freebsd-nq/sys/i386/isa/if_sr.c
1996-09-06 23:09:20 +00:00

1631 lines
39 KiB
C

/*
* Copyright (c) 1996 John Hay. All rights reserved.
*
* Redistribution and use in source and binary forms, with or without
* modification, are permitted provided that the following conditions
* are met:
* 1. Redistributions of source code must retain the above copyright
* notice, this list of conditions and the following disclaimer.
* 2. Redistributions in binary form must reproduce the above copyright
* notice, this list of conditions and the following disclaimer in the
* documentation and/or other materials provided with the distribution.
* 3. All advertising materials mentioning features or use of this software
* must display the following acknowledgement:
* This product includes software developed by John Hay.
* 4. Neither the name of the author nor the names of any co-contributors
* may be used to endorse or promote products derived from this software
* without specific prior written permission.
*
* THIS SOFTWARE IS PROVIDED BY John Hay ``AS IS'' AND
* ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE
* IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE
* ARE DISCLAIMED. IN NO EVENT SHALL John Hay BE LIABLE
* FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL
* DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS
* OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION)
* HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT
* LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY
* OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF
* SUCH DAMAGE.
*
* $Id: if_sr.c,v 1.1 1996/07/05 18:49:21 jhay Exp $
*/
/*
* Programming assumptions and other issues.
*
* Only a 16K window will be used.
*
* The descriptors of a DMA channel will fit in a 16K memory window.
*
* The buffers of a transmit DMA channel will fit in a 16K memory window.
*
* When interface is going up, handshaking is set and it is only cleared
* when the interface is down'ed.
*
* There should be a way to set/reset Raw HDLC/PPP, Loopback, DCE/DTE,
* internal/external clock, etc.....
*
*/
#include "sr.h"
#include "bpfilter.h"
#include <sys/param.h>
#include <sys/systm.h>
#include <sys/kernel.h>
#include <sys/mbuf.h>
#include <sys/ioctl.h>
#include <sys/socket.h>
#include <sys/conf.h>
#include <sys/errno.h>
#include <sys/malloc.h>
#include <sys/syslog.h>
#include <net/if.h>
#include <net/if_types.h>
#include <net/if_sppp.h>
#if NBPFILTER > 0
#include <net/bpf.h>
#include <net/bpfdesc.h>
#endif
#include <machine/clock.h>
#include <machine/md_var.h>
#include <i386/isa/if_srregs.h>
#include <i386/isa/ic/hd64570.h>
#ifdef TRACE
#define TRC(x) x
#else
#define TRC(x)
#endif
#define TRCL(x) x
#define PPP_HEADER_LEN 4
#define SRC_REG(iobase,y) ((y & 0xf) + ((y & 0xf0) << 6) + \
iobase | 0x8000)
#define SRC_GET8(iobase,off) inb(SRC_REG(iobase,(u_int)&off))
#define SRC_GET16(iobase,off) inw(SRC_REG(iobase,(u_int)&off))
#define SRC_PUT8(iobase,off,d) outb(SRC_REG(iobase,(u_int)&off),d)
#define SRC_PUT16(iobase,off,d) outw(SRC_REG(iobase,(u_int)&off),d)
#define SRC_GET_WIN(addr) ((addr >> SRC_WIN_SHFT) & SR_PG_MSK)
#define SRC_SET_ON(iobase) outb(iobase+SR_PCR, \
SR_PCR_MEM_WIN | inb(iobase+SR_PCR))
#define SRC_SET_MEM(iobase,win) outb(iobase+SR_PSR, SRC_GET_WIN(win) | \
inb(iobase+SR_PSR) & ~SR_PG_MSK)
#define SRC_SET_OFF(iobase) outb(iobase+SR_PCR, \
~SR_PCR_MEM_WIN & inb(iobase+SR_PCR))
static struct sr_hardc {
int cunit;
struct sr_softc *sc;
u_short iobase;
int startunit;
int numports;
caddr_t mem_start;
caddr_t mem_end;
u_int memsize; /* in bytes */
sca_regs *sca;
}sr_hardc[NSR];
struct sr_softc {
struct sppp ifsppp;
int unit; /* With regards to all sr devices */
int subunit; /* With regards to this card */
struct sr_hardc *hc;
struct buf_block {
u_int txdesc; /* On card address */
u_int txstart; /* On card address */
u_int txend; /* On card address */
u_int txtail; /* Index of first unused buffer */
u_int txmax; /* number of usable buffers/descriptors */
u_int txeda; /* Error descriptor addresses */
}block[SR_TX_BLOCKS];
char xmit_busy; /* Transmitter is busy */
char txb_inuse; /* Number of tx blocks currently in use */
char txb_new; /* Index to where new buffer will be added */
char txb_next_tx; /* Index to next block ready to tx */
u_int rxdesc; /* On card address */
u_int rxstart; /* On card address */
u_int rxend; /* On card address */
u_int rxhind; /* Index to the head of the rx buffers. */
u_int rxmax; /* number of usable buffers/descriptors */
u_int clk_cfg; /* Clock configuration */
int scachan;
};
static int srprobe(struct isa_device *id);
static int srattach(struct isa_device *id);
/*
* List of valid interrupt numbers.
*/
static int sr_irqtable[16] = {
0, /* 0 */
0, /* 1 */
0, /* 2 */
1, /* 3 */
1, /* 4 */
1, /* 5 */
0, /* 6 */
1, /* 7 */
0, /* 8 */
0, /* 9 */
1, /* 10 */
1, /* 11 */
1, /* 12 */
0, /* 13 */
0, /* 14 */
1 /* 15 */
};
struct isa_driver srdriver = {srprobe, srattach, "src"};
static void sr_xmit(struct sr_softc *sc);
static void srstart(struct ifnet *ifp);
static int srioctl(struct ifnet *ifp, int cmd, caddr_t data);
static void srwatchdog(struct ifnet *ifp);
static int sr_packet_avail(struct sr_softc *sc, int *len, u_char *rxstat);
static void sr_copy_rxbuf(struct mbuf *m, struct sr_softc *sc, int len);
static void sr_eat_packet(struct sr_softc *sc, int single);
static void sr_get_packets(struct sr_softc *sc);
static void sr_up(struct sr_softc *sc);
static void sr_down(struct sr_softc *sc);
static void src_init(struct isa_device *id);
static void sr_init_sca(struct sr_hardc *hc);
static void sr_init_msci(struct sr_softc *sc);
static void sr_init_rx_dmac(struct sr_softc *sc);
static void sr_init_tx_dmac(struct sr_softc *sc);
static void sr_dmac_intr(struct sr_hardc *hc, u_char isr);
static void sr_msci_intr(struct sr_hardc *hc, u_char isr);
static void sr_timer_intr(struct sr_hardc *hc, u_char isr);
/*
* Register the Adapter.
* Probe to see if it is there.
