xref: /DragonOS/kernel/src/arch/x86_64/kvm/vmx/vcpu.rs (revision c635d8a9cfe25bc11779f323ef0c7d7a0f597d4a)
1 use super::vmcs::{
2     VMCSRegion, VmcsFields, VmxEntryCtrl, VmxPrimaryExitCtrl, VmxPrimaryProcessBasedExecuteCtrl,
3     VmxSecondaryProcessBasedExecuteCtrl,
4 };
5 use super::vmx_asm_wrapper::{vmx_vmclear, vmx_vmptrld, vmx_vmread, vmx_vmwrite, vmxoff, vmxon};
6 use crate::arch::kvm::vmx::mmu::KvmMmu;
7 use crate::arch::kvm::vmx::seg::{seg_setup, Sreg};
8 use crate::arch::kvm::vmx::{VcpuRegIndex, X86_CR0};
9 use crate::arch::mm::{LockedFrameAllocator, PageMapper};
10 use crate::arch::x86_64::mm::X86_64MMArch;
11 use crate::arch::MMArch;
12 
13 use crate::mm::{MemoryManagementArch, PageTableKind};
14 use crate::mm::{PhysAddr, VirtAddr};
15 use crate::virt::kvm::vcpu::Vcpu;
16 use crate::virt::kvm::vm::Vm;
17 use alloc::alloc::Global;
18 use alloc::boxed::Box;
19 use core::slice;
20 use log::debug;
21 use raw_cpuid::CpuId;
22 use system_error::SystemError;
23 use x86;
24 use x86::{controlregs, msr, segmentation};
25 // use crate::arch::kvm::vmx::seg::RMODE_TSS_SIZE;
26 // use crate::virt::kvm::{KVM};
27 
28 // KERNEL_ALLOCATOR
29 pub const PAGE_SIZE: usize = 0x1000;
30 pub const NR_VCPU_REGS: usize = 16;
31 
32 #[repr(C, align(4096))]
33 #[derive(Debug)]
34 pub struct VmxonRegion {
35     pub revision_id: u32,
36     pub data: [u8; PAGE_SIZE - 4],
37 }
38 
39 #[repr(C, align(4096))]
40 #[derive(Debug)]
41 pub struct MSRBitmap {
42     pub data: [u8; PAGE_SIZE],
43 }
44 
45 #[allow(dead_code)]
46 #[derive(Debug)]
47 pub struct VcpuData {
48     /// The virtual and physical address of the Vmxon naturally aligned 4-KByte region of memory
49     pub vmxon_region: Box<VmxonRegion>,
50     pub vmxon_region_physical_address: u64, // vmxon需要该地址
51     /// The virtual and physical address of the Vmcs naturally aligned 4-KByte region of memory
52     /// holds the complete CPU state of both the host and the guest.
53     /// includes the segment registers, GDT, IDT, TR, various MSR’s
54     /// and control field structures for handling exit and entry operations
55     pub vmcs_region: Box<VMCSRegion>,
56     pub vmcs_region_physical_address: u64, // vmptrld, vmclear需要该地址
57     pub msr_bitmap: Box<MSRBitmap>,
58     pub msr_bitmap_physical_address: u64,
59 }
60 
61 #[derive(Default, Debug)]
62 #[repr(C)]
63 pub struct VcpuContextFrame {
64     pub regs: [usize; NR_VCPU_REGS], // 通用寄存器
65     pub rip: usize,
66     pub rflags: usize,
67 }
68 
69 #[derive(Debug)]
70 #[allow(dead_code)]
71 pub enum VcpuState {
72     Inv = 0,
73     Pend = 1,
74     Act = 2,
75 }
76 
77 #[allow(dead_code)]
78 #[derive(Debug)]
79 pub struct VmxVcpu {
80     pub vcpu_id: u32,
81     pub vcpu_ctx: VcpuContextFrame, // 保存vcpu切换时的上下文,如通用寄存器等
82     pub vcpu_state: VcpuState,      // vcpu当前运行状态
83     pub mmu: KvmMmu,                // vcpu的内存管理单元
84     pub data: VcpuData,             // vcpu的数据
85     pub parent_vm: Vm,              // parent KVM
86 }
87 
88 impl VcpuData {
89     pub fn alloc() -> Result<Self, SystemError> {
90         let vmxon_region: Box<VmxonRegion> = unsafe {
91             Box::try_new_zeroed_in(Global)
92                 .expect("Try new zeroed fail!")
