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libvirt/tests/qemuxml2argvtest.c

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#include <config.h>
#include <unistd.h>
2007-07-19 01:34:22 +04:00
#include <sys/types.h>
#include <fcntl.h>
#include "testutils.h"
#ifdef WITH_QEMU
# include "internal.h"
2012-12-12 22:06:53 +04:00
# include "viralloc.h"
# include "viridentity.h"
# include "qemu/qemu_capabilities.h"
# include "qemu/qemu_domain.h"
# include "qemu/qemu_migration.h"
# include "qemu/qemu_process.h"
# include "qemu/qemu_slirp.h"
# include "datatypes.h"
# include "conf/storage_conf.h"
# include "virfilewrapper.h"
# include "configmake.h"
# include "testutilsqemuschema.h"
2007-07-19 01:34:22 +04:00
# define LIBVIRT_QEMU_CAPSPRIV_H_ALLOW
# include "qemu/qemu_capspriv.h"
# include "testutilsqemu.h"
# define VIR_FROM_THIS VIR_FROM_QEMU
static virQEMUDriver driver;
static virCaps *linuxCaps;
static virCaps *macOSCaps;
2007-07-19 01:34:22 +04:00
static unsigned char *
fakeSecretGetValue(virSecretPtr obj G_GNUC_UNUSED,
size_t *value_size,
unsigned int fakeflags G_GNUC_UNUSED)
{
char *secret;
secret = g_strdup("AQCVn5hO6HzFAhAAq0NCv8jtJcIcE+HOBlMQ1A");
*value_size = strlen(secret);
return (unsigned char *) secret;
}
static virSecretPtr
fakeSecretLookupByUsage(virConnectPtr conn,
int usageType,
const char *usageID)
{
unsigned char uuid[VIR_UUID_BUFLEN];
if (usageType == VIR_SECRET_USAGE_TYPE_VOLUME) {
if (!STRPREFIX(usageID, "/storage/guest_disks/")) {
virReportError(VIR_ERR_INTERNAL_ERROR,
"test provided invalid volume storage prefix '%s'",
usageID);
return NULL;
}
} else if (STRNEQ(usageID, "mycluster_myname") &&
STRNEQ(usageID, "client.admin secret")) {
virReportError(VIR_ERR_INTERNAL_ERROR,
"test provided incorrect usage '%s'", usageID);
return NULL;
}
if (virUUIDGenerate(uuid) < 0)
return NULL;
return virGetSecret(conn, uuid, usageType, usageID);
}
static virSecretPtr
fakeSecretLookupByUUID(virConnectPtr conn,
const unsigned char *uuid)
{
/* NB: This mocked value could be "tls" or "volume" depending on
* which test is being run, we'll leave at NONE (or 0) */
return virGetSecret(conn, uuid, VIR_SECRET_USAGE_TYPE_NONE, "");
}
static virSecretDriver fakeSecretDriver = {
.connectNumOfSecrets = NULL,
.connectListSecrets = NULL,
.secretLookupByUUID = fakeSecretLookupByUUID,
.secretLookupByUsage = fakeSecretLookupByUsage,
.secretDefineXML = NULL,
.secretGetXMLDesc = NULL,
.secretSetValue = NULL,
.secretGetValue = fakeSecretGetValue,
.secretUndefine = NULL,
};
# define STORAGE_POOL_XML_PATH "storagepoolxml2xmlout/"
static const unsigned char fakeUUID[VIR_UUID_BUFLEN] = "fakeuuid";
static virStoragePoolPtr
fakeStoragePoolLookupByName(virConnectPtr conn,
const char *name)
{
g_autofree char *xmlpath = NULL;
if (STRNEQ(name, "inactive")) {
xmlpath = g_strdup_printf("%s/%s%s.xml", abs_srcdir,
STORAGE_POOL_XML_PATH, name);
if (!virFileExists(xmlpath)) {
virReportError(VIR_ERR_NO_STORAGE_POOL,
"File '%s' not found", xmlpath);
return NULL;
}
}
return virGetStoragePool(conn, name, fakeUUID, NULL, NULL);
}
static virStorageVolPtr
fakeStorageVolLookupByName(virStoragePoolPtr pool,
const char *name)
{
g_auto(GStrv) volinfo = NULL;
if (STREQ(pool->name, "inactive")) {
virReportError(VIR_ERR_OPERATION_INVALID,
"storage pool '%s' is not active", pool->name);
return NULL;
}
if (STREQ(name, "nonexistent")) {
virReportError(VIR_ERR_NO_STORAGE_VOL,
"no storage vol with matching name '%s'", name);
return NULL;
}
if (!(volinfo = g_strsplit(name, "+", 2)))
return NULL;
if (!volinfo[1]) {
return virGetStorageVol(pool->conn, pool->name, name, "block", NULL, NULL);
}
return virGetStorageVol(pool->conn, pool->name, volinfo[1], volinfo[0],
NULL, NULL);
}
static int
fakeStorageVolGetInfo(virStorageVolPtr vol,
virStorageVolInfoPtr info)
{
memset(info, 0, sizeof(*info));
info->type = virStorageVolTypeFromString(vol->key);
if (info->type < 0) {
virReportError(VIR_ERR_INTERNAL_ERROR,
"Invalid volume type '%s'", vol->key);
return -1;
}
return 0;
}
static char *
fakeStorageVolGetPath(virStorageVolPtr vol)
{
return g_strdup_printf("/some/%s/device/%s", vol->key, vol->name);
}
static char *
fakeStoragePoolGetXMLDesc(virStoragePoolPtr pool,
unsigned int flags_unused G_GNUC_UNUSED)
{
g_autofree char *xmlpath = NULL;
char *xmlbuf = NULL;
if (STREQ(pool->name, "inactive")) {
virReportError(VIR_ERR_NO_STORAGE_POOL, NULL);
return NULL;
}
xmlpath = g_strdup_printf("%s/%s%s.xml", abs_srcdir, STORAGE_POOL_XML_PATH,
pool->name);
if (virTestLoadFile(xmlpath, &xmlbuf) < 0) {
virReportError(VIR_ERR_INTERNAL_ERROR,
"failed to load XML file '%s'",
xmlpath);
return NULL;
}
return xmlbuf;
}
static int
fakeStoragePoolIsActive(virStoragePoolPtr pool)
{
if (STREQ(pool->name, "inactive"))
return 0;
return 1;
}
/* Test storage pool implementation
*
* These functions aid testing of storage pool related stuff when creating a
* qemu command line.
*
* There are a few "magic" values to pass to these functions:
*
* 1) "inactive" as a pool name to create an inactive pool. All other names are
* interpreted as file names in storagepoolxml2xmlout/ and are used as the
* definition for the pool. If the file doesn't exist the pool doesn't exist.
*
* 2) "nonexistent" returns an error while looking up a volume. Otherwise
* pattern VOLUME_TYPE+VOLUME_PATH can be used to simulate a volume in a pool.
* This creates a fake path for this volume. If the '+' sign is omitted, block
* type is assumed.
*/
static virStorageDriver fakeStorageDriver = {
.storagePoolLookupByName = fakeStoragePoolLookupByName,
.storageVolLookupByName = fakeStorageVolLookupByName,
.storagePoolGetXMLDesc = fakeStoragePoolGetXMLDesc,
.storageVolGetPath = fakeStorageVolGetPath,
.storageVolGetInfo = fakeStorageVolGetInfo,
.storagePoolIsActive = fakeStoragePoolIsActive,
};
/* virNetDevOpenvswitchGetVhostuserIfname mocks a portdev name - handle that */
static virNWFilterBindingPtr
fakeNWFilterBindingLookupByPortDev(virConnectPtr conn,
const char *portdev)
{
if (STREQ(portdev, "vhost-user0"))
return virGetNWFilterBinding(conn, "fake_vnet0", "fakeFilterName");
virReportError(VIR_ERR_NO_NWFILTER_BINDING,
"no nwfilter binding for port dev '%s'", portdev);
return NULL;
}
static int
fakeNWFilterBindingDelete(virNWFilterBindingPtr binding G_GNUC_UNUSED)
{
return 0;
}
static virNWFilterDriver fakeNWFilterDriver = {
.nwfilterBindingLookupByPortDev = fakeNWFilterBindingLookupByPortDev,
.nwfilterBindingDelete = fakeNWFilterBindingDelete,
};
static int
testAddCPUModels(virQEMUCaps *caps, bool skipLegacy)
{
virArch arch = virQEMUCapsGetArch(caps);
const char *x86Models[] = {
"Opteron_G3", "Opteron_G2", "Opteron_G1",
"Nehalem", "Penryn", "Conroe",
"Haswell-noTSX", "Haswell",
};
const char *x86LegacyModels[] = {
"n270", "athlon", "pentium3", "pentium2", "pentium",
"486", "coreduo", "kvm32", "qemu32", "kvm64",
"core2duo", "phenom", "qemu64",
};
const char *armModels[] = {
"cortex-a9", "cortex-a8", "cortex-a57", "cortex-a53",
};
const char *ppc64Models[] = {
"POWER8", "POWER7",
};
const char *s390xModels[] = {
"z990", "zEC12", "z13",
};
if (ARCH_IS_X86(arch)) {
if (virQEMUCapsAddCPUDefinitions(caps, VIR_DOMAIN_VIRT_KVM, x86Models,
G_N_ELEMENTS(x86Models),
VIR_DOMCAPS_CPU_USABLE_UNKNOWN) < 0 ||
virQEMUCapsAddCPUDefinitions(caps, VIR_DOMAIN_VIRT_QEMU, x86Models,
G_N_ELEMENTS(x86Models),
VIR_DOMCAPS_CPU_USABLE_UNKNOWN) < 0)
return -1;
if (!skipLegacy) {
if (virQEMUCapsAddCPUDefinitions(caps, VIR_DOMAIN_VIRT_KVM,
x86LegacyModels,
G_N_ELEMENTS(x86LegacyModels),
VIR_DOMCAPS_CPU_USABLE_UNKNOWN) < 0 ||
virQEMUCapsAddCPUDefinitions(caps, VIR_DOMAIN_VIRT_QEMU,
x86LegacyModels,
G_N_ELEMENTS(x86LegacyModels),
VIR_DOMCAPS_CPU_USABLE_UNKNOWN) < 0)
return -1;
}
} else if (ARCH_IS_ARM(arch)) {
if (virQEMUCapsAddCPUDefinitions(caps, VIR_DOMAIN_VIRT_KVM, armModels,
G_N_ELEMENTS(armModels),
VIR_DOMCAPS_CPU_USABLE_UNKNOWN) < 0 ||
virQEMUCapsAddCPUDefinitions(caps, VIR_DOMAIN_VIRT_QEMU, armModels,
G_N_ELEMENTS(armModels),
VIR_DOMCAPS_CPU_USABLE_UNKNOWN) < 0)
return -1;
} else if (ARCH_IS_PPC64(arch)) {
if (virQEMUCapsAddCPUDefinitions(caps, VIR_DOMAIN_VIRT_KVM, ppc64Models,
G_N_ELEMENTS(ppc64Models),
VIR_DOMCAPS_CPU_USABLE_UNKNOWN) < 0 ||
virQEMUCapsAddCPUDefinitions(caps, VIR_DOMAIN_VIRT_QEMU, ppc64Models,
G_N_ELEMENTS(ppc64Models),
VIR_DOMCAPS_CPU_USABLE_UNKNOWN) < 0)
return -1;
} else if (ARCH_IS_S390(arch)) {
if (virQEMUCapsAddCPUDefinitions(caps, VIR_DOMAIN_VIRT_KVM, s390xModels,
G_N_ELEMENTS(s390xModels),
VIR_DOMCAPS_CPU_USABLE_UNKNOWN) < 0)
return -1;
}
return 0;
}
testutilsqemu: introduce ARG_CAPS_HOST_CPU_MODEL When loading a latest caps for an arch for the first time the following occurs in testQemuInfoInitArgs(): - the caps file is located. It's not in the cache since it's the first time it's being read; - the cachecaps are retrieved using qemuTestParseCapabilitiesArch() and stored in the capscache; - FLAG_REAL_CAPS is set and regular flow continues. Loading the same latest caps for the second time the caps are loaded from the cache, skipping qemuTestParseCapabilitiesArch(). By skipping this function it means that it also skips virQEMUCapsLoadCache() and, more relevant to our case, virQEMUCapsInitHostCPUModel(). This function will use the current arch and cpuModel settings to write the qemuCaps that are being stored in the cache. And we're also setting FLAG_REAL_CAPS, meaning that we won't be updating the qemucaps host model via testUpdateQEMUCaps() as well. This has side-effects such as: - the first time the latest caps for an arch is loaded determines the cpuModel it'll use during the current qemuxml2argvtest run. For example, when running all tests, the first time the latest ppc64 caps are read is on "disk-floppy-pseries" test. Since the current host arch at this point is x86_64, the cpuModel that will be set for this capability is "core2duo"; - every other latest arch test will use the same hostCPU as the first one set since we read it from the cache after the first run. qemuTestSetHostCPU() makes no difference because we won't update the host model due to FLAG_REAL_CAPS being set. Using the previous example, every other latest ppc64 test that will be run will be using the "core2duo" cpuModel. Using fake capabilities (e.g. using DO_TEST()) prevents FLAG_REAL_CAPS to be set, meaning that the cpuModel will be updated using the current settings the test is being ran due to testUpdateQEMUCaps(). Note that not all latest caps arch tests care about the cpuModel being set to an unexpected default cpuModel. But some tests will care, e.g. "pseries-cpu-compat-power9", and changing it from DO_TEST() to DO_TEST_CAPS_ARCH_LATEST() will make it fail every time the "disk-floppy-pseries" is being ran first. One way of fixing it is to rethink all the existing logic, for example not setting FLAG_REAL_CAPS for latest arch tests. Another way is presented here. ARGS_CAPS_HOST_CPU_MODEL is a new testQemuInfo arg that allow us to set any specific host CPU model we want when running latest arch caps tests. This new arg can then be used when converting existing DO_TEST() testcases to DO_TEST_CAPS_ARCH_LATEST() that requires a specific host CPU setting to be successful, which we're going to do in the next patch with "pseries-cpu-compat-power9". Reviewed-by: Martin Kletzander <mkletzan@redhat.com> Signed-off-by: Daniel Henrique Barboza <danielhb413@gmail.com>
2022-05-20 16:58:23 +03:00
static void
testUpdateQEMUCapsHostCPUModel(virQEMUCaps *qemuCaps, virArch hostArch)
{
virQEMUCapsUpdateHostCPUModel(qemuCaps, hostArch, VIR_DOMAIN_VIRT_KVM);
virQEMUCapsUpdateHostCPUModel(qemuCaps, hostArch, VIR_DOMAIN_VIRT_QEMU);
}
static int
testUpdateQEMUCaps(const struct testQemuInfo *info,
virArch arch,
virCaps *caps)
{
if (!caps)
return -1;
virQEMUCapsSetArch(info->qemuCaps, arch);
virQEMUCapsInitQMPBasicArch(info->qemuCaps);
if (testAddCPUModels(info->qemuCaps,
!!(info->flags & FLAG_SKIP_LEGACY_CPUS)) < 0)
return -1;
testutilsqemu: introduce ARG_CAPS_HOST_CPU_MODEL When loading a latest caps for an arch for the first time the following occurs in testQemuInfoInitArgs(): - the caps file is located. It's not in the cache since it's the first time it's being read; - the cachecaps are retrieved using qemuTestParseCapabilitiesArch() and stored in the capscache; - FLAG_REAL_CAPS is set and regular flow continues. Loading the same latest caps for the second time the caps are loaded from the cache, skipping qemuTestParseCapabilitiesArch(). By skipping this function it means that it also skips virQEMUCapsLoadCache() and, more relevant to our case, virQEMUCapsInitHostCPUModel(). This function will use the current arch and cpuModel settings to write the qemuCaps that are being stored in the cache. And we're also setting FLAG_REAL_CAPS, meaning that we won't be updating the qemucaps host model via testUpdateQEMUCaps() as well. This has side-effects such as: - the first time the latest caps for an arch is loaded determines the cpuModel it'll use during the current qemuxml2argvtest run. For example, when running all tests, the first time the latest ppc64 caps are read is on "disk-floppy-pseries" test. Since the current host arch at this point is x86_64, the cpuModel that will be set for this capability is "core2duo"; - every other latest arch test will use the same hostCPU as the first one set since we read it from the cache after the first run. qemuTestSetHostCPU() makes no difference because we won't update the host model due to FLAG_REAL_CAPS being set. Using the previous example, every other latest ppc64 test that will be run will be using the "core2duo" cpuModel. Using fake capabilities (e.g. using DO_TEST()) prevents FLAG_REAL_CAPS to be set, meaning that the cpuModel will be updated using the current settings the test is being ran due to testUpdateQEMUCaps(). Note that not all latest caps arch tests care about the cpuModel being set to an unexpected default cpuModel. But some tests will care, e.g. "pseries-cpu-compat-power9", and changing it from DO_TEST() to DO_TEST_CAPS_ARCH_LATEST() will make it fail every time the "disk-floppy-pseries" is being ran first. One way of fixing it is to rethink all the existing logic, for example not setting FLAG_REAL_CAPS for latest arch tests. Another way is presented here. ARGS_CAPS_HOST_CPU_MODEL is a new testQemuInfo arg that allow us to set any specific host CPU model we want when running latest arch caps tests. This new arg can then be used when converting existing DO_TEST() testcases to DO_TEST_CAPS_ARCH_LATEST() that requires a specific host CPU setting to be successful, which we're going to do in the next patch with "pseries-cpu-compat-power9". Reviewed-by: Martin Kletzander <mkletzan@redhat.com> Signed-off-by: Daniel Henrique Barboza <danielhb413@gmail.com>
2022-05-20 16:58:23 +03:00
testUpdateQEMUCapsHostCPUModel(info->qemuCaps, caps->host.arch);
return 0;
}
static int
testCheckExclusiveFlags(int flags)
{
virCheckFlags(FLAG_EXPECT_FAILURE |
FLAG_EXPECT_PARSE_ERROR |
FLAG_FIPS_HOST |
FLAG_REAL_CAPS |
FLAG_SKIP_LEGACY_CPUS |
FLAG_SLIRP_HELPER |
0, -1);
VIR_EXCLUSIVE_FLAGS_RET(FLAG_REAL_CAPS, FLAG_SKIP_LEGACY_CPUS, -1);
return 0;
}
static virCommand *
testCompareXMLToArgvCreateArgs(virQEMUDriver *drv,
virDomainObj *vm,
const char *migrateURI,
struct testQemuInfo *info,
unsigned int flags)
{
qemuDomainObjPrivate *priv = vm->privateData;
size_t i;
drv->hostFips = flags & FLAG_FIPS_HOST;
if (qemuProcessCreatePretendCmdPrepare(drv, vm, migrateURI,
VIR_QEMU_PROCESS_START_COLD) < 0)
return NULL;
if (qemuDomainDeviceBackendChardevForeach(vm->def,
testQemuPrepareHostBackendChardevOne,
vm) < 0)
return NULL;
if (testQemuPrepareHostBackendChardevOne(NULL, priv->monConfig, vm) < 0)
return NULL;
for (i = 0; i < vm->def->ndisks; i++) {
virDomainDiskDef *disk = vm->def->disks[i];
/* host cdrom requires special treatment in qemu, mock it */
if (disk->device == VIR_DOMAIN_DISK_DEVICE_CDROM &&
disk->src->format == VIR_STORAGE_FILE_RAW &&
virStorageSourceIsBlockLocal(disk->src) &&
STREQ(disk->src->path, "/dev/cdrom"))
disk->src->hostcdrom = true;
}
for (i = 0; i < vm->def->nhostdevs; i++) {
virDomainHostdevDef *hostdev = vm->def->hostdevs[i];
if (hostdev->mode == VIR_DOMAIN_HOSTDEV_MODE_SUBSYS &&
hostdev->source.subsys.type == VIR_DOMAIN_HOSTDEV_SUBSYS_TYPE_PCI &&
hostdev->source.subsys.u.pci.backend == VIR_DOMAIN_HOSTDEV_PCI_BACKEND_DEFAULT) {
hostdev->source.subsys.u.pci.backend = VIR_DOMAIN_HOSTDEV_PCI_BACKEND_VFIO;
}
if (virHostdevIsSCSIDevice(hostdev)) {
virDomainHostdevSubsysSCSI *scsisrc = &hostdev->source.subsys.u.scsi;
switch ((virDomainHostdevSCSIProtocolType) scsisrc->protocol) {
case VIR_DOMAIN_HOSTDEV_SCSI_PROTOCOL_TYPE_NONE:
scsisrc->u.host.src->path = g_strdup("/dev/sg0");
break;
case VIR_DOMAIN_HOSTDEV_SCSI_PROTOCOL_TYPE_ISCSI:
break;
case VIR_DOMAIN_HOSTDEV_SCSI_PROTOCOL_TYPE_LAST:
default:
virReportEnumRangeError(virDomainHostdevSCSIProtocolType, scsisrc->protocol);
return NULL;
}
}
}
if (vm->def->vsock) {
virDomainVsockDef *vsock = vm->def->vsock;
qemuDomainVsockPrivate *vsockPriv =
(qemuDomainVsockPrivate *)vsock->privateData;
if (vsock->auto_cid == VIR_TRISTATE_BOOL_YES)
vsock->guest_cid = 42;
vsockPriv->vhostfd = 6789;
}
for (i = 0; i < vm->def->ntpms; i++) {
if (vm->def->tpms[i]->type != VIR_DOMAIN_TPM_TYPE_EMULATOR)
continue;
VIR_FREE(vm->def->tpms[i]->data.emulator.source->data.nix.path);
vm->def->tpms[i]->data.emulator.source->type = VIR_DOMAIN_CHR_TYPE_UNIX;
vm->def->tpms[i]->data.emulator.source->data.nix.path = g_strdup("/dev/test");
}
for (i = 0; i < vm->def->nvideos; i++) {
virDomainVideoDef *video = vm->def->videos[i];
if (video->backend == VIR_DOMAIN_VIDEO_BACKEND_TYPE_VHOSTUSER) {
qemuDomainVideoPrivate *vpriv = QEMU_DOMAIN_VIDEO_PRIVATE(video);
vpriv->vhost_user_fd = 1729;
}
}
if (flags & FLAG_SLIRP_HELPER) {
for (i = 0; i < vm->def->nnets; i++) {
virDomainNetDef *net = vm->def->nets[i];
if (net->type == VIR_DOMAIN_NET_TYPE_USER &&
virQEMUCapsGet(info->qemuCaps, QEMU_CAPS_DBUS_VMSTATE)) {
qemuSlirp *slirp = qemuSlirpNew();
slirp->fd[0] = 42;
QEMU_DOMAIN_NETWORK_PRIVATE(net)->slirp = slirp;
}
}
}
return qemuProcessCreatePretendCmdBuild(vm, migrateURI);
}
struct testValidateSchemaCommandData {
const char *name;
const char *schema;
bool allowIncomplete; /* relax validator for commands with incomplete schema */
};
static const struct testValidateSchemaCommandData commands[] = {
{ "-blockdev", "blockdev-add", false },
{ "-netdev", "netdev_add", false },
{ "-object", "object-add", false },
{ "-device", "device_add", true },
};
static int
testCompareXMLToArgvValidateSchemaCommand(GStrv args,
GHashTable *schema)
{
GStrv arg;
for (arg = args; *arg; arg++) {
const char *curcommand = *arg;
const char *curargs = *(arg + 1);
size_t i;
for (i = 0; i < G_N_ELEMENTS(commands); i++) {
const struct testValidateSchemaCommandData *command = commands + i;
g_auto(virBuffer) debug = VIR_BUFFER_INITIALIZER;
g_autoptr(virJSONValue) jsonargs = NULL;
if (STRNEQ(curcommand, command->name))
continue;
if (!curargs) {
VIR_TEST_VERBOSE("expected arguments for command '%s'",
command->name);
return -1;
}
if (*curargs != '{') {
arg++;
break;
}
if (!(jsonargs = virJSONValueFromString(curargs)))
return -1;
if (testQEMUSchemaValidateCommand(command->schema, jsonargs,
schema, false, false,
command->allowIncomplete,
&debug) < 0) {
VIR_TEST_VERBOSE("failed to validate '%s %s' against QAPI schema: %s",
command->name, curargs, virBufferCurrentContent(&debug));
return -1;
}
arg++;
}
}
return 0;
}
static int
testCompareXMLToArgvValidateSchema(virCommand *cmd,
struct testQemuInfo *info)
{
g_auto(GStrv) args = NULL;
GHashTable *schema = NULL;
/* comment out with line comment to enable schema checking for non _CAPS tests
if (!info->schemafile)
info->schemafile = testQemuGetLatestCapsForArch(virArchToString(info->arch), "replies");
// */
if (info->schemafile) {
/* lookup and insert into cache if not found */
if (!g_hash_table_lookup_extended(info->conf->qapiSchemaCache,
info->schemafile,
NULL, (void **) &schema)) {
schema = testQEMUSchemaLoad(info->schemafile);
g_hash_table_insert(info->conf->qapiSchemaCache,
g_strdup(info->schemafile),
schema);
}
}
if (!schema)
return 0;
if (virCommandGetArgList(cmd, &args) < 0)
return -1;
if (testCompareXMLToArgvValidateSchemaCommand(args, schema) < 0)
return -1;
return 0;
}
static int
testCompareXMLToArgv(const void *data)
{
struct testQemuInfo *info = (void *) data;
g_autofree char *migrateURI = NULL;
g_auto(virBuffer) actualBuf = VIR_BUFFER_INITIALIZER;
g_autofree char *actualargv = NULL;
unsigned int flags = info->flags;
unsigned int parseFlags = info->parseFlags;
int ret = -1;
virDomainObj *vm = NULL;
virDomainChrSourceDef monitor_chr;
g_autoptr(virConnect) conn = NULL;
virError *err = NULL;
g_autofree char *log = NULL;
g_autoptr(virCommand) cmd = NULL;
qemuDomainObjPrivate *priv = NULL;
g_autoptr(xmlDoc) xml = NULL;
g_autoptr(xmlXPathContext) ctxt = NULL;
g_autofree char *archstr = NULL;
virArch arch = VIR_ARCH_NONE;
g_autoptr(virIdentity) sysident = virIdentityGetSystem();
int rc;
memset(&monitor_chr, 0, sizeof(monitor_chr));
if (testQemuInfoInitArgs((struct testQemuInfo *) info) < 0)
goto cleanup;
if (info->args.hostOS == HOST_OS_MACOS)
driver.caps = macOSCaps;
else
driver.caps = linuxCaps;
if (info->arch != VIR_ARCH_NONE && info->arch != VIR_ARCH_X86_64)
qemuTestSetHostArch(&driver, info->arch);
testutilsqemu: introduce ARG_CAPS_HOST_CPU_MODEL When loading a latest caps for an arch for the first time the following occurs in testQemuInfoInitArgs(): - the caps file is located. It's not in the cache since it's the first time it's being read; - the cachecaps are retrieved using qemuTestParseCapabilitiesArch() and stored in the capscache; - FLAG_REAL_CAPS is set and regular flow continues. Loading the same latest caps for the second time the caps are loaded from the cache, skipping qemuTestParseCapabilitiesArch(). By skipping this function it means that it also skips virQEMUCapsLoadCache() and, more relevant to our case, virQEMUCapsInitHostCPUModel(). This function will use the current arch and cpuModel settings to write the qemuCaps that are being stored in the cache. And we're also setting FLAG_REAL_CAPS, meaning that we won't be updating the qemucaps host model via testUpdateQEMUCaps() as well. This has side-effects such as: - the first time the latest caps for an arch is loaded determines the cpuModel it'll use during the current qemuxml2argvtest run. For example, when running all tests, the first time the latest ppc64 caps are read is on "disk-floppy-pseries" test. Since the current host arch at this point is x86_64, the cpuModel that will be set for this capability is "core2duo"; - every other latest arch test will use the same hostCPU as the first one set since we read it from the cache after the first run. qemuTestSetHostCPU() makes no difference because we won't update the host model due to FLAG_REAL_CAPS being set. Using the previous example, every other latest ppc64 test that will be run will be using the "core2duo" cpuModel. Using fake capabilities (e.g. using DO_TEST()) prevents FLAG_REAL_CAPS to be set, meaning that the cpuModel will be updated using the current settings the test is being ran due to testUpdateQEMUCaps(). Note that not all latest caps arch tests care about the cpuModel being set to an unexpected default cpuModel. But some tests will care, e.g. "pseries-cpu-compat-power9", and changing it from DO_TEST() to DO_TEST_CAPS_ARCH_LATEST() will make it fail every time the "disk-floppy-pseries" is being ran first. One way of fixing it is to rethink all the existing logic, for example not setting FLAG_REAL_CAPS for latest arch tests. Another way is presented here. ARGS_CAPS_HOST_CPU_MODEL is a new testQemuInfo arg that allow us to set any specific host CPU model we want when running latest arch caps tests. This new arg can then be used when converting existing DO_TEST() testcases to DO_TEST_CAPS_ARCH_LATEST() that requires a specific host CPU setting to be successful, which we're going to do in the next patch with "pseries-cpu-compat-power9". Reviewed-by: Martin Kletzander <mkletzan@redhat.com> Signed-off-by: Daniel Henrique Barboza <danielhb413@gmail.com>
2022-05-20 16:58:23 +03:00
if (info->args.capsHostCPUModel) {
virCPUDef *hostCPUModel = qemuTestGetCPUDef(info->args.capsHostCPUModel);
qemuTestSetHostCPU(&driver, driver.hostarch, hostCPUModel);
testUpdateQEMUCapsHostCPUModel(info->qemuCaps, driver.hostarch);
}
if (!(conn = virGetConnect()))
goto cleanup;
conn->secretDriver = &fakeSecretDriver;
conn->storageDriver = &fakeStorageDriver;
conn->nwfilterDriver = &fakeNWFilterDriver;
2007-07-19 01:34:22 +04:00
virSetConnectInterface(conn);
virSetConnectNetwork(conn);
virSetConnectNWFilter(conn);
virSetConnectNodeDev(conn);
virSetConnectSecret(conn);
virSetConnectStorage(conn);
if (virIdentitySetCurrent(sysident) < 0)
goto cleanup;
if (testCheckExclusiveFlags(info->flags) < 0)
goto cleanup;
if (!(xml = virXMLParse(info->infile, NULL, "(domain_definition)",
"domain", &ctxt, NULL, false)))
goto cleanup;
if ((archstr = virXPathString("string(./os/type[1]/@arch)", ctxt)))
arch = virArchFromString(archstr);
if (arch == VIR_ARCH_NONE)
arch = virArchFromHost();
if (!(info->flags & FLAG_REAL_CAPS)) {
if (testUpdateQEMUCaps(info, arch, driver.caps) < 0)
goto cleanup;
}
if (info->args.hostOS == HOST_OS_MACOS)
rc = qemuTestCapsCacheInsertMacOS(driver.qemuCapsCache, info->qemuCaps);
else
rc = qemuTestCapsCacheInsert(driver.qemuCapsCache, info->qemuCaps);
if (rc < 0)
goto cleanup;
if (info->migrateFrom &&
!(migrateURI = qemuMigrationDstGetURI(info->migrateFrom,
info->migrateFd)))
goto cleanup;
if (!(vm = virDomainObjNew(driver.xmlopt)))
goto cleanup;
if (!virFileExists(info->infile)) {
virReportError(VIR_ERR_INTERNAL_ERROR,
"Input file '%s' not found", info->infile);
goto cleanup;
}
parseFlags |= VIR_DOMAIN_DEF_PARSE_INACTIVE;
if (!(vm->def = virDomainDefParseNode(ctxt, driver.xmlopt, NULL, parseFlags))) {
err = virGetLastError();
if (!err) {
VIR_TEST_DEBUG("no error was reported for expected parse error");
goto cleanup;
}
if (flags & FLAG_EXPECT_PARSE_ERROR) {
g_autofree char *tmperr = g_strdup_printf("%s\n", NULLSTR(err->message));
if (virTestCompareToFile(tmperr, info->errfile) >= 0)
goto ok;
}
goto cleanup;
}
if (flags & FLAG_EXPECT_PARSE_ERROR) {
VIR_TEST_DEBUG("passed instead of expected parse error");
goto cleanup;
}
priv = vm->privateData;
2007-07-19 01:34:22 +04:00
if (virBitmapParse("0-3", &priv->autoNodeset, 4) < 0)
goto cleanup;
if (!virDomainDefCheckABIStability(vm->def, vm->def, driver.xmlopt)) {
VIR_TEST_DEBUG("ABI stability check failed on %s", info->infile);
goto cleanup;
}
vm->def->id = -1;
if (qemuProcessPrepareMonitorChr(&monitor_chr, priv->libDir) < 0)
goto cleanup;
virResetLastError();
2010-10-22 20:50:34 +04:00
if (!(cmd = testCompareXMLToArgvCreateArgs(&driver, vm, migrateURI, info,
flags))) {
err = virGetLastError();
if (!err) {
VIR_TEST_DEBUG("no error was reported for expected failure");
goto cleanup;
}
if (flags & FLAG_EXPECT_FAILURE) {
g_autofree char *tmperr = g_strdup_printf("%s\n", NULLSTR(err->message));
if (virTestCompareToFile(tmperr, info->errfile) >= 0)
goto ok;
}
goto cleanup;
2010-10-22 20:50:34 +04:00
}
if (flags & FLAG_EXPECT_FAILURE) {
VIR_TEST_DEBUG("passed instead of expected failure");
goto cleanup;
}
2010-10-22 20:50:34 +04:00
if (testCompareXMLToArgvValidateSchema(cmd, info) < 0)
goto cleanup;
if (virCommandToStringBuf(cmd, &actualBuf, true, false) < 0)
goto cleanup;
virBufferAddLit(&actualBuf, "\n");
actualargv = virBufferContentAndReset(&actualBuf);
if (virTestCompareToFileFull(actualargv, info->outfile, false) < 0)
goto cleanup;
2007-07-19 01:34:22 +04:00
ret = 0;
ok:
if (ret == 0 && flags & FLAG_EXPECT_FAILURE) {
ret = -1;
VIR_TEST_DEBUG("Error expected but there wasn't any.");
goto cleanup;
}
if (flags & FLAG_EXPECT_FAILURE) {
if ((log = virTestLogContentAndReset()))
VIR_TEST_DEBUG("Got expected error: \n%s", log);
}
virResetLastError();
ret = 0;
cleanup:
virDomainChrSourceDefClear(&monitor_chr);
virObjectUnref(vm);
virIdentitySetCurrent(NULL);
virSetConnectSecret(NULL);
virSetConnectStorage(NULL);
if (info->arch != VIR_ARCH_NONE && info->arch != VIR_ARCH_X86_64)
qemuTestSetHostArch(&driver, VIR_ARCH_NONE);
return ret;
2007-07-19 01:34:22 +04:00
}
static void
testInfoSetPaths(struct testQemuInfo *info,
const char *suffix)
{
info->infile = g_strdup_printf("%s/qemuxml2argvdata/%s.xml",
abs_srcdir, info->name);
info->outfile = g_strdup_printf("%s/qemuxml2argvdata/%s%s.args",
abs_srcdir, info->name, suffix ? suffix : "");
info->errfile = g_strdup_printf("%s/qemuxml2argvdata/%s%s.err",
abs_srcdir, info->name, suffix ? suffix : "");
}
# define FAKEROOTDIRTEMPLATE abs_builddir "/fakerootdir-XXXXXX"
static int
tests: simplify common setup A few of the tests were missing basic sanity checks, while most of them were doing copy-and-paste initialization (in fact, some of them pasted the argc > 1 check more than once!). It's much nicer to do things in one common place, and minimizes the size of the next patch that fixes getcwd usage. * tests/testutils.h (EXIT_AM_HARDFAIL): New define. (progname, abs_srcdir): Define for all tests. (VIRT_TEST_MAIN): Change callback signature. * tests/testutils.c (virtTestMain): Do more common init. * tests/commandtest.c (mymain): Simplify. * tests/cputest.c (mymain): Likewise. * tests/esxutilstest.c (mymain): Likewise. * tests/eventtest.c (mymain): Likewise. * tests/hashtest.c (mymain): Likewise. * tests/networkxml2xmltest.c (mymain): Likewise. * tests/nodedevxml2xmltest.c (myname): Likewise. * tests/nodeinfotest.c (mymain): Likewise. * tests/nwfilterxml2xmltest.c (mymain): Likewise. * tests/qemuargv2xmltest.c (mymain): Likewise. * tests/qemuhelptest.c (mymain): Likewise. * tests/qemuxml2argvtest.c (mymain): Likewise. * tests/qemuxml2xmltest.c (mymain): Likewise. * tests/qparamtest.c (mymain): Likewise. * tests/sexpr2xmltest.c (mymain): Likewise. * tests/sockettest.c (mymain): Likewise. * tests/statstest.c (mymain): Likewise. * tests/storagepoolxml2xmltest.c (mymain): Likewise. * tests/storagevolxml2xmltest.c (mymain): Likewise. * tests/virbuftest.c (mymain): Likewise. * tests/virshtest.c (mymain): Likewise. * tests/vmx2xmltest.c (mymain): Likewise. * tests/xencapstest.c (mymain): Likewise. * tests/xmconfigtest.c (mymain): Likewise. * tests/xml2sexprtest.c (mymain): Likewise. * tests/xml2vmxtest.c (mymain): Likewise.
