/* * cpu_x86.c: CPU driver for CPUs with x86 compatible CPUID instruction * * Copyright (C) 2009-2014 Red Hat, Inc. * * This library is free software; you can redistribute it and/or * modify it under the terms of the GNU Lesser General Public * License as published by the Free Software Foundation; either * version 2.1 of the License, or (at your option) any later version. * * This library is distributed in the hope that it will be useful, * but WITHOUT ANY WARRANTY; without even the implied warranty of * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU * Lesser General Public License for more details. * * You should have received a copy of the GNU Lesser General Public * License along with this library. If not, see * . * * Authors: * Jiri Denemark */ #include #include #include "virlog.h" #include "viralloc.h" #include "cpu.h" #include "cpu_map.h" #include "cpu_x86.h" #include "virbuffer.h" #include "virendian.h" #include "virstring.h" #define VIR_FROM_THIS VIR_FROM_CPU VIR_LOG_INIT("cpu.cpu_x86"); #define VENDOR_STRING_LENGTH 12 static const virCPUx86CPUID cpuidNull = { 0, 0, 0, 0, 0 }; static const virArch archs[] = { VIR_ARCH_I686, VIR_ARCH_X86_64 }; struct x86_vendor { char *name; virCPUx86CPUID cpuid; struct x86_vendor *next; }; struct x86_feature { char *name; virCPUx86Data *data; struct x86_feature *next; }; struct x86_kvm_feature { const char *name; const virCPUx86CPUID cpuid; }; static const struct x86_kvm_feature x86_kvm_features[] = { {VIR_CPU_x86_KVM_CLOCKSOURCE, { .function = 0x40000001, .eax = 0x00000001 }}, {VIR_CPU_x86_KVM_NOP_IO_DELAY, { .function = 0x40000001, .eax = 0x00000002 }}, {VIR_CPU_x86_KVM_MMU_OP, { .function = 0x40000001, .eax = 0x00000004 }}, {VIR_CPU_x86_KVM_CLOCKSOURCE2, { .function = 0x40000001, .eax = 0x00000008 }}, {VIR_CPU_x86_KVM_ASYNC_PF, { .function = 0x40000001, .eax = 0x00000010 }}, {VIR_CPU_x86_KVM_STEAL_TIME, { .function = 0x40000001, .eax = 0x00000020 }}, {VIR_CPU_x86_KVM_PV_EOI, { .function = 0x40000001, .eax = 0x00000040 }}, {VIR_CPU_x86_KVM_PV_UNHALT, { .function = 0x40000001, .eax = 0x00000080 }}, {VIR_CPU_x86_KVM_CLOCKSOURCE_STABLE_BIT, { .function = 0x40000001, .eax = 0x01000000 }}, }; struct x86_model { char *name; const struct x86_vendor *vendor; virCPUx86Data *data; struct x86_model *next; }; struct x86_map { struct x86_vendor *vendors; struct x86_feature *features; struct x86_model *models; struct x86_feature *migrate_blockers; }; static struct x86_map* virCPUx86Map; int virCPUx86MapOnceInit(void); VIR_ONCE_GLOBAL_INIT(virCPUx86Map); enum compare_result { SUBSET, EQUAL, SUPERSET, UNRELATED }; struct virCPUx86DataIterator { const virCPUx86Data *data; int pos; }; #define virCPUx86DataIteratorInit(data) \ { data, -1 } static bool x86cpuidMatch(const virCPUx86CPUID *cpuid1, const virCPUx86CPUID *cpuid2) { return (cpuid1->eax == cpuid2->eax && cpuid1->ebx == cpuid2->ebx && cpuid1->ecx == cpuid2->ecx && cpuid1->edx == cpuid2->edx); } static bool x86cpuidMatchMasked(const virCPUx86CPUID *cpuid, const virCPUx86CPUID *mask) { return ((cpuid->eax & mask->eax) == mask->eax && (cpuid->ebx & mask->ebx) == mask->ebx && (cpuid->ecx & mask->ecx) == mask->ecx && (cpuid->edx & mask->edx) == mask->edx); } static void x86cpuidSetBits(virCPUx86CPUID *cpuid, const virCPUx86CPUID *mask) { if (!mask) return; cpuid->eax |= mask->eax; cpuid->ebx |= mask->ebx; cpuid->ecx |= mask->ecx; cpuid->edx |= mask->edx; } static void x86cpuidClearBits(virCPUx86CPUID *cpuid, const virCPUx86CPUID *mask) { if (!mask) return; cpuid->eax &= ~mask->eax; cpuid->ebx &= ~mask->ebx; cpuid->ecx &= ~mask->ecx; cpuid->edx &= ~mask->edx; } static void x86cpuidAndBits(virCPUx86CPUID *cpuid, const virCPUx86CPUID *mask) { if (!mask) return; cpuid->eax &= mask->eax; cpuid->ebx &= mask->ebx; cpuid->ecx &= mask->ecx; cpuid->edx &= mask->edx; } static int virCPUx86CPUIDSorter(const void *a, const void *b) { virCPUx86CPUID *da = (virCPUx86CPUID *) a; virCPUx86CPUID *db = (virCPUx86CPUID *) b; if (da->function > db->function) return 1; else if (da->function < db->function) return -1; return 0; } /* skips all zero CPUID leafs */ static virCPUx86CPUID * x86DataCpuidNext(struct virCPUx86DataIterator *iterator) { const virCPUx86Data *data = iterator->data; if (!data) return NULL; while (++iterator->pos < data->len) { if (!x86cpuidMatch(data->data + iterator->pos, &cpuidNull)) return data->data + iterator->pos; } return NULL; } static virCPUx86CPUID * x86DataCpuid(const virCPUx86Data *data, uint32_t function) { size_t i; for (i = 0; i < data->len; i++) { if (data->data[i].function == function) return data->data + i; } return NULL; } void virCPUx86DataFree(virCPUx86Data *data) { if (data == NULL) return; VIR_FREE(data->data); VIR_FREE(data); } virCPUDataPtr virCPUx86MakeData(virArch arch, virCPUx86Data **data) { virCPUDataPtr cpuData; if (VIR_ALLOC(cpuData) < 0) return NULL; cpuData->arch = arch; cpuData->data.x86 = *data; *data = NULL; return cpuData; } static void x86FreeCPUData(virCPUDataPtr data) { if (!data) return; virCPUx86DataFree(data->data.x86); VIR_FREE(data); } static virCPUx86Data * x86DataCopy(const virCPUx86Data *data) { virCPUx86Data *copy = NULL; size_t i; if (VIR_ALLOC(copy) < 0 || VIR_ALLOC_N(copy->data, data->len) < 0) { virCPUx86DataFree(copy); return NULL; } copy->len = data->len; for (i = 0; i < data->len; i++) copy->data[i] = data->data[i]; return copy; } int virCPUx86DataAddCPUID(virCPUx86Data *data, const virCPUx86CPUID *cpuid) { virCPUx86CPUID *existing; if ((existing = x86DataCpuid(data, cpuid->function))) { x86cpuidSetBits(existing, cpuid); } else { if (VIR_APPEND_ELEMENT_COPY(data->data, data->len, *((virCPUx86CPUID *)cpuid)) < 0) return -1; qsort(data->data, data->len, sizeof(virCPUx86CPUID), virCPUx86CPUIDSorter); } return 0; } static int x86DataAdd(virCPUx86Data *data1, const virCPUx86Data *data2) { struct virCPUx86DataIterator iter = virCPUx86DataIteratorInit(data2); virCPUx86CPUID *cpuid1; virCPUx86CPUID *cpuid2; while ((cpuid2 = x86DataCpuidNext(&iter))) { cpuid1 = x86DataCpuid(data1, cpuid2->function); if (cpuid1) { x86cpuidSetBits(cpuid1, cpuid2); } else { if (virCPUx86DataAddCPUID(data1, cpuid2) < 0) return -1; } } return 0; } static void x86DataSubtract(virCPUx86Data *data1, const virCPUx86Data *data2) { struct virCPUx86DataIterator iter = virCPUx86DataIteratorInit(data1); virCPUx86CPUID *cpuid1; virCPUx86CPUID *cpuid2; while ((cpuid1 = x86DataCpuidNext(&iter))) { cpuid2 = x86DataCpuid(data2, cpuid1->function); x86cpuidClearBits(cpuid1, cpuid2); } } static void x86DataIntersect(virCPUx86Data *data1, const virCPUx86Data *data2) { struct virCPUx86DataIterator iter = virCPUx86DataIteratorInit(data1); virCPUx86CPUID *cpuid1; virCPUx86CPUID *cpuid2; while ((cpuid1 = x86DataCpuidNext(&iter))) { cpuid2 = x86DataCpuid(data2, cpuid1->function); if (cpuid2) x86cpuidAndBits(cpuid1, cpuid2); else x86cpuidClearBits(cpuid1, cpuid1); } } static bool x86DataIsEmpty(virCPUx86Data *data) { struct virCPUx86DataIterator iter = virCPUx86DataIteratorInit(data); return x86DataCpuidNext(&iter) == NULL; } static bool x86DataIsSubset(const virCPUx86Data *data, const virCPUx86Data *subset) { struct virCPUx86DataIterator iter = virCPUx86DataIteratorInit((virCPUx86Data *)subset); const virCPUx86CPUID *cpuid; const virCPUx86CPUID *cpuidSubset; while ((cpuidSubset = x86DataCpuidNext(&iter))) { if (!(cpuid = x86DataCpuid(data, cpuidSubset->function)) || !x86cpuidMatchMasked(cpuid, cpuidSubset)) return false; } return true; } /* also removes all detected features from data */ static int x86DataToCPUFeatures(virCPUDefPtr cpu, int policy, virCPUx86Data *data, const struct x86_map *map) { const struct x86_feature *feature = map->features; while (feature != NULL) { if (x86DataIsSubset(data, feature->data)) { x86DataSubtract(data, feature->data); if (virCPUDefAddFeature(cpu, feature->name, policy) < 0) return -1; } feature = feature->next; } return 0; } /* also removes bits corresponding to vendor string from data */ static const struct x86_vendor * x86DataToVendor(virCPUx86Data *data, const struct x86_map *map) { const struct x86_vendor *vendor = map->vendors; virCPUx86CPUID *cpuid; while (vendor) { if ((cpuid = x86DataCpuid(data, vendor->cpuid.function)) && x86cpuidMatchMasked(cpuid, &vendor->cpuid)) { x86cpuidClearBits(cpuid, &vendor->cpuid); return vendor; } vendor = vendor->next; } return NULL; } static virCPUDefPtr x86DataToCPU(const virCPUx86Data *data, const struct x86_model *model, const struct x86_map *map) { virCPUDefPtr cpu; virCPUx86Data *copy = NULL; virCPUx86Data *modelData = NULL; const struct x86_vendor *vendor; if (VIR_ALLOC(cpu) < 0 || VIR_STRDUP(cpu->model, model->name) < 0 || !(copy = x86DataCopy(data)) || !(modelData = x86DataCopy(model->data))) goto error; if ((vendor = x86DataToVendor(copy, map)) && VIR_STRDUP(cpu->vendor, vendor->name) < 0) goto error; x86DataSubtract(copy, modelData); x86DataSubtract(modelData, data); /* because feature policy is ignored for host CPU */ cpu->type = VIR_CPU_TYPE_GUEST; if (x86DataToCPUFeatures(cpu, VIR_CPU_FEATURE_REQUIRE, copy, map) || x86DataToCPUFeatures(cpu, VIR_CPU_FEATURE_DISABLE, modelData, map)) goto error; cleanup: virCPUx86DataFree(modelData); virCPUx86DataFree(copy); return cpu; error: virCPUDefFree(cpu); cpu = NULL; goto cleanup; } static void x86VendorFree(struct x86_vendor *vendor) { if (!vendor) return; VIR_FREE(vendor->name); VIR_FREE(vendor); } static struct x86_vendor * x86VendorFind(const struct x86_map *map, const char *name) { struct x86_vendor *vendor; vendor = map->vendors; while (vendor) { if (STREQ(vendor->name, name)) return vendor; vendor = vendor->next; } return NULL; } static int x86VendorLoad(xmlXPathContextPtr ctxt, struct x86_map *map) { struct x86_vendor *vendor = NULL; char *string = NULL; int ret = 0; if (VIR_ALLOC(vendor) < 0) goto error; vendor->name = virXPathString("string(@name)", ctxt); if (!vendor->name) { virReportError(VIR_ERR_INTERNAL_ERROR, "%s", _("Missing CPU vendor name")); goto ignore; } if (x86VendorFind(map, vendor->name)) { virReportError(VIR_ERR_INTERNAL_ERROR, _("CPU vendor %s already defined"), vendor->name); goto ignore; } string = virXPathString("string(@string)", ctxt); if (!string) { virReportError(VIR_ERR_INTERNAL_ERROR, _("Missing vendor string for CPU vendor %s"), vendor->name); goto ignore; } if (strlen(string) != VENDOR_STRING_LENGTH) { virReportError(VIR_ERR_INTERNAL_ERROR, _("Invalid CPU vendor string '%s'"), string); goto ignore; } vendor->cpuid.function = 0; vendor->cpuid.ebx = virReadBufInt32LE(string); vendor->cpuid.edx = virReadBufInt32LE(string + 4); vendor->cpuid.ecx = virReadBufInt32LE(string + 8); if (!map->vendors) { map->vendors = vendor; } else { vendor->next = map->vendors; map->vendors = vendor; } out: VIR_FREE(string); return ret; error: ret = -1; ignore: x86VendorFree(vendor); goto out; } static struct x86_feature * x86FeatureNew(void) { struct x86_feature *feature; if (VIR_ALLOC(feature) < 0) return NULL; if (VIR_ALLOC(feature->data) < 0) { VIR_FREE(feature); return NULL; } return feature; } static void x86FeatureFree(struct x86_feature *feature) { if (feature == NULL) return; VIR_FREE(feature->name); virCPUx86DataFree(feature->data); VIR_FREE(feature); } static struct x86_feature * x86FeatureCopy(const struct x86_feature *src) { struct x86_feature *feature; if (VIR_ALLOC(feature) < 0) return NULL; if (VIR_STRDUP(feature->name, src->name) < 0) goto error; if ((feature->data = x86DataCopy(src->data)) == NULL) goto error; return feature; error: x86FeatureFree(feature); return NULL; } static struct x86_feature * x86FeatureFind(const struct x86_map *map, const char *name) { struct x86_feature *feature; feature = map->features; while (feature != NULL) { if (STREQ(feature->name, name)) return feature; feature = feature->next; } return NULL; } static char * x86FeatureNames(const struct x86_map *map, const char *separator, virCPUx86Data *data) { virBuffer ret = VIR_BUFFER_INITIALIZER; bool first = true; struct x86_feature *next_feature = map->features; virBufferAdd(&ret, "", 0); while (next_feature) { if (x86DataIsSubset(data, next_feature->data)) { if (!first) virBufferAdd(&ret, separator, -1); else first = false; virBufferAdd(&ret, next_feature->name, -1); } next_feature = next_feature->next; } return virBufferContentAndReset(&ret); } static int x86ParseCPUID(xmlXPathContextPtr ctxt, virCPUx86CPUID *cpuid) { unsigned long fun, eax, ebx, ecx, edx; int ret_fun, ret_eax, ret_ebx, ret_ecx, ret_edx; memset(cpuid, 0, sizeof(*cpuid)); fun = eax = ebx = ecx = edx = 0; ret_fun = virXPathULongHex("string(@function)", ctxt, &fun); ret_eax = virXPathULongHex("string(@eax)", ctxt, &eax); ret_ebx = virXPathULongHex("string(@ebx)", ctxt, &ebx); ret_ecx = virXPathULongHex("string(@ecx)", ctxt, &ecx); ret_edx = virXPathULongHex("string(@edx)", ctxt, &edx); if (ret_fun < 0 || ret_eax == -2 || ret_ebx == -2 || ret_ecx == -2 || ret_edx == -2) return -1; cpuid->function = fun; cpuid->eax = eax; cpuid->ebx = ebx; cpuid->ecx = ecx; cpuid->edx = edx; return 0; } static int x86FeatureLoad(xmlXPathContextPtr ctxt, struct x86_map *map) { xmlNodePtr *nodes = NULL; xmlNodePtr ctxt_node = ctxt->node; struct x86_feature *feature; virCPUx86CPUID cpuid; int ret = 0; size_t i; int n; char *str = NULL; bool migratable = true; struct x86_feature *migrate_blocker = NULL; if (!(feature = x86FeatureNew())) goto error; feature->name = virXPathString("string(@name)", ctxt); if (feature->name == NULL) { virReportError(VIR_ERR_INTERNAL_ERROR, "%s", _("Missing CPU feature name")); goto ignore; } if (x86FeatureFind(map, feature->name)) { virReportError(VIR_ERR_INTERNAL_ERROR, _("CPU feature %s already defined"), feature->name); goto ignore; } str = virXPathString("string(@migratable)", ctxt); if (STREQ_NULLABLE(str, "no")) migratable = false; n = virXPathNodeSet("./cpuid", ctxt, &nodes); if (n < 0) goto ignore; for (i = 0; i < n; i++) { ctxt->node = nodes[i]; if (x86ParseCPUID(ctxt, &cpuid) < 0) { virReportError(VIR_ERR_INTERNAL_ERROR, _("Invalid cpuid[%zu] in %s feature"), i, feature->name); goto ignore; } if (virCPUx86DataAddCPUID(feature->data, &cpuid)) goto error; } if (!migratable) { if ((migrate_blocker = x86FeatureCopy(feature)) == NULL) goto error; migrate_blocker->next = map->migrate_blockers; map->migrate_blockers = migrate_blocker; } if (map->features == NULL) { map->features = feature; } else { feature->next = map->features; map->features = feature; } out: ctxt->node = ctxt_node; VIR_FREE(nodes); VIR_FREE(str); return ret; error: ret = -1; ignore: x86FeatureFree(feature); x86FeatureFree(migrate_blocker); goto out; } static virCPUx86Data * x86DataFromCPUFeatures(virCPUDefPtr cpu, const struct x86_map *map) { virCPUx86Data *data; size_t i; if (VIR_ALLOC(data) < 0) return NULL; for (i = 0; i < cpu->nfeatures; i++) { const struct x86_feature *feature; if (!(feature = x86FeatureFind(map, cpu->features[i].name))) { virReportError(VIR_ERR_INTERNAL_ERROR, _("Unknown CPU feature %s"), cpu->features[i].name); goto error; } if (x86DataAdd(data, feature->data) < 0) goto error; } return data; error: virCPUx86DataFree(data); return NULL; } static struct x86_model * x86ModelNew(void) { struct x86_model *model; if (VIR_ALLOC(model) < 0) return NULL; if (VIR_ALLOC(model->data) < 0) { VIR_FREE(model); return NULL; } return model; } static void x86ModelFree(struct x86_model *model) { if (model == NULL) return; VIR_FREE(model->name); virCPUx86DataFree(model->data); VIR_FREE(model); } static struct x86_model * x86ModelCopy(const struct x86_model *model) { struct x86_model *copy; if (VIR_ALLOC(copy) < 0 || VIR_STRDUP(copy->name, model->name) < 0 || !(copy->data = x86DataCopy(model->data))) { x86ModelFree(copy); return NULL; } copy->vendor = model->vendor; return copy; } static struct x86_model * x86ModelFind(const struct x86_map *map, const char *name) { struct x86_model *model; model = map->models; while (model != NULL) { if (STREQ(model->name, name)) return model; model = model->next; } return NULL; } static struct x86_model * x86ModelFromCPU(const virCPUDef *cpu, const struct x86_map *map, int policy) { struct x86_model *model = NULL; size_t i; if (policy == VIR_CPU_FEATURE_REQUIRE) { if ((model = x86ModelFind(map, cpu->model)) == NULL) { virReportError(VIR_ERR_INTERNAL_ERROR, _("Unknown CPU model %s"), cpu->model); goto error; } if ((model = x86ModelCopy(model)) == NULL) goto error; } else if (!