FreeRTOS/Demo/ARM7_AT91SAM7X256_Eclipse/RTOSDemo/USB/USBSample.c

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*/

/*
	Sample interrupt driven mouse device driver.  This is a minimal implementation 
	for demonstration only.  Although functional, it may not be a fully and 
	compliant implementation.  The small joystick on the SAM7X EK can be used to
	move the mouse cursor, pressing the joystick transmits mouse clicks.  Note
	that it might be necessary to run the demo stand along (without the 
	debugger) in order for the USB device to be recognised by the host computer.

	The interrupt handler itself is contained within USB_ISR.c.
	
	See the FreeRTOS.org online documentation for more information.
*/

/* Standard includes. */
#include <string.h>

/* Scheduler includes. */
#include "FreeRTOS.h"
#include "task.h"
#include "queue.h"

/* Demo application includes. */
#include "USBSample.h"

/* Joystick inputs used to move the 'mouse' cursor. */
#define usbSW1 	( 1 << 21 )	/* PA21 */
#define usbSW2 	( 1 << 22 )	/* PA22 */
#define usbSW3 	( 1 << 23 )	/* PA23 */
#define usbSW4 	( 1 << 24 )	/* PA24 */
#define usbSW_CLICK	( 1 << 25 ) /* PA25 */

/* Descriptor type definitions. */
#define usbDESCRIPTOR_TYPE_DEVICE			( 0x01 )
#define usbDESCRIPTOR_TYPE_CONFIGURATION	( 0x02 )
#define usbDESCRIPTOR_TYPE_STRING			( 0x03 )

/* USB request type definitions. */
#define usbGET_REPORT_REQUEST				( 0x01 )
#define usbGET_IDLE_REQUEST					( 0x02 )
#define usbGET_PROTOCOL_REQUEST				( 0x03 )
#define usbSET_REPORT_REQUEST				( 0x09 )
#define usbSET_IDLE_REQUEST					( 0x0A )
#define usbSET_PROTOCOL_REQUEST				( 0x0B )
#define usbGET_CONFIGURATION_REQUEST		( 0x08 )
#define usbGET_STATUS_REQUEST				( 0x00 )
#define usbCLEAR_FEATURE_REQUEST			( 0x01 )
#define usbSET_FEATURE_REQUEST				( 0x03 )
#define usbSET_ADDRESS_REQUEST				( 0x05 )
#define usbGET_DESCRIPTOR_REQUEST			( 0x06 )
#define usbSET_CONFIGURATION_REQUEST		( 0x09 )
#define usbGET_INTERFACE_REQUEST			( 0x0A )
#define usbSET_INTERFACE_REQUEST			( 0x0B )


/* Misc USB definitions. */
#define usbDEVICE_CLASS_VENDOR_SPECIFIC		( 0xFF )
#define usbBUS_POWERED						( 0x80 )
#define usbHID_REPORT_DESCRIPTOR			( 0x22 )
#define AT91C_UDP_TRANSCEIVER_ENABLE			( *( ( unsigned long * ) 0xfffb0074 ) )

/* Index to the various string. */
#define usbLANGUAGE_STRING					( 0 )
#define usbMANUFACTURER_STRING				( 1 )
#define usbPRODUCT_STRING					( 2 )
#define usbCONFIGURATION_STRING				( 3 )
#define usbINTERFACE_STRING					( 4 )

/* Data indexes for reading the request from the xISRStatus.ucFifoData[]
into xUSB_REQUEST.  The data order is designed for speed - so looks a 
little odd. */
#define usbREQUEST_TYPE_INDEX				( 7 )
#define usbREQUEST_INDEX					( 6 )
#define usbVALUE_HIGH_BYTE					( 4 )
#define usbVALUE_LOW_BYTE					( 5 )
#define usbINDEX_HIGH_BYTE					( 2 )
#define usbINDEX_LOW_BYTE					( 3 )
#define usbLENGTH_HIGH_BYTE					( 0 )
#define usbLENGTH_LOW_BYTE					( 1 )

/* Misc application definitions. */
#define usbINTERRUPT_PRIORITY				( 3 )
#define usbFIFO_LENGTH						( ( unsigned long ) 8 )
#define usbXUP								( 1 )
#define usbXDOWN							( 2 )
#define usbYUP								( 3 )
#define usbYDOWN							( 4 )
#define usbMAX_COORD						( 120 )
#define usbMAX_TX_MESSAGE_SIZE				( 128 )
#define usbSHORTEST_DELAY					( ( TickType_t ) 1 )
#define usbINIT_DELAY						( ( TickType_t ) 1000 / portTICK_PERIOD_MS )
#define usbSHORT_DELAY						( ( TickType_t ) 50 / portTICK_PERIOD_MS )
#define usbEND_POINT_RESET_MASK				( ( unsigned long ) 0x0f )
#define usbDATA_INC							( ( char ) 5 )
#define usbEXPECTED_NUMBER_OF_BYTES			( ( unsigned long ) 8 )

/* Control request types. */
#define usbSTANDARD_DEVICE_REQUEST			( 0 )
#define usbSTANDARD_INTERFACE_REQUEST		( 1 )
#define usbSTANDARD_END_POINT_REQUEST		( 2 )
#define usbCLASS_INTERFACE_REQUEST			( 5 )

