/* * config.c: VM configuration management * * Copyright (C) 2006, 2007, 2008 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, write to the Free Software * Foundation, Inc., 59 Temple Place, Suite 330, Boston, MA 02111-1307 USA * * Author: Daniel P. Berrange */ #include #ifdef WITH_QEMU #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #if HAVE_NUMACTL #include #endif #include "libvirt/virterror.h" #include "qemu_conf.h" #include "uuid.h" #include "buf.h" #include "conf.h" #include "util.h" #include "memory.h" #include "verify.h" #include "c-ctype.h" #include "xml.h" #define qemudLog(level, msg...) fprintf(stderr, msg) void qemudReportError(virConnectPtr conn, virDomainPtr dom, virNetworkPtr net, int code, const char *fmt, ...) { va_list args; char errorMessage[QEMUD_MAX_ERROR_LEN]; const char *virerr; if (fmt) { va_start(args, fmt); vsnprintf(errorMessage, QEMUD_MAX_ERROR_LEN-1, fmt, args); va_end(args); } else { errorMessage[0] = '\0'; } virerr = __virErrorMsg(code, (errorMessage[0] ? errorMessage : NULL)); __virRaiseError(conn, dom, net, VIR_FROM_QEMU, code, VIR_ERR_ERROR, virerr, errorMessage, NULL, -1, -1, virerr, errorMessage); } int qemudLoadDriverConfig(struct qemud_driver *driver, const char *filename) { virConfPtr conf; virConfValuePtr p; /* Setup 2 critical defaults */ strcpy(driver->vncListen, "127.0.0.1"); if (!(driver->vncTLSx509certdir = strdup(SYSCONF_DIR "/pki/libvirt-vnc"))) { qemudReportError(NULL, NULL, NULL, VIR_ERR_NO_MEMORY, "%s", _("failed to allocate vncTLSx509certdir")); return -1; } /* Just check the file is readable before opening it, otherwise * libvirt emits an error. */ if (access (filename, R_OK) == -1) return 0; conf = virConfReadFile (filename); if (!conf) return 0; #define CHECK_TYPE(name,typ) if (p && p->type != (typ)) { \ qemudReportError(NULL, NULL, NULL, VIR_ERR_INTERNAL_ERROR, \ "remoteReadConfigFile: %s: %s: expected type " #typ "\n", \ filename, (name)); \ virConfFree(conf); \ return -1; \ } p = virConfGetValue (conf, "vnc_tls"); CHECK_TYPE ("vnc_tls", VIR_CONF_LONG); if (p) driver->vncTLS = p->l; p = virConfGetValue (conf, "vnc_tls_x509_verify"); CHECK_TYPE ("vnc_tls_x509_verify", VIR_CONF_LONG); if (p) driver->vncTLSx509verify = p->l; p = virConfGetValue (conf, "vnc_tls_x509_cert_dir"); CHECK_TYPE ("vnc_tls_x509_cert_dir", VIR_CONF_STRING); if (p && p->str) { free(driver->vncTLSx509certdir); if (!(driver->vncTLSx509certdir = strdup(p->str))) { qemudReportError(NULL, NULL, NULL, VIR_ERR_NO_MEMORY, "%s", _("failed to allocate vncTLSx509certdir")); virConfFree(conf); return -1; } } p = virConfGetValue (conf, "vnc_listen"); CHECK_TYPE ("vnc_listen", VIR_CONF_STRING); if (p && p->str) { strncpy(driver->vncListen, p->str, sizeof(driver->vncListen)); driver->vncListen[sizeof(driver->vncListen)-1] = '\0'; } virConfFree (conf); return 0; } struct qemud_vm *qemudFindVMByID(const struct qemud_driver *driver, int id) { struct qemud_vm *vm = driver->vms; while (vm) { if (qemudIsActiveVM(vm) && vm->id == id) return vm; vm = vm->next; } return NULL; } struct qemud_vm *qemudFindVMByUUID(const struct qemud_driver *driver, const unsigned char *uuid) { struct qemud_vm *vm = driver->vms; while (vm) { if (!memcmp(vm->def->uuid, uuid, VIR_UUID_BUFLEN)) return vm; vm = vm->next; } return NULL; } struct qemud_vm *qemudFindVMByName(const struct qemud_driver *driver, const char *name) { struct qemud_vm *vm = driver->vms; while (vm) { if (STREQ(vm->def->name, name)) return vm; vm = vm->next; } return NULL; } struct qemud_network *qemudFindNetworkByUUID(const struct qemud_driver *driver, const unsigned char *uuid) { struct qemud_network *network = driver->networks; while (network) { if (!memcmp(network->def->uuid, uuid, VIR_UUID_BUFLEN)) return network; network = network->next; } return NULL; } struct qemud_network *qemudFindNetworkByName(const struct qemud_driver *driver, const char *name) { struct qemud_network *network = driver->networks; while (network) { if (STREQ(network->def->name, name)) return network; network = network->next; } return NULL; } /* Free all memory associated with a struct qemud_vm object */ void qemudFreeVMDef(struct qemud_vm_def *def) { struct qemud_vm_disk_def *disk = def->disks; struct qemud_vm_net_def *net = def->nets; struct qemud_vm_input_def *input = def->inputs; struct qemud_vm_chr_def *serial = def->serials; struct qemud_vm_chr_def *parallel = def->parallels; while (disk) { struct qemud_vm_disk_def *prev = disk; disk = disk->next; free(prev); } while (net) { struct qemud_vm_net_def *prev = net; net = net->next; free(prev); } while (input) { struct qemud_vm_input_def *prev = input; input = input->next; free(prev); } while (serial) { struct qemud_vm_chr_def *prev = serial; serial = serial->next; free(prev); } while (parallel) { struct qemud_vm_chr_def *prev = parallel; parallel = parallel->next; free(prev); } xmlFree(def->keymap); free(def); } void qemudFreeVM(struct qemud_vm *vm) { qemudFreeVMDef(vm->def); if (vm->newDef) qemudFreeVMDef(vm->newDef); free(vm); } /* The list of possible machine types for various architectures, as supported by QEMU - taken from 'qemu -M ?' for each arch */ static const char *const arch_info_hvm_x86_machines[] = { "pc", "isapc" }; static const char *const arch_info_hvm_mips_machines[] = { "mips" }; static const char *const arch_info_hvm_sparc_machines[] = { "sun4m" }; static const char *const arch_info_hvm_ppc_machines[] = { "g3bw", "mac99", "prep" }; static const char *const arch_info_xen_x86_machines[] = { "xenner" }; struct qemu_feature_flags { const char *name; const int default_on; const int toggle; }; struct qemu_arch_info { const char *arch; int wordsize; const char *const *machines; int nmachines; const char *binary; const struct qemu_feature_flags *flags; int nflags; }; /* Feature flags for the architecture info */ static const struct qemu_feature_flags const arch_info_i686_flags [] = { { "pae", 1, 0 }, { "nonpae", 1, 0 }, { "acpi", 1, 1 }, { "apic", 1, 0 }, }; static const struct qemu_feature_flags const arch_info_x86_64_flags [] = { { "acpi", 1, 1 }, { "apic", 1, 0 }, }; /* The archicture tables for supported QEMU archs */ static const struct qemu_arch_info const arch_info_hvm[] = { { "i686", 32, arch_info_hvm_x86_machines, 2, "/usr/bin/qemu", arch_info_i686_flags, 4 }, { "x86_64", 64, arch_info_hvm_x86_machines, 2, "/usr/bin/qemu-system-x86_64", arch_info_x86_64_flags, 2 }, { "mips", 32, arch_info_hvm_mips_machines, 1, "/usr/bin/qemu-system-mips", NULL, 0 }, { "mipsel", 32, arch_info_hvm_mips_machines, 1, "/usr/bin/qemu-system-mipsel", NULL, 0 }, { "sparc", 32, arch_info_hvm_sparc_machines, 1, "/usr/bin/qemu-system-sparc", NULL, 0 }, { "ppc", 32, arch_info_hvm_ppc_machines, 3, "/usr/bin/qemu-system-ppc", NULL, 0 }, }; static const struct qemu_arch_info const arch_info_xen[] = { { "i686", 32, arch_info_xen_x86_machines, 1, "/usr/bin/xenner", arch_info_i686_flags, 4 }, { "x86_64", 64, arch_info_xen_x86_machines, 1, "/usr/bin/xenner", arch_info_x86_64_flags, 2 }, }; static int qemudCapsInitGuest(virCapsPtr caps, const char *hostmachine, const struct qemu_arch_info *info, int hvm) { virCapsGuestPtr guest; int i; if ((guest = virCapabilitiesAddGuest(caps, hvm ? "hvm" : "xen", info->arch, info->wordsize, info->binary, NULL, info->nmachines, info->machines)) == NULL) return -1; if (hvm) { /* Check for existance of base emulator */ if (access(info->binary, X_OK) == 0 && virCapabilitiesAddGuestDomain(guest, "qemu", NULL, NULL, 0, NULL) == NULL) return -1; /* If guest & host match, then we can accelerate */ if (STREQ(info->arch, hostmachine)) { if (access("/dev/kqemu", F_OK) == 0 && virCapabilitiesAddGuestDomain(guest, "kqemu", NULL, NULL, 0, NULL) == NULL) return -1; if (access("/dev/kvm", F_OK) == 0 && virCapabilitiesAddGuestDomain(guest, "kvm", "/usr/bin/qemu-kvm", NULL, 0, NULL) == NULL) return -1; } } else { if (virCapabilitiesAddGuestDomain(guest, "kvm", NULL, NULL, 0, NULL) == NULL) return -1; } if (info->nflags) { for (i = 0 ; i < info->nflags ; i++) { if (virCapabilitiesAddGuestFeature(guest, info->flags[i].name, info->flags[i].default_on, info->flags[i].toggle) == NULL) return -1; } } return 0; } #if HAVE_NUMACTL #define MAX_CPUS 4096 #define MAX_CPUS_MASK_SIZE (sizeof(unsigned long)) #define MAX_CPUS_MASK_LEN (MAX_CPUS / MAX_CPUS_MASK_SIZE) #define MAX_CPUS_MASK_BYTES (MAX_CPUS / 8) #define MASK_CPU_ISSET(mask, cpu) \ (((mask)[((cpu) / MAX_CPUS_MASK_SIZE)] >> ((cpu) % MAX_CPUS_MASK_SIZE)) & 1) static int qemudCapsInitNUMA(virCapsPtr caps) { int n, i; unsigned long *mask = NULL; int ncpus; int *cpus = NULL; int ret = -1; if (numa_available() < 0) return 0; if (VIR_ALLOC_N(mask, MAX_CPUS_MASK_LEN) < 0) goto cleanup; for (n = 0 ; n <= numa_max_node() ; n++) { if (numa_node_to_cpus(n, mask, MAX_CPUS_MASK_BYTES) < 0) goto cleanup; for (ncpus = 0, i = 0 ; i < MAX_CPUS ; i++) if (MASK_CPU_ISSET(mask, i)) ncpus++; if (VIR_ALLOC_N(cpus, ncpus) < 0) goto cleanup; for (ncpus = 0, i = 0 ; i < MAX_CPUS ; i++) if (MASK_CPU_ISSET(mask, i)) cpus[ncpus++] = i; if (virCapabilitiesAddHostNUMACell(caps, n, ncpus, cpus) < 0) goto cleanup; VIR_FREE(cpus); } ret = 0; cleanup: VIR_FREE(cpus); VIR_FREE(mask); return ret; } #else static int qemudCapsInitNUMA(virCapsPtr caps ATTRIBUTE_UNUSED) { return 0; } #endif virCapsPtr qemudCapsInit(void) { struct utsname utsname; virCapsPtr caps; int i; /* Really, this never fails - look at the man-page. */ uname (&utsname); if ((caps = virCapabilitiesNew(utsname.machine, 0, 0)) == NULL) goto no_memory; if (qemudCapsInitNUMA(caps) < 0) goto no_memory; for (i = 0 ; i < (sizeof(arch_info_hvm)/sizeof(arch_info_hvm[0])) ; i++) if (qemudCapsInitGuest(caps, utsname.machine, &arch_info_hvm[i], 1) < 0) goto no_memory; if (access("/usr/bin/xenner", X_OK) == 0 && access("/dev/kvm", F_OK) == 0) { for (i = 0 ; i < (sizeof(arch_info_xen)/sizeof(arch_info_xen[0])) ; i++) /* Allow Xen 32-on-32, 32-on-64 and 64-on-64 */ if (STREQ(arch_info_xen[i].arch, utsname.machine) || (STREQ(utsname.machine, "x86_64") && STREQ(arch_info_xen[i].arch, "i686"))) { if (qemudCapsInitGuest(caps, utsname.machine, &arch_info_xen[i], 0) < 0) goto no_memory; } } return caps; no_memory: virCapabilitiesFree(caps); return NULL; } static int qemudExtractVersionInfo(const char *qemu, int *version, int *flags) { pid_t child; int newstdout[2]; *flags = 0; *version = 0; if (pipe(newstdout) < 0) { return -1; } if ((child = fork()) < 0) { close(newstdout[0]); close(newstdout[1]); return -1; } if (child == 0) { /* Kid */ /* Just in case QEMU is translated someday we force to C locale.. */ const char *const qemuenv[] = { "LANG=C", NULL }; if (close(STDIN_FILENO) < 0) goto cleanup1; if (close(STDERR_FILENO) < 0) goto cleanup1; if (close(newstdout[0]) < 0) goto cleanup1; if (dup2(newstdout[1], STDOUT_FILENO) < 0) goto cleanup1; /* Passing -help, rather than relying on no-args which doesn't always work */ execle(qemu, qemu, "-help", (char*)NULL, qemuenv); cleanup1: _exit(-1); /* Just in case */ } else { /* Parent */ char help[8192]; /* Ought to be enough to hold QEMU help screen */ int got = 0, ret = -1; int major, minor, micro; if (close(newstdout[1]) < 0) goto cleanup2; while (got < (sizeof(help)-1)) { int len; if ((len = read(newstdout[0], help+got, sizeof(help)-got-1)) <= 0) { if (!len) break; if (errno == EINTR) continue; goto cleanup2; } got += len; } help[got] = '\0'; if (sscanf(help, "QEMU PC emulator version %d.%d.