FreeRTOS/Demo/CORTEX_A53_64-bit_UltraScale_MPSoC/RTOSDemo_A53_bsp/psu_cortexa53_0/libsrc/scugic_v3_9/src/xscugic_hw.c - third_party/github/FreeRTOS/FreeRTOS-Kernel - Git at Google

 /******************************************************************************
 *
 * Copyright (C) 2010 - 2015 Xilinx, Inc.  All rights reserved.
 *
 * Permission is hereby granted, free of charge, to any person obtaining a copy
 * of this software and associated documentation files (the "Software"), to deal
 * in the Software without restriction, including without limitation the rights
 * to use, copy, modify, merge, publish, distribute, sublicense, and/or sell
 * copies of the Software, and to permit persons to whom the Software is
 * furnished to do so, subject to the following conditions:
 *
 * The above copyright notice and this permission notice shall be included in
 * all copies or substantial portions of the Software.
 *
 * Use of the Software is limited solely to applications:
 * (a) running on a Xilinx device, or
 * (b) that interact with a Xilinx device through a bus or interconnect.
 *
 * THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, EXPRESS OR
 * IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF MERCHANTABILITY,
 * FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT. IN NO EVENT SHALL
 * XILINX  BE LIABLE FOR ANY CLAIM, DAMAGES OR OTHER LIABILITY,
 * WHETHER IN AN ACTION OF CONTRACT, TORT OR OTHERWISE, ARISING FROM, OUT OF
 * OR IN CONNECTION WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS IN THE
 * SOFTWARE.
 *
 * Except as contained in this notice, the name of the Xilinx shall not be used
 * in advertising or otherwise to promote the sale, use or other dealings in
 * this Software without prior written authorization from Xilinx.
 *
 ******************************************************************************/
 /*****************************************************************************/
 /**
 *
 * @file xscugic_hw.c
 * @addtogroup scugic_v3_8
 * @{
 *
 * This file contains low-level driver functions that can be used to access the
 * device.  The user should refer to the hardware device specification for more
 * details of the device operation.
 * These routines are used when the user does not want to create an instance of
 * XScuGic structure but still wants to use the ScuGic device. Hence the
 * routines provided here take device id or scugic base address as arguments.
 * Separate static versions of DistInit and CPUInit are provided to implement
 * the low level driver routines.
 *
 * <pre>
 * MODIFICATION HISTORY:
 *
 * Ver   Who  Date     Changes
 * ----- ---- -------- -------------------------------------------------------
 * 1.01a sdm  07/18/11 First release
 * 1.03a srt  02/27/13 Moved Offset calculation macros from *_hw.c (CR
 *		      702687).
 *					  Added support to direct interrupts to the appropriate CPU.
 *			  Earlier interrupts were directed to CPU1 (hard coded). Now
 *			  depending upon the CPU selected by the user (xparameters.h),
 *			  interrupts will be directed to the relevant CPU.
 *			  This fixes CR 699688.
 * 1.04a hk   05/04/13 Fix for CR#705621. Moved functions
 *			  XScuGic_SetPriTrigTypeByDistAddr and
 *             XScuGic_GetPriTrigTypeByDistAddr here from xscugic.c
 * 3.00  kvn  02/13/15 Modified code for MISRA-C:2012 compliance.
 * 3.6   kvn  02/17/17 Add support for changing GIC CPU master at run time.
 *       kvn  02/28/17 Make the CpuId as static variable and Added new
 *                     XScugiC_GetCpuId to access CpuId.
 * 3.9   mus  02/21/18 Added new API's XScuGic_InterruptUnmapFromCpuByDistAddr
 *					  and XScuGic_UnmapAllInterruptsFromCpuByDistAddr, These
 *					  API's can be used by applications to unmap specific/all
 *					  interrupts from target CPU. It fixes CR#992490.
 *
 * </pre>
 *
 ******************************************************************************/


 /***************************** Include Files *********************************/

 #include "xil_types.h"
 #include "xil_assert.h"
 #include "xscugic.h"
 #include "xparameters.h"

 /************************** Constant Definitions *****************************/

 /**************************** Type Definitions *******************************/

 /***************** Macros (Inline Functions) Definitions *********************/

 /************************** Function Prototypes ******************************/

 static void DistInit(XScuGic_Config *Config, u32 CpuID);
 static void CPUInit(XScuGic_Config *Config);
 static XScuGic_Config *LookupConfigByBaseAddress(u32 CpuBaseAddress);

 /************************** Variable Definitions *****************************/

 extern XScuGic_Config XScuGic_ConfigTable[XPAR_XSCUGIC_NUM_INSTANCES];
 extern u32 CpuId;

 /*****************************************************************************/
 /**
 *
 * DistInit initializes the distributor of the GIC. The
 * initialization entails:
 *
 * - Write the trigger mode, priority and target CPU
 * - All interrupt sources are disabled
 * - Enable the distributor
 *
 * @param	InstancePtr is a pointer to the XScuGic instance.
 * @param	CpuID is the Cpu ID to be initialized.
 *
 * @return	None
 *
 * @note		None.
 *
 ******************************************************************************/
 static void DistInit(XScuGic_Config *Config, u32 CpuID)
 {
 	u32 Int_Id;
 	u32 LocalCpuID = CpuID;

 #if USE_AMP==1
 	#warning "Building GIC for AMP"

 	/*
 	 * The distrubutor should not be initialized by FreeRTOS in the case of
 	 * AMP -- it is assumed that Linux is the master of this device in that
 	 * case.
 	 */
 	return;
 #endif

 	XScuGic_WriteReg(Config->DistBaseAddress, XSCUGIC_DIST_EN_OFFSET, 0U);

 	/*
 	 * Set the security domains in the int_security registers for non-secure
 	 * interrupts. All are secure, so leave at the default. Set to 1 for
 	 * non-secure interrupts.
 	 */


