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|
; $Id: tstX86-1A.asm $
;; @file
; X86 instruction set exploration/testcase #1.
;
;
; Copyright (C) 2011-2020 Oracle Corporation
;
; This file is part of VirtualBox Open Source Edition (OSE), as
; available from http://www.virtualbox.org. This file is free software;
; you can redistribute it and/or modify it under the terms of the GNU
; General Public License (GPL) as published by the Free Software
; Foundation, in version 2 as it comes in the "COPYING" file of the
; VirtualBox OSE distribution. VirtualBox OSE is distributed in the
; hope that it will be useful, but WITHOUT ANY WARRANTY of any kind.
;
;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;
; Header Files ;
;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;
%include "iprt/asmdefs.mac"
%include "iprt/x86.mac"
;; @todo Move this to a header?
struc TRAPINFO
.uTrapPC RTCCPTR_RES 1
.uResumePC RTCCPTR_RES 1
.u8TrapNo resb 1
.cbInstr resb 1
.au8Padding resb (RTCCPTR_CB*2 - 2)
endstruc
%ifdef RT_ARCH_AMD64
%define arch_fxsave o64 fxsave
%define arch_fxrstor o64 fxrstor
%else
%define arch_fxsave fxsave
%define arch_fxrstor fxrstor
%endif
;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;
; Global Variables ;
;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;
BEGINDATA
extern NAME(g_pbEfPage)
extern NAME(g_pbEfExecPage)
GLOBALNAME g_szAlpha
db "abcdefghijklmnopqrstuvwxyz", 0
g_szAlpha_end:
%define g_cchAlpha (g_szAlpha_end - NAME(g_szAlpha))
db 0, 0, 0,
;; @name Floating point constants.
; @{
g_r32_0dot1: dd 0.1
g_r32_3dot2: dd 3.2
g_r32_Zero: dd 0.0
g_r32_One: dd 1.0
g_r32_Two: dd 2.0
g_r32_Three: dd 3.0
g_r32_Ten: dd 10.0
g_r32_Eleven: dd 11.0
g_r32_ThirtyTwo:dd 32.0
g_r32_Min: dd 000800000h
g_r32_Max: dd 07f7fffffh
g_r32_Inf: dd 07f800000h
g_r32_SNaN: dd 07f800001h
g_r32_SNaNMax: dd 07fbfffffh
g_r32_QNaN: dd 07fc00000h
g_r32_QNaNMax: dd 07fffffffh
g_r32_NegQNaN: dd 0ffc00000h
g_r64_0dot1: dq 0.1
g_r64_6dot9: dq 6.9
g_r64_Zero: dq 0.0
g_r64_One: dq 1.0
g_r64_Two: dq 2.0
g_r64_Three: dq 3.0
g_r64_Ten: dq 10.0
g_r64_Eleven: dq 11.0
g_r64_ThirtyTwo:dq 32.0
g_r64_Min: dq 00010000000000000h
g_r64_Max: dq 07fefffffffffffffh
g_r64_Inf: dq 07ff0000000000000h
g_r64_SNaN: dq 07ff0000000000001h
g_r64_SNaNMax: dq 07ff7ffffffffffffh
g_r64_NegQNaN: dq 0fff8000000000000h
g_r64_QNaN: dq 07ff8000000000000h
g_r64_QNaNMax: dq 07fffffffffffffffh
g_r64_DnMin: dq 00000000000000001h
g_r64_DnMax: dq 0000fffffffffffffh
g_r80_0dot1: dt 0.1
g_r80_3dot2: dt 3.2
g_r80_Zero: dt 0.0
g_r80_One: dt 1.0
g_r80_Two: dt 2.0
g_r80_Three: dt 3.0
g_r80_Ten: dt 10.0
g_r80_Eleven: dt 11.0
g_r80_ThirtyTwo:dt 32.0
g_r80_Min: dt 000018000000000000000h
g_r80_Max: dt 07ffeffffffffffffffffh
g_r80_Inf: dt 07fff8000000000000000h
g_r80_QNaN: dt 07fffc000000000000000h
g_r80_QNaNMax: dt 07fffffffffffffffffffh
g_r80_NegQNaN: dt 0ffffc000000000000000h
g_r80_SNaN: dt 07fff8000000000000001h
g_r80_SNaNMax: dt 07fffbfffffffffffffffh
g_r80_DnMin: dt 000000000000000000001h
g_r80_DnMax: dt 000007fffffffffffffffh
g_r32V1: dd 3.2
g_r32V2: dd -1.9
g_r64V1: dq 6.4
g_r80V1: dt 8.0
; Denormal numbers.
g_r32D0: dd 000200000h
;; @}
;; @name Upconverted Floating point constants
; @{
;g_r80_r32_0dot1: dt 0.1
g_r80_r32_3dot2: dt 04000cccccd0000000000h
;g_r80_r32_Zero: dt 0.0
;g_r80_r32_One: dt 1.0
;g_r80_r32_Two: dt 2.0
;g_r80_r32_Three: dt 3.0
;g_r80_r32_Ten: dt 10.0
;g_r80_r32_Eleven: dt 11.0
;g_r80_r32_ThirtyTwo: dt 32.0
;; @}
;; @name Decimal constants.
; @{
g_u64Zero: dd 0
g_u32Zero: dw 0
g_u64Two: dd 2
g_u32Two: dw 2
;; @}
;;
; The last global data item. We build this as we write the code.
align 8
GLOBALNAME g_aTrapInfo
;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;
; Defined Constants And Macros ;
;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;
;; Reference a variable
%ifdef RT_ARCH_AMD64
%define REF(a_Name) a_Name wrt rip
%else
%define REF(a_Name) a_Name
%endif
;; Reference a global variable
%ifdef RT_ARCH_AMD64
%define REF_EXTERN(a_Name) NAME(a_Name) wrt rip
%else
%define REF_EXTERN(a_Name) NAME(a_Name)
%endif
;;
; Macro for checking a memory value.
;
; @param 1 The size (byte, word, dword, etc)
; @param 2 The memory address expression.
; @param 3 The valued expected at the location.
%macro CheckMemoryValue 3
cmp %1 [%2], %3
je %%ok
mov eax, __LINE__
jmp .return
%%ok:
%endmacro
;;
; Checks if a 32-bit floating point memory value is the same as the specified
; constant (also memory).
;
; @uses eax
; @param 1 Address expression for the 32-bit floating point value
; to be checked.
; @param 2 The address expression of the constant.
;
%macro CheckMemoryR32ValueConst 2
mov eax, [%2]
cmp dword [%1], eax
je %%ok
%%bad:
mov eax, 90000000 + __LINE__
jmp .return
%%ok:
%endmacro
;;
; Checks if a 80-bit floating point memory value is the same as the specified
; constant (also memory).
;
; @uses eax
; @param 1 Address expression for the FXSAVE image.
; @param 2 The address expression of the constant.
;
%macro CheckMemoryR80ValueConst 2
mov eax, [%2]
cmp dword [%1], eax
je %%ok1
%%bad:
mov eax, 92000000 + __LINE__
jmp .return
%%ok1:
mov eax, [4 + %2]
cmp dword [%1 + 4], eax
jne %%bad
mov ax, [8 + %2]
cmp word [%1 + 8], ax
jne %%bad
%endmacro
;;
; Macro for recording a trapping instruction (simple).
;
; @param 1 The trap number.
; @param 2+ The instruction which should trap.
%macro ShouldTrap 2+
%%trap:
%2
%%trap_end:
mov eax, __LINE__
jmp .return
BEGINDATA
%%trapinfo: istruc TRAPINFO
at TRAPINFO.uTrapPC, RTCCPTR_DEF %%trap
at TRAPINFO.uResumePC, RTCCPTR_DEF %%resume
at TRAPINFO.u8TrapNo, db %1
at TRAPINFO.cbInstr, db (%%trap_end - %%trap)
iend
BEGINCODE
%%resume:
%endmacro
;;
; Macro for recording a trapping instruction in the exec page.
;
; @uses xAX, xDX
; @param 1 The trap number.
; @param 2 The offset into the exec page.
%macro ShouldTrapExecPage 2
lea xDX, [REF(NAME(g_aTrapInfoExecPage))]
lea xAX, [REF(%%resume)]
mov byte [xDX + TRAPINFO.cbInstr], PAGE_SIZE - (%2)
mov byte [xDX + TRAPINFO.u8TrapNo], %1
mov [xDX + TRAPINFO.uResumePC], xAX
mov xAX, [REF_EXTERN(g_pbEfExecPage)]
lea xAX, [xAX + (%2)]
mov [xDX + TRAPINFO.uTrapPC], xAX
jmp xAX
%%resume:
%endmacro
;;
; Macro for recording a FPU instruction trapping on a following fwait.
;
; Uses stack.
;
; @param 1 The status flags that are expected to be set afterwards.
; @param 2 C0..C3 to mask out in case undefined.
; @param 3+ The instruction which should trap.
; @uses eax
;
%macro FpuShouldTrap 3+
fnclex
%3
%%trap:
fwait
%%trap_end:
mov eax, __LINE__
jmp .return
BEGINDATA
%%trapinfo: istruc TRAPINFO
at TRAPINFO.uTrapPC, RTCCPTR_DEF %%trap
at TRAPINFO.uResumePC, RTCCPTR_DEF %%resume
at TRAPINFO.u8TrapNo, db X86_XCPT_MF
at TRAPINFO.cbInstr, db (%%trap_end - %%trap)
iend
BEGINCODE
%%resume:
FpuCheckFSW ((%1) | X86_FSW_ES | X86_FSW_B), %2
fnclex
%endmacro
;;
; Macro for recording checking the FSW value.
;
; Uses stack.
;
; @param 1 The status flags that are expected to be set afterwards.
; @param 2 C0..C3 to mask out in case undefined.
; @uses eax
;
%macro FpuCheckFSW 2
%%resume:
fnstsw ax
and eax, ~X86_FSW_TOP_MASK & ~(%2)
cmp eax, (%1)
je %%ok
;int3
lea eax, [eax + __LINE__ * 100000]
jmp .return
%%ok:
%endmacro
;;
; Checks that ST0 has a certain value
;
; @uses tword at [xSP]
;
%macro CheckSt0Value 3
fstp tword [xSP]
fld tword [xSP]
cmp dword [xSP], %1
je %%ok1
%%bad:
mov eax, __LINE__
jmp .return
%%ok1:
cmp dword [xSP + 4], %2
jne %%bad
cmp word [xSP + 8], %3
jne %%bad
%endmacro
;; Checks that ST0 contains QNaN.
%define CheckSt0Value_QNaN CheckSt0Value 0x00000000, 0xc0000000, 0xffff
;; Checks that ST0 contains +Inf.
%define CheckSt0Value_PlusInf CheckSt0Value 0x00000000, 0x80000000, 0x7fff
;; Checks that ST0 contains 3 & 1/3.
%define CheckSt0Value_3_and_a_3rd CheckSt0Value 0x55555555, 0xd5555555, 0x4000
;; Checks that ST0 contains 3 & 1/3.
%define CheckSt0Value_3_and_two_3rds CheckSt0Value 0xaaaaaaab, 0xeaaaaaaa, 0x4000
;; Checks that ST0 contains 8.0.
%define CheckSt0Value_Eight CheckSt0Value 0x00000000, 0x80000000, 0x4002
;;
; Macro for recording checking the FSW value of a FXSAVE image.
;
; Uses stack.
;
; @param 1 Address expression for the FXSAVE image.
; @param 2 The status flags that are expected to be set afterwards.
; @param 3 C0..C3 to mask out in case undefined.
; @uses eax
; @sa FpuCheckFSW
;
%macro FxSaveCheckFSW 3
%%resume:
movzx eax, word [%1 + X86FXSTATE.FSW]
and eax, ~X86_FSW_TOP_MASK & ~(%3)
cmp eax, (%2)
je %%ok
mov eax, 100000000 + __LINE__
jmp .return
%%ok:
%endmacro
;;
; Checks that ST0 is empty in an FXSAVE image.
;
; @uses eax
; @param 1 Address expression for the FXSAVE image.
;
%macro FxSaveCheckSt0Empty 1
movzx eax, word [%1 + X86FXSTATE.FSW]
and eax, X86_FSW_TOP_MASK
shr eax, X86_FSW_TOP_SHIFT
bt [%1 + X86FXSTATE.FTW], eax
jnc %%ok
mov eax, 200000000 + __LINE__
jmp .return
%%ok:
%endmacro
;;
; Checks that ST0 is not-empty in an FXSAVE image.
;
; @uses eax
; @param 1 Address expression for the FXSAVE image.
;
%macro FxSaveCheckSt0NonEmpty 1
movzx eax, word [%1 + X86FXSTATE.FSW]
and eax, X86_FSW_TOP_MASK
shr eax, X86_FSW_TOP_SHIFT
bt [%1 + X86FXSTATE.FTW], eax
jc %%ok
mov eax, 30000000 + __LINE__
jmp .return
%%ok:
%endmacro
;;
; Checks that STn in a FXSAVE image has a certain value (empty or not
; is ignored).
;
; @uses eax
; @param 1 Address expression for the FXSAVE image.
; @param 2 The register number.
; @param 3 First dword of value.
; @param 4 Second dword of value.
; @param 5 Final word of value.
;
%macro FxSaveCheckStNValueEx 5
cmp dword [%1 + X86FXSTATE.st0 + %2 * 16], %3
je %%ok1
%%bad:
mov eax, 40000000 + __LINE__
jmp .return
%%ok1:
cmp dword [%1 + X86FXSTATE.st0 + %2 * 16 + 4], %4
jne %%bad
cmp word [%1 + X86FXSTATE.st0 + %2 * 16 + 8], %5
jne %%bad
%endmacro
;;
; Checks if STn in a FXSAVE image has the same value as the specified
; floating point (80-bit) constant.
;
; @uses eax, xDX
; @param 1 Address expression for the FXSAVE image.
; @param 2 The register number.
; @param 3 The address expression of the constant.
;
%macro FxSaveCheckStNValueConstEx 3
mov eax, [%3]
cmp dword [%1 + X86FXSTATE.st0 + %2 * 16], eax
je %%ok1
%%bad:
mov eax, 40000000 + __LINE__
jmp .return
%%ok1:
mov eax, [4 + %3]
cmp dword [%1 + X86FXSTATE.st0 + %2 * 16 + 4], eax
jne %%bad
mov ax, [8 + %3]
cmp word [%1 + X86FXSTATE.st0 + %2 * 16 + 8], ax
jne %%bad
%endmacro
;;
; Checks that ST0 in a FXSAVE image has a certain value.
;
; @uses eax
; @param 1 Address expression for the FXSAVE image.
; @param 2 First dword of value.
; @param 3 Second dword of value.
; @param 4 Final word of value.
;
%macro FxSaveCheckSt0Value 4
FxSaveCheckSt0NonEmpty %1
FxSaveCheckStNValueEx %1, 0, %2, %3, %4
%endmacro
;;
; Checks that ST0 in a FXSAVE image is empty and that the value stored is the
; init value set by FpuInitWithCW.
;
; @uses eax
; @param 1 Address expression for the FXSAVE image.
;
%macro FxSaveCheckSt0EmptyInitValue 1
FxSaveCheckSt0Empty %1
FxSaveCheckStNValueEx %1, 0, 0x40404040, 0x40404040, 0xffff
%endmacro
;;
; Checks that ST0 in a FXSAVE image is non-empty and has the same value as the
; specified constant (80-bit).
;
; @uses eax, xDX
; @param 1 Address expression for the FXSAVE image.
; @param 2 The address expression of the constant.
%macro FxSaveCheckSt0ValueConst 2
FxSaveCheckSt0NonEmpty %1
FxSaveCheckStNValueConstEx %1, 0, %2
%endmacro
;; Checks that ST0 contains QNaN.
%define FxSaveCheckSt0Value_QNaN(p) FxSaveCheckSt0Value p, 0x00000000, 0xc0000000, 0xffff
;; Checks that ST0 contains +Inf.
%define FxSaveCheckSt0Value_PlusInf(p) FxSaveCheckSt0Value p, 0x00000000, 0x80000000, 0x7fff
;; Checks that ST0 contains 3 & 1/3.
%define FxSaveCheckSt0Value_3_and_a_3rd(p) FxSaveCheckSt0Value p, 0x55555555, 0xd5555555, 0x4000
;; Checks that ST0 contains 3 & 1/3.
%define FxSaveCheckSt0Value_3_and_two_3rds(p) FxSaveCheckSt0Value p, 0xaaaaaaab, 0xeaaaaaaa, 0x4000
;;
; Checks that STn is empty in an FXSAVE image.
;
; @uses eax
; @param 1 Address expression for the FXSAVE image.
; @param 2 The register number.
;
%macro FxSaveCheckStNEmpty 2
movzx eax, word [%1 + X86FXSTATE.FSW]
and eax, X86_FSW_TOP_MASK
shr eax, X86_FSW_TOP_SHIFT
add eax, %2
and eax, X86_FSW_TOP_SMASK
bt [%1 + X86FXSTATE.FTW], eax
jnc %%ok
mov eax, 20000000 + __LINE__
jmp .return
%%ok:
%endmacro
;;
; Checks that STn is not-empty in an FXSAVE image.
