/* * node_device_udev.c: node device enumeration - libudev implementation * * Copyright (C) 2009-2015 Red Hat, Inc. * * This library is free software; you can redistribute it and/or * modify it under the terms of the GNU Lesser General Public * License as published by the Free Software Foundation; either * version 2.1 of the License, or (at your option) any later version. * * This library is distributed in the hope that it will be useful, * but WITHOUT ANY WARRANTY; without even the implied warranty of * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU * Lesser General Public License for more details. * * You should have received a copy of the GNU Lesser General Public * License along with this library. If not, see * . */ #include #include #include #include #include "node_device_conf.h" #include "node_device_event.h" #include "node_device_driver.h" #include "node_device_udev.h" #include "virerror.h" #include "driver.h" #include "datatypes.h" #include "virlog.h" #include "viralloc.h" #include "viruuid.h" #include "virbuffer.h" #include "virfile.h" #include "virpci.h" #include "virpidfile.h" #include "virstring.h" #include "virnetdev.h" #include "virmdev.h" #include "virutil.h" #include "configmake.h" #define VIR_FROM_THIS VIR_FROM_NODEDEV VIR_LOG_INIT("node_device.node_device_udev"); #ifndef TYPE_RAID # define TYPE_RAID 12 #endif typedef struct _udevEventData udevEventData; typedef udevEventData *udevEventDataPtr; struct _udevEventData { virObjectLockable parent; struct udev_monitor *udev_monitor; int watch; /* Thread data */ virThread th; virCond threadCond; bool threadQuit; bool dataReady; }; static virClassPtr udevEventDataClass; static void udevEventDataDispose(void *obj) { struct udev *udev = NULL; udevEventDataPtr priv = obj; if (priv->watch != -1) virEventRemoveHandle(priv->watch); if (!priv->udev_monitor) return; udev = udev_monitor_get_udev(priv->udev_monitor); udev_monitor_unref(priv->udev_monitor); udev_unref(udev); virCondDestroy(&priv->threadCond); } static int udevEventDataOnceInit(void) { if (!VIR_CLASS_NEW(udevEventData, virClassForObjectLockable())) return -1; return 0; } VIR_ONCE_GLOBAL_INIT(udevEventData); static udevEventDataPtr udevEventDataNew(void) { udevEventDataPtr ret = NULL; if (udevEventDataInitialize() < 0) return NULL; if (!(ret = virObjectLockableNew(udevEventDataClass))) return NULL; if (virCondInit(&ret->threadCond) < 0) { virObjectUnref(ret); return NULL; } ret->watch = -1; return ret; } static bool udevHasDeviceProperty(struct udev_device *dev, const char *key) { if (udev_device_get_property_value(dev, key)) return true; return false; } static const char * udevGetDeviceProperty(struct udev_device *udev_device, const char *property_key) { const char *ret = NULL; ret = udev_device_get_property_value(udev_device, property_key); VIR_DEBUG("Found property key '%s' value '%s' for device with sysname '%s'", property_key, NULLSTR(ret), udev_device_get_sysname(udev_device)); return ret; } static int udevGetStringProperty(struct udev_device *udev_device, const char *property_key, char **value) { *value = g_strdup(udevGetDeviceProperty(udev_device, property_key)); return 0; } static int udevGetIntProperty(struct udev_device *udev_device, const char *property_key, int *value, int base) { const char *str = NULL; str = udevGetDeviceProperty(udev_device, property_key); if (str && virStrToLong_i(str, NULL, base, value) < 0) { virReportError(VIR_ERR_INTERNAL_ERROR, _("Failed to convert '%s' to int"), str); return -1; } return 0; } static int udevGetUintProperty(struct udev_device *udev_device, const char *property_key, unsigned int *value, int base) { const char *str = NULL; str = udevGetDeviceProperty(udev_device, property_key); if (str && virStrToLong_ui(str, NULL, base, value) < 0) { virReportError(VIR_ERR_INTERNAL_ERROR, _("Failed to convert '%s' to int"), str); return -1; } return 0; } static const char * udevGetDeviceSysfsAttr(struct udev_device *udev_device, const char *attr_name) { const char *ret = NULL; ret = udev_device_get_sysattr_value(udev_device, attr_name); VIR_DEBUG("Found sysfs attribute '%s' value '%s' " "for device with sysname '%s'", attr_name, NULLSTR(ret), udev_device_get_sysname(udev_device)); return ret; } static int udevGetStringSysfsAttr(struct udev_device *udev_device, const char *attr_name, char **value) { *value = g_strdup(udevGetDeviceSysfsAttr(udev_device, attr_name)); virStringStripControlChars(*value); if (*value != NULL && (STREQ(*value, ""))) VIR_FREE(*value); return 0; } static int udevGetIntSysfsAttr(struct udev_device *udev_device, const char *attr_name, int *value, int base) { const char *str = NULL; str = udevGetDeviceSysfsAttr(udev_device, attr_name); if (str && virStrToLong_i(str, NULL, base, value) < 0) { virReportError(VIR_ERR_INTERNAL_ERROR, _("Failed to convert '%s' to int"), str); return -1; } return 0; } static int udevGetUintSysfsAttr(struct udev_device *udev_device, const char *attr_name, unsigned int *value, int base) { const char *str = NULL; str = udevGetDeviceSysfsAttr(udev_device, attr_name); if (str && virStrToLong_ui(str, NULL, base, value) < 0) { virReportError(VIR_ERR_INTERNAL_ERROR, _("Failed to convert '%s' to unsigned int"), str); return -1; } return 0; } static int udevGetUint64SysfsAttr(struct udev_device *udev_device, const char *attr_name, unsigned long long *value) { const char *str = NULL; str = udevGetDeviceSysfsAttr(udev_device, attr_name); if (str && virStrToLong_ull(str, NULL, 0, value) < 0) { virReportError(VIR_ERR_INTERNAL_ERROR, _("Failed to convert '%s' to unsigned long long"), str); return -1; } return 0; } static int udevGenerateDeviceName(struct udev_device *device, virNodeDeviceDefPtr def, const char *s) { size_t i; virBuffer buf = VIR_BUFFER_INITIALIZER; virBufferAsprintf(&buf, "%s_%s", udev_device_get_subsystem(device), udev_device_get_sysname(device)); if (s != NULL) virBufferAsprintf(&buf, "_%s", s); def->name = virBufferContentAndReset(&buf); for (i = 0; i < strlen(def->name); i++) { if (!