 	/*
 	 * For the Shared Peripheral Interrupts INT_ID[MAX..32], set:
 	 */

 	/*
 	 * 1. The trigger mode in the int_config register
 	 * Only write to the SPI interrupts, so start at 32
 	 */
 	for (Int_Id = 32U; Int_Id<XSCUGIC_MAX_NUM_INTR_INPUTS;Int_Id=Int_Id+16U) {
 	/*
 	 * Each INT_ID uses two bits, or 16 INT_ID per register
 	 * Set them all to be level sensitive, active HIGH.
 	 */
 		XScuGic_WriteReg(Config->DistBaseAddress,
 			XSCUGIC_INT_CFG_OFFSET_CALC(Int_Id), 0U);
 	}


 #define DEFAULT_PRIORITY	0xa0a0a0a0U
 	for (Int_Id = 0U; Int_Id<XSCUGIC_MAX_NUM_INTR_INPUTS;Int_Id=Int_Id+4U) {
 		/*
 		 * 2. The priority using int the priority_level register
 		 * The priority_level and spi_target registers use one byte per
 		 * INT_ID.
 		 * Write a default value that can be changed elsewhere.
 		 */
 		XScuGic_WriteReg(Config->DistBaseAddress,
 				XSCUGIC_PRIORITY_OFFSET_CALC(Int_Id),
 				DEFAULT_PRIORITY);
 	}

 	for (Int_Id = 32U; Int_Id<XSCUGIC_MAX_NUM_INTR_INPUTS;Int_Id=Int_Id+4U) {
 		/*
 		 * 3. The CPU interface in the spi_target register
 		 * Only write to the SPI interrupts, so start at 32
 		 */
 		LocalCpuID |= LocalCpuID << 8U;
 		LocalCpuID |= LocalCpuID << 16U;

 		XScuGic_WriteReg(Config->DistBaseAddress,
 				XSCUGIC_SPI_TARGET_OFFSET_CALC(Int_Id), LocalCpuID);
 	}

 	for (Int_Id = 0U; Int_Id<XSCUGIC_MAX_NUM_INTR_INPUTS;Int_Id=Int_Id+32U) {
 	/*
 	 * 4. Enable the SPI using the enable_set register. Leave all disabled
 	 * for now.
 	 */
 		XScuGic_WriteReg(Config->DistBaseAddress,
 		XSCUGIC_EN_DIS_OFFSET_CALC(XSCUGIC_DISABLE_OFFSET,
 		Int_Id),
 		0xFFFFFFFFU);

 	}

 	XScuGic_WriteReg(Config->DistBaseAddress, XSCUGIC_DIST_EN_OFFSET,
 						XSCUGIC_EN_INT_MASK);

 }

 /*****************************************************************************/
 /**
 *
 * CPUInit initializes the CPU Interface of the GIC. The initialization entails:
 *
 * - Set the priority of the CPU.
 * - Enable the CPU interface
 *
 * @param	ConfigPtr is a pointer to a config table for the particular
 *		device this driver is associated with.
 *
 * @return	None
 *
 * @note		None.
 *
 ******************************************************************************/
 static void CPUInit(XScuGic_Config *Config)
 {
 	/*
 	 * Program the priority mask of the CPU using the Priority mask
 	 * register
 	 */
 	XScuGic_WriteReg(Config->CpuBaseAddress, XSCUGIC_CPU_PRIOR_OFFSET,
 									0xF0U);

 	/*
 	 * If the CPU operates in both security domains, set parameters in the
 	 * control_s register.
 	 * 1. Set FIQen=1 to use FIQ for secure interrupts,
 	 * 2. Program the AckCtl bit
 	 * 3. Program the SBPR bit to select the binary pointer behavior
 	 * 4. Set EnableS = 1 to enable secure interrupts
 	 * 5. Set EnbleNS = 1 to enable non secure interrupts
 	 */

 	/*
 	 * If the CPU operates only in the secure domain, setup the
 	 * control_s register.
 	 * 1. Set FIQen=1,
 	 * 2. Set EnableS=1, to enable the CPU interface to signal secure .
 	 * interrupts Only enable the IRQ output unless secure interrupts
 	 * are needed.
 	 */
 	XScuGic_WriteReg(Config->CpuBaseAddress, XSCUGIC_CONTROL_OFFSET, 0x07U);

 }

 /*****************************************************************************/
 /**
 *
 * CfgInitialize a specific interrupt controller instance/driver. The
 * initialization entails:
 *
 * - Initialize fields of the XScuGic structure
 * - Initial vector table with stub function calls
 * - All interrupt sources are disabled
 *
 * @param InstancePtr is a pointer to the XScuGic instance to be worked on.
 * @param ConfigPtr is a pointer to a config table for the particular device
 *        this driver is associated with.
 * @param EffectiveAddr is the device base address in the virtual memory address
 *        space. The caller is responsible for keeping the address mapping
 *        from EffectiveAddr to the device physical base address unchanged
 *        once this function is invoked. Unexpected errors may occur if the
 *        address mapping changes after this function is called. If address
 *        translation is not used, use Config->BaseAddress for this parameters,
 *        passing the physical address instead.
 *
 * @return
 *
 * - XST_SUCCESS if initialization was successful
 *
 * @note
 *
 * None.
 *
 ******************************************************************************/
 s32 XScuGic_DeviceInitialize(u32 DeviceId)
 {
 	XScuGic_Config *Config;
 	u32 Cpu_Id = XScuGic_GetCpuID() + (u32)1;

 	Config = &XScuGic_ConfigTable[(u32 )DeviceId];

 	DistInit(Config, Cpu_Id);

 	CPUInit(Config);

 	return XST_SUCCESS;
 }

 /*****************************************************************************/
 /**
 * This function is the primary interrupt handler for the driver.  It must be
 * connected to the interrupt source such that it is called when an interrupt of
 * the interrupt controller is active. It will resolve which interrupts are
 * active and enabled and call the appropriate interrupt handler. It uses
 * the Interrupt Type information to determine when to acknowledge the
 * interrupt.Highest priority interrupts are serviced first.
 *
 * This function assumes that an interrupt vector table has been previously
 * initialized.  It does not verify that entries in the table are valid before
 * calling an interrupt handler.
 *
 * @param	DeviceId is the unique identifier for the ScuGic device.
 *
 * @return	None.
 *
 * @note		None.
 *
 ******************************************************************************/
 void XScuGic_DeviceInterruptHandler(void *DeviceId)
 {

 	u32 InterruptID;
 	u32 IntIDFull;
 	XScuGic_VectorTableEntry *TablePtr;
 	XScuGic_Config *CfgPtr;