;
; @uses eax
; @param 1 Address expression for the FXSAVE image.
; @param 2 The register number.
;
%macro FxSaveCheckStNNonEmpty 2
movzx eax, word [%1 + X86FXSTATE.FSW]
and eax, X86_FSW_TOP_MASK
shr eax, X86_FSW_TOP_SHIFT
add eax, %2
and eax, X86_FSW_TOP_SMASK
bt [%1 + X86FXSTATE.FTW], eax
jc %%ok
mov eax, 30000000 + __LINE__
jmp .return
%%ok:
%endmacro
;;
; Checks that STn in a FXSAVE image has a certain value.
;
; @uses eax
; @param 1 Address expression for the FXSAVE image.
; @param 2 The register number.
; @param 3 First dword of value.
; @param 4 Second dword of value.
; @param 5 Final word of value.
;
%macro FxSaveCheckStNValue 5
FxSaveCheckStNNonEmpty %1, %2
FxSaveCheckStNValueEx %1, %2, %3, %4, %5
%endmacro
;;
; Checks that ST0 in a FXSAVE image is non-empty and has the same value as the
; specified constant (80-bit).
;
; @uses eax, xDX
; @param 1 Address expression for the FXSAVE image.
; @param 2 The register number.
; @param 3 The address expression of the constant.
%macro FxSaveCheckStNValueConst 3
FxSaveCheckStNNonEmpty %1, %2
FxSaveCheckStNValueConstEx %1, %2, %3
%endmacro
;; Checks that ST0 contains QNaN.
%define FxSaveCheckStNValue_QNaN(p, iSt) FxSaveCheckStNValue p, iSt, 0x00000000, 0xc0000000, 0xffff
;; Checks that ST0 contains +Inf.
%define FxSaveCheckStNValue_PlusInf(p, iSt) FxSaveCheckStNValue p, iSt, 0x00000000, 0x80000000, 0x7fff
;; Checks that ST0 contains 3 & 1/3.
%define FxSaveCheckStNValue_3_and_a_3rd(p, iSt) FxSaveCheckStNValue p, iSt, 0x55555555, 0xd5555555, 0x4000
;; Checks that ST0 contains 3 & 1/3.
%define FxSaveCheckStNValue_3_and_two_3rds(p, iSt) FxSaveCheckStNValue p, iSt, 0xaaaaaaab, 0xeaaaaaaa, 0x4000
;;
; Function prologue saving all registers except EAX and aligns the stack
; on a 16-byte boundrary.
;
%macro SAVE_ALL_PROLOGUE 0
push xBP
mov xBP, xSP
pushf
push xBX
push xCX
push xDX
push xSI
push xDI
%ifdef RT_ARCH_AMD64
push r8
push r9
push r10
push r11
push r12
push r13
push r14
push r15
%endif
and xSP, ~0fh;
%endmacro
;;
; Function epilogue restoring all regisers except EAX.
;
%macro SAVE_ALL_EPILOGUE 0
%ifdef RT_ARCH_AMD64
lea rsp, [rbp - 14 * 8]
pop r15
pop r14
pop r13
pop r12
pop r11
pop r10
pop r9
pop r8
%else
lea esp, [ebp - 6 * 4]
%endif
pop xDI
pop xSI
pop xDX
pop xCX
pop xBX
popf
leave
%endmacro
BEGINCODE
;;
; Loads all general registers except xBP and xSP with unique values.
;
x861_LoadUniqueRegValues:
%ifdef RT_ARCH_AMD64
mov rax, 00000000000000000h
mov rcx, 01111111111111111h
mov rdx, 02222222222222222h
mov rbx, 03333333333333333h
mov rsi, 06666666666666666h
mov rdi, 07777777777777777h
mov r8, 08888888888888888h
mov r9, 09999999999999999h
mov r10, 0aaaaaaaaaaaaaaaah
mov r11, 0bbbbbbbbbbbbbbbbh
mov r12, 0cccccccccccccccch
mov r13, 0ddddddddddddddddh
mov r14, 0eeeeeeeeeeeeeeeeh
mov r15, 0ffffffffffffffffh
%else
mov eax, 000000000h
mov ecx, 011111111h
mov edx, 022222222h
mov ebx, 033333333h
mov esi, 066666666h
mov edi, 077777777h
%endif
ret
; end x861_LoadUniqueRegValues
;;
; Clears all general registers except xBP and xSP.
;
x861_ClearRegisters:
xor eax, eax
xor ebx, ebx
xor ecx, ecx
xor edx, edx
xor esi, esi
xor edi, edi
%ifdef RT_ARCH_AMD64
xor r8, r8
xor r9, r9
xor r10, r10
xor r11, r11
xor r12, r12
xor r13, r13
xor r14, r14
xor r15, r15
%endif
ret
; x861_ClearRegisters
;;
; Loads all MMX and SSE registers except xBP and xSP with unique values.
;
x861_LoadUniqueRegValuesSSE:
fninit
movq mm0, [REF(._mm0)]
movq mm1, [REF(._mm1)]
movq mm2, [REF(._mm2)]
movq mm3, [REF(._mm3)]
movq mm4, [REF(._mm4)]
movq mm5, [REF(._mm5)]
movq mm6, [REF(._mm6)]
movq mm7, [REF(._mm7)]
movdqu xmm0, [REF(._xmm0)]
movdqu xmm1, [REF(._xmm1)]
movdqu xmm2, [REF(._xmm2)]
movdqu xmm3, [REF(._xmm3)]
movdqu xmm4, [REF(._xmm4)]
movdqu xmm5, [REF(._xmm5)]
movdqu xmm6, [REF(._xmm6)]
movdqu xmm7, [REF(._xmm7)]
%ifdef RT_ARCH_AMD64
movdqu xmm8, [REF(._xmm8)]
movdqu xmm9, [REF(._xmm9)]
movdqu xmm10, [REF(._xmm10)]
movdqu xmm11, [REF(._xmm11)]
movdqu xmm12, [REF(._xmm12)]
movdqu xmm13, [REF(._xmm13)]
movdqu xmm14, [REF(._xmm14)]
movdqu xmm15, [REF(._xmm15)]
%endif
ret
._mm0: times 8 db 040h
._mm1: times 8 db 041h
._mm2: times 8 db 042h
._mm3: times 8 db 043h
._mm4: times 8 db 044h
._mm5: times 8 db 045h
._mm6: times 8 db 046h
._mm7: times 8 db 047h
._xmm0: times 16 db 080h
._xmm1: times 16 db 081h
._xmm2: times 16 db 082h
._xmm3: times 16 db 083h
._xmm4: times 16 db 084h
._xmm5: times 16 db 085h
._xmm6: times 16 db 086h
._xmm7: times 16 db 087h
%ifdef RT_ARCH_AMD64
._xmm8: times 16 db 088h
._xmm9: times 16 db 089h
._xmm10: times 16 db 08ah
._xmm11: times 16 db 08bh
._xmm12: times 16 db 08ch
._xmm13: times 16 db 08dh
._xmm14: times 16 db 08eh
._xmm15: times 16 db 08fh
%endif
; end x861_LoadUniqueRegValuesSSE
;;
; Clears all MMX and SSE registers.
;
x861_ClearRegistersSSE:
fninit
movq mm0, [REF(.zero)]
movq mm1, [REF(.zero)]
movq mm2, [REF(.zero)]
movq mm3, [REF(.zero)]
movq mm4, [REF(.zero)]
movq mm5, [REF(.zero)]
movq mm6, [REF(.zero)]
movq mm7, [REF(.zero)]
movdqu xmm0, [REF(.zero)]
movdqu xmm1, [REF(.zero)]
movdqu xmm2, [REF(.zero)]
movdqu xmm3, [REF(.zero)]
movdqu xmm4, [REF(.zero)]
movdqu xmm5, [REF(.zero)]
movdqu xmm6, [REF(.zero)]
movdqu xmm7, [REF(.zero)]
%ifdef RT_ARCH_AMD64
movdqu xmm8, [REF(.zero)]
movdqu xmm9, [REF(.zero)]
movdqu xmm10, [REF(.zero)]
movdqu xmm11, [REF(.zero)]
movdqu xmm12, [REF(.zero)]
movdqu xmm13, [REF(.zero)]
movdqu xmm14, [REF(.zero)]
movdqu xmm15, [REF(.zero)]
%endif
ret
ret
.zero times 16 db 000h
; x861_ClearRegistersSSE
;;
; Loads all general, MMX and SSE registers except xBP and xSP with unique values.
;
x861_LoadUniqueRegValuesSSEAndGRegs:
call x861_LoadUniqueRegValuesSSE
call x861_LoadUniqueRegValues
ret
;;
; Clears all general, MMX and SSE registers except xBP and xSP.
;
x861_ClearRegistersSSEAndGRegs:
call x861_ClearRegistersSSE
call x861_ClearRegisters
ret
BEGINPROC x861_Test1
push xBP
mov xBP, xSP
pushf
push xBX
push xCX
push xDX
push xSI
push xDI
%ifdef RT_ARCH_AMD64
push r8
push r9
push r10
push r11
push r12
push r13
push r14
push r15
%endif
;
; Odd push behavior
;
%if 0 ; Seems to be so on AMD only
%ifdef RT_ARCH_X86
; upper word of a 'push cs' is cleared.
mov eax, __LINE__
mov dword [esp - 4], 0f0f0f0fh
push cs
pop ecx
mov bx, cs
and ebx, 0000ffffh
cmp ecx, ebx
jne .failed
; upper word of a 'push ds' is cleared.
mov eax, __LINE__
mov dword [esp - 4], 0f0f0f0fh
push ds
pop ecx
mov bx, ds
and ebx, 0000ffffh
cmp ecx, ebx
jne .failed
; upper word of a 'push es' is cleared.
mov eax, __LINE__
mov dword [esp - 4], 0f0f0f0fh
push es
pop ecx
mov bx, es
and ebx, 0000ffffh
cmp ecx, ebx
jne .failed
%endif ; RT_ARCH_X86
; The upper part of a 'push fs' is cleared.
mov eax, __LINE__
xor ecx, ecx
not xCX
push xCX
pop xCX
push fs
pop xCX
mov bx, fs
and ebx, 0000ffffh
cmp xCX, xBX
jne .failed
; The upper part of a 'push gs' is cleared.
mov eax, __LINE__
xor ecx, ecx
not xCX
push xCX
pop xCX
push gs
pop xCX
mov bx, gs
and ebx, 0000ffffh
cmp xCX, xBX
jne .failed
%endif
%ifdef RT_ARCH_AMD64
; REX.B works with 'push r64'.
call x861_LoadUniqueRegValues
mov eax, __LINE__
push rcx
pop rdx
cmp rdx, rcx
jne .failed
call x861_LoadUniqueRegValues
mov eax, __LINE__
db 041h ; REX.B
push rcx
pop rdx
cmp rdx, r9
jne .failed
call x861_LoadUniqueRegValues
mov eax, __LINE__
db 042h ; REX.X
push rcx
pop rdx
cmp rdx, rcx
jne .failed
call x861_LoadUniqueRegValues
mov eax, __LINE__
db 044h ; REX.R
push rcx
pop rdx
cmp rdx, rcx
jne .failed
call x861_LoadUniqueRegValues
mov eax, __LINE__
db 048h ; REX.W
push rcx
pop rdx
cmp rdx, rcx
jne .failed
call x861_LoadUniqueRegValues
mov eax, __LINE__
db 04fh ; REX.*
push rcx
pop rdx
cmp rdx, r9
jne .failed
%endif
;
; Zero extening when moving from a segreg as well as memory access sizes.
;
call x861_LoadUniqueRegValues
mov eax, __LINE__
mov ecx, ds
shr xCX, 16
cmp xCX, 0
jnz .failed
%ifdef RT_ARCH_AMD64
call x861_LoadUniqueRegValues
mov eax, __LINE__
mov rcx, ds
shr rcx, 16
cmp rcx, 0
jnz .failed
%endif
call x861_LoadUniqueRegValues
mov eax, __LINE__
mov xDX, xCX
mov cx, ds
shr xCX, 16
shr xDX, 16
cmp xCX, xDX
jnz .failed
; Loading is always a word access.
mov eax, __LINE__
mov xDI, [REF_EXTERN(g_pbEfPage)]
lea xDI, [xDI + 0x1000 - 2]
mov xDX, es
mov [xDI], dx
mov es, [xDI] ; should not crash
; Saving is always a word access.
mov eax, __LINE__
mov xDI, [REF_EXTERN(g_pbEfPage)]
mov dword [xDI + 0x1000 - 4], -1
mov [xDI + 0x1000 - 2], ss ; Should not crash.
mov bx, ss
mov cx, [xDI + 0x1000 - 2]
cmp cx, bx
jne .failed
%ifdef RT_ARCH_AMD64
; Check that the rex.R and rex.W bits don't have any influence over a memory write.
call x861_ClearRegisters
mov eax, __LINE__
mov xDI, [REF_EXTERN(g_pbEfPage)]
mov dword [xDI + 0x1000 - 4], -1
db 04ah
mov [xDI + 0x1000 - 2], ss ; Should not crash.
mov bx, ss
mov cx, [xDI + 0x1000 - 2]
cmp cx, bx
jne .failed
%endif
;
; Check what happens when both string prefixes are used.
;
cld
mov dx, ds
mov es, dx
; check that repne scasb (al=0) behaves like expected.
lea xDI, [REF(NAME(g_szAlpha))]
xor eax, eax ; find the end
mov ecx, g_cchAlpha + 1
repne scasb
cmp ecx, 1
mov eax, __LINE__
jne .failed
; check that repe scasb (al=0) behaves like expected.
lea xDI, [REF(NAME(g_szAlpha))]
xor eax, eax ; find the end
mov ecx, g_cchAlpha + 1
repe scasb
cmp ecx, g_cchAlpha
mov eax, __LINE__
jne .failed
; repne is last, it wins.
lea xDI, [REF(NAME(g_szAlpha))]
xor eax, eax ; find the end
mov ecx, g_cchAlpha + 1
db 0f3h ; repe - ignored
db 0f2h ; repne
scasb
cmp ecx, 1
mov eax, __LINE__
jne .failed
; repe is last, it wins.
lea xDI, [REF(NAME(g_szAlpha))]
xor eax, eax ; find the end
mov ecx, g_cchAlpha + 1
db 0f2h ; repne - ignored
db 0f3h ; repe
scasb
cmp ecx, g_cchAlpha
mov eax, __LINE__
jne .failed
;
; Check if stosb works with both prefixes.
;
cld
mov dx, ds
mov es, dx
mov xDI, [REF_EXTERN(g_pbEfPage)]
xor eax, eax
mov ecx, 01000h
rep stosb
mov xDI, [REF_EXTERN(g_pbEfPage)]
mov ecx, 4
mov eax, 0ffh
db 0f2h ; repne
stosb
mov eax, __LINE__
cmp ecx, 0
jne .failed
mov eax, __LINE__
mov xDI, [REF_EXTERN(g_pbEfPage)]
cmp dword [xDI], 0ffffffffh
jne .failed
cmp dword [xDI+4], 0
jne .failed
mov xDI, [REF_EXTERN(g_pbEfPage)]
mov ecx, 4
mov eax, 0feh
db 0f3h ; repe
stosb
mov eax, __LINE__
cmp ecx, 0
jne .failed
mov eax, __LINE__
mov xDI, [REF_EXTERN(g_pbEfPage)]
cmp dword [xDI], 0fefefefeh
jne .failed
cmp dword [xDI+4], 0
jne .failed
;
; String operations shouldn't crash because of an invalid address if rCX is 0.
;
mov eax, __LINE__
cld
mov dx, ds
mov es, dx
mov xDI, [REF_EXTERN(g_pbEfPage)]
xor xCX, xCX
rep stosb ; no trap
;
; INS/OUTS will trap in ring-3 even when rCX is 0. (ASSUMES IOPL < 3)
;
mov eax, __LINE__
cld
mov dx, ss
mov ss, dx
mov xDI, xSP
xor xCX, xCX
ShouldTrap X86_XCPT_GP, rep insb
;
; SMSW can get to the whole of CR0.
;
mov eax, __LINE__
xor xBX, xBX
smsw xBX
test ebx, X86_CR0_PG
jz .failed
test ebx, X86_CR0_PE
jz .failed
;
; Will the CPU decode the whole r/m+sib stuff before signalling a lock
; prefix error? Use the EF exec page and a LOCK ADD CL,[rDI + disp32]
; instruction at the very end of it.