2011-04-29 20:21:20 +04:00
mymain(void)
2007-07-19 01:34:22 +04:00
{
int ret = 0;
g_autofree char *fakerootdir = NULL;
g_autoptr(GHashTable) capslatest = testQemuGetLatestCaps();
g_autoptr(GHashTable) qapiSchemaCache = virHashNew((GDestroyNotify) g_hash_table_unref);
g_autoptr(GHashTable) capscache = virHashNew(virObjectUnref);
struct testQemuConf testConf = { .capslatest = capslatest,
.capscache = capscache,
.qapiSchemaCache = qapiSchemaCache };
if (!capslatest)
return EXIT_FAILURE;
2007-07-19 01:34:22 +04:00
fakerootdir = g_strdup(FAKEROOTDIRTEMPLATE);
if (!g_mkdtemp(fakerootdir)) {
fprintf(stderr, "Cannot create fakerootdir");
abort();
}
g_setenv("LIBVIRT_FAKE_ROOT_DIR", fakerootdir, TRUE);
/* Set the timezone because we are mocking the time() function.
* If we don't do that, then localtime() may return unpredictable
* results. In order to detect things that just work by a blind
* chance, we need to set an virtual timezone that no libvirt
* developer resides in. */
if (g_setenv("TZ", "VIR00:30", TRUE) == FALSE) {
perror("g_setenv");
return EXIT_FAILURE;
}
if (qemuTestDriverInit(&driver) < 0)
return EXIT_FAILURE;
/* By default, the driver gets a virCaps instance that's suitable for
* tests that expect Linux as the host OS. We create another one for
* macOS and keep around pointers to both: this allows us to later
* pick the appropriate one for each test case */
linuxCaps = driver.caps;
macOSCaps = testQemuCapsInitMacOS();
driver.privileged = true;
VIR_FREE(driver.config->defaultTLSx509certdir);
driver.config->defaultTLSx509certdir = g_strdup("/etc/pki/qemu");
VIR_FREE(driver.config->vncTLSx509certdir);
driver.config->vncTLSx509certdir = g_strdup("/etc/pki/libvirt-vnc");
VIR_FREE(driver.config->spiceTLSx509certdir);
driver.config->spiceTLSx509certdir = g_strdup("/etc/pki/libvirt-spice");
VIR_FREE(driver.config->chardevTLSx509certdir);
driver.config->chardevTLSx509certdir = g_strdup("/etc/pki/libvirt-chardev");
VIR_FREE(driver.config->vxhsTLSx509certdir);
driver.config->vxhsTLSx509certdir = g_strdup("/etc/pki/libvirt-vxhs/dummy,path");
VIR_FREE(driver.config->nbdTLSx509certdir);
driver.config->nbdTLSx509certdir = g_strdup("/etc/pki/libvirt-nbd/dummy,path");
VIR_FREE(driver.config->hugetlbfs);
driver.config->hugetlbfs = g_new0(virHugeTLBFS, 2);
driver.config->nhugetlbfs = 2;
driver.config->hugetlbfs[0].mnt_dir = g_strdup("/dev/hugepages2M");
driver.config->hugetlbfs[1].mnt_dir = g_strdup("/dev/hugepages1G");
driver.config->hugetlbfs[0].size = 2048;
driver.config->hugetlbfs[0].deflt = true;
driver.config->hugetlbfs[1].size = 1048576;
driver.config->spiceTLS = 1;
driver.config->spicePassword = g_strdup("123456");
VIR_FREE(driver.config->memoryBackingDir);
driver.config->memoryBackingDir = g_strdup("/var/lib/libvirt/qemu/ram");
VIR_FREE(driver.config->nvramDir);
driver.config->nvramDir = g_strdup("/var/lib/libvirt/qemu/nvram");
virFileWrapperAddPrefix(SYSCONFDIR "/qemu/firmware",
abs_srcdir "/qemufirmwaredata/etc/qemu/firmware");
virFileWrapperAddPrefix(PREFIX "/share/qemu/firmware",
abs_srcdir "/qemufirmwaredata/usr/share/qemu/firmware");
virFileWrapperAddPrefix("/home/user/.config/qemu/firmware",
abs_srcdir "/qemufirmwaredata/home/user/.config/qemu/firmware");
virFileWrapperAddPrefix(SYSCONFDIR "/qemu/vhost-user",
abs_srcdir "/qemuvhostuserdata/etc/qemu/vhost-user");
virFileWrapperAddPrefix(PREFIX "/share/qemu/vhost-user",
abs_srcdir "/qemuvhostuserdata/usr/share/qemu/vhost-user");
virFileWrapperAddPrefix("/home/user/.config/qemu/vhost-user",
abs_srcdir "/qemuvhostuserdata/home/user/.config/qemu/vhost-user");
virFileWrapperAddPrefix("/usr/libexec/qemu/vhost-user",
abs_srcdir "/qemuvhostuserdata/usr/libexec/qemu/vhost-user");
/**
* The following set of macros allows testing of XML -> argv conversion with a
* real set of capabilities gathered from a real qemu copy. It is desired to use
* these for positive test cases as it provides combinations of flags which
* can be met in real life.
*
* The capabilities are taken from the real capabilities stored in
* tests/qemucapabilitiesdata.
*
* It is suggested to use the DO_TEST_CAPS_LATEST macro which always takes the
* most recent capability set. In cases when the new code would change behaviour
* the test cases should be forked using DO_TEST_CAPS_VER with the appropriate
* version.
*/
# define DO_TEST_FULL(_name, _suffix, ...) \
do { \
static struct testQemuInfo info = { \
.name = _name, \
}; \
testQemuInfoSetArgs(&info, &testConf, __VA_ARGS__); \
testInfoSetPaths(&info, _suffix); \
virTestRunLog(&ret, "QEMU XML-2-ARGV " _name _suffix, testCompareXMLToArgv, &info); \
testQemuInfoClear(&info); \
} while (0)
# define DO_TEST_CAPS_INTERNAL(name, arch, ver, ...) \
DO_TEST_FULL(name, "." arch "-" ver, \
ARG_CAPS_ARCH, arch, \
ARG_CAPS_VER, ver, \
__VA_ARGS__, \
ARG_END)
# define DO_TEST_CAPS_ARCH_LATEST_FULL(name, arch, ...) \
DO_TEST_CAPS_INTERNAL(name, arch, "latest", __VA_ARGS__)
# define DO_TEST_CAPS_ARCH_VER_FULL(name, arch, ver, ...) \
DO_TEST_CAPS_INTERNAL(name, arch, ver, __VA_ARGS__)
# define DO_TEST_CAPS_ARCH_LATEST(name, arch) \
DO_TEST_CAPS_ARCH_LATEST_FULL(name, arch, ARG_END)
# define DO_TEST_CAPS_ARCH_VER(name, arch, ver) \
DO_TEST_CAPS_ARCH_VER_FULL(name, arch, ver, ARG_END)
# define DO_TEST_CAPS_LATEST(name) \
DO_TEST_CAPS_ARCH_LATEST(name, "x86_64")
# define DO_TEST_CAPS_VER(name, ver) \
DO_TEST_CAPS_ARCH_VER(name, "x86_64", ver)
# define DO_TEST_CAPS_LATEST_PPC64(name) \
DO_TEST_CAPS_ARCH_LATEST(name, "ppc64")
# define DO_TEST_CAPS_LATEST_PPC64_HOSTCPU(name, hostcpu) \
DO_TEST_CAPS_ARCH_LATEST_FULL(name, "ppc64", \
ARG_CAPS_HOST_CPU_MODEL, hostcpu)
# define DO_TEST_CAPS_LATEST_PPC64_HOSTCPU_FAILURE(name, hostcpu) \
DO_TEST_CAPS_ARCH_LATEST_FULL(name, "ppc64", \
ARG_CAPS_HOST_CPU_MODEL, hostcpu, \
ARG_FLAGS, FLAG_EXPECT_FAILURE)
# define DO_TEST_CAPS_ARCH_LATEST_FAILURE(name, arch) \
DO_TEST_CAPS_ARCH_LATEST_FULL(name, arch, \
ARG_FLAGS, FLAG_EXPECT_FAILURE)
# define DO_TEST_CAPS_ARCH_VER_FAILURE(name, arch, ver) \
DO_TEST_CAPS_ARCH_VER_FULL(name, arch, ver, \
ARG_FLAGS, FLAG_EXPECT_FAILURE)
# define DO_TEST_CAPS_LATEST_FAILURE(name) \
DO_TEST_CAPS_ARCH_LATEST_FAILURE(name, "x86_64")
# define DO_TEST_CAPS_VER_FAILURE(name, ver) \
DO_TEST_CAPS_ARCH_VER_FAILURE(name, "x86_64", ver)
# define DO_TEST_CAPS_ARCH_LATEST_PARSE_ERROR(name, arch) \
DO_TEST_CAPS_ARCH_LATEST_FULL(name, arch, \
ARG_FLAGS, FLAG_EXPECT_PARSE_ERROR)
# define DO_TEST_CAPS_ARCH_VER_PARSE_ERROR(name, arch, ver) \
DO_TEST_CAPS_ARCH_VER_FULL(name, arch, ver, \
ARG_FLAGS, FLAG_EXPECT_PARSE_ERROR)
# define DO_TEST_CAPS_LATEST_PARSE_ERROR(name) \
DO_TEST_CAPS_ARCH_LATEST_PARSE_ERROR(name, "x86_64")
# define DO_TEST_CAPS_VER_PARSE_ERROR(name, ver) \
DO_TEST_CAPS_ARCH_VER_PARSE_ERROR(name, "x86_64", ver)
/* All the following macros require an explicit QEMU_CAPS_* list
* at the end of the argument list, or the NONE placeholder.
* */
# define DO_TEST(name, ...) \
DO_TEST_FULL(name, "", ARG_QEMU_CAPS, __VA_ARGS__, QEMU_CAPS_LAST, ARG_END)
# define DO_TEST_NOCAPS(name) \
DO_TEST_FULL(name, "", ARG_END)
# define DO_TEST_GIC(name, gic, ...) \
DO_TEST_FULL(name, "", \
ARG_GIC, gic, \
ARG_QEMU_CAPS, __VA_ARGS__, QEMU_CAPS_LAST, ARG_END)
# define DO_TEST_MACOS(name, ...) \
DO_TEST_FULL(name, "", \
ARG_HOST_OS, HOST_OS_MACOS, \
ARG_QEMU_CAPS, __VA_ARGS__, QEMU_CAPS_LAST, ARG_END)
# define DO_TEST_FAILURE(name, ...) \
DO_TEST_FULL(name, "", \
ARG_FLAGS, FLAG_EXPECT_FAILURE, \
ARG_QEMU_CAPS, __VA_ARGS__, QEMU_CAPS_LAST, ARG_END)
# define DO_TEST_FAILURE_NOCAPS(name) \
DO_TEST_FULL(name, "", ARG_FLAGS, FLAG_EXPECT_FAILURE, ARG_END)
# define DO_TEST_PARSE_ERROR(name, ...) \
DO_TEST_FULL(name, "", \
ARG_FLAGS, FLAG_EXPECT_PARSE_ERROR | FLAG_EXPECT_FAILURE, \
ARG_QEMU_CAPS, __VA_ARGS__, QEMU_CAPS_LAST, ARG_END)
# define DO_TEST_PARSE_ERROR_NOCAPS(name) \
DO_TEST_FULL(name, "", \
ARG_FLAGS, FLAG_EXPECT_PARSE_ERROR | FLAG_EXPECT_FAILURE, \
ARG_END)
/* Unset or set all envvars here that are copied in qemudBuildCommandLine
* using ADD_ENV_COPY, otherwise these tests may fail due to unexpected
* values for these envvars */
g_setenv("PATH", "/bin", TRUE);
g_setenv("USER", "test", TRUE);
g_setenv("LOGNAME", "test", TRUE);
g_setenv("HOME", "/home/test", TRUE);
g_setenv("LC_ALL", "C", TRUE);
g_unsetenv("TMPDIR");
g_unsetenv("LD_PRELOAD");
g_unsetenv("LD_LIBRARY_PATH");
g_unsetenv("DYLD_INSERT_LIBRARIES");
g_unsetenv("DYLD_FORCE_FLAT_NAMESPACE");
g_unsetenv("QEMU_AUDIO_DRV");
g_unsetenv("SDL_AUDIODRIVER");
2008-10-10 20:52:20 +04:00
DO_TEST_NOCAPS("minimal");
DO_TEST_PARSE_ERROR_NOCAPS("minimal-no-memory");
DO_TEST_CAPS_LATEST("genid");
DO_TEST_CAPS_LATEST("genid-auto");
DO_TEST_NOCAPS("machine-aliases1");
DO_TEST("machine-aliases2", QEMU_CAPS_KVM);
DO_TEST_NOCAPS("machine-core-on");
driver.config->dumpGuestCore = true;
DO_TEST_NOCAPS("machine-core-off");
driver.config->dumpGuestCore = false;
DO_TEST_CAPS_LATEST("machine-smm-on");
DO_TEST_CAPS_LATEST("machine-smm-off");
DO_TEST("machine-vmport-opt",
QEMU_CAPS_MACHINE_VMPORT_OPT);
DO_TEST_NOCAPS("default-kvm-host-arch");
DO_TEST_NOCAPS("default-qemu-host-arch");
DO_TEST_CAPS_LATEST("x86-kvm-32-on-64");
DO_TEST_CAPS_LATEST("boot-cdrom");
DO_TEST_CAPS_LATEST("boot-network");
DO_TEST_CAPS_LATEST("boot-floppy");
DO_TEST_CAPS_LATEST("boot-floppy-q35");
DO_TEST_CAPS_LATEST("boot-multi");
DO_TEST_CAPS_LATEST("boot-menu-enable");
DO_TEST_CAPS_LATEST("boot-menu-enable-with-timeout");
DO_TEST_CAPS_LATEST_PARSE_ERROR("boot-menu-enable-with-timeout-invalid");
DO_TEST_CAPS_LATEST("boot-menu-disable");
DO_TEST_CAPS_LATEST("boot-menu-disable-drive");
DO_TEST_CAPS_LATEST_PARSE_ERROR("boot-dev+order");
DO_TEST_CAPS_LATEST("boot-order");
DO_TEST_CAPS_LATEST("boot-complex");
2012-09-18 14:32:07 +04:00
DO_TEST_CAPS_LATEST("audio-none-minimal");
DO_TEST_CAPS_LATEST("audio-alsa-minimal");
DO_TEST_CAPS_LATEST("audio-coreaudio-minimal");
DO_TEST_CAPS_LATEST("audio-jack-minimal");
DO_TEST_CAPS_LATEST("audio-oss-minimal");
DO_TEST_CAPS_LATEST("audio-pulseaudio-minimal");
DO_TEST_CAPS_LATEST("audio-sdl-minimal");
DO_TEST_CAPS_LATEST("audio-spice-minimal");
DO_TEST_CAPS_LATEST("audio-file-minimal");
DO_TEST_CAPS_LATEST("audio-none-best");
DO_TEST_CAPS_LATEST("audio-alsa-best");
DO_TEST_CAPS_LATEST("audio-coreaudio-best");
DO_TEST_CAPS_LATEST("audio-oss-best");
DO_TEST_CAPS_LATEST("audio-pulseaudio-best");
DO_TEST_CAPS_LATEST("audio-sdl-best");
DO_TEST_CAPS_LATEST("audio-spice-best");
DO_TEST_CAPS_LATEST("audio-file-best");
DO_TEST_CAPS_LATEST("audio-none-full");
DO_TEST_CAPS_LATEST("audio-alsa-full");
DO_TEST_CAPS_LATEST("audio-coreaudio-full");
DO_TEST_CAPS_LATEST("audio-jack-full");
DO_TEST_CAPS_LATEST("audio-oss-full");
DO_TEST_CAPS_LATEST("audio-pulseaudio-full");
DO_TEST_CAPS_LATEST("audio-sdl-full");
DO_TEST_CAPS_LATEST("audio-spice-full");
DO_TEST_CAPS_LATEST("audio-file-full");
DO_TEST_CAPS_LATEST("audio-many-backends");
/* Validate auto-creation of <audio> for legacy compat */
g_setenv("QEMU_AUDIO_DRV", "sdl", TRUE);
g_setenv("SDL_AUDIODRIVER", "esd", TRUE);
DO_TEST("audio-default-sdl", QEMU_CAPS_DEVICE_CIRRUS_VGA, QEMU_CAPS_SDL);
DO_TEST_CAPS_LATEST("audio-default-sdl");
g_unsetenv("QEMU_AUDIO_DRV");
g_unsetenv("SDL_AUDIODRIVER");
g_setenv("QEMU_AUDIO_DRV", "alsa", TRUE);
driver.config->vncAllowHostAudio = true;
DO_TEST("audio-default-vnc", QEMU_CAPS_VNC, QEMU_CAPS_DEVICE_CIRRUS_VGA);
DO_TEST_CAPS_LATEST("audio-default-vnc");
driver.config->vncAllowHostAudio = false;
g_unsetenv("QEMU_AUDIO_DRV");
DO_TEST("audio-default-spice", QEMU_CAPS_SPICE, QEMU_CAPS_DEVICE_CIRRUS_VGA);
DO_TEST_CAPS_LATEST("audio-default-spice");
g_setenv("QEMU_AUDIO_DRV", "alsa", TRUE);
driver.config->nogfxAllowHostAudio = true;
DO_TEST_CAPS_LATEST("audio-default-nographics");
driver.config->nogfxAllowHostAudio = false;
g_unsetenv("QEMU_AUDIO_DRV");
DO_TEST_NOCAPS("reboot-timeout-disabled");
DO_TEST_NOCAPS("reboot-timeout-enabled");
2012-09-18 14:32:07 +04:00
DO_TEST("firmware-manual-bios",
QEMU_CAPS_DEVICE_ISA_SERIAL);
conf: support stateless UEFI firmware Normally when an UEFI firmware is marked as read-only, an associated NVRAM file will be created. Some builds of UEFI firmware, however, wish to remain stateless and so will be read-only, but never have any NVRAM file. To represent this concept a 'stateless' tristate bool attribute is introduced on the <loader/> element. There are rather a large number of permutations to consider. With default firmware selection * <os/> => Historic default, no change * <os> <loader stateless='yes'/> </os> => Explicit version of historic default, no change * <os> <loader stateless='no'/> </os> => Invalid, bios is always stateless With manual legacy BIOS selection * <os> <loader>/path/to/seabios</loader> ... </os> => Historic default, no change * <os> <loader stateless='yes'>/path/to/seabios</loader> ... </os> => Explicit version of historic default, no change * <os> <loader stateless='no'>/path/to/seabios</loader> ... </os> => Invalid, bios is always stateless With manual UEFI selection * <os> <loader type='pflash'>/path/to/edk2</loader> ... </os> => Historic default, no change * <os> <loader type='pflash' stateless='yes'>/path/to/edk2</loader> ... </os> => Skip auto-filling NVRAM / template * <os> <loader type='pflash' stateless='no'>/path/to/edk2</loader> ... </os> => Explicit version of historic default, no change With automatic firmware selection * <os firmware='bios'/> => Historic default, no change * <os firmware='bios'> <loader stateless='yes'/> </os> => Explicit version of historic default, no change * <os firmware='bios'> <loader stateless='no'/> </os> => Invalid, bios is always stateless * <os firmware='uefi'/> => Historic default, no change * <os firmware='uefi'> <loader stateless='yes'/> </os> => Skip auto-filling NVRAM / template * <os firmware='uefi'> <loader stateless='no'/> </os> => Explicit version of historic default, no change Reviewed-by: Michal Privoznik <mprivozn@redhat.com> Signed-off-by: Daniel P. Berrangé <berrange@redhat.com>
2022-07-22 17:27:55 +03:00
DO_TEST("firmware-manual-bios-stateless",
QEMU_CAPS_DEVICE_ISA_SERIAL);
DO_TEST_PARSE_ERROR("firmware-manual-bios-not-stateless",
QEMU_CAPS_DEVICE_ISA_SERIAL);
DO_TEST_NOCAPS("firmware-manual-efi");
DO_TEST_PARSE_ERROR_NOCAPS("firmware-manual-efi-no-path");
DO_TEST_CAPS_LATEST_PARSE_ERROR("firmware-manual-efi-features");
DO_TEST_CAPS_LATEST("firmware-manual-bios-rw");
DO_TEST_CAPS_LATEST("firmware-manual-bios-rw-implicit");
DO_TEST("firmware-manual-efi-secure",
QEMU_CAPS_DEVICE_DMI_TO_PCI_BRIDGE,
QEMU_CAPS_DEVICE_PCI_BRIDGE,
qemu: initially reserve one open pcie-root-port for hotplug For machinetypes with a pci-root bus (all legacy PCI), libvirt will make a "fake" reservation for one extra slot prior to assigning addresses to unaddressed PCI endpoint devices in the domain. This will trigger auto-adding of a pci-bridge for the final device to be assigned an address *if that device would have otherwise instead been the last device on the last available pci-bridge*; thus it assures that there will always be at least one slot left open in the domain's bus topology for expansion (which is important both for hotplug (since a new pci-bridge can't be added while the guest is running) as well as for offline additions to the config (since adding a new device might otherwise in some cases require re-addressing existing devices, which we want to avoid)). It's important to note that for the above case (legacy PCI), we must check for the special case of all slots on all buses being occupied *prior to assigning any addresses*, and avoid attempting to reserve the extra address in that case, because there is no free address in the existing topology, so no place to auto-add a pci-bridge for expansion (i.e. it would always fail anyway). Since that condition can only be reached by manual intervention, this is acceptable. For machinetypes with pcie-root (Q35, aarch64 virt), libvirt's methodology for automatically expanding the bus topology is different - pcie-root-ports are plugged into slots (soon to be functions) of pcie-root as needed, and the new endpoint devices are assigned to the single slot in each pcie-root-port. This is done so that the devices are, by default, hotpluggable (the slots of pcie-root don't support hotplug, but the single slot of the pcie-root-port does). Since pcie-root-ports can only be plugged into pcie-root, and we don't auto-assign endpoint devices to the pcie-root slots, this means topology expansion doesn't compete with endpoint devices for slots, so we don't need to worry about checking for all "useful" slots being free *prior* to assigning addresses to new endpoint devices - as a matter of fact, if we attempt to reserve the open slots before the used slots, it can lead to errors. Instead this patch just reserves one slot for a "future potential" PCIe device after doing the assignment for actual devices, but only if the only PCI controller defined prior to starting address assignment was pcie-root, and only if we auto-added at least one PCI controller during address assignment. This assures two things: 1) that reserving the open slots will only be done when the domain is initially defined, never at any time after, and 2) that if the user understands enough about PCI controllers that they are adding them manually, that we don't mess up their plan by adding extras - if they know enough to add one pcie-root-port, or to manually assign addresses such that no pcie-root-ports are needed, they know enough to add extra pcie-root-ports if they want them (this could be called the "libguestfs clause", since libguestfs needs to be able to create domains with as few devices/controllers as possible). This is set to reserve a single free port for now, but could be increased in the future if public sentiment goes in that direction (it's easy to increase later, but essentially impossible to decrease)
2016-09-28 03:37:30 +03:00
QEMU_CAPS_DEVICE_IOH3420,
QEMU_CAPS_ICH9_AHCI,
QEMU_CAPS_VIRTIO_SCSI);
DO_TEST_CAPS_LATEST("firmware-manual-efi-stateless");
DO_TEST_CAPS_LATEST("firmware-manual-efi-nvram-template");
conf: support stateless UEFI firmware Normally when an UEFI firmware is marked as read-only, an associated NVRAM file will be created. Some builds of UEFI firmware, however, wish to remain stateless and so will be read-only, but never have any NVRAM file. To represent this concept a 'stateless' tristate bool attribute is introduced on the <loader/> element. There are rather a large number of permutations to consider. With default firmware selection * <os/> => Historic default, no change * <os> <loader stateless='yes'/> </os> => Explicit version of historic default, no change * <os> <loader stateless='no'/> </os> => Invalid, bios is always stateless With manual legacy BIOS selection * <os> <loader>/path/to/seabios</loader> ... </os> => Historic default, no change * <os> <loader stateless='yes'>/path/to/seabios</loader> ... </os> => Explicit version of historic default, no change * <os> <loader stateless='no'>/path/to/seabios</loader> ... </os> => Invalid, bios is always stateless With manual UEFI selection * <os> <loader type='pflash'>/path/to/edk2</loader> ... </os> => Historic default, no change * <os> <loader type='pflash' stateless='yes'>/path/to/edk2</loader> ... </os> => Skip auto-filling NVRAM / template * <os> <loader type='pflash' stateless='no'>/path/to/edk2</loader> ... </os> => Explicit version of historic default, no change With automatic firmware selection * <os firmware='bios'/> => Historic default, no change * <os firmware='bios'> <loader stateless='yes'/> </os> => Explicit version of historic default, no change * <os firmware='bios'> <loader stateless='no'/> </os> => Invalid, bios is always stateless * <os firmware='uefi'/> => Historic default, no change * <os firmware='uefi'> <loader stateless='yes'/> </os> => Skip auto-filling NVRAM / template * <os firmware='uefi'> <loader stateless='no'/> </os> => Explicit version of historic default, no change Reviewed-by: Michal Privoznik <mprivozn@redhat.com> Signed-off-by: Daniel P. Berrangé <berrange@redhat.com>
2022-07-22 17:27:55 +03:00
DO_TEST_CAPS_LATEST_PARSE_ERROR("firmware-manual-efi-nvram-template-stateless");
DO_TEST_CAPS_LATEST("firmware-manual-efi-nvram-network-iscsi");
DO_TEST_CAPS_LATEST("firmware-manual-efi-nvram-network-nbd");
DO_TEST_CAPS_LATEST("firmware-manual-efi-nvram-file");
conf: support stateless UEFI firmware Normally when an UEFI firmware is marked as read-only, an associated NVRAM file will be created. Some builds of UEFI firmware, however, wish to remain stateless and so will be read-only, but never have any NVRAM file. To represent this concept a 'stateless' tristate bool attribute is introduced on the <loader/> element. There are rather a large number of permutations to consider. With default firmware selection * <os/> => Historic default, no change * <os> <loader stateless='yes'/> </os> => Explicit version of historic default, no change * <os> <loader stateless='no'/> </os> => Invalid, bios is always stateless With manual legacy BIOS selection * <os> <loader>/path/to/seabios</loader> ... </os> => Historic default, no change * <os> <loader stateless='yes'>/path/to/seabios</loader> ... </os> => Explicit version of historic default, no change * <os> <loader stateless='no'>/path/to/seabios</loader> ... </os> => Invalid, bios is always stateless With manual UEFI selection * <os> <loader type='pflash'>/path/to/edk2</loader> ... </os> => Historic default, no change * <os> <loader type='pflash' stateless='yes'>/path/to/edk2</loader> ... </os> => Skip auto-filling NVRAM / template * <os> <loader type='pflash' stateless='no'>/path/to/edk2</loader> ... </os> => Explicit version of historic default, no change With automatic firmware selection * <os firmware='bios'/> => Historic default, no change * <os firmware='bios'> <loader stateless='yes'/> </os> => Explicit version of historic default, no change * <os firmware='bios'> <loader stateless='no'/> </os> => Invalid, bios is always stateless * <os firmware='uefi'/> => Historic default, no change * <os firmware='uefi'> <loader stateless='yes'/> </os> => Skip auto-filling NVRAM / template * <os firmware='uefi'> <loader stateless='no'/> </os> => Explicit version of historic default, no change Reviewed-by: Michal Privoznik <mprivozn@redhat.com> Signed-off-by: Daniel P. Berrangé <berrange@redhat.com>
2022-07-22 17:27:55 +03:00
DO_TEST_CAPS_LATEST_PARSE_ERROR("firmware-manual-efi-nvram-stateless");
/* Make sure all combinations of ACPI and UEFI behave as expected */
DO_TEST_NOCAPS("firmware-manual-efi-acpi-aarch64");
DO_TEST_NOCAPS("firmware-manual-efi-acpi-q35");
DO_TEST_NOCAPS("firmware-manual-efi-noacpi-aarch64");
DO_TEST_PARSE_ERROR_NOCAPS("firmware-manual-efi-noacpi-q35");
DO_TEST_PARSE_ERROR_NOCAPS("firmware-manual-noefi-acpi-aarch64");
DO_TEST_NOCAPS("firmware-manual-noefi-acpi-q35");
DO_TEST_NOCAPS("firmware-manual-noefi-noacpi-aarch64");
DO_TEST_NOCAPS("firmware-manual-noefi-noacpi-q35");
DO_TEST_CAPS_LATEST("firmware-auto-bios");
conf: support stateless UEFI firmware Normally when an UEFI firmware is marked as read-only, an associated NVRAM file will be created. Some builds of UEFI firmware, however, wish to remain stateless and so will be read-only, but never have any NVRAM file. To represent this concept a 'stateless' tristate bool attribute is introduced on the <loader/> element. There are rather a large number of permutations to consider. With default firmware selection * <os/> => Historic default, no change * <os> <loader stateless='yes'/> </os> => Explicit version of historic default, no change * <os> <loader stateless='no'/> </os> => Invalid, bios is always stateless With manual legacy BIOS selection * <os> <loader>/path/to/seabios</loader> ... </os> => Historic default, no change * <os> <loader stateless='yes'>/path/to/seabios</loader> ... </os> => Explicit version of historic default, no change * <os> <loader stateless='no'>/path/to/seabios</loader> ... </os> => Invalid, bios is always stateless With manual UEFI selection * <os> <loader type='pflash'>/path/to/edk2</loader> ... </os> => Historic default, no change * <os> <loader type='pflash' stateless='yes'>/path/to/edk2</loader> ... </os> => Skip auto-filling NVRAM / template * <os> <loader type='pflash' stateless='no'>/path/to/edk2</loader> ... </os> => Explicit version of historic default, no change With automatic firmware selection * <os firmware='bios'/> => Historic default, no change * <os firmware='bios'> <loader stateless='yes'/> </os> => Explicit version of historic default, no change * <os firmware='bios'> <loader stateless='no'/> </os> => Invalid, bios is always stateless * <os firmware='uefi'/> => Historic default, no change * <os firmware='uefi'> <loader stateless='yes'/> </os> => Skip auto-filling NVRAM / template * <os firmware='uefi'> <loader stateless='no'/> </os> => Explicit version of historic default, no change Reviewed-by: Michal Privoznik <mprivozn@redhat.com> Signed-off-by: Daniel P. Berrangé <berrange@redhat.com>
2022-07-22 17:27:55 +03:00
DO_TEST_CAPS_LATEST("firmware-auto-bios-stateless");
DO_TEST_CAPS_LATEST_PARSE_ERROR("firmware-auto-bios-not-stateless");
DO_TEST_CAPS_LATEST_PARSE_ERROR("firmware-auto-bios-nvram");
DO_TEST_CAPS_LATEST("firmware-auto-efi");
DO_TEST_CAPS_LATEST("firmware-auto-efi-stateless");
DO_TEST_CAPS_LATEST("firmware-auto-efi-nvram");
DO_TEST_CAPS_LATEST("firmware-auto-efi-loader-secure");
DO_TEST_CAPS_LATEST_PARSE_ERROR("firmware-auto-efi-loader-insecure");
DO_TEST_CAPS_LATEST_PARSE_ERROR("firmware-auto-efi-loader-path");
DO_TEST_CAPS_LATEST("firmware-auto-efi-secboot");
DO_TEST_CAPS_LATEST("firmware-auto-efi-no-secboot");
DO_TEST_CAPS_LATEST("firmware-auto-efi-enrolled-keys");
DO_TEST_CAPS_LATEST("firmware-auto-efi-no-enrolled-keys");
DO_TEST_CAPS_LATEST_PARSE_ERROR("firmware-auto-efi-enrolled-keys-no-secboot");
DO_TEST_CAPS_ARCH_LATEST("firmware-auto-efi-aarch64", "aarch64");
DO_TEST_NOCAPS("clock-utc");
DO_TEST_NOCAPS("clock-localtime");
DO_TEST_NOCAPS("clock-localtime-basis-localtime");
DO_TEST_NOCAPS("clock-variable");
DO_TEST_NOCAPS("clock-france");
DO_TEST_NOCAPS("clock-hpet-off");
DO_TEST("clock-catchup", QEMU_CAPS_KVM_PIT_TICK_POLICY);
DO_TEST_NOCAPS("cpu-kvmclock");
DO_TEST_NOCAPS("cpu-host-kvmclock");
DO_TEST("kvmclock", QEMU_CAPS_KVM);
DO_TEST("clock-timer-hyperv-rtc", QEMU_CAPS_KVM);
DO_TEST_NOCAPS("clock-realtime");
DO_TEST_CAPS_LATEST("clock-absolute");
DO_TEST_CAPS_LATEST("controller-usb-order");
DO_TEST("controller-order",
QEMU_CAPS_KVM,
QEMU_CAPS_PIIX3_USB_UHCI,
QEMU_CAPS_CCID_PASSTHRU,
QEMU_CAPS_SPICE,
QEMU_CAPS_HDA_DUPLEX,
QEMU_CAPS_USB_HUB,
QEMU_CAPS_DEVICE_ISA_SERIAL,
QEMU_CAPS_DEVICE_CIRRUS_VGA);
/* 'eoi' cpu feature with an explicit CPU defined */
DO_TEST_CAPS_LATEST("cpu-eoi-disabled");
DO_TEST_CAPS_LATEST("cpu-eoi-enabled");
/* 'eoi' cpu feature without an explicit CPU defined */
DO_TEST_CAPS_LATEST("eoi-disabled");
DO_TEST_CAPS_LATEST("eoi-enabled");
DO_TEST_CAPS_LATEST("pv-spinlock-disabled");
DO_TEST_CAPS_LATEST("pv-spinlock-enabled");
DO_TEST_CAPS_LATEST("kvmclock+eoi-disabled");
DO_TEST_CAPS_LATEST("hyperv");
DO_TEST_CAPS_LATEST("hyperv-off");
DO_TEST_CAPS_LATEST("hyperv-panic");
DO_TEST_CAPS_VER("hyperv-passthrough", "6.1.0");
DO_TEST_CAPS_LATEST("hyperv-passthrough");
DO_TEST_CAPS_LATEST("hyperv-stimer-direct");
DO_TEST_NOCAPS("kvm-features");
DO_TEST_NOCAPS("kvm-features-off");
DO_TEST_NOCAPS("pmu-feature");
DO_TEST_NOCAPS("pmu-feature-off");
DO_TEST_CAPS_LATEST("pages-discard");
DO_TEST_CAPS_LATEST("pages-discard-hugepages");
DO_TEST_CAPS_LATEST("pages-dimm-discard");
DO_TEST_CAPS_LATEST("hugepages-default");
DO_TEST_CAPS_LATEST("hugepages-default-2M");
DO_TEST_CAPS_LATEST("hugepages-default-system-size");
DO_TEST_CAPS_LATEST_FAILURE("hugepages-default-5M");
DO_TEST_PARSE_ERROR_NOCAPS("hugepages-default-1G-nodeset-2M");
DO_TEST_CAPS_LATEST("hugepages-nodeset");
DO_TEST_CAPS_LATEST_PARSE_ERROR("hugepages-nodeset-nonexist");
DO_TEST_CAPS_LATEST("hugepages-numa-default");
DO_TEST_CAPS_LATEST("hugepages-numa-default-2M");
DO_TEST_CAPS_LATEST("hugepages-numa-default-dimm");
DO_TEST_CAPS_LATEST("hugepages-numa-nodeset");
DO_TEST_CAPS_LATEST("hugepages-numa-nodeset-part");
DO_TEST_CAPS_LATEST_PARSE_ERROR("hugepages-numa-nodeset-nonexist");
DO_TEST_CAPS_LATEST("hugepages-shared");
DO_TEST_PARSE_ERROR_NOCAPS("hugepages-memaccess-invalid");
DO_TEST_CAPS_LATEST("hugepages-memaccess");
DO_TEST_CAPS_LATEST("hugepages-memaccess2");
DO_TEST_PARSE_ERROR("hugepages-memaccess3",
QEMU_CAPS_OBJECT_MEMORY_RAM,
QEMU_CAPS_OBJECT_MEMORY_FILE);
DO_TEST_CAPS_LATEST("hugepages-memaccess3");
DO_TEST_CAPS_LATEST("hugepages-nvdimm");
DO_TEST_NOCAPS("nosharepages");
DO_TEST_CAPS_ARCH_LATEST_PARSE_ERROR("non-x86_64-timer-error", "s390x");
DO_TEST_CAPS_LATEST("disk-cdrom");
DO_TEST_CAPS_LATEST("disk-cdrom-empty-network-invalid");
DO_TEST_CAPS_LATEST("disk-cdrom-bus-other");
DO_TEST_CAPS_LATEST("disk-cdrom-network");
DO_TEST_CAPS_LATEST("disk-cdrom-tray");
DO_TEST_CAPS_LATEST("disk-floppy");
DO_TEST_CAPS_LATEST("disk-floppy-q35");
DO_TEST_CAPS_ARCH_LATEST_FAILURE("disk-floppy-pseries", "ppc64");
DO_TEST_CAPS_LATEST("disk-floppy-tray");
DO_TEST_CAPS_LATEST("disk-virtio");
DO_TEST_CAPS_ARCH_LATEST("disk-virtio-ccw", "s390x");
DO_TEST_CAPS_ARCH_LATEST("disk-virtio-ccw-many", "s390x");
DO_TEST_CAPS_ARCH_LATEST("disk-virtio-s390-zpci", "s390x");
DO_TEST_CAPS_LATEST("disk-order");
DO_TEST_CAPS_LATEST("disk-virtio-queues");
DO_TEST_CAPS_LATEST("disk-boot-disk");
DO_TEST_CAPS_LATEST("disk-boot-cdrom");
DO_TEST_CAPS_LATEST("floppy-drive-fat");
DO_TEST_CAPS_LATEST("disk-readonly-disk");
DO_TEST_CAPS_LATEST("disk-fmt-qcow");
DO_TEST_CAPS_LATEST_PARSE_ERROR("disk-fmt-cow");
DO_TEST_CAPS_LATEST_PARSE_ERROR("disk-fmt-dir");
DO_TEST_CAPS_LATEST_PARSE_ERROR("disk-fmt-iso");
DO_TEST_CAPS_LATEST("disk-shared");
DO_TEST_CAPS_LATEST_PARSE_ERROR("disk-shared-qcow");
DO_TEST_CAPS_LATEST("disk-error-policy");
DO_TEST_CAPS_ARCH_LATEST("disk-error-policy-s390x", "s390x");
DO_TEST_CAPS_LATEST("disk-cache");
DO_TEST_CAPS_LATEST("disk-metadata-cache");
DO_TEST_CAPS_LATEST("disk-transient");
DO_TEST_CAPS_LATEST("disk-network-nbd");
DO_TEST_CAPS_LATEST("disk-network-iscsi");
DO_TEST_CAPS_LATEST_PARSE_ERROR("disk-network-iscsi-auth-secrettype-invalid");
DO_TEST_CAPS_LATEST_PARSE_ERROR("disk-network-iscsi-auth-wrong-secrettype");
DO_TEST_CAPS_LATEST_PARSE_ERROR("disk-network-source-auth-both");
DO_TEST_CAPS_LATEST("disk-network-gluster");
DO_TEST_CAPS_LATEST("disk-network-rbd");
DO_TEST_CAPS_VER_PARSE_ERROR("disk-network-rbd-encryption", "6.0.0");
DO_TEST_CAPS_LATEST("disk-network-rbd-encryption");
DO_TEST_CAPS_LATEST_PARSE_ERROR("disk-encryption-wrong");
DO_TEST_CAPS_LATEST("disk-network-rbd-no-colon");
/* qemu-6.0 is the last qemu version supporting sheepdog */
DO_TEST_CAPS_VER("disk-network-sheepdog", "6.0.0");
DO_TEST_CAPS_LATEST("disk-network-source-auth");
DO_TEST_CAPS_LATEST("disk-network-nfs");
driver.config->vxhsTLS = 1;
driver.config->nbdTLSx509secretUUID = g_strdup("6fd3f62d-9fe7-4a4e-a869-7acd6376d8ea");
driver.config->vxhsTLSx509secretUUID = g_strdup("6fd3f62d-9fe7-4a4e-a869-7acd6376d8ea");
DO_TEST_CAPS_VER("disk-network-tlsx509-nbd", "5.2.0");
DO_TEST_CAPS_LATEST("disk-network-tlsx509-nbd");
DO_TEST_CAPS_VER_PARSE_ERROR("disk-network-tlsx509-nbd-hostname", "6.2.0");
DO_TEST_CAPS_LATEST("disk-network-tlsx509-nbd-hostname");
DO_TEST_CAPS_VER("disk-network-tlsx509-vxhs", "5.0.0");
DO_TEST_CAPS_LATEST("disk-network-http");
driver.config->vxhsTLS = 0;
VIR_FREE(driver.config->vxhsTLSx509certdir);
DO_TEST_CAPS_LATEST("disk-no-boot");
DO_TEST_CAPS_LATEST("disk-nvme");
DO_TEST_CAPS_VER("disk-vhostuser-numa", "4.2.0");
DO_TEST_CAPS_LATEST("disk-vhostuser-numa");
DO_TEST_CAPS_LATEST("disk-vhostuser");
DO_TEST_CAPS_LATEST_PARSE_ERROR("disk-device-lun-type-invalid");
DO_TEST_CAPS_LATEST_PARSE_ERROR("disk-attaching-partition-nosupport");
DO_TEST_CAPS_LATEST("disk-usb-device");
DO_TEST_CAPS_LATEST("disk-usb-device-removable");
DO_TEST_CAPS_LATEST_PARSE_ERROR("disk-usb-pci");
DO_TEST_CAPS_LATEST("disk-scsi");
DO_TEST_CAPS_LATEST("disk-scsi-device-auto");
DO_TEST_CAPS_LATEST("disk-scsi-disk-split");
DO_TEST_CAPS_LATEST("disk-scsi-disk-wwn");
DO_TEST_CAPS_LATEST("disk-scsi-disk-vpd");
DO_TEST_CAPS_LATEST_PARSE_ERROR("disk-scsi-disk-vpd-build-error");
DO_TEST_CAPS_LATEST("controller-virtio-scsi");
DO_TEST_CAPS_LATEST("disk-sata-device");
DO_TEST_CAPS_LATEST("disk-aio");
DO_TEST_CAPS_LATEST("disk-aio-io_uring");
DO_TEST_CAPS_LATEST("disk-source-pool");
DO_TEST_CAPS_LATEST("disk-source-pool-mode");
DO_TEST_CAPS_LATEST("disk-ioeventfd");
DO_TEST_CAPS_LATEST("disk-copy_on_read");
DO_TEST_CAPS_LATEST("disk-discard");
DO_TEST_CAPS_LATEST("disk-detect-zeroes");
DO_TEST_CAPS_LATEST("disk-snapshot");
DO_TEST_CAPS_LATEST_PARSE_ERROR("disk-same-targets");
DO_TEST_CAPS_LATEST_PARSE_ERROR("disk-missing-target-invalid");
DO_TEST_CAPS_LATEST_PARSE_ERROR("disk-address-conflict");
DO_TEST_CAPS_LATEST_PARSE_ERROR("disk-hostdev-scsi-address-conflict");
DO_TEST_CAPS_LATEST_PARSE_ERROR("hostdevs-drive-address-conflict");
DO_TEST_CAPS_LATEST("event_idx");
DO_TEST_CAPS_LATEST("virtio-lun");
DO_TEST_CAPS_LATEST("disk-scsi-lun-passthrough");
DO_TEST_CAPS_LATEST("disk-serial");
DO_TEST_CAPS_LATEST_PARSE_ERROR("disk-fdc-incompatible-address");
DO_TEST_CAPS_LATEST_PARSE_ERROR("disk-ide-incompatible-address");
DO_TEST_CAPS_LATEST_PARSE_ERROR("disk-sata-incompatible-address");
DO_TEST_CAPS_LATEST_PARSE_ERROR("disk-scsi-incompatible-address");
DO_TEST_CAPS_LATEST("disk-backing-chains-index");
DO_TEST_CAPS_LATEST("disk-backing-chains-noindex");
DO_TEST_CAPS_LATEST("disk-slices");
DO_TEST_CAPS_LATEST("disk-rotation");
DO_TEST_CAPS_ARCH_LATEST("disk-arm-virtio-sd", "aarch64");
DO_TEST_CAPS_LATEST("encrypted-disk");
DO_TEST_CAPS_LATEST("encrypted-disk-usage");
DO_TEST_CAPS_LATEST("luks-disks");
DO_TEST_CAPS_LATEST("luks-disks-source");
DO_TEST_CAPS_VER("luks-disks-source-qcow2", "5.2.0");
DO_TEST_CAPS_LATEST("luks-disks-source-qcow2");
DO_TEST_CAPS_LATEST_PARSE_ERROR("luks-disk-invalid");
DO_TEST_CAPS_LATEST_PARSE_ERROR("luks-disks-source-both");
DO_TEST_CAPS_LATEST("disk-ide-split");
DO_TEST_CAPS_LATEST("disk-ide-wwn");
DO_TEST_CAPS_LATEST("disk-geometry");
DO_TEST_CAPS_LATEST("disk-blockio");
DO_TEST_CAPS_VER("disk-virtio-scsi-reservations", "5.2.0");
DO_TEST_CAPS_LATEST("disk-virtio-scsi-reservations");
DO_TEST("graphics-egl-headless",
QEMU_CAPS_DEVICE_CIRRUS_VGA,
QEMU_CAPS_EGL_HEADLESS);
DO_TEST_CAPS_LATEST("graphics-egl-headless");
DO_TEST_CAPS_LATEST("graphics-egl-headless-rendernode");
DO_TEST_CAPS_LATEST("graphics-vnc");
DO_TEST_CAPS_LATEST("graphics-vnc-socket");
DO_TEST_CAPS_LATEST("graphics-vnc-websocket");
DO_TEST_CAPS_LATEST("graphics-vnc-policy");
DO_TEST_CAPS_LATEST("graphics-vnc-power");
DO_TEST_CAPS_LATEST("graphics-vnc-no-listen-attr");
DO_TEST_CAPS_LATEST("graphics-vnc-remove-generated-socket");
driver.config->vncAutoUnixSocket = true;
DO_TEST_CAPS_LATEST("graphics-vnc-auto-socket-cfg");
driver.config->vncAutoUnixSocket = false;
DO_TEST_CAPS_LATEST("graphics-vnc-auto-socket");
DO_TEST_CAPS_LATEST("graphics-vnc-none");
DO_TEST_CAPS_LATEST("graphics-vnc-socket-new-cmdline");
2009-03-16 16:54:26 +03:00
driver.config->vncSASL = 1;
VIR_FREE(driver.config->vncSASLdir);
driver.config->vncSASLdir = g_strdup("/root/.sasl2");
DO_TEST_CAPS_LATEST("graphics-vnc-sasl");
driver.config->vncTLS = 1;
driver.config->vncTLSx509verify = 1;
DO_TEST_CAPS_LATEST("graphics-vnc-tls");
driver.config->vncTLSx509secretUUID = g_strdup("6fd3f62d-9fe7-4a4e-a869-7acd6376d8ea");
DO_TEST_CAPS_VER("graphics-vnc-tls-secret", "5.2.0");
DO_TEST_CAPS_LATEST("graphics-vnc-tls-secret");
VIR_FREE(driver.config->vncTLSx509secretUUID);
driver.config->vncSASL = driver.config->vncTLSx509verify = driver.config->vncTLS = 0;
VIR_FREE(driver.config->vncSASLdir);
VIR_FREE(driver.config->vncTLSx509certdir);
DO_TEST_CAPS_LATEST("graphics-vnc-egl-headless");
2009-03-16 16:54:26 +03:00
DO_TEST("graphics-sdl",
QEMU_CAPS_DEVICE_VGA, QEMU_CAPS_SDL);
DO_TEST_CAPS_LATEST_PARSE_ERROR("graphics-sdl-egl-headless");
DO_TEST("graphics-sdl-fullscreen",
QEMU_CAPS_DEVICE_CIRRUS_VGA, QEMU_CAPS_SDL);
DO_TEST_CAPS_LATEST("graphics-spice");
DO_TEST_CAPS_LATEST("graphics-spice-no-args");
driver.config->spiceSASL = 1;
driver.config->spiceSASLdir = g_strdup("/root/.sasl2");
DO_TEST_CAPS_LATEST("graphics-spice-sasl");
VIR_FREE(driver.config->spiceSASLdir);
driver.config->spiceSASL = 0;
DO_TEST_CAPS_LATEST("graphics-spice-agentmouse");
DO_TEST_CAPS_LATEST("graphics-spice-compression");
DO_TEST_CAPS_LATEST("graphics-spice-timeout");
DO_TEST_CAPS_LATEST("graphics-spice-qxl-vga");
DO_TEST_CAPS_LATEST("graphics-spice-usb-redir");
DO_TEST_CAPS_LATEST("graphics-spice-agent-file-xfer");
DO_TEST_CAPS_LATEST("graphics-spice-socket");
DO_TEST_CAPS_LATEST("graphics-spice-auto-socket");
driver.config->spiceAutoUnixSocket = true;
DO_TEST_CAPS_LATEST("graphics-spice-auto-socket-cfg");
driver.config->spiceAutoUnixSocket = false;
DO_TEST_CAPS_LATEST("graphics-spice-egl-headless");
DO_TEST_CAPS_LATEST_PARSE_ERROR("graphics-spice-invalid-egl-headless");
DO_TEST_CAPS_LATEST("graphics-spice-gl-auto-rendernode");
DO_TEST("graphics-dbus",
QEMU_CAPS_DEVICE_CIRRUS_VGA, QEMU_CAPS_DISPLAY_DBUS);
DO_TEST("graphics-dbus-address",
QEMU_CAPS_DEVICE_CIRRUS_VGA, QEMU_CAPS_DISPLAY_DBUS);
DO_TEST("graphics-dbus-p2p",
QEMU_CAPS_DEVICE_CIRRUS_VGA, QEMU_CAPS_DISPLAY_DBUS);
DO_TEST("graphics-dbus-audio",
QEMU_CAPS_DEVICE_CIRRUS_VGA, QEMU_CAPS_DISPLAY_DBUS);
DO_TEST("graphics-dbus-chardev",
QEMU_CAPS_DEVICE_ISA_SERIAL,
QEMU_CAPS_DEVICE_CIRRUS_VGA,
QEMU_CAPS_DISPLAY_DBUS);
DO_TEST("graphics-dbus-usbredir",
QEMU_CAPS_DEVICE_CIRRUS_VGA,
QEMU_CAPS_DISPLAY_DBUS,
QEMU_CAPS_USB_REDIR);
DO_TEST_NOCAPS("input-usbmouse");
DO_TEST_NOCAPS("input-usbtablet");
DO_TEST_NOCAPS("misc-acpi");
DO_TEST("misc-disable-s3", QEMU_CAPS_PIIX_DISABLE_S3);
DO_TEST("misc-disable-suspends", QEMU_CAPS_PIIX_DISABLE_S3, QEMU_CAPS_PIIX_DISABLE_S4);
DO_TEST("misc-enable-s4", QEMU_CAPS_PIIX_DISABLE_S4);
DO_TEST_PARSE_ERROR_NOCAPS("misc-enable-s4");
DO_TEST_CAPS_VER("misc-no-reboot", "5.2.0");
DO_TEST_CAPS_LATEST("misc-no-reboot");
DO_TEST_NOCAPS("misc-uuid");
DO_TEST_PARSE_ERROR_NOCAPS("vhost_queues-invalid");
DO_TEST_NOCAPS("net-vhostuser");
DO_TEST_CAPS_LATEST("net-vhostuser");
DO_TEST_NOCAPS("net-vhostuser-multiq");
DO_TEST_FAILURE_NOCAPS("net-vhostuser-fail");
DO_TEST_NOCAPS("net-user");
DO_TEST_CAPS_ARCH_LATEST_FULL("net-user", "x86_64", ARG_FLAGS, FLAG_SLIRP_HELPER);
DO_TEST_NOCAPS("net-user-addr");
DO_TEST_NOCAPS("net-virtio");
DO_TEST_NOCAPS("net-virtio-device");
DO_TEST_NOCAPS("net-virtio-disable-offloads");
DO_TEST_NOCAPS("net-virtio-netdev");
DO_TEST_CAPS_ARCH_LATEST("net-virtio-ccw", "s390x");
DO_TEST("net-virtio-rxtxqueuesize",
QEMU_CAPS_VIRTIO_NET_RX_QUEUE_SIZE,
QEMU_CAPS_VIRTIO_NET_TX_QUEUE_SIZE);
DO_TEST_PARSE_ERROR("net-virtio-rxqueuesize-invalid-size",
QEMU_CAPS_VIRTIO_NET_RX_QUEUE_SIZE);
qemu: support interface <teaming> functionality The QEMU driver uses the <teaming type='persistent|transient' persistent='blah'/> element to setup a "failover" pair of devices - the persistent device must be a virtio emulated NIC, with the only extra configuration being the addition of ",failover=on" to the device commandline, and the transient device must be a hostdev NIC (<interface type='hostdev'> or <interface type='network'> with a network that is a pool of SRIOV VFs) where the extra configuration is the addition of ",failover_pair_id=$aliasOfVirtio" to the device commandline. These new options are supported in QEMU 4.2.0 and later. Extra qemu-specific validation is added to ensure that the device type/model is appropriate and that the qemu binary supports these commandline options. The result of this will be: 1) The virtio device presented to the guest will have an extra bit set in its PCI capabilities indicating that it can be used as a failover backup device. The virtio guest driver will need to be equipped to do something with this information - this is included in the Linux virtio-net driver in kernel 4.18 and above (and also backported to some older distro kernels). Unfortunately there is no way for libvirt to learn whether or not the guest driver supports failover - if it doesn't then the extra PCI capability will be ignored and the guest OS will just see two independent devices. (NB: the current virtio guest driver also requires that the MAC addresses of the two NICs match in order to pair them into a bond). 2) When a migration is requested, QEMu will automatically unplug the transient/hostdev NIC from the guest on the source host before starting migration, and automatically re-plug a similar device after restarting the guest CPUs on the destination host. While the transient NIC is unplugged, all network traffic will go through the persistent/virtio device, but when the hostdev NIC is plugged in, it will get all the traffic. This means that in normal circumstances the guest gets the performance advantage of vfio-assigned "real hardware" networking, but it can still be migrated with the only downside being a performance penalty (due to using an emulated NIC) during the migration. Signed-off-by: Laine Stump <laine@redhat.com> Reviewed-by: Daniel P. Berrangé <berrange@redhat.com>
2020-01-23 23:34:53 +03:00
DO_TEST("net-virtio-teaming",
QEMU_CAPS_VIRTIO_NET_FAILOVER,
QEMU_CAPS_DEVICE_VFIO_PCI);
DO_TEST_PARSE_ERROR_NOCAPS("net-virtio-teaming");
DO_TEST("net-virtio-teaming-hostdev",
QEMU_CAPS_VIRTIO_NET_FAILOVER,
QEMU_CAPS_DEVICE_VFIO_PCI);
DO_TEST_NOCAPS("net-eth");
DO_TEST_NOCAPS("net-eth-ifname");
DO_TEST_NOCAPS("net-eth-names");
DO_TEST_NOCAPS("net-eth-hostip");
DO_TEST_NOCAPS("net-eth-unmanaged-tap");
DO_TEST_NOCAPS("net-client");
DO_TEST_NOCAPS("net-server");
DO_TEST_NOCAPS("net-many-models");
DO_TEST_NOCAPS("net-mcast");
DO_TEST_NOCAPS("net-udp");
DO_TEST("net-hostdev", QEMU_CAPS_DEVICE_VFIO_PCI);
DO_TEST("net-hostdev-bootorder", QEMU_CAPS_DEVICE_VFIO_PCI);
DO_TEST("net-hostdev-multidomain", QEMU_CAPS_DEVICE_VFIO_PCI);
DO_TEST("net-hostdev-vfio",
QEMU_CAPS_DEVICE_VFIO_PCI);
DO_TEST("net-hostdev-vfio-multidomain",
QEMU_CAPS_DEVICE_VFIO_PCI);
DO_TEST_FAILURE("net-hostdev-fail",
QEMU_CAPS_DEVICE_VFIO_PCI);
DO_TEST_CAPS_LATEST("net-vdpa");
DO_TEST_CAPS_LATEST("net-vdpa-multiqueue");
DO_TEST_CAPS_LATEST("net-virtio-rss");
DO_TEST("hostdev-pci-multifunction",
QEMU_CAPS_KVM,
QEMU_CAPS_DEVICE_VFIO_PCI);
DO_TEST("hostdev-pci-address-unassigned",
QEMU_CAPS_KVM,
QEMU_CAPS_DEVICE_VFIO_PCI);
DO_TEST("serial-file-log",
QEMU_CAPS_DEVICE_ISA_SERIAL);
DO_TEST("serial-spiceport",
QEMU_CAPS_DEVICE_QXL,
QEMU_CAPS_SPICE,
QEMU_CAPS_DEVICE_ISA_SERIAL);
DO_TEST("console-compat",
QEMU_CAPS_DEVICE_ISA_SERIAL);
DO_TEST("console-compat-auto",
QEMU_CAPS_DEVICE_ISA_SERIAL);
DO_TEST("serial-vc-chardev",
QEMU_CAPS_DEVICE_ISA_SERIAL);
DO_TEST("serial-pty-chardev",
QEMU_CAPS_DEVICE_ISA_SERIAL);
DO_TEST("serial-dev-chardev",
QEMU_CAPS_DEVICE_ISA_SERIAL);
DO_TEST("serial-dev-chardev-iobase",
QEMU_CAPS_DEVICE_ISA_SERIAL);
DO_TEST("serial-file-chardev",
QEMU_CAPS_DEVICE_ISA_SERIAL);
DO_TEST("serial-unix-chardev",
QEMU_CAPS_DEVICE_ISA_SERIAL);
DO_TEST_CAPS_LATEST("serial-file-log");
DO_TEST_CAPS_LATEST("serial-spiceport");
DO_TEST_CAPS_LATEST("serial-debugcon");
DO_TEST_CAPS_LATEST("console-compat");
DO_TEST_CAPS_LATEST("console-compat-auto");
DO_TEST_CAPS_LATEST("serial-vc-chardev");
DO_TEST_CAPS_LATEST("serial-pty-chardev");
DO_TEST_CAPS_LATEST("serial-dev-chardev");
DO_TEST_CAPS_LATEST("serial-dev-chardev-iobase");
DO_TEST_CAPS_LATEST("serial-file-chardev");
DO_TEST_CAPS_LATEST("serial-unix-chardev");
DO_TEST_PARSE_ERROR_NOCAPS("serial-unix-missing-source");
DO_TEST("serial-tcp-chardev",
QEMU_CAPS_DEVICE_ISA_SERIAL);
DO_TEST("serial-udp-chardev",
QEMU_CAPS_DEVICE_ISA_SERIAL);
DO_TEST("serial-tcp-telnet-chardev",
QEMU_CAPS_DEVICE_ISA_SERIAL);
DO_TEST_CAPS_LATEST("serial-unix-chardev");
DO_TEST_CAPS_LATEST_PARSE_ERROR("serial-unix-missing-source");
DO_TEST_CAPS_LATEST("serial-tcp-chardev");
DO_TEST_CAPS_LATEST("serial-udp-chardev");
DO_TEST_CAPS_LATEST("serial-tcp-telnet-chardev");
driver.config->chardevTLS = 1;
DO_TEST("serial-tcp-tlsx509-chardev",
QEMU_CAPS_DEVICE_ISA_SERIAL);
DO_TEST_CAPS_LATEST("serial-tcp-tlsx509-chardev");
driver.config->chardevTLSx509verify = 1;
DO_TEST("serial-tcp-tlsx509-chardev-verify",
QEMU_CAPS_DEVICE_ISA_SERIAL);
DO_TEST_CAPS_LATEST("serial-tcp-tlsx509-chardev-verify");
driver.config->chardevTLSx509verify = 0;
DO_TEST("serial-tcp-tlsx509-chardev-notls",
QEMU_CAPS_DEVICE_ISA_SERIAL);
DO_TEST_CAPS_LATEST("serial-tcp-tlsx509-chardev-notls");
VIR_FREE(driver.config->chardevTLSx509certdir);
driver.config->chardevTLSx509certdir = g_strdup("/etc/pki/libvirt-chardev");
driver.config->chardevTLSx509secretUUID = g_strdup("6fd3f62d-9fe7-4a4e-a869-7acd6376d8ea");
DO_TEST("serial-tcp-tlsx509-secret-chardev",
QEMU_CAPS_DEVICE_ISA_SERIAL);
DO_TEST_CAPS_LATEST("serial-tcp-tlsx509-secret-chardev");
driver.config->chardevTLS = 0;
VIR_FREE(driver.config->chardevTLSx509certdir);
DO_TEST("serial-many-chardev",
QEMU_CAPS_DEVICE_ISA_SERIAL);
DO_TEST_NOCAPS("parallel-tcp-chardev");
DO_TEST_NOCAPS("parallel-parport-chardev");
DO_TEST_CAPS_LATEST("serial-many-chardev");
DO_TEST_CAPS_LATEST("parallel-tcp-chardev");
DO_TEST_CAPS_LATEST("parallel-parport-chardev");
DO_TEST_CAPS_LATEST("parallel-unix-chardev");
DO_TEST("console-compat-chardev",
QEMU_CAPS_DEVICE_ISA_SERIAL);
DO_TEST("pci-serial-dev-chardev",
QEMU_CAPS_DEVICE_PCI_SERIAL);
DO_TEST_CAPS_LATEST("console-compat-chardev");
DO_TEST_CAPS_LATEST("pci-serial-dev-chardev");
DO_TEST_NOCAPS("channel-guestfwd");
DO_TEST_CAPS_LATEST("channel-unix-guestfwd");
DO_TEST_NOCAPS("channel-virtio");
DO_TEST_NOCAPS("channel-virtio-state");
DO_TEST_NOCAPS("channel-virtio-auto");
DO_TEST_NOCAPS("channel-virtio-autoassign");
DO_TEST_NOCAPS("channel-virtio-autoadd");
DO_TEST_NOCAPS("console-virtio");
DO_TEST("console-virtio-many",
QEMU_CAPS_DEVICE_ISA_SERIAL);
DO_TEST_CAPS_ARCH_LATEST("console-virtio-ccw", "s390x");
DO_TEST_CAPS_LATEST("console-virtio-unix");
DO_TEST_CAPS_ARCH_LATEST("console-sclp", "s390x");
DO_TEST("channel-spicevmc",
QEMU_CAPS_SPICE,
QEMU_CAPS_DEVICE_CIRRUS_VGA);
DO_TEST_CAPS_LATEST("channel-qemu-vdagent");
DO_TEST_CAPS_LATEST("channel-qemu-vdagent-features");
DO_TEST("channel-virtio-default",
QEMU_CAPS_SPICE,
QEMU_CAPS_DEVICE_CIRRUS_VGA);
DO_TEST_NOCAPS("channel-virtio-unix");
DO_TEST("smartcard-host",
QEMU_CAPS_CCID_EMULATED);
DO_TEST("smartcard-host-certificates",
QEMU_CAPS_CCID_EMULATED);
DO_TEST("smartcard-host-certificates-database",
QEMU_CAPS_CCID_EMULATED);
DO_TEST("smartcard-passthrough-tcp",
QEMU_CAPS_CCID_PASSTHRU);
DO_TEST("smartcard-passthrough-spicevmc",
QEMU_CAPS_CCID_PASSTHRU,
QEMU_CAPS_SPICE,
QEMU_CAPS_DEVICE_CIRRUS_VGA);
DO_TEST("smartcard-controller",
QEMU_CAPS_CCID_EMULATED);
DO_TEST_CAPS_LATEST("smartcard-passthrough-unix");
DO_TEST("chardev-reconnect",
QEMU_CAPS_CHARDEV_RECONNECT,
QEMU_CAPS_USB_REDIR,
QEMU_CAPS_DEVICE_VIRTIO_RNG,
QEMU_CAPS_OBJECT_RNG_EGD,
QEMU_CAPS_CCID_PASSTHRU);
DO_TEST_PARSE_ERROR("chardev-reconnect-invalid-timeout",
QEMU_CAPS_CHARDEV_RECONNECT);
DO_TEST_PARSE_ERROR("chardev-reconnect-generated-path",
QEMU_CAPS_CHARDEV_RECONNECT);
DO_TEST_NOCAPS("usb-controller");
DO_TEST("usb-piix3-controller",
QEMU_CAPS_PIIX3_USB_UHCI);
DO_TEST("usb-ich9-ehci-addr",
QEMU_CAPS_ICH9_USB_EHCI1);
DO_TEST_NOCAPS("input-usbmouse-addr");
DO_TEST("usb-ich9-companion",
QEMU_CAPS_ICH9_USB_EHCI1);
DO_TEST_PARSE_ERROR("usb-ich9-no-companion",
QEMU_CAPS_ICH9_USB_EHCI1);
DO_TEST("usb-ich9-autoassign",
QEMU_CAPS_ICH9_USB_EHCI1,
QEMU_CAPS_USB_HUB);
DO_TEST("usb-hub",
QEMU_CAPS_USB_HUB);
DO_TEST("usb-hub-autoadd",
QEMU_CAPS_USB_HUB);
DO_TEST("usb-hub-autoadd-deluxe",
QEMU_CAPS_USB_HUB);
DO_TEST_PARSE_ERROR("usb-hub-conflict",
QEMU_CAPS_USB_HUB);
DO_TEST_PARSE_ERROR("usb-hub-nonexistent",
QEMU_CAPS_USB_HUB);
DO_TEST("usb-port-missing",
QEMU_CAPS_USB_HUB);
DO_TEST_FAILURE("usb-bus-missing",
QEMU_CAPS_USB_HUB);
DO_TEST("usb-ports",
QEMU_CAPS_USB_HUB);
DO_TEST_PARSE_ERROR("usb-ports-out-of-range",
QEMU_CAPS_USB_HUB);
DO_TEST("usb-port-autoassign",
QEMU_CAPS_USB_HUB);
DO_TEST("usb-redir",
QEMU_CAPS_USB_HUB,
QEMU_CAPS_ICH9_USB_EHCI1,
QEMU_CAPS_USB_REDIR,
QEMU_CAPS_SPICE,
QEMU_CAPS_DEVICE_CIRRUS_VGA);
DO_TEST("usb-redir-boot",
QEMU_CAPS_USB_HUB,
QEMU_CAPS_ICH9_USB_EHCI1,
QEMU_CAPS_USB_REDIR,
QEMU_CAPS_SPICE,
QEMU_CAPS_DEVICE_CIRRUS_VGA);
DO_TEST("usb-redir-filter",
QEMU_CAPS_USB_HUB,
QEMU_CAPS_ICH9_USB_EHCI1,
QEMU_CAPS_USB_REDIR,
QEMU_CAPS_SPICE,
QEMU_CAPS_USB_REDIR_FILTER,
QEMU_CAPS_DEVICE_CIRRUS_VGA);
DO_TEST("usb-redir-filter-version",
QEMU_CAPS_USB_REDIR,
QEMU_CAPS_SPICE,
QEMU_CAPS_USB_REDIR_FILTER,
QEMU_CAPS_DEVICE_CIRRUS_VGA);
DO_TEST_CAPS_LATEST("usb-redir-unix");
DO_TEST("usb1-usb2",
QEMU_CAPS_PIIX3_USB_UHCI,
QEMU_CAPS_USB_HUB,
QEMU_CAPS_ICH9_USB_EHCI1);
DO_TEST_NOCAPS("usb-none");
DO_TEST_PARSE_ERROR_NOCAPS("usb-none-other");
DO_TEST_PARSE_ERROR("usb-none-hub",
QEMU_CAPS_USB_HUB);
DO_TEST_PARSE_ERROR_NOCAPS("usb-none-usbtablet");
DO_TEST("usb-controller-default-q35",
qemu: initially reserve one open pcie-root-port for hotplug For machinetypes with a pci-root bus (all legacy PCI), libvirt will make a "fake" reservation for one extra slot prior to assigning addresses to unaddressed PCI endpoint devices in the domain. This will trigger auto-adding of a pci-bridge for the final device to be assigned an address *if that device would have otherwise instead been the last device on the last available pci-bridge*; thus it assures that there will always be at least one slot left open in the domain's bus topology for expansion (which is important both for hotplug (since a new pci-bridge can't be added while the guest is running) as well as for offline additions to the config (since adding a new device might otherwise in some cases require re-addressing existing devices, which we want to avoid)). It's important to note that for the above case (legacy PCI), we must check for the special case of all slots on all buses being occupied *prior to assigning any addresses*, and avoid attempting to reserve the extra address in that case, because there is no free address in the existing topology, so no place to auto-add a pci-bridge for expansion (i.e. it would always fail anyway). Since that condition can only be reached by manual intervention, this is acceptable. For machinetypes with pcie-root (Q35, aarch64 virt), libvirt's methodology for automatically expanding the bus topology is different - pcie-root-ports are plugged into slots (soon to be functions) of pcie-root as needed, and the new endpoint devices are assigned to the single slot in each pcie-root-port. This is done so that the devices are, by default, hotpluggable (the slots of pcie-root don't support hotplug, but the single slot of the pcie-root-port does). Since pcie-root-ports can only be plugged into pcie-root, and we don't auto-assign endpoint devices to the pcie-root slots, this means topology expansion doesn't compete with endpoint devices for slots, so we don't need to worry about checking for all "useful" slots being free *prior* to assigning addresses to new endpoint devices - as a matter of fact, if we attempt to reserve the open slots before the used slots, it can lead to errors. Instead this patch just reserves one slot for a "future potential" PCIe device after doing the assignment for actual devices, but only if the only PCI controller defined prior to starting address assignment was pcie-root, and only if we auto-added at least one PCI controller during address assignment. This assures two things: 1) that reserving the open slots will only be done when the domain is initially defined, never at any time after, and 2) that if the user understands enough about PCI controllers that they are adding them manually, that we don't mess up their plan by adding extras - if they know enough to add one pcie-root-port, or to manually assign addresses such that no pcie-root-ports are needed, they know enough to add extra pcie-root-ports if they want them (this could be called the "libguestfs clause", since libguestfs needs to be able to create domains with as few devices/controllers as possible). This is set to reserve a single free port for now, but could be increased in the future if public sentiment goes in that direction (it's easy to increase later, but essentially impossible to decrease)
