| Author | Tokens | Token Proportion | Commits | Commit Proportion |
|---|---|---|---|---|
| Paolo Bonzini | 2987 | 36.00% | 9 | 5.49% |
| Sean Christopherson | 1247 | 15.03% | 60 | 36.59% |
| Andrew Jones | 767 | 9.24% | 22 | 13.41% |
| Maciej S. Szmigiero | 537 | 6.47% | 1 | 0.61% |
| Ricardo Koller | 429 | 5.17% | 6 | 3.66% |
| Peter Xu | 406 | 4.89% | 8 | 4.88% |
| Ben Gardon | 341 | 4.11% | 5 | 3.05% |
| Vipin Sharma | 313 | 3.77% | 3 | 1.83% |
| David Matlack | 237 | 2.86% | 2 | 1.22% |
| Eric Auger | 174 | 2.10% | 2 | 1.22% |
| Axel Rasmussen | 166 | 2.00% | 4 | 2.44% |
| Marc Zyngier | 150 | 1.81% | 3 | 1.83% |
| Oliver Upton | 102 | 1.23% | 3 | 1.83% |
| Yanan Wang | 80 | 0.96% | 3 | 1.83% |
| Jing Zhang | 57 | 0.69% | 1 | 0.61% |
| Aaron Lewis | 56 | 0.67% | 6 | 3.66% |
| Christian Bornträger | 52 | 0.63% | 2 | 1.22% |
| Thomas Huth | 38 | 0.46% | 2 | 1.22% |
| Vitaly Kuznetsov | 36 | 0.43% | 3 | 1.83% |
| Vishal Annapurve | 30 | 0.36% | 3 | 1.83% |
| David Dunn | 26 | 0.31% | 1 | 0.61% |
| Drew Schmitt | 14 | 0.17% | 1 | 0.61% |
| Peter Gonda | 13 | 0.16% | 1 | 0.61% |
| Wainer dos Santos Moschetta | 10 | 0.12% | 1 | 0.61% |
| Alexander Graf | 7 | 0.08% | 1 | 0.61% |
| Duan Zhenzhong | 6 | 0.07% | 2 | 1.22% |
| Like Xu | 3 | 0.04% | 1 | 0.61% |
| Thomas Gleixner | 2 | 0.02% | 1 | 0.61% |
| Joao Martins | 2 | 0.02% | 1 | 0.61% |
| Fuad Tabba | 2 | 0.02% | 1 | 0.61% |
| Colton Lewis | 2 | 0.02% | 1 | 0.61% |
| Colin Ian King | 2 | 0.02% | 2 | 1.22% |
| Gavin Shan | 2 | 0.02% | 1 | 0.61% |
| Shaoqin Huang | 1 | 0.01% | 1 | 0.61% |
| Total | 8297 | 164 |
// SPDX-License-Identifier: GPL-2.0-only /* * tools/testing/selftests/kvm/lib/kvm_util.c * * Copyright (C) 2018, Google LLC. */ #define _GNU_SOURCE /* for program_invocation_name */ #include "test_util.h" #include "kvm_util.h" #include "processor.h" #include <assert.h> #include <sched.h> #include <sys/mman.h> #include <sys/types.h> #include <sys/stat.h> #include <unistd.h> #include <linux/kernel.h> #define KVM_UTIL_MIN_PFN 2 static int vcpu_mmap_sz(void); int open_path_or_exit(const char *path, int flags) { int fd; fd = open(path, flags); __TEST_REQUIRE(fd >= 0, "%s not available (errno: %d)", path, errno); return fd; } /* * Open KVM_DEV_PATH if available, otherwise exit the entire program. * * Input Args: * flags - The flags to pass when opening KVM_DEV_PATH. * * Return: * The opened file descriptor of /dev/kvm. */ static int _open_kvm_dev_path_or_exit(int flags) { return open_path_or_exit(KVM_DEV_PATH, flags); } int open_kvm_dev_path_or_exit(void) { return _open_kvm_dev_path_or_exit(O_RDONLY); } static bool get_module_param_bool(const char *module_name, const char *param) { const int path_size = 128; char path[path_size]; char value; ssize_t r; int fd; r = snprintf(path, path_size, "/sys/module/%s/parameters/%s", module_name, param); TEST_ASSERT(r < path_size, "Failed to construct sysfs path in %d bytes.", path_size); fd = open_path_or_exit(path, O_RDONLY); r = read(fd, &value, 1); TEST_ASSERT(r == 1, "read(%s) failed", path); r = close(fd); TEST_ASSERT(!r, "close(%s) failed", path); if (value == 'Y') return true; else if (value == 'N') return false; TEST_FAIL("Unrecognized value '%c' for boolean module param", value); } bool get_kvm_param_bool(const char *param) { return get_module_param_bool("kvm", param); } bool get_kvm_intel_param_bool(const char *param) { return get_module_param_bool("kvm_intel", param); } bool get_kvm_amd_param_bool(const char *param) { return get_module_param_bool("kvm_amd", param); } /* * Capability * * Input Args: * cap - Capability * * Output Args: None * * Return: * On success, the Value corresponding to the capability (KVM_CAP_*) * specified by the value of cap. On failure a TEST_ASSERT failure * is produced. * * Looks up and returns the value corresponding to the capability * (KVM_CAP_*) given by cap. */ unsigned int kvm_check_cap(long cap) { int ret; int kvm_fd; kvm_fd = open_kvm_dev_path_or_exit(); ret = __kvm_ioctl(kvm_fd, KVM_CHECK_EXTENSION, (void *)cap); TEST_ASSERT(ret >= 0, KVM_IOCTL_ERROR(KVM_CHECK_EXTENSION, ret)); close(kvm_fd); return (unsigned int)ret; } void vm_enable_dirty_ring(struct kvm_vm *vm, uint32_t ring_size) { if (vm_check_cap(vm, KVM_CAP_DIRTY_LOG_RING_ACQ_REL)) vm_enable_cap(vm, KVM_CAP_DIRTY_LOG_RING_ACQ_REL, ring_size); else vm_enable_cap(vm, KVM_CAP_DIRTY_LOG_RING, ring_size); vm->dirty_ring_size = ring_size; } static void vm_open(struct kvm_vm *vm) { vm->kvm_fd = _open_kvm_dev_path_or_exit(O_RDWR); TEST_REQUIRE(kvm_has_cap(KVM_CAP_IMMEDIATE_EXIT)); vm->fd = __kvm_ioctl(vm->kvm_fd, KVM_CREATE_VM, (void *)vm->type); TEST_ASSERT(vm->fd >= 0, KVM_IOCTL_ERROR(KVM_CREATE_VM, vm->fd)); } const char *vm_guest_mode_string(uint32_t i) { static const char * const strings[] = { [VM_MODE_P52V48_4K] = "PA-bits:52, VA-bits:48, 4K pages", [VM_MODE_P52V48_64K] = "PA-bits:52, VA-bits:48, 64K pages", [VM_MODE_P48V48_4K] = "PA-bits:48, VA-bits:48, 4K pages", [VM_MODE_P48V48_16K] = "PA-bits:48, VA-bits:48, 16K pages", [VM_MODE_P48V48_64K] = "PA-bits:48, VA-bits:48, 64K pages", [VM_MODE_P40V48_4K] = "PA-bits:40, VA-bits:48, 4K pages", [VM_MODE_P40V48_16K] = "PA-bits:40, VA-bits:48, 16K pages", [VM_MODE_P40V48_64K] = "PA-bits:40, VA-bits:48, 64K pages", [VM_MODE_PXXV48_4K] = "PA-bits:ANY, VA-bits:48, 4K pages", [VM_MODE_P47V64_4K] = "PA-bits:47, VA-bits:64, 4K pages", [VM_MODE_P44V64_4K] = "PA-bits:44, VA-bits:64, 4K pages", [VM_MODE_P36V48_4K] = "PA-bits:36, VA-bits:48, 4K pages", [VM_MODE_P36V48_16K] = "PA-bits:36, VA-bits:48, 16K pages", [VM_MODE_P36V48_64K] = "PA-bits:36, VA-bits:48, 64K pages", [VM_MODE_P36V47_16K] = "PA-bits:36, VA-bits:47, 16K pages", }; _Static_assert(sizeof(strings)/sizeof(char *) == NUM_VM_MODES, "Missing new mode strings?"); TEST_ASSERT(i < NUM_VM_MODES, "Guest mode ID %d too big", i); return strings[i]; } const struct vm_guest_mode_params vm_guest_mode_params[] = { [VM_MODE_P52V48_4K] = { 52, 48, 0x1000, 12 }, [VM_MODE_P52V48_64K] = { 52, 48, 0x10000, 16 }, [VM_MODE_P48V48_4K] = { 48, 48, 0x1000, 12 }, [VM_MODE_P48V48_16K] = { 48, 48, 0x4000, 14 }, [VM_MODE_P48V48_64K] = { 48, 48, 0x10000, 16 }, [VM_MODE_P40V48_4K] = { 40, 48, 0x1000, 12 }, [VM_MODE_P40V48_16K] = { 40, 48, 0x4000, 14 }, [VM_MODE_P40V48_64K] = { 40, 48, 0x10000, 16 }, [VM_MODE_PXXV48_4K] = { 0, 0, 0x1000, 12 }, [VM_MODE_P47V64_4K] = { 47, 64, 0x1000, 12 }, [VM_MODE_P44V64_4K] = { 44, 64, 0x1000, 12 }, [VM_MODE_P36V48_4K] = { 36, 48, 0x1000, 12 }, [VM_MODE_P36V48_16K] = { 36, 48, 0x4000, 14 }, [VM_MODE_P36V48_64K] = { 36, 48, 0x10000, 16 }, [VM_MODE_P36V47_16K] = { 36, 47, 0x4000, 14 }, }; _Static_assert(sizeof(vm_guest_mode_params)/sizeof(struct vm_guest_mode_params) == NUM_VM_MODES, "Missing new mode params?"); /* * Initializes vm->vpages_valid to match the canonical VA space of the * architecture. * * The default implementation is valid for architectures which split the * range addressed by a single page table into a low and high region * based on the MSB of the VA. On architectures with this behavior * the VA region spans [0, 2^(va_bits - 1)), [-(2^(va_bits - 1), -1]. */ __weak void vm_vaddr_populate_bitmap(struct kvm_vm *vm) { sparsebit_set_num(vm->vpages_valid, 0, (1ULL << (vm->va_bits - 1)) >> vm->page_shift); sparsebit_set_num(vm->vpages_valid, (~((1ULL << (vm->va_bits - 1)) - 1)) >> vm->page_shift, (1ULL << (vm->va_bits - 1)) >> vm->page_shift); } struct kvm_vm *____vm_create(enum vm_guest_mode mode) { struct kvm_vm *vm; vm = calloc(1, sizeof(*vm)); TEST_ASSERT(vm != NULL, "Insufficient Memory"); INIT_LIST_HEAD(&vm->vcpus); vm->regions.gpa_tree = RB_ROOT; vm->regions.hva_tree = RB_ROOT; hash_init(vm->regions.slot_hash); vm->mode = mode; vm->type = 0; vm->pa_bits = vm_guest_mode_params[mode].pa_bits; vm->va_bits = vm_guest_mode_params[mode].va_bits; vm->page_size = vm_guest_mode_params[mode].page_size; vm->page_shift = vm_guest_mode_params[mode].page_shift; /* Setup mode specific traits. */ switch (vm->mode) { case VM_MODE_P52V48_4K: vm->pgtable_levels = 4; break; case VM_MODE_P52V48_64K: vm->pgtable_levels = 3; break; case VM_MODE_P48V48_4K: vm->pgtable_levels = 4; break; case VM_MODE_P48V48_64K: vm->pgtable_levels = 3; break; case VM_MODE_P40V48_4K: case VM_MODE_P36V48_4K: vm->pgtable_levels = 4; break; case VM_MODE_P40V48_64K: case VM_MODE_P36V48_64K: vm->pgtable_levels = 3; break; case VM_MODE_P48V48_16K: case VM_MODE_P40V48_16K: case VM_MODE_P36V48_16K: vm->pgtable_levels = 4; break; case VM_MODE_P36V47_16K: vm->pgtable_levels = 3; break; case VM_MODE_PXXV48_4K: #ifdef __x86_64__ kvm_get_cpu_address_width(&vm->pa_bits, &vm->va_bits); /* * Ignore KVM support for 5-level paging (vm->va_bits == 57), * it doesn't take effect unless a CR4.LA57 is set, which it * isn't for this VM_MODE. */ TEST_ASSERT(vm->va_bits == 48 || vm->va_bits == 57, "Linear address width (%d bits) not supported", vm->va_bits); pr_debug("Guest physical address width detected: %d\n", vm->pa_bits); vm->pgtable_levels = 4; vm->va_bits = 48; #else TEST_FAIL("VM_MODE_PXXV48_4K not supported on non-x86 platforms"); #endif break; case VM_MODE_P47V64_4K: vm->pgtable_levels = 5; break; case VM_MODE_P44V64_4K: vm->pgtable_levels = 5; break; default: TEST_FAIL("Unknown guest mode, mode: 0x%x", mode); } #ifdef __aarch64__ if (vm->pa_bits != 40) vm->type = KVM_VM_TYPE_ARM_IPA_SIZE(vm->pa_bits); #endif vm_open(vm); /* Limit to VA-bit canonical virtual addresses. */ vm->vpages_valid = sparsebit_alloc(); vm_vaddr_populate_bitmap(vm); /* Limit physical addresses to PA-bits. */ vm->max_gfn = vm_compute_max_gfn(vm); /* Allocate and setup memory for guest. */ vm->vpages_mapped = sparsebit_alloc(); return vm; } static uint64_t vm_nr_pages_required(enum vm_guest_mode mode, uint32_t nr_runnable_vcpus, uint64_t extra_mem_pages) { uint64_t page_size = vm_guest_mode_params[mode].page_size; uint64_t nr_pages; TEST_ASSERT(nr_runnable_vcpus, "Use vm_create_barebones() for VMs that _never_ have vCPUs\n"); TEST_ASSERT(nr_runnable_vcpus <= kvm_check_cap(KVM_CAP_MAX_VCPUS), "nr_vcpus = %d too large for host, max-vcpus = %d", nr_runnable_vcpus, kvm_check_cap(KVM_CAP_MAX_VCPUS)); /* * Arbitrarily allocate 512 pages (2mb when page size is 4kb) for the * test code and other per-VM assets that will be loaded into memslot0. */ nr_pages = 512; /* Account for the per-vCPU stacks on behalf of the test. */ nr_pages += nr_runnable_vcpus * DEFAULT_STACK_PGS; /* * Account for the number of pages needed for the page tables. The * maximum page table size for a memory region will be when the * smallest page size is used. Considering each page contains x page * table descriptors, the total extra size for page tables (for extra * N pages) will be: N/x+N/x^2+N/x^3+... which is definitely smaller * than N/x*2. */ nr_pages += (nr_pages + extra_mem_pages) / PTES_PER_MIN_PAGE * 2; /* Account for the number of pages needed by ucall. */ nr_pages += ucall_nr_pages_required(page_size); return vm_adjust_num_guest_pages(mode, nr_pages); } struct kvm_vm *__vm_create(enum vm_guest_mode mode, uint32_t nr_runnable_vcpus, uint64_t nr_extra_pages) { uint64_t nr_pages = vm_nr_pages_required(mode, nr_runnable_vcpus, nr_extra_pages); struct userspace_mem_region *slot0; struct kvm_vm *vm; int i; pr_debug("%s: mode='%s' pages='%ld'\n", __func__, vm_guest_mode_string(mode), nr_pages); vm = ____vm_create(mode); vm_userspace_mem_region_add(vm, VM_MEM_SRC_ANONYMOUS, 0, 0, nr_pages, 0); for (i = 0; i < NR_MEM_REGIONS; i++) vm->memslots[i] = 0; kvm_vm_elf_load(vm, program_invocation_name); /* * TODO: Add proper defines to protect the library's memslots, and then * carve out memslot1 for the ucall MMIO address. KVM treats writes to * read-only memslots as MMIO, and creating a read-only memslot for the * MMIO region would prevent silently clobbering the MMIO region. */ slot0 = memslot2region(vm, 0); ucall_init(vm, slot0->region.guest_phys_addr + slot0->region.memory_size); kvm_arch_vm_post_create(vm); return vm; } /* * VM Create with customized parameters * * Input Args: * mode - VM Mode (e.g. VM_MODE_P52V48_4K) * nr_vcpus - VCPU count * extra_mem_pages - Non-slot0 physical memory total size * guest_code - Guest entry point * vcpuids - VCPU IDs * * Output Args: None * * Return: * Pointer to opaque structure that describes the created VM. * * Creates a VM with the mode specified by mode (e.g. VM_MODE_P52V48_4K). * extra_mem_pages is only used to calculate the maximum page table size, * no real memory allocation for non-slot0 memory in this function. */ struct kvm_vm *__vm_create_with_vcpus(enum vm_guest_mode mode, uint32_t nr_vcpus, uint64_t extra_mem_pages, void *guest_code, struct kvm_vcpu *vcpus[]) { struct kvm_vm *vm; int i; TEST_ASSERT(!nr_vcpus || vcpus, "Must provide vCPU array"); vm = __vm_create(mode, nr_vcpus, extra_mem_pages); for (i = 0; i < nr_vcpus; ++i) vcpus[i] = vm_vcpu_add(vm, i, guest_code); return vm; } struct kvm_vm *__vm_create_with_one_vcpu(struct kvm_vcpu **vcpu, uint64_t extra_mem_pages, void *guest_code) { struct kvm_vcpu *vcpus[1]; struct kvm_vm *vm; vm = __vm_create_with_vcpus(VM_MODE_DEFAULT, 1, extra_mem_pages, guest_code, vcpus); *vcpu = vcpus[0]; return vm; } /* * VM Restart * * Input Args: * vm - VM that has been released before * * Output Args: None * * Reopens the file descriptors associated to the VM and reinstates the * global state, such as the irqchip and the memory regions that are mapped * into the guest. */ void kvm_vm_restart(struct kvm_vm *vmp) { int ctr; struct userspace_mem_region *region; vm_open(vmp); if (vmp->has_irqchip) vm_create_irqchip(vmp); hash_for_each(vmp->regions.slot_hash, ctr, region, slot_node) { int ret = ioctl(vmp->fd, KVM_SET_USER_MEMORY_REGION, ®ion->region); TEST_ASSERT(ret == 0, "KVM_SET_USER_MEMORY_REGION IOCTL failed,\n" " rc: %i errno: %i\n" " slot: %u flags: 0x%x\n" " guest_phys_addr: 0x%llx size: 0x%llx", ret, errno, region->region.slot, region->region.flags, region->region.guest_phys_addr, region->region.memory_size); } } __weak struct kvm_vcpu *vm_arch_vcpu_recreate(struct kvm_vm *vm, uint32_t vcpu_id) { return __vm_vcpu_add(vm, vcpu_id); } struct kvm_vcpu *vm_recreate_with_one_vcpu(struct kvm_vm *vm) { kvm_vm_restart(vm); return vm_vcpu_recreate(vm, 0); } void kvm_pin_this_task_to_pcpu(uint32_t pcpu) { cpu_set_t mask; int r; CPU_ZERO(&mask); CPU_SET(pcpu, &mask); r = sched_setaffinity(0, sizeof(mask), &mask); TEST_ASSERT(!r, "sched_setaffinity() failed for pCPU '%u'.