OvmfPkg/Library/CcExitLib/CcExitVeHandler.c - third_party/edk2 - Git at Google

 /** @file

   Copyright (c) 2021, Intel Corporation. All rights reserved.<BR>

   SPDX-License-Identifier: BSD-2-Clause-Patent

 **/

 #include <Library/BaseLib.h>
 #include <Library/DebugLib.h>
 #include "CcExitTd.h"
 #include <Library/CcExitLib.h>
 #include <Library/BaseMemoryLib.h>
 #include <IndustryStandard/Tdx.h>
 #include <IndustryStandard/InstructionParsing.h>
 #include "CcInstruction.h"

 #define TDX_MMIO_READ   0
 #define TDX_MMIO_WRITE  1

 typedef union {
   struct {
     UINT32    Eax;
     UINT32    Edx;
   } Regs;
   UINT64    Val;
 } MSR_DATA;

 typedef union {
   UINT8    Val;
   struct {
     UINT8    B : 1;
     UINT8    X : 1;
     UINT8    R : 1;
     UINT8    W : 1;
   } Bits;
 } REX;

 typedef union {
   UINT8    Val;
   struct {
     UINT8    Rm  : 3;
     UINT8    Reg : 3;
     UINT8    Mod : 2;
   } Bits;
 } MODRM;

 typedef struct {
   UINT64    Regs[4];
 } CPUID_DATA;

 /**
   Handle an CPUID event.

   Use the TDVMCALL instruction to handle cpuid #ve

   @param[in, out] Regs             x64 processor context
   @param[in]      Veinfo           VE Info

   @retval 0                        Event handled successfully
   @return                          New exception value to propagate
 **/
 STATIC
 UINT64
 EFIAPI
 CpuIdExit (
   IN EFI_SYSTEM_CONTEXT_X64     *Regs,
   IN TDCALL_VEINFO_RETURN_DATA  *Veinfo
   )
 {
   CPUID_DATA  CpuIdData;
   UINT64      Status;

   Status = TdVmCallCpuid (Regs->Rax, Regs->Rcx, &CpuIdData);

   if (Status == 0) {
     Regs->Rax = CpuIdData.Regs[0];
     Regs->Rbx = CpuIdData.Regs[1];
     Regs->Rcx = CpuIdData.Regs[2];
     Regs->Rdx = CpuIdData.Regs[3];
   }

   return Status;
 }

 /**
   Handle an IO event.

   Use the TDVMCALL instruction to handle either an IO read or an IO write.

   @param[in, out] Regs             x64 processor context
   @param[in]      Veinfo           VE Info

   @retval 0                        Event handled successfully
   @return                          New exception value to propagate
 **/
 STATIC
 UINT64
 EFIAPI
 IoExit (
   IN OUT EFI_SYSTEM_CONTEXT_X64  *Regs,
   IN TDCALL_VEINFO_RETURN_DATA   *Veinfo
   )
 {
   BOOLEAN  Write;
   UINTN    Size;
   UINTN    Port;
   UINT64   Val;
   UINT64   RepCnt;
   UINT64   Status;

   Val    = 0;
   Status = 0;
   Write  = Veinfo->ExitQualification.Io.Direction ? FALSE : TRUE;
   Size   = Veinfo->ExitQualification.Io.Size + 1;
   Port   = Veinfo->ExitQualification.Io.Port;

   if (Veinfo->ExitQualification.Io.String) {
     //
     // If REP is set, get rep-cnt from Rcx
     //
     RepCnt = Veinfo->ExitQualification.Io.Rep ? Regs->Rcx : 1;

     while (RepCnt) {
       Val = 0;
       if (Write == TRUE) {
         CopyMem (&Val, (VOID *)Regs->Rsi, Size);
         Regs->Rsi += Size;
       }

       Status = TdVmCall (EXIT_REASON_IO_INSTRUCTION, Size, Write, Port, Val, (Write ? NULL : &Val));
       if (Status != 0) {
         break;
       }

       if (Write == FALSE) {
         CopyMem ((VOID *)Regs->Rdi, &Val, Size);
         Regs->Rdi += Size;
       }

       if (Veinfo->ExitQualification.Io.Rep) {
         Regs->Rcx -= 1;
       }

       RepCnt -= 1;
     }
   } else {
     if (Write == TRUE) {
       CopyMem (&Val, (VOID *)&Regs->Rax, Size);
     }

     Status = TdVmCall (EXIT_REASON_IO_INSTRUCTION, Size, Write, Port, Val, (Write ? NULL : &Val));
     if ((Status == 0) && (Write == FALSE)) {
       CopyMem ((VOID *)&Regs->Rax, &Val, Size);
     }
   }

   return Status;
 }

 /**
   Handle an READ MSR event.

   Use the TDVMCALL instruction to handle msr read

   @param[in, out] Regs             x64 processor context
   @param[in]      Veinfo           VE Info

   @retval 0                        Event handled successfully
   @return                          New exception value to propagate
 **/
 STATIC
 UINT64
 ReadMsrExit (
   IN OUT EFI_SYSTEM_CONTEXT_X64  *Regs,
   IN TDCALL_VEINFO_RETURN_DATA   *Veinfo
   )
 {
   MSR_DATA  Data;
   UINT64    Status;

   Status = TdVmCall (EXIT_REASON_MSR_READ, Regs->Rcx, 0, 0, 0, &Data);
   if (Status == 0) {
     Regs->Rax = Data.Regs.Eax;
     Regs->Rdx = Data.Regs.Edx;
   }

   return Status;
 }

 /**
   Handle an WRITE MSR event.

   Use the TDVMCALL instruction to handle msr write

   @param[in, out] Regs             x64 processor context
   @param[in]      Veinfo           VE Info

   @retval 0                        Event handled successfully
   @return                          New exception value to propagate
 **/
 STATIC
 UINT64
 WriteMsrExit (
   IN OUT EFI_SYSTEM_CONTEXT_X64  *Regs,
   IN TDCALL_VEINFO_RETURN_DATA   *Veinfo
   )
 {
   UINT64    Status;
   MSR_DATA  Data;

   Data.Regs.Eax = (UINT32)Regs->Rax;
   Data.Regs.Edx = (UINT32)Regs->Rdx;

   Status =  TdVmCall (EXIT_REASON_MSR_WRITE, Regs->Rcx, Data.Val, 0, 0, NULL);

   return Status;
 }

 STATIC
 VOID
 EFIAPI
 TdxDecodeInstruction (
   IN UINT8   *Rip,
   IN UINT32  Length
   )
 {
   UINTN  i;