%d", &major,&minor, µ) != 3) { goto cleanup2; } *version = (major * 1000 * 1000) + (minor * 1000) + micro; if (strstr(help, "-no-kqemu")) *flags |= QEMUD_CMD_FLAG_KQEMU; if (strstr(help, "-no-reboot")) *flags |= QEMUD_CMD_FLAG_NO_REBOOT; if (strstr(help, "-name")) *flags |= QEMUD_CMD_FLAG_NAME; if (strstr(help, "-drive")) *flags |= QEMUD_CMD_FLAG_DRIVE; if (strstr(help, "boot=on")) *flags |= QEMUD_CMD_FLAG_DRIVE_BOOT; if (*version >= 9000) *flags |= QEMUD_CMD_FLAG_VNC_COLON; ret = 0; qemudDebug("Version %d %d %d Cooked version: %d, with flags ? %d", major, minor, micro, *version, *flags); cleanup2: if (close(newstdout[0]) < 0) ret = -1; rewait: if (waitpid(child, &got, 0) != child) { if (errno == EINTR) { goto rewait; } qemudLog(QEMUD_ERR, _("Unexpected exit status from qemu %d pid %lu"), got, (unsigned long)child); ret = -1; } /* Check & log unexpected exit status, but don't fail, * as there's really no need to throw an error if we did * actually read a valid version number above */ if (WEXITSTATUS(got) != 0) { qemudLog(QEMUD_WARN, _("Unexpected exit status '%d', qemu probably failed"), got); } return ret; } } int qemudExtractVersion(virConnectPtr conn, struct qemud_driver *driver) { const char *binary; struct stat sb; int ignored; if (driver->qemuVersion > 0) return 0; if ((binary = virCapabilitiesDefaultGuestEmulator(driver->caps, "hvm", "i686", "qemu")) == NULL) return -1; if (stat(binary, &sb) < 0) { qemudReportError(conn, NULL, NULL, VIR_ERR_INTERNAL_ERROR, _("Cannot find QEMU binary %s: %s"), binary, strerror(errno)); return -1; } if (qemudExtractVersionInfo(binary, &driver->qemuVersion, &ignored) < 0) { return -1; } return 0; } /* Converts def->virtType to applicable string type * @param type integer virt type * @return string type on success, NULL on fail */ const char * qemudVirtTypeToString(int type) { switch (type) { case QEMUD_VIRT_QEMU: return "qemu"; case QEMUD_VIRT_KQEMU: return "kqemu"; case QEMUD_VIRT_KVM: return "kvm"; } return NULL; } /* Parse the XML definition for a disk * @param disk pre-allocated & zero'd disk record * @param node XML nodeset to parse for disk definition * @return 0 on success, -1 on failure */ static int qemudParseDiskXML(virConnectPtr conn, struct qemud_vm_disk_def *disk, xmlNodePtr node) { xmlNodePtr cur; xmlChar *device = NULL; xmlChar *source = NULL; xmlChar *target = NULL; xmlChar *type = NULL; xmlChar *bus = NULL; int typ = 0; type = xmlGetProp(node, BAD_CAST "type"); if (type != NULL) { if (xmlStrEqual(type, BAD_CAST "file")) typ = QEMUD_DISK_FILE; else if (xmlStrEqual(type, BAD_CAST "block")) typ = QEMUD_DISK_BLOCK; else { typ = QEMUD_DISK_FILE; } xmlFree(type); type = NULL; } device = xmlGetProp(node, BAD_CAST "device"); cur = node->children; while (cur != NULL) { if (cur->type == XML_ELEMENT_NODE) { if ((source == NULL) && (xmlStrEqual(cur->name, BAD_CAST "source"))) { if (typ == QEMUD_DISK_FILE) source = xmlGetProp(cur, BAD_CAST "file"); else source = xmlGetProp(cur, BAD_CAST "dev"); } else if ((target == NULL) && (xmlStrEqual(cur->name, BAD_CAST "target"))) { target = xmlGetProp(cur, BAD_CAST "dev"); bus = xmlGetProp(cur, BAD_CAST "bus"); } else if (xmlStrEqual(cur->name, BAD_CAST "readonly")) { disk->readonly = 1; } } cur = cur->next; } if (source == NULL) { /* There is a case without the source * to the CD-ROM device */ if (!device || STRNEQ((const char *) device, "cdrom")) { qemudReportError(conn, NULL, NULL, VIR_ERR_NO_SOURCE, target ? "%s" : NULL, target); goto error; } } if (target == NULL) { qemudReportError(conn, NULL, NULL, VIR_ERR_NO_TARGET, source ? "%s" : NULL, source); goto error; } if (device && STREQ((const char *)device, "floppy") && STRNEQ((const char *)target, "fda") && STRNEQ((const char *)target, "fdb")) { qemudReportError(conn, NULL, NULL, VIR_ERR_INTERNAL_ERROR, _("Invalid floppy device name: %s"), target); goto error; } if (device && STREQ((const char *)device, "cdrom") && STRNEQ((const char *)target, "hdc")) { qemudReportError(conn, NULL, NULL, VIR_ERR_INTERNAL_ERROR, _("Invalid cdrom device name: %s"), target); goto error; } if (device && STREQ((const char *)device, "cdrom")) disk->readonly = 1; if ((!device || STREQ((const char *)device, "disk")) && !STRPREFIX((const char *)target, "hd") && !STRPREFIX((const char *)target, "sd") && !STRPREFIX((const char *)target, "vd") && !STRPREFIX((const char *)target, "xvd")) { qemudReportError(conn, NULL, NULL, VIR_ERR_INTERNAL_ERROR, _("Invalid harddisk device name: %s"), target); goto error; } strncpy(disk->src, (source ? (const char *) source : "\0"), NAME_MAX-1); disk->src[NAME_MAX-1] = '\0'; strncpy(disk->dst, (const char *)target, NAME_MAX-1); disk->dst[NAME_MAX-1] = '\0'; disk->type = typ; if (!device) disk->device = QEMUD_DISK_DISK; else if (STREQ((const char *)device, "disk")) disk->device = QEMUD_DISK_DISK; else if (STREQ((const char *)device, "cdrom")) disk->device = QEMUD_DISK_CDROM; else if (STREQ((const char *)device, "floppy")) disk->device = QEMUD_DISK_FLOPPY; else { qemudReportError(conn, NULL, NULL, VIR_ERR_INTERNAL_ERROR, _("Invalid device type: %s"), device); goto error; } if (!bus) { if (disk->device == QEMUD_DISK_FLOPPY) { disk->bus = QEMUD_DISK_BUS_FDC; } else { if (STRPREFIX((const char *)target, "hd")) disk->bus = QEMUD_DISK_BUS_IDE; else if (STRPREFIX((const char *)target, "sd")) disk->bus = QEMUD_DISK_BUS_SCSI; else if (STRPREFIX((const char *)target, "vd")) disk->bus = QEMUD_DISK_BUS_VIRTIO; else if (STRPREFIX((const char *)target, "xvd")) disk->bus = QEMUD_DISK_BUS_XEN; else disk->bus = QEMUD_DISK_BUS_IDE; } } else if (STREQ((const char *)bus, "ide")) disk->bus = QEMUD_DISK_BUS_IDE; else if (STREQ((const char *)bus, "fdc")) disk->bus = QEMUD_DISK_BUS_FDC; else if (STREQ((const char *)bus, "scsi")) disk->bus = QEMUD_DISK_BUS_SCSI; else if (STREQ((const char *)bus, "virtio")) disk->bus = QEMUD_DISK_BUS_VIRTIO; else if (STREQ((const char *)bus, "xen")) disk->bus = QEMUD_DISK_BUS_XEN; else { qemudReportError(conn, NULL, NULL, VIR_ERR_INTERNAL_ERROR, _("Invalid bus type: %s"), bus); goto error; } if (disk->device == QEMUD_DISK_FLOPPY && disk->bus != QEMUD_DISK_BUS_FDC) { qemudReportError(conn, NULL, NULL, VIR_ERR_INTERNAL_ERROR, _("Invalid bus type '%s' for floppy disk"), bus); goto error; } xmlFree(device); xmlFree(target); xmlFree(source); xmlFree(bus); return 0; error: xmlFree(bus); xmlFree(type); xmlFree(target); xmlFree(source); xmlFree(device); return -1; } static void qemudRandomMAC(struct qemud_vm_net_def *net) { net->mac[0] = 0x52; net->mac[1] = 0x54; net->mac[2] = 0x00; net->mac[3] = 1 + (int)(256*(rand()/(RAND_MAX+1.0))); net->mac[4] = 1 + (int)(256*(rand()/(RAND_MAX+1.0))); net->mac[5] = 1 + (int)(256*(rand()/(RAND_MAX+1.0))); } /* Parse the XML definition for a network interface * @param net pre-allocated & zero'd net record * @param node XML nodeset to parse for net definition * @return 0 on success, -1 on failure */ static int qemudParseInterfaceXML(virConnectPtr conn, struct qemud_vm_net_def *net, xmlNodePtr node) { xmlNodePtr cur; xmlChar *macaddr = NULL; xmlChar *type = NULL; xmlChar *network = NULL; xmlChar *bridge = NULL; xmlChar *ifname = NULL; xmlChar *script = NULL; xmlChar *address = NULL; xmlChar *port = NULL; xmlChar *model = NULL; net->type = QEMUD_NET_USER; type = xmlGetProp(node, BAD_CAST "type"); if (type != NULL) { if (xmlStrEqual(type, BAD_CAST "user")) net->type = QEMUD_NET_USER; else if (xmlStrEqual(type, BAD_CAST "ethernet")) net->type = QEMUD_NET_ETHERNET; else if (xmlStrEqual(type, BAD_CAST "server")) net->type = QEMUD_NET_SERVER; else if (xmlStrEqual(type, BAD_CAST "client")) net->type = QEMUD_NET_CLIENT; else if (xmlStrEqual(type, BAD_CAST "mcast")) net->type = QEMUD_NET_MCAST; else if (xmlStrEqual(type, BAD_CAST "network")) net->type = QEMUD_NET_NETWORK; else if (xmlStrEqual(type, BAD_CAST "bridge")) net->type = QEMUD_NET_BRIDGE; else net->type = QEMUD_NET_USER; xmlFree(type); type = NULL; } cur = node->children; while (cur != NULL) { if (cur->type == XML_ELEMENT_NODE) { if ((macaddr == NULL) && (xmlStrEqual(cur->name, BAD_CAST "mac"))) { macaddr = xmlGetProp(cur, BAD_CAST "address"); } else if ((network == NULL) && (net->type == QEMUD_NET_NETWORK) && (xmlStrEqual(cur->name, BAD_CAST "source"))) { network = xmlGetProp(cur, BAD_CAST "network"); } else if ((network == NULL) && (net->type == QEMUD_NET_BRIDGE) && (xmlStrEqual(cur->name, BAD_CAST "source"))) { bridge = xmlGetProp(cur, BAD_CAST "bridge"); } else if ((network == NULL) && ((net->type == QEMUD_NET_SERVER) || (net->type == QEMUD_NET_CLIENT) || (net->type == QEMUD_NET_MCAST)) && (xmlStrEqual(cur->name, BAD_CAST "source"))) { address = xmlGetProp(cur, BAD_CAST "address"); port = xmlGetProp(cur, BAD_CAST "port"); } else if ((ifname == NULL) && ((net->type == QEMUD_NET_NETWORK) || (net->type == QEMUD_NET_ETHERNET) || (net->type == QEMUD_NET_BRIDGE)) && xmlStrEqual(cur->name, BAD_CAST "target")) { ifname = xmlGetProp(cur, BAD_CAST "dev"); if (STRPREFIX((const char*)ifname, "vnet")) { /* An auto-generated target name, blank it out */ xmlFree(ifname); ifname = NULL; } } else if ((script == NULL) && (net->type == QEMUD_NET_ETHERNET) && xmlStrEqual(cur->name, BAD_CAST "script")) { script = xmlGetProp(cur, BAD_CAST "path"); } else if (xmlStrEqual (cur->name, BAD_CAST "model")) { model = xmlGetProp (cur, BAD_CAST "type"); } } cur = cur->next; } if (macaddr) { unsigned int mac[6]; sscanf((const char *)macaddr, "%02x:%02x:%02x:%02x:%02x:%02x", (unsigned int*)&mac[0], (unsigned int*)&mac[1], (unsigned int*)&mac[2], (unsigned int*)&mac[3], (unsigned int*)&mac[4], (unsigned int*)&mac[5]); net->mac[0] = mac[0]; net->mac[1] = mac[1]; net->mac[2] = mac[2]; net->mac[3] = mac[3]; net->mac[4] = mac[4]; net->mac[5] = mac[5]; xmlFree(macaddr); macaddr = NULL; } else { qemudRandomMAC(net); } if (net->type == QEMUD_NET_NETWORK) { int len; if (network == NULL) { qemudReportError(conn, NULL, NULL, VIR_ERR_INTERNAL_ERROR, "%s", _("No 'network' attribute specified with ")); goto error; } else if ((len = xmlStrlen(network)) >= (QEMUD_MAX_NAME_LEN-1)) { qemudReportError(conn, NULL, NULL, VIR_ERR_INTERNAL_ERROR, _("Network name '%s' too long"), network); goto error; } else { strncpy(net->dst.network.name, (char *)network, len); net->dst.network.name[len] = '\0'; } if (network) { xmlFree(network); network = NULL; } if (ifname != NULL) { if ((len = xmlStrlen(ifname)) >= (BR_IFNAME_MAXLEN-1)) { qemudReportError(conn, NULL, NULL, VIR_ERR_INTERNAL_ERROR, _("TAP interface name '%s' is too long"), ifname); goto error; } else { strncpy(net->dst.network.ifname, (char *)ifname, len); net->dst.network.ifname[len] = '\0'; } xmlFree(ifname); ifname = NULL; } } else if (net->type == QEMUD_NET_ETHERNET) { int len; if (script != NULL) { if ((len = xmlStrlen(script)) >= (PATH_MAX-1)) { qemudReportError(conn, NULL, NULL, VIR_ERR_INTERNAL_ERROR, _("TAP script path '%s' is too long"), script); goto error; } else { strncpy(net->dst.ethernet.script, (char *)script, len); net->dst.ethernet.script[len] = '\0'; } xmlFree(script); script = NULL; } if (ifname != NULL) { if ((len = xmlStrlen(ifname)) >= (BR_IFNAME_MAXLEN-1)) { qemudReportError(conn, NULL, NULL, VIR_ERR_INTERNAL_ERROR, _("TAP interface name '%s' is too long"), ifname); goto error; } else { strncpy(net->dst.ethernet.ifname, (char *)ifname, len); net->dst.ethernet.ifname[len] = '\0'; } xmlFree(ifname); } } else if (net->type == QEMUD_NET_BRIDGE) { int len; if (bridge == NULL) { qemudReportError(conn, NULL, NULL, VIR_ERR_INTERNAL_ERROR, "%s", _("No 'dev' attribute specified with ")); goto error; } else if ((len = xmlStrlen(bridge)) >= (BR_IFNAME_MAXLEN-1)) { qemudReportError(conn, NULL, NULL, VIR_ERR_INTERNAL_ERROR, _("TAP bridge path '%s' is too long"), bridge); goto error; } else { strncpy(net->dst.bridge.brname, (char *)bridge, len); net->dst.bridge.brname[len] = '\0'; } xmlFree(bridge); bridge = NULL; if (ifname != NULL) { if ((len = xmlStrlen(ifname)) >= (BR_IFNAME_MAXLEN-1)) { qemudReportError(conn, NULL, NULL, VIR_ERR_INTERNAL_ERROR, _("TAP interface name '%s' is too long"), ifname); goto error; } else { strncpy(net->dst.bridge.ifname, (char *)ifname, len); net->dst.bridge.ifname[len] = '\0'; } xmlFree(ifname); } } else if (net->type == QEMUD_NET_CLIENT || net->type == QEMUD_NET_SERVER || net->type == QEMUD_NET_MCAST) { int len = 0; char *ret; if (port == NULL) { qemudReportError(conn, NULL, NULL, VIR_ERR_INTERNAL_ERROR, "%s", _("No 'port' attribute specified with socket interface")); goto error; } if (!