FreeRTOS/Demo/CORTEX_A53_64-bit_UltraScale_MPSoC/RTOSDemo_A53_bsp/psu_cortexa53_0/libsrc/canps_v3_2/src/xcanps.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 xcanps.c
 * @addtogroup canps_v3_2
 * @{
 *
 * Functions in this file are the minimum required functions for the XCanPs
 * driver. See xcanps.h for a detailed description of the driver.
 *
 * @note 	None.
 *
 *
 * <pre>
 * MODIFICATION HISTORY:
 *
 * Ver   Who    Date	Changes
 * ----- -----  -------- -----------------------------------------------
 * 1.00a xd/sv  01/12/10 First release
 * 1.01a bss    12/27/11 Added the APIs XCanPs_SetTxIntrWatermark and
 * 			XCanPs_GetTxIntrWatermark.
 * 3.00  kvn    02/13/15 Modified code for MISRA-C:2012 compliance.
 * </pre>
 *
 ******************************************************************************/

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

 #include "xcanps.h"

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

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

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

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

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

 static void StubHandler(void);

 /*****************************************************************************/
 /*
 *
 * This function initializes a XCanPs instance/driver.
 *
 * The initialization entails:
 * - Initialize all members of the XCanPs structure.
 * - Reset the CAN device. The CAN device will enter Configuration Mode
 *   immediately after the reset is finished.
 *
 * @param	InstancePtr is a pointer to the XCanPs instance.
 * @param	ConfigPtr points to the XCanPs device configuration structure.
 * @param	EffectiveAddr is the device base address in the virtual memory
 *		address space. If the address translation is not used then the
 *		physical address is passed.
 *		Unexpected errors may occur if the address mapping is changed
 *		after this function is invoked.
 *
 * @return	XST_SUCCESS always.
 *
 * @note		None.
 *
 ******************************************************************************/
 s32 XCanPs_CfgInitialize(XCanPs *InstancePtr, XCanPs_Config *ConfigPtr,
 				u32 EffectiveAddr)
 {
 	s32 Status;
 	Xil_AssertNonvoid(InstancePtr != NULL);
 	Xil_AssertNonvoid(ConfigPtr != NULL);

 	/*
 	 * Set some default values for instance data, don't indicate the device
 	 * is ready to use until everything has been initialized successfully.
 	 */
 	InstancePtr->IsReady = 0U;
 	InstancePtr->CanConfig.BaseAddr = EffectiveAddr;
 	InstancePtr->CanConfig.DeviceId = ConfigPtr->DeviceId;

 	/*
 	 * Set all handlers to stub values, let user configure this data later.
 	 */
 	InstancePtr->SendHandler = (XCanPs_SendRecvHandler) StubHandler;
 	InstancePtr->RecvHandler = (XCanPs_SendRecvHandler) StubHandler;
 	InstancePtr->ErrorHandler = (XCanPs_ErrorHandler) StubHandler;
 	InstancePtr->EventHandler = (XCanPs_EventHandler) StubHandler;

 	/*
 	 * Indicate the component is now ready to use.
 	 */
 	InstancePtr->IsReady = XIL_COMPONENT_IS_READY;

 	/*
 	 * Reset the device to get it into its initial state.
 	 */
 	XCanPs_Reset(InstancePtr);

 	Status = XST_SUCCESS;
 	return Status;
 }

 /*****************************************************************************/
 /**
 *
 * This function resets the CAN device. Calling this function resets the device
 * immediately, and any pending transmission or reception is terminated at once.
 * Both Object Layer and Transfer Layer are reset. This function does not reset
 * the Physical Layer. All registers are reset to the default values, and no
 * previous status will be restored. TX FIFO, RX FIFO and TX High Priority
 * Buffer are also reset.
 *
 * When a reset is required due to an internal error, the driver notifies the
 * upper layer software of this need through the error status code or interrupts.
 * The upper layer software is responsible for calling this Reset function and
 * then re-configuring the device.
 *
 * The CAN device will be in Configuration Mode immediately after this function
 * returns.
 *
 * @param	InstancePtr is a pointer to the XCanPs instance.
 *
 * @return	None.
 *
 * @note		None.
 *
 ******************************************************************************/
 void XCanPs_Reset(XCanPs *InstancePtr)
 {
 	Xil_AssertVoid(InstancePtr != NULL);
 	Xil_AssertVoid(InstancePtr->IsReady == XIL_COMPONENT_IS_READY);

 	XCanPs_WriteReg(InstancePtr->CanConfig.BaseAddr, XCANPS_SRR_OFFSET, \
 			   XCANPS_SRR_SRST_MASK);
 }

 /****************************************************************************/
 /**
 *
 * This routine returns the current operation mode of the CAN device.
 *
 * @param	InstancePtr is a pointer to the XCanPs instance.
 *
 * @return
 * 		- XCANPS_MODE_CONFIG if the device is in Configuration Mode.
 * 		- XCANPS_MODE_SLEEP if the device is in Sleep Mode.
 * 		- XCANPS_MODE_NORMAL if the device is in Normal Mode.
 * 		- XCANPS_MODE_LOOPBACK if the device is in Loop Back Mode.
 * 		- XCANPS_MODE_SNOOP if the device is in Snoop Mode.
 *
 * @note		None.
 *
 *****************************************************************************/
 u8 XCanPs_GetMode(XCanPs *InstancePtr)
 {
 	u32 StatusReg;

 	Xil_AssertNonvoid(InstancePtr != NULL);
 	Xil_AssertNonvoid(InstancePtr->IsReady == XIL_COMPONENT_IS_READY);

 	StatusReg = XCanPs_GetStatus(InstancePtr);

 	if ((StatusReg & XCANPS_SR_CONFIG_MASK) != (u32)0) {
 		return (u8)XCANPS_MODE_CONFIG;

 	}
 	else if ((StatusReg & XCANPS_SR_SLEEP_MASK) != (u32)0) {
 		return (u8)XCANPS_MODE_SLEEP;

