FreeRTOS/Demo/ARM7_LPC2368_Eclipse/RTOSDemo/webserver/emac.c - third_party/github/FreeRTOS/FreeRTOS-Kernel - Git at Google

 /******************************************************************
  *****                                                        *****
  *****  Name: cs8900.c                                        *****
  *****  Ver.: 1.0                                             *****
  *****  Date: 07/05/2001                                      *****
  *****  Auth: Andreas Dannenberg                              *****
  *****        HTWK Leipzig                                    *****
  *****        university of applied sciences                  *****
  *****        Germany                                         *****
  *****  Func: ethernet packet-driver for use with LAN-        *****
  *****        controller CS8900 from Crystal/Cirrus Logic     *****
  *****                                                        *****
  *****  Keil: Module modified for use with Philips            *****
  *****        LPC2378 EMAC Ethernet controller                *****
  *****                                                        *****
  ******************************************************************/

 /* Adapted from file originally written by Andreas Dannenberg.  Supplied with permission. */

 #include "FreeRTOS.h"
 #include "semphr.h"
 #include "task.h"
 #include "emac.h"

 /* The semaphore used to wake the uIP task when data arives. */
 xSemaphoreHandle xEMACSemaphore = NULL;

 static unsigned short *rptr;
 static unsigned short *tptr;

 // easyWEB internal function
 // help function to swap the byte order of a WORD

 static unsigned short SwapBytes(unsigned short Data)
 {
   return (Data >> 8) | (Data << 8);
 }

 // Keil: function added to write PHY
 void write_PHY (int PhyReg, int Value)
 {
   unsigned int tout;

   MAC_MADR = DP83848C_DEF_ADR | PhyReg;
   MAC_MWTD = Value;

   /* Wait utill operation completed */
   tout = 0;
   for (tout = 0; tout < MII_WR_TOUT; tout++) {
     if ((MAC_MIND & MIND_BUSY) == 0) {
       break;
     }
   }
 }


 // Keil: function added to read PHY
 unsigned short read_PHY (unsigned char PhyReg)
 {
   unsigned int tout;

   MAC_MADR = DP83848C_DEF_ADR | PhyReg;
   MAC_MCMD = MCMD_READ;

   /* Wait until operation completed */
   tout = 0;
   for (tout = 0; tout < MII_RD_TOUT; tout++) {
     if ((MAC_MIND & MIND_BUSY) == 0) {
       break;
     }
   }
   MAC_MCMD = 0;
   return (MAC_MRDD);
 }


 // Keil: function added to initialize Rx Descriptors
 void rx_descr_init (void)
 {
   unsigned int i;

   for (i = 0; i < NUM_RX_FRAG; i++) {
     RX_DESC_PACKET(i)  = RX_BUF(i);
     RX_DESC_CTRL(i)    = RCTRL_INT | (ETH_FRAG_SIZE-1);
     RX_STAT_INFO(i)    = 0;
     RX_STAT_HASHCRC(i) = 0;
   }

   /* Set EMAC Receive Descriptor Registers. */
   MAC_RXDESCRIPTOR    = RX_DESC_BASE;
   MAC_RXSTATUS        = RX_STAT_BASE;
   MAC_RXDESCRIPTORNUM = NUM_RX_FRAG-1;

   /* Rx Descriptors Point to 0 */
   MAC_RXCONSUMEINDEX  = 0;
 }


 // Keil: function added to initialize Tx Descriptors
 void tx_descr_init (void) {
   unsigned int i;

   for (i = 0; i < NUM_TX_FRAG; i++) {
     TX_DESC_PACKET(i) = TX_BUF(i);
     TX_DESC_CTRL(i)   = 0;
     TX_STAT_INFO(i)   = 0;
   }

   /* Set EMAC Transmit Descriptor Registers. */
   MAC_TXDESCRIPTOR    = TX_DESC_BASE;
   MAC_TXSTATUS        = TX_STAT_BASE;
   MAC_TXDESCRIPTORNUM = NUM_TX_FRAG-1;

