#ifndef _BX_DISASM_H_ #define _BX_DISASM_H_ #include "config.h" #define BX_DECODE_MODRM(modrm_byte, mod, opcode, rm) { \ mod = (modrm_byte >> 6) & 0x03; \ opcode = (modrm_byte >> 3) & 0x07; \ rm = modrm_byte & 0x07; \ } #define BX_DECODE_SIB(sib_byte, scale, index, base) { \ scale = sib_byte >> 6; \ index = (sib_byte >> 3) & 0x07; \ base = sib_byte & 0x07; \ } // will be used in future #define IA_8086 0x00000000 /* 8086 instruction */ #define IA_286 0x00000000 /* 286+ instruction */ #define IA_386 0x00000000 /* 386+ instruction */ #define IA_FPU 0x00000000 #define IA_486 0x00000000 /* 486+ instruction */ #define IA_PENTIUM 0x00000000 /* Pentium instruction */ #define IA_P6 0x00000000 /* P6 instruction */ #define IA_KATMAI 0x00000000 /* Katmai instruction */ #define IA_WILLAMETTE 0x00000000 /* Willamette instruction */ #define IA_PRESCOTT 0x00000000 /* Prescott instruction */ #define IA_X86_64 0x00000000 /* x86-64 specific instruction */ #define IF_ARITHMETIC 0x00000000 /* arithmetic instruction */ #define IF_LOGIC 0x00000000 /* logic instruction */ #define IF_SYSTEM 0x00000000 /* system instruction (require CPL=0) */ #define IF_BRANCH 0x00000000 /* branch instruction */ #define IF_FPU 0x00000000 /* FPU instruction */ #define IF_MMX 0x00000000 /* MMX instruction */ #define IF_3DNOW 0x00000000 /* 3DNow! instruction */ #define IF_KNI 0x00000000 /* Katmai new instruction */ #define IF_PREFETCH 0x00000000 /* Prefetch instruction */ #define IF_SSE 0x00000000 /* SSE instruction */ #define IF_SSE2 0x00000000 /* SSE2 instruction */ #define IF_PNI 0x00000000 /* Prescott new instruction */ /* general purpose bit register */ enum { rAX_REG, rCX_REG, rDX_REG, rBX_REG, rSP_REG, rBP_REG, rSI_REG, rDI_REG }; /* segment register */ enum { ES_REG, CS_REG, SS_REG, DS_REG, FS_REG, GS_REG, INVALID_SEG1, INVALID_SEG2 }; class disassembler; struct x86_insn; typedef void (disassembler::*BxDisasmPtr_t)(const x86_insn *insn); typedef void (disassembler::*BxDisasmResolveModrmPtr_t)(const x86_insn *insn, unsigned attr); struct BxDisasmOpcodeInfo_t { const char *IntelOpcode; const char *AttOpcode; BxDisasmPtr_t Operand1; BxDisasmPtr_t Operand2; BxDisasmPtr_t Operand3; }; struct BxDisasmOpcodeTable_t { Bit32u Attr; const void *OpcodeInfo; }; // segment override not used #define NO_SEG_OVERRIDE 0xFF // datasize attributes #define X_SIZE 0x0000 #define B_SIZE 0x0100 #define W_SIZE 0x0200 #define D_SIZE 0x0300 #define Q_SIZE 0x0400 #define Z_SIZE 0x0500 #define V_SIZE 0x0600 #define O_SIZE 0x0700 #define T_SIZE 0x0800 #define P_SIZE 0x0900 // branch hint attribute #define BRANCH_HINT 0x1000 struct x86_insn { public: x86_insn(bx_bool is32, bx_bool is64); bx_bool is_seg_override() const { return (seg_override != NO_SEG_OVERRIDE); } public: bx_bool is_32, is_64; bx_bool as_32, as_64; bx_bool os_32, os_64; Bit8u extend8b; Bit8u rex_r, rex_x, rex_b; Bit8u seg_override; unsigned b1, prefixes; unsigned ilen; Bit8u modrm, mod, nnn, rm; Bit8u sib, scale, index, base; union { Bit16u displ16; Bit32u displ32; } displacement; }; BX_CPP_INLINE x86_insn::x86_insn(bx_bool is32, bx_bool is64) { is_32 = is32; is_64 = is64; if (is_64) { os_64 = 0; as_64 = 1; os_32 = 1; as_32 = 1; } else { os_64 = 0; as_64 = 0; os_32 = is_32; as_32 = is_32; } extend8b = 0; rex_r = rex_b = rex_x = 0; seg_override = NO_SEG_OVERRIDE; prefixes = 0; ilen = 0; b1 = 0; modrm = mod = nnn = rm = 0; sib = scale = index = base = 0; displacement.displ32 = 0; } class disassembler { public: disassembler() { set_syntax_intel(); } unsigned disasm(bx_bool is_32, bx_bool is_64, bx_address