NetBSD/sys/arch/sparc/dev/esp.c
1996-10-11 00:44:42 +00:00

2129 lines
54 KiB
C

/* $NetBSD: esp.c,v 1.58 1996/10/11 00:46:35 christos Exp $ */
#ifdef __sparc__
#define SPARC_DRIVER
#endif
/*
* Copyright (c) 1996 Charles M. Hannum. 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 M. Hannum.
* 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.
*/
/*
* Copyright (c) 1994 Peter Galbavy
* Copyright (c) 1995 Paul Kranenburg
* 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 Peter Galbavy
* 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.
*/
/*
* Based on aic6360 by Jarle Greipsland
*
* Acknowledgements: Many of the algorithms used in this driver are
* inspired by the work of Julian Elischer (julian@tfs.com) and
* Charles Hannum (mycroft@duality.gnu.ai.mit.edu). Thanks a million!
*/
#include <sys/types.h>
#include <sys/param.h>
#include <sys/systm.h>
#include <sys/kernel.h>
#include <sys/errno.h>
#include <sys/ioctl.h>
#include <sys/device.h>
#include <sys/buf.h>
#include <sys/proc.h>
#include <sys/user.h>
#include <sys/queue.h>
#include <scsi/scsi_all.h>
#include <scsi/scsiconf.h>
#include <scsi/scsi_message.h>
#include <machine/cpu.h>
#ifdef SPARC_DRIVER
#include <machine/autoconf.h>
#include <sparc/dev/sbusvar.h>
#include <sparc/dev/dmareg.h>
#include <sparc/dev/dmavar.h>
#include <sparc/dev/espreg.h>
#include <sparc/dev/espvar.h>
#else
#include <dev/tc/tcvar.h>
#include <alpha/tc/tcdsvar.h>
#include <alpha/tc/espreg.h>
#include <alpha/tc/espvar.h>
#endif
int esp_debug = 0; /*ESP_SHOWPHASE|ESP_SHOWMISC|ESP_SHOWTRAC|ESP_SHOWCMDS;*/
/*static*/ void espattach __P((struct device *, struct device *, void *));
/*static*/ int espmatch __P((struct device *, void *, void *));
/*static*/ u_int esp_adapter_info __P((struct esp_softc *));
/*static*/ void espreadregs __P((struct esp_softc *));
/*static*/ void esp_select __P((struct esp_softc *, struct esp_ecb *));
/*static*/ int esp_reselect __P((struct esp_softc *, int));
/*static*/ void esp_scsi_reset __P((struct esp_softc *));
/*static*/ void esp_reset __P((struct esp_softc *));
/*static*/ void esp_init __P((struct esp_softc *, int));
/*static*/ int esp_scsi_cmd __P((struct scsi_xfer *));
/*static*/ int esp_poll __P((struct esp_softc *, struct scsi_xfer *, int));
/*static*/ void esp_sched __P((struct esp_softc *));
/*static*/ void esp_done __P((struct esp_softc *, struct esp_ecb *));
/*static*/ void esp_msgin __P((struct esp_softc *));
/*static*/ void esp_msgout __P((struct esp_softc *));
/*static*/ int espintr __P((struct esp_softc *));
/*static*/ void esp_timeout __P((void *arg));
/*static*/ void esp_abort __P((struct esp_softc *, struct esp_ecb *));
/*static*/ void esp_dequeue __P((struct esp_softc *, struct esp_ecb *));
void esp_sense __P((struct esp_softc *, struct esp_ecb *));
void esp_free_ecb __P((struct esp_softc *, struct esp_ecb *, int));
struct esp_ecb *esp_get_ecb __P((struct esp_softc *, int));
static inline int esp_stp2cpb __P((struct esp_softc *, int));
static inline int esp_cpb2stp __P((struct esp_softc *, int));
static inline void esp_setsync __P((struct esp_softc *, struct esp_tinfo *));
/* Linkup to the rest of the kernel */
struct cfattach esp_ca = {
sizeof(struct esp_softc), espmatch, espattach
};
struct cfdriver esp_cd = {
NULL, "esp", DV_DULL
};
struct scsi_adapter esp_switch = {
esp_scsi_cmd,
minphys, /* no max at this level; handled by DMA code */
NULL,
NULL,
};
struct scsi_device esp_dev = {
NULL, /* Use default error handler */
NULL, /* have a queue, served by this */
NULL, /* have no async handler */
NULL, /* Use default 'done' routine */
};
int
espmatch(parent, vcf, aux)
struct device *parent;
void *vcf, *aux;
{
struct cfdata *cf = vcf;
#ifdef SPARC_DRIVER
register struct confargs *ca = aux;
register struct romaux *ra = &ca->ca_ra;
if (strcmp(cf->cf_driver->cd_name, ra->ra_name))
return (0);
if (ca->ca_bustype == BUS_SBUS)
return (1);
ra->ra_len = NBPG;
return (probeget(ra->ra_vaddr, 1) != -1);
#else
struct tcdsdev_attach_args *tcdsdev = aux;
if (strncmp(tcdsdev->tcdsda_modname, "PMAZ-AA ", TC_ROM_LLEN))
return (0);
return (!tc_badaddr(tcdsdev->tcdsda_addr));
#endif
}
/*
* Attach this instance, and then all the sub-devices
*/
void
espattach(parent, self, aux)
struct device *parent, *self;
void *aux;
{
#ifdef SPARC_DRIVER
register struct confargs *ca = aux;
#else
register struct tcdsdev_attach_args *tcdsdev = aux;
#endif
struct esp_softc *sc = (void *)self;
#ifdef SPARC_DRIVER
struct bootpath *bp;
int dmachild = strncmp(parent->dv_xname, "dma", 3) == 0;
#endif
#ifdef SPARC_DRIVER
/*
* Make sure things are sane. I don't know if this is ever
* necessary, but it seem to be in all of Torek's code.
*/
if (ca->ca_ra.ra_nintr != 1) {
kprintf(": expected 1 interrupt, got %d\n", ca->ca_ra.ra_nintr);
return;
}
sc->sc_pri = ca->ca_ra.ra_intr[0].int_pri;
kprintf(" pri %d", sc->sc_pri);
/*
* Map my registers in, if they aren't already in virtual
* address space.
*/
if (ca->ca_ra.ra_vaddr)
sc->sc_reg = (volatile u_char *) ca->ca_ra.ra_vaddr;
else {
sc->sc_reg = (volatile u_char *)
mapiodev(ca->ca_ra.ra_reg, 0, ca->ca_ra.ra_len, ca->ca_bustype);
}
#else
sc->sc_reg = (volatile u_int32_t *)tcdsdev->tcdsda_addr;
sc->sc_cookie = tcdsdev->tcdsda_cookie;
sc->sc_dma = tcdsdev->tcdsda_sc;
kprintf(": address %x", sc->sc_reg);
tcds_intr_establish(parent, sc->sc_cookie, TC_IPL_BIO,
(int (*)(void *))espintr, sc);
#endif
#ifdef SPARC_DRIVER
/* Other settings */
sc->sc_node = ca->ca_ra.ra_node;
if (ca->ca_bustype == BUS_SBUS) {
sc->sc_id = getpropint(sc->sc_node, "initiator-id", 7);
sc->sc_freq = getpropint(sc->sc_node, "clock-frequency", -1);
} else {
sc->sc_id = 7;
sc->sc_freq = 24000000;
}
if (sc->sc_freq < 0)
sc->sc_freq = ((struct sbus_softc *)
sc->sc_dev.dv_parent)->sc_clockfreq;
#else
if (parent->dv_cfdata->cf_driver == &tcds_cd) {
sc->sc_id = tcdsdev->tcdsda_id;
sc->sc_freq = tcdsdev->tcdsda_freq;
} else {
/* XXX */
sc->sc_id = 7;
sc->sc_freq = 24000000;
}
#endif
/* gimme Mhz */
sc->sc_freq /= 1000000;
#ifdef SPARC_DRIVER
if (dmachild) {
sc->sc_dma = (struct dma_softc *)parent;
sc->sc_dma->sc_esp = sc;
} else {
/*
* find the DMA by poking around the dma device structures
*
* What happens here is that if the dma driver has not been
* configured, then this returns a NULL pointer. Then when the
* dma actually gets configured, it does the opposing test, and
* if the sc->sc_esp field in it's softc is NULL, then tries to
* find the matching esp driver.
*
*/
sc->sc_dma = (struct dma_softc *)
getdevunit("dma", sc->sc_dev.dv_unit);
/*
* and a back pointer to us, for DMA
*/
if (sc->sc_dma)
sc->sc_dma->sc_esp = sc;
else
panic("espattach: no dma found");
}
#else
sc->sc_dma->sc_esp = sc; /* XXX */
#endif
/*
* It is necessary to try to load the 2nd config register here,
* to find out what rev the esp chip is, else the esp_reset
* will not set up the defaults correctly.
*/
sc->sc_cfg1 = sc->sc_id | ESPCFG1_PARENB;
#ifdef SPARC_DRIVER
sc->sc_cfg2 = ESPCFG2_SCSI2 | ESPCFG2_RPE;
sc->sc_cfg3 = ESPCFG3_CDB;
ESP_WRITE_REG(sc, ESP_CFG2, sc->sc_cfg2);
if ((ESP_READ_REG(sc, ESP_CFG2) & ~ESPCFG2_RSVD) != (ESPCFG2_SCSI2 | ESPCFG2_RPE)) {
kprintf(": ESP100");
sc->sc_rev = ESP100;
} else {
sc->sc_cfg2 = ESPCFG2_SCSI2;
ESP_WRITE_REG(sc, ESP_CFG2, sc->sc_cfg2);
sc->sc_cfg3 = 0;
ESP_WRITE_REG(sc, ESP_CFG3, sc->sc_cfg3);
sc->sc_cfg3 = (ESPCFG3_CDB | ESPCFG3_FCLK);
ESP_WRITE_REG(sc, ESP_CFG3, sc->sc_cfg3);
if (ESP_READ_REG(sc, ESP_CFG3) != (ESPCFG3_CDB | ESPCFG3_FCLK)) {
kprintf(": ESP100A");
sc->sc_rev = ESP100A;
} else {
/* ESPCFG2_FE enables > 64K transfers */
sc->sc_cfg2 |= ESPCFG2_FE;
sc->sc_cfg3 = 0;
ESP_WRITE_REG(sc, ESP_CFG3, sc->sc_cfg3);
kprintf(": ESP200");
sc->sc_rev = ESP200;
}
}
#else
sc->sc_cfg2 = ESPCFG2_SCSI2;
sc->sc_cfg3 = 0x4; /* Save residual byte. XXX??? */
kprintf(": NCR53C94");
sc->sc_rev = NCR53C94;
#endif
/*
* This is the value used to start sync negotiations
* Note that the ESP register "SYNCTP" is programmed
* in "clocks per byte", and has a minimum value of 4.
* The SCSI period used in negotiation is one-fourth
* of the time (in nanoseconds) needed to transfer one byte.
* Since the chip's clock is given in MHz, we have the following
* formula: 4 * period = (1000 / freq) * 4
*/
sc->sc_minsync = 1000 / sc->sc_freq;
#ifdef SPARC_DRIVER
/*
* Alas, we must now modify the value a bit, because it's
* only valid when can switch on FASTCLK and FASTSCSI bits
* in config register 3...
*/
switch (sc->sc_rev) {
case ESP100:
sc->sc_maxxfer = 64 * 1024;
sc->sc_minsync = 0; /* No synch on old chip? */
break;
case ESP100A:
sc->sc_maxxfer = 64 * 1024;
sc->sc_minsync = esp_cpb2stp(sc, 5); /* Min clocks/byte is 5 */
break;
case ESP200:
sc->sc_maxxfer = 16 * 1024 * 1024;
/* XXX - do actually set FAST* bits */
}
#else
sc->sc_maxxfer = 64 * 1024;
#endif
sc->sc_ccf = FREQTOCCF(sc->sc_freq);
/* The value *must not* be == 1. Make it 2 */
if (sc->sc_ccf == 1)
sc->sc_ccf = 2;
/*
* The recommended timeout is 250ms. This register is loaded
* with a value calculated as follows, from the docs:
*
* (timout period) x (CLK frequency)
* reg = -------------------------------------
* 8192 x (Clock Conversion Factor)
*
* Since CCF has a linear relation to CLK, this generally computes
* to the constant of 153.
*/
sc->sc_timeout = ((250 * 1000) * sc->sc_freq) / (8192 * sc->sc_ccf);
/* CCF register only has 3 bits; 0 is actually 8 */
sc->sc_ccf &= 7;
/* Reset state & bus */
sc->sc_state = 0;
esp_init(sc, 1);
kprintf(" %dMhz, target %d\n", sc->sc_freq, sc->sc_id);
#ifdef SPARC_DRIVER
/* add me to the sbus structures */
sc->sc_sd.sd_reset = (void *) esp_reset;
#if defined(SUN4C) || defined(SUN4M)
if (ca->ca_bustype == BUS_SBUS) {
if (dmachild)
sbus_establish(&sc->sc_sd, sc->sc_dev.dv_parent);
else
sbus_establish(&sc->sc_sd, &sc->sc_dev);
}
#endif /* SUN4C || SUN4M */
#endif
#ifdef SPARC_DRIVER
/* and the interuppts */
sc->sc_ih.ih_fun = (void *) espintr;
sc->sc_ih.ih_arg = sc;
intr_establish(sc->sc_pri, &sc->sc_ih);
evcnt_attach(&sc->sc_dev, "intr", &sc->sc_intrcnt);
#endif
/*
* fill in the prototype scsi_link.
*/
sc->sc_link.channel = SCSI_CHANNEL_ONLY_ONE;
sc->sc_link.adapter_softc = sc;
sc->sc_link.adapter_target = sc->sc_id;
sc->sc_link.adapter = &esp_switch;
sc->sc_link.device = &esp_dev;
sc->sc_link.openings = 2;
/*
* If the boot path is "esp" at the moment and it's me, then
* walk our pointer to the sub-device, ready for the config
* below.
*/
#ifdef SPARC_DRIVER
bp = ca->ca_ra.ra_bp;
switch (ca->ca_bustype) {
case BUS_SBUS:
if (bp != NULL && strcmp(bp->name, "esp") == 0 &&
SAME_ESP(sc, bp, ca))
bootpath_store(1, bp + 1);
break;
default:
if (bp != NULL && strcmp(bp->name, "esp") == 0 &&
bp->val[0] == -1 && bp->val[1] == sc->sc_dev.dv_unit)
bootpath_store(1, bp + 1);
break;
}
#endif
/*
* Now try to attach all the sub-devices
*/
config_found(self, &sc->sc_link, scsiprint);
#ifdef SPARC_DRIVER
bootpath_store(1, NULL);
#endif
}
/*
* This is the generic esp reset function. It does not reset the SCSI bus,
* only this controllers, but kills any on-going commands, and also stops
* and resets the DMA.
*
* After reset, registers are loaded with the defaults from the attach
* routine above.
*/
void
esp_reset(sc)
struct esp_softc *sc;
{
/* reset DMA first */
DMA_RESET(sc->sc_dma);
/* reset SCSI chip */
ESPCMD(sc, ESPCMD_RSTCHIP);
ESPCMD(sc, ESPCMD_NOP);
DELAY(500);
/* do these backwards, and fall through */
switch (sc->sc_rev) {
#ifndef SPARC_DRIVER
case NCR53C94:
#endif
case ESP200:
ESP_WRITE_REG(sc, ESP_CFG3, sc->sc_cfg3);
case ESP100A:
ESP_WRITE_REG(sc, ESP_CFG2, sc->sc_cfg2);
case ESP100:
ESP_WRITE_REG(sc, ESP_CFG1, sc->sc_cfg1);
ESP_WRITE_REG(sc, ESP_CCF, sc->sc_ccf);
ESP_WRITE_REG(sc, ESP_SYNCOFF, 0);
ESP_WRITE_REG(sc, ESP_TIMEOUT, sc->sc_timeout);
break;
default:
kprintf("%s: unknown revision code, assuming ESP100\n",
sc->sc_dev.dv_xname);
ESP_WRITE_REG(sc, ESP_CFG1, sc->sc_cfg1);
ESP_WRITE_REG(sc, ESP_CCF, sc->sc_ccf);
ESP_WRITE_REG(sc, ESP_SYNCOFF, 0);
ESP_WRITE_REG(sc, ESP_TIMEOUT, sc->sc_timeout);
}
}
/*
* Reset the SCSI bus, but not the chip
*/
void
esp_scsi_reset(sc)
struct esp_softc *sc;
{
#ifdef SPARC_DRIVER
/* stop DMA first, as the chip will return to Bus Free phase */
DMACSR(sc->sc_dma) &= ~D_EN_DMA;
#else
/*
* XXX STOP DMA FIRST
*/
#endif
kprintf("esp: resetting SCSI bus\n");
ESPCMD(sc, ESPCMD_RSTSCSI);
}
/*
* Initialize esp state machine
*/
void
esp_init(sc, doreset)
struct esp_softc *sc;
int doreset;
{
struct esp_ecb *ecb;
int r;
ESP_TRACE(("[ESP_INIT(%d)] ", doreset));
if (sc->sc_state == 0) {
/* First time through; initialize. */
TAILQ_INIT(&sc->ready_list);
TAILQ_INIT(&sc->nexus_list);
TAILQ_INIT(&sc->free_list);
sc->sc_nexus = NULL;
ecb = sc->sc_ecb;
bzero(ecb, sizeof(sc->sc_ecb));
for (r = 0; r < sizeof(sc->sc_ecb) / sizeof(*ecb); r++) {
TAILQ_INSERT_TAIL(&sc->free_list, ecb, chain);
ecb++;
}
bzero(sc->sc_tinfo, sizeof(sc->sc_tinfo));
} else {
/* Cancel any active commands. */
sc->sc_state = ESP_CLEANING;
if ((ecb = sc->sc_nexus) != NULL) {
ecb->xs->error = XS_DRIVER_STUFFUP;
untimeout(esp_timeout, ecb);
esp_done(sc, ecb);
}
while ((ecb = sc->nexus_list.tqh_first) != NULL) {
ecb->xs->error = XS_DRIVER_STUFFUP;
untimeout(esp_timeout, ecb);
esp_done(sc, ecb);
}
}
/*
* reset the chip to a known state
*/
esp_reset(sc);
sc->sc_phase = sc->sc_prevphase = INVALID_PHASE;
for (r = 0; r < 8; r++) {
struct esp_tinfo *ti = &sc->sc_tinfo[r];
/* XXX - config flags per target: low bits: no reselect; high bits: no synch */
int fl = sc->sc_dev.dv_cfdata->cf_flags;
ti->flags = ((sc->sc_minsync && !(fl & (1<<(r+8))))
? T_NEGOTIATE : 0) |
((fl & (1<<r)) ? T_RSELECTOFF : 0) |
T_NEED_TO_RESET;
ti->period = sc->sc_minsync;
ti->offset = 0;
}
if (doreset) {
sc->sc_state = ESP_SBR;
ESPCMD(sc, ESPCMD_RSTSCSI);
} else {
sc->sc_state = ESP_IDLE;
}
}
/*
* Read the ESP registers, and save their contents for later use.
* ESP_STAT, ESP_STEP & ESP_INTR are mostly zeroed out when reading
* ESP_INTR - so make sure it is the last read.
*
* I think that (from reading the docs) most bits in these registers
* only make sense when he DMA CSR has an interrupt showing. Call only
* if an interrupt is pending.
*/
void
espreadregs(sc)
struct esp_softc *sc;
{
sc->sc_espstat = ESP_READ_REG(sc, ESP_STAT);
/* Only the stepo bits are of interest */
sc->sc_espstep = ESP_READ_REG(sc, ESP_STEP) & ESPSTEP_MASK;
sc->sc_espintr = ESP_READ_REG(sc, ESP_INTR);
#ifndef SPARC_DRIVER
/* Clear the TCDS interrupt bit. */
(void)tcds_scsi_isintr(sc->sc_dma, 1);
#endif
/*
* Determine the SCSI bus phase, return either a real SCSI bus phase
* or some pseudo phase we use to detect certain exceptions.
*/
sc->sc_phase = (sc->sc_espintr & ESPINTR_DIS)
? /* Disconnected */ BUSFREE_PHASE
: sc->sc_espstat & ESPSTAT_PHASE;
ESP_MISC(("regs[intr=%02x,stat=%02x,step=%02x] ",
sc->sc_espintr, sc->sc_espstat, sc->sc_espstep));
}
/*
* Convert chip register Clock Per Byte value to Synchronous Transfer Period.
*/
static inline int
esp_cpb2stp(sc, cpb)
struct esp_softc *sc;
int cpb;
{
return ((250 * cpb) / sc->sc_freq);
}
/*
* Convert Synchronous Transfer Period to chip register Clock Per Byte value.
*/
static inline int
esp_stp2cpb(sc, period)
struct esp_softc *sc;
int period;
{
int v;
v = (sc->sc_freq * period) / 250;
if (esp_cpb2stp(sc, v) < period)
/* Correct round-down error */
v++;
return v;
}
static inline void
esp_setsync(sc, ti)
struct esp_softc *sc;
struct esp_tinfo *ti;
{
if (ti->flags & T_SYNCMODE) {
ESP_WRITE_REG(sc, ESP_SYNCOFF, ti->offset);
ESP_WRITE_REG(sc, ESP_SYNCTP, esp_stp2cpb(sc, ti->period));
} else {
ESP_WRITE_REG(sc, ESP_SYNCOFF, 0);
ESP_WRITE_REG(sc, ESP_SYNCTP, 0);
}
}
/*
* Send a command to a target, set the driver state to ESP_SELECTING
* and let the caller take care of the rest.
*
* Keeping this as a function allows me to say that this may be done
* by DMA instead of programmed I/O soon.
*/
void
esp_select(sc, ecb)
struct esp_softc *sc;
struct esp_ecb *ecb;
{
struct scsi_link *sc_link = ecb->xs->sc_link;
int target = sc_link->target;
struct esp_tinfo *ti = &sc->sc_tinfo[target];
u_char *cmd;
int clen;
ESP_TRACE(("[esp_select(t%d,l%d,cmd:%x)] ", sc_link->target, sc_link->lun, ecb->cmd.opcode));
/* new state ESP_SELECTING */
sc->sc_state = ESP_SELECTING;
ESPCMD(sc, ESPCMD_FLUSH);
/*
* The docs say the target register is never reset, and I
* can't think of a better place to set it
*/
ESP_WRITE_REG(sc, ESP_SELID, target);
esp_setsync(sc, ti);
/*
* Who am I. This is where we tell the target that we are
* happy for it to disconnect etc.
*/
ESP_WRITE_REG(sc, ESP_FIFO,
MSG_IDENTIFY(sc_link->lun, (ti->flags & T_RSELECTOFF)?0:1));
if (ti->flags & T_NEGOTIATE) {
/* Arbitrate, select and stop after IDENTIFY message */
ESPCMD(sc, ESPCMD_SELATNS);
return;
}
/* Now the command into the FIFO */
cmd = (u_char *)&ecb->cmd;
clen = ecb->clen;
while (clen--)
ESP_WRITE_REG(sc, ESP_FIFO, *cmd++);
/* And get the targets attention */
ESPCMD(sc, ESPCMD_SELATN);
}
void
esp_free_ecb(sc, ecb, flags)
struct esp_softc *sc;
struct esp_ecb *ecb;
int flags;
{
int s;
s = splbio();
ecb->flags = 0;
TAILQ_INSERT_HEAD(&sc->free_list, ecb, chain);
/*
* If there were none, wake anybody waiting for one to come free,
* starting with queued entries.
*/
if (ecb->chain.tqe_next == 0)
wakeup(&sc->free_list);
splx(s);
}
struct esp_ecb *
esp_get_ecb(sc, flags)
struct esp_softc *sc;
int flags;
{
struct esp_ecb *ecb;
int s;
s = splbio();
while ((ecb = sc->free_list.tqh_first) == NULL &&
(flags & SCSI_NOSLEEP) == 0)
tsleep(&sc->free_list, PRIBIO, "especb", 0);
if (ecb) {
TAILQ_REMOVE(&sc->free_list, ecb, chain);
ecb->flags |= ECB_ALLOC;
}
splx(s);
return ecb;
}
/*
* DRIVER FUNCTIONS CALLABLE FROM HIGHER LEVEL DRIVERS
*/
/*
* Start a SCSI-command
* This function is called by the higher level SCSI-driver to queue/run
* SCSI-commands.
*/
int
esp_scsi_cmd(xs)
struct scsi_xfer *xs;
{
struct scsi_link *sc_link = xs->sc_link;
struct esp_softc *sc = sc_link->adapter_softc;
struct esp_ecb *ecb;
int s, flags;
ESP_TRACE(("[esp_scsi_cmd] "));
ESP_CMDS(("[0x%x, %d]->%d ", (int)xs->cmd->opcode, xs->cmdlen,
sc_link->target));
flags = xs->flags;
if ((ecb = esp_get_ecb(sc, flags)) == NULL) {
xs->error = XS_DRIVER_STUFFUP;
return TRY_AGAIN_LATER;
}
/* Initialize ecb */
ecb->xs = xs;
ecb->timeout = xs->timeout;
if (xs->flags & SCSI_RESET) {
ecb->flags |= ECB_RESET;
ecb->clen = 0;
ecb->dleft = 0;
} else {
bcopy(xs->cmd, &ecb->cmd, xs->cmdlen);
ecb->clen = xs->cmdlen;
ecb->daddr = xs->data;
ecb->dleft = xs->datalen;
}
ecb->stat = 0;
s = splbio();
TAILQ_INSERT_TAIL(&sc->ready_list, ecb, chain);
if (sc->sc_state == ESP_IDLE)
esp_sched(sc);
splx(s);
if ((flags & SCSI_POLL) == 0)
return SUCCESSFULLY_QUEUED;
/* Not allowed to use interrupts, use polling instead */
if (esp_poll(sc, xs, ecb->timeout)) {
esp_timeout(ecb);
if (esp_poll(sc, xs, ecb->timeout))
esp_timeout(ecb);
}
return COMPLETE;
}
/*
* Used when interrupt driven I/O isn't allowed, e.g. during boot.
*/
int
esp_poll(sc, xs, count)
struct esp_softc *sc;
struct scsi_xfer *xs;
int count;
{
ESP_TRACE(("[esp_poll] "));
while (count) {
if (DMA_ISINTR(sc->sc_dma)) {
espintr(sc);
}
#if alternatively
if (ESP_READ_REG(sc, ESP_STAT) & ESPSTAT_INT)
espintr(sc);
#endif
if ((xs->flags & ITSDONE) != 0)
return 0;
if (sc->sc_state == ESP_IDLE) {
ESP_TRACE(("[esp_poll: rescheduling] "));
esp_sched(sc);
}
DELAY(1000);
count--;
}
return 1;
}
/*
* LOW LEVEL SCSI UTILITIES
*/
/*
* Schedule a scsi operation. This has now been pulled out of the interrupt
* handler so that we may call it from esp_scsi_cmd and esp_done. This may
* save us an unecessary interrupt just to get things going. Should only be
* called when state == ESP_IDLE and at bio pl.
*/
void
esp_sched(sc)
struct esp_softc *sc;
{
struct esp_ecb *ecb;
struct scsi_link *sc_link;
struct esp_tinfo *ti;
ESP_TRACE(("[esp_sched] "));
if (sc->sc_state != ESP_IDLE)
panic("esp_sched: not IDLE (state=%d)", sc->sc_state);
/*
* Find first ecb in ready queue that is for a target/lunit
* combinations that is not busy.
*/
for (ecb = sc->ready_list.tqh_first; ecb; ecb = ecb->chain.tqe_next) {
sc_link = ecb->xs->sc_link;
ti = &sc->sc_tinfo[sc_link->target];
if ((ti->lubusy & (1 << sc_link->lun)) == 0) {
TAILQ_REMOVE(&sc->ready_list, ecb, chain);
sc->sc_nexus = ecb;
esp_select(sc, ecb);
break;
} else
ESP_MISC(("%d:%d busy\n",
sc_link->target, sc_link->lun));
}
}
void
esp_sense(sc, ecb)
struct esp_softc *sc;
struct esp_ecb *ecb;
{
struct scsi_xfer *xs = ecb->xs;
struct scsi_link *sc_link = xs->sc_link;
struct esp_tinfo *ti = &sc->sc_tinfo[sc_link->target];
struct scsi_sense *ss = (void *)&ecb->cmd;
ESP_MISC(("requesting sense "));
/* Next, setup a request sense command block */
bzero(ss, sizeof(*ss));
ss->opcode = REQUEST_SENSE;
ss->byte2 = sc_link->lun << 5;
ss->length = sizeof(struct scsi_sense_data);
ecb->clen = sizeof(*ss);
ecb->daddr = (char *)&xs->sense;
ecb->dleft = sizeof(struct scsi_sense_data);
ecb->flags |= ECB_SENSE;
ti->senses++;
if (ecb->flags & ECB_NEXUS)
ti->lubusy &= ~(1 << sc_link->lun);
if (ecb == sc->sc_nexus) {
esp_select(sc, ecb);
} else {
esp_dequeue(sc, ecb);
TAILQ_INSERT_HEAD(&sc->ready_list, ecb, chain);
if (sc->sc_state == ESP_IDLE)
esp_sched(sc);
}
}
/*
* POST PROCESSING OF SCSI_CMD (usually current)
*/
void
esp_done(sc, ecb)
struct esp_softc *sc;
struct esp_ecb *ecb;
{
struct scsi_xfer *xs = ecb->xs;
struct scsi_link *sc_link = xs->sc_link;
struct esp_tinfo *ti = &sc->sc_tinfo[sc_link->target];
ESP_TRACE(("[esp_done(error:%x)] ", xs->error));
/*
* Now, if we've come here with no error code, i.e. we've kept the
* initial XS_NOERROR, and the status code signals that we should
* check sense, we'll need to set up a request sense cmd block and
* push the command back into the ready queue *before* any other
* commands for this target/lunit, else we lose the sense info.
* We don't support chk sense conditions for the request sense cmd.
*/
if (xs->error == XS_NOERROR) {
if ((ecb->flags & ECB_ABORT) != 0) {
xs->error = XS_DRIVER_STUFFUP;
} else if ((ecb->flags & ECB_SENSE) != 0) {
xs->error = XS_SENSE;
} else if ((ecb->stat & ST_MASK) == SCSI_CHECK) {
/* First, save the return values */
xs->resid = ecb->dleft;
xs->status = ecb->stat;
esp_sense(sc, ecb);
return;
} else {
xs->resid = ecb->dleft;
}
}
xs->flags |= ITSDONE;
#ifdef ESP_DEBUG
if (esp_debug & ESP_SHOWMISC) {
if (xs->resid != 0)
kprintf("resid=%d ", xs->resid);
if (xs->error == XS_SENSE)
kprintf("sense=0x%02x\n", xs->sense.error_code);
else
kprintf("error=%d\n", xs->error);
}
#endif
/*
* Remove the ECB from whatever queue it's on.
*/
if (ecb->flags & ECB_NEXUS)
ti->lubusy &= ~(1 << sc_link->lun);
if (ecb == sc->sc_nexus) {
sc->sc_nexus = NULL;
sc->sc_state = ESP_IDLE;
esp_sched(sc);
} else
esp_dequeue(sc, ecb);
esp_free_ecb(sc, ecb, xs->flags);
ti->cmds++;
scsi_done(xs);
}
void
esp_dequeue(sc, ecb)
struct esp_softc *sc;
struct esp_ecb *ecb;
{
if (ecb->flags & ECB_NEXUS) {
TAILQ_REMOVE(&sc->nexus_list, ecb, chain);
} else {
TAILQ_REMOVE(&sc->ready_list, ecb, chain);
}
}
/*
* INTERRUPT/PROTOCOL ENGINE
*/
/*
* Schedule an outgoing message by prioritizing it, and asserting
* attention on the bus. We can only do this when we are the initiator
* else there will be an illegal command interrupt.
*/
#define esp_sched_msgout(m) \
do { \
ESP_MISC(("esp_sched_msgout %d ", m)); \
ESPCMD(sc, ESPCMD_SETATN); \
sc->sc_flags |= ESP_ATN; \
sc->sc_msgpriq |= (m); \
} while (0)
int
esp_reselect(sc, message)
struct esp_softc *sc;
int message;
{
u_char selid, target, lun;
struct esp_ecb *ecb;
struct scsi_link *sc_link;
struct esp_tinfo *ti;
/*
* The SCSI chip made a snapshot of the data bus while the reselection
* was being negotiated. This enables us to determine which target did
* the reselect.
*/
selid = sc->sc_selid & ~(1 << sc->sc_id);
if (selid & (selid - 1)) {
kprintf("%s: reselect with invalid selid %02x; sending DEVICE RESET\n",
sc->sc_dev.dv_xname, selid);
goto reset;
}
/*
* Search wait queue for disconnected cmd
* The list should be short, so I haven't bothered with
* any more sophisticated structures than a simple
* singly linked list.
*/
target = ffs(selid) - 1;
lun = message & 0x07;
for (ecb = sc->nexus_list.tqh_first; ecb != NULL;
ecb = ecb->chain.tqe_next) {
sc_link = ecb->xs->sc_link;
if (sc_link->target == target && sc_link->lun == lun)
break;
}
if (ecb == NULL) {
kprintf("%s: reselect from target %d lun %d with no nexus; sending ABORT\n",
sc->sc_dev.dv_xname, target, lun);
goto abort;
}
/* Make this nexus active again. */
TAILQ_REMOVE(&sc->nexus_list, ecb, chain);
sc->sc_state = ESP_CONNECTED;
sc->sc_nexus = ecb;
ti = &sc->sc_tinfo[target];
ti->lubusy |= (1 << lun);
esp_setsync(sc, ti);
if (ecb->flags & ECB_RESET)
esp_sched_msgout(SEND_DEV_RESET);
else if (ecb->flags & ECB_ABORT)
esp_sched_msgout(SEND_ABORT);
/* Do an implicit RESTORE POINTERS. */
sc->sc_dp = ecb->daddr;
sc->sc_dleft = ecb->dleft;
return (0);
reset:
esp_sched_msgout(SEND_DEV_RESET);
return (1);
abort:
esp_sched_msgout(SEND_ABORT);
return (1);
}
#define IS1BYTEMSG(m) (((m) != 1 && (m) < 0x20) || (m) & 0x80)
#define IS2BYTEMSG(m) (((m) & 0xf0) == 0x20)
#define ISEXTMSG(m) ((m) == 1)
/*
* Get an incoming message as initiator.
*
* The SCSI bus must already be in MESSAGE_IN_PHASE and there is a
* byte in the FIFO
*/
void
esp_msgin(sc)
register struct esp_softc *sc;
{
register int v;
ESP_TRACE(("[esp_msgin(curmsglen:%d)] ", sc->sc_imlen));
if ((ESP_READ_REG(sc, ESP_FFLAG) & ESPFIFO_FF) == 0) {
kprintf("%s: msgin: no msg byte available\n",
sc->sc_dev.dv_xname);
return;
}
/*
* Prepare for a new message. A message should (according
* to the SCSI standard) be transmitted in one single
* MESSAGE_IN_PHASE. If we have been in some other phase,
* then this is a new message.
*/
if (sc->sc_prevphase != MESSAGE_IN_PHASE) {
sc->sc_flags &= ~ESP_DROP_MSGI;
sc->sc_imlen = 0;
}
v = ESP_READ_REG(sc, ESP_FIFO);
ESP_MISC(("<msgbyte:0x%02x>", v));
#if 0
if (sc->sc_state == ESP_RESELECTED && sc->sc_imlen == 0) {
/*
* Which target is reselecting us? (The ID bit really)
*/
sc->sc_selid = v;
ESP_MISC(("selid=0x%2x ", sc->sc_selid));
return;
}
#endif
sc->sc_imess[sc->sc_imlen] = v;
/*
* If we're going to reject the message, don't bother storing
* the incoming bytes. But still, we need to ACK them.
*/
if ((sc->sc_flags & ESP_DROP_MSGI)) {
ESPCMD(sc, ESPCMD_MSGOK);
kprintf("<dropping msg byte %x>",
sc->sc_imess[sc->sc_imlen]);
return;
}
if (sc->sc_imlen >= ESP_MAX_MSG_LEN) {
esp_sched_msgout(SEND_REJECT);
sc->sc_flags |= ESP_DROP_MSGI;
} else {
sc->sc_imlen++;
/*
* This testing is suboptimal, but most
* messages will be of the one byte variety, so
* it should not effect performance
* significantly.
*/
if (sc->sc_imlen == 1 && IS1BYTEMSG(sc->sc_imess[0]))
goto gotit;
if (sc->sc_imlen == 2 && IS2BYTEMSG(sc->sc_imess[0]))
goto gotit;
if (sc->sc_imlen >= 3 && ISEXTMSG(sc->sc_imess[0]) &&
sc->sc_imlen == sc->sc_imess[1] + 2)
goto gotit;
}
/* Ack what we have so far */
ESPCMD(sc, ESPCMD_MSGOK);
return;
gotit:
ESP_MSGS(("gotmsg(%x)", sc->sc_imess[0]));
/*
* Now we should have a complete message (1 byte, 2 byte
* and moderately long extended messages). We only handle
* extended messages which total length is shorter than
* ESP_MAX_MSG_LEN. Longer messages will be amputated.
*/
switch (sc->sc_state) {
struct esp_ecb *ecb;
struct esp_tinfo *ti;
case ESP_CONNECTED:
ecb = sc->sc_nexus;
ti = &sc->sc_tinfo[ecb->xs->sc_link->target];
switch (sc->sc_imess[0]) {
case MSG_CMDCOMPLETE:
ESP_MSGS(("cmdcomplete "));
if (sc->sc_dleft < 0) {
struct scsi_link *sc_link = ecb->xs->sc_link;
kprintf("%s: %d extra bytes from %d:%d\n",
sc->sc_dev.dv_xname, -sc->sc_dleft,
sc_link->target, sc_link->lun);
sc->sc_dleft = 0;
}
ecb->xs->resid = ecb->dleft = sc->sc_dleft;
sc->sc_state = ESP_CMDCOMPLETE;
break;
case MSG_MESSAGE_REJECT:
if (esp_debug & ESP_SHOWMSGS)
kprintf("%s: our msg rejected by target\n",
sc->sc_dev.dv_xname);
switch (sc->sc_msgout) {
case SEND_SDTR:
sc->sc_flags &= ~ESP_SYNCHNEGO;
ti->flags &= ~(T_NEGOTIATE | T_SYNCMODE);
esp_setsync(sc, ti);
break;
case SEND_INIT_DET_ERR:
goto abort;
}
break;
case MSG_NOOP:
ESP_MSGS(("noop "));
break;
case MSG_DISCONNECT:
ESP_MSGS(("disconnect "));
ti->dconns++;
sc->sc_state = ESP_DISCONNECT;
if ((ecb->xs->sc_link->quirks & SDEV_AUTOSAVE) == 0)
break;
/*FALLTHROUGH*/
case MSG_SAVEDATAPOINTER:
ESP_MSGS(("save datapointer "));
ecb->daddr = sc->sc_dp;
ecb->dleft = sc->sc_dleft;
break;
case MSG_RESTOREPOINTERS:
ESP_MSGS(("restore datapointer "));
sc->sc_dp = ecb->daddr;
sc->sc_dleft = ecb->dleft;
break;
case MSG_EXTENDED:
ESP_MSGS(("extended(%x) ", sc->sc_imess[2]));
switch (sc->sc_imess[2]) {
case MSG_EXT_SDTR:
ESP_MSGS(("SDTR period %d, offset %d ",
sc->sc_imess[3], sc->sc_imess[4]));
if (sc->sc_imess[1] != 3)
goto reject;
ti->period = sc->sc_imess[3];
ti->offset = sc->sc_imess[4];
ti->flags &= ~T_NEGOTIATE;
if (sc->sc_minsync == 0 ||
ti->offset == 0 ||
ti->period > 124) {
kprintf("%s:%d: async\n", "esp",
ecb->xs->sc_link->target);
if ((sc->sc_flags&ESP_SYNCHNEGO) == 0) {
/* target initiated negotiation */
ti->offset = 0;
ti->flags &= ~T_SYNCMODE;
esp_sched_msgout(SEND_SDTR);
} else {
/* we are async */
ti->flags &= ~T_SYNCMODE;
}
} else {
int r = 250/ti->period;
int s = (100*250)/ti->period - 100*r;
int p;
p = esp_stp2cpb(sc, ti->period);
ti->period = esp_cpb2stp(sc, p);
#ifdef ESP_DEBUG
sc_print_addr(ecb->xs->sc_link);
kprintf("max sync rate %d.%02dMb/s\n",
r, s);
#endif
if ((sc->sc_flags&ESP_SYNCHNEGO) == 0) {
/* target initiated negotiation */
if (ti->period < sc->sc_minsync)
ti->period = sc->sc_minsync;
if (ti->offset > 15)
ti->offset = 15;
ti->flags &= ~T_SYNCMODE;
esp_sched_msgout(SEND_SDTR);
} else {
/* we are sync */
ti->flags |= T_SYNCMODE;
}
}
sc->sc_flags &= ~ESP_SYNCHNEGO;
esp_setsync(sc, ti);
break;
default:
kprintf("%s: unrecognized MESSAGE EXTENDED; sending REJECT\n",
sc->sc_dev.dv_xname);
goto reject;
}
break;
default:
ESP_MSGS(("ident "));
kprintf("%s: unrecognized MESSAGE; sending REJECT\n",
sc->sc_dev.dv_xname);
reject:
esp_sched_msgout(SEND_REJECT);
break;
}
break;
case ESP_RESELECTED:
if (!MSG_ISIDENTIFY(sc->sc_imess[0])) {
kprintf("%s: reselect without IDENTIFY; sending DEVICE RESET\n",
sc->sc_dev.dv_xname);
goto reset;
}
(void) esp_reselect(sc, sc->sc_imess[0]);
break;
default:
kprintf("%s: unexpected MESSAGE IN; sending DEVICE RESET\n",
sc->sc_dev.dv_xname);
reset:
esp_sched_msgout(SEND_DEV_RESET);
break;
abort:
esp_sched_msgout(SEND_ABORT);
break;
}
/* Ack last message byte */
ESPCMD(sc, ESPCMD_MSGOK);
/* Done, reset message pointer. */
sc->sc_flags &= ~ESP_DROP_MSGI;
sc->sc_imlen = 0;
}
/*
* Send the highest priority, scheduled message
*/
void
esp_msgout(sc)
register struct esp_softc *sc;
{
struct esp_tinfo *ti;
struct esp_ecb *ecb;
size_t size;
ESP_TRACE(("[esp_msgout(priq:%x, prevphase:%x)]", sc->sc_msgpriq, sc->sc_prevphase));
if (sc->sc_flags & ESP_ATN) {
if (sc->sc_prevphase != MESSAGE_OUT_PHASE) {
new:
ESPCMD(sc, ESPCMD_FLUSH);
DELAY(1);
sc->sc_msgoutq = 0;
sc->sc_omlen = 0;
}
} else {
if (sc->sc_prevphase == MESSAGE_OUT_PHASE) {
esp_sched_msgout(sc->sc_msgoutq);
goto new;
} else {
kprintf("esp at line %d: unexpected MESSAGE OUT phase\n", __LINE__);
}
}
if (sc->sc_omlen == 0) {
/* Pick up highest priority message */
sc->sc_msgout = sc->sc_msgpriq & -sc->sc_msgpriq;
sc->sc_msgoutq |= sc->sc_msgout;
sc->sc_msgpriq &= ~sc->sc_msgout;
sc->sc_omlen = 1; /* "Default" message len */
switch (sc->sc_msgout) {
case SEND_SDTR:
ecb = sc->sc_nexus;
ti = &sc->sc_tinfo[ecb->xs->sc_link->target];
sc->sc_omess[0] = MSG_EXTENDED;
sc->sc_omess[1] = 3;
sc->sc_omess[2] = MSG_EXT_SDTR;
sc->sc_omess[3] = ti->period;
sc->sc_omess[4] = ti->offset;
sc->sc_omlen = 5;
if ((sc->sc_flags & ESP_SYNCHNEGO) == 0) {
ti->flags |= T_SYNCMODE;
esp_setsync(sc, ti);
}
break;
case SEND_IDENTIFY:
if (sc->sc_state != ESP_CONNECTED) {
kprintf("esp at line %d: no nexus\n", __LINE__);
}
ecb = sc->sc_nexus;
sc->sc_omess[0] = MSG_IDENTIFY(ecb->xs->sc_link->lun,0);
break;
case SEND_DEV_RESET:
sc->sc_flags |= ESP_ABORTING;
sc->sc_omess[0] = MSG_BUS_DEV_RESET;
ecb = sc->sc_nexus;
ti = &sc->sc_tinfo[ecb->xs->sc_link->target];
ti->flags &= ~T_SYNCMODE;
ti->flags |= T_NEGOTIATE;
break;
case SEND_PARITY_ERROR:
sc->sc_omess[0] = MSG_PARITY_ERROR;
break;
case SEND_ABORT:
sc->sc_flags |= ESP_ABORTING;
sc->sc_omess[0] = MSG_ABORT;
break;
case SEND_INIT_DET_ERR:
sc->sc_omess[0] = MSG_INITIATOR_DET_ERR;
break;
case SEND_REJECT:
sc->sc_omess[0] = MSG_MESSAGE_REJECT;
break;
default:
ESPCMD(sc, ESPCMD_RSTATN);
sc->sc_flags &= ~ESP_ATN;
sc->sc_omess[0] = MSG_NOOP;
break;
}
sc->sc_omp = sc->sc_omess;
}
#if 1
/* (re)send the message */
size = min(sc->sc_omlen, sc->sc_maxxfer);
DMA_SETUP(sc->sc_dma, &sc->sc_omp, &sc->sc_omlen, 0, &size);
/* Program the SCSI counter */
ESP_WRITE_REG(sc, ESP_TCL, size);
ESP_WRITE_REG(sc, ESP_TCM, size >> 8);
if (sc->sc_cfg2 & ESPCFG2_FE) {
ESP_WRITE_REG(sc, ESP_TCH, size >> 16);
}
/* load the count in */
ESPCMD(sc, ESPCMD_NOP|ESPCMD_DMA);
ESPCMD(sc, ESPCMD_TRANS|ESPCMD_DMA);
DMA_GO(sc->sc_dma);
#else
{ int i;
for (i = 0; i < sc->sc_omlen; i++)
ESP_WRITE_REG(sc, FIFO, sc->sc_omess[i]);
ESPCMD(sc, ESPCMD_TRANS);
sc->sc_omlen = 0;
}
#endif
}
/*
* This is the most critical part of the driver, and has to know
* how to deal with *all* error conditions and phases from the SCSI
* bus. If there are no errors and the DMA was active, then call the
* DMA pseudo-interrupt handler. If this returns 1, then that was it
* and we can return from here without further processing.
*
* Most of this needs verifying.
*/
int
espintr(sc)
register struct esp_softc *sc;
{
register struct esp_ecb *ecb;
register struct scsi_link *sc_link;
struct esp_tinfo *ti;
int loop;
size_t size;
ESP_TRACE(("[espintr]"));
/*
* I have made some (maybe seriously flawed) assumptions here,
* but basic testing (uncomment the kprintf() below), show that
* certainly something happens when this loop is here.
*
* The idea is that many of the SCSI operations take very little
* time, and going away and getting interrupted is too high an
* overhead to pay. For example, selecting, sending a message
* and command and then doing some work can be done in one "pass".
*
* The DELAY is not variable because I do not understand that the
* DELAY loop should be fixed-time regardless of CPU speed, but
* I am *assuming* that the faster SCSI processors get things done
* quicker (sending a command byte etc), and so there is no
* need to be too slow.
*
* This is a heuristic. It is 2 when at 20Mhz, 2 at 25Mhz and 1
* at 40Mhz. This needs testing.
*/
for (loop = 0; 1;loop++, DELAY(50/sc->sc_freq)) {
/* a feeling of deja-vu */
if (!DMA_ISINTR(sc->sc_dma))
return (loop != 0);
#if 0
if (loop)
kprintf("*");
#endif
/* and what do the registers say... */
espreadregs(sc);
sc->sc_intrcnt.ev_count++;
/*
* At the moment, only a SCSI Bus Reset or Illegal
* Command are classed as errors. A disconnect is a
* valid condition, and we let the code check is the
* "ESP_BUSFREE_OK" flag was set before declaring it
* and error.
*
* Also, the status register tells us about "Gross
* Errors" and "Parity errors". Only the Gross Error
* is really bad, and the parity errors are dealt
* with later
*
* TODO
* If there are too many parity error, go to slow
* cable mode ?
*/
/* SCSI Reset */
if (sc->sc_espintr & ESPINTR_SBR) {
if (ESP_READ_REG(sc, ESP_FFLAG) & ESPFIFO_FF) {
ESPCMD(sc, ESPCMD_FLUSH);
DELAY(1);
}
if (sc->sc_state != ESP_SBR) {
kprintf("%s: SCSI bus reset\n",
sc->sc_dev.dv_xname);
esp_init(sc, 0); /* Restart everything */
return 1;
}
#if 0
/*XXX*/ kprintf("<expected bus reset: "
"[intr %x, stat %x, step %d]>\n",
sc->sc_espintr, sc->sc_espstat,
sc->sc_espstep);
#endif
if (sc->sc_nexus)
panic("%s: nexus in reset state",
sc->sc_dev.dv_xname);
goto sched;
}
ecb = sc->sc_nexus;
#define ESPINTR_ERR (ESPINTR_SBR|ESPINTR_ILL)
if (sc->sc_espintr & ESPINTR_ERR ||
sc->sc_espstat & ESPSTAT_GE) {
if (sc->sc_espstat & ESPSTAT_GE) {
/* no target ? */
if (ESP_READ_REG(sc, ESP_FFLAG) & ESPFIFO_FF) {
ESPCMD(sc, ESPCMD_FLUSH);
DELAY(1);
}
if (sc->sc_state == ESP_CONNECTED ||
sc->sc_state == ESP_SELECTING) {
ecb->xs->error = XS_DRIVER_STUFFUP;
esp_done(sc, ecb);
}
return 1;
}
if (sc->sc_espintr & ESPINTR_ILL) {
/* illegal command, out of sync ? */
kprintf("%s: illegal command: 0x%x (state %d, phase %x, prevphase %x)\n",
sc->sc_dev.dv_xname, sc->sc_lastcmd,
sc->sc_state, sc->sc_phase,
sc->sc_prevphase);
if (ESP_READ_REG(sc, ESP_FFLAG) & ESPFIFO_FF) {
ESPCMD(sc, ESPCMD_FLUSH);
DELAY(1);
}
esp_init(sc, 0); /* Restart everything */
return 1;
}
}
/*
* Call if DMA is active.
*
* If DMA_INTR returns true, then maybe go 'round the loop
* again in case there is no more DMA queued, but a phase
* change is expected.