(net->dst.socket.port = strtol((char*)port, &ret, 10)) && ret == (char*)port) { qemudReportError(conn, NULL, NULL, VIR_ERR_INTERNAL_ERROR, "%s", _("Cannot parse 'port' attribute with socket interface")); goto error; } xmlFree(port); port = NULL; if (address == NULL) { if (net->type == QEMUD_NET_CLIENT || net->type == QEMUD_NET_MCAST) { qemudReportError(conn, NULL, NULL, VIR_ERR_INTERNAL_ERROR, "%s", _("No 'address' attribute specified with socket interface")); goto error; } } else if ((len = xmlStrlen(address)) >= (BR_INET_ADDR_MAXLEN)) { qemudReportError(conn, NULL, NULL, VIR_ERR_INTERNAL_ERROR, _("IP address '%s' is too long"), address); goto error; } if (address == NULL) { net->dst.socket.address[0] = '\0'; } else { strncpy(net->dst.socket.address, (char*)address,len); net->dst.socket.address[len] = '\0'; } xmlFree(address); } /* NIC model (see -net nic,model=?). We only check that it looks * reasonable, not that it is a supported NIC type. FWIW kvm * supports these types as of April 2008: * i82551 i82557b i82559er ne2k_pci pcnet rtl8139 e1000 virtio */ if (model != NULL) { int i, len; len = xmlStrlen (model); if (len >= QEMUD_MODEL_MAX_LEN) { qemudReportError (conn, NULL, NULL, VIR_ERR_INVALID_ARG, _("Model name '%s' is too long"), model); goto error; } for (i = 0; i < len; ++i) { int char_ok = c_isalnum(model[i]) || model[i] == '_'; if (!char_ok) { qemudReportError (conn, NULL, NULL, VIR_ERR_INVALID_ARG, "%s", _("Model name contains invalid characters")); goto error; } } strncpy (net->model, (const char*) model, len); net->model[len] = '\0'; xmlFree (model); model = NULL; } else net->model[0] = '\0'; return 0; error: xmlFree(network); xmlFree(address); xmlFree(port); xmlFree(ifname); xmlFree(script); xmlFree(bridge); xmlFree(model); return -1; } /* Parse the XML definition for a character device * @param net pre-allocated & zero'd net record * @param node XML nodeset to parse for net definition * @return 0 on success, -1 on failure * * The XML we're dealing with looks like * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * */ static int qemudParseCharXML(virConnectPtr conn, struct qemud_vm_chr_def *chr, int portNum, xmlNodePtr node) { xmlNodePtr cur; xmlChar *type = NULL; xmlChar *bindHost = NULL; xmlChar *bindService = NULL; xmlChar *connectHost = NULL; xmlChar *connectService = NULL; xmlChar *path = NULL; xmlChar *mode = NULL; xmlChar *protocol = NULL; int ret = -1; chr->srcType = QEMUD_CHR_SRC_TYPE_PTY; type = xmlGetProp(node, BAD_CAST "type"); if (type != NULL) { if (xmlStrEqual(type, BAD_CAST "null")) chr->srcType = QEMUD_CHR_SRC_TYPE_NULL; else if (xmlStrEqual(type, BAD_CAST "vc")) chr->srcType = QEMUD_CHR_SRC_TYPE_VC; else if (xmlStrEqual(type, BAD_CAST "pty")) chr->srcType = QEMUD_CHR_SRC_TYPE_PTY; else if (xmlStrEqual(type, BAD_CAST "dev")) chr->srcType = QEMUD_CHR_SRC_TYPE_DEV; else if (xmlStrEqual(type, BAD_CAST "file")) chr->srcType = QEMUD_CHR_SRC_TYPE_FILE; else if (xmlStrEqual(type, BAD_CAST "pipe")) chr->srcType = QEMUD_CHR_SRC_TYPE_PIPE; else if (xmlStrEqual(type, BAD_CAST "stdio")) chr->srcType = QEMUD_CHR_SRC_TYPE_STDIO; else if (xmlStrEqual(type, BAD_CAST "udp")) chr->srcType = QEMUD_CHR_SRC_TYPE_UDP; else if (xmlStrEqual(type, BAD_CAST "tcp")) chr->srcType = QEMUD_CHR_SRC_TYPE_TCP; else if (xmlStrEqual(type, BAD_CAST "unix")) chr->srcType = QEMUD_CHR_SRC_TYPE_UNIX; else chr->srcType = QEMUD_CHR_SRC_TYPE_NULL; } cur = node->children; while (cur != NULL) { if (cur->type == XML_ELEMENT_NODE) { if (xmlStrEqual(cur->name, BAD_CAST "source")) { if (mode == NULL) mode = xmlGetProp(cur, BAD_CAST "mode"); switch (chr->srcType) { case QEMUD_CHR_SRC_TYPE_PTY: case QEMUD_CHR_SRC_TYPE_DEV: case QEMUD_CHR_SRC_TYPE_FILE: case QEMUD_CHR_SRC_TYPE_PIPE: case QEMUD_CHR_SRC_TYPE_UNIX: if (path == NULL) path = xmlGetProp(cur, BAD_CAST "path"); break; case QEMUD_CHR_SRC_TYPE_UDP: case QEMUD_CHR_SRC_TYPE_TCP: if (mode == NULL || STREQ((const char *)mode, "connect")) { if (connectHost == NULL) connectHost = xmlGetProp(cur, BAD_CAST "host"); if (connectService == NULL) connectService = xmlGetProp(cur, BAD_CAST "service"); } else { if (bindHost == NULL) bindHost = xmlGetProp(cur, BAD_CAST "host"); if (bindService == NULL) bindService = xmlGetProp(cur, BAD_CAST "service"); } if (chr->srcType == QEMUD_CHR_SRC_TYPE_UDP) { xmlFree(mode); mode = NULL; } } } else if (xmlStrEqual(cur->name, BAD_CAST "protocol")) { if (protocol == NULL) protocol = xmlGetProp(cur, BAD_CAST "type"); } } cur = cur->next; } chr->dstPort = portNum; switch (chr->srcType) { case QEMUD_CHR_SRC_TYPE_NULL: /* Nada */ break; case QEMUD_CHR_SRC_TYPE_VC: break; case QEMUD_CHR_SRC_TYPE_PTY: /* @path attribute is an output only property - pty is auto-allocted */ break; case QEMUD_CHR_SRC_TYPE_DEV: case QEMUD_CHR_SRC_TYPE_FILE: case QEMUD_CHR_SRC_TYPE_PIPE: if (path == NULL) { qemudReportError(conn, NULL, NULL, VIR_ERR_INTERNAL_ERROR, "%s", _("Missing source path attribute for char device")); goto cleanup; } strncpy(chr->srcData.file.path, (const char *)path, sizeof(chr->srcData.file.path)); NUL_TERMINATE(chr->srcData.file.path); break; case QEMUD_CHR_SRC_TYPE_STDIO: /* Nada */ break; case QEMUD_CHR_SRC_TYPE_TCP: if (mode == NULL || STREQ((const char *)mode, "connect")) { if (connectHost == NULL) { qemudReportError(conn, NULL, NULL, VIR_ERR_INTERNAL_ERROR, "%s", _("Missing source host attribute for char device")); goto cleanup; } if (connectService == NULL) { qemudReportError(conn, NULL, NULL, VIR_ERR_INTERNAL_ERROR, "%s", _("Missing source service attribute for char device")); goto cleanup; } strncpy(chr->srcData.tcp.host, (const char *)connectHost, sizeof(chr->srcData.tcp.host)); NUL_TERMINATE(chr->srcData.tcp.host); strncpy(chr->srcData.tcp.service, (const char *)connectService, sizeof(chr->srcData.tcp.service)); NUL_TERMINATE(chr->srcData.tcp.service); chr->srcData.tcp.listen = 0; } else { if (bindHost == NULL) { qemudReportError(conn, NULL, NULL, VIR_ERR_INTERNAL_ERROR, "%s", _("Missing source host attribute for char device")); goto cleanup; } if (bindService == NULL) { qemudReportError(conn, NULL, NULL, VIR_ERR_INTERNAL_ERROR, "%s", _("Missing source service attribute for char device")); goto cleanup; } strncpy(chr->srcData.tcp.host, (const char *)bindHost, sizeof(chr->srcData.tcp.host)); NUL_TERMINATE(chr->srcData.tcp.host); strncpy(chr->srcData.tcp.service, (const char *)bindService, sizeof(chr->srcData.tcp.service)); NUL_TERMINATE(chr->srcData.tcp.service); chr->srcData.tcp.listen = 1; } if (protocol != NULL && STREQ((const char *)protocol, "telnet")) chr->srcData.tcp.protocol = QEMUD_CHR_SRC_TCP_PROTOCOL_TELNET; else chr->srcData.tcp.protocol = QEMUD_CHR_SRC_TCP_PROTOCOL_RAW; break; case QEMUD_CHR_SRC_TYPE_UDP: if (connectService == NULL) { qemudReportError(conn, NULL, NULL, VIR_ERR_INTERNAL_ERROR, "%s", _("Missing source service attribute for char device")); goto cleanup; } if (connectHost != NULL) { strncpy(chr->srcData.udp.connectHost, (const char *)connectHost, sizeof(chr->srcData.udp.connectHost)); NUL_TERMINATE(chr->srcData.udp.connectHost); } strncpy(chr->srcData.udp.connectService, (const char *)connectService, sizeof(chr->srcData.udp.connectService)); NUL_TERMINATE(chr->srcData.udp.connectService); if (bindHost != NULL) { strncpy(chr->srcData.udp.bindHost, (const char *)bindHost, sizeof(chr->srcData.udp.bindHost)); NUL_TERMINATE(chr->srcData.udp.bindHost); } if (bindService != NULL) { strncpy(chr->srcData.udp.bindService, (const char *)bindService, sizeof(chr->srcData.udp.bindService)); NUL_TERMINATE(chr->srcData.udp.bindService); } break; case QEMUD_CHR_SRC_TYPE_UNIX: if (path == NULL) { qemudReportError(conn, NULL, NULL, VIR_ERR_INTERNAL_ERROR, "%s", _("Missing source path attribute for char device")); goto cleanup; } if (mode != NULL && STRNEQ((const char *)mode, "connect")) chr->srcData.nix.listen = 1; else chr->srcData.nix.listen = 0; strncpy(chr->srcData.nix.path, (const char *)path, sizeof(chr->srcData.nix.path)); NUL_TERMINATE(chr->srcData.nix.path); break; } ret = 0; cleanup: xmlFree(mode); xmlFree(protocol); xmlFree(type); xmlFree(bindHost); xmlFree(bindService); xmlFree(connectHost); xmlFree(connectService); xmlFree(path); return ret; } static int qemudParseCharXMLDevices(virConnectPtr conn, xmlXPathContextPtr ctxt, const char *xpath, unsigned int *ndevs, struct qemud_vm_chr_def **devs) { xmlXPathObjectPtr obj; int i, ret = -1; obj = xmlXPathEval(BAD_CAST xpath, ctxt); if ((obj != NULL) && (obj->type == XPATH_NODESET) && (obj->nodesetval != NULL) && (obj->nodesetval->nodeNr >= 0)) { struct qemud_vm_chr_def *prev = *devs; if (ndevs == NULL && obj->nodesetval->nodeNr > 1) { qemudReportError(conn, NULL, NULL, VIR_ERR_INTERNAL_ERROR, "%s", _("too many character devices")); goto cleanup; } for (i = 0; i < obj->nodesetval->nodeNr; i++) { struct qemud_vm_chr_def *chr = calloc(1, sizeof(*chr)); if (!chr) { qemudReportError(conn, NULL, NULL, VIR_ERR_NO_MEMORY, "%s", _("failed to allocate space for char device")); goto cleanup; } if (qemudParseCharXML(conn, chr, i, obj->nodesetval->nodeTab[i]) < 0) { free(chr); goto cleanup; } if (ndevs) (*ndevs)++; chr->next = NULL; if (i == 0) { *devs = chr; } else { prev->next = chr; } prev = chr; } } ret = 0; cleanup: xmlXPathFreeObject(obj); return ret; } /* Parse the XML definition for a network interface */ static int qemudParseInputXML(virConnectPtr conn, const struct qemud_vm_def *vm, struct qemud_vm_input_def *input, xmlNodePtr node) { xmlChar *type = NULL; xmlChar *bus = NULL; type = xmlGetProp(node, BAD_CAST "type"); bus = xmlGetProp(node, BAD_CAST "bus"); if (!type) { qemudReportError(conn, NULL, NULL, VIR_ERR_INTERNAL_ERROR, "%s", _("missing input device type")); goto error; } if (STREQ((const char *)type, "mouse")) { input->type = QEMU_INPUT_TYPE_MOUSE; } else if (STREQ((const char *)type, "tablet")) { input->type = QEMU_INPUT_TYPE_TABLET; } else { qemudReportError(conn, NULL, NULL, VIR_ERR_INTERNAL_ERROR, _("unsupported input device type %s"), (const char*)type); goto error; } if (bus) { if (STREQ(vm->os.type, "hvm")) { if (STREQ((const char*)bus, "ps2")) { /* Only allow mouse */ if (input->type != QEMU_INPUT_TYPE_MOUSE) { qemudReportError(conn, NULL, NULL, VIR_ERR_INTERNAL_ERROR, _("ps2 bus does not support %s input device"), (const char*)type); goto error; } input->bus = QEMU_INPUT_BUS_PS2; } else if (STREQ((const char *)bus, "usb")) { /* Allow mouse & tablet */ input->bus = QEMU_INPUT_BUS_USB; } else { qemudReportError(conn, NULL, NULL, VIR_ERR_INTERNAL_ERROR, _("unsupported input bus %s"), (const char*)bus); goto error; } } else { if (STREQ((const char *)bus, "xen")) { /* Allow mouse only */ input->bus = QEMU_INPUT_BUS_XEN; if (input->type != QEMU_INPUT_TYPE_MOUSE) { qemudReportError(conn, NULL, NULL, VIR_ERR_INTERNAL_ERROR, _("xen bus does not support %s input device"), (const char*)type); goto error; } } else { qemudReportError(conn, NULL, NULL, VIR_ERR_INTERNAL_ERROR, _("unsupported input bus %s"), (const char*)bus); goto error; } } } else { if (STREQ(vm->os.type, "hvm")) { if (input->type == QEMU_INPUT_TYPE_MOUSE) input->bus = QEMU_INPUT_BUS_PS2; else input->bus = QEMU_INPUT_BUS_USB; } else { input->bus = QEMU_INPUT_BUS_XEN; } } xmlFree(type); xmlFree(bus); return 0; error: xmlFree(type); xmlFree(bus); return -1; } static int qemudDiskCompare(const void *aptr, const void *bptr) { struct qemud_vm_disk_def *a = (struct qemud_vm_disk_def *) aptr; struct qemud_vm_disk_def *b = (struct qemud_vm_disk_def *) bptr; if (a->bus == b->bus) return virDiskNameToIndex(a->dst) - virDiskNameToIndex(b->dst); else return a->bus - b->bus; } static const char *qemudBusIdToName(int busId, int qemuIF) { const char *busnames[] = { "ide", (qemuIF ? "floppy" : "fdc"), "scsi", "virtio", "xen"}; verify_true(ARRAY_CARDINALITY(busnames) == QEMUD_DISK_BUS_LAST); return busnames[busId]; } /* Sound device helper functions */ static int qemudSoundModelFromString(const char *model) { if (STREQ(model, "sb16")) { return QEMU_SOUND_SB16; } else if (STREQ(model, "es1370")) { return QEMU_SOUND_ES1370; } else if (STREQ(model, "pcspk")) { return QEMU_SOUND_PCSPK; } return -1; } static const char *qemudSoundModelToString(const int model) { if (model == QEMU_SOUND_SB16) { return "sb16"; } else if (model == QEMU_SOUND_ES1370) { return "es1370"; } else if (model == QEMU_SOUND_PCSPK) { return "pcspk"; } return NULL; } static int qemudParseSoundXML(virConnectPtr conn, struct qemud_vm_sound_def *sound, const xmlNodePtr node) { int err = -1; xmlChar *model = NULL; model = xmlGetProp(node, BAD_CAST "model"); if (!model) { qemudReportError(conn, NULL, NULL, VIR_ERR_INTERNAL_ERROR, "%s", _("missing sound model")); goto error; } if ((sound->model = qemudSoundModelFromString((char *) model)) < 0) { qemudReportError(conn, NULL, NULL, VIR_ERR_INTERNAL_ERROR, _("invalid sound model '%s'"), (char *) model); goto error; } err = 0; error: xmlFree(model); return err; } /* * Parses a libvirt XML definition of a guest, and populates the * the qemud_vm struct with matching data about the guests config */ static struct qemud_vm_def *qemudParseXML(virConnectPtr conn, struct qemud_driver *driver, xmlDocPtr xml) { xmlNodePtr root = NULL; xmlChar *prop = NULL; xmlXPathContextPtr ctxt = NULL; xmlXPathObjectPtr obj = NULL; char *conv = NULL; int i; struct qemud_vm_def *def; if (!