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*/ | |
/* | |
* Interrupt driven driver for the EMAC peripheral. This driver is not | |
* reentrant, re-entrancy is handled by a semaphore at the network interface | |
* level. | |
*/ | |
/* | |
Changes from V3.2.2 | |
+ Corrected the byte order when writing the MAC address to the MAC. | |
+ Support added for MII interfaces. Previously only RMII was supported. | |
Changes from V3.2.3 | |
+ The MII interface is now the default. | |
+ Modified the initialisation sequence slightly to allow auto init more | |
time to complete. | |
Changes from V4.0.1 | |
+ Made the function vClearEMACTxBuffer() more robust by moving the index | |
manipulation into the if() statement. This allows the tx interrupt to | |
execute even when there is no data to handle. | |
Changes from V4.0.4 | |
+ Corrected the Rx frame length mask when obtaining the length from the | |
rx descriptor. | |
*/ | |
/* Standard includes. */ | |
#include <string.h> | |
/* Scheduler includes. */ | |
#include "FreeRTOS.h" | |
#include "semphr.h" | |
#include "task.h" | |
/* Demo app includes. */ | |
#include "SAM7_EMAC.h" | |
/* Hardware specific includes. */ | |
#include "Emac.h" | |
#include "mii.h" | |
#include "AT91SAM7X256.h" | |
/* USE_RMII_INTERFACE must be defined as 1 to use an RMII interface, or 0 | |
to use an MII interface. */ | |
#define USE_RMII_INTERFACE 0 | |
/* The buffer addresses written into the descriptors must be aligned so the | |
last few bits are zero. These bits have special meaning for the EMAC | |
peripheral and cannot be used as part of the address. */ | |
#define emacADDRESS_MASK ( ( unsigned long ) 0xFFFFFFFC ) | |
/* Bit used within the address stored in the descriptor to mark the last | |
descriptor in the array. */ | |
#define emacRX_WRAP_BIT ( ( unsigned long ) 0x02 ) | |
/* Bit used within the Tx descriptor status to indicate whether the | |
descriptor is under the control of the EMAC or the software. */ | |
#define emacTX_BUF_USED ( ( unsigned long ) 0x80000000 ) | |
/* A short delay is used to wait for a buffer to become available, should | |
one not be immediately available when trying to transmit a frame. */ | |
#define emacBUFFER_WAIT_DELAY ( 2 ) | |
#define emacMAX_WAIT_CYCLES ( ( portBASE_TYPE ) ( configTICK_RATE_HZ / 40 ) ) | |
/* The time to block waiting for input. */ | |
#define emacBLOCK_TIME_WAITING_FOR_INPUT ( ( TickType_t ) 100 ) | |
/* Peripheral setup for the EMAC. */ | |
#define emacPERIPHERAL_A_SETUP ( ( unsigned long ) AT91C_PB2_ETX0 ) | \ | |
( ( unsigned long ) AT91C_PB12_ETXER ) | \ | |
( ( unsigned long ) AT91C_PB16_ECOL ) | \ | |
( ( unsigned long ) AT91C_PB11_ETX3 ) | \ | |
( ( unsigned long ) AT91C_PB6_ERX1 ) | \ | |
( ( unsigned long ) AT91C_PB15_ERXDV ) | \ | |
( ( unsigned long ) AT91C_PB13_ERX2 ) | \ | |
( ( unsigned long ) AT91C_PB3_ETX1 ) | \ | |
( ( unsigned long ) AT91C_PB8_EMDC ) | \ | |
( ( unsigned long ) AT91C_PB5_ERX0 ) | \ | |
( ( unsigned long ) AT91C_PB14_ERX3 ) | \ | |
( ( unsigned long ) AT91C_PB4_ECRS_ECRSDV ) | \ | |
( ( unsigned long ) AT91C_PB1_ETXEN ) | \ | |
( ( unsigned long ) AT91C_PB10_ETX2 ) | \ | |
( ( unsigned long ) AT91C_PB0_ETXCK_EREFCK ) | \ | |
( ( unsigned long ) AT91C_PB9_EMDIO ) | \ | |
( ( unsigned long ) AT91C_PB7_ERXER ) | \ | |
( ( unsigned long ) AT91C_PB17_ERXCK ); | |
/* Misc defines. */ | |
#define emacINTERRUPT_LEVEL ( 5 ) | |
#define emacNO_DELAY ( 0 ) | |
