/** * @file xmc_scu.h * @date 2016-03-09 * * @cond ********************************************************************************************************************* * XMClib v2.1.24 - XMC Peripheral Driver Library * * Copyright (c) 2015-2019, Infineon Technologies AG * All rights reserved. * * Redistribution and use in source and binary forms, with or without modification,are permitted provided that the * following conditions are met: * * Redistributions of source code must retain the above copyright notice, this list of conditions and the following * disclaimer. * * Redistributions in binary form must reproduce the above copyright notice, this list of conditions and the following * disclaimer in the documentation and/or other materials provided with the distribution. * * Neither the name of the copyright holders nor the names of its contributors may be used to endorse or promote * products derived from this software without specific prior written permission. * * THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS "AS IS" AND ANY EXPRESS OR IMPLIED WARRANTIES, * INCLUDING, BUT NOT LIMITED TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE ARE * DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT HOLDER OR CONTRIBUTORS BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, * SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR * SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, * WHETHER IN CONTRACT, STRICT LIABILITY,OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE * OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE. * * To improve the quality of the software, users are encouraged to share modifications, enhancements or bug fixes with * Infineon Technologies AG dave@infineon.com). ********************************************************************************************************************* * * Change History * -------------- * * 2015-02-20: * - Initial
* * 2015-05-20: * - Documentation improved
* - XMC_ASSERT() hanging issues have fixed for XMC4 devices.
* * 2015-06-20: * - Removed version macros and declaration of GetDriverVersion API * - Removed STATIC_INLINE property for the below APIs and declared as void * XMC_SCU_INTERRUPT_EnableEvent, XMC_SCU_INTERRUPT_DisableEvent, * XMC_SCU_INTERRUPT_TriggerEvent, XMC_SCU_INTERUPT_GetEventStatus, * XMC_SCU_INTERUPT_ClearEventStatus * * 2015-11-30: * - Documentation improved
* * 2016-03-09: * - Optimization of write only registers * * @endcond * */ #ifndef XMC_SCU_H #define XMC_SCU_H /********************************************************************************************************************* * HEADER FILES ********************************************************************************************************************/ #include /** * @addtogroup XMClib XMC Peripheral Library * @{ */ /** * @addtogroup SCU * @brief System Control Unit(SCU) driver for XMC microcontroller family. * * System control unit is the SoC power, reset and a clock manager with additional responsibility of * providing system stability protection and other auxiliary functions.
* SCU provides the following features, * -# Power control \if XMC4 * -# Hibernate control \endif * -# Reset control * -# Clock control * -# Miscellaneous control(boot mode, system interrupts etc.)

* * The SCU driver is divided in to clock control logic, reset control logic, system interrupt control logic \if XMC4 * , hibernate control logic, trap control logic, parity control logic \endif * and miscellaneous control logic.
* * Clock driver features: * -# Allows clock configuration using the structure XMC_SCU_CLOCK_CONFIG_t and API XMC_SCU_CLOCK_Init() \if XMC4 * -# Provides structure XMC_SCU_CLOCK_SYSPLL_CONFIG_t for configuring the system PLL * -# Allows selection of clock source for system PLL, XMC_SCU_CLOCK_GetSystemPllClockSource() * -# Provides APIs for configuring different module clock frequencies XMC_SCU_CLOCK_SetWdtClockDivider(), XMC_SCU_CLOCK_SetUsbClockDivider() * -# Allows selection of clock source for external output, XMC_SCU_CLOCK_SetExternalOutputClockSource() * -# Provides APIs for enabling external high power oscillator and ultra low power oscillator, XMC_SCU_CLOCK_EnableHighPerformanceOscillator(), XMC_SCU_CLOCK_EnableLowPowerOscillator() * -# Provides APIs for getting various clock frequencies XMC_SCU_CLOCK_GetPeripheralClockFrequency(), XMC_SCU_CLOCK_GetCpuClockFrequency(), XMC_SCU_CLOCK_GetSystemClockFrequency()