 	CfgPtr = &XScuGic_ConfigTable[(INTPTR )DeviceId];

 	/*
 	 * Read the int_ack register to identify the highest priority
 	 * interrupt ID and make sure it is valid. Reading Int_Ack will
 	 * clear the interrupt in the GIC.
 	 */
 	IntIDFull = XScuGic_ReadReg(CfgPtr->CpuBaseAddress, XSCUGIC_INT_ACK_OFFSET);
 	InterruptID = IntIDFull & XSCUGIC_ACK_INTID_MASK;
 	if(XSCUGIC_MAX_NUM_INTR_INPUTS < InterruptID){
 		goto IntrExit;
 	}

 	/*
 	 * If the interrupt is shared, do some locking here if there are
 	 * multiple processors.
 	 */
 	/*
 	 * If pre-eption is required:
 	 * Re-enable pre-emption by setting the CPSR I bit for non-secure ,
 	 * interrupts or the F bit for secure interrupts
 	 */

 	/*
 	 * If we need to change security domains, issue a SMC instruction here.
 	 */

 	/*
 	 * Execute the ISR. Jump into the Interrupt service routine based on
 	 * the IRQSource. A software trigger is cleared by the ACK.
 	 */
 	TablePtr = &(CfgPtr->HandlerTable[InterruptID]);
 	if(TablePtr != NULL) {
 		TablePtr->Handler(TablePtr->CallBackRef);
 	}

 IntrExit:
 	/*
 	 * Write to the EOI register, we are all done here.
 	 * Let this function return, the boot code will restore the stack.
 	 */
 	XScuGic_WriteReg(CfgPtr->CpuBaseAddress, XSCUGIC_EOI_OFFSET, IntIDFull);

 	/*
 	 * Return from the interrupt. Change security domains could happen
 	 * here.
 	 */
 }

 /*****************************************************************************/
 /**
 *
 * Register a handler function for a specific interrupt ID.  The vector table
 * of the interrupt controller is updated, overwriting any previous handler.
 * The handler function will be called when an interrupt occurs for the given
 * interrupt ID.
 *
 * @param	BaseAddress is the CPU Interface Register base address of the
 *		interrupt controller whose vector table will be modified.
 * @param	InterruptId is the interrupt ID to be associated with the input
 *		handler.
 * @param	Handler is the function pointer that will be added to
 *		the vector table for the given interrupt ID.
 * @param	CallBackRef is the argument that will be passed to the new
 *		handler function when it is called. This is user-specific.
 *
 * @return	None.
 *
 * @note
 *
 * Note that this function has no effect if the input base address is invalid.
 *
 ******************************************************************************/
 void XScuGic_RegisterHandler(u32 BaseAddress, s32 InterruptID,
 			     Xil_InterruptHandler IntrHandler, void *CallBackRef)
 {
 	XScuGic_Config *CfgPtr;
 	CfgPtr = LookupConfigByBaseAddress(BaseAddress);

 	if(CfgPtr != NULL) {
 		if( IntrHandler != NULL) {
 			CfgPtr->HandlerTable[InterruptID].Handler = IntrHandler;
 		}
 		if( CallBackRef != NULL) {
 			CfgPtr->HandlerTable[InterruptID].CallBackRef = CallBackRef;
 		}
 	}
 }

 /*****************************************************************************/
 /**
 *
 * Looks up the device configuration based on the CPU interface base address of
 * the device. A table contains the configuration info for each device in the
 * system.
 *
 * @param	CpuBaseAddress is the CPU Interface Register base address.
 *
 * @return 	A pointer to the configuration structure for the specified
 *		device, or NULL if the device was not found.
 *
 * @note		None.
 *
 ******************************************************************************/
 static XScuGic_Config *LookupConfigByBaseAddress(u32 CpuBaseAddress)
 {
 	XScuGic_Config *CfgPtr = NULL;
 	u32 Index;

 	for (Index = 0U; Index < XPAR_SCUGIC_NUM_INSTANCES; Index++) {
 		if (XScuGic_ConfigTable[Index].CpuBaseAddress ==
 				CpuBaseAddress) {
 			CfgPtr = &XScuGic_ConfigTable[Index];
 			break;
 		}
 	}

 	return (XScuGic_Config *)CfgPtr;
 }

 /****************************************************************************/
 /**
 * Sets the interrupt priority and trigger type for the specificd IRQ source.
 *
 * @param	BaseAddr is the device base address
 * @param	Int_Id is the IRQ source number to modify
 * @param	Priority is the new priority for the IRQ source. 0 is highest
 * 			priority, 0xF8 (248) is lowest. There are 32 priority levels
 *			supported with a step of 8. Hence the supported priorities are
 *			0, 8, 16, 32, 40 ..., 248.
 * @param	Trigger is the new trigger type for the IRQ source.
 * Each bit pair describes the configuration for an INT_ID.
 * SFI    Read Only    b10 always
 * PPI    Read Only    depending on how the PPIs are configured.
 *                    b01    Active HIGH level sensitive
 *                    b11 Rising edge sensitive
 * SPI                LSB is read only.
 *                    b01    Active HIGH level sensitive
 *                    b11 Rising edge sensitive/
 *
 * @return	None.
 *
 * @note		This API has the similar functionality of XScuGic_SetPriority
 *	        TriggerType() and should be used when there is no InstancePtr.
 *
 *****************************************************************************/
 void XScuGic_SetPriTrigTypeByDistAddr(u32 DistBaseAddress, u32 Int_Id,
 					u8 Priority, u8 Trigger)
 {
 	u32 RegValue;
 	u8 LocalPriority = Priority;

 	Xil_AssertVoid(Int_Id < XSCUGIC_MAX_NUM_INTR_INPUTS);
 	Xil_AssertVoid(Trigger <= XSCUGIC_INT_CFG_MASK);
 	Xil_AssertVoid(LocalPriority <= XSCUGIC_MAX_INTR_PRIO_VAL);

