/** ****************************************************************************** * @file stm32f4xx_hal_dsi.c * @author MCD Application Team * @brief DSI HAL module driver. * This file provides firmware functions to manage the following * functionalities of the DSI peripheral: * + Initialization and de-initialization functions * + IO operation functions * + Peripheral Control functions * + Peripheral State and Errors functions ****************************************************************************** * @attention * * Copyright (c) 2016 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 ============================================================================== ##### How to use this driver ##### ============================================================================== [..] The DSI HAL driver can be used as follows: (#) Declare a DSI_HandleTypeDef handle structure, for example: DSI_HandleTypeDef hdsi; (#) Initialize the DSI low level resources by implementing the HAL_DSI_MspInit() API: (##) Enable the DSI interface clock (##) NVIC configuration if you need to use interrupt process (+++) Configure the DSI interrupt priority (+++) Enable the NVIC DSI IRQ Channel (#) Initialize the DSI Host peripheral, the required PLL parameters, number of lances and TX Escape clock divider by calling the HAL_DSI_Init() API which calls HAL_DSI_MspInit(). *** Configuration *** ========================= [..] (#) Use HAL_DSI_ConfigAdaptedCommandMode() function to configure the DSI host in adapted command mode. (#) When operating in video mode , use HAL_DSI_ConfigVideoMode() to configure the DSI host. (#) Function HAL_DSI_ConfigCommand() is used to configure the DSI commands behavior in low power mode. (#) To configure the DSI PHY timings parameters, use function HAL_DSI_ConfigPhyTimer(). (#) The DSI Host can be started/stopped using respectively functions HAL_DSI_Start() and HAL_DSI_Stop(). Functions HAL_DSI_ShortWrite(), HAL_DSI_LongWrite() and HAL_DSI_Read() allows respectively to write DSI short packets, long packets and to read DSI packets. (#) The DSI Host Offers two Low power modes : (++) Low Power Mode on data lanes only: Only DSI data lanes are shut down. It is possible to enter/exit from this mode using respectively functions HAL_DSI_EnterULPMData() and HAL_DSI_ExitULPMData() (++) Low Power Mode on data and clock lanes : All DSI lanes are shut down including data and clock lanes. It is possible to enter/exit from this mode using respectively functions HAL_DSI_EnterULPM() and HAL_DSI_ExitULPM() (#) To control DSI state you can use the following function: HAL_DSI_GetState() *** Error management *** ======================== [..] (#) User can select the DSI errors to be reported/monitored using function HAL_DSI_ConfigErrorMonitor() When an error occurs, the callback HAL_DSI_ErrorCallback() is asserted and then user can retrieve the error code by calling function HAL_DSI_GetError() *** DSI HAL driver macros list *** ============================================= [..] Below the list of most used macros in DSI HAL driver. (+) __HAL_DSI_ENABLE: Enable the DSI Host. (+) __HAL_DSI_DISABLE: Disable the DSI Host. (+) __HAL_DSI_WRAPPER_ENABLE: Enables the DSI wrapper. (+) __HAL_DSI_WRAPPER_DISABLE: Disable the DSI wrapper. (+) __HAL_DSI_PLL_ENABLE: Enables the DSI PLL. (+) __HAL_DSI_PLL_DISABLE: Disables the DSI PLL. (+) __HAL_DSI_REG_ENABLE: Enables the DSI regulator. (+) __HAL_DSI_REG_DISABLE: Disables the DSI regulator. (+) __HAL_DSI_GET_FLAG: Get the DSI pending flags. (+) __HAL_DSI_CLEAR_FLAG: Clears the DSI pending flags. (+) __HAL_DSI_ENABLE_IT: Enables the specified DSI interrupts. (+) __HAL_DSI_DISABLE_IT: Disables the specified DSI interrupts. (+) __HAL_DSI_GET_IT_SOURCE: Checks whether the specified DSI interrupt source is enabled or not. [..] (@) You can refer to the DSI HAL driver header file for more useful macros *** Callback registration *** ============================================= [..] The compilation define USE_HAL_DSI_REGISTER_CALLBACKS when set to 1 allows the user to configure dynamically the driver callbacks. Use Function HAL_DSI_RegisterCallback() to register a callback. [..] Function HAL_DSI_RegisterCallback() allows to register following callbacks: (+) TearingEffectCallback : DSI Tearing Effect Callback. (+) EndOfRefreshCallback : DSI End Of Refresh Callback. (+) ErrorCallback : DSI Error Callback (+) MspInitCallback : DSI MspInit. (+) MspDeInitCallback : DSI MspDeInit. [..] This function takes as parameters the HAL peripheral handle, the callback ID and a pointer to the user callback function. [..] Use function HAL_DSI_UnRegisterCallback() to reset a callback to the default weak function. HAL_DSI_UnRegisterCallback takes as parameters the HAL peripheral handle, and the callback ID. [..] This function allows to reset following callbacks: (+) TearingEffectCallback : DSI Tearing Effect Callback. (+) EndOfRefreshCallback : DSI End Of Refresh Callback. (+) ErrorCallback : DSI Error Callback (+) MspInitCallback : DSI MspInit. (+) MspDeInitCallback : DSI MspDeInit. [..] By default, after the HAL_DSI_Init and when the state is HAL_DSI_STATE_RESET all callbacks are set to the corresponding weak functions: examples HAL_DSI_TearingEffectCallback(), HAL_DSI_EndOfRefreshCallback(). Exception done for MspInit and MspDeInit functions that are respectively reset to the legacy weak (surcharged) functions in the HAL_DSI_Init() and HAL_DSI_DeInit() only when these callbacks are null (not registered beforehand). If not, MspInit or MspDeInit are not null, the HAL_DSI_Init() and HAL_DSI_DeInit() keep and use the user MspInit/MspDeInit callbacks (registered beforehand). [..] Callbacks can be registered/unregistered in HAL_DSI_STATE_READY state only. Exception done MspInit/MspDeInit that can be registered/unregistered in HAL_DSI_STATE_READY or HAL_DSI_STATE_RESET state, thus registered (user) MspInit/DeInit callbacks can be used during the Init/DeInit. In that case first register the MspInit/MspDeInit user callbacks using HAL_DSI_RegisterCallback() before calling HAL_DSI_DeInit() or HAL_DSI_Init() function. [..] When The compilation define USE_HAL_DSI_REGISTER_CALLBACKS is set to 0 or not defined, the callback registration feature is not available and all callbacks are set to the corresponding weak functions. @endverbatim ****************************************************************************** */ /* Includes ------------------------------------------------------------------*/ #include "stm32f4xx_hal.h" /** @addtogroup STM32F4xx_HAL_Driver * @{ */ #ifdef HAL_DSI_MODULE_ENABLED #if defined(DSI) /** @addtogroup DSI * @{ */ /* Private types -------------------------------------------------------------*/ /* Private defines -----------------------------------------------------------*/ /** @addtogroup DSI_Private_Constants * @{ */ #define DSI_TIMEOUT_VALUE ((uint32_t)1000U) /* 1s */ #define DSI_ERROR_ACK_MASK (DSI_ISR0_AE0 | DSI_ISR0_AE1 | DSI_ISR0_AE2 | DSI_ISR0_AE3 | \ DSI_ISR0_AE4 | DSI_ISR0_AE5 | DSI_ISR0_AE6 | DSI_ISR0_AE7 | \ DSI_ISR0_AE8 | DSI_ISR0_AE9 | DSI_ISR0_AE10 | DSI_ISR0_AE11 | \ DSI_ISR0_AE12 | DSI_ISR0_AE13 | DSI_ISR0_AE14 | DSI_ISR0_AE15) #define DSI_ERROR_PHY_MASK (DSI_ISR0_PE0 | DSI_ISR0_PE1 | DSI_ISR0_PE2 | DSI_ISR0_PE3 | DSI_ISR0_PE4) #define DSI_ERROR_TX_MASK DSI_ISR1_TOHSTX #define DSI_ERROR_RX_MASK DSI_ISR1_TOLPRX #define DSI_ERROR_ECC_MASK (DSI_ISR1_ECCSE | DSI_ISR1_ECCME) #define DSI_ERROR_CRC_MASK DSI_ISR1_CRCE #define DSI_ERROR_PSE_MASK DSI_ISR1_PSE #define DSI_ERROR_EOT_MASK DSI_ISR1_EOTPE #define DSI_ERROR_OVF_MASK DSI_ISR1_LPWRE #define DSI_ERROR_GEN_MASK (DSI_ISR1_GCWRE | DSI_ISR1_GPWRE | DSI_ISR1_GPTXE | DSI_ISR1_GPRDE | DSI_ISR1_GPRXE) /** * @} */ /* Private variables ---------------------------------------------------------*/ /* Private constants ---------------------------------------------------------*/ /* Private macros ------------------------------------------------------------*/ /* Private function prototypes -----------------------------------------------*/ static void DSI_ConfigPacketHeader(DSI_TypeDef *DSIx, uint32_t ChannelID, uint32_t DataType, uint32_t Data0, uint32_t Data1); static HAL_StatusTypeDef DSI_ShortWrite(DSI_HandleTypeDef *hdsi, uint32_t ChannelID, uint32_t Mode, uint32_t Param1, uint32_t Param2); /* Private functions ---------------------------------------------------------*/ /** @defgroup DSI_Private_Functions DSI Private Functions * @{ */ /** * @brief Generic DSI packet header configuration * @param DSIx Pointer to DSI register base * @param ChannelID Virtual channel ID of the header packet * @param DataType Packet data type of the header packet * This parameter can be any value of : * @arg DSI_SHORT_WRITE_PKT_Data_Type * @arg DSI_LONG_WRITE_PKT_Data_Type * @arg DSI_SHORT_READ_PKT_Data_Type * @arg DSI_MAX_RETURN_PKT_SIZE * @param Data0 Word count LSB * @param Data1 Word count MSB * @retval None */ static void DSI_ConfigPacketHeader(DSI_TypeDef *DSIx, uint32_t ChannelID, uint32_t DataType, uint32_t Data0, uint32_t Data1) { /* Update the DSI packet header with new information */ DSIx->GHCR = (DataType | (ChannelID << 6U) | (Data0 << 8U) | (Data1 << 16U)); } /** * @brief write short DCS or short Generic command * @param hdsi pointer to a DSI_HandleTypeDef structure that contains * the configuration information for the DSI. * @param ChannelID Virtual channel ID. * @param Mode DSI short packet data type. * This parameter can be any value of @arg DSI_SHORT_WRITE_PKT_Data_Type. * @param Param1 DSC command or first generic parameter. * This parameter can be any value of @arg DSI_DCS_Command or a * generic command code. * @param Param2 DSC parameter or second generic parameter. * @retval HAL status */ static HAL_StatusTypeDef DSI_ShortWrite(DSI_HandleTypeDef *hdsi, uint32_t ChannelID, uint32_t Mode, uint32_t Param1, uint32_t Param2) { uint32_t tickstart; /* Get tick */ tickstart = HAL_GetTick(); /* Wait for Command FIFO Empty */ while ((hdsi->Instance->GPSR & DSI_GPSR_CMDFE) == 0U) { /* Check for the Timeout */ if ((HAL_GetTick() - tickstart) > DSI_TIMEOUT_VALUE) { return HAL_TIMEOUT; } } /* Configure the packet to send a short DCS command with 0 or 1 parameter */ /* Update the DSI packet header with new information */ hdsi->Instance->GHCR = (Mode | (ChannelID << 6U) | (Param1 << 8U) | (Param2 << 16U)); return HAL_OK; } /** * @} */ /* Exported functions --------------------------------------------------------*/ /** @addtogroup DSI_Exported_Functions * @{ */ /** @defgroup DSI_Group1 Initialization and Configuration functions * @brief Initialization