コード例 #1
0
ファイル: qspi.c プロジェクト: IngenicC/cloud-rtr
/**
*
* This function initializes the controller for the QSPI interface.
*
* @param	None
*
* @return	None
*
* @note		None
*
****************************************************************************/
u32 InitQspi(void)
{
	XQspiPs_Config *QspiConfig;
	int Status;

	QspiInstancePtr = &QspiInstance;

	/*
	 * Set up the base address for access
	 */
	FlashReadBaseAddress = XPS_QSPI_LINEAR_BASEADDR;

	/*
	 * Initialize the QSPI driver so that it's ready to use
	 */
	QspiConfig = XQspiPs_LookupConfig(QSPI_DEVICE_ID);
	if (NULL == QspiConfig) {
		return XST_FAILURE;
	}

	Status = XQspiPs_CfgInitialize(QspiInstancePtr, QspiConfig,
					QspiConfig->BaseAddress);
	if (Status != XST_SUCCESS) {
		return XST_FAILURE;
	}

	/*
	 * Set Manual Chip select options and drive HOLD_B pin high.
	 */
	XQspiPs_SetOptions(QspiInstancePtr, XQSPIPS_FORCE_SSELECT_OPTION |
			XQSPIPS_HOLD_B_DRIVE_OPTION);

	/*
	 * Set the prescaler for QSPI clock
	 */
	XQspiPs_SetClkPrescaler(QspiInstancePtr, XQSPIPS_CLK_PRESCALE_8);

	/*
	 * Assert the FLASH chip select.
	 */
	XQspiPs_SetSlaveSelect(QspiInstancePtr);

	/*
	 * Read Flash ID and extract Manufacture and Size information
	 */
	Status = FlashReadID();
	if (Status != XST_SUCCESS) {
		return XST_FAILURE;
	}

	if (XPAR_PS7_QSPI_0_QSPI_MODE == SINGLE_FLASH_CONNECTION) {

		fsbl_printf(DEBUG_INFO,"QSPI is in single flash connection\r\n");
		/*
		 * For Flash size <128Mbit controller configured in linear mode
		 */
		if (QspiFlashSize <= FLASH_SIZE_16MB) {
			LinearBootDeviceFlag = 1;

			/*
			 * Enable linear mode
			 */
			XQspiPs_SetOptions(QspiInstancePtr,  XQSPIPS_LQSPI_MODE_OPTION |
					XQSPIPS_HOLD_B_DRIVE_OPTION);

			/*
			 * Single linear read
			 */
			XQspiPs_SetLqspiConfigReg(QspiInstancePtr, SINGLE_QSPI_CONFIG_QUAD_READ);

			/*
			 * Enable the controller
			 */
			XQspiPs_Enable(QspiInstancePtr);
		} else {
			/*
			 * Single flash IO read
			 */
			XQspiPs_SetLqspiConfigReg(QspiInstancePtr, SINGLE_QSPI_IO_CONFIG_QUAD_READ);

			/*
			 * Enable the controller
			 */
			XQspiPs_Enable(QspiInstancePtr);
		}
	}

	if (XPAR_PS7_QSPI_0_QSPI_MODE == DUAL_PARALLEL_CONNECTION) {

		fsbl_printf(DEBUG_INFO,"QSPI is in Dual Parallel connection\r\n");
		/*
		 * For Single Flash size <128Mbit controller configured in linear mode
		 */
		if (QspiFlashSize <= FLASH_SIZE_16MB) {
			/*
			 * Setting linear access flag
			 */
			LinearBootDeviceFlag = 1;

			/*
			 * Enable linear mode
			 */
			XQspiPs_SetOptions(QspiInstancePtr,  XQSPIPS_LQSPI_MODE_OPTION |
					XQSPIPS_HOLD_B_DRIVE_OPTION);

			/*
			 * Dual linear read
			 */
			XQspiPs_SetLqspiConfigReg(QspiInstancePtr, DUAL_QSPI_CONFIG_QUAD_READ);

			/*
			 * Enable the controller
			 */
			XQspiPs_Enable(QspiInstancePtr);
		} else {
			/*
			 * Dual flash IO read
			 */
			XQspiPs_SetLqspiConfigReg(QspiInstancePtr, DUAL_QSPI_IO_CONFIG_QUAD_READ);

			/*
			 * Enable the controller
			 */
			XQspiPs_Enable(QspiInstancePtr);

		}

		/*
		 * Total flash size is two time of single flash size
		 */
		QspiFlashSize = 2 * QspiFlashSize;
	}

	/*
	 * It is expected to same flash size for both chip selection
	 */
	if (XPAR_PS7_QSPI_0_QSPI_MODE == DUAL_STACK_CONNECTION) {

		fsbl_printf(DEBUG_INFO,"QSPI is in Dual Stack connection\r\n");

