mirror of
https://github.com/CrazyRedMachine/popnhax.git
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837 lines
35 KiB
C
837 lines
35 KiB
C
#ifndef LIBDISASM_H
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#define LIBDISASM_H
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#ifdef WIN32
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#include <windows.h>
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#endif
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#include <stdint.h>
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/* 'NEW" types
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* __________________________________________________________________________*/
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#ifndef LIBDISASM_QWORD_H /* do not interfere with qword.h */
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#define LIBDISASM_QWORD_H
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#ifdef _MSC_VER
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typedef __int64 qword_t;
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#else
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typedef int64_t qword_t;
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#endif
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#endif
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#include <sys/types.h>
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#ifdef __cplusplus
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extern "C" {
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#endif
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/* 'NEW" x86 API
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* __________________________________________________________________________*/
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/* ========================================= Error Reporting */
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/* REPORT CODES
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* These are passed to a reporter function passed at initialization.
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* Each code determines the type of the argument passed to the reporter;
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* this allows the report to recover from errors, or just log them.
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*/
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enum x86_report_codes {
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report_disasm_bounds, /* RVA OUT OF BOUNDS : The disassembler could
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not disassemble the supplied RVA as it is
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out of the range of the buffer. The
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application should store the address and
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attempt to determine what section of the
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binary it is in, then disassemble the
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address from the bytes in that section.
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data: uint32_t rva */
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report_insn_bounds, /* INSTRUCTION OUT OF BOUNDS: The disassembler
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could not disassemble the instruction as
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the instruction would require bytes beyond
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the end of the current buffer. This usually
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indicated garbage bytes at the end of a
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buffer, or an incorrectly-sized buffer.
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data: uint32_t rva */
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report_invalid_insn, /* INVALID INSTRUCTION: The disassembler could
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not disassemble the instruction as it has an
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invalid combination of opcodes and operands.
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This will stop automated disassembly; the
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application can restart the disassembly
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after the invalid instruction.
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data: uint32_t rva */
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report_unknown
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};
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/* 'arg' is optional arbitrary data provided by the code passing the
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* callback -- for example, it could be 'this' or 'self' in OOP code.
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* 'code' is provided by libdisasm, it is one of the above
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* 'data' is provided by libdisasm and is context-specific, per the enums */
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typedef void (*DISASM_REPORTER)( enum x86_report_codes code,
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void *data, void *arg );
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/* x86_report_error : Call the register reporter to report an error */
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void x86_report_error( enum x86_report_codes code, void *data );
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/* ========================================= Libdisasm Management Routines */
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enum x86_options { /* these can be ORed together */
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opt_none= 0,
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opt_ignore_nulls=1, /* ignore sequences of > 4 NULL bytes */
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opt_16_bit=2, /* 16-bit/DOS disassembly */
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opt_att_mnemonics=4, /* use AT&T syntax names for alternate opcode mnemonics */
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};
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/* management routines */
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/* 'arg' is caller-specific data which is passed as the first argument
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* to the reporter callback routine */
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int x86_init( enum x86_options options, DISASM_REPORTER reporter, void *arg);
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void x86_set_reporter( DISASM_REPORTER reporter, void *arg);
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void x86_set_options( enum x86_options options );
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enum x86_options x86_get_options( void );
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int x86_cleanup(void);
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/* ========================================= Instruction Representation */
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/* these defines are only intended for use in the array decl's */
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#define MAX_REGNAME 8
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#define MAX_PREFIX_STR 32
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#define MAX_MNEM_STR 16
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#define MAX_INSN_SIZE 20 /* same as in i386.h */
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#define MAX_OP_STRING 32 /* max possible operand size in string form */
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#define MAX_OP_RAW_STRING 64 /* max possible operand size in raw form */
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#define MAX_OP_XML_STRING 256 /* max possible operand size in xml form */
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#define MAX_NUM_OPERANDS 8 /* max # implicit and explicit operands */
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/* in these, the '2 *' is arbitrary: the max # of operands should require
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* more space than the rest of the insn */
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#define MAX_INSN_STRING 512 /* 2 * 8 * MAX_OP_STRING */
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#define MAX_INSN_RAW_STRING 1024 /* 2 * 8 * MAX_OP_RAW_STRING */
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#define MAX_INSN_XML_STRING 4096 /* 2 * 8 * MAX_OP_XML_STRING */
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enum x86_reg_type { /* NOTE: these may be ORed together */
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reg_gen = 0x00001, /* general purpose */
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reg_in = 0x00002, /* incoming args, ala RISC */
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reg_out = 0x00004, /* args to calls, ala RISC */
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reg_local = 0x00008, /* local vars, ala RISC */