 	}
 	else if ((StatusReg & XCANPS_SR_NORMAL_MASK) != (u32)0) {
 		if ((StatusReg & XCANPS_SR_SNOOP_MASK) != (u32)0) {
 			return (u8)XCANPS_MODE_SNOOP;
 		} else {
 			return (u8)XCANPS_MODE_NORMAL;
 		}
 	}
 	else {
 		/*
 		 * If this line is reached, the device is in Loop Back Mode.
 		 */
 		return (u8)XCANPS_MODE_LOOPBACK;
 	}
 }

 /*****************************************************************************/
 /**
 *
 * This function allows the CAN device to enter one of the following operation
 * modes:
 *	- Configuration Mode: Pass in parameter XCANPS_MODE_CONFIG
 *	- Sleep Mode: Pass in parameter XCANPS_MODE_SLEEP
 *	- Normal Mode: Pass in parameter XCANPS_MODE_NORMAL
 *	- Loop Back Mode: Pass in parameter XCANPS_MODE_LOOPBACK.
 *	- Snoop Mode: Pass in parameter XCANPS_MODE_SNOOP.
 *
 * Read the xcanps.h file and device specification for detailed description of
 * each operation mode.
 *
 * @param	InstancePtr is a pointer to the XCanPs instance.
 * @param	OperationMode specify which operation mode to enter. Valid value
 *		is any of XCANPS_MODE_* defined in xcanps.h. Multiple modes
 *		can not be entered at the same time.
 *
 * @return	None.
 *
 * @note
 *
 * This function does NOT ensure CAN device enters the specified operation mode
 * before it returns the control to the caller. The caller is responsible for
 * checking current operation mode using XCanPs_GetMode().
 *
 ******************************************************************************/
 void XCanPs_EnterMode(XCanPs *InstancePtr, u8 OperationMode)
 {
 	u8 CurrentMode;

 	Xil_AssertVoid(InstancePtr != NULL);
 	Xil_AssertVoid(InstancePtr->IsReady == XIL_COMPONENT_IS_READY);
 	Xil_AssertVoid((OperationMode == (u8)XCANPS_MODE_CONFIG) ||
 			(OperationMode == (u8)XCANPS_MODE_SLEEP) ||
 			(OperationMode == (u8)XCANPS_MODE_NORMAL) ||
 			(OperationMode == (u8)XCANPS_MODE_LOOPBACK) ||
 			(OperationMode == (u8)XCANPS_MODE_SNOOP));

 	CurrentMode = XCanPs_GetMode(InstancePtr);

 	/*
 	 * If current mode is Normal Mode and the mode to enter is Sleep Mode,
 	 * or if current mode is Sleep Mode and the mode to enter is Normal
 	 * Mode, no transition through Configuration Mode is needed.
 	 */
 	if ((CurrentMode == (u8)XCANPS_MODE_NORMAL) &&
 		(OperationMode == (u8)XCANPS_MODE_SLEEP)) {
 		/*
 		 * Normal Mode ---> Sleep Mode
 		 */
 		XCanPs_WriteReg(InstancePtr->CanConfig.BaseAddr,
 				XCANPS_MSR_OFFSET, XCANPS_MSR_SLEEP_MASK);
 		return;

 	} else if ((CurrentMode == (u8)XCANPS_MODE_SLEEP) &&
 		 (OperationMode == (u8)XCANPS_MODE_NORMAL)) {
 		/*
 		 * Sleep Mode ---> Normal Mode
 		 */
 		XCanPs_WriteReg(InstancePtr->CanConfig.BaseAddr,
 					XCANPS_MSR_OFFSET, 0U);
 		return;
 	}
 	else {
 		/*This else was made for misra-c compliance*/
 		;
 	}

 	/*
 	 * If the mode transition is not any of the two cases above, CAN must
 	 * enter Configuration Mode before switching into the target operation
 	 * mode.
 	 */
 	XCanPs_WriteReg(InstancePtr->CanConfig.BaseAddr,
 				XCANPS_SRR_OFFSET, 0U);

 	/*
 	 * Check if the device has entered Configuration Mode, if not, return to
 	 * the caller.
 	 */
 	if (XCanPs_GetMode(InstancePtr) != (u8)XCANPS_MODE_CONFIG) {
 		return;
 	}

 	switch (OperationMode) {
 		case XCANPS_MODE_CONFIG:
 			/*
 			 * As CAN is in Configuration Mode already.
 			 * Nothing is needed to be done here.
 			 */
 			break;

 		case XCANPS_MODE_SLEEP:
 			XCanPs_WriteReg(InstancePtr->CanConfig.BaseAddr,
 					XCANPS_MSR_OFFSET, XCANPS_MSR_SLEEP_MASK);
 			XCanPs_WriteReg(InstancePtr->CanConfig.BaseAddr,
 					XCANPS_SRR_OFFSET, XCANPS_SRR_CEN_MASK);
 			break;

 		case XCANPS_MODE_NORMAL:
 			XCanPs_WriteReg(InstancePtr->CanConfig.BaseAddr,
 					XCANPS_MSR_OFFSET, 0U);
 			XCanPs_WriteReg(InstancePtr->CanConfig.BaseAddr,
 					XCANPS_SRR_OFFSET, XCANPS_SRR_CEN_MASK);
 			break;

 		case XCANPS_MODE_LOOPBACK:
 			XCanPs_WriteReg(InstancePtr->CanConfig.BaseAddr,
 					XCANPS_MSR_OFFSET, XCANPS_MSR_LBACK_MASK);
 			XCanPs_WriteReg(InstancePtr->CanConfig.BaseAddr,
 					XCANPS_SRR_OFFSET, XCANPS_SRR_CEN_MASK);
 			break;

 		case XCANPS_MODE_SNOOP:
 			XCanPs_WriteReg(InstancePtr->CanConfig.BaseAddr,
 					XCANPS_MSR_OFFSET, XCANPS_MSR_SNOOP_MASK);
 			XCanPs_WriteReg(InstancePtr->CanConfig.BaseAddr,
 					XCANPS_SRR_OFFSET, XCANPS_SRR_CEN_MASK);
 			break;

 		default:
 			/*This default was made for misra-c compliance*/
 			break;