;
mov eax, __LINE__
mov xDI, [REF_EXTERN(g_pbEfExecPage)]
add xDI, 1000h - 8h
mov byte [xDI+0], 0f0h
mov byte [xDI+1], 002h
mov byte [xDI+2], 08fh
mov dword [xDI+3], 000000000h
mov byte [xDI+7], 0cch
ShouldTrap X86_XCPT_UD, call xDI
mov eax, __LINE__
mov xDI, [REF_EXTERN(g_pbEfExecPage)]
add xDI, 1000h - 7h
mov byte [xDI+0], 0f0h
mov byte [xDI+1], 002h
mov byte [xDI+2], 08Fh
mov dword [xDI+3], 000000000h
ShouldTrap X86_XCPT_UD, call xDI
mov eax, __LINE__
mov xDI, [REF_EXTERN(g_pbEfExecPage)]
add xDI, 1000h - 4h
mov byte [xDI+0], 0f0h
mov byte [xDI+1], 002h
mov byte [xDI+2], 08Fh
mov byte [xDI+3], 000h
ShouldTrap X86_XCPT_PF, call xDI
mov eax, __LINE__
mov xDI, [REF_EXTERN(g_pbEfExecPage)]
add xDI, 1000h - 6h
mov byte [xDI+0], 0f0h
mov byte [xDI+1], 002h
mov byte [xDI+2], 08Fh
mov byte [xDI+3], 00h
mov byte [xDI+4], 00h
mov byte [xDI+5], 00h
ShouldTrap X86_XCPT_PF, call xDI
mov eax, __LINE__
mov xDI, [REF_EXTERN(g_pbEfExecPage)]
add xDI, 1000h - 5h
mov byte [xDI+0], 0f0h
mov byte [xDI+1], 002h
mov byte [xDI+2], 08Fh
mov byte [xDI+3], 00h
mov byte [xDI+4], 00h
ShouldTrap X86_XCPT_PF, call xDI
mov eax, __LINE__
mov xDI, [REF_EXTERN(g_pbEfExecPage)]
add xDI, 1000h - 4h
mov byte [xDI+0], 0f0h
mov byte [xDI+1], 002h
mov byte [xDI+2], 08Fh
mov byte [xDI+3], 00h
ShouldTrap X86_XCPT_PF, call xDI
mov eax, __LINE__
mov xDI, [REF_EXTERN(g_pbEfExecPage)]
add xDI, 1000h - 3h
mov byte [xDI+0], 0f0h
mov byte [xDI+1], 002h
mov byte [xDI+2], 08Fh
ShouldTrap X86_XCPT_PF, call xDI
mov eax, __LINE__
mov xDI, [REF_EXTERN(g_pbEfExecPage)]
add xDI, 1000h - 2h
mov byte [xDI+0], 0f0h
mov byte [xDI+1], 002h
ShouldTrap X86_XCPT_PF, call xDI
mov eax, __LINE__
mov xDI, [REF_EXTERN(g_pbEfExecPage)]
add xDI, 1000h - 1h
mov byte [xDI+0], 0f0h
ShouldTrap X86_XCPT_PF, call xDI
.success:
xor eax, eax
.return:
%ifdef RT_ARCH_AMD64
pop r15
pop r14
pop r13
pop r12
pop r11
pop r10
pop r9
pop r8
%endif
pop xDI
pop xSI
pop xDX
pop xCX
pop xBX
popf
leave
ret
.failed2:
mov eax, -1
.failed:
jmp .return
ENDPROC x861_Test1
;;
; Tests the effect of prefix order in group 14.
;
BEGINPROC x861_Test2
SAVE_ALL_PROLOGUE
; Check testcase preconditions.
call x861_LoadUniqueRegValuesSSEAndGRegs
mov eax, __LINE__
db 00Fh, 073h, 0D0h, 080h ; psrlq mm0, 128
call .check_mm0_zero_and_xmm0_nz
call x861_LoadUniqueRegValuesSSEAndGRegs
mov eax, __LINE__
db 066h, 00Fh, 073h, 0D0h, 080h ; psrlq xmm0, 128
call .check_xmm0_zero_and_mm0_nz
;
; Real test - Inject other prefixes before the 066h and see what
; happens.
;
; General checks that order does not matter, etc.
call x861_LoadUniqueRegValuesSSEAndGRegs
mov eax, __LINE__
db 026h, 066h, 00Fh, 073h, 0D0h, 080h
call .check_xmm0_zero_and_mm0_nz
call x861_LoadUniqueRegValuesSSEAndGRegs
mov eax, __LINE__
db 066h, 026h, 00Fh, 073h, 0D0h, 080h
call .check_xmm0_zero_and_mm0_nz
call x861_LoadUniqueRegValuesSSEAndGRegs
mov eax, __LINE__
db 066h, 067h, 00Fh, 073h, 0D0h, 080h
call .check_xmm0_zero_and_mm0_nz
call x861_LoadUniqueRegValuesSSEAndGRegs
mov eax, __LINE__
db 067h, 066h, 00Fh, 073h, 0D0h, 080h
call .check_xmm0_zero_and_mm0_nz
call x861_LoadUniqueRegValuesSSEAndGRegs
mov eax, __LINE__
db 067h, 066h, 065h, 00Fh, 073h, 0D0h, 080h
call .check_xmm0_zero_and_mm0_nz
%ifdef RT_ARCH_AMD64
call x861_LoadUniqueRegValuesSSEAndGRegs
mov eax, __LINE__
db 048h, 066h, 00Fh, 073h, 0D0h, 080h ; REX.W
call .check_xmm0_zero_and_mm0_nz
call x861_LoadUniqueRegValuesSSEAndGRegs
mov eax, __LINE__
db 044h, 066h, 00Fh, 073h, 0D0h, 080h ; REX.R
call .check_xmm0_zero_and_mm0_nz
call x861_LoadUniqueRegValuesSSEAndGRegs
mov eax, __LINE__
db 042h, 066h, 00Fh, 073h, 0D0h, 080h ; REX.X
call .check_xmm0_zero_and_mm0_nz
; Actually for REX, order does matter if the prefix is used.
call x861_LoadUniqueRegValuesSSEAndGRegs
mov eax, __LINE__
db 041h, 066h, 00Fh, 073h, 0D0h, 080h ; REX.B
call .check_xmm0_zero_and_mm0_nz
call x861_LoadUniqueRegValuesSSEAndGRegs
mov eax, __LINE__
db 066h, 041h, 00Fh, 073h, 0D0h, 080h ; REX.B
call .check_xmm8_zero_and_xmm0_nz
%endif
; Check all ignored prefixes (repeates some of the above).
call x861_LoadUniqueRegValuesSSEAndGRegs
mov eax, __LINE__
db 066h, 026h, 00Fh, 073h, 0D0h, 080h ; es
call .check_xmm0_zero_and_mm0_nz
call x861_LoadUniqueRegValuesSSEAndGRegs
mov eax, __LINE__
db 066h, 065h, 00Fh, 073h, 0D0h, 080h ; gs
call .check_xmm0_zero_and_mm0_nz
call x861_LoadUniqueRegValuesSSEAndGRegs
mov eax, __LINE__
db 066h, 064h, 00Fh, 073h, 0D0h, 080h ; fs
call .check_xmm0_zero_and_mm0_nz
call x861_LoadUniqueRegValuesSSEAndGRegs
mov eax, __LINE__
db 066h, 02eh, 00Fh, 073h, 0D0h, 080h ; cs
call .check_xmm0_zero_and_mm0_nz
call x861_LoadUniqueRegValuesSSEAndGRegs
mov eax, __LINE__
db 066h, 036h, 00Fh, 073h, 0D0h, 080h ; ss
call .check_xmm0_zero_and_mm0_nz
call x861_LoadUniqueRegValuesSSEAndGRegs
mov eax, __LINE__
db 066h, 03eh, 00Fh, 073h, 0D0h, 080h ; ds
call .check_xmm0_zero_and_mm0_nz
call x861_LoadUniqueRegValuesSSEAndGRegs
mov eax, __LINE__
db 066h, 067h, 00Fh, 073h, 0D0h, 080h ; addr size
call .check_xmm0_zero_and_mm0_nz
%ifdef RT_ARCH_AMD64
call x861_LoadUniqueRegValuesSSEAndGRegs
mov eax, __LINE__
db 066h, 048h, 00Fh, 073h, 0D0h, 080h ; REX.W
call .check_xmm0_zero_and_mm0_nz
call x861_LoadUniqueRegValuesSSEAndGRegs
mov eax, __LINE__
db 066h, 044h, 00Fh, 073h, 0D0h, 080h ; REX.R
call .check_xmm0_zero_and_mm0_nz
call x861_LoadUniqueRegValuesSSEAndGRegs
mov eax, __LINE__
db 066h, 042h, 00Fh, 073h, 0D0h, 080h ; REX.X
call .check_xmm0_zero_and_mm0_nz
call x861_LoadUniqueRegValuesSSEAndGRegs
mov eax, __LINE__
db 066h, 041h, 00Fh, 073h, 0D0h, 080h ; REX.B - has actual effect on the instruction.
call .check_xmm8_zero_and_xmm0_nz
%endif
; Repeated prefix until we hit the max opcode limit.
call x861_LoadUniqueRegValuesSSEAndGRegs
mov eax, __LINE__
db 066h, 066h, 00Fh, 073h, 0D0h, 080h
call .check_xmm0_zero_and_mm0_nz
call x861_LoadUniqueRegValuesSSEAndGRegs
mov eax, __LINE__
db 066h, 066h, 066h, 00Fh, 073h, 0D0h, 080h
call .check_xmm0_zero_and_mm0_nz
call x861_LoadUniqueRegValuesSSEAndGRegs
mov eax, __LINE__
db 066h, 066h, 066h, 066h, 066h, 066h, 066h, 066h, 00Fh, 073h, 0D0h, 080h
call .check_xmm0_zero_and_mm0_nz
call x861_LoadUniqueRegValuesSSEAndGRegs
mov eax, __LINE__
db 066h, 066h, 066h, 066h, 066h, 066h, 066h, 066h, 066h, 066h, 066h, 00Fh, 073h, 0D0h, 080h
call .check_xmm0_zero_and_mm0_nz
ShouldTrap X86_XCPT_GP, db 066h, 066h, 066h, 066h, 066h, 066h, 066h, 066h, 066h, 066h, 066h, 066h, 00Fh, 073h, 0D0h, 080h
%ifdef RT_ARCH_AMD64
; Repeated REX is parsed, but only the last byte matters.
call x861_LoadUniqueRegValuesSSEAndGRegs
mov eax, __LINE__
db 066h, 041h, 048h, 00Fh, 073h, 0D0h, 080h ; REX.B, REX.W
call .check_xmm0_zero_and_mm0_nz
call x861_LoadUniqueRegValuesSSEAndGRegs
mov eax, __LINE__
db 066h, 048h, 041h, 00Fh, 073h, 0D0h, 080h ; REX.B, REX.W
call .check_xmm8_zero_and_xmm0_nz
call x861_LoadUniqueRegValuesSSEAndGRegs
mov eax, __LINE__
db 066h, 048h, 044h, 042h, 048h, 044h, 042h, 048h, 044h, 042h, 041h, 00Fh, 073h, 0D0h, 080h
call .check_xmm8_zero_and_xmm0_nz
call x861_LoadUniqueRegValuesSSEAndGRegs
mov eax, __LINE__
db 066h, 041h, 041h, 041h, 041h, 041h, 041h, 041h, 041h, 041h, 04eh, 00Fh, 073h, 0D0h, 080h
call .check_xmm0_zero_and_mm0_nz
%endif
; Undefined sequences with prefixes that counts.
ShouldTrap X86_XCPT_UD, db 0f0h, 066h, 00Fh, 073h, 0D0h, 080h ; LOCK
ShouldTrap X86_XCPT_UD, db 0f2h, 066h, 00Fh, 073h, 0D0h, 080h ; REPNZ
ShouldTrap X86_XCPT_UD, db 0f3h, 066h, 00Fh, 073h, 0D0h, 080h ; REPZ
ShouldTrap X86_XCPT_UD, db 066h, 0f2h, 00Fh, 073h, 0D0h, 080h
ShouldTrap X86_XCPT_UD, db 066h, 0f3h, 00Fh, 073h, 0D0h, 080h
ShouldTrap X86_XCPT_UD, db 066h, 0f3h, 0f2h, 00Fh, 073h, 0D0h, 080h
ShouldTrap X86_XCPT_UD, db 066h, 0f2h, 0f3h, 00Fh, 073h, 0D0h, 080h
ShouldTrap X86_XCPT_UD, db 0f2h, 066h, 0f3h, 00Fh, 073h, 0D0h, 080h
ShouldTrap X86_XCPT_UD, db 0f3h, 066h, 0f2h, 00Fh, 073h, 0D0h, 080h
ShouldTrap X86_XCPT_UD, db 0f3h, 0f2h, 066h, 00Fh, 073h, 0D0h, 080h
ShouldTrap X86_XCPT_UD, db 0f2h, 0f3h, 066h, 00Fh, 073h, 0D0h, 080h
ShouldTrap X86_XCPT_UD, db 0f0h, 0f2h, 066h, 0f3h, 00Fh, 073h, 0D0h, 080h
ShouldTrap X86_XCPT_UD, db 0f0h, 0f3h, 066h, 0f2h, 00Fh, 073h, 0D0h, 080h
ShouldTrap X86_XCPT_UD, db 0f0h, 0f3h, 0f2h, 066h, 00Fh, 073h, 0D0h, 080h
ShouldTrap X86_XCPT_UD, db 0f0h, 0f2h, 0f3h, 066h, 00Fh, 073h, 0D0h, 080h
.success:
xor eax, eax
.return:
SAVE_ALL_EPILOGUE
ret
.check_xmm0_zero_and_mm0_nz:
sub xSP, 20h
movdqu [xSP], xmm0
cmp dword [xSP], 0
jne .failed3
cmp dword [xSP + 4], 0
jne .failed3
cmp dword [xSP + 8], 0
jne .failed3
cmp dword [xSP + 12], 0
jne .failed3
movq [xSP], mm0
cmp dword [xSP], 0
je .failed3
cmp dword [xSP + 4], 0
je .failed3
add xSP, 20h
ret
.check_mm0_zero_and_xmm0_nz:
sub xSP, 20h
movq [xSP], mm0
cmp dword [xSP], 0
jne .failed3
cmp dword [xSP + 4], 0
jne .failed3
movdqu [xSP], xmm0
cmp dword [xSP], 0
je .failed3
cmp dword [xSP + 4], 0
je .failed3
cmp dword [xSP + 8], 0
je .failed3
cmp dword [xSP + 12], 0
je .failed3
add xSP, 20h
ret
%ifdef RT_ARCH_AMD64
.check_xmm8_zero_and_xmm0_nz:
sub xSP, 20h
movdqu [xSP], xmm8
cmp dword [xSP], 0
jne .failed3
cmp dword [xSP + 4], 0
jne .failed3
cmp dword [xSP + 8], 0
jne .failed3
cmp dword [xSP + 12], 0
jne .failed3
movdqu [xSP], xmm0
cmp dword [xSP], 0
je .failed3
cmp dword [xSP + 4], 0
je .failed3
cmp dword [xSP + 8], 0
je .failed3
cmp dword [xSP + 12], 0
je .failed3
add xSP, 20h
ret
%endif
.failed3:
add xSP, 20h + xCB
jmp .return
ENDPROC x861_Test2
;;
; Tests how much fxsave and fxrstor actually accesses of their 512 memory
; operand.
;
BEGINPROC x861_Test3
SAVE_ALL_PROLOGUE
call x861_LoadUniqueRegValuesSSEAndGRegs
mov xDI, [REF_EXTERN(g_pbEfExecPage)]
; Check testcase preconditions.
fxsave [xDI]
fxrstor [xDI]
add xDI, PAGE_SIZE - 512
mov xSI, xDI
fxsave [xDI]
fxrstor [xDI]
; 464:511 are available to software use. Check that they are left
; untouched by fxsave.
mov eax, 0aabbccddh
mov ecx, 512 / 4
cld
rep stosd
mov xDI, xSI
fxsave [xDI]
mov ebx, 512
.chech_software_area_loop:
cmp [xDI + xBX - 4], eax
jne .chech_software_area_done
sub ebx, 4
jmp .chech_software_area_loop
.chech_software_area_done:
cmp ebx, 464
mov eax, __LINE__
ja .return
; Check that a save + restore + save cycle yield the same results.
mov xBX, [REF_EXTERN(g_pbEfExecPage)]
mov xDI, xBX
mov eax, 066778899h
mov ecx, 512 * 2 / 4
cld
rep stosd
fxsave [xBX]
call x861_ClearRegistersSSEAndGRegs
mov xBX, [REF_EXTERN(g_pbEfExecPage)]
fxrstor [xBX]
fxsave [xBX + 512]
mov xSI, xBX
lea xDI, [xBX + 512]
mov ecx, 512
cld
repe cmpsb
mov eax, __LINE__
jnz .return
; 464:511 are available to software use. Let see how carefully access
; to the full 512 bytes are checked...
call x861_LoadUniqueRegValuesSSEAndGRegs
mov xDI, [REF_EXTERN(g_pbEfExecPage)]
add xDI, PAGE_SIZE - 512
ShouldTrap X86_XCPT_PF, fxsave [xDI + 16]
ShouldTrap X86_XCPT_PF, fxsave [xDI + 32]
ShouldTrap X86_XCPT_PF, fxsave [xDI + 48]
ShouldTrap X86_XCPT_PF, fxsave [xDI + 64]
ShouldTrap X86_XCPT_PF, fxsave [xDI + 80]
ShouldTrap X86_XCPT_PF, fxsave [xDI + 96]
ShouldTrap X86_XCPT_PF, fxsave [xDI + 128]
ShouldTrap X86_XCPT_PF, fxsave [xDI + 144]
ShouldTrap X86_XCPT_PF, fxsave [xDI + 160]
ShouldTrap X86_XCPT_PF, fxsave [xDI + 176]
ShouldTrap X86_XCPT_PF, fxsave [xDI + 192]
ShouldTrap X86_XCPT_PF, fxsave [xDI + 208]
ShouldTrap X86_XCPT_PF, fxsave [xDI + 224]
ShouldTrap X86_XCPT_PF, fxsave [xDI + 240]
ShouldTrap X86_XCPT_PF, fxsave [xDI + 256]
ShouldTrap X86_XCPT_PF, fxsave [xDI + 384]
ShouldTrap X86_XCPT_PF, fxsave [xDI + 432]
ShouldTrap X86_XCPT_PF, fxsave [xDI + 496]
ShouldTrap X86_XCPT_PF, fxrstor [xDI + 16]
ShouldTrap X86_XCPT_PF, fxrstor [xDI + 32]
ShouldTrap X86_XCPT_PF, fxrstor [xDI + 48]
ShouldTrap X86_XCPT_PF, fxrstor [xDI + 64]
ShouldTrap X86_XCPT_PF, fxrstor [xDI + 80]
ShouldTrap X86_XCPT_PF, fxrstor [xDI + 96]
ShouldTrap X86_XCPT_PF, fxrstor [xDI + 128]
ShouldTrap X86_XCPT_PF, fxrstor [xDI + 144]
ShouldTrap X86_XCPT_PF, fxrstor [xDI + 160]
ShouldTrap X86_XCPT_PF, fxrstor [xDI + 176]
ShouldTrap X86_XCPT_PF, fxrstor [xDI + 192]
ShouldTrap X86_XCPT_PF, fxrstor [xDI + 208]
ShouldTrap X86_XCPT_PF, fxrstor [xDI + 224]
ShouldTrap X86_XCPT_PF, fxrstor [xDI + 240]
ShouldTrap X86_XCPT_PF, fxrstor [xDI + 256]
ShouldTrap X86_XCPT_PF, fxrstor [xDI + 384]
ShouldTrap X86_XCPT_PF, fxrstor [xDI + 432]
ShouldTrap X86_XCPT_PF, fxrstor [xDI + 496]
; Unaligned accesses will cause #GP(0). This takes precedence over #PF.