 	/*
 	 * Determine the register to write to using the Int_Id.
 	 */
 	RegValue = XScuGic_ReadReg(DistBaseAddress,
 			XSCUGIC_PRIORITY_OFFSET_CALC(Int_Id));

 	/*
 	 * The priority bits are Bits 7 to 3 in GIC Priority Register. This
 	 * means the number of priority levels supported are 32 and they are
 	 * in steps of 8. The priorities can be 0, 8, 16, 32, 48, ... etc.
 	 * The lower order 3 bits are masked before putting it in the register.
 	 */
 	LocalPriority = LocalPriority & XSCUGIC_INTR_PRIO_MASK;
 	/*
 	 * Shift and Mask the correct bits for the priority and trigger in the
 	 * register
 	 */
 	RegValue &= ~(XSCUGIC_PRIORITY_MASK << ((Int_Id%4U)*8U));
 	RegValue |= (u32)LocalPriority << ((Int_Id%4U)*8U);

 	/*
 	 * Write the value back to the register.
 	 */
 	XScuGic_WriteReg(DistBaseAddress, XSCUGIC_PRIORITY_OFFSET_CALC(Int_Id),
 					RegValue);
 	/*
 	 * Determine the register to write to using the Int_Id.
 	 */
 	RegValue = XScuGic_ReadReg(DistBaseAddress,
 			XSCUGIC_INT_CFG_OFFSET_CALC (Int_Id));

 	/*
 	 * Shift and Mask the correct bits for the priority and trigger in the
 	 * register
 	 */
 	RegValue &= ~(XSCUGIC_INT_CFG_MASK << ((Int_Id%16U)*2U));
 	RegValue |= (u32)Trigger << ((Int_Id%16U)*2U);

 	/*
 	 * Write the value back to the register.
 	 */
 	XScuGic_WriteReg(DistBaseAddress, XSCUGIC_INT_CFG_OFFSET_CALC(Int_Id),
 				RegValue);
 }

 /****************************************************************************/
 /**
 * Gets the interrupt priority and trigger type for the specificd IRQ source.
 *
 * @param	BaseAddr is the device base address
 * @param	Int_Id is the IRQ source number to modify
 * @param	Priority is a pointer to the value of the priority of the IRQ
 *		source. This is a return value.
 * @param	Trigger is pointer to the value of the trigger of the IRQ
 *		source. This is a return value.
 *
 * @return	None.
 *
 * @note		This API has the similar functionality of XScuGic_GetPriority
 *	        TriggerType() and should be used when there is no InstancePtr.
 *
 *****************************************************************************/
 void XScuGic_GetPriTrigTypeByDistAddr(u32 DistBaseAddress, u32 Int_Id,
 					u8 *Priority, u8 *Trigger)
 {
 	u32 RegValue;

 	Xil_AssertVoid(Int_Id < XSCUGIC_MAX_NUM_INTR_INPUTS);
 	Xil_AssertVoid(Priority != NULL);
 	Xil_AssertVoid(Trigger != NULL);

 	/*
 	 * Determine the register to read to using the Int_Id.
 	 */
 	RegValue = XScuGic_ReadReg(DistBaseAddress,
 	    XSCUGIC_PRIORITY_OFFSET_CALC(Int_Id));

 	/*
 	 * Shift and Mask the correct bits for the priority and trigger in the
 	 * register
 	 */
 	RegValue = RegValue >> ((Int_Id%4U)*8U);
 	*Priority = (u8)(RegValue & XSCUGIC_PRIORITY_MASK);

 	/*
 	 * Determine the register to read to using the Int_Id.
 	 */
 	RegValue = XScuGic_ReadReg(DistBaseAddress,
 	    XSCUGIC_INT_CFG_OFFSET_CALC (Int_Id));

 	/*
 	 * Shift and Mask the correct bits for the priority and trigger in the
 	 * register
 	 */
 	RegValue = RegValue >> ((Int_Id%16U)*2U);

 	*Trigger = (u8)(RegValue & XSCUGIC_INT_CFG_MASK);
 }

 /****************************************************************************/
 /**
 * Unmaps specific SPI interrupt from the target CPU
 *
 * @param	DistBaseAddress is the device base address
 * @param	Cpu_Id is a CPU number from which the interrupt has to be
 *			unmapped
 * @param	Int_Id is the IRQ source number to modify
 *
 * @return	None.
 *
 * @note		None
 *
 *****************************************************************************/
 void XScuGic_InterruptUnmapFromCpuByDistAddr(u32 DistBaseAddress,
 											 u8 Cpu_Id, u32 Int_Id)
 {
 	u32 RegValue;
 	u8 BitPos;

 	Xil_AssertVoid(Int_Id < XSCUGIC_MAX_NUM_INTR_INPUTS);

 	RegValue = XScuGic_ReadReg(DistBaseAddress,
 				XSCUGIC_SPI_TARGET_OFFSET_CALC(Int_Id));

 	/*
 	 * Identify bit position corresponding to  Int_Id and Cpu_Id,
 	 * in interrupt target register and clear it
 	 */
 	BitPos = ((Int_Id % 4U) * 8U) + Cpu_Id;
 	RegValue &= (~ ( 1U << BitPos ));
 	XScuGic_WriteReg(DistBaseAddress,
 			XSCUGIC_SPI_TARGET_OFFSET_CALC(Int_Id), RegValue);
 }

 /****************************************************************************/
 /**
 * Unmaps all SPI interrupts from the target CPU
 *
 * @param	DistBaseAddress is the device base address
 * @param	Cpu_Id is a CPU number from which the interrupts has to be
 *			unmapped
 *
 * @return	None.
 *
 * @note		None
 *
 *****************************************************************************/
 void XScuGic_UnmapAllInterruptsFromCpuByDistAddr(u32 DistBaseAddress,
 												 u8 Cpu_Id)
 {
 	u32 Int_Id;
 	u32 Target_Cpu;
 	u32 LocalCpuID = (1U << Cpu_Id);

