/* * Copyright (c) 2008 Juan Romero Pardines * Copyright (c) 2008 Mark Kettenis * Copyright (c) 2009 Michael Lorenz * * Permission to use, copy, modify, and distribute this software for any * purpose with or without fee is hereby granted, provided that the above * copyright notice and this permission notice appear in all copies. * * THE SOFTWARE IS PROVIDED "AS IS" AND THE AUTHOR DISCLAIMS ALL WARRANTIES * WITH REGARD TO THIS SOFTWARE INCLUDING ALL IMPLIED WARRANTIES OF * MERCHANTABILITY AND FITNESS. IN NO EVENT SHALL THE AUTHOR BE LIABLE FOR * ANY SPECIAL, DIRECT, INDIRECT, OR CONSEQUENTIAL DAMAGES OR ANY DAMAGES * WHATSOEVER RESULTING FROM LOSS OF USE, DATA OR PROFITS, WHETHER IN AN * ACTION OF CONTRACT, NEGLIGENCE OR OTHER TORTIOUS ACTION, ARISING OUT OF * OR IN CONNECTION WITH THE USE OR PERFORMANCE OF THIS SOFTWARE. */ #ifdef HAVE_CONFIG_H #include "config.h" #endif #include #include #include #include #ifdef HAVE_MTRR #include #include #ifdef _X86_SYSARCH_L /* NetBSD 5.x and newer */ #define netbsd_set_mtrr(mr, num) _X86_SYSARCH_L(set_mtrr)(mr, num) #else /* NetBSD 4.x and older */ #ifdef __i386__ #define netbsd_set_mtrr(mr, num) i386_set_mtrr((mr), (num)) #endif #ifdef __amd64__ #define netbsd_set_mtrr(mr, num) x86_64_set_mtrr((mr), (num)) #endif #endif #endif #include #include #include #include #include #include #include #include #include #include #include #include "pciaccess.h" #include "pciaccess_private.h" typedef struct _pcibus { int fd; /* /dev/pci* */ int num; /* bus number */ int maxdevs; /* maximum number of devices */ } PciBus; static PciBus buses[32]; /* indexed by pci_device.domain */ static int nbuses = 0; /* number of buses found */ /* * NetBSD's userland has a /dev/pci* entry for each bus but userland has no way * to tell if a bus is a subordinate of another one or if it's on a different * host bridge. On some architectures ( macppc for example ) all root buses have * bus number 0 but on sparc64 for example the two roots in an Ultra60 have * different bus numbers - one is 0 and the other 128. * With each /dev/pci* we can map everything on the same root and we can also * see all devices on the same root, trying to do that causes problems though: * - since we can't tell which /dev/pci* is a subordinate we would find some * devices more than once * - we would have to guess subordinate bus numbers which is a waste of time * since we can ask each /dev/pci* for its bus number so we can scan only the * buses we know exist, not all 256 which may exist in each domain. * - some bus_space_mmap() methods may limit mappings to address ranges which * belong to known devices on that bus only. * Each host bridge may or may not have its own IO range, to avoid guesswork * here each /dev/pci* will let userland map its appropriate IO range at * PCI_MAGIC_IO_RANGE if defined in * With all this we should be able to use any PCI graphics device on any PCI * bus on any architecture as long as Xorg has a driver, without allowing * arbitrary mappings via /dev/mem and without userland having to know or care * about translating bus addresses to physical addresses or the other way * around. */ static int pci_read(int domain, int bus, int dev, int func, uint32_t reg, uint32_t *val) { uint32_t rval; if ((domain < 0) || (domain > nbuses)) return -1; if (pcibus_conf_read(buses[domain].fd, (unsigned int)bus, (unsigned int)dev, (unsigned int)func, reg, &rval) == -1) return (-1); *val = rval; return 0; } static int pci_write(int domain, int bus, int dev, int func, uint32_t reg, uint32_t val) { if ((domain < 0) || (domain > nbuses)) return -1; return pcibus_conf_write(buses[domain].fd, (unsigned int)bus, (unsigned int)dev, (unsigned int)func, reg, val); } static int pci_nfuncs(int domain, int bus, int dev) { uint32_t hdr; if ((domain < 0) || (domain > nbuses)) return -1; if (pci_read(domain, bus, dev, 0, PCI_BHLC_REG, &hdr) != 0) return -1; return (PCI_HDRTYPE_MULTIFN(hdr) ? 8 : 1); } /*ARGSUSED*/ static int pci_device_netbsd_map_range(struct pci_device *dev, struct pci_device_mapping *map) { #ifdef HAVE_MTRR struct mtrr m; int n = 1; #endif int prot, ret = 0; prot = PROT_READ; if (map->flags & PCI_DEV_MAP_FLAG_WRITABLE) prot |= PROT_WRITE; map->memory = mmap(NULL, (size_t)map->size, prot, MAP_SHARED, buses[dev->domain].fd, (off_t)map->base); if (map->memory == MAP_FAILED) return errno; #ifdef HAVE_MTRR memset(&m, 0, sizeof(m)); /* No need to set an MTRR if it's the default mode. */ if ((map->flags & PCI_DEV_MAP_FLAG_CACHABLE) || (map->flags & PCI_DEV_MAP_FLAG_WRITE_COMBINE)) { m.base = map->base; m.flags = MTRR_VALID | MTRR_PRIVATE; m.len = map->size; m.owner = getpid(); if (map->flags & PCI_DEV_MAP_FLAG_CACHABLE) m.type = MTRR_TYPE_WB; if (map->flags & PCI_DEV_MAP_FLAG_WRITE_COMBINE) m.type = MTRR_TYPE_WC; if ((netbsd_set_mtrr(&m, &n)) == -1) { fprintf(stderr, "mtrr set failed: %s\n", strerror(errno)); } } #endif return ret; } static int pci_device_netbsd_unmap_range(struct pci_device *dev, struct pci_device_mapping *map) { #ifdef HAVE_MTRR struct mtrr m; int n = 1; memset(&m, 0, sizeof(m)); if ((map->flags & PCI_DEV_MAP_FLAG_CACHABLE) || (map->flags & PCI_DEV_MAP_FLAG_WRITE_COMBINE)) { m.base = map->base; m.flags = 0; m.len = map->size; m.type = MTRR_TYPE_UC; (void)netbsd_set_mtrr(&m, &n); } #endif return pci_device_generic_unmap_range(dev, map); } static int pci_device_netbsd_read(struct pci_device *dev, void *data, pciaddr_t offset, pciaddr_t size, pciaddr_t *bytes_read) { u_int reg, rval; *bytes_read = 0; while (size > 0) { size_t toread = MIN(size, 4 - (offset & 0x3)); reg = (u_int)(offset & ~0x3); if ((pcibus_conf_read(buses[dev->domain].fd, (unsigned int)dev->bus, (unsigned int)dev->dev, (unsigned int)dev->func, reg, &rval)) == -1) return errno; rval = htole32(rval); rval >>= ((offset & 0x3) * 8); memcpy(data, &rval, toread); offset += toread; data = (char *)data + toread; size -= toread; *bytes_read += toread; } return 0; } static int pci_device_netbsd_write(struct pci_device *dev, const void *data, pciaddr_t offset, pciaddr_t size, pciaddr_t *bytes_written) { u_int reg, val; if ((offset % 4) != 0 || (size % 4) != 0) return EINVAL; *bytes_written = 0; while (size > 0) { reg = (u_int)offset; memcpy(&val, data, 4); if ((pcibus_conf_write(buses[dev->domain].fd, (unsigned int)dev->bus, (unsigned int)dev->dev, (unsigned int)dev->func, reg, val)) == -1) return errno; offset += 4; data = (const char *)data + 4; size -= 4; *bytes_written += 4; } return 0; } #if defined(WSDISPLAYIO_GET_BUSID) static int pci_device_netbsd_boot_vga(struct