/*! \file gd32f30x_adc.c \brief ADC driver */ /* Copyright (C) 2017 GigaDevice 2017-02-10, V1.0.2, firmware for GD32F30x */ #include "gd32f30x_adc.h" /*! \brief reset ADC \param[in] adc_periph: ADCx,x=0,1,2 only one among these parameters can be selected \param[out] none \retval none */ void adc_deinit(uint32_t adc_periph) { switch(adc_periph){ case ADC0: rcu_periph_reset_enable(RCU_ADC0RST); rcu_periph_reset_disable(RCU_ADC0RST); break; case ADC1: rcu_periph_reset_enable(RCU_ADC1RST); rcu_periph_reset_disable(RCU_ADC1RST); break; #if (defined(GD32F30X_HD) || defined(GD32F30X_XD)) case ADC2: rcu_periph_reset_enable(RCU_ADC2RST); rcu_periph_reset_disable(RCU_ADC2RST); break; #endif default: break; } } /*! \brief enable ADC interface \param[in] adc_periph: ADCx,x=0,1,2 only one among these parameters can be selected \param[out] none \retval none */ void adc_enable(uint32_t adc_periph) { if(RESET == (ADC_CTL1(adc_periph) & ADC_CTL1_ADCON)){ ADC_CTL1(adc_periph) |= (uint32_t)ADC_CTL1_ADCON; } } /*! \brief disable ADC interface \param[in] adc_periph: ADCx,x=0,1,2 only one among these parameters can be selected \param[out] none \retval none */ void adc_disable(uint32_t adc_periph) { ADC_CTL1(adc_periph) &= ~((uint32_t)ADC_CTL1_ADCON); } /*! \brief ADC calibration and reset calibration \param[in] adc_periph: ADCx,x=0,1,2 only one among these parameters can be selected \param[out] none \retval none */ void adc_calibration_enable(uint32_t adc_periph) { /* reset the selected ADC1 calibration registers */ ADC_CTL1(adc_periph) |= (uint32_t) ADC_CTL1_RSTCLB; /* check the RSTCLB bit state */ while((ADC_CTL1(adc_periph) & ADC_CTL1_RSTCLB)){ } /* enable ADC calibration process */ ADC_CTL1(adc_periph) |= ADC_CTL1_CLB; /* check the CLB bit state */ while((ADC_CTL1(adc_periph) & ADC_CTL1_CLB)){ } } /*! \brief enable DMA request \param[in] adc_periph: ADCx,x=0,1,2 only one among these parameters can be selected \param[out] none \retval none */ void adc_dma_mode_enable(uint32_t adc_periph) { ADC_CTL1(adc_periph) |= (uint32_t)(ADC_CTL1_DMA); } /*! \brief disable DMA request \param[in] adc_periph: ADCx,x=0,1,2 only one among these parameters can be selected \param[out] none \retval none */ void adc_dma_mode_disable(uint32_t adc_periph) { ADC_CTL1(adc_periph) &= ~((uint32_t)ADC_CTL1_DMA); } /*! \brief enable the temperature sensor and Vrefint channel \param[in] none \param[out] none \retval none */ void adc_tempsensor_vrefint_enable(void) { /* enable the temperature sensor and Vrefint channel */ ADC_CTL1(ADC0) |= ADC_CTL1_TSVREN; } /*! \brief disable the temperature sensor and Vrefint channel \param[in] none \param[out] none \retval none */ void adc_tempsensor_vrefint_disable(void) { /* disable the temperature sensor and Vrefint channel */ ADC_CTL1(ADC0) &= ~ADC_CTL1_TSVREN; } /*! \brief configure ADC resolution \param[in] adc_periph: ADCx,x=0,1,2 only one among these parameters can be selected \param[in] resolution: ADC resolution only one among these parameters can be selected \arg ADC_RESOLUTION_12B: 12-bit ADC resolution \arg ADC_RESOLUTION_10B: 10-bit ADC resolution \arg ADC_RESOLUTION_8B: 8-bit ADC resolution \arg ADC_RESOLUTION_6B: 6-bit ADC resolution \param[out] none \retval none */ void adc_resolution_config(uint32_t adc_periph , uint32_t resolution) { ADC_OVSAMPCTL(adc_periph) &= ~((uint32_t)ADC_OVSAMPCTL_DRES); ADC_OVSAMPCTL(adc_periph) |= (uint32_t)resolution; } /*! \brief configure ADC discontinuous mode \param[in] adc_periph: ADCx,x=0,1,2 only one among these parameters can be selected \param[in] adc_channel_group: select the channel group only one among these parameters can be selected \arg ADC_REGULAR_CHANNEL: regular channel group \arg ADC_INSERTED_CHANNEL: inserted channel group \arg ADC_CHANNEL_DISCON_DISABLE: disable discontinuous mode of regular & inserted channel \param[in] length: number of conversions in discontinuous mode,the number can be 1..8 for regular channel ,the number has no effect for inserted channel \param[out] none \retval none */ void adc_discontinuous_mode_config(uint32_t adc_periph, uint8_t adc_channel_group, uint8_t length) { ADC_CTL0(adc_periph) &= ~((uint32_t)( ADC_CTL0_DISRC | ADC_CTL0_DISIC )); switch(adc_channel_group){ case ADC_REGULAR_CHANNEL: /* config the number of conversions in discontinuous mode */ ADC_CTL0(adc_periph) &= ~((uint32_t)ADC_CTL0_DISNUM); ADC_CTL0(adc_periph) |= CTL0_DISNUM(((uint32_t)length - 1U)); ADC_CTL0(adc_periph) |= (uint32_t)ADC_CTL0_DISRC; break; case ADC_INSERTED_CHANNEL: ADC_CTL0(adc_periph) |= (uint32_t)ADC_CTL0_DISIC; break; case ADC_CHANNEL_DISCON_DISABLE: default: break; } } /*! \brief configure the ADC sync mode \param[in] mode: ADC mode only one among these parameters can be selected \arg ADC_MODE_FREE: all the ADCs work independently \arg ADC_DAUL_REGULAL_PARALLEL_INSERTED_PARALLEL: ADC0 and ADC1 work in combined regular parallel + inserted parallel mode \arg ADC_DAUL_REGULAL_PARALLEL_INSERTED_ROTATION: ADC0 and ADC1 work in combined regular parallel + trigger rotation mode \arg ADC_DAUL_INSERTED_PARALLEL_REGULAL_FOLLOWUP_FAST: ADC0 and ADC1 work in combined inserted parallel + follow-up fast mode \arg ADC_DAUL_INSERTED_PARALLEL_REGULAL_FOLLOWUP_SLOW: ADC0 and ADC1 work in combined inserted parallel + follow-up slow mode \arg ADC_DAUL_INSERTED_PARALLEL: ADC0 and ADC1 work in inserted parallel mode only \arg ADC_DAUL_REGULAL_PARALLEL: ADC0 and ADC1 work in regular parallel mode only \arg ADC_DAUL_REGULAL_FOLLOWUP_FAST: ADC0 and ADC1 work in follow-up fast mode only \arg ADC_DAUL_REGULAL_FOLLOWUP_SLOW: ADC0 and ADC1 work in follow-up slow mode only \arg ADC_DAUL_INSERTED_TRRIGGER_ROTATION: ADC0 and ADC1 work in trigger rotation mode only \param[out] none \retval none */ void adc_mode_config(uint32_t mode) { ADC_CTL0(ADC0) &= ~(ADC_CTL0_SYNCM); ADC_CTL0(ADC0) |= mode; } /*! \brief enable or disable ADC special function \param[in] adc_periph: ADCx,x=0,1,2 only one among these parameters can be selected \param[in] function: the function to config one or more parameters can be selected below \arg ADC_SCAN_MODE: scan mode select \arg ADC_INSERTED_CHANNEL_AUTO: inserted channel group convert automatically \arg ADC_CONTINUOUS_MODE: continuous mode select \param[in] newvalue: ENABLE or DISABLE \param[out] none \retval none */ void adc_special_function_config(uint32_t adc_periph , uint32_t function , ControlStatus newvalue) { if(newvalue){ if(0U != (function & ADC_SCAN_MODE)){ ADC_CTL0(adc_periph) |= ADC_SCAN_MODE; } if(0U != (function & ADC_INSERTED_CHANNEL_AUTO)){ ADC_CTL0(adc_periph) |= ADC_INSERTED_CHANNEL_AUTO; } if(0U != (function & ADC_CONTINUOUS_MODE)){ ADC_CTL1(adc_periph) |= ADC_CONTINUOUS_MODE; } }else{ if(0U != (function & ADC_SCAN_MODE)){ ADC_CTL0(adc_periph) &= ~ADC_SCAN_MODE; } if(0U != (function & ADC_INSERTED_CHANNEL_AUTO)){ ADC_CTL0(adc_periph) &= ~ADC_INSERTED_CHANNEL_AUTO; } if(0U != (function & ADC_CONTINUOUS_MODE)){ ADC_CTL1(adc_periph) &= ~ADC_CONTINUOUS_MODE; } } } /*! \brief configure ADC data alignment \param[in] adc_periph: ADCx,x=0,1,2 only one among these parameters can be selected \param[in] data_alignment: data alignment select only