure peripheral increasing mode */ if(DMA_PERIPH_INCREASE_ENABLE == init_struct.periph_inc){ DMA_CHCTL(dma_periph,channelx) |= DMA_CHXCTL_PNAGA; }else if(DMA_PERIPH_INCREASE_DISABLE == init_struct.periph_inc){ DMA_CHCTL(dma_periph,channelx) &= ~DMA_CHXCTL_PNAGA; }else{ DMA_CHCTL(dma_periph,channelx) |= DMA_CHXCTL_PAIF; } /* configure memory increasing mode */ if(DMA_MEMORY_INCREASE_ENABLE == init_struct.memory_inc){ DMA_CHCTL(dma_periph,channelx) |= DMA_CHXCTL_MNAGA; }else{ DMA_CHCTL(dma_periph,channelx) &= ~DMA_CHXCTL_MNAGA; } /* configure DMA circular mode */ if(DMA_CIRCULAR_MODE_ENABLE == init_struct.circular_mode){ DMA_CHCTL(dma_periph,channelx) |= DMA_CHXCTL_CMEN; }else{ DMA_CHCTL(dma_periph,channelx) &= ~DMA_CHXCTL_CMEN; } } /*! \brief initialize DMA multi data mode \param[in] dma_periph: DMAx(x=0,1) \arg DMAx(x=0,1) \param[in] channelx: specify which DMA channel is initialized \arg DMA_CHx(x=0..7) \param[in] dma_multi_data_parameter_struct: the data needed to initialize DMA multi data mode periph_addr: peripheral base address periph_width: DMA_PERIPH_WIDTH_8BIT,DMA_PERIPH_WIDTH_16BIT,DMA_PERIPH_WIDTH_32BIT periph_inc: DMA_PERIPH_INCREASE_ENABLE,DMA_PERIPH_INCREASE_DISABLE,DMA_PERIPH_INCREASE_FIX memory0_addr: memory0 base address memory_width: DMA_MEMORY_WIDTH_8BIT,DMA_MEMORY_WIDTH_16BIT,DMA_MEMORY_WIDTH_32BIT memory_inc: DMA_MEMORY_INCREASE_ENABLE,DMA_MEMORY_INCREASE_DISABLE direction: DMA_PERIPH_TO_MEMORY,DMA_MEMORY_TO_PERIPH,DMA_MEMORY_TO_MEMORY number: the number of remaining data to be transferred by the DMA priority: DMA_PRIORITY_LOW,DMA_PRIORITY_MEDIUM,DMA_PRIORITY_HIGH,DMA_PRIORITY_ULTRA_HIGH circular_mode: DMA_CIRCULAR_MODE_ENABLE,DMA_CIRCULAR_MODE_DISABLE memory_burst_width: DMA_MEMORY_BURST_SINGLE,DMA_MEMORY_BURST_4_BEAT,DMA_MEMORY_BURST_8_BEAT,DMA_MEMORY_BURST_16_BEAT periph_burst_width: DMA_PERIPH_BURST_SINGLE,DMA_PERIPH_BURST_4_BEAT,DMA_PERIPH_BURST_8_BEAT,DMA_PERIPH_BURST_16_BEAT critical_value: DMA_FIFO_1_WORD,DMA_FIFO_2_WORD,DMA_FIFO_3_WORD,DMA_FIFO_4_WORD \param[out] none \retval none */ void dma_multi_data_mode_init(uint32_t dma_periph,dma_channel_enum channelx,dma_multi_data_parameter_struct init_struct) { uint32_t ctl; /* select multi data mode and configure FIFO critical value */ DMA_CHFCTL(dma_periph,channelx) |= (DMA_CHXFCTL_MDMEN | init_struct.critical_value); /* configure peripheral base address */ DMA_CHPADDR(dma_periph,channelx) = init_struct.periph_addr; /* configure memory base address */ DMA_CHM0ADDR(dma_periph,channelx) = init_struct.memory0_addr; /* configure the number of remaining data to be transferred */ DMA_CHCNT(dma_periph,channelx) = init_struct.number; /* configure peripheral and memory transfer width,channel priotity,transfer mode,peripheral and memory burst transfer width */ ctl = DMA_CHCTL(dma_periph,channelx); ctl &= ~(DMA_CHXCTL_PWIDTH | DMA_CHXCTL_MWIDTH | DMA_CHXCTL_PRIO | DMA_CHXCTL_TM | DMA_CHXCTL_PBURST | DMA_CHXCTL_MBURST); ctl |= (init_struct.periph_width | (init_struct.memory_width ) | init_struct.priority | init_struct.direction | init_struct.memory_burst_width | init_struct.periph_burst_width); DMA_CHCTL(dma_periph,channelx) = ctl; /* configure peripheral increasing mode */ if(DMA_PERIPH_INCREASE_ENABLE == init_struct.periph_inc){ DMA_CHCTL(dma_periph,channelx) |= DMA_CHXCTL_PNAGA; }else if(DMA_PERIPH_INCREASE_DISABLE == init_struct.periph_inc){ DMA_CHCTL(dma_periph,channelx) &= ~DMA_CHXCTL_PNAGA; }else{ DMA_CHCTL(dma_periph,channelx) |= DMA_CHXCTL_PAIF; } /* configure memory increasing mode */ if(DMA_MEMORY_INCREASE_ENABLE == init_struct.memory_inc){ DMA_CHCTL(dma_periph,channelx) |= DMA_CHXCTL_MNAGA; }else{ DMA_CHCTL(dma_periph,channelx) &= ~DMA_CHXCTL_MNAGA; } /* configure DMA circular mode */ if(DMA_CIRCULAR_MODE_ENABLE == init_struct.circular_mode){ DMA_CHCTL(dma_periph,channelx) |= DMA_CHXCTL_CMEN; }else{ DMA_CHCTL(dma_periph,channelx) &= ~DMA_CHXCTL_CMEN; } } /*! \brief get DMA flag is set or not \param[in] dma_periph: DMAx(x=0,1) \arg DMAx(x=0,1) \param[in] channelx: specify which DMA channel to get flag \arg DMA_CHx(x=0..7) \param[in] flag: specify get which flag \arg DMA_INTF_FEEIF: FIFO error and exception flag \arg DMA_INTF_SDEIF: single data mode exception flag \arg DMA_INTF_TAEIF: transfer access error flag \arg DMA_INTF_HTFIF: half transfer finish flag \arg DMA_INTF_FTFIF: full transger finish flag \param[out] none \retval FlagStatus: SET or RESET */ FlagStatus dma_flag_get(uint32_t dma_periph,dma_channel_enum channelx,uint32_t flag) { if(channelx < DMA_CH4){ if(DMA_INTF0(dma_periph) & DMA_FLAG_ADD(flag,channelx)){ return SET; }else{ return RESET; } }else{ channelx -= (dma_channel_enum)4; if(DMA_INTF1(dma_periph) & DMA_FLAG_ADD(flag,channelx)){ return SET; }else{ return RESET; } } } /*! \brief clear DMA a channel flag \param[in] dma_periph: DMAx(x=0,1) \arg DMAx(x=0,1) \param[in] channelx: specify which DMA channel to get flag \arg DMA_CHx(x=0..7) \param[in] flag: specify get which flag \arg DMA_INTF_FEEIF: FIFO error and exception flag \arg DMA_INTF_SDEIF: single data mode exception flag \arg DMA_INTF_TAEIF: transfer access error flag \arg DMA_INTF_HTFIF: half transfer finish flag \arg DMA_INTF_FTFIF: full transger finish flag \param[out] none \retval none */ void dma_flag_clear(uint32_t dma_periph,dma_channel_enum channelx,uint32_t flag) { if(channelx < DMA_CH4){ DMA_INTC0(dma_periph) |= DMA_FLAG_ADD(flag,channelx); }else{ channelx -= (dma_channel_enum)4; DMA_INTC1(dma_periph) |= DMA_FLAG_ADD(flag,channelx); } } /*! \brief get DMA interrupt flag is set or not \param[in] dma_periph: DMAx(x=0,1) \arg DMAx(x=0,1) \param[in] channelx: specify which DMA channel to get interrupt flag \arg DMA_CHx(x=0..7) \param[in] interrupt: specify get which flag \arg DMA_INTF_FEEIF: FIFO error and exception flag \arg DMA_INTF_SDEIF: single data mode exception flag \arg DMA_INTF_TAEIF: transfer access error flag \arg DMA_INTF_HTFIF: half transfer finish flag \arg DMA_INTF_FTFIF: full transger finish flag \param[out] none \retval FlagStatus: SET or RESET */ FlagStatus dma_interrupt_flag_get(uint32_t dma_periph,dma_channel_enum channelx,uint32_t interrupt) { uint32_t interrupt_enable = 0U,interrupt_flag = 0U; dma_channel_enum channel_flag_offset = channelx; if(channelx < DMA_CH4){ switch(interrupt){ case DMA_INTF_FEEIF: interrupt_flag = DMA_INTF0(dma_periph) & DMA_FLAG_ADD(interrupt,channelx); interrupt_enable = DMA_CHFCTL(dma_periph,channelx) & DMA_CHXFCTL_FEEIE; break; case DMA_INTF_SDEIF: interrupt_flag = DMA_INTF0(dma_periph) & DMA_FLAG_ADD(interrupt,channelx); interrupt_enable = DMA_CHCTL(dma_periph,channelx) & DMA_CHXCTL_SDEIE; break; case DMA_INTF_TAEIF: interrupt_flag = DMA_INTF0(dma_periph) & DMA_FLAG_ADD(interrupt,channelx); interrupt_enable = DMA_CHCTL(dma_periph,channelx) & DMA_CHXCTL_TAEIE; break; case DMA_INTF_HTFIF: interrupt_flag = DMA_INTF0(dma_periph) & DMA_FLAG_ADD(interrupt,channelx); interrupt_enable = DMA_CHCTL(dma_periph,channelx) & DMA_CHXCTL_HTFIE; break; case DMA_INTF_FTFIF: interrupt_flag = (DMA_INTF0(dma_periph) & DMA_FLAG_ADD(interrupt,channelx)); interrupt_enable = (DMA_CHCTL(dma_periph,channelx) & DMA_CHXCTL_FTFIE); break; default: break; } }else{ channel_flag_offset -= (dma_channel_enum)4; switch(interrupt){ case DMA_INTF_FEEIF: interrupt_flag = DMA_INTF1(dma_periph) & DMA_FLAG_ADD(interrupt,channel_flag_offset); interrupt_enable = DMA_CHFCTL(dma_periph,channelx) & DMA_CHXFCTL_FEEIE; break; case DMA_INTF_SDEIF: interrupt_flag = DMA_INTF1(dma_periph) & DMA_FLAG_ADD(interrupt,channel_flag_offset); interrupt_enable = DMA_CHCTL(dma_periph,channelx) & DMA_CHXCTL_SDEIE; break; case DMA_INTF_TAEIF: interrupt_flag = DMA_INTF1(dma_periph) & DMA_FLAG_ADD(interrupt,channel_flag_offset); interrupt_enable = DMA_CHCTL(dma_periph,channelx) & DMA_CHXCTL_TAEIE; break; case DMA_INTF_HTFIF: interrupt_flag = DMA_INTF1(dma_periph) & DMA_FLAG_ADD(interrupt,channel_flag_offset); interrupt_enable = DMA_CHCTL(dma_periph,channelx) & DMA_CHXCTL_HTFIE; break; case DMA_INTF_FTFIF: interrupt_flag = DMA_INTF1(dma_periph) & DMA_FLAG_ADD(interrupt,channel_flag_offset); interrupt_enable = DMA_CHCTL(dma_periph,channelx) & DMA_CHXCTL_FTFIE; break; default: break; } } if(interrupt_flag && interrupt_enable){ return SET; }else{ return RESET; } } /*! \brief clear DMA a channel interrupt flag \param[in] dma_periph: DMAx(x=0,1) \arg DMAx(x=0,1) \param[in] channelx: specify which DMA channel to clear interrupt flag \arg DMA_CHx(x=0..7) \param[in] interrupt: specify get which flag \arg DMA_INTC_FEEIFC: clear FIFO error and exception flag \arg DMA_INTC_SDEIFC: clear single data mode exception flag \arg DMA_INTC_TAEIFC: clear transfer access error flag \arg DMA_INTC_HTFIFC: clear half