acrn-hypervisor/hypervisor/arch/x86/guest/vmcall.c

293 lines
9.6 KiB
C

/*
* Copyright (C) 2018 Intel Corporation. All rights reserved.
*
* SPDX-License-Identifier: BSD-3-Clause
*/
#include <types.h>
#include <errno.h>
#include <asm/lib/spinlock.h>
#include <asm/guest/vcpu.h>
#include <asm/guest/vm.h>
#include <asm/guest/virq.h>
#include <asm/guest/optee.h>
#include <acrn_hv_defs.h>
#include <hypercall.h>
#include <trace.h>
#include <logmsg.h>
static spinlock_t vm_id_lock = { .head = 0U, .tail = 0U };
struct hc_dispatch {
int32_t (*handler)(struct acrn_vcpu *vcpu, struct acrn_vm *target_vm, uint64_t param1, uint64_t param2);
/* The permission_flags is a bitmap of guest flags indicating whether a VM can invoke this hypercall:
*
* - If permission_flags == 0UL (which is the default value), this hypercall can only be invoked by the
* Service VM.
* - Otherwise, this hypercall can only be invoked by a VM whose guest flags have ALL set bits in
* permission_flags.
*/
uint64_t permission_flags;
};
/* VM Dispatch table for Exit condition handling */
static const struct hc_dispatch hc_dispatch_table[] = {
[HC_IDX(HC_GET_API_VERSION)] = {
.handler = hcall_get_api_version},
[HC_IDX(HC_SERVICE_VM_OFFLINE_CPU)] = {
.handler = hcall_service_vm_offline_cpu},
[HC_IDX(HC_SET_CALLBACK_VECTOR)] = {
.handler = hcall_set_callback_vector},
[HC_IDX(HC_CREATE_VM)] = {
.handler = hcall_create_vm},
[HC_IDX(HC_DESTROY_VM)] = {
.handler = hcall_destroy_vm},
[HC_IDX(HC_START_VM)] = {
.handler = hcall_start_vm},
[HC_IDX(HC_RESET_VM)] = {
.handler = hcall_reset_vm},
[HC_IDX(HC_PAUSE_VM)] = {
.handler = hcall_pause_vm},
[HC_IDX(HC_SET_VCPU_REGS)] = {
.handler = hcall_set_vcpu_regs},
[HC_IDX(HC_CREATE_VCPU)] = {
.handler = hcall_create_vcpu},
[HC_IDX(HC_SET_IRQLINE)] = {
.handler = hcall_set_irqline},
[HC_IDX(HC_INJECT_MSI)] = {
.handler = hcall_inject_msi},
[HC_IDX(HC_SET_IOREQ_BUFFER)] = {
.handler = hcall_set_ioreq_buffer},
[HC_IDX(HC_NOTIFY_REQUEST_FINISH)] = {
.handler = hcall_notify_ioreq_finish},
[HC_IDX(HC_VM_SET_MEMORY_REGIONS)] = {
.handler = hcall_set_vm_memory_regions},
[HC_IDX(HC_VM_WRITE_PROTECT_PAGE)] = {
.handler = hcall_write_protect_page},
[HC_IDX(HC_VM_GPA2HPA)] = {
.handler = hcall_gpa_to_hpa},
[HC_IDX(HC_ASSIGN_PCIDEV)] = {
.handler = hcall_assign_pcidev},
[HC_IDX(HC_DEASSIGN_PCIDEV)] = {
.handler = hcall_deassign_pcidev},
[HC_IDX(HC_ASSIGN_MMIODEV)] = {
.handler = hcall_assign_mmiodev},
[HC_IDX(HC_DEASSIGN_MMIODEV)] = {
.handler = hcall_deassign_mmiodev},
[HC_IDX(HC_ADD_VDEV)] = {
.handler = hcall_add_vdev},
[HC_IDX(HC_REMOVE_VDEV)] = {
.handler = hcall_remove_vdev},
[HC_IDX(HC_SET_PTDEV_INTR_INFO)] = {