pci_device *dev) { int ret; struct wsdisplayio_bus_id busid; int fd; fd = open("/dev/ttyE0", O_RDONLY); if (fd == -1) { fprintf(stderr, "failed to open /dev/ttyE0: %s\n", strerror(errno)); return 0; } ret = ioctl(fd, WSDISPLAYIO_GET_BUSID, &busid); close(fd); if (ret == -1) { fprintf(stderr, "ioctl WSDISPLAYIO_GET_BUSID failed: %s\n", strerror(errno)); return 0; } if (busid.bus_type != WSDISPLAYIO_BUS_PCI) return 0; if (busid.ubus.pci.domain != dev->domain) return 0; if (busid.ubus.pci.bus != dev->bus) return 0; if (busid.ubus.pci.device != dev->dev) return 0; if (busid.ubus.pci.function != dev->func) return 0; return 1; } #endif static void pci_system_netbsd_destroy(void) { int i; for (i = 0; i < nbuses; i++) { close(buses[i].fd); } free(pci_sys); pci_sys = NULL; } static int pci_device_netbsd_probe(struct pci_device *device) { struct pci_device_private *priv = (struct pci_device_private *)(void *)device; struct pci_mem_region *region; uint64_t reg64, size64; uint32_t bar, reg, size; int bus, dev, func, err, domain; domain = device->domain; bus = device->bus; dev = device->dev; func = device->func; /* Enable the device if necessary */ err = pci_read(domain, bus, dev, func, PCI_COMMAND_STATUS_REG, ®); if (err) return err; if ((reg & (PCI_COMMAND_IO_ENABLE | PCI_COMMAND_MEM_ENABLE | PCI_COMMAND_MASTER_ENABLE)) != (PCI_COMMAND_IO_ENABLE | PCI_COMMAND_MEM_ENABLE | PCI_COMMAND_MASTER_ENABLE)) { reg |= PCI_COMMAND_IO_ENABLE | PCI_COMMAND_MEM_ENABLE | PCI_COMMAND_MASTER_ENABLE; err = pci_write(domain, bus, dev, func, PCI_COMMAND_STATUS_REG, reg); if (err) return err; } err = pci_read(domain, bus, dev, func, PCI_BHLC_REG, ®); if (err) return err; priv->header_type = PCI_HDRTYPE_TYPE(reg); if (priv->header_type != 0) return 0; region = device->regions; for (bar = PCI_MAPREG_START; bar < PCI_MAPREG_END; bar += sizeof(uint32_t), region++) { err = pci_read(domain, bus, dev, func, bar, ®); if (err) return err; /* Probe the size of the region. */ err = pci_write(domain, bus, dev, func, bar, (unsigned int)~0); if (err) return err; pci_read(domain, bus, dev, func, bar, &size); pci_write(domain, bus, dev, func, bar, reg); if (PCI_MAPREG_TYPE(reg) == PCI_MAPREG_TYPE_IO) { region->is_IO = 1; region->base_addr = PCI_MAPREG_IO_ADDR(reg); region->size = PCI_MAPREG_IO_SIZE(size); } else { if (PCI_MAPREG_MEM_PREFETCHABLE(reg)) region->is_prefetchable = 1; switch(PCI_MAPREG_MEM_TYPE(reg)) { case PCI_MAPREG_MEM_TYPE_32BIT: case PCI_MAPREG_MEM_TYPE_32BIT_1M: region->base_addr = PCI_MAPREG_MEM_ADDR(reg); region->size = PCI_MAPREG_MEM_SIZE(size); break; case PCI_MAPREG_MEM_TYPE_64BIT: region->is_64 = 1; reg64 = reg; size64 = size; bar += sizeof(uint32_t); err = pci_read(domain, bus, dev, func, bar, ®); if (err) return err; reg64 |= (uint64_t)reg << 32; err = pci_write(domain, bus, dev, func, bar, (unsigned int)~0); if (err) return err; pci_read(domain, bus, dev, func, bar, &size); pci_write(domain, bus, dev, func, bar, (unsigned int)(reg64 >> 32)); size64 |= (uint64_t)size << 32; region->base_addr = (unsigned long)PCI_MAPREG_MEM64_ADDR(reg64); region->size = (unsigned long)PCI_MAPREG_MEM64_SIZE(size64); region++; break; } } } /* Probe expansion ROM if present */ err = pci_read(domain, bus, dev, func, PCI_MAPREG_ROM, ®); if (err) return