 	LocalCpuID |= LocalCpuID << 8U;
 	LocalCpuID |= LocalCpuID << 16U;

 	for (Int_Id = 32U; Int_Id<XSCUGIC_MAX_NUM_INTR_INPUTS;Int_Id=Int_Id+4U)
 	{

 		Target_Cpu = XScuGic_ReadReg(DistBaseAddress,
 				XSCUGIC_SPI_TARGET_OFFSET_CALC(Int_Id));
 		/* Remove LocalCpuID from interrupt target register */
 		Target_Cpu &= (~LocalCpuID);
 		XScuGic_WriteReg(DistBaseAddress,
 			XSCUGIC_SPI_TARGET_OFFSET_CALC(Int_Id), Target_Cpu);

 	}
 }
 /** @} */
	/******************************************************************************
	*
	* Copyright (C) 2010 - 2015 Xilinx, Inc. All rights reserved.
	*
	* Permission is hereby granted, free of charge, to any person obtaining a copy
	* of this software and associated documentation files (the "Software"), to deal
	* in the Software without restriction, including without limitation the rights
	* to use, copy, modify, merge, publish, distribute, sublicense, and/or sell
	* copies of the Software, and to permit persons to whom the Software is
	* furnished to do so, subject to the following conditions:
	*
	* The above copyright notice and this permission notice shall be included in
	* all copies or substantial portions of the Software.
	*
	* Use of the Software is limited solely to applications:
	* (a) running on a Xilinx device, or
	* (b) that interact with a Xilinx device through a bus or interconnect.
	*
	* THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, EXPRESS OR
	* IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF MERCHANTABILITY,
	* FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT. IN NO EVENT SHALL
	* XILINX BE LIABLE FOR ANY CLAIM, DAMAGES OR OTHER LIABILITY,
	* WHETHER IN AN ACTION OF CONTRACT, TORT OR OTHERWISE, ARISING FROM, OUT OF
	* OR IN CONNECTION WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS IN THE
	* SOFTWARE.
	*
	* Except as contained in this notice, the name of the Xilinx shall not be used
	* in advertising or otherwise to promote the sale, use or other dealings in
	* this Software without prior written authorization from Xilinx.
	*
	******************************************************************************/
	/*****************************************************************************/
	/**
	*
	* @file xscugic_hw.c
	* @addtogroup scugic_v3_8
	* @{
	*
	* This file contains low-level driver functions that can be used to access the
	* device. The user should refer to the hardware device specification for more
	* details of the device operation.
	* These routines are used when the user does not want to create an instance of
	* XScuGic structure but still wants to use the ScuGic device. Hence the
	* routines provided here take device id or scugic base address as arguments.
	* Separate static versions of DistInit and CPUInit are provided to implement
	* the low level driver routines.
	*
	* <pre>
	* MODIFICATION HISTORY:
	*
	* Ver Who Date Changes
	* ----- ---- -------- -------------------------------------------------------
	* 1.01a sdm 07/18/11 First release
	* 1.03a srt 02/27/13 Moved Offset calculation macros from *_hw.c (CR
	* 702687).
	* Added support to direct interrupts to the appropriate CPU.
	* Earlier interrupts were directed to CPU1 (hard coded). Now
	* depending upon the CPU selected by the user (xparameters.h),
	* interrupts will be directed to the relevant CPU.
	* This fixes CR 699688.
	* 1.04a hk 05/04/13 Fix for CR#705621. Moved functions
	* XScuGic_SetPriTrigTypeByDistAddr and
	* XScuGic_GetPriTrigTypeByDistAddr here from xscugic.c
	* 3.00 kvn 02/13/15 Modified code for MISRA-C:2012 compliance.
	* 3.6 kvn 02/17/17 Add support for changing GIC CPU master at run time.
	* kvn 02/28/17 Make the CpuId as static variable and Added new
	* XScugiC_GetCpuId to access CpuId.
	* 3.9 mus 02/21/18 Added new API's XScuGic_InterruptUnmapFromCpuByDistAddr
	* and XScuGic_UnmapAllInterruptsFromCpuByDistAddr, These
	* API's can be used by applications to unmap specific/all
	* interrupts from target CPU. It fixes CR#992490.
	*
	* </pre>
	*
	******************************************************************************/


	/*************************** Include Files *******************************/

	#include "xil_types.h"
	#include "xil_assert.h"
	#include "xscugic.h"
	#include "xparameters.h"

	/************************ Constant Definitions ***************************/

	/************************** Type Definitions *****************************/

	/*************** Macros (Inline Functions) Definitions *******************/

	/************************ Function Prototypes ****************************/

	static void DistInit(XScuGic_Config *Config, u32 CpuID);
	static void CPUInit(XScuGic_Config *Config);
	static XScuGic_Config *LookupConfigByBaseAddress(u32 CpuBaseAddress);

	/************************ Variable Definitions ***************************/

	extern XScuGic_Config XScuGic_ConfigTable[XPAR_XSCUGIC_NUM_INSTANCES];
	extern u32 CpuId;

	/*****************************************************************************/
	/**
	*
	* DistInit initializes the distributor of the GIC. The
	* initialization entails:
	*
	* - Write the trigger mode, priority and target CPU
	* - All interrupt sources are disabled
	* - Enable the distributor
	*
	* @param InstancePtr is a pointer to the XScuGic instance.
	* @param CpuID is the Cpu ID to be initialized.
	*
	* @return None
	*
	* @note None.
	*
	******************************************************************************/
	static void DistInit(XScuGic_Config *Config, u32 CpuID)
	{
	u32 Int_Id;
	u32 LocalCpuID = CpuID;

	#if USE_AMP==1
	#warning "Building GIC for AMP"

	/*
	* The distrubutor should not be initialized by FreeRTOS in the case of
	* AMP -- it is assumed that Linux is the master of this device in that
	* case.
	*/
	return;
	#endif

	XScuGic_WriteReg(Config->DistBaseAddress, XSCUGIC_DIST_EN_OFFSET, 0U);

	/*
	* Set the security domains in the int_security registers for non-secure
	* interrupts. All are secure, so leave at the default. Set to 1 for
	* non-secure interrupts.
	*/


