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|
/*
FreeRTOS V8.2.0rc1 - Copyright (C) 2014 Real Time Engineers Ltd.
All rights reserved
VISIT http://www.FreeRTOS.org TO ENSURE YOU ARE USING THE LATEST VERSION.
This file is part of the FreeRTOS distribution.
FreeRTOS is free software; you can redistribute it and/or modify it under
the terms of the GNU General Public License (version 2) as published by the
Free Software Foundation >>!AND MODIFIED BY!<< the FreeRTOS exception.
>>! NOTE: The modification to the GPL is included to allow you to !<<
>>! distribute a combined work that includes FreeRTOS without being !<<
>>! obliged to provide the source code for proprietary components !<<
>>! outside of the FreeRTOS kernel. !<<
FreeRTOS is distributed in the hope that it will be useful, but WITHOUT ANY
WARRANTY; without even the implied warranty of MERCHANTABILITY or FITNESS
FOR A PARTICULAR PURPOSE. Full license text is available on the following
link: http://www.freertos.org/a00114.html
1 tab == 4 spaces!
***************************************************************************
* *
* Having a problem? Start by reading the FAQ "My application does *
* not run, what could be wrong?". Have you defined configASSERT()? *
* *
* http://www.FreeRTOS.org/FAQHelp.html *
* *
***************************************************************************
***************************************************************************
* *
* FreeRTOS provides completely free yet professionally developed, *
* robust, strictly quality controlled, supported, and cross *
* platform software that is more than just the market leader, it *
* is the industry's de facto standard. *
* *
* Help yourself get started quickly while simultaneously helping *
* to support the FreeRTOS project by purchasing a FreeRTOS *
* tutorial book, reference manual, or both: *
* http://www.FreeRTOS.org/Documentation *
* *
***************************************************************************
***************************************************************************
* *
* Investing in training allows your team to be as productive as *
* possible as early as possible, lowering your overall development *
* cost, and enabling you to bring a more robust product to market *
* earlier than would otherwise be possible. Richard Barry is both *
* the architect and key author of FreeRTOS, and so also the world's *
* leading authority on what is the world's most popular real time *
* kernel for deeply embedded MCU designs. Obtaining your training *
* from Richard ensures your team will gain directly from his in-depth *
* product knowledge and years of usage experience. Contact Real Time *
* Engineers Ltd to enquire about the FreeRTOS Masterclass, presented *
* by Richard Barry: http://www.FreeRTOS.org/contact
* *
***************************************************************************
***************************************************************************
* *
* You are receiving this top quality software for free. Please play *
* fair and reciprocate by reporting any suspected issues and *
* participating in the community forum: *
* http://www.FreeRTOS.org/support *
* *
* Thank you! *
* *
***************************************************************************
http://www.FreeRTOS.org - Documentation, books, training, latest versions,
license and Real Time Engineers Ltd. contact details.
http://www.FreeRTOS.org/plus - A selection of FreeRTOS ecosystem products,
including FreeRTOS+Trace - an indispensable productivity tool, a DOS
compatible FAT file system, and our tiny thread aware UDP/IP stack.
http://www.FreeRTOS.org/labs - Where new FreeRTOS products go to incubate.
Come and try FreeRTOS+TCP, our new open source TCP/IP stack for FreeRTOS.
http://www.OpenRTOS.com - Real Time Engineers ltd license FreeRTOS to High
Integrity Systems ltd. to sell under the OpenRTOS brand. Low cost OpenRTOS
licenses offer ticketed support, indemnification and commercial middleware.
http://www.SafeRTOS.com - High Integrity Systems also provide a safety
engineered and independently SIL3 certified version for use in safety and
mission critical applications that require provable dependability.
1 tab == 4 spaces!
*/
/*
USB Communications Device Class driver.
Implements task vUSBCDCTask and provides an Abstract Control Model serial
interface. Control is through endpoint 0, device-to-host notification is
provided by interrupt-in endpoint 3, and raw data is transferred through
bulk endpoints 1 and 2.