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reg_fpu = 0x00010, /* FPU data register */
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reg_seg = 0x00020, /* segment register */
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reg_simd = 0x00040, /* SIMD/MMX reg */
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reg_sys = 0x00080, /* restricted/system register */
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reg_sp = 0x00100, /* stack pointer */
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reg_fp = 0x00200, /* frame pointer */
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reg_pc = 0x00400, /* program counter */
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reg_retaddr = 0x00800, /* return addr for func */
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reg_cond = 0x01000, /* condition code / flags */
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reg_zero = 0x02000, /* zero register, ala RISC */
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reg_ret = 0x04000, /* return value */
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reg_src = 0x10000, /* array/rep source */
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reg_dest = 0x20000, /* array/rep destination */
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reg_count = 0x40000 /* array/rep/loop counter */
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};
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/* x86_reg_t : an X86 CPU register */
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typedef struct {
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char name[MAX_REGNAME];
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enum x86_reg_type type; /* what register is used for */
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unsigned int size; /* size of register in bytes */
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unsigned int id; /* register ID #, for quick compares */
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unsigned int alias; /* ID of reg this is an alias for */
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unsigned int shift; /* amount to shift aliased reg by */
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} x86_reg_t;
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/* x86_ea_t : an X86 effective address (address expression) */
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typedef struct {
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unsigned int scale; /* scale factor */
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x86_reg_t index, base; /* index, base registers */
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int32_t disp; /* displacement */
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char disp_sign; /* is negative? 1/0 */
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char disp_size; /* 0, 1, 2, 4 */
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} x86_ea_t;
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/* x86_absolute_t : an X86 segment:offset address (descriptor) */
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typedef struct {
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unsigned short segment; /* loaded directly into CS */
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union {
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unsigned short off16; /* loaded directly into IP */
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uint32_t off32; /* loaded directly into EIP */
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} offset;
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} x86_absolute_t;
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enum x86_op_type { /* mutually exclusive */
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op_unused = 0, /* empty/unused operand: should never occur */
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op_register = 1, /* CPU register */
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op_immediate = 2, /* Immediate Value */
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op_relative_near = 3, /* Relative offset from IP */
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op_relative_far = 4, /* Relative offset from IP */
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op_absolute = 5, /* Absolute address (ptr16:32) */
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op_expression = 6, /* Address expression (scale/index/base/disp) */
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op_offset = 7, /* Offset from start of segment (m32) */
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op_unknown
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};
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#define x86_optype_is_address( optype ) \
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( optype == op_absolute || optype == op_offset )
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#define x86_optype_is_relative( optype ) \
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( optype == op_relative_near || optype == op_relative_far )
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#define x86_optype_is_memory( optype ) \
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( optype > op_immediate && optype < op_unknown )
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enum x86_op_datatype { /* these use Intel's lame terminology */
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op_byte = 1, /* 1 byte integer */
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op_word = 2, /* 2 byte integer */
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op_dword = 3, /* 4 byte integer */
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op_qword = 4, /* 8 byte integer */
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op_dqword = 5, /* 16 byte integer */
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op_sreal = 6, /* 4 byte real (single real) */
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op_dreal = 7, /* 8 byte real (double real) */
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op_extreal = 8, /* 10 byte real (extended real) */
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op_bcd = 9, /* 10 byte binary-coded decimal */
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op_ssimd = 10, /* 16 byte : 4 packed single FP (SIMD, MMX) */
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op_dsimd = 11, /* 16 byte : 2 packed double FP (SIMD, MMX) */
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op_sssimd = 12, /* 4 byte : scalar single FP (SIMD, MMX) */
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op_sdsimd = 13, /* 8 byte : scalar double FP (SIMD, MMX) */
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op_descr32 = 14, /* 6 byte Intel descriptor 2:4 */
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op_descr16 = 15, /* 4 byte Intel descriptor 2:2 */
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op_pdescr32 = 16, /* 6 byte Intel pseudo-descriptor 32:16 */
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op_pdescr16 = 17, /* 6 byte Intel pseudo-descriptor 8:24:16 */
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op_bounds16 = 18, /* signed 16:16 lower:upper bounds */
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op_bounds32 = 19, /* signed 32:32 lower:upper bounds */
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op_fpuenv16 = 20, /* 14 byte FPU control/environment data */
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op_fpuenv32 = 21, /* 28 byte FPU control/environment data */
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op_fpustate16 = 22, /* 94 byte FPU state (env & reg stack) */
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op_fpustate32 = 23, /* 108 byte FPU state (env & reg stack) */
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op_fpregset = 24, /* 512 bytes: register set */
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op_fpreg = 25, /* FPU register */
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op_none = 0xFF, /* operand without a datatype (INVLPG) */
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};
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enum x86_op_access { /* ORed together */
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op_read = 1,
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op_write = 2,
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op_execute = 4
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};
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enum x86_op_flags { /* ORed together, but segs are mutually exclusive */
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op_signed = 1, /* signed integer */
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op_string = 2, /* possible string or array */
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op_constant = 4, /* symbolic constant */
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op_pointer = 8, /* operand points to a memory address */
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op_sysref = 0x010, /* operand is a syscall number */