   /* Tx Descriptors Point to 0 */
   MAC_TXPRODUCEINDEX  = 0;
 }


 // configure port-pins for use with LAN-controller,
 // reset it and send the configuration-sequence

 portBASE_TYPE Init_EMAC(void)
 {
 portBASE_TYPE xReturn = pdPASS;

 // Keil: function modified to access the EMAC
 // Initializes the EMAC ethernet controller
   volatile unsigned int regv,tout,id1,id2;

   /* Enable P1 Ethernet Pins. */
   PINSEL2 = configPINSEL2_VALUE;
   PINSEL3 = (PINSEL3 & ~0x0000000F) | 0x00000005;

   /* Power Up the EMAC controller. */
   PCONP |= 0x40000000;
   vTaskDelay( 1 );

   /* Reset all EMAC internal modules. */
   MAC_MAC1 = MAC1_RES_TX | MAC1_RES_MCS_TX | MAC1_RES_RX | MAC1_RES_MCS_RX | MAC1_SIM_RES | MAC1_SOFT_RES;
   MAC_COMMAND = CR_REG_RES | CR_TX_RES | CR_RX_RES;

   /* A short delay after reset. */
   vTaskDelay( 1 );

   /* Initialize MAC control registers. */
   MAC_MAC1 = MAC1_PASS_ALL;
   MAC_MAC2 = MAC2_CRC_EN | MAC2_PAD_EN;
   MAC_MAXF = ETH_MAX_FLEN;
   MAC_CLRT = CLRT_DEF;
   MAC_IPGR = IPGR_DEF;

   /* Enable Reduced MII interface. */
   MAC_COMMAND = CR_RMII | CR_PASS_RUNT_FRM;

   /* Reset Reduced MII Logic. */
   MAC_SUPP = SUPP_RES_RMII;
   MAC_SUPP = 0;

   /* Put the DP83848C in reset mode */
   write_PHY (PHY_REG_BMCR, 0x8000);
   write_PHY (PHY_REG_BMCR, 0x8000);

   /* Wait for hardware reset to end. */
   for (tout = 0; tout < 100; tout++) {
     vTaskDelay( 10 );
     regv = read_PHY (PHY_REG_BMCR);
     if (!(regv & 0x8000)) {
       /* Reset complete */
       break;
     }
   }

   /* Check if this is a DP83848C PHY. */
   id1 = read_PHY (PHY_REG_IDR1);
   id2 = read_PHY (PHY_REG_IDR2);
   if (((id1 << 16) | (id2 & 0xFFF0)) == DP83848C_ID) {
     /* Configure the PHY device */

     /* Use autonegotiation about the link speed. */
     write_PHY (PHY_REG_BMCR, PHY_AUTO_NEG);
     /* Wait to complete Auto_Negotiation. */
     for (tout = 0; tout < 10; tout++) {
       vTaskDelay( 100 );
       regv = read_PHY (PHY_REG_BMSR);
       if (regv & 0x0020) {
         /* Autonegotiation Complete. */
         break;
       }
     }
   }
   else
   {
     xReturn = pdFAIL;
   }

   /* Check the link status. */
   if( xReturn == pdPASS )
   {
     xReturn = pdFAIL;
     for (tout = 0; tout < 10; tout++) {
       vTaskDelay( 100 );
       regv = read_PHY (PHY_REG_STS);
       if (regv & 0x0001) {
         /* Link is on. */
         xReturn = pdPASS;
         break;
       }
     }
   }

   if( xReturn == pdPASS )
   {
     /* Configure Full/Half Duplex mode. */
     if (regv & 0x0004) {
       /* Full duplex is enabled. */
       MAC_MAC2    |= MAC2_FULL_DUP;
       MAC_COMMAND |= CR_FULL_DUP;
       MAC_IPGT     = IPGT_FULL_DUP;
     }
     else {
       /* Half duplex mode. */
       MAC_IPGT = IPGT_HALF_DUP;
     }

     /* Configure 100MBit/10MBit mode. */
     if (regv & 0x0002) {
       /* 10MBit mode. */
       MAC_SUPP = 0;
     }
     else {
       /* 100MBit mode. */
       MAC_SUPP = SUPP_SPEED;
     }

     /* Set the Ethernet MAC Address registers */
     MAC_SA0 = (emacETHADDR0 << 8) | emacETHADDR1;
     MAC_SA1 = (emacETHADDR2 << 8) | emacETHADDR3;
     MAC_SA2 = (emacETHADDR4 << 8) | emacETHADDR5;

     /* Initialize Tx and Rx DMA Descriptors */
     rx_descr_init ();
     tx_descr_init ();

     /* Receive Broadcast and Perfect Match Packets */
     MAC_RXFILTERCTRL = RFC_UCAST_EN | RFC_BCAST_EN | RFC_PERFECT_EN;

     /* Create the semaphore used ot wake the uIP task. */
     vSemaphoreCreateBinary( xEMACSemaphore );

     /* Reset all interrupts */
     MAC_INTCLEAR  = 0xFFFF;

     /* Enable receive and transmit mode of MAC Ethernet core */
     MAC_COMMAND  |= (CR_RX_EN | CR_TX_EN);
     MAC_MAC1     |= MAC1_REC_EN;
   }

   return xReturn;
 }


 // reads a word in little-endian byte order from RX_BUFFER

 unsigned short ReadFrame_EMAC(void)
 {
   return (*rptr++);
 }

 // reads a word in big-endian byte order from RX_FRAME_PORT
 // (useful to avoid permanent byte-swapping while reading
 // TCP/IP-data)

 unsigned short ReadFrameBE_EMAC(void)
 {
   unsigned short ReturnValue;

   ReturnValue = SwapBytes (*rptr++);
   return (ReturnValue);
 }


 // copies bytes from frame port to MCU-memory
 // NOTES: * an odd number of byte may only be transfered
 //          if the frame is read to the end!
 //        * MCU-memory MUST start at word-boundary

 void CopyFromFrame_EMAC(void *Dest, unsigned short Size)
 {
   unsigned short * piDest;                       // Keil: Pointer added to correct expression

   piDest = Dest;                                 // Keil: Line added
   while (Size > 1) {
     *piDest++ = ReadFrame_EMAC();
     Size -= 2;
   }

   if (Size) {                                         // check for leftover byte...
     *(unsigned char *)piDest = (char)ReadFrame_EMAC();// the LAN-Controller will return 0
   }                                                   // for the highbyte
 }

 // does a dummy read on frame-I/O-port
 // NOTE: only an even number of bytes is read!

 void DummyReadFrame_EMAC(unsigned short Size)    // discards an EVEN number of bytes
 {                                                // from RX-fifo
   while (Size > 1) {
     ReadFrame_EMAC();
     Size -= 2;
   }
 }

 // Reads the length of the received ethernet frame and checks if the
 // destination address is a broadcast message or not
 // returns the frame length
 unsigned short StartReadFrame(void) {
   unsigned short RxLen;
   unsigned int idx;

   idx = MAC_RXCONSUMEINDEX;
   RxLen = (RX_STAT_INFO(idx) & RINFO_SIZE) - 3;
   rptr = (unsigned short *)RX_DESC_PACKET(idx);
   return(RxLen);
 }

 void EndReadFrame(void) {
   unsigned int idx;

   /* DMA free packet. */
   idx = MAC_RXCONSUMEINDEX;

   if (++idx == NUM_RX_FRAG)
     idx = 0;

   MAC_RXCONSUMEINDEX = idx;
 }

 unsigned int CheckFrameReceived(void) {             // Packet received ?