2016-09-28 03:37:30 +03:00
QEMU_CAPS_DEVICE_IOH3420,
QEMU_CAPS_PCI_OHCI,
QEMU_CAPS_PIIX3_USB_UHCI,
QEMU_CAPS_NEC_USB_XHCI);
DO_TEST_FAILURE("usb-controller-default-unavailable-q35",
qemu: initially reserve one open pcie-root-port for hotplug For machinetypes with a pci-root bus (all legacy PCI), libvirt will make a "fake" reservation for one extra slot prior to assigning addresses to unaddressed PCI endpoint devices in the domain. This will trigger auto-adding of a pci-bridge for the final device to be assigned an address *if that device would have otherwise instead been the last device on the last available pci-bridge*; thus it assures that there will always be at least one slot left open in the domain's bus topology for expansion (which is important both for hotplug (since a new pci-bridge can't be added while the guest is running) as well as for offline additions to the config (since adding a new device might otherwise in some cases require re-addressing existing devices, which we want to avoid)). It's important to note that for the above case (legacy PCI), we must check for the special case of all slots on all buses being occupied *prior to assigning any addresses*, and avoid attempting to reserve the extra address in that case, because there is no free address in the existing topology, so no place to auto-add a pci-bridge for expansion (i.e. it would always fail anyway). Since that condition can only be reached by manual intervention, this is acceptable. For machinetypes with pcie-root (Q35, aarch64 virt), libvirt's methodology for automatically expanding the bus topology is different - pcie-root-ports are plugged into slots (soon to be functions) of pcie-root as needed, and the new endpoint devices are assigned to the single slot in each pcie-root-port. This is done so that the devices are, by default, hotpluggable (the slots of pcie-root don't support hotplug, but the single slot of the pcie-root-port does). Since pcie-root-ports can only be plugged into pcie-root, and we don't auto-assign endpoint devices to the pcie-root slots, this means topology expansion doesn't compete with endpoint devices for slots, so we don't need to worry about checking for all "useful" slots being free *prior* to assigning addresses to new endpoint devices - as a matter of fact, if we attempt to reserve the open slots before the used slots, it can lead to errors. Instead this patch just reserves one slot for a "future potential" PCIe device after doing the assignment for actual devices, but only if the only PCI controller defined prior to starting address assignment was pcie-root, and only if we auto-added at least one PCI controller during address assignment. This assures two things: 1) that reserving the open slots will only be done when the domain is initially defined, never at any time after, and 2) that if the user understands enough about PCI controllers that they are adding them manually, that we don't mess up their plan by adding extras - if they know enough to add one pcie-root-port, or to manually assign addresses such that no pcie-root-ports are needed, they know enough to add extra pcie-root-ports if they want them (this could be called the "libguestfs clause", since libguestfs needs to be able to create domains with as few devices/controllers as possible). This is set to reserve a single free port for now, but could be increased in the future if public sentiment goes in that direction (it's easy to increase later, but essentially impossible to decrease)
2016-09-28 03:37:30 +03:00
QEMU_CAPS_DEVICE_IOH3420,
QEMU_CAPS_PCI_OHCI,
QEMU_CAPS_NEC_USB_XHCI);
DO_TEST("usb-controller-explicit-q35",
qemu: initially reserve one open pcie-root-port for hotplug For machinetypes with a pci-root bus (all legacy PCI), libvirt will make a "fake" reservation for one extra slot prior to assigning addresses to unaddressed PCI endpoint devices in the domain. This will trigger auto-adding of a pci-bridge for the final device to be assigned an address *if that device would have otherwise instead been the last device on the last available pci-bridge*; thus it assures that there will always be at least one slot left open in the domain's bus topology for expansion (which is important both for hotplug (since a new pci-bridge can't be added while the guest is running) as well as for offline additions to the config (since adding a new device might otherwise in some cases require re-addressing existing devices, which we want to avoid)). It's important to note that for the above case (legacy PCI), we must check for the special case of all slots on all buses being occupied *prior to assigning any addresses*, and avoid attempting to reserve the extra address in that case, because there is no free address in the existing topology, so no place to auto-add a pci-bridge for expansion (i.e. it would always fail anyway). Since that condition can only be reached by manual intervention, this is acceptable. For machinetypes with pcie-root (Q35, aarch64 virt), libvirt's methodology for automatically expanding the bus topology is different - pcie-root-ports are plugged into slots (soon to be functions) of pcie-root as needed, and the new endpoint devices are assigned to the single slot in each pcie-root-port. This is done so that the devices are, by default, hotpluggable (the slots of pcie-root don't support hotplug, but the single slot of the pcie-root-port does). Since pcie-root-ports can only be plugged into pcie-root, and we don't auto-assign endpoint devices to the pcie-root slots, this means topology expansion doesn't compete with endpoint devices for slots, so we don't need to worry about checking for all "useful" slots being free *prior* to assigning addresses to new endpoint devices - as a matter of fact, if we attempt to reserve the open slots before the used slots, it can lead to errors. Instead this patch just reserves one slot for a "future potential" PCIe device after doing the assignment for actual devices, but only if the only PCI controller defined prior to starting address assignment was pcie-root, and only if we auto-added at least one PCI controller during address assignment. This assures two things: 1) that reserving the open slots will only be done when the domain is initially defined, never at any time after, and 2) that if the user understands enough about PCI controllers that they are adding them manually, that we don't mess up their plan by adding extras - if they know enough to add one pcie-root-port, or to manually assign addresses such that no pcie-root-ports are needed, they know enough to add extra pcie-root-ports if they want them (this could be called the "libguestfs clause", since libguestfs needs to be able to create domains with as few devices/controllers as possible). This is set to reserve a single free port for now, but could be increased in the future if public sentiment goes in that direction (it's easy to increase later, but essentially impossible to decrease)
2016-09-28 03:37:30 +03:00
QEMU_CAPS_DEVICE_IOH3420,
QEMU_CAPS_PCI_OHCI,
QEMU_CAPS_PIIX3_USB_UHCI,
QEMU_CAPS_NEC_USB_XHCI);
DO_TEST_FAILURE("usb-controller-explicit-unavailable-q35",
qemu: initially reserve one open pcie-root-port for hotplug For machinetypes with a pci-root bus (all legacy PCI), libvirt will make a "fake" reservation for one extra slot prior to assigning addresses to unaddressed PCI endpoint devices in the domain. This will trigger auto-adding of a pci-bridge for the final device to be assigned an address *if that device would have otherwise instead been the last device on the last available pci-bridge*; thus it assures that there will always be at least one slot left open in the domain's bus topology for expansion (which is important both for hotplug (since a new pci-bridge can't be added while the guest is running) as well as for offline additions to the config (since adding a new device might otherwise in some cases require re-addressing existing devices, which we want to avoid)). It's important to note that for the above case (legacy PCI), we must check for the special case of all slots on all buses being occupied *prior to assigning any addresses*, and avoid attempting to reserve the extra address in that case, because there is no free address in the existing topology, so no place to auto-add a pci-bridge for expansion (i.e. it would always fail anyway). Since that condition can only be reached by manual intervention, this is acceptable. For machinetypes with pcie-root (Q35, aarch64 virt), libvirt's methodology for automatically expanding the bus topology is different - pcie-root-ports are plugged into slots (soon to be functions) of pcie-root as needed, and the new endpoint devices are assigned to the single slot in each pcie-root-port. This is done so that the devices are, by default, hotpluggable (the slots of pcie-root don't support hotplug, but the single slot of the pcie-root-port does). Since pcie-root-ports can only be plugged into pcie-root, and we don't auto-assign endpoint devices to the pcie-root slots, this means topology expansion doesn't compete with endpoint devices for slots, so we don't need to worry about checking for all "useful" slots being free *prior* to assigning addresses to new endpoint devices - as a matter of fact, if we attempt to reserve the open slots before the used slots, it can lead to errors. Instead this patch just reserves one slot for a "future potential" PCIe device after doing the assignment for actual devices, but only if the only PCI controller defined prior to starting address assignment was pcie-root, and only if we auto-added at least one PCI controller during address assignment. This assures two things: 1) that reserving the open slots will only be done when the domain is initially defined, never at any time after, and 2) that if the user understands enough about PCI controllers that they are adding them manually, that we don't mess up their plan by adding extras - if they know enough to add one pcie-root-port, or to manually assign addresses such that no pcie-root-ports are needed, they know enough to add extra pcie-root-ports if they want them (this could be called the "libguestfs clause", since libguestfs needs to be able to create domains with as few devices/controllers as possible). This is set to reserve a single free port for now, but could be increased in the future if public sentiment goes in that direction (it's easy to increase later, but essentially impossible to decrease)
2016-09-28 03:37:30 +03:00
QEMU_CAPS_DEVICE_IOH3420,
QEMU_CAPS_PCI_OHCI,
QEMU_CAPS_PIIX3_USB_UHCI);
DO_TEST("usb-controller-xhci",
QEMU_CAPS_PIIX3_USB_UHCI,
QEMU_CAPS_NEC_USB_XHCI);
DO_TEST("usb-xhci-autoassign",
QEMU_CAPS_PIIX3_USB_UHCI,
QEMU_CAPS_NEC_USB_XHCI,
QEMU_CAPS_USB_HUB);
DO_TEST_PARSE_ERROR("usb-controller-xhci-limit",
QEMU_CAPS_PIIX3_USB_UHCI,
QEMU_CAPS_NEC_USB_XHCI);
DO_TEST("usb-controller-qemu-xhci", QEMU_CAPS_DEVICE_QEMU_XHCI);
DO_TEST_FAILURE_NOCAPS("usb-controller-qemu-xhci-unavailable");
DO_TEST_PARSE_ERROR("usb-controller-qemu-xhci-limit",
QEMU_CAPS_DEVICE_QEMU_XHCI);
DO_TEST_NOCAPS("smbios");
DO_TEST_PARSE_ERROR_NOCAPS("smbios-date");
DO_TEST_PARSE_ERROR_NOCAPS("smbios-uuid-match");
DO_TEST_NOCAPS("smbios-type-fwcfg");
DO_TEST_CAPS_LATEST("watchdog");
DO_TEST_CAPS_LATEST("watchdog-device");
DO_TEST_CAPS_LATEST("watchdog-dump");
DO_TEST_CAPS_LATEST("watchdog-injectnmi");
DO_TEST_CAPS_ARCH_LATEST("watchdog-diag288", "s390x");
DO_TEST_NOCAPS("balloon-device");
DO_TEST("balloon-device-deflate",
QEMU_CAPS_VIRTIO_BALLOON_AUTODEFLATE);
DO_TEST_CAPS_ARCH_LATEST("balloon-ccw-deflate", "s390x");
DO_TEST("balloon-mmio-deflate",
QEMU_CAPS_DEVICE_VIRTIO_MMIO,
QEMU_CAPS_VIRTIO_BALLOON_AUTODEFLATE);
DO_TEST("balloon-device-deflate-off",
QEMU_CAPS_VIRTIO_BALLOON_AUTODEFLATE);
DO_TEST_NOCAPS("balloon-device-auto");
DO_TEST_NOCAPS("balloon-device-period");
DO_TEST_NOCAPS("sound");
DO_TEST("sound-device",
QEMU_CAPS_HDA_DUPLEX, QEMU_CAPS_HDA_MICRO,
QEMU_CAPS_HDA_OUTPUT,
QEMU_CAPS_DEVICE_ICH9_INTEL_HDA,
QEMU_CAPS_OBJECT_USB_AUDIO);
DO_TEST_CAPS_LATEST("fs9p");
DO_TEST_CAPS_ARCH_LATEST("fs9p-ccw", "s390x");
DO_TEST_CAPS_LATEST("hostdev-usb-address");
DO_TEST_CAPS_LATEST("hostdev-usb-address-device");
DO_TEST_CAPS_LATEST("hostdev-usb-address-device-boot");
DO_TEST_PARSE_ERROR_NOCAPS("hostdev-usb-duplicate");
DO_TEST_CAPS_LATEST("hostdev-pci-address");
DO_TEST_CAPS_LATEST("hostdev-pci-address-device");
DO_TEST_PARSE_ERROR("hostdev-pci-duplicate",
QEMU_CAPS_DEVICE_VFIO_PCI);
DO_TEST("hostdev-vfio",
QEMU_CAPS_DEVICE_VFIO_PCI);
DO_TEST("hostdev-vfio-multidomain",
QEMU_CAPS_DEVICE_VFIO_PCI);
DO_TEST("hostdev-mdev-precreated",
QEMU_CAPS_DEVICE_VFIO_PCI);
DO_TEST_PARSE_ERROR("hostdev-mdev-src-address-invalid",
QEMU_CAPS_DEVICE_VFIO_PCI);
DO_TEST_PARSE_ERROR("hostdev-mdev-invalid-target-address",
QEMU_CAPS_DEVICE_VFIO_PCI);
DO_TEST_PARSE_ERROR("hostdev-mdev-duplicate",
QEMU_CAPS_DEVICE_VFIO_PCI);
DO_TEST_CAPS_LATEST("hostdev-mdev-display-spice-opengl");
DO_TEST_CAPS_LATEST("hostdev-mdev-display-spice-egl-headless");
DO_TEST_CAPS_LATEST("hostdev-mdev-display-vnc");
DO_TEST_CAPS_LATEST("hostdev-mdev-display-vnc-egl-headless");
DO_TEST_PARSE_ERROR("hostdev-mdev-display-missing-graphics",
QEMU_CAPS_DEVICE_VFIO_PCI,
QEMU_CAPS_VFIO_PCI_DISPLAY);
DO_TEST_CAPS_LATEST("hostdev-mdev-display-ramfb");
DO_TEST_CAPS_LATEST_PARSE_ERROR("hostdev-mdev-display-ramfb-multiple");
DO_TEST_PARSE_ERROR("hostdev-vfio-zpci-wrong-arch",
QEMU_CAPS_DEVICE_VFIO_PCI);
DO_TEST("hostdev-vfio-zpci",
QEMU_CAPS_DEVICE_VFIO_PCI,
QEMU_CAPS_DEVICE_ZPCI);
DO_TEST_PARSE_ERROR("hostdev-vfio-zpci-autogenerate-fids",
QEMU_CAPS_DEVICE_VFIO_PCI);
DO_TEST_CAPS_ARCH_LATEST_PARSE_ERROR("hostdev-vfio-zpci-invalid-uid-valid-fid", "s390x");
DO_TEST_CAPS_ARCH_LATEST("hostdev-vfio-zpci-multidomain-many", "s390x");
DO_TEST_CAPS_ARCH_LATEST("hostdev-vfio-zpci-autogenerate", "s390x");
DO_TEST_CAPS_ARCH_LATEST("hostdev-vfio-zpci-autogenerate-uids", "s390x");
DO_TEST_CAPS_ARCH_LATEST("hostdev-vfio-zpci-autogenerate-fids", "s390x");
conf: fix zPCI address auto-generation on s390 Let us fix the issues with zPCI address validation and auto-generation on s390. Currently, there are two issues with handling the ZPCI address extension. Firstly, when the uid is to be auto-generated with a specified fid, .i.e.: ... <address type='pci'> <zpci fid='0x0000001f'/> </address> ... we expect uid='0x0001' (or the next available uid for the domain). However, we get a parsing error: $ virsh define zpci.xml error: XML error: Invalid PCI address uid='0x0000', must be > 0x0000 and <= 0xffff Secondly, when the uid is specified explicitly with the invalid numerical value '0x0000', we actually expect the parsing error above. However, the domain is being defined and the uid value is silently changed to a valid value. The first issue is a bug and the second one is undesired behaviour, and both issues are related to how we (in-band) signal invalid values for uid and fid. So let's fix the XML parsing to do validation based on what is actually specified in the XML. The first issue is also related to the current code behaviour, which is, if either uid or fid is specified by the user, it is incorrectly assumed that both uid and fid are specified. This bug is fixed by identifying when the user specified ZPCI address is incomplete and auto-generating the missing ZPCI address. Signed-off-by: Bjoern Walk <bwalk@linux.ibm.com> Signed-off-by: Boris Fiuczynski <fiuczy@linux.ibm.com> Signed-off-by: Shalini Chellathurai Saroja <shalini@linux.ibm.com> Reviewed-by: Andrea Bolognani <abologna@redhat.com>
2020-06-18 11:25:15 +03:00
DO_TEST_PARSE_ERROR("hostdev-vfio-zpci-uid-set-zero",
QEMU_CAPS_DEVICE_VFIO_PCI,
QEMU_CAPS_DEVICE_ZPCI);
DO_TEST("hostdev-vfio-zpci-boundaries",
QEMU_CAPS_DEVICE_VFIO_PCI,
QEMU_CAPS_DEVICE_PCI_BRIDGE,
QEMU_CAPS_DEVICE_ZPCI);
DO_TEST_PARSE_ERROR("hostdev-vfio-zpci",
QEMU_CAPS_DEVICE_VFIO_PCI);
DO_TEST_PARSE_ERROR("hostdev-vfio-zpci-duplicate",
QEMU_CAPS_DEVICE_VFIO_PCI,
QEMU_CAPS_DEVICE_ZPCI);
DO_TEST_PARSE_ERROR("hostdev-vfio-zpci-set-zero",
QEMU_CAPS_DEVICE_VFIO_PCI,
QEMU_CAPS_DEVICE_ZPCI);
DO_TEST_CAPS_ARCH_LATEST("hostdev-vfio-zpci-ccw-memballoon", "s390x");
DO_TEST("pci-rom", QEMU_CAPS_DEVICE_VFIO_PCI);
DO_TEST_NOCAPS("pci-rom-disabled");
DO_TEST_NOCAPS("pci-rom-disabled-invalid");
DO_TEST_CAPS_ARCH_LATEST("hostdev-subsys-mdev-vfio-ccw", "s390x");
DO_TEST_CAPS_ARCH_LATEST("hostdev-subsys-mdev-vfio-ccw-boot",
"s390x");
DO_TEST_PARSE_ERROR_NOCAPS("hostdev-subsys-mdev-vfio-ccw");
DO_TEST_PARSE_ERROR("hostdev-subsys-mdev-vfio-ccw-duplicate-address",
QEMU_CAPS_DEVICE_VFIO_CCW);
DO_TEST_PARSE_ERROR("hostdev-subsys-mdev-vfio-ccw-invalid-address",
QEMU_CAPS_DEVICE_VFIO_CCW);
DO_TEST_CAPS_ARCH_LATEST("hostdev-subsys-mdev-vfio-ap",
"s390x");
DO_TEST_CAPS_ARCH_LATEST_PARSE_ERROR("hostdev-subsys-mdev-vfio-ap-boot-fail",
"s390x");
DO_TEST_FULL("restore-v2", "",
ARG_MIGRATE_FROM, "exec:cat",
ARG_MIGRATE_FD, 7,
ARG_END);
DO_TEST_FULL("restore-v2-fd", "",
ARG_MIGRATE_FROM, "stdio",
ARG_MIGRATE_FD, 7,
ARG_END);
DO_TEST_FULL("restore-v2-fd", "",
ARG_MIGRATE_FROM, "fd:7",
ARG_MIGRATE_FD, 7, ARG_END);
DO_TEST_FULL("migrate", "",
ARG_MIGRATE_FROM, "tcp:10.0.0.1:5000", ARG_END);
DO_TEST_FULL("migrate-numa-unaligned", "",
ARG_MIGRATE_FROM, "stdio",
ARG_MIGRATE_FD, 7,
ARG_QEMU_CAPS,
QEMU_CAPS_NUMA,
QEMU_CAPS_OBJECT_MEMORY_RAM,
QEMU_CAPS_LAST,
ARG_END);
DO_TEST_CAPS_LATEST("qemu-ns");
DO_TEST_NOCAPS("qemu-ns-no-env");
DO_TEST_NOCAPS("qemu-ns-alt");
DO_TEST_NOCAPS("smp");
DO_TEST("smp-dies", QEMU_CAPS_SMP_DIES);
DO_TEST("iothreads", QEMU_CAPS_OBJECT_IOTHREAD);
DO_TEST("iothreads-ids", QEMU_CAPS_OBJECT_IOTHREAD);
DO_TEST("iothreads-ids-partial", QEMU_CAPS_OBJECT_IOTHREAD);
DO_TEST_CAPS_LATEST("iothreads-ids-pool-sizes");
DO_TEST_FAILURE_NOCAPS("iothreads-nocap");
DO_TEST("iothreads-disk", QEMU_CAPS_OBJECT_IOTHREAD);
DO_TEST_CAPS_ARCH_VER("iothreads-disk-virtio-ccw", "s390x", "4.2.0");
DO_TEST_CAPS_VER("iothreads-virtio-scsi-pci", "5.2.0");
DO_TEST_CAPS_LATEST("iothreads-virtio-scsi-pci");
DO_TEST_CAPS_ARCH_LATEST("iothreads-virtio-scsi-ccw", "s390x");
DO_TEST_NOCAPS("cpu-topology1");
DO_TEST_NOCAPS("cpu-topology2");
DO_TEST_NOCAPS("cpu-topology3");
DO_TEST("cpu-minimum1", QEMU_CAPS_KVM);
DO_TEST("cpu-minimum2", QEMU_CAPS_KVM);
DO_TEST("cpu-exact1", QEMU_CAPS_KVM);
DO_TEST("cpu-exact2", QEMU_CAPS_KVM);
DO_TEST("cpu-exact2-nofallback", QEMU_CAPS_KVM);
DO_TEST("cpu-fallback", QEMU_CAPS_KVM);
DO_TEST_FAILURE("cpu-nofallback", QEMU_CAPS_KVM);
DO_TEST("cpu-strict1", QEMU_CAPS_KVM);
DO_TEST("cpu-no-removed-features", QEMU_CAPS_KVM);
DO_TEST_NOCAPS("cpu-numa1");
DO_TEST_NOCAPS("cpu-numa2");
DO_TEST_NOCAPS("cpu-numa-no-memory-element");
DO_TEST_PARSE_ERROR_NOCAPS("cpu-numa3");
DO_TEST_PARSE_ERROR_NOCAPS("cpu-numa-disjoint");
DO_TEST("cpu-numa-disjoint", QEMU_CAPS_NUMA);
DO_TEST_FAILURE("cpu-numa-memshared", QEMU_CAPS_OBJECT_MEMORY_RAM);
DO_TEST("cpu-numa-memshared", QEMU_CAPS_OBJECT_MEMORY_FILE);
DO_TEST("cpu-host-model",
QEMU_CAPS_DEVICE_PCI_BRIDGE,
QEMU_CAPS_DEVICE_DMI_TO_PCI_BRIDGE,
QEMU_CAPS_DEVICE_IOH3420,
QEMU_CAPS_ICH9_AHCI,
QEMU_CAPS_ICH9_USB_EHCI1);
/* host-model cpu expansion depends on the cpu reported by qemu and thus
* we invoke it for all real capability dumps we have */
DO_TEST_CAPS_VER("cpu-host-model", "4.2.0");
DO_TEST_CAPS_VER("cpu-host-model", "5.0.0");
DO_TEST_CAPS_VER("cpu-host-model", "5.1.0");
DO_TEST_CAPS_VER("cpu-host-model", "5.2.0");
DO_TEST_CAPS_VER("cpu-host-model", "6.0.0");
DO_TEST_CAPS_VER("cpu-host-model", "6.1.0");
/* For this specific test we accept the increased likelihood of changes
* if qemu updates the CPU model */
DO_TEST_CAPS_LATEST("cpu-host-model");
DO_TEST_NOCAPS("cpu-host-model-vendor");
DO_TEST_FULL("cpu-host-model-fallback", "",
ARG_FLAGS, FLAG_SKIP_LEGACY_CPUS, ARG_END);
DO_TEST_FULL("cpu-host-model-nofallback", "",
ARG_FLAGS, FLAG_SKIP_LEGACY_CPUS | FLAG_EXPECT_FAILURE,
ARG_END);
DO_TEST("cpu-host-passthrough", QEMU_CAPS_KVM);
DO_TEST_FAILURE("cpu-qemu-host-passthrough", QEMU_CAPS_KVM);
qemuTestSetHostArch(&driver, VIR_ARCH_S390X);
DO_TEST("cpu-s390-zEC12", QEMU_CAPS_KVM);
DO_TEST("cpu-s390-features", QEMU_CAPS_KVM, QEMU_CAPS_QUERY_CPU_MODEL_EXPANSION);
DO_TEST_FAILURE("cpu-s390-features", QEMU_CAPS_KVM);
qemuTestSetHostArch(&driver, VIR_ARCH_NONE);
qemuTestSetHostCPU(&driver, driver.hostarch, qemuTestGetCPUDef(QEMU_CPU_DEF_HASWELL));
DO_TEST("cpu-Haswell", QEMU_CAPS_KVM);
DO_TEST("cpu-Haswell2", QEMU_CAPS_KVM);
DO_TEST("cpu-Haswell3", QEMU_CAPS_KVM);
DO_TEST("cpu-Haswell-noTSX", QEMU_CAPS_KVM);
DO_TEST_NOCAPS("cpu-host-model-cmt");
DO_TEST("cpu-tsc-frequency", QEMU_CAPS_KVM);
qemuTestSetHostCPU(&driver, driver.hostarch, NULL);
DO_TEST_CAPS_LATEST("cpu-translation");
DO_TEST_NOCAPS("memtune");
DO_TEST_NOCAPS("memtune-unlimited");
DO_TEST_NOCAPS("blkiotune");
DO_TEST_NOCAPS("blkiotune-device");
DO_TEST_NOCAPS("cputune");
DO_TEST_NOCAPS("cputune-zero-shares");
DO_TEST_PARSE_ERROR_NOCAPS("cputune-iothreadsched-toomuch");
DO_TEST_PARSE_ERROR_NOCAPS("cputune-vcpusched-overlap");
DO_TEST("cputune-numatune",
QEMU_CAPS_KVM,
qemu: Fix qemu startup check for QEMU_CAPS_OBJECT_IOTHREAD https://bugzilla.redhat.com/show_bug.cgi?id=1249981 When qemuDomainPinIOThread was added in commit id 'fb562614', a check for the IOThread capability was not needed since a check for iothreadpids covered the condition where the support for IOThreads was not present. The iothreadpids array was only created if qemuProcessDetectIOThreadPIDs was able to query the monitor for IOThreads. It would only do that if the QEMU_CAPS_OBJECT_IOTHREAD capability was set. However, when iothreadids were added in commit id '8d4614a5' and the check for iothreadpids was replaced by a search through the iothreadids[] array for the matching iothread_id that left open the possibility that an iothreadids[] array was defined, but the entries essentially pointed to elements with only the 'iothread_id' defined leaving the 'thread_id' value of 0 and eventually the cpumap entry of NULL. This was because, the original IOThreads commit id '72edaae7' only checked if IOThreads were defined and if the emulator had the IOThreads capability, then IOThread objects were added at startup. The "capability failure" check was only done when a disk was assigned to an IOThread in qemuCheckIOThreads. This was because the initial implementation had no way to dynamically add IOThreads, but it was possible to dynamically add a disk to the domain. So the decision was if the domain supported it, then add the IOThread objects. Then if a disk with an IOThread defined was added, it could check the capability and fail to add if not there. This just meant the 'iothreads' value was essentially ignored. Eventually commit id 'a27ed6e7' allowed for the dynamic addition and deletion of IOThread objects. So it was no longer necessary to generate IOThread objects to dynamically attach a disk to. However, the startup and disk check code was not modified to reflect this. This patch will move the capability failure check to when IOThread objects are being added to the command line. Thus a domain that has IOThreads defined will not be started if the emulator doesn't support the capability. This means when qemuCheckIOThreads is called to add a disk, it's no longer necessary to check the capability. Instead the code can use the IOThreadFind call to indicate that the IOThread doesn't exist. Finally because it could be possible to have a domain running with the iothreadids[] defined prior to this change if libvirtd is restarted each having mostly empty elements, qemuProcessDetectIOThreadPIDs will check if there are niothreadids when the QEMU_CAPS_OBJECT_IOTHREAD capability check fails and remove the elements and array if it exists. With these changes in place, it turns out the cputune-numatune test was failing because the right bit wasn't set in the test. So used the opportunity to fix that and create a test that would expect to fail with some sort of iothreads defined and used, but not having the correct capability.