(def = calloc(1, sizeof(*def)))) { qemudReportError(conn, NULL, NULL, VIR_ERR_NO_MEMORY, "%s", _("failed to allocate space for xmlXPathContext")); return NULL; } /* Prepare parser / xpath context */ root = xmlDocGetRootElement(xml); if ((root == NULL) || (!xmlStrEqual(root->name, BAD_CAST "domain"))) { qemudReportError(conn, NULL, NULL, VIR_ERR_INTERNAL_ERROR, "%s", _("incorrect root element")); goto error; } ctxt = xmlXPathNewContext(xml); if (ctxt == NULL) { qemudReportError(conn, NULL, NULL, VIR_ERR_NO_MEMORY, "%s", _("failed to allocate space for xmlXPathContext")); goto error; } /* Find out what type of QEMU virtualization to use */ if (!(prop = xmlGetProp(root, BAD_CAST "type"))) { qemudReportError(conn, NULL, NULL, VIR_ERR_INTERNAL_ERROR, "%s", _("missing domain type attribute")); goto error; } if (STREQ((char *)prop, "qemu")) def->virtType = QEMUD_VIRT_QEMU; else if (STREQ((char *)prop, "kqemu")) def->virtType = QEMUD_VIRT_KQEMU; else if (STREQ((char *)prop, "kvm")) def->virtType = QEMUD_VIRT_KVM; else { qemudReportError(conn, NULL, NULL, VIR_ERR_INTERNAL_ERROR, "%s", _("invalid domain type attribute")); goto error; } free(prop); prop = NULL; /* Extract domain name */ obj = xmlXPathEval(BAD_CAST "string(/domain/name[1])", ctxt); if ((obj == NULL) || (obj->type != XPATH_STRING) || (obj->stringval == NULL) || (obj->stringval[0] == 0)) { qemudReportError(conn, NULL, NULL, VIR_ERR_NO_NAME, NULL); goto error; } if (strlen((const char *)obj->stringval) >= (QEMUD_MAX_NAME_LEN-1)) { qemudReportError(conn, NULL, NULL, VIR_ERR_INTERNAL_ERROR, "%s", _("domain name length too long")); goto error; } strcpy(def->name, (const char *)obj->stringval); xmlXPathFreeObject(obj); /* Extract domain uuid */ obj = xmlXPathEval(BAD_CAST "string(/domain/uuid[1])", ctxt); if ((obj == NULL) || (obj->type != XPATH_STRING) || (obj->stringval == NULL) || (obj->stringval[0] == 0)) { int err; if ((err = virUUIDGenerate(def->uuid))) { qemudReportError(conn, NULL, NULL, VIR_ERR_INTERNAL_ERROR, _("Failed to generate UUID: %s"), strerror(err)); goto error; } } else if (virUUIDParse((const char *)obj->stringval, def->uuid) < 0) { qemudReportError(conn, NULL, NULL, VIR_ERR_INTERNAL_ERROR, "%s", _("malformed uuid element")); goto error; } xmlXPathFreeObject(obj); /* Extract domain memory */ obj = xmlXPathEval(BAD_CAST "string(/domain/memory[1])", ctxt); if ((obj == NULL) || (obj->type != XPATH_STRING) || (obj->stringval == NULL) || (obj->stringval[0] == 0)) { qemudReportError(conn, NULL, NULL, VIR_ERR_INTERNAL_ERROR, "%s", _("missing memory element")); goto error; } else { conv = NULL; def->maxmem = strtoll((const char*)obj->stringval, &conv, 10); if (conv == (const char*)obj->stringval) { qemudReportError(conn, NULL, NULL, VIR_ERR_INTERNAL_ERROR, "%s", _("malformed memory information")); goto error; } } xmlXPathFreeObject(obj); /* Extract domain memory */ obj = xmlXPathEval(BAD_CAST "string(/domain/currentMemory[1])", ctxt); if ((obj == NULL) || (obj->type != XPATH_STRING) || (obj->stringval == NULL) || (obj->stringval[0] == 0)) { def->memory = def->maxmem; } else { conv = NULL; def->memory = strtoll((const char*)obj->stringval, &conv, 10); if (def->memory > def->maxmem) def->memory = def->maxmem; if (conv == (const char*)obj->stringval) { qemudReportError(conn, NULL, NULL, VIR_ERR_INTERNAL_ERROR, "%s", _("malformed memory information")); goto error; } } xmlXPathFreeObject(obj); /* Extract domain vcpu info */ obj = xmlXPathEval(BAD_CAST "string(/domain/vcpu[1])", ctxt); if ((obj == NULL) || (obj->type != XPATH_STRING) || (obj->stringval == NULL) || (obj->stringval[0] == 0)) { def->vcpus = 1; } else { conv = NULL; def->vcpus = strtoll((const char*)obj->stringval, &conv, 10); if (conv == (const char*)obj->stringval) { qemudReportError(conn, NULL, NULL, VIR_ERR_INTERNAL_ERROR, "%s", _("malformed vcpu information")); goto error; } } xmlXPathFreeObject(obj); /* Extract domain vcpu info */ obj = xmlXPathEval(BAD_CAST "string(/domain/vcpu[1]/@cpuset)", ctxt); if ((obj == NULL) || (obj->type != XPATH_STRING) || (obj->stringval == NULL) || (obj->stringval[0] == 0)) { /* Allow use on all CPUS */ memset(def->cpumask, 1, QEMUD_CPUMASK_LEN); } else { char *set = (char *)obj->stringval; memset(def->cpumask, 0, QEMUD_CPUMASK_LEN); if (virParseCpuSet(conn, (const char **)&set, 0, def->cpumask, QEMUD_CPUMASK_LEN) < 0) { qemudReportError(conn, NULL, NULL, VIR_ERR_INTERNAL_ERROR, "%s", _("malformed vcpu mask information")); goto error; } } xmlXPathFreeObject(obj); /* See if ACPI feature is requested */ obj = xmlXPathEval(BAD_CAST "/domain/features/acpi", ctxt); if ((obj != NULL) && (obj->type == XPATH_NODESET) && (obj->nodesetval != NULL) && (obj->nodesetval->nodeNr == 1)) { def->features |= QEMUD_FEATURE_ACPI; } xmlXPathFreeObject(obj); /* See if we disable reboots */ obj = xmlXPathEval(BAD_CAST "string(/domain/on_reboot)", ctxt); if ((obj == NULL) || (obj->type != XPATH_STRING) || (obj->stringval == NULL) || (obj->stringval[0] == 0)) { def->noReboot = 0; } else { if (STREQ((char*)obj->stringval, "destroy")) def->noReboot = 1; else def->noReboot = 0; } xmlXPathFreeObject(obj); /* See if we set clock to localtime */ obj = xmlXPathEval(BAD_CAST "string(/domain/clock/@offset)", ctxt); if ((obj == NULL) || (obj->type != XPATH_STRING) || (obj->stringval == NULL) || (obj->stringval[0] == 0)) { def->localtime = 0; } else { if (STREQ((char*)obj->stringval, "localtime")) def->localtime = 1; else def->localtime = 0; } xmlXPathFreeObject(obj); /* Extract bootloader */ obj = xmlXPathEval(BAD_CAST "string(/domain/bootloader)", ctxt); if ((obj != NULL) && (obj->type == XPATH_STRING) && (obj->stringval != NULL) && (obj->stringval[0] != 0)) { strncpy(def->os.bootloader, (const char*)obj->stringval, sizeof(def->os.bootloader)); NUL_TERMINATE(def->os.bootloader); /* Set a default OS type, since is optional with bootloader */ strcpy(def->os.type, "xen"); } xmlXPathFreeObject(obj); /* Extract OS type info */ obj = xmlXPathEval(BAD_CAST "string(/domain/os/type[1])", ctxt); if ((obj == NULL) || (obj->type != XPATH_STRING) || (obj->stringval == NULL) || (obj->stringval[0] == 0)) { if (!def->os.type[0]) { qemudReportError(conn, NULL, NULL, VIR_ERR_OS_TYPE, "%s", _("no OS type")); goto error; } } else { strcpy(def->os.type, (const char *)obj->stringval); } xmlXPathFreeObject(obj); obj = NULL; if (!virCapabilitiesSupportsGuestOSType(driver->caps, def->os.type)) { qemudReportError(conn, NULL, NULL, VIR_ERR_OS_TYPE, "%s", def->os.type); goto error; } obj = xmlXPathEval(BAD_CAST "string(/domain/os/type[1]/@arch)", ctxt); if ((obj == NULL) || (obj->type != XPATH_STRING) || (obj->stringval == NULL) || (obj->stringval[0] == 0)) { const char *defaultArch = virCapabilitiesDefaultGuestArch(driver->caps, def->os.type); if (defaultArch == NULL) { qemudReportError(conn, NULL, NULL, VIR_ERR_INTERNAL_ERROR, "%s", _("unsupported architecture")); goto error; } if (strlen(defaultArch) >= (QEMUD_OS_TYPE_MAX_LEN-1)) { qemudReportError(conn, NULL, NULL, VIR_ERR_INTERNAL_ERROR, "%s", _("architecture type too long")); goto error; } strcpy(def->os.arch, defaultArch); } else { if (strlen((const char *)obj->stringval) >= (QEMUD_OS_TYPE_MAX_LEN-1)) { qemudReportError(conn, NULL, NULL, VIR_ERR_INTERNAL_ERROR, "%s", _("architecture type too long")); goto error; } strcpy(def->os.arch, (const char *)obj->stringval); } xmlXPathFreeObject(obj); obj = xmlXPathEval(BAD_CAST "string(/domain/os/type[1]/@machine)", ctxt); if ((obj == NULL) || (obj->type != XPATH_STRING) || (obj->stringval == NULL) || (obj->stringval[0] == 0)) { const char *defaultMachine = virCapabilitiesDefaultGuestMachine(driver->caps, def->os.type, def->os.arch); if (defaultMachine == NULL) { qemudReportError(conn, NULL, NULL, VIR_ERR_INTERNAL_ERROR, "%s", _("unsupported architecture")); goto error; } if (strlen(defaultMachine) >= (QEMUD_OS_MACHINE_MAX_LEN-1)) { qemudReportError(conn, NULL, NULL, VIR_ERR_INTERNAL_ERROR, "%s", _("machine type too long")); goto error; } strcpy(def->os.machine, defaultMachine); } else { if (strlen((const char *)obj->stringval) >= (QEMUD_OS_MACHINE_MAX_LEN-1)) { qemudReportError(conn, NULL, NULL, VIR_ERR_INTERNAL_ERROR, "%s", _("architecture type too long")); goto error; } strcpy(def->os.machine, (const char *)obj->stringval); } xmlXPathFreeObject(obj); if (!def->os.bootloader[0]) { obj = xmlXPathEval(BAD_CAST "string(/domain/os/kernel[1])", ctxt); if ((obj != NULL) && (obj->type == XPATH_STRING) && (obj->stringval != NULL) && (obj->stringval[0] != 0)) { if (strlen((const char *)obj->stringval) >= (PATH_MAX-1)) { qemudReportError(conn, NULL, NULL, VIR_ERR_INTERNAL_ERROR, "%s", _("kernel path too long")); goto error; } strcpy(def->os.kernel, (const char *)obj->stringval); } xmlXPathFreeObject(obj); obj = xmlXPathEval(BAD_CAST "string(/domain/os/initrd[1])", ctxt); if ((obj != NULL) && (obj->type == XPATH_STRING) && (obj->stringval != NULL) && (obj->stringval[0] != 0)) { if (strlen((const char *)obj->stringval) >= (PATH_MAX-1)) { qemudReportError(conn, NULL, NULL, VIR_ERR_INTERNAL_ERROR, "%s", _("initrd path too long")); goto error; } strcpy(def->os.initrd, (const char *)obj->stringval); } xmlXPathFreeObject(obj); obj = xmlXPathEval(BAD_CAST "string(/domain/os/cmdline[1])", ctxt); if ((obj != NULL) && (obj->type == XPATH_STRING) && (obj->stringval != NULL) && (obj->stringval[0] != 0)) { if (strlen((const char *)obj->stringval) >= (PATH_MAX-1)) { qemudReportError(conn, NULL, NULL, VIR_ERR_INTERNAL_ERROR, "%s", _("cmdline arguments too long")); goto error; } strcpy(def->os.cmdline, (const char *)obj->stringval); } xmlXPathFreeObject(obj); /* analysis of the disk devices */ obj = xmlXPathEval(BAD_CAST "/domain/os/boot", ctxt); if ((obj != NULL) && (obj->type == XPATH_NODESET) && (obj->nodesetval != NULL) && (obj->nodesetval->nodeNr >= 0)) { for (i = 0; i < obj->nodesetval->nodeNr && i < QEMUD_MAX_BOOT_DEVS ; i++) { if (!