/* ChibiOS/RT - Copyright (C) 2006,2007,2008,2009,2010 Giovanni Di Sirio. This file is part of ChibiOS/RT. ChibiOS/RT is free software; you can redistribute it and/or modify it under the terms of the GNU General Public License as published by the Free Software Foundation; either version 3 of the License, or (at your option) any later version. ChibiOS/RT is distributed in the hope that it will be useful, but WITHOUT ANY WARRANTY; without even the implied warranty of MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU General Public License for more details. You should have received a copy of the GNU General Public License along with this program. If not, see . */ /** * @file adc.c * @brief ADC Driver code. * * @addtogroup ADC * @{ */ #include "ch.h" #include "hal.h" #if CH_HAL_USE_ADC || defined(__DOXYGEN__) /*===========================================================================*/ /* Driver exported variables. */ /*===========================================================================*/ /*===========================================================================*/ /* Driver local variables. */ /*===========================================================================*/ /*===========================================================================*/ /* Driver local functions. */ /*===========================================================================*/ /*===========================================================================*/ /* Driver exported functions. */ /*===========================================================================*/ /** * @brief ADC Driver initialization. */ void adcInit(void) { adc_lld_init(); } /** * @brief Initializes the standard part of a @p ADCDriver structure. * * @param[in] adcp pointer to the @p ADCDriver object */ void adcObjectInit(ADCDriver *adcp) { adcp->ad_state = ADC_STOP; adcp->ad_config = NULL; adcp->ad_callback = NULL; adcp->ad_samples = NULL; adcp->ad_depth = 0; adcp->ad_grpp = NULL; chSemInit(&adcp->ad_sem, 0); } /** * @brief Configures and activates the ADC peripheral. * * @param[in] adcp pointer to the @p ADCDriver object * @param[in] config pointer to the @p ADCConfig object */ void adcStart(ADCDriver *adcp, const ADCConfig *config) { chDbgCheck((adcp != NULL) && (config != NULL), "adcStart"); chSysLock(); chDbgAssert((adcp->ad_state == ADC_STOP) || (adcp->ad_state == ADC_READY), "adcStart(), #1", "invalid state"); adcp->ad_config = config; adc_lld_start(adcp); adcp->ad_state = ADC_READY; chSysUnlock(); } /** * @brief Deactivates the ADC peripheral. * * @param[in] adcp pointer to the @p ADCDriver object */ void adcStop(ADCDriver *adcp) { chDbgCheck(adcp != NULL, "adcStop"); chSysLock(); chDbgAssert((adcp->ad_state == ADC_STOP) || (adcp->ad_state == ADC_READY), "adcStop(), #1", "invalid state"); adc_lld_stop(adcp); adcp->ad_state = ADC_STOP; chSysUnlock(); } /** * @brief Starts an ADC conversion. * @details Starts a conversion operation, there are two kind of conversion * modes: * - LINEAR, in this mode the buffer is filled once and then * the conversion stops automatically. * - CIRCULAR, in this mode the conversion never stops and * the buffer is filled circularly.
* During the conversion the callback function is invoked when * the buffer is 50% filled and when the buffer is 100% filled, * this way is possible to process the conversion stream in real * time. This kind of conversion can only be stopped by explicitly * invoking @p adcStopConversion(). * . * @note The buffer is organized as a matrix of M*N elements where M is the * channels number configured into the conversion group and N is the * buffer depth. The samples are sequentially written into the buffer * with no gaps. * * @param[in] adcp pointer to the @p ADCDriver object * @param[in] grpp pointer to a @p ADCConversionGroup object * @param[out] samples pointer to the samples buffer * @param[in] depth buffer depth (matrix rows number). The buffer depth * must be one or an even number. * @param[in] callback pointer to the conversion callback function, this * parameter can be @p NULL if a callback is not required * @return The operation status. * @retval FALSE the conversion has been started. * @retval TRUE the driver is busy, conversion not started. */ bool_t adcStartConversion(ADCDriver *adcp, const ADCConversionGroup *grpp, adcsample_t *samples, size_t depth, adccallback_t callback) { bool_t result; chSysLock(); result = adcStartConversionI(adcp, grpp, samples, depth, callback); chSysUnlock(); return result; } /** * @brief Starts an ADC conversion. * @details Starts a conversion operation, there are two kind of conversion * modes: * - LINEAR, in this mode the buffer is filled once and then * the conversion stops automatically. * - CIRCULAR, in this mode the conversion never stops and * the buffer is filled circularly.