\n", pcpu); } static uint32_t parse_pcpu(const char *cpu_str, const cpu_set_t *allowed_mask) { uint32_t pcpu = atoi_non_negative("CPU number", cpu_str); TEST_ASSERT(CPU_ISSET(pcpu, allowed_mask), "Not allowed to run on pCPU '%d', check cgroups?\n", pcpu); return pcpu; } void kvm_print_vcpu_pinning_help(void) { const char *name = program_invocation_name; printf(" -c: Pin tasks to physical CPUs. Takes a list of comma separated\n" " values (target pCPU), one for each vCPU, plus an optional\n" " entry for the main application task (specified via entry\n" " <nr_vcpus + 1>). If used, entries must be provided for all\n" " vCPUs, i.e. pinning vCPUs is all or nothing.\n\n" " E.g. to create 3 vCPUs, pin vCPU0=>pCPU22, vCPU1=>pCPU23,\n" " vCPU2=>pCPU24, and pin the application task to pCPU50:\n\n" " %s -v 3 -c 22,23,24,50\n\n" " To leave the application task unpinned, drop the final entry:\n\n" " %s -v 3 -c 22,23,24\n\n" " (default: no pinning)\n", name, name); } void kvm_parse_vcpu_pinning(const char *pcpus_string, uint32_t vcpu_to_pcpu[], int nr_vcpus) { cpu_set_t allowed_mask; char *cpu, *cpu_list; char delim[2] = ","; int i, r; cpu_list = strdup(pcpus_string); TEST_ASSERT(cpu_list, "strdup() allocation failed.\n"); r = sched_getaffinity(0, sizeof(allowed_mask), &allowed_mask); TEST_ASSERT(!r, "sched_getaffinity() failed"); cpu = strtok(cpu_list, delim); /* 1. Get all pcpus for vcpus. */ for (i = 0; i < nr_vcpus; i++) { TEST_ASSERT(cpu, "pCPU not provided for vCPU '%d'\n", i); vcpu_to_pcpu[i] = parse_pcpu(cpu, &allowed_mask); cpu = strtok(NULL, delim); } /* 2. Check if the main worker needs to be pinned. */ if (cpu) { kvm_pin_this_task_to_pcpu(parse_pcpu(cpu, &allowed_mask)); cpu = strtok(NULL, delim); } TEST_ASSERT(!cpu, "pCPU list contains trailing garbage characters '%s'", cpu); free(cpu_list); } /* * Userspace Memory Region Find * * Input Args: * vm - Virtual Machine * start - Starting VM physical address * end - Ending VM physical address, inclusive. * * Output Args: None * * Return: * Pointer to overlapping region, NULL if no such region. * * Searches for a region with any physical memory that overlaps with * any portion of the guest physical addresses from start to end * inclusive. If multiple overlapping regions exist, a pointer to any * of the regions is returned. Null is returned only when no overlapping * region exists. */ static struct userspace_mem_region * userspace_mem_region_find(struct kvm_vm *vm, uint64_t start, uint64_t end) { struct rb_node *node; for (node = vm->regions.gpa_tree.rb_node; node; ) { struct userspace_mem_region *region = container_of(node, struct userspace_mem_region, gpa_node); uint64_t existing_start = region->region.guest_phys_addr; uint64_t existing_end = region->region.guest_phys_addr + region->region.memory_size - 1; if (start <= existing_end && end >= existing_start) return region; if (start < existing_start) node = node->rb_left; else node = node->rb_right; } return NULL; } /* * KVM Userspace Memory Region Find * * Input Args: * vm - Virtual Machine * start - Starting VM physical address * end - Ending VM physical address, inclusive. * * Output Args: None * * Return: * Pointer to overlapping region, NULL if no such region. * * Public interface to userspace_mem_region_find. Allows tests to look up * the memslot datastructure for a given range of guest physical memory. */ struct kvm_userspace_memory_region * kvm_userspace_memory_region_find(struct kvm_vm *vm, uint64_t start, uint64_t end) { struct userspace_mem_region *region; region = userspace_mem_region_find(vm, start, end); if (!region) return NULL; return ®ion->region; } __weak void vcpu_arch_free(struct kvm_vcpu *vcpu) { } /* * VM VCPU Remove * * Input Args: * vcpu - VCPU to remove * * Output Args: None * * Return: None, TEST_ASSERT failures for all error conditions * * Removes a vCPU from a VM and frees its resources. */ static void vm_vcpu_rm(struct kvm_vm *vm, struct kvm_vcpu *vcpu) { int ret; if (vcpu->dirty_gfns) { ret = munmap(vcpu->dirty_gfns, vm->dirty_ring_size); TEST_ASSERT(!ret, __KVM_SYSCALL_ERROR("munmap()", ret)); vcpu->dirty_gfns = NULL; } ret = munmap(vcpu->run, vcpu_mmap_sz()); TEST_ASSERT(!ret, __KVM_SYSCALL_ERROR("munmap()", ret)); ret = close(vcpu->fd); TEST_ASSERT(!ret, __KVM_SYSCALL_ERROR("close()", ret)); list_del(&vcpu->list); vcpu_arch_free(vcpu); free(vcpu); } void kvm_vm_release(struct kvm_vm *vmp) { struct kvm_vcpu *vcpu, *tmp; int ret; list_for_each_entry_safe(vcpu, tmp, &vmp->vcpus, list) vm_vcpu_rm(vmp, vcpu); ret = close(vmp->fd); TEST_ASSERT(!ret, __KVM_SYSCALL_ERROR("close()", ret)); ret = close(vmp->kvm_fd); TEST_ASSERT(!ret, __KVM_SYSCALL_ERROR("close()", ret)); } static void __vm_mem_region_delete(struct kvm_vm *vm, struct userspace_mem_region *region, bool unlink) { int ret; if (unlink) { rb_erase(®ion->gpa_node, &vm->regions.gpa_tree); rb_erase(®ion->hva_node, &vm->regions.hva_tree); hash_del(®ion->slot_node); } region->region.memory_size = 0; vm_ioctl(vm, KVM_SET_USER_MEMORY_REGION, ®ion->region); sparsebit_free(®ion->unused_phy_pages); ret = munmap(region->mmap_start, region->mmap_size); TEST_ASSERT(!ret, __KVM_SYSCALL_ERROR("munmap()", ret)); if (region->fd >= 0) { /* There's an extra map when using shared memory. */ ret = munmap(region->mmap_alias, region->mmap_size); TEST_ASSERT(!ret, __KVM_SYSCALL_ERROR("munmap()", ret)); close(region->fd); } free(region); } /* * Destroys and frees the VM pointed to by vmp. */ void kvm_vm_free(struct kvm_vm *vmp) { int ctr; struct hlist_node *node; struct userspace_mem_region *region; if (vmp == NULL) return; /* Free cached stats metadata and close FD */ if (vmp->stats_fd) { free(vmp->stats_desc); close(vmp->stats_fd); } /* Free userspace_mem_regions. */ hash_for_each_safe(vmp->regions.slot_hash, ctr, node, region, slot_node) __vm_mem_region_delete(vmp, region, false); /* Free sparsebit arrays. */ sparsebit_free(&vmp->vpages_valid); sparsebit_free(&vmp->vpages_mapped); kvm_vm_release(vmp); /* Free the structure describing the VM. */ free(vmp); } int kvm_memfd_alloc(size_t size, bool hugepages) { int memfd_flags = MFD_CLOEXEC; int fd, r; if (hugepages) memfd_flags |= MFD_HUGETLB; fd = memfd_create("kvm_selftest", memfd_flags); TEST_ASSERT(fd != -1, __KVM_SYSCALL_ERROR("memfd_create()", fd)); r = ftruncate(fd, size); TEST_ASSERT(!r, __KVM_SYSCALL_ERROR("ftruncate()", r)); r = fallocate(fd, FALLOC_FL_PUNCH_HOLE | FALLOC_FL_KEEP_SIZE, 0, size); TEST_ASSERT(!r, __KVM_SYSCALL_ERROR("fallocate()", r)); return fd; } /* * Memory Compare, host virtual to guest virtual * * Input Args: * hva - Starting host virtual address * vm - Virtual Machine * gva - Starting guest virtual address * len - number of bytes to compare * * Output Args: None * * Input/Output Args: None * * Return: * Returns 0 if the bytes starting at hva for a length of len * are equal the guest virtual bytes starting at gva. Returns * a value < 0, if bytes at hva are less than those at gva. * Otherwise a value > 0 is returned. * * Compares the bytes starting at the host virtual address hva, for * a length of len, to the guest bytes starting at the guest virtual * address given by gva. */ int kvm_memcmp_hva_gva(void *hva, struct kvm_vm *vm, vm_vaddr_t gva, size_t len) { size_t