#define emacTOTAL_FRAME_HEADER_SIZE ( 54 ) | |
#define emacPHY_INIT_DELAY ( 5000 / portTICK_PERIOD_MS ) | |
#define emacRESET_KEY ( ( unsigned long ) 0xA5000000 ) | |
#define emacRESET_LENGTH ( ( unsigned long ) ( 0x01 << 8 ) ) | |
/* The Atmel header file only defines the TX frame length mask. */ | |
#define emacRX_LENGTH_FRAME ( 0xfff ) | |
/*-----------------------------------------------------------*/ | |
/* Buffer written to by the EMAC DMA. Must be aligned as described by the | |
comment above the emacADDRESS_MASK definition. */ | |
static volatile char pcRxBuffer[ NB_RX_BUFFERS * ETH_RX_BUFFER_SIZE ] __attribute__ ((aligned (8))); | |
/* Buffer read by the EMAC DMA. Must be aligned as described by the comment | |
above the emacADDRESS_MASK definition. */ | |
static char pcTxBuffer[ NB_TX_BUFFERS * ETH_TX_BUFFER_SIZE ] __attribute__ ((aligned (8))); | |
/* Descriptors used to communicate between the program and the EMAC peripheral. | |
These descriptors hold the locations and state of the Rx and Tx buffers. */ | |
static volatile AT91S_TxTdDescriptor xTxDescriptors[ NB_TX_BUFFERS ]; | |
static volatile AT91S_RxTdDescriptor xRxDescriptors[ NB_RX_BUFFERS ]; | |
/* The IP and Ethernet addresses are read from the header files. */ | |
const char cMACAddress[ 6 ] = { emacETHADDR0, emacETHADDR1, emacETHADDR2, emacETHADDR3, emacETHADDR4, emacETHADDR5 }; | |
const unsigned char ucIPAddress[ 4 ] = { emacIPADDR0, emacIPADDR1, emacIPADDR2, emacIPADDR3 }; | |
/*-----------------------------------------------------------*/ | |
/* See the header file for descriptions of public functions. */ | |
/* | |
* Prototype for the EMAC interrupt function. | |
*/ | |
void vEMACISR_Wrapper( void ) __attribute__ ((naked)); | |
/* | |
* Initialise both the Tx and Rx descriptors used by the EMAC. | |
*/ | |
static void prvSetupDescriptors(void); | |
/* | |
* Write our MAC address into the EMAC. | |
*/ | |
static void prvSetupMACAddress( void ); | |
/* | |
* Configure the EMAC and AIC for EMAC interrupts. | |
*/ | |
static void prvSetupEMACInterrupt( void ); | |
/* | |
* Some initialisation functions taken from the Atmel EMAC sample code. | |
*/ | |
static void vReadPHY( unsigned char ucPHYAddress, unsigned char ucAddress, unsigned long *pulValue ); | |
static portBASE_TYPE xGetLinkSpeed( void ); | |
static portBASE_TYPE prvProbePHY( void ); | |
#if USE_RMII_INTERFACE != 1 | |
static void vWritePHY( unsigned char ucPHYAddress, unsigned char ucAddress, unsigned long ulValue); | |
#endif | |
/* The semaphore used by the EMAC ISR to wake the EMAC task. */ | |
static SemaphoreHandle_t xSemaphore = NULL; | |
/* Holds the index to the next buffer from which data will be read. */ | |
static volatile unsigned long ulNextRxBuffer = 0; | |
/*-----------------------------------------------------------*/ | |
/* See the header file for descriptions of public functions. */ | |
long lEMACSend( char *pcFrom, unsigned long ulLength, long lEndOfFrame ) | |
{ | |
static unsigned portBASE_TYPE uxTxBufferIndex = 0; | |
portBASE_TYPE xWaitCycles = 0; | |
long lReturn = pdPASS; | |
char *pcBuffer; | |
unsigned long ulLastBuffer, ulDataBuffered = 0, ulDataRemainingToSend, ulLengthToSend; | |
/* If the length of data to be transmitted is greater than each individual | |
transmit buffer then the data will be split into more than one buffer. | |
Loop until the entire length has been buffered. */ | |
while( ulDataBuffered < ulLength ) | |
{ | |