one parameter can be selected \arg ADC_DATAALIGN_RIGHT: LSB alignment \arg ADC_DATAALIGN_LEFT: MSB alignment \param[out] none \retval none */ void adc_data_alignment_config(uint32_t adc_periph , uint32_t data_alignment) { if(ADC_DATAALIGN_RIGHT != data_alignment){ ADC_CTL1(adc_periph) |= ADC_CTL1_DAL; }else{ ADC_CTL1(adc_periph) &= ~((uint32_t)ADC_CTL1_DAL); } } /*! \brief configure the length of regular channel group or inserted channel group \param[in] adc_periph: ADCx,x=0,1,2 only one among these parameters can be selected \param[in] adc_channel_group: select the channel group only one parameter can be selected \arg ADC_REGULAR_CHANNEL: regular channel group \arg ADC_INSERTED_CHANNEL: inserted channel group \param[in] length: the length of the channel regular channel 1-16 inserted channel 1-4 \param[out] none \retval none */ void adc_channel_length_config(uint32_t adc_periph, uint8_t adc_channel_group, uint32_t length) { switch(adc_channel_group){ case ADC_REGULAR_CHANNEL: ADC_RSQ0(adc_periph) &= ~((uint32_t)ADC_RSQ0_RL); ADC_RSQ0(adc_periph) |= RSQ0_RL((uint32_t)(length-1U)); break; case ADC_INSERTED_CHANNEL: ADC_ISQ(adc_periph) &= ~((uint32_t)ADC_ISQ_IL); ADC_ISQ(adc_periph) |= ISQ_IL((uint32_t)(length-1U)); break; default: break; } } /*! \brief configure ADC regular channel \param[in] adc_periph: ADCx,x=0,1,2 only one among these parameters can be selected \param[in] rank: the regular group sequence rank,this parameter must be between 0 to 15 \param[in] adc_channel: the selected ADC channel only one among these parameters can be selected \arg ADC_CHANNEL_x(x=0..17)(x=16 and x=17 are only for ADC0): ADC Channelx \param[in] sample_time: the sample time value only one parameter can be selected \arg ADC_SAMPLETIME_1POINT5: 1.5 cycles \arg ADC_SAMPLETIME_7POINT5: 7.5 cycles \arg ADC_SAMPLETIME_13POINT5: 13.5 cycles \arg ADC_SAMPLETIME_28POINT5: 28.5 cycles \arg ADC_SAMPLETIME_41POINT5: 41.5 cycles \arg ADC_SAMPLETIME_55POINT5: 55.5 cycles \arg ADC_SAMPLETIME_71POINT5: 71.5 cycles \arg ADC_SAMPLETIME_239POINT5: 239.5 cycles \param[out] none \retval none */ void adc_regular_channel_config(uint32_t adc_periph , uint8_t rank , uint8_t adc_channel , uint32_t sample_time) { uint32_t rsq,sampt; /* ADC regular sequence config */ if(rank < 6U){ rsq = ADC_RSQ2(adc_periph); rsq &= ~((uint32_t)(ADC_RSQX_RSQN << (5U*rank))); rsq |= ((uint32_t)adc_channel << (5U*rank)); ADC_RSQ2(adc_periph) = rsq; }else if(rank < 12U){ rsq = ADC_RSQ1(adc_periph); rsq &= ~((uint32_t)(ADC_RSQX_RSQN << (5U*(rank-6U)))); rsq |= ((uint32_t)adc_channel << (5U*(rank-6U))); ADC_RSQ1(adc_periph) = rsq; }else if(rank < 16U){ rsq = ADC_RSQ0(adc_periph); rsq &= ~((uint32_t)(ADC_RSQX_RSQN << (5U*(rank-12U)))); rsq |= ((uint32_t)adc_channel << (5U*(rank-12U))); ADC_RSQ0(adc_periph) = rsq; }else{ } /* ADC sampling time config */ if(adc_channel < 10U){ sampt = ADC_SAMPT1(adc_periph); sampt &= ~((uint32_t)(ADC_SAMPTX_SPTN << (3U*adc_channel))); sampt |= (uint32_t)(sample_time << (3U*adc_channel)); ADC_SAMPT1(adc_periph) = sampt; }else if(adc_channel < 18U){ sampt = ADC_SAMPT0(adc_periph); sampt &= ~((uint32_t)(ADC_SAMPTX_SPTN << (3U*(adc_channel-10U)))); sampt |= (uint32_t)(sample_time << (3U*(adc_channel-10U))); ADC_SAMPT0(adc_periph) = sampt; }else{ } } /*! \brief configure ADC inserted channel \param[in] adc_periph: ADCx,x=0,1,2 only one among these parameters can be selected \param[in] rank: the inserted group sequencer rank,this parameter must be between 0 to 3 \param[in] adc_channel: the selected ADC channel only one among these parameters can be