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op_implied = 0x020, /* operand is implicit in the insn */
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op_hardcode = 0x40, /* operand is hardcoded in insn definition */
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/* NOTE: an 'implied' operand is one which can be considered a side
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* effect of the insn, e.g. %esp being modified by PUSH or POP. A
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* 'hard-coded' operand is one which is specified in the instruction
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* definition, e.g. %es:%edi in MOVSB or 1 in ROL Eb, 1. The difference
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* is that hard-coded operands are printed by disassemblers and are
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* required to re-assemble, while implicit operands are invisible. */
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op_es_seg = 0x100, /* ES segment override */
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op_cs_seg = 0x200, /* CS segment override */
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op_ss_seg = 0x300, /* SS segment override */
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op_ds_seg = 0x400, /* DS segment override */
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op_fs_seg = 0x500, /* FS segment override */
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op_gs_seg = 0x600 /* GS segment override */
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};
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/* x86_op_t : an X86 instruction operand */
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typedef struct {
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enum x86_op_type type; /* operand type */
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enum x86_op_datatype datatype; /* operand size */
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enum x86_op_access access; /* operand access [RWX] */
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enum x86_op_flags flags; /* misc flags */
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union {
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/* sizeof will have to work on these union members! */
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/* immediate values */
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char sbyte;
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short sword;
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int32_t sdword;
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qword_t sqword;
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unsigned char byte;
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unsigned short word;
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uint32_t dword;
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qword_t qword;
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float sreal;
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double dreal;
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/* misc large/non-native types */
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unsigned char extreal[10];
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unsigned char bcd[10];
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qword_t dqword[2];
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unsigned char simd[16];
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unsigned char fpuenv[28];
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/* offset from segment */
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uint32_t offset;
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/* ID of CPU register */
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x86_reg_t reg;
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/* offsets from current insn */
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char relative_near;
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int32_t relative_far;
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/* segment:offset */
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x86_absolute_t absolute;
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/* effective address [expression] */
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x86_ea_t expression;
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} data;
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/* this is needed to make formatting operands more sane */
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void * insn; /* pointer to x86_insn_t owning operand */
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} x86_op_t;
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/* Linked list of x86_op_t; provided for manual traversal of the operand
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* list in an insn. Users wishing to add operands to this list, e.g. to add
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* implicit operands, should use x86_operand_new in x86_operand_list.h */
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typedef struct x86_operand_list {
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x86_op_t op;
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struct x86_operand_list *next;
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} x86_oplist_t;
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enum x86_insn_group {
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insn_none = 0, /* invalid instruction */
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insn_controlflow = 1,
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insn_arithmetic = 2,
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insn_logic = 3,
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insn_stack = 4,
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insn_comparison = 5,
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insn_move = 6,
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insn_string = 7,
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insn_bit_manip = 8,
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insn_flag_manip = 9,
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insn_fpu = 10,
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insn_interrupt = 13,
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insn_system = 14,
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insn_other = 15
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};
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enum x86_insn_type {
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insn_invalid = 0, /* invalid instruction */
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/* insn_controlflow */
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insn_jmp = 0x1001,
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insn_jcc = 0x1002,
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insn_call = 0x1003,
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insn_callcc = 0x1004,
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insn_return = 0x1005,
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/* insn_arithmetic */
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insn_add = 0x2001,
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insn_sub = 0x2002,
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insn_mul = 0x2003,
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insn_div = 0x2004,
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insn_inc = 0x2005,
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insn_dec = 0x2006,
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insn_shl = 0x2007,
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insn_shr = 0x2008,
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insn_rol = 0x2009,
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insn_ror = 0x200A,
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/* insn_logic */
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insn_and = 0x3001,
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insn_or = 0x3002,
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insn_xor = 0x3003,
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insn_not = 0x3004,
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insn_neg = 0x3005,
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/* insn_stack */
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insn_push = 0x4001,
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insn_pop = 0x4002,
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insn_pushregs = 0x4003,
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insn_popregs = 0x4004,
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insn_pushflags = 0x4005,
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insn_popflags = 0x4006,
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insn_enter = 0x4007,
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insn_leave = 0x4008,
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/* insn_comparison */
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insn_test = 0x5001,