(model = x86ModelNew())) { goto error; } else if (cpu->type == VIR_CPU_TYPE_HOST) { return model; } for (i = 0; i < cpu->nfeatures; i++) { const struct x86_feature *feature; if (cpu->type == VIR_CPU_TYPE_GUEST && cpu->features[i].policy != policy) continue; if ((feature = x86FeatureFind(map, cpu->features[i].name)) == NULL) { virReportError(VIR_ERR_INTERNAL_ERROR, _("Unknown CPU feature %s"), cpu->features[i].name); goto error; } if (x86DataAdd(model->data, feature->data)) goto error; } return model; error: x86ModelFree(model); return NULL; } static int x86ModelSubtractCPU(struct x86_model *model, const virCPUDef *cpu, const struct x86_map *map) { const struct x86_model *cpu_model; size_t i; if (!(cpu_model = x86ModelFind(map, cpu->model))) { virReportError(VIR_ERR_INTERNAL_ERROR, _("Unknown CPU model %s"), cpu->model); return -1; } x86DataSubtract(model->data, cpu_model->data); for (i = 0; i < cpu->nfeatures; i++) { const struct x86_feature *feature; if (!(feature = x86FeatureFind(map, cpu->features[i].name))) { virReportError(VIR_ERR_INTERNAL_ERROR, _("Unknown CPU feature %s"), cpu->features[i].name); return -1; } x86DataSubtract(model->data, feature->data); } return 0; } static enum compare_result x86ModelCompare(const struct x86_model *model1, const struct x86_model *model2) { enum compare_result result = EQUAL; struct virCPUx86DataIterator iter1 = virCPUx86DataIteratorInit(model1->data); struct virCPUx86DataIterator iter2 = virCPUx86DataIteratorInit(model2->data); virCPUx86CPUID *cpuid1; virCPUx86CPUID *cpuid2; while ((cpuid1 = x86DataCpuidNext(&iter1))) { enum compare_result match = SUPERSET; if ((cpuid2 = x86DataCpuid(model2->data, cpuid1->function))) { if (x86cpuidMatch(cpuid1, cpuid2)) continue; else if (!x86cpuidMatchMasked(cpuid1, cpuid2)) match = SUBSET; } if (result == EQUAL) result = match; else if (result != match) return UNRELATED; } while ((cpuid2 = x86DataCpuidNext(&iter2))) { enum compare_result match = SUBSET; if ((cpuid1 = x86DataCpuid(model1->data, cpuid2->function))) { if (x86cpuidMatch(cpuid2, cpuid1)) continue; else if (!x86cpuidMatchMasked(cpuid2, cpuid1)) match = SUPERSET; } if (result == EQUAL) result = match; else if (result != match) return UNRELATED; } return result; } static int x86ModelLoad(xmlXPathContextPtr ctxt, struct x86_map *map) { xmlNodePtr *nodes = NULL; struct x86_model *model; char *vendor = NULL; int ret = 0; size_t i; int n; if (!(model = x86ModelNew())) goto error; model->name = virXPathString("string(@name)", ctxt); if (model->name == NULL) { virReportError(VIR_ERR_INTERNAL_ERROR, "%s", _("Missing CPU model name")); goto ignore; } if (virXPathNode("./model", ctxt) != NULL) { const struct x86_model *ancestor; char *name; name = virXPathString("string(./model/@name)", ctxt); if (name == NULL) { virReportError(VIR_ERR_INTERNAL_ERROR, _("Missing ancestor's name in CPU model %s"), model->name); goto ignore; } if ((ancestor = x86ModelFind(map, name)) == NULL) { virReportError(VIR_ERR_INTERNAL_ERROR, _("Ancestor model %s not found for CPU model %s"), name, model->name); VIR_FREE(name); goto ignore; } VIR_FREE(name); model->vendor = ancestor->vendor; virCPUx86DataFree(model->data); if (!(model->data = x86DataCopy(ancestor->data))) goto error; } if (virXPathBoolean("boolean(./vendor)", ctxt)) { vendor = virXPathString("string(./vendor/@name)", ctxt); if (!vendor) { virReportError(VIR_ERR_INTERNAL_ERROR, _("Invalid vendor element in CPU model %s"), model->name); goto ignore; } if (!(model->vendor = x86VendorFind(map, vendor))) { virReportError(VIR_ERR_INTERNAL_ERROR, _("Unknown vendor %s referenced by CPU model %s"), vendor, model->name); goto ignore; } } n = virXPathNodeSet("./feature", ctxt, &nodes); if (n < 0) goto ignore; for (i = 0; i < n; i++) { const struct x86_feature *feature; char *name; if ((name = virXMLPropString(nodes[i], "name")) == NULL) { virReportError(VIR_ERR_INTERNAL_ERROR, _("Missing feature name for CPU model %s"), model->name); goto ignore; } if ((feature = x86FeatureFind(map, name)) == NULL) { virReportError(VIR_ERR_INTERNAL_ERROR, _("Feature %s required by CPU model %s not found"), name, model->name); VIR_FREE(name); goto ignore; } VIR_FREE(name); if (x86DataAdd(model->data, feature->data)) goto error; } if (map->models == NULL) { map->models = model; } else { model->next = map->models; map->models = model; } out: VIR_FREE(vendor); VIR_FREE(nodes); return ret; error: ret = -1; ignore: x86ModelFree(model); goto out; } static void x86MapFree(struct x86_map *map) { if (map == NULL) return; while (map->features != NULL) { struct x86_feature *feature = map->features; map->features = feature->next; x86FeatureFree(feature); } while (map->models != NULL) { struct x86_model *model = map->models; map->models = model->next; x86ModelFree(model); } while (map->vendors != NULL) { struct x86_vendor *vendor = map->vendors; map->vendors = vendor->next; x86VendorFree(vendor); } while (map->migrate_blockers != NULL) { struct x86_feature *migrate_blocker = map->migrate_blockers; map->migrate_blockers = migrate_blocker->next; x86FeatureFree(migrate_blocker); } VIR_FREE(map); } static int x86MapLoadCallback(cpuMapElement element, xmlXPathContextPtr ctxt, void *data) { struct x86_map *map = data; switch (element) { case CPU_MAP_ELEMENT_VENDOR: return x86VendorLoad(ctxt, map); case CPU_MAP_ELEMENT_FEATURE: return x86FeatureLoad(ctxt, map); case CPU_MAP_ELEMENT_MODEL: return x86ModelLoad(ctxt, map); case CPU_MAP_ELEMENT_LAST: break; } return 0; } static int x86MapLoadInternalFeatures(struct x86_map *map) { size_t i; struct x86_feature *feature = NULL; for (i = 0; i < ARRAY_CARDINALITY(x86_kvm_features); i++) { const char *name = x86_kvm_features[i].name; if (x86FeatureFind(map, name)) { virReportError(VIR_ERR_INTERNAL_ERROR, _("CPU feature %s already defined"), name); return -1; } if (!