.handler = hcall_set_ptdev_intr_info},
[HC_IDX(HC_RESET_PTDEV_INTR_INFO)] = {
.handler = hcall_reset_ptdev_intr_info},
[HC_IDX(HC_PM_GET_CPU_STATE)] = {
.handler = hcall_get_cpu_pm_state},
[HC_IDX(HC_VM_INTR_MONITOR)] = {
.handler = hcall_vm_intr_monitor},
[HC_IDX(HC_SETUP_SBUF)] = {
.handler = hcall_setup_sbuf},
[HC_IDX(HC_SETUP_HV_NPK_LOG)] = {
.handler = hcall_setup_hv_npk_log},
[HC_IDX(HC_PROFILING_OPS)] = {
.handler = hcall_profiling_ops},
[HC_IDX(HC_GET_HW_INFO)] = {
.handler = hcall_get_hw_info},
[HC_IDX(HC_INITIALIZE_TRUSTY)] = {
.handler = hcall_initialize_trusty,
.permission_flags = GUEST_FLAG_SECURE_WORLD_ENABLED},
[HC_IDX(HC_WORLD_SWITCH)] = {
.handler = hcall_world_switch,
.permission_flags = GUEST_FLAG_SECURE_WORLD_ENABLED},
[HC_IDX(HC_SAVE_RESTORE_SWORLD_CTX)] = {
.handler = hcall_save_restore_sworld_ctx,
.permission_flags = GUEST_FLAG_SECURE_WORLD_ENABLED},
[HC_IDX(HC_TEE_VCPU_BOOT_DONE)] = {
.handler = hcall_handle_tee_vcpu_boot_done,
.permission_flags = GUEST_FLAG_TEE},
[HC_IDX(HC_SWITCH_EE)] = {
.handler = hcall_switch_ee,
.permission_flags = (GUEST_FLAG_TEE | GUEST_FLAG_REE)},
};
uint16_t allocate_dynamical_vmid(struct acrn_vm_creation *cv)
{
uint16_t vm_id;
struct acrn_vm_config *vm_config;
spinlock_obtain(&vm_id_lock);
vm_id = get_unused_vmid();
if (vm_id != ACRN_INVALID_VMID) {
vm_config = get_vm_config(vm_id);
memcpy_s(vm_config->name, MAX_VM_NAME_LEN, cv->name, MAX_VM_NAME_LEN);
vm_config->cpu_affinity = cv->cpu_affinity;
}
spinlock_release(&vm_id_lock);
return vm_id;
}
#define GUEST_FLAGS_ALLOWING_HYPERCALLS GUEST_FLAG_SECURE_WORLD_ENABLED
static bool is_guest_hypercall(struct acrn_vm *vm)
{
uint64_t guest_flags = get_vm_config(vm->vm_id)->guest_flags;
bool ret = true;
if ((guest_flags & (GUEST_FLAG_SECURE_WORLD_ENABLED |
GUEST_FLAG_TEE | GUEST_FLAG_REE)) == 0UL) {
ret = false;
}
return ret;
}
struct acrn_vm *parse_target_vm(struct acrn_vm *service_vm, uint64_t hcall_id, uint64_t param1, __unused uint64_t param2)
{
struct acrn_vm *target_vm = NULL;
uint16_t vm_id = ACRN_INVALID_VMID;
struct acrn_vm_creation cv;
struct set_regions regions;
uint16_t relative_vm_id;
switch (hcall_id) {
case HC_CREATE_VM:
if (copy_from_gpa(service_vm, &cv, param1, sizeof(cv)) == 0) {
vm_id = get_vmid_by_name((char *)cv.name);
/* if the vm-name is not found, it indicates that it is not in pre-defined vm_list.
* So try to allocate one free slot to start one vm based on user-requirement
*/
if (vm_id == ACRN_INVALID_VMID) {
vm_id = allocate_dynamical_vmid(&cv);
/* it doesn't find the available vm_slot for the given vm_name.
* Maybe the CONFIG_MAX_VM_NUM is too small to start the VM.