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insn_cmp = 0x5002,
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/* insn_move */
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insn_mov = 0x6001, /* move */
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insn_movcc = 0x6002, /* conditional move */
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insn_xchg = 0x6003, /* exchange */
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insn_xchgcc = 0x6004, /* conditional exchange */
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/* insn_string */
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insn_strcmp = 0x7001,
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insn_strload = 0x7002,
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insn_strmov = 0x7003,
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insn_strstore = 0x7004,
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insn_translate = 0x7005, /* xlat */
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/* insn_bit_manip */
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insn_bittest = 0x8001,
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insn_bitset = 0x8002,
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insn_bitclear = 0x8003,
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/* insn_flag_manip */
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insn_clear_carry = 0x9001,
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insn_clear_zero = 0x9002,
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insn_clear_oflow = 0x9003,
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insn_clear_dir = 0x9004,
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insn_clear_sign = 0x9005,
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insn_clear_parity = 0x9006,
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insn_set_carry = 0x9007,
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insn_set_zero = 0x9008,
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insn_set_oflow = 0x9009,
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insn_set_dir = 0x900A,
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insn_set_sign = 0x900B,
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insn_set_parity = 0x900C,
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insn_tog_carry = 0x9010,
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insn_tog_zero = 0x9020,
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insn_tog_oflow = 0x9030,
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insn_tog_dir = 0x9040,
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insn_tog_sign = 0x9050,
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insn_tog_parity = 0x9060,
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/* insn_fpu */
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insn_fmov = 0xA001,
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insn_fmovcc = 0xA002,
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insn_fneg = 0xA003,
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insn_fabs = 0xA004,
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insn_fadd = 0xA005,
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insn_fsub = 0xA006,
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insn_fmul = 0xA007,
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insn_fdiv = 0xA008,
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insn_fsqrt = 0xA009,
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insn_fcmp = 0xA00A,
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insn_fcos = 0xA00C,
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insn_fldpi = 0xA00D,
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insn_fldz = 0xA00E,
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insn_ftan = 0xA00F,
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insn_fsine = 0xA010,
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insn_fsys = 0xA020,
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/* insn_interrupt */
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insn_int = 0xD001,
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insn_intcc = 0xD002, /* not present in x86 ISA */
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insn_iret = 0xD003,
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insn_bound = 0xD004,
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insn_debug = 0xD005,
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insn_trace = 0xD006,
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insn_invalid_op = 0xD007,
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insn_oflow = 0xD008,
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/* insn_system */
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insn_halt = 0xE001,
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insn_in = 0xE002, /* input from port/bus */
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insn_out = 0xE003, /* output to port/bus */
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insn_cpuid = 0xE004,
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/* insn_other */
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insn_nop = 0xF001,
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insn_bcdconv = 0xF002, /* convert to or from BCD */
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insn_szconv = 0xF003 /* change size of operand */
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};
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/* These flags specify special characteristics of the instruction, such as
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* whether the inatruction is privileged or whether it serializes the
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* pipeline.
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* NOTE : These may not be accurate for all instructions; updates to the
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* opcode tables have not been completed. */
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enum x86_insn_note {
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insn_note_ring0 = 1, /* Only available in ring 0 */
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insn_note_smm = 2, /* "" in System Management Mode */
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insn_note_serial = 4, /* Serializing instruction */
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insn_note_nonswap = 8, /* Does not swap arguments in att-style formatting */
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insn_note_nosuffix = 16, /* Does not have size suffix in att-style formatting */
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};
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/* This specifies what effects the instruction has on the %eflags register */
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enum x86_flag_status {
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insn_carry_set = 0x1, /* CF */
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insn_zero_set = 0x2, /* ZF */
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insn_oflow_set = 0x4, /* OF */
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insn_dir_set = 0x8, /* DF */
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insn_sign_set = 0x10, /* SF */
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insn_parity_set = 0x20, /* PF */
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insn_carry_or_zero_set = 0x40,
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insn_zero_set_or_sign_ne_oflow = 0x80,
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insn_carry_clear = 0x100,
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insn_zero_clear = 0x200,
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insn_oflow_clear = 0x400,
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insn_dir_clear = 0x800,
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insn_sign_clear = 0x1000,
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insn_parity_clear = 0x2000,
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insn_sign_eq_oflow = 0x4000,
|
|
insn_sign_ne_oflow = 0x8000
|
|
};
|
|
|
|
/* The CPU model in which the insturction first appeared; this can be used
|
|
* to mask out instructions appearing in earlier or later models or to
|
|
* check the portability of a binary.
|
|
* NOTE : These may not be accurate for all instructions; updates to the
|
|
* opcode tables have not been completed. */
|
|
enum x86_insn_cpu {
|
|
cpu_8086 = 1, /* Intel */
|
|
cpu_80286 = 2,
|
|
cpu_80386 = 3,
|
|
cpu_80387 = 4,
|
|
cpu_80486 = 5,
|
|
cpu_pentium = 6,
|
|
cpu_pentiumpro = 7,
|
|
cpu_pentium2 = 8,
|
|
cpu_pentium3 = 9,
|
|
cpu_pentium4 = 10,
|
|
cpu_k6 = 16, /* AMD */
|
|
cpu_k7 = 32,
|
|
cpu_athlon = 48
|
|
};
|
|
|
|
/* CPU ISA subsets: These are derived from the Instruction Groups in
|
|
* Intel Vol 1 Chapter 5; they represent subsets of the IA32 ISA but
|
|
* do not reflect the 'type' of the instruction in the same way that
|
|
* x86_insn_group does. In short, these are AMD/Intel's somewhat useless
|
|
* designations.
