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enc28j60.h
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enc28j60.h
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// -*- mode: c++; indent-tabs-mode: nil; -*-
// Based on the this:
/*********************************************
* vim:sw=8:ts=8:si:et
* To use the above modeline in vim you must have "set modeline" in your .vimrc
* Author: Guido Socher
* Copyright: GPL V2
* http://www.gnu.org/licenses/gpl.html
*
* Based on the enc28j60.c file from the AVRlib library by Pascal Stang.
* For AVRlib See http://www.procyonengineering.com/
* Used with explicit permission of Pascal Stang.
*
* Title: Microchip ENC28J60 Ethernet Interface Driver
* Chip type : ATMEGA88 with ENC28J60
*********************************************/
#include "arduino--.h"
#include "spi.h"
#include <util/delay.h>
template <class CSPin> class ENC28J60
{
static void Select() { CSPin::clear(); }
static void Deselect() { CSPin::set(); }
public:
static byte ReadOp(byte op, byte address)
{
ScopedInterruptDisable dis;
//CSACTIVE;
Select();
// issue read command
SPDR = op | (address & ADDR_MASK);
//waitspi();
SPI::wait();
// read data
SPDR = 0x00;
//waitspi();
SPI::wait();
// do dummy read if needed (for mac and mii, see datasheet page 29)
if(address & 0x80)
{
SPDR = 0x00;
//waitspi();
SPI::wait();
}
// release CS
//CSPASSIVE;
Deselect();
return SPDR;
}
static void WriteOp(uint8_t op, uint8_t address, uint8_t data)
{
ScopedInterruptDisable dis;
//CSACTIVE;
Select();
// issue write command
SPDR = op | (address & ADDR_MASK);
//waitspi();
SPI::wait();
// write data
SPDR = data;
//waitspi();
SPI::wait();
//CSPASSIVE;
Deselect();
}
static void ReadBuffer(uint16_t len, uint8_t* data)
{
ScopedInterruptDisable dis;
//CSACTIVE;
Select();
// issue read command
SPDR = ENC28J60_READ_BUF_MEM;
//waitspi();
SPI::wait();
while(len)
{
len--;
// read data
SPDR = 0x00;
//waitspi();
SPI::wait();
*data = SPDR;
data++;
}
// FIXME: buffer overrun!!
*data='\0';
//CSPASSIVE;
Deselect();
}
static void WriteBuffer(uint16_t len, uint8_t* data)
{
ScopedInterruptDisable dis;
//CSACTIVE;
Select();
// issue write command
SPDR = ENC28J60_WRITE_BUF_MEM;
//waitspi();
SPI::wait();
while(len)
{
len--;
// write data
SPDR = *data;
data++;
//waitspi();
SPI::wait();
}
//CSPASSIVE;
Deselect();
}
static void SetBank(uint8_t address)
{
// set the bank (if needed)
if((address & BANK_MASK) != Enc28j60Bank)
{
// set the bank
WriteOp(ENC28J60_BIT_FIELD_CLR, ECON1,
(ECON1_BSEL1|ECON1_BSEL0));
WriteOp(ENC28J60_BIT_FIELD_SET, ECON1,
(address & BANK_MASK)>>5);
Enc28j60Bank = (address & BANK_MASK);
}
}
static uint8_t Read(uint8_t address)
{
// set the bank
SetBank(address);
// do the read
return ReadOp(ENC28J60_READ_CTRL_REG, address);
}
static void Write(uint8_t address, uint8_t data)
{
// set the bank
SetBank(address);
// do the write
WriteOp(ENC28J60_WRITE_CTRL_REG, address, data);
}
static void PhyWrite(uint8_t address, uint16_t data)
{
// set the PHY register address
Write(MIREGADR, address);
// write the PHY data
Write(MIWRL, data);
Write(MIWRH, data>>8);
// wait until the PHY write completes
while(Read(MISTAT) & MISTAT_BUSY)
// FIXME: why delay at all?
_delay_us(15);
}
static void clkout(uint8_t clk)
{
//setup clkout: 2 is 12.5MHz:
Write(ECOCON, clk & 0x7);
}
static void Init(const uint8_t *macaddr)
{
// initialize I/O
//CSPASSIVE; // ss=0
Deselect();
// ss as output:
//pinMode(ENC28J60_CONTROL_CS, OUTPUT);
CSPin::modeOutput();
// Note the old code cleared MOSI and SCK, SPI::init()
// currently doesn't.