		QspiFlashSize = 2 * QspiFlashSize;

		/*
		 * Enable two flash memories on separate buses
		 */
		XQspiPs_SetLqspiConfigReg(QspiInstancePtr, DUAL_STACK_CONFIG_READ);
	}

	return XST_SUCCESS;
}
コード例 #2
0
/*****************************************************************************
*
* The purpose of this function is to illustrate how to use the XQspiPs
* device driver in single, parallel and stacked modes using
* flash devices greater than 128Mb.
* This function reads and writes data in I/O mode.
*
* @param	None.
*
* @return	XST_SUCCESS if successful, else XST_FAILURE.
*
* @note		None.
*
*****************************************************************************/
int QspiG128FlashExample(XQspiPs *QspiInstancePtr, u16 QspiDeviceId)
{
	int Status;
	u8 UniqueValue;
	int Count;
	int Page;
	XQspiPs_Config *QspiConfig;

	/*
	 * Initialize the QSPI driver so that it's ready to use
	 */
	QspiConfig = XQspiPs_LookupConfig(QspiDeviceId);
	if (NULL == QspiConfig) {
		return XST_FAILURE;
	}

	Status = XQspiPs_CfgInitialize(QspiInstancePtr, QspiConfig,
					QspiConfig->BaseAddress);
	if (Status != XST_SUCCESS) {
		return XST_FAILURE;
	}

	/*
	 * Perform a self-test to check hardware build
	 */
	Status = XQspiPs_SelfTest(QspiInstancePtr);
	if (Status != XST_SUCCESS) {
		return XST_FAILURE;
	}



	/*
	 * Set the pre-scaler for QSPI clock
	 */
	XQspiPs_SetClkPrescaler(QspiInstancePtr, XQSPIPS_CLK_PRESCALE_8);

	/*
	 * Set Manual Start and Manual Chip select options and drive the
	 * HOLD_B high.
	 */
	XQspiPs_SetOptions(QspiInstancePtr, XQSPIPS_FORCE_SSELECT_OPTION |
					     XQSPIPS_MANUAL_START_OPTION |
					     XQSPIPS_HOLD_B_DRIVE_OPTION);
	if(QspiConfig->ConnectionMode == XQSPIPS_CONNECTION_MODE_STACKED) {
		/*
		 * Enable two flash memories, Shared bus (NOT separate bus),
		 * L_PAGE selected by default
	 	 */
		XQspiPs_SetLqspiConfigReg(QspiInstancePtr, DUAL_STACK_CONFIG_WRITE);
	}

	if(QspiConfig->ConnectionMode == XQSPIPS_CONNECTION_MODE_PARALLEL) {
		/*
		 * Enable two flash memories on separate buses
		 */
		XQspiPs_SetLqspiConfigReg(QspiInstancePtr, DUAL_QSPI_CONFIG_WRITE);
	}

	/*
	 * Assert the Flash chip select.
	 */
	XQspiPs_SetSlaveSelect(QspiInstancePtr);

	/*
	 * Read flash ID and obtain all flash related information
	 * It is important to call the read id function before
	 * performing proceeding to any operation, including
	 * preparing the WriteBuffer
	 */
	FlashReadID(QspiInstancePtr, WriteBuffer, ReadBuffer);

	/*
	 * Initialize MaxData according to page size.
	 */
	MaxData = PAGE_COUNT * (Flash_Config_Table[FCTIndex].PageSize);


	/*
	 * Initialize the write buffer for a pattern to write to the Flash
	 * and the read buffer to zero so it can be verified after the read, the
	 * test value that is added to the unique value allows the value to be
	 * changed in a debug environment to guarantee
	 */
	for (UniqueValue = UNIQUE_VALUE, Count = 0;
			Count < Flash_Config_Table[FCTIndex].PageSize;
			Count++, UniqueValue++) {
		WriteBuffer[DATA_OFFSET + Count] = (u8)(UniqueValue + Test);
	}
	memset(ReadBuffer, 0x00, sizeof(ReadBuffer));


	/*
	 * Erase the flash.
	 */
	FlashErase(QspiInstancePtr, TEST_ADDRESS, MaxData, WriteBuffer);

	/*
	 * Write the data in the write buffer to the serial Flash a page at a
	 * time, starting from TEST_ADDRESS
	 */
	for (Page = 0; Page < PAGE_COUNT; Page++) {
		FlashWrite(QspiInstancePtr,
			(Page * Flash_Config_Table[FCTIndex].PageSize) + TEST_ADDRESS,
			Flash_Config_Table[FCTIndex].PageSize, WRITE_CMD, WriteBuffer);
	}