 	}
 }

 /*****************************************************************************/
 /**
 *
 * This function returns Status value from Status Register (SR). Use the
 * XCANPS_SR_* constants defined in xcanps_hw.h to interpret the returned
 * value.
 *
 * @param	InstancePtr is a pointer to the XCanPs instance.
 *
 * @return	The 32-bit value read from Status Register.
 *
 * @note		None.
 *
 ******************************************************************************/
 u32 XCanPs_GetStatus(XCanPs *InstancePtr)
 {

 	Xil_AssertNonvoid(InstancePtr != NULL);
 	Xil_AssertNonvoid(InstancePtr->IsReady == XIL_COMPONENT_IS_READY);

 	return XCanPs_ReadReg(InstancePtr->CanConfig.BaseAddr,
 				XCANPS_SR_OFFSET);
 }

 /*****************************************************************************/
 /**
 *
 * This function reads Receive and Transmit error counters.
 *
 * @param	InstancePtr is a pointer to the XCanPs instance.
 * @param	RxErrorCount is a pointer to data in which the Receive Error
 *		counter value is returned.
 * @param	TxErrorCount is a pointer to data in which the Transmit Error
 *		counter value is returned.
 *
 * @return	None.
 *
 * @note		None.
 *
 ******************************************************************************/
 void XCanPs_GetBusErrorCounter(XCanPs *InstancePtr, u8 *RxErrorCount,
 				 u8 *TxErrorCount)
 {
 	u32 ErrorCount;

 	Xil_AssertVoid(InstancePtr != NULL);
 	Xil_AssertVoid(InstancePtr->IsReady == XIL_COMPONENT_IS_READY);
 	Xil_AssertVoid(RxErrorCount != NULL);
 	Xil_AssertVoid(TxErrorCount != NULL);
 	/*
 	 * Read Error Counter Register and parse it.
 	 */
 	ErrorCount = XCanPs_ReadReg(InstancePtr->CanConfig.BaseAddr,
 				XCANPS_ECR_OFFSET);
 	*RxErrorCount = (u8)((ErrorCount & XCANPS_ECR_REC_MASK) >>
 				XCANPS_ECR_REC_SHIFT);
 	*TxErrorCount = (u8)(ErrorCount & XCANPS_ECR_TEC_MASK);
 }

 /*****************************************************************************/
 /**
 *
 * This function reads Error Status value from Error Status Register (ESR). Use
 * the XCANPS_ESR_* constants defined in xcanps_hw.h to interpret the
 * returned value.
 *
 * @param	InstancePtr is a pointer to the XCanPs instance.
 *
 * @return	The 32-bit value read from Error Status Register.
 *
 * @note		None.
 *
 ******************************************************************************/
 u32 XCanPs_GetBusErrorStatus(XCanPs *InstancePtr)
 {

 	Xil_AssertNonvoid(InstancePtr != NULL);
 	Xil_AssertNonvoid(InstancePtr->IsReady == XIL_COMPONENT_IS_READY);

 	return XCanPs_ReadReg(InstancePtr->CanConfig.BaseAddr,
 				XCANPS_ESR_OFFSET);
 }

 /*****************************************************************************/
 /**
 *
 * This function clears Error Status bit(s) previously set in Error
 * Status Register (ESR). Use the XCANPS_ESR_* constants defined in xcanps_hw.h
 * to create the value to pass in. If a bit was cleared in Error Status Register
 * before this function is called, it will not be modified.
 *
 * @param	InstancePtr is a pointer to the XCanPs instance.
 *
 * @param	Mask is he 32-bit mask used to clear bits in Error Status
 *		Register. Multiple XCANPS_ESR_* values can be 'OR'ed to clear
 *		multiple bits.
 *
 * @note		None.
 *
 ******************************************************************************/
 void XCanPs_ClearBusErrorStatus(XCanPs *InstancePtr, u32 Mask)
 {
 	Xil_AssertVoid(InstancePtr != NULL);
 	Xil_AssertVoid(InstancePtr->IsReady == XIL_COMPONENT_IS_READY);

 	XCanPs_WriteReg(InstancePtr->CanConfig.BaseAddr,
 			XCANPS_ESR_OFFSET, Mask);
 }

 /*****************************************************************************/
 /**
 *
 * This function sends a CAN Frame. If the TX FIFO is not full then the given
 * frame is written into the the TX FIFO otherwise, it returns an error code
 * immediately.
 * This function does not wait for the given frame being sent to CAN bus.
 *
 * @param	InstancePtr is a pointer to the XCanPs instance.
 * @param	FramePtr is a pointer to a 32-bit aligned buffer containing the
 *		CAN frame to be sent.
 *
 * @return
 *		- XST_SUCCESS if TX FIFO was not full and the given frame was
 *		written into the FIFO.
 *		- XST_FIFO_NO_ROOM if there is no room in the TX FIFO for the
 *		given frame.
 *
 * @note		None.
 *
 ******************************************************************************/
 s32 XCanPs_Send(XCanPs *InstancePtr, u32 *FramePtr)
 {
 	s32 Status;
 	Xil_AssertNonvoid(InstancePtr != NULL);
 	Xil_AssertNonvoid(FramePtr != NULL);
 	Xil_AssertNonvoid(InstancePtr->IsReady == XIL_COMPONENT_IS_READY);

 	if (XCanPs_IsTxFifoFull(InstancePtr) == TRUE) {
 		Status = XST_FIFO_NO_ROOM;
 	} else {

 		/*
 		 * Write IDR, DLC, Data Word 1 and Data Word 2 to the CAN device.
 		 */
 		XCanPs_WriteReg(InstancePtr->CanConfig.BaseAddr,
 				XCANPS_TXFIFO_ID_OFFSET, FramePtr[0]);
 		XCanPs_WriteReg(InstancePtr->CanConfig.BaseAddr,
 				XCANPS_TXFIFO_DLC_OFFSET, FramePtr[1]);
 		XCanPs_WriteReg(InstancePtr->CanConfig.BaseAddr,
 				XCANPS_TXFIFO_DW1_OFFSET, Xil_EndianSwap32(FramePtr[2]));
 		XCanPs_WriteReg(InstancePtr->CanConfig.BaseAddr,
 				XCANPS_TXFIFO_DW2_OFFSET, Xil_EndianSwap32(FramePtr[3]));

