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|
/* $OpenBSD: midway.c,v 1.7 1996/06/29 23:22:31 chuck Exp $ */
/* (sync'd to midway.c 1.56) */
/*
*
* Copyright (c) 1996 Charles D. Cranor and Washington University.
* 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 Charles D. Cranor and
* Washington University.
* 4. The name of the author may not be used to endorse or promote products
* derived from this software without specific prior written permission.
*
* THIS SOFTWARE IS PROVIDED BY THE AUTHOR ``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 THE AUTHOR 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.
*/
/*
*
* m i d w a y . c e n i 1 5 5 d r i v e r
*
* author: Chuck Cranor <chuck@ccrc.wustl.edu>
* started: spring, 1996 (written from scratch).
*
* notes from the author:
* Extra special thanks go to Werner Almesberger, EPFL LRC. Werner's
* ENI driver was especially useful in figuring out how this card works.
* I would also like to thank Werner for promptly answering email and being
* generally helpful.
*/
#undef EN_DEBUG
#undef EN_DEBUG_RANGE /* check ranges on en_read/en_write's? */
#define EN_MBUF_OPT /* try and put more stuff in mbuf? */
#define EN_DIAG
#define EN_STAT
#ifndef EN_DMA
#define EN_DMA 1 /* use dma? */
#endif
#define EN_NOTXDMA 0 /* hook to disable tx dma only */
#define EN_NORXDMA 0 /* hook to disable rx dma only */
#define EN_NOWMAYBE 1 /* hook to disable word maybe DMA */
/* XXX: WMAYBE doesn't work, needs debugging */
#define EN_DDBHOOK 1 /* compile in ddb functions */
#if defined(DIAGNOSTIC) && !defined(EN_DIAG)
#define EN_DIAG /* link in with master DIAG option */
#endif
#ifdef EN_STAT
#define EN_COUNT(X) (X)++
#else
#define EN_COUNT(X) /* nothing */
#endif
#ifdef EN_DEBUG
#undef EN_DDBHOOK
#define EN_DDBHOOK 1
#define STATIC /* nothing */
#define INLINE /* nothing */
#else /* EN_DEBUG */
#define STATIC static
#define INLINE inline
#endif /* EN_DEBUG */
#include <sys/param.h>
#include <sys/systm.h>
#include <sys/types.h>
#include <sys/device.h>
#include <sys/ioctl.h>
#include <sys/mbuf.h>
#include <sys/socket.h>
#include <sys/socketvar.h>
#include <net/if.h>
#include <net/if_atm.h>
#include <vm/vm.h>
#ifdef INET
#include <netinet/if_atm.h>
#endif
#ifdef NATM
#include <netinet/in.h>
#include <netnatm/natm.h>
#endif
#ifndef sparc
#include <machine/bus.h>
#endif
#include <dev/ic/midwayreg.h>
#include <dev/ic/midwayvar.h>
/*
* params
*/
#ifndef EN_TXHIWAT
#define EN_TXHIWAT (32*1024) /* max 32 KB waiting to be DMAd out */
#endif
#ifndef EN_MINDMA
#define EN_MINDMA 64 /* don't DMA anything less than this (bytes) */
#endif
#define RX_NONE 0xffff /* recv VC not in use */
#define EN_OBHDR ATM_PH_DRIVER7 /* TBD in first mbuf ! */
#define EN_OBTRL ATM_PH_DRIVER8 /* PDU trailier in last mbuf ! */
#define ENOTHER_FREE 0x01 /* free rxslot */
#define ENOTHER_DRAIN 0x02 /* almost free (drain DRQ dma) */
#define ENOTHER_RAW 0x04 /* 'raw' access (aka boodi mode) */
#define ENOTHER_SWSL 0x08 /* in software service list */
int en_dma = EN_DMA; /* use DMA (switch off for dbg) */
/*
* autoconfig attachments
*/
struct cfdriver en_cd = {
0, "en", DV_IFNET,
};
/*
* local structures
*/
/*
* params to en_txlaunch() function
*/
struct en_launch {
u_int32_t tbd1; /* TBD 1 */
u_int32_t tbd2; /* TBD 2 */
u_int32_t pdu1; /* PDU 1 (aal5) */
int nodma; /* don't use DMA */
int need; /* total space we need (pad out if less data) */
int mlen; /* length of mbuf (for dtq) */
struct mbuf *t; /* data */
u_int32_t aal; /* aal code */
u_int32_t atm_vci; /* vci */
u_int8_t atm_flags; /* flags */
};
/*
* dma table (index by # of words)
*
* plan A: use WMAYBE
* plan B: avoid WMAYBE
*/
struct en_dmatab {
u_int8_t bcode; /* code */
u_int8_t divshift; /* byte divisor */
};
static struct en_dmatab en_dma_planA[] = {
{ 0, 0 }, /* 0 */ { MIDDMA_WORD, 2 }, /* 1 */
{ MIDDMA_2WORD, 3}, /* 2 */ { MIDDMA_4WMAYBE, 2}, /* 3 */
{ MIDDMA_4WORD, 4}, /* 4 */ { MIDDMA_8WMAYBE, 2}, /* 5 */
{ MIDDMA_8WMAYBE, 2}, /* 6 */ { MIDDMA_8WMAYBE, 2}, /* 7 */
{ MIDDMA_8WORD, 5}, /* 8 */ { MIDDMA_16WMAYBE, 2}, /* 9 */
{ MIDDMA_16WMAYBE,2}, /* 10 */ { MIDDMA_16WMAYBE, 2}, /* 11 */
{ MIDDMA_16WMAYBE,2}, /* 12 */ { MIDDMA_16WMAYBE, 2}, /* 13 */
{ MIDDMA_16WMAYBE,2}, /* 14 */ { MIDDMA_16WMAYBE, 2}, /* 15 */
{ MIDDMA_16WORD, 6}, /* 16 */
};
static struct en_dmatab en_dma_planB[] = {
{ 0, 0 }, /* 0 */ { MIDDMA_WORD, 2}, /* 1 */
{ MIDDMA_2WORD, 3}, /* 2 */ { MIDDMA_WORD, 2}, /* 3 */
{ MIDDMA_4WORD, 4}, /* 4 */ { MIDDMA_WORD, 2}, /* 5 */
{ MIDDMA_2WORD, 3}, /* 6 */ { MIDDMA_WORD, 2}, /* 7 */
{ MIDDMA_8WORD, 5}, /* 8 */ { MIDDMA_WORD, 2}, /* 9 */
{ MIDDMA_2WORD, 3}, /* 10 */ { MIDDMA_WORD, 2}, /* 11 */
{ MIDDMA_4WORD, 4}, /* 12 */ { MIDDMA_WORD, 2}, /* 13 */
{ MIDDMA_2WORD, 3}, /* 14 */ { MIDDMA_WORD, 2}, /* 15 */
{ MIDDMA_16WORD, 6}, /* 16 */
};
static struct en_dmatab *en_dmaplan = en_dma_planA;
/*
* macros/inline
*/
#ifdef EN_DEBUG_RANGE
u_int32_t en_read(sc, r)
struct en_softc *sc;
u_int32_t r;
{
if (r > MID_MAXOFF || (r % 4)) {
printf("en_read out of range, r=0x%x\n", r);
panic("en_read");
}
return(bus_mem_read_4(sc->en_bc, sc->en_base, r));
}
#define EN_READ(SC,R) ntohl(en_read(SC,R))
#define EN_READDAT(SC,R) en_read(SC,R)
void en_write(sc, r, v)
struct en_softc *sc;
u_int32_t r, v;
{
if (r > MID_MAXOFF || (r % 4)) {
printf("en_write out of range, r=0x%x\n", r);
panic("en_write");
}
bus_mem_write_4(sc->en_bc, sc->en_base, r, v);
}
#define EN_WRITE(SC,R,V) en_write(SC,R, htonl(V))
#define EN_WRITEDAT(SC,R,V) en_write(SC,R,V)
#else /* EN_DEBUG_RANGE */
#define EN_READ(SC,R) ntohl(bus_mem_read_4((SC)->en_bc, (SC)->en_base, (R)))
#define EN_WRITE(SC,R,V) \
bus_mem_write_4((SC)->en_bc, (SC)->en_base, (R), htonl((V)))
#define EN_READDAT(SC,R) bus_mem_read_4((SC)->en_bc, (SC)->en_base, (R))
#define EN_WRITEDAT(SC,R,V) \
bus_mem_write_4((SC)->en_bc, (SC)->en_base, (R), (V))
#define EN_WRAPADD(START,STOP,CUR,VAL) { \
(CUR) = (CUR) + (VAL); \
if ((CUR) >= (STOP)) \
(CUR) = (START) + ((CUR) - (STOP)); \
}
#endif /* EN_DEBUG_RANGE */
#define WORD_IDX(START, X) (((X) - (START)) / sizeof(u_int32_t))
/* we store sc->dtq and sc->drq data in the following format... */
#define EN_DQ_MK(SLOT,LEN) (((SLOT) << 20)|(LEN))
#define EN_DQ_SLOT(X) ((X) >> 20)
#define EN_DQ_LEN(X) ((X) & 0xfffff)
/* add an item to the DTQ (more to come) */
#define EN_DTQADD(SC,CNT,CHAN,BCODE,ADDR) \
EN_DTQADD_XXX(SC,CNT,CHAN,BCODE,ADDR,0)
/* add a final item to the DTQ and kick it */
#define EN_DTQADDEND(SC,CNT,CHAN,BCODE,ADDR,LEN) { \
(SC)->dtq[MID_DTQ_A2REG((SC)->dtq_us)] = EN_DQ_MK(CHAN,LEN); \
EN_DTQADD_XXX(SC,CNT,CHAN,BCODE,ADDR,MID_DMA_END); \
EN_WRITE((SC), MID_DMA_WRTX, MID_DTQ_A2REG((SC)->dtq_us)); \
}
/* DTQ add helper macro */
#define EN_DTQADD_XXX(SC,CNT,CHAN,BCODE,ADDR,END) { \
EN_WRITE((SC), (SC)->dtq_us, \
MID_MK_TXQ((CNT), (CHAN), (END), (BCODE))); \
(SC)->dtq_us += 4; \
EN_WRITE((SC), (SC)->dtq_us, (ADDR)); \
EN_WRAPADD(MID_DTQOFF, MID_DTQEND, (SC)->dtq_us, 4); \
(SC)->dtq_free--; \
}
/* add an item to the DRQ (more to come) */
#define EN_DRQADD(SC,CNT,VCI,BCODE,ADDR) \
EN_DRQADD_XXX(SC,CNT,VCI,BCODE,ADDR,0)
/* add a final item to the DRQ and kick it */
#define EN_DRQADDEND(SC,CNT,VCI,BCODE,ADDR,LEN,SLOT) { \
(SC)->drq[MID_DRQ_A2REG((SC)->drq_us)] = EN_DQ_MK(SLOT,LEN); \
EN_DRQADD_XXX(SC,CNT,VCI,BCODE,ADDR,MID_DMA_END); \
EN_WRITE((SC), MID_DMA_WRRX, MID_DRQ_A2REG((SC)->drq_us)); \
}
/* DRQ add helper macro */
#define EN_DRQADD_XXX(SC,CNT,VCI,BCODE,ADDR,END) { \
EN_WRITE((SC), (SC)->drq_us, \
MID_MK_RXQ((CNT), (VCI), (END), (BCODE))); \
(SC)->drq_us += 4; \
EN_WRITE((SC), (SC)->drq_us, (ADDR)); \
EN_WRAPADD(MID_DRQOFF, MID_DRQEND, (SC)->drq_us, 4); \
(SC)->drq_free--; \
}
/*
* prototypes
*/
void en_attach __P((struct en_softc *));
STATIC int en_b2sz __P((int));
#ifdef EN_DEBUG
int en_dump __P((int,int));
int en_dumpmem __P((int,int,int));
#endif
STATIC void en_dmaprobe __P((struct en_softc *));
STATIC int en_dmaprobe_doit __P((struct en_softc *, u_int8_t *,
u_int8_t *, int));
STATIC int en_dqneed __P((struct en_softc *, caddr_t, u_int));
STATIC void en_init __P((struct en_softc *));
int en_intr __P((void *));
STATIC int en_ioctl __P((struct ifnet *, u_long, caddr_t));
STATIC int en_k2sz __P((int));
STATIC void en_loadvc __P((struct en_softc *, int));
STATIC void en_mfix __P((struct en_softc *, struct mbuf *));
STATIC struct mbuf *en_mget __P((struct en_softc *, u_int, u_int *));
STATIC void en_reset __P((struct en_softc *));
STATIC int en_rxctl __P((struct en_softc *, struct atm_pseudoioctl *, int));
STATIC void en_txdma __P((struct en_softc *, int));
STATIC void en_txlaunch __P((struct en_softc *, int, struct en_launch *));
STATIC void en_service __P((struct en_softc *));
STATIC void en_start __P((struct ifnet *));
STATIC int en_sz2b __P((int));
/*
* the driver code
*
* the code is arranged in a specific way:
* [1] short/inline functions
* [2] autoconfig stuff
* [3] ioctl stuff
* [4] reset -> init -> trasmit -> intr -> receive functions
*
*/
/***********************************************************************/
/*
* en_k2sz: convert KBytes to a size parameter (a log2)
*/
STATIC INLINE int en_k2sz(k)
int k;
{
switch(k) {
case 1: return(0);
case 2: return(1);
case 4: return(2);
case 8: return(3);
case 16: return(4);
case 32: return(5);
case 64: return(6);
case 128: return(7);
default: panic("en_k2sz");
}
return(0);
}
#define en_log2(X) en_k2sz(X)
/*
* en_b2sz: convert a DMA burst code to its byte size
*/
STATIC INLINE int en_b2sz(b)
int b;
{
switch (b) {
case MIDDMA_WORD: return(1*4);
case MIDDMA_2WMAYBE:
case MIDDMA_2WORD: return(2*4);
case MIDDMA_4WMAYBE:
case MIDDMA_4WORD: return(4*4);
case MIDDMA_8WMAYBE:
case MIDDMA_8WORD: return(8*4);
case MIDDMA_16WMAYBE:
case MIDDMA_16WORD: return(16*4);
default: panic("en_k2sz");
}
return(0);
}
/*
* en_sz2b: convert a burst size (bytes) to DMA burst code
*/
STATIC INLINE int en_sz2b(sz)
int sz;
{
switch (sz) {
case 1*4: return(MIDDMA_WORD);
case 2*4: return(MIDDMA_2WORD);
case 4*4: return(MIDDMA_4WORD);
case 8*4: return(MIDDMA_8WORD);
case 16*4: return(MIDDMA_16WORD);
default: panic("en_k2sz");
}
return(0);
}
/*
* en_dqneed: calculate number of DTQ/DRQ's needed for a buffer
*/
STATIC INLINE int en_dqneed(sc, data, len)
struct en_softc *sc;
caddr_t data;
u_int len;
{
int result = 0, needalign;
if (len < EN_MINDMA) {
return(1); /* will copy/DMA_JK */
}
if (sc->alburst) {
needalign = (((u_int) data) & sc->bestburstmask);
if (needalign) {
result++; /* alburst */
len = len - (sc->bestburstlen - needalign);
}
}
if (len)
result++; /* best shot */
if (len > sc->bestburstlen && (len & sc->bestburstmask) != 0)
result++; /* clean up */
return(result);
}
/*
* en_mget: get an mbuf chain that can hold totlen bytes and return it
* (for recv) [based on am7990_get from if_le and ieget from if_ie]
* after this call the sum of all the m_len's in the chain will be totlen.
*/
STATIC INLINE struct mbuf *en_mget(sc, totlen, drqneed)
struct en_softc *sc;
u_int totlen, *drqneed;
{
struct mbuf *m;
struct mbuf *top, **mp;
*drqneed = 0;
MGETHDR(m, M_DONTWAIT, MT_DATA);
if (m == NULL)
return(NULL);
m->m_pkthdr.rcvif = &sc->enif;
m->m_pkthdr.len = totlen;
m->m_len = MHLEN;
top = NULL;
mp = ⊤
/* if (top != NULL) then we've already got 1 mbuf on the chain */
while (totlen > 0) {
if (top) {
MGET(m, M_DONTWAIT, MT_DATA);
if (!m) {
m_freem(top);
return(NULL); /* out of mbufs */
}
m->m_len = MLEN;
}
if (top && totlen >= MINCLSIZE) {
MCLGET(m, M_DONTWAIT);
if (m->m_flags & M_EXT)
m->m_len = MCLBYTES;
}
m->m_len = min(totlen, m->m_len);
totlen -= m->m_len;
*mp = m;
mp = &m->m_next;
*drqneed += en_dqneed(sc, m->m_data, m->m_len);
}
return(top);
}
/***********************************************************************/
/*
* autoconfig stuff
*/
void en_attach(sc)
struct en_softc *sc;
{
struct ifnet *ifp = &sc->enif;
bus_mem_addr_t membase;
const char *intrstr;
int retval, sz;
u_int32_t reg, lcv, check, ptr, sav, midvloc;
/*
* probe card to determine memory size. the stupid ENI card always
* reports to PCI that it needs 4MB of space (2MB regs and 2MB RAM).
* if it has less than 2MB RAM the addresses wrap in the RAM address space.
* (i.e. on a 512KB card addresses 0x3ffffc, 0x37fffc, and 0x2ffffc
* are aliases for 0x27fffc [note that RAM starts at offset 0x200000]).
*/
EN_WRITE(sc, MID_RESID, 0x0); /* reset card before touching RAM */
for (lcv = MID_PROBEOFF; lcv <= MID_MAXOFF ; lcv += MID_PROBSIZE) {
EN_WRITE(sc, lcv, lcv); /* data[address] = address */
for (check = MID_PROBEOFF ; check < lcv ; check += MID_PROBSIZE) {
reg = EN_READ(sc, check);
if (reg != check) { /* found an alias! */
lcv -= MID_PROBSIZE; /* take one step back */
goto done_probe; /* and quit */
}
}
}
done_probe:
sc->en_obmemsz = (lcv + 4) - MID_RAMOFF;
/*
* determine the largest DMA burst supported
*/
en_dmaprobe(sc);
/*
* "hello world"
*/
EN_WRITE(sc, MID_RESID, 0x0); /* reset */
for (lcv = MID_RAMOFF ; lcv < MID_RAMOFF + sc->en_obmemsz ; lcv += 4)
EN_WRITE(sc, lcv, 0); /* zero memory */
reg = EN_READ(sc, MID_RESID);
printf("%s: ATM midway v%d, board IDs %d.%d, %s%s%s, %dKB on-board RAM\n",
sc->sc_dev.dv_xname, MID_VER(reg), MID_MID(reg), MID_DID(reg),
(MID_IS_SABRE(reg)) ? "sabre controller, " : "",
(MID_IS_SUNI(reg)) ? "SUNI" : "Utopia",
(!MID_IS_SUNI(reg) && MID_IS_UPIPE(reg)) ? " (pipelined)" : "",
sc->en_obmemsz / 1024);
printf("%s: maximum DMA burst length = %d bytes%s\n", sc->sc_dev.dv_xname,
sc->bestburstlen, (sc->alburst) ? " (must align)" : "");
#if 0 /* WMAYBE doesn't work, don't complain about it */
/* check if en_dmaprobe disabled wmaybe */
if (en_dmaplan == en_dma_planB)
printf("%s: note: WMAYBE DMA has been disabled\n", sc->sc_dev.dv_xname);
#endif
/*
* link into network subsystem and prepare card
*/
bcopy(sc->sc_dev.dv_xname, sc->enif.if_xname, IFNAMSIZ);
sc->enif.if_softc = sc;
ifp->if_flags = IFF_SIMPLEX|IFF_NOTRAILERS;
ifp->if_ioctl = en_ioctl;
ifp->if_output = atm_output;
ifp->if_start = en_start;
/*
* init softc
*/
for (lcv = 0 ; lcv < MID_N_VC ; lcv++) {
sc->rxvc2slot[lcv] = RX_NONE;
sc->txspeed[lcv] = 0; /* full */
}
sz = sc->en_obmemsz - (MID_BUFOFF - MID_RAMOFF);
ptr = sav = MID_BUFOFF;
ptr = roundup(ptr, EN_TXSZ * 1024); /* align */
sz = sz - (ptr - sav);
if (EN_TXSZ*1024 * EN_NTX > sz) {
printf("%s: EN_NTX/EN_TXSZ too big\n", sc->sc_dev.dv_xname);
return;
}
for (lcv = 0 ; lcv < EN_NTX ; lcv++) {
sc->txslot[lcv].mbsize = 0;
sc->txslot[lcv].start = ptr;
ptr += (EN_TXSZ * 1024);
sz -= (EN_TXSZ * 1024);
sc->txslot[lcv].stop = ptr;
bzero(&sc->txslot[lcv].indma, sizeof(sc->txslot[lcv].indma));
bzero(&sc->txslot[lcv].q, sizeof(sc->txslot[lcv].q));
#ifdef EN_DEBUG
printf("%s: tx%d: start 0x%x, stop 0x%x\n", sc->sc_dev.dv_xname, lcv,
sc->txslot[lcv].start, sc->txslot[lcv].stop);
#endif
}
sav = ptr;
ptr = roundup(ptr, EN_RXSZ * 1024); /* align */
sz = sz - (ptr - sav);
sc->en_nrx = sz / (EN_RXSZ * 1024);
if (sc->en_nrx <= 0) {
printf("%s: EN_NTX/EN_TXSZ/EN_RXSZ too big\n", sc->sc_dev.dv_xname);
return;
}
for (lcv = 0 ; lcv < sc->en_nrx ; lcv++) {
sc->rxslot[lcv].rxhand = NULL;
sc->rxslot[lcv].oth_flags = ENOTHER_FREE;
bzero(&sc->rxslot[lcv].indma, sizeof(sc->rxslot[lcv].indma));
bzero(&sc->rxslot[lcv].q, sizeof(sc->rxslot[lcv].q));
midvloc = sc->rxslot[lcv].start = ptr;
ptr += (EN_RXSZ * 1024);
sz -= (EN_RXSZ * 1024);
sc->rxslot[lcv].stop = ptr;
midvloc = (midvloc & ~((EN_RXSZ*1024) - 1)) >> 2; /* mask, cvt to words */
midvloc = midvloc >> MIDV_LOCTOPSHFT; /* we only want the top 11 bits */
midvloc = (midvloc & MIDV_LOCMASK) << MIDV_LOCSHIFT;
sc->rxslot[lcv].mode = midvloc |
(en_k2sz(EN_RXSZ) << MIDV_SZSHIFT) | MIDV_TRASH;
#ifdef EN_DEBUG
printf("%s: rx%d: start 0x%x, stop 0x%x, mode 0x%x\n", sc->sc_dev.dv_xname,
lcv, sc->rxslot[lcv].start, sc->rxslot[lcv].stop, sc->rxslot[lcv].mode);
#endif
}
#ifdef EN_STAT
sc->vtrash = sc->otrash = sc->mfix = sc->txmbovr = sc->dmaovr = 0;
sc->txoutspace = sc->txdtqout = sc->launch = sc->lheader = sc->ltail = 0;
sc->hwpull = sc->swadd = sc->rxqnotus = sc->rxqus = sc->rxoutboth = 0;
sc->rxdrqout = sc->ttrash = sc->rxmbufout = 0;
#endif
sc->need_drqs = sc->need_dtqs = 0;
printf("%s: %d %dKB receive buffers, %d %dKB transmit buffers allocated\n",
sc->sc_dev.dv_xname, sc->en_nrx, EN_RXSZ, EN_NTX, EN_TXSZ);
/*
* final commit
*/
if_attach(ifp);
atm_ifattach(ifp);
}
/*
* en_dmaprobe: helper function for en_attach.
*
* see how the card handles DMA by running a few DMA tests. we need
* to figure out the largest number of bytes we can DMA in one burst
* ("bestburstlen"), and if the starting address for a burst needs to
* be aligned on any sort of boundary or not ("alburst").
*
* typical findings:
* sparc1: bestburstlen=4, alburst=0 (ick, broken DMA!)