	/*
	 * I/O Read - for any flash size
	 */
	FlashRead(QspiInstancePtr, TEST_ADDRESS, MaxData, QUAD_READ_CMD,
				WriteBuffer, ReadBuffer);

	/*
	 * Setup a pointer to the start of the data that was read into the read
	 * buffer and verify the data read is the data that was written
	 */
	for (UniqueValue = UNIQUE_VALUE, Count = 0; Count < MaxData;
	     Count++, UniqueValue++) {
		if (ReadBuffer[Count] != (u8)(UniqueValue + Test)) {
			return XST_FAILURE;
		}
	}

	/*
	 * Initialize the write buffer for a pattern to write to the Flash
	 * and the read buffer to zero so it can be verified after the read, the
	 * test value that is added to the unique value allows the value to be
	 * changed in a debug environment to guarantee
	 */
	for (UniqueValue = UNIQUE_VALUE, Count = 0;
			Count < Flash_Config_Table[FCTIndex].PageSize;
			Count++, UniqueValue++) {
		WriteBuffer[DATA_OFFSET + Count] = (u8)(UniqueValue + Test);
	}
	memset(ReadBuffer, 0x00, sizeof(ReadBuffer));

	/*
	 * Set Auto Start and Manual Chip select options and drive the
	 * HOLD_B high.
	 */
	XQspiPs_SetOptions(QspiInstancePtr, XQSPIPS_FORCE_SSELECT_OPTION |
					     XQSPIPS_HOLD_B_DRIVE_OPTION);

	/*
	 * Erase the flash.
	 */
	FlashErase(QspiInstancePtr, TEST_ADDRESS, MaxData, WriteBuffer);

	/*
	 * Write the data in the write buffer to the serial Flash a page at a
	 * time, starting from TEST_ADDRESS
	 */
	for (Page = 0; Page < PAGE_COUNT; Page++) {
		FlashWrite(QspiInstancePtr,
			(Page * Flash_Config_Table[FCTIndex].PageSize) + TEST_ADDRESS,
			Flash_Config_Table[FCTIndex].PageSize, WRITE_CMD, WriteBuffer);
	}

	/*
	 * I/O Read - for any flash size
	 */
	FlashRead(QspiInstancePtr, TEST_ADDRESS, MaxData, QUAD_READ_CMD,
				WriteBuffer, ReadBuffer);

	/*
	 * Setup a pointer to the start of the data that was read into the read
	 * buffer and verify the data read is the data that was written
	 */
	for (UniqueValue = UNIQUE_VALUE, Count = 0; Count < MaxData;
	     Count++, UniqueValue++) {
		if (ReadBuffer[Count] != (u8)(UniqueValue + Test)) {
			return XST_FAILURE;
		}
	}

	return XST_SUCCESS;
}
コード例 #3
0
/*****************************************************************************
*
* The purpose of this function is to illustrate how to use the XQspiPs
* device driver in Linear mode. This function writes data to the serial
* FLASH in QSPI mode and reads data in Linear QSPI mode.
*
* @param	None.
*
* @return	XST_SUCCESS if successful, else XST_FAILURE.
*
* @note		None.
*
*****************************************************************************/
int LinearQspiFlashExample(XQspiPs *QspiInstancePtr, u16 QspiDeviceId)
{
	int Status;
	u8 UniqueValue;
	int Count;
	int Page;
	XQspiPs_Config *QspiConfig;

	/*
	 * Initialize the QSPI driver so that it's ready to use
	 */
	QspiConfig = XQspiPs_LookupConfig(QspiDeviceId);
	if (NULL == QspiConfig) {
		return XST_FAILURE;
	}

	Status = XQspiPs_CfgInitialize(QspiInstancePtr, QspiConfig,
					QspiConfig->BaseAddress);
	if (Status != XST_SUCCESS) {
		return XST_FAILURE;
	}

	/*
	 * Perform a self-test to check hardware build
	 */
	Status = XQspiPs_SelfTest(QspiInstancePtr);
	if (Status != XST_SUCCESS) {
		return XST_FAILURE;
	}

	/*
	 * Enable two flash memories on seperate buses
	 */
	XQspiPs_SetLqspiConfigReg(QspiInstancePtr, DUAL_QSPI_CONFIG_WRITE);

	/*
	 * Set the QSPI device as a master and enable manual CS, manual start
	 * and flash interface mode options and drive HOLD_B pin high.
	 */
	XQspiPs_SetOptions(QspiInstancePtr,  XQSPIPS_FORCE_SSELECT_OPTION |
					    XQSPIPS_MANUAL_START_OPTION |
					    XQSPIPS_HOLD_B_DRIVE_OPTION);

