mirror of
https://github.com/bitdefender/bddisasm.git
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767bf2e5c0
Added support for AMD RMPREAD instruction. Improved EVEX decoding, including the new U bit. Fixed ENTER & LEAVE operands.
1413 lines
58 KiB
Python
1413 lines
58 KiB
Python
#!/usr/bin/env python3
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#
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# Copyright (c) 2024 Bitdefender
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# SPDX-License-Identifier: Apache-2.0
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#
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import os
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import sys
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import re
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import glob
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# Instruction attributes. These values go with the 'a' metadata key.
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valid_attributes = {
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# Misc instruction properties.
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'MODRM', # Mod r/m is present.
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'3DNOW', # Instruction uses 3dnow encoding.
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'COND', # Instruction has condition encoded in lower 4 bit of the opcode.
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'LOCKSP', # Special lock - MOV CR on amd can use LOCK to access CR8 in 32 bit mode.
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'VECTOR', # Vector instruction.
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'S66', # 0x66 prefix changes length even if it is in special map (66, f2, f3).
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'SHS', # Instruction accesses the shadow stack.
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'MFR', # The Mod inside Mod R/M is forced to register. No SIB/disp present.
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'CETT', # Instruction is CET tracked.
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'SERIAL', # Instruction is serializing.
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'SCALABLE', # EVEX.pp prefix can be 0 or 1, simulating the presence of 0x66 prefix.
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# 64-bit modifiers.
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'I64', # Instruction invalid in 64 bit mode.
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'O64', # Instruction valid only in 64 bit mode.
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'F64', # Operand size forced to 64 bit.
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'D64', # Operand size defaults to 64 bit.
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# Per operand indicators.
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'OP1DEF', # Operand 1 is default (implicit).
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'OP2DEF', # Operand 2 is default (implicit).
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'OP2SIGNEXO1', # Operand 2 is sign-extended to the size of the first operand.
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'OP3SIGNEXO1', # Operand 3 is sign-extended to the size of the first operand.
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'OP1SIGNEXDW', # Operand 1 is sign-extended to the size of the default word.
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# Addressing flags.
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'AG', # Instruction uses address generation, no memory access.
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'BITBASE', # Instruction uses bitbase addressing.
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'VSIB', # Instruction uses VSIB addressing.
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'MIB', # Instruction uses MIB addressing.
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'SIBMEM', # Instruction uses sibmem addressing (AMX instructions).
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# Ignored fields.
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'LIG', # *vex.L is ignored.
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'WIG', # *vex.W is ignored.
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'I67', # Ignore the address size override (0x67) prefix in 64 bit mode.
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'IER', # Ignore embedded rounding for the instruction.
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'IWO64', # The VEX/EVEX.W field is ignored outside 64 bit mode, and behaves as if it's 0.
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# Restrictions - these fields being present leads to #UD.
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'MMASK', # Instruction must have mask specified (mask cannot be k0).
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'NOMZ', # Zeroing not allowed with memory addressing.
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'NOL0', # Vector length 128 not supported.
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'NOA16', # 16 bit addressing not supported.
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'NORIPREL', # RIP relative addressing not supported.
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'NO66', # 0x66 prefix causes #UD.
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'NO67', # 0x67 prefix causes #UD.
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'NOREP', # REP prefixes will cause #UD.
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'NOREX2', # REX2 prefix will cause #UD.
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'NOV', # XOP/VEX/EVEX.v will cause #UD if not logical 0.
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'NOVP', # EVEX.v' will cause #UD if not logical 0.
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}
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# Explicit operands types.
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valid_optypes = [
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'A', # Direct addressing. Used by direct branches.
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'B', # The vvvv field inside VEX/EVEX encodes a general purpose registr.
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'C', # The reg field inside Mod R/M encodes a control register.
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'D', # The reg field inside Mod R/M encodes a debug register.
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'E', # The rm field inside Mod R/M encodes a general purpose register or memory.
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'F', # Implicit flags register.
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'G', # The reg field inside Mod R/M encodes a general purpose register.
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'H', # The vvvv field inside VEX/EVEX encodes a SIMD register.
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'I', # Immediate encoded in instruction bytes.
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'J', # Relative offset encoded in instruction bytes.
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'K', # The operand is the stack.
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'L', # The upper 4-bit of an immediate encode a SIMD register.
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'M', # The rm field inside Mod R/M encodes memory.
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'N', # The rm field inside Mod R/M encodes a MMX register.
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'O', # Moffset addressing.
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'P', # The reg field inside Mod R/M encodes a MMX register.
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'Q', # The rm field inside Mod R/M encodes a MMX register or memory.
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'R', # The rm field inside Mod R/M encodes a general purpose register.
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'S', # The reg field inside Mod R/M emcodes a segment register.
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'T', # The reg field inside Mod R/M encodes a test register.
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'U', # The rm field inside Mod R/M encodes a SIMD register.
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'V', # The reg field inside Mod R/M encodes a SIMD register.
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'W', # The rm field inside Mod R/M enocdes a SIMD register or memory.
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'X', # DS:rSI addressing.
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'Y', # ES:rDI addressing.
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'Z', # The low 3 bits inside the opcode encode a general purpose register.
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'rB', # The reg field inside Mod R/M enocdes a bound register.
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'mB', # The rm field inside Mod R/M enocdes a bound register or memory.
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'rK', # The reg field inside Mod R/M enocdes a mask register.
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'vK', # The vvvv field inside VEX/EVEX encodes a mask register.
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'mK', # The rm field inside Mod R/M encodes a mask register.
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'aK', # The aaa field inside EVEX encodes a mask register.
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'rM', # The reg field inside Mod R/M encodes the base address of a memory operand.
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# Default segment is ES.
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'mM', # The rm field inside Mod R/M encodes the base address of a memory operand.
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# Default segment is DS.
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'rT', # The reg field inside Mod R/M encodes a tile register (AMX extension).
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'mT', # The rm field inside Mod R/M encodes a tile register (AMX extension).
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'vT', # The vvvv field inside VEX/EVEX encodes a tile register (AMX extension).
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'm2zI', # Bits [1,0] of the immediate byte which encodes the fourth register.
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'dfv', # The EVEX.VVVV encodes a default flags value (OF,SF,ZF,CF).
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]
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# Operand sizes.
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# Unless otherwise stated, where multiple sizes are given, the correct size is selected by the
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# operand size or vector length as follows:
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# - the first size if operand size is 16-bit or vector length is 128-bit
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# - the second size if operand size is 32-bit or vector length is 256-bit
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# - the third size of the operand size is 64-bit or vector length is 512-bit.
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# If only two sizes are given, only 16-bit and 32-bit operand sizes are considered, unles otherwise
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# indicated.
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# If only a size is given, that is available in all modes and with all operand sizes.
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valid_opsizes = [
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'a', # 2 x 16 bits (16-bit opsize) or 2 x 32 bits (32-bit opsize).
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# Fixed integer sizes.
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'b', # 8 bits.
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'w', # 16 bits.
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'd', # 32 bits.
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'q', # 64 bits.
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# Variable integer sizes.
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'z', # 16 bits (16-bit opsize) or 32 bits (32 or 64-bit opsize).
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'v', # 16, 32 or 64 bits.
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'y', # 64 bits (64-bit opsize), 32 bits othwerwise.
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'yf', # 64 bits (64-bit mode), 32 bits (16, 32-bit opsize).
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's', # 48 or 80 bits descriptor.
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'p', # 32, 48 or 80 bits pointer.
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'l', # 64 (16 or 32-bit opsize) or 128 bits (64-bit opsize).
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# FPU sizes.
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'fa', # 80 bits packed BCD.
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'fw', # 16 bits real number.
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'fd', # 32 bits real number.
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'fq', # 64 bits real number.
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'ft', # 80 bits real number.
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'fe', # 14 bytes or 28 bytes FPU environment.
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'fs', # 94 bytes or 108 bytes FPU state.
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# SIMD sizes.
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'dq', # 128 bits.
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'qq', # 256 bits.
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'oq', # 512 bits.
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'ev', # 1/8 of vlen: 16, 32 or 64 bits.
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'qv', # 1/4 of vlen: 32, 64 or 128 bits.
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'hv', # 1/2 of vlen: 64, 128 or 256 bits.
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'x', # 128 bits (128-bit vlen) or 256 bits (256-bit vlen).
