NetBSD-5.0.2/sys/arch/sgimips/hpc/hpc.c
/* $NetBSD: hpc.c,v 1.60 2007/10/17 19:57:04 garbled Exp $ */
/*
* Copyright (c) 2000 Soren S. Jorvang
* Copyright (c) 2001 Rafal K. Boni
* Copyright (c) 2001 Jason R. Thorpe
* 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 for the
* NetBSD Project. See http://www.NetBSD.org/ for
* information about NetBSD.
* 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.
*/
#include <sys/cdefs.h>
__KERNEL_RCSID(0, "$NetBSD: hpc.c,v 1.60 2007/10/17 19:57:04 garbled Exp $");
#include <sys/param.h>
#include <sys/systm.h>
#include <sys/kernel.h>
#include <sys/device.h>
#include <sys/reboot.h>
#include <sys/callout.h>
#define _SGIMIPS_BUS_DMA_PRIVATE
#include <machine/bus.h>
#include <machine/machtype.h>
#include <machine/sysconf.h>
#include <sgimips/gio/gioreg.h>
#include <sgimips/gio/giovar.h>
#include <sgimips/hpc/hpcvar.h>
#include <sgimips/hpc/hpcreg.h>
#include <sgimips/ioc/iocreg.h>
#include <dev/ic/smc93cx6var.h>
#include "locators.h"
struct hpc_device {
const char *hd_name;
bus_addr_t hd_base;
bus_addr_t hd_devoff;
bus_addr_t hd_dmaoff;
int hd_irq;
int hd_sysmask;
};
static const struct hpc_device hpc1_devices[] = {
/* probe order is important for IP20 zsc */
{ "zsc", /* Personal Iris/Indigo serial 0/1 duart 1 */
HPC_BASE_ADDRESS_0,
0x0d10, 0,
5,
HPCDEV_IP12 | HPCDEV_IP20 },
{ "zsc", /* Personal Iris/Indigo kbd/ms duart 0 */
HPC_BASE_ADDRESS_0,
0x0d00, 0,
5,
HPCDEV_IP12 | HPCDEV_IP20 },
{ "sq", /* Personal Iris/Indigo onboard ethernet */
HPC_BASE_ADDRESS_0,
HPC1_ENET_DEVREGS, HPC1_ENET_REGS,
3,
HPCDEV_IP12 | HPCDEV_IP20 },
{ "sq", /* E++ GIO adapter slot 0 (Indigo) */
HPC_BASE_ADDRESS_1,
HPC1_ENET_DEVREGS, HPC1_ENET_REGS,
6,
HPCDEV_IP12 | HPCDEV_IP20 },
{ "sq", /* E++ GIO adapter slot 0 (Indy) */
HPC_BASE_ADDRESS_1,
HPC1_ENET_DEVREGS, HPC1_ENET_REGS,
22,
HPCDEV_IP24 },
{ "sq", /* E++ GIO adapter slot 1 (Indigo) */
HPC_BASE_ADDRESS_2,
HPC1_ENET_DEVREGS, HPC1_ENET_REGS,
6,
HPCDEV_IP12 | HPCDEV_IP20 },
{ "sq", /* E++ GIO adapter slot 1 (Indy/Challenge S) */
HPC_BASE_ADDRESS_2,
HPC1_ENET_DEVREGS, HPC1_ENET_REGS,
23,
HPCDEV_IP24 },
{ "wdsc", /* Personal Iris/Indigo onboard SCSI */
HPC_BASE_ADDRESS_0,
HPC1_SCSI0_DEVREGS, HPC1_SCSI0_REGS,
2, /* XXX 1 = IRQ_LOCAL0 + 2 */
HPCDEV_IP12 | HPCDEV_IP20 },
{ "wdsc", /* GIO32 SCSI adapter slot 0 (Indigo) */
HPC_BASE_ADDRESS_1,
HPC1_SCSI0_DEVREGS, HPC1_SCSI0_REGS,
