/* * qemu_domain.c: QEMU domain private state * * Copyright (C) 2006-2016 Red Hat, Inc. * Copyright (C) 2006 Daniel P. Berrange * * 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 * . * * Author: Daniel P. Berrange */ #include #include "qemu_domain.h" #include "qemu_alias.h" #include "qemu_block.h" #include "qemu_cgroup.h" #include "qemu_command.h" #include "qemu_process.h" #include "qemu_parse_command.h" #include "qemu_capabilities.h" #include "qemu_migration.h" #include "qemu_security.h" #include "viralloc.h" #include "virlog.h" #include "virerror.h" #include "c-ctype.h" #include "cpu/cpu.h" #include "viruuid.h" #include "virfile.h" #include "domain_addr.h" #include "domain_event.h" #include "virtime.h" #include "virnetdevopenvswitch.h" #include "virstoragefile.h" #include "virstring.h" #include "virthreadjob.h" #include "viratomic.h" #include "virprocess.h" #include "vircrypto.h" #include "virsystemd.h" #include "secret_util.h" #include "logging/log_manager.h" #include "locking/domain_lock.h" #include "storage/storage_driver.h" #include "storage/storage_source.h" #ifdef MAJOR_IN_MKDEV # include #elif MAJOR_IN_SYSMACROS # include #endif #include #include #if defined(HAVE_SYS_MOUNT_H) # include #endif #ifdef WITH_SELINUX # include #endif #include #include "dosname.h" #define VIR_FROM_THIS VIR_FROM_QEMU VIR_LOG_INIT("qemu.qemu_domain"); #define QEMU_NAMESPACE_HREF "http://libvirt.org/schemas/domain/qemu/1.0" VIR_ENUM_IMPL(qemuDomainJob, QEMU_JOB_LAST, "none", "query", "destroy", "suspend", "modify", "abort", "migration operation", "none", /* async job is never stored in job.active */ "async nested", ); VIR_ENUM_IMPL(qemuDomainAsyncJob, QEMU_ASYNC_JOB_LAST, "none", "migration out", "migration in", "save", "dump", "snapshot", "start", ); VIR_ENUM_IMPL(qemuDomainNamespace, QEMU_DOMAIN_NS_LAST, "mount", ); #define PROC_MOUNTS "/proc/mounts" #define DEVPREFIX "/dev/" #define DEV_VFIO "/dev/vfio/vfio" struct _qemuDomainLogContext { virObject parent; int writefd; int readfd; /* Only used if manager == NULL */ off_t pos; ino_t inode; /* Only used if manager != NULL */ char *path; virLogManagerPtr manager; }; static virClassPtr qemuDomainLogContextClass; static virClassPtr qemuDomainSaveCookieClass; static void qemuDomainLogContextDispose(void *obj); static void qemuDomainSaveCookieDispose(void *obj); static int qemuDomainOnceInit(void) { if (!(qemuDomainLogContextClass = virClassNew(virClassForObject(), "qemuDomainLogContext", sizeof(qemuDomainLogContext), qemuDomainLogContextDispose))) return -1; if (!(qemuDomainSaveCookieClass = virClassNew(virClassForObject(), "qemuDomainSaveCookie", sizeof(qemuDomainSaveCookie), qemuDomainSaveCookieDispose))) return -1; return 0; } VIR_ONCE_GLOBAL_INIT(qemuDomain) static void qemuDomainLogContextDispose(void *obj) { qemuDomainLogContextPtr ctxt = obj; VIR_DEBUG("ctxt=%p", ctxt); virLogManagerFree(ctxt->manager); VIR_FREE(ctxt->path); VIR_FORCE_CLOSE(ctxt->writefd); VIR_FORCE_CLOSE(ctxt->readfd); } const char * qemuDomainAsyncJobPhaseToString(qemuDomainAsyncJob job, int phase ATTRIBUTE_UNUSED) { switch (job) { case QEMU_ASYNC_JOB_MIGRATION_OUT: case QEMU_ASYNC_JOB_MIGRATION_IN: return qemuMigrationJobPhaseTypeToString(phase); case QEMU_ASYNC_JOB_SAVE: case QEMU_ASYNC_JOB_DUMP: case QEMU_ASYNC_JOB_SNAPSHOT: case QEMU_ASYNC_JOB_START: case QEMU_ASYNC_JOB_NONE: case QEMU_ASYNC_JOB_LAST: ATTRIBUTE_FALLTHROUGH; } return "none"; } int qemuDomainAsyncJobPhaseFromString(qemuDomainAsyncJob job, const char *phase) { if (!phase) return 0; switch (job) { case QEMU_ASYNC_JOB_MIGRATION_OUT: case QEMU_ASYNC_JOB_MIGRATION_IN: return qemuMigrationJobPhaseTypeFromString(phase); case QEMU_ASYNC_JOB_SAVE: case QEMU_ASYNC_JOB_DUMP: case QEMU_ASYNC_JOB_SNAPSHOT: case QEMU_ASYNC_JOB_START: case QEMU_ASYNC_JOB_NONE: case QEMU_ASYNC_JOB_LAST: ATTRIBUTE_FALLTHROUGH; } if (STREQ(phase, "none")) return 0; else return -1; } bool qemuDomainNamespaceEnabled(virDomainObjPtr vm, qemuDomainNamespace ns) { qemuDomainObjPrivatePtr priv = vm->privateData; return priv->namespaces && virBitmapIsBitSet(priv->namespaces, ns); } static int qemuDomainEnableNamespace(virDomainObjPtr vm, qemuDomainNamespace ns) { qemuDomainObjPrivatePtr priv = vm->privateData; if (!priv->namespaces && !(priv->namespaces = virBitmapNew(QEMU_DOMAIN_NS_LAST))) return -1; if (virBitmapSetBit(priv->namespaces, ns) < 0) { virReportError(VIR_ERR_INTERNAL_ERROR, _("Unable to enable namespace: %s"), qemuDomainNamespaceTypeToString(ns)); return -1; } return 0; } static void qemuDomainDisableNamespace(virDomainObjPtr vm, qemuDomainNamespace ns) { qemuDomainObjPrivatePtr priv = vm->privateData; if (priv->namespaces) { ignore_value(virBitmapClearBit(priv->namespaces, ns)); if (virBitmapIsAllClear(priv->namespaces)) { virBitmapFree(priv->namespaces); priv->namespaces = NULL; } } } void qemuDomainEventQueue(virQEMUDriverPtr driver, virObjectEventPtr event) { if (event) virObjectEventStateQueue(driver->domainEventState, event); } void qemuDomainEventEmitJobCompleted(virQEMUDriverPtr driver, virDomainObjPtr vm) { qemuDomainObjPrivatePtr priv = vm->privateData; virObjectEventPtr event; virTypedParameterPtr params = NULL; int nparams = 0; int type; if (!priv->job.completed) return; if (qemuDomainJobInfoToParams(priv->job.completed, &type, ¶ms, &nparams) < 0) { VIR_WARN("Could not get stats for completed job; domain %s", vm->def->name); } event = virDomainEventJobCompletedNewFromObj(vm, params, nparams); qemuDomainEventQueue(driver, event); } static int qemuDomainObjInitJob(qemuDomainObjPrivatePtr priv) { memset(&priv->job, 0, sizeof(priv->job)); if (virCondInit(&priv->job.cond) < 0) return -1; if (virCondInit(&priv->job.asyncCond) < 0) { virCondDestroy(&priv->job.cond); return -1; } return 0; } static void qemuDomainObjResetJob(qemuDomainObjPrivatePtr priv) { struct qemuDomainJobObj *job = &priv->job; job->active = QEMU_JOB_NONE; job->owner = 0; job->ownerAPI = NULL; job->started = 0; } static void qemuDomainObjResetAsyncJob(qemuDomainObjPrivatePtr priv) { struct qemuDomainJobObj *job = &priv->job; job->asyncJob = QEMU_ASYNC_JOB_NONE; job->asyncOwner = 0; job->asyncOwnerAPI = NULL; job->asyncStarted = 0; job->phase = 0; job->mask = QEMU_JOB_DEFAULT_MASK; job->dump_memory_only = false; job->abortJob = false; job->spiceMigration = false; job->spiceMigrated = false; job->postcopyEnabled = false; job->dumpCompleted = false; VIR_FREE(job->error); VIR_FREE(job->current); } void qemuDomainObjRestoreJob(virDomainObjPtr obj, struct qemuDomainJobObj *job) { qemuDomainObjPrivatePtr priv = obj->privateData; memset(job, 0, sizeof(*job)); job->active = priv->job.active; job->owner = priv->job.owner; job->asyncJob = priv->job.asyncJob; job->asyncOwner = priv->job.asyncOwner; job->phase = priv->job.phase; qemuDomainObjResetJob(priv); qemuDomainObjResetAsyncJob(priv); } static void qemuDomainObjFreeJob(qemuDomainObjPrivatePtr priv) { VIR_FREE(priv->job.current); VIR_FREE(priv->job.completed); virCondDestroy(&priv->job.cond); virCondDestroy(&priv->job.asyncCond); } static bool qemuDomainTrackJob(qemuDomainJob job) { return (QEMU_DOMAIN_TRACK_JOBS & JOB_MASK(job)) != 0; } int qemuDomainJobInfoUpdateTime(qemuDomainJobInfoPtr jobInfo) { unsigned long long now; if (!jobInfo->started) return 0; if (virTimeMillisNow(&now) < 0) return -1; if (now < jobInfo->started) { VIR_WARN("Async job starts in the future"); jobInfo->started = 0; return 0; } jobInfo->timeElapsed = now - jobInfo->started; return 0; } int qemuDomainJobInfoUpdateDowntime(qemuDomainJobInfoPtr jobInfo) { unsigned long long now; if (!jobInfo->stopped) return 0; if (virTimeMillisNow(&now) < 0) return -1; if (now < jobInfo->stopped) { VIR_WARN("Guest's CPUs stopped in the future"); jobInfo->stopped = 0; return 0; } jobInfo->stats.mig.downtime = now - jobInfo->stopped; jobInfo->stats.mig.downtime_set = true; return 0; } static virDomainJobType qemuDomainJobStatusToType(qemuDomainJobStatus status) { switch (status) { case QEMU_DOMAIN_JOB_STATUS_NONE: break; case QEMU_DOMAIN_JOB_STATUS_ACTIVE: case QEMU_DOMAIN_JOB_STATUS_MIGRATING: case QEMU_DOMAIN_JOB_STATUS_QEMU_COMPLETED: case QEMU_DOMAIN_JOB_STATUS_POSTCOPY: case QEMU_DOMAIN_JOB_STATUS_PAUSED: return VIR_DOMAIN_JOB_UNBOUNDED; case QEMU_DOMAIN_JOB_STATUS_COMPLETED: return VIR_DOMAIN_JOB_COMPLETED; case QEMU_DOMAIN_JOB_STATUS_FAILED: return VIR_DOMAIN_JOB_FAILED; case QEMU_DOMAIN_JOB_STATUS_CANCELED: return VIR_DOMAIN_JOB_CANCELLED; } return VIR_DOMAIN_JOB_NONE; } int qemuDomainJobInfoToInfo(qemuDomainJobInfoPtr jobInfo, virDomainJobInfoPtr info) { info->type = qemuDomainJobStatusToType(jobInfo->status); info->timeElapsed = jobInfo->timeElapsed; switch (jobInfo->statsType) { case QEMU_DOMAIN_JOB_STATS_TYPE_MIGRATION: info->memTotal = jobInfo->stats.mig.ram_total; info->memRemaining = jobInfo->stats.mig.ram_remaining; info->memProcessed = jobInfo->stats.mig.ram_transferred; info->fileTotal = jobInfo->stats.mig.disk_total + jobInfo->mirrorStats.total; info->fileRemaining = jobInfo->stats.mig.disk_remaining + (jobInfo->mirrorStats.total - jobInfo->mirrorStats.transferred); info->fileProcessed = jobInfo->stats.mig.disk_transferred + jobInfo->mirrorStats.transferred; break; case QEMU_DOMAIN_JOB_STATS_TYPE_SAVEDUMP: info->memTotal = jobInfo->stats.mig.ram_total; info->memRemaining = jobInfo->stats.mig.ram_remaining; info->memProcessed = jobInfo->stats.mig.ram_transferred; break; case QEMU_DOMAIN_JOB_STATS_TYPE_MEMDUMP: case QEMU_DOMAIN_JOB_STATS_TYPE_NONE: break; } info->dataTotal = info->memTotal + info->fileTotal; info->dataRemaining = info->memRemaining + info->fileRemaining; info->dataProcessed = info->memProcessed + info->fileProcessed; return 0; } static int qemuDomainMigrationJobInfoToParams(qemuDomainJobInfoPtr jobInfo, int *type, virTypedParameterPtr *params, int *nparams) { qemuMonitorMigrationStats *stats = &jobInfo->stats.mig; qemuDomainMirrorStatsPtr mirrorStats = &jobInfo->mirrorStats; virTypedParameterPtr par = NULL; int maxpar = 0; int npar = 0; unsigned long long mirrorRemaining = mirrorStats->total - mirrorStats->transferred; if (virTypedParamsAddInt(&par, &npar, &maxpar, VIR_DOMAIN_JOB_OPERATION, jobInfo->operation) < 0) goto error; if (virTypedParamsAddULLong(&par, &npar, &maxpar, VIR_DOMAIN_JOB_TIME_ELAPSED, jobInfo->timeElapsed) < 0) goto error; if (jobInfo->timeDeltaSet && jobInfo->timeElapsed > jobInfo->timeDelta && virTypedParamsAddULLong(&par, &npar, &maxpar, VIR_DOMAIN_JOB_TIME_ELAPSED_NET, jobInfo->timeElapsed - jobInfo->timeDelta) < 0) goto error; if (stats->downtime_set && virTypedParamsAddULLong(&par, &npar, &maxpar, VIR_DOMAIN_JOB_DOWNTIME, stats->downtime) < 0) goto error; if (stats->downtime_set && jobInfo->timeDeltaSet && stats->downtime > jobInfo->timeDelta && virTypedParamsAddULLong(&par, &npar, &maxpar, VIR_DOMAIN_JOB_DOWNTIME_NET, stats->downtime - jobInfo->timeDelta) < 0) goto error; if (stats->setup_time_set && virTypedParamsAddULLong(&par, &npar, &maxpar, VIR_DOMAIN_JOB_SETUP_TIME, stats->setup_time) < 0) goto error; if (virTypedParamsAddULLong(&par, &npar, &maxpar, VIR_DOMAIN_JOB_DATA_TOTAL, stats->ram_total + stats->disk_total + mirrorStats->total) < 0 || virTypedParamsAddULLong(&par, &npar, &maxpar, VIR_DOMAIN_JOB_DATA_PROCESSED, stats->ram_transferred + stats->disk_transferred + mirrorStats->transferred) < 0 || virTypedParamsAddULLong(&par, &npar, &maxpar, VIR_DOMAIN_JOB_DATA_REMAINING, stats->ram_remaining + stats->disk_remaining + mirrorRemaining) < 0) goto error; if (virTypedParamsAddULLong(&par, &npar, &maxpar, VIR_DOMAIN_JOB_MEMORY_TOTAL, stats->ram_total) < 0 || virTypedParamsAddULLong(&par, &npar, &maxpar, VIR_DOMAIN_JOB_MEMORY_PROCESSED, stats->ram_transferred) < 0 || virTypedParamsAddULLong(&par, &npar, &maxpar, VIR_DOMAIN_JOB_MEMORY_REMAINING, stats->ram_remaining) < 0) goto error; if (stats->ram_bps && virTypedParamsAddULLong(&par, &npar, &maxpar, VIR_DOMAIN_JOB_MEMORY_BPS, stats->ram_bps) < 0) goto error; if (stats->ram_duplicate_set) { if (virTypedParamsAddULLong(&par, &npar, &maxpar, VIR_DOMAIN_JOB_MEMORY_CONSTANT, stats->ram_duplicate) < 0 || virTypedParamsAddULLong(&par, &npar, &maxpar, VIR_DOMAIN_JOB_MEMORY_NORMAL, stats->ram_normal) < 0 || virTypedParamsAddULLong(&par, &npar, &maxpar, VIR_DOMAIN_JOB_MEMORY_NORMAL_BYTES, stats->ram_normal_bytes) < 0) goto error; } if (virTypedParamsAddULLong(&par, &npar, &maxpar, VIR_DOMAIN_JOB_MEMORY_DIRTY_RATE, stats->ram_dirty_rate) < 0 || virTypedParamsAddULLong(&par, &npar, &maxpar, VIR_DOMAIN_JOB_MEMORY_ITERATION, stats->ram_iteration) < 0) goto error; if (stats->ram_page_size > 0 && virTypedParamsAddULLong(&par, &npar, &maxpar, VIR_DOMAIN_JOB_MEMORY_PAGE_SIZE, stats->ram_page_size) < 0) goto error; /* The remaining stats are disk, mirror, or migration specific * so if this is a SAVEDUMP, we can just skip them */ if (jobInfo->statsType == QEMU_DOMAIN_JOB_STATS_TYPE_SAVEDUMP) goto done; if (virTypedParamsAddULLong(&par, &npar, &maxpar, VIR_DOMAIN_JOB_DISK_TOTAL, stats->disk_total + mirrorStats->total) < 0 || virTypedParamsAddULLong(&par, &npar, &maxpar, VIR_DOMAIN_JOB_DISK_PROCESSED, stats->disk_transferred + mirrorStats->transferred) < 0 || virTypedParamsAddULLong(&par, &npar, &maxpar, VIR_DOMAIN_JOB_DISK_REMAINING, stats->disk_remaining + mirrorRemaining) < 0) goto error; if (stats->disk_bps && virTypedParamsAddULLong(&par, &npar, &maxpar, VIR_DOMAIN_JOB_DISK_BPS, stats->disk_bps) < 0) goto error; if (stats->xbzrle_set) { if (virTypedParamsAddULLong(&par, &npar, &maxpar, VIR_DOMAIN_JOB_COMPRESSION_CACHE, stats->xbzrle_cache_size) < 0 || virTypedParamsAddULLong(&par, &npar, &maxpar, VIR_DOMAIN_JOB_COMPRESSION_BYTES, stats->xbzrle_bytes) < 0 || virTypedParamsAddULLong(&par, &npar, &maxpar, VIR_DOMAIN_JOB_COMPRESSION_PAGES, stats->xbzrle_pages) < 0 || virTypedParamsAddULLong(&par, &npar, &maxpar, VIR_DOMAIN_JOB_COMPRESSION_CACHE_MISSES, stats->xbzrle_cache_miss) < 0 || virTypedParamsAddULLong(&par, &npar, &maxpar, VIR_DOMAIN_JOB_COMPRESSION_OVERFLOW, stats->xbzrle_overflow) < 0) goto error; } if (stats->cpu_throttle_percentage && virTypedParamsAddInt(&par, &npar, &maxpar, VIR_DOMAIN_JOB_AUTO_CONVERGE_THROTTLE, stats->cpu_throttle_percentage) < 0) goto error; done: *type = qemuDomainJobStatusToType(jobInfo->status); *params = par; *nparams = npar; return 0; error: virTypedParamsFree(par, npar); return -1; } int qemuDomainJobInfoToParams(qemuDomainJobInfoPtr jobInfo, int *type, virTypedParameterPtr *params, int *nparams) { switch (jobInfo->statsType) { case QEMU_DOMAIN_JOB_STATS_TYPE_MIGRATION: case QEMU_DOMAIN_JOB_STATS_TYPE_SAVEDUMP: return qemuDomainMigrationJobInfoToParams(jobInfo, type, params, nparams); case QEMU_DOMAIN_JOB_STATS_TYPE_MEMDUMP: case QEMU_DOMAIN_JOB_STATS_TYPE_NONE: break; } return -1; } /* qemuDomainGetMasterKeyFilePath: * @libDir: Directory path to domain lib files * * Generate a path to the domain master key file for libDir. * It's up to the caller to handle checking if path exists. * * Returns path to memory containing the name of the file. It is up to the * caller to free; otherwise, NULL on failure. */ char * qemuDomainGetMasterKeyFilePath(const char *libDir) { if (!libDir) { virReportError(VIR_ERR_INTERNAL_ERROR, "%s", _("invalid path for master key file")); return NULL; } return virFileBuildPath(libDir, "master-key.aes", NULL); } /* qemuDomainWriteMasterKeyFile: * @driver: qemu driver data * @vm: Pointer to the vm object * * Get the desired path to the masterKey file and store it in the path. * * Returns 0 on success, -1 on failure with error message indicating failure */ int qemuDomainWriteMasterKeyFile(virQEMUDriverPtr driver, virDomainObjPtr vm) { char *path; int fd = -1; int ret = -1; qemuDomainObjPrivatePtr priv = vm->privateData; /* Only gets filled in if we have the capability */ if (!priv->masterKey) return 0; if (!(path = qemuDomainGetMasterKeyFilePath(priv->libDir))) return -1; if ((fd = open(path, O_WRONLY|O_TRUNC|O_CREAT, 0600)) < 0) { virReportError(VIR_ERR_INTERNAL_ERROR, "%s", _("failed to open domain master key file for write")); goto cleanup; } if (safewrite(fd, priv->masterKey, priv->masterKeyLen) < 0) { virReportError(VIR_ERR_INTERNAL_ERROR, "%s", _("failed to write master key file for domain")); goto cleanup; } if (qemuSecurityDomainSetPathLabel(driver->securityManager, vm->def, path, false) < 0) goto cleanup; ret = 0; cleanup: VIR_FORCE_CLOSE(fd); VIR_FREE(path); return ret; } static void qemuDomainMasterKeyFree(qemuDomainObjPrivatePtr priv) { if (!priv->masterKey) return; VIR_DISPOSE_N(priv->masterKey, priv->masterKeyLen); } /* qemuDomainMasterKeyReadFile: * @priv: pointer to domain private object * * Expected to be called during qemuProcessReconnect once the domain * libDir has been generated through qemuStateInitialize calling * virDomainObjListLoadAllConfigs which will restore the libDir path * to the domain private object. * * This function will get the path to the master key file and if it * exists, it will read the contents of the file saving it in priv->masterKey. * * Once the file exists, the validity checks may cause failures; however, * if the file doesn't exist or the capability doesn't exist, we just * return (mostly) quietly. * * Returns 0 on success or lack of capability * -1 on failure with error message indicating failure */ int qemuDomainMasterKeyReadFile(qemuDomainObjPrivatePtr priv) { char *path; int fd = -1; uint8_t *masterKey = NULL; ssize_t masterKeyLen = 0; /* If we don't have the capability, then do nothing. */ if (!virQEMUCapsGet(priv->qemuCaps, QEMU_CAPS_OBJECT_SECRET)) return 0; if (!(path = qemuDomainGetMasterKeyFilePath(priv->libDir))) return -1; if (!virFileExists(path)) { virReportError(VIR_ERR_INTERNAL_ERROR, _("domain master key file doesn't exist in %s"), priv->libDir); goto error; } if ((fd = open(path, O_RDONLY)) < 0) { virReportError(VIR_ERR_INTERNAL_ERROR, "%s", _("failed to open domain master key file for read")); goto error; } if (VIR_ALLOC_N(masterKey, 1024) < 0) goto error; if ((masterKeyLen = saferead(fd, masterKey, 1024)) < 0) { virReportError(VIR_ERR_INTERNAL_ERROR, "%s", _("unable to read domain master key file")); goto error; } if (masterKeyLen != QEMU_DOMAIN_MASTER_KEY_LEN) { virReportError(VIR_ERR_INTERNAL_ERROR, _("invalid master key read, size=%zd"), masterKeyLen); goto error; } ignore_value(VIR_REALLOC_N_QUIET(masterKey, masterKeyLen)); priv->masterKey = masterKey; priv->masterKeyLen = masterKeyLen; VIR_FORCE_CLOSE(fd); VIR_FREE(path); return 0; error: if (masterKeyLen > 0) memset(masterKey, 0, masterKeyLen); VIR_FREE(masterKey); VIR_FORCE_CLOSE(fd); VIR_FREE(path); return -1; } /* qemuDomainMasterKeyRemove: * @priv: Pointer to the domain private object * * Remove the traces of the master key, clear the heap, clear the file, * delete the file. */ void qemuDomainMasterKeyRemove(qemuDomainObjPrivatePtr priv) { char *path = NULL; if (!priv->masterKey) return; /* Clear the contents */ qemuDomainMasterKeyFree(priv); /* Delete the master key file */ path = qemuDomainGetMasterKeyFilePath(priv->libDir); unlink(path); VIR_FREE(path); } /* qemuDomainMasterKeyCreate: * @vm: Pointer to the domain object * * As long as the underlying qemu has the secret capability, * generate and store 'raw' in a file a random 32-byte key to * be used as a secret shared with qemu to share sensitive data. * * Returns: 0 on success, -1 w/ error message on failure */ int qemuDomainMasterKeyCreate(virDomainObjPtr vm) { qemuDomainObjPrivatePtr priv = vm->privateData; /* If we don't have the capability, then do nothing. */ if (!virQEMUCapsGet(priv->qemuCaps, QEMU_CAPS_OBJECT_SECRET)) return 0; if (!(priv->masterKey = virCryptoGenerateRandom(QEMU_DOMAIN_MASTER_KEY_LEN))) return -1; priv->masterKeyLen = QEMU_DOMAIN_MASTER_KEY_LEN; return 0; } static void qemuDomainSecretPlainClear(qemuDomainSecretPlain secret) { VIR_FREE(secret.username); VIR_DISPOSE_N(secret.secret, secret.secretlen); } static void qemuDomainSecretAESClear(qemuDomainSecretAES secret) { VIR_FREE(secret.username); VIR_FREE(secret.alias); VIR_FREE(secret.iv); VIR_FREE(secret.ciphertext); } void qemuDomainSecretInfoFree(qemuDomainSecretInfoPtr *secinfo) { if (!*secinfo) return; switch ((qemuDomainSecretInfoType) (*secinfo)->type) { case VIR_DOMAIN_SECRET_INFO_TYPE_PLAIN: qemuDomainSecretPlainClear((*secinfo)->s.plain); break; case VIR_DOMAIN_SECRET_INFO_TYPE_AES: qemuDomainSecretAESClear((*secinfo)->s.aes); break; case VIR_DOMAIN_SECRET_INFO_TYPE_LAST: break; } VIR_FREE(*secinfo); } static virClassPtr qemuDomainDiskPrivateClass; static void qemuDomainDiskPrivateDispose(void *obj); static int qemuDomainDiskPrivateOnceInit(void) { qemuDomainDiskPrivateClass = virClassNew(virClassForObject(), "qemuDomainDiskPrivate", sizeof(qemuDomainDiskPrivate), qemuDomainDiskPrivateDispose); if (!qemuDomainDiskPrivateClass) return -1; else return 0; } VIR_ONCE_GLOBAL_INIT(qemuDomainDiskPrivate) static virObjectPtr qemuDomainDiskPrivateNew(void) { qemuDomainDiskPrivatePtr priv; if (qemuDomainDiskPrivateInitialize() < 0) return NULL; if (!(priv = virObjectNew(qemuDomainDiskPrivateClass))) return NULL; return (virObjectPtr) priv; } static void qemuDomainDiskPrivateDispose(void *obj) { qemuDomainDiskPrivatePtr priv = obj; VIR_FREE(priv->blockJobError); } static virClassPtr qemuDomainStorageSourcePrivateClass; static void qemuDomainStorageSourcePrivateDispose(void *obj); static int qemuDomainStorageSourcePrivateOnceInit(void) { qemuDomainStorageSourcePrivateClass = virClassNew(virClassForObject(), "qemuDomainStorageSourcePrivate", sizeof(qemuDomainStorageSourcePrivate), qemuDomainStorageSourcePrivateDispose); if (!qemuDomainStorageSourcePrivateClass) return -1; else return 0; } VIR_ONCE_GLOBAL_INIT(qemuDomainStorageSourcePrivate) virObjectPtr qemuDomainStorageSourcePrivateNew(void) { qemuDomainStorageSourcePrivatePtr priv; if (qemuDomainStorageSourcePrivateInitialize() < 0) return NULL; if (!(priv = virObjectNew(qemuDomainStorageSourcePrivateClass))) return NULL; return (virObjectPtr) priv; } static void qemuDomainStorageSourcePrivateDispose(void *obj) { qemuDomainStorageSourcePrivatePtr priv = obj; qemuDomainSecretInfoFree(&priv->secinfo); qemuDomainSecretInfoFree(&priv->encinfo); } static virClassPtr qemuDomainVcpuPrivateClass; static void qemuDomainVcpuPrivateDispose(void *obj); static int qemuDomainVcpuPrivateOnceInit(void) { qemuDomainVcpuPrivateClass = virClassNew(virClassForObject(), "qemuDomainVcpuPrivate", sizeof(qemuDomainVcpuPrivate), qemuDomainVcpuPrivateDispose); if (!qemuDomainVcpuPrivateClass) return -1; else return 0; } VIR_ONCE_GLOBAL_INIT(qemuDomainVcpuPrivate) static virObjectPtr qemuDomainVcpuPrivateNew(void) { qemuDomainVcpuPrivatePtr priv; if (qemuDomainVcpuPrivateInitialize() < 0) return NULL; if (!(priv = virObjectNew(qemuDomainVcpuPrivateClass))) return NULL; return (virObjectPtr) priv; } static void qemuDomainVcpuPrivateDispose(void *obj) { qemuDomainVcpuPrivatePtr priv = obj; VIR_FREE(priv->type); VIR_FREE(priv->alias); return; } static virClassPtr qemuDomainChrSourcePrivateClass; static void qemuDomainChrSourcePrivateDispose(void *obj); static int qemuDomainChrSourcePrivateOnceInit(void) { qemuDomainChrSourcePrivateClass = virClassNew(virClassForObject(), "qemuDomainChrSourcePrivate", sizeof(qemuDomainChrSourcePrivate), qemuDomainChrSourcePrivateDispose); if (!qemuDomainChrSourcePrivateClass) return -1; else return 0; } VIR_ONCE_GLOBAL_INIT(qemuDomainChrSourcePrivate) static virObjectPtr qemuDomainChrSourcePrivateNew(void) { qemuDomainChrSourcePrivatePtr priv; if (qemuDomainChrSourcePrivateInitialize() < 0) return NULL; if (!(priv = virObjectNew(qemuDomainChrSourcePrivateClass))) return NULL; return (virObjectPtr) priv; } static void qemuDomainChrSourcePrivateDispose(void *obj) { qemuDomainChrSourcePrivatePtr priv = obj; qemuDomainSecretInfoFree(&priv->secinfo); } /* qemuDomainSecretPlainSetup: * @conn: Pointer to connection * @secinfo: Pointer to secret info * @usageType: The virSecretUsageType * @username: username to use for authentication (may be NULL) * @seclookupdef: Pointer to seclookupdef data * * Taking a secinfo, fill in the plaintext information * * Returns 0 on success, -1 on failure with error message */ static int qemuDomainSecretPlainSetup(virConnectPtr conn, qemuDomainSecretInfoPtr secinfo, virSecretUsageType usageType, const char *username, virSecretLookupTypeDefPtr seclookupdef) { secinfo->type = VIR_DOMAIN_SECRET_INFO_TYPE_PLAIN; if (VIR_STRDUP(secinfo->s.plain.username, username) < 0) return -1; return virSecretGetSecretString(conn, seclookupdef, usageType, &secinfo->s.plain.secret, &secinfo->s.plain.secretlen); } /* qemuDomainSecretAESSetup: * @conn: Pointer to connection * @priv: pointer to domain private object * @secinfo: Pointer to secret info * @srcalias: Alias of the disk/hostdev used to generate the secret alias * @usageType: The virSecretUsageType * @username: username to use for authentication (may be NULL) * @seclookupdef: Pointer to seclookupdef data * @isLuks: True/False for is for luks (alias generation) * * Taking a secinfo, fill in the AES specific information using the * * Returns 0 on success, -1 on failure with error message */ static int qemuDomainSecretAESSetup(virConnectPtr conn, qemuDomainObjPrivatePtr priv, qemuDomainSecretInfoPtr secinfo, const char *srcalias, virSecretUsageType usageType, const char *username, virSecretLookupTypeDefPtr seclookupdef, bool isLuks) { int ret = -1; uint8_t *raw_iv = NULL; size_t ivlen = QEMU_DOMAIN_AES_IV_LEN; uint8_t *secret = NULL; size_t secretlen = 0; uint8_t *ciphertext = NULL; size_t ciphertextlen = 0; secinfo->type = VIR_DOMAIN_SECRET_INFO_TYPE_AES; if (VIR_STRDUP(secinfo->s.aes.username, username) < 0) return -1; if (!(secinfo->s.aes.alias = qemuDomainGetSecretAESAlias(srcalias, isLuks))) return -1; /* Create a random initialization vector */ if (!(raw_iv = virCryptoGenerateRandom(ivlen))) return -1; /* Encode the IV and save that since qemu will need it */ if (!(secinfo->s.aes.iv = virStringEncodeBase64(raw_iv, ivlen))) goto cleanup; /* Grab the unencoded secret */ if (virSecretGetSecretString(conn, seclookupdef, usageType, &secret, &secretlen) < 0) goto cleanup; if (virCryptoEncryptData(VIR_CRYPTO_CIPHER_AES256CBC, priv->masterKey, QEMU_DOMAIN_MASTER_KEY_LEN, raw_iv, ivlen, secret, secretlen, &ciphertext, &ciphertextlen) < 0) goto cleanup; /* Clear out the secret */ memset(secret, 0, secretlen); /* Now encode the ciphertext and store to be passed to qemu */ if (!(secinfo->s.aes.ciphertext = virStringEncodeBase64(ciphertext, ciphertextlen))) goto cleanup; ret = 0; cleanup: VIR_DISPOSE_N(raw_iv, ivlen); VIR_DISPOSE_N(secret, secretlen); VIR_DISPOSE_N(ciphertext, ciphertextlen); return ret; } /* qemuDomainSecretSetup: * @conn: Pointer to connection * @priv: pointer to domain private object * @secinfo: Pointer to secret info * @srcalias: Alias of the disk/hostdev used to generate the secret alias * @usageType: The virSecretUsageType * @username: username to use for authentication (may be NULL) * @seclookupdef: Pointer to seclookupdef data * @isLuks: True when is luks (generates different alias) * * If we have the encryption API present and can support a secret object, then * build the AES secret; otherwise, build the Plain secret. This is the magic * decision point for utilizing the AES secrets for an RBD disk. For now iSCSI * disks and hostdevs will not be able to utilize this mechanism. * * Returns 0 on success, -1 on failure */ static int qemuDomainSecretSetup(virConnectPtr conn, qemuDomainObjPrivatePtr priv, qemuDomainSecretInfoPtr secinfo, const char *srcalias, virSecretUsageType usageType, const char *username, virSecretLookupTypeDefPtr seclookupdef, bool isLuks) { bool iscsiHasPS = virQEMUCapsGet(priv->qemuCaps, QEMU_CAPS_ISCSI_PASSWORD_SECRET); if (virCryptoHaveCipher(VIR_CRYPTO_CIPHER_AES256CBC) && virQEMUCapsGet(priv->qemuCaps, QEMU_CAPS_OBJECT_SECRET) && (usageType == VIR_SECRET_USAGE_TYPE_CEPH || (usageType == VIR_SECRET_USAGE_TYPE_ISCSI && iscsiHasPS) || usageType == VIR_SECRET_USAGE_TYPE_VOLUME || usageType == VIR_SECRET_USAGE_TYPE_TLS)) { if (qemuDomainSecretAESSetup(conn, priv, secinfo, srcalias, usageType, username, seclookupdef, isLuks) < 0) return -1; } else { if (qemuDomainSecretPlainSetup(conn, secinfo, usageType, username, seclookupdef) < 0) return -1; } return 0; } /* qemuDomainSecretInfoNew: * @conn: Pointer to connection * @priv: pointer to domain private object * @srcAlias: Alias base to use for TLS object * @usageType: Secret usage type * @username: username for plain secrets (only) * @looupdef: lookup def describing secret * @isLuks: boolean for luks lookup * * Helper function to create a secinfo to be used for secinfo consumers * * Returns @secinfo on success, NULL on failure. Caller is responsible * to eventually free @secinfo. */ static qemuDomainSecretInfoPtr qemuDomainSecretInfoNew(virConnectPtr conn, qemuDomainObjPrivatePtr priv, const char *srcAlias, virSecretUsageType usageType, const char *username, virSecretLookupTypeDefPtr lookupDef, bool isLuks) { qemuDomainSecretInfoPtr secinfo = NULL; if (VIR_ALLOC(secinfo) < 0) return NULL; if (qemuDomainSecretSetup(conn, priv, secinfo, srcAlias, usageType, username, lookupDef, isLuks) < 0) goto error; if (!username && secinfo->type == VIR_DOMAIN_SECRET_INFO_TYPE_PLAIN) { virReportError(VIR_ERR_CONFIG_UNSUPPORTED, "%s", _("encrypted secrets are not supported")); goto error; } return secinfo; error: qemuDomainSecretInfoFree(&secinfo); return NULL; } /** * qemuDomainSecretInfoTLSNew: * @conn: Pointer to connection * @priv: pointer to domain private object * @srcAlias: Alias base to use for TLS object * @secretUUID: Provide a secretUUID value to look up/create the secretInfo * * Using the passed @secretUUID, generate a seclookupdef that can be used * to generate the returned qemuDomainSecretInfoPtr for a TLS based secret. * * Returns qemuDomainSecretInfoPtr or NULL on error. */ qemuDomainSecretInfoPtr qemuDomainSecretInfoTLSNew(virConnectPtr conn, qemuDomainObjPrivatePtr priv, const char *srcAlias, const char *secretUUID) { virSecretLookupTypeDef seclookupdef = {0}; if (virUUIDParse(secretUUID, seclookupdef.u.uuid) < 0) { virReportError(VIR_ERR_CONFIG_UNSUPPORTED, _("malformed TLS secret uuid '%s' provided"), secretUUID); return NULL; } seclookupdef.type = VIR_SECRET_LOOKUP_TYPE_UUID; return qemuDomainSecretInfoNew(conn, priv, srcAlias, VIR_SECRET_USAGE_TYPE_TLS, NULL, &seclookupdef, false); } static void qemuDomainSecretStorageSourceDestroy(virStorageSourcePtr src) { qemuDomainStorageSourcePrivatePtr srcPriv = QEMU_DOMAIN_STORAGE_SOURCE_PRIVATE(src); if (srcPriv && srcPriv->secinfo) qemuDomainSecretInfoFree(&srcPriv->secinfo); if (srcPriv && srcPriv->encinfo) qemuDomainSecretInfoFree(&srcPriv->encinfo); } /* qemuDomainSecretDiskDestroy: * @disk: Pointer to a disk definition * * Clear and destroy memory associated with the secret */ void qemuDomainSecretDiskDestroy(virDomainDiskDefPtr disk) { virStorageSourcePtr next; for (next = disk->src; virStorageSourceIsBacking(next); next = next->backingStore) qemuDomainSecretStorageSourceDestroy(next); } bool qemuDomainSecretDiskCapable(virStorageSourcePtr src) { if (!virStorageSourceIsEmpty(src) && virStorageSourceGetActualType(src) == VIR_STORAGE_TYPE_NETWORK && src->auth && (src->protocol == VIR_STORAGE_NET_PROTOCOL_ISCSI || src->protocol == VIR_STORAGE_NET_PROTOCOL_RBD)) return true; return false; } bool qemuDomainDiskHasEncryptionSecret(virStorageSourcePtr src) { if (!virStorageSourceIsEmpty(src) && src->encryption && src->encryption->format == VIR_STORAGE_ENCRYPTION_FORMAT_LUKS && src->encryption->nsecrets > 0) return true; return false; } /** * qemuDomainSecretStorageSourcePrepare: * @conn: connection object - for secret lookup * @priv: domain private object * @src: storage source struct to setup * @authalias: prefix of the alias for secret holding authentication data * @encalias: prefix of the alias for secret holding encryption password * * Prepares data necessary for encryption and authentication of @src. The two * alias prefixes are provided since in the backing chain authentication belongs * to the storage protocol data whereas encryption is relevant to the format * driver in qemu. The two will have different node names. * * Returns 0 on success; -1 on error while reporting an libvirt error. */ static int qemuDomainSecretStorageSourcePrepare(virConnectPtr conn, qemuDomainObjPrivatePtr priv, virStorageSourcePtr src, const char *authalias, const char *encalias) { qemuDomainStorageSourcePrivatePtr srcPriv; bool hasAuth = qemuDomainSecretDiskCapable(src); bool hasEnc = qemuDomainDiskHasEncryptionSecret(src); if (!hasAuth && !hasEnc) return 0; if (!(src->privateData = qemuDomainStorageSourcePrivateNew())) return -1; srcPriv = QEMU_DOMAIN_STORAGE_SOURCE_PRIVATE(src); if (hasAuth) { virSecretUsageType usageType = VIR_SECRET_USAGE_TYPE_ISCSI; if (src->protocol == VIR_STORAGE_NET_PROTOCOL_RBD) usageType = VIR_SECRET_USAGE_TYPE_CEPH; if (!(srcPriv->secinfo = qemuDomainSecretInfoNew(conn, priv, authalias, usageType, src->auth->username, &src->auth->seclookupdef, false))) return -1; } if (hasEnc) { if (!(srcPriv->encinfo = qemuDomainSecretInfoNew(conn, priv, encalias, VIR_SECRET_USAGE_TYPE_VOLUME, NULL, &src->encryption->secrets[0]->seclookupdef, true))) return -1; } return 0; } /* qemuDomainSecretDiskPrepare: * @conn: Pointer to connection * @priv: pointer to domain private object * @disk: Pointer to a disk definition * * For the right disk, generate the qemuDomainSecretInfo structure. * * Returns 0 on success, -1 on failure */ static int qemuDomainSecretDiskPrepare(virConnectPtr conn, qemuDomainObjPrivatePtr priv, virDomainDiskDefPtr disk) { return qemuDomainSecretStorageSourcePrepare(conn, priv, disk->src, disk->info.alias, disk->info.alias); } /* qemuDomainSecretHostdevDestroy: * @disk: Pointer to a hostdev definition * * Clear and destroy memory associated with the secret */ void qemuDomainSecretHostdevDestroy(virDomainHostdevDefPtr hostdev) { qemuDomainStorageSourcePrivatePtr srcPriv; if (virHostdevIsSCSIDevice(hostdev)) { virDomainHostdevSubsysSCSIPtr scsisrc = &hostdev->source.subsys.u.scsi; virDomainHostdevSubsysSCSIiSCSIPtr iscsisrc = &scsisrc->u.iscsi; if (scsisrc->protocol == VIR_DOMAIN_HOSTDEV_SCSI_PROTOCOL_TYPE_ISCSI) { srcPriv = QEMU_DOMAIN_STORAGE_SOURCE_PRIVATE(iscsisrc->src); if (srcPriv && srcPriv->secinfo) qemuDomainSecretInfoFree(&srcPriv->secinfo); } } } /* qemuDomainSecretHostdevPrepare: * @conn: Pointer to connection * @priv: pointer to domain private object * @hostdev: Pointer to a hostdev definition * * For the right host device, generate the qemuDomainSecretInfo structure. * * Returns 0 on success, -1 on failure */ int qemuDomainSecretHostdevPrepare(virConnectPtr conn, qemuDomainObjPrivatePtr priv, virDomainHostdevDefPtr hostdev) { if (virHostdevIsSCSIDevice(hostdev)) { virDomainHostdevSubsysSCSIPtr scsisrc = &hostdev->source.subsys.u.scsi; virDomainHostdevSubsysSCSIiSCSIPtr iscsisrc = &scsisrc->u.iscsi; virStorageSourcePtr src = iscsisrc->src; qemuDomainStorageSourcePrivatePtr srcPriv; if (scsisrc->protocol == VIR_DOMAIN_HOSTDEV_SCSI_PROTOCOL_TYPE_ISCSI && src->auth) { if (!