/* Is a buffer available? */ | |
while( !( xTxDescriptors[ uxTxBufferIndex ].U_Status.status & AT91C_TRANSMIT_OK ) ) | |
{ | |
/* There is no room to write the Tx data to the Tx buffer. Wait a | |
short while, then try again. */ | |
xWaitCycles++; | |
if( xWaitCycles > emacMAX_WAIT_CYCLES ) | |
{ | |
/* Give up. */ | |
lReturn = pdFAIL; | |
break; | |
} | |
else | |
{ | |
vTaskDelay( emacBUFFER_WAIT_DELAY ); | |
} | |
} | |
/* lReturn will only be pdPASS if a buffer is available. */ | |
if( lReturn == pdPASS ) | |
{ | |
portENTER_CRITICAL(); | |
{ | |
/* Get the address of the buffer from the descriptor, then copy | |
the data into the buffer. */ | |
pcBuffer = ( char * ) xTxDescriptors[ uxTxBufferIndex ].addr; | |
/* How much can we write to the buffer? */ | |
ulDataRemainingToSend = ulLength - ulDataBuffered; | |
if( ulDataRemainingToSend <= ETH_TX_BUFFER_SIZE ) | |
{ | |
/* We can write all the remaining bytes. */ | |
ulLengthToSend = ulDataRemainingToSend; | |
} | |
else | |
{ | |
/* We can not write more than ETH_TX_BUFFER_SIZE in one go. */ | |
ulLengthToSend = ETH_TX_BUFFER_SIZE; | |
} | |
/* Copy the data into the buffer. */ | |
memcpy( ( void * ) pcBuffer, ( void * ) &( pcFrom[ ulDataBuffered ] ), ulLengthToSend ); | |
ulDataBuffered += ulLengthToSend; | |
/* Is this the last data for the frame? */ | |
if( lEndOfFrame && ( ulDataBuffered >= ulLength ) ) | |
{ | |
/* No more data remains for this frame so we can start the | |
transmission. */ | |
ulLastBuffer = AT91C_LAST_BUFFER; | |
} | |
else | |
{ | |
/* More data to come for this frame. */ | |
ulLastBuffer = 0; | |
} | |
/* Fill out the necessary in the descriptor to get the data sent, | |
then move to the next descriptor, wrapping if necessary. */ | |
if( uxTxBufferIndex >= ( NB_TX_BUFFERS - 1 ) ) | |
{ | |
xTxDescriptors[ uxTxBufferIndex ].U_Status.status = ( ulLengthToSend & ( unsigned long ) AT91C_LENGTH_FRAME ) | |
| ulLastBuffer | |
| AT91C_TRANSMIT_WRAP; | |
uxTxBufferIndex = 0; | |
} | |
else | |
{ | |
xTxDescriptors[ uxTxBufferIndex ].U_Status.status = ( ulLengthToSend & ( unsigned long ) AT91C_LENGTH_FRAME ) | |
| ulLastBuffer; | |
uxTxBufferIndex++; | |
} | |
/* If this is the last buffer to be sent for this frame we can | |
start the transmission. */ | |
if( ulLastBuffer ) | |
{ | |
AT91C_BASE_EMAC->EMAC_NCR |= AT91C_EMAC_TSTART; | |
} | |
} | |
portEXIT_CRITICAL(); | |
} | |
else | |
{ | |
break; | |
} | |
} | |
return lReturn; | |
} | |
/*-----------------------------------------------------------*/ | |
/* See the header file for descriptions of public functions. */ | |
unsigned long ulEMACInputLength( void ) | |
{ | |
register unsigned long ulIndex, ulLength = 0; | |
/* Skip any fragments. We are looking for the first buffer that contains | |
data and has the SOF (start of frame) bit set. */ | |
while( ( xRxDescriptors[ ulNextRxBuffer ].addr & AT91C_OWNERSHIP_BIT ) && !( xRxDescriptors[ ulNextRxBuffer ].U_Status.status & AT91C_SOF ) ) | |
{ | |
/* Ignoring this buffer. Mark it as free again. */ | |
xRxDescriptors[ ulNextRxBuffer ].addr &= ~( AT91C_OWNERSHIP_BIT ); | |
ulNextRxBuffer++; | |
if( ulNextRxBuffer >= NB_RX_BUFFERS ) | |
{ | |
ulNextRxBuffer = 0; | |
} | |
} | |
/* We are going to walk through the descriptors that make up this frame, | |
but don't want to alter ulNextRxBuffer as this would prevent vEMACRead() | |
from finding the data. Therefore use a copy of ulNextRxBuffer instead. */ | |
ulIndex = ulNextRxBuffer; | |