err; if (reg != 0) { err = pci_write(domain, bus, dev, func, PCI_MAPREG_ROM, (uint32_t)(~PCI_MAPREG_ROM_ENABLE)); if (err) return err; pci_read(domain, bus, dev, func, PCI_MAPREG_ROM, &size); pci_write(domain, bus, dev, func, PCI_MAPREG_ROM, reg); if ((reg & PCI_MAPREG_MEM_ADDR_MASK) != 0) { priv->rom_base = reg & PCI_MAPREG_MEM_ADDR_MASK; device->rom_size = -(size & PCI_MAPREG_MEM_ADDR_MASK); } } return 0; } /** * Read a VGA rom using the 0xc0000 mapping. * * This function should be extended to handle access through PCI resources, * which should be more reliable when available. */ static int pci_device_netbsd_read_rom(struct pci_device *dev, void *buffer) { struct pci_device_private *priv = (struct pci_device_private *)(void *)dev; void *bios; pciaddr_t rom_base; size_t rom_size; uint32_t bios_val, command_val; int pci_rom; if (((priv->base.device_class >> 16) & 0xff) != PCI_CLASS_DISPLAY || ((priv->base.device_class >> 8) & 0xff) != PCI_SUBCLASS_DISPLAY_VGA) return ENOSYS; if (priv->rom_base == 0) { #if defined(__amd64__) || defined(__i386__) /* * We need a way to detect when this isn't the console and reject * this request outright. */ rom_base = 0xc0000; rom_size = 0x10000; pci_rom = 0; #else return ENOSYS; #endif } else { rom_base = priv->rom_base; rom_size = dev->rom_size; pci_rom = 1; if ((pcibus_conf_read(buses[dev->domain].fd, (unsigned int)dev->bus, (unsigned int)dev->dev, (unsigned int)dev->func, PCI_COMMAND_STATUS_REG, &command_val)) == -1) return errno; if ((command_val & PCI_COMMAND_MEM_ENABLE) == 0) { if ((pcibus_conf_write(buses[dev->domain].fd, (unsigned int)dev->bus, (unsigned int)dev->dev, (unsigned int)dev->func, PCI_COMMAND_STATUS_REG, command_val | PCI_COMMAND_MEM_ENABLE)) == -1) return errno; } if ((pcibus_conf_read(buses[dev->domain].fd, (unsigned int)dev->bus, (unsigned int)dev->dev, (unsigned int)dev->func, PCI_MAPREG_ROM, &bios_val)) == -1) return errno; if ((bios_val & PCI_MAPREG_ROM_ENABLE) == 0) { if ((pcibus_conf_write(buses[dev->domain].fd, (unsigned int)dev->bus, (unsigned int)dev->dev, (unsigned int)dev->func, PCI_MAPREG_ROM, bios_val | PCI_MAPREG_ROM_ENABLE)) == -1) return errno; } } fprintf(stderr, "Using rom_base = 0x%lx 0x%lx (pci_rom=%d)\n", (long)rom_base, (long)rom_size, pci_rom); bios = mmap(NULL, rom_size, PROT_READ, MAP_SHARED, buses[dev->domain].fd, (off_t)rom_base); if (bios == MAP_FAILED) { int serrno = errno; return serrno; } memcpy(buffer, bios, rom_size); munmap(bios, rom_size); if (pci_rom) { if ((command_val & PCI_COMMAND_MEM_ENABLE) == 0) { if ((pcibus_conf_write(buses[dev->domain].fd, (unsigned int)dev->bus, (unsigned int)dev->dev, (unsigned int)dev->func, PCI_COMMAND_STATUS_REG, command_val)) == -1) return errno; } if ((bios_val & PCI_MAPREG_ROM_ENABLE) == 0) { if ((pcibus_conf_write(buses[dev->domain].fd, (unsigned int)dev->bus, (unsigned int)dev->dev, (unsigned int)dev->func, PCI_MAPREG_ROM, bios_val)) == -1) return errno; } } return 0; } #if defined(__i386__) || defined(__amd64__) #include /* * Functions to provide access to x86 programmed I/O instructions. * * The in[bwl]() and out[bwl]() functions are split into two varieties: one to * use a small, constant, 8-bit port number, and another to use a large or * variable port number. The former can be