and Configuration functions * @verbatim =============================================================================== ##### Initialization and Configuration functions ##### =============================================================================== [..] This section provides functions allowing to: (+) Initialize and configure the DSI (+) De-initialize the DSI @endverbatim * @{ */ /** * @brief Initializes the DSI according to the specified * parameters in the DSI_InitTypeDef and create the associated handle. * @param hdsi pointer to a DSI_HandleTypeDef structure that contains * the configuration information for the DSI. * @param PLLInit pointer to a DSI_PLLInitTypeDef structure that contains * the PLL Clock structure definition for the DSI. * @retval HAL status */ HAL_StatusTypeDef HAL_DSI_Init(DSI_HandleTypeDef *hdsi, DSI_PLLInitTypeDef *PLLInit) { uint32_t tickstart; uint32_t unitIntervalx4; uint32_t tempIDF; /* Check the DSI handle allocation */ if (hdsi == NULL) { return HAL_ERROR; } /* Check function parameters */ assert_param(IS_DSI_PLL_NDIV(PLLInit->PLLNDIV)); assert_param(IS_DSI_PLL_IDF(PLLInit->PLLIDF)); assert_param(IS_DSI_PLL_ODF(PLLInit->PLLODF)); assert_param(IS_DSI_AUTO_CLKLANE_CONTROL(hdsi->Init.AutomaticClockLaneControl)); assert_param(IS_DSI_NUMBER_OF_LANES(hdsi->Init.NumberOfLanes)); #if (USE_HAL_DSI_REGISTER_CALLBACKS == 1) if (hdsi->State == HAL_DSI_STATE_RESET) { /* Reset the DSI callback to the legacy weak callbacks */ hdsi->TearingEffectCallback = HAL_DSI_TearingEffectCallback; /* Legacy weak TearingEffectCallback */ hdsi->EndOfRefreshCallback = HAL_DSI_EndOfRefreshCallback; /* Legacy weak EndOfRefreshCallback */ hdsi->ErrorCallback = HAL_DSI_ErrorCallback; /* Legacy weak ErrorCallback */ if (hdsi->MspInitCallback == NULL) { hdsi->MspInitCallback = HAL_DSI_MspInit; } /* Initialize the low level hardware */ hdsi->MspInitCallback(hdsi); } #else if (hdsi->State == HAL_DSI_STATE_RESET) { /* Initialize the low level hardware */ HAL_DSI_MspInit(hdsi); } #endif /* USE_HAL_DSI_REGISTER_CALLBACKS */ /* Change DSI peripheral state */ hdsi->State = HAL_DSI_STATE_BUSY; /**************** Turn on the regulator and enable the DSI PLL ****************/ /* Enable the regulator */ __HAL_DSI_REG_ENABLE(hdsi); /* Get tick */ tickstart = HAL_GetTick(); /* Wait until the regulator is ready */ while (__HAL_DSI_GET_FLAG(hdsi, DSI_FLAG_RRS) == 0U) { /* Check for the Timeout */ if ((HAL_GetTick() - tickstart) > DSI_TIMEOUT_VALUE) { return HAL_TIMEOUT; } } /* Set the PLL division factors */ hdsi->Instance->WRPCR &= ~(DSI_WRPCR_PLL_NDIV | DSI_WRPCR_PLL_IDF | DSI_WRPCR_PLL_ODF); hdsi->Instance->WRPCR |= (((PLLInit->PLLNDIV) << DSI_WRPCR_PLL_NDIV_Pos) | \ ((PLLInit->PLLIDF) << DSI_WRPCR_PLL_IDF_Pos) | \ ((PLLInit->PLLODF) << DSI_WRPCR_PLL_ODF_Pos)); /* Enable the DSI PLL */ __HAL_DSI_PLL_ENABLE(hdsi); /* Requires min of 400us delay before reading the PLLLS flag */ /* 1ms delay is inserted that is the minimum HAL delay granularity */ HAL_Delay(1); /* Get tick */ tickstart = HAL_GetTick(); /* Wait for the lock of the PLL */ while (__HAL_DSI_GET_FLAG(hdsi, DSI_FLAG_PLLLS) == 0U) { /* Check for the Timeout */ if ((HAL_GetTick() - tickstart) > DSI_TIMEOUT_VALUE) { return HAL_TIMEOUT; } } /*************************** Set the PHY parameters ***************************/ /* D-PHY clock and digital enable*/ hdsi->Instance->PCTLR |= (DSI_PCTLR_CKE | DSI_PCTLR_DEN); /* Clock lane configuration */ hdsi->Instance->CLCR &= ~(DSI_CLCR_DPCC | DSI_CLCR_ACR); hdsi->Instance->CLCR |= (DSI_CLCR_DPCC | hdsi->Init.AutomaticClockLaneControl); /* Configure the number of active data lanes */ hdsi->Instance->PCONFR &= ~DSI_PCONFR_NL; hdsi->Instance->PCONFR |= hdsi->Init.NumberOfLanes; /************************ Set the DSI clock parameters ************************/ /* Set the TX escape clock division factor */ hdsi->Instance->CCR &= ~DSI_CCR_TXECKDIV; hdsi->Instance->CCR |= hdsi->Init.TXEscapeCkdiv; /* Calculate the bit period in high-speed mode in unit of 0.25 ns (UIX4) */ /* The equation is : UIX4 = IntegerPart( (1000/F_PHY_Mhz) * 4 ) */ /* Where : F_PHY_Mhz = (NDIV * HSE_Mhz) / (IDF * ODF) */ tempIDF = (PLLInit->PLLIDF > 0U) ? PLLInit->PLLIDF : 1U; unitIntervalx4 = (4000000U * tempIDF * ((1UL << (0x3U & PLLInit->PLLODF)))) / ((HSE_VALUE / 1000U) * PLLInit->PLLNDIV); /* Set the bit period in high-speed mode */ hdsi->Instance->WPCR[0U] &= ~DSI_WPCR0_UIX4; hdsi->Instance->WPCR[0U] |= unitIntervalx4; /****************************** Error management *****************************/ /* Disable all error interrupts and reset the Error Mask */ hdsi->Instance->IER[0U] = 0U; hdsi->Instance->IER[1U] = 0U; hdsi->ErrorMsk = 0U; /* Initialize the error code */ hdsi->ErrorCode = HAL_DSI_ERROR_NONE; /* Initialize the DSI state*/ hdsi->State = HAL_DSI_STATE_READY; return HAL_OK; } /** * @brief De-initializes the DSI peripheral registers to their default reset * values. * @param hdsi pointer to a DSI_HandleTypeDef structure that contains * the configuration information for the DSI. * @retval HAL status */ HAL_StatusTypeDef HAL_DSI_DeInit(DSI_HandleTypeDef *hdsi) { /* Check the DSI handle allocation */ if (hdsi == NULL) { return HAL_ERROR; } /* Change DSI peripheral state */ hdsi->State = HAL_DSI_STATE_BUSY; /* Disable the DSI wrapper */ __HAL_DSI_WRAPPER_DISABLE(hdsi); /* Disable the DSI host */ __HAL_DSI_DISABLE(hdsi); /* D-PHY clock and digital disable */ hdsi->Instance->PCTLR &= ~(DSI_PCTLR_CKE | DSI_PCTLR_DEN); /* Turn off the DSI PLL */ __HAL_DSI_PLL_DISABLE(hdsi); /* Disable the regulator */ __HAL_DSI_REG_DISABLE(hdsi); #if (USE_HAL_DSI_REGISTER_CALLBACKS == 1) if (hdsi->MspDeInitCallback == NULL) { hdsi->MspDeInitCallback = HAL_DSI_MspDeInit; } /* DeInit the low level hardware */ hdsi->MspDeInitCallback(hdsi); #else /* DeInit the low level hardware */ HAL_DSI_MspDeInit(hdsi); #endif /* USE_HAL_DSI_REGISTER_CALLBACKS */ /* Initialize the error code */ hdsi->ErrorCode = HAL_DSI_ERROR_NONE; /* Initialize the DSI state*/ hdsi->State = HAL_DSI_STATE_RESET; /* Release Lock */ __HAL_UNLOCK(hdsi); return HAL_OK; } /** * @brief Enable the error monitor flags * @param hdsi pointer to a DSI_HandleTypeDef structure that contains * the configuration information for the DSI. * @param ActiveErrors indicates which error interrupts will be enabled. * This parameter can be any combination of @arg DSI_Error_Data_Type. * @retval HAL status */ HAL_StatusTypeDef HAL_DSI_ConfigErrorMonitor(DSI_HandleTypeDef *hdsi, uint32_t ActiveErrors) { /* Process locked */ __HAL_LOCK(hdsi); hdsi->Instance->IER[0U] = 0U; hdsi->Instance->IER[1U] = 0U; /* Store active errors to the handle */ hdsi->ErrorMsk = ActiveErrors; if ((ActiveErrors & HAL_DSI_ERROR_ACK) != 0U) { /* Enable the interrupt generation on selected errors */ hdsi->Instance->IER[0U] |= DSI_ERROR_ACK_MASK; } if ((ActiveErrors & HAL_DSI_ERROR_PHY) != 0U) { /* Enable the interrupt generation on selected errors */ hdsi->Instance->IER[0U] |= DSI_ERROR_PHY_MASK; } if ((ActiveErrors & HAL_DSI_ERROR_TX) != 0U) { /* Enable the interrupt generation on selected errors */ hdsi->Instance->IER[1U] |= DSI_ERROR_TX_MASK; } if ((ActiveErrors & HAL_DSI_ERROR_RX) != 0U) { /* Enable the interrupt generation on selected errors */ hdsi->Instance->IER[1U] |= DSI_ERROR_RX_MASK; } if ((ActiveErrors & HAL_DSI_ERROR_ECC) != 0U) { /* Enable the interrupt generation on selected errors */ hdsi->Instance->IER[1U] |= DSI_ERROR_ECC_MASK; } if ((ActiveErrors & HAL_DSI_ERROR_CRC) != 0U) { /* Enable the interrupt generation on selected errors */ hdsi->Instance->IER[1U] |= DSI_ERROR_CRC_MASK; } if ((ActiveErrors & HAL_DSI_ERROR_PSE) != 0U) { /* Enable the interrupt generation on selected errors */ hdsi->Instance->IER[1U] |= DSI_ERROR_PSE_MASK; } if ((ActiveErrors & HAL_DSI_ERROR_EOT) != 0U) { /* Enable the interrupt generation on selected errors */ hdsi->Instance->IER[1U] |= DSI_ERROR_EOT_MASK; } if ((ActiveErrors & HAL_DSI_ERROR_OVF) != 0U) { /* Enable the interrupt generation on selected errors */ hdsi->Instance->IER[1U] |= DSI_ERROR_OVF_MASK; } if ((ActiveErrors & HAL_DSI_ERROR_GEN) != 0U) { /* Enable the interrupt generation on selected errors */ hdsi->Instance->IER[1U] |= DSI_ERROR_GEN_MASK; } /* Process Unlocked */ __HAL_UNLOCK(hdsi); return HAL_OK; } /** * @brief Initializes the DSI MSP. * @param hdsi pointer to a DSI_HandleTypeDef structure that contains * the configuration information for the DSI. * @retval None */ __weak void HAL_DSI_MspInit(DSI_HandleTypeDef *hdsi) { /* Prevent unused argument(s) compilation warning */ UNUSED(hdsi); /* NOTE : This function Should not be modified, when the callback is needed, the HAL_DSI_MspInit could be implemented in the user file */ } /** * @brief De-initializes the DSI MSP. * @param hdsi pointer to a DSI_HandleTypeDef structure that contains * the configuration information for the DSI. * @retval None */ __weak void HAL_DSI_MspDeInit(DSI_HandleTypeDef *hdsi) { /* Prevent unused argument(s) compilation warning */ UNUSED(hdsi); /* NOTE : This function Should not be modified, when the callback is needed, the HAL_DSI_MspDeInit could be implemented in the user file */ } #if (USE_HAL_DSI_REGISTER_CALLBACKS == 1) /** * @brief Register a User DSI Callback * To be used instead of the weak predefined callback * @param hdsi dsi handle * @param CallbackID ID of the callback to be registered * This parameter can be one of the following values: * @arg HAL_DSI_TEARING_EFFECT_CB_ID Tearing Effect Callback ID * @arg HAL_DSI_ENDOF_REFRESH_CB_ID End Of Refresh Callback ID * @arg HAL_DSI_ERROR_CB_ID Error Callback ID * @arg HAL_DSI_MSPINIT_CB_ID MspInit callback ID * @arg HAL_DSI_MSPDEINIT_CB_ID MspDeInit callback ID * @param pCallback pointer to the Callback function * @retval status */ HAL_StatusTypeDef HAL_DSI_RegisterCallback(DSI_HandleTypeDef *hdsi, HAL_DSI_CallbackIDTypeDef CallbackID, pDSI_CallbackTypeDef pCallback) { HAL_StatusTypeDef status = HAL_OK; if (pCallback == NULL) { /* Update the error code */ hdsi->ErrorCode |= HAL_DSI_ERROR_INVALID_CALLBACK; return HAL_ERROR; } /* Process locked */ __HAL_LOCK(hdsi); if (hdsi->State == HAL_DSI_STATE_READY) { switch (CallbackID) { case HAL_DSI_TEARING_EFFECT_CB_ID : hdsi->TearingEffectCallback = pCallback; break; case HAL_DSI_ENDOF_REFRESH_CB_ID : hdsi->EndOfRefreshCallback = pCallback; break; case HAL_DSI_ERROR_CB_ID : hdsi->ErrorCallback = pCallback; break; case HAL_DSI_MSPINIT_CB_ID : hdsi->MspInitCallback = pCallback; break; case HAL_DSI_MSPDEINIT_CB_ID : hdsi->MspDeInitCallback = pCallback; break; default : /* Update the error code */ hdsi->ErrorCode |= HAL_DSI_ERROR_INVALID_CALLBACK; /* Return error status */ status = HAL_ERROR; break; } } else if (hdsi->State == HAL_DSI_STATE_RESET) { switch (CallbackID) { case HAL_DSI_MSPINIT_CB_ID : hdsi->MspInitCallback = pCallback; break; case HAL_DSI_MSPDEINIT_CB_ID : hdsi->MspDeInitCallback = pCallback; break; default : /* Update the error code */ hdsi->ErrorCode |= HAL_DSI_ERROR_INVALID_CALLBACK; /* Return error status */ status = HAL_ERROR; break; } } else { /* Update the error code */ hdsi->ErrorCode |= HAL_DSI_ERROR_INVALID_CALLBACK; /* Return error status */ status = HAL_ERROR; } /* Release Lock */ __HAL_UNLOCK(hdsi); return status; } /** * @brief Unregister a DSI Callback * DSI callback is redirected to the weak predefined callback * @param hdsi dsi handle * @param CallbackID ID of the callback to be unregistered * This parameter can be one of the following values: * @arg HAL_DSI_TEARING_EFFECT_CB_ID Tearing Effect Callback ID * @arg HAL_DSI_ENDOF_REFRESH_CB_ID End Of Refresh Callback ID * @arg HAL_DSI_ERROR_CB_ID Error Callback ID * @arg HAL_DSI_MSPINIT_CB_ID MspInit callback ID * @arg HAL_DSI_MSPDEINIT_CB_ID MspDeInit callback ID * @retval status */ HAL_StatusTypeDef HAL_DSI_UnRegisterCallback(DSI_HandleTypeDef *hdsi, HAL_DSI_CallbackIDTypeDef CallbackID) { HAL_StatusTypeDef status = HAL_OK; /* Process locked */ __HAL_LOCK(hdsi); if (hdsi->State == HAL_DSI_STATE_READY) { switch (CallbackID) { case HAL_DSI_TEARING_EFFECT_CB_ID : hdsi->TearingEffectCallback = HAL_DSI_TearingEffectCallback; /* Legacy weak TearingEffectCallback */ break; case HAL_DSI_ENDOF_REFRESH_CB_ID : hdsi->EndOfRefreshCallback = HAL_DSI_EndOfRefreshCallback; /* Legacy weak EndOfRefreshCallback */ break; case HAL_DSI_ERROR_CB_ID : hdsi->ErrorCallback = HAL_DSI_ErrorCallback; /* Legacy weak ErrorCallback */ break; case HAL_DSI_MSPINIT_CB_ID : hdsi->MspInitCallback = HAL_DSI_MspInit; /* Legacy weak MspInit Callback */ break; case HAL_DSI_MSPDEINIT_CB_ID : hdsi->MspDeInitCallback = HAL_DSI_MspDeInit; /* Legacy weak MspDeInit Callback */ break; default : /* Update the error code */ hdsi->ErrorCode |= HAL_DSI_ERROR_INVALID_CALLBACK; /* Return error status */ status = HAL_ERROR; break; } } else if (hdsi->State == HAL_DSI_STATE_RESET) { switch (CallbackID) { case HAL_DSI_MSPINIT_CB_ID : hdsi->MspInitCallback = HAL_DSI_MspInit; /* Legacy weak MspInit Callback */ break; case HAL_DSI_MSPDEINIT_CB_ID : hdsi->MspDeInitCallback = HAL_DSI_MspDeInit; /* Legacy weak MspDeInit Callback */ break; default : /* Update the error code */ hdsi->ErrorCode |= HAL_DSI_ERROR_INVALID_CALLBACK; /* Return error status */ status = HAL_ERROR; break; } } else { /* Update the error code */ hdsi->ErrorCode |= HAL_DSI_ERROR_INVALID_CALLBACK; /* Return error status */ status = HAL_ERROR; } /* Release Lock */ __HAL_UNLOCK(hdsi); return status; } #endif /* USE_HAL_DSI_REGISTER_CALLBACKS */ /** * @} */ /** @defgroup DSI_Group2 IO operation functions * @brief IO operation functions * @verbatim =============================================================================== ##### IO operation functions ##### =============================================================================== [..] This section provides function allowing to: (+) Handle DSI interrupt request @endverbatim * @{ */ /** * @brief Handles DSI interrupt request. * @param hdsi pointer to a DSI_HandleTypeDef structure that contains * the configuration information for the DSI. * @retval HAL status */ void HAL_DSI_IRQHandler(DSI_HandleTypeDef *hdsi) { uint32_t ErrorStatus0; uint32_t ErrorStatus1; /* Tearing Effect Interrupt management ***************************************/ if (__HAL_DSI_GET_FLAG(hdsi, DSI_FLAG_TE) != 0U) { if (__HAL_DSI_GET_IT_SOURCE(hdsi, DSI_IT_TE) != 0U) { /* Clear the Tearing Effect Interrupt Flag */ __HAL_DSI_CLEAR_FLAG(hdsi, DSI_FLAG_TE); /* Tearing Effect Callback */ #if (USE_HAL_DSI_REGISTER_CALLBACKS == 1) /*Call registered Tearing Effect callback */ hdsi->TearingEffectCallback(hdsi); #else /*Call legacy Tearing Effect callback*/ HAL_DSI_TearingEffectCallback(hdsi); #endif /* USE_HAL_DSI_REGISTER_CALLBACKS */ } } /* End of Refresh Interrupt management ***************************************/ if (__HAL_DSI_GET_FLAG(hdsi, DSI_FLAG_ER) != 0U) { if (__HAL_DSI_GET_IT_SOURCE(hdsi, DSI_IT_ER) != 0U) { /* Clear the End of Refresh Interrupt Flag */ __HAL_DSI_CLEAR_FLAG(hdsi, DSI_FLAG_ER); /* End of Refresh Callback */ #if (USE_HAL_DSI_REGISTER_CALLBACKS == 1) /*Call registered End of refresh callback */ hdsi->EndOfRefreshCallback(hdsi); #else /*Call Legacy End of refresh callback */ HAL_DSI_EndOfRefreshCallback(hdsi); #endif /* USE_HAL_DSI_REGISTER_CALLBACKS */ } } /* Error Interrupts management ***********************************************/ if (hdsi->ErrorMsk != 0U) { ErrorStatus0 = hdsi->Instance->ISR[0U]; ErrorStatus0 &= hdsi->Instance->IER[0U]; ErrorStatus1 = hdsi->Instance->ISR[1U]; ErrorStatus1 &= hdsi->Instance->IER[1U]; if ((ErrorStatus0 & DSI_ERROR_ACK_MASK) != 0U) { hdsi->ErrorCode |= HAL_DSI_ERROR_ACK; } if ((ErrorStatus0 & DSI_ERROR_PHY_MASK) != 0U) { hdsi->ErrorCode |= HAL_DSI_ERROR_PHY; } if ((ErrorStatus1 & DSI_ERROR_TX_MASK) != 0U) { hdsi->ErrorCode |= HAL_DSI_ERROR_TX; } if ((ErrorStatus1 & DSI_ERROR_RX_MASK) != 0U) { hdsi->ErrorCode |= HAL_DSI_ERROR_RX; } if ((ErrorStatus1 & DSI_ERROR_ECC_MASK) != 0U) { hdsi->ErrorCode |= HAL_DSI_ERROR_ECC; } if ((ErrorStatus1 & DSI_ERROR_CRC_MASK) != 0U) { hdsi->ErrorCode |= HAL_DSI_ERROR_CRC; } if ((ErrorStatus1 & DSI_ERROR_PSE_MASK) != 0U) { hdsi->ErrorCode |= HAL_DSI_ERROR_PSE; } if ((ErrorStatus1 & DSI_ERROR_EOT_MASK) != 0U) { hdsi->ErrorCode |= HAL_DSI_ERROR_EOT; } if ((ErrorStatus1 & DSI_ERROR_OVF_MASK) != 0U) { hdsi->ErrorCode |= HAL_DSI_ERROR_OVF; } if ((ErrorStatus1 & DSI_ERROR_GEN_MASK) != 0U) { hdsi->ErrorCode |= HAL_DSI_ERROR_GEN; } /* Check only selected errors */ if (hdsi->ErrorCode != HAL_DSI_ERROR_NONE) { /* DSI error interrupt callback */ #if (USE_HAL_DSI_REGISTER_CALLBACKS == 1) /*Call registered Error callback */ hdsi->ErrorCallback(hdsi); #else /*Call Legacy Error callback */ HAL_DSI_ErrorCallback(hdsi); #endif /* USE_HAL_DSI_REGISTER_CALLBACKS */ } } } /** * @brief Tearing Effect DSI callback. * @param hdsi pointer to a DSI_HandleTypeDef structure that contains * the configuration information for the DSI. * @retval None */ __weak void HAL_DSI_TearingEffectCallback(DSI_HandleTypeDef *hdsi) { /* Prevent unused argument(s) compilation warning */ UNUSED(hdsi); /* NOTE : This function Should not be modified, when the callback is needed, the HAL_DSI_TearingEffectCallback could be implemented in the user file */ } /** * @brief End of Refresh DSI callback. * @param hdsi pointer to a DSI_HandleTypeDef structure that contains * the configuration information for the DSI. * @retval None */ __weak void HAL_DSI_EndOfRefreshCallback(DSI_HandleTypeDef *hdsi) { /* Prevent unused argument(s) compilation warning */ UNUSED(hdsi); /* NOTE : This function Should not be modified, when the callback is needed, the HAL_DSI_EndOfRefreshCallback could be implemented in the user file */ } /** * @brief Operation Error DSI callback. * @param hdsi pointer to a DSI_HandleTypeDef structure that contains * the configuration information for the DSI. * @retval None */ __weak void HAL_DSI_ErrorCallback(DSI_HandleTypeDef *hdsi) { /* Prevent unused argument(s) compilation warning */ UNUSED(hdsi); /* NOTE : This function Should not be modified, when the callback is needed, the HAL_DSI_ErrorCallback could be implemented in the user file */ } /** * @} */ /** @defgroup DSI_Group3 Peripheral Control functions * @brief Peripheral Control functions * @verbatim =============================================================================== ##### Peripheral Control functions ##### =============================================================================== [..] This section provides functions allowing to: (+) Configure the Generic interface read-back Virtual Channel ID (+) Select video mode and configure the corresponding parameters (+) Configure command transmission mode: High-speed or Low-power (+) Configure the flow control (+) Configure the DSI PHY timer (+) Configure the DSI HOST timeout (+) Configure the DSI HOST timeout (+) Start/Stop the DSI module (+) Refresh the display in command mode (+) Controls the display color mode in Video mode (+) Control the display shutdown in Video mode (+) write short DCS or short Generic command (+) write long DCS or long Generic command (+) Read command (DCS or generic) (+) Enter/Exit the Ultra Low Power Mode on data only (D-PHY PLL running) (+) Enter/Exit the Ultra Low Power Mode on data only and clock (D-PHY PLL turned off) (+) Start/Stop test pattern generation (+) Slew-Rate And Delay Tuning (+) Low-Power Reception Filter Tuning (+) Activate an additional current path on all lanes to meet the SDDTx parameter (+) Custom lane pins configuration (+) Set custom timing for the PHY (+) Force the Clock/Data Lane in TX Stop Mode (+) Force LP Receiver in Low-Power Mode (+) Force Data Lanes in RX Mode after a BTA (+) Enable a pull-down on the lanes to prevent from floating states when unused (+) Switch off the contention detection on data lanes @endverbatim * @{ */ /** * @brief Configure the Generic interface read-back Virtual Channel ID. * @param hdsi pointer to a DSI_HandleTypeDef structure that contains * the configuration information for the DSI. * @param VirtualChannelID Virtual channel ID * @retval HAL status */ HAL_StatusTypeDef HAL_DSI_SetGenericVCID(DSI_HandleTypeDef *hdsi, uint32_t VirtualChannelID) { /* Process locked */ __HAL_LOCK(hdsi); /* Update the GVCID register */ hdsi->Instance->GVCIDR &= ~DSI_GVCIDR_VCID; hdsi->Instance->GVCIDR |= VirtualChannelID; /* Process unlocked */ __HAL_UNLOCK(hdsi); return HAL_OK; } /** * @brief Select video mode and configure the corresponding parameters * @param hdsi pointer to a DSI_HandleTypeDef structure that contains * the configuration information for the DSI. * @param VidCfg pointer to a DSI_VidCfgTypeDef structure that contains * the DSI video mode configuration parameters * @retval HAL status */ HAL_StatusTypeDef HAL_DSI_ConfigVideoMode(DSI_HandleTypeDef *hdsi, DSI_VidCfgTypeDef *VidCfg) { /* Process locked */ __HAL_LOCK(hdsi); /* Check the parameters */ assert_param(IS_DSI_COLOR_CODING(VidCfg->ColorCoding)); assert_param(IS_DSI_VIDEO_MODE_TYPE(VidCfg->Mode)); assert_param(IS_DSI_LP_COMMAND(VidCfg->LPCommandEnable)); assert_param(IS_DSI_LP_HFP(VidCfg->LPHorizontalFrontPorchEnable)); assert_param(IS_DSI_LP_HBP(VidCfg->LPHorizontalBackPorchEnable)); assert_param(IS_DSI_LP_VACTIVE(VidCfg->LPVerticalActiveEnable)); assert_param(IS_DSI_LP_VFP(VidCfg->LPVerticalFrontPorchEnable)); assert_param(IS_DSI_LP_VBP(VidCfg->LPVerticalBackPorchEnable)); assert_param(IS_DSI_LP_VSYNC(VidCfg->LPVerticalSyncActiveEnable)); assert_param(IS_DSI_FBTAA(VidCfg->FrameBTAAcknowledgeEnable)); assert_param(IS_DSI_DE_POLARITY(VidCfg->DEPolarity)); assert_param(IS_DSI_VSYNC_POLARITY(VidCfg->VSPolarity)); assert_param(IS_DSI_HSYNC_POLARITY(VidCfg->HSPolarity)); /* Check the LooselyPacked variant only in 18-bit mode */ if (VidCfg->ColorCoding == DSI_RGB666) { assert_param(IS_DSI_LOOSELY_PACKED(VidCfg->LooselyPacked)); } /* Select video mode by resetting CMDM and DSIM bits */ hdsi->Instance->MCR &= ~DSI_MCR_CMDM; hdsi->Instance->WCFGR &= ~DSI_WCFGR_DSIM; /* Configure the video mode transmission type */ hdsi->Instance->VMCR &= ~DSI_VMCR_VMT; hdsi->Instance->VMCR |= VidCfg->Mode; /* Configure the video packet size */ hdsi->Instance->VPCR &= ~DSI_VPCR_VPSIZE; hdsi->Instance->VPCR |= VidCfg->PacketSize; /* Set the chunks number to be transmitted through the DSI link */ hdsi->Instance->VCCR &= ~DSI_VCCR_NUMC; hdsi->Instance->VCCR |= VidCfg->NumberOfChunks; /* Set the size of the null packet */ hdsi->Instance->VNPCR &= ~DSI_VNPCR_NPSIZE; hdsi->Instance->VNPCR |= VidCfg->NullPacketSize; /* Select the virtual channel for the LTDC interface traffic */ hdsi->Instance->LVCIDR &= ~DSI_LVCIDR_VCID; hdsi->Instance->LVCIDR |= VidCfg->VirtualChannelID; /* Configure the polarity of control signals */ hdsi->Instance->LPCR &= ~(DSI_LPCR_DEP | DSI_LPCR_VSP | DSI_LPCR_HSP); hdsi->Instance->LPCR |= (VidCfg->DEPolarity | VidCfg->VSPolarity | VidCfg->HSPolarity); /* Select the color coding for the host */ hdsi->Instance->LCOLCR &= ~DSI_LCOLCR_COLC; hdsi->Instance->LCOLCR |= VidCfg->ColorCoding; /* Select the color coding for the wrapper */ hdsi->Instance->WCFGR &= ~DSI_WCFGR_COLMUX; hdsi->Instance->WCFGR |= ((VidCfg->ColorCoding) << 1U); /* Enable/disable the loosely packed variant to 18-bit configuration */ if (VidCfg->ColorCoding == DSI_RGB666) { hdsi->Instance->LCOLCR &= ~DSI_LCOLCR_LPE; hdsi->Instance->LCOLCR |= VidCfg->LooselyPacked; } /* Set the Horizontal Synchronization Active (HSA) in lane byte clock cycles */ hdsi->Instance->VHSACR &= ~DSI_VHSACR_HSA; hdsi->Instance->VHSACR |= VidCfg->HorizontalSyncActive; /* Set the Horizontal Back Porch (HBP) in lane byte clock cycles */ hdsi->Instance->VHBPCR &= ~DSI_VHBPCR_HBP; hdsi->Instance->VHBPCR |= VidCfg->HorizontalBackPorch; /* Set the total line time (HLINE=HSA+HBP+HACT+HFP) in lane byte clock cycles */ hdsi->Instance->VLCR &= ~DSI_VLCR_HLINE; hdsi->Instance->VLCR |= VidCfg->HorizontalLine; /* Set the Vertical Synchronization Active (VSA) */ hdsi->Instance->VVSACR &= ~DSI_VVSACR_VSA; hdsi->Instance->VVSACR |= VidCfg->VerticalSyncActive; /* Set the Vertical Back Porch (VBP)*/ hdsi->Instance->VVBPCR &= ~DSI_VVBPCR_VBP; hdsi->Instance->VVBPCR |= VidCfg->VerticalBackPorch; /* Set the Vertical Front Porch (VFP)*/ hdsi->Instance->VVFPCR &= ~DSI_VVFPCR_VFP; hdsi->Instance->VVFPCR |= VidCfg->VerticalFrontPorch; /* Set the Vertical Active period*/ hdsi->Instance->VVACR &= ~DSI_VVACR_VA; hdsi->Instance->VVACR |= VidCfg->VerticalActive; /* Configure the command transmission mode */ hdsi->Instance->VMCR &= ~DSI_VMCR_LPCE; hdsi->Instance->VMCR |= VidCfg->LPCommandEnable; /* Low power largest packet size */ hdsi->Instance->LPMCR &= ~DSI_LPMCR_LPSIZE; hdsi->Instance->LPMCR |= ((VidCfg->LPLargestPacketSize) << 16U); /* Low power VACT largest packet size */ hdsi->Instance->LPMCR &= ~DSI_LPMCR_VLPSIZE; hdsi->Instance->LPMCR |= VidCfg->LPVACTLargestPacketSize; /* Enable LP transition in HFP period */ hdsi->Instance->VMCR &= ~DSI_VMCR_LPHFPE; hdsi->Instance->VMCR |= VidCfg->LPHorizontalFrontPorchEnable; /* Enable LP transition in HBP period */ hdsi->Instance->VMCR &= ~DSI_VMCR_LPHBPE; hdsi->Instance->VMCR |= VidCfg->LPHorizontalBackPorchEnable; /* Enable LP transition in VACT period */ hdsi->Instance->VMCR &= ~DSI_VMCR_LPVAE; hdsi->Instance->VMCR |= VidCfg->LPVerticalActiveEnable; /* Enable LP transition in VFP period */ hdsi->Instance->VMCR &= ~DSI_VMCR_LPVFPE; hdsi->Instance->VMCR |= VidCfg->LPVerticalFrontPorchEnable; /* Enable LP transition in VBP period */ hdsi->Instance->VMCR &= ~DSI_VMCR_LPVBPE; hdsi->Instance->VMCR |= VidCfg->LPVerticalBackPorchEnable; /* Enable LP transition in vertical sync period */ hdsi->Instance->VMCR &= ~DSI_VMCR_LPVSAE; hdsi->Instance->VMCR |= VidCfg->LPVerticalSyncActiveEnable; /* Enable the request for an acknowledge response at the end of a frame */ hdsi->Instance->VMCR &= ~DSI_VMCR_FBTAAE; hdsi->Instance->VMCR |= VidCfg->FrameBTAAcknowledgeEnable; /* Process unlocked */ __HAL_UNLOCK(hdsi); return HAL_OK; } /** * @brief Select adapted command mode and configure the corresponding parameters * @param hdsi pointer to a DSI_HandleTypeDef structure that contains * the configuration information for the DSI. * @param CmdCfg pointer to a DSI_CmdCfgTypeDef structure that contains * the DSI command mode configuration parameters * @retval HAL status */ HAL_StatusTypeDef HAL_DSI_ConfigAdaptedCommandMode(DSI_HandleTypeDef *hdsi, DSI_CmdCfgTypeDef *CmdCfg) { /* Process locked */ __HAL_LOCK(hdsi); /* Check the parameters */ assert_param(IS_DSI_COLOR_CODING(CmdCfg->ColorCoding)); assert_param(IS_DSI_TE_SOURCE(CmdCfg->TearingEffectSource)); assert_param(IS_DSI_TE_POLARITY(CmdCfg->TearingEffectPolarity)); assert_param(IS_DSI_AUTOMATIC_REFRESH(CmdCfg->AutomaticRefresh)); assert_param(IS_DSI_VS_POLARITY(CmdCfg->VSyncPol)); assert_param(IS_DSI_TE_ACK_REQUEST(CmdCfg->TEAcknowledgeRequest)); assert_param(IS_DSI_DE_POLARITY(CmdCfg->DEPolarity)); assert_param(IS_DSI_VSYNC_POLARITY(CmdCfg->VSPolarity)); assert_param(IS_DSI_HSYNC_POLARITY(CmdCfg->HSPolarity)); /* Select command mode by setting CMDM and DSIM bits */ hdsi->Instance->MCR |= DSI_MCR_CMDM; hdsi->Instance->WCFGR &= ~DSI_WCFGR_DSIM; hdsi->Instance->WCFGR |= DSI_WCFGR_DSIM; /* Select the virtual channel for the LTDC interface traffic */ hdsi->Instance->LVCIDR &= ~DSI_LVCIDR_VCID; hdsi->Instance->LVCIDR |= CmdCfg->VirtualChannelID; /* Configure the polarity of control signals */ hdsi->Instance->LPCR &= ~(DSI_LPCR_DEP | DSI_LPCR_VSP | DSI_LPCR_HSP); hdsi->Instance->LPCR |= (CmdCfg->DEPolarity | CmdCfg->VSPolarity | CmdCfg->HSPolarity); /* Select the color coding for the host */ hdsi->Instance->LCOLCR &= ~DSI_LCOLCR_COLC; hdsi->Instance->LCOLCR |= CmdCfg->ColorCoding; /* Select the color coding for the wrapper */ hdsi->Instance->WCFGR &= ~DSI_WCFGR_COLMUX; hdsi->Instance->WCFGR |= ((CmdCfg->ColorCoding) << 1U); /* Configure the maximum allowed size for write memory command */ hdsi->Instance->LCCR &= ~DSI_LCCR_CMDSIZE; hdsi->Instance->LCCR |= CmdCfg->CommandSize; /* Configure the tearing effect source and polarity and select the refresh mode */ hdsi->Instance->WCFGR &= ~(DSI_WCFGR_TESRC | DSI_WCFGR_TEPOL | DSI_WCFGR_AR | DSI_WCFGR_VSPOL); hdsi->Instance->WCFGR |= (CmdCfg->TearingEffectSource | CmdCfg->TearingEffectPolarity | CmdCfg->AutomaticRefresh | CmdCfg->VSyncPol); /* Configure the tearing effect acknowledge request */ hdsi->Instance->CMCR &= ~DSI_CMCR_TEARE; hdsi->Instance->CMCR |= CmdCfg->TEAcknowledgeRequest; /* Enable the Tearing Effect interrupt */ __HAL_DSI_ENABLE_IT(hdsi, DSI_IT_TE); /* Enable the End of Refresh interrupt */ __HAL_DSI_ENABLE_IT(hdsi, DSI_IT_ER); /* Process unlocked */ __HAL_UNLOCK(hdsi); return HAL_OK; } /** * @brief Configure command transmission mode: High-speed or Low-power * and enable/disable acknowledge request after packet transmission * @param hdsi pointer to a DSI_HandleTypeDef structure that contains * the configuration information for the DSI. * @param LPCmd pointer to a DSI_LPCmdTypeDef structure that contains * the DSI command transmission mode configuration parameters * @retval HAL status */ HAL_StatusTypeDef HAL_DSI_ConfigCommand(DSI_HandleTypeDef *hdsi, DSI_LPCmdTypeDef *LPCmd) { /* Process locked */ __HAL_LOCK(hdsi); assert_param(IS_DSI_LP_GSW0P(LPCmd->LPGenShortWriteNoP)); assert_param(IS_DSI_LP_GSW1P(LPCmd->LPGenShortWriteOneP)); assert_param(IS_DSI_LP_GSW2P(LPCmd->LPGenShortWriteTwoP)); assert_param(IS_DSI_LP_GSR0P(LPCmd->LPGenShortReadNoP)); assert_param(IS_DSI_LP_GSR1P(LPCmd->LPGenShortReadOneP)); assert_param(IS_DSI_LP_GSR2P(LPCmd->LPGenShortReadTwoP)); assert_param(IS_DSI_LP_GLW(LPCmd->LPGenLongWrite)); assert_param(IS_DSI_LP_DSW0P(LPCmd->LPDcsShortWriteNoP)); assert_param(IS_DSI_LP_DSW1P(LPCmd->LPDcsShortWriteOneP)); assert_param(IS_DSI_LP_DSR0P(LPCmd->LPDcsShortReadNoP)); assert_param(IS_DSI_LP_DLW(LPCmd->LPDcsLongWrite)); assert_param(IS_DSI_LP_MRDP(LPCmd->LPMaxReadPacket)); assert_param(IS_DSI_ACK_REQUEST(LPCmd->AcknowledgeRequest)); /* Select High-speed or Low-power for command transmission */ hdsi->Instance->CMCR &= ~(DSI_CMCR_GSW0TX | \ DSI_CMCR_GSW1TX | \ DSI_CMCR_GSW2TX | \ DSI_CMCR_GSR0TX | \ DSI_CMCR_GSR1TX | \ DSI_CMCR_GSR2TX | \ DSI_CMCR_GLWTX | \ DSI_CMCR_DSW0TX | \ DSI_CMCR_DSW1TX | \ DSI_CMCR_DSR0TX | \ DSI_CMCR_DLWTX | \ DSI_CMCR_MRDPS); hdsi->Instance->CMCR |= (LPCmd->LPGenShortWriteNoP | \ LPCmd->LPGenShortWriteOneP | \ LPCmd->LPGenShortWriteTwoP | \ LPCmd->LPGenShortReadNoP | \ LPCmd->LPGenShortReadOneP | \ LPCmd->LPGenShortReadTwoP | \ LPCmd->LPGenLongWrite | \ LPCmd->LPDcsShortWriteNoP | \ LPCmd->LPDcsShortWriteOneP | \ LPCmd->LPDcsShortReadNoP | \ LPCmd->LPDcsLongWrite | \ LPCmd->LPMaxReadPacket); /* Configure the acknowledge request after each packet transmission */ hdsi->Instance->CMCR &= ~DSI_CMCR_ARE; hdsi->Instance->CMCR |= LPCmd->AcknowledgeRequest; /* Process unlocked */ __HAL_UNLOCK(hdsi); return HAL_OK; } /** * @brief Configure the flow control parameters * @param hdsi pointer to a DSI_HandleTypeDef structure that contains * the configuration information for the DSI. * @param FlowControl flow control feature(s) to be enabled. * This parameter can be any combination of @arg DSI_FlowControl. * @retval HAL status */ HAL_StatusTypeDef HAL_DSI_ConfigFlowControl(DSI_HandleTypeDef *hdsi, uint32_t FlowControl) { /* Process locked */ __HAL_LOCK(hdsi); /* Check the parameters */ assert_param(IS_DSI_FLOW_CONTROL(FlowControl)); /* Set the DSI Host Protocol Configuration Register */ hdsi->Instance->PCR &= ~DSI_FLOW_CONTROL_ALL; hdsi->Instance->PCR |= FlowControl; /* Process unlocked */ __HAL_UNLOCK(hdsi); return HAL_OK; } /** * @brief Configure the DSI PHY timer parameters * @param hdsi pointer to a DSI_HandleTypeDef structure that contains * the configuration information for the DSI. * @param PhyTimers DSI_PHY_TimerTypeDef