path: root/OvmfPkg/ResetVector/Ia32/PageTables64.asm

;------------------------------------------------------------------------------
; @file
; Sets the CR3 register for 64-bit paging
;
; Copyright (c) 2008 - 2013, Intel Corporation. All rights reserved.<BR>
; SPDX-License-Identifier: BSD-2-Clause-Patent
;
;------------------------------------------------------------------------------

BITS    32

%define PAGE_PRESENT            0x01
%define PAGE_READ_WRITE         0x02
%define PAGE_USER_SUPERVISOR    0x04
%define PAGE_WRITE_THROUGH      0x08
%define PAGE_CACHE_DISABLE     0x010
%define PAGE_ACCESSED          0x020
%define PAGE_DIRTY             0x040
%define PAGE_PAT               0x080
%define PAGE_GLOBAL           0x0100
%define PAGE_2M_MBO            0x080
%define PAGE_2M_PAT          0x01000

%define PAGE_4K_PDE_ATTR (PAGE_ACCESSED + \
                          PAGE_DIRTY + \
                          PAGE_READ_WRITE + \
                          PAGE_PRESENT)

%define PAGE_2M_PDE_ATTR (PAGE_2M_MBO + \
                          PAGE_ACCESSED + \
                          PAGE_DIRTY + \
                          PAGE_READ_WRITE + \
                          PAGE_PRESENT)

%define PAGE_PDP_ATTR (PAGE_ACCESSED + \
                       PAGE_READ_WRITE + \
                       PAGE_PRESENT)

;
; SEV-ES #VC exception handler support
;
; #VC handler local variable locations
;
%define VC_CPUID_RESULT_EAX         0
%define VC_CPUID_RESULT_EBX         4
%define VC_CPUID_RESULT_ECX         8
%define VC_CPUID_RESULT_EDX        12
%define VC_GHCB_MSR_EDX            16
%define VC_GHCB_MSR_EAX            20
%define VC_CPUID_REQUEST_REGISTER  24
%define VC_CPUID_FUNCTION          28

; #VC handler total local variable size
;
%define VC_VARIABLE_SIZE           32

; #VC handler GHCB CPUID request/response protocol values
;
%define GHCB_CPUID_REQUEST          4
%define GHCB_CPUID_RESPONSE         5
%define GHCB_CPUID_REGISTER_SHIFT  30
%define CPUID_INSN_LEN              2


; Check if Secure Encrypted Virtualization (SEV) feature is enabled
;
; Modified:  EAX, EBX, ECX, EDX, ESP
;
; If SEV is enabled then EAX will be at least 32.
; If SEV is disabled then EAX will be zero.
;
CheckSevFeature:
    ; Set the first byte of the workarea to zero to communicate to the SEC
    ; phase that SEV-ES is not enabled. If SEV-ES is enabled, the CPUID
    ; instruction will trigger a #VC exception where the first byte of the
    ; workarea will be set to one.
    mov     byte[SEV_ES_WORK_AREA], 0

    ;
    ; Set up exception handlers to check for SEV-ES
    ;   Load temporary RAM stack based on PCDs (see SevEsIdtVmmComm for
    ;   stack usage)
    ;   Establish exception handlers
    ;
    mov       esp, SEV_ES_VC_TOP_OF_STACK
    mov       eax, ADDR_OF(Idtr)
    lidt      [cs:eax]

    ; Check if we have a valid (0x8000_001F) CPUID leaf
    ;   CPUID raises a #VC exception if running as an SEV-ES guest
    mov       eax, 0x80000000
    cpuid

    ; This check should fail on Intel or Non SEV AMD CPUs. In future if
    ; Intel CPUs supports this CPUID leaf then we are guranteed to have exact
    ; same bit definition.
    cmp       eax, 0x8000001f
    jl        NoSev

    ; Check for memory encryption feature:
    ; CPUID  Fn8000_001F[EAX] - Bit 1
    ;   CPUID raises a #VC exception if running as an SEV-ES guest
    mov       eax,  0x8000001f
    cpuid
    bt        eax, 1
    jnc       NoSev

    ; Check if memory encryption is enabled
    ;  MSR_0xC0010131 - Bit 0 (SEV enabled)
    mov       ecx, 0xc0010131
    rdmsr
    bt        eax, 0
    jnc       NoSev

    ; Get pte bit position to enable memory encryption
    ; CPUID Fn8000_001F[EBX] - Bits 5:0
    ;
    mov       eax, ebx
    and       eax, 0x3f
    jmp       SevExit