93                 .assume_init()
94         };
95         let vmcs_region: Box<VMCSRegion> = unsafe {
96             Box::try_new_zeroed_in(Global)
97                 .expect("Try new zeroed fail!")
98                 .assume_init()
99         };
100         let msr_bitmap: Box<MSRBitmap> = unsafe {
101             Box::try_new_zeroed_in(Global)
102                 .expect("Try new zeroed fail!")
103                 .assume_init()
104         };
105         // FIXME: virt_2_phys的转换正确性存疑
106         let vmxon_region_physical_address = {
107             let vaddr = VirtAddr::new(vmxon_region.as_ref() as *const _ as _);
108             unsafe { MMArch::virt_2_phys(vaddr).unwrap().data() as u64 }
109         };
110         let vmcs_region_physical_address = {
111             let vaddr = VirtAddr::new(vmcs_region.as_ref() as *const _ as _);
112             unsafe { MMArch::virt_2_phys(vaddr).unwrap().data() as u64 }
113         };
114         let msr_bitmap_physical_address = {
115             let vaddr = VirtAddr::new(msr_bitmap.as_ref() as *const _ as _);
116             unsafe { MMArch::virt_2_phys(vaddr).unwrap().data() as u64 }
117         };
118 
119         let mut instance = Self {
120             // Allocate a naturally aligned 4-KByte VMXON region of memory to enable VMX operation (Intel Manual: 25.11.5 VMXON Region)
121             vmxon_region,
122             vmxon_region_physical_address,
123             // Allocate a naturally aligned 4-KByte VMCS region of memory
124             vmcs_region,
125             vmcs_region_physical_address,
126             msr_bitmap,
127             msr_bitmap_physical_address,
128         };
129         // printk_color!(GREEN, BLACK, "[+] init_region\n");
130         instance.init_region()?;
131         Ok(instance)
132     }
133 
134     pub fn init_region(&mut self) -> Result<(), SystemError> {
135         // Get the Virtual Machine Control Structure revision identifier (VMCS revision ID)
136         // (Intel Manual: 25.11.5 VMXON Region)
137         let revision_id = unsafe { (msr::rdmsr(msr::IA32_VMX_BASIC) as u32) & 0x7FFF_FFFF };
138         debug!("[+] VMXON Region Virtual Address: {:p}", self.vmxon_region);
139         debug!(
140             "[+] VMXON Region Physical Addresss: 0x{:x}",
141             self.vmxon_region_physical_address
142         );
143         debug!("[+] VMCS Region Virtual Address: {:p}", self.vmcs_region);
144         debug!(
145             "[+] VMCS Region Physical Address1: 0x{:x}",
146             self.vmcs_region_physical_address
147         );
148         self.vmxon_region.revision_id = revision_id;
149         self.vmcs_region.revision_id = revision_id;
150         return Ok(());
151     }
152 }
153 
154 impl VmxVcpu {
155     pub fn new(vcpu_id: u32, parent_vm: Vm) -> Result<Self, SystemError> {
156         debug!("Creating processor {}", vcpu_id);
157         let instance = Self {
158             vcpu_id,
159             vcpu_ctx: VcpuContextFrame {
160                 regs: [0; NR_VCPU_REGS],
161                 rip: 0,
162                 rflags: 0,
163             },
164             vcpu_state: VcpuState::Inv,
165             mmu: KvmMmu::default(),
166             data: VcpuData::alloc()?,
167             parent_vm,