 		Status = XST_SUCCESS;
 	}
 	return Status;
 }

 /*****************************************************************************/
 /**
 *
 * This function receives a CAN Frame. This function first checks if RX FIFO is
 * empty, if not, it then reads a frame from the RX FIFO into the given buffer.
 * This function returns error code immediately if there is no frame in the RX
 * FIFO.
 *
 * @param	InstancePtr is a pointer to the XCanPs instance.
 * @param	FramePtr is a pointer to a 32-bit aligned buffer where the CAN
 *		frame to be written.
 *
 * @return
 *		- XST_SUCCESS if RX FIFO was not empty and a frame was read from
 *		RX FIFO successfully and written into the given buffer.
 *		- XST_NO_DATA if there is no frame to be received from the FIFO.
 *
 * @note		None.
 *
 ******************************************************************************/
 s32 XCanPs_Recv(XCanPs *InstancePtr, u32 *FramePtr)
 {
 	s32 Status;
 	Xil_AssertNonvoid(InstancePtr != NULL);
 	Xil_AssertNonvoid(FramePtr != NULL);
 	Xil_AssertNonvoid(InstancePtr->IsReady == XIL_COMPONENT_IS_READY);

 	if (XCanPs_IsRxEmpty(InstancePtr) == TRUE) {
 		Status = XST_NO_DATA;
 	} else {

 		/*
 		 * Read IDR, DLC, Data Word 1 and Data Word 2 from the CAN device.
 		 */
 		FramePtr[0] = XCanPs_ReadReg(InstancePtr->CanConfig.BaseAddr,
 						XCANPS_RXFIFO_ID_OFFSET);
 		FramePtr[1] = XCanPs_ReadReg(InstancePtr->CanConfig.BaseAddr,
 						XCANPS_RXFIFO_DLC_OFFSET);
 		FramePtr[2] = Xil_EndianSwap32(XCanPs_ReadReg(InstancePtr->CanConfig.BaseAddr,
 						XCANPS_RXFIFO_DW1_OFFSET));
 		FramePtr[3] = Xil_EndianSwap32(XCanPs_ReadReg(InstancePtr->CanConfig.BaseAddr,
 						XCANPS_RXFIFO_DW2_OFFSET));

 		/*
 		 * Clear RXNEMP bit in ISR. This allows future XCanPs_IsRxEmpty() call
 		 * returns correct RX FIFO occupancy/empty condition.
 		 */
 		XCanPs_IntrClear(InstancePtr, XCANPS_IXR_RXNEMP_MASK);

 		Status = XST_SUCCESS;
 	}
 	return Status;
 }

 /*****************************************************************************/
 /**
 *
 * This routine sends a CAN High Priority frame. This function first checks if
 * TX High Priority Buffer is empty. If yes, it then writes the given frame into
 * the Buffer. If not, this function returns immediately. This function does not
 * wait for the given frame being sent to CAN bus.
 *
 * @param	InstancePtr is a pointer to the XCanPs instance.
 * @param	FramePtr is a pointer to a 32-bit aligned buffer containing the
 *		CAN High Priority frame to be sent.
 *
 * @return
 *		- XST_SUCCESS if TX High Priority Buffer was not full and the
 *		given frame was written into the buffer.
 *		- XST_FIFO_NO_ROOM if there is no room in the TX High Priority
 *		Buffer for this frame.
 *
 * @note
 *
 * If the frame needs to be sent immediately and not delayed by processor's
 * interrupt handling, the caller should disable interrupt at processor
 * level before invoking this function.
 *
 ******************************************************************************/
 s32 XCanPs_SendHighPriority(XCanPs *InstancePtr, u32 *FramePtr)
 {
 	s32 Status;
 	Xil_AssertNonvoid(InstancePtr != NULL);
 	Xil_AssertNonvoid(FramePtr != NULL);
 	Xil_AssertNonvoid(InstancePtr->IsReady == XIL_COMPONENT_IS_READY);

 	if (XCanPs_IsHighPriorityBufFull(InstancePtr) == TRUE) {
 		Status = XST_FIFO_NO_ROOM;
 	} else {

 		/*
 		 * Write IDR, DLC, Data Word 1 and Data Word 2 to the CAN device.
 		 */
 		XCanPs_WriteReg(InstancePtr->CanConfig.BaseAddr,
 				XCANPS_TXHPB_ID_OFFSET, FramePtr[0]);
 		XCanPs_WriteReg(InstancePtr->CanConfig.BaseAddr,
 				XCANPS_TXHPB_DLC_OFFSET, FramePtr[1]);
 		XCanPs_WriteReg(InstancePtr->CanConfig.BaseAddr,
 				XCANPS_TXHPB_DW1_OFFSET, Xil_EndianSwap32(FramePtr[2]));
 		XCanPs_WriteReg(InstancePtr->CanConfig.BaseAddr,
 				XCANPS_TXHPB_DW2_OFFSET, Xil_EndianSwap32(FramePtr[3]));

 		Status = XST_SUCCESS;
 	}
 	return Status;
 }

 /*****************************************************************************/
 /**
 *
 * This routine enables individual acceptance filters. Up to 4 filters could
 * be enabled.
 *
 * @param	InstancePtr is a pointer to the XCanPs instance.
 * @param	FilterIndexes specifies which filter(s) to enable. Use
 *		any XCANPS_AFR_UAF*_MASK to enable one filter, and "Or"
 *		multiple XCANPS_AFR_UAF*_MASK values if multiple filters need
 *		to be enabled. Any filter not specified in this parameter will
 *		keep its previous enable/disable setting.
 *
 * @return	None.
 *
 * @note		None.
 *
 *
 ******************************************************************************/
 void XCanPs_AcceptFilterEnable(XCanPs *InstancePtr, u32 FilterIndexes)
 {
 	u32 EnabledFilters;