compiled as a smaller instruction. */ #ifdef __OPTIMIZE__ #define __use_immediate_port(port) \ (__builtin_constant_p((port)) && (port) < 0x100) #else #define __use_immediate_port(port) 0 #endif #define inb(port) \ (/* CONSTCOND */ __use_immediate_port(port) ? __inbc(port) : __inb(port)) static __inline u_int8_t __inbc(unsigned port) { u_int8_t data; __asm __volatile("inb %w1,%0" : "=a" (data) : "id" (port)); return data; } static __inline u_int8_t __inb(unsigned port) { u_int8_t data; __asm __volatile("inb %w1,%0" : "=a" (data) : "d" (port)); return data; } static __inline void insb(unsigned port, void *addr, int cnt) { void *dummy1; int dummy2; __asm __volatile("cld\n\trepne\n\tinsb" : "=D" (dummy1), "=c" (dummy2) : "d" (port), "0" (addr), "1" (cnt) : "memory"); } #define inw(port) \ (/* CONSTCOND */ __use_immediate_port(port) ? __inwc(port) : __inw(port)) static __inline u_int16_t __inwc(unsigned port) { u_int16_t data; __asm __volatile("inw %w1,%0" : "=a" (data) : "id" (port)); return data; } static __inline u_int16_t __inw(unsigned port) { u_int16_t data; __asm __volatile("inw %w1,%0" : "=a" (data) : "d" (port)); return data; } static __inline void insw(unsigned port, void *addr, int cnt) { void *dummy1; int dummy2; __asm __volatile("cld\n\trepne\n\tinsw" : "=D" (dummy1), "=c" (dummy2) : "d" (port), "0" (addr), "1" (cnt) : "memory"); } #define inl(port) \ (/* CONSTCOND */ __use_immediate_port(port) ? __inlc(port) : __inl(port)) static __inline u_int32_t __inlc(unsigned port) { u_int32_t data; __asm __volatile("inl %w1,%0" : "=a" (data) : "id" (port)); return data; } static __inline u_int32_t __inl(unsigned port) { u_int32_t data; __asm __volatile("inl %w1,%0" : "=a" (data) : "d" (port)); return data; } static __inline void insl(unsigned port, void *addr, int cnt) { void *dummy1; int dummy2; __asm __volatile("cld\n\trepne\n\tinsl" : "=D" (dummy1), "=c" (dummy2) : "d" (port), "0" (addr), "1" (cnt) : "memory"); } #define outb(port, data) \ (/* CONSTCOND */__use_immediate_port(port) ? __outbc(port, data) : \ __outb(port, data)) static __inline void __outbc(unsigned port, u_int8_t data) { __asm __volatile("outb %0,%w1" : : "a" (data), "id" (port)); } static __inline void __outb(unsigned port, u_int8_t data) { __asm __volatile("outb %0,%w1" : : "a" (data), "d" (port)); } static __inline void outsb(unsigned port, const void *addr, int cnt) { void *dummy1; int dummy2; __asm __volatile("cld\n\trepne\n\toutsb" : "=S" (dummy1), "=c" (dummy2) : "d" (port), "0" (addr), "1" (cnt)); } #define outw(port, data) \ (/* CONSTCOND */ __use_immediate_port(port) ? __outwc(port, data) : \ __outw(port, data)) static __inline void __outwc(unsigned port, u_int16_t data) { __asm __volatile("outw %0,%w1" : : "a" (data), "id" (port)); } static __inline void __outw(unsigned port, u_int16_t data) { __asm __volatile("outw %0,%w1" : : "a" (data), "d" (port)); } static __inline void outsw(unsigned port, const void *addr, int cnt) { void *dummy1; int dummy2; __asm __volatile("cld\n\trepne\n\toutsw" : "=S" (dummy1), "=c" (dummy2) : "d" (port), "0" (addr), "1" (cnt)); } #define outl(port, data) \ (/* CONSTCOND */ __use_immediate_port(port) ? __outlc(port, data) : \ __outl(port, data)) static __inline void __outlc(unsigned port, u_int32_t data) { __asm __volatile("outl %0,%w1" : : "a" (data), "id" (port)); } static __inline void __outl(unsigned port, u_int32_t data) { __asm __volatile("outl %0,%w1" : : "a" (data), "d" (port)); } static __inline void outsl(unsigned port, const void *addr, int cnt) { void *dummy1; int dummy2; __asm __volatile("cld\n\trepne\n\toutsl" : "=S" (dummy1), "=c" (dummy2) : "d" (port), "0" (addr), "1" (cnt)); } #endif static struct pci_io_handle * pci_device_netbsd_open_legacy_io(struct pci_io_handle *ret, struct pci_device *dev, pciaddr_t base, pciaddr_t size) { #if defined(__i386__) struct i386_iopl_args ia; ia.iopl = 1; if (sysarch(I386_IOPL, &ia)) return NULL; ret->base = base; ret->size = size; ret->is_legacy = 1; return ret; #elif defined(__amd64__) struct x86_64_iopl_args ia; ia.iopl = 1; if (sysarch(X86_64_IOPL, &ia)) return NULL; ret->base = base; ret->size = size; ret->is_legacy = 1; return ret; #else return NULL; #endif } static uint32_t pci_device_netbsd_read32(struct pci_io_handle *handle, uint32_t reg) { #if defined(__i386__) || defined(__amd64__) return inl(handle->base + reg); #else return *(uint32_t *)((uintptr_t)handle->memory + reg); #endif } static uint16_t pci_device_netbsd_read16(struct pci_io_handle *handle, uint32_t reg) { #if defined(__i386__) || defined(__amd64__) return inw(handle->base + reg); #else return *(uint16_t *)((uintptr_t)handle->memory + reg); #endif } static uint8_t pci_device_netbsd_read8(struct pci_io_handle *handle, uint32_t reg) { #if defined(__i386__) || defined(__amd64__) return inb(handle->base + reg); #else return *(uint8_t *)((uintptr_t)handle->memory + reg); #endif } static void pci_device_netbsd_write32(struct pci_io_handle *handle, uint32_t reg, uint32_t data) { #if defined(__i386__) || defined(__amd64__) outl(handle->base + reg, data); #else *(uint16_t *)((uintptr_t)handle->memory + reg) = data; #endif } static void pci_device_netbsd_write16(struct pci_io_handle *handle, uint32_t reg, uint16_t data) { #if defined(__i386__) || defined(__amd64__) outw(handle->base + reg, data); #else *(uint8_t *)((uintptr_t)handle->memory + reg) = data; #endif } static void pci_device_netbsd_write8(struct pci_io_handle *handle, uint32_t reg, uint8_t data) { #if defined(__i386__) || defined(__amd64__) outb(handle->base + reg, data); #else *(uint32_t *)((uintptr_t)handle->memory + reg) = data; #endif } static int pci_device_netbsd_map_legacy(struct pci_device *dev, pciaddr_t base, pciaddr_t size, unsigned map_flags, void **addr) { struct pci_device_mapping map; int err; map.base = base; map.size = size; map.flags = map_flags; map.memory = NULL; err = pci_device_netbsd_map_range(dev, &map); *addr = map.memory; return err; } static int pci_device_netbsd_unmap_legacy(struct pci_device *dev, void *addr, pciaddr_t size) { struct pci_device_mapping map; map.memory = addr; map.size = size; map.flags = 0; return pci_device_netbsd_unmap_range(dev, &map); } static int pci_device_netbsd_has_kernel_driver(struct pci_device *dev) { #ifdef PCI_IOC_DRVNAME /* * NetBSD PCI_IOC_DRVNAME appears at the same time as pci_drvname(3) */ char drvname[16]; if (dev->bus >= nbuses) return 0; /* * vga(4) should be considered "not bound". */ if (pci_drvname(buses[dev->bus].fd, dev->dev, dev->func, drvname, sizeof drvname) == 0 && strncmp(drvname, "vga", 3) != 0) return 1; #endif return 0; } static const struct pci_system_methods netbsd_pci_methods = { .destroy = pci_system_netbsd_destroy, .destroy_device = NULL, .read_rom = pci_device_netbsd_read_rom, .probe = pci_device_netbsd_probe, .map_range = pci_device_netbsd_map_range, .unmap_range = pci_device_netbsd_unmap_range, .read = pci_device_netbsd_read, .write = pci_device_netbsd_write, .fill_capabilities = pci_fill_capabilities_generic, #if defined(WSDISPLAYIO_GET_BUSID) .boot_vga = pci_device_netbsd_boot_vga, #else .boot_vga = NULL, #endif .open_legacy_io = pci_device_netbsd_open_legacy_io, .read32 = pci_device_netbsd_read32, .read16 = pci_device_netbsd_read16, .read8 = pci_device_netbsd_read8, .write32 = pci_device_netbsd_write32, .write16 = pci_device_netbsd_write16, .write8 = pci_device_netbsd_write8, .map_legacy = pci_device_netbsd_map_legacy, .unmap_legacy = pci_device_netbsd_unmap_legacy, .has_kernel_driver = pci_device_netbsd_has_kernel_driver, }; int pci_system_netbsd_create(void) { struct pci_device_private *device; int bus, dev, func, ndevs, nfuncs, domain, pcifd; uint32_t reg; char netbsd_devname[32]; struct pciio_businfo businfo; pci_sys = calloc(1, sizeof(struct pci_system)); pci_sys->methods = &netbsd_pci_methods; ndevs = 0; nbuses = 0; snprintf(netbsd_devname, 32, "/dev/pci%d", nbuses); pcifd = open(netbsd_devname, O_RDWR | O_CLOEXEC); while (pcifd > 0) { ioctl(pcifd, PCI_IOC_BUSINFO, &businfo); buses[nbuses].fd = pcifd; buses[nbuses].num = bus = businfo.busno; buses[nbuses].maxdevs = businfo.maxdevs; domain = nbuses; nbuses++; for (dev = 0; dev < businfo.maxdevs; dev++) { nfuncs = pci_nfuncs(domain, bus, dev); for (func = 0; func < nfuncs; func++) { if (pci_read(domain, bus, dev, func, PCI_ID_REG, ®) != 0) continue; if (PCI_VENDOR(reg) == PCI_VENDOR_INVALID || PCI_VENDOR(reg) == 0) continue; ndevs++; } } snprintf(netbsd_devname, 32, "/dev/pci%d", nbuses); pcifd = open(netbsd_devname, O_RDWR); } pci_sys->num_devices = ndevs; pci_sys->devices = calloc(ndevs, sizeof(struct pci_device_private)); if (pci_sys->devices == NULL) { int i; for (i = 0; i < nbuses; i++) close(buses[i].fd); free(pci_sys); pci_sys = NULL; return ENOMEM; } device = pci_sys->devices; for (domain = 0; domain < nbuses; domain++) { bus = buses[domain].num; for (dev = 0; dev < buses[domain].maxdevs; dev++) { nfuncs = pci_nfuncs(domain, bus, dev); for (func = 0; func < nfuncs; func++) { if (pci_read(domain, bus, dev, func, PCI_ID_REG, ®) != 0) continue; if (PCI_VENDOR(reg) == PCI_VENDOR_INVALID || PCI_VENDOR(reg) == 0) continue; device->base.domain = domain; if (domain > 0xffff) device->base.domain_16 = 0xffff; else device->base.domain_16 = domain & 0xffff; device->base.bus = bus; device->base.dev = dev; device->base.func = func; device->base.vendor_id = PCI_VENDOR(reg); device->base.device_id = PCI_PRODUCT(reg); if (pci_read(domain, bus, dev, func, PCI_CLASS_REG, ®) != 0) continue; device->base.device_class = PCI_INTERFACE(reg) | PCI_CLASS(reg) << 16 | PCI_SUBCLASS(reg) << 8; device->base.revision = PCI_REVISION(reg); if (pci_read(domain, bus, dev, func, PCI_SUBSYS_ID_REG, ®) != 0) continue; device->base.subvendor_id = PCI_VENDOR(reg); device->base.subdevice_id = PCI_PRODUCT(reg); device++; } } } return 0; }