   if (MAC_RXPRODUCEINDEX != MAC_RXCONSUMEINDEX)     // more packets received ?
     return(1);
   else
     return(0);
 }

 unsigned int uiGetEMACRxData( unsigned char *ucBuffer )
 {
 unsigned int uiLen = 0;

     if( MAC_RXPRODUCEINDEX != MAC_RXCONSUMEINDEX )
     {
         uiLen = StartReadFrame();
         CopyFromFrame_EMAC( ucBuffer, uiLen );
         EndReadFrame();
     }

     return uiLen;
 }

 // requests space in EMAC memory for storing an outgoing frame

 void RequestSend(void)
 {
   unsigned int idx;

   idx  = MAC_TXPRODUCEINDEX;
   tptr = (unsigned short *)TX_DESC_PACKET(idx);
 }

 // check if ethernet controller is ready to accept the
 // frame we want to send

 unsigned int Rdy4Tx(void)
 {
   return (1);   // the ethernet controller transmits much faster
 }               // than the CPU can load its buffers


 // writes a word in little-endian byte order to TX_BUFFER
 void WriteFrame_EMAC(unsigned short Data)
 {
   *tptr++ = Data;
 }

 // copies bytes from MCU-memory to frame port
 // NOTES: * an odd number of byte may only be transfered
 //          if the frame is written to the end!
 //        * MCU-memory MUST start at word-boundary

 void CopyToFrame_EMAC(void *Source, unsigned int Size)
 {
   unsigned short * piSource;

   piSource = Source;
   Size = (Size + 1) & 0xFFFE;    // round Size up to next even number
   while (Size > 0) {
     WriteFrame_EMAC(*piSource++);
     Size -= 2;
   }
 }

 void DoSend_EMAC(unsigned short FrameSize)
 {
   unsigned int idx;

   idx = MAC_TXPRODUCEINDEX;
   TX_DESC_CTRL(idx) = FrameSize | TCTRL_LAST;
   if (++idx == NUM_TX_FRAG) idx = 0;
   MAC_TXPRODUCEINDEX = idx;
 }
	/******************************************************************
	*** ***
	*** Name: cs8900.c ***
	*** Ver.: 1.0 ***
	*** Date: 07/05/2001 ***
	*** Auth: Andreas Dannenberg ***
	*** HTWK Leipzig ***
	*** university of applied sciences ***
	*** Germany ***
	*** Func: ethernet packet-driver for use with LAN- ***
	*** controller CS8900 from Crystal/Cirrus Logic ***
	*** ***
	*** Keil: Module modified for use with Philips ***
	*** LPC2378 EMAC Ethernet controller ***
	*** ***
	******************************************************************/

	/* Adapted from file originally written by Andreas Dannenberg. Supplied with permission. */

	#include "FreeRTOS.h"
	#include "semphr.h"
	#include "task.h"
	#include "emac.h"

	/* The semaphore used to wake the uIP task when data arives. */
	xSemaphoreHandle xEMACSemaphore = NULL;

	static unsigned short *rptr;
	static unsigned short *tptr;

	// easyWEB internal function
	// help function to swap the byte order of a WORD

	static unsigned short SwapBytes(unsigned short Data)
	{
	return (Data >> 8) \| (Data << 8);
	}

	// Keil: function added to write PHY
	void write_PHY (int PhyReg, int Value)
	{
	unsigned int tout;

	MAC_MADR = DP83848C_DEF_ADR \| PhyReg;
	MAC_MWTD = Value;

	/* Wait utill operation completed */
	tout = 0;
	for (tout = 0; tout < MII_WR_TOUT; tout++) {
	if ((MAC_MIND & MIND_BUSY) == 0) {
	break;
	}
	}
	}


	// Keil: function added to read PHY
	unsigned short read_PHY (unsigned char PhyReg)
	{
	unsigned int tout;