\endif \if XMC1 * -# Allows selection of peripheral clock frequency, XMC_SCU_CLOCK_SetFastPeripheralClockSource() * -# Provides API to get the peripheral clock frequency, XMC_SCU_CLOCK_GetFastPeripheralClockFrequency() \endif * * Reset driver features: \if XMC4 * -# Allows to handle peripheral reset XMC_SCU_RESET_AssertPeripheralReset(), XMC_SCU_RESET_DeassertPeripheralReset() * -# Allows configuration of NMI generation for selected events, XMC_SCU_INTERRUPT_EnableNmiRequest() \endif \if XMC1 * -# Allows to trigger device reset XMC_SCU_RESET_AssertMasterReset() * -# Allows to configure multiple sources for reset, XMC_SCU_RESET_EnableResetRequest() \endif
* * Interrupt driver features: * -# Provides APIs for enabling/ disabling interrupt event generation XMC_SCU_INTERRUPT_EnableEvent(), XMC_SCU_INTERRUPT_DisableEvent() * -# Provides API for registering callback function for events XMC_SCU_INTERRUPT_SetEventHandler()
* \if XMC4 * Hibernate driver features: * -# Allows configuration of hibernate domain XMC_SCU_HIB_EnableHibernateDomain(), XMC_SCU_HIB_DisableHibernateDomain() * -# Allows selection of standby clock source, XMC_SCU_HIB_SetStandbyClockSource() * -# Allows selection of RTC clock source, XMC_SCU_HIB_SetRtcClockSource() * -# Provides API for enabling slow internal clock used for backup clock, XMC_SCU_HIB_EnableInternalSlowClock()
* * Trap driver features: * -# Allows handling of trap XMC_SCU_TRAP_Enable(), XMC_SCU_TRAP_GetStatus(), XMC_SCU_TRAP_Trigger()
* * Parity driver features: * -# Parity error generated by on-chip RAM can be monitored, XMC_SCU_PARITY_Enable(), XMC_SCU_PARITY_GetStatus() * -# Allows configuration of trap generation on detection of parity error, XMC_SCU_PARITY_EnableTrapGeneration() * * Power driver features: * -# Allows to power the USB module XMC_SCU_POWER_EnableUsb(), XMC_SCU_POWER_DisableUsb() \endif * * Miscellaneous features: * -# Allows to trigger multiple capture compare unit(CCU) channels to be started together XMC_SCU_SetCcuTriggerHigh() \if XMC4 * -# Enables configuration of out of range comparator (ORC) XMC_SCU_EnableOutOfRangeComparator() * -# Enables configuration of die temperature sensor XMC_SCU_EnableTemperatureSensor(), XMC_SCU_CalibrateTemperatureSensor() * -# Enables configuration of device boot mode XMC_SCU_SetBootMode()
\endif \if XMC1 * -# Enables configuration of die temperature sensor XMC_SCU_StartTempMeasurement(), XMC_SCU_SetRawTempLimits() * -# Allows configuring supply monitor unit using the structure XMC_SCU_SUPPLYMONITOR_t and API XMC_SCU_SupplyMonitorInit() * -# Allows handling of protected bits XMC_SCU_LockProtectedBits(), XMC_SCU_UnlockProtectedBits()
\endif * @{ */ /********************************************************************************************************************* * MACROS ********************************************************************************************************************/ /********************************************************************************************************************* * ENUMS ********************************************************************************************************************/ /** * Defines the status of SCU API execution, used to verify the SCU related API calls. */ typedef enum XMC_SCU_STATUS { XMC_SCU_STATUS_OK = 0UL, /**< SCU related operation successfully completed.*/ XMC_SCU_STATUS_ERROR, /**< SCU related operation failed. When API cannot fulfill request, this value is returned. */ XMC_SCU_STATUS_BUSY, /**< Cannot execute the SCU related operation request because another operation is in progress. \a XMC_SCU_STATUS_BUSY is returned when API is busy processing another request. */ } XMC_SCU_STATUS_t; /********************************************************************************************************************* * DATA TYPES ********************************************************************************************************************/ /** * Function pointer type used for registering callback functions on SCU event occurrence. */ typedef void (*XMC_SCU_INTERRUPT_EVENT_HANDLER_t)(void); /********************************************************************************************************************* * DEVICE EXTENSIONS ********************************************************************************************************************/ #if (UC_FAMILY == XMC1) #include #elif (UC_FAMILY == XMC4) #include #else #error "Unspecified chipset" #endif /********************************************************************************************************************* * API Prototypes ********************************************************************************************************************/ #ifdef __cplusplus extern "C" { #endif /** * * @param trigger CCU slices to be triggered synchronously via software. The value is a bitmask of CCU slice bits * in the register CCUCON.