NoSev:
    xor       eax, eax

SevExit:
    ;
    ; Clear exception handlers and stack
    ;
    push      eax
    mov       eax, ADDR_OF(IdtrClear)
    lidt      [cs:eax]
    pop       eax
    mov       esp, 0

    OneTimeCallRet CheckSevFeature

; Check if Secure Encrypted Virtualization - Encrypted State (SEV-ES) feature
; is enabled.
;
; Modified:  EAX, EBX, ECX
;
; If SEV-ES is enabled then EAX will be non-zero.
; If SEV-ES is disabled then EAX will be zero.
;
CheckSevEsFeature:
    xor       eax, eax

    ; SEV-ES can't be enabled if SEV isn't, so first check the encryption
    ; mask.
    test      edx, edx
    jz        NoSevEs

    ; Save current value of encryption mask
    mov       ebx, edx

    ; Check if SEV-ES is enabled
    ;  MSR_0xC0010131 - Bit 1 (SEV-ES enabled)
    mov       ecx, 0xc0010131
    rdmsr
    and       eax, 2

    ; Restore encryption mask
    mov       edx, ebx

NoSevEs:
    OneTimeCallRet CheckSevEsFeature

;
; Modified:  EAX, EBX, ECX, EDX
;
SetCr3ForPageTables64:

    OneTimeCall   CheckSevFeature
    xor     edx, edx
    test    eax, eax
    jz      SevNotActive

    ; If SEV is enabled, C-bit is always above 31
    sub     eax, 32
    bts     edx, eax

SevNotActive:

    ;
    ; For OVMF, build some initial page tables at
    ; PcdOvmfSecPageTablesBase - (PcdOvmfSecPageTablesBase + 0x6000).
    ;
    ; This range should match with PcdOvmfSecPageTablesSize which is
    ; declared in the FDF files.
    ;
    ; At the end of PEI, the pages tables will be rebuilt into a
    ; more permanent location by DxeIpl.
    ;

    mov     ecx, 6 * 0x1000 / 4
    xor     eax, eax
clearPageTablesMemoryLoop:
    mov     dword[ecx * 4 + PT_ADDR (0) - 4], eax
    loop    clearPageTablesMemoryLoop

    ;
    ; Top level Page Directory Pointers (1 * 512GB entry)
    ;
    mov     dword[PT_ADDR (0)], PT_ADDR (0x1000) + PAGE_PDP_ATTR
    mov     dword[PT_ADDR (4)], edx

    ;
    ; Next level Page Directory Pointers (4 * 1GB entries => 4GB)
    ;
    mov     dword[PT_ADDR (0x1000)], PT_ADDR (0x2000) + PAGE_PDP_ATTR
    mov     dword[PT_ADDR (0x1004)], edx
    mov     dword[PT_ADDR (0x1008)], PT_ADDR (0x3000) + PAGE_PDP_ATTR
    mov     dword[PT_ADDR (0x100C)], edx
    mov     dword[PT_ADDR (0x1010)], PT_ADDR (0x4000) + PAGE_PDP_ATTR
    mov     dword[PT_ADDR (0x1014)], edx
    mov     dword[PT_ADDR (0x1018)], PT_ADDR (0x5000) + PAGE_PDP_ATTR
    mov     dword[PT_ADDR (0x101C)], edx

    ;
    ; Page Table Entries (2048 * 2MB entries => 4GB)
    ;
    mov     ecx, 0x800
pageTableEntriesLoop:
    mov     eax, ecx
    dec     eax
    shl     eax, 21
    add     eax, PAGE_2M_PDE_ATTR
    mov     [ecx * 8 + PT_ADDR (0x2000 - 8)], eax
    mov     [(ecx * 8 + PT_ADDR (0x2000 - 8)) + 4], edx
    loop    pageTableEntriesLoop

    OneTimeCall   CheckSevEsFeature
    test    eax, eax
    jz      SetCr3

    ;
    ; The initial GHCB will live at GHCB_BASE and needs to be un-encrypted.
    ; This requires the 2MB page for this range be broken down into 512 4KB
    ; pages.  All will be marked encrypted, except for the GHCB.
    ;
    mov     ecx, (GHCB_BASE >> 21)
    mov     eax, GHCB_PT_ADDR + PAGE_PDP_ATTR
    mov     [ecx * 8 + PT_ADDR (0x2000)], eax

