dev/pci/pciconf.c

1.1  briggs /*	$NetBSD: pciconf.c,v 1.1 2001/02/09 14:33:15 briggs Exp $	*/
1.1  briggs
1.1  briggs /*
1.1  briggs  * Copyright 2001 Wasabi Systems, Inc.
1.1  briggs  * All rights reserved.
1.1  briggs  *
1.1  briggs  * Written by Allen Briggs for Wasabi Systems, Inc.
1.1  briggs  *
1.1  briggs  * Redistribution and use in source and binary forms, with or without
1.1  briggs  * modification, are permitted provided that the following conditions
1.1  briggs  * are met:
1.1  briggs  * 1. Redistributions of source code must retain the above copyright
1.1  briggs  *    notice, this list of conditions and the following disclaimer.
1.1  briggs  * 2. Redistributions in binary form must reproduce the above copyright
1.1  briggs  *    notice, this list of conditions and the following disclaimer in the
1.1  briggs  *    documentation and/or other materials provided with the distribution.
1.1  briggs  * 3. All advertising materials mentioning features or use of this software
1.1  briggs  *    must display the following acknowledgement:
1.1  briggs  *      This product includes software developed for the NetBSD Project by
1.1  briggs  *      Wasabi Systems, Inc.
1.1  briggs  * 4. The name of Wasabi Systems, Inc. may not be used to endorse
1.1  briggs  *    or promote products derived from this software without specific prior
1.1  briggs  *    written permission.
1.1  briggs  *
1.1  briggs  * THIS SOFTWARE IS PROVIDED BY WASABI SYSTEMS, INC. ``AS IS'' AND
1.1  briggs  * ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED
1.1  briggs  * TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR
1.1  briggs  * PURPOSE ARE DISCLAIMED.  IN NO EVENT SHALL WASABI SYSTEMS, INC
1.1  briggs  * BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR
1.1  briggs  * CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF
1.1  briggs  * SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS
1.1  briggs  * INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN
1.1  briggs  * CONTRACT, STRICT LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE)
1.1  briggs  * ARISING IN ANY WAY OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE
1.1  briggs  * POSSIBILITY OF SUCH DAMAGE.
1.1  briggs  */
1.1  briggs /*
1.1  briggs  * Derived in part from code from PMON/2000 (http://pmon.groupbsd.org/).
1.1  briggs  */
1.1  briggs
1.1  briggs #include "opt_pci.h"
1.1  briggs
1.1  briggs #include <sys/param.h>
1.1  briggs #include <sys/extent.h>
1.1  briggs #include <sys/queue.h>
1.1  briggs #include <sys/systm.h>
1.1  briggs #include <sys/malloc.h>
1.1  briggs
1.1  briggs #include <dev/pci/pcivar.h>
1.1  briggs #include <dev/pci/pciconf.h>
1.1  briggs #include <dev/pci/pcidevs.h>
1.1  briggs
1.1  briggs #ifdef PCI_CONFIGURATION_DEBUG
1.1  briggs int pci_conf_debug = 0;
1.1  briggs #endif
1.1  briggs
1.1  briggs #if !defined(MIN)
1.1  briggs #define	MIN(a,b) (((a)<(b))?(a):(b))
1.1  briggs #define	MAX(a,b) (((a)>(b))?(a):(b))
1.1  briggs #endif
1.1  briggs
1.1  briggs /* per-bus constants. */
1.1  briggs #define MAX_CONF_DEV	8			/* Arbitrary */
1.1  briggs #define MAX_CONF_MEM	(3 * MAX_CONF_DEV)	/* Avg. 3 per device -- Arb. */
1.1  briggs #define MAX_CONF_IO	(1 * MAX_CONF_DEV)	/* Avg. 1 per device -- Arb. */
1.1  briggs
1.1  briggs #define PCI_BUSNO_SPACING	(1 << 5)
1.1  briggs
1.1  briggs struct _s_pciconf_bus_t;			/* Forward declaration */
1.1  briggs
1.1  briggs typedef struct _s_pciconf_dev_t {
1.1  briggs 	int		ipin;
1.1  briggs 	int		iline;
1.1  briggs 	int		min_gnt;
1.1  briggs 	int		max_lat;
1.1  briggs 	pcitag_t	tag;
1.1  briggs 	pci_chipset_tag_t	pc;
1.1  briggs 	struct _s_pciconf_bus_t	*ppb;		/* I am really a bridge */
1.1  briggs } pciconf_dev_t;
1.1  briggs
1.1  briggs typedef struct _s_pciconf_win_t {
1.1  briggs 	pciconf_dev_t	*dev;
1.1  briggs 	int		reg;			/* 0 for busses */
1.1  briggs 	int		align;
1.1  briggs 	int		prefetch;
1.1  briggs 	u_int64_t	size;
1.1  briggs 	u_int64_t	address;
1.1  briggs } pciconf_win_t;
1.1  briggs
1.1  briggs typedef struct _s_pciconf_bus_t {
1.1  briggs 	int		busno;
1.1  briggs 	int		next_busno;
1.1  briggs 	int		last_busno;
1.1  briggs 	int		busno_spacing;
1.1  briggs 	int		max_mingnt;
1.1  briggs 	int		min_maxlat;
1.1  briggs 	int		prefetch;
1.1  briggs 	int		fast_b2b;
1.1  briggs 	int		freq_66;
1.1  briggs 	int		def_ltim;
1.1  briggs 	int		max_ltim;
1.1  briggs 	int		bandwidth_used;
1.1  briggs 	int		swiz;
1.1  briggs
1.1  briggs 	int		ndevs;
1.1  briggs 	pciconf_dev_t	device[MAX_CONF_DEV];
1.1  briggs
1.1  briggs 	/* These should be sorted in order of decreasing size */
1.1  briggs 	int		nmemwin;
1.1  briggs 	pciconf_win_t	pcimemwin[MAX_CONF_MEM];
1.1  briggs 	int		niowin;
1.1  briggs 	pciconf_win_t	pciiowin[MAX_CONF_IO];
1.1  briggs
1.1  briggs 	bus_size_t	io_total;
1.1  briggs 	bus_size_t	mem_total;
1.1  briggs 	bus_size_t	pmem_total;
1.1  briggs
1.1  briggs 	struct extent	*ioext;
1.1  briggs 	struct extent	*memext;
1.1  briggs 	struct extent	*pmemext;
1.1  briggs
1.1  briggs 	pci_chipset_tag_t	pc;
1.1  briggs 	struct _s_pciconf_bus_t *parent_bus;
1.1  briggs } pciconf_bus_t;
1.1  briggs
1.1  briggs static int	probe_bus(pciconf_bus_t *);
1.1  briggs static void	alloc_busno(pciconf_bus_t *, pciconf_bus_t *);
1.1  briggs static int	pci_do_device_query(pciconf_bus_t *, pcitag_t, int, int);
1.1  briggs static int	setup_iowins(pciconf_bus_t *);
1.1  briggs static int	setup_memwins(pciconf_bus_t *);
1.1  briggs static int	configure_bridge(pciconf_dev_t *);
1.1  briggs static int	configure_bus(pciconf_bus_t *);
1.1  briggs static u_int64_t	pci_allocate_range(struct extent *, u_int64_t, int);
1.1  briggs static pciconf_win_t	*get_io_desc(pciconf_bus_t *, bus_size_t);
1.1  briggs static pciconf_win_t	*get_mem_desc(pciconf_bus_t *, bus_size_t);
1.1  briggs static pciconf_bus_t	*query_bus(pciconf_bus_t *, pciconf_dev_t *, int);
1.1  briggs
1.1  briggs #ifdef PCI_CONFIGURATION_DEBUG
1.1  briggs static void	print_tag(pci_chipset_tag_t, pcitag_t);
1.1  briggs
1.1  briggs static void
1.1  briggs print_tag(pci_chipset_tag_t pc, pcitag_t tag)
1.1  briggs {
1.1  briggs 	int	bus, dev, func;
1.1  briggs
1.1  briggs 	pci_decompose_tag(pc, tag, &bus, &dev, &func);
1.1  briggs 	printf("PCI: bus %d, device %d, function %d: ", bus, dev, func);
1.1  briggs }
1.1  briggs #endif
1.1  briggs
1.1  briggs /************************************************************************/
1.1  briggs /************************************************************************/
1.1  briggs /***********************   Bus probing routines   ***********************/
1.1  briggs /************************************************************************/
1.1  briggs /************************************************************************/
1.1  briggs static pciconf_win_t *
1.1  briggs get_io_desc(pciconf_bus_t *pb, bus_size_t size)
1.1  briggs {
1.1  briggs 	int	i, n;
1.1  briggs
1.1  briggs 	n = pb->niowin;
1.1  briggs 	for (i=n; i > 0 && size > pb->pciiowin[i-1].size; i--)
1.1  briggs 		pb->pciiowin[i] = pb->pciiowin[i-1]; /* struct copy */
1.1  briggs 	return &pb->pciiowin[i];
1.1  briggs }
1.1  briggs
1.1  briggs static pciconf_win_t *
1.1  briggs get_mem_desc(pciconf_bus_t *pb, bus_size_t size)
1.1  briggs {
1.1  briggs 	int	i, n;
1.1  briggs
1.1  briggs 	n = pb->nmemwin;
1.1  briggs 	for (i=n; i > 0 && size > pb->pcimemwin[i-1].size; i--)
1.1  briggs 		pb->pcimemwin[i] = pb->pcimemwin[i-1]; /* struct copy */
1.1  briggs 	return &pb->pcimemwin[i];
1.1  briggs }
1.1  briggs
1.1  briggs /*
1.1  briggs  * Set up bus common stuff, then loop over devices & functions.
1.1  briggs  * If we find something, call pci_do_device_query()).
1.1  briggs  */
1.1  briggs static int
1.1  briggs probe_bus(pciconf_bus_t *pb)
1.1  briggs {
1.1  briggs 	int device, maxdevs;
1.1  briggs
1.1  briggs 	maxdevs = pci_bus_maxdevs(pb->pc, pb->busno);
1.1  briggs 	pb->ndevs = 0;
1.1  briggs 	pb->niowin = 0;
1.1  briggs 	pb->nmemwin = 0;
1.1  briggs 	pb->freq_66 = 1;
1.1  briggs 	pb->fast_b2b = 1;
1.1  briggs 	pb->prefetch = 1;
1.1  briggs 	pb->max_mingnt = 0;	/* we are looking for the maximum */
1.1  briggs 	pb->min_maxlat = 0x100;	/* we are looking for the minimum */
1.1  briggs 	pb->bandwidth_used = 0;
1.1  briggs 	for (device=0; device < maxdevs; device++) {
1.1  briggs 		pcitag_t tag;
1.1  briggs 		pcireg_t id, bhlcr;
1.1  briggs 		int function, nfunction;
1.1  briggs
1.1  briggs 		tag = pci_make_tag(pb->pc, pb->busno, device, 0);
1.1  briggs #ifdef PCI_CONFIGURATION_DEBUG
1.1  briggs 		if (pci_conf_debug) {
1.1  briggs 			print_tag(pb->pc, tag);
1.1  briggs 			printf("probing.\n");
1.1  briggs 		}
1.1  briggs #endif
1.1  briggs 		id = pci_conf_read(pb->pc, tag, PCI_ID_REG);
1.1  briggs
1.1  briggs 		/* Invalid vendor ID value? */
1.1  briggs 		if (PCI_VENDOR(id) == PCI_VENDOR_INVALID)
1.1  briggs 			continue;
1.1  briggs
1.1  briggs 		bhlcr = pci_conf_read(pb->pc, tag, PCI_BHLC_REG);
1.1  briggs 		nfunction = PCI_HDRTYPE_MULTIFN(bhlcr) ? 8 : 1;
1.1  briggs 		for (function = 0 ; function < nfunction ; function++) {
1.1  briggs 			tag = pci_make_tag(pb->pc, pb->busno, device, function);
1.1  briggs 			id = pci_conf_read(pb->pc, tag, PCI_ID_REG);
1.1  briggs 			if (PCI_VENDOR(id) == PCI_VENDOR_INVALID)
1.1  briggs 				continue;
1.1  briggs 			if (pb->ndevs+1 < MAX_CONF_DEV) {
1.1  briggs #ifdef PCI_CONFIGURATION_DEBUG
1.1  briggs 				if (pci_conf_debug) {
1.1  briggs 					print_tag(pb->pc, tag);
1.1  briggs 					printf("Found dev--really probing.\n");
1.1  briggs 				}
1.1  briggs #endif
1.1  briggs 				if (pci_do_device_query(pb, tag, device,
1.1  briggs 				    function))
1.1  briggs 					return -1;
1.1  briggs 				pb->ndevs++;
1.1  briggs 			}
1.1  briggs 		}
1.1  briggs 	}
1.1  briggs 	return 0;
1.1  briggs }
1.1  briggs
1.1  briggs static void
1.1  briggs alloc_busno(pciconf_bus_t *parent, pciconf_bus_t *pb)
1.1  briggs {
1.1  briggs 	pb->busno = parent->next_busno;
1.1  briggs 	if (parent->next_busno + parent->busno_spacing > parent->last_busno)
1.1  briggs 		panic("Too many PCI busses on bus %d", parent->busno);
1.1  briggs 	parent->next_busno = parent->next_busno + parent->busno_spacing;
1.1  briggs 	pb->next_busno = pb->busno+1;
1.1  briggs 	pb->busno_spacing = parent->busno_spacing >> 1;
1.1  briggs 	if (!pb->busno_spacing)
1.1  briggs 		panic("PCI busses nested too deep.");
1.1  briggs 	pb->last_busno = parent->next_busno - 1;
1.1  briggs }
1.1  briggs
1.1  briggs static pciconf_bus_t *
1.1  briggs query_bus(pciconf_bus_t *parent, pciconf_dev_t *pd, int dev)
1.1  briggs {
1.1  briggs 	pciconf_bus_t	*pb;
1.1  briggs 	pcireg_t	busreg;
1.1  briggs 	pciconf_win_t	*pi, *pm;
1.1  briggs
1.1  briggs 	pb = malloc (sizeof (pciconf_bus_t), M_DEVBUF, M_NOWAIT);
1.1  briggs 	if (!pb)
1.1  briggs 		panic("Unable to allocate memory for PCI configuration.");
1.1  briggs
1.1  briggs 	pb->parent_bus = parent;
1.1  briggs 	alloc_busno(parent, pb);
1.1  briggs #ifdef PCI_CONFIGURATION_DEBUG
1.1  briggs 	if (pci_conf_debug)
1.1  briggs 		printf("PCI bus bridge covers busses %d-%d\n",
1.1  briggs 			pb->busno, pb->last_busno);
1.1  briggs #endif
1.1  briggs
1.1  briggs 	busreg  =  parent->busno << PCI_BRIDGE_BUS_PRIMARY_SHIFT;
1.1  briggs 	busreg |=      pb->busno << PCI_BRIDGE_BUS_SECONDARY_SHIFT;
1.1  briggs 	busreg |= pb->last_busno << PCI_BRIDGE_BUS_SUBORDINATE_SHIFT;
1.1  briggs 	pci_conf_write(pb->pc, pd->tag, PCI_BRIDGE_BUS_REG, busreg);
1.1  briggs
1.1  briggs 	pb->swiz = parent->swiz + dev;
1.1  briggs
1.1  briggs 	pb->ioext = NULL;
1.1  briggs 	pb->memext = NULL;
1.1  briggs 	pb->pmemext = NULL;
1.1  briggs 	pb->pc = parent->pc;
1.1  briggs 	pb->io_total = pb->mem_total = pb->pmem_total = 0;
1.1  briggs
1.1  briggs 	if (probe_bus(pb)) {
1.1  briggs 		printf("Failed to probe bus %d\n", pb->busno);
1.1  briggs 		goto err;
1.1  briggs 	}
1.1  briggs
1.1  briggs 	if (pb->io_total > 0) {
1.1  briggs 		if (parent->niowin >= MAX_CONF_IO) {
1.1  briggs 			printf("pciconf: too many I/O windows");
1.1  briggs 			goto err;
1.1  briggs 		}
1.1  briggs 		pb->io_total |= 0xfff;	/* Round up */
1.1  briggs 		pi = get_io_desc(parent, pb->io_total);
1.1  briggs 		pi->dev = pd;
1.1  briggs 		pi->reg = 0;
1.1  briggs 		pi->size = pb->io_total;
1.1  briggs 		pi->align = 0x1000;	/* 4K alignment */
1.1  briggs 		pi->prefetch = 0;
1.1  briggs 		parent->niowin++;
1.1  briggs 		parent->io_total += pb->io_total;
1.1  briggs 	}
1.1  briggs
1.1  briggs 	if (pb->mem_total > 0) {
1.1  briggs 		if (parent->nmemwin >= MAX_CONF_MEM) {
1.1  briggs 			printf("pciconf: too many MEM windows");
1.1  briggs 			goto err;
1.1  briggs 		}
1.1  briggs 		pb->mem_total |= 0xfffff;	/* Round up */
1.1  briggs 		pm = get_mem_desc(parent, pb->mem_total);
1.1  briggs 		pm->dev = pd;
1.1  briggs 		pm->reg = 0;
1.1  briggs 		pm->size = pb->mem_total;
1.1  briggs 		pm->align = 0x100000;	/* 1M alignment */
1.1  briggs 		pm->prefetch = 0;
1.1  briggs 		parent->nmemwin++;
1.1  briggs 		parent->mem_total += pb->mem_total;
1.1  briggs 	}
1.1  briggs
1.1  briggs 	if (pb->pmem_total > 0) {
1.1  briggs 		if (parent->nmemwin >= MAX_CONF_MEM) {
1.1  briggs 			printf("pciconf: too many MEM windows");
1.1  briggs 			goto err;
1.1  briggs 		}
1.1  briggs 		pb->pmem_total |= 0xfffff;	/* Round up */
1.1  briggs 		pm = get_mem_desc(parent, pb->pmem_total);
1.1  briggs 		pm->dev = pd;
1.1  briggs 		pm->reg = 0;
1.1  briggs 		pm->size = pb->pmem_total;
1.1  briggs 		pm->align = 0x100000;		/* 1M alignment */
1.1  briggs 		pm->prefetch = 1;
1.1  briggs 		parent->nmemwin++;
1.1  briggs 		parent->pmem_total += pb->pmem_total;
1.1  briggs 	}
1.1  briggs
1.1  briggs 	return pb;
1.1  briggs err:
1.1  briggs 	free(pb, M_DEVBUF);
1.1  briggs 	return NULL;
1.1  briggs }
1.1  briggs
1.1  briggs static int
1.1  briggs pci_do_device_query(pciconf_bus_t *pb, pcitag_t tag, int dev, int func)
1.1  briggs {
1.1  briggs 	pciconf_dev_t	*pd;
1.1  briggs 	pciconf_win_t	*pi, *pm;
1.1  briggs 	pcireg_t	class, cmd, icr, bar, mask, bar64, mask64;
1.1  briggs 	u_int64_t	size;
1.1  briggs 	int		br, width;
1.1  briggs
1.1  briggs 	pd = &pb->device[pb->ndevs];
1.1  briggs 	pd->pc = pb->pc;
1.1  briggs 	pd->tag = tag;
1.1  briggs 	pd->ppb = NULL;
1.1  briggs
1.1  briggs 	class = pci_conf_read(pb->pc, tag, PCI_CLASS_REG);
1.1  briggs
1.1  briggs 	cmd = pci_conf_read(pb->pc, tag, PCI_COMMAND_STATUS_REG);
1.1  briggs
1.1  briggs 	if (PCI_CLASS(class) != PCI_CLASS_BRIDGE) {
1.1  briggs 		cmd &= ~(PCI_COMMAND_MASTER_ENABLE |
1.1  briggs 		    PCI_COMMAND_IO_ENABLE | PCI_COMMAND_MEM_ENABLE);
1.1  briggs 		pci_conf_write(pb->pc, tag, PCI_COMMAND_STATUS_REG, cmd);
1.1  briggs 	}
1.1  briggs
1.1  briggs 	if ((cmd & PCI_STATUS_BACKTOBACK_SUPPORT) == 0)
1.1  briggs 		pb->fast_b2b = 0;
1.1  briggs
1.1  briggs 	if ((cmd & PCI_STATUS_66MHZ_SUPPORT) == 0)
1.1  briggs 		pb->freq_66 = 0;
1.1  briggs
1.1  briggs 	if (   (PCI_CLASS(class) == PCI_CLASS_BRIDGE)
1.1  briggs 	    && (PCI_SUBCLASS(class) == PCI_SUBCLASS_BRIDGE_PCI)) {
1.1  briggs 		pd->ppb = query_bus(pb, pd, dev);
1.1  briggs 		if (pd->ppb == NULL)
1.1  briggs 			return -1;
1.1  briggs 		return 0;
1.1  briggs 	}
1.1  briggs
1.1  briggs 	icr = pci_conf_read(pb->pc, tag, PCI_INTERRUPT_REG);
1.1  briggs 	pd->ipin = PCI_INTERRUPT_PIN(icr);
1.1  briggs 	pd->iline = PCI_INTERRUPT_LINE(icr);
1.1  briggs 	pd->min_gnt = PCI_MIN_GNT(icr);
1.1  briggs 	pd->max_lat = PCI_MAX_LAT(icr);
1.1  briggs 	if (pd->iline || pd->ipin) {
1.1  briggs 		pci_conf_interrupt(pb->pc, pb->busno, dev, func, pb->swiz,
1.1  briggs 		    &pd->iline);
1.1  briggs 		icr &= ~(PCI_INTERRUPT_LINE_MASK << PCI_INTERRUPT_LINE_SHIFT);
1.1  briggs 		icr |= (pd->iline << PCI_INTERRUPT_LINE_SHIFT);
1.1  briggs 		pci_conf_write(pb->pc, tag, PCI_INTERRUPT_REG, icr);
1.1  briggs 	}
1.1  briggs
1.1  briggs 	if (pd->min_gnt != 0 || pd->max_lat != 0) {
1.1  briggs 		if (pd->min_gnt != 0 && pd->min_gnt > pb->max_mingnt)
1.1  briggs 			pb->max_mingnt = pd->min_gnt;
1.1  briggs
1.1  briggs 		if (pd->max_lat != 0 && pd->max_lat < pb->min_maxlat)
1.1  briggs 			pb->min_maxlat = pd->max_lat;
1.1  briggs
1.1  briggs 		pb->bandwidth_used += pd->min_gnt * 4000000 /
1.1  briggs 				(pd->min_gnt + pd->max_lat);
1.1  briggs 	}
1.1  briggs
1.1  briggs 	width = 4;
1.1  briggs 	for (br = PCI_MAPREG_START; br < PCI_MAPREG_END; br += width) {
1.1  briggs 		if (PCI_CLASS(class) == PCI_CLASS_MASS_STORAGE &&
1.1  briggs 		    PCI_SUBCLASS(class) == PCI_SUBCLASS_MASS_STORAGE_IDE) {
1.1  briggs 			break;
1.1  briggs 		}
1.1  briggs 		bar = pci_conf_read(pb->pc, tag, br);
1.1  briggs 		pci_conf_write(pb->pc, tag, br, 0xfffffffe);
1.1  briggs 		mask = pci_conf_read(pb->pc, tag, br);
1.1  briggs 		pci_conf_write(pb->pc, tag, br, bar);
1.1  briggs 		width = 4;
1.1  briggs
1.1  briggs 		if (mask == 0 || mask == 0xffffffff)
1.1  briggs 			break;
1.1  briggs
1.1  briggs 		if (PCI_MAPREG_TYPE(mask) == PCI_MAPREG_TYPE_IO) {
1.1  briggs 			if (pb->niowin >= MAX_CONF_IO) {
1.1  briggs 				printf("pciconf: too many I/O windows");
1.1  briggs 				return -1;
1.1  briggs 			}
1.1  briggs
1.1  briggs 			mask |= 0xffff0000;
1.1  briggs 			size = PCI_MAPREG_IO_SIZE(mask);
1.1  briggs
1.1  briggs 			pi = get_io_desc(pb, size);
1.1  briggs 			pi->dev = pd;
1.1  briggs 			pi->reg = br;
1.1  briggs 			pi->size = (u_int64_t) size;
1.1  briggs 			pi->align = 4;
1.1  briggs 			pi->prefetch = 0;
1.1  briggs #ifdef PCI_CONFIGURATION_DEBUG
1.1  briggs 			if (pci_conf_debug) {
1.1  briggs 				print_tag(pb->pc, tag);
1.1  briggs 				printf("Register %d, I/O size %llu\n",
1.1  briggs 				    br, pi->size);
1.1  briggs 			}
1.1  briggs #endif
1.1  briggs 			pb->niowin++;
1.1  briggs 			pb->io_total += size;
1.1  briggs 		} else {
1.1  briggs 			switch (PCI_MAPREG_MEM_TYPE(mask)) {
1.1  briggs 			case PCI_MAPREG_MEM_TYPE_32BIT:
1.1  briggs 			case PCI_MAPREG_MEM_TYPE_32BIT_1M:
1.1  briggs 				size = (u_int64_t) PCI_MAPREG_MEM_SIZE(mask);
1.1  briggs 				break;
1.1  briggs 			case PCI_MAPREG_MEM_TYPE_64BIT:
1.1  briggs 				bar64 = pci_conf_read(pb->pc, tag, br + 4);
1.1  briggs 				pci_conf_write(pb->pc, tag, br + 4, 0xffffffff);
1.1  briggs 				mask64 = pci_conf_read(pb->pc, tag, br + 4);
1.1  briggs 				pci_conf_write(pb->pc, tag, br + 4, bar64);
1.1  briggs 				size = (u_int64_t) PCI_MAPREG_MEM64_SIZE(
1.1  briggs 				      (((u_int64_t) mask64) << 32) | mask);
1.1  briggs 				width = 8;
1.1  briggs 				continue;
1.1  briggs 			default:
1.1  briggs 				print_tag(pb->pc, tag);
1.1  briggs 				printf("reserved mapping type 0x%x\n",
1.1  briggs 					PCI_MAPREG_MEM_TYPE(mask));
1.1  briggs 				continue;
1.1  briggs 			}
1.1  briggs
1.1  briggs 			if (pb->nmemwin >= MAX_CONF_MEM) {
1.1  briggs 				printf("pciconf: too many memory windows");
1.1  briggs 				return -1;
1.1  briggs 			}
1.1  briggs
1.1  briggs
1.1  briggs 			pm = get_mem_desc(pb, size);
1.1  briggs 			pm->dev = pd;
1.1  briggs 			pm->reg = br;
1.1  briggs 			pm->size = size;
1.1  briggs 			pm->align = 4;
1.1  briggs 			pm->prefetch = PCI_MAPREG_MEM_PREFETCHABLE(mask);
1.1  briggs #ifdef PCI_CONFIGURATION_DEBUG
1.1  briggs 			if (pci_conf_debug) {
1.1  briggs 				print_tag(pb->pc, tag);
1.1  briggs 				printf("Register %d, memory size %llu\n",
1.1  briggs 				    br, pm->size);
1.1  briggs 			}
1.1  briggs #endif
1.1  briggs 			pb->nmemwin++;
1.1  briggs 			if (pm->prefetch) {
1.1  briggs 				pb->pmem_total += size;
1.1  briggs 			} else {
1.1  briggs 				pb->mem_total += size;
1.1  briggs 			}
1.1  briggs 		}
1.1  briggs 	}
1.1  briggs
1.1  briggs 	bar = pci_conf_read(pb->pc, tag, PCI_MAPREG_ROM);
1.1  briggs 	pci_conf_write(pb->pc, tag, PCI_MAPREG_ROM, 0xfffffffe);
1.1  briggs 	mask = pci_conf_read(pb->pc, tag, PCI_MAPREG_ROM);
1.1  briggs 	pci_conf_write(pb->pc, tag, PCI_MAPREG_ROM, bar);
1.1  briggs
1.1  briggs 	if (mask != 0 && mask != 0xffffffff) {
1.1  briggs 		if (pb->nmemwin >= MAX_CONF_MEM) {
1.1  briggs 			printf("pciconf: too many memory windows");
1.1  briggs 			return -1;
1.1  briggs 		}
1.1  briggs 		size = (u_int64_t) PCI_MAPREG_MEM_SIZE(mask);
1.1  briggs
1.1  briggs 		pm = get_mem_desc(pb, size);
1.1  briggs 		pm->dev = pd;
1.1  briggs 		pm->reg = PCI_MAPREG_ROM;
1.1  briggs 		pm->size = size;
1.1  briggs 		pm->align = 4;
1.1  briggs 		pm->prefetch = 1;
1.1  briggs #ifdef PCI_CONFIGURATION_DEBUG
1.1  briggs 		if (pci_conf_debug) {
1.1  briggs 			print_tag(pb->pc, tag);
1.1  briggs 			printf("Expansion ROM memory size %llu\n", pm->size);
1.1  briggs 		}
1.1  briggs #endif
1.1  briggs 		pb->nmemwin++;
1.1  briggs 		pb->pmem_total += size;
1.1  briggs 	}
1.1  briggs
1.1  briggs 	return 0;
1.1  briggs }
1.1  briggs
1.1  briggs /************************************************************************/
1.1  briggs /************************************************************************/
1.1  briggs /********************   Bus configuration routines   ********************/
1.1  briggs /************************************************************************/
1.1  briggs /************************************************************************/
1.1  briggs static u_int64_t
1.1  briggs pci_allocate_range(struct extent *ex, u_int64_t amt, int align)
1.1  briggs {
1.1  briggs 	int	r;
1.1  briggs 	u_long	addr;
1.1  briggs
1.1  briggs 	r = extent_alloc(ex, amt, align, 0, EX_NOWAIT, &addr);
1.1  briggs 	if (r) {
1.1  briggs 		addr = (u_long) -1;
1.1  briggs 		printf("extent_alloc() returned %d\n", r);
1.1  briggs 	}
1.1  briggs 	return (pcireg_t) addr;
1.1  briggs }
1.1  briggs
1.1  briggs static int
1.1  briggs setup_iowins(pciconf_bus_t *pb)
1.1  briggs {
1.1  briggs 	pciconf_win_t	*pi;
1.1  briggs 	pciconf_dev_t	*pd;
1.1  briggs
1.1  briggs 	for (pi=pb->pciiowin; pi < &pb->pciiowin[pb->niowin] ; pi++) {
1.1  briggs 		if (pi->size == 0)
1.1  briggs 			continue;
1.1  briggs
1.1  briggs 		pd = pi->dev;
1.1  briggs 		pi->address = pci_allocate_range(pb->ioext, pi->size,
1.1  briggs 		    pi->align);
1.1  briggs 		if (pi->address == -1) {
1.1  briggs 			print_tag(pd->pc, pd->tag);
1.1  briggs 			printf("Failed to allocate PCI I/O space (%llu req)\n",
1.1  briggs 			   pi->size);
1.1  briggs 			return -1;
1.1  briggs 		}
1.1  briggs 		if (pd->ppb && pi->reg == 0) {
1.1  briggs 			pd->ppb->ioext = extent_create("pciconf", pi->address,
1.1  briggs 			    pi->address + pi->size, M_DEVBUF, NULL, 0,
1.1  briggs 			    EX_NOWAIT);
1.1  briggs 			if (pd->ppb->ioext == NULL) {
1.1  briggs 				print_tag(pd->pc, pd->tag);
1.1  briggs 				printf("Failed to alloc I/O ext. for bus %d\n",
1.1  briggs 				    pd->ppb->busno);
1.1  briggs 				return -1;
1.1  briggs 			}
1.1  briggs 			continue;
1.1  briggs 		}
1.1  briggs #ifdef PCI_CONFIGURATION_DEBUG
1.1  briggs 		if (pci_conf_debug) {
1.1  briggs 			print_tag(pd->pc, pd->tag);
1.1  briggs 			printf("Putting %llu I/O bytes @ %#llx (reg %x)\n",
1.1  briggs 			    pi->size, pi->address, pi->reg);
1.1  briggs 		}
1.1  briggs #endif
1.1  briggs 		pci_conf_write(pd->pc, pd->tag, pi->reg,
1.1  briggs 		    PCI_MAPREG_IO_ADDR(pi->address) | PCI_MAPREG_TYPE_IO);
1.1  briggs 	}
1.1  briggs 	return 0;
1.1  briggs }
1.1  briggs
1.1  briggs static int
1.1  briggs setup_memwins(pciconf_bus_t *pb)
1.1  briggs {
1.1  briggs 	pciconf_win_t	*pm;
1.1  briggs 	pciconf_dev_t	*pd;
1.1  briggs 	pcireg_t	base;
1.1  briggs 	struct extent	*ex;
1.1  briggs
1.1  briggs 	for (pm=pb->pcimemwin; pm < &pb->pcimemwin[pb->nmemwin] ; pm++) {
1.1  briggs 		if (pm->size == 0)
1.1  briggs 			continue;
1.1  briggs
1.1  briggs 		pd = pm->dev;
1.1  briggs 		ex = (pm->prefetch) ? pb->pmemext : pb->memext;
1.1  briggs 		pm->address = pci_allocate_range(ex, pm->size, pm->align);
1.1  briggs 		if (pm->address == -1) {
1.1  briggs 			print_tag(pd->pc, pd->tag);
1.1  briggs 			printf(
1.1  briggs 			   "Failed to allocate PCI memory space (%llu req)\n",
1.1  briggs 			   pm->size);
1.1  briggs 			return -1;
1.1  briggs 		}
1.1  briggs 		if (pd->ppb && pm->reg == 0) {
1.1  briggs 			ex = extent_create("pciconf", pm->address,
1.1  briggs 			    pm->address + pm->size, M_DEVBUF, NULL, 0,
1.1  briggs 			    EX_NOWAIT);
1.1  briggs 			if (ex == NULL) {
1.1  briggs 				print_tag(pd->pc, pd->tag);
1.1  briggs 				printf("Failed to alloc MEM ext. for bus %d\n",
1.1  briggs 				    pd->ppb->busno);
1.1  briggs 				return -1;
1.1  briggs 			}
1.1  briggs 			if (pm->prefetch) {
1.1  briggs 				pd->ppb->pmemext = ex;
1.1  briggs 			} else {
1.1  briggs 				pd->ppb->memext = ex;
1.1  briggs 			}
1.1  briggs 			continue;
1.1  briggs 		}
1.1  briggs 		if (pm->reg != PCI_MAPREG_ROM) {
1.1  briggs #ifdef PCI_CONFIGURATION_DEBUG
1.1  briggs 			if (pci_conf_debug) {
1.1  briggs 				print_tag(pd->pc, pd->tag);
1.1  briggs 				printf(
1.1  briggs 				    "Putting %llu MEM bytes @ %#llx (reg %x)\n",
1.1  briggs 				     pm->size, pm->address, pm->reg);
1.1  briggs 			}
1.1  briggs #endif
1.1  briggs 			base = pci_conf_read(pd->pc, pd->tag, pm->reg);
1.1  briggs 			base = PCI_MAPREG_MEM_ADDR(pm->address) |
1.1  briggs 			    PCI_MAPREG_MEM_TYPE(base);
1.1  briggs 			pci_conf_write(pd->pc, pd->tag, pm->reg, base);
1.1  briggs 			if (PCI_MAPREG_MEM_TYPE(base) ==
1.1  briggs 			    PCI_MAPREG_MEM_TYPE_64BIT) {
1.1  briggs 				base = (pcireg_t)
1.1  briggs 				    (PCI_MAPREG_MEM64_ADDR(pm->address) >> 32);
1.1  briggs 				pci_conf_write(pd->pc, pd->tag, pm->reg + 4,
1.1  briggs 				    base);
1.1  briggs 			}
1.1  briggs 		}
1.1  briggs 	}
1.1  briggs 	for (pm=pb->pcimemwin; pm < &pb->pcimemwin[pb->nmemwin] ; pm++) {
1.1  briggs 		if (pm->reg == PCI_MAPREG_ROM && pm->address != -1) {
1.1  briggs 			pd = pm->dev;
1.1  briggs #ifdef PCI_CONFIGURATION_DEBUG
1.1  briggs 			if (pci_conf_debug) {
1.1  briggs 				print_tag(pd->pc, pd->tag);
1.1  briggs 				printf(
1.1  briggs 				    "Putting %llu ROM bytes @ %#llx (reg %x)\n",
1.1  briggs 				    pm->size, pm->address, pm->reg);
1.1  briggs 			}
1.1  briggs #endif
1.1  briggs 			base = ((pcireg_t) pm->address) | PCI_MAPREG_TYPE_ROM;
1.1  briggs 			pci_conf_write(pd->pc, pd->tag, pm->reg, base);
1.1  briggs 		}
1.1  briggs 	}
1.1  briggs 	return 0;
1.1  briggs }
1.1  briggs
1.1  briggs /*
1.1  briggs  * Configure I/O, memory, and prefetcable memory spaces, then make
1.1  briggs  * a call to configure_bus().
1.1  briggs  */
1.1  briggs static int
1.1  briggs configure_bridge(pciconf_dev_t *pd)
1.1  briggs {
1.1  briggs 	unsigned long	io_base, io_limit, mem_base, mem_limit;
1.1  briggs 	pciconf_bus_t	*pb;
1.1  briggs 	pcireg_t	io, iohigh, mem, cmd;
1.1  briggs 	int		rv;
1.1  briggs
1.1  briggs 	pb = pd->ppb;
1.1  briggs 	/* Configure I/O base & limit*/
1.1  briggs 	if (pb->ioext) {
1.1  briggs 		io_base = pb->ioext->ex_start;
1.1  briggs 		io_limit = pb->ioext->ex_end;
1.1  briggs 		io = pci_conf_read(pb->pc, pd->tag, PCI_BRIDGE_STATIO_REG);
1.1  briggs 		if (PCI_BRIDGE_IO_32BITS(io)) {
1.1  briggs 			iohigh =
1.1  briggs 			    ((io_base >> 16) << PCI_BRIDGE_IOHIGH_BASE_SHIFT) |
1.1  briggs 			    ((io_limit >> 16) << PCI_BRIDGE_IOHIGH_LIMIT_SHIFT);
1.1  briggs 		} else {
1.1  briggs 			iohigh = 0;
1.1  briggs 		}
1.1  briggs 		io &= (PCI_BRIDGE_STATIO_STATUS_MASK <<
1.1  briggs 		    PCI_BRIDGE_STATIO_STATUS_SHIFT);
1.1  briggs 		io |= (((io_base >> 8) & PCI_BRIDGE_STATIO_IOBASE_MASK)
1.1  briggs 		    << PCI_BRIDGE_STATIO_IOBASE_SHIFT);
1.1  briggs 		io |= (((io_limit >> 8) & PCI_BRIDGE_STATIO_IOLIMIT_MASK)
1.1  briggs 		    << PCI_BRIDGE_STATIO_IOLIMIT_SHIFT);
1.1  briggs 		pci_conf_write(pb->pc, pd->tag, PCI_BRIDGE_STATIO_REG, io);
1.1  briggs 		pci_conf_write(pb->pc, pd->tag, PCI_BRIDGE_IOHIGH_REG, iohigh);
1.1  briggs 	}
1.1  briggs
1.1  briggs 	/* Configure mem base & limit */
1.1  briggs 	if (pb->memext) {
1.1  briggs 		mem_base = pb->memext->ex_start;
1.1  briggs 		mem_limit = pb->memext->ex_end;
1.1  briggs 		mem = (((mem_base >> 20) & PCI_BRIDGE_MEMORY_BASE_MASK)
1.1  briggs 		    << PCI_BRIDGE_MEMORY_BASE_SHIFT);
1.1  briggs 		mem |= (((mem_limit >> 20) & PCI_BRIDGE_MEMORY_LIMIT_MASK)
1.1  briggs 		    << PCI_BRIDGE_MEMORY_LIMIT_SHIFT);
1.1  briggs 		pci_conf_write(pb->pc, pd->tag, PCI_BRIDGE_MEMORY_REG, mem);
1.1  briggs 	}
1.1  briggs
1.1  briggs 	/* Configure prefetchable mem base & limit */
1.1  briggs 	if (pb->pmemext) {
1.1  briggs 		mem_base = pb->pmemext->ex_start;
1.1  briggs 		mem_limit = pb->pmemext->ex_end;
1.1  briggs 		mem = (((mem_base >> 20) & PCI_BRIDGE_PREFETCHMEM_BASE_MASK)
1.1  briggs 		    << PCI_BRIDGE_PREFETCHMEM_BASE_SHIFT);
1.1  briggs 		mem |= (((mem_limit >> 20) & PCI_BRIDGE_PREFETCHMEM_LIMIT_MASK)
1.1  briggs 		    << PCI_BRIDGE_PREFETCHMEM_LIMIT_SHIFT);
1.1  briggs 		pci_conf_write(pb->pc, pd->tag, PCI_BRIDGE_PREFETCHMEM_REG,
1.1  briggs 		    mem);
1.1  briggs 		/*
1.1  briggs 		 * XXX -- 64-bit systems need a lot more than just this...