base, bx_address ip, const Bit8u *instr, char *disbuf); unsigned disasm16(bx_address base, bx_address ip, const Bit8u *instr, char *disbuf) { return disasm(0, 0, base, ip, instr, disbuf); } unsigned disasm32(bx_address base, bx_address ip, const Bit8u *instr, char *disbuf) { return disasm(1, 0, base, ip, instr, disbuf); } unsigned disasm64(bx_address base, bx_address ip, const Bit8u *instr, char *disbuf) { return disasm(1, 1, base, ip, instr, disbuf); } x86_insn decode(bx_bool is_32, bx_bool is_64, bx_address base, bx_address ip, const Bit8u *instr, char *disbuf); x86_insn decode16(bx_address base, bx_address ip, const Bit8u *instr, char *disbuf) { return decode(0, 0, base, ip, instr, disbuf); } x86_insn decode32(bx_address base, bx_address ip, const Bit8u *instr, char *disbuf) { return decode(1, 0, base, ip, instr, disbuf); } x86_insn decode64(bx_address base, bx_address ip, const Bit8u *instr, char *disbuf) { return decode(1, 1, base, ip, instr, disbuf); } void set_syntax_intel(); void set_syntax_att (); void toggle_syntax_mode(); private: bx_bool intel_mode; const char **general_16bit_regname; const char **general_8bit_regname; const char **general_32bit_regname; const char **general_8bit_regname_rex; const char **general_64bit_regname; const char **segment_name; const char **index16; const char *sreg_mod01or10_rm32[8]; const char *sreg_mod00_base32[8]; const char *sreg_mod01or10_base32[8]; const char *sreg_mod00_rm16[8]; const char *sreg_mod01or10_rm16[8]; private: bx_address db_eip, db_base; const Bit8u *instruction; // for fetching of next byte of instruction char *disbufptr; BxDisasmResolveModrmPtr_t resolve_modrm; BX_CPP_INLINE Bit8u fetch_byte() { db_eip++; return(*instruction++); }; BX_CPP_INLINE Bit8u peek_byte() { return(*instruction); }; BX_CPP_INLINE Bit16u fetch_word() { Bit8u b0 = * (Bit8u *) instruction++; Bit8u b1 = * (Bit8u *) instruction++; Bit16u ret16 = (b1<<8) | b0; db_eip += 2; return(ret16); }; BX_CPP_INLINE Bit32u fetch_dword() { Bit8u b0 = * (Bit8u *) instruction++; Bit8u b1 = * (Bit8u *) instruction++; Bit8u b2 = * (Bit8u *) instruction++; Bit8u b3 = * (Bit8u *) instruction++; Bit32u ret32 = (b3<<24) | (b2<<16) | (b1<<8) | b0; db_eip += 4; return(ret32); }; BX_CPP_INLINE Bit64u fetch_qword() { Bit64u d0 = fetch_dword(); Bit64u d1 = fetch_dword(); Bit64u ret64 = (d1<<32) | d0; return(ret64); }; void dis_putc(char symbol); void dis_sprintf(char *fmt, ...); void decode_modrm(x86_insn *insn); void resolve16_mod0 (const x86_insn *insn, unsigned mode); void resolve16_mod1or2(const x86_insn *insn, unsigned mode); void resolve32_mod0 (const x86_insn *insn, unsigned mode); void resolve32_mod1or2(const x86_insn *insn, unsigned mode); void resolve32_mod0_rm4 (const x86_insn *insn, unsigned mode); void resolve32_mod1or2_rm4(const x86_insn *insn, unsigned mode); void resolve64_mod0 (const x86_insn *insn, unsigned mode); void resolve64_mod1or2(const x86_insn *insn, unsigned mode); void resolve64_mod0_rm4 (const x86_insn *insn, unsigned mode); void resolve64_mod1or2_rm4(const x86_insn *insn, unsigned mode); void initialize_modrm_segregs(); void print_datasize (unsigned mode); void print_memory_access16(int datasize, const char *seg, const char *index, Bit16u disp); void print_memory_access (int datasize, const char *seg, const char *base, const char *index, int scale, Bit32u disp); void print_disassembly_intel(const x86_insn *insn, const BxDisasmOpcodeInfo_t *entry); void print_disassembly_att (const x86_insn *insn, const BxDisasmOpcodeInfo_t *entry); public: /* * Codes for Addressing