// SPDX-License-Identifier: GPL-2.0+ /* * Copyright (c) 2014 Google, Inc * Written by Simon Glass */ #define LOG_CATEGORY UCLASS_PCI #include #include #include #include #include #include #include #include #include #include #include #include #if defined(CONFIG_X86) && defined(CONFIG_HAVE_FSP) #include #endif #include #include #include "pci_internal.h" DECLARE_GLOBAL_DATA_PTR; int pci_get_bus(int busnum, struct udevice **busp) { int ret; ret = uclass_get_device_by_seq(UCLASS_PCI, busnum, busp); /* Since buses may not be numbered yet try a little harder with bus 0 */ if (ret == -ENODEV) { ret = uclass_first_device_err(UCLASS_PCI, busp); if (ret) return ret; ret = uclass_get_device_by_seq(UCLASS_PCI, busnum, busp); } return ret; } struct udevice *pci_get_controller(struct udevice *dev) { while (device_is_on_pci_bus(dev)) dev = dev->parent; return dev; } pci_dev_t dm_pci_get_bdf(const struct udevice *dev) { struct pci_child_plat *pplat = dev_get_parent_plat(dev); struct udevice *bus = dev->parent; /* * This error indicates that @dev is a device on an unprobed PCI bus. * The bus likely has bus=seq == -1, so the PCI_ADD_BUS() macro below * will produce a bad BDF> * * A common cause of this problem is that this function is called in the * of_to_plat() method of @dev. Accessing the PCI bus in that * method is not allowed, since it has not yet been probed. To fix this, * move that access to the probe() method of @dev instead. */ if (!device_active(bus)) log_err("PCI: Device '%s' on unprobed bus '%s'\n", dev->name, bus->name); return PCI_ADD_BUS(dev_seq(bus), pplat->devfn); } /** * pci_get_bus_max() - returns the bus number of the last active bus * * Return: last bus number, or -1 if no active buses */ static int pci_get_bus_max(void) { struct udevice *bus; struct uclass *uc; int ret = -1; ret = uclass_get(UCLASS_PCI, &uc); uclass_foreach_dev(bus, uc) { if (dev_seq(bus) > ret) ret = dev_seq(bus); } debug("%s: ret=%d\n", __func__, ret); return ret; } int pci_last_busno(void) { return pci_get_bus_max(); } int pci_get_ff(enum pci_size_t size) { switch (size) { case PCI_SIZE_8: return 0xff; case PCI_SIZE_16: return 0xffff; default: return 0xffffffff; } } static void pci_dev_find_ofnode(struct udevice *bus, phys_addr_t bdf, ofnode *rnode) { struct fdt_pci_addr addr; ofnode node; int ret; dev_for_each_subnode(node, bus) { ret = ofnode_read_pci_addr(node, FDT_PCI_SPACE_CONFIG, "reg", &addr); if (ret) continue; if (PCI_MASK_BUS(addr.phys_hi) != PCI_MASK_BUS(bdf)) continue; *rnode = node; break; } }; int pci_bus_find_devfn(const struct udevice *bus, pci_dev_t find_devfn, struct udevice **devp) { struct udevice *dev; for (device_find_first_child(bus, &dev); dev; device_find_next_child(&dev)) { struct pci_child_plat *pplat; pplat = dev_get_parent_plat(dev); if (pplat && pplat->devfn == find_devfn) { *devp = dev; return 0; } } return -ENODEV; } int dm_pci_bus_find_bdf(pci_dev_t bdf, struct udevice **devp) { struct udevice *bus; int ret; ret = pci_get_bus(PCI_BUS(bdf), &bus); if (ret) return ret; return pci_bus_find_devfn(bus, PCI_MASK_BUS(bdf), devp); } static int pci_device_matches_ids(struct udevice *dev, const struct pci_device_id *ids) { struct pci_child_plat *pplat; int i; pplat = dev_get_parent_plat(dev); if (!pplat) return -EINVAL; for (i = 0; ids[i].vendor != 0; i++) { if (pplat->vendor == ids[i].vendor && pplat->device == ids[i].device) return i; } return -EINVAL; } int pci_bus_find_devices(struct udevice *bus, const struct pci_device_id *ids, int *indexp, struct udevice **devp) { struct udevice *dev; /* Scan all devices on this bus */ for (device_find_first_child(bus, &dev); dev; device_find_next_child(&dev)) { if (pci_device_matches_ids(dev, ids) >= 0) { if ((*indexp)-- <= 0) { *devp = dev; return 0; } } } return -ENODEV; } int pci_find_device_id(const struct pci_device_id *ids, int index, struct udevice **devp) { struct udevice *bus; /* Scan all known buses */ for (uclass_first_device(UCLASS_PCI, &bus); bus; uclass_next_device(&bus)) { if (!pci_bus_find_devices(bus, ids, &index, devp)) return 0; } *devp = NULL; return -ENODEV; } static int dm_pci_bus_find_device(struct udevice *bus, unsigned int vendor, unsigned int device, int *indexp, struct udevice **devp) { struct pci_child_plat *pplat; struct udevice *dev; for (device_find_first_child(bus, &dev); dev; device_find_next_child(&dev)) { pplat = dev_get_parent_plat(dev); if (pplat->vendor == vendor && pplat->device == device) { if (!