* \b Range: Use type @ref XMC_SCU_CCU_TRIGGER_t for bitmask of individual CCU slices. Multiple slices can be * combined using \a OR operation. * * @return None * * \parDescription
* Generates active edge(low to high) trigger for multiple CCU units at the same time.\n\n * Before executing this API, all the required CCU timers should configure external start. * The edge of the start signal should be selected as active edge. * The input signal for the CCU slice should be selected as SCU input. * The above mentioned configurations can be made using the CCU LLD API XMC_CCU4_SLICE_StartConfig(). * CCU timer slice should be started using XMC_CCU4_SLICE_StartTimer() before triggering * the timer using this API.
* \parRelated APIs:
* XMC_CCU4_SLICE_StartConfig(), XMC_CCU4_SLICE_SetInput(), XMC_SCU_SetCcuTriggerLow()\n\n\n */ __STATIC_INLINE void XMC_SCU_SetCcuTriggerHigh(const uint32_t trigger) { SCU_GENERAL->CCUCON |= (uint32_t)trigger; } /** * * @param trigger CCU slices to be triggered synchronously via software. The value is a bitmask of CCU slice bits * in the register CCUCON.
* \b Range: Use type @ref XMC_SCU_CCU_TRIGGER_t for bitmask of individual CCU slices. Multiple slices can be * combined using \a OR operation. * * @return None * * \parDescription
* Generates passive edge(high to low) trigger for multiple CCU units at the same time.\n\n * Before executing this API, all the required CCU timers should configure external start. * The edge of the start signal should be selected as passive edge. * The input signal for the CCU slice should be selected as SCU input. * The above mentioned configurations can be made using the CCU LLD API XMC_CCU4_SLICE_StartConfig(). * CCU timer slice should be started using XMC_CCU4_SLICE_StartTimer() before triggering * the timer using this API.
* \parRelated APIs:
* XMC_CCU4_SLICE_StartConfig(), XMC_CCU4_SLICE_SetInput(), XMC_SCU_SetCcuTriggerHigh()\n\n\n */ __STATIC_INLINE void XMC_SCU_SetCcuTriggerLow(const uint32_t trigger) { SCU_GENERAL->CCUCON &= (uint32_t)~trigger; } /** * * @param config Pointer to structure holding the clock prescaler values and divider values for * configuring clock generators and clock tree.\n * \b Range: Configure the members of structure @ref XMC_SCU_CLOCK_CONFIG_t for various * parameters of clock setup. * * @return None * * \parDescription
* Initializes clock generators and clock tree.\n\n * \if XMC1 * Peripheral clock and system clock are configured based on the input configuration \a config. * The system clock frequency is tuned by configuring the FDIV and IDIV values of CLKCR register. * The values of FDIV and IDIV can be provided as part of input configuration. * The PCLK divider determines the ratio of peripheral clock to the system clock. * The source of RTC clock is set based on the input configuration. * \a SystemCoreClock variable will be updated with the value of * system clock frequency. Access to protected bit fields are handled internally. * \endif * \if XMC4 * Enables the high precision oscillator(fOHP) input and configures the system and peripheral clock frequencies. * Based on the system clock source selected in \a config, either fPLL or fOFI will be chosen as system clock. * Based on PLL mode(normal or prescaler mode) used, PLL ramps up in steps to achieve target frequency. * The clock dividers for CPU, CCU and peripheral clocks will be set based on the input configuration. * The \a SystemCoreClock variable is set with the value of system clock frequency. * \endif * \parRelated APIs:
* XMC_SCU_CLOCK_GetPeripheralClockFrequency(), XMC_SCU_CLOCK_GetCpuClockFrequency() \n\n\n */ void XMC_SCU_CLOCK_Init(const XMC_SCU_CLOCK_CONFIG_t *const config); /** * * @param event Bit mask of the event to enable. \b Range: Use type @ref XMC_SCU_INTERRUPT_EVENT_t * for providing the input value. Multiple events can be combined using the \a OR operation. * * @return None * * \parDescription
* Enables the generation of interrupt for the input events.\n\n * The events are enabled by setting the respective bit fields in the SRMSK register. \n * Note: User should separately enable the NVIC node responsible for handling the SCU interrupt. * The interrupt will be generated when the respective event occurs. * \parRelated APIs:
* NVIC_EnableIRQ(), XMC_SCU_INTERRUPT_DisableEvent()\n\n\n */ void XMC_SCU_INTERRUPT_EnableEvent(const XMC_SCU_INTERRUPT_EVENT_t event); /** * * @param event Bit mask of the event to disable. \b Range: Use type @ref XMC_SCU_INTERRUPT_EVENT_t * for providing the input value. Multiple events can be combined using the \a OR operation. * * @return None * * \parDescription
* Disables generation of interrupt on occurrence of the input event.\n\n * The events are disabled by resetting the respective bit fields in the SRMSK register. \n * \parRelated APIs:
* NVIC_DisableIRQ(), XMC_SCU_INTERRUPT_EnableEvent()\n\n\n */ void XMC_SCU_INTERRUPT_DisableEvent(const XMC_SCU_INTERRUPT_EVENT_t event); /** * * @param event Bit mask of the event to be triggered. \b Range: Use type @ref XMC_SCU_INTERRUPT_EVENT_t * for providing the input value. Multiple events can be combined using the \a OR operation. * * @return None * * \parDescription
* Triggers the event as if the hardware raised it.\n\n * Event will be triggered by setting the respective bitfield in the SRSET register.\n * Note: User should enable the NVIC node that handles the respective event for interrupt generation. * \parRelated APIs:
* NVIC_EnableIRQ(), XMC_SCU_INTERUPT_GetEventStatus(), XMC_SCU_INTERRUPT_ClearEventStatus() \n\n\n */ void XMC_SCU_INTERRUPT_TriggerEvent(const XMC_SCU_INTERRUPT_EVENT_t event); /** * @return uint32_t Status of the SCU events. * * \parDescription
* Provides the status of all SCU events.\n\n * The status is read from the SRRAW register. To check the status of a particular * event, the returned value should be masked with the bit mask of the event. The bitmask * of events can be obtained using the type @ref XMC_SCU_INTERRUPT_EVENT_t. Multiple events' * status can be checked by combining the bit masks using \a OR operation. * After detecting the event, the event status should be cleared using software to detect the event again. * \parRelated APIs:
* XMC_SCU_INTERRUPT_ClearEventStatus(), XMC_SCU_INTERRUPT_TriggerEvent(), XMC_SCU_INTERRUPT_SetEventHandler() \n\n\n */ XMC_SCU_INTERRUPT_EVENT_t XMC_SCU_INTERUPT_GetEventStatus(void); /** * * @param event Bit mask of the events to clear. \b Range: Use type @ref XMC_SCU_INTERRUPT_EVENT_t * for providing the input value. Multiple events can be combined using the \a OR operation. * * @return None * * \parDescription
* Clears the event status bit in SRRAW register.\n\n * The events are cleared by writing value 1 to their bit positions in the SRCLR register. * The API can be used when polling method is used. After detecting the event, the event status * should be cleared using software to detect the event again. * * \parRelated APIs:
* XMC_SCU_INTERUPT_GetEventStatus(), XMC_SCU_INTERRUPT_TriggerEvent() \n\n\n */ void XMC_SCU_INTERRUPT_ClearEventStatus(const XMC_SCU_INTERRUPT_EVENT_t event); /** * * @return uint32_t Status representing the reason for device reset. * * \parDescription
* Provides the value representing the reason for device reset.\n\n * The return value is an encoded word, which can indicate multiple reasons for the last reset. Each bit position of the * returned word is representative of a last reset cause. The returned value should be appropriately masked to check * the cause of reset. * The cause of the last reset gets automatically stored in * the \a SCU_RSTSTAT register. The reset status shall be reset after each * startup in order to ensure consistent source indication after the next reset. * \b Range: The type @ref XMC_SCU_RESET_REASON_t can be used to get the bit masks of the reset cause. * * \parRelated APIs:
* XMC_SCU_RESET_ClearDeviceResetReason() \n\n\n */ __STATIC_INLINE uint32_t XMC_SCU_RESET_GetDeviceResetReason(void) { return ((SCU_RESET->RSTSTAT) & SCU_RESET_RSTSTAT_RSTSTAT_Msk); } /** * @return None * * \parDescription
* Clears the reset reason bits in the reset status register. \n\n * Clearing of the reset status information in the \a SCU_RSTSTAT register via register bit \a RSTCLR.RSCLR is strongly * recommended to ensure a clear indication of the cause of next reset. * * \parRelated APIs:
* XMC_SCU_RESET_GetDeviceResetReason() \n\n\n */ __STATIC_INLINE void XMC_SCU_RESET_ClearDeviceResetReason(void) { /* Clear RSTSTAT.RSTSTAT bitfield */ SCU_RESET->RSTCLR = (uint32_t)SCU_RESET_RSTCLR_RSCLR_Msk; } /** * @return uint32_t Value of CPU clock frequency. * * \parDescription
* Provides the vlaue of CPU clock frequency.\n\n * The value is stored in a global variable \a \b SystemCoreClock. * It is updated when the clock configuration is done using the SCU LLD APIs. * The value represents the frequency of clock used for CPU operation. * \b Range: Value is of type uint32_t, and gives the value of frequency in Hertz. * * \parRelated APIs:
* XMC_SCU_CLOCK_GetPeripheralClockFrequency(), XMC_SCU_CLOCK_GatePeripheralClock() \n\n\n */ __STATIC_INLINE uint32_t XMC_SCU_CLOCK_GetCpuClockFrequency(void) { return SystemCoreClock; } /** * @return uint32_t Value of peripheral clock frequency in Hertz. * * \parDescription
* Provides the vlaue of clock frequency at which the peripherals are working.\n\n * The value is derived from the CPU frequency. \b Range: Value is of type uint32_t. It is represented in Hertz. * \parRelated APIs:
* XMC_SCU_CLOCK_GetCpuClockFrequency(),XMC_SCU_CLOCK_GatePeripheralClock() \n\n\n */ uint32_t XMC_SCU_CLOCK_GetPeripheralClockFrequency(void); #if(UC_SERIES != XMC45) /** * * @param peripheral The peripheral for which the clock has to be gated. \b Range: Use type @ref XMC_SCU_PERIPHERAL_CLOCK_t * to identify the peripheral clock to be gated. * * @return None * * \parDescription
* Blocks the supply of clock to the selected peripheral.\n\n * Clock gating helps in reducing the power consumption. User can selectively gate the clocks of unused peripherals. * \if XMC1 * fPCLK is the source of clock to various peripherals. Some peripherals support clock gate. Such a gate blocks * the clock supply for the selected peripheral. * Software can request for individual gating of such peripheral clocks by enabling the \a SCU_CGATSET0 * register bit field. Every bit in \a SCU_CGATSET0 register is protected by the bit protection scheme. Access to protected * bit fields are handled internally. * \endif * \if XMC4 * fPERI is the source of clock to various peripherals. Some peripherals support clock gate. Such a gate blocks * the clock supply for the selected peripheral. * Software can request for individual gating of such peripheral clocks by enabling one of the \a * SCU_CGATSET0, \a SCU_CGATSET1 or \a SCU_CGATSET2 register bitfields. * * \endif * Note: Clock gating shall not be activated unless the module is in reset state. So use \a * XMC_SCU_CLOCK_IsPeripheralClockGated() API before enabling the gating of any peripheral. * \parRelated APIs:
* XMC_SCU_CLOCK_IsPeripheralClockGated(), XMC_SCU_CLOCK_UngatePeripheralClock() \n\n\n */ void XMC_SCU_CLOCK_GatePeripheralClock(const XMC_SCU_PERIPHERAL_CLOCK_t peripheral); /** * * @param peripheral The peripheral for which the clock has to be ungated. \b Range: Use type @ref XMC_SCU_PERIPHERAL_CLOCK_t * to identify the peripheral. * * @return None * * \parDescription
* Enables the supply of clock to the selected peripheral.\n\n * By default when the device powers on, the peripheral clock will be gated for the * peripherals that support clock gating. * The peripheral clock should be enabled before using it for any functionality. * \if XMC1 * fPCLK is the source of clock to various peripherals. Some peripherals support clock gate. * Software can request for individual ungating of such peripheral clocks by setting respective bits * in the \a SCU_CGATCLR0 register. * \endif * \if XMC4 * fPERI is the source of clock to various peripherals. Some peripherals support clock gate. * Software can request for individual ungating of such peripheral clocks by setting the respective bits in one of \a * SCU_CGATCLR0, \a SCU_CGATCLR1 or \a SCU_CGATCLR2 registers. * \endif * * \parRelated APIs:
* XMC_SCU_CLOCK_IsPeripheralClockGated(), XMC_SCU_CLOCK_GatePeripheralClock() \n\n\n */ void XMC_SCU_CLOCK_UngatePeripheralClock(const XMC_SCU_PERIPHERAL_CLOCK_t peripheral); /** * * @param peripheral The peripheral for which the check for clock gating has to be done. * \b Range: Use type @ref XMC_SCU_PERIPHERAL_CLOCK_t to identify the peripheral. * * @return bool Status of the peripheral clock gating. \b Range: true if the peripheral clock is gated. * false if the peripheral clock ungated(gate de-asserted). * * \parDescription