168         };
169         Ok(instance)
170     }
171 
172     pub fn vmx_set_cr0(cr0: X86_CR0) -> Result<(), SystemError> {
173         let mut hw_cr0 = cr0 & !(X86_CR0::CR0_NW | X86_CR0::CR0_CD);
174         hw_cr0 |= X86_CR0::CR0_WP | X86_CR0::CR0_NE;
175 
176         vmx_vmwrite(VmcsFields::GUEST_CR0 as u32, cr0.bits() as u64)?;
177         Ok(())
178     }
179 
180     pub fn vmcs_init_guest(&self) -> Result<(), SystemError> {
181         // https://www.sandpile.org/x86/initial.htm
182         // segment field initialization
183         seg_setup(Sreg::CS as usize)?;
184         vmx_vmwrite(VmcsFields::GUEST_CS_SELECTOR as u32, 0xf000)?;
185         vmx_vmwrite(VmcsFields::GUEST_CS_BASE as u32, 0xffff0000)?;
186 
187         seg_setup(Sreg::DS as usize)?;
188         seg_setup(Sreg::ES as usize)?;
189         seg_setup(Sreg::FS as usize)?;
190         seg_setup(Sreg::GS as usize)?;
191         seg_setup(Sreg::SS as usize)?;
192 
193         vmx_vmwrite(VmcsFields::GUEST_TR_SELECTOR as u32, 0)?;
194         vmx_vmwrite(VmcsFields::GUEST_TR_BASE as u32, 0)?;
195         vmx_vmwrite(VmcsFields::GUEST_TR_LIMIT as u32, 0xffff)?;
196         vmx_vmwrite(VmcsFields::GUEST_TR_ACCESS_RIGHTS as u32, 0x008b)?;
197 
198         vmx_vmwrite(VmcsFields::GUEST_LDTR_SELECTOR as u32, 0)?;
199         vmx_vmwrite(VmcsFields::GUEST_LDTR_BASE as u32, 0)?;
200         vmx_vmwrite(VmcsFields::GUEST_LDTR_LIMIT as u32, 0xffff)?;
201         vmx_vmwrite(VmcsFields::GUEST_LDTR_ACCESS_RIGHTS as u32, 0x00082)?;
202 
203         vmx_vmwrite(VmcsFields::GUEST_RFLAGS as u32, 2)?;
204 
205         vmx_vmwrite(VmcsFields::GUEST_GDTR_BASE as u32, 0)?;
206         vmx_vmwrite(VmcsFields::GUEST_GDTR_LIMIT as u32, 0x0000_FFFF_u64)?;
207 
208         vmx_vmwrite(VmcsFields::GUEST_IDTR_BASE as u32, 0)?;
209         vmx_vmwrite(VmcsFields::GUEST_IDTR_LIMIT as u32, 0x0000_FFFF_u64)?;
210 
211         vmx_vmwrite(VmcsFields::GUEST_ACTIVITY_STATE as u32, 0)?; // State = Active
212         vmx_vmwrite(VmcsFields::GUEST_INTERRUPTIBILITY_STATE as u32, 0)?;
213         vmx_vmwrite(VmcsFields::GUEST_PENDING_DBG_EXCEPTIONS as u32, 0)?;
214 
215         vmx_vmwrite(VmcsFields::CTRL_VM_ENTRY_INTR_INFO_FIELD as u32, 0)?;
216 
217         let cr0 = X86_CR0::CR0_NW | X86_CR0::CR0_CD | X86_CR0::CR0_ET;
218         Self::vmx_set_cr0(cr0)?;
219 
220         vmx_vmwrite(VmcsFields::GUEST_CR0 as u32, cr0.bits() as u64)?;
221 
222         vmx_vmwrite(
223             VmcsFields::GUEST_SYSENTER_CS as u32,
224             vmx_vmread(VmcsFields::HOST_SYSENTER_CS as u32).unwrap(),
225         )?;
226         vmx_vmwrite(VmcsFields::GUEST_VMX_PREEMPT_TIMER_VALUE as u32, 0)?;
227 
228         vmx_vmwrite(VmcsFields::GUEST_INTR_STATUS as u32, 0)?;
229         vmx_vmwrite(VmcsFields::GUEST_PML_INDEX as u32, 0)?;
230 
231         vmx_vmwrite(VmcsFields::GUEST_VMCS_LINK_PTR as u32, u64::MAX)?;
232         vmx_vmwrite(VmcsFields::GUEST_DEBUGCTL as u32, unsafe {
233             msr::rdmsr(msr::IA32_DEBUGCTL)
234         })?;
235 
236         vmx_vmwrite(
237             VmcsFields::GUEST_SYSENTER_ESP as u32,
238             vmx_vmread(VmcsFields::HOST_SYSENTER_ESP as u32).unwrap(),
239         )?;
240         vmx_vmwrite(
241             VmcsFields::GUEST_SYSENTER_EIP as u32,