* sparc2: bestburstlen=64, alburst=1
* p166: bestburstlen=64, alburst=0
*/
STATIC void en_dmaprobe(sc)
struct en_softc *sc;
{
u_int32_t srcbuf[64], dstbuf[64];
u_int8_t *sp, *dp;
int bestalgn, bestnotalgn, lcv, try, fail;
sc->alburst = 0;
sp = (u_int8_t *) srcbuf;
while ((((u_int) sp) % MIDDMA_MAXBURST) != 0)
sp += 4;
dp = (u_int8_t *) dstbuf;
while ((((u_int) dp) % MIDDMA_MAXBURST) != 0)
dp += 4;
bestalgn = bestnotalgn = en_dmaprobe_doit(sc, sp, dp, 0);
for (lcv = 4 ; lcv < MIDDMA_MAXBURST ; lcv += 4) {
try = en_dmaprobe_doit(sc, sp+lcv, dp+lcv, 0);
if (try < bestnotalgn)
bestnotalgn = try;
}
if (bestalgn != bestnotalgn) /* need bursts aligned */
sc->alburst = 1;
sc->bestburstlen = bestalgn;
sc->bestburstshift = en_log2(bestalgn);
sc->bestburstmask = sc->bestburstlen - 1; /* must be power of 2 */
sc->bestburstcode = en_sz2b(bestalgn);
if (sc->bestburstlen <= 2*sizeof(u_int32_t))
return; /* won't be using WMAYBE */
/*
* test that WMAYBE dma works like we think it should
* (i.e. no alignment restrictions on host address other than alburst)
*/
try = sc->bestburstlen - 4;
fail = 0;
fail += en_dmaprobe_doit(sc, sp, dp, try);
for (lcv = 4 ; lcv < sc->bestburstlen ; lcv += 4) {
fail += en_dmaprobe_doit(sc, sp+lcv, dp+lcv, try);
if (sc->alburst)
try -= 4;
}
if (EN_NOWMAYBE || fail) {
if (fail)
printf("%s: WARNING: WMAYBE DMA test failed %d time(s)\n",
sc->sc_dev.dv_xname, fail);
en_dmaplan = en_dma_planB; /* fall back to plan B */
}
}
/*
* en_dmaprobe_doit: do actual testing
*/
en_dmaprobe_doit(sc, sp, dp, wmtry)
struct en_softc *sc;
u_int8_t *sp, *dp;
int wmtry;
{
int lcv, retval = 4, cnt, count;
u_int32_t reg, bcode, midvloc;
/*
* set up a 1k buffer at MID_BUFOFF
*/
EN_WRITE(sc, MID_RESID, 0x0); /* reset card before touching RAM */
for (lcv = MID_BUFOFF ; lcv < 1024; lcv += 4)
EN_WRITE(sc, lcv, 0); /* zero memory */
midvloc = (MID_BUFOFF / sizeof(u_int32_t)) >> MIDV_LOCTOPSHFT;
EN_WRITE(sc, MIDX_PLACE(0), MIDX_MKPLACE(en_k2sz(1), midvloc));
EN_WRITE(sc, MID_VC(0), (midvloc << MIDV_LOCSHIFT)
| (en_k2sz(1) << MIDV_SZSHIFT) | MIDV_TRASH);
EN_WRITE(sc, MID_DST_RP(0), 0);
EN_WRITE(sc, MID_WP_ST_CNT(0), 0);
for (lcv = 0 ; lcv < 68 ; lcv++) /* set up sample data */
sp[lcv] = lcv+1;
EN_WRITE(sc, MID_MAST_CSR, MID_MCSR_ENDMA); /* enable DMA (only) */
sc->drq_chip = MID_DRQ_REG2A(EN_READ(sc, MID_DMA_RDRX));
sc->dtq_chip = MID_DTQ_REG2A(EN_READ(sc, MID_DMA_RDTX));
/*
* try it now . . . DMA it out, then DMA it back in and compare
*
* note: in order to get the dma stuff to reverse directions it wants
* the "end" flag set! since we are not dma'ing valid data we may
* get an ident mismatch interrupt (which we will ignore).
*
* note: we've got two different tests rolled up in the same loop
* if (wmtry)
* then we are doing a wmaybe test and wmtry is a byte count
* else we are doing a burst test
*/
for (lcv = 8 ; lcv <= MIDDMA_MAXBURST ; lcv = lcv * 2) {
if (wmtry) {
count = (sc->bestburstlen - sizeof(u_int32_t)) / sizeof(u_int32_t);
bcode = en_dmaplan[count].bcode;
count = wmtry >> en_dmaplan[count].divshift;
} else {
bcode = en_sz2b(lcv);
count = 1;
}
EN_WRITE(sc, sc->dtq_chip, MID_MK_TXQ(count, 0, MID_DMA_END, bcode));
EN_WRITE(sc, sc->dtq_chip+4, vtophys(sp));
EN_WRITE(sc, MID_DMA_WRTX, MID_DTQ_A2REG(sc->dtq_chip+8));
cnt = 1000;
while (EN_READ(sc, MID_DMA_RDTX) == MID_DTQ_A2REG(sc->dtq_chip)) {
DELAY(1);
cnt--;
if (cnt == 0) {
printf("%s: unexpected timeout in tx DMA test\n", sc->sc_dev.dv_xname);
return(retval); /* timeout, give up */
}
}
EN_WRAPADD(MID_DTQOFF, MID_DTQEND, sc->dtq_chip, 8);
reg = EN_READ(sc, MID_INTACK);
if ((reg & MID_INT_DMA_TX) != MID_INT_DMA_TX) {
printf("%s: unexpected status in tx DMA test: 0x%x\n",
sc->sc_dev.dv_xname, reg);
return(retval);
}
EN_WRITE(sc, MID_MAST_CSR, MID_MCSR_ENDMA); /* re-enable DMA (only) */
/* "return to sender..." address is known ... */
EN_WRITE(sc, sc->drq_chip, MID_MK_RXQ(count, 0, MID_DMA_END, bcode));
EN_WRITE(sc, sc->drq_chip+4, vtophys(dp));
EN_WRITE(sc, MID_DMA_WRRX, MID_DRQ_A2REG(sc->drq_chip+8));
cnt = 1000;
while (EN_READ(sc, MID_DMA_RDRX) == MID_DRQ_A2REG(sc->drq_chip)) {
DELAY(1);
cnt--;
if (cnt == 0) {
printf("%s: unexpected timeout in rx DMA test\n", sc->sc_dev.dv_xname);
return(retval); /* timeout, give up */
}
}
EN_WRAPADD(MID_DRQOFF, MID_DRQEND, sc->drq_chip, 8);
reg = EN_READ(sc, MID_INTACK);
if ((reg & MID_INT_DMA_RX) != MID_INT_DMA_RX) {
printf("%s: unexpected status in rx DMA test: 0x%x\n",
sc->sc_dev.dv_xname, reg);
return(retval);
}
EN_WRITE(sc, MID_MAST_CSR, MID_MCSR_ENDMA); /* re-enable DMA (only) */
if (wmtry) {
return(bcmp(sp, dp, wmtry)); /* wmtry always exits here, no looping */
}
if (bcmp(sp, dp, lcv))
return(retval); /* failed, use last value */
retval = lcv;
}
return(retval); /* studly 64 byte DMA present! oh baby!! */
}
/***********************************************************************/
/*
* en_ioctl: handle ioctl requests
*/
STATIC int en_ioctl(ifp, cmd, data)
struct ifnet *ifp;
u_long cmd;
caddr_t data;
{
struct en_softc *sc = (struct en_softc *) ifp->if_softc;
struct ifaddr *ifa = (struct ifaddr *) data;
struct ifreq *ifr = (struct ifreq *) data;
struct atm_pseudoioctl *api = (struct atm_pseudoioctl *)data;
#ifdef NATM
struct atm_rawioctl *ario = (struct atm_rawioctl *)data;
#endif
int s, error = 0, slot;
s = splnet();
switch (cmd) {
case SIOCATMENA: /* enable circuit for recv */
error = en_rxctl(sc, api, 1);
break;
case SIOCATMDIS: /* disable circuit for recv */
error = en_rxctl(sc, api, 0);
break;
#ifdef NATM
case SIOCXRAWATM:
if ((slot = sc->rxvc2slot[ario->npcb->npcb_vci]) == RX_NONE) {
error = EINVAL;
break;
}
if (ario->rawvalue > EN_RXSZ*1024)
ario->rawvalue = EN_RXSZ*1024;
if (ario->rawvalue) {
sc->rxslot[slot].oth_flags |= ENOTHER_RAW;
sc->rxslot[slot].raw_threshold = ario->rawvalue;
} else {
sc->rxslot[slot].oth_flags &= (~ENOTHER_RAW);
sc->rxslot[slot].raw_threshold = 0;
}
#ifdef EN_DEBUG
printf("%s: rxvci%d: turn %s raw (boodi) mode\n",
sc->sc_dev.dv_xname, ario->npcb->npcb_vci,
(ario->rawvalue) ? "on" : "off");
#endif
break;
#endif
case SIOCSIFADDR:
ifp->if_flags |= IFF_UP;
#ifdef INET
if (ifa->ifa_addr->sa_family == AF_INET) {
en_reset(sc);
en_init(sc);
ifa->ifa_rtrequest = atm_rtrequest; /* ??? */
break;
}
#endif /* INET */
/* what to do if not INET? */
en_reset(sc);
en_init(sc);
break;
case SIOCGIFADDR:
error = EINVAL;
break;
case SIOCSIFFLAGS:
error = EINVAL;
break;
#if defined(SIOCSIFMTU) /* ??? copied from if_de */
#if !defined(ifr_mtu)
#define ifr_mtu ifr_metric
#endif
case SIOCSIFMTU:
/*
* Set the interface MTU.
*/
#ifdef notsure
if (ifr->ifr_mtu > ATMMTU) {
error = EINVAL;
break;
}
#endif
ifp->if_mtu = ifr->ifr_mtu;
/* XXXCDC: do we really need to reset on MTU size change? */
en_reset(sc);
en_init(sc);
break;
#endif /* SIOCSIFMTU */
default:
error = EINVAL;
break;
}
splx(s);
return error;
}
/*
* en_rxctl: turn on and off VCs for recv.
*/
STATIC int en_rxctl(sc, pi, on)
struct en_softc *sc;
struct atm_pseudoioctl *pi;
int on;
{
u_int s, vci, flags, slot;
u_int32_t oldmode, newmode;
vci = ATM_PH_VCI(&pi->aph);
flags = ATM_PH_FLAGS(&pi->aph);
#ifdef EN_DEBUG
printf("%s: %s vpi=%d, vci=%d, flags=%d\n", sc->sc_dev.dv_xname,
(on) ? "enable" : "disable", ATM_PH_VPI(&pi->aph), vci, flags);
#endif
if (ATM_PH_VPI(&pi->aph) || vci >= MID_N_VC)
return(EINVAL);
/*
* turn on VCI!
*/
if (on) {
if (sc->rxvc2slot[vci] != RX_NONE)
return(EINVAL);
for (slot = 0 ; slot < sc->en_nrx ; slot++)
if (sc->rxslot[slot].oth_flags & ENOTHER_FREE)
break;
if (slot == sc->en_nrx)
return(ENOSPC);
sc->rxvc2slot[vci] = slot;
sc->rxslot[slot].rxhand = NULL;
oldmode = sc->rxslot[slot].mode;
newmode = (flags & ATM_PH_AAL5) ? MIDV_AAL5 : MIDV_NOAAL;
sc->rxslot[slot].mode = MIDV_SETMODE(oldmode, newmode);
sc->rxslot[slot].atm_vci = vci;
sc->rxslot[slot].atm_flags = flags;
sc->rxslot[slot].oth_flags = 0;
sc->rxslot[slot].rxhand = pi->rxhand;
if (sc->rxslot[slot].indma.ifq_head || sc->rxslot[slot].q.ifq_head)
panic("en_rxctl: left over mbufs on enable");
en_loadvc(sc, vci); /* does debug printf for us */
return(0);
}
/*
* turn off VCI
*/
if (sc->rxvc2slot[vci] == RX_NONE)
return(EINVAL);
slot = sc->rxvc2slot[vci];
if ((sc->rxslot[slot].oth_flags & (ENOTHER_FREE|ENOTHER_DRAIN)) != 0)
return(EINVAL);
s = splimp(); /* block out enintr() */
oldmode = EN_READ(sc, MID_VC(vci));
newmode = MIDV_SETMODE(oldmode, MIDV_TRASH);
EN_WRITE(sc, MID_VC(vci), (newmode | (oldmode & MIDV_INSERVICE)));
/* halt in tracks, be careful to preserve inserivce bit */
DELAY(27);
sc->rxslot[slot].rxhand = NULL;
sc->rxslot[slot].mode = newmode;
/* if stuff is still going on we are going to have to drain it out */
if (sc->rxslot[slot].indma.ifq_head ||
sc->rxslot[slot].q.ifq_head ||
(EN_READ(sc, MID_VC(vci)) & MIDV_INSERVICE) != 0 ||
(sc->rxslot[slot].oth_flags & ENOTHER_SWSL) != 0) {
sc->rxslot[slot].oth_flags |= ENOTHER_DRAIN;
} else {
sc->rxslot[slot].oth_flags = ENOTHER_FREE;
sc->rxslot[slot].atm_vci = RX_NONE;
sc->rxvc2slot[vci] = RX_NONE;
}
splx(s); /* enable enintr() */
#ifdef EN_DEBUG
printf("%s: rx%d: VCI %d is now %s\n", sc->sc_dev.dv_xname, slot, vci,
(sc->rxslot[slot].oth_flags & ENOTHER_DRAIN) ? "draining" : "free");
#endif
return(0);
}
/***********************************************************************/
/*
* en_reset: reset the board, throw away work in progress.