	XQspiPs_SetClkPrescaler(QspiInstancePtr, XQSPIPS_CLK_PRESCALE_8);

	/*
	 * Initialize the write buffer for a pattern to write to the FLASH
	 * and the read buffer to zero so it can be verified after the read, the
	 * test value that is added to the unique value allows the value to be
	 * changed in a debug environment to guarantee
	 */
	for (UniqueValue = UNIQUE_VALUE, Count = 0; Count < PAGE_SIZE;
	     Count++, UniqueValue++) {
		WriteBuffer[DATA_OFFSET + Count] = (u8)(UniqueValue + Test);
	}
	memset(ReadBuffer, 0x00, sizeof(ReadBuffer));

	/*
	 * Assert the FLASH chip select.
	 */
	XQspiPs_SetSlaveSelect(QspiInstancePtr);

	/*
	 * Erase the flash sectors
	 */
	FlashErase(QspiInstancePtr, TEST_ADDRESS, MAX_DATA);

	/*
	 * Write data to the two flash memories on seperate buses, starting from
	 * TEST_ADDRESS. This is same as writing to a single flash memory. The
	 * LQSPI controller takes care of splitting the data words and writing
	 * them to the two flash memories. The user needs to take care of the
	 * address translation
	 */
	for (Page = 0; Page < PAGE_COUNT; Page++) {
		FlashWrite(QspiInstancePtr, ((Page * PAGE_SIZE) +
			   TEST_ADDRESS) / 2, PAGE_SIZE, WRITE_CMD);
	}

	/*
	 * Read from the two flash memories on seperate buses in LQSPI mode.
	 */
	XQspiPs_SetOptions(QspiInstancePtr,  XQSPIPS_LQSPI_MODE_OPTION |
					     XQSPIPS_HOLD_B_DRIVE_OPTION);
	XQspiPs_SetLqspiConfigReg(QspiInstancePtr, DUAL_QSPI_CONFIG_QUAD_READ);

	Status = XQspiPs_LqspiRead(QspiInstancePtr, ReadBuffer, TEST_ADDRESS,
				   MAX_DATA);
	if (Status != XST_SUCCESS) {
		return XST_FAILURE;
	}

	/*
	 * Setup a pointer to the start of the data that was read into the read
	 * buffer and verify the data read is the data that was written
	 */
	for (UniqueValue = UNIQUE_VALUE, Count = 0; Count < MAX_DATA;
	     Count++, UniqueValue++) {
		if (ReadBuffer[Count] != WriteBuffer[DATA_OFFSET +
						     (Count % PAGE_SIZE)]) {
			return XST_FAILURE;
		}
	}

	/*
	 * Set the QSPI device as a master and enable manual CS, manual start
	 * and flash interface mode options and drive HOLD_B pin high.
	 */
	XQspiPs_SetOptions(QspiInstancePtr,  XQSPIPS_FORCE_SSELECT_OPTION |
					    XQSPIPS_HOLD_B_DRIVE_OPTION);

	/*
	 * Initialize the write buffer for a pattern to write to the FLASH
	 * and the read buffer to zero so it can be verified after the read, the
	 * test value that is added to the unique value allows the value to be
	 * changed in a debug environment to guarantee
	 */
	for (UniqueValue = UNIQUE_VALUE, Count = 0; Count < PAGE_SIZE;
	     Count++, UniqueValue++) {
		WriteBuffer[DATA_OFFSET + Count] = (u8)(UniqueValue + Test);
	}
	memset(ReadBuffer, 0x00, sizeof(ReadBuffer));

	/*
	 * Erase the flash sectors
	 */
	FlashErase(QspiInstancePtr, TEST_ADDRESS, MAX_DATA);

	/*
	 * Write data to the two flash memories on seperate buses, starting from
	 * TEST_ADDRESS. This is same as writing to a single flash memory. The
	 * LQSPI controller takes care of splitting the data words and writing
	 * them to the two flash memories. The user needs to take care of the
	 * address translation
	 */
	for (Page = 0; Page < PAGE_COUNT; Page++) {
		FlashWrite(QspiInstancePtr, ((Page * PAGE_SIZE) +
			   TEST_ADDRESS) / 2, PAGE_SIZE, WRITE_CMD);
	}

	/*
	 * Read from the two flash memories on seperate buses in LQSPI mode.
	 */
	XQspiPs_SetOptions(QspiInstancePtr,  XQSPIPS_LQSPI_MODE_OPTION |
					     XQSPIPS_HOLD_B_DRIVE_OPTION);
	XQspiPs_SetLqspiConfigReg(QspiInstancePtr, DUAL_QSPI_CONFIG_QUAD_READ);