selected \arg ADC_CHANNEL_x(x=0..17)(x=16 and x=17 are only for ADC0): ADC Channelx \param[in] sample_time: The sample time value only one parameter can be selected \arg ADC_SAMPLETIME_1POINT5: 1.5 cycles \arg ADC_SAMPLETIME_7POINT5: 7.5 cycles \arg ADC_SAMPLETIME_13POINT5: 13.5 cycles \arg ADC_SAMPLETIME_28POINT5: 28.5 cycles \arg ADC_SAMPLETIME_41POINT5: 41.5 cycles \arg ADC_SAMPLETIME_55POINT5: 55.5 cycles \arg ADC_SAMPLETIME_71POINT5: 71.5 cycles \arg ADC_SAMPLETIME_239POINT5: 239.5 cycles \param[out] none \retval none */ void adc_inserted_channel_config(uint32_t adc_periph , uint8_t rank , uint8_t adc_channel , uint32_t sample_time) { uint8_t inserted_length; uint32_t isq,sampt; inserted_length = (uint8_t)GET_BITS(ADC_ISQ(adc_periph) , 20U , 21U); isq = ADC_ISQ(adc_periph); isq &= ~((uint32_t)(ADC_ISQ_ISQN << (15U-(inserted_length-rank)*5U))); isq |= ((uint32_t)adc_channel << (15U-(inserted_length-rank)*5U)); ADC_ISQ(adc_periph) = isq; /* ADC sampling time config */ if(adc_channel < 10U){ sampt = ADC_SAMPT1(adc_periph); sampt &= ~((uint32_t)(ADC_SAMPTX_SPTN << (3U*adc_channel))); sampt |= (uint32_t) sample_time << (3U*adc_channel); ADC_SAMPT1(adc_periph) = sampt; }else if(adc_channel < 18U){ sampt = ADC_SAMPT0(adc_periph); sampt &= ~((uint32_t)(ADC_SAMPTX_SPTN << (3U*(adc_channel-10U)))); sampt |= ((uint32_t)sample_time << (3U*(adc_channel-10U))); ADC_SAMPT0(adc_periph) = sampt; }else{ } } /*! \brief configure ADC inserted channel offset \param[in] adc_periph: ADCx,x=0,1,2 only one among these parameters can be selected \param[in] inserted_channel : insert channel select only one parameter can be selected \arg ADC_INSERTED_CHANNEL_0: inserted channel0 \arg ADC_INSERTED_CHANNEL_1: inserted channel1 \arg ADC_INSERTED_CHANNEL_2: inserted channel2 \arg ADC_INSERTED_CHANNEL_3: inserted channel3 \param[in] offset : the offset data \param[out] none \retval none */ void adc_inserted_channel_offset_config(uint32_t adc_periph , uint8_t inserted_channel , uint16_t offset) { uint8_t inserted_length; uint32_t num = 0U; inserted_length = (uint8_t)GET_BITS(ADC_ISQ(adc_periph) , 20U , 21U); num = 3U - (inserted_length - inserted_channel); if(num <= 3U){ /* calculate the offset of the register */ num = num * 4U; /* config the offset of the selected channels */ REG32((adc_periph) + 0x14U + num) = IOFFX_IOFF((uint32_t)offset); } } /*! \brief enable ADC external trigger \param[in] adc_periph: ADCx,x=0,1,2 only one among these parameters can be selected \param[in] adc_channel_group: select the channel group one or more parameters can be selected \arg ADC_REGULAR_CHANNEL: regular channel group \arg ADC_INSERTED_CHANNEL: inserted channel group \param[in] newvalue: ENABLE or DISABLE \param[out] none \retval none */ void adc_external_trigger_config(uint32_t adc_periph, uint8_t adc_channel_group, ControlStatus newvalue) { if(newvalue){ if(0U != (adc_channel_group & ADC_REGULAR_CHANNEL)){ ADC_CTL1(adc_periph) |= ADC_CTL1_ETERC; } if(0U != (adc_channel_group & ADC_INSERTED_CHANNEL)){ ADC_CTL1(adc_periph) |= ADC_CTL1_ETEIC; } }else{ if(0U != (adc_channel_group & ADC_REGULAR_CHANNEL)){ ADC_CTL1(adc_periph) &= ~ADC_CTL1_ETERC; } if(0U != (adc_channel_group & ADC_INSERTED_CHANNEL)){ ADC_CTL1(adc_periph) &= ~ADC_CTL1_ETEIC; } } } /*! \brief configure ADC external trigger source \param[in] adc_periph: ADCx,x=0,1,2 only one among these parameters can be selected \param[in] adc_channel_group: select the channel group only one parameter can be selected \arg ADC_REGULAR_CHANNEL: regular channel group \arg ADC_INSERTED_CHANNEL: inserted channel