- developed from original FreeRTOS HID example by Scott Miller
- modified to support 3.2 GCC by najay
*/
/* Standard includes. */
#include <string.h>
#include <stdio.h>
/* Demo board includes. */
#include "Board.h"
/* Scheduler includes. */
#include "FreeRTOS.h"
#include "task.h"
#include "queue.h"
/* Demo app includes. */
#include "USB-CDC.h"
#include "descriptors.h"
#define usbNO_BLOCK ( ( TickType_t ) 0 )
/* Reset all endpoints */
static void prvResetEndPoints( void );
/* Clear pull up resistor to detach device from host */
static void vDetachUSBInterface( void );
/* Set up interface and initialize variables */
static void vInitUSBInterface( void );
/* Handle control endpoint events. */
static void prvProcessEndPoint0Interrupt( xISRStatus *pxMessage );
/* Handle standard device requests. */
static void prvHandleStandardDeviceRequest( xUSB_REQUEST *pxRequest );
/* Handle standard interface requests. */
static void prvHandleStandardInterfaceRequest( xUSB_REQUEST *pxRequest );
/* Handle endpoint requests. */
static void prvHandleStandardEndPointRequest( xUSB_REQUEST *pxRequest );
/* Handle class interface requests. */
static void prvHandleClassInterfaceRequest( xUSB_REQUEST *pxRequest );
/* Prepare control data transfer. prvSendNextSegment starts transfer. */
static void prvSendControlData( unsigned char *pucData, unsigned short usRequestedLength, unsigned long ulLengthLeftToSend, long lSendingDescriptor );
/* Send next segment of data for the control transfer */
static void prvSendNextSegment( void );
/* Send stall - used to respond to unsupported requests */
static void prvSendStall( void );
/* Send a zero-length (null) packet */
static void prvSendZLP( void );
/* Handle requests for standard interface descriptors */
static void prvGetStandardInterfaceDescriptor( xUSB_REQUEST *pxRequest );
/*------------------------------------------------------------*/
/* File scope static variables */
static unsigned char ucUSBConfig = ( unsigned char ) 0;
static unsigned long ulReceivedAddress = ( unsigned long ) 0;
static eDRIVER_STATE eDriverState = eNOTHING;
/* Incoming and outgoing control data structures */
static xCONTROL_MESSAGE pxControlTx;
static xCONTROL_MESSAGE pxControlRx;
/* Queue holding pointers to pending messages */
QueueHandle_t xUSBInterruptQueue;
/* Queues used to hold received characters, and characters waiting to be
transmitted. Rx queue must be larger than FIFO size. */
static QueueHandle_t xRxCDC;
static QueueHandle_t xTxCDC;
/* Line coding - 115,200 baud, N-8-1 */
static const unsigned char pxLineCoding[] = { 0x00, 0xC2, 0x01, 0x00, 0x00, 0x00, 0x08 };
/* Status variables. */
static unsigned char ucControlState;
static unsigned int uiCurrentBank;
/*------------------------------------------------------------*/
void vUSBCDCTask( void *pvParameters )
{
xISRStatus *pxMessage;
unsigned long ulStatus;
unsigned long ulRxBytes;
unsigned char ucByte;
portBASE_TYPE xByte;
( void ) pvParameters;
/* Disconnect USB device from hub. For debugging - causes host to register reset */
portENTER_CRITICAL();
vDetachUSBInterface();
portEXIT_CRITICAL();
vTaskDelay( portTICK_PERIOD_MS * 60 );
