NetBSD-5.0.2/sys/dev/mvme/vme_two.c
/* $NetBSD: vme_two.c,v 1.7 2008/04/28 20:23:54 martin Exp $ */
/*-
* Copyright (c) 1999, 2002 The NetBSD Foundation, Inc.
* All rights reserved.
*
* This code is derived from software contributed to The NetBSD Foundation
* by Steve C. Woodford.
*
* 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.
*
* THIS SOFTWARE IS PROVIDED BY THE NETBSD FOUNDATION, INC. AND CONTRIBUTORS
* ``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 FOUNDATION OR CONTRIBUTORS
* 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.
*/
/*
* VME support specific to the VMEchip2 found on all high-end MVME boards
*/
#include <sys/cdefs.h>
__KERNEL_RCSID(0, "$NetBSD: vme_two.c,v 1.7 2008/04/28 20:23:54 martin Exp $");
#include "vmetwo.h"
#include <sys/param.h>
#include <sys/kernel.h>
#include <sys/systm.h>
#include <sys/device.h>
#include <sys/cpu.h>
#include <sys/bus.h>
#include <dev/vme/vmereg.h>
#include <dev/vme/vmevar.h>
#include <dev/mvme/mvmebus.h>
#include <dev/mvme/vme_tworeg.h>
#include <dev/mvme/vme_twovar.h>
void vmetwo_master_range(struct vmetwo_softc *, int, struct mvmebus_range *);
void vmetwo_slave_range(struct vmetwo_softc *, int, vme_am_t,
struct mvmebus_range *);
/* ARGSUSED */
void
vmetwo_init(sc)
struct vmetwo_softc *sc;
{
u_int32_t reg;
int i;
/* Initialise stuff for the common mvmebus front-end */
sc->sc_mvmebus.sc_chip = sc;
sc->sc_mvmebus.sc_nmasters = VME2_NMASTERS;
sc->sc_mvmebus.sc_masters = &sc->sc_master[0];
sc->sc_mvmebus.sc_nslaves = VME2_NSLAVES;
sc->sc_mvmebus.sc_slaves = &sc->sc_slave[0];
sc->sc_mvmebus.sc_intr_establish = vmetwo_intr_establish;
sc->sc_mvmebus.sc_intr_disestablish = vmetwo_intr_disestablish;
/* Initialise interrupts */
vmetwo_intr_init(sc);
reg = vme2_lcsr_read(sc, VME2LCSR_BOARD_CONTROL);
printf(": Type 2 VMEchip, scon jumper %s\n",
(reg & VME2_BOARD_CONTROL_SCON) ? "enabled" : "disabled");
/*
* Figure out what bits of the VMEbus we can access.
* First record the `fixed' maps (if they're enabled)
*/
reg = vme2_lcsr_read(sc, VME2LCSR_IO_CONTROL);
if (reg & VME2_IO_CONTROL_I1EN) {
/* This range is fixed to A16, DATA */
sc->sc_master[0].vr_am = VME_AM_A16 | MVMEBUS_AM_CAP_DATA;
/* However, SUPER/USER is selectable... */
if (reg & VME2_IO_CONTROL_I1SU)
sc->sc_master[0].vr_am |= MVMEBUS_AM_CAP_SUPER;
else
sc->sc_master[0].vr_am |= MVMEBUS_AM_CAP_USER;
/* As is the datasize */
sc->sc_master[0].vr_datasize = VME_D32 | VME_D16;
if (reg & VME2_IO_CONTROL_I1D16)
sc->sc_master[0].vr_datasize &= ~VME_D32;
sc->sc_master[0].vr_locstart = VME2_IO0_LOCAL_START;
sc->sc_master[0].vr_mask = VME2_IO0_MASK;
sc->sc_master[0].vr_vmestart = VME2_IO0_VME_START;
sc->sc_master[0].vr_vmeend = VME2_IO0_VME_END;
} else
sc->sc_master[0].vr_am = MVMEBUS_AM_DISABLED;
if (reg & VME2_IO_CONTROL_I2EN) {
/* These two ranges are fixed to A24D16 and A32D16 */
sc->sc_master[1].vr_am = VME_AM_A24;
sc->sc_master[1].vr_datasize = VME_D16;
sc->sc_master[2].vr_am = VME_AM_A32;
sc->sc_master[2].vr_datasize = VME_D16;
/* However, SUPER/USER is selectable */
