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targets/hal/TARGET_Atmel/TARGET_SAM21/drivers/adc/adc_sam_d_r/adc.c
- Committer:
- mbed_official
- Date:
- 2015-07-17
- Revision:
- 592:a274ee790e56
- Parent:
- 579:53297373a894
File content as of revision 592:a274ee790e56:
#include "adc.h" #if SAMD20 /* The Die revision D number */ #define REVISON_D_NUM 3 #endif /** * \brief Initializes an ADC configuration structure to defaults * * Initializes a given ADC configuration struct to a set of known default * values. This function should be called on any new instance of the * configuration struct before being modified by the user application. * * The default configuration is as follows: * \li GCLK generator 0 (GCLK main) clock source * \li 1V from internal bandgap reference * \li Div 4 clock prescaler * \li 12 bit resolution * \li Window monitor disabled * \li No gain * \li Positive input on ADC PIN 0 * \li Negative input on ADC PIN 1 * \li Averaging disabled * \li Oversampling disabled * \li Right adjust data * \li Single-ended mode * \li Free running disabled * \li All events (input and generation) disabled * \li Sleep operation disabled * \li No reference compensation * \li No gain/offset correction * \li No added sampling time * \li Pin scan mode disabled * * \param[out] config Pointer to configuration struct to initialize to * default values */ void adc_get_config_defaults(struct adc_config *const config) { Assert(config); config->clock_source = GCLK_GENERATOR_0; config->reference = ADC_REFERENCE_INT1V; config->clock_prescaler = ADC_CLOCK_PRESCALER_DIV4; config->resolution = ADC_RESOLUTION_12BIT; config->window.window_mode = ADC_WINDOW_MODE_DISABLE; config->window.window_upper_value = 0; config->window.window_lower_value = 0; config->gain_factor = ADC_GAIN_FACTOR_1X; #if SAMR21 config->positive_input = ADC_POSITIVE_INPUT_PIN6 ; #else config->positive_input = ADC_POSITIVE_INPUT_PIN0 ; #endif config->negative_input = ADC_NEGATIVE_INPUT_GND ; config->accumulate_samples = ADC_ACCUMULATE_DISABLE; config->divide_result = ADC_DIVIDE_RESULT_DISABLE; config->left_adjust = false; config->differential_mode = false; config->freerunning = false; config->event_action = ADC_EVENT_ACTION_DISABLED; config->run_in_standby = false; config->reference_compensation_enable = false; config->correction.correction_enable = false; config->correction.gain_correction = ADC_GAINCORR_RESETVALUE; config->correction.offset_correction = ADC_OFFSETCORR_RESETVALUE; config->sample_length = 0; config->pin_scan.offset_start_scan = 0; config->pin_scan.inputs_to_scan = 0; } /** * \brief Sets the ADC window mode * * Sets the ADC window mode to a given mode and value range. * * \param[in] module_inst Pointer to the ADC software instance struct * \param[in] window_mode Window monitor mode to set * \param[in] window_lower_value Lower window monitor threshold value * \param[in] window_upper_value Upper window monitor threshold value */ void adc_set_window_mode( struct adc_module *const module_inst, const enum adc_window_mode window_mode, const int16_t window_lower_value, const int16_t window_upper_value) { /* Sanity check arguments */ Assert(module_inst); Assert(module_inst->hw); Adc *const adc_module = module_inst->hw; while (adc_is_syncing(module_inst)) { /* Wait for synchronization */ } /* Set window mode */ adc_module->WINCTRL.reg = window_mode << ADC_WINCTRL_WINMODE_Pos; while (adc_is_syncing(module_inst)) { /* Wait for synchronization */ } /* Set lower window monitor threshold value */ adc_module->WINLT.reg = window_lower_value << ADC_WINLT_WINLT_Pos; while (adc_is_syncing(module_inst)) { /* Wait for synchronization */ } /* Set upper window monitor threshold value */ adc_module->WINUT.reg = window_upper_value << ADC_WINUT_WINUT_Pos; } /** * \internal Configure MUX settings for the analog pins * * This function will set the given ADC input pins * to the analog function in the pinmux, giving * the ADC access to the analog signal * * \param [in] pin AINxx pin to configure */ static inline void _adc_configure_ain_pin(uint32_t pin) { #define PIN_INVALID_ADC_AIN 0xFFFFUL /* Pinmapping table for AINxx -> GPIO pin number */ const uint32_t pinmapping[] = { #if (SAMD20E | SAMD21E) PIN_PA02B_ADC_AIN0, PIN_PA03B_ADC_AIN1, PIN_INVALID_ADC_AIN, PIN_INVALID_ADC_AIN, PIN_PA04B_ADC_AIN4, PIN_PA05B_ADC_AIN5, PIN_PA06B_ADC_AIN6, PIN_PA07B_ADC_AIN7, PIN_INVALID_ADC_AIN, PIN_INVALID_ADC_AIN, PIN_INVALID_ADC_AIN, PIN_INVALID_ADC_AIN, PIN_INVALID_ADC_AIN, PIN_INVALID_ADC_AIN, PIN_INVALID_ADC_AIN, PIN_INVALID_ADC_AIN, PIN_PA08B_ADC_AIN16, PIN_PA09B_ADC_AIN17, PIN_PA10B_ADC_AIN18, PIN_PA11B_ADC_AIN19, #elif (SAMD20G | SAMD21G) PIN_PA02B_ADC_AIN0, PIN_PA03B_ADC_AIN1, PIN_PB08B_ADC_AIN2, PIN_PB09B_ADC_AIN3, PIN_PA04B_ADC_AIN4, PIN_PA05B_ADC_AIN5, PIN_PA06B_ADC_AIN6, PIN_PA07B_ADC_AIN7, PIN_INVALID_ADC_AIN, PIN_INVALID_ADC_AIN, PIN_PB02B_ADC_AIN10, PIN_PB03B_ADC_AIN11, PIN_INVALID_ADC_AIN, PIN_INVALID_ADC_AIN, PIN_INVALID_ADC_AIN, PIN_INVALID_ADC_AIN, PIN_PA08B_ADC_AIN16, PIN_PA09B_ADC_AIN17, PIN_PA10B_ADC_AIN18, PIN_PA11B_ADC_AIN19, #elif (SAMD20J | SAMD21J) PIN_PA02B_ADC_AIN0, PIN_PA03B_ADC_AIN1, PIN_PB08B_ADC_AIN2, PIN_PB09B_ADC_AIN3, PIN_PA04B_ADC_AIN4, PIN_PA05B_ADC_AIN5, PIN_PA06B_ADC_AIN6, PIN_PA07B_ADC_AIN7, PIN_PB00B_ADC_AIN8, PIN_PB01B_ADC_AIN9, PIN_PB02B_ADC_AIN10, PIN_PB03B_ADC_AIN11, PIN_PB04B_ADC_AIN12, PIN_PB05B_ADC_AIN13, PIN_PB06B_ADC_AIN14, PIN_PB07B_ADC_AIN15, PIN_PA08B_ADC_AIN16, PIN_PA09B_ADC_AIN17, PIN_PA10B_ADC_AIN18, PIN_PA11B_ADC_AIN19, #elif SAMR21E PIN_INVALID_ADC_AIN, PIN_INVALID_ADC_AIN, PIN_INVALID_ADC_AIN, PIN_INVALID_ADC_AIN, PIN_INVALID_ADC_AIN, PIN_INVALID_ADC_AIN, PIN_PA06B_ADC_AIN6, PIN_PA07B_ADC_AIN7, PIN_INVALID_ADC_AIN, PIN_INVALID_ADC_AIN, PIN_INVALID_ADC_AIN, PIN_INVALID_ADC_AIN, PIN_INVALID_ADC_AIN, PIN_INVALID_ADC_AIN, PIN_INVALID_ADC_AIN, PIN_INVALID_ADC_AIN, PIN_PA08B_ADC_AIN16, PIN_PA09B_ADC_AIN17, PIN_INVALID_ADC_AIN, PIN_INVALID_ADC_AIN, #elif SAMR21G PIN_INVALID_ADC_AIN, PIN_INVALID_ADC_AIN, PIN_INVALID_ADC_AIN, PIN_INVALID_ADC_AIN, PIN_PA04B_ADC_AIN4, PIN_PA05B_ADC_AIN5, PIN_PA06B_ADC_AIN6, PIN_PA07B_ADC_AIN7, PIN_INVALID_ADC_AIN, PIN_INVALID_ADC_AIN, PIN_PB02B_ADC_AIN10, PIN_PB03B_ADC_AIN11, PIN_INVALID_ADC_AIN, PIN_INVALID_ADC_AIN, PIN_INVALID_ADC_AIN, PIN_INVALID_ADC_AIN, PIN_PA08B_ADC_AIN16, PIN_PA09B_ADC_AIN17, PIN_INVALID_ADC_AIN, PIN_INVALID_ADC_AIN, #elif (SAMD10C | SAMD11C) PIN_PA02B_ADC_AIN0, PIN_INVALID_ADC_AIN, PIN_PA04B_ADC_AIN2, PIN_PA05B_ADC_AIN3, PIN_INVALID_ADC_AIN, PIN_INVALID_ADC_AIN, PIN_PA14B_ADC_AIN6, PIN_PA15B_ADC_AIN7, PIN_INVALID_ADC_AIN, PIN_INVALID_ADC_AIN, PIN_INVALID_ADC_AIN, PIN_INVALID_ADC_AIN, PIN_INVALID_ADC_AIN, PIN_INVALID_ADC_AIN, PIN_INVALID_ADC_AIN, PIN_INVALID_ADC_AIN, PIN_INVALID_ADC_AIN, PIN_INVALID_ADC_AIN, PIN_INVALID_ADC_AIN, PIN_INVALID_ADC_AIN, #elif (SAMD10DS | SAMD11DS) PIN_PA02B_ADC_AIN0, PIN_INVALID_ADC_AIN, PIN_PA04B_ADC_AIN2, PIN_PA05B_ADC_AIN3, PIN_PA06B_ADC_AIN4, PIN_PA07B_ADC_AIN5, PIN_PA14B_ADC_AIN6, PIN_PA15B_ADC_AIN7, PIN_INVALID_ADC_AIN, PIN_INVALID_ADC_AIN, PIN_INVALID_ADC_AIN, PIN_INVALID_ADC_AIN, PIN_INVALID_ADC_AIN, PIN_INVALID_ADC_AIN, PIN_INVALID_ADC_AIN, PIN_INVALID_ADC_AIN, PIN_INVALID_ADC_AIN, PIN_INVALID_ADC_AIN, PIN_INVALID_ADC_AIN, PIN_INVALID_ADC_AIN, #elif (SAMD10DM | SAMD11DM) PIN_PA02B_ADC_AIN0, PIN_PA03B_ADC_AIN1, PIN_PA04B_ADC_AIN2, PIN_PA05B_ADC_AIN3, PIN_PA06B_ADC_AIN4, PIN_PA07B_ADC_AIN5, PIN_PA14B_ADC_AIN6, PIN_PA15B_ADC_AIN7, PIN_PA10B_ADC_AIN8, PIN_PA11B_ADC_AIN9, PIN_INVALID_ADC_AIN, PIN_INVALID_ADC_AIN, PIN_INVALID_ADC_AIN, PIN_INVALID_ADC_AIN, PIN_INVALID_ADC_AIN, PIN_INVALID_ADC_AIN, PIN_INVALID_ADC_AIN, PIN_INVALID_ADC_AIN, PIN_INVALID_ADC_AIN, PIN_INVALID_ADC_AIN, #else # error ADC pin mappings are not defined for this device. #endif }; uint32_t pin_map_result = PIN_INVALID_ADC_AIN; if (pin <= ADC_EXTCHANNEL_MSB) { pin_map_result = pinmapping[pin >> ADC_INPUTCTRL_MUXPOS_Pos]; Assert(pin_map_result != PIN_INVALID_ADC_AIN); struct system_pinmux_config config; system_pinmux_get_config_defaults(&config); /* Analog functions are all on MUX setting B */ config.input_pull = SYSTEM_PINMUX_PIN_PULL_NONE; config.mux_position = 1; system_pinmux_pin_set_config(pin_map_result, &config); } } /** * \internal Writes an ADC configuration to the hardware module * * Writes out a given ADC module configuration to the hardware module. * * \param[out] module_inst Pointer to the ADC software instance struct * \param[in] config Pointer to configuration struct * * \return Status of the configuration procedure * \retval STATUS_OK The configuration was successful * \retval STATUS_ERR_INVALID_ARG Invalid argument(s) were provided */ static enum status_code _adc_set_config( struct adc_module *const module_inst, struct adc_config *const config) { uint8_t adjres = 0; uint32_t resolution = ADC_RESOLUTION_16BIT; enum adc_accumulate_samples accumulate = ADC_ACCUMULATE_DISABLE; #if SAMD20 uint8_t revision_num = ((REG_DSU_DID & DSU_DID_DIE_Msk) >> DSU_DID_DIE_Pos); #endif /* Get the hardware module pointer */ Adc *const adc_module = module_inst->hw; /* Configure GCLK channel and enable clock */ struct system_gclk_chan_config gclk_chan_conf; system_gclk_chan_get_config_defaults(&gclk_chan_conf); gclk_chan_conf.source_generator = config->clock_source; system_gclk_chan_set_config(ADC_GCLK_ID, &gclk_chan_conf); system_gclk_chan_enable(ADC_GCLK_ID); /* Setup pinmuxing for analog inputs */ if (config->pin_scan.inputs_to_scan != 0) { uint8_t offset = config->pin_scan.offset_start_scan; uint8_t start_pin = offset +(uint8_t)config->positive_input; uint8_t end_pin = start_pin + config->pin_scan.inputs_to_scan; while (start_pin < end_pin) { _adc_configure_ain_pin((offset % 