ShouldTrap X86_XCPT_GP, fxsave [xDI + 1]
ShouldTrap X86_XCPT_GP, fxsave [xDI + 2]
ShouldTrap X86_XCPT_GP, fxsave [xDI + 3]
ShouldTrap X86_XCPT_GP, fxsave [xDI + 4]
ShouldTrap X86_XCPT_GP, fxsave [xDI + 5]
ShouldTrap X86_XCPT_GP, fxsave [xDI + 6]
ShouldTrap X86_XCPT_GP, fxsave [xDI + 7]
ShouldTrap X86_XCPT_GP, fxsave [xDI + 8]
ShouldTrap X86_XCPT_GP, fxsave [xDI + 9]
ShouldTrap X86_XCPT_GP, fxsave [xDI + 10]
ShouldTrap X86_XCPT_GP, fxsave [xDI + 11]
ShouldTrap X86_XCPT_GP, fxsave [xDI + 12]
ShouldTrap X86_XCPT_GP, fxsave [xDI + 13]
ShouldTrap X86_XCPT_GP, fxsave [xDI + 14]
ShouldTrap X86_XCPT_GP, fxsave [xDI + 15]
ShouldTrap X86_XCPT_GP, fxrstor [xDI + 1]
ShouldTrap X86_XCPT_GP, fxrstor [xDI + 2]
ShouldTrap X86_XCPT_GP, fxrstor [xDI + 3]
ShouldTrap X86_XCPT_GP, fxrstor [xDI + 4]
ShouldTrap X86_XCPT_GP, fxrstor [xDI + 5]
ShouldTrap X86_XCPT_GP, fxrstor [xDI + 6]
ShouldTrap X86_XCPT_GP, fxrstor [xDI + 7]
ShouldTrap X86_XCPT_GP, fxrstor [xDI + 8]
ShouldTrap X86_XCPT_GP, fxrstor [xDI + 9]
ShouldTrap X86_XCPT_GP, fxrstor [xDI + 10]
ShouldTrap X86_XCPT_GP, fxrstor [xDI + 11]
ShouldTrap X86_XCPT_GP, fxrstor [xDI + 12]
ShouldTrap X86_XCPT_GP, fxrstor [xDI + 13]
ShouldTrap X86_XCPT_GP, fxrstor [xDI + 14]
ShouldTrap X86_XCPT_GP, fxrstor [xDI + 15]
; Lets check what a FP in fxsave changes ... nothing on intel.
mov ebx, 16
.fxsave_pf_effect_loop:
mov xDI, [REF_EXTERN(g_pbEfExecPage)]
add xDI, PAGE_SIZE - 512 * 2
mov xSI, xDI
mov eax, 066778899h
mov ecx, 512 * 2 / 4
cld
rep stosd
ShouldTrap X86_XCPT_PF, fxsave [xSI + PAGE_SIZE - 512 + xBX]
mov ecx, 512 / 4
lea xDI, [xSI + 512]
cld
repz cmpsd
lea xAX, [xBX + 20000]
jnz .return
add ebx, 16
cmp ebx, 512
jbe .fxsave_pf_effect_loop
; Lets check that a FP in fxrstor does not have any effect on the FPU or SSE state.
mov xDI, [REF_EXTERN(g_pbEfExecPage)]
mov ecx, PAGE_SIZE / 4
mov eax, 0ffaa33cch
cld
rep stosd
call x861_LoadUniqueRegValuesSSEAndGRegs
mov xDI, [REF_EXTERN(g_pbEfExecPage)]
fxsave [xDI]
call x861_ClearRegistersSSEAndGRegs
mov xDI, [REF_EXTERN(g_pbEfExecPage)]
fxsave [xDI + 512]
mov ebx, 16
.fxrstor_pf_effect_loop:
mov xDI, [REF_EXTERN(g_pbEfExecPage)]
mov xSI, xDI
lea xDI, [xDI + PAGE_SIZE - 512 + xBX]
mov ecx, 512
sub ecx, ebx
cld
rep movsb ; copy unique state to end of page.
push xBX
call x861_ClearRegistersSSEAndGRegs
pop xBX
mov xDI, [REF_EXTERN(g_pbEfExecPage)]
ShouldTrap X86_XCPT_PF, fxrstor [xDI + PAGE_SIZE - 512 + xBX] ; try load unique state
mov xDI, [REF_EXTERN(g_pbEfExecPage)]
lea xSI, [xDI + 512] ; point it to the clean state, which is what we expect.
lea xDI, [xDI + 1024]
fxsave [xDI] ; save whatever the fpu state currently is.
mov ecx, 512 / 4
cld
repe cmpsd
lea xAX, [xBX + 40000]
jnz .return ; it shouldn't be modified by faulting fxrstor, i.e. a clean state.
add ebx, 16
cmp ebx, 512
jbe .fxrstor_pf_effect_loop
.success:
xor eax, eax
.return:
SAVE_ALL_EPILOGUE
ret
ENDPROC x861_Test3
;;
; Tests various multibyte NOP sequences.
;
BEGINPROC x861_Test4
SAVE_ALL_PROLOGUE
call x861_ClearRegisters
; Intel recommended sequences.
nop
db 066h, 090h
db 00fh, 01fh, 000h
db 00fh, 01fh, 040h, 000h
db 00fh, 01fh, 044h, 000h, 000h
db 066h, 00fh, 01fh, 044h, 000h, 000h
db 00fh, 01fh, 080h, 000h, 000h, 000h, 000h
db 00fh, 01fh, 084h, 000h, 000h, 000h, 000h, 000h
db 066h, 00fh, 01fh, 084h, 000h, 000h, 000h, 000h, 000h
; Check that the NOPs are allergic to lock prefixing.
ShouldTrap X86_XCPT_UD, db 0f0h, 090h ; lock prefixed NOP.
ShouldTrap X86_XCPT_UD, db 0f0h, 066h, 090h ; lock prefixed two byte NOP.
ShouldTrap X86_XCPT_UD, db 0f0h, 00fh, 01fh, 000h ; lock prefixed three byte NOP.
; Check the range of instructions that AMD marks as NOPs.
%macro TST_NOP 1
db 00fh, %1, 000h
db 00fh, %1, 040h, 000h
db 00fh, %1, 044h, 000h, 000h
db 066h, 00fh, %1, 044h, 000h, 000h
db 00fh, %1, 080h, 000h, 000h, 000h, 000h
db 00fh, %1, 084h, 000h, 000h, 000h, 000h, 000h
db 066h, 00fh, %1, 084h, 000h, 000h, 000h, 000h, 000h
ShouldTrap X86_XCPT_UD, db 0f0h, 00fh, %1, 000h
%endmacro
TST_NOP 019h
TST_NOP 01ah
TST_NOP 01bh
TST_NOP 01ch
TST_NOP 01dh
TST_NOP 01eh
TST_NOP 01fh
; The AMD P group, intel marks this as a NOP.
TST_NOP 00dh
.success:
xor eax, eax
.return:
SAVE_ALL_EPILOGUE
ret
ENDPROC x861_Test4
;;
; Tests various odd/weird/bad encodings.
;
BEGINPROC x861_Test5
SAVE_ALL_PROLOGUE
call x861_ClearRegisters
%if 0
; callf eax...
ShouldTrap X86_XCPT_UD, db 0xff, 11011000b
ShouldTrap X86_XCPT_UD, db 0xff, 11011001b
ShouldTrap X86_XCPT_UD, db 0xff, 11011010b
ShouldTrap X86_XCPT_UD, db 0xff, 11011011b
ShouldTrap X86_XCPT_UD, db 0xff, 11011100b
ShouldTrap X86_XCPT_UD, db 0xff, 11011101b
ShouldTrap X86_XCPT_UD, db 0xff, 11011110b
ShouldTrap X86_XCPT_UD, db 0xff, 11011111b
; jmpf eax...
ShouldTrap X86_XCPT_UD, db 0xff, 11101000b
ShouldTrap X86_XCPT_UD, db 0xff, 11101001b
ShouldTrap X86_XCPT_UD, db 0xff, 11101010b
ShouldTrap X86_XCPT_UD, db 0xff, 11101011b
ShouldTrap X86_XCPT_UD, db 0xff, 11101100b
ShouldTrap X86_XCPT_UD, db 0xff, 11101101b
ShouldTrap X86_XCPT_UD, db 0xff, 11101110b
ShouldTrap X86_XCPT_UD, db 0xff, 11101111b
; #GP(0) vs #UD.
ShouldTrap X86_XCPT_GP, mov xAX, cr0
ShouldTrap X86_XCPT_UD, lock mov xAX, cr0
ShouldTrap X86_XCPT_GP, mov cr0, xAX
ShouldTrap X86_XCPT_UD, lock mov cr0, xAX
ShouldTrap X86_XCPT_UD, db 0x0f, 0x20,11001000b ; mov xAX, cr1
ShouldTrap X86_XCPT_UD, db 0x0f, 0x20,11101000b ; mov xAX, cr5
ShouldTrap X86_XCPT_UD, db 0x0f, 0x20,11110000b ; mov xAX, cr6
ShouldTrap X86_XCPT_UD, db 0x0f, 0x20,11111000b ; mov xAX, cr7
ShouldTrap X86_XCPT_GP, mov xAX, dr7
ShouldTrap X86_XCPT_UD, lock mov xAX, dr7
; The MOD is ignored by MOV CRx,GReg and MOV GReg,CRx
ShouldTrap X86_XCPT_GP, db 0x0f, 0x20,00000000b ; mov xAX, cr0
ShouldTrap X86_XCPT_GP, db 0x0f, 0x20,01000000b ; mov xAX, cr0
ShouldTrap X86_XCPT_GP, db 0x0f, 0x20,10000000b ; mov xAX, cr0
ShouldTrap X86_XCPT_GP, db 0x0f, 0x20,11000000b ; mov xAX, cr0
ShouldTrap X86_XCPT_GP, db 0x0f, 0x22,00000000b ; mov cr0, xAX
ShouldTrap X86_XCPT_GP, db 0x0f, 0x22,01000000b ; mov cr0, xAX
ShouldTrap X86_XCPT_GP, db 0x0f, 0x22,10000000b ; mov cr0, xAX
ShouldTrap X86_XCPT_GP, db 0x0f, 0x22,11000000b ; mov cr0, xAX
%endif
; mov eax, tr0, 0x0f 0x24
ShouldTrap X86_XCPT_UD, db 0x0f, 0x24, 0xc0 ; mov xAX, tr1
mov xAX, [REF_EXTERN(g_pbEfExecPage)]
add xAX, PAGE_SIZE - 3
mov byte [xAX ], 0x0f
mov byte [xAX + 1], 0x24
mov byte [xAX + 2], 0xc0
ShouldTrapExecPage X86_XCPT_UD, PAGE_SIZE - 3
mov xAX, [REF_EXTERN(g_pbEfExecPage)]
add xAX, PAGE_SIZE - 2
mov byte [xAX ], 0x0f
mov byte [xAX + 1], 0x24
ShouldTrapExecPage X86_XCPT_UD, PAGE_SIZE - 2
.success:
xor eax, eax
.return:
SAVE_ALL_EPILOGUE
ret
ENDPROC x861_Test5
;;
; Tests an reserved FPU encoding, checking that it does not affect the FPU or
; CPU state in any way.
;
; @uses stack
%macro FpuNopEncoding 1+
fnclex
call SetFSW_C0_thru_C3
push xBP
mov xBP, xSP
sub xSP, 1024
and xSP, ~0fh
call SaveFPUAndGRegsToStack
%1
call CompareFPUAndGRegsOnStackIgnoreOpAndIp
leave
jz %%ok
add eax, __LINE__
jmp .return
%%ok:
%endmacro
;;
; Used for marking encodings which has a meaning other than FNOP and
; needs investigating.
%macro FpuReservedEncoding 2
fnclex
call SetFSW_C0_thru_C3
push xBP
mov xBP, xSP
sub xSP, 2048
and xSP, ~0fh
mov dword [xSP + 1024 + X86FXSTATE.FPUIP], 0
mov dword [xSP + 1024 + X86FXSTATE.FPUCS], 0
mov dword [xSP + 1024 + X86FXSTATE.FPUDP], 0
mov dword [xSP + 1024 + X86FXSTATE.FPUDS], 0
arch_fxsave [xSP + 1024]
%1
call SaveFPUAndGRegsToStack
arch_fxrstor [xSP + 1024]
%2
call CompareFPUAndGRegsOnStackIgnoreOpAndIp
;arch_fxrstor [xSP + 1024]
leave
jz %%ok
add eax, __LINE__
jmp .return
%%ok:
%endmacro
;;
; Saves the FPU and general registers to the stack area right next to the
; return address.
;
; The required area size is 512 + 80h = 640.
;
; @uses Nothing, except stack.
;
SaveFPUAndGRegsToStack:
; Must clear the FXSAVE area.
pushf
push xCX
push xAX
push xDI
lea xDI, [xSP + xCB * 5]
mov xCX, 512 / 4
mov eax, 0cccccccch
cld
rep stosd
pop xDI
pop xAX
pop xCX
popf
; Save the FPU state.
mov dword [xSP + xCB + X86FXSTATE.FPUIP], 0
mov dword [xSP + xCB + X86FXSTATE.FPUCS], 0
mov dword [xSP + xCB + X86FXSTATE.FPUDP], 0
mov dword [xSP + xCB + X86FXSTATE.FPUDS], 0
arch_fxsave [xSP + xCB]
; Save GRegs (80h bytes).
%ifdef RT_ARCH_AMD64
mov [xSP + 512 + xCB + 000h], xAX
mov [xSP + 512 + xCB + 008h], xBX
mov [xSP + 512 + xCB + 010h], xCX
mov [xSP + 512 + xCB + 018h], xDX
mov [xSP + 512 + xCB + 020h], xDI
mov [xSP + 512 + xCB + 028h], xSI
mov [xSP + 512 + xCB + 030h], xBP
mov [xSP + 512 + xCB + 038h], r8
mov [xSP + 512 + xCB + 040h], r9
mov [xSP + 512 + xCB + 048h], r10
mov [xSP + 512 + xCB + 050h], r11
mov [xSP + 512 + xCB + 058h], r12
mov [xSP + 512 + xCB + 060h], r13
mov [xSP + 512 + xCB + 068h], r14
mov [xSP + 512 + xCB + 070h], r15
pushf
pop rax
mov [xSP + 512 + xCB + 078h], rax
mov rax, [xSP + 512 + xCB + 000h]
%else
mov [xSP + 512 + xCB + 000h], eax
mov [xSP + 512 + xCB + 004h], eax
mov [xSP + 512 + xCB + 008h], ebx
mov [xSP + 512 + xCB + 00ch], ebx
mov [xSP + 512 + xCB + 010h], ecx
mov [xSP + 512 + xCB + 014h], ecx
mov [xSP + 512 + xCB + 018h], edx
mov [xSP + 512 + xCB + 01ch], edx
mov [xSP + 512 + xCB + 020h], edi
mov [xSP + 512 + xCB + 024h], edi
mov [xSP + 512 + xCB + 028h], esi
mov [xSP + 512 + xCB + 02ch], esi
mov [xSP + 512 + xCB + 030h], ebp
mov [xSP + 512 + xCB + 034h], ebp
mov [xSP + 512 + xCB + 038h], eax
mov [xSP + 512 + xCB + 03ch], eax
mov [xSP + 512 + xCB + 040h], eax
mov [xSP + 512 + xCB + 044h], eax
mov [xSP + 512 + xCB + 048h], eax
mov [xSP + 512 + xCB + 04ch], eax
mov [xSP + 512 + xCB + 050h], eax
mov [xSP + 512 + xCB + 054h], eax
mov [xSP + 512 + xCB + 058h], eax
mov [xSP + 512 + xCB + 05ch], eax
mov [xSP + 512 + xCB + 060h], eax
mov [xSP + 512 + xCB + 064h], eax
mov [xSP + 512 + xCB + 068h], eax
mov [xSP + 512 + xCB + 06ch], eax
mov [xSP + 512 + xCB + 070h], eax
mov [xSP + 512 + xCB + 074h], eax
pushf
pop eax
mov [xSP + 512 + xCB + 078h], eax
mov [xSP + 512 + xCB + 07ch], eax
mov eax, [xSP + 512 + xCB + 000h]
%endif
ret
;;
; Compares the current FPU and general registers to that found in the stack
; area prior to the return address.