/* Structure used to hold the received requests. */
typedef struct 
{
	unsigned char ucReqType;
	unsigned char ucRequest;
	unsigned short usValue;
	unsigned short usIndex;
	unsigned short usLength;
} xUSB_REQUEST;

typedef enum
{
	eNOTHING,
	eJUST_RESET,
	eJUST_GOT_CONFIG,
	eJUST_GOT_ADDRESS,
	eSENDING_EVEN_DESCRIPTOR,
	eREADY_TO_SEND
} eDRIVER_STATE;

/* Structure used to control the data being sent to the host. */
typedef struct
{
	unsigned char ucTxBuffer[ usbMAX_TX_MESSAGE_SIZE ];
	unsigned long ulNextCharIndex;
	unsigned long ulTotalDataLength;
} xTX_MESSAGE;

/*-----------------------------------------------------------*/

/* 
 * The USB interrupt service routine.  This takes a snapshot of the USB
 * device at the time of the interrupt, clears the interrupts, and posts
 * the data to the USB processing task.  This is implemented in USB_ISR.c.
 */
extern void vUSB_ISR_Wrapper( void );

/*
 * Called after the bus reset interrupt - this function readies all the
 * end points for communication.
 */
static void prvResetEndPoints( void );

/*
 * Setup the USB hardware, install the interrupt service routine and 
 * initialise all the state variables.
 */
static void vInitUSBInterface( void );

/*
 * Decode and act upon an interrupt generated by the control end point.
 */
static void prvProcessEndPoint0Interrupt( xISRStatus *pxMessage );

/* 
 * For simplicity requests are separated into device, interface, class 
 * interface and end point requests.
 *
 * Decode and handle standard device requests originating on the control
 * end point. 
 */
static void prvHandleStandardDeviceRequest( xUSB_REQUEST *pxRequest );

/*
 * For simplicity requests are separated into device, interface, class 
 * interface and end point requests.
 *
 * Decode and handle standard interface requests originating on the control
 * end point.
 */
static void prvHandleStandardInterfaceRequest( xUSB_REQUEST *pxRequest );

/*
 * For simplicity requests are separated into device, interface, class 
 * interface and end point requests.
 *
 * Decode and handle standard end point requests originating on the control
 * end point.
 */
static void prvHandleStandardEndPointRequest( xUSB_REQUEST *pxRequest );

/*
 * For simplicity requests are separated into device, interface, class 
 * interface and end point requests.
 *
 * Decode and handle the class interface requests.
 */
static void prvHandleClassInterfaceRequest( xUSB_REQUEST *pxRequest );

/*
 * Setup the Tx buffer to send data in response to a control request.
 *
 * The data to be transmitted is buffered, the state variables are updated,
 * then prvSendNextSegment() is called to start the transmission off.  Once
 * the first segment has been sent the remaining segments are transmitted
 * in response to TXCOMP interrupts until the entire buffer has been
 * sent.
 */
static void prvSendControlData( unsigned char *pucData, unsigned short usRequestedLength, unsigned long ulLengthLeftToSend, long lSendingDescriptor );

/*
 * Examine the Tx buffer to see if there is any more data to be transmitted.
 * 
 * If there is data to be transmitted then send the next segment.  A segment
 * can have a maximum of 8 bytes (this is defined as the maximum for the end
 * point by the descriptor).  The final segment may be less than 8 bytes if
 * the total data length was not an exact multiple of 8.
 */
static void prvSendNextSegment( void );

/*
 * A stall condition is forced each time the host makes a request that is not
 * supported by this minimal implementation.
 * 
 * A stall is forced by setting the appropriate bit in the end points control
 * and status register. 
 */
static void prvSendStall( void );

/*
 * A NULL (or zero length packet) is transmitted in acknowledge the reception 
 * of certain events from the host.
 */
static void prvUSBTransmitNull( void );

/* 
 * When the host requests a descriptor this function is called to determine 
 * which descriptor is being requested and start its transmission.
 */
static void prvGetStandardInterfaceDescriptor( xUSB_REQUEST *pxRequest );

/*
 * Transmit movement and clicks on the EK joystick as mouse inputs.
 */
static void prvTransmitSampleValues( void );

/*
 * The created task to handle the USB demo functionality. 
 */
static void vUSBDemoTask( void *pvParameters );

/*
 * Simple algorithm to ramp up the mouse cursor speed to make it easier to
 * use.
 */
static void prvControlCursorSpeed( signed char *cVal, unsigned long ulInput, unsigned long ulSwitch1, unsigned long ulSwitch2 );
/*-----------------------------------------------------------*/

/*
	- DESCRIPTOR DEFINITIONS -
*/

/* String descriptors used during the enumeration process.
These take the form:

{
	Length of descriptor,
	Descriptor type,
	Data
}
*/
const char pxLanguageStringDescriptor[] =
{
	4,
	usbDESCRIPTOR_TYPE_STRING,
	0x09, 0x04
};

const char pxManufacturerStringDescriptor[] = 
{
	18,
	usbDESCRIPTOR_TYPE_STRING,

	'F', 0x00,
	'r', 0x00,
	'e', 0x00,
	'e', 0x00,
	'R', 0x00,
	'T', 0x00,
	'O', 0x00,
	'S', 0x00	
};

const char pxProductStringDescriptor[] = 
{
	38,
	usbDESCRIPTOR_TYPE_STRING,

	'F', 0x00,
	'r', 0x00,
	'e', 0x00,
	'e', 0x00,
	'R', 0x00,
	'T', 0x00,
	'O', 0x00,
	'S', 0x00,
	'.', 0x00,
	'o', 0x00,
	'r', 0x00,
	'g', 0x00,
	' ', 0x00,
	'M', 0x00,
	'o', 0x00,
	'u', 0x00,
	's', 0x00,
	'e', 0x00
};

const char pxConfigurationStringDescriptor[] = 
{
	38,
	usbDESCRIPTOR_TYPE_STRING,