transfer finish flag \arg DMA_INTC_FTFIFC: clear full transger finish flag \param[out] none \retval none */ void dma_interrupt_flag_clear(uint32_t dma_periph,dma_channel_enum channelx,uint32_t interrupt) { if(channelx < DMA_CH4){ DMA_INTC0(dma_periph) |= DMA_FLAG_ADD(interrupt,channelx); }else{ channelx -= (dma_channel_enum)4; DMA_INTC1(dma_periph) |= DMA_FLAG_ADD(interrupt,channelx); } } /*! \brief enable DMA interrupt \param[in] dma_periph: DMAx(x=0,1) \arg DMAx(x=0,1) \param[in] channelx: specify which DMA channel \arg DMA_CHx(x=0..7) \param[in] source: specify which interrupt to enbale \arg DMA_CHXCTL_SDEIE: single data mode exception interrupt enable \arg DMA_CHXCTL_TAEIE: tranfer access error interrupt enable \arg DMA_CHXCTL_HTFIE: half transfer finish interrupt enable \arg DMA_CHXCTL_FTFIE: full transfer finish interrupt enable \arg DMA_CHXFCTL_FEEIE: FIFO exception interrupt enable \param[out] none \retval none */ void dma_interrupt_enable(uint32_t dma_periph,dma_channel_enum channelx,uint32_t source) { if(DMA_CHXFCTL_FEEIE != source){ DMA_CHCTL(dma_periph,channelx) |= source; }else{ DMA_CHFCTL(dma_periph,channelx) |= source; } } /*! \brief disable DMA interrupt \param[in] dma_periph: DMAx(x=0,1) \arg DMAx(x=0,1) \param[in] channelx: specify which DMA channel \arg DMA_CHx(x=0..7) \param[in] source: specify which interrupt to disbale \arg DMA_CHXCTL_SDEIE: single data mode exception interrupt enable \arg DMA_CHXCTL_TAEIE: tranfer access error interrupt enable \arg DMA_CHXCTL_HTFIE: half transfer finish interrupt enable \arg DMA_CHXCTL_FTFIE: full transfer finish interrupt enable \arg DMA_CHXFCTL_FEEIE: FIFO exception interrupt enable \param[out] none \retval none */ void dma_interrupt_disable(uint32_t dma_periph,dma_channel_enum channelx,uint32_t source) { if(DMA_CHXFCTL_FEEIE != source){ DMA_CHCTL(dma_periph,channelx) &= ~source; }else{ DMA_CHFCTL(dma_periph,channelx) &= ~source; } } /*! \brief set DMA peripheral base address \param[in] dma_periph: DMAx(x=0,1) \arg DMAx(x=0,1) \param[in] channelx: specify which DMA channel to set peripheral base address \arg DMA_CHx(x=0..7) \param[in] address: peripheral base address \param[out] none \retval none */ void dma_periph_address_config(uint32_t dma_periph,dma_channel_enum channelx,uint32_t address) { DMA_CHPADDR(dma_periph,channelx) = address; } /*! \brief set DMA Memory0 base address \param[in] dma_periph: DMAx(x=0,1) \arg DMAx(x=0,1) \param[in] channelx: specify which DMA channel to set Memory base address \arg DMA_CHx(x=0..7) \param[in] memory_flag: DMA_MEMORY_x(x=0,1) \param[in] address: Memory base address \param[out] none \retval none */ void dma_memory_address_config(uint32_t dma_periph,dma_channel_enum channelx,uint8_t memory_flag,uint32_t address) { if(memory_flag){ DMA_CHM1ADDR(dma_periph,channelx) = address; }else{ DMA_CHM0ADDR(dma_periph,channelx) = address; } } /*! \brief set the