SPI::init(0, true);
// perform system reset
WriteOp(ENC28J60_SOFT_RESET, 0, ENC28J60_SOFT_RESET);
_delay_ms(50);
// check CLKRDY bit to see if reset is complete
// The CLKRDY does not work. See Rev. B4 Silicon Errata point. Just wait.
//while(!(enc28j60Read(ESTAT) & ESTAT_CLKRDY));
// do bank 0 stuff
// initialize receive buffer
// 16-bit transfers, must write low byte first
// set receive buffer start address
NextPacketPtr = RXSTART_INIT;
// Rx start
Write(ERXSTL, RXSTART_INIT&0xFF);
Write(ERXSTH, RXSTART_INIT>>8);
// set receive pointer address
Write(ERXRDPTL, RXSTART_INIT&0xFF);
Write(ERXRDPTH, RXSTART_INIT>>8);
// RX end
Write(ERXNDL, RXSTOP_INIT&0xFF);
Write(ERXNDH, RXSTOP_INIT>>8);
// TX start
Write(ETXSTL, TXSTART_INIT&0xFF);
Write(ETXSTH, TXSTART_INIT>>8);
// TX end
Write(ETXNDL, TXSTOP_INIT&0xFF);
Write(ETXNDH, TXSTOP_INIT>>8);
// do bank 1 stuff, packet filter:
// For broadcast packets we allow only ARP packtets
// All other packets should be unicast only for our mac (MAADR)
//
// The pattern to match on is therefore
// Type ETH.DST
// ARP BROADCAST
// 06 08 -- ff ff ff ff ff ff -> ip checksum for theses bytes=f7f9
// in binary these poitions are:11 0000 0011 1111
// This is hex 303F->EPMM0=0x3f,EPMM1=0x30
Write(ERXFCON, ERXFCON_UCEN | ERXFCON_CRCEN | ERXFCON_PMEN);
Write(EPMM0, 0x3f);
Write(EPMM1, 0x30);
Write(EPMCSL, 0xf9);
Write(EPMCSH, 0xf7);
// do bank 2 stuff
// enable MAC receive
Write(MACON1, MACON1_MARXEN | MACON1_TXPAUS | MACON1_RXPAUS);
// bring MAC out of reset
Write(MACON2, 0x00);
// enable automatic padding to 60bytes and CRC operations
WriteOp(ENC28J60_BIT_FIELD_SET, MACON3,
MACON3_PADCFG0 | MACON3_TXCRCEN | MACON3_FRMLNEN);
// set inter-frame gap (non-back-to-back)
Write(MAIPGL, 0x12);
Write(MAIPGH, 0x0C);
// set inter-frame gap (back-to-back)
Write(MABBIPG, 0x12);
// Set the maximum packet size which the controller will accept
// Do not send packets longer than MAX_FRAMELEN:
Write(MAMXFLL, MAX_FRAMELEN&0xFF);
Write(MAMXFLH, MAX_FRAMELEN>>8);
// do bank 3 stuff
// write MAC address
// NOTE: MAC address in ENC28J60 is byte-backward
Write(MAADR5, macaddr[0]);
Write(MAADR4, macaddr[1]);
Write(MAADR3, macaddr[2]);
Write(MAADR2, macaddr[3]);
Write(MAADR1, macaddr[4]);
Write(MAADR0, macaddr[5]);
// no loopback of transmitted frames
PhyWrite(PHCON2, PHCON2_HDLDIS);
// switch to bank 0
SetBank(ECON1);
// enable interrutps
WriteOp(ENC28J60_BIT_FIELD_SET, EIE, EIE_INTIE | EIE_PKTIE);
// enable packet reception
WriteOp(ENC28J60_BIT_FIELD_SET, ECON1, ECON1_RXEN);
}
// read the revision of the chip:
static uint8_t getrev(void)
{
return Read(EREVID);
}
static void PacketSend(uint16_t len, uint8_t* packet)
{
// Set the write pointer to start of transmit buffer area
Write(EWRPTL, TXSTART_INIT&0xFF);
Write(EWRPTH, TXSTART_INIT>>8);
// Set the TXND pointer to correspond to the packet size given
Write(ETXNDL, (TXSTART_INIT+len)&0xFF);
Write(ETXNDH, (TXSTART_INIT+len)>>8);
// write per-packet control byte (0x00 means use macon3 settings)
WriteOp(ENC28J60_WRITE_BUF_MEM, 0, 0x00);
// copy the packet into the transmit buffer
WriteBuffer(len, packet);
// send the contents of the transmit buffer onto the network
WriteOp(ENC28J60_BIT_FIELD_SET, ECON1, ECON1_TXRTS);
// Reset the transmit logic problem. See Rev. B4 Silicon Errata point 12.
