/* * Copyright (c) 2015, Freescale Semiconductor, Inc. * Copyright 2016-2020 NXP * All rights reserved. * * SPDX-License-Identifier: BSD-3-Clause */ #ifndef _FSL_GPT_H_ #define _FSL_GPT_H_ #include "fsl_common.h" /*! * @addtogroup gpt * @{ */ /******************************************************************************* * Definitions ******************************************************************************/ /*! @name Driver version */ /*@{*/ #define FSL_GPT_DRIVER_VERSION (MAKE_VERSION(2, 0, 3)) /*@}*/ /*! * @brief List of clock sources * @note Actual number of clock sources is SoC dependent */ typedef enum _gpt_clock_source { kGPT_ClockSource_Off = 0U, /*!< GPT Clock Source Off.*/ kGPT_ClockSource_Periph = 1U, /*!< GPT Clock Source from Peripheral Clock.*/ kGPT_ClockSource_HighFreq = 2U, /*!< GPT Clock Source from High Frequency Reference Clock.*/ kGPT_ClockSource_Ext = 3U, /*!< GPT Clock Source from external pin.*/ kGPT_ClockSource_LowFreq = 4U, /*!< GPT Clock Source from Low Frequency Reference Clock.*/ kGPT_ClockSource_Osc = 5U, /*!< GPT Clock Source from Crystal oscillator.*/ } gpt_clock_source_t; /*! @brief List of input capture channel number. */ typedef enum _gpt_input_capture_channel { kGPT_InputCapture_Channel1 = 0U, /*!< GPT Input Capture Channel1.*/ kGPT_InputCapture_Channel2 = 1U, /*!< GPT Input Capture Channel2.*/ } gpt_input_capture_channel_t; /*! @brief List of input capture operation mode. */ typedef enum _gpt_input_operation_mode { kGPT_InputOperation_Disabled = 0U, /*!< Don't capture.*/ kGPT_InputOperation_RiseEdge = 1U, /*!< Capture on rising edge of input pin.*/ kGPT_InputOperation_FallEdge = 2U, /*!< Capture on falling edge of input pin.*/ kGPT_InputOperation_BothEdge = 3U, /*!< Capture on both edges of input pin.*/ } gpt_input_operation_mode_t; /*! @brief List of output compare channel number. */ typedef enum _gpt_output_compare_channel { kGPT_OutputCompare_Channel1 = 0U, /*!< Output Compare Channel1.*/ kGPT_OutputCompare_Channel2 = 1U, /*!< Output Compare Channel2.*/ kGPT_OutputCompare_Channel3 = 2U, /*!< Output Compare Channel3.*/ } gpt_output_compare_channel_t; /*! @brief List of output compare operation mode. */ typedef enum _gpt_output_operation_mode { kGPT_OutputOperation_Disconnected = 0U, /*!< Don't change output pin.*/ kGPT_OutputOperation_Toggle = 1U, /*!< Toggle output pin.*/ kGPT_OutputOperation_Clear = 2U, /*!< Set output pin low.*/ kGPT_OutputOperation_Set = 3U, /*!< Set output pin high.*/ kGPT_OutputOperation_Activelow = 4U, /*!< Generate a active low pulse on output pin.*/ } gpt_output_operation_mode_t; /*! @brief List of GPT interrupts */ typedef enum _gpt_interrupt_enable { kGPT_OutputCompare1InterruptEnable = GPT_IR_OF1IE_MASK, /*!< Output Compare Channel1 interrupt enable*/ kGPT_OutputCompare2InterruptEnable = GPT_IR_OF2IE_MASK, /*!< Output Compare Channel2 interrupt enable*/ kGPT_OutputCompare3InterruptEnable = GPT_IR_OF3IE_MASK, /*!< Output Compare Channel3 interrupt enable*/ kGPT_InputCapture1InterruptEnable = GPT_IR_IF1IE_MASK, /*!< Input Capture Channel1 interrupt enable*/ kGPT_InputCapture2InterruptEnable = GPT_IR_IF2IE_MASK, /*!< Input Capture Channel1 interrupt enable*/ kGPT_RollOverFlagInterruptEnable = GPT_IR_ROVIE_MASK, /*!< Counter rolled over interrupt enable*/ } gpt_interrupt_enable_t; /*! @brief Status flag. */ typedef enum _gpt_status_flag { kGPT_OutputCompare1Flag = GPT_SR_OF1_MASK, /*!< Output compare channel 1 event.*/ kGPT_OutputCompare2Flag = GPT_SR_OF2_MASK, /*!< Output compare channel 2 event.*/ kGPT_OutputCompare3Flag = GPT_SR_OF3_MASK, /*!< Output compare channel 3 event.*/ kGPT_InputCapture1Flag = GPT_SR_IF1_MASK, /*!< Input Capture channel 1 event.*/ kGPT_InputCapture2Flag = GPT_SR_IF2_MASK, /*!< Input Capture channel 2 event.