242             vmx_vmread(VmcsFields::HOST_SYSENTER_EIP as u32).unwrap(),
243         )?;
244 
245         // Self::vmx_set_cr0();
246         vmx_vmwrite(VmcsFields::GUEST_CR3 as u32, 0)?;
247         vmx_vmwrite(
248             VmcsFields::GUEST_CR4 as u32,
249             1, // enable vme
250         )?;
251         vmx_vmwrite(VmcsFields::GUEST_DR7 as u32, 0x0000_0000_0000_0400)?;
252         vmx_vmwrite(
253             VmcsFields::GUEST_RSP as u32,
254             self.vcpu_ctx.regs[VcpuRegIndex::Rsp as usize] as u64,
255         )?;
256         vmx_vmwrite(VmcsFields::GUEST_RIP as u32, self.vcpu_ctx.rip as u64)?;
257         debug!("vmcs init guest rip: {:#x}", self.vcpu_ctx.rip as u64);
258         debug!(
259             "vmcs init guest rsp: {:#x}",
260             self.vcpu_ctx.regs[VcpuRegIndex::Rsp as usize] as u64
261         );
262 
263         // vmx_vmwrite(VmcsFields::GUEST_RFLAGS as u32, x86::bits64::rflags::read().bits())?;
264         Ok(())
265     }
266 
267     #[allow(deprecated)]
268     pub fn vmcs_init_host(&self) -> Result<(), SystemError> {
269         vmx_vmwrite(VmcsFields::HOST_CR0 as u32, unsafe {
270             controlregs::cr0().bits().try_into().unwrap()
271         })?;
272         vmx_vmwrite(VmcsFields::HOST_CR3 as u32, unsafe { controlregs::cr3() })?;
273         vmx_vmwrite(VmcsFields::HOST_CR4 as u32, unsafe {
274             controlregs::cr4().bits().try_into().unwrap()
275         })?;
276         vmx_vmwrite(
277             VmcsFields::HOST_ES_SELECTOR as u32,
278             (segmentation::es().bits() & (!0x07)).into(),
279         )?;
280         vmx_vmwrite(
281             VmcsFields::HOST_CS_SELECTOR as u32,
282             (segmentation::cs().bits() & (!0x07)).into(),
283         )?;
284         vmx_vmwrite(
285             VmcsFields::HOST_SS_SELECTOR as u32,
286             (segmentation::ss().bits() & (!0x07)).into(),
287         )?;
288         vmx_vmwrite(
289             VmcsFields::HOST_DS_SELECTOR as u32,
290             (segmentation::ds().bits() & (!0x07)).into(),
291         )?;
292         vmx_vmwrite(
293             VmcsFields::HOST_FS_SELECTOR as u32,
294             (segmentation::fs().bits() & (!0x07)).into(),
295         )?;
296         vmx_vmwrite(
297             VmcsFields::HOST_GS_SELECTOR as u32,
298             (segmentation::gs().bits() & (!0x07)).into(),
299         )?;
300         vmx_vmwrite(VmcsFields::HOST_TR_SELECTOR as u32, unsafe {
301             (x86::task::tr().bits() & (!0x07)).into()
302         })?;
303         vmx_vmwrite(VmcsFields::HOST_FS_BASE as u32, unsafe {
304             msr::rdmsr(msr::IA32_FS_BASE)
305         })?;
306         vmx_vmwrite(VmcsFields::HOST_GS_BASE as u32, unsafe {
307             msr::rdmsr(msr::IA32_GS_BASE)
308         })?;
309 
310         let mut pseudo_descriptpr: x86::dtables::DescriptorTablePointer<u64> = Default::default();
311         unsafe {
312             x86::dtables::sgdt(&mut pseudo_descriptpr);
313         };
314 
315         vmx_vmwrite(
316             VmcsFields::HOST_TR_BASE as u32,
317             get_segment_base(pseudo_descriptpr.base, pseudo_descriptpr.limit, unsafe {
318                 x86::task::tr().bits()
319             }),
320         )?;
321         vmx_vmwrite(
