/*! \file gd32f4xx_usart.c \brief USART driver */ /* Copyright (C) 2016 GigaDevice 2016-08-15, V1.0.0, firmware for GD32F4xx */ #include "gd32f4xx_usart.h" /*! \brief reset USART/UART \param[in] usart_periph: USARTx(x=0,1,2,5)/UARTx(x=3,4,6,7) \param[out] none \retval none */ void usart_deinit(uint32_t usart_periph) { switch(usart_periph){ case USART0: rcu_periph_reset_enable(RCU_USART0RST); rcu_periph_reset_disable(RCU_USART0RST); break; case USART1: rcu_periph_reset_enable(RCU_USART1RST); rcu_periph_reset_disable(RCU_USART1RST); break; case USART2: rcu_periph_reset_enable(RCU_USART2RST); rcu_periph_reset_disable(RCU_USART2RST); break; case USART5: rcu_periph_reset_enable(RCU_USART5RST); rcu_periph_reset_disable(RCU_USART5RST); break; case UART3: rcu_periph_reset_enable(RCU_UART3RST); rcu_periph_reset_disable(RCU_UART3RST); break; case UART4: rcu_periph_reset_enable(RCU_UART4RST); rcu_periph_reset_disable(RCU_UART4RST); break; case UART6: rcu_periph_reset_enable(RCU_UART6RST); rcu_periph_reset_disable(RCU_UART6RST); break; case UART7: rcu_periph_reset_enable(RCU_UART7RST); rcu_periph_reset_disable(RCU_UART7RST); break; default: break; } } /*! \brief configure USART baud rate value \param[in] usart_periph: USARTx(x=0,1,2,5)/UARTx(x=3,4,6,7) \param[in] baudval: baud rate value \param[out] none \retval none */ void usart_baudrate_set(uint32_t usart_periph, uint32_t baudval) { uint32_t uclk=0U, intdiv=0U, fradiv=0U, udiv=0U; switch(usart_periph){ /* get clock frequency */ case USART0: uclk=rcu_clock_freq_get(CK_APB2); break; case USART5: uclk=rcu_clock_freq_get(CK_APB2); break; case USART1: uclk=rcu_clock_freq_get(CK_APB1); break; case USART2: uclk=rcu_clock_freq_get(CK_APB1); break; case UART3: uclk=rcu_clock_freq_get(CK_APB1); break; case UART4: uclk=rcu_clock_freq_get(CK_APB1); break; case UART6: uclk=rcu_clock_freq_get(CK_APB1); break; case UART7: uclk=rcu_clock_freq_get(CK_APB1); break; default: break; } if(USART_CTL0(usart_periph) & USART_CTL0_OVSMOD){ /* when oversampling by 8, configure the value of USART_BAUD */ udiv = ((2U*uclk) + baudval/2U)/baudval; intdiv = udiv & 0xfff0U; fradiv = udiv & 0x7U; USART_BAUD(usart_periph) |= ((USART_BAUD_FRADIV | USART_BAUD_INTDIV) & (intdiv | fradiv)); }else{ /* when oversampling by 16, configure the value of USART_BAUD */ udiv = (uclk+baudval/2U)/baudval; intdiv = udiv & 0xfff0U; fradiv = udiv & 0xfU; USART_BAUD(usart_periph) |= ((USART_BAUD_FRADIV | USART_BAUD_INTDIV) & (intdiv | fradiv)); } } /*! \brief configure USART parity function \param[in] usart_periph: USARTx(x=0,1,2,5)/UARTx(x=3,4,6,7) \param[in] paritycfg: configure USART parity \arg USART_PM_NONE: no parity \arg USART_PM_ODD: odd parity \arg USART_PM_EVEN: even parity \param[out] none \retval none */ void usart_parity_config(uint32_t usart_periph, uint32_t paritycfg) { /* clear USART_CTL0 PM,PCEN Bits */ USART_CTL0(usart_periph) &= ~(USART_CTL0_PM | USART_CTL0_PCEN); /* configure USART parity mode */ USART_CTL0(usart_periph) |= paritycfg ; } /*! \brief configure USART word length \param[in] usart_periph: USARTx(x=0,1,2,5)/UARTx(x=3,4,6,7) \param[in] wlen: USART