structure that contains * the DSI PHY timing parameters * @retval HAL status */ HAL_StatusTypeDef HAL_DSI_ConfigPhyTimer(DSI_HandleTypeDef *hdsi, DSI_PHY_TimerTypeDef *PhyTimers) { uint32_t maxTime; /* Process locked */ __HAL_LOCK(hdsi); maxTime = (PhyTimers->ClockLaneLP2HSTime > PhyTimers->ClockLaneHS2LPTime) ? PhyTimers->ClockLaneLP2HSTime : PhyTimers->ClockLaneHS2LPTime; /* Clock lane timer configuration */ /* In Automatic Clock Lane control mode, the DSI Host can turn off the clock lane between two High-Speed transmission. To do so, the DSI Host calculates the time required for the clock lane to change from HighSpeed to Low-Power and from Low-Power to High-Speed. This timings are configured by the HS2LP_TIME and LP2HS_TIME in the DSI Host Clock Lane Timer Configuration Register (DSI_CLTCR). But the DSI Host is not calculating LP2HS_TIME + HS2LP_TIME but 2 x HS2LP_TIME. Workaround : Configure HS2LP_TIME and LP2HS_TIME with the same value being the max of HS2LP_TIME or LP2HS_TIME. */ hdsi->Instance->CLTCR &= ~(DSI_CLTCR_LP2HS_TIME | DSI_CLTCR_HS2LP_TIME); hdsi->Instance->CLTCR |= (maxTime | ((maxTime) << 16U)); /* Data lane timer configuration */ hdsi->Instance->DLTCR &= ~(DSI_DLTCR_MRD_TIME | DSI_DLTCR_LP2HS_TIME | DSI_DLTCR_HS2LP_TIME); hdsi->Instance->DLTCR |= (PhyTimers->DataLaneMaxReadTime | ((PhyTimers->DataLaneLP2HSTime) << 16U) | (( PhyTimers->DataLaneHS2LPTime) << 24U)); /* Configure the wait period to request HS transmission after a stop state */ hdsi->Instance->PCONFR &= ~DSI_PCONFR_SW_TIME; hdsi->Instance->PCONFR |= ((PhyTimers->StopWaitTime) << 8U); /* Process unlocked */ __HAL_UNLOCK(hdsi); return HAL_OK; } /** * @brief Configure the DSI HOST timeout parameters * @param hdsi pointer to a DSI_HandleTypeDef structure that contains * the configuration information for the DSI. * @param HostTimeouts DSI_HOST_TimeoutTypeDef structure that contains * the DSI host timeout parameters * @retval HAL status */ HAL_StatusTypeDef HAL_DSI_ConfigHostTimeouts(DSI_HandleTypeDef *hdsi, DSI_HOST_TimeoutTypeDef *HostTimeouts) { /* Process locked */ __HAL_LOCK(hdsi); /* Set the timeout clock division factor */ hdsi->Instance->CCR &= ~DSI_CCR_TOCKDIV; hdsi->Instance->CCR |= ((HostTimeouts->TimeoutCkdiv) << 8U); /* High-speed transmission timeout */ hdsi->Instance->TCCR[0U] &= ~DSI_TCCR0_HSTX_TOCNT; hdsi->Instance->TCCR[0U] |= ((HostTimeouts->HighSpeedTransmissionTimeout) << 16U); /* Low-power reception timeout */ hdsi->Instance->TCCR[0U] &= ~DSI_TCCR0_LPRX_TOCNT; hdsi->Instance->TCCR[0U] |= HostTimeouts->LowPowerReceptionTimeout; /* High-speed read timeout */ hdsi->Instance->TCCR[1U] &= ~DSI_TCCR1_HSRD_TOCNT; hdsi->Instance->TCCR[1U] |= HostTimeouts->HighSpeedReadTimeout; /* Low-power read timeout */ hdsi->Instance->TCCR[2U] &= ~DSI_TCCR2_LPRD_TOCNT; hdsi->Instance->TCCR[2U] |= HostTimeouts->LowPowerReadTimeout; /* High-speed write timeout */ hdsi->Instance->TCCR[3U] &= ~DSI_TCCR3_HSWR_TOCNT; hdsi->Instance->TCCR[3U] |= HostTimeouts->HighSpeedWriteTimeout; /* High-speed write presp mode */ hdsi->Instance->TCCR[3U] &= ~DSI_TCCR3_PM; hdsi->Instance->TCCR[3U] |= HostTimeouts->HighSpeedWritePrespMode; /* Low-speed write timeout */ hdsi->Instance->TCCR[4U] &= ~DSI_TCCR4_LPWR_TOCNT; hdsi->Instance->TCCR[4U] |= HostTimeouts->LowPowerWriteTimeout; /* BTA timeout */ hdsi->Instance->TCCR[5U] &= ~DSI_TCCR5_BTA_TOCNT; hdsi->Instance->TCCR[5U] |= HostTimeouts->BTATimeout; /* Process unlocked */ __HAL_UNLOCK(hdsi); return HAL_OK; } /** * @brief Start the DSI module * @param hdsi pointer to a DSI_HandleTypeDef structure that contains * the configuration information for the DSI. * @retval HAL status */ HAL_StatusTypeDef HAL_DSI_Start(DSI_HandleTypeDef *hdsi) { /* Process locked */ __HAL_LOCK(hdsi); /* Enable the DSI host */ __HAL_DSI_ENABLE(hdsi); /* Enable the DSI wrapper */ __HAL_DSI_WRAPPER_ENABLE(hdsi); /* Process unlocked */ __HAL_UNLOCK(hdsi); return HAL_OK; } /** * @brief Stop the DSI module * @param hdsi pointer to a DSI_HandleTypeDef structure that contains * the configuration information for the DSI. * @retval HAL status */ HAL_StatusTypeDef HAL_DSI_Stop(DSI_HandleTypeDef *hdsi) { /* Process locked */ __HAL_LOCK(hdsi); /* Disable the DSI host */ __HAL_DSI_DISABLE(hdsi); /* Disable the DSI wrapper */ __HAL_DSI_WRAPPER_DISABLE(hdsi); /* Process unlocked */ __HAL_UNLOCK(hdsi); return HAL_OK; } /** * @brief Refresh the display in command mode * @param hdsi pointer to a DSI_HandleTypeDef structure that contains * the configuration information for the DSI. * @retval HAL status */ HAL_StatusTypeDef HAL_DSI_Refresh(DSI_HandleTypeDef *hdsi) { /* Process locked */ __HAL_LOCK(hdsi); /* Update the display */ hdsi->Instance->WCR |= DSI_WCR_LTDCEN; /* Process unlocked */ __HAL_UNLOCK(hdsi); return HAL_OK; } /** * @brief Controls the display color mode in Video mode * @param hdsi pointer to a DSI_HandleTypeDef structure that contains * the configuration information for the DSI. * @param ColorMode Color mode (full or 8-colors). * This parameter can be any value of @arg DSI_Color_Mode * @retval HAL status */ HAL_StatusTypeDef HAL_DSI_ColorMode(DSI_HandleTypeDef *hdsi, uint32_t ColorMode) { /* Process locked */ __HAL_LOCK(hdsi); /* Check the parameters */ assert_param(IS_DSI_COLOR_MODE(ColorMode)); /* Update the display color mode */ hdsi->Instance->WCR &= ~DSI_WCR_COLM; hdsi->Instance->WCR |= ColorMode; /* Process unlocked */ __HAL_UNLOCK(hdsi); return HAL_OK; } /** * @brief Control the display shutdown in Video mode * @param hdsi pointer to a DSI_HandleTypeDef structure that contains * the configuration information for the DSI. * @param Shutdown Shut-down (Display-ON or Display-OFF). * This parameter can be any value of @arg DSI_ShutDown * @retval HAL status */ HAL_StatusTypeDef HAL_DSI_Shutdown(DSI_HandleTypeDef *hdsi, uint32_t Shutdown) { /* Process locked */ __HAL_LOCK(hdsi); /* Check the parameters */ assert_param(IS_DSI_SHUT_DOWN(Shutdown)); /* Update the display Shutdown */ hdsi->Instance->WCR &= ~DSI_WCR_SHTDN; hdsi->Instance->WCR |= Shutdown; /* Process unlocked */ __HAL_UNLOCK(hdsi); return HAL_OK; } /** * @brief write short DCS or short Generic command * @param hdsi pointer to a DSI_HandleTypeDef structure that contains * the configuration information for the DSI. * @param ChannelID Virtual channel ID. * @param Mode DSI short packet data type. * This parameter can be any value of @arg DSI_SHORT_WRITE_PKT_Data_Type. * @param Param1 DSC command or first generic parameter. * This parameter can be any value of @arg DSI_DCS_Command or a * generic command code. * @param Param2 DSC parameter or second generic parameter. * @retval HAL status */ HAL_StatusTypeDef HAL_DSI_ShortWrite(DSI_HandleTypeDef *hdsi, uint32_t ChannelID, uint32_t Mode, uint32_t Param1, uint32_t Param2) { HAL_StatusTypeDef status; /* Check the parameters */ assert_param(IS_DSI_SHORT_WRITE_PACKET_TYPE(Mode)); /* Process locked */ __HAL_LOCK(hdsi); status = DSI_ShortWrite(hdsi, ChannelID, Mode, Param1, Param2); /* Process unlocked */ __HAL_UNLOCK(hdsi); return status; } /** * @brief write long DCS or long Generic command * @param hdsi pointer to a DSI_HandleTypeDef structure that contains * the configuration information for the DSI. * @param ChannelID Virtual channel ID. * @param Mode DSI long packet data type. * This parameter can be any value of @arg DSI_LONG_WRITE_PKT_Data_Type. * @param NbParams Number of parameters. * @param Param1 DSC command or first generic parameter. * This parameter can be any value of @arg DSI_DCS_Command or a * generic command code * @param ParametersTable Pointer to parameter values table. * @retval HAL status */ HAL_StatusTypeDef HAL_DSI_LongWrite(DSI_HandleTypeDef *hdsi, uint32_t ChannelID, uint32_t Mode, uint32_t NbParams, uint32_t Param1, uint8_t *ParametersTable) { uint32_t uicounter; uint32_t nbBytes; uint32_t count; uint32_t tickstart; uint32_t fifoword; uint8_t *pparams = ParametersTable; /* Process locked */ __HAL_LOCK(hdsi); /* Check the parameters */ assert_param(IS_DSI_LONG_WRITE_PACKET_TYPE(Mode)); /* Get tick */ tickstart = HAL_GetTick(); /* Wait for Command FIFO Empty */ while ((hdsi->Instance->GPSR & DSI_GPSR_CMDFE) == 0U) { /* Check for the Timeout */ if ((HAL_GetTick() - tickstart) > DSI_TIMEOUT_VALUE) { /* Process Unlocked */ __HAL_UNLOCK(hdsi); return HAL_TIMEOUT; } } /* Set the DCS code on payload byte 1, and the other parameters on the write FIFO command*/ fifoword = Param1; nbBytes = (NbParams < 3U) ? NbParams : 3U; for (count = 0U; count < nbBytes; count++) { fifoword |= (((uint32_t)(*(pparams + count))) << (8U + (8U * count))); } hdsi->Instance->GPDR = fifoword; uicounter = NbParams - nbBytes; pparams += nbBytes; /* Set the Next parameters on the write FIFO command*/ while (uicounter != 0U) { nbBytes = (uicounter < 4U) ? uicounter : 4U; fifoword = 0U; for (count = 0U; count < nbBytes; count++) { fifoword |= (((uint32_t)(*(pparams + count))) << (8U * count)); } hdsi->Instance->GPDR = fifoword; uicounter -= nbBytes; pparams += nbBytes; } /* Configure the packet to send a long DCS command */ DSI_ConfigPacketHeader(hdsi->Instance, ChannelID, Mode, ((NbParams + 1U) & 0x00FFU), (((NbParams + 1U) & 0xFF00U) >> 8U)); /* Process unlocked */ __HAL_UNLOCK(hdsi); return HAL_OK; } /** * @brief Read command (DCS or generic) * @param hdsi pointer to a DSI_HandleTypeDef structure that contains * the configuration information for the DSI. * @param ChannelNbr Virtual channel ID * @param Array pointer to a buffer to store the payload of a read back operation. * @param Size Data size to be read (in byte). * @param Mode DSI read packet data type. * This parameter can be any value of @arg DSI_SHORT_READ_PKT_Data_Type. * @param DCSCmd DCS get/read command. * @param ParametersTable Pointer to parameter values table. * @retval HAL status */ HAL_StatusTypeDef HAL_DSI_Read(DSI_HandleTypeDef *hdsi, uint32_t ChannelNbr, uint8_t *Array, uint32_t Size, uint32_t Mode, uint32_t DCSCmd, uint8_t *ParametersTable) { uint32_t tickstart; uint8_t *pdata = Array; uint32_t datasize = Size; uint32_t fifoword; uint32_t nbbytes; uint32_t count; /* Process locked */ __HAL_LOCK(hdsi); /* Check the parameters */ assert_param(IS_DSI_READ_PACKET_TYPE(Mode)); if (datasize > 2U) { /* set max return packet size */ if (DSI_ShortWrite(hdsi, ChannelNbr, DSI_MAX_RETURN_PKT_SIZE, ((datasize) & 0xFFU), (((datasize) >> 8U) & 0xFFU)) != HAL_OK) { /* Process Unlocked */ __HAL_UNLOCK(hdsi); return HAL_ERROR; } } /* Configure the packet to read command */ if (Mode == DSI_DCS_SHORT_PKT_READ) { DSI_ConfigPacketHeader(hdsi->Instance, ChannelNbr, Mode, DCSCmd, 