group \param[in] external_trigger_source: regular or inserted group trigger source only one parameter can be selected for regular channel: \arg ADC0_1_EXTTRIG_REGULAR_T0_CH0: timer 0 CC0 event select \arg ADC0_1_EXTTRIG_REGULAR_T0_CH1: timer 0 CC1 event select \arg ADC0_1_EXTTRIG_REGULAR_T0_CH2: timer 0 CC2 event select \arg ADC0_1_EXTTRIG_REGULAR_T1_CH1: timer 1 CC1 event select \arg ADC0_1_EXTTRIG_REGULAR_T2_TRGO: timer 2 TRGO event select \arg ADC0_1_EXTTRIG_REGULAR_T3_CH3: timer 3 CC3 event select \arg ADC0_1_EXTTRIG_REGULAR_T7_TRGO: timer 7 TRGO event select \arg ADC0_1_EXTTRIG_REGULAR_EXTI_11 : external interrupt line 11 \arg ADC2_EXTTRIG_REGULAR_T2_CH0: timer 2 CC0 event select \arg ADC2_EXTTRIG_REGULAR_T1_CH2: timer 1 CC2 event select \arg ADC2_EXTTRIG_REGULAR_T0_CH2: timer 0 CC2 event select \arg ADC2_EXTTRIG_REGULAR_T7_CH0: timer 7 CC0 event select \arg ADC2_EXTTRIG_REGULAR_T7_TRGO: timer 7 TRGO event select \arg ADC2_EXTTRIG_REGULAR_T4_CH0: timer 4 CC0 event select \arg ADC2_EXTTRIG_REGULAR_T4_CH2: timer 4 CC2 event select \arg ADC0_1_2_EXTTRIG_REGULAR_NONE: software trigger for inserted channel: \arg ADC0_1_EXTTRIG_INSERTED_T0_TRGO: timer 0 TRGO event select \arg ADC0_1_EXTTRIG_INSERTED_T0_CH3: timer 0 CC3 event select \arg ADC0_1_EXTTRIG_INSERTED_T1_TRGO: timer 1 TRGO event select \arg ADC0_1_EXTTRIG_INSERTED_T1_CH0: timer 1 CC0 event select \arg ADC0_1_EXTTRIG_INSERTED_T2_CH3: timer 2 CC3 event select \arg ADC0_1_EXTTRIG_INSERTED_T3_TRGO: timer 3 TRGO event select \arg ADC0_1_EXTTRIG_INSERTED_EXTI_15: external interrupt line 15 \arg ADC0_1_EXTTRIG_INSERTED_T7_CH3: timer 7 CC3 event select \arg ADC2_EXTTRIG_INSERTED_T0_TRGO: timer 0 TRGO event select \arg ADC2_EXTTRIG_INSERTED_T0_CH3: timer 0 CC3 event select \arg ADC2_EXTTRIG_INSERTED_T3_CH2: timer 3 CC2 event select \arg ADC2_EXTTRIG_INSERTED_T7_CH1: timer 7 CC1 event select \arg ADC2_EXTTRIG_INSERTED_T7_CH3: timer 7 CC3 event select \arg ADC2_EXTTRIG_INSERTED_T4_TRGO: timer 4 TRGO event select \arg ADC2_EXTTRIG_INSERTED_T4_CH3: timer 4 CC3 event select \arg ADC0_1_2_EXTTRIG_INSERTED_NONE: software trigger \param[out] none \retval none */ void adc_external_trigger_source_config(uint32_t adc_periph, uint8_t adc_channel_group, uint32_t external_trigger_source) { switch(adc_channel_group){ case ADC_REGULAR_CHANNEL: ADC_CTL1(adc_periph) &= ~((uint32_t)ADC_CTL1_ETSRC); ADC_CTL1(adc_periph) |= (uint32_t)external_trigger_source; break; case ADC_INSERTED_CHANNEL: ADC_CTL1(adc_periph) &= ~((uint32_t)ADC_CTL1_ETSIC); ADC_CTL1(adc_periph) |= (uint32_t)external_trigger_source; break; default: break; } } /*! \brief enable ADC software trigger \param[in] adc_periph: ADCx,x=0,1,2 only one among these parameters can be selected \param[in] adc_channel_group: select the channel group one or more parameters can be selected \arg ADC_REGULAR_CHANNEL: regular channel group \arg ADC_INSERTED_CHANNEL: inserted channel group \param[out] none \retval none */ void adc_software_trigger_enable(uint32_t adc_periph , uint8_t adc_channel_group) { if(0U != (adc_channel_group & ADC_REGULAR_CHANNEL)){ ADC_CTL1(adc_periph) |= ADC_CTL1_SWRCST; } if(0U != (adc_channel_group & ADC_INSERTED_CHANNEL)){ ADC_CTL1(adc_periph) |= ADC_CTL1_SWICST; } } /*! \brief read ADC regular group data register \param[in] adc_periph: ADCx,x=0,1,2 only one among these parameters can be selected \param[in] none \param[out] none \retval the conversion value */ uint16_t adc_regular_data_read(uint32_t adc_periph) { return (uint16_t)(ADC_RDATA(adc_periph)); } /*! \brief read ADC inserted group data register \param[in] adc_periph: ADCx,x=0,1,2 only one among these parameters can be selected \param[in] inserted_channel : insert channel select only one parameter can be selected \arg ADC_INSERTED_CHANNEL_0: inserted Channel0 \arg ADC_INSERTED_CHANNEL_1: inserted channel1 \arg ADC_INSERTED_CHANNEL_2: inserted Channel2 \arg ADC_INSERTED_CHANNEL_3: inserted Channel3 \param[out] none \retval the conversion value */ uint16_t adc_inserted_data_read(uint32_t adc_periph , uint8_t inserted_channel) { uint32_t idata; /* read the data of the selected channel */ switch(inserted_channel){ case ADC_INSERTED_CHANNEL_0: idata = ADC_IDATA0(adc_periph); break; case ADC_INSERTED_CHANNEL_1: idata = ADC_IDATA1(adc_periph); break; case ADC_INSERTED_CHANNEL_2: idata = ADC_IDATA2(adc_periph); break; case ADC_INSERTED_CHANNEL_3: idata = ADC_IDATA3(adc_periph); break; default: idata = 0U; break; } return (uint16_t)idata; } /*! \brief read the last ADC0 and ADC1 conversion result data in sync mode \param[in] none \param[out] none \retval the conversion value */ uint32_t adc_sync_mode_convert_value_read(void) { /* return conversion value */ return ADC_RDATA(ADC0); } /*! \brief get the ADC flag bits \param[in] adc_periph: ADCx,x=0,1,2 only one among these parameters can be selected \param[in] adc_flag: the adc flag bits only one parameter can be selected \arg ADC_FLAG_WDE: analog watchdog event flag \arg ADC_FLAG_EOC: end of group conversion flag \arg ADC_FLAG_EOIC: end of inserted group conversion flag \arg ADC_FLAG_STIC: start flag of inserted channel group \arg ADC_FLAG_STRC: start flag of regular channel group \param[out] none \retval FlagStatus: SET or RESET */ FlagStatus adc_flag_get(uint32_t adc_periph , uint32_t adc_flag) { FlagStatus reval = RESET; if(ADC_STAT(adc_periph) & adc_flag){ reval = SET; } return reval; } /*! \brief clear the ADC flag bits \param[in] adc_periph: ADCx,x=0,1,2 only one among these parameters can be selected \param[in] adc_flag: the adc flag bits one or more parameters can be selected \arg ADC_FLAG_WDE: analog watchdog event flag \arg ADC_FLAG_EOC: end of group conversion flag \arg ADC_FLAG_EOIC: end of inserted group conversion flag \arg ADC_FLAG_STIC: start flag of inserted channel group \arg ADC_FLAG_STRC: start flag of regular channel group \param[out] none \retval none */ void adc_flag_clear(uint32_t adc_periph , uint32_t adc_flag) { ADC_STAT(adc_periph) &= ~((uint32_t)adc_flag); } /*! \brief get the ADC interrupt bits \param[in] adc_periph: ADCx,x=0,1,2 only one among these parameters can be selected \param[in] adc_interrupt: the adc interrupt bits only oneparameter can be selected \arg ADC_INT_FLAG_WDE: analog watchdog interrupt \arg ADC_INT_FLAG_EOC: end of group conversion interrupt \arg ADC_INT_FLAG_EOIC: end of inserted group conversion interrupt \param[out] none \retval FlagStatus: SET or RESET */ FlagStatus adc_interrupt_flag_get(uint32_t adc_periph , uint32_t adc_interrupt) { FlagStatus interrupt_flag = RESET; uint32_t state; /* check the interrupt bits */ switch(adc_interrupt){ case ADC_INT_FLAG_WDE: state = ADC_STAT(adc_periph) & ADC_STAT_WDE; if((ADC_CTL0(adc_periph) & ADC_CTL0_WDEIE) && state){ interrupt_flag = SET; } break; case ADC_INT_FLAG_EOC: state = ADC_STAT(adc_periph) & ADC_STAT_EOC; if((ADC_CTL0(adc_periph) & ADC_CTL0_EOCIE) && state){ interrupt_flag = SET; } break; case ADC_INT_FLAG_EOIC: state = ADC_STAT(adc_periph) & ADC_STAT_EOIC; if((ADC_CTL0(adc_periph) & ADC_CTL0_EOICIE) && state){ interrupt_flag = SET; } break; default: break; } return interrupt_flag; } /*! \brief clear the ADC