1.1  briggs 		 */
1.1  briggs 		if (sizeof(u_long) > 4) {
1.1  briggs 			mem_base  = (int64_t) mem_base  >> 32;
1.1  briggs 			mem_limit = (int64_t) mem_limit >> 32;
1.1  briggs 		}
1.1  briggs 		pci_conf_write(pb->pc, pd->tag, PCI_BRIDGE_PREFETCHBASE32_REG,
1.1  briggs 		    mem_base & 0xffffffff);
1.1  briggs 		pci_conf_write(pb->pc, pd->tag, PCI_BRIDGE_PREFETCHLIMIT32_REG,
1.1  briggs 		    mem_limit & 0xffffffff);
1.1  briggs 	}
1.1  briggs
1.1  briggs 	rv = configure_bus(pb);
1.1  briggs
1.1  briggs 	if (pb->ioext)
1.1  briggs 		extent_destroy(pb->ioext);
1.1  briggs 	if (pb->memext)
1.1  briggs 		extent_destroy(pb->memext);
1.1  briggs 	if (pb->pmemext)
1.1  briggs 		extent_destroy(pb->pmemext);
1.1  briggs 	if (rv == 0) {
1.1  briggs 		cmd = pci_conf_read(pd->pc, pd->tag, PCI_BRIDGE_CONTROL_REG);
1.1  briggs 		cmd &= PCI_BRIDGE_CONTROL_MASK;
1.1  briggs 		cmd |= (PCI_BRIDGE_CONTROL_PERE | PCI_BRIDGE_CONTROL_SERR)
1.1  briggs 		    << PCI_BRIDGE_CONTROL_SHIFT;
1.1  briggs 		if (pb->fast_b2b) {
1.1  briggs 			cmd |= PCI_BRIDGE_CONTROL_SECFASTB2B
1.1  briggs 			    << PCI_BRIDGE_CONTROL_SHIFT;
1.1  briggs 		}
1.1  briggs 		pci_conf_write(pd->pc, pd->tag, PCI_BRIDGE_CONTROL_REG, cmd);
1.1  briggs 		cmd = pci_conf_read(pd->pc, pd->tag, PCI_COMMAND_STATUS_REG);
1.1  briggs 		cmd |= PCI_COMMAND_IO_ENABLE | PCI_COMMAND_MEM_ENABLE;
1.1  briggs 		pci_conf_write(pd->pc, pd->tag, PCI_COMMAND_STATUS_REG, cmd);
1.1  briggs 	}
1.1  briggs
1.1  briggs 	return rv;
1.1  briggs }
1.1  briggs
1.1  briggs /*
1.1  briggs  * Calculate latency values, allocate I/O and MEM segments, then set them
1.1  briggs  * up.  If a PCI-PCI bridge is found, configure the bridge separately,
1.1  briggs  * which will cause a recursive call back here.
1.1  briggs  */
1.1  briggs static int
1.1  briggs configure_bus(pciconf_bus_t *pb)
1.1  briggs {
1.1  briggs 	pciconf_dev_t	*pd;
1.1  briggs 	int		def_ltim, max_ltim, band;
1.1  briggs
1.1  briggs 				/* MIN_GNT assumes a clock rate of 33MHz */
1.1  briggs 	max_ltim = pb->max_mingnt * 33 / 4;	/* cvt to cycle count */
1.1  briggs 	band = 40000000;			/* 0.25us cycles/sec */
1.1  briggs 	if (band < pb->bandwidth_used) {
1.1  briggs 		printf("PCI bus %d: Warning: Total bandwidth exceeded!?\n",
1.1  briggs 		    pb->busno);
1.1  briggs 		def_ltim = -1;
1.1  briggs 	} else {
1.1  briggs 		def_ltim = (band - pb->bandwidth_used) / pb->ndevs;
1.1  briggs 		if (def_ltim > pb->min_maxlat)
1.1  briggs 			def_ltim = pb->min_maxlat;
1.1  briggs 		def_ltim = def_ltim * 33 / 4;
1.1  briggs 	}
1.1  briggs 	def_ltim = (def_ltim + 7) & ~7;
1.1  briggs 	max_ltim = (max_ltim + 7) & ~7;
1.1  briggs
1.1  briggs 	pb->def_ltim = MIN( def_ltim, 255 );
1.1  briggs 	pb->max_ltim = MIN( MAX(max_ltim, def_ltim ), 255 );
1.1  briggs
1.1  briggs 	/*
1.1  briggs 	 * Now we have what we need to initialize the devices.
1.1  briggs 	 * It would probably be better if we could allocate all of these
1.1  briggs 	 * for all busses at once, but "not right now".  First, get a list
1.1  briggs 	 * of free memory ranges from the m.d. system.
1.1  briggs 	 */
1.1  briggs 	if (setup_iowins(pb) || setup_memwins(pb)) {
1.1  briggs 		printf("PCI bus configuration failed: ");
1.1  briggs 		printf("unable to assign all I/O and memory ranges.");
1.1  briggs 		return -1;
1.1  briggs 	}
1.1  briggs
1.1  briggs 	/*
1.1  briggs 	 * Configure the latency for the devices, and enable them.
1.1  briggs 	 */
1.1  briggs 	for (pd=pb->device ; pd < &pb->device[pb->ndevs] ; pd++) {
1.1  briggs 		pcireg_t cmd, class, misc;
1.1  briggs 		int	ltim;
1.1  briggs
1.1  briggs #ifdef PCI_CONFIGURATION_DEBUG
1.1  briggs 		if (pci_conf_debug) {
1.1  briggs 			print_tag(pd->pc, pd->tag);
1.1  briggs 			printf("Configuring device.\n");
1.1  briggs 		}
1.1  briggs #endif
1.1  briggs 		class = pci_conf_read(pd->pc, pd->tag, PCI_CLASS_REG);
1.1  briggs 		misc = pci_conf_read(pd->pc, pd->tag, PCI_BHLC_REG);
1.1  briggs 		cmd = pci_conf_read(pd->pc, pd->tag, PCI_COMMAND_STATUS_REG);
1.1  briggs 		cmd |= PCI_COMMAND_MASTER_ENABLE
1.1  briggs 		    | PCI_COMMAND_SERR_ENABLE
1.1  briggs 		    | PCI_COMMAND_PARITY_ENABLE;
1.1  briggs 		if (pb->fast_b2b)
1.1  briggs 			cmd |= PCI_COMMAND_BACKTOBACK_ENABLE;
1.1  briggs 		if (PCI_CLASS(class) != PCI_CLASS_BRIDGE ||
1.1  briggs 		    PCI_SUBCLASS(class) != PCI_SUBCLASS_BRIDGE_PCI) {
1.1  briggs 			cmd |= PCI_COMMAND_IO_ENABLE | PCI_COMMAND_MEM_ENABLE;
1.1  briggs 			ltim = pd->min_gnt * 33 / 4;
1.1  briggs 			ltim = MIN (MAX (pb->def_ltim, ltim), pb->max_ltim);
1.1  briggs 		} else {
1.1  briggs 			ltim = MIN (pb->def_ltim, pb->max_ltim);
1.1  briggs 		}
1.1  briggs 		pci_conf_write(pd->pc, pd->tag, PCI_COMMAND_STATUS_REG, cmd);
1.1  briggs
1.1  briggs 		misc = (misc & ~(PCI_LATTIMER_MASK << PCI_LATTIMER_SHIFT))
1.1  briggs 		    | ((ltim & 0xff) << PCI_LATTIMER_SHIFT);
1.1  briggs 		pci_conf_write(pd->pc, pd->tag, PCI_BHLC_REG, misc);
1.1  briggs
1.1  briggs 		if (pd->ppb) {
1.1  briggs 			if (configure_bridge(pd) < 0)
1.1  briggs 				return -1;
1.1  briggs 			continue;
1.1  briggs 		}
1.1  briggs 	}
1.1  briggs
1.1  briggs #ifdef PCI_CONFIGURATION_DEBUG
1.1  briggs 	if (pci_conf_debug) {
1.1  briggs 		printf("PCI bus %d configured\n", pb->busno);
1.1  briggs 	}
1.1  briggs #endif
1.1  briggs
1.1  briggs 	return 0;
1.1  briggs }
1.1  briggs
1.1  briggs /*
1.1  briggs  * Let's configure the PCI bus.
1.1  briggs  * This consists of basically scanning for all existing devices,
1.1  briggs  * identifying their needs, and then making another pass over them
1.1  briggs  * to set:
1.1  briggs  *	1. I/O addresses
1.1  briggs  *	2. Memory addresses (Prefetchable and not)
1.1  briggs  *	3. PCI command register
1.1  briggs  *	4. The latency part of the PCI BHLC (BIST (Built-In Self Test),
1.1  briggs  *	    Header type, Latency timer, Cache line size) register
1.1  briggs  *
1.1  briggs  * The command register is set to enable fast back-to-back transactions
1.1  briggs  * if the host bridge says it can handle it.  We also configure
1.1  briggs  * Master Enable, SERR enable, parity enable, and (if this is not a
1.1  briggs  * PCI-PCI bridge) the I/O and Memory spaces.  Apparently some devices
1.1  briggs  * will not report some I/O space.
1.1  briggs  *
1.1  briggs  * The latency is computed to be a "fair share" of the bus bandwidth.
1.1  briggs  * The bus bandwidth variable is initialized to the number of PCI cycles
1.1  briggs  * in one second.  The number of cycles taken for one transaction by each
1.1  briggs  * device (MAX_LAT + MIN_GNT) is then subtracted from the bandwidth.
1.1  briggs  * Care is taken to ensure that the latency timer won't be set such that
1.1  briggs  * it would exceed the critical time for any device.
1.1  briggs  *
1.1  briggs  * This is complicated somewhat due to the presence of bridges.  PCI-PCI
1.1  briggs  * bridges are probed and configured recursively.
1.1  briggs  */
1.1  briggs int
1.1  briggs pci_configure_bus(pci_chipset_tag_t pc, struct extent *ioext,
1.1  briggs     struct extent *memext, struct extent *pmemext)
1.1  briggs {
1.1  briggs 	pciconf_bus_t	*pb;
1.1  briggs 	int		rv;
1.1  briggs
1.1  briggs 	pb = malloc (sizeof (pciconf_bus_t), M_DEVBUF, M_NOWAIT);
1.1  briggs 	pb->busno = 0;
1.1  briggs 	pb->busno_spacing = PCI_BUSNO_SPACING;
1.1  briggs 	pb->next_busno = pb->busno + 1;
1.1  briggs 	pb->last_busno = 255;
1.1  briggs 	pb->parent_bus = NULL;
1.1  briggs 	pb->swiz = 0;
1.1  briggs 	pb->ioext = ioext;
1.1  briggs 	pb->memext = memext;
1.1  briggs 	if (pmemext == NULL) {
1.1  briggs 		pb->pmemext = memext;
1.1  briggs 	} else {
1.1  briggs 		pb->pmemext = pmemext;
1.1  briggs 	}
1.1  briggs 	pb->pc = pc;
1.1  briggs 	pb->io_total = pb->mem_total = pb->pmem_total = 0;
1.1  briggs
1.1  briggs 	rv = probe_bus(pb);
1.1  briggs 	if (rv == 0) {
1.1  briggs 		rv = configure_bus(pb);
1.1  briggs 	}
1.1  briggs
1.1  briggs 	/*
1.1  briggs 	 * All done!
1.1  briggs 	 */
1.1  briggs 	free(pb, M_DEVBUF);
1.1  briggs 	return rv;
1.1  briggs }