 	Xil_AssertVoid(InstancePtr != NULL);
 	Xil_AssertVoid(InstancePtr->IsReady == XIL_COMPONENT_IS_READY);

 	/*
 	 *  Calculate the new value and write to AFR.
 	 */
 	EnabledFilters =  XCanPs_ReadReg(InstancePtr->CanConfig.BaseAddr,
 						XCANPS_AFR_OFFSET);
 	EnabledFilters |= FilterIndexes;
 	EnabledFilters &= (u32)XCANPS_AFR_UAF_ALL_MASK;
 	XCanPs_WriteReg(InstancePtr->CanConfig.BaseAddr, XCANPS_AFR_OFFSET,
 			EnabledFilters);
 }

 /*****************************************************************************/
 /**
 *
 * This routine disables individual acceptance filters. Up to 4 filters could
 * be disabled. If all acceptance filters are disabled then all the received
 * frames are stored in the RX FIFO.
 *
 * @param	InstancePtr is a pointer to the XCanPs instance.
 * @param	FilterIndexes specifies which filter(s) to disable. Use
 *		any XCANPS_AFR_UAF*_MASK to disable one filter, and "Or"
 *		multiple XCANPS_AFR_UAF*_MASK values if multiple filters need
 * 		to be disabled. Any filter not specified in this parameter will
 *		keep its previous enable/disable setting. If all acceptance
 *		filters are disabled then all received frames are stored in the
 *		RX FIFO.
 *
 * @return	None.
 *
 * @note		None.
 *
 ******************************************************************************/
 void XCanPs_AcceptFilterDisable(XCanPs *InstancePtr, u32 FilterIndexes)
 {
 	u32 EnabledFilters;

 	Xil_AssertVoid(InstancePtr != NULL);
 	Xil_AssertVoid(InstancePtr->IsReady == XIL_COMPONENT_IS_READY);

 	/*
 	 *  Calculate the new value and write to AFR.
 	 */
 	EnabledFilters = XCanPs_ReadReg(InstancePtr->CanConfig.BaseAddr,
 					XCANPS_AFR_OFFSET);
 	EnabledFilters &= (u32)XCANPS_AFR_UAF_ALL_MASK & (~FilterIndexes);
 	XCanPs_WriteReg(InstancePtr->CanConfig.BaseAddr, XCANPS_AFR_OFFSET,
 			   EnabledFilters);
 }

 /*****************************************************************************/
 /**
 *
 * This function returns enabled acceptance filters. Use XCANPS_AFR_UAF*_MASK
 * defined in xcanps_hw.h to interpret the returned value. If no acceptance
 * filters are enabled then all received frames are stored in the RX FIFO.
 *
 * @param	InstancePtr is a pointer to the XCanPs instance.
 *
 * @return	The value stored in Acceptance Filter Register.
 *
 * @note		None.
 *
 *
 ******************************************************************************/
 u32 XCanPs_AcceptFilterGetEnabled(XCanPs *InstancePtr)
 {

 	Xil_AssertNonvoid(InstancePtr != NULL);
 	Xil_AssertNonvoid(InstancePtr->IsReady == XIL_COMPONENT_IS_READY);

 	return XCanPs_ReadReg(InstancePtr->CanConfig.BaseAddr,
 				XCANPS_AFR_OFFSET);

 }

 /*****************************************************************************/
 /**
 *
 * This function sets values to the Acceptance Filter Mask Register (AFMR) and
 * Acceptance Filter ID Register (AFIR) for the specified Acceptance Filter.
 * Use XCANPS_IDR_* defined in xcanps_hw.h to create the values to set the
 * filter. Read the xcanps.h file and device specification for details.
 *
 * This function should be called only after:
 *   - The given filter is disabled by calling XCanPs_AcceptFilterDisable()
 *   - And the CAN device is ready to accept writes to AFMR and AFIR, i.e.,
 *	 XCanPs_IsAcceptFilterBusy() returns FALSE.
 *
 * @param	InstancePtr is a pointer to the XCanPs instance.
 * @param	FilterIndex defines which Acceptance Filter Mask and ID Register
 *		to set. Use any single XCANPS_AFR_UAF*_MASK value.
 * @param	MaskValue is the value to write to the chosen Acceptance Filter
 *		Mask Register.
 * @param	IdValue is the value to write to the chosen Acceptance Filter
 *		ID Register.
 *
 * @return
 *		- XST_SUCCESS if the values were set successfully.
 *		- XST_FAILURE if the given filter was not disabled, or the CAN
 *		device was not ready to accept writes to AFMR and AFIR.
 *
 * @note		None.
 *
 ******************************************************************************/
 s32 XCanPs_AcceptFilterSet(XCanPs *InstancePtr, u32 FilterIndex,
 			 u32 MaskValue, u32 IdValue)
 {
 	u32 EnabledFilters;
 	s32 Status;

 	Xil_AssertNonvoid(InstancePtr != NULL);
 	Xil_AssertNonvoid(InstancePtr->IsReady == XIL_COMPONENT_IS_READY);
 	Xil_AssertNonvoid((FilterIndex == XCANPS_AFR_UAF4_MASK) ||
 			(FilterIndex == XCANPS_AFR_UAF3_MASK) ||
 			(FilterIndex == XCANPS_AFR_UAF2_MASK) ||
 			(FilterIndex == XCANPS_AFR_UAF1_MASK));

 	/*
 	 * Return an error if the given filter is currently enabled.
 	 */
 	EnabledFilters = XCanPs_AcceptFilterGetEnabled(InstancePtr);
 	if ((EnabledFilters & FilterIndex) == FilterIndex) {
 		Status = XST_FAILURE;
 	} else {

 		/*
 		 * If the CAN device is not ready to accept writes to AFMR and AFIR,
 		 * return error code.
 		 */
 		if (XCanPs_IsAcceptFilterBusy(InstancePtr) == TRUE) {
 			Status = XST_FAILURE;
 		} else {