/* Walk through the descriptors until we find the last buffer for this | |
frame. The last buffer will give us the length of the entire frame. */ | |
while( ( xRxDescriptors[ ulIndex ].addr & AT91C_OWNERSHIP_BIT ) && !ulLength ) | |
{ | |
ulLength = xRxDescriptors[ ulIndex ].U_Status.status & emacRX_LENGTH_FRAME; | |
/* Increment to the next buffer, wrapping if necessary. */ | |
ulIndex++; | |
if( ulIndex >= NB_RX_BUFFERS ) | |
{ | |
ulIndex = 0; | |
} | |
} | |
return ulLength; | |
} | |
/*-----------------------------------------------------------*/ | |
/* See the header file for descriptions of public functions. */ | |
void vEMACRead( char *pcTo, unsigned long ulSectionLength, unsigned long ulTotalFrameLength ) | |
{ | |
static unsigned long ulSectionBytesReadSoFar = 0, ulBufferPosition = 0, ulFameBytesReadSoFar = 0; | |
static char *pcSource; | |
register unsigned long ulBytesRemainingInBuffer, ulRemainingSectionBytes; | |
/* Read ulSectionLength bytes from the Rx buffers. This is not necessarily any | |
correspondence between the length of our Rx buffers, and the length of the | |
data we are returning or the length of the data being requested. Therefore, | |
between calls we have to remember not only which buffer we are currently | |
processing, but our position within that buffer. This would be greatly | |
simplified if PBUF_POOL_BUFSIZE could be guaranteed to be greater than | |
the size of each Rx buffer, and that memory fragmentation did not occur. | |
This function should only be called after a call to ulEMACInputLength(). | |
This will ensure ulNextRxBuffer is set to the correct buffer. */ | |
/* vEMACRead is called with pcTo set to NULL to indicate that we are about | |
to read a new frame. Any fragments remaining in the frame we were | |
processing during the last call should be dropped. */ | |
if( pcTo == NULL ) | |
{ | |
/* How many bytes are indicated as being in this buffer? If none then | |
the buffer is completely full and the frame is contained within more | |
than one buffer. */ | |
/* Reset our state variables ready for the next read from this buffer. */ | |
pcSource = ( char * )( xRxDescriptors[ ulNextRxBuffer ].addr & emacADDRESS_MASK ); | |
ulFameBytesReadSoFar = ( unsigned long ) 0; | |
ulBufferPosition = ( unsigned long ) 0; | |
} | |
else | |
{ | |
/* Loop until we have obtained the required amount of data. */ | |
ulSectionBytesReadSoFar = 0; | |
while( ulSectionBytesReadSoFar < ulSectionLength ) | |
{ | |
/* We may have already read some data from this buffer. How much | |
data remains in the buffer? */ | |
ulBytesRemainingInBuffer = ( ETH_RX_BUFFER_SIZE - ulBufferPosition ); | |
/* How many more bytes do we need to read before we have the | |
required amount of data? */ | |
ulRemainingSectionBytes = ulSectionLength - ulSectionBytesReadSoFar; | |
/* Do we want more data than remains in the buffer? */ | |
if( ulRemainingSectionBytes > ulBytesRemainingInBuffer ) | |
{ | |
/* We want more data than remains in the buffer so we can | |
write the remains of the buffer to the destination, then move | |
onto the next buffer to get the rest. */ | |
memcpy( &( pcTo[ ulSectionBytesReadSoFar ] ), &( pcSource[ ulBufferPosition ] ), ulBytesRemainingInBuffer ); | |
ulSectionBytesReadSoFar += ulBytesRemainingInBuffer; | |
ulFameBytesReadSoFar += ulBytesRemainingInBuffer; | |
/* Mark the buffer as free again. */ | |
xRxDescriptors[ ulNextRxBuffer ].addr &= ~( AT91C_OWNERSHIP_BIT ); | |