* Get its information and fill it in.
*/
static int
srprobe(struct isa_device *id)
{
struct sr_hardc *hc = &sr_hardc[id->id_unit];
u_int pgs, i, tmp;
u_short port;
u_short *smem;
u_char mar;
sca_regs *sca = 0;
/*
* Now see if the card is realy there.
*
* If it is there, size its memory.
*/
hc->sca = 0;
port = id->id_iobase;
hc->memsize = 64 * 1024;
hc->numports = NCHAN;
if(id->id_flags & SR_FLAGS_NCHAN_MSK)
hc->numports = id->id_flags & SR_FLAGS_NCHAN_MSK;
outb(port + SR_PCR, 0);
for(i=0;i<0x100;i++) {
outb(port + SR_BAR, i);
inb(port + SR_PCR);
tmp = inb(port + SR_BAR);
if(tmp != i) {
printf("sr%d: probe failed BAR %x, %x.\n",
id->id_unit,
i,
tmp);
return 0;
}
}
/*
* Now see if its memory also works.
*/
outb(port + SR_PCR, SR_PCR_EN_VPM |
SR_PCR_ISA16);
outb(port + SR_PSR, SR_PSR_WIN_16K);
mar = (kvtop(id->id_maddr) >> 16) & SR_PCR_16M_SEL;
outb(port + SR_PCR, mar | inb(port + SR_PCR));
mar = kvtop(id->id_maddr) >> 12;
outb(port + SR_BAR, mar);
outb(port + SR_PCR, inb(port + SR_PCR) | SR_PCR_MEM_WIN);
smem = (u_short *)id->id_maddr;
for(i=0;i<=SR_PSR_PG_SEL;i++) {
outb(port + SR_PSR,
(inb(port + SR_PSR) & ~SR_PSR_PG_SEL) | i);
*smem = 0xAA55;
}
for(i=0;i<=SR_PSR_PG_SEL;i++) {
outb(port + SR_PSR,
(inb(port + SR_PSR) & ~SR_PSR_PG_SEL) | i);
if(*smem != 0xAA55) {
/*
* If we have less than 64k of memory, give up.
* That is 4 x 16k pages.
*/
if(i<4) {
printf("sr%d: Bad mem page %d, mem %x, %x.\n",
id->id_unit,
i,
0xAA55,
*smem);
return 0;
}
break;
}
*smem = i;
}
hc->memsize = i * SRC_WIN_SIZ;
pgs = i;
for(i=0;i<=pgs;i++) {
outb(port + SR_PSR,
(inb(port + SR_PSR) & ~SR_PSR_PG_SEL) | i);
bzero(smem, SRC_WIN_SIZ);
}
/*
* Now see if we can see the SCA.
*/
outb(port + SR_PCR, SR_PCR_SCARUN | inb(port + SR_PCR));
SRC_PUT8(port, sca->wcrl, 0);
SRC_PUT8(port, sca->wcrm, 0);
SRC_PUT8(port, sca->wcrh, 0);
SRC_PUT8(port, sca->pcr, 0);
SRC_PUT8(port, sca->msci[0].tmc, 0);
inb(port);
tmp = SRC_GET8(port, sca->msci[0].tmc);
if(tmp != 0) {
printf("sr%d: Error reading SCA 0, %x\n", id->id_unit, tmp);
return 0;
}
SRC_PUT8(port, sca->msci[0].tmc, 0x5A);
inb(port);
tmp = SRC_GET8(port, sca->msci[0].tmc);
if(tmp != 0x5A) {
printf("sr%d: Error reading SCA 0x5A, %x\n", id->id_unit, tmp);
return 0;
}
SRC_PUT16(port, sca->dmac[0].cda, 0);
inb(port);
tmp = SRC_GET16(port, sca->dmac[0].cda);
if(tmp != 0) {
printf("sr%d: Error reading SCA 0, %x\n", id->id_unit, tmp);
return 0;
}
SRC_PUT16(port, sca->dmac[0].cda, 0x55AA);
inb(port);
tmp = SRC_GET16(port, sca->dmac[0].cda);
if(tmp != 0x55AA) {
printf("sr%d: Error reading SCA 0x55AA, %x\n", id->id_unit, tmp);
return 0;
}
SRC_SET_OFF(port);
/*
* We have a card here, fill in what we can.
*/
id->id_msize = SRC_WIN_SIZ;
hc->iobase = id->id_iobase;
hc->mem_start = id->id_maddr;
hc->mem_end = id->id_maddr + id->id_msize;
hc->cunit = id->id_unit;
if(id->id_unit == 0)
hc->startunit = 0;
else
hc->startunit = sr_hardc[id->id_unit - 1].startunit +
sr_hardc[id->id_unit - 1].numports;
/*
* Do a little sanity check.
*/
if(sr_irqtable[ffs(id->id_irq) - 1] == 0)
printf("sr%d: Warning illegal interrupt %d\n",
id->id_unit, ffs(id->id_irq) - 1);
if((hc->numports > NCHAN) || (hc->memsize > (512*1024)))
return 0;
return SRC_IO_SIZ; /* return the amount of IO addresses used. */
}
/*
* Malloc memory for the softc structures.
* Reset the card to put it in a known state.
* Register the ports on the adapter.
* Fill in the info for each port.
* Attach each port to sppp and bpf.
*/
static int
srattach(struct isa_device *id)
{
struct sr_hardc *hc = &sr_hardc[id->id_unit];
struct sr_softc *sc;
struct ifnet *ifp;
int unit;
printf("src%d: %uK RAM, %u ports.\n",
id->id_unit,
hc->memsize/1024,
hc->numports);
src_init(id);
sc = hc->sc;
sr_init_sca(hc);
/*
* Now configure each port on the card.
*/
for(unit=0;unit<hc->numports;sc++,unit++) {
sc->hc = hc;
sc->subunit = unit;
sc->unit = hc->startunit + unit;
sc->scachan = unit%NCHAN;
sr_init_rx_dmac(sc);
sr_init_tx_dmac(sc);
sr_init_msci(sc);
ifp = &sc->ifsppp.pp_if;
ifp->if_softc = sc;
ifp->if_unit = hc->startunit + unit;
ifp->if_name = "sr";
ifp->if_mtu = PP_MTU;
ifp->if_flags = IFF_POINTOPOINT | IFF_MULTICAST;
ifp->if_ioctl = srioctl;
ifp->if_start = srstart;
ifp->if_watchdog = srwatchdog;
sc->ifsppp.pp_flags = PP_KEEPALIVE;
printf("sr%d: Adapter %d, port %d.\n",
sc->unit,
hc->cunit,
sc->subunit);
sppp_attach((struct ifnet *)&sc->ifsppp);
if_attach(ifp);
#if NBPFILTER > 0
bpfattach(ifp, DLT_PPP, PPP_HEADER_LEN);
#endif
}
SRC_SET_OFF(hc->iobase);
return 1;
}
/*
* First figure out which SCA gave the interrupt.
* Process it.
* See if there is other interrupts pending.
* Repeat until there is no more interrupts.
*/
void
srintr(int unit)
{
struct sr_hardc *hc = &sr_hardc[unit];
sca_regs *sca = hc->sca;
u_char isr0, isr1, isr2;
/*
* Loop until no outstanding interrupts.
*/
isr0 = SRC_GET8(hc->iobase, sca->isr0);
isr1 = SRC_GET8(hc->iobase, sca->isr1);
isr2 = SRC_GET8(hc->iobase, sca->isr2);
do {
/*
* Acknoledge all the interrupts pending.
*
* XXX Does this really work?
*/
SRC_PUT8(hc->iobase, sca->isr0, isr0);
SRC_PUT8(hc->iobase, sca->isr1, isr1);
SRC_PUT8(hc->iobase, sca->isr2, isr2);
TRC(printf("src%d: SRINTR isr0 %x, isr1 %x, isr2 %x\n",
unit,
isr0,
isr1,
isr2));
if(isr0)
sr_msci_intr(hc, isr0);
if(isr1)
sr_dmac_intr(hc, isr1);
if(isr2)
sr_timer_intr(hc, isr2);
isr0 = SRC_GET8(hc->iobase, sca->isr0);
isr1 = SRC_GET8(hc->iobase, sca->isr1);
isr2 = SRC_GET8(hc->iobase, sca->isr2);
} while (isr0 | isr1 | isr2);
}
/*
* This will only start the transmitter. It is assumed that the data
* is already there. It is normally called from srstart() or sr_dmac_intr().
*
*/
static void
sr_xmit(struct sr_softc *sc)
{
struct ifnet *ifp = &sc->ifsppp.pp_if;
dmac_channel *dmac = &sc->hc->sca->dmac[DMAC_TXCH(sc->scachan)];
SRC_PUT16(sc->hc->iobase, dmac->cda,
(u_short)(sc->block[sc->txb_next_tx].txdesc & 0xffff));
SRC_PUT16(sc->hc->iobase, dmac->eda,
(u_short)(sc->block[sc->txb_next_tx].txeda & 0xffff));
SRC_PUT8(sc->hc->iobase, dmac->dsr, SCA_DSR_DE);
sc->xmit_busy = 1;
sc->txb_next_tx++;
if(sc->txb_next_tx == SR_TX_BLOCKS)
sc->txb_next_tx = 0;
ifp->if_timer = 2; /* Value in seconds. */
}
/*
* This function will be called from the upper level when a user add a
* packet to be send, and from the interrupt handler after a finished
* transmit.
*
* NOTE: it should run at spl_imp().
*
* This function only place the data in the oncard buffers. It does not
* start the transmition. sr_xmit() does that.
*
* Transmitter idle state is indicated by the IFF_OACTIVE flag. The function
* that clears that should ensure that the transmitter and it's DMA is
* in a "good" idle state.
*/
static void
srstart(struct ifnet *ifp)
{
struct sr_softc *sc = ifp->if_softc;
int i, len, tlen;
struct mbuf *mtx;
u_char *txdata;
sca_descriptor *txdesc;
struct buf_block *blkp;
if(!(ifp->if_flags & IFF_RUNNING))
return;
/*
* It is OK to set the memory window outside the loop because
* all tx buffers and descriptors are assumed to be in the same
* 16K window.
*/
SRC_SET_ON(sc->hc->iobase);
SRC_SET_MEM(sc->hc->iobase, sc->block[0].txdesc);
top_srstart:
/*
* See if we have space for more packets.
*/
if(sc->txb_inuse == SR_TX_BLOCKS) {
ifp->if_flags |= IFF_OACTIVE;
SRC_SET_OFF(sc->hc->iobase);
return;
}
mtx = sppp_dequeue(ifp);
if(!mtx) {
SRC_SET_OFF(sc->hc->iobase);
return;
}
/*
* We stay in this loop until there is nothing in the
* TX queue left or the tx buffers are full.
*/
i = 0;
blkp = &sc->block[sc->txb_new];
txdesc = (sca_descriptor *)
(sc->hc->mem_start + (blkp->txdesc & SRC_WIN_MSK));
txdata = (u_char *)(sc->hc->mem_start + (blkp->txstart & SRC_WIN_MSK));
for(;;) {
len = mtx->m_pkthdr.len;
TRC(printf("sr%d: SRstart len %u\n", sc->unit, len));
/*
* We can do this because the tx buffers don't wrap.
*/
m_copydata(mtx, 0, len, txdata);
tlen = len;
while(tlen > SR_BUF_SIZ) {
txdesc->stat = 0;
txdesc->len = SR_BUF_SIZ;
tlen -= SR_BUF_SIZ;
txdesc++;
txdata += SR_BUF_SIZ;
i++;
}
/* XXX Move into the loop? */
txdesc->stat = SCA_DESC_EOM;
txdesc->len = tlen;
txdesc++;
txdata += SR_BUF_SIZ;
i++;
#if NBPFILTER > 0
if(ifp->if_bpf)
bpf_mtap(ifp, mtx);
#endif
m_freem(mtx);
++sc->ifsppp.pp_if.if_opackets;
/*
* Check if we have space for another mbuf.
* XXX This is hardcoded. A packet won't be larger
* than 3 buffers (3 x 512).
*/
if((i + 3) >= blkp->txmax)
break;
mtx = sppp_dequeue(ifp);
if(!mtx)
break;
}
blkp->txtail = i;
/*
* Mark the last descriptor, so that the SCA know where
* to stop.
*/
txdesc--;
txdesc->stat |= SCA_DESC_EOT;
txdesc = (sca_descriptor *)blkp->txdesc;
blkp->txeda = (u_short)((u_int)&txdesc[i]);
sc->txb_inuse++;
sc->txb_new++;
if(sc->txb_new == SR_TX_BLOCKS)
sc->txb_new = 0;
if(sc->xmit_busy == 0)
sr_xmit(sc);
goto top_srstart;
}
static int
srioctl(struct ifnet *ifp, int cmd, caddr_t data)
{
int s, error;
int was_up, should_be_up;
struct sppp *sp = (struct sppp *)ifp;
struct sr_softc *sc = ifp->if_softc;
TRC(printf("sr%d: srioctl.\n", ifp->if_unit);)
if(cmd == SIOCSIFFLAGS) {
if(ifp->if_flags & IFF_LINK2)
sp->pp_flags |= PP_CISCO;
else
sp->pp_flags &= ~PP_CISCO;
}
was_up = ifp->if_flags & IFF_RUNNING;
error = sppp_ioctl(ifp, cmd, data);
TRC(printf("sr%d: ioctl: ifsppp.pp_flags = %x, if_flags %x.\n",
ifp->if_unit, ((struct sppp *)ifp)->pp_flags, ifp->if_flags);)
if(error)
return error;
if((cmd != SIOCSIFFLAGS) && cmd != (SIOCSIFADDR))
return 0;
TRC(printf("sr%d: srioctl %s.\n", ifp->if_unit,
(cmd == SIOCSIFFLAGS) ? "SIOCSIFFLAGS" : "SIOCSIFADDR");)
s = splimp();
should_be_up = ifp->if_flags & IFF_RUNNING;
if(!was_up && should_be_up) {
/* Interface should be up -- start it. */
sr_up(sc);
srstart(ifp);
/* XXX Clear the IFF_UP flag so that the link
* will only go up after sppp lcp and ipcp negotiation.
*/
ifp->if_flags &= ~IFF_UP;
} else if(was_up && !should_be_up) {
/* Interface should be down -- stop it. */
sr_down(sc);
sppp_flush(ifp);
}
splx(s);
return 0;
}
/*
* This is to catch lost tx interrupts.
*/
static void
srwatchdog(struct ifnet *ifp)
{
struct sr_softc *sc = ifp->if_softc;
msci_channel *msci = &sc->hc->sca->msci[sc->scachan];
if(!(ifp->if_flags & IFF_RUNNING))
return;
/* XXX if(sc->ifsppp.pp_if.if_flags & IFF_DEBUG) */
printf("sr%d: transmit failed, "
"ST0 %x, ST1 %x, ST3 %x, DSR %x.\n",
ifp->if_unit,
SRC_GET8(sc->hc->iobase, msci->st0),
SRC_GET8(sc->hc->iobase, msci->st1),
SRC_GET8(sc->hc->iobase, msci->st3),
SRC_GET8(sc->hc->iobase,
sc->hc->sca->dmac[DMAC_TXCH(sc->scachan)].dsr));
if(SRC_GET8(sc->hc->iobase, msci->st1) & SCA_ST1_UDRN) {
SRC_PUT8(sc->hc->iobase, msci->cmd, SCA_CMD_TXABORT);
SRC_PUT8(sc->hc->iobase, msci->cmd, SCA_CMD_TXENABLE);
SRC_PUT8(sc->hc->iobase, msci->st1, SCA_ST1_UDRN);
}
sc->xmit_busy = 0;
ifp->if_flags &= ~IFF_OACTIVE;
if(sc->txb_inuse && --sc->txb_inuse)
sr_xmit(sc);
srstart(ifp);
}
static void
sr_up(struct sr_softc *sc)
{
sca_regs *sca = sc->hc->sca;
msci_channel *msci = &sca->msci[sc->scachan];
/*
* Enable transmitter and receiver.
* Raise DTR and RTS.
* Enable interrupts.
*/
/* XXX
* What about using AUTO mode in msci->md0 ???
*/
SRC_PUT8(sc->hc->iobase, msci->ctl,
SRC_GET8(sc->hc->iobase, msci->ctl) & ~SCA_CTL_RTS);
if(sc->scachan == 0)
outb(sc->hc->iobase + SR_MCR,
inb(sc->hc->iobase + SR_MCR) & ~SR_MCR_DTR0);
else
outb(sc->hc->iobase + SR_MCR,
inb(sc->hc->iobase + SR_MCR) & ~SR_MCR_DTR1);
if(sc->scachan == 0) {
SRC_PUT8(sc->hc->iobase, sca->ier0,
SRC_GET8(sc->hc->iobase, sca->ier0) | 0x0F);
SRC_PUT8(sc->hc->iobase, sca->ier1,
SRC_GET8(sc->hc->iobase, sca->ier1) | 0x0F);
} else {
SRC_PUT8(sc->hc->iobase, sca->ier0,
SRC_GET8(sc->hc->iobase, sca->ier0) | 0xF0);
SRC_PUT8(sc->hc->iobase, sca->ier1,
SRC_GET8(sc->hc->iobase, sca->ier1) | 0xF0);
}
SRC_PUT8(sc->hc->iobase, msci->cmd, SCA_CMD_RXENABLE);
inb(sc->hc->iobase); /* XXX slow it down a bit. */
SRC_PUT8(sc->hc->iobase, msci->cmd, SCA_CMD_TXENABLE);
}
static void
sr_down(struct sr_softc *sc)
{
sca_regs *sca = sc->hc->sca;
msci_channel *msci = &sca->msci[sc->scachan];
/*
* Disable transmitter and receiver.
* Lower DTR and RTS.
* Disable interrupts.
*/
SRC_PUT8(sc->hc->iobase, msci->cmd, SCA_CMD_RXDISABLE);
inb(sc->hc->iobase); /* XXX slow it down a bit. */
SRC_PUT8(sc->hc->iobase, msci->cmd, SCA_CMD_TXDISABLE);
SRC_PUT8(sc->hc->iobase, msci->ctl,
SRC_GET8(sc->hc->iobase, msci->ctl) | SCA_CTL_RTS);
if(sc->scachan == 0)
outb(sc->hc->iobase + SR_MCR,
inb(sc->hc->iobase + SR_MCR) | SR_MCR_DTR0);
else
outb(sc->hc->iobase + SR_MCR,
inb(sc->hc->iobase + SR_MCR) | SR_MCR_DTR1);
if(sc->scachan == 0) {
SRC_PUT8(sc->hc->iobase, sca->ier0,
SRC_GET8(sc->hc->iobase, sca->ier0) & ~0x0F);
SRC_PUT8(sc->hc->iobase, sca->ier1,
SRC_GET8(sc->hc->iobase, sca->ier1) & ~0x0F);
} else {
SRC_PUT8(sc->hc->iobase, sca->ier0,
SRC_GET8(sc->hc->iobase, sca->ier0) & ~0xF0);
SRC_PUT8(sc->hc->iobase, sca->ier1,
SRC_GET8(sc->hc->iobase, sca->ier1) & ~0xF0);
}
}
/*
* Initialize the card, allocate memory for the sr_softc structures
* and fill in the pointers.
*/
static void
src_init(struct isa_device *id)
{
struct sr_hardc *hc = &sr_hardc[id->id_unit];
struct sr_softc *sc;
int x;
u_int chanmem;
u_int bufmem;
u_int next;
u_int descneeded;
u_char mar;
sc = hc->sc = malloc(hc->numports * sizeof(struct sr_softc),
M_DEVBUF, M_WAITOK);
bzero(sc, hc->numports * sizeof(struct sr_softc));
outb(hc->iobase + SR_PCR, inb(hc->iobase + SR_PCR) | SR_PCR_SCARUN);
outb(hc->iobase + SR_PSR, inb(hc->iobase + SR_PSR) | SR_PSR_EN_SCA_DMA);
outb(hc->iobase + SR_MCR, SR_MCR_DTR0 |
SR_MCR_DTR1 |
SR_MCR_TE0 |
SR_MCR_TE1);
SRC_SET_ON(hc->iobase);
/*
* Configure the card.
