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view Common/Drivers/STM32F4xx_HAL_Driver/Src/stm32f4xx_hal_dfsdm.c @ 519:2c49561c8062
Reset Safety Stop display in case of a new descend:
In previous version safety stop was displayed in while the stop depth was reached. The count down was interrupted in case of a new descend but the safety stop was still displayed, blocking the NDL visualization in the big font view. To avoid this scenario a restart function has been added which will return to NDL view in case of a descend > 2m. If just a short drop happend then the countdown will be continued when the safety stop depth is reached again. If that takes more then a minute the safety stop counter is restarted.
author | Ideenmodellierer |
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date | Sun, 06 Sep 2020 22:11:51 +0200 |
parents | c78bcbd5deda |
children |
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/** ****************************************************************************** * @file stm32f4xx_hal_dfsdm.c * @author MCD Application Team * @brief This file provides firmware functions to manage the following * functionalities of the Digital Filter for Sigma-Delta Modulators * (DFSDM) peripherals: * + Initialization and configuration of channels and filters * + Regular channels configuration * + Injected channels configuration * + Regular/Injected Channels DMA Configuration * + Interrupts and flags management * + Analog watchdog feature * + Short-circuit detector feature * + Extremes detector feature * + Clock absence detector feature * + Break generation on analog watchdog or short-circuit event * @verbatim ============================================================================== ##### How to use this driver ##### ============================================================================== [..] *** Channel initialization *** ============================== [..] (#) User has first to initialize channels (before filters initialization). (#) As prerequisite, fill in the HAL_DFSDM_ChannelMspInit() : (++) Enable DFSDMz clock interface with __HAL_RCC_DFSDMz_CLK_ENABLE(). (++) Enable the clocks for the DFSDMz GPIOS with __HAL_RCC_GPIOx_CLK_ENABLE(). (++) Configure these DFSDMz pins in alternate mode using HAL_GPIO_Init(). (++) If interrupt mode is used, enable and configure DFSDMz_FLT0 global interrupt with HAL_NVIC_SetPriority() and HAL_NVIC_EnableIRQ(). (#) Configure the output clock, input, serial interface, analog watchdog, offset and data right bit shift parameters for this channel using the HAL_DFSDM_ChannelInit() function. *** Channel clock absence detector *** ====================================== [..] (#) Start clock absence detector using HAL_DFSDM_ChannelCkabStart() or HAL_DFSDM_ChannelCkabStart_IT(). (#) In polling mode, use HAL_DFSDM_ChannelPollForCkab() to detect the clock absence. (#) In interrupt mode, HAL_DFSDM_ChannelCkabCallback() will be called if clock absence is detected. (#) Stop clock absence detector using HAL_DFSDM_ChannelCkabStop() or HAL_DFSDM_ChannelCkabStop_IT(). (#) Please note that the same mode (polling or interrupt) has to be used for all channels because the channels are sharing the same interrupt. (#) Please note also that in interrupt mode, if clock absence detector is stopped for one channel, interrupt will be disabled for all channels. *** Channel short circuit detector *** ====================================== [..] (#) Start short circuit detector using HAL_DFSDM_ChannelScdStart() or or HAL_DFSDM_ChannelScdStart_IT(). (#) In polling mode, use HAL_DFSDM_ChannelPollForScd() to detect short circuit. (#) In interrupt mode, HAL_DFSDM_ChannelScdCallback() will be called if short circuit is detected. (#) Stop short circuit detector using HAL_DFSDM_ChannelScdStop() or or HAL_DFSDM_ChannelScdStop_IT(). (#) Please note that the same mode (polling or interrupt) has to be used for all channels because the channels are sharing the same interrupt. (#) Please note also that in interrupt mode, if short circuit detector is stopped for one channel, interrupt will be disabled for all channels. *** Channel analog watchdog value *** ===================================== [..] (#) Get analog watchdog filter value of a channel using HAL_DFSDM_ChannelGetAwdValue(). *** Channel offset value *** ===================================== [..] (#) Modify offset value of a channel using HAL_DFSDM_ChannelModifyOffset(). *** Filter initialization *** ============================= [..] (#) After channel initialization, user has to init filters. (#) As prerequisite, fill in the HAL_DFSDM_FilterMspInit() : (++) If interrupt mode is used , enable and configure DFSDMz_FLTx global interrupt with HAL_NVIC_SetPriority() and HAL_NVIC_EnableIRQ(). Please note that DFSDMz_FLT0 global interrupt could be already enabled if interrupt is used for channel. (++) If DMA mode is used, configure DMA with HAL_DMA_Init() and link it with DFSDMz filter handle using __HAL_LINKDMA(). (#) Configure the regular conversion, injected conversion and filter parameters for this filter using the HAL_DFSDM_FilterInit() function. *** Filter regular channel conversion *** ========================================= [..] (#) Select regular channel and enable/disable continuous mode using HAL_DFSDM_FilterConfigRegChannel(). (#) Start regular conversion using HAL_DFSDM_FilterRegularStart(), HAL_DFSDM_FilterRegularStart_IT(), HAL_DFSDM_FilterRegularStart_DMA() or HAL_DFSDM_FilterRegularMsbStart_DMA(). (#) In polling mode, use HAL_DFSDM_FilterPollForRegConversion() to detect the end of regular conversion. (#) In interrupt mode, HAL_DFSDM_FilterRegConvCpltCallback() will be called at the end of regular conversion. (#) Get value of regular conversion and corresponding channel using HAL_DFSDM_FilterGetRegularValue(). (#) In DMA mode, HAL_DFSDM_FilterRegConvHalfCpltCallback() and HAL_DFSDM_FilterRegConvCpltCallback() will be called respectively at the half transfer and at the transfer complete. Please note that HAL_DFSDM_FilterRegConvHalfCpltCallback() will be called only in DMA circular mode. (#) Stop regular conversion using HAL_DFSDM_FilterRegularStop(), HAL_DFSDM_FilterRegularStop_IT() or HAL_DFSDM_FilterRegularStop_DMA(). *** Filter injected channels conversion *** =========================================== [..] (#) Select injected channels using HAL_DFSDM_FilterConfigInjChannel(). (#) Start injected conversion using HAL_DFSDM_FilterInjectedStart(), HAL_DFSDM_FilterInjectedStart_IT(), HAL_DFSDM_FilterInjectedStart_DMA() or HAL_DFSDM_FilterInjectedMsbStart_DMA(). (#) In polling mode, use HAL_DFSDM_FilterPollForInjConversion() to detect the end of injected conversion. (#) In interrupt mode, HAL_DFSDM_FilterInjConvCpltCallback() will be called at the end of injected conversion. (#) Get value of injected conversion and corresponding channel using HAL_DFSDM_FilterGetInjectedValue(). (#) In DMA mode, HAL_DFSDM_FilterInjConvHalfCpltCallback() and HAL_DFSDM_FilterInjConvCpltCallback() will be called respectively at the half transfer and at the transfer complete. Please note that HAL_DFSDM_FilterInjConvCpltCallback() will be called only in DMA circular mode. (#) Stop injected conversion using HAL_DFSDM_FilterInjectedStop(), HAL_DFSDM_FilterInjectedStop_IT() or HAL_DFSDM_FilterInjectedStop_DMA(). *** Filter analog watchdog *** ============================== [..] (#) Start filter analog watchdog using HAL_DFSDM_FilterAwdStart_IT(). (#) HAL_DFSDM_FilterAwdCallback() will be called if analog watchdog occurs. (#) Stop filter analog watchdog using HAL_DFSDM_FilterAwdStop_IT(). *** Filter extreme detector *** =============================== [..] (#) Start filter extreme detector using HAL_DFSDM_FilterExdStart(). (#) Get extreme detector maximum value using HAL_DFSDM_FilterGetExdMaxValue(). (#) Get extreme detector minimum value using HAL_DFSDM_FilterGetExdMinValue(). (#) Start filter extreme detector using HAL_DFSDM_FilterExdStop(). *** Filter conversion time *** ============================== [..] (#) Get conversion time value using HAL_DFSDM_FilterGetConvTimeValue(). @endverbatim ****************************************************************************** * @attention * * <h2><center>© COPYRIGHT(c) 2017 STMicroelectronics</center></h2> * * Redistribution and use in source and binary forms, with or without modification, * are permitted provided that the following conditions are met: * 1. Redistributions of source code must retain the above copyright notice, * this list of conditions and the following disclaimer. * 2. Redistributions in binary form must reproduce the above copyright notice, * this list of conditions and the following disclaimer in the documentation * and/or other materials provided with the distribution. * 3. Neither the name of STMicroelectronics nor the names of its contributors * may be used to endorse or promote products derived from this software * without specific prior written permission. * * THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS "AS IS" * AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE * IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE ARE * DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT HOLDER OR CONTRIBUTORS BE LIABLE * FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL * DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR * SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER * CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, * OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE * OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE. * ****************************************************************************** */ /* Includes ------------------------------------------------------------------*/ #include "stm32f4xx_hal.h" /** @addtogroup STM32F4xx_HAL_Driver * @{ */ #ifdef HAL_DFSDM_MODULE_ENABLED #if defined(STM32F412Zx) || defined(STM32F412Vx) || defined(STM32F412Rx) || defined(STM32F412Cx) || defined(STM32F413xx) || defined(STM32F423xx) /** @defgroup DFSDM DFSDM * @brief DFSDM HAL driver module * @{ */ /* Private typedef -----------------------------------------------------------*/ /* Private define ------------------------------------------------------------*/ /** @defgroup DFSDM_Private_Define DFSDM Private Define * @{ */ #define DFSDM_FLTCR1_MSB_RCH_OFFSET 8U #define DFSDM_MSB_MASK 0xFFFF0000U #define DFSDM_LSB_MASK 0x0000FFFFU #define DFSDM_CKAB_TIMEOUT 5000U #define DFSDM1_CHANNEL_NUMBER 4U #if defined (DFSDM2_Channel0) #define DFSDM2_CHANNEL_NUMBER 8U #endif /* DFSDM2_Channel0 */ /** * @} */ /** @addtogroup DFSDM_Private_Macros * @{ */ /** * @} */ /* Private macro -------------------------------------------------------------*/ /* Private variables ---------------------------------------------------------*/ /** @defgroup DFSDM_Private_Variables DFSDM Private Variables * @{ */ __IO uint32_t v_dfsdm1ChannelCounter = 0U; DFSDM_Channel_HandleTypeDef* a_dfsdm1ChannelHandle[DFSDM1_CHANNEL_NUMBER] = {NULL}; #if defined (DFSDM2_Channel0) __IO uint32_t v_dfsdm2ChannelCounter = 0U; DFSDM_Channel_HandleTypeDef* a_dfsdm2ChannelHandle[DFSDM2_CHANNEL_NUMBER] = {NULL}; #endif /* DFSDM2_Channel0 */ /** * @} */ /* Private function prototypes -----------------------------------------------*/ /** @defgroup DFSDM_Private_Functions DFSDM Private Functions * @{ */ static uint32_t DFSDM_GetInjChannelsNbr(uint32_t Channels); static uint32_t DFSDM_GetChannelFromInstance(DFSDM_Channel_TypeDef* Instance); static void DFSDM_RegConvStart(DFSDM_Filter_HandleTypeDef *hdfsdm_filter); static void DFSDM_RegConvStop(DFSDM_Filter_HandleTypeDef* hdfsdm_filter); static void DFSDM_InjConvStart(DFSDM_Filter_HandleTypeDef* hdfsdm_filter); static void DFSDM_InjConvStop(DFSDM_Filter_HandleTypeDef* hdfsdm_filter); static void DFSDM_DMARegularHalfConvCplt(DMA_HandleTypeDef *hdma); static void DFSDM_DMARegularConvCplt(DMA_HandleTypeDef *hdma); static void DFSDM_DMAInjectedHalfConvCplt(DMA_HandleTypeDef *hdma); static void DFSDM_DMAInjectedConvCplt(DMA_HandleTypeDef *hdma); static void DFSDM_DMAError(DMA_HandleTypeDef *hdma); /** * @} */ /* Exported functions --------------------------------------------------------*/ /** @defgroup DFSDM_Exported_Functions DFSDM Exported Functions * @{ */ /** @defgroup DFSDM_Exported_Functions_Group1_Channel Channel initialization and de-initialization functions * @brief Channel initialization and de-initialization functions * @verbatim ============================================================================== ##### Channel initialization and de-initialization functions ##### ============================================================================== [..] This section provides functions allowing to: (+) Initialize the DFSDM channel. (+) De-initialize the DFSDM channel. @endverbatim * @{ */ /** * @brief Initialize the DFSDM channel according to the specified parameters * in the DFSDM_ChannelInitTypeDef structure and initialize the associated handle. * @param hdfsdm_channel DFSDM channel handle. * @retval HAL status. */ HAL_StatusTypeDef HAL_DFSDM_ChannelInit(DFSDM_Channel_HandleTypeDef *hdfsdm_channel) { #if defined(DFSDM2_Channel0) __IO uint32_t* channelCounterPtr; DFSDM_Channel_HandleTypeDef **channelHandleTable; DFSDM_Channel_TypeDef* channel0Instance; #endif /* defined(DFSDM2_Channel0) */ /* Check DFSDM Channel handle */ if(hdfsdm_channel == NULL) { return HAL_ERROR; } /* Check parameters */ assert_param(IS_DFSDM_CHANNEL_ALL_INSTANCE(hdfsdm_channel->Instance)); assert_param(IS_FUNCTIONAL_STATE(hdfsdm_channel->Init.OutputClock.Activation)); assert_param(IS_DFSDM_CHANNEL_INPUT(hdfsdm_channel->Init.Input.Multiplexer)); assert_param(IS_DFSDM_CHANNEL_DATA_PACKING(hdfsdm_channel->Init.Input.DataPacking)); assert_param(IS_DFSDM_CHANNEL_INPUT_PINS(hdfsdm_channel->Init.Input.Pins)); assert_param(IS_DFSDM_CHANNEL_SERIAL_INTERFACE_TYPE(hdfsdm_channel->Init.SerialInterface.Type)); assert_param(IS_DFSDM_CHANNEL_SPI_CLOCK(hdfsdm_channel->Init.SerialInterface.SpiClock)); assert_param(IS_DFSDM_CHANNEL_FILTER_ORDER(hdfsdm_channel->Init.Awd.FilterOrder)); assert_param(IS_DFSDM_CHANNEL_FILTER_OVS_RATIO(hdfsdm_channel->Init.Awd.Oversampling)); assert_param(IS_DFSDM_CHANNEL_OFFSET(hdfsdm_channel->Init.Offset)); assert_param(IS_DFSDM_CHANNEL_RIGHT_BIT_SHIFT(hdfsdm_channel->Init.RightBitShift)); #if defined(DFSDM2_Channel0) /* Get channel counter, channel handle table and channel 0 instance */ if(IS_DFSDM1_CHANNEL_INSTANCE(hdfsdm_channel->Instance)) { channelCounterPtr = &v_dfsdm1ChannelCounter; channelHandleTable = a_dfsdm1ChannelHandle; channel0Instance = DFSDM1_Channel0; } else { channelCounterPtr = &v_dfsdm2ChannelCounter; channelHandleTable = a_dfsdm2ChannelHandle; channel0Instance = DFSDM2_Channel0; } /* Check that channel has not been already initialized */ if(channelHandleTable[DFSDM_GetChannelFromInstance(hdfsdm_channel->Instance)] != NULL) { return HAL_ERROR; } /* Call MSP init function */ HAL_DFSDM_ChannelMspInit(hdfsdm_channel); /* Update the channel counter */ (*channelCounterPtr)++; /* Configure output serial clock and enable global DFSDM interface only for first channel */ if(*channelCounterPtr == 1U) { assert_param(IS_DFSDM_CHANNEL_OUTPUT_CLOCK(hdfsdm_channel->Init.OutputClock.Selection)); /* Set the output serial clock source */ channel0Instance->CHCFGR1 &= ~(DFSDM_CHCFGR1_CKOUTSRC); channel0Instance->CHCFGR1 |= hdfsdm_channel->Init.OutputClock.Selection; /* Reset clock divider */ channel0Instance->CHCFGR1 &= ~(DFSDM_CHCFGR1_CKOUTDIV); if(hdfsdm_channel->Init.OutputClock.Activation == ENABLE) { assert_param(IS_DFSDM_CHANNEL_OUTPUT_CLOCK_DIVIDER(hdfsdm_channel->Init.OutputClock.Divider)); /* Set the output clock divider */ channel0Instance->CHCFGR1 |= (uint32_t) ((hdfsdm_channel->Init.OutputClock.Divider - 1U) << DFSDM_CHCFGR1_CKOUTDIV_Pos); } /* enable the DFSDM global interface */ channel0Instance->CHCFGR1 |= DFSDM_CHCFGR1_DFSDMEN; } /* Set channel input parameters */ hdfsdm_channel->Instance->CHCFGR1 &= ~(DFSDM_CHCFGR1_DATPACK | DFSDM_CHCFGR1_DATMPX | DFSDM_CHCFGR1_CHINSEL); hdfsdm_channel->Instance->CHCFGR1 |= (hdfsdm_channel->Init.Input.Multiplexer | hdfsdm_channel->Init.Input.DataPacking | hdfsdm_channel->Init.Input.Pins); /* Set serial interface parameters */ hdfsdm_channel->Instance->CHCFGR1 &= ~(DFSDM_CHCFGR1_SITP | DFSDM_CHCFGR1_SPICKSEL); hdfsdm_channel->Instance->CHCFGR1 |= (hdfsdm_channel->Init.SerialInterface.Type | hdfsdm_channel->Init.SerialInterface.SpiClock); /* Set analog watchdog parameters */ hdfsdm_channel->Instance->CHAWSCDR &= ~(DFSDM_CHAWSCDR_AWFORD | DFSDM_CHAWSCDR_AWFOSR); hdfsdm_channel->Instance->CHAWSCDR |= (hdfsdm_channel->Init.Awd.FilterOrder | ((hdfsdm_channel->Init.Awd.Oversampling - 1U) << DFSDM_CHAWSCDR_AWFOSR_Pos)); /* Set channel offset and right bit shift */ hdfsdm_channel->Instance->CHCFGR2 &= ~(DFSDM_CHCFGR2_OFFSET | DFSDM_CHCFGR2_DTRBS); hdfsdm_channel->Instance->CHCFGR2 |= (((uint32_t) hdfsdm_channel->Init.Offset << DFSDM_CHCFGR2_OFFSET_Pos) | (hdfsdm_channel->Init.RightBitShift << DFSDM_CHCFGR2_DTRBS_Pos)); /* Enable DFSDM channel */ hdfsdm_channel->Instance->CHCFGR1 |= DFSDM_CHCFGR1_CHEN; /* Set DFSDM Channel to ready state */ hdfsdm_channel->State = HAL_DFSDM_CHANNEL_STATE_READY; /* Store channel handle in DFSDM channel handle table */ channelHandleTable[DFSDM_GetChannelFromInstance(hdfsdm_channel->Instance)] = hdfsdm_channel; #else /* Check that channel has not been already initialized */ if(a_dfsdm1ChannelHandle[DFSDM_GetChannelFromInstance(hdfsdm_channel->Instance)] != NULL) { return HAL_ERROR; } /* Call MSP init function */ HAL_DFSDM_ChannelMspInit(hdfsdm_channel); /* Update the channel counter */ v_dfsdm1ChannelCounter++; /* Configure output serial clock and enable global DFSDM interface only for first channel */ if(v_dfsdm1ChannelCounter == 1U) { assert_param(IS_DFSDM_CHANNEL_OUTPUT_CLOCK(hdfsdm_channel->Init.OutputClock.Selection)); /* Set the output serial clock source */ DFSDM1_Channel0->CHCFGR1 &= ~(DFSDM_CHCFGR1_CKOUTSRC); DFSDM1_Channel0->CHCFGR1 |= hdfsdm_channel->Init.OutputClock.Selection; /* Reset clock divider */ DFSDM1_Channel0->CHCFGR1 &= ~(DFSDM_CHCFGR1_CKOUTDIV); if(hdfsdm_channel->Init.OutputClock.Activation == ENABLE) { assert_param(IS_DFSDM_CHANNEL_OUTPUT_CLOCK_DIVIDER(hdfsdm_channel->Init.OutputClock.Divider)); /* Set the output clock divider */ DFSDM1_Channel0->CHCFGR1 |= (uint32_t) ((hdfsdm_channel->Init.OutputClock.Divider - 1U) << DFSDM_CHCFGR1_CKOUTDIV_Pos); } /* enable the DFSDM global interface */ DFSDM1_Channel0->CHCFGR1 |= DFSDM_CHCFGR1_DFSDMEN; } /* Set channel input parameters */ hdfsdm_channel->Instance->CHCFGR1 &= ~(DFSDM_CHCFGR1_DATPACK | DFSDM_CHCFGR1_DATMPX | DFSDM_CHCFGR1_CHINSEL); hdfsdm_channel->Instance->CHCFGR1 |= (hdfsdm_channel->Init.Input.Multiplexer | hdfsdm_channel->Init.Input.DataPacking | hdfsdm_channel->Init.Input.Pins); /* Set serial interface parameters */ hdfsdm_channel->Instance->CHCFGR1 &= ~(DFSDM_CHCFGR1_SITP | DFSDM_CHCFGR1_SPICKSEL); hdfsdm_channel->Instance->CHCFGR1 |= (hdfsdm_channel->Init.SerialInterface.Type | hdfsdm_channel->Init.SerialInterface.SpiClock); /* Set analog watchdog parameters */ hdfsdm_channel->Instance->CHAWSCDR &= ~(DFSDM_CHAWSCDR_AWFORD | DFSDM_CHAWSCDR_AWFOSR); hdfsdm_channel->Instance->CHAWSCDR |= (hdfsdm_channel->Init.Awd.FilterOrder | ((hdfsdm_channel->Init.Awd.Oversampling - 1U) << DFSDM_CHAWSCDR_AWFOSR_Pos)); /* Set channel offset and right bit shift */ hdfsdm_channel->Instance->CHCFGR2 &= ~(DFSDM_CHCFGR2_OFFSET | DFSDM_CHCFGR2_DTRBS); hdfsdm_channel->Instance->CHCFGR2 |= (((uint32_t) hdfsdm_channel->Init.Offset << DFSDM_CHCFGR2_OFFSET_Pos) | (hdfsdm_channel->Init.RightBitShift << DFSDM_CHCFGR2_DTRBS_Pos)); /* Enable DFSDM channel */ hdfsdm_channel->Instance->CHCFGR1 |= DFSDM_CHCFGR1_CHEN; /* Set DFSDM Channel to ready state */ hdfsdm_channel->State = HAL_DFSDM_CHANNEL_STATE_READY; /* Store channel handle in DFSDM channel handle table */ a_dfsdm1ChannelHandle[DFSDM_GetChannelFromInstance(hdfsdm_channel->Instance)] = hdfsdm_channel; #endif /* DFSDM2_Channel0 */ return HAL_OK; } /** * @brief De-initialize the DFSDM channel. * @param hdfsdm_channel DFSDM channel handle. * @retval HAL status. */ HAL_StatusTypeDef HAL_DFSDM_ChannelDeInit(DFSDM_Channel_HandleTypeDef *hdfsdm_channel) { #if defined(DFSDM2_Channel0) __IO uint32_t* channelCounterPtr; DFSDM_Channel_HandleTypeDef **channelHandleTable; DFSDM_Channel_TypeDef* channel0Instance; #endif /* defined(DFSDM2_Channel0) */ /* Check DFSDM Channel handle */ if(hdfsdm_channel == NULL) { return HAL_ERROR; } /* Check parameters */ assert_param(IS_DFSDM_CHANNEL_ALL_INSTANCE(hdfsdm_channel->Instance)); #if defined(DFSDM2_Channel0) /* Get channel counter, channel handle table and channel 0 instance */ if(IS_DFSDM1_CHANNEL_INSTANCE(hdfsdm_channel->Instance)) { channelCounterPtr = &v_dfsdm1ChannelCounter; channelHandleTable = a_dfsdm1ChannelHandle; channel0Instance = DFSDM1_Channel0; } else { channelCounterPtr = &v_dfsdm2ChannelCounter; channelHandleTable = a_dfsdm2ChannelHandle; channel0Instance = DFSDM2_Channel0; } /* Check that channel has not been already deinitialized */ if(channelHandleTable[DFSDM_GetChannelFromInstance(hdfsdm_channel->Instance)] == NULL) { return HAL_ERROR; } /* Disable the DFSDM channel */ hdfsdm_channel->Instance->CHCFGR1 &= ~(DFSDM_CHCFGR1_CHEN); /* Update the channel counter */ (*channelCounterPtr)--; /* Disable global DFSDM at deinit of last channel */ if(*channelCounterPtr == 0U) { channel0Instance->CHCFGR1 &= ~(DFSDM_CHCFGR1_DFSDMEN); } /* Call MSP deinit function */ HAL_DFSDM_ChannelMspDeInit(hdfsdm_channel); /* Set DFSDM Channel in reset state */ hdfsdm_channel->State = HAL_DFSDM_CHANNEL_STATE_RESET; /* Reset channel handle in DFSDM channel handle table */ channelHandleTable[DFSDM_GetChannelFromInstance(hdfsdm_channel->Instance)] = NULL; #else /* Check that channel has not been already deinitialized */ if(a_dfsdm1ChannelHandle[DFSDM_GetChannelFromInstance(hdfsdm_channel->Instance)] == NULL) { return HAL_ERROR; } /* Disable the DFSDM channel */ hdfsdm_channel->Instance->CHCFGR1 &= ~(DFSDM_CHCFGR1_CHEN); /* Update the channel counter */ v_dfsdm1ChannelCounter--; /* Disable global DFSDM at deinit of last channel */ if(v_dfsdm1ChannelCounter == 0U) { DFSDM1_Channel0->CHCFGR1 &= ~(DFSDM_CHCFGR1_DFSDMEN); } /* Call MSP deinit function */ HAL_DFSDM_ChannelMspDeInit(hdfsdm_channel); /* Set DFSDM Channel in reset state */ hdfsdm_channel->State = HAL_DFSDM_CHANNEL_STATE_RESET; /* Reset channel handle in DFSDM channel handle table */ a_dfsdm1ChannelHandle[DFSDM_GetChannelFromInstance(hdfsdm_channel->Instance)] = (DFSDM_Channel_HandleTypeDef *) NULL; #endif /* defined(DFSDM2_Channel0) */ return HAL_OK; } /** * @brief Initialize the DFSDM channel MSP. * @param hdfsdm_channel DFSDM channel handle. * @retval None */ __weak void HAL_DFSDM_ChannelMspInit(DFSDM_Channel_HandleTypeDef *hdfsdm_channel) { /* Prevent unused argument(s) compilation warning */ UNUSED(hdfsdm_channel); /* NOTE : This function should not be modified, when the function is needed, the HAL_DFSDM_ChannelMspInit could be implemented in the user file. */ } /** * @brief De-initialize the DFSDM channel MSP. * @param hdfsdm_channel DFSDM channel handle. * @retval None */ __weak void HAL_DFSDM_ChannelMspDeInit(DFSDM_Channel_HandleTypeDef *hdfsdm_channel) { /* Prevent unused argument(s) compilation warning */ UNUSED(hdfsdm_channel); /* NOTE : This function should not be modified, when the function is needed, the HAL_DFSDM_ChannelMspDeInit could be implemented in the user file. */ } /** * @} */ /** @defgroup DFSDM_Exported_Functions_Group2_Channel Channel operation functions * @brief Channel operation functions * @verbatim ============================================================================== ##### Channel operation functions ##### ============================================================================== [..] This section provides functions allowing to: (+) Manage clock absence detector feature. (+) Manage short circuit detector feature. (+) Get analog watchdog value. (+) Modify offset value. @endverbatim * @{ */ /** * @brief This function allows to start clock absence detection in polling mode. * @note Same mode has to be used for all channels. * @note If clock is not available on this channel during 5 seconds, * clock absence detection will not be activated and function * will return HAL_TIMEOUT error. * @param hdfsdm_channel DFSDM channel handle. * @retval HAL status */ HAL_StatusTypeDef HAL_DFSDM_ChannelCkabStart(DFSDM_Channel_HandleTypeDef *hdfsdm_channel) { HAL_StatusTypeDef status = HAL_OK; uint32_t tickstart; uint32_t channel; #if defined(DFSDM2_Channel0) DFSDM_Filter_TypeDef* filter0Instance; #endif /* defined(DFSDM2_Channel0) */ /* Check parameters */ assert_param(IS_DFSDM_CHANNEL_ALL_INSTANCE(hdfsdm_channel->Instance)); /* Check DFSDM channel state */ if(hdfsdm_channel->State != HAL_DFSDM_CHANNEL_STATE_READY) { /* Return error status */ status = HAL_ERROR; } else { #if defined (DFSDM2_Channel0) /* Get channel counter, channel handle table and channel 0 instance */ if(IS_DFSDM1_CHANNEL_INSTANCE(hdfsdm_channel->Instance)) { filter0Instance = DFSDM1_Filter0; } else { filter0Instance = DFSDM2_Filter0; } /* Get channel number from channel instance */ channel = DFSDM_GetChannelFromInstance(hdfsdm_channel->Instance); /* Get timeout */ tickstart = HAL_GetTick(); /* Clear clock absence flag */ while((((filter0Instance->FLTISR & DFSDM_FLTISR_CKABF) >> (DFSDM_FLTISR_CKABF_Pos + channel)) & 1U) != 0U) { filter0Instance->FLTICR = (1U << (DFSDM_FLTICR_CLRCKABF_Pos + channel)); /* Check the Timeout */ if((HAL_GetTick()-tickstart) > DFSDM_CKAB_TIMEOUT) { /* Set timeout status */ status = HAL_TIMEOUT; break; } } #else /* Get channel number from channel instance */ channel = DFSDM_GetChannelFromInstance(hdfsdm_channel->Instance); /* Get timeout */ tickstart = HAL_GetTick(); /* Clear clock absence flag */ while((((DFSDM1_Filter0->FLTISR & DFSDM_FLTISR_CKABF) >> (DFSDM_FLTISR_CKABF_Pos + channel)) & 1U) != 0U) { DFSDM1_Filter0->FLTICR = (1U << (DFSDM_FLTICR_CLRCKABF_Pos + channel)); /* Check the Timeout */ if((HAL_GetTick()-tickstart) > DFSDM_CKAB_TIMEOUT) { /* Set timeout status */ status = HAL_TIMEOUT; break; } } #endif /* DFSDM2_Channel0 */ if(status == HAL_OK) { /* Start clock absence detection */ hdfsdm_channel->Instance->CHCFGR1 |= DFSDM_CHCFGR1_CKABEN; } } /* Return function status */ return status; } /** * @brief This function allows to poll for the clock absence detection. * @param hdfsdm_channel DFSDM channel handle. * @param Timeout Timeout value in milliseconds. * @retval HAL status */ HAL_StatusTypeDef HAL_DFSDM_ChannelPollForCkab(DFSDM_Channel_HandleTypeDef *hdfsdm_channel, uint32_t Timeout) { uint32_t tickstart; uint32_t channel; #if defined(DFSDM2_Channel0) DFSDM_Filter_TypeDef* filter0Instance; #endif /* defined(DFSDM2_Channel0) */ /* Check parameters */ assert_param(IS_DFSDM_CHANNEL_ALL_INSTANCE(hdfsdm_channel->Instance)); /* Check DFSDM channel state */ if(hdfsdm_channel->State != HAL_DFSDM_CHANNEL_STATE_READY) { /* Return error status */ return HAL_ERROR; } else { #if defined(DFSDM2_Channel0) /* Get channel counter, channel handle table and channel 0 instance */ if(IS_DFSDM1_CHANNEL_INSTANCE(hdfsdm_channel->Instance)) { filter0Instance = DFSDM1_Filter0; } else { filter0Instance = DFSDM2_Filter0; } /* Get channel number from channel instance */ channel = DFSDM_GetChannelFromInstance(hdfsdm_channel->Instance); /* Get timeout */ tickstart = HAL_GetTick(); /* Wait clock absence detection */ while((((filter0Instance->FLTISR & DFSDM_FLTISR_CKABF) >> (DFSDM_FLTISR_CKABF_Pos + channel)) & 1U) == 0U) { /* Check the Timeout */ if(Timeout != HAL_MAX_DELAY) { if((Timeout == 0U) || ((HAL_GetTick()-tickstart) > Timeout)) { /* Return timeout status */ return HAL_TIMEOUT; } } } /* Clear clock absence detection flag */ filter0Instance->FLTICR = (1U << (DFSDM_FLTICR_CLRCKABF_Pos + channel)); #else /* Get channel number from channel instance */ channel = DFSDM_GetChannelFromInstance(hdfsdm_channel->Instance); /* Get timeout */ tickstart = HAL_GetTick(); /* Wait clock absence detection */ while((((DFSDM1_Filter0->FLTISR & DFSDM_FLTISR_CKABF) >> (DFSDM_FLTISR_CKABF_Pos + channel)) & 1U) == 0U) { /* Check the Timeout */ if(Timeout != HAL_MAX_DELAY) { if((Timeout == 0U) || ((HAL_GetTick()-tickstart) > Timeout)) { /* Return timeout status */ return HAL_TIMEOUT; } } } /* Clear clock absence detection flag */ DFSDM1_Filter0->FLTICR = (1U << (DFSDM_FLTICR_CLRCKABF_Pos + channel)); #endif /* defined(DFSDM2_Channel0) */ /* Return function status */ return HAL_OK; } } /** * @brief This function allows to stop clock absence detection in polling mode. * @param hdfsdm_channel DFSDM channel handle. * @retval HAL status */ HAL_StatusTypeDef HAL_DFSDM_ChannelCkabStop(DFSDM_Channel_HandleTypeDef *hdfsdm_channel) { HAL_StatusTypeDef status = HAL_OK; uint32_t channel; #if defined(DFSDM2_Channel0) DFSDM_Filter_TypeDef* filter0Instance; #endif /* defined(DFSDM2_Channel0) */ /* Check parameters */ assert_param(IS_DFSDM_CHANNEL_ALL_INSTANCE(hdfsdm_channel->Instance)); /* Check DFSDM channel state */ if(hdfsdm_channel->State != HAL_DFSDM_CHANNEL_STATE_READY) { /* Return error status */ status = HAL_ERROR; } else { #if defined(DFSDM2_Channel0) /* Get channel counter, channel handle table and channel 0 instance */ if(IS_DFSDM1_CHANNEL_INSTANCE(hdfsdm_channel->Instance)) { filter0Instance = DFSDM1_Filter0; } else { filter0Instance = DFSDM2_Filter0; } /* Stop clock absence detection */ hdfsdm_channel->Instance->CHCFGR1 &= ~(DFSDM_CHCFGR1_CKABEN); /* Clear clock absence flag */ channel = DFSDM_GetChannelFromInstance(hdfsdm_channel->Instance); filter0Instance->FLTICR = (1U << (DFSDM_FLTICR_CLRCKABF_Pos + channel)); #else /* Stop clock absence detection */ hdfsdm_channel->Instance->CHCFGR1 &= ~(DFSDM_CHCFGR1_CKABEN); /* Clear clock absence flag */ channel = DFSDM_GetChannelFromInstance(hdfsdm_channel->Instance); DFSDM1_Filter0->FLTICR = (1U << (DFSDM_FLTICR_CLRCKABF_Pos + channel)); #endif /* DFSDM2_Channel0 */ } /* Return function status */ return status; } /** * @brief This function allows to start clock absence detection in interrupt mode. * @note Same mode has to be used for all channels. * @note If clock is not available on this channel during 5 seconds, * clock absence detection will not be activated and function * will return HAL_TIMEOUT error. * @param hdfsdm_channel DFSDM channel handle. * @retval HAL status */ HAL_StatusTypeDef HAL_DFSDM_ChannelCkabStart_IT(DFSDM_Channel_HandleTypeDef *hdfsdm_channel) { HAL_StatusTypeDef status = HAL_OK; uint32_t channel; uint32_t tickstart; #if defined(DFSDM2_Channel0) DFSDM_Filter_TypeDef* filter0Instance; #endif /* defined(DFSDM2_Channel0) */ /* Check parameters */ assert_param(IS_DFSDM_CHANNEL_ALL_INSTANCE(hdfsdm_channel->Instance)); /* Check DFSDM channel state */ if(hdfsdm_channel->State != HAL_DFSDM_CHANNEL_STATE_READY) { /* Return error status */ status = HAL_ERROR; } else { #if defined(DFSDM2_Channel0) /* Get channel counter, channel handle table and channel 0 instance */ if(IS_DFSDM1_CHANNEL_INSTANCE(hdfsdm_channel->Instance)) { filter0Instance = DFSDM1_Filter0; } else { filter0Instance = DFSDM2_Filter0; } /* Get channel number from channel instance */ channel = DFSDM_GetChannelFromInstance(hdfsdm_channel->Instance); /* Get timeout */ tickstart = HAL_GetTick(); /* Clear clock absence flag */ while((((filter0Instance->FLTISR & DFSDM_FLTISR_CKABF) >> (DFSDM_FLTISR_CKABF_Pos + channel)) & 1U) != 0U) { filter0Instance->FLTICR = (1U << (DFSDM_FLTICR_CLRCKABF_Pos + channel)); /* Check the Timeout */ if((HAL_GetTick()-tickstart) > DFSDM_CKAB_TIMEOUT) { /* Set timeout status */ status = HAL_TIMEOUT; break; } } if(status == HAL_OK) { /* Activate clock absence detection interrupt */ filter0Instance->FLTCR2 |= DFSDM_FLTCR2_CKABIE; /* Start clock absence detection */ hdfsdm_channel->Instance->CHCFGR1 |= DFSDM_CHCFGR1_CKABEN; } #else /* Get channel number from channel instance */ channel = DFSDM_GetChannelFromInstance(hdfsdm_channel->Instance); /* Get timeout */ tickstart = HAL_GetTick(); /* Clear clock absence flag */ while((((DFSDM1_Filter0->FLTISR & DFSDM_FLTISR_CKABF) >> (DFSDM_FLTISR_CKABF_Pos + channel)) & 1U) != 0U) { DFSDM1_Filter0->FLTICR = (1U << (DFSDM_FLTICR_CLRCKABF_Pos + channel)); /* Check the Timeout */ if((HAL_GetTick()-tickstart) > DFSDM_CKAB_TIMEOUT) { /* Set timeout status */ status = HAL_TIMEOUT; break; } } if(status == HAL_OK) { /* Activate clock absence detection interrupt */ DFSDM1_Filter0->FLTCR2 |= DFSDM_FLTCR2_CKABIE; /* Start clock absence detection */ hdfsdm_channel->Instance->CHCFGR1 |= DFSDM_CHCFGR1_CKABEN; } #endif /* defined(DFSDM2_Channel0) */ } /* Return function status */ return status; } /** * @brief Clock absence detection callback. * @param hdfsdm_channel DFSDM channel handle. * @retval None */ __weak void HAL_DFSDM_ChannelCkabCallback(DFSDM_Channel_HandleTypeDef *hdfsdm_channel) { /* Prevent unused argument(s) compilation warning */ UNUSED(hdfsdm_channel); /* NOTE : This function should not be modified, when the callback is needed, the HAL_DFSDM_ChannelCkabCallback could be implemented in the user file */ } /** * @brief This function allows to stop clock absence detection in interrupt mode. * @note Interrupt will be disabled for all channels * @param hdfsdm_channel DFSDM channel handle. * @retval HAL status */ HAL_StatusTypeDef HAL_DFSDM_ChannelCkabStop_IT(DFSDM_Channel_HandleTypeDef *hdfsdm_channel) { HAL_StatusTypeDef status = HAL_OK; uint32_t channel; #if defined(DFSDM2_Channel0) DFSDM_Filter_TypeDef* filter0Instance; #endif /* defined(DFSDM2_Channel0) */ /* Check parameters */ assert_param(IS_DFSDM_CHANNEL_ALL_INSTANCE(hdfsdm_channel->Instance)); /* Check DFSDM channel state */ if(hdfsdm_channel->State != HAL_DFSDM_CHANNEL_STATE_READY) { /* Return error status */ status = HAL_ERROR; } else { #if defined(DFSDM2_Channel0) /* Get channel counter, channel handle table and channel 0 instance */ if(IS_DFSDM1_CHANNEL_INSTANCE(hdfsdm_channel->Instance)) { filter0Instance = DFSDM1_Filter0; } else { filter0Instance = DFSDM2_Filter0; } /* Stop clock absence detection */ hdfsdm_channel->Instance->CHCFGR1 &= ~(DFSDM_CHCFGR1_CKABEN); /* Clear clock absence flag */ channel = DFSDM_GetChannelFromInstance(hdfsdm_channel->Instance); filter0Instance->FLTICR = (1U << (DFSDM_FLTICR_CLRCKABF_Pos + channel)); /* Disable clock absence detection interrupt */ filter0Instance->FLTCR2 &= ~(DFSDM_FLTCR2_CKABIE); #else /* Stop clock absence detection */ hdfsdm_channel->Instance->CHCFGR1 &= ~(DFSDM_CHCFGR1_CKABEN); /* Clear clock absence flag */ channel = DFSDM_GetChannelFromInstance(hdfsdm_channel->Instance); DFSDM1_Filter0->FLTICR = (1U << (DFSDM_FLTICR_CLRCKABF_Pos + channel)); /* Disable clock absence detection interrupt */ DFSDM1_Filter0->FLTCR2 &= ~(DFSDM_FLTCR2_CKABIE); #endif /* DFSDM2_Channel0 */ } /* Return function status */ return status; } /** * @brief This function allows to start short circuit detection in polling mode. * @note Same mode has to be used for all channels * @param hdfsdm_channel DFSDM channel handle. * @param Threshold Short circuit detector threshold. * This parameter must be a number between Min_Data = 0 and Max_Data = 255. * @param BreakSignal Break signals assigned to short circuit event. * This parameter can be a values combination of @ref DFSDM_BreakSignals. * @retval HAL status */ HAL_StatusTypeDef HAL_DFSDM_ChannelScdStart(DFSDM_Channel_HandleTypeDef *hdfsdm_channel, uint32_t Threshold, uint32_t BreakSignal) { HAL_StatusTypeDef status = HAL_OK; /* Check parameters */ assert_param(IS_DFSDM_CHANNEL_ALL_INSTANCE(hdfsdm_channel->Instance)); assert_param(IS_DFSDM_CHANNEL_SCD_THRESHOLD(Threshold)); assert_param(IS_DFSDM_BREAK_SIGNALS(BreakSignal)); /* Check DFSDM channel state */ if(hdfsdm_channel->State != HAL_DFSDM_CHANNEL_STATE_READY) { /* Return error status */ status = HAL_ERROR; } else { /* Configure threshold and break signals */ hdfsdm_channel->Instance->CHAWSCDR &= ~(DFSDM_CHAWSCDR_BKSCD | DFSDM_CHAWSCDR_SCDT); hdfsdm_channel->Instance->CHAWSCDR |= ((BreakSignal << DFSDM_CHAWSCDR_BKSCD_Pos) | \ Threshold); /* Start short circuit detection */ hdfsdm_channel->Instance->CHCFGR1 |= DFSDM_CHCFGR1_SCDEN; } /* Return function status */ return status; } /** * @brief This function allows to poll for the short circuit detection. * @param hdfsdm_channel DFSDM channel handle. * @param Timeout Timeout value in milliseconds. * @retval HAL status */ HAL_StatusTypeDef HAL_DFSDM_ChannelPollForScd(DFSDM_Channel_HandleTypeDef *hdfsdm_channel, uint32_t Timeout) { uint32_t tickstart; uint32_t channel; #if defined(DFSDM2_Channel0) DFSDM_Filter_TypeDef* filter0Instance; #endif /* defined(DFSDM2_Channel0) */ /* Check parameters */ assert_param(IS_DFSDM_CHANNEL_ALL_INSTANCE(hdfsdm_channel->Instance)); /* Check DFSDM channel state */ if(hdfsdm_channel->State != HAL_DFSDM_CHANNEL_STATE_READY) { /* Return error status */ return HAL_ERROR; } else { /* Get channel number from channel instance */ channel = DFSDM_GetChannelFromInstance(hdfsdm_channel->Instance); #if defined(DFSDM2_Channel0) /* Get channel counter, channel handle table and channel 0 instance */ if(IS_DFSDM1_CHANNEL_INSTANCE(hdfsdm_channel->Instance)) { filter0Instance = DFSDM1_Filter0; } else { filter0Instance = DFSDM2_Filter0; } /* Get timeout */ tickstart = HAL_GetTick(); /* Wait short circuit detection */ while(((filter0Instance->FLTISR & DFSDM_FLTISR_SCDF) >> (DFSDM_FLTISR_SCDF_Pos + channel)) == 0U) { /* Check the Timeout */ if(Timeout != HAL_MAX_DELAY) { if((Timeout == 0U) || ((HAL_GetTick()-tickstart) > Timeout)) { /* Return timeout status */ return HAL_TIMEOUT; } } } /* Clear short circuit detection flag */ filter0Instance->FLTICR = (1U << (DFSDM_FLTICR_CLRSCSDF_Pos + channel)); #else /* Get timeout */ tickstart = HAL_GetTick(); /* Wait short circuit detection */ while(((DFSDM1_Filter0->FLTISR & DFSDM_FLTISR_SCDF) >> (DFSDM_FLTISR_SCDF_Pos + channel)) == 0U) { /* Check the Timeout */ if(Timeout != HAL_MAX_DELAY) { if((Timeout == 0U) || ((HAL_GetTick()-tickstart) > Timeout)) { /* Return timeout status */ return HAL_TIMEOUT; } } } /* Clear short circuit detection flag */ DFSDM1_Filter0->FLTICR = (1U << (DFSDM_FLTICR_CLRSCSDF_Pos + channel)); #endif /* DFSDM2_Channel0 */ /* Return function status */ return HAL_OK; } } /** * @brief This function allows to stop short circuit detection in polling mode. * @param hdfsdm_channel DFSDM channel handle. * @retval HAL status */ HAL_StatusTypeDef HAL_DFSDM_ChannelScdStop(DFSDM_Channel_HandleTypeDef *hdfsdm_channel) { HAL_StatusTypeDef status = HAL_OK; uint32_t channel; #if defined(DFSDM2_Channel0) DFSDM_Filter_TypeDef* filter0Instance; #endif /* defined(DFSDM2_Channel0) */ /* Check parameters */ assert_param(IS_DFSDM_CHANNEL_ALL_INSTANCE(hdfsdm_channel->Instance)); /* Check DFSDM channel state */ if(hdfsdm_channel->State != HAL_DFSDM_CHANNEL_STATE_READY) { /* Return error status */ status = HAL_ERROR; } else { /* Stop short circuit detection */ hdfsdm_channel->Instance->CHCFGR1 &= ~(DFSDM_CHCFGR1_SCDEN); /* Clear short circuit detection flag */ channel = DFSDM_GetChannelFromInstance(hdfsdm_channel->Instance); #if defined(DFSDM2_Channel0) /* Get channel counter, channel handle table and channel 0 instance */ if(IS_DFSDM1_CHANNEL_INSTANCE(hdfsdm_channel->Instance)) { filter0Instance = DFSDM1_Filter0; } else { filter0Instance = DFSDM2_Filter0; } filter0Instance->FLTICR = (1U << (DFSDM_FLTICR_CLRSCSDF_Pos + channel)); #else DFSDM1_Filter0->FLTICR = (1U << (DFSDM_FLTICR_CLRSCSDF_Pos + channel)); #endif /* DFSDM2_Channel0*/ } /* Return function status */ return status; } /** * @brief This function allows to start short circuit detection in interrupt mode. * @note Same mode has to be used for all channels * @param hdfsdm_channel DFSDM channel handle. * @param Threshold Short circuit detector threshold. * This parameter must be a number between Min_Data = 0 and Max_Data = 255. * @param BreakSignal Break signals assigned to short circuit event. * This parameter can be a values combination of @ref DFSDM_BreakSignals. * @retval HAL status */ HAL_StatusTypeDef HAL_DFSDM_ChannelScdStart_IT(DFSDM_Channel_HandleTypeDef *hdfsdm_channel, uint32_t Threshold, uint32_t BreakSignal) { HAL_StatusTypeDef status = HAL_OK; #if defined(DFSDM2_Channel0) DFSDM_Filter_TypeDef* filter0Instance; #endif /* defined(DFSDM2_Channel0) */ /* Check parameters */ assert_param(IS_DFSDM_CHANNEL_ALL_INSTANCE(hdfsdm_channel->Instance)); assert_param(IS_DFSDM_CHANNEL_SCD_THRESHOLD(Threshold)); assert_param(IS_DFSDM_BREAK_SIGNALS(BreakSignal)); /* Check DFSDM channel state */ if(hdfsdm_channel->State != HAL_DFSDM_CHANNEL_STATE_READY) { /* Return error status */ status = HAL_ERROR; } else { #if defined(DFSDM2_Channel0) /* Get channel counter, channel handle table and channel 0 instance */ if(IS_DFSDM1_CHANNEL_INSTANCE(hdfsdm_channel->Instance)) { filter0Instance = DFSDM1_Filter0; } else { filter0Instance = DFSDM2_Filter0; } /* Activate short circuit detection interrupt */ filter0Instance->FLTCR2 |= DFSDM_FLTCR2_SCDIE; #else /* Activate short circuit detection interrupt */ DFSDM1_Filter0->FLTCR2 |= DFSDM_FLTCR2_SCDIE; #endif /* DFSDM2_Channel0 */ /* Configure threshold and break signals */ hdfsdm_channel->Instance->CHAWSCDR &= ~(DFSDM_CHAWSCDR_BKSCD | DFSDM_CHAWSCDR_SCDT); hdfsdm_channel->Instance->CHAWSCDR |= ((BreakSignal << DFSDM_CHAWSCDR_BKSCD_Pos) | \ Threshold); /* Start short circuit detection */ hdfsdm_channel->Instance->CHCFGR1 |= DFSDM_CHCFGR1_SCDEN; } /* Return function status */ return status; } /** * @brief Short circuit detection callback. * @param hdfsdm_channel DFSDM channel handle. * @retval None */ __weak void HAL_DFSDM_ChannelScdCallback(DFSDM_Channel_HandleTypeDef *hdfsdm_channel) { /* Prevent unused argument(s) compilation warning */ UNUSED(hdfsdm_channel); /* NOTE : This function should not be modified, when the callback is needed, the HAL_DFSDM_ChannelScdCallback could be implemented in the user file */ } /** * @brief This function allows to stop short circuit detection in interrupt mode. * @note Interrupt will be disabled for all channels * @param hdfsdm_channel DFSDM channel handle. * @retval HAL status */ HAL_StatusTypeDef HAL_DFSDM_ChannelScdStop_IT(DFSDM_Channel_HandleTypeDef *hdfsdm_channel) { HAL_StatusTypeDef status = HAL_OK; uint32_t channel; #if defined(DFSDM2_Channel0) DFSDM_Filter_TypeDef* filter0Instance; #endif /* defined(DFSDM2_Channel0) */ /* Check parameters */ assert_param(IS_DFSDM_CHANNEL_ALL_INSTANCE(hdfsdm_channel->Instance)); /* Check DFSDM channel state */ if(hdfsdm_channel->State != HAL_DFSDM_CHANNEL_STATE_READY) { /* Return error status */ status = HAL_ERROR; } else { /* Stop short circuit detection */ hdfsdm_channel->Instance->CHCFGR1 &= ~(DFSDM_CHCFGR1_SCDEN); /* Clear short circuit detection flag */ channel = DFSDM_GetChannelFromInstance(hdfsdm_channel->Instance); #if defined(DFSDM2_Channel0) /* Get channel counter, channel handle table and channel 0 instance */ if(IS_DFSDM1_CHANNEL_INSTANCE(hdfsdm_channel->Instance)) { filter0Instance = DFSDM1_Filter0; } else { filter0Instance = DFSDM2_Filter0; } filter0Instance->FLTICR = (1U << (DFSDM_FLTICR_CLRSCSDF_Pos + channel)); /* Disable short circuit detection interrupt */ filter0Instance->FLTCR2 &= ~(DFSDM_FLTCR2_SCDIE); #else DFSDM1_Filter0->FLTICR = (1U << (DFSDM_FLTICR_CLRSCSDF_Pos + channel)); /* Disable short circuit detection interrupt */ DFSDM1_Filter0->FLTCR2 &= ~(DFSDM_FLTCR2_SCDIE); #endif /* DFSDM2_Channel0 */ } /* Return function status */ return status; } /** * @brief This function allows to get channel analog watchdog value. * @param hdfsdm_channel DFSDM channel handle. * @retval Channel analog watchdog value. */ int16_t HAL_DFSDM_ChannelGetAwdValue(DFSDM_Channel_HandleTypeDef *hdfsdm_channel) { return (int16_t) hdfsdm_channel->Instance->CHWDATAR; } /** * @brief This function allows to modify channel offset value. * @param hdfsdm_channel DFSDM channel handle. * @param Offset DFSDM channel offset. * This parameter must be a