    ;
    ; Page Table Entries (512 * 4KB entries => 2MB)
    ;
    mov     ecx, 512
pageTableEntries4kLoop:
    mov     eax, ecx
    dec     eax
    shl     eax, 12
    add     eax, GHCB_BASE & 0xFFE0_0000
    add     eax, PAGE_4K_PDE_ATTR
    mov     [ecx * 8 + GHCB_PT_ADDR - 8], eax
    mov     [(ecx * 8 + GHCB_PT_ADDR - 8) + 4], edx
    loop    pageTableEntries4kLoop

    ;
    ; Clear the encryption bit from the GHCB entry
    ;
    mov     ecx, (GHCB_BASE & 0x1F_FFFF) >> 12
    mov     [ecx * 8 + GHCB_PT_ADDR + 4], strict dword 0

    mov     ecx, GHCB_SIZE / 4
    xor     eax, eax
clearGhcbMemoryLoop:
    mov     dword[ecx * 4 + GHCB_BASE - 4], eax
    loop    clearGhcbMemoryLoop

SetCr3:
    ;
    ; Set CR3 now that the paging structures are available
    ;
    mov     eax, PT_ADDR (0)
    mov     cr3, eax

    OneTimeCallRet SetCr3ForPageTables64

;
; Start of #VC exception handling routines
;

SevEsIdtNotCpuid:
    ;
    ; Use VMGEXIT to request termination.
    ;   1 - #VC was not for CPUID
    ;
    mov     eax, 1
    jmp     SevEsIdtTerminate

SevEsIdtNoCpuidResponse:
    ;
    ; Use VMGEXIT to request termination.
    ;   2 - GHCB_CPUID_RESPONSE not received
    ;
    mov     eax, 2

SevEsIdtTerminate:
    ;
    ; Use VMGEXIT to request termination. At this point the reason code is
    ; located in EAX, so shift it left 16 bits to the proper location.
    ;
    ; EAX[11:0]  => 0x100 - request termination
    ; EAX[15:12] => 0x1   - OVMF
    ; EAX[23:16] => 0xXX  - REASON CODE
    ;
    shl     eax, 16
    or      eax, 0x1100
    xor     edx, edx
    mov     ecx, 0xc0010130
    wrmsr
    ;
    ; Issue VMGEXIT - NASM doesn't support the vmmcall instruction in 32-bit
    ; mode, so work around this by temporarily switching to 64-bit mode.
    ;
BITS    64
    rep     vmmcall
BITS    32

    ;
    ; We shouldn't come back from the VMGEXIT, but if we do, just loop.
    ;
SevEsIdtHlt:
    hlt
    jmp     SevEsIdtHlt
    iret

    ;
    ; Total stack usage for the #VC handler is 44 bytes:
    ;   - 12 bytes for the exception IRET (after popping error code)
    ;   - 32 bytes for the local variables.
    ;
SevEsIdtVmmComm:
    ;
    ; If we're here, then we are an SEV-ES guest and this
    ; was triggered by a CPUID instruction
    ;
    ; Set the first byte of the workarea to one to communicate to the SEC
    ; phase that SEV-ES is enabled.
    mov     byte[SEV_ES_WORK_AREA], 1

    pop     ecx                     ; Error code
    cmp     ecx, 0x72               ; Be sure it was CPUID
    jne     SevEsIdtNotCpuid

    ; Set up local variable room on the stack
    ;   CPUID function         : + 28
    ;   CPUID request register : + 24
    ;   GHCB MSR (EAX)         : + 20
    ;   GHCB MSR (EDX)         : + 16
    ;   CPUID result (EDX)     : + 12
    ;   CPUID result (ECX)     : + 8
    ;   CPUID result (EBX)     : + 4
    ;   CPUID result (EAX)     : + 0
    sub     esp, VC_VARIABLE_SIZE

    ; Save the CPUID function being requested
    mov     [esp + VC_CPUID_FUNCTION], eax

    ; The GHCB CPUID protocol uses the following mapping to request
    ; a specific register:
    ;   0 => EAX, 1 => EBX, 2 => ECX, 3 => EDX
    ;
    ; Set EAX as the first register to request. This will also be used as a
    ; loop variable to request all register values (EAX to EDX).
    xor     eax, eax
    mov     [esp + VC_CPUID_REQUEST_REGISTER], eax

    ; Save current GHCB MSR value
    mov     ecx, 0xc0010130
    rdmsr
    mov     [esp + VC_GHCB_MSR_EAX], eax
    mov     [esp + VC_GHCB_MSR_EDX], edx