* Mem address, irq,
*/
mar = (kvtop(id->id_maddr) >> 16) & SR_PCR_16M_SEL;
outb(hc->iobase + SR_PCR,
mar | (inb(hc->iobase + SR_PCR) & ~SR_PCR_16M_SEL));
mar = kvtop(id->id_maddr) >> 12;
outb(hc->iobase + SR_BAR, mar);
/*
* Get the TX clock direction and configuration.
* The default is a single external clock which is
* used by RX and TX.
*/
if(id->id_flags & SR_FLAGS_0_CLK_MSK)
sc[0].clk_cfg = (id->id_flags & SR_FLAGS_0_CLK_MSK) >>
SR_FLAGS_CLK_SHFT;
if((hc->numports == 2) && (id->id_flags & SR_FLAGS_1_CLK_MSK))
sc[1].clk_cfg = (id->id_flags & SR_FLAGS_1_CLK_MSK) >>
(SR_FLAGS_CLK_SHFT + SR_FLAGS_CLK_CHAN_SHFT);
chanmem = hc->memsize / hc->numports;
next = 0;
for(x=0;x<hc->numports;x++, sc++) {
int blk;
for(blk = 0; blk < SR_TX_BLOCKS; blk++) {
sc->block[blk].txdesc = next;
bufmem = (16 * 1024) / SR_TX_BLOCKS;
descneeded = bufmem / SR_BUF_SIZ;
sc->block[blk].txstart = sc->block[blk].txdesc +
((((descneeded * sizeof(sca_descriptor)) /
SR_BUF_SIZ) + 1) * SR_BUF_SIZ);
sc->block[blk].txend = next + bufmem;
sc->block[blk].txmax =
(sc->block[blk].txend - sc->block[blk].txstart)
/ SR_BUF_SIZ;
next += bufmem;
TRC(printf("sr%d: blk %d: txdesc %x, txstart %x, "
"txend %x, txmax %d\n",
x,
blk,
sc->block[blk].txdesc,
sc->block[blk].txstart,
sc->block[blk].txend,
sc->block[blk].txmax));
}
sc->rxdesc = next;
bufmem = chanmem - (bufmem * SR_TX_BLOCKS);
descneeded = bufmem / SR_BUF_SIZ;
sc->rxstart = sc->rxdesc +
((((descneeded * sizeof(sca_descriptor)) /
SR_BUF_SIZ) + 1) * SR_BUF_SIZ);
sc->rxend = next + bufmem;
sc->rxmax = (sc->rxend - sc->rxstart) / SR_BUF_SIZ;
next += bufmem;
}
}
/*
* The things done here are channel independent.
*
* Configure the sca waitstates.
* Configure the global interrupt registers.
* Enable master dma enable.
*/
static void
sr_init_sca(struct sr_hardc *hc)
{
sca_regs *sca = hc->sca;
/*
* Do the wait registers.
* Set everything to 0 wait states.
*/
SRC_PUT8(hc->iobase, sca->pabr0, 0);
SRC_PUT8(hc->iobase, sca->pabr1, 0);
SRC_PUT8(hc->iobase, sca->wcrl, 0);
SRC_PUT8(hc->iobase, sca->wcrm, 0);
SRC_PUT8(hc->iobase, sca->wcrh, 0);
/*
* Configure the interrupt registers.
* Most are cleared until the interface is configured.
*/
SRC_PUT8(hc->iobase, sca->ier0, 0x00); /* MSCI interrupts. */
SRC_PUT8(hc->iobase, sca->ier1, 0x00); /* DMAC interrupts */
SRC_PUT8(hc->iobase, sca->ier2, 0x00); /* TIMER interrupts. */
SRC_PUT8(hc->iobase, sca->itcr, 0x00); /* Use ivr and no intr ack */
SRC_PUT8(hc->iobase, sca->ivr, 0x40); /* Interrupt vector. */
SRC_PUT8(hc->iobase, sca->imvr, 0x40);
/*
* Configure the timers.
* XXX Later
*/
/*
* Set the DMA channel priority to rotate between
* all four channels.
*
* Enable all dma channels.
*/
SRC_PUT8(hc->iobase, sca->pcr, SCA_PCR_PR2);
SRC_PUT8(hc->iobase, sca->dmer, SCA_DMER_EN);
}
/*
* Configure the msci
*
* NOTE: The serial port configuration is hardcoded at the moment.
*/
static void
sr_init_msci(struct sr_softc *sc)
{
msci_channel *msci = &sc->hc->sca->msci[sc->scachan];
u_short iobase = sc->hc->iobase;
SRC_PUT8(iobase, msci->cmd, SCA_CMD_RESET);
SRC_PUT8(iobase, msci->md0, SCA_MD0_CRC_1 |
SCA_MD0_CRC_CCITT |
SCA_MD0_CRC_ENABLE |
SCA_MD0_MODE_HDLC);
SRC_PUT8(iobase, msci->md1, SCA_MD1_NOADDRCHK);
SRC_PUT8(iobase, msci->md2, SCA_MD2_DUPLEX | SCA_MD2_NRZ);
/*
* According to the manual I should give a reset after changing the
* mode registers.
*/
SRC_PUT8(iobase, msci->cmd, SCA_CMD_RXRESET);
SRC_PUT8(iobase, msci->ctl, SCA_CTL_IDLPAT |
SCA_CTL_UDRNC |
SCA_CTL_RTS);
/*
* XXX Later we will have to support different clock settings.
*/
switch(sc->clk_cfg) {
default:
case SR_FLAGS_EXT_CLK:
/*
* For now all interfaces are programmed to use the
* RX clock for the TX clock.
*/
SRC_PUT8(iobase, msci->rxs, SCA_RXS_CLK_RXC0 | SCA_RXS_DIV1);
SRC_PUT8(iobase, msci->txs, SCA_TXS_CLK_RX | SCA_TXS_DIV1);
break;
case SR_FLAGS_EXT_SEP_CLK:
SRC_PUT8(iobase, msci->rxs, SCA_RXS_CLK_RXC0 | SCA_RXS_DIV1);
SRC_PUT8(iobase, msci->txs, SCA_TXS_CLK_TXC | SCA_TXS_DIV1);
break;
case SR_FLAGS_INT_CLK:
/*
* XXX I do need some code to set the baud rate here!
*/
SRC_PUT8(iobase, msci->rxs, SCA_RXS_CLK_INT | SCA_RXS_DIV1);
SRC_PUT8(iobase, msci->txs, SCA_TXS_CLK_INT | SCA_TXS_DIV1);
SRC_PUT8(iobase, msci->tmc, 153);
if(sc->scachan == 0)
outb(iobase + SR_MCR, inb(iobase + SR_MCR) |
SR_MCR_ETC0);
else
outb(iobase + SR_MCR, inb(iobase + SR_MCR) |
SR_MCR_ETC1);
}
/* XXX
* Disable all interrupts for now. I think if you are using
* the dmac you don't use these interrupts.