amt; /* * Compare a batch of bytes until either a match is found * or all the bytes have been compared. */ for (uintptr_t offset = 0; offset < len; offset += amt) { uintptr_t ptr1 = (uintptr_t)hva + offset; /* * Determine host address for guest virtual address * at offset. */ uintptr_t ptr2 = (uintptr_t)addr_gva2hva(vm, gva + offset); /* * Determine amount to compare on this pass. * Don't allow the comparsion to cross a page boundary. */ amt = len - offset; if ((ptr1 >> vm->page_shift) != ((ptr1 + amt) >> vm->page_shift)) amt = vm->page_size - (ptr1 % vm->page_size); if ((ptr2 >> vm->page_shift) != ((ptr2 + amt) >> vm->page_shift)) amt = vm->page_size - (ptr2 % vm->page_size); assert((ptr1 >> vm->page_shift) == ((ptr1 + amt - 1) >> vm->page_shift)); assert((ptr2 >> vm->page_shift) == ((ptr2 + amt - 1) >> vm->page_shift)); /* * Perform the comparison. If there is a difference * return that result to the caller, otherwise need * to continue on looking for a mismatch. */ int ret = memcmp((void *)ptr1, (void *)ptr2, amt); if (ret != 0) return ret; } /* * No mismatch found. Let the caller know the two memory * areas are equal. */ return 0; } static void vm_userspace_mem_region_gpa_insert(struct rb_root *gpa_tree, struct userspace_mem_region *region) { struct rb_node **cur, *parent; for (cur = &gpa_tree->rb_node, parent = NULL; *cur; ) { struct userspace_mem_region *cregion; cregion = container_of(*cur, typeof(*cregion), gpa_node); parent = *cur; if (region->region.guest_phys_addr < cregion->region.guest_phys_addr) cur = &(*cur)->rb_left; else { TEST_ASSERT(region->region.guest_phys_addr != cregion->region.guest_phys_addr, "Duplicate GPA in region tree"); cur = &(*cur)->rb_right; } } rb_link_node(®ion->gpa_node, parent, cur); rb_insert_color(®ion->gpa_node, gpa_tree); } static void vm_userspace_mem_region_hva_insert(struct rb_root *hva_tree, struct userspace_mem_region *region) { struct rb_node **cur, *parent; for (cur = &hva_tree->rb_node, parent = NULL; *cur; ) { struct userspace_mem_region *cregion; cregion = container_of(*cur, typeof(*cregion), hva_node); parent = *cur; if (region->host_mem < cregion->host_mem) cur = &(*cur)->rb_left; else { TEST_ASSERT(region->host_mem != cregion->host_mem, "Duplicate HVA in region tree"); cur = &(*cur)->rb_right; } } rb_link_node(®ion->hva_node, parent, cur); rb_insert_color(®ion->hva_node, hva_tree); } int __vm_set_user_memory_region(struct kvm_vm *vm, uint32_t slot, uint32_t flags, uint64_t gpa, uint64_t size, void *hva) { struct kvm_userspace_memory_region region = { .slot = slot, .flags = flags, .guest_phys_addr = gpa, .memory_size = size, .userspace_addr = (uintptr_t)hva, }; return ioctl(vm->fd, KVM_SET_USER_MEMORY_REGION, ®ion); } void vm_set_user_memory_region(struct kvm_vm *vm, uint32_t slot, uint32_t flags, uint64_t gpa, uint64_t size, void *hva) { int ret = __vm_set_user_memory_region(vm, slot, flags, gpa, size, hva); TEST_ASSERT(!ret, "KVM_SET_USER_MEMORY_REGION failed, errno = %d (%s)", errno, strerror(errno)); } /* * VM Userspace Memory Region Add * * Input Args: * vm - Virtual Machine * src_type - Storage source for this region. * NULL to use anonymous memory. * guest_paddr - Starting guest physical address * slot - KVM region slot * npages - Number of physical pages * flags - KVM memory region flags (e.g. KVM_MEM_LOG_DIRTY_PAGES) * * Output Args: None * * Return: None * * Allocates a memory area of the number of pages specified by npages * and maps it to the VM specified by vm, at a starting physical address * given by guest_paddr. The region is created with a KVM region slot * given by slot, which must be unique and < KVM_MEM_SLOTS_NUM. The * region is created with the flags given by flags. */ void vm_userspace_mem_region_add(struct kvm_vm *vm, enum vm_mem_backing_src_type src_type, uint64_t guest_paddr, uint32_t slot, uint64_t npages, uint32_t flags) { int ret; struct userspace_mem_region *region; size_t backing_src_pagesz = get_backing_src_pagesz(src_type); size_t alignment; TEST_ASSERT(vm_adjust_num_guest_pages(vm->mode, npages) == npages, "Number of guest pages is not compatible with the host. " "Try npages=%d", vm_adjust_num_guest_pages(vm->mode, npages)); TEST_ASSERT((guest_paddr % vm->page_size) == 0, "Guest physical " "address not on a page boundary.\n" " guest_paddr: 0x%lx vm->page_size: 0x%x", guest_paddr, vm->page_size); TEST_ASSERT((((guest_paddr >> vm->page_shift) + npages) - 1) <= vm->max_gfn, "Physical range beyond maximum " "supported physical address,\n" " guest_paddr: 0x%lx npages: 0x%lx\n" " vm->max_gfn: 0x%lx vm->page_size: 0x%x", guest_paddr, npages, vm->max_gfn, vm->page_size); /* * Confirm a mem region with an overlapping address doesn't * already exist. */ region = (struct userspace_mem_region *) userspace_mem_region_find( vm, guest_paddr, (guest_paddr + npages * vm->page_size) - 1); if (region != NULL) TEST_FAIL("overlapping userspace_mem_region already " "exists\n" " requested guest_paddr: 0x%lx npages: 0x%lx " "page_size: 0x%x\n" " existing guest_paddr: 0x%lx size: 0x%lx", guest_paddr, npages, vm->page_size, (uint64_t) region->region.guest_phys_addr, (uint64_t) region->region.memory_size); /* Confirm no region with the requested slot already exists. */ hash_for_each_possible(vm->regions.slot_hash, region, slot_node, slot) { if (region->region.slot != slot) continue; TEST_FAIL("A mem region with the requested slot " "already exists.\n" " requested slot: %u paddr: 0x%lx npages: 0x%lx\n" " existing slot: %u paddr: 0x%lx size: 0x%lx", slot, guest_paddr, npages, region->region.slot, (uint64_t) region->region.guest_phys_addr, (uint64_t) region->region.memory_size); } /* Allocate and initialize new mem region structure. */ region = calloc(1, sizeof(*region)); TEST_ASSERT(region != NULL, "Insufficient Memory"); region->mmap_size = npages * vm->page_size; #ifdef __s390x__ /* On s390x, the host address must be aligned to 1M (due to PGSTEs) */ alignment = 0x100000; #else alignment = 1; #endif /* * When using THP mmap is not guaranteed to returned a hugepage aligned * address so we have to pad the mmap. Padding is not needed for HugeTLB * because mmap will always return an address aligned to the HugeTLB * page size. */ if (src_type == VM_MEM_SRC_ANONYMOUS_THP) alignment = max(backing_src_pagesz, alignment); TEST_ASSERT_EQ(guest_paddr, align_up(guest_paddr, backing_src_pagesz)); /* Add enough memory to align up if necessary */ if (alignment > 1) region->mmap_size += alignment; region->fd = -1; if (backing_src_is_shared(src_type)) region->fd = kvm_memfd_alloc(region->mmap_size, src_type == VM_MEM_SRC_SHARED_HUGETLB); region->mmap_start = mmap(NULL, region->mmap_size, PROT_READ | PROT_WRITE, vm_mem_backing_src_alias(src_type)->flag, region->fd, 0); TEST_ASSERT(region->mmap_start != MAP_FAILED, __KVM_SYSCALL_ERROR("mmap()", (int)(unsigned long)MAP_FAILED)); TEST_ASSERT(!is_backing_src_hugetlb(src_type) || region->mmap_start == align_ptr_up(region->mmap_start, backing_src_pagesz), "mmap_start %p is not aligned to HugeTLB page size 0x%lx", region->mmap_start, backing_src_pagesz); /* Align host address */ region->host_mem = align_ptr_up(region->mmap_start, alignment); /* As needed perform madvise */ if ((src_type == VM_MEM_SRC_ANONYMOUS || src_type == VM_MEM_SRC_ANONYMOUS_THP) && thp_configured()) { ret = madvise(region->host_mem, npages * vm->page_size, src_type == VM_MEM_SRC_ANONYMOUS ? MADV_NOHUGEPAGE : MADV_HUGEPAGE); TEST_ASSERT(ret == 0, "madvise failed, addr: %p length: 0x%lx src_type: %s", region->host_mem, npages * vm->page_size, vm_mem_backing_src_alias(src_type)->name); } region->backing_src_type = src_type; region->unused_phy_pages = sparsebit_alloc(); sparsebit_set_num(region->unused_phy_pages, guest_paddr >> vm->page_shift, npages); region->region.slot = slot; region->region.flags = flags; region->region.guest_phys_addr = guest_paddr; region->region.memory_size = npages * vm->page_size; region->region.userspace_addr = (uintptr_t) region->host_mem; ret = __vm_ioctl(vm, KVM_SET_USER_MEMORY_REGION, ®ion->region); TEST_ASSERT(ret == 0, "KVM_SET_USER_MEMORY_REGION IOCTL failed,\n" " rc: %i errno: %i\n" " slot: %u flags: 0x%x\n" " guest_phys_addr: 0x%lx size: 0x%lx", ret, errno, slot, flags, guest_paddr, (uint64_t) region->region.memory_size); /* Add to quick lookup data structures */ vm_userspace_mem_region_gpa_insert(&vm->regions.gpa_tree, region); vm_userspace_mem_region_hva_insert(&vm->regions.hva_tree, region); hash_add(vm->regions.slot_hash, ®ion->slot_node, slot); /* If shared memory, create an alias. */ if (region->fd >= 0) { region->mmap_alias = mmap(NULL, region->mmap_size, PROT_READ | PROT_WRITE, vm_mem_backing_src_alias(src_type)->flag, region->fd, 0); TEST_ASSERT(region->mmap_alias != MAP_FAILED, __KVM_SYSCALL_ERROR("mmap()", (int)(unsigned long)MAP_FAILED)); /* Align host alias address */ region->host_alias = align_ptr_up(region->mmap_alias, alignment); } } /* * Memslot to region * * Input Args: * vm - Virtual Machine * memslot - KVM memory slot ID * * Output Args: None * * Return: * Pointer to memory region structure that describe memory region * using kvm memory slot ID given by memslot. TEST_ASSERT failure * on error (e.g. currently no memory region using memslot as a KVM * memory slot ID). */ struct userspace_mem_region * memslot2region(struct kvm_vm *vm, uint32_t memslot) { struct userspace_mem_region *region; hash_for_each_possible(vm->regions.slot_hash, region, slot_node, memslot) if (region->region.slot == memslot) return region; fprintf(stderr, "No mem region with the requested slot found,\n" " requested slot: %u\n", memslot); fputs("---- vm dump ----\n", stderr); vm_dump(stderr, vm, 2); TEST_FAIL("Mem region not found"); return NULL; } /* * VM Memory Region Flags Set * * Input Args: * vm - Virtual Machine * flags - Starting guest physical address * * Output Args: None * * Return: None * * Sets the flags of the memory region specified by the value of slot, * to the values given by flags. */ void vm_mem_region_set_flags(struct kvm_vm *vm, uint32_t slot, uint32_t flags) { int ret; struct userspace_mem_region *region; region = memslot2region(vm, slot); region->region.flags = flags; ret = __vm_ioctl(vm, KVM_SET_USER_MEMORY_REGION, ®ion->region); TEST_ASSERT(ret == 0, "KVM_SET_USER_MEMORY_REGION IOCTL failed,\n" " rc: %i errno: %i slot: %u flags: 0x%x", ret, errno, slot, flags); } /* * VM Memory Region Move * * Input Args: * vm - Virtual Machine * slot - Slot of the memory region to move * new_gpa - Starting guest physical address * * Output Args: None * * Return: None * * Change the gpa of a memory region. */ void vm_mem_region_move(struct kvm_vm *vm, uint32_t slot, uint64_t new_gpa) { struct userspace_mem_region *region; int ret; region = memslot2region(vm, slot); region->region.guest_phys_addr = new_gpa; ret = __vm_ioctl(vm, KVM_SET_USER_MEMORY_REGION, ®ion->region); TEST_ASSERT(!ret, "KVM_SET_USER_MEMORY_REGION failed\n" "ret: %i errno: %i slot: %u new_gpa: 0x%lx", ret, errno, slot, new_gpa); } /* * VM Memory Region Delete * * Input Args: * vm - Virtual Machine * slot - Slot of the memory region to delete * * Output Args: None * * Return: None * * Delete a memory region. */ void vm_mem_region_delete(struct kvm_vm *vm, uint32_t slot) { __vm_mem_region_delete(vm, memslot2region(vm, slot), true); } /* Returns the size of a vCPU's kvm_run structure. */ static int vcpu_mmap_sz(void) { int dev_fd, ret; dev_fd = open_kvm_dev_path_or_exit(); ret = ioctl(dev_fd, KVM_GET_VCPU_MMAP_SIZE, NULL); TEST_ASSERT(ret >= sizeof(struct kvm_run), KVM_IOCTL_ERROR(KVM_GET_VCPU_MMAP_SIZE, ret)); close(dev_fd); return ret; } static bool vcpu_exists(struct kvm_vm *vm, uint32_t vcpu_id) { struct kvm_vcpu *vcpu; list_for_each_entry(vcpu, &vm->vcpus, list) { if (vcpu->id == vcpu_id) return true; } return false; } /* * Adds a virtual CPU to the VM specified by vm with the ID given by vcpu_id. * No additional vCPU setup is done. Returns the vCPU. */ struct kvm_vcpu *__vm_vcpu_add(struct kvm_vm *vm, uint32_t vcpu_id) { struct kvm_vcpu *vcpu; /* Confirm a vcpu with the specified id doesn't already exist. */ TEST_ASSERT(!vcpu_exists(vm, vcpu_id), "vCPU%d already exists\n", vcpu_id); /* Allocate and initialize new vcpu structure. */ vcpu = calloc(1, sizeof(*vcpu)); TEST_ASSERT(vcpu != NULL, "Insufficient Memory"); vcpu->vm = vm; vcpu->id = vcpu_id; vcpu->fd = __vm_ioctl(vm, KVM_CREATE_VCPU, (void *)(unsigned long)vcpu_id); TEST_ASSERT(vcpu->fd >= 0, KVM_IOCTL_ERROR(KVM_CREATE_VCPU, vcpu->fd)); TEST_ASSERT(vcpu_mmap_sz() >= sizeof(*vcpu->run), "vcpu mmap size " "smaller than expected, vcpu_mmap_sz: %i expected_min: %zi", vcpu_mmap_sz(), sizeof(*vcpu->run)); vcpu->run = (struct kvm_run *) mmap(NULL, vcpu_mmap_sz(), PROT_READ | PROT_WRITE, MAP_SHARED, vcpu->fd, 0); TEST_ASSERT(vcpu->run != MAP_FAILED, __KVM_SYSCALL_ERROR("mmap()", (int)(unsigned long)MAP_FAILED)); /* Add to linked-list of VCPUs. */ list_add(&vcpu->list, &vm->vcpus); return vcpu; } /* * VM Virtual Address Unused Gap * * Input Args: * vm - Virtual Machine * sz - Size (bytes) * vaddr_min - Minimum Virtual Address * * Output Args: None * * Return: * Lowest virtual address at or below vaddr_min, with at least * sz unused bytes. TEST_ASSERT failure if no area of at least * size sz is available. * * Within the VM specified by vm, locates the lowest starting virtual * address >= vaddr_min, that has at least sz unallocated bytes. A * TEST_ASSERT failure occurs for invalid input or no area of at least * sz unallocated bytes >= vaddr_min is available. */ vm_vaddr_t vm_vaddr_unused_gap(struct kvm_vm *vm, size_t sz, vm_vaddr_t vaddr_min) { uint64_t pages = (sz + vm->page_size - 1) >> vm->page_shift; /* Determine lowest permitted virtual page index. */ uint64_t pgidx_start = (vaddr_min + vm->page_size - 1) >> vm->page_shift; if ((pgidx_start * vm->page_size) < vaddr_min) goto no_va_found; /* Loop over section with enough valid virtual page indexes. */ if (!sparsebit_is_set_num(vm->vpages_valid, pgidx_start, pages)) pgidx_start = sparsebit_next_set_num(vm->vpages_valid, pgidx_start, pages); do { /* * Are there enough unused virtual pages available at * the currently proposed starting virtual page index. * If not, adjust proposed starting index to next * possible. */ if (sparsebit_is_clear_num(vm->vpages_mapped, pgidx_start, pages)) goto va_found; pgidx_start = sparsebit_next_clear_num(vm->vpages_mapped, pgidx_start, pages); if (pgidx_start == 0) goto