(prop = xmlGetProp(obj->nodesetval->nodeTab[i], BAD_CAST "dev"))) continue; if (STREQ((char *)prop, "hd")) { def->os.bootDevs[def->os.nBootDevs++] = QEMUD_BOOT_DISK; } else if (STREQ((char *)prop, "fd")) { def->os.bootDevs[def->os.nBootDevs++] = QEMUD_BOOT_FLOPPY; } else if (STREQ((char *)prop, "cdrom")) { def->os.bootDevs[def->os.nBootDevs++] = QEMUD_BOOT_CDROM; } else if (STREQ((char *)prop, "network")) { def->os.bootDevs[def->os.nBootDevs++] = QEMUD_BOOT_NET; } else { qemudReportError(conn, NULL, NULL, VIR_ERR_INTERNAL_ERROR, _("unknown boot device \'%s\'"), (char*)prop); goto error; } xmlFree(prop); prop = NULL; } } xmlXPathFreeObject(obj); if (def->os.nBootDevs == 0) { def->os.nBootDevs = 1; def->os.bootDevs[0] = QEMUD_BOOT_DISK; } } obj = xmlXPathEval(BAD_CAST "string(/domain/devices/emulator[1])", ctxt); if ((obj == NULL) || (obj->type != XPATH_STRING) || (obj->stringval == NULL) || (obj->stringval[0] == 0)) { const char *type = qemudVirtTypeToString(def->virtType); if (!type) { qemudReportError(conn, NULL, NULL, VIR_ERR_INTERNAL_ERROR, "%s", _("unknown virt type")); goto error; } const char *emulator = virCapabilitiesDefaultGuestEmulator(driver->caps, def->os.type, def->os.arch, type); if (!emulator) { qemudReportError(conn, NULL, NULL, VIR_ERR_INTERNAL_ERROR, "%s", _("unsupported guest type")); goto error; } strcpy(def->os.binary, emulator); } else { if (strlen((const char *)obj->stringval) >= (PATH_MAX-1)) { qemudReportError(conn, NULL, NULL, VIR_ERR_INTERNAL_ERROR, "%s", _("emulator path too long")); goto error; } strcpy(def->os.binary, (const char *)obj->stringval); } xmlXPathFreeObject(obj); obj = xmlXPathEval(BAD_CAST "/domain/devices/graphics", ctxt); if ((obj == NULL) || (obj->type != XPATH_NODESET) || (obj->nodesetval == NULL) || (obj->nodesetval->nodeNr == 0)) { def->graphicsType = QEMUD_GRAPHICS_NONE; } else if ((prop = xmlGetProp(obj->nodesetval->nodeTab[0], BAD_CAST "type"))) { if (STREQ((char *)prop, "vnc")) { xmlChar *vncport, *vnclisten; def->graphicsType = QEMUD_GRAPHICS_VNC; vncport = xmlGetProp(obj->nodesetval->nodeTab[0], BAD_CAST "port"); if (vncport) { conv = NULL; def->vncPort = strtoll((const char*)vncport, &conv, 10); } else { def->vncPort = -1; } vnclisten = xmlGetProp(obj->nodesetval->nodeTab[0], BAD_CAST "listen"); if (vnclisten && *vnclisten) strncpy(def->vncListen, (char *)vnclisten, BR_INET_ADDR_MAXLEN-1); else strcpy(def->vncListen, driver->vncListen); def->vncListen[BR_INET_ADDR_MAXLEN-1] = '\0'; def->keymap = (char *) xmlGetProp(obj->nodesetval->nodeTab[0], BAD_CAST "keymap"); xmlFree(vncport); xmlFree(vnclisten); } else if (STREQ((char *)prop, "sdl")) { def->graphicsType = QEMUD_GRAPHICS_SDL; } else { qemudReportError(conn, NULL, NULL, VIR_ERR_INTERNAL_ERROR, _("Unsupported graphics type %s"), prop); goto error; } xmlFree(prop); prop = NULL; } xmlXPathFreeObject(obj); /* analysis of the disk devices */ obj = xmlXPathEval(BAD_CAST "/domain/devices/disk", ctxt); if ((obj != NULL) && (obj->type == XPATH_NODESET) && (obj->nodesetval != NULL) && (obj->nodesetval->nodeNr >= 0)) { for (i = 0; i < obj->nodesetval->nodeNr; i++) { struct qemud_vm_disk_def *disk = calloc(1, sizeof(*disk)); if (!disk) { qemudReportError(conn, NULL, NULL, VIR_ERR_NO_MEMORY, "%s", _("failed to allocate space for disk string")); goto error; } if (qemudParseDiskXML(conn, disk, obj->nodesetval->nodeTab[i]) < 0) { free(disk); goto error; } def->ndisks++; if (i == 0) { disk->next = NULL; def->disks = disk; } else { struct qemud_vm_disk_def *ptr = def->disks; while (ptr) { if (!ptr->next || qemudDiskCompare(disk, ptr->next) < 0) { disk->next = ptr->next; ptr->next = disk; break; } ptr = ptr->next; } } } } xmlXPathFreeObject(obj); obj = NULL; /* analysis of the character devices */ if (qemudParseCharXMLDevices(conn, ctxt, "/domain/devices/parallel", &def->nparallels, &def->parallels) < 0) goto error; if (qemudParseCharXMLDevices(conn, ctxt, "/domain/devices/serial", &def->nserials, &def->serials) < 0) goto error; /* * If no serial devices were listed, then look for console * devices which is the legacy syntax for the same thing */ if (def->nserials == 0) { obj = xmlXPathEval(BAD_CAST "/domain/devices/console", ctxt); if ((obj != NULL) && (obj->type == XPATH_NODESET) && (obj->nodesetval != NULL) && (obj->nodesetval->nodeNr == 1)) { struct qemud_vm_chr_def *chr = calloc(1, sizeof(*chr)); if (!chr) { qemudReportError(conn, NULL, NULL, VIR_ERR_NO_MEMORY, "%s", _("failed to allocate space for char device")); goto error; } if (qemudParseCharXML(conn, chr, 0, obj->nodesetval->nodeTab[0]) < 0) { free(chr); goto error; } def->nserials = 1; def->serials = chr; } xmlXPathFreeObject(obj); } /* analysis of the network devices */ obj = xmlXPathEval(BAD_CAST "/domain/devices/interface", ctxt); if ((obj != NULL) && (obj->type == XPATH_NODESET) && (obj->nodesetval != NULL) && (obj->nodesetval->nodeNr >= 0)) { struct qemud_vm_net_def *prev = NULL; for (i = 0; i < obj->nodesetval->nodeNr; i++) { struct qemud_vm_net_def *net = calloc(1, sizeof(*net)); if (!net) { qemudReportError(conn, NULL, NULL, VIR_ERR_NO_MEMORY, "%s", _("failed to allocate space for net string")); goto error; } if (qemudParseInterfaceXML(conn, net, obj->nodesetval->nodeTab[i]) < 0) { free(net); goto error; } def->nnets++; net->next = NULL; if (i == 0) { def->nets = net; } else { prev->next = net; } prev = net; } } xmlXPathFreeObject(obj); /* analysis of the input devices */ obj = xmlXPathEval(BAD_CAST "/domain/devices/input", ctxt); if ((obj != NULL) && (obj->type == XPATH_NODESET) && (obj->nodesetval != NULL) && (obj->nodesetval->nodeNr >= 0)) { struct qemud_vm_input_def *prev = NULL; for (i = 0; i < obj->nodesetval->nodeNr; i++) { struct qemud_vm_input_def *input = calloc(1, sizeof(*input)); if (!input) { qemudReportError(conn, NULL, NULL, VIR_ERR_NO_MEMORY, "%s", _("failed to allocate space for input string")); goto error; } if (qemudParseInputXML(conn, def, input, obj->nodesetval->nodeTab[i]) < 0) { free(input); goto error; } /* Mouse + PS/2 is implicit with graphics, so don't store it */ if (input->bus == QEMU_INPUT_BUS_PS2 && input->type == QEMU_INPUT_TYPE_MOUSE) { free(input); continue; } def->ninputs++; input->next = NULL; if (def->inputs == NULL) { def->inputs = input; } else { prev->next = input; } prev = input; } } xmlXPathFreeObject(obj); /* Parse sound driver xml */ obj = xmlXPathEval(BAD_CAST "/domain/devices/sound", ctxt); if ((obj != NULL) && (obj->type == XPATH_NODESET) && (obj->nodesetval != NULL) && (obj->nodesetval->nodeNr >= 0)) { struct qemud_vm_sound_def *prev = NULL; for (i = 0; i < obj->nodesetval->nodeNr; i++) { struct qemud_vm_sound_def *sound = calloc(1, sizeof(*sound)); struct qemud_vm_sound_def *check = def->sounds; int collision = 0; if (!sound) { qemudReportError(conn, NULL, NULL, VIR_ERR_NO_MEMORY, "%s", _("failed to allocate space for sound dev")); goto error; } if (qemudParseSoundXML(conn, sound, obj->nodesetval->nodeTab[i]) < 0) { free(sound); goto error; } // Check that model type isn't already present in sound dev list while(check) { if (check->model == sound->model) { collision = 1; break; } check = check->next; } if (collision) continue; def->nsounds++; sound->next = NULL; if (def->sounds == NULL) { def->sounds = sound; } else { prev->next = sound; } prev = sound; } } xmlXPathFreeObject(obj); obj = NULL; /* If graphics are enabled, there's an implicit PS2 mouse */ if (def->graphicsType != QEMUD_GRAPHICS_NONE) { int hasPS2mouse = 0; struct qemud_vm_input_def *input = def->inputs; while (input) { if (input->type == QEMU_INPUT_TYPE_MOUSE && input->bus == QEMU_INPUT_BUS_PS2) hasPS2mouse = 1; input = input->next; } if (!hasPS2mouse) { input = calloc(1, sizeof(*input)); if (!input) { qemudReportError(conn, NULL, NULL, VIR_ERR_NO_MEMORY, "%s", _("failed to allocate space for input string")); goto error; } input->type = QEMU_INPUT_TYPE_MOUSE; input->bus = QEMU_INPUT_BUS_PS2; input->next = def->inputs; def->inputs = input; def->ninputs++; } } xmlXPathFreeContext(ctxt); return def; error: free(prop); xmlXPathFreeObject(obj); xmlXPathFreeContext(ctxt); qemudFreeVMDef(def); return NULL; } static char * qemudNetworkIfaceConnect(virConnectPtr conn, struct qemud_driver *driver, struct qemud_vm *vm, struct qemud_vm_net_def *net, int vlan) { struct qemud_network *network = NULL; char *brname; char *ifname; char tapfdstr[4+3+32+7]; char *retval = NULL; int err; int tapfd = -1; int *tapfds; if (net->type == QEMUD_NET_NETWORK) { if (!(network = qemudFindNetworkByName(driver, net->dst.network.name))) { qemudReportError(conn, NULL, NULL, VIR_ERR_INTERNAL_ERROR, _("Network '%s' not found"), net->dst.network.name); goto error; } else if (network->bridge[0] == '\0') { qemudReportError(conn, NULL, NULL, VIR_ERR_INTERNAL_ERROR, _("Network '%s' not active"), net->dst.network.name); goto error; } brname = network->bridge; if (net->dst.network.ifname[0] == '\0' || STRPREFIX(net->dst.network.ifname, "vnet") || strchr(net->dst.network.ifname, '%')) { strcpy(net->dst.network.ifname, "vnet%d"); } ifname = net->dst.network.ifname; } else if (net->type == QEMUD_NET_BRIDGE) { brname = net->dst.bridge.brname; if (net->dst.bridge.ifname[0] == '\0' || STRPREFIX(net->dst.bridge.ifname, "vnet") || strchr(net->dst.bridge.ifname, '%')) { strcpy(net->dst.bridge.ifname, "vnet%d"); } ifname = net->dst.bridge.ifname; } else { qemudReportError(conn, NULL, NULL, VIR_ERR_INTERNAL_ERROR, _("Network type %d is not supported"), net->type); goto error; } if (!driver->brctl && (err = brInit(&driver->brctl))) { qemudReportError(conn, NULL, NULL, VIR_ERR_INTERNAL_ERROR, _("cannot initialize bridge support: %s"), strerror(err)); goto error; } if ((err = brAddTap(driver->brctl, brname, ifname, BR_IFNAME_MAXLEN, &tapfd))) { qemudReportError(conn, NULL, NULL, VIR_ERR_INTERNAL_ERROR, _("Failed to add tap interface '%s' to bridge '%s' : %s"), ifname, brname, strerror(err)); goto error; } snprintf(tapfdstr, sizeof(tapfdstr), "tap,fd=%d,script=,vlan=%d,ifname=%s", tapfd, vlan, ifname); if (!(retval = strdup(tapfdstr))) goto no_memory; if (!(tapfds = realloc(vm->tapfds, sizeof(*tapfds) * (vm->ntapfds+2)))) goto no_memory; vm->tapfds = tapfds; vm->tapfds[vm->ntapfds++] = tapfd; vm->tapfds[vm->ntapfds] = -1; return retval; no_memory: qemudReportError(conn, NULL, NULL, VIR_ERR_NO_MEMORY, "%s", _("failed to allocate space for tapfds string")); error: free(retval); if (tapfd != -1) close(tapfd); return NULL; } static int qemudBuildCommandLineChrDevStr(struct qemud_vm_chr_def *dev, char *buf, int buflen) { switch (dev->srcType) { case QEMUD_CHR_SRC_TYPE_NULL: strncpy(buf, "null", buflen); buf[buflen-1] = '\0'; break; case QEMUD_CHR_SRC_TYPE_VC: strncpy(buf, "vc", buflen); buf[buflen-1] = '\0'; break; case QEMUD_CHR_SRC_TYPE_PTY: strncpy(buf, "pty", buflen); buf[buflen-1] = '\0'; break; case QEMUD_CHR_SRC_TYPE_DEV: if (snprintf(buf, buflen, "%s", dev->srcData.file.path) >= buflen) return -1; break; case QEMUD_CHR_SRC_TYPE_FILE: if (snprintf(buf, buflen, "file:%s", dev->srcData.file.path) >= buflen) return -1; break; case QEMUD_CHR_SRC_TYPE_PIPE: if (snprintf(buf, buflen, "pipe:%s", dev->srcData.file.path) >= buflen) return -1; break; case QEMUD_CHR_SRC_TYPE_STDIO: strncpy(buf, "stdio", buflen); buf[buflen-1] = '\0'; break; case QEMUD_CHR_SRC_TYPE_UDP: if (snprintf(buf, buflen, "udp:%s:%s@%s:%s", dev->srcData.udp.connectHost, dev->srcData.udp.connectService, dev->srcData.udp.bindHost, dev->srcData.udp.bindService) >= buflen) return -1; break; case QEMUD_CHR_SRC_TYPE_TCP: if (snprintf(buf, buflen, "%s:%s:%s%s", dev->srcData.tcp.protocol == QEMUD_CHR_SRC_TCP_PROTOCOL_TELNET ? "telnet" : "tcp", dev->srcData.tcp.host, dev->srcData.tcp.service, dev->srcData.tcp.listen ? ",listen" : "") >= buflen) return -1; break; case QEMUD_CHR_SRC_TYPE_UNIX: if (snprintf(buf, buflen, "unix:%s%s", dev->srcData.nix.path, dev->srcData.nix.listen ? ",listen" : "") >= buflen) return -1; break; } return 0; } /* * Constructs a argv suitable for launching qemu with config