(feature = x86FeatureNew())) goto error; if (VIR_STRDUP(feature->name, name) < 0) goto error; if (virCPUx86DataAddCPUID(feature->data, &x86_kvm_features[i].cpuid)) goto error; if (map->features == NULL) { map->features = feature; } else { feature->next = map->features; map->features = feature; } feature = NULL; } return 0; error: x86FeatureFree(feature); return -1; } static struct x86_map * virCPUx86LoadMap(void) { struct x86_map *map; if (VIR_ALLOC(map) < 0) return NULL; if (cpuMapLoad("x86", x86MapLoadCallback, map) < 0) goto error; if (x86MapLoadInternalFeatures(map) < 0) goto error; return map; error: x86MapFree(map); return NULL; } int virCPUx86MapOnceInit(void) { if (!(virCPUx86Map = virCPUx86LoadMap())) return -1; return 0; } static const struct x86_map * virCPUx86GetMap(void) { if (virCPUx86MapInitialize() < 0) return NULL; return virCPUx86Map; } static char * x86CPUDataFormat(const virCPUData *data) { struct virCPUx86DataIterator iter = virCPUx86DataIteratorInit(data->data.x86); virCPUx86CPUID *cpuid; virBuffer buf = VIR_BUFFER_INITIALIZER; virBufferAddLit(&buf, "\n"); while ((cpuid = x86DataCpuidNext(&iter))) { virBufferAsprintf(&buf, " \n", cpuid->function, cpuid->eax, cpuid->ebx, cpuid->ecx, cpuid->edx); } virBufferAddLit(&buf, "\n"); if (virBufferCheckError(&buf) < 0) return NULL; return virBufferContentAndReset(&buf); } static virCPUDataPtr x86CPUDataParse(const char *xmlStr) { xmlDocPtr xml = NULL; xmlXPathContextPtr ctxt = NULL; xmlNodePtr *nodes = NULL; virCPUDataPtr cpuData = NULL; virCPUx86Data *data = NULL; virCPUx86CPUID cpuid; size_t i; int n; if (VIR_ALLOC(data) < 0) goto cleanup; if (!(xml = virXMLParseStringCtxt(xmlStr, _("CPU data"), &ctxt))) { virReportError(VIR_ERR_INTERNAL_ERROR, "%s", _("cannot parse CPU data")); goto cleanup; } ctxt->node = xmlDocGetRootElement(xml); n = virXPathNodeSet("/cpudata[@arch='x86']/data", ctxt, &nodes); if (n < 0) { virReportError(VIR_ERR_INTERNAL_ERROR, "%s", _("no x86 CPU data found")); goto cleanup; } for (i = 0; i < n; i++) { ctxt->node = nodes[i]; if (x86ParseCPUID(ctxt, &cpuid) < 0) { virReportError(VIR_ERR_INTERNAL_ERROR, _("failed to parse cpuid[%zu]"), i); goto cleanup; } if (virCPUx86DataAddCPUID(data, &cpuid) < 0) goto cleanup; } cpuData = virCPUx86MakeData(VIR_ARCH_X86_64, &data); cleanup: VIR_FREE(nodes); xmlXPathFreeContext(ctxt); xmlFreeDoc(xml); virCPUx86DataFree(data); return cpuData; } /* A helper macro to exit the cpu computation function without writing * redundant code: * MSG: error message * CPU_DEF: a virCPUx86Data pointer with flags that are conflicting * RET: return code to set * * This macro generates the error string outputs it into logs. */ #define virX86CpuIncompatible(MSG, CPU_DEF) \ do { \ char *flagsStr = NULL; \ if (!(flagsStr = x86FeatureNames(map, ", ", (CPU_DEF)))) { \ virReportOOMError(); \ goto error; \ } \ if (message && \ virAsprintf(message, "%s: %s", _(MSG), flagsStr) < 0) { \ VIR_FREE(flagsStr); \ goto error; \ } \ VIR_DEBUG("%s: %s", MSG, flagsStr); \ VIR_FREE(flagsStr); \ ret = VIR_CPU_COMPARE_INCOMPATIBLE; \ } while (0) static virCPUCompareResult x86Compute(virCPUDefPtr host, virCPUDefPtr cpu, virCPUDataPtr *guest, char **message) { const struct x86_map *map = NULL; struct x86_model *host_model = NULL; struct x86_model *cpu_force = NULL; struct x86_model *cpu_require = NULL; struct x86_model *cpu_optional = NULL; struct x86_model *cpu_disable = NULL; struct x86_model *cpu_forbid = NULL; struct x86_model *diff = NULL; struct x86_model *guest_model = NULL; virCPUCompareResult ret; enum compare_result result; virArch arch; size_t i; if (cpu->arch != VIR_ARCH_NONE) { bool found = false; for (i = 0; i < ARRAY_CARDINALITY(archs); i++) { if (archs[i] == cpu->arch) { found = true; break; } } if (!found) { VIR_DEBUG("CPU arch %s does not match host arch", virArchToString(cpu->arch)); if (message && virAsprintf(message, _("CPU arch %s does not match host arch"), virArchToString(cpu->arch)) < 0) goto error; return VIR_CPU_COMPARE_INCOMPATIBLE; } arch = cpu->arch; } else { arch = host->arch; } if (cpu->vendor && (!host->vendor || STRNEQ(cpu->vendor, host->vendor))) { VIR_DEBUG("host CPU vendor does not match required CPU vendor %s", cpu->vendor); if (message && virAsprintf(message, _("host CPU vendor does not match required " "CPU vendor %s"), cpu->vendor) < 0) goto error; return VIR_CPU_COMPARE_INCOMPATIBLE; } if (!(map = virCPUx86GetMap()) || !(host_model = x86ModelFromCPU(host, map, VIR_CPU_FEATURE_REQUIRE)) || !(cpu_force = x86ModelFromCPU(cpu, map, VIR_CPU_FEATURE_FORCE)) || !(cpu_require = x86ModelFromCPU(cpu, map, VIR_CPU_FEATURE_REQUIRE)) || !(cpu_optional = x86ModelFromCPU(cpu, map, VIR_CPU_FEATURE_OPTIONAL)) || !(cpu_disable = x86ModelFromCPU(cpu, map, VIR_CPU_FEATURE_DISABLE)) || !