   DEBUG ((DEBUG_INFO, "TDX: #TD[EPT] instruction (%p):", Rip));
   for (i = 0; i < MIN (15, Length); i++) {
     DEBUG ((DEBUG_INFO, "%02x ", Rip[i]));
   }

   DEBUG ((DEBUG_INFO, "\n"));
 }

 #define TDX_DECODER_BUG_ON(x)               \
   if ((x)) {                                \
     TdxDecodeInstruction(Rip);              \
     TdVmCall(TDVMCALL_HALT, 0, 0, 0, 0, 0); \
     CpuDeadLoop (); \
   }

 /**
  * Tdx MMIO access via TdVmcall.
  *
  * @param MmioSize      Size of the MMIO access
  * @param ReadOrWrite   Read or write operation
  * @param GuestPA       Guest physical address
  * @param Val           Pointer to the value which is read or written

  * @retval EFI_SUCCESS  Successfully access the mmio
  * @retval Others       Other errors as indicated
  */
 STATIC
 EFI_STATUS
 TdxMmioReadWrite (
   IN UINT32  MmioSize,
   IN UINT32  ReadOrWrite,
   IN UINT64  GuestPA,
   IN UINT64  *Val
   )
 {
   UINT64  TdStatus;

   if ((MmioSize != 1) && (MmioSize != 2) && (MmioSize != 4) && (MmioSize != 8)) {
     DEBUG ((DEBUG_ERROR, "%a: Invalid MmioSize - %d\n", __func__, MmioSize));
     return EFI_INVALID_PARAMETER;
   }

   if (Val == NULL) {
     return EFI_INVALID_PARAMETER;
   }

   TdStatus = 0;
   if (ReadOrWrite == TDX_MMIO_READ) {
     TdStatus = TdVmCall (TDVMCALL_MMIO, MmioSize, TDX_MMIO_READ, GuestPA, 0, Val);
   } else if (ReadOrWrite == TDX_MMIO_WRITE) {
     TdStatus = TdVmCall (TDVMCALL_MMIO, MmioSize, TDX_MMIO_WRITE, GuestPA, *Val, 0);
   } else {
     return EFI_INVALID_PARAMETER;
   }

   if (TdStatus != 0) {
     DEBUG ((DEBUG_ERROR, "%a: TdVmcall failed with %llx\n", __func__, TdStatus));
     return EFI_ABORTED;
   }

   return EFI_SUCCESS;
 }

 typedef struct {
   UINT8                   OpCode;
   UINT32                  Bytes;
   EFI_PHYSICAL_ADDRESS    Address;
   UINT64                  Val;
   UINT64                  *Register;
   UINT32                  ReadOrWrite;
 } MMIO_EXIT_PARSED_INSTRUCTION;

 /**
  * Parse the MMIO instructions.
  *
  * @param Regs              Pointer to the EFI_SYSTEM_CONTEXT_X64 which includes the instructions
  * @param InstructionData   Pointer to the CC_INSTRUCTION_DATA
  * @param ParsedInstruction Pointer to the parsed instruction data
  *
  * @retval EFI_SUCCESS      Successfully parsed the instructions
  * @retval Others           Other error as indicated
  */
 STATIC
 EFI_STATUS
 ParseMmioExitInstructions (
   IN OUT EFI_SYSTEM_CONTEXT_X64     *Regs,
   IN OUT CC_INSTRUCTION_DATA        *InstructionData,
   OUT MMIO_EXIT_PARSED_INSTRUCTION  *ParsedInstruction
   )
 {
   EFI_STATUS            Status;
   UINT8                 OpCode;
   UINT8                 SignByte;
   UINT32                Bytes;
   EFI_PHYSICAL_ADDRESS  Address;
   UINT64                Val;
   UINT64                *Register;
   UINT32                ReadOrWrite;

   Address  = 0;
   Bytes    = 0;
   Register = NULL;
   Status   = EFI_SUCCESS;
   Val      = 0;

   Status = CcInitInstructionData (InstructionData, NULL, Regs);
   if (EFI_ERROR (Status)) {
     DEBUG ((DEBUG_ERROR, "%a: Initialize InstructionData failed! (%r)\n", __func__, Status));
     return Status;
   }

   OpCode = *(InstructionData->OpCodes);
   if (OpCode == TWO_BYTE_OPCODE_ESCAPE) {
     OpCode = *(InstructionData->OpCodes + 1);
   }

   switch (OpCode) {
     //
     // MMIO write (MOV reg/memX, regX)
     //
     case 0x88:
       Bytes = 1;
     //
     // fall through
     //
     case 0x89:
       CcDecodeModRm (Regs, InstructionData);
       Bytes = ((Bytes != 0) ? Bytes :
                (InstructionData->DataSize == Size16Bits) ? 2 :
                (InstructionData->DataSize == Size32Bits) ? 4 :
                (InstructionData->DataSize == Size64Bits) ? 8 :
                0);

       if (InstructionData->Ext.ModRm.Mod == 3) {
         DEBUG ((DEBUG_ERROR, "%a: Parse Ext.ModRm.Mod error! (OpCode: 0x%x)\n", __func__, OpCode));
         return EFI_UNSUPPORTED;
       }

       Address     = InstructionData->Ext.RmData;
       Val         = InstructionData->Ext.RegData;
       ReadOrWrite = TDX_MMIO_WRITE;

       break;

     //
     // MMIO write (MOV moffsetX, aX)
     //
     case 0xA2:
       Bytes = 1;
     //
     // fall through
     //
     case 0xA3:
       Bytes = ((Bytes != 0) ? Bytes :
                (InstructionData->DataSize == Size16Bits) ? 2 :
                (InstructionData->DataSize == Size32Bits) ? 4 :
                (InstructionData->DataSize == Size64Bits) ? 8 :
                0);

       InstructionData->ImmediateSize = (UINTN)(1 << InstructionData->AddrSize);
       InstructionData->End          += InstructionData->ImmediateSize;
       CopyMem (&Address, InstructionData->Immediate, InstructionData->ImmediateSize);

       Val         = Regs->Rax;
       ReadOrWrite = TDX_MMIO_WRITE;
       break;

     //
     // MMIO write (MOV reg/memX, immX)
     //
     case 0xC6:
       Bytes = 1;
     //
     // fall through
     //
     case 0xC7:
       CcDecodeModRm (Regs, InstructionData);
       Bytes = ((Bytes != 0) ? Bytes :
                (InstructionData->DataSize == Size16Bits) ? 2 :
                (InstructionData->DataSize == Size32Bits) ? 4 :
                (InstructionData->DataSize == Size64Bits) ? 8 :
                0);

       InstructionData->ImmediateSize = Bytes;
       InstructionData->End          += Bytes;