|
|
* NOTE : These may not be accurate for all instructions; updates to the
|
|
* opcode tables have not been completed. */
|
|
enum x86_insn_isa {
|
|
isa_gp = 1, /* general purpose */
|
|
isa_fp = 2, /* floating point */
|
|
isa_fpumgt = 3, /* FPU/SIMD management */
|
|
isa_mmx = 4, /* Intel MMX */
|
|
isa_sse1 = 5, /* Intel SSE SIMD */
|
|
isa_sse2 = 6, /* Intel SSE2 SIMD */
|
|
isa_sse3 = 7, /* Intel SSE3 SIMD */
|
|
isa_3dnow = 8, /* AMD 3DNow! SIMD */
|
|
isa_sys = 9 /* system instructions */
|
|
};
|
|
|
|
enum x86_insn_prefix {
|
|
insn_no_prefix = 0,
|
|
insn_rep_zero = 1, /* REPZ and REPE */
|
|
insn_rep_notzero = 2, /* REPNZ and REPNZ */
|
|
insn_lock = 4 /* LOCK: */
|
|
};
|
|
|
|
/* TODO: maybe provide insn_new/free(), and have disasm return new insn_t */
|
|
/* x86_insn_t : an X86 instruction */
|
|
typedef struct {
|
|
/* information about the instruction */
|
|
uint32_t addr; /* load address */
|
|
uint32_t offset; /* offset into file/buffer */
|
|
enum x86_insn_group group; /* meta-type, e.g. INS_EXEC */
|
|
enum x86_insn_type type; /* type, e.g. INS_BRANCH */
|
|
enum x86_insn_note note; /* note, e.g. RING0 */
|
|
unsigned char bytes[MAX_INSN_SIZE];
|
|
unsigned char size; /* size of insn in bytes */
|
|
/* 16/32-bit mode settings */
|
|
unsigned char addr_size; /* default address size : 2 or 4 */
|
|
unsigned char op_size; /* default operand size : 2 or 4 */
|
|
/* CPU/instruction set */
|
|
enum x86_insn_cpu cpu;
|
|
enum x86_insn_isa isa;
|
|
/* flags */
|
|
enum x86_flag_status flags_set; /* flags set or tested by insn */
|
|
enum x86_flag_status flags_tested;
|
|
/* stack */
|
|
unsigned char stack_mod; /* 0 or 1 : is the stack modified? */
|
|
int32_t stack_mod_val; /* val stack is modified by if known */
|
|
|
|
/* the instruction proper */
|
|
enum x86_insn_prefix prefix; /* prefixes ORed together */
|
|
char prefix_string[MAX_PREFIX_STR]; /* prefixes [might be truncated] */
|
|
char mnemonic[MAX_MNEM_STR];
|
|
x86_oplist_t *operands; /* list of explicit/implicit operands */
|
|
size_t operand_count; /* total number of operands */
|
|
size_t explicit_count; /* number of explicit operands */
|
|
/* convenience fields for user */
|
|
void *block; /* code block containing this insn */
|
|
void *function; /* function containing this insn */
|
|
int tag; /* tag the insn as seen/processed */
|
|
} x86_insn_t;
|
|
|
|
|
|
/* returns 0 if an instruction is invalid, 1 if valid */
|
|
int x86_insn_is_valid( x86_insn_t *insn );
|
|
|
|
/* DISASSEMBLY ROUTINES
|
|
* Canonical order of arguments is
|
|
* (buf, buf_len, buf_rva, offset, len, insn, func, arg, resolve_func)
|
|
* ...but of course all of these are not used at the same time.
|
|
*/
|
|
|
|
|
|
/* Function prototype for caller-supplied callback routine
|
|
* These callbacks are intended to process 'insn' further, e.g. by
|
|
* adding it to a linked list, database, etc */
|
|
typedef void (*DISASM_CALLBACK)( x86_insn_t *insn, void * arg );
|
|
|
|
/* Function prototype for caller-supplied address resolver.
|
|
* This routine is used to determine the rva to disassemble next, given
|
|
* the 'dest' operand of a jump/call. This allows the caller to resolve
|
|
* jump/call targets stored in a register or on the stack, and also allows
|
|
* the caller to prevent endless loops by checking if an address has
|
|
* already been disassembled. If an address cannot be resolved from the
|
|
* operand, or if the address has already been disassembled, this routine
|
|
* should return -1; in all other cases the RVA to be disassembled next
|
|
* should be returned. */
|
|
typedef int32_t (*DISASM_RESOLVER)( x86_op_t *op, x86_insn_t * current_insn,
|
|
void *arg );
|
|
|
|
|
|
/* x86_disasm: Disassemble a single instruction from a buffer of bytes.
|
|
* Returns size of instruction in bytes.
|
|
* Caller is responsible for calling x86_oplist_free() on
|
|
* a reused "insn" to avoid leaking memory when calling this
|
|
* function repeatedly.