	'C', 0x00,
	'o', 0x00,
	'n', 0x00,
	'f', 0x00,
	'i', 0x00,
	'g', 0x00,
	'u', 0x00,
	'r', 0x00,
	'a', 0x00,
	't', 0x00,
	'i', 0x00,
	'o', 0x00,
	'n', 0x00,
	' ', 0x00,
	'N', 0x00,
	'a', 0x00,
	'm', 0x00,
	'e', 0x00
};

const char pxInterfaceStringDescriptor[] = 
{
	30,
	usbDESCRIPTOR_TYPE_STRING,

	'I', 0x00,
	'n', 0x00,
	't', 0x00,
	'e', 0x00,
	'r', 0x00,
	'f', 0x00,
	'a', 0x00,
	'c', 0x00,
	'e', 0x00,
	' ', 0x00,
	'N', 0x00,
	'a', 0x00,
	'm', 0x00,
	'e', 0x00
};

/* Enumeration descriptors. */
const char pxReportDescriptor[] =
{
	0x05, 0x01,						/* USAGE_PAGE (Generic Desktop)			*/
	0x09, 0x02,						/* USAGE (Mouse)						*/
	0xa1, 0x01,						/* COLLECTION (Application)				*/
	0x09, 0x01,						/*   USAGE (Pointer)					*/
	0xa1, 0x00,						/*   COLLECTION (Physical)				*/
	0x95, 0x03,						/*     REPORT_COUNT (3)					*/
	0x75, 0x01,						/*     REPORT_SIZE (1)					*/
	0x05, 0x09,						/*     USAGE_PAGE (Button)				*/
	0x19, 0x01,						/*     USAGE_MINIMUM (Button 1)			*/
	0x29, 0x03,						/*     USAGE_MAXIMUM (Button 3)			*/
	0x15, 0x00,						/*     LOGICAL_MINIMUM (0)				*/
	0x25, 0x01,						/*     LOGICAL_MAXIMUM (1)				*/
	0x81, 0x02,						/*     INPUT (Data,Var,Abs)				*/
	0x95, 0x01,						/*     REPORT_COUNT (1)					*/
	0x75, 0x05,						/*     REPORT_SIZE (5)					*/
	0x81, 0x01,						/*     INPUT (Cnst,Ary,Abs)				*/
	0x75, 0x08,						/*     REPORT_SIZE (8)					*/
	0x95, 0x02,						/*     REPORT_COUNT (2)					*/
	0x05, 0x01,						/*     USAGE_PAGE (Generic Desktop)		*/
	0x09, 0x30,						/*     USAGE (X)						*/
	0x09, 0x31,						/*     USAGE (Y)						*/
	0x15, 0x81,						/*     LOGICAL_MINIMUM (-127)			*/
	0x25, 0x7f,						/*     LOGICAL_MAXIMUM (127)			*/
	0x81, 0x06,						/*     INPUT (Data,Var,Rel)				*/
	0xc0,							/*   END_COLLECTION						*/
	0xc0							/* END_COLLECTION						*/
};



const char pxDeviceDescriptor[] = 
{
	/* Device descriptor */
	0x12,								/* bLength				*/
	0x01,								/* bDescriptorType		*/
	0x10, 0x01,							/* bcdUSBL				*/
	usbDEVICE_CLASS_VENDOR_SPECIFIC,	/* bDeviceClass:		*/
	0x00,								/* bDeviceSubclass:		*/
	0x00,								/* bDeviceProtocol:		*/
	0x08,								/* bMaxPacketSize0		*/
	0xFF, 0xFF,							/* idVendorL			*/
	0x02, 0x00,							/* idProductL			*/
	0x00, 0x01,							/* bcdDeviceL			*/
	usbMANUFACTURER_STRING,				/* iManufacturer		*/
	usbPRODUCT_STRING,					/* iProduct				*/
	0x00,								/* SerialNumber			*/
	0x01								/* bNumConfigs			*/
};


const char pxConfigDescriptor[] = {
	/* Configuration 1 descriptor */
	0x09,			/* CbLength									*/
	0x02,			/* CbDescriptorType							*/
	0x22, 0x00,		/* CwTotalLength 2 EP + Control				*/
	0x01,			/* CbNumInterfaces							*/
	0x01,			/* CbConfigurationValue						*/
	usbCONFIGURATION_STRING,/* CiConfiguration					*/
	usbBUS_POWERED,	/* CbmAttributes Bus powered + Remote Wakeup*/
	0x32,			/* CMaxPower: 100mA							*/

	/* Mouse Interface Descriptor Requirement */
	0x09,			/* bLength									*/
	0x04,			/* bDescriptorType							*/
	0x00,			/* bInterfaceNumber							*/
	0x00,			/* bAlternateSetting						*/
	0x01,			/* bNumEndpoints							*/
	0x03,			/* bInterfaceClass: HID code				*/
	0x01,			/* bInterfaceSubclass boot					*/
	0x02,			/* bInterfaceProtocol mouse boot			*/
	usbINTERFACE_STRING,/* iInterface							*/