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'uv', # 256 bits (256-bit vlen) or 512 bits (512-bit vlen).
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'fv', # 128, 256 or 512 bits.
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'pd', # 128 or 256 bits.
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'ps', # 128 or 256 bits.
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'ph', # Packed FP16 values.
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'sd', # 128 bits scalar element (double precision).
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'ss', # 128 bits scalar element (single precision).
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'sh', # FP16 Scalar element.
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# VSIB addressing.
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'vm32x', # VSIB addressing, using DWORD indices in XMM register, select 32/64 bit.
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'vm32y', # VSIB addressing, using DWORD indices in YMM register, select 32/64 bit.
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'vm32z', # VSIB addressing, using DWORD indices in ZMM register, select 32/64 bit.
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'vm32h', # VSIB addressing, using DWORD indices in half register, select 32/64 bit.
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'vm32n', # VSIB addressing, using DWORD indices in normal register, select 32/64 bit.
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'vm64x', # VSIB addressing, using QWORD indices in XMM register, select 32/64 bit.
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'vm64y', # VSIB addressing, using QWORD indices in YMM register, select 32/64 bit.
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'vm64z', # VSIB addressing, using QWORD indices in ZMM register, select 32/64 bit.
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'vm64h', # VSIB addressing, using QWORD indices in half register, select 32/64 bit.
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'vm64n', # VSIB addressing, using QWORD indices in normal register, select 32/64 bit.
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# MIB addressing.
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'mib', # MIB addressing, the base & the index are used to form a pointer.
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# Stack sizes and partial access.
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'v2', # Two stack words.
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'v3', # Three stack words.
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'v4', # Four stack words.
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'v5', # Five stack words.
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'v8', # Eight stack words.
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# Misc and special sizes.
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'?', # Unknown operand size. Depends on many factors (for example, XSAVE).
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'0', # Used for instructions that do not actually access any memory.
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'asz', # The size of the operand is given by the current addressing mode.
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'ssz', # The size of the operand is given by the current stack mode.
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'rx', # 512 bytes extended state.
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'cl', # 32/64/128 bytes - the size of one cache line.
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'12', # 4 bytes (0) + 8 bytes (old SSP), used by SAVEPREVSSP.
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't', # A tile register. The size varies depending on execution environment, but can be as high as 1K.
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'384', # 384 bits representing a Key Locker handle.
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'512', # 512 bits representing a Key Locker handle.
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'4096', # 4096 bits representing an MSR address/value table.
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]
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# Implicit/fixed operands.
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valid_impops = {# register size
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'AH' : ('AH', 'b'), # AH register.
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'AL' : ('rAX', 'b'), # AL register.
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'AX' : ('rAX', 'w'), # AX register.
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'EAX' : ('rAX', 'd'), # EAX register.
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'RAX' : ('rAX', 'q'), # RAX register.
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'eAX' : ('rAX', 'z'), # AX or EAX register, depending on op size.
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'rAX' : ('rAX', 'v'), # AX, EAX or RAX register, depending on op size.
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'yAX' : ('rAX', 'y'), # EAX or RAX register, depending on op size.
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'CL' : ('rCX', 'b'), # CL register.
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'ECX' : ('rCX', 'd'), # ECX register.
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'RCX' : ('rCX', 'q'), # RCX register.
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'eCX' : ('rCX', 'z'), # CX or ECX register.
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'rCX' : ('rCX', 'v'), # CX, ECX or RCX register, depending on op size.
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'yCX' : ('rCX', 'y'), # ECX or RCX register, depending on op size.
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'aCX' : ('rCX', 'asz'), # CX, ECX or RCX register, depedning on address size.
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'DX' : ('rDX', 'w'), # DX register.
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'EDX' : ('rDX', 'd'), # EDX register.
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'RDX' : ('rDX', 'q'), # RDX register.
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'eDX' : ('rDX', 'z'), # DX or EDX register, depending on op size.
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'rDX' : ('rDX', 'v'), # DX, EDX or RDX register, depending on op size.
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'yDX' : ('rDX', 'y'), # EDX or RDX register, depending on op size.
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'EBX' : ('rBX', 'd'), # EBX register.
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'RBX' : ('rBX', 'q'), # RBX register.
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'rBX' : ('rBX', 'v'), # BX, EBX or RBX register, depending on op size.
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'yBX' : ('rBX', 'y'), # EBX or RBX register, depending on op size.
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'rBP' : ('rBP', 'v'), # BP, EBP or RBP register, depending on op size.
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'sBP' : ('rBP', 'ssz'), # BP, EBP or RBP register, depending on stack size.
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'rSP' : ('rSP', 'v'), # SP, ESP or RSP register, depending on op size.
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'sSP' : ('rSP', 'ssz'), # SP, ESP or RSP register, depending on stack size.
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'aSI' : ('rSI', 'asz'), # SI, ESI, or RSI register, depending on address size.
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'aDI' : ('rDI', 'asz'), # DI, EDI, or RDI register, depending on address size.
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'R8' : ('rR8', 'q'), # R8 register.
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'R9' : ('rR9', 'q'), # R9 register.
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'R11' : ('rR11', 'q'), # R11 register.
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'rIP' : ('rIP', 'v'), # IP, EIP or RIP, depending on op size.
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'yIP' : ('rIP', 'yf'), # EIP in 16/32 bit mode, or RIP in 64 bit mode.
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'1' : ('1', 'b'), # Constant 1.
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'XMM0' : ('XMM0', 'dq'), # XMM0 register.
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'XMM1' : ('XMM1', 'dq'), # XMM1 register.
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'XMM2' : ('XMM2', 'dq'), # XMM2 register.
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'XMM3' : ('XMM3', 'dq'), # XMM3 register.
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'XMM4' : ('XMM4', 'dq'), # XMM4 register.
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'XMM5' : ('XMM5', 'dq'), # XMM5 register.
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'XMM6' : ('XMM6', 'dq'), # XMM6 register.
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'XMM7' : ('XMM7', 'dq'), # XMM7 register.
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'ST(0)' : ('ST0', 'ft'), # ST(0) register.
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'ST(i)' : ('STi', 'ft'), # ST(1) register.
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'CS' : ('CS', 'v'), # CS register.
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'SS' : ('SS', 'v'), # SS register.
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'DS' : ('DS', 'v'), # DS register.
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'ES' : ('ES', 'v'), # ES register.
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'FS' : ('FS', 'v'), # FS register.
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'GS' : ('GS', 'v'), # GS register.
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'CR0' : ('CR0', 'yf'), # CR0 register.
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'XCR' : ('XCR', 'q'), # An XCR register.
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'XCR0' : ('XCR0', 'q'), # XCR0 register.
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'MSR' : ('MSR', 'q'), # A MSR.
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'TSC' : ('TSC', 'q'), # TSC register.
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'TSCAUX' : ('TSCAUX', 'q'), # TSXAUX register.
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'SCS' : ('SCS', 'q'), # IA32_SYSNETER_CS register.
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'SEIP' : ('SEIP', 'q'), # IA32_SYSENTER_EIP register.
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'SESP' : ('SESP', 'q'), # IA32_SYSENTER_ESP register.
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'FSBASE' : ('FSBASE', 'q'), # IA32_FS_BASE register.
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'GSBASE' : ('GSBASE', 'q'), # IA32_GS_BASE register.
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'KGSBASE' : ('KGSBASE', 'q'), # IA32_KERNEL_GS_BASE register.
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'STAR' : ('STAR', 'q'), # IA32_STAR register.
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'LSTAR' : ('LSTAR', 'q'), # IA32_LSTAR register.
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'FMASK' : ('FMASK', 'q'), # IA32_FMASK register.
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'GDTR' : ('GDTR', 's'), # GDT register.
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'IDTR' : ('IDTR', 's'), # IDT register.
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'LDTR' : ('LDTR', 'w'), # LDT register.
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'TR' : ('TR', 'w'), # Task register.
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'BANK' : ('BANK', '?'), # A register bank.
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'X87CONTROL':('X87CONTROL', 'w'), # X87 control register.
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'X87TAG' : ('X87TAG', 'w'), # X87 tag register.
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'X87STATUS': ('X87STATUS', 'w'), # X87 status register.
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'MXCSR' : ('MXCSR', 'd'), # MXCSR register.
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'PKRU' : ('PKRU', 'd'), # PKRU register.