 			/*
 			 * Write to the AFMR and AFIR of the specified filter.
 			 */
 			switch (FilterIndex) {
 				case XCANPS_AFR_UAF1_MASK:	/* Acceptance Filter No. 1 */

 					XCanPs_WriteReg(InstancePtr->CanConfig.BaseAddr,
 							XCANPS_AFMR1_OFFSET, MaskValue);
 					XCanPs_WriteReg(InstancePtr->CanConfig.BaseAddr,
 							XCANPS_AFIR1_OFFSET, IdValue);
 					break;

 				case XCANPS_AFR_UAF2_MASK:	/* Acceptance Filter No. 2 */
 					XCanPs_WriteReg(InstancePtr->CanConfig.BaseAddr,
 							XCANPS_AFMR2_OFFSET, MaskValue);
 					XCanPs_WriteReg(InstancePtr->CanConfig.BaseAddr,
 							XCANPS_AFIR2_OFFSET, IdValue);
 					break;

 				case XCANPS_AFR_UAF3_MASK:	/* Acceptance Filter No. 3 */
 					XCanPs_WriteReg(InstancePtr->CanConfig.BaseAddr,
 							XCANPS_AFMR3_OFFSET, MaskValue);
 					XCanPs_WriteReg(InstancePtr->CanConfig.BaseAddr,
 							XCANPS_AFIR3_OFFSET, IdValue);
 					break;

 				case XCANPS_AFR_UAF4_MASK:	/* Acceptance Filter No. 4 */
 					XCanPs_WriteReg(InstancePtr->CanConfig.BaseAddr,
 							XCANPS_AFMR4_OFFSET, MaskValue);
 					XCanPs_WriteReg(InstancePtr->CanConfig.BaseAddr,
 							XCANPS_AFIR4_OFFSET, IdValue);
 					break;

 				default:
 					/*This default was made for misra-c compliance*/
 					break;
 			}

 			Status = XST_SUCCESS;
 		}
 	}
 	return Status;
 }

 /*****************************************************************************/
 /**
 *
 * This function reads the values of the Acceptance Filter Mask and ID Register
 * for the specified Acceptance Filter. Use XCANPS_IDR_* defined in xcanps_hw.h
 * to interpret the values. Read the xcanps.h file and device specification for
 * details.
 *
 * @param	InstancePtr is a pointer to the XCanPs instance.
 * @param	FilterIndex defines which Acceptance Filter Mask Register to get
 *		Mask and ID from. Use any single XCANPS_FILTER_* value.
 * @param	MaskValue is a pointer to the data in which the Mask value read
 *		from the chosen Acceptance Filter Mask Register is returned.
 * @param	IdValue is a pointer to the data in which the ID value read
 *		from the chosen Acceptance Filter ID Register is returned.
 *
 * @return	None.
 *
 * @note		None.
 *
 ******************************************************************************/
 void XCanPs_AcceptFilterGet(XCanPs *InstancePtr, u32 FilterIndex,
 			  u32 *MaskValue, u32 *IdValue)
 {
 	Xil_AssertVoid(InstancePtr != NULL);
 	Xil_AssertVoid(InstancePtr->IsReady == XIL_COMPONENT_IS_READY);
 	Xil_AssertVoid((FilterIndex == XCANPS_AFR_UAF4_MASK) ||
 			 (FilterIndex == XCANPS_AFR_UAF3_MASK) ||
 			 (FilterIndex == XCANPS_AFR_UAF2_MASK) ||
 			 (FilterIndex == XCANPS_AFR_UAF1_MASK));
 	Xil_AssertVoid(MaskValue != NULL);
 	Xil_AssertVoid(IdValue != NULL);

 	/*
 	 * Read from the AFMR and AFIR of the specified filter.
 	 */
 	switch (FilterIndex) {
 		case XCANPS_AFR_UAF1_MASK:	/* Acceptance Filter No. 1 */
 			*MaskValue = XCanPs_ReadReg(InstancePtr->CanConfig.BaseAddr,
 						  XCANPS_AFMR1_OFFSET);
 			*IdValue = XCanPs_ReadReg(InstancePtr->CanConfig.BaseAddr,
 						  XCANPS_AFIR1_OFFSET);
 			break;

 		case XCANPS_AFR_UAF2_MASK:	/* Acceptance Filter No. 2 */
 			*MaskValue = XCanPs_ReadReg(InstancePtr->CanConfig.BaseAddr,
 						  XCANPS_AFMR2_OFFSET);
 			*IdValue = XCanPs_ReadReg(InstancePtr->CanConfig.BaseAddr,
 						  XCANPS_AFIR2_OFFSET);
 			break;

 		case XCANPS_AFR_UAF3_MASK:	/* Acceptance Filter No. 3 */
 			*MaskValue = XCanPs_ReadReg(InstancePtr->CanConfig.BaseAddr,
 						  XCANPS_AFMR3_OFFSET);
 			*IdValue = XCanPs_ReadReg(InstancePtr->CanConfig.BaseAddr,
 						  XCANPS_AFIR3_OFFSET);
 			break;

 		case XCANPS_AFR_UAF4_MASK:	/* Acceptance Filter No. 4 */
 			*MaskValue = XCanPs_ReadReg(InstancePtr->CanConfig.BaseAddr,
 						  XCANPS_AFMR4_OFFSET);
 			*IdValue = XCanPs_ReadReg(InstancePtr->CanConfig.BaseAddr,
 						  XCANPS_AFIR4_OFFSET);
 			break;

 		default:
 			/*This default was made for misra-c compliance*/
 			break;
 	}
 }

 /*****************************************************************************/
 /**
 *
 * This routine sets Baud Rate Prescaler value. The system clock for the CAN
 * controller is divided by (Prescaler + 1) to generate the quantum clock
 * needed for sampling and synchronization. Read the device specification
 * for details.
 *
 * Baud Rate Prescaler can be set only if the CAN device is in Configuration
 * Mode. Call XCanPs_EnterMode() to enter Configuration Mode before using this
 * function.
 *
 * @param	InstancePtr is a pointer to the XCanPs instance.
 * @param	Prescaler is the value to set. Valid values are from 0 to 255.
 *
 * @return
 *		- XST_SUCCESS if the Baud Rate Prescaler value is set
 *		successfully.
 *		- XST_FAILURE if CAN device is not in Configuration Mode.
 *
 * @note		None.
 *
 ******************************************************************************/
 s32 XCanPs_SetBaudRatePrescaler(XCanPs *InstancePtr, u8 Prescaler)
 {
 	s32 Status;
 	Xil_AssertNonvoid(InstancePtr != NULL);
 	Xil_AssertNonvoid(InstancePtr->IsReady == XIL_COMPONENT_IS_READY);

 	if (XCanPs_GetMode(InstancePtr) != (u8)XCANPS_MODE_CONFIG) {
 		Status = XST_FAILURE;
 	} else {