|
|
* buf : Buffer of bytes to disassemble
|
|
* buf_len : Length of the buffer
|
|
* buf_rva : Load address of the start of the buffer
|
|
* offset : Offset in buffer to disassemble
|
|
* insn : Structure to fill with disassembled instruction
|
|
*/
|
|
unsigned int x86_disasm( unsigned char *buf, unsigned int buf_len,
|
|
uint32_t buf_rva, unsigned int offset,
|
|
x86_insn_t * insn );
|
|
|
|
/* x86_disasm_range: Sequential disassembly of a range of bytes in a buffer,
|
|
* invoking a callback function each time an instruction
|
|
* is successfully disassembled. The 'range' refers to the
|
|
* bytes between 'offset' and 'offset + len' in the buffer;
|
|
* 'len' is assumed to be less than the length of the buffer.
|
|
* Returns number of instructions processed.
|
|
* buf : Buffer of bytes to disassemble (e.g. .text section)
|
|
* buf_rva : Load address of buffer (e.g. ELF Virtual Address)
|
|
* offset : Offset in buffer to start disassembly at
|
|
* len : Number of bytes to disassemble
|
|
* func : Callback function to invoke (may be NULL)
|
|
* arg : Arbitrary data to pass to callback (may be NULL)
|
|
*/
|
|
unsigned int x86_disasm_range( unsigned char *buf, uint32_t buf_rva,
|
|
unsigned int offset, unsigned int len,
|
|
DISASM_CALLBACK func, void *arg );
|
|
|
|
/* x86_disasm_forward: Flow-of-execution disassembly of the bytes in a buffer,
|
|
* invoking a callback function each time an instruction
|
|
* is successfully disassembled.
|
|
* buf : Buffer to disassemble (e.g. .text section)
|
|
* buf_len : Number of bytes in buffer
|
|
* buf_rva : Load address of buffer (e.g. ELF Virtual Address)
|
|
* offset : Offset in buffer to start disassembly at (e.g. entry point)
|
|
* func : Callback function to invoke (may be NULL)
|
|
* arg : Arbitrary data to pass to callback (may be NULL)
|
|
* resolver: Caller-supplied address resolver. If no resolver is
|
|
* supplied, a default internal one is used -- however the
|
|
* internal resolver does NOT catch loops and could end up
|
|
* disassembling forever..
|
|
* r_arg : Arbitrary data to pass to resolver (may be NULL)
|
|
*/
|
|
unsigned int x86_disasm_forward( unsigned char *buf, unsigned int buf_len,
|
|
uint32_t buf_rva, unsigned int offset,
|
|
DISASM_CALLBACK func, void *arg,
|
|
DISASM_RESOLVER resolver, void *r_arg );
|
|
|
|
/* Instruction operands: these are stored as a list of explicit and
|
|
* implicit operands. It is recommended that the 'foreach' routines
|
|
* be used to when examining operands for purposes of data flow analysis */
|
|
|
|
/* Operand FOREACH callback: 'arg' is an abritrary parameter passed to the
|
|
* foreach routine, 'insn' is the x86_insn_t whose operands are being
|
|
* iterated over, and 'op' is the current x86_op_t */
|
|
typedef void (*x86_operand_fn)(x86_op_t *op, x86_insn_t *insn, void *arg);
|
|
|
|
/* FOREACH types: these are used to limit the foreach results to
|
|
* operands which match a certain "type" (implicit or explicit)
|
|
* or which are accessed in certain ways (e.g. read or write). Note
|
|
* that this operates on the operand list of single instruction, so
|
|
* specifying the 'real' operand type (register, memory, etc) is not
|
|
* useful. Note also that by definition Execute Access implies Read
|
|
* Access and implies Not Write Access.