(cpu_forbid = x86ModelFromCPU(cpu, map, VIR_CPU_FEATURE_FORBID))) goto error; x86DataIntersect(cpu_forbid->data, host_model->data); if (!x86DataIsEmpty(cpu_forbid->data)) { virX86CpuIncompatible(N_("Host CPU provides forbidden features"), cpu_forbid->data); goto cleanup; } /* first remove features that were inherited from the CPU model and were * explicitly forced, disabled, or made optional */ x86DataSubtract(cpu_require->data, cpu_force->data); x86DataSubtract(cpu_require->data, cpu_optional->data); x86DataSubtract(cpu_require->data, cpu_disable->data); result = x86ModelCompare(host_model, cpu_require); if (result == SUBSET || result == UNRELATED) { x86DataSubtract(cpu_require->data, host_model->data); virX86CpuIncompatible(N_("Host CPU does not provide required " "features"), cpu_require->data); goto cleanup; } ret = VIR_CPU_COMPARE_IDENTICAL; if ((diff = x86ModelCopy(host_model)) == NULL) goto error; x86DataSubtract(diff->data, cpu_optional->data); x86DataSubtract(diff->data, cpu_require->data); x86DataSubtract(diff->data, cpu_disable->data); x86DataSubtract(diff->data, cpu_force->data); if (!x86DataIsEmpty(diff->data)) ret = VIR_CPU_COMPARE_SUPERSET; if (ret == VIR_CPU_COMPARE_SUPERSET && cpu->type == VIR_CPU_TYPE_GUEST && cpu->match == VIR_CPU_MATCH_STRICT) { virX86CpuIncompatible(N_("Host CPU does not strictly match guest CPU: " "Extra features"), diff->data); goto cleanup; } if (guest != NULL) { virCPUx86Data *guestData; if ((guest_model = x86ModelCopy(host_model)) == NULL) goto error; if (cpu->type == VIR_CPU_TYPE_GUEST && cpu->match == VIR_CPU_MATCH_EXACT) x86DataSubtract(guest_model->data, diff->data); if (x86DataAdd(guest_model->data, cpu_force->data)) goto error; x86DataSubtract(guest_model->data, cpu_disable->data); if (!(guestData = x86DataCopy(guest_model->data)) || !(*guest = virCPUx86MakeData(arch, &guestData))) { virCPUx86DataFree(guestData); goto error; } } cleanup: x86ModelFree(host_model); x86ModelFree(diff); x86ModelFree(cpu_force); x86ModelFree(cpu_require); x86ModelFree(cpu_optional); x86ModelFree(cpu_disable); x86ModelFree(cpu_forbid); x86ModelFree(guest_model); return ret; error: ret = VIR_CPU_COMPARE_ERROR; goto cleanup; } #undef virX86CpuIncompatible static virCPUCompareResult x86Compare(virCPUDefPtr host, virCPUDefPtr cpu, bool failIncomaptible) { virCPUCompareResult ret; char *message = NULL; ret = x86Compute(host, cpu, NULL, &message); if (failIncomaptible && ret == VIR_CPU_COMPARE_INCOMPATIBLE) { ret = VIR_CPU_COMPARE_ERROR; if (message) { virReportError(VIR_ERR_CPU_INCOMPATIBLE, "%s", message); } else { virReportError(VIR_ERR_CPU_INCOMPATIBLE, NULL); } } VIR_FREE(message); return ret; } static virCPUCompareResult x86GuestData(virCPUDefPtr host, virCPUDefPtr guest, virCPUDataPtr *data, char **message) { return x86Compute(host, guest, data, message); } static int x86Decode(virCPUDefPtr cpu, const virCPUx86Data *data, const char **models, unsigned int nmodels, const char *preferred, unsigned int flags) { int ret = -1; const struct x86_map *map; const struct x86_model *candidate; virCPUDefPtr cpuCandidate; virCPUDefPtr cpuModel = NULL; virCPUx86Data *copy = NULL; virCPUx86Data *features = NULL; const virCPUx86Data *cpuData = NULL; size_t i; virCheckFlags(VIR_CONNECT_BASELINE_CPU_EXPAND_FEATURES | VIR_CONNECT_BASELINE_CPU_MIGRATABLE, -1); if (!data || !(map = virCPUx86GetMap())) return -1; candidate = map->models; while (candidate != NULL) { if (!cpuModelIsAllowed(candidate->name, models, nmodels)) { if (preferred && STREQ(candidate->name, preferred)) { if (cpu->fallback != VIR_CPU_FALLBACK_ALLOW) { virReportError(VIR_ERR_CONFIG_UNSUPPORTED, _("CPU model %s is not supported by hypervisor"), preferred); goto out; } else { VIR_WARN("Preferred CPU model %s not allowed by" " hypervisor; closest supported model will be" " used", preferred); } } else { VIR_DEBUG("CPU model %s not allowed by hypervisor; ignoring", candidate->name); } goto next; } if (!(cpuCandidate = x86DataToCPU(data, candidate, map))) goto out; if (candidate->vendor && cpuCandidate->vendor && STRNEQ(candidate->vendor->name, cpuCandidate->vendor)) { VIR_DEBUG("CPU vendor %s of model %s differs from %s; ignoring", candidate->vendor->name, candidate->name, cpuCandidate->vendor); virCPUDefFree(cpuCandidate); goto next; } if (cpu->type == VIR_CPU_TYPE_HOST) { cpuCandidate->type = VIR_CPU_TYPE_HOST; for (i = 0; i < cpuCandidate->nfeatures; i++) { switch (cpuCandidate->features[i].policy) { case VIR_CPU_FEATURE_DISABLE: virCPUDefFree(cpuCandidate); goto next; default: cpuCandidate->features[i].policy = -1; } } } if (preferred && STREQ(cpuCandidate->model, preferred)) { virCPUDefFree(cpuModel); cpuModel = cpuCandidate; cpuData = candidate->data; break; } if (cpuModel == NULL || cpuModel->nfeatures > cpuCandidate->nfeatures) { virCPUDefFree(cpuModel); cpuModel = cpuCandidate; cpuData = candidate->data; } else { virCPUDefFree(cpuCandidate); } next: candidate = candidate->next; } if (cpuModel == NULL) { virReportError(VIR_ERR_INTERNAL_ERROR, "%s", _("Cannot find suitable CPU model for given data")); goto out; } /* Remove non-migratable features if requested * Note: this only works as long as no CPU model contains non-migratable * features directly */ if (flags & VIR_CONNECT_BASELINE_CPU_MIGRATABLE) { for (i = 0; i < cpuModel->nfeatures; i++) { const struct x86_feature *feat; for (feat = map->migrate_blockers; feat; feat = feat->next) { if (STREQ(feat->name, cpuModel->features[i].name)) { VIR_FREE(cpuModel->features[i].name); VIR_DELETE_ELEMENT_INPLACE(cpuModel->features, i, cpuModel->nfeatures); } } } } if (flags & VIR_CONNECT_BASELINE_CPU_EXPAND_FEATURES) { if (!(copy = x86DataCopy(cpuData)) || !(features = x86DataFromCPUFeatures(cpuModel, map))) goto out; x86DataSubtract(copy, features); if (x86DataToCPUFeatures(cpuModel, VIR_CPU_FEATURE_REQUIRE, copy, map) < 0) goto out; } cpu->model = cpuModel->model; cpu->vendor = cpuModel->vendor; cpu->nfeatures = cpuModel->nfeatures; cpu->features = cpuModel->features; VIR_FREE(cpuModel); ret = 0; out: virCPUDefFree(cpuModel); virCPUx86DataFree(copy); virCPUx86DataFree(features); return ret; } static int x86DecodeCPUData(virCPUDefPtr cpu, const virCPUData *data, const char **models, unsigned int nmodels, const char *preferred, unsigned int flags) { return x86Decode(cpu, data->data.x86, models, nmodels, preferred, flags); } static virCPUx86Data * x86EncodePolicy(const virCPUDef *cpu, const struct x86_map *map, virCPUFeaturePolicy policy) { struct x86_model *model; virCPUx86Data *data = NULL; if (!