* Gives the status of peripheral clock gating.\n\n * \if XMC1 * Checks the status of peripheral clock gating using the register CGATSTAT0. * \endif * \if XMC4 * Checks the status of peripheral clock gating using one of CGATSTAT0, CGATSTAT1 or CGATSTAT2 registers. * \endif * It is recommended to use this API before * enabling the gating of any peripherals through \a XMC_SCU_CLOCK_GatePeripheralClock() API. * * \parRelated APIs:
* XMC_SCU_CLOCK_UngatePeripheralClock(), XMC_SCU_CLOCK_GatePeripheralClock() \n\n\n */ bool XMC_SCU_CLOCK_IsPeripheralClockGated(const XMC_SCU_PERIPHERAL_CLOCK_t peripheral); #endif /** * @return uint32_t Status of the register mirror update.\n * \b Range: Use the bit mask of the SCU_GENERAL_MIRRSTS register for the mirror update event of * interest. e.g.: SCU_GENERAL_MIRRSTS_RTC_CTR_Msk. Multiple update events can be combined * using \a OR operation. * * \parDescription
* Provides the status of hibernate domain register update, when the respective mirror registers are changed. \n\n * The hibernate domain is connected to the core domain via SPI serial communication. MIRRSTS is a status register * representing the communication of changed value of a mirror register to its corresponding register in the * hibernate domain. The bit fields of the register indicate * that a corresponding register of the hibernate domain is ready to accept a write or that the communication interface * is busy with executing the previous operation.\n * Note: There is no hibernate domain in XMC1x devices. This register is retained for legacy purpose. */ __STATIC_INLINE uint32_t XMC_SCU_GetMirrorStatus(void) { return(SCU_GENERAL->MIRRSTS); } /** * @param event The event for which the interrupt handler is to be configured. \n * \b Range: Use type @ref XMC_SCU_INTERRUPT_EVENT_t for identifying the event. * @param handler Name of the function to be executed when the event if detected. \n * \b Range: The function accepts no arguments and returns no value. * @return XMC_SCU_STATUS_t Status of configuring the event handler function for the selected event.\n * \b Range: \a XMC_SCU_STATUS_OK if the event handler is successfully configured.\n * \a XMC_SCU_STATUS_ERROR if the input event is invalid.\n * \parDescription
* Assigns the event handler function to be executed on occurrence of the selected event.\n\n * If the input event is valid, the handler function will be assigned to a table to be executed * when the interrupt is generated and the event status is set in the event status register. By using this API, * polling for a particular event can be avoided. This way the CPU utilization will be optimized. Multiple SCU events * can generate a common interrupt. When the interrupt is generated, a common interrupt service routine is executed. * It checks for status flags of events which can generate the interrupt. The handler function will be executed if the * event flag is set. * * \parRelated APIs:
* XMC_SCU_INTERRUPT_TriggerEvent(), XMC_SCU_INTERUPT_GetEventStatus() \n\n\n */ XMC_SCU_STATUS_t XMC_SCU_INTERRUPT_SetEventHandler(const XMC_SCU_INTERRUPT_EVENT_t event, const XMC_SCU_INTERRUPT_EVENT_HANDLER_t handler); /** * @param sr_num Service request number identifying the SCU interrupt generated.\n * \b Range: 0 to 2. XMC4x devices have one common SCU interrupt, so the value should be 0.\n * But XMC1x devices support 3 interrupt nodes. * @return None * \parDescription
* A common function to execute callback functions for multiple events.\n\n * It checks for the status of events which can generate the interrupt with the selected service request. * If the event is set, the corresponding callback function will be executed. It also clears the event status bit.\n * \b Note: This is an internal function. It should not be called by the user application. * * \parRelated APIs:
* XMC_SCU_INTERRUPT_SetEventHandler() \n\n\n */ void XMC_SCU_IRQHandler(uint32_t sr_num); #ifdef __cplusplus } #endif /** * @} */ /** * @} */ #endif /* SCU_H */