/* Move onto the next buffer. */ | |
ulNextRxBuffer++; | |
if( ulNextRxBuffer >= NB_RX_BUFFERS ) | |
{ | |
ulNextRxBuffer = ( unsigned long ) 0; | |
} | |
/* Reset the variables for the new buffer. */ | |
pcSource = ( char * )( xRxDescriptors[ ulNextRxBuffer ].addr & emacADDRESS_MASK ); | |
ulBufferPosition = ( unsigned long ) 0; | |
} | |
else | |
{ | |
/* We have enough data in this buffer to send back. Read out | |
enough data and remember how far we read up to. */ | |
memcpy( &( pcTo[ ulSectionBytesReadSoFar ] ), &( pcSource[ ulBufferPosition ] ), ulRemainingSectionBytes ); | |
/* There may be more data in this buffer yet. Increment our | |
position in this buffer past the data we have just read. */ | |
ulBufferPosition += ulRemainingSectionBytes; | |
ulSectionBytesReadSoFar += ulRemainingSectionBytes; | |
ulFameBytesReadSoFar += ulRemainingSectionBytes; | |
/* Have we now finished with this buffer? */ | |
if( ( ulBufferPosition >= ETH_RX_BUFFER_SIZE ) || ( ulFameBytesReadSoFar >= ulTotalFrameLength ) ) | |
{ | |
/* Mark the buffer as free again. */ | |
xRxDescriptors[ ulNextRxBuffer ].addr &= ~( AT91C_OWNERSHIP_BIT ); | |
/* Move onto the next buffer. */ | |
ulNextRxBuffer++; | |
if( ulNextRxBuffer >= NB_RX_BUFFERS ) | |
{ | |
ulNextRxBuffer = 0; | |
} | |
pcSource = ( char * )( xRxDescriptors[ ulNextRxBuffer ].addr & emacADDRESS_MASK ); | |
ulBufferPosition = 0; | |
} | |
} | |
} | |
} | |
} | |
/*-----------------------------------------------------------*/ | |
/* See the header file for descriptions of public functions. */ | |
SemaphoreHandle_t xEMACInit( void ) | |
{ | |
/* Code supplied by Atmel -------------------------------*/ | |
/* Disable pull up on RXDV => PHY normal mode (not in test mode), | |
PHY has internal pull down. */ | |
AT91C_BASE_PIOB->PIO_PPUDR = 1 << 15; | |
#if USE_RMII_INTERFACE != 1 | |
/* PHY has internal pull down : set MII mode. */ | |
AT91C_BASE_PIOB->PIO_PPUDR = 1 << 16; | |
#endif | |
/* Clear PB18 <=> PHY powerdown. */ | |
AT91C_BASE_PIOB->PIO_PER = 1 << 18; | |
AT91C_BASE_PIOB->PIO_OER = 1 << 18; | |
AT91C_BASE_PIOB->PIO_CODR = 1 << 18; | |
/* After PHY power up, hardware reset. */ | |
AT91C_BASE_RSTC->RSTC_RMR = emacRESET_KEY | emacRESET_LENGTH; | |
AT91C_BASE_RSTC->RSTC_RCR = emacRESET_KEY | AT91C_RSTC_EXTRST; | |
/* Wait for hardware reset end. */ | |
while( !( AT91C_BASE_RSTC->RSTC_RSR & AT91C_RSTC_NRSTL ) ) | |
{ | |
__asm volatile ( "NOP" ); | |
} | |
__asm volatile ( "NOP" ); | |
/* Setup the pins. */ | |
AT91C_BASE_PIOB->PIO_ASR = emacPERIPHERAL_A_SETUP; | |
AT91C_BASE_PIOB->PIO_PDR = emacPERIPHERAL_A_SETUP; | |
/* Enable com between EMAC PHY. | |
Enable management port. */ | |
AT91C_BASE_EMAC->EMAC_NCR |= AT91C_EMAC_MPE; | |
/* MDC = MCK/32. */ | |
AT91C_BASE_EMAC->EMAC_NCFGR |= ( 2 ) << 10; | |
/* Wait for PHY auto init end (rather crude delay!). */ | |
vTaskDelay( emacPHY_INIT_DELAY ); | |
/* PHY configuration. */ | |
#if USE_RMII_INTERFACE != 1 | |
{ | |
unsigned long ulControl; | |
/* PHY has internal pull down : disable MII isolate. */ | |
vReadPHY( AT91C_PHY_ADDR, MII_BMCR, &ulControl ); | |
vReadPHY( AT91C_PHY_ADDR, MII_BMCR, &ulControl ); | |
ulControl &= ~BMCR_ISOLATE; | |
vWritePHY( AT91C_PHY_ADDR, MII_BMCR, ulControl ); | |
} | |
#endif | |
/* Disable management port again. */ | |
AT91C_BASE_EMAC->EMAC_NCR &= ~AT91C_EMAC_MPE; | |
#if USE_RMII_INTERFACE != 1 | |
/* Enable EMAC in MII mode, enable clock ERXCK and ETXCK. */ | |