322             VmcsFields::HOST_GDTR_BASE as u32,
323             pseudo_descriptpr.base as usize as u64,
324         )?;
325         vmx_vmwrite(VmcsFields::HOST_IDTR_BASE as u32, unsafe {
326             let mut pseudo_descriptpr: x86::dtables::DescriptorTablePointer<u64> =
327                 Default::default();
328             x86::dtables::sidt(&mut pseudo_descriptpr);
329             pseudo_descriptpr.base as usize as u64
330         })?;
331 
332         // fast entry into the kernel
333         vmx_vmwrite(VmcsFields::HOST_SYSENTER_ESP as u32, unsafe {
334             msr::rdmsr(msr::IA32_SYSENTER_ESP)
335         })?;
336         vmx_vmwrite(VmcsFields::HOST_SYSENTER_EIP as u32, unsafe {
337             msr::rdmsr(msr::IA32_SYSENTER_EIP)
338         })?;
339         vmx_vmwrite(VmcsFields::HOST_SYSENTER_CS as u32, unsafe {
340             msr::rdmsr(msr::IA32_SYSENTER_CS)
341         })?;
342 
343         // vmx_vmwrite(VmcsFields::HOST_RIP as u32, vmx_return as *const () as u64)?;
344         // debug!("vmcs init host rip: {:#x}", vmx_return as *const () as u64);
345 
346         Ok(())
347     }
348 
349     // Intel SDM Volume 3C Chapter 25.3 “Organization of VMCS Data”
350     pub fn vmcs_init(&self) -> Result<(), SystemError> {
351         vmx_vmwrite(VmcsFields::CTRL_PAGE_FAULT_ERR_CODE_MASK as u32, 0)?;
352         vmx_vmwrite(VmcsFields::CTRL_PAGE_FAULT_ERR_CODE_MATCH as u32, 0)?;
353         vmx_vmwrite(VmcsFields::CTRL_CR3_TARGET_COUNT as u32, 0)?;
354 
355         vmx_vmwrite(
356             VmcsFields::CTRL_PIN_BASED_VM_EXEC_CTRLS as u32,
357             adjust_vmx_pinbased_controls() as u64,
358         )?;
359 
360         vmx_vmwrite(
361             VmcsFields::CTRL_MSR_BITMAP_ADDR as u32,
362             self.data.msr_bitmap_physical_address,
363         )?;
364 
365         vmx_vmwrite(VmcsFields::CTRL_CR0_READ_SHADOW as u32, unsafe {
366             controlregs::cr0().bits().try_into().unwrap()
367         })?;
368         vmx_vmwrite(VmcsFields::CTRL_CR4_READ_SHADOW as u32, unsafe {
369             controlregs::cr4().bits().try_into().unwrap()
370         })?;
371         vmx_vmwrite(
372             VmcsFields::CTRL_VM_ENTRY_CTRLS as u32,
373             adjust_vmx_entry_controls() as u64,
374         )?;
375         vmx_vmwrite(
376             VmcsFields::CTRL_PRIMARY_VM_EXIT_CTRLS as u32,
377             adjust_vmx_exit_controls() as u64,
378         )?;
379         vmx_vmwrite(
380             VmcsFields::CTRL_PRIMARY_PROCESSOR_VM_EXEC_CTRLS as u32,
381             adjust_vmx_primary_process_exec_controls() as u64,
382         )?;
383         vmx_vmwrite(
384             VmcsFields::CTRL_SECONDARY_PROCESSOR_VM_EXEC_CTRLS as u32,
385             adjust_vmx_secondary_process_exec_controls() as u64,
386         )?;
387 
388         self.vmcs_init_host()?;
389         self.vmcs_init_guest()?;
390         Ok(())
391     }
392 
393     fn kvm_mmu_load(&mut self) -> Result<(), SystemError> {
394         debug!("kvm_mmu_load!");
395         // 申请并创建新的页表
396         let mapper: crate::mm::page::PageMapper<X86_64MMArch, LockedFrameAllocator> = unsafe {
397             PageMapper::create(PageTableKind::EPT, LockedFrameAllocator)
398                 .ok_or(SystemError::ENOMEM)?
