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xserver-multidpi/hw/xfree86/os-support/bus/sparcPci.c
Eric Anholt 3fe67d23ed Remove the BusAccWindows resource code which is now unused. 
This was a bunch of poorly defined resource ranges per OS/platform combination
which were supposed to represent what regions could potentially have resources
allocated into them.
2007-08-27 19:02:41 -07:00

980 lines
30 KiB
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/*
* Copyright (C) 2001-2003 The XFree86 Project, Inc. All Rights Reserved.
*
* Permission is hereby granted, free of charge, to any person obtaining a copy
* of this software and associated documentation files (the "Software"), to
* deal in the Software without restriction, including without limitation the
* rights to use, copy, modify, merge, publish, distribute, sublicense, and/or
* sell copies of the Software, and to permit persons to whom the Software is
* furnished to do so, subject to the following conditions:
*
* The above copyright notice and this permission notice shall be included in
* all copies or substantial portions of the Software.
*
* THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, EXPRESS OR
* IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF MERCHANTABILITY,
* FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT. IN NO EVENT SHALL THE
* XFREE86 PROJECT BE LIABLE FOR ANY CLAIM, DAMAGES OR OTHER LIABILITY, WHETHER
* IN AN ACTION OF CONTRACT, TORT OR OTHERWISE, ARISING FROM, OUT OF OR IN
* CONNECTION WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS IN THE SOFTWARE.
*
* Except as contained in this notice, the name of the XFree86 Project shall
* not be used in advertising or otherwise to promote the sale, use or other
* dealings in this Software without prior written authorization from the
* XFree86 Project.
*/
#ifdef HAVE_XORG_CONFIG_H
#include <xorg-config.h>
#endif
#include "xf86.h"
#include "xf86Priv.h"
#include "xf86_OSlib.h"
#include "Pci.h"
#include "xf86sbusBus.h"
#if defined(sun)
extern char *apertureDevName;
static int apertureFd = -1;
/*
* A version of xf86MapVidMem() that allows for 64-bit displacements (but not
* sizes). Areas thus mapped can be unmapped by xf86UnMapVidMem().
*/
static pointer
sparcMapAperture(int iScreen, int Flags,
unsigned long long Base, unsigned long Size)
{
pointer result;
static int lastFlags = 0;
/* Assume both Base & Size are multiples of the page size */
if ((apertureFd < 0) || (Flags != lastFlags)) {
if (apertureFd >= 0)
close(apertureFd);
lastFlags = Flags;
apertureFd = open(apertureDevName,
(Flags & VIDMEM_READONLY) ? O_RDONLY : O_RDWR);
if (apertureFd < 0)
FatalError("sparcMapAperture: open failure: %s\n",
strerror(errno));
}
result = mmap(NULL, Size,
(Flags & VIDMEM_READONLY) ?
PROT_READ : (PROT_READ | PROT_WRITE),
MAP_SHARED, apertureFd, (off_t)Base);
if (result == MAP_FAILED)
FatalError("sparcMapAperture: mmap failure: %s\n", strerror(errno));
return result;
}
/*
* Platform-specific bus privates.
*/
typedef struct _sparcDomainRec {
unsigned long long io_addr, io_size;
unsigned long long mem_addr, mem_size;
pointer pci, io;
int bus_min, bus_max;
unsigned char dfn_mask[256 / 8];
} sparcDomainRec, *sparcDomainPtr;
#define SetBitInMap(bit, map) \
do { \
int _bit = (bit); \
(map)[_bit >> 3] |= 1 << (_bit & 7); \
} while (0)
#define IsBitSetInMap(bit, map) \
((map)[(bit) >> 3] & (1 << ((bit) & 7)))
/*
* Domain 0 is reserved for the one that represents the system as a whole, i.e.
* the one without any resource relocations.