       Val = 0;
       CopyMem (&Val, InstructionData->Immediate, InstructionData->ImmediateSize);

       Address     = InstructionData->Ext.RmData;
       ReadOrWrite = TDX_MMIO_WRITE;

       break;

     //
     // MMIO read (MOV regX, reg/memX)
     //
     case 0x8A:
       Bytes = 1;
     //
     // fall through
     //
     case 0x8B:
       CcDecodeModRm (Regs, InstructionData);
       Bytes = ((Bytes != 0) ? Bytes :
                (InstructionData->DataSize == Size16Bits) ? 2 :
                (InstructionData->DataSize == Size32Bits) ? 4 :
                (InstructionData->DataSize == Size64Bits) ? 8 :
                0);
       if (InstructionData->Ext.ModRm.Mod == 3) {
         //
         // NPF on two register operands???
         //
         DEBUG ((DEBUG_ERROR, "%a: Parse Ext.ModRm.Mod error! (OpCode: 0x%x)\n", __func__, OpCode));
         return EFI_UNSUPPORTED;
       }

       Address     = InstructionData->Ext.RmData;
       ReadOrWrite = TDX_MMIO_READ;

       Register = CcGetRegisterPointer (Regs, InstructionData->Ext.ModRm.Reg);
       if (Register == NULL) {
         return EFI_ABORTED;
       }

       if (Bytes == 4) {
         //
         // Zero-extend for 32-bit operation
         //
         *Register = 0;
       }

       break;

     //
     // MMIO read (MOV aX, moffsetX)
     //
     case 0xA0:
       Bytes = 1;
     //
     // fall through
     //
     case 0xA1:
       Bytes = ((Bytes != 0) ? Bytes :
                (InstructionData->DataSize == Size16Bits) ? 2 :
                (InstructionData->DataSize == Size32Bits) ? 4 :
                (InstructionData->DataSize == Size64Bits) ? 8 :
                0);

       InstructionData->ImmediateSize = (UINTN)(1 << InstructionData->AddrSize);
       InstructionData->End          += InstructionData->ImmediateSize;

       Address = 0;
       CopyMem (
         &Address,
         InstructionData->Immediate,
         InstructionData->ImmediateSize
         );

       if (Bytes == 4) {
         //
         // Zero-extend for 32-bit operation
         //
         Regs->Rax = 0;
       }

       Register    = &Regs->Rax;
       ReadOrWrite = TDX_MMIO_READ;

       break;

     //
     // MMIO read w/ zero-extension ((MOVZX regX, reg/memX)
     //
     case 0xB6:
       Bytes = 1;
     //
     // fall through
     //
     case 0xB7:
       CcDecodeModRm (Regs, InstructionData);
       Bytes   = (Bytes != 0) ? Bytes : 2;
       Address = InstructionData->Ext.RmData;

       Register = CcGetRegisterPointer (Regs, InstructionData->Ext.ModRm.Reg);
       if (Register == NULL) {
         return EFI_ABORTED;
       }

       SetMem (Register, (UINTN)(1 << InstructionData->DataSize), 0);

       ReadOrWrite = TDX_MMIO_READ;

       break;

     //
     // MMIO read w/ sign-extension (MOVSX regX, reg/memX)
     //
     case 0xBE:
       Bytes = 1;
     //
     // fall through
     //
     case 0xBF:
       CcDecodeModRm (Regs, InstructionData);
       Bytes = (Bytes != 0) ? Bytes : 2;

       Address = InstructionData->Ext.RmData;

       if (Bytes == 1) {
         UINT8  *Data;
         Data     = (UINT8 *)&Val;
         SignByte = ((*Data & BIT7) != 0) ? 0xFF : 0x00;
       } else {
         UINT16  *Data;
         Data     = (UINT16 *)&Val;
         SignByte = ((*Data & BIT15) != 0) ? 0xFF : 0x00;
       }

       Register = CcGetRegisterPointer (Regs, InstructionData->Ext.ModRm.Reg);
       if (Register == NULL) {
         return EFI_ABORTED;
       }

       SetMem (Register, (UINTN)(1 << InstructionData->DataSize), SignByte);

       ReadOrWrite = TDX_MMIO_READ;

       break;

     default:
       DEBUG ((DEBUG_ERROR, "%a: Invalid MMIO opcode (%x)\n", __func__, OpCode));
       Status = EFI_UNSUPPORTED;
   }

   if (!EFI_ERROR (Status)) {
     ParsedInstruction->OpCode      = OpCode;
     ParsedInstruction->Address     = Address;
     ParsedInstruction->Bytes       = Bytes;
     ParsedInstruction->Register    = Register;
     ParsedInstruction->Val         = Val;
     ParsedInstruction->ReadOrWrite = ReadOrWrite;
   }

   return Status;
 }

 /**
   Handle an MMIO event.

   Use the TDVMCALL instruction to handle either an mmio read or an mmio write.

   @param[in, out] Regs             x64 processor context
   @param[in]      Veinfo           VE Info

   @retval 0                        Event handled successfully
 **/
 STATIC
 UINT64
 EFIAPI
 MmioExit (
   IN OUT EFI_SYSTEM_CONTEXT_X64  *Regs,
   IN TDCALL_VEINFO_RETURN_DATA   *Veinfo
   )
 {
   UINT64                        TdStatus;
   EFI_STATUS                    Status;
   TD_RETURN_DATA                TdReturnData;
   UINT8                         Gpaw;
   UINT64                        Val;
   UINT64                        TdSharedPageMask;
   CC_INSTRUCTION_DATA           InstructionData;
   MMIO_EXIT_PARSED_INSTRUCTION  ParsedInstruction;

   TdStatus = TdCall (TDCALL_TDINFO, 0, 0, 0, &TdReturnData);
   if (TdStatus == TDX_EXIT_REASON_SUCCESS) {
     Gpaw             = (UINT8)(TdReturnData.TdInfo.Gpaw & 0x3f);
     TdSharedPageMask = 1ULL << (Gpaw - 1);
   } else {
     DEBUG ((DEBUG_ERROR, "%a: TDCALL failed with status=%llx\n", __func__, TdStatus));
     goto FatalError;
   }

   if ((Veinfo->GuestPA & TdSharedPageMask) == 0) {
     DEBUG ((DEBUG_ERROR, "%a: EPT-violation #VE on private memory is not allowed!", __func__));
     goto FatalError;
   }