AT91C_BASE_EMAC->EMAC_USRIO = AT91C_EMAC_CLKEN ; | |
#else | |
/* Enable EMAC in RMII mode, enable RMII clock (50MHz from oscillator | |
on ERFCK). */ | |
AT91C_BASE_EMAC->EMAC_USRIO = AT91C_EMAC_RMII | AT91C_EMAC_CLKEN ; | |
#endif | |
/* End of code supplied by Atmel ------------------------*/ | |
/* Setup the buffers and descriptors. */ | |
prvSetupDescriptors(); | |
/* Load our MAC address into the EMAC. */ | |
prvSetupMACAddress(); | |
/* Are we connected? */ | |
if( prvProbePHY() ) | |
{ | |
/* Enable the interrupt! */ | |
portENTER_CRITICAL(); | |
{ | |
prvSetupEMACInterrupt(); | |
vPassEMACSemaphore( xSemaphore ); | |
} | |
portEXIT_CRITICAL(); | |
} | |
return xSemaphore; | |
} | |
/*-----------------------------------------------------------*/ | |
/* See the header file for descriptions of public functions. */ | |
void vClearEMACTxBuffer( void ) | |
{ | |
static unsigned portBASE_TYPE uxNextBufferToClear = 0; | |
/* Called on Tx interrupt events to reset the AT91C_TRANSMIT_OK bit in each | |
Tx buffer within the frame just transmitted. This marks all the buffers | |
as available again. | |
The first buffer in the frame should have the bit set automatically. */ | |
if( xTxDescriptors[ uxNextBufferToClear ].U_Status.status & AT91C_TRANSMIT_OK ) | |
{ | |
/* Loop through the other buffers in the frame. */ | |
while( !( xTxDescriptors[ uxNextBufferToClear ].U_Status.status & AT91C_LAST_BUFFER ) ) | |
{ | |
uxNextBufferToClear++; | |
if( uxNextBufferToClear >= NB_TX_BUFFERS ) | |
{ | |
uxNextBufferToClear = 0; | |
} | |
xTxDescriptors[ uxNextBufferToClear ].U_Status.status |= AT91C_TRANSMIT_OK; | |
} | |
/* Start with the next buffer the next time a Tx interrupt is called. */ | |
uxNextBufferToClear++; | |
/* Do we need to wrap back to the first buffer? */ | |
if( uxNextBufferToClear >= NB_TX_BUFFERS ) | |
{ | |
uxNextBufferToClear = 0; | |
} | |
} | |
} | |
/*-----------------------------------------------------------*/ | |
static void prvSetupDescriptors(void) | |
{ | |
unsigned portBASE_TYPE xIndex; | |
unsigned long ulAddress; | |
/* Initialise xRxDescriptors descriptor. */ | |
for( xIndex = 0; xIndex < NB_RX_BUFFERS; ++xIndex ) | |
{ | |
/* Calculate the address of the nth buffer within the array. */ | |
ulAddress = ( unsigned long )( pcRxBuffer + ( xIndex * ETH_RX_BUFFER_SIZE ) ); | |
/* Write the buffer address into the descriptor. The DMA will place | |
the data at this address when this descriptor is being used. Mask off | |
the bottom bits of the address as these have special meaning. */ | |
xRxDescriptors[ xIndex ].addr = ulAddress & emacADDRESS_MASK; | |
} | |
/* The last buffer has the wrap bit set so the EMAC knows to wrap back | |
to the first buffer. */ | |
xRxDescriptors[ NB_RX_BUFFERS - 1 ].addr |= emacRX_WRAP_BIT; | |
/* Initialise xTxDescriptors. */ | |
for( xIndex = 0; xIndex < NB_TX_BUFFERS; ++xIndex ) | |
{ | |
/* Calculate the address of the nth buffer within the array. */ | |
ulAddress = ( unsigned long )( pcTxBuffer + ( xIndex * ETH_TX_BUFFER_SIZE ) ); | |
/* Write the buffer address into the descriptor. The DMA will read | |
data from here when the descriptor is being used. */ | |
xTxDescriptors[ xIndex ].addr = ulAddress & emacADDRESS_MASK; | |
xTxDescriptors[ xIndex ].U_Status.status = AT91C_TRANSMIT_OK; | |
} | |
/* The last buffer has the wrap bit set so the EMAC knows to wrap back | |
to the first buffer. */ | |