	/* HID Descriptor */
	0x09,			/* bLength									*/
	0x21,			/* bDescriptor type: HID Descriptor Type	*/
	0x00, 0x01,		/* bcdHID									*/
	0x00,			/* bCountryCode								*/
	0x01,			/* bNumDescriptors							*/
	usbHID_REPORT_DESCRIPTOR,	  /* bDescriptorType			*/
	sizeof( pxReportDescriptor ), 0x00, /* wItemLength			*/

	/* Endpoint 1 descriptor */
	0x07,			/* bLength									*/
	0x05,			/* bDescriptorType							*/
	0x81,			/* bEndpointAddress, Endpoint 01 - IN		*/
	0x03,			/* bmAttributes      INT					*/
	0x08, 0x00,		/* wMaxPacketSize: 8?						*/
	0x0A			/* bInterval								*/
};

/*-----------------------------------------------------------*/

/* File scope state variables. */
static unsigned char ucUSBConfig = ( unsigned char ) 0;
static unsigned long ulReceivedAddress = ( unsigned long ) 0;
static eDRIVER_STATE eDriverState = eNOTHING;

/* Structure used to control the characters being sent to the host. */
static xTX_MESSAGE pxCharsForTx;

/* Queue used to pass messages between the ISR and the task. */
QueueHandle_t xUSBInterruptQueue; 

/*-----------------------------------------------------------*/

void vStartUSBTask( unsigned portBASE_TYPE uxPriority )
{
	/* Create the queue used to communicate between the USB ISR and task. */
	xUSBInterruptQueue = xQueueCreate( usbQUEUE_LENGTH + 1, sizeof( xISRStatus * ) );

	/* Create the task itself. */
	xTaskCreate( vUSBDemoTask, "USB", configMINIMAL_STACK_SIZE, NULL, uxPriority, NULL );
}
/*-----------------------------------------------------------*/

static void vUSBDemoTask( void *pvParameters )
{
xISRStatus *pxMessage;

	/* The parameters are not used in this task. */
	( void ) pvParameters;

    /* Init USB device */
    portENTER_CRITICAL();
	    vInitUSBInterface();
    portEXIT_CRITICAL();

	/* Process interrupts as they arrive.   The ISR takes a snapshot of the 
	interrupt status then posts the information on this queue for processing
	at the task level.  This simple demo implementation only processes
	a few interrupt sources. */
	for( ;; )
	{
		if( xQueueReceive( xUSBInterruptQueue, &pxMessage, usbSHORT_DELAY ) )
		{
			if( pxMessage->ulISR & AT91C_UDP_EPINT0 )
			{
				/* Process end point 0 interrupt. */
				prvProcessEndPoint0Interrupt( pxMessage );
			}

			if( pxMessage->ulISR & AT91C_UDP_ENDBUSRES )
			{
				/* Process an end of bus reset interrupt. */
				prvResetEndPoints();		
			}
		}
		else
		{
			/* The ISR did not post any data for us to process on the queue, so
			just generate and send some sample data. */
			if( eDriverState == eREADY_TO_SEND )
			{
				prvTransmitSampleValues();
			}
		}
	}
}
/*-----------------------------------------------------------*/

static void prvControlCursorSpeed( signed char *cVal, unsigned long ulInput, unsigned long ulSwitch1, unsigned long ulSwitch2 )
{
const char cSpeed = 20;

	if( !( ulInput & ulSwitch1 ) )
	{
		/* We are going in the decreasing y direction. */
		if( *cVal > 0 )
		{
			/* We have changed direction since last time so start from
			0 again. */
			*cVal = 0;
		}
		
		if( *cVal > -cSpeed )
		{
			/* Ramp y down to the max speed. */
			(*cVal)--;
		}
	}
	else if( !( ulInput & ulSwitch2 ) )
	{
		/* We are going in the increasing y direction. */
		if( *cVal < 0 )
		{
			/* We have changed direction since last time, so start from
			0 again. */
			*cVal = 0;
		}
		
		if( *cVal < cSpeed )
		{
			/* Ramp y up to the max speed again. */
			(*cVal)++;
		}
	}
	else
	{
		*cVal = 0;
	}
}
/*-----------------------------------------------------------*/

static void prvTransmitSampleValues( void )
{
/* Variables to hold dummy x, y and z joystick axis data. */
static signed char x = 0, y = 0, z = 0;
unsigned long ulStatus;

	ulStatus = 	AT91C_BASE_PIOA->PIO_PDSR;

	prvControlCursorSpeed( &y, ulStatus, ( unsigned long ) usbSW1, ( unsigned long ) usbSW2 );
	prvControlCursorSpeed( &x, ulStatus, ( unsigned long ) usbSW3, ( unsigned long ) usbSW4 );
	
	/* Just make the z axis go up and down. */
	z = ( ( ulStatus & usbSW_CLICK ) == 0 );

	/* Can we place data in the fifo? */
	if( !( AT91C_BASE_UDP->UDP_CSR[ usbEND_POINT_1 ] & AT91C_UDP_TXPKTRDY ) )
	{
		/* Write our sample data to the fifo. */
		AT91C_BASE_UDP->UDP_FDR[ usbEND_POINT_1 ] = z;
		AT91C_BASE_UDP->UDP_FDR[ usbEND_POINT_1 ] = x;
		AT91C_BASE_UDP->UDP_FDR[ usbEND_POINT_1 ] = y;
		