   Status = ParseMmioExitInstructions (Regs, &InstructionData, &ParsedInstruction);
   if (EFI_ERROR (Status)) {
     goto FatalError;
   }

   if (Veinfo->GuestPA != (ParsedInstruction.Address | TdSharedPageMask)) {
     DEBUG ((
       DEBUG_ERROR,
       "%a: Address is not correct! (%d: 0x%llx != 0x%llx)\n",
       __func__,
       ParsedInstruction.OpCode,
       Veinfo->GuestPA,
       ParsedInstruction.Address
       ));
     goto FatalError;
   }

   if (ParsedInstruction.ReadOrWrite == TDX_MMIO_WRITE ) {
     Status = TdxMmioReadWrite (ParsedInstruction.Bytes, TDX_MMIO_WRITE, Veinfo->GuestPA, &ParsedInstruction.Val);
   } else if (ParsedInstruction.ReadOrWrite == TDX_MMIO_READ) {
     Val    = 0;
     Status = TdxMmioReadWrite (ParsedInstruction.Bytes, TDX_MMIO_READ, Veinfo->GuestPA, &Val);
     if (!EFI_ERROR (Status)) {
       CopyMem (ParsedInstruction.Register, &Val, ParsedInstruction.Bytes);
     }
   } else {
     goto FatalError;
   }

   if (EFI_ERROR (Status)) {
     goto FatalError;
   }

   //
   // We change instruction length to reflect true size so handler can
   // bump rip
   //
   Veinfo->ExitInstructionLength =  (UINT32)(CcInstructionLength (&InstructionData));
   TdxDecodeInstruction ((UINT8 *)Regs->Rip, Veinfo->ExitInstructionLength);

   return 0;

 FatalError:
   TdVmCall (TDVMCALL_HALT, 0, 0, 0, 0, 0);
   CpuDeadLoop ();
   return 0;
 }

 /**
   Handle a #VE exception.

   Performs the necessary processing to handle a #VE exception.

   @param[in, out]  ExceptionType  Pointer to an EFI_EXCEPTION_TYPE to be set
                                   as value to use on error.
   @param[in, out]  SystemContext  Pointer to EFI_SYSTEM_CONTEXT

   @retval  EFI_SUCCESS            Exception handled
   @retval  EFI_UNSUPPORTED        #VE not supported, (new) exception value to
                                   propagate provided
   @retval  EFI_PROTOCOL_ERROR     #VE handling failed, (new) exception value to
                                   propagate provided

 **/
 EFI_STATUS
 EFIAPI
 CcExitHandleVe (
   IN OUT EFI_EXCEPTION_TYPE  *ExceptionType,
   IN OUT EFI_SYSTEM_CONTEXT  SystemContext
   )
 {
   UINT64                  Status;
   TD_RETURN_DATA          ReturnData;
   EFI_SYSTEM_CONTEXT_X64  *Regs;

   Regs   = SystemContext.SystemContextX64;
   Status = TdCall (TDCALL_TDGETVEINFO, 0, 0, 0, &ReturnData);
   ASSERT (Status == 0);
   if (Status != 0) {
     DEBUG ((DEBUG_ERROR, "#VE happened. TDGETVEINFO failed with Status = 0x%llx\n", Status));
     TdVmCall (TDVMCALL_HALT, 0, 0, 0, 0, 0);
     CpuDeadLoop ();
   }

   switch (ReturnData.VeInfo.ExitReason) {
     case EXIT_REASON_CPUID:
       Status = CpuIdExit (Regs, &ReturnData.VeInfo);
       DEBUG ((
         DEBUG_VERBOSE,
         "CPUID #VE happened, ExitReasion is %d, ExitQualification = 0x%x.\n",
         ReturnData.VeInfo.ExitReason,
         ReturnData.VeInfo.ExitQualification.Val
         ));
       break;

     case EXIT_REASON_HLT:
       Status = TdVmCall (EXIT_REASON_HLT, 0, 0, 0, 0, 0);
       break;

     case EXIT_REASON_IO_INSTRUCTION:
       Status = IoExit (Regs, &ReturnData.VeInfo);
       DEBUG ((
         DEBUG_VERBOSE,
         "IO_Instruction #VE happened, ExitReasion is %d, ExitQualification = 0x%x.\n",
         ReturnData.VeInfo.ExitReason,
         ReturnData.VeInfo.ExitQualification.Val
         ));
       break;

     case EXIT_REASON_MSR_READ:
       Status = ReadMsrExit (Regs, &ReturnData.VeInfo);
       DEBUG ((
         DEBUG_VERBOSE,
         "RDMSR #VE happened, ExitReasion is %d, ExitQualification = 0x%x. Regs->Rcx=0x%llx, Status = 0x%llx\n",
         ReturnData.VeInfo.ExitReason,
         ReturnData.VeInfo.ExitQualification.Val,
         Regs->Rcx,
         Status
         ));
       break;

     case EXIT_REASON_MSR_WRITE:
       Status = WriteMsrExit (Regs, &ReturnData.VeInfo);
       DEBUG ((
         DEBUG_VERBOSE,
         "WRMSR #VE happened, ExitReasion is %d, ExitQualification = 0x%x. Regs->Rcx=0x%llx, Status = 0x%llx\n",
         ReturnData.VeInfo.ExitReason,
         ReturnData.VeInfo.ExitQualification.Val,
         Regs->Rcx,
         Status
         ));
       break;

     case EXIT_REASON_EPT_VIOLATION:
       Status = MmioExit (Regs, &ReturnData.VeInfo);
       DEBUG ((
         DEBUG_VERBOSE,
         "MMIO #VE happened, ExitReasion is %d, ExitQualification = 0x%x.\n",
         ReturnData.VeInfo.ExitReason,
         ReturnData.VeInfo.ExitQualification.Val
         ));
       break;

     case EXIT_REASON_VMCALL:
     case EXIT_REASON_MWAIT_INSTRUCTION:
     case EXIT_REASON_MONITOR_INSTRUCTION:
     case EXIT_REASON_WBINVD:
     case EXIT_REASON_RDPMC:
     case EXIT_REASON_INVD:
       /* Handle as nops. */
       break;

     default:
       DEBUG ((
         DEBUG_ERROR,
         "Unsupported #VE happened, ExitReason is %d, ExitQualification = 0x%x.\n",
         ReturnData.VeInfo.ExitReason,
         ReturnData.VeInfo.ExitQualification.Val
         ));

       ASSERT (FALSE);
       CpuDeadLoop ();
   }

   if (Status) {
     DEBUG ((
       DEBUG_ERROR,
       "#VE Error (0x%llx) returned from host, ExitReason is %d, ExitQualification = 0x%x.\n",
       Status,
       ReturnData.VeInfo.ExitReason,
       ReturnData.VeInfo.ExitQualification.Val
       ));