* During the conversion the callback function is invoked when * the buffer is 50% filled and when the buffer is 100% filled, * this way is possible to process the conversion stream in real * time. This kind of conversion can only be stopped by explicitly * invoking @p adcStopConversion(). * . * @note The buffer is organized as a matrix of M*N elements where M is the * channels number configured into the conversion group and N is the * buffer depth. The samples are sequentially written into the buffer * with no gaps. * * @param[in] adcp pointer to the @p ADCDriver object * @param[in] grpp pointer to a @p ADCConversionGroup object * @param[out] samples pointer to the samples buffer * @param[in] depth buffer depth (matrix rows number). The buffer depth * must be one or an even number. * @param[in] callback pointer to the conversion callback function, this * parameter can be @p NULL if a callback is not required * @return The operation status. * @retval FALSE the conversion has been started. * @retval TRUE the driver is busy, conversion not started. */ bool_t adcStartConversionI(ADCDriver *adcp, const ADCConversionGroup *grpp, adcsample_t *samples, size_t depth, adccallback_t callback) { chDbgCheck((adcp != NULL) && (grpp != NULL) && (samples != NULL) && ((depth == 1) || ((depth & 1) == 0)), "adcStartConversionI"); chDbgAssert((adcp->ad_state == ADC_READY) || (adcp->ad_state == ADC_RUNNING) || (adcp->ad_state == ADC_COMPLETE), "adcStartConversionI(), #1", "invalid state"); if (adcp->ad_state == ADC_RUNNING) return TRUE; adcp->ad_callback = callback; adcp->ad_samples = samples; adcp->ad_depth = depth; adcp->ad_grpp = grpp; adc_lld_start_conversion(adcp); adcp->ad_state = ADC_RUNNING; return FALSE; } /** * @brief Stops an ongoing conversion. * * @param[in] adcp pointer to the @p ADCDriver object */ void adcStopConversion(ADCDriver *adcp) { chDbgCheck(adcp != NULL, "adcStopConversion"); chSysLock(); chDbgAssert((adcp->ad_state == ADC_READY) || (adcp->ad_state == ADC_RUNNING) || (adcp->ad_state == ADC_COMPLETE), "adcStopConversion(), #1", "invalid state"); if (adcp->ad_state == ADC_RUNNING) { adc_lld_stop_conversion(adcp); adcp->ad_grpp = NULL; adcp->ad_state = ADC_READY; chSemResetI(&adcp->ad_sem, 0); chSchRescheduleS(); } else adcp->ad_state = ADC_READY; chSysUnlock(); } /** * @brief Stops an ongoing conversion. * * @param[in] adcp pointer to the @p ADCDriver object */ void adcStopConversionI(ADCDriver *adcp) { chDbgCheck(adcp != NULL, "adcStopConversionI"); chDbgAssert((adcp->ad_state == ADC_READY) || (adcp->ad_state == ADC_RUNNING) || (adcp->ad_state == ADC_COMPLETE), "adcStopConversionI(), #1", "invalid state"); if (adcp->ad_state == ADC_RUNNING) { adc_lld_stop_conversion(adcp); adcp->ad_grpp = NULL; adcp->ad_state = ADC_READY; chSemResetI(&adcp->ad_sem, 0); } else adcp->ad_state = ADC_READY; } /** * @brief Waits for completion. * @details If the conversion is not completed or not yet started then the * invoking thread waits for a conversion completion event. * * @param[in] adcp pointer to the @p ADCDriver object * @param[in] timeout the number of ticks before the operation timeouts, * the following special values are allowed: * - @a TIME_IMMEDIATE immediate timeout. * - @a TIME_INFINITE no timeout. * . * @return The operation result. * @retval RDY_OK conversion finished. * @retval RDY_TIMEOUT conversion not finished within the specified time. */ msg_t adcWaitConversion(ADCDriver *adcp, systime_t timeout) { chSysLock(); chDbgAssert((adcp->ad_state == ADC_READY) || (adcp->ad_state == ADC_RUNNING) || (adcp->ad_state == ADC_COMPLETE), "adcWaitConversion(), #1", "invalid state"); if (adcp->ad_state != ADC_COMPLETE) { if (chSemWaitTimeoutS(&adcp->ad_sem, timeout) == RDY_TIMEOUT) { chSysUnlock(); return RDY_TIMEOUT; } } chSysUnlock(); return RDY_OK; } #endif /* CH_HAL_USE_ADC */ /** @} */