*/
SRC_PUT8(iobase, msci->ie0, 0);
SRC_PUT8(iobase, msci->ie1, 0x0C); /* XXX CTS and DCD level change. */
SRC_PUT8(iobase, msci->ie2, 0);
SRC_PUT8(iobase, msci->fie, 0);
SRC_PUT8(iobase, msci->sa0, 0);
SRC_PUT8(iobase, msci->sa1, 0);
SRC_PUT8(iobase, msci->idl, 0x7E); /* XXX This is what cisco does. */
SRC_PUT8(iobase, msci->rrc, 0x0E);
SRC_PUT8(iobase, msci->trc0, 0x10);
SRC_PUT8(iobase, msci->trc1, 0x1F);
}
/*
* Configure the rx dma controller.
*/
static void
sr_init_rx_dmac(struct sr_softc *sc)
{
dmac_channel *dmac = &sc->hc->sca->dmac[DMAC_RXCH(sc->scachan)];
sca_descriptor *rxd;
u_int rxbuf;
u_int rxda;
u_int rxda_d;
u_short iobase = sc->hc->iobase;
SRC_SET_MEM(iobase, sc->rxdesc);
rxd = (sca_descriptor *)(sc->hc->mem_start + (sc->rxdesc&SRC_WIN_MSK));
rxda_d = (u_int)sc->hc->mem_start - (sc->rxdesc & ~SRC_WIN_MSK);
for(rxbuf=sc->rxstart;rxbuf<sc->rxend;rxbuf += SR_BUF_SIZ, rxd++) {
rxda = (u_int)&rxd[1] - rxda_d;
rxd->cp = (u_short)(rxda & 0xfffful);
TRC(printf("Descrp %p, data pt %p, data long %lx, ",
&sc->rxdesc[x], rxinuse->buf, rxbuf));
rxd->bp = (u_short)(rxbuf & 0xfffful);
rxd->bpb = (u_char)((rxbuf >> 16) & 0xff);
rxd->len = 0;
rxd->stat = 0xff; /* The sca write here when it is finished. */
TRC(printf("bpb %x, bp %x.\n", rxd->bpb, rxd->bp));
}
rxd--;
rxd->cp = (u_short)(sc->rxdesc & 0xfffful);
sc->rxhind = 0;
SRC_PUT8(iobase, dmac->dsr, 0); /* Disable DMA transfer */
SRC_PUT8(iobase, dmac->dcr, SCA_DCR_ABRT);
/* XXX maybe also SCA_DMR_CNTE */
SRC_PUT8(iobase, dmac->dmr, SCA_DMR_TMOD | SCA_DMR_NF);
SRC_PUT16(iobase, dmac->bfl, SR_BUF_SIZ);
SRC_PUT16(iobase, dmac->cda, (u_short)(sc->rxdesc & 0xffff));
SRC_PUT8(iobase, dmac->sarb, (u_char)((sc->rxdesc >> 16) & 0xff));
rxd = (sca_descriptor *)sc->rxstart;
SRC_PUT16(iobase, dmac->eda,
(u_short)((u_int)&rxd[sc->rxmax - 1] & 0xffff));
SRC_PUT8(iobase, dmac->dir, 0xF0);
SRC_PUT8(iobase, dmac->dsr, SCA_DSR_DE);
}
/*
* Configure the TX DMA descriptors.
* Initialize the needed values and chain the descriptors.
*/
static void
sr_init_tx_dmac(struct sr_softc *sc)
{
dmac_channel *dmac = &sc->hc->sca->dmac[DMAC_TXCH(sc->scachan)];
struct buf_block *blkp;
int blk;
sca_descriptor *txd;
u_int txbuf;
u_int txda;
u_int txda_d;
u_short iobase = sc->hc->iobase;
SRC_SET_MEM(iobase, sc->block[0].txdesc);
for(blk = 0; blk < SR_TX_BLOCKS; blk++) {
blkp = &sc->block[blk];
txd = (sca_descriptor *)(sc->hc->mem_start +
(blkp->txdesc & SRC_WIN_MSK));
txda_d = (u_int)sc->hc->mem_start -
(blkp->txdesc & ~SRC_WIN_MSK);
txbuf=blkp->txstart;
for(;txbuf<blkp->txend;txbuf += SR_BUF_SIZ, txd++) {
txda = (u_int)&txd[1] - txda_d;
txd->cp = (u_short)(txda & 0xfffful);
txd->bp = (u_short)(txbuf & 0xfffful);
txd->bpb = (u_char)((txbuf >> 16) & 0xff);
TRC(printf("sr%d: txbuf %x, bpb %x, bp %x\n",
sc->unit, txbuf, txd->bpb, txd->bp));
txd->len = 0;
txd->stat = 0;
}
txd--;
txd->cp = (u_short)(blkp->txdesc & 0xfffful);
blkp->txtail = (u_int)txd - (u_int)sc->hc->mem_start;
TRC(printf("TX Descriptors start %x, end %x.\n",
blkp->txhead,
blkp->txtail));
}
SRC_PUT8(iobase, dmac->dsr, 0); /* Disable DMA */
SRC_PUT8(iobase, dmac->dcr, SCA_DCR_ABRT);
SRC_PUT8(iobase, dmac->dmr, SCA_DMR_TMOD | SCA_DMR_NF);
SRC_PUT8(iobase, dmac->dir, SCA_DIR_EOT | SCA_DIR_BOF | SCA_DIR_COF);
SRC_PUT8(iobase, dmac->sarb,
(u_char)((sc->block[0].txdesc >> 16) & 0xff));
}
/*
* Look through the descriptors to see if there is a complete packet
* available. Stop if we get to where the sca is busy.
*
* Return the length and status of the packet.
* Return nonzero if there is a packet available.
*
* NOTE:
* It seems that we get the interrupt a bit early. The updateing of
* descriptor values is not always completed when this is called.
*/
static int
sr_packet_avail(struct sr_softc *sc,
int *len,
u_char *rxstat)
{
sca_descriptor *rxdesc;
sca_descriptor *endp;
sca_descriptor *cda;
cda = (sca_descriptor *)(sc->hc->mem_start +
(SRC_GET16(sc->hc->iobase,
sc->hc->sca->dmac[DMAC_RXCH(sc->scachan)].cda) &
SRC_WIN_MSK));
SRC_SET_MEM(sc->hc->iobase, sc->rxdesc);
rxdesc = (sca_descriptor *)
(sc->hc->mem_start + (sc->rxdesc & SRC_WIN_MSK));
endp = rxdesc;
rxdesc = &rxdesc[sc->rxhind];
endp = &endp[sc->rxmax];
*len = 0;
while(rxdesc != cda) {
*len += rxdesc->len;
if(rxdesc->stat & SCA_DESC_EOM) {
*rxstat = rxdesc->stat;
TRC(printf("sr%d: PKT AVAIL len %d, %x, bufs %u.\n",
sc->unit, *len, *rxstat, x));
return 1;
}
rxdesc++;
if(rxdesc == endp)
rxdesc = (sca_descriptor *)
(sc->hc->mem_start + (sc->rxdesc & SRC_WIN_MSK));
}
*len = 0;
*rxstat = 0;
return 0;
}
/*
* Copy a packet from the on card memory into a provided mbuf.