xTxDescriptors[ NB_TX_BUFFERS - 1 ].U_Status.status = AT91C_TRANSMIT_WRAP | AT91C_TRANSMIT_OK; | |
/* Tell the EMAC where to find the descriptors. */ | |
AT91C_BASE_EMAC->EMAC_RBQP = ( unsigned long ) xRxDescriptors; | |
AT91C_BASE_EMAC->EMAC_TBQP = ( unsigned long ) xTxDescriptors; | |
/* Clear all the bits in the receive status register. */ | |
AT91C_BASE_EMAC->EMAC_RSR = ( AT91C_EMAC_OVR | AT91C_EMAC_REC | AT91C_EMAC_BNA ); | |
/* Enable the copy of data into the buffers, ignore broadcasts, | |
and don't copy FCS. */ | |
AT91C_BASE_EMAC->EMAC_NCFGR |= ( AT91C_EMAC_CAF | AT91C_EMAC_NBC | AT91C_EMAC_DRFCS); | |
/* Enable Rx and Tx, plus the stats register. */ | |
AT91C_BASE_EMAC->EMAC_NCR |= ( AT91C_EMAC_TE | AT91C_EMAC_RE | AT91C_EMAC_WESTAT ); | |
} | |
/*-----------------------------------------------------------*/ | |
static void prvSetupMACAddress( void ) | |
{ | |
/* Must be written SA1L then SA1H. */ | |
AT91C_BASE_EMAC->EMAC_SA1L = ( ( unsigned long ) cMACAddress[ 3 ] << 24 ) | | |
( ( unsigned long ) cMACAddress[ 2 ] << 16 ) | | |
( ( unsigned long ) cMACAddress[ 1 ] << 8 ) | | |
cMACAddress[ 0 ]; | |
AT91C_BASE_EMAC->EMAC_SA1H = ( ( unsigned long ) cMACAddress[ 5 ] << 8 ) | | |
cMACAddress[ 4 ]; | |
} | |
/*-----------------------------------------------------------*/ | |
static void prvSetupEMACInterrupt( void ) | |
{ | |
/* Create the semaphore used to trigger the EMAC task. */ | |
vSemaphoreCreateBinary( xSemaphore ); | |
if( xSemaphore ) | |
{ | |
/* We start by 'taking' the semaphore so the ISR can 'give' it when the | |
first interrupt occurs. */ | |
xSemaphoreTake( xSemaphore, emacNO_DELAY ); | |
portENTER_CRITICAL(); | |
{ | |
/* We want to interrupt on Rx and Tx events. */ | |
AT91C_BASE_EMAC->EMAC_IER = AT91C_EMAC_RCOMP | AT91C_EMAC_TCOMP; | |
/* Enable the interrupts in the AIC. */ | |
AT91F_AIC_ConfigureIt( AT91C_ID_EMAC, emacINTERRUPT_LEVEL, AT91C_AIC_SRCTYPE_INT_HIGH_LEVEL, ( void (*)( void ) ) vEMACISR_Wrapper ); | |
AT91C_BASE_AIC->AIC_IECR = 0x1 << AT91C_ID_EMAC; | |
} | |
portEXIT_CRITICAL(); | |
} | |
} | |
/* | |
* The following functions are initialisation functions taken from the Atmel | |
* EMAC sample code. | |
*/ | |
static portBASE_TYPE prvProbePHY( void ) | |
{ | |
unsigned long ulPHYId1, ulPHYId2, ulStatus; | |
portBASE_TYPE xReturn = pdPASS; | |
/* Code supplied by Atmel (reformatted) -----------------*/ | |
/* Enable management port */ | |
AT91C_BASE_EMAC->EMAC_NCR |= AT91C_EMAC_MPE; | |
AT91C_BASE_EMAC->EMAC_NCFGR |= ( 2 ) << 10; | |
/* Read the PHY ID. */ | |
vReadPHY( AT91C_PHY_ADDR, MII_PHYSID1, &ulPHYId1 ); | |
vReadPHY(AT91C_PHY_ADDR, MII_PHYSID2, &ulPHYId2 ); | |
/* AMD AM79C875: | |
PHY_ID1 = 0x0022 | |
PHY_ID2 = 0x5541 | |
Bits 3:0 Revision Number Four bit manufacturer?s revision number. | |
0001 stands for Rev. A, etc. | |
*/ | |
if( ( ( ulPHYId1 << 16 ) | ( ulPHYId2 & 0xfff0 ) ) != MII_DM9161_ID ) | |
{ | |
/* Did not expect this ID. */ | |
xReturn = pdFAIL; | |
} | |
else | |
{ | |
ulStatus = xGetLinkSpeed(); | |
if( ulStatus != pdPASS ) | |
{ | |
xReturn = pdFAIL; | |
} | |
} | |
/* Disable management port */ | |
AT91C_BASE_EMAC->EMAC_NCR &= ~AT91C_EMAC_MPE; | |
/* End of code supplied by Atmel ------------------------*/ | |
return xReturn; | |
} | |
/*-----------------------------------------------------------*/ | |
static void vReadPHY( unsigned char ucPHYAddress, unsigned char ucAddress, unsigned long *pulValue ) | |
{ | |