(src->privateData = qemuDomainStorageSourcePrivateNew())) return -1; srcPriv = QEMU_DOMAIN_STORAGE_SOURCE_PRIVATE(src); if (!(srcPriv->secinfo = qemuDomainSecretInfoNew(conn, priv, hostdev->info->alias, VIR_SECRET_USAGE_TYPE_ISCSI, src->auth->username, &src->auth->seclookupdef, false))) return -1; } } return 0; } /* qemuDomainSecretChardevDestroy: * @disk: Pointer to a chardev definition * * Clear and destroy memory associated with the secret */ void qemuDomainSecretChardevDestroy(virDomainChrSourceDefPtr dev) { qemuDomainChrSourcePrivatePtr chrSourcePriv = QEMU_DOMAIN_CHR_SOURCE_PRIVATE(dev); if (!chrSourcePriv || !chrSourcePriv->secinfo) return; qemuDomainSecretInfoFree(&chrSourcePriv->secinfo); } /* qemuDomainSecretChardevPrepare: * @conn: Pointer to connection * @cfg: Pointer to driver config object * @priv: pointer to domain private object * @chrAlias: Alias of the chr device * @dev: Pointer to a char source definition * * For a TCP character device, generate a qemuDomainSecretInfo to be used * by the command line code to generate the secret for the tls-creds to use. * * Returns 0 on success, -1 on failure */ int qemuDomainSecretChardevPrepare(virConnectPtr conn, virQEMUDriverConfigPtr cfg, qemuDomainObjPrivatePtr priv, const char *chrAlias, virDomainChrSourceDefPtr dev) { char *charAlias = NULL; if (dev->type != VIR_DOMAIN_CHR_TYPE_TCP) return 0; if (dev->data.tcp.haveTLS == VIR_TRISTATE_BOOL_YES && cfg->chardevTLSx509secretUUID) { qemuDomainChrSourcePrivatePtr chrSourcePriv = QEMU_DOMAIN_CHR_SOURCE_PRIVATE(dev); if (!(charAlias = qemuAliasChardevFromDevAlias(chrAlias))) return -1; chrSourcePriv->secinfo = qemuDomainSecretInfoTLSNew(conn, priv, charAlias, cfg->chardevTLSx509secretUUID); VIR_FREE(charAlias); if (!chrSourcePriv->secinfo) return -1; } return 0; } /* qemuDomainSecretDestroy: * @vm: Domain object * * Once completed with the generation of the command line it is * expect to remove the secrets */ void qemuDomainSecretDestroy(virDomainObjPtr vm) { size_t i; for (i = 0; i < vm->def->ndisks; i++) qemuDomainSecretDiskDestroy(vm->def->disks[i]); for (i = 0; i < vm->def->nhostdevs; i++) qemuDomainSecretHostdevDestroy(vm->def->hostdevs[i]); for (i = 0; i < vm->def->nserials; i++) qemuDomainSecretChardevDestroy(vm->def->serials[i]->source); for (i = 0; i < vm->def->nparallels; i++) qemuDomainSecretChardevDestroy(vm->def->parallels[i]->source); for (i = 0; i < vm->def->nchannels; i++) qemuDomainSecretChardevDestroy(vm->def->channels[i]->source); for (i = 0; i < vm->def->nconsoles; i++) qemuDomainSecretChardevDestroy(vm->def->consoles[i]->source); for (i = 0; i < vm->def->nsmartcards; i++) { if (vm->def->smartcards[i]->type == VIR_DOMAIN_SMARTCARD_TYPE_PASSTHROUGH) qemuDomainSecretChardevDestroy(vm->def->smartcards[i]->data.passthru); } for (i = 0; i < vm->def->nrngs; i++) { if (vm->def->rngs[i]->backend == VIR_DOMAIN_RNG_BACKEND_EGD) qemuDomainSecretChardevDestroy(vm->def->rngs[i]->source.chardev); } for (i = 0; i < vm->def->nredirdevs; i++) qemuDomainSecretChardevDestroy(vm->def->redirdevs[i]->source); } /* qemuDomainSecretPrepare: * @conn: Pointer to connection * @driver: Pointer to driver object * @vm: Domain object * * For any objects that may require an auth/secret setup, create a * qemuDomainSecretInfo and save it in the approriate place within * the private structures. This will be used by command line build * code in order to pass the secret along to qemu in order to provide * the necessary authentication data. * * Returns 0 on success, -1 on failure with error message set */ int qemuDomainSecretPrepare(virConnectPtr conn, virQEMUDriverPtr driver, virDomainObjPtr vm) { qemuDomainObjPrivatePtr priv = vm->privateData; virQEMUDriverConfigPtr cfg = virQEMUDriverGetConfig(driver); size_t i; int ret = -1; /* disk secrets are prepared when preparing disks */ for (i = 0; i < vm->def->nhostdevs; i++) { if (qemuDomainSecretHostdevPrepare(conn, priv, vm->def->hostdevs[i]) < 0) goto cleanup; } for (i = 0; i < vm->def->nserials; i++) { if (qemuDomainSecretChardevPrepare(conn, cfg, priv, vm->def->serials[i]->info.alias, vm->def->serials[i]->source) < 0) goto cleanup; } for (i = 0; i < vm->def->nparallels; i++) { if (qemuDomainSecretChardevPrepare(conn, cfg, priv, vm->def->parallels[i]->info.alias, vm->def->parallels[i]->source) < 0) goto cleanup; } for (i = 0; i < vm->def->nchannels; i++) { if (qemuDomainSecretChardevPrepare(conn, cfg, priv, vm->def->channels[i]->info.alias, vm->def->channels[i]->source) < 0) goto cleanup; } for (i = 0; i < vm->def->nconsoles; i++) { if (qemuDomainSecretChardevPrepare(conn, cfg, priv, vm->def->consoles[i]->info.alias, vm->def->consoles[i]->source) < 0) goto cleanup; } for (i = 0; i < vm->def->nsmartcards; i++) if (vm->def->smartcards[i]->type == VIR_DOMAIN_SMARTCARD_TYPE_PASSTHROUGH && qemuDomainSecretChardevPrepare(conn, cfg, priv, vm->def->smartcards[i]->info.alias, vm->def->smartcards[i]->data.passthru) < 0) goto cleanup; for (i = 0; i < vm->def->nrngs; i++) { if (vm->def->rngs[i]->backend == VIR_DOMAIN_RNG_BACKEND_EGD && qemuDomainSecretChardevPrepare(conn, cfg, priv, vm->def->rngs[i]->info.alias, vm->def->rngs[i]->source.chardev) < 0) goto cleanup; } for (i = 0; i < vm->def->nredirdevs; i++) { if (qemuDomainSecretChardevPrepare(conn, cfg, priv, vm->def->redirdevs[i]->info.alias, vm->def->redirdevs[i]->source) < 0) goto cleanup; } ret = 0; cleanup: virObjectUnref(cfg); return ret; } /* This is the old way of setting up per-domain directories */ static int qemuDomainSetPrivatePathsOld(virQEMUDriverPtr driver, virDomainObjPtr vm) { qemuDomainObjPrivatePtr priv = vm->privateData; virQEMUDriverConfigPtr cfg = virQEMUDriverGetConfig(driver); int ret = -1; if (!priv->libDir && virAsprintf(&priv->libDir, "%s/domain-%s", cfg->libDir, vm->def->name) < 0) goto cleanup; if (!priv->channelTargetDir && virAsprintf(&priv->channelTargetDir, "%s/domain-%s", cfg->channelTargetDir, vm->def->name) < 0) goto cleanup; ret = 0; cleanup: virObjectUnref(cfg); return ret; } int qemuDomainSetPrivatePaths(virQEMUDriverPtr driver, virDomainObjPtr vm) { virQEMUDriverConfigPtr cfg = virQEMUDriverGetConfig(driver); qemuDomainObjPrivatePtr priv = vm->privateData; char *domname = virDomainDefGetShortName(vm->def); int ret = -1; if (!domname) goto cleanup; if (!priv->libDir && virAsprintf(&priv->libDir, "%s/domain-%s", cfg->libDir, domname) < 0) goto cleanup; if (!priv->channelTargetDir && virAsprintf(&priv->channelTargetDir, "%s/domain-%s", cfg->channelTargetDir, domname) < 0) goto cleanup; ret = 0; cleanup: virObjectUnref(cfg); VIR_FREE(domname); return ret; } static void * qemuDomainObjPrivateAlloc(void *opaque) { qemuDomainObjPrivatePtr priv; if (VIR_ALLOC(priv) < 0) return NULL; if (qemuDomainObjInitJob(priv) < 0) { virReportSystemError(errno, "%s", _("Unable to init qemu driver mutexes")); goto error; } if (!(priv->devs = virChrdevAlloc())) goto error; priv->migMaxBandwidth = QEMU_DOMAIN_MIG_BANDWIDTH_MAX; priv->driver = opaque; return priv; error: VIR_FREE(priv); return NULL; } /** * qemuDomainObjPrivateDataClear: * @priv: domain private data * * Clears private data entries, which are not necessary or stale if the VM is * not running. */ void qemuDomainObjPrivateDataClear(qemuDomainObjPrivatePtr priv) { virStringListFree(priv->qemuDevices); priv->qemuDevices = NULL; virCgroupFree(&priv->cgroup); virPerfFree(priv->perf); priv->perf = NULL; VIR_FREE(priv->machineName); virObjectUnref(priv->qemuCaps); priv->qemuCaps = NULL; VIR_FREE(priv->pidfile); VIR_FREE(priv->libDir); VIR_FREE(priv->channelTargetDir); /* remove automatic pinning data */ virBitmapFree(priv->autoNodeset); priv->autoNodeset = NULL; virBitmapFree(priv->autoCpuset); priv->autoCpuset = NULL; /* remove address data */ virDomainPCIAddressSetFree(priv->pciaddrs); priv->pciaddrs = NULL; virDomainUSBAddressSetFree(priv->usbaddrs); priv->usbaddrs = NULL; /* clean up migration data */ VIR_FREE(priv->migTLSAlias); virCPUDefFree(priv->origCPU); priv->origCPU = NULL; /* clear previously used namespaces */ virBitmapFree(priv->namespaces); priv->namespaces = NULL; priv->reconnectBlockjobs = VIR_TRISTATE_BOOL_ABSENT; priv->allowReboot = VIR_TRISTATE_BOOL_ABSENT; virBitmapFree(priv->migrationCaps); priv->migrationCaps = NULL; } static void qemuDomainObjPrivateFree(void *data) { qemuDomainObjPrivatePtr priv = data; qemuDomainObjPrivateDataClear(priv); virDomainChrSourceDefFree(priv->monConfig); qemuDomainObjFreeJob(priv); VIR_FREE(priv->lockState); VIR_FREE(priv->origname); virChrdevFree(priv->devs); /* This should never be non-NULL if we get here, but just in case... */ if (priv->mon) { VIR_ERROR(_("Unexpected QEMU monitor still active during domain deletion")); qemuMonitorClose(priv->mon); } if (priv->agent) { VIR_ERROR(_("Unexpected QEMU agent still active during domain deletion")); qemuAgentClose(priv->agent); } VIR_FREE(priv->cleanupCallbacks); qemuDomainSecretInfoFree(&priv->migSecinfo); qemuDomainMasterKeyFree(priv); VIR_FREE(priv); } static void qemuDomainObjPrivateXMLFormatVcpus(virBufferPtr buf, virDomainDefPtr def) { size_t i; size_t maxvcpus = virDomainDefGetVcpusMax(def); virDomainVcpuDefPtr vcpu; pid_t tid; virBufferAddLit(buf, "\n"); virBufferAdjustIndent(buf, 2); for (i = 0; i < maxvcpus; i++) { vcpu = virDomainDefGetVcpu(def, i); tid = QEMU_DOMAIN_VCPU_PRIVATE(vcpu)->tid; if (!vcpu->online || tid == 0) continue; virBufferAsprintf(buf, "\n", i, tid); } virBufferAdjustIndent(buf, -2); virBufferAddLit(buf, "\n"); } static int qemuDomainObjPrivateXMLFormatAutomaticPlacement(virBufferPtr buf, qemuDomainObjPrivatePtr priv) { char *nodeset = NULL; char *cpuset = NULL; int ret = -1; if (!priv->autoNodeset && !priv->autoCpuset) return 0; if (priv->autoNodeset && !((nodeset = virBitmapFormat(priv->autoNodeset)))) goto cleanup; if (priv->autoCpuset && !((cpuset = virBitmapFormat(priv->autoCpuset)))) goto cleanup; virBufferAddLit(buf, "\n"); ret = 0; cleanup: VIR_FREE(nodeset); VIR_FREE(cpuset); return ret; } static int qemuDomainObjPrivateXMLFormatBlockjobs(virBufferPtr buf, virDomainObjPtr vm) { virBuffer attrBuf = VIR_BUFFER_INITIALIZER; bool bj = qemuDomainHasBlockjob(vm, false); virBufferAsprintf(&attrBuf, " active='%s'", virTristateBoolTypeToString(virTristateBoolFromBool(bj))); return virXMLFormatElement(buf, "blockjobs", &attrBuf, NULL); } void qemuDomainObjPrivateXMLFormatAllowReboot(virBufferPtr buf, virTristateBool allowReboot) { virBufferAsprintf(buf, "\n", virTristateBoolTypeToString(allowReboot)); } static int qemuDomainObjPrivateXMLFormat(virBufferPtr buf, virDomainObjPtr vm) { qemuDomainObjPrivatePtr priv = vm->privateData; const char *monitorpath; qemuDomainJob job; /* priv->monitor_chr is set only for qemu */ if (priv->monConfig) { switch (priv->monConfig->type) { case VIR_DOMAIN_CHR_TYPE_UNIX: monitorpath = priv->monConfig->data.nix.path; break; default: case VIR_DOMAIN_CHR_TYPE_PTY: monitorpath = priv->monConfig->data.file.path; break; } virBufferEscapeString(buf, "monJSON) virBufferAddLit(buf, " json='1'"); virBufferAsprintf(buf, " type='%s'/>\n", virDomainChrTypeToString(priv->monConfig->type)); } if (priv->namespaces) { ssize_t ns = -1; virBufferAddLit(buf, "\n"); virBufferAdjustIndent(buf, 2); while ((ns = virBitmapNextSetBit(priv->namespaces, ns)) >= 0) virBufferAsprintf(buf, "<%s/>\n", qemuDomainNamespaceTypeToString(ns)); virBufferAdjustIndent(buf, -2); virBufferAddLit(buf, "\n"); } qemuDomainObjPrivateXMLFormatVcpus(buf, vm->def); if (priv->qemuCaps) { size_t i; virBufferAddLit(buf, "\n"); virBufferAdjustIndent(buf, 2); for (i = 0; i < QEMU_CAPS_LAST; i++) { if (virQEMUCapsGet(priv->qemuCaps, i)) { virBufferAsprintf(buf, "\n", virQEMUCapsTypeToString(i)); } } virBufferAdjustIndent(buf, -2); virBufferAddLit(buf, "\n"); } if (priv->lockState) virBufferAsprintf(buf, "%s\n", priv->lockState); job = priv->job.active; if (!qemuDomainTrackJob(job)) priv->job.active = QEMU_JOB_NONE; if (priv->job.active || priv->job.asyncJob) { virBufferAsprintf(buf, "job.active), qemuDomainAsyncJobTypeToString(priv->job.asyncJob)); if (priv->job.phase) { virBufferAsprintf(buf, " phase='%s'", qemuDomainAsyncJobPhaseToString( priv->job.asyncJob, priv->job.phase)); } if (priv->job.asyncJob != QEMU_ASYNC_JOB_MIGRATION_OUT) { virBufferAddLit(buf, "/>\n"); } else { size_t i; virDomainDiskDefPtr disk; qemuDomainDiskPrivatePtr diskPriv; virBufferAddLit(buf, ">\n"); virBufferAdjustIndent(buf, 2); for (i = 0; i < vm->def->ndisks; i++) { disk = vm->def->disks[i]; diskPriv = QEMU_DOMAIN_DISK_PRIVATE(disk); virBufferAsprintf(buf, "\n", disk->dst, diskPriv->migrating ? "yes" : "no"); } virBufferAdjustIndent(buf, -2); virBufferAddLit(buf, "\n"); } } priv->job.active = job; if (priv->fakeReboot) virBufferAddLit(buf, "\n"); if (priv->qemuDevices && *priv->qemuDevices) { char **tmp = priv->qemuDevices; virBufferAddLit(buf, "\n"); virBufferAdjustIndent(buf, 2); while (*tmp) { virBufferAsprintf(buf, "\n", *tmp); tmp++; } virBufferAdjustIndent(buf, -2); virBufferAddLit(buf, "\n"); } if (qemuDomainObjPrivateXMLFormatAutomaticPlacement(buf, priv) < 0) return -1; /* Various per-domain paths */ virBufferEscapeString(buf, "\n", priv->libDir); virBufferEscapeString(buf, "\n", priv->channelTargetDir); virCPUDefFormatBufFull(buf, priv->origCPU, NULL); if (priv->chardevStdioLogd) virBufferAddLit(buf, "\n"); qemuDomainObjPrivateXMLFormatAllowReboot(buf, priv->allowReboot); if (qemuDomainObjPrivateXMLFormatBlockjobs(buf, vm) < 0) return -1; return 0; } static int qemuDomainObjPrivateXMLParseVcpu(xmlNodePtr node, unsigned int idx, virDomainDefPtr def) { virDomainVcpuDefPtr vcpu; char *idstr; char *pidstr; unsigned int tmp; int ret = -1; idstr = virXMLPropString(node, "id"); if (idstr && (virStrToLong_uip(idstr, NULL, 10, &idx) < 0)) { virReportError(VIR_ERR_INTERNAL_ERROR, _("cannot parse vcpu index '%s'"), idstr); goto cleanup; } if (!(vcpu = virDomainDefGetVcpu(def, idx))) { virReportError(VIR_ERR_INTERNAL_ERROR, _("invalid vcpu index '%u'"), idx); goto cleanup; } if (!(pidstr = virXMLPropString(node, "pid"))) goto cleanup; if (virStrToLong_uip(pidstr, NULL, 10, &tmp) < 0) goto cleanup; QEMU_DOMAIN_VCPU_PRIVATE(vcpu)->tid = tmp; ret = 0; cleanup: VIR_FREE(idstr); VIR_FREE(pidstr); return ret; } static int qemuDomainObjPrivateXMLParseAutomaticPlacement(xmlXPathContextPtr ctxt, qemuDomainObjPrivatePtr priv, virQEMUDriverPtr driver) { virCapsPtr caps = NULL; char *nodeset; char *cpuset; int ret = -1; nodeset = virXPathString("string(./numad/@nodeset)", ctxt); cpuset = virXPathString("string(./numad/@cpuset)", ctxt); if (!nodeset && !cpuset) return 0; if (!(caps = virQEMUDriverGetCapabilities(driver, false))) goto cleanup; if (nodeset && virBitmapParse(nodeset, &priv->autoNodeset, caps->host.nnumaCell_max) < 0) goto cleanup; if (cpuset) { if (virBitmapParse(cpuset, &priv->autoCpuset, VIR_DOMAIN_CPUMASK_LEN) < 0) goto cleanup; } else { /* autoNodeset is present in this case, since otherwise we wouldn't * reach this code */ if (!(priv->autoCpuset = virCapabilitiesGetCpusForNodemask(caps, priv->autoNodeset))) goto cleanup; } ret = 0; cleanup: virObjectUnref(caps); VIR_FREE(nodeset); VIR_FREE(cpuset); return ret; } static int qemuDomainObjPrivateXMLParseBlockjobs(qemuDomainObjPrivatePtr priv, xmlXPathContextPtr ctxt) { char *active; int tmp; if ((active = virXPathString("string(./blockjobs/@active)", ctxt)) && (tmp = virTristateBoolTypeFromString(active)) > 0) priv->reconnectBlockjobs = tmp; VIR_FREE(active); return 0; } int qemuDomainObjPrivateXMLParseAllowReboot(xmlXPathContextPtr ctxt, virTristateBool *allowReboot) { int ret = -1; int val; char *valStr; if ((valStr = virXPathString("string(./allowReboot/@value)", ctxt))) { if ((val = virTristateBoolTypeFromString(valStr)) < 0) { virReportError(VIR_ERR_INTERNAL_ERROR, _("invalid allowReboot value '%s'"), valStr); goto cleanup; } *allowReboot = val; } ret = 0; cleanup: VIR_FREE(valStr); return ret; } static int qemuDomainObjPrivateXMLParse(xmlXPathContextPtr ctxt, virDomainObjPtr vm, virDomainDefParserConfigPtr config) { qemuDomainObjPrivatePtr priv = vm->privateData; virQEMUDriverPtr driver = config->priv; char *monitorpath; char *tmp = NULL; int n; size_t i; xmlNodePtr *nodes = NULL; xmlNodePtr node = NULL; virQEMUCapsPtr qemuCaps = NULL; if (VIR_ALLOC(priv->monConfig) < 0) goto error; if (!(monitorpath = virXPathString("string(./monitor[1]/@path)", ctxt))) { virReportError(VIR_ERR_INTERNAL_ERROR, "%s", _("no monitor path")); goto error; } tmp = virXPathString("string(./monitor[1]/@type)", ctxt); if (tmp) priv->monConfig->type = virDomainChrTypeFromString(tmp); else priv->monConfig->type = VIR_DOMAIN_CHR_TYPE_PTY; VIR_FREE(tmp); priv->monJSON = virXPathBoolean("count(./monitor[@json = '1']) > 0", ctxt) > 0; switch (priv->monConfig->type) { case VIR_DOMAIN_CHR_TYPE_PTY: priv->monConfig->data.file.path = monitorpath; break; case VIR_DOMAIN_CHR_TYPE_UNIX: priv->monConfig->data.nix.path = monitorpath; break; default: VIR_FREE(monitorpath); virReportError(VIR_ERR_INTERNAL_ERROR, _("unsupported monitor type '%s'"), virDomainChrTypeToString(priv->monConfig->type)); goto error; } if ((node = virXPathNode("./namespaces", ctxt))) { xmlNodePtr next; for (next = node->children; next; next = next->next) { int ns = qemuDomainNamespaceTypeFromString((const char *) next->name); if (ns < 0) { virReportError(VIR_ERR_INTERNAL_ERROR, _("malformed namespace name: %s"), next->name); goto error; } if (qemuDomainEnableNamespace(vm, ns) < 0) goto error; } } if (priv->namespaces && virBitmapIsAllClear(priv->namespaces)) { virBitmapFree(priv->namespaces); priv->namespaces = NULL; } if ((n = virXPathNodeSet("./vcpus/vcpu", ctxt, &nodes)) < 0) goto error; for (i = 0; i < n; i++) { if (qemuDomainObjPrivateXMLParseVcpu(nodes[i], i, vm->def) < 0) goto error; } VIR_FREE(nodes); if ((n = virXPathNodeSet("./qemuCaps/flag", ctxt, &nodes)) < 0) { virReportError(VIR_ERR_INTERNAL_ERROR, "%s", _("failed to parse qemu capabilities flags")); goto error; } if (n > 0) { if (!(qemuCaps = virQEMUCapsNew())) goto error; for (i = 0; i < n; i++) { char *str = virXMLPropString(nodes[i], "name"); if (str) { int flag = virQEMUCapsTypeFromString(str); if (flag < 0) { virReportError(VIR_ERR_INTERNAL_ERROR, _("Unknown qemu capabilities flag %s"), str); VIR_FREE(str); goto error; } VIR_FREE(str); virQEMUCapsSet(qemuCaps, flag); } } priv->qemuCaps = qemuCaps; qemuCaps = NULL; } VIR_FREE(nodes); priv->lockState = virXPathString("string(./lockstate)", ctxt); if ((tmp = virXPathString("string(./job[1]/@type)", ctxt))) { int type; if ((type = qemuDomainJobTypeFromString(tmp)) < 0) { virReportError(VIR_ERR_INTERNAL_ERROR, _("Unknown job type %s"), tmp); VIR_FREE(tmp); goto error; } VIR_FREE(tmp); priv->job.active = type; } if ((tmp = virXPathString("string(./job[1]/@async)", ctxt))) { int async; if ((async = qemuDomainAsyncJobTypeFromString(tmp)) < 0) { virReportError(VIR_ERR_INTERNAL_ERROR, _("Unknown async job type %s"), tmp); VIR_FREE(tmp); goto error; } VIR_FREE(tmp); priv->job.asyncJob = async; if ((tmp = virXPathString("string(./job[1]/@phase)", ctxt))) { priv->job.phase = qemuDomainAsyncJobPhaseFromString(async, tmp); if (priv->job.phase < 0) { virReportError(VIR_ERR_INTERNAL_ERROR, _("Unknown job phase %s"), tmp); VIR_FREE(tmp); goto error; } VIR_FREE(tmp); } } if ((n = virXPathNodeSet("./job[1]/disk[@migrating='yes']", ctxt, &nodes)) < 0) { virReportError(VIR_ERR_INTERNAL_ERROR, "%s", _("failed to parse list of disks marked for migration")); goto error; } if (n > 0) { if (priv->job.asyncJob != QEMU_ASYNC_JOB_MIGRATION_OUT) { VIR_WARN("Found disks marked for migration but we were not " "migrating"); n = 0; } for (i = 0; i < n; i++) { char *dst = virXMLPropString(nodes[i], "dev"); virDomainDiskDefPtr disk; if (dst && (disk = virDomainDiskByName(vm->def, dst, false))) QEMU_DOMAIN_DISK_PRIVATE(disk)->migrating = true; VIR_FREE(dst); } } VIR_FREE(nodes); priv->fakeReboot = virXPathBoolean("boolean(./fakereboot)", ctxt) == 1; if ((n = virXPathNodeSet("./devices/device", ctxt, &nodes)) < 0) { virReportError(VIR_ERR_INTERNAL_ERROR, "%s", _("failed to parse qemu device list")); goto error; } if (n > 0) { /* NULL-terminated list */ if (VIR_ALLOC_N(priv->qemuDevices, n + 1) < 0) goto error; for (i = 0; i < n; i++) { priv->qemuDevices[i] = virXMLPropString(nodes[i], "alias"); if (!priv->qemuDevices[i]) { virReportError(VIR_ERR_INTERNAL_ERROR, "%s", _("failed to parse qemu device list")); goto error; } } } VIR_FREE(nodes); if (qemuDomainObjPrivateXMLParseAutomaticPlacement(ctxt, priv, driver) < 0) goto error; if ((tmp = virXPathString("string(./libDir/@path)", ctxt))) priv->libDir = tmp; if ((tmp = virXPathString("string(./channelTargetDir/@path)", ctxt))) priv->channelTargetDir = tmp; tmp = NULL; if (qemuDomainSetPrivatePathsOld(driver, vm) < 0) goto error; if (virCPUDefParseXML(ctxt, "./cpu", VIR_CPU_TYPE_GUEST, &priv->origCPU) < 0) goto error; priv->chardevStdioLogd = virXPathBoolean("boolean(./chardevStdioLogd)", ctxt) == 1; qemuDomainObjPrivateXMLParseAllowReboot(ctxt, &priv->allowReboot); if (qemuDomainObjPrivateXMLParseBlockjobs(priv, ctxt) < 0) goto error; return 0; error: VIR_FREE(nodes); VIR_FREE(tmp); virBitmapFree(priv->namespaces); priv->namespaces = NULL; virDomainChrSourceDefFree(priv->monConfig); priv->monConfig = NULL; virStringListFree(priv->qemuDevices); priv->qemuDevices = NULL; virObjectUnref(qemuCaps); return -1; } virDomainXMLPrivateDataCallbacks virQEMUDriverPrivateDataCallbacks = { .alloc = qemuDomainObjPrivateAlloc, .free = qemuDomainObjPrivateFree, .diskNew = qemuDomainDiskPrivateNew, .vcpuNew = qemuDomainVcpuPrivateNew, .chrSourceNew = qemuDomainChrSourcePrivateNew, .parse = qemuDomainObjPrivateXMLParse, .format = qemuDomainObjPrivateXMLFormat, .storageParse = virStorageSourcePrivateDataParseRelPath, .storageFormat = virStorageSourcePrivateDataFormatRelPath, }; static void qemuDomainDefNamespaceFree(void *nsdata) { qemuDomainCmdlineDefPtr cmd = nsdata; qemuDomainCmdlineDefFree(cmd); } static int qemuDomainDefNamespaceParse(xmlDocPtr xml ATTRIBUTE_UNUSED, xmlNodePtr root ATTRIBUTE_UNUSED, xmlXPathContextPtr ctxt, void **data) { qemuDomainCmdlineDefPtr cmd = NULL; bool uses_qemu_ns = false; xmlNodePtr *nodes = NULL; int n; size_t i; if (xmlXPathRegisterNs(ctxt, BAD_CAST "qemu", BAD_CAST QEMU_NAMESPACE_HREF) < 0) { virReportError(VIR_ERR_INTERNAL_ERROR, _("Failed to register xml namespace '%s'"), QEMU_NAMESPACE_HREF); return -1; } if (VIR_ALLOC(cmd) < 0) return -1; /* first handle the extra command-line arguments */ n = virXPathNodeSet("./qemu:commandline/qemu:arg", ctxt, &nodes); if (n < 0) goto error; uses_qemu_ns |= n > 0; if (n && VIR_ALLOC_N(cmd->args, n) < 0) goto error; for (i = 0; i < n; i++) { cmd->args[cmd->num_args] = virXMLPropString(nodes[i], "value"); if (cmd->args[cmd->num_args] == NULL) { virReportError(VIR_ERR_INTERNAL_ERROR, "%s", _("No qemu command-line argument specified")); goto error; } cmd->num_args++; } VIR_FREE(nodes); /* now handle the extra environment variables */ n = virXPathNodeSet("./qemu:commandline/qemu:env", ctxt, &nodes); if (n < 0) goto error; uses_qemu_ns |= n > 0; if (n && VIR_ALLOC_N(cmd->env_name, n) < 0) goto error; if (n && VIR_ALLOC_N(cmd->env_value, n) < 0) goto error; for (i = 0; i < n; i++) { char *tmp; tmp = virXMLPropString(nodes[i], "name"); if (tmp == NULL) { virReportError(VIR_ERR_INTERNAL_ERROR, "%s", _("No qemu environment name specified")); goto error; } if (tmp[0] == '\0') { virReportError(VIR_ERR_INTERNAL_ERROR, "%s", _("Empty qemu environment name specified")); goto error; } if (!c_isalpha(tmp[0]) && tmp[0] != '_') { virReportError(VIR_ERR_INTERNAL_ERROR, "%s", _("Invalid environment name, it must begin with a letter or underscore")); goto error; } if (strspn(tmp, "ABCDEFGHIJKLMNOPQRSTUVWXYZabcdefghijklmnopqrstuvwxyz0123456789_") != strlen(tmp)) { virReportError(VIR_ERR_INTERNAL_ERROR, "%s", _("Invalid environment name, it must contain only alphanumerics and underscore")); goto error; } cmd->env_name[cmd->num_env] = tmp; cmd->env_value[cmd->num_env] = virXMLPropString(nodes[i], "value"); /* a NULL value for command is allowed, since it might be empty */ cmd->num_env++; } VIR_FREE(nodes); if (uses_qemu_ns) *data = cmd; else VIR_FREE(cmd); return 0; error: VIR_FREE(nodes); qemuDomainDefNamespaceFree(cmd); return -1; } static int qemuDomainDefNamespaceFormatXML(virBufferPtr buf, void *nsdata) { qemuDomainCmdlineDefPtr cmd = nsdata; size_t i; if (!cmd->num_args && !cmd->num_env) return 0; virBufferAddLit(buf, "\n"); virBufferAdjustIndent(buf, 2); for (i = 0; i < cmd->num_args; i++) virBufferEscapeString(buf, "\n", cmd->args[i]); for (i = 0; i < cmd->num_env; i++) { virBufferAsprintf(buf, "env_name[i]); if (cmd->env_value[i]) virBufferEscapeString(buf, " value='%s'", cmd->env_value[i]); virBufferAddLit(buf, "/>\n"); } virBufferAdjustIndent(buf, -2); virBufferAddLit(buf, "\n"); return 0; } static const char * qemuDomainDefNamespaceHref(void) { return "xmlns:qemu='" QEMU_NAMESPACE_HREF "'"; } virDomainXMLNamespace virQEMUDriverDomainXMLNamespace = { .parse = qemuDomainDefNamespaceParse, .free = qemuDomainDefNamespaceFree, .format = qemuDomainDefNamespaceFormatXML, .href = qemuDomainDefNamespaceHref, }; static int qemuDomainDefAddImplicitInputDevice(virDomainDef *def) { if (ARCH_IS_X86(def->os.arch)) { if (virDomainDefMaybeAddInput(def, VIR_DOMAIN_INPUT_TYPE_MOUSE, VIR_DOMAIN_INPUT_BUS_PS2) < 0) return -1; if (virDomainDefMaybeAddInput(def, VIR_DOMAIN_INPUT_TYPE_KBD, VIR_DOMAIN_INPUT_BUS_PS2) < 0) return -1; } return 0; } static int qemuDomainDefAddDefaultDevices(virDomainDefPtr def, virQEMUCapsPtr qemuCaps) { bool addDefaultUSB = true; int usbModel = -1; /* "default for machinetype" */ int pciRoot; /* index within def->controllers */ bool addImplicitSATA = false; bool addPCIRoot = false; bool addPCIeRoot = false; bool addDefaultMemballoon = true; bool addDefaultUSBKBD = false; bool addDefaultUSBMouse = false; bool addPanicDevice = false; int ret = -1; /* add implicit input devices */ if (qemuDomainDefAddImplicitInputDevice(def) < 0) goto cleanup; /* Add implicit PCI root controller if the machine has one */ switch (def->os.arch) { case VIR_ARCH_I686: case VIR_ARCH_X86_64: if (STREQ(def->os.machine, "isapc")) { addDefaultUSB = false; break; } if (qemuDomainIsQ35(def)) { addPCIeRoot = true; addImplicitSATA = true; /* Prefer adding a USB3 controller if supported, fall back * to USB2 if there is no USB3 available, and if that's * unavailable don't add anything. */ if (virQEMUCapsGet(qemuCaps, QEMU_CAPS_DEVICE_QEMU_XHCI)) usbModel = VIR_DOMAIN_CONTROLLER_MODEL_USB_QEMU_XHCI; else if (virQEMUCapsGet(qemuCaps, QEMU_CAPS_NEC_USB_XHCI)) usbModel = VIR_DOMAIN_CONTROLLER_MODEL_USB_NEC_XHCI; else if (virQEMUCapsGet(qemuCaps, QEMU_CAPS_ICH9_USB_EHCI1)) usbModel = VIR_DOMAIN_CONTROLLER_MODEL_USB_ICH9_EHCI1; else addDefaultUSB = false; break; } if (qemuDomainIsI440FX(def)) addPCIRoot = true; break; case VIR_ARCH_ARMV7L: case VIR_ARCH_AARCH64: addDefaultUSB = false; addDefaultMemballoon = false; if (qemuDomainIsVirt(def)) addPCIeRoot = virQEMUCapsGet(qemuCaps, QEMU_CAPS_OBJECT_GPEX); break; case VIR_ARCH_PPC64: case VIR_ARCH_PPC64LE: addPCIRoot = true; addDefaultUSBKBD = true; addDefaultUSBMouse = true; /* For pSeries guests, the firmware provides the same * functionality as the pvpanic device, so automatically * add the definition if not already present */ if (qemuDomainIsPSeries(def)) addPanicDevice = true; break; case VIR_ARCH_ALPHA: case VIR_ARCH_PPC: case VIR_ARCH_PPCEMB: case VIR_ARCH_SH4: case VIR_ARCH_SH4EB: addPCIRoot = true; break; case VIR_ARCH_S390: case VIR_ARCH_S390X: addDefaultUSB = false; addPanicDevice = true; break; case VIR_ARCH_SPARC: case VIR_ARCH_SPARC64: addPCIRoot = true; break; default: break; } if (addDefaultUSB && virDomainControllerFind(def, VIR_DOMAIN_CONTROLLER_TYPE_USB, 0) < 0 && virDomainDefAddUSBController(def, 0, usbModel) < 0) goto cleanup; if (addImplicitSATA && virDomainDefMaybeAddController( def, VIR_DOMAIN_CONTROLLER_TYPE_SATA, 0, -1) < 0) goto cleanup; pciRoot = virDomainControllerFind(def, VIR_DOMAIN_CONTROLLER_TYPE_PCI, 0); /* NB: any machine that sets addPCIRoot to true must also return * true from the function qemuDomainSupportsPCI(). */ if (addPCIRoot) { if (pciRoot >= 0) { if (def->controllers[pciRoot]->model != VIR_DOMAIN_CONTROLLER_MODEL_PCI_ROOT) { virReportError(VIR_ERR_XML_ERROR, _("The PCI controller with index='0' must be " "model='pci-root' for this machine type, " "but model='%s' was found instead"), virDomainControllerModelPCITypeToString(def->controllers[pciRoot]->model)); goto cleanup; } } else if (!virDomainDefAddController(def, VIR_DOMAIN_CONTROLLER_TYPE_PCI, 0, VIR_DOMAIN_CONTROLLER_MODEL_PCI_ROOT)) { goto cleanup; } } /* When a machine has a pcie-root, make sure that there is always * a dmi-to-pci-bridge controller added as bus 1, and a pci-bridge * as bus 2, so that standard PCI devices can be connected * * NB: any machine that sets addPCIeRoot to true must also return * true from the function qemuDomainSupportsPCI(). */ if (addPCIeRoot) { if (pciRoot >= 0) { if (def->controllers[pciRoot]->model != VIR_DOMAIN_CONTROLLER_MODEL_PCIE_ROOT) { virReportError(VIR_ERR_XML_ERROR, _("The PCI controller with index='0' must be " "model='pcie-root' for this machine type, " "but model='%s' was found instead"), virDomainControllerModelPCITypeToString(def->controllers[pciRoot]->model)); goto cleanup; } } else if (!virDomainDefAddController(def, VIR_DOMAIN_CONTROLLER_TYPE_PCI, 0, VIR_DOMAIN_CONTROLLER_MODEL_PCIE_ROOT)) { goto cleanup; } } if (addDefaultMemballoon && !def->memballoon) { virDomainMemballoonDefPtr memballoon; if (VIR_ALLOC(memballoon) < 0) goto cleanup; memballoon->model = VIR_DOMAIN_MEMBALLOON_MODEL_VIRTIO; def->memballoon = memballoon; } if (addDefaultUSBKBD && def->ngraphics > 0 && virDomainDefMaybeAddInput(def, VIR_DOMAIN_INPUT_TYPE_KBD, VIR_DOMAIN_INPUT_BUS_USB) < 0) goto cleanup; if (addDefaultUSBMouse && def->ngraphics > 0 && virDomainDefMaybeAddInput(def, VIR_DOMAIN_INPUT_TYPE_MOUSE, VIR_DOMAIN_INPUT_BUS_USB) < 0) goto cleanup; if (addPanicDevice) { size_t j; for (j = 0; j < def->npanics; j++) { if (def->panics[j]->model == VIR_DOMAIN_PANIC_MODEL_DEFAULT || (ARCH_IS_PPC64(def->os.arch) && def->panics[j]->model == VIR_DOMAIN_PANIC_MODEL_PSERIES) || (ARCH_IS_S390(def->os.arch) && def->panics[j]->model == VIR_DOMAIN_PANIC_MODEL_S390)) break; } if (j == def->npanics) { virDomainPanicDefPtr panic; if (VIR_ALLOC(panic) < 0 || VIR_APPEND_ELEMENT_COPY(def->panics, def->npanics, panic) < 0) { VIR_FREE(panic); goto cleanup; } } } ret = 0; cleanup: return ret; } /** * qemuDomainDefEnableDefaultFeatures: * @def: domain definition * @qemuCaps: QEMU capabilities * * Make sure that features that should be enabled by default are actually * enabled and configure default values related to those features. */ static void qemuDomainDefEnableDefaultFeatures(virDomainDefPtr def, virQEMUCapsPtr qemuCaps) { virGICVersion version; /* The virt machine type always uses GIC: if the relevant element * was not included in the domain XML, we need to choose a suitable * GIC version ourselves */ if (def->features[VIR_DOMAIN_FEATURE_GIC] == VIR_TRISTATE_SWITCH_ABSENT && qemuDomainIsVirt(def)) { VIR_DEBUG("Looking for usable GIC version in domain capabilities"); for (version = VIR_GIC_VERSION_LAST - 1; version > VIR_GIC_VERSION_NONE; version--) { /* We want to use the highest available GIC version for guests; * however, the emulated GICv3 is currently lacking a MSI controller, * making it unsuitable for the pure PCIe topology we aim for. * * For that reason, we skip this step entirely for TCG guests, * and rely on the code below to pick the default version, GICv2, * which supports all the features we need. * * We'll want to revisit this once MSI support for GICv3 has been * implemented in QEMU. * * See https://bugzilla.redhat.com/show_bug.cgi?id=1414081 */ if (version == VIR_GIC_VERSION_3 && def->virtType == VIR_DOMAIN_VIRT_QEMU) { continue; } if (virQEMUCapsSupportsGICVersion(qemuCaps, def->virtType, version)) { VIR_DEBUG("Using GIC version %s", virGICVersionTypeToString(version)); def->gic_version = version; break; } } /* Even if we haven't found a usable GIC version in the domain * capabilities, we still want to enable this */ def->features[VIR_DOMAIN_FEATURE_GIC] = VIR_TRISTATE_SWITCH_ON; } /* Use the default GIC version (GICv2) if no version was specified */ if (def->features[VIR_DOMAIN_FEATURE_GIC] == VIR_TRISTATE_SWITCH_ON && def->gic_version == VIR_GIC_VERSION_NONE) { VIR_DEBUG("Using GIC version 2 (default)"); def->gic_version = VIR_GIC_VERSION_2; } } static int qemuCanonicalizeMachine(virDomainDefPtr def, virQEMUCapsPtr qemuCaps) { const char *canon; if (!