NextReg:
    ;
    ; Setup GHCB MSR
    ;   GHCB_MSR[63:32] = CPUID function
    ;   GHCB_MSR[31:30] = CPUID register
    ;   GHCB_MSR[11:0]  = CPUID request protocol
    ;
    mov     eax, [esp + VC_CPUID_REQUEST_REGISTER]
    cmp     eax, 4
    jge     VmmDone

    shl     eax, GHCB_CPUID_REGISTER_SHIFT
    or      eax, GHCB_CPUID_REQUEST
    mov     edx, [esp + VC_CPUID_FUNCTION]
    mov     ecx, 0xc0010130
    wrmsr

    ;
    ; Issue VMGEXIT - NASM doesn't support the vmmcall instruction in 32-bit
    ; mode, so work around this by temporarily switching to 64-bit mode.
    ;
BITS    64
    rep     vmmcall
BITS    32

    ;
    ; Read GHCB MSR
    ;   GHCB_MSR[63:32] = CPUID register value
    ;   GHCB_MSR[31:30] = CPUID register
    ;   GHCB_MSR[11:0]  = CPUID response protocol
    ;
    mov     ecx, 0xc0010130
    rdmsr
    mov     ecx, eax
    and     ecx, 0xfff
    cmp     ecx, GHCB_CPUID_RESPONSE
    jne     SevEsIdtNoCpuidResponse

    ; Save returned value
    shr     eax, GHCB_CPUID_REGISTER_SHIFT
    mov     [esp + eax * 4], edx

    ; Next register
    inc     word [esp + VC_CPUID_REQUEST_REGISTER]

    jmp     NextReg

VmmDone:
    ;
    ; At this point we have all CPUID register values. Restore the GHCB MSR,
    ; set the return register values and return.
    ;
    mov     eax, [esp + VC_GHCB_MSR_EAX]
    mov     edx, [esp + VC_GHCB_MSR_EDX]
    mov     ecx, 0xc0010130
    wrmsr

    mov     eax, [esp + VC_CPUID_RESULT_EAX]
    mov     ebx, [esp + VC_CPUID_RESULT_EBX]
    mov     ecx, [esp + VC_CPUID_RESULT_ECX]
    mov     edx, [esp + VC_CPUID_RESULT_EDX]

    add     esp, VC_VARIABLE_SIZE

    ; Update the EIP value to skip over the now handled CPUID instruction
    ; (the CPUID instruction has a length of 2)
    add     word [esp], CPUID_INSN_LEN
    iret

ALIGN   2

Idtr:
    dw      IDT_END - IDT_BASE - 1  ; Limit
    dd      ADDR_OF(IDT_BASE)       ; Base

IdtrClear:
    dw      0                       ; Limit
    dd      0                       ; Base

ALIGN   16

;
; The Interrupt Descriptor Table (IDT)
;   This will be used to determine if SEV-ES is enabled.  Upon execution
;   of the CPUID instruction, a VMM Communication Exception will occur.
;   This will tell us if SEV-ES is enabled.  We can use the current value
;   of the GHCB MSR to determine the SEV attributes.
;
IDT_BASE:
;
; Vectors 0 - 28 (No handlers)
;
%rep 29
    dw      0                                    ; Offset low bits 15..0
    dw      0x10                                 ; Selector
    db      0                                    ; Reserved
    db      0x8E                                 ; Gate Type (IA32_IDT_GATE_TYPE_INTERRUPT_32)
    dw      0                                    ; Offset high bits 31..16
%endrep
;
; Vector 29 (VMM Communication Exception)
;
    dw      (ADDR_OF(SevEsIdtVmmComm) & 0xffff)  ; Offset low bits 15..0
    dw      0x10                                 ; Selector
    db      0                                    ; Reserved
    db      0x8E                                 ; Gate Type (IA32_IDT_GATE_TYPE_INTERRUPT_32)
    dw      (ADDR_OF(SevEsIdtVmmComm) >> 16)     ; Offset high bits 31..16
;
; Vectors 30 - 31 (No handlers)
;
%rep 2
    dw      0                                    ; Offset low bits 15..0
    dw      0x10                                 ; Selector
    db      0                                    ; Reserved
    db      0x8E                                 ; Gate Type (IA32_IDT_GATE_TYPE_INTERRUPT_32)
    dw      0                                    ; Offset high bits 31..16
%endrep
IDT_END: