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[/] [openrisc/] [trunk/] [rtos/] [rtems/] [c/] [src/] [lib/] [libbsp/] [powerpc/] [shared/] [bootloader/] [pci.c] - Rev 173
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/* * pci.c -- Crude pci handling for early boot. * * Copyright (C) 1998, 1999 Gabriel Paubert, paubert@iram.es * * Modified to compile in RTEMS development environment * by Eric Valette * * Copyright (C) 1999 Eric Valette. valette@crf.canon.fr * * The license and distribution terms for this file may be * found in found in the file LICENSE in this distribution or at * http://www.OARcorp.com/rtems/license.html. * * $Id: pci.c,v 1.2 2001-09-27 12:01:06 chris Exp $ */ #include <sys/types.h> #include <libcpu/spr.h> #include "bootldr.h" #include "pci.h" #include <libcpu/io.h> #include <bsp/consoleIo.h> typedef unsigned int u32; /*#define DEBUG*/ /* Used to reorganize PCI space on stupid machines which spread resources * across a wide address space. This is bad when P2P bridges are present * or when it limits the mappings that a resource hog like a PCI<->VME * bridge can use. */ typedef struct _pci_resource { struct _pci_resource *next; struct pci_dev *dev; u_long base; /* will be 64 bits on 64 bits machines */ u_long size; u_char type; /* 1 is I/O else low order 4 bits of the memory type */ u_char reg; /* Register # in conf space header */ u_short cmd; /* Original cmd byte */ } pci_resource; typedef struct _pci_area { struct _pci_area *next; u_long start; u_long end; struct pci_bus *bus; u_int flags; } pci_area; typedef struct _pci_area_head { pci_area *head; u_long mask; int high; /* To allocate from top */ } pci_area_head; #define PCI_AREA_PREFETCHABLE 0 #define PCI_AREA_MEMORY 1 #define PCI_AREA_IO 2 struct _pci_private { volatile u_int * config_addr; volatile u_char * config_data; struct pci_dev **last_dev_p; struct pci_bus pci_root; pci_resource *resources; pci_area_head io, mem; } pci_private = { config_addr: NULL, config_data: (volatile u_char *) 0x80800000, last_dev_p: NULL, resources: NULL, io: {NULL, 0xfff, 0}, mem: {NULL, 0xfffff, 0} }; #define pci ((struct _pci_private *)(bd->pci_private)) #define pci_root pci->pci_root #if !defined(DEBUG) #undef PCI_DEBUG /* #else #define PCI_DEBUG */ #endif #if defined(PCI_DEBUG) static void print_pci_resources(const char *s) { pci_resource *p; printk("%s", s); for (p=pci->resources; p; p=p->next) { printk(" %p:%p %06x %08lx %08lx %d\n", p, p->next, (p->dev->devfn<<8)+(p->dev->bus->number<<16) +0x10+p->reg*4, p->base, p->size, p->type); } } static void print_pci_area(pci_area *p) { for (; p; p=p->next) { printk(" %p:%p %p %08lx %08lx\n", p, p->next, p->bus, p->start, p->end); } } static void print_pci_areas(const char *s) { printk("%s PCI I/O areas:\n",s); print_pci_area(pci->io.head); printk(" PCI memory areas:\n"); print_pci_area(pci->mem.head); } #else #define print_pci_areas(x) #define print_pci_resources(x) #endif /* Maybe there are some devices who use a size different * from the alignment. For now we assume both are the same. * The blacklist might be used for other weird things in the future too, * since weird non PCI complying devices seem to proliferate these days. */ struct blacklist_entry { u_short vendor, device; u_char reg; u_long actual_size; }; #define BLACKLIST(vid, did, breg, actual_size) \ {PCI_VENDOR_ID_##vid, PCI_DEVICE_ID_##vid##_##did, breg, actual_size} static struct blacklist_entry blacklist[] = { BLACKLIST(S3, TRIO, 0, 0x04000000), {0xffff, 0, 0, 0} }; /* This function filters resources and then inserts them into a list of * configurable pci resources. */ #define AREA(r) \ (((r->type&PCI_BASE_ADDRESS_SPACE)==PCI_BASE_ADDRESS_SPACE_IO) ? PCI_AREA_IO :\ ((r->type&PCI_BASE_ADDRESS_MEM_PREFETCH) ? PCI_AREA_PREFETCHABLE :\ PCI_AREA_MEMORY)) static int insert_before(pci_resource *e, pci_resource *t) { if (e->dev->bus->number != t->dev->bus->number) return e->dev->bus->number > t->dev->bus->number; if (AREA(e) != AREA(t)) return AREA(e)<AREA(t); return (e->size > t->size); } static void insert_resource(pci_resource *r) { struct blacklist_entry *b; pci_resource *p; if (!r) return; /* First fixup in case we have a blacklist entry. Note that this * may temporarily leave a resource in an inconsistent state: with * (base & (size-1)) !=0. This is harmless. */ for (b=blacklist; b->vendor!=0xffff; b++) { if ((r->dev->vendor==b->vendor) && (r->dev->device==b->device) && (r->reg==b->reg)) { r->size=b->actual_size; break; } } /* Motorola NT firmware does not configure pci devices which are not * required for booting, others do. For now: * - allocated devices in the ISA range (64kB I/O, 16Mb memory) * but non zero base registers are left as is. * - all other registers, whether already allocated or not, are * reallocated unless they require an inordinate amount of * resources (>256 Mb for memory >64kB for I/O). These * devices with too large mapping requirements are simply ignored * and their bases are set to 0. This should disable the * corresponding decoders according to the PCI specification. * Many devices are buggy in this respect, however, but the * limits have hopefully been set high enough to avoid problems. */ if ((r->type==PCI_BASE_ADDRESS_SPACE_IO) ? (r->base && r->base <0x10000) : (r->base && r->base <0x1000000)) { sfree(r); return; } if ((r->type==PCI_BASE_ADDRESS_SPACE_IO) ? (r->size >= 0x10000) : (r->size >= 0x10000000)) { r->size = 0; r->base = 0; } /* Now insert into the list sorting by * 1) decreasing bus number * 2) space: prefetchable memory, non-prefetchable and finally I/O * 3) decreasing size */ if (!pci->resources || insert_before(r, pci->resources)) { r->next = pci->resources; pci->resources=r; } else { for (p=pci->resources; p->next; p=p->next) { if (insert_before(r, p->next)) break; } r->next=p->next; p->next=r; } } /* This version only works for bus 0. I don't have any P2P bridges to test * a more sophisticated version which has therefore not been implemented. * Prefetchable memory is not yet handled correctly either. * And several levels of PCI bridges much less even since there must be * allocated together to be able to setup correctly the top bridge. */ static u_long find_range(u_char bus, u_char type, pci_resource **first, pci_resource **past, u_int *flags) { pci_resource *p; u_long total=0; u_int fl=0; for (p=pci->resources; p; p=p->next) { if ((p->dev->bus->number == bus) && AREA(p)==type) break; } *first = p; for (; p; p=p->next) { if ((p->dev->bus->number != bus) || AREA(p)!=type || p->size == 0) break; total = total+p->size; fl |= 1<<p->type; } *past = p; /* This will be used later to tell whether there are any 32 bit * devices in an area which could be mapped higher than 4Gb * on 64 bits architectures */ *flags = fl; return total; } static inline void init_free_area(pci_area_head *h, u_long start, u_long end, u_int mask, int high) { pci_area *p; p = salloc(sizeof(pci_area)); if (!p) return; h->head = p; p->next = NULL; p->start = (start+mask)&~mask; p->end = (end-mask)|mask; p->bus = NULL; h->mask = mask; h->high = high; } static void insert_area(pci_area_head *h, pci_area *p) { pci_area *q = h->head; if (!p) return; if (q && (q->start< p->start)) { for(;q->next && q->next->start<p->start; q = q->next); if ((q->end >= p->start) || (q->next && p->end>=q->next->start)) { sfree(p); printk("Overlapping pci areas!\n"); return; } p->next = q->next; q->next = p; } else { /* Insert at head */ if (q && (p->end >= q->start)) { sfree(p); printk("Overlapping pci areas!\n"); return; } p->next = q; h->head = p; } } static void remove_area(pci_area_head *h, pci_area *p) { pci_area *q = h->head; if (!p || !q) return; if (q==p) { h->head = q->next; return; } for(;q && q->next!=p; q=q->next); if (q) q->next=p->next; } static pci_area * alloc_area(pci_area_head *h, struct pci_bus *bus, u_long required, u_long mask, u_int flags) { pci_area *p; pci_area *from, *split, *new; required = (required+h->mask) & ~h->mask; for (p=h->head, from=NULL; p; p=p->next) { u_long l1 = ((p->start+required+mask)&~mask)-1; u_long l2 = ((p->start+mask)&~mask)+required-1; /* Allocated areas point to the bus to which they pertain */ if (p->bus) continue; if ((p->end)>=l1 || (p->end)>=l2) from=p; if (from && !h->high) break; } if (!from) return NULL; split = salloc(sizeof(pci_area)); new = salloc(sizeof(pci_area)); /* If allocation of new succeeds then allocation of split has * also been successful (given the current mm algorithms) ! */ if (!new) { sfree(split); return NULL; } new->bus = bus; new->flags = flags; /* Now allocate pci_space taking alignment into account ! */ if (h->high) { u_long l1 = ((from->end+1)&~mask)-required; u_long l2 = (from->end+1-required)&~mask; new->start = (l1>l2) ? l1 : l2; split->end = from->end; from->end = new->start-1; split->start = new->start+required; new->end = new->start+required-1; } else { u_long l1 = ((from->start+mask)&~mask)+required-1; u_long l2 = ((from->start+required+mask)&~mask)-1; new->end = (l1<l2) ? l1 : l2; split->start = from->start; from->start = new->end+1; new->start = new->end+1-required; split->end = new->start-1; } if (from->end+1 == from->start) remove_area(h, from); if (split->end+1 != split->start) { split->bus = NULL; insert_area(h, split); } else { sfree(split); } insert_area(h, new); print_pci_areas("alloc_area called:\n"); return new; } static inline void alloc_space(pci_area *p, pci_resource *r) { if (p->start & (r->size-1)) { r->base = p->end+1-r->size; p->end -= r->size; } else { r->base = p->start; p->start += r->size; } } static void reconfigure_bus_space(u_char bus, u_char type, pci_area_head *h) { pci_resource *first, *past, *r; pci_area *area, tmp; u_int flags; u_int required = find_range(bus, type, &first, &past, &flags); if (required==0) return; area = alloc_area(h, first->dev->bus, required, first->size-1, flags); if (!area) return; tmp = *area; for (r=first; r!=past; r=r->next) { alloc_space(&tmp, r); } } static void reconfigure_pci(void) { pci_resource *r; struct pci_dev *dev; /* FIXME: for now memory is relocated from low, it's better * to start from higher addresses. */ init_free_area(&pci->io, 0x10000, 0x7fffff, 0xfff, 0); init_free_area(&pci->mem, 0x1000000, 0x3cffffff, 0xfffff, 0); /* First reconfigure the I/O space, this will be more * complex when there is more than 1 bus. And 64 bits * devices are another kind of problems. */ reconfigure_bus_space(0, PCI_AREA_IO, &pci->io); reconfigure_bus_space(0, PCI_AREA_MEMORY, &pci->mem); reconfigure_bus_space(0, PCI_AREA_PREFETCHABLE, &pci->mem); /* Now we have to touch