(canon = virQEMUCapsGetCanonicalMachine(qemuCaps, def->os.machine))) return 0; if (STRNEQ(canon, def->os.machine)) { char *tmp; if (VIR_STRDUP(tmp, canon) < 0) return -1; VIR_FREE(def->os.machine); def->os.machine = tmp; } return 0; } static int qemuDomainRecheckInternalPaths(virDomainDefPtr def, virQEMUDriverConfigPtr cfg, unsigned int flags) { size_t i = 0; size_t j = 0; for (i = 0; i < def->ngraphics; ++i) { virDomainGraphicsDefPtr graphics = def->graphics[i]; for (j = 0; j < graphics->nListens; ++j) { virDomainGraphicsListenDefPtr glisten = &graphics->listens[j]; /* This will happen only if we parse XML from old libvirts where * unix socket was available only for VNC graphics. In this * particular case we should follow the behavior and if we remove * the auto-generated socket based on config option from qemu.conf * we need to change the listen type to address. */ if (graphics->type == VIR_DOMAIN_GRAPHICS_TYPE_VNC && glisten->type == VIR_DOMAIN_GRAPHICS_LISTEN_TYPE_SOCKET && glisten->socket && !glisten->autoGenerated && STRPREFIX(glisten->socket, cfg->libDir)) { if (flags & VIR_DOMAIN_DEF_PARSE_INACTIVE) { VIR_FREE(glisten->socket); glisten->type = VIR_DOMAIN_GRAPHICS_LISTEN_TYPE_ADDRESS; } else { glisten->fromConfig = true; } } } } return 0; } static int qemuDomainDefVcpusPostParse(virDomainDefPtr def) { unsigned int maxvcpus = virDomainDefGetVcpusMax(def); virDomainVcpuDefPtr vcpu; virDomainVcpuDefPtr prevvcpu; size_t i; bool has_order = false; /* vcpu 0 needs to be present, first, and non-hotpluggable */ vcpu = virDomainDefGetVcpu(def, 0); if (!vcpu->online) { virReportError(VIR_ERR_CONFIG_UNSUPPORTED, "%s", _("vcpu 0 can't be offline")); return -1; } if (vcpu->hotpluggable == VIR_TRISTATE_BOOL_YES) { virReportError(VIR_ERR_CONFIG_UNSUPPORTED, "%s", _("vcpu0 can't be hotpluggable")); return -1; } if (vcpu->order != 0 && vcpu->order != 1) { virReportError(VIR_ERR_CONFIG_UNSUPPORTED, "%s", _("vcpu0 must be enabled first")); return -1; } if (vcpu->order != 0) has_order = true; prevvcpu = vcpu; /* all online vcpus or non online vcpu need to have order set */ for (i = 1; i < maxvcpus; i++) { vcpu = virDomainDefGetVcpu(def, i); if (vcpu->online && (vcpu->order != 0) != has_order) { virReportError(VIR_ERR_CONFIG_UNSUPPORTED, "%s", _("all vcpus must have either set or unset order")); return -1; } /* few conditions for non-hotpluggable (thus online) vcpus */ if (vcpu->hotpluggable == VIR_TRISTATE_BOOL_NO) { /* they can be ordered only at the beginning */ if (prevvcpu->hotpluggable == VIR_TRISTATE_BOOL_YES) { virReportError(VIR_ERR_CONFIG_UNSUPPORTED, "%s", _("online non-hotpluggable vcpus need to be " "ordered prior to hotplugable vcpus")); return -1; } /* they need to be in order (qemu doesn't support any order yet). * Also note that multiple vcpus may share order on some platforms */ if (prevvcpu->order > vcpu->order) { virReportError(VIR_ERR_CONFIG_UNSUPPORTED, "%s", _("online non-hotpluggable vcpus must be ordered " "in ascending order")); return -1; } } prevvcpu = vcpu; } return 0; } static int qemuDomainDefCPUPostParse(virDomainDefPtr def) { if (!def->cpu) return 0; if (def->cpu->cache) { virCPUCacheDefPtr cache = def->cpu->cache; if (!ARCH_IS_X86(def->os.arch)) { virReportError(VIR_ERR_CONFIG_UNSUPPORTED, _("CPU cache specification is not supported " "for '%s' architecture"), virArchToString(def->os.arch)); return -1; } switch (cache->mode) { case VIR_CPU_CACHE_MODE_EMULATE: if (cache->level != 3) { virReportError(VIR_ERR_CONFIG_UNSUPPORTED, _("CPU cache mode '%s' can only be used with " "level='3'"), virCPUCacheModeTypeToString(cache->mode)); return -1; } break; case VIR_CPU_CACHE_MODE_PASSTHROUGH: if (def->cpu->mode != VIR_CPU_MODE_HOST_PASSTHROUGH) { virReportError(VIR_ERR_CONFIG_UNSUPPORTED, _("CPU cache mode '%s' can only be used with " "'%s' CPUs"), virCPUCacheModeTypeToString(cache->mode), virCPUModeTypeToString(VIR_CPU_MODE_HOST_PASSTHROUGH)); return -1; } if (cache->level != -1) { virReportError(VIR_ERR_CONFIG_UNSUPPORTED, _("unsupported CPU cache level for mode '%s'"), virCPUCacheModeTypeToString(cache->mode)); return -1; } break; case VIR_CPU_CACHE_MODE_DISABLE: if (cache->level != -1) { virReportError(VIR_ERR_CONFIG_UNSUPPORTED, _("unsupported CPU cache level for mode '%s'"), virCPUCacheModeTypeToString(cache->mode)); return -1; } break; case VIR_CPU_CACHE_MODE_LAST: break; } } /* Nothing to be done if only CPU topology is specified. */ if (def->cpu->mode == VIR_CPU_MODE_CUSTOM && !def->cpu->model) return 0; if (def->cpu->check != VIR_CPU_CHECK_DEFAULT) return 0; switch ((virCPUMode) def->cpu->mode) { case VIR_CPU_MODE_HOST_PASSTHROUGH: def->cpu->check = VIR_CPU_CHECK_NONE; break; case VIR_CPU_MODE_HOST_MODEL: def->cpu->check = VIR_CPU_CHECK_PARTIAL; break; case VIR_CPU_MODE_CUSTOM: /* Custom CPUs in TCG mode are not compared to host CPU by default. */ if (def->virtType == VIR_DOMAIN_VIRT_QEMU) def->cpu->check = VIR_CPU_CHECK_NONE; else def->cpu->check = VIR_CPU_CHECK_PARTIAL; break; case VIR_CPU_MODE_LAST: break; } return 0; } static int qemuDomainDefVerifyFeatures(const virDomainDef *def) { if (def->features[VIR_DOMAIN_FEATURE_IOAPIC] == VIR_TRISTATE_SWITCH_ON && !ARCH_IS_X86(def->os.arch)) { virReportError(VIR_ERR_CONFIG_UNSUPPORTED, _("I/O APIC tuning is not supported " "for '%s' architecture"), virArchToString(def->os.arch)); return -1; } if (def->features[VIR_DOMAIN_FEATURE_HPT] == VIR_TRISTATE_SWITCH_ON && !qemuDomainIsPSeries(def)) { virReportError(VIR_ERR_CONFIG_UNSUPPORTED, "%s", _("HPT tuning is only supported for pSeries guests")); return -1; } return 0; } static int qemuDomainDefPostParseBasic(virDomainDefPtr def, virCapsPtr caps, void *opaque ATTRIBUTE_UNUSED) { /* check for emulator and create a default one if needed */ if (!def->emulator && !(def->emulator = virDomainDefGetDefaultEmulator(def, caps))) return 1; return 0; } static int qemuDomainDefPostParse(virDomainDefPtr def, virCapsPtr caps ATTRIBUTE_UNUSED, unsigned int parseFlags, void *opaque, void *parseOpaque) { virQEMUDriverPtr driver = opaque; virQEMUDriverConfigPtr cfg = virQEMUDriverGetConfig(driver); /* Note that qemuCaps may be NULL when this function is called. This * function shall not fail in that case. It will be re-run on VM startup * with the capabilities populated. */ virQEMUCapsPtr qemuCaps = parseOpaque; int ret = -1; if (def->os.bootloader || def->os.bootloaderArgs) { virReportError(VIR_ERR_CONFIG_UNSUPPORTED, "%s", _("bootloader is not supported by QEMU")); goto cleanup; } if (!def->os.machine) { virReportError(VIR_ERR_INTERNAL_ERROR, "%s", _("missing machine type")); goto cleanup; } if (def->os.loader && def->os.loader->type == VIR_DOMAIN_LOADER_TYPE_PFLASH && def->os.loader->readonly == VIR_TRISTATE_SWITCH_ON && !def->os.loader->nvram) { if (virAsprintf(&def->os.loader->nvram, "%s/%s_VARS.fd", cfg->nvramDir, def->name) < 0) goto cleanup; } if (qemuDomainDefAddDefaultDevices(def, qemuCaps) < 0) goto cleanup; if (qemuCanonicalizeMachine(def, qemuCaps) < 0) goto cleanup; qemuDomainDefEnableDefaultFeatures(def, qemuCaps); if (qemuDomainDefVerifyFeatures(def) < 0) goto cleanup; if (qemuDomainRecheckInternalPaths(def, cfg, parseFlags) < 0) goto cleanup; if (qemuSecurityVerify(driver->securityManager, def) < 0) goto cleanup; if (qemuDomainDefVcpusPostParse(def) < 0) goto cleanup; if (qemuDomainDefCPUPostParse(def) < 0) goto cleanup; ret = 0; cleanup: virObjectUnref(cfg); return ret; } /** * qemuDomainDefGetVcpuHotplugGranularity: * @def: domain definition * * With QEMU 2.7 and newer, vCPUs can only be hotplugged in groups that * respect the guest's hotplug granularity; because of that, QEMU will * not allow guests to start unless the initial number of vCPUs is a * multiple of the hotplug granularity. * * Returns the vCPU hotplug granularity. */ static unsigned int qemuDomainDefGetVcpuHotplugGranularity(const virDomainDef *def) { /* If the guest CPU topology has not been configured, assume we * can hotplug vCPUs one at a time */ if (!def->cpu || def->cpu->sockets == 0) return 1; /* For pSeries guests, hotplug can only be performed one core * at a time, so the vCPU hotplug granularity is the number * of threads per core */ if (qemuDomainIsPSeries(def)) return def->cpu->threads; /* In all other cases, we can hotplug vCPUs one at a time */ return 1; } #define QEMU_MAX_VCPUS_WITHOUT_EIM 255 static int qemuDomainDefValidate(const virDomainDef *def, virCapsPtr caps ATTRIBUTE_UNUSED, void *opaque) { virQEMUDriverPtr driver = opaque; virQEMUCapsPtr qemuCaps = NULL; int ret = -1; if (!(qemuCaps = virQEMUCapsCacheLookup(driver->qemuCapsCache, def->emulator))) goto cleanup; if (def->mem.min_guarantee) { virReportError(VIR_ERR_CONFIG_UNSUPPORTED, "%s", _("Parameter 'min_guarantee' not supported by QEMU.")); goto cleanup; } /* On x86, UEFI requires ACPI */ if (def->os.loader && def->os.loader->type == VIR_DOMAIN_LOADER_TYPE_PFLASH && ARCH_IS_X86(def->os.arch) && def->features[VIR_DOMAIN_FEATURE_ACPI] != VIR_TRISTATE_SWITCH_ON) { virReportError(VIR_ERR_CONFIG_UNSUPPORTED, "%s", _("UEFI requires ACPI on this architecture")); goto cleanup; } /* On aarch64, ACPI requires UEFI */ if (def->features[VIR_DOMAIN_FEATURE_ACPI] == VIR_TRISTATE_SWITCH_ON && def->os.arch == VIR_ARCH_AARCH64 && (!def->os.loader || def->os.loader->type != VIR_DOMAIN_LOADER_TYPE_PFLASH)) { virReportError(VIR_ERR_CONFIG_UNSUPPORTED, "%s", _("ACPI requires UEFI on this architecture")); goto cleanup; } if (def->os.loader && def->os.loader->secure == VIR_TRISTATE_BOOL_YES) { /* These are the QEMU implementation limitations. But we * have to live with them for now. */ if (!qemuDomainIsQ35(def)) { virReportError(VIR_ERR_CONFIG_UNSUPPORTED, "%s", _("Secure boot is supported with q35 machine types only")); goto cleanup; } /* Now, technically it is possible to have secure boot on * 32bits too, but that would require some -cpu xxx magic * too. Not worth it unless we are explicitly asked. */ if (def->os.arch != VIR_ARCH_X86_64) { virReportError(VIR_ERR_CONFIG_UNSUPPORTED, "%s", _("Secure boot is supported for x86_64 architecture only")); goto cleanup; } if (def->features[VIR_DOMAIN_FEATURE_SMM] != VIR_TRISTATE_SWITCH_ON) { virReportError(VIR_ERR_CONFIG_UNSUPPORTED, "%s", _("Secure boot requires SMM feature enabled")); goto cleanup; } } /* QEMU 2.7 (detected via the availability of query-hotpluggable-cpus) * enforces stricter rules than previous versions when it comes to guest * CPU topology. Verify known constraints are respected */ if (virQEMUCapsGet(qemuCaps, QEMU_CAPS_QUERY_HOTPLUGGABLE_CPUS)) { unsigned int topologycpus; unsigned int granularity; /* Starting from QEMU 2.5, max vCPU count and overall vCPU topology * must agree. We only actually enforce this with QEMU 2.7+, due * to the capability check above */ if (virDomainDefGetVcpusTopology(def, &topologycpus) == 0 && topologycpus != virDomainDefGetVcpusMax(def)) { virReportError(VIR_ERR_CONFIG_UNSUPPORTED, "%s", _("CPU topology doesn't match maximum vcpu count")); goto cleanup; } /* vCPU hotplug granularity must be respected */ granularity = qemuDomainDefGetVcpuHotplugGranularity(def); if ((virDomainDefGetVcpus(def) % granularity) != 0) { virReportError(VIR_ERR_CONFIG_UNSUPPORTED, _("vCPUs count must be a multiple of the vCPU " "hotplug granularity (%u)"), granularity); goto cleanup; } } if (ARCH_IS_X86(def->os.arch) && virDomainDefGetVcpusMax(def) > QEMU_MAX_VCPUS_WITHOUT_EIM) { if (!qemuDomainIsQ35(def)) { virReportError(VIR_ERR_CONFIG_UNSUPPORTED, _("more than %d vCPUs are only supported on " "q35-based machine types"), QEMU_MAX_VCPUS_WITHOUT_EIM); goto cleanup; } if (!def->iommu || def->iommu->eim != VIR_TRISTATE_SWITCH_ON) { virReportError(VIR_ERR_CONFIG_UNSUPPORTED, _("more than %d vCPUs require extended interrupt " "mode enabled on the iommu device"), QEMU_MAX_VCPUS_WITHOUT_EIM); goto cleanup; } } ret = 0; cleanup: virObjectUnref(qemuCaps); return ret; } static bool qemuDomainNetSupportsCoalesce(virDomainNetType type) { switch (type) { case VIR_DOMAIN_NET_TYPE_NETWORK: case VIR_DOMAIN_NET_TYPE_BRIDGE: return true; case VIR_DOMAIN_NET_TYPE_VHOSTUSER: case VIR_DOMAIN_NET_TYPE_ETHERNET: case VIR_DOMAIN_NET_TYPE_DIRECT: case VIR_DOMAIN_NET_TYPE_HOSTDEV: case VIR_DOMAIN_NET_TYPE_USER: case VIR_DOMAIN_NET_TYPE_SERVER: case VIR_DOMAIN_NET_TYPE_CLIENT: case VIR_DOMAIN_NET_TYPE_MCAST: case VIR_DOMAIN_NET_TYPE_INTERNAL: case VIR_DOMAIN_NET_TYPE_UDP: case VIR_DOMAIN_NET_TYPE_LAST: break; } return false; } static int qemuDomainChrSourceReconnectDefValidate(const virDomainChrSourceReconnectDef *def) { if (def->enabled == VIR_TRISTATE_BOOL_YES && def->timeout == 0) { virReportError(VIR_ERR_INVALID_ARG, "%s", _("chardev reconnect source timeout cannot be '0'")); return -1; } return 0; } static int qemuDomainChrSourceDefValidate(const virDomainChrSourceDef *def) { switch ((virDomainChrType)def->type) { case VIR_DOMAIN_CHR_TYPE_TCP: if (qemuDomainChrSourceReconnectDefValidate(&def->data.tcp.reconnect) < 0) return -1; break; case VIR_DOMAIN_CHR_TYPE_UNIX: if (qemuDomainChrSourceReconnectDefValidate(&def->data.nix.reconnect) < 0) return -1; break; case VIR_DOMAIN_CHR_TYPE_NULL: case VIR_DOMAIN_CHR_TYPE_VC: case VIR_DOMAIN_CHR_TYPE_PTY: case VIR_DOMAIN_CHR_TYPE_DEV: case VIR_DOMAIN_CHR_TYPE_FILE: case VIR_DOMAIN_CHR_TYPE_PIPE: case VIR_DOMAIN_CHR_TYPE_STDIO: case VIR_DOMAIN_CHR_TYPE_UDP: case VIR_DOMAIN_CHR_TYPE_SPICEVMC: case VIR_DOMAIN_CHR_TYPE_SPICEPORT: case VIR_DOMAIN_CHR_TYPE_NMDM: case VIR_DOMAIN_CHR_TYPE_LAST: break; } return 0; } static int qemuDomainChrSerialTargetTypeToAddressType(int targetType) { switch ((virDomainChrSerialTargetType) targetType) { case VIR_DOMAIN_CHR_SERIAL_TARGET_TYPE_ISA: return VIR_DOMAIN_DEVICE_ADDRESS_TYPE_ISA; case VIR_DOMAIN_CHR_SERIAL_TARGET_TYPE_USB: return VIR_DOMAIN_DEVICE_ADDRESS_TYPE_USB; case VIR_DOMAIN_CHR_SERIAL_TARGET_TYPE_PCI: return VIR_DOMAIN_DEVICE_ADDRESS_TYPE_PCI; case VIR_DOMAIN_CHR_SERIAL_TARGET_TYPE_SPAPR_VIO: return VIR_DOMAIN_DEVICE_ADDRESS_TYPE_SPAPRVIO; case VIR_DOMAIN_CHR_SERIAL_TARGET_TYPE_SYSTEM: case VIR_DOMAIN_CHR_SERIAL_TARGET_TYPE_SCLP: case VIR_DOMAIN_CHR_SERIAL_TARGET_TYPE_LAST: case VIR_DOMAIN_CHR_SERIAL_TARGET_TYPE_NONE: break; } return VIR_DOMAIN_DEVICE_ADDRESS_TYPE_NONE; } static int qemuDomainChrSerialTargetModelToTargetType(int targetModel) { switch ((virDomainChrSerialTargetModel) targetModel) { case VIR_DOMAIN_CHR_SERIAL_TARGET_MODEL_ISA_SERIAL: return VIR_DOMAIN_CHR_SERIAL_TARGET_TYPE_ISA; case VIR_DOMAIN_CHR_SERIAL_TARGET_MODEL_USB_SERIAL: return VIR_DOMAIN_CHR_SERIAL_TARGET_TYPE_USB; case VIR_DOMAIN_CHR_SERIAL_TARGET_MODEL_PCI_SERIAL: return VIR_DOMAIN_CHR_SERIAL_TARGET_TYPE_PCI; case VIR_DOMAIN_CHR_SERIAL_TARGET_MODEL_SPAPR_VTY: return VIR_DOMAIN_CHR_SERIAL_TARGET_TYPE_SPAPR_VIO; case VIR_DOMAIN_CHR_SERIAL_TARGET_MODEL_PL011: return VIR_DOMAIN_CHR_SERIAL_TARGET_TYPE_SYSTEM; case VIR_DOMAIN_CHR_SERIAL_TARGET_MODEL_SCLPCONSOLE: case VIR_DOMAIN_CHR_SERIAL_TARGET_MODEL_SCLPLMCONSOLE: return VIR_DOMAIN_CHR_SERIAL_TARGET_TYPE_SCLP; case VIR_DOMAIN_CHR_SERIAL_TARGET_MODEL_NONE: case VIR_DOMAIN_CHR_SERIAL_TARGET_MODEL_LAST: break; } return VIR_DOMAIN_CHR_SERIAL_TARGET_TYPE_NONE; } static int qemuDomainChrTargetDefValidate(const virDomainChrDef *chr) { int expected; switch ((virDomainChrDeviceType) chr->deviceType) { case VIR_DOMAIN_CHR_DEVICE_TYPE_SERIAL: /* Validate target type */ switch ((virDomainChrSerialTargetType) chr->targetType) { case VIR_DOMAIN_CHR_SERIAL_TARGET_TYPE_ISA: case VIR_DOMAIN_CHR_SERIAL_TARGET_TYPE_USB: case VIR_DOMAIN_CHR_SERIAL_TARGET_TYPE_PCI: case VIR_DOMAIN_CHR_SERIAL_TARGET_TYPE_SPAPR_VIO: expected = qemuDomainChrSerialTargetTypeToAddressType(chr->targetType); if (chr->info.type != VIR_DOMAIN_DEVICE_ADDRESS_TYPE_NONE && chr->info.type != expected) { virReportError(VIR_ERR_CONFIG_UNSUPPORTED, _("Target type '%s' requires address type '%s'"), virDomainChrSerialTargetTypeToString(chr->targetType), virDomainDeviceAddressTypeToString(expected)); return -1; } break; case VIR_DOMAIN_CHR_SERIAL_TARGET_TYPE_SYSTEM: case VIR_DOMAIN_CHR_SERIAL_TARGET_TYPE_SCLP: if (chr->info.type != VIR_DOMAIN_DEVICE_ADDRESS_TYPE_NONE) { virReportError(VIR_ERR_CONFIG_UNSUPPORTED, _("Target type '%s' cannot have an " "associated address"), virDomainChrSerialTargetTypeToString(chr->targetType)); return -1; } break; case VIR_DOMAIN_CHR_SERIAL_TARGET_TYPE_NONE: case VIR_DOMAIN_CHR_SERIAL_TARGET_TYPE_LAST: break; } /* Validate target model */ switch ((virDomainChrSerialTargetModel) chr->targetModel) { case VIR_DOMAIN_CHR_SERIAL_TARGET_MODEL_ISA_SERIAL: case VIR_DOMAIN_CHR_SERIAL_TARGET_MODEL_USB_SERIAL: case VIR_DOMAIN_CHR_SERIAL_TARGET_MODEL_PCI_SERIAL: case VIR_DOMAIN_CHR_SERIAL_TARGET_MODEL_SPAPR_VTY: case VIR_DOMAIN_CHR_SERIAL_TARGET_MODEL_PL011: case VIR_DOMAIN_CHR_SERIAL_TARGET_MODEL_SCLPCONSOLE: case VIR_DOMAIN_CHR_SERIAL_TARGET_MODEL_SCLPLMCONSOLE: expected = qemuDomainChrSerialTargetModelToTargetType(chr->targetModel); if (chr->targetType != expected) { virReportError(VIR_ERR_CONFIG_UNSUPPORTED, _("Target model '%s' requires target type '%s'"), virDomainChrSerialTargetModelTypeToString(chr->targetModel), virDomainChrSerialTargetTypeToString(expected)); return -1; } break; case VIR_DOMAIN_CHR_SERIAL_TARGET_MODEL_NONE: case VIR_DOMAIN_CHR_SERIAL_TARGET_MODEL_LAST: break; } break; case VIR_DOMAIN_CHR_DEVICE_TYPE_CONSOLE: case VIR_DOMAIN_CHR_DEVICE_TYPE_PARALLEL: case VIR_DOMAIN_CHR_DEVICE_TYPE_CHANNEL: case VIR_DOMAIN_CHR_DEVICE_TYPE_LAST: /* Nothing to do */ break; } return 0; } static int qemuDomainChrDefValidate(const virDomainChrDef *dev, const virDomainDef *def) { if (qemuDomainChrSourceDefValidate(dev->source) < 0) return -1; if (qemuDomainChrTargetDefValidate(dev) < 0) return -1; if (dev->deviceType == VIR_DOMAIN_CHR_DEVICE_TYPE_PARALLEL && (ARCH_IS_S390(def->os.arch) || qemuDomainIsPSeries(def))) { virReportError(VIR_ERR_CONFIG_UNSUPPORTED, "%s", _("parallel ports are not supported")); return -1; } if (dev->deviceType == VIR_DOMAIN_CHR_DEVICE_TYPE_SERIAL) { bool isCompatible = true; if (!qemuDomainIsPSeries(def) && (dev->targetType == VIR_DOMAIN_CHR_SERIAL_TARGET_TYPE_SPAPR_VIO || dev->targetModel == VIR_DOMAIN_CHR_SERIAL_TARGET_MODEL_SPAPR_VTY)) { isCompatible = false; } if (!qemuDomainIsVirt(def) && (dev->targetType == VIR_DOMAIN_CHR_SERIAL_TARGET_TYPE_SYSTEM || dev->targetModel == VIR_DOMAIN_CHR_SERIAL_TARGET_MODEL_PL011)) { isCompatible = false; } if (!ARCH_IS_S390(def->os.arch) && (dev->targetType == VIR_DOMAIN_CHR_SERIAL_TARGET_TYPE_SCLP || dev->targetModel == VIR_DOMAIN_CHR_SERIAL_TARGET_MODEL_SCLPCONSOLE || dev->targetModel == VIR_DOMAIN_CHR_SERIAL_TARGET_MODEL_SCLPLMCONSOLE)) { isCompatible = false; } if (!isCompatible) { virReportError(VIR_ERR_CONFIG_UNSUPPORTED, _("Serial device with target type '%s' and " "target model '%s' not compatible with guest " "architecture or machine type"), virDomainChrSerialTargetTypeToString(dev->targetType), virDomainChrSerialTargetModelTypeToString(dev->targetModel)); return -1; } } return 0; } static int qemuDomainSmartcardDefValidate(const virDomainSmartcardDef *def) { if (def->type == VIR_DOMAIN_SMARTCARD_TYPE_PASSTHROUGH && qemuDomainChrSourceDefValidate(def->data.passthru) < 0) return -1; return 0; } static int qemuDomainRNGDefValidate(const virDomainRNGDef *def) { if (def->backend == VIR_DOMAIN_RNG_BACKEND_EGD && qemuDomainChrSourceDefValidate(def->source.chardev) < 0) return -1; return 0; } static int qemuDomainRedirdevDefValidate(const virDomainRedirdevDef *def) { if (qemuDomainChrSourceDefValidate(def->source) < 0) return -1; return 0; } static int qemuDomainWatchdogDefValidate(const virDomainWatchdogDef *dev, const virDomainDef *def) { switch ((virDomainWatchdogModel) dev->model) { case VIR_DOMAIN_WATCHDOG_MODEL_I6300ESB: if (dev->info.type != VIR_DOMAIN_DEVICE_ADDRESS_TYPE_NONE && dev->info.type != VIR_DOMAIN_DEVICE_ADDRESS_TYPE_PCI) { virReportError(VIR_ERR_CONFIG_UNSUPPORTED, _("%s model of watchdog can go only on PCI bus"), virDomainWatchdogModelTypeToString(dev->model)); return -1; } break; case VIR_DOMAIN_WATCHDOG_MODEL_IB700: if (dev->info.type != VIR_DOMAIN_DEVICE_ADDRESS_TYPE_NONE && dev->info.type != VIR_DOMAIN_DEVICE_ADDRESS_TYPE_ISA) { virReportError(VIR_ERR_CONFIG_UNSUPPORTED, _("%s model of watchdog can go only on ISA bus"), virDomainWatchdogModelTypeToString(dev->model)); return -1; } break; case VIR_DOMAIN_WATCHDOG_MODEL_DIAG288: if (dev->info.type != VIR_DOMAIN_DEVICE_ADDRESS_TYPE_NONE) { virReportError(VIR_ERR_CONFIG_UNSUPPORTED, _("%s model of watchdog is virtual and cannot go on any bus."), virDomainWatchdogModelTypeToString(dev->model)); return -1; } if (!(ARCH_IS_S390(def->os.arch))) { virReportError(VIR_ERR_CONFIG_UNSUPPORTED, _("%s model of watchdog is allowed for s390 and s390x only"), virDomainWatchdogModelTypeToString(dev->model)); return -1; } break; case VIR_DOMAIN_WATCHDOG_MODEL_LAST: break; } return 0; } static int qemuDomainDeviceDefValidateNetwork(const virDomainNetDef *net) { bool hasIPv4 = false; bool hasIPv6 = false; size_t i; if (net->type == VIR_DOMAIN_NET_TYPE_USER) { if (net->guestIP.nroutes) { virReportError(VIR_ERR_CONFIG_UNSUPPORTED, "%s", _("Invalid attempt to set network interface " "guest-side IP route, not supported by QEMU")); return -1; } for (i = 0; i < net->guestIP.nips; i++) { const virNetDevIPAddr *ip = net->guestIP.ips[i]; if (VIR_SOCKET_ADDR_VALID(&net->guestIP.ips[i]->peer)) { virReportError(VIR_ERR_CONFIG_UNSUPPORTED, "%s", _("Invalid attempt to set peer IP for guest")); return -1; } if (VIR_SOCKET_ADDR_IS_FAMILY(&ip->address, AF_INET)) { if (hasIPv4) { virReportError(VIR_ERR_CONFIG_UNSUPPORTED, "%s", _("Only one IPv4 address per " "interface is allowed")); return -1; } hasIPv4 = true; if (ip->prefix > 27) { virReportError(VIR_ERR_XML_ERROR, "%s", _("prefix too long")); return -1; } } if (VIR_SOCKET_ADDR_IS_FAMILY(&ip->address, AF_INET6)) { if (hasIPv6) { virReportError(VIR_ERR_CONFIG_UNSUPPORTED, "%s", _("Only one IPv6 address per " "interface is allowed")); return -1; } hasIPv6 = true; if (ip->prefix > 120) { virReportError(VIR_ERR_XML_ERROR, "%s", _("prefix too long")); return -1; } } } } else if (net->guestIP.nroutes || net->guestIP.nips) { virReportError(VIR_ERR_CONFIG_UNSUPPORTED, "%s", _("Invalid attempt to set network interface " "guest-side IP route and/or address info, " "not supported by QEMU")); return -1; } if (STREQ_NULLABLE(net->model, "virtio")) { if (net->driver.virtio.rx_queue_size & (net->driver.virtio.rx_queue_size - 1)) { virReportError(VIR_ERR_CONFIG_UNSUPPORTED, "%s", _("rx_queue_size has to be a power of two")); return -1; } if (net->driver.virtio.tx_queue_size & (net->driver.virtio.tx_queue_size - 1)) { virReportError(VIR_ERR_CONFIG_UNSUPPORTED, "%s", _("tx_queue_size has to be a power of two")); return -1; } } if (net->mtu && !qemuDomainNetSupportsMTU(net->type)) { virReportError(VIR_ERR_CONFIG_UNSUPPORTED, _("setting MTU on interface type %s is not supported yet"), virDomainNetTypeToString(net->type)); return -1; } if (net->coalesce && !qemuDomainNetSupportsCoalesce(net->type)) { virReportError(VIR_ERR_CONFIG_UNSUPPORTED, _("coalesce settings on interface type %s are not supported"), virDomainNetTypeToString(net->type)); return -1; } return 0; } static int qemuDomainDeviceDefValidateHostdev(const virDomainHostdevDef *hostdev, const virDomainDef *def) { /* forbid capabilities mode hostdev in this kind of hypervisor */ if (hostdev->mode == VIR_DOMAIN_HOSTDEV_MODE_CAPABILITIES) { virReportError(VIR_ERR_CONFIG_UNSUPPORTED, _("hostdev mode 'capabilities' is not " "supported in %s"), virDomainVirtTypeToString(def->virtType)); return -1; } return 0; } static int qemuDomainDeviceDefValidateVideo(const virDomainVideoDef *video) { switch (video->type) { case VIR_DOMAIN_VIDEO_TYPE_XEN: case VIR_DOMAIN_VIDEO_TYPE_VBOX: case VIR_DOMAIN_VIDEO_TYPE_PARALLELS: case VIR_DOMAIN_VIDEO_TYPE_DEFAULT: virReportError(VIR_ERR_CONFIG_UNSUPPORTED, _("video type '%s' is not supported with QEMU"), virDomainVideoTypeToString(video->type)); return -1; case VIR_DOMAIN_VIDEO_TYPE_VGA: case VIR_DOMAIN_VIDEO_TYPE_CIRRUS: case VIR_DOMAIN_VIDEO_TYPE_VMVGA: case VIR_DOMAIN_VIDEO_TYPE_QXL: case VIR_DOMAIN_VIDEO_TYPE_VIRTIO: case VIR_DOMAIN_VIDEO_TYPE_LAST: break; } if (!video->primary && video->type != VIR_DOMAIN_VIDEO_TYPE_QXL && video->type != VIR_DOMAIN_VIDEO_TYPE_VIRTIO) { virReportError(VIR_ERR_CONFIG_UNSUPPORTED, _("video type '%s' is only valid as primary " "video device"), virDomainVideoTypeToString(video->type)); return -1; } if (video->accel && video->accel->accel2d == VIR_TRISTATE_SWITCH_ON) { virReportError(VIR_ERR_CONFIG_UNSUPPORTED, "%s", _("qemu does not support the accel2d setting")); return -1; } if (video->type == VIR_DOMAIN_VIDEO_TYPE_QXL) { if (video->vram > (UINT_MAX / 1024)) { virReportError(VIR_ERR_OVERFLOW, _("value for 'vram' must be less than '%u'"), UINT_MAX / 1024); return -1; } if (video->ram > (UINT_MAX / 1024)) { virReportError(VIR_ERR_OVERFLOW, _("value for 'ram' must be less than '%u'"), UINT_MAX / 1024); return -1; } if (video->vgamem) { if (video->vgamem < 1024) { virReportError(VIR_ERR_CONFIG_UNSUPPORTED, "%s", _("value for 'vgamem' must be at least 1 MiB " "(1024 KiB)")); return -1; } if (video->vgamem != VIR_ROUND_UP_POWER_OF_TWO(video->vgamem)) { virReportError(VIR_ERR_CONFIG_UNSUPPORTED, "%s", _("value for 'vgamem' must be power of two")); return -1; } } } if (video->type == VIR_DOMAIN_VIDEO_TYPE_VGA || video->type == VIR_DOMAIN_VIDEO_TYPE_VMVGA) { if (video->vram && video->vram < 1024) { virReportError(VIR_ERR_CONFIG_UNSUPPORTED, "%s", _("value for 'vram' must be at least " "1 MiB (1024 KiB)")); return -1; } } return 0; } static int qemuDomainDeviceDefValidateDisk(const virDomainDiskDef *disk) { if (disk->src->shared && !disk->src->readonly) { if (disk->src->format <= VIR_STORAGE_FILE_AUTO) { virReportError(VIR_ERR_CONFIG_UNSUPPORTED, _("shared access for disk '%s' requires use of " "explicitly specified disk format"), disk->dst); return -1; } if (!qemuBlockStorageSourceSupportsConcurrentAccess(disk->src)) { virReportError(VIR_ERR_CONFIG_UNSUPPORTED, _("shared access for disk '%s' requires use of " "supported storage format"), disk->dst); return -1; } } return 0; } static int qemuDomainDeviceDefValidateControllerAttributes(const virDomainControllerDef *controller) { if (!(controller->type == VIR_DOMAIN_CONTROLLER_TYPE_SCSI && controller->model == VIR_DOMAIN_CONTROLLER_MODEL_SCSI_VIRTIO_SCSI)) { if (controller->queues) { virReportError(VIR_ERR_CONFIG_UNSUPPORTED, "%s", _("'queues' is only supported by virtio-scsi controller")); return -1; } if (controller->cmd_per_lun) { virReportError(VIR_ERR_CONFIG_UNSUPPORTED, "%s", _("'cmd_per_lun' is only supported by virtio-scsi controller")); return -1; } if (controller->max_sectors) { virReportError(VIR_ERR_CONFIG_UNSUPPORTED, "%s", _("'max_sectors' is only supported by virtio-scsi controller")); return -1; } if (controller->ioeventfd) { virReportError(VIR_ERR_CONFIG_UNSUPPORTED, "%s", _("'ioeventfd' is only supported by virtio-scsi controller")); return -1; } if (controller->iothread) { virReportError(VIR_ERR_CONFIG_UNSUPPORTED, "%s", _("'iothread' is only supported for virtio-scsi controller")); return -1; } } return 0; } /** * @qemuCaps: QEMU capabilities * @model: SCSI model to check * * Using the @qemuCaps, let's ensure the provided @model can be supported * * Returns true if acceptible, false otherwise with error message set. */ static bool qemuDomainCheckSCSIControllerModel(virQEMUCapsPtr qemuCaps, int model) { switch ((virDomainControllerModelSCSI) model) { case VIR_DOMAIN_CONTROLLER_MODEL_SCSI_LSILOGIC: if (!virQEMUCapsGet(qemuCaps, QEMU_CAPS_SCSI_LSI)) { virReportError(VIR_ERR_CONFIG_UNSUPPORTED, "%s", _("This QEMU doesn't support " "the LSI 53C895A SCSI controller")); return false; } break; case VIR_DOMAIN_CONTROLLER_MODEL_SCSI_VIRTIO_SCSI: if (!virQEMUCapsGet(qemuCaps, QEMU_CAPS_VIRTIO_SCSI)) { virReportError(VIR_ERR_CONFIG_UNSUPPORTED, "%s", _("This QEMU doesn't support " "virtio scsi controller")); return false; } break; case VIR_DOMAIN_CONTROLLER_MODEL_SCSI_IBMVSCSI: /*TODO: need checking work here if necessary */ break; case VIR_DOMAIN_CONTROLLER_MODEL_SCSI_LSISAS1068: if (!virQEMUCapsGet(qemuCaps, QEMU_CAPS_SCSI_MPTSAS1068)) { virReportError(VIR_ERR_CONFIG_UNSUPPORTED, "%s", _("This QEMU doesn't support " "the LSI SAS1068 (MPT Fusion) controller")); return false; } break; case VIR_DOMAIN_CONTROLLER_MODEL_SCSI_LSISAS1078: if (!virQEMUCapsGet(qemuCaps, QEMU_CAPS_SCSI_MEGASAS)) { virReportError(VIR_ERR_CONFIG_UNSUPPORTED, "%s", _("This QEMU doesn't support " "the LSI SAS1078 (MegaRAID) controller")); return false; } break; case VIR_DOMAIN_CONTROLLER_MODEL_SCSI_AUTO: case VIR_DOMAIN_CONTROLLER_MODEL_SCSI_BUSLOGIC: case VIR_DOMAIN_CONTROLLER_MODEL_SCSI_VMPVSCSI: case VIR_DOMAIN_CONTROLLER_MODEL_SCSI_LAST: virReportError(VIR_ERR_CONFIG_UNSUPPORTED, _("Unsupported controller model: %s"), virDomainControllerModelSCSITypeToString(model)); return false; } return true; } static int qemuDomainDeviceDefValidateControllerIDE(const virDomainControllerDef *controller, const virDomainDef *def) { /* first IDE controller is implicit on various machines */ if (controller->idx == 0 && qemuDomainHasBuiltinIDE(def)) return 0; /* Since we currently only support the integrated IDE * controller on various boards, if we ever get to here, it's * because some other machinetype had an IDE controller * specified, or one with a single IDE controller had multiple * IDE controllers specified. */ if (qemuDomainHasBuiltinIDE(def)) virReportError(VIR_ERR_CONFIG_UNSUPPORTED, "%s", _("Only a single IDE controller is supported " "for this machine type")); else virReportError(VIR_ERR_CONFIG_UNSUPPORTED, "%s", _("IDE controllers are unsupported for " "this QEMU binary or machine type")); return -1; } /* qemuDomainCheckSCSIControllerIOThreads: * @controller: Pointer to controller def * @def: Pointer to domain def * * If this controller definition has iothreads set, let's make sure the * configuration is right before adding to the command line * * Returns true if either supported or there are no iothreads for controller; * otherwise, returns false if configuration is not quite right. */ static bool qemuDomainCheckSCSIControllerIOThreads(const virDomainControllerDef *controller, const virDomainDef *def) { if (!controller->iothread) return true; if (controller->info.type != VIR_DOMAIN_DEVICE_ADDRESS_TYPE_PCI && controller->info.type != VIR_DOMAIN_DEVICE_ADDRESS_TYPE_CCW) { virReportError(VIR_ERR_CONFIG_UNSUPPORTED, "%s", _("IOThreads only available for virtio pci and " "virtio ccw controllers")); return false; } /* Can we find the controller iothread in the iothreadid list? */ if (!virDomainIOThreadIDFind(def, controller->iothread)) { virReportError(VIR_ERR_CONFIG_UNSUPPORTED, _("controller iothread '%u' not defined in iothreadid"), controller->iothread); return false; } return true; } static int qemuDomainDeviceDefValidateControllerSCSI(const virDomainControllerDef *controller, const virDomainDef *def) { switch ((virDomainControllerModelSCSI) controller->model) { case VIR_DOMAIN_CONTROLLER_MODEL_SCSI_VIRTIO_SCSI: if (!qemuDomainCheckSCSIControllerIOThreads(controller, def)) return -1; break; case VIR_DOMAIN_CONTROLLER_MODEL_SCSI_AUTO: case VIR_DOMAIN_CONTROLLER_MODEL_SCSI_BUSLOGIC: case VIR_DOMAIN_CONTROLLER_MODEL_SCSI_LSILOGIC: case VIR_DOMAIN_CONTROLLER_MODEL_SCSI_LSISAS1068: case VIR_DOMAIN_CONTROLLER_MODEL_SCSI_VMPVSCSI: case VIR_DOMAIN_CONTROLLER_MODEL_SCSI_IBMVSCSI: case VIR_DOMAIN_CONTROLLER_MODEL_SCSI_LSISAS1078: case VIR_DOMAIN_CONTROLLER_MODEL_SCSI_LAST: break; } return 0; } static int qemuDomainDeviceDefValidateControllerPCI(const virDomainControllerDef *controller, const virDomainDef *def, virQEMUCapsPtr qemuCaps) { virDomainControllerModelPCI model = controller->model; const virDomainPCIControllerOpts *pciopts; const char *modelName = NULL; /* skip pcie-root */ if (controller->model == VIR_DOMAIN_CONTROLLER_MODEL_PCIE_ROOT) return 0; /* Skip pci-root, except for pSeries guests (which actually * support more than one PCI Host Bridge per guest) */ if (!qemuDomainIsPSeries(def) && controller->model == VIR_DOMAIN_CONTROLLER_MODEL_PCI_ROOT) return 0; /* First pass - just check the controller index for the model's * that we care to check... */ switch (model) { case VIR_DOMAIN_CONTROLLER_MODEL_PCI_BRIDGE: case VIR_DOMAIN_CONTROLLER_MODEL_DMI_TO_PCI_BRIDGE: case VIR_DOMAIN_CONTROLLER_MODEL_PCIE_ROOT_PORT: case VIR_DOMAIN_CONTROLLER_MODEL_PCIE_SWITCH_UPSTREAM_PORT: case VIR_DOMAIN_CONTROLLER_MODEL_PCIE_SWITCH_DOWNSTREAM_PORT: case VIR_DOMAIN_CONTROLLER_MODEL_PCI_EXPANDER_BUS: case VIR_DOMAIN_CONTROLLER_MODEL_PCIE_EXPANDER_BUS: if (controller->idx == 0) { virReportError(VIR_ERR_CONFIG_UNSUPPORTED, _("index for pci controllers of model '%s' must be > 0"), virDomainControllerModelPCITypeToString(model)); return -1; } break; case VIR_DOMAIN_CONTROLLER_MODEL_PCI_ROOT: case VIR_DOMAIN_CONTROLLER_MODEL_PCIE_ROOT: case VIR_DOMAIN_CONTROLLER_MODEL_PCI_LAST: break; } pciopts = &controller->opts.pciopts; if (controller->model != VIR_DOMAIN_CONTROLLER_MODEL_PCIE_ROOT && controller->model != VIR_DOMAIN_CONTROLLER_MODEL_PCI_LAST) { if (pciopts->modelName == VIR_DOMAIN_CONTROLLER_PCI_MODEL_NAME_NONE) { virReportError(VIR_ERR_INTERNAL_ERROR, _("autogenerated %s options not set"), virDomainControllerModelPCITypeToString(controller->model)); return -1; } modelName = virDomainControllerPCIModelNameTypeToString(pciopts->modelName); if (!modelName) { virReportError(VIR_ERR_INTERNAL_ERROR, _("unknown %s modelName value %d"), virDomainControllerModelPCITypeToString(controller->model), pciopts->modelName); return -1; } } /* Second pass - now the model specific checks */ switch (model) { case VIR_DOMAIN_CONTROLLER_MODEL_PCI_BRIDGE: if (pciopts->chassisNr == -1) { virReportError(VIR_ERR_INTERNAL_ERROR, "%s", _("autogenerated pci-bridge options not set")); return -1; } if (pciopts->modelName != VIR_DOMAIN_CONTROLLER_PCI_MODEL_NAME_PCI_BRIDGE) { virReportError(VIR_ERR_CONFIG_UNSUPPORTED, _("PCI controller model name '%s' is not valid " "for a pci-bridge"), modelName); return -1; } if (!virQEMUCapsGet(qemuCaps, QEMU_CAPS_DEVICE_PCI_BRIDGE)) { virReportError(VIR_ERR_CONFIG_UNSUPPORTED, "%s", _("the pci-bridge controller is not supported " "in this QEMU binary")); return -1; } break; case VIR_DOMAIN_CONTROLLER_MODEL_PCI_EXPANDER_BUS: if (pciopts->busNr == -1) { virReportError(VIR_ERR_INTERNAL_ERROR, "%s", _("autogenerated pci-expander-bus options not set")); return -1; } if (pciopts->modelName != VIR_DOMAIN_CONTROLLER_PCI_MODEL_NAME_PXB) { virReportError(VIR_ERR_CONFIG_UNSUPPORTED, _("PCI controller model name '%s' is not valid " "for a pci-expander-bus"), modelName); return -1; } if (!virQEMUCapsGet(qemuCaps, QEMU_CAPS_DEVICE_PXB)) { virReportError(VIR_ERR_CONFIG_UNSUPPORTED, "%s", _("the pxb controller is not supported in this " "QEMU binary")); return -1; } break; case VIR_DOMAIN_CONTROLLER_MODEL_DMI_TO_PCI_BRIDGE: if (pciopts->modelName != VIR_DOMAIN_CONTROLLER_PCI_MODEL_NAME_I82801B11_BRIDGE) { virReportError(VIR_ERR_CONFIG_UNSUPPORTED, _("PCI controller model name '%s' is not valid " "for a dmi-to-pci-bridge"), modelName); return -1; } if (!virQEMUCapsGet(qemuCaps, QEMU_CAPS_DEVICE_DMI_TO_PCI_BRIDGE)) { virReportError(VIR_ERR_CONFIG_UNSUPPORTED, "%s", _("the dmi-to-pci-bridge (i82801b11-bridge) " "controller is not supported in this QEMU binary")); return -1; } break; case VIR_DOMAIN_CONTROLLER_MODEL_PCIE_ROOT_PORT: if (pciopts->chassis == -1 || pciopts->port == -1) { virReportError(VIR_ERR_INTERNAL_ERROR, "%s", _("autogenerated pcie-root-port options not set")); return -1; } if ((pciopts->modelName != VIR_DOMAIN_CONTROLLER_PCI_MODEL_NAME_IOH3420) && (pciopts->modelName != VIR_DOMAIN_CONTROLLER_PCI_MODEL_NAME_PCIE_ROOT_PORT)) { virReportError(VIR_ERR_CONFIG_UNSUPPORTED, _("PCI controller model name '%s' is not valid " "for a pcie-root-port"), modelName); return -1; } if ((pciopts->modelName == VIR_DOMAIN_CONTROLLER_PCI_MODEL_NAME_IOH3420) && !virQEMUCapsGet(qemuCaps, QEMU_CAPS_DEVICE_IOH3420)) { virReportError(VIR_ERR_CONFIG_UNSUPPORTED, "%s", _("the pcie-root-port (ioh3420) controller " "is not supported in this QEMU binary")); return -1; } if ((pciopts->modelName == VIR_DOMAIN_CONTROLLER_PCI_MODEL_NAME_PCIE_ROOT_PORT) && !virQEMUCapsGet(qemuCaps, QEMU_CAPS_DEVICE_PCIE_ROOT_PORT)) { virReportError(VIR_ERR_CONFIG_UNSUPPORTED, "%s", _("the pcie-root-port (pcie-root-port) controller " "is not supported in this QEMU binary")); return -1; } break; case VIR_DOMAIN_CONTROLLER_MODEL_PCIE_SWITCH_UPSTREAM_PORT: if (pciopts->modelName != VIR_DOMAIN_CONTROLLER_PCI_MODEL_NAME_X3130_UPSTREAM) { virReportError(VIR_ERR_CONFIG_UNSUPPORTED, _("PCI controller model name '%s' is not valid " "for a pcie-switch-upstream-port"), modelName); return -1; } if (!virQEMUCapsGet(qemuCaps, QEMU_CAPS_DEVICE_X3130_UPSTREAM)) { virReportError(VIR_ERR_CONFIG_UNSUPPORTED, "%s", _("the pcie-switch-upstream-port (x3130-upstream) " "controller is not supported in this QEMU binary")); return -1; } break; case VIR_DOMAIN_CONTROLLER_MODEL_PCIE_SWITCH_DOWNSTREAM_PORT: if (pciopts->chassis == -1 || pciopts->port == -1) { virReportError(VIR_ERR_INTERNAL_ERROR, "%s", _("autogenerated pcie-switch-downstream-port " "options not set")); return -1; } if (pciopts->modelName != VIR_DOMAIN_CONTROLLER_PCI_MODEL_NAME_XIO3130_DOWNSTREAM) { virReportError(VIR_ERR_CONFIG_UNSUPPORTED, _("PCI controller model name '%s' is not valid " "for a pcie-switch-downstream-port"), modelName); return -1; } if (!virQEMUCapsGet(qemuCaps, QEMU_CAPS_DEVICE_XIO3130_DOWNSTREAM)) { virReportError(VIR_ERR_CONFIG_UNSUPPORTED, "%s", _("The pcie-switch-downstream-port " "(xio3130-downstream) controller is not " "supported in this QEMU binary")); return -1; } break; case VIR_DOMAIN_CONTROLLER_MODEL_PCIE_EXPANDER_BUS: if (pciopts->busNr == -1) { virReportError(VIR_ERR_INTERNAL_ERROR, "%s", _("autogenerated pcie-expander-bus options not set")); return -1; } if (pciopts->modelName != VIR_DOMAIN_CONTROLLER_PCI_MODEL_NAME_PXB_PCIE) { virReportError(VIR_ERR_CONFIG_UNSUPPORTED, _("PCI controller model name '%s' is not valid " "for a pcie-expander-bus"), modelName); return -1; } if (!virQEMUCapsGet(qemuCaps, QEMU_CAPS_DEVICE_PXB_PCIE)) { virReportError(VIR_ERR_CONFIG_UNSUPPORTED, "%s", _("the pxb-pcie controller is not supported " "in this QEMU binary")); return -1; } break; case VIR_DOMAIN_CONTROLLER_MODEL_PCI_ROOT: if (pciopts->targetIndex == -1) { virReportError(VIR_ERR_INTERNAL_ERROR, "%s", _("autogenerated pci-root options not set")); return -1; } /* Skip the implicit one */ if (pciopts->targetIndex == 0) return 0; if (pciopts->modelName != VIR_DOMAIN_CONTROLLER_PCI_MODEL_NAME_SPAPR_PCI_HOST_BRIDGE) { virReportError(VIR_ERR_CONFIG_UNSUPPORTED, _("PCI controller model name '%s' is not valid " "for a pci-root"), modelName); return 0; } if (!virQEMUCapsGet(qemuCaps, QEMU_CAPS_DEVICE_SPAPR_PCI_HOST_BRIDGE)) { virReportError(VIR_ERR_CONFIG_UNSUPPORTED, "%s", _("the spapr-pci-host-bridge controller is not " "supported in this QEMU binary")); return -1; } if (pciopts->numaNode != -1 && !virQEMUCapsGet(qemuCaps, QEMU_CAPS_SPAPR_PCI_HOST_BRIDGE_NUMA_NODE)) { virReportError(VIR_ERR_CONFIG_UNSUPPORTED, "%s", _("the spapr-pci-host-bridge controller doesn't " "support numa_node in this QEMU binary")); return -1; } break; case VIR_DOMAIN_CONTROLLER_MODEL_PCIE_ROOT: case VIR_DOMAIN_CONTROLLER_MODEL_PCI_LAST: break; } return 0; } static int qemuDomainDeviceDefValidateControllerSATA(const virDomainControllerDef *controller, const virDomainDef *def, virQEMUCapsPtr qemuCaps) { /* first SATA controller on Q35 machines is implicit */ if (controller->idx == 0 && qemuDomainIsQ35(def)) return 0; if (!virQEMUCapsGet(qemuCaps, QEMU_CAPS_ICH9_AHCI)) { virReportError(VIR_ERR_CONFIG_UNSUPPORTED, "%s", _("SATA is not supported with this QEMU binary")); return -1; } return 0; } static int qemuDomainDeviceDefValidateController(const virDomainControllerDef *controller, const virDomainDef *def, virQEMUCapsPtr qemuCaps) { int ret = 0; if (!qemuDomainCheckCCWS390AddressSupport(def, controller->info, qemuCaps, "controller")) return -1; if (controller->type == VIR_DOMAIN_CONTROLLER_TYPE_SCSI && !qemuDomainCheckSCSIControllerModel(qemuCaps, controller->model)) return -1; if (qemuDomainDeviceDefValidateControllerAttributes(controller) < 0) return -1; switch ((virDomainControllerType) controller->type) { case VIR_DOMAIN_CONTROLLER_TYPE_IDE: ret = qemuDomainDeviceDefValidateControllerIDE(controller, def); break; case VIR_DOMAIN_CONTROLLER_TYPE_SCSI: ret = qemuDomainDeviceDefValidateControllerSCSI(controller, def); break; case VIR_DOMAIN_CONTROLLER_TYPE_PCI: ret = qemuDomainDeviceDefValidateControllerPCI(controller, def, qemuCaps); break; case VIR_DOMAIN_CONTROLLER_TYPE_SATA: ret = qemuDomainDeviceDefValidateControllerSATA(controller, def, qemuCaps); break; case VIR_DOMAIN_CONTROLLER_TYPE_FDC: case VIR_DOMAIN_CONTROLLER_TYPE_VIRTIO_SERIAL: case VIR_DOMAIN_CONTROLLER_TYPE_CCID: case VIR_DOMAIN_CONTROLLER_TYPE_USB: case VIR_DOMAIN_CONTROLLER_TYPE_LAST: break; } return ret; } static int qemuDomainDeviceDefValidateMemory(const virDomainMemoryDef *memory ATTRIBUTE_UNUSED, const virDomainDef *def) { const long system_page_size = virGetSystemPageSizeKB(); /* We can't guarantee any other mem.access * if no guest NUMA nodes are defined. */ if (def->mem.nhugepages != 0 && def->mem.hugepages[0].size != system_page_size && virDomainNumaGetNodeCount(def->numa) == 0 && def->mem.access != VIR_DOMAIN_MEMORY_ACCESS_DEFAULT && def->mem.access != VIR_DOMAIN_MEMORY_ACCESS_PRIVATE) { virReportError(VIR_ERR_CONFIG_UNSUPPORTED, _("memory access mode '%s' not supported " "without guest numa node"), virDomainMemoryAccessTypeToString(def->mem.access)); return -1; } return 0; } static int qemuDomainDeviceDefValidate(const virDomainDeviceDef *dev, const virDomainDef *def, void *opaque) { int ret = 0; virQEMUDriverPtr driver = opaque; virQEMUCapsPtr qemuCaps = NULL; if (!(qemuCaps = virQEMUCapsCacheLookup(driver->qemuCapsCache, def->emulator))) return -1; switch ((virDomainDeviceType) dev->type) { case VIR_DOMAIN_DEVICE_NET: ret = qemuDomainDeviceDefValidateNetwork(dev->data.net); break; case VIR_DOMAIN_DEVICE_CHR: ret = qemuDomainChrDefValidate(dev->data.chr, def); break; case VIR_DOMAIN_DEVICE_SMARTCARD: ret = qemuDomainSmartcardDefValidate(dev->data.smartcard); break; case VIR_DOMAIN_DEVICE_RNG: ret = qemuDomainRNGDefValidate(dev->data.rng); break; case VIR_DOMAIN_DEVICE_REDIRDEV: ret = qemuDomainRedirdevDefValidate(dev->data.redirdev); break; case VIR_DOMAIN_DEVICE_WATCHDOG: ret = qemuDomainWatchdogDefValidate(dev->data.watchdog, def); break; case VIR_DOMAIN_DEVICE_HOSTDEV: ret = qemuDomainDeviceDefValidateHostdev(dev->data.hostdev, def); break; case VIR_DOMAIN_DEVICE_VIDEO: ret = qemuDomainDeviceDefValidateVideo(dev->data.video); break; case VIR_DOMAIN_DEVICE_DISK: ret = qemuDomainDeviceDefValidateDisk(dev->data.disk); break; case VIR_DOMAIN_DEVICE_CONTROLLER: ret = qemuDomainDeviceDefValidateController(dev->data.controller, def, qemuCaps); break; case VIR_DOMAIN_DEVICE_MEMORY: ret = qemuDomainDeviceDefValidateMemory(dev->data.memory, def); break; case VIR_DOMAIN_DEVICE_LEASE: case VIR_DOMAIN_DEVICE_FS: case VIR_DOMAIN_DEVICE_INPUT: case VIR_DOMAIN_DEVICE_SOUND: case VIR_DOMAIN_DEVICE_GRAPHICS: case VIR_DOMAIN_DEVICE_HUB: case VIR_DOMAIN_DEVICE_MEMBALLOON: case VIR_DOMAIN_DEVICE_NVRAM: case VIR_DOMAIN_DEVICE_SHMEM: case VIR_DOMAIN_DEVICE_TPM: case VIR_DOMAIN_DEVICE_PANIC: case VIR_DOMAIN_DEVICE_IOMMU: case VIR_DOMAIN_DEVICE_NONE: case VIR_DOMAIN_DEVICE_LAST: break; } virObjectUnref(qemuCaps); return ret; } /** * qemuDomainDefaultNetModel: * @def: domain definition * @qemuCaps: qemu capabilities * * Returns the default network model for a given domain. Note that if @qemuCaps * is NULL this function may return NULL if the default model depends on the * capabilities. */ static const char * qemuDomainDefaultNetModel(const virDomainDef *def, virQEMUCapsPtr qemuCaps) { if (ARCH_IS_S390(def->os.arch)) return "virtio"; if (def->os.arch == VIR_ARCH_ARMV7L || def->os.arch == VIR_ARCH_AARCH64) { if (STREQ(def->os.machine, "versatilepb")) return "smc91c111"; if (qemuDomainIsVirt(def)) return "virtio"; /* Incomplete. vexpress (and a few others) use this, but not all * arm boards */ return "lan9118"; } /* In all other cases the model depends on the capabilities. If they were * not provided don't report any default. */ if (!qemuCaps) return NULL; /* Try several network devices in turn; each of these devices is * less likely be supported out-of-the-box by the guest operating * system than the previous one */ if (virQEMUCapsGet(qemuCaps, QEMU_CAPS_DEVICE_RTL8139)) return "rtl8139"; else if (virQEMUCapsGet(qemuCaps, QEMU_CAPS_DEVICE_E1000)) return "e1000"; else if (virQEMUCapsGet(qemuCaps, QEMU_CAPS_DEVICE_VIRTIO_NET)) return "virtio"; /* We've had no luck detecting support for any network device, * but we have to return something: might as well be rtl8139 */ return "rtl8139"; } /* * Clear auto generated unix socket paths: * * libvirt 1.2.18 and older: * {cfg->channelTargetDir}/{dom-name}.{target-name} * * libvirt 1.2.19 - 1.3.2: * {cfg->channelTargetDir}/domain-{dom-name}/{target-name} * * libvirt 1.3.3 and newer: * {cfg->channelTargetDir}/domain-{dom-id}-{short-dom-name}/{target-name} * * The unix socket path was stored in config XML until libvirt 1.3.0. * If someone specifies the same path as we generate, they shouldn't do it. * * This function clears the path for migration as well, so we need to clear * the path even if we are not storing it in the XML. */ static int qemuDomainChrDefDropDefaultPath(virDomainChrDefPtr chr, virQEMUDriverPtr driver) { virQEMUDriverConfigPtr cfg; virBuffer buf = VIR_BUFFER_INITIALIZER; char *regexp = NULL; int ret = -1; if (chr->deviceType != VIR_DOMAIN_CHR_DEVICE_TYPE_CHANNEL || chr->targetType != VIR_DOMAIN_CHR_CHANNEL_TARGET_TYPE_VIRTIO || chr->source->type != VIR_DOMAIN_CHR_TYPE_UNIX || !chr->source->data.nix.path) { return 0; } cfg = virQEMUDriverGetConfig(driver); virBufferEscapeRegex(&buf, "^%s", cfg->channelTargetDir); virBufferAddLit(&buf, "/([^/]+\\.)|(domain-[^/]+/)"); virBufferEscapeRegex(&buf, "%s$", chr->target.name); if (virBufferCheckError(&buf) < 0) goto cleanup; regexp = virBufferContentAndReset(&buf); if (virStringMatch(chr->source->data.nix.path, regexp)) VIR_FREE(chr->source->data.nix.path); ret = 0; cleanup: VIR_FREE(regexp); virObjectUnref(cfg); return ret; } static int qemuDomainShmemDefPostParse(virDomainShmemDefPtr shm) { /* This was the default since the introduction of this device. */ if (shm->model != VIR_DOMAIN_SHMEM_MODEL_IVSHMEM_DOORBELL && !shm->size) shm->size = 4 << 20; /* Nothing more to check/change for IVSHMEM */ if (shm->model == VIR_DOMAIN_SHMEM_MODEL_IVSHMEM) return 0; if (!shm->server.enabled) { if (shm->model == VIR_DOMAIN_SHMEM_MODEL_IVSHMEM_DOORBELL) { virReportError(VIR_ERR_CONFIG_UNSUPPORTED, _("shmem model '%s' is supported " "only with server option enabled"), virDomainShmemModelTypeToString(shm->model)); return -1; } if (shm->msi.enabled) { virReportError(VIR_ERR_CONFIG_UNSUPPORTED, _("shmem model '%s' doesn't support " "msi"), virDomainShmemModelTypeToString(shm->model)); } } else { if (shm->model == VIR_DOMAIN_SHMEM_MODEL_IVSHMEM_PLAIN) { virReportError(VIR_ERR_CONFIG_UNSUPPORTED, _("shmem model '%s' is supported " "only with server option disabled"), virDomainShmemModelTypeToString(shm->model)); return -1; } if (shm->size) { virReportError(VIR_ERR_CONFIG_UNSUPPORTED, _("shmem model '%s' does not support size setting"), virDomainShmemModelTypeToString(shm->model)); return -1; } shm->msi.enabled = true; if (!shm->msi.ioeventfd) shm->msi.ioeventfd = VIR_TRISTATE_SWITCH_ON; } return 0; } #define QEMU_USB_XHCI_MAXPORTS 15 static int qemuDomainControllerDefPostParse(virDomainControllerDefPtr cont, const virDomainDef *def, virQEMUCapsPtr qemuCaps, unsigned int parseFlags) { switch ((virDomainControllerType)cont->type) { case VIR_DOMAIN_CONTROLLER_TYPE_SCSI: /* Set the default SCSI controller model if not already set */ if (qemuDomainSetSCSIControllerModel(def, cont, qemuCaps) < 0) return -1; break; case VIR_DOMAIN_CONTROLLER_TYPE_USB: if (cont->model == -1 && qemuCaps) { /* Pick a suitable default model for the USB controller if none * has been selected by the user and we have the qemuCaps for * figuring out which contollers are supported. * * We rely on device availability instead of setting the model * unconditionally because, for some machine types, there's a * chance we will get away with using the legacy USB controller * when the relevant device is not available. * * See qemuBuildControllerDevCommandLine() */ /* Default USB controller is piix3-uhci if available. */ if (virQEMUCapsGet(qemuCaps, QEMU_CAPS_PIIX3_USB_UHCI)) cont->model = VIR_DOMAIN_CONTROLLER_MODEL_USB_PIIX3_UHCI; if (ARCH_IS_S390(def->os.arch)) { if (cont->info.type == VIR_DOMAIN_DEVICE_ADDRESS_TYPE_NONE) { /* set the default USB model to none for s390 unless an * address is found */ cont->model = VIR_DOMAIN_CONTROLLER_MODEL_USB_NONE; } } else if (ARCH_IS_PPC64(def->os.arch)) { /* To not break migration we need to set default USB controller * for ppc64 to pci-ohci if we cannot change ABI of the VM. * The nec-usb-xhci or qemu-xhci controller is used as default * only for newly defined domains or devices. */ if ((parseFlags & VIR_DOMAIN_DEF_PARSE_ABI_UPDATE) && virQEMUCapsGet(qemuCaps, QEMU_CAPS_DEVICE_QEMU_XHCI)) { cont->model = VIR_DOMAIN_CONTROLLER_MODEL_USB_QEMU_XHCI; } else if ((parseFlags & VIR_DOMAIN_DEF_PARSE_ABI_UPDATE) && virQEMUCapsGet(qemuCaps, QEMU_CAPS_NEC_USB_XHCI)) { cont->model = VIR_DOMAIN_CONTROLLER_MODEL_USB_NEC_XHCI; } else if (virQEMUCapsGet(qemuCaps, QEMU_CAPS_PCI_OHCI)) { cont->model = VIR_DOMAIN_CONTROLLER_MODEL_USB_PCI_OHCI; } else { /* Explicitly fallback to legacy USB controller for PPC64. */ cont->model = -1; } } else if (def->os.arch == VIR_ARCH_AARCH64) { if (virQEMUCapsGet(qemuCaps, QEMU_CAPS_DEVICE_QEMU_XHCI)) cont->model = VIR_DOMAIN_CONTROLLER_MODEL_USB_QEMU_XHCI; else if (virQEMUCapsGet(qemuCaps, QEMU_CAPS_NEC_USB_XHCI)) cont->model = VIR_DOMAIN_CONTROLLER_MODEL_USB_NEC_XHCI; } } /* forbid usb model 'qusb1' and 'qusb2' in this kind of hyperviosr */ if (cont->model == VIR_DOMAIN_CONTROLLER_MODEL_USB_QUSB1 || cont->model == VIR_DOMAIN_CONTROLLER_MODEL_USB_QUSB2) { virReportError(VIR_ERR_CONFIG_UNSUPPORTED, _("USB controller model type 'qusb1' or 'qusb2' " "is not supported in %s"), virDomainVirtTypeToString(def->virtType)); return -1; } if ((cont->model == VIR_DOMAIN_CONTROLLER_MODEL_USB_NEC_XHCI || cont->model == VIR_DOMAIN_CONTROLLER_MODEL_USB_QEMU_XHCI) && cont->opts.usbopts.ports > QEMU_USB_XHCI_MAXPORTS) { virReportError(VIR_ERR_CONFIG_UNSUPPORTED, _("'%s' controller only supports up to '%u' ports"), virDomainControllerModelUSBTypeToString(cont->model), QEMU_USB_XHCI_MAXPORTS); return -1; } break; case VIR_DOMAIN_CONTROLLER_TYPE_PCI: /* pSeries guests can have multiple pci-root controllers, * but other machine types only support a single one */ if (!qemuDomainIsPSeries(def) && (cont->model == VIR_DOMAIN_CONTROLLER_MODEL_PCI_ROOT || cont->model == VIR_DOMAIN_CONTROLLER_MODEL_PCIE_ROOT) && cont->idx != 0) { virReportError(VIR_ERR_XML_ERROR, "%s", _("pci-root and pcie-root controllers " "should have index 0")); return -1; } if (cont->model == VIR_DOMAIN_CONTROLLER_MODEL_PCI_EXPANDER_BUS && !qemuDomainIsI440FX(def)) { virReportError(VIR_ERR_CONFIG_UNSUPPORTED, "%s", _("pci-expander-bus controllers are only supported " "on 440fx-based machinetypes")); return -1; } if (cont->model == VIR_DOMAIN_CONTROLLER_MODEL_PCIE_EXPANDER_BUS && !qemuDomainIsQ35(def)) { virReportError(VIR_ERR_CONFIG_UNSUPPORTED, "%s", _("pcie-expander-bus controllers are only supported " "on q35-based machinetypes")); return -1; } /* if a PCI expander bus or pci-root on Pseries has a NUMA node * set, make sure that NUMA node is configured in the guest * array. NUMA cell id's in this array are numbered * from 0 .. size-1. */ if (cont->opts.pciopts.numaNode >= 0 && cont->opts.pciopts.numaNode >= (int) virDomainNumaGetNodeCount(def->numa)) { virReportError(VIR_ERR_XML_ERROR, _("%s with index %d is " "configured for a NUMA node (%d) " "not present in the domain's " " array (%zu)"), virDomainControllerModelPCITypeToString(cont->model), cont->idx, cont->opts.pciopts.numaNode, virDomainNumaGetNodeCount(def->numa)); return -1; } break; case VIR_DOMAIN_CONTROLLER_TYPE_SATA: case VIR_DOMAIN_CONTROLLER_TYPE_VIRTIO_SERIAL: case VIR_DOMAIN_CONTROLLER_TYPE_CCID: case VIR_DOMAIN_CONTROLLER_TYPE_IDE: case VIR_DOMAIN_CONTROLLER_TYPE_FDC: case VIR_DOMAIN_CONTROLLER_TYPE_LAST: break; } return 0; } static int qemuDomainChrDefPostParse(virDomainChrDefPtr chr, const virDomainDef *def, virQEMUDriverPtr driver, unsigned int parseFlags) { /* Historically, isa-serial and the default matched, so in order to * maintain backwards compatibility we map them here. The actual default * will be picked below based on the architecture and machine type. */ if (chr->deviceType == VIR_DOMAIN_CHR_DEVICE_TYPE_SERIAL && chr->targetType == VIR_DOMAIN_CHR_SERIAL_TARGET_TYPE_ISA) { chr->targetType = VIR_DOMAIN_CHR_SERIAL_TARGET_TYPE_NONE; } /* Set the default serial type */ if (chr->deviceType == VIR_DOMAIN_CHR_DEVICE_TYPE_SERIAL && chr->targetType == VIR_DOMAIN_CHR_SERIAL_TARGET_TYPE_NONE) { if (ARCH_IS_X86(def->os.arch)) { chr->targetType = VIR_DOMAIN_CHR_SERIAL_TARGET_TYPE_ISA; } else if (qemuDomainIsPSeries(def)) { chr->targetType = VIR_DOMAIN_CHR_SERIAL_TARGET_TYPE_SPAPR_VIO; } else if (qemuDomainIsVirt(def)) { chr->targetType = VIR_DOMAIN_CHR_SERIAL_TARGET_TYPE_SYSTEM; } else if (ARCH_IS_S390(def->os.arch)) { chr->targetType = VIR_DOMAIN_CHR_SERIAL_TARGET_TYPE_SCLP; } } /* Set the default target model */ if (chr->deviceType == VIR_DOMAIN_CHR_DEVICE_TYPE_SERIAL && chr->targetModel == VIR_DOMAIN_CHR_SERIAL_TARGET_MODEL_NONE) { switch ((virDomainChrSerialTargetType) chr->targetType) { case VIR_DOMAIN_CHR_SERIAL_TARGET_TYPE_ISA: chr->targetModel = VIR_DOMAIN_CHR_SERIAL_TARGET_MODEL_ISA_SERIAL; break; case VIR_DOMAIN_CHR_SERIAL_TARGET_TYPE_USB: chr->targetModel = VIR_DOMAIN_CHR_SERIAL_TARGET_MODEL_USB_SERIAL; break; case VIR_DOMAIN_CHR_SERIAL_TARGET_TYPE_PCI: chr->targetModel = VIR_DOMAIN_CHR_SERIAL_TARGET_MODEL_PCI_SERIAL; break; case VIR_DOMAIN_CHR_SERIAL_TARGET_TYPE_SPAPR_VIO: chr->targetModel = VIR_DOMAIN_CHR_SERIAL_TARGET_MODEL_SPAPR_VTY; break; case VIR_DOMAIN_CHR_SERIAL_TARGET_TYPE_SYSTEM: chr->targetModel = VIR_DOMAIN_CHR_SERIAL_TARGET_MODEL_PL011; break; case VIR_DOMAIN_CHR_SERIAL_TARGET_TYPE_SCLP: chr->targetModel = VIR_DOMAIN_CHR_SERIAL_TARGET_MODEL_SCLPCONSOLE; break; case VIR_DOMAIN_CHR_SERIAL_TARGET_TYPE_NONE: case VIR_DOMAIN_CHR_SERIAL_TARGET_TYPE_LAST: /* Nothing to do */ break; } } /* clear auto generated unix socket path for inactive definitions */ if (parseFlags & VIR_DOMAIN_DEF_PARSE_INACTIVE) { if (qemuDomainChrDefDropDefaultPath(chr, driver) < 0) return -1; /* For UNIX chardev if no path is provided we generate one. * This also implies that the mode is 'bind'. */ if (chr->source && chr->source->type == VIR_DOMAIN_CHR_TYPE_UNIX && !chr->source->data.nix.path) { chr->source->data.nix.listen = true; } } return 0; } static int qemuDomainDeviceDefPostParse(virDomainDeviceDefPtr dev, const virDomainDef *def, virCapsPtr caps ATTRIBUTE_UNUSED, unsigned int parseFlags, void *opaque, void *parseOpaque) { virQEMUDriverPtr driver = opaque; /* Note that qemuCaps may be NULL when this function is called. This * function shall not fail in that case. It will be re-run on VM startup * with the capabilities populated. */ virQEMUCapsPtr qemuCaps = parseOpaque; virQEMUDriverConfigPtr cfg = virQEMUDriverGetConfig(driver); int ret = -1; if (dev->type == VIR_DOMAIN_DEVICE_NET && dev->data.net->type != VIR_DOMAIN_NET_TYPE_HOSTDEV && !dev->data.net->model) { if (VIR_STRDUP(dev->data.net->model, qemuDomainDefaultNetModel(def, qemuCaps)) < 0) goto cleanup; } /* set default disk types and drivers */ if (dev->type == VIR_DOMAIN_DEVICE_DISK) { virDomainDiskDefPtr disk = dev->data.disk; /* assign default storage format and driver according to config */ if (cfg->allowDiskFormatProbing) { /* default disk format for drives */ if (virDomainDiskGetFormat(disk) == VIR_STORAGE_FILE_NONE && (virDomainDiskGetType(disk) == VIR_STORAGE_TYPE_FILE || virDomainDiskGetType(disk) == VIR_STORAGE_TYPE_BLOCK)) virDomainDiskSetFormat(disk, VIR_STORAGE_FILE_AUTO); /* default disk format for mirrored drive */ if (disk->mirror && disk->mirror->format == VIR_STORAGE_FILE_NONE) disk->mirror->format = VIR_STORAGE_FILE_AUTO; } else { /* default driver if probing is forbidden */ if (!virDomainDiskGetDriver(disk) && virDomainDiskSetDriver(disk, "qemu") < 0) goto cleanup; /* default disk format for drives */ if (virDomainDiskGetFormat(disk) == VIR_STORAGE_FILE_NONE && (virDomainDiskGetType(disk) == VIR_STORAGE_TYPE_FILE || virDomainDiskGetType(disk) == VIR_STORAGE_TYPE_BLOCK)) virDomainDiskSetFormat(disk, VIR_STORAGE_FILE_RAW); /* default disk format for mirrored drive */ if (disk->mirror && disk->mirror->format == VIR_STORAGE_FILE_NONE) disk->mirror->format = VIR_STORAGE_FILE_RAW; } } if (dev->type == VIR_DOMAIN_DEVICE_VIDEO) { if (dev->data.video->type == VIR_DOMAIN_VIDEO_TYPE_DEFAULT) { if ARCH_IS_PPC64(def->os.arch) dev->data.video->type = VIR_DOMAIN_VIDEO_TYPE_VGA; else if (qemuDomainIsVirt(def)) dev->data.video->type = VIR_DOMAIN_VIDEO_TYPE_VIRTIO; else dev->data.video->type = VIR_DOMAIN_VIDEO_TYPE_CIRRUS; } if (dev->data.video->type == VIR_DOMAIN_VIDEO_TYPE_QXL && !dev->data.video->vgamem) { dev->data.video->vgamem = QEMU_QXL_VGAMEM_DEFAULT; } } if (dev->type == VIR_DOMAIN_DEVICE_PANIC && dev->data.panic->model == VIR_DOMAIN_PANIC_MODEL_DEFAULT) { if (qemuDomainIsPSeries(def)) dev->data.panic->model = VIR_DOMAIN_PANIC_MODEL_PSERIES; else if (ARCH_IS_S390(def->os.arch)) dev->data.panic->model = VIR_DOMAIN_PANIC_MODEL_S390; else dev->data.panic->model = VIR_DOMAIN_PANIC_MODEL_ISA; } if (dev->type == VIR_DOMAIN_DEVICE_CONTROLLER && qemuDomainControllerDefPostParse(dev->data.controller, def, qemuCaps, parseFlags) < 0) goto cleanup; if (dev->type == VIR_DOMAIN_DEVICE_SHMEM && qemuDomainShmemDefPostParse(dev->data.shmem) < 0) goto cleanup; if (dev->type == VIR_DOMAIN_DEVICE_CHR && qemuDomainChrDefPostParse(dev->data.chr, def, driver, parseFlags) < 0) { goto cleanup; } ret = 0; cleanup: virObjectUnref(cfg); return ret; } static int qemuDomainDefAssignAddresses(virDomainDef *def, virCapsPtr caps ATTRIBUTE_UNUSED, unsigned int parseFlags ATTRIBUTE_UNUSED, void *opaque, void *parseOpaque) { virQEMUDriverPtr driver = opaque; /* Note that qemuCaps may be NULL when this function is called. This * function shall not fail in that case. It will be re-run on VM startup * with the capabilities populated. */ virQEMUCapsPtr qemuCaps = parseOpaque; bool newDomain = parseFlags & VIR_DOMAIN_DEF_PARSE_ABI_UPDATE; /* Skip address assignment if @qemuCaps is not present. In such case devices * which are automatically added may be missing. Additionally @qemuCaps should * only be missing when reloading configs, thus addresses were already * assigned. */ if (!qemuCaps) return 1; return qemuDomainAssignAddresses(def, qemuCaps, driver, NULL, newDomain); } static int qemuDomainPostParseDataAlloc(const virDomainDef *def, virCapsPtr caps ATTRIBUTE_UNUSED, unsigned int parseFlags ATTRIBUTE_UNUSED, void *opaque, void **parseOpaque) { virQEMUDriverPtr driver = opaque; if (!(*parseOpaque = virQEMUCapsCacheLookup(driver->qemuCapsCache, def->emulator))) return 1; return 0; } static void qemuDomainPostParseDataFree(void *parseOpaque) { virQEMUCapsPtr qemuCaps = parseOpaque; virObjectUnref(qemuCaps); } virDomainDefParserConfig virQEMUDriverDomainDefParserConfig = { .domainPostParseBasicCallback = qemuDomainDefPostParseBasic, .domainPostParseDataAlloc = qemuDomainPostParseDataAlloc, .domainPostParseDataFree = qemuDomainPostParseDataFree, .devicesPostParseCallback = qemuDomainDeviceDefPostParse, .domainPostParseCallback = qemuDomainDefPostParse, .assignAddressesCallback = qemuDomainDefAssignAddresses, .domainValidateCallback = qemuDomainDefValidate, .deviceValidateCallback = qemuDomainDeviceDefValidate, .features = VIR_DOMAIN_DEF_FEATURE_MEMORY_HOTPLUG | VIR_DOMAIN_DEF_FEATURE_OFFLINE_VCPUPIN | VIR_DOMAIN_DEF_FEATURE_INDIVIDUAL_VCPUS | VIR_DOMAIN_DEF_FEATURE_USER_ALIAS, }; static void qemuDomainObjSaveJob(virQEMUDriverPtr driver, virDomainObjPtr obj) { virQEMUDriverConfigPtr cfg = virQEMUDriverGetConfig(driver); if (virDomainObjIsActive(obj)) { if (virDomainSaveStatus(driver->xmlopt, cfg->stateDir, obj, driver->caps) < 0) VIR_WARN("Failed to save status on vm %s", obj->def->name); } virObjectUnref(cfg); } void qemuDomainObjSetJobPhase(virQEMUDriverPtr driver, virDomainObjPtr obj, int phase) { qemuDomainObjPrivatePtr priv = obj->privateData; unsigned long long me = virThreadSelfID(); if (!priv->job.asyncJob) return; VIR_DEBUG("Setting '%s' phase to '%s'", qemuDomainAsyncJobTypeToString(priv->job.asyncJob), qemuDomainAsyncJobPhaseToString(priv->job.asyncJob, phase)); if (priv->job.asyncOwner && me != priv->job.asyncOwner) { VIR_WARN("'%s' async job is owned by thread %llu", qemuDomainAsyncJobTypeToString(priv->job.asyncJob), priv->job.asyncOwner); } priv->job.phase = phase; priv->job.asyncOwner = me; qemuDomainObjSaveJob(driver, obj); } void qemuDomainObjSetAsyncJobMask(virDomainObjPtr obj, unsigned long long allowedJobs) { qemuDomainObjPrivatePtr priv = obj->privateData; if (!priv->job.asyncJob) return; priv->job.mask = allowedJobs | JOB_MASK(QEMU_JOB_DESTROY); } void qemuDomainObjDiscardAsyncJob(virQEMUDriverPtr driver, virDomainObjPtr obj) { qemuDomainObjPrivatePtr priv = obj->privateData; if (priv->job.active == QEMU_JOB_ASYNC_NESTED) qemuDomainObjResetJob(priv); qemuDomainObjResetAsyncJob(priv); qemuDomainObjSaveJob(driver, obj); } void qemuDomainObjReleaseAsyncJob(virDomainObjPtr obj) { qemuDomainObjPrivatePtr priv = obj->privateData; VIR_DEBUG("Releasing ownership of '%s' async job", qemuDomainAsyncJobTypeToString(priv->job.asyncJob)); if (priv->job.asyncOwner != virThreadSelfID()) { VIR_WARN("'%s' async job is owned by thread %llu", qemuDomainAsyncJobTypeToString(priv->job.asyncJob), priv->job.asyncOwner); } priv->job.asyncOwner = 0; } static bool qemuDomainNestedJobAllowed(qemuDomainObjPrivatePtr priv, qemuDomainJob job) { return !priv->job.asyncJob || (priv->job.mask & JOB_MASK(job)) != 0; } bool qemuDomainJobAllowed(qemuDomainObjPrivatePtr priv, qemuDomainJob job) { return !priv->job.active && qemuDomainNestedJobAllowed(priv, job); } /* Give up waiting for mutex after 30 seconds */ #define QEMU_JOB_WAIT_TIME (1000ull * 30) /* * obj must be locked before calling */ static int ATTRIBUTE_NONNULL(1) qemuDomainObjBeginJobInternal(virQEMUDriverPtr driver, virDomainObjPtr obj, qemuDomainJob job, qemuDomainAsyncJob asyncJob) { qemuDomainObjPrivatePtr priv = obj->privateData; unsigned long long now; unsigned long long then; bool nested = job == QEMU_JOB_ASYNC_NESTED; bool async = job == QEMU_JOB_ASYNC; virQEMUDriverConfigPtr cfg = virQEMUDriverGetConfig(driver); const char *blocker = NULL; int ret = -1; unsigned long long duration = 0; unsigned long long asyncDuration = 0; const char *jobStr; if (async) jobStr = qemuDomainAsyncJobTypeToString(asyncJob); else jobStr = qemuDomainJobTypeToString(job); VIR_DEBUG("Starting %s: %s (vm=%p name=%s, current job=%s async=%s)", async ? "async job" : "job", jobStr, obj, obj->def->name, qemuDomainJobTypeToString(priv->job.active), qemuDomainAsyncJobTypeToString(priv->job.asyncJob)); if (virTimeMillisNow(&now) < 0) { virObjectUnref(cfg); return -1; } priv->jobs_queued++; then = now + QEMU_JOB_WAIT_TIME; retry: if (cfg->maxQueuedJobs && priv->jobs_queued > cfg->maxQueuedJobs) { goto error; } while (!nested && !qemuDomainNestedJobAllowed(priv, job)) { VIR_DEBUG("Waiting for async job (vm=%p name=%s)", obj, obj->def->name); if (virCondWaitUntil(&priv->job.asyncCond, &obj->parent.lock, then) < 0) goto error; } while (priv->job.active) { VIR_DEBUG("Waiting for job (vm=%p name=%s)", obj, obj->def->name); if (virCondWaitUntil(&priv->job.cond, &obj->parent.lock, then) < 0) goto error; } /* No job is active but a new async job could have been started while obj * was unlocked, so we need to recheck it. */ if (!nested && !qemuDomainNestedJobAllowed(priv, job)) goto retry; qemuDomainObjResetJob(priv); ignore_value(virTimeMillisNow(&now)); if (job != QEMU_JOB_ASYNC) { VIR_DEBUG("Started job: %s (async=%s vm=%p name=%s)", qemuDomainJobTypeToString(job), qemuDomainAsyncJobTypeToString(priv->job.asyncJob), obj, obj->def->name); priv->job.active = job; priv->job.owner = virThreadSelfID(); priv->job.ownerAPI = virThreadJobGet(); priv->job.started = now; } else { VIR_DEBUG("Started async job: %s (vm=%p name=%s)", qemuDomainAsyncJobTypeToString(asyncJob), obj, obj->def->name); qemuDomainObjResetAsyncJob(priv); if (VIR_ALLOC(priv->job.current) < 0) goto cleanup; priv->job.current->status = QEMU_DOMAIN_JOB_STATUS_ACTIVE; priv->job.asyncJob = asyncJob; priv->job.asyncOwner = virThreadSelfID(); priv->job.asyncOwnerAPI = virThreadJobGet(); priv->job.asyncStarted = now; priv->job.current->started = now; } if (qemuDomainTrackJob(job)) qemuDomainObjSaveJob(driver, obj); virObjectUnref(cfg); return 0; error: ignore_value(virTimeMillisNow(&now)); if (priv->job.active && priv->job.started) duration = now - priv->job.started; if (priv->job.asyncJob && priv->job.asyncStarted) asyncDuration = now - priv->job.asyncStarted; VIR_WARN("Cannot start job (%s, %s) for domain %s; " "current job is (%s, %s) owned by (%llu %s, %llu %s) " "for (%llus, %llus)", qemuDomainJobTypeToString(job), qemuDomainAsyncJobTypeToString(asyncJob), obj->def->name, qemuDomainJobTypeToString(priv->job.active), qemuDomainAsyncJobTypeToString(priv->job.asyncJob), priv->job.owner, NULLSTR(priv->job.ownerAPI), priv->job.asyncOwner, NULLSTR(priv->job.asyncOwnerAPI), duration / 1000, asyncDuration / 1000); if (nested || qemuDomainNestedJobAllowed(priv, job)) blocker = priv->job.ownerAPI; else blocker = priv->job.asyncOwnerAPI; ret = -1; if (errno == ETIMEDOUT) { if (blocker) { virReportError(VIR_ERR_OPERATION_TIMEOUT, _("cannot acquire state change lock (held by %s)"), blocker); } else { virReportError(VIR_ERR_OPERATION_TIMEOUT, "%s", _("cannot acquire state change lock")); } ret = -2; } else if (cfg->maxQueuedJobs && priv->jobs_queued > cfg->maxQueuedJobs) { if (blocker) { virReportError(VIR_ERR_OPERATION_FAILED, _("cannot acquire state change lock (held by %s) " "due to max_queued limit"), blocker); } else { virReportError(VIR_ERR_OPERATION_FAILED, "%s", _("cannot acquire state change lock " "due to max_queued limit")); } ret = -2; } else { virReportSystemError(errno, "%s", _("cannot acquire job mutex")); } cleanup: priv->jobs_queued--; virObjectUnref(cfg); return ret; } /* * obj must be locked before calling * * This must be called by anything that will change the VM state * in any way, or anything that will use the QEMU monitor. * * Successful calls must be followed by EndJob eventually */ int qemuDomainObjBeginJob(virQEMUDriverPtr driver, virDomainObjPtr obj, qemuDomainJob job) { if (qemuDomainObjBeginJobInternal(driver, obj, job, QEMU_ASYNC_JOB_NONE) < 0) return -1; else return 0; } int qemuDomainObjBeginAsyncJob(virQEMUDriverPtr driver, virDomainObjPtr obj, qemuDomainAsyncJob asyncJob, virDomainJobOperation operation) { qemuDomainObjPrivatePtr priv; if (qemuDomainObjBeginJobInternal(driver, obj, QEMU_JOB_ASYNC, asyncJob) < 0) return -1; priv = obj->privateData; priv->job.current->operation = operation; return 0; } int qemuDomainObjBeginNestedJob(virQEMUDriverPtr driver, virDomainObjPtr obj, qemuDomainAsyncJob asyncJob) { qemuDomainObjPrivatePtr priv = obj->privateData; if (asyncJob != priv->job.asyncJob) { virReportError(VIR_ERR_INTERNAL_ERROR, _("unexpected async job %d"), asyncJob); return -1; } if (priv->job.asyncOwner != virThreadSelfID()) { VIR_WARN("This thread doesn't seem to be the async job owner: %llu", priv->job.asyncOwner); } return qemuDomainObjBeginJobInternal(driver, obj, QEMU_JOB_ASYNC_NESTED, QEMU_ASYNC_JOB_NONE); } /* * obj must be locked and have a reference before calling * * To be called after completing the work associated with the * earlier qemuDomainBeginJob() call */ void qemuDomainObjEndJob(virQEMUDriverPtr driver, virDomainObjPtr obj) { qemuDomainObjPrivatePtr priv = obj->privateData; qemuDomainJob job = priv->job.active; priv->jobs_queued--; VIR_DEBUG("Stopping job: %s (async=%s vm=%p name=%s)", qemuDomainJobTypeToString(job), qemuDomainAsyncJobTypeToString(priv->job.asyncJob), obj, obj->def->name); qemuDomainObjResetJob(priv); if (qemuDomainTrackJob(job)) qemuDomainObjSaveJob(driver, obj); virCondSignal(&priv->job.cond); } void qemuDomainObjEndAsyncJob(virQEMUDriverPtr driver, virDomainObjPtr obj) { qemuDomainObjPrivatePtr