399         };
400 
401         let ept_root_hpa = mapper.table().phys();
402         let set_eptp_fn = self.mmu.set_eptp.unwrap();
403         set_eptp_fn(ept_root_hpa.data() as u64)?;
404         self.mmu.root_hpa = ept_root_hpa.data() as u64;
405         debug!("ept_root_hpa:{:x}!", ept_root_hpa.data() as u64);
406 
407         return Ok(());
408     }
409 
410     pub fn set_regs(&mut self, regs: VcpuContextFrame) -> Result<(), SystemError> {
411         self.vcpu_ctx = regs;
412         Ok(())
413     }
414 }
415 
416 impl Vcpu for VmxVcpu {
417     /// Virtualize the CPU
418     fn virtualize_cpu(&mut self) -> Result<(), SystemError> {
419         match has_intel_vmx_support() {
420             Ok(_) => {
421                 debug!("[+] CPU supports Intel VMX");
422             }
423             Err(e) => {
424                 debug!("[-] CPU does not support Intel VMX: {:?}", e);
425                 return Err(SystemError::ENOSYS);
426             }
427         };
428 
429         match enable_vmx_operation() {
430             Ok(_) => {
431                 debug!("[+] Enabling Virtual Machine Extensions (VMX)");
432             }
433             Err(_) => {
434                 debug!("[-] VMX operation is not supported on this processor.");
435                 return Err(SystemError::ENOSYS);
436             }
437         }
438 
439         vmxon(self.data.vmxon_region_physical_address)?;
440         debug!("[+] VMXON successful!");
441         vmx_vmclear(self.data.vmcs_region_physical_address)?;
442         vmx_vmptrld(self.data.vmcs_region_physical_address)?;
443         debug!("[+] VMPTRLD successful!");
444         self.vmcs_init().expect("vncs_init fail");
445         debug!("[+] VMCS init!");
446         // debug!("vmcs init host rip: {:#x}", vmx_return as *const () as u64);
447         // debug!("vmcs init host rsp: {:#x}", x86::bits64::registers::rsp());
448         // vmx_vmwrite(VmcsFields::HOST_RSP as u32, x86::bits64::registers::rsp())?;
449         // vmx_vmwrite(VmcsFields::HOST_RIP as u32, vmx_return as *const () as u64)?;
450         // vmx_vmwrite(VmcsFields::HOST_RSP as u32,  x86::bits64::registers::rsp())?;
451         self.kvm_mmu_load()?;
452         Ok(())
453     }
454 
455     fn devirtualize_cpu(&self) -> Result<(), SystemError> {
456         vmxoff()?;
457         Ok(())
458     }
459 
460     /// Gets the index of the current logical/virtual processor
461     fn id(&self) -> u32 {
462         self.vcpu_id
463     }
464 }
465 
466 pub fn get_segment_base(gdt_base: *const u64, gdt_size: u16, segment_selector: u16) -> u64 {
467     let table = segment_selector & 0x0004; // get table indicator in selector
468     let index = (segment_selector >> 3) as usize; // get index in selector
469     if table == 0 && index == 0 {
470         return 0;
471     }
472     let descriptor_table = unsafe { slice::from_raw_parts(gdt_base, gdt_size.into()) };
473     let descriptor = descriptor_table[index];
474 
475     let base_high = (descriptor & 0xFF00_0000_0000_0000) >> 32;
476     let base_mid = (descriptor & 0x0000_00FF_0000_0000) >> 16;
477     let base_low = (descriptor & 0x0000_0000_FFFF_0000) >> 16;
478     let segment_base = (base_high | base_mid | base_low) & 0xFFFFFFFF;
479     let virtaddr = unsafe { MMArch::phys_2_virt(PhysAddr::new(segment_base as usize)).unwrap() };
480 
481     return virtaddr.data() as u64;