/* Init USB interface */
portENTER_CRITICAL();
vInitUSBInterface();
portEXIT_CRITICAL();
/* Main task loop. Process incoming endpoint 0 interrupts, handle data transfers. */
for( ;; )
{
/* Look for data coming from the ISR. */
if( xQueueReceive( xUSBInterruptQueue, &pxMessage, usbSHORTEST_DELAY ) )
{
if( pxMessage->ulISR & AT91C_UDP_EPINT0 )
{
/* All endpoint 0 interrupts are handled here. */
prvProcessEndPoint0Interrupt( pxMessage );
}
if( pxMessage->ulISR & AT91C_UDP_ENDBUSRES )
{
/* End of bus reset - reset the endpoints and de-configure. */
prvResetEndPoints();
}
}
/* See if we're ready to send and receive data. */
if( eDriverState == eREADY_TO_SEND && ucControlState )
{
if( ( !(AT91C_BASE_UDP->UDP_CSR[ usbEND_POINT_2 ] & AT91C_UDP_TXPKTRDY) ) && uxQueueMessagesWaiting( xTxCDC ) )
{
for( xByte = 0; xByte < 64; xByte++ )
{
if( !xQueueReceive( xTxCDC, &ucByte, 0 ) )
{
/* No data buffered to transmit. */
break;
}
/* Got a byte to transmit. */
AT91C_BASE_UDP->UDP_FDR[ usbEND_POINT_2 ] = ucByte;
}
AT91C_BASE_UDP->UDP_CSR[ usbEND_POINT_2 ] |= AT91C_UDP_TXPKTRDY;
}
/* Check for incoming data (host-to-device) on endpoint 1. */
while( AT91C_BASE_UDP->UDP_CSR[ usbEND_POINT_1 ] & (AT91C_UDP_RX_DATA_BK0 | AT91C_UDP_RX_DATA_BK1) )
{
ulRxBytes = (AT91C_BASE_UDP->UDP_CSR[ usbEND_POINT_1 ] >> 16) & usbRX_COUNT_MASK;
/* Only process FIFO if there's room to store it in the queue */
if( ulRxBytes < ( USB_CDC_QUEUE_SIZE - uxQueueMessagesWaiting( xRxCDC ) ) )
{
while( ulRxBytes-- )
{
ucByte = AT91C_BASE_UDP->UDP_FDR[ usbEND_POINT_1 ];
xQueueSend( xRxCDC, &ucByte, 0 );
}
/* Release the FIFO */
portENTER_CRITICAL();
{
ulStatus = AT91C_BASE_UDP->UDP_CSR[ usbEND_POINT_1 ];
usbCSR_CLEAR_BIT( &ulStatus, uiCurrentBank );
AT91C_BASE_UDP->UDP_CSR[ usbEND_POINT_1 ] = ulStatus;
}
portEXIT_CRITICAL();
/* Re-enable endpoint 1's interrupts */
AT91C_BASE_UDP->UDP_IER = AT91C_UDP_EPINT1;
/* Update the current bank in use */
if( uiCurrentBank == AT91C_UDP_RX_DATA_BK0 )
{
uiCurrentBank = AT91C_UDP_RX_DATA_BK1;
}
else
{
uiCurrentBank = AT91C_UDP_RX_DATA_BK0;
}
}
else
{
break;
}
}
}
}
}
/*------------------------------------------------------------*/
void vUSBSendByte( char cByte )
{
/* Queue the byte to be sent. The USB task will send it. */
xQueueSend( xTxCDC, &cByte, usbNO_BLOCK );
}
/*------------------------------------------------------------*/
static void prvSendZLP( 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();
{
/* Cancel any further pending data */
pxControlTx.ulTotalDataLength = pxControlTx.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;
ucControlState = 0;
/* 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();
uiCurrentBank = AT91C_UDP_RX_DATA_BK0;
}
/*------------------------------------------------------------*/
static void prvProcessEndPoint0Interrupt( xISRStatus *pxMessage )
{
static xUSB_REQUEST xRequest;
unsigned long ulRxBytes;
/* Get number of bytes received, if any */
ulRxBytes = pxMessage->ulCSR0 >> 16;
ulRxBytes &= usbRX_COUNT_MASK;
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.
TODO: Config 0 sets unconfigured state, should enter Address state.