	MAC_MADR = DP83848C_DEF_ADR \| PhyReg;
	MAC_MCMD = MCMD_READ;

	/* Wait until operation completed */
	tout = 0;
	for (tout = 0; tout < MII_RD_TOUT; tout++) {
	if ((MAC_MIND & MIND_BUSY) == 0) {
	break;
	}
	}
	MAC_MCMD = 0;
	return (MAC_MRDD);
	}


	// Keil: function added to initialize Rx Descriptors
	void rx_descr_init (void)
	{
	unsigned int i;

	for (i = 0; i < NUM_RX_FRAG; i++) {
	RX_DESC_PACKET(i) = RX_BUF(i);
	RX_DESC_CTRL(i) = RCTRL_INT \| (ETH_FRAG_SIZE-1);
	RX_STAT_INFO(i) = 0;
	RX_STAT_HASHCRC(i) = 0;
	}

	/* Set EMAC Receive Descriptor Registers. */
	MAC_RXDESCRIPTOR = RX_DESC_BASE;
	MAC_RXSTATUS = RX_STAT_BASE;
	MAC_RXDESCRIPTORNUM = NUM_RX_FRAG-1;

	/* Rx Descriptors Point to 0 */
	MAC_RXCONSUMEINDEX = 0;
	}


	// Keil: function added to initialize Tx Descriptors
	void tx_descr_init (void) {
	unsigned int i;

	for (i = 0; i < NUM_TX_FRAG; i++) {
	TX_DESC_PACKET(i) = TX_BUF(i);
	TX_DESC_CTRL(i) = 0;
	TX_STAT_INFO(i) = 0;
	}

	/* Set EMAC Transmit Descriptor Registers. */
	MAC_TXDESCRIPTOR = TX_DESC_BASE;
	MAC_TXSTATUS = TX_STAT_BASE;
	MAC_TXDESCRIPTORNUM = NUM_TX_FRAG-1;

	/* Tx Descriptors Point to 0 */
	MAC_TXPRODUCEINDEX = 0;
	}


	// configure port-pins for use with LAN-controller,
	// reset it and send the configuration-sequence

	portBASE_TYPE Init_EMAC(void)
	{
	portBASE_TYPE xReturn = pdPASS;

	// Keil: function modified to access the EMAC
	// Initializes the EMAC ethernet controller
	volatile unsigned int regv,tout,id1,id2;

	/* Enable P1 Ethernet Pins. */
	PINSEL2 = configPINSEL2_VALUE;
	PINSEL3 = (PINSEL3 & ~0x0000000F) \| 0x00000005;

	/* Power Up the EMAC controller. */
	PCONP \|= 0x40000000;
	vTaskDelay( 1 );

	/* Reset all EMAC internal modules. */
	MAC_MAC1 = MAC1_RES_TX \| MAC1_RES_MCS_TX \| MAC1_RES_RX \| MAC1_RES_MCS_RX \| MAC1_SIM_RES \| MAC1_SOFT_RES;
	MAC_COMMAND = CR_REG_RES \| CR_TX_RES \| CR_RX_RES;

	/* A short delay after reset. */
	vTaskDelay( 1 );

	/* Initialize MAC control registers. */
	MAC_MAC1 = MAC1_PASS_ALL;
	MAC_MAC2 = MAC2_CRC_EN \| MAC2_PAD_EN;
	MAC_MAXF = ETH_MAX_FLEN;
	MAC_CLRT = CLRT_DEF;
	MAC_IPGR = IPGR_DEF;

	/* Enable Reduced MII interface. */
	MAC_COMMAND = CR_RMII \| CR_PASS_RUNT_FRM;

	/* Reset Reduced MII Logic. */
	MAC_SUPP = SUPP_RES_RMII;
	MAC_SUPP = 0;

	/* Put the DP83848C in reset mode */
	write_PHY (PHY_REG_BMCR, 0x8000);
	write_PHY (PHY_REG_BMCR, 0x8000);

	/* Wait for hardware reset to end. */
	for (tout = 0; tout < 100; tout++) {
	vTaskDelay( 10 );
	regv = read_PHY (PHY_REG_BMCR);
	if (!(regv & 0x8000)) {
	/* Reset complete */
	break;
	}
	}

	/* Check if this is a DP83848C PHY. */
	id1 = read_PHY (PHY_REG_IDR1);
	id2 = read_PHY (PHY_REG_IDR2);
	if (((id1 << 16) \| (id2 & 0xFFF0)) == DP83848C_ID) {
	/* Configure the PHY device */

	/* Use autonegotiation about the link speed. */
	write_PHY (PHY_REG_BMCR, PHY_AUTO_NEG);
	/* Wait to complete Auto_Negotiation. */
	for (tout = 0; tout < 10; tout++) {
	vTaskDelay( 100 );
	regv = read_PHY (PHY_REG_BMSR);
	if (regv & 0x0020) {
	/* Autonegotiation Complete. */
	break;
	}
	}
	}
	else
	{
	xReturn = pdFAIL;
	}

	/* Check the link status. */
	if( xReturn == pdPASS )
	{
	xReturn = pdFAIL;
	for (tout = 0; tout < 10; tout++) {
	vTaskDelay( 100 );
	regv = read_PHY (PHY_REG_STS);
	if (regv & 0x0001) {
	/* Link is on. */
	xReturn = pdPASS;
	break;
	}
	}
	}

	if( xReturn == pdPASS )
	{
	/* Configure Full/Half Duplex mode. */
	if (regv & 0x0004) {
	/* Full duplex is enabled. */
	MAC_MAC2 \|= MAC2_FULL_DUP;
	MAC_COMMAND \|= CR_FULL_DUP;
	MAC_IPGT = IPGT_FULL_DUP;
	}
	else {
	/* Half duplex mode. */
	MAC_IPGT = IPGT_HALF_DUP;
	}

	/* Configure 100MBit/10MBit mode. */
	if (regv & 0x0002) {
	/* 10MBit mode. */
	MAC_SUPP = 0;
	}
	else {
	/* 100MBit mode. */
	MAC_SUPP = SUPP_SPEED;
	}

	/* Set the Ethernet MAC Address registers */
	MAC_SA0 = (emacETHADDR0 << 8) \| emacETHADDR1;
	MAC_SA1 = (emacETHADDR2 << 8) \| emacETHADDR3;
	MAC_SA2 = (emacETHADDR4 << 8) \| emacETHADDR5;

	/* Initialize Tx and Rx DMA Descriptors */
	rx_descr_init ();
	tx_descr_init ();

	/* Receive Broadcast and Perfect Match Packets */
	MAC_RXFILTERCTRL = RFC_UCAST_EN \| RFC_BCAST_EN \| RFC_PERFECT_EN;

	/* Create the semaphore used ot wake the uIP task. */
	vSemaphoreCreateBinary( xEMACSemaphore );

	/* Reset all interrupts */
	MAC_INTCLEAR = 0xFFFF;

	/* Enable receive and transmit mode of MAC Ethernet core */
	MAC_COMMAND \|= (CR_RX_EN \| CR_TX_EN);
	MAC_MAC1 \|= MAC1_REC_EN;
	}

	return xReturn;
	}


	// reads a word in little-endian byte order from RX_BUFFER

	unsigned short ReadFrame_EMAC(void)
	{
	return (*rptr++);
	}

	// reads a word in big-endian byte order from RX_FRAME_PORT
	// (useful to avoid permanent byte-swapping while reading
	// TCP/IP-data)

	unsigned short ReadFrameBE_EMAC(void)
	{
	unsigned short ReturnValue;