(*indexp)--) { *devp = dev; return 0; } } } return -ENODEV; } int dm_pci_find_device(unsigned int vendor, unsigned int device, int index, struct udevice **devp) { struct udevice *bus; /* Scan all known buses */ for (uclass_first_device(UCLASS_PCI, &bus); bus; uclass_next_device(&bus)) { if (!dm_pci_bus_find_device(bus, vendor, device, &index, devp)) return device_probe(*devp); } *devp = NULL; return -ENODEV; } int dm_pci_find_class(uint find_class, int index, struct udevice **devp) { struct udevice *dev; /* Scan all known buses */ for (pci_find_first_device(&dev); dev; pci_find_next_device(&dev)) { struct pci_child_plat *pplat = dev_get_parent_plat(dev); if (pplat->class == find_class && !index--) { *devp = dev; return device_probe(*devp); } } *devp = NULL; return -ENODEV; } int pci_bus_write_config(struct udevice *bus, pci_dev_t bdf, int offset, unsigned long value, enum pci_size_t size) { struct dm_pci_ops *ops; ops = pci_get_ops(bus); if (!ops->write_config) return -ENOSYS; if (offset < 0 || offset >= 4096) return -EINVAL; return ops->write_config(bus, bdf, offset, value, size); } int pci_bus_clrset_config32(struct udevice *bus, pci_dev_t bdf, int offset, u32 clr, u32 set) { ulong val; int ret; ret = pci_bus_read_config(bus, bdf, offset, &val, PCI_SIZE_32); if (ret) return ret; val &= ~clr; val |= set; return pci_bus_write_config(bus, bdf, offset, val, PCI_SIZE_32); } static int pci_write_config(pci_dev_t bdf, int offset, unsigned long value, enum pci_size_t size) { struct udevice *bus; int ret; ret = pci_get_bus(PCI_BUS(bdf), &bus); if (ret) return ret; return pci_bus_write_config(bus, bdf, offset, value, size); } int dm_pci_write_config(struct udevice *dev, int offset, unsigned long value, enum pci_size_t size) { struct udevice *bus; for (bus = dev; device_is_on_pci_bus(bus);) bus = bus->parent; return pci_bus_write_config(bus, dm_pci_get_bdf(dev), offset, value, size); } int pci_write_config32(pci_dev_t bdf, int offset, u32 value) { return pci_write_config(bdf, offset, value, PCI_SIZE_32); } int pci_write_config16(pci_dev_t bdf, int offset, u16 value) { return pci_write_config(bdf, offset, value, PCI_SIZE_16); } int pci_write_config8(pci_dev_t bdf, int offset, u8 value) { return pci_write_config(bdf, offset, value, PCI_SIZE_8); } int dm_pci_write_config8(struct udevice *dev, int offset, u8 value) { return dm_pci_write_config(dev, offset, value, PCI_SIZE_8); } int dm_pci_write_config16(struct udevice *dev, int offset, u16 value) { return dm_pci_write_config(dev, offset, value, PCI_SIZE_16); } int dm_pci_write_config32(struct udevice *dev, int offset, u32 value) { return dm_pci_write_config(dev, offset, value, PCI_SIZE_32); } int pci_bus_read_config(const struct udevice *bus, pci_dev_t bdf, int offset, unsigned long *valuep, enum pci_size_t size) { struct dm_pci_ops *ops; ops = pci_get_ops(bus); if (!ops->read_config) { *valuep = pci_conv_32_to_size(~0, offset, size); return -ENOSYS; } if (offset < 0 || offset >= 4096) { *valuep = pci_conv_32_to_size(0, offset, size); return -EINVAL; } return ops->read_config(bus, bdf, offset, valuep, size); } static int pci_read_config(pci_dev_t bdf, int offset, unsigned long *valuep, enum pci_size_t size) { struct udevice *bus; int ret; ret = pci_get_bus(PCI_BUS(bdf), &bus); if (ret) return ret; return pci_bus_read_config(bus, bdf, offset, valuep, size); } int dm_pci_read_config(const struct udevice *dev, int offset, unsigned long *valuep, enum pci_size_t size) { const struct udevice *bus; for (bus = dev; device_is_on_pci_bus(bus);) bus = bus->parent; return pci_bus_read_config(bus, dm_pci_get_bdf(dev), offset, valuep, size); } int pci_read_config32(pci_dev_t bdf, int offset, u32 *valuep) { unsigned long value; int ret; ret = pci_read_config(bdf, offset, &value, PCI_SIZE_32); if (ret) return ret; *valuep = value; return 0; } int pci_read_config16(pci_dev_t bdf, int offset, u16 *valuep) { unsigned long value; int ret; ret = pci_read_config(bdf, offset, &value, PCI_SIZE_16); if (ret) return ret; *valuep = value; return 0; } int pci_read_config8(pci_dev_t bdf, int offset, u8 *valuep) { unsigned long value; int ret; ret = pci_read_config(bdf, offset, &value, PCI_SIZE_8); if (ret) return ret; *valuep = value; return 0; } int dm_pci_read_config8(const struct udevice *dev, int offset, u8 *valuep) { unsigned long value; int ret; ret = dm_pci_read_config(dev, offset, &value, PCI_SIZE_8); if (ret) return ret; *valuep = value; return 0; } int dm_pci_read_config16(const struct udevice *dev, int offset, u16 *valuep) { unsigned long value; int ret; ret = dm_pci_read_config(dev, offset, &value, PCI_SIZE_16); if (ret) return ret; *valuep = value; return 0; } int dm_pci_read_config32(const struct udevice *dev, int offset, u32 *valuep) { unsigned long value; int ret; ret = dm_pci_read_config(dev, offset, &value, PCI_SIZE_32); if (ret) return ret; *valuep = value; return 0; } int dm_pci_clrset_config8(struct udevice *dev, int offset, u32 clr, u32 set) { u8 val; int ret; ret = dm_pci_read_config8(dev, offset, &val); if (ret) return ret; val &= ~clr; val |= set; return dm_pci_write_config8(dev, offset, val); } int dm_pci_clrset_config16(struct udevice *dev, int offset, u32 clr, u32 set) { u16 val; int ret; ret = dm_pci_read_config16(dev, offset, &val); if (ret) return ret; val &= ~clr; val |= set; return dm_pci_write_config16(dev, offset, val); } int dm_pci_clrset_config32(struct udevice *dev, int offset, u32 clr, u32 set) { u32 val; int ret; ret = dm_pci_read_config32(dev, offset, &val); if (ret) return ret; val &= ~clr; val |= set; return dm_pci_write_config32(dev, offset, val); } static void set_vga_bridge_bits(struct udevice *dev) { struct udevice *parent = dev->parent; u16 bc; while (dev_seq(parent) != 0) { dm_pci_read_config16(parent, PCI_BRIDGE_CONTROL, &bc); bc |= PCI_BRIDGE_CTL_VGA; dm_pci_write_config16(parent, PCI_BRIDGE_CONTROL, bc); parent = parent->parent; } } int