2015-10-15 19:30:40 +03:00
QEMU_CAPS_OBJECT_IOTHREAD,
QEMU_CAPS_OBJECT_MEMORY_RAM,
QEMU_CAPS_OBJECT_MEMORY_FILE);
DO_TEST("vcpu-placement-static",
QEMU_CAPS_KVM,
QEMU_CAPS_OBJECT_IOTHREAD);
DO_TEST_CAPS_LATEST("cputune-cpuset-big-id");
DO_TEST_NOCAPS("numatune-memory");
DO_TEST_PARSE_ERROR_NOCAPS("numatune-memory-invalid-nodeset");
DO_TEST("numatune-memnode",
QEMU_CAPS_NUMA,
QEMU_CAPS_OBJECT_MEMORY_RAM);
DO_TEST_PARSE_ERROR_NOCAPS("numatune-memnode");
DO_TEST_CAPS_VER("numatune-memnode", "5.2.0");
DO_TEST_CAPS_LATEST("numatune-memnode");
DO_TEST_PARSE_ERROR_NOCAPS("numatune-memnode-invalid-mode");
DO_TEST_CAPS_LATEST("numatune-memnode-restrictive-mode");
DO_TEST_CAPS_LATEST("numatune-system-memory");
DO_TEST("numatune-memnode-no-memory",
QEMU_CAPS_NUMA,
QEMU_CAPS_OBJECT_MEMORY_RAM);
DO_TEST_PARSE_ERROR_NOCAPS("numatune-memnode-no-memory");
DO_TEST("numatune-distances", QEMU_CAPS_NUMA);
DO_TEST_NOCAPS("numatune-no-vcpu");
DO_TEST_CAPS_LATEST("numatune-hmat");
DO_TEST_NOCAPS("numatune-auto-nodeset-invalid");
DO_TEST("numatune-auto-prefer", QEMU_CAPS_OBJECT_MEMORY_RAM,
QEMU_CAPS_OBJECT_MEMORY_FILE);
DO_TEST_FAILURE("numatune-static-nodeset-exceed-hostnode",
QEMU_CAPS_OBJECT_MEMORY_RAM);
DO_TEST_PARSE_ERROR_NOCAPS("numatune-memnode-nocpu");
DO_TEST_PARSE_ERROR_NOCAPS("numatune-memnodes-problematic");
DO_TEST_NOCAPS("numad");
DO_TEST_NOCAPS("numad-auto-vcpu-static-numatune");
DO_TEST_PARSE_ERROR_NOCAPS("numad-auto-vcpu-static-numatune-no-nodeset");
DO_TEST_NOCAPS("numad-auto-memory-vcpu-cpuset");
DO_TEST_NOCAPS("numad-auto-memory-vcpu-no-cpuset-and-placement");
DO_TEST_NOCAPS("numad-static-memory-auto-vcpu");
DO_TEST_CAPS_LATEST("blkdeviotune");
DO_TEST_CAPS_LATEST("blkdeviotune-max");
DO_TEST_CAPS_LATEST("blkdeviotune-group-num");
DO_TEST_CAPS_LATEST("blkdeviotune-max-length");
DO_TEST("multifunction-pci-device",
QEMU_CAPS_SCSI_LSI);
DO_TEST_NOCAPS("monitor-json");
DO_TEST_NOCAPS("seclabel-dynamic");
DO_TEST_NOCAPS("seclabel-dynamic-baselabel");
DO_TEST_NOCAPS("seclabel-dynamic-override");
DO_TEST_NOCAPS("seclabel-dynamic-labelskip");
DO_TEST_NOCAPS("seclabel-dynamic-relabel");
DO_TEST_NOCAPS("seclabel-static");
DO_TEST_NOCAPS("seclabel-static-relabel");
DO_TEST_NOCAPS("seclabel-static-labelskip");
DO_TEST_NOCAPS("seclabel-none");
DO_TEST_NOCAPS("seclabel-dac-none");
DO_TEST_PARSE_ERROR_NOCAPS("seclabel-multiple");
DO_TEST_PARSE_ERROR_NOCAPS("seclabel-device-duplicates");
DO_TEST_CAPS_LATEST_PPC64("pseries-basic");
DO_TEST_CAPS_LATEST_PPC64("pseries-vio");
DO_TEST_CAPS_LATEST_PPC64("pseries-usb-default");
DO_TEST_CAPS_LATEST_PPC64("pseries-usb-multi");
DO_TEST_CAPS_LATEST_PPC64("pseries-vio-user-assigned");
DO_TEST_CAPS_LATEST_PPC64("pseries-nvram");
DO_TEST_CAPS_LATEST_PPC64("pseries-usb-kbd");
DO_TEST_CAPS_LATEST_PPC64("pseries-cpu-exact");
DO_TEST_PARSE_ERROR_NOCAPS("pseries-no-parallel");
DO_TEST_CAPS_LATEST_PPC64("pseries-cpu-le");
qemuTestSetHostArch(&driver, VIR_ARCH_PPC64);
DO_TEST_CAPS_LATEST_PPC64_HOSTCPU("pseries-cpu-compat",
QEMU_CPU_DEF_POWER9);
DO_TEST_CAPS_LATEST_PPC64_HOSTCPU_FAILURE("pseries-cpu-compat-power9",
QEMU_CPU_DEF_POWER8);
DO_TEST_CAPS_LATEST_PPC64_HOSTCPU("pseries-cpu-compat-power9",
QEMU_CPU_DEF_POWER9);
DO_TEST_CAPS_LATEST_PPC64_HOSTCPU_FAILURE("pseries-cpu-compat-power10",
QEMU_CPU_DEF_POWER9);
DO_TEST_CAPS_LATEST_PPC64_HOSTCPU("pseries-cpu-compat-power10",
QEMU_CPU_DEF_POWER10);
qemuTestSetHostArch(&driver, VIR_ARCH_NONE);
DO_TEST_CAPS_LATEST_PPC64("pseries-panic-missing");
DO_TEST_CAPS_LATEST_PPC64("pseries-panic-no-address");
DO_TEST_CAPS_ARCH_LATEST_PARSE_ERROR("pseries-panic-address", "ppc64");
DO_TEST_CAPS_LATEST_PPC64("pseries-phb-simple");
DO_TEST_CAPS_LATEST_PPC64("pseries-phb-default-missing");
DO_TEST_CAPS_LATEST_PPC64("pseries-phb-numa-node");
DO_TEST_CAPS_ARCH_LATEST_PARSE_ERROR("pseries-default-phb-numa-node",
"ppc64");
DO_TEST_PARSE_ERROR_NOCAPS("pseries-phb-invalid-target-index-1");
DO_TEST_PARSE_ERROR_NOCAPS("pseries-phb-invalid-target-index-2");
DO_TEST_PARSE_ERROR_NOCAPS("pseries-phb-invalid-target-index-3");
DO_TEST_CAPS_LATEST_PPC64("pseries-many-devices");
DO_TEST_CAPS_LATEST_PPC64("pseries-many-buses-1");
DO_TEST_CAPS_LATEST_PPC64("pseries-many-buses-2");
DO_TEST_CAPS_LATEST_PPC64("pseries-hostdevs-1");
DO_TEST_CAPS_LATEST_PPC64("pseries-hostdevs-2");
DO_TEST_CAPS_LATEST_PPC64("pseries-hostdevs-3");
DO_TEST_CAPS_LATEST_PPC64("pseries-features");
/* parse error: no QEMU_CAPS_MACHINE_PSERIES_CAP_HPT_MAX_PAGE_SIZE */
tests: refactor pseries features parse failure tests The qemuxml2argvtest pseries-feature parse failure tests uses a symlink to the pseries-features.xml test domain and control which feature it is supposed to fail by excluding it from the capabilities list. The advantage of this approach is that the same XML can be used in multiple tests. One downside is that any new pseries capability must be declared in all existent tests, otherwise all other tests can break if this new capability happens to be validated early in qemu_validate.c. Any new parse_error test must declare all other existent capabilities. Another downside is the fact that we're testing fairly improbable scenarios: all pseries capabilities being tested here were introduced by the same QEMU version, 4.2.0, at least as far as libvirt is aware of. This means that it's no possible to have a scenario where, for example, ccf-assist is not present but cfpc is. And last, but not the least, it's getting in the way of our effort to convert all pseries tests to not use explicit capabilities. Changing all these tests to use DO_TEST_PARSE_ERROR_NOCAPS() will allow us to test exactly what we want to test, which is the parse error given for each feature if the binary does not have support for it. The XML being used for each test can be simplified to just declare a single feature. In the end we'll end up with more XML lines, but less complexity inside qemuxml2argvtest.c. Reviewed-by: Michal Privoznik <mprivozn@redhat.com> Signed-off-by: Daniel Henrique Barboza <danielhb413@gmail.com>
2022-09-15 19:22:08 +03:00
DO_TEST_PARSE_ERROR_NOCAPS("pseries-features-hpt-pagesize");
/* parse error: no QEMU_CAPS_MACHINE_PSERIES_CAP_HTM */
tests: refactor pseries features parse failure tests The qemuxml2argvtest pseries-feature parse failure tests uses a symlink to the pseries-features.xml test domain and control which feature it is supposed to fail by excluding it from the capabilities list. The advantage of this approach is that the same XML can be used in multiple tests. One downside is that any new pseries capability must be declared in all existent tests, otherwise all other tests can break if this new capability happens to be validated early in qemu_validate.c. Any new parse_error test must declare all other existent capabilities. Another downside is the fact that we're testing fairly improbable scenarios: all pseries capabilities being tested here were introduced by the same QEMU version, 4.2.0, at least as far as libvirt is aware of. This means that it's no possible to have a scenario where, for example, ccf-assist is not present but cfpc is. And last, but not the least, it's getting in the way of our effort to convert all pseries tests to not use explicit capabilities. Changing all these tests to use DO_TEST_PARSE_ERROR_NOCAPS() will allow us to test exactly what we want to test, which is the parse error given for each feature if the binary does not have support for it. The XML being used for each test can be simplified to just declare a single feature. In the end we'll end up with more XML lines, but less complexity inside qemuxml2argvtest.c. Reviewed-by: Michal Privoznik <mprivozn@redhat.com> Signed-off-by: Daniel Henrique Barboza <danielhb413@gmail.com>
2022-09-15 19:22:08 +03:00
DO_TEST_PARSE_ERROR_NOCAPS("pseries-features-htm");
/* parse error: no QEMU_CAPS_MACHINE_PSERIES_CAP_NESTED_HV */
tests: refactor pseries features parse failure tests The qemuxml2argvtest pseries-feature parse failure tests uses a symlink to the pseries-features.xml test domain and control which feature it is supposed to fail by excluding it from the capabilities list. The advantage of this approach is that the same XML can be used in multiple tests. One downside is that any new pseries capability must be declared in all existent tests, otherwise all other tests can break if this new capability happens to be validated early in qemu_validate.c. Any new parse_error test must declare all other existent capabilities. Another downside is the fact that we're testing fairly improbable scenarios: all pseries capabilities being tested here were introduced by the same QEMU version, 4.2.0, at least as far as libvirt is aware of. This means that it's no possible to have a scenario where, for example, ccf-assist is not present but cfpc is. And last, but not the least, it's getting in the way of our effort to convert all pseries tests to not use explicit capabilities. Changing all these tests to use DO_TEST_PARSE_ERROR_NOCAPS() will allow us to test exactly what we want to test, which is the parse error given for each feature if the binary does not have support for it. The XML being used for each test can be simplified to just declare a single feature. In the end we'll end up with more XML lines, but less complexity inside qemuxml2argvtest.c. Reviewed-by: Michal Privoznik <mprivozn@redhat.com> Signed-off-by: Daniel Henrique Barboza <danielhb413@gmail.com>
2022-09-15 19:22:08 +03:00
DO_TEST_PARSE_ERROR_NOCAPS("pseries-features-nested-hv");
/* parse error: no QEMU_CAPS_MACHINE_PSERIES_CAP_CCF_ASSIST */
tests: refactor pseries features parse failure tests The qemuxml2argvtest pseries-feature parse failure tests uses a symlink to the pseries-features.xml test domain and control which feature it is supposed to fail by excluding it from the capabilities list. The advantage of this approach is that the same XML can be used in multiple tests. One downside is that any new pseries capability must be declared in all existent tests, otherwise all other tests can break if this new capability happens to be validated early in qemu_validate.c. Any new parse_error test must declare all other existent capabilities. Another downside is the fact that we're testing fairly improbable scenarios: all pseries capabilities being tested here were introduced by the same QEMU version, 4.2.0, at least as far as libvirt is aware of. This means that it's no possible to have a scenario where, for example, ccf-assist is not present but cfpc is. And last, but not the least, it's getting in the way of our effort to convert all pseries tests to not use explicit capabilities. Changing all these tests to use DO_TEST_PARSE_ERROR_NOCAPS() will allow us to test exactly what we want to test, which is the parse error given for each feature if the binary does not have support for it. The XML being used for each test can be simplified to just declare a single feature. In the end we'll end up with more XML lines, but less complexity inside qemuxml2argvtest.c. Reviewed-by: Michal Privoznik <mprivozn@redhat.com> Signed-off-by: Daniel Henrique Barboza <danielhb413@gmail.com>
2022-09-15 19:22:08 +03:00
DO_TEST_PARSE_ERROR_NOCAPS("pseries-features-ccf");
/* parse error: no QEMU_CAPS_MACHINE_PSERIES_CFPC */
tests: refactor pseries features parse failure tests The qemuxml2argvtest pseries-feature parse failure tests uses a symlink to the pseries-features.xml test domain and control which feature it is supposed to fail by excluding it from the capabilities list. The advantage of this approach is that the same XML can be used in multiple tests. One downside is that any new pseries capability must be declared in all existent tests, otherwise all other tests can break if this new capability happens to be validated early in qemu_validate.c. Any new parse_error test must declare all other existent capabilities. Another downside is the fact that we're testing fairly improbable scenarios: all pseries capabilities being tested here were introduced by the same QEMU version, 4.2.0, at least as far as libvirt is aware of. This means that it's no possible to have a scenario where, for example, ccf-assist is not present but cfpc is. And last, but not the least, it's getting in the way of our effort to convert all pseries tests to not use explicit capabilities. Changing all these tests to use DO_TEST_PARSE_ERROR_NOCAPS() will allow us to test exactly what we want to test, which is the parse error given for each feature if the binary does not have support for it. The XML being used for each test can be simplified to just declare a single feature. In the end we'll end up with more XML lines, but less complexity inside qemuxml2argvtest.c. Reviewed-by: Michal Privoznik <mprivozn@redhat.com> Signed-off-by: Daniel Henrique Barboza <danielhb413@gmail.com>
2022-09-15 19:22:08 +03:00
DO_TEST_PARSE_ERROR_NOCAPS("pseries-features-cfpc");
/* parse error: no QEMU_CAPS_MACHINE_PSERIES_SBBC */
tests: refactor pseries features parse failure tests The qemuxml2argvtest pseries-feature parse failure tests uses a symlink to the pseries-features.xml test domain and control which feature it is supposed to fail by excluding it from the capabilities list. The advantage of this approach is that the same XML can be used in multiple tests. One downside is that any new pseries capability must be declared in all existent tests, otherwise all other tests can break if this new capability happens to be validated early in qemu_validate.c. Any new parse_error test must declare all other existent capabilities. Another downside is the fact that we're testing fairly improbable scenarios: all pseries capabilities being tested here were introduced by the same QEMU version, 4.2.0, at least as far as libvirt is aware of. This means that it's no possible to have a scenario where, for example, ccf-assist is not present but cfpc is. And last, but not the least, it's getting in the way of our effort to convert all pseries tests to not use explicit capabilities. Changing all these tests to use DO_TEST_PARSE_ERROR_NOCAPS() will allow us to test exactly what we want to test, which is the parse error given for each feature if the binary does not have support for it. The XML being used for each test can be simplified to just declare a single feature. In the end we'll end up with more XML lines, but less complexity inside qemuxml2argvtest.c. Reviewed-by: Michal Privoznik <mprivozn@redhat.com> Signed-off-by: Daniel Henrique Barboza <danielhb413@gmail.com>
2022-09-15 19:22:08 +03:00
DO_TEST_PARSE_ERROR_NOCAPS("pseries-features-sbbc");
/* parse error: no QEMU_CAPS_MACHINE_PSERIES_IBS */
tests: refactor pseries features parse failure tests The qemuxml2argvtest pseries-feature parse failure tests uses a symlink to the pseries-features.xml test domain and control which feature it is supposed to fail by excluding it from the capabilities list. The advantage of this approach is that the same XML can be used in multiple tests. One downside is that any new pseries capability must be declared in all existent tests, otherwise all other tests can break if this new capability happens to be validated early in qemu_validate.c. Any new parse_error test must declare all other existent capabilities. Another downside is the fact that we're testing fairly improbable scenarios: all pseries capabilities being tested here were introduced by the same QEMU version, 4.2.0, at least as far as libvirt is aware of. This means that it's no possible to have a scenario where, for example, ccf-assist is not present but cfpc is. And last, but not the least, it's getting in the way of our effort to convert all pseries tests to not use explicit capabilities. Changing all these tests to use DO_TEST_PARSE_ERROR_NOCAPS() will allow us to test exactly what we want to test, which is the parse error given for each feature if the binary does not have support for it. The XML being used for each test can be simplified to just declare a single feature. In the end we'll end up with more XML lines, but less complexity inside qemuxml2argvtest.c. Reviewed-by: Michal Privoznik <mprivozn@redhat.com> Signed-off-by: Daniel Henrique Barboza <danielhb413@gmail.com>
2022-09-15 19:22:08 +03:00
DO_TEST_PARSE_ERROR_NOCAPS("pseries-features-ibs");
DO_TEST_PARSE_ERROR_NOCAPS("pseries-features-invalid-machine");
DO_TEST_CAPS_LATEST_PPC64("pseries-serial-native");
DO_TEST_CAPS_LATEST_PPC64("pseries-serial+console-native");
DO_TEST_CAPS_LATEST_PPC64("pseries-serial-compat");
DO_TEST_CAPS_LATEST_PPC64("pseries-serial-pci");
DO_TEST_CAPS_LATEST_PPC64("pseries-serial-usb");
DO_TEST_CAPS_LATEST_PPC64("pseries-console-native");
DO_TEST_CAPS_LATEST_PPC64("pseries-console-virtio");
DO_TEST_PARSE_ERROR_NOCAPS("pseries-serial-invalid-machine");
DO_TEST_PARSE_ERROR_NOCAPS("pseries-spaprvio-invalid");
DO_TEST("mach-virt-serial-native",
QEMU_CAPS_DEVICE_PL011);
DO_TEST("mach-virt-serial+console-native",
QEMU_CAPS_DEVICE_PL011);
DO_TEST("mach-virt-serial-compat",
QEMU_CAPS_DEVICE_PL011);
DO_TEST("mach-virt-serial-pci",
QEMU_CAPS_OBJECT_GPEX,
QEMU_CAPS_DEVICE_PCIE_ROOT_PORT,
QEMU_CAPS_DEVICE_DMI_TO_PCI_BRIDGE,
QEMU_CAPS_DEVICE_PCI_BRIDGE,
QEMU_CAPS_DEVICE_PCI_SERIAL);
DO_TEST("mach-virt-serial-usb",
QEMU_CAPS_OBJECT_GPEX,
QEMU_CAPS_DEVICE_PCIE_ROOT_PORT,
QEMU_CAPS_DEVICE_QEMU_XHCI,
QEMU_CAPS_DEVICE_USB_SERIAL);
DO_TEST("mach-virt-console-native",
QEMU_CAPS_DEVICE_PL011);
DO_TEST("mach-virt-console-virtio",
QEMU_CAPS_DEVICE_VIRTIO_MMIO);
DO_TEST_PARSE_ERROR_NOCAPS("mach-virt-serial-invalid-machine");
DO_TEST("video-device-pciaddr-default",
QEMU_CAPS_KVM,
QEMU_CAPS_VNC,
QEMU_CAPS_DEVICE_QXL);
DO_TEST("video-vga-device", QEMU_CAPS_DEVICE_VGA);
DO_TEST("video-vga-device-vgamem", QEMU_CAPS_DEVICE_VGA,
QEMU_CAPS_VGA_VGAMEM);
DO_TEST("video-qxl-device",
QEMU_CAPS_DEVICE_QXL);
DO_TEST("video-qxl-device-vgamem",
QEMU_CAPS_DEVICE_QXL,
QEMU_CAPS_QXL_VGAMEM);
DO_TEST_CAPS_LATEST("video-qxl-device-vram64");
DO_TEST("video-qxl-sec-device",
QEMU_CAPS_DEVICE_QXL);
DO_TEST("video-qxl-sec-device-vgamem",
QEMU_CAPS_DEVICE_QXL,
QEMU_CAPS_QXL_VGAMEM);
DO_TEST_CAPS_LATEST("video-qxl-sec-device-vram64");
DO_TEST("video-qxl-heads", QEMU_CAPS_DEVICE_QXL);
DO_TEST("video-vga-qxl-heads", QEMU_CAPS_DEVICE_QXL);
DO_TEST("video-qxl-noheads", QEMU_CAPS_DEVICE_QXL);
DO_TEST("video-qxl-resolution",
QEMU_CAPS_DEVICE_QXL,
QEMU_CAPS_QXL_VGAMEM);
DO_TEST("video-virtio-gpu-device",
QEMU_CAPS_DEVICE_VIRTIO_GPU);
DO_TEST("video-virtio-gpu-virgl",
QEMU_CAPS_DEVICE_VIRTIO_GPU,
QEMU_CAPS_VIRTIO_GPU_VIRGL);
DO_TEST("video-virtio-gpu-spice-gl",
QEMU_CAPS_DEVICE_VIRTIO_GPU,
QEMU_CAPS_VIRTIO_GPU_VIRGL,
QEMU_CAPS_SPICE,
QEMU_CAPS_SPICE_GL,
QEMU_CAPS_SPICE_RENDERNODE);
DO_TEST("video-virtio-gpu-sdl-gl",
QEMU_CAPS_DEVICE_VIRTIO_GPU,
QEMU_CAPS_VIRTIO_GPU_VIRGL,
QEMU_CAPS_SDL);
DO_TEST("video-virtio-gpu-secondary",
QEMU_CAPS_DEVICE_VIRTIO_GPU);
DO_TEST("video-virtio-vga",
QEMU_CAPS_DEVICE_VIRTIO_GPU,
QEMU_CAPS_DEVICE_VIRTIO_VGA);
DO_TEST_CAPS_LATEST("video-virtio-vga-gpu-gl");
DO_TEST_CAPS_LATEST("video-bochs-display-device");
DO_TEST_CAPS_LATEST("video-ramfb-display-device");
DO_TEST_CAPS_LATEST_PARSE_ERROR("video-ramfb-display-device-pci-address");
DO_TEST("video-none-device",
QEMU_CAPS_VNC);
DO_TEST_PARSE_ERROR_NOCAPS("video-invalid-multiple-devices");
DO_TEST_PARSE_ERROR_NOCAPS("default-video-type-x86_64-caps-test-0");
DO_TEST_CAPS_ARCH_LATEST("default-video-type-aarch64", "aarch64");
DO_TEST_CAPS_ARCH_LATEST("default-video-type-ppc64", "ppc64");
DO_TEST_CAPS_ARCH_LATEST("default-video-type-riscv64", "riscv64");
DO_TEST_CAPS_ARCH_LATEST("default-video-type-s390x", "s390x");
DO_TEST_PARSE_ERROR("video-multiple-primaries",
QEMU_CAPS_DEVICE_QXL,
QEMU_CAPS_DEVICE_VGA);
DO_TEST("virtio-rng-default",
QEMU_CAPS_DEVICE_VIRTIO_RNG,
QEMU_CAPS_OBJECT_RNG_RANDOM);
DO_TEST("virtio-rng-random",
QEMU_CAPS_DEVICE_VIRTIO_RNG,
QEMU_CAPS_OBJECT_RNG_RANDOM);
DO_TEST("virtio-rng-egd",
QEMU_CAPS_DEVICE_VIRTIO_RNG,
QEMU_CAPS_OBJECT_RNG_EGD);
DO_TEST_CAPS_VER("virtio-rng-builtin", "5.2.0");
DO_TEST_CAPS_LATEST("virtio-rng-builtin");
DO_TEST_CAPS_VER("virtio-rng-egd-unix", "5.2.0");
DO_TEST_CAPS_LATEST("virtio-rng-egd-unix");
DO_TEST("virtio-rng-multiple",
QEMU_CAPS_DEVICE_VIRTIO_RNG,
QEMU_CAPS_OBJECT_RNG_EGD,
QEMU_CAPS_OBJECT_RNG_RANDOM);
DO_TEST_PARSE_ERROR("virtio-rng-egd-crash",
QEMU_CAPS_DEVICE_VIRTIO_RNG,
QEMU_CAPS_OBJECT_RNG_EGD);
DO_TEST_CAPS_ARCH_LATEST("virtio-rng-ccw", "s390x");
DO_TEST_CAPS_ARCH_LATEST("s390-allow-bogus-usb-none", "s390x");
DO_TEST_CAPS_ARCH_LATEST("s390-allow-bogus-usb-controller", "s390x");
DO_TEST_NOCAPS("s390-panic-no-address");
DO_TEST_PARSE_ERROR_NOCAPS("s390-panic-address");
DO_TEST_NOCAPS("s390-panic-missing");
DO_TEST_PARSE_ERROR_NOCAPS("s390-no-parallel");
DO_TEST("s390-serial", QEMU_CAPS_DEVICE_SCLPCONSOLE);
DO_TEST("s390-serial-2",
QEMU_CAPS_DEVICE_SCLPCONSOLE,
QEMU_CAPS_DEVICE_SCLPLMCONSOLE);
DO_TEST("s390-serial-console",
QEMU_CAPS_DEVICE_SCLPCONSOLE);
DO_TEST("ppc-dtb",
QEMU_CAPS_KVM);
DO_TEST("ppce500-serial",
QEMU_CAPS_KVM);
DO_TEST_CAPS_LATEST("tpm-passthrough");
DO_TEST_CAPS_LATEST("tpm-passthrough-crb");
DO_TEST_PARSE_ERROR("tpm-no-backend-invalid",
QEMU_CAPS_DEVICE_TPM_PASSTHROUGH, QEMU_CAPS_DEVICE_TPM_TIS);
DO_TEST_CAPS_LATEST("tpm-emulator");
DO_TEST_CAPS_LATEST("tpm-emulator-tpm2");
DO_TEST_CAPS_LATEST("tpm-emulator-tpm2-enc");
DO_TEST_CAPS_LATEST("tpm-emulator-tpm2-pstate");
DO_TEST_CAPS_LATEST_PPC64("tpm-emulator-spapr");
DO_TEST_CAPS_ARCH_LATEST("aarch64-tpm", "aarch64");
DO_TEST_PARSE_ERROR_NOCAPS("aarch64-tpm-wrong-model");
conf: more useful error message when pci function is out of range If a pci address had a function number out of range, the error message would be: Insufficient specification for PCI address which is logged by virDevicePCIAddressParseXML() after virDevicePCIAddressIsValid returns a failure. This patch enhances virDevicePCIAddressIsValid() to optionally report the error itself (since it is the place that decides which part of the address is "invalid"), and uses that feature when calling from virDevicePCIAddressParseXML(), so that the error will be more useful, e.g.: Invalid PCI address function=0x8, must be <= 7 Previously, virDevicePCIAddressIsValid didn't check for the theoretical limits of domain or bus, only for slot or function. While adding log messages, we also correct that ommission. (The RNG for PCI addresses already enforces this limit, which by the way means that we can't add any negative tests for this - as far as I know our domainschematest has no provisions for passing XML that is supposed to fail). Note that virDevicePCIAddressIsValid() can only check against the absolute maximum attribute values for *any* possible PCI controller, not for the actual maximums of the specific controller that this device is attaching to; fortunately there is later more specific validation for guest-side PCI addresses when building the set of assigned PCI addresses. For host-side PCI addresses (e.g. for <hostdev> and for network device pools), we rely on the error that will be logged when it is found that the device doesn't actually exist. This resolves: https://bugzilla.redhat.com/show_bug.cgi?id=1004596
2015-07-22 18:59:00 +03:00
g_setenv(TEST_TPM_ENV_VAR, TPM_VER_2_0, true);
DO_TEST_CAPS_LATEST_PARSE_ERROR("tpm-emulator");
g_setenv(TEST_TPM_ENV_VAR, TPM_VER_1_2, true);
DO_TEST_CAPS_LATEST_PARSE_ERROR("tpm-emulator-tpm2");
unsetenv(TEST_TPM_ENV_VAR);
DO_TEST_PARSE_ERROR_NOCAPS("pci-domain-invalid");
DO_TEST_PARSE_ERROR_NOCAPS("pci-bus-invalid");
DO_TEST_PARSE_ERROR_NOCAPS("pci-slot-invalid");
DO_TEST_PARSE_ERROR_NOCAPS("pci-function-invalid");
conf: more useful error message when pci function is out of range If a pci address had a function number out of range, the error message would be: Insufficient specification for PCI address which is logged by virDevicePCIAddressParseXML() after virDevicePCIAddressIsValid returns a failure. This patch enhances virDevicePCIAddressIsValid() to optionally report the error itself (since it is the place that decides which part of the address is "invalid"), and uses that feature when calling from virDevicePCIAddressParseXML(), so that the error will be more useful, e.g.: Invalid PCI address function=0x8, must be <= 7 Previously, virDevicePCIAddressIsValid didn't check for the theoretical limits of domain or bus, only for slot or function. While adding log messages, we also correct that ommission. (The RNG for PCI addresses already enforces this limit, which by the way means that we can't add any negative tests for this - as far as I know our domainschematest has no provisions for passing XML that is supposed to fail). Note that virDevicePCIAddressIsValid() can only check against the absolute maximum attribute values for *any* possible PCI controller, not for the actual maximums of the specific controller that this device is attaching to; fortunately there is later more specific validation for guest-side PCI addresses when building the set of assigned PCI addresses. For host-side PCI addresses (e.g. for <hostdev> and for network device pools), we rely on the error that will be logged when it is found that the device doesn't actually exist. This resolves: https://bugzilla.redhat.com/show_bug.cgi?id=1004596
2015-07-22 18:59:00 +03:00
DO_TEST("pci-bridge",
QEMU_CAPS_DEVICE_PCI_BRIDGE,
QEMU_CAPS_VNC,
QEMU_CAPS_DEVICE_CIRRUS_VGA);
DO_TEST("pci-autoadd-addr",
QEMU_CAPS_DEVICE_PCI_BRIDGE,
QEMU_CAPS_DEVICE_CIRRUS_VGA);
DO_TEST("pci-autoadd-idx",
QEMU_CAPS_DEVICE_PCI_BRIDGE,
QEMU_CAPS_DEVICE_CIRRUS_VGA);
DO_TEST("pci-autofill-addr", QEMU_CAPS_DEVICE_CIRRUS_VGA);
DO_TEST("pci-many",
QEMU_CAPS_DEVICE_CIRRUS_VGA);
qemu: set/validate slot/connection type when assigning slots for PCI devices Since PCI bridges, PCIe bridges, PCIe switches, and PCIe root ports all share the same namespace, they are all defined as controllers of type='pci' in libvirt (but with a differing model attribute). Each of these controllers has a certain connection type upstream, allows certain connection types downstream, and each can either allow a single downstream connection at slot 0, or connections from slot 1 - 31. Right now, we only support the pci-root and pci-bridge devices, both of which only allow PCI devices to connect, and both which have usable slots 1 - 31. In preparation for adding other types of controllers that have different capabilities, this patch 1) adds info to the qemuDomainPCIAddressBus object to indicate the capabilities, 2) sets those capabilities appropriately for pci-root and pci-bridge devices, and 3) validates that the controller being connected to is the proper type when allocating slots or validating that a user-selected slot is appropriate for a device.. Having this infrastructure in place will make it much easier to add support for the other PCI controller types. While it would be possible to do all the necessary checking by just storing the controller model in the qemyuDomainPCIAddressBus, it greatly simplifies all the validation code to also keep a "flags", "minSlot" and "maxSlot" for each - that way we can just check those attributes rather than requiring a nearly identical switch statement everywhere we need to validate compatibility. You may notice many places where the flags are seemingly hard-coded to QEMU_PCI_CONNECT_HOTPLUGGABLE | QEMU_PCI_CONNECT_TYPE_PCI This is currently the correct value for all PCI devices, and in the future will be the default, with small bits of code added to change to the flags for the few devices which are the exceptions to this rule. Finally, there are a few places with "FIXME" comments. Note that these aren't indicating places that are broken according to the currently supported devices, they are places that will need fixing when support for new PCI controller models is added. To assure that there was no regression in the auto-allocation of PCI addresses or auto-creation of integrated pci-root, ide, and usb controllers, a new test case (pci-bridge-many-disks) has been added to both the qemuxml2argv and qemuxml2xml tests. This new test defines a domain with several dozen virtio disks but no pci-root or pci-bridges. The .args file of the new test case was created using libvirt sources from before this patch, and the test still passes after this patch has been applied.