|
|
* The "type" (implicit or explicit) and the access method can
|
|
* be ORed together, e.g. op_wo | op_explicit */
|
|
enum x86_op_foreach_type {
|
|
op_any = 0, /* ALL operands (explicit, implicit, rwx) */
|
|
op_dest = 1, /* operands with Write access */
|
|
op_src = 2, /* operands with Read access */
|
|
op_ro = 3, /* operands with Read but not Write access */
|
|
op_wo = 4, /* operands with Write but not Read access */
|
|
op_xo = 5, /* operands with Execute access */
|
|
op_rw = 6, /* operands with Read AND Write access */
|
|
op_implicit = 0x10, /* operands that are implied by the opcode */
|
|
op_explicit = 0x20 /* operands that are not side-effects */
|
|
};
|
|
|
|
|
|
/* free the operand list associated with an instruction -- useful for
|
|
* preventing memory leaks when free()ing an x86_insn_t */
|
|
void x86_oplist_free( x86_insn_t *insn );
|
|
|
|
/* Operand foreach: invokes 'func' with 'insn' and 'arg' as arguments. The
|
|
* 'type' parameter is used to select only operands matching specific
|
|
* criteria. */
|
|
int x86_operand_foreach( x86_insn_t *insn, x86_operand_fn func, void *arg,
|
|
enum x86_op_foreach_type type);
|
|
|
|
/* convenience routine: returns count of operands matching 'type' */
|
|
size_t x86_operand_count( x86_insn_t *insn, enum x86_op_foreach_type type );
|
|
|
|
/* accessor functions for the operands */
|
|
x86_op_t * x86_operand_1st( x86_insn_t *insn );
|
|
x86_op_t * x86_operand_2nd( x86_insn_t *insn );
|
|
x86_op_t * x86_operand_3rd( x86_insn_t *insn );
|
|
|
|
/* these allow libdisasm 2.0 accessor functions to still be used */
|
|
#define x86_get_dest_operand( insn ) x86_operand_1st( insn )
|
|
#define x86_get_src_operand( insn ) x86_operand_2nd( insn )
|
|
#define x86_get_imm_operand( insn ) x86_operand_3rd( insn )
|
|
|
|
/* get size of operand data in bytes */
|
|
unsigned int x86_operand_size( x86_op_t *op );
|
|
|
|
/* Operand Convenience Routines: the following three routines are common
|
|
* operations on operands, intended to ease the burden of the programmer. */
|
|
|
|
/* Get Address: return the value of an offset operand, or the offset of
|
|
* a segment:offset absolute address */
|
|
uint32_t x86_get_address( x86_insn_t *insn );
|
|
|
|
/* Get Relative Offset: return as a sign-extended int32_t the near or far
|
|
* relative offset operand, or 0 if there is none. There can be only one
|
|
* relaive offset operand in an instruction. */
|
|
int32_t x86_get_rel_offset( x86_insn_t *insn );
|
|
|
|
/* Get Branch Target: return the x86_op_t containing the target of
|
|
* a jump or call operand, or NULL if there is no branch target.
|
|
* Internally, a 'branch target' is defined as any operand with
|
|
* Execute Access set. There can be only one branch target per instruction. */
|
|
x86_op_t * x86_get_branch_target( x86_insn_t *insn );
|
|
|
|
/* Get Immediate: return the x86_op_t containing the immediate operand
|
|
* for this instruction, or NULL if there is no immediate operand. There
|
|
* can be only one immediate operand per instruction */
|
|
x86_op_t * x86_get_imm( x86_insn_t *insn );
|
|
|
|
/* Get Raw Immediate Data: returns a pointer to the immediate data encoded
|
|
* in the instruction. This is useful for large data types [>32 bits] currently
|
|
* not supported by libdisasm, or for determining if the disassembler
|
|
* screwed up the conversion of the immediate data. Note that 'imm' in this
|
|
* context refers to immediate data encoded at the end of an instruction as
|
|
* detailed in the Intel Manual Vol II Chapter 2; it does not refer to the
|
|
* 'op_imm' operand (the third operand in instructions like 'mul' */
|
|
unsigned char * x86_get_raw_imm( x86_insn_t *insn );
|
|
|
|
|
|
/* More accessor fuctions, this time for user-defined info... */
|
|
/* set the address (usually RVA) of the insn */
|
|
void x86_set_insn_addr( x86_insn_t *insn, uint32_t addr );
|
|
|
|
/* set the offset (usually offset into file) of the insn */
|
|
void x86_set_insn_offset( x86_insn_t *insn, unsigned int offset );
|
|
|
|
/* set a pointer to the function owning the instruction. The
|
|
* type of 'func' is user-defined; libdisasm does not use the func field. */
|
|
void x86_set_insn_function( x86_insn_t *insn, void * func );
|
|
|
|
/* set a pointer to the block of code owning the instruction. The
|
|
* type of 'block' is user-defined; libdisasm does not use the block field. */
|
|
void x86_set_insn_block( x86_insn_t *insn, void * block );
|
|
|
|
/* instruction tagging: these routines allow the programmer to mark
|
|
* instructions as "seen" in a DFS, for example. libdisasm does not use
|
|
* the tag field.*/
|
|
/* set insn->tag to 1 */
|
|
void x86_tag_insn( x86_insn_t *insn );
|
|
/* set insn->tag to 0 */
|
|
void x86_untag_insn( x86_insn_t *insn );
|
|
/* return insn->tag */
|
|
int x86_insn_is_tagged( x86_insn_t *insn );
|
|
|
|