	Status = XQspiPs_LqspiRead(QspiInstancePtr, ReadBuffer, TEST_ADDRESS,
				   MAX_DATA);
	if (Status != XST_SUCCESS) {
		return XST_FAILURE;
	}

	/*
	 * Setup a pointer to the start of the data that was read into the read
	 * buffer and verify the data read is the data that was written
	 */
	for (UniqueValue = UNIQUE_VALUE, Count = 0; Count < MAX_DATA;
	     Count++, UniqueValue++) {
		if (ReadBuffer[Count] != WriteBuffer[DATA_OFFSET +
						     (Count % PAGE_SIZE)]) {
			return XST_FAILURE;
		}
	}

	return XST_SUCCESS;
}
コード例 #4
0
/*****************************************************************************
*
* The purpose of this function is to illustrate how to use the XQspiPs
* device driver in Linear mode. This function writes data to the serial
* FLASH in QSPI mode and reads data in Linear QSPI mode.
*
* @param	None.
*
* @return	XST_SUCCESS if successful, else XST_FAILURE.
*
* @note		None.
*
*****************************************************************************/
int LinearQspiFlashExample(XQspiPs *QspiInstancePtr, u16 QspiDeviceId)
{
	int Status;
	u8 UniqueValue;
	int Count;
	int Page;
	XQspiPs_Config *QspiConfig;

	/*
	 * Initialize the QSPI driver so that it's ready to use
	 */
	QspiConfig = XQspiPs_LookupConfig(QspiDeviceId);
	if (NULL == QspiConfig) {
		return XST_FAILURE;
	}

	Status = XQspiPs_CfgInitialize(QspiInstancePtr, QspiConfig,
					QspiConfig->BaseAddress);
	if (Status != XST_SUCCESS) {
		return XST_FAILURE;
	}

	/*
	 * Perform a self-test to check hardware build
	 */
	Status = XQspiPs_SelfTest(QspiInstancePtr);
	if (Status != XST_SUCCESS) {
		return XST_FAILURE;
	}

	/*
	 * Initialize the write buffer for a pattern to write to the FLASH
	 * and the read buffer to zero so it can be verified after the read, the
	 * test value that is added to the unique value allows the value to be
	 * changed in a debug environment to guarantee
	 */
	for (UniqueValue = UNIQUE_VALUE, Count = 0; Count < PAGE_SIZE;
	     Count++, UniqueValue++) {
		WriteBuffer[DATA_OFFSET + Count] = (u8)(UniqueValue + Test);
	}
	memset(ReadBuffer, 0x00, sizeof(ReadBuffer));

	/*
	 * Set the prescaler for QSPI clock
	 */
	XQspiPs_SetClkPrescaler(QspiInstancePtr, XQSPIPS_CLK_PRESCALE_8);

	/*
	 * Set Manual Start and Manual Chip select options and drive the
	 * HOLD_B high.
	 */
	XQspiPs_SetOptions(QspiInstancePtr, XQSPIPS_FORCE_SSELECT_OPTION |
					     XQSPIPS_MANUAL_START_OPTION |
					     XQSPIPS_HOLD_B_DRIVE_OPTION);

	/*
	 * Assert the FLASH chip select.
	 */
	XQspiPs_SetSlaveSelect(QspiInstancePtr);

	FlashReadID();

	/*
	 * Erase the flash.
	 */
	FlashErase(QspiInstancePtr, TEST_ADDRESS, MAX_DATA);

	/*
	 * Write the data in the write buffer to the serial FLASH a page at a
	 * time, starting from TEST_ADDRESS
	 */
	for (Page = 0; Page < PAGE_COUNT; Page++) {
		FlashWrite(QspiInstancePtr, (Page * PAGE_SIZE) + TEST_ADDRESS,
			   PAGE_SIZE, WRITE_CMD);
	}

	/*
	 * Read from the flash in LQSPI mode.
	 */
	XQspiPs_SetOptions(QspiInstancePtr, XQSPIPS_LQSPI_MODE_OPTION |
					     XQSPIPS_HOLD_B_DRIVE_OPTION);

	Status = XQspiPs_LqspiRead(QspiInstancePtr, ReadBuffer, TEST_ADDRESS,
				   MAX_DATA);
	if (Status != XST_SUCCESS) {
		return XST_FAILURE;
	}

	/*
	 * Setup a pointer to the start of the data that was read into the read
	 * buffer and verify the data read is the data that was written
	 */
	for (UniqueValue = UNIQUE_VALUE, Count = 0; Count < MAX_DATA;
	     Count++, UniqueValue++) {
		if (ReadBuffer[Count] != (u8)(UniqueValue + Test)) {
			return XST_FAILURE;
		}
	}