2013-07-15 04:09:44 +04:00
DO_TEST("pci-bridge-many-disks",
QEMU_CAPS_DEVICE_PCI_BRIDGE);
DO_TEST("pcie-root",
QEMU_CAPS_DEVICE_IOH3420,
QEMU_CAPS_ICH9_AHCI,
QEMU_CAPS_DEVICE_QXL);
qemu: add dmi-to-pci-bridge controller This PCI controller, named "dmi-to-pci-bridge" in the libvirt config, and implemented with qemu's "i82801b11-bridge" device, connects to a PCI Express slot (e.g. one of the slots provided by the pcie-root controller, aka "pcie.0" on the qemu commandline), and provides 31 *non-hot-pluggable* PCI (*not* PCIe) slots, numbered 1-31. Any time a machine is defined which has a pcie-root controller (i.e. any q35-based machinetype), libvirt will automatically add a dmi-to-pci-bridge controller if one doesn't exist, and also add a pci-bridge controller. The reasoning here is that any useful domain will have either an immediate (startup time) or eventual (subsequent hot-plug) need for a standard PCI slot; since the pcie-root controller only provides PCIe slots, we need to connect a dmi-to-pci-bridge controller to it in order to get a non-hot-plug PCI slot that we can then use to connect a pci-bridge - the slots provided by the pci-bridge will be both standard PCI and hot-pluggable. Since pci-bridge devices themselves can not be hot-plugged into a running system (although you can hot-plug other devices into a pci-bridge's slots), any new pci-bridge controller that is added can (and will) be plugged into the dmi-to-pci-bridge as long as it has empty slots available. This patch is also changing the qemuxml2xml-pcie test from a "DO_TEST" to a "DO_DIFFERENT_TEST". This is so that the "before" xml can omit the automatically added dmi-to-pci-bridge and pci-bridge devices, and the "after" xml can include it - this way we are testing if libvirt is properly adding these devices.
2013-07-31 05:37:32 +04:00
DO_TEST("q35",
QEMU_CAPS_DEVICE_PCI_BRIDGE,
qemu: add dmi-to-pci-bridge controller This PCI controller, named "dmi-to-pci-bridge" in the libvirt config, and implemented with qemu's "i82801b11-bridge" device, connects to a PCI Express slot (e.g. one of the slots provided by the pcie-root controller, aka "pcie.0" on the qemu commandline), and provides 31 *non-hot-pluggable* PCI (*not* PCIe) slots, numbered 1-31. Any time a machine is defined which has a pcie-root controller (i.e. any q35-based machinetype), libvirt will automatically add a dmi-to-pci-bridge controller if one doesn't exist, and also add a pci-bridge controller. The reasoning here is that any useful domain will have either an immediate (startup time) or eventual (subsequent hot-plug) need for a standard PCI slot; since the pcie-root controller only provides PCIe slots, we need to connect a dmi-to-pci-bridge controller to it in order to get a non-hot-plug PCI slot that we can then use to connect a pci-bridge - the slots provided by the pci-bridge will be both standard PCI and hot-pluggable. Since pci-bridge devices themselves can not be hot-plugged into a running system (although you can hot-plug other devices into a pci-bridge's slots), any new pci-bridge controller that is added can (and will) be plugged into the dmi-to-pci-bridge as long as it has empty slots available. This patch is also changing the qemuxml2xml-pcie test from a "DO_TEST" to a "DO_DIFFERENT_TEST". This is so that the "before" xml can omit the automatically added dmi-to-pci-bridge and pci-bridge devices, and the "after" xml can include it - this way we are testing if libvirt is properly adding these devices.
2013-07-31 05:37:32 +04:00
QEMU_CAPS_DEVICE_DMI_TO_PCI_BRIDGE,
qemu: initially reserve one open pcie-root-port for hotplug For machinetypes with a pci-root bus (all legacy PCI), libvirt will make a "fake" reservation for one extra slot prior to assigning addresses to unaddressed PCI endpoint devices in the domain. This will trigger auto-adding of a pci-bridge for the final device to be assigned an address *if that device would have otherwise instead been the last device on the last available pci-bridge*; thus it assures that there will always be at least one slot left open in the domain's bus topology for expansion (which is important both for hotplug (since a new pci-bridge can't be added while the guest is running) as well as for offline additions to the config (since adding a new device might otherwise in some cases require re-addressing existing devices, which we want to avoid)). It's important to note that for the above case (legacy PCI), we must check for the special case of all slots on all buses being occupied *prior to assigning any addresses*, and avoid attempting to reserve the extra address in that case, because there is no free address in the existing topology, so no place to auto-add a pci-bridge for expansion (i.e. it would always fail anyway). Since that condition can only be reached by manual intervention, this is acceptable. For machinetypes with pcie-root (Q35, aarch64 virt), libvirt's methodology for automatically expanding the bus topology is different - pcie-root-ports are plugged into slots (soon to be functions) of pcie-root as needed, and the new endpoint devices are assigned to the single slot in each pcie-root-port. This is done so that the devices are, by default, hotpluggable (the slots of pcie-root don't support hotplug, but the single slot of the pcie-root-port does). Since pcie-root-ports can only be plugged into pcie-root, and we don't auto-assign endpoint devices to the pcie-root slots, this means topology expansion doesn't compete with endpoint devices for slots, so we don't need to worry about checking for all "useful" slots being free *prior* to assigning addresses to new endpoint devices - as a matter of fact, if we attempt to reserve the open slots before the used slots, it can lead to errors. Instead this patch just reserves one slot for a "future potential" PCIe device after doing the assignment for actual devices, but only if the only PCI controller defined prior to starting address assignment was pcie-root, and only if we auto-added at least one PCI controller during address assignment. This assures two things: 1) that reserving the open slots will only be done when the domain is initially defined, never at any time after, and 2) that if the user understands enough about PCI controllers that they are adding them manually, that we don't mess up their plan by adding extras - if they know enough to add one pcie-root-port, or to manually assign addresses such that no pcie-root-ports are needed, they know enough to add extra pcie-root-ports if they want them (this could be called the "libguestfs clause", since libguestfs needs to be able to create domains with as few devices/controllers as possible). This is set to reserve a single free port for now, but could be increased in the future if public sentiment goes in that direction (it's easy to increase later, but essentially impossible to decrease)
2016-09-28 03:37:30 +03:00
QEMU_CAPS_DEVICE_IOH3420,
QEMU_CAPS_ICH9_AHCI,
QEMU_CAPS_ICH9_USB_EHCI1,
QEMU_CAPS_DEVICE_QXL);
DO_TEST_PARSE_ERROR("q35-dmi-bad-address1",
QEMU_CAPS_DEVICE_PCI_BRIDGE,
QEMU_CAPS_DEVICE_DMI_TO_PCI_BRIDGE,
QEMU_CAPS_DEVICE_IOH3420);
DO_TEST_PARSE_ERROR("q35-dmi-bad-address2",
QEMU_CAPS_DEVICE_PCI_BRIDGE,
QEMU_CAPS_DEVICE_DMI_TO_PCI_BRIDGE,
QEMU_CAPS_DEVICE_IOH3420);
DO_TEST("q35-pm-disable",
QEMU_CAPS_DEVICE_PCI_BRIDGE,
qemu: initially reserve one open pcie-root-port for hotplug For machinetypes with a pci-root bus (all legacy PCI), libvirt will make a "fake" reservation for one extra slot prior to assigning addresses to unaddressed PCI endpoint devices in the domain. This will trigger auto-adding of a pci-bridge for the final device to be assigned an address *if that device would have otherwise instead been the last device on the last available pci-bridge*; thus it assures that there will always be at least one slot left open in the domain's bus topology for expansion (which is important both for hotplug (since a new pci-bridge can't be added while the guest is running) as well as for offline additions to the config (since adding a new device might otherwise in some cases require re-addressing existing devices, which we want to avoid)). It's important to note that for the above case (legacy PCI), we must check for the special case of all slots on all buses being occupied *prior to assigning any addresses*, and avoid attempting to reserve the extra address in that case, because there is no free address in the existing topology, so no place to auto-add a pci-bridge for expansion (i.e. it would always fail anyway). Since that condition can only be reached by manual intervention, this is acceptable. For machinetypes with pcie-root (Q35, aarch64 virt), libvirt's methodology for automatically expanding the bus topology is different - pcie-root-ports are plugged into slots (soon to be functions) of pcie-root as needed, and the new endpoint devices are assigned to the single slot in each pcie-root-port. This is done so that the devices are, by default, hotpluggable (the slots of pcie-root don't support hotplug, but the single slot of the pcie-root-port does). Since pcie-root-ports can only be plugged into pcie-root, and we don't auto-assign endpoint devices to the pcie-root slots, this means topology expansion doesn't compete with endpoint devices for slots, so we don't need to worry about checking for all "useful" slots being free *prior* to assigning addresses to new endpoint devices - as a matter of fact, if we attempt to reserve the open slots before the used slots, it can lead to errors. Instead this patch just reserves one slot for a "future potential" PCIe device after doing the assignment for actual devices, but only if the only PCI controller defined prior to starting address assignment was pcie-root, and only if we auto-added at least one PCI controller during address assignment. This assures two things: 1) that reserving the open slots will only be done when the domain is initially defined, never at any time after, and 2) that if the user understands enough about PCI controllers that they are adding them manually, that we don't mess up their plan by adding extras - if they know enough to add one pcie-root-port, or to manually assign addresses such that no pcie-root-ports are needed, they know enough to add extra pcie-root-ports if they want them (this could be called the "libguestfs clause", since libguestfs needs to be able to create domains with as few devices/controllers as possible). This is set to reserve a single free port for now, but could be increased in the future if public sentiment goes in that direction (it's easy to increase later, but essentially impossible to decrease)
2016-09-28 03:37:30 +03:00
QEMU_CAPS_DEVICE_IOH3420,
QEMU_CAPS_DEVICE_DMI_TO_PCI_BRIDGE, QEMU_CAPS_ICH9_AHCI,
QEMU_CAPS_PIIX_DISABLE_S3, QEMU_CAPS_PIIX_DISABLE_S4,
QEMU_CAPS_ICH9_DISABLE_S3, QEMU_CAPS_ICH9_DISABLE_S4);
DO_TEST("q35-pm-disable-fallback",
QEMU_CAPS_DEVICE_PCI_BRIDGE,
qemu: initially reserve one open pcie-root-port for hotplug For machinetypes with a pci-root bus (all legacy PCI), libvirt will make a "fake" reservation for one extra slot prior to assigning addresses to unaddressed PCI endpoint devices in the domain. This will trigger auto-adding of a pci-bridge for the final device to be assigned an address *if that device would have otherwise instead been the last device on the last available pci-bridge*; thus it assures that there will always be at least one slot left open in the domain's bus topology for expansion (which is important both for hotplug (since a new pci-bridge can't be added while the guest is running) as well as for offline additions to the config (since adding a new device might otherwise in some cases require re-addressing existing devices, which we want to avoid)). It's important to note that for the above case (legacy PCI), we must check for the special case of all slots on all buses being occupied *prior to assigning any addresses*, and avoid attempting to reserve the extra address in that case, because there is no free address in the existing topology, so no place to auto-add a pci-bridge for expansion (i.e. it would always fail anyway). Since that condition can only be reached by manual intervention, this is acceptable. For machinetypes with pcie-root (Q35, aarch64 virt), libvirt's methodology for automatically expanding the bus topology is different - pcie-root-ports are plugged into slots (soon to be functions) of pcie-root as needed, and the new endpoint devices are assigned to the single slot in each pcie-root-port. This is done so that the devices are, by default, hotpluggable (the slots of pcie-root don't support hotplug, but the single slot of the pcie-root-port does). Since pcie-root-ports can only be plugged into pcie-root, and we don't auto-assign endpoint devices to the pcie-root slots, this means topology expansion doesn't compete with endpoint devices for slots, so we don't need to worry about checking for all "useful" slots being free *prior* to assigning addresses to new endpoint devices - as a matter of fact, if we attempt to reserve the open slots before the used slots, it can lead to errors. Instead this patch just reserves one slot for a "future potential" PCIe device after doing the assignment for actual devices, but only if the only PCI controller defined prior to starting address assignment was pcie-root, and only if we auto-added at least one PCI controller during address assignment. This assures two things: 1) that reserving the open slots will only be done when the domain is initially defined, never at any time after, and 2) that if the user understands enough about PCI controllers that they are adding them manually, that we don't mess up their plan by adding extras - if they know enough to add one pcie-root-port, or to manually assign addresses such that no pcie-root-ports are needed, they know enough to add extra pcie-root-ports if they want them (this could be called the "libguestfs clause", since libguestfs needs to be able to create domains with as few devices/controllers as possible). This is set to reserve a single free port for now, but could be increased in the future if public sentiment goes in that direction (it's easy to increase later, but essentially impossible to decrease)
2016-09-28 03:37:30 +03:00
QEMU_CAPS_DEVICE_IOH3420,
QEMU_CAPS_DEVICE_DMI_TO_PCI_BRIDGE, QEMU_CAPS_ICH9_AHCI,
QEMU_CAPS_PIIX_DISABLE_S3, QEMU_CAPS_PIIX_DISABLE_S4);
DO_TEST_CAPS_LATEST("pc-i440fx-acpi-root-hotplug-disable");
DO_TEST_CAPS_LATEST("pc-i440fx-acpi-root-hotplug-enable");
DO_TEST_CAPS_VER_PARSE_ERROR("pc-i440fx-acpi-root-hotplug-disable", "5.1.0");
DO_TEST_CAPS_VER_PARSE_ERROR("pc-i440fx-acpi-root-hotplug-enable", "5.1.0");
DO_TEST("q35-usb2",
QEMU_CAPS_DEVICE_PCI_BRIDGE,
QEMU_CAPS_DEVICE_DMI_TO_PCI_BRIDGE,
qemu: initially reserve one open pcie-root-port for hotplug For machinetypes with a pci-root bus (all legacy PCI), libvirt will make a "fake" reservation for one extra slot prior to assigning addresses to unaddressed PCI endpoint devices in the domain. This will trigger auto-adding of a pci-bridge for the final device to be assigned an address *if that device would have otherwise instead been the last device on the last available pci-bridge*; thus it assures that there will always be at least one slot left open in the domain's bus topology for expansion (which is important both for hotplug (since a new pci-bridge can't be added while the guest is running) as well as for offline additions to the config (since adding a new device might otherwise in some cases require re-addressing existing devices, which we want to avoid)). It's important to note that for the above case (legacy PCI), we must check for the special case of all slots on all buses being occupied *prior to assigning any addresses*, and avoid attempting to reserve the extra address in that case, because there is no free address in the existing topology, so no place to auto-add a pci-bridge for expansion (i.e. it would always fail anyway). Since that condition can only be reached by manual intervention, this is acceptable. For machinetypes with pcie-root (Q35, aarch64 virt), libvirt's methodology for automatically expanding the bus topology is different - pcie-root-ports are plugged into slots (soon to be functions) of pcie-root as needed, and the new endpoint devices are assigned to the single slot in each pcie-root-port. This is done so that the devices are, by default, hotpluggable (the slots of pcie-root don't support hotplug, but the single slot of the pcie-root-port does). Since pcie-root-ports can only be plugged into pcie-root, and we don't auto-assign endpoint devices to the pcie-root slots, this means topology expansion doesn't compete with endpoint devices for slots, so we don't need to worry about checking for all "useful" slots being free *prior* to assigning addresses to new endpoint devices - as a matter of fact, if we attempt to reserve the open slots before the used slots, it can lead to errors. Instead this patch just reserves one slot for a "future potential" PCIe device after doing the assignment for actual devices, but only if the only PCI controller defined prior to starting address assignment was pcie-root, and only if we auto-added at least one PCI controller during address assignment. This assures two things: 1) that reserving the open slots will only be done when the domain is initially defined, never at any time after, and 2) that if the user understands enough about PCI controllers that they are adding them manually, that we don't mess up their plan by adding extras - if they know enough to add one pcie-root-port, or to manually assign addresses such that no pcie-root-ports are needed, they know enough to add extra pcie-root-ports if they want them (this could be called the "libguestfs clause", since libguestfs needs to be able to create domains with as few devices/controllers as possible). This is set to reserve a single free port for now, but could be increased in the future if public sentiment goes in that direction (it's easy to increase later, but essentially impossible to decrease)
2016-09-28 03:37:30 +03:00
QEMU_CAPS_DEVICE_IOH3420,
QEMU_CAPS_ICH9_AHCI,
QEMU_CAPS_ICH9_USB_EHCI1,
QEMU_CAPS_DEVICE_QXL);
DO_TEST("q35-usb2-multi",
QEMU_CAPS_DEVICE_PCI_BRIDGE,
QEMU_CAPS_DEVICE_DMI_TO_PCI_BRIDGE,
qemu: initially reserve one open pcie-root-port for hotplug For machinetypes with a pci-root bus (all legacy PCI), libvirt will make a "fake" reservation for one extra slot prior to assigning addresses to unaddressed PCI endpoint devices in the domain. This will trigger auto-adding of a pci-bridge for the final device to be assigned an address *if that device would have otherwise instead been the last device on the last available pci-bridge*; thus it assures that there will always be at least one slot left open in the domain's bus topology for expansion (which is important both for hotplug (since a new pci-bridge can't be added while the guest is running) as well as for offline additions to the config (since adding a new device might otherwise in some cases require re-addressing existing devices, which we want to avoid)). It's important to note that for the above case (legacy PCI), we must check for the special case of all slots on all buses being occupied *prior to assigning any addresses*, and avoid attempting to reserve the extra address in that case, because there is no free address in the existing topology, so no place to auto-add a pci-bridge for expansion (i.e. it would always fail anyway). Since that condition can only be reached by manual intervention, this is acceptable. For machinetypes with pcie-root (Q35, aarch64 virt), libvirt's methodology for automatically expanding the bus topology is different - pcie-root-ports are plugged into slots (soon to be functions) of pcie-root as needed, and the new endpoint devices are assigned to the single slot in each pcie-root-port. This is done so that the devices are, by default, hotpluggable (the slots of pcie-root don't support hotplug, but the single slot of the pcie-root-port does). Since pcie-root-ports can only be plugged into pcie-root, and we don't auto-assign endpoint devices to the pcie-root slots, this means topology expansion doesn't compete with endpoint devices for slots, so we don't need to worry about checking for all "useful" slots being free *prior* to assigning addresses to new endpoint devices - as a matter of fact, if we attempt to reserve the open slots before the used slots, it can lead to errors. Instead this patch just reserves one slot for a "future potential" PCIe device after doing the assignment for actual devices, but only if the only PCI controller defined prior to starting address assignment was pcie-root, and only if we auto-added at least one PCI controller during address assignment. This assures two things: 1) that reserving the open slots will only be done when the domain is initially defined, never at any time after, and 2) that if the user understands enough about PCI controllers that they are adding them manually, that we don't mess up their plan by adding extras - if they know enough to add one pcie-root-port, or to manually assign addresses such that no pcie-root-ports are needed, they know enough to add extra pcie-root-ports if they want them (this could be called the "libguestfs clause", since libguestfs needs to be able to create domains with as few devices/controllers as possible). This is set to reserve a single free port for now, but could be increased in the future if public sentiment goes in that direction (it's easy to increase later, but essentially impossible to decrease)
2016-09-28 03:37:30 +03:00
QEMU_CAPS_DEVICE_IOH3420,
QEMU_CAPS_ICH9_AHCI,
QEMU_CAPS_ICH9_USB_EHCI1,
QEMU_CAPS_DEVICE_QXL);
DO_TEST("q35-usb2-reorder",
QEMU_CAPS_DEVICE_PCI_BRIDGE,
QEMU_CAPS_DEVICE_DMI_TO_PCI_BRIDGE,
qemu: initially reserve one open pcie-root-port for hotplug For machinetypes with a pci-root bus (all legacy PCI), libvirt will make a "fake" reservation for one extra slot prior to assigning addresses to unaddressed PCI endpoint devices in the domain. This will trigger auto-adding of a pci-bridge for the final device to be assigned an address *if that device would have otherwise instead been the last device on the last available pci-bridge*; thus it assures that there will always be at least one slot left open in the domain's bus topology for expansion (which is important both for hotplug (since a new pci-bridge can't be added while the guest is running) as well as for offline additions to the config (since adding a new device might otherwise in some cases require re-addressing existing devices, which we want to avoid)). It's important to note that for the above case (legacy PCI), we must check for the special case of all slots on all buses being occupied *prior to assigning any addresses*, and avoid attempting to reserve the extra address in that case, because there is no free address in the existing topology, so no place to auto-add a pci-bridge for expansion (i.e. it would always fail anyway). Since that condition can only be reached by manual intervention, this is acceptable. For machinetypes with pcie-root (Q35, aarch64 virt), libvirt's methodology for automatically expanding the bus topology is different - pcie-root-ports are plugged into slots (soon to be functions) of pcie-root as needed, and the new endpoint devices are assigned to the single slot in each pcie-root-port. This is done so that the devices are, by default, hotpluggable (the slots of pcie-root don't support hotplug, but the single slot of the pcie-root-port does). Since pcie-root-ports can only be plugged into pcie-root, and we don't auto-assign endpoint devices to the pcie-root slots, this means topology expansion doesn't compete with endpoint devices for slots, so we don't need to worry about checking for all "useful" slots being free *prior* to assigning addresses to new endpoint devices - as a matter of fact, if we attempt to reserve the open slots before the used slots, it can lead to errors. Instead this patch just reserves one slot for a "future potential" PCIe device after doing the assignment for actual devices, but only if the only PCI controller defined prior to starting address assignment was pcie-root, and only if we auto-added at least one PCI controller during address assignment. This assures two things: 1) that reserving the open slots will only be done when the domain is initially defined, never at any time after, and 2) that if the user understands enough about PCI controllers that they are adding them manually, that we don't mess up their plan by adding extras - if they know enough to add one pcie-root-port, or to manually assign addresses such that no pcie-root-ports are needed, they know enough to add extra pcie-root-ports if they want them (this could be called the "libguestfs clause", since libguestfs needs to be able to create domains with as few devices/controllers as possible). This is set to reserve a single free port for now, but could be increased in the future if public sentiment goes in that direction (it's easy to increase later, but essentially impossible to decrease)
2016-09-28 03:37:30 +03:00
QEMU_CAPS_DEVICE_IOH3420,
QEMU_CAPS_ICH9_AHCI,
QEMU_CAPS_ICH9_USB_EHCI1,
QEMU_CAPS_DEVICE_QXL);
/* Note: The real caps versions of the following tests based on qemu-4.2.0
* were added as a comparison point between fake caps testing and real caps
* testing and don't have any other specific purpose */
qemu: assign virtio devices to PCIe slot when appropriate libvirt previously assigned nearly all devices to a "hotpluggable" legacy PCI slot even on machines with a PCIe root bus (and even though most such machines don't even support hotplug on legacy PCI slots!) Forcing all devices onto legacy PCI slots means that the domain will need a dmi-to-pci-bridge (to convert from PCIe to legacy PCI) and a pci-bridge (to provide hotpluggable legacy PCI slots which, again, usually aren't hotpluggable anyway). To help reduce the need for these legacy controllers, this patch tries to assign virtio-1.0-capable devices to PCIe slots whenever possible, by setting appropriate connectFlags in virDomainCalculateDevicePCIConnectFlags(). Happily, when that function was written (just a few commits ago) it was created with a "virtioFlags" argument, set by both of its callers, which is the proper connectFlags to set for any virtio-*-pci device - depending on the arch/machinetype of the domain, and whether or not the qemu binary supports virtio-1.0, that flag will have either been set to PCI or PCIe. This patch merely enables the functionality by setting the flags for the device to whatever is in virtioFlags if the device is a virtio-*-pci device. NB: the first virtio video device will be placed directly on bus 0 slot 1 rather than on a pcie-root-port due to the override for primary video devices in qemuDomainValidateDevicePCISlotsQ35(). Whether or not to change that is a topic of discussion, but this patch doesn't change that particular behavior. NB2: since the slot must be hotpluggable, and pcie-root (the PCIe root complex) does *not* support hotplug, this means that suitable controllers must also be in the config (i.e. either pcie-root-port, or pcie-downstream-port). For now, libvirt doesn't add those automatically, so if you put virtio devices in a config for a qemu that has PCIe-capable virtio devices, you'll need to add extra pcie-root-ports yourself. That requirement will be eliminated in a future patch, but for now, it's simple to do this: <controller type='pci' model='pcie-root-port'/> <controller type='pci' model='pcie-root-port'/> <controller type='pci' model='pcie-root-port'/> ... Partially Resolves: https://bugzilla.redhat.com/show_bug.cgi?id=1330024
2016-08-14 01:10:41 +03:00
/* verify that devices with pcie capability are assigned to a pcie slot */
DO_TEST_CAPS_VER("q35-pcie", "4.2.0");
DO_TEST_CAPS_LATEST("q35-pcie");
qemu: auto-add pcie-root-port/dmi-to-pci-bridge controllers as needed Previously libvirt would only add pci-bridge devices automatically when an address was requested for a device that required a legacy PCI slot and none was available. This patch expands that support to dmi-to-pci-bridge (which is needed in order to add a pci-bridge on a machine with a pcie-root), and pcie-root-port (which is needed to add a hotpluggable PCIe device). It does *not* automatically add pcie-switch-upstream-ports or pcie-switch-downstream-ports (and currently there are no plans for that). Given the existing code to auto-add pci-bridge devices, automatically adding pcie-root-ports is fairly straightforward. The dmi-to-pci-bridge support is a bit tricky though, for a few reasons: 1) Although the only reason to add a dmi-to-pci-bridge is so that there is a reasonable place to plug in a pci-bridge controller, most of the time it's not the presence of a pci-bridge *in the config* that triggers the requirement to add a dmi-to-pci-bridge. Rather, it is the presence of a legacy-PCI device in the config, which triggers auto-add of a pci-bridge, which triggers auto-add of a dmi-to-pci-bridge (this is handled in virDomainPCIAddressSetGrow() - if there's a request to add a pci-bridge we'll check if there is a suitable bus to plug it into; if not, we first add a dmi-to-pci-bridge). 2) Once there is already a single dmi-to-pci-bridge on the system, there won't be a need for any more, even if it's full, as long as there is a pci-bridge with an open slot - you can also plug pci-bridges into existing pci-bridges. So we have to make sure we don't add a dmi-to-pci-bridge unless there aren't any dmi-to-pci-bridges *or* any pci-bridges. 3) Although it is strongly discouraged, it is legal for a pci-bridge to be directly plugged into pcie-root, and we don't want to auto-add a dmi-to-pci-bridge if there is already a pci-bridge that's been forced directly into pcie-root. Although libvirt will now automatically create a dmi-to-pci-bridge when it's needed, the code still remains for now that forces a dmi-to-pci-bridge on all domains with pcie-root (in qemuDomainDefAddDefaultDevices()). That will be removed in a future patch. For now, the pcie-root-ports are added one to a slot, which is a bit wasteful and means it will fail after 31 total PCIe devices (30 if there are also some PCI devices), but helps keep the changeset down for this patch. A future patch will have 8 pcie-root-ports sharing the functions on a single slot.