	/*
	* For the Shared Peripheral Interrupts INT_ID[MAX..32], set:
	*/

	/*
	* 1. The trigger mode in the int_config register
	* Only write to the SPI interrupts, so start at 32
	*/
	for (Int_Id = 32U; Int_Id<XSCUGIC_MAX_NUM_INTR_INPUTS;Int_Id=Int_Id+16U) {
	/*
	* Each INT_ID uses two bits, or 16 INT_ID per register
	* Set them all to be level sensitive, active HIGH.
	*/
	XScuGic_WriteReg(Config->DistBaseAddress,
	XSCUGIC_INT_CFG_OFFSET_CALC(Int_Id), 0U);
	}


	#define DEFAULT_PRIORITY 0xa0a0a0a0U
	for (Int_Id = 0U; Int_Id<XSCUGIC_MAX_NUM_INTR_INPUTS;Int_Id=Int_Id+4U) {
	/*
	* 2. The priority using int the priority_level register
	* The priority_level and spi_target registers use one byte per
	* INT_ID.
	* Write a default value that can be changed elsewhere.
	*/
	XScuGic_WriteReg(Config->DistBaseAddress,
	XSCUGIC_PRIORITY_OFFSET_CALC(Int_Id),
	DEFAULT_PRIORITY);
	}

	for (Int_Id = 32U; Int_Id<XSCUGIC_MAX_NUM_INTR_INPUTS;Int_Id=Int_Id+4U) {
	/*
	* 3. The CPU interface in the spi_target register
	* Only write to the SPI interrupts, so start at 32
	*/
	LocalCpuID \|= LocalCpuID << 8U;
	LocalCpuID \|= LocalCpuID << 16U;

	XScuGic_WriteReg(Config->DistBaseAddress,
	XSCUGIC_SPI_TARGET_OFFSET_CALC(Int_Id), LocalCpuID);
	}

	for (Int_Id = 0U; Int_Id<XSCUGIC_MAX_NUM_INTR_INPUTS;Int_Id=Int_Id+32U) {
	/*
	* 4. Enable the SPI using the enable_set register. Leave all disabled
	* for now.
	*/
	XScuGic_WriteReg(Config->DistBaseAddress,
	XSCUGIC_EN_DIS_OFFSET_CALC(XSCUGIC_DISABLE_OFFSET,
	Int_Id),
	0xFFFFFFFFU);

	}

	XScuGic_WriteReg(Config->DistBaseAddress, XSCUGIC_DIST_EN_OFFSET,
	XSCUGIC_EN_INT_MASK);

	}

	/*****************************************************************************/
	/**
	*
	* CPUInit initializes the CPU Interface of the GIC. The initialization entails:
	*
	* - Set the priority of the CPU.
	* - Enable the CPU interface
	*
	* @param ConfigPtr is a pointer to a config table for the particular
	* device this driver is associated with.
	*
	* @return None
	*
	* @note None.
	*
	******************************************************************************/
	static void CPUInit(XScuGic_Config *Config)
	{
	/*
	* Program the priority mask of the CPU using the Priority mask
	* register
	*/
	XScuGic_WriteReg(Config->CpuBaseAddress, XSCUGIC_CPU_PRIOR_OFFSET,
	0xF0U);

	/*
	* If the CPU operates in both security domains, set parameters in the
	* control_s register.
	* 1. Set FIQen=1 to use FIQ for secure interrupts,
	* 2. Program the AckCtl bit
	* 3. Program the SBPR bit to select the binary pointer behavior
	* 4. Set EnableS = 1 to enable secure interrupts
	* 5. Set EnbleNS = 1 to enable non secure interrupts
	*/

	/*
	* If the CPU operates only in the secure domain, setup the
	* control_s register.
	* 1. Set FIQen=1,
	* 2. Set EnableS=1, to enable the CPU interface to signal secure .
	* interrupts Only enable the IRQ output unless secure interrupts
	* are needed.
	*/
	XScuGic_WriteReg(Config->CpuBaseAddress, XSCUGIC_CONTROL_OFFSET, 0x07U);

	}

	/*****************************************************************************/
	/**
	*
	* CfgInitialize a specific interrupt controller instance/driver. The
	* initialization entails:
	*
	* - Initialize fields of the XScuGic structure
	* - Initial vector table with stub function calls
	* - All interrupt sources are disabled
	*
	* @param InstancePtr is a pointer to the XScuGic instance to be worked on.
	* @param ConfigPtr is a pointer to a config table for the particular device
	* this driver is associated with.
	* @param EffectiveAddr is the device base address in the virtual memory address
	* space. The caller is responsible for keeping the address mapping
	* from EffectiveAddr to the device physical base address unchanged
	* once this function is invoked. Unexpected errors may occur if the
	* address mapping changes after this function is called. If address
	* translation is not used, use Config->BaseAddress for this parameters,
	* passing the physical address instead.
	*
	* @return
	*
	* - XST_SUCCESS if initialization was successful
	*
	* @note
	*
	* None.
	*
	******************************************************************************/
	s32 XScuGic_DeviceInitialize(u32 DeviceId)
	{
	XScuGic_Config *Config;
	u32 Cpu_Id = XScuGic_GetCpuID() + (u32)1;

	Config = &XScuGic_ConfigTable[(u32 )DeviceId];

	DistInit(Config, Cpu_Id);

	CPUInit(Config);

	return XST_SUCCESS;
	}

	/*****************************************************************************/
	/**
	* This function is the primary interrupt handler for the driver. It must be
	* connected to the interrupt source such that it is called when an interrupt of
	* the interrupt controller is active. It will resolve which interrupts are
	* active and enabled and call the appropriate interrupt handler. It uses
	* the Interrupt Type information to determine when to acknowledge the
	* interrupt.Highest priority interrupts are serviced first.
	*
	* This function assumes that an interrupt vector table has been previously
	* initialized. It does not verify that entries in the table are valid before
	* calling an interrupt handler.
	*
	* @param DeviceId is the unique identifier for the ScuGic device.
	*
	* @return None.
	*
	* @note None.
	*
	******************************************************************************/
	void XScuGic_DeviceInterruptHandler(void *DeviceId)
	{

	u32 InterruptID;
	u32 IntIDFull;
	XScuGic_VectorTableEntry *TablePtr;
	XScuGic_Config *CfgPtr;