	/*
	 * Initialize the write buffer for a pattern to write to the FLASH
	 * and the read buffer to zero so it can be verified after the read, the
	 * test value that is added to the unique value allows the value to be
	 * changed in a debug environment to guarantee
	 */
	for (UniqueValue = UNIQUE_VALUE, Count = 0; Count < PAGE_SIZE;
	     Count++, UniqueValue++) {
		WriteBuffer[DATA_OFFSET + Count] = (u8)(UniqueValue + Test);
	}
	memset(ReadBuffer, 0x00, sizeof(ReadBuffer));

	/*
	 * Set Auto Start and Manual Chip select options and drive the
	 * HOLD_B high.
	 */
	XQspiPs_SetOptions(QspiInstancePtr, XQSPIPS_FORCE_SSELECT_OPTION |
					     XQSPIPS_HOLD_B_DRIVE_OPTION);

	/*
	 * Erase the flash.
	 */
	FlashErase(QspiInstancePtr, TEST_ADDRESS, MAX_DATA);

	/*
	 * Write the data in the write buffer to the serial FLASH a page at a
	 * time, starting from TEST_ADDRESS
	 */
	for (Page = 0; Page < PAGE_COUNT; Page++) {
		FlashWrite(QspiInstancePtr, (Page * PAGE_SIZE) + TEST_ADDRESS,
			   PAGE_SIZE, WRITE_CMD);
	}

	/*
	 * Read from the flash in LQSPI mode.
	 */
	XQspiPs_SetOptions(QspiInstancePtr, XQSPIPS_LQSPI_MODE_OPTION |
					     XQSPIPS_HOLD_B_DRIVE_OPTION);

	Status = XQspiPs_LqspiRead(QspiInstancePtr, ReadBuffer, TEST_ADDRESS,
				   MAX_DATA);
	if (Status != XST_SUCCESS) {
		return XST_FAILURE;
	}

	/*
	 * Setup a pointer to the start of the data that was read into the read
	 * buffer and verify the data read is the data that was written
	 */
	for (UniqueValue = UNIQUE_VALUE, Count = 0; Count < MAX_DATA;
	     Count++, UniqueValue++) {
		if (ReadBuffer[Count] != (u8)(UniqueValue + Test)) {
			return XST_FAILURE;
		}
	}

	return XST_SUCCESS;
}
コード例 #5
0
/*****************************************************************************
*
* The purpose of this function is to illustrate how to use the XQspiPs
* device driver in interrupt mode. This function writes and reads data
* from a serial FLASH.
*
* @param	None.
*
* @return	XST_SUCCESS if successful else XST_FAILURE.
*
* @note
*
* This function calls other functions which contain loops that may be infinite
* if interrupts are not working such that it may not return. If the device
* slave select is not correct and the device is not responding on bus it will
* read a status of 0xFF for the status register as the bus is pulled up.
*
*****************************************************************************/
int QspiFlashIntrExample(XScuGic *IntcInstancePtr, XQspiPs *QspiInstancePtr,
			 u16 QspiDeviceId, u16 QspiIntrId)
{
	int Status;
	u8 *BufferPtr;
	u8 UniqueValue;
	int Count;
	int Page;
	XQspiPs_Config *QspiConfig;

	/*
	 * Initialize the QSPI driver so that it's ready to use
	 */
	QspiConfig = XQspiPs_LookupConfig(QspiDeviceId);
	if (NULL == QspiConfig) {
		return XST_FAILURE;
	}

	Status = XQspiPs_CfgInitialize(QspiInstancePtr, QspiConfig,
					QspiConfig->BaseAddress);
	if (Status != XST_SUCCESS) {
		return XST_FAILURE;
	}

	/*
	 * Perform a self-test to check hardware build
	 */
	Status = XQspiPs_SelfTest(QspiInstancePtr);
	if (Status != XST_SUCCESS) {
		return XST_FAILURE;
	}

	/*
	 * Connect the Qspi device to the interrupt subsystem such that
	 * interrupts can occur. This function is application specific
	 */
	Status = QspiSetupIntrSystem(IntcInstancePtr, QspiInstancePtr,
				     QspiIntrId);
	if (Status != XST_SUCCESS) {
		return XST_FAILURE;
	}

	/*
	 * Setup the handler for the QSPI that will be called from the
	 * interrupt context when an QSPI status occurs, specify a pointer to
	 * the QSPI driver instance as the callback reference so the handler is
	 * able to access the instance data
	 */
	XQspiPs_SetStatusHandler(QspiInstancePtr, QspiInstancePtr,
				 (XQspiPs_StatusHandler) QspiHandler);