* Take into account that buffers wrap and that a packet may
* be larger than a buffer.
*/
static void
sr_copy_rxbuf(struct mbuf *m,
struct sr_softc *sc,
int len)
{
sca_descriptor *rxdesc;
u_int rxdata;
u_int rxmax;
u_int off = 0;
u_int tlen;
rxdata = sc->rxstart + (sc->rxhind * SR_BUF_SIZ);
rxmax = sc->rxstart + (sc->rxmax * SR_BUF_SIZ);
rxdesc = (sca_descriptor *)
(sc->hc->mem_start + (sc->rxdesc & SRC_WIN_MSK));
rxdesc = &rxdesc[sc->rxhind];
while(len) {
tlen = (len < SR_BUF_SIZ) ? len : SR_BUF_SIZ;
SRC_SET_MEM(sc->hc->iobase, rxdata);
bcopy(sc->hc->mem_start + (rxdata & SRC_WIN_MSK),
mtod(m, caddr_t) + off,
tlen);
off += tlen;
len -= tlen;
SRC_SET_MEM(sc->hc->iobase, sc->rxdesc);
rxdesc->len = 0;
rxdesc->stat = 0xff;
rxdata += SR_BUF_SIZ;
rxdesc++;
if(rxdata == rxmax) {
rxdata = sc->rxstart;
rxdesc = (sca_descriptor *)
(sc->hc->mem_start + (sc->rxdesc & SRC_WIN_MSK));
}
}
}
/*
* If single is set, just eat a packet. Otherwise eat everything up to
* where cda points. Update pointers to point to the next packet.
*/
static void
sr_eat_packet(struct sr_softc *sc, int single)
{
sca_descriptor *rxdesc;
sca_descriptor *endp;
sca_descriptor *cda;
int loopcnt = 0;
u_char stat;
cda = (sca_descriptor *)(sc->hc->mem_start +
(SRC_GET16(sc->hc->iobase,
sc->hc->sca->dmac[DMAC_RXCH(sc->scachan)].cda) &
SRC_WIN_MSK));
/*
* Loop until desc->stat == (0xff || EOM)
* Clear the status and length in the descriptor.
* Increment the descriptor.
*/
SRC_SET_MEM(sc->hc->iobase, sc->rxdesc);
rxdesc = (sca_descriptor *)
(sc->hc->mem_start + (sc->rxdesc & SRC_WIN_MSK));
endp = rxdesc;
rxdesc = &rxdesc[sc->rxhind];
endp = &endp[sc->rxmax];
while(rxdesc != cda) {
loopcnt++;
if(loopcnt > sc->rxmax) {
printf("sr%d: eat pkt %d loop, cda %x, "
"rxdesc %x, stat %x.\n",
sc->unit,
loopcnt,
cda,
rxdesc,
rxdesc->stat);
break;
}
stat = rxdesc->stat;
rxdesc->len = 0;
rxdesc->stat = 0xff;
rxdesc++;
sc->rxhind++;
if(rxdesc == endp) {
rxdesc = (sca_descriptor *)
(sc->hc->mem_start + (sc->rxdesc & SRC_WIN_MSK));
sc->rxhind = 0;
}
if(single && (stat == SCA_DESC_EOM))
break;
}
/*
* Update the eda to the previous descriptor.
*/
rxdesc = (sca_descriptor *)sc->rxdesc;
rxdesc = &rxdesc[(sc->rxhind + sc->rxmax - 2 ) % sc->rxmax];
SRC_PUT16(sc->hc->iobase,
sc->hc->sca->dmac[DMAC_RXCH(sc->scachan)].eda,
(u_short)((u_int)rxdesc & 0xffff));
}
/*
* While there is packets available in the rx buffer, read them out
* into mbufs and ship them off.
*/
static void
sr_get_packets(struct sr_softc *sc)
{
sca_descriptor *rxdesc;
struct mbuf *m = NULL;
int i;
int len;
u_char rxstat;
SRC_SET_ON(sc->hc->iobase);
while(sr_packet_avail(sc, &len, &rxstat)) {
if((rxstat & SCA_DESC_ERRORS) == 0) {
MGETHDR(m, M_DONTWAIT, MT_DATA);
if(m == NULL) {
/* eat packet if get mbuf fail!! */
sr_eat_packet(sc, 1);
continue;
}
m->m_pkthdr.rcvif = &sc->ifsppp.pp_if;
m->m_pkthdr.len = m->m_len = len;
if(len > MHLEN) {
MCLGET(m, M_DONTWAIT);
if((m->m_flags & M_EXT) == 0) {
m_freem(m);
sr_eat_packet(sc, 1);
continue;
}
}
sr_copy_rxbuf(m, sc, len);
#if NBPFILTER > 0
if(sc->ifsppp.pp_if.if_bpf)
bpf_mtap(&sc->ifsppp.pp_if, m);
#endif
sppp_input(&sc->ifsppp.pp_if, m);
sc->ifsppp.pp_if.if_ipackets++;
/*
* Update the eda to the previous descriptor.
*/
i = (len + SR_BUF_SIZ - 1) / SR_BUF_SIZ;
sc->rxhind = (sc->rxhind + i) % sc->rxmax;
rxdesc = (sca_descriptor *)sc->rxdesc;
rxdesc =
&rxdesc[(sc->rxhind + sc->rxmax - 2 ) % sc->rxmax];
SRC_PUT16(sc->hc->iobase,
sc->hc->sca->dmac[DMAC_RXCH(sc->scachan)].eda,
(u_short)((u_int)rxdesc & 0xffff));
} else {
msci_channel *msci = &sc->hc->sca->msci[sc->scachan];
sr_eat_packet(sc, 1);
sc->ifsppp.pp_if.if_ierrors++;
TRCL(printf("sr%d: Receive error chan %d, "
"stat %x, msci st3 %x,"
"rxhind %d, cda %x, eda %x.\n",
sc->unit,
sc->scachan,
rxstat,
SRC_GET8(sc->hc->iobase, msci->st3),
sc->rxhind,
SRC_GET16(sc->hc->iobase,
sc->hc->sca->dmac[
DMAC_RXCH(sc->scachan)].cda),
SRC_GET16(sc->hc->iobase,
sc->hc->sca->dmac[
DMAC_RXCH(sc->scachan)].eda)));
}
}
SRC_SET_OFF(sc->hc->iobase);
}
/*
* All DMA interrupts come here.
