Plan 9 from Bell Labs’s /usr/web/sources/contrib/quanstro/root/sys/src/boot/pc-e820/ether8390.c

Copyright © 2021 Plan 9 Foundation.
Distributed under the MIT License.
Download the Plan 9 distribution.


/*
 * National Semiconductor DP8390 and clone
 * Network Interface Controller.
 */
#include "u.h"
#include "lib.h"
#include "mem.h"
#include "dat.h"
#include "fns.h"
#include "io.h"

#include "etherif.h"
#include "ether8390.h"

#define Hdr _Hdr

enum {					/* NIC core registers */
	Cr		= 0x00,		/* command register, all pages */

					/* Page 0, read */
	Clda0		= 0x01,		/* current local DMA address 0 */
	Clda1		= 0x02,		/* current local DMA address 1 */
	Bnry		= 0x03,		/* boundary pointer (R/W) */
	Tsr		= 0x04,		/* transmit status register */
	Ncr		= 0x05,		/* number of collisions register */
	Fifo		= 0x06,		/* FIFO */
	Isr		= 0x07,		/* interrupt status register (R/W) */
	Crda0		= 0x08,		/* current remote DMA address 0 */
	Crda1		= 0x09,		/* current remote DMA address 1 */
	Rsr		= 0x0C,		/* receive status register */
	Cntr0		= 0x0D,		/* frame alignment errors */
	Cntr1		= 0x0E,		/* CRC errors */
	Cntr2		= 0x0F,		/* missed packet errors */

					/* Page 0, write */
	Pstart		= 0x01,		/* page start register */
	Pstop		= 0x02,		/* page stop register */
	Tpsr		= 0x04,		/* transmit page start address */
	Tbcr0		= 0x05,		/* transmit byte count register 0 */
	Tbcr1		= 0x06,		/* transmit byte count register 1 */
	Rsar0		= 0x08,		/* remote start address register 0 */
	Rsar1		= 0x09,		/* remote start address register 1 */
	Rbcr0		= 0x0A,		/* remote byte count register 0 */
	Rbcr1		= 0x0B,		/* remote byte count register 1 */
	Rcr		= 0x0C,		/* receive configuration register */
	Tcr		= 0x0D,		/* transmit configuration register */
	Dcr		= 0x0E,		/* data configuration register */
	Imr		= 0x0F,		/* interrupt mask */

					/* Page 1, read/write */
	Par0		= 0x01,		/* physical address register 0 */
	Curr		= 0x07,		/* current page register */
	Mar0		= 0x08,		/* multicast address register 0 */
};

enum {					/* Cr */
	Stp		= 0x01,		/* stop */
	Sta		= 0x02,		/* start */
	Txp		= 0x04,		/* transmit packet */
	Rd0		= 0x08,		/* remote DMA command */
	Rd1		= 0x10,	
	Rd2		= 0x20,
	RdREAD		= Rd0,		/* remote read */
	RdWRITE		= Rd1,		/* remote write */
	RdSEND		= Rd1|Rd0,	/* send packet */
	RdABORT		= Rd2,		/* abort/complete remote DMA */
	Ps0		= 0x40,		/* page select */
	Ps1		= 0x80,
	Page0		= 0x00,
	Page1		= Ps0,
	Page2		= Ps1,
};

enum {					/* Isr/Imr */
	Prx		= 0x01,		/* packet received */
	Ptx		= 0x02,		/* packet transmitted */
	Rxe		= 0x04,		/* receive error */
	Txe		= 0x08,		/* transmit error */
	Ovw		= 0x10,		/* overwrite warning */
	Cnt		= 0x20,		/* counter overflow */
	Rdc		= 0x40,		/* remote DMA complete */
	Rst		= 0x80,		/* reset status */
};