		/* Send the data. */
		portENTER_CRITICAL();
		{
			ulStatus = AT91C_BASE_UDP->UDP_CSR[ usbEND_POINT_1 ];
			usbCSR_SET_BIT( &ulStatus, ( AT91C_UDP_TXPKTRDY ) );
			AT91C_BASE_UDP->UDP_CSR[ usbEND_POINT_1 ] = ulStatus;
		}
		portEXIT_CRITICAL();
	}
}
/*-----------------------------------------------------------*/

static void prvUSBTransmitNull( void )
{
unsigned long ulStatus;

	/* Wait until the FIFO is free - even though we are not going to use it.
	THERE IS NO TIMEOUT HERE! */
	while( AT91C_BASE_UDP->UDP_CSR[ usbEND_POINT_0 ] & AT91C_UDP_TXPKTRDY )
	{
		vTaskDelay( usbSHORTEST_DELAY );
	}

	portENTER_CRITICAL();
	{
		/* Set the length of data to send to equal the index of the next byte
		to send.  This will prevent the ACK to this NULL packet causing any
		further data transmissions. */
		pxCharsForTx.ulTotalDataLength = pxCharsForTx.ulNextCharIndex;

		/* Set the TXPKTRDY bit to cause a transmission with no data. */
		ulStatus = AT91C_BASE_UDP->UDP_CSR[ usbEND_POINT_0 ];
		usbCSR_SET_BIT( &ulStatus, ( AT91C_UDP_TXPKTRDY ) );
		AT91C_BASE_UDP->UDP_CSR[ usbEND_POINT_0 ] = ulStatus;
	}
	portEXIT_CRITICAL();
}
/*-----------------------------------------------------------*/

static void prvSendStall( void )
{
unsigned long ulStatus;

	portENTER_CRITICAL();
	{
		/* Force a stall by simply setting the FORCESTALL bit in the CSR. */
		ulStatus = AT91C_BASE_UDP->UDP_CSR[ usbEND_POINT_0 ];
		usbCSR_SET_BIT( &ulStatus, AT91C_UDP_FORCESTALL );
		AT91C_BASE_UDP->UDP_CSR[ usbEND_POINT_0 ] = ulStatus;
	}
	portEXIT_CRITICAL();
}
/*-----------------------------------------------------------*/

static void prvResetEndPoints( void )
{
unsigned long ulTemp;

	eDriverState = eJUST_RESET;

	/* Reset all the end points. */
	AT91C_BASE_UDP->UDP_RSTEP  = usbEND_POINT_RESET_MASK;
	AT91C_BASE_UDP->UDP_RSTEP  = ( unsigned long ) 0x00;

	/* Enable data to be sent and received. */
	AT91C_BASE_UDP->UDP_FADDR = AT91C_UDP_FEN;

	/* Repair the configuration end point. */
	portENTER_CRITICAL();
	{
		ulTemp = AT91C_BASE_UDP->UDP_CSR[ usbEND_POINT_0 ];
		usbCSR_SET_BIT( &ulTemp, ( ( unsigned long ) ( AT91C_UDP_EPEDS | AT91C_UDP_EPTYPE_CTRL ) ) );
		AT91C_BASE_UDP->UDP_CSR[ usbEND_POINT_0 ] = ulTemp;
		AT91C_BASE_UDP->UDP_IER = AT91C_UDP_EPINT0;
	}
	portEXIT_CRITICAL();
}
/*-----------------------------------------------------------*/

static void prvProcessEndPoint0Interrupt( xISRStatus *pxMessage )
{
	if( pxMessage->ulCSR0 & AT91C_UDP_RX_DATA_BK0 )
	{		
		/* We only expect to receive zero length data here as ACK's. 
		Set the data pointer to the end of the current Tx packet to
		ensure we don't send out any more data. */	
		pxCharsForTx.ulNextCharIndex = pxCharsForTx.ulTotalDataLength;
	}

	if( pxMessage->ulCSR0 & AT91C_UDP_TXCOMP )
	{
		/* We received a TX complete interrupt.  What we do depends on
		what we sent to get this interrupt. */

		if( eDriverState == eJUST_GOT_CONFIG )
		{
			/* We sent an acknowledgement of a SET_CONFIG request.  We
			are now at the end of the enumeration. */
			AT91C_BASE_UDP->UDP_GLBSTATE = AT91C_UDP_CONFG;

			/* Read the end point for data transfer. */
			portENTER_CRITICAL();
			{
				unsigned long ulTemp;

				ulTemp = AT91C_BASE_UDP->UDP_CSR[ usbEND_POINT_1 ];					
				usbCSR_SET_BIT( &ulTemp, AT91C_UDP_EPEDS | AT91C_UDP_EPTYPE_INT_IN );
				AT91C_BASE_UDP->UDP_CSR[ usbEND_POINT_1 ] = ulTemp;		
				AT91C_BASE_UDP->UDP_IER = AT91C_UDP_EPINT1;
			}
			portEXIT_CRITICAL();

			eDriverState = eREADY_TO_SEND;
		}		
		else if( eDriverState == eJUST_GOT_ADDRESS )
		{
			/* We sent an acknowledgement of a SET_ADDRESS request.  Move
			to the addressed state. */
			if( ulReceivedAddress != ( unsigned long ) 0 )
			{			
				AT91C_BASE_UDP->UDP_GLBSTATE = AT91C_UDP_FADDEN;
			}
			else
			{
				AT91C_BASE_UDP->UDP_GLBSTATE = 0;
			}			