0U); } else if (Mode == DSI_GEN_SHORT_PKT_READ_P0) { DSI_ConfigPacketHeader(hdsi->Instance, ChannelNbr, Mode, 0U, 0U); } else if (Mode == DSI_GEN_SHORT_PKT_READ_P1) { DSI_ConfigPacketHeader(hdsi->Instance, ChannelNbr, Mode, ParametersTable[0U], 0U); } else if (Mode == DSI_GEN_SHORT_PKT_READ_P2) { DSI_ConfigPacketHeader(hdsi->Instance, ChannelNbr, Mode, ParametersTable[0U], ParametersTable[1U]); } else { /* Process Unlocked */ __HAL_UNLOCK(hdsi); return HAL_ERROR; } /* Get tick */ tickstart = HAL_GetTick(); /* If DSI fifo is not empty, read requested bytes */ while (((int32_t)(datasize)) > 0) { if ((hdsi->Instance->GPSR & DSI_GPSR_PRDFE) == 0U) { fifoword = hdsi->Instance->GPDR; nbbytes = (datasize < 4U) ? datasize : 4U; for (count = 0U; count < nbbytes; count++) { *pdata = (uint8_t)(fifoword >> (8U * count)); pdata++; datasize--; } } /* Check for the Timeout */ if ((HAL_GetTick() - tickstart) > DSI_TIMEOUT_VALUE) { /* Process Unlocked */ __HAL_UNLOCK(hdsi); return HAL_TIMEOUT; } /* Software workaround to avoid HAL_TIMEOUT when a DSI read command is */ /* issued to the panel and the read data is not captured by the DSI Host */ /* which returns Packet Size Error. */ /* Need to ensure that the Read command has finished before checking PSE */ if ((hdsi->Instance->GPSR & DSI_GPSR_RCB) == 0U) { if ((hdsi->Instance->ISR[1U] & DSI_ISR1_PSE) == DSI_ISR1_PSE) { /* Process Unlocked */ __HAL_UNLOCK(hdsi); return HAL_ERROR; } } } /* Process unlocked */ __HAL_UNLOCK(hdsi); return HAL_OK; } /** * @brief Enter the ULPM (Ultra Low Power Mode) with the D-PHY PLL running * (only data lanes are in ULPM) * @param hdsi pointer to a DSI_HandleTypeDef structure that contains * the configuration information for the DSI. * @retval HAL status */ HAL_StatusTypeDef HAL_DSI_EnterULPMData(DSI_HandleTypeDef *hdsi) { uint32_t tickstart; /* Process locked */ __HAL_LOCK(hdsi); /* Verify the initial status of the DSI Host */ /* Verify that the clock lane and the digital section of the D-PHY are enabled */ if ((hdsi->Instance->PCTLR & (DSI_PCTLR_CKE | DSI_PCTLR_DEN)) != (DSI_PCTLR_CKE | DSI_PCTLR_DEN)) { /* Process Unlocked */ __HAL_UNLOCK(hdsi); return HAL_ERROR; } /* Verify that the D-PHY PLL and the reference bias are enabled */ if ((hdsi->Instance->WRPCR & DSI_WRPCR_PLLEN) != DSI_WRPCR_PLLEN) { /* Process Unlocked */ __HAL_UNLOCK(hdsi); return HAL_ERROR; } else if ((hdsi->Instance->WRPCR & DSI_WRPCR_REGEN) != DSI_WRPCR_REGEN) { /* Process Unlocked */ __HAL_UNLOCK(hdsi); return HAL_ERROR; } else { /* Nothing to do */ } /* Verify that there are no ULPS exit or request on data lanes */ if ((hdsi->Instance->PUCR & (DSI_PUCR_UEDL | DSI_PUCR_URDL)) != 0U) { /* Process Unlocked */ __HAL_UNLOCK(hdsi); return HAL_ERROR; } /* Verify that there are no Transmission trigger */ if ((hdsi->Instance->PTTCR & DSI_PTTCR_TX_TRIG) != 0U) { /* Process Unlocked */ __HAL_UNLOCK(hdsi); return HAL_ERROR; } /* Requires min of 400us delay before reading the PLLLS flag */ /* 1ms delay is inserted that is the minimum HAL delay granularity */ HAL_Delay(1); /* Verify that D-PHY PLL is locked */ tickstart = HAL_GetTick(); while ((__HAL_DSI_GET_FLAG(hdsi, DSI_FLAG_PLLLS) == 0U)) { /* Check for the Timeout */ if ((HAL_GetTick() - tickstart) > DSI_TIMEOUT_VALUE) { /* Process Unlocked */ __HAL_UNLOCK(hdsi); return HAL_TIMEOUT; } } /* Verify that all active lanes are in Stop state */ if ((hdsi->Instance->PCONFR & DSI_PCONFR_NL) == DSI_ONE_DATA_LANE) { if ((hdsi->Instance->PSR & DSI_PSR_UAN0) != DSI_PSR_UAN0) { /* Process Unlocked */ __HAL_UNLOCK(hdsi); return HAL_ERROR; } } else if ((hdsi->Instance->PCONFR & DSI_PCONFR_NL) == DSI_TWO_DATA_LANES) { if ((hdsi->Instance->PSR & (DSI_PSR_UAN0 | DSI_PSR_UAN1)) != (DSI_PSR_UAN0 | DSI_PSR_UAN1)) { /* Process Unlocked */ __HAL_UNLOCK(hdsi); return HAL_ERROR; } } else { /* Process unlocked */ __HAL_UNLOCK(hdsi); return HAL_ERROR; } /* ULPS Request on Data Lanes */ hdsi->Instance->PUCR |= DSI_PUCR_URDL; /* Get tick */ tickstart = HAL_GetTick(); /* Wait until the D-PHY active lanes enter into ULPM */ if ((hdsi->Instance->PCONFR & DSI_PCONFR_NL) == DSI_ONE_DATA_LANE) { while ((hdsi->Instance->PSR & DSI_PSR_UAN0) != 0U) { /* Check for the Timeout */ if ((HAL_GetTick() - tickstart) > DSI_TIMEOUT_VALUE) { /* Process Unlocked */ __HAL_UNLOCK(hdsi); return HAL_TIMEOUT; } } } else if ((hdsi->Instance->PCONFR & DSI_PCONFR_NL) == DSI_TWO_DATA_LANES) { while ((hdsi->Instance->PSR & (DSI_PSR_UAN0 | DSI_PSR_UAN1)) != 0U) { /* Check for the Timeout */ if ((HAL_GetTick() - tickstart) > DSI_TIMEOUT_VALUE) { /* Process Unlocked */ __HAL_UNLOCK(hdsi); return HAL_TIMEOUT; } } } else { /* Process unlocked */ __HAL_UNLOCK(hdsi); return HAL_ERROR; } /* Process unlocked */ __HAL_UNLOCK(hdsi); return HAL_OK; } /** * @brief Exit the ULPM (Ultra Low Power Mode) with the D-PHY PLL running * (only data lanes are in ULPM) * @param hdsi pointer to a DSI_HandleTypeDef structure that contains * the configuration information for the DSI. * @retval HAL status */ HAL_StatusTypeDef HAL_DSI_ExitULPMData(DSI_HandleTypeDef *hdsi) { uint32_t tickstart; /* Process locked */ __HAL_LOCK(hdsi); /* Verify that all active lanes are in ULPM */ if ((hdsi->Instance->PCONFR & DSI_PCONFR_NL) == DSI_ONE_DATA_LANE) { if ((hdsi->Instance->PSR & DSI_PSR_UAN0) != 0U) { /* Process Unlocked */ __HAL_UNLOCK(hdsi); return HAL_ERROR; } } else if ((hdsi->Instance->PCONFR & DSI_PCONFR_NL) == DSI_TWO_DATA_LANES) { if ((hdsi->Instance->PSR & (DSI_PSR_UAN0 | DSI_PSR_UAN1)) != 0U) { /* Process Unlocked */ __HAL_UNLOCK(hdsi); return HAL_ERROR; } } else { /* Process unlocked */ __HAL_UNLOCK(hdsi); return HAL_ERROR; } /* Turn on the DSI PLL */ __HAL_DSI_PLL_ENABLE(hdsi); /* Requires min of 400us delay before reading the PLLLS flag */ /* 1ms delay is inserted that is the minimum HAL delay granularity */ HAL_Delay(1); /* Get tick */ tickstart = HAL_GetTick(); /* Wait for the lock of the PLL */ while (__HAL_DSI_GET_FLAG(hdsi, DSI_FLAG_PLLLS) == 0U) { /* Check for the Timeout */ if ((HAL_GetTick() - tickstart) > DSI_TIMEOUT_VALUE) { /* Process Unlocked */ __HAL_UNLOCK(hdsi); return HAL_TIMEOUT; } } /* Exit ULPS on Data Lanes */ hdsi->Instance->PUCR |= DSI_PUCR_UEDL; /* Get tick */ tickstart = HAL_GetTick(); /* Wait until all active lanes exit ULPM */ if ((hdsi->Instance->PCONFR & DSI_PCONFR_NL) == DSI_ONE_DATA_LANE) { while ((hdsi->Instance->PSR & DSI_PSR_UAN0) != DSI_PSR_UAN0) { /* Check for the Timeout */ if ((HAL_GetTick() - tickstart) > DSI_TIMEOUT_VALUE) { /* Process Unlocked */ __HAL_UNLOCK(hdsi); return HAL_TIMEOUT; } } } else if ((hdsi->Instance->PCONFR & DSI_PCONFR_NL) == DSI_TWO_DATA_LANES) { while ((hdsi->Instance->PSR & (DSI_PSR_UAN0 | DSI_PSR_UAN1)) != (DSI_PSR_UAN0 | DSI_PSR_UAN1)) { /* Check for the Timeout */ if ((HAL_GetTick() - tickstart) > DSI_TIMEOUT_VALUE) { /* Process Unlocked */ __HAL_UNLOCK(hdsi); return HAL_TIMEOUT; } } } else { /* Process unlocked */ __HAL_UNLOCK(hdsi); return HAL_ERROR; } /* wait for 1 ms*/ HAL_Delay(1U); /* De-assert the ULPM requests and the ULPM exit bits */ hdsi->Instance->PUCR = 0U; /* Verify that D-PHY PLL is enabled */ if ((hdsi->Instance->WRPCR & DSI_WRPCR_PLLEN) != DSI_WRPCR_PLLEN) { /* Process Unlocked */ __HAL_UNLOCK(hdsi); return HAL_ERROR; } /* Verify that all active lanes are in Stop state */ if ((hdsi->Instance->PCONFR & DSI_PCONFR_NL) == DSI_ONE_DATA_LANE) { if ((hdsi->Instance->PSR & DSI_PSR_UAN0) != DSI_PSR_UAN0) { /* Process Unlocked */ __HAL_UNLOCK(hdsi); return HAL_ERROR; } } else if ((hdsi->Instance->PCONFR & DSI_PCONFR_NL) == DSI_TWO_DATA_LANES) { if ((hdsi->Instance->PSR & (DSI_PSR_UAN0 | DSI_PSR_UAN1)) != (DSI_PSR_UAN0 | DSI_PSR_UAN1)) { /* Process Unlocked */ __HAL_UNLOCK(hdsi); return HAL_ERROR; } } else { /* Process unlocked */ __HAL_UNLOCK(hdsi); return HAL_ERROR; } /* Verify that D-PHY PLL is locked */ /* Requires min of 400us delay before reading the PLLLS flag */ /* 1ms delay is inserted that is the minimum HAL delay granularity */ HAL_Delay(1); /* Get tick */ tickstart = HAL_GetTick(); /* Wait for the lock of the PLL */ while (__HAL_DSI_GET_FLAG(hdsi, DSI_FLAG_PLLLS) == 0U) { /* Check for the Timeout */ if ((HAL_GetTick() - tickstart) > DSI_TIMEOUT_VALUE) { /* Process Unlocked */ __HAL_UNLOCK(hdsi); return HAL_TIMEOUT; } } /* Process unlocked */ __HAL_UNLOCK(hdsi); return HAL_OK; } /** * @brief Enter the ULPM (Ultra Low Power Mode) with the D-PHY PLL turned off * (both data and clock lanes are in ULPM) * @param hdsi pointer to a DSI_HandleTypeDef structure that contains * the configuration information for the DSI. * @retval HAL status */ HAL_StatusTypeDef HAL_DSI_EnterULPM(DSI_HandleTypeDef *hdsi) { uint32_t tickstart; /* Process locked */ __HAL_LOCK(hdsi); /* Verify the initial status of the DSI Host */ /* Verify that the clock lane and the digital section of the D-PHY are enabled */ if ((hdsi->Instance->PCTLR & (DSI_PCTLR_CKE | DSI_PCTLR_DEN)) != (DSI_PCTLR_CKE | DSI_PCTLR_DEN)) { /* Process Unlocked */ __HAL_UNLOCK(hdsi); return HAL_ERROR; } /* Verify that the D-PHY PLL and the reference bias are enabled */ if ((hdsi->Instance->WRPCR & DSI_WRPCR_PLLEN) != DSI_WRPCR_PLLEN) { /* Process Unlocked */ __HAL_UNLOCK(hdsi); return HAL_ERROR; } else if ((hdsi->Instance->WRPCR & DSI_WRPCR_REGEN) != DSI_WRPCR_REGEN) { /* Process Unlocked */ __HAL_UNLOCK(hdsi); return HAL_ERROR; } else { /* Nothing to do */ } /* Verify that there are no ULPS exit or request on both data and clock lanes */ if ((hdsi->Instance->PUCR & (DSI_PUCR_UEDL | DSI_PUCR_URDL | DSI_PUCR_UECL | DSI_PUCR_URCL)) != 0U) { /* Process Unlocked */ __HAL_UNLOCK(hdsi); return HAL_ERROR; } /* Verify that there are no Transmission trigger */ if ((hdsi->Instance->PTTCR & DSI_PTTCR_TX_TRIG) != 0U) { /* Process Unlocked */ __HAL_UNLOCK(hdsi); return HAL_ERROR; } /* Requires min of 400us delay before reading the PLLLS flag */ /* 1ms delay is inserted that is the minimum HAL delay granularity */ HAL_Delay(1); /* Verify that D-PHY PLL is locked */ tickstart = HAL_GetTick(); while ((__HAL_DSI_GET_FLAG(hdsi, DSI_FLAG_PLLLS) == 0U)) { /* Check for the Timeout */ if ((HAL_GetTick() - tickstart) > DSI_TIMEOUT_VALUE) { /* Process Unlocked */ __HAL_UNLOCK(hdsi); return HAL_TIMEOUT; } } /* Verify that all active lanes are in Stop state */ if ((hdsi->Instance->PCONFR & DSI_PCONFR_NL) == DSI_ONE_DATA_LANE) { if ((hdsi->Instance->PSR & (DSI_PSR_UAN0 | DSI_PSR_PSS0)) != (DSI_PSR_UAN0 | DSI_PSR_PSS0)) { /* Process Unlocked */ __HAL_UNLOCK(hdsi); return HAL_ERROR; } } else if ((hdsi->Instance->PCONFR & DSI_PCONFR_NL) == DSI_TWO_DATA_LANES) { if ((hdsi->Instance->PSR & (DSI_PSR_UAN0 | DSI_PSR_PSS0 | DSI_PSR_PSS1 | \ DSI_PSR_UAN1)) != (DSI_PSR_UAN0 | DSI_PSR_PSS0 | DSI_PSR_PSS1 | DSI_PSR_UAN1)) { /* Process Unlocked */ __HAL_UNLOCK(hdsi); return HAL_ERROR; } } else { /* Process unlocked */ __HAL_UNLOCK(hdsi); return HAL_ERROR; } /* Clock lane configuration: no more HS request */ hdsi->Instance->CLCR &= ~DSI_CLCR_DPCC; /* Use system PLL as byte lane clock source before stopping DSIPHY clock source */ __HAL_RCC_DSI_CONFIG(RCC_DSICLKSOURCE_PLLR); /* ULPS Request on Clock and Data Lanes */ hdsi->Instance->PUCR |= (DSI_PUCR_URCL | DSI_PUCR_URDL); /* Get tick */ tickstart = HAL_GetTick(); /* Wait until all active lanes enter ULPM */ if ((hdsi->Instance->PCONFR & DSI_PCONFR_NL) == DSI_ONE_DATA_LANE) { while ((hdsi->Instance->PSR & (DSI_PSR_UAN0 | DSI_PSR_UANC)) != 0U) { /* Check for the Timeout */ if ((HAL_GetTick() - tickstart) > DSI_TIMEOUT_VALUE) { /* Process Unlocked */ __HAL_UNLOCK(hdsi); return HAL_TIMEOUT; } } } else if ((hdsi->Instance->PCONFR & DSI_PCONFR_NL) == DSI_TWO_DATA_LANES) { while ((hdsi->Instance->PSR & (DSI_PSR_UAN0 | DSI_PSR_UAN1 | DSI_PSR_UANC)) != 0U) { /* Check for the Timeout */ if ((HAL_GetTick() - tickstart) > DSI_TIMEOUT_VALUE) { /* Process Unlocked */ __HAL_UNLOCK(hdsi); return HAL_TIMEOUT; } } } else { /* Process unlocked */ __HAL_UNLOCK(hdsi); return HAL_ERROR; } /* Turn off the DSI PLL */ __HAL_DSI_PLL_DISABLE(hdsi); /* Process unlocked */ __HAL_UNLOCK(hdsi); return HAL_OK; } /** * @brief Exit the ULPM (Ultra Low Power Mode) with the D-PHY PLL turned off * (both data and clock lanes are in ULPM) * @param hdsi pointer to a DSI_HandleTypeDef structure that contains * the configuration information for the DSI. * @retval HAL status */ HAL_StatusTypeDef HAL_DSI_ExitULPM(DSI_HandleTypeDef *hdsi) { uint32_t tickstart; /* Process locked */ __HAL_LOCK(hdsi); /* Verify that all active lanes are in ULPM */ if ((hdsi->Instance->PCONFR & DSI_PCONFR_NL) == DSI_ONE_DATA_LANE) { if ((hdsi->Instance->PSR & (DSI_PSR_RUE0 | DSI_PSR_UAN0 | DSI_PSR_PSS0 | \ DSI_PSR_UANC | DSI_PSR_PSSC | DSI_PSR_PD)) != 0U) { /* Process Unlocked */ __HAL_UNLOCK(hdsi); return HAL_ERROR; } } else if ((hdsi->Instance->PCONFR & DSI_PCONFR_NL) == DSI_TWO_DATA_LANES) { if ((hdsi->Instance->PSR & (DSI_PSR_RUE0 | DSI_PSR_UAN0 | DSI_PSR_PSS0 | DSI_PSR_UAN1 | \ DSI_PSR_PSS1 | DSI_PSR_UANC | DSI_PSR_PSSC | DSI_PSR_PD)) != 0U) { /* Process Unlocked */ __HAL_UNLOCK(hdsi); return HAL_ERROR; } } else { /* Process unlocked */ __HAL_UNLOCK(hdsi); return HAL_ERROR; } /* Turn on the DSI PLL */ __HAL_DSI_PLL_ENABLE(hdsi); /* Requires min of 400us delay before reading the PLLLS flag */ /* 1ms delay is inserted that is the minimum HAL delay granularity */ HAL_Delay(1); /* Get tick */ tickstart = HAL_GetTick(); /* Wait for the lock of the PLL */ while (__HAL_DSI_GET_FLAG(hdsi, DSI_FLAG_PLLLS) == 0U) { /* Check for the Timeout */ if ((HAL_GetTick() - tickstart) > DSI_TIMEOUT_VALUE) { /* Process Unlocked */ __HAL_UNLOCK(hdsi); return HAL_TIMEOUT; } } /* Exit ULPS on Clock and Data Lanes */ hdsi->Instance->PUCR |= (DSI_PUCR_UECL | DSI_PUCR_UEDL); /* Get tick */ tickstart = HAL_GetTick(); /* Wait until all active lanes exit ULPM */ if ((hdsi->Instance->PCONFR & DSI_PCONFR_NL) == DSI_ONE_DATA_LANE) { while ((hdsi->Instance->PSR & (DSI_PSR_UAN0 | DSI_PSR_UANC)) != (DSI_PSR_UAN0 | DSI_PSR_UANC)) { /* Check for the Timeout */ if ((HAL_GetTick() - tickstart) > DSI_TIMEOUT_VALUE) { /* Process Unlocked */ __HAL_UNLOCK(hdsi); return HAL_TIMEOUT; } } } else if ((hdsi->Instance->PCONFR & DSI_PCONFR_NL) == DSI_TWO_DATA_LANES) { while ((hdsi->Instance->PSR & (DSI_PSR_UAN0 | DSI_PSR_UAN1 | DSI_PSR_UANC)) != (DSI_PSR_UAN0 | DSI_PSR_UAN1 | DSI_PSR_UANC)) { /* Check for the Timeout */ if ((HAL_GetTick() - tickstart) > DSI_TIMEOUT_VALUE) { /* Process Unlocked */ __HAL_UNLOCK(hdsi); return HAL_TIMEOUT; } } } else { /* Process unlocked */ __HAL_UNLOCK(hdsi); return HAL_ERROR; } /* wait for 1 ms */ HAL_Delay(1U); /* De-assert the ULPM requests and the ULPM exit bits */ hdsi->Instance->PUCR = 0U; /* Switch the lane byte clock source in the RCC from system PLL to D-PHY */ __HAL_RCC_DSI_CONFIG(RCC_DSICLKSOURCE_DSIPHY); /* Restore clock lane configuration to HS */ hdsi->Instance->CLCR |= DSI_CLCR_DPCC; /* Verify that D-PHY PLL is enabled */ if ((hdsi->Instance->WRPCR & DSI_WRPCR_PLLEN) != DSI_WRPCR_PLLEN) { /* Process Unlocked */ __HAL_UNLOCK(hdsi); return HAL_ERROR; } /* Verify that all active lanes are in Stop state */ if ((hdsi->Instance->PCONFR & DSI_PCONFR_NL) == DSI_ONE_DATA_LANE) { if ((hdsi->Instance->PSR & (DSI_PSR_UAN0 | DSI_PSR_PSS0)) != (DSI_PSR_UAN0 | DSI_PSR_PSS0)) { /* Process Unlocked */ __HAL_UNLOCK(hdsi); return HAL_ERROR; } } else if ((hdsi->Instance->PCONFR & DSI_PCONFR_NL) == DSI_TWO_DATA_LANES) { if ((hdsi->Instance->PSR & (DSI_PSR_UAN0 | DSI_PSR_PSS0 | DSI_PSR_PSS1 | \ DSI_PSR_UAN1)) != (DSI_PSR_UAN0 | DSI_PSR_PSS0 | DSI_PSR_PSS1 | DSI_PSR_UAN1)) { /* Process Unlocked */ __HAL_UNLOCK(hdsi); return HAL_ERROR; } } else { /* Process unlocked */ __HAL_UNLOCK(hdsi); return HAL_ERROR; } /* Verify that D-PHY PLL is locked */ /* Requires min of 400us delay before reading the PLLLS flag */ /* 1ms delay is inserted that is the minimum HAL delay granularity */ HAL_Delay(1); /* Get tick */ tickstart = HAL_GetTick(); /* Wait for the lock of the PLL */ while (__HAL_DSI_GET_FLAG(hdsi, DSI_FLAG_PLLLS) == 0U) { /* Check for the Timeout */ if ((HAL_GetTick() - tickstart) > DSI_TIMEOUT_VALUE) { /* Process Unlocked */ __HAL_UNLOCK(hdsi); return HAL_TIMEOUT; } } /* Process unlocked */ __HAL_UNLOCK(hdsi); return HAL_OK; } /** * @brief Start test pattern generation * @param hdsi pointer to a DSI_HandleTypeDef structure that contains * the configuration information for the DSI. * @param Mode Pattern generator mode * This parameter can be one of the following values: * 0 : Color bars (horizontal or vertical) * 1 : BER pattern (vertical only) * @param Orientation Pattern generator orientation * This parameter can be one of the following values: * 0 : Vertical color bars * 1 : Horizontal color bars * @retval HAL status */ HAL_StatusTypeDef HAL_DSI_PatternGeneratorStart(DSI_HandleTypeDef *hdsi, uint32_t Mode, uint32_t Orientation) { /* Process locked */ __HAL_LOCK(hdsi); /* Configure pattern generator mode and orientation */ hdsi->Instance->VMCR &= ~(DSI_VMCR_PGM | DSI_VMCR_PGO); hdsi->Instance->VMCR |= ((Mode << 20U) | (Orientation << 24U)); /* Enable pattern generator by setting PGE bit */ hdsi->Instance->VMCR |= DSI_VMCR_PGE; /* Process unlocked */ __HAL_UNLOCK(hdsi); return HAL_OK; } /** * @brief Stop test pattern generation * @param hdsi pointer to a DSI_HandleTypeDef structure that contains * the configuration information for the DSI. * @retval HAL status */ HAL_StatusTypeDef HAL_DSI_PatternGeneratorStop(DSI_HandleTypeDef *hdsi) { /* Process locked */ __HAL_LOCK(hdsi); /* Disable pattern generator by clearing PGE bit */ hdsi->Instance->VMCR &= ~DSI_VMCR_PGE; /* Process unlocked */ __HAL_UNLOCK(hdsi); return HAL_OK; } /** * @brief Set Slew-Rate And Delay Tuning * @param hdsi pointer to a DSI_HandleTypeDef structure that contains * the configuration information for the DSI. * @param CommDelay Communication delay to be adjusted. * This parameter can be any value of @arg DSI_Communication_Delay * @param Lane select between clock or data lanes. * This parameter can be any value of @arg DSI_Lane_Group * @param Value Custom value of the slew-rate or delay * @retval HAL status */ HAL_StatusTypeDef HAL_DSI_SetSlewRateAndDelayTuning(DSI_HandleTypeDef *hdsi, uint32_t CommDelay, uint32_t Lane, uint32_t Value) { /* Process locked */ __HAL_LOCK(hdsi); /* Check function parameters */ assert_param(IS_DSI_COMMUNICATION_DELAY(CommDelay)); assert_param(IS_DSI_LANE_GROUP(Lane)); switch (CommDelay) { case DSI_SLEW_RATE_HSTX: if (Lane == DSI_CLOCK_LANE) { /* High-Speed Transmission Slew Rate Control on Clock Lane */ hdsi->Instance->WPCR[1U] &= ~DSI_WPCR1_HSTXSRCCL; hdsi->Instance->WPCR[1U] |= Value << 16U; } else if (Lane == DSI_DATA_LANES) { /* High-Speed Transmission Slew Rate Control on Data Lanes */ hdsi->Instance->WPCR[1U] &= ~DSI_WPCR1_HSTXSRCDL; hdsi->Instance->WPCR[1U] |= Value << 18U; } else { /* Process unlocked */ __HAL_UNLOCK(hdsi); return HAL_ERROR; } break; case DSI_SLEW_RATE_LPTX: if (Lane == DSI_CLOCK_LANE) { /* Low-Power transmission Slew Rate Compensation on Clock Lane */ hdsi->Instance->WPCR[1U] &= ~DSI_WPCR1_LPSRCCL; hdsi->Instance->WPCR[1U] |= Value << 6U; } else if (Lane == DSI_DATA_LANES) { /* Low-Power transmission Slew Rate Compensation on Data Lanes */ hdsi->Instance->WPCR[1U] &= ~DSI_WPCR1_LPSRCDL; hdsi->Instance->WPCR[1U] |= Value << 8U; } else { /* Process unlocked */ __HAL_UNLOCK(hdsi); return HAL_ERROR; } break; case DSI_HS_DELAY: if (Lane == DSI_CLOCK_LANE) { /* High-Speed Transmission Delay on Clock Lane */ hdsi->Instance->WPCR[1U] &= ~DSI_WPCR1_HSTXDCL; hdsi->Instance->WPCR[1U] |= Value; } else if (Lane == DSI_DATA_LANES) { /* High-Speed Transmission Delay on Data Lanes */ hdsi->Instance->WPCR[1U] &= ~DSI_WPCR1_HSTXDDL; hdsi->Instance->WPCR[1U] |= Value << 2U; } else { /* Process unlocked */ __HAL_UNLOCK(hdsi); return HAL_ERROR; } break; default: break; } /* Process unlocked */ __HAL_UNLOCK(hdsi); return HAL_OK; } /** * @brief Low-Power Reception Filter Tuning * @param hdsi pointer to a DSI_HandleTypeDef structure that contains * the configuration information for the DSI. * @param Frequency cutoff frequency of low-pass filter at the input of LPRX * @retval HAL status */ HAL_StatusTypeDef HAL_DSI_SetLowPowerRXFilter(DSI_HandleTypeDef *hdsi, uint32_t Frequency) { /* Process locked */ __HAL_LOCK(hdsi); /* Low-Power RX low-pass Filtering Tuning */ hdsi->Instance->WPCR[1U] &= ~DSI_WPCR1_LPRXFT; hdsi->Instance->WPCR[1U] |= Frequency << 25U; /* Process unlocked */ __HAL_UNLOCK(hdsi); return HAL_OK; } /** * @brief Activate an additional current path on all lanes to meet the SDDTx parameter * defined in the MIPI D-PHY specification * @param hdsi pointer to a DSI_HandleTypeDef structure that contains * the configuration information for the DSI. * @param State ENABLE or DISABLE * @retval HAL status */ HAL_StatusTypeDef HAL_DSI_SetSDD(DSI_HandleTypeDef *hdsi, FunctionalState State) { /* Process locked */ __HAL_LOCK(hdsi); /* Check function parameters */ assert_param(IS_FUNCTIONAL_STATE(State)); /* Activate/Disactivate additional current path on all lanes */ hdsi->Instance->WPCR[1U] &= ~DSI_WPCR1_SDDC; hdsi->Instance->WPCR[1U] |= ((uint32_t)State << 12U); /* Process unlocked */ __HAL_UNLOCK(hdsi); return HAL_OK; } /** * @brief