enum {					/* Dcr */
	Wts		= 0x01,		/* word transfer select */
	Bos		= 0x02,		/* byte order select */
	Las		= 0x04,		/* long address select */
	Ls		= 0x08,		/* loopback select */
	Arm		= 0x10,		/* auto-initialise remote */
	Ft0		= 0x20,		/* FIFO threshold select */
	Ft1		= 0x40,
	Ft1WORD		= 0x00,
	Ft2WORD		= Ft0,
	Ft4WORD		= Ft1,
	Ft6WORD		= Ft1|Ft0,
};

enum {					/* Tcr */
	Crc		= 0x01,		/* inhibit CRC */
	Lb0		= 0x02,		/* encoded loopback control */
	Lb1		= 0x04,
	LpbkNORMAL	= 0x00,		/* normal operation */
	LpbkNIC		= Lb0,		/* internal NIC module loopback */
	LpbkENDEC	= Lb1,		/* internal ENDEC module loopback */
	LpbkEXTERNAL	= Lb1|Lb0,	/* external loopback */
	Atd		= 0x08,		/* auto transmit disable */
	Ofst		= 0x10,		/* collision offset enable */
};

enum {					/* Tsr */
	Ptxok		= 0x01,		/* packet transmitted */
	Col		= 0x04,		/* transmit collided */
	Abt		= 0x08,		/* tranmit aborted */
	Crs		= 0x10,		/* carrier sense lost */
	Fu		= 0x20,		/* FIFO underrun */
	Cdh		= 0x40,		/* CD heartbeat */
	Owc		= 0x80,		/* out of window collision */
};

enum {					/* Rcr */
	Sep		= 0x01,		/* save errored packets */
	Ar		= 0x02,		/* accept runt packets */
	Ab		= 0x04,		/* accept broadcast */
	Am		= 0x08,		/* accept multicast */
	Pro		= 0x10,		/* promiscuous physical */
	Mon		= 0x20,		/* monitor mode */
};

enum {					/* Rsr */
	Prxok		= 0x01,		/* packet received intact */
	Crce		= 0x02,		/* CRC error */
	Fae		= 0x04,		/* frame alignment error */
	Fo		= 0x08,		/* FIFO overrun */
	Mpa		= 0x10,		/* missed packet */
	Phy		= 0x20,		/* physical/multicast address */
	Dis		= 0x40,		/* receiver disabled */
	Dfr		= 0x80,		/* deferring */
};

typedef struct {
	uchar	status;
	uchar	next;
	uchar	len0;
	uchar	len1;
} Hdr;

void
dp8390getea(Ether* ether, uchar* ea)
{
	Dp8390 *ctlr;
	uchar cr;
	int i;

	ctlr = ether->ctlr;

	/*
	 * Get the ethernet address from the chip.
	 * Take care to restore the command register
	 * afterwards.
	 */
	ilock(ctlr);
	cr = regr(ctlr, Cr) & ~Txp;
	regw(ctlr, Cr, Page1|(~(Ps1|Ps0) & cr));
	for(i = 0; i < Eaddrlen; i++)
		ea[i] = regr(ctlr, Par0+i);
	regw(ctlr, Cr, cr);
	iunlock(ctlr);
}

void
dp8390setea(Ether* ether)
{
	int i;
	uchar cr;
	Dp8390 *ctlr;

	ctlr = ether->ctlr;

	/*
	 * Set the ethernet address into the chip.
	 * Take care to restore the command register
	 * afterwards. Don't care about multicast
	 * addresses as multicast is never enabled
	 * (currently).
	 */
	ilock(ctlr);
	cr = regr(ctlr, Cr) & ~Txp;
	regw(ctlr, Cr, Page1|(~(Ps1|Ps0) & cr));
	for(i = 0; i < Eaddrlen; i++)
		regw(ctlr, Par0+i, ether->ea[i]);
	regw(ctlr, Cr, cr);
	iunlock(ctlr);
}

static void*
_dp8390read(Dp8390* ctlr, void* to, ulong from, ulong len)
{
	uchar cr;
	int timo;

	/*
	 * Read some data at offset 'from' in the card's memory
	 * using the DP8390 remote DMA facility, and place it at
	 * 'to' in main memory, via the I/O data port.
	 */
	cr = regr(ctlr, Cr) & ~Txp;
	regw(ctlr, Cr, Page0|RdABORT|Sta);
	regw(ctlr, Isr, Rdc);