*/
if (vm_id == ACRN_INVALID_VMID) {
pr_err("The VM name provided (%s) is invalid, cannot create VM", cv.name);
}
}
}
break;
case HC_PM_GET_CPU_STATE:
vm_id = rel_vmid_2_vmid(service_vm->vm_id, (uint16_t)((param1 & PMCMD_VMID_MASK) >> PMCMD_VMID_SHIFT));
break;
case HC_VM_SET_MEMORY_REGIONS:
if (copy_from_gpa(service_vm, &regions, param1, sizeof(regions)) == 0) {
/* the vmid in regions is a relative vm id, need to convert to absolute vm id */
vm_id = rel_vmid_2_vmid(service_vm->vm_id, regions.vmid);
}
break;
case HC_GET_API_VERSION:
case HC_SERVICE_VM_OFFLINE_CPU:
case HC_SET_CALLBACK_VECTOR:
case HC_SETUP_SBUF:
case HC_SETUP_HV_NPK_LOG:
case HC_PROFILING_OPS:
case HC_GET_HW_INFO:
target_vm = service_vm;
break;
default:
relative_vm_id = (uint16_t)param1;
vm_id = rel_vmid_2_vmid(service_vm->vm_id, relative_vm_id);
break;
}
if ((target_vm == NULL) && (vm_id < CONFIG_MAX_VM_NUM)) {
target_vm = get_vm_from_vmid(vm_id);
if (hcall_id == HC_CREATE_VM) {
target_vm->vm_id = vm_id;
}
}
return target_vm;
}
static int32_t dispatch_hypercall(struct acrn_vcpu *vcpu)
{
int32_t ret = -ENOTTY;
struct acrn_vm *vm = vcpu->vm;
uint64_t guest_flags = get_vm_config(vm->vm_id)->guest_flags; /* hypercall ID from guest */
uint64_t hcall_id = vcpu_get_gpreg(vcpu, CPU_REG_R8); /* hypercall ID from guest */
if (HC_IDX(hcall_id) < ARRAY_SIZE(hc_dispatch_table)) {
const struct hc_dispatch *dispatch = &(hc_dispatch_table[HC_IDX(hcall_id)]);
uint64_t permission_flags = dispatch->permission_flags;
if (dispatch->handler != NULL) {
uint64_t param1 = vcpu_get_gpreg(vcpu, CPU_REG_RDI); /* hypercall param1 from guest */
uint64_t param2 = vcpu_get_gpreg(vcpu, CPU_REG_RSI); /* hypercall param2 from guest */
if ((permission_flags == 0UL) && is_service_vm(vm) && !is_ree_vm(vm)) {
/* A permission_flags of 0 indicates that this hypercall is for Service VM to manage
* post-launched VMs.
*
* Though REE VM has its load order to be Service_VM, it does not offer services as
* Service VM does. The only hypercalls allowed for REE are the ones with permission flag
* GUEST_FLAG_REE.
*/
struct acrn_vm *target_vm = parse_target_vm(vm, hcall_id, param1, param2);
if ((target_vm != NULL) && !is_prelaunched_vm(target_vm)) {
get_vm_lock(target_vm);
ret = dispatch->handler(vcpu, target_vm, param1, param2);
put_vm_lock(target_vm);
}
} else if ((permission_flags != 0UL) &&
((guest_flags & permission_flags) != 0UL)) {
ret = dispatch->handler(vcpu, vcpu->vm, param1, param2);
} else {
/* The vCPU is not allowed to invoke the given hypercall. Keep `ret` as -ENOTTY and no
* further actions required.
*/
}
}
}
return ret;
}
/*
* Pass return value to Service VM by register rax.
* This function should always return 0 since we shouldn't
* deal with hypercall error in hypervisor.
*/
int32_t vmcall_vmexit_handler(struct acrn_vcpu *vcpu)
{
int32_t ret;
struct acrn_vm *vm = vcpu->vm;
/* hypercall ID from guest*/
uint64_t hypcall_id = vcpu_get_gpreg(vcpu, CPU_REG_R8);
/*
* The following permission checks are applied to hypercalls.
*
* 1. Only Service VM and VMs with specific guest flags (referred to as 'allowed VMs' hereinafter) can invoke
* hypercalls by executing the `vmcall` instruction. Attempts to execute the `vmcall` instruction in the
* other VMs will trigger #UD.
* 2. Attempts to execute the `vmcall` instruction from ring 1, 2 or 3 in an allowed VM will trigger #GP(0).
* 3. An allowed VM is permitted to only invoke some of the supported hypercalls depending on its load order and
* guest flags. Attempts to invoke an unpermitted hypercall will make a vCPU see -EINVAL as the return
* value. No exception is triggered in this case.
*/
if (!is_service_vm(vm) && !is_guest_hypercall(vm)) {
vcpu_inject_ud(vcpu);
ret = -ENODEV;
} else if (!is_hypercall_from_ring0()) {
vcpu_inject_gp(vcpu, 0U);
ret = -EACCES;
} else {
ret = dispatch_hypercall(vcpu);
}
if ((ret != -EACCES) && (ret != -ENODEV)) {
vcpu_set_gpreg(vcpu, CPU_REG_RAX, (uint64_t)ret);
}
if (ret < 0) {
pr_err("ret=%d hypercall=0x%lx failed in %s\n", ret, hypcall_id, __func__);
}
TRACE_2L(TRACE_VMEXIT_VMCALL, vm->vm_id, hypcall_id);
return 0;
}