no_va_found; /* * If needed, adjust proposed starting virtual address, * to next range of valid virtual addresses. */ if (!sparsebit_is_set_num(vm->vpages_valid, pgidx_start, pages)) { pgidx_start = sparsebit_next_set_num( vm->vpages_valid, pgidx_start, pages); if (pgidx_start == 0) goto no_va_found; } } while (pgidx_start != 0); no_va_found: TEST_FAIL("No vaddr of specified pages available, pages: 0x%lx", pages); /* NOT REACHED */ return -1; va_found: TEST_ASSERT(sparsebit_is_set_num(vm->vpages_valid, pgidx_start, pages), "Unexpected, invalid virtual page index range,\n" " pgidx_start: 0x%lx\n" " pages: 0x%lx", pgidx_start, pages); TEST_ASSERT(sparsebit_is_clear_num(vm->vpages_mapped, pgidx_start, pages), "Unexpected, pages already mapped,\n" " pgidx_start: 0x%lx\n" " pages: 0x%lx", pgidx_start, pages); return pgidx_start * vm->page_size; } vm_vaddr_t __vm_vaddr_alloc(struct kvm_vm *vm, size_t sz, vm_vaddr_t vaddr_min, enum kvm_mem_region_type type) { uint64_t pages = (sz >> vm->page_shift) + ((sz % vm->page_size) != 0); virt_pgd_alloc(vm); vm_paddr_t paddr = vm_phy_pages_alloc(vm, pages, KVM_UTIL_MIN_PFN * vm->page_size, vm->memslots[type]); /* * Find an unused range of virtual page addresses of at least * pages in length. */ vm_vaddr_t vaddr_start = vm_vaddr_unused_gap(vm, sz, vaddr_min); /* Map the virtual pages. */ for (vm_vaddr_t vaddr = vaddr_start; pages > 0; pages--, vaddr += vm->page_size, paddr += vm->page_size) { virt_pg_map(vm, vaddr, paddr); sparsebit_set(vm->vpages_mapped, vaddr >> vm->page_shift); } return vaddr_start; } /* * VM Virtual Address Allocate * * Input Args: * vm - Virtual Machine * sz - Size in bytes * vaddr_min - Minimum starting virtual address * * Output Args: None * * Return: * Starting guest virtual address * * Allocates at least sz bytes within the virtual address space of the vm * given by vm. The allocated bytes are mapped to a virtual address >= * the address given by vaddr_min. Note that each allocation uses a * a unique set of pages, with the minimum real allocation being at least * a page. The allocated physical space comes from the TEST_DATA memory region. */ vm_vaddr_t vm_vaddr_alloc(struct kvm_vm *vm, size_t sz, vm_vaddr_t vaddr_min) { return __vm_vaddr_alloc(vm, sz, vaddr_min, MEM_REGION_TEST_DATA); } /* * VM Virtual Address Allocate Pages * * Input Args: * vm - Virtual Machine * * Output Args: None * * Return: * Starting guest virtual address * * Allocates at least N system pages worth of bytes within the virtual address * space of the vm. */ vm_vaddr_t vm_vaddr_alloc_pages(struct kvm_vm *vm, int nr_pages) { return vm_vaddr_alloc(vm, nr_pages * getpagesize(), KVM_UTIL_MIN_VADDR); } vm_vaddr_t __vm_vaddr_alloc_page(struct kvm_vm *vm, enum kvm_mem_region_type type) { return __vm_vaddr_alloc(vm, getpagesize(), KVM_UTIL_MIN_VADDR, type); } /* * VM Virtual Address Allocate Page * * Input Args: * vm - Virtual Machine * * Output Args: None * * Return: * Starting guest virtual address * * Allocates at least one system page worth of bytes within the virtual address * space of the vm. */ vm_vaddr_t vm_vaddr_alloc_page(struct kvm_vm *vm) { return vm_vaddr_alloc_pages(vm, 1); } /* * Map a range of VM virtual address to the VM's physical address * * Input Args: * vm - Virtual Machine * vaddr - Virtuall address to map * paddr - VM Physical Address * npages - The number of pages to map * * Output Args: None * * Return: None * * Within the VM given by @vm, creates a virtual translation for * @npages starting at @vaddr to the page range starting at @paddr. */ void virt_map(struct kvm_vm *vm, uint64_t vaddr, uint64_t paddr, unsigned int npages) { size_t page_size = vm->page_size; size_t size = npages * page_size; TEST_ASSERT(vaddr + size > vaddr, "Vaddr overflow"); TEST_ASSERT(paddr + size > paddr, "Paddr overflow"); while (npages--) { virt_pg_map(vm, vaddr, paddr); sparsebit_set(vm->vpages_mapped, vaddr >> vm->page_shift); vaddr += page_size; paddr += page_size; } } /* * Address VM Physical to Host Virtual * * Input Args: * vm - Virtual Machine * gpa - VM physical address * * Output Args: None * * Return: * Equivalent host virtual address * * Locates the memory region containing the VM physical address given * by gpa, within the VM given by vm. When found, the host virtual * address providing the memory to the vm physical address is returned. * A TEST_ASSERT failure occurs if no region containing gpa exists. */ void *addr_gpa2hva(struct kvm_vm *vm, vm_paddr_t gpa) { struct userspace_mem_region *region; region = userspace_mem_region_find(vm, gpa, gpa); if (!region) { TEST_FAIL("No vm physical memory at 0x%lx", gpa); return NULL; } return (void *)((uintptr_t)region->host_mem + (gpa - region->region.guest_phys_addr)); } /* * Address Host Virtual to VM Physical * * Input Args: * vm - Virtual Machine * hva - Host virtual address * * Output Args: None * * Return: * Equivalent VM physical address * * Locates the memory region containing the host virtual address given * by hva, within the VM given by vm. When found, the equivalent * VM physical address is returned. A TEST_ASSERT failure occurs if no * region containing hva exists. */ vm_paddr_t addr_hva2gpa(struct kvm_vm *vm, void *hva) { struct rb_node *node; for (node = vm->regions.hva_tree.rb_node; node; ) { struct userspace_mem_region *region = container_of(node, struct userspace_mem_region, hva_node); if (hva >= region->host_mem) { if (hva <= (region->host_mem + region->region.memory_size - 1)) return (vm_paddr_t)((uintptr_t) region->region.guest_phys_addr + (hva - (uintptr_t)region->host_mem)); node = node->rb_right; } else node = node->rb_left; } TEST_FAIL("No mapping to a guest physical address, hva: %p", hva); return -1; } /* * Address VM physical to Host Virtual *alias*. * * Input Args: * vm - Virtual Machine * gpa - VM physical address * * Output Args: None * * Return: * Equivalent address within the host virtual *alias* area, or NULL * (without failing the test) if the guest memory is not shared (so * no alias exists). * * Create a writable, shared virtual=>physical alias for the specific GPA. * The primary use case is to allow the host selftest to manipulate guest * memory without mapping said memory in the guest's address space. And, for * userfaultfd-based demand paging, to do so without triggering userfaults. */ void *addr_gpa2alias(struct kvm_vm *vm, vm_paddr_t gpa) { struct userspace_mem_region *region; uintptr_t offset; region = userspace_mem_region_find(vm, gpa, gpa); if (!region) return NULL; if (!region->host_alias) return NULL; offset = gpa - region->region.guest_phys_addr; return (void *) ((uintptr_t) region->host_alias + offset); } /* Create an interrupt controller chip for the specified VM. */ void vm_create_irqchip(struct kvm_vm *vm) { vm_ioctl(vm, KVM_CREATE_IRQCHIP, NULL); vm->has_irqchip = true; } int _vcpu_run(struct kvm_vcpu *vcpu) { int rc; do { rc = __vcpu_run(vcpu); } while (rc == -1 && errno == EINTR); assert_on_unhandled_exception(vcpu); return rc; } /* * Invoke KVM_RUN on a vCPU until KVM returns something other than -EINTR. * Assert if the KVM returns an error (other than -EINTR). */ void vcpu_run(struct kvm_vcpu *vcpu) { int ret = _vcpu_run(vcpu); TEST_ASSERT(!ret, KVM_IOCTL_ERROR(KVM_RUN, ret)); } void vcpu_run_complete_io(struct kvm_vcpu *vcpu) { int ret; vcpu->run->immediate_exit = 1; ret = __vcpu_run(vcpu); vcpu->run->immediate_exit = 0; TEST_ASSERT(ret == -1 && errno == EINTR, "KVM_RUN IOCTL didn't exit immediately, rc: %i, errno: %i", ret, errno); } /* * Get the list of guest registers which are supported for * KVM_GET_ONE_REG/KVM_SET_ONE_REG ioctls. Returns a kvm_reg_list pointer, * it is the caller's responsibility to free the list. */ struct kvm_reg_list *vcpu_get_reg_list(struct kvm_vcpu *vcpu) { struct kvm_reg_list reg_list_n = { .n = 0 }, *reg_list; int ret; ret = __vcpu_ioctl(vcpu, KVM_GET_REG_LIST, ®_list_n); TEST_ASSERT(ret == -1 && errno == E2BIG, "KVM_GET_REG_LIST n=0"); reg_list = calloc(1, sizeof(*reg_list) + reg_list_n.n * sizeof(__u64)); reg_list->n = reg_list_n.n; vcpu_ioctl(vcpu, KVM_GET_REG_LIST, reg_list); return reg_list; } void *vcpu_map_dirty_ring(struct kvm_vcpu *vcpu) { uint32_t page_size = getpagesize(); uint32_t size = vcpu->vm->dirty_ring_size; TEST_ASSERT(size > 0, "Should enable dirty ring first"); if (!vcpu->dirty_gfns) { void *addr; addr = mmap(NULL, size, PROT_READ, MAP_PRIVATE, vcpu->fd, page_size * KVM_DIRTY_LOG_PAGE_OFFSET); TEST_ASSERT(addr == MAP_FAILED, "Dirty ring mapped private"); addr = mmap(NULL, size, PROT_READ | PROT_EXEC, MAP_PRIVATE, vcpu->fd, page_size * KVM_DIRTY_LOG_PAGE_OFFSET); TEST_ASSERT(addr == MAP_FAILED, "Dirty ring mapped exec"); addr = mmap(NULL, size, PROT_READ | PROT_WRITE, MAP_SHARED, vcpu->fd, page_size * KVM_DIRTY_LOG_PAGE_OFFSET); TEST_ASSERT(addr != MAP_FAILED, "Dirty ring map failed"); vcpu->dirty_gfns = addr; vcpu->dirty_gfns_count = size / sizeof(struct kvm_dirty_gfn); } return vcpu->dirty_gfns; } /* * Device Ioctl */ int __kvm_has_device_attr(int dev_fd, uint32_t group, uint64_t attr) { struct kvm_device_attr attribute = { .group = group, .attr = attr, .flags = 0, }; return ioctl(dev_fd, KVM_HAS_DEVICE_ATTR, &attribute); } int __kvm_test_create_device(struct kvm_vm *vm, uint64_t type) { struct kvm_create_device create_dev = { .type = type, .flags = KVM_CREATE_DEVICE_TEST, }; return __vm_ioctl(vm, KVM_CREATE_DEVICE, &create_dev); } int __kvm_create_device(struct kvm_vm *vm, uint64_t type) { struct kvm_create_device create_dev = { .type = type, .fd = -1, .flags = 0, }; int err; err = __vm_ioctl(vm, KVM_CREATE_DEVICE, &create_dev); TEST_ASSERT(err <= 0, "KVM_CREATE_DEVICE shouldn't return a positive value"); return err ? : create_dev.fd; } int __kvm_device_attr_get(int dev_fd, uint32_t group, uint64_t attr, void *val) { struct kvm_device_attr kvmattr = { .group = group, .attr = attr, .flags = 0, .addr = (uintptr_t)val, }; return __kvm_ioctl(dev_fd, KVM_GET_DEVICE_ATTR, &kvmattr); } int __kvm_device_attr_set(int dev_fd, uint32_t group, uint64_t attr, void *val) { struct kvm_device_attr kvmattr = { .group = group, .attr = attr, .flags = 0, .addr = (uintptr_t)val, }; return __kvm_ioctl(dev_fd, KVM_SET_DEVICE_ATTR, &kvmattr); } /* * IRQ related functions. */ int _kvm_irq_line(struct kvm_vm *vm, uint32_t irq, int level) { struct kvm_irq_level irq_level = { .irq = irq, .level = level, }; return __vm_ioctl(vm, KVM_IRQ_LINE, &irq_level); } void kvm_irq_line(struct kvm_vm *vm, uint32_t irq, int level) { int ret = _kvm_irq_line(vm, irq, level); TEST_ASSERT(ret >= 0, KVM_IOCTL_ERROR(KVM_IRQ_LINE, ret)); } struct kvm_irq_routing *kvm_gsi_routing_create(void) { struct kvm_irq_routing *routing; size_t size; size = sizeof(struct kvm_irq_routing); /* Allocate space for the max number of entries: this wastes 196 KBs. */ size += KVM_MAX_IRQ_ROUTES * sizeof(struct kvm_irq_routing_entry); routing = calloc(1, size); assert(routing); return routing; } void kvm_gsi_routing_irqchip_add(struct kvm_irq_routing *routing, uint32_t gsi, uint32_t pin) { int i; assert(routing); assert(routing->nr < KVM_MAX_IRQ_ROUTES); i = routing->nr; routing->entries[i].gsi = gsi; routing->entries[i].type = KVM_IRQ_ROUTING_IRQCHIP; routing->entries[i].flags = 0; routing->entries[i].u.irqchip.irqchip = 0; routing->entries[i].u.irqchip.pin = pin; routing->nr++; } int _kvm_gsi_routing_write(struct kvm_vm *vm, struct kvm_irq_routing *routing) { int ret; assert(routing); ret = __vm_ioctl(vm, KVM_SET_GSI_ROUTING, routing); free(routing); return ret; } void kvm_gsi_routing_write(struct kvm_vm *vm, struct kvm_irq_routing *routing) { int ret; ret = _kvm_gsi_routing_write(vm, routing); TEST_ASSERT(!ret, KVM_IOCTL_ERROR(KVM_SET_GSI_ROUTING, ret)); } /* * VM Dump * * Input Args: * vm - Virtual Machine * indent - Left margin indent amount * * Output Args: * stream - Output FILE stream * * Return: None * * Dumps the current state of the VM given by vm, to the FILE stream * given by stream. */ void vm_dump(FILE *stream, struct kvm_vm *vm, uint8_t indent) { int ctr; struct userspace_mem_region *region; struct kvm_vcpu *vcpu; fprintf(stream, "%*smode: 0x%x\n", indent, "", vm->mode); fprintf(stream, "%*sfd: %i\n", indent, "", vm->fd); fprintf(stream, "%*spage_size: 0x%x\n", indent, "", vm->page_size); fprintf(stream, "%*sMem Regions:\n", indent, ""); hash_for_each(vm->regions.slot_hash, ctr, region, slot_node) { fprintf(stream, "%*sguest_phys: 0x%lx size: 0x%lx " "host_virt: %p\n", indent + 2, "", (uint64_t) region->region.guest_phys_addr, (uint64_t) region->region.memory_size, region->host_mem); fprintf(stream, "%*sunused_phy_pages: ", indent + 2, ""); sparsebit_dump(stream, region->unused_phy_pages, 0); } fprintf(stream, "%*sMapped Virtual Pages:\n", indent, ""); sparsebit_dump(stream, vm->vpages_mapped, indent + 2); fprintf(stream, "%*spgd_created: %u\n", indent, "", vm->pgd_created); if (vm->pgd_created) { fprintf(stream, "%*sVirtual Translation Tables:\n", indent + 2, ""); virt_dump(stream, vm, indent + 4); } fprintf(stream, "%*sVCPUs:\n", indent, ""); list_for_each_entry(vcpu, &vm->vcpus, list) vcpu_dump(stream, vcpu, indent + 2); } #define KVM_EXIT_STRING(x) {KVM_EXIT_##x, #x} /* Known KVM exit reasons */ static struct exit_reason { unsigned int reason; const char *name; } exit_reasons_known[] = { KVM_EXIT_STRING(UNKNOWN), KVM_EXIT_STRING(EXCEPTION), KVM_EXIT_STRING(IO), KVM_EXIT_STRING(HYPERCALL), KVM_EXIT_STRING(DEBUG), KVM_EXIT_STRING(HLT), KVM_EXIT_STRING(MMIO), KVM_EXIT_STRING(IRQ_WINDOW_OPEN), KVM_EXIT_STRING(SHUTDOWN), KVM_EXIT_STRING(FAIL_ENTRY), KVM_EXIT_STRING(INTR), KVM_EXIT_STRING(SET_TPR), KVM_EXIT_STRING(TPR_ACCESS), KVM_EXIT_STRING(S390_SIEIC), KVM_EXIT_STRING(S390_RESET), KVM_EXIT_STRING(DCR), KVM_EXIT_STRING(NMI), KVM_EXIT_STRING(INTERNAL_ERROR), KVM_EXIT_STRING(OSI), KVM_EXIT_STRING(PAPR_HCALL), KVM_EXIT_STRING(S390_UCONTROL), KVM_EXIT_STRING(WATCHDOG), KVM_EXIT_STRING(S390_TSCH), KVM_EXIT_STRING(EPR), KVM_EXIT_STRING(SYSTEM_EVENT), KVM_EXIT_STRING(S390_STSI), KVM_EXIT_STRING(IOAPIC_EOI), KVM_EXIT_STRING(HYPERV), KVM_EXIT_STRING(ARM_NISV), KVM_EXIT_STRING(X86_RDMSR), KVM_EXIT_STRING(X86_WRMSR), KVM_EXIT_STRING(DIRTY_RING_FULL), KVM_EXIT_STRING(AP_RESET_HOLD), KVM_EXIT_STRING(X86_BUS_LOCK), KVM_EXIT_STRING(XEN), KVM_EXIT_STRING(RISCV_SBI), KVM_EXIT_STRING(RISCV_CSR), KVM_EXIT_STRING(NOTIFY), #ifdef KVM_EXIT_MEMORY_NOT_PRESENT KVM_EXIT_STRING(MEMORY_NOT_PRESENT), #endif }; /* * Exit Reason String * * Input