priv = obj->privateData; priv->jobs_queued--; VIR_DEBUG("Stopping async job: %s (vm=%p name=%s)", qemuDomainAsyncJobTypeToString(priv->job.asyncJob), obj, obj->def->name); qemuDomainObjResetAsyncJob(priv); qemuDomainObjSaveJob(driver, obj); virCondBroadcast(&priv->job.asyncCond); } void qemuDomainObjAbortAsyncJob(virDomainObjPtr obj) { qemuDomainObjPrivatePtr priv = obj->privateData; VIR_DEBUG("Requesting abort of async job: %s (vm=%p name=%s)", qemuDomainAsyncJobTypeToString(priv->job.asyncJob), obj, obj->def->name); priv->job.abortJob = true; virDomainObjBroadcast(obj); } /* * obj must be locked before calling * * To be called immediately before any QEMU monitor API call * Must have already either called qemuDomainObjBeginJob() and checked * that the VM is still active; may not be used for nested async jobs. * * To be followed with qemuDomainObjExitMonitor() once complete */ static int qemuDomainObjEnterMonitorInternal(virQEMUDriverPtr driver, virDomainObjPtr obj, qemuDomainAsyncJob asyncJob) { qemuDomainObjPrivatePtr priv = obj->privateData; if (asyncJob != QEMU_ASYNC_JOB_NONE) { int ret; if ((ret = qemuDomainObjBeginNestedJob(driver, obj, asyncJob)) < 0) return ret; if (!virDomainObjIsActive(obj)) { virReportError(VIR_ERR_OPERATION_FAILED, "%s", _("domain is no longer running")); qemuDomainObjEndJob(driver, obj); return -1; } } else if (priv->job.asyncOwner == virThreadSelfID()) { VIR_WARN("This thread seems to be the async job owner; entering" " monitor without asking for a nested job is dangerous"); } VIR_DEBUG("Entering monitor (mon=%p vm=%p name=%s)", priv->mon, obj, obj->def->name); virObjectLock(priv->mon); virObjectRef(priv->mon); ignore_value(virTimeMillisNow(&priv->monStart)); virObjectUnlock(obj); return 0; } static void ATTRIBUTE_NONNULL(1) qemuDomainObjExitMonitorInternal(virQEMUDriverPtr driver, virDomainObjPtr obj) { qemuDomainObjPrivatePtr priv = obj->privateData; bool hasRefs; hasRefs = virObjectUnref(priv->mon); if (hasRefs) virObjectUnlock(priv->mon); virObjectLock(obj); VIR_DEBUG("Exited monitor (mon=%p vm=%p name=%s)", priv->mon, obj, obj->def->name); priv->monStart = 0; if (!hasRefs) priv->mon = NULL; if (priv->job.active == QEMU_JOB_ASYNC_NESTED) qemuDomainObjEndJob(driver, obj); } void qemuDomainObjEnterMonitor(virQEMUDriverPtr driver, virDomainObjPtr obj) { ignore_value(qemuDomainObjEnterMonitorInternal(driver, obj, QEMU_ASYNC_JOB_NONE)); } /* obj must NOT be locked before calling * * Should be paired with an earlier qemuDomainObjEnterMonitor() call * * Returns -1 if the domain is no longer alive after exiting the monitor. * In that case, the caller should be careful when using obj's data, * e.g. the live definition in vm->def has been freed by qemuProcessStop * and replaced by the persistent definition, so pointers stolen * from the live definition could no longer be valid. */ int qemuDomainObjExitMonitor(virQEMUDriverPtr driver, virDomainObjPtr obj) { qemuDomainObjExitMonitorInternal(driver, obj); if (!virDomainObjIsActive(obj)) { if (!virGetLastError()) virReportError(VIR_ERR_OPERATION_FAILED, "%s", _("domain is no longer running")); return -1; } return 0; } /* * obj must be locked before calling * * To be called immediately before any QEMU monitor API call. * Must have already either called qemuDomainObjBeginJob() * and checked that the VM is still active, with asyncJob of * QEMU_ASYNC_JOB_NONE; or already called qemuDomainObjBeginAsyncJob, * with the same asyncJob. * * Returns 0 if job was started, in which case this must be followed with * qemuDomainObjExitMonitor(); -2 if waiting for the nested job times out; * or -1 if the job could not be started (probably because the vm exited * in the meantime). */ int qemuDomainObjEnterMonitorAsync(virQEMUDriverPtr driver, virDomainObjPtr obj, qemuDomainAsyncJob asyncJob) { return qemuDomainObjEnterMonitorInternal(driver, obj, asyncJob); } /* * obj must be locked before calling * * To be called immediately before any QEMU agent API call. * Must have already called qemuDomainObjBeginJob() and checked * that the VM is still active. * * To be followed with qemuDomainObjExitAgent() once complete */ qemuAgentPtr qemuDomainObjEnterAgent(virDomainObjPtr obj) { qemuDomainObjPrivatePtr priv = obj->privateData; qemuAgentPtr agent = priv->agent; VIR_DEBUG("Entering agent (agent=%p vm=%p name=%s)", priv->agent, obj, obj->def->name); virObjectLock(agent); virObjectRef(agent); virObjectUnlock(obj); return agent; } /* obj must NOT be locked before calling * * Should be paired with an earlier qemuDomainObjEnterAgent() call */ void qemuDomainObjExitAgent(virDomainObjPtr obj, qemuAgentPtr agent) { virObjectUnlock(agent); virObjectUnref(agent); virObjectLock(obj); VIR_DEBUG("Exited agent (agent=%p vm=%p name=%s)", agent, obj, obj->def->name); } void qemuDomainObjEnterRemote(virDomainObjPtr obj) { VIR_DEBUG("Entering remote (vm=%p name=%s)", obj, obj->def->name); virObjectUnlock(obj); } void qemuDomainObjExitRemote(virDomainObjPtr obj) { virObjectLock(obj); VIR_DEBUG("Exited remote (vm=%p name=%s)", obj, obj->def->name); } static virDomainDefPtr qemuDomainDefFromXML(virQEMUDriverPtr driver, const char *xml) { virCapsPtr caps; virDomainDefPtr def; if (!(caps = virQEMUDriverGetCapabilities(driver, false))) return NULL; def = virDomainDefParseString(xml, caps, driver->xmlopt, NULL, VIR_DOMAIN_DEF_PARSE_INACTIVE | VIR_DOMAIN_DEF_PARSE_SKIP_VALIDATE); virObjectUnref(caps); return def; } virDomainDefPtr qemuDomainDefCopy(virQEMUDriverPtr driver, virDomainDefPtr src, unsigned int flags) { virDomainDefPtr ret = NULL; char *xml; if (!(xml = qemuDomainDefFormatXML(driver, src, flags))) return NULL; ret = qemuDomainDefFromXML(driver, xml); VIR_FREE(xml); return ret; } static int qemuDomainDefFormatBufInternal(virQEMUDriverPtr driver, virDomainDefPtr def, virCPUDefPtr origCPU, unsigned int flags, virBuffer *buf) { int ret = -1; virDomainDefPtr copy = NULL; virCapsPtr caps = NULL; virQEMUCapsPtr qemuCaps = NULL; if (!(caps = virQEMUDriverGetCapabilities(driver, false))) goto cleanup; if (!(flags & (VIR_DOMAIN_XML_UPDATE_CPU | VIR_DOMAIN_XML_MIGRATABLE))) goto format; if (!(copy = virDomainDefCopy(def, caps, driver->xmlopt, NULL, flags & VIR_DOMAIN_XML_MIGRATABLE))) goto cleanup; def = copy; /* Update guest CPU requirements according to host CPU */ if ((flags & VIR_DOMAIN_XML_UPDATE_CPU) && def->cpu && (def->cpu->mode != VIR_CPU_MODE_CUSTOM || def->cpu->model)) { if (!(qemuCaps = virQEMUCapsCacheLookupCopy(driver->qemuCapsCache, def->emulator, def->os.machine))) goto cleanup; if (virCPUUpdate(def->os.arch, def->cpu, virQEMUCapsGetHostModel(qemuCaps, def->virtType, VIR_QEMU_CAPS_HOST_CPU_MIGRATABLE)) < 0) goto cleanup; } if ((flags & VIR_DOMAIN_XML_MIGRATABLE)) { size_t i; int toremove = 0; virDomainControllerDefPtr usb = NULL, pci = NULL; /* If only the default USB controller is present, we can remove it * and make the XML compatible with older versions of libvirt which * didn't support USB controllers in the XML but always added the * default one to qemu anyway. */ for (i = 0; i < def->ncontrollers; i++) { if (def->controllers[i]->type == VIR_DOMAIN_CONTROLLER_TYPE_USB) { if (usb) { usb = NULL; break; } usb = def->controllers[i]; } } /* In order to maintain compatibility with version of libvirt that * didn't support (<= 0.9.4), we need to * drop the default USB controller, ie. a USB controller at index * zero with no model or with the default piix3-ohci model. * * However, we only need to do so for x86 i440fx machine types, * because other architectures and machine types were introduced * when libvirt already supported . */ if (ARCH_IS_X86(def->os.arch) && qemuDomainIsI440FX(def) && usb && usb->idx == 0 && (usb->model == -1 || usb->model == VIR_DOMAIN_CONTROLLER_MODEL_USB_PIIX3_UHCI)) { VIR_DEBUG("Removing default USB controller from domain '%s'" " for migration compatibility", def->name); toremove++; } else { usb = NULL; } /* Remove the default PCI controller if there is only one present * and its model is pci-root */ for (i = 0; i < def->ncontrollers; i++) { if (def->controllers[i]->type == VIR_DOMAIN_CONTROLLER_TYPE_PCI) { if (pci) { pci = NULL; break; } pci = def->controllers[i]; } } if (pci && pci->idx == 0 && pci->model == VIR_DOMAIN_CONTROLLER_MODEL_PCI_ROOT) { VIR_DEBUG("Removing default pci-root from domain '%s'" " for migration compatibility", def->name); toremove++; } else { pci = NULL; } if (toremove) { virDomainControllerDefPtr *controllers = def->controllers; int ncontrollers = def->ncontrollers; if (VIR_ALLOC_N(def->controllers, ncontrollers - toremove) < 0) { def->controllers = controllers; goto cleanup; } def->ncontrollers = 0; for (i = 0; i < ncontrollers; i++) { if (controllers[i] != usb && controllers[i] != pci) def->controllers[def->ncontrollers++] = controllers[i]; } VIR_FREE(controllers); virDomainControllerDefFree(pci); virDomainControllerDefFree(usb); } /* Remove the panic device for selected models if present */ for (i = 0; i < def->npanics; i++) { if (def->panics[i]->model == VIR_DOMAIN_PANIC_MODEL_S390 || def->panics[i]->model == VIR_DOMAIN_PANIC_MODEL_PSERIES) { VIR_DELETE_ELEMENT(def->panics, i, def->npanics); break; } } for (i = 0; i < def->nchannels; i++) { if (qemuDomainChrDefDropDefaultPath(def->channels[i], driver) < 0) goto cleanup; } for (i = 0; i < def->nserials; i++) { virDomainChrDefPtr serial = def->serials[i]; /* Historically, the native console type for some machine types * was not set at all, which means it defaulted to ISA even * though that was not even remotely accurate. To ensure migration * towards older libvirt versions works for such guests, we switch * it back to the default here */ if (flags & VIR_DOMAIN_XML_MIGRATABLE) { switch ((virDomainChrSerialTargetType) serial->targetType) { case VIR_DOMAIN_CHR_SERIAL_TARGET_TYPE_SPAPR_VIO: case VIR_DOMAIN_CHR_SERIAL_TARGET_TYPE_SYSTEM: serial->targetType = VIR_DOMAIN_CHR_SERIAL_TARGET_TYPE_NONE; serial->targetModel = VIR_DOMAIN_CHR_SERIAL_TARGET_MODEL_NONE; break; case VIR_DOMAIN_CHR_SERIAL_TARGET_TYPE_ISA: case VIR_DOMAIN_CHR_SERIAL_TARGET_TYPE_PCI: case VIR_DOMAIN_CHR_SERIAL_TARGET_TYPE_USB: case VIR_DOMAIN_CHR_SERIAL_TARGET_TYPE_SCLP: case VIR_DOMAIN_CHR_SERIAL_TARGET_TYPE_NONE: case VIR_DOMAIN_CHR_SERIAL_TARGET_TYPE_LAST: /* Nothing to do */ break; } } } /* Replace the CPU definition updated according to QEMU with the one * used for starting the domain. The updated def will be sent * separately for backward compatibility. */ if (origCPU) { virCPUDefFree(def->cpu); if (!(def->cpu = virCPUDefCopy(origCPU))) goto cleanup; } } format: ret = virDomainDefFormatInternal(def, caps, virDomainDefFormatConvertXMLFlags(flags), buf, driver->xmlopt); cleanup: virDomainDefFree(copy); virObjectUnref(caps); virObjectUnref(qemuCaps); return ret; } int qemuDomainDefFormatBuf(virQEMUDriverPtr driver, virDomainDefPtr def, unsigned int flags, virBufferPtr buf) { return qemuDomainDefFormatBufInternal(driver, def, NULL, flags, buf); } static char * qemuDomainDefFormatXMLInternal(virQEMUDriverPtr driver, virDomainDefPtr def, virCPUDefPtr origCPU, unsigned int flags) { virBuffer buf = VIR_BUFFER_INITIALIZER; if (qemuDomainDefFormatBufInternal(driver, def, origCPU, flags, &buf) < 0) return NULL; return virBufferContentAndReset(&buf); } char * qemuDomainDefFormatXML(virQEMUDriverPtr driver, virDomainDefPtr def, unsigned int flags) { return qemuDomainDefFormatXMLInternal(driver, def, NULL, flags); } char *qemuDomainFormatXML(virQEMUDriverPtr driver, virDomainObjPtr vm, unsigned int flags) { virDomainDefPtr def; qemuDomainObjPrivatePtr priv = vm->privateData; virCPUDefPtr origCPU = NULL; if ((flags & VIR_DOMAIN_XML_INACTIVE) && vm->newDef) { def = vm->newDef; } else { def = vm->def; origCPU = priv->origCPU; } return qemuDomainDefFormatXMLInternal(driver, def, origCPU, flags); } char * qemuDomainDefFormatLive(virQEMUDriverPtr driver, virDomainDefPtr def, virCPUDefPtr origCPU, bool inactive, bool compatible) { unsigned int flags = QEMU_DOMAIN_FORMAT_LIVE_FLAGS; if (inactive) flags |= VIR_DOMAIN_XML_INACTIVE; if (compatible) flags |= VIR_DOMAIN_XML_MIGRATABLE; return qemuDomainDefFormatXMLInternal(driver, def, origCPU, flags); } /* qemuDomainFilePathIsHostCDROM * @path: Supplied path. * * Determine if the path is a host CD-ROM path. Typically this is * either /dev/cdrom[n] or /dev/srN, so those are easy checks, but * it's also possible that @path resolves to /dev/srN, so check for * those conditions on @path in order to emit the tainted message. * * Returns true if the path is a CDROM, false otherwise or on error. */ static bool qemuDomainFilePathIsHostCDROM(const char *path) { bool ret = false; char *linkpath = NULL; if (virFileResolveLink(path, &linkpath) < 0) goto cleanup; if (STRPREFIX(path, "/dev/cdrom") || STRPREFIX(path, "/dev/sr") || STRPREFIX(linkpath, "/dev/sr")) ret = true; cleanup: VIR_FREE(linkpath); return ret; } void qemuDomainObjTaint(virQEMUDriverPtr driver, virDomainObjPtr obj, virDomainTaintFlags taint, qemuDomainLogContextPtr logCtxt) { virErrorPtr orig_err = NULL; bool closeLog = false; char *timestamp = NULL; char uuidstr[VIR_UUID_STRING_BUFLEN]; if (!virDomainObjTaint(obj, taint)) return; virUUIDFormat(obj->def->uuid, uuidstr); VIR_WARN("Domain id=%d name='%s' uuid=%s is tainted: %s", obj->def->id, obj->def->name, uuidstr, virDomainTaintTypeToString(taint)); /* We don't care about errors logging taint info, so * preserve original error, and clear any error that * is raised */ orig_err = virSaveLastError(); if (!(timestamp = virTimeStringNow())) goto cleanup; if (logCtxt == NULL) { logCtxt = qemuDomainLogContextNew(driver, obj, QEMU_DOMAIN_LOG_CONTEXT_MODE_ATTACH); if (!logCtxt) { VIR_WARN("Unable to open domainlog"); goto cleanup; } closeLog = true; } if (qemuDomainLogContextWrite(logCtxt, "%s: Domain id=%d is tainted: %s\n", timestamp, obj->def->id, virDomainTaintTypeToString(taint)) < 0) virResetLastError(); cleanup: VIR_FREE(timestamp); if (closeLog) virObjectUnref(logCtxt); if (orig_err) { virSetError(orig_err); virFreeError(orig_err); } } void qemuDomainObjCheckTaint(virQEMUDriverPtr driver, virDomainObjPtr obj, qemuDomainLogContextPtr logCtxt) { size_t i; virQEMUDriverConfigPtr cfg = virQEMUDriverGetConfig(driver); qemuDomainObjPrivatePtr priv = obj->privateData; if (virQEMUDriverIsPrivileged(driver) && (!cfg->clearEmulatorCapabilities || cfg->user == 0 || cfg->group == 0)) qemuDomainObjTaint(driver, obj, VIR_DOMAIN_TAINT_HIGH_PRIVILEGES, logCtxt); if (priv->hookRun) qemuDomainObjTaint(driver, obj, VIR_DOMAIN_TAINT_HOOK, logCtxt); if (obj->def->namespaceData) { qemuDomainCmdlineDefPtr qemucmd = obj->def->namespaceData; if (qemucmd->num_args || qemucmd->num_env) qemuDomainObjTaint(driver, obj, VIR_DOMAIN_TAINT_CUSTOM_ARGV, logCtxt); } if (obj->def->cpu && obj->def->cpu->mode == VIR_CPU_MODE_HOST_PASSTHROUGH) qemuDomainObjTaint(driver, obj, VIR_DOMAIN_TAINT_HOST_CPU, logCtxt); for (i = 0; i < obj->def->ndisks; i++) qemuDomainObjCheckDiskTaint(driver, obj, obj->def->disks[i], logCtxt); for (i = 0; i < obj->def->nhostdevs; i++) qemuDomainObjCheckHostdevTaint(driver, obj, obj->def->hostdevs[i], logCtxt); for (i = 0; i < obj->def->nnets; i++) qemuDomainObjCheckNetTaint(driver, obj, obj->def->nets[i], logCtxt); if (obj->def->os.dtb) qemuDomainObjTaint(driver, obj, VIR_DOMAIN_TAINT_CUSTOM_DTB, logCtxt); virObjectUnref(cfg); } void qemuDomainObjCheckDiskTaint(virQEMUDriverPtr driver, virDomainObjPtr obj, virDomainDiskDefPtr disk, qemuDomainLogContextPtr logCtxt) { virQEMUDriverConfigPtr cfg = virQEMUDriverGetConfig(driver); int format = virDomainDiskGetFormat(disk); if ((!format || format == VIR_STORAGE_FILE_AUTO) && cfg->allowDiskFormatProbing) qemuDomainObjTaint(driver, obj, VIR_DOMAIN_TAINT_DISK_PROBING, logCtxt); if (disk->rawio == VIR_TRISTATE_BOOL_YES) qemuDomainObjTaint(driver, obj, VIR_DOMAIN_TAINT_HIGH_PRIVILEGES, logCtxt); if (disk->device == VIR_DOMAIN_DISK_DEVICE_CDROM && virStorageSourceGetActualType(disk->src) == VIR_STORAGE_TYPE_BLOCK && disk->src->path && qemuDomainFilePathIsHostCDROM(disk->src->path)) qemuDomainObjTaint(driver, obj, VIR_DOMAIN_TAINT_CDROM_PASSTHROUGH, logCtxt); virObjectUnref(cfg); } void qemuDomainObjCheckHostdevTaint(virQEMUDriverPtr driver, virDomainObjPtr obj, virDomainHostdevDefPtr hostdev, qemuDomainLogContextPtr logCtxt) { if (!virHostdevIsSCSIDevice(hostdev)) return; if (hostdev->source.subsys.u.scsi.rawio == VIR_TRISTATE_BOOL_YES) qemuDomainObjTaint(driver, obj, VIR_DOMAIN_TAINT_HIGH_PRIVILEGES, logCtxt); } void qemuDomainObjCheckNetTaint(virQEMUDriverPtr driver, virDomainObjPtr obj, virDomainNetDefPtr net, qemuDomainLogContextPtr logCtxt) { /* script is only useful for NET_TYPE_ETHERNET (qemu) and * NET_TYPE_BRIDGE (xen), but could be (incorrectly) specified for * any interface type. In any case, it's adding user sauce into * the soup, so it should taint the domain. */ if (net->script != NULL) qemuDomainObjTaint(driver, obj, VIR_DOMAIN_TAINT_SHELL_SCRIPTS, logCtxt); } qemuDomainLogContextPtr qemuDomainLogContextNew(virQEMUDriverPtr driver, virDomainObjPtr vm, qemuDomainLogContextMode mode) { virQEMUDriverConfigPtr cfg = virQEMUDriverGetConfig(driver); qemuDomainLogContextPtr ctxt = NULL; if (qemuDomainInitialize() < 0) goto cleanup; if (!(ctxt = virObjectNew(qemuDomainLogContextClass))) goto cleanup; VIR_DEBUG("Context new %p stdioLogD=%d", ctxt, cfg->stdioLogD); ctxt->writefd = -1; ctxt->readfd = -1; if (virAsprintf(&ctxt->path, "%s/%s.log", cfg->logDir, vm->def->name) < 0) goto error; if (cfg->stdioLogD) { ctxt->manager = virLogManagerNew(virQEMUDriverIsPrivileged(driver)); if (!ctxt->manager) goto error; ctxt->writefd = virLogManagerDomainOpenLogFile(ctxt->manager, "qemu", vm->def->uuid, vm->def->name, ctxt->path, 0, &ctxt->inode, &ctxt->pos); if (ctxt->writefd < 0) goto error; } else { if ((ctxt->writefd = open(ctxt->path, O_WRONLY | O_CREAT | O_APPEND, S_IRUSR | S_IWUSR)) < 0) { virReportSystemError(errno, _("failed to create logfile %s"), ctxt->path); goto error; } if (virSetCloseExec(ctxt->writefd) < 0) { virReportSystemError(errno, _("failed to set close-on-exec flag on %s"), ctxt->path); goto error; } /* For unprivileged startup we must truncate the file since * we can't rely on logrotate. We don't use O_TRUNC since * it is better for SELinux policy if we truncate afterwards */ if (mode == QEMU_DOMAIN_LOG_CONTEXT_MODE_START && !virQEMUDriverIsPrivileged(driver) && ftruncate(ctxt->writefd, 0) < 0) { virReportSystemError(errno, _("failed to truncate %s"), ctxt->path); goto error; } if (mode == QEMU_DOMAIN_LOG_CONTEXT_MODE_START) { if ((ctxt->readfd = open(ctxt->path, O_RDONLY, S_IRUSR | S_IWUSR)) < 0) { virReportSystemError(errno, _("failed to open logfile %s"), ctxt->path); goto error; } if (virSetCloseExec(ctxt->readfd) < 0) { virReportSystemError(errno, _("failed to set close-on-exec flag on %s"), ctxt->path); goto error; } } if ((ctxt->pos = lseek(ctxt->writefd, 0, SEEK_END)) < 0) { virReportSystemError(errno, _("failed to seek in log file %s"), ctxt->path); goto error; } } cleanup: virObjectUnref(cfg); return ctxt; error: virObjectUnref(ctxt); ctxt = NULL; goto cleanup; } int qemuDomainLogContextWrite(qemuDomainLogContextPtr ctxt, const char *fmt, ...) { va_list argptr; char *message = NULL; int ret = -1; va_start(argptr, fmt); if (virVasprintf(&message, fmt, argptr) < 0) goto cleanup; if (!ctxt->manager && lseek(ctxt->writefd, 0, SEEK_END) < 0) { virReportSystemError(errno, "%s", _("Unable to seek to end of domain logfile")); goto cleanup; } if (safewrite(ctxt->writefd, message, strlen(message)) < 0) { virReportSystemError(errno, "%s", _("Unable to write to domain logfile")); goto cleanup; } ret = 0; cleanup: va_end(argptr); VIR_FREE(message); return ret; } ssize_t qemuDomainLogContextRead(qemuDomainLogContextPtr ctxt, char **msg) { VIR_DEBUG("Context read %p manager=%p inode=%llu pos=%llu", ctxt, ctxt->manager, (unsigned long long)ctxt->inode, (unsigned long long)ctxt->pos); char *buf; size_t buflen; if (ctxt->manager) { buf = virLogManagerDomainReadLogFile(ctxt->manager, ctxt->path, ctxt->inode, ctxt->pos, 1024 * 128, 0); if (!buf) return -1; buflen = strlen(buf); } else { ssize_t got; buflen = 1024 * 128; /* Best effort jump to start of messages */ ignore_value(lseek(ctxt->readfd, ctxt->pos, SEEK_SET)); if (VIR_ALLOC_N(buf, buflen) < 0) return -1; got = saferead(ctxt->readfd, buf, buflen - 1); if (got < 0) { VIR_FREE(buf); virReportSystemError(errno, "%s", _("Unable to read from log file")); return -1; } buf[got] = '\0'; ignore_value(VIR_REALLOC_N_QUIET(buf, got + 1)); buflen = got; } *msg = buf; return buflen; } /** * qemuDomainLogAppendMessage: * * This is a best-effort attempt to add a log message to the qemu log file * either by using virtlogd or the legacy approach */ int qemuDomainLogAppendMessage(virQEMUDriverPtr driver, virDomainObjPtr vm, const char *fmt, ...) { virQEMUDriverConfigPtr cfg = virQEMUDriverGetConfig(driver); virLogManagerPtr manager = NULL; va_list ap; char *path = NULL; int writefd = -1; char *message = NULL; int ret = -1; va_start(ap, fmt); if (virVasprintf(&message, fmt, ap) < 0) goto cleanup; VIR_DEBUG("Append log message (vm='%s' message='%s) stdioLogD=%d", vm->def->name, message, cfg->stdioLogD); if (virAsprintf(&path, "%s/%s.log", cfg->logDir, vm->def->name) < 0) goto cleanup; if (cfg->stdioLogD) { if (!(manager = virLogManagerNew(virQEMUDriverIsPrivileged(driver)))) goto cleanup; if (virLogManagerDomainAppendMessage(manager, "qemu", vm->def->uuid, vm->def->name, path, message, 0) < 0) goto cleanup; } else { if ((writefd = open(path, O_WRONLY | O_CREAT | O_APPEND, S_IRUSR | S_IWUSR)) < 0) { virReportSystemError(errno, _("failed to create logfile %s"), path); goto cleanup; } if (safewrite(writefd, message, strlen(message)) < 0) goto cleanup; } ret = 0; cleanup: va_end(ap); VIR_FREE(message); VIR_FORCE_CLOSE(writefd); virLogManagerFree(manager); virObjectUnref(cfg); VIR_FREE(path); return ret; } int qemuDomainLogContextGetWriteFD(qemuDomainLogContextPtr ctxt) { return ctxt->writefd; } void qemuDomainLogContextMarkPosition(qemuDomainLogContextPtr ctxt) { if (ctxt->manager) virLogManagerDomainGetLogFilePosition(ctxt->manager, ctxt->path, 0, &ctxt->inode, &ctxt->pos); else ctxt->pos = lseek(ctxt->writefd, 0, SEEK_END); } virLogManagerPtr qemuDomainLogContextGetManager(qemuDomainLogContextPtr ctxt) { return ctxt->manager; } /* Locate an appropriate 'qemu-img' binary. */ const char * qemuFindQemuImgBinary(virQEMUDriverPtr driver) { if (!driver->qemuImgBinary) virReportError(VIR_ERR_INTERNAL_ERROR, "%s", _("unable to find qemu-img")); return driver->qemuImgBinary; } int qemuDomainSnapshotWriteMetadata(virDomainObjPtr vm, virDomainSnapshotObjPtr snapshot, virCapsPtr caps, virDomainXMLOptionPtr xmlopt, char *snapshotDir) { char *newxml = NULL; int ret = -1; char *snapDir = NULL; char *snapFile = NULL; char uuidstr[VIR_UUID_STRING_BUFLEN]; virUUIDFormat(vm->def->uuid, uuidstr); newxml = virDomainSnapshotDefFormat( uuidstr, snapshot->def, caps, xmlopt, virDomainDefFormatConvertXMLFlags(QEMU_DOMAIN_FORMAT_LIVE_FLAGS), 1); if (newxml == NULL) return -1; if (virAsprintf(&snapDir, "%s/%s", snapshotDir, vm->def->name) < 0) goto cleanup; if (virFileMakePath(snapDir) < 0) { virReportSystemError(errno, _("cannot create snapshot directory '%s'"), snapDir); goto cleanup; } if (virAsprintf(&snapFile, "%s/%s.xml", snapDir, snapshot->def->name) < 0) goto cleanup; ret = virXMLSaveFile(snapFile, NULL, "snapshot-edit", newxml); cleanup: VIR_FREE(snapFile); VIR_FREE(snapDir); VIR_FREE(newxml); return ret; } /* The domain is expected to be locked and inactive. Return -1 on normal * failure, 1 if we skipped a disk due to try_all. */ static int qemuDomainSnapshotForEachQcow2Raw(virQEMUDriverPtr driver, virDomainDefPtr def, const char *name, const char *op, bool try_all, int ndisks) { const char *qemuimgarg[] = { NULL, "snapshot", NULL, NULL, NULL, NULL }; size_t i; bool skipped = false; qemuimgarg[0] = qemuFindQemuImgBinary(driver); if (qemuimgarg[0] == NULL) { /* qemuFindQemuImgBinary set the error */ return -1; } qemuimgarg[2] = op; qemuimgarg[3] = name; for (i = 0; i < ndisks; i++) { /* FIXME: we also need to handle LVM here */ if (def->disks[i]->device == VIR_DOMAIN_DISK_DEVICE_DISK) { int format = virDomainDiskGetFormat(def->disks[i]); if (format > 0 && format != VIR_STORAGE_FILE_QCOW2) { if (try_all) { /* Continue on even in the face of error, since other * disks in this VM may have the same snapshot name. */ VIR_WARN("skipping snapshot action on %s", def->disks[i]->dst); skipped = true; continue; } else if (STREQ(op, "-c") && i) { /* We must roll back partial creation by deleting * all earlier snapshots. */ qemuDomainSnapshotForEachQcow2Raw(driver, def, name, "-d", false, i); } virReportError(VIR_ERR_OPERATION_INVALID, _("Disk device '%s' does not support" " snapshotting"), def->disks[i]->dst); return -1; } qemuimgarg[4] = virDomainDiskGetSource(def->disks[i]); if (virRun(qemuimgarg, NULL) < 0) { if (try_all) { VIR_WARN("skipping snapshot action on %s", def->disks[i]->dst); skipped = true; continue; } else if (STREQ(op, "-c") && i) { /* We must roll back partial creation by deleting * all earlier snapshots. */ qemuDomainSnapshotForEachQcow2Raw(driver, def, name, "-d", false, i); } return -1; } } } return skipped ? 1 : 0; } /* The domain is expected to be locked and inactive. Return -1 on normal * failure, 1 if we skipped a disk due to try_all. */ int qemuDomainSnapshotForEachQcow2(virQEMUDriverPtr driver, virDomainObjPtr vm, virDomainSnapshotObjPtr snap, const char *op, bool try_all) { /* Prefer action on the disks in use at the time the snapshot was * created; but fall back to current definition if dealing with a * snapshot created prior to libvirt 0.9.5. */ virDomainDefPtr def = snap->def->dom; if (!def) def = vm->def; return qemuDomainSnapshotForEachQcow2Raw(driver, def, snap->def->name, op, try_all, def->ndisks); } /* Discard one snapshot (or its metadata), without reparenting any children. */ int qemuDomainSnapshotDiscard(virQEMUDriverPtr driver, virDomainObjPtr vm, virDomainSnapshotObjPtr snap, bool update_current, bool metadata_only) { char *snapFile = NULL; int ret = -1; qemuDomainObjPrivatePtr priv; virDomainSnapshotObjPtr parentsnap = NULL; virQEMUDriverConfigPtr cfg = virQEMUDriverGetConfig(driver); if (!metadata_only) { if (!virDomainObjIsActive(vm)) { /* Ignore any skipped disks */ if (qemuDomainSnapshotForEachQcow2(driver, vm, snap, "-d", true) < 0) goto cleanup; } else { priv = vm->privateData; qemuDomainObjEnterMonitor(driver, vm); /* we continue on even in the face of error */ qemuMonitorDeleteSnapshot(priv->mon, snap->def->name); ignore_value(qemuDomainObjExitMonitor(driver, vm)); } } if (virAsprintf(&snapFile, "%s/%s/%s.xml", cfg->snapshotDir, vm->def->name, snap->def->name) < 0) goto cleanup; if (snap == vm->current_snapshot) { if (update_current && snap->def->parent) { parentsnap = virDomainSnapshotFindByName(vm->snapshots, snap->def->parent); if (!parentsnap) { VIR_WARN("missing parent snapshot matching name '%s'", snap->def->parent); } else { parentsnap->def->current = true; if (qemuDomainSnapshotWriteMetadata(vm, parentsnap, driver->caps, driver->xmlopt, cfg->snapshotDir) < 0) { VIR_WARN("failed to set parent snapshot '%s' as current", snap->def->parent); parentsnap->def->current = false; parentsnap = NULL; } } } vm->current_snapshot = parentsnap; } if (unlink(snapFile) < 0) VIR_WARN("Failed to unlink %s", snapFile); virDomainSnapshotObjListRemove(vm->snapshots, snap); ret = 0; cleanup: VIR_FREE(snapFile); virObjectUnref(cfg); return ret; } /* Hash iterator callback to discard multiple snapshots. */ int qemuDomainSnapshotDiscardAll(void *payload, const void *name ATTRIBUTE_UNUSED, void *data) { virDomainSnapshotObjPtr snap = payload; virQEMUSnapRemovePtr curr = data; int err; if (snap->def->current) curr->current = true; err = qemuDomainSnapshotDiscard(curr->driver, curr->vm, snap, false, curr->metadata_only); if (err && !curr->err) curr->err = err; return 0; } int qemuDomainSnapshotDiscardAllMetadata(virQEMUDriverPtr driver, virDomainObjPtr vm) { virQEMUSnapRemove rem; rem.driver = driver; rem.vm = vm; rem.metadata_only = true; rem.err = 0; virDomainSnapshotForEach(vm->snapshots, qemuDomainSnapshotDiscardAll, &rem); return rem.err; } /** * qemuDomainRemoveInactive: * * The caller must hold a lock to the vm. */ void qemuDomainRemoveInactive(virQEMUDriverPtr driver, virDomainObjPtr vm) { char *snapDir; virQEMUDriverConfigPtr cfg; if (vm->persistent) { /* Short-circuit, we don't want to remove a persistent domain */ return; } cfg = virQEMUDriverGetConfig(driver); /* Remove any snapshot metadata prior to removing the domain */ if (qemuDomainSnapshotDiscardAllMetadata(driver, vm) < 0) { VIR_WARN("unable to remove all snapshots for domain %s", vm->def->name); } else if (virAsprintf(&snapDir, "%s/%s", cfg->snapshotDir, vm->def->name) < 0) { VIR_WARN("unable to remove snapshot directory %s/%s", cfg->snapshotDir, vm->def->name); } else { if (rmdir(snapDir) < 0 && errno != ENOENT) VIR_WARN("unable to remove snapshot directory %s", snapDir); VIR_FREE(snapDir); } virObjectRef(vm); virDomainObjListRemove(driver->domains, vm); /* * virDomainObjListRemove() leaves the domain unlocked so it can * be unref'd for other drivers that depend on that, but we still * need to reset a job and we have a reference from the API that * called this function. So we need to lock it back. This is * just a workaround for the qemu driver. * * XXX: Ideally, the global handling of domain objects and object * lists would be refactored so we don't need hacks like * this, but since that requires refactor of all drivers, * it's a work for another day. */ virObjectLock(vm); virObjectUnref(cfg); virObjectUnref(vm); } /** * qemuDomainRemoveInactiveJob: * * Just like qemuDomainRemoveInactive but it tries to grab a * QEMU_JOB_MODIFY first. Even though it doesn't succeed in * grabbing the job the control carries with * qemuDomainRemoveInactive call. */ void qemuDomainRemoveInactiveJob(virQEMUDriverPtr driver, virDomainObjPtr vm) { bool haveJob; haveJob = qemuDomainObjBeginJob(driver, vm, QEMU_JOB_MODIFY) >= 0; qemuDomainRemoveInactive(driver, vm); if (haveJob) qemuDomainObjEndJob(driver, vm); } void qemuDomainSetFakeReboot(virQEMUDriverPtr driver, virDomainObjPtr vm, bool value) { qemuDomainObjPrivatePtr priv = vm->privateData; virQEMUDriverConfigPtr cfg = virQEMUDriverGetConfig(driver); if (priv->fakeReboot == value) goto cleanup; priv->fakeReboot = value; if (virDomainSaveStatus(driver->xmlopt, cfg->stateDir, vm, driver->caps) < 0) VIR_WARN("Failed to save status on vm %s", vm->def->name); cleanup: virObjectUnref(cfg); } static void qemuDomainCheckRemoveOptionalDisk(virQEMUDriverPtr driver, virDomainObjPtr vm, size_t diskIndex) { char uuid[VIR_UUID_STRING_BUFLEN]; virObjectEventPtr event = NULL; virDomainDiskDefPtr disk = vm->def->disks[diskIndex]; const char *src = virDomainDiskGetSource(disk); virUUIDFormat(vm->def->uuid, uuid); VIR_DEBUG("Dropping disk '%s' on domain '%s' (UUID '%s') " "due to inaccessible source '%s'", disk->dst, vm->def->name, uuid, src); if (disk->device == VIR_DOMAIN_DISK_DEVICE_CDROM || disk->device == VIR_DOMAIN_DISK_DEVICE_FLOPPY) { event = virDomainEventDiskChangeNewFromObj(vm, src, NULL, disk->info.alias, VIR_DOMAIN_EVENT_DISK_CHANGE_MISSING_ON_START); virDomainDiskEmptySource(disk); /* keeping the old startup policy would be invalid for new images */ disk->startupPolicy = VIR_DOMAIN_STARTUP_POLICY_DEFAULT; } else { event = virDomainEventDiskChangeNewFromObj(vm, src, NULL, disk->info.alias, VIR_DOMAIN_EVENT_DISK_DROP_MISSING_ON_START); virDomainDiskRemove(vm->def, diskIndex); virDomainDiskDefFree(disk); } qemuDomainEventQueue(driver, event); } /** * qemuDomainCheckDiskStartupPolicy: * @driver: qemu driver object * @vm: domain object * @disk: index of disk to check * @cold_boot: true if a new VM is being started * * This function should be called when the source storage for a disk device is * missing. The function checks whether the startup policy for the disk allows * removal of the source (or disk) according to the state of the VM. * * The function returns 0 if the source or disk was dropped and -1 if the state * of the VM does not allow this. This function does not report errors, but * clears any reported error if 0 is returned. */ int qemuDomainCheckDiskStartupPolicy(virQEMUDriverPtr driver, virDomainObjPtr vm, size_t diskIndex, bool cold_boot) { int startupPolicy = vm->def->disks[diskIndex]->startupPolicy; int device = vm->def->disks[diskIndex]->device; switch ((virDomainStartupPolicy) startupPolicy) { case VIR_DOMAIN_STARTUP_POLICY_OPTIONAL: /* Once started with an optional disk, qemu saves its section * in the migration stream, so later, when restoring from it * we must make sure the sections match. */ if (!cold_boot && device != VIR_DOMAIN_DISK_DEVICE_FLOPPY && device != VIR_DOMAIN_DISK_DEVICE_CDROM) return -1; break; case VIR_DOMAIN_STARTUP_POLICY_DEFAULT: case VIR_DOMAIN_STARTUP_POLICY_MANDATORY: return -1; case VIR_DOMAIN_STARTUP_POLICY_REQUISITE: if (cold_boot) return -1; break; case VIR_DOMAIN_STARTUP_POLICY_LAST: /* this should never happen */ break; } qemuDomainCheckRemoveOptionalDisk(driver, vm, diskIndex); virResetLastError(); return 0; } /* * The vm must be locked when any of the following cleanup functions is * called. */ int qemuDomainCleanupAdd(virDomainObjPtr vm, qemuDomainCleanupCallback cb) { qemuDomainObjPrivatePtr priv = vm->privateData; size_t i; VIR_DEBUG("vm=%s, cb=%p", vm->def->name, cb); for (i = 0; i < priv->ncleanupCallbacks; i++) { if (priv->cleanupCallbacks[i] == cb) return 0; } if (VIR_RESIZE_N(priv->cleanupCallbacks, priv->ncleanupCallbacks_max, priv->ncleanupCallbacks, 1) < 0) return -1; priv->cleanupCallbacks[priv->ncleanupCallbacks++] = cb; return 0; } void qemuDomainCleanupRemove(virDomainObjPtr vm, qemuDomainCleanupCallback cb) { qemuDomainObjPrivatePtr priv = vm->privateData; size_t i; VIR_DEBUG("vm=%s, cb=%p", vm->def->name, cb); for (i = 0; i < priv->ncleanupCallbacks; i++) { if (priv->cleanupCallbacks[i] == cb) VIR_DELETE_ELEMENT_INPLACE(priv->cleanupCallbacks, i, priv->ncleanupCallbacks); } VIR_SHRINK_N(priv->cleanupCallbacks, priv->ncleanupCallbacks_max, priv->ncleanupCallbacks_max - priv->ncleanupCallbacks); } void qemuDomainCleanupRun(virQEMUDriverPtr driver, virDomainObjPtr vm) { qemuDomainObjPrivatePtr priv = vm->privateData; size_t i; VIR_DEBUG("driver=%p, vm=%s", driver, vm->def->name); /* run cleanup callbacks in reverse order */ for (i = 0; i < priv->ncleanupCallbacks; i++) { if (priv->cleanupCallbacks[priv->ncleanupCallbacks - (i + 1)]) priv->cleanupCallbacks[i](driver, vm); } VIR_FREE(priv->cleanupCallbacks); priv->ncleanupCallbacks = 0; priv->ncleanupCallbacks_max = 0; } static void qemuDomainGetImageIds(virQEMUDriverConfigPtr cfg, virDomainObjPtr vm, virStorageSourcePtr src, virStorageSourcePtr parentSrc, uid_t *uid, gid_t *gid) { virSecurityLabelDefPtr vmlabel; virSecurityDeviceLabelDefPtr disklabel; if (uid) *uid = -1; if (gid) *gid = -1; if (cfg) { if (uid) *uid = cfg->user; if (gid) *gid = cfg->group; } if (vm && (vmlabel = virDomainDefGetSecurityLabelDef(vm->def, "dac")) && vmlabel->label) virParseOwnershipIds(vmlabel->label, uid, gid); if (parentSrc && (disklabel = virStorageSourceGetSecurityLabelDef(parentSrc, "dac")) && disklabel->label) virParseOwnershipIds(disklabel->label, uid, gid); if ((disklabel = virStorageSourceGetSecurityLabelDef(src, "dac")) && disklabel->label) virParseOwnershipIds(disklabel->label, uid, gid); } int qemuDomainStorageFileInit(virQEMUDriverPtr driver, virDomainObjPtr vm, virStorageSourcePtr src, virStorageSourcePtr parent) { virQEMUDriverConfigPtr cfg = virQEMUDriverGetConfig(driver); uid_t uid; gid_t gid; int ret = -1; qemuDomainGetImageIds(cfg, vm, src, parent, &uid, &gid); if (virStorageFileInitAs(src, uid, gid) < 0) goto cleanup; ret = 0; cleanup: virObjectUnref(cfg); return ret; } char * qemuDomainStorageAlias(const char *device, int depth) { char *alias; device = qemuAliasDiskDriveSkipPrefix(device); if (!depth) ignore_value(VIR_STRDUP(alias, device)); else ignore_value(virAsprintf(&alias, "%s.