Method: * --------------------------- * A - Direct address. The instruction has no ModR/M byte; the address * of the operand is encoded in the instruction; and no base register, * index register, or scaling factor can be applied. * C - The reg field of the ModR/M byte selects a control register. * D - The reg field of the ModR/M byte selects a debug register. * E - A ModR/M byte follows the opcode and specifies the operand. The * operand is either a general-purpose register or a memory address. * If it is a memory address, the address is computed from a segment * register and any of the following values: a base register, an * index register, a scaling factor, a displacement. * F - Flags Register. * G - The reg field of the ModR/M byte selects a general register. * I - Immediate data. The operand value is encoded in subsequent bytes of * the instruction. * J - The instruction contains a relative offset to be added to the * instruction pointer register. * M - The ModR/M byte may refer only to memory. * O - The instruction has no ModR/M byte; the offset of the operand is * coded as a word or double word (depending on address size attribute) * in the instruction. No base register, index register, or scaling * factor can be applied. * P - The reg field of the ModR/M byte selects a packed quadword MMX * technology register. * Q - A ModR/M byte follows the opcode and specifies the operand. The * operand is either an MMX technology register or a memory address. * If it is a memory address, the address is computed from a segment * register and any of the following values: a base register, an * index register, a scaling factor, and a displacement. * R - The mod field of the ModR/M byte may refer only to a general register. * S - The reg field of the ModR/M byte selects a segment register. * T - The reg field of the ModR/M byte selects a test register. * V - The reg field of the ModR/M byte selects a 128-bit XMM register. * W - A ModR/M byte follows the opcode and specifies the operand. The * operand is either a 128-bit XMM register or a memory address. If * it is a memory address, the address is computed from a segment * register and any of the following values: a base register, an * index register, a scaling factor, and a displacement. * X - Memory addressed by the DS:rSI register pair. * Y - Memory addressed by the ES:rDI register pair. */ /* * Codes for Operand Type: * ---------------------- * a - Two one-word operands in memory or two double-word operands in * memory, depending on operand-size attribute (used only by the BOUND * instruction). * b - Byte, regardless of operand-size attribute. * d - Doubleword, regardless of operand-size attribute. * dq - Double-quadword, regardless of operand-size attribute. * p - 32-bit or 48-bit pointer, depending on operand-size attribute. * pd - 128-bit packed double-precision floating-point data. * pi - Quadword MMX technology register (packed integer) * ps - 128-bit packed single-precision floating-point data. * q - Quadword, regardless of operand-size attribute. * s - 6-byte or 10-byte pseudo-descriptor. * si - Doubleword integer register (scalar integer) * ss - Scalar element of a 128-bit packed single-precision floating data. * sd - Scalar element of a 128-bit packed double-precision floating data. * v - Word, doubleword or quadword, depending on operand-size attribute. * w - Word, regardless of operand-size attr. */ // far call/jmp void Apw(const x86_insn *insn); void Apd(const x86_insn *insn); // 8-bit general purpose registers void AL(const x86_insn *insn); void