	/*
	 * Set up the remote DMA address and count.
	 */
	len = ROUNDUP(len, ctlr->width);
	regw(ctlr, Rbcr0, len & 0xFF);
	regw(ctlr, Rbcr1, (len>>8) & 0xFF);
	regw(ctlr, Rsar0, from & 0xFF);
	regw(ctlr, Rsar1, (from>>8) & 0xFF);

	/*
	 * Start the remote DMA read and suck the data
	 * out of the I/O port.
	 */
	regw(ctlr, Cr, Page0|RdREAD|Sta);
	rdread(ctlr, to, len);

	/*
	 * Wait for the remote DMA to complete. The timeout
	 * is necessary because this routine may be called on
	 * a non-existent chip during initialisation and, due
	 * to the miracles of the bus, it's possible to get this
	 * far and still be talking to a slot full of nothing.
	 */
	for(timo = 10000; (regr(ctlr, Isr) & Rdc) == 0 && timo; timo--)
			;

	regw(ctlr, Isr, Rdc);
	regw(ctlr, Cr, cr);

	return to;
}

void*
dp8390read(Dp8390* ctlr, void* to, ulong from, ulong len)
{
	void *v;

	ilock(ctlr);
	v = _dp8390read(ctlr, to, from, len);
	iunlock(ctlr);

	return v;
}

static void*
dp8390write(Dp8390* ctlr, ulong to, void* from, ulong len)
{
	ulong crda;
	uchar cr;
	int timo, width;

top:
	/*
	 * Write some data to offset 'to' in the card's memory
	 * using the DP8390 remote DMA facility, reading it at
	 * 'from' in main memory, via the I/O data port.
	 */
	cr = regr(ctlr, Cr) & ~Txp;
	regw(ctlr, Cr, Page0|RdABORT|Sta);
	regw(ctlr, Isr, Rdc);

	len = ROUNDUP(len, ctlr->width);

	/*
	 * Set up the remote DMA address and count.
	 * This is straight from the DP8390[12D] datasheet,
	 * hence the initial set up for read.
	 * Assumption here that the A7000 EtherV card will
	 * never need a dummyrr.
	 */
	if(ctlr->dummyrr && (ctlr->width == 1 || ctlr->width == 2)){
		if(ctlr->width == 2)
			width = 1;
		else
			width = 0;
		crda = to-1-width;
		regw(ctlr, Rbcr0, (len+1+width) & 0xFF);
		regw(ctlr, Rbcr1, ((len+1+width)>>8) & 0xFF);
		regw(ctlr, Rsar0, crda & 0xFF);
		regw(ctlr, Rsar1, (crda>>8) & 0xFF);
		regw(ctlr, Cr, Page0|RdREAD|Sta);
	
		for(timo=0;; timo++){
			if(timo > 10000){
				print("ether8390: dummyrr timeout; assuming nodummyrr\n");
				ctlr->dummyrr = 0;
				goto top;
			}
			crda = regr(ctlr, Crda0);
			crda |= regr(ctlr, Crda1)<<8;
			if(crda == to){
				/*
				 * Start the remote DMA write and make sure
				 * the registers are correct.
				 */
				regw(ctlr, Cr, Page0|RdWRITE|Sta);
	
				crda = regr(ctlr, Crda0);
				crda |= regr(ctlr, Crda1)<<8;
				if(crda != to)
					panic("crda write %lux to %lux\n", crda, to);
	
				break;
			}
		}
	}
	else{
		regw(ctlr, Rsar0, to & 0xFF);
		regw(ctlr, Rsar1, (to>>8) & 0xFF);
		regw(ctlr, Rbcr0, len & 0xFF);
		regw(ctlr, Rbcr1, (len>>8) & 0xFF);
		regw(ctlr, Cr, Page0|RdWRITE|Sta);
	}