	/*
	 * Set Manual Start and Manual Chip select options and drive the
	 * HOLD_B high.
	 */
	XQspiPs_SetOptions(QspiInstancePtr, XQSPIPS_FORCE_SSELECT_OPTION |
				XQSPIPS_MANUAL_START_OPTION |
				XQSPIPS_HOLD_B_DRIVE_OPTION);

	/*
	 * Set the operating clock frequency using the clock divider
	 */
	XQspiPs_SetClkPrescaler(QspiInstancePtr, XQSPIPS_CLK_PRESCALE_8);

	/*
	 * Assert the FLASH chip select
	 */
	XQspiPs_SetSlaveSelect(QspiInstancePtr);

	/*
	 * Initialize the write buffer for a pattern to write to the FLASH
	 * and the read buffer to zero so it can be verified after the read, the
	 * test value that is added to the unique value allows the value to be
	 * changed in a debug environment to guarantee
	 */
	for (UniqueValue = UNIQUE_VALUE, Count = 0; Count < PAGE_SIZE;
	     Count++, UniqueValue++) {
		WriteBuffer[DATA_OFFSET + Count] = (u8)(UniqueValue + Test);
	}

	memset(ReadBuffer, 0x00, sizeof(ReadBuffer));

	FlashReadID();

	/*
	 * Erase the flash.
	 */
	FlashErase(QspiInstancePtr, TEST_ADDRESS, MAX_DATA);

	/*
	 * Write the data in the write buffer to the serial FLASH a page at a
	 * time, starting from TEST_ADDRESS
	 */
	for (Page = 0; Page < PAGE_COUNT; Page++) {
		FlashWrite(QspiInstancePtr, (Page * PAGE_SIZE) + TEST_ADDRESS,
			   PAGE_SIZE, WRITE_CMD);
	}

	/*
	 * Read the contents of the FLASH from TEST_ADDRESS, using Normal Read
	 * command.
	 */
	FlashRead(QspiInstancePtr, TEST_ADDRESS, MAX_DATA, READ_CMD);

	/*
	 * Setup a pointer to the start of the data that was read into the read
	 * buffer and verify the data read is the data that was written
	 */
	BufferPtr = &ReadBuffer[DATA_OFFSET];

	for (UniqueValue = UNIQUE_VALUE, Count = 0; Count < MAX_DATA;
	     Count++, UniqueValue++) {
		if (BufferPtr[Count] != (u8)(UniqueValue + Test)) {
			return XST_FAILURE;
		}
	}

	/*
	 * Read the contents of the FLASH from TEST_ADDRESS, using Fast Read
	 * command
	 */
	memset(ReadBuffer, 0x00, sizeof(ReadBuffer));
	FlashRead(QspiInstancePtr, TEST_ADDRESS, MAX_DATA, FAST_READ_CMD);

	/*
	 * Setup a pointer to the start of the data that was read into the read
	 * buffer and verify the data read is the data that was written
	 */
	BufferPtr = &ReadBuffer[DATA_OFFSET + DUMMY_SIZE];
	for (UniqueValue = UNIQUE_VALUE, Count = 0; Count < MAX_DATA;
	     Count++, UniqueValue++) {
		if (BufferPtr[Count] != (u8)(UniqueValue + Test)) {
			return XST_FAILURE;
		}
	}

	/*
	 * Read the contents of the FLASH from TEST_ADDRESS, using Dual Read
	 * command
	 */
	memset(ReadBuffer, 0x00, sizeof(ReadBuffer));
	FlashRead(QspiInstancePtr, TEST_ADDRESS, MAX_DATA, DUAL_READ_CMD);

	/*
	 * Setup a pointer to the start of the data that was read into the read
	 * buffer and verify the data read is the data that was written
	 */
	BufferPtr = &ReadBuffer[DATA_OFFSET + DUMMY_SIZE];

	for (UniqueValue = UNIQUE_VALUE, Count = 0; Count < MAX_DATA;
	     Count++, UniqueValue++) {
		if (BufferPtr[Count] != (u8)(UniqueValue + Test)) {
			return XST_FAILURE;
		}
	}

	/*
	 * Read the contents of the FLASH from TEST_ADDRESS, using Quad Read
	 * command
	 */
	memset(ReadBuffer, 0x00, sizeof(ReadBuffer));
	FlashRead(QspiInstancePtr, TEST_ADDRESS, MAX_DATA, QUAD_READ_CMD);

	/*
	 * Setup a pointer to the start of the data that was read into the read
	 * buffer and verify the data read is the data that was written
	 */
	BufferPtr = &ReadBuffer[DATA_OFFSET + DUMMY_SIZE];

	for (UniqueValue = UNIQUE_VALUE, Count = 0; Count < MAX_DATA;
	     Count++, UniqueValue++) {
		if (BufferPtr[Count] != (u8)(UniqueValue + Test)) {
			return XST_FAILURE;
		}
	}