     TdVmCall (TDVMCALL_HALT, 0, 0, 0, 0, 0);
     CpuDeadLoop ();
   }

   SystemContext.SystemContextX64->Rip += ReturnData.VeInfo.ExitInstructionLength;
   return EFI_SUCCESS;
 }
	/** @file

	Copyright (c) 2021, Intel Corporation. All rights reserved.<BR>

	SPDX-License-Identifier: BSD-2-Clause-Patent

	**/

	#include <Library/BaseLib.h>
	#include <Library/DebugLib.h>
	#include "CcExitTd.h"
	#include <Library/CcExitLib.h>
	#include <Library/BaseMemoryLib.h>
	#include <IndustryStandard/Tdx.h>
	#include <IndustryStandard/InstructionParsing.h>
	#include "CcInstruction.h"

	#define TDX_MMIO_READ 0
	#define TDX_MMIO_WRITE 1

	typedef union {
	struct {
	UINT32 Eax;
	UINT32 Edx;
	} Regs;
	UINT64 Val;
	} MSR_DATA;

	typedef union {
	UINT8 Val;
	struct {
	UINT8 B : 1;
	UINT8 X : 1;
	UINT8 R : 1;
	UINT8 W : 1;
	} Bits;
	} REX;

	typedef union {
	UINT8 Val;
	struct {
	UINT8 Rm : 3;
	UINT8 Reg : 3;
	UINT8 Mod : 2;
	} Bits;
	} MODRM;

	typedef struct {
	UINT64 Regs[4];
	} CPUID_DATA;

	/**
	Handle an CPUID event.

	Use the TDVMCALL instruction to handle cpuid #ve

	@param[in, out] Regs x64 processor context
	@param[in] Veinfo VE Info

	@retval 0 Event handled successfully
	@return New exception value to propagate
	**/
	STATIC
	UINT64
	EFIAPI
	CpuIdExit (
	IN EFI_SYSTEM_CONTEXT_X64 *Regs,
	IN TDCALL_VEINFO_RETURN_DATA *Veinfo
	)
	{
	CPUID_DATA CpuIdData;
	UINT64 Status;

	Status = TdVmCallCpuid (Regs->Rax, Regs->Rcx, &CpuIdData);

	if (Status == 0) {
	Regs->Rax = CpuIdData.Regs[0];
	Regs->Rbx = CpuIdData.Regs[1];
	Regs->Rcx = CpuIdData.Regs[2];
	Regs->Rdx = CpuIdData.Regs[3];
	}

	return Status;
	}

	/**
	Handle an IO event.

	Use the TDVMCALL instruction to handle either an IO read or an IO write.

	@param[in, out] Regs x64 processor context
	@param[in] Veinfo VE Info

	@retval 0 Event handled successfully
	@return New exception value to propagate
	**/
	STATIC
	UINT64
	EFIAPI
	IoExit (
	IN OUT EFI_SYSTEM_CONTEXT_X64 *Regs,
	IN TDCALL_VEINFO_RETURN_DATA *Veinfo
	)
	{
	BOOLEAN Write;
	UINTN Size;
	UINTN Port;
	UINT64 Val;
	UINT64 RepCnt;
	UINT64 Status;

	Val = 0;
	Status = 0;
	Write = Veinfo->ExitQualification.Io.Direction ? FALSE : TRUE;
	Size = Veinfo->ExitQualification.Io.Size + 1;
	Port = Veinfo->ExitQualification.Io.Port;

	if (Veinfo->ExitQualification.Io.String) {
	//
	// If REP is set, get rep-cnt from Rcx
	//
	RepCnt = Veinfo->ExitQualification.Io.Rep ? Regs->Rcx : 1;

	while (RepCnt) {
	Val = 0;
	if (Write == TRUE) {
	CopyMem (&Val, (VOID *)Regs->Rsi, Size);
	Regs->Rsi += Size;
	}

	Status = TdVmCall (EXIT_REASON_IO_INSTRUCTION, Size, Write, Port, Val, (Write ? NULL : &Val));
	if (Status != 0) {
	break;
	}

	if (Write == FALSE) {
	CopyMem ((VOID *)Regs->Rdi, &Val, Size);
	Regs->Rdi += Size;
	}

	if (Veinfo->ExitQualification.Io.Rep) {
	Regs->Rcx -= 1;
	}

	RepCnt -= 1;
	}
	} else {
	if (Write == TRUE) {
	CopyMem (&Val, (VOID *)&Regs->Rax, Size);
	}

	Status = TdVmCall (EXIT_REASON_IO_INSTRUCTION, Size, Write, Port, Val, (Write ? NULL : &Val));
	if ((Status == 0) && (Write == FALSE)) {
	CopyMem ((VOID *)&Regs->Rax, &Val, Size);
	}
	}

	return Status;
	}

	/**
	Handle an READ MSR event.

	Use the TDVMCALL instruction to handle msr read

	@param[in, out] Regs x64 processor context
	@param[in] Veinfo VE Info

	@retval 0 Event handled successfully
	@return New exception value to propagate
	**/
	STATIC
	UINT64
	ReadMsrExit (
	IN OUT EFI_SYSTEM_CONTEXT_X64 *Regs,
	IN TDCALL_VEINFO_RETURN_DATA *Veinfo
	)
	{
	MSR_DATA Data;
	UINT64 Status;

	Status = TdVmCall (EXIT_REASON_MSR_READ, Regs->Rcx, 0, 0, 0, &Data);
	if (Status == 0) {
	Regs->Rax = Data.Regs.Eax;
	Regs->Rdx = Data.Regs.Edx;
	}

	return Status;
	}

	/**
	Handle an WRITE MSR event.

	Use the TDVMCALL instruction to handle msr write

	@param[in, out] Regs x64 processor context
	@param[in] Veinfo VE Info

	@retval 0 Event handled successfully
	@return New exception value to propagate
	**/
	STATIC
	UINT64
	WriteMsrExit (
	IN OUT EFI_SYSTEM_CONTEXT_X64 *Regs,
	IN TDCALL_VEINFO_RETURN_DATA *Veinfo
	)
	{
	UINT64 Status;
	MSR_DATA Data;

	Data.Regs.Eax = (UINT32)Regs->Rax;
	Data.Regs.Edx = (UINT32)Regs->Rdx;

	Status = TdVmCall (EXIT_REASON_MSR_WRITE, Regs->Rcx, Data.Val, 0, 0, NULL);

	return Status;
	}

	STATIC
	VOID
	EFIAPI
	TdxDecodeInstruction (
	IN UINT8 *Rip,
	IN UINT32 Length
	)
	{
	UINTN i;