Request for unsupported config should stall. */
AT91C_BASE_UDP->UDP_GLBSTATE = AT91C_UDP_CONFG;
/* Set up endpoints */
portENTER_CRITICAL();
{
unsigned long ulTemp;
/* Set endpoint 1 to bulk-out */
ulTemp = AT91C_BASE_UDP->UDP_CSR[ usbEND_POINT_1 ];
usbCSR_SET_BIT( &ulTemp, AT91C_UDP_EPEDS | AT91C_UDP_EPTYPE_BULK_OUT );
AT91C_BASE_UDP->UDP_CSR[ usbEND_POINT_1 ] = ulTemp;
AT91C_BASE_UDP->UDP_IER = AT91C_UDP_EPINT1;
/* Set endpoint 2 to bulk-in */
ulTemp = AT91C_BASE_UDP->UDP_CSR[ usbEND_POINT_2 ];
usbCSR_SET_BIT( &ulTemp, AT91C_UDP_EPEDS | AT91C_UDP_EPTYPE_BULK_IN );
AT91C_BASE_UDP->UDP_CSR[ usbEND_POINT_2 ] = ulTemp;
AT91C_BASE_UDP->UDP_IER = AT91C_UDP_EPINT2;
/* Set endpoint 3 to interrupt-in, enable it, and enable interrupts */
ulTemp = AT91C_BASE_UDP->UDP_CSR[ usbEND_POINT_3 ];
usbCSR_SET_BIT( &ulTemp, AT91C_UDP_EPEDS | AT91C_UDP_EPTYPE_INT_IN );
AT91C_BASE_UDP->UDP_CSR[ usbEND_POINT_3 ] = ulTemp;
/*AT91F_UDP_EnableIt( AT91C_BASE_UDP, AT91C_UDP_EPINT3 ); */
}
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_RX_DATA_BK0 )
{
/* Received a control data packet. May be a 0-length ACK or a data stage. */
unsigned char ucBytesToGet;
/* Got data. Cancel any outgoing data. */
pxControlTx.ulNextCharIndex = pxControlTx.ulTotalDataLength;
/* Determine how many bytes we need to receive. */
ucBytesToGet = pxControlRx.ulTotalDataLength - pxControlRx.ulNextCharIndex;
if( ucBytesToGet > ulRxBytes )
{
ucBytesToGet = ulRxBytes;
}
/* If we're not expecting any data, it's an ack - just quit now. */
if( !ucBytesToGet )
{
return;
}
/* Get the required data and update the index. */
memcpy( pxControlRx.ucBuffer, pxMessage->ucFifoData, ucBytesToGet );
pxControlRx.ulNextCharIndex += ucBytesToGet;
}
if( pxMessage->ulCSR0 & AT91C_UDP_RXSETUP )
{
/* Received a SETUP packet. May be followed by data packets. */
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 ];
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 ];
pxControlRx.ulNextCharIndex = 0;
if( ! (xRequest.ucReqType & 0x80) ) /* Host-to-Device transfer, may need to get data first */
{
if( xRequest.usLength > usbMAX_CONTROL_MESSAGE_SIZE )
{
/* Too big! No space for control data, stall and abort. */
prvSendStall();
return;
}
pxControlRx.ulTotalDataLength = xRequest.usLength;
}
else
{
/* We're sending the data, don't wait for any. */
pxControlRx.ulTotalDataLength = 0;
}
}
}
/* See if we've got a pending request and all its associated data ready */
if( ( pxMessage->ulCSR0 & ( AT91C_UDP_RX_DATA_BK0 | AT91C_UDP_RXSETUP ) )
&& ( pxControlRx.ulNextCharIndex >= pxControlRx.ulTotalDataLength ) )
{
unsigned char ucRequest;
/* 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:
prvSendStall();
break;
}
break;
default:
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:
prvSendZLP();
break;
case usbSET_ADDRESS_REQUEST:
/* Get assigned address and send ack, but don't implement new address until we get a TXCOMP */
prvSendZLP();
eDriverState = eJUST_GOT_ADDRESS;
ulReceivedAddress = ( unsigned long ) pxRequest->usValue;
break;
case usbSET_CONFIGURATION_REQUEST:
/* Ack SET_CONFIGURATION request, but don't implement until TXCOMP */
ucUSBConfig = ( unsigned char ) ( pxRequest->usValue & 0xff );