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'SSP' : ('SSP', 'yf'), # Shadow stack pointer. 32 bit in protected/compat mode, 64 in long mode.
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'SMT' : ('SMT', '4096'),# Source MSR table, encododed in [RSI], up to 4096 bits long (64 entries x 64 bits per entry).
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'DMT' : ('DMT', '4096'),# Value MSR table, encododed in [RDI], up to 4096 bits long (64 entries x 64 bits per entry).
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# Implicit memory operands.
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'pAXb' : ('pAX', 'b'), # Implicit byte [rAX], used by MONITOR and MONITORX. Can be overriden.
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'pCXdq' : ('pCX', 'dq'), # Implicit xmmword [rCX], used by RMPADJUST. Can be overriden.
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'pBXALb' : ('pBXAL', 'b'), # Implicit [RBX + AL], as used by XLAT.
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'pDIq' : ('pDI', 'q'), # Implicit qword [RDI].
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'pDIdq' : ('pDI', 'dq'), # Implicit xmmword [RDI].
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'pBP' : ('pBP', 'v'), # Implicit operand size loaded from [RBP]. RBP is subject to stack address size.
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# Implicit shadow stack accesses.
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'SHS' : ('SHS', 'q'), # Shadow stack (SSP) implicit access, 1 qword (use by CET instructions).
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'SHS0' : ('SHS0', 'q'), # Shadow stack (IA32_PL0_SSP) implicit access, 1 qword (use by CET instructions).
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'SHSI' : ('SHS', 'v2'), # Shadow stack load & discard, 2 elements (INCCSPD/INCSSPQ).
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'SHSS' : ('SHS', '12'), # Shadow stack read & store 4 + 8 bytes (SAVEPREVSSP).
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'SHS1' : ('SHSP', 'v'), # Shadow stack push/pop, 1 word.
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'SHS2' : ('SHSP', 'v2'), # Shadow stack push/pop, 2 words.
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'SHS3' : ('SHSP', 'v3'), # Shadow stack push/pop, 3 words.
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'SHS4' : ('SHSP', 'v4'), # Shadow stack push/pop, 4 words.
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# User Interrupt Flag.
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'UIF' : ('UIF', 'b'), # User Interrupt Flag, stored with size of 1 byte, although it is 1 bit.
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}
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# If an operand type is not present here, than that operand is implicit & it's not encoded inside the instruction.
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operand_encoding = {
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'A' : 'D', # Immediate, encoded directly in the instruction bytes.
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'B' : 'V', # VEX/EVEX.vvvv encoded general purpose register.
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'C' : 'R', # Modrm.reg encoded control register.
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'D' : 'R', # Modrm.reg encoded debug register.
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'E' : 'M', # Modrm.rm encoded general purpose register or memory.
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'G' : 'R', # Modrm.reg encoded general purpose register.
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'H' : 'V', # VEX/EVEX.vvvv encoded vector register.
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'I' : 'I', # Immediate, encoded directly in the instruction bytes.
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'J' : 'D', # Relative offset, encoded directly in the instruction bytes.
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'L' : 'L', # Register encoded in an immediate.
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'M' : 'M', # Modrm.rm encoded memory.
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'N' : 'M', # Modrm.rm encoded MMX register.
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'O' : 'D', # Absolute memory encoded directly in the instruction.
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'P' : 'R', # Modrm.reg encoded MMX register.
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'Q' : 'M', # Modrm.rm encoded MMX register or memory.
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'R' : 'M', # Modrm.rm encoded general purpose register.
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'S' : 'R', # Modrm.reg encoded segment register.
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'T' : 'R', # Modrm.reg encoded test register.
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'U' : 'M', # Modrm.rm encoded vector register.
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'V' : 'R', # Modrm.reg encoded vector register.
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'W' : 'M', # Modrm.rm encoded vector register or memory.
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'Z' : 'O', # General purpose register encoded in opcode low 3 bit.
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'rB' : 'R', # Modrm.reg encoded bound register.
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'mB' : 'M', # Modrm.rm encoded bound register or memory.
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'rK' : 'R', # Modrm.reg encoded mask register.
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'vK' : 'V', # VEX/EVEX.vvvv encoded mask register.
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'mK' : 'M', # Modrm.rm encoded mask register or memory.
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'aK' : 'A', # EVEX.aaa encoded mask register.
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'mR' : 'R', # Modrm.reg encoded memory.
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'mM' : 'M', # Modrm.rm encoded memory (always).
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'1' : '1', # Constant 1.
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'CL' : 'C', # CL register.
|
|
'ST(i)' : 'M', # Modrm.rm encoded FPU register.
|
|
'm2zI' : 'L', # Immediate encodes a register.
|
|
'dfv' : 'V', # EVEX.VVVV encodes a default flags value.
|
|
}
|
|
|
|
# Accepted prefixes. These values go with the 'p' metadata key.
|
|
valid_prefixes = [
|
|
'REP', # Rep prefix is accepted.
|
|
'REPC', # Conditional rep prefix is accepted.
|
|
'HLE', # Hardware Lock Elision accepted.
|
|
'BND', # Bound prefix accepted (MPX).
|
|
'LOCK', # Lock prefix accepted.
|
|
'BH', # Branch hints accepted.
|
|
'XACQUIRE', # Xacquire prefix accepted.
|
|
'XRELEASE', # Xrelease prefix accepted.
|
|
'HLEWOL', # HLE prefix is accepted without lock - used by MOV instructions.
|
|
'DNT', # Do Not Track prefix accepted (CET).
|
|
]
|
|
|
|
# Accepted access types. These values go with the 'w' metadata key (operand access map).
|
|
valid_access = [
|
|
'N', # No access.
|
|
'P', # Prefetch access.
|
|
'R', # Read.
|
|
'W', # Write.
|
|
'CR', # Conditional read.
|
|
'CW', # Conditional write.
|
|
'RW', # Read-Write.
|
|
'CRW', # Conditional Read-Write.
|
|
'RCW', # Read-Conditional Write.
|
|
'CRCW', # Conditional Read-Conditional Write.
|
|
]
|
|
|
|
# Valid flags. These values go with the 'f' metadata key.
|
|
valid_flags = [
|
|
'CF', # Carry.
|
|
'PF', # Parity.
|
|
'AF', # Auxiliary.
|
|
'ZF', # Zero.
|
|
'SF', # Sign.
|
|
'TF', # Trap.
|
|
'IF', # Interrupt.
|
|
'DF', # Direction.
|
|
'OF', # Overflow.
|
|
'IOPL', # I/O privilege level.
|
|
'NT', # Nested Task.
|
|
'RF', # Resume Flag.
|
|
'VM', # V8086 mmode.
|
|
'AC', # Alignment Check.
|
|
'VIF', # Virtual IF.
|
|
'VIP', # Virtual IP.
|
|
'ID' # CPUID ID flag.
|
|
]
|
|
|
|
# Valid flags access. These values go with the 'f' metadata key.
|
|
valid_flag_op = [
|
|
'm', # modified.
|
|
't', # tested.
|
|
'0', # cleared.
|
|
'1', # set.
|
|
'u', # undefined.
|
|
'n', # not accessed.
|
|
]
|
|
|
|
# Valid CPU modes. These values go with the 'm' metadata key.
|
|
valid_cpu_modes = [
|
|
'r0', # Ring 0.
|
|
'r1', # Ring 1.
|
|
'r2', # Ring 2.
|
|
'r3', # Ring 3.
|
|
'real', # Real mode.
|
|
'v8086', # V8086 mode.
|
|
'prot', # Protected mode.
|
|
'compat', # Compatibility mode.
|
|
'long', # Long mode.
|
|
'smm', # System Management Mode.
|
|
'smm_off', # Outside SMM.
|
|
'sgx', # Software Guard Extensions SGX enclave.
|
|
'sgx_off', # Outside SGX.
|
|
'tsx', # Transactional Synchronization Extensions.
|
|
'tsx_off', # Outside TSX.
|
|
'vmxr', # VMX root.
|
|
'vmxn', # VMX non-root.
|
|
'vmxr_seam', # VMX root SEAM.
|
|
'vmxn_seam', # VMX non-root SEAM.
|
|
'vmx_off', # Outside VMX operation.