the configuration space of all * the devices to remap them better than they are right now. * This is done in 3 steps: * 1) first disable I/O and memory response of all devices * 2) modify the base registers * 3) restore the original PCI_COMMAND register. */ for (r=pci->resources; r; r= r->next) { if (!r->dev->sysdata) { r->dev->sysdata=r; pci_read_config_word(r->dev, PCI_COMMAND, &r->cmd); pci_write_config_word(r->dev, PCI_COMMAND, r->cmd & ~(PCI_COMMAND_IO| PCI_COMMAND_MEMORY)); } } for (r=pci->resources; r; r= r->next) { pci_write_config_dword(r->dev, PCI_BASE_ADDRESS_0+(r->reg<<2), r->base); if ((r->type& (PCI_BASE_ADDRESS_SPACE| PCI_BASE_ADDRESS_MEM_TYPE_MASK)) == (PCI_BASE_ADDRESS_SPACE_MEMORY| PCI_BASE_ADDRESS_MEM_TYPE_64)) { pci_write_config_dword(r->dev, PCI_BASE_ADDRESS_1+ (r->reg<<2), 0); } } for (dev=bd->pci_devices; dev; dev= dev->next) { if (dev->sysdata) { pci_write_config_word(dev, PCI_COMMAND, ((pci_resource *)dev->sysdata) ->cmd); dev->sysdata=NULL; } } } static int indirect_pci_read_config_byte(unsigned char bus, unsigned char dev_fn, unsigned char offset, unsigned char *val) { out_be32(pci->config_addr, 0x80|(bus<<8)|(dev_fn<<16)|((offset&~3)<<24)); *val=in_8(pci->config_data + (offset&3)); return PCIBIOS_SUCCESSFUL; } static int indirect_pci_read_config_word(unsigned char bus, unsigned char dev_fn, unsigned char offset, unsigned short *val) { *val = 0xffff; if (offset&1) return PCIBIOS_BAD_REGISTER_NUMBER; out_be32(pci->config_addr, 0x80|(bus<<8)|(dev_fn<<16)|((offset&~3)<<24)); *val=in_le16((volatile u_short *)(pci->config_data + (offset&3))); return PCIBIOS_SUCCESSFUL; } static int indirect_pci_read_config_dword(unsigned char bus, unsigned char dev_fn, unsigned char offset, unsigned int *val) { *val = 0xffffffff; if (offset&3) return PCIBIOS_BAD_REGISTER_NUMBER; out_be32(pci->config_addr, 0x80|(bus<<8)|(dev_fn<<16)|(offset<<24)); *val=in_le32((volatile u_int *)pci->config_data); return PCIBIOS_SUCCESSFUL; } static int indirect_pci_write_config_byte(unsigned char bus, unsigned char dev_fn, unsigned char offset, unsigned char val) { out_be32(pci->config_addr, 0x80|(bus<<8)|(dev_fn<<16)|((offset&~3)<<24)); out_8(pci->config_data + (offset&3), val); return PCIBIOS_SUCCESSFUL; } static int indirect_pci_write_config_word(unsigned char bus, unsigned char dev_fn, unsigned char offset, unsigned short val) { if (offset&1) return PCIBIOS_BAD_REGISTER_NUMBER; out_be32(pci->config_addr, 0x80|(bus<<8)|(dev_fn<<16)|((offset&~3)<<24)); out_le16((volatile u_short *)(pci->config_data + (offset&3)), val); return PCIBIOS_SUCCESSFUL; } static int indirect_pci_write_config_dword(unsigned char bus, unsigned char dev_fn, unsigned char offset, unsigned int val) { if (offset&3) return PCIBIOS_BAD_REGISTER_NUMBER; out_be32(pci->config_addr, 0x80|(bus<<8)|(dev_fn<<16)|(offset<<24)); out_le32((volatile u_int *)pci->config_data, val); return PCIBIOS_SUCCESSFUL; } static const struct pci_config_access_functions indirect_functions = { indirect_pci_read_config_byte, indirect_pci_read_config_word, indirect_pci_read_config_dword, indirect_pci_write_config_byte, indirect_pci_write_config_word, indirect_pci_write_config_dword }; static int direct_pci_read_config_byte(unsigned char bus, unsigned char dev_fn, unsigned char offset, unsigned char *val) { if (bus != 0 || (1<<PCI_SLOT(dev_fn) & 0xff8007fe)) { *val=0xff; return PCIBIOS_DEVICE_NOT_FOUND; } *val=in_8(pci->config_data + ((1<<PCI_SLOT(dev_fn))&~1) + (PCI_FUNC(dev_fn)<<8) + offset); return PCIBIOS_SUCCESSFUL; } static