number of remaining data to be transferred by the DMA \param[in] dma_periph: DMAx(x=0,1) \arg DMAx(x=0,1) \param[in] channelx: specify which DMA channel to set number \arg DMA_CHx(x=0..7) \param[in] number: the number of remaining data to be transferred by the DMA \param[out] none \retval none */ void dma_transfer_number_config(uint32_t dma_periph,dma_channel_enum channelx,uint32_t number) { DMA_CHCNT(dma_periph,channelx) = number; } /*! \brief get the number of remaining data to be transferred by the DMA \param[in] dma_periph: DMAx(x=0,1) \arg DMAx(x=0,1) \param[in] channelx: specify which DMA channel to set number \arg DMA_CHx(x=0..7) \param[out] none \retval uint32_t: the number of remaining data to be transferred by the DMA */ uint32_t dma_transfer_number_get(uint32_t dma_periph,dma_channel_enum channelx) { return (uint32_t)DMA_CHCNT(dma_periph,channelx); } /*! \brief configure priority level of DMA channel \param[in] dma_periph: DMAx(x=0,1) \arg DMAx(x=0,1) \param[in] channelx: specify which DMA channel \arg DMA_CHx(x=0..7) \param[in] priority: priority Level of this channel \arg DMA_PRIORITY_LOW: low priority \arg DMA_PRIORITY_MEDIUM: medium priority \arg DMA_PRIORITY_HIGH: high priority \arg DMA_PRIORITY_ULTRA_HIGH: ultra high priority \param[out] none \retval none */ void dma_priority_config(uint32_t dma_periph,dma_channel_enum channelx,uint32_t priority) { uint32_t ctl; /* acquire DMA_CHxCTL register */ ctl = DMA_CHCTL(dma_periph,channelx); /* assign regiser */ ctl &= ~DMA_CHXCTL_PRIO; ctl |= priority; DMA_CHCTL(dma_periph,channelx) = ctl; } /*! \brief configure transfer burst beats of memory \param[in] dma_periph: DMAx(x=0,1) \arg DMAx(x=0,1) \param[in] channelx: specify which DMA channel \arg DMA_CHx(x=0..7) \param[in] mbeat: transfer burst beats \arg DMA_MEMORY_BURST_SINGLE: memory transfer single burst \arg DMA_MEMORY_BURST_4_BEAT: memory transfer 4-beat burst \arg DMA_MEMORY_BURST_8_BEAT: memory transfer 8-beat burst \arg DMA_MEMORY_BURST_16_BEAT: memory transfer 16-beat burst \param[out] none \retval none */ void dma_memory_burst_beats_config (uint32_t dma_periph,dma_channel_enum channelx,uint32_t mbeat) { uint32_t ctl; /* acquire DMA_CHxCTL register */ ctl = DMA_CHCTL(dma_periph,channelx); /* assign regiser */ ctl &= ~DMA_CHXCTL_MBURST; ctl |= mbeat; DMA_CHCTL(dma_periph,channelx) = ctl; } /*! \brief configure transfer burst beats of peripheral \param[in] dma_periph: DMAx(x=0,1) \arg DMAx(x=0,1) \param[in] channelx: specify which DMA channel \arg DMA_CHx(x=0..7) \param[in] pbeat: transfer burst beats \arg DMA_PERIPH_BURST_SINGLE: peripheral transfer single burst \arg DMA_PERIPH_BURST_4_BEAT: peripheral transfer 4-beat burst \arg DMA_PERIPH_BURST_8_BEAT: peripheral transfer 8-beat burst \arg DMA_PERIPH_BURST_16_BEAT: peripheral transfer 16-beat burst \param[out] none \retval none */ void dma_periph_burst_beats_config (uint32_t