*/ kGPT_RollOverFlag = GPT_SR_ROV_MASK, /*!< Counter reaches maximum value and rolled over to 0 event.*/ } gpt_status_flag_t; /*! @brief Structure to configure the running mode. */ typedef struct _gpt_init_config { gpt_clock_source_t clockSource; /*!< clock source for GPT module. */ uint32_t divider; /*!< clock divider (prescaler+1) from clock source to counter. */ bool enableFreeRun; /*!< true: FreeRun mode, false: Restart mode. */ bool enableRunInWait; /*!< GPT enabled in wait mode. */ bool enableRunInStop; /*!< GPT enabled in stop mode. */ bool enableRunInDoze; /*!< GPT enabled in doze mode. */ bool enableRunInDbg; /*!< GPT enabled in debug mode. */ bool enableMode; /*!< true: counter reset to 0 when enabled; false: counter retain its value when enabled. */ } gpt_config_t; /******************************************************************************* * API ******************************************************************************/ #if defined(__cplusplus) extern "C" { #endif /*! * @name Initialization and deinitialization * @{ */ /*! * @brief Initialize GPT to reset state and initialize running mode. * * @param base GPT peripheral base address. * @param initConfig GPT mode setting configuration. */ void GPT_Init(GPT_Type *base, const gpt_config_t *initConfig); /*! * @brief Disables the module and gates the GPT clock. * * @param base GPT peripheral base address. */ void GPT_Deinit(GPT_Type *base); /*! * @brief Fills in the GPT configuration structure with default settings. * * The default values are: * @code * config->clockSource = kGPT_ClockSource_Periph; * config->divider = 1U; * config->enableRunInStop = true; * config->enableRunInWait = true; * config->enableRunInDoze = false; * config->enableRunInDbg = false; * config->enableFreeRun = false; * config->enableMode = true; * @endcode * @param config Pointer to the user configuration structure. */ void GPT_GetDefaultConfig(gpt_config_t *config); /*! * @name Software Reset * @{ */ /*! * @brief Software reset of GPT module. * * @param base GPT peripheral base address. */ static inline void GPT_SoftwareReset(GPT_Type *base) { base->CR |= GPT_CR_SWR_MASK; /* Wait reset finished. */ while ((base->CR & GPT_CR_SWR_MASK) == GPT_CR_SWR_MASK) { } } /*! * @name Clock source and frequency control * @{ */ /*! * @brief Set clock source of GPT. * * @param base GPT peripheral base address. * @param gptClkSource Clock source (see @ref gpt_clock_source_t typedef enumeration). */ static inline void GPT_SetClockSource(GPT_Type *base, gpt_clock_source_t gptClkSource) { if (gptClkSource == kGPT_ClockSource_Osc) { base->CR = (base->CR & ~GPT_CR_CLKSRC_MASK) | GPT_CR_EN_24M_MASK | GPT_CR_CLKSRC(gptClkSource); } else { base->CR = (base->CR & ~(GPT_CR_CLKSRC_MASK | GPT_CR_EN_24M_MASK)) | GPT_CR_CLKSRC(gptClkSource); } } /*! * @brief Get clock source of GPT. * * @param base GPT peripheral base address. * @return clock source (see @ref gpt_clock_source_t typedef enumeration). */ static inline gpt_clock_source_t GPT_GetClockSource(GPT_Type *base) { return (gpt_clock_source_t)(uint8_t)((base->CR & GPT_CR_CLKSRC_MASK) >> GPT_CR_CLKSRC_SHIFT); } /*! * @brief Set pre scaler of GPT. * * @param base GPT peripheral base address. * @param divider Divider of GPT (1-4096). */ static inline void GPT_SetClockDivider(GPT_Type *base, uint32_t divider) { assert(divider - 1U <= GPT_PR_PRESCALER_MASK); base->PR = (base->PR & ~GPT_PR_PRESCALER_MASK) | GPT_PR_PRESCALER(divider - 1U); } /*! * @brief Get clock divider in GPT module. * * @param base GPT peripheral base address. * @return clock divider in GPT module (1-4096). */ static inline uint32_t GPT_GetClockDivider(GPT_Type *base) { return ((base->PR & GPT_PR_PRESCALER_MASK) >> GPT_PR_PRESCALER_SHIFT) + 