	ReturnValue = SwapBytes (*rptr++);
	return (ReturnValue);
	}


	// copies bytes from frame port to MCU-memory
	// NOTES: * an odd number of byte may only be transfered
	// if the frame is read to the end!
	// * MCU-memory MUST start at word-boundary

	void CopyFromFrame_EMAC(void *Dest, unsigned short Size)
	{
	unsigned short * piDest; // Keil: Pointer added to correct expression

	piDest = Dest; // Keil: Line added
	while (Size > 1) {
	*piDest++ = ReadFrame_EMAC();
	Size -= 2;
	}

	if (Size) { // check for leftover byte...
	(unsigned char )piDest = (char)ReadFrame_EMAC();// the LAN-Controller will return 0
	} // for the highbyte
	}

	// does a dummy read on frame-I/O-port
	// NOTE: only an even number of bytes is read!

	void DummyReadFrame_EMAC(unsigned short Size) // discards an EVEN number of bytes
	{ // from RX-fifo
	while (Size > 1) {
	ReadFrame_EMAC();
	Size -= 2;
	}
	}

	// Reads the length of the received ethernet frame and checks if the
	// destination address is a broadcast message or not
	// returns the frame length
	unsigned short StartReadFrame(void) {
	unsigned short RxLen;
	unsigned int idx;

	idx = MAC_RXCONSUMEINDEX;
	RxLen = (RX_STAT_INFO(idx) & RINFO_SIZE) - 3;
	rptr = (unsigned short *)RX_DESC_PACKET(idx);
	return(RxLen);
	}

	void EndReadFrame(void) {
	unsigned int idx;

	/* DMA free packet. */
	idx = MAC_RXCONSUMEINDEX;

	if (++idx == NUM_RX_FRAG)
	idx = 0;

	MAC_RXCONSUMEINDEX = idx;
	}

	unsigned int CheckFrameReceived(void) { // Packet received ?

	if (MAC_RXPRODUCEINDEX != MAC_RXCONSUMEINDEX) // more packets received ?
	return(1);
	else
	return(0);
	}

	unsigned int uiGetEMACRxData( unsigned char *ucBuffer )
	{
	unsigned int uiLen = 0;

	if( MAC_RXPRODUCEINDEX != MAC_RXCONSUMEINDEX )
	{
	uiLen = StartReadFrame();
	CopyFromFrame_EMAC( ucBuffer, uiLen );
	EndReadFrame();
	}

	return uiLen;
	}

	// requests space in EMAC memory for storing an outgoing frame

	void RequestSend(void)
	{
	unsigned int idx;

	idx = MAC_TXPRODUCEINDEX;
	tptr = (unsigned short *)TX_DESC_PACKET(idx);
	}

	// check if ethernet controller is ready to accept the
	// frame we want to send

	unsigned int Rdy4Tx(void)
	{
	return (1); // the ethernet controller transmits much faster
	} // than the CPU can load its buffers


	// writes a word in little-endian byte order to TX_BUFFER
	void WriteFrame_EMAC(unsigned short Data)
	{
	*tptr++ = Data;
	}

	// copies bytes from MCU-memory to frame port
	// NOTES: * an odd number of byte may only be transfered
	// if the frame is written to the end!
	// * MCU-memory MUST start at word-boundary

	void CopyToFrame_EMAC(void *Source, unsigned int Size)
	{
	unsigned short * piSource;

	piSource = Source;
	Size = (Size + 1) & 0xFFFE; // round Size up to next even number
	while (Size > 0) {
	WriteFrame_EMAC(*piSource++);
	Size -= 2;
	}
	}

	void DoSend_EMAC(unsigned short FrameSize)
	{
	unsigned int idx;

	idx = MAC_TXPRODUCEINDEX;
	TX_DESC_CTRL(idx) = FrameSize \| TCTRL_LAST;
	if (++idx == NUM_TX_FRAG) idx = 0;
	MAC_TXPRODUCEINDEX = idx;
	}