*
* Each channel has two interrupts.
* Interrupt A for errors and Interrupt B for normal stuff like end
* of transmit or receive dmas.
*/
static void
sr_dmac_intr(struct sr_hardc *hc, u_char isr1)
{
u_char dsr;
u_char dotxstart = isr1;
int mch;
struct sr_softc *sc;
sca_regs *sca = hc->sca;
dmac_channel *dmac;
mch = 0;
/*
* Shortcut if there is no interrupts for dma channel 0 or 1
*/
if((isr1 & 0x0F) == 0) {
mch = 1;
isr1 >>= 4;
}
do {
sc = &hc->sc[mch];
/*
* Transmit channel
*/
if(isr1 & 0x0C) {
dmac = &sca->dmac[DMAC_TXCH(mch)];
dsr = SRC_GET8(hc->iobase, dmac->dsr);
SRC_PUT8(hc->iobase, dmac->dsr, dsr);
/* Counter overflow */
if(dsr & SCA_DSR_COF) {
printf("sr%d: TX DMA Counter overflow, "
"txpacket no %lu.\n",
sc->unit,
sc->ifsppp.pp_if.if_opackets);
sc->ifsppp.pp_if.if_oerrors++;
}
/* Buffer overflow */
if(dsr & SCA_DSR_BOF) {
printf("sr%d: TX DMA Buffer overflow, "
"txpacket no %lu, dsr %02x, "
"cda %04x, eda %04x.\n",
sc->unit,
sc->ifsppp.pp_if.if_opackets,
dsr,
SRC_GET16(hc->iobase, dmac->cda),
SRC_GET16(hc->iobase, dmac->eda));
sc->ifsppp.pp_if.if_oerrors++;
}
/* End of Transfer */
if(dsr & SCA_DSR_EOT) {
/*
* This should be the most common case.
*
* Clear the IFF_OACTIVE flag.
*
* Call srstart to start a new transmit if
* there is data to transmit.
*/
sc->xmit_busy = 0;
sc->ifsppp.pp_if.if_flags &= ~IFF_OACTIVE;
sc->ifsppp.pp_if.if_timer = 0;
if(sc->txb_inuse && --sc->txb_inuse)
sr_xmit(sc);
}
}
/*
* Receive channel
*/
if(isr1 & 0x03) {
dmac = &sca->dmac[DMAC_RXCH(mch)];
dsr = SRC_GET8(hc->iobase, dmac->dsr);
SRC_PUT8(hc->iobase, dmac->dsr, dsr);
TRC(printf("SR: RX DSR %x\n", dsr));
/* End of frame */
if(dsr & SCA_DSR_EOM) {
TRC(int tt = sc->ifsppp.pp_if.if_ipackets;)
TRC(int ind = sc->rxhind;)
sr_get_packets(sc);
TRC(
if(tt == sc->ifsppp.pp_if.if_ipackets) {
sca_descriptor *rxdesc;
int i;
printf("SR: RXINTR isr1 %x, dsr %x, "
"no data %d pkts, orxhind %d.\n",
dotxstart,
dsr,
tt,
ind);
printf("SR: rxdesc %x, rxstart %x, "
"rxend %x, rxhind %d, "
"rxmax %d.\n",
sc->rxdesc,
sc->rxstart,
sc->rxend,
sc->rxhind,
sc->rxmax);
printf("SR: cda %x, eda %x.\n",
SRC_GET16(hc->iobase, dmac->cda),
SRC_GET16(hc->iobase, dmac->eda));
SRC_SET_ON(hc->iobase);
SRC_SET_MEM(hc->iobase, sc->rxdesc);
rxdesc = (sca_descriptor *)
(hc->mem_start +
(sc->rxdesc & SRC_WIN_MSK));
rxdesc = &rxdesc[sc->rxhind];
for(i=0;i<3;i++,rxdesc++)
printf("SR: rxdesc->stat %x, "
"len %d.\n",
rxdesc->stat,
rxdesc->len);
SRC_SET_OFF(hc->iobase);
})
}
/* Counter overflow */
if(dsr & SCA_DSR_COF) {
printf("sr%d: RX DMA Counter overflow, "
"rxpkts %lu.\n",
sc->unit,
sc->ifsppp.pp_if.if_ipackets);
sc->ifsppp.pp_if.if_ierrors++;
}
/* Buffer overflow */
if(dsr & SCA_DSR_BOF) {
printf("sr%d: RX DMA Buffer overflow, "
"rxpkts %lu, rxind %d, "
"cda %x, eda %x, dsr %x.\n",
sc->unit,
sc->ifsppp.pp_if.if_ipackets,
sc->rxhind,
SRC_GET16(hc->iobase, dmac->cda),
SRC_GET16(hc->iobase, dmac->eda),
dsr);
/*
* Make sure we eat as many as possible.
* Then get the system running again.
*/
SRC_SET_ON(sc->hc->iobase);
sr_eat_packet(sc, 0);
sc->ifsppp.pp_if.if_ierrors++;
SRC_PUT8(hc->iobase,
sca->msci[mch].cmd,
SCA_CMD_RXMSGREJ);
SRC_PUT8(hc->iobase, dmac->dsr, SCA_DSR_DE);
TRC(printf("sr%d: RX DMA Buffer overflow, "
"rxpkts %lu, rxind %d, "
"cda %x, eda %x, dsr %x. After\n",
sc->unit,
sc->ifsppp.pp_if.if_ipackets,
sc->rxhind,
SRC_GET16(hc->iobase, dmac->cda),
SRC_GET16(hc->iobase, dmac->eda),
SRC_GET8(hc->iobase, dmac->dsr));)
SRC_SET_OFF(sc->hc->iobase);
}
/* End of Transfer */
if(dsr & SCA_DSR_EOT) {
/*
* If this happen, it means that we are
* receiving faster than what the processor
* can handle.
*
* XXX We should enable the dma again.
*/
printf("sr%d: RX End of transfer, rxpkts %lu.\n",
sc->unit,
sc->ifsppp.pp_if.if_ipackets);
sc->ifsppp.pp_if.if_ierrors++;
}
}
isr1 >>= 4;
mch++;
}while((mch<NCHAN) && isr1);
/*
* Now that we have done all the urgent things, see if we
* can fill the transmit buffers.
*/
for(mch = 0; mch < NCHAN; mch++) {
if(dotxstart & 0x0C) {
sc = &hc->sc[mch];
srstart(&sc->ifsppp.pp_if);
}
dotxstart >>= 4;
}
}
static void
sr_msci_intr(struct sr_hardc *hc, u_char isr0)
{
printf("src%d: SRINTR: MSCI\n", hc->cunit);
}
static void
sr_timer_intr(struct sr_hardc *hc, u_char isr2)
{
printf("src%d: SRINTR: TIMER\n", hc->cunit);
}
/*
********************************* END ************************************
*/