/* SPDX-License-Identifier: GPL-2.0-only */ #include #include #include #include #include #include #include #include /** Linked list of ALL devices */ DEVTREE_CONST struct device *DEVTREE_CONST all_devices = &dev_root; /** * Given a PCI bus and a devfn number, find the device structure. * * Note that this function can return the incorrect device prior * to PCI enumeration because the secondary field of the bus object * is 0. The failing scenario is determined by the order of the * devices in all_devices singly-linked list as well as the time * when this function is called (secondary reflecting topology). * * @param bus The bus number. * @param devfn A device/function number. * @return Pointer to the device structure (if found), 0 otherwise. */ static DEVTREE_CONST struct device *dev_find_slot(unsigned int bus, unsigned int devfn) { DEVTREE_CONST struct device *dev, *result; result = 0; for (dev = all_devices; dev; dev = dev->next) { if ((dev->path.type == DEVICE_PATH_PCI) && (dev->upstream->secondary == bus) && (dev->upstream->segment_group == 0) && (dev->path.pci.devfn == devfn)) { result = dev; break; } } return result; } /** * Given a Device Path Type, find the device structure. * * @param prev_match The previously matched device instance. * @param path_type The Device Path Type. * @return Pointer to the device structure (if found), 0 otherwise. */ DEVTREE_CONST struct device *dev_find_path( DEVTREE_CONST struct device *prev_match, enum device_path_type path_type) { DEVTREE_CONST struct device *dev, *result = NULL; if (prev_match == NULL) prev_match = all_devices; else prev_match = prev_match->next; for (dev = prev_match; dev; dev = dev->next) { if (dev->path.type == path_type) { result = dev; break; } } return result; } /** * Given a device pointer, find the next PCI device. * * @param previous_dev A pointer to a PCI device structure. * @return Pointer to the next device structure (if found), 0 otherwise. */ DEVTREE_CONST struct device *dev_find_next_pci_device( DEVTREE_CONST struct device *previous_dev) { return dev_find_path(previous_dev, DEVICE_PATH_PCI); } static int path_eq(const struct device_path *path1, const struct device_path *path2) { int equal = 0; if (!path1 || !path2) { assert(path1); assert(path2); /* Return 0 in case assert is considered non-fatal. */ return 0; } if (path1->type != path2->type) return 0; switch (path1->type) { case DEVICE_PATH_NONE: break; case DEVICE_PATH_ROOT: equal = 1; break; case DEVICE_PATH_PCI: equal = (path1->pci.devfn == path2->pci.devfn); break; case DEVICE_PATH_PNP: equal = (path1->pnp.port == path2->pnp.port) && (path1->pnp.device == path2->pnp.device); break; case DEVICE_PATH_I2C: equal = (path1->i2c.device == path2->i2c.device) && (path1->i2c.mode_10bit == path2->i2c.mode_10bit); break; case DEVICE_PATH_APIC: equal = (path1->apic.apic_id == path2->apic.apic_id); break; case DEVICE_PATH_DOMAIN: equal = (path1->domain.domain == path2->domain.domain); break; case DEVICE_PATH_CPU_CLUSTER: equal = (path1->cpu_cluster.cluster == path2->cpu_cluster.cluster); break; case DEVICE_PATH_CPU: equal = (path1->cpu.id == path2->cpu.id); break; case DEVICE_PATH_CPU_BUS: equal = (path1->cpu_bus.id == path2->cpu_bus.id); break; case DEVICE_PATH_GENERIC: equal = (path1->generic.id == path2->generic.id) && (path1->generic.subid == path2->generic.subid); break; case DEVICE_PATH_SPI: equal = (path1->spi.cs == path2->spi.cs); break; case DEVICE_PATH_USB: equal = (path1->usb.port_type == path2->usb.port_type) && (path1->usb.port_id == path2->usb.port_id); break; case DEVICE_PATH_MMIO: equal = (path1->mmio.addr == path2->mmio.addr); break; case DEVICE_PATH_GPIO: equal = (path1->gpio.id == path2->gpio.id); break; case DEVICE_PATH_MDIO: equal = (path1->mdio.addr == path2->mdio.addr); break; default: printk(BIOS_ERR, "Unknown device type: %d\n", path1->type); break; } return equal; } /** * See if a device structure exists for path. * * @param parent The bus to find the device on. * @param path The relative path from the bus to the appropriate device. * @return Pointer to a device structure for the device on bus at path * or 0/NULL if no device is found. */ DEVTREE_CONST struct device *find_dev_path( const struct bus *parent, const struct device_path *path) { DEVTREE_CONST struct device *child; if (!parent) { BUG(); /* Return NULL in case asserts are considered non-fatal. */ return NULL; } for (child = parent->children; child; child = child->sibling) { if (path_eq(path, &child->path)) break; } return child; } /** * Find the device structure given an array of nested device paths, * * @param parent The parent bus to start the search on. * @param nested_path An array of relative paths from the parent bus to the target device. * @param nested_path_length Number of path elements in nested_path array. * @return Pointer to a device structure for the device at nested path * or 0/NULL if no device is found. */ DEVTREE_CONST struct device *find_dev_nested_path( const struct bus *parent, const struct device_path nested_path[], size_t nested_path_length) { DEVTREE_CONST struct device *child; if (!parent || !nested_path || !nested_path_length) return NULL; child = find_dev_path(parent, nested_path); /* Terminate recursion at end of nested path or child not found */ if (nested_path_length == 1 || !child) return child; return find_dev_nested_path(child->downstream, nested_path + 1, nested_path_length - 1); } DEVTREE_CONST struct device *pcidev_path_behind( const struct bus *parent, pci_devfn_t devfn) { const struct device_path path = { .type = DEVICE_PATH_PCI, .pci.devfn = devfn, }; return find_dev_path(parent, &path); } DEVTREE_CONST struct device *pcidev_path_on_bus(unsigned int bus, pci_devfn_t devfn) { DEVTREE_CONST struct bus *parent = pci_root_bus(); DEVTREE_CONST struct device *dev = parent->children; /* FIXME: Write the loop with topology links. */ while (dev) { if (dev->path.type != DEVICE_PATH_PCI) { dev = dev->next; continue; } if (dev->upstream->secondary == bus && dev->upstream->segment_group == 0) return pcidev_path_behind(dev->upstream, devfn); dev = dev->next; } return NULL; } DEVTREE_CONST struct bus *pci_root_bus(void) { DEVTREE_CONST struct device *pci_domain; static DEVTREE_CONST struct bus *pci_root; if (pci_root) return pci_root; pci_domain = dev_find_path(NULL, DEVICE_PATH_DOMAIN); if (!pci_domain) return NULL; pci_root = pci_domain->downstream; return pci_root; } DEVTREE_CONST struct device *pcidev_path_on_root(pci_devfn_t devfn) { return pcidev_path_behind(pci_root_bus(), devfn); } DEVTREE_CONST struct device *pcidev_on_root(uint8_t dev, uint8_t fn) { return pcidev_path_on_root(PCI_DEVFN(dev, fn)); } DEVTREE_CONST struct device *pcidev_path_behind_pci2pci_bridge( const struct device *bridge, pci_devfn_t devfn) { if (!bridge || (bridge->path.type != DEVICE_PATH_PCI)) { BUG(); /* Return NULL in case asserts are non-fatal. */ return NULL; } return pcidev_path_behind(bridge->downstream, devfn); } DEVTREE_CONST struct device *pcidev_path_on_root_debug(pci_devfn_t devfn, const char *func) { DEVTREE_CONST struct device *dev = pcidev_path_on_root(devfn); if (dev) return dev; devtree_bug(func, devfn); /* FIXME: This can return wrong device. */ return dev_find_slot(0, devfn); } void devtree_bug(const char *func, pci_devfn_t devfn) { printk(BIOS_ERR, "BUG: %s requests hidden 00:%02x.%u\n", func, devfn >> 3, devfn & 7); } void __noreturn devtree_die(void) { die("DEVTREE: dev or chip_info is NULL\n"); } /** * Given an SMBus bus and a device number, find the device structure. * * @param bus The bus number. * @param addr A device number. * @return Pointer to the device structure (if found), 0 otherwise. */ DEVTREE_CONST struct device *dev_find_slot_on_smbus(unsigned int bus, unsigned int addr) { DEVTREE_CONST struct device *dev, *result; result = 0; for (dev = all_devices; dev; dev = dev->next) { if ((dev->path.type == DEVICE_PATH_I2C) && (dev->upstream->secondary == bus) && (dev->path.i2c.device == addr)) { result = dev; break; } } return result; } /** * Given a PnP port and a device number, find the device structure. * * @param port The I/O port. * @param device Logical device number. * @return Pointer to the device structure (if found), 0 otherwise. */ DEVTREE_CONST struct device *dev_find_slot_pnp(u16 port, u16 device) { DEVTREE_CONST struct device *dev; for (dev = all_devices; dev; dev = dev->next) { if ((dev->path.type == DEVICE_PATH_PNP) && (dev->path.pnp.port == port) && (dev->path.pnp.device == device)) { return dev; } } return 0; } /** * Given a device and previous match iterate through all the children. * * @param bus parent device's bus holding all the children * @param prev_child previous child already traversed, if NULL start at * children of parent bus. * @return pointer to child or NULL when no more children */ DEVTREE_CONST struct device *dev_bus_each_child(const struct bus *parent, DEVTREE_CONST struct device *prev_child) { DEVTREE_CONST struct device *dev; if (parent == NULL) return NULL; if (prev_child == NULL) dev = parent->children; else dev = prev_child->sibling; return dev; } bool is_dev_enabled(const struct device *dev) { if (!dev) return false; /* For stages with immutable device tree, first check if device is disabled because of fw_config probing. In these stages, dev->enabled does not reflect the true state of a device that uses fw_config probing. */ if (DEVTREE_EARLY && !fw_config_probe_dev(dev, NULL)) return false; return dev->enabled; } bool is_devfn_enabled(unsigned int devfn) { const struct device *dev = pcidev_path_on_root(devfn); return is_dev_enabled(dev); }