Args: * exit_reason - Exit reason * * Output Args: None * * Return: * Constant string pointer describing the exit reason. * * Locates and returns a constant string that describes the KVM exit * reason given by exit_reason. If no such string is found, a constant * string of "Unknown" is returned. */ const char *exit_reason_str(unsigned int exit_reason) { unsigned int n1; for (n1 = 0; n1 < ARRAY_SIZE(exit_reasons_known); n1++) { if (exit_reason == exit_reasons_known[n1].reason) return exit_reasons_known[n1].name; } return "Unknown"; } /* * Physical Contiguous Page Allocator * * Input Args: * vm - Virtual Machine * num - number of pages * paddr_min - Physical address minimum * memslot - Memory region to allocate page from * * Output Args: None * * Return: * Starting physical address * * Within the VM specified by vm, locates a range of available physical * pages at or above paddr_min. If found, the pages are marked as in use * and their base address is returned. A TEST_ASSERT failure occurs if * not enough pages are available at or above paddr_min. */ vm_paddr_t vm_phy_pages_alloc(struct kvm_vm *vm, size_t num, vm_paddr_t paddr_min, uint32_t memslot) { struct userspace_mem_region *region; sparsebit_idx_t pg, base; TEST_ASSERT(num > 0, "Must allocate at least one page"); TEST_ASSERT((paddr_min % vm->page_size) == 0, "Min physical address " "not divisible by page size.\n" " paddr_min: 0x%lx page_size: 0x%x", paddr_min, vm->page_size); region = memslot2region(vm, memslot); base = pg = paddr_min >> vm->page_shift; do { for (; pg < base + num; ++pg) { if (!sparsebit_is_set(region->unused_phy_pages, pg)) { base = pg = sparsebit_next_set(region->unused_phy_pages, pg); break; } } } while (pg && pg != base + num); if (pg == 0) { fprintf(stderr, "No guest physical page available, " "paddr_min: 0x%lx page_size: 0x%x memslot: %u\n", paddr_min, vm->page_size, memslot); fputs("---- vm dump ----\n", stderr); vm_dump(stderr, vm, 2); abort(); } for (pg = base; pg < base + num; ++pg) sparsebit_clear(region->unused_phy_pages, pg); return base * vm->page_size; } vm_paddr_t vm_phy_page_alloc(struct kvm_vm *vm, vm_paddr_t paddr_min, uint32_t memslot) { return vm_phy_pages_alloc(vm, 1, paddr_min, memslot); } vm_paddr_t vm_alloc_page_table(struct kvm_vm *vm) { return vm_phy_page_alloc(vm, KVM_GUEST_PAGE_TABLE_MIN_PADDR, vm->memslots[MEM_REGION_PT]); } /* * Address Guest Virtual to Host Virtual * * Input Args: * vm - Virtual Machine * gva - VM virtual address * * Output Args: None * * Return: * Equivalent host virtual address */ void *addr_gva2hva(struct kvm_vm *vm, vm_vaddr_t gva) { return addr_gpa2hva(vm, addr_gva2gpa(vm, gva)); } unsigned long __weak vm_compute_max_gfn(struct kvm_vm *vm) { return ((1ULL << vm->pa_bits) >> vm->page_shift) - 1; } static unsigned int vm_calc_num_pages(unsigned int num_pages, unsigned int page_shift, unsigned int new_page_shift, bool ceil) { unsigned int n = 1 << (new_page_shift - page_shift); if (page_shift >= new_page_shift) return num_pages * (1 << (page_shift - new_page_shift)); return num_pages / n + !!(ceil && num_pages % n); } static inline int getpageshift(void) { return __builtin_ffs(getpagesize()) - 1; } unsigned int vm_num_host_pages(enum vm_guest_mode mode, unsigned int num_guest_pages) { return vm_calc_num_pages(num_guest_pages, vm_guest_mode_params[mode].page_shift, getpageshift(), true); } unsigned int vm_num_guest_pages(enum vm_guest_mode mode, unsigned int num_host_pages) { return vm_calc_num_pages(num_host_pages, getpageshift(), vm_guest_mode_params[mode].page_shift, false); } unsigned int vm_calc_num_guest_pages(enum vm_guest_mode mode, size_t size) { unsigned int n; n = DIV_ROUND_UP(size, vm_guest_mode_params[mode].page_size); return vm_adjust_num_guest_pages(mode, n); } /* * Read binary stats descriptors * * Input Args: * stats_fd - the file descriptor for the binary stats file from which to read * header - the binary stats metadata header corresponding to the given FD * * Output Args: None * * Return: * A pointer to a newly allocated series of stat descriptors. * Caller is responsible for freeing the returned kvm_stats_desc. * * Read the stats descriptors from the binary stats interface. */ struct kvm_stats_desc *read_stats_descriptors(int stats_fd, struct kvm_stats_header *header) { struct kvm_stats_desc *stats_desc; ssize_t desc_size, total_size, ret; desc_size = get_stats_descriptor_size(header); total_size = header->num_desc * desc_size; stats_desc = calloc(header->num_desc, desc_size); TEST_ASSERT(stats_desc, "Allocate memory for stats descriptors"); ret = pread(stats_fd, stats_desc, total_size, header->desc_offset); TEST_ASSERT(ret == total_size, "Read KVM stats descriptors"); return stats_desc; } /* * Read stat data for a particular stat * * Input Args: * stats_fd - the file descriptor for the binary stats file from which to read * header - the binary stats metadata header corresponding to the given FD * desc - the binary stat metadata for the particular stat to be read * max_elements - the maximum number of 8-byte values to read into data * * Output Args: * data - the buffer into which stat data should be read * * Read the data values of a specified stat from the binary stats interface. */ void read_stat_data(int stats_fd, struct kvm_stats_header *header, struct kvm_stats_desc *desc, uint64_t *data, size_t max_elements) { size_t nr_elements = min_t(ssize_t, desc->size, max_elements); size_t size = nr_elements * sizeof(*data); ssize_t ret; TEST_ASSERT(desc->size, "No elements in stat '%s'", desc->name); TEST_ASSERT(max_elements, "Zero elements requested for stat '%s'", desc->name); ret = pread(stats_fd, data, size, header->data_offset + desc->offset); TEST_ASSERT(ret >= 0, "pread() failed on stat '%s', errno: %i (%s)", desc->name, errno, strerror(errno)); TEST_ASSERT(ret == size, "pread() on stat '%s' read %ld bytes, wanted %lu bytes", desc->name, size, ret); } /* * Read the data of the named stat * * Input Args: * vm - the VM for which the stat should be read * stat_name - the name of the stat to read * max_elements - the maximum number of 8-byte values to read into data * * Output Args: * data - the buffer into which stat data should be read * * Read the data values of a specified stat from the binary stats interface. */ void __vm_get_stat(struct kvm_vm *vm, const char *stat_name, uint64_t *data, size_t max_elements) { struct kvm_stats_desc *desc; size_t size_desc; int i; if (!vm->stats_fd) { vm->stats_fd = vm_get_stats_fd(vm); read_stats_header(vm->stats_fd, &vm->stats_header); vm->stats_desc = read_stats_descriptors(vm->stats_fd, &vm->stats_header); } size_desc = get_stats_descriptor_size(&vm->stats_header); for (i = 0; i < vm->stats_header.num_desc; ++i) { desc = (void *)vm->stats_desc + (i * size_desc); if (strcmp(desc->name, stat_name)) continue; read_stat_data(vm->stats_fd, &vm->stats_header, desc, data, max_elements); break; } } __weak void kvm_arch_vm_post_create(struct kvm_vm *vm) { } __weak void kvm_selftest_arch_init(void) { } void __attribute((constructor)) kvm_selftest_init(void) { /* Tell stdout not to buffer its content. */ setbuf(stdout, NULL); kvm_selftest_arch_init(); }
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