	DEBUG ((DEBUG_INFO, "TDX: #TD[EPT] instruction (%p):", Rip));
	for (i = 0; i < MIN (15, Length); i++) {
	DEBUG ((DEBUG_INFO, "%02x ", Rip[i]));
	}

	DEBUG ((DEBUG_INFO, "\n"));
	}

	#define TDX_DECODER_BUG_ON(x) \
	if ((x)) { \
	TdxDecodeInstruction(Rip); \
	TdVmCall(TDVMCALL_HALT, 0, 0, 0, 0, 0); \
	CpuDeadLoop (); \
	}

	/**
	* Tdx MMIO access via TdVmcall.
	*
	* @param MmioSize Size of the MMIO access
	* @param ReadOrWrite Read or write operation
	* @param GuestPA Guest physical address
	* @param Val Pointer to the value which is read or written

	* @retval EFI_SUCCESS Successfully access the mmio
	* @retval Others Other errors as indicated
	*/
	STATIC
	EFI_STATUS
	TdxMmioReadWrite (
	IN UINT32 MmioSize,
	IN UINT32 ReadOrWrite,
	IN UINT64 GuestPA,
	IN UINT64 *Val
	)
	{
	UINT64 TdStatus;

	if ((MmioSize != 1) && (MmioSize != 2) && (MmioSize != 4) && (MmioSize != 8)) {
	DEBUG ((DEBUG_ERROR, "%a: Invalid MmioSize - %d\n", __func__, MmioSize));
	return EFI_INVALID_PARAMETER;
	}

	if (Val == NULL) {
	return EFI_INVALID_PARAMETER;
	}

	TdStatus = 0;
	if (ReadOrWrite == TDX_MMIO_READ) {
	TdStatus = TdVmCall (TDVMCALL_MMIO, MmioSize, TDX_MMIO_READ, GuestPA, 0, Val);
	} else if (ReadOrWrite == TDX_MMIO_WRITE) {
	TdStatus = TdVmCall (TDVMCALL_MMIO, MmioSize, TDX_MMIO_WRITE, GuestPA, *Val, 0);
	} else {
	return EFI_INVALID_PARAMETER;
	}

	if (TdStatus != 0) {
	DEBUG ((DEBUG_ERROR, "%a: TdVmcall failed with %llx\n", __func__, TdStatus));
	return EFI_ABORTED;
	}

	return EFI_SUCCESS;
	}

	typedef struct {
	UINT8 OpCode;
	UINT32 Bytes;
	EFI_PHYSICAL_ADDRESS Address;
	UINT64 Val;
	UINT64 *Register;
	UINT32 ReadOrWrite;
	} MMIO_EXIT_PARSED_INSTRUCTION;

	/**
	* Parse the MMIO instructions.
	*
	* @param Regs Pointer to the EFI_SYSTEM_CONTEXT_X64 which includes the instructions
	* @param InstructionData Pointer to the CC_INSTRUCTION_DATA
	* @param ParsedInstruction Pointer to the parsed instruction data
	*
	* @retval EFI_SUCCESS Successfully parsed the instructions
	* @retval Others Other error as indicated
	*/
	STATIC
	EFI_STATUS
	ParseMmioExitInstructions (
	IN OUT EFI_SYSTEM_CONTEXT_X64 *Regs,
	IN OUT CC_INSTRUCTION_DATA *InstructionData,
	OUT MMIO_EXIT_PARSED_INSTRUCTION *ParsedInstruction
	)
	{
	EFI_STATUS Status;
	UINT8 OpCode;
	UINT8 SignByte;
	UINT32 Bytes;
	EFI_PHYSICAL_ADDRESS Address;
	UINT64 Val;
	UINT64 *Register;
	UINT32 ReadOrWrite;

	Address = 0;
	Bytes = 0;
	Register = NULL;
	Status = EFI_SUCCESS;
	Val = 0;

	Status = CcInitInstructionData (InstructionData, NULL, Regs);
	if (EFI_ERROR (Status)) {
	DEBUG ((DEBUG_ERROR, "%a: Initialize InstructionData failed! (%r)\n", __func__, Status));
	return Status;
	}

	OpCode = *(InstructionData->OpCodes);
	if (OpCode == TWO_BYTE_OPCODE_ESCAPE) {
	OpCode = *(InstructionData->OpCodes + 1);
	}

	switch (OpCode) {
	//
	// MMIO write (MOV reg/memX, regX)
	//
	case 0x88:
	Bytes = 1;
	//
	// fall through
	//
	case 0x89:
	CcDecodeModRm (Regs, InstructionData);
	Bytes = ((Bytes != 0) ? Bytes :
	(InstructionData->DataSize == Size16Bits) ? 2 :
	(InstructionData->DataSize == Size32Bits) ? 4 :
	(InstructionData->DataSize == Size64Bits) ? 8 :
	0);

	if (InstructionData->Ext.ModRm.Mod == 3) {
	DEBUG ((DEBUG_ERROR, "%a: Parse Ext.ModRm.Mod error! (OpCode: 0x%x)\n", __func__, OpCode));
	return EFI_UNSUPPORTED;
	}

	Address = InstructionData->Ext.RmData;
	Val = InstructionData->Ext.RegData;
	ReadOrWrite = TDX_MMIO_WRITE;

	break;

	//
	// MMIO write (MOV moffsetX, aX)
	//
	case 0xA2:
	Bytes = 1;
	//
	// fall through
	//
	case 0xA3:
	Bytes = ((Bytes != 0) ? Bytes :
	(InstructionData->DataSize == Size16Bits) ? 2 :
	(InstructionData->DataSize == Size32Bits) ? 4 :
	(InstructionData->DataSize == Size64Bits) ? 8 :
	0);

	InstructionData->ImmediateSize = (UINTN)(1 << InstructionData->AddrSize);
	InstructionData->End += InstructionData->ImmediateSize;
	CopyMem (&Address, InstructionData->Immediate, InstructionData->ImmediateSize);

	Val = Regs->Rax;
	ReadOrWrite = TDX_MMIO_WRITE;
	break;

	//
	// MMIO write (MOV reg/memX, immX)
	//
	case 0xC6:
	Bytes = 1;
	//
	// fall through
	//
	case 0xC7:
	CcDecodeModRm (Regs, InstructionData);
	Bytes = ((Bytes != 0) ? Bytes :
	(InstructionData->DataSize == Size16Bits) ? 2 :
	(InstructionData->DataSize == Size32Bits) ? 4 :
	(InstructionData->DataSize == Size64Bits) ? 8 :
	0);

	InstructionData->ImmediateSize = Bytes;
	InstructionData->End += Bytes;

	Val = 0;
	CopyMem (&Val, InstructionData->Immediate, InstructionData->ImmediateSize);