pci_auto_config_devices(struct udevice *bus) { struct pci_controller *hose = dev_get_uclass_priv(bus); struct pci_child_plat *pplat; unsigned int sub_bus; struct udevice *dev; int ret; sub_bus = dev_seq(bus); debug("%s: start\n", __func__); pciauto_config_init(hose); for (ret = device_find_first_child(bus, &dev); !ret && dev; ret = device_find_next_child(&dev)) { unsigned int max_bus; int ret; debug("%s: device %s\n", __func__, dev->name); if (dev_has_ofnode(dev) && dev_read_bool(dev, "pci,no-autoconfig")) continue; ret = dm_pciauto_config_device(dev); if (ret < 0) return log_msg_ret("auto", ret); max_bus = ret; sub_bus = max(sub_bus, max_bus); if (dev_get_parent(dev) == bus) continue; pplat = dev_get_parent_plat(dev); if (pplat->class == (PCI_CLASS_DISPLAY_VGA << 8)) set_vga_bridge_bits(dev); } if (hose->last_busno < sub_bus) hose->last_busno = sub_bus; debug("%s: done\n", __func__); return log_msg_ret("sub", sub_bus); } int pci_generic_mmap_write_config( const struct udevice *bus, int (*addr_f)(const struct udevice *bus, pci_dev_t bdf, uint offset, void **addrp), pci_dev_t bdf, uint offset, ulong value, enum pci_size_t size) { void *address; if (addr_f(bus, bdf, offset, &address) < 0) return 0; switch (size) { case PCI_SIZE_8: writeb(value, address); return 0; case PCI_SIZE_16: writew(value, address); return 0; case PCI_SIZE_32: writel(value, address); return 0; default: return -EINVAL; } } int pci_generic_mmap_read_config( const struct udevice *bus, int (*addr_f)(const struct udevice *bus, pci_dev_t bdf, uint offset, void **addrp), pci_dev_t bdf, uint offset, ulong *valuep, enum pci_size_t size) { void *address; if (addr_f(bus, bdf, offset, &address) < 0) { *valuep = pci_get_ff(size); return 0; } switch (size) { case PCI_SIZE_8: *valuep = readb(address); return 0; case PCI_SIZE_16: *valuep = readw(address); return 0; case PCI_SIZE_32: *valuep = readl(address); return 0; default: return -EINVAL; } } int dm_pci_hose_probe_bus(struct udevice *bus) { u8 header_type; int sub_bus; int ret; int ea_pos; u8 reg; debug("%s\n", __func__); dm_pci_read_config8(bus, PCI_HEADER_TYPE, &header_type); header_type &= 0x7f; if (header_type != PCI_HEADER_TYPE_BRIDGE) { debug("%s: Skipping PCI device %d with Non-Bridge Header Type 0x%x\n", __func__, PCI_DEV(dm_pci_get_bdf(bus)), header_type); return log_msg_ret("probe", -EINVAL); } if (IS_ENABLED(CONFIG_PCI_ENHANCED_ALLOCATION)) ea_pos = dm_pci_find_capability(bus, PCI_CAP_ID_EA); else ea_pos = 0; if (ea_pos) { dm_pci_read_config8(bus, ea_pos + sizeof(u32) + sizeof(u8), ®); sub_bus = reg; } else { sub_bus = pci_get_bus_max() + 1; } debug("%s: bus = %d/%s\n", __func__, sub_bus, bus->name); dm_pciauto_prescan_setup_bridge(bus, sub_bus); ret = device_probe(bus); if (ret) { debug("%s: Cannot probe bus %s: %d\n", __func__, bus->name, ret); return log_msg_ret("probe", ret); } if (!ea_pos) sub_bus = pci_get_bus_max(); dm_pciauto_postscan_setup_bridge(bus, sub_bus); return sub_bus; } /** * pci_match_one_device - Tell if a PCI device structure has a matching * PCI device id structure * @id: single PCI device id structure to match * @find: the PCI device id structure to match against * * Returns true if the finding pci_device_id structure matched or false if * there is no match. */ static bool pci_match_one_id(const struct pci_device_id *id, const struct pci_device_id *find) { if ((id->vendor == PCI_ANY_ID || id->vendor == find->vendor) && (id->device == PCI_ANY_ID || id->device == find->device) && (id->subvendor == PCI_ANY_ID || id->subvendor == find->subvendor) && (id->subdevice == PCI_ANY_ID || id->subdevice == find->subdevice) && !((id->class ^ find->class) & id->class_mask)) return true; return false; } /** * pci_need_device_pre_reloc() - Check if a device should be bound * * This checks a list of vendor/device-ID values indicating devices that should * be bound before relocation. * * @bus: Bus to check * @vendor: Vendor ID to check * @device: Device ID to check * Return: true if the vendor/device is in the list, false if not */ static bool pci_need_device_pre_reloc(struct udevice *bus, uint vendor, uint device) { u32 vendev; int index; for (index = 0; !dev_read_u32_index(bus, "u-boot,pci-pre-reloc", index, &vendev); index++) { if (vendev == PCI_VENDEV(vendor, device)) return true; } return false; } /** * pci_find_and_bind_driver() - Find and bind the right PCI driver * * This only looks at certain fields in the descriptor. * * @parent: Parent bus * @find_id: Specification of the driver to find * @bdf: Bus/device/function addreess - see PCI_BDF() * @devp: Returns a pointer to the device created * Return: 0 if OK, -EPERM if the device is not needed before relocation and * therefore was not created, other -ve value on error */ static int pci_find_and_bind_driver(struct udevice *parent, struct pci_device_id *find_id, pci_dev_t bdf, struct udevice **devp) { struct pci_driver_entry *start, *entry; ofnode node = ofnode_null(); const char *drv; int n_ents; int ret; char name[30], *str; bool bridge; *devp = NULL; debug("%s: Searching for driver: vendor=%x, device=%x\n", __func__, find_id->vendor, find_id->device); /* Determine optional OF node */ if (ofnode_valid(dev_ofnode(parent))) pci_dev_find_ofnode(parent, bdf, &node); if (ofnode_valid(node) && !ofnode_is_enabled(node)) { debug("%s: Ignoring disabled device\n", __func__); return log_msg_ret("dis", -EPERM); } start = ll_entry_start(struct pci_driver_entry, pci_driver_entry); n_ents = ll_entry_count(struct pci_driver_entry, pci_driver_entry); for (entry = start; entry != start + n_ents; entry++) { const struct pci_device_id *id; struct udevice *dev; const struct driver *drv; for (id = entry->match; id->vendor || id->subvendor || id->class_mask; id++) { if (!pci_match_one_id(id, find_id)) continue; drv = entry->driver; /* * In the pre-relocation phase, we only bind devices * whose driver has the DM_FLAG_PRE_RELOC set, to save * precious memory space as on some platforms as that * space is pretty limited (ie: using Cache As RAM). */ if (!(gd->flags & GD_FLG_RELOC) && !(drv->flags & DM_FLAG_PRE_RELOC)) return log_msg_ret("pre", -EPERM); /* * We could pass the descriptor to the driver as * plat (instead of NULL) and allow its bind() * method to return -ENOENT if it doesn't support this * device. That way we could continue the search to * find another driver. For now this doesn't seem * necesssary, so just bind the first match. */ ret = device_bind(parent, drv, drv->name, NULL, node, &dev); if (ret) goto error; debug("%s: Match found: %s\n", __func__, drv->name); dev->driver_data = id->driver_data; *devp = dev; return 0; } } bridge = (find_id->class >> 8) == PCI_CLASS_BRIDGE_PCI; /* * In the pre-relocation phase, we only bind bridge devices to save * precious memory space as on some platforms as that space is pretty * limited (ie: using Cache As RAM). */ if (!(gd->flags & GD_FLG_RELOC) && !bridge && !pci_need_device_pre_reloc(parent, find_id->vendor, find_id->device)) return log_msg_ret("notbr", -EPERM); /* Bind a generic driver so that the device can be used */ sprintf(name, "pci_%x:%x.%x", dev_seq(parent), PCI_DEV(bdf), PCI_FUNC(bdf)); str = strdup(name); if (!str) return -ENOMEM; drv = bridge ? "pci_bridge_drv" : "pci_generic_drv"; ret = device_bind_driver_to_node(parent, drv, str, node, devp); if (ret) { debug("%s: Failed to bind generic driver: %d\n", __func__, ret); free(str); return ret; } debug("%s: No match found: bound generic driver instead\n", __func__); return 0; error: debug("%s: No match found: error %d\n", __func__, ret); return ret; } __weak extern void board_pci_fixup_dev(struct udevice *bus, struct udevice *dev) { } int pci_bind_bus_devices(struct udevice *bus) { ulong vendor, device; ulong header_type; pci_dev_t bdf, end; bool found_multi; int ari_off; int ret; found_multi = false; end = PCI_BDF(dev_seq(bus), PCI_MAX_PCI_DEVICES - 1, PCI_MAX_PCI_FUNCTIONS - 1); for (bdf = PCI_BDF(dev_seq(bus), 0, 0); bdf <= end; bdf += PCI_BDF(0, 0, 1)) { struct pci_child_plat *pplat; struct udevice *dev; ulong class; if (!PCI_FUNC(bdf)) found_multi = false; if (PCI_FUNC(bdf) && !found_multi) continue; /* Check only the first access, we don't expect problems */ ret = pci_bus_read_config(bus, bdf, PCI_VENDOR_ID, &vendor, PCI_SIZE_16); if (ret || vendor == 0xffff || vendor == 0x0000) continue; pci_bus_read_config(bus, bdf, PCI_HEADER_TYPE, &header_type, PCI_SIZE_8); if (!PCI_FUNC(bdf)) found_multi = header_type & 0x80; debug("%s: bus %d/%s: found device %x, function %d", __func__, dev_seq(bus), bus->name, PCI_DEV(bdf), PCI_FUNC(bdf)); pci_bus_read_config(bus, bdf, PCI_DEVICE_ID, &device, PCI_SIZE_16); pci_bus_read_config(bus, bdf, PCI_CLASS_REVISION, &class, PCI_SIZE_32); class >>= 8; /* Find this device in the device tree */ ret = pci_bus_find_devfn(bus, PCI_MASK_BUS(bdf), &dev); debug(": find ret=%d\n", ret); /* If nothing in the device tree, bind a device */ if (ret == -ENODEV) { struct pci_device_id find_id; ulong val; memset(&find_id, '\0', sizeof(find_id)); find_id.vendor = vendor; find_id.device = device; find_id.class = class; if ((header_type & 0x7f) == PCI_HEADER_TYPE_NORMAL) { pci_bus_read_config(bus, bdf, PCI_SUBSYSTEM_VENDOR_ID, &val, PCI_SIZE_32); find_id.subvendor = val & 0xffff; find_id.subdevice = val >> 16; } ret = pci_find_and_bind_driver(bus, &find_id, bdf, &dev); } if (ret == -EPERM) continue; else if (ret) return ret; /* Update the platform data */ pplat = dev_get_parent_plat(dev); pplat->devfn = PCI_MASK_BUS(bdf); pplat->vendor = vendor; pplat->device = device; pplat->class = class; if (IS_ENABLED(CONFIG_PCI_ARID)) { ari_off = dm_pci_find_ext_capability(dev, PCI_EXT_CAP_ID_ARI); if (ari_off) { u16 ari_cap; /* * Read Next Function number in ARI Cap * Register */ dm_pci_read_config16(dev, ari_off + 4, &ari_cap); /* * Update next scan on this function number, * subtract 1 in BDF to satisfy loop increment. */ if (ari_cap & 0xff00) { bdf = PCI_BDF(PCI_BUS(bdf), PCI_DEV(ari_cap), PCI_FUNC(ari_cap)); bdf = bdf - 0x100; } } } board_pci_fixup_dev(bus, dev); } return 0; } static int decode_regions(struct pci_controller *hose, ofnode parent_node, ofnode node) { int pci_addr_cells, addr_cells, size_cells; int cells_per_record; struct bd_info *bd; const u32 *prop; int max_regions; int len; int i; /* handle booting from coreboot, etc. */ if (!ll_boot_init()) return 0; prop = ofnode_get_property(node, "ranges", &len); if (!prop) { debug("%s: Cannot decode regions\n", __func__); return -EINVAL; } pci_addr_cells = ofnode_read_simple_addr_cells(node); addr_cells = ofnode_read_simple_addr_cells(parent_node); size_cells = ofnode_read_simple_size_cells(node); /* PCI addresses are always 3-cells */ len /= sizeof(u32); cells_per_record = pci_addr_cells + addr_cells + size_cells; hose->region_count = 0; debug("%s: len=%d, cells_per_record=%d\n", __func__, len, cells_per_record); /* Dynamically allocate the regions array */ max_regions = len / cells_per_record + CONFIG_NR_DRAM_BANKS; hose->regions = (struct pci_region *) calloc(1, max_regions * sizeof(struct pci_region)); if (!hose->regions) return -ENOMEM; for (i = 0; i < max_regions; i++, len -= cells_per_record) { u64 pci_addr, addr, size; int space_code; u32 flags; int type; int pos; if (len < cells_per_record) break; flags = fdt32_to_cpu(prop[0]); space_code = (flags >> 24) & 3; pci_addr = fdtdec_get_number(prop + 1, 2); prop += pci_addr_cells; addr = fdtdec_get_number(prop, addr_cells); prop += addr_cells; size = fdtdec_get_number(prop, size_cells); prop += size_cells; debug("%s: region %d, pci_addr=%llx, addr=%llx, size=%llx, space_code=%d\n", __func__, hose->region_count, pci_addr, addr, size, space_code); if (space_code & 2) { type = flags & (1U << 30) ? PCI_REGION_PREFETCH : PCI_REGION_MEM; } else if (space_code & 1) { type = PCI_REGION_IO; } else { continue; } if (!IS_ENABLED(CONFIG_SYS_PCI_64BIT) && type == PCI_REGION_MEM && upper_32_bits(pci_addr)) { debug(" - pci_addr beyond the 32-bit boundary, ignoring\n"); continue; } if (!IS_ENABLED(CONFIG_PHYS_64BIT) && upper_32_bits(addr)) { debug(" - addr beyond the 32-bit boundary, ignoring\n"); continue; } if (~((pci_addr_t)0) - pci_addr < size) { debug(" - PCI range exceeds max address, ignoring\n"); continue; } if (~((phys_addr_t)0) - addr < size) { debug(" - phys range exceeds max address, ignoring\n"); continue; } pos = -1; if (!IS_ENABLED(CONFIG_PCI_REGION_MULTI_ENTRY)) { for (i = 0; i < hose->region_count; i++) { if (hose->regions[i].flags == type) pos = i; } } if (pos == -1) pos = hose->region_count++; debug(" - type=%d, pos=%d\n", type, pos); pci_set_region(hose->regions + pos, pci_addr, addr, size, type); } /* Add a region for our local memory */ bd = gd->bd; if (!bd) return 0; for (i = 0; i < CONFIG_NR_DRAM_BANKS; ++i) { if (bd->bi_dram[i].size) { phys_addr_t start = bd->bi_dram[i].start; if (IS_ENABLED(CONFIG_PCI_MAP_SYSTEM_MEMORY)) start = virt_to_phys((void *)(uintptr_t)bd->bi_dram[i].start); pci_set_region(hose->regions + hose->region_count++, start, start, bd->bi_dram[i].size, PCI_REGION_MEM | PCI_REGION_SYS_MEMORY); } } return 0; } static int pci_uclass_pre_probe(struct udevice *bus) { struct pci_controller *hose; struct uclass *uc; int ret; debug("%s, bus=%d/%s, parent=%s\n", __func__, dev_seq(bus), bus->name, bus->parent->name); hose = dev_get_uclass_priv(bus); /* * Set the sequence number, if device_bind() doesn't. We want control * of this so that numbers are allocated as devices are probed. That * ensures that sub-bus numbered is correct (sub-buses must get numbers * higher than their parents) */ if (dev_seq(bus) == -1) { ret = uclass_get(UCLASS_PCI, &uc); if (ret) return ret; bus->seq_ = uclass_find_next_free_seq(uc); } /* For bridges, use the top-level PCI controller */ if (!device_is_on_pci_bus(bus)) { hose->ctlr = bus; ret = decode_regions(hose, dev_ofnode(bus->parent), dev_ofnode(bus)); if (ret) return ret; } else { struct pci_controller *parent_hose; parent_hose = dev_get_uclass_priv(bus->parent); hose->ctlr = parent_hose->bus; } hose->bus = bus; hose->first_busno = dev_seq(bus); hose->last_busno = dev_seq(bus); if (dev_has_ofnode(bus)) { hose->skip_auto_config_until_reloc = dev_read_bool(bus, "u-boot,skip-auto-config-until-reloc"); } return 0; } static int pci_uclass_post_probe(struct udevice *bus) { struct pci_controller *hose = dev_get_uclass_priv(bus); int ret; debug("%s: probing bus %d\n", __func__, dev_seq(bus)); ret = pci_bind_bus_devices(bus); if (ret) return log_msg_ret("bind", ret); if (CONFIG_IS_ENABLED(PCI_PNP) && ll_boot_init() && (!hose->skip_auto_config_until_reloc || (gd->flags & GD_FLG_RELOC))) { ret = pci_auto_config_devices(bus); if (ret < 0) return log_msg_ret("cfg", ret); } #if defined(CONFIG_X86) && defined(CONFIG_HAVE_FSP) /* * Per Intel FSP specification, we should call FSP notify API to * inform FSP that PCI enumeration has been done so that FSP will * do any necessary initialization as required by the chipset's * BIOS Writer's Guide (BWG). * * Unfortunately we have to put this call here as with driver model, * the enumeration is all done on a lazy basis as needed, so until * something is touched on PCI it won't happen. * * Note we only call this 1) after U-Boot is relocated, and 2) * root bus has finished probing. */ if ((gd->flags & GD_FLG_RELOC) && dev_seq(bus) == 0 && ll_boot_init()) { ret = fsp_init_phase_pci(); if (ret) return log_msg_ret("fsp", ret); } #endif return 0; } static int pci_uclass_child_post_bind(struct udevice *dev) { struct pci_child_plat *pplat; if (!dev_has_ofnode(dev)) return 0; pplat = dev_get_parent_plat(dev); /* Extract