6,
HPCDEV_IP12 | HPCDEV_IP20 },
{ "wdsc", /* GIO32 SCSI adapter slot 0 (Indy) */
HPC_BASE_ADDRESS_1,
HPC1_SCSI0_DEVREGS, HPC1_SCSI0_REGS,
22,
HPCDEV_IP24 },
{ "wdsc", /* GIO32 SCSI adapter slot 1 (Indigo) */
HPC_BASE_ADDRESS_2,
HPC1_SCSI0_DEVREGS, HPC1_SCSI0_REGS,
6,
HPCDEV_IP12 | HPCDEV_IP20 },
{ "wdsc", /* GIO32 SCSI adapter slot 1 (Indy/Challenge S) */
HPC_BASE_ADDRESS_2,
HPC1_SCSI0_DEVREGS, HPC1_SCSI0_REGS,
23,
HPCDEV_IP24 },
{ "dpclock", /* Personal Iris/Indigo clock */
HPC_BASE_ADDRESS_0,
HPC1_PBUS_BBRAM, 0,
-1,
HPCDEV_IP12 | HPCDEV_IP20 },
{ NULL,
0,
0, 0,
0,
0
}
};
static const struct hpc_device hpc3_devices[] = {
{ "zsc", /* serial 0/1 duart 0 */
HPC_BASE_ADDRESS_0,
/* XXX Magic numbers */
HPC3_PBUS_CH6_DEVREGS + IOC_SERIAL_REGS, 0,
29,
HPCDEV_IP22 | HPCDEV_IP24 },
{ "pckbc", /* Indigo2/Indy ps2 keyboard/mouse controller */
HPC_BASE_ADDRESS_0,
HPC3_PBUS_CH6_DEVREGS + IOC_KB_REGS, 0,
28,
HPCDEV_IP22 | HPCDEV_IP24 },
{ "sq", /* Indigo2/Indy/Challenge S/Challenge M onboard enet */
HPC_BASE_ADDRESS_0,
HPC3_ENET_DEVREGS, HPC3_ENET_REGS,
3,
HPCDEV_IP22 | HPCDEV_IP24 },
{ "sq", /* Challenge S IOPLUS secondary ethernet */
HPC_BASE_ADDRESS_1,
HPC3_ENET_DEVREGS, HPC3_ENET_REGS,
0,
HPCDEV_IP24 },
{ "wdsc", /* Indigo2/Indy/Challenge S/Challenge M onboard SCSI */
HPC_BASE_ADDRESS_0,
HPC3_SCSI0_DEVREGS, HPC3_SCSI0_REGS,
1, /* XXX 1 = IRQ_LOCAL0 + 1 */
HPCDEV_IP22 | HPCDEV_IP24 },
{ "wdsc", /* Indigo2/Challenge M secondary onboard SCSI */
HPC_BASE_ADDRESS_0,
HPC3_SCSI1_DEVREGS, HPC3_SCSI1_REGS,
2, /* XXX 2 = IRQ_LOCAL0 + 2 */
HPCDEV_IP22 },
{ "dsclock", /* Indigo2/Indy/Challenge S/Challenge M clock */
HPC_BASE_ADDRESS_0,
HPC3_PBUS_BBRAM, 0,
-1,
HPCDEV_IP22 | HPCDEV_IP24 },
{ "haltwo", /* Indigo2/Indy onboard audio */
HPC_BASE_ADDRESS_0,
HPC3_PBUS_CH0_DEVREGS, HPC3_PBUS_DMAREGS,
8 + 4, /* XXX IRQ_LOCAL1 + 4 */
HPCDEV_IP22 | HPCDEV_IP24 },
{ "pi1ppc", /* Indigo2/Indy/Challenge S/Challenge M onboard pport */
HPC_BASE_ADDRESS_0,
HPC3_PBUS_CH6_DEVREGS + IOC_PLP_REGS, 0,
-1,
HPCDEV_IP22 | HPCDEV_IP24 },
{ NULL,
0,
0, 0,
0,
0
}
};
struct hpc_softc {
struct device sc_dev;
bus_addr_t sc_base;
bus_space_tag_t sc_ct;
bus_space_handle_t sc_ch;
};
static struct hpc_values hpc1_values = {
.revision = 1,
.scsi0_regs = HPC1_SCSI0_REGS,
.scsi0_regs_size = HPC1_SCSI0_REGS_SIZE,
.scsi0_cbp = HPC1_SCSI0_CBP,
.scsi0_ndbp = HPC1_SCSI0_NDBP,
.scsi0_bc = HPC1_SCSI0_BC,
.scsi0_ctl = HPC1_SCSI0_CTL,
.scsi0_gio = HPC1_SCSI0_GIO,
.scsi0_dev = HPC1_SCSI0_DEV,
.scsi0_dmacfg = HPC1_SCSI0_DMACFG,
.scsi0_piocfg = HPC1_SCSI0_PIOCFG,
.scsi1_regs = 0,
.scsi1_regs_size = 0,
.scsi1_cbp = 0,
.scsi1_ndbp = 0,
.scsi1_bc = 0,
.scsi1_ctl = 0,
.scsi1_gio = 0,
.scsi1_dev = 0,
.scsi1_dmacfg = 0,
.scsi1_piocfg = 0,
.enet_regs = HPC1_ENET_REGS,
.enet_regs_size = HPC1_ENET_REGS_SIZE,
.enet_intdelay = HPC1_ENET_INTDELAY,
.enet_intdelayval = HPC1_ENET_INTDELAY_OFF,
.enetr_cbp = HPC1_ENETR_CBP,
.enetr_ndbp = HPC1_ENETR_NDBP,
.enetr_bc = HPC1_ENETR_BC,
.enetr_ctl = HPC1_ENETR_CTL,
.enetr_ctl_active = HPC1_ENETR_CTL_ACTIVE,
.enetr_reset = HPC1_ENETR_RESET,
.enetr_dmacfg = 0,
.enetr_piocfg = 0,
.enetx_cbp = HPC1_ENETX_CBP,
.enetx_ndbp = HPC1_ENETX_NDBP,
.enetx_bc = HPC1_ENETX_BC,
.enetx_ctl = HPC1_ENETX_CTL,
.enetx_ctl_active = HPC1_ENETX_CTL_ACTIVE,
.enetx_dev = 0,
.enetr_fifo = HPC1_ENETR_FIFO,
.enetr_fifo_size = HPC1_ENETR_FIFO_SIZE,
.enetx_fifo = HPC1_ENETX_FIFO,
.enetx_fifo_size = HPC1_ENETX_FIFO_SIZE,
.scsi0_devregs_size = HPC1_SCSI0_DEVREGS_SIZE,
.scsi1_devregs_size = 0,
.enet_devregs = HPC1_ENET_DEVREGS,
.enet_devregs_size = HPC1_ENET_DEVREGS_SIZE,
.pbus_fifo = 0,
.pbus_fifo_size = 0,
.pbus_bbram = 0,
#define MAX_SCSI_XFER (512*1024)
.scsi_max_xfer = MAX_SCSI_XFER,
.scsi_dma_segs = (MAX_SCSI_XFER / 4096),
.scsi_dma_segs_size = 4096,
.scsi_dma_datain_cmd = (HPC1_SCSI_DMACTL_ACTIVE | HPC1_SCSI_DMACTL_DIR),
.scsi_dma_dataout_cmd = HPC1_SCSI_DMACTL_ACTIVE,
.scsi_dmactl_flush = HPC1_SCSI_DMACTL_FLUSH,
.scsi_dmactl_active = HPC1_SCSI_DMACTL_ACTIVE,
.scsi_dmactl_reset = HPC1_SCSI_DMACTL_RESET
};
static struct hpc_values hpc3_values = {
.revision = 3,
.scsi0_regs = HPC3_SCSI0_REGS,
.scsi0_regs_size = HPC3_SCSI0_REGS_SIZE,
.scsi0_cbp = HPC3_SCSI0_CBP,
.scsi0_ndbp = HPC3_SCSI0_NDBP,
.scsi0_bc = HPC3_SCSI0_BC,
.scsi0_ctl = HPC3_SCSI0_CTL,
.scsi0_gio = HPC3_SCSI0_GIO,
.scsi0_dev = HPC3_SCSI0_DEV,
.scsi0_dmacfg = HPC3_SCSI0_DMACFG,
.scsi0_piocfg = HPC3_SCSI0_PIOCFG,
.scsi1_regs = HPC3_SCSI1_REGS,
.scsi1_regs_size = HPC3_SCSI1_REGS_SIZE,
.scsi1_cbp = HPC3_SCSI1_CBP,
.scsi1_ndbp = HPC3_SCSI1_NDBP,
.scsi1_bc = HPC3_SCSI1_BC,
.scsi1_ctl = HPC3_SCSI1_CTL,
.scsi1_gio = HPC3_SCSI1_GIO,
.scsi1_dev = HPC3_SCSI1_DEV,
.scsi1_dmacfg = HPC3_SCSI1_DMACFG,
.scsi1_piocfg = HPC3_SCSI1_PIOCFG,
.enet_regs = HPC3_ENET_REGS,
.enet_regs_size = HPC3_ENET_REGS_SIZE,
.enet_intdelay = 0,
.enet_intdelayval = 0,
.enetr_cbp = HPC3_ENETR_CBP,
.enetr_ndbp = HPC3_ENETR_NDBP,
.enetr_bc = HPC3_ENETR_BC,
.enetr_ctl = HPC3_ENETR_CTL,
.enetr_ctl_active = HPC3_ENETR_CTL_ACTIVE,
.enetr_reset = HPC3_ENETR_RESET,
.enetr_dmacfg = HPC3_ENETR_DMACFG,
.enetr_piocfg = HPC3_ENETR_PIOCFG,
.enetx_cbp = HPC3_ENETX_CBP,
.enetx_ndbp = HPC3_ENETX_NDBP,
.enetx_bc = HPC3_ENETX_BC,
.enetx_ctl = HPC3_ENETX_CTL,
.enetx_ctl_active = HPC3_ENETX_CTL_ACTIVE,
.enetx_dev = HPC3_ENETX_DEV,
.enetr_fifo = HPC3_ENETR_FIFO,
.enetr_fifo_size = HPC3_ENETR_FIFO_SIZE,
.enetx_fifo = HPC3_ENETX_FIFO,
.enetx_fifo_size = HPC3_ENETX_FIFO_SIZE,
.scsi0_devregs_size = HPC3_SCSI0_DEVREGS_SIZE,
.scsi1_devregs_size = HPC3_SCSI1_DEVREGS_SIZE,
.enet_devregs = HPC3_ENET_DEVREGS,
.enet_devregs_size = HPC3_ENET_DEVREGS_SIZE,
.pbus_fifo = HPC3_PBUS_FIFO,
.pbus_fifo_size = HPC3_PBUS_FIFO_SIZE,
.pbus_bbram = HPC3_PBUS_BBRAM,
.scsi_max_xfer = MAX_SCSI_XFER,
.scsi_dma_segs = (MAX_SCSI_XFER / 8192),
.scsi_dma_segs_size = 8192,
.scsi_dma_datain_cmd = HPC3_SCSI_DMACTL_ACTIVE,
.scsi_dma_dataout_cmd =(HPC3_SCSI_DMACTL_ACTIVE | HPC3_SCSI_DMACTL_DIR),
.scsi_dmactl_flush = HPC3_SCSI_DMACTL_FLUSH,
.scsi_dmactl_active = HPC3_SCSI_DMACTL_ACTIVE,
.scsi_dmactl_reset = HPC3_SCSI_DMACTL_RESET
};
static int powerintr_established;
static int hpc_match(struct device *, struct cfdata *, void *);
static void hpc_attach(struct device *, struct device *, void *);
static int hpc_print(void *, const char *);
static int hpc_revision(struct hpc_softc *, struct gio_attach_args *);
static int hpc_submatch(struct device *, struct cfdata *,
const int *, void *);
//static int hpc_power_intr(void *);
#if defined(BLINK)
static callout_t hpc_blink_ch;
static void hpc_blink(void *);
#endif
static int hpc_read_eeprom(int, bus_space_tag_t, bus_space_handle_t,
uint8_t *, size_t);
CFATTACH_DECL(hpc, sizeof(struct hpc_softc),
hpc_match, hpc_attach, NULL, NULL);
static int
hpc_match(struct device *parent, struct cfdata *cf, void *aux)
{
struct gio_attach_args* ga = aux;
/* Make sure it's actually there and readable */
if (platform.badaddr((void*)MIPS_PHYS_TO_KSEG1(ga->ga_addr),
sizeof(u_int32_t)))
return 0;
return 1;
}
static void
hpc_attach(struct device *parent, struct device *self, void *aux)
{
struct hpc_softc *sc = (struct hpc_softc *)self;
struct gio_attach_args* ga = aux;
struct hpc_attach_args ha;
const struct hpc_device *hd;
uint32_t hpctype;
int isonboard;
int isioplus;
int sysmask;
#ifdef BLINK
callout_init(&hpc_blink_ch, 0);
#endif
switch (mach_type) {
case MACH_SGI_IP12:
sysmask = HPCDEV_IP12;
break;
case MACH_SGI_IP20:
sysmask = HPCDEV_IP20;
break;
case MACH_SGI_IP22:
if (mach_subtype == MACH_SGI_IP22_FULLHOUSE)
sysmask = HPCDEV_IP22;
else
sysmask = HPCDEV_IP24;
break;
default:
panic("hpc_attach: can't handle HPC on an IP%d", mach_type);
};
if ((hpctype = hpc_revision(sc, ga)) == 0)
panic("hpc_attach: could not identify HPC revision\n");
/* force big-endian mode */
if (hpctype == 15)
*(uint32_t *)MIPS_PHYS_TO_KSEG1(ga->ga_addr+HPC1_BIGENDIAN) = 0;
/*
* All machines have only one HPC on the mainboard itself. ''Extra''
* HPCs require bus arbiter and other magic to run happily.
*/
isonboard = (ga->ga_addr == HPC_BASE_ADDRESS_0);
isioplus = (ga->ga_addr == HPC_BASE_ADDRESS_1 && hpctype == 3 &&
sysmask == HPCDEV_IP24);
printf(": SGI HPC%d%s (%s)\n", (hpctype == 3) ? 3 : 1,
(hpctype == 15) ? ".5" : "", (isonboard) ? "onboard" :
(isioplus) ? "IOPLUS mezzanine" : "GIO slot");
/*
* Configure the bus arbiter appropriately.
*
* In the case of Challenge S, we must tell the IOPLUS board which
* DMA channel to use (we steal it from one of the slots). SGI permits
* an HPC1.5 in slot 1, in which case IOPLUS must use EXP0, or any
* other DMA-capable board in slot 0, which leaves us to use EXP1. Of
* course, this means that only one GIO board may use DMA.
*
* Note that this never happens on Indigo2.
*/
if (isioplus) {
int arb_slot;
if (platform.badaddr(
(void *)MIPS_PHYS_TO_KSEG1(HPC_BASE_ADDRESS_2), 4))
arb_slot = GIO_SLOT_EXP1;
else
arb_slot = GIO_SLOT_EXP0;
if (gio_arb_config(arb_slot, GIO_ARB_LB | GIO_ARB_MST |
GIO_ARB_64BIT | GIO_ARB_HPC2_64BIT)) {
printf("%s: failed to configure GIO bus arbiter\n",
sc->sc_dev.dv_xname);
return;
}
printf("%s: using EXP%d's DMA channel\n", sc->sc_dev.dv_xname,
(arb_slot == GIO_SLOT_EXP0) ? 0 : 1);
bus_space_write_4(ga->ga_iot, ga->ga_ioh,
HPC3_PBUS_CFGPIO_REGS, 0x0003ffff);
if (arb_slot == GIO_SLOT_EXP0)
bus_space_write_4(ga->ga_iot, ga->ga_ioh,
HPC3_PBUS_CH0_DEVREGS, 0x20202020);
else
bus_space_write_4(ga->ga_iot, ga->ga_ioh,
HPC3_PBUS_CH0_DEVREGS, 0x30303030);
} else if (!isonboard) {
int arb_slot;
arb_slot = (ga->ga_addr == HPC_BASE_ADDRESS_1) ?
GIO_SLOT_EXP0 : GIO_SLOT_EXP1;
if (gio_arb_config(arb_slot, GIO_ARB_RT | GIO_ARB_MST)) {
printf("%s: failed to configure GIO bus arbiter\n",
sc->sc_dev.dv_xname);
return;
}
}
sc->sc_ct = SGIMIPS_BUS_SPACE_HPC;
sc->sc_ch = ga->ga_ioh;
sc->sc_base = ga->ga_addr;
hpc_read_eeprom(hpctype, SGIMIPS_BUS_SPACE_HPC,
MIPS_PHYS_TO_KSEG1(sc->sc_base), ha.hpc_eeprom,
sizeof(ha.hpc_eeprom));
hd = (hpctype == 3) ? hpc3_devices : hpc1_devices;
for (; hd->hd_name != NULL; hd++) {
if (!(hd->hd_sysmask & sysmask) || hd->hd_base != sc->sc_base)
continue;
ha.ha_name = hd->hd_name;
ha.ha_devoff = hd->hd_devoff;
ha.ha_dmaoff = hd->hd_dmaoff;
ha.ha_irq = hd->hd_irq;
/* XXX This is disgusting. */
ha.ha_st = SGIMIPS_BUS_SPACE_HPC;
ha.ha_sh = MIPS_PHYS_TO_KSEG1(sc->sc_base);
ha.ha_dmat = &sgimips_default_bus_dma_tag;
if (hpctype == 3)
ha.hpc_regs = &hpc3_values;
else
ha.hpc_regs = &hpc1_values;
ha.hpc_regs->revision = hpctype;
/* XXXgross! avoid complaining in E++ and GIO32 SCSI cases */
if (hpctype != 3 && sc->sc_base != HPC_BASE_ADDRESS_0) {
(void)config_found_sm_loc(self, "hpc", NULL, &ha,
NULL, hpc_submatch);
} else {
(void)config_found_sm_loc(self, "hpc", NULL, &ha,
hpc_print, hpc_submatch);
}
}
/*
* XXX: Only attach the powerfail interrupt once, since the
* interrupt code doesn't let you share interrupt just yet.
*
* Since the powerfail interrupt is hardcoded to read from
* a specific register anyway (XXX#2!), we don't care when
* it gets attached, as long as it only happens once.
*/
if (mach_type == MACH_SGI_IP22 && !powerintr_established) {
// cpu_intr_establish(9, IPL_NONE, hpc_power_intr, sc);
powerintr_established++;
}
#if defined(BLINK)
if (mach_type == MACH_SGI_IP12 || mach_type == MACH_SGI_IP20)
hpc_blink(sc);
#endif
}
/*
* HPC revision detection isn't as simple as it should be. Devices probe
* differently depending on their slots, but luckily there is only one
* instance in which we have to decide the major revision (HPC1 vs HPC3).
*
* The HPC is found in the following configurations:
* o Personal Iris 4D/3x:
* One on-board HPC1 or HPC1.5.
*
* o Indigo R3k/R4k:
* One on-board HPC1 or HPC1.5.
* Up to two additional HPC1.5's in GIO slots 0 and 1.
*
* o Indy:
* One on-board HPC3.
* Up to two additional HPC1.5's in GIO slots 0 and 1.
*
* o Challenge S
* One on-board HPC3.
* Up to one additional HPC3 on the IOPLUS board (if installed).
* Up to one additional HPC1.5 in slot 1 of the IOPLUS board.
*
* o Indigo2, Challenge M
* One on-board HPC3.
*
* All we really have to worry about is the IP22 case.
*/
static int
hpc_revision(struct hpc_softc *sc, struct gio_attach_args *ga)
{
/* No hardware ever supported the last hpc base address. */
if (ga->ga_addr == HPC_BASE_ADDRESS_3)
return (0);
if (mach_type == MACH_SGI_IP12 || mach_type == MACH_SGI_IP20) {
u_int32_t reg;
if (!platform.badaddr((void *)MIPS_PHYS_TO_KSEG1(ga->ga_addr +
HPC1_BIGENDIAN), 4)) {
reg = *(uint32_t *)MIPS_PHYS_TO_KSEG1(ga->ga_addr +
HPC1_BIGENDIAN);
if (((reg >> HPC1_REVSHIFT) & HPC1_REVMASK) ==
HPC1_REV15)
return (15);
else
return (1);
}
return (1);
}
/*
* If IP22, probe slot 0 to determine if HPC1.5 or HPC3. Slot 1 must
* be HPC1.5.