int direct_pci_read_config_word(unsigned char bus, unsigned char dev_fn, unsigned char offset, unsigned short *val) { *val = 0xffff; if (offset&1) return PCIBIOS_BAD_REGISTER_NUMBER; if (bus != 0 || (1<<PCI_SLOT(dev_fn) & 0xff8007fe)) { return PCIBIOS_DEVICE_NOT_FOUND; } *val=in_le16((volatile u_short *) (pci->config_data + ((1<<PCI_SLOT(dev_fn))&~1) + (PCI_FUNC(dev_fn)<<8) + offset)); return PCIBIOS_SUCCESSFUL; } static int direct_pci_read_config_dword(unsigned char bus, unsigned char dev_fn, unsigned char offset, unsigned int *val) { *val = 0xffffffff; if (offset&3) return PCIBIOS_BAD_REGISTER_NUMBER; if (bus != 0 || (1<<PCI_SLOT(dev_fn) & 0xff8007fe)) { return PCIBIOS_DEVICE_NOT_FOUND; } *val=in_le32((volatile u_int *) (pci->config_data + ((1<<PCI_SLOT(dev_fn))&~1) + (PCI_FUNC(dev_fn)<<8) + offset)); return PCIBIOS_SUCCESSFUL; } static int direct_pci_write_config_byte(unsigned char bus, unsigned char dev_fn, unsigned char offset, unsigned char val) { if (bus != 0 || (1<<PCI_SLOT(dev_fn) & 0xff8007fe)) { return PCIBIOS_DEVICE_NOT_FOUND; } out_8(pci->config_data + ((1<<PCI_SLOT(dev_fn))&~1) + (PCI_FUNC(dev_fn)<<8) + offset, val); return PCIBIOS_SUCCESSFUL; } static int direct_pci_write_config_word(unsigned char bus, unsigned char dev_fn, unsigned char offset, unsigned short val) { if (offset&1) return PCIBIOS_BAD_REGISTER_NUMBER; if (bus != 0 || (1<<PCI_SLOT(dev_fn) & 0xff8007fe)) { return PCIBIOS_DEVICE_NOT_FOUND; } out_le16((volatile u_short *) (pci->config_data + ((1<<PCI_SLOT(dev_fn))&~1) + (PCI_FUNC(dev_fn)<<8) + offset), val); return PCIBIOS_SUCCESSFUL; } static int direct_pci_write_config_dword(unsigned char bus, unsigned char dev_fn, unsigned char offset, unsigned int val) { if (offset&3) return PCIBIOS_BAD_REGISTER_NUMBER; if (bus != 0 || (1<<PCI_SLOT(dev_fn) & 0xff8007fe)) { return PCIBIOS_DEVICE_NOT_FOUND; } out_le32((volatile u_int *) (pci->config_data + ((1<<PCI_SLOT(dev_fn))&~1) + (PCI_FUNC(dev_fn)<<8) + offset), val); return PCIBIOS_SUCCESSFUL; } static const struct pci_config_access_functions direct_functions = { direct_pci_read_config_byte, direct_pci_read_config_word, direct_pci_read_config_dword, direct_pci_write_config_byte, direct_pci_write_config_word, direct_pci_write_config_dword }; void pci_read_bases(struct pci_dev *dev, unsigned int howmany) { unsigned int reg, nextreg; #define REG (PCI_BASE_ADDRESS_0 + (reg<<2)) u_short cmd; u32 l, ml; pci_read_config_word(dev, PCI_COMMAND, &cmd); for(reg=0; reg<howmany; reg=nextreg) { pci_resource *r; nextreg=reg+1; pci_read_config_dword(dev, REG, &l); #if 0 if (l == 0xffffffff /*AJF || !l*/) continue; #endif /* Note that disabling the memory response of a host bridge * would lose data if a DMA transfer were in progress. In a * bootloader we don't care however. Also we can't print any * message for a while since we might just disable the console. */ pci_write_config_word(dev, PCI_COMMAND, cmd & ~(PCI_COMMAND_IO|PCI_COMMAND_MEMORY)); pci_write_config_dword(dev, REG, ~0); pci_read_config_dword(dev, REG, &ml); pci_write_config_dword(dev, REG, l); /* Reenable the device now that we've played with * base registers. */ pci_write_config_word(dev, PCI_COMMAND, cmd); /* seems to be an unused entry skip it */ if ( ml == 0 || ml == 0xffffffff ) continue; if ((l & (PCI_BASE_ADDRESS_SPACE|PCI_BASE_ADDRESS_MEM_TYPE_MASK)) == (PCI_BASE_ADDRESS_MEM_TYPE_64 |PCI_BASE_ADDRESS_SPACE_MEMORY)) { nextreg=reg+2; } dev->base_address[reg] = l; r = salloc(sizeof(pci_resource)); if (!r) { printk("Error allocating pci_resource struct.\n"); continue; } r->dev = dev; r->reg = reg; if ((l&PCI_BASE_ADDRESS_SPACE) == PCI_BASE_ADDRESS_SPACE_IO) { r->type = l&~PCI_BASE_ADDRESS_IO_MASK; r->base = l&PCI_BASE_ADDRESS_IO_MASK; r->size = ~(ml&PCI_BASE_ADDRESS_IO_MASK)+1; } else { r->type = l&~PCI_BASE_ADDRESS_MEM_MASK; r->base = l&PCI_BASE_ADDRESS_MEM_MASK; r->size = ~(ml&PCI_BASE_ADDRESS_MEM_MASK)+1; } /* Check for the blacklisted entries */ insert_resource(r); } } u_int pci_scan_bus(struct pci_bus *bus) { unsigned int devfn, l, max, class; unsigned char irq, hdr_type, is_multi = 0; struct pci_dev *dev, **bus_last; struct pci_bus *child; bus_last = &bus->devices; max = bus->secondary; for (devfn = 0; devfn < 0xff; ++devfn) { if (PCI_FUNC(devfn) && !is_multi) { /* not a multi-function device */ continue; } if (pcibios_read_config_byte(bus->number, devfn, PCI_HEADER_TYPE, &hdr_type)) continue; if (!PCI_FUNC(devfn)) is_multi = hdr_type & 0x80; if (pcibios_read_config_dword(bus->number, devfn, PCI_VENDOR_ID, &l) || /* some broken boards return 0 if a slot is empty: */ l == 0xffffffff || l == 0x00000000 || l == 0x0000ffff || l == 0xffff0000) { is_multi = 0; continue; } dev = salloc(sizeof(*dev)); dev->bus = bus; dev->devfn = devfn; dev->vendor = l & 0xffff; dev->device = (l >> 16) & 0xffff; pcibios_read_config_dword(bus->number, devfn, PCI_CLASS_REVISION, &class); class >>= 8; /* upper 3 bytes */ dev->class = class; class >>= 8; dev->hdr_type = hdr_type; switch (hdr_type & 0x7f) { /* header type */ case PCI_HEADER_TYPE_NORMAL: /* standard header */ if (class == PCI_CLASS_BRIDGE_PCI) goto bad; /* * If the card generates interrupts, read IRQ number * (some architectures change it during pcibios_fixup()) */ pcibios_read_config_byte(bus->number, dev->devfn, PCI_INTERRUPT_PIN, &irq); if (irq) pcibios_read_config_byte(bus->number, dev->devfn, PCI_INTERRUPT_LINE, &irq); dev->irq = irq; /* * read base address registers, again pcibios_fixup() can * tweak these */ pci_read_bases(dev, 6); pcibios_read_config_dword(bus->number, devfn, PCI_ROM_ADDRESS, &l); dev->rom_address = (l == 0xffffffff) ? 0 : l; break; case PCI_HEADER_TYPE_BRIDGE: /* bridge header */ if (class != PCI_CLASS_BRIDGE_PCI) goto bad; pci_read_bases(dev, 2); pcibios_read_config_dword(bus->number, devfn, PCI_ROM_ADDRESS1, &l); dev->rom_address = (l == 0xffffffff) ? 0 : l; break; case PCI_HEADER_TYPE_CARDBUS: /* CardBus bridge header */ if (class != PCI_CLASS_BRIDGE_CARDBUS) goto bad; pci_read_bases(dev, 1); break; default: /* unknown header */ bad: printk("PCI device with unknown " "header type %d ignored.\n", hdr_type&0x7f); continue; } /* * Put it into the global PCI device chain. It's used to * find devices once everything is set up. */ *pci->last_dev_p = dev; pci->last_dev_p = &dev->next; /* * Now insert it into the list of devices held * by the parent bus. */ *bus_last = dev; bus_last = &dev->sibling; } /* * After performing arch-dependent fixup of the bus, look behind * all PCI-to-PCI bridges on this bus. */ for(dev=bus->devices; dev; dev=dev->sibling) /* * If it's a bridge, scan the bus behind it. */ if ((dev->class >> 8) == PCI_CLASS_BRIDGE_PCI) { unsigned int buses; unsigned int devfn = dev->devfn; unsigned short cr; /* * Insert it into the tree of buses. */ child = salloc(sizeof(*child)); child->next = bus->children; bus->children = child; child->self = dev; child->parent = bus; /* * Set up the primary, secondary and subordinate * bus numbers. */ child->number = child->secondary = ++max; child->primary = bus->secondary; child->subordinate = 0xff; /* * Clear all status bits and turn off memory, * I/O and master enables. */ pcibios_read_config_word(bus->number, devfn, PCI_COMMAND, &cr); pcibios_write_config_word(bus->number, devfn, PCI_COMMAND, 0x0000); pcibios_write_config_word(bus->number, devfn, PCI_STATUS, 0xffff); /* * Read the existing primary/secondary/subordinate bus * number configuration to determine if the PCI bridge * has already been configured by the system. If so, * do not modify the configuration, merely note it. */ pcibios_read_config_dword(bus->number, devfn, PCI_PRIMARY_BUS, &buses); if ((buses & 0xFFFFFF) != 0) { unsigned int cmax; child->primary = buses & 0xFF; child->secondary = (buses >> 8) & 0xFF; child->subordinate = (buses >> 16) & 0xFF; child->number = child->secondary; cmax = pci_scan_bus(child); if (cmax > max) max = cmax; } else { /* * Configure the bus numbers for this bridge: */ buses &= 0xff000000; buses |= (((unsigned int)(child->primary) << 0) | ((unsigned int)(child->secondary) << 8) | ((unsigned int)(child->subordinate) << 16)); pcibios_write_config_dword(bus->number, devfn, PCI_PRIMARY_BUS, buses); /* * Now we can scan all subordinate buses: */ max = pci_scan_bus(child); /* * Set the subordinate bus number to its real * value: */ child->subordinate = max; buses = (buses & 0xff00ffff) | ((unsigned int)(child->subordinate) << 16); pcibios_write_config_dword(bus->number, devfn, PCI_PRIMARY_BUS, buses); } pcibios_write_config_word(bus->number, devfn, PCI_COMMAND, cr); } /* * We've scanned the bus and so we know all about what's on * the other side of any bridges that may be on this bus plus * any devices. * * Return how far we've got finding sub-buses. */ return max; } void pci_fixup(void) { struct pci_dev *p; struct pci_bus *bus; for (bus = &pci_root; bus; bus=bus->next) { for (p=bus->devices; p; p=p->sibling) { } } } void pci_init(void) { PPC_DEVICE *hostbridge; if (pci->last_dev_p) { printk("Two or more calls to pci_init!\n"); return; } pci->last_dev_p = &(bd->pci_devices); hostbridge=residual_find_device(PROCESSORDEVICE, NULL, BridgeController, PCIBridge, -1, 0); if (hostbridge) { if (hostbridge->DeviceId.Interface==PCIBridgeIndirect) { bd->pci_functions=&indirect_functions; /* Should be extracted from residual data, * indeed MPC106 in CHRP mode is different, * but we should not use residual data in * this case anyway. */ pci->config_addr = ((volatile u_int *) (ptr_mem_map->io_base+0xcf8)); pci->config_data = ptr_mem_map->io_base+0xcfc; } else if(hostbridge->DeviceId.Interface==PCIBridgeDirect) { bd->pci_functions=&direct_functions; pci->config_data=(u_char *) 0x80800000; } else { } } else { /* Let us try by experimentation at our own risk! */ u_int id0; bd->pci_functions = &direct_functions; /* On all direct bridges I know the host bridge itself * appears as device 0 function 0. */ pcibios_read_config_dword(0, 0, PCI_VENDOR_ID, &id0); if (id0==~0U) { bd->pci_functions = &indirect_functions; pci->config_addr = ((volatile u_int *) (ptr_mem_map->io_base+0xcf8)); pci->config_data = ptr_mem_map->io_base+0xcfc; } /* Here we should check that the host bridge is actually * present, but if it not, we are in such a desperate * situation, that we probably can't even tell it. */ } /* Now build a small database of all found PCI devices */ printk("\nPCI: Probing PCI hardware\n"); pci_root.subordinate=pci_scan_bus(&pci_root); print_pci_resources("Configurable PCI resources:\n"); reconfigure_pci(); print_pci_resources("Allocated PCI resources:\n"); }