Custom lane pins configuration * @param hdsi pointer to a DSI_HandleTypeDef structure that contains * the configuration information for the DSI. * @param CustomLane Function to be applied on selected lane. * This parameter can be any value of @arg DSI_CustomLane * @param Lane select between clock or data lane 0 or data lane 1. * This parameter can be any value of @arg DSI_Lane_Select * @param State ENABLE or DISABLE * @retval HAL status */ HAL_StatusTypeDef HAL_DSI_SetLanePinsConfiguration(DSI_HandleTypeDef *hdsi, uint32_t CustomLane, uint32_t Lane, FunctionalState State) { /* Process locked */ __HAL_LOCK(hdsi); /* Check function parameters */ assert_param(IS_DSI_CUSTOM_LANE(CustomLane)); assert_param(IS_DSI_LANE(Lane)); assert_param(IS_FUNCTIONAL_STATE(State)); switch (CustomLane) { case DSI_SWAP_LANE_PINS: if (Lane == DSI_CLK_LANE) { /* Swap pins on clock lane */ hdsi->Instance->WPCR[0U] &= ~DSI_WPCR0_SWCL; hdsi->Instance->WPCR[0U] |= ((uint32_t)State << 6U); } else if (Lane == DSI_DATA_LANE0) { /* Swap pins on data lane 0 */ hdsi->Instance->WPCR[0U] &= ~DSI_WPCR0_SWDL0; hdsi->Instance->WPCR[0U] |= ((uint32_t)State << 7U); } else if (Lane == DSI_DATA_LANE1) { /* Swap pins on data lane 1 */ hdsi->Instance->WPCR[0U] &= ~DSI_WPCR0_SWDL1; hdsi->Instance->WPCR[0U] |= ((uint32_t)State << 8U); } else { /* Process unlocked */ __HAL_UNLOCK(hdsi); return HAL_ERROR; } break; case DSI_INVERT_HS_SIGNAL: if (Lane == DSI_CLK_LANE) { /* Invert HS signal on clock lane */ hdsi->Instance->WPCR[0U] &= ~DSI_WPCR0_HSICL; hdsi->Instance->WPCR[0U] |= ((uint32_t)State << 9U); } else if (Lane == DSI_DATA_LANE0) { /* Invert HS signal on data lane 0 */ hdsi->Instance->WPCR[0U] &= ~DSI_WPCR0_HSIDL0; hdsi->Instance->WPCR[0U] |= ((uint32_t)State << 10U); } else if (Lane == DSI_DATA_LANE1) { /* Invert HS signal on data lane 1 */ hdsi->Instance->WPCR[0U] &= ~DSI_WPCR0_HSIDL1; hdsi->Instance->WPCR[0U] |= ((uint32_t)State << 11U); } else { /* Process unlocked */ __HAL_UNLOCK(hdsi); return HAL_ERROR; } break; default: break; } /* Process unlocked */ __HAL_UNLOCK(hdsi); return HAL_OK; } /** * @brief Set custom timing for the PHY * @param hdsi pointer to a DSI_HandleTypeDef structure that contains * the configuration information for the DSI. * @param Timing PHY timing to be adjusted. * This parameter can be any value of @arg DSI_PHY_Timing * @param State ENABLE or DISABLE * @param Value Custom value of the timing * @retval HAL status */ HAL_StatusTypeDef HAL_DSI_SetPHYTimings(DSI_HandleTypeDef *hdsi, uint32_t Timing, FunctionalState State, uint32_t Value) { /* Process locked */ __HAL_LOCK(hdsi); /* Check function parameters */ assert_param(IS_DSI_PHY_TIMING(Timing)); assert_param(IS_FUNCTIONAL_STATE(State)); switch (Timing) { case DSI_TCLK_POST: /* Enable/Disable custom timing setting */ hdsi->Instance->WPCR[0U] &= ~DSI_WPCR0_TCLKPOSTEN; hdsi->Instance->WPCR[0U] |= ((uint32_t)State << 27U); if (State != DISABLE) { /* Set custom value */ hdsi->Instance->WPCR[4U] &= ~DSI_WPCR4_TCLKPOST; hdsi->Instance->WPCR[4U] |= Value & DSI_WPCR4_TCLKPOST; } break; case DSI_TLPX_CLK: /* Enable/Disable custom timing setting */ hdsi->Instance->WPCR[0U] &= ~DSI_WPCR0_TLPXCEN; hdsi->Instance->WPCR[0U] |= ((uint32_t)State << 26U); if (State != DISABLE) { /* Set custom value */ hdsi->Instance->WPCR[3U] &= ~DSI_WPCR3_TLPXC; hdsi->Instance->WPCR[3U] |= (Value << 24U) & DSI_WPCR3_TLPXC; } break; case DSI_THS_EXIT: /* Enable/Disable custom timing setting */ hdsi->Instance->WPCR[0U] &= ~DSI_WPCR0_THSEXITEN; hdsi->Instance->WPCR[0U] |= ((uint32_t)State << 25U); if (State != DISABLE) { /* Set custom value */ hdsi->Instance->WPCR[3U] &= ~DSI_WPCR3_THSEXIT; hdsi->Instance->WPCR[3U] |= (Value << 16U) & DSI_WPCR3_THSEXIT; } break; case DSI_TLPX_DATA: /* Enable/Disable custom timing setting */ hdsi->Instance->WPCR[0U] &= ~DSI_WPCR0_TLPXDEN; hdsi->Instance->WPCR[0U] |= ((uint32_t)State << 24U); if (State != DISABLE) { /* Set custom value */ hdsi->Instance->WPCR[3U] &= ~DSI_WPCR3_TLPXD; hdsi->Instance->WPCR[3U] |= (Value << 8U) & DSI_WPCR3_TLPXD; } break; case DSI_THS_ZERO: /* Enable/Disable custom timing setting */ hdsi->Instance->WPCR[0U] &= ~DSI_WPCR0_THSZEROEN; hdsi->Instance->WPCR[0U] |= ((uint32_t)State << 23U); if (State != DISABLE) { /* Set custom value */ hdsi->Instance->WPCR[3U] &= ~DSI_WPCR3_THSZERO; hdsi->Instance->WPCR[3U] |= Value & DSI_WPCR3_THSZERO; } break; case DSI_THS_TRAIL: /* Enable/Disable custom timing setting */ hdsi->Instance->WPCR[0U] &= ~DSI_WPCR0_THSTRAILEN; hdsi->Instance->WPCR[0U] |= ((uint32_t)State << 22U); if (State != DISABLE) { /* Set custom value */ hdsi->Instance->WPCR[2U] &= ~DSI_WPCR2_THSTRAIL; hdsi->Instance->WPCR[2U] |= (Value << 24U) & DSI_WPCR2_THSTRAIL; } break; case DSI_THS_PREPARE: /* Enable/Disable custom timing setting */ hdsi->Instance->WPCR[0U] &= ~DSI_WPCR0_THSPREPEN; hdsi->Instance->WPCR[0U] |= ((uint32_t)State << 21U); if (State != DISABLE) { /* Set custom value */ hdsi->Instance->WPCR[2U] &= ~DSI_WPCR2_THSPREP; hdsi->Instance->WPCR[2U] |= (Value << 16U) & DSI_WPCR2_THSPREP; } break; case DSI_TCLK_ZERO: /* Enable/Disable custom timing setting */ hdsi->Instance->WPCR[0U] &= ~DSI_WPCR0_TCLKZEROEN; hdsi->Instance->WPCR[0U] |= ((uint32_t)State << 20U); if (State != DISABLE) { /* Set custom value */ hdsi->Instance->WPCR[2U] &= ~DSI_WPCR2_TCLKZERO; hdsi->Instance->WPCR[2U] |= (Value << 8U) & DSI_WPCR2_TCLKZERO; } break; case DSI_TCLK_PREPARE: /* Enable/Disable custom timing setting */ hdsi->Instance->WPCR[0U] &= ~DSI_WPCR0_TCLKPREPEN; hdsi->Instance->WPCR[0U] |= ((uint32_t)State << 19U); if (State != DISABLE) { /* Set custom value */ hdsi->Instance->WPCR[2U] &= ~DSI_WPCR2_TCLKPREP; hdsi->Instance->WPCR[2U] |= Value & DSI_WPCR2_TCLKPREP; } break; default: break; } /* Process unlocked */ __HAL_UNLOCK(hdsi); return HAL_OK; } /** * @brief Force the Clock/Data Lane in TX Stop Mode * @param hdsi pointer to a DSI_HandleTypeDef structure that contains * the configuration information for the DSI. * @param Lane select between clock or data lanes. * This parameter can be any value of @arg DSI_Lane_Group * @param State ENABLE or DISABLE * @retval HAL status */ HAL_StatusTypeDef HAL_DSI_ForceTXStopMode(DSI_HandleTypeDef *hdsi, uint32_t Lane, FunctionalState State) { /* Process locked */ __HAL_LOCK(hdsi); /* Check function parameters */ assert_param(IS_DSI_LANE_GROUP(Lane)); assert_param(IS_FUNCTIONAL_STATE(State)); if (Lane == DSI_CLOCK_LANE) { /* Force/Unforce the Clock Lane in TX Stop Mode */ hdsi->Instance->WPCR[0U] &= ~DSI_WPCR0_FTXSMCL; hdsi->Instance->WPCR[0U] |= ((uint32_t)State << 12U); } else if (Lane == DSI_DATA_LANES) { /* Force/Unforce the Data Lanes in TX Stop Mode */ hdsi->Instance->WPCR[0U] &= ~DSI_WPCR0_FTXSMDL; hdsi->Instance->WPCR[0U] |= ((uint32_t)State << 13U); } else { /* Process unlocked */ __HAL_UNLOCK(hdsi); return HAL_ERROR; } /* Process unlocked */ __HAL_UNLOCK(hdsi); return HAL_OK; } /** * @brief Force LP Receiver in Low-Power Mode * @param hdsi pointer to a DSI_HandleTypeDef structure that contains * the configuration information for the DSI. * @param State ENABLE or DISABLE * @retval HAL status */ HAL_StatusTypeDef HAL_DSI_ForceRXLowPower(DSI_HandleTypeDef *hdsi, FunctionalState State) { /* Process locked */ __HAL_LOCK(hdsi); /* Check function parameters */ assert_param(IS_FUNCTIONAL_STATE(State)); /* Force/Unforce LP Receiver in Low-Power Mode */ hdsi->Instance->WPCR[1U] &= ~DSI_WPCR1_FLPRXLPM; hdsi->Instance->WPCR[1U] |= ((uint32_t)State << 22U); /* Process unlocked */ __HAL_UNLOCK(hdsi); return HAL_OK; } /** * @brief Force Data Lanes in RX Mode after a BTA * @param hdsi pointer to a DSI_HandleTypeDef structure that contains * the configuration information for the DSI. * @param State ENABLE or DISABLE * @retval HAL status */ HAL_StatusTypeDef HAL_DSI_ForceDataLanesInRX(DSI_HandleTypeDef *hdsi, FunctionalState State) { /* Process locked */ __HAL_LOCK(hdsi); /* Check function parameters */ assert_param(IS_FUNCTIONAL_STATE(State)); /* Force Data Lanes in RX Mode */ hdsi->Instance->WPCR[0U] &= ~DSI_WPCR0_TDDL; hdsi->Instance->WPCR[0U] |= ((uint32_t)State << 16U); /* Process unlocked */ __HAL_UNLOCK(hdsi); return HAL_OK; } /** * @brief Enable a pull-down on the lanes to prevent from floating states when unused * @param hdsi pointer to a DSI_HandleTypeDef structure that contains * the configuration information for the DSI. * @param State ENABLE or DISABLE * @retval HAL status */ HAL_StatusTypeDef HAL_DSI_SetPullDown(DSI_HandleTypeDef *hdsi, FunctionalState State) { /* Process locked */ __HAL_LOCK(hdsi); /* Check function parameters */ assert_param(IS_FUNCTIONAL_STATE(State)); /* Enable/Disable pull-down on lanes */ hdsi->Instance->WPCR[0U] &= ~DSI_WPCR0_PDEN; hdsi->Instance->WPCR[0U] |= ((uint32_t)State << 18U); /* Process unlocked */ __HAL_UNLOCK(hdsi); return HAL_OK; } /** * @brief Switch off the contention detection on data lanes * @param hdsi pointer to a DSI_HandleTypeDef structure that contains * the configuration information for the DSI. * @param State ENABLE or DISABLE * @retval HAL status */ HAL_StatusTypeDef HAL_DSI_SetContentionDetectionOff(DSI_HandleTypeDef *hdsi, FunctionalState State) { /* Process locked */ __HAL_LOCK(hdsi); /* Check function parameters */ assert_param(IS_FUNCTIONAL_STATE(State)); /* Contention Detection on Data Lanes OFF */ hdsi->Instance->WPCR[0U] &= ~DSI_WPCR0_CDOFFDL; hdsi->Instance->WPCR[0U] |= ((uint32_t)State << 14U); /* Process unlocked */ __HAL_UNLOCK(hdsi); return HAL_OK; } /** * @} */ /** @defgroup DSI_Group4 Peripheral State and Errors functions * @brief Peripheral State and Errors functions * @verbatim =============================================================================== ##### Peripheral State and Errors functions ##### =============================================================================== [..] This subsection provides functions allowing to (+) Check the DSI state. (+) Get error code. @endverbatim * @{ */ /** * @brief Return the DSI state * @param hdsi pointer to a DSI_HandleTypeDef structure that contains * the configuration information for the DSI. * @retval HAL state */ HAL_DSI_StateTypeDef HAL_DSI_GetState(DSI_HandleTypeDef *hdsi) { return hdsi->State; } /** * @brief Return the DSI error code * @param hdsi pointer to a DSI_HandleTypeDef structure that contains * the configuration information for the DSI. * @retval DSI Error Code */ uint32_t HAL_DSI_GetError(DSI_HandleTypeDef *hdsi) { /* Get the error code */ return hdsi->ErrorCode; } /** * @} */ /** * @} */ /** * @} */ #endif /* DSI */ #endif /* HAL_DSI_MODULE_ENABLED */ /** * @} */