*/
#define MAX_DOMAINS (MAX_PCI_BUSES / 256)
static sparcDomainPtr xf86DomainInfo[MAX_DOMAINS];
static int pciNumDomains = 1;
/* Variables that are assigned this must be declared volatile */
#define PciReg(base, tag, off, type) \
*(volatile type *)(pointer)((char *)(base) + \
(PCI_TAG_NO_DOMAIN(tag) | (off)))
/* Generic SPARC PCI access functions */
static CARD32
sparcPciCfgRead32(PCITAG tag, int off)
{
pciBusInfo_t *pBusInfo;
sparcDomainPtr pDomain;
volatile CARD32 result = (CARD32)(-1); /* Must be volatile */
int bus;
if ((off >= 0) && (off <= 252) && !(off & 3) &&
((bus = PCI_BUS_FROM_TAG(tag)) < pciNumBuses) &&
(pBusInfo = pciBusInfo[bus]) && (pDomain = pBusInfo->pciBusPriv) &&
(bus >= pDomain->bus_min) && (bus < pDomain->bus_max) &&
((bus > pDomain->bus_min) ||
IsBitSetInMap(PCI_DFN_FROM_TAG(tag), pDomain->dfn_mask))) {
result = PciReg(pDomain->pci, tag, off, CARD32);
result = PCI_CPU(result);
}
return result;
}
static void
sparcPciCfgWrite32(PCITAG tag, int off, CARD32 val)
{
pciBusInfo_t *pBusInfo;
sparcDomainPtr pDomain;
int bus;
if ((off < 0) || (off > 252) || (off & 3) ||
((bus = PCI_BUS_FROM_TAG(tag)) >= pciNumBuses) ||
!(pBusInfo = pciBusInfo[bus]) || !(pDomain = pBusInfo->pciBusPriv) ||
(bus < pDomain->bus_min) || (bus >= pDomain->bus_max) ||
((bus == pDomain->bus_min) &&
!IsBitSetInMap(PCI_DFN_FROM_TAG(tag), pDomain->dfn_mask)))
return;
val = PCI_CPU(val);
PciReg(pDomain->pci, tag, off, CARD32) = val;
}
static void
sparcPciCfgSetBits32(PCITAG tag, int off, CARD32 mask, CARD32 bits)
{
CARD32 PciVal;
PciVal = sparcPciCfgRead32(tag, off);
PciVal &= ~mask;
PciVal |= bits;
sparcPciCfgWrite32(tag, off, PciVal);
}
static pciBusFuncs_t sparcPCIFunctions =
{
sparcPciCfgRead32,
sparcPciCfgWrite32,
sparcPciCfgSetBits32,
pciAddrNOOP,
pciAddrNOOP
};
/*
* Sabre-specific versions of the above because of its peculiar access size
* requirements.
*/
static CARD32
sabrePciCfgRead32(PCITAG tag, int off)
{
pciBusInfo_t *pBusInfo;
sparcDomainPtr pDomain;
volatile CARD32 result; /* Must be volatile */
int bus;
if (PCI_BDEV_FROM_TAG(tag))
return sparcPciCfgRead32(tag, off);
if (PCI_FUNC_FROM_TAG(tag) || (off < 0) || (off > 252) || (off & 3) ||
((bus = PCI_BUS_FROM_TAG(tag)) >= pciNumBuses) ||
!(pBusInfo = pciBusInfo[bus]) || !(pDomain = pBusInfo->pciBusPriv) ||
(bus != pDomain->bus_min))
return (CARD32)(-1);
if (off < 8) {
result = (PciReg(pDomain->pci, tag, off, CARD16) << 16) |
PciReg(pDomain->pci, tag, off + 2, CARD16);
return PCI_CPU(result);
}
result = (PciReg(pDomain->pci, tag, off + 3, CARD8) << 24) |
(PciReg(pDomain->pci, tag, off + 2, CARD8) << 16) |
(PciReg(pDomain->pci, tag, off + 1, CARD8) << 8) |
(PciReg(pDomain->pci, tag, off , CARD8) );
return result;
}
static void
sabrePciCfgWrite32(PCITAG tag, int off, CARD32 val)
{
pciBusInfo_t *pBusInfo;
sparcDomainPtr pDomain;
int bus;
if (PCI_BDEV_FROM_TAG(tag))
sparcPciCfgWrite32(tag, off, val);
else if (!PCI_FUNC_FROM_TAG(tag) &&
(off >= 0) && (off <= 252) && !(off & 3) &&
((bus = PCI_BUS_FROM_TAG(tag)) < pciNumBuses) &&
(pBusInfo = pciBusInfo[bus]) &&
(pDomain = pBusInfo->pciBusPriv) &&
(bus == pDomain->bus_min)) {
if (off < 8) {
val = PCI_CPU(val);
PciReg(pDomain->pci, tag, off , CARD16) = val >> 16;
PciReg(pDomain->pci, tag, off + 2, CARD16) = val;
} else {
PciReg(pDomain->pci, tag, off , CARD8) = val;
PciReg(pDomain->pci, tag, off + 1, CARD8) = val >> 8;
PciReg(pDomain->pci, tag, off + 2, CARD8) = val >> 16;
PciReg(pDomain->pci, tag, off + 3, CARD8) = val >> 24;
}
}
}
static void
sabrePciCfgSetBits32(PCITAG tag, int off, CARD32 mask, CARD32 bits)
{
CARD32 PciVal;
PciVal = sabrePciCfgRead32(tag, off);
PciVal &= ~mask;
PciVal |= bits;
sabrePciCfgWrite32(tag, off, PciVal);
}
static pciBusFuncs_t sabrePCIFunctions =
{
sabrePciCfgRead32,
sabrePciCfgWrite32,
sabrePciCfgSetBits32,
pciAddrNOOP,
pciAddrNOOP
};
static int pagemask;
/* Scan PROM for all PCI host bridges in the system */
void
sparcPciInit(void)
{
int node, node2;
if (!xf86LinearVidMem())
return;
apertureFd = open(apertureDevName, O_RDWR);
if (apertureFd < 0) {
xf86Msg(X_ERROR,
"sparcPciInit: open failure: %s\n", strerror(errno));
return;
}
sparcPromInit();
pagemask = xf86getpagesize() - 1;
for (node = promGetChild(promRootNode);
node;
node = promGetSibling(node)) {
unsigned long long pci_addr;
sparcDomainRec domain;
sparcDomainPtr pDomain;
pciBusFuncs_p pFunctions;
char *prop_val;
int prop_len, bus;
prop_val = promGetProperty("name", &prop_len);
/* Some PROMs include the trailing null; some don't */
if (!prop_val || (prop_len < 3) || (prop_len > 4) ||
strcmp(prop_val, "pci"))
continue;
prop_val = promGetProperty("model", &prop_len);
if (!prop_val || (prop_len <= 0)) {
prop_val = promGetProperty("compatible", &prop_len);
if (!prop_val || (prop_len <= 0))
continue;
}
pFunctions = &sparcPCIFunctions;
(void)memset(&domain, 0, sizeof(domain));
if (!strncmp("SUNW,sabre", prop_val, prop_len) ||
!strncmp("pci108e,a000", prop_val, prop_len) ||
!strncmp("pci108e,a001", prop_val, prop_len)) {
/*
* There can only be one "Sabre" bridge in a system. It provides
* PCI configuration space, a 24-bit I/O space and a 32-bit memory
* space, all three of which are at fixed physical CPU addresses.
*/
static Bool sabre_seen = FALSE;
xf86Msg(X_INFO,
"Sabre or Hummingbird PCI host bridge found (\"%s\")\n",
prop_val);
/* There can only be one Sabre */
if (sabre_seen)
continue;
sabre_seen = TRUE;
/* Get "bus-range" property */
prop_val = promGetProperty("bus-range", &prop_len);
if (!prop_val || (prop_len != 8) ||
(((unsigned int *)prop_val)[0]) ||
(((unsigned int *)prop_val)[1] >= 256))
continue;
pci_addr = 0x01fe01000000ull;
domain.io_addr = 0x01fe02000000ull;
domain.io_size = 0x000001000000ull;
domain.mem_addr = 0x01ff00000000ull;
domain.mem_size = 0x000100000000ull;
domain.bus_min = 0; /* Always */
domain.bus_max = ((int *)prop_val)[1];
pFunctions = &sabrePCIFunctions;
} else
if (!strncmp("SUNW,psycho", prop_val, prop_len) ||
!strncmp("pci108e,8000", prop_val, prop_len)) {
/*
* A "Psycho" host bridge provides two PCI interfaces, each with
* its own 16-bit I/O and 31-bit memory spaces. Both share the
* same PCI configuration space. Here, they are assigned separate
* domain numbers to prevent unintentional I/O and/or memory
* resource conflicts.
*/
xf86Msg(X_INFO,
"Psycho PCI host bridge found (\"%s\")\n", prop_val);
/* Get "bus-range" property */
prop_val = promGetProperty("bus-range", &prop_len);
if (!prop_val || (prop_len != 8) ||
(((unsigned int *)prop_val)[1] >= 256) ||
(((unsigned int *)prop_val)[0] > ((unsigned int *)prop_val)[1]))
continue;
domain.bus_min = ((int *)prop_val)[0];
domain.bus_max = ((int *)prop_val)[1];
/* Get "ranges" property */
prop_val = promGetProperty("ranges", &prop_len);
if (!prop_val || (prop_len != 112) ||
prop_val[0] || (prop_val[28] != 0x01u) ||
(prop_val[56] != 0x02u) || (prop_val[84] != 0x03u) ||
(((unsigned int *)prop_val)[4] != 0x01000000u) ||
((unsigned int *)prop_val)[5] ||
((unsigned int *)prop_val)[12] ||
(((unsigned int *)prop_val)[13] != 0x00010000u) ||
((unsigned int *)prop_val)[19] ||
(((unsigned int *)prop_val)[20] != 0x80000000u) ||
((((unsigned int *)prop_val)[11] & ~0x00010000u) !=
0x02000000u) ||
(((unsigned int *)prop_val)[18] & ~0x80000000u) ||
(((unsigned int *)prop_val)[3] !=
((unsigned int *)prop_val)[10]) ||
(((unsigned int *)prop_val)[17] !=
((unsigned int *)prop_val)[24]) ||
(((unsigned int *)prop_val)[18] !=
((unsigned int *)prop_val)[25]) ||
(((unsigned int *)prop_val)[19] !=
((unsigned int *)prop_val)[26]) ||
(((unsigned int *)prop_val)[20] !=
((unsigned int *)prop_val)[27]))
continue;
/* Use memcpy() to avoid alignment issues */
(void)memcpy(&pci_addr, prop_val + 12,
sizeof(pci_addr));
(void)memcpy(&domain.io_addr, prop_val + 40,
sizeof(domain.io_addr));
(void)memcpy(&domain.mem_addr, prop_val + 68,
sizeof(domain.mem_addr));
domain.io_size = 0x000000010000ull;
domain.mem_size = 0x000080000000ull;
} else
if (!strncmp("SUNW,schizo", prop_val, prop_len) ||
!strncmp("pci108e,8001", prop_val, prop_len)) {
/*
* I have no docs on the "Schizo", but judging from the Linux
* kernel, it also provides two PCI domains. Each PCI
* configuration space is the usual 16M in size, followed by a
* variable-length I/O space. Each domain also provides a
* variable-length memory space. The kernel seems to think the I/O
* spaces are 16M long, and the memory spaces, 2G, but these
* assumptions are actually only present in source code comments.
* Sun has, however, confirmed to me the validity of these
* assumptions.
*/
volatile unsigned long long mem_match, mem_mask, io_match, io_mask;
unsigned long Offset;
pointer pSchizo;
xf86Msg(X_INFO,
"Schizo PCI host bridge found (\"%s\")\n", prop_val);
/* Get "bus-range" property */
prop_val = promGetProperty("bus-range", &prop_len);
if (!prop_val || (prop_len != 8) ||
(((unsigned int *)prop_val)[1] >= 256) ||
(((unsigned int *)prop_val)[0] > ((unsigned int *)prop_val)[1]))
continue;
domain.bus_min = ((int *)prop_val)[0];
domain.bus_max = ((int *)prop_val)[1];
/* Get "reg" property */
prop_val = promGetProperty("reg", &prop_len);
if (!prop_val || (prop_len != 48))
continue;
/* Temporarily map some of Schizo's registers */
pSchizo = sparcMapAperture(-1, VIDMEM_MMIO,
((unsigned long long *)prop_val)[2] - 0x000000010000ull,
0x00010000ul);
/* Determine where PCI config, I/O and memory spaces reside */
if ((((unsigned long long *)prop_val)[0] & 0x000000700000ull) ==
0x000000600000ull)
Offset = 0x0040;
else
Offset = 0x0060;
mem_match = PciReg(pSchizo, 0, Offset, unsigned long long);
mem_mask = PciReg(pSchizo, 0, Offset + 8, unsigned long long);
io_match = PciReg(pSchizo, 0, Offset + 16, unsigned long long);
io_mask = PciReg(pSchizo, 0, Offset + 24, unsigned long long);
/* Unmap Schizo registers */
xf86UnMapVidMem(-1, pSchizo, 0x00010000ul);
/* Calculate sizes */
mem_mask = (((mem_mask - 1) ^ mem_mask) >> 1) + 1;
io_mask = (((io_mask - 1) ^ io_mask ) >> 1) + 1;
if (io_mask <= 0x000001000000ull) /* Nothing left for I/O */
continue;
domain.mem_addr = mem_match & ~0x8000000000000000ull;
domain.mem_size = mem_mask;
pci_addr = io_match & ~0x8000000000000000ull;
domain.io_addr = pci_addr + 0x0000000001000000ull;
domain.io_size = io_mask - 0x0000000001000000ull;
} else {
xf86Msg(X_WARNING, "Unknown PCI host bridge: \"%s\"\n", prop_val);
continue;
}
/* Only map as much PCI configuration as we need */
domain.pci = (char *)sparcMapAperture(-1, VIDMEM_MMIO,
pci_addr + PCI_MAKE_TAG(domain.bus_min, 0, 0),
PCI_MAKE_TAG(domain.bus_max - domain.bus_min + 1, 0, 0)) -
PCI_MAKE_TAG(domain.bus_min, 0, 0);
/* Allocate a domain record */
pDomain = xnfalloc(sizeof(sparcDomainRec));
*pDomain = domain;
/*
* Allocate and prime pciBusInfo records. These are allocated one at a
* time because those for empty buses are eventually released.
*/
bus = pDomain->bus_min =
PCI_MAKE_BUS(pciNumDomains, domain.bus_min);
pciNumBuses = pDomain->bus_max =
PCI_MAKE_BUS(pciNumDomains, domain.bus_max) + 1;
pciBusInfo[bus] = xnfcalloc(1, sizeof(pciBusInfo_t));
pciBusInfo[bus]->configMech = PCI_CFG_MECH_OTHER;
pciBusInfo[bus]->numDevices = 32;
pciBusInfo[bus]->funcs = pFunctions;
pciBusInfo[bus]->pciBusPriv = pDomain;
while (++bus < pciNumBuses) {
pciBusInfo[bus] = xnfalloc(sizeof(pciBusInfo_t));
*(pciBusInfo[bus]) = *(pciBusInfo[bus - 1]);
pciBusInfo[bus]->funcs = &sparcPCIFunctions;
}
/* Next domain, please... */
xf86DomainInfo[pciNumDomains++] = pDomain;
/*
* OK, enough of the straight-forward stuff. Time to deal with some
* brokenness...
*
* The PCI specs require that when a bus transaction remains unclaimed
* for too long, the master entity on that bus is to cancel the
* transaction it issued or passed on with a master abort. Two
* outcomes are possible:
*
* - the master abort can be treated as an error that is propogated
* back through the bus tree to the entity that ultimately originated
* the transaction; or
* - the transaction can be allowed to complete normally, which means
* that writes are ignored and reads return all ones.
*
* In the first case, if the CPU happens to be at the tail end of the
* tree path through one of its host bridges, it will be told there is
* a hardware mal-function, despite being generated by software.
*
* For a software function (be it firmware, OS or userland application)
* to determine how a PCI bus tree is populated, it must be able to
* detect when master aborts occur. Obviously, PCI discovery is much
* simpler when master aborts are allowed to complete normally.
*
* Unfortunately, a number of non-Intel PCI implementations have chosen
* to treat master aborts as severe errors. The net effect is to
* cripple PCI discovery algorithms in userland.
*
* On SPARCs, master aborts cause a number of different behaviours,
* including delivering a signal to the userland application, rebooting
* the system, "dropping down" to firmware, or, worst of all, bus
* lockouts. Even in the first case, the SIGBUS signal that is
* eventually generated isn't delivered in a timely enough fashion to
* allow an application to reliably detect the master abort that
* ultimately caused it.
*
* This can be somewhat mitigated. On all architectures, master aborts
* that occur on secondary buses can be forced to complete normally
* because the PCI-to-PCI bridges that serve them are governed by an
* industry-wide specification. (This is just another way of saying
* that whatever justification there might be for erroring out master
* aborts is deemed by the industry as insufficient to generate more
* PCI non-compliance than there already is...)
*
* This leaves us with master aborts that occur on primary buses.
* There is no specification for host-to-PCI bridges. Bridges used in
* SPARCs can be told to ignore all PCI errors, but not specifically
* master aborts. Not only is this too coarse-grained, but
* master-aborted read transactions on the primary bus end up returning
* garbage rather than all ones.
*
* I have elected to work around this the only way I can think of doing
* so right now. The following scans an additional PROM level and
* builds a device/function map for the primary bus. I can only hope
* this PROM information represents all devices on the primary bus,
* rather than only a subset of them.
*
* Master aborts are useful in other ways too, that are not addressed
* here. These include determining whether or not a domain provides
* VGA, or if a PCI device actually implements PCI disablement.
*
* --- TSI @ UQV 2001.09.19
*/
for (node2 = promGetChild(node);
node2;
node2 = promGetSibling(node2)) {
/* Get "reg" property */
prop_val = promGetProperty("reg", &prop_len);
if (!prop_val || (prop_len % 20))
continue;
/*
* It's unnecessary to scan the entire "reg" property, but I'll do
* so anyway.
*/
prop_len /= 20;
for (; prop_len--; prop_val += 20)
SetBitInMap(PCI_DFN_FROM_TAG(*(PCITAG *)prop_val),
pDomain->dfn_mask);
}
/* Assume the host bridge is device 0, function 0 on its bus */
SetBitInMap(0, pDomain->dfn_mask);
}
sparcPromClose();
close(apertureFd);
apertureFd = -1;
}
#ifndef INCLUDE_XF86_NO_DOMAIN
_X_EXPORT int
xf86GetPciDomain(PCITAG Tag)
{
return PCI_DOM_FROM_TAG(Tag);
}
_X_EXPORT pointer
xf86MapDomainMemory(int ScreenNum, int Flags, PCITAG Tag,
ADDRESS Base, unsigned long Size)
{
sparcDomainPtr pDomain;
pointer result;
int domain = PCI_DOM_FROM_TAG(Tag);
if ((domain <= 0) || (domain >= pciNumDomains) ||
!(pDomain = xf86DomainInfo[domain]) ||
(((unsigned long long)Base + (unsigned long long)Size) >
pDomain->mem_size))
FatalError("xf86MapDomainMemory() called with invalid parameters.\n");
result = sparcMapAperture(ScreenNum, Flags, pDomain->mem_addr + Base, Size);
if (apertureFd >= 0) {
close(apertureFd);
apertureFd = -1;
}
return result;
}
_X_EXPORT IOADDRESS
xf86MapLegacyIO(int ScreenNum, int Flags, PCITAG Tag,
IOADDRESS Base, unsigned long Size)
{
sparcDomainPtr pDomain;
int domain = PCI_DOM_FROM_TAG(Tag);
if ((domain <= 0) || (domain >= pciNumDomains) ||
!(pDomain = xf86DomainInfo[domain]) ||
(((unsigned long long)Base + (unsigned long long)Size) >
pDomain->io_size))
FatalError("xf86MapLegacyIO() called with invalid parameters.\n");
/* Permanently map all of I/O space */
if (!pDomain->io) {
pDomain->io = sparcMapAperture(ScreenNum, Flags,
pDomain->io_addr, pDomain->io_size);
if (apertureFd >= 0) {
close(apertureFd);
apertureFd = -1;
}
}
return (IOADDRESS)pDomain->io + Base;
}
resPtr
xf86AccResFromOS(resPtr pRes)
{
sparcDomainPtr pDomain;
resRange range;
int domain;
for (domain = 1; domain < pciNumDomains; domain++) {
if (!(pDomain = xf86DomainInfo[domain]))
continue;
/*
* At minimum, the top and bottom resources must be claimed, so that
* resources that are (or appear to be) unallocated can be relocated.
*/
RANGE(range, 0x00000000u, 0x0009ffffu,
RANGE_TYPE(ResExcMemBlock, domain));
pRes = xf86AddResToList(pRes, &range, -1);
RANGE(range, 0x000c0000u, 0x000effffu,
RANGE_TYPE(ResExcMemBlock, domain));
pRes = xf86AddResToList(pRes, &range, -1);
RANGE(range, 0x000f0000u, 0x000fffffu,
RANGE_TYPE(ResExcMemBlock, domain));
pRes = xf86AddResToList(pRes, &range, -1);
RANGE(range, pDomain->mem_size - 1, pDomain->mem_size - 1,
RANGE_TYPE(ResExcMemBlock, domain));
pRes = xf86AddResToList(pRes, &range, -1);
RANGE(range, 0x00000000u, 0x00000000u,
RANGE_TYPE(ResExcIoBlock, domain));
pRes = xf86AddResToList(pRes, &range, -1);
RANGE(range, pDomain->io_size - 1, pDomain->io_size - 1,
RANGE_TYPE(ResExcIoBlock, domain));
pRes = xf86AddResToList(pRes, &range, -1);
}
return pRes;
}
#endif /* !INCLUDE_XF86_NO_DOMAIN */
#endif /* defined(sun) */
#if defined(ARCH_PCI_PCI_BRIDGE)
/* Definitions specific to Sun's APB P2P bridge (a.k.a. Simba) */
#define APB_IO_ADDRESS_MAP 0xDE
#define APB_MEM_ADDRESS_MAP 0xDF
/*
* Simba's can only occur on bus 0. Furthermore, Simba's must have a non-zero
* device/function number because the Sabre interface they must connect to
* occupies the 0:0:0 slot. Also, there can be only one Sabre interface in the
* system, and therefore, only one Simba function can route any particular
* resource. Thus, it is appropriate to use a single set of static variables
* to hold the tag of the Simba function routing a VGA resource range at any
* one time, and to test these variables for non-zero to determine whether or
* not the Sabre would master-abort a VGA access (and kill the system).
*
* The trick is to determine when it is safe to re-route VGA, because doing so
* re-routes much more.
*/
static PCITAG simbavgaIOTag = 0, simbavgaMemTag = 0;
static Bool simbavgaRoutingAllow = TRUE;
/*
* Scan the bus subtree rooted at 'bus' for a non-display device that might be
* decoding the bottom 2 MB of I/O space and/or the bottom 512 MB of memory
* space. Reset simbavgaRoutingAllow if such a device is found.
*
* XXX For now, this is very conservative and should be made less so as the
* need arises.
