extern v3_cpu_arch_t v3_cpu_types[];
-static addr_t active_vmcs_ptrs[V3_CONFIG_MAX_CPUS] = { [0 ... V3_CONFIG_MAX_CPUS - 1] = 0};
static addr_t host_vmcs_ptrs[V3_CONFIG_MAX_CPUS] = { [0 ... V3_CONFIG_MAX_CPUS - 1] = 0};
extern int v3_vmx_launch(struct v3_gprs * vm_regs, struct guest_info * info, struct v3_ctrl_regs * ctrl_regs);
PrintDebug("Loading VMCS\n");
vmx_ret = vmcs_load(vmx_state->vmcs_ptr_phys);
- active_vmcs_ptrs[V3_Get_CPU()] = vmx_state->vmcs_ptr_phys;
vmx_state->state = VMX_UNLAUNCHED;
if (vmx_ret != VMX_SUCCESS) {
#ifdef __V3_64BIT__
+ // Ensure host runs in 64-bit mode at each VM EXIT
vmx_state->exit_ctrls.host_64_on = 1;
#endif
-
- /* Not sure how exactly to handle this... */
+ // Hook all accesses to EFER register
v3_hook_msr(core->vm_info, EFER_MSR,
&v3_handle_efer_read,
&v3_handle_efer_write,
core);
- // Or is it this???
- vmx_state->entry_ctrls.ld_efer = 1;
+ // Restore host's EFER register on each VM EXIT
vmx_state->exit_ctrls.ld_efer = 1;
+
+ // Save/restore guest's EFER register to/from VMCS on VM EXIT/ENTRY
vmx_state->exit_ctrls.save_efer = 1;
- /* *** */
+ vmx_state->entry_ctrls.ld_efer = 1;
- vmx_ret |= check_vmcs_write(VMCS_CR4_MASK, CR4_VMXE);
+ // Cause VM_EXIT whenever CR4.VMXE or CR4.PAE bits are written
+ vmx_ret |= check_vmcs_write(VMCS_CR4_MASK, CR4_VMXE | CR4_PAE);
/* Setup paging */
v3_vmxassist_init(core, vmx_state);
} else if ((core->shdw_pg_mode == NESTED_PAGING) &&
- (v3_cpu_types[core->cpu_id] == V3_VMX_EPT_CPU)) {
+ (v3_cpu_types[core->pcpu_id] == V3_VMX_EPT_CPU)) {
#define CR0_PE 0x00000001
#define CR0_PG 0x80000000
}
} else if ((core->shdw_pg_mode == NESTED_PAGING) &&
- (v3_cpu_types[core->cpu_id] == V3_VMX_EPT_UG_CPU)) {
+ (v3_cpu_types[core->pcpu_id] == V3_VMX_EPT_UG_CPU)) {
int i = 0;
// For now we will assume that unrestricted guest mode is assured w/ EPT
return -1;
}
+ PrintDebug("Serializing VMCS: %p\n", (void *)vmx_state->vmcs_ptr_phys);
+ vmx_ret = vmcs_clear(vmx_state->vmcs_ptr_phys);
+
return 0;
}
struct vmx_data * vmx_state = core->vmm_data;
V3_FreePages((void *)(vmx_state->vmcs_ptr_phys), 1);
- V3_FreePages(vmx_state->msr_area, 1);
+ V3_FreePages(V3_PAddr(vmx_state->msr_area), 1);
V3_Free(vmx_state);
// Perform any additional yielding needed for time adjustment
v3_adjust_time(info);
- // Update timer devices prior to entering VM.
- v3_update_timers(info);
-
// disable global interrupts for vm state transition
v3_disable_ints();
+ // Update timer devices late after being in the VM so that as much
+ // of hte time in the VM is accounted for as possible. Also do it before
+ // updating IRQ entry state so that any interrupts the timers raise get
+ // handled on the next VM entry. Must be done with interrupts disabled.
+ v3_update_timers(info);
- if (active_vmcs_ptrs[V3_Get_CPU()] != vmx_info->vmcs_ptr_phys) {
+ if (vmcs_store() != vmx_info->vmcs_ptr_phys) {
vmcs_load(vmx_info->vmcs_ptr_phys);
- active_vmcs_ptrs[V3_Get_CPU()] = vmx_info->vmcs_ptr_phys;
}
-
v3_vmx_restore_vmcs(info);
exit_log[info->num_exits % 10] = exit_info;
-
#ifdef V3_CONFIG_SYMCALL
if (info->sym_core_state.symcall_state.sym_call_active == 0) {
update_irq_exit_state(info);
int v3_start_vmx_guest(struct guest_info * info) {
- PrintDebug("Starting VMX core %u\n", info->cpu_id);
+ PrintDebug("Starting VMX core %u\n", info->vcpu_id);
- if (info->cpu_id == 0) {
+ if (info->vcpu_id == 0) {
info->core_run_state = CORE_RUNNING;
info->vm_info->run_state = VM_RUNNING;
} else {
- PrintDebug("VMX core %u: Waiting for core initialization\n", info->cpu_id);
+ PrintDebug("VMX core %u: Waiting for core initialization\n", info->vcpu_id);
while (info->core_run_state == CORE_STOPPED) {
v3_yield(info);
- //PrintDebug("VMX core %u: still waiting for INIT\n",info->cpu_id);
+ //PrintDebug("VMX core %u: still waiting for INIT\n",info->vcpu_id);
}
- PrintDebug("VMX core %u initialized\n", info->cpu_id);
+ PrintDebug("VMX core %u initialized\n", info->vcpu_id);
}
PrintDebug("VMX core %u: I am starting at CS=0x%x (base=0x%p, limit=0x%x), RIP=0x%p\n",
- info->cpu_id, info->segments.cs.selector, (void *)(info->segments.cs.base),
+ info->vcpu_id, info->segments.cs.selector, (void *)(info->segments.cs.base),
info->segments.cs.limit, (void *)(info->rip));
- PrintDebug("VMX core %u: Launching VMX VM\n", info->cpu_id);
+ PrintDebug("VMX core %u: Launching VMX VM on logical core %u\n", info->vcpu_id, info->pcpu_id);
v3_start_time(info);
}
+int v3_reset_vmx_vm_core(struct guest_info * core, addr_t rip) {
+ // init vmcs bios
+
+ if ((core->shdw_pg_mode == NESTED_PAGING) &&
+ (v3_cpu_types[core->pcpu_id] == V3_VMX_EPT_UG_CPU)) {
+ // easy
+ core->rip = 0;
+ core->segments.cs.selector = rip << 8;
+ core->segments.cs.limit = 0xffff;
+ core->segments.cs.base = rip << 12;
+ } else {
+ core->vm_regs.rdx = core->vcpu_id;
+ core->vm_regs.rbx = rip;
+ }
+ return 0;
+}
PrintDebug("VMXON pointer: 0x%p\n", (void *)host_vmcs_ptrs[cpu_id]);
if (vmx_on(host_vmcs_ptrs[cpu_id]) == VMX_SUCCESS) {
- PrintDebug("VMX Enabled\n");
+ V3_Print("VMX Enabled\n");
} else {
PrintError("VMX initialization failure\n");
return;