482 }
483 
484 // FIXME: may have bug
485 // pub fn read_segment_access_rights(segement_selector: u16) -> u32{
486 //     let table = segement_selector & 0x0004; // get table indicator in selector
487 //     let index = segement_selector & 0xFFF8; // get index in selector
488 //     let mut flag: u16;
489 //     if table==0 && index==0 {
490 //         return 0;
491 //     }
492 //     unsafe{
493 //         asm!(
494 //             "lar {0:r}, rcx",
495 //             "mov {1:r}, {0:r}",
496 //             in(reg) segement_selector,
497 //             out(reg) flag,
498 //         );
499 //     }
500 //     return (flag >> 8) as u32;
501 // }
502 pub fn adjust_vmx_controls(ctl_min: u32, ctl_opt: u32, msr: u32, result: &mut u32) {
503     let vmx_msr_low: u32 = unsafe { (msr::rdmsr(msr) & 0x0000_0000_FFFF_FFFF) as u32 };
504     let vmx_msr_high: u32 = unsafe { (msr::rdmsr(msr) << 32) as u32 };
505     let mut ctl: u32 = ctl_min | ctl_opt;
506     ctl &= vmx_msr_high; /* bit == 0 in high word ==> must be zero */
507     ctl |= vmx_msr_low; /* bit == 1 in low word  ==> must be one  */
508     *result = ctl;
509 }
510 
511 pub fn adjust_vmx_entry_controls() -> u32 {
512     let mut entry_controls: u32 = 0;
513     adjust_vmx_controls(
514         VmxEntryCtrl::LOAD_DBG_CTRLS.bits(),
515         VmxEntryCtrl::IA32E_MODE_GUEST.bits(),
516         msr::IA32_VMX_ENTRY_CTLS, //Capability Reporting Register of VM-entry Controls (R/O)
517         &mut entry_controls,
518     );
519     return entry_controls;
520     // msr::IA32_VMX_TRUE_ENTRY_CTLS//Capability Reporting Register of VM-entry Flex Controls (R/O) See Table 35-2
521 }
522 
523 pub fn adjust_vmx_exit_controls() -> u32 {
524     let mut exit_controls: u32 = 0;
525     adjust_vmx_controls(
526         VmxPrimaryExitCtrl::SAVE_DBG_CTRLS.bits(),
527         VmxPrimaryExitCtrl::HOST_ADDR_SPACE_SIZE.bits(),
528         msr::IA32_VMX_EXIT_CTLS,
529         &mut exit_controls,
530     );
531     return exit_controls;
532 }
533 
534 pub fn adjust_vmx_pinbased_controls() -> u32 {
535     let mut controls: u32 = 16;
536     adjust_vmx_controls(0, 0, msr::IA32_VMX_TRUE_PINBASED_CTLS, &mut controls);
537     // debug!("adjust_vmx_pinbased_controls: {:x}", controls);
538     return controls;
539 }
540 
541 pub fn adjust_vmx_primary_process_exec_controls() -> u32 {
542     let mut controls: u32 = 0;
543     adjust_vmx_controls(
544         0,
545         VmxPrimaryProcessBasedExecuteCtrl::USE_MSR_BITMAPS.bits()
546             | VmxPrimaryProcessBasedExecuteCtrl::ACTIVATE_SECONDARY_CONTROLS.bits(),
547         msr::IA32_VMX_PROCBASED_CTLS,
548         &mut controls,
549     );
550     return controls;
551 }
552 
553 pub fn adjust_vmx_secondary_process_exec_controls() -> u32 {
554     let mut controls: u32 = 0;
555     adjust_vmx_controls(
556         0,
557         VmxSecondaryProcessBasedExecuteCtrl::ENABLE_RDTSCP.bits()
558             | VmxSecondaryProcessBasedExecuteCtrl::ENABLE_XSAVES_XRSTORS.bits()
559             | VmxSecondaryProcessBasedExecuteCtrl::ENABLE_INVPCID.bits()
560             | VmxSecondaryProcessBasedExecuteCtrl::ENABLE_EPT.bits()
561             | VmxSecondaryProcessBasedExecuteCtrl::UNRESTRICTED_GUEST.bits(),
562         msr::IA32_VMX_PROCBASED_CTLS2,
563         &mut controls,
564     );
565     return controls;
566 }
567 
568 /// Check to see if CPU is Intel (“GenuineIntel”).
569 /// Check processor supports for Virtual Machine Extension (VMX) technology
570 //  CPUID.1:ECX.VMX[bit 5] = 1 (Intel Manual: 24.6 Discovering Support for VMX)
571 pub fn has_intel_vmx_support() -> Result<(), SystemError> {
572     let cpuid = CpuId::new();
573     if let Some(vi) = cpuid.get_vendor_info() {
574         if vi.as_str() != "GenuineIntel" {
575             return Err(SystemError::ENOSYS);
576         }
577     }
578     if let Some(fi) = cpuid.get_feature_info() {
579         if !fi.has_vmx() {
580             return Err(SystemError::ENOSYS);
581         }
582     }
583     Ok(())
584 }
585 
586 /// Enables Virtual Machine Extensions
587 // - CR4.VMXE[bit 13] = 1 (Intel Manual: 24.7 Enabling and Entering VMX Operation)
588 pub fn enable_vmx_operation() -> Result<(), SystemError> {
589     let mut cr4 = unsafe { controlregs::cr4() };
590     cr4.set(controlregs::Cr4::CR4_ENABLE_VMX, true);
591     unsafe { controlregs::cr4_write(cr4) };
592 
593     set_lock_bit()?;
594     debug!("[+] Lock bit set via IA32_FEATURE_CONTROL");
595     set_cr0_bits();
596     debug!("[+] Mandatory bits in CR0 set/cleared");
597     set_cr4_bits();
598     debug!("[+] Mandatory bits in CR4 set/cleared");
599 
600     Ok(())
601 }
602 
603 /// Check if we need to set bits in IA32_FEATURE_CONTROL
604 // (Intel Manual: 24.7 Enabling and Entering VMX Operation)
605 fn set_lock_bit() -> Result<(), SystemError> {
606     const VMX_LOCK_BIT: u64 = 1 << 0;
607     const VMXON_OUTSIDE_SMX: u64 = 1 << 2;
608 
609     let ia32_feature_control = unsafe { msr::rdmsr(msr::IA32_FEATURE_CONTROL) };
610 
611     if (ia32_feature_control & VMX_LOCK_BIT) == 0 {
612         unsafe {
613             msr::wrmsr(
614                 msr::IA32_FEATURE_CONTROL,
615                 VMXON_OUTSIDE_SMX | VMX_LOCK_BIT | ia32_feature_control,
616             )
617         };
618     } else if (ia32_feature_control & VMXON_OUTSIDE_SMX) == 0 {
619         return Err(SystemError::EPERM);
620     }
621 
622     Ok(())
623 }
624 
625 /// Set the mandatory bits in CR0 and clear bits that are mandatory zero
626 /// (Intel Manual: 24.8 Restrictions on VMX Operation)
627 fn set_cr0_bits() {
628     let ia32_vmx_cr0_fixed0 = unsafe { msr::rdmsr(msr::IA32_VMX_CR0_FIXED0) };
629     let ia32_vmx_cr0_fixed1 = unsafe { msr::rdmsr(msr::IA32_VMX_CR0_FIXED1) };
630 
631     let mut cr0 = unsafe { controlregs::cr0() };
632 
633     cr0 |= controlregs::Cr0::from_bits_truncate(ia32_vmx_cr0_fixed0 as usize);
634     cr0 &= controlregs::Cr0::from_bits_truncate(ia32_vmx_cr0_fixed1 as usize);
635 
636     unsafe { controlregs::cr0_write(cr0) };
637 }
638 
639 /// Set the mandatory bits in CR4 and clear bits that are mandatory zero
640 /// (Intel Manual: 24.8 Restrictions on VMX Operation)
641 fn set_cr4_bits() {
642     let ia32_vmx_cr4_fixed0 = unsafe { msr::rdmsr(msr::IA32_VMX_CR4_FIXED0) };
643     let ia32_vmx_cr4_fixed1 = unsafe { msr::rdmsr(msr::IA32_VMX_CR4_FIXED1) };
644 
645     let mut cr4 = unsafe { controlregs::cr4() };
646 
647     cr4 |= controlregs::Cr4::from_bits_truncate(ia32_vmx_cr4_fixed0 as usize);
648     cr4 &= controlregs::Cr4::from_bits_truncate(ia32_vmx_cr4_fixed1 as usize);
649 
650     unsafe { controlregs::cr4_write(cr4) };
651 }
652