 		XCanPs_WriteReg(InstancePtr->CanConfig.BaseAddr, XCANPS_BRPR_OFFSET,
 					(u32)Prescaler);

 		Status = XST_SUCCESS;
 	}
 	return Status;
 }

 /*****************************************************************************/
 /**
 *
 * This routine gets Baud Rate Prescaler value. The system clock for the CAN
 * controller is divided by (Prescaler + 1) to generate the quantum clock
 * needed for sampling and synchronization. Read the device specification for
 * details.
 *
 * @param	InstancePtr is a pointer to the XCanPs instance.
 *
 * @return	Current used Baud Rate Prescaler value. The value's range is
 *		from 0 to 255.
 *
 * @note		None.
 *
 ******************************************************************************/
 u8 XCanPs_GetBaudRatePrescaler(XCanPs *InstancePtr)
 {
 	u32 ReadValue;
 	Xil_AssertNonvoid(InstancePtr != NULL);
 	Xil_AssertNonvoid(InstancePtr->IsReady == XIL_COMPONENT_IS_READY);

 	ReadValue = XCanPs_ReadReg(InstancePtr->CanConfig.BaseAddr,
 					XCANPS_BRPR_OFFSET);
 	return ((u8)ReadValue);
 }

 /*****************************************************************************/
 /**
 *
 * This routine sets Bit time. Time segment 1, Time segment 2 and
 * Synchronization Jump Width are set in this function. Device specification
 * requires the values passed into this function be one less than the actual
 * values of these fields. Read the device specification for details.
 *
 * Bit time can be set only if the CAN device is in Configuration Mode.
 * Call XCanPs_EnterMode() to enter Configuration Mode before using this
 * function.
 *
 * @param	InstancePtr is a pointer to the XCanPs instance.
 * @param	SyncJumpWidth is the Synchronization Jump Width value to set.
 *		Valid values are from 0 to 3.
 * @param	TimeSegment2 is the Time Segment 2 value to set. Valid values
 *		are from 0 to 7.
 * @param	TimeSegment1 is the Time Segment 1 value to set. Valid values
 *		are from 0 to 15.
 *
 * @return
 *		- XST_SUCCESS if the Bit time is set successfully.
 *		- XST_FAILURE if CAN device is not in Configuration Mode.
 *
 * @note		None.
 *
 ******************************************************************************/
 s32 XCanPs_SetBitTiming(XCanPs *InstancePtr, u8 SyncJumpWidth,
 			  u8 TimeSegment2, u8 TimeSegment1)
 {
 	u32 Value;
 	s32 Status;

 	Xil_AssertNonvoid(InstancePtr != NULL);
 	Xil_AssertNonvoid(InstancePtr->IsReady == XIL_COMPONENT_IS_READY);
 	Xil_AssertNonvoid(SyncJumpWidth <= (u8)3U);
 	Xil_AssertNonvoid(TimeSegment2 <= (u8)7U);
 	Xil_AssertNonvoid(TimeSegment1 <= (u8)15U );

 	if (XCanPs_GetMode(InstancePtr) != (u8)XCANPS_MODE_CONFIG) {
 		Status = XST_FAILURE;
 	} else {

 		Value = ((u32) TimeSegment1) & XCANPS_BTR_TS1_MASK;
 		Value |= (((u32) TimeSegment2) << XCANPS_BTR_TS2_SHIFT) &
 			XCANPS_BTR_TS2_MASK;
 		Value |= (((u32) SyncJumpWidth) << XCANPS_BTR_SJW_SHIFT) &
 			XCANPS_BTR_SJW_MASK;

 		XCanPs_WriteReg(InstancePtr->CanConfig.BaseAddr,
 				XCANPS_BTR_OFFSET, Value);

 		Status = XST_SUCCESS;
 	}
 	return Status;
 }

 /*****************************************************************************/
 /**
 *
 * This routine gets Bit time. Time segment 1, Time segment 2 and
 * Synchronization Jump Width values are read in this function. According to
 * device specification, the actual value of each of these fields is one
 * more than the value read. Read the device specification for details.
 *
 * @param	InstancePtr is a pointer to the XCanPs instance.
 * @param	SyncJumpWidth will store the Synchronization Jump Width value
 *		after this function returns. Its value ranges from 0 to 3.
 * @param	TimeSegment2 will store the Time Segment 2 value after this
 *		function returns. Its value ranges from 0 to 7.
 * @param	TimeSegment1 will store the Time Segment 1 value after this
 *		function returns. Its value ranges from 0 to 15.
 *
 * @return	None.
 *
 * @note		None.
 *
 ******************************************************************************/
 void XCanPs_GetBitTiming(XCanPs *InstancePtr, u8 *SyncJumpWidth,
 			   u8 *TimeSegment2, u8 *TimeSegment1)
 {
 	u32 Value;

 	Xil_AssertVoid(InstancePtr != NULL);
 	Xil_AssertVoid(InstancePtr->IsReady == XIL_COMPONENT_IS_READY);
 	Xil_AssertVoid(SyncJumpWidth != NULL);
 	Xil_AssertVoid(TimeSegment2 != NULL);
 	Xil_AssertVoid(TimeSegment1 != NULL);

 	Value = XCanPs_ReadReg(InstancePtr->CanConfig.BaseAddr,
 				XCANPS_BTR_OFFSET);