*/
if (mach_type == MACH_SGI_IP22) {
if (ga->ga_addr == HPC_BASE_ADDRESS_0)
return (3);
if (ga->ga_addr == HPC_BASE_ADDRESS_2)
return (15);
/*
* Probe for it. We use one of the PBUS registers. Note
* that this probe succeeds with my E++ adapter in slot 1
* (bad), but it appears to always do the right thing in
* slot 0 (good!) and we're only worried about that one
* anyhow.
*/
if (platform.badaddr((void *)MIPS_PHYS_TO_KSEG1(ga->ga_addr +
HPC3_PBUS_CH7_BP), 4))
return (15);
else
return (3);
}
return (0);
}
static int
hpc_submatch(struct device *parent, struct cfdata *cf,
const int *ldesc, void *aux)
{
struct hpc_attach_args *ha = aux;
if (cf->cf_loc[HPCCF_OFFSET] != HPCCF_OFFSET_DEFAULT &&
(bus_addr_t) cf->cf_loc[HPCCF_OFFSET] != ha->ha_devoff)
return (0);
return (config_match(parent, cf, aux));
}
static int
hpc_print(void *aux, const char *pnp)
{
struct hpc_attach_args *ha = aux;
if (pnp)
printf("%s at %s", ha->ha_name, pnp);
printf(" offset 0x%lx", (vaddr_t)ha->ha_devoff);
return (UNCONF);
}
#if 0
static int
hpc_power_intr(void *arg)
{
u_int32_t pwr_reg;
pwr_reg = *((volatile u_int32_t *)MIPS_PHYS_TO_KSEG1(0x1fbd9850));
*((volatile u_int32_t *)MIPS_PHYS_TO_KSEG1(0x1fbd9850)) = pwr_reg;
printf("hpc_power_intr: panel reg = %08x\n", pwr_reg);
if (pwr_reg & 2)
cpu_reboot(RB_HALT, NULL);
return 1;
}
#endif
#if defined(BLINK)
static void
hpc_blink(void *self)
{
struct hpc_softc *sc = (struct hpc_softc *) self;
register int s;
int value;
s = splhigh();
value = *(volatile uint8_t *)MIPS_PHYS_TO_KSEG1(HPC_BASE_ADDRESS_0 +
HPC1_AUX_REGS);
value ^= HPC1_AUX_CONSLED;
*(volatile u_int8_t *)MIPS_PHYS_TO_KSEG1(HPC_BASE_ADDRESS_0 +
HPC1_AUX_REGS) = value;
splx(s);
/*
* Blink rate is:
* full cycle every second if completely idle (loadav = 0)
* full cycle every 2 seconds if loadav = 1
* full cycle every 3 seconds if loadav = 2
* etc.
*/
s = (((averunnable.ldavg[0] + FSCALE) * hz) >> (FSHIFT + 1));
callout_reset(&hpc_blink_ch, s, hpc_blink, sc);
}
#endif
/*
* Read the eeprom associated with one of the HPC's.
*
* NB: An eeprom is not always present, but the HPC should be able to
* handle this gracefully. Any consumers should validate the data to
* ensure it's reasonable.
*/
static int
hpc_read_eeprom(int hpctype, bus_space_tag_t t, bus_space_handle_t h,
uint8_t *buf, size_t len)
{
struct seeprom_descriptor sd;
bus_space_handle_t bsh;
bus_space_tag_t tag;
bus_size_t offset;
if (!len || len & 0x1)
return (1);
offset = (hpctype == 3) ? HPC3_EEPROM_DATA : HPC1_AUX_REGS;
tag = SGIMIPS_BUS_SPACE_NORMAL;
if (bus_space_subregion(t, h, offset, 1, &bsh) != 0)
return (1);
sd.sd_chip = C56_66;
sd.sd_tag = tag;
sd.sd_bsh = bsh;
sd.sd_regsize = 1;
sd.sd_control_offset = 0;
sd.sd_status_offset = 0;
sd.sd_dataout_offset = 0;
sd.sd_DI = 0x10; /* EEPROM -> CPU */
sd.sd_DO = 0x08; /* CPU -> EEPROM */
sd.sd_CK = 0x04;
sd.sd_CS = 0x02;
sd.sd_MS = 0;
sd.sd_RDY = 0;
if (read_seeprom(&sd, (uint16_t *)buf, 0, len / 2) != 1)
return (1);
bus_space_unmap(t, bsh, 1);
return (0);
}