flag \param[in] adc_periph: ADCx,x=0,1,2 only one among these parameters can be selected \param[in] adc_interrupt: the adc status flag one or more parameters can be selected \arg ADC_INT_FLAG_WDE: analog watchdog interrupt \arg ADC_INT_FLAG_EOC: end of group conversion interrupt \arg ADC_INT_FLAG_EOIC: end of inserted group conversion interrupt \param[out] none \retval none */ void adc_interrupt_flag_clear(uint32_t adc_periph , uint32_t adc_interrupt) { ADC_STAT(adc_periph) &= ~((uint32_t)adc_interrupt); } /*! \brief enable ADC interrupt \param[in] adc_periph: ADCx,x=0,1,2 only one among these parameters can be selected \param[in] adc_interrupt: the adc interrupt one or more parameters can be selected \arg ADC_INT_WDE: analog watchdog interrupt flag \arg ADC_INT_EOC: end of group conversion interrupt flag \arg ADC_INT_EOIC: end of inserted group conversion interrupt flag \param[out] none \retval none */ void adc_interrupt_enable(uint32_t adc_periph , uint32_t adc_interrupt) { if(0U != (adc_interrupt & ADC_INT_WDE)){ ADC_CTL0(adc_periph) |= (uint32_t) ADC_CTL0_WDEIE; } if(0U != (adc_interrupt & ADC_INT_EOC)){ ADC_CTL0(adc_periph) |= (uint32_t) ADC_CTL0_EOCIE; } if(0U != (adc_interrupt & ADC_INT_EOIC)){ ADC_CTL0(adc_periph) |= (uint32_t) ADC_CTL0_EOICIE; } } /*! \brief disable ADC interrupt \param[in] adc_periph: ADCx,x=0,1,2 only one among these parameters can be selected \param[in] adc_interrupt: the adc interrupt flag one or more parameters can be selected \arg ADC_INT_WDE: analog watchdog interrupt flag \arg ADC_INT_EOC: end of group conversion interrupt flag \arg ADC_INT_EOIC: end of inserted group conversion interrupt flag \param[out] none \retval none */ void adc_interrupt_disable(uint32_t adc_periph, uint32_t adc_interrupt) { if(0U != (adc_interrupt & ADC_INT_WDE)){ ADC_CTL0(adc_periph) &= ~(uint32_t) ADC_CTL0_WDEIE; } if(0U != (adc_interrupt & ADC_INT_EOC)){ ADC_CTL0(adc_periph) &= ~(uint32_t) ADC_CTL0_EOCIE; } if(0U != (adc_interrupt & ADC_INT_EOIC)){ ADC_CTL0(adc_periph) &= ~(uint32_t) ADC_CTL0_EOICIE; } } /*! \brief configure ADC analog watchdog single channel \param[in] adc_periph: ADCx,x=0,1,2 only one among these parameters can be selected \param[in] adc_channel: the selected ADC channel only one among these parameters can be selected \arg ADC_CHANNEL_x: ADC Channelx(x=0..17)(x=16 and x=17 are only for ADC0) \param[out] none \retval none */ void adc_watchdog_single_channel_enable(uint32_t adc_periph, uint8_t adc_channel) { ADC_CTL0(adc_periph) &= (uint32_t)~(ADC_CTL0_RWDEN | ADC_CTL0_IWDEN | ADC_CTL0_WDSC | ADC_CTL0_WDCHSEL); ADC_CTL0(adc_periph) |= (uint32_t)adc_channel; ADC_CTL0(adc_periph) |= (uint32_t)(ADC_CTL0_RWDEN | ADC_CTL0_IWDEN | ADC_CTL0_WDSC); } /*! \brief configure ADC analog watchdog group channel \param[in] adc_periph: ADCx,x=0,1,2 only one among these parameters can be selected \param[in] adc_channel_group: the channel group use analog watchdog only one parameter can be selected \arg ADC_REGULAR_CHANNEL: regular channel group \arg ADC_INSERTED_CHANNEL: inserted channel group \arg ADC_REGULAR_INSERTED_CHANNEL: both regular and inserted group \param[out] none \retval none */ void adc_watchdog_group_channel_enable(uint32_t adc_periph, uint8_t adc_channel_group) { ADC_CTL0(adc_periph) &= (uint32_t)~(ADC_CTL0_RWDEN | ADC_CTL0_IWDEN | ADC_CTL0_WDSC); /* select the group */ switch(adc_channel_group){ case ADC_REGULAR_CHANNEL: ADC_CTL0(adc_periph) |= (uint32_t) ADC_CTL0_RWDEN; break; case ADC_INSERTED_CHANNEL: ADC_CTL0(adc_periph) |= (uint32_t) ADC_CTL0_IWDEN; break; case ADC_REGULAR_INSERTED_CHANNEL: ADC_CTL0(adc_periph) |= (uint32_t)(ADC_CTL0_RWDEN | ADC_CTL0_IWDEN); break; default: break; } } /*! \brief disable ADC analog watchdog \param[in] adc_periph: ADCx,x=0,1,2 only one among these parameters can be selected \param[out] none \retval none */ void adc_watchdog_disable(uint32_t adc_periph) { ADC_CTL0(adc_periph) &= (uint32_t)~(ADC_CTL0_RWDEN | ADC_CTL0_IWDEN | ADC_CTL0_WDSC | ADC_CTL0_WDCHSEL); } /*! \brief configure ADC analog watchdog threshold \param[in] adc_periph: ADCx,x=0,1,2 only one among these parameters can be selected \param[in] low_threshold: analog watchdog low threshold,0..4095 \param[in] high_threshold: analog watchdog high threshold,0..4095 \param[out] none \retval none */ void adc_watchdog_threshold_config(uint32_t adc_periph , uint16_t low_threshold , uint16_t high_threshold) { ADC_WDLT(adc_periph) = (uint32_t)WDLT_WDLT(low_threshold); ADC_WDHT(adc_periph) = (uint32_t)WDHT_WDHT(high_threshold); } /*! \brief configure ADC oversample mode \param[in] adc_periph: ADCx,x=0,1,2 only one among these parameters can be selected \param[in] mode: ADC oversampling mode only oneparameter can be selected \arg ADC_OVERSAMPLING_ALL_CONVERT: all oversampled conversions for a channel are done consecutively after a trigger \arg ADC_OVERSAMPLING_ONE_CONVERT: each oversampled conversion for a channel needs a trigger \param[in] shift: ADC oversampling shift only oneparameter can be selected \arg ADC_OVERSAMPLING_SHIFT_NONE: no oversampling shift \arg ADC_OVERSAMPLING_SHIFT_1B: 1-bit oversampling shift \arg ADC_OVERSAMPLING_SHIFT_2B: 2-bit oversampling shift \arg ADC_OVERSAMPLING_SHIFT_3B: 3-bit oversampling shift \arg ADC_OVERSAMPLING_SHIFT_4B: 3-bit oversampling shift \arg ADC_OVERSAMPLING_SHIFT_5B: 5-bit oversampling shift \arg ADC_OVERSAMPLING_SHIFT_6B: 6-bit oversampling shift \arg ADC_OVERSAMPLING_SHIFT_7B: 7-bit oversampling shift \arg ADC_OVERSAMPLING_SHIFT_8B: 8-bit oversampling shift \param[in] ratio: ADC oversampling ratio only oneparameter can be selected \arg ADC_OVERSAMPLING_RATIO_MUL2: oversampling ratio multiple 2 \arg ADC_OVERSAMPLING_RATIO_MUL4: oversampling ratio multiple 4 \arg ADC_OVERSAMPLING_RATIO_MUL8: oversampling ratio multiple 8 \arg ADC_OVERSAMPLING_RATIO_MUL16: oversampling ratio multiple 16 \arg ADC_OVERSAMPLING_RATIO_MUL32: oversampling ratio multiple 32 \arg ADC_OVERSAMPLING_RATIO_MUL64: oversampling ratio multiple 64 \arg ADC_OVERSAMPLING_RATIO_MUL128: oversampling ratio multiple 128 \arg ADC_OVERSAMPLING_RATIO_MUL256: oversampling ratio multiple 256 \param[out] none \retval none */ void adc_oversample_mode_config(uint32_t adc_periph, uint8_t mode, uint16_t shift, uint8_t ratio) { if(ADC_OVERSAMPLING_ONE_CONVERT == mode){ ADC_OVSAMPCTL(adc_periph) |= (uint32_t)ADC_OVSAMPCTL_TOVS; }else{ ADC_OVSAMPCTL(adc_periph) &= ~((uint32_t)ADC_OVSAMPCTL_TOVS); } /* config the shift and ratio */ ADC_OVSAMPCTL(adc_periph) &= ~((uint32_t)(ADC_OVSAMPCTL_OVSR | ADC_OVSAMPCTL_OVSS)); ADC_OVSAMPCTL(adc_periph) |= ((uint32_t)shift | (uint32_t)ratio); } /*! \brief enable ADC oversample mode \param[in] adc_periph: ADCx,x=0,1,2 only one among these parameters can be selected \param[out] none \retval none */ void adc_oversample_mode_enable(uint32_t adc_periph) { ADC_OVSAMPCTL(adc_periph) |= ADC_OVSAMPCTL_OVSEN; } /*! \brief disable ADC oversample mode \param[in] adc_periph: ADCx,x=0,1,2 only one among these parameters can be selected \param[out] none \retval none */ void adc_oversample_mode_disable(uint32_t adc_periph) { ADC_OVSAMPCTL(adc_periph) &= ~((uint32_t)ADC_OVSAMPCTL_OVSEN); }