	CfgPtr = &XScuGic_ConfigTable[(INTPTR )DeviceId];

	/*
	* Read the int_ack register to identify the highest priority
	* interrupt ID and make sure it is valid. Reading Int_Ack will
	* clear the interrupt in the GIC.
	*/
	IntIDFull = XScuGic_ReadReg(CfgPtr->CpuBaseAddress, XSCUGIC_INT_ACK_OFFSET);
	InterruptID = IntIDFull & XSCUGIC_ACK_INTID_MASK;
	if(XSCUGIC_MAX_NUM_INTR_INPUTS < InterruptID){
	goto IntrExit;
	}

	/*
	* If the interrupt is shared, do some locking here if there are
	* multiple processors.
	*/
	/*
	* If pre-eption is required:
	* Re-enable pre-emption by setting the CPSR I bit for non-secure ,
	* interrupts or the F bit for secure interrupts
	*/

	/*
	* If we need to change security domains, issue a SMC instruction here.
	*/

	/*
	* Execute the ISR. Jump into the Interrupt service routine based on
	* the IRQSource. A software trigger is cleared by the ACK.
	*/
	TablePtr = &(CfgPtr->HandlerTable[InterruptID]);
	if(TablePtr != NULL) {
	TablePtr->Handler(TablePtr->CallBackRef);
	}

	IntrExit:
	/*
	* Write to the EOI register, we are all done here.
	* Let this function return, the boot code will restore the stack.
	*/
	XScuGic_WriteReg(CfgPtr->CpuBaseAddress, XSCUGIC_EOI_OFFSET, IntIDFull);

	/*
	* Return from the interrupt. Change security domains could happen
	* here.
	*/
	}

	/*****************************************************************************/
	/**
	*
	* Register a handler function for a specific interrupt ID. The vector table
	* of the interrupt controller is updated, overwriting any previous handler.
	* The handler function will be called when an interrupt occurs for the given
	* interrupt ID.
	*
	* @param BaseAddress is the CPU Interface Register base address of the
	* interrupt controller whose vector table will be modified.
	* @param InterruptId is the interrupt ID to be associated with the input
	* handler.
	* @param Handler is the function pointer that will be added to
	* the vector table for the given interrupt ID.
	* @param CallBackRef is the argument that will be passed to the new
	* handler function when it is called. This is user-specific.
	*
	* @return None.
	*
	* @note
	*
	* Note that this function has no effect if the input base address is invalid.
	*
	******************************************************************************/
	void XScuGic_RegisterHandler(u32 BaseAddress, s32 InterruptID,
	Xil_InterruptHandler IntrHandler, void *CallBackRef)
	{
	XScuGic_Config *CfgPtr;
	CfgPtr = LookupConfigByBaseAddress(BaseAddress);

	if(CfgPtr != NULL) {
	if( IntrHandler != NULL) {
	CfgPtr->HandlerTable[InterruptID].Handler = IntrHandler;
	}
	if( CallBackRef != NULL) {
	CfgPtr->HandlerTable[InterruptID].CallBackRef = CallBackRef;
	}
	}
	}

	/*****************************************************************************/
	/**
	*
	* Looks up the device configuration based on the CPU interface base address of
	* the device. A table contains the configuration info for each device in the
	* system.
	*
	* @param CpuBaseAddress is the CPU Interface Register base address.
	*
	* @return A pointer to the configuration structure for the specified
	* device, or NULL if the device was not found.
	*
	* @note None.
	*
	******************************************************************************/
	static XScuGic_Config *LookupConfigByBaseAddress(u32 CpuBaseAddress)
	{
	XScuGic_Config *CfgPtr = NULL;
	u32 Index;

	for (Index = 0U; Index < XPAR_SCUGIC_NUM_INSTANCES; Index++) {
	if (XScuGic_ConfigTable[Index].CpuBaseAddress ==
	CpuBaseAddress) {
	CfgPtr = &XScuGic_ConfigTable[Index];
	break;
	}
	}

	return (XScuGic_Config *)CfgPtr;
	}

	/****************************************************************************/
	/**
	* Sets the interrupt priority and trigger type for the specificd IRQ source.
	*
	* @param BaseAddr is the device base address
	* @param Int_Id is the IRQ source number to modify
	* @param Priority is the new priority for the IRQ source. 0 is highest
	* priority, 0xF8 (248) is lowest. There are 32 priority levels
	* supported with a step of 8. Hence the supported priorities are
	* 0, 8, 16, 32, 40 ..., 248.
	* @param Trigger is the new trigger type for the IRQ source.
	* Each bit pair describes the configuration for an INT_ID.
	* SFI Read Only b10 always
	* PPI Read Only depending on how the PPIs are configured.
	* b01 Active HIGH level sensitive
	* b11 Rising edge sensitive
	* SPI LSB is read only.
	* b01 Active HIGH level sensitive
	* b11 Rising edge sensitive/
	*
	* @return None.
	*
	* @note This API has the similar functionality of XScuGic_SetPriority
	* TriggerType() and should be used when there is no InstancePtr.
	*
	*****************************************************************************/
	void XScuGic_SetPriTrigTypeByDistAddr(u32 DistBaseAddress, u32 Int_Id,
	u8 Priority, u8 Trigger)
	{
	u32 RegValue;
	u8 LocalPriority = Priority;

	Xil_AssertVoid(Int_Id < XSCUGIC_MAX_NUM_INTR_INPUTS);
	Xil_AssertVoid(Trigger <= XSCUGIC_INT_CFG_MASK);
	Xil_AssertVoid(LocalPriority <= XSCUGIC_MAX_INTR_PRIO_VAL);

	/*
	* Determine the register to write to using the Int_Id.
	*/
	RegValue = XScuGic_ReadReg(DistBaseAddress,
	XSCUGIC_PRIORITY_OFFSET_CALC(Int_Id));