	/*
	 * Pump the data into the I/O port
	 * then wait for the remote DMA to finish.
	 */
	rdwrite(ctlr, from, len);
	for(timo = 10000; (regr(ctlr, Isr) & Rdc) == 0 && timo; timo--)
			;

	regw(ctlr, Isr, Rdc);
	regw(ctlr, Cr, cr);

	return (void*)to;
}

static void
ringinit(Dp8390* ctlr)
{
	regw(ctlr, Pstart, ctlr->pstart);
	regw(ctlr, Pstop, ctlr->pstop);
	regw(ctlr, Bnry, ctlr->pstop-1);

	regw(ctlr, Cr, Page1|RdABORT|Stp);
	regw(ctlr, Curr, ctlr->pstart);
	regw(ctlr, Cr, Page0|RdABORT|Stp);

	ctlr->nxtpkt = ctlr->pstart;
}

static uchar
getcurr(Dp8390* ctlr)
{
	uchar cr, curr;

	cr = regr(ctlr, Cr) & ~Txp;
	regw(ctlr, Cr, Page1|(~(Ps1|Ps0) & cr));
	curr = regr(ctlr, Curr);
	regw(ctlr, Cr, cr);

	return curr;
}

static void
receive(Ether* ether)
{
	Dp8390 *ctlr;
	uchar curr, *p;
	Hdr hdr;
	ulong count, data, len;
	RingBuf *ring;

	ctlr = ether->ctlr;
	for(curr = getcurr(ctlr); ctlr->nxtpkt != curr; curr = getcurr(ctlr)){
		data = ctlr->nxtpkt*Dp8390BufSz;
		if(ctlr->ram)
			memmove(&hdr, (void*)(ether->mem+data), sizeof(Hdr));
		else
			_dp8390read(ctlr, &hdr, data, sizeof(Hdr));

		/*
		 * Don't believe the upper byte count, work it
		 * out from the software next-page pointer and
		 * the current next-page pointer.
		 */
		if(hdr.next > ctlr->nxtpkt)
			len = hdr.next - ctlr->nxtpkt - 1;
		else
			len = (ctlr->pstop-ctlr->nxtpkt) + (hdr.next-ctlr->pstart) - 1;
		if(hdr.len0 > (Dp8390BufSz-sizeof(Hdr)))
			len--;

		len = ((len<<8)|hdr.len0)-4;

		/*
		 * Chip is badly scrogged, reinitialise the ring.
		 */
		if(hdr.next < ctlr->pstart || hdr.next >= ctlr->pstop
		  || len < 60 || len > sizeof(Etherpkt)){
			print("dp8390: H#%2.2ux#%2.2ux#%2.2ux#%2.2ux,%lud\n",
				hdr.status, hdr.next, hdr.len0, hdr.len1, len);
			regw(ctlr, Cr, Page0|RdABORT|Stp);
			ringinit(ctlr);
			regw(ctlr, Cr, Page0|RdABORT|Sta);

			return;
		}

		/*
		 * If it's a good packet read it in to the software buffer.
		 * If the packet wraps round the hardware ring, read it in
		 * two pieces.
		 */
		ring = &ether->rb[ether->ri];
		if((hdr.status & (Fo|Fae|Crce|Prxok)) == Prxok && ring->owner == Interface){
			p = ring->pkt;
			ring->len = len;
			data += sizeof(Hdr);

			if((data+len) >= ctlr->pstop*Dp8390BufSz){
				count = ctlr->pstop*Dp8390BufSz - data;
				if(ctlr->ram)
					memmove(p, (void*)(ether->mem+data), count);
				else
					_dp8390read(ctlr, p, data, count);
				p += count;
				data = ctlr->pstart*Dp8390BufSz;
				len -= count;
			}
			if(len){
				if(ctlr->ram)
					memmove(p, (void*)(ether->mem+data), len);
				else
					_dp8390read(ctlr, p, data, len);
			}

			/*
			 * Copy the packet to whoever wants it.
			 */
			ring->owner = Host;
			ether->ri = NEXT(ether->ri, ether->nrb);
		}

