%ignore insn_t; %ignore op_t; %ignore cmd; %ignore ua_out; %ignore showAsChar; %ignore out_real; %ignore init_output_buffer; %ignore term_output_buffer; %ignore OutValue; %ignore OutImmChar; %ignore out_name_expr; %ignore ua_stkvar2; %ignore ua_add_off_drefs; %ignore ua_add_off_drefs2; %ignore out_snprintf; %ignore set_output_ptr; %ignore get_output_ptr; %ignore out_insert; %ignore get_immval; %ignore get_spoiled_reg; %ignore construct_macro; %ignore decode_preceding_insn; %ignore init_ua; %ignore term_ua; %ignore term_uaterm_ua; %ignore get_equal_items; %ignore get_equal_itemsget_equal_items; %ignore ua_use_fixup; %ignore get_immval; %ignore ua_stkvar; %include "ua.hpp" %rename (init_output_buffer) py_init_output_buffer; %rename (term_output_buffer) py_term_output_buffer; %rename (OutValue) py_OutValue; %rename (OutImmChar) py_OutImmChar; %rename (out_name_expr) py_out_name_expr; %rename (ua_stkvar2) py_ua_stkvar2; %rename (ua_add_off_drefs) py_ua_add_off_drefs; %rename (ua_add_off_drefs2) py_ua_add_off_drefs2; %rename (decode_preceding_insn) py_decode_preceding_insn; %inline %{ // //------------------------------------------------------------------------- /* # def init_output_buffer(size = MAXSTR): """ This function initialize an output buffer with the given size. It should be called before using any out_xxxx() functions. @return: It returns a string. This string should then be passed to MakeLine(). This function could return None if it failed to create a buffer with the given size. """ pass # */ PyObject *py_init_output_buffer(size_t size = MAXSTR) { // Let Python allocate a writable string buffer for us PyObject *py_str = PyString_FromStringAndSize(NULL, size); if ( py_str == NULL ) Py_RETURN_NONE; init_output_buffer(PyString_AsString(py_str), size); return py_str; } //------------------------------------------------------------------------- /* # def term_output_buffer(): """Use this function to terminate an output buffer.""" pass # */ void py_term_output_buffer() { term_output_buffer(); } //------------------------------------------------------------------------- /* # def decode_preceding_insn(ea): """ Decodes the preceding instruction. Please check ua.hpp / decode_preceding_insn() @param ea: current ea @return: tuple(preceeding_ea or BADADDR, farref = Boolean) """ pass # */ PyObject *py_decode_preceding_insn(ea_t ea) { bool farref; ea_t r = decode_preceding_insn(ea, &farref); return Py_BuildValue("(" PY_FMT64 "i)", pyul_t(r), farref ? 1 : 0); } //------------------------------------------------------------------------- /* # def OutValue(op, outflags = 0): """ Output immediate value @param op: operand (of type op_t) @return: flags of the output value -1: value is output with COLOR_ERROR 0: value is output as a number or character or segment """ pass # */ flags_t py_OutValue(PyObject *x, int outflags=0) { op_t *op = op_t_get_clink(x); if ( op == NULL ) return 0; return OutValue(*op, outflags); } //------------------------------------------------------------------------- /* # def get_stkvar(op, v): """ Get pointer to stack variable @param op: reference to instruction operand @param v: immediate value in the operand (usually op.addr) @return: - None on failure - tuple(member_t, actval) where actval: actual value used to fetch stack variable """ pass # */ PyObject *py_get_stkvar(PