| blob | bdb8ea100e73ee8637c8ea587378000292b0b37b |
1 /*
2 * Contains common pci routines for ALL ppc platform
3 * (based on pci_32.c and pci_64.c)
4 *
5 * Port for PPC64 David Engebretsen, IBM Corp.
6 * Contains common pci routines for ppc64 platform, pSeries and iSeries brands.
7 *
8 * Copyright (C) 2003 Anton Blanchard <anton@au.ibm.com>, IBM
9 * Rework, based on alpha PCI code.
10 *
11 * Common pmac/prep/chrp pci routines. -- Cort
12 *
13 * This program is free software; you can redistribute it and/or
14 * modify it under the terms of the GNU General Public License
15 * as published by the Free Software Foundation; either version
16 * 2 of the License, or (at your option) any later version.
17 */
19 #include <linux/kernel.h>
20 #include <linux/pci.h>
21 #include <linux/string.h>
22 #include <linux/init.h>
23 #include <linux/bootmem.h>
24 #include <linux/mm.h>
25 #include <linux/list.h>
26 #include <linux/syscalls.h>
27 #include <linux/irq.h>
28 #include <linux/vmalloc.h>
29 #include <linux/slab.h>
30 #include <linux/of.h>
31 #include <linux/of_address.h>
32 #include <linux/of_pci.h>
33 #include <linux/export.h>
35 #include <asm/processor.h>
36 #include <linux/io.h>
37 #include <asm/pci-bridge.h>
38 #include <asm/byteorder.h>
43 /* XXX kill that some day ... */
46 /* ISA Memory physical address */
47 resource_size_t isa_mem_base;
57 {
59 }
62 {
64 }
68 {
81 }
84 {
91 }
94 {
96 }
99 {
102 resource_size_t size;
111 }
112 }
115 }
118 {
120 resource_size_t size;
132 }
133 }
137 }
140 /*
141 * Return the domain number for this bus.
142 */
144 {
148 }
151 /* This routine is meant to be used early during boot, when the
152 * PCI bus numbers have not yet been assigned, and you need to
153 * issue PCI config cycles to an OF device.
154 * It could also be used to "fix" RTAS config cycles if you want
155 * to set pci_assign_all_buses to 1 and still use RTAS for PCI
156 * config cycles.
157 */
159 {
166 }
168 }
172 {
181 }
184 /* Add sysfs properties */
186 {
188 }
191 {
192 /* No special bus mastering setup handling */
193 }
195 /*
196 * Reads the interrupt pin to determine if interrupt is use by card.
197 * If the interrupt is used, then gets the interrupt line from the
198 * openfirmware and sets it in the pci_dev and pci_config line.
199 */
201 {
205 /* The current device-tree that iSeries generates from the HV
206 * PCI informations doesn't contain proper interrupt routing,
207 * and all the fallback would do is print out crap, so we
208 * don't attempt to resolve the interrupts here at all, some
209 * iSeries specific fixup does it.
210 *
211 * In the long run, we will hopefully fix the generated device-tree
212 * instead.
213 */
216 #ifdef DEBUG
218 #endif
219 /* Try to get a mapping from the device-tree */
223 /* If that fails, lets fallback to what is in the config
224 * space and map that through the default controller. We
225 * also set the type to level low since that's what PCI
226 * interrupts are. If your platform does differently, then
227 * either provide a proper interrupt tree or don't use this
228 * function.
229 */
237 }
251 }
255 }
262 }
265 /*
266 * Platform support for /proc/bus/pci/X/Y mmap()s,
267 * modelled on the sparc64 implementation by Dave Miller.
268 * -- paulus.
269 */
271 /*
272 * Adjust vm_pgoff of VMA such that it is the physical page offset
273 * corresponding to the 32-bit pci bus offset for DEV requested by the user.
274 *
275 * Basically, the user finds the base address for his device which he wishes
276 * to mmap. They read the 32-bit value from the config space base register,
277 * add whatever PAGE_SIZE multiple offset they wish, and feed this into the
278 * offset parameter of mmap on /proc/bus/pci/XXX for that device.
279 *
280 * Returns negative error code on failure, zero on success.
281 */
285 {
293 /* If memory, add on the PCI bridge address offset */
297 #endif
303 }
305 /*
306 * Check that the offset requested corresponds to one of the
307 * resources of the device.
308 */
313 /* treat ROM as memory (should be already) */
317 /* Active and same type? */
321 /* In the range of this resource? */
325 /* found it! construct the final physical address */
329 }
332 }
334 /*
335 * Set vm_page_prot of VMA, as appropriate for this architecture, for a pci
336 * device mapping.
337 */
339 pgprot_t protection,
342 {
345 /* Write combine is always 0 on non-memory space mappings. On
346 * memory space, if the user didn't pass 1, we check for a
347 * "prefetchable" resource. This is a bit hackish, but we use
348 * this to workaround the inability of /sysfs to provide a write
349 * combine bit
350 */
356 }
359 }
361 /*
362 * This one is used by /dev/mem and fbdev who have no clue about the
363 * PCI device, it tries to find the PCI device first and calls the
364 * above routine
365 */
369 pgprot_t prot)
370 {
385 /* Active and same type? */
388 /* In the range of this resource? */
394 }
397 }
402 }
408 }
410 /*
411 * Perform the actual remap of the pages for a PCI device mapping, as
412 * appropriate for this architecture. The region in the process to map
413 * is described by vm_start and vm_end members of VMA, the base physical
414 * address is found in vm_pgoff.
415 * The pci device structure is provided so that architectures may make mapping
416 * decisions on a per-device or per-bus basis.
417 *
418 * Returns a negative error code on failure, zero on success.
419 */
422 {
423 resource_size_t offset =
441 }
443 /* This provides legacy IO read access on a bus */
445 {
451 /* Check if port can be supported by that bus. We only check
452 * the ranges of the PHB though, not the bus itself as the rules
453 * for forwarding legacy cycles down bridges are not our problem
454 * here. So if the host bridge supports it, we do it.
455 */
479 }
481 }
483 /* This provides legacy IO write access on a bus */
485 {
491 /* Check if port can be supported by that bus. We only check
492 * the ranges of the PHB though, not the bus itself as the rules
493 * for forwarding legacy cycles down bridges are not our problem
494 * here. So if the host bridge supports it, we do it.
495 */
505 /* WARNING: The generic code is idiotic. It gets passed a pointer
506 * to what can be a 1, 2 or 4 byte quantity and always reads that
507 * as a u32, which means that we have to correct the location of
508 * the data read within those 32 bits for size 1 and 2
509 */
524 }
526 }
528 /* This provides legacy IO or memory mmap access on a bus */
532 {
534 resource_size_t offset =
546 /* Hack alert !
547 *
548 * Because X is lame and can fail starting if it gets an error
549 * trying to mmap legacy_mem (instead of just moving on without
550 * legacy memory access) we fake it here by giving it anonymous
551 * memory, effectively behaving just like /dev/zero
552 */
554 #ifdef CONFIG_MMU
559 #endif
563 }
567 _IO_BASE;
575 }
583 }
588 {
598 /* We pass a fully fixed up address to userland for MMIO instead of
599 * a BAR value because X is lame and expects to be able to use that
600 * to pass to /dev/mem !
601 *
602 * That means that we'll have potentially 64 bits values where some
603 * userland apps only expect 32 (like X itself since it thinks only
604 * Sparc has 64 bits MMIO) but if we don't do that, we break it on
605 * 32 bits CHRPs :-(
606 *
607 * Hopefully, the sysfs insterface is immune to that gunk. Once X
608 * has been fixed (and the fix spread enough), we can re-enable the
609 * 2 lines below and pass down a BAR value to userland. In that case
610 * we'll also have to re-enable the matching code in
611 * __pci_mmap_make_offset().
612 *
613 * BenH.
614 */
615 #if 0
618 #endif
622 }
624 /**
625 * pci_process_bridge_OF_ranges - Parse PCI bridge resources from device tree
626 * @hose: newly allocated pci_controller to be setup
627 * @dev: device node of the host bridge
628 * @primary: set if primary bus (32 bits only, soon to be deprecated)
629 *
630 * This function will parse the "ranges" property of a PCI host bridge device
631 * node and setup the resource mapping of a pci controller based on its
632 * content.
633 *
634 * Life would be boring if it wasn't for a few issues that we have to deal
635 * with here:
636 *
637 * - We can only cope with one IO space range and up to 3 Memory space
638 * ranges. However, some machines (thanks Apple !) tend to split their
639 * space into lots of small contiguous ranges. So we have to coalesce.
640 *
641 * - We can only cope with all memory ranges having the same offset
642 * between CPU addresses and PCI addresses. Unfortunately, some bridges
643 * are setup for a large 1:1 mapping along with a small "window" which
644 * maps PCI address 0 to some arbitrary high address of the CPU space in
645 * order to give access to the ISA memory hole.
646 * The way out of here that I've chosen for now is to always set the
647 * offset based on the first resource found, then override it if we
648 * have a different offset and the previous was set by an ISA hole.
649 *
650 * - Some busses have IO space not starting at 0, which causes trouble with
651 * the way we do our IO resource renumbering. The code somewhat deals with
652 * it for 64 bits but I would expect problems on 32 bits.
653 *
654 * - Some 32 bits platforms such as 4xx can have physical space larger than
655 * 32 bits so we need to use 64 bits values for the parsing
656 */
659 {
665 u32 pci_space;
673 /* Get ranges property */
678 /* Parse it */
681 /* Read next ranges element */
694 /* If we failed translation or got a zero-sized region
695 * (some FW try to feed us with non sensical zero sized regions
696 * such as power3 which look like some kind of attempt
697 * at exposing the VGA memory hole)
698 */
702 /* Now consume following elements while they are contiguous */
713 }
715 /* Act based on address space type */
722 /* We support only one IO range */
726 }
727 /* On 32 bits, limit I/O space to 16MB */
731 /* 32 bits needs to map IOs here */
734 /* Expect trouble if pci_addr is not 0 */
736 isa_io_base =
738 /* pci_io_size and io_base_phys always represent IO
739 * space starting at 0 so we factor in pci_addr
740 */
744 /* Build resource */
755 /* We support only 3 memory ranges */
759 }
760 /* Handles ISA memory hole space here */
768 }
770 /* We get the PCI/Mem offset from the first range or
771 * the, current one if the offset came from an ISA
772 * hole. If they don't match, bugger.
773 */
782 }
784 /* Build resource */
791 }
798 }
799 }
801 /* If there's an ISA hole and the pci_mem_offset is -not- matching
802 * the ISA hole offset, then we need to remove the ISA hole from
803 * the resource list for that brige
804 */
813 }
814 }
816 /* Decide whether to display the domain number in /proc */
818 {
820 }
822 /* This header fixup will do the resource fixup for all devices as they are
823 * probed, but not for bridge ranges
824 */
826 {
834 }
850 }
857 }
858 }
861 /* This function tries to figure out if a bridge resource has been initialized
862 * by the firmware or not. It doesn't have to be absolutely bullet proof, but
863 * things go more smoothly when it gets it right. It should covers cases such
864 * as Apple "closed" bridge resources and bare-metal pSeries unassigned bridges
865 */
868 {
871 resource_size_t offset;
872 u16 command;
875 /* Job is a bit different between memory and IO */
877 /* If the BAR is non-0 (res != pci_mem_offset) then it's
878 * probably been initialized by somebody
879 */
883 /* The BAR is 0, let's check if memory decoding is enabled on
884 * the bridge. If not, we consider it unassigned
885 */
890 /* Memory decoding is enabled and the BAR is 0. If any of
891 * the bridge resources covers that starting address (0 then
892 * it's good enough for us for memory
893 */
898 }
900 /* Well, it starts at 0 and we know it will collide so we may as
901 * well consider it as unassigned. That covers the Apple case.
902 */
905 /* If the BAR is non-0, then we consider it assigned */
910 /* Here, we are a bit different than memory as typically IO
911 * space starting at low addresses -is- valid. What we do
912 * instead if that we consider as unassigned anything that
913 * doesn't have IO enabled in the PCI command register,
914 * and that's it.
915 */
920 /* It's starting at 0 and IO is disabled in the bridge, consider
921 * it unassigned
922 */
924 }
925 }
927 /* Fixup resources of a PCI<->PCI bridge */
929 {
949 /* Try to detect uninitialized P2P bridge resources,
950 * and clear them out so they get re-assigned later
951 */
961 }
962 }
963 }
966 {
967 /* Fix up the bus resources for P2P bridges */
970 }
973 {
980 /* Setup OF node pointer in archdata */
983 /* Fixup NUMA node as it may not be setup yet by the generic
984 * code and is needed by the DMA init
985 */
988 /* Hook up default DMA ops */
992 /* Read default IRQs and fixup if necessary */
994 }
995 }
998 {
999 /* When called from the generic PCI probe, read PCI<->PCI bridge
1000 * bases. This is -not- called when generating the PCI tree from
1001 * the OF device-tree.
1002 */
1006 /* Now fixup the bus bus */
1009 /* Now fixup devices on that bus */
1011 }
1015 {
1017 }
1019 /*
1020 * We need to avoid collisions with `mirrored' VGA ports
1021 * and other strange ISA hardware, so we always want the
1022 * addresses to be allocated in the 0x000-0x0ff region
1023 * modulo 0x400.
1024 *
1025 * Why? Because some silly external IO cards only decode
1026 * the low 10 bits of the IO address. The 0x00-0xff region
1027 * is reserved for motherboard devices that decode all 16
1028 * bits, so it's ok to allocate at, say, 0x2800-0x28ff,
1029 * but we want to try to avoid allocating at 0x2900-0x2bff
1030 * which might have be mirrored at 0x0100-0x03ff..
1031 */
1034 {
1043 }
1046 }
1049 /*
1050 * Reparent resource children of pr that conflict with res
1051 * under res, and make res replace those children.
1052 */
1055 {
1068 }
1082 }
1084 }
1086 /*
1087 * Handle resources of PCI devices. If the world were perfect, we could
1088 * just allocate all the resource regions and do nothing more. It isn't.
1089 * On the other hand, we cannot just re-allocate all devices, as it would
1090 * require us to know lots of host bridge internals. So we attempt to
1091 * keep as much of the original configuration as possible, but tweak it
1092 * when it's found to be wrong.
1093 *
1094 * Known BIOS problems we have to work around:
1095 * - I/O or memory regions not configured
1096 * - regions configured, but not enabled in the command register
1097 * - bogus I/O addresses above 64K used
1098 * - expansion ROMs left enabled (this may sound harmless, but given
1099 * the fact the PCI specs explicitly allow address decoders to be
1100 * shared between expansion ROMs and other resource regions, it's
1101 * at least dangerous)
1102 *
1103 * Our solution:
1104 * (1) Allocate resources for all buses behind PCI-to-PCI bridges.
1105 * This gives us fixed barriers on where we can allocate.
1106 * (2) Allocate resources for all enabled devices. If there is
1107 * a collision, just mark the resource as unallocated. Also
1108 * disable expansion ROMs during this step.
1109 * (3) Try to allocate resources for disabled devices. If the
1110 * resources were assigned correctly, everything goes well,
1111 * if they weren't, they won't disturb allocation of other
1112 * resources.
1113 * (4) Assign new addresses to resources which were either
1114 * not configured at all or misconfigured. If explicitly
1115 * requested by the user, configure expansion ROM address
1116 * as well.
1117 */
1120 {
1136 /* Don't bother with non-root busses when
1137 * re-assigning all resources. We clear the
1138 * resource flags as if they were colliding
1139 * and as such ensure proper re-allocation
1140 * later.
1141 */
1144 /* this happens when the generic PCI
1145 * code (wrongly) decides that this
1146 * bridge is transparent -- paulus
1147 */
1149 }
1150 }
1164 /*
1165 * Must be a conflict with an existing entry.
1166 * Move that entry (or entries) under the
1167 * bridge resource and try again.
1168 */
1171 }
1176 }
1180 }
1183 {
1199 pr,
1203 /* We'll assign a new address later */
1207 }
1208 }
1211 {
1214 u16 command;
1225 /* We only allocate ROMs on pass 1 just in case they
1226 * have been screwed up by firmware
1227 */
1232 else
1236 }
1241 /* Turn the ROM off, leave the resource region,
1242 * but keep it unregistered.
1243 */
1244 u32 reg;
1252 }
1253 }
1254 }
1255 }
1258 {
1260 resource_size_t offset;
1267 /* Check for IO */
1282 }
1284 no_io:
1285 /* Check for memory */
1296 }
1310 }
1311 }
1314 {
1317 /* Allocate and assign resources. If we re-assign everything, then
1318 * we skip the allocate phase
1319 */
1326 /* Before we start assigning unassigned resource, we try to reserve
1327 * the low IO area and the VGA memory area if they intersect the
1328 * bus available resources to avoid allocating things on top of them
1329 */
1333 /* Now proceed to assigning things that were left unassigned */
1336 }
1338 /* This is used by the PCI hotplug driver to allocate resource
1339 * of newly plugged busses. We can try to consolidate with the
1340 * rest of the code later, for now, keep it as-is as our main
1341 * resource allocation function doesn't deal with sub-trees yet.
1342 */
1344 {
1364 }
1365 }
1369 }
1373 /* pcibios_finish_adding_to_bus
1374 *
1375 * This is to be called by the hotplug code after devices have been
1376 * added to a bus, this include calling it for a PHB that is just
1377 * being added
1378 */
1380 {
1384 /* Allocate bus and devices resources */
1388 /* Add new devices to global lists. Register in proc, sysfs. */
1391 /* Fixup EEH */
1392 /* eeh_add_device_tree_late(bus); */
1393 }
1397 {
1399 }
1403 {
1408 /* Hookup PHB IO resource */
1411 /* Fixup IO space offset */
1420 /* Workaround for lack of IO resource only on 32-bit */
1424 }
1433 /* Hookup PHB Memory resources */
1443 /* Workaround for lack of MEM resource only on 32-bit */
1448 }
1455 }
1461 }
1464 {
1468 }
1471 {
1487 }
1492 }
1495 {
1501 /* Scan all of the recorded PCI controllers. */
1507 }
1510 /* Call common code to handle resource allocation */
1514 }
1519 {
1526 }
1528 /* Provide information on locations of various I/O regions in physical
1529 * memory. Do this on a per-card basis so that we choose the right
1530 * root bridge.
1531 * Note that the returned IO or memory base is a physical address
1532 */
1535 {
1554 }
1557 }
1559 /*
1560 * Null PCI config access functions, for the case when we can't
1561 * find a hose.
1562 */
1563 #define NULL_PCI_OP(rw, size, type) \
1564 static int \
1565 null_##rw##_config_##size(struct pci_dev *dev, int offset, type val) \
1566 { \
1567 return PCIBIOS_DEVICE_NOT_FOUND; \
1568 }
1570 static int
1573 {
1575 }
1577 static int
1580 {
1582 }
1587 };
1589 /*
1590 * These functions are used early on before PCI scanning is done
1591 * and all of the pci_dev and pci_bus structures have been created.
1592 */
1595 {
1605 }
1607 #define EARLY_PCI_OP(rw, size, type) \
1608 int early_##rw##_config_##size(struct pci_controller *hose, int bus, \
1609 int devfn, int offset, type value) \
1610 { \
1611 return pci_bus_##rw##_config_##size(fake_pci_bus(hose, bus), \
1612 devfn, offset, value); \
1613 }
1624 {
1626 }