|
|
]
|
|
|
|
valid_mode_groups = [
|
|
'ring',
|
|
'mode',
|
|
'vmx',
|
|
'other',
|
|
]
|
|
|
|
valid_ring_modes = [
|
|
'r0',
|
|
'r1',
|
|
'r2',
|
|
'r3',
|
|
]
|
|
|
|
valid_mode_modes = [
|
|
'real',
|
|
'v8086',
|
|
'prot',
|
|
'compat',
|
|
'long',
|
|
]
|
|
|
|
valid_vmx_modes = [
|
|
'vmxr',
|
|
'vmxn',
|
|
'vmxr_seam',
|
|
'vmxn_seam',
|
|
'vmx_off',
|
|
]
|
|
|
|
valid_other_modes = [
|
|
'smm',
|
|
'smm_off',
|
|
'sgx',
|
|
'sgx_off',
|
|
'tsx',
|
|
'tsx_off',
|
|
]
|
|
|
|
valid_mode_map = {
|
|
'ring' : valid_ring_modes,
|
|
'mode' : valid_mode_modes,
|
|
'vmx' : valid_vmx_modes,
|
|
'other' : valid_other_modes,
|
|
}
|
|
|
|
# Valid decoratoras that can be present in either mnemonic or operand.
|
|
valid_decorators = [
|
|
'{K}', # Masking support.
|
|
'{z}', # Zeroing support.
|
|
'{sae}', # Surpress All Exceptions.
|
|
'{er}', # Embedded Rounding.
|
|
'|B32', # Broadcast 32.
|
|
'|B64', # Broadcast 64.
|
|
'|B16', # Broadcast 16.
|
|
'{ND}', # New data destination.
|
|
'{NF}', # No flags.
|
|
'{ZU}', # Zero-upper.
|
|
]
|
|
|
|
# Maps decorator to global flags.
|
|
deco_flags = {
|
|
'{K}' : 'MASK',
|
|
'{z}' : 'ZERO',
|
|
'{sae}' : 'SAE',
|
|
'{er}' : 'ER',
|
|
'|B32' : 'BROADCAST',
|
|
'|B64' : 'BROADCAST',
|
|
'|B16' : 'BROADCAST',
|
|
'{ND}' : 'ND',
|
|
'{ZU}' : 'ZU',
|
|
'{NF}' : 'NF',
|
|
}
|
|
|
|
# Maps decorator to operand flags.
|
|
deco_op_flags = {
|
|
'{K}' : 'MASK',
|
|
'{z}' : 'ZERO',
|
|
'{sae}' : 'SAE',
|
|
'{er}' : 'ER',
|
|
'|B32' : 'B32',
|
|
'|B64' : 'B64',
|
|
'|B16' : 'B16',
|
|
}
|
|
|
|
# Valid EVEX tuples. These values go with the 'l' metadata key.
|
|
valid_tuples = [
|
|
'fv', # Full Vector, Load+Op (Full Vector Dword/Qword).
|
|
'hv', # Half Vector, Load+Op (Half Vector).
|
|
'qv', # Quarter vector, Load+op (Quarter Vector, FP16)
|
|
'fvm', # Full Vector Memory, Load/store or subDword full vector.
|
|
'hvm', # Half Vector Memory, SubQword Conversion.
|
|
'qvm', # Quarter Vector Memory, SubDword Conversion.
|
|
'ovm', # Oct Vector Memory, SubWord Conversion.
|
|
'dup', # Dup, VMOVDDUP.
|
|
'm128', # Mem 128, Shift count from memory.
|
|
't1s8', # Tuple 1 Scalar, 8 bit, 1Tuple less than Full Vector.
|
|
't1s16', # Tuple 1 Scalar, 16 bit, 1Tuple less than Full Vector.
|
|
't1s', # Tuple 1 Scalar, 32/64 bit, 1Tuple less than Full Vector.
|
|
't1f', # Tuple 1 Fixed, 1 Tuple memsize not affected by EVEX.W.
|
|
't2', # Tuple 2, Broadcast (2 elements).
|
|
't4', # Tuple 4, Broadcast (4 elements).
|
|
't8', # Tuple 8, Broadcast (8 elements).
|
|
't1_4x',
|
|
]
|
|
|
|
# Valid EVEX modes. These values go with the 'v' metadata key.
|
|
valid_evex_mode = [
|
|
'none', # Legacy EVEX
|
|
'vex', # EVEX extension for VEX
|
|
'legacy', # EVEX extension for legacy instructions
|
|
'cond', # EVEX extension for conditional instructons
|
|
]
|
|
|
|
|
|
# Use one of these value to indicate absent operands.
|
|
absent_op = ['n/a', '']
|
|
|
|
# Global templates, extracted from template files.
|
|
template_flags = {}
|
|
template_cpuid = {}
|
|
template_modes = {}
|
|
|
|
|
|
def my_str(x):
|
|
if x is None:
|
|
return x
|
|
else:
|
|
return str(x)
|
|
|
|
|
|
class InvalidSpecificationException(Exception):
|
|
def __init__(self, value):
|
|
self.value = value
|
|
|
|
def __str__(self):
|
|
return repr(self.value)
|
|
|
|
|
|
class CpuidFeatureFlag():
|
|
"""
|
|
Describes a CPUID feature flag.
|
|
|
|
Attributes
|
|
----------
|
|
Name: str
|
|
Feature name.
|
|
Leaf: str
|
|
Leaf number (the EAX input value).
|
|
SubLeaf: str
|
|
SubLeaf number (the ECX input value. '0xFFFFFFFF' if no subleaf present).
|
|
Reg: str
|
|
The output register that contains the feature indication.
|
|
Bit: str
|
|
The bit inside Reg that indicates whether the feature is present or not.
|
|
"""
|
|
def __init__(self, finfo):
|
|
self.Name = finfo['name']
|
|
self.Leaf = finfo['leaf']
|
|
self.SubLeaf = finfo['subleaf']
|
|
self.Reg = finfo['reg']
|
|
self.Bit = finfo['bit']
|
|
|
|
def __str__(self):
|
|
return '%s: %s, %s, %s, %s' % (self.Name, self.Leaf, self.SubLeaf, self.Reg, self.Bit)
|
|
|
|
|
|
class Operand():
|
|
"""
|
|
Describes an x86 instruction operand.
|
|
|
|
Attributes
|
|
----------
|
|
Raw: str
|
|
Raw operand description (examples: 'Gv', or 'EAX').
|
|
Type: str
|
|
Operand type. One of valid_optypes (example: 'G').
|
|
Size: str
|
|
Operand size. One of valid_opsizes (example: 'v').
|
|
Flags: list[str]
|
|
Operand flags (example: ['OPDEF']).
|
|
Decorators: list[str]
|
|
Operand decorators (example: ['MASK', 'ZERO']). Entries from deco_op_flags.
|
|
Access: str
|
|
Operand access mode (example: 'RW'). One of valid_access.
|
|
Block: int
|
|
Operand block register access. Usually 0.
|
|
Encoding: str
|
|
Operand encoding (example: 'R'). One of operand_encoding values.
|
|
Implicit: bool
|
|
Whether the operand is implicit or explicit.
|
|
"""
|
|
def __init__(self, op, access, flags, imp = False):
|
|
self.Raw = op
|
|
self.Type = 0
|
|
self.Size = 0
|
|
self.Flags = flags
|
|
self.Decorators = []
|
|
self.Access = []
|
|
self.Block = 0
|
|
self.Encoding = 'S'
|
|
self.Implicit = imp
|
|
orig = op
|
|
|
|
# Handle block registers.
|
|
if op.endswith('+3'):
|
|
self.Block = 4
|
|
op = op.replace('+3', '')
|
|
elif op.endswith('+1'):
|
|
self.Block = 2
|
|
op = op.replace('+1', '')
|
|
else:
|
|
m = re.match(r'XMM(\d)-(\d)', op)
|
|
if m:
|
|
start = m.group(1)
|
|
end = m.group(2)
|
|
self.Block = int(end) - int(start) + 1
|
|
op = 'XMM' + start
|
|
|
|
# Handle the decorators.
|
|
for dec in valid_decorators:
|
|
if -1 != op.find(dec):
|
|
# Found decorator.
|
|
self.Decorators.append(dec)
|
|
# Remove it from the opstring.
|
|
op = op.replace(dec, '')