	/*
	 * Set Auto Start and Manual Chip select options and drive the
	 * HOLD_B high.
	 */
	XQspiPs_SetOptions(QspiInstancePtr, XQSPIPS_FORCE_SSELECT_OPTION |
				XQSPIPS_HOLD_B_DRIVE_OPTION);

	/*
	 * Initialize the write buffer for a pattern to write to the FLASH
	 * and the read buffer to zero so it can be verified after the read, the
	 * test value that is added to the unique value allows the value to be
	 * changed in a debug environment to guarantee
	 */
	for (UniqueValue = UNIQUE_VALUE, Count = 0; Count < PAGE_SIZE;
	     Count++, UniqueValue++) {
		WriteBuffer[DATA_OFFSET + Count] = (u8)(UniqueValue + Test);
	}

	memset(ReadBuffer, 0x00, sizeof(ReadBuffer));

	/*
	 * Erase the flash.
	 */
	FlashErase(QspiInstancePtr, TEST_ADDRESS, MAX_DATA);

	/*
	 * Write the data in the write buffer to the serial FLASH a page at a
	 * time, starting from TEST_ADDRESS
	 */
	for (Page = 0; Page < PAGE_COUNT; Page++) {
		FlashWrite(QspiInstancePtr, (Page * PAGE_SIZE) + TEST_ADDRESS,
			   PAGE_SIZE, WRITE_CMD);
	}

	/*
	 * Read the contents of the FLASH from TEST_ADDRESS, using Normal Read
	 * command.
	 */
	FlashRead(QspiInstancePtr, TEST_ADDRESS, MAX_DATA, READ_CMD);

	/*
	 * Setup a pointer to the start of the data that was read into the read
	 * buffer and verify the data read is the data that was written
	 */
	BufferPtr = &ReadBuffer[DATA_OFFSET];

	for (UniqueValue = UNIQUE_VALUE, Count = 0; Count < MAX_DATA;
	     Count++, UniqueValue++) {
		if (BufferPtr[Count] != (u8)(UniqueValue + Test)) {
			return XST_FAILURE;
		}
	}

	/*
	 * Read the contents of the FLASH from TEST_ADDRESS, using Fast Read
	 * command
	 */
	memset(ReadBuffer, 0x00, sizeof(ReadBuffer));
	FlashRead(QspiInstancePtr, TEST_ADDRESS, MAX_DATA, FAST_READ_CMD);

	/*
	 * Setup a pointer to the start of the data that was read into the read
	 * buffer and verify the data read is the data that was written
	 */
	BufferPtr = &ReadBuffer[DATA_OFFSET + DUMMY_SIZE];
	for (UniqueValue = UNIQUE_VALUE, Count = 0; Count < MAX_DATA;
	     Count++, UniqueValue++) {
		if (BufferPtr[Count] != (u8)(UniqueValue + Test)) {
			return XST_FAILURE;
		}
	}

	/*
	 * Read the contents of the FLASH from TEST_ADDRESS, using Dual Read
	 * command
	 */
	memset(ReadBuffer, 0x00, sizeof(ReadBuffer));
	FlashRead(QspiInstancePtr, TEST_ADDRESS, MAX_DATA, DUAL_READ_CMD);

	/*
	 * Setup a pointer to the start of the data that was read into the read
	 * buffer and verify the data read is the data that was written
	 */
	BufferPtr = &ReadBuffer[DATA_OFFSET + DUMMY_SIZE];

	for (UniqueValue = UNIQUE_VALUE, Count = 0; Count < MAX_DATA;
	     Count++, UniqueValue++) {
		if (BufferPtr[Count] != (u8)(UniqueValue + Test)) {
			return XST_FAILURE;
		}
	}

	/*
	 * Read the contents of the FLASH from TEST_ADDRESS, using Quad Read
	 * command
	 */
	memset(ReadBuffer, 0x00, sizeof(ReadBuffer));
	FlashRead(QspiInstancePtr, TEST_ADDRESS, MAX_DATA, QUAD_READ_CMD);

	/*
	 * Setup a pointer to the start of the data that was read into the read
	 * buffer and verify the data read is the data that was written
	 */
	BufferPtr = &ReadBuffer[DATA_OFFSET + DUMMY_SIZE];

	for (UniqueValue = UNIQUE_VALUE, Count = 0; Count < MAX_DATA;
	     Count++, UniqueValue++) {
		if (BufferPtr[Count] != (u8)(UniqueValue + Test)) {
			return XST_FAILURE;
		}
	}

	QspiDisableIntrSystem(IntcInstancePtr, QspiIntrId);
	return XST_SUCCESS;
}