%d", device, depth)); return alias; } int qemuDomainDetermineDiskChain(virQEMUDriverPtr driver, virDomainObjPtr vm, virDomainDiskDefPtr disk, bool force_probe, bool report_broken) { virQEMUDriverConfigPtr cfg = virQEMUDriverGetConfig(driver); virStorageSourcePtr src = disk->src; int ret = -1; uid_t uid; gid_t gid; if (virStorageSourceIsEmpty(src)) { ret = 0; goto cleanup; } if (force_probe) virStorageSourceBackingStoreClear(src); /* There is no need to check the backing chain for disks without backing * support */ if (virStorageSourceIsLocalStorage(src) && src->format > VIR_STORAGE_FILE_NONE && src->format < VIR_STORAGE_FILE_BACKING) { if (!virFileExists(src->path)) { if (report_broken) virStorageFileReportBrokenChain(errno, src, disk->src); goto cleanup; } /* terminate the chain for such images as the code below would do */ if (!src->backingStore && VIR_ALLOC(src->backingStore) < 0) goto cleanup; ret = 0; goto cleanup; } /* skip to the end of the chain if there is any */ while (virStorageSourceHasBacking(src)) { if (report_broken && virStorageFileSupportsAccess(src)) { if (qemuDomainStorageFileInit(driver, vm, src, disk->src) < 0) goto cleanup; if (virStorageFileAccess(src, F_OK) < 0) { virStorageFileReportBrokenChain(errno, src, disk->src); virStorageFileDeinit(src); goto cleanup; } virStorageFileDeinit(src); } src = src->backingStore; } /* We skipped to the end of the chain. Skip detection if there's the * terminator. (An allocated but empty backingStore) */ if (src->backingStore) { ret = 0; goto cleanup; } qemuDomainGetImageIds(cfg, vm, src, disk->src, &uid, &gid); if (virStorageFileGetMetadata(src, uid, gid, cfg->allowDiskFormatProbing, report_broken) < 0) goto cleanup; ret = 0; cleanup: virObjectUnref(cfg); return ret; } /** * qemuDomainDiskChainElementRevoke: * * Revoke access to a single backing chain element. This restores the labels, * removes cgroup ACLs for devices and removes locks. */ void qemuDomainDiskChainElementRevoke(virQEMUDriverPtr driver, virDomainObjPtr vm, virStorageSourcePtr elem) { if (qemuTeardownImageCgroup(vm, elem) < 0) VIR_WARN("Failed to teardown cgroup for disk path %s", NULLSTR(elem->path)); if (qemuSecurityRestoreImageLabel(driver, vm, elem) < 0) VIR_WARN("Unable to restore security label on %s", NULLSTR(elem->path)); if (qemuDomainNamespaceTeardownDisk(vm, elem) < 0) VIR_WARN("Unable to remove /dev entry for %s", NULLSTR(elem->path)); if (virDomainLockImageDetach(driver->lockManager, vm, elem) < 0) VIR_WARN("Unable to release lock on %s", NULLSTR(elem->path)); } /** * qemuDomainDiskChainElementPrepare: * @driver: qemu driver data * @vm: domain object * @elem: source structure to set access for * @readonly: setup read-only access if true * @newSource: @elem describes a storage source which @vm can't access yet * * Allow a VM access to a single element of a disk backing chain; this helper * ensures that the lock manager, cgroup device controller, and security manager * labelling are all aware of each new file before it is added to a chain. * * When modifying permissions of @elem which @vm can already access (is in the * backing chain) @newSource needs to be set to false. */ int qemuDomainDiskChainElementPrepare(virQEMUDriverPtr driver, virDomainObjPtr vm, virStorageSourcePtr elem, bool readonly, bool newSource) { bool was_readonly = elem->readonly; virQEMUDriverConfigPtr cfg = NULL; int ret = -1; cfg = virQEMUDriverGetConfig(driver); elem->readonly = readonly; if (virDomainLockImageAttach(driver->lockManager, cfg->uri, vm, elem) < 0) goto cleanup; if (newSource && qemuDomainNamespaceSetupDisk(vm, elem) < 0) goto cleanup; if (qemuSetupImageCgroup(vm, elem) < 0) goto cleanup; if (qemuSecuritySetImageLabel(driver, vm, elem) < 0) goto cleanup; ret = 0; cleanup: elem->readonly = was_readonly; virObjectUnref(cfg); return ret; } bool qemuDomainDiskSourceDiffers(virDomainDiskDefPtr disk, virDomainDiskDefPtr origDisk) { char *diskSrc = NULL, *origDiskSrc = NULL; bool diskEmpty, origDiskEmpty; bool ret = true; diskEmpty = virStorageSourceIsEmpty(disk->src); origDiskEmpty = virStorageSourceIsEmpty(origDisk->src); if (diskEmpty && origDiskEmpty) return false; if (diskEmpty ^ origDiskEmpty) return true; /* This won't be a network storage, so no need to get the diskPriv * in order to fetch the secret, thus NULL for param2 */ if (qemuGetDriveSourceString(disk->src, NULL, &diskSrc) < 0 || qemuGetDriveSourceString(origDisk->src, NULL, &origDiskSrc) < 0) goto cleanup; /* So far in qemu disk sources are considered different * if either path to disk or its format changes. */ ret = virDomainDiskGetFormat(disk) != virDomainDiskGetFormat(origDisk) || STRNEQ_NULLABLE(diskSrc, origDiskSrc); cleanup: VIR_FREE(diskSrc); VIR_FREE(origDiskSrc); return ret; } /* * Makes sure the @disk differs from @orig_disk only by the source * path and nothing else. Fields that are being checked and the * information whether they are nullable (may not be specified) or is * taken from the virDomainDiskDefFormat() code. */ bool qemuDomainDiskChangeSupported(virDomainDiskDefPtr disk, virDomainDiskDefPtr orig_disk) { #define CHECK_EQ(field, field_name, nullable) \ do { \ if (nullable && !disk->field) \ break; \ if (disk->field != orig_disk->field) { \ virReportError(VIR_ERR_OPERATION_UNSUPPORTED, \ _("cannot modify field '%s' of the disk"), \ field_name); \ return false; \ } \ } while (0) CHECK_EQ(device, "device", false); CHECK_EQ(bus, "bus", false); if (STRNEQ(disk->dst, orig_disk->dst)) { virReportError(VIR_ERR_OPERATION_UNSUPPORTED, _("cannot modify field '%s' of the disk"), "target"); return false; } CHECK_EQ(tray_status, "tray", true); CHECK_EQ(removable, "removable", true); if (disk->geometry.cylinders && disk->geometry.heads && disk->geometry.sectors) { CHECK_EQ(geometry.cylinders, "geometry cylinders", false); CHECK_EQ(geometry.heads, "geometry heads", false); CHECK_EQ(geometry.sectors, "geometry sectors", false); CHECK_EQ(geometry.trans, "BIOS-translation-modus", true); } CHECK_EQ(blockio.logical_block_size, "blockio logical_block_size", false); CHECK_EQ(blockio.physical_block_size, "blockio physical_block_size", false); CHECK_EQ(blkdeviotune.total_bytes_sec, "blkdeviotune total_bytes_sec", true); CHECK_EQ(blkdeviotune.read_bytes_sec, "blkdeviotune read_bytes_sec", true); CHECK_EQ(blkdeviotune.write_bytes_sec, "blkdeviotune write_bytes_sec", true); CHECK_EQ(blkdeviotune.total_iops_sec, "blkdeviotune total_iops_sec", true); CHECK_EQ(blkdeviotune.read_iops_sec, "blkdeviotune read_iops_sec", true); CHECK_EQ(blkdeviotune.write_iops_sec, "blkdeviotune write_iops_sec", true); CHECK_EQ(blkdeviotune.total_bytes_sec_max, "blkdeviotune total_bytes_sec_max", true); CHECK_EQ(blkdeviotune.read_bytes_sec_max, "blkdeviotune read_bytes_sec_max", true); CHECK_EQ(blkdeviotune.write_bytes_sec_max, "blkdeviotune write_bytes_sec_max", true); CHECK_EQ(blkdeviotune.total_iops_sec_max, "blkdeviotune total_iops_sec_max", true); CHECK_EQ(blkdeviotune.read_iops_sec_max, "blkdeviotune read_iops_sec_max", true); CHECK_EQ(blkdeviotune.write_iops_sec_max, "blkdeviotune write_iops_sec_max", true); CHECK_EQ(blkdeviotune.size_iops_sec, "blkdeviotune size_iops_sec", true); if (disk->serial && STRNEQ_NULLABLE(disk->serial, orig_disk->serial)) { virReportError(VIR_ERR_OPERATION_UNSUPPORTED, _("cannot modify field '%s' of the disk"), "serial"); return false; } if (disk->wwn && STRNEQ_NULLABLE(disk->wwn, orig_disk->wwn)) { virReportError(VIR_ERR_OPERATION_UNSUPPORTED, _("cannot modify field '%s' of the disk"), "wwn"); return false; } if (disk->vendor && STRNEQ_NULLABLE(disk->vendor, orig_disk->vendor)) { virReportError(VIR_ERR_OPERATION_UNSUPPORTED, _("cannot modify field '%s' of the disk"), "vendor"); return false; } if (disk->product && STRNEQ_NULLABLE(disk->product, orig_disk->product)) { virReportError(VIR_ERR_OPERATION_UNSUPPORTED, _("cannot modify field '%s' of the disk"), "product"); return false; } CHECK_EQ(cachemode, "cache", true); CHECK_EQ(error_policy, "error_policy", true); CHECK_EQ(rerror_policy, "rerror_policy", true); CHECK_EQ(iomode, "io", true); CHECK_EQ(ioeventfd, "ioeventfd", true); CHECK_EQ(event_idx, "event_idx", true); CHECK_EQ(copy_on_read, "copy_on_read", true); /* "snapshot" is a libvirt internal field and thus can be changed */ /* startupPolicy is allowed to be updated. Therefore not checked here. */ CHECK_EQ(transient, "transient", true); /* Note: For some address types the address auto generation for * @disk has still not happened at this point (e.g. driver * specific addresses) therefore we can't catch these possible * address modifications here. */ if (disk->info.type != VIR_DOMAIN_DEVICE_ADDRESS_TYPE_NONE && !virDomainDeviceInfoAddressIsEqual(&disk->info, &orig_disk->info)) { virReportError(VIR_ERR_OPERATION_UNSUPPORTED, _("cannot modify field '%s' of the disk"), "address"); return false; } if (disk->info.alias && STRNEQ_NULLABLE(disk->info.alias, orig_disk->info.alias)) { virReportError(VIR_ERR_OPERATION_UNSUPPORTED, _("cannot modify field '%s' of the disk"), "alias"); return false; } CHECK_EQ(info.bootIndex, "boot order", true); CHECK_EQ(rawio, "rawio", true); CHECK_EQ(sgio, "sgio", true); CHECK_EQ(discard, "discard", true); CHECK_EQ(iothread, "iothread", true); if (disk->domain_name && STRNEQ_NULLABLE(disk->domain_name, orig_disk->domain_name)) { virReportError(VIR_ERR_OPERATION_UNSUPPORTED, _("cannot modify field '%s' of the disk"), "backenddomain"); return false; } /* checks for fields stored in disk->src */ /* unfortunately 'readonly' and 'shared' can't be converted to tristate * values thus we need to ignore the check if the new value is 'false' */ CHECK_EQ(src->readonly, "readonly", true); CHECK_EQ(src->shared, "shared", true); #undef CHECK_EQ return true; } bool qemuDomainDiskBlockJobIsActive(virDomainDiskDefPtr disk) { qemuDomainDiskPrivatePtr diskPriv = QEMU_DOMAIN_DISK_PRIVATE(disk); if (disk->mirror) { virReportError(VIR_ERR_BLOCK_COPY_ACTIVE, _("disk '%s' already in active block job"), disk->dst); return true; } if (diskPriv->blockjob) { virReportError(VIR_ERR_OPERATION_UNSUPPORTED, _("disk '%s' already in active block job"), disk->dst); return true; } return false; } /** * qemuDomainHasBlockjob: * @vm: domain object * @copy_only: Reject only block copy job * * Return true if @vm has at least one disk involved in a current block * copy/commit/pull job. If @copy_only is true this returns true only if the * disk is involved in a block copy. * */ bool qemuDomainHasBlockjob(virDomainObjPtr vm, bool copy_only) { size_t i; for (i = 0; i < vm->def->ndisks; i++) { virDomainDiskDefPtr disk = vm->def->disks[i]; qemuDomainDiskPrivatePtr diskPriv = QEMU_DOMAIN_DISK_PRIVATE(disk); if (!copy_only && diskPriv->blockjob) return true; if (disk->mirror && disk->mirrorJob == VIR_DOMAIN_BLOCK_JOB_TYPE_COPY) return true; } return false; } int qemuDomainUpdateDeviceList(virQEMUDriverPtr driver, virDomainObjPtr vm, int asyncJob) { qemuDomainObjPrivatePtr priv = vm->privateData; char **aliases; int rc; if (!virQEMUCapsGet(priv->qemuCaps, QEMU_CAPS_DEVICE_DEL_EVENT)) return 0; if (qemuDomainObjEnterMonitorAsync(driver, vm, asyncJob) < 0) return -1; rc = qemuMonitorGetDeviceAliases(priv->mon, &aliases); if (qemuDomainObjExitMonitor(driver, vm) < 0) return -1; if (rc < 0) return -1; virStringListFree(priv->qemuDevices); priv->qemuDevices = aliases; return 0; } int qemuDomainUpdateMemoryDeviceInfo(virQEMUDriverPtr driver, virDomainObjPtr vm, int asyncJob) { qemuDomainObjPrivatePtr priv = vm->privateData; virHashTablePtr meminfo = NULL; int rc; size_t i; if (vm->def->nmems == 0) return 0; if (qemuDomainObjEnterMonitorAsync(driver, vm, asyncJob) < 0) return -1; rc = qemuMonitorGetMemoryDeviceInfo(priv->mon, &meminfo); if (qemuDomainObjExitMonitor(driver, vm) < 0) { virHashFree(meminfo); return -1; } /* if qemu doesn't support the info request, just carry on */ if (rc == -2) return 0; if (rc < 0) return -1; for (i = 0; i < vm->def->nmems; i++) { virDomainMemoryDefPtr mem = vm->def->mems[i]; qemuMonitorMemoryDeviceInfoPtr dimm; if (!mem->info.alias) continue; if (!(dimm = virHashLookup(meminfo, mem->info.alias))) continue; mem->info.type = VIR_DOMAIN_DEVICE_ADDRESS_TYPE_DIMM; mem->info.addr.dimm.slot = dimm->slot; mem->info.addr.dimm.base = dimm->address; } virHashFree(meminfo); return 0; } static bool qemuDomainABIStabilityCheck(const virDomainDef *src, const virDomainDef *dst) { size_t i; if (src->mem.source != dst->mem.source) { virReportError(VIR_ERR_CONFIG_UNSUPPORTED, _("Target memoryBacking source '%s' doesn't " "match source memoryBacking source'%s'"), virDomainMemorySourceTypeToString(dst->mem.source), virDomainMemorySourceTypeToString(src->mem.source)); return false; } for (i = 0; i < src->nmems; i++) { const char *srcAlias = src->mems[i]->info.alias; const char *dstAlias = dst->mems[i]->info.alias; if (STRNEQ_NULLABLE(srcAlias, dstAlias)) { virReportError(VIR_ERR_CONFIG_UNSUPPORTED, _("Target memory device alias '%s' doesn't " "match source alias '%s'"), NULLSTR(srcAlias), NULLSTR(dstAlias)); return false; } } return true; } virDomainABIStability virQEMUDriverDomainABIStability = { .domain = qemuDomainABIStabilityCheck, }; static bool qemuDomainMigratableDefCheckABIStability(virQEMUDriverPtr driver, virDomainDefPtr src, virDomainDefPtr migratableSrc, virDomainDefPtr dst, virDomainDefPtr migratableDst) { if (!virDomainDefCheckABIStabilityFlags(migratableSrc, migratableDst, driver->xmlopt, VIR_DOMAIN_DEF_ABI_CHECK_SKIP_VOLATILE)) return false; /* Force update any skipped values from the volatile flag */ dst->mem.cur_balloon = src->mem.cur_balloon; return true; } #define COPY_FLAGS (VIR_DOMAIN_XML_SECURE | \ VIR_DOMAIN_XML_MIGRATABLE) bool qemuDomainDefCheckABIStability(virQEMUDriverPtr driver, virDomainDefPtr src, virDomainDefPtr dst) { virDomainDefPtr migratableDefSrc = NULL; virDomainDefPtr migratableDefDst = NULL; bool ret = false; if (!(migratableDefSrc = qemuDomainDefCopy(driver, src, COPY_FLAGS)) || !(migratableDefDst = qemuDomainDefCopy(driver, dst, COPY_FLAGS))) goto cleanup; ret = qemuDomainMigratableDefCheckABIStability(driver, src, migratableDefSrc, dst, migratableDefDst); cleanup: virDomainDefFree(migratableDefSrc); virDomainDefFree(migratableDefDst); return ret; } bool qemuDomainCheckABIStability(virQEMUDriverPtr driver, virDomainObjPtr vm, virDomainDefPtr dst) { virDomainDefPtr migratableSrc = NULL; virDomainDefPtr migratableDst = NULL; char *xml = NULL; bool ret = false; if (!(xml = qemuDomainFormatXML(driver, vm, COPY_FLAGS)) || !(migratableSrc = qemuDomainDefFromXML(driver, xml)) || !(migratableDst = qemuDomainDefCopy(driver, dst, COPY_FLAGS))) goto cleanup; ret = qemuDomainMigratableDefCheckABIStability(driver, vm->def, migratableSrc, dst, migratableDst); cleanup: VIR_FREE(xml); virDomainDefFree(migratableSrc); virDomainDefFree(migratableDst); return ret; } #undef COPY_FLAGS bool qemuDomainAgentAvailable(virDomainObjPtr vm, bool reportError) { qemuDomainObjPrivatePtr priv = vm->privateData; if (virDomainObjGetState(vm, NULL) != VIR_DOMAIN_RUNNING) { if (reportError) { virReportError(VIR_ERR_OPERATION_INVALID, "%s", _("domain is not running")); } return false; } if (priv->agentError) { if (reportError) { virReportError(VIR_ERR_AGENT_UNRESPONSIVE, "%s", _("QEMU guest agent is not " "available due to an error")); } return false; } if (!priv->agent) { if (qemuFindAgentConfig(vm->def)) { if (reportError) { virReportError(VIR_ERR_AGENT_UNRESPONSIVE, "%s", _("QEMU guest agent is not connected")); } return false; } else { if (reportError) { virReportError(VIR_ERR_ARGUMENT_UNSUPPORTED, "%s", _("QEMU guest agent is not configured")); } return false; } } return true; } static unsigned long long qemuDomainGetMemorySizeAlignment(virDomainDefPtr def) { /* PPC requires the memory sizes to be rounded to 256MiB increments, so * round them to the size always. */ if (ARCH_IS_PPC64(def->os.arch)) return 256 * 1024; /* Align memory size. QEMU requires rounding to next 4KiB block. * We'll take the "traditional" path and round it to 1MiB*/ return 1024; } static unsigned long long qemuDomainGetMemoryModuleSizeAlignment(const virDomainDef *def, const virDomainMemoryDef *mem ATTRIBUTE_UNUSED) { /* PPC requires the memory sizes to be rounded to 256MiB increments, so * round them to the size always. */ if (ARCH_IS_PPC64(def->os.arch)) return 256 * 1024; /* dimm memory modules require 2MiB alignment rather than the 1MiB we are * using elsewhere. */ return 2048; } int qemuDomainAlignMemorySizes(virDomainDefPtr def) { unsigned long long maxmemkb = virMemoryMaxValue(false) >> 10; unsigned long long maxmemcapped = virMemoryMaxValue(true) >> 10; unsigned long long initialmem = 0; unsigned long long hotplugmem = 0; unsigned long long mem; unsigned long long align = qemuDomainGetMemorySizeAlignment(def); size_t ncells = virDomainNumaGetNodeCount(def->numa); size_t i; /* align NUMA cell sizes if relevant */ for (i = 0; i < ncells; i++) { mem = VIR_ROUND_UP(virDomainNumaGetNodeMemorySize(def->numa, i), align); initialmem += mem; if (mem > maxmemkb) { virReportError(VIR_ERR_CONFIG_UNSUPPORTED, _("memory size of NUMA node '%zu' overflowed after " "alignment"), i); return -1; } virDomainNumaSetNodeMemorySize(def->numa, i, mem); } /* align initial memory size, if NUMA is present calculate it as total of * individual aligned NUMA node sizes */ if (initialmem == 0) initialmem = VIR_ROUND_UP(virDomainDefGetMemoryInitial(def), align); if (initialmem > maxmemcapped) { virReportError(VIR_ERR_CONFIG_UNSUPPORTED, "%s", _("initial memory size overflowed after alignment")); return -1; } def->mem.max_memory = VIR_ROUND_UP(def->mem.max_memory, align); if (def->mem.max_memory > maxmemkb) { virReportError(VIR_ERR_CONFIG_UNSUPPORTED, "%s", _("maximum memory size overflowed after alignment")); return -1; } /* Align memory module sizes */ for (i = 0; i < def->nmems; i++) { align = qemuDomainGetMemoryModuleSizeAlignment(def, def->mems[i]); def->mems[i]->size = VIR_ROUND_UP(def->mems[i]->size, align); hotplugmem += def->mems[i]->size; if (def->mems[i]->size > maxmemkb) { virReportError(VIR_ERR_CONFIG_UNSUPPORTED, _("size of memory module '%zu' overflowed after " "alignment"), i); return -1; } } virDomainDefSetMemoryTotal(def, initialmem + hotplugmem); return 0; } /** * qemuDomainMemoryDeviceAlignSize: * @mem: memory device definition object * * Aligns the size of the memory module as qemu enforces it. The size is updated * inplace. Default rounding is now to 1 MiB (qemu requires rouding to page, * size so this should be safe). */ void qemuDomainMemoryDeviceAlignSize(virDomainDefPtr def, virDomainMemoryDefPtr mem) { mem->size = VIR_ROUND_UP(mem->size, qemuDomainGetMemorySizeAlignment(def)); } /** * qemuDomainGetMonitor: * @vm: domain object * * Returns the monitor pointer corresponding to the domain object @vm. */ qemuMonitorPtr qemuDomainGetMonitor(virDomainObjPtr vm) { return ((qemuDomainObjPrivatePtr) vm->privateData)->mon; } /** * qemuDomainSupportsBlockJobs: * @vm: domain object * * Returns -1 in case when qemu does not support block jobs at all. Otherwise * returns 0. */ int qemuDomainSupportsBlockJobs(virDomainObjPtr vm) { qemuDomainObjPrivatePtr priv = vm->privateData; bool asynchronous = virQEMUCapsGet(priv->qemuCaps, QEMU_CAPS_BLOCKJOB_ASYNC); if (!asynchronous) { virReportError(VIR_ERR_CONFIG_UNSUPPORTED, "%s", _("block jobs not supported with this QEMU binary")); return -1; } return 0; } /** * qemuFindAgentConfig: * @def: domain definition * * Returns the pointer to the channel definition that is used to access the * guest agent if the agent is configured or NULL otherwise. */ virDomainChrDefPtr qemuFindAgentConfig(virDomainDefPtr def) { size_t i; for (i = 0; i < def->nchannels; i++) { virDomainChrDefPtr channel = def->channels[i]; if (channel->targetType != VIR_DOMAIN_CHR_CHANNEL_TARGET_TYPE_VIRTIO) continue; if (STREQ_NULLABLE(channel->target.name, "org.qemu.guest_agent.0")) return channel; } return NULL; } bool qemuDomainIsQ35(const virDomainDef *def) { return qemuDomainMachineIsQ35(def->os.machine); } bool qemuDomainMachineIsQ35(const char *machine) { return (STRPREFIX(machine, "pc-q35") || STREQ(machine, "q35")); } bool qemuDomainIsI440FX(const virDomainDef *def) { return qemuDomainMachineIsI440FX(def->os.machine); } bool qemuDomainMachineIsI440FX(const char *machine) { return (STREQ(machine, "pc") || STRPREFIX(machine, "pc-0.") || STRPREFIX(machine, "pc-1.") || STRPREFIX(machine, "pc-i440") || STRPREFIX(machine, "rhel")); } bool qemuDomainHasPCIRoot(const virDomainDef *def) { int root = virDomainControllerFind(def, VIR_DOMAIN_CONTROLLER_TYPE_PCI, 0); if (root < 0) return false; if (def->controllers[root]->model != VIR_DOMAIN_CONTROLLER_MODEL_PCI_ROOT) return false; return true; } bool qemuDomainHasPCIeRoot(const virDomainDef *def) { int root = virDomainControllerFind(def, VIR_DOMAIN_CONTROLLER_TYPE_PCI, 0); if (root < 0) return false; if (def->controllers[root]->model != VIR_DOMAIN_CONTROLLER_MODEL_PCIE_ROOT) return false; return true; } bool qemuDomainNeedsFDC(const virDomainDef *def) { return qemuDomainMachineNeedsFDC(def->os.machine); } bool qemuDomainMachineNeedsFDC(const char *machine) { const char *p = STRSKIP(machine, "pc-q35-"); if (p) { if (STRPREFIX(p, "1.") || STRPREFIX(p, "2.0") || STRPREFIX(p, "2.1") || STRPREFIX(p, "2.2") || STRPREFIX(p, "2.3")) return false; return true; } return false; } bool qemuDomainIsS390CCW(const virDomainDef *def) { return qemuDomainMachineIsS390CCW(def->os.machine); } bool qemuDomainMachineIsS390CCW(const char *machine) { return STRPREFIX(machine, "s390-ccw"); } bool qemuDomainIsVirt(const virDomainDef *def) { return qemuDomainMachineIsVirt(def->os.machine, def->os.arch); } bool qemuDomainMachineIsVirt(const char *machine, const virArch arch) { if (arch != VIR_ARCH_ARMV7L && arch != VIR_ARCH_AARCH64) return false; if (STRNEQ(machine, "virt") && !STRPREFIX(machine, "virt-")) return false; return true; } bool qemuDomainIsPSeries(const virDomainDef *def) { return qemuDomainMachineIsPSeries(def->os.machine, def->os.arch); } bool qemuDomainMachineIsPSeries(const char *machine, const virArch arch) { if (!ARCH_IS_PPC64(arch)) return false; if (STRNEQ(machine, "pseries") && !STRPREFIX(machine, "pseries-")) return false; return true; } static bool qemuCheckMemoryDimmConflict(const virDomainDef *def, const virDomainMemoryDef *mem) { size_t i; for (i = 0; i < def->nmems; i++) { virDomainMemoryDefPtr tmp = def->mems[i]; if (tmp == mem || tmp->info.type != VIR_DOMAIN_DEVICE_ADDRESS_TYPE_DIMM) continue; if (mem->info.addr.dimm.slot == tmp->info.addr.dimm.slot) { virReportError(VIR_ERR_CONFIG_UNSUPPORTED, _("memory device slot '%u' is already being " "used by another memory device"), mem->info.addr.dimm.slot); return true; } if (mem->info.addr.dimm.base != 0 && mem->info.addr.dimm.base == tmp->info.addr.dimm.base) { virReportError(VIR_ERR_CONFIG_UNSUPPORTED, _("memory device base '0x%llx' is already being " "used by another memory device"), mem->info.addr.dimm.base); return true; } } return false; } static int qemuDomainDefValidateMemoryHotplugDevice(const virDomainMemoryDef *mem, const virDomainDef *def) { switch ((virDomainMemoryModel) mem->model) { case VIR_DOMAIN_MEMORY_MODEL_DIMM: case VIR_DOMAIN_MEMORY_MODEL_NVDIMM: if (mem->info.type != VIR_DOMAIN_DEVICE_ADDRESS_TYPE_DIMM && mem->info.type != VIR_DOMAIN_DEVICE_ADDRESS_TYPE_NONE) { virReportError(VIR_ERR_CONFIG_UNSUPPORTED, "%s", _("only 'dimm' addresses are supported for the " "pc-dimm device")); return -1; } if (virDomainNumaGetNodeCount(def->numa) != 0) { if (mem->targetNode == -1) { virReportError(VIR_ERR_CONFIG_UNSUPPORTED, "%s", _("target NUMA node needs to be specified for " "memory device")); return -1; } } if (mem->info.type == VIR_DOMAIN_DEVICE_ADDRESS_TYPE_DIMM) { if (mem->info.addr.dimm.slot >= def->mem.memory_slots) { virReportError(VIR_ERR_CONFIG_UNSUPPORTED, _("memory device slot '%u' exceeds slots " "count '%u'"), mem->info.addr.dimm.slot, def->mem.memory_slots); return -1; } if (qemuCheckMemoryDimmConflict(def, mem)) return -1; } break; case VIR_DOMAIN_MEMORY_MODEL_NONE: case VIR_DOMAIN_MEMORY_MODEL_LAST: return -1; } return 0; } /** * qemuDomainDefValidateMemoryHotplug: * @def: domain definition * @qemuCaps: qemu capabilities object * @mem: definition of memory device that is to be added to @def with hotplug, * NULL in case of regular VM startup * * Validates that the domain definition and memory modules have valid * configuration and are possibly able to accept @mem via hotplug if it's * non-NULL. * * Returns 0 on success; -1 and a libvirt error on error. */ int qemuDomainDefValidateMemoryHotplug(const virDomainDef *def, virQEMUCapsPtr qemuCaps, const virDomainMemoryDef *mem) { unsigned int nmems = def->nmems; unsigned long long hotplugSpace; unsigned long long hotplugMemory = 0; bool needPCDimmCap = false; bool needNvdimmCap = false; size_t i; hotplugSpace = def->mem.max_memory - virDomainDefGetMemoryInitial(def); if (mem) { nmems++; hotplugMemory = mem->size; if (qemuDomainDefValidateMemoryHotplugDevice(mem, def) < 0) return -1; } if (!virDomainDefHasMemoryHotplug(def)) { if (nmems) { virReportError(VIR_ERR_CONFIG_UNSUPPORTED, "%s", _("cannot use/hotplug a memory device when domain " "'maxMemory' is not defined")); return -1; } return 0; } if (!ARCH_IS_PPC64(def->os.arch)) { /* due to guest support, qemu would silently enable NUMA with one node * once the memory hotplug backend is enabled. To avoid possible * confusion we will enforce user originated numa configuration along * with memory hotplug. */ if (virDomainNumaGetNodeCount(def->numa) == 0) { virReportError(VIR_ERR_CONFIG_UNSUPPORTED, "%s", _("At least one numa node has to be configured when " "enabling memory hotplug")); return -1; } } if (nmems > def->mem.memory_slots) { virReportError(VIR_ERR_CONFIG_UNSUPPORTED, _("memory device count '%u' exceeds slots count '%u'"), nmems, def->mem.memory_slots); return -1; } for (i = 0; i < def->nmems; i++) { hotplugMemory += def->mems[i]->size; switch ((virDomainMemoryModel) def->mems[i]->model) { case VIR_DOMAIN_MEMORY_MODEL_DIMM: needPCDimmCap = true; break; case VIR_DOMAIN_MEMORY_MODEL_NVDIMM: needNvdimmCap = true; break; case VIR_DOMAIN_MEMORY_MODEL_NONE: case VIR_DOMAIN_MEMORY_MODEL_LAST: break; } /* already existing devices don't need to be checked on hotplug */ if (!mem && qemuDomainDefValidateMemoryHotplugDevice(def->mems[i], def) < 0) return -1; } if (needPCDimmCap && !virQEMUCapsGet(qemuCaps, QEMU_CAPS_DEVICE_PC_DIMM)) { virReportError(VIR_ERR_CONFIG_UNSUPPORTED, "%s", _("memory hotplug isn't supported by this QEMU binary")); return -1; } if (needNvdimmCap && !virQEMUCapsGet(qemuCaps, QEMU_CAPS_DEVICE_NVDIMM)) { virReportError(VIR_ERR_CONFIG_UNSUPPORTED, "%s", _("nvdimm isn't supported by this QEMU binary")); return -1; } if (hotplugMemory > hotplugSpace) { virReportError(VIR_ERR_CONFIG_UNSUPPORTED, "%s", _("memory device total size exceeds hotplug space")); return -1; } return 0; } bool qemuDomainHasBuiltinIDE(const virDomainDef *def) { return qemuDomainMachineHasBuiltinIDE(def->os.machine); } bool qemuDomainMachineHasBuiltinIDE(const char *machine) { return qemuDomainMachineIsI440FX(machine) || STREQ(machine, "malta") || STREQ(machine, "sun4u") || STREQ(machine, "g3beige"); } /** * qemuDomainUpdateCurrentMemorySize: * * Updates the current balloon size from the monitor if necessary. In case when * the balloon is not present for the domain, the function recalculates the * maximum size to reflect possible changes. * * Returns 0 on success and updates vm->def->mem.cur_balloon if necessary, -1 on * error and reports libvirt error. */ int qemuDomainUpdateCurrentMemorySize(virQEMUDriverPtr driver, virDomainObjPtr vm) { qemuDomainObjPrivatePtr priv = vm->privateData; unsigned long long balloon; int ret = -1; /* inactive domain doesn't need size update */ if (!virDomainObjIsActive(vm)) return 0; /* if no balloning is available, the current size equals to the current * full memory size */ if (!virDomainDefHasMemballoon(vm->def)) { vm->def->mem.cur_balloon = virDomainDefGetMemoryTotal(vm->def); return 0; } /* current size is always automagically updated via the event */ if (virQEMUCapsGet(priv->qemuCaps, QEMU_CAPS_BALLOON_EVENT)) return 0; /* here we need to ask the monitor */ /* Don't delay if someone's using the monitor, just use existing most * recent data instead */ if (qemuDomainJobAllowed(priv, QEMU_JOB_QUERY)) { if (qemuDomainObjBeginJob(driver, vm, QEMU_JOB_QUERY) < 0) return -1; if (!virDomainObjIsActive(vm)) { virReportError(VIR_ERR_OPERATION_INVALID, "%s", _("domain is not running")); goto endjob; } qemuDomainObjEnterMonitor(driver, vm); ret = qemuMonitorGetBalloonInfo(priv->mon, &balloon); if (qemuDomainObjExitMonitor(driver, vm) < 0) ret = -1; endjob: qemuDomainObjEndJob(driver, vm); if (ret < 0) return -1; vm->def->mem.cur_balloon = balloon; } return 0; } /** * qemuDomainGetMemLockLimitBytes: * @def: domain definition * * Calculate the memory locking limit that needs to be set in order for * the guest to operate properly. The limit depends on a number of factors, * including certain configuration options and less immediately apparent ones * such as the guest architecture or the use of certain devices. * * Returns: the memory locking limit, or 0 if setting the limit is not needed */ unsigned long long qemuDomainGetMemLockLimitBytes(virDomainDefPtr def) { unsigned long long memKB = 0; size_t i; /* prefer the hard limit */ if (virMemoryLimitIsSet(def->mem.hard_limit)) { memKB = def->mem.hard_limit; goto done; } /* If the guest wants its memory to be locked, we need to raise the memory * locking limit so that the OS will not refuse allocation requests; * however, there is no reliable way for us to figure out how much memory * the QEMU process will allocate for its own use, so our only way out is * to remove the limit altogether. Use with extreme care */ if (def->mem.locked) return VIR_DOMAIN_MEMORY_PARAM_UNLIMITED; if (ARCH_IS_PPC64(def->os.arch) && def->virtType == VIR_DOMAIN_VIRT_KVM) { unsigned long long maxMemory; unsigned long long memory; unsigned long long baseLimit; unsigned long long passthroughLimit; size_t nPCIHostBridges = 0; bool usesVFIO = false; for (i = 0; i < def->ncontrollers; i++) { virDomainControllerDefPtr cont = def->controllers[i]; if (!virDomainControllerIsPSeriesPHB(cont)) continue; nPCIHostBridges++; } for (i = 0; i < def->nhostdevs; i++) { virDomainHostdevDefPtr dev = def->hostdevs[i]; if (dev->mode == VIR_DOMAIN_HOSTDEV_MODE_SUBSYS && dev->source.subsys.type == VIR_DOMAIN_HOSTDEV_SUBSYS_TYPE_PCI && dev->source.subsys.u.pci.backend == VIR_DOMAIN_HOSTDEV_PCI_BACKEND_VFIO) { usesVFIO = true; break; } } memory = virDomainDefGetMemoryTotal(def); if (def->mem.max_memory) maxMemory = def->mem.max_memory; else maxMemory = memory; /* baseLimit := maxMemory / 128 (a) * + 4 MiB * #PHBs + 8 MiB (b) * * (a) is the hash table * * (b) is accounting for the 32-bit DMA window - it could be either the * KVM accelerated TCE tables for emulated devices, or the VFIO * userspace view. The 4 MiB per-PHB (including the default one) covers * a 2GiB DMA window: default is 1GiB, but it's possible it'll be * increased to help performance. The 8 MiB extra should be plenty for * the TCE table index for any reasonable number of PHBs and several * spapr-vlan or spapr-vscsi devices (512kB + a tiny bit each) */ baseLimit = maxMemory / 128 + 4096 * nPCIHostBridges + 8192; /* passthroughLimit := max( 2 GiB * #PHBs, (c) * memory (d) * + memory * 1/512 * #PHBs + 8 MiB ) (e) * * (c) is the pre-DDW VFIO DMA window accounting. We're allowing 2 GiB * rather than 1 GiB * * (d) is the with-DDW (and memory pre-registration and related * features) DMA window accounting - assuming that we only account RAM * once, even if mapped to multiple PHBs * * (e) is the with-DDW userspace view and overhead for the 64-bit DMA * window. This is based a bit on expected guest behaviour, but there * really isn't a way to completely avoid that. We assume the guest * requests a 64-bit DMA window (per PHB) just big enough to map all * its RAM. 4 kiB page size gives the 1/512; it will be less with 64 * kiB pages, less still if the guest is mapped with hugepages (unlike * the default 32-bit DMA window, DDW windows can use large IOMMU * pages). 