if(Read(EIR) & EIR_TXERIF)
WriteOp(ENC28J60_BIT_FIELD_CLR, ECON1, ECON1_TXRTS);
}
// Gets a packet from the network receive buffer, if one is available.
// The packet will by headed by an ethernet header.
// maxlen The maximum acceptable length of a retrieved packet.
// packet Pointer where packet data should be stored.
// Returns: Packet length in bytes if a packet was retrieved, zero otherwise.
static uint16_t PacketReceive(uint16_t maxlen, uint8_t* packet)
{
uint16_t rxstat;
uint16_t len;
// check if a packet has been received and buffered
//if( !(enc28j60Read(EIR) & EIR_PKTIF) ){
// The above does not work. See Rev. B4 Silicon Errata point 6.
if (Read(EPKTCNT) == 0)
return 0;
// Set the read pointer to the start of the received packet
Write(ERDPTL, (NextPacketPtr));
Write(ERDPTH, (NextPacketPtr)>>8);
// read the next packet pointer
NextPacketPtr = ReadOp(ENC28J60_READ_BUF_MEM, 0);
NextPacketPtr |= ReadOp(ENC28J60_READ_BUF_MEM, 0)<<8;
// read the packet length (see datasheet page 43)
len = ReadOp(ENC28J60_READ_BUF_MEM, 0);
len |= ReadOp(ENC28J60_READ_BUF_MEM, 0)<<8;
len -= 4; //remove the CRC count
// read the receive status (see datasheet page 43)
rxstat = ReadOp(ENC28J60_READ_BUF_MEM, 0);
rxstat |= ReadOp(ENC28J60_READ_BUF_MEM, 0)<<8;
// limit retrieve length
if (len > maxlen-1)
len=maxlen-1;
// check CRC and symbol errors (see datasheet page 44, table 7-3):
// The ERXFCON.CRCEN is set by default. Normally we should not
// need to check this.
if ((rxstat & 0x80) == 0)
{
// invalid
len=0;
}
else
{
// copy the packet from the receive buffer
ReadBuffer(len, packet);
}
// Move the RX read pointer to the start of the next received packet
// This frees the memory we just read out
Write(ERXRDPTL, (NextPacketPtr));
Write(ERXRDPTH, (NextPacketPtr)>>8);
// decrement the packet counter indicate we are done with this packet
WriteOp(ENC28J60_BIT_FIELD_SET, ECON2, ECON2_PKTDEC);
return len;
}
static void phlcon(uint16_t val) { PhyWrite(PHLCON, val); }
static void setup(const byte *mac)
{
Init(mac);
clkout(2); // change clkout from 6.25MHz to 12.5MHz
_delay_ms(10);
/* Magjack leds configuration, see enc28j60 datasheet, page 11 */
// LEDA=greed LEDB=yellow
// 0x880 is PHLCON LEDB=on, LEDA=on
// enc28j60PhyWrite(PHLCON,0b0000 1000 1000 00 00);
phlcon(0x880);
_delay_ms(500);
// 0x990 is PHLCON LEDB=off, LEDA=off
// enc28j60PhyWrite(PHLCON,0b0000 1001 1001 00 00);
phlcon(0x990);
_delay_ms(500);
// 0x880 is PHLCON LEDB=on, LEDA=on
// enc28j60PhyWrite(PHLCON,0b0000 1000 1000 00 00);
phlcon(0x880);
_delay_ms(500);
// 0x990 is PHLCON LEDB=off, LEDA=off