*/
static void
simbaCheckBus(CARD16 pcicommand, int bus)
{
pciConfigPtr pPCI, *ppPCI = xf86scanpci(0);
while ((pPCI = *ppPCI++)) {
if (pPCI->busnum < bus)
continue;
if (pPCI->busnum > bus)
break;
/* XXX Assume all devices respect PCI disablement */
if (!(pcicommand & pPCI->pci_command))
continue;
/* XXX This doesn't deal with mis-advertised classes */
switch (pPCI->pci_base_class) {
case PCI_CLASS_PREHISTORIC:
if (pPCI->pci_sub_class == PCI_SUBCLASS_PREHISTORIC_VGA)
continue; /* Ignore VGA */
break;
case PCI_CLASS_DISPLAY:
continue;
case PCI_CLASS_BRIDGE:
switch (pPCI->pci_sub_class) {
case PCI_SUBCLASS_BRIDGE_PCI:
case PCI_SUBCLASS_BRIDGE_CARDBUS:
/* Scan secondary bus */
/* XXX First check bridge routing? */
simbaCheckBus(pcicommand & pPCI->pci_command,
PCI_SECONDARY_BUS_EXTRACT(pPCI->pci_pp_bus_register,
pPCI->tag));
if (!simbavgaRoutingAllow)
return;
default:
break;
}
default:
break;
}
/*
* XXX We could check the device's bases here, but PCI doesn't limit
* the device's decoding to them.
*/
simbavgaRoutingAllow = FALSE;
break;
}
}
static pciConfigPtr
simbaVerifyBus(int bus)
{
pciConfigPtr pPCI;
if ((bus < 0) || (bus >= pciNumBuses) ||
!pciBusInfo[bus] || !(pPCI = pciBusInfo[bus]->bridge) ||
(pPCI->pci_device_vendor != DEVID(VENDOR_SUN, CHIP_SIMBA)))
return NULL;
return pPCI;
}
static CARD16
simbaControlBridge(int bus, CARD16 mask, CARD16 value)
{
pciConfigPtr pPCI;
CARD16 current = 0, tmp;
CARD8 iomap, memmap;
if ((pPCI = simbaVerifyBus(bus))) {
/*
* The Simba does not implement VGA enablement as described in the P2P
* spec. It does however route I/O and memory in large enough chunks
* so that we can determine were VGA resources would be routed
* (including ISA VGA I/O aliases). We can allow changes to that
* routing only under certain circumstances.
*/
iomap = pciReadByte(pPCI->tag, APB_IO_ADDRESS_MAP);
memmap = pciReadByte(pPCI->tag, APB_MEM_ADDRESS_MAP);
if (iomap & memmap & 0x01) {
current |= PCI_PCI_BRIDGE_VGA_EN;
if ((mask & PCI_PCI_BRIDGE_VGA_EN) &&
!(value & PCI_PCI_BRIDGE_VGA_EN)) {
if (!simbavgaRoutingAllow) {
xf86MsgVerb(X_WARNING, 3, "Attempt to disable VGA routing"
" through Simba at %x:%x:%x disallowed.\n",
pPCI->busnum, pPCI->devnum, pPCI->funcnum);
value |= PCI_PCI_BRIDGE_VGA_EN;
} else {
pciWriteByte(pPCI->tag, APB_IO_ADDRESS_MAP,
iomap & ~0x01);
pciWriteByte(pPCI->tag, APB_MEM_ADDRESS_MAP,
memmap & ~0x01);
simbavgaIOTag = simbavgaMemTag = 0;
}
}
} else {
if (mask & value & PCI_PCI_BRIDGE_VGA_EN) {
if (!simbavgaRoutingAllow) {
xf86MsgVerb(X_WARNING, 3, "Attempt to enable VGA routing"
" through Simba at %x:%x:%x disallowed.\n",
pPCI->busnum, pPCI->devnum, pPCI->funcnum);
value &= ~PCI_PCI_BRIDGE_VGA_EN;
} else {
if (pPCI->tag != simbavgaIOTag) {
if (simbavgaIOTag) {
tmp = pciReadByte(simbavgaIOTag,
APB_IO_ADDRESS_MAP);
pciWriteByte(simbavgaIOTag, APB_IO_ADDRESS_MAP,
tmp & ~0x01);
}
pciWriteByte(pPCI->tag, APB_IO_ADDRESS_MAP,
iomap | 0x01);
simbavgaIOTag = pPCI->tag;
}
if (pPCI->tag != simbavgaMemTag) {
if (simbavgaMemTag) {
tmp = pciReadByte(simbavgaMemTag,
APB_MEM_ADDRESS_MAP);
pciWriteByte(simbavgaMemTag, APB_MEM_ADDRESS_MAP,
tmp & ~0x01);
}
pciWriteByte(pPCI->tag, APB_MEM_ADDRESS_MAP,
memmap | 0x01);
simbavgaMemTag = pPCI->tag;
}
}
}
}
/* Move on to master abort failure enablement (as per P2P spec) */
tmp = pciReadWord(pPCI->tag, PCI_PCI_BRIDGE_CONTROL_REG);
current |= tmp;
if (tmp & PCI_PCI_BRIDGE_MASTER_ABORT_EN) {
if ((mask & PCI_PCI_BRIDGE_MASTER_ABORT_EN) &&
!(value & PCI_PCI_BRIDGE_MASTER_ABORT_EN))
pciWriteWord(pPCI->tag, PCI_PCI_BRIDGE_CONTROL_REG,
tmp & ~PCI_PCI_BRIDGE_MASTER_ABORT_EN);
} else {
if (mask & value & PCI_PCI_BRIDGE_MASTER_ABORT_EN)
pciWriteWord(pPCI->tag, PCI_PCI_BRIDGE_CONTROL_REG,
tmp | PCI_PCI_BRIDGE_MASTER_ABORT_EN);
}
/* Insert emulation of other P2P controls here */
}
return (current & ~mask) | (value & mask);
}
static void
simbaGetBridgeResources(int bus,
pointer *ppIoRes,
pointer *ppMemRes,
pointer *ppPmemRes)
{
pciConfigPtr pPCI = simbaVerifyBus(bus);
resRange range;
int i;
if (!pPCI)
return;
if (ppIoRes) {
xf86FreeResList(*ppIoRes);
*ppIoRes = NULL;
if (pPCI->pci_command & PCI_CMD_IO_ENABLE) {
unsigned char iomap = pciReadByte(pPCI->tag, APB_IO_ADDRESS_MAP);
if (simbavgaRoutingAllow)
iomap |= 0x01;
for (i = 0; i < 8; i++) {
if (iomap & (1 << i)) {
RANGE(range, i << 21, ((i + 1) << 21) - 1,
RANGE_TYPE(ResExcIoBlock,
xf86GetPciDomain(pPCI->tag)));
*ppIoRes = xf86AddResToList(*ppIoRes, &range, -1);
}
}
}
}
if (ppMemRes) {
xf86FreeResList(*ppMemRes);
*ppMemRes = NULL;
if (pPCI->pci_command & PCI_CMD_MEM_ENABLE) {
unsigned char memmap = pciReadByte(pPCI->tag, APB_MEM_ADDRESS_MAP);
if (simbavgaRoutingAllow)
memmap |= 0x01;
for (i = 0; i < 8; i++) {
if (memmap & (1 << i)) {
RANGE(range, i << 29, ((i + 1) << 29) - 1,
RANGE_TYPE(ResExcMemBlock,
xf86GetPciDomain(pPCI->tag)));
*ppMemRes = xf86AddResToList(*ppMemRes, &range, -1);
}
}
}
}
if (ppPmemRes) {
xf86FreeResList(*ppPmemRes);
*ppPmemRes = NULL;
}
}
void ARCH_PCI_PCI_BRIDGE(pciConfigPtr pPCI)
{
static pciBusFuncs_t simbaBusFuncs;
pciBusInfo_t *pBusInfo;
CARD16 pcicommand;
if (pPCI->pci_device_vendor != DEVID(VENDOR_SUN, CHIP_SIMBA))
return;
pBusInfo = pPCI->businfo;
simbaBusFuncs = *(pBusInfo->funcs);
simbaBusFuncs.pciControlBridge = simbaControlBridge;
simbaBusFuncs.pciGetBridgeResources = simbaGetBridgeResources;
pBusInfo->funcs = &simbaBusFuncs;
if (!simbavgaRoutingAllow)
return;
pcicommand = 0;
if (pciReadByte(pPCI->tag, APB_IO_ADDRESS_MAP) & 0x01) {
pcicommand |= PCI_CMD_IO_ENABLE;
simbavgaIOTag = pPCI->tag;
}
if (pciReadByte(pPCI->tag, APB_MEM_ADDRESS_MAP) & 0x01) {
pcicommand |= PCI_CMD_MEM_ENABLE;
simbavgaMemTag = pPCI->tag;
}
if (!pcicommand)
return;
simbaCheckBus(pcicommand,
PCI_SECONDARY_BUS_EXTRACT(pPCI->pci_pp_bus_register, pPCI->tag));
}
#endif /* defined(ARCH_PCI_PCI_BRIDGE) */
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