/* Code supplied by Atmel (reformatted) ----------------------*/ | |
AT91C_BASE_EMAC->EMAC_MAN = (AT91C_EMAC_SOF & (0x01<<30)) | |
| (2 << 16) | (2 << 28) | |
| ((ucPHYAddress & 0x1f) << 23) | |
| (ucAddress << 18); | |
/* Wait until IDLE bit in Network Status register is cleared. */ | |
while( !( AT91C_BASE_EMAC->EMAC_NSR & AT91C_EMAC_IDLE ) ) | |
{ | |
__asm( "NOP" ); | |
} | |
*pulValue = ( AT91C_BASE_EMAC->EMAC_MAN & 0x0000ffff ); | |
/* End of code supplied by Atmel ------------------------*/ | |
} | |
/*-----------------------------------------------------------*/ | |
#if USE_RMII_INTERFACE != 1 | |
static void vWritePHY( unsigned char ucPHYAddress, unsigned char ucAddress, unsigned long ulValue ) | |
{ | |
/* Code supplied by Atmel (reformatted) ----------------------*/ | |
AT91C_BASE_EMAC->EMAC_MAN = (( AT91C_EMAC_SOF & (0x01<<30)) | |
| (2 << 16) | (1 << 28) | |
| ((ucPHYAddress & 0x1f) << 23) | |
| (ucAddress << 18)) | |
| (ulValue & 0xffff); | |
/* Wait until IDLE bit in Network Status register is cleared */ | |
while( !( AT91C_BASE_EMAC->EMAC_NSR & AT91C_EMAC_IDLE ) ) | |
{ | |
__asm( "NOP" ); | |
}; | |
/* End of code supplied by Atmel ------------------------*/ | |
} | |
#endif | |
/*-----------------------------------------------------------*/ | |
static portBASE_TYPE xGetLinkSpeed( void ) | |
{ | |
unsigned long ulBMSR, ulBMCR, ulLPA, ulMACCfg, ulSpeed, ulDuplex; | |
/* Code supplied by Atmel (reformatted) -----------------*/ | |
/* Link status is latched, so read twice to get current value */ | |
vReadPHY(AT91C_PHY_ADDR, MII_BMSR, &ulBMSR); | |
vReadPHY(AT91C_PHY_ADDR, MII_BMSR, &ulBMSR); | |
if( !( ulBMSR & BMSR_LSTATUS ) ) | |
{ | |
/* No Link. */ | |
return pdFAIL; | |
} | |
vReadPHY(AT91C_PHY_ADDR, MII_BMCR, &ulBMCR); | |
if (ulBMCR & BMCR_ANENABLE) | |
{ | |
/* AutoNegotiation is enabled. */ | |
if (!(ulBMSR & BMSR_ANEGCOMPLETE)) | |
{ | |
/* Auto-negotitation in progress. */ | |
return pdFAIL; | |
} | |
vReadPHY(AT91C_PHY_ADDR, MII_LPA, &ulLPA); | |
if( ( ulLPA & LPA_100FULL ) || ( ulLPA & LPA_100HALF ) ) | |
{ | |
ulSpeed = SPEED_100; | |
} | |
else | |
{ | |
ulSpeed = SPEED_10; | |
} | |
if( ( ulLPA & LPA_100FULL ) || ( ulLPA & LPA_10FULL ) ) | |
{ | |
ulDuplex = DUPLEX_FULL; | |
} | |
else | |
{ | |
ulDuplex = DUPLEX_HALF; | |
} | |
} | |
else | |
{ | |
ulSpeed = ( ulBMCR & BMCR_SPEED100 ) ? SPEED_100 : SPEED_10; | |
ulDuplex = ( ulBMCR & BMCR_FULLDPLX ) ? DUPLEX_FULL : DUPLEX_HALF; | |
} | |
/* Update the MAC */ | |
ulMACCfg = AT91C_BASE_EMAC->EMAC_NCFGR & ~( AT91C_EMAC_SPD | AT91C_EMAC_FD ); | |
if( ulSpeed == SPEED_100 ) | |
{ | |
if( ulDuplex == DUPLEX_FULL ) | |
{ | |
/* 100 Full Duplex */ | |
AT91C_BASE_EMAC->EMAC_NCFGR = ulMACCfg | AT91C_EMAC_SPD | AT91C_EMAC_FD; | |
} | |
else | |
{ | |
/* 100 Half Duplex */ | |
AT91C_BASE_EMAC->EMAC_NCFGR = ulMACCfg | AT91C_EMAC_SPD; | |
} | |
} | |
else | |
{ | |
if (ulDuplex == DUPLEX_FULL) | |
{ | |
/* 10 Full Duplex */ | |
AT91C_BASE_EMAC->EMAC_NCFGR = ulMACCfg | AT91C_EMAC_FD; | |
} | |
else | |
{ /* 10 Half Duplex */ | |
AT91C_BASE_EMAC->EMAC_NCFGR = ulMACCfg; | |
} | |
} | |
/* End of code supplied by Atmel ------------------------*/ | |
return pdPASS; | |
} | |
/*-----------------------------------------------------------*/ | |
void vEMACWaitForInput( void ) | |
{ | |
/* Just wait until we are signled from an ISR that data is available, or | |
we simply time out. */ | |
xSemaphoreTake( xSemaphore, emacBLOCK_TIME_WAITING_FOR_INPUT ); | |
} |