2016-09-19 21:38:47 +03:00
/* same as q35-pcie, but all PCI controllers are added automatically */
DO_TEST_CAPS_VER("q35-pcie-autoadd", "4.2.0");
DO_TEST_CAPS_LATEST("q35-pcie-autoadd");
DO_TEST_CAPS_VER("q35-default-devices-only", "4.2.0");
DO_TEST_CAPS_LATEST("q35-default-devices-only");
DO_TEST_CAPS_VER("q35-multifunction", "4.2.0");
DO_TEST_CAPS_LATEST("q35-multifunction");
DO_TEST_CAPS_VER("q35-virt-manager-basic", "4.2.0");
DO_TEST_CAPS_LATEST("q35-virt-manager-basic");
/* Test automatic and manual setting of pcie-root-port attributes */
DO_TEST("pcie-root-port",
QEMU_CAPS_DEVICE_IOH3420,
QEMU_CAPS_ICH9_AHCI,
QEMU_CAPS_DEVICE_QXL);
/* Make sure the default model for PCIe Root Ports is picked correctly
* based on QEMU binary capabilities. We use x86/q35 for the test, but
* any PCIe machine type (such as aarch64/virt) will behave the same */
DO_TEST("pcie-root-port-model-generic",
QEMU_CAPS_DEVICE_PCIE_ROOT_PORT,
QEMU_CAPS_DEVICE_IOH3420);
DO_TEST("pcie-root-port-model-ioh3420",
QEMU_CAPS_DEVICE_IOH3420);
DO_TEST_CAPS_LATEST("pcie-root-port-nohotplug");
DO_TEST("autoindex",
QEMU_CAPS_DEVICE_PCI_BRIDGE,
QEMU_CAPS_DEVICE_DMI_TO_PCI_BRIDGE,
QEMU_CAPS_DEVICE_IOH3420,
QEMU_CAPS_DEVICE_X3130_UPSTREAM,
QEMU_CAPS_DEVICE_XIO3130_DOWNSTREAM,
QEMU_CAPS_ICH9_AHCI,
QEMU_CAPS_ICH9_USB_EHCI1,
QEMU_CAPS_NEC_USB_XHCI);
/* Make sure the user can always override libvirt's default device
* placement policy by providing an explicit PCI address */
DO_TEST("q35-pci-force-address",
QEMU_CAPS_DEVICE_PCI_BRIDGE,
QEMU_CAPS_DEVICE_DMI_TO_PCI_BRIDGE,
QEMU_CAPS_DEVICE_IOH3420,
QEMU_CAPS_HDA_DUPLEX);
DO_TEST_PARSE_ERROR("q35-wrong-root",
qemu: initially reserve one open pcie-root-port for hotplug For machinetypes with a pci-root bus (all legacy PCI), libvirt will make a "fake" reservation for one extra slot prior to assigning addresses to unaddressed PCI endpoint devices in the domain. This will trigger auto-adding of a pci-bridge for the final device to be assigned an address *if that device would have otherwise instead been the last device on the last available pci-bridge*; thus it assures that there will always be at least one slot left open in the domain's bus topology for expansion (which is important both for hotplug (since a new pci-bridge can't be added while the guest is running) as well as for offline additions to the config (since adding a new device might otherwise in some cases require re-addressing existing devices, which we want to avoid)). It's important to note that for the above case (legacy PCI), we must check for the special case of all slots on all buses being occupied *prior to assigning any addresses*, and avoid attempting to reserve the extra address in that case, because there is no free address in the existing topology, so no place to auto-add a pci-bridge for expansion (i.e. it would always fail anyway). Since that condition can only be reached by manual intervention, this is acceptable. For machinetypes with pcie-root (Q35, aarch64 virt), libvirt's methodology for automatically expanding the bus topology is different - pcie-root-ports are plugged into slots (soon to be functions) of pcie-root as needed, and the new endpoint devices are assigned to the single slot in each pcie-root-port. This is done so that the devices are, by default, hotpluggable (the slots of pcie-root don't support hotplug, but the single slot of the pcie-root-port does). Since pcie-root-ports can only be plugged into pcie-root, and we don't auto-assign endpoint devices to the pcie-root slots, this means topology expansion doesn't compete with endpoint devices for slots, so we don't need to worry about checking for all "useful" slots being free *prior* to assigning addresses to new endpoint devices - as a matter of fact, if we attempt to reserve the open slots before the used slots, it can lead to errors. Instead this patch just reserves one slot for a "future potential" PCIe device after doing the assignment for actual devices, but only if the only PCI controller defined prior to starting address assignment was pcie-root, and only if we auto-added at least one PCI controller during address assignment. This assures two things: 1) that reserving the open slots will only be done when the domain is initially defined, never at any time after, and 2) that if the user understands enough about PCI controllers that they are adding them manually, that we don't mess up their plan by adding extras - if they know enough to add one pcie-root-port, or to manually assign addresses such that no pcie-root-ports are needed, they know enough to add extra pcie-root-ports if they want them (this could be called the "libguestfs clause", since libguestfs needs to be able to create domains with as few devices/controllers as possible). This is set to reserve a single free port for now, but could be increased in the future if public sentiment goes in that direction (it's easy to increase later, but essentially impossible to decrease)
2016-09-28 03:37:30 +03:00
QEMU_CAPS_DEVICE_IOH3420,
QEMU_CAPS_ICH9_AHCI,
QEMU_CAPS_ICH9_USB_EHCI1,
QEMU_CAPS_DEVICE_QXL);
DO_TEST_PARSE_ERROR_NOCAPS("440fx-wrong-root");
DO_TEST_PARSE_ERROR_NOCAPS("440fx-ide-address-conflict");
DO_TEST_PARSE_ERROR("pcie-root-port-too-many",
QEMU_CAPS_DEVICE_IOH3420,
QEMU_CAPS_ICH9_AHCI,
QEMU_CAPS_DEVICE_QXL);
DO_TEST("pcie-switch-upstream-port",
QEMU_CAPS_DEVICE_IOH3420,
QEMU_CAPS_DEVICE_X3130_UPSTREAM,
QEMU_CAPS_ICH9_AHCI,
QEMU_CAPS_DEVICE_QXL);
DO_TEST("pcie-switch-downstream-port",
QEMU_CAPS_DEVICE_IOH3420,
QEMU_CAPS_DEVICE_X3130_UPSTREAM,
QEMU_CAPS_DEVICE_XIO3130_DOWNSTREAM,
QEMU_CAPS_ICH9_AHCI,
QEMU_CAPS_DEVICE_QXL);
DO_TEST("pci-expander-bus",
QEMU_CAPS_DEVICE_PXB);
DO_TEST_PARSE_ERROR("pci-expander-bus-bad-node",
QEMU_CAPS_DEVICE_PXB);
DO_TEST_PARSE_ERROR("pci-expander-bus-bad-machine",
QEMU_CAPS_DEVICE_PXB);
DO_TEST_PARSE_ERROR("pci-expander-bus-bad-bus",
QEMU_CAPS_DEVICE_PXB);
DO_TEST("pcie-expander-bus",
QEMU_CAPS_DEVICE_IOH3420,
QEMU_CAPS_DEVICE_X3130_UPSTREAM,
QEMU_CAPS_DEVICE_XIO3130_DOWNSTREAM,
QEMU_CAPS_DEVICE_PXB_PCIE);
DO_TEST_PARSE_ERROR("pcie-expander-bus-bad-machine",
QEMU_CAPS_DEVICE_IOH3420,
QEMU_CAPS_DEVICE_X3130_UPSTREAM,
QEMU_CAPS_DEVICE_XIO3130_DOWNSTREAM,
QEMU_CAPS_DEVICE_PXB_PCIE);
DO_TEST_PARSE_ERROR("pcie-expander-bus-bad-bus",
QEMU_CAPS_DEVICE_IOH3420,
QEMU_CAPS_DEVICE_PXB_PCIE);
DO_TEST_CAPS_ARCH_LATEST("pcie-expander-bus-aarch64", "aarch64");
DO_TEST_CAPS_LATEST("hostdev-scsi-lsi");
DO_TEST_CAPS_LATEST("hostdev-scsi-virtio-scsi");
DO_TEST("hostdev-scsi-vhost-scsi-ccw",
QEMU_CAPS_VIRTIO_SCSI, QEMU_CAPS_DEVICE_VHOST_SCSI);
DO_TEST("hostdev-scsi-vhost-scsi-pci",
QEMU_CAPS_VIRTIO_SCSI,
QEMU_CAPS_DEVICE_VHOST_SCSI);
DO_TEST_CAPS_LATEST_PARSE_ERROR("hostdev-scsi-vhost-scsi-pci-boot-fail");
DO_TEST_CAPS_VER("hostdev-scsi-vhost-scsi-pcie", "4.2.0");
DO_TEST_CAPS_LATEST("hostdev-scsi-vhost-scsi-pcie");
DO_TEST_PARSE_ERROR("hostdev-scsi-duplicate",
QEMU_CAPS_VIRTIO_SCSI,
QEMU_CAPS_DEVICE_VHOST_SCSI);
qemu: Build qemu command line for scsi host device Except the scsi host device's controller is "lsilogic", mapping between the libvirt attributes and scsi-generic properties is: libvirt qemu ----------------------------------------- controller bus ($libvirt_controller.0) bus channel target scsi-id unit lun For scsi host device with "lsilogic" controller, the mapping is: ('target (libvirt)' must be 0, as it's not used; 'unit (libvirt) must <= 7). libvirt qemu ---------------------------------------------------------- controller && bus bus ($libvirt_controller.$libvirt_bus) unit scsi-id It's not good to hardcode/hard-check limits of these attributes, and even worse, these limits are not documented, one has to find out by either testing or reading the qemu code, I'm looking forward to qemu expose limits like these one day). For example, exposing "max_target", "max_lun" for megasas: static const struct SCSIBusInfo megasas_scsi_info = { .tcq = true, .max_target = MFI_MAX_LD, .max_lun = 255, .transfer_data = megasas_xfer_complete, .get_sg_list = megasas_get_sg_list, .complete = megasas_command_complete, .cancel = megasas_command_cancel, }; Example of the qemu command line (lsilogic controller): -drive file=/dev/sg2,if=none,id=drive-hostdev-scsi_host7-0-0-0 \ -device scsi-generic,bus=scsi0.0,scsi-id=8,\ drive=drive-hostdev-scsi_host7-0-0-0,id=hostdev-scsi_host7-0-0-0 Example of the qemu command line (virtio-scsi controller): -drive file=/dev/sg2,if=none,id=drive-hostdev-scsi_host7-0-0-0 \ -device scsi-generic,bus=scsi0.0,channel=0,scsi-id=128,lun=128,\ drive=drive-hostdev-scsi_host7-0-0-0,id=hostdev-scsi_host7-0-0-0 Signed-off-by: Han Cheng <hanc.fnst@cn.fujitsu.com> Signed-off-by: Osier Yang <jyang@redhat.com>
2013-05-03 22:07:23 +04:00
DO_TEST_CAPS_LATEST("mlock-on");
DO_TEST_CAPS_LATEST("mlock-off");
DO_TEST_PARSE_ERROR_NOCAPS("pci-bridge-negative-index-invalid");
DO_TEST_PARSE_ERROR_NOCAPS("pci-bridge-duplicate-index");
DO_TEST_PARSE_ERROR_NOCAPS("pci-root-nonzero-index");
DO_TEST_PARSE_ERROR_NOCAPS("pci-root-address");
DO_TEST("hotplug-base",
QEMU_CAPS_KVM, QEMU_CAPS_VIRTIO_SCSI);
DO_TEST_NOCAPS("pcihole64");
DO_TEST("pcihole64-q35",
qemu: initially reserve one open pcie-root-port for hotplug For machinetypes with a pci-root bus (all legacy PCI), libvirt will make a "fake" reservation for one extra slot prior to assigning addresses to unaddressed PCI endpoint devices in the domain. This will trigger auto-adding of a pci-bridge for the final device to be assigned an address *if that device would have otherwise instead been the last device on the last available pci-bridge*; thus it assures that there will always be at least one slot left open in the domain's bus topology for expansion (which is important both for hotplug (since a new pci-bridge can't be added while the guest is running) as well as for offline additions to the config (since adding a new device might otherwise in some cases require re-addressing existing devices, which we want to avoid)). It's important to note that for the above case (legacy PCI), we must check for the special case of all slots on all buses being occupied *prior to assigning any addresses*, and avoid attempting to reserve the extra address in that case, because there is no free address in the existing topology, so no place to auto-add a pci-bridge for expansion (i.e. it would always fail anyway). Since that condition can only be reached by manual intervention, this is acceptable. For machinetypes with pcie-root (Q35, aarch64 virt), libvirt's methodology for automatically expanding the bus topology is different - pcie-root-ports are plugged into slots (soon to be functions) of pcie-root as needed, and the new endpoint devices are assigned to the single slot in each pcie-root-port. This is done so that the devices are, by default, hotpluggable (the slots of pcie-root don't support hotplug, but the single slot of the pcie-root-port does). Since pcie-root-ports can only be plugged into pcie-root, and we don't auto-assign endpoint devices to the pcie-root slots, this means topology expansion doesn't compete with endpoint devices for slots, so we don't need to worry about checking for all "useful" slots being free *prior* to assigning addresses to new endpoint devices - as a matter of fact, if we attempt to reserve the open slots before the used slots, it can lead to errors. Instead this patch just reserves one slot for a "future potential" PCIe device after doing the assignment for actual devices, but only if the only PCI controller defined prior to starting address assignment was pcie-root, and only if we auto-added at least one PCI controller during address assignment. This assures two things: 1) that reserving the open slots will only be done when the domain is initially defined, never at any time after, and 2) that if the user understands enough about PCI controllers that they are adding them manually, that we don't mess up their plan by adding extras - if they know enough to add one pcie-root-port, or to manually assign addresses such that no pcie-root-ports are needed, they know enough to add extra pcie-root-ports if they want them (this could be called the "libguestfs clause", since libguestfs needs to be able to create domains with as few devices/controllers as possible). This is set to reserve a single free port for now, but could be increased in the future if public sentiment goes in that direction (it's easy to increase later, but essentially impossible to decrease)
2016-09-28 03:37:30 +03:00
QEMU_CAPS_DEVICE_IOH3420,
QEMU_CAPS_ICH9_AHCI,
QEMU_CAPS_DEVICE_QXL);
DO_TEST_NOCAPS("arm-vexpressa9-nodevs");
DO_TEST_NOCAPS("arm-vexpressa9-basic");
DO_TEST("arm-vexpressa9-virtio",
QEMU_CAPS_DEVICE_VIRTIO_MMIO,
QEMU_CAPS_DEVICE_VIRTIO_RNG, QEMU_CAPS_OBJECT_RNG_RANDOM);
DO_TEST("arm-virt-virtio",
QEMU_CAPS_DEVICE_VIRTIO_MMIO,
QEMU_CAPS_DEVICE_PL011,
QEMU_CAPS_DEVICE_VIRTIO_RNG, QEMU_CAPS_OBJECT_RNG_RANDOM);
DO_TEST("aarch64-virt-virtio",
QEMU_CAPS_DEVICE_VIRTIO_MMIO,
QEMU_CAPS_DEVICE_PL011,
QEMU_CAPS_DEVICE_VIRTIO_RNG, QEMU_CAPS_OBJECT_RNG_RANDOM);
/* Demonstrates the virtio-pci default... namely that there isn't any!
q35 style PCI controllers will be added if the binary supports it,
but virtio-mmio is always used unless PCI addresses are manually
specified. */
DO_TEST_CAPS_ARCH_VER("aarch64-virtio-pci-default", "aarch64", "4.2.0");
DO_TEST_CAPS_ARCH_LATEST("aarch64-virtio-pci-default", "aarch64");
DO_TEST("aarch64-virt-2.6-virtio-pci-default",
QEMU_CAPS_DEVICE_VIRTIO_MMIO,
QEMU_CAPS_DEVICE_VIRTIO_RNG, QEMU_CAPS_OBJECT_RNG_RANDOM,
QEMU_CAPS_OBJECT_GPEX, QEMU_CAPS_DEVICE_PCI_BRIDGE,
qemu: initially reserve one open pcie-root-port for hotplug For machinetypes with a pci-root bus (all legacy PCI), libvirt will make a "fake" reservation for one extra slot prior to assigning addresses to unaddressed PCI endpoint devices in the domain. This will trigger auto-adding of a pci-bridge for the final device to be assigned an address *if that device would have otherwise instead been the last device on the last available pci-bridge*; thus it assures that there will always be at least one slot left open in the domain's bus topology for expansion (which is important both for hotplug (since a new pci-bridge can't be added while the guest is running) as well as for offline additions to the config (since adding a new device might otherwise in some cases require re-addressing existing devices, which we want to avoid)). It's important to note that for the above case (legacy PCI), we must check for the special case of all slots on all buses being occupied *prior to assigning any addresses*, and avoid attempting to reserve the extra address in that case, because there is no free address in the existing topology, so no place to auto-add a pci-bridge for expansion (i.e. it would always fail anyway). Since that condition can only be reached by manual intervention, this is acceptable. For machinetypes with pcie-root (Q35, aarch64 virt), libvirt's methodology for automatically expanding the bus topology is different - pcie-root-ports are plugged into slots (soon to be functions) of pcie-root as needed, and the new endpoint devices are assigned to the single slot in each pcie-root-port. This is done so that the devices are, by default, hotpluggable (the slots of pcie-root don't support hotplug, but the single slot of the pcie-root-port does). Since pcie-root-ports can only be plugged into pcie-root, and we don't auto-assign endpoint devices to the pcie-root slots, this means topology expansion doesn't compete with endpoint devices for slots, so we don't need to worry about checking for all "useful" slots being free *prior* to assigning addresses to new endpoint devices - as a matter of fact, if we attempt to reserve the open slots before the used slots, it can lead to errors. Instead this patch just reserves one slot for a "future potential" PCIe device after doing the assignment for actual devices, but only if the only PCI controller defined prior to starting address assignment was pcie-root, and only if we auto-added at least one PCI controller during address assignment. This assures two things: 1) that reserving the open slots will only be done when the domain is initially defined, never at any time after, and 2) that if the user understands enough about PCI controllers that they are adding them manually, that we don't mess up their plan by adding extras - if they know enough to add one pcie-root-port, or to manually assign addresses such that no pcie-root-ports are needed, they know enough to add extra pcie-root-ports if they want them (this could be called the "libguestfs clause", since libguestfs needs to be able to create domains with as few devices/controllers as possible). This is set to reserve a single free port for now, but could be increased in the future if public sentiment goes in that direction (it's easy to increase later, but essentially impossible to decrease)
2016-09-28 03:37:30 +03:00
QEMU_CAPS_DEVICE_DMI_TO_PCI_BRIDGE,
QEMU_CAPS_DEVICE_PL011,
qemu: initially reserve one open pcie-root-port for hotplug For machinetypes with a pci-root bus (all legacy PCI), libvirt will make a "fake" reservation for one extra slot prior to assigning addresses to unaddressed PCI endpoint devices in the domain. This will trigger auto-adding of a pci-bridge for the final device to be assigned an address *if that device would have otherwise instead been the last device on the last available pci-bridge*; thus it assures that there will always be at least one slot left open in the domain's bus topology for expansion (which is important both for hotplug (since a new pci-bridge can't be added while the guest is running) as well as for offline additions to the config (since adding a new device might otherwise in some cases require re-addressing existing devices, which we want to avoid)). It's important to note that for the above case (legacy PCI), we must check for the special case of all slots on all buses being occupied *prior to assigning any addresses*, and avoid attempting to reserve the extra address in that case, because there is no free address in the existing topology, so no place to auto-add a pci-bridge for expansion (i.e. it would always fail anyway). Since that condition can only be reached by manual intervention, this is acceptable. For machinetypes with pcie-root (Q35, aarch64 virt), libvirt's methodology for automatically expanding the bus topology is different - pcie-root-ports are plugged into slots (soon to be functions) of pcie-root as needed, and the new endpoint devices are assigned to the single slot in each pcie-root-port. This is done so that the devices are, by default, hotpluggable (the slots of pcie-root don't support hotplug, but the single slot of the pcie-root-port does). Since pcie-root-ports can only be plugged into pcie-root, and we don't auto-assign endpoint devices to the pcie-root slots, this means topology expansion doesn't compete with endpoint devices for slots, so we don't need to worry about checking for all "useful" slots being free *prior* to assigning addresses to new endpoint devices - as a matter of fact, if we attempt to reserve the open slots before the used slots, it can lead to errors. Instead this patch just reserves one slot for a "future potential" PCIe device after doing the assignment for actual devices, but only if the only PCI controller defined prior to starting address assignment was pcie-root, and only if we auto-added at least one PCI controller during address assignment. This assures two things: 1) that reserving the open slots will only be done when the domain is initially defined, never at any time after, and 2) that if the user understands enough about PCI controllers that they are adding them manually, that we don't mess up their plan by adding extras - if they know enough to add one pcie-root-port, or to manually assign addresses such that no pcie-root-ports are needed, they know enough to add extra pcie-root-ports if they want them (this could be called the "libguestfs clause", since libguestfs needs to be able to create domains with as few devices/controllers as possible). This is set to reserve a single free port for now, but could be increased in the future if public sentiment goes in that direction (it's easy to increase later, but essentially impossible to decrease)
2016-09-28 03:37:30 +03:00
QEMU_CAPS_DEVICE_IOH3420);
/* Example of using virtio-pci with no explicit PCI controller
but with manual PCI addresses */
DO_TEST("aarch64-virtio-pci-manual-addresses",
QEMU_CAPS_DEVICE_VIRTIO_MMIO,
QEMU_CAPS_DEVICE_VIRTIO_RNG, QEMU_CAPS_OBJECT_RNG_RANDOM,
QEMU_CAPS_OBJECT_GPEX, QEMU_CAPS_DEVICE_PCI_BRIDGE,
qemu: initially reserve one open pcie-root-port for hotplug For machinetypes with a pci-root bus (all legacy PCI), libvirt will make a "fake" reservation for one extra slot prior to assigning addresses to unaddressed PCI endpoint devices in the domain. This will trigger auto-adding of a pci-bridge for the final device to be assigned an address *if that device would have otherwise instead been the last device on the last available pci-bridge*; thus it assures that there will always be at least one slot left open in the domain's bus topology for expansion (which is important both for hotplug (since a new pci-bridge can't be added while the guest is running) as well as for offline additions to the config (since adding a new device might otherwise in some cases require re-addressing existing devices, which we want to avoid)). It's important to note that for the above case (legacy PCI), we must check for the special case of all slots on all buses being occupied *prior to assigning any addresses*, and avoid attempting to reserve the extra address in that case, because there is no free address in the existing topology, so no place to auto-add a pci-bridge for expansion (i.e. it would always fail anyway). Since that condition can only be reached by manual intervention, this is acceptable. For machinetypes with pcie-root (Q35, aarch64 virt), libvirt's methodology for automatically expanding the bus topology is different - pcie-root-ports are plugged into slots (soon to be functions) of pcie-root as needed, and the new endpoint devices are assigned to the single slot in each pcie-root-port. This is done so that the devices are, by default, hotpluggable (the slots of pcie-root don't support hotplug, but the single slot of the pcie-root-port does). Since pcie-root-ports can only be plugged into pcie-root, and we don't auto-assign endpoint devices to the pcie-root slots, this means topology expansion doesn't compete with endpoint devices for slots, so we don't need to worry about checking for all "useful" slots being free *prior* to assigning addresses to new endpoint devices - as a matter of fact, if we attempt to reserve the open slots before the used slots, it can lead to errors. Instead this patch just reserves one slot for a "future potential" PCIe device after doing the assignment for actual devices, but only if the only PCI controller defined prior to starting address assignment was pcie-root, and only if we auto-added at least one PCI controller during address assignment. This assures two things: 1) that reserving the open slots will only be done when the domain is initially defined, never at any time after, and 2) that if the user understands enough about PCI controllers that they are adding them manually, that we don't mess up their plan by adding extras - if they know enough to add one pcie-root-port, or to manually assign addresses such that no pcie-root-ports are needed, they know enough to add extra pcie-root-ports if they want them (this could be called the "libguestfs clause", since libguestfs needs to be able to create domains with as few devices/controllers as possible). This is set to reserve a single free port for now, but could be increased in the future if public sentiment goes in that direction (it's easy to increase later, but essentially impossible to decrease)
2016-09-28 03:37:30 +03:00
QEMU_CAPS_DEVICE_DMI_TO_PCI_BRIDGE,
QEMU_CAPS_DEVICE_IOH3420,
QEMU_CAPS_VIRTIO_SCSI);
qemu: map "virtio" video model to "virt" machtype correctly (arm/aarch64) Most of QEMU's PCI display device models, such as: libvirt video/model/@type QEMU -device ------------------------- ------------ cirrus cirrus-vga vga VGA qxl qxl-vga virtio virtio-vga come with a linear framebuffer (sometimes called "VGA compatibility framebuffer"). This linear framebuffer lives in one of the PCI device's MMIO BARs, and allows guest code (primarily: firmware drivers, and non-accelerated OS drivers) to display graphics with direct memory access. Due to architectural reasons on aarch64/KVM hosts, this kind of framebuffer doesn't / can't work in qemu-system-(arm|aarch64) -M virt machines. Cache coherency issues guarantee a corrupted / unusable display. The problem has been researched by several people, including kvm-arm maintainers, and it's been decided that the best way (practically the only way) to have boot time graphics for such guests is to consolidate on QEMU's "virtio-gpu-pci" device. >From <https://bugzilla.redhat.com/show_bug.cgi?id=1195176>, libvirt supports <devices> <video> <model type='virtio'/> </video> </devices> but libvirt unconditionally maps @type='virtio' to QEMU's "virtio-vga" device model. (See the qemuBuildDeviceVideoStr() function and the "qemuDeviceVideo" enum impl.) According to the above, this is not right for the "virt" machine type; the qemu-system-(arm|aarch64) binaries don't even recognize the "virtio-vga" device model (justifiedly). Whereas "virtio-gpu-pci", which is a pure virtio device without a compatibility framebuffer, is available, and works fine. (The ArmVirtQemu ("AAVMF") platform of edk2 -- that is, the UEFI firmware for "virt" -- supports "virtio-gpu-pci", as of upstream commit 3ef3209d3028. See <https://tianocore.acgmultimedia.com/show_bug.cgi?id=66>.) Override the default mapping of "virtio", from "virtio-vga" to "virtio-gpu-pci", if qemuDomainMachineIsVirt() evaluates to true. Cc: Andrea Bolognani <abologna@redhat.com> Cc: Drew Jones <drjones@redhat.com> Cc: Marc-André Lureau <marcandre.lureau@redhat.com> Cc: Martin Kletzander <mkletzan@redhat.com> Suggested-by: Marc-André Lureau <marcandre.lureau@redhat.com> Resolves: https://bugzilla.redhat.com/show_bug.cgi?id=1372901 Signed-off-by: Laszlo Ersek <lersek@redhat.com> Acked-by: Martin Kletzander <mkletzan@redhat.com>
2016-09-16 10:30:23 +03:00
DO_TEST("aarch64-video-virtio-gpu-pci",
QEMU_CAPS_OBJECT_GPEX,