(g_ascii_isalnum(*(def->name + i)))) *(def->name + i) = '_'; } return 0; } static int udevTranslatePCIIds(unsigned int vendor, unsigned int product, char **vendor_string, char **product_string) { struct pci_id_match m; const char *vendor_name = NULL, *device_name = NULL; m.vendor_id = vendor; m.device_id = product; m.subvendor_id = PCI_MATCH_ANY; m.subdevice_id = PCI_MATCH_ANY; m.device_class = 0; m.device_class_mask = 0; m.match_data = 0; /* pci_get_strings returns void */ pci_get_strings(&m, &device_name, &vendor_name, NULL, NULL); *vendor_string = g_strdup(vendor_name); *product_string = g_strdup(device_name); return 0; } static int udevProcessPCI(struct udev_device *device, virNodeDeviceDefPtr def) { virNodeDevCapPCIDevPtr pci_dev = &def->caps->data.pci_dev; virPCIEDeviceInfoPtr pci_express = NULL; virPCIDevicePtr pciDev = NULL; int ret = -1; char *p; bool privileged; nodeDeviceLock(); privileged = driver->privileged; nodeDeviceUnlock(); pci_dev->klass = -1; if (udevGetIntProperty(device, "PCI_CLASS", &pci_dev->klass, 16) < 0) goto cleanup; if ((p = strrchr(def->sysfs_path, '/')) == NULL || virStrToLong_ui(p + 1, &p, 16, &pci_dev->domain) < 0 || p == NULL || virStrToLong_ui(p + 1, &p, 16, &pci_dev->bus) < 0 || p == NULL || virStrToLong_ui(p + 1, &p, 16, &pci_dev->slot) < 0 || p == NULL || virStrToLong_ui(p + 1, &p, 16, &pci_dev->function) < 0) { virReportError(VIR_ERR_INTERNAL_ERROR, _("failed to parse the PCI address from sysfs path: '%s'"), def->sysfs_path); goto cleanup; } if (udevGetUintSysfsAttr(device, "vendor", &pci_dev->vendor, 16) < 0) goto cleanup; if (udevGetUintSysfsAttr(device, "device", &pci_dev->product, 16) < 0) goto cleanup; if (udevTranslatePCIIds(pci_dev->vendor, pci_dev->product, &pci_dev->vendor_name, &pci_dev->product_name) != 0) { goto cleanup; } if (udevGenerateDeviceName(device, def, NULL) != 0) goto cleanup; /* The default value is -1, because it can't be 0 * as zero is valid node number. */ pci_dev->numa_node = -1; if (udevGetIntSysfsAttr(device, "numa_node", &pci_dev->numa_node, 10) < 0) goto cleanup; if (virNodeDeviceGetPCIDynamicCaps(def->sysfs_path, pci_dev) < 0) goto cleanup; if (!(pciDev = virPCIDeviceNew(pci_dev->domain, pci_dev->bus, pci_dev->slot, pci_dev->function))) goto cleanup; /* We need to be root to read PCI device configs */ if (privileged) { if (virPCIGetHeaderType(pciDev, &pci_dev->hdrType) < 0) goto cleanup; if (virPCIDeviceIsPCIExpress(pciDev) > 0) { if (VIR_ALLOC(pci_express) < 0) goto cleanup; if (virPCIDeviceHasPCIExpressLink(pciDev) > 0) { if (VIR_ALLOC(pci_express->link_cap) < 0 || VIR_ALLOC(pci_express->link_sta) < 0) goto cleanup; if (virPCIDeviceGetLinkCapSta(pciDev, &pci_express->link_cap->port, &pci_express->link_cap->speed, &pci_express->link_cap->width, &pci_express->link_sta->speed, &pci_express->link_sta->width) < 0) goto cleanup; pci_express->link_sta->port = -1; /* PCIe can't negotiate port. Yet :) */ } pci_dev->flags |= VIR_NODE_DEV_CAP_FLAG_PCIE; pci_dev->pci_express = pci_express; pci_express = NULL; } } ret = 0; cleanup: virPCIDeviceFree(pciDev); virPCIEDeviceInfoFree(pci_express); return ret; } static int drmGetMinorType(int minor) { int type = minor >> 6; if (minor < 0) return -1; switch (type) { case VIR_NODE_DEV_DRM_PRIMARY: case VIR_NODE_DEV_DRM_CONTROL: case VIR_NODE_DEV_DRM_RENDER: return type; default: return -1; } } static int udevProcessDRMDevice(struct udev_device *device, virNodeDeviceDefPtr def) { virNodeDevCapDRMPtr drm = &def->caps->data.drm; int minor; if (udevGenerateDeviceName(device, def, NULL) != 0) return -1; if (udevGetIntProperty(device, "MINOR", &minor, 10) < 0) return -1; if ((minor = drmGetMinorType(minor)) == -1) return -1; drm->type = minor; return 0; } static int udevProcessUSBDevice(struct udev_device *device, virNodeDeviceDefPtr def) { virNodeDevCapUSBDevPtr usb_dev = &def->caps->data.usb_dev; if (udevGetUintProperty(device, "BUSNUM", &usb_dev->bus, 10) < 0) return -1; if (udevGetUintProperty(device, "DEVNUM", &usb_dev->device, 10) < 0) return -1; if (udevGetUintProperty(device, "ID_VENDOR_ID", &usb_dev->vendor, 16) < 0) return -1; if (udevGetStringProperty(device, "ID_VENDOR_FROM_DATABASE", &usb_dev->vendor_name) < 0) return -1; if (!usb_dev->vendor_name && udevGetStringSysfsAttr(device, "manufacturer", &usb_dev->vendor_name) < 0) return -1; if (udevGetUintProperty(device, "ID_MODEL_ID", &usb_dev->product, 16) < 0) return -1; if (udevGetStringProperty(device, "ID_MODEL_FROM_DATABASE", &usb_dev->product_name) < 0) return -1; if (!usb_dev->product_name && udevGetStringSysfsAttr(device, "product", &usb_dev->product_name) < 0) return -1; if (udevGenerateDeviceName(device, def, NULL) != 0) return -1; return 0; } static int udevProcessUSBInterface(struct udev_device *device, virNodeDeviceDefPtr def) { virNodeDevCapUSBIfPtr usb_if = &def->caps->data.usb_if; if (udevGetUintSysfsAttr(device, "bInterfaceNumber", &usb_if->number, 16) < 0) return -1; if (udevGetUintSysfsAttr(device, "bInterfaceClass", &usb_if->klass, 16) < 0) return -1; if (udevGetUintSysfsAttr(device, "bInterfaceSubClass", &usb_if->subclass, 16) < 0) return -1; if (udevGetUintSysfsAttr(device, "bInterfaceProtocol", &usb_if->protocol, 16) < 0) return -1; if (udevGenerateDeviceName(device, def, NULL) != 0) return -1; return 0; } static int udevProcessNetworkInterface(struct udev_device *device, virNodeDeviceDefPtr def) { const char *devtype = udev_device_get_devtype(device); virNodeDevCapNetPtr net = &def->caps->data.net; if (devtype && STREQ(devtype, "wlan")) { net->subtype = VIR_NODE_DEV_CAP_NET_80211; } else { net->subtype = VIR_NODE_DEV_CAP_NET_80203; } if (udevGetStringProperty(device, "INTERFACE", &net->ifname) < 0) return -1; if (udevGetStringSysfsAttr(device, "address", &net->address) < 0) return -1; if (udevGetUintSysfsAttr(device, "addr_len", &net->address_len, 0) < 0) return -1; if (udevGenerateDeviceName(device, def, net->address) != 0) return -1; if (virNetDevGetLinkInfo(net->ifname, &net->lnk) < 0) return -1; if (virNetDevGetFeatures(net->ifname, &net->features) < 0) return -1; return 0; } static int udevProcessSCSIHost(struct udev_device *device G_GNUC_UNUSED, virNodeDeviceDefPtr def) { virNodeDevCapSCSIHostPtr scsi_host = &def->caps->data.scsi_host; g_autofree char *filename = NULL; char *str; filename = g_path_get_basename(def->sysfs_path); if (!(str = STRSKIP(filename, "host")) || virStrToLong_ui(str, NULL, 0, &scsi_host->host) < 0) { virReportError(VIR_ERR_INTERNAL_ERROR, _("failed to parse SCSI host '%s'"), filename); return -1; } virNodeDeviceGetSCSIHostCaps(&def->caps->data.scsi_host); if (udevGenerateDeviceName(device, def, NULL) != 0) return -1; return 0; } static int udevProcessSCSITarget(struct udev_device *device, virNodeDeviceDefPtr def) { const char *sysname = NULL; virNodeDevCapSCSITargetPtr scsi_target = &def->caps->data.scsi_target; sysname = udev_device_get_sysname(device); scsi_target->name = g_strdup(sysname); virNodeDeviceGetSCSITargetCaps(def->sysfs_path, &def->caps->data.scsi_target); if (udevGenerateDeviceName(device, def, NULL) != 0) return -1; return 0; } static int udevGetSCSIType(virNodeDeviceDefPtr def G_GNUC_UNUSED, unsigned int type, char **typestring) { int ret = 0; int foundtype = 1; *typestring = NULL; switch (type) { case TYPE_DISK: *typestring = g_strdup("disk"); break; case TYPE_TAPE: *typestring = g_strdup("tape"); break; case TYPE_PROCESSOR: *typestring = g_strdup("processor"); break; case TYPE_WORM: *typestring = g_strdup("worm"); break; case TYPE_ROM: *typestring = g_strdup("cdrom"); break; case TYPE_SCANNER: *typestring = g_strdup("scanner"); break; case TYPE_MOD: *typestring = g_strdup("mod"); break; case TYPE_MEDIUM_CHANGER: *typestring = g_strdup("changer"); break; case TYPE_ENCLOSURE: *typestring = g_strdup("enclosure"); break; case TYPE_RAID: *typestring = g_strdup("raid"); break; case TYPE_NO_LUN: default: foundtype = 0; break; } if (*typestring == NULL) { if (foundtype == 1) { ret = -1; } else { VIR_DEBUG("Failed to find SCSI device type %d for %s", type, def->sysfs_path); } } return ret; } static int udevProcessSCSIDevice(struct udev_device *device G_GNUC_UNUSED, virNodeDeviceDefPtr def) { int ret = -1; unsigned int tmp = 0; virNodeDevCapSCSIPtr scsi = &def->caps->data.scsi; g_autofree char *filename = NULL; char *p = NULL; filename = g_path_get_basename(def->sysfs_path); if (virStrToLong_ui(filename, &p, 10, &scsi->host) < 0 || p == NULL || virStrToLong_ui(p + 1, &p, 10, &scsi->bus) < 0 || p == NULL || virStrToLong_ui(p + 1, &p, 10, &scsi->target) < 0 || p == NULL || virStrToLong_ui(p + 1, &p, 10, &scsi->lun) < 0) { virReportError(VIR_ERR_INTERNAL_ERROR, _("failed to parse the SCSI address from filename: '%s'"), filename); return -1; } if (udev_device_get_sysattr_value(device, "type")) { if (udevGetUintSysfsAttr(device, "type", &tmp, 0) < 0) goto cleanup; if (udevGetSCSIType(def, tmp, &scsi->type) < 0) goto cleanup; } if (udevGenerateDeviceName(device, def, NULL) != 0) goto cleanup; ret = 0; cleanup: if (ret != 0) { virReportError(VIR_ERR_INTERNAL_ERROR, _("Failed to process SCSI device with sysfs path '%s'"), def->sysfs_path); } return ret; } static int udevProcessDisk(struct udev_device *device, virNodeDeviceDefPtr def) { virNodeDevCapStoragePtr storage = &def->caps->data.storage; if (udevGetUint64SysfsAttr(device, "size", &storage->num_blocks) < 0) return -1; if (udevGetUint64SysfsAttr(device, "queue/logical_block_size", &storage->logical_block_size) < 0) return -1; storage->size = storage->num_blocks * storage->logical_block_size; return 0; } static int udevProcessRemoveableMedia(struct udev_device *device, virNodeDeviceDefPtr def, int has_media) { virNodeDevCapStoragePtr storage = &def->caps->data.storage; int is_removable = 0; if (udevGetIntSysfsAttr(device, "removable", &is_removable, 0) < 0) return -1; if (is_removable == 1) def->caps->data.storage.flags |= VIR_NODE_DEV_CAP_STORAGE_REMOVABLE; if (!has_media) return 0; def->caps->data.storage.flags |= VIR_NODE_DEV_CAP_STORAGE_REMOVABLE_MEDIA_AVAILABLE; if (udevGetStringProperty(device, "ID_FS_LABEL", &storage->media_label) < 0) return -1; if (udevGetUint64SysfsAttr(device, "size", &storage->num_blocks) < 0) return -1; if (udevGetUint64SysfsAttr(device, "queue/logical_block_size", &storage->logical_block_size) < 0) return -1; /* XXX This calculation is wrong for the qemu virtual cdrom * which reports the size in 512 byte blocks, but the logical * block size as 2048. I don't have a physical cdrom on a * devel system to see how they behave. */ def->caps->data.storage.removable_media_size = def->caps->data.storage.num_blocks * def->caps->data.storage.logical_block_size; return 0; } static int udevProcessCDROM(struct udev_device *device, virNodeDeviceDefPtr def) { int has_media = 0; /* NB: the drive_type string provided by udev is different from * that provided by HAL; now it's "cd" instead of "cdrom" We * change it to cdrom to preserve compatibility with earlier * versions of libvirt. */ VIR_FREE(def->caps->data.storage.drive_type); def->caps->data.storage.drive_type = g_strdup("cdrom"); if (udevHasDeviceProperty(device, "ID_CDROM_MEDIA") && udevGetIntProperty(device, "ID_CDROM_MEDIA", &has_media, 0) < 0) return -1; return udevProcessRemoveableMedia(device, def, has_media); } static int udevProcessFloppy(struct udev_device *device, virNodeDeviceDefPtr def) { int has_media = 0; if (udevHasDeviceProperty(device, "ID_CDROM_MEDIA")) { /* USB floppy */ if (udevGetIntProperty(device, "DKD_MEDIA_AVAILABLE", &has_media, 0) < 0) return -1; } else if (udevHasDeviceProperty(device, "ID_FS_LABEL")) { /* Legacy floppy */ has_media = 1; } return udevProcessRemoveableMedia(device, def, has_media); } static int udevProcessSD(struct udev_device *device, virNodeDeviceDefPtr def) { virNodeDevCapStoragePtr storage = &def->caps->data.storage; if (udevGetUint64SysfsAttr(device, "size", &storage->num_blocks) < 0) return -1; if (udevGetUint64SysfsAttr(device, "queue/logical_block_size", &storage->logical_block_size) < 0) return -1; storage->size = storage->num_blocks * storage->logical_block_size; return 0; } /* This function exists to deal with the case in which a driver does * not provide a device type in the usual place, but udev told us it's * a storage device, and we can make a good guess at what kind of * storage device it is from other information that is provided. */ static int udevKludgeStorageType(virNodeDeviceDefPtr def) { VIR_DEBUG("Could not find definitive storage type for device " "with sysfs path '%s', trying to guess it", def->sysfs_path); /* virtio disk */ if (STRPREFIX(def->caps->data.storage.block, "/dev/vd")) { def->caps->data.storage.drive_type = g_strdup("disk"); VIR_DEBUG("Found storage type '%s' for device " "with sysfs path '%s'", def->caps->data.storage.drive_type, def->sysfs_path); return 0; } VIR_DEBUG("Could not determine storage type " "for device with sysfs path '%s'", def->sysfs_path); return -1; } static int udevProcessStorage(struct udev_device *device, virNodeDeviceDefPtr def) { virNodeDevCapStoragePtr storage = &def->caps->data.storage; int ret = -1; const char* devnode; devnode = udev_device_get_devnode(device); if (!devnode) { VIR_DEBUG("No devnode for '%s'", udev_device_get_devpath(device)); goto cleanup; } storage->block = g_strdup(devnode); if (udevGetStringProperty(device, "ID_BUS", &storage->bus) < 0) goto cleanup; if (udevGetStringProperty(device, "ID_SERIAL", &storage->serial) < 0) goto cleanup; if (udevGetStringSysfsAttr(device, "device/vendor", &storage->vendor) < 0) goto cleanup; if (def->caps->data.storage.vendor) virTrimSpaces(def->caps->data.storage.vendor, NULL); if (udevGetStringSysfsAttr(device, "device/model", &storage->model) < 0) goto cleanup; if (def->caps->data.storage.model) virTrimSpaces(def->caps->data.storage.model, NULL); /* There is no equivalent of the hotpluggable property in libudev, * but storage is going toward a world in which hotpluggable is * expected, so I don't see a problem with not having a property * for it. */ if (udevGetStringProperty(device, "ID_TYPE", &storage->drive_type) < 0) goto cleanup; if (!storage->drive_type || STREQ(def->caps->data.storage.drive_type, "generic")) { int val = 0; const char *str = NULL; /* All floppy drives have the ID_DRIVE_FLOPPY prop. This is * needed since legacy floppies don't have a drive_type */ if (udevGetIntProperty(device, "ID_DRIVE_FLOPPY", &val, 0) < 0) goto cleanup; else if (val == 1) str = "floppy"; if (!str) { if (udevGetIntProperty(device, "ID_CDROM", &val, 0) < 0) goto cleanup; else if (val == 1) str = "cd"; } if (!str) { if (udevGetIntProperty(device, "ID_DRIVE_FLASH_SD", &val, 0) < 0) goto cleanup; if (val == 1) str = "sd"; } if (str) { storage->drive_type = g_strdup(str); } else { /* If udev doesn't have it, perhaps we can guess it. */ if (udevKludgeStorageType(def) != 0) goto cleanup; } } if (STREQ(def->caps->data.storage.drive_type, "cd")) { ret = udevProcessCDROM(device, def); } else if (STREQ(def->caps->data.storage.drive_type, "disk")) { ret = udevProcessDisk(device, def); } else if (STREQ(def->caps->data.storage.drive_type, "floppy")) { ret = udevProcessFloppy(device, def); } else if (STREQ(def->caps->data.storage.drive_type, "sd")) { ret = udevProcessSD(device, def); } else { VIR_DEBUG("Unsupported storage type '%s'", def->caps->data.storage.drive_type); goto cleanup; } if (udevGenerateDeviceName(device, def, storage->serial) != 0) goto cleanup; cleanup: VIR_DEBUG("Storage ret=%d", ret); return ret; } static int udevProcessSCSIGeneric(struct udev_device *dev, virNodeDeviceDefPtr def) { if (udevGetStringProperty(dev, "DEVNAME", &def->caps->data.sg.path) < 0 || !def->caps->data.sg.path) return -1; if (udevGenerateDeviceName(dev, def, NULL) != 0) return -1; return 0; } static int udevProcessMediatedDevice(struct udev_device *dev, virNodeDeviceDefPtr def) { int ret = -1; int iommugrp = -1; char *linkpath = NULL; char *canonicalpath = NULL; virNodeDevCapMdevPtr data = &def->caps->data.mdev; /* Because of a kernel uevent race, we might get the 'add' event prior to * the sysfs tree being ready, so any attempt to access any sysfs attribute * would result in ENOENT and us dropping the device, so let's work around * it by waiting for the attributes to become available. */ linkpath = g_strdup_printf("%s/mdev_type", udev_device_get_syspath(dev)); if (virFileWaitForExists(linkpath, 1, 100) < 0) { virReportSystemError(errno, _("failed to wait for file '%s' to appear"), linkpath); goto cleanup; } if (virFileResolveLink(linkpath, &canonicalpath) < 0) { virReportSystemError(errno, _("failed to resolve '%s'"), linkpath); goto cleanup; } data->type = g_path_get_basename(canonicalpath); data->uuid = g_strdup(udev_device_get_sysname(dev)); if ((iommugrp = virMediatedDeviceGetIOMMUGroupNum(data->uuid)) < 0) goto cleanup; if (udevGenerateDeviceName(dev, def, NULL) != 0) goto cleanup; data->iommuGroupNumber = iommugrp; ret = 0; cleanup: VIR_FREE(linkpath); VIR_FREE(canonicalpath); return ret; } static int udevProcessCCW(struct udev_device *device, virNodeDeviceDefPtr def) { int online; char *p; virNodeDevCapDataPtr data = &def->caps->data; /* process only online devices to keep the list sane */ if (udevGetIntSysfsAttr(device, "online", &online, 0) < 0 || online != 1) return -1; if ((p = strrchr(def->sysfs_path, '/')) == NULL || virStrToLong_ui(p + 1, &p, 16, &data->ccw_dev.cssid) < 0 || p == NULL || virStrToLong_ui(p + 1, &p, 16, &data->ccw_dev.ssid) < 0 || p == NULL || virStrToLong_ui(p + 1, &p, 16, &data->ccw_dev.devno) < 0) { virReportError(VIR_ERR_INTERNAL_ERROR, _("failed to parse the CCW address from sysfs path: '%s'"), def->sysfs_path); return -1; } if (udevGenerateDeviceName(device, def, NULL) != 0) return -1; return 0; } static int udevGetDeviceNodes(struct udev_device *device, virNodeDeviceDefPtr def) { const char *devnode = NULL; struct udev_list_entry *list_entry = NULL; int n = 0; devnode = udev_device_get_devnode(device); def->devnode = g_strdup(devnode); udev_list_entry_foreach(list_entry, udev_device_get_devlinks_list_entry(device)) n++; if (VIR_ALLOC_N(def->devlinks, n + 1) < 0) return -1; n = 0; udev_list_entry_foreach(list_entry, udev_device_get_devlinks_list_entry(device)) { def->devlinks[n++] = g_strdup(udev_list_entry_get_name(list_entry)); } return 0; } static int udevGetDeviceType(struct udev_device *device, virNodeDevCapType *type) { const char *devtype = NULL; char *subsystem = NULL; int ret = -1; devtype = udev_device_get_devtype(device); *type = 0; if (devtype) { if (STREQ(devtype, "usb_device")) *type = VIR_NODE_DEV_CAP_USB_DEV; else if (STREQ(devtype, "usb_interface")) *type = VIR_NODE_DEV_CAP_USB_INTERFACE; else if (STREQ(devtype, "scsi_host")) *type = VIR_NODE_DEV_CAP_SCSI_HOST; else if (STREQ(devtype, "scsi_target")) *type = VIR_NODE_DEV_CAP_SCSI_TARGET; else if (STREQ(devtype, "scsi_device")) *type = VIR_NODE_DEV_CAP_SCSI; else if (STREQ(devtype, "disk")) *type = VIR_NODE_DEV_CAP_STORAGE; else if (STREQ(devtype, "wlan")) *type = VIR_NODE_DEV_CAP_NET; else if (STREQ(devtype, "drm_minor")) *type = VIR_NODE_DEV_CAP_DRM; } else { /* PCI devices don't set the DEVTYPE property. */ if (udevHasDeviceProperty(device, "PCI_CLASS")) *type = VIR_NODE_DEV_CAP_PCI_DEV; /* Wired network interfaces don't set the DEVTYPE property, * USB devices also have an INTERFACE property, but they do * set DEVTYPE, so if devtype is NULL and the INTERFACE * property exists, we have a network device. */ if (udevHasDeviceProperty(device, "INTERFACE")) *type = VIR_NODE_DEV_CAP_NET; /* The following devices do not set the DEVTYPE property, therefore * we need to rely on the SUBSYSTEM property */ if (udevGetStringProperty(device, "SUBSYSTEM", &subsystem) < 0) return -1; if (STREQ_NULLABLE(subsystem, "scsi_generic")) *type = VIR_NODE_DEV_CAP_SCSI_GENERIC; else if (STREQ_NULLABLE(subsystem, "mdev")) *type = VIR_NODE_DEV_CAP_MDEV; else if (STREQ_NULLABLE(subsystem, "ccw")) *type = VIR_NODE_DEV_CAP_CCW_DEV; VIR_FREE(subsystem); } if (!*type) VIR_DEBUG("Could not determine device type for device " "with sysfs name '%s'", udev_device_get_sysname(device)); else ret = 0; return ret; } static int udevGetDeviceDetails(struct udev_device *device, virNodeDeviceDefPtr def) { switch (def->caps->data.type) { case VIR_NODE_DEV_CAP_PCI_DEV: return udevProcessPCI(device, def); case VIR_NODE_DEV_CAP_USB_DEV: return udevProcessUSBDevice(device, def); case VIR_NODE_DEV_CAP_USB_INTERFACE: return udevProcessUSBInterface(device, def); case VIR_NODE_DEV_CAP_NET: return udevProcessNetworkInterface(device, def); case VIR_NODE_DEV_CAP_SCSI_HOST: return udevProcessSCSIHost(device, def); case VIR_NODE_DEV_CAP_SCSI_TARGET: return udevProcessSCSITarget(device, def); case VIR_NODE_DEV_CAP_SCSI: return udevProcessSCSIDevice(device, def); case VIR_NODE_DEV_CAP_STORAGE: return udevProcessStorage(device, def); case VIR_NODE_DEV_CAP_SCSI_GENERIC: return udevProcessSCSIGeneric(device, def); case VIR_NODE_DEV_CAP_DRM: return udevProcessDRMDevice(device, def); case VIR_NODE_DEV_CAP_MDEV: return udevProcessMediatedDevice(device, def); case VIR_NODE_DEV_CAP_CCW_DEV: return udevProcessCCW(device, def); case VIR_NODE_DEV_CAP_MDEV_TYPES: case VIR_NODE_DEV_CAP_SYSTEM: case VIR_NODE_DEV_CAP_FC_HOST: case VIR_NODE_DEV_CAP_VPORTS: case VIR_NODE_DEV_CAP_LAST: break; } return 0; } static int udevRemoveOneDeviceSysPath(const char *path) { virNodeDeviceObjPtr obj = NULL; virNodeDeviceDefPtr def; virObjectEventPtr event = NULL; if (!(obj = virNodeDeviceObjListFindBySysfsPath(driver->devs, path))) { VIR_DEBUG("Failed to find device to remove that has udev path '%s'", path); return -1; } def = virNodeDeviceObjGetDef(obj); event = virNodeDeviceEventLifecycleNew(def->name, VIR_NODE_DEVICE_EVENT_DELETED, 0); VIR_DEBUG("Removing device '%s' with sysfs path '%s'", def->name, path); virNodeDeviceObjListRemove(driver->devs, obj); virNodeDeviceObjEndAPI(&obj); virObjectEventStateQueue(driver->nodeDeviceEventState, event); return 0; } static int udevRemoveOneDevice(struct udev_device *device) { const char *path = udev_device_get_syspath(device); return udevRemoveOneDeviceSysPath(path); } static int udevSetParent(struct udev_device *device, virNodeDeviceDefPtr def) { struct udev_device *parent_device = NULL; const char *parent_sysfs_path = NULL; virNodeDeviceObjPtr obj = NULL; virNodeDeviceDefPtr objdef; parent_device = device; do { parent_device = udev_device_get_parent(parent_device); if (parent_device == NULL) break; parent_sysfs_path = udev_device_get_syspath(parent_device); if (parent_sysfs_path == NULL) { virReportError(VIR_ERR_INTERNAL_ERROR, _("Could not get syspath for parent of '%s'"), udev_device_get_syspath(parent_device)); return -1; } if ((obj = virNodeDeviceObjListFindBySysfsPath(driver->devs, parent_sysfs_path))) { objdef = virNodeDeviceObjGetDef(obj); def->parent = g_strdup(objdef->name); virNodeDeviceObjEndAPI(&obj); def->parent_sysfs_path = g_strdup(parent_sysfs_path); } } while (def->parent == NULL && parent_device != NULL); if (!def->parent) def->parent = g_strdup("computer"); return 0; } static int udevAddOneDevice(struct udev_device *device) { virNodeDeviceDefPtr def = NULL; virNodeDeviceObjPtr obj = NULL; virNodeDeviceDefPtr objdef; virObjectEventPtr event = NULL; bool new_device = true; int ret = -1; if (VIR_ALLOC(def) != 0) goto cleanup; def->sysfs_path = g_strdup(udev_device_get_syspath(device)); if (udevGetStringProperty(device, "DRIVER", &def->driver) < 0) goto cleanup; if (VIR_ALLOC(def->caps) != 0) goto cleanup; if (udevGetDeviceType(device, &def->caps->data.type) != 0) goto cleanup; if (udevGetDeviceNodes(device, def) != 0) goto cleanup; if (udevGetDeviceDetails(device, def) != 0) goto cleanup; if (udevSetParent(device, def) != 0) goto cleanup; if ((obj = virNodeDeviceObjListFindByName(driver->devs, def->name))) { virNodeDeviceObjEndAPI(&obj); new_device = false; } /* If this is a device change, the old definition will be freed * and the current definition will take its place. */ if (!(obj = virNodeDeviceObjListAssignDef(driver->devs, def))) goto cleanup; objdef = virNodeDeviceObjGetDef(obj); if (new_device) event = virNodeDeviceEventLifecycleNew(objdef->name, VIR_NODE_DEVICE_EVENT_CREATED, 0); else event = virNodeDeviceEventUpdateNew(objdef->name); virNodeDeviceObjEndAPI(&obj); ret = 0; cleanup: virObjectEventStateQueue(driver->nodeDeviceEventState, event); if (ret != 0) { VIR_DEBUG("Discarding device %d %p %s", ret, def, def ? NULLSTR(def->sysfs_path) : ""); virNodeDeviceDefFree(def); } return ret; } static int udevProcessDeviceListEntry(struct udev *udev, struct udev_list_entry *list_entry) { struct udev_device *device; const char *name = NULL; int ret = -1; name = udev_list_entry_get_name(list_entry); device = udev_device_new_from_syspath(udev, name); if (device != NULL) { if (udevAddOneDevice(device) != 0) { VIR_DEBUG("Failed to create node device for udev device '%s'", name); } ret = 0; } udev_device_unref(device); return ret; } /* We do not care about every device (see udevGetDeviceType). * Do not bother enumerating over subsystems that do not * contain interesting devices. */ const char *subsystem_ignored[] = { "acpi", "tty", "vc", "i2c", }; static int udevEnumerateAddMatches(struct udev_enumerate *udev_enumerate) { size_t i; for (i = 0; i < G_N_ELEMENTS(subsystem_ignored); i++) { const char *s = subsystem_ignored[i]; if (udev_enumerate_add_nomatch_subsystem(udev_enumerate, s) < 0) { virReportSystemError(errno, "%s", _("failed to add susbsystem filter")); return -1; } } return 0; } static int udevEnumerateDevices(struct udev *udev) { struct udev_enumerate *udev_enumerate = NULL; struct udev_list_entry *list_entry = NULL; int ret = -1; udev_enumerate = udev_enumerate_new(udev); if (udevEnumerateAddMatches(udev_enumerate) < 0) goto cleanup; if (udev_enumerate_scan_devices(udev_enumerate) < 0) VIR_WARN("udev scan devices failed"); udev_list_entry_foreach(list_entry, udev_enumerate_get_list_entry(udev_enumerate)) { udevProcessDeviceListEntry(udev, list_entry); } ret = 0; cleanup: udev_enumerate_unref(udev_enumerate); return ret; } static void udevPCITranslateDeinit(void) { #if defined __s390__ || defined __s390x_ /* Nothing was initialized, nothing needs to be cleaned up */ #else /* pci_system_cleanup returns void */ pci_system_cleanup(); #endif return; } static int nodeStateCleanup(void) { udevEventDataPtr priv = NULL; if (!driver) return -1; priv = driver->privateData; if (priv) { virObjectLock(priv); priv->threadQuit = true; virCondSignal(&priv->threadCond); virObjectUnlock(priv); virThreadJoin(&priv->th); } virObjectUnref(priv); virObjectUnref(driver->nodeDeviceEventState); virNodeDeviceObjListFree(driver->devs); if (driver->lockFD != -1) virPidFileRelease(driver->stateDir, "driver", driver->lockFD); VIR_FREE(driver->stateDir); virCondDestroy(&driver->initCond); virMutexDestroy(&driver->lock); VIR_FREE(driver); udevPCITranslateDeinit(); return 0; } static int udevHandleOneDevice(struct udev_device *device) { const char *action = udev_device_get_action(device); VIR_DEBUG("udev action: '%s'", action); if (STREQ(action, "add") || STREQ(action, "change")) return udevAddOneDevice(device); if (STREQ(action, "remove")) return udevRemoveOneDevice(device); if (STREQ(action, "move")) { const char *devpath_old = udevGetDeviceProperty(device, "DEVPATH_OLD"); if (devpath_old) { g_autofree char *devpath_old_fixed = g_strdup_printf("/sys%s", devpath_old); udevRemoveOneDeviceSysPath(devpath_old_fixed); } return udevAddOneDevice(device); } return 0; } /* the caller must be holding the udevEventData object lock prior to calling * this function */ static bool udevEventMonitorSanityCheck(udevEventDataPtr priv, int fd) { int rc = -1; rc = udev_monitor_get_fd(priv->udev_monitor); if (fd != rc) { virReportError(VIR_ERR_INTERNAL_ERROR, _("File descriptor returned by udev %d does not " "match node device file descriptor %d"), fd, rc); /* this is a non-recoverable error, let's remove the handle, so that we * don't get in here again because of some spurious behaviour and report * the same error multiple times */ virEventRemoveHandle(priv->watch); priv->watch = -1; return false; } return true; } /** * udevEventHandleThread * @opaque: unused * * Thread to handle the udevEventHandleCallback