|
|
/* Disassembly formats:
|
|
* AT&T is standard AS/GAS-style: "mnemonic\tsrc, dest, imm"
|
|
* Intel is standard MASM/NASM/TASM: "mnemonic\tdest,src, imm"
|
|
* Native is tab-delimited: "RVA\tbytes\tmnemonic\tdest\tsrc\timm"
|
|
* XML is your typical <insn> ... </insn>
|
|
* Raw is addr|offset|size|bytes|prefix... see libdisasm_formats.7
|
|
*/
|
|
enum x86_asm_format {
|
|
unknown_syntax = 0, /* never use! */
|
|
native_syntax, /* header: 35 bytes */
|
|
intel_syntax, /* header: 23 bytes */
|
|
att_syntax, /* header: 23 bytes */
|
|
xml_syntax, /* header: 679 bytes */
|
|
raw_syntax /* header: 172 bytes */
|
|
};
|
|
|
|
/* format (sprintf) an operand into 'buf' using specified syntax */
|
|
int x86_format_operand(x86_op_t *op, char *buf, int len,
|
|
enum x86_asm_format format);
|
|
|
|
/* format (sprintf) an instruction mnemonic into 'buf' using specified syntax */
|
|
int x86_format_mnemonic(x86_insn_t *insn, char *buf, int len,
|
|
enum x86_asm_format format);
|
|
|
|
/* format (sprintf) an instruction into 'buf' using specified syntax;
|
|
* this includes formatting all operands */
|
|
int x86_format_insn(x86_insn_t *insn, char *buf, int len, enum x86_asm_format);
|
|
|
|
/* fill 'buf' with a description of the format's syntax */
|
|
int x86_format_header( char *buf, int len, enum x86_asm_format format);
|
|
|
|
/* Endianness of an x86 CPU : 0 is big, 1 is little; always returns 1 */
|
|
unsigned int x86_endian(void);
|
|
|
|
/* Default address and operand size in bytes */
|
|
unsigned int x86_addr_size(void);
|
|
unsigned int x86_op_size(void);
|
|
|
|
/* Size of a machine word in bytes */
|
|
unsigned int x86_word_size(void);
|
|
|
|
/* maximum size of a code instruction */
|
|
#define x86_max_inst_size(x) x86_max_insn_size(x)
|
|
unsigned int x86_max_insn_size(void);
|
|
|
|
/* register IDs of Stack, Frame, Instruction pointer and Flags register */
|
|
unsigned int x86_sp_reg(void);
|
|
unsigned int x86_fp_reg(void);
|
|
unsigned int x86_ip_reg(void);
|
|
unsigned int x86_flag_reg(void);
|
|
|
|
/* fill 'reg' struct with details of register 'id' */
|
|
void x86_reg_from_id( unsigned int id, x86_reg_t * reg );
|
|
|
|
/* convenience macro demonstrating how to get an aliased register; proto is
|
|
* void x86_get_aliased_reg( x86_reg_t *alias_reg, x86_reg_t *output_reg )
|
|
* where 'alias_reg' is a reg operand and 'output_reg' is filled with the
|
|
* register that the operand is an alias for */
|
|
#define x86_get_aliased_reg( alias_reg, output_reg ) \
|
|
x86_reg_from_id( alias_reg->alias, output_reg )
|
|
|
|
|
|
/* ================================== Invariant Instruction Representation */
|
|
/* Invariant instructions are used for generating binary signatures;
|
|
* the instruction is modified so that all variant bytes in an instruction
|
|
* are replaced with a wildcard byte.
|
|
*
|
|
* A 'variant byte' is one that is expected to be modified by either the
|
|
* static or the dynamic linker: for example, an address encoded in an
|
|
* instruction.
|
|
*
|
|
* By comparing the invariant representation of one instruction [or of a
|
|
* sequence of instructions] with the invariant representation of another,
|
|
* one determine whether the two invariant representations are from the same
|
|
* relocatable object [.o] file. Thus one can use binary signatures [which
|
|
* are just sequences of invariant instruction representations] to look for
|
|
* library routines which have been statically-linked into a binary.
|
|
*
|
|
* The invariant routines are faster and smaller than the disassembly
|
|
* routines; they can be used to determine the size of an instruction
|
|
* without all of the overhead of a full instruction disassembly.
|
|
*/
|
|
|
|
/* This byte is used to replace variant bytes */
|
|
#define X86_WILDCARD_BYTE 0xF4
|
|
|
|
typedef struct {
|
|
enum x86_op_type type; /* operand type */
|
|
enum x86_op_datatype datatype; /* operand size */
|
|
enum x86_op_access access; /* operand access [RWX] */
|
|
enum x86_op_flags flags; /* misc flags */
|
|
} x86_invariant_op_t;
|
|
|
|
typedef struct {
|
|
unsigned char bytes[64]; /* invariant representation */
|
|
unsigned int size; /* number of bytes in insn */
|
|
enum x86_insn_group group; /* meta-type, e.g. INS_EXEC */
|
|
enum x86_insn_type type; /* type, e.g. INS_BRANCH */
|
|
x86_invariant_op_t operands[3]; /* operands: dest, src, imm */
|
|
} x86_invariant_t;
|
|
|
|
|
|
/* return a version of the instruction with the variant bytes masked out */
|
|
size_t x86_invariant_disasm( unsigned char *buf, int buf_len,
|
|
x86_invariant_t *inv );
|
|
/* return the size in bytes of the intruction pointed to by 'buf';
|
|
* this used x86_invariant_disasm since it faster than x86_disasm */
|
|
size_t x86_size_disasm( unsigned char *buf, unsigned int buf_len );
|
|
|
|
#ifdef __cplusplus
|
|
}
|
|
#endif
|
|
|
|
|
|
#endif
|