 	*TimeSegment1 = (u8) (Value & XCANPS_BTR_TS1_MASK);
 	*TimeSegment2 =
 		(u8) ((Value & XCANPS_BTR_TS2_MASK) >> XCANPS_BTR_TS2_SHIFT);
 	*SyncJumpWidth =
 		(u8) ((Value & XCANPS_BTR_SJW_MASK) >> XCANPS_BTR_SJW_SHIFT);
 }


 /****************************************************************************/
 /**
 *
 * This routine sets the Rx Full threshold in the Watermark Interrupt Register.
 *
 * @param	InstancePtr is a pointer to the XCanPs instance.
 * @param	Threshold is the threshold to be set. The valid values are
 *		from 1 to 63.
 *
 * @return
 *		- XST_FAILURE - If the CAN device is not in Configuration Mode.
 *		- XST_SUCCESS - If the Rx Full threshold is set in Watermark
 *		Interrupt Register.
 *
 * @note		The threshold can only be set when the CAN device is in the
 *		configuration mode.
 *
 *****************************************************************************/
 s32 XCanPs_SetRxIntrWatermark(XCanPs *InstancePtr, u8 Threshold)
 {

 	u32 ThrReg;
 	s32 Status;
 	Xil_AssertNonvoid(InstancePtr != NULL);
 	Xil_AssertNonvoid(InstancePtr->IsReady == XIL_COMPONENT_IS_READY);
 	Xil_AssertNonvoid(Threshold <= (u8)63);

 	if (XCanPs_GetMode(InstancePtr) != (u8)XCANPS_MODE_CONFIG) {
 		Status = XST_FAILURE;
 	} else {

 		ThrReg = XCanPs_ReadReg(InstancePtr->CanConfig.BaseAddr,
 				XCANPS_WIR_OFFSET);

 		ThrReg &= XCANPS_WIR_EW_MASK;
 		ThrReg |= ((u32)Threshold & XCANPS_WIR_FW_MASK);
 		XCanPs_WriteReg(InstancePtr->CanConfig.BaseAddr,
 				XCANPS_WIR_OFFSET, ThrReg);

 		Status = XST_SUCCESS;
 	}
 	return Status;
 }

 /****************************************************************************/
 /**
 *
 * This routine gets the Rx Full threshold from the Watermark Interrupt Register.
 *
 * @param	InstancePtr is a pointer to the XCanPs instance.
 *
 * @return	The Rx FIFO full watermark threshold value. The valid values
 *		are 1 to 63.
 *
 * @note		None.
 *
 *****************************************************************************/
 u8 XCanPs_GetRxIntrWatermark(XCanPs *InstancePtr)
 {

 	Xil_AssertNonvoid(InstancePtr != NULL);
 	Xil_AssertNonvoid(InstancePtr->IsReady == XIL_COMPONENT_IS_READY);


 	return (u8) (XCanPs_ReadReg(InstancePtr->CanConfig.BaseAddr,
 					XCANPS_WIR_OFFSET) &
 					XCANPS_WIR_FW_MASK);
 }


 /****************************************************************************/
 /**
 *
 * This routine sets the Tx Empty Threshold in the Watermark Interrupt Register.
 *
 * @param	InstancePtr is a pointer to the XCanPs instance.
 * @param	Threshold is the threshold to be set. The valid values are
 *		from 1 to 63.
 *
 * @return
 *		- XST_FAILURE - If the CAN device is not in Configuration Mode.
 *		- XST_SUCCESS - If the threshold is set in Watermark
 *		Interrupt Register.
 *
 * @note		The threshold can only be set when the CAN device is in the
 *		configuration mode.
 *
 *****************************************************************************/
 s32 XCanPs_SetTxIntrWatermark(XCanPs *InstancePtr, u8 Threshold)
 {
 	u32 ThrReg;
 	s32 Status;
 	Xil_AssertNonvoid(InstancePtr != NULL);
 	Xil_AssertNonvoid(InstancePtr->IsReady == XIL_COMPONENT_IS_READY);
 	Xil_AssertNonvoid(Threshold <= (u8)63);

 	if (XCanPs_GetMode(InstancePtr) != (u8)XCANPS_MODE_CONFIG) {
 		Status = XST_FAILURE;
 	} else {

 		ThrReg = XCanPs_ReadReg(InstancePtr->CanConfig.BaseAddr,
 				XCANPS_WIR_OFFSET);

 		ThrReg &= XCANPS_WIR_FW_MASK;
 		ThrReg |= (((u32)Threshold << XCANPS_WIR_EW_SHIFT)
 				& XCANPS_WIR_EW_MASK);
 		XCanPs_WriteReg(InstancePtr->CanConfig.BaseAddr,
 				XCANPS_WIR_OFFSET, ThrReg);

 		Status = XST_SUCCESS;
 	}
 	return Status;
 }

 /****************************************************************************/
 /**
 *
 * This routine gets the Tx Empty threshold from Watermark Interrupt Register.
 *
 * @param	InstancePtr is a pointer to the XCanPs instance.
 *
 * @return	The Tx Empty FIFO threshold value. The valid values are 1 to 63.
 *
 * @note		None.
 *
 *****************************************************************************/
 u8 XCanPs_GetTxIntrWatermark(XCanPs *InstancePtr)
 {

 	Xil_AssertNonvoid(InstancePtr != NULL);
 	Xil_AssertNonvoid(InstancePtr->IsReady == XIL_COMPONENT_IS_READY);


 	return (u8) ((XCanPs_ReadReg(InstancePtr->CanConfig.BaseAddr,
 				XCANPS_WIR_OFFSET) & XCANPS_WIR_EW_MASK) >>
 					XCANPS_WIR_EW_SHIFT);
 }


 /******************************************************************************/
 /*
  * This routine is a stub for the asynchronous callbacks. The stub is here in
  * case the upper layer forgot to set the handler(s). On initialization, all
  * handlers are set to this callback. It is considered an error for this handler
  * to be invoked.
  *
  ******************************************************************************/
 static void StubHandler(void)
 {
 	Xil_AssertVoidAlways();
 }
 /** @} */