;
; @uses Stack, flags and eax/rax.
; @returns eax is zero on success, eax is 1000000 * offset on failure.
; ZF reflects the eax value to save a couple of instructions...
;
CompareFPUAndGRegsOnStack:
lea xSP, [xSP - (1024 - xCB)]
call SaveFPUAndGRegsToStack
push xSI
push xDI
push xCX
mov xCX, 640
lea xSI, [xSP + xCB*3]
lea xDI, [xSI + 1024]
cld
repe cmpsb
je .ok
;int3
lea xAX, [xSP + xCB*3]
xchg xAX, xSI
sub xAX, xSI
push xDX
mov xDX, 1000000
mul xDX
pop xDX
jmp .return
.ok:
xor eax, eax
.return:
pop xCX
pop xDI
pop xSI
lea xSP, [xSP + (1024 - xCB)]
or eax, eax
ret
;;
; Same as CompareFPUAndGRegsOnStack, except that it ignores the FOP and FPUIP
; registers.
;
; @uses Stack, flags and eax/rax.
; @returns eax is zero on success, eax is 1000000 * offset on failure.
; ZF reflects the eax value to save a couple of instructions...
;
CompareFPUAndGRegsOnStackIgnoreOpAndIp:
lea xSP, [xSP - (1024 - xCB)]
call SaveFPUAndGRegsToStack
push xSI
push xDI
push xCX
mov xCX, 640
lea xSI, [xSP + xCB*3]
lea xDI, [xSI + 1024]
mov word [xSI + X86FXSTATE.FOP], 0 ; ignore
mov word [xDI + X86FXSTATE.FOP], 0 ; ignore
mov dword [xSI + X86FXSTATE.FPUIP], 0 ; ignore
mov dword [xDI + X86FXSTATE.FPUIP], 0 ; ignore
cld
repe cmpsb
je .ok
;int3
lea xAX, [xSP + xCB*3]
xchg xAX, xSI
sub xAX, xSI
push xDX
mov xDX, 1000000
mul xDX
pop xDX
jmp .return
.ok:
xor eax, eax
.return:
pop xCX
pop xDI
pop xSI
lea xSP, [xSP + (1024 - xCB)]
or eax, eax
ret
SetFSW_C0_thru_C3:
sub xSP, 20h
fstenv [xSP]
or word [xSP + 4], X86_FSW_C0 | X86_FSW_C1 | X86_FSW_C2 | X86_FSW_C3
fldenv [xSP]
add xSP, 20h
ret
;;
; Tests some odd floating point instruction encodings.
;
BEGINPROC x861_Test6
SAVE_ALL_PROLOGUE
; standard stuff...
fld dword [REF(g_r32V1)]
fld qword [REF(g_r64V1)]
fld tword [REF(g_r80V1)]
fld qword [REF(g_r64V1)]
fld dword [REF(g_r32V2)]
fld dword [REF(g_r32V1)]
; Test the nop check.
FpuNopEncoding fnop
; the 0xd9 block
ShouldTrap X86_XCPT_UD, db 0d9h, 008h
ShouldTrap X86_XCPT_UD, db 0d9h, 009h
ShouldTrap X86_XCPT_UD, db 0d9h, 00ah
ShouldTrap X86_XCPT_UD, db 0d9h, 00bh
ShouldTrap X86_XCPT_UD, db 0d9h, 00ch
ShouldTrap X86_XCPT_UD, db 0d9h, 00dh
ShouldTrap X86_XCPT_UD, db 0d9h, 00eh
ShouldTrap X86_XCPT_UD, db 0d9h, 00fh
ShouldTrap X86_XCPT_UD, db 0d9h, 0d1h
ShouldTrap X86_XCPT_UD, db 0d9h, 0d2h
ShouldTrap X86_XCPT_UD, db 0d9h, 0d3h
ShouldTrap X86_XCPT_UD, db 0d9h, 0d4h
ShouldTrap X86_XCPT_UD, db 0d9h, 0d5h
ShouldTrap X86_XCPT_UD, db 0d9h, 0d6h
ShouldTrap X86_XCPT_UD, db 0d9h, 0d7h
FpuReservedEncoding {db 0d9h, 0d8h}, { fstp st0 }
FpuReservedEncoding {db 0d9h, 0d9h}, { fstp st1 }
FpuReservedEncoding {db 0d9h, 0dah}, { fstp st2 }
FpuReservedEncoding {db 0d9h, 0dbh}, { fstp st3 }
FpuReservedEncoding {db 0d9h, 0dch}, { fstp st4 }
FpuReservedEncoding {db 0d9h, 0ddh}, { fstp st5 }
FpuReservedEncoding {db 0d9h, 0deh}, { fstp st6 }
;FpuReservedEncoding {db 0d9h, 0dfh}, { fstp st7 } ; This variant seems to ignore empty ST(0) values!
ShouldTrap X86_XCPT_UD, db 0d9h, 0e2h
ShouldTrap X86_XCPT_UD, db 0d9h, 0e3h
ShouldTrap X86_XCPT_UD, db 0d9h, 0e6h
ShouldTrap X86_XCPT_UD, db 0d9h, 0e7h
ShouldTrap X86_XCPT_UD, db 0d9h, 0efh
ShouldTrap X86_XCPT_UD, db 0d9h, 008h
ShouldTrap X86_XCPT_UD, db 0d9h, 00fh
; the 0xda block
ShouldTrap X86_XCPT_UD, db 0dah, 0e0h
ShouldTrap X86_XCPT_UD, db 0dah, 0e1h
ShouldTrap X86_XCPT_UD, db 0dah, 0e2h
ShouldTrap X86_XCPT_UD, db 0dah, 0e3h
ShouldTrap X86_XCPT_UD, db 0dah, 0e4h
ShouldTrap X86_XCPT_UD, db 0dah, 0e5h
ShouldTrap X86_XCPT_UD, db 0dah, 0e6h
ShouldTrap X86_XCPT_UD, db 0dah, 0e7h
ShouldTrap X86_XCPT_UD, db 0dah, 0e8h
ShouldTrap X86_XCPT_UD, db 0dah, 0eah
ShouldTrap X86_XCPT_UD, db 0dah, 0ebh
ShouldTrap X86_XCPT_UD, db 0dah, 0ech
ShouldTrap X86_XCPT_UD, db 0dah, 0edh
ShouldTrap X86_XCPT_UD, db 0dah, 0eeh
ShouldTrap X86_XCPT_UD, db 0dah, 0efh
ShouldTrap X86_XCPT_UD, db 0dah, 0f0h
ShouldTrap X86_XCPT_UD, db 0dah, 0f1h
ShouldTrap X86_XCPT_UD, db 0dah, 0f2h
ShouldTrap X86_XCPT_UD, db 0dah, 0f3h
ShouldTrap X86_XCPT_UD, db 0dah, 0f4h
ShouldTrap X86_XCPT_UD, db 0dah, 0f5h
ShouldTrap X86_XCPT_UD, db 0dah, 0f6h
ShouldTrap X86_XCPT_UD, db 0dah, 0f7h
ShouldTrap X86_XCPT_UD, db 0dah, 0f8h
ShouldTrap X86_XCPT_UD, db 0dah, 0f9h
ShouldTrap X86_XCPT_UD, db 0dah, 0fah
ShouldTrap X86_XCPT_UD, db 0dah, 0fbh
ShouldTrap X86_XCPT_UD, db 0dah, 0fch
ShouldTrap X86_XCPT_UD, db 0dah, 0fdh
ShouldTrap X86_XCPT_UD, db 0dah, 0feh
ShouldTrap X86_XCPT_UD, db 0dah, 0ffh
; the 0xdb block
FpuNopEncoding db 0dbh, 0e0h ; fneni
FpuNopEncoding db 0dbh, 0e1h ; fndisi
FpuNopEncoding db 0dbh, 0e4h ; fnsetpm
ShouldTrap X86_XCPT_UD, db 0dbh, 0e5h
ShouldTrap X86_XCPT_UD, db 0dbh, 0e6h
ShouldTrap X86_XCPT_UD, db 0dbh, 0e7h
ShouldTrap X86_XCPT_UD, db 0dbh, 0f8h
ShouldTrap X86_XCPT_UD, db 0dbh, 0f9h
ShouldTrap X86_XCPT_UD, db 0dbh, 0fah
ShouldTrap X86_XCPT_UD, db 0dbh, 0fbh
ShouldTrap X86_XCPT_UD, db 0dbh, 0fch
ShouldTrap X86_XCPT_UD, db 0dbh, 0fdh
ShouldTrap X86_XCPT_UD, db 0dbh, 0feh
ShouldTrap X86_XCPT_UD, db 0dbh, 0ffh
ShouldTrap X86_XCPT_UD, db 0dbh, 020h
ShouldTrap X86_XCPT_UD, db 0dbh, 023h
ShouldTrap X86_XCPT_UD, db 0dbh, 030h
ShouldTrap X86_XCPT_UD, db 0dbh, 032h
; the 0xdc block
FpuReservedEncoding {db 0dch, 0d0h}, { fcom st0 }
FpuReservedEncoding {db 0dch, 0d1h}, { fcom st1 }
FpuReservedEncoding {db 0dch, 0d2h}, { fcom st2 }
FpuReservedEncoding {db 0dch, 0d3h}, { fcom st3 }
FpuReservedEncoding {db 0dch, 0d4h}, { fcom st4 }
FpuReservedEncoding {db 0dch, 0d5h}, { fcom st5 }
FpuReservedEncoding {db 0dch, 0d6h}, { fcom st6 }
FpuReservedEncoding {db 0dch, 0d7h}, { fcom st7 }
FpuReservedEncoding {db 0dch, 0d8h}, { fcomp st0 }
FpuReservedEncoding {db 0dch, 0d9h}, { fcomp st1 }
FpuReservedEncoding {db 0dch, 0dah}, { fcomp st2 }
FpuReservedEncoding {db 0dch, 0dbh}, { fcomp st3 }
FpuReservedEncoding {db 0dch, 0dch}, { fcomp st4 }
FpuReservedEncoding {db 0dch, 0ddh}, { fcomp st5 }
FpuReservedEncoding {db 0dch, 0deh}, { fcomp st6 }
FpuReservedEncoding {db 0dch, 0dfh}, { fcomp st7 }
; the 0xdd block
FpuReservedEncoding {db 0ddh, 0c8h}, { fxch st0 }
FpuReservedEncoding {db 0ddh, 0c9h}, { fxch st1 }
FpuReservedEncoding {db 0ddh, 0cah}, { fxch st2 }
FpuReservedEncoding {db 0ddh, 0cbh}, { fxch st3 }
FpuReservedEncoding {db 0ddh, 0cch}, { fxch st4 }
FpuReservedEncoding {db 0ddh, 0cdh}, { fxch st5 }
FpuReservedEncoding {db 0ddh, 0ceh}, { fxch st6 }
FpuReservedEncoding {db 0ddh, 0cfh}, { fxch st7 }
ShouldTrap X86_XCPT_UD, db 0ddh, 0f0h
ShouldTrap X86_XCPT_UD, db 0ddh, 0f1h
ShouldTrap X86_XCPT_UD, db 0ddh, 0f2h
ShouldTrap X86_XCPT_UD, db 0ddh, 0f3h
ShouldTrap X86_XCPT_UD, db 0ddh, 0f4h
ShouldTrap X86_XCPT_UD, db 0ddh, 0f5h
ShouldTrap X86_XCPT_UD, db 0ddh, 0f6h
ShouldTrap X86_XCPT_UD, db 0ddh, 0f7h
ShouldTrap X86_XCPT_UD, db 0ddh, 0f8h
ShouldTrap X86_XCPT_UD, db 0ddh, 0f9h
ShouldTrap X86_XCPT_UD, db 0ddh, 0fah
ShouldTrap X86_XCPT_UD, db 0ddh, 0fbh
ShouldTrap X86_XCPT_UD, db 0ddh, 0fch
ShouldTrap X86_XCPT_UD, db 0ddh, 0fdh
ShouldTrap X86_XCPT_UD, db 0ddh, 0feh
ShouldTrap X86_XCPT_UD, db 0ddh, 0ffh
ShouldTrap X86_XCPT_UD, db 0ddh, 028h
ShouldTrap X86_XCPT_UD, db 0ddh, 02fh
; the 0xde block
FpuReservedEncoding {db 0deh, 0d0h}, { fcomp st0 }
FpuReservedEncoding {db 0deh, 0d1h}, { fcomp st1 }
FpuReservedEncoding {db 0deh, 0d2h}, { fcomp st2 }
FpuReservedEncoding {db 0deh, 0d3h}, { fcomp st3 }
FpuReservedEncoding {db 0deh, 0d4h}, { fcomp st4 }
FpuReservedEncoding {db 0deh, 0d5h}, { fcomp st5 }
FpuReservedEncoding {db 0deh, 0d6h}, { fcomp st6 }
FpuReservedEncoding {db 0deh, 0d7h}, { fcomp st7 }
ShouldTrap X86_XCPT_UD, db 0deh, 0d8h
ShouldTrap X86_XCPT_UD, db 0deh, 0dah
ShouldTrap X86_XCPT_UD, db 0deh, 0dbh
ShouldTrap X86_XCPT_UD, db 0deh, 0dch
ShouldTrap X86_XCPT_UD, db 0deh, 0ddh
ShouldTrap X86_XCPT_UD, db 0deh, 0deh
ShouldTrap X86_XCPT_UD, db 0deh, 0dfh
; the 0xdf block
FpuReservedEncoding {db 0dfh, 0c8h}, { fxch st0 }
FpuReservedEncoding {db 0dfh, 0c9h}, { fxch st1 }
FpuReservedEncoding {db 0dfh, 0cah}, { fxch st2 }
FpuReservedEncoding {db 0dfh, 0cbh}, { fxch st3 }
FpuReservedEncoding {db 0dfh, 0cch}, { fxch st4 }
FpuReservedEncoding {db 0dfh, 0cdh}, { fxch st5 }
FpuReservedEncoding {db 0dfh, 0ceh}, { fxch st6 }
FpuReservedEncoding {db 0dfh, 0cfh}, { fxch st7 }
FpuReservedEncoding {db 0dfh, 0d0h}, { fstp st0 }
FpuReservedEncoding {db 0dfh, 0d1h}, { fstp st1 }
FpuReservedEncoding {db 0dfh, 0d2h}, { fstp st2 }
FpuReservedEncoding {db 0dfh, 0d3h}, { fstp st3 }
FpuReservedEncoding {db 0dfh, 0d4h}, { fstp st4 }
FpuReservedEncoding {db 0dfh, 0d5h}, { fstp st5 }
FpuReservedEncoding {db 0dfh, 0d6h}, { fstp st6 }
FpuReservedEncoding {db 0dfh, 0d7h}, { fstp st7 }
FpuReservedEncoding {db 0dfh, 0d8h}, { fstp st0 }
FpuReservedEncoding {db 0dfh, 0d9h}, { fstp st1 }
FpuReservedEncoding {db 0dfh, 0dah}, { fstp st2 }
FpuReservedEncoding {db 0dfh, 0dbh}, { fstp st3 }
FpuReservedEncoding {db 0dfh, 0dch}, { fstp st4 }
FpuReservedEncoding {db 0dfh, 0ddh}, { fstp st5 }
FpuReservedEncoding {db 0dfh, 0deh}, { fstp st6 }
FpuReservedEncoding {db 0dfh, 0dfh}, { fstp st7 }
ShouldTrap X86_XCPT_UD, db 0dfh, 0e1h
ShouldTrap X86_XCPT_UD, db 0dfh, 0e2h
ShouldTrap X86_XCPT_UD, db 0dfh, 0e3h
ShouldTrap X86_XCPT_UD, db 0dfh, 0e4h
ShouldTrap X86_XCPT_UD, db 0dfh, 0e5h
ShouldTrap X86_XCPT_UD, db 0dfh, 0e6h
ShouldTrap X86_XCPT_UD, db 0dfh, 0e7h
ShouldTrap X86_XCPT_UD, db 0dfh, 0f8h
ShouldTrap X86_XCPT_UD, db 0dfh, 0f9h
ShouldTrap X86_XCPT_UD, db 0dfh, 0fah
ShouldTrap X86_XCPT_UD, db 0dfh, 0fbh
ShouldTrap X86_XCPT_UD, db 0dfh, 0fch
ShouldTrap X86_XCPT_UD, db 0dfh, 0fdh
ShouldTrap X86_XCPT_UD, db 0dfh, 0feh
ShouldTrap X86_XCPT_UD, db 0dfh, 0ffh
.success:
xor eax, eax
.return:
SAVE_ALL_EPILOGUE
ret
ENDPROC x861_Test6
;;
; Tests some floating point exceptions and such.
