/** ****************************************************************************** * @file stm32l4xx_hal_opamp.c * @author MCD Application Team * @brief OPAMP HAL module driver. * This file provides firmware functions to manage the following * functionalities of the operational amplifier(s) peripheral: * + Initialization and de-initialization functions * + IO operation functions * + Peripheral Control functions * + Peripheral State functions * ****************************************************************************** * @attention * * Copyright (c) 2017 STMicroelectronics. * All rights reserved. * * This software is licensed under terms that can be found in the LICENSE file * in the root directory of this software component. * If no LICENSE file comes with this software, it is provided AS-IS. * ****************************************************************************** @verbatim ================================================================================ ##### OPAMP Peripheral Features ##### ================================================================================ [..] The device integrates 1 or 2 operational amplifiers OPAMP1 & OPAMP2 (#) The OPAMP(s) provide(s) several exclusive running modes. (++) 1 OPAMP: STM32L412xx STM32L422xx STM32L431xx STM32L432xx STM32L433xx STM32L442xx STM32L443xx (++) 2 OPAMP: STM32L471xx STM32L475xx STM32L476xx STM32L485xx STM32L486xx (#) The OPAMP(s) provide(s) several exclusive running modes. (++) Standalone mode (++) Programmable Gain Amplifier (PGA) mode (Resistor feedback output) (++) Follower mode (#) All OPAMP (same for all OPAMPs) can operate in (++) Either Low range (VDDA < 2.4V) power supply (++) Or High range (VDDA > 2.4V) power supply (#) Each OPAMP(s) can be configured in normal and low power mode. (#) The OPAMP(s) provide(s) calibration capabilities. (++) Calibration aims at correcting some offset for running mode. (++) The OPAMP uses either factory calibration settings OR user defined calibration (trimming) settings (i.e. trimming mode). (++) The user defined settings can be figured out using self calibration handled by HAL_OPAMP_SelfCalibrate, HAL_OPAMPEx_SelfCalibrateAll (++) HAL_OPAMP_SelfCalibrate: (+++) Runs automatically the calibration. (+++) Enables the user trimming mode (+++) Updates the init structure with trimming values with fresh calibration results. The user may store the calibration results for larger (ex monitoring the trimming as a function of temperature for instance) (+++) HAL_OPAMPEx_SelfCalibrateAll runs calibration of all OPAMPs in parallel to save search time. (#) Running mode: Standalone mode (++) Gain is set externally (gain depends on external loads). (++) Follower mode also possible externally by connecting the inverting input to the output. (#) Running mode: Follower mode (++) No Inverting Input is connected. (#) Running mode: Programmable Gain Amplifier (PGA) mode (Resistor feedback output) (++) The OPAMP(s) output(s) can be internally connected to resistor feedback output. (++) OPAMP gain is either 2, 4, 8 or 16. (#) The OPAMPs inverting input can be selected according to the Reference Manual "OPAMP function description" chapter. (#) The OPAMPs non inverting input can be selected according to the Reference Manual "OPAMP function description" chapter. ##### How to use this driver ##### ================================================================================ [..] *** Power supply range *** ============================================ [..] To run in low power mode: (#) Configure the OPAMP using HAL_OPAMP_Init() function: (++) Select OPAMP_POWERSUPPLY_LOW (VDDA lower than 2.4V) (++) Otherwise select OPAMP_POWERSUPPLY_HIGH (VDDA higher than 2.4V) *** Low / normal power mode *** ============================================ [..] To run in low power mode: (#) Configure the OPAMP using HAL_OPAMP_Init() function: (++) Select OPAMP_POWERMODE_LOWPOWER (++) Otherwise select OPAMP_POWERMODE_NORMALPOWER *** Calibration *** ============================================ [..] To run the OPAMP calibration self calibration: (#) Start calibration using HAL_OPAMP_SelfCalibrate. Store the calibration results. *** Running mode *** ============================================ [..] To use the OPAMP, perform the following steps: (#) Fill in the HAL_OPAMP_MspInit() to (++) Enable the OPAMP Peripheral clock using macro __HAL_RCC_OPAMP_CLK_ENABLE() (++) Configure the OPAMP input AND output in analog mode using HAL_GPIO_Init() to map the OPAMP output to the GPIO pin. (#) Registrate Callbacks (++) The compilation define USE_HAL_OPAMP_REGISTER_CALLBACKS when set to 1 allows the user to configure dynamically the driver callbacks. (++) Use Functions HAL_OPAMP_RegisterCallback() to register a user callback, it allows to register following callbacks: (+++) MspInitCallback : OPAMP MspInit. (+++) MspDeInitCallback : OPAMP MspFeInit. This function takes as parameters the HAL peripheral handle, the Callback ID and a pointer to the user callback function. (++) Use function HAL_OPAMP_UnRegisterCallback() to reset a callback to the default weak (overridden) function. It allows to reset following callbacks: (+++) MspInitCallback : OPAMP MspInit. (+++) MspDeInitCallback : OPAMP MspdeInit. (+++) All Callbacks (#) Configure the OPAMP using HAL_OPAMP_Init() function: (++) Select the mode (++) Select the inverting input (++) Select the non-inverting input (++) If PGA mode is enabled, Select if inverting input is connected. (++) Select either factory or user defined trimming mode. (++) If the user-defined trimming mode is enabled, select PMOS & NMOS trimming values (typically values set by HAL_OPAMP_SelfCalibrate function). (#) Enable the OPAMP using HAL_OPAMP_Start() function. (#) Disable the OPAMP using HAL_OPAMP_Stop() function. (#) Lock the OPAMP in running mode using HAL_OPAMP_Lock() function. Caution: On STM32L4, HAL OPAMP lock is software lock only (not hardware lock as on some other STM32 devices) (#) If needed, unlock the OPAMP using HAL_OPAMPEx_Unlock() function. *** Running mode: change of configuration while OPAMP ON *** ============================================ [..] To Re-configure OPAMP when OPAMP is ON (change on the fly) (#) If needed, fill in the HAL_OPAMP_MspInit() (++) This is the case for instance if you wish to use new OPAMP I/O (#) Configure the OPAMP using HAL_OPAMP_Init() function: (++) As in configure case, select first the parameters you wish to modify. (#) Change from low power mode to normal power mode (& vice versa) requires first HAL_OPAMP_DeInit() (force OPAMP OFF) and then HAL_OPAMP_Init(). In other words, of OPAMP is ON, HAL_OPAMP_Init can NOT change power mode alone. @endverbatim ****************************************************************************** Table 1. OPAMPs inverting/non-inverting inputs for the STM32L4 devices: +------------------------------------------------------------------------| | | | OPAMP1 | OPAMP2 | |-----------------|---------|----------------------|---------------------| | Inverting Input | VM_SEL | | | | | | IO0-> PA1 | IO0-> PA7 | | | | LOW LEAKAGE IO (2) | LOW LEAKAGE IO (2) | | | | Not connected | Not connected | | (1) | | PGA mode only | PGA mode only | |-----------------|---------|----------------------|---------------------| | Non Inverting | VP_SEL | | | | | | IO0-> PA0 (GPIO) | IO0-> PA6 (GPIO) | | Input | | DAC1_OUT1 internal | DAC1_OUT2 internal | +------------------------------------------------------------------------| (1): NA in follower mode. (2): Available on some package only (ex. BGA132). Table 2. OPAMPs outputs for the STM32L4 devices: +------------------------------------------------------------------------- | | | OPAMP1 | OPAMP2 | |-----------------|--------|-----------------------|---------------------| | Output | VOUT | PA3 | PB0 | | | | & (1) ADC12_IN if | & (1) ADC12_IN if | | | | connected internally | connected internally| |-----------------|--------|-----------------------|---------------------| (1): ADC1 or ADC2 shall select IN15. */ /* Includes ------------------------------------------------------------------*/ #include "stm32l4xx_hal.h" /** @addtogroup STM32L4xx_HAL_Driver * @{ */ /** @defgroup OPAMP OPAMP * @brief OPAMP module driver * @{ */ #ifdef HAL_OPAMP_MODULE_ENABLED /* Private types -------------------------------------------------------------*/ /* Private variables ---------------------------------------------------------*/ /* Private constants ---------------------------------------------------------*/ /** @addtogroup OPAMP_Private_Constants * @{ */ /* CSR register reset value */ #define OPAMP_CSR_RESET_VALUE ((uint32_t)0x00000000) #define OPAMP_CSR_RESET_BITS (OPAMP_CSR_OPAMPxEN | OPAMP_CSR_OPALPM | OPAMP_CSR_OPAMODE \ | OPAMP_CSR_PGGAIN | OPAMP_CSR_VMSEL | OPAMP_CSR_VPSEL \ | OPAMP_CSR_CALON | OPAMP_CSR_USERTRIM) /* CSR Init masks */ #define OPAMP_CSR_INIT_MASK_PGA (OPAMP_CSR_OPALPM | OPAMP_CSR_OPAMODE| OPAMP_CSR_PGGAIN \ | OPAMP_CSR_VMSEL | OPAMP_CSR_VPSEL | OPAMP_CSR_USERTRIM) #define OPAMP_CSR_INIT_MASK_FOLLOWER (OPAMP_CSR_OPALPM | OPAMP_CSR_OPAMODE| OPAMP_CSR_VPSEL \ | OPAMP_CSR_USERTRIM) #define OPAMP_CSR_INIT_MASK_STANDALONE (OPAMP_CSR_OPALPM | OPAMP_CSR_OPAMODE| OPAMP_CSR_VPSEL \ | OPAMP_CSR_VMSEL | OPAMP_CSR_USERTRIM) /** * @} */ /* Private macros ------------------------------------------------------------*/ /* Private functions ---------------------------------------------------------*/ /* Exported functions --------------------------------------------------------*/ /** @defgroup OPAMP_Exported_Functions OPAMP Exported Functions * @{ */ /** @defgroup OPAMP_Exported_Functions_Group1 Initialization and de-initialization functions * @brief Initialization and Configuration functions * @verbatim ============================================================================== ##### Initialization and de-initialization functions ##### ============================================================================== @endverbatim * @{ */ /** * @brief Initializes the OPAMP according to the specified * parameters in the OPAMP_InitTypeDef and initialize the associated handle. * @note If the selected opamp is locked, initialization can't be performed. * To unlock the configuration, perform a system reset. * @param hopamp OPAMP handle * @retval HAL status */ HAL_StatusTypeDef HAL_OPAMP_Init(OPAMP_HandleTypeDef *hopamp) { HAL_StatusTypeDef status = HAL_OK; uint32_t updateotrlpotr; /* Check the OPAMP handle allocation and lock status */ /* Init not allowed if calibration is ongoing */ if(hopamp == NULL) { return HAL_ERROR; } else if(hopamp->State == HAL_OPAMP_STATE_BUSYLOCKED) { return HAL_ERROR; } else if(hopamp->State == HAL_OPAMP_STATE_CALIBBUSY) { return HAL_ERROR; } else { /* Check the parameter */ assert_param(IS_OPAMP_ALL_INSTANCE(hopamp->Instance)); /* Set OPAMP parameters */ assert_param(IS_OPAMP_POWER_SUPPLY_RANGE(hopamp->Init.PowerSupplyRange)); assert_param(IS_OPAMP_POWERMODE(hopamp->Init.PowerMode)); assert_param(IS_OPAMP_FUNCTIONAL_NORMALMODE(hopamp->Init.Mode)); assert_param(IS_OPAMP_NONINVERTING_INPUT(hopamp->Init.NonInvertingInput)); #if (USE_HAL_OPAMP_REGISTER_CALLBACKS == 1) if(hopamp->State == HAL_OPAMP_STATE_RESET) { if(hopamp->MspInitCallback == NULL) { hopamp->MspInitCallback = HAL_OPAMP_MspInit; } } #endif /* USE_HAL_OPAMP_REGISTER_CALLBACKS */ if ((hopamp->Init.Mode) == OPAMP_STANDALONE_MODE) { assert_param(IS_OPAMP_INVERTING_INPUT_STANDALONE(hopamp->Init.InvertingInput)); } if ((hopamp->Init.Mode) == OPAMP_PGA_MODE) { assert_param(IS_OPAMP_INVERTING_INPUT_PGA(hopamp->Init.InvertingInput)); } if ((hopamp->Init.Mode) == OPAMP_PGA_MODE) { assert_param(IS_OPAMP_PGA_GAIN(hopamp->Init.PgaGain)); } assert_param(IS_OPAMP_TRIMMING(hopamp->Init.UserTrimming)); if ((hopamp->Init.UserTrimming) == OPAMP_TRIMMING_USER) { if (hopamp->Init.PowerMode == OPAMP_POWERMODE_NORMALPOWER) { assert_param(IS_OPAMP_TRIMMINGVALUE(hopamp->Init.TrimmingValueP)); assert_param(IS_OPAMP_TRIMMINGVALUE(hopamp->Init.TrimmingValueN)); } else { assert_param(IS_OPAMP_TRIMMINGVALUE(hopamp->Init.TrimmingValuePLowPower)); assert_param(IS_OPAMP_TRIMMINGVALUE(hopamp->Init.TrimmingValueNLowPower)); } } if(hopamp->State == HAL_OPAMP_STATE_RESET) { /* Allocate lock resource and initialize it */ hopamp->Lock = HAL_UNLOCKED; } #if (USE_HAL_OPAMP_REGISTER_CALLBACKS == 1) hopamp->MspInitCallback(hopamp); #else /* Call MSP init function */ HAL_OPAMP_MspInit(hopamp); #endif /* USE_HAL_OPAMP_REGISTER_CALLBACKS */ /* Set operating mode */ CLEAR_BIT(hopamp->Instance->CSR, OPAMP_CSR_CALON); if (hopamp->Init.Mode == OPAMP_PGA_MODE) { MODIFY_REG(hopamp->Instance->CSR, OPAMP_CSR_INIT_MASK_PGA, \ hopamp->Init.PowerMode | \ hopamp->Init.Mode | \ hopamp->Init.PgaGain | \ hopamp->Init.InvertingInput | \ hopamp->Init.NonInvertingInput | \ hopamp->Init.UserTrimming); } if (hopamp->Init.Mode == OPAMP_FOLLOWER_MODE) { /* In Follower mode InvertingInput is Not Applicable */ MODIFY_REG(hopamp->Instance->CSR, OPAMP_CSR_INIT_MASK_FOLLOWER, \ hopamp->Init.PowerMode | \ hopamp->Init.Mode | \ hopamp->Init.NonInvertingInput | \ hopamp->Init.UserTrimming); } if (hopamp->Init.Mode == OPAMP_STANDALONE_MODE) { MODIFY_REG(hopamp->Instance->CSR, OPAMP_CSR_INIT_MASK_STANDALONE, \ hopamp->Init.PowerMode | \ hopamp->Init.Mode | \ hopamp->Init.InvertingInput | \ hopamp->Init.NonInvertingInput | \ hopamp->Init.UserTrimming); } if (hopamp->Init.UserTrimming == OPAMP_TRIMMING_USER) { /* Set power mode and associated calibration parameters */ if (hopamp->Init.PowerMode != OPAMP_POWERMODE_LOWPOWER) { /* OPAMP_POWERMODE_NORMALPOWER */ /* Set calibration mode (factory or user) and values for */ /* transistors differential pair high (PMOS) and low (NMOS) for */ /* normal mode. */ updateotrlpotr = (((hopamp->Init.TrimmingValueP) << (OPAMP_INPUT_NONINVERTING)) \ | (hopamp->Init.TrimmingValueN)); MODIFY_REG(hopamp->Instance->OTR, OPAMP_OTR_TRIMOFFSETN | OPAMP_OTR_TRIMOFFSETP, updateotrlpotr); } else { /* OPAMP_POWERMODE_LOWPOWER */ /* transistors differential pair high (PMOS) and low (NMOS) for */ /* low power mode. */ updateotrlpotr = (((hopamp->Init.TrimmingValuePLowPower) << (OPAMP_INPUT_NONINVERTING)) \ | (hopamp->Init.TrimmingValueNLowPower)); MODIFY_REG(hopamp->Instance->LPOTR, OPAMP_OTR_TRIMOFFSETN | OPAMP_OTR_TRIMOFFSETP, updateotrlpotr); } } /* Configure the power supply range */ /* The OPAMP_CSR_OPARANGE is common configuration for all OPAMPs */ /* bit OPAMP1_CSR_OPARANGE is used for both OPAMPs */ MODIFY_REG(OPAMP1->CSR, OPAMP1_CSR_OPARANGE, hopamp->Init.PowerSupplyRange); /* Update the OPAMP state*/ if (hopamp->State == HAL_OPAMP_STATE_RESET) { /* From RESET state to READY State */ hopamp->State = HAL_OPAMP_STATE_READY; } /* else: remain in READY or BUSY state (no update) */ return status; } } /** * @brief DeInitialize the OPAMP peripheral. * @note Deinitialization can be performed if the OPAMP configuration is locked. * (the lock is SW in L4) * @param hopamp OPAMP handle * @retval HAL status */ HAL_StatusTypeDef HAL_OPAMP_DeInit(OPAMP_HandleTypeDef *hopamp) { HAL_StatusTypeDef status = HAL_OK; /* Check the OPAMP handle allocation */ /* DeInit not allowed if calibration is ongoing */ if(hopamp == NULL) { status = HAL_ERROR; } else if(hopamp->State == HAL_OPAMP_STATE_CALIBBUSY) { status = HAL_ERROR; } else { /* Check the parameter */ assert_param(IS_OPAMP_ALL_INSTANCE(hopamp->Instance)); /* Set OPAMP_CSR register to reset value */ /* Mind that OPAMP1_CSR_OPARANGE of CSR of OPAMP1 remains unchanged (applies to both OPAMPs) */ /* OPAMP shall be disabled first separately */ CLEAR_BIT(hopamp->Instance->CSR, OPAMP_CSR_OPAMPxEN); MODIFY_REG(hopamp->Instance->CSR, OPAMP_CSR_RESET_BITS, OPAMP_CSR_RESET_VALUE); #if (USE_HAL_OPAMP_REGISTER_CALLBACKS == 1) if(hopamp->MspDeInitCallback == NULL) { hopamp->MspDeInitCallback = HAL_OPAMP_MspDeInit; } /* DeInit the low level hardware */ hopamp->MspDeInitCallback(hopamp); #else /* DeInit the low level hardware: GPIO, CLOCK and NVIC */ HAL_OPAMP_MspDeInit(hopamp); #endif /* USE_HAL_OPAMP_REGISTER_CALLBACKS */ /* Update the OPAMP state*/ hopamp->State = HAL_OPAMP_STATE_RESET; /* Process unlocked */ __HAL_UNLOCK(hopamp); } return status; } /** * @brief Initialize the OPAMP MSP. * @param hopamp OPAMP handle * @retval None */ __weak void HAL_OPAMP_MspInit(OPAMP_HandleTypeDef *hopamp) { /* Prevent unused argument(s) compilation warning */ UNUSED(hopamp); /* NOTE : This function should not be modified, when the callback is needed, the function "HAL_OPAMP_MspInit()" must be implemented in the user file. */ } /** * @brief DeInitialize OPAMP MSP. * @param hopamp OPAMP handle * @retval None */ __weak void HAL_OPAMP_MspDeInit(OPAMP_HandleTypeDef *hopamp) { /* Prevent unused argument(s) compilation warning */ UNUSED(hopamp); /* NOTE : This function should not be modified, when the callback is needed, the function "HAL_OPAMP_MspDeInit()" must be implemented in the user file. */ } /** * @} */ /** @defgroup OPAMP_Exported_Functions_Group2 IO operation functions * @brief IO operation functions * @verbatim =============================================================================== ##### IO operation functions ##### =============================================================================== [..] This subsection provides a set of functions allowing to manage the OPAMP start, stop and calibration actions. @endverbatim * @{ */ /** * @brief Start the OPAMP. * @param hopamp OPAMP handle * @retval HAL status */ HAL_StatusTypeDef HAL_OPAMP_Start(OPAMP_HandleTypeDef *hopamp) { HAL_StatusTypeDef status = HAL_OK; /* Check the OPAMP handle allocation */ /* Check if OPAMP locked */ if(hopamp == NULL) { status = HAL_ERROR; } else if(hopamp->State == HAL_OPAMP_STATE_BUSYLOCKED) { status = HAL_ERROR; } else { /* Check the parameter */ assert_param(IS_OPAMP_ALL_INSTANCE(hopamp->Instance)); if(hopamp->State == HAL_OPAMP_STATE_READY) { /* Enable the selected opamp */ SET_BIT (hopamp->Instance->CSR, OPAMP_CSR_OPAMPxEN); /* Update the OPAMP state*/ /* From HAL_OPAMP_STATE_READY to HAL_OPAMP_STATE_BUSY */ hopamp->State = HAL_OPAMP_STATE_BUSY; } else { status = HAL_ERROR; } } return status; } /** * @brief Stop the OPAMP. * @param hopamp OPAMP handle * @retval HAL status */ HAL_StatusTypeDef HAL_OPAMP_Stop(OPAMP_HandleTypeDef *hopamp) { HAL_StatusTypeDef status = HAL_OK; /* Check the OPAMP handle allocation */ /* Check if OPAMP locked */ /* Check if OPAMP calibration ongoing */ if(hopamp == NULL) { status = HAL_ERROR; } else if(hopamp->State == HAL_OPAMP_STATE_BUSYLOCKED) { status = HAL_ERROR; } else if(hopamp->State == HAL_OPAMP_STATE_CALIBBUSY) { status = HAL_ERROR; } else { /* Check the parameter */ assert_param(IS_OPAMP_ALL_INSTANCE(hopamp->Instance)); if(hopamp->State == HAL_OPAMP_STATE_BUSY) { /* Disable the selected opamp */ CLEAR_BIT (hopamp->Instance->CSR, OPAMP_CSR_OPAMPxEN); /* Update the OPAMP state*/ /* From HAL_OPAMP_STATE_BUSY to HAL_OPAMP_STATE_READY*/ hopamp->State = HAL_OPAMP_STATE_READY; } else { status = HAL_ERROR; } } return status; } /** * @brief Run the self calibration of one OPAMP. * @note Calibration is performed in the mode specified in OPAMP init * structure (mode normal or low-power). To perform calibration for * both modes, repeat this function twice after OPAMP init structure * accordingly updated. * @note Calibration runs about 10 ms. * @param hopamp handle * @retval Updated offset trimming values (PMOS & NMOS), user trimming is enabled * @retval HAL status */ HAL_StatusTypeDef HAL_OPAMP_SelfCalibrate(OPAMP_HandleTypeDef *hopamp) { HAL_StatusTypeDef status = HAL_OK; uint32_t trimmingvaluen; uint32_t trimmingvaluep; uint32_t delta; uint32_t opampmode; __IO uint32_t* tmp_opamp_reg_trimming; /* Selection of register of trimming depending on power mode: OTR or LPOTR */ /* Check the OPAMP handle allocation */ /* Check if OPAMP locked */ if(hopamp == NULL) { status = HAL_ERROR; } else if(hopamp->State == HAL_OPAMP_STATE_BUSYLOCKED) { status = HAL_ERROR; } else { /* Check if OPAMP in calibration mode and calibration not yet enable */ if(hopamp->State == HAL_OPAMP_STATE_READY) { /* Check the parameter */ assert_param(IS_OPAMP_ALL_INSTANCE(hopamp->Instance)); assert_param(IS_OPAMP_POWERMODE(hopamp->Init.PowerMode)); /* Save OPAMP mode as in */ /* STM32L471xx STM32L475xx STM32L476xx STM32L485xx STM32L486xx */ /* the calibration is not working in PGA mode */ opampmode = READ_BIT(hopamp->Instance->CSR,OPAMP_CSR_OPAMODE); /* Use of standalone mode */ MODIFY_REG(hopamp->Instance->CSR, OPAMP_CSR_OPAMODE, OPAMP_STANDALONE_MODE); /* user trimming values are used for offset calibration */ SET_BIT(hopamp->Instance->CSR, OPAMP_CSR_USERTRIM); /* Select trimming settings depending on power mode */ if (hopamp->Init.PowerMode == OPAMP_POWERMODE_NORMALPOWER) { tmp_opamp_reg_trimming = &hopamp->Instance->OTR; } else { tmp_opamp_reg_trimming = &hopamp->Instance->LPOTR; } /* Enable calibration */ SET_BIT (hopamp->Instance->CSR, OPAMP_CSR_CALON); /* 1st calibration - N */ CLEAR_BIT (hopamp->Instance->CSR, OPAMP_CSR_CALSEL); /* Enable the selected opamp */ SET_BIT (hopamp->Instance->CSR, OPAMP_CSR_OPAMPxEN); /* Init trimming counter */ /* Medium value */ trimmingvaluen = 16U; delta = 8U; while (delta != 0U) { /* Set candidate trimming */ /* OPAMP_POWERMODE_NORMALPOWER */ MODIFY_REG(*tmp_opamp_reg_trimming, OPAMP_OTR_TRIMOFFSETN, trimmingvaluen); /* OFFTRIMmax delay 1 ms as per datasheet (electrical characteristics */ /* Offset trim time: during calibration, minimum time needed between */ /* two steps to have 1 mV accuracy */ HAL_Delay(OPAMP_TRIMMING_DELAY); if (READ_BIT(hopamp->Instance->CSR, OPAMP_CSR_CALOUT) != 0U) { /* OPAMP_CSR_CALOUT is HIGH try higher trimming */ trimmingvaluen -= delta; } else { /* OPAMP_CSR_CALOUT is LOW try lower trimming */ trimmingvaluen += delta; } /* Divide range by 2 to continue dichotomy sweep */ delta >>= 1U; } /* Still need to check if right calibration is current value or one step below */ /* Indeed the first value that causes the OUTCAL bit to change from 0 to 1 */ /* Set candidate trimming */ MODIFY_REG(*tmp_opamp_reg_trimming, OPAMP_OTR_TRIMOFFSETN, trimmingvaluen); /* OFFTRIMmax delay 1 ms as per datasheet (electrical characteristics */ /* Offset trim time: during calibration, minimum time needed between */ /* two steps to have 1 mV accuracy */ HAL_Delay(OPAMP_TRIMMING_DELAY); if ((READ_BIT(hopamp->Instance->CSR, OPAMP_CSR_CALOUT)) == 0U) { /* Trimming value is actually one value more */ trimmingvaluen++; /* Set right trimming */ MODIFY_REG(*tmp_opamp_reg_trimming, OPAMP_OTR_TRIMOFFSETN, trimmingvaluen); } /* 2nd calibration - P */ SET_BIT (hopamp->Instance->CSR, OPAMP_CSR_CALSEL); /* Init trimming counter */ /* Medium value */ trimmingvaluep = 16U; delta = 8U; while (delta != 0U) { /* Set candidate trimming */ /* OPAMP_POWERMODE_NORMALPOWER */ MODIFY_REG(*tmp_opamp_reg_trimming, OPAMP_OTR_TRIMOFFSETP, (trimmingvaluep<Instance->CSR, OPAMP_CSR_CALOUT) != 0U) { /* OPAMP_CSR_CALOUT is HIGH try higher trimming */ trimmingvaluep += delta; } else { /* OPAMP_CSR_CALOUT is LOW try lower trimming */ trimmingvaluep -= delta; } /* Divide range by 2 to continue dichotomy sweep */ delta >>= 1U; } /* Still need to check if right calibration is current value or one step below */ /* Indeed the first value that causes the OUTCAL bit to change from 1 to 0 */ /* Set candidate trimming */ MODIFY_REG(*tmp_opamp_reg_trimming, OPAMP_OTR_TRIMOFFSETP, (trimmingvaluep<Instance->CSR, OPAMP_CSR_CALOUT) != 0U) { /* Trimming value is actually one value more */ trimmingvaluep++; MODIFY_REG(*tmp_opamp_reg_trimming, OPAMP_OTR_TRIMOFFSETP, (trimmingvaluep<Instance->CSR, OPAMP_CSR_OPAMPxEN); /* Disable calibration & set normal mode (operating mode) */ CLEAR_BIT (hopamp->Instance->CSR, OPAMP_CSR_CALON); /* Self calibration is successful */ /* Store calibration(user trimming) results in init structure. */ /* Set user trimming mode */ hopamp->Init.UserTrimming = OPAMP_TRIMMING_USER; /* Affect calibration parameters depending on mode normal/low power */ if (hopamp->Init.PowerMode != OPAMP_POWERMODE_LOWPOWER) { /* Write calibration result N */ hopamp->Init.TrimmingValueN = trimmingvaluen; /* Write calibration result P */ hopamp->Init.TrimmingValueP = trimmingvaluep; } else { /* Write calibration result N */ hopamp->Init.TrimmingValueNLowPower = trimmingvaluen; /* Write calibration result P */ hopamp->Init.TrimmingValuePLowPower = trimmingvaluep; } /* Restore OPAMP mode after calibration */ MODIFY_REG(hopamp->Instance->CSR, OPAMP_CSR_OPAMODE, opampmode); } else { /* OPAMP can not be calibrated from this mode */ status = HAL_ERROR; } } return status; } /** * @} */ /** @defgroup OPAMP_Exported_Functions_Group3 Peripheral Control functions * @brief Peripheral Control functions * @verbatim =============================================================================== ##### Peripheral Control functions ##### =============================================================================== [..] This subsection provides a set of functions allowing to control the OPAMP data transfers. @endverbatim * @{ */ /** * @brief Lock the selected OPAMP configuration. * @note On STM32L4, HAL OPAMP lock is software lock only (in * contrast of hardware lock available on some other STM32 * devices). * @param hopamp OPAMP handle * @retval HAL status */ HAL_StatusTypeDef HAL_OPAMP_Lock(OPAMP_HandleTypeDef *hopamp) { HAL_StatusTypeDef status = HAL_OK; /* Check the OPAMP handle allocation */ /* Check if OPAMP locked */ /* OPAMP can be locked when enabled and running in normal mode */ /* It is meaningless otherwise */ if(hopamp == NULL) { status = HAL_ERROR; } else if(hopamp->State == HAL_OPAMP_STATE_BUSY) { /* Check the parameter */ assert_param(IS_OPAMP_ALL_INSTANCE(hopamp->Instance)); /* OPAMP state changed to locked */ hopamp->State = HAL_OPAMP_STATE_BUSYLOCKED; } else { status = HAL_ERROR; } return status; } /** * @brief Return the OPAMP factory trimming value. * @note On STM32L4 OPAMP, user can retrieve factory trimming if * OPAMP has never been set to user trimming before. * Therefore, this function must be called when OPAMP init * parameter "UserTrimming" is set to trimming factory, * and before OPAMP calibration (function * "HAL_OPAMP_SelfCalibrate()"). * Otherwise, factory trimming value cannot be retrieved and * error status is returned. * @param hopamp : OPAMP handle * @param trimmingoffset : Trimming offset (P or N) * This parameter must be a value of @ref OPAMP_FactoryTrimming * @note Calibration parameter retrieved is corresponding to the mode * specified in OPAMP init structure (mode normal or low-power). * To retrieve calibration parameters for both modes, repeat this * function after OPAMP init structure accordingly updated. * @retval Trimming value (P or N): range: 0->31 * or OPAMP_FACTORYTRIMMING_DUMMY if trimming value is not available * */ HAL_OPAMP_TrimmingValueTypeDef HAL_OPAMP_GetTrimOffset (OPAMP_HandleTypeDef *hopamp, uint32_t trimmingoffset) { HAL_OPAMP_TrimmingValueTypeDef trimmingvalue; __IO uint32_t* tmp_opamp_reg_trimming; /* Selection of register of trimming depending on power mode: OTR or LPOTR */ /* Check the OPAMP handle allocation */ /* Value can be retrieved in HAL_OPAMP_STATE_READY state */ if(hopamp == NULL) { return OPAMP_FACTORYTRIMMING_DUMMY; } /* Check the OPAMP handle allocation */ /* Value can be retrieved in HAL_OPAMP_STATE_READY state */ if(hopamp->State == HAL_OPAMP_STATE_READY) { /* Check the parameter */ assert_param(IS_OPAMP_ALL_INSTANCE(hopamp->Instance)); assert_param(IS_OPAMP_FACTORYTRIMMING(trimmingoffset)); assert_param(IS_OPAMP_POWERMODE(hopamp->Init.PowerMode)); /* Check the trimming mode */ if (READ_BIT(hopamp->Instance->CSR,OPAMP_CSR_USERTRIM) != 0U) { /* This function must called when OPAMP init parameter "UserTrimming" */ /* is set to trimming factory, and before OPAMP calibration (function */ /* "HAL_OPAMP_SelfCalibrate()"). */ /* Otherwise, factory trimming value cannot be retrieved and error */ /* status is returned. */ trimmingvalue = OPAMP_FACTORYTRIMMING_DUMMY; } else { /* Select trimming settings depending on power mode */ if (hopamp->Init.PowerMode == OPAMP_POWERMODE_NORMALPOWER) { tmp_opamp_reg_trimming = &OPAMP->OTR; } else { tmp_opamp_reg_trimming = &OPAMP->LPOTR; } /* Get factory trimming */ if (trimmingoffset == OPAMP_FACTORYTRIMMING_P) { /* OPAMP_FACTORYTRIMMING_P */ trimmingvalue = ((*tmp_opamp_reg_trimming) & OPAMP_OTR_TRIMOFFSETP) >> OPAMP_INPUT_NONINVERTING; } else { /* OPAMP_FACTORYTRIMMING_N */ trimmingvalue = (*tmp_opamp_reg_trimming) & OPAMP_OTR_TRIMOFFSETN; } } } else { return OPAMP_FACTORYTRIMMING_DUMMY; } return trimmingvalue; } /** * @} */ /** @defgroup OPAMP_Exported_Functions_Group4 Peripheral State functions * @brief Peripheral State functions * @verbatim =============================================================================== ##### Peripheral State functions ##### =============================================================================== [..] This subsection permits to get in run-time the status of the peripheral. @endverbatim * @{ */ /** * @brief Return the OPAMP handle state. * @param hopamp : OPAMP handle * @retval HAL state */ HAL_OPAMP_StateTypeDef HAL_OPAMP_GetState(OPAMP_HandleTypeDef *hopamp) { /* Check the OPAMP handle allocation */ if(hopamp == NULL) { return HAL_OPAMP_STATE_RESET; } /* Check the parameter */ assert_param(IS_OPAMP_ALL_INSTANCE(hopamp->Instance)); /* Return OPAMP handle state */ return hopamp->State; } /** * @} */ #if (USE_HAL_OPAMP_REGISTER_CALLBACKS == 1) /** * @brief Register a User OPAMP Callback * To be used instead of the weak (overridden) predefined callback * @param hopamp : OPAMP handle * @param CallbackID : ID of the callback to be registered * This parameter can be one of the following values: * @arg @ref HAL_OPAMP_MSPINIT_CB_ID OPAMP MspInit callback ID * @arg @ref HAL_OPAMP_MSPDEINIT_CB_ID OPAMP MspDeInit callback ID * @param pCallback : pointer to the Callback function * @retval status */ HAL_StatusTypeDef HAL_OPAMP_RegisterCallback (OPAMP_HandleTypeDef *hopamp, HAL_OPAMP_CallbackIDTypeDef CallbackID, pOPAMP_CallbackTypeDef pCallback) { HAL_StatusTypeDef status = HAL_OK; if(pCallback == NULL) { return HAL_ERROR; } /* Process locked */ __HAL_LOCK(hopamp); if(hopamp->State == HAL_OPAMP_STATE_READY) { switch (CallbackID) { case HAL_OPAMP_MSPINIT_CB_ID : hopamp->MspInitCallback = pCallback; break; case HAL_OPAMP_MSPDEINIT_CB_ID : hopamp->MspDeInitCallback = pCallback; break; default : /* update return status */ status = HAL_ERROR; break; } } else if (hopamp->State == HAL_OPAMP_STATE_RESET) { switch (CallbackID) { case HAL_OPAMP_MSPINIT_CB_ID : hopamp->MspInitCallback = pCallback; break; case HAL_OPAMP_MSPDEINIT_CB_ID : hopamp->MspDeInitCallback = pCallback; break; default : /* update return status */ status = HAL_ERROR; break; } } else { /* update return status */ status = HAL_ERROR; } /* Release Lock */ __HAL_UNLOCK(hopamp); return status; } /** * @brief Unregister a User OPAMP Callback * OPAMP Callback is redirected to the weak (overridden) predefined callback * @param hopamp : OPAMP handle * @param CallbackID : ID of the callback to be unregistered * This parameter can be one of the following values: * @arg @ref HAL_OPAMP_MSPINIT_CB_ID OPAMP MSP Init Callback ID * @arg @ref HAL_OPAMP_MSPDEINIT_CB_ID OPAMP MSP DeInit Callback ID * @arg @ref HAL_OPAMP_ALL_CB_ID OPAMP All Callbacks * @retval status */ HAL_StatusTypeDef HAL_OPAMP_UnRegisterCallback (OPAMP_HandleTypeDef *hopamp, HAL_OPAMP_CallbackIDTypeDef CallbackID) { HAL_StatusTypeDef status = HAL_OK; /* Process locked */ __HAL_LOCK(hopamp); if(hopamp->State == HAL_OPAMP_STATE_READY) { switch (CallbackID) { case HAL_OPAMP_MSPINIT_CB_ID : hopamp->MspInitCallback = HAL_OPAMP_MspInit; break; case HAL_OPAMP_MSPDEINIT_CB_ID : hopamp->MspDeInitCallback = HAL_OPAMP_MspDeInit; break; case HAL_OPAMP_ALL_CB_ID : hopamp->MspInitCallback = HAL_OPAMP_MspInit; hopamp->MspDeInitCallback = HAL_OPAMP_MspDeInit; break; default : /* update return status */ status = HAL_ERROR; break; } } else if (hopamp->State == HAL_OPAMP_STATE_RESET) { switch (CallbackID) { case HAL_OPAMP_MSPINIT_CB_ID : hopamp->MspInitCallback = HAL_OPAMP_MspInit; break; case HAL_OPAMP_MSPDEINIT_CB_ID : hopamp->MspDeInitCallback = HAL_OPAMP_MspDeInit; break; default : /* update return status */ status = HAL_ERROR; break; } } else { /* update return status */ status = HAL_ERROR; } /* Release Lock */ __HAL_UNLOCK(hopamp); return status; } #endif /* USE_HAL_OPAMP_REGISTER_CALLBACKS */ /** * @} */ /** * @} */ #endif /* HAL_OPAMP_MODULE_ENABLED */ /** * @} */ /** * @} */