word length configure \arg USART_WL_8BIT: 8 bits \arg USART_WL_9BIT: 9 bits \param[out] none \retval none */ void usart_word_length_set(uint32_t usart_periph, uint32_t wlen) { /* clear USART_CTL0 WL bit */ USART_CTL0(usart_periph) &= ~USART_CTL0_WL; /* configure USART word length */ USART_CTL0(usart_periph) |= wlen; } /*! \brief configure USART stop bit length \param[in] usart_periph: USARTx(x=0,1,2,5)/UARTx(x=3,4,6,7) \param[in] stblen: USART stop bit configure \arg USART_STB_1BIT: 1 bit \arg USART_STB_0_5BIT: 0.5 bit \arg USART_STB_2BIT: 2 bits \arg USART_STB_1_5BIT: 1.5 bits \param[out] none \retval none */ void usart_stop_bit_set(uint32_t usart_periph, uint32_t stblen) { /* clear USART_CTL1 STB bits */ USART_CTL1(usart_periph) &= ~USART_CTL1_STB; /* configure USART stop bits */ USART_CTL1(usart_periph) |= stblen; } /*! \brief enable USART \param[in] usart_periph: USARTx(x=0,1,2,5)/UARTx(x=3,4,6,7) \param[out] none \retval none */ void usart_enable(uint32_t usart_periph) { USART_CTL0(usart_periph) |= USART_CTL0_UEN; } /*! \brief disable USART \param[in] usart_periph: USARTx(x=0,1,2,5)/UARTx(x=3,4,6,7) \param[out] none \retval none */ void usart_disable(uint32_t usart_periph) { USART_CTL0(usart_periph) &= ~(USART_CTL0_UEN); } /*! \brief configure USART transmitter \param[in] usart_periph: USARTx(x=0,1,2,5)/UARTx(x=3,4,6,7) \param[in] rtconfig: enable or disable USART transmitter \arg USART_TRANSMIT_ENABLE: enable USART transmission \arg USART_TRANSMIT_DISABLE: enable USART transmission \param[out] none \retval none */ void usart_transmit_config(uint32_t usart_periph, uint32_t txconfig) { uint32_t ctl = 0U; ctl = USART_CTL0(usart_periph); ctl &= ~USART_CTL0_TEN; ctl |= txconfig; /* configure transfer mode */ USART_CTL0(usart_periph) = ctl; } /*! \brief configure USART receiver \param[in] usart_periph: USARTx(x=0,1,2,5)/UARTx(x=3,4,6,7) \param[in] rtconfig: enable or disable USART receiver \arg USART_RECEIVE_ENABLE: enable USART reception \arg USART_RECEIVE_DISABLE: disable USART reception \param[out] none \retval none */ void usart_receive_config(uint32_t usart_periph, uint32_t rxconfig) { uint32_t ctl = 0U; ctl = USART_CTL0(usart_periph); ctl &= ~USART_CTL0_REN; ctl |= rxconfig; /* configure transfer mode */ USART_CTL0(usart_periph) = ctl; } /*! \brief data is transmitted/received with the LSB/MSB first \param[in] usart_periph: USARTx(x=0,1,2,5) \param[in] msbf: LSB/MSB \arg USART_MSBF_LSB: LSB first \arg USART_MSBF_MSB: MSB first \param[out] none \retval none */ void usart_data_first_config(uint32_t usart_periph, uint32_t msbf) { USART_CTL3(usart_periph) &= ~(USART_CTL3_MSBF); USART_CTL3(usart_periph) |= msbf; } /*! \brief configure USART inversion \param[in] usart_periph: USARTx(x=0,1,2,5) \param[in] invertpara: refer to enum USART_INVERT_CONFIG \arg USART_DINV_ENABLE: data bit level inversion \arg USART_DINV_DISABLE: data bit level not inversion \arg USART_TXPIN_ENABLE: TX pin level inversion \arg USART_TXPIN_DISABLE: TX pin level not inversion \arg USART_RXPIN_ENABLE: RX pin level inversion \arg USART_RXPIN_DISABLE: RX pin level not inversion \param[out] none \retval none */ void usart_invert_config(uint32_t usart_periph, usart_invert_enum invertpara) { /* inverted or not the specified siginal */ switch(invertpara){ case USART_DINV_ENABLE: USART_CTL3(usart_periph) |= USART_CTL3_DINV; break; case USART_TXPIN_ENABLE: USART_CTL3(usart_periph) |= USART_CTL3_TINV; break; case USART_RXPIN_ENABLE: USART_CTL3(usart_periph) |= USART_CTL3_RINV; break; case USART_DINV_DISABLE: USART_CTL3(usart_periph) &= ~(USART_CTL3_DINV); break; case USART_TXPIN_DISABLE: USART_CTL3(usart_periph) &= ~(USART_CTL3_TINV); break; case USART_RXPIN_DISABLE: USART_CTL3(usart_periph) &= ~(USART_CTL3_RINV); break; default: break; } } /*! \brief configure the USART oversample mode \param[in] usart_periph: USARTx(x=0,1,2,5)/UARTx(x=3,4,6,7) \param[in] oversamp: oversample value \arg USART_OVSMOD_8: 8 bits \arg USART_OVSMOD_16: 16 bits \param[out] none \retval none */ void usart_oversample_config(uint32_t usart_periph, uint32_t oversamp) { /* clear OVSMOD bit */ USART_CTL0(usart_periph) &= ~(USART_CTL0_OVSMOD); USART_CTL0(usart_periph) |= oversamp; } /*! \brief configure sample bit method \param[in] usart_periph: USARTx(x=0,1,2,5)/UARTx(x=3,4,6,7) \param[in] obsm: sample bit \arg USART_OSB_1bit: 1 bit \arg USART_OSB_3bit: 3 bits \param[out] none \retval none */ void usart_sample_bit_config(uint32_t usart_periph, uint32_t obsm) { USART_CTL2(usart_periph) &= ~(USART_CTL2_OSB); USART_CTL2(usart_periph) |= obsm; } /*! \brief enable receiver timeout of USART \param[in] usart_periph: USARTx(x=0,1,2,5) \param[out] none \retval none */ void usart_receiver_timeout_enable(uint32_t usart_periph) { USART_CTL3(usart_periph) |= USART_CTL3_RTEN; } /*! \brief disable receiver timeout of USART \param[in] usart_periph: USARTx(x=0,1,2,5) \param[out] none \retval none */ void usart_receiver_timeout_disable(uint32_t usart_periph) { USART_CTL3(usart_periph) &= ~(USART_CTL3_RTEN); } /*! \brief set the receiver timeout threshold of USART \param[in] usart_periph: USARTx(x=0,1,2,5) \param[in] rtimeout: 0-0x00FFFFFF \param[out] none \retval none */ void usart_receiver_timeout_threshold_config(uint32_t usart_periph, uint32_t rtimeout) { USART_RT(usart_periph) &= ~(USART_RT_RT); USART_RT(usart_periph) |= rtimeout; } /*! \brief USART transmit data function \param[in] usart_periph: USARTx(x=0,1,2,5)/UARTx(x=3,4,6,7) \param[in] data: data of transmission \param[out] none \retval none */ void usart_data_transmit(uint32_t usart_periph, uint32_t data) { USART_DATA(usart_periph) = ((uint16_t)USART_DATA_DATA & data); } /*! \brief USART receive data function \param[in] usart_periph: USARTx(x=0,1,2,5)/UARTx(x=3,4,6,7) \param[out] none \retval data of received */ uint16_t usart_data_receive(uint32_t usart_periph) { return (uint16_t)(USART_DATA(usart_periph) & (uint16_t)USART_DATA_DATA); } /*! \brief configure the address of the USART in wake up by address match mode \param[in] usart_periph: USARTx(x=0,1,2,5)/UARTx(x=3,4,6,7) \param[in] addr: address of USART/UART \param[out] none \retval none */ void usart_address_config(uint32_t usart_periph, uint8_t