eDriverState = eJUST_GOT_CONFIG;
prvSendZLP();
break;
default:
/* Any unsupported request results in a STALL response. */
prvSendStall();
break;
}
}
/*------------------------------------------------------------*/
static void prvHandleClassInterfaceRequest( xUSB_REQUEST *pxRequest )
{
switch( pxRequest->ucRequest )
{
case usbSEND_ENCAPSULATED_COMMAND:
prvSendStall();
break;
case usbGET_ENCAPSULATED_RESPONSE:
prvSendStall();
break;
case usbSET_LINE_CODING:
/* Set line coding - baud rate, data bits, parity, stop bits */
prvSendZLP();
memcpy( ( void * ) pxLineCoding, pxControlRx.ucBuffer, sizeof( pxLineCoding ) );
break;
case usbGET_LINE_CODING:
/* Get line coding */
prvSendControlData( (unsigned char *) &pxLineCoding, pxRequest->usLength, sizeof( pxLineCoding ), pdFALSE );
break;
case usbSET_CONTROL_LINE_STATE:
/* D0: 1=DTR, 0=No DTR, D1: 1=Activate Carrier, 0=Deactivate carrier (RTS, half-duplex) */
prvSendZLP();
ucControlState = pxRequest->usValue;
break;
default:
prvSendStall();
break;
}
}
/*------------------------------------------------------------*/
static void prvGetStandardInterfaceDescriptor( xUSB_REQUEST *pxRequest )
{
switch( ( pxRequest->usValue & ( unsigned short ) 0xff00 ) >> 8 )
{
default:
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 vDetachUSBInterface( void)
{
/* 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;
/* Disable pull up */
AT91C_BASE_PIOA->PIO_SODR = AT91C_PIO_PA16;
}
/*-----------------------------------------------------------*/
static void vInitUSBInterface( void )
{
extern void ( vUSB_ISR_Wrapper )( void );
/* Create the queue used to communicate between the USB ISR and task. */
xUSBInterruptQueue = xQueueCreate( usbQUEUE_LENGTH + 1, sizeof( xISRStatus * ) );
/* Create the queues used to hold Rx and Tx characters. */
xRxCDC = xQueueCreate( USB_CDC_QUEUE_SIZE, ( unsigned char ) sizeof( signed char ) );
xTxCDC = xQueueCreate( USB_CDC_QUEUE_SIZE + 1, ( unsigned char ) sizeof( signed char ) );
if( (!xUSBInterruptQueue) || (!xRxCDC) || (!xTxCDC) )
{
/* Not enough RAM to create queues!. */
return;
}
/* Initialise a few state variables. */
pxControlTx.ulNextCharIndex = ( unsigned long ) 0;
pxControlRx.ulNextCharIndex = ( unsigned long ) 0;
ucUSBConfig = ( unsigned char ) 0;
eDriverState = eNOTHING;
ucControlState = 0;
uiCurrentBank = AT91C_UDP_RX_DATA_BK0;
/* 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_CSR[ 2 ] = ( unsigned long ) 0x00;
AT91C_BASE_UDP->UDP_CSR[ 3 ] = ( 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( pxControlTx.ucBuffer, pucData, ulLengthToSend );
/* Reinitialise the buffer index so we start sending from the start of
the data. */
pxControlTx.ulTotalDataLength = ulLengthToSend;
pxControlTx.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( pxControlTx.ulTotalDataLength > pxControlTx.ulNextCharIndex )
{
ulLengthLeftToSend = pxControlTx.ulTotalDataLength - pxControlTx.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 ] = pxControlTx.ucBuffer[ pxControlTx.ulNextCharIndex ];
ulNextLength--;
pxControlTx.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 )
{
prvSendZLP();
eDriverState = eNOTHING;
}
}
}
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