1U; } /*! * @brief OSC 24M pre-scaler before selected by clock source. * * @param base GPT peripheral base address. * @param divider OSC Divider(1-16). */ static inline void GPT_SetOscClockDivider(GPT_Type *base, uint32_t divider) { assert(divider - 1U <= (GPT_PR_PRESCALER24M_MASK >> GPT_PR_PRESCALER24M_SHIFT)); base->PR = (base->PR & ~GPT_PR_PRESCALER24M_MASK) | GPT_PR_PRESCALER24M(divider - 1U); } /*! * @brief Get OSC 24M clock divider in GPT module. * * @param base GPT peripheral base address. * @return OSC clock divider in GPT module (1-16). */ static inline uint32_t GPT_GetOscClockDivider(GPT_Type *base) { return ((base->PR & GPT_PR_PRESCALER24M_MASK) >> GPT_PR_PRESCALER24M_SHIFT) + 1U; } /*! @}*/ /*! * @name Timer Start and Stop * @{ */ /*! * @brief Start GPT timer. * * @param base GPT peripheral base address. */ static inline void GPT_StartTimer(GPT_Type *base) { base->CR |= GPT_CR_EN_MASK; } /*! * @brief Stop GPT timer. * * @param base GPT peripheral base address. */ static inline void GPT_StopTimer(GPT_Type *base) { base->CR &= ~GPT_CR_EN_MASK; } /*! * @name Read the timer period * @{ */ /*! * @brief Reads the current GPT counting value. * * @param base GPT peripheral base address. * @return Current GPT counter value. */ static inline uint32_t GPT_GetCurrentTimerCount(GPT_Type *base) { return base->CNT; } /*@}*/ /*! * @name GPT Input/Output Signal Control * @{ */ /*! * @brief Set GPT operation mode of input capture channel. * * @param base GPT peripheral base address. * @param channel GPT capture channel (see @ref gpt_input_capture_channel_t typedef enumeration). * @param mode GPT input capture operation mode (see @ref gpt_input_operation_mode_t typedef enumeration). */ static inline void GPT_SetInputOperationMode(GPT_Type *base, gpt_input_capture_channel_t channel, gpt_input_operation_mode_t mode) { assert(channel <= kGPT_InputCapture_Channel2); base->CR = (base->CR & ~(GPT_CR_IM1_MASK << ((uint32_t)channel * 2UL))) | (GPT_CR_IM1(mode) << ((uint32_t)channel * 2UL)); } /*! * @brief Get GPT operation mode of input capture channel. * * @param base GPT peripheral base address. * @param channel GPT capture channel (see @ref gpt_input_capture_channel_t typedef enumeration). * @return GPT input capture operation mode (see @ref gpt_input_operation_mode_t typedef enumeration). */ static inline gpt_input_operation_mode_t GPT_GetInputOperationMode(GPT_Type *base, gpt_input_capture_channel_t channel) { assert(channel <= kGPT_InputCapture_Channel2); return (gpt_input_operation_mode_t)(uint8_t)((base->CR >> (GPT_CR_IM1_SHIFT + (uint32_t)channel * 2UL)) & (GPT_CR_IM1_MASK >> GPT_CR_IM1_SHIFT)); } /*! * @brief Get GPT input capture value of certain channel. * * @param base GPT peripheral base address. * @param channel GPT capture channel (see @ref gpt_input_capture_channel_t typedef enumeration). * @return GPT input capture value. */ static inline uint32_t GPT_GetInputCaptureValue(GPT_Type *base, gpt_input_capture_channel_t channel) { assert(channel <= kGPT_InputCapture_Channel2); return base->ICR[(uint32_t)channel]; } /*! * @brief Set GPT operation mode of output compare channel. * * @param base GPT peripheral base address. * @param channel GPT output compare channel (see @ref gpt_output_compare_channel_t typedef enumeration). * @param mode GPT output operation mode (see @ref gpt_output_operation_mode_t typedef enumeration). */ static inline void GPT_SetOutputOperationMode(GPT_Type *base, gpt_output_compare_channel_t channel, gpt_output_operation_mode_t mode) { assert(channel <= kGPT_OutputCompare_Channel3); base->CR = (base->CR & ~(GPT_CR_OM1_MASK << ((uint32_t)channel * 3UL))) | (GPT_CR_OM1(mode) << ((uint32_t)channel * 3UL)); } /*! * @brief Get GPT operation mode of output compare channel. * * @param