			AT91C_BASE_UDP->UDP_FADDR = ( AT91C_UDP_FEN | ulReceivedAddress );		
			eDriverState = eNOTHING;
		}
		else
		{		
			/* The TXCOMP was not for any special type of transmission.  See
			if there is any more data to send. */
			prvSendNextSegment();
		}
	}

	if( pxMessage->ulCSR0 & AT91C_UDP_RXSETUP )
	{
		xUSB_REQUEST xRequest;
		unsigned char ucRequest;
		unsigned long ulRxBytes;

		/* A data packet is available. */	
		ulRxBytes = pxMessage->ulCSR0 >> 16;
		ulRxBytes &= usbRX_COUNT_MASK;

		if( ulRxBytes >= usbEXPECTED_NUMBER_OF_BYTES )
		{
			/* Create an xUSB_REQUEST variable from the raw bytes array. */

			xRequest.ucReqType = pxMessage->ucFifoData[ usbREQUEST_TYPE_INDEX ];
			xRequest.ucRequest = pxMessage->ucFifoData[ usbREQUEST_INDEX ];

			/* NOT PORTABLE CODE! */
			xRequest.usValue = pxMessage->ucFifoData[ usbVALUE_HIGH_BYTE ];
			xRequest.usValue <<= 8;
			xRequest.usValue |= pxMessage->ucFifoData[ usbVALUE_LOW_BYTE ];
						
			xRequest.usIndex = pxMessage->ucFifoData[ usbINDEX_HIGH_BYTE ];
			xRequest.usIndex <<= 8;
			xRequest.usIndex |= pxMessage->ucFifoData[ usbINDEX_LOW_BYTE ];
			
			xRequest.usLength = pxMessage->ucFifoData[ usbLENGTH_HIGH_BYTE ];
			xRequest.usLength <<= 8;
			xRequest.usLength |= pxMessage->ucFifoData[ usbLENGTH_LOW_BYTE ];
	
			/* Manipulate the ucRequestType and the ucRequest parameters to 
			generate a zero based request selection.  This is just done to 
			break up the requests into subsections for clarity.  The 
			alternative would be to have more huge switch statement that would
			be difficult to optimise. */
			ucRequest = ( ( xRequest.ucReqType & 0x60 ) >> 3 );
			ucRequest |= ( xRequest.ucReqType & 0x03 );

			switch( ucRequest )
			{
				case usbSTANDARD_DEVICE_REQUEST:	
							/* Standard Device request */
							prvHandleStandardDeviceRequest( &xRequest );
							break;
	
				case usbSTANDARD_INTERFACE_REQUEST:	
							/* Standard Interface request */
							prvHandleStandardInterfaceRequest( &xRequest );
							break;
	
				case usbSTANDARD_END_POINT_REQUEST:	
							/* Standard Endpoint request */
							prvHandleStandardEndPointRequest( &xRequest );
							break;
	
				case usbCLASS_INTERFACE_REQUEST:	
							/* Class Interface request */
							prvHandleClassInterfaceRequest( &xRequest );
							break;
	
				default:	/* This is not something we want to respond to. */
							prvSendStall();	
			}
		}
	}
}
/*-----------------------------------------------------------*/

static void prvGetStandardDeviceDescriptor( xUSB_REQUEST *pxRequest )
{
	/* The type is in the high byte.  Return whatever has been requested. */
	switch( ( pxRequest->usValue & 0xff00 ) >> 8 )
	{
	    case usbDESCRIPTOR_TYPE_DEVICE:
			prvSendControlData( ( unsigned char * ) &pxDeviceDescriptor, pxRequest->usLength, sizeof( pxDeviceDescriptor ), pdTRUE );
		    break;
	
	    case usbDESCRIPTOR_TYPE_CONFIGURATION:
			prvSendControlData( ( unsigned char * ) &( pxConfigDescriptor ), pxRequest->usLength, sizeof( pxConfigDescriptor ), pdTRUE );
		    break;

	    case usbDESCRIPTOR_TYPE_STRING:

			/* The index to the string descriptor is the lower byte. */
		    switch( pxRequest->usValue & 0xff )
			{			
		        case usbLANGUAGE_STRING:
					prvSendControlData( ( unsigned char * ) &pxLanguageStringDescriptor, pxRequest->usLength, sizeof(pxLanguageStringDescriptor), pdTRUE );
			        break;

		        case usbMANUFACTURER_STRING:
					prvSendControlData( ( unsigned char * ) &pxManufacturerStringDescriptor, pxRequest->usLength, sizeof( pxManufacturerStringDescriptor ), pdTRUE );
			        break;

		        case usbPRODUCT_STRING:
					prvSendControlData( ( unsigned char * ) &pxProductStringDescriptor, pxRequest->usLength, sizeof( pxProductStringDescriptor ), pdTRUE );
			        break;

		        case usbCONFIGURATION_STRING:
					prvSendControlData( ( unsigned char * ) &pxConfigurationStringDescriptor, pxRequest->usLength, sizeof( pxConfigurationStringDescriptor ), pdTRUE );
			        break;

		        case usbINTERFACE_STRING:
					prvSendControlData( ( unsigned char * ) &pxInterfaceStringDescriptor, pxRequest->usLength, sizeof( pxInterfaceStringDescriptor ), pdTRUE );
			        break;

		        default:
			        /* Don't know what this string is. */
					prvSendStall();
					break;
			}

			break;

	    default:
			/* We are not responding to anything else. */
			prvSendStall();
		    break;
	}
}
/*-----------------------------------------------------------*/

static void prvHandleStandardDeviceRequest( xUSB_REQUEST *pxRequest )
{
unsigned short usStatus = 0;