CL(const x86_insn *insn); // 16-bit general purpose registers void AX(const x86_insn *insn); void DX(const x86_insn *insn); // 32-bit general purpose registers void EAX(const x86_insn *insn); // 64-bit general purpose registers void RAX(const x86_insn *insn); // segment registers void CS(const x86_insn *insn); void DS(const x86_insn *insn); void ES(const x86_insn *insn); void SS(const x86_insn *insn); void FS(const x86_insn *insn); void GS(const x86_insn *insn); // segment registers void Sw(const x86_insn *insn); // test registers void Td(const x86_insn *insn); // control register void Cd(const x86_insn *insn); void Cq(const x86_insn *insn); // debug register void Dd(const x86_insn *insn); void Dq(const x86_insn *insn); // 8-bit general purpose register void R8(const x86_insn *insn); // 16-bit general purpose register void RX(const x86_insn *insn); // 32-bit general purpose register void ERX(const x86_insn *insn); // 64-bit general purpose register void RRX(const x86_insn *insn); // general purpose register or memory operand void Eb(const x86_insn *insn); void Ew(const x86_insn *insn); void Ed(const x86_insn *insn); void Eq(const x86_insn *insn); // general purpose register void Gb(const x86_insn *insn); void Gw(const x86_insn *insn); void Gd(const x86_insn *insn); void Gq(const x86_insn *insn); // immediate void I1(const x86_insn *insn); void Ib(const x86_insn *insn); void Iw(const x86_insn *insn); void Id(const x86_insn *insn); void Iq(const x86_insn *insn); // sign extended immediate void sIbw(const x86_insn *insn); void sIbd(const x86_insn *insn); void sIbq(const x86_insn *insn); void sIdq(const x86_insn *insn); // floating point void ST0(const x86_insn *insn); void STi(const x86_insn *insn); // general purpose register void Rw(const x86_insn *insn); void Rd(const x86_insn *insn); void Rq(const x86_insn *insn); // mmx register void Pq(const x86_insn *insn); // mmx register or memory operand void Qd(const x86_insn *insn); void Qq(const x86_insn *insn); void Vq(const x86_insn *insn); // xmm register void Vdq(const x86_insn *insn); void Vss(const x86_insn *insn); void Vsd(const x86_insn *insn); void Vps(const x86_insn *insn); void Vpd(const x86_insn *insn); // xmm register or memory operand void Wq(const x86_insn *insn); void Wdq(const x86_insn *insn); void Wss(const x86_insn *insn); void Wsd(const x86_insn *insn); void Wps(const x86_insn *insn); void Wpd(const x86_insn *insn); // direct memory access void OP_O(const x86_insn *insn, unsigned size); void Ob(const x86_insn *insn); void Ow(const x86_insn *insn); void Od(const x86_insn *insn); void Oq(const x86_insn *insn); // memory operand void OP_M(const x86_insn *insn, unsigned size); void Ma(const x86_insn *insn); void Mp(const x86_insn *insn); void Ms(const x86_insn *insn); void Mx(const x86_insn *insn); void Mb(const x86_insn *insn); void Mw(const x86_insn *insn); void Md(const x86_insn *insn); void Mq(const x86_insn *insn); void Mt(const x86_insn *insn); void Mdq(const x86_insn *insn); void Mps(const x86_insn *insn); void Mpd(const x86_insn *insn); // string instructions void OP_X(const x86_insn *insn, unsigned size); void Xb(const x86_insn *insn); void Xw(const x86_insn *insn); void Xd(const x86_insn *insn); void Xq(const x86_insn *insn); // string instructions void OP_Y(const x86_insn *insn, unsigned size); void Yb(const x86_insn *insn); void Yw(const x86_insn *insn); void Yd(const x86_insn *insn); void Yq(const x86_insn *insn); // jump offset void Jb(const x86_insn *insn); void Jw(const x86_insn *insn); void Jd(const x86_insn *insn); }; #endif