16)+(uint8_t)config->positive_input); start_pin++; offset++; } _adc_configure_ain_pin(config->negative_input); } else { _adc_configure_ain_pin(config->positive_input); _adc_configure_ain_pin(config->negative_input); } /* Configure run in standby */ adc_module->CTRLA.reg = (config->run_in_standby << ADC_CTRLA_RUNSTDBY_Pos); /* Configure reference */ adc_module->REFCTRL.reg = (config->reference_compensation_enable << ADC_REFCTRL_REFCOMP_Pos) | (config->reference); /* Set adjusting result and number of samples */ switch (config->resolution) { case ADC_RESOLUTION_CUSTOM: adjres = config->divide_result; accumulate = config->accumulate_samples; /* 16-bit result register */ resolution = ADC_RESOLUTION_16BIT; break; case ADC_RESOLUTION_13BIT: /* Increase resolution by 1 bit */ adjres = ADC_DIVIDE_RESULT_2; accumulate = ADC_ACCUMULATE_SAMPLES_4; /* 16-bit result register */ resolution = ADC_RESOLUTION_16BIT; break; case ADC_RESOLUTION_14BIT: /* Increase resolution by 2 bit */ adjres = ADC_DIVIDE_RESULT_4; accumulate = ADC_ACCUMULATE_SAMPLES_16; /* 16-bit result register */ resolution = ADC_RESOLUTION_16BIT; break; #if SAMD20 /* See $35.1.8 for ADC errata of SAM D20. The revisions before D have this issue.*/ case ADC_RESOLUTION_15BIT: /* Increase resolution by 3 bit */ if(revision_num < REVISON_D_NUM) { adjres = ADC_DIVIDE_RESULT_8; } else { adjres = ADC_DIVIDE_RESULT_2; } accumulate = ADC_ACCUMULATE_SAMPLES_64; /* 16-bit result register */ resolution = ADC_RESOLUTION_16BIT; break; case ADC_RESOLUTION_16BIT: if(revision_num < REVISON_D_NUM) { /* Increase resolution by 4 bit */ adjres = ADC_DIVIDE_RESULT_16; } else { adjres = ADC_DIVIDE_RESULT_DISABLE; } accumulate = ADC_ACCUMULATE_SAMPLES_256; /* 16-bit result register */ resolution = ADC_RESOLUTION_16BIT; break; #else case ADC_RESOLUTION_15BIT: /* Increase resolution by 3 bit */ adjres = ADC_DIVIDE_RESULT_2; accumulate = ADC_ACCUMULATE_SAMPLES_64; /* 16-bit result register */ resolution = ADC_RESOLUTION_16BIT; break; case ADC_RESOLUTION_16BIT: /* Increase resolution by 4 bit */ adjres = ADC_DIVIDE_RESULT_DISABLE; accumulate = ADC_ACCUMULATE_SAMPLES_256; /* 16-bit result register */ resolution = ADC_RESOLUTION_16BIT; break; #endif case ADC_RESOLUTION_8BIT: /* 8-bit result register */ resolution = ADC_RESOLUTION_8BIT; break; case ADC_RESOLUTION_10BIT: /* 10-bit result register */ resolution = ADC_RESOLUTION_10BIT; break; case ADC_RESOLUTION_12BIT: /* 12-bit result register */ resolution = ADC_RESOLUTION_12BIT; break; default: /* Unknown. Abort. */ return STATUS_ERR_INVALID_ARG; } adc_module->AVGCTRL.reg = ADC_AVGCTRL_ADJRES(adjres) | accumulate; /* Check validity of sample length value */ if (config->sample_length > 63) { return STATUS_ERR_INVALID_ARG; } else { /* Configure sample length */ adc_module->SAMPCTRL.reg = (config->sample_length << ADC_SAMPCTRL_SAMPLEN_Pos); } while (adc_is_syncing(module_inst)) { /* Wait for synchronization */ } /* Configure CTRLB */ adc_module->CTRLB.reg = config->clock_prescaler | resolution | (config->correction.correction_enable << ADC_CTRLB_CORREN_Pos) | (config->freerunning << ADC_CTRLB_FREERUN_Pos) | (config->left_adjust << ADC_CTRLB_LEFTADJ_Pos) | (config->differential_mode << ADC_CTRLB_DIFFMODE_Pos); /* Check validity of window thresholds */ if (config->window.window_mode != ADC_WINDOW_MODE_DISABLE) { switch (resolution) { case ADC_RESOLUTION_8BIT: if (config->differential_mode && (config->window.window_lower_value > 127 || config->window.window_lower_value < -128 || config->window.window_upper_value > 127 || config->window.window_upper_value < -128)) { /* Invalid value */ return STATUS_ERR_INVALID_ARG; } else if (config->window.window_lower_value > 255 || config->window.window_upper_value > 255) { /* Invalid value */ return STATUS_ERR_INVALID_ARG; } break; case ADC_RESOLUTION_10BIT: if (config->differential_mode && (config->window.window_lower_value > 511 || config->window.window_lower_value < -512 || config->window.window_upper_value > 511 || config->window.window_upper_value > -512)) { /* Invalid value */ return STATUS_ERR_INVALID_ARG; } else if (config->window.window_lower_value > 1023 || config->window.window_upper_value > 1023) { /* Invalid value */ return STATUS_ERR_INVALID_ARG; } break; case ADC_RESOLUTION_12BIT: if (config->differential_mode && (config->window.window_lower_value > 2047 || config->window.window_lower_value < -2048 || config->window.window_upper_value > 2047 || config->window.window_upper_value < -2048)) { /* Invalid value */ return STATUS_ERR_INVALID_ARG; } else if (config->window.window_lower_value > 4095 || config->window.window_upper_value > 4095) { /* Invalid value */ return STATUS_ERR_INVALID_ARG; } break; case ADC_RESOLUTION_16BIT: if (config->differential_mode && (config->window.window_lower_value > 32767 || config->window.window_lower_value < -32768 || config->window.window_upper_value > 32767 || config->window.window_upper_value < -32768)) { /* Invalid value */ return STATUS_ERR_INVALID_ARG; } else if (config->window.window_lower_value > 65535 || config->window.window_upper_value > 65535) { /* Invalid value */ return STATUS_ERR_INVALID_ARG; } break; } } while (adc_is_syncing(module_inst)) { /* Wait for synchronization */ } /* Configure window mode */ adc_module->WINCTRL.reg = config->window.window_mode; while (adc_is_syncing(module_inst)) { /* Wait for synchronization */ } /* Configure lower threshold */ adc_module->WINLT.reg = config->window.window_lower_value << ADC_WINLT_WINLT_Pos; while (adc_is_syncing(module_inst)) { /* Wait for synchronization */ } /* Configure lower threshold */ adc_module->WINUT.reg = config->window.window_upper_value << ADC_WINUT_WINUT_Pos; uint8_t inputs_to_scan = config->pin_scan.inputs_to_scan; if (inputs_to_scan > 0) { /* * Number of input sources included is the value written to INPUTSCAN * plus 1. */ inputs_to_scan--; } if (inputs_to_scan > (ADC_INPUTCTRL_INPUTSCAN_Msk >> ADC_INPUTCTRL_INPUTSCAN_Pos) || config->pin_scan.offset_start_scan > (ADC_INPUTCTRL_INPUTOFFSET_Msk >> ADC_INPUTCTRL_INPUTOFFSET_Pos)) { /* Invalid number of input pins or input offset */ return STATUS_ERR_INVALID_ARG; } while (adc_is_syncing(module_inst)) { /* Wait for synchronization */ } /* Configure pin scan mode and positive and negative input pins */ adc_module->INPUTCTRL.reg = config->gain_factor | (config->pin_scan.offset_start_scan << ADC_INPUTCTRL_INPUTOFFSET_Pos) | (inputs_to_scan << ADC_INPUTCTRL_INPUTSCAN_Pos) | config->negative_input | config->positive_input; /* Configure events */ adc_module->EVCTRL.reg = config->event_action; /* Disable all interrupts */ adc_module->INTENCLR.reg = (1 << ADC_INTENCLR_SYNCRDY_Pos) | (1 << ADC_INTENCLR_WINMON_Pos) | (1 << ADC_INTENCLR_OVERRUN_Pos) | (1 << ADC_INTENCLR_RESRDY_Pos); if (config->correction.correction_enable) { /* Make sure gain_correction value is valid */ if (config->correction.gain_correction > ADC_GAINCORR_GAINCORR_Msk) { return STATUS_ERR_INVALID_ARG; } else { /* Set gain correction value */ adc_module->GAINCORR.reg = config->correction.gain_correction << ADC_GAINCORR_GAINCORR_Pos; } /* Make sure offset correction value is valid */ if (config->correction.offset_correction > 2047 || config->correction.offset_correction < -2048) { return STATUS_ERR_INVALID_ARG; } else { /* Set offset correction value */ adc_module->OFFSETCORR.reg = config->correction.offset_correction << ADC_OFFSETCORR_OFFSETCORR_Pos; } } /* Load in the fixed device ADC calibration constants */ adc_module->CALIB.reg = ADC_CALIB_BIAS_CAL( (*(uint32_t *)ADC_FUSES_BIASCAL_ADDR >> ADC_FUSES_BIASCAL_Pos) ) | ADC_CALIB_LINEARITY_CAL( (*(uint64_t *)ADC_FUSES_LINEARITY_0_ADDR >> ADC_FUSES_LINEARITY_0_Pos) ); return STATUS_OK; } /** * \brief Initializes the ADC * * Initializes the ADC device struct and the hardware module based on the * given configuration struct values. * * \param[out] module_inst Pointer to the ADC software instance struct * \param[in] hw Pointer to the ADC module instance * \param[in] config Pointer to the configuration struct * * \return Status of the initialization procedure. * \retval STATUS_OK The initialization was successful * \retval STATUS_ERR_INVALID_ARG Invalid argument(s) were provided * \retval STATUS_BUSY The module is busy with a reset operation * \retval STATUS_ERR_DENIED The module is enabled */ enum status_code adc_init( struct adc_module *const module_inst, Adc *hw, struct adc_config *config) { /* Sanity check arguments */ Assert(module_inst); Assert(hw); Assert(config); /* Associate the software module instance with the hardware module */ module_inst->hw = hw; /* Turn on the digital interface clock */ system_apb_clock_set_mask(SYSTEM_CLOCK_APB_APBC, PM_APBCMASK_ADC); if (hw->CTRLA.reg & ADC_CTRLA_SWRST) { /* We are in the middle of a reset. Abort. */ return STATUS_BUSY; } if (hw->CTRLA.reg & ADC_CTRLA_ENABLE) { /* Module must be disabled before initialization. Abort. */ return STATUS_ERR_DENIED; } /* Store the selected reference for later use */ module_inst->reference = config->reference; /* Make sure bandgap is enabled if requested by the config */ if (module_inst->reference == ADC_REFERENCE_INT1V) { system_voltage_reference_enable(SYSTEM_VOLTAGE_REFERENCE_BANDGAP); } #if ADC_CALLBACK_MODE == true for (uint8_t i = 0; i < ADC_CALLBACK_N; i++) { module_inst->callback[i] = NULL; }; module_inst->registered_callback_mask = 0; module_inst->enabled_callback_mask = 0; module_inst->remaining_conversions = 0; module_inst->job_status = STATUS_OK; _adc_instances[0] = module_inst; if (config->event_action == ADC_EVENT_ACTION_DISABLED && !config->freerunning) { module_inst->software_trigger = true; } else { module_inst->software_trigger = false; } #endif /* Write configuration to module */ return _adc_set_config(module_inst, config); }