	switch( pxRequest->ucRequest )
	{
	    case usbGET_STATUS_REQUEST:
			/* Just send two byte dummy status. */
			prvSendControlData( ( unsigned char * ) &usStatus, sizeof( usStatus ), sizeof( usStatus ), pdFALSE );
		    break;

	    case usbGET_DESCRIPTOR_REQUEST:
			/* Send device descriptor */
		    prvGetStandardDeviceDescriptor( pxRequest );
		    break;

	    case usbGET_CONFIGURATION_REQUEST:
			/* Send selected device configuration */
			prvSendControlData( ( unsigned char * ) &ucUSBConfig, sizeof( ucUSBConfig ), sizeof( ucUSBConfig ), pdFALSE );
		    break;

		case usbSET_FEATURE_REQUEST:
		    prvUSBTransmitNull();
		    break;

	    case usbSET_ADDRESS_REQUEST:
	    	
			/* Acknowledge the SET_ADDRESS, but (according to the manual) we
			cannot actually move to the addressed state until we get a TXCOMP
			interrupt from this NULL packet.  Therefore we just remember the
			address and set our state so we know we have received the address. */
	    	prvUSBTransmitNull();			
			eDriverState = eJUST_GOT_ADDRESS;	    	
			ulReceivedAddress = ( unsigned long ) pxRequest->usValue;
		    break;

	    case usbSET_CONFIGURATION_REQUEST:

			/* Acknowledge the SET_CONFIGURATION, but (according to the manual) 
			we cannot actually move to the configured state until we get a 
			TXCOMP interrupt from this NULL packet.  Therefore we just remember the
			config and set our state so we know we have received the go ahead. */			
			ucUSBConfig = ( unsigned char ) ( pxRequest->usValue & 0xff );
			eDriverState = eJUST_GOT_CONFIG;
			prvUSBTransmitNull();
		    break;

	    default:

		    /* We don't answer to anything else. */
			prvSendStall();
		    break;
	}
}
/*-----------------------------------------------------------*/

static void prvHandleClassInterfaceRequest( xUSB_REQUEST *pxRequest )
{
	switch( pxRequest->ucRequest )
	{
	    case usbSET_IDLE_REQUEST:
	    	prvUSBTransmitNull();
			break;

		/* This minimal implementation ignores these. */
	    case usbGET_REPORT_REQUEST:
	    case usbGET_IDLE_REQUEST:
	    case usbGET_PROTOCOL_REQUEST:
	    case usbSET_REPORT_REQUEST:
	    case usbSET_PROTOCOL_REQUEST:	
	    default:

			prvSendStall();
			break;
	}
}
/*-----------------------------------------------------------*/

static void prvGetStandardInterfaceDescriptor( xUSB_REQUEST *pxRequest )
{
	switch( ( pxRequest->usValue & ( unsigned short ) 0xff00 ) >> 8 )
	{
	    case usbHID_REPORT_DESCRIPTOR:
			prvSendControlData( ( unsigned char * ) pxReportDescriptor, pxRequest->usLength, sizeof( pxReportDescriptor ), pdTRUE );
		    break;

	    default:

			/* Don't expect to send any others. */
			prvSendStall();
		    break;
	}
}
/*-----------------------------------------------------------*/

static void prvHandleStandardInterfaceRequest( xUSB_REQUEST *pxRequest )
{
unsigned short usStatus = 0;

	switch( pxRequest->ucRequest )
	{
	    case usbGET_STATUS_REQUEST:
			/* Send dummy 2 bytes. */
			prvSendControlData( ( unsigned char * ) &usStatus, sizeof( usStatus ), sizeof( usStatus ), pdFALSE );
			break;

	    case usbGET_DESCRIPTOR_REQUEST:
			prvGetStandardInterfaceDescriptor( pxRequest ); 
			break;

		/* This minimal implementation does not respond to these. */
	    case usbGET_INTERFACE_REQUEST:
	    case usbSET_FEATURE_REQUEST:
	    case usbSET_INTERFACE_REQUEST:	

	    default:
			prvSendStall();
			break;
	}
}
/*-----------------------------------------------------------*/

static void prvHandleStandardEndPointRequest( xUSB_REQUEST *pxRequest )
{
	switch( pxRequest->ucRequest )
	{
		/* This minimal implementation does not expect to respond to these. */
	    case usbGET_STATUS_REQUEST:
	    case usbCLEAR_FEATURE_REQUEST: 
	    case usbSET_FEATURE_REQUEST:

	    default:			
			prvSendStall();
			break;
	}
}
/*-----------------------------------------------------------*/

static void vInitUSBInterface( void )
{
volatile unsigned long ulTemp;

	/* Initialise a few state variables. */
	pxCharsForTx.ulNextCharIndex = ( unsigned long ) 0;
	ucUSBConfig = ( unsigned char ) 0;
	eDriverState = eNOTHING;

	/* HARDWARE SETUP */

    /* Set the PLL USB Divider */
    AT91C_BASE_CKGR->CKGR_PLLR |= AT91C_CKGR_USBDIV_1;

    /* Enables the 48MHz USB clock UDPCK and System Peripheral USB Clock. */
    AT91C_BASE_PMC->PMC_SCER = AT91C_PMC_UDP;
    AT91C_BASE_PMC->PMC_PCER = (1 << AT91C_ID_UDP);

    /* Setup the PIO for the USB pull up resistor. */
    AT91C_BASE_PIOA->PIO_PER = AT91C_PIO_PA16;
    AT91C_BASE_PIOA->PIO_OER = AT91C_PIO_PA16;
    