processing when udev * tells us there's a device change for us (add, modify, delete, etc). * * Once notified there is data to be processed, the actual @device * data retrieval by libudev may be delayed due to how threads are * scheduled. In fact, the event loop could be scheduled earlier than * the handler thread, thus potentially emitting the very same event * the handler thread is currently trying to process, simply because * the data hadn't been retrieved from the socket. * * NB: Some older distros, such as CentOS 6, libudev opens sockets * without the NONBLOCK flag which might cause issues with event * based algorithm. Although the issue can be mitigated by resetting * priv->dataReady for each event found; however, the scheduler issues * would still come into play. */ static void udevEventHandleThread(void *opaque G_GNUC_UNUSED) { udevEventDataPtr priv = driver->privateData; struct udev_device *device = NULL; /* continue rather than break from the loop on non-fatal errors */ while (1) { virObjectLock(priv); while (!priv->dataReady && !priv->threadQuit) { if (virCondWait(&priv->threadCond, &priv->parent.lock)) { virReportSystemError(errno, "%s", _("handler failed to wait on condition")); virObjectUnlock(priv); return; } } if (priv->threadQuit) { virObjectUnlock(priv); return; } errno = 0; device = udev_monitor_receive_device(priv->udev_monitor); virObjectUnlock(priv); if (!device) { if (errno == 0) { virReportError(VIR_ERR_INTERNAL_ERROR, "%s", _("failed to receive device from udev monitor")); return; } /* POSIX allows both EAGAIN and EWOULDBLOCK to be used * interchangeably when the read would block or timeout was fired */ VIR_WARNINGS_NO_WLOGICALOP_EQUAL_EXPR if (errno != EAGAIN && errno != EWOULDBLOCK) { VIR_WARNINGS_RESET virReportSystemError(errno, "%s", _("failed to receive device from udev " "monitor")); return; } /* Trying to move the reset of the @priv->dataReady flag to * after the udev_monitor_receive_device wouldn't help much * due to event mgmt and scheduler timing. */ virObjectLock(priv); priv->dataReady = false; virObjectUnlock(priv); continue; } udevHandleOneDevice(device); udev_device_unref(device); /* Instead of waiting for the next event after processing @device * data, let's keep reading from the udev monitor and only wait * for the next event once either a EAGAIN or a EWOULDBLOCK error * is encountered. */ } } static void udevEventHandleCallback(int watch G_GNUC_UNUSED, int fd, int events G_GNUC_UNUSED, void *data G_GNUC_UNUSED) { udevEventDataPtr priv = driver->privateData; virObjectLock(priv); if (!udevEventMonitorSanityCheck(priv, fd)) priv->threadQuit = true; else priv->dataReady = true; virCondSignal(&priv->threadCond); virObjectUnlock(priv); } /* DMI is intel-compatible specific */ #if defined(__x86_64__) || defined(__i386__) || defined(__amd64__) static void udevGetDMIData(virNodeDevCapSystemPtr syscap) { udevEventDataPtr priv = driver->privateData; struct udev *udev = NULL; struct udev_device *device = NULL; virNodeDevCapSystemHardwarePtr hardware = &syscap->hardware; virNodeDevCapSystemFirmwarePtr firmware = &syscap->firmware; virObjectLock(priv); udev = udev_monitor_get_udev(priv->udev_monitor); device = udev_device_new_from_syspath(udev, DMI_DEVPATH); if (device == NULL) { device = udev_device_new_from_syspath(udev, DMI_DEVPATH_FALLBACK); if (device == NULL) { virReportError(VIR_ERR_INTERNAL_ERROR, _("Failed to get udev device for syspath '%s' or '%s'"), DMI_DEVPATH, DMI_DEVPATH_FALLBACK); virObjectUnlock(priv); return; } } virObjectUnlock(priv); if (udevGetStringSysfsAttr(device, "product_name", &syscap->product_name) < 0) goto cleanup; if (udevGetStringSysfsAttr(device, "sys_vendor", &hardware->vendor_name) < 0) goto cleanup; if (udevGetStringSysfsAttr(device, "product_version", &hardware->version) < 0) goto cleanup; if (udevGetStringSysfsAttr(device, "product_serial", &hardware->serial) < 0) goto cleanup; if (virGetHostUUID(hardware->uuid)) goto cleanup; if (udevGetStringSysfsAttr(device, "bios_vendor", &firmware->vendor_name) < 0) goto cleanup; if (udevGetStringSysfsAttr(device, "bios_version", &firmware->version) < 0) goto cleanup; if (udevGetStringSysfsAttr(device, "bios_date", &firmware->release_date) < 0) goto cleanup; cleanup: if (device != NULL) udev_device_unref(device); return; } #endif static int udevSetupSystemDev(void) { virNodeDeviceDefPtr def = NULL; virNodeDeviceObjPtr obj = NULL; int ret = -1; if (VIR_ALLOC(def) < 0) return -1; def->name = g_strdup("computer"); if (VIR_ALLOC(def->caps) != 0) goto cleanup; #if defined(__x86_64__) || defined(__i386__) || defined(__amd64__) udevGetDMIData(&def->caps->data.system); #endif if (!(obj = virNodeDeviceObjListAssignDef(driver->devs, def))) goto cleanup; virNodeDeviceObjEndAPI(&obj); ret = 0; cleanup: if (ret == -1) virNodeDeviceDefFree(def); return ret; } static void nodeStateInitializeEnumerate(void *opaque) { struct udev *udev = opaque; udevEventDataPtr priv = driver->privateData; /* Populate with known devices */ if (udevEnumerateDevices(udev) != 0) goto error; nodeDeviceLock(); driver->initialized = true; nodeDeviceUnlock(); virCondBroadcast(&driver->initCond); return; error: virObjectLock(priv); ignore_value(virEventRemoveHandle(priv->watch)); priv->watch = -1; priv->threadQuit = true; virCondSignal(&priv->threadCond); virObjectUnlock(priv); } static int udevPCITranslateInit(bool privileged G_GNUC_UNUSED) { #if defined __s390__ || defined __s390x_ /* On s390(x) system there is no PCI bus. * Therefore there is nothing to initialize here. */ #else int rc; if ((rc = pci_system_init()) != 0) { /* Ignore failure as non-root; udev is not as helpful in that * situation, but a non-privileged user won't benefit much * from udev in the first place. */ if (errno != ENOENT && (privileged || errno != EACCES)) { virReportSystemError(rc, "%s", _("Failed to initialize libpciaccess")); return -1; } } #endif return 0; } static int nodeStateInitialize(bool privileged, const char *root, virStateInhibitCallback callback G_GNUC_UNUSED, void *opaque G_GNUC_UNUSED) { udevEventDataPtr priv = NULL; struct udev *udev = NULL; virThread enumThread; if (root != NULL) { virReportError(VIR_ERR_INVALID_ARG, "%s", _("Driver does not support embedded mode")); return -1; } if (VIR_ALLOC(driver) < 0) return VIR_DRV_STATE_INIT_ERROR; driver->lockFD = -1; if (virMutexInit(&driver->lock) < 0) { virReportError(VIR_ERR_INTERNAL_ERROR, "%s", _("Unable to initialize mutex")); VIR_FREE(driver); return VIR_DRV_STATE_INIT_ERROR; } if (virCondInit(&driver->initCond) < 0) { virReportSystemError(errno, "%s", _("Unable to initialize condition variable")); virMutexDestroy(&driver->lock); VIR_FREE(driver); return VIR_DRV_STATE_INIT_ERROR; } driver->privileged = privileged; if (privileged) { driver->stateDir = g_strdup_printf("%s/libvirt/nodedev", RUNSTATEDIR); } else { g_autofree char *rundir = NULL; rundir = virGetUserRuntimeDirectory(); driver->stateDir = g_strdup_printf("%s/nodedev/run", rundir); } if (virFileMakePathWithMode(driver->stateDir, S_IRWXU) < 0) { virReportSystemError(errno, _("cannot create state directory '%s'"), driver->stateDir); goto cleanup; } if ((driver->lockFD = virPidFileAcquire(driver->stateDir, "driver", false, getpid())) < 0) goto cleanup; if (!(driver->devs = virNodeDeviceObjListNew()) || !(priv = udevEventDataNew())) goto cleanup; driver->privateData = priv; driver->nodeDeviceEventState = virObjectEventStateNew(); if (udevPCITranslateInit(privileged) < 0) goto cleanup; udev = udev_new(); if (!udev) { virReportError(VIR_ERR_INTERNAL_ERROR, "%s", _("failed to create udev context")); goto cleanup; } virObjectLock(priv); priv->udev_monitor = udev_monitor_new_from_netlink(udev, "kernel"); if (!priv->udev_monitor) { virReportError(VIR_ERR_INTERNAL_ERROR, "%s", _("udev_monitor_new_from_netlink returned NULL")); goto unlock; } udev_monitor_enable_receiving(priv->udev_monitor); /* mimic udevd's behaviour and override the systems rmem_max limit in case * there's a significant number of device 'add' events */ if (geteuid() == 0) udev_monitor_set_receive_buffer_size(priv->udev_monitor, 128 * 1024 * 1024); if (virThreadCreateFull(&priv->th, true, udevEventHandleThread, "udev-event", false, NULL) < 0) { virReportSystemError(errno, "%s", _("failed to create udev handler thread")); goto unlock; } /* We register the monitor with the event callback so we are * notified by udev of device changes before we enumerate existing * devices because libvirt will simply recreate the device if we * try to register it twice, i.e., if the device appears between * the time we register the callback and the time we begin * enumeration. The alternative is to register the callback after * we enumerate, in which case we will fail to create any devices * that appear while the enumeration is taking place. */ priv->watch = virEventAddHandle(udev_monitor_get_fd(priv->udev_monitor), VIR_EVENT_HANDLE_READABLE, udevEventHandleCallback, NULL, NULL); if (priv->watch == -1) goto unlock; virObjectUnlock(priv); /* Create a fictional 'computer' device to root the device tree. */ if (udevSetupSystemDev() != 0) goto cleanup; if (virThreadCreateFull(&enumThread, false, nodeStateInitializeEnumerate, "nodedev-init", false, udev) < 0) { virReportSystemError(errno, "%s", _("failed to create udev enumerate thread")); goto cleanup; } return VIR_DRV_STATE_INIT_COMPLETE; cleanup: nodeStateCleanup(); return VIR_DRV_STATE_INIT_ERROR; unlock: virObjectUnlock(priv); goto cleanup; } static int nodeStateReload(void) { return 0; } static virNodeDeviceDriver udevNodeDeviceDriver = { .name = "udev", .nodeNumOfDevices = nodeNumOfDevices, /* 0.7.3 */ .nodeListDevices = nodeListDevices, /* 0.7.3 */ .connectListAllNodeDevices = nodeConnectListAllNodeDevices, /* 0.10.2 */ .connectNodeDeviceEventRegisterAny = nodeConnectNodeDeviceEventRegisterAny, /* 2.2.0 */ .connectNodeDeviceEventDeregisterAny = nodeConnectNodeDeviceEventDeregisterAny, /* 2.2.0 */ .nodeDeviceLookupByName = nodeDeviceLookupByName, /* 0.7.3 */ .nodeDeviceLookupSCSIHostByWWN = nodeDeviceLookupSCSIHostByWWN, /* 1.0.2 */ .nodeDeviceGetXMLDesc = nodeDeviceGetXMLDesc, /* 0.7.3 */ .nodeDeviceGetParent = nodeDeviceGetParent, /* 0.7.3 */ .nodeDeviceNumOfCaps = nodeDeviceNumOfCaps, /* 0.7.3 */ .nodeDeviceListCaps = nodeDeviceListCaps, /* 0.7.3 */ .nodeDeviceCreateXML = nodeDeviceCreateXML, /* 0.7.3 */ .nodeDeviceDestroy = nodeDeviceDestroy, /* 0.7.3 */ }; static virHypervisorDriver udevHypervisorDriver = { .name = "nodedev", .connectOpen = nodeConnectOpen, /* 4.1.0 */ .connectClose = nodeConnectClose, /* 4.1.0 */ .connectIsEncrypted = nodeConnectIsEncrypted, /* 4.1.0 */ .connectIsSecure = nodeConnectIsSecure, /* 4.1.0 */ .connectIsAlive = nodeConnectIsAlive, /* 4.1.0 */ }; static virConnectDriver udevConnectDriver = { .localOnly = true, .uriSchemes = (const char *[]){ "nodedev", NULL }, .hypervisorDriver = &udevHypervisorDriver, .nodeDeviceDriver = &udevNodeDeviceDriver, }; static virStateDriver udevStateDriver = { .name = "udev", .stateInitialize = nodeStateInitialize, /* 0.7.3 */ .stateCleanup = nodeStateCleanup, /* 0.7.3 */ .stateReload = nodeStateReload, /* 0.7.3 */ }; int udevNodeRegister(void) { VIR_DEBUG("Registering udev node device backend"); if (virRegisterConnectDriver(&udevConnectDriver, false) < 0) return -1; if (virSetSharedNodeDeviceDriver(&udevNodeDeviceDriver) < 0) return -1; return virRegisterStateDriver(&udevStateDriver); }