	Address = InstructionData->Ext.RmData;
	ReadOrWrite = TDX_MMIO_WRITE;

	break;

	//
	// MMIO read (MOV regX, reg/memX)
	//
	case 0x8A:
	Bytes = 1;
	//
	// fall through
	//
	case 0x8B:
	CcDecodeModRm (Regs, InstructionData);
	Bytes = ((Bytes != 0) ? Bytes :
	(InstructionData->DataSize == Size16Bits) ? 2 :
	(InstructionData->DataSize == Size32Bits) ? 4 :
	(InstructionData->DataSize == Size64Bits) ? 8 :
	0);
	if (InstructionData->Ext.ModRm.Mod == 3) {
	//
	// NPF on two register operands???
	//
	DEBUG ((DEBUG_ERROR, "%a: Parse Ext.ModRm.Mod error! (OpCode: 0x%x)\n", __func__, OpCode));
	return EFI_UNSUPPORTED;
	}

	Address = InstructionData->Ext.RmData;
	ReadOrWrite = TDX_MMIO_READ;

	Register = CcGetRegisterPointer (Regs, InstructionData->Ext.ModRm.Reg);
	if (Register == NULL) {
	return EFI_ABORTED;
	}

	if (Bytes == 4) {
	//
	// Zero-extend for 32-bit operation
	//
	*Register = 0;
	}

	break;

	//
	// MMIO read (MOV aX, moffsetX)
	//
	case 0xA0:
	Bytes = 1;
	//
	// fall through
	//
	case 0xA1:
	Bytes = ((Bytes != 0) ? Bytes :
	(InstructionData->DataSize == Size16Bits) ? 2 :
	(InstructionData->DataSize == Size32Bits) ? 4 :
	(InstructionData->DataSize == Size64Bits) ? 8 :
	0);

	InstructionData->ImmediateSize = (UINTN)(1 << InstructionData->AddrSize);
	InstructionData->End += InstructionData->ImmediateSize;

	Address = 0;
	CopyMem (
	&Address,
	InstructionData->Immediate,
	InstructionData->ImmediateSize
	);

	if (Bytes == 4) {
	//
	// Zero-extend for 32-bit operation
	//
	Regs->Rax = 0;
	}

	Register = &Regs->Rax;
	ReadOrWrite = TDX_MMIO_READ;

	break;

	//
	// MMIO read w/ zero-extension ((MOVZX regX, reg/memX)
	//
	case 0xB6:
	Bytes = 1;
	//
	// fall through
	//
	case 0xB7:
	CcDecodeModRm (Regs, InstructionData);
	Bytes = (Bytes != 0) ? Bytes : 2;
	Address = InstructionData->Ext.RmData;

	Register = CcGetRegisterPointer (Regs, InstructionData->Ext.ModRm.Reg);
	if (Register == NULL) {
	return EFI_ABORTED;
	}

	SetMem (Register, (UINTN)(1 << InstructionData->DataSize), 0);

	ReadOrWrite = TDX_MMIO_READ;

	break;

	//
	// MMIO read w/ sign-extension (MOVSX regX, reg/memX)
	//
	case 0xBE:
	Bytes = 1;
	//
	// fall through
	//
	case 0xBF:
	CcDecodeModRm (Regs, InstructionData);
	Bytes = (Bytes != 0) ? Bytes : 2;

	Address = InstructionData->Ext.RmData;

	if (Bytes == 1) {
	UINT8 *Data;
	Data = (UINT8 *)&Val;
	SignByte = ((*Data & BIT7) != 0) ? 0xFF : 0x00;
	} else {
	UINT16 *Data;
	Data = (UINT16 *)&Val;
	SignByte = ((*Data & BIT15) != 0) ? 0xFF : 0x00;
	}

	Register = CcGetRegisterPointer (Regs, InstructionData->Ext.ModRm.Reg);
	if (Register == NULL) {
	return EFI_ABORTED;
	}

	SetMem (Register, (UINTN)(1 << InstructionData->DataSize), SignByte);

	ReadOrWrite = TDX_MMIO_READ;

	break;

	default:
	DEBUG ((DEBUG_ERROR, "%a: Invalid MMIO opcode (%x)\n", __func__, OpCode));
	Status = EFI_UNSUPPORTED;
	}

	if (!EFI_ERROR (Status)) {
	ParsedInstruction->OpCode = OpCode;
	ParsedInstruction->Address = Address;
	ParsedInstruction->Bytes = Bytes;
	ParsedInstruction->Register = Register;
	ParsedInstruction->Val = Val;
	ParsedInstruction->ReadOrWrite = ReadOrWrite;
	}

	return Status;
	}

	/**
	Handle an MMIO event.

	Use the TDVMCALL instruction to handle either an mmio read or an mmio write.

	@param[in, out] Regs x64 processor context
	@param[in] Veinfo VE Info

	@retval 0 Event handled successfully
	**/
	STATIC
	UINT64
	EFIAPI
	MmioExit (
	IN OUT EFI_SYSTEM_CONTEXT_X64 *Regs,
	IN TDCALL_VEINFO_RETURN_DATA *Veinfo
	)
	{
	UINT64 TdStatus;
	EFI_STATUS Status;
	TD_RETURN_DATA TdReturnData;
	UINT8 Gpaw;
	UINT64 Val;
	UINT64 TdSharedPageMask;
	CC_INSTRUCTION_DATA InstructionData;
	MMIO_EXIT_PARSED_INSTRUCTION ParsedInstruction;

	TdStatus = TdCall (TDCALL_TDINFO, 0, 0, 0, &TdReturnData);
	if (TdStatus == TDX_EXIT_REASON_SUCCESS) {
	Gpaw = (UINT8)(TdReturnData.TdInfo.Gpaw & 0x3f);
	TdSharedPageMask = 1ULL << (Gpaw - 1);
	} else {
	DEBUG ((DEBUG_ERROR, "%a: TDCALL failed with status=%llx\n", __func__, TdStatus));
	goto FatalError;
	}

	if ((Veinfo->GuestPA & TdSharedPageMask) == 0) {
	DEBUG ((DEBUG_ERROR, "%a: EPT-violation #VE on private memory is not allowed!", __func__));
	goto FatalError;
	}

	Status = ParseMmioExitInstructions (Regs, &InstructionData, &ParsedInstruction);
	if (EFI_ERROR (Status)) {
	goto FatalError;
	}

	if (Veinfo->GuestPA != (ParsedInstruction.Address \| TdSharedPageMask)) {
	DEBUG ((
	DEBUG_ERROR,
	"%a: Address is not correct! (%d: 0x%llx != 0x%llx)\n",
	__func__,
	ParsedInstruction.OpCode,
	Veinfo->GuestPA,
	ParsedInstruction.Address
	));
	goto FatalError;
	}

	if (ParsedInstruction.ReadOrWrite == TDX_MMIO_WRITE ) {
	Status = TdxMmioReadWrite (ParsedInstruction.Bytes, TDX_MMIO_WRITE, Veinfo->GuestPA, &ParsedInstruction.Val);
	} else if (ParsedInstruction.ReadOrWrite == TDX_MMIO_READ) {
	Val = 0;
	Status = TdxMmioReadWrite (ParsedInstruction.Bytes, TDX_MMIO_READ, Veinfo->GuestPA, &Val);
	if (!EFI_ERROR (Status)) {
	CopyMem (ParsedInstruction.Register, &Val, ParsedInstruction.Bytes);
	}
	} else {
	goto FatalError;
	}

	if (EFI_ERROR (Status)) {
	goto FatalError;
	}

	//
	// We change instruction length to reflect true size so handler can
	// bump rip
	//
	Veinfo->ExitInstructionLength = (UINT32)(CcInstructionLength (&InstructionData));
	TdxDecodeInstruction ((UINT8 *)Regs->Rip, Veinfo->ExitInstructionLength);

	return 0;

	FatalError:
	TdVmCall (TDVMCALL_HALT, 0, 0, 0, 0, 0);
	CpuDeadLoop ();
	return 0;
	}

	/**
	Handle a #VE exception.

	Performs the necessary processing to handle a #VE exception.

	@param[in, out] ExceptionType Pointer to an EFI_EXCEPTION_TYPE to be set
	as value to use on error.
	@param[in, out] SystemContext Pointer to EFI_SYSTEM_CONTEXT

	@retval EFI_SUCCESS Exception handled
	@retval EFI_UNSUPPORTED #VE not supported, (new) exception value to
	propagate provided
	@retval EFI_PROTOCOL_ERROR #VE handling failed, (new) exception value to
	propagate provided

	**/
	EFI_STATUS
	EFIAPI
	CcExitHandleVe (
	IN OUT EFI_EXCEPTION_TYPE *ExceptionType,
	IN OUT EFI_SYSTEM_CONTEXT SystemContext
	)
	{
	UINT64 Status;
	TD_RETURN_DATA ReturnData;
	EFI_SYSTEM_CONTEXT_X64 *Regs;

	Regs = SystemContext.SystemContextX64;
	Status = TdCall (TDCALL_TDGETVEINFO, 0, 0, 0, &ReturnData);
	ASSERT (Status == 0);
	if (Status != 0) {
	DEBUG ((DEBUG_ERROR, "#VE happened. TDGETVEINFO failed with Status = 0x%llx\n", Status));
	TdVmCall (TDVMCALL_HALT, 0, 0, 0, 0, 0);
	CpuDeadLoop ();
	}

	switch (ReturnData.VeInfo.ExitReason) {
	case EXIT_REASON_CPUID:
	Status = CpuIdExit (Regs, &ReturnData.VeInfo);
	DEBUG ((
	DEBUG_VERBOSE,
	"CPUID #VE happened, ExitReasion is %d, ExitQualification = 0x%x.\n",
	ReturnData.VeInfo.ExitReason,
	ReturnData.VeInfo.ExitQualification.Val
	));
	break;

	case EXIT_REASON_HLT:
	Status = TdVmCall (EXIT_REASON_HLT, 0, 0, 0, 0, 0);
	break;

	case EXIT_REASON_IO_INSTRUCTION:
	Status = IoExit (Regs, &ReturnData.VeInfo);
	DEBUG ((
	DEBUG_VERBOSE,
	"IO_Instruction #VE happened, ExitReasion is %d, ExitQualification = 0x%x.\n",
	ReturnData.VeInfo.ExitReason,
	ReturnData.VeInfo.ExitQualification.Val
	));
	break;

	case EXIT_REASON_MSR_READ:
	Status = ReadMsrExit (Regs, &ReturnData.VeInfo);
	DEBUG ((
	DEBUG_VERBOSE,
	"RDMSR #VE happened, ExitReasion is %d, ExitQualification = 0x%x. Regs->Rcx=0x%llx, Status = 0x%llx\n",
	ReturnData.VeInfo.ExitReason,
	ReturnData.VeInfo.ExitQualification.Val,
	Regs->Rcx,
	Status
	));
	break;

	case EXIT_REASON_MSR_WRITE:
	Status = WriteMsrExit (Regs, &ReturnData.VeInfo);
	DEBUG ((
	DEBUG_VERBOSE,
	"WRMSR #VE happened, ExitReasion is %d, ExitQualification = 0x%x. Regs->Rcx=0x%llx, Status = 0x%llx\n",
	ReturnData.VeInfo.ExitReason,
	ReturnData.VeInfo.ExitQualification.Val,
	Regs->Rcx,
	Status
	));
	break;

	case EXIT_REASON_EPT_VIOLATION:
	Status = MmioExit (Regs, &ReturnData.VeInfo);
	DEBUG ((
	DEBUG_VERBOSE,
	"MMIO #VE happened, ExitReasion is %d, ExitQualification = 0x%x.\n",
	ReturnData.VeInfo.ExitReason,
	ReturnData.VeInfo.ExitQualification.Val
	));
	break;

	case EXIT_REASON_VMCALL:
	case EXIT_REASON_MWAIT_INSTRUCTION:
	case EXIT_REASON_MONITOR_INSTRUCTION:
	case EXIT_REASON_WBINVD:
	case EXIT_REASON_RDPMC:
	case EXIT_REASON_INVD:
	/* Handle as nops. */
	break;

	default:
	DEBUG ((
	DEBUG_ERROR,
	"Unsupported #VE happened, ExitReason is %d, ExitQualification = 0x%x.\n",
	ReturnData.VeInfo.ExitReason,
	ReturnData.VeInfo.ExitQualification.Val
	));

	ASSERT (FALSE);
	CpuDeadLoop ();
	}

	if (Status) {
	DEBUG ((
	DEBUG_ERROR,
	"#VE Error (0x%llx) returned from host, ExitReason is %d, ExitQualification = 0x%x.\n",
	Status,
	ReturnData.VeInfo.ExitReason,
	ReturnData.VeInfo.ExitQualification.Val
	));

	TdVmCall (TDVMCALL_HALT, 0, 0, 0, 0, 0);
	CpuDeadLoop ();
	}

	SystemContext.SystemContextX64->Rip += ReturnData.VeInfo.ExitInstructionLength;
	return EFI_SUCCESS;
	}