|
|
|
|
# Handle hard-coded operators - those that are implicit/are not encoded anywhere.
|
|
if op in valid_impops:
|
|
self.Type, self.Size = valid_impops[op][0], valid_impops[op][1]
|
|
# Now handle explicit operators.
|
|
else:
|
|
# Attempt a match inside the explicit operands map.
|
|
for opt in valid_optypes:
|
|
if op.startswith(opt):
|
|
self.Type = opt
|
|
op = op.replace(opt, '')
|
|
break
|
|
|
|
# Now the operand size. After parsing the decorator and the operand type, we should be left with
|
|
# the operand size only.
|
|
if self.Type in ['rK', 'mK', 'vK', 'aK'] and not op in valid_opsizes:
|
|
self.Size = 'q'
|
|
elif self.Type in ['dfv']:
|
|
# No size for default flags value.
|
|
self.Size = '0'
|
|
elif op in valid_opsizes:
|
|
self.Size = op
|
|
else:
|
|
raise InvalidSpecificationException("Invalid operand size specified: " + orig)
|
|
|
|
if self.Type in operand_encoding:
|
|
self.Encoding = operand_encoding[self.Type]
|
|
elif self.Raw in operand_encoding:
|
|
self.Encoding = operand_encoding[self.Raw]
|
|
|
|
if imp and 'OPDEF' not in self.Flags:
|
|
self.Flags.append('OPDEF')
|
|
|
|
self.Access = access
|
|
|
|
def __str__(self):
|
|
return self.Raw
|
|
|
|
|
|
class Instruction():
|
|
"""
|
|
Describes an x86 instruction.
|
|
|
|
Attributes
|
|
----------
|
|
Mnemonic: str
|
|
The instruction mnemonic. Decorators are not included.
|
|
RawExpOps: list[str]
|
|
Raw explicit operands, as supplied in the specification file (example: ['Gv', 'Ev']).
|
|
RawImpOps: list[str]
|
|
Raw implicit operands, as supplied in the specification file (example: ['Fv', 'rIP']).
|
|
RawEnc: str
|
|
Raw encoding, as supplied in the specification file (example: '0xBD /r').
|
|
RawMeta: list[str]
|
|
Raw meta-data, as supplied in the specification file (example: ['a:MODRM', 'p:LOCK', 's:ABC']).
|
|
DecoFlags: list[str]
|
|
Decorator flags, extracted from mnemonic & operands. Indicates what decorators are accepted
|
|
by the instruction.
|
|
Xop: bool
|
|
True if instruction uses XOP encoding.
|
|
Vex: bool
|
|
True if instruction uses VEX encoding.
|
|
Evex: bool
|
|
True if instruction uses EVEX encoding.
|
|
ExpOps: list[Operand]
|
|
Processed explicit operands. A list of Operand objects.
|
|
ImpOps: list[Operand]
|
|
Processed implicit operands. A list of Operand objects.
|
|
Attributes: list[str]
|
|
A list of instruction attributes (example: ['MODRM', 'I64']). Each attriubute in this list
|
|
must be one of the values listed in valid_attributes.
|
|
Prefmap: list[str]
|
|
A list of accepted prefixes (example: ['LOCK', 'HLE']). Each prefix in this list must be one
|
|
of the values listed in valid_prefixes.
|
|
Set: str
|
|
Instruction set (example: 'ABCD').
|
|
Category: str
|
|
Instruction category (example: 'XYZQ').
|
|
Class: str
|
|
Instruction class. Usually the same as the mnemonic. Can be overridden, if it is explicitly
|
|
specified.
|
|
Rwm: list[str]
|
|
Operand access map (example: ['RW', 'W']). Length must be equal to len(ExpOps) + len(ImpOps).
|
|
Inside the Rwm list, the entry at position x indicates the access mode for operand x.
|
|
Id: str
|
|
CPUID feature flag, if any (example: 'AVX512VBMI2').
|
|
Tuple: str
|
|
EVEX tuple, if any (example: 'fvm').
|
|
ExType: str
|
|
Exception type, if any (example: '1', or 'EVEX_PP2').
|
|
Rflags: dict
|
|
Flags access mode (example: {'m': ['CF'], 't': ['CF'], 'u': ['ZF'], '0': ['AF'], '1': ['OF']}).
|
|
A dictionary with keys 'm' (modified), 't' (tested), 'u' (undefined), '0' (cleared), '1' (set),
|
|
and each key pointing to a list of flags which are accessed in the indicated mode.
|
|
FpuFlags: list[str]
|
|
FPU flags access mode (example: ['u', 'u', 'u', 'u']). A list of 4 str elements, each one
|
|
indicating the access mode for flag Cx, where x is the position in the list.
|
|
Modes: list[str]
|
|
Valid operating modes for the indicated instruction.
|
|
Encoding: dict
|
|
A dictionary containing all the encoding components.
|
|
"""
|
|
def __init__(self, mnemonic, expops, impops, encoding, meta):
|
|
# Fill in raw instruction information
|
|
self.Mnemonic = mnemonic
|
|
self.RawExpOps = expops
|
|
self.RawImpOps = impops
|
|
self.RawEnc = encoding
|
|
self.RawMeta = meta
|
|
self.DecoFlags = []
|
|
|
|
# Assume no XOP/VEX/EVEX.
|
|
self.Xop = self.Vex = self.Evex = False
|
|
|
|
# Pre-process the mnemonic, which may contain decorators.
|
|
for vd in valid_decorators:
|
|
if vd in self.Mnemonic:
|
|
self.DecoFlags.append(deco_flags[vd])
|
|
self.Mnemonic = self.Mnemonic.replace(vd, '')
|
|
|
|
# Parse meta-information.
|
|
if self.RawMeta:
|
|
self.process_meta()
|
|
|
|
# Parse the instruction encoding.
|
|
if self.RawEnc:
|
|
self.process_encoding()
|
|
else:
|
|
raise InvalidSpecificationException("Instruction with no encoding specified: " + self.Mnemonic)
|
|
|
|
# Pre-process the explicit operands. The mask register is contained as a decorator, but put it as a direct
|
|
# operand as well. The access flag is already present in rwm.
|
|
if len(self.RawExpOps) >= 1 and self.RawExpOps[0].find('{K') > 0:
|
|
self.RawExpOps.insert(1, 'aKq')
|
|
|
|
# Parse the explicit instruction operands.
|
|
self.ExpOps = self.process_operands(self.RawExpOps, False)
|
|
|
|
# Parse the implicit instruction operands.
|
|
self.ImpOps = self.process_operands(self.RawImpOps, True)
|
|
|
|
# Post-process the operands. We fill up the flags with additional info based on the operands.
|
|
usesv = usesvp = False
|
|
for op in self.ExpOps:
|
|
for deco in op.Decorators:
|
|
self.DecoFlags.append(deco_flags[deco])
|
|
if op.Type in ['U', 'V', 'W', 'H', 'L']:
|
|
self.add_attribute('VECTOR')
|
|
if op.Type in ['B', 'H', 'vK', 'vT', 'dfv']:
|
|
usesv = True
|
|
if self.Evex:
|
|
if op.Type in ['B', 'H']:
|
|
usesvp = True
|
|
if 'VSIB' in self.Attributes:
|
|
usesvp = True
|
|
if self.Encoding["sc"]:
|
|
usesvp = True
|
|
if self.Xop or self.Vex or self.Evex:
|
|
if not usesv:
|
|
self.add_attribute('NOV')
|
|
if self.Evex and not usesvp:
|
|
self.add_attribute('NOVP')
|
|
|
|
|
|
# VEX, XOP, EVEX instructions are not valid in real or v8086 modes.
|
|
if self.Vex or self.Xop or self.Evex:
|
|
if 'real' in self.Modes:
|
|
self.Modes.remove('real')
|
|
if 'v8086' in self.Modes:
|
|
self.Modes.remove('v8086')
|
|
if 'long' not in self.Modes and 'I64' not in self.Attributes:
|
|
self.Attributes.append('I64')
|
|
if 'long' in self.Modes and 'prot' not in self.Modes and 'O64' not in self.Attributes:
|
|
self.Attributes.append('O64')
|
|
|
|
|
|
def process_meta(self):
|
|
"""
|
|
Extract all the meta-data from the instruction spec, and fill in class attributes.