defined * for a given virtual machine. */ int qemudBuildCommandLine(virConnectPtr conn, struct qemud_driver *driver, struct qemud_vm *vm, char ***retargv) { int i; char memory[50]; char vcpus[50]; char boot[QEMUD_MAX_BOOT_DEVS+1]; struct qemud_vm_disk_def *disk = vm->def->disks; struct qemud_vm_net_def *net = vm->def->nets; struct qemud_vm_input_def *input = vm->def->inputs; struct qemud_vm_sound_def *sound = vm->def->sounds; struct qemud_vm_chr_def *serial = vm->def->serials; struct qemud_vm_chr_def *parallel = vm->def->parallels; struct utsname ut; int disableKQEMU = 0; int qargc = 0, qarga = 0; char **qargv = NULL; if (vm->qemuVersion == 0) { if (qemudExtractVersionInfo(vm->def->os.binary, &(vm->qemuVersion), &(vm->qemuCmdFlags)) < 0) return -1; } uname(&ut); /* Nasty hack make i?86 look like i686 to simplify next comparison */ if (ut.machine[0] == 'i' && ut.machine[2] == '8' && ut.machine[3] == '6' && !ut.machine[4]) ut.machine[1] = '6'; /* Need to explicitly disable KQEMU if * 1. Arch matches host arch * 2. Guest is 'qemu' * 3. The qemu binary has the -no-kqemu flag */ if ((vm->qemuCmdFlags & QEMUD_CMD_FLAG_KQEMU) && STREQ(ut.machine, vm->def->os.arch) && vm->def->virtType == QEMUD_VIRT_QEMU) disableKQEMU = 1; #define ADD_ARG_SPACE \ do { \ if (qargc == qarga) { \ qarga += 10; \ if (VIR_REALLOC_N(qargv, qarga) < 0) \ goto no_memory; \ } \ } while (0) #define ADD_ARG(thisarg) \ do { \ ADD_ARG_SPACE; \ qargv[qargc++] = thisarg; \ } while (0) #define ADD_ARG_LIT(thisarg) \ do { \ ADD_ARG_SPACE; \ if ((qargv[qargc++] = strdup(thisarg)) == NULL) \ goto no_memory; \ } while (0) snprintf(memory, sizeof(memory), "%lu", vm->def->memory/1024); snprintf(vcpus, sizeof(vcpus), "%d", vm->def->vcpus); ADD_ARG_LIT(vm->def->os.binary); ADD_ARG_LIT("-S"); ADD_ARG_LIT("-M"); ADD_ARG_LIT(vm->def->os.machine); if (disableKQEMU) ADD_ARG_LIT("-no-kqemu"); ADD_ARG_LIT("-m"); ADD_ARG_LIT(memory); ADD_ARG_LIT("-smp"); ADD_ARG_LIT(vcpus); if (vm->qemuCmdFlags & QEMUD_CMD_FLAG_NAME) { ADD_ARG_LIT("-name"); ADD_ARG_LIT(vm->def->name); } /* * NB, -nographic *MUST* come before any serial, or monitor * or parallel port flags due to QEMU craziness, where it * decides to change the serial port & monitor to be on stdout * if you ask for nographic. So we have to make sure we override * these defaults ourselves... */ if (vm->def->graphicsType == QEMUD_GRAPHICS_NONE) ADD_ARG_LIT("-nographic"); ADD_ARG_LIT("-monitor"); ADD_ARG_LIT("pty"); if (vm->def->localtime) ADD_ARG_LIT("-localtime"); if ((vm->qemuCmdFlags & QEMUD_CMD_FLAG_NO_REBOOT) && vm->def->noReboot) ADD_ARG_LIT("-no-reboot"); if (!(vm->def->features & QEMUD_FEATURE_ACPI)) ADD_ARG_LIT("-no-acpi"); if (!vm->def->os.bootloader[0]) { for (i = 0 ; i < vm->def->os.nBootDevs ; i++) { switch (vm->def->os.bootDevs[i]) { case QEMUD_BOOT_CDROM: boot[i] = 'd'; break; case QEMUD_BOOT_FLOPPY: boot[i] = 'a'; break; case QEMUD_BOOT_DISK: boot[i] = 'c'; break; case QEMUD_BOOT_NET: boot[i] = 'n'; break; default: boot[i] = 'c'; break; } } boot[vm->def->os.nBootDevs] = '\0'; ADD_ARG_LIT("-boot"); ADD_ARG_LIT(boot); if (vm->def->os.kernel[0]) { ADD_ARG_LIT("-kernel"); ADD_ARG_LIT(vm->def->os.kernel); } if (vm->def->os.initrd[0]) { ADD_ARG_LIT("-initrd"); ADD_ARG_LIT(vm->def->os.initrd); } if (vm->def->os.cmdline[0]) { ADD_ARG_LIT("-append"); ADD_ARG_LIT(vm->def->os.cmdline); } } else { ADD_ARG_LIT("-bootloader"); ADD_ARG_LIT(vm->def->os.bootloader); } /* If QEMU supports -drive param instead of old -hda, -hdb, -cdrom .. */ if (vm->qemuCmdFlags & QEMUD_CMD_FLAG_DRIVE) { int bootCD = 0, bootFloppy = 0, bootDisk = 0; /* If QEMU supports boot=on for -drive param... */ if (vm->qemuCmdFlags & QEMUD_CMD_FLAG_DRIVE_BOOT) { for (i = 0 ; i < vm->def->os.nBootDevs ; i++) { switch (vm->def->os.bootDevs[i]) { case QEMUD_BOOT_CDROM: bootCD = 1; break; case QEMUD_BOOT_FLOPPY: bootFloppy = 1; break; case QEMUD_BOOT_DISK: bootDisk = 1; break; } } } while (disk) { char opt[PATH_MAX]; const char *media = NULL; int bootable = 0; int idx = virDiskNameToIndex(disk->dst); if (idx < 0) { qemudReportError(conn, NULL, NULL, VIR_ERR_INTERNAL_ERROR, _("unsupported disk type '%s'"), disk->dst); goto error; } if (disk->device == QEMUD_DISK_CDROM) media = "media=cdrom,"; switch (disk->device) { case QEMUD_DISK_CDROM: bootable = bootCD; bootCD = 0; break; case QEMUD_DISK_FLOPPY: bootable = bootFloppy; bootFloppy = 0; break; case QEMUD_DISK_DISK: bootable = bootDisk; bootDisk = 0; break; } snprintf(opt, PATH_MAX, "file=%s,if=%s,%sindex=%d%s", disk->src, qemudBusIdToName(disk->bus, 1), media ? media : "", idx, bootable ? ",boot=on" : ""); ADD_ARG_LIT("-drive"); ADD_ARG_LIT(opt); disk = disk->next; } } else { while (disk) { char dev[NAME_MAX]; char file[PATH_MAX]; if (STREQ(disk->dst, "hdc") && disk->device == QEMUD_DISK_CDROM) { if (disk->src[0]) { snprintf(dev, NAME_MAX, "-%s", "cdrom"); } else { disk = disk->next; continue; } } else { if (STRPREFIX(disk->dst, "hd") || STRPREFIX(disk->dst, "fd")) { snprintf(dev, NAME_MAX, "-%s", disk->dst); } else { qemudReportError(conn, NULL, NULL, VIR_ERR_INTERNAL_ERROR, _("unsupported disk type '%s'"), disk->dst); goto error; } } snprintf(file, PATH_MAX, "%s", disk->src); ADD_ARG_LIT(dev); ADD_ARG_LIT(file); disk = disk->next; } } if (!net) { ADD_ARG_LIT("-net"); ADD_ARG_LIT("none"); } else { int vlan = 0; while (net) { char nic[100]; if (snprintf(nic, sizeof(nic), "nic,macaddr=%02x:%02x:%02x:%02x:%02x:%02x,vlan=%d%s%s", net->mac[0], net->mac[1], net->mac[2], net->mac[3], net->mac[4], net->mac[5], vlan, (net->model[0] ? ",model=" : ""), net->model) >= sizeof(nic)) goto error; ADD_ARG_LIT("-net"); ADD_ARG_LIT(nic); ADD_ARG_LIT("-net"); switch (net->type) { case QEMUD_NET_NETWORK: case QEMUD_NET_BRIDGE: ADD_ARG(qemudNetworkIfaceConnect(conn, driver, vm, net, vlan)); break; case QEMUD_NET_ETHERNET: { char arg[PATH_MAX]; if (snprintf(arg, PATH_MAX-1, "tap,ifname=%s,script=%s,vlan=%d", net->dst.ethernet.ifname, net->dst.ethernet.script, vlan) >= (PATH_MAX-1)) goto error; ADD_ARG_LIT(arg); } break; case QEMUD_NET_CLIENT: case QEMUD_NET_SERVER: case QEMUD_NET_MCAST: { char arg[PATH_MAX]; const char *mode = NULL; switch (net->type) { case QEMUD_NET_CLIENT: mode = "connect"; break; case QEMUD_NET_SERVER: mode = "listen"; break; case QEMUD_NET_MCAST: mode = "mcast"; break; } if (snprintf(arg, PATH_MAX-1, "socket,%s=%s:%d,vlan=%d", mode, net->dst.socket.address, net->dst.socket.port, vlan) >= (PATH_MAX-1)) goto error; ADD_ARG_LIT(arg); } break; case QEMUD_NET_USER: default: { char arg[PATH_MAX]; if (snprintf(arg, PATH_MAX-1, "user,vlan=%d", vlan) >= (PATH_MAX-1)) goto error; ADD_ARG_LIT(arg); } } net = net->next; vlan++; } } if (!serial) { ADD_ARG_LIT("-serial"); ADD_ARG_LIT("none"); } else { while (serial) { char buf[4096]; if (qemudBuildCommandLineChrDevStr(serial, buf, sizeof(buf)) < 0) goto error; ADD_ARG_LIT("-serial"); ADD_ARG_LIT(buf); serial = serial->next; } } if (!parallel) { ADD_ARG_LIT("-parallel"); ADD_ARG_LIT("none"); } else { while (parallel) { char buf[4096]; if (qemudBuildCommandLineChrDevStr(parallel, buf, sizeof(buf)) < 0) goto error; ADD_ARG_LIT("-parallel"); ADD_ARG_LIT(buf); parallel = parallel->next; } } ADD_ARG_LIT("-usb"); while (input) { if (input->bus == QEMU_INPUT_BUS_USB) { ADD_ARG_LIT("-usbdevice"); ADD_ARG_LIT(input->type == QEMU_INPUT_TYPE_MOUSE ? "mouse" : "tablet"); } input = input->next; } if (vm->def->graphicsType == QEMUD_GRAPHICS_VNC) { char vncdisplay[PATH_MAX]; int ret; if (vm->qemuCmdFlags & QEMUD_CMD_FLAG_VNC_COLON) { char options[PATH_MAX] = ""; if (driver->vncTLS) { strcat(options, ",tls"); if (driver->vncTLSx509verify) { strcat(options, ",x509verify="); } else { strcat(options, ",x509="); } strncat(options, driver->vncTLSx509certdir, sizeof(options) - (strlen(driver->vncTLSx509certdir)-1)); options[sizeof(options)-1] = '\0'; } ret = snprintf(vncdisplay, sizeof(vncdisplay), "%s:%d%s", vm->def->vncListen, vm->def->vncActivePort - 5900, options); } else { ret = snprintf(vncdisplay, sizeof(vncdisplay), "%d", vm->def->vncActivePort - 5900); } if (ret < 0 || ret >= (int)sizeof(vncdisplay)) goto error; ADD_ARG_LIT("-vnc"); ADD_ARG_LIT(vncdisplay); if (vm->def->keymap) { ADD_ARG_LIT("-k"); ADD_ARG_LIT(vm->def->keymap); } } else if (vm->def->graphicsType == QEMUD_GRAPHICS_NONE) { /* Nada - we added -nographic earlier in this function */ } else { /* SDL is the default. no args needed */ } /* Add sound hardware */ if (sound) { int size = 100; char *modstr = calloc(1, size+1); if (!modstr) goto no_memory; while(sound && size > 0) { const char *model = qemudSoundModelToString(sound->model); if (!model) { free(modstr); qemudReportError(conn, NULL, NULL, VIR_ERR_INTERNAL_ERROR, "%s", _("invalid sound model")); goto error; } strncat(modstr, model, size); size -= strlen(model); sound = sound->next; if (sound) strncat(modstr, ",", size--); } ADD_ARG_LIT("-soundhw"); ADD_ARG(modstr); } if (vm->migrateFrom[0]) { ADD_ARG_LIT("-incoming"); ADD_ARG_LIT(vm->migrateFrom); } ADD_ARG(NULL); *retargv = qargv; return 0; no_memory: qemudReportError(conn, NULL, NULL, VIR_ERR_NO_MEMORY, "%s", _("failed to allocate space for argv string")); error: if (vm->tapfds) { for (i = 0; vm->tapfds[i] != -1; i++) close(vm->tapfds[i]); free(vm->tapfds); vm->tapfds = NULL; vm->ntapfds = 0; } if (qargv) { for (i = 0 ; i < qargc ; i++) free((qargv)[i]); free(qargv); } return -1; #undef ADD_ARG #undef ADD_ARG_LIT #undef ADD_ARG_SPACE } /* Save a guest's config data into a persistent file */ static int qemudSaveConfig(virConnectPtr conn, struct qemud_driver *driver, struct qemud_vm *vm, struct qemud_vm_def *def) { char *xml; int fd = -1, ret = -1; int towrite; if (!(xml = qemudGenerateXML(conn, driver, vm, def, 0))) return -1; if ((fd = open(vm->configFile, O_WRONLY | O_CREAT | O_TRUNC, S_IRUSR | S_IWUSR )) < 0) { qemudReportError(conn, NULL, NULL, VIR_ERR_INTERNAL_ERROR, _("cannot create config file %s: %s"), vm->configFile, strerror(errno)); goto cleanup; } towrite = strlen(xml); if (safewrite(fd, xml, towrite) < 0) { qemudReportError(conn, NULL, NULL, VIR_ERR_INTERNAL_ERROR, _("cannot write config file %s: %s"), vm->configFile, strerror(errno)); goto cleanup; } if (close(fd) < 0) { qemudReportError(conn, NULL, NULL, VIR_ERR_INTERNAL_ERROR, _("cannot save config file %s: %s"), vm->configFile, strerror(errno)); goto cleanup; } ret = 0; cleanup: if (fd != -1) close(fd); free(xml); return ret; } struct qemud_vm_device_def * qemudParseVMDeviceDef(virConnectPtr conn, const struct qemud_vm_def *def, const char *xmlStr) { xmlDocPtr xml; xmlNodePtr node; struct qemud_vm_device_def *dev = calloc(1, sizeof(*dev)); if (!(xml = xmlReadDoc(BAD_CAST xmlStr, "device.xml", NULL, XML_PARSE_NOENT | XML_PARSE_NONET | XML_PARSE_NOERROR | XML_PARSE_NOWARNING))) { qemudReportError(conn, NULL, NULL, VIR_ERR_XML_ERROR, NULL); return NULL; } node = xmlDocGetRootElement(xml); if (node == NULL) { qemudReportError(conn, NULL, NULL, VIR_ERR_XML_ERROR, "%s", _("missing root element")); goto error; } if (xmlStrEqual(node->name, BAD_CAST "disk")) { dev->type = QEMUD_DEVICE_DISK; qemudParseDiskXML(conn, &(dev->data.disk), node); } else if (xmlStrEqual(node->name, BAD_CAST "net")) { dev->type = QEMUD_DEVICE_NET; qemudParseInterfaceXML(conn, &(dev->data.net), node); } else if (xmlStrEqual(node->name, BAD_CAST "input")) { dev->type = QEMUD_DEVICE_DISK; qemudParseInputXML(conn, def, &(dev->data.input), node); } else if (xmlStrEqual(node->name, BAD_CAST "sound")) { dev->type = QEMUD_DEVICE_SOUND; qemudParseSoundXML(conn, &(dev->data.sound), node); } else { qemudReportError(conn, NULL, NULL, VIR_ERR_XML_ERROR, "%s", _("unknown device type")); goto error; } xmlFreeDoc(xml); return dev; error: if (xml) xmlFreeDoc(xml); free(dev); return NULL; } struct qemud_vm_def * qemudParseVMDef(virConnectPtr conn, struct qemud_driver *driver, const char *xmlStr, const char *displayName) { xmlDocPtr xml; struct qemud_vm_def *def = NULL; if (!(xml = xmlReadDoc(BAD_CAST xmlStr, displayName ? displayName : "domain.xml", NULL, XML_PARSE_NOENT | XML_PARSE_NONET | XML_PARSE_NOERROR | XML_PARSE_NOWARNING))) { qemudReportError(conn, NULL, NULL, VIR_ERR_XML_ERROR, NULL); return NULL; } def = qemudParseXML(conn, driver, xml); xmlFreeDoc(xml); return def; } struct qemud_vm * qemudAssignVMDef(virConnectPtr conn, struct qemud_driver *driver, struct qemud_vm_def *def) { struct qemud_vm *vm = NULL; if ((vm = qemudFindVMByName(driver, def->name))) { if (!qemudIsActiveVM(vm)) { qemudFreeVMDef(vm->def); vm->def = def; } else { if (vm->newDef) qemudFreeVMDef(vm->newDef); vm->newDef = def; } /* Reset version, because the emulator path might have changed */ vm->qemuVersion = 0; vm->qemuCmdFlags = 0; return vm; } if (!(vm = calloc(1, sizeof(*vm)))) { qemudReportError(conn, NULL, NULL, VIR_ERR_NO_MEMORY, "%s", _("failed to allocate space for vm string")); return NULL; } vm->stdin = -1; vm->stdout = -1; vm->stderr = -1; vm->monitor = -1; vm->pid = -1; vm->id = -1; vm->state = VIR_DOMAIN_SHUTOFF; vm->def = def; vm->next = driver->vms; driver->vms = vm; driver->ninactivevms++; return vm; } void qemudRemoveInactiveVM(struct qemud_driver *driver, struct qemud_vm *vm) { struct qemud_vm *prev = NULL, *curr; curr = driver->vms; while (curr != vm) { prev = curr; curr = curr->next; } if (curr) { if (prev) prev->next = curr->next; else driver->vms = curr->next; driver->ninactivevms--; } qemudFreeVM(vm); } int qemudSaveVMDef(virConnectPtr conn, struct qemud_driver *driver, struct qemud_vm *vm, struct qemud_vm_def *def) { if (vm->configFile[0] == '\0') { int err; if ((err = virFileMakePath(driver->configDir))) { qemudReportError(conn, NULL, NULL, VIR_ERR_INTERNAL_ERROR, _("cannot create config directory %s: %s"), driver->configDir, strerror(err)); return -1; } if (virFileBuildPath(driver->configDir, def->name, ".xml", vm->configFile, PATH_MAX) < 0) { qemudReportError(conn, NULL, NULL, VIR_ERR_INTERNAL_ERROR, "%s", _("cannot construct config file path")); return -1; } if (virFileBuildPath(driver->autostartDir, def->name, ".xml", vm->autostartLink, PATH_MAX) < 0) { qemudReportError(conn, NULL, NULL, VIR_ERR_INTERNAL_ERROR, "%s", _("cannot construct autostart link path")); vm->configFile[0] = '\0'; return -1; } } return qemudSaveConfig(conn, driver, vm, def); } static int qemudSaveNetworkConfig(virConnectPtr conn, struct qemud_driver *driver, struct qemud_network *network, struct qemud_network_def *def) { char *xml; int fd, ret = -1; int towrite; int err; if (!(xml = qemudGenerateNetworkXML(conn, driver, network, def))) { return -1; } if ((err = virFileMakePath(driver->networkConfigDir))) { qemudReportError(conn, NULL, NULL, VIR_ERR_INTERNAL_ERROR, _("cannot create config directory %s: %s"), driver->networkConfigDir, strerror(err)); goto cleanup; } if ((fd = open(network->configFile, O_WRONLY | O_CREAT | O_TRUNC, S_IRUSR | S_IWUSR )) < 0) { qemudReportError(conn, NULL, NULL, VIR_ERR_INTERNAL_ERROR, _("cannot create config file %s: %s"), network->configFile, strerror(errno)); goto cleanup; } towrite = strlen(xml); if (safewrite(fd, xml, towrite) < 0) { qemudReportError(conn, NULL, NULL, VIR_ERR_INTERNAL_ERROR, _("cannot write config file %s: %s"), network->configFile, strerror(errno)); goto cleanup; } if (close(fd) < 0) { qemudReportError(conn, NULL, NULL, VIR_ERR_INTERNAL_ERROR, _("cannot save config file %s: %s"), network->configFile, strerror(errno)); goto cleanup; } ret = 0; cleanup: free(xml); return ret; } void qemudFreeNetworkDef(struct qemud_network_def *def) { struct qemud_dhcp_range_def *range = def->ranges; while (range) { struct qemud_dhcp_range_def *next = range->next; free(range); range = next; } free(def); } void qemudFreeNetwork(struct qemud_network *network) { qemudFreeNetworkDef(network->def); if (network->newDef) qemudFreeNetworkDef(network->newDef); free(network); } static int qemudParseBridgeXML(struct qemud_driver *driver ATTRIBUTE_UNUSED, struct qemud_network_def *def, xmlNodePtr node) { xmlChar *name, *stp, *delay; name = xmlGetProp(node, BAD_CAST "name"); if (name != NULL) { strncpy(def->bridge, (const char *)name, IF_NAMESIZE-1); def->bridge[IF_NAMESIZE-1] = '\0'; xmlFree(name); name = NULL; } stp = xmlGetProp(node, BAD_CAST "stp"); if (stp != NULL) { if (xmlStrEqual(stp, BAD_CAST "off")) { def->disableSTP = 1; } xmlFree(stp); stp = NULL; } delay = xmlGetProp(node, BAD_CAST "delay"); if (delay != NULL) { def->forwardDelay = strtol((const char *)delay, NULL, 10); xmlFree(delay); delay = NULL; } return 1; } static int qemudParseDhcpRangesXML(virConnectPtr conn, struct qemud_driver *driver ATTRIBUTE_UNUSED, struct qemud_network_def *def, xmlNodePtr node) { xmlNodePtr cur; cur = node->children; while (cur != NULL) { struct qemud_dhcp_range_def *range; xmlChar *start, *end; if (cur->type != XML_ELEMENT_NODE || !xmlStrEqual(cur->name, BAD_CAST "range")) { cur = cur->next; continue; } if (!(range = calloc(1, sizeof(*range)))) { qemudReportError(conn, NULL, NULL, VIR_ERR_NO_MEMORY, "%s", _("failed to allocate space for range string")); return 0; } start = xmlGetProp(cur, BAD_CAST "start"); end = xmlGetProp(cur, BAD_CAST "end"); if (start && start[0] && end && end[0]) { strncpy(range->start, (const char *)start, BR_INET_ADDR_MAXLEN-1); range->start[BR_INET_ADDR_MAXLEN-1] = '\0'; strncpy(range->end, (const char *)end, BR_INET_ADDR_MAXLEN-1); range->end[BR_INET_ADDR_MAXLEN-1] = '\0'; range->next = def->ranges; def->ranges = range; def->nranges++; } else { free(range); } xmlFree(start); xmlFree(end); cur = cur->next; } return 1; } static int qemudParseInetXML(virConnectPtr conn, struct qemud_driver *driver ATTRIBUTE_UNUSED, struct qemud_network_def *def, xmlNodePtr node) { xmlChar *address, *netmask; xmlNodePtr cur; address = xmlGetProp(node, BAD_CAST "address"); if (address != NULL) { strncpy(def->ipAddress, (const char *)address, BR_INET_ADDR_MAXLEN-1); def->ipAddress[BR_INET_ADDR_MAXLEN-1] = '\0'; xmlFree(address); address = NULL; } netmask = xmlGetProp(node, BAD_CAST "netmask"); if (netmask != NULL) { strncpy(def->netmask, (const char *)netmask, BR_INET_ADDR_MAXLEN-1); def->netmask[BR_INET_ADDR_MAXLEN-1] = '\0'; xmlFree(netmask); netmask = NULL; } if (def->ipAddress[0] && def->netmask[0]) { struct in_addr inaddress, innetmask; char *netaddr; inet_aton((const char*)def->ipAddress, &inaddress); inet_aton((const char*)def->netmask, &innetmask); inaddress.s_addr &= innetmask.s_addr; netaddr = inet_ntoa(inaddress); snprintf(def->network,sizeof(def->network)-1, "%s/%s", netaddr, (const char *)def->netmask); } cur = node->children; while (cur != NULL) { if (cur->type == XML_ELEMENT_NODE && xmlStrEqual(cur->name, BAD_CAST "dhcp") && !qemudParseDhcpRangesXML(conn, driver, def, cur)) return 0; cur = cur->next; } return 1; } static struct qemud_network_def *qemudParseNetworkXML(virConnectPtr conn, struct qemud_driver *driver, xmlDocPtr xml) { xmlNodePtr root = NULL; xmlXPathContextPtr ctxt = NULL; xmlXPathObjectPtr obj = NULL, tmp = NULL; struct qemud_network_def *def; if (!(def = calloc(1, sizeof(*def)))) { qemudReportError(conn, NULL, NULL, VIR_ERR_NO_MEMORY, "%s", _("failed to allocate space for network_def string")); return NULL; } /* Prepare parser / xpath context */ root = xmlDocGetRootElement(xml); if ((root == NULL) || (!xmlStrEqual(root->name, BAD_CAST "network"))) { qemudReportError(conn, NULL, NULL, VIR_ERR_INTERNAL_ERROR, "%s", _("incorrect root element")); goto error; } ctxt = xmlXPathNewContext(xml); if (ctxt == NULL) { qemudReportError(conn, NULL, NULL, VIR_ERR_NO_MEMORY, "%s", _("failed to allocate space for xmlXPathContext string")); goto error; } /* Extract network name */ obj = xmlXPathEval(BAD_CAST "string(/network/name[1])", ctxt); if ((obj == NULL) || (obj->type != XPATH_STRING) || (obj->stringval == NULL) || (obj->stringval[0] == 0)) { qemudReportError(conn, NULL, NULL, VIR_ERR_NO_NAME, NULL); goto error; } if (strlen((const char *)obj->stringval) >= (QEMUD_MAX_NAME_LEN-1)) { qemudReportError(conn, NULL, NULL, VIR_ERR_INTERNAL_ERROR, "%s", _("network name length too long")); goto error; } strcpy(def->name, (const char *)obj->stringval); xmlXPathFreeObject(obj); /* Extract network uuid */ obj = xmlXPathEval(BAD_CAST "string(/network/uuid[1])", ctxt); if ((obj == NULL) || (obj->type != XPATH_STRING) || (obj->stringval == NULL) || (obj->stringval[0] == 0)) { int err; if ((err = virUUIDGenerate(def->uuid))) { qemudReportError(conn, NULL, NULL, VIR_ERR_INTERNAL_ERROR, _("Failed to generate UUID: %s"), strerror(err)); goto error; } } else if (virUUIDParse((const char *)obj->stringval, def->uuid) < 0) { qemudReportError(conn, NULL, NULL, VIR_ERR_INTERNAL_ERROR, "%s", _("malformed uuid element")); goto error; } xmlXPathFreeObject(obj); /* Parse bridge information */ obj = xmlXPathEval(BAD_CAST "/network/bridge[1]", ctxt); if ((obj != NULL) && (obj->type == XPATH_NODESET) && (obj->nodesetval != NULL) && (obj->nodesetval->nodeNr > 0)) { if (!qemudParseBridgeXML(driver, def, obj->nodesetval->nodeTab[0])) { goto error; } } xmlXPathFreeObject(obj); /* Parse IP information */ obj = xmlXPathEval(BAD_CAST "/network/ip[1]", ctxt); if ((obj != NULL) && (obj->type == XPATH_NODESET) && (obj->nodesetval != NULL) && (obj->nodesetval->nodeNr > 0)) { if (!qemudParseInetXML(conn, driver, def, obj->nodesetval->nodeTab[0])) { goto error; } } xmlXPathFreeObject(obj); /* IPv4 forwarding setup */ obj = xmlXPathEval(BAD_CAST "count(/network/forward) > 0", ctxt); if ((obj != NULL) && (obj->type == XPATH_BOOLEAN) && obj->boolval) { if (!def->ipAddress[0] || !def->netmask[0]) { qemudReportError(conn, NULL, NULL, VIR_ERR_INTERNAL_ERROR, "%s", _("Forwarding requested, but no IPv4 address/netmask provided")); goto error; } def->forward = 1; tmp = xmlXPathEval(BAD_CAST "string(/network/forward[1]/@mode)", ctxt); if ((tmp != NULL) && (tmp->type == XPATH_STRING) && (tmp->stringval != NULL) && (xmlStrEqual(tmp->stringval, BAD_CAST "route"))) { def->forwardMode = QEMUD_NET_FORWARD_ROUTE; } else { def->forwardMode = QEMUD_NET_FORWARD_NAT; } xmlXPathFreeObject(tmp); tmp = NULL; tmp = xmlXPathEval(BAD_CAST "string(/network/forward[1]/@dev)", ctxt); if ((tmp != NULL) && (tmp->type == XPATH_STRING) && (tmp->stringval != NULL) && (tmp->stringval[0] != 0)) { int len; if ((len = xmlStrlen(tmp->stringval)) >= (BR_IFNAME_MAXLEN-1)) { qemudReportError(conn, NULL, NULL, VIR_ERR_INTERNAL_ERROR, _("forward device name '%s' is too long"), (char*)tmp->stringval); goto error; } strcpy(def->forwardDev, (char*)tmp->stringval); } else { def->forwardDev[0] = '\0'; } xmlXPathFreeObject(tmp); tmp = NULL; } else { def->forward = 0; } xmlXPathFreeObject(obj); xmlXPathFreeContext(ctxt); return def; error: /* XXX free all the stuff in the qemud_network struct, or leave it upto the caller ? */ xmlXPathFreeObject(obj); xmlXPathFreeObject(tmp); xmlXPathFreeContext(ctxt); qemudFreeNetworkDef(def); return NULL; } struct qemud_network_def * qemudParseNetworkDef(virConnectPtr conn, struct qemud_driver *driver, const char *xmlStr, const char *displayName) { xmlDocPtr xml; struct qemud_network_def *def; if (!(xml = xmlReadDoc(BAD_CAST xmlStr, displayName ? displayName : "network.xml", NULL, XML_PARSE_NOENT | XML_PARSE_NONET | XML_PARSE_NOERROR | XML_PARSE_NOWARNING))) { qemudReportError(conn, NULL, NULL, VIR_ERR_XML_ERROR, NULL); return NULL; } def = qemudParseNetworkXML(conn, driver, xml); xmlFreeDoc(xml); return def; } struct qemud_network * qemudAssignNetworkDef(virConnectPtr conn, struct qemud_driver *driver, struct qemud_network_def *def) { struct qemud_network *network; if ((network = qemudFindNetworkByName(driver, def->name))) { if (!qemudIsActiveNetwork(network)) { qemudFreeNetworkDef(network->def); network->def = def; } else { if (network->newDef) qemudFreeNetworkDef(network->newDef); network->newDef = def; } return network; } if (!(network = calloc(1, sizeof(*network)))) { qemudReportError(conn, NULL, NULL, VIR_ERR_NO_MEMORY, "%s", _("failed to allocate space for network string")); return NULL; } network->def = def; network->next = driver->networks; driver->networks = network; driver->ninactivenetworks++; return network; } void qemudRemoveInactiveNetwork(struct qemud_driver *driver, struct qemud_network *network) { struct qemud_network *prev = NULL, *curr; curr = driver->networks; while (curr != network) { prev = curr; curr = curr->next; } if (curr) { if (prev) prev->next = curr->next; else driver->networks = curr->next; driver->ninactivenetworks--; } qemudFreeNetwork(network); } int qemudSaveNetworkDef(virConnectPtr conn, struct qemud_driver *driver, struct qemud_network *network, struct qemud_network_def *def) { if (network->configFile[0] == '\0') { int err; if ((err = virFileMakePath(driver->networkConfigDir))) { qemudReportError(conn, NULL, NULL, VIR_ERR_INTERNAL_ERROR, _("cannot create config directory %s: %s"), driver->networkConfigDir, strerror(err)); return -1; } if (virFileBuildPath(driver->networkConfigDir, def->name, ".xml", network->configFile, PATH_MAX) < 0) { qemudReportError(conn, NULL, NULL, VIR_ERR_INTERNAL_ERROR, "%s", _("cannot construct config file path")); return -1; } if (virFileBuildPath(driver->networkAutostartDir, def->name, ".xml", network->autostartLink, PATH_MAX) < 0) { qemudReportError(conn, NULL, NULL, VIR_ERR_INTERNAL_ERROR, "%s", _("cannot construct autostart link path")); network->configFile[0] = '\0'; return -1; } } return qemudSaveNetworkConfig(conn, driver, network, def); } static struct qemud_vm * qemudLoadConfig(struct qemud_driver *driver, const char *file, const char *path, const char *xml, const char *autostartLink) { struct qemud_vm_def *def; struct qemud_vm *vm; if (!(def = qemudParseVMDef(NULL, driver, xml, file))) { virErrorPtr err = virGetLastError(); qemudLog(QEMUD_WARN, _("Error parsing QEMU guest config '%s' : %s"), path, (err ? err->message : _("BUG: unknown error - please report it\n"))); return NULL; } if (!virFileMatchesNameSuffix(file, def->name, ".xml")) { qemudLog(QEMUD_WARN, _("QEMU guest config filename '%s'" " does not match guest name '%s'"), path, def->name); qemudFreeVMDef(def); return NULL; } if (!(vm = qemudAssignVMDef(NULL, driver, def))) { qemudLog(QEMUD_WARN, _("Failed to load QEMU guest config '%s': out of memory"), path); qemudFreeVMDef(def); return NULL; } strncpy(vm->configFile, path, PATH_MAX); vm->configFile[PATH_MAX-1] = '\0'; strncpy(vm->autostartLink, autostartLink, PATH_MAX); vm->autostartLink[PATH_MAX-1] = '\0'; vm->autostart = virFileLinkPointsTo(vm->autostartLink, vm->configFile); return vm; } static struct qemud_network * qemudLoadNetworkConfig(struct qemud_driver *driver, const char *file, const char *path, const char *xml, const char *autostartLink) { struct qemud_network_def *def; struct qemud_network *network; if (!(def = qemudParseNetworkDef(NULL, driver, xml, file))) { virErrorPtr err = virGetLastError(); qemudLog(QEMUD_WARN, _("Error parsing network config '%s' : %s"), path, err->message); return NULL; } if (!virFileMatchesNameSuffix(file, def->name, ".xml")) { qemudLog(QEMUD_WARN, _("Network config filename '%s'" " does not match network name '%s'"), path, def->name); qemudFreeNetworkDef(def); return NULL; } if (!(network = qemudAssignNetworkDef(NULL, driver, def))) { qemudLog(QEMUD_WARN, _("Failed to load network config '%s': out of memory"), path); qemudFreeNetworkDef(def); return NULL; } strncpy(network->configFile, path, PATH_MAX); network->configFile[PATH_MAX-1] = '\0'; strncpy(network->autostartLink, autostartLink, PATH_MAX); network->autostartLink[PATH_MAX-1] = '\0'; network->autostart = virFileLinkPointsTo(network->autostartLink, network->configFile); return network; } static int qemudScanConfigDir(struct qemud_driver *driver, const char *configDir, const char *autostartDir, int isGuest) { DIR *dir; struct dirent *entry; if (!(dir = opendir(configDir))) { if (errno == ENOENT) return 0; qemudLog(QEMUD_ERR, _("Failed to open dir '%s': %s"), configDir, strerror(errno)); return -1; } while ((entry = readdir(dir))) { char *xml; char path[PATH_MAX]; char autostartLink[PATH_MAX]; if (entry->d_name[0] == '.') continue; if (!virFileHasSuffix(entry->d_name, ".xml")) continue; if (virFileBuildPath(configDir, entry->d_name, NULL, path, PATH_MAX) < 0) { qemudLog(QEMUD_WARN, _("Config filename '%s/%s' is too long"), configDir, entry->d_name); continue; } if (virFileBuildPath(autostartDir, entry->d_name, NULL, autostartLink, PATH_MAX) < 0) { qemudLog(QEMUD_WARN, _("Autostart link path '%s/%s' is too long"), autostartDir, entry->d_name); continue; } if (virFileReadAll(path, QEMUD_MAX_XML_LEN, &xml) < 0) continue; if (isGuest) qemudLoadConfig(driver, entry->d_name, path, xml, autostartLink); else qemudLoadNetworkConfig(driver, entry->d_name, path, xml, autostartLink); free(xml); } closedir(dir); return 0; } /* Scan for all guest and network config files */ int qemudScanConfigs(struct qemud_driver *driver) { if (qemudScanConfigDir(driver, driver->configDir, driver->autostartDir, 1) < 0) return -1; if (qemudScanConfigDir(driver, driver->networkConfigDir, driver->networkAutostartDir, 0) < 0) return -1; return 0; } static int qemudGenerateXMLChar(virBufferPtr buf, const struct qemud_vm_chr_def *dev, const char *type) { const char *const types[] = { "null", "vc", "pty", "dev", "file", "pipe", "stdio", "udp", "tcp", "unix" }; verify_true(ARRAY_CARDINALITY(types) == QEMUD_CHR_SRC_TYPE_LAST); /* Compat with legacy syntax */ if (STREQ(type, "console") && dev->srcType == QEMUD_CHR_SRC_TYPE_PTY && dev->srcData.file.path[0] != '\0') { virBufferVSprintf(buf, " <%s type='%s' tty='%s'>\n", type, types[dev->srcType], dev->srcData.file.path); } else { virBufferVSprintf(buf, " <%s type='%s'>\n", type, types[dev->srcType]); } switch (dev->srcType) { case QEMUD_CHR_SRC_TYPE_NULL: case QEMUD_CHR_SRC_TYPE_VC: case QEMUD_CHR_SRC_TYPE_STDIO: /* nada */ break; case QEMUD_CHR_SRC_TYPE_PTY: case QEMUD_CHR_SRC_TYPE_DEV: case QEMUD_CHR_SRC_TYPE_FILE: case QEMUD_CHR_SRC_TYPE_PIPE: if (dev->srcType != QEMUD_CHR_SRC_TYPE_PTY || dev->srcData.file.path[0]) { virBufferVSprintf(buf, " \n", dev->srcData.file.path); } break; case QEMUD_CHR_SRC_TYPE_UDP: if (dev->srcData.udp.bindService[0] != '\0' && dev->srcData.udp.bindHost[0] != '\0') { virBufferVSprintf(buf, " \n", dev->srcData.udp.bindHost, dev->srcData.udp.bindService); } else if (dev->srcData.udp.bindHost[0] !='\0') { virBufferVSprintf(buf, " \n", dev->srcData.udp.bindHost); } else if (dev->srcData.udp.bindService[0] != '\0') { virBufferVSprintf(buf, " \n", dev->srcData.udp.bindService); } if (dev->srcData.udp.connectService[0] != '\0' && dev->srcData.udp.connectHost[0] != '\0') { virBufferVSprintf(buf, " \n", dev->srcData.udp.connectHost, dev->srcData.udp.connectService); } else if (dev->srcData.udp.connectHost[0] != '\0') { virBufferVSprintf(buf, " \n", dev->srcData.udp.connectHost); } else if (dev->srcData.udp.connectService[0] != '\0') { virBufferVSprintf(buf, " \n", dev->srcData.udp.connectService); } break; case QEMUD_CHR_SRC_TYPE_TCP: virBufferVSprintf(buf, " \n", dev->srcData.tcp.listen ? "bind" : "connect", dev->srcData.tcp.host, dev->srcData.tcp.service); virBufferVSprintf(buf, " \n", dev->srcData.tcp.protocol == QEMUD_CHR_SRC_TCP_PROTOCOL_TELNET ? "telnet" : "raw"); break; case QEMUD_CHR_SRC_TYPE_UNIX: virBufferVSprintf(buf, " \n", dev->srcData.nix.listen ? "bind" : "connect", dev->srcData.nix.path); break; } virBufferVSprintf(buf, " \n", dev->dstPort); virBufferVSprintf(buf, " \n", type); return 0; } /* Generate an XML document describing the guest's configuration */ char *qemudGenerateXML(virConnectPtr conn, struct qemud_driver *driver ATTRIBUTE_UNUSED, struct qemud_vm *vm, struct qemud_vm_def *def, int live) { virBuffer buf = VIR_BUFFER_INITIALIZER; unsigned char *uuid; char uuidstr[VIR_UUID_STRING_BUFLEN]; const struct qemud_vm_disk_def *disk; const struct qemud_vm_net_def *net; const struct qemud_vm_input_def *input; const struct qemud_vm_sound_def *sound; const struct qemud_vm_chr_def *chr; const char *type = NULL; int n, allones = 1; if (!(type = qemudVirtTypeToString(def->virtType))) { qemudReportError(conn, NULL, NULL, VIR_ERR_INTERNAL_ERROR, _("unexpected domain type %d"), def->virtType); goto cleanup; } if (qemudIsActiveVM(vm) && live) virBufferVSprintf(&buf, "\n", type, vm->id); else virBufferVSprintf(&buf, "\n", type); virBufferVSprintf(&buf, " %s\n", def->name); uuid = def->uuid; virUUIDFormat(uuid, uuidstr); virBufferVSprintf(&buf, " %s\n", uuidstr); virBufferVSprintf(&buf, " %lu\n", def->maxmem); virBufferVSprintf(&buf, " %lu\n", def->memory); for (n = 0 ; n < QEMUD_CPUMASK_LEN ; n++) if (def->cpumask[n] != 1) allones = 0; if (allones) { virBufferVSprintf(&buf, " %d\n", def->vcpus); } else { char *cpumask = NULL; if ((cpumask = virSaveCpuSet(conn, def->cpumask, QEMUD_CPUMASK_LEN)) == NULL) { qemudReportError(conn, NULL, NULL, VIR_ERR_NO_MEMORY, "%s", _("allocating cpu mask")); goto cleanup; } virBufferVSprintf(&buf, " %d\n", cpumask, def->vcpus); free(cpumask); } if (def->os.bootloader[0]) virBufferVSprintf(&buf, " %s\n", def->os.bootloader); virBufferAddLit(&buf, " \n"); if (def->virtType == QEMUD_VIRT_QEMU) virBufferVSprintf(&buf, " %s\n", def->os.arch, def->os.machine, def->os.type); else virBufferVSprintf(&buf, " %s\n", def->os.type); if (!def->os.bootloader[0]) { if (def->os.kernel[0]) virBufferVSprintf(&buf, " %s\n", def->os.kernel); if (def->os.initrd[0]) virBufferVSprintf(&buf, " %s\n", def->os.initrd); if (def->os.cmdline[0]) virBufferVSprintf(&buf, " %s\n", def->os.cmdline); for (n = 0 ; n < def->os.nBootDevs ; n++) { const char *boottype = "hd"; switch (def->os.bootDevs[n]) { case QEMUD_BOOT_FLOPPY: boottype = "fd"; break; case QEMUD_BOOT_DISK: boottype = "hd"; break; case QEMUD_BOOT_CDROM: boottype = "cdrom"; break; case QEMUD_BOOT_NET: boottype = "network"; break; } virBufferVSprintf(&buf, " \n", boottype); } } virBufferAddLit(&buf, " \n"); if (def->features & QEMUD_FEATURE_ACPI) { virBufferAddLit(&buf, " \n"); virBufferAddLit(&buf, " \n"); virBufferAddLit(&buf, " \n"); } virBufferVSprintf(&buf, " \n", def->localtime ? "localtime" : "utc"); virBufferAddLit(&buf, " destroy\n"); if (def->noReboot) virBufferAddLit(&buf, " destroy\n"); else virBufferAddLit(&buf, " restart\n"); virBufferAddLit(&buf, " destroy\n"); virBufferAddLit(&buf, " \n"); virBufferVSprintf(&buf, " %s\n", def->os.binary); disk = def->disks; while (disk) { const char *types[] = { "block", "file", }; const char *typeAttrs[] = { "dev", "file", }; const char *devices[] = { "disk", "cdrom", "floppy", }; virBufferVSprintf(&buf, " \n", types[disk->type], devices[disk->device]); if (disk->src[0]) virBufferVSprintf(&buf, " \n", typeAttrs[disk->type], disk->src); virBufferVSprintf(&buf, " \n", disk->dst, qemudBusIdToName(disk->bus, 0)); if (disk->readonly) virBufferAddLit(&buf, " \n"); virBufferAddLit(&buf, " \n"); disk = disk->next; } net = def->nets; while (net) { const char *types[] = { "user", "ethernet", "server", "client", "mcast", "network", "bridge", }; virBufferVSprintf(&buf, " \n", types[net->type]); virBufferVSprintf(&buf, " \n", net->mac[0], net->mac[1], net->mac[2], net->mac[3], net->mac[4], net->mac[5]); switch (net->type) { case QEMUD_NET_NETWORK: virBufferVSprintf(&buf, " \n", net->dst.network.name); if (net->dst.network.ifname[0] != '\0') virBufferVSprintf(&buf, " \n", net->dst.network.ifname); break; case QEMUD_NET_ETHERNET: if (net->dst.ethernet.ifname[0] != '\0') virBufferVSprintf(&buf, " \n", net->dst.ethernet.ifname); if (net->dst.ethernet.script[0] != '\0') virBufferVSprintf(&buf, "