*/
if (DMA_ISACTIVE(sc->sc_dma)) {
DMA_INTR(sc->sc_dma);
/* If DMA active here, then go back to work... */
if (DMA_ISACTIVE(sc->sc_dma))
return 1;
if (sc->sc_dleft == 0 &&
(sc->sc_espstat & ESPSTAT_TC) == 0)
kprintf("%s: !TC [intr %x, stat %x, step %d]"
" prevphase %x, resid %x\n",
sc->sc_dev.dv_xname,
sc->sc_espintr,
sc->sc_espstat,
sc->sc_espstep,
sc->sc_prevphase,
ecb?ecb->dleft:-1);
}
#if 0 /* Unreliable on some ESP revisions? */
if ((sc->sc_espstat & ESPSTAT_INT) == 0) {
kprintf("%s: spurious interrupt\n", sc->sc_dev.dv_xname);
return 1;
}
#endif
/*
* check for less serious errors
*/
if (sc->sc_espstat & ESPSTAT_PE) {
kprintf("%s: SCSI bus parity error\n",
sc->sc_dev.dv_xname);
if (sc->sc_prevphase == MESSAGE_IN_PHASE)
esp_sched_msgout(SEND_PARITY_ERROR);
else
esp_sched_msgout(SEND_INIT_DET_ERR);
}
if (sc->sc_espintr & ESPINTR_DIS) {
ESP_MISC(("<DISC [intr %x, stat %x, step %d]>",
sc->sc_espintr,sc->sc_espstat,sc->sc_espstep));
if (ESP_READ_REG(sc, ESP_FFLAG) & ESPFIFO_FF) {
ESPCMD(sc, ESPCMD_FLUSH);
DELAY(1);
}
/*
* This command must (apparently) be issued within
* 250mS of a disconnect. So here you are...
*/
ESPCMD(sc, ESPCMD_ENSEL);
switch (sc->sc_state) {
case ESP_RESELECTED:
goto sched;
case ESP_SELECTING:
ecb->xs->error = XS_SELTIMEOUT;
goto finish;
case ESP_CONNECTED:
if ((sc->sc_flags & ESP_SYNCHNEGO)) {
#ifdef ESP_DEBUG
if (ecb)
sc_print_addr(ecb->xs->sc_link);
kprintf("sync nego not completed!\n");
#endif
ti = &sc->sc_tinfo[ecb->xs->sc_link->target];
sc->sc_flags &= ~ESP_SYNCHNEGO;
ti->flags &= ~(T_NEGOTIATE | T_SYNCMODE);
}
/* it may be OK to disconnect */
if ((sc->sc_flags & ESP_ABORTING) == 0) {
/*
* Section 5.1.1 of the SCSI 2 spec
* suggests issuing a REQUEST SENSE
* following an unexpected disconnect.
* Some devices go into a contingent
* allegiance condition when
* disconnecting, and this is necessary
* to clean up their state.
*/
kprintf("%s: unexpected disconnect; ",
sc->sc_dev.dv_xname);
if (ecb->flags & ECB_SENSE) {
kprintf("resetting\n");
goto reset;
}
kprintf("sending REQUEST SENSE\n");
esp_sense(sc, ecb);
goto out;
}
ecb->xs->error = XS_DRIVER_STUFFUP;
goto finish;
case ESP_DISCONNECT:
TAILQ_INSERT_HEAD(&sc->nexus_list, ecb, chain);
sc->sc_nexus = NULL;
goto sched;
case ESP_CMDCOMPLETE:
goto finish;
}
}
switch (sc->sc_state) {
case ESP_SBR:
kprintf("%s: waiting for SCSI Bus Reset to happen\n",
sc->sc_dev.dv_xname);
return 1;
case ESP_RESELECTED:
/*
* we must be continuing a message ?
*/
if (sc->sc_phase != MESSAGE_IN_PHASE) {
kprintf("%s: target didn't identify\n",
sc->sc_dev.dv_xname);
esp_init(sc, 1);
return 1;
}
kprintf("<<RESELECT CONT'd>>");
#if XXXX
esp_msgin(sc);
if (sc->sc_state != ESP_CONNECTED) {
/* IDENTIFY fail?! */
kprintf("%s: identify failed\n",
sc->sc_dev.dv_xname);
esp_init(sc, 1);
return 1;
}
#endif
break;
case ESP_IDLE:
if (sc->sc_flags & ESP_ICCS) kprintf("[[esp: BUMMER]]");
case ESP_SELECTING:
sc->sc_msgpriq = sc->sc_msgout = sc->sc_msgoutq = 0;
sc->sc_flags = 0;
if (sc->sc_espintr & ESPINTR_RESEL) {
/*
* If we're trying to select a
* target ourselves, push our command
* back into the ready list.
*/
if (sc->sc_state == ESP_SELECTING) {
ESP_MISC(("backoff selector "));
sc_link = sc->sc_nexus->xs->sc_link;
ti = &sc->sc_tinfo[sc_link->target];
TAILQ_INSERT_HEAD(&sc->ready_list,
sc->sc_nexus, chain);
ecb = sc->sc_nexus = NULL;
}
sc->sc_state = ESP_RESELECTED;
if (sc->sc_phase != MESSAGE_IN_PHASE) {
/*
* Things are seriously fucked up.
* Pull the brakes, i.e. reset
*/
kprintf("%s: target didn't identify\n",
sc->sc_dev.dv_xname);
esp_init(sc, 1);
return 1;
}
if ((ESP_READ_REG(sc, ESP_FFLAG) & ESPFIFO_FF) != 2) {
kprintf("%s: RESELECT: %d bytes in FIFO!\n",
sc->sc_dev.dv_xname,
ESP_READ_REG(sc, ESP_FFLAG) &
ESPFIFO_FF);
esp_init(sc, 1);
return 1;
}
sc->sc_selid = ESP_READ_REG(sc, ESP_FIFO);
ESP_MISC(("selid=0x%2x ", sc->sc_selid));
esp_msgin(sc); /* Handle identify message */
if (sc->sc_state != ESP_CONNECTED) {
/* IDENTIFY fail?! */
kprintf("%s: identify failed\n",
sc->sc_dev.dv_xname);
esp_init(sc, 1);
return 1;
}
continue; /* ie. next phase expected soon */
}
#define ESPINTR_DONE (ESPINTR_FC|ESPINTR_BS)
if ((sc->sc_espintr & ESPINTR_DONE) == ESPINTR_DONE) {
ecb = sc->sc_nexus;
if (!ecb)
panic("esp: not nexus at sc->sc_nexus");
sc_link = ecb->xs->sc_link;
ti = &sc->sc_tinfo[sc_link->target];
switch (sc->sc_espstep) {
case 0:
kprintf("%s: select timeout/no disconnect\n",
sc->sc_dev.dv_xname);
ecb->xs->error = XS_SELTIMEOUT;
goto finish;
case 1:
if ((ti->flags & T_NEGOTIATE) == 0) {
kprintf("%s: step 1 & !NEG\n",
sc->sc_dev.dv_xname);
goto reset;
}
if (sc->sc_phase != MESSAGE_OUT_PHASE) {
kprintf("%s: !MSGOUT\n",
sc->sc_dev.dv_xname);
goto reset;
}
/* Start negotiating */
ti->period = sc->sc_minsync;
ti->offset = 15;
sc->sc_flags |= ESP_SYNCHNEGO;
esp_sched_msgout(SEND_SDTR);
break;
case 3:
/*
* Grr, this is supposed to mean
* "target left command phase
* prematurely". It seems to happen
* regularly when sync mode is on.
* Look at FIFO to see if command
* went out.
* (Timing problems?)
*/
if ((ESP_READ_REG(sc, ESP_FFLAG)&ESPFIFO_FF) == 0) {
/* Hope for the best.. */
break;
}
kprintf("(%s:%d:%d): selection failed;"
" %d left in FIFO "
"[intr %x, stat %x, step %d]\n",
sc->sc_dev.dv_xname,
sc_link->target,
sc_link->lun,
ESP_READ_REG(sc, ESP_FFLAG) & ESPFIFO_FF,
sc->sc_espintr, sc->sc_espstat,
sc->sc_espstep);
ESPCMD(sc, ESPCMD_FLUSH);
esp_sched_msgout(SEND_ABORT);
return 1;
case 2:
/* Select stuck at Command Phase */
ESPCMD(sc, ESPCMD_FLUSH);
case 4:
/* So far, everything went fine */
break;
}
#if 0
if (ecb->xs->flags & SCSI_RESET)
esp_sched_msgout(SEND_DEV_RESET);
else if (ti->flags & T_NEGOTIATE)
esp_sched_msgout(
SEND_IDENTIFY | SEND_SDTR);
else
esp_sched_msgout(SEND_IDENTIFY);
#endif
ecb->flags |= ECB_NEXUS;
ti->lubusy |= (1 << sc_link->lun);
sc->sc_prevphase = INVALID_PHASE; /* ?? */
/* Do an implicit RESTORE POINTERS. */
sc->sc_dp = ecb->daddr;
sc->sc_dleft = ecb->dleft;
/* On our first connection, schedule a timeout. */
if ((ecb->xs->flags & SCSI_POLL) == 0)
timeout(esp_timeout, ecb, (ecb->timeout * hz) / 1000);
sc->sc_state = ESP_CONNECTED;
break;
} else {
kprintf("%s: unexpected status after select"
": [intr %x, stat %x, step %x]\n",
sc->sc_dev.dv_xname,
sc->sc_espintr, sc->sc_espstat,
sc->sc_espstep);
ESPCMD(sc, ESPCMD_FLUSH);
DELAY(1);
goto reset;
}
if (sc->sc_state == ESP_IDLE) {
kprintf("%s: stray interrupt\n", sc->sc_dev.dv_xname);
return 0;
}
break;
case ESP_CONNECTED:
if (sc->sc_flags & ESP_ICCS) {
u_char msg;
sc->sc_flags &= ~ESP_ICCS;
if (!(sc->sc_espintr & ESPINTR_DONE)) {
kprintf("%s: ICCS: "
": [intr %x, stat %x, step %x]\n",
sc->sc_dev.dv_xname,
sc->sc_espintr, sc->sc_espstat,
sc->sc_espstep);
}
if ((ESP_READ_REG(sc, ESP_FFLAG) & ESPFIFO_FF) != 2) {
int i = (ESP_READ_REG(sc, ESP_FFLAG) & ESPFIFO_FF) - 2;
while (i--)
(void) ESP_READ_REG(sc, ESP_FIFO);
}
ecb->stat = ESP_READ_REG(sc, ESP_FIFO);
msg = ESP_READ_REG(sc, ESP_FIFO);
ESP_PHASE(("<stat:(%x,%x)>", ecb->stat, msg));
if (msg == MSG_CMDCOMPLETE) {
ecb->xs->resid = ecb->dleft = sc->sc_dleft;
sc->sc_state = ESP_CMDCOMPLETE;
} else
kprintf("%s: STATUS_PHASE: msg %d\n",
sc->sc_dev.dv_xname, msg);
ESPCMD(sc, ESPCMD_MSGOK);
continue; /* ie. wait for disconnect */
}
break;
default:
panic("%s: invalid state: %d",
sc->sc_dev.dv_xname,
sc->sc_state);
}
/*
* Driver is now in state ESP_CONNECTED, i.e. we
* have a current command working the SCSI bus.
*/
if (sc->sc_state != ESP_CONNECTED || ecb == NULL) {
panic("esp no nexus");
}
switch (sc->sc_phase) {
case MESSAGE_OUT_PHASE:
ESP_PHASE(("MESSAGE_OUT_PHASE "));
esp_msgout(sc);
sc->sc_prevphase = MESSAGE_OUT_PHASE;
break;
case MESSAGE_IN_PHASE:
ESP_PHASE(("MESSAGE_IN_PHASE "));
if (sc->sc_espintr & ESPINTR_BS) {
ESPCMD(sc, ESPCMD_FLUSH);
sc->sc_flags |= ESP_WAITI;
ESPCMD(sc, ESPCMD_TRANS);
} else if (sc->sc_espintr & ESPINTR_FC) {
if ((sc->sc_flags & ESP_WAITI) == 0) {
kprintf("%s: MSGIN: unexpected FC bit: "
"[intr %x, stat %x, step %x]\n",
sc->sc_dev.dv_xname,
sc->sc_espintr, sc->sc_espstat,
sc->sc_espstep);
}
sc->sc_flags &= ~ESP_WAITI;
esp_msgin(sc);
} else {
kprintf("%s: MSGIN: weird bits: "
"[intr %x, stat %x, step %x]\n",
sc->sc_dev.dv_xname,
sc->sc_espintr, sc->sc_espstat,
sc->sc_espstep);
}
sc->sc_prevphase = MESSAGE_IN_PHASE;
break;
case COMMAND_PHASE: {
/* well, this means send the command again */
u_char *cmd = (u_char *)&ecb->cmd;
int i;
ESP_PHASE(("COMMAND_PHASE 0x%02x (%d) ",
ecb->cmd.opcode, ecb->clen));
if (ESP_READ_REG(sc, ESP_FFLAG) & ESPFIFO_FF) {
ESPCMD(sc, ESPCMD_FLUSH);
DELAY(1);
}
/* Now the command into the FIFO */
for (i = 0; i < ecb->clen; i++)
ESP_WRITE_REG(sc, ESP_FIFO, *cmd++);
ESPCMD(sc, ESPCMD_TRANS);
sc->sc_prevphase = COMMAND_PHASE;
}
break;
case DATA_OUT_PHASE:
ESP_PHASE(("DATA_OUT_PHASE [%d] ", sc->sc_dleft));
ESPCMD(sc, ESPCMD_FLUSH);
size = min(sc->sc_dleft, sc->sc_maxxfer);
DMA_SETUP(sc->sc_dma, &sc->sc_dp, &sc->sc_dleft,
0, &size);
sc->sc_prevphase = DATA_OUT_PHASE;
goto setup_xfer;
case DATA_IN_PHASE:
ESP_PHASE(("DATA_IN_PHASE "));
if (sc->sc_rev == ESP100)
ESPCMD(sc, ESPCMD_FLUSH);
size = min(sc->sc_dleft, sc->sc_maxxfer);
DMA_SETUP(sc->sc_dma, &sc->sc_dp, &sc->sc_dleft,
1, &size);
sc->sc_prevphase = DATA_IN_PHASE;
setup_xfer:
/* Program the SCSI counter */
ESP_WRITE_REG(sc, ESP_TCL, size);
ESP_WRITE_REG(sc, ESP_TCM, size >> 8);
if (sc->sc_cfg2 & ESPCFG2_FE) {
ESP_WRITE_REG(sc, ESP_TCH, size >> 16);
}
/* load the count in */
ESPCMD(sc, ESPCMD_NOP|ESPCMD_DMA);
/*
* Note that if `size' is 0, we've already transceived
* all the bytes we want but we're still in DATA PHASE.
* Apparently, the device needs padding. Also, a
* transfer size of 0 means "maximum" to the chip
* DMA logic.
*/
ESPCMD(sc,
(size==0?ESPCMD_TRPAD:ESPCMD_TRANS)|ESPCMD_DMA);
DMA_GO(sc->sc_dma);
return 1;
case STATUS_PHASE:
ESP_PHASE(("STATUS_PHASE "));
sc->sc_flags |= ESP_ICCS;
ESPCMD(sc, ESPCMD_ICCS);
sc->sc_prevphase = STATUS_PHASE;
break;
case INVALID_PHASE:
break;
default:
kprintf("%s: unexpected bus phase; resetting\n",
sc->sc_dev.dv_xname);
goto reset;
}
}
panic("esp: should not get here..");
reset:
esp_init(sc, 1);
return 1;
finish:
untimeout(esp_timeout, ecb);
esp_done(sc, ecb);
goto out;
sched:
sc->sc_state = ESP_IDLE;
esp_sched(sc);
goto out;
out:
return 1;
}
void
esp_abort(sc, ecb)
struct esp_softc *sc;
struct esp_ecb *ecb;
{
/* 2 secs for the abort */
ecb->timeout = ESP_ABORT_TIMEOUT;
ecb->flags |= ECB_ABORT;
if (ecb == sc->sc_nexus) {
/*
* If we're still selecting, the message will be scheduled
* after selection is complete.
*/
if (sc->sc_state == ESP_CONNECTED)
esp_sched_msgout(SEND_ABORT);
} else {
esp_dequeue(sc, ecb);
TAILQ_INSERT_HEAD(&sc->ready_list, ecb, chain);
if (sc->sc_state == ESP_IDLE)
esp_sched(sc);
}
}
void
esp_timeout(arg)
void *arg;
{
struct esp_ecb *ecb = arg;
struct scsi_xfer *xs = ecb->xs;
struct scsi_link *sc_link = xs->sc_link;
struct esp_softc *sc = sc_link->adapter_softc;
int s;
sc_print_addr(sc_link);
kprintf("%s: timed out [ecb %p (flags 0x%x, dleft %x, stat %x)], "
"<state %d, nexus %p, phase(c %x, p %x), resid %x, msg(q %x,o %x) %s>",
sc->sc_dev.dv_xname,
ecb, ecb->flags, ecb->dleft, ecb->stat,
sc->sc_state, sc->sc_nexus, sc->sc_phase, sc->sc_prevphase,
sc->sc_dleft, sc->sc_msgpriq, sc->sc_msgout,
DMA_ISACTIVE(sc->sc_dma) ? "DMA active" : "");
#if ESP_DEBUG > 0
kprintf("TRACE: %s.", ecb->trace);
#endif
s = splbio();
if (ecb->flags & ECB_ABORT) {
/* abort timed out */
kprintf(" AGAIN\n");
esp_init(sc, 1);
} else {
/* abort the operation that has timed out */
kprintf("\n");
xs->error = XS_TIMEOUT;
esp_abort(sc, ecb);
}
splx(s);
}