(model = x86ModelFromCPU(cpu, map, policy))) return NULL; data = model->data; model->data = NULL; x86ModelFree(model); return data; } static int x86Encode(virArch arch, const virCPUDef *cpu, virCPUDataPtr *forced, virCPUDataPtr *required, virCPUDataPtr *optional, virCPUDataPtr *disabled, virCPUDataPtr *forbidden, virCPUDataPtr *vendor) { const struct x86_map *map = NULL; virCPUx86Data *data_forced = NULL; virCPUx86Data *data_required = NULL; virCPUx86Data *data_optional = NULL; virCPUx86Data *data_disabled = NULL; virCPUx86Data *data_forbidden = NULL; virCPUx86Data *data_vendor = NULL; if (forced) *forced = NULL; if (required) *required = NULL; if (optional) *optional = NULL; if (disabled) *disabled = NULL; if (forbidden) *forbidden = NULL; if (vendor) *vendor = NULL; if ((map = virCPUx86GetMap()) == NULL) goto error; if (forced) { data_forced = x86EncodePolicy(cpu, map, VIR_CPU_FEATURE_FORCE); if (!data_forced) goto error; } if (required) { data_required = x86EncodePolicy(cpu, map, VIR_CPU_FEATURE_REQUIRE); if (!data_required) goto error; } if (optional) { data_optional = x86EncodePolicy(cpu, map, VIR_CPU_FEATURE_OPTIONAL); if (!data_optional) goto error; } if (disabled) { data_disabled = x86EncodePolicy(cpu, map, VIR_CPU_FEATURE_DISABLE); if (!data_disabled) goto error; } if (forbidden) { data_forbidden = x86EncodePolicy(cpu, map, VIR_CPU_FEATURE_FORBID); if (!data_forbidden) goto error; } if (vendor) { const struct x86_vendor *v = NULL; if (cpu->vendor && !(v = x86VendorFind(map, cpu->vendor))) { virReportError(VIR_ERR_OPERATION_FAILED, _("CPU vendor %s not found"), cpu->vendor); goto error; } if (v && (VIR_ALLOC(data_vendor) < 0 || virCPUx86DataAddCPUID(data_vendor, &v->cpuid) < 0)) { goto error; } } if (forced && !(*forced = virCPUx86MakeData(arch, &data_forced))) goto error; if (required && !(*required = virCPUx86MakeData(arch, &data_required))) goto error; if (optional && !(*optional = virCPUx86MakeData(arch, &data_optional))) goto error; if (disabled && !(*disabled = virCPUx86MakeData(arch, &data_disabled))) goto error; if (forbidden && !(*forbidden = virCPUx86MakeData(arch, &data_forbidden))) goto error; if (vendor && !(*vendor = virCPUx86MakeData(arch, &data_vendor))) goto error; return 0; error: virCPUx86DataFree(data_forced); virCPUx86DataFree(data_required); virCPUx86DataFree(data_optional); virCPUx86DataFree(data_disabled); virCPUx86DataFree(data_forbidden); virCPUx86DataFree(data_vendor); if (forced) x86FreeCPUData(*forced); if (required) x86FreeCPUData(*required); if (optional) x86FreeCPUData(*optional); if (disabled) x86FreeCPUData(*disabled); if (forbidden) x86FreeCPUData(*forbidden); if (vendor) x86FreeCPUData(*vendor); return -1; } #if HAVE_CPUID static inline void cpuidCall(virCPUx86CPUID *cpuid) { # if __x86_64__ asm("xor %%ebx, %%ebx;" /* clear the other registers as some cpuid */ "xor %%ecx, %%ecx;" /* functions may use them as additional */ "xor %%edx, %%edx;" /* arguments */ "cpuid;" : "=a" (cpuid->eax), "=b" (cpuid->ebx), "=c" (cpuid->ecx), "=d" (cpuid->edx) : "a" (cpuid->function)); # else /* we need to avoid direct use of ebx for CPUID output as it is used * for global offset table on i386 with -fPIC */ asm("push %%ebx;" "xor %%ebx, %%ebx;" /* clear the other registers as some cpuid */ "xor %%ecx, %%ecx;" /* functions may use them as additional */ "xor %%edx, %%edx;" /* arguments */ "cpuid;" "mov %%ebx, %1;" "pop %%ebx;" : "=a" (cpuid->eax), "=r" (cpuid->ebx), "=c" (cpuid->ecx), "=d" (cpuid->edx) : "a" (cpuid->function) : "cc"); # endif } static int cpuidSet(uint32_t base, virCPUx86Data *data) { uint32_t max; uint32_t i; virCPUx86CPUID cpuid = { base, 0, 0, 0, 0 }; cpuidCall(&cpuid); max = cpuid.eax; for (i = base; i <= max; i++) { cpuid.function = i; cpuidCall(&cpuid); if (virCPUx86DataAddCPUID(data, &cpuid) < 0) return -1; } return 0; } static virCPUDataPtr x86NodeData(virArch arch) { virCPUDataPtr cpuData = NULL; virCPUx86Data *data; if (VIR_ALLOC(data) < 0) return NULL; if (cpuidSet(CPUX86_BASIC, data) < 0) goto error; if (cpuidSet(CPUX86_EXTENDED, data) < 0) goto error; if (!(cpuData = virCPUx86MakeData(arch, &data))) goto error; return cpuData; error: virCPUx86DataFree(data); return NULL; } #endif static virCPUDefPtr x86Baseline(virCPUDefPtr *cpus, unsigned int ncpus, const char **models, unsigned int nmodels, unsigned int flags) { const struct x86_map *map = NULL; struct x86_model *base_model = NULL; virCPUDefPtr cpu = NULL; size_t i; const struct x86_vendor *vendor = NULL; struct x86_model *model = NULL; bool outputVendor = true; const char *modelName; bool matchingNames = true; virCheckFlags(VIR_CONNECT_BASELINE_CPU_EXPAND_FEATURES | VIR_CONNECT_BASELINE_CPU_MIGRATABLE, NULL); if (!(map = virCPUx86GetMap())) goto error; if (!(base_model = x86ModelFromCPU(cpus[0], map, VIR_CPU_FEATURE_REQUIRE))) goto error; if (VIR_ALLOC(cpu) < 0) goto error; cpu->arch = cpus[0]->arch; cpu->type = VIR_CPU_TYPE_GUEST; cpu->match = VIR_CPU_MATCH_EXACT; if (!cpus[0]->vendor) { outputVendor = false; } else if (!(vendor = x86VendorFind(map, cpus[0]->vendor))) { virReportError(VIR_ERR_OPERATION_FAILED, _("Unknown CPU vendor %s"), cpus[0]->vendor); goto error; } modelName = cpus[0]->model; for (i = 1; i < ncpus; i++) { const char *vn = NULL; if (matchingNames && cpus[i]->model) { if (!modelName) { modelName = cpus[i]->model; } else if (STRNEQ(modelName, cpus[i]->model)) { modelName = NULL; matchingNames = false; } } if (!