* must en_init to recover.
*/
STATIC void en_reset(sc)
struct en_softc *sc;
{
struct mbuf *m;
int lcv, slot;
#ifdef EN_DEBUG
printf("%s: reset\n", sc->sc_dev.dv_xname);
#endif
EN_WRITE(sc, MID_RESID, 0x0); /* reset hardware */
/*
* recv: dump any mbufs we are dma'ing into, if DRAINing, then a reset
* will free us!
*/
for (lcv = 0 ; lcv < MID_N_VC ; lcv++) {
if (sc->rxvc2slot[lcv] == RX_NONE)
continue;
slot = sc->rxvc2slot[lcv];
while (1) {
IF_DEQUEUE(&sc->rxslot[slot].indma, m);
if (m == NULL)
break; /* >>> exit 'while(1)' here <<< */
m_freem(m);
}
while (1) {
IF_DEQUEUE(&sc->rxslot[slot].q, m);
if (m == NULL)
break; /* >>> exit 'while(1)' here <<< */
m_freem(m);
}
sc->rxslot[slot].oth_flags &= ~ENOTHER_SWSL;
if (sc->rxslot[slot].oth_flags & ENOTHER_DRAIN) {
sc->rxslot[slot].oth_flags = ENOTHER_FREE;
sc->rxvc2slot[lcv] = RX_NONE;
#ifdef EN_DEBUG
printf("%s: rx%d: VCI %d is now free\n", sc->sc_dev.dv_xname, slot, lcv);
#endif
}
}
/*
* xmit: dump everything
*/
for (lcv = 0 ; lcv < EN_NTX ; lcv++) {
while (1) {
IF_DEQUEUE(&sc->txslot[lcv].indma, m);
if (m == NULL)
break; /* >>> exit 'while(1)' here <<< */
m_freem(m);
}
while (1) {
IF_DEQUEUE(&sc->txslot[lcv].q, m);
if (m == NULL)
break; /* >>> exit 'while(1)' here <<< */
m_freem(m);
}
sc->txslot[lcv].mbsize = 0;
}
return;
}
/*
* en_init: init board and sync the card with the data in the softc.
*/
STATIC void en_init(sc)
struct en_softc *sc;
{
int vc, slot;
u_int32_t reg, loc;
if ((sc->enif.if_flags & IFF_UP) == 0) {
#ifdef EN_DEBUG
printf("%s: going down\n", sc->sc_dev.dv_xname);
#endif
en_reset(sc); /* to be safe */
sc->enif.if_flags &= ~IFF_RUNNING; /* disable */
return;
}
#ifdef EN_DEBUG
printf("%s: going up\n", sc->sc_dev.dv_xname);
#endif
sc->enif.if_flags |= IFF_RUNNING; /* enable */
EN_WRITE(sc, MID_RESID, 0x0); /* reset */
/*
* init obmem data structures: vc tab, dma q's, slist.
*/
for (vc = 0 ; vc < MID_N_VC ; vc++)
en_loadvc(sc, vc);
bzero(&sc->drq, sizeof(sc->drq));
sc->drq_free = MID_DRQ_N;
sc->drq_chip = MID_DRQ_REG2A(EN_READ(sc, MID_DMA_RDRX));
EN_WRITE(sc, MID_DMA_WRRX, MID_DRQ_A2REG(sc->drq_chip));
/* ensure zero queue */
sc->drq_us = sc->drq_chip;
bzero(&sc->dtq, sizeof(sc->dtq));
sc->dtq_free = MID_DTQ_N;
sc->dtq_chip = MID_DTQ_REG2A(EN_READ(sc, MID_DMA_RDTX));
EN_WRITE(sc, MID_DMA_WRTX, MID_DRQ_A2REG(sc->dtq_chip));
/* ensure zero queue */
sc->dtq_us = sc->dtq_chip;
sc->hwslistp = MID_SL_REG2A(EN_READ(sc, MID_SERV_WRITE));
sc->swsl_size = sc->swsl_head = sc->swsl_tail = 0;
#ifdef EN_DEBUG
printf("%s: drq free/chip: %d/0x%x, dtq free/chip: %d/0x%x, hwslist: 0x%x\n",
sc->sc_dev.dv_xname, sc->drq_free, sc->drq_chip,
sc->dtq_free, sc->dtq_chip, sc->hwslistp);
#endif
for (slot = 0 ; slot < EN_NTX ; slot++) {
sc->txslot[slot].bfree = EN_TXSZ * 1024;
EN_WRITE(sc, MIDX_READPTR(slot), 0);
EN_WRITE(sc, MIDX_DESCSTART(slot), 0);
loc = sc->txslot[slot].cur = sc->txslot[slot].start;
loc = (loc & ~((EN_TXSZ*1024) - 1)) >> 2; /* mask, cvt to words */
loc = loc >> MIDV_LOCTOPSHFT; /* top 11 bits */
EN_WRITE(sc, MIDX_PLACE(slot), MIDX_MKPLACE(en_k2sz(EN_TXSZ), loc));
#ifdef EN_DEBUG
printf("%s: tx%d: place 0x%x\n", sc->sc_dev.dv_xname, slot,
EN_READ(sc, MIDX_PLACE(slot)));
#endif
}
/*
* enable!
*/
EN_WRITE(sc, MID_INTENA, MID_INT_TX|MID_INT_DMA_OVR|MID_INT_IDENT|
MID_INT_LERR|MID_INT_DMA_ERR|MID_INT_DMA_RX|MID_INT_DMA_TX|
MID_INT_SERVICE| /* >>> MID_INT_SUNI| XXXCDC<<< */ MID_INT_STATS);
EN_WRITE(sc, MID_MAST_CSR, MID_SETIPL(sc->ipl)|MID_MCSR_ENDMA|
MID_MCSR_ENTX|MID_MCSR_ENRX);
}
/*
* en_loadvc: load a vc tab entry from a slot
*/
STATIC void en_loadvc(sc, vc)
struct en_softc *sc;
int vc;
{
int slot;
u_int32_t reg = EN_READ(sc, MID_VC(vc));
reg = MIDV_SETMODE(reg, MIDV_TRASH);
EN_WRITE(sc, MID_VC(vc), reg);
DELAY(27);
if ((slot = sc->rxvc2slot[vc]) == RX_NONE)
return;
/* no need to set CRC */
EN_WRITE(sc, MID_DST_RP(vc), 0); /* read pointer = 0, desc. start = 0 */
EN_WRITE(sc, MID_WP_ST_CNT(vc), 0); /* write pointer = 0 */
EN_WRITE(sc, MID_VC(vc), sc->rxslot[slot].mode); /* set mode, size, loc */
sc->rxslot[slot].cur = sc->rxslot[slot].start;
#ifdef EN_DEBUG
printf("%s: rx%d: assigned to VCI %d\n", sc->sc_dev.dv_xname, slot, vc);
#endif
}
/*
* en_start: start transmitting the next packet that needs to go out
* if there is one. note that atm_output() has already splimp()'d us.
*/
STATIC void en_start(ifp)
struct ifnet *ifp;
{
struct en_softc *sc = (struct en_softc *) ifp->if_softc;
struct ifqueue *ifq = &ifp->if_snd; /* if INPUT QUEUE */
struct mbuf *m, *lastm;
struct atm_pseudohdr *ap, *new_ap;
int txchan, c, mlen, got, need, toadd, cellcnt;
u_int32_t atm_vpi, atm_vci, atm_flags, *dat, aal;
u_int8_t *cp;
if ((ifp->if_flags & IFF_RUNNING) == 0)
return;
/*
* remove everything from interface queue since we handle all queueing
* locally ...
*/
while (1) {
IF_DEQUEUE(ifq, m);
if (m == NULL)
return; /* EMPTY: >>> exit here <<< */
/*
* calculate size of packet (in bytes)
* we also eliminate all stupid (non-word) alignments here using
* en_mfix(). a well behaved protocol will never need en_mfix()!
* after this loop mlen total length of mbuf chain (including atm_ph),
* and lastm is a pointer to the last mbuf on the chain.
*/
lastm = m;
mlen = 0;
while (1) {
if ( (mtod(lastm, u_int) % sizeof(u_int32_t)) != 0 ||
((lastm->m_len % sizeof(u_int32_t)) != 0 && lastm->m_next))
en_mfix(sc, lastm);
mlen += lastm->m_len;
if (lastm->m_next == NULL)
break;
lastm = lastm->m_next;
}
ap = mtod(m, struct atm_pseudohdr *);
atm_vpi = ATM_PH_VPI(ap);
atm_vci = ATM_PH_VCI(ap);
atm_flags = ATM_PH_FLAGS(ap) & ~(EN_OBHDR|EN_OBTRL);
aal = ((atm_flags & ATM_PH_AAL5) != 0)
? MID_TBD_AAL5 : MID_TBD_NOAAL5;
/*
* check that vpi/vci is one we can use
*/
if (atm_vpi || atm_vci > MID_N_VC) {
printf("%s: output vpi=%d, vci=%d out of card range, dropping...\n",
ifp->if_xname, atm_vpi, atm_vci);
m_freem(m);
continue;
}
/*
* computing how much padding we need on the end of the mbuf, then
* see if we can put the TBD at the front of the mbuf where the
* link header goes (well behaved protocols will reserve room for us).
* last, check if room for PDU tail.