	/*
	* The priority bits are Bits 7 to 3 in GIC Priority Register. This
	* means the number of priority levels supported are 32 and they are
	* in steps of 8. The priorities can be 0, 8, 16, 32, 48, ... etc.
	* The lower order 3 bits are masked before putting it in the register.
	*/
	LocalPriority = LocalPriority & XSCUGIC_INTR_PRIO_MASK;
	/*
	* Shift and Mask the correct bits for the priority and trigger in the
	* register
	*/
	RegValue &= ~(XSCUGIC_PRIORITY_MASK << ((Int_Id%4U)*8U));
	RegValue \|= (u32)LocalPriority << ((Int_Id%4U)*8U);

	/*
	* Write the value back to the register.
	*/
	XScuGic_WriteReg(DistBaseAddress, XSCUGIC_PRIORITY_OFFSET_CALC(Int_Id),
	RegValue);
	/*
	* Determine the register to write to using the Int_Id.
	*/
	RegValue = XScuGic_ReadReg(DistBaseAddress,
	XSCUGIC_INT_CFG_OFFSET_CALC (Int_Id));

	/*
	* Shift and Mask the correct bits for the priority and trigger in the
	* register
	*/
	RegValue &= ~(XSCUGIC_INT_CFG_MASK << ((Int_Id%16U)*2U));
	RegValue \|= (u32)Trigger << ((Int_Id%16U)*2U);

	/*
	* Write the value back to the register.
	*/
	XScuGic_WriteReg(DistBaseAddress, XSCUGIC_INT_CFG_OFFSET_CALC(Int_Id),
	RegValue);
	}

	/****************************************************************************/
	/**
	* Gets the interrupt priority and trigger type for the specificd IRQ source.
	*
	* @param BaseAddr is the device base address
	* @param Int_Id is the IRQ source number to modify
	* @param Priority is a pointer to the value of the priority of the IRQ
	* source. This is a return value.
	* @param Trigger is pointer to the value of the trigger of the IRQ
	* source. This is a return value.
	*
	* @return None.
	*
	* @note This API has the similar functionality of XScuGic_GetPriority
	* TriggerType() and should be used when there is no InstancePtr.
	*
	*****************************************************************************/
	void XScuGic_GetPriTrigTypeByDistAddr(u32 DistBaseAddress, u32 Int_Id,
	u8 Priority, u8 Trigger)
	{
	u32 RegValue;

	Xil_AssertVoid(Int_Id < XSCUGIC_MAX_NUM_INTR_INPUTS);
	Xil_AssertVoid(Priority != NULL);
	Xil_AssertVoid(Trigger != NULL);

	/*
	* Determine the register to read to using the Int_Id.
	*/
	RegValue = XScuGic_ReadReg(DistBaseAddress,
	XSCUGIC_PRIORITY_OFFSET_CALC(Int_Id));

	/*
	* Shift and Mask the correct bits for the priority and trigger in the
	* register
	*/
	RegValue = RegValue >> ((Int_Id%4U)*8U);
	*Priority = (u8)(RegValue & XSCUGIC_PRIORITY_MASK);

	/*
	* Determine the register to read to using the Int_Id.
	*/
	RegValue = XScuGic_ReadReg(DistBaseAddress,
	XSCUGIC_INT_CFG_OFFSET_CALC (Int_Id));

	/*
	* Shift and Mask the correct bits for the priority and trigger in the
	* register
	*/
	RegValue = RegValue >> ((Int_Id%16U)*2U);

	*Trigger = (u8)(RegValue & XSCUGIC_INT_CFG_MASK);
	}

	/****************************************************************************/
	/**
	* Unmaps specific SPI interrupt from the target CPU
	*
	* @param DistBaseAddress is the device base address
	* @param Cpu_Id is a CPU number from which the interrupt has to be
	* unmapped
	* @param Int_Id is the IRQ source number to modify
	*
	* @return None.
	*
	* @note None
	*
	*****************************************************************************/
	void XScuGic_InterruptUnmapFromCpuByDistAddr(u32 DistBaseAddress,
	u8 Cpu_Id, u32 Int_Id)
	{
	u32 RegValue;
	u8 BitPos;

	Xil_AssertVoid(Int_Id < XSCUGIC_MAX_NUM_INTR_INPUTS);

	RegValue = XScuGic_ReadReg(DistBaseAddress,
	XSCUGIC_SPI_TARGET_OFFSET_CALC(Int_Id));

	/*
	* Identify bit position corresponding to Int_Id and Cpu_Id,
	* in interrupt target register and clear it
	*/
	BitPos = ((Int_Id % 4U) * 8U) + Cpu_Id;
	RegValue &= (~ ( 1U << BitPos ));
	XScuGic_WriteReg(DistBaseAddress,
	XSCUGIC_SPI_TARGET_OFFSET_CALC(Int_Id), RegValue);
	}

	/****************************************************************************/
	/**
	* Unmaps all SPI interrupts from the target CPU
	*
	* @param DistBaseAddress is the device base address
	* @param Cpu_Id is a CPU number from which the interrupts has to be
	* unmapped
	*
	* @return None.
	*
	* @note None
	*
	*****************************************************************************/
	void XScuGic_UnmapAllInterruptsFromCpuByDistAddr(u32 DistBaseAddress,
	u8 Cpu_Id)
	{
	u32 Int_Id;
	u32 Target_Cpu;
	u32 LocalCpuID = (1U << Cpu_Id);

	LocalCpuID \|= LocalCpuID << 8U;
	LocalCpuID \|= LocalCpuID << 16U;

	for (Int_Id = 32U; Int_Id<XSCUGIC_MAX_NUM_INTR_INPUTS;Int_Id=Int_Id+4U)
	{

	Target_Cpu = XScuGic_ReadReg(DistBaseAddress,
	XSCUGIC_SPI_TARGET_OFFSET_CALC(Int_Id));
	/* Remove LocalCpuID from interrupt target register */
	Target_Cpu &= (~LocalCpuID);
	XScuGic_WriteReg(DistBaseAddress,
	XSCUGIC_SPI_TARGET_OFFSET_CALC(Int_Id), Target_Cpu);

	}
	}
	/** @} */