dma_periph,dma_channel_enum channelx,uint32_t pbeat) { uint32_t ctl; /* acquire DMA_CHxCTL register */ ctl = DMA_CHCTL(dma_periph,channelx); /* assign regiser */ ctl &= ~DMA_CHXCTL_PBURST; ctl |= pbeat; DMA_CHCTL(dma_periph,channelx) = ctl; } /*! \brief configure transfer data size of memory \param[in] dma_periph: DMAx(x=0,1) \arg DMAx(x=0,1) \param[in] channelx: specify which DMA channel \arg DMA_CHx(x=0..7) \param[in] msize: transfer data size of memory \arg DMA_MEMORY_WIDTH_8BIT: transfer data size of memory is 8-bit \arg DMA_MEMORY_WIDTH_16BIT: transfer data size of memory is 16-bit \arg DMA_MEMORY_WIDTH_32BIT: transfer data size of memory is 32-bit \param[out] none \retval none */ void dma_memory_width_config(uint32_t dma_periph,dma_channel_enum channelx,uint32_t msize) { uint32_t ctl; /* acquire DMA_CHxCTL register */ ctl = DMA_CHCTL(dma_periph,channelx); /* assign regiser */ ctl &= ~DMA_CHXCTL_MWIDTH; ctl |= msize; DMA_CHCTL(dma_periph,channelx) = ctl; } /*! \brief configure transfer data size of peripheral \param[in] dma_periph: DMAx(x=0,1) \arg DMAx(x=0,1) \param[in] channelx: specify which DMA channel \arg DMA_CHx(x=0..7) \param[in] msize: transfer data size of peripheral \arg DMA_PERIPHERAL_WIDTH_8BIT: transfer data size of peripheral is 8-bit \arg DMA_PERIPHERAL_WIDTH_16BIT: transfer data size of peripheral is 16-bit \arg DMA_PERIPHERAL_WIDTH_32BIT: transfer data size of peripheral is 32-bit \param[out] none \retval none */ void dma_periph_width_config (uint32_t dma_periph,dma_channel_enum channelx,uint32_t psize) { uint32_t ctl; /* acquire DMA_CHxCTL register */ ctl = DMA_CHCTL(dma_periph,channelx); /* assign regiser */ ctl &= ~DMA_CHXCTL_PWIDTH; ctl |= psize; DMA_CHCTL(dma_periph,channelx) = ctl; } /*! \brief configure memory address generation generation_algorithm \param[in] dma_periph: DMAx(x=0,1) \arg DMAx(x=0,1) \param[in] channelx: specify which DMA channel \arg DMA_CHx(x=0..7) \param[in] generation_algorithm: the address generation algorithm \arg DMA_MEMORY_INCREASE_ENABLE: next address of memory is increasing address mode \arg DMA_MEMORY_INCREASE_DISABLE: next address of memory is fixed address mode \param[out] none \retval none */ void dma_memory_address_generation_config(uint32_t dma_periph,dma_channel_enum channelx,uint8_t generation_algorithm) { if(DMA_MEMORY_INCREASE_ENABLE == generation_algorithm){ DMA_CHCTL(dma_periph,channelx) |= DMA_CHXCTL_MNAGA; }else{ DMA_CHCTL(dma_periph,channelx) &= ~DMA_CHXCTL_MNAGA; } } /*! \brief configure peripheral address generation generation_algorithm \param[in] dma_periph: DMAx(x=0,1) \arg DMAx(x=0,1) \param[in] channelx: specify which DMA channel \arg DMA_CHx(x=0..7) \param[in] generation_algorithm: the address generation algorithm \arg DMA_PERIPH_INCREASE_ENABLE: next address of peripheral is increasing address mode \arg DMA_PERIPH_INCREASE_DISABLE: next address of peripheral is fixed