*
* got = number of bytes of data we have
* cellcnt = number of cells in this mbuf
* need = number of bytes of data + padding we need (excludes TBD)
* toadd = number of bytes of data we need to add to end of mbuf,
* [including AAL5 PDU, if AAL5]
*/
got = mlen - sizeof(struct atm_pseudohdr *);
toadd = (aal == MID_TBD_AAL5) ? MID_PDU_SIZE : 0; /* PDU */
cellcnt = (got + toadd + (MID_ATMDATASZ - 1)) / MID_ATMDATASZ;
need = cellcnt * MID_ATMDATASZ;
toadd = need - got; /* recompute, including zero padding */
#ifdef EN_DEBUG
printf("%s: txvci%d: mlen=%d, got=%d, need=%d, toadd=%d, cell#=%d\n",
sc->sc_dev.dv_xname, atm_vci, mlen, got, need, toadd, cellcnt);
printf(" leading_space=%d, trailing_space=%d\n",
M_LEADINGSPACE(m), M_TRAILINGSPACE(lastm));
#endif
#ifdef EN_MBUF_OPT
if (M_LEADINGSPACE(m) >= MID_TBD_SIZE) {
m->m_data -= MID_TBD_SIZE;
m->m_len += MID_TBD_SIZE;
mlen += MID_TBD_SIZE;
new_ap = mtod(m, struct atm_pseudohdr *);
*new_ap = *ap; /* move it back */
ap = new_ap;
dat = ((u_int32_t *) ap) + 1;
/* make sure the TBD is in proper byte order */
*dat++ = htonl(MID_TBD_MK1(aal, sc->txspeed[atm_vci], cellcnt));
*dat = htonl(MID_TBD_MK2(atm_vci, 0, 0));
atm_flags |= EN_OBHDR;
}
if (toadd && M_TRAILINGSPACE(lastm) >= toadd) {
cp = mtod(lastm, u_int8_t *) + lastm->m_len;
lastm->m_len += toadd;
mlen += toadd;
if (aal == MID_TBD_AAL5) {
bzero(cp, toadd - MID_PDU_SIZE);
dat = (u_int32_t *)(cp + toadd - MID_PDU_SIZE);
/* make sure the PDU is in proper byte order */
*dat = htonl(MID_PDU_MK1(0, 0, got));
} else {
bzero(cp, toadd);
}
atm_flags |= EN_OBTRL;
}
#endif /* EN_MBUF_OPT */
ATM_PH_FLAGS(ap) = atm_flags; /* update EN_OBHDR/EN_OBTRL bits */
/*
* choose channel with smallest # of bytes waiting for DMA
*/
if (sc->txspeed[atm_vci]) {
txchan = 1;
for (c = 1 ; c < EN_NTX; c++) {
if (sc->txslot[c].mbsize < sc->txslot[txchan].mbsize)
txchan = c;
if (sc->txslot[txchan].mbsize == 0) break; /* zero length!!! */
}
} else {
txchan = 0;
}
if (sc->txslot[txchan].mbsize > EN_TXHIWAT) {
EN_COUNT(sc->txmbovr);
m_freem(m);
#ifdef EN_DEBUG
printf("%s: tx%d: buffer space shortage\n", ifp->if_xname,
txchan);
#endif
continue;
}
sc->txslot[txchan].mbsize += mlen;
#ifdef EN_DEBUG
printf("%s: tx%d: VPI=%d, VCI=%d, FLAGS=0x%x, speed=0x%x\n",
sc->sc_dev.dv_xname, txchan, atm_vpi, atm_vci, atm_flags,
sc->txspeed[atm_vci]);
printf(" adjusted mlen=%d, mbsize=%d\n", mlen,
sc->txslot[txchan].mbsize);
#endif
IF_ENQUEUE(&sc->txslot[txchan].q, m);
en_txdma(sc, txchan);
}
/*NOTREACHED*/
}
/*
* en_mfix: fix a stupid mbuf
*/
STATIC void en_mfix(sc, m)
struct en_softc *sc;
struct mbuf *m;
{
u_char *d = mtod(m, u_char *), *cp;
int off = ((u_int) d) % sizeof(u_int32_t);
struct mbuf *nxt;
EN_COUNT(sc->mfix); /* count # of calls */
#ifdef EN_DEBUG
printf("%s: mfix mbuf m_data=0x%x, m_len=%d\n", sc->sc_dev.dv_xname,
m->m_data, m->m_len);
#endif
if (off) {
bcopy(d, d - off, m->m_len); /* ALIGN! (with costly data copy...) */
d -= off;
m->m_data = (caddr_t)d;
}
off = m->m_len % sizeof(u_int32_t);
if (off == 0)
return;
d = d + m->m_len;
off = sizeof(u_int32_t) - off;
nxt = m->m_next;
while (off--) {
for ( ; nxt != NULL && nxt->m_len == 0 ; nxt = nxt->m_next)
/*null*/;
if (nxt == NULL) { /* out of data, zero fill */
*d++ = 0;
continue; /* next "off" */
}
cp = mtod(nxt, u_char *);
*d++ = *cp++;
m->m_len++;
nxt->m_len--;
nxt->m_data = (caddr_t)cp;
}
return;
}
/*
* en_txdma: start trasmit DMA, if possible
*/
STATIC void en_txdma(sc, chan)
struct en_softc *sc;
int chan;
{
struct mbuf *tmp;
struct atm_pseudohdr *ap;
struct en_launch launch;
int datalen, dtqneed, len, ncells, needalign;
u_int8_t *cp;
#ifdef EN_DEBUG
printf("%s: tx%d: starting...\n", sc->sc_dev.dv_xname, chan);
#endif
again:
launch.nodma = 0;
/*
* get an mbuf waiting for DMA
*/
launch.t = sc->txslot[chan].q.ifq_head; /* peek at head of queue */
if (launch.t == NULL) {
#ifdef EN_DEBUG
printf("%s: tx%d: ...done!\n", sc->sc_dev.dv_xname, chan);
#endif
return; /* >>> exit here if no data waiting for DMA <<< */
}
/*
* get flags, vci
*
* note: launch.need = # bytes we need to get on the card
* dtqneed = # of DTQs we need for this packet
* launch.mlen = # of bytes in in mbuf chain (<= launch.need)
*/
ap = mtod(launch.t, struct atm_pseudohdr *);
launch.atm_vci = ATM_PH_VCI(ap);
launch.atm_flags = ATM_PH_FLAGS(ap);
launch.aal = ((launch.atm_flags & ATM_PH_AAL5) != 0) ?
MID_TBD_AAL5 : MID_TBD_NOAAL5;
/*
* XXX: have to recompute the length again, even though we already did
* it in en_start(). might as well compute dtqneed here as well, so
* this isn't that bad.
*/
if ((launch.atm_flags & EN_OBHDR) == 0) {
dtqneed = 1; /* header still needs to be added */
launch.need = MID_TBD_SIZE; /* not includeded with mbuf */
} else {
dtqneed = 0; /* header on-board, dma with mbuf */
launch.need = 0;
}
launch.mlen = 0;
for (tmp = launch.t ; tmp != NULL ; tmp = tmp->m_next) {
len = tmp->m_len;
launch.mlen += len;
cp = mtod(tmp, u_int8_t *);
if (tmp == launch.t) {
len -= sizeof(struct atm_pseudohdr); /* don't count this! */
cp += sizeof(struct atm_pseudohdr);
}
launch.need += len;
if (len == 0)
continue; /* atm_pseudohdr alone in first mbuf */
dtqneed += en_dqneed(sc, (caddr_t) cp, len);
}
if ((launch.atm_flags & EN_OBTRL) == 0) {
if (launch.aal == MID_TBD_AAL5) {
datalen = launch.need - MID_TBD_SIZE;
launch.need += MID_PDU_SIZE; /* AAL5: need PDU tail */
}
dtqneed++; /* need to work on the end a bit */
}
/*
* finish calculation of launch.need (need to figure out how much padding
* we will need). launch.need includes MID_TBD_SIZE, but we need to
* remove that to so we can round off properly. we have to add
* MID_TBD_SIZE back in after calculating ncells.
*/
launch.need = roundup(launch.need - MID_TBD_SIZE, MID_ATMDATASZ);
ncells = launch.need / MID_ATMDATASZ;
launch.need += MID_TBD_SIZE;
if (launch.need > EN_TXSZ * 1024) {
printf("%s: tx%d: packet larger than xmit buffer (%d > %d)\n",
sc->sc_dev.dv_xname, chan, launch.need, EN_TXSZ * 1024);
goto dequeue_drop;
}
if (launch.need > sc->txslot[chan].bfree) {
EN_COUNT(sc->txoutspace);
#ifdef EN_DEBUG
printf("%s: tx%d: out of trasmit space\n", sc->sc_dev.dv_xname, chan);
#endif
return; /* >>> exit here if out of obmem buffer space <<< */
}
/*
* ensure we have enough dtqs to go, if not, wait for more
* note that we only need 1 dtq if we are copying everything.
*
* XXX: we may want to modify the above to set launch.nodma if launch.mlen is
* less than a certain size (and avoid the DMA setup costs for small data)
*/
#if 0
if (launch.mlen < SomeValueToBeDetermined)
launch.nodma = 1;
#endif
if (EN_NOTXDMA || !en_dma || launch.nodma) {
dtqneed = 1;
launch.nodma = 1;
}
if (dtqneed > sc->dtq_free) {
sc->need_dtqs = 1;
EN_COUNT(sc->txdtqout);
#ifdef EN_DEBUG
printf("%s: tx%d: out of trasmit DTQs\n", sc->sc_dev.dv_xname, chan);
#endif
return; /* >>> exit here if out of dtqs <<< */
}
/*
* it is a go, commit! dequeue mbuf start working on the xfer.
*/
IF_DEQUEUE(&sc->txslot[chan].q, tmp);
#ifdef EN_DIAG
if (launch.t != tmp)
panic("en dequeue");
#endif /* EN_DIAG */
/*
* launch!
*/
EN_COUNT(sc->launch);
if ((launch.atm_flags & EN_OBHDR) == 0) {
EN_COUNT(sc->lheader);
/* store tbd1/tbd2 in network byte order */
launch.tbd1 = htonl(MID_TBD_MK1(launch.aal, sc->txspeed[launch.atm_vci],
ncells));
launch.tbd2 = htonl(MID_TBD_MK2(launch.atm_vci, 0, 0));
}
if ((launch.atm_flags & EN_OBTRL) == 0 && launch.aal == MID_TBD_AAL5) {
EN_COUNT(sc->ltail);
/* store pdu1 in network byte order */
launch.pdu1 = htonl(MID_PDU_MK1(0, 0, datalen));
}
en_txlaunch(sc, chan, &launch);
/*
* do some housekeeping and get the next packet
*/
sc->txslot[chan].bfree -= launch.need;
IF_ENQUEUE(&sc->txslot[chan].indma, launch.t);
goto again;
/*
* END of txdma loop!
*/
/*
* error handles
*/
dequeue_drop:
IF_DEQUEUE(&sc->txslot[chan].q, tmp);
if (launch.t != tmp)
panic("en dequeue drop");
m_freem(launch.t);
sc->txslot[chan].mbsize -= launch.mlen;
goto again;
}
/*
* en_txlaunch: launch an mbuf into the dma pool! note that we have
* en_mfix()ed any strange mbufs so we can count on u_int32_t alignment.
*/
STATIC void en_txlaunch(sc, chan, l)
struct en_softc *sc;
int chan;
struct en_launch *l;
{
struct mbuf *tmp;
u_int32_t cur = sc->txslot[chan].cur,
start = sc->txslot[chan].start,
stop = sc->txslot[chan].stop,
dma, *data, *datastop, count, bcode;
int pad, addtail, need, last, len, needalign, cnt;
/*
* vars:
* need = # bytes card still needs (decr. to zero)
* len = # of bytes left in current mbuf
* cur = our current pointer
* dma = last place we programmed into the DMA
* data = pointer into data area of mbuf that needs to go next
* cnt = # of bytes to transfer in this DTQ
* bcode/count = DMA burst code, and chip's version of cnt
*
* note that for odd length mbufs we have already padded them out with
* zeros, so "len" and "need" are rounded up to a word boundary. an
* odd length mbuf can only happen on the last mbuf of a chain [because we've
* done en_mfix on the chain]. for aal5, the true length is already in
* l->pdu.
*/
need = roundup(l->need, sizeof(u_int32_t));
dma = cur;
addtail = (l->atm_flags & EN_OBTRL) == 0; /* add a tail? */
#ifdef EN_DIAG
if ((need - MID_TBD_SIZE) % MID_ATMDATASZ)
printf("%s: tx%d: bogus trasmit needs (%d)\n", sc->sc_dev.dv_xname, chan,
need);
#endif
#ifdef EN_DEBUG
printf("%s: tx%d: launch mbuf 0x%x! cur=0x%x[%d], need=%d, addtail=%d\n",
sc->sc_dev.dv_xname, chan, l->t, cur, (cur-start)/4, need, addtail);
count = EN_READ(sc, MIDX_PLACE(chan));
printf(" HW: base_address=0x%x, size=%d, read=%d, descstart=%d\n",
MIDX_BASE(count), MIDX_SZ(count), EN_READ(sc, MIDX_READPTR(chan)),
EN_READ(sc, MIDX_DESCSTART(chan)));
#endif
/*
* do we need to insert the TBD by hand?
*/
if ((l->atm_flags & EN_OBHDR) == 0) {
/* note: data already in correct byte order. use WRITEDAT to xfer */
#ifdef EN_DEBUG
printf("%s: tx%d: insert header 0x%x 0x%x\n", sc->sc_dev.dv_xname,
chan, ntohl(l->tbd1), ntohl(l->tbd2));
#endif
EN_WRITEDAT(sc, cur, l->tbd1);
EN_WRAPADD(start, stop, cur, 4);
EN_WRITEDAT(sc, cur, l->tbd2);
EN_WRAPADD(start, stop, cur, 4);
need -= 8;
}
/*
* now do the mbufs...
*/
last = 0;
for (tmp = l->t ; tmp != NULL ; tmp = tmp->m_next) {
/* get pointer to data and length */
data = mtod(tmp, u_int32_t *);
len = roundup(tmp->m_len, sizeof(u_int32_t));
last = (tmp->m_next == NULL);
if (tmp == l->t) {
data += sizeof(struct atm_pseudohdr)/sizeof(u_int32_t);
len -= sizeof(struct atm_pseudohdr);
}
/* now, determine if we should copy it */
if (l->nodma || len < EN_MINDMA) {
datastop = data + (len / sizeof(u_int32_t));
/* copy loop: preserve byte order!!! use WRITEDAT */
while (data != datastop) {
EN_WRITEDAT(sc, cur, *data);
data++;
EN_WRAPADD(start, stop, cur, 4);
}
need -= len;
#ifdef EN_DEBUG
printf("%s: tx%d: copied %d bytes (%d left, cur now 0x%x)\n",
sc->sc_dev.dv_xname, chan, len, need, cur);
#endif
continue; /* continue on to next mbuf */
}
/* going to do DMA, first make sure the dtq is in sync. */
if (dma != cur) {
EN_DTQADD(sc, WORD_IDX(start,cur), chan, MIDDMA_JK, 0);
#ifdef EN_DEBUG
printf("%s: tx%d: dtq_sync: advance pointer to %d\n",
sc->sc_dev.dv_xname, chan, cur);
#endif
}
/* do we need to do a DMA op to align? */
if (sc->alburst &&
(needalign = (((u_int) data) & sc->bestburstmask)) != 0) {
cnt = sc->bestburstlen - needalign;
count = cnt / sizeof(u_int32_t);
bcode = en_dmaplan[count].bcode;
count = cnt >> en_dmaplan[count].divshift;
need -= cnt;
EN_WRAPADD(start, stop, cur, cnt);
#ifdef EN_DEBUG
printf("%s: tx%d: al_dma %d bytes (%d left, cur now 0x%x)\n",
sc->sc_dev.dv_xname, chan, cnt, need, cur);
#endif
len -= cnt;
if (len == 0 && last && addtail == 0) {
EN_DTQADDEND(sc, count, chan, bcode, vtophys(data), l->mlen);
goto done; /* finished ! */
}
EN_DTQADD(sc, count, chan, bcode, vtophys(data));
data = (u_int32_t *) ((u_char *)data + cnt);
}
/* do we need to do a max-sized burst? */
if (len >= sc->bestburstlen) {
count = len >> sc->bestburstshift;
cnt = count << sc->bestburstshift;
bcode = sc->bestburstcode;
need -= cnt;
EN_WRAPADD(start, stop, cur, cnt);
#ifdef EN_DEBUG
printf("%s: tx%d: best_dma %d bytes (%d left, cur now 0x%x)\n",
sc->sc_dev.dv_xname, chan, cnt, need, cur);
#endif
len -= cnt;
if (len == 0 && last && addtail == 0) {
EN_DTQADDEND(sc, count, chan, bcode, vtophys(data), l->mlen);
goto done; /* finished ! */
}
EN_DTQADD(sc, count, chan, bcode, vtophys(data));
data = (u_int32_t *) ((u_char *)data + cnt);
}
/* do we need to do a cleanup burst? */
if (len) {
count = len / sizeof(u_int32_t);
bcode = en_dmaplan[count].bcode;
count = len >> en_dmaplan[count].divshift;
need -= len;
EN_WRAPADD(start, stop, cur, len);
#ifdef EN_DEBUG
printf("%s: tx%d: cleanup_dma %d bytes (%d left, cur now 0x%x)\n",
sc->sc_dev.dv_xname, chan, len, need, cur);
#endif
if (last && addtail == 0) {
EN_DTQADDEND(sc, count, chan, bcode, vtophys(data), l->mlen);
goto done; /* finished ! */
}
EN_DTQADD(sc, count, chan, bcode, vtophys(data));
}
dma = cur; /* update dma pointer */
} /* next mbuf, please */
/*
* all mbuf data has been copied out to the obmem (or set up to be DMAd).
* if the trailer or padding needs to be put in, do it now. note that
* we round down the padding size since we may have already padded some.
*/
if (addtail) {
/* copy data */
pad = need / sizeof(u_int32_t); /* round *down* */
if (l->aal == MID_TBD_AAL5)
pad -= 2;
#ifdef EN_DEBUG
printf("%s: tx%d: padding %d bytes\n",
sc->sc_dev.dv_xname, chan, pad * sizeof(u_int32_t));
#endif
while (pad--) {
EN_WRITEDAT(sc, cur, 0); /* no byte order issues with zero */
EN_WRAPADD(start, stop, cur, 4);
}
if (l->aal == MID_TBD_AAL5) {
EN_WRITEDAT(sc, cur, l->pdu1); /* already in network order */
EN_WRAPADD(start, stop, cur, 8);
}
}
if (addtail || dma != cur) {
/* write final descritor */
EN_DTQADDEND(sc, WORD_IDX(start,cur), chan, MIDDMA_JK, 0, l->mlen);
/* dma = cur; */ /* not necessary since we are done */
}
done:
/* update current pointer */
sc->txslot[chan].cur = cur;
#ifdef EN_DEBUG
printf("%s: tx%d: DONE! cur now = 0x%x\n",
sc->sc_dev.dv_xname, chan, cur);
#endif
return;
}
/*
* interrupt handler
*/
int en_intr(arg)
void *arg;
{
struct en_softc *sc = (struct en_softc *) arg;
struct mbuf *m;
struct atm_pseudohdr ah;
u_int32_t reg, kick, val, mask, chip, vci, slot, dtq, drq;
int lcv, idx, need_softserv = 0;
reg = EN_READ(sc, MID_INTACK);
if ((reg & MID_INT_ANY) == 0)
return(0); /* not us */
#ifdef EN_DEBUG
printf("%s: interrupt=0x%b\n", sc->sc_dev.dv_xname, reg, MID_INTBITS);
#endif
/*
* unexpected errors that need a reset
*/
if ((reg & (MID_INT_IDENT|MID_INT_LERR|MID_INT_DMA_ERR|MID_INT_SUNI)) != 0) {
printf("%s: unexpected interrupt=0x%b, resetting card\n",
sc->sc_dev.dv_xname, reg, MID_INTBITS);
#ifdef EN_DEBUG
#ifdef DDB
Debugger();
#endif /* DDB */
sc->enif.if_flags &= ~IFF_RUNNING; /* FREEZE! */
#else
en_reset(sc);
en_init(sc);
#endif
return(1);
}
/*******************
* xmit interrupts *
******************/
kick = 0; /* bitmask of channels to kick */
if (reg & MID_INT_TX) { /* TX done! */
/*
* check for tx complete, if detected then this means that some space
* has come free on the card. we must account for it and arrange to
* kick the channel to life (in case it is stalled waiting on the card).
*/
for (mask = 1, lcv = 0 ; lcv < EN_NTX ; lcv++, mask = mask * 2) {
if (reg & MID_TXCHAN(lcv)) {
kick = kick | mask; /* want to kick later */
val = EN_READ(sc, MIDX_READPTR(lcv)); /* current read pointer */
val = (val * sizeof(u_int32_t)) + sc->txslot[lcv].start;
/* convert to offset */
if (val > sc->txslot[lcv].cur)
sc->txslot[lcv].bfree = val - sc->txslot[lcv].cur;
else
sc->txslot[lcv].bfree = (val + (EN_TXSZ*1024)) - sc->txslot[lcv].cur;
#ifdef EN_DEBUG
printf("%s: tx%d: trasmit done. %d bytes now free in buffer\n",
sc->sc_dev.dv_xname, lcv, sc->txslot[lcv].bfree);
#endif
}
}
}
if (reg & MID_INT_DMA_TX) { /* TX DMA done! */
/*
* check for TX DMA complete, if detected then this means that some DTQs
* are now free. it also means some indma mbufs can be freed.
* if we needed DTQs, kick all channels.
*/
val = EN_READ(sc, MID_DMA_RDTX); /* chip's current location */
idx = MID_DTQ_A2REG(sc->dtq_chip);/* where we last saw chip */
if (sc->need_dtqs) {
kick = MID_NTX_CH - 1; /* assume power of 2, kick all! */
sc->need_dtqs = 0; /* recalculated in "kick" loop below */
#ifdef EN_DEBUG
printf("%s: cleared need DTQ condition\n", sc->sc_dev.dv_xname);
#endif
}
do { /* while idx != val */
sc->dtq_free++;
if ((dtq = sc->dtq[idx]) != 0) {
sc->dtq[idx] = 0; /* don't forget to zero it out when done */
slot = EN_DQ_SLOT(dtq);
IF_DEQUEUE(&sc->txslot[slot].indma, m);
if (!m) panic("enintr: dtqsync");
sc->txslot[slot].mbsize -= EN_DQ_LEN(dtq);
#ifdef EN_DEBUG
printf("%s: tx%d: free %d dma bytes, mbsize now %d\n",
sc->sc_dev.dv_xname, slot, EN_DQ_LEN(dtq),
sc->txslot[slot].mbsize);
#endif
m_freem(m);
}
EN_WRAPADD(0, MID_DTQ_N, idx, 1);
} while (idx != val);
sc->dtq_chip = MID_DTQ_REG2A(val); /* sync softc */
}
/*
* kick xmit channels as needed
*/
if (kick) {
#ifdef EN_DEBUG
printf("%s: tx kick mask = 0x%x\n", sc->sc_dev.dv_xname, kick);
#endif
for (mask = 1, lcv = 0 ; lcv < EN_NTX ; lcv++, mask = mask * 2) {
if ((kick & mask) && sc->txslot[lcv].q.ifq_head) {
en_txdma(sc, lcv); /* kick it! */
}
} /* for each slot */
} /* if kick */
/*******************
* recv interrupts *
******************/
/*
* check for RX DMA complete, and pass the data "upstairs"
*/
if (reg & MID_INT_DMA_RX) {
val = EN_READ(sc, MID_DMA_RDRX); /* chip's current location */
idx = MID_DRQ_A2REG(sc->drq_chip);/* where we last saw chip */
do { /* while (idx != val) */
sc->drq_free++;
if ((drq = sc->drq[idx]) != 0) {
sc->drq[idx] = 0; /* don't forget to zero it out when done */
slot = EN_DQ_SLOT(drq);
IF_DEQUEUE(&sc->rxslot[slot].indma, m);
if (!m) {
printf("%s: lost mbuf in slot %d!\n", sc->sc_dev.dv_xname, slot);
panic("enintr: drqsync");
}
/* do something with this mbuf */
if (sc->rxslot[slot].oth_flags & ENOTHER_DRAIN) { /* drain? */
m_freem(m);
vci = sc->rxslot[slot].atm_vci;
if (sc->rxslot[slot].indma.ifq_head == NULL &&
sc->rxslot[slot].q.ifq_head == NULL &&
(EN_READ(sc, MID_VC(vci)) & MIDV_INSERVICE) == 0 &&
(sc->rxslot[slot].oth_flags & ENOTHER_SWSL) == 0) {
sc->rxslot[slot].oth_flags = ENOTHER_FREE; /* done drain */
sc->rxslot[slot].atm_vci = RX_NONE;
sc->rxvc2slot[vci] = RX_NONE;
#ifdef EN_DEBUG
printf("%s: rx%d: VCI %d now free\n", sc->sc_dev.dv_xname,
slot, vci);
#endif
}
} else {
ATM_PH_FLAGS(&ah) = sc->rxslot[slot].atm_flags;
ATM_PH_VPI(&ah) = 0;
ATM_PH_SETVCI(&ah, sc->rxslot[slot].atm_vci);
#ifdef EN_DEBUG
printf("%s: rx%d: rxvci%d: atm_input, mbuf 0x%x, len %d, hand 0x%x\n",
sc->sc_dev.dv_xname, slot, sc->rxslot[slot].atm_vci, m,
EN_DQ_LEN(drq), sc->rxslot[slot].rxhand);
#endif
atm_input(&sc->enif, &ah, m, sc->rxslot[slot].rxhand);
}
}
EN_WRAPADD(0, MID_DRQ_N, idx, 1);
} while (idx != val);
sc->drq_chip = MID_DRQ_REG2A(val); /* sync softc */
if (sc->need_drqs) { /* true if we had a DRQ shortage */
need_softserv = 1;
sc->need_drqs = 0;
#ifdef EN_DEBUG
printf("%s: cleared need DRQ condition\n", sc->sc_dev.dv_xname);
#endif
}
}
/*
* handle service interrupts
*/
if (reg & MID_INT_SERVICE) {
chip = MID_SL_REG2A(EN_READ(sc, MID_SERV_WRITE));
do { /* while sc->hwslistp != chip */
/* fetch and remove it from hardware service list */
vci = EN_READ(sc, sc->hwslistp);
EN_WRAPADD(MID_SLOFF, MID_SLEND, sc->hwslistp, 4);/* advance hw ptr */
slot = sc->rxvc2slot[vci];
if (slot == RX_NONE) {
printf("%s: unexpected rx interrupt on VCI %d\n",
sc->sc_dev.dv_xname, vci);
EN_WRITE(sc, MID_VC(vci), MIDV_TRASH); /* rx off, damn it! */
continue; /* next */
}
EN_WRITE(sc, MID_VC(vci), sc->rxslot[slot].mode); /* remove from hwsl */
EN_COUNT(sc->hwpull);
#ifdef EN_DEBUG
printf("%s: pulled VCI %d off hwslist\n", sc->sc_dev.dv_xname, vci);
#endif
/* add it to the software service list (if needed) */
if ((sc->rxslot[slot].oth_flags & ENOTHER_SWSL) == 0) {
EN_COUNT(sc->swadd);
need_softserv = 1;
sc->rxslot[slot].oth_flags |= ENOTHER_SWSL;
sc->swslist[sc->swsl_tail] = slot;
EN_WRAPADD(0, MID_SL_N, sc->swsl_tail, 1);
sc->swsl_size++;
#ifdef EN_DEBUG
printf("%s: added VCI %d to swslist\n", sc->sc_dev.dv_xname, vci);
#endif
}
} while (sc->hwslistp != chip);
}
/*
* now service (function too big to include here)
*/
if (need_softserv)
en_service(sc);
/*
* keep our stats
*/
if (reg & MID_INT_DMA_OVR) {
EN_COUNT(sc->dmaovr);
#ifdef EN_DEBUG
printf("%s: MID_INT_DMA_OVR\n", sc->sc_dev.dv_xname);
#endif
}
reg = EN_READ(sc, MID_STAT);
#ifdef EN_STAT
sc->otrash += MID_OTRASH(reg);
sc->vtrash += MID_VTRASH(reg);
#endif
return(1);
}
/*
* en_service: handle a service interrupt
*
* Q: why do we need a software service list?
*
* A: if we remove a VCI from the hardware list and we find that we are
* out of DRQs we must defer processing until some DRQs become free.
* so we must remember to look at this RX VCI/slot later, but we can't
* put it back on the hardware service list (since that isn't allowed).
* so we instead save it on the software service list. it would be nice
* if we could peek at the VCI on top of the hwservice list without removing
* it, however this leads to a race condition: if we peek at it and
* decide we are done with it new data could come in before we have a
* chance to remove it from the hwslist. by the time we get it out of
* the list the interrupt for the new data will be lost. oops!
*
*/
STATIC void en_service(sc)
struct en_softc *sc;
{
struct mbuf *m, *tmp;
u_int32_t cur, dstart, rbd, pdu, *sav, dma, bcode, count, *data, *datastop;
u_int32_t start, stop, cnt, needalign;
int slot, raw, aal5, llc, vci, fill, mlen, tlen, drqneed, need, needfill;
next_vci:
if (sc->swsl_size == 0) {
#ifdef EN_DEBUG
printf("%s: en_service done\n", sc->sc_dev.dv_xname);
#endif
return; /* >>> exit here if swsl now empty <<< */
}
/*
* get slot/vci to service
*/
slot = sc->swslist[sc->swsl_head];
vci = sc->rxslot[slot].atm_vci;
#ifdef EN_DIAG
if (sc->rxvc2slot[vci] != slot) panic("en_service rx slot/vci sync");
#endif
/*
* determine our mode and if we've got any work to do
*/
raw = sc->rxslot[slot].oth_flags & ENOTHER_RAW;
start= sc->rxslot[slot].start;
stop= sc->rxslot[slot].stop;
cur = sc->rxslot[slot].cur;
#ifdef EN_DEBUG
printf("%s: rx%d: service vci=%d raw=%d start/stop/cur=0x%x 0x%x 0x%x\n",
sc->sc_dev.dv_xname, slot, vci, raw, start, stop, cur);
#endif
same_vci:
dstart = MIDV_DSTART(EN_READ(sc, MID_DST_RP(vci)));
dstart = (dstart * sizeof(u_int32_t)) + start;
/* check to see if there is any data at all */
if (dstart == cur) {
defer: /* defer processing */
EN_WRAPADD(0, MID_SL_N, sc->swsl_head, 1);
sc->rxslot[slot].oth_flags &= ~ENOTHER_SWSL;
sc->swsl_size--;
/* >>> remove from swslist <<< */
#ifdef EN_DEBUG
printf("%s: rx%d: remove vci %d from swslist\n",
sc->sc_dev.dv_xname, slot, vci);
#endif
goto next_vci;
}
/*
* figure out how many bytes we need
* [mlen = # bytes to go in mbufs, fill = # bytes to dump (MIDDMA_JK)]
*/
if (raw) {
/* raw mode (aka boodi mode) */
fill = 0;
if (dstart > cur)
mlen = dstart - cur;
else
mlen = (dstart + (EN_RXSZ*1024)) - cur;
if (mlen < sc->rxslot[slot].raw_threshold)
goto defer; /* too little data to deal with */
} else {
/* normal mode */
aal5 = (sc->rxslot[slot].atm_flags & ATM_PH_AAL5);
llc = (aal5 && (sc->rxslot[slot].atm_flags & ATM_PH_LLCSNAP)) ? 1 : 0;
rbd = EN_READ(sc, cur);
if (MID_RBD_ID(rbd) != MID_RBD_STDID)
panic("en_service: id mismatch\n");
if (rbd & MID_RBD_T) {
mlen = 0; /* we've got trash */
fill = MID_RBD_SIZE;
EN_COUNT(sc->ttrash);
} else if (!aal5) {
mlen = MID_RBD_SIZE + MID_CHDR_SIZE + MID_ATMDATASZ; /* 1 cell (ick!) */
fill = 0;
} else {
tlen = (MID_RBD_CNT(rbd) * MID_ATMDATASZ) + MID_RBD_SIZE;
pdu = cur + tlen - MID_PDU_SIZE;
if (pdu >= stop)
pdu -= (EN_RXSZ*1024);
pdu = EN_READ(sc, pdu); /* READ swaps to proper byte order */
fill = tlen - MID_RBD_SIZE - MID_PDU_LEN(pdu);
mlen = tlen - fill;
}
}
/*
* now allocate mbufs for mlen bytes of data, if out of mbufs, trash all
*
* notes:
* 1. it is possible that we've already allocated an mbuf for this pkt
* but ran out of DRQs, in which case we saved the allocated mbuf on
* "q".
* 2. if we save an mbuf in "q" we store the "cur" (pointer) in the front
* of the mbuf as an identity (that we can check later), and we also
* store drqneed (so we don't have to recompute it).
* 3. after this block of code, if m is still NULL then we ran out of mbufs
*/
m = sc->rxslot[slot].q.ifq_head;
if (m) {
sav = mtod(m, u_int32_t *);
if (sav[0] != cur) {
#ifdef EN_DEBUG
printf("%s: rx%d: q'ed mbuf 0x%x not ours\n",
sc->sc_dev.dv_xname, slot, m);
#endif
m = NULL; /* wasn't ours */
EN_COUNT(sc->rxqnotus);
} else {
EN_COUNT(sc->rxqus);
IF_DEQUEUE(&sc->rxslot[slot].q, m);
drqneed = sav[1];
#ifdef EN_DEBUG
printf("%s: rx%d: recovered q'ed mbuf 0x%x (drqneed=%d)\n",
sc->sc_dev.dv_xname, slot, drqneed);
#endif
}
}
if (m == NULL) {
m = en_mget(sc, mlen, &drqneed); /* allocate! */
if (m == NULL) {
fill += mlen;
mlen = 0;
EN_COUNT(sc->rxmbufout);
#ifdef EN_DEBUG
printf("%s: rx%d: out of mbufs\n", sc->sc_dev.dv_xname, slot);
#endif
}
#ifdef EN_DEBUG
printf("%s: rx%d: allocate mbuf 0x%x, mlen=%d, drqneed=%d\n",
sc->sc_dev.dv_xname, slot, m, mlen, drqneed);
#endif
}
#ifdef EN_DEBUG
printf("%s: rx%d: VCI %d, mbuf_chain 0x%x, mlen %d, fill %d\n",
sc->sc_dev.dv_xname, slot, vci, m, mlen, fill);
#endif
/*
* now check to see if we've got the DRQs needed. if we are out of
* DRQs we must quit (saving our mbuf, if we've got one).
*/
needfill = (fill) ? 1 : 0;
if (drqneed + needfill > sc->drq_free) {
sc->need_drqs = 1; /* flag condition */
if (m == NULL) {
EN_COUNT(sc->rxoutboth);
#ifdef EN_DEBUG
printf("%s: rx%d: out of DRQs *and* mbufs!\n", sc->sc_dev.dv_xname, slot);
#endif
return; /* >>> exit here if out of both mbufs and DRQs <<< */
}
sav = mtod(m, u_int32_t *);
sav[0] = cur;
sav[1] = drqneed;
IF_ENQUEUE(&sc->rxslot[slot].q, m);
EN_COUNT(sc->rxdrqout);
#ifdef EN_DEBUG
printf("%s: rx%d: out of DRQs\n", sc->sc_dev.dv_xname, slot);
#endif
return; /* >>> exit here if out of DRQs <<< */
}
/*
* at this point all resources have been allocated and we are commited
* to servicing this slot.
*
* dma = last location we told chip about
* cur = current location
* mlen = space in the mbuf we want
* need = bytes to xfer in (decrs to zero)
* fill = how much fill we need
* tlen = how much data to transfer to this mbuf
* cnt/bcode/count = <same as xmit>
*
* 'needfill' not used after this point
*/
dma = cur; /* dma = last location we told chip about */
need = roundup(mlen, sizeof(u_int32_t));
fill = fill - (need - mlen); /* note: may invalidate 'needfill' */
for (tmp = m ; tmp != NULL && need > 0 ; tmp = tmp->m_next) {
tlen = roundup(tmp->m_len, sizeof(u_int32_t)); /* m_len set by en_mget */
data = mtod(tmp, u_int32_t *);
#ifdef EN_DEBUG
printf("%s: rx%d: load mbuf 0x%x, m_len=%d, m_data=0x%x, tlen=%d\n",
sc->sc_dev.dv_xname, slot, tmp, tmp->m_len, tmp->m_data, tlen);
#endif
/* copy data */
if (EN_NORXDMA || !en_dma || tlen < EN_MINDMA) {
datastop = (u_int32_t *)((u_char *) data + tlen);
/* copy loop: preserve byte order!!! use READDAT */
while (data != datastop) {
*data = EN_READDAT(sc, cur);
data++;
EN_WRAPADD(start, stop, cur, 4);
}
need -= tlen;
#ifdef EN_DEBUG
printf("%s: rx%d: vci%d: copied %d bytes (%d left)\n",
sc->sc_dev.dv_xname, slot, vci, tlen, need);
#endif
continue;
}
/* DMA data (check to see if we need to sync DRQ first) */
if (dma != cur) {
EN_DRQADD(sc, WORD_IDX(start,cur), vci, MIDDMA_JK, 0);
#ifdef EN_DEBUG
printf("%s: rx%d: vci%d: drq_sync: advance pointer to %d\n",
sc->sc_dev.dv_xname, slot, vci, cur);
#endif
}
/* do we need to do a DMA op to align? */
if (sc->alburst &&
(needalign = (((u_int) data) & sc->bestburstmask)) != 0) {
cnt = sc->bestburstlen - needalign;
count = cnt / sizeof(u_int32_t);
bcode = en_dmaplan[count].bcode;
count = cnt >> en_dmaplan[count].divshift;
need -= cnt;
EN_WRAPADD(start, stop, cur, cnt);
#ifdef EN_DEBUG
printf("%s: rx%d: vci%d: al_dma %d bytes (%d left)\n",
sc->sc_dev.dv_xname, slot, vci, cnt, need);
#endif
tlen -= cnt;
if (need == 0 && !fill) {
EN_DRQADDEND(sc, count, vci, bcode, vtophys(data), mlen, slot);
goto done; /* finished! */
}
EN_DRQADD(sc, count, vci, bcode, vtophys(data));
data = (u_int32_t *)((u_char *) data + cnt);
}
/* do we need a max-sized burst? */
if (tlen >= sc->bestburstlen) {
count = tlen >> sc->bestburstshift;
cnt = count << sc->bestburstshift;
bcode = sc->bestburstcode;
need -= cnt;
EN_WRAPADD(start, stop, cur, cnt);
#ifdef EN_DEBUG
printf("%s: rx%d: vci%d: best_dma %d bytes (%d left)\n",
sc->sc_dev.dv_xname, slot, vci, cnt, need);
#endif
tlen -= cnt;
if (need == 0 && !fill) {
EN_DRQADDEND(sc, count, vci, bcode, vtophys(data), mlen, slot);
goto done; /* finished! */
}
EN_DRQADD(sc, count, vci, bcode, vtophys(data));
data = (u_int32_t *)((u_char *) data + cnt);
}
/* do we need to do a cleanup burst? */
if (tlen) {
count = tlen / sizeof(u_int32_t);
bcode = en_dmaplan[count].bcode;
count = tlen >> en_dmaplan[count].divshift;
need -= tlen;
EN_WRAPADD(start, stop, cur, tlen);
#ifdef EN_DEBUG
printf("%s: rx%d: vci%d: cleanup_dma %d bytes (%d left)\n",
sc->sc_dev.dv_xname, slot, vci, tlen, need);
#endif
if (need == 0 && !fill) {
EN_DRQADDEND(sc, count, vci, bcode, vtophys(data), mlen, slot);
goto done; /* finished! */
}
EN_DRQADD(sc, count, vci, bcode, vtophys(data));
}
dma = cur; /* update dma pointer */
}
/* skip the end */
if (fill || dma != cur) {
#ifdef EN_DEBUG
if (fill)
printf("%s: rx%d: vci%d: skipping %d bytes of fill\n",
sc->sc_dev.dv_xname, slot, vci, fill);
else
printf("%s: rx%d: vci%d: syncing chip from 0x%x to 0x%x [cur]\n",
sc->sc_dev.dv_xname, slot, vci, dma, cur);
#endif
EN_WRAPADD(start, stop, cur, fill);
EN_DRQADDEND(sc, WORD_IDX(start,cur), vci, MIDDMA_JK, 0, mlen, slot);
/* dma = cur; */ /* not necessary since we are done */
}
/*
* done, remove stuff we don't want to pass up:
* raw mode (boodi mode): pass everything up for later processing
* aal5: remove RBD
* aal0: remove RBD + cell header
*/
done:
if (m) {
if (!raw) {
cnt = MID_RBD_SIZE;
if (!aal5) cnt += MID_CHDR_SIZE;
m->m_len -= cnt; /* chop! */
m->m_pkthdr.len -= cnt;
m->m_data += cnt;
}
IF_ENQUEUE(&sc->rxslot[slot].indma, m);
}
sc->rxslot[slot].cur = cur; /* update master copy of 'cur' */
#ifdef EN_DEBUG
printf("%s: rx%d: vci%d: DONE! cur now =0x%x\n",
sc->sc_dev.dv_xname, slot, vci, cur);
#endif
goto same_vci; /* get next packet in this slot */
}
#ifdef EN_DDBHOOK
/*
* functions we can call from ddb
*/
/*
* en_dump: dump the state
*/
#define END_SWSL 0x00000040 /* swsl state */
#define END_DRQ 0x00000020 /* drq state */
#define END_DTQ 0x00000010 /* dtq state */
#define END_RX 0x00000008 /* rx state */
#define END_TX 0x00000004 /* tx state */
#define END_MREGS 0x00000002 /* registers */
#define END_STATS 0x00000001 /* dump stats */
#define END_BITS "\20\7SWSL\6DRQ\5DTQ\4RX\3TX\2MREGS\1STATS"
int en_dump(unit, level)
int unit, level;
{
struct en_softc *sc;
int lcv, cnt, slot;
u_int32_t ptr, reg;
for (lcv = 0 ; lcv < en_cd.cd_ndevs ; lcv++) {
sc = (struct en_softc *) en_cd.cd_devs[lcv];
if (sc == NULL) continue;
if (unit != -1 && unit != lcv)
continue;
printf("dumping device %s at level 0x%b\n", sc->sc_dev.dv_xname, level,
END_BITS);
if (sc->dtq_us == 0) {
printf("<hasn't been en_init'd yet>\n");
continue;
}
if (level & END_STATS) {
printf(" en_stats:\n");
printf(" %d mbufs fixed by mfix (should be zero)\n", sc->mfix);
printf(" %d rx dma overflow interrupts\n", sc->dmaovr);
printf(" %d times we ran out of TX space and stalled\n",
sc->txoutspace);
printf(" %d times we ran out of DTQs\n", sc->txdtqout);
printf(" %d times we launched a packet\n", sc->launch);
printf(" %d times we launched without on-board header\n", sc->lheader);
printf(" %d times we launched without on-board tail\n", sc->ltail);
printf(" %d times we pulled the hw service list\n", sc->hwpull);
printf(" %d times we pushed a vci on the sw service list\n",
sc->swadd);
printf(" %d times RX pulled an mbuf from Q that wasn't ours\n",
sc->rxqnotus);
printf(" %d times RX pulled a good mbuf from Q\n", sc->rxqus);
printf(" %d times we ran out of mbufs *and* DRQs\n", sc->rxoutboth);
printf(" %d times we ran out of DRQs\n", sc->rxdrqout);
printf(" %d trasmit packets dropped due to mbsize\n", sc->txmbovr);
printf(" %d cells trashed due to turned off rxvc\n", sc->vtrash);
printf(" %d cells trashed due to totally full buffer\n", sc->otrash);
printf(" %d cells trashed due almost full buffer\n", sc->ttrash);
printf(" %d rx mbuf allocation failures\n", sc->rxmbufout);
#ifdef NATM
printf(" %d drops at natmintrq\n", natmintrq.ifq_drops);
#ifdef NATM_STAT
printf(" natmintr so_rcv: ok/drop cnt: %d/%d, ok/drop bytes: %d/%d\n",
natm_sookcnt, natm_sodropcnt, natm_sookbytes, natm_sodropbytes);
#endif
#endif
}
if (level & END_MREGS) {
printf("mregs:\n");
printf("resid = 0x%x\n", EN_READ(sc, MID_RESID));
printf("interrupt status = 0x%b\n",
EN_READ(sc, MID_INTSTAT), MID_INTBITS);
printf("interrupt enable = 0x%b\n",
EN_READ(sc, MID_INTENA), MID_INTBITS);
printf("mcsr = 0x%b\n", EN_READ(sc, MID_MAST_CSR), MID_MCSRBITS);
printf("serv_write = [chip=%d] [us=%d]\n", EN_READ(sc, MID_SERV_WRITE),
MID_SL_A2REG(sc->hwslistp));
printf("dma addr = 0x%x\n", EN_READ(sc, MID_DMA_ADDR));
printf("DRQ: chip[rd=0x%x,wr=0x%x], sc[chip=0x%x,us=0x%x]\n",
MID_DRQ_REG2A(EN_READ(sc, MID_DMA_RDRX)),
MID_DRQ_REG2A(EN_READ(sc, MID_DMA_WRRX)), sc->drq_chip, sc->drq_us);
printf("DTQ: chip[rd=0x%x,wr=0x%x], sc[chip=0x%x,us=0x%x]\n",
MID_DTQ_REG2A(EN_READ(sc, MID_DMA_RDTX)),
MID_DTQ_REG2A(EN_READ(sc, MID_DMA_WRTX)), sc->dtq_chip, sc->dtq_us);
printf(" unusal txspeeds: ");
for (cnt = 0 ; cnt < MID_N_VC ; cnt++)
if (sc->txspeed[cnt])
printf(" vci%d=0x%x", cnt, sc->txspeed[cnt]);
printf("\n");
printf(" rxvc slot mappings: ");
for (cnt = 0 ; cnt < MID_N_VC ; cnt++)
if (sc->rxvc2slot[cnt] != RX_NONE)
printf(" %d->%d", cnt, sc->rxvc2slot[cnt]);
printf("\n");
}
if (level & END_TX) {
printf("tx:\n");
for (slot = 0 ; slot < EN_NTX; slot++) {
printf("tx%d: start/stop/cur=0x%x/0x%x/0x%x [%d] ", slot,
sc->txslot[slot].start, sc->txslot[slot].stop, sc->txslot[slot].cur,
(sc->txslot[slot].cur - sc->txslot[slot].start)/4);
printf("mbsize=%d, bfree=%d\n", sc->txslot[slot].mbsize,
sc->txslot[slot].bfree);
printf("txhw: base_address=0x%x, size=%d, read=%d, descstart=%d\n",
MIDX_BASE(EN_READ(sc, MIDX_PLACE(slot))),
MIDX_SZ(EN_READ(sc, MIDX_PLACE(slot))),
EN_READ(sc, MIDX_READPTR(slot)), EN_READ(sc, MIDX_DESCSTART(slot)));
}
}
if (level & END_RX) {
printf(" recv slots:\n");
for (slot = 0 ; slot < sc->en_nrx; slot++) {
printf("rx%d: vci=%d: start/stop/cur=0x%x/0x%x/0x%x ", slot,
sc->rxslot[slot].atm_vci, sc->rxslot[slot].start,
sc->rxslot[slot].stop, sc->rxslot[slot].cur);
printf("mode=0x%x, atm_flags=0x%x, oth_flags=0x%x\n",
sc->rxslot[slot].mode, sc->rxslot[slot].atm_flags,
sc->rxslot[slot].oth_flags);
printf("RXHW: mode=0x%x, DST_RP=0x%x, WP_ST_CNT=0x%x\n",
EN_READ(sc, MID_VC(sc->rxslot[slot].atm_vci)),
EN_READ(sc, MID_DST_RP(sc->rxslot[slot].atm_vci)),
EN_READ(sc, MID_WP_ST_CNT(sc->rxslot[slot].atm_vci)));
}
}
if (level & END_DTQ) {
printf(" dtq [need_dtqs=%d,dtq_free=%d]:\n",
sc->need_dtqs, sc->dtq_free);
ptr = sc->dtq_chip;
while (ptr != sc->dtq_us) {
reg = EN_READ(sc, ptr);
printf("\t0x%x=[cnt=%d, chan=%d, end=%d, type=%d @ 0x%x]\n",
sc->dtq[MID_DTQ_A2REG(ptr)], MID_DMA_CNT(reg), MID_DMA_TXCHAN(reg),
(reg & MID_DMA_END) != 0, MID_DMA_TYPE(reg), EN_READ(sc, ptr+4));
EN_WRAPADD(MID_DTQOFF, MID_DTQEND, ptr, 8);
}
}
if (level & END_DRQ) {
printf(" drq [need_drqs=%d,drq_free=%d]:\n",
sc->need_drqs, sc->drq_free);
ptr = sc->drq_chip;
while (ptr != sc->drq_us) {
reg = EN_READ(sc, ptr);
printf("\t0x%x=[cnt=%d, chan=%d, end=%d, type=%d @ 0x%x]\n",
sc->drq[MID_DRQ_A2REG(ptr)], MID_DMA_CNT(reg), MID_DMA_RXVCI(reg),
(reg & MID_DMA_END) != 0, MID_DMA_TYPE(reg), EN_READ(sc, ptr+4));
EN_WRAPADD(MID_DRQOFF, MID_DRQEND, ptr, 8);
}
}
if (level & END_SWSL) {
printf(" swslist [size=%d]: ", sc->swsl_size);
for (cnt = sc->swsl_head ; cnt != sc->swsl_tail ;
cnt = (cnt + 1) % MID_SL_N)
printf("0x%x ", sc->swslist[cnt]);
printf("\n");
}
}
return(0);
}
/*
* en_dumpmem: dump the memory
*/
int en_dumpmem(unit, addr, len)
int unit, addr, len;
{
struct en_softc *sc;
u_int32_t reg;
if (unit < 0 || unit > en_cd.cd_ndevs ||
(sc = (struct en_softc *) en_cd.cd_devs[unit]) == NULL) {
printf("invalid unit number: %d\n", unit);
return(0);
}
addr = addr & ~3;
if (addr < MID_RAMOFF || addr + len*4 > MID_MAXOFF || len <= 0) {
printf("invalid addr/len number: %d, %d\n", addr, len);
return(0);
}
printf("dumping %d words starting at offset 0x%x\n", len, addr);
while (len--) {
reg = EN_READ(sc, addr);
printf("mem[0x%x] = 0x%x\n", addr, reg);
addr += 4;
}
return(0);
}
#endif
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