// enc28j60PhyWrite(PHLCON,0b0000 1001 1001 00 00);
phlcon(0x990);
_delay_ms(500);
// 0x476 is PHLCON LEDA=links status, LEDB=receive/transmit
// enc28j60PhyWrite(PHLCON,0b0000 0100 0111 01 10);
phlcon(0x476);
_delay_ms(100);
}
private:
static const byte ADDR_MASK = 0x1f;
static const byte BANK_MASK = 0x60;
static const byte RXSTART_INIT = 0x0;
static const uint16_t RXSTOP_INIT = 0x1FFF-0x0600-1;
static const uint16_t TXSTART_INIT = 0x1FFF-0x0600;
static const uint16_t TXSTOP_INIT = 0x1FFF;
static const uint16_t MAX_FRAMELEN = 1500; // (note: maximum ethernet frame
enum Opcode
{
ENC28J60_READ_CTRL_REG = 0x00,
ENC28J60_READ_BUF_MEM = 0x3A,
ENC28J60_WRITE_CTRL_REG = 0x40,
ENC28J60_WRITE_BUF_MEM = 0x7A,
ENC28J60_BIT_FIELD_SET = 0x80,
ENC28J60_BIT_FIELD_CLR = 0xA0,
ENC28J60_SOFT_RESET = 0xFF,
};
enum Register
{
PHCON2 = 0x10,
PHLCON = 0x14,
EIE = 0x1B,
EIR = 0x1C,
ECON2 = 0x1E,
ECON1 = 0x1F,
ERDPTL = (0x00|0x00),
ERDPTH = (0x01|0x00),
EWRPTL = (0x02|0x00),
EWRPTH = (0x03|0x00),
ETXSTL = (0x04|0x00),
ETXSTH = (0x05|0x00),
ETXNDL = (0x06|0x00),
ETXNDH = (0x07|0x00),
ERXSTL = (0x08|0x00),
ERXSTH = (0x09|0x00),
ERXNDL = (0x0A|0x00),
ERXNDH = (0x0B|0x00),
ERXRDPTL = (0x0C|0x00),
ERXRDPTH = (0x0D|0x00),
EPMM0 = (0x08|0x20),
EPMM1 = (0x09|0x20),
EPMCSL = (0x10|0x20),
EPMCSH = (0x11|0x20),
ERXFCON = (0x18|0x20),
EPKTCNT = (0x19|0x20),
ECOCON = (0x15|0x60),
MACON1 = (0x00|0x40|0x80),
MACON2 = (0x01|0x40|0x80),
MACON3 = (0x02|0x40|0x80),
MABBIPG = (0x04|0x40|0x80),
MAIPGL = (0x06|0x40|0x80),
MAIPGH = (0x07|0x40|0x80),
MAMXFLL = (0x0A|0x40|0x80),
MAMXFLH = (0x0B|0x40|0x80),
MIREGADR = (0x14|0x40|0x80),
MIWRL = (0x16|0x40|0x80),
MIWRH = (0x17|0x40|0x80),
MAADR1 = (0x00|0x60|0x80),
MAADR0 = (0x01|0x60|0x80),
MAADR3 = (0x02|0x60|0x80),
MAADR2 = (0x03|0x60|0x80),
MAADR5 = (0x04|0x60|0x80),
MAADR4 = (0x05|0x60|0x80),
MISTAT = (0x0A|0x60|0x80),
EREVID = (0x12|0x60),
};
enum ECON1Bit
{
ECON1_TXRTS = 0x08,
ECON1_RXEN = 0x04,
ECON1_BSEL1 = 0x02,
ECON1_BSEL0 = 0x01,
};
enum ECON2Bit
{
ECON2_PKTDEC = 0x40,
};
enum MISTATBit
{
MISTAT_BUSY = 0x01,
};
enum ERXFCONBit
{
ERXFCON_UCEN = 0x80,
ERXFCON_CRCEN = 0x20,
ERXFCON_PMEN = 0x10,
};
enum MACON1Bit
{
MACON1_TXPAUS = 0x08,
MACON1_RXPAUS = 0x04,
MACON1_MARXEN = 0x01,
};
enum MACON3Bit
{
MACON3_PADCFG0 = 0x20,
MACON3_TXCRCEN = 0x10,
MACON3_FRMLNEN = 0x02,
};
enum PHCON2Bit
{
PHCON2_HDLDIS = 0x0100,
};
enum EIEBit
{
EIE_INTIE = 0x80,
EIE_PKTIE = 0x40,
};
enum EIRBit
{
EIR_TXERIF = 0x02,
};
static byte Enc28j60Bank;
static uint16_t NextPacketPtr;
};
template<class Pin> byte ENC28J60<Pin>::Enc28j60Bank;
template<class Pin> uint16_t ENC28J60<Pin>::NextPacketPtr;