;
;
;
BEGINPROC x861_Test7
SAVE_ALL_PROLOGUE
sub xSP, 2048
; Load some pointers.
lea xSI, [REF(g_r32V1)]
mov xDI, [REF_EXTERN(g_pbEfExecPage)]
add xDI, PAGE_SIZE ; invalid page.
;
; Check denormal numbers.
; Turns out the number is loaded onto the stack even if an exception is triggered.
;
fninit
mov dword [xSP], X86_FCW_PC_64 | X86_FCW_RC_NEAREST
fldcw [xSP]
FpuShouldTrap X86_FSW_DE, 0, fld dword [REF(g_r32D0)]
CheckSt0Value 0x00000000, 0x80000000, 0x3f7f
mov dword [xSP], X86_FCW_PC_64 | X86_FCW_RC_NEAREST | X86_FCW_DM
fldcw [xSP]
fld dword [REF(g_r32D0)]
fwait
FpuCheckFSW X86_FSW_DE, 0
CheckSt0Value 0x00000000, 0x80000000, 0x3f7f
;
; stack overflow
;
fninit
mov dword [xSP], X86_FCW_PC_64 | X86_FCW_RC_NEAREST
fldcw [xSP]
fld qword [REF(g_r64V1)]
fld dword [xSI]
fld dword [xSI]
fld dword [xSI]
fld dword [xSI]
fld dword [xSI]
fld dword [xSI]
fld tword [REF(g_r80V1)]
fwait
FpuShouldTrap X86_FSW_IE | X86_FSW_SF | X86_FSW_C1, X86_FSW_C0 | X86_FSW_C2 | X86_FSW_C3, \
fld dword [xSI]
CheckSt0Value_Eight
FpuShouldTrap X86_FSW_IE | X86_FSW_SF | X86_FSW_C1, X86_FSW_C0 | X86_FSW_C2 | X86_FSW_C3, \
fld dword [xSI]
CheckSt0Value_Eight
; stack overflow vs #PF.
ShouldTrap X86_XCPT_PF, fld dword [xDI]
fwait
; stack overflow vs denormal number
FpuShouldTrap X86_FSW_IE | X86_FSW_SF | X86_FSW_C1, X86_FSW_C0 | X86_FSW_C2 | X86_FSW_C3, \
fld dword [xSI]
CheckSt0Value_Eight
;
; Mask the overflow exception. We should get QNaN now regardless of
; what we try to push (provided the memory is valid).
;
mov dword [xSP], X86_FCW_PC_64 | X86_FCW_RC_NEAREST | X86_FCW_IM
fldcw [xSP]
fld dword [xSI]
FpuCheckFSW X86_FSW_IE | X86_FSW_SF | X86_FSW_C1, X86_FSW_C0 | X86_FSW_C2 | X86_FSW_C3
fnclex
CheckSt0Value 0x00000000, 0xc0000000, 0xffff
fld qword [REF(g_r64V1)]
FpuCheckFSW X86_FSW_IE | X86_FSW_SF | X86_FSW_C1, X86_FSW_C0 | X86_FSW_C2 | X86_FSW_C3
fnclex
CheckSt0Value 0x00000000, 0xc0000000, 0xffff
; This is includes denormal values.
fld dword [REF(g_r32D0)]
fwait
FpuCheckFSW X86_FSW_IE | X86_FSW_SF | X86_FSW_C1, X86_FSW_C0 | X86_FSW_C2 | X86_FSW_C3
CheckSt0Value 0x00000000, 0xc0000000, 0xffff
fnclex
;
; #PF vs previous stack overflow. I.e. whether pending FPU exception
; is checked before fetching memory operands.
;
mov dword [xSP], X86_FCW_PC_64 | X86_FCW_RC_NEAREST
fldcw [xSP]
fld qword [REF(g_r64V1)]
ShouldTrap X86_XCPT_MF, fld dword [xDI]
fnclex
;
; What happens when we unmask an exception and fwait?
;
mov dword [xSP], X86_FCW_PC_64 | X86_FCW_RC_NEAREST | X86_FCW_IM
fldcw [xSP]
fld dword [xSI]
fwait
FpuCheckFSW X86_FSW_IE | X86_FSW_SF | X86_FSW_C1, X86_FSW_C0 | X86_FSW_C2 | X86_FSW_C3
mov dword [xSP], X86_FCW_PC_64 | X86_FCW_RC_NEAREST
fldcw [xSP]
FpuCheckFSW X86_FSW_ES | X86_FSW_B | X86_FSW_IE | X86_FSW_SF | X86_FSW_C1, X86_FSW_C0 | X86_FSW_C2 | X86_FSW_C3
ShouldTrap X86_XCPT_MF, fwait
ShouldTrap X86_XCPT_MF, fwait
ShouldTrap X86_XCPT_MF, fwait
fnclex
.success:
xor eax, eax
.return:
add xSP, 2048
SAVE_ALL_EPILOGUE
ret
ENDPROC x861_Test7
extern NAME(RTTestISub)
;;
; Sets the current subtest.
%macro SetSubTest 1
%ifdef RT_ARCH_AMD64
%ifdef ASM_CALL64_GCC
lea rdi, [%%s_szName wrt rip]
%else
lea rcx, [%%s_szName wrt rip]
%endif
call NAME(RTTestISub)
%else
%ifdef RT_OS_DARWIN
sub esp, 12
push %%s_szName
call NAME(RTTestISub)
add esp, 16
%else
push %%s_szName
call NAME(RTTestISub)
add esp, 4
%endif
%endif
jmp %%done
%%s_szName:
db %1, 0
%%done:
%endmacro
;;
; Checks the opcode and CS:IP FPU.
;
; @returns ZF=1 on success, ZF=0 on failure.
; @param xSP + xCB fxsave image followed by fnstenv.
; @param xCX Opcode address (no prefixes).
;
CheckOpcodeCsIp:
push xBP
mov xBP, xSP
push xAX
; Check the IP.
%ifdef RT_ARCH_AMD64
cmp rcx, [xBP + xCB*2 + X86FXSTATE.FPUIP]
%else
cmp ecx, [xBP + xCB*2 + X86FXSTATE.FPUIP]
%endif
jne .failure1
.check_fpucs:
mov ax, cs
cmp ax, [xBP + xCB*2 + 512 + X86FSTENV32P.FPUCS]
jne .failure2
; Check the opcode. This may be disabled.
mov ah, [xCX]
mov al, [xCX + 1]
and ax, 07ffh
cmp ax, [xBP + xCB*2 + X86FXSTATE.FOP]
je .success
cmp ax, [xBP + xCB*2 + 512 + X86FSTENV32P.FOP]
je .success
; xor ax, ax
; cmp ax, [xBP + xCB*2 + X86FXSTATE.FOP]
; jne .failure3
.success:
xor eax, eax ; clear Z
.return:
pop xAX
leave
ret
.failure1:
; AMD64 doesn't seem to store anything at IP and DP, so use the
; fnstenv image instead even if that only contains the lower 32-bit.
xor eax, eax
cmp xAX, [xBP + xCB*2 + X86FXSTATE.FPUIP]
jne .failure1_for_real
cmp xAX, [xBP + xCB*2 + X86FXSTATE.FPUDP]
jne .failure1_for_real
cmp ecx, [xBP + xCB*2 + 512 + X86FSTENV32P.FPUIP]
je .check_fpucs
.failure1_for_real:
mov eax, 10000000
jmp .failure
.failure2:
mov eax, 20000000
jmp .failure
.failure3:
mov eax, 30000000
jmp .failure
.failure:
or eax, eax
leave
ret
;;
; Checks a FPU instruction, no memory operand.
;
; @uses xCX, xAX, Stack.
;
%macro FpuCheckOpcodeCsIp 1
mov dword [xSP + X86FXSTATE.FPUIP], 0
mov dword [xSP + X86FXSTATE.FPUCS], 0
mov dword [xSP + X86FXSTATE.FPUDP], 0
mov dword [xSP + X86FXSTATE.FPUDS], 0
%%instruction:
%1
arch_fxsave [xSP]
fnstenv [xSP + 512] ; for the selectors (64-bit)
arch_fxrstor [xSP] ; fnstenv screws up the ES bit.
lea xCX, [REF(%%instruction)]
call CheckOpcodeCsIp
jz %%ok
lea xAX, [xAX + __LINE__]
jmp .return
%%ok:
%endmacro
;;
; Checks a trapping FPU instruction, no memory operand.
;
; Upon return, there is are two FXSAVE image on the stack at xSP.
;
; @uses xCX, xAX, Stack.
;
; @param %1 The instruction.
;
%macro FpuTrapOpcodeCsIp 1
mov dword [xSP + 1024 + 512 + X86FXSTATE.FPUIP], 0
mov dword [xSP + 1024 + 512 + X86FXSTATE.FPUCS], 0
mov dword [xSP + 1024 + 512 + X86FXSTATE.FPUDP], 0
mov dword [xSP + 1024 + 512 + X86FXSTATE.FPUDS], 0
mov dword [xSP + X86FXSTATE.FPUIP], 0
mov dword [xSP + X86FXSTATE.FPUCS], 0
mov dword [xSP + X86FXSTATE.FPUDP], 0
mov dword [xSP + X86FXSTATE.FPUDS], 0
%%instruction:
%1
fxsave [xSP + 1024 +512] ; FPUDS and FPUCS for 64-bit hosts.
; WEIRD: When saved after FWAIT they are ZEROed! (64-bit Intel)
arch_fxsave [xSP]
fnstenv [xSP + 512]
arch_fxrstor [xSP]
%%trap:
fwait
%%trap_end:
mov eax, __LINE__
jmp .return
BEGINDATA
%%trapinfo: istruc TRAPINFO
at TRAPINFO.uTrapPC, RTCCPTR_DEF %%trap
at TRAPINFO.uResumePC, RTCCPTR_DEF %%resume
at TRAPINFO.u8TrapNo, db X86_XCPT_MF
at TRAPINFO.cbInstr, db (%%trap_end - %%trap)
iend
BEGINCODE
%%resume:
lea xCX, [REF(%%instruction)]
call CheckOpcodeCsIp
jz %%ok
lea xAX, [xAX + __LINE__]
jmp .return
%%ok:
%endmacro
;;
; Checks the opcode, CS:IP and DS:DP of the FPU.
;
; @returns ZF=1 on success, ZF=0+EAX on failure.
; @param xSP + xCB fxsave image followed by fnstenv.
; @param xCX Opcode address (no prefixes).
; @param xDX Memory address (DS relative).
;
CheckOpcodeCsIpDsDp:
push xBP
mov xBP, xSP
push xAX
; Check the memory operand.
%ifdef RT_ARCH_AMD64
cmp rdx, [xBP + xCB*2 + X86FXSTATE.FPUDP]
%else
cmp edx, [xBP + xCB*2 + X86FXSTATE.FPUDP]
%endif
jne .failure1
.check_fpuds:
mov ax, ds
cmp ax, [xBP + xCB*2 + 512 + X86FSTENV32P.FPUDS]
jne .failure2
.success:
pop xAX
leave
; Let CheckOpcodeCsIp to the rest.
jmp CheckOpcodeCsIp
.failure1:
; AMD may leave all fields as ZERO in the FXSAVE image - figure
; if there is a flag controlling this anywhere...
xor eax, eax
cmp xAX, [xBP + xCB*2 + X86FXSTATE.FPUDP]
jne .failure1_for_real
cmp xAX, [xBP + xCB*2 + X86FXSTATE.FPUIP]
jne .failure1_for_real
cmp edx, [xBP + xCB*2 + 512 + X86FSTENV32P.FPUDP]
je .check_fpuds
.failure1_for_real:
mov eax, 60000000
jmp .failure
.failure2:
mov eax, 80000000
.failure:
or eax, eax
leave
ret
;;
; Checks a FPU instruction taking a memory operand.
;
; @uses xCX, xDX, xAX, Stack.
;
%macro FpuCheckOpcodeCsIpDsDp 2
mov dword [xSP + X86FXSTATE.FPUIP], 0
mov dword [xSP + X86FXSTATE.FPUCS], 0
mov dword [xSP + X86FXSTATE.FPUDP], 0
mov dword [xSP + X86FXSTATE.FPUDS], 0
%%instruction:
%1
arch_fxsave [xSP]
fnstenv [xSP + 512] ; for the selectors (64-bit)
arch_fxrstor [xSP] ; fnstenv screws up the ES bit.
lea xDX, %2
lea xCX, [REF(%%instruction)]
call CheckOpcodeCsIpDsDp
jz %%ok
lea xAX, [xAX + __LINE__]
jmp .return
%%ok:
%endmacro
;;
; Checks a trapping FPU instruction taking a memory operand.
;
; Upon return, there is are two FXSAVE image on the stack at xSP.
;
; @uses xCX, xDX, xAX, Stack.
;
; @param %1 The instruction.
; @param %2 Operand memory address (DS relative).
;
%macro FpuTrapOpcodeCsIpDsDp 2
mov dword [xSP + X86FXSTATE.FPUIP], 0
mov dword [xSP + X86FXSTATE.FPUCS], 0
mov dword [xSP + X86FXSTATE.FPUDP], 0
mov dword [xSP + X86FXSTATE.FPUDS], 0
%%instruction:
%1
fxsave [xSP + 1024 +512] ; FPUDS and FPUCS for 64-bit hosts.
; WEIRD: When saved after FWAIT they are ZEROed! (64-bit Intel)
arch_fxsave [xSP]
fnstenv [xSP + 512]
arch_fxrstor [xSP]
%%trap:
fwait
%%trap_end:
mov eax, __LINE__
jmp .return
BEGINDATA
%%trapinfo: istruc TRAPINFO
at TRAPINFO.uTrapPC, RTCCPTR_DEF %%trap
at TRAPINFO.uResumePC, RTCCPTR_DEF %%resume
at TRAPINFO.u8TrapNo, db X86_XCPT_MF
at TRAPINFO.cbInstr, db (%%trap_end - %%trap)
iend
BEGINCODE
%%resume:
lea xDX, %2
lea xCX, [REF(%%instruction)]
call CheckOpcodeCsIpDsDp
jz %%ok
lea xAX, [xAX + __LINE__]
jmp .return
%%ok:
%endmacro
;;
; Checks that the FPU and GReg state is completely unchanged after an instruction
; resulting in a CPU trap.
;
; @param 1 The trap number.
; @param 2+ The instruction which should trap.
;
%macro FpuCheckCpuTrapUnchangedState 2+
call SaveFPUAndGRegsToStack
ShouldTrap %1, %2
call CompareFPUAndGRegsOnStack
jz %%ok
lea xAX, [xAX + __LINE__]
jmp .return
%%ok:
%endmacro
;;
; Initialize the FPU and set CW to %1.
;
; @uses dword at [xSP].
;
%macro FpuInitWithCW 1
call x861_LoadUniqueRegValuesSSE
fninit
mov dword [xSP], %1
fldcw [xSP]
%endmacro
;;
; First bunch of FPU instruction tests.
;
;
BEGINPROC x861_TestFPUInstr1
SAVE_ALL_PROLOGUE
sub xSP, 2048
%if 0
;
; FDIV with 64-bit floating point memory operand.
;
SetSubTest "FDIV m64r"
; ## Normal operation. ##
fninit
FpuCheckOpcodeCsIpDsDp { fld dword [REF(g_r32_3dot2)] }, [REF(g_r32_3dot2)]
CheckSt0Value 0x00000000, 0xcccccd00, 0x4000
FpuCheckOpcodeCsIpDsDp { fdiv qword [REF(g_r64_One)] }, [REF(g_r64_One)]
FpuCheckFSW 0, X86_FSW_C0 | X86_FSW_C2 | X86_FSW_C3
CheckSt0Value 0x00000000, 0xcccccd00, 0x4000
; ## Masked exceptions. ##
; Masked stack underflow.
fninit
FpuCheckOpcodeCsIpDsDp { fdiv qword [REF(g_r64_One)] }, [REF(g_r64_One)]
FpuCheckFSW X86_FSW_IE | X86_FSW_SF, X86_FSW_C0 | X86_FSW_C2 | X86_FSW_C3
CheckSt0Value_QNaN
; Masked zero divide.
fninit
FpuCheckOpcodeCsIpDsDp { fld dword [REF(g_r32_3dot2)] }, [REF(g_r32_3dot2)]
FpuCheckOpcodeCsIpDsDp { fdiv qword [REF(g_r64_Zero)] }, [REF(g_r64_Zero)]
FpuCheckFSW X86_FSW_ZE, X86_FSW_C0 | X86_FSW_C2 | X86_FSW_C3
CheckSt0Value_PlusInf
; Masked Inf/Inf.
fninit
FpuCheckOpcodeCsIpDsDp { fld dword [REF(g_r32_Inf)] }, [REF(g_r32_Inf)]
FpuCheckOpcodeCsIpDsDp { fdiv qword [REF(g_r64_Inf)] }, [REF(g_r64_Inf)]
FpuCheckFSW X86_FSW_IE, X86_FSW_C0 | X86_FSW_C2 | X86_FSW_C3
CheckSt0Value_QNaN
; Masked 0/0.
fninit
FpuCheckOpcodeCsIpDsDp { fld dword [REF(g_r32_Zero)] }, [REF(g_r32_Zero)]
FpuCheckOpcodeCsIpDsDp { fdiv qword [REF(g_r64_Zero)] }, [REF(g_r64_Zero)]
FpuCheckFSW X86_FSW_IE, X86_FSW_C0 | X86_FSW_C2 | X86_FSW_C3
CheckSt0Value_QNaN
; Masked precision exception, rounded down.
fninit
FpuCheckOpcodeCsIpDsDp { fld dword [REF(g_r32_Ten)] }, [REF(g_r32_Ten)]
FpuCheckOpcodeCsIpDsDp { fdiv qword [REF(g_r64_Three)] }, [REF(g_r64_Three)]
FpuCheckFSW X86_FSW_PE, X86_FSW_C0 | X86_FSW_C2 | X86_FSW_C3
CheckSt0Value_3_and_a_3rd
; Masked precision exception, rounded up.
fninit
FpuCheckOpcodeCsIpDsDp { fld dword [REF(g_r32_Eleven)] }, [REF(g_r32_Eleven)]
FpuCheckOpcodeCsIpDsDp { fdiv qword [REF(g_r64_Three)] }, [REF(g_r64_Three)]
FpuCheckFSW X86_FSW_PE | X86_FSW_C1, X86_FSW_C0 | X86_FSW_C2 | X86_FSW_C3
CheckSt0Value_3_and_two_3rds
; Masked overflow exception.
fninit
FpuCheckOpcodeCsIpDsDp { fld tword [REF(g_r80_Max)] }, [REF(g_r80_Max)]
FpuCheckOpcodeCsIpDsDp { fdiv qword [REF(g_r64_0dot1)] }, [REF(g_r64_0dot1)]
FpuCheckFSW X86_FSW_PE | X86_FSW_OE | X86_FSW_C1, X86_FSW_C0 | X86_FSW_C2 | X86_FSW_C3
CheckSt0Value_PlusInf
; Masked underflow exception.
fninit
FpuCheckOpcodeCsIpDsDp { fld tword [REF(g_r80_Min)] }, [REF(g_r80_Min)]
FpuCheckOpcodeCsIpDsDp { fdiv qword [REF(g_r64_Ten)] }, [REF(g_r64_Ten)]
FpuCheckFSW X86_FSW_PE | X86_FSW_UE | X86_FSW_C1, X86_FSW_C0 | X86_FSW_C2 | X86_FSW_C3
CheckSt0Value 0xcccccccd, 0x0ccccccc, 0x0000
; Denormal operand.
fninit
FpuCheckOpcodeCsIpDsDp { fld tword [REF(g_r80_One)] }, [REF(g_r80_One)]
FpuCheckOpcodeCsIpDsDp { fdiv qword [REF(g_r64_DnMax)] }, [REF(g_r64_DnMax)]
FxSaveCheckFSW xSP, X86_FSW_DE | X86_FSW_PE, X86_FSW_C0 | X86_FSW_C2 | X86_FSW_C3
FxSaveCheckSt0Value xSP, 0x00000800, 0x80000000, 0x43fd
; ## Unmasked exceptions. ##
; Stack underflow - TOP and ST0 unmodified.
FpuInitWithCW X86_FCW_PC_64 | X86_FCW_RC_NEAREST
FpuTrapOpcodeCsIpDsDp { fdiv qword [REF(g_r64_One)] }, [REF(g_r64_One)]
FxSaveCheckFSW xSP, X86_FSW_IE | X86_FSW_SF | X86_FSW_B | X86_FSW_ES, X86_FSW_C0 | X86_FSW_C2 | X86_FSW_C3
FxSaveCheckSt0EmptyInitValue xSP
; Zero divide - Unmodified ST0.
FpuInitWithCW X86_FCW_PC_64 | X86_FCW_RC_NEAREST
FpuCheckOpcodeCsIpDsDp { fld dword [REF(g_r32_3dot2)] }, [REF(g_r32_3dot2)]
FpuTrapOpcodeCsIpDsDp { fdiv qword [REF(g_r64_Zero)] }, [REF(g_r64_Zero)]
FxSaveCheckFSW xSP, X86_FSW_ZE | X86_FSW_ES | X86_FSW_B, X86_FSW_C0 | X86_FSW_C2 | X86_FSW_C3
FxSaveCheckSt0ValueConst xSP, REF(g_r80_r32_3dot2)
; Invalid Operand (Inf/Inf) - Unmodified ST0.
FpuInitWithCW X86_FCW_PC_64 | X86_FCW_RC_NEAREST
FpuCheckOpcodeCsIpDsDp { fld dword [REF(g_r32_Inf)] }, [REF(g_r32_Inf)]
FpuTrapOpcodeCsIpDsDp { fdiv qword [REF(g_r64_Inf)] }, [REF(g_r64_Inf)]
FpuCheckFSW X86_FSW_IE | X86_FSW_ES | X86_FSW_B, X86_FSW_C0 | X86_FSW_C2 | X86_FSW_C3
FxSaveCheckSt0ValueConst xSP, REF(g_r80_Inf)
; Invalid Operand (0/0) - Unmodified ST0.
FpuInitWithCW X86_FCW_PC_64 | X86_FCW_RC_NEAREST
FpuCheckOpcodeCsIpDsDp { fld dword [REF(g_r32_Zero)] }, [REF(g_r32_Zero)]
FpuTrapOpcodeCsIpDsDp { fdiv qword [REF(g_r64_Zero)] }, [REF(g_r64_Zero)]
FxSaveCheckFSW xSP, X86_FSW_IE | X86_FSW_ES | X86_FSW_B, X86_FSW_C0 | X86_FSW_C2 | X86_FSW_C3
FxSaveCheckSt0ValueConst xSP, REF(g_r80_Zero)
; Precision exception, rounded down.
FpuInitWithCW X86_FCW_PC_64 | X86_FCW_RC_NEAREST
FpuCheckOpcodeCsIpDsDp { fld dword [REF(g_r32_Ten)] }, [REF(g_r32_Ten)]
FpuTrapOpcodeCsIpDsDp { fdiv qword [REF(g_r64_Three)] }, [REF(g_r64_Three)]
FxSaveCheckFSW xSP, X86_FSW_PE | X86_FSW_ES | X86_FSW_B, X86_FSW_C0 | X86_FSW_C2 | X86_FSW_C3
FxSaveCheckSt0Value_3_and_a_3rd(xSP)
; Precision exception, rounded up.
FpuInitWithCW X86_FCW_PC_64 | X86_FCW_RC_NEAREST
FpuCheckOpcodeCsIpDsDp { fld dword [REF(g_r32_Eleven)] }, [REF(g_r32_Eleven)]
FpuTrapOpcodeCsIpDsDp { fdiv qword [REF(g_r64_Three)] }, [REF(g_r64_Three)]
FxSaveCheckFSW xSP, X86_FSW_PE | X86_FSW_C1 | X86_FSW_ES | X86_FSW_B, X86_FSW_C0 | X86_FSW_C2 | X86_FSW_C3
FxSaveCheckSt0Value_3_and_two_3rds(xSP)
; Overflow exception.
FpuInitWithCW X86_FCW_PC_64 | X86_FCW_RC_NEAREST
FpuCheckOpcodeCsIpDsDp { fld tword [REF(g_r80_Max)] }, [REF(g_r80_Max)]
FpuTrapOpcodeCsIpDsDp { fdiv qword [REF(g_r64_0dot1)] }, [REF(g_r64_0dot1)]
FxSaveCheckFSW xSP, X86_FSW_PE | X86_FSW_OE | X86_FSW_ES | X86_FSW_B, X86_FSW_C0 | X86_FSW_C2 | X86_FSW_C3
FxSaveCheckSt0Value xSP, 0xfffffd7f, 0x9fffffff, 0x2002
; Underflow exception.
FpuInitWithCW X86_FCW_PC_64 | X86_FCW_RC_NEAREST
FpuCheckOpcodeCsIpDsDp { fld tword [REF(g_r80_Min)] }, [REF(g_r80_Min)]
FpuTrapOpcodeCsIpDsDp { fdiv qword [REF(g_r64_Ten)] }, [REF(g_r64_Ten)]
FxSaveCheckFSW xSP, X86_FSW_PE | X86_FSW_UE | X86_FSW_C1 | X86_FSW_ES | X86_FSW_B, X86_FSW_C0 | X86_FSW_C2 | X86_FSW_C3
FxSaveCheckSt0Value xSP, 0xcccccccd, 0xcccccccc, 0x5ffd
; Denormal operand - Unmodified ST0.
FpuInitWithCW X86_FCW_PC_64 | X86_FCW_RC_NEAREST
FpuCheckOpcodeCsIpDsDp { fld tword [REF(g_r80_One)] }, [REF(g_r80_One)]
FpuTrapOpcodeCsIpDsDp { fdiv qword [REF(g_r64_DnMax)] }, [REF(g_r64_DnMax)]
FxSaveCheckFSW xSP, X86_FSW_DE | X86_FSW_ES | X86_FSW_B, X86_FSW_C0 | X86_FSW_C2 | X86_FSW_C3
FxSaveCheckSt0ValueConst xSP, REF(g_r80_One)
;;; @todo exception priority checks.
; ## A couple of variations on the #PF theme. ##
FpuInitWithCW X86_FCW_PC_64 | X86_FCW_RC_NEAREST
mov xBX, [REF_EXTERN(g_pbEfExecPage)]
FpuCheckCpuTrapUnchangedState X86_XCPT_PF, fdiv qword [xBX + PAGE_SIZE]
; Check that a pending FPU exception takes precedence over a #PF.
fninit
fdiv qword [REF(g_r64_One)]
fstcw [xSP]
and word [xSP], ~(X86_FCW_IM)
fldcw [xSP]
mov xBX, [REF_EXTERN(g_pbEfExecPage)]
ShouldTrap X86_XCPT_MF, fdiv qword [xBX + PAGE_SIZE]
;
; FSUBRP STn, ST0
;
SetSubTest "FSUBRP STn, ST0"
; ## Normal operation. ##
fninit
FpuCheckOpcodeCsIpDsDp { fld dword [REF(g_r32_3dot2)] }, [REF(g_r32_3dot2)]
FpuCheckOpcodeCsIpDsDp { fld dword [REF(g_r32_3dot2)] }, [REF(g_r32_3dot2)]
FpuCheckOpcodeCsIp { fsubrp st1, st0 }
FxSaveCheckFSW xSP, 0, 0
FxSaveCheckSt0ValueConst xSP, REF(g_r80_Zero)
; ## Masked exceptions. ##
; Masked stack underflow, both operands.
fninit
FpuCheckOpcodeCsIp { fsubrp st1, st0 }
FxSaveCheckFSW xSP, X86_FSW_IE | X86_FSW_SF, X86_FSW_C0 | X86_FSW_C2 | X86_FSW_C3
FxSaveCheckSt0Value_QNaN(xSP)
; Masked stack underflow, one operand.
fninit
FpuCheckOpcodeCsIpDsDp { fld dword [REF(g_r32_3dot2)] }, [REF(g_r32_3dot2)]
FpuCheckOpcodeCsIp { fsubrp st1, st0 }
FxSaveCheckFSW xSP, X86_FSW_IE | X86_FSW_SF, X86_FSW_C0 | X86_FSW_C2 | X86_FSW_C3
FxSaveCheckSt0Value_QNaN(xSP)
; Denormal operand.
fninit
fld tword [REF(g_r80_DnMax)]
fld tword [REF(g_r80_DnMin)]
FpuCheckOpcodeCsIp { fsubrp st1, st0 }
FxSaveCheckFSW xSP, X86_FSW_DE, X86_FSW_C0 | X86_FSW_C2 | X86_FSW_C3
FxSaveCheckSt0Value xSP, 0xfffffffe, 0x7fffffff, 0x8000
; ## Unmasked exceptions. ##
; Stack underflow, both operands - no pop or change.
FpuInitWithCW X86_FCW_PC_64 | X86_FCW_RC_NEAREST
FpuTrapOpcodeCsIp { fsubrp st1, st0 }
FxSaveCheckFSW xSP, X86_FSW_IE | X86_FSW_SF | X86_FSW_ES | X86_FSW_B, X86_FSW_C0 | X86_FSW_C2 | X86_FSW_C3
FxSaveCheckSt0EmptyInitValue xSP
; Stack underflow, one operand - no pop or change.
FpuInitWithCW X86_FCW_PC_64 | X86_FCW_RC_NEAREST
FpuCheckOpcodeCsIpDsDp { fld dword [REF(g_r32_3dot2)] }, [REF(g_r32_3dot2)]
FpuTrapOpcodeCsIp { fsubrp st1, st0 }
FxSaveCheckFSW xSP, X86_FSW_IE | X86_FSW_SF | X86_FSW_ES | X86_FSW_B, X86_FSW_C0 | X86_FSW_C2 | X86_FSW_C3
FxSaveCheckSt0ValueConst xSP, REF(g_r80_r32_3dot2)
; Denormal operand - no pop.
fninit
fld tword [REF(g_r80_DnMax)]
fld tword [REF(g_r80_DnMin)]
fnclex
mov dword [xSP], X86_FCW_PC_64 | X86_FCW_RC_NEAREST
fldcw [xSP]
FpuTrapOpcodeCsIp { fsubrp st1, st0 }
FxSaveCheckFSW xSP, X86_FSW_DE | X86_FSW_ES | X86_FSW_B, X86_FSW_C0 | X86_FSW_C2 | X86_FSW_C3
FxSaveCheckStNValueConst xSP, 1, REF(g_r80_DnMax)
FxSaveCheckStNValueConst xSP, 0, REF(g_r80_DnMin)
;
; FSTP ST0, STn
;
SetSubTest "FSTP ST0, STn"
; ## Normal operation. ##
FpuInitWithCW X86_FCW_PC_64 | X86_FCW_RC_NEAREST
fld tword [REF(g_r80_0dot1)]
fld tword [REF(g_r80_3dot2)]
FpuCheckOpcodeCsIp { fstp st2 }
FxSaveCheckFSW xSP, 0, 0
FxSaveCheckStNValueConst xSP, 0, REF(g_r80_0dot1)
FxSaveCheckStNValueConst xSP, 1, REF(g_r80_3dot2)
FpuInitWithCW X86_FCW_PC_64 | X86_FCW_RC_NEAREST
fld tword [REF(g_r80_Max)]
fld tword [REF(g_r80_Inf)]
FpuCheckOpcodeCsIp { fstp st3 }
FxSaveCheckFSW xSP, 0, 0
FxSaveCheckStNValueConst xSP, 0, REF(g_r80_Max)
FxSaveCheckStNValueConst xSP, 2, REF(g_r80_Inf)
; Denormal register values doesn't matter get reasserted.
fninit
fld tword [REF(g_r80_DnMin)]
fld tword [REF(g_r80_DnMax)]
fnclex
mov dword [xSP], X86_FCW_PC_64 | X86_FCW_RC_NEAREST
fldcw [xSP]
FpuCheckOpcodeCsIp { fstp st2 }
FxSaveCheckFSW xSP, 0, 0
FxSaveCheckStNValueConst xSP, 0, REF(g_r80_DnMin)
FxSaveCheckStNValueConst xSP, 1, REF(g_r80_DnMax)
; Signaled NaN doesn't matter.
FpuInitWithCW X86_FCW_PC_64 | X86_FCW_RC_NEAREST
fld tword [REF(g_r80_SNaN)]
fld tword [REF(g_r80_SNaN)]
fnclex
FpuCheckOpcodeCsIp { fstp st3 }
FxSaveCheckFSW xSP, 0, 0
FxSaveCheckStNValueConst xSP, 0, REF(g_r80_SNaN)
FxSaveCheckStNValueConst xSP, 2, REF(g_r80_SNaN)
; Quiet NaN doesn't matter either
FpuInitWithCW X86_FCW_PC_64 | X86_FCW_RC_NEAREST
fld tword [REF(g_r80_QNaN)]
fld tword [REF(g_r80_QNaN)]
fnclex
FpuCheckOpcodeCsIp { fstp st4 }
FxSaveCheckFSW xSP, 0, 0
FxSaveCheckStNValueConst xSP, 0, REF(g_r80_QNaN)
FxSaveCheckStNValueConst xSP, 3, REF(g_r80_QNaN)
; There is no overflow signalled.
FpuInitWithCW X86_FCW_PC_64 | X86_FCW_RC_NEAREST
fld tword [REF(g_r80_SNaNMax)]
fld tword [REF(g_r80_SNaNMax)]
fnclex
FpuCheckOpcodeCsIp { fstp st1 }
FxSaveCheckFSW xSP, 0, 0
FxSaveCheckStNValueConst xSP, 0, REF(g_r80_SNaNMax)
; ## Masked exceptions. ##
; Masked stack underflow.
fninit
FpuCheckOpcodeCsIp { fstp st1 }
FxSaveCheckFSW xSP, X86_FSW_IE | X86_FSW_SF, X86_FSW_C0 | X86_FSW_C2 | X86_FSW_C3
FxSaveCheckSt0Value_QNaN(xSP)
fninit
FpuCheckOpcodeCsIp { fstp st0 }
FxSaveCheckFSW xSP, X86_FSW_IE | X86_FSW_SF, X86_FSW_C0 | X86_FSW_C2 | X86_FSW_C3
FxSaveCheckSt0Empty xSP
; ## Unmasked exceptions. ##
; Stack underflow - no pop or change.
FpuInitWithCW X86_FCW_PC_64 | X86_FCW_RC_NEAREST
fld tword [REF(g_r80_0dot1)]
fld tword [REF(g_r80_3dot2)]
fld tword [REF(g_r80_Ten)]
ffree st0
FpuTrapOpcodeCsIp { fstp st1 }
FxSaveCheckFSW xSP, X86_FSW_IE | X86_FSW_SF | X86_FSW_ES | X86_FSW_B, X86_FSW_C0 | X86_FSW_C2 | X86_FSW_C3
FxSaveCheckSt0Empty xSP
FxSaveCheckStNValueConst xSP, 1, REF(g_r80_3dot2)
FxSaveCheckStNValueConst xSP, 2, REF(g_r80_0dot1)
%endif
;
; FSTP M32R, ST0
;
SetSubTest "FSTP M32R, ST0"
mov xBX, [REF_EXTERN(g_pbEfExecPage)]
lea xBX, [xBX + PAGE_SIZE - 4]
; ## Normal operation. ##
FpuInitWithCW X86_FCW_PC_64 | X86_FCW_RC_NEAREST
fld dword [REF(g_r32_Ten)]
FpuCheckOpcodeCsIp { fstp dword [xBX] }
FxSaveCheckFSW xSP, 0, 0
FxSaveCheckSt0Empty xSP
CheckMemoryR32ValueConst xBX, REF(g_r32_Ten)
; ## Masked exceptions. ##
; Masked stack underflow.
fninit
FpuCheckOpcodeCsIp { fstp dword [xBX] }
FxSaveCheckFSW xSP, X86_FSW_IE | X86_FSW_SF, X86_FSW_C0 | X86_FSW_C2 | X86_FSW_C3
CheckMemoryR32ValueConst xBX, REF(g_r32_NegQNaN)
fninit
fld tword [REF(g_r80_0dot1)]
fld tword [REF(g_r80_3dot2)]
fld tword [REF(g_r80_Ten)]
ffree st0
FpuCheckOpcodeCsIp { fstp dword [xBX] }
FxSaveCheckFSW xSP, X86_FSW_IE | X86_FSW_SF, X86_FSW_C0 | X86_FSW_C2 | X86_FSW_C3
CheckMemoryR32ValueConst xBX, REF(g_r32_NegQNaN)
FxSaveCheckStNValueConst xSP, 0, REF(g_r80_3dot2)
FxSaveCheckStNValueConst xSP, 1, REF(g_r80_0dot1)
; Masked #IA caused by SNaN.
fninit
fld tword [REF(g_r80_SNaN)]
FpuCheckOpcodeCsIp { fstp dword [xBX] }
FxSaveCheckFSW xSP, X86_FSW_IE, X86_FSW_C0 | X86_FSW_C2 | X86_FSW_C3
CheckMemoryR32ValueConst xBX, REF(g_r32_QNaN)
; Masked #U caused by a denormal value.
fninit
fld tword [REF(g_r80_DnMin)]
FpuCheckOpcodeCsIp { fstp dword [xBX] }
FxSaveCheckFSW xSP, X86_FSW_UE | X86_FSW_PE, X86_FSW_C0 | X86_FSW_C2 | X86_FSW_C3
CheckMemoryR32ValueConst xBX, REF(g_r32_Zero)
; Masked #P caused by a decimal value.
fninit
fld tword [REF(g_r80_3dot2)]
FpuCheckOpcodeCsIp { fstp dword [xBX] }
FxSaveCheckFSW xSP, X86_FSW_C1 | X86_FSW_PE, X86_FSW_C0 | X86_FSW_C2 | X86_FSW_C3
CheckMemoryR32ValueConst xBX, REF(g_r32_3dot2)
; ## Unmasked exceptions. ##
; Stack underflow - nothing stored or popped.
FpuInitWithCW X86_FCW_PC_64 | X86_FCW_RC_NEAREST
mov dword [xBX], 0xffeeddcc
FpuTrapOpcodeCsIp { fstp dword [xBX] }
FxSaveCheckFSW xSP, X86_FSW_IE | X86_FSW_SF | X86_FSW_ES | X86_FSW_B, X86_FSW_C0 | X86_FSW_C2 | X86_FSW_C3
CheckMemoryValue dword, xBX, 0xffeeddcc
FpuInitWithCW X86_FCW_PC_64 | X86_FCW_RC_NEAREST
fld tword [REF(g_r80_0dot1)]
fld tword [REF(g_r80_3dot2)]
fld tword [REF(g_r80_Ten)]
ffree st0
mov dword [xBX], 0xffeeddcc
FpuTrapOpcodeCsIp { fstp dword [xBX] }
FxSaveCheckFSW xSP, X86_FSW_IE | X86_FSW_SF | X86_FSW_ES | X86_FSW_B, X86_FSW_C0 | X86_FSW_C2 | X86_FSW_C3
CheckMemoryValue dword, xBX, 0xffeeddcc
FxSaveCheckStNEmpty xSP, 0
FxSaveCheckStNValueConst xSP, 1, REF(g_r80_3dot2)
FxSaveCheckStNValueConst xSP, 2, REF(g_r80_0dot1)
; #IA caused by SNaN.
FpuInitWithCW X86_FCW_PC_64 | X86_FCW_RC_NEAREST
fld tword [REF(g_r80_SNaN)]
mov dword [xBX], 0xffeeddcc
FpuTrapOpcodeCsIp { fstp dword [xBX] }
FxSaveCheckFSW xSP, X86_FSW_IE | X86_FSW_ES | X86_FSW_B, X86_FSW_C0 | X86_FSW_C2 | X86_FSW_C3
CheckMemoryValue dword, xBX, 0xffeeddcc
; #U caused by a denormal value - nothing written
FpuInitWithCW X86_FCW_PC_64 | X86_FCW_RC_NEAREST
fld tword [REF(g_r80_DnMin)]
mov dword [xBX], 0xffeeddcc
FpuTrapOpcodeCsIp { fstp dword [xBX] }
FxSaveCheckFSW xSP, X86_FSW_UE | X86_FSW_ES | X86_FSW_B, X86_FSW_C0 | X86_FSW_C2 | X86_FSW_C3
CheckMemoryValue dword, xBX, 0xffeeddcc
; #U caused by a small value - nothing written
FpuInitWithCW X86_FCW_PC_64 | X86_FCW_RC_NEAREST
fld tword [REF(g_r80_Min)]
mov dword [xBX], 0xffeeddcc
FpuTrapOpcodeCsIp { fstp dword [xBX] }
FxSaveCheckFSW xSP, X86_FSW_UE | X86_FSW_ES | X86_FSW_B, X86_FSW_C0 | X86_FSW_C2 | X86_FSW_C3
CheckMemoryValue dword, xBX, 0xffeeddcc
; #O caused by a small value - nothing written
FpuInitWithCW X86_FCW_PC_64 | X86_FCW_RC_NEAREST
fld tword [REF(g_r80_Max)]
mov dword [xBX], 0xffeeddcc
FpuTrapOpcodeCsIp { fstp dword [xBX] }
FxSaveCheckFSW xSP, X86_FSW_OE | X86_FSW_ES | X86_FSW_B, X86_FSW_C0 | X86_FSW_C2 | X86_FSW_C3
CheckMemoryValue dword, xBX, 0xffeeddcc
; #P caused by a decimal value - rounded value is written just like if it was masked.
FpuInitWithCW X86_FCW_PC_64 | X86_FCW_RC_NEAREST
fld tword [REF(g_r80_3dot2)]
mov dword [xBX], 0xffeeddcc
FpuTrapOpcodeCsIp { fstp dword [xBX] }
FxSaveCheckFSW xSP, X86_FSW_C1 | X86_FSW_PE | X86_FSW_ES | X86_FSW_B, X86_FSW_C0 | X86_FSW_C2 | X86_FSW_C3
CheckMemoryR32ValueConst xBX, REF(g_r32_3dot2)
%if 0 ;; @todo implement me
;
; FISTP M32I, ST0
;
SetSubTest "FISTP M32I, ST0"
mov xBX, [REF_EXTERN(g_pbEfExecPage)]
lea xBX, [xBX + PAGE_SIZE - 4]
; ## Normal operation. ##
FpuInitWithCW X86_FCW_PC_64 | X86_FCW_RC_NEAREST
fld tword [REF(g_r80_Ten)]
FpuCheckOpcodeCsIp { fistp dword [xBX] }
FxSaveCheckFSW xSP, 0, 0
FxSaveCheckSt0Empty xSP
CheckMemoryValue dword, xBX, 10
; ## Masked exceptions. ##
; Masked stack underflow.
fninit
FpuCheckOpcodeCsIp { fistp dword [xBX] }
FxSaveCheckFSW xSP, X86_FSW_IE | X86_FSW_SF, X86_FSW_C0 | X86_FSW_C2 | X86_FSW_C3
CheckMemoryValue dword, xBX, 0x80000000
fninit
fld tword [REF(g_r80_0dot1)]
fld tword [REF(g_r80_3dot2)]
fld tword [REF(g_r80_Ten)]
ffree st0
FpuCheckOpcodeCsIp { fistp dword [xBX] }
FxSaveCheckFSW xSP, X86_FSW_IE | X86_FSW_SF, X86_FSW_C0 | X86_FSW_C2 | X86_FSW_C3
CheckMemoryValue dword, xBX, 0x80000000
FxSaveCheckStNValueConst xSP, 0, REF(g_r80_3dot2)
FxSaveCheckStNValueConst xSP, 1, REF(g_r80_0dot1)
; ## Unmasked exceptions. ##
; Stack underflow - no pop or change.
FpuInitWithCW X86_FCW_PC_64 | X86_FCW_RC_NEAREST
fld tword [REF(g_r80_0dot1)]
fld tword [REF(g_r80_3dot2)]
fld tword [REF(g_r80_Ten)]
ffree st0
mov dword [xBX], 0xffeeddcc
FpuTrapOpcodeCsIp { fistp dword [xBX] }
FxSaveCheckFSW xSP, X86_FSW_IE | X86_FSW_SF | X86_FSW_ES | X86_FSW_B, X86_FSW_C0 | X86_FSW_C2 | X86_FSW_C3
FxSaveCheckSt0Empty xSP
CheckMemoryValue dword, xBX, 0xffeeddcc
FxSaveCheckStNValueConst xSP, 1, REF(g_r80_3dot2)
FxSaveCheckStNValueConst xSP, 2, REF(g_r80_0dot1)
%endif
%if 0
;
; FPTAN - calc, store ST0, push 1.0.
;
SetSubTest "FPTAN"
; ## Normal operation. ##
fninit
fldpi
FpuCheckOpcodeCsIp { fptan }
FxSaveCheckStNValueConst xSP, 0, REF(g_r80_One)
FxSaveCheckStNValue xSP, 1, 0x00000000, 0x80000000, 0x3fbf ; should be zero, so, this might fail due to precision later.
; Masked stack underflow - two QNaNs.
fninit
FpuCheckOpcodeCsIp { fptan }
FxSaveCheckStNValueConst xSP, 0, REF(g_r80_NegQNaN)
FxSaveCheckStNValueConst xSP, 1, REF(g_r80_NegQNaN)
; Masked stack overflow - two QNaNs
fninit
fldpi
fldpi
fldpi
fldpi
fldpi
fldpi
fldpi
fldpi
FpuCheckOpcodeCsIp { fptan }
FxSaveCheckStNValueConst xSP, 0, REF(g_r80_NegQNaN)
FxSaveCheckStNValueConst xSP, 1, REF(g_r80_NegQNaN)
;; @todo Finish FPTAN testcase.
;
; FCMOVB - move if CF=1.
;
SetSubTest "FCMOVB ST0,STn"
; ## Normal operation. ##
fninit
fldz
fldpi
call SetFSW_C0_thru_C3
stc
FpuCheckOpcodeCsIp { fcmovb st0,st1 }
FxSaveCheckFSW xSP, X86_FSW_C0 | X86_FSW_C1 | X86_FSW_C2 | X86_FSW_C3, 0 ; seems to be preserved...
FxSaveCheckStNValueConst xSP, 0, REF(g_r80_Zero)
FxSaveCheckStNValueConst xSP, 1, REF(g_r80_Zero)
fninit
fldz
fld1
call SetFSW_C0_thru_C3
clc
FpuCheckOpcodeCsIp { fcmovb st0,st1 }
FxSaveCheckFSW xSP, X86_FSW_C0 | X86_FSW_C1 | X86_FSW_C2 | X86_FSW_C3, 0 ; seems to be preserved...
FxSaveCheckStNValueConst xSP, 0, REF(g_r80_One)
FxSaveCheckStNValueConst xSP, 1, REF(g_r80_Zero)
; ## Masked exceptions. ##
; Masked stack underflow - both.
; Note! #IE triggers regardless of the test result!
fninit
stc
FpuCheckOpcodeCsIp { fcmovb st0,st1 }
FxSaveCheckFSW xSP, X86_FSW_IE | X86_FSW_SF, X86_FSW_C0 | X86_FSW_C2 | X86_FSW_C3
FxSaveCheckStNValue_QNaN(xSP, 0)
FxSaveCheckStNEmpty xSP, 1
fninit
clc
FpuCheckOpcodeCsIp { fcmovb st0,st1 }
FxSaveCheckFSW xSP, X86_FSW_IE | X86_FSW_SF, X86_FSW_C0 | X86_FSW_C2 | X86_FSW_C3
FxSaveCheckStNValue_QNaN(xSP, 0)
FxSaveCheckStNEmpty xSP, 1
; Masked stack underflow - source.
fninit
fldz
stc
FpuCheckOpcodeCsIp { fcmovb st0,st1 }
FxSaveCheckFSW xSP, X86_FSW_IE | X86_FSW_SF, X86_FSW_C0 | X86_FSW_C2 | X86_FSW_C3
FxSaveCheckStNValue_QNaN(xSP, 0)
FxSaveCheckStNEmpty xSP, 1
fninit
fldz
stc
FpuCheckOpcodeCsIp { fcmovb st0,st1 }
FxSaveCheckFSW xSP, X86_FSW_IE | X86_FSW_SF, X86_FSW_C0 | X86_FSW_C2 | X86_FSW_C3
FxSaveCheckStNValue_QNaN(xSP, 0)
FxSaveCheckStNEmpty xSP, 1
; Masked stack underflow - destination.
fninit
fldz
fldpi
ffree st0
stc
FpuCheckOpcodeCsIp { fcmovb st0,st1 }
FxSaveCheckFSW xSP, X86_FSW_IE | X86_FSW_SF, X86_FSW_C0 | X86_FSW_C2 | X86_FSW_C3
FxSaveCheckStNValue_QNaN(xSP, 0)
FxSaveCheckStNValueConst xSP, 1, REF(g_r80_Zero)
fninit
fldz
fldpi
ffree st0
clc
FpuCheckOpcodeCsIp { fcmovb st0,st1 }
FxSaveCheckFSW xSP, X86_FSW_IE | X86_FSW_SF, X86_FSW_C0 | X86_FSW_C2 | X86_FSW_C3
FxSaveCheckStNValue_QNaN(xSP, 0)
FxSaveCheckStNValueConst xSP, 1, REF(g_r80_Zero)
;; @todo Finish FCMOVB testcase.
%endif
.success:
xor eax, eax
.return:
add xSP, 2048
SAVE_ALL_EPILOGUE
ret
ENDPROC x861_TestFPUInstr1
;;
; Terminate the trap info array with a NIL entry.
BEGINDATA
GLOBALNAME g_aTrapInfoExecPage
istruc TRAPINFO
at TRAPINFO.uTrapPC, RTCCPTR_DEF 1
at TRAPINFO.uResumePC, RTCCPTR_DEF 1
at TRAPINFO.u8TrapNo, db 16
at TRAPINFO.cbInstr, db 3
iend
GLOBALNAME g_aTrapInfoEnd
istruc TRAPINFO
at TRAPINFO.uTrapPC, RTCCPTR_DEF 0
at TRAPINFO.uResumePC, RTCCPTR_DEF 0
at TRAPINFO.u8TrapNo, db 0
at TRAPINFO.cbInstr, db 0
iend
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