|
|
"""
|
|
self.Attributes = []
|
|
self.Prefmap = []
|
|
self.Set = 'UNKNOWN'
|
|
self.Category = 'UNKNOWN'
|
|
self.Class = self.Mnemonic
|
|
self.Rwm = None
|
|
self.Id = self.Set
|
|
self.Tuple = None
|
|
self.ExType = None
|
|
self.EvexMode = None
|
|
self.Rflags = {'m': [], 't': [], '0': [], '1': [], 'u': []}
|
|
self.FpuFlags = ['u', 'u', 'u', 'u']
|
|
self.Modes = valid_cpu_modes.copy()
|
|
|
|
for y in self.RawMeta:
|
|
token, value = y.strip().split(':')
|
|
|
|
if token == 'a':
|
|
# Instruction attributes.
|
|
self.Attributes = value.split('|')
|
|
for a in self.Attributes:
|
|
if a not in valid_attributes:
|
|
raise InvalidSpecificationException(
|
|
"Unknown attribute specifier '%s', expecting one of [%s]" % (a, ','.join(valid_attributes)))
|
|
elif token == 'p':
|
|
# Accepted prefixes.
|
|
self.Prefmap = value.split('|')
|
|
for p in self.Prefmap:
|
|
if p not in valid_prefixes:
|
|
raise InvalidSpecificationException(
|
|
"Unknown prefix specifier '%s', expecting one of [%s]" % (p, ','.join(valid_prefixes)))
|
|
elif token == 's':
|
|
# Instruction set.
|
|
self.Set = self.Id = value
|
|
elif token == 't':
|
|
# Instruction type.
|
|
self.Category = value
|
|
elif token == 'c':
|
|
# Instruction class.
|
|
self.Class = value
|
|
elif token == 'w':
|
|
# Operand access.
|
|
self.Rwm = value.split('|')
|
|
# The read/write map must have the same size as the number of operands.
|
|
if len(self.Rwm) < len(self.RawExpOps) + len(self.RawImpOps):
|
|
raise InvalidSpecificationException(
|
|
"Invalid number of operand access specifiers: provided %d, expecting %d" %
|
|
(len(self.Rwm), len(self.RawExpOps) + len(self.RawImpOps)))
|
|
for r in self.Rwm:
|
|
if r not in valid_access:
|
|
raise InvalidSpecificationException(
|
|
"Unknown operand access specifier '%s', expecting one of [%s]" % (r, ','.join(valid_access)))
|
|
elif token == 'i':
|
|
# CPUID flag.
|
|
self.Id = value
|
|
elif token == 'l':
|
|
# EVEX tuple.
|
|
self.Tuple = value
|
|
if self.Tuple not in valid_tuples:
|
|
raise InvalidSpecificationException(
|
|
"Unknown tuple specifier '%s', expecting one of [%s]" % (self.Tuple, ','.join(valid_tuples)))
|
|
elif token == 'v':
|
|
# EVEX mode.
|
|
self.EvexMode = value
|
|
if self.EvexMode not in valid_evex_mode:
|
|
raise InvalidSpecificationException("Unknown evex extension type '%s', expecting one of [%s]" %
|
|
(self.EvexMode, ','.join(valid_evex_mode)))
|
|
elif token == 'e':
|
|
# VEX/EVEX exception type.
|
|
self.ExType = value
|
|
elif token == 'f':
|
|
# RFLAGS access.
|
|
flgaccess = []
|
|
for v in value.split('|'):
|
|
if v in template_flags:
|
|
flgaccess += template_flags[v].split('|')
|
|
else:
|
|
flgaccess.append(v)
|
|
revflg = {}
|
|
for m in valid_flag_op:
|
|
revflg[m] = []
|
|
for flg in flgaccess:
|
|
f, m = flg.split('=')
|
|
if m not in valid_flag_op:
|
|
raise InvalidSpecificationException(
|
|
"Unknown flag access specifier '%s', expecting one of [%s]" % (m, ','.join(valid_flag_op)))
|
|
if f not in valid_flags:
|
|
raise InvalidSpecificationException(
|
|
"Unknown flag specifier '%s', expecting one of [%s]" % (f, ','.join(valid_flags)))
|
|
revflg[m].append(f)
|
|
flgaccess = revflg
|
|
self.Rflags = flgaccess
|
|
elif token == 'u':
|
|
# FPU flags access.
|
|
self.FpuFlags = ['u', 'u', 'u', 'u'] # each one is undefined.
|
|
for v in value.split('|'):
|
|
flg, acc = v.split('=')
|
|
if flg not in ['C0', 'C1', 'C2', 'C3']:
|
|
raise InvalidSpecificationException("Unknown FPU flag: %s" % flg)
|
|
if acc not in ['0', '1', 'm', 'u']:
|
|
raise InvalidSpecificationException("Unknown FPU flag access: %s" % acc)
|
|
self.FpuFlags[int(flg[1])] = acc
|
|
elif token == 'm':
|
|
# Example: m:ring=0,1,2,3|vmx=root,nonroot|mode=real,v8086,smm,prot,compat,long|other=sgx,tsx
|
|
# Note: any group that is not specified is considered entirely valid
|
|
# Note: any group that is specified overrides all the other fields in the group; example:
|
|
# mode=real - this means the instruction is valid ONLY in real mode.
|
|
# mode=!v8086 - this means the instructiom is valid is ANY mode except for V8086
|
|
tmodes = []
|
|
for t in value.split('|'):
|
|
if t in template_modes:
|
|
tmodes += template_modes[t].split('|')
|
|
else:
|
|
tmodes.append(t)
|
|
|
|
modes = []
|
|
groups = {}
|
|
for g in valid_mode_groups:
|
|
groups[g] = {}
|
|
groups[g]['negated'] = False
|
|
groups[g]['specified'] = False
|
|
groups[g]['modes'] = []
|
|
|
|
for tm in tmodes:
|
|
m, v = tm.split('=')
|
|
for vx in v.split('+'):
|
|
if vx.startswith('!'):
|
|
vx = vx[1:]
|
|
groups[m]['negated'] = True
|
|
if m not in valid_mode_groups:
|
|
raise InvalidSpecificationException("Unknown CPU mode group specified: %s" % m)
|
|
if vx not in valid_mode_map[m]:
|
|
raise InvalidSpecificationException("Mode %s is not valid for mode group %s; it can be one of [%s]" %
|
|
(vx, m, ','.join(valid_mode_map[m])))
|
|
groups[m]['specified'] = True
|
|
groups[m]['modes'].append(vx)
|
|
|
|
for g in groups:
|
|
if not groups[g]['specified']:
|
|
modes += valid_mode_map[g]
|
|
elif not groups[g]['negated']:
|
|
modes += groups[g]['modes']
|
|
else:
|
|
modes += [x for x in valid_mode_map[g] if x not in groups[g]['modes']]
|
|
|
|
for m in modes:
|
|
if m.startswith('!'):
|
|
m = m[1:]
|
|
if m not in valid_cpu_modes:
|
|
raise InvalidSpecificationException("Unknown CPU mode specifier '%s', expecting one of [%s]" %
|
|
(m, ','.join(valid_cpu_modes)))
|
|
|
|
self.Modes = modes
|
|
else:
|
|
raise InvalidSpecificationException("Unknown token specified: %s" % token)
|
|
|
|
|
|
def process_encoding(self):
|
|
"""
|
|
Extract all the encoding fields from the instruction spec, and fill in the Encoding dictionary.
|
|
Once instruction grouping has been performed, the Encoding dictionary may be left with empty values.
|
|
This function can be called an arbitrary number of times to regenerate the Encoding dictionary.
|
|
"""
|
|
# The order of the entries in Encoding does not matter. When grouping instructions, whoemever does the grouping,
|
|
# can choose whatever order they wish.
|
|
self.Encoding = {
|
|
'opcode' : [], # Opcode group
|
|
'opcode_last' : [], # Opcode group, but opcode comes after ModR/M (3DNow! instructions)
|
|
'vendor' : [], # Vendor grouping
|
|
'feature' : [], # Feature grouping; generally useful for instructions which act like NOP if feature is off
|
|
'prefix' : [], # Mandatory prefix grouping: NP, 0x66, 0xF3, 0xF2
|
|
'modrmreg' : [], # ModR/M.reg group
|
|
'modrmmod' : [], # ModR/M.mod group (mem or reg)
|
|
'modrmrm' : [], # ModR/M.rm group
|
|
'mode' : [], # Operating mode group (16, 32, 64)
|
|
'dsize' : [], # Data size group
|
|
'asize' : [], # Address size group
|
|
'auxiliary' : [], # Other grouping criteria
|
|
'mmmmm' : [], # XOP/VEX/EVEX.map
|
|
'pp' : [], # XOP/VEX/EVEX.pp, compressed prefix
|
|
'l' : [], # XOP/VEX/EVEX.l, vector length
|
|
'w' : [], # XOP/VEX/EVEX.w, width
|
|
'wi' : [], # XOP/VEX/EVEX.w, width, but ignored if outside 64-bit
|
|
'nd' : [], # EVEX.nd, new data destination
|
|
'nf' : [], # EVEX.nf, no flags
|
|
'sc' : [], # EVEX.sc, standard condition code
|
|
}
|
|
|
|
had_modrm = False
|
|
|
|
# Now parse each info chunk and extract the actual data
|
|
for t in self.RawEnc.split(' '):
|
|
if not t:
|
|
continue # Skip empty tokens
|
|
if t == 'xop':
|
|
self.Xop = True
|
|
elif t == 'vex':
|
|
self.Vex = True
|
|
elif t == 'evex':
|
|
self.Evex = True
|
|
# Mandatory prefixes.
|
|
elif t in ['NP', '0x66', '0xF3', '0xF2'] and not self.Encoding['opcode'] and not (self.Xop or self.Vex or self.Evex):
|
|
self.Encoding['prefix'].append('P' + t) # Prefix with P, so we don't confuse this with an opcode.
|
|
# Auxiliary conditions.
|
|
elif t in ['repz', 'mo64', 'rexw', 'rexb', 'rep', 'riprel', 'rex2', 'rex2w']:
|
|
self.Encoding['auxiliary'].append(t)
|
|
# Data size.
|
|
elif t in ['ds16', 'ds32', 'ds64', 'dds64', 'fds64']:
|
|
self.Encoding['dsize'].append(t)
|
|
# Address size.
|
|
elif t in ['as16', 'as32', 'as64']:
|
|
self.Encoding['asize'].append(t)
|
|
# Vendor.
|
|
elif t in ['intel', 'amd']:
|
|
self.Encoding['vendor'].append(t)
|
|
# Feature.
|
|
elif t in ['mpx', 'cet', 'cldm', 'piti']:
|
|
self.Encoding['feature'].append(t)
|
|
# ModR/M.
|
|
elif t.startswith('/'):
|
|
had_modrm = True
|
|
self.add_attribute('MODRM')
|
|
if m := re.match(r'^/r$', t):
|
|
pass
|
|
elif m := re.match(r'^/r:(reg|mem)$', t):
|
|
# Modrm mod
|
|
self.Encoding['modrmmod'].append(m[1])
|
|
elif m := re.match(r'^/([0-7])$', t):
|
|
# Modrm reg
|
|
self.Encoding['modrmreg'].append(str(m[1]))
|
|
elif m := re.match(r'^/([0-7]):(reg|mem)$', t):
|
|
# Modrm reg & mod
|
|
self.Encoding['modrmreg'].append(str(m[1]))
|
|
self.Encoding['modrmmod'].append(m[2])
|
|
# Handle opcode-like ModR/M
|
|
elif m := re.match(r'^/(0x[0-9a-fA-F]{2})$', t):
|
|
mrm = int(m[1], 16)
|
|
if 0xC0 == (mrm & 0xC0):
|
|
self.Encoding['modrmmod'].append('reg')
|
|
else:
|
|
self.Encoding['modrmmod'].append('mem')
|
|
self.Encoding['modrmrm'].append(str(mrm & 7))
|
|
self.Encoding['modrmreg'].append(str((mrm >> 3) & 7))
|
|
else:
|
|
raise InvalidSpecificationException("Invalid encoding: modrm specification is invalid: '%s'!" % t)
|
|
# Modrm.rm value.
|
|
elif m := re.match(r'^rm:([0-7])$', t):
|
|
self.Encoding['modrmrm'].append(m[1])
|
|
# Map field inside XOP/VEX/EVEX.
|
|
elif m := re.match(r'^m:([0-9A-C])$', t):
|
|
self.Encoding['mmmmm'].append(m[1])
|
|
# Compressed prefix field inside XOP/VEX/EVEX.
|
|
elif m := re.match(r'^p:([0-3])$', t):
|
|
self.Encoding['pp'].append(m[1])
|
|
# Vector length field inside XOP/VEX/EVEX.
|
|
elif m := re.match(r'^l:([x|i|0|1|2|3])$', t):
|
|
if m[1] == 'x':
|
|
pass
|
|
elif m[1] == 'i':
|
|
self.add_attribute('LIG')
|
|
else:
|
|
self.Encoding['l'].append(m[1])
|
|
# W field inside XOP/VEX/EVEX/REX2.
|
|
elif m := re.match(r'^w:(x|i|0|1)$', t):
|
|
if m[1] == 'x':
|
|
pass
|
|
elif m[1] == 'i':
|
|
self.add_attribute('WIG')
|
|
else:
|
|
if 'IWO64' in self.Attributes:
|
|
self.Encoding['wi'].append(m[1])
|
|
else:
|
|
self.Encoding['w'].append(m[1])
|
|
# New Data Destination field inside EVEX.
|
|
elif m := re.match(r'^nd:(0|1)$', t):
|
|
self.Encoding['nd'].append(m[1])
|
|
# No Flags field inside EVEX.
|
|
elif m := re.match(r'^nf:(0|1)$', t):
|
|
self.Encoding['nf'].append(m[1])
|
|
# Standard Condition Code field inside EVEX.
|
|
elif m := re.match(r'^sc:([0-9A-F]{1})$', t):
|
|
self.Encoding['sc'].append(m[1])
|
|
# Opcode.
|
|
elif re.match(r'^0x[0-9a-fA-F]{2}$', t):
|
|
if had_modrm:
|
|
self.Encoding['opcode_last'].append(t)
|
|
else:
|
|
self.Encoding['opcode'].append(t)
|
|
# Misc encoding & addressing
|
|
elif 'vsib' == t:
|
|
self.add_attribute('VSIB')
|
|
elif 'mib' == t:
|
|
self.add_attribute('MIB')
|
|
elif 'bitbase' == t:
|
|
self.add_attribute('BITBASE')
|
|
elif 'sibmem' == t:
|
|
self.add_attribute('SIBMEM')
|
|
# Misc immediates
|
|
elif t in ['ib', 'iw', 'iz', 'iv', 'id', 'cb', 'cz', 'cv', 'cp', 'cq', 'is4']:
|
|
# Not used for now, but they must be specified, for a complete instruction encoding specification.
|
|
pass
|
|
else:
|
|
raise InvalidSpecificationException(f"Invalid encoding: Unknown token: {t}")
|
|
|
|
|
|
def process_operands(self, ops, imp = False):
|
|
"""
|
|
Process the provided operands list, and generate a list of Operand objects.
|
|
"""
|
|
p, res = 1, []
|
|
for op in ops:
|
|
if op in absent_op:
|
|
break
|
|
flags = []
|
|
if not imp:
|
|
for f in self.Attributes:
|
|
if f.startswith('OP%d' % p):
|
|
flags.append('OP' + f[3:])
|
|
self.Attributes.remove(f)
|
|
else:
|
|
flags.append('OPDEF')
|
|
if not imp:
|
|
res.append(Operand(op, self.Rwm[p - 1], flags, imp))
|
|
else:
|
|
res.append(Operand(op, self.Rwm[len(self.ExpOps) + p - 1], flags, imp))
|
|
p += 1
|
|
return res
|
|
|
|
|
|
def add_attribute(self, attribute):
|
|
if attribute not in self.Attributes:
|
|
self.Attributes.append(attribute)
|
|
|
|
def __str__(self):
|
|
ops = ''
|
|
for o in self.ExpOps:
|
|
ops += o.__str__() + ','
|
|
ops = ops[:-1]
|
|
|
|
# Return a text reprezentation of the encoding
|
|
return (self.Mnemonic + ' ' + ops).strip()
|
|
|
|
|
|
def parse_entry(
|
|
entry: str
|
|
) -> Instruction:
|
|
"""
|
|
Parse one instruction specification line, and return an Instruction object.
|
|
For examples on how an entry must look, check any entry inside table_* files.
|
|
An instruction specification must contain 5 elements:
|
|
1. The mnemonic
|
|
2. The explicit operands (n/a or empty if none is present)
|
|
3. The implicit operands (n/a or empty if none is present)
|
|
4. The encoding (mandatory, cannot be empty)
|
|
5. Metadata
|
|
The instruction metadata includes several 'key:value' pairs; 'key' can be one of the following:
|
|
1. 'a': instruction attributes
|
|
2. 's': instruction set
|
|
3. 'c': instruction class
|
|
4. 'p': accepted prefixes
|
|
5. 'w': operand access map
|
|
6. 'i': CPUID feature flag; by default, the instruction set is used to look up a potential CPUID flag
|
|
7. 'l': EVEX tuple type
|
|
8. 'e': VEX/EVEX exception type
|
|
9. 'v': EVEX mode (normal EVEX, extended VEX, extended legacy, conditional)
|
|
10. 'f': flags access ('m': modified, 't': tested, 'u': undefined, '0': cleared, '1': set to 1)
|
|
11. 'u': FPU flags access
|
|
12. 'm': valid operating modes
|
|
|
|
Raises
|
|
------
|
|
InvalidSpecificationException
|
|
- If the specification is incomplete
|
|
- If an unknwon operand type or size is used
|
|
- If an invalid encoding is specified
|
|
- If an unknown metadata key is specified
|
|
- If any metadata value is invalid/unknown
|
|
|
|
Parameters
|
|
----------
|
|
entry: str
|
|
The instruction specification.
|
|
|
|
Returns
|
|
-------
|
|
An object representing the instruction.
|
|
"""
|
|
# Make sure this is not a comment. Skip comments.
|
|
if entry.startswith('#') or len(entry) < 4:
|
|
return None
|
|
|
|
# Preprocess: remove comments, CR/LF
|
|
entry = entry.replace('\x0D', '').replace('\x0A', '')
|
|
com = entry.find('#')
|
|
if -1 != com: x = entry[:com]
|
|
|
|
# Space can't be the first character.
|
|
if entry[0] == ' ':
|
|
raise InvalidSpecificationException("Space cannot be the first character!")
|
|
|
|
components = entry.split(';')
|
|
if len(components) != 5:
|
|
raise InvalidSpecificationException("Expected 5 components per line, but found %d (missing semicolon?)!" % len(components))
|
|
|
|
mnemonic = components[0].strip()
|
|
expops = components[1].strip().split(',')
|
|
impops = components[2].strip().split(',')
|
|
encoding = components[3].strip()
|
|
meta = components[4].strip().split(',')
|
|
|
|
if len(mnemonic) < 1:
|
|
raise InvalidSpecificationException("Mnemonic cannot be empty!")
|
|
|
|
if len(expops) == 1 and expops[0] in absent_op:
|
|
expops = []
|
|
|
|
if len(impops) == 1 and impops[0] in absent_op:
|
|
impops = []
|
|
|
|
return Instruction(mnemonic, expops, impops, encoding, meta)
|
|
|
|
|
|
def parse_ins_file(
|
|
fpath: str
|
|
) -> list[Instruction]:
|
|
"""
|
|
Parse an entire instruction specification file, and return a list of Instruction objects.
|
|
|
|
Parameters
|
|
----------
|
|
fpath: str
|
|
The file containing multiple instruction specifications.
|
|
|
|
Returns
|
|
-------
|
|
A list containing Instruction objects generated from the specs inside the provided file.
|
|
"""
|
|
instructions = []
|
|
lcount = 0
|
|
for line in open(fpath, 'rt'):
|
|
lcount += 1
|
|
try:
|
|
ins = parse_entry(line)
|
|
if ins: instructions.append(ins)
|
|
except Exception as e:
|
|
print('ERROR: Parsing failed at %s:%d: %s' % (fpath, lcount, e))
|
|
raise
|
|
return instructions
|
|
|
|
|
|
def parse_cff_file(
|
|
fpath: str
|
|
) -> list[CpuidFeatureFlag]:
|
|
"""
|
|
Parse the CPUID feature flags file, and return a list of CpuidFeatureFlag objects.
|
|
|
|
Parameters
|
|
----------
|
|
fpath: str
|
|
The file containing multiple CPUID feature specifications.
|
|
|
|
Returns
|
|
-------
|
|
A list containing CpuidFeatureFlag objects generated from the specs inside the provided file.
|
|
"""
|
|
global template_cpuid
|
|
features = []
|
|
for line in open(fpath, 'rt'):
|
|
if line.startswith('#'):
|
|
continue
|
|
res = re.findall(r'([^\s]+)\s+:\s+(0x[0-9a-fA-F]+),\s+(0x[0-9a-fA-F]+),\s+(EAX|ECX|EDX|EBX),\s+(\d+)', line)
|
|
if not res:
|
|
continue
|
|
res = res[0]
|
|
cffi = {}
|
|
cffi['name'] = res[0]
|
|
cffi['leaf'] = res[1]
|
|
cffi['subleaf'] = res[2]
|
|
cffi['reg'] = res[3]
|
|
cffi['bit'] = res[4]
|
|
features.append(CpuidFeatureFlag(cffi))
|
|
template_cpuid = features
|
|
return features
|
|
|
|
|
|
def parse_flags_file(
|
|
fpath: str
|
|
) -> dict:
|
|
"""
|
|
Parse the flags access file, and return a list of flags access templates.
|
|
|
|
Parameters
|
|
----------
|
|
fpath: str
|
|
The file containing multiple flags access templates.
|
|
|
|
Returns
|
|
-------
|
|
A dictionary containing all the flags access templates in the provided file.
|
|
"""
|
|
global template_flags
|
|
flags = {}
|
|
for line in open(fpath, 'rt'):
|
|
if line.startswith('#'):
|
|
continue
|
|
res = re.findall(r'([^\s]+)\s+:([^$]+)', line)
|
|
if not res:
|
|
continue
|
|
res = res[0]
|
|
flags[res[0]] = res[1].strip('\n\r ')
|
|
template_flags = flags
|
|
return flags
|
|
|
|
|
|
def parse_modess_file(
|
|
fpath: str
|
|
) -> dict:
|
|
"""
|
|
Parse the valid modes file, and return a dictionary of existing valid modes templates.
|
|
|
|
Parameters
|
|
----------
|
|
fpath: str
|
|
The file containing multiple valid modes specifications.
|
|
|
|
Returns
|
|
-------
|
|
A dictionary containing all the valid modes templates in the provided file.
|
|
"""
|
|
global template_modes
|
|
modes = {}
|
|
for line in open(fpath, 'rt'):
|
|
if line.startswith('#'):
|
|
continue
|
|
res = re.findall(r'([^\s]+)\s+:([^$]+)', line)
|
|
if not res:
|
|
continue
|
|
res = res[0]
|
|
modes[res[0]] = res[1].strip('\n\r ')
|
|
template_modes = modes
|
|
return modes
|
|
|
|
|
|
#
|
|
# =============================================================================
|
|
# Main
|
|
# =============================================================================
|
|
#
|
|
if __name__ == "__main__":
|
|
if len(sys.argv) < 2:
|
|
print('Usage: %s defs-file' % os.path.basename(sys.argv[0]))
|
|
sys.exit(-1)
|
|
|
|
# Parse the flags file.
|
|
template_flags = parse_flags_file('%s/flags.dat' % sys.argv[1])
|
|
|
|
# Parse the cpuid feature flags and extract each feature
|
|
template_cpuid = parse_cff_file('%s/cpuid.dat' % sys.argv[1])
|
|
|
|
# Parse the modes file.
|
|
template_modes = parse_modess_file('%s/modes.dat' % sys.argv[1])
|
|
|
|
# Parse the instruction file and extract the instructions
|
|
instructions = []
|
|
for fn in glob.glob('%s/table*.dat' % sys.argv[1]):
|
|
instructions += parse_ins_file(fn)
|
|
|
|
# Sort the instructions.
|
|
instructions = sorted(instructions, key = lambda x: x.Mnemonic)
|
|
for i in range(0, len(instructions)):
|
|
print(instructions[i])
|
|
|
|
features = sorted(template_cpuid, key = lambda x: x.Name)
|
|
for i in range(0, len(features)):
|
|
print(features[i])
|