vendor id and device id if available */ ofnode_read_pci_vendev(dev_ofnode(dev), &pplat->vendor, &pplat->device); /* Extract the devfn from fdt_pci_addr */ pplat->devfn = pci_get_devfn(dev); return 0; } static int pci_bridge_read_config(const struct udevice *bus, pci_dev_t bdf, uint offset, ulong *valuep, enum pci_size_t size) { struct pci_controller *hose = dev_get_uclass_priv(bus); return pci_bus_read_config(hose->ctlr, bdf, offset, valuep, size); } static int pci_bridge_write_config(struct udevice *bus, pci_dev_t bdf, uint offset, ulong value, enum pci_size_t size) { struct pci_controller *hose = dev_get_uclass_priv(bus); return pci_bus_write_config(hose->ctlr, bdf, offset, value, size); } static int skip_to_next_device(struct udevice *bus, struct udevice **devp) { struct udevice *dev; /* * Scan through all the PCI controllers. On x86 there will only be one * but that is not necessarily true on other hardware. */ while (bus) { device_find_first_child(bus, &dev); if (dev) { *devp = dev; return 0; } uclass_next_device(&bus); } return 0; } int pci_find_next_device(struct udevice **devp) { struct udevice *child = *devp; struct udevice *bus = child->parent; /* First try all the siblings */ *devp = NULL; while (child) { device_find_next_child(&child); if (child) { *devp = child; return 0; } } /* We ran out of siblings. Try the next bus */ uclass_next_device(&bus); return bus ? skip_to_next_device(bus, devp) : 0; } int pci_find_first_device(struct udevice **devp) { struct udevice *bus; *devp = NULL; uclass_first_device(UCLASS_PCI, &bus); return skip_to_next_device(bus, devp); } ulong pci_conv_32_to_size(ulong value, uint offset, enum pci_size_t size) { switch (size) { case PCI_SIZE_8: return (value >> ((offset & 3) * 8)) & 0xff; case PCI_SIZE_16: return (value >> ((offset & 2) * 8)) & 0xffff; default: return value; } } ulong pci_conv_size_to_32(ulong old, ulong value, uint offset, enum pci_size_t size) { uint off_mask; uint val_mask, shift; ulong ldata, mask; switch (size) { case PCI_SIZE_8: off_mask = 3; val_mask = 0xff; break; case PCI_SIZE_16: off_mask = 2; val_mask = 0xffff; break; default: return value; } shift = (offset & off_mask) * 8; ldata = (value & val_mask) << shift; mask = val_mask << shift; value = (old & ~mask) | ldata; return value; } int pci_get_dma_regions(struct udevice *dev, struct pci_region *memp, int index) { int pci_addr_cells, addr_cells, size_cells; int cells_per_record; const u32 *prop; int len; int i = 0; prop = ofnode_get_property(dev_ofnode(dev), "dma-ranges", &len); if (!prop) { log_err("PCI: Device '%s': Cannot decode dma-ranges\n", dev->name); return -EINVAL; } pci_addr_cells = ofnode_read_simple_addr_cells(dev_ofnode(dev)); addr_cells = ofnode_read_simple_addr_cells(dev_ofnode(dev->parent)); size_cells = ofnode_read_simple_size_cells(dev_ofnode(dev)); /* PCI addresses are always 3-cells */ len /= sizeof(u32); cells_per_record = pci_addr_cells + addr_cells + size_cells; debug("%s: len=%d, cells_per_record=%d\n", __func__, len, cells_per_record); while (len) { memp->bus_start = fdtdec_get_number(prop + 1, 2); prop += pci_addr_cells; memp->phys_start = fdtdec_get_number(prop, addr_cells); prop += addr_cells; memp->size = fdtdec_get_number(prop, size_cells); prop += size_cells; if (i == index) return 0; i++; len -= cells_per_record; } return -EINVAL; } int pci_get_regions(struct udevice *dev, struct pci_region **iop, struct pci_region **memp, struct pci_region **prefp) { struct udevice *bus = pci_get_controller(dev); struct pci_controller *hose = dev_get_uclass_priv(bus); int i; *iop = NULL; *memp = NULL; *prefp = NULL; for (i = 0; i < hose->region_count; i++) { switch (hose->regions[i].flags) { case PCI_REGION_IO: if (!*iop || (*iop)->size < hose->regions[i].size) *iop = hose->regions + i; break; case PCI_REGION_MEM: if (!*memp || (*memp)->size < hose->regions[i].size) *memp = hose->regions + i; break; case (PCI_REGION_MEM | PCI_REGION_PREFETCH): if (!*prefp || (*prefp)->size < hose->regions[i].size) *prefp = hose->regions + i; break; } } return (*iop != NULL) + (*memp != NULL) + (*prefp != NULL); } u32 dm_pci_read_bar32(const struct udevice *dev, int barnum) { u32 addr; int bar; bar = PCI_BASE_ADDRESS_0 + barnum * 4; dm_pci_read_config32(dev, bar, &addr); /* * If we get an invalid address, return this so that comparisons with * FDT_ADDR_T_NONE work correctly */ if (addr == 0xffffffff) return addr; else if (addr & PCI_BASE_ADDRESS_SPACE_IO) return addr & PCI_BASE_ADDRESS_IO_MASK; else return addr & PCI_BASE_ADDRESS_MEM_MASK; } void dm_pci_write_bar32(struct udevice *dev, int barnum, u32 addr) { int bar; bar = PCI_BASE_ADDRESS_0 + barnum * 4; dm_pci_write_config32(dev, bar, addr); } phys_addr_t dm_pci_bus_to_phys(struct udevice *dev, pci_addr_t bus_addr, size_t len, unsigned long mask, unsigned long flags) { struct udevice *ctlr; struct pci_controller *hose; struct pci_region *res; pci_addr_t offset; int i; /* The root controller has the region information */ ctlr = pci_get_controller(dev); hose = dev_get_uclass_priv(ctlr); if (hose->region_count == 0) return bus_addr; for (i = 0; i < hose->region_count; i++) { res = &hose->regions[i]; if ((res->flags & mask) != flags) continue; if (bus_addr < res->bus_start) continue; offset = bus_addr - res->bus_start; if (offset >= res->size) continue; if (len > res->size - offset) continue; return res->phys_start + offset; } puts("pci_hose_bus_to_phys: invalid physical address\n"); return 0; } pci_addr_t dm_pci_phys_to_bus(struct udevice *dev, phys_addr_t phys_addr, size_t len, unsigned long mask, unsigned long flags) { struct udevice *ctlr; struct pci_controller *hose; struct pci_region *res; phys_addr_t offset; int i; /* The root controller has the region information */ ctlr = pci_get_controller(dev); hose = dev_get_uclass_priv(ctlr); if (hose->region_count == 0) return phys_addr; for (i = 0; i < hose->region_count; i++) { res = &hose->regions[i]; if ((res->flags & mask) != flags) continue; if (phys_addr < res->phys_start) continue; offset = phys_addr - res->phys_start; if (offset >= res->size) continue; if (len > res->size - offset) continue; return res->bus_start + offset; } puts("pci_hose_phys_to_bus: invalid physical address\n"); return 0; } static phys_addr_t dm_pci_map_ea_virt(struct udevice *dev, int ea_off, struct pci_child_plat *pdata) { phys_addr_t addr = 0; /* * In the case of a Virtual Function device using BAR * base and size, add offset for VFn BAR(1, 2, 3...n) */ if (pdata->is_virtfn) { size_t sz; u32 ea_entry; /* MaxOffset, 1st DW */ dm_pci_read_config32(dev, ea_off + 8, &ea_entry); sz = ea_entry & PCI_EA_FIELD_MASK; /* Fill up lower 2 bits */ sz |= (~PCI_EA_FIELD_MASK); if (ea_entry & PCI_EA_IS_64) { /* MaxOffset 2nd DW */ dm_pci_read_config32(dev, ea_off + 16, &ea_entry); sz |= ((u64)ea_entry) << 32; } addr = (pdata->virtid - 1) * (sz + 1); } return addr; } static void *dm_pci_map_ea_bar(struct udevice *dev, int bar, size_t offset, size_t len, int ea_off, struct pci_child_plat *pdata) { int ea_cnt, i, entry_size; int bar_id = (bar - PCI_BASE_ADDRESS_0) >> 2; u32 ea_entry; phys_addr_t addr; if (IS_ENABLED(CONFIG_PCI_SRIOV)) { /* * In the case of a Virtual Function device, device is * Physical function, so pdata will point to required VF * specific data. */ if (pdata->is_virtfn) bar_id += PCI_EA_BEI_VF_BAR0; } /* EA capability structure header */ dm_pci_read_config32(dev, ea_off, &ea_entry); ea_cnt = (ea_entry >> 16) & PCI_EA_NUM_ENT_MASK; ea_off += PCI_EA_FIRST_ENT; for (i = 0; i < ea_cnt; i++, ea_off += entry_size) { /* Entry header */ dm_pci_read_config32(dev, ea_off, &ea_entry); entry_size = ((ea_entry & PCI_EA_ES) + 1) << 2; if (((ea_entry & PCI_EA_BEI) >> 4) != bar_id) continue; /* Base address, 1st DW */ dm_pci_read_config32(dev, ea_off + 4, &ea_entry); addr = ea_entry & PCI_EA_FIELD_MASK; if (ea_entry & PCI_EA_IS_64) { /* Base address, 2nd DW, skip over 4B MaxOffset */ dm_pci_read_config32(dev, ea_off + 12, &ea_entry); addr |= ((u64)ea_entry) << 32; } if (IS_ENABLED(CONFIG_PCI_SRIOV)) addr += dm_pci_map_ea_virt(dev, ea_off, pdata); if (~((phys_addr_t)0) - addr < offset) return NULL; /* size ignored for now */ return map_physmem(addr + offset, len, MAP_NOCACHE); } return 0; } void *dm_pci_map_bar(struct udevice *dev, int bar, size_t offset, size_t len, unsigned long mask, unsigned long flags) { struct pci_child_plat *pdata = dev_get_parent_plat(dev); struct udevice *udev = dev; pci_addr_t pci_bus_addr; u32 bar_response; int ea_off; if (IS_ENABLED(CONFIG_PCI_SRIOV)) { /* * In case of Virtual Function devices, use PF udevice * as EA capability is defined in Physical Function */ if (pdata->is_virtfn) udev = pdata->pfdev; } /* * if the function supports Enhanced Allocation use that instead of * BARs * Incase of virtual functions, pdata will help read VF BEI * and EA entry size. */ if (IS_ENABLED(CONFIG_PCI_ENHANCED_ALLOCATION)) ea_off = dm_pci_find_capability(udev, PCI_CAP_ID_EA); else ea_off = 0; if (ea_off) return dm_pci_map_ea_bar(udev, bar, offset, len, ea_off, pdata); /* read BAR address */ dm_pci_read_config32(udev, bar, &bar_response); pci_bus_addr = (pci_addr_t)(bar_response & ~0xf); if (~((pci_addr_t)0) - pci_bus_addr < offset) return NULL; /* * Forward the length argument to dm_pci_bus_to_virt. The length will * be used to check that the entire address range has been declared as * a PCI range, but a better check would be to probe for the size of * the bar and prevent overflow more locally. */ return dm_pci_bus_to_virt(udev, pci_bus_addr + offset, len, mask, flags, MAP_NOCACHE); } static int _dm_pci_find_next_capability(struct udevice *dev, u8 pos, int cap) { int ttl = PCI_FIND_CAP_TTL; u8 id; u16 ent; dm_pci_read_config8(dev, pos, &pos); while (ttl--) { if (pos < PCI_STD_HEADER_SIZEOF) break; pos &= ~3; dm_pci_read_config16(dev, pos, &ent); id = ent & 0xff; if (id == 0xff) break; if (id == cap) return pos; pos = (ent >> 8); } return 0; } int dm_pci_find_next_capability(struct udevice *dev, u8 start, int cap) { return _dm_pci_find_next_capability(dev, start + PCI_CAP_LIST_NEXT, cap); } int dm_pci_find_capability(struct udevice *dev, int cap) { u16 status; u8 header_type; u8 pos; dm_pci_read_config16(dev, PCI_STATUS, &status); if (!(status & PCI_STATUS_CAP_LIST)) return 0; dm_pci_read_config8(dev, PCI_HEADER_TYPE, &header_type); if ((header_type & 0x7f) == PCI_HEADER_TYPE_CARDBUS) pos = PCI_CB_CAPABILITY_LIST; else pos = PCI_CAPABILITY_LIST; return _dm_pci_find_next_capability(dev, pos, cap); } int dm_pci_find_next_ext_capability(struct udevice *dev, int start, int cap) { u32 header; int ttl; int pos = PCI_CFG_SPACE_SIZE; /* minimum 8 bytes per capability */ ttl = (PCI_CFG_SPACE_EXP_SIZE - PCI_CFG_SPACE_SIZE) / 8; if (start) pos = start; dm_pci_read_config32(dev, pos, &header); /* * If we have no capabilities, this is indicated by cap ID, * cap version and next pointer all being 0. */ if (header == 0) return 0; while (ttl--) { if (PCI_EXT_CAP_ID(header) == cap) return pos; pos = PCI_EXT_CAP_NEXT(header); if (pos < PCI_CFG_SPACE_SIZE) break; dm_pci_read_config32(dev, pos, &header); } return 0; } int dm_pci_find_ext_capability(struct udevice *dev, int cap) { return dm_pci_find_next_ext_capability(dev, 0, cap); } int dm_pci_flr(struct udevice *dev) { int pcie_off; u32 cap; /* look for PCI Express Capability */ pcie_off = dm_pci_find_capability(dev, PCI_CAP_ID_EXP); if (!pcie_off) return -ENOENT; /* check FLR capability */ dm_pci_read_config32(dev, pcie_off + PCI_EXP_DEVCAP, &cap); if (!(cap & PCI_EXP_DEVCAP_FLR)) return -ENOENT; dm_pci_clrset_config16(dev, pcie_off + PCI_EXP_DEVCTL, 0, PCI_EXP_DEVCTL_BCR_FLR); /* wait 100ms, per PCI spec */ mdelay(100); return 0; } #if defined(CONFIG_PCI_SRIOV) int pci_sriov_init(struct udevice *pdev, int vf_en) { u16 vendor, device; struct udevice *bus; struct udevice *dev; pci_dev_t bdf; u16 ctrl; u16 num_vfs; u16 total_vf; u16 vf_offset; u16 vf_stride; int vf, ret; int pos; pos = dm_pci_find_ext_capability(pdev, PCI_EXT_CAP_ID_SRIOV); if (!pos) { debug("Error: SRIOV capability not found\n"); return -ENOENT; } dm_pci_read_config16(pdev, pos + PCI_SRIOV_CTRL, &ctrl); dm_pci_read_config16(pdev, pos + PCI_SRIOV_TOTAL_VF, &total_vf); if (vf_en > total_vf) vf_en = total_vf; dm_pci_write_config16(pdev, pos + PCI_SRIOV_NUM_VF, vf_en); ctrl |= PCI_SRIOV_CTRL_VFE | PCI_SRIOV_CTRL_MSE; dm_pci_write_config16(pdev, pos + PCI_SRIOV_CTRL, ctrl); dm_pci_read_config16(pdev, pos + PCI_SRIOV_NUM_VF, &num_vfs); if (num_vfs > vf_en) num_vfs = vf_en; dm_pci_read_config16(pdev, pos + PCI_SRIOV_VF_OFFSET, &vf_offset); dm_pci_read_config16(pdev, pos + PCI_SRIOV_VF_STRIDE, &vf_stride); dm_pci_read_config16(pdev, PCI_VENDOR_ID, &vendor); dm_pci_read_config16(pdev, pos + PCI_SRIOV_VF_DID, &device); bdf = dm_pci_get_bdf(pdev); ret = pci_get_bus(PCI_BUS(bdf), &bus); if (ret) return ret; bdf += PCI_BDF(0, 0, vf_offset); for (vf = 0; vf < num_vfs; vf++) { struct pci_child_plat *pplat; ulong class; pci_bus_read_config(bus, bdf, PCI_CLASS_DEVICE, &class, PCI_SIZE_16); debug("%s: bus %d/%s: found VF %x:%x\n", __func__, dev_seq(bus), bus->name, PCI_DEV(bdf), PCI_FUNC(bdf)); /* Find this device in the device tree */ ret = pci_bus_find_devfn(bus, PCI_MASK_BUS(bdf), &dev); if (ret == -ENODEV) { struct pci_device_id find_id; memset(&find_id, '\0', sizeof(find_id)); find_id.vendor = vendor; find_id.device = device; find_id.class = class; ret = pci_find_and_bind_driver(bus, &find_id, bdf, &dev); if (ret) return ret; } /* Update the platform data */ pplat = dev_get_parent_plat(dev); pplat->devfn = PCI_MASK_BUS(bdf); pplat->vendor = vendor; pplat->device = device; pplat->class = class; pplat->is_virtfn = true; pplat->pfdev = pdev; pplat->virtid = vf * vf_stride + vf_offset; debug("%s: bus %d/%s: found VF %x:%x %x:%x class %lx id %x\n", __func__, dev_seq(dev), dev->name, PCI_DEV(bdf), PCI_FUNC(bdf), vendor, device, class, pplat->virtid); bdf += PCI_BDF(0, 0, vf_stride); } return 0; } int pci_sriov_get_totalvfs(struct udevice *pdev) { u16 total_vf; int pos; pos = dm_pci_find_ext_capability(pdev, PCI_EXT_CAP_ID_SRIOV); if (!pos) { debug("Error: SRIOV capability not found\n"); return -ENOENT; } dm_pci_read_config16(pdev, pos + PCI_SRIOV_TOTAL_VF, &total_vf); return total_vf; } #endif /* SRIOV */ UCLASS_DRIVER(pci) = { .id = UCLASS_PCI, .name = "pci", .flags = DM_UC_FLAG_SEQ_ALIAS | DM_UC_FLAG_NO_AUTO_SEQ, .post_bind = dm_scan_fdt_dev, .pre_probe = pci_uclass_pre_probe, .post_probe = pci_uclass_post_probe, .child_post_bind = pci_uclass_child_post_bind, .per_device_auto = sizeof(struct pci_controller), .per_child_plat_auto = sizeof(struct pci_child_plat), }; static const struct dm_pci_ops pci_bridge_ops = { .read_config = pci_bridge_read_config, .write_config = pci_bridge_write_config, }; static const struct udevice_id pci_bridge_ids[] = { { .compatible = "pci-bridge" }, { } }; U_BOOT_DRIVER(pci_bridge_drv) = { .name = "pci_bridge_drv", .id = UCLASS_PCI, .of_match = pci_bridge_ids, .ops = &pci_bridge_ops, }; UCLASS_DRIVER(pci_generic) = { .id = UCLASS_PCI_GENERIC, .name = "pci_generic", }; static const struct udevice_id pci_generic_ids[] = { { .compatible = "pci-generic" }, { } }; U_BOOT_DRIVER(pci_generic_drv) = { .name = "pci_generic_drv", .id = UCLASS_PCI_GENERIC, .of_match = pci_generic_ids, }; int pci_init(void) { struct udevice *bus; /* * Enumerate all known controller devices. Enumeration has the side- * effect of probing them, so PCIe devices will be enumerated too. */ for (uclass_first_device_check(UCLASS_PCI, &bus); bus; uclass_next_device_check(&bus)) { ; } return 0; }