    /* Start without the pullup - this will get set at the end of this 
	function. */
    AT91C_BASE_PIOA->PIO_SODR = AT91C_PIO_PA16;

	/* When using the USB debugger the peripheral registers do not always get
	set to the correct default values.  To make sure set the relevant registers
	manually here. */
	AT91C_BASE_UDP->UDP_IDR = ( unsigned long ) 0xffffffff;
	AT91C_BASE_UDP->UDP_ICR = ( unsigned long ) 0xffffffff;
	AT91C_BASE_UDP->UDP_CSR[ 0 ] = ( unsigned long ) 0x00;
	AT91C_BASE_UDP->UDP_CSR[ 1 ] = ( unsigned long ) 0x00;
	AT91C_BASE_UDP->UDP_GLBSTATE = 0;
	AT91C_BASE_UDP->UDP_FADDR = 0;

	/* Enable the transceiver. */
	AT91C_UDP_TRANSCEIVER_ENABLE = 0;

	/* Enable the USB interrupts - other interrupts get enabled as the 
	enumeration process progresses. */
	AT91F_AIC_ConfigureIt( AT91C_ID_UDP, usbINTERRUPT_PRIORITY, AT91C_AIC_SRCTYPE_INT_HIGH_LEVEL, ( void (*)( void ) ) vUSB_ISR_Wrapper );
	AT91C_BASE_AIC->AIC_IECR = 0x1 << AT91C_ID_UDP;

	/* Wait a short while before making our presence known. */
	vTaskDelay( usbINIT_DELAY );
	AT91C_BASE_PIOA->PIO_CODR = AT91C_PIO_PA16;
}
/*-----------------------------------------------------------*/

static void prvSendControlData( unsigned char *pucData, unsigned short usRequestedLength, unsigned long ulLengthToSend, long lSendingDescriptor )
{
	if( ( ( unsigned long ) usRequestedLength < ulLengthToSend ) )
	{
		/* Cap the data length to that requested. */
		ulLengthToSend = ( unsigned short ) usRequestedLength;
	}
	else if( ( ulLengthToSend < ( unsigned long ) usRequestedLength ) && lSendingDescriptor )
	{
		/* We are sending a descriptor.  If the descriptor is an exact 
		multiple of the FIFO length then it will have to be terminated
		with a NULL packet.  Set the state to indicate this if
		necessary. */
		if( ( ulLengthToSend % usbFIFO_LENGTH ) == 0 )
		{
			eDriverState = eSENDING_EVEN_DESCRIPTOR;
		}
	}

	/* Here we assume that the previous message has been sent.  THERE IS NO
	BUFFER OVERFLOW PROTECTION HERE.

	Copy the data to send into the buffer as we cannot send it all at once
	(if it is greater than 8 bytes in length). */
	memcpy( pxCharsForTx.ucTxBuffer, pucData, ulLengthToSend );

	/* Reinitialise the buffer index so we start sending from the start of 
	the data. */
	pxCharsForTx.ulTotalDataLength = ulLengthToSend;
	pxCharsForTx.ulNextCharIndex = ( unsigned long ) 0;

	/* Send the first 8 bytes now.  The rest will get sent in response to 
	TXCOMP interrupts. */
	prvSendNextSegment();
}
/*-----------------------------------------------------------*/

static void prvSendNextSegment( void )
{
volatile unsigned long ulNextLength, ulStatus, ulLengthLeftToSend;

	/* Is there any data to send? */
	if( pxCharsForTx.ulTotalDataLength > pxCharsForTx.ulNextCharIndex )
	{
		ulLengthLeftToSend = pxCharsForTx.ulTotalDataLength - pxCharsForTx.ulNextCharIndex;
	
		/* We can only send 8 bytes to the fifo at a time. */
		if( ulLengthLeftToSend > usbFIFO_LENGTH )
		{
			ulNextLength = usbFIFO_LENGTH;
		}
		else
		{
			ulNextLength = ulLengthLeftToSend;
		}

		/* Wait until we can place data in the fifo.  THERE IS NO TIMEOUT
		HERE! */
		while( AT91C_BASE_UDP->UDP_CSR[ usbEND_POINT_0 ] & AT91C_UDP_TXPKTRDY )
		{
			vTaskDelay( usbSHORTEST_DELAY );
		}

		/* Write the data to the FIFO. */
		while( ulNextLength > ( unsigned long ) 0 )
		{
			AT91C_BASE_UDP->UDP_FDR[ usbEND_POINT_0 ] = pxCharsForTx.ucTxBuffer[ pxCharsForTx.ulNextCharIndex ];
	
			ulNextLength--;
			pxCharsForTx.ulNextCharIndex++;
		}
	
		/* Start the transmission. */
		portENTER_CRITICAL();
		{
			ulStatus = AT91C_BASE_UDP->UDP_CSR[ usbEND_POINT_0 ];
			usbCSR_SET_BIT( &ulStatus, ( ( unsigned long ) 0x10 ) );
			AT91C_BASE_UDP->UDP_CSR[ usbEND_POINT_0 ] = ulStatus;
		}
		portEXIT_CRITICAL();
	}
	else
	{
		/* There is no data to send.  If we were sending a descriptor and the 
		descriptor was an exact multiple of the max packet size then we need
		to send a null to terminate the transmission. */
		if( eDriverState == eSENDING_EVEN_DESCRIPTOR )
		{
			prvUSBTransmitNull();
			eDriverState = eNOTHING;
		}
	}
}