address mode \arg DMA_PERIPH_INCREASE_FIX: increasing steps of peripheral address is fixed \param[out] none \retval none */ void dma_peripheral_address_generation_config(uint32_t dma_periph,dma_channel_enum channelx,uint8_t generation_algorithm) { if(DMA_PERIPH_INCREASE_ENABLE == generation_algorithm){ DMA_CHCTL(dma_periph,channelx) |= DMA_CHXCTL_PNAGA; }else if(DMA_PERIPH_INCREASE_DISABLE == generation_algorithm){ DMA_CHCTL(dma_periph,channelx) &= ~DMA_CHXCTL_PNAGA; }else{ DMA_CHCTL(dma_periph,channelx) |= DMA_CHXCTL_PNAGA; DMA_CHCTL(dma_periph,channelx) |= DMA_CHXCTL_PAIF; } } /*! \brief enable DMA circulation mode \param[in] dma_periph: DMAx(x=0,1) \arg DMAx(x=0,1) \param[in] channelx: specify which DMA channel \arg DMA_CHx(x=0..7) \param[out] none \retval none */ void dma_circulation_enable(uint32_t dma_periph,dma_channel_enum channelx) { DMA_CHCTL(dma_periph,channelx) |= DMA_CHXCTL_CMEN; } /*! \brief disable DMA circulation mode \param[in] dma_periph: DMAx(x=0,1) \arg DMAx(x=0,1) \param[in] channelx: specify which DMA channel \arg DMA_CHx(x=0..7) \param[out] none \retval none */ void dma_circulation_disable(uint32_t dma_periph,dma_channel_enum channelx) { DMA_CHCTL(dma_periph,channelx) &= ~DMA_CHXCTL_CMEN; } /*! \brief configure the direction of data transfer on the channel \param[in] dma_periph: DMAx(x=0,1) \arg DMAx(x=0,1) \param[in] channelx: specify which DMA channel \arg DMA_CHx(x=0..7) \param[in] direction: specify the direction of data transfer \arg DMA_PERIPH_TO_MEMORY: read from peripheral and write to memory \arg DMA_MEMORY_TO_PERIPH: read from memory and write to peripheral \arg DMA_MEMORY_TO_MEMORY: read from memory and write to memory \param[out] none \retval none */ void dma_transfer_direction_config(uint32_t dma_periph,dma_channel_enum channelx,uint8_t direction) { uint32_t ctl; /* acquire DMA_CHxCTL register */ ctl = DMA_CHCTL(dma_periph,channelx); /* assign regiser */ ctl &= ~DMA_CHXCTL_TM; ctl |= direction; DMA_CHCTL(dma_periph,channelx) = ctl; } /*! \brief enable DMA channel \param[in] dma_periph: DMAx(x=0,1) \arg DMAx(x=0,1) \param[in] channelx: specify which DMA channel \arg DMA_CHx(x=0..7) \param[out] none \retval none */ void dma_channel_enable(uint32_t dma_periph,dma_channel_enum channelx) { DMA_CHCTL(dma_periph,channelx) |= DMA_CHXCTL_CHEN; } /*! \brief disable DMA channel \param[in] dma_periph: DMAx(x=0,1) \arg DMAx(x=0,1) \param[in] channelx: specify which DMA channel \arg DMA_CHx(x=0..7) \param[out] none \retval none */ void dma_channel_disable(uint32_t dma_periph,dma_channel_enum channelx) { DMA_CHCTL(dma_periph,channelx) &= ~DMA_CHXCTL_CHEN; } /*! \brief DMA channel peripheral select \param[in] dma_periph: DMAx(x=0,1) \arg DMAx(x=0,1) \param[in] channelx: specify which DMA channel \arg DMA_CHx(x=0..7) \param[in] sub_periph: specify DMA channel peripheral \arg DMA_SUBPERIx(x=0..7) \param[out] none \retval none */ void dma_channel_subperipheral_select(uint32_t dma_periph,dma_channel_enum channelx,dma_subperipheral_enum sub_periph) { uint32_t ctl; /* acquire DMA_CHxCTL register */ ctl = DMA_CHCTL(dma_periph,channelx); /* assign regiser */ ctl &= ~DMA_CHXCTL_PERIEN; ctl |= ((uint32_t)sub_periph << CHXCTL_PERIEN_OFFSET); DMA_CHCTL(dma_periph,channelx) = ctl; } /*! \brief DMA switch buffer mode config \param[in] dma_periph: DMAx(x=0,1) \arg DMAx(x=0,1) \param[in] channelx: specify which DMA channel \arg DMA_CHx(x=0..7) \param[in] memory1_addr: memory1 base address \param[in] memory_select: DMA_MEMORY_0 or DMA_MEMORY_1 \param[out] none \retval none */ void dma_switch_buffer_mode_config(uint32_t dma_periph,dma_channel_enum channelx,uint32_t memory1_addr,uint32_t memory_select) { /* configure memory1 base address */ DMA_CHM1ADDR(dma_periph,channelx) = memory1_addr; if(DMA_MEMORY_0 == memory_select){ DMA_CHCTL(dma_periph,channelx) &= ~DMA_CHXCTL_MBS; }else{ DMA_CHCTL(dma_periph,channelx) |= DMA_CHXCTL_MBS; } } /*! \brief DMA switch buffer mode enable \param[in] dma_periph: DMAx(x=0,1) \arg DMAx(x=0,1) \param[in] channelx: specify which DMA channel \arg DMA_CHx(x=0..7) \param[in] newvalue: ENABLE or DISABLE \param[out] none \retval none */ void dma_switch_buffer_mode_enable(uint32_t dma_periph,dma_channel_enum channelx,ControlStatus newvalue) { if(ENABLE == newvalue){ /* switch buffer mode enable */ DMA_CHCTL(dma_periph,channelx) |= DMA_CHXCTL_SBMEN; }else{ /* switch buffer mode disable */ DMA_CHCTL(dma_periph,channelx) &= ~DMA_CHXCTL_SBMEN; } } /*! \brief DMA using memory get \param[in] dma_periph: DMAx(x=0,1) \arg DMAx(x=0,1) \param[in] channelx: specify which DMA channel \arg DMA_CHx(x=0..7) \param[out] none \retval the using memory */ uint32_t dma_using_memory_get(uint32_t dma_periph,dma_channel_enum channelx) { if((DMA_CHCTL(dma_periph,channelx)) & DMA_CHXCTL_MBS){ return DMA_MEMORY_1; }else{ return DMA_MEMORY_0; } } /*! \brief DMA flow controller configure \param[in] dma_periph: DMAx(x=0,1) \arg DMAx(x=0,1) \param[in] channelx: specify which DMA channel \arg DMA_CHx(x=0..7) \param[in] controller: specify DMA flow controler \arg DMA_FLOW_CONTROLLER_DMA: DMA is the flow controller \arg DMA_FLOW_CONTROLLER_PERI: peripheral is the flow controller \param[out] none \retval none */ void dma_flow_controller_config(uint32_t dma_periph,dma_channel_enum channelx,uint32_t controller) { if(DMA_FLOW_CONTROLLER_DMA == controller){ DMA_CHCTL(dma_periph,channelx) &= ~DMA_CHXCTL_TFCS; }else{ DMA_CHCTL(dma_periph,channelx) |= DMA_CHXCTL_TFCS; } } /*! \brief DMA FIFO status get \param[in] dma_periph: DMAx(x=0,1) \arg DMAx(x=0,1) \param[in] channelx: specify which DMA channel \arg DMA_CHx(x=0..7) \param[out] none \retval the using memory */ uint32_t dma_fifo_status_get(uint32_t dma_periph,dma_channel_enum channelx) { return (DMA_CHFCTL(dma_periph,channelx) & DMA_CHXFCTL_FCNT); }