if (reg & VME2_IO_CONTROL_I2SU) {
sc->sc_master[1].vr_am |= MVMEBUS_AM_CAP_SUPER;
sc->sc_master[2].vr_am |= MVMEBUS_AM_CAP_SUPER;
} else {
sc->sc_master[1].vr_am |= MVMEBUS_AM_CAP_USER;
sc->sc_master[2].vr_am |= MVMEBUS_AM_CAP_USER;
}
/* As is PROGRAM/DATA */
if (reg & VME2_IO_CONTROL_I2PD) {
sc->sc_master[1].vr_am |= MVMEBUS_AM_CAP_PROG;
sc->sc_master[2].vr_am |= MVMEBUS_AM_CAP_PROG;
} else {
sc->sc_master[1].vr_am |= MVMEBUS_AM_CAP_DATA;
sc->sc_master[2].vr_am |= MVMEBUS_AM_CAP_DATA;
}
sc->sc_master[1].vr_locstart = VME2_IO1_LOCAL_START;
sc->sc_master[1].vr_mask = VME2_IO1_MASK;
sc->sc_master[1].vr_vmestart = VME2_IO1_VME_START;
sc->sc_master[1].vr_vmeend = VME2_IO1_VME_END;
sc->sc_master[2].vr_locstart = VME2_IO2_LOCAL_START;
sc->sc_master[2].vr_mask = VME2_IO2_MASK;
sc->sc_master[2].vr_vmestart = VME2_IO2_VME_START;
sc->sc_master[2].vr_vmeend = VME2_IO2_VME_END;
} else {
sc->sc_master[1].vr_am = MVMEBUS_AM_DISABLED;
sc->sc_master[2].vr_am = MVMEBUS_AM_DISABLED;
}
/*
* Now read the progammable maps
*/
for (i = 0; i < VME2_MASTER_WINDOWS; i++)
vmetwo_master_range(sc, i,
&(sc->sc_master[i + VME2_MASTER_PROG_START]));
/* XXX: No A16 slave yet :XXX */
sc->sc_slave[VME2_SLAVE_A16].vr_am = MVMEBUS_AM_DISABLED;
for (i = 0; i < VME2_SLAVE_WINDOWS; i++) {
vmetwo_slave_range(sc, i, VME_AM_A32,
&sc->sc_slave[i + VME2_SLAVE_PROG_START]);
vmetwo_slave_range(sc, i, VME_AM_A24,
&sc->sc_slave[i + VME2_SLAVE_PROG_START + 2]);
}
mvmebus_attach(&sc->sc_mvmebus);
}
void
vmetwo_master_range(sc, range, vr)
struct vmetwo_softc *sc;
int range;
struct mvmebus_range *vr;
{
u_int32_t start, end, attr;
u_int32_t reg;
/*
* First, check if the range is actually enabled...
*/
reg = vme2_lcsr_read(sc, VME2LCSR_MASTER_ENABLE);
if ((reg & VME2_MASTER_ENABLE(range)) == 0) {
vr->vr_am = MVMEBUS_AM_DISABLED;
return;
}
/*
* Fetch and record the range's attributes
*/
attr = vme2_lcsr_read(sc, VME2LCSR_MASTER_ATTR);
attr >>= VME2_MASTER_ATTR_AM_SHIFT(range);
/*
* Fix up the datasizes available through this range
*/
vr->vr_datasize = VME_D32 | VME_D16;
if (attr & VME2_MASTER_ATTR_D16)
vr->vr_datasize &= ~VME_D32;
attr &= VME2_MASTER_ATTR_AM_MASK;
vr->vr_am = (attr & VME_AM_ADRSIZEMASK) | MVMEBUS_AM2CAP(attr);
switch (vr->vr_am & VME_AM_ADRSIZEMASK) {
case VME_AM_A32:
default:
vr->vr_mask = 0xffffffffu;
break;
case VME_AM_A24:
vr->vr_mask = 0x00ffffffu;
break;
case VME_AM_A16:
vr->vr_mask = 0x0000ffffu;
break;
}
/*
* XXX
* It would be nice if users of the MI VMEbus code could pass down
* whether they can tolerate Write-Posting to their device(s).
* XXX
*/
/*
* Fetch the local-bus start and end addresses for the range
*/
reg = vme2_lcsr_read(sc, VME2LCSR_MASTER_ADDRESS(range));
start = (reg & VME2_MAST_ADDRESS_START_MASK);
start <<= VME2_MAST_ADDRESS_START_SHIFT;
vr->vr_locstart = start & ~vr->vr_mask;
end = (reg & VME2_MAST_ADDRESS_END_MASK);
end <<= VME2_MAST_ADDRESS_END_SHIFT;
end |= 0xffffu;
end += 1;
/*
* Local->VMEbus map '4' has optional translation bits, so
* the VMEbus start and end addresses may need to be adjusted.
*/
if (range == 3 && (reg = vme2_lcsr_read(sc, VME2LCSR_MAST4_TRANS))!=0) {
uint32_t addr, sel, len = end - start;
reg = vme2_lcsr_read(sc, VME2LCSR_MAST4_TRANS);
reg &= VME2_MAST4_TRANS_SELECT_MASK;
sel = reg << VME2_MAST4_TRANS_SELECT_SHIFT;
reg = vme2_lcsr_read(sc, VME2LCSR_MAST4_TRANS);
reg &= VME2_MAST4_TRANS_ADDRESS_MASK;
addr = reg << VME2_MAST4_TRANS_ADDRESS_SHIFT;
start = (addr & sel) | (start & (~sel));
end = start + len;
vr->vr_mask &= len - 1;
}
/* XXX Deal with overlap of onboard RAM address space */
/* XXX Then again, 167-Bug warns about this at setup time ... */
/*
* Fixup the addresses this range corresponds to
*/
vr->vr_vmestart = start & vr->vr_mask;
vr->vr_vmeend = (end - 1) & vr->vr_mask;
}
void
vmetwo_slave_range(sc, range, am, vr)
struct vmetwo_softc *sc;
int range;
vme_am_t am;
struct mvmebus_range *vr;
{
u_int32_t reg;
/*
* First, check if the range is actually enabled.
* Note that bit 1 of `range' is used to indicte if we're
* looking for an A24 range (set) or an A32 range (clear).
*/
reg = vme2_lcsr_read(sc, VME2LCSR_SLAVE_CTRL);
if (am == VME_AM_A32 && (reg & VME2_SLAVE_AMSEL_A32(range))) {
vr->vr_am = VME_AM_A32;
vr->vr_mask = 0xffffffffu;
} else
if (am == VME_AM_A24 && (reg & VME2_SLAVE_AMSEL_A24(range))) {
vr->vr_am = VME_AM_A24;
vr->vr_mask = 0x00ffffffu;
} else {
/* The range is not enabled */
vr->vr_am = MVMEBUS_AM_DISABLED;
return;
}
if ((reg & VME2_SLAVE_AMSEL_DAT(range)) != 0)
vr->vr_am |= MVMEBUS_AM_CAP_DATA;
if ((reg & VME2_SLAVE_AMSEL_PGM(range)) != 0)
vr->vr_am |= MVMEBUS_AM_CAP_PROG;
if ((reg & VME2_SLAVE_AMSEL_USR(range)) != 0)
vr->vr_am |= MVMEBUS_AM_CAP_USER;
if ((reg & VME2_SLAVE_AMSEL_SUP(range)) != 0)
vr->vr_am |= MVMEBUS_AM_CAP_SUPER;
if ((reg & VME2_SLAVE_AMSEL_BLK(range)) != 0)
vr->vr_am |= MVMEBUS_AM_CAP_BLK;
if ((reg & VME2_SLAVE_AMSEL_BLKD64(range)) != 0)
vr->vr_am |= MVMEBUS_AM_CAP_BLKD64;
vr->vr_datasize = VME_D32 | VME_D16 | VME_D8;
/*
* Record the VMEbus start and end addresses of the slave image
*/
reg = vme2_lcsr_read(sc, VME2LCSR_SLAVE_ADDRESS(range));
vr->vr_vmestart = reg & VME2_SLAVE_ADDRESS_START_MASK;
vr->vr_vmestart <<= VME2_SLAVE_ADDRESS_START_SHIFT;
vr->vr_vmestart &= vr->vr_mask;
vr->vr_vmeend = reg & VME2_SLAVE_ADDRESS_END_MASK;
vr->vr_vmeend <<= VME2_SLAVE_ADDRESS_END_SHIFT;
vr->vr_vmeend &= vr->vr_mask;
vr->vr_vmeend |= 0xffffu;
/*
* Now figure out the local-bus address
*/
reg = vme2_lcsr_read(sc, VME2LCSR_SLAVE_CTRL);
if ((reg & VME2_SLAVE_CTRL_ADDER(range)) != 0) {
reg = vme2_lcsr_read(sc, VME2LCSR_SLAVE_TRANS(range));
reg &= VME2_SLAVE_TRANS_ADDRESS_MASK;
reg <<= VME2_SLAVE_TRANS_ADDRESS_SHIFT;
vr->vr_locstart = vr->vr_vmestart + reg;
} else {
u_int32_t sel, addr;
reg = vme2_lcsr_read(sc, VME2LCSR_SLAVE_TRANS(range));
sel = reg & VME2_SLAVE_TRANS_SELECT_MASK;
sel <<= VME2_SLAVE_TRANS_SELECT_SHIFT;
addr = reg & VME2_SLAVE_TRANS_ADDRESS_MASK;
addr <<= VME2_SLAVE_TRANS_ADDRESS_SHIFT;
vr->vr_locstart = addr & sel;
vr->vr_locstart |= vr->vr_vmestart & (~sel);
}
}