		/*
		 * Finished with this packet, update the
		 * hardware and software ring pointers.
		 */
		ctlr->nxtpkt = hdr.next;

		hdr.next--;
		if(hdr.next < ctlr->pstart)
			hdr.next = ctlr->pstop-1;
		regw(ctlr, Bnry, hdr.next);
	}
}

static void
txstart(Ether* ether)
{
	int len;
	Dp8390 *ctlr;
	RingBuf *ring;
	uchar minpkt[ETHERMINTU], *rp;

	ctlr = ether->ctlr;

	/*
	 * This routine is called both from the top level and from interrupt
	 * level and expects to be called with ctlr already locked.
	 */
	if(ether->tbusy)
		return;
	ring = &ether->tb[ether->ti];
	if(ring->owner != Interface)
		return;

	/*
	 * Make sure the packet is of minimum length;
	 * copy it to the card's memory by the appropriate means;
	 * start the transmission.
	 */
	len = ring->len;
	rp = ring->pkt;
	if(len < ETHERMINTU){
		rp = minpkt;
		memmove(rp, ring->pkt, len);
		memset(rp+len, 0, ETHERMINTU-len);
		len = ETHERMINTU;
	}

	if(ctlr->ram)
		memmove((void*)(ether->mem+ctlr->tstart*Dp8390BufSz), rp, len);
	else
		dp8390write(ctlr, ctlr->tstart*Dp8390BufSz, rp, len);

	regw(ctlr, Tbcr0, len & 0xFF);
	regw(ctlr, Tbcr1, (len>>8) & 0xFF);
	regw(ctlr, Cr, Page0|RdABORT|Txp|Sta);

	ether->tbusy = 1;
}

static void
transmit(Ether* ether)
{
	Dp8390 *ctlr;

	ctlr = ether->ctlr;

	ilock(ctlr);
	txstart(ether);
	iunlock(ctlr);
}

static void
overflow(Ether *ether)
{
	Dp8390 *ctlr;
	uchar txp;
	int resend;

	ctlr = ether->ctlr;

	/*
	 * The following procedure is taken from the DP8390[12D] datasheet,
	 * it seems pretty adamant that this is what has to be done.
	 */
	txp = regr(ctlr, Cr) & Txp;
	regw(ctlr, Cr, Page0|RdABORT|Stp);
	delay(2);
	regw(ctlr, Rbcr0, 0);
	regw(ctlr, Rbcr1, 0);

	resend = 0;
	if(txp && (regr(ctlr, Isr) & (Txe|Ptx)) == 0)
		resend = 1;

	regw(ctlr, Tcr, LpbkNIC);
	regw(ctlr, Cr, Page0|RdABORT|Sta);
	receive(ether);
	regw(ctlr, Isr, Ovw);
	regw(ctlr, Tcr, LpbkNORMAL);

	if(resend)
		regw(ctlr, Cr, Page0|RdABORT|Txp|Sta);
}

static void
interrupt(Ureg*, void* arg)
{
	Ether *ether;
	Dp8390 *ctlr;
	RingBuf *ring;
	uchar isr, r;

	ether = arg;
	ctlr = ether->ctlr;

	/*
	 * While there is something of interest,
	 * clear all the interrupts and process.
	 */
	ilock(ctlr);
	regw(ctlr, Imr, 0x00);
	while(isr = (regr(ctlr, Isr) & (Cnt|Ovw|Txe|Rxe|Ptx|Prx))){
		if(isr & Ovw){
			overflow(ether);
			regw(ctlr, Isr, Ovw);
		}

		/*
		 * Packets have been received.
		 * Take a spin round the ring.
		 */
		if(isr & (Rxe|Prx)){
			receive(ether);
			regw(ctlr, Isr, Rxe|Prx);
		}

		/*
		 * A packet completed transmission, successfully or
		 * not. Start transmission on the next buffered packet,
		 * and wake the output routine.
		 */
		if(isr & (Txe|Ptx)){
			r = regr(ctlr, Tsr);
			if((isr & Txe) && (r & (Cdh|Fu|Crs|Abt))){
				print("dp8390: Tsr#%2.2ux|", r);
			}

			regw(ctlr, Isr, Txe|Ptx);

			ring = &ether->tb[ether->ti];
			ring->owner = Host;
			ether->ti = NEXT(ether->ti, ether->ntb);
			ether->tbusy = 0;
			txstart(ether);
		}

		if(isr & Cnt){
			regr(ctlr, Cntr0);
			regr(ctlr, Cntr1);
			regr(ctlr, Cntr2);
			regw(ctlr, Isr, Cnt);
		}
	}
	regw(ctlr, Imr, Cnt|Ovw|Txe|Rxe|Ptx|Prx);
	iunlock(ctlr);
}

static void
attach(Ether* ether)
{
	Dp8390 *ctlr;
	uchar r;

	ctlr = ether->ctlr;

	/*
	 * Enable the chip for transmit/receive.
	 * The init routine leaves the chip in monitor
	 * mode. Clear the missed-packet counter, it
	 * increments while in monitor mode.
	 * Sometimes there's an interrupt pending at this
	 * point but there's nothing in the Isr, so
	 * any pending interrupts are cleared and the
	 * mask of acceptable interrupts is enabled here.
	 */
	r = Ab;
	ilock(ctlr);
	regw(ctlr, Isr, 0xFF);
	regw(ctlr, Imr, Cnt|Ovw|Txe|Rxe|Ptx|Prx);
	regw(ctlr, Rcr, r);
	r = regr(ctlr, Cntr2);
	regw(ctlr, Tcr, LpbkNORMAL);
	iunlock(ctlr);
	USED(r);
}

static void
detach(Ether* ether)
{
	int timo;
	Dp8390 *ctlr;

	/*
	 * Stop the chip. Set the Stp bit and wait for the chip
	 * to finish whatever was on its tiny mind before it sets
	 * the Rst bit.
	 * The timeout is needed because there may not be a real
	 * chip there if this is called when probing for a device
	 * at boot.
	 */
	ctlr = ether->ctlr;
	regw(ctlr, Cr, Page0|RdABORT|Stp);
	regw(ctlr, Rbcr0, 0);
	regw(ctlr, Rbcr1, 0);
	for(timo = 10000; (regr(ctlr, Isr) & Rst) == 0 && timo; timo--)
			;
}

int
dp8390reset(Ether* ether)
{
	Dp8390 *ctlr;

	ctlr = ether->ctlr;

	/*
	 * This is the initialisation procedure described
	 * as 'mandatory' in the datasheet, with references
	 * to the 3C503 technical reference manual.
	 */ 
	detach(ether);
	if(ctlr->width != 1)
		regw(ctlr, Dcr, Ft4WORD|Ls|Wts);
	else
		regw(ctlr, Dcr, Ft4WORD|Ls);

	regw(ctlr, Rbcr0, 0);
	regw(ctlr, Rbcr1, 0);

	regw(ctlr, Tcr, LpbkNIC);
	regw(ctlr, Rcr, Mon);

	/*
	 * Init the ring hardware and software ring pointers.
	 * Can't initialise ethernet address as it may not be
	 * known yet.
	 */
	ringinit(ctlr);
	regw(ctlr, Tpsr, ctlr->tstart);

	/*
	 * Clear any pending interrupts and mask then all off.
	 */
	regw(ctlr, Isr, 0xFF);
	regw(ctlr, Imr, 0);

	/*
	 * Leave the chip initialised,
	 * but in monitor mode.
	 */
	regw(ctlr, Cr, Page0|RdABORT|Sta);

	/*
	 * Set up the software configuration.
	 */
	ether->attach = attach;
	ether->transmit = transmit;
	ether->interrupt = interrupt;
	ether->detach = detach;

	return 0;
}

Bell Labs OSI certified Powered by Plan 9

(Return to Plan 9 Home Page)

Copyright © 2021 Plan 9 Foundation. All Rights Reserved.
Comments to [email protected].