(model = x86ModelFromCPU(cpus[i], map, VIR_CPU_FEATURE_REQUIRE))) goto error; if (cpus[i]->vendor && model->vendor && STRNEQ(cpus[i]->vendor, model->vendor->name)) { virReportError(VIR_ERR_OPERATION_FAILED, _("CPU vendor %s of model %s differs from vendor %s"), model->vendor->name, model->name, cpus[i]->vendor); goto error; } if (cpus[i]->vendor) { vn = cpus[i]->vendor; } else { outputVendor = false; if (model->vendor) vn = model->vendor->name; } if (vn) { if (!vendor) { if (!(vendor = x86VendorFind(map, vn))) { virReportError(VIR_ERR_OPERATION_FAILED, _("Unknown CPU vendor %s"), vn); goto error; } } else if (STRNEQ(vendor->name, vn)) { virReportError(VIR_ERR_OPERATION_FAILED, "%s", _("CPU vendors do not match")); goto error; } } x86DataIntersect(base_model->data, model->data); x86ModelFree(model); model = NULL; } if (x86DataIsEmpty(base_model->data)) { virReportError(VIR_ERR_OPERATION_FAILED, "%s", _("CPUs are incompatible")); goto error; } if (vendor && virCPUx86DataAddCPUID(base_model->data, &vendor->cpuid) < 0) goto error; if (x86Decode(cpu, base_model->data, models, nmodels, modelName, flags) < 0) goto error; if (STREQ_NULLABLE(cpu->model, modelName)) cpu->fallback = VIR_CPU_FALLBACK_FORBID; if (!outputVendor) VIR_FREE(cpu->vendor); cpu->arch = VIR_ARCH_NONE; cleanup: x86ModelFree(base_model); return cpu; error: x86ModelFree(model); virCPUDefFree(cpu); cpu = NULL; goto cleanup; } static int x86UpdateCustom(virCPUDefPtr guest, const virCPUDef *host) { int ret = -1; size_t i; const struct x86_map *map; struct x86_model *host_model = NULL; if (!(map = virCPUx86GetMap()) || !(host_model = x86ModelFromCPU(host, map, VIR_CPU_FEATURE_REQUIRE))) goto cleanup; for (i = 0; i < guest->nfeatures; i++) { if (guest->features[i].policy == VIR_CPU_FEATURE_OPTIONAL) { const struct x86_feature *feature; if (!(feature = x86FeatureFind(map, guest->features[i].name))) { virReportError(VIR_ERR_INTERNAL_ERROR, _("Unknown CPU feature %s"), guest->features[i].name); goto cleanup; } if (x86DataIsSubset(host_model->data, feature->data)) guest->features[i].policy = VIR_CPU_FEATURE_REQUIRE; else guest->features[i].policy = VIR_CPU_FEATURE_DISABLE; } } if (guest->match == VIR_CPU_MATCH_MINIMUM) { guest->match = VIR_CPU_MATCH_EXACT; if (x86ModelSubtractCPU(host_model, guest, map) || x86DataToCPUFeatures(guest, VIR_CPU_FEATURE_REQUIRE, host_model->data, map)) goto cleanup; } ret = 0; cleanup: x86ModelFree(host_model); return ret; } static int x86UpdateHostModel(virCPUDefPtr guest, const virCPUDef *host, bool passthrough) { virCPUDefPtr oldguest = NULL; const struct x86_map *map; const struct x86_feature *feat; size_t i; int ret = -1; if (!(map = virCPUx86GetMap())) goto cleanup; /* update the host model according to the desired configuration */ if (!(oldguest = virCPUDefCopy(guest))) goto cleanup; virCPUDefFreeModel(guest); if (virCPUDefCopyModel(guest, host, true) < 0) goto cleanup; /* Remove non-migratable features by default * Note: this only works as long as no CPU model contains non-migratable * features directly */ for (i = 0; i < guest->nfeatures; i++) { for (feat = map->migrate_blockers; feat; feat = feat->next) { if (STREQ(feat->name, guest->features[i].name)) { VIR_FREE(guest->features[i].name); VIR_DELETE_ELEMENT_INPLACE(guest->features, i, guest->nfeatures); } } } for (i = 0; !passthrough && i < oldguest->nfeatures; i++) { if (virCPUDefUpdateFeature(guest, oldguest->features[i].name, oldguest->features[i].policy) < 0) goto cleanup; } ret = 0; cleanup: virCPUDefFree(oldguest); return ret; } static int x86Update(virCPUDefPtr guest, const virCPUDef *host) { switch ((virCPUMode) guest->mode) { case VIR_CPU_MODE_CUSTOM: return x86UpdateCustom(guest, host); case VIR_CPU_MODE_HOST_MODEL: guest->match = VIR_CPU_MATCH_EXACT; return x86UpdateHostModel(guest, host, false); case VIR_CPU_MODE_HOST_PASSTHROUGH: guest->match = VIR_CPU_MATCH_MINIMUM; return x86UpdateHostModel(guest, host, true); case VIR_CPU_MODE_LAST: break; } virReportError(VIR_ERR_INTERNAL_ERROR, _("Unexpected CPU mode: %d"), guest->mode); return -1; } static int x86HasFeature(const virCPUData *data, const char *name) { const struct x86_map *map; struct x86_feature *feature; int ret = -1; if (!(map = virCPUx86GetMap())) return -1; if (!(feature = x86FeatureFind(map, name))) goto cleanup; ret = x86DataIsSubset(data->data.x86, feature->data) ? 1 : 0; cleanup: return ret; } static int x86GetModels(char ***models) { const struct x86_map *map; struct x86_model *model; char *name; size_t nmodels = 0; if (!(map = virCPUx86GetMap())) return -1; if (models && VIR_ALLOC_N(*models, 0) < 0) goto error; model = map->models; while (model != NULL) { if (models) { if (VIR_STRDUP(name, model->name) < 0) goto error; if (VIR_APPEND_ELEMENT(*models, nmodels, name) < 0) goto error; } else { nmodels++; } model = model->next; } return nmodels; error: if (models) { virStringFreeList(*models); *models = NULL; } return -1; } struct cpuArchDriver cpuDriverX86 = { .name = "x86", .arch = archs, .narch = ARRAY_CARDINALITY(archs), .compare = x86Compare, .decode = x86DecodeCPUData, .encode = x86Encode, .free = x86FreeCPUData, #if HAVE_CPUID .nodeData = x86NodeData, #else .nodeData = NULL, #endif .guestData = x86GuestData, .baseline = x86Baseline, .update = x86Update, .hasFeature = x86HasFeature, .dataFormat = x86CPUDataFormat, .dataParse = x86CPUDataParse, .getModels = x86GetModels, };