qemu: map "virtio" video model to "virt" machtype correctly (arm/aarch64) Most of QEMU's PCI display device models, such as: libvirt video/model/@type QEMU -device ------------------------- ------------ cirrus cirrus-vga vga VGA qxl qxl-vga virtio virtio-vga come with a linear framebuffer (sometimes called "VGA compatibility framebuffer"). This linear framebuffer lives in one of the PCI device's MMIO BARs, and allows guest code (primarily: firmware drivers, and non-accelerated OS drivers) to display graphics with direct memory access. Due to architectural reasons on aarch64/KVM hosts, this kind of framebuffer doesn't / can't work in qemu-system-(arm|aarch64) -M virt machines. Cache coherency issues guarantee a corrupted / unusable display. The problem has been researched by several people, including kvm-arm maintainers, and it's been decided that the best way (practically the only way) to have boot time graphics for such guests is to consolidate on QEMU's "virtio-gpu-pci" device. >From <https://bugzilla.redhat.com/show_bug.cgi?id=1195176>, libvirt supports <devices> <video> <model type='virtio'/> </video> </devices> but libvirt unconditionally maps @type='virtio' to QEMU's "virtio-vga" device model. (See the qemuBuildDeviceVideoStr() function and the "qemuDeviceVideo" enum impl.) According to the above, this is not right for the "virt" machine type; the qemu-system-(arm|aarch64) binaries don't even recognize the "virtio-vga" device model (justifiedly). Whereas "virtio-gpu-pci", which is a pure virtio device without a compatibility framebuffer, is available, and works fine. (The ArmVirtQemu ("AAVMF") platform of edk2 -- that is, the UEFI firmware for "virt" -- supports "virtio-gpu-pci", as of upstream commit 3ef3209d3028. See <https://tianocore.acgmultimedia.com/show_bug.cgi?id=66>.) Override the default mapping of "virtio", from "virtio-vga" to "virtio-gpu-pci", if qemuDomainMachineIsVirt() evaluates to true. Cc: Andrea Bolognani <abologna@redhat.com> Cc: Drew Jones <drjones@redhat.com> Cc: Marc-André Lureau <marcandre.lureau@redhat.com> Cc: Martin Kletzander <mkletzan@redhat.com> Suggested-by: Marc-André Lureau <marcandre.lureau@redhat.com> Resolves: https://bugzilla.redhat.com/show_bug.cgi?id=1372901 Signed-off-by: Laszlo Ersek <lersek@redhat.com> Acked-by: Martin Kletzander <mkletzan@redhat.com>
2016-09-16 10:30:23 +03:00
QEMU_CAPS_DEVICE_PCI_BRIDGE, QEMU_CAPS_DEVICE_IOH3420,
QEMU_CAPS_DEVICE_VIRTIO_GPU);
DO_TEST("aarch64-video-default",
QEMU_CAPS_OBJECT_GPEX,
QEMU_CAPS_DEVICE_PCI_BRIDGE, QEMU_CAPS_DEVICE_IOH3420,
QEMU_CAPS_DEVICE_VIRTIO_GPU, QEMU_CAPS_DEVICE_DMI_TO_PCI_BRIDGE,
QEMU_CAPS_VNC);
DO_TEST("aarch64-aavmf-virtio-mmio",
QEMU_CAPS_DEVICE_VIRTIO_MMIO,
QEMU_CAPS_DEVICE_VIRTIO_RNG, QEMU_CAPS_OBJECT_RNG_RANDOM);
DO_TEST("aarch64-virt-default-nic",
QEMU_CAPS_DEVICE_VIRTIO_MMIO);
qemuTestSetHostArch(&driver, VIR_ARCH_AARCH64);
DO_TEST("aarch64-cpu-passthrough",
QEMU_CAPS_DEVICE_VIRTIO_MMIO,
QEMU_CAPS_KVM);
DO_TEST_GIC("aarch64-gic-none", GIC_NONE,
QEMU_CAPS_KVM,
QEMU_CAPS_MACH_VIRT_GIC_VERSION);
DO_TEST_GIC("aarch64-gic-none-v2", GIC_V2,
QEMU_CAPS_KVM,
QEMU_CAPS_MACH_VIRT_GIC_VERSION);
DO_TEST_GIC("aarch64-gic-none-v3", GIC_V3,
QEMU_CAPS_KVM,
QEMU_CAPS_MACH_VIRT_GIC_VERSION);
DO_TEST_GIC("aarch64-gic-none-both", GIC_BOTH,
QEMU_CAPS_KVM,
QEMU_CAPS_MACH_VIRT_GIC_VERSION);
DO_TEST_GIC("aarch64-gic-none-tcg", GIC_BOTH,
QEMU_CAPS_MACH_VIRT_GIC_VERSION);
DO_TEST_GIC("aarch64-gic-default", GIC_NONE,
QEMU_CAPS_KVM,
QEMU_CAPS_MACH_VIRT_GIC_VERSION);
DO_TEST_GIC("aarch64-gic-default-v2", GIC_V2,
QEMU_CAPS_KVM,
QEMU_CAPS_MACH_VIRT_GIC_VERSION);
DO_TEST_GIC("aarch64-gic-default-v3", GIC_V3,
QEMU_CAPS_KVM,
QEMU_CAPS_MACH_VIRT_GIC_VERSION);
DO_TEST_GIC("aarch64-gic-default-both", GIC_BOTH,
QEMU_CAPS_KVM,
QEMU_CAPS_MACH_VIRT_GIC_VERSION);
DO_TEST_GIC("aarch64-gic-v2", GIC_NONE,
QEMU_CAPS_KVM,
QEMU_CAPS_MACH_VIRT_GIC_VERSION);
DO_TEST_GIC("aarch64-gic-v2", GIC_V2,
QEMU_CAPS_KVM,
QEMU_CAPS_MACH_VIRT_GIC_VERSION);
DO_TEST_GIC("aarch64-gic-v2", GIC_V3,
QEMU_CAPS_KVM,
QEMU_CAPS_MACH_VIRT_GIC_VERSION);
DO_TEST_GIC("aarch64-gic-v2", GIC_BOTH,
QEMU_CAPS_KVM,
QEMU_CAPS_MACH_VIRT_GIC_VERSION);
DO_TEST_GIC("aarch64-gic-v3", GIC_NONE,
QEMU_CAPS_KVM,
QEMU_CAPS_MACH_VIRT_GIC_VERSION);
DO_TEST_GIC("aarch64-gic-v3", GIC_V2,
QEMU_CAPS_KVM,
QEMU_CAPS_MACH_VIRT_GIC_VERSION);
DO_TEST_GIC("aarch64-gic-v3", GIC_V3,
QEMU_CAPS_KVM,
QEMU_CAPS_MACH_VIRT_GIC_VERSION);
DO_TEST_GIC("aarch64-gic-v3", GIC_BOTH,
QEMU_CAPS_KVM,
QEMU_CAPS_MACH_VIRT_GIC_VERSION);
DO_TEST_GIC("aarch64-gic-host", GIC_NONE,
QEMU_CAPS_KVM,
QEMU_CAPS_MACH_VIRT_GIC_VERSION);
DO_TEST_GIC("aarch64-gic-host", GIC_V2,
QEMU_CAPS_KVM,
QEMU_CAPS_MACH_VIRT_GIC_VERSION);
DO_TEST_GIC("aarch64-gic-host", GIC_V3,
QEMU_CAPS_KVM,
QEMU_CAPS_MACH_VIRT_GIC_VERSION);
DO_TEST_GIC("aarch64-gic-host", GIC_BOTH,
QEMU_CAPS_KVM,
QEMU_CAPS_MACH_VIRT_GIC_VERSION);
DO_TEST_PARSE_ERROR("aarch64-gic-invalid",
QEMU_CAPS_KVM,
QEMU_CAPS_MACH_VIRT_GIC_VERSION);
DO_TEST_PARSE_ERROR("aarch64-gic-not-virt",
QEMU_CAPS_KVM,
QEMU_CAPS_MACH_VIRT_GIC_VERSION);
DO_TEST_PARSE_ERROR("aarch64-gic-not-arm",
QEMU_CAPS_KVM,
QEMU_CAPS_MACH_VIRT_GIC_VERSION);
DO_TEST("aarch64-kvm-32-on-64",
QEMU_CAPS_DEVICE_VIRTIO_MMIO,
QEMU_CAPS_DEVICE_PL011,
QEMU_CAPS_KVM, QEMU_CAPS_CPU_AARCH64_OFF);
DO_TEST_PARSE_ERROR("aarch64-kvm-32-on-64",
QEMU_CAPS_DEVICE_VIRTIO_MMIO,
QEMU_CAPS_KVM);
DO_TEST("aarch64-pci-serial",
QEMU_CAPS_DEVICE_PCI_SERIAL,
QEMU_CAPS_OBJECT_GPEX,
QEMU_CAPS_DEVICE_PCI_BRIDGE,
QEMU_CAPS_DEVICE_DMI_TO_PCI_BRIDGE,
QEMU_CAPS_DEVICE_PCIE_ROOT_PORT);
DO_TEST("aarch64-traditional-pci",
QEMU_CAPS_OBJECT_GPEX,
QEMU_CAPS_DEVICE_PCIE_ROOT_PORT,
QEMU_CAPS_DEVICE_DMI_TO_PCI_BRIDGE,
QEMU_CAPS_DEVICE_PCIE_PCI_BRIDGE,
QEMU_CAPS_DEVICE_PCI_BRIDGE,
QEMU_CAPS_DEVICE_PCI_SERIAL);
/* aarch64 doesn't support the same CPU features as x86 */
DO_TEST_CAPS_ARCH_LATEST_FAILURE("aarch64-features-wrong", "aarch64");
/* Can't enable vector lengths when SVE is overall disabled */
DO_TEST_CAPS_ARCH_LATEST_PARSE_ERROR("aarch64-features-sve-disabled", "aarch64");
/* SVE aarch64 CPU features work on modern QEMU */
DO_TEST_CAPS_ARCH_LATEST("aarch64-features-sve", "aarch64");
DO_TEST_CAPS_ARCH_LATEST("clock-timer-armvtimer", "aarch64");
qemuTestSetHostArch(&driver, VIR_ARCH_NONE);
DO_TEST("kvm-pit-delay", QEMU_CAPS_KVM_PIT_TICK_POLICY);
DO_TEST("kvm-pit-discard", QEMU_CAPS_KVM_PIT_TICK_POLICY);
DO_TEST_CAPS_LATEST("panic");
DO_TEST_CAPS_LATEST("panic-double");
DO_TEST_CAPS_LATEST("panic-no-address");
DO_TEST_CAPS_ARCH_VER_FULL("fips-enabled", "x86_64", "5.1.0", ARG_FLAGS, FLAG_FIPS_HOST);
DO_TEST_CAPS_ARCH_LATEST_FULL("fips-enabled", "x86_64", ARG_FLAGS, FLAG_FIPS_HOST);
DO_TEST("shmem", QEMU_CAPS_DEVICE_IVSHMEM);
DO_TEST("shmem-plain-doorbell", QEMU_CAPS_DEVICE_IVSHMEM,
QEMU_CAPS_DEVICE_IVSHMEM_PLAIN,
QEMU_CAPS_DEVICE_IVSHMEM_DOORBELL);
DO_TEST_PARSE_ERROR_NOCAPS("shmem");
DO_TEST_FAILURE("shmem-invalid-size",
QEMU_CAPS_DEVICE_IVSHMEM);
DO_TEST_FAILURE("shmem-invalid-address",
QEMU_CAPS_DEVICE_IVSHMEM);
DO_TEST_FAILURE("shmem-small-size",
QEMU_CAPS_DEVICE_IVSHMEM);
DO_TEST_PARSE_ERROR_NOCAPS("shmem-msi-only");
DO_TEST("cpu-host-passthrough-features", QEMU_CAPS_KVM);
DO_TEST_FAILURE_NOCAPS("memory-align-fail");
DO_TEST_PARSE_ERROR("memory-hotplug-nonuma", QEMU_CAPS_DEVICE_PC_DIMM);
DO_TEST_PARSE_ERROR_NOCAPS("memory-hotplug-invalid-targetnode");
DO_TEST_NOCAPS("memory-hotplug");
DO_TEST("memory-hotplug", QEMU_CAPS_DEVICE_PC_DIMM, QEMU_CAPS_NUMA);
DO_TEST("memory-hotplug-dimm", QEMU_CAPS_DEVICE_PC_DIMM, QEMU_CAPS_NUMA,
QEMU_CAPS_OBJECT_MEMORY_RAM, QEMU_CAPS_OBJECT_MEMORY_FILE);
DO_TEST_CAPS_LATEST("memory-hotplug-dimm-addr");
DO_TEST("memory-hotplug-ppc64-nonuma", QEMU_CAPS_KVM, QEMU_CAPS_DEVICE_PC_DIMM, QEMU_CAPS_NUMA,
QEMU_CAPS_DEVICE_SPAPR_PCI_HOST_BRIDGE,
QEMU_CAPS_OBJECT_MEMORY_RAM, QEMU_CAPS_OBJECT_MEMORY_FILE);
DO_TEST_FULL("memory-hotplug-ppc64-nonuma-abi-update", "",
qemu_domain.c: align all pSeries mem modules when PARSE_ABI_UPDATE qemuDomainAlignMemorySizes() has an operation order problem. We are calculating 'initialmem' without aligning the memory modules first. Since we're aligning the dimms afterwards this can create inconsistencies in the end result. x86 has alignment of 1-2MiB and it's not severely impacted by it, but pSeries works with 256MiB alignment and the difference is noticeable. This is the case of the existing 'memory-hotplug-ppc64-nonuma' test. The test consists of a 2GiB (aligned value) guest with 2 ~520MiB dimms, both unaligned. 'initialmem' is calculated by taking total_mem and subtracting the dimms size (via virDomainDefGetMemoryInitial()), which wil give us 2GiB - 520MiB - 520MiB, ending up with a little more than an 1GiB of 'initialmem'. Note that this value is now unaligned, and will be aligned up via VIR_ROUND_UP(), and we'll end up with 'initialmem' of 1GiB + 256MiB. Given that the dimms are aligned later on, the end result for QEMU is that the guest will have a 'mem' size of 1310720k, plus the two 512 MiB dimms, exceeding in 256MiB the desired 2GiB memory and currentMemory specified in the XML. Existing guests can't be fixed without breaking ABI, but we have code already in place to align pSeries NVDIMM modules for new guests. Let's extend it to align all pSeries mem modules. A new test, 'memory-hotplug-ppc64-nonuma-abi-update', a copy of the existing 'memory-hotplug-ppc64-nonuma', was added to demonstrate the result for new pSeries guests. For the same unaligned XML mentioned above, after applying this patch: - starting QEMU mem size without PARSE_ABI_UPDATE: -m size=1310720k,slots=16,maxmem=4194304k \ (no changes) - starting QEMU mem size with PARSE_ABI_UPDATE: -m size=1048576k,slots=16,maxmem=4194304k \ (size fixed) Reviewed-by: Andrea Bolognani <abologna@redhat.com> Reviewed-by: Michal Privoznik <mprivozn@redhat.com> Signed-off-by: Daniel Henrique Barboza <danielhb413@gmail.com>
2020-11-18 22:58:34 +03:00
ARG_PARSEFLAGS, VIR_DOMAIN_DEF_PARSE_ABI_UPDATE,
ARG_QEMU_CAPS,
QEMU_CAPS_KVM, QEMU_CAPS_DEVICE_PC_DIMM,
QEMU_CAPS_NUMA, QEMU_CAPS_DEVICE_SPAPR_PCI_HOST_BRIDGE,
QEMU_CAPS_OBJECT_MEMORY_RAM,
QEMU_CAPS_OBJECT_MEMORY_FILE,
QEMU_CAPS_LAST,
ARG_END);
DO_TEST_CAPS_LATEST("memory-hotplug-nvdimm");
DO_TEST_CAPS_LATEST("memory-hotplug-nvdimm-access");
DO_TEST_CAPS_VER("memory-hotplug-nvdimm-label", "5.2.0");
DO_TEST_CAPS_LATEST("memory-hotplug-nvdimm-label");
DO_TEST_CAPS_VER("memory-hotplug-nvdimm-align", "5.2.0");
DO_TEST_CAPS_LATEST("memory-hotplug-nvdimm-align");
DO_TEST_CAPS_VER("memory-hotplug-nvdimm-pmem", "5.2.0");
DO_TEST_CAPS_LATEST("memory-hotplug-nvdimm-pmem");
DO_TEST_CAPS_VER("memory-hotplug-nvdimm-readonly", "5.2.0");
DO_TEST_CAPS_LATEST("memory-hotplug-nvdimm-readonly");
DO_TEST("memory-hotplug-nvdimm-ppc64", QEMU_CAPS_DEVICE_SPAPR_PCI_HOST_BRIDGE,
QEMU_CAPS_OBJECT_MEMORY_FILE,
QEMU_CAPS_DEVICE_NVDIMM);
DO_TEST_FULL("memory-hotplug-nvdimm-ppc64-abi-update", "",
ARG_PARSEFLAGS, VIR_DOMAIN_DEF_PARSE_ABI_UPDATE,
ARG_QEMU_CAPS,
QEMU_CAPS_DEVICE_SPAPR_PCI_HOST_BRIDGE,
QEMU_CAPS_OBJECT_MEMORY_FILE,
QEMU_CAPS_DEVICE_NVDIMM,
QEMU_CAPS_LAST,
ARG_END);
DO_TEST_CAPS_VER("memory-hotplug-virtio-pmem", "5.2.0");
DO_TEST_CAPS_LATEST("memory-hotplug-virtio-pmem");
DO_TEST_CAPS_LATEST("memory-hotplug-virtio-mem");
DO_TEST("machine-aeskeywrap-on-caps",
QEMU_CAPS_AES_KEY_WRAP,
QEMU_CAPS_DEA_KEY_WRAP,
QEMU_CAPS_VIRTIO_SCSI);
DO_TEST("machine-aeskeywrap-on-cap",
QEMU_CAPS_AES_KEY_WRAP,
QEMU_CAPS_VIRTIO_SCSI);
DO_TEST("machine-aeskeywrap-off-caps",
QEMU_CAPS_AES_KEY_WRAP, QEMU_CAPS_DEA_KEY_WRAP,
QEMU_CAPS_VIRTIO_SCSI);
DO_TEST("machine-aeskeywrap-off-cap",
QEMU_CAPS_AES_KEY_WRAP,
QEMU_CAPS_VIRTIO_SCSI);
DO_TEST("machine-deakeywrap-on-caps",
QEMU_CAPS_AES_KEY_WRAP, QEMU_CAPS_DEA_KEY_WRAP,
QEMU_CAPS_VIRTIO_SCSI);
DO_TEST("machine-deakeywrap-on-cap",
QEMU_CAPS_DEA_KEY_WRAP,
QEMU_CAPS_VIRTIO_SCSI);
DO_TEST("machine-deakeywrap-off-caps",
QEMU_CAPS_AES_KEY_WRAP, QEMU_CAPS_DEA_KEY_WRAP,
QEMU_CAPS_VIRTIO_SCSI);
DO_TEST("machine-deakeywrap-off-cap",
QEMU_CAPS_DEA_KEY_WRAP,
QEMU_CAPS_VIRTIO_SCSI);
DO_TEST("machine-keywrap-none-caps",
QEMU_CAPS_AES_KEY_WRAP, QEMU_CAPS_DEA_KEY_WRAP,
QEMU_CAPS_VIRTIO_SCSI);
DO_TEST("machine-keywrap-none",
QEMU_CAPS_VIRTIO_SCSI);
DO_TEST("machine-loadparm-s390",
QEMU_CAPS_LOADPARM);
DO_TEST("machine-loadparm-net-s390",
QEMU_CAPS_LOADPARM);
DO_TEST("machine-loadparm-multiple-disks-nets-s390",
QEMU_CAPS_LOADPARM);
DO_TEST_PARSE_ERROR("machine-loadparm-s390-char-invalid",
QEMU_CAPS_LOADPARM);
DO_TEST_PARSE_ERROR("machine-loadparm-s390-len-invalid",
QEMU_CAPS_LOADPARM);
DO_TEST_NOCAPS("qemu-ns-domain-ns0");
DO_TEST_NOCAPS("qemu-ns-domain-commandline");
DO_TEST_NOCAPS("qemu-ns-domain-commandline-ns0");
DO_TEST_NOCAPS("qemu-ns-commandline");
DO_TEST_NOCAPS("qemu-ns-commandline-ns0");
DO_TEST_NOCAPS("qemu-ns-commandline-ns1");
DO_TEST("virtio-input", QEMU_CAPS_VIRTIO_KEYBOARD,
QEMU_CAPS_VIRTIO_MOUSE, QEMU_CAPS_VIRTIO_TABLET);
DO_TEST("virtio-input-passthrough", QEMU_CAPS_VIRTIO_INPUT_HOST);
DO_TEST_CAPS_LATEST("input-linux");
DO_TEST("ppc64-usb-controller",
QEMU_CAPS_DEVICE_SPAPR_PCI_HOST_BRIDGE,
QEMU_CAPS_PCI_OHCI);
DO_TEST("ppc64-usb-controller-legacy",
QEMU_CAPS_DEVICE_SPAPR_PCI_HOST_BRIDGE,
QEMU_CAPS_PIIX3_USB_UHCI);
DO_TEST_FULL("ppc64-usb-controller-qemu-xhci", "",
ARG_PARSEFLAGS, VIR_DOMAIN_DEF_PARSE_ABI_UPDATE,
ARG_QEMU_CAPS,
QEMU_CAPS_DEVICE_SPAPR_PCI_HOST_BRIDGE,
QEMU_CAPS_NEC_USB_XHCI,
QEMU_CAPS_DEVICE_QEMU_XHCI,
QEMU_CAPS_LAST,
ARG_END);
DO_TEST_PARSE_ERROR("ppc64-tpmproxy-double",
QEMU_CAPS_DEVICE_SPAPR_PCI_HOST_BRIDGE,
QEMU_CAPS_PCI_OHCI,
QEMU_CAPS_DEVICE_TPM_PASSTHROUGH,
QEMU_CAPS_DEVICE_SPAPR_TPM_PROXY);
DO_TEST_PARSE_ERROR("ppc64-tpm-double",
QEMU_CAPS_DEVICE_SPAPR_PCI_HOST_BRIDGE,
QEMU_CAPS_PCI_OHCI,
QEMU_CAPS_DEVICE_TPM_PASSTHROUGH,
QEMU_CAPS_DEVICE_SPAPR_TPM_PROXY);
DO_TEST_CAPS_LATEST_PPC64("ppc64-tpmproxy-single");
DO_TEST_CAPS_LATEST_PPC64("ppc64-tpmproxy-with-tpm");
DO_TEST("aarch64-usb-controller-qemu-xhci",
QEMU_CAPS_OBJECT_GPEX,
QEMU_CAPS_NEC_USB_XHCI,
QEMU_CAPS_DEVICE_QEMU_XHCI);
DO_TEST("aarch64-usb-controller-nec-xhci",
QEMU_CAPS_OBJECT_GPEX,
QEMU_CAPS_NEC_USB_XHCI);
DO_TEST("sparc-minimal",
QEMU_CAPS_SCSI_NCR53C90);
DO_TEST_CAPS_LATEST_PARSE_ERROR("missing-machine");
DO_TEST_CAPS_LATEST("name-escape");
DO_TEST_NOCAPS("master-key");
DO_TEST("usb-long-port-path",
QEMU_CAPS_USB_HUB);
DO_TEST_PARSE_ERROR("usb-too-long-port-path-invalid",
QEMU_CAPS_USB_HUB);
DO_TEST_NOCAPS("acpi-table");
DO_TEST_CAPS_LATEST("intel-iommu");
DO_TEST_CAPS_LATEST("intel-iommu-caching-mode");
DO_TEST_CAPS_LATEST("intel-iommu-eim");
DO_TEST_CAPS_LATEST("intel-iommu-device-iotlb");
DO_TEST_CAPS_LATEST("intel-iommu-aw-bits");
DO_TEST_CAPS_LATEST_PARSE_ERROR("intel-iommu-wrong-machine");
DO_TEST_CAPS_ARCH_LATEST("iommu-smmuv3", "aarch64");
DO_TEST_CAPS_LATEST("virtio-iommu-x86_64");
DO_TEST_CAPS_VER_PARSE_ERROR("virtio-iommu-x86_64", "6.1.0");
DO_TEST_CAPS_ARCH_LATEST("virtio-iommu-aarch64", "aarch64");
DO_TEST_CAPS_LATEST_PARSE_ERROR("virtio-iommu-wrong-machine");
DO_TEST_CAPS_LATEST_PARSE_ERROR("virtio-iommu-no-acpi");
DO_TEST_CAPS_LATEST_PARSE_ERROR("virtio-iommu-invalid-address-type");
DO_TEST_CAPS_LATEST_PARSE_ERROR("virtio-iommu-invalid-address");
DO_TEST("cpu-hotplug-startup", QEMU_CAPS_QUERY_HOTPLUGGABLE_CPUS);
DO_TEST_PARSE_ERROR("cpu-hotplug-granularity",
QEMU_CAPS_QUERY_HOTPLUGGABLE_CPUS);
DO_TEST_CAPS_LATEST("virtio-options");
DO_TEST_CAPS_LATEST("virtio-options-controller-iommu");
DO_TEST_CAPS_LATEST("virtio-options-disk-iommu");
DO_TEST_CAPS_LATEST("virtio-options-fs-iommu");
DO_TEST_CAPS_LATEST("virtio-options-input-iommu");
DO_TEST_CAPS_LATEST("virtio-options-memballoon-iommu");
DO_TEST_CAPS_LATEST("virtio-options-net-iommu");
DO_TEST_CAPS_LATEST("virtio-options-rng-iommu");
DO_TEST_CAPS_LATEST("virtio-options-video-iommu");
DO_TEST_CAPS_LATEST("virtio-options-controller-ats");
DO_TEST_CAPS_LATEST("virtio-options-disk-ats");
DO_TEST_CAPS_LATEST("virtio-options-fs-ats");
DO_TEST_CAPS_LATEST("virtio-options-input-ats");
DO_TEST_CAPS_LATEST("virtio-options-memballoon-ats");
DO_TEST_CAPS_LATEST("virtio-options-net-ats");
DO_TEST_CAPS_LATEST("virtio-options-rng-ats");
DO_TEST_CAPS_LATEST("virtio-options-video-ats");
DO_TEST_CAPS_LATEST("virtio-options-controller-packed");
DO_TEST_CAPS_LATEST("virtio-options-disk-packed");
DO_TEST_CAPS_LATEST("virtio-options-fs-packed");
DO_TEST_CAPS_LATEST("virtio-options-input-packed");
DO_TEST_CAPS_LATEST("virtio-options-memballoon-packed");
DO_TEST_CAPS_LATEST("virtio-options-memballoon-freepage-reporting");
DO_TEST_CAPS_LATEST("virtio-options-net-packed");
DO_TEST_CAPS_LATEST("virtio-options-rng-packed");
DO_TEST_CAPS_LATEST("virtio-options-video-packed");
DO_TEST_PARSE_ERROR_NOCAPS("virtio-options-memballoon-freepage-reporting");
DO_TEST("fd-memory-numa-topology", QEMU_CAPS_OBJECT_MEMORY_FILE,
QEMU_CAPS_KVM);
DO_TEST("fd-memory-numa-topology2", QEMU_CAPS_OBJECT_MEMORY_FILE,
QEMU_CAPS_KVM);
DO_TEST("fd-memory-numa-topology3", QEMU_CAPS_OBJECT_MEMORY_FILE,
QEMU_CAPS_KVM);
DO_TEST_CAPS_LATEST("fd-memory-numa-topology4");
DO_TEST("fd-memory-no-numa-topology", QEMU_CAPS_OBJECT_MEMORY_FILE,
QEMU_CAPS_KVM);
DO_TEST_CAPS_LATEST("memfd-memory-numa");
DO_TEST_CAPS_LATEST("memfd-memory-default-hugepage");
DO_TEST("cpu-check-none", QEMU_CAPS_KVM);
DO_TEST("cpu-check-partial", QEMU_CAPS_KVM);
DO_TEST("cpu-check-full", QEMU_CAPS_KVM);
DO_TEST("cpu-check-default-none", QEMU_CAPS_KVM);
DO_TEST_NOCAPS("cpu-check-default-none2");
DO_TEST("cpu-check-default-partial", QEMU_CAPS_KVM);
DO_TEST("cpu-check-default-partial2", QEMU_CAPS_KVM);
qemu: Add support for guest CPU cache This patch maps /domain/cpu/cache element into -cpu parameters: - <cache mode='passthrough'/> is translated to host-cache-info=on - <cache level='3' mode='emulate'/> is transformed into l3-cache=on - <cache mode='disable'/> is turned in host-cache-info=off,l3-cache=off Any other <cache> element is forbidden. The tricky part is detecting whether QEMU supports the CPU properties. The 'host-cache-info' property is introduced in v2.4.0-1389-ge265e3e480, earlier QEMU releases enabled host-cache-info by default and had no way to disable it. If the property is present, it defaults to 'off' for any QEMU until at least 2.9.0. The 'l3-cache' property was introduced later by v2.7.0-200-g14c985cffa. Earlier versions worked as if l3-cache=off was passed. For any QEMU until at least 2.9.0 l3-cache is 'off' by default. QEMU 2.9.0 was the first release which supports probing both properties by running device-list-properties with typename=host-x86_64-cpu. Older QEMU releases did not support device-list-properties command for CPU devices. Thus we can't really rely on probing them and we can just use query-cpu-model-expansion QMP command as a witness. Because the cache property probing is only reliable for QEMU >= 2.9.0 when both are already supported for quite a few releases, we let QEMU report an error if a specific cache mode is explicitly requested. The other mode (or both if a user requested CPU cache to be disabled) is explicitly turned off for QEMU >= 2.9.0 to avoid any surprises in case the QEMU defaults change. Any older QEMU already turns them off so not doing so explicitly does not make any harm. Signed-off-by: Jiri Denemark <jdenemar@redhat.com>
2017-04-25 20:07:19 +03:00
DO_TEST("cpu-cache-disable", QEMU_CAPS_KVM, QEMU_CAPS_CPU_CACHE);
DO_TEST("cpu-cache-disable2", QEMU_CAPS_KVM);
DO_TEST("cpu-cache-disable3", QEMU_CAPS_KVM, QEMU_CAPS_CPU_CACHE);
DO_TEST("cpu-cache-passthrough", QEMU_CAPS_KVM, QEMU_CAPS_CPU_CACHE);
DO_TEST("cpu-cache-passthrough2", QEMU_CAPS_KVM);
DO_TEST("cpu-cache-emulate-l3", QEMU_CAPS_KVM, QEMU_CAPS_CPU_CACHE);
DO_TEST_PARSE_ERROR("cpu-cache-emulate-l2", QEMU_CAPS_KVM);
DO_TEST_PARSE_ERROR("cpu-cache-passthrough3", QEMU_CAPS_KVM);
DO_TEST_PARSE_ERROR("cpu-cache-passthrough-l3", QEMU_CAPS_KVM);
DO_TEST("vmcoreinfo", QEMU_CAPS_DEVICE_VMCOREINFO);
qemu: Add support for guest CPU cache This patch maps /domain/cpu/cache element into -cpu parameters: - <cache mode='passthrough'/> is translated to host-cache-info=on - <cache level='3' mode='emulate'/> is transformed into l3-cache=on - <cache mode='disable'/> is turned in host-cache-info=off,l3-cache=off Any other <cache> element is forbidden. The tricky part is detecting whether QEMU supports the CPU properties. The 'host-cache-info' property is introduced in v2.4.0-1389-ge265e3e480, earlier QEMU releases enabled host-cache-info by default and had no way to disable it. If the property is present, it defaults to 'off' for any QEMU until at least 2.9.0. The 'l3-cache' property was introduced later by v2.7.0-200-g14c985cffa. Earlier versions worked as if l3-cache=off was passed. For any QEMU until at least 2.9.0 l3-cache is 'off' by default. QEMU 2.9.0 was the first release which supports probing both properties by running device-list-properties with typename=host-x86_64-cpu. Older QEMU releases did not support device-list-properties command for CPU devices. Thus we can't really rely on probing them and we can just use query-cpu-model-expansion QMP command as a witness. Because the cache property probing is only reliable for QEMU >= 2.9.0 when both are already supported for quite a few releases, we let QEMU report an error if a specific cache mode is explicitly requested. The other mode (or both if a user requested CPU cache to be disabled) is explicitly turned off for QEMU >= 2.9.0 to avoid any surprises in case the QEMU defaults change. Any older QEMU already turns them off so not doing so explicitly does not make any harm. Signed-off-by: Jiri Denemark <jdenemar@redhat.com>
2017-04-25 20:07:19 +03:00
DO_TEST_CAPS_LATEST("user-aliases");
DO_TEST_CAPS_LATEST("user-aliases2");
DO_TEST_CAPS_LATEST("user-aliases-usb");
DO_TEST_CAPS_LATEST("tseg-explicit-size");
DO_TEST_CAPS_LATEST_PARSE_ERROR("tseg-i440fx");
DO_TEST_CAPS_LATEST_PARSE_ERROR("tseg-invalid-size");
DO_TEST("video-virtio-gpu-ccw",
QEMU_CAPS_DEVICE_VIRTIO_GPU,
QEMU_CAPS_VNC,
QEMU_CAPS_DEVICE_VIRTIO_GPU_CCW);
DO_TEST("input-virtio-ccw",
QEMU_CAPS_VIRTIO_KEYBOARD,
QEMU_CAPS_VIRTIO_MOUSE,
QEMU_CAPS_VIRTIO_TABLET,
QEMU_CAPS_DEVICE_VIRTIO_KEYBOARD_CCW,
QEMU_CAPS_DEVICE_VIRTIO_MOUSE_CCW,
QEMU_CAPS_DEVICE_VIRTIO_TABLET_CCW);
DO_TEST_CAPS_LATEST("vhost-vsock");
DO_TEST_CAPS_LATEST("vhost-vsock-auto");
DO_TEST_CAPS_ARCH_LATEST("vhost-vsock-ccw", "s390x");
DO_TEST_CAPS_ARCH_LATEST("vhost-vsock-ccw-auto", "s390x");
DO_TEST_CAPS_ARCH_LATEST("vhost-vsock-ccw-iommu", "s390x");
DO_TEST_CAPS_VER("launch-security-sev", "6.0.0");
DO_TEST_CAPS_VER("launch-security-sev-missing-platform-info", "6.0.0");
DO_TEST_CAPS_ARCH_LATEST_FULL("launch-security-sev-direct",
"x86_64",
ARG_QEMU_CAPS,
QEMU_CAPS_SEV_GUEST,
QEMU_CAPS_LAST);
DO_TEST_CAPS_ARCH_LATEST("launch-security-s390-pv", "s390x");
DO_TEST_CAPS_LATEST("vhost-user-fs-fd-memory");
DO_TEST_CAPS_LATEST("vhost-user-fs-hugepages");
DO_TEST_CAPS_LATEST_PARSE_ERROR("vhost-user-fs-readonly");
DO_TEST("riscv64-virt",
QEMU_CAPS_DEVICE_VIRTIO_MMIO);
DO_TEST("riscv64-virt-pci",
QEMU_CAPS_OBJECT_GPEX);
DO_TEST_CAPS_LATEST("virtio-transitional");
DO_TEST_CAPS_LATEST("virtio-non-transitional");
DO_TEST_CAPS_LATEST_PARSE_ERROR("virtio-transitional-not-supported");
/* Simple headless guests for various architectures */
DO_TEST_CAPS_ARCH_LATEST("aarch64-virt-headless", "aarch64");
DO_TEST_CAPS_ARCH_LATEST("ppc64-pseries-headless", "ppc64");
DO_TEST_CAPS_ARCH_LATEST("riscv64-virt-headless", "riscv64");
DO_TEST_CAPS_ARCH_LATEST("s390x-ccw-headless", "s390x");
DO_TEST_CAPS_ARCH_LATEST("x86_64-pc-headless", "x86_64");
DO_TEST_CAPS_ARCH_LATEST("x86_64-q35-headless", "x86_64");
/* Simple guests with graphics for various architectures */
DO_TEST_CAPS_ARCH_LATEST("aarch64-virt-graphics", "aarch64");
DO_TEST_CAPS_ARCH_LATEST("ppc64-pseries-graphics", "ppc64");
DO_TEST_CAPS_ARCH_LATEST("riscv64-virt-graphics", "riscv64");
DO_TEST_CAPS_ARCH_LATEST("s390x-ccw-graphics", "s390x");
DO_TEST_CAPS_ARCH_LATEST("x86_64-pc-graphics", "x86_64");
DO_TEST_CAPS_ARCH_LATEST("x86_64-q35-graphics", "x86_64");
DO_TEST_CAPS_LATEST("vhost-user-vga");
DO_TEST_CAPS_LATEST("vhost-user-gpu-secondary");
DO_TEST_CAPS_LATEST("cpu-Icelake-Server-pconfig");
DO_TEST_CAPS_ARCH_LATEST("aarch64-default-cpu-kvm-virt-4.2", "aarch64");
DO_TEST_CAPS_ARCH_LATEST("aarch64-default-cpu-tcg-virt-4.2", "aarch64");
DO_TEST_CAPS_ARCH_LATEST("ppc64-default-cpu-kvm-pseries-2.7", "ppc64");
DO_TEST_CAPS_ARCH_LATEST("ppc64-default-cpu-tcg-pseries-2.7", "ppc64");
DO_TEST_CAPS_ARCH_LATEST("ppc64-default-cpu-kvm-pseries-3.1", "ppc64");
DO_TEST_CAPS_ARCH_LATEST("ppc64-default-cpu-tcg-pseries-3.1", "ppc64");
DO_TEST_CAPS_ARCH_LATEST("ppc64-default-cpu-kvm-pseries-4.2", "ppc64");
DO_TEST_CAPS_ARCH_LATEST("ppc64-default-cpu-tcg-pseries-4.2", "ppc64");
DO_TEST_CAPS_ARCH_LATEST("s390-default-cpu-kvm-ccw-virtio-2.7", "s390x");
DO_TEST_CAPS_ARCH_LATEST("s390-default-cpu-tcg-ccw-virtio-2.7", "s390x");
DO_TEST_CAPS_ARCH_LATEST("s390-default-cpu-kvm-ccw-virtio-4.2", "s390x");
DO_TEST_CAPS_ARCH_LATEST("s390-default-cpu-tcg-ccw-virtio-4.2", "s390x");
DO_TEST_CAPS_ARCH_LATEST("x86_64-default-cpu-kvm-pc-4.2", "x86_64");
DO_TEST_CAPS_ARCH_LATEST("x86_64-default-cpu-tcg-pc-4.2", "x86_64");
DO_TEST_CAPS_ARCH_LATEST("x86_64-default-cpu-kvm-q35-4.2", "x86_64");
DO_TEST_CAPS_ARCH_LATEST("x86_64-default-cpu-tcg-q35-4.2", "x86_64");
DO_TEST_CAPS_ARCH_LATEST("x86_64-default-cpu-tcg-features", "x86_64");
DO_TEST_CAPS_LATEST("virtio-9p-multidevs");
DO_TEST_CAPS_LATEST("virtio-9p-createmode");
DO_TEST_CAPS_LATEST("devices-acpi-index");
DO_TEST_MACOS("hvf-x86_64-q35-headless",
QEMU_CAPS_VIRTIO_PCI_TRANSITIONAL,
QEMU_CAPS_DEVICE_PCIE_ROOT_PORT,
QEMU_CAPS_DEVICE_VIRTIO_NET,
QEMU_CAPS_DEVICE_ISA_SERIAL,
QEMU_CAPS_DEVICE_VIRTIO_RNG,
QEMU_CAPS_OBJECT_RNG_RANDOM);
DO_TEST_MACOS("hvf-aarch64-virt-headless",
QEMU_CAPS_OBJECT_GPEX,
QEMU_CAPS_VIRTIO_PCI_TRANSITIONAL,
QEMU_CAPS_DEVICE_PCIE_ROOT_PORT,
QEMU_CAPS_DEVICE_VIRTIO_NET,
QEMU_CAPS_DEVICE_PL011,
QEMU_CAPS_DEVICE_VIRTIO_RNG,
QEMU_CAPS_OBJECT_RNG_RANDOM);
/* HVF guests should not work on Linux with KVM */
DO_TEST_CAPS_LATEST_PARSE_ERROR("hvf-x86_64-q35-headless");
DO_TEST("cpu-phys-bits-passthrough", QEMU_CAPS_KVM);
DO_TEST("cpu-phys-bits-emulate", QEMU_CAPS_KVM);
DO_TEST("cpu-phys-bits-emulate2", QEMU_CAPS_KVM);
DO_TEST_PARSE_ERROR("cpu-phys-bits-emulate3", QEMU_CAPS_KVM);
DO_TEST_PARSE_ERROR("cpu-phys-bits-passthrough2", QEMU_CAPS_KVM);
if (getenv("LIBVIRT_SKIP_CLEANUP") == NULL)
virFileDeleteTree(fakerootdir);
VIR_FREE(driver.config->nbdTLSx509certdir);
qemuTestDriverFree(&driver);
virFileWrapperClearPrefixes();
return ret == 0 ? EXIT_SUCCESS : EXIT_FAILURE;
2007-07-19 01:34:22 +04:00
}
VIR_TEST_MAIN_PRELOAD(mymain,
VIR_TEST_MOCK("qemuxml2argv"),
VIR_TEST_MOCK("domaincaps"),
VIR_TEST_MOCK("virrandom"),
VIR_TEST_MOCK("qemucpu"),
VIR_TEST_MOCK("virpci"))
#else
int main(void)
{
return EXIT_AM_SKIP;
}
#endif /* WITH_QEMU */