number between Min_Data = -8388608 and Max_Data = 8388607. * @retval HAL status. */ HAL_StatusTypeDef HAL_DFSDM_ChannelModifyOffset(DFSDM_Channel_HandleTypeDef *hdfsdm_channel, int32_t Offset) { HAL_StatusTypeDef status = HAL_OK; /* Check parameters */ assert_param(IS_DFSDM_CHANNEL_ALL_INSTANCE(hdfsdm_channel->Instance)); assert_param(IS_DFSDM_CHANNEL_OFFSET(Offset)); /* Check DFSDM channel state */ if(hdfsdm_channel->State != HAL_DFSDM_CHANNEL_STATE_READY) { /* Return error status */ status = HAL_ERROR; } else { /* Modify channel offset */ hdfsdm_channel->Instance->CHCFGR2 &= ~(DFSDM_CHCFGR2_OFFSET); hdfsdm_channel->Instance->CHCFGR2 |= ((uint32_t) Offset << DFSDM_CHCFGR2_OFFSET_Pos); } /* Return function status */ return status; } /** * @} */ /** @defgroup DFSDM_Exported_Functions_Group3_Channel Channel state function * @brief Channel state function * @verbatim ============================================================================== ##### Channel state function ##### ============================================================================== [..] This section provides function allowing to: (+) Get channel handle state. @endverbatim * @{ */ /** * @brief This function allows to get the current DFSDM channel handle state. * @param hdfsdm_channel DFSDM channel handle. * @retval DFSDM channel state. */ HAL_DFSDM_Channel_StateTypeDef HAL_DFSDM_ChannelGetState(DFSDM_Channel_HandleTypeDef *hdfsdm_channel) { /* Return DFSDM channel handle state */ return hdfsdm_channel->State; } /** * @} */ /** @defgroup DFSDM_Exported_Functions_Group1_Filter Filter initialization and de-initialization functions * @brief Filter initialization and de-initialization functions * @verbatim ============================================================================== ##### Filter initialization and de-initialization functions ##### ============================================================================== [..] This section provides functions allowing to: (+) Initialize the DFSDM filter. (+) De-initialize the DFSDM filter. @endverbatim * @{ */ /** * @brief Initialize the DFSDM filter according to the specified parameters * in the DFSDM_FilterInitTypeDef structure and initialize the associated handle. * @param hdfsdm_filter DFSDM filter handle. * @retval HAL status. */ HAL_StatusTypeDef HAL_DFSDM_FilterInit(DFSDM_Filter_HandleTypeDef *hdfsdm_filter) { /* Check DFSDM Channel handle */ if(hdfsdm_filter == NULL) { return HAL_ERROR; } /* Check parameters */ assert_param(IS_DFSDM_FILTER_ALL_INSTANCE(hdfsdm_filter->Instance)); assert_param(IS_DFSDM_FILTER_REG_TRIGGER(hdfsdm_filter->Init.RegularParam.Trigger)); assert_param(IS_FUNCTIONAL_STATE(hdfsdm_filter->Init.RegularParam.FastMode)); assert_param(IS_FUNCTIONAL_STATE(hdfsdm_filter->Init.RegularParam.DmaMode)); assert_param(IS_DFSDM_FILTER_INJ_TRIGGER(hdfsdm_filter->Init.InjectedParam.Trigger)); assert_param(IS_FUNCTIONAL_STATE(hdfsdm_filter->Init.InjectedParam.ScanMode)); assert_param(IS_FUNCTIONAL_STATE(hdfsdm_filter->Init.InjectedParam.DmaMode)); assert_param(IS_DFSDM_FILTER_SINC_ORDER(hdfsdm_filter->Init.FilterParam.SincOrder)); assert_param(IS_DFSDM_FILTER_OVS_RATIO(hdfsdm_filter->Init.FilterParam.Oversampling)); assert_param(IS_DFSDM_FILTER_INTEGRATOR_OVS_RATIO(hdfsdm_filter->Init.FilterParam.IntOversampling)); /* Check parameters compatibility */ if((hdfsdm_filter->Instance == DFSDM1_Filter0) && ((hdfsdm_filter->Init.RegularParam.Trigger == DFSDM_FILTER_SYNC_TRIGGER) || (hdfsdm_filter->Init.InjectedParam.Trigger == DFSDM_FILTER_SYNC_TRIGGER))) { return HAL_ERROR; } #if defined (DFSDM2_Channel0) if((hdfsdm_filter->Instance == DFSDM2_Filter0) && ((hdfsdm_filter->Init.RegularParam.Trigger == DFSDM_FILTER_SYNC_TRIGGER) || (hdfsdm_filter->Init.InjectedParam.Trigger == DFSDM_FILTER_SYNC_TRIGGER))) { return HAL_ERROR; } #endif /* DFSDM2_Channel0 */ /* Initialize DFSDM filter variables with default values */ hdfsdm_filter->RegularContMode = DFSDM_CONTINUOUS_CONV_OFF; hdfsdm_filter->InjectedChannelsNbr = 1U; hdfsdm_filter->InjConvRemaining = 1U; hdfsdm_filter->ErrorCode = DFSDM_FILTER_ERROR_NONE; /* Call MSP init function */ HAL_DFSDM_FilterMspInit(hdfsdm_filter); /* Set regular parameters */ hdfsdm_filter->Instance->FLTCR1 &= ~(DFSDM_FLTCR1_RSYNC); if(hdfsdm_filter->Init.RegularParam.FastMode == ENABLE) { hdfsdm_filter->Instance->FLTCR1 |= DFSDM_FLTCR1_FAST; } else { hdfsdm_filter->Instance->FLTCR1 &= ~(DFSDM_FLTCR1_FAST); } if(hdfsdm_filter->Init.RegularParam.DmaMode == ENABLE) { hdfsdm_filter->Instance->FLTCR1 |= DFSDM_FLTCR1_RDMAEN; } else { hdfsdm_filter->Instance->FLTCR1 &= ~(DFSDM_FLTCR1_RDMAEN); } /* Set injected parameters */ hdfsdm_filter->Instance->FLTCR1 &= ~(DFSDM_FLTCR1_JSYNC | DFSDM_FLTCR1_JEXTEN | DFSDM_FLTCR1_JEXTSEL); if(hdfsdm_filter->Init.InjectedParam.Trigger == DFSDM_FILTER_EXT_TRIGGER) { assert_param(IS_DFSDM_FILTER_EXT_TRIG(hdfsdm_filter->Init.InjectedParam.ExtTrigger)); assert_param(IS_DFSDM_FILTER_EXT_TRIG_EDGE(hdfsdm_filter->Init.InjectedParam.ExtTriggerEdge)); hdfsdm_filter->Instance->FLTCR1 |= (hdfsdm_filter->Init.InjectedParam.ExtTrigger); } if(hdfsdm_filter->Init.InjectedParam.ScanMode == ENABLE) { hdfsdm_filter->Instance->FLTCR1 |= DFSDM_FLTCR1_JSCAN; } else { hdfsdm_filter->Instance->FLTCR1 &= ~(DFSDM_FLTCR1_JSCAN); } if(hdfsdm_filter->Init.InjectedParam.DmaMode == ENABLE) { hdfsdm_filter->Instance->FLTCR1 |= DFSDM_FLTCR1_JDMAEN; } else { hdfsdm_filter->Instance->FLTCR1 &= ~(DFSDM_FLTCR1_JDMAEN); } /* Set filter parameters */ hdfsdm_filter->Instance->FLTFCR &= ~(DFSDM_FLTFCR_FORD | DFSDM_FLTFCR_FOSR | DFSDM_FLTFCR_IOSR); hdfsdm_filter->Instance->FLTFCR |= (hdfsdm_filter->Init.FilterParam.SincOrder | ((hdfsdm_filter->Init.FilterParam.Oversampling - 1U) << DFSDM_FLTFCR_FOSR_Pos) | (hdfsdm_filter->Init.FilterParam.IntOversampling - 1U)); /* Store regular and injected triggers and injected scan mode*/ hdfsdm_filter->RegularTrigger = hdfsdm_filter->Init.RegularParam.Trigger; hdfsdm_filter->InjectedTrigger = hdfsdm_filter->Init.InjectedParam.Trigger; hdfsdm_filter->ExtTriggerEdge = hdfsdm_filter->Init.InjectedParam.ExtTriggerEdge; hdfsdm_filter->InjectedScanMode = hdfsdm_filter->Init.InjectedParam.ScanMode; /* Enable DFSDM filter */ hdfsdm_filter->Instance->FLTCR1 |= DFSDM_FLTCR1_DFEN; /* Set DFSDM filter to ready state */ hdfsdm_filter->State = HAL_DFSDM_FILTER_STATE_READY; return HAL_OK; } /** * @brief De-initializes the DFSDM filter. * @param hdfsdm_filter DFSDM filter handle. * @retval HAL status. */ HAL_StatusTypeDef HAL_DFSDM_FilterDeInit(DFSDM_Filter_HandleTypeDef *hdfsdm_filter) { /* Check DFSDM filter handle */ if(hdfsdm_filter == NULL) { return HAL_ERROR; } /* Check parameters */ assert_param(IS_DFSDM_FILTER_ALL_INSTANCE(hdfsdm_filter->Instance)); /* Disable the DFSDM filter */ hdfsdm_filter->Instance->FLTCR1 &= ~(DFSDM_FLTCR1_DFEN); /* Call MSP deinit function */ HAL_DFSDM_FilterMspDeInit(hdfsdm_filter); /* Set DFSDM filter in reset state */ hdfsdm_filter->State = HAL_DFSDM_FILTER_STATE_RESET; return HAL_OK; } /** * @brief Initializes the DFSDM filter MSP. * @param hdfsdm_filter DFSDM filter handle. * @retval None */ __weak void HAL_DFSDM_FilterMspInit(DFSDM_Filter_HandleTypeDef *hdfsdm_filter) { /* Prevent unused argument(s) compilation warning */ UNUSED(hdfsdm_filter); /* NOTE : This function should not be modified, when the function is needed, the HAL_DFSDM_FilterMspInit could be implemented in the user file. */ } /** * @brief De-initializes the DFSDM filter MSP. * @param hdfsdm_filter DFSDM filter handle. * @retval None */ __weak void HAL_DFSDM_FilterMspDeInit(DFSDM_Filter_HandleTypeDef *hdfsdm_filter) { /* Prevent unused argument(s) compilation warning */ UNUSED(hdfsdm_filter); /* NOTE : This function should not be modified, when the function is needed, the HAL_DFSDM_FilterMspDeInit could be implemented in the user file. */ } /** * @} */ /** @defgroup DFSDM_Exported_Functions_Group2_Filter Filter control functions * @brief Filter control functions * @verbatim ============================================================================== ##### Filter control functions ##### ============================================================================== [..] This section provides functions allowing to: (+) Select channel and enable/disable continuous mode for regular conversion. (+) Select channels for injected conversion. @endverbatim * @{ */ /** * @brief This function allows to select channel and to enable/disable * continuous mode for regular conversion. * @param hdfsdm_filter DFSDM filter handle. * @param Channel Channel for regular conversion. * This parameter can be a value of @ref DFSDM_Channel_Selection. * @param ContinuousMode Enable/disable continuous mode for regular conversion. * This parameter can be a value of @ref DFSDM_ContinuousMode. * @retval HAL status */ HAL_StatusTypeDef HAL_DFSDM_FilterConfigRegChannel(DFSDM_Filter_HandleTypeDef *hdfsdm_filter, uint32_t Channel, uint32_t ContinuousMode) { HAL_StatusTypeDef status = HAL_OK; /* Check parameters */ assert_param(IS_DFSDM_FILTER_ALL_INSTANCE(hdfsdm_filter->Instance)); assert_param(IS_DFSDM_REGULAR_CHANNEL(Channel)); assert_param(IS_DFSDM_CONTINUOUS_MODE(ContinuousMode)); /* Check DFSDM filter state */ if((hdfsdm_filter->State != HAL_DFSDM_FILTER_STATE_RESET) && (hdfsdm_filter->State != HAL_DFSDM_FILTER_STATE_ERROR)) { /* Configure channel and continuous mode for regular conversion */ hdfsdm_filter->Instance->FLTCR1 &= ~(DFSDM_FLTCR1_RCH | DFSDM_FLTCR1_RCONT); if(ContinuousMode == DFSDM_CONTINUOUS_CONV_ON) { hdfsdm_filter->Instance->FLTCR1 |= (uint32_t) (((Channel & DFSDM_MSB_MASK) << DFSDM_FLTCR1_MSB_RCH_OFFSET) | DFSDM_FLTCR1_RCONT); } else { hdfsdm_filter->Instance->FLTCR1 |= (uint32_t) ((Channel & DFSDM_MSB_MASK) << DFSDM_FLTCR1_MSB_RCH_OFFSET); } /* Store continuous mode information */ hdfsdm_filter->RegularContMode = ContinuousMode; } else { status = HAL_ERROR; } /* Return function status */ return status; } /** * @brief This function allows to select channels for injected conversion. * @param hdfsdm_filter DFSDM filter handle. * @param Channel Channels for injected conversion. * This parameter can be a values combination of @ref DFSDM_Channel_Selection. * @retval HAL status */ HAL_StatusTypeDef HAL_DFSDM_FilterConfigInjChannel(DFSDM_Filter_HandleTypeDef *hdfsdm_filter, uint32_t Channel) { HAL_StatusTypeDef status = HAL_OK; /* Check parameters */ assert_param(IS_DFSDM_FILTER_ALL_INSTANCE(hdfsdm_filter->Instance)); assert_param(IS_DFSDM_INJECTED_CHANNEL(Channel)); /* Check DFSDM filter state */ if((hdfsdm_filter->State != HAL_DFSDM_FILTER_STATE_RESET) && (hdfsdm_filter->State != HAL_DFSDM_FILTER_STATE_ERROR)) { /* Configure channel for injected conversion */ hdfsdm_filter->Instance->FLTJCHGR = (uint32_t) (Channel & DFSDM_LSB_MASK); /* Store number of injected channels */ hdfsdm_filter->InjectedChannelsNbr = DFSDM_GetInjChannelsNbr(Channel); /* Update number of injected channels remaining */ hdfsdm_filter->InjConvRemaining = (hdfsdm_filter->InjectedScanMode == ENABLE) ? \ hdfsdm_filter->InjectedChannelsNbr : 1U; } else { status = HAL_ERROR; } /* Return function status */ return status; } /** * @} */ /** @defgroup DFSDM_Exported_Functions_Group3_Filter Filter operation functions * @brief Filter operation functions * @verbatim ============================================================================== ##### Filter operation functions ##### ============================================================================== [..] This section provides functions allowing to: (+) Start conversion of regular/injected channel. (+) Poll for the end of regular/injected conversion. (+) Stop conversion of regular/injected channel. (+) Start conversion of regular/injected channel and enable interrupt. (+) Call the callback functions at the end of regular/injected conversions. (+) Stop conversion of regular/injected channel and disable interrupt. (+) Start conversion of regular/injected channel and enable DMA transfer. (+) Stop conversion of regular/injected channel and disable DMA transfer. (+) Start analog watchdog and enable interrupt. (+) Call the callback function when analog watchdog occurs. (+) Stop analog watchdog and disable interrupt. (+) Start extreme detector. (+) Stop extreme detector. (+) Get result of regular channel conversion. (+) Get result of injected channel conversion. (+) Get extreme detector maximum and minimum values. (+) Get conversion time. (+) Handle DFSDM interrupt request. @endverbatim * @{ */ /** * @brief This function allows to start regular conversion in polling mode. * @note This function should be called only when DFSDM filter instance is * in idle state or if injected conversion is ongoing. * @param hdfsdm_filter DFSDM filter handle. * @retval HAL status */ HAL_StatusTypeDef HAL_DFSDM_FilterRegularStart(DFSDM_Filter_HandleTypeDef *hdfsdm_filter) { HAL_StatusTypeDef status = HAL_OK; /* Check parameters */ assert_param(IS_DFSDM_FILTER_ALL_INSTANCE(hdfsdm_filter->Instance)); /* Check DFSDM filter state */ if((hdfsdm_filter->State == HAL_DFSDM_FILTER_STATE_READY) || \ (hdfsdm_filter->State == HAL_DFSDM_FILTER_STATE_INJ)) { /* Start regular conversion */ DFSDM_RegConvStart(hdfsdm_filter); } else { status = HAL_ERROR; } /* Return function status */ return status; } /** * @brief This function allows to poll for the end of regular conversion. * @note This function should be called only if regular conversion is ongoing. * @param hdfsdm_filter DFSDM filter handle. * @param Timeout Timeout value in milliseconds. * @retval HAL status */ HAL_StatusTypeDef HAL_DFSDM_FilterPollForRegConversion(DFSDM_Filter_HandleTypeDef *hdfsdm_filter, uint32_t Timeout) { uint32_t tickstart; /* Check parameters */ assert_param(IS_DFSDM_FILTER_ALL_INSTANCE(hdfsdm_filter->Instance)); /* Check DFSDM filter state */ if((hdfsdm_filter->State != HAL_DFSDM_FILTER_STATE_REG) && \ (hdfsdm_filter->State != HAL_DFSDM_FILTER_STATE_REG_INJ)) { /* Return error status */ return HAL_ERROR; } else { /* Get timeout */ tickstart = HAL_GetTick(); /* Wait end of regular conversion */ while((hdfsdm_filter->Instance->FLTISR & DFSDM_FLTISR_REOCF) != DFSDM_FLTISR_REOCF) { /* Check the Timeout */ if(Timeout != HAL_MAX_DELAY) { if((Timeout == 0U) || ((HAL_GetTick()-tickstart) > Timeout)) { /* Return timeout status */ return HAL_TIMEOUT; } } } /* Check if overrun occurs */ if((hdfsdm_filter->Instance->FLTISR & DFSDM_FLTISR_ROVRF) == DFSDM_FLTISR_ROVRF) { /* Update error code and call error callback */ hdfsdm_filter->ErrorCode = DFSDM_FILTER_ERROR_REGULAR_OVERRUN; HAL_DFSDM_FilterErrorCallback(hdfsdm_filter); /* Clear regular overrun flag */ hdfsdm_filter->Instance->FLTICR = DFSDM_FLTICR_CLRROVRF; } /* Update DFSDM filter state only if not continuous conversion and SW trigger */ if((hdfsdm_filter->RegularContMode == DFSDM_CONTINUOUS_CONV_OFF) && \ (hdfsdm_filter->RegularTrigger == DFSDM_FILTER_SW_TRIGGER)) { hdfsdm_filter->State = (hdfsdm_filter->State == HAL_DFSDM_FILTER_STATE_REG) ? \ HAL_DFSDM_FILTER_STATE_READY : HAL_DFSDM_FILTER_STATE_INJ; } /* Return function status */ return HAL_OK; } } /** * @brief This function allows to stop regular conversion in polling mode. * @note This function should be called only if regular conversion is ongoing. * @param hdfsdm_filter DFSDM filter handle. * @retval HAL status */ HAL_StatusTypeDef HAL_DFSDM_FilterRegularStop(DFSDM_Filter_HandleTypeDef *hdfsdm_filter) { HAL_StatusTypeDef status = HAL_OK; /* Check parameters */ assert_param(IS_DFSDM_FILTER_ALL_INSTANCE(hdfsdm_filter->Instance)); /* Check DFSDM filter state */ if((hdfsdm_filter->State != HAL_DFSDM_FILTER_STATE_REG) && \ (hdfsdm_filter->State != HAL_DFSDM_FILTER_STATE_REG_INJ)) { /* Return error status */ status = HAL_ERROR; } else { /* Stop regular conversion */ DFSDM_RegConvStop(hdfsdm_filter); } /* Return function status */ return status; } /** * @brief This function allows to start regular conversion in interrupt mode. * @note This function should be called only when DFSDM filter instance is * in idle state or if injected conversion is ongoing. * @param hdfsdm_filter DFSDM filter handle. * @retval HAL status */ HAL_StatusTypeDef HAL_DFSDM_FilterRegularStart_IT(DFSDM_Filter_HandleTypeDef *hdfsdm_filter) { HAL_StatusTypeDef status = HAL_OK; /* Check parameters */ assert_param(IS_DFSDM_FILTER_ALL_INSTANCE(hdfsdm_filter->Instance)); /* Check DFSDM filter state */ if((hdfsdm_filter->State == HAL_DFSDM_FILTER_STATE_READY) || \ (hdfsdm_filter->State == HAL_DFSDM_FILTER_STATE_INJ)) { /* Enable interrupts for regular conversions */ hdfsdm_filter->Instance->FLTCR2 |= (DFSDM_FLTCR2_REOCIE | DFSDM_FLTCR2_ROVRIE); /* Start regular conversion */ DFSDM_RegConvStart(hdfsdm_filter); } else { status = HAL_ERROR; } /* Return function status */ return status; } /** * @brief This function allows to stop regular conversion in interrupt mode. * @note This function should be called only if regular conversion is ongoing. * @param hdfsdm_filter DFSDM filter handle. * @retval HAL status */ HAL_StatusTypeDef HAL_DFSDM_FilterRegularStop_IT(DFSDM_Filter_HandleTypeDef *hdfsdm_filter) { HAL_StatusTypeDef status = HAL_OK; /* Check parameters */ assert_param(IS_DFSDM_FILTER_ALL_INSTANCE(hdfsdm_filter->Instance)); /* Check DFSDM filter state */ if((hdfsdm_filter->State != HAL_DFSDM_FILTER_STATE_REG) && \ (hdfsdm_filter->State != HAL_DFSDM_FILTER_STATE_REG_INJ)) { /* Return error status */ status = HAL_ERROR; } else { /* Disable interrupts for regular conversions */ hdfsdm_filter->Instance->FLTCR2 &= ~(DFSDM_FLTCR2_REOCIE | DFSDM_FLTCR2_ROVRIE); /* Stop regular conversion */ DFSDM_RegConvStop(hdfsdm_filter); } /* Return function status */ return status; } /** * @brief This function allows to start regular conversion in DMA mode. * @note This function should be called only when DFSDM filter instance is * in idle state or if injected conversion is ongoing. * Please note that data on buffer will contain signed regular conversion * value on 24 most significant bits and corresponding channel on 3 least * significant bits. * @param hdfsdm_filter DFSDM filter handle. * @param pData The destination buffer address. * @param Length The length of data to be transferred from DFSDM filter to memory. * @retval HAL status */ HAL_StatusTypeDef HAL_DFSDM_FilterRegularStart_DMA(DFSDM_Filter_HandleTypeDef *hdfsdm_filter, int32_t *pData, uint32_t Length) { HAL_StatusTypeDef status = HAL_OK; /* Check parameters */ assert_param(IS_DFSDM_FILTER_ALL_INSTANCE(hdfsdm_filter->Instance)); /* Check destination address and length */ if((pData == NULL) || (Length == 0U)) { status = HAL_ERROR; } /* Check that DMA is enabled for regular conversion */ else if((hdfsdm_filter->Instance->FLTCR1 & DFSDM_FLTCR1_RDMAEN) != DFSDM_FLTCR1_RDMAEN) { status = HAL_ERROR; } /* Check parameters compatibility */ else if((hdfsdm_filter->RegularTrigger == DFSDM_FILTER_SW_TRIGGER) && \ (hdfsdm_filter->RegularContMode == DFSDM_CONTINUOUS_CONV_OFF) && \ (hdfsdm_filter->hdmaReg->Init.Mode == DMA_NORMAL) && \ (Length != 1U)) { status = HAL_ERROR; } else if((hdfsdm_filter->RegularTrigger == DFSDM_FILTER_SW_TRIGGER) && \ (hdfsdm_filter->RegularContMode == DFSDM_CONTINUOUS_CONV_OFF) && \ (hdfsdm_filter->hdmaReg->Init.Mode == DMA_CIRCULAR)) { status = HAL_ERROR; } /* Check DFSDM filter state */ else if((hdfsdm_filter->State == HAL_DFSDM_FILTER_STATE_READY) || \ (hdfsdm_filter->State == HAL_DFSDM_FILTER_STATE_INJ)) { /* Set callbacks on DMA handler */ hdfsdm_filter->hdmaReg->XferCpltCallback = DFSDM_DMARegularConvCplt; hdfsdm_filter->hdmaReg->XferErrorCallback = DFSDM_DMAError; hdfsdm_filter->hdmaReg->XferHalfCpltCallback = (hdfsdm_filter->hdmaReg->Init.Mode == DMA_CIRCULAR) ?\ DFSDM_DMARegularHalfConvCplt : NULL; /* Start DMA in interrupt mode */ if(HAL_DMA_Start_IT(hdfsdm_filter->hdmaReg, (uint32_t)&hdfsdm_filter->Instance->FLTRDATAR, \ (uint32_t) pData, Length) != HAL_OK) { /* Set DFSDM filter in error state */ hdfsdm_filter->State = HAL_DFSDM_FILTER_STATE_ERROR; status = HAL_ERROR; } else { /* Start regular conversion */ DFSDM_RegConvStart(hdfsdm_filter); } } else { status = HAL_ERROR; } /* Return function status */ return status; } /** * @brief This function allows to start regular conversion in DMA mode and to get * only the 16 most significant bits of conversion. * @note This function should be called only when DFSDM filter instance is * in idle state or if injected conversion is ongoing. * Please note that data on buffer will contain signed 16 most significant * bits of regular conversion. * @param hdfsdm_filter DFSDM filter handle. * @param pData The destination buffer address. * @param Length The length of data to be transferred from DFSDM filter to memory. * @retval HAL status */ HAL_StatusTypeDef HAL_DFSDM_FilterRegularMsbStart_DMA(DFSDM_Filter_HandleTypeDef *hdfsdm_filter, int16_t *pData, uint32_t Length) { HAL_StatusTypeDef status = HAL_OK; /* Check parameters */ assert_param(IS_DFSDM_FILTER_ALL_INSTANCE(hdfsdm_filter->Instance)); /* Check destination address and length */ if((pData == NULL) || (Length == 0U)) { status = HAL_ERROR; } /* Check that DMA is enabled for regular conversion */ else if((hdfsdm_filter->Instance->FLTCR1 & DFSDM_FLTCR1_RDMAEN) != DFSDM_FLTCR1_RDMAEN) { status = HAL_ERROR; } /* Check parameters compatibility */ else if((hdfsdm_filter->RegularTrigger == DFSDM_FILTER_SW_TRIGGER) && \ (hdfsdm_filter->RegularContMode == DFSDM_CONTINUOUS_CONV_OFF) && \ (hdfsdm_filter->hdmaReg->Init.Mode == DMA_NORMAL) && \ (Length != 1U)) { status = HAL_ERROR; } else if((hdfsdm_filter->RegularTrigger == DFSDM_FILTER_SW_TRIGGER) && \ (hdfsdm_filter->RegularContMode == DFSDM_CONTINUOUS_CONV_OFF) && \ (hdfsdm_filter->hdmaReg->Init.Mode == DMA_CIRCULAR)) { status = HAL_ERROR; } /* Check DFSDM filter state */ else if((hdfsdm_filter->State == HAL_DFSDM_FILTER_STATE_READY) || \ (hdfsdm_filter->State == HAL_DFSDM_FILTER_STATE_INJ)) { /* Set callbacks on DMA handler */ hdfsdm_filter->hdmaReg->XferCpltCallback = DFSDM_DMARegularConvCplt; hdfsdm_filter->hdmaReg->XferErrorCallback = DFSDM_DMAError; hdfsdm_filter->hdmaReg->XferHalfCpltCallback = (hdfsdm_filter->hdmaReg->Init.Mode == DMA_CIRCULAR) ?\ DFSDM_DMARegularHalfConvCplt : NULL; /* Start DMA in interrupt mode */ if(HAL_DMA_Start_IT(hdfsdm_filter->hdmaReg, (uint32_t)(&hdfsdm_filter->Instance->FLTRDATAR) + 2U, \ (uint32_t) pData, Length) != HAL_OK) { /* Set DFSDM filter in error state */ hdfsdm_filter->State = HAL_DFSDM_FILTER_STATE_ERROR; status = HAL_ERROR; } else { /* Start regular conversion */ DFSDM_RegConvStart(hdfsdm_filter); } } else { status = HAL_ERROR; } /* Return function status */ return status; } /** * @brief This function allows to stop regular conversion in DMA mode. * @note This function should be called only if regular conversion is ongoing. * @param hdfsdm_filter DFSDM filter handle. * @retval HAL status */ HAL_StatusTypeDef HAL_DFSDM_FilterRegularStop_DMA(DFSDM_Filter_HandleTypeDef *hdfsdm_filter) { HAL_StatusTypeDef status = HAL_OK; /* Check parameters */ assert_param(IS_DFSDM_FILTER_ALL_INSTANCE(hdfsdm_filter->Instance)); /* Check DFSDM filter state */ if((hdfsdm_filter->State != HAL_DFSDM_FILTER_STATE_REG) && \ (hdfsdm_filter->State != HAL_DFSDM_FILTER_STATE_REG_INJ)) { /* Return error status */ status = HAL_ERROR; } else { /* Stop current DMA transfer */ if(HAL_DMA_Abort(hdfsdm_filter->hdmaReg) != HAL_OK) { /* Set DFSDM filter in error state */ hdfsdm_filter->State = HAL_DFSDM_FILTER_STATE_ERROR; status = HAL_ERROR; } else { /* Stop regular conversion */ DFSDM_RegConvStop(hdfsdm_filter); } } /* Return function status */ return status; } /** * @brief This function allows to get regular conversion value. * @param hdfsdm_filter DFSDM filter handle. * @param Channel Corresponding channel of regular conversion. * @retval Regular conversion value */ int32_t HAL_DFSDM_FilterGetRegularValue(DFSDM_Filter_HandleTypeDef *hdfsdm_filter, uint32_t *Channel) { uint32_t reg = 0U; int32_t value = 0; /* Check parameters */ assert_param(IS_DFSDM_FILTER_ALL_INSTANCE(hdfsdm_filter->Instance)); assert_param(Channel != NULL); /* Get value of data register for regular channel */ reg = hdfsdm_filter->Instance->FLTRDATAR; /* Extract channel and regular conversion value */ *Channel = (reg & DFSDM_FLTRDATAR_RDATACH); value = ((int32_t)(reg & DFSDM_FLTRDATAR_RDATA) >> DFSDM_FLTRDATAR_RDATA_Pos); /* return regular conversion value */ return value; } /** * @brief This function allows to start injected conversion in polling mode. * @note This function should be called only when DFSDM filter instance is * in idle state or if regular conversion is ongoing. * @param hdfsdm_filter DFSDM filter handle. * @retval HAL status */ HAL_StatusTypeDef HAL_DFSDM_FilterInjectedStart(DFSDM_Filter_HandleTypeDef *hdfsdm_filter) { HAL_StatusTypeDef status = HAL_OK; /* Check parameters */ assert_param(IS_DFSDM_FILTER_ALL_INSTANCE(hdfsdm_filter->Instance)); /* Check DFSDM filter state */ if((hdfsdm_filter->State == HAL_DFSDM_FILTER_STATE_READY) || \ (hdfsdm_filter->State == HAL_DFSDM_FILTER_STATE_REG)) { /* Start injected conversion */ DFSDM_InjConvStart(hdfsdm_filter); } else { status = HAL_ERROR; } /* Return function status */ return status; } /** * @brief This function allows to poll for the end of injected conversion. * @note This function should be called only if injected conversion is ongoing. * @param hdfsdm_filter DFSDM filter handle. * @param Timeout Timeout value in milliseconds. * @retval HAL status */ HAL_StatusTypeDef HAL_DFSDM_FilterPollForInjConversion(DFSDM_Filter_HandleTypeDef *hdfsdm_filter, uint32_t Timeout) { uint32_t tickstart; /* Check parameters */ assert_param(IS_DFSDM_FILTER_ALL_INSTANCE(hdfsdm_filter->Instance)); /* Check DFSDM filter state */ if((hdfsdm_filter->State != HAL_DFSDM_FILTER_STATE_INJ) && \ (hdfsdm_filter->State != HAL_DFSDM_FILTER_STATE_REG_INJ)) { /* Return error status */ return HAL_ERROR; } else { /* Get timeout */ tickstart = HAL_GetTick(); /* Wait end of injected conversions */ while((hdfsdm_filter->Instance->FLTISR & DFSDM_FLTISR_JEOCF) != DFSDM_FLTISR_JEOCF) { /* Check the Timeout */ if(Timeout != HAL_MAX_DELAY) { if((Timeout == 0U) || ((HAL_GetTick()-tickstart) > Timeout)) { /* Return timeout status */ return HAL_TIMEOUT; } } } /* Check if overrun occurs */ if((hdfsdm_filter->Instance->FLTISR & DFSDM_FLTISR_JOVRF) == DFSDM_FLTISR_JOVRF) { /* Update error code and call error callback */ hdfsdm_filter->ErrorCode = DFSDM_FILTER_ERROR_INJECTED_OVERRUN; HAL_DFSDM_FilterErrorCallback(hdfsdm_filter); /* Clear injected overrun flag */ hdfsdm_filter->Instance->FLTICR = DFSDM_FLTICR_CLRJOVRF; } /* Update remaining injected conversions */ hdfsdm_filter->InjConvRemaining--; if(hdfsdm_filter->InjConvRemaining == 0U) { /* Update DFSDM filter state only if trigger is software */ if(hdfsdm_filter->InjectedTrigger == DFSDM_FILTER_SW_TRIGGER) { hdfsdm_filter->State = (hdfsdm_filter->State == HAL_DFSDM_FILTER_STATE_INJ) ? \ HAL_DFSDM_FILTER_STATE_READY : HAL_DFSDM_FILTER_STATE_REG; } /* end of injected sequence, reset the value */ hdfsdm_filter->InjConvRemaining = (hdfsdm_filter->InjectedScanMode == ENABLE) ? \ hdfsdm_filter->InjectedChannelsNbr : 1U; } /* Return function status */ return HAL_OK; } } /** * @brief This function allows to stop injected conversion in polling mode. * @note This function should be called only if injected conversion is ongoing. * @param hdfsdm_filter DFSDM filter handle. * @retval HAL status */ HAL_StatusTypeDef HAL_DFSDM_FilterInjectedStop(DFSDM_Filter_HandleTypeDef *hdfsdm_filter) { HAL_StatusTypeDef status = HAL_OK; /* Check parameters */ assert_param(IS_DFSDM_FILTER_ALL_INSTANCE(hdfsdm_filter->Instance)); /* Check DFSDM filter state */ if((hdfsdm_filter->State != HAL_DFSDM_FILTER_STATE_INJ) && \ (hdfsdm_filter->State != HAL_DFSDM_FILTER_STATE_REG_INJ)) { /* Return error status */ status = HAL_ERROR; } else { /* Stop injected conversion */ DFSDM_InjConvStop(hdfsdm_filter); } /* Return function status */ return status; } /** * @brief This function allows to start injected conversion in interrupt mode. * @note This function should be called only when DFSDM filter instance is * in idle state or if regular conversion is ongoing. * @param hdfsdm_filter DFSDM filter handle. * @retval HAL status */ HAL_StatusTypeDef HAL_DFSDM_FilterInjectedStart_IT(DFSDM_Filter_HandleTypeDef *hdfsdm_filter) { HAL_StatusTypeDef status = HAL_OK; /* Check parameters */ assert_param(IS_DFSDM_FILTER_ALL_INSTANCE(hdfsdm_filter->Instance)); /* Check DFSDM filter state */ if((hdfsdm_filter->State == HAL_DFSDM_FILTER_STATE_READY) || \ (hdfsdm_filter->State == HAL_DFSDM_FILTER_STATE_REG)) { /* Enable interrupts for injected conversions */ hdfsdm_filter->Instance->FLTCR2 |= (DFSDM_FLTCR2_JEOCIE | DFSDM_FLTCR2_JOVRIE); /* Start injected conversion */ DFSDM_InjConvStart(hdfsdm_filter); } else { status = HAL_ERROR; } /* Return function status */ return status; } /** * @brief This function allows to stop injected conversion in interrupt mode. * @note This function should be called only if injected conversion is ongoing. * @param hdfsdm_filter DFSDM filter handle. * @retval HAL status */ HAL_StatusTypeDef HAL_DFSDM_FilterInjectedStop_IT(DFSDM_Filter_HandleTypeDef *hdfsdm_filter) { HAL_StatusTypeDef status = HAL_OK; /* Check parameters */ assert_param(IS_DFSDM_FILTER_ALL_INSTANCE(hdfsdm_filter->Instance)); /* Check DFSDM filter state */ if((hdfsdm_filter->State != HAL_DFSDM_FILTER_STATE_INJ) && \ (hdfsdm_filter->State != HAL_DFSDM_FILTER_STATE_REG_INJ)) { /* Return error status */ status = HAL_ERROR; } else { /* Disable interrupts for injected conversions */ hdfsdm_filter->Instance->FLTCR2 &= ~(DFSDM_FLTCR2_JEOCIE | DFSDM_FLTCR2_JOVRIE); /* Stop injected conversion */ DFSDM_InjConvStop(hdfsdm_filter); } /* Return function status */ return status; } /** * @brief This function allows to start injected conversion in DMA mode. * @note This function should be called only when DFSDM filter instance is * in idle state or if regular conversion is ongoing. * Please note that data on buffer will contain signed injected conversion * value on 24 most significant bits and corresponding channel on 3 least * significant bits. * @param hdfsdm_filter DFSDM filter handle. * @param pData The destination buffer address. * @param Length The length of data to be transferred from DFSDM filter to memory. * @retval HAL status */ HAL_StatusTypeDef HAL_DFSDM_FilterInjectedStart_DMA(DFSDM_Filter_HandleTypeDef *hdfsdm_filter, int32_t *pData, uint32_t Length) { HAL_StatusTypeDef status = HAL_OK; /* Check parameters */ assert_param(IS_DFSDM_FILTER_ALL_INSTANCE(hdfsdm_filter->Instance)); /* Check destination address and length */ if((pData == NULL) || (Length == 0U)) { status = HAL_ERROR; } /* Check that DMA is enabled for injected conversion */ else if((hdfsdm_filter->Instance->FLTCR1 & DFSDM_FLTCR1_JDMAEN) != DFSDM_FLTCR1_JDMAEN) { status = HAL_ERROR; } /* Check parameters compatibility */ else if((hdfsdm_filter->InjectedTrigger == DFSDM_FILTER_SW_TRIGGER) && \ (hdfsdm_filter->hdmaInj->Init.Mode == DMA_NORMAL) && \ (Length > hdfsdm_filter->InjConvRemaining)) { status = HAL_ERROR; } else if((hdfsdm_filter->InjectedTrigger == DFSDM_FILTER_SW_TRIGGER) && \ (hdfsdm_filter->hdmaInj->Init.Mode == DMA_CIRCULAR)) { status = HAL_ERROR; } /* Check DFSDM filter state */ else if((hdfsdm_filter->State == HAL_DFSDM_FILTER_STATE_READY) || \ (hdfsdm_filter->State == HAL_DFSDM_FILTER_STATE_REG)) { /* Set callbacks on DMA handler */ hdfsdm_filter->hdmaInj->XferCpltCallback = DFSDM_DMAInjectedConvCplt; hdfsdm_filter->hdmaInj->XferErrorCallback = DFSDM_DMAError; hdfsdm_filter->hdmaInj->XferHalfCpltCallback = (hdfsdm_filter->hdmaInj->Init.Mode == DMA_CIRCULAR) ?\ DFSDM_DMAInjectedHalfConvCplt : NULL; /* Start DMA in interrupt mode */ if(HAL_DMA_Start_IT(hdfsdm_filter->hdmaInj, (uint32_t)&hdfsdm_filter->Instance->FLTJDATAR, \ (uint32_t) pData, Length) != HAL_OK) { /* Set DFSDM filter in error state */ hdfsdm_filter->State = HAL_DFSDM_FILTER_STATE_ERROR; status = HAL_ERROR; } else { /* Start injected conversion */ DFSDM_InjConvStart(hdfsdm_filter); } } else { status = HAL_ERROR; } /* Return function status */ return status; } /** * @brief This function allows to start injected conversion in DMA mode and to get * only the 16 most significant bits of conversion. * @note This function should be called only when DFSDM filter instance is * in idle state or if regular conversion is ongoing. * Please note that data on buffer will contain signed 16 most significant * bits of injected conversion. * @param hdfsdm_filter DFSDM filter handle. * @param pData The destination buffer address. * @param Length The length of data to be transferred from DFSDM filter to memory. * @retval HAL status */ HAL_StatusTypeDef HAL_DFSDM_FilterInjectedMsbStart_DMA(DFSDM_Filter_HandleTypeDef *hdfsdm_filter, int16_t *pData, uint32_t Length) { HAL_StatusTypeDef status = HAL_OK; /* Check parameters */ assert_param(IS_DFSDM_FILTER_ALL_INSTANCE(hdfsdm_filter->Instance)); /* Check destination address and length */ if((pData == NULL) || (Length == 0U)) { status = HAL_ERROR; } /* Check that DMA is enabled for injected conversion */ else if((hdfsdm_filter->Instance->FLTCR1 & DFSDM_FLTCR1_JDMAEN) != DFSDM_FLTCR1_JDMAEN) { status = HAL_ERROR; } /* Check parameters compatibility */ else if((hdfsdm_filter->InjectedTrigger == DFSDM_FILTER_SW_TRIGGER) && \ (hdfsdm_filter->hdmaInj->Init.Mode == DMA_NORMAL) && \ (Length > hdfsdm_filter->InjConvRemaining)) { status = HAL_ERROR; } else if((hdfsdm_filter->InjectedTrigger == DFSDM_FILTER_SW_TRIGGER) && \ (hdfsdm_filter->hdmaInj->Init.Mode == DMA_CIRCULAR)) { status = HAL_ERROR; } /* Check DFSDM filter state */ else if((hdfsdm_filter->State == HAL_DFSDM_FILTER_STATE_READY) || \ (hdfsdm_filter->State == HAL_DFSDM_FILTER_STATE_REG)) { /* Set callbacks on DMA handler */ hdfsdm_filter->hdmaInj->XferCpltCallback = DFSDM_DMAInjectedConvCplt; hdfsdm_filter->hdmaInj->XferErrorCallback = DFSDM_DMAError; hdfsdm_filter->hdmaInj->XferHalfCpltCallback = (hdfsdm_filter->hdmaInj->Init.Mode == DMA_CIRCULAR) ?\ DFSDM_DMAInjectedHalfConvCplt : NULL; /* Start DMA in interrupt mode */ if(HAL_DMA_Start_IT(hdfsdm_filter->hdmaInj, (uint32_t)(&hdfsdm_filter->Instance->FLTJDATAR) + 2U, \ (uint32_t) pData, Length) != HAL_OK) { /* Set DFSDM filter in error state */ hdfsdm_filter->State = HAL_DFSDM_FILTER_STATE_ERROR; status = HAL_ERROR; } else { /* Start injected conversion */ DFSDM_InjConvStart(hdfsdm_filter); } } else { status = HAL_ERROR; } /* Return function status */ return status; } /** * @brief This function allows to stop injected conversion in DMA mode. * @note This function should be called only if injected conversion is ongoing. * @param hdfsdm_filter DFSDM filter handle. * @retval HAL status */ HAL_StatusTypeDef HAL_DFSDM_FilterInjectedStop_DMA(DFSDM_Filter_HandleTypeDef *hdfsdm_filter) { HAL_StatusTypeDef status = HAL_OK; /* Check parameters */ assert_param(IS_DFSDM_FILTER_ALL_INSTANCE(hdfsdm_filter->Instance)); /* Check DFSDM filter state */ if((hdfsdm_filter->State != HAL_DFSDM_FILTER_STATE_INJ) && \ (hdfsdm_filter->State != HAL_DFSDM_FILTER_STATE_REG_INJ)) { /* Return error status */ status = HAL_ERROR; } else { /* Stop current DMA transfer */ if(HAL_DMA_Abort(hdfsdm_filter->hdmaInj) != HAL_OK) { /* Set DFSDM filter in error state */ hdfsdm_filter->State = HAL_DFSDM_FILTER_STATE_ERROR; status = HAL_ERROR; } else { /* Stop regular conversion */ DFSDM_InjConvStop(hdfsdm_filter); } } /* Return function status */ return status; } /** * @brief This function allows to get injected conversion value. * @param hdfsdm_filter DFSDM filter handle. * @param Channel Corresponding channel of injected conversion. * @retval Injected conversion value */ int32_t HAL_DFSDM_FilterGetInjectedValue(DFSDM_Filter_HandleTypeDef *hdfsdm_filter, uint32_t *Channel) { uint32_t reg = 0U; int32_t value = 0; /* Check parameters */ assert_param(IS_DFSDM_FILTER_ALL_INSTANCE(hdfsdm_filter->Instance)); assert_param(Channel != NULL); /* Get value of data register for injected channel */ reg = hdfsdm_filter->Instance->FLTJDATAR; /* Extract channel and injected conversion value */ *Channel = (reg & DFSDM_FLTJDATAR_JDATACH); value = ((int32_t)(reg & DFSDM_FLTJDATAR_JDATA) >> DFSDM_FLTJDATAR_JDATA_Pos); /* return regular conversion value */ return value; } /** * @brief This function allows to start filter analog watchdog in interrupt mode. * @param hdfsdm_filter DFSDM filter handle. * @param awdParam DFSDM filter analog watchdog parameters. * @retval HAL status */ HAL_StatusTypeDef HAL_DFSDM_FilterAwdStart_IT(DFSDM_Filter_HandleTypeDef *hdfsdm_filter, DFSDM_Filter_AwdParamTypeDef *awdParam) { HAL_StatusTypeDef status = HAL_OK; /* Check parameters */ assert_param(IS_DFSDM_FILTER_ALL_INSTANCE(hdfsdm_filter->Instance)); assert_param(IS_DFSDM_FILTER_AWD_DATA_SOURCE(awdParam->DataSource)); assert_param(IS_DFSDM_INJECTED_CHANNEL(awdParam->Channel)); assert_param(IS_DFSDM_FILTER_AWD_THRESHOLD(awdParam->HighThreshold)); assert_param(IS_DFSDM_FILTER_AWD_THRESHOLD(awdParam->LowThreshold)); assert_param(IS_DFSDM_BREAK_SIGNALS(awdParam->HighBreakSignal)); assert_param(IS_DFSDM_BREAK_SIGNALS(awdParam->LowBreakSignal)); /* Check DFSDM filter state */ if((hdfsdm_filter->State == HAL_DFSDM_FILTER_STATE_RESET) || \ (hdfsdm_filter->State == HAL_DFSDM_FILTER_STATE_ERROR)) { /* Return error status */ status = HAL_ERROR; } else { /* Set analog watchdog data source */ hdfsdm_filter->Instance->FLTCR1 &= ~(DFSDM_FLTCR1_AWFSEL); hdfsdm_filter->Instance->FLTCR1 |= awdParam->DataSource; /* Set thresholds and break signals */ hdfsdm_filter->Instance->FLTAWHTR &= ~(DFSDM_FLTAWHTR_AWHT | DFSDM_FLTAWHTR_BKAWH); hdfsdm_filter->Instance->FLTAWHTR |= (((uint32_t) awdParam->HighThreshold << DFSDM_FLTAWHTR_AWHT_Pos) | \ awdParam->HighBreakSignal); hdfsdm_filter->Instance->FLTAWLTR &= ~(DFSDM_FLTAWLTR_AWLT | DFSDM_FLTAWLTR_BKAWL); hdfsdm_filter->Instance->FLTAWLTR |= (((uint32_t) awdParam->LowThreshold << DFSDM_FLTAWLTR_AWLT_Pos) | \ awdParam->LowBreakSignal); /* Set channels and interrupt for analog watchdog */ hdfsdm_filter->Instance->FLTCR2 &= ~(DFSDM_FLTCR2_AWDCH); hdfsdm_filter->Instance->FLTCR2 |= (((awdParam->Channel & DFSDM_LSB_MASK) << DFSDM_FLTCR2_AWDCH_Pos) | \ DFSDM_FLTCR2_AWDIE); } /* Return function status */ return status; } /** * @brief This function allows to stop filter analog watchdog in interrupt mode. * @param hdfsdm_filter DFSDM filter handle. * @retval HAL status */ HAL_StatusTypeDef HAL_DFSDM_FilterAwdStop_IT(DFSDM_Filter_HandleTypeDef *hdfsdm_filter) { HAL_StatusTypeDef status = HAL_OK; /* Check parameters */ assert_param(IS_DFSDM_FILTER_ALL_INSTANCE(hdfsdm_filter->Instance)); /* Check DFSDM filter state */ if((hdfsdm_filter->State == HAL_DFSDM_FILTER_STATE_RESET) || \ (hdfsdm_filter->State == HAL_DFSDM_FILTER_STATE_ERROR)) { /* Return error status */ status = HAL_ERROR; } else { /* Reset channels for analog watchdog and deactivate interrupt */ hdfsdm_filter->Instance->FLTCR2 &= ~(DFSDM_FLTCR2_AWDCH | DFSDM_FLTCR2_AWDIE); /* Clear all analog watchdog flags */ hdfsdm_filter->Instance->FLTAWCFR = (DFSDM_FLTAWCFR_CLRAWHTF | DFSDM_FLTAWCFR_CLRAWLTF); /* Reset thresholds and break signals */ hdfsdm_filter->Instance->FLTAWHTR &= ~(DFSDM_FLTAWHTR_AWHT | DFSDM_FLTAWHTR_BKAWH); hdfsdm_filter->Instance->FLTAWLTR &= ~(DFSDM_FLTAWLTR_AWLT | DFSDM_FLTAWLTR_BKAWL); /* Reset analog watchdog data source */ hdfsdm_filter->Instance->FLTCR1 &= ~(DFSDM_FLTCR1_AWFSEL); } /* Return function status */ return status; } /** * @brief This function allows to start extreme detector feature. * @param hdfsdm_filter DFSDM filter handle. * @param Channel Channels where extreme detector is enabled. * This parameter can be a values combination of @ref DFSDM_Channel_Selection. * @retval HAL status */ HAL_StatusTypeDef HAL_DFSDM_FilterExdStart(DFSDM_Filter_HandleTypeDef *hdfsdm_filter, uint32_t Channel) { HAL_StatusTypeDef status = HAL_OK; /* Check parameters */ assert_param(IS_DFSDM_FILTER_ALL_INSTANCE(hdfsdm_filter->Instance)); assert_param(IS_DFSDM_INJECTED_CHANNEL(Channel)); /* Check DFSDM filter state */ if((hdfsdm_filter->State == HAL_DFSDM_FILTER_STATE_RESET) || \ (hdfsdm_filter->State == HAL_DFSDM_FILTER_STATE_ERROR)) { /* Return error status */ status = HAL_ERROR; } else { /* Set channels for extreme detector */ hdfsdm_filter->Instance->FLTCR2 &= ~(DFSDM_FLTCR2_EXCH); hdfsdm_filter->Instance->FLTCR2 |= ((Channel & DFSDM_LSB_MASK) << DFSDM_FLTCR2_EXCH_Pos); } /* Return function status */ return status; } /** * @brief This function allows to stop extreme detector feature. * @param hdfsdm_filter DFSDM filter handle. * @retval HAL status */ HAL_StatusTypeDef HAL_DFSDM_FilterExdStop(DFSDM_Filter_HandleTypeDef *hdfsdm_filter) { HAL_StatusTypeDef status = HAL_OK; __IO uint32_t reg1; __IO uint32_t reg2; /* Check parameters */ assert_param(IS_DFSDM_FILTER_ALL_INSTANCE(hdfsdm_filter->Instance)); /* Check DFSDM filter state */ if((hdfsdm_filter->State == HAL_DFSDM_FILTER_STATE_RESET) || \ (hdfsdm_filter->State == HAL_DFSDM_FILTER_STATE_ERROR)) { /* Return error status */ status = HAL_ERROR; } else { /* Reset channels for extreme detector */ hdfsdm_filter->Instance->FLTCR2 &= ~(DFSDM_FLTCR2_EXCH); /* Clear extreme detector values */ reg1 = hdfsdm_filter->Instance->FLTEXMAX; reg2 = hdfsdm_filter->Instance->FLTEXMIN; UNUSED(reg1); /* To avoid GCC warning */ UNUSED(reg2); /* To avoid GCC warning */ } /* Return function status */ return status; } /** * @brief This function allows to get extreme detector maximum value. * @param hdfsdm_filter DFSDM filter handle. * @param Channel Corresponding channel. * @retval Extreme detector maximum value * This value is between Min_Data = -8388608 and Max_Data = 8388607. */ int32_t HAL_DFSDM_FilterGetExdMaxValue(DFSDM_Filter_HandleTypeDef *hdfsdm_filter, uint32_t *Channel) { uint32_t reg = 0U; int32_t value = 0; /* Check parameters */ assert_param(IS_DFSDM_FILTER_ALL_INSTANCE(hdfsdm_filter->Instance)); assert_param(Channel != NULL); /* Get value of extreme detector maximum register */ reg = hdfsdm_filter->Instance->FLTEXMAX; /* Extract channel and extreme detector maximum value */ *Channel = (reg & DFSDM_FLTEXMAX_EXMAXCH); value = ((int32_t)(reg & DFSDM_FLTEXMAX_EXMAX) >> DFSDM_FLTEXMAX_EXMAX_Pos); /* return extreme detector maximum value */ return value; } /** * @brief This function allows to get extreme detector minimum value. * @param hdfsdm_filter DFSDM filter handle. * @param Channel Corresponding channel. * @retval Extreme detector minimum value * This value is between Min_Data = -8388608 and Max_Data = 8388607. */ int32_t HAL_DFSDM_FilterGetExdMinValue(DFSDM_Filter_HandleTypeDef *hdfsdm_filter, uint32_t *Channel) { uint32_t reg = 0U; int32_t value = 0; /* Check parameters */ assert_param(IS_DFSDM_FILTER_ALL_INSTANCE(hdfsdm_filter->Instance)); assert_param(Channel != NULL); /* Get value of extreme detector minimum register */ reg = hdfsdm_filter->Instance->FLTEXMIN; /* Extract channel and extreme detector minimum value */ *Channel = (reg & DFSDM_FLTEXMIN_EXMINCH); value = ((int32_t)(reg & DFSDM_FLTEXMIN_EXMIN) >> DFSDM_FLTEXMIN_EXMIN_Pos); /* return extreme detector minimum value */ return value; } /** * @brief This function allows to get conversion time value. * @param hdfsdm_filter DFSDM filter handle. * @retval Conversion time value * @note To get time in second, this value has to be divided by DFSDM clock frequency. */ uint32_t HAL_DFSDM_FilterGetConvTimeValue(DFSDM_Filter_HandleTypeDef *hdfsdm_filter) { uint32_t reg = 0U; uint32_t value = 0U; /* Check parameters */ assert_param(IS_DFSDM_FILTER_ALL_INSTANCE(hdfsdm_filter->Instance)); /* Get value of conversion timer register */ reg = hdfsdm_filter->Instance->FLTCNVTIMR; /* Extract conversion time value */ value = ((reg & DFSDM_FLTCNVTIMR_CNVCNT) >> DFSDM_FLTCNVTIMR_CNVCNT_Pos); /* return extreme detector minimum value */ return value; } /** * @brief This function handles the DFSDM interrupts. * @param hdfsdm_filter DFSDM filter handle. * @retval None */ void HAL_DFSDM_IRQHandler(DFSDM_Filter_HandleTypeDef *hdfsdm_filter) { /* Check if overrun occurs during regular conversion */ if(((hdfsdm_filter->Instance->FLTISR & DFSDM_FLTISR_ROVRF) != 0U) && \ ((hdfsdm_filter->Instance->FLTCR2 & DFSDM_FLTCR2_ROVRIE) != 0U)) { /* Clear regular overrun flag */ hdfsdm_filter->Instance->FLTICR = DFSDM_FLTICR_CLRROVRF; /* Update error code */ hdfsdm_filter->ErrorCode = DFSDM_FILTER_ERROR_REGULAR_OVERRUN; /* Call error callback */ HAL_DFSDM_FilterErrorCallback(hdfsdm_filter); } /* Check if overrun occurs during injected conversion */ else if(((hdfsdm_filter->Instance->FLTISR & DFSDM_FLTISR_JOVRF) != 0U) && \ ((hdfsdm_filter->Instance->FLTCR2 & DFSDM_FLTCR2_JOVRIE) != 0U)) { /* Clear injected overrun flag */ hdfsdm_filter->Instance->FLTICR = DFSDM_FLTICR_CLRJOVRF; /* Update error code */ hdfsdm_filter->ErrorCode = DFSDM_FILTER_ERROR_INJECTED_OVERRUN; /* Call error callback */ HAL_DFSDM_FilterErrorCallback(hdfsdm_filter); } /* Check if end of regular conversion */ else if(((hdfsdm_filter->Instance->FLTISR & DFSDM_FLTISR_REOCF) != 0U) && \ ((hdfsdm_filter->Instance->FLTCR2 & DFSDM_FLTCR2_REOCIE) != 0U)) { /* Call regular conversion complete callback */ HAL_DFSDM_FilterRegConvCpltCallback(hdfsdm_filter); /* End of conversion if mode is not continuous and software trigger */ if((hdfsdm_filter->RegularContMode == DFSDM_CONTINUOUS_CONV_OFF) && \ (hdfsdm_filter->RegularTrigger == DFSDM_FILTER_SW_TRIGGER)) { /* Disable interrupts for regular conversions */ hdfsdm_filter->Instance->FLTCR2 &= ~(DFSDM_FLTCR2_REOCIE); /* Update DFSDM filter state */ hdfsdm_filter->State = (hdfsdm_filter->State == HAL_DFSDM_FILTER_STATE_REG) ? \ HAL_DFSDM_FILTER_STATE_READY : HAL_DFSDM_FILTER_STATE_INJ; } } /* Check if end of injected conversion */ else if(((hdfsdm_filter->Instance->FLTISR & DFSDM_FLTISR_JEOCF) != 0U) && \ ((hdfsdm_filter->Instance->FLTCR2 & DFSDM_FLTCR2_JEOCIE) != 0U)) { /* Call injected conversion complete callback */ HAL_DFSDM_FilterInjConvCpltCallback(hdfsdm_filter); /* Update remaining injected conversions */ hdfsdm_filter->InjConvRemaining--; if(hdfsdm_filter->InjConvRemaining == 0U) { /* End of conversion if trigger is software */ if(hdfsdm_filter->InjectedTrigger == DFSDM_FILTER_SW_TRIGGER) { /* Disable interrupts for injected conversions */ hdfsdm_filter->Instance->FLTCR2 &= ~(DFSDM_FLTCR2_JEOCIE); /* Update DFSDM filter state */ hdfsdm_filter->State = (hdfsdm_filter->State == HAL_DFSDM_FILTER_STATE_INJ) ? \ HAL_DFSDM_FILTER_STATE_READY : HAL_DFSDM_FILTER_STATE_REG; } /* end of injected sequence, reset the value */ hdfsdm_filter->InjConvRemaining = (hdfsdm_filter->InjectedScanMode == ENABLE) ? \ hdfsdm_filter->InjectedChannelsNbr : 1U; } } /* Check if analog watchdog occurs */ else if(((hdfsdm_filter->Instance->FLTISR & DFSDM_FLTISR_AWDF) != 0U) && \ ((hdfsdm_filter->Instance->FLTCR2 & DFSDM_FLTCR2_AWDIE) != 0U)) { uint32_t reg = 0U; uint32_t threshold = 0U; uint32_t channel = 0U; /* Get channel and threshold */ reg = hdfsdm_filter->Instance->FLTAWSR; threshold = ((reg & DFSDM_FLTAWSR_AWLTF) != 0U) ? DFSDM_AWD_LOW_THRESHOLD : DFSDM_AWD_HIGH_THRESHOLD; if(threshold == DFSDM_AWD_HIGH_THRESHOLD) { reg = reg >> DFSDM_FLTAWSR_AWHTF_Pos; } while((reg & 1U) == 0U) { channel++; reg = reg >> 1U; } /* Clear analog watchdog flag */ hdfsdm_filter->Instance->FLTAWCFR = (threshold == DFSDM_AWD_HIGH_THRESHOLD) ? \ (1U << (DFSDM_FLTAWSR_AWHTF_Pos + channel)) : \ (1U << channel); /* Call analog watchdog callback */ HAL_DFSDM_FilterAwdCallback(hdfsdm_filter, channel, threshold); } /* Check if clock absence occurs */ else if((hdfsdm_filter->Instance == DFSDM1_Filter0) && \ ((hdfsdm_filter->Instance->FLTISR & DFSDM_FLTISR_CKABF) != 0U) && \ ((hdfsdm_filter->Instance->FLTCR2 & DFSDM_FLTCR2_CKABIE) != 0U)) { uint32_t reg = 0U; uint32_t channel = 0U; reg = ((hdfsdm_filter->Instance->FLTISR & DFSDM_FLTISR_CKABF) >> DFSDM_FLTISR_CKABF_Pos); while(channel < DFSDM1_CHANNEL_NUMBER) { /* Check if flag is set and corresponding channel is enabled */ if(((reg & 1U) != 0U) && (a_dfsdm1ChannelHandle[channel] != NULL)) { /* Check clock absence has been enabled for this channel */ if((a_dfsdm1ChannelHandle[channel]->Instance->CHCFGR1 & DFSDM_CHCFGR1_CKABEN) != 0U) { /* Clear clock absence flag */ hdfsdm_filter->Instance->FLTICR = (1U << (DFSDM_FLTICR_CLRCKABF_Pos + channel)); /* Call clock absence callback */ HAL_DFSDM_ChannelCkabCallback(a_dfsdm1ChannelHandle[channel]); } } channel++; reg = reg >> 1U; } } #if defined (DFSDM2_Channel0) /* Check if clock absence occurs */ else if((hdfsdm_filter->Instance == DFSDM2_Filter0) && \ ((hdfsdm_filter->Instance->FLTISR & DFSDM_FLTISR_CKABF) != 0U) && \ ((hdfsdm_filter->Instance->FLTCR2 & DFSDM_FLTCR2_CKABIE) != 0U)) { uint32_t reg = 0U; uint32_t channel = 0U; reg = ((hdfsdm_filter->Instance->FLTISR & DFSDM_FLTISR_CKABF) >> DFSDM_FLTISR_CKABF_Pos); while(channel < DFSDM2_CHANNEL_NUMBER) { /* Check if flag is set and corresponding channel is enabled */ if(((reg & 1U) != 0U) && (a_dfsdm2ChannelHandle[channel] != NULL)) { /* Check clock absence has been enabled for this channel */ if((a_dfsdm2ChannelHandle[channel]->Instance->CHCFGR1 & DFSDM_CHCFGR1_CKABEN) != 0U) { /* Clear clock absence flag */ hdfsdm_filter->Instance->FLTICR = (1U << (DFSDM_FLTICR_CLRCKABF_Pos + channel)); /* Call clock absence callback */ HAL_DFSDM_ChannelCkabCallback(a_dfsdm2ChannelHandle[channel]); } } channel++; reg = reg >> 1U; } } #endif /* DFSDM2_Channel0 */ /* Check if short circuit detection occurs */ else if((hdfsdm_filter->Instance == DFSDM1_Filter0) && \ ((hdfsdm_filter->Instance->FLTISR & DFSDM_FLTISR_SCDF) != 0U) && \ ((hdfsdm_filter->Instance->FLTCR2 & DFSDM_FLTCR2_SCDIE) != 0U)) { uint32_t reg = 0U; uint32_t channel = 0U; /* Get channel */ reg = ((hdfsdm_filter->Instance->FLTISR & DFSDM_FLTISR_SCDF) >> DFSDM_FLTISR_SCDF_Pos); while((reg & 1U) == 0U) { channel++; reg = reg >> 1U; } /* Clear short circuit detection flag */ hdfsdm_filter->Instance->FLTICR = (1U << (DFSDM_FLTICR_CLRSCSDF_Pos + channel)); /* Call short circuit detection callback */ HAL_DFSDM_ChannelScdCallback(a_dfsdm1ChannelHandle[channel]); } #if defined (DFSDM2_Channel0) /* Check if short circuit detection occurs */ else if((hdfsdm_filter->Instance == DFSDM2_Filter0) && \ ((hdfsdm_filter->Instance->FLTISR & DFSDM_FLTISR_SCDF) != 0U) && \ ((hdfsdm_filter->Instance->FLTCR2 & DFSDM_FLTCR2_SCDIE) != 0U)) { uint32_t reg = 0U; uint32_t channel = 0U; /* Get channel */ reg = ((hdfsdm_filter->Instance->FLTISR & DFSDM_FLTISR_SCDF) >> DFSDM_FLTISR_SCDF_Pos); while((reg & 1U) == 0U) { channel++; reg = reg >> 1U; } /* Clear short circuit detection flag */ hdfsdm_filter->Instance->FLTICR = (1U << (DFSDM_FLTICR_CLRSCSDF_Pos + channel)); /* Call short circuit detection callback */ HAL_DFSDM_ChannelScdCallback(a_dfsdm2ChannelHandle[channel]); } #endif /* DFSDM2_Channel0 */ } /** * @brief Regular conversion complete callback. * @note In interrupt mode, user has to read conversion value in this function * using HAL_DFSDM_FilterGetRegularValue. * @param hdfsdm_filter DFSDM filter handle. * @retval None */ __weak void HAL_DFSDM_FilterRegConvCpltCallback(DFSDM_Filter_HandleTypeDef *hdfsdm_filter) { /* Prevent unused argument(s) compilation warning */ UNUSED(hdfsdm_filter); /* NOTE : This function should not be modified, when the callback is needed, the HAL_DFSDM_FilterRegConvCpltCallback could be implemented in the user file. */ } /** * @brief Half regular conversion complete callback. * @param hdfsdm_filter DFSDM filter handle. * @retval None */ __weak void HAL_DFSDM_FilterRegConvHalfCpltCallback(DFSDM_Filter_HandleTypeDef *hdfsdm_filter) { /* Prevent unused argument(s) compilation warning */ UNUSED(hdfsdm_filter); /* NOTE : This function should not be modified, when the callback is needed, the HAL_DFSDM_FilterRegConvHalfCpltCallback could be implemented in the user file. */ } /** * @brief Injected conversion complete callback. * @note In interrupt mode, user has to read conversion value in this function * using HAL_DFSDM_FilterGetInjectedValue. * @param hdfsdm_filter DFSDM filter handle. * @retval None */ __weak void HAL_DFSDM_FilterInjConvCpltCallback(DFSDM_Filter_HandleTypeDef *hdfsdm_filter) { /* Prevent unused argument(s) compilation warning */ UNUSED(hdfsdm_filter); /* NOTE : This function should not be modified, when the callback is needed, the HAL_DFSDM_FilterInjConvCpltCallback could be implemented in the user file. */ } /** * @brief Half injected conversion complete callback. * @param hdfsdm_filter DFSDM filter handle. * @retval None */ __weak void HAL_DFSDM_FilterInjConvHalfCpltCallback(DFSDM_Filter_HandleTypeDef *hdfsdm_filter) { /* Prevent unused argument(s) compilation warning */ UNUSED(hdfsdm_filter); /* NOTE : This function should not be modified, when the callback is needed, the HAL_DFSDM_FilterInjConvHalfCpltCallback could be implemented in the user file. */ } /** * @brief Filter analog watchdog callback. * @param hdfsdm_filter DFSDM filter handle. * @param Channel Corresponding channel. * @param Threshold Low or high threshold has been reached. * @retval None */ __weak void HAL_DFSDM_FilterAwdCallback(DFSDM_Filter_HandleTypeDef *hdfsdm_filter, uint32_t Channel, uint32_t Threshold) { /* Prevent unused argument(s) compilation warning */ UNUSED(hdfsdm_filter); UNUSED(Channel); UNUSED(Threshold); /* NOTE : This function should not be modified, when the callback is needed, the HAL_DFSDM_FilterAwdCallback could be implemented in the user file. */ } /** * @brief Error callback. * @param hdfsdm_filter DFSDM filter handle. * @retval None */ __weak void HAL_DFSDM_FilterErrorCallback(DFSDM_Filter_HandleTypeDef *hdfsdm_filter) { /* Prevent unused argument(s) compilation warning */ UNUSED(hdfsdm_filter); /* NOTE : This function should not be modified, when the callback is needed, the HAL_DFSDM_FilterErrorCallback could be implemented in the user file. */ } /** * @} */ /** @defgroup DFSDM_Exported_Functions_Group4_Filter Filter state functions * @brief Filter state functions * @verbatim ============================================================================== ##### Filter state functions ##### ============================================================================== [..] This section provides functions allowing to: (+) Get the DFSDM filter state. (+) Get the DFSDM filter error. @endverbatim * @{ */ /** * @brief This function allows to get the current DFSDM filter handle state. * @param hdfsdm_filter DFSDM filter handle. * @retval DFSDM filter state. */ HAL_DFSDM_Filter_StateTypeDef HAL_DFSDM_FilterGetState(DFSDM_Filter_HandleTypeDef *hdfsdm_filter) { /* Return DFSDM filter handle state */ return hdfsdm_filter->State; } /** * @brief This function allows to get the current DFSDM filter error. * @param hdfsdm_filter DFSDM filter handle. * @retval DFSDM filter error code. */ uint32_t HAL_DFSDM_FilterGetError(DFSDM_Filter_HandleTypeDef *hdfsdm_filter) { return hdfsdm_filter->ErrorCode; } /** * @} */ /** @defgroup DFSDM_Exported_Functions_Group5_Filter MultiChannel operation functions * @brief Filter state functions * @verbatim ============================================================================== ##### Filter MultiChannel operation functions ##### ============================================================================== [..] This section provides functions allowing to: (+) Control the DFSDM Multi channel delay block @endverbatim * @{ */ #if defined(SYSCFG_MCHDLYCR_BSCKSEL) /** * @brief Select the DFSDM2 as clock source for the bitstream clock. * @note The SYSCFG clock marco __HAL_RCC_SYSCFG_CLK_ENABLE() must be called * before HAL_DFSDM_BitstreamClock_Start() */ void HAL_DFSDM_BitstreamClock_Start(void) { uint32_t tmp = 0; tmp = SYSCFG->MCHDLYCR; tmp = (tmp &(~SYSCFG_MCHDLYCR_BSCKSEL)); SYSCFG->MCHDLYCR = (tmp|SYSCFG_MCHDLYCR_BSCKSEL); } /** * @brief Stop the DFSDM2 as clock source for the bitstream clock. * @note The SYSCFG clock marco __HAL_RCC_SYSCFG_CLK_ENABLE() must be called * before HAL_DFSDM_BitstreamClock_Stop() * @retval None */ void HAL_DFSDM_BitstreamClock_Stop(void) { uint32_t tmp = 0U; tmp = SYSCFG->MCHDLYCR; tmp = (tmp &(~SYSCFG_MCHDLYCR_BSCKSEL)); SYSCFG->MCHDLYCR = tmp; } /** * @brief Disable Delay Clock for DFSDM1/2. * @param MCHDLY HAL_MCHDLY_CLOCK_DFSDM2. * HAL_MCHDLY_CLOCK_DFSDM1. * @note The SYSCFG clock marco __HAL_RCC_SYSCFG_CLK_ENABLE() must be called * before HAL_DFSDM_DisableDelayClock() * @retval None */ void HAL_DFSDM_DisableDelayClock(uint32_t MCHDLY) { uint32_t tmp = 0U; assert_param(IS_DFSDM_DELAY_CLOCK(MCHDLY)); tmp = SYSCFG->MCHDLYCR; if(MCHDLY == HAL_MCHDLY_CLOCK_DFSDM2) { tmp = tmp &(~SYSCFG_MCHDLYCR_MCHDLY2EN); } else { tmp = tmp &(~SYSCFG_MCHDLYCR_MCHDLY1EN); } SYSCFG->MCHDLYCR = tmp; } /** * @brief Enable Delay Clock for DFSDM1/2. * @param MCHDLY HAL_MCHDLY_CLOCK_DFSDM2. * HAL_MCHDLY_CLOCK_DFSDM1. * @note The SYSCFG clock marco __HAL_RCC_SYSCFG_CLK_ENABLE() must be called * before HAL_DFSDM_EnableDelayClock() * @retval None */ void HAL_DFSDM_EnableDelayClock(uint32_t MCHDLY) { uint32_t tmp = 0U; assert_param(IS_DFSDM_DELAY_CLOCK(MCHDLY)); tmp = SYSCFG->MCHDLYCR; tmp = tmp & ~MCHDLY; SYSCFG->MCHDLYCR = (tmp|MCHDLY); } /** * @brief Select the source for CKin signals for DFSDM1/2. * @param source DFSDM2_CKIN_PAD. * DFSDM2_CKIN_DM. * DFSDM1_CKIN_PAD. * DFSDM1_CKIN_DM. * @retval None */ void HAL_DFSDM_ClockIn_SourceSelection(uint32_t source) { uint32_t tmp = 0U; assert_param(IS_DFSDM_CLOCKIN_SELECTION(source)); tmp = SYSCFG->MCHDLYCR; if((source == HAL_DFSDM2_CKIN_PAD) || (source == HAL_DFSDM2_CKIN_DM)) { tmp = (tmp & ~SYSCFG_MCHDLYCR_DFSDM2CFG); if(source == HAL_DFSDM2_CKIN_PAD) { source = 0x000000U; } } else { tmp = (tmp & ~SYSCFG_MCHDLYCR_DFSDM1CFG); } SYSCFG->MCHDLYCR = (source|tmp); } /** * @brief Select the source for CKOut signals for DFSDM1/2. * @param source: DFSDM2_CKOUT_DFSDM2. * DFSDM2_CKOUT_M27. * DFSDM1_CKOUT_DFSDM1. * DFSDM1_CKOUT_M27. * @retval None */ void HAL_DFSDM_ClockOut_SourceSelection(uint32_t source) { uint32_t tmp = 0U; assert_param(IS_DFSDM_CLOCKOUT_SELECTION(source)); tmp = SYSCFG->MCHDLYCR; if((source == HAL_DFSDM2_CKOUT_DFSDM2) || (source == HAL_DFSDM2_CKOUT_M27)) { tmp = (tmp & ~SYSCFG_MCHDLYCR_DFSDM2CKOSEL); if(source == HAL_DFSDM2_CKOUT_DFSDM2) { source = 0x000U; } } else { tmp = (tmp & ~SYSCFG_MCHDLYCR_DFSDM1CKOSEL); } SYSCFG->MCHDLYCR = (source|tmp); } /** * @brief Select the source for DataIn0 signals for DFSDM1/2. * @param source DATAIN0_DFSDM2_PAD. * DATAIN0_DFSDM2_DATAIN1. * DATAIN0_DFSDM1_PAD. * DATAIN0_DFSDM1_DATAIN1. * @retval None */ void HAL_DFSDM_DataIn0_SourceSelection(uint32_t source) { uint32_t tmp = 0U; assert_param(IS_DFSDM_DATAIN0_SRC_SELECTION(source)); tmp = SYSCFG->MCHDLYCR; if((source == HAL_DATAIN0_DFSDM2_PAD)|| (source == HAL_DATAIN0_DFSDM2_DATAIN1)) { tmp = (tmp & ~SYSCFG_MCHDLYCR_DFSDM2D0SEL); if(source == HAL_DATAIN0_DFSDM2_PAD) { source = 0x00000U; } } else { tmp = (tmp & ~SYSCFG_MCHDLYCR_DFSDM1D0SEL); } SYSCFG->MCHDLYCR = (source|tmp); } /** * @brief Select the source for DataIn2 signals for DFSDM1/2. * @param source DATAIN2_DFSDM2_PAD. * DATAIN2_DFSDM2_DATAIN3. * DATAIN2_DFSDM1_PAD. * DATAIN2_DFSDM1_DATAIN3. * @retval None */ void HAL_DFSDM_DataIn2_SourceSelection(uint32_t source) { uint32_t tmp = 0U; assert_param(IS_DFSDM_DATAIN2_SRC_SELECTION(source)); tmp = SYSCFG->MCHDLYCR; if((source == HAL_DATAIN2_DFSDM2_PAD)|| (source == HAL_DATAIN2_DFSDM2_DATAIN3)) { tmp = (tmp & ~SYSCFG_MCHDLYCR_DFSDM2D2SEL); if (source == HAL_DATAIN2_DFSDM2_PAD) { source = 0x0000U; } } else { tmp = (tmp & ~SYSCFG_MCHDLYCR_DFSDM1D2SEL); } SYSCFG->MCHDLYCR = (source|tmp); } /** * @brief Select the source for DataIn4 signals for DFSDM2. * @param source DATAIN4_DFSDM2_PAD. * DATAIN4_DFSDM2_DATAIN5 * @retval None */ void HAL_DFSDM_DataIn4_SourceSelection(uint32_t source) { uint32_t tmp = 0U; assert_param(IS_DFSDM_DATAIN4_SRC_SELECTION(source)); tmp = SYSCFG->MCHDLYCR; tmp = (tmp & ~SYSCFG_MCHDLYCR_DFSDM2D4SEL); SYSCFG->MCHDLYCR = (source|tmp); } /** * @brief Select the source for DataIn6 signals for DFSDM2. * @param source DATAIN6_DFSDM2_PAD. * DATAIN6_DFSDM2_DATAIN7. * @retval None */ void HAL_DFSDM_DataIn6_SourceSelection(uint32_t source) { uint32_t tmp = 0U; assert_param(IS_DFSDM_DATAIN6_SRC_SELECTION(source)); tmp = SYSCFG->MCHDLYCR; tmp = (tmp & ~SYSCFG_MCHDLYCR_DFSDM2D6SEL); SYSCFG->MCHDLYCR = (source|tmp); } /** * @brief Configure the distribution of the bitstream clock gated from TIM4_OC * for DFSDM1 or TIM3_OC for DFSDM2 * @param source DFSDM1_CLKIN0_TIM4OC2 * DFSDM1_CLKIN2_TIM4OC2 * DFSDM1_CLKIN1_TIM4OC1 * DFSDM1_CLKIN3_TIM4OC1 * DFSDM2_CLKIN0_TIM3OC4 * DFSDM2_CLKIN4_TIM3OC4 * DFSDM2_CLKIN1_TIM3OC3 * DFSDM2_CLKIN5_TIM3OC3 * DFSDM2_CLKIN2_TIM3OC2 * DFSDM2_CLKIN6_TIM3OC2 * DFSDM2_CLKIN3_TIM3OC1 * DFSDM2_CLKIN7_TIM3OC1 * @retval None */ void HAL_DFSDM_BitStreamClkDistribution_Config(uint32_t source) { uint32_t tmp = 0U; assert_param(IS_DFSDM_BITSTREM_CLK_DISTRIBUTION(source)); tmp = SYSCFG->MCHDLYCR; if ((source == HAL_DFSDM1_CLKIN0_TIM4OC2) || (source == HAL_DFSDM1_CLKIN2_TIM4OC2)) { tmp = (tmp & ~SYSCFG_MCHDLYCR_DFSDM1CK02SEL); } else if ((source == HAL_DFSDM1_CLKIN1_TIM4OC1) || (source == HAL_DFSDM1_CLKIN3_TIM4OC1)) { tmp = (tmp & ~SYSCFG_MCHDLYCR_DFSDM1CK13SEL); } else if ((source == HAL_DFSDM2_CLKIN0_TIM3OC4) || (source == HAL_DFSDM2_CLKIN4_TIM3OC4)) { tmp = (tmp & ~SYSCFG_MCHDLYCR_DFSDM2CK04SEL); } else if ((source == HAL_DFSDM2_CLKIN1_TIM3OC3) || (source == HAL_DFSDM2_CLKIN5_TIM3OC3)) { tmp = (tmp & ~SYSCFG_MCHDLYCR_DFSDM2CK15SEL); }else if ((source == HAL_DFSDM2_CLKIN2_TIM3OC2) || (source == HAL_DFSDM2_CLKIN6_TIM3OC2)) { tmp = (tmp & ~SYSCFG_MCHDLYCR_DFSDM2CK26SEL); } else { tmp = (tmp & ~SYSCFG_MCHDLYCR_DFSDM2CK37SEL); } if((source == HAL_DFSDM1_CLKIN0_TIM4OC2) ||(source == HAL_DFSDM1_CLKIN1_TIM4OC1)|| (source == HAL_DFSDM2_CLKIN0_TIM3OC4) ||(source == HAL_DFSDM2_CLKIN1_TIM3OC3)|| (source == HAL_DFSDM2_CLKIN2_TIM3OC2) ||(source == HAL_DFSDM2_CLKIN3_TIM3OC1)) { source = 0x0000U; } SYSCFG->MCHDLYCR = (source|tmp); } /** * @brief Configure multi channel delay block: Use DFSDM2 audio clock source as input * clock for DFSDM1 and DFSDM2 filters to Synchronize DFSDMx filters. * Set the path of the DFSDM2 clock output (dfsdm2_ckout) to the * DFSDM1/2 CkInx and data inputs channels by configuring following MCHDLY muxes * or demuxes: M1, M2, M3, M4, M5, M6, M7, M8, DM1, DM2, DM3, DM4, DM5, DM6, * M9, M10, M11, M12, M13, M14, M15, M16, M17, M18, M19, M20 based on the * contains of the DFSDM_MultiChannelConfigTypeDef structure * @param mchdlystruct Structure of multi channel configuration * @retval None * @note The SYSCFG clock marco __HAL_RCC_SYSCFG_CLK_ENABLE() must be called * before HAL_DFSDM_ConfigMultiChannelDelay() * @note The HAL_DFSDM_ConfigMultiChannelDelay() function clears the SYSCFG-MCHDLYCR * register before setting the new configuration. */ void HAL_DFSDM_ConfigMultiChannelDelay(DFSDM_MultiChannelConfigTypeDef* mchdlystruct) { uint32_t mchdlyreg = 0U; assert_param(IS_DFSDM_DFSDM1_CLKOUT(mchdlystruct->DFSDM1ClockOut)); assert_param(IS_DFSDM_DFSDM2_CLKOUT(mchdlystruct->DFSDM2ClockOut)); assert_param(IS_DFSDM_DFSDM1_CLKIN(mchdlystruct->DFSDM1ClockIn)); assert_param(IS_DFSDM_DFSDM2_CLKIN(mchdlystruct->DFSDM2ClockIn)); assert_param(IS_DFSDM_DFSDM1_BIT_CLK((mchdlystruct->DFSDM1BitClkDistribution))); assert_param(IS_DFSDM_DFSDM2_BIT_CLK(mchdlystruct->DFSDM2BitClkDistribution)); assert_param(IS_DFSDM_DFSDM1_DATA_DISTRIBUTION(mchdlystruct->DFSDM1DataDistribution)); assert_param(IS_DFSDM_DFSDM2_DATA_DISTRIBUTION(mchdlystruct->DFSDM2DataDistribution)); mchdlyreg = (SYSCFG->MCHDLYCR & 0x80103U); SYSCFG->MCHDLYCR = (mchdlyreg |(mchdlystruct->DFSDM1ClockOut)|(mchdlystruct->DFSDM2ClockOut)| (mchdlystruct->DFSDM1ClockIn)|(mchdlystruct->DFSDM2ClockIn)| (mchdlystruct->DFSDM1BitClkDistribution)| (mchdlystruct->DFSDM2BitClkDistribution)| (mchdlystruct->DFSDM1DataDistribution)| (mchdlystruct->DFSDM2DataDistribution)); } #endif /* SYSCFG_MCHDLYCR_BSCKSEL */ /** * @} */ /** * @} */ /* End of exported functions -------------------------------------------------*/ /* Private functions ---------------------------------------------------------*/ /** @addtogroup DFSDM_Private_Functions DFSDM Private Functions * @{ */ /** * @brief DMA half transfer complete callback for regular conversion. * @param hdma DMA handle. * @retval None */ static void DFSDM_DMARegularHalfConvCplt(DMA_HandleTypeDef *hdma) { /* Get DFSDM filter handle */ DFSDM_Filter_HandleTypeDef* hdfsdm_filter = (DFSDM_Filter_HandleTypeDef*) ((DMA_HandleTypeDef*)hdma)->Parent; /* Call regular half conversion complete callback */ HAL_DFSDM_FilterRegConvHalfCpltCallback(hdfsdm_filter); } /** * @brief DMA transfer complete callback for regular conversion. * @param hdma DMA handle. * @retval None */ static void DFSDM_DMARegularConvCplt(DMA_HandleTypeDef *hdma) { /* Get DFSDM filter handle */ DFSDM_Filter_HandleTypeDef* hdfsdm_filter = (DFSDM_Filter_HandleTypeDef*) ((DMA_HandleTypeDef*)hdma)->Parent; /* Call regular conversion complete callback */ HAL_DFSDM_FilterRegConvCpltCallback(hdfsdm_filter); } /** * @brief DMA half transfer complete callback for injected conversion. * @param hdma DMA handle. * @retval None */ static void DFSDM_DMAInjectedHalfConvCplt(DMA_HandleTypeDef *hdma) { /* Get DFSDM filter handle */ DFSDM_Filter_HandleTypeDef* hdfsdm_filter = (DFSDM_Filter_HandleTypeDef*) ((DMA_HandleTypeDef*)hdma)->Parent; /* Call injected half conversion complete callback */ HAL_DFSDM_FilterInjConvHalfCpltCallback(hdfsdm_filter); } /** * @brief DMA transfer complete callback for injected conversion. * @param hdma DMA handle. * @retval None */ static void DFSDM_DMAInjectedConvCplt(DMA_HandleTypeDef *hdma) { /* Get DFSDM filter handle */ DFSDM_Filter_HandleTypeDef* hdfsdm_filter = (DFSDM_Filter_HandleTypeDef*) ((DMA_HandleTypeDef*)hdma)->Parent; /* Call injected conversion complete callback */ HAL_DFSDM_FilterInjConvCpltCallback(hdfsdm_filter); } /** * @brief DMA error callback. * @param hdma DMA handle. * @retval None */ static void DFSDM_DMAError(DMA_HandleTypeDef *hdma) { /* Get DFSDM filter handle */ DFSDM_Filter_HandleTypeDef* hdfsdm_filter = (DFSDM_Filter_HandleTypeDef*) ((DMA_HandleTypeDef*)hdma)->Parent; /* Update error code */ hdfsdm_filter->ErrorCode = DFSDM_FILTER_ERROR_DMA; /* Call error callback */ HAL_DFSDM_FilterErrorCallback(hdfsdm_filter); } /** * @brief This function allows to get the number of injected channels. * @param Channels bitfield of injected channels. * @retval Number of injected channels. */ static uint32_t DFSDM_GetInjChannelsNbr(uint32_t Channels) { uint32_t nbChannels = 0U; uint32_t tmp; /* Get the number of channels from bitfield */ tmp = (uint32_t) (Channels & DFSDM_LSB_MASK); while(tmp != 0U) { if((tmp & 1U) != 0U) { nbChannels++; } tmp = (uint32_t) (tmp >> 1U); } return nbChannels; } /** * @brief This function allows to get the channel number from channel instance. * @param Instance DFSDM channel instance. * @retval Channel number. */ static uint32_t DFSDM_GetChannelFromInstance(DFSDM_Channel_TypeDef* Instance) { uint32_t channel = 0xFFU; /* Get channel from instance */ #if defined(DFSDM2_Channel0) if((Instance == DFSDM1_Channel0) || (Instance == DFSDM2_Channel0)) { channel = 0U; } else if((Instance == DFSDM1_Channel1) || (Instance == DFSDM2_Channel1)) { channel = 1U; } else if((Instance == DFSDM1_Channel2) || (Instance == DFSDM2_Channel2)) { channel = 2U; } else if((Instance == DFSDM1_Channel3) || (Instance == DFSDM2_Channel3)) { channel = 3U; } else if(Instance == DFSDM2_Channel4) { channel = 4U; } else if(Instance == DFSDM2_Channel5) { channel = 5U; } else if(Instance == DFSDM2_Channel6) { channel = 6U; } else if(Instance == DFSDM2_Channel7) { channel = 7U; } #else if(Instance == DFSDM1_Channel0) { channel = 0U; } else if(Instance == DFSDM1_Channel1) { channel = 1U; } else if(Instance == DFSDM1_Channel2) { channel = 2U; } else if(Instance == DFSDM1_Channel3) { channel = 3U; } #endif /* defined(DFSDM2_Channel0) */ return channel; } /** * @brief This function allows to really start regular conversion. * @param hdfsdm_filter DFSDM filter handle. * @retval None */ static void DFSDM_RegConvStart(DFSDM_Filter_HandleTypeDef* hdfsdm_filter) { /* Check regular trigger */ if(hdfsdm_filter->RegularTrigger == DFSDM_FILTER_SW_TRIGGER) { /* Software start of regular conversion */ hdfsdm_filter->Instance->FLTCR1 |= DFSDM_FLTCR1_RSWSTART; } else /* synchronous trigger */ { /* Disable DFSDM filter */ hdfsdm_filter->Instance->FLTCR1 &= ~(DFSDM_FLTCR1_DFEN); /* Set RSYNC bit in DFSDM_FLTCR1 register */ hdfsdm_filter->Instance->FLTCR1 |= DFSDM_FLTCR1_RSYNC; /* Enable DFSDM filter */ hdfsdm_filter->Instance->FLTCR1 |= DFSDM_FLTCR1_DFEN; /* If injected conversion was in progress, restart it */ if(hdfsdm_filter->State == HAL_DFSDM_FILTER_STATE_INJ) { if(hdfsdm_filter->InjectedTrigger == DFSDM_FILTER_SW_TRIGGER) { hdfsdm_filter->Instance->FLTCR1 |= DFSDM_FLTCR1_JSWSTART; } /* Update remaining injected conversions */ hdfsdm_filter->InjConvRemaining = (hdfsdm_filter->InjectedScanMode == ENABLE) ? \ hdfsdm_filter->InjectedChannelsNbr : 1U; } } /* Update DFSDM filter state */ hdfsdm_filter->State = (hdfsdm_filter->State == HAL_DFSDM_FILTER_STATE_READY) ? \ HAL_DFSDM_FILTER_STATE_REG : HAL_DFSDM_FILTER_STATE_REG_INJ; } /** * @brief This function allows to really stop regular conversion. * @param hdfsdm_filter DFSDM filter handle. * @retval None */ static void DFSDM_RegConvStop(DFSDM_Filter_HandleTypeDef* hdfsdm_filter) { /* Disable DFSDM filter */ hdfsdm_filter->Instance->FLTCR1 &= ~(DFSDM_FLTCR1_DFEN); /* If regular trigger was synchronous, reset RSYNC bit in DFSDM_FLTCR1 register */ if(hdfsdm_filter->RegularTrigger == DFSDM_FILTER_SYNC_TRIGGER) { hdfsdm_filter->Instance->FLTCR1 &= ~(DFSDM_FLTCR1_RSYNC); } /* Enable DFSDM filter */ hdfsdm_filter->Instance->FLTCR1 |= DFSDM_FLTCR1_DFEN; /* If injected conversion was in progress, restart it */ if(hdfsdm_filter->State == HAL_DFSDM_FILTER_STATE_REG_INJ) { if(hdfsdm_filter->InjectedTrigger == DFSDM_FILTER_SW_TRIGGER) { hdfsdm_filter->Instance->FLTCR1 |= DFSDM_FLTCR1_JSWSTART; } /* Update remaining injected conversions */ hdfsdm_filter->InjConvRemaining = (hdfsdm_filter->InjectedScanMode == ENABLE) ? \ hdfsdm_filter->InjectedChannelsNbr : 1U; } /* Update DFSDM filter state */ hdfsdm_filter->State = (hdfsdm_filter->State == HAL_DFSDM_FILTER_STATE_REG) ? \ HAL_DFSDM_FILTER_STATE_READY : HAL_DFSDM_FILTER_STATE_INJ; } /** * @brief This function allows to really start injected conversion. * @param hdfsdm_filter DFSDM filter handle. * @retval None */ static void DFSDM_InjConvStart(DFSDM_Filter_HandleTypeDef* hdfsdm_filter) { /* Check injected trigger */ if(hdfsdm_filter->InjectedTrigger == DFSDM_FILTER_SW_TRIGGER) { /* Software start of injected conversion */ hdfsdm_filter->Instance->FLTCR1 |= DFSDM_FLTCR1_JSWSTART; } else /* external or synchronous trigger */ { /* Disable DFSDM filter */ hdfsdm_filter->Instance->FLTCR1 &= ~(DFSDM_FLTCR1_DFEN); if(hdfsdm_filter->InjectedTrigger == DFSDM_FILTER_SYNC_TRIGGER) { /* Set JSYNC bit in DFSDM_FLTCR1 register */ hdfsdm_filter->Instance->FLTCR1 |= DFSDM_FLTCR1_JSYNC; } else /* external trigger */ { /* Set JEXTEN[1:0] bits in DFSDM_FLTCR1 register */ hdfsdm_filter->Instance->FLTCR1 |= hdfsdm_filter->ExtTriggerEdge; } /* Enable DFSDM filter */ hdfsdm_filter->Instance->FLTCR1 |= DFSDM_FLTCR1_DFEN; /* If regular conversion was in progress, restart it */ if((hdfsdm_filter->State == HAL_DFSDM_FILTER_STATE_REG) && \ (hdfsdm_filter->RegularTrigger == DFSDM_FILTER_SW_TRIGGER)) { hdfsdm_filter->Instance->FLTCR1 |= DFSDM_FLTCR1_RSWSTART; } } /* Update DFSDM filter state */ hdfsdm_filter->State = (hdfsdm_filter->State == HAL_DFSDM_FILTER_STATE_READY) ? \ HAL_DFSDM_FILTER_STATE_INJ : HAL_DFSDM_FILTER_STATE_REG_INJ; } /** * @brief This function allows to really stop injected conversion. * @param hdfsdm_filter DFSDM filter handle. * @retval None */ static void DFSDM_InjConvStop(DFSDM_Filter_HandleTypeDef* hdfsdm_filter) { /* Disable DFSDM filter */ hdfsdm_filter->Instance->FLTCR1 &= ~(DFSDM_FLTCR1_DFEN); /* If injected trigger was synchronous, reset JSYNC bit in DFSDM_FLTCR1 register */ if(hdfsdm_filter->InjectedTrigger == DFSDM_FILTER_SYNC_TRIGGER) { hdfsdm_filter->Instance->FLTCR1 &= ~(DFSDM_FLTCR1_JSYNC); } else if(hdfsdm_filter->InjectedTrigger == DFSDM_FILTER_EXT_TRIGGER) { /* Reset JEXTEN[1:0] bits in DFSDM_FLTCR1 register */ hdfsdm_filter->Instance->FLTCR1 &= ~(DFSDM_FLTCR1_JEXTEN); } /* Enable DFSDM filter */ hdfsdm_filter->Instance->FLTCR1 |= DFSDM_FLTCR1_DFEN; /* If regular conversion was in progress, restart it */ if((hdfsdm_filter->State == HAL_DFSDM_FILTER_STATE_REG_INJ) && \ (hdfsdm_filter->RegularTrigger == DFSDM_FILTER_SW_TRIGGER)) { hdfsdm_filter->Instance->FLTCR1 |= DFSDM_FLTCR1_RSWSTART; } /* Update remaining injected conversions */ hdfsdm_filter->InjConvRemaining = (hdfsdm_filter->InjectedScanMode == ENABLE) ? \ hdfsdm_filter->InjectedChannelsNbr : 1U; /* Update DFSDM filter state */ hdfsdm_filter->State = (hdfsdm_filter->State == HAL_DFSDM_FILTER_STATE_INJ) ? \ HAL_DFSDM_FILTER_STATE_READY : HAL_DFSDM_FILTER_STATE_REG; } /** * @} */ /* End of private functions --------------------------------------------------*/ /** * @} */ #endif /* STM32F412Zx || STM32F412Vx || STM32F412Rx || STM32F412Cx || STM32F413xx || STM32F423xx */ #endif /* HAL_DFSDM_MODULE_ENABLED */ /** * @} */ /************************ (C) COPYRIGHT STMicroelectronics *****END OF FILE****/