addr) { USART_CTL1(usart_periph) &= ~(USART_CTL1_ADDR); USART_CTL1(usart_periph) |= (USART_CTL1_ADDR & addr); } /*! \brief receiver in mute mode \param[in] usart_periph: USARTx(x=0,1,2,5)/UARTx(x=3,4,6,7) \param[out] none \retval none */ void usart_mute_mode_enable(uint32_t usart_periph) { USART_CTL0(usart_periph) |= USART_CTL0_RWU; } /*! \brief receiver in active mode \param[in] usart_periph: USARTx(x=0,1,2,5)/UARTx(x=3,4,6,7) \param[out] none \retval none */ void usart_mute_mode_disable(uint32_t usart_periph) { USART_CTL0(usart_periph) &= ~(USART_CTL0_RWU); } /*! \brief configure wakeup method in mute mode \param[in] usart_periph: USARTx(x=0,1,2,5)/UARTx(x=3,4,6,7) \param[in] wmehtod: two method be used to enter or exit the mute mode \arg USART_WM_IDLE: idle line \arg USART_WM_ADDR: address mask \param[out] none \retval none */ void usart_mute_mode_wakeup_config(uint32_t usart_periph, uint32_t wmehtod) { USART_CTL0(usart_periph) &= ~(USART_CTL0_WM); USART_CTL0(usart_periph) |= wmehtod; } /*! \brief enable LIN mode \param[in] usart_periph: USARTx(x=0,1,2,5)/UARTx(x=3,4,6,7) \param[out] none \retval none */ void usart_lin_mode_enable(uint32_t usart_periph) { USART_CTL1(usart_periph) |= USART_CTL1_LMEN; } /*! \brief disable LIN mode \param[in] usart_periph: USARTx(x=0,1,2,5)/UARTx(x=3,4,6,7) \param[out] none \retval none */ void usart_lin_mode_disable(uint32_t usart_periph) { USART_CTL1(usart_periph) &= ~(USART_CTL1_LMEN); } /*! \brief configure lin break frame length \param[in] usart_periph: USARTx(x=0,1,2,5)/UARTx(x=3,4,6,7) \param[in] lblen: lin break frame length \arg USART_LBLEN_10B: 10 bits \arg USART_LBLEN_11B: 11 bits \param[out] none \retval none */ void usart_lin_break_dection_length_config(uint32_t usart_periph, uint32_t lblen) { USART_CTL1(usart_periph) &= ~(USART_CTL1_LBLEN); USART_CTL1(usart_periph) |= (USART_CTL1_LBLEN & lblen); } /*! \brief send break frame \param[in] usart_periph: USARTx(x=0,1,2,5)/UARTx(x=3,4,6,7) \param[out] none \retval none */ void usart_send_break(uint32_t usart_periph) { USART_CTL0(usart_periph) |= USART_CTL0_SBKCMD; } /*! \brief enable half duplex mode \param[in] usart_periph: USARTx(x=0,1,2,5)/UARTx(x=3,4,6,7) \param[out] none \retval none */ void usart_halfduplex_enable(uint32_t usart_periph) { USART_CTL2(usart_periph) |= USART_CTL2_HDEN; } /*! \brief disable half duplex mode \param[in] usart_periph: USARTx(x=0,1,2,5)/UARTx(x=3,4,6,7) \param[out] none \retval none */ void usart_halfduplex_disable(uint32_t usart_periph) { USART_CTL2(usart_periph) &= ~(USART_CTL2_HDEN); } /*! \brief enable CK pin in synchronous mode \param[in] usart_periph: USARTx(x=0,1,2,5) \param[out] none \retval none */ void usart_synchronous_clock_enable(uint32_t usart_periph) { USART_CTL1(usart_periph) |= USART_CTL1_CKEN; } /*! \brief disable CK pin in synchronous mode \param[in] usart_periph: USARTx(x=0,1,2,5) \param[out] none \retval none */ void usart_synchronous_clock_disable(uint32_t usart_periph) { USART_CTL1(usart_periph) &= ~(USART_CTL1_CKEN); } /*! \brief configure USART synchronous mode parameters \param[in] usart_periph: USARTx(x=0,1,2,5) \param[in] clen: CK length \arg USART_CLEN_NONE: there are 7 CK pulses for an 8 bit frame and 8 CK pulses for a 9 bit frame \arg USART_CLEN_EN: there are 8 CK pulses for an 8 bit frame and 9 CK pulses for a 9 bit frame \param[in] cph: clock phase \arg USART_CPH_1CK: first clock transition is the first data capture edge \arg USART_CPH_2CK: second clock transition is the first data capture edge \param[in] cpl: clock polarity \arg USART_CPL_LOW: steady low value on CK pin \arg USART_CPL_HIGH: steady high value on CK pin \param[out] none \retval none */ void usart_synchronous_clock_config(uint32_t usart_periph, uint32_t clen, uint32_t cph, uint32_t cpl) { uint32_t ctl = 0U; /* read USART_CTL1 register */ ctl = USART_CTL1(usart_periph); /* set CK length, CK phase, CK polarity */ ctl |= (USART_CTL1_CLEN & clen) | (USART_CTL1_CPH & cph) | (USART_CTL1_CPL & cpl); USART_CTL1(usart_periph) |= ctl; } /*! \brief configure guard time value in smartcard mode \param[in] usart_periph: USARTx(x=0,1,2,5) \param[in] gaut: guard time value \param[out] none \retval none */ void usart_guard_time_config(uint32_t usart_periph,uint32_t gaut) { USART_GP(usart_periph) &= ~(USART_GP_GUAT); USART_GP(usart_periph) |= (USART_GP_GUAT & ((gaut)<<8)); } /*! \brief enable smartcard mode \param[in] usart_periph: USARTx(x=0,1,2,5) \param[out] none \retval none */ void usart_smartcard_mode_enable(uint32_t usart_periph) { USART_CTL2(usart_periph) |= USART_CTL2_SCEN; } /*! \brief disable smartcard mode \param[in] usart_periph: USARTx(x=0,1,2,5) \param[out] none \retval none */ void usart_smartcard_mode_disable(uint32_t usart_periph) { USART_CTL2(usart_periph) &= ~(USART_CTL2_SCEN); } /*! \brief enable NACK in smartcard mode \param[in] usart_periph: USARTx(x=0,1,2,5) \param[out] none \retval none */ void usart_smartcard_mode_nack_enable(uint32_t usart_periph) { USART_CTL2(usart_periph) |= USART_CTL2_NKEN; } /*! \brief disable NACK in smartcard mode \param[in] usart_periph: USARTx(x=0,1,2,5) \param[out] none \retval none */ void usart_smartcard_mode_nack_disable(uint32_t usart_periph) { USART_CTL2(usart_periph) &= ~(USART_CTL2_NKEN); } /*! \brief configure smartcard auto-retry number \param[in] usart_periph: USARTx(x=0,1,2,5) \param[in] scrtnum: smartcard auto-retry number \param[out] none \retval none */ void usart_smartcard_autoretry_config(uint32_t usart_periph, uint32_t scrtnum) { USART_CTL3(usart_periph) &= ~(USART_CTL3_SCRTNUM); USART_CTL3(usart_periph) |= (USART_CTL3_SCRTNUM & ((scrtnum)<<1)); } /*! \brief configure block length in Smartcard T=1 reception \param[in] usart_periph: USARTx(x=0,1,2,5) \param[in] bl: block length \param[out] none \retval none */ void usart_block_length_config(uint32_t usart_periph, uint32_t bl) { USART_RT(usart_periph) &= ~(USART_RT_BL); USART_RT(usart_periph) |= (USART_RT_BL & ((bl)<<24)); } /*! \brief enable IrDA mode \param[in] usart_periph: USARTx(x=0,1,2,5)/UARTx(x=3,4,6,7) \param[out] none \retval none */ void usart_irda_mode_enable(uint32_t usart_periph) { USART_CTL2(usart_periph) |= USART_CTL2_IREN; } /*! \brief disable IrDA mode \param[in] usart_periph: USARTx(x=0,1,2,5)/UARTx(x=3,4,6,7) \param[out] none \retval none */ void usart_irda_mode_disable(uint32_t usart_periph) { USART_CTL2(usart_periph) &= ~(USART_CTL2_IREN); } /*! \brief configure the peripheral clock prescaler in USART IrDA low-power mode \param[in] usart_periph: USARTx(x=0,1,2,5)/UARTx(x=3,4,6,7) \param[in] psc: 0-0x00FFFFFF \param[out] none \retval none */ void usart_prescaler_config(uint32_t usart_periph, uint32_t psc) { USART_GP(usart_periph) &= ~(USART_GP_PSC); USART_GP(usart_periph) |= psc; } /*! \brief configure IrDA low-power \param[in] usart_periph: USARTx(x=0,1,2,5)/UARTx(x=3,4,6,7) \param[in] irlp: IrDA low-power or normal \arg USART_IRLP_LOW: low-power \arg USART_IRLP_NORMAL: normal \param[out] none \retval none */ void usart_irda_lowpower_config(uint32_t usart_periph, uint32_t irlp) { USART_CTL2(usart_periph) &= ~(USART_CTL2_IRLP); USART_CTL2(usart_periph) |= (USART_CTL2_IRLP & irlp); } /*! \brief configure hardware flow control RTS \param[in] usart_periph: USARTx(x=0,1,2,5) \param[in] hardwareflow: enable or disable RTS \arg USART_RTS_ENABLE: enable RTS \arg USART_RTS_DISABLE: disable RTS \param[out] none \retval none */ void usart_hardware_flow_rts_config(uint32_t usart_periph, uint32_t rtsconfig) { uint32_t ctl = 0U; ctl = USART_CTL2(usart_periph); ctl &= ~USART_CTL2_RTSEN; ctl |= rtsconfig; /* configure RTS */ USART_CTL2(usart_periph) = ctl; } /*! \brief configure hardware flow control CTS \param[in] usart_periph: USARTx(x=0,1,2,5) \param[in] hardwareflow: enable or disable CTS \arg USART_CTS_ENABLE: enable CTS \arg USART_CTS_DISABLE: disable CTS \param[out] none \retval none */ void usart_hardware_flow_cts_config(uint32_t usart_periph, uint32_t ctsconfig) { uint32_t ctl = 0U; ctl = USART_CTL2(usart_periph); ctl &= ~USART_CTL2_CTSEN; ctl |= ctsconfig; /* configure CTS */ USART_CTL2(usart_periph) = ctl; } /*! \brief configure break frame coherence mode \param[in] usart_periph: USARTx(x=0,1,2,5) \param[in] bcm: \arg USART_BCM_NONE: no parity error is detected \arg USART_BCM_EN: parity error is detected \param[out] none \retval none */ void usart_break_frame_coherence_config(uint32_t usart_periph, uint32_t bcm) { USART_CHC(usart_periph) &= ~(USART_CHC_BCM); USART_CHC(usart_periph) |= (USART_CHC_BCM & bcm); } /*! \brief configure parity check coherence mode \param[in] usart_periph: USARTx(x=0,1,2,5)/UARTx(x=3,4,6,7) \param[in] pcm: \arg USART_PCM_NONE: not check parity \arg USART_PCM_EN: check the parity \param[out] none \retval none */ void usart_parity_check_coherence_config(uint32_t usart_periph, uint32_t pcm) { USART_CHC(usart_periph) &= ~(USART_CHC_PCM); USART_CHC(usart_periph) |= (USART_CHC_PCM & pcm); } /*! \brief configure hardware flow control coherence mode \param[in] usart_periph: USARTx(x=0,1,2,5) \param[in] hcm: \arg USART_HCM_NONE: nRTS signal equals to the rxne status register \arg USART_HCM_EN: nRTS signal is set when the last data bit has been sampled \param[out] none \retval none */ void usart_hardware_flow_coherence_config(uint32_t usart_periph, uint32_t hcm) { USART_CHC(usart_periph) &= ~(USART_CHC_HCM); USART_CHC(usart_periph) |= (USART_CHC_HCM & hcm); } /*! \brief configure USART DMA reception \param[in] usart_periph: USARTx(x=0,1,2,5)/UARTx(x=3,4,6,7) \param[in] dmacmd: enable or disable DMA for reception \arg USART_DENR_ENABLE: DMA enable for reception \arg USART_DENR_DISABLE: DMA disable for reception \param[out] none \retval none */ void usart_dma_receive_config(uint32_t usart_periph, uint32_t dmacmd) { uint32_t ctl = 0U; ctl = USART_CTL2(usart_periph); ctl &= ~USART_CTL2_DENR; ctl |= dmacmd; /* configure DMA reception */ USART_CTL2(usart_periph) = ctl; } /*! \brief configure USART DMA transmission \param[in] usart_periph: USARTx(x=0,1,2,5)/UARTx(x=3,4,6,7) \param[in] dmacmd: enable or disable DMA for transmission \arg USART_DENT_ENABLE: DMA enable for transmission \arg USART_DENT_DISABLE: DMA disable for transmission \param[out] none \retval none */ void usart_dma_transmit_config(uint32_t usart_periph, uint32_t dmacmd) { uint32_t ctl = 0U; ctl = USART_CTL2(usart_periph); ctl &= ~USART_CTL2_DENT; ctl |= dmacmd; /* configure DMA transmission */ USART_CTL2(usart_periph) = ctl; } /*! \brief get flag in STAT0/STAT1/CHC register \param[in] usart_periph: USARTx(x=0,1,2,5)/UARTx(x=3,4,6,7) \param[in] flag: USART flags, refer to usart_flag_enum \arg USART_FLAG_CTSF: CTS change flag \arg USART_FLAG_LBDF: LIN break detected flag \arg USART_FLAG_TBE: transmit data buffer empty \arg USART_FLAG_TC: transmission complete \arg USART_FLAG_RBNE: read data buffer not empty \arg USART_FLAG_IDLEF: IDLE frame detected flag \arg USART_FLAG_ORERR: overrun error \arg USART_FLAG_NERR: noise error flag \arg USART_FLAG_FERR: frame error flag \arg USART_FLAG_PERR: parity error flag \arg USART_FLAG_BSY: busy flag \arg USART_FLAG_EBF: end of block flag \arg USART_FLAG_RTF: receiver timeout flag \arg USART_FLAG_EPERR: early parity error flag \param[out] none \retval FlagStatus: SET or RESET */ FlagStatus usart_flag_get(uint32_t usart_periph, usart_flag_enum flag) { if(RESET != (USART_REG_VAL(usart_periph, flag) & BIT(USART_BIT_POS(flag)))){ return SET; }else{ return RESET; } } /*! \brief clear flag in STAT0/STAT1/CHC register \param[in] usart_periph: USARTx(x=0,1,2,5)/UARTx(x=3,4,6,7) \param[in] flag: USART flags, refer to usart_flag_enum \arg USART_FLAG_CTSF: CTS change flag \arg USART_FLAG_LBDF: LIN break detected flag \arg USART_FLAG_TC: transmission complete \arg USART_FLAG_RBNE: read data buffer not empty \arg USART_FLAG_EBF: end of block flag \arg USART_FLAG_RTF: receiver timeout flag \arg USART_FLAG_EPERR: early parity error flag \param[out] none \retval none */ void usart_flag_clear(uint32_t usart_periph, usart_flag_enum flag) { USART_REG_VAL(usart_periph, flag) &= ~BIT(USART_BIT_POS(flag)); } /*! \brief enable USART interrupt \param[in] usart_periph: USARTx(x=0,1,2,5)/UARTx(x=3,4,6,7) \param[in] int_flag \arg USART_INTEN_PERRIE: parity error interrupt \arg USART_INTEN_TBEIE: transmitter buffer empty interrupt \arg USART_INTEN_TCIE: transmission complete interrupt \arg USART_INTEN_RBNEIE: read data buffer not empty interrupt and overrun error interrupt \arg USART_INTEN_IDLEIE: IDLE line detected interrupt \arg USART_INTEN_LBDIE: LIN break detected interrupt \arg USART_INTEN_ERRIE: error interrupt \arg USART_INTEN_CTSIE: CTS interrupt \arg USART_INTEN_RTIE: interrupt enable bit of receive timeout event \arg USART_INTEN_EBIE: interrupt enable bit of end of block event \param[out] none */ void usart_interrupt_enable(uint32_t usart_periph, uint32_t int_flag) { uint32_t usart_reg = 0U; usart_reg = int_flag & (~(uint32_t)USART_INTEN_MASK); int_flag &= USART_INTEN_MASK; /* flags in USART_CTL0 */ if(USART_INTS_CTL0 == usart_reg){ USART_CTL0(usart_periph) |= int_flag; /* flags in USART_CTL1 */ }else if(USART_INTS_CTL1 == usart_reg){ USART_CTL1(usart_periph) |= int_flag; /* flags in USART_CTL2 */ }else if(USART_INTS_CTL2 == usart_reg){ USART_CTL2(usart_periph) |= int_flag; /* flags in USART_CTL3 */ }else if(USART_INTS_CTL3 == usart_reg){ USART_CTL3(usart_periph) |= int_flag; }else{ /* illegal parameters */ } } /*! \brief disable USART interrupt \param[in] usart_periph: USARTx(x=0,1,2,5)/UARTx(x=3,4,6,7) \param[in] int_flag \arg USART_INTEN_PERRIE: parity error interrupt \arg USART_INTEN_TBEIE: transmitter buffer empty interrupt \arg USART_INTEN_TCIE: transmission complete interrupt \arg USART_INTEN_RBNEIE: read data buffer not empty interrupt and overrun error interrupt \arg USART_INTEN_IDLEIE: IDLE line detected interrupt \arg USART_INTEN_LBDIE: LIN break detected interrupt \arg USART_INTEN_ERRIE: error interrupt \arg USART_INTEN_CTSIE: CTS interrupt \arg USART_INTEN_RTIE: interrupt enable bit of receive timeout event \arg USART_INTEN_EBIE: interrupt enable bit of end of block event \param[out] none */ void usart_interrupt_disable(uint32_t usart_periph, uint32_t int_flag) { uint32_t usart_reg = 0U; usart_reg = int_flag & (~(uint32_t)USART_INTEN_MASK); int_flag &= USART_INTEN_MASK; /* flags in USART_CTL0 */ if(USART_INTS_CTL0 == usart_reg){ USART_CTL0(usart_periph) &= ~(int_flag); /* flags in USART_CTL1 */ }else if(USART_INTS_CTL1 == usart_reg){ USART_CTL1(usart_periph) &= ~(int_flag); /* flags in USART_CTL2 */ }else if(USART_INTS_CTL2 == usart_reg){ USART_CTL2(usart_periph) &= ~(int_flag); /* flags in USART_CTL3 */ }else if(USART_INTS_CTL3 == usart_reg){ USART_CTL3(usart_periph) &= ~(int_flag); }else{ /* illegal parameters */ } } /*! \brief get USART interrupt enable flag \param[in] usart_periph: USARTx(x=0,1,2,5)/UARTx(x=3,4,6,7) \param[in] int_flag \arg USART_INT_PERRIE: parity error interrupt \arg USART_INT_TBEIE: transmitter buffer empty interrupt \arg USART_INT_TCIE: transmission complete interrupt \arg USART_INT_RBNEIE: read data buffer not empty interrupt and overrun error interrupt \arg USART_INT_IDLEIE: IDLE line detected interrupt \arg USART_INT_LBDIE: LIN break detected interrupt \arg USART_INT_CTSIE: CTS interrupt \arg USART_INT_ERRIE: error interrupt \arg USART_INT_EBIE: interrupt enable bit of end of block event \arg USART_INT_RTIE: interrupt enable bit of receive timeout event \param[out] none \retval FlagStatus */ FlagStatus usart_interrupt_flag_get(uint32_t usart_periph, uint32_t int_flag) { if(RESET != (USART_REG_VAL(usart_periph, int_flag) & BIT(USART_BIT_POS(int_flag)))){ return SET; }else{ return RESET; } }