base GPT peripheral base address. * @param channel GPT output compare channel (see @ref gpt_output_compare_channel_t typedef enumeration). * @return GPT output operation mode (see @ref gpt_output_operation_mode_t typedef enumeration). */ static inline gpt_output_operation_mode_t GPT_GetOutputOperationMode(GPT_Type *base, gpt_output_compare_channel_t channel) { assert(channel <= kGPT_OutputCompare_Channel3); return (gpt_output_operation_mode_t)(uint8_t)((base->CR >> (GPT_CR_OM1_SHIFT + (uint32_t)channel * 3UL)) & (GPT_CR_OM1_MASK >> GPT_CR_OM1_SHIFT)); } /*! * @brief Set GPT output compare value of output compare channel. * * @param base GPT peripheral base address. * @param channel GPT output compare channel (see @ref gpt_output_compare_channel_t typedef enumeration). * @param value GPT output compare value. */ static inline void GPT_SetOutputCompareValue(GPT_Type *base, gpt_output_compare_channel_t channel, uint32_t value) { assert(channel <= kGPT_OutputCompare_Channel3); base->OCR[(uint32_t)channel] = value; } /*! * @brief Get GPT output compare value of output compare channel. * * @param base GPT peripheral base address. * @param channel GPT output compare channel (see @ref gpt_output_compare_channel_t typedef enumeration). * @return GPT output compare value. */ static inline uint32_t GPT_GetOutputCompareValue(GPT_Type *base, gpt_output_compare_channel_t channel) { assert(channel <= kGPT_OutputCompare_Channel3); return base->OCR[(uint32_t)channel]; } /*! * @brief Force GPT output action on output compare channel, ignoring comparator. * * @param base GPT peripheral base address. * @param channel GPT output compare channel (see @ref gpt_output_compare_channel_t typedef enumeration). */ static inline void GPT_ForceOutput(GPT_Type *base, gpt_output_compare_channel_t channel) { assert(channel <= kGPT_OutputCompare_Channel3); base->CR |= (GPT_CR_FO1_MASK << (uint32_t)channel); } /*@}*/ /*! * @name GPT Interrupt and Status Interface * @{ */ /*! * @brief Enables the selected GPT interrupts. * * @param base GPT peripheral base address. * @param mask The interrupts to enable. This is a logical OR of members of the * enumeration ::gpt_interrupt_enable_t */ static inline void GPT_EnableInterrupts(GPT_Type *base, uint32_t mask) { base->IR |= mask; } /*! * @brief Disables the selected GPT interrupts. * * @param base GPT peripheral base address * @param mask The interrupts to disable. This is a logical OR of members of the * enumeration ::gpt_interrupt_enable_t */ static inline void GPT_DisableInterrupts(GPT_Type *base, uint32_t mask) { base->IR &= ~mask; } /*! * @brief Gets the enabled GPT interrupts. * * @param base GPT peripheral base address * * @return The enabled interrupts. This is the logical OR of members of the * enumeration ::gpt_interrupt_enable_t */ static inline uint32_t GPT_GetEnabledInterrupts(GPT_Type *base) { return (base->IR & (GPT_IR_OF1IE_MASK | GPT_IR_OF2IE_MASK | GPT_IR_OF3IE_MASK | GPT_IR_IF1IE_MASK | GPT_IR_IF2IE_MASK | GPT_IR_ROVIE_MASK)); } /*! * @name Status Interface * @{ */ /*! * @brief Get GPT status flags. * * @param base GPT peripheral base address. * @param flags GPT status flag mask (see @ref gpt_status_flag_t for bit definition). * @return GPT status, each bit represents one status flag. */ static inline uint32_t GPT_GetStatusFlags(GPT_Type *base, gpt_status_flag_t flags) { return base->SR & (uint32_t)flags; } /*! * @brief Clears the GPT status flags. * * @param base GPT peripheral base address. * @param flags GPT status flag mask (see @ref gpt_status_flag_t for bit definition). */ static inline void GPT_ClearStatusFlags(GPT_Type *base, gpt_status_flag_t flags) { base->SR = (uint32_t)flags; } /*@}*/ #if defined(__cplusplus) } #endif /*! @}*/ #endif /* _FSL_GPT_H_ */