8 MiB is for second and further level overheads, like (b) */ passthroughLimit = MAX(2 * 1024 * 1024 * nPCIHostBridges, memory + memory / 512 * nPCIHostBridges + 8192); if (usesVFIO) memKB = baseLimit + passthroughLimit; else memKB = baseLimit; goto done; } /* For device passthrough using VFIO the guest memory and MMIO memory * regions need to be locked persistent in order to allow DMA. * * Currently the below limit is based on assumptions about the x86 platform. * * The chosen value of 1GiB below originates from x86 systems where it was * used as space reserved for the MMIO region for the whole system. * * On x86_64 systems the MMIO regions of the IOMMU mapped devices don't * count towards the locked memory limit since the memory is owned by the * device. Emulated devices though do count, but the regions are usually * small. Although it's not guaranteed that the limit will be enough for all * configurations it didn't pose a problem for now. * * http://www.redhat.com/archives/libvir-list/2015-November/msg00329.html * * Note that this may not be valid for all platforms. */ for (i = 0; i < def->nhostdevs; i++) { virDomainHostdevSubsysPtr subsys = &def->hostdevs[i]->source.subsys; if (def->hostdevs[i]->mode == VIR_DOMAIN_HOSTDEV_MODE_SUBSYS && (subsys->type == VIR_DOMAIN_HOSTDEV_SUBSYS_TYPE_MDEV || (subsys->type == VIR_DOMAIN_HOSTDEV_SUBSYS_TYPE_PCI && subsys->u.pci.backend == VIR_DOMAIN_HOSTDEV_PCI_BACKEND_VFIO))) { memKB = virDomainDefGetMemoryTotal(def) + 1024 * 1024; goto done; } } done: return memKB << 10; } /** * qemuDomainAdjustMaxMemLock: * @vm: domain * * Adjust the memory locking limit for the QEMU process associated to @vm, in * order to comply with VFIO or architecture requirements. * * The limit will not be changed unless doing so is needed; the first time * the limit is changed, the original (default) limit is stored in @vm and * that value will be restored if qemuDomainAdjustMaxMemLock() is called once * memory locking is no longer required. * * Returns: 0 on success, <0 on failure */ int qemuDomainAdjustMaxMemLock(virDomainObjPtr vm) { unsigned long long bytes = 0; int ret = -1; bytes = qemuDomainGetMemLockLimitBytes(vm->def); if (bytes) { /* If this is the first time adjusting the limit, save the current * value so that we can restore it once memory locking is no longer * required. Failing to obtain the current limit is not a critical * failure, it just means we'll be unable to lower it later */ if (!vm->original_memlock) { if (virProcessGetMaxMemLock(vm->pid, &(vm->original_memlock)) < 0) vm->original_memlock = 0; } } else { /* Once memory locking is no longer required, we can restore the * original, usually very low, limit */ bytes = vm->original_memlock; vm->original_memlock = 0; } /* Trying to set the memory locking limit to zero is a no-op */ if (virProcessSetMaxMemLock(vm->pid, bytes) < 0) goto out; ret = 0; out: return ret; } /** * qemuDomainHasVcpuPids: * @vm: Domain object * * Returns true if we were able to successfully detect vCPU pids for the VM. */ bool qemuDomainHasVcpuPids(virDomainObjPtr vm) { size_t i; size_t maxvcpus = virDomainDefGetVcpusMax(vm->def); virDomainVcpuDefPtr vcpu; for (i = 0; i < maxvcpus; i++) { vcpu = virDomainDefGetVcpu(vm->def, i); if (QEMU_DOMAIN_VCPU_PRIVATE(vcpu)->tid > 0) return true; } return false; } /** * qemuDomainGetVcpuPid: * @vm: domain object * @vcpu: cpu id * * Returns the vCPU pid. If @vcpu is offline or out of range 0 is returned. */ pid_t qemuDomainGetVcpuPid(virDomainObjPtr vm, unsigned int vcpuid) { virDomainVcpuDefPtr vcpu = virDomainDefGetVcpu(vm->def, vcpuid); return QEMU_DOMAIN_VCPU_PRIVATE(vcpu)->tid; } /** * qemuDomainValidateVcpuInfo: * * Validates vcpu thread information. If vcpu thread IDs are reported by qemu, * this function validates that online vcpus have thread info present and * offline vcpus don't. * * Returns 0 on success -1 on error. */ int qemuDomainValidateVcpuInfo(virDomainObjPtr vm) { size_t maxvcpus = virDomainDefGetVcpusMax(vm->def); virDomainVcpuDefPtr vcpu; qemuDomainVcpuPrivatePtr vcpupriv; size_t i; if (!qemuDomainHasVcpuPids(vm)) return 0; for (i = 0; i < maxvcpus; i++) { vcpu = virDomainDefGetVcpu(vm->def, i); vcpupriv = QEMU_DOMAIN_VCPU_PRIVATE(vcpu); if (vcpu->online && vcpupriv->tid == 0) { virReportError(VIR_ERR_INTERNAL_ERROR, _("qemu didn't report thread id for vcpu '%zu'"), i); return -1; } if (!vcpu->online && vcpupriv->tid != 0) { virReportError(VIR_ERR_INTERNAL_ERROR, _("qemu reported thread id for inactive vcpu '%zu'"), i); return -1; } } return 0; } bool qemuDomainSupportsNewVcpuHotplug(virDomainObjPtr vm) { qemuDomainObjPrivatePtr priv = vm->privateData; return virQEMUCapsGet(priv->qemuCaps, QEMU_CAPS_QUERY_HOTPLUGGABLE_CPUS); } /** * qemuDomainRefreshVcpuInfo: * @driver: qemu driver data * @vm: domain object * @asyncJob: current asynchronous job type * @state: refresh vcpu state * * Updates vCPU information private data of @vm. Due to historical reasons this * function returns success even if some data were not reported by qemu. * * If @state is true, the vcpu state is refreshed as reported by the monitor. * * Returns 0 on success and -1 on fatal error. */ int qemuDomainRefreshVcpuInfo(virQEMUDriverPtr driver, virDomainObjPtr vm, int asyncJob, bool state) { virDomainVcpuDefPtr vcpu; qemuDomainVcpuPrivatePtr vcpupriv; qemuMonitorCPUInfoPtr info = NULL; size_t maxvcpus = virDomainDefGetVcpusMax(vm->def); size_t i; bool hotplug; int rc; int ret = -1; hotplug = qemuDomainSupportsNewVcpuHotplug(vm); if (qemuDomainObjEnterMonitorAsync(driver, vm, asyncJob) < 0) return -1; rc = qemuMonitorGetCPUInfo(qemuDomainGetMonitor(vm), &info, maxvcpus, hotplug); if (qemuDomainObjExitMonitor(driver, vm) < 0) goto cleanup; if (rc < 0) goto cleanup; for (i = 0; i < maxvcpus; i++) { vcpu = virDomainDefGetVcpu(vm->def, i); vcpupriv = QEMU_DOMAIN_VCPU_PRIVATE(vcpu); /* * Current QEMU *can* report info about host threads mapped * to vCPUs, but it is not in a manner we can correctly * deal with. The TCG CPU emulation does have a separate vCPU * thread, but it runs every vCPU in that same thread. So it * is impossible to setup different affinity per thread. * * What's more the 'query-cpus' command returns bizarre * data for the threads. It gives the TCG thread for the * vCPU 0, but for vCPUs 1-> N, it actually replies with * the main process thread ID. * * The result is that when we try to set affinity for * vCPU 1, it will actually change the affinity of the * emulator thread :-( When you try to set affinity for * vCPUs 2, 3.... it will fail if the affinity was * different from vCPU 1. * * We *could* allow vcpu pinning with TCG, if we made the * restriction that all vCPUs had the same mask. This would * at least let us separate emulator from vCPUs threads, as * we do for KVM. It would need some changes to our cgroups * CPU layout though, and error reporting for the config * restrictions. * * Just disable CPU pinning with TCG until someone wants * to try to do this hard work. */ if (vm->def->virtType != VIR_DOMAIN_VIRT_QEMU) vcpupriv->tid = info[i].tid; vcpupriv->socket_id = info[i].socket_id; vcpupriv->core_id = info[i].core_id; vcpupriv->thread_id = info[i].thread_id; vcpupriv->node_id = info[i].node_id; vcpupriv->vcpus = info[i].vcpus; VIR_FREE(vcpupriv->type); VIR_STEAL_PTR(vcpupriv->type, info[i].type); VIR_FREE(vcpupriv->alias); VIR_STEAL_PTR(vcpupriv->alias, info[i].alias); vcpupriv->enable_id = info[i].id; vcpupriv->qemu_id = info[i].qemu_id; if (hotplug && state) { vcpu->online = info[i].online; if (info[i].hotpluggable) vcpu->hotpluggable = VIR_TRISTATE_BOOL_YES; else vcpu->hotpluggable = VIR_TRISTATE_BOOL_NO; } } ret = 0; cleanup: qemuMonitorCPUInfoFree(info, maxvcpus); return ret; } /** * qemuDomainGetVcpuHalted: * @vm: domain object * @vcpu: cpu id * * Returns the vCPU halted state. */ bool qemuDomainGetVcpuHalted(virDomainObjPtr vm, unsigned int vcpuid) { virDomainVcpuDefPtr vcpu = virDomainDefGetVcpu(vm->def, vcpuid); return QEMU_DOMAIN_VCPU_PRIVATE(vcpu)->halted; } /** * qemuDomainRefreshVcpuHalted: * @driver: qemu driver data * @vm: domain object * @asyncJob: current asynchronous job type * * Updates vCPU halted state in the private data of @vm. * * Returns 0 on success and -1 on error */ int qemuDomainRefreshVcpuHalted(virQEMUDriverPtr driver, virDomainObjPtr vm, int asyncJob) { virDomainVcpuDefPtr vcpu; qemuDomainVcpuPrivatePtr vcpupriv; size_t maxvcpus = virDomainDefGetVcpusMax(vm->def); virBitmapPtr haltedmap = NULL; size_t i; int ret = -1; /* Not supported currently for TCG, see qemuDomainRefreshVcpuInfo */ if (vm->def->virtType == VIR_DOMAIN_VIRT_QEMU) return 0; if (qemuDomainObjEnterMonitorAsync(driver, vm, asyncJob) < 0) return -1; haltedmap = qemuMonitorGetCpuHalted(qemuDomainGetMonitor(vm), maxvcpus); if (qemuDomainObjExitMonitor(driver, vm) < 0 || !haltedmap) goto cleanup; for (i = 0; i < maxvcpus; i++) { vcpu = virDomainDefGetVcpu(vm->def, i); vcpupriv = QEMU_DOMAIN_VCPU_PRIVATE(vcpu); vcpupriv->halted = virBitmapIsBitSet(haltedmap, vcpupriv->qemu_id); } ret = 0; cleanup: virBitmapFree(haltedmap); return ret; } bool qemuDomainSupportsNicdev(virDomainDefPtr def, virDomainNetDefPtr net) { /* non-virtio ARM nics require legacy -net nic */ if (((def->os.arch == VIR_ARCH_ARMV7L) || (def->os.arch == VIR_ARCH_AARCH64)) && net->info.type != VIR_DOMAIN_DEVICE_ADDRESS_TYPE_VIRTIO_MMIO && net->info.type != VIR_DOMAIN_DEVICE_ADDRESS_TYPE_PCI) return false; return true; } bool qemuDomainSupportsNetdev(virDomainDefPtr def, virQEMUCapsPtr qemuCaps, virDomainNetDefPtr net) { if (!qemuDomainSupportsNicdev(def, net)) return false; return virQEMUCapsGet(qemuCaps, QEMU_CAPS_NETDEV); } bool qemuDomainNetSupportsMTU(virDomainNetType type) { switch (type) { case VIR_DOMAIN_NET_TYPE_NETWORK: case VIR_DOMAIN_NET_TYPE_BRIDGE: case VIR_DOMAIN_NET_TYPE_ETHERNET: case VIR_DOMAIN_NET_TYPE_VHOSTUSER: return true; case VIR_DOMAIN_NET_TYPE_USER: case VIR_DOMAIN_NET_TYPE_SERVER: case VIR_DOMAIN_NET_TYPE_CLIENT: case VIR_DOMAIN_NET_TYPE_MCAST: case VIR_DOMAIN_NET_TYPE_INTERNAL: case VIR_DOMAIN_NET_TYPE_DIRECT: case VIR_DOMAIN_NET_TYPE_HOSTDEV: case VIR_DOMAIN_NET_TYPE_UDP: case VIR_DOMAIN_NET_TYPE_LAST: break; } return false; } int qemuDomainNetVLAN(virDomainNetDefPtr def) { return qemuDomainDeviceAliasIndex(&def->info, "net"); } virDomainDiskDefPtr qemuDomainDiskByName(virDomainDefPtr def, const char *name) { virDomainDiskDefPtr ret; if (!(ret = virDomainDiskByName(def, name, true))) { virReportError(VIR_ERR_INVALID_ARG, "%s", _("No device found for specified path")); return NULL; } return ret; } /** * qemuDomainDefValidateDiskLunSource: * @src: disk source struct * * Validate whether the disk source is valid for disk device='lun'. * * Returns 0 if the configuration is valid -1 and a libvirt error if the soure * is invalid. */ int qemuDomainDefValidateDiskLunSource(const virStorageSource *src) { if (virStorageSourceGetActualType(src) == VIR_STORAGE_TYPE_NETWORK) { if (src->protocol != VIR_STORAGE_NET_PROTOCOL_ISCSI) { virReportError(VIR_ERR_CONFIG_UNSUPPORTED, _("disk device='lun' is not supported " "for protocol='%s'"), virStorageNetProtocolTypeToString(src->protocol)); return -1; } } else if (!virStorageSourceIsBlockLocal(src)) { virReportError(VIR_ERR_CONFIG_UNSUPPORTED, "%s", _("disk device='lun' is only valid for block " "type disk source")); return -1; } return 0; } int qemuDomainPrepareChannel(virDomainChrDefPtr channel, const char *domainChannelTargetDir) { if (channel->targetType != VIR_DOMAIN_CHR_CHANNEL_TARGET_TYPE_VIRTIO || channel->source->type != VIR_DOMAIN_CHR_TYPE_UNIX || channel->source->data.nix.path) return 0; if (channel->target.name) { if (virAsprintf(&channel->source->data.nix.path, "%s/%s", domainChannelTargetDir, channel->target.name) < 0) return -1; } else { /* Generate a unique name */ if (virAsprintf(&channel->source->data.nix.path, "%s/vioser-%02d-%02d-%02d.sock", domainChannelTargetDir, channel->info.addr.vioserial.controller, channel->info.addr.vioserial.bus, channel->info.addr.vioserial.port) < 0) return -1; } return 0; } /* qemuDomainPrepareChardevSourceTLS: * @source: pointer to host interface data for char devices * @cfg: driver configuration * * Updates host interface TLS encryption setting based on qemu.conf * for char devices. This will be presented as "tls='yes|no'" in * live XML of a guest. */ void qemuDomainPrepareChardevSourceTLS(virDomainChrSourceDefPtr source, virQEMUDriverConfigPtr cfg) { if (source->type == VIR_DOMAIN_CHR_TYPE_TCP) { if (source->data.tcp.haveTLS == VIR_TRISTATE_BOOL_ABSENT) { if (cfg->chardevTLS) source->data.tcp.haveTLS = VIR_TRISTATE_BOOL_YES; else source->data.tcp.haveTLS = VIR_TRISTATE_BOOL_NO; source->data.tcp.tlsFromConfig = true; } } } /* qemuDomainPrepareChardevSource: * @def: live domain definition * @cfg: driver configuration * * Iterate through all devices that use virDomainChrSourceDefPtr as host * interface part. */ void qemuDomainPrepareChardevSource(virDomainDefPtr def, virQEMUDriverConfigPtr cfg) { size_t i; for (i = 0; i < def->nserials; i++) qemuDomainPrepareChardevSourceTLS(def->serials[i]->source, cfg); for (i = 0; i < def->nparallels; i++) qemuDomainPrepareChardevSourceTLS(def->parallels[i]->source, cfg); for (i = 0; i < def->nchannels; i++) qemuDomainPrepareChardevSourceTLS(def->channels[i]->source, cfg); for (i = 0; i < def->nconsoles; i++) qemuDomainPrepareChardevSourceTLS(def->consoles[i]->source, cfg); for (i = 0; i < def->nrngs; i++) if (def->rngs[i]->backend == VIR_DOMAIN_RNG_BACKEND_EGD) qemuDomainPrepareChardevSourceTLS(def->rngs[i]->source.chardev, cfg); for (i = 0; i < def->nsmartcards; i++) if (def->smartcards[i]->type == VIR_DOMAIN_SMARTCARD_TYPE_PASSTHROUGH) qemuDomainPrepareChardevSourceTLS(def->smartcards[i]->data.passthru, cfg); for (i = 0; i < def->nredirdevs; i++) qemuDomainPrepareChardevSourceTLS(def->redirdevs[i]->source, cfg); } /* qemuProcessPrepareDiskSourceTLS: * @source: pointer to host interface data for disk device * @cfg: driver configuration * * Updates host interface TLS encryption setting based on qemu.conf * for disk devices. This will be presented as "tls='yes|no'" in * live XML of a guest. * * Returns 0 on success, -1 on bad config/failure */ static int qemuDomainPrepareDiskSourceTLS(virStorageSourcePtr src, virQEMUDriverConfigPtr cfg) { virStorageSourcePtr next; for (next = src; virStorageSourceIsBacking(next); next = next->backingStore) { /* VxHS uses only client certificates and thus has no need for * the server-key.pem nor a secret that could be used to decrypt * the it, so no need to add a secinfo for a secret UUID. */ if (next->type == VIR_STORAGE_TYPE_NETWORK && next->protocol == VIR_STORAGE_NET_PROTOCOL_VXHS) { if (next->haveTLS == VIR_TRISTATE_BOOL_ABSENT) { if (cfg->vxhsTLS) next->haveTLS = VIR_TRISTATE_BOOL_YES; else next->haveTLS = VIR_TRISTATE_BOOL_NO; next->tlsFromConfig = true; } if (next->haveTLS == VIR_TRISTATE_BOOL_YES) { /* Grab the vxhsTLSx509certdir and set the verify/listen values. * NB: tlsAlias filled in during qemuDomainGetTLSObjects. */ if (VIR_STRDUP(next->tlsCertdir, cfg->vxhsTLSx509certdir) < 0) return -1; next->tlsVerify = true; } } } return 0; } int qemuDomainPrepareShmemChardev(virDomainShmemDefPtr shmem) { if (!shmem->server.enabled || shmem->server.chr.data.nix.path) return 0; return virAsprintf(&shmem->server.chr.data.nix.path, "/var/lib/libvirt/shmem-%s-sock", shmem->name); } /** * qemuDomainVcpuHotplugIsInOrder: * @def: domain definition * * Returns true if online vcpus were added in order (clustered behind vcpu0 * with increasing order). */ bool qemuDomainVcpuHotplugIsInOrder(virDomainDefPtr def) { size_t maxvcpus = virDomainDefGetVcpusMax(def); virDomainVcpuDefPtr vcpu; unsigned int prevorder = 0; size_t seenonlinevcpus = 0; size_t i; for (i = 0; i < maxvcpus; i++) { vcpu = virDomainDefGetVcpu(def, i); if (!vcpu->online) break; if (vcpu->order < prevorder) break; if (vcpu->order > prevorder) prevorder = vcpu->order; seenonlinevcpus++; } return seenonlinevcpus == virDomainDefGetVcpus(def); } /** * qemuDomainVcpuPersistOrder: * @def: domain definition * * Saves the order of vcpus detected from qemu to the domain definition. * The private data note the order only for the entry describing the * hotpluggable entity. This function copies the order into the definition part * of all sub entities. */ void qemuDomainVcpuPersistOrder(virDomainDefPtr def) { size_t maxvcpus = virDomainDefGetVcpusMax(def); virDomainVcpuDefPtr vcpu; qemuDomainVcpuPrivatePtr vcpupriv; unsigned int prevorder = 0; size_t i; for (i = 0; i < maxvcpus; i++) { vcpu = virDomainDefGetVcpu(def, i); vcpupriv = QEMU_DOMAIN_VCPU_PRIVATE(vcpu); if (!vcpu->online) { vcpu->order = 0; } else { if (vcpupriv->enable_id != 0) prevorder = vcpupriv->enable_id; vcpu->order = prevorder; } } } int qemuDomainCheckMonitor(virQEMUDriverPtr driver, virDomainObjPtr vm, qemuDomainAsyncJob asyncJob) { qemuDomainObjPrivatePtr priv = vm->privateData; int ret; if (qemuDomainObjEnterMonitorAsync(driver, vm, asyncJob) < 0) return -1; ret = qemuMonitorCheck(priv->mon); if (qemuDomainObjExitMonitor(driver, vm) < 0) return -1; return ret; } bool qemuDomainSupportsVideoVga(virDomainVideoDefPtr video, virQEMUCapsPtr qemuCaps) { if (video->type == VIR_DOMAIN_VIDEO_TYPE_VIRTIO && !virQEMUCapsGet(qemuCaps, QEMU_CAPS_DEVICE_VIRTIO_VGA)) return false; return true; } /** * qemuDomainGetHostdevPath: * @def: domain definition * @dev: host device definition * @teardown: true if device will be removed * @npaths: number of items in @path and @perms arrays * @path: resulting path to @dev * @perms: Optional pointer to VIR_CGROUP_DEVICE_* perms * * For given device @dev fetch its host path and store it at * @path. If a device requires other paths to be present/allowed * they are stored in the @path array after the actual path. * Optionally, caller can get @perms on the path (e.g. rw/ro). * * The caller is responsible for freeing the memory. * * Returns 0 on success, -1 otherwise. */ int qemuDomainGetHostdevPath(virDomainDefPtr def, virDomainHostdevDefPtr dev, bool teardown, size_t *npaths, char ***path, int **perms) { int ret = -1; virDomainHostdevSubsysUSBPtr usbsrc = &dev->source.subsys.u.usb; virDomainHostdevSubsysPCIPtr pcisrc = &dev->source.subsys.u.pci; virDomainHostdevSubsysSCSIPtr scsisrc = &dev->source.subsys.u.scsi; virDomainHostdevSubsysSCSIVHostPtr hostsrc = &dev->source.subsys.u.scsi_host; virDomainHostdevSubsysMediatedDevPtr mdevsrc = &dev->source.subsys.u.mdev; virPCIDevicePtr pci = NULL; virUSBDevicePtr usb = NULL; virSCSIDevicePtr scsi = NULL; virSCSIVHostDevicePtr host = NULL; char *tmpPath = NULL; bool freeTmpPath = false; bool includeVFIO = false; char **tmpPaths = NULL; int *tmpPerms = NULL; size_t i, tmpNpaths = 0; int perm = 0; *npaths = 0; switch ((virDomainHostdevMode) dev->mode) { case VIR_DOMAIN_HOSTDEV_MODE_SUBSYS: switch ((virDomainHostdevSubsysType) dev->source.subsys.type) { case VIR_DOMAIN_HOSTDEV_SUBSYS_TYPE_PCI: if (pcisrc->backend == VIR_DOMAIN_HOSTDEV_PCI_BACKEND_VFIO) { pci = virPCIDeviceNew(pcisrc->addr.domain, pcisrc->addr.bus, pcisrc->addr.slot, pcisrc->addr.function); if (!pci) goto cleanup; if (!(tmpPath = virPCIDeviceGetIOMMUGroupDev(pci))) goto cleanup; freeTmpPath = true; perm = VIR_CGROUP_DEVICE_RW; if (teardown) { size_t nvfios = 0; for (i = 0; i < def->nhostdevs; i++) { virDomainHostdevDefPtr tmp = def->hostdevs[i]; if (tmp->mode == VIR_DOMAIN_HOSTDEV_MODE_SUBSYS && tmp->source.subsys.type == VIR_DOMAIN_HOSTDEV_SUBSYS_TYPE_PCI && tmp->source.subsys.u.pci.backend == VIR_DOMAIN_HOSTDEV_PCI_BACKEND_VFIO) nvfios++; } if (nvfios == 0) includeVFIO = true; } else { includeVFIO = true; } } break; case VIR_DOMAIN_HOSTDEV_SUBSYS_TYPE_USB: if (dev->missing) break; usb = virUSBDeviceNew(usbsrc->bus, usbsrc->device, NULL); if (!usb) goto cleanup; if (!(tmpPath = (char *) virUSBDeviceGetPath(usb))) goto cleanup; perm = VIR_CGROUP_DEVICE_RW; break; case VIR_DOMAIN_HOSTDEV_SUBSYS_TYPE_SCSI: if (scsisrc->protocol == VIR_DOMAIN_HOSTDEV_SCSI_PROTOCOL_TYPE_ISCSI) { virDomainHostdevSubsysSCSIiSCSIPtr iscsisrc = &scsisrc->u.iscsi; /* Follow qemuSetupDiskCgroup() and qemuSetImageCgroupInternal() * which does nothing for non local storage */ VIR_DEBUG("Not updating /dev for hostdev iSCSI path '%s'", iscsisrc->src->path); } else { virDomainHostdevSubsysSCSIHostPtr scsihostsrc = &scsisrc->u.host; scsi = virSCSIDeviceNew(NULL, scsihostsrc->adapter, scsihostsrc->bus, scsihostsrc->target, scsihostsrc->unit, dev->readonly, dev->shareable); if (!scsi) goto cleanup; if (!(tmpPath = (char *) virSCSIDeviceGetPath(scsi))) goto cleanup; perm = virSCSIDeviceGetReadonly(scsi) ? VIR_CGROUP_DEVICE_READ : VIR_CGROUP_DEVICE_RW; } break; case VIR_DOMAIN_HOSTDEV_SUBSYS_TYPE_SCSI_HOST: { if (hostsrc->protocol == VIR_DOMAIN_HOSTDEV_SUBSYS_SCSI_HOST_PROTOCOL_TYPE_VHOST) { if (!(host = virSCSIVHostDeviceNew(hostsrc->wwpn))) goto cleanup; if (!(tmpPath = (char *) virSCSIVHostDeviceGetPath(host))) goto cleanup; perm = VIR_CGROUP_DEVICE_RW; } break; } case VIR_DOMAIN_HOSTDEV_SUBSYS_TYPE_MDEV: if (!(tmpPath = virMediatedDeviceGetIOMMUGroupDev(mdevsrc->uuidstr))) goto cleanup; freeTmpPath = true; includeVFIO = true; perm = VIR_CGROUP_DEVICE_RW; break; case VIR_DOMAIN_HOSTDEV_SUBSYS_TYPE_LAST: break; } break; case VIR_DOMAIN_HOSTDEV_MODE_CAPABILITIES: case VIR_DOMAIN_HOSTDEV_MODE_LAST: /* nada */ break; } if (tmpPath) { size_t toAlloc = 1; if (includeVFIO) toAlloc = 2; if (VIR_ALLOC_N(tmpPaths, toAlloc) < 0 || VIR_ALLOC_N(tmpPerms, toAlloc) < 0 || VIR_STRDUP(tmpPaths[0], tmpPath) < 0) goto cleanup; tmpNpaths = toAlloc; tmpPerms[0] = perm; if (includeVFIO) { if (VIR_STRDUP(tmpPaths[1], DEV_VFIO) < 0) goto cleanup; tmpPerms[1] = VIR_CGROUP_DEVICE_RW; } } *npaths = tmpNpaths; tmpNpaths = 0; *path = tmpPaths; tmpPaths = NULL; if (perms) { *perms = tmpPerms; tmpPerms = NULL; } ret = 0; cleanup: for (i = 0; i < tmpNpaths; i++) VIR_FREE(tmpPaths[i]); VIR_FREE(tmpPaths); VIR_FREE(tmpPerms); virPCIDeviceFree(pci); virUSBDeviceFree(usb); virSCSIDeviceFree(scsi); virSCSIVHostDeviceFree(host); if (freeTmpPath) VIR_FREE(tmpPath); return ret; } /** * qemuDomainGetPreservedMountPath: * @cfg: driver configuration data * @vm: domain object * @mountpoint: mount point path to convert * * For given @mountpoint return new path where the mount point * should be moved temporarily whilst building the namespace. * * Returns: allocated string on success which the caller must free, * NULL on failure. */ static char * qemuDomainGetPreservedMountPath(virQEMUDriverConfigPtr cfg, virDomainObjPtr vm, const char *mountpoint) { char *path = NULL; char *tmp; const char *suffix = mountpoint + strlen(DEVPREFIX); char *domname = virDomainDefGetShortName(vm->def); size_t off; if (!domname) return NULL; if (STREQ(mountpoint, "/dev")) suffix = "dev"; if (virAsprintf(&path, "%s/%s.%s", cfg->stateDir, domname, suffix) < 0) goto cleanup; /* Now consider that @mountpoint is "/dev/blah/blah2". * @suffix then points to "blah/blah2". However, caller * expects all the @paths to be the same depth. The * caller doesn't always do `mkdir -p` but sometimes bare * `touch`. Therefore fix all the suffixes. */ off = strlen(path) - strlen(suffix); tmp = path + off; while (*tmp) { if (*tmp == '/') *tmp = '.'; tmp++; } cleanup: VIR_FREE(domname); return path; } /** * qemuDomainGetPreservedMounts: * * Process list of mounted filesystems and: * a) save all FSs mounted under /dev to @devPath * b) generate backup path for all the entries in a) * * Any of the return pointers can be NULL. * * Returns 0 on success, -1 otherwise (with error reported) */ static int qemuDomainGetPreservedMounts(virQEMUDriverConfigPtr cfg, virDomainObjPtr vm, char ***devPath, char ***devSavePath, size_t *ndevPath) { char **paths = NULL, **mounts = NULL; size_t i, j, nmounts; if (virFileGetMountSubtree(PROC_MOUNTS, "/dev", &mounts, &nmounts) < 0) goto error; if (!nmounts) { if (ndevPath) *ndevPath = 0; return 0; } /* There can be nested mount points. For instance * /dev/shm/blah can be a mount point and /dev/shm too. It * doesn't make much sense to return the former path because * caller preserves the latter (and with that the former * too). Therefore prune nested mount points. * NB mounts[0] is "/dev". Should we start the outer loop * from the beginning of the array all we'd be left with is * just the first element. Think about it. */ for (i = 1; i < nmounts; i++) { j = i + 1; while (j < nmounts) { char *c = STRSKIP(mounts[j], mounts[i]); if (c && (*c == '/' || *c == '\0')) { VIR_DEBUG("Dropping path %s because of %s", mounts[j], mounts[i]); VIR_DELETE_ELEMENT(mounts, j, nmounts); } else { j++; } } } if (VIR_ALLOC_N(paths, nmounts) < 0) goto error; for (i = 0; i < nmounts; i++) { if (!(paths[i] = qemuDomainGetPreservedMountPath(cfg, vm, mounts[i]))) goto error; } if (devPath) *devPath = mounts; else virStringListFreeCount(mounts, nmounts); if (devSavePath) *devSavePath = paths; else virStringListFreeCount(paths, nmounts); if (ndevPath) *ndevPath = nmounts; return 0; error: virStringListFreeCount(mounts, nmounts); virStringListFreeCount(paths, nmounts); return -1; } struct qemuDomainCreateDeviceData { const char *path; /* Path to temp new /dev location */ char * const *devMountsPath; size_t ndevMountsPath; }; static int qemuDomainCreateDeviceRecursive(const char *device, const struct qemuDomainCreateDeviceData *data, bool allow_noent, unsigned int ttl) { char *devicePath = NULL; char *target = NULL; struct stat sb; int ret = -1; bool isLink = false; bool isDev = false; bool isReg = false; bool isDir = false; bool create = false; #ifdef WITH_SELINUX char *tcon = NULL; #endif if (!ttl) { virReportSystemError(ELOOP, _("Too many levels of symbolic links: %s"), device); return ret; } if (lstat(device, &sb) < 0) { if (errno == ENOENT && allow_noent) { /* Ignore non-existent device. */ return 0; } virReportSystemError(errno, _("Unable to stat %s"), device); return ret; } isLink = S_ISLNK(sb.st_mode); isDev = S_ISCHR(sb.st_mode) || S_ISBLK(sb.st_mode); isReg = S_ISREG(sb.st_mode) || S_ISFIFO(sb.st_mode) || S_ISSOCK(sb.st_mode); isDir = S_ISDIR(sb.st_mode); /* Here, @device might be whatever path in the system. We * should create the path in the namespace iff it's "/dev" * prefixed. However, if it is a symlink, we need to traverse * it too (it might point to something in "/dev"). Just * consider: * * /var/sym1 -> /var/sym2 -> /dev/sda (because users can) * * This means, "/var/sym1" is not created (it's shared with * the parent namespace), nor "/var/sym2", but "/dev/sda". * * TODO Remove all `.' and `..' from the @device path. * Otherwise we might get fooled with `/dev/../var/my_image'. * For now, lets hope callers play nice. */ if (STRPREFIX(device, DEVPREFIX)) { size_t i; for (i = 0; i < data->ndevMountsPath; i++) { if (STREQ(data->devMountsPath[i], "/dev")) continue; if (STRPREFIX(device, data->devMountsPath[i])) break; } if (i == data->ndevMountsPath) { /* Okay, @device is in /dev but not in any mount point under /dev. * Create it. */ if (virAsprintf(&devicePath, "%s/%s", data->path, device + strlen(DEVPREFIX)) < 0) goto cleanup; if (virFileMakeParentPath(devicePath) < 0) { virReportSystemError(errno, _("Unable to create %s"), devicePath); goto cleanup; } VIR_DEBUG("Creating dev %s", device); create = true; } else { VIR_DEBUG("Skipping dev %s because of %s mount point", device, data->devMountsPath[i]); } } if (isLink) { /* We are dealing with a symlink. Create a dangling symlink and descend * down one level which hopefully creates the symlink's target. */ if (virFileReadLink(device, &target) < 0) { virReportSystemError(errno, _("unable to resolve symlink %s"), device); goto cleanup; } if (create && symlink(target, devicePath) < 0) { if (errno == EEXIST) { ret = 0; } else { virReportSystemError(errno, _("unable to create symlink %s"), devicePath); } goto cleanup; } /* Tricky part. If the target starts with a slash then we need to take * it as it is. Otherwise we need to replace the last component in the * original path with the link target: * /dev/rtc -> rtc0 (want /dev/rtc0) * /dev/disk/by-id/ata-SanDisk_SDSSDXPS480G_161101402485 -> ../../sda * (want /dev/disk/by-id/../../sda) * /dev/stdout -> /proc/self/fd/1 (no change needed) */ if (IS_RELATIVE_FILE_NAME(target)) { char *c = NULL, *tmp = NULL, *devTmp = NULL; if (VIR_STRDUP(devTmp, device) < 0) goto cleanup; if ((c = strrchr(devTmp, '/'))) *(c + 1) = '\0'; if (virAsprintf(&tmp, "%s%s", devTmp, target) < 0) { VIR_FREE(devTmp); goto cleanup; } VIR_FREE(devTmp); VIR_FREE(target); target = tmp; tmp = NULL; } if (qemuDomainCreateDeviceRecursive(target, data, allow_noent, ttl - 1) < 0) goto cleanup; } else if (isDev) { if (create && mknod(devicePath, sb.st_mode, sb.st_rdev) < 0) { if (errno == EEXIST) { ret = 0; } else { virReportSystemError(errno, _("Failed to make device %s"), devicePath); } goto cleanup; } } else if (isReg) { if (create && virFileTouch(devicePath, sb.st_mode) < 0) goto cleanup; /* Just create the file here so that code below sets * proper owner and mode. Bind mount only after that. */ } else if (isDir) { if (create && virFileMakePathWithMode(devicePath, sb.st_mode) < 0) goto cleanup; } else { virReportError(VIR_ERR_OPERATION_UNSUPPORTED, _("unsupported device type %s 0%o"), device, sb.st_mode); goto cleanup; } if (!create) { ret = 0; goto cleanup; } if (lchown(devicePath, sb.st_uid, sb.st_gid) < 0) { virReportSystemError(errno, _("Failed to chown device %s"), devicePath); goto cleanup; } /* Symlinks don't have mode */ if (!isLink && chmod(devicePath, sb.st_mode) < 0) { virReportSystemError(errno, _("Failed to set permissions for device %s"), devicePath); goto cleanup; } /* Symlinks don't have ACLs. */ if (!isLink && virFileCopyACLs(device, devicePath) < 0 && errno != ENOTSUP) { virReportSystemError(errno, _("Failed to copy ACLs on device %s"), devicePath); goto cleanup; } #ifdef WITH_SELINUX if (lgetfilecon_raw(device, &tcon) < 0 && (errno != ENOTSUP && errno != ENODATA)) { virReportSystemError(errno, _("Unable to get SELinux label from %s"), device); goto cleanup; } if (tcon && lsetfilecon_raw(devicePath, (VIR_SELINUX_CTX_CONST char *) tcon) < 0) { VIR_WARNINGS_NO_WLOGICALOP_EQUAL_EXPR if (errno != EOPNOTSUPP && errno != ENOTSUP) { VIR_WARNINGS_RESET virReportSystemError(errno, _("Unable to set SELinux label on %s"), devicePath); goto cleanup; } } #endif /* Finish mount process started earlier. */ if ((isReg || isDir) && virFileBindMountDevice(device, devicePath) < 0) goto cleanup; ret = 0; cleanup: VIR_FREE(target); VIR_FREE(devicePath); #ifdef WITH_SELINUX freecon(tcon); #endif return ret; } static int qemuDomainCreateDevice(const char *device, const struct qemuDomainCreateDeviceData *data, bool allow_noent) { long symloop_max = sysconf(_SC_SYMLOOP_MAX); return qemuDomainCreateDeviceRecursive(device, data, allow_noent, symloop_max); } static int qemuDomainPopulateDevices(virQEMUDriverConfigPtr cfg, virDomainObjPtr vm ATTRIBUTE_UNUSED, const struct qemuDomainCreateDeviceData *data) { const char *const *devices = (const char *const *) cfg->cgroupDeviceACL; size_t i; int ret = -1; if (!devices) devices = defaultDeviceACL; for (i = 0; devices[i]; i++) { if (qemuDomainCreateDevice(devices[i], data, true) < 0) goto cleanup; } ret = 0; cleanup: return ret; } static int qemuDomainSetupDev(virQEMUDriverConfigPtr cfg, virSecurityManagerPtr mgr, virDomainObjPtr vm, const struct qemuDomainCreateDeviceData *data) { char *mount_options = NULL; char *opts = NULL; int ret = -1; VIR_DEBUG("Setting up /dev/ for domain %s", vm->def->name); mount_options = qemuSecurityGetMountOptions(mgr, vm->def); if (!mount_options && VIR_STRDUP(mount_options, "") < 0) goto cleanup; /* * tmpfs is limited to 64kb, since we only have device nodes in there * and don't want to DOS the entire OS RAM usage */ if (virAsprintf(&opts, "mode=755,size=65536%s", mount_options) < 0) goto cleanup; if (virFileSetupDev(data->path, opts) < 0) goto cleanup; if (qemuDomainPopulateDevices(cfg, vm, data) < 0) goto cleanup; ret = 0; cleanup: VIR_FREE(opts); VIR_FREE(mount_options); return ret; } static int qemuDomainSetupDisk(virQEMUDriverConfigPtr cfg ATTRIBUTE_UNUSED, virDomainDiskDefPtr disk, const struct qemuDomainCreateDeviceData *data) { virStorageSourcePtr next; char *dst = NULL; int ret = -1; for (next = disk->src; virStorageSourceIsBacking(next); next = next->backingStore) { if (!next->path || !virStorageSourceIsLocalStorage(next)) { /* Not creating device. Just continue. */ continue; } if (qemuDomainCreateDevice(next->path, data, false) < 0) goto cleanup; } ret = 0; cleanup: VIR_FREE(dst); return ret; } static int qemuDomainSetupAllDisks(virQEMUDriverConfigPtr cfg, virDomainObjPtr vm, const struct qemuDomainCreateDeviceData *data) { size_t i; VIR_DEBUG("Setting up disks"); for (i = 0; i < vm->def->ndisks; i++) { if (qemuDomainSetupDisk(cfg, vm->def->disks[i], data) < 0) return -1; } VIR_DEBUG("Setup all disks"); return 0; } static int qemuDomainSetupHostdev(virQEMUDriverConfigPtr cfg ATTRIBUTE_UNUSED, virDomainHostdevDefPtr dev, const struct qemuDomainCreateDeviceData *data) { int ret = -1; char **path = NULL; size_t i, npaths = 0; if (qemuDomainGetHostdevPath(NULL, dev, false, &npaths, &path, NULL) < 0) goto cleanup; for (i = 0; i < npaths; i++) { if (qemuDomainCreateDevice(path[i], data, false) < 0) goto cleanup; } ret = 0; cleanup: for (i = 0; i < npaths; i++) VIR_FREE(path[i]); VIR_FREE(path); return ret; } static int qemuDomainSetupAllHostdevs(virQEMUDriverConfigPtr cfg, virDomainObjPtr vm, const struct qemuDomainCreateDeviceData *data) { size_t i; VIR_DEBUG("Setting up hostdevs"); for (i = 0; i < vm->def->nhostdevs; i++) { if (qemuDomainSetupHostdev(cfg, vm->def->hostdevs[i], data) < 0) return -1; } VIR_DEBUG("Setup all hostdevs"); return 0; } static int qemuDomainSetupMemory(virQEMUDriverConfigPtr cfg ATTRIBUTE_UNUSED, virDomainMemoryDefPtr mem, const struct qemuDomainCreateDeviceData *data) { if (mem->model != VIR_DOMAIN_MEMORY_MODEL_NVDIMM) return 0; return qemuDomainCreateDevice(mem->nvdimmPath, data, false); } static int qemuDomainSetupAllMemories(virQEMUDriverConfigPtr cfg, virDomainObjPtr vm, const struct qemuDomainCreateDeviceData *data) { size_t i; VIR_DEBUG("Setting up memories"); for (i = 0; i < vm->def->nmems; i++) { if (qemuDomainSetupMemory(cfg, vm->def->mems[i], data) < 0) return -1; } VIR_DEBUG("Setup all memories"); return 0; } static int qemuDomainSetupChardev(virDomainDefPtr def ATTRIBUTE_UNUSED, virDomainChrDefPtr dev, void *opaque) { const struct qemuDomainCreateDeviceData *data = opaque; const char *path = NULL; if (!(path = virDomainChrSourceDefGetPath(dev->source))) return 0; /* Socket created by qemu. It doesn't exist upfront. */ if (dev->source->type == VIR_DOMAIN_CHR_TYPE_UNIX && dev->source->data.nix.listen) return 0; return qemuDomainCreateDevice(path, data, true); } static int qemuDomainSetupAllChardevs(virQEMUDriverConfigPtr cfg ATTRIBUTE_UNUSED, virDomainObjPtr vm, const struct qemuDomainCreateDeviceData *data) { VIR_DEBUG("Setting up chardevs"); if (virDomainChrDefForeach(vm->def, true, qemuDomainSetupChardev, (void *) data) < 0) return -1; VIR_DEBUG("Setup all chardevs"); return 0; } static int qemuDomainSetupTPM(virQEMUDriverConfigPtr cfg ATTRIBUTE_UNUSED, virDomainObjPtr vm, const struct qemuDomainCreateDeviceData *data) { virDomainTPMDefPtr dev = vm->def->tpm; if (!dev) return 0; VIR_DEBUG("Setting up TPM"); switch (dev->type) { case VIR_DOMAIN_TPM_TYPE_PASSTHROUGH: if (qemuDomainCreateDevice(dev->data.passthrough.source.data.file.path, data, false) < 0) return -1; break; case VIR_DOMAIN_TPM_TYPE_LAST: /* nada */ break; } VIR_DEBUG("Setup TPM"); return 0; } static int qemuDomainSetupGraphics(virQEMUDriverConfigPtr cfg ATTRIBUTE_UNUSED, virDomainGraphicsDefPtr gfx, const struct qemuDomainCreateDeviceData *data) { const char *rendernode = gfx->data.spice.rendernode; if (gfx->type != VIR_DOMAIN_GRAPHICS_TYPE_SPICE || gfx->data.spice.gl != VIR_TRISTATE_BOOL_YES || !rendernode) return 0; return qemuDomainCreateDevice(rendernode, data, false); } static int qemuDomainSetupAllGraphics(virQEMUDriverConfigPtr cfg, virDomainObjPtr vm, const struct qemuDomainCreateDeviceData *data) { size_t i; VIR_DEBUG("Setting up graphics"); for (i = 0; i < vm->def->ngraphics; i++) { if (qemuDomainSetupGraphics(cfg, vm->def->graphics[i], data) < 0) return -1; } VIR_DEBUG("Setup all graphics"); return 0; } static int qemuDomainSetupInput(virQEMUDriverConfigPtr cfg ATTRIBUTE_UNUSED, virDomainInputDefPtr input, const struct qemuDomainCreateDeviceData *data) { const char *path = virDomainInputDefGetPath(input); if (path && qemuDomainCreateDevice(path, data, false) < 0) return -1; return 0; } static int qemuDomainSetupAllInputs(virQEMUDriverConfigPtr cfg, virDomainObjPtr vm, const struct qemuDomainCreateDeviceData *data) { size_t i; VIR_DEBUG("Setting up inputs"); for (i = 0; i < vm->def->ninputs; i++) { if (qemuDomainSetupInput(cfg, vm->def->inputs[i], data) < 0) return -1; } VIR_DEBUG("Setup all inputs"); return 0; } static int qemuDomainSetupRNG(virQEMUDriverConfigPtr cfg ATTRIBUTE_UNUSED, virDomainRNGDefPtr rng, const struct qemuDomainCreateDeviceData *data) { switch ((virDomainRNGBackend) rng->backend) { case VIR_DOMAIN_RNG_BACKEND_RANDOM: if (qemuDomainCreateDevice(rng->source.file, data, false) < 0) return -1; case VIR_DOMAIN_RNG_BACKEND_EGD: case VIR_DOMAIN_RNG_BACKEND_LAST: /* nada */ break; } return 0; } static int qemuDomainSetupAllRNGs(virQEMUDriverConfigPtr cfg, virDomainObjPtr vm, const struct qemuDomainCreateDeviceData *data) { size_t i; VIR_DEBUG("Setting up RNGs"); for (i = 0; i < vm->def->nrngs; i++) { if (qemuDomainSetupRNG(cfg, vm->def->rngs[i], data) < 0) return -1; } VIR_DEBUG("Setup all RNGs"); return 0; } static int qemuDomainSetupLoader(virQEMUDriverConfigPtr cfg ATTRIBUTE_UNUSED, virDomainObjPtr vm, const struct qemuDomainCreateDeviceData *data) { virDomainLoaderDefPtr loader = vm->def->os.loader; int ret = -1; VIR_DEBUG("Setting up loader"); if (loader) { switch ((virDomainLoader) loader->type) { case VIR_DOMAIN_LOADER_TYPE_ROM: if (qemuDomainCreateDevice(loader->path, data, false) < 0) goto cleanup; break; case VIR_DOMAIN_LOADER_TYPE_PFLASH: if (qemuDomainCreateDevice(loader->path, data, false) < 0) goto cleanup; if (loader->nvram && qemuDomainCreateDevice(loader->nvram, data, false) < 0) goto cleanup; break; case VIR_DOMAIN_LOADER_TYPE_LAST: break; } } VIR_DEBUG("Setup loader"); ret = 0; cleanup: return ret; } int qemuDomainBuildNamespace(virQEMUDriverConfigPtr cfg, virSecurityManagerPtr mgr, virDomainObjPtr vm) { struct qemuDomainCreateDeviceData data; char *devPath = NULL; char **devMountsPath = NULL, **devMountsSavePath = NULL; size_t ndevMountsPath = 0, i; int ret = -1; if (!qemuDomainNamespaceEnabled(vm, QEMU_DOMAIN_NS_MOUNT)) { ret = 0; goto cleanup; } if (qemuDomainGetPreservedMounts(cfg, vm, &devMountsPath, &devMountsSavePath, &ndevMountsPath) < 0) goto cleanup; for (i = 0; i < ndevMountsPath; i++) { if (STREQ(devMountsPath[i], "/dev")) { devPath = devMountsSavePath[i]; break; } } if (!devPath) { virReportError(VIR_ERR_INTERNAL_ERROR, "%s", _("Unable to find any /dev mount")); goto cleanup; } data.path = devPath; data.devMountsPath = devMountsPath; data.ndevMountsPath = ndevMountsPath; if (virProcessSetupPrivateMountNS() < 0) goto cleanup; if (qemuDomainSetupDev(cfg, mgr, vm, &data) < 0) goto cleanup; if (qemuDomainSetupAllDisks(cfg, vm, &data) < 0) goto cleanup; if (qemuDomainSetupAllHostdevs(cfg, vm, &data) < 0) goto cleanup; if (qemuDomainSetupAllMemories(cfg, vm, &data) < 0) goto cleanup; if (qemuDomainSetupAllChardevs(cfg, vm, &data) < 0) goto cleanup; if (qemuDomainSetupTPM(cfg, vm, &data) < 0) goto cleanup; if (qemuDomainSetupAllGraphics(cfg, vm, &data) < 0) goto cleanup; if (qemuDomainSetupAllInputs(cfg, vm, &data) < 0) goto cleanup; if (qemuDomainSetupAllRNGs(cfg, vm, &data) < 0) goto cleanup; if (qemuDomainSetupLoader(cfg, vm, &data) < 0) goto cleanup; /* Save some mount points because we want to share them with the host */ for (i = 0; i < ndevMountsPath; i++) { struct stat sb; if (devMountsSavePath[i] == devPath) continue; if (stat(devMountsPath[i], &sb) < 0) { virReportSystemError(errno, _("Unable to stat: %s"), devMountsPath[i]); goto cleanup; } /* At this point, devMountsPath is either: * a file (regular or special), or * a directory. */ if ((S_ISDIR(sb.st_mode) && virFileMakePath(devMountsSavePath[i]) < 0) || (!S_ISDIR(sb.st_mode) && virFileTouch(devMountsSavePath[i], sb.st_mode) < 0)) { virReportSystemError(errno, _("Failed to create %s"), devMountsSavePath[i]); goto cleanup; } if (virFileMoveMount(devMountsPath[i], devMountsSavePath[i]) < 0) goto cleanup; } if (virFileMoveMount(devPath, "/dev") < 0) goto cleanup; for (i = 0; i < ndevMountsPath; i++) { struct stat sb; if (devMountsSavePath[i] == devPath) continue; if (stat(devMountsSavePath[i], &sb) < 0) { virReportSystemError(errno, _("Unable to stat: %s"), devMountsSavePath[i]); goto cleanup; } if (S_ISDIR(sb.st_mode)) { if (virFileMakePath(devMountsPath[i]) < 0) { virReportSystemError(errno, _("Cannot create %s"), devMountsPath[i]); goto cleanup; } } else { if (virFileMakeParentPath(devMountsPath[i]) < 0 || virFileTouch(devMountsPath[i], sb.st_mode) < 0) { virReportSystemError(errno, _("Cannot create %s"), devMountsPath[i]); goto cleanup; } } if (virFileMoveMount(devMountsSavePath[i], devMountsPath[i]) < 0) goto cleanup; } ret = 0; cleanup: for (i = 0; i < ndevMountsPath; i++) { /* The path can be either a regular file or a dir. */ if (virFileIsDir(devMountsSavePath[i])) rmdir(devMountsSavePath[i]); else unlink(devMountsSavePath[i]); } virStringListFreeCount(devMountsPath, ndevMountsPath); virStringListFreeCount(devMountsSavePath, ndevMountsPath); return ret; } int qemuDomainCreateNamespace(virQEMUDriverPtr driver, virDomainObjPtr vm) { virQEMUDriverConfigPtr cfg = virQEMUDriverGetConfig(driver); int ret = -1; if (virBitmapIsBitSet(cfg->namespaces, QEMU_DOMAIN_NS_MOUNT) && qemuDomainEnableNamespace(vm, QEMU_DOMAIN_NS_MOUNT) < 0) goto cleanup; ret = 0; cleanup: virObjectUnref(cfg); return ret; } void qemuDomainDestroyNamespace(virQEMUDriverPtr driver ATTRIBUTE_UNUSED, virDomainObjPtr vm) { if (qemuDomainNamespaceEnabled(vm, QEMU_DOMAIN_NS_MOUNT)) qemuDomainDisableNamespace(vm, QEMU_DOMAIN_NS_MOUNT); } bool qemuDomainNamespaceAvailable(qemuDomainNamespace ns ATTRIBUTE_UNUSED) { #if !defined(__linux__) /* Namespaces are Linux specific. */ return false; #else /* defined(__linux__) */ switch (ns) { case QEMU_DOMAIN_NS_MOUNT: # if !defined(HAVE_SYS_ACL_H) || !defined(WITH_SELINUX) /* We can't create the exact copy of paths if either of * these is not available. */ return false; # else if (virProcessNamespaceAvailable(VIR_PROCESS_NAMESPACE_MNT) < 0) return false; # endif break; case QEMU_DOMAIN_NS_LAST: break; } return true; #endif /* defined(__linux__) */ } struct qemuDomainAttachDeviceMknodData { virQEMUDriverPtr driver; virDomainObjPtr vm; const char *file; const char *target; struct stat sb; void *acl; #ifdef WITH_SELINUX char *tcon; #endif }; /* Our way of creating devices is highly linux specific */ #if defined(__linux__) static int qemuDomainAttachDeviceMknodHelper(pid_t pid ATTRIBUTE_UNUSED, void *opaque) { struct qemuDomainAttachDeviceMknodData *data = opaque; int ret = -1; bool delDevice = false; bool isLink = S_ISLNK(data->sb.st_mode); bool isDev = S_ISCHR(data->sb.st_mode) || S_ISBLK(data->sb.st_mode); bool isReg = S_ISREG(data->sb.st_mode) || S_ISFIFO(data->sb.st_mode) || S_ISSOCK(data->sb.st_mode); bool isDir = S_ISDIR(data->sb.st_mode); qemuSecurityPostFork(data->driver->securityManager); if (virFileMakeParentPath(data->file) < 0) { virReportSystemError(errno, _("Unable to create %s"), data->file); goto cleanup; } if (isLink) { VIR_DEBUG("Creating symlink %s -> %s", data->file, data->target); /* First, unlink the symlink target. Symlinks change and * therefore we have no guarantees that pre-existing * symlink is still valid. */ if (unlink(data->file) < 0 && errno != ENOENT) { virReportSystemError(errno, _("Unable to remove symlink %s"), data->file); goto cleanup; } if (symlink(data->target, data->file) < 0) { virReportSystemError(errno, _("Unable to create symlink %s (pointing to %s)"), data->file, data->target); goto cleanup; } else { delDevice = true; } } else if (isDev) { VIR_DEBUG("Creating dev %s (%d,%d)", data->file, major(data->sb.st_rdev), minor(data->sb.st_rdev)); if (mknod(data->file, data->sb.st_mode, data->sb.st_rdev) < 0) { /* Because we are not removing devices on hotunplug, or * we might be creating part of backing chain that * already exist due to a different disk plugged to * domain, accept EEXIST. */ if (errno != EEXIST) { virReportSystemError(errno, _("Unable to create device %s"), data->file); goto cleanup; } } else { delDevice = true; } } else if (isReg || isDir) { /* We are not cleaning up disks on virDomainDetachDevice * because disk might be still in use by different disk * as its backing chain. This might however clash here. * Therefore do the cleanup here. */ if (umount(data->file) < 0 && errno != ENOENT && errno != EINVAL) { virReportSystemError(errno, _("Unable to umount %s"), data->file); goto cleanup; } if ((isReg && virFileTouch(data->file, data->sb.st_mode) < 0) || (isDir && virFileMakePathWithMode(data->file, data->sb.st_mode) < 0)) goto cleanup; delDevice = true; /* Just create the file here so that code below sets * proper owner and mode. Move the mount only after that. */ } else { virReportError(VIR_ERR_OPERATION_UNSUPPORTED, _("unsupported device type %s 0%o"), data->file, data->sb.st_mode); goto cleanup; } if (lchown(data->file, data->sb.st_uid, data->sb.st_gid) < 0) { virReportSystemError(errno, _("Failed to chown device %s"), data->file); goto cleanup; } /* Symlinks don't have mode */ if (!isLink && chmod(data->file, data->sb.st_mode) < 0) { virReportSystemError(errno, _("Failed to set permissions for device %s"), data->file); goto cleanup; } /* Symlinks don't have ACLs. */ if (!isLink && virFileSetACLs(data->file, data->acl) < 0 && errno != ENOTSUP) { virReportSystemError(errno, _("Unable to set ACLs on %s"), data->file); goto cleanup; } # ifdef WITH_SELINUX if (data->tcon && lsetfilecon_raw(data->file, (VIR_SELINUX_CTX_CONST char *) data->tcon) < 0) { VIR_WARNINGS_NO_WLOGICALOP_EQUAL_EXPR if (errno != EOPNOTSUPP && errno != ENOTSUP) { VIR_WARNINGS_RESET virReportSystemError(errno, _("Unable to set SELinux label on %s"), data->file); goto cleanup; } } # endif /* Finish mount process started earlier. */ if ((isReg || isDir) && virFileMoveMount(data->target, data->file) < 0) goto cleanup; ret = 0; cleanup: if (ret < 0 && delDevice) { if (isDir) virFileDeleteTree(data->file); else unlink(data->file); } # ifdef WITH_SELINUX freecon(data->tcon); # endif virFileFreeACLs(&data->acl); return ret; } static int qemuDomainAttachDeviceMknodRecursive(virQEMUDriverPtr driver, virDomainObjPtr vm, const char *file, char * const *devMountsPath, size_t ndevMountsPath, unsigned int ttl) { virQEMUDriverConfigPtr cfg = NULL; struct qemuDomainAttachDeviceMknodData data; int ret = -1; char *target = NULL; bool isLink; bool isReg; bool isDir; if (!ttl) { virReportSystemError(ELOOP, _("Too many levels of symbolic links: %s"), file); return ret; } memset(&data, 0, sizeof(data)); data.driver = driver; data.vm = vm; data.file = file; if (lstat(file, &data.sb) < 0) { virReportSystemError(errno, _("Unable to access %s"), file); return ret; } isLink = S_ISLNK(data.sb.st_mode); isReg = S_ISREG(data.sb.st_mode) || S_ISFIFO(data.sb.st_mode) || S_ISSOCK(data.sb.st_mode); isDir = S_ISDIR(data.sb.st_mode); if ((isReg || isDir) && STRPREFIX(file, DEVPREFIX)) { cfg = virQEMUDriverGetConfig(driver); if (!(target = qemuDomainGetPreservedMountPath(cfg, vm, file))) goto cleanup; if (virFileBindMountDevice(file, target) < 0) goto cleanup; data.target = target; } else if (isLink) { if (virFileReadLink(file, &target) < 0) { virReportSystemError(errno, _("unable to resolve symlink %s"), file); return ret; } if (IS_RELATIVE_FILE_NAME(target)) { char *c = NULL, *tmp = NULL, *fileTmp = NULL; if (VIR_STRDUP(fileTmp, file) < 0) goto cleanup; if ((c = strrchr(fileTmp, '/'))) *(c + 1) = '\0'; if (virAsprintf(&tmp, "%s%s", fileTmp, target) < 0) { VIR_FREE(fileTmp); goto cleanup; } VIR_FREE(fileTmp); VIR_FREE(target); target = tmp; tmp = NULL; } data.target = target; } /* Symlinks don't have ACLs. */ if (!isLink && virFileGetACLs(file, &data.acl) < 0 && errno != ENOTSUP) { virReportSystemError(errno, _("Unable to get ACLs on %s"), file); goto cleanup; } # ifdef WITH_SELINUX if (lgetfilecon_raw(file, &data.tcon) < 0 && (errno != ENOTSUP && errno != ENODATA)) { virReportSystemError(errno, _("Unable to get SELinux label from %s"), file); goto cleanup; } # endif if (STRPREFIX(file, DEVPREFIX)) { size_t i; for (i = 0; i < ndevMountsPath; i++) { if (STREQ(devMountsPath[i], "/dev")) continue; if (STRPREFIX(file, devMountsPath[i])) break; } if (i == ndevMountsPath) { if (qemuSecurityPreFork(driver->securityManager) < 0) goto cleanup; if (virProcessRunInMountNamespace(vm->pid, qemuDomainAttachDeviceMknodHelper, &data) < 0) { qemuSecurityPostFork(driver->securityManager); goto cleanup; } qemuSecurityPostFork(driver->securityManager); } else { VIR_DEBUG("Skipping dev %s because of %s mount point", file, devMountsPath[i]); } } if (isLink && qemuDomainAttachDeviceMknodRecursive(driver, vm, target, devMountsPath, ndevMountsPath, ttl -1) < 0) goto cleanup; ret = 0; cleanup: # ifdef WITH_SELINUX freecon(data.tcon); # endif virFileFreeACLs(&data.acl); if (isReg && target) umount(target); VIR_FREE(target); virObjectUnref(cfg); return ret; } #else /* !defined(__linux__) */ static int qemuDomainAttachDeviceMknodRecursive(virQEMUDriverPtr driver ATTRIBUTE_UNUSED, virDomainObjPtr vm ATTRIBUTE_UNUSED, const char *file ATTRIBUTE_UNUSED, char * const *devMountsPath ATTRIBUTE_UNUSED, size_t ndevMountsPath ATTRIBUTE_UNUSED, unsigned int ttl ATTRIBUTE_UNUSED) { virReportSystemError(ENOSYS, "%s", _("Namespaces are not supported on this platform.")); return -1; } #endif /* !defined(__linux__) */ static int qemuDomainAttachDeviceMknod(virQEMUDriverPtr driver, virDomainObjPtr vm, const char *file, char * const *devMountsPath, size_t ndevMountsPath) { long symloop_max = sysconf(_SC_SYMLOOP_MAX); return qemuDomainAttachDeviceMknodRecursive(driver, vm, file, devMountsPath, ndevMountsPath, symloop_max); } static int qemuDomainDetachDeviceUnlinkHelper(pid_t pid ATTRIBUTE_UNUSED, void *opaque) { const char *path = opaque; VIR_DEBUG("Unlinking %s", path); if (unlink(path) < 0 && errno != ENOENT) { virReportSystemError(errno, _("Unable to remove device %s"), path); return -1; } return 0; } static int qemuDomainDetachDeviceUnlink(virQEMUDriverPtr driver ATTRIBUTE_UNUSED, virDomainObjPtr vm, const char *file, char * const *devMountsPath, size_t ndevMountsPath) { int ret = -1; size_t i; if (STRPREFIX(file, DEVPREFIX)) { for (i = 0; i < ndevMountsPath; i++) { if (STREQ(devMountsPath[i], "/dev")) continue; if (STRPREFIX(file, devMountsPath[i])) break; } if (i == ndevMountsPath) { if (virProcessRunInMountNamespace(vm->pid, qemuDomainDetachDeviceUnlinkHelper, (void *)file) < 0) goto cleanup; } } ret = 0; cleanup: return ret; } static int qemuDomainNamespaceMknodPaths(virDomainObjPtr vm, const char **paths, size_t npaths) { qemuDomainObjPrivatePtr priv = vm->privateData; virQEMUDriverPtr driver = priv->driver; virQEMUDriverConfigPtr cfg; char **devMountsPath = NULL; size_t ndevMountsPath = 0; int ret = -1; size_t i; if (!qemuDomainNamespaceEnabled(vm, QEMU_DOMAIN_NS_MOUNT)) return 0; cfg = virQEMUDriverGetConfig(driver); if (qemuDomainGetPreservedMounts(cfg, vm, &devMountsPath, NULL, &ndevMountsPath) < 0) goto cleanup; for (i = 0; i < npaths; i++) { if (qemuDomainAttachDeviceMknod(driver, vm, paths[i], devMountsPath, ndevMountsPath) < 0) goto cleanup; } ret = 0; cleanup: virStringListFreeCount(devMountsPath, ndevMountsPath); virObjectUnref(cfg); return ret; } static int qemuDomainNamespaceMknodPath(virDomainObjPtr vm, const char *path) { const char *paths[] = { path }; return qemuDomainNamespaceMknodPaths(vm, paths, 1); } static int qemuDomainNamespaceUnlinkPaths(virDomainObjPtr vm, const char **paths, size_t npaths) { qemuDomainObjPrivatePtr priv = vm->privateData; virQEMUDriverPtr driver = priv->driver; virQEMUDriverConfigPtr cfg; char **devMountsPath = NULL; size_t ndevMountsPath = 0; size_t i; int ret = -1; if (!qemuDomainNamespaceEnabled(vm, QEMU_DOMAIN_NS_MOUNT)) return 0; cfg = virQEMUDriverGetConfig(driver); if (qemuDomainGetPreservedMounts(cfg, vm, &devMountsPath, NULL, &ndevMountsPath) < 0) goto cleanup; for (i = 0; i < npaths; i++) { if (qemuDomainDetachDeviceUnlink(driver, vm, paths[i], devMountsPath, ndevMountsPath) < 0) goto cleanup; } ret = 0; cleanup: virStringListFreeCount(devMountsPath, ndevMountsPath); virObjectUnref(cfg); return ret; } static int qemuDomainNamespaceUnlinkPath(virDomainObjPtr vm, const char *path) { const char *paths[] = { path }; return qemuDomainNamespaceUnlinkPaths(vm, paths, 1); } int qemuDomainNamespaceSetupDisk(virDomainObjPtr vm, virStorageSourcePtr src) { virStorageSourcePtr next; char **paths = NULL; size_t npaths = 0; int ret = -1; if (!qemuDomainNamespaceEnabled(vm, QEMU_DOMAIN_NS_MOUNT)) return 0; for (next = src; virStorageSourceIsBacking(next); next = next->backingStore) { if (virStorageSourceIsEmpty(next) || !virStorageSourceIsLocalStorage(next)) { /* Not creating device. Just continue. */ continue; } if (VIR_APPEND_ELEMENT_COPY(paths, npaths, next->path) < 0) goto cleanup; } if (qemuDomainNamespaceMknodPaths(vm, (const char **)paths, npaths) < 0) return -1; ret = 0; cleanup: VIR_FREE(paths); return ret; } int qemuDomainNamespaceTeardownDisk(virDomainObjPtr vm ATTRIBUTE_UNUSED, virStorageSourcePtr src ATTRIBUTE_UNUSED) { /* While in hotplug case we create the whole backing chain, * here we must limit ourselves. The disk we want to remove * might be a part of backing chain of another disk. * If you are reading these lines and have some spare time * you can come up with and algorithm that checks for that. * I don't, therefore: */ return 0; } int qemuDomainNamespaceSetupHostdev(virDomainObjPtr vm, virDomainHostdevDefPtr hostdev) { int ret = -1; char **paths = NULL; size_t i, npaths = 0; if (!qemuDomainNamespaceEnabled(vm, QEMU_DOMAIN_NS_MOUNT)) return 0; if (qemuDomainGetHostdevPath(NULL, hostdev, false, &npaths, &paths, NULL) < 0) goto cleanup; if (qemuDomainNamespaceMknodPaths(vm, (const char **)paths, npaths) < 0) goto cleanup; ret = 0; cleanup: for (i = 0; i < npaths; i++) VIR_FREE(paths[i]); VIR_FREE(paths); return ret; } int qemuDomainNamespaceTeardownHostdev(virDomainObjPtr vm, virDomainHostdevDefPtr hostdev) { int ret = -1; char **paths = NULL; size_t i, npaths = 0; if (!qemuDomainNamespaceEnabled(vm, QEMU_DOMAIN_NS_MOUNT)) return 0; if (qemuDomainGetHostdevPath(vm->def, hostdev, true, &npaths, &paths, NULL) < 0) goto cleanup; if (npaths != 0 && qemuDomainNamespaceUnlinkPaths(vm, (const char **)paths, npaths) < 0) goto cleanup; ret = 0; cleanup: for (i = 0; i < npaths; i++) VIR_FREE(paths[i]); VIR_FREE(paths); return ret; } int qemuDomainNamespaceSetupMemory(virDomainObjPtr vm, virDomainMemoryDefPtr mem) { if (mem->model != VIR_DOMAIN_MEMORY_MODEL_NVDIMM) return 0; if (qemuDomainNamespaceMknodPath(vm, mem->nvdimmPath) < 0) return -1; return 0; } int qemuDomainNamespaceTeardownMemory(virDomainObjPtr vm, virDomainMemoryDefPtr mem) { if (mem->model != VIR_DOMAIN_MEMORY_MODEL_NVDIMM) return 0; if (qemuDomainNamespaceUnlinkPath(vm, mem->nvdimmPath) < 0) return -1; return 0; } int qemuDomainNamespaceSetupChardev(virDomainObjPtr vm, virDomainChrDefPtr chr) { const char *path; if (!(path = virDomainChrSourceDefGetPath(chr->source))) return 0; /* Socket created by qemu. It doesn't exist upfront. */ if (chr->source->type == VIR_DOMAIN_CHR_TYPE_UNIX && chr->source->data.nix.listen) return 0; if (qemuDomainNamespaceMknodPath(vm, path) < 0) return -1; return 0; } int qemuDomainNamespaceTeardownChardev(virDomainObjPtr vm, virDomainChrDefPtr chr) { const char *path = NULL; if (chr->source->type != VIR_DOMAIN_CHR_TYPE_DEV) return 0; path = chr->source->data.file.path; if (qemuDomainNamespaceUnlinkPath(vm, path) < 0) return -1; return 0; } int qemuDomainNamespaceSetupRNG(virDomainObjPtr vm, virDomainRNGDefPtr rng) { const char *path = NULL; switch ((virDomainRNGBackend) rng->backend) { case VIR_DOMAIN_RNG_BACKEND_RANDOM: path = rng->source.file; break; case VIR_DOMAIN_RNG_BACKEND_EGD: case VIR_DOMAIN_RNG_BACKEND_LAST: break; } if (path && qemuDomainNamespaceMknodPath(vm, path) < 0) return -1; return 0; } int qemuDomainNamespaceTeardownRNG(virDomainObjPtr vm, virDomainRNGDefPtr rng) { const char *path = NULL; switch ((virDomainRNGBackend) rng->backend) { case VIR_DOMAIN_RNG_BACKEND_RANDOM: path = rng->source.file; break; case VIR_DOMAIN_RNG_BACKEND_EGD: case VIR_DOMAIN_RNG_BACKEND_LAST: break; } if (path && qemuDomainNamespaceUnlinkPath(vm, path) < 0) return -1; return 0; } int qemuDomainNamespaceSetupInput(virDomainObjPtr vm, virDomainInputDefPtr input) { const char *path = NULL; if (!(path = virDomainInputDefGetPath(input))) return 0; if (path && qemuDomainNamespaceMknodPath(vm, path) < 0) return -1; return 0; } int qemuDomainNamespaceTeardownInput(virDomainObjPtr vm, virDomainInputDefPtr input) { const char *path = NULL; if (!(path = virDomainInputDefGetPath(input))) return 0; if (path && qemuDomainNamespaceUnlinkPath(vm, path) < 0) return -1; return 0; } /** * qemuDomainDiskLookupByNodename: * @def: domain definition to look for the disk * @nodename: block backend node name to find * @src: filled with the specific backing store element if provided * @idx: index of @src in the backing chain, if provided * * Looks up the disk in the domain via @nodename and returns its definition. * Optionally fills @src and @idx if provided with the specific backing chain * element which corresponds to the node name. */ virDomainDiskDefPtr qemuDomainDiskLookupByNodename(virDomainDefPtr def, const char *nodename, virStorageSourcePtr *src, unsigned int *idx) { size_t i; unsigned int srcindex; virStorageSourcePtr tmp = NULL; if (!idx) idx = &srcindex; if (src) *src = NULL; *idx = 0; for (i = 0; i < def->ndisks; i++) { if ((tmp = virStorageSourceFindByNodeName(def->disks[i]->src, nodename, idx))) { if (src) *src = tmp; return def->disks[i]; } } return NULL; } /** * qemuDomainDiskBackingStoreGetName: * * Creates a name using the indexed syntax (vda[1])for the given backing store * entry for a disk. */ char * qemuDomainDiskBackingStoreGetName(virDomainDiskDefPtr disk, virStorageSourcePtr src ATTRIBUTE_UNUSED, unsigned int idx) { char *ret = NULL; if (idx) ignore_value(virAsprintf(&ret, "%s[%d]", disk->dst, idx)); else ignore_value(VIR_STRDUP(ret, disk->dst)); return ret; } virStorageSourcePtr qemuDomainGetStorageSourceByDevstr(const char *devstr, virDomainDefPtr def) { virDomainDiskDefPtr disk = NULL; virStorageSourcePtr src = NULL; char *target = NULL; unsigned int idx; size_t i; if (virStorageFileParseBackingStoreStr(devstr, &target, &idx) < 0) { virReportError(VIR_ERR_INVALID_ARG, _("failed to parse block device '%s'"), devstr); return NULL; } for (i = 0; i < def->ndisks; i++) { if (STREQ(target, def->disks[i]->dst)) { disk = def->disks[i]; break; } } if (!disk) { virReportError(VIR_ERR_INVALID_ARG, _("failed to find disk '%s'"), target); goto cleanup; } if (idx == 0) src = disk->src; else src = virStorageFileChainLookup(disk->src, NULL, NULL, idx, NULL); cleanup: VIR_FREE(target); return src; } static void qemuDomainSaveCookieDispose(void *obj) { qemuDomainSaveCookiePtr cookie = obj; VIR_DEBUG("cookie=%p", cookie); virCPUDefFree(cookie->cpu); } qemuDomainSaveCookiePtr qemuDomainSaveCookieNew(virDomainObjPtr vm ATTRIBUTE_UNUSED) { qemuDomainObjPrivatePtr priv = vm->privateData; qemuDomainSaveCookiePtr cookie = NULL; if (qemuDomainInitialize() < 0) goto error; if (!(cookie = virObjectNew(qemuDomainSaveCookieClass))) goto error; if (priv->origCPU && !(cookie->cpu = virCPUDefCopy(vm->def->cpu))) goto error; VIR_DEBUG("Save cookie %p, cpu=%p", cookie, cookie->cpu); return cookie; error: virObjectUnref(cookie); return NULL; } static int qemuDomainSaveCookieParse(xmlXPathContextPtr ctxt ATTRIBUTE_UNUSED, virObjectPtr *obj) { qemuDomainSaveCookiePtr cookie = NULL; if (qemuDomainInitialize() < 0) goto error; if (!(cookie = virObjectNew(qemuDomainSaveCookieClass))) goto error; if (virCPUDefParseXML(ctxt, "./cpu[1]", VIR_CPU_TYPE_GUEST, &cookie->cpu) < 0) goto error; *obj = (virObjectPtr) cookie; return 0; error: virObjectUnref(cookie); return -1; } static int qemuDomainSaveCookieFormat(virBufferPtr buf, virObjectPtr obj) { qemuDomainSaveCookiePtr cookie = (qemuDomainSaveCookiePtr) obj; if (cookie->cpu && virCPUDefFormatBufFull(buf, cookie->cpu, NULL) < 0) return -1; return 0; } virSaveCookieCallbacks virQEMUDriverDomainSaveCookie = { .parse = qemuDomainSaveCookieParse, .format = qemuDomainSaveCookieFormat, }; /** * qemuDomainUpdateCPU: * @vm: domain which is being started * @cpu: CPU updated when the domain was running previously (before migration, * snapshot, or save) * @origCPU: where to store the original CPU from vm->def in case @cpu was * used instead * * Replace the CPU definition with the updated one when QEMU is new enough to * allow us to check extra features it is about to enable or disable when * starting a domain. The original CPU is stored in @origCPU. * * Returns 0 on success, -1 on error. */ int qemuDomainUpdateCPU(virDomainObjPtr vm, virCPUDefPtr cpu, virCPUDefPtr *origCPU) { qemuDomainObjPrivatePtr priv = vm->privateData; *origCPU = NULL; if (!cpu || !vm->def->cpu || !virQEMUCapsGet(priv->qemuCaps, QEMU_CAPS_QUERY_CPU_MODEL_EXPANSION) || virCPUDefIsEqual(vm->def->cpu, cpu, false)) return 0; if (!(cpu = virCPUDefCopy(cpu))) return -1; VIR_DEBUG("Replacing CPU def with the updated one"); *origCPU = vm->def->cpu; vm->def->cpu = cpu; return 0; } /** * qemuDomainFixupCPUS: * @vm: domain object * @origCPU: original CPU used when the domain was started * * Libvirt older than 3.9.0 could have messed up the expansion of host-model * CPU when reconnecting to a running domain by adding features QEMU does not * support (such as cmt). This API fixes both the actual CPU provided by QEMU * (stored in the domain object) and the @origCPU used when starting the * domain. * * This is safe even if the original CPU definition used mode='custom' (rather * than host-model) since we know QEMU was able to start the domain and thus * the CPU definitions do not contain any features unknown to QEMU. * * This function can only be used on an active domain or when restoring a * domain which was running. * * Returns 0 on success, -1 on error. */ int qemuDomainFixupCPUs(virDomainObjPtr vm, virCPUDefPtr *origCPU) { virCPUDefPtr fixedCPU = NULL; virCPUDefPtr fixedOrig = NULL; virArch arch = vm->def->os.arch; int ret = -1; if (!ARCH_IS_X86(arch)) return 0; if (!vm->def->cpu || vm->def->cpu->mode != VIR_CPU_MODE_CUSTOM || !vm->def->cpu->model) return 0; /* Missing origCPU means QEMU created exactly the same virtual CPU which * we asked for or libvirt was too old to mess up the translation from * host-model. */ if (!*origCPU) return 0; if (virCPUDefFindFeature(vm->def->cpu, "cmt") && (!(fixedCPU = virCPUDefCopyWithoutModel(vm->def->cpu)) || virCPUDefCopyModelFilter(fixedCPU, vm->def->cpu, false, virQEMUCapsCPUFilterFeatures, &arch) < 0)) goto cleanup; if (virCPUDefFindFeature(*origCPU, "cmt") && (!(fixedOrig = virCPUDefCopyWithoutModel(*origCPU)) || virCPUDefCopyModelFilter(fixedOrig, *origCPU, false, virQEMUCapsCPUFilterFeatures, &arch) < 0)) goto cleanup; if (fixedCPU) { virCPUDefFree(vm->def->cpu); VIR_STEAL_PTR(vm->def->cpu, fixedCPU); } if (fixedOrig) { virCPUDefFree(*origCPU); VIR_STEAL_PTR(*origCPU, fixedOrig); } ret = 0; cleanup: virCPUDefFree(fixedCPU); virCPUDefFree(fixedOrig); return ret; } char * qemuDomainGetMachineName(virDomainObjPtr vm) { qemuDomainObjPrivatePtr priv = vm->privateData; virQEMUDriverPtr driver = priv->driver; char *ret = NULL; if (vm->pid > 0) { ret = virSystemdGetMachineNameByPID(vm->pid); if (!ret) virResetLastError(); } if (!ret) ret = virDomainGenerateMachineName("qemu", vm->def->id, vm->def->name, virQEMUDriverIsPrivileged(driver)); return ret; } /* Check whether the device address is using either 'ccw' or default s390 * address format and whether that's "legal" for the current qemu and/or * guest os.machine type. This is the corollary to the code which doesn't * find the address type set using an emulator that supports either 'ccw' * or s390 and sets the address type based on the capabilities. * * If the address is using 'ccw' or s390 and it's not supported, generate * an error and return false; otherwise, return true. */ bool qemuDomainCheckCCWS390AddressSupport(const virDomainDef *def, virDomainDeviceInfo info, virQEMUCapsPtr qemuCaps, const char *devicename) { if (info.type == VIR_DOMAIN_DEVICE_ADDRESS_TYPE_CCW) { if (!qemuDomainIsS390CCW(def)) { virReportError(VIR_ERR_CONFIG_UNSUPPORTED, _("cannot use CCW address type for device " "'%s' using machine type '%s'"), devicename, def->os.machine); return false; } else if (!virQEMUCapsGet(qemuCaps, QEMU_CAPS_VIRTIO_CCW)) { virReportError(VIR_ERR_CONFIG_UNSUPPORTED, "%s", _("CCW address type is not supported by " "this QEMU")); return false; } } else if (info.type == VIR_DOMAIN_DEVICE_ADDRESS_TYPE_VIRTIO_S390) { if (!virQEMUCapsGet(qemuCaps, QEMU_CAPS_VIRTIO_S390)) { virReportError(VIR_ERR_CONFIG_UNSUPPORTED, "%s", _("virtio S390 address type is not supported by " "this QEMU")); return false; } } return true; } int qemuDomainCheckMigrationCapabilities(virQEMUDriverPtr driver, virDomainObjPtr vm, qemuDomainAsyncJob asyncJob) { qemuDomainObjPrivatePtr priv = vm->privateData; char **caps = NULL; char **capStr; int ret = -1; int rc; if (qemuDomainObjEnterMonitorAsync(driver, vm, asyncJob) < 0) return -1; rc = qemuMonitorGetMigrationCapabilities(priv->mon, &caps); if (qemuDomainObjExitMonitor(driver, vm) < 0 || rc < 0) goto cleanup; if (!caps) { ret = 0; goto cleanup; } priv->migrationCaps = virBitmapNew(QEMU_MONITOR_MIGRATION_CAPS_LAST); if (!priv->migrationCaps) goto cleanup; for (capStr = caps; *capStr; capStr++) { int cap = qemuMonitorMigrationCapsTypeFromString(*capStr); if (cap < 0) { VIR_DEBUG("Unknown migration capability: '%s'", *capStr); } else { ignore_value(virBitmapSetBit(priv->migrationCaps, cap)); VIR_DEBUG("Found migration capability: '%s'", *capStr); } } if (virQEMUCapsGet(priv->qemuCaps, QEMU_CAPS_MIGRATION_EVENT)) { if (qemuDomainObjEnterMonitorAsync(driver, vm, asyncJob) < 0) goto cleanup; rc = qemuMonitorSetMigrationCapability(priv->mon, QEMU_MONITOR_MIGRATION_CAPS_EVENTS, true); if (qemuDomainObjExitMonitor(driver, vm) < 0) goto cleanup; if (rc < 0) { virResetLastError(); VIR_DEBUG("Cannot enable migration events; clearing capability"); virQEMUCapsClear(priv->qemuCaps, QEMU_CAPS_MIGRATION_EVENT); } } /* Migration events capability must always be enabled, clearing it from * migration capabilities bitmap makes sure it won't be touched anywhere * else. */ ignore_value(virBitmapClearBit(priv->migrationCaps, QEMU_MONITOR_MIGRATION_CAPS_EVENTS)); ret = 0; cleanup: virStringListFree(caps); return ret; } int qemuDomainPrepareDiskSource(virConnectPtr conn, virDomainDiskDefPtr disk, qemuDomainObjPrivatePtr priv, virQEMUDriverConfigPtr cfg) { if (qemuDomainPrepareDiskSourceTLS(disk->src, cfg) < 0) return -1; if (qemuDomainSecretDiskPrepare(conn, priv, disk) < 0) return -1; if (disk->src->type == VIR_STORAGE_TYPE_NETWORK && disk->src->protocol == VIR_STORAGE_NET_PROTOCOL_GLUSTER && virQEMUCapsGet(priv->qemuCaps, QEMU_CAPS_GLUSTER_DEBUG_LEVEL)) { disk->src->debug = true; disk->src->debugLevel = cfg->glusterDebugLevel; } return 0; } void qemuProcessEventFree(struct qemuProcessEvent *event) { if (!event) return; switch (event->eventType) { case QEMU_PROCESS_EVENT_GUESTPANIC: qemuMonitorEventPanicInfoFree(event->data); break; case QEMU_PROCESS_EVENT_WATCHDOG: case QEMU_PROCESS_EVENT_DEVICE_DELETED: case QEMU_PROCESS_EVENT_NIC_RX_FILTER_CHANGED: case QEMU_PROCESS_EVENT_SERIAL_CHANGED: case QEMU_PROCESS_EVENT_BLOCK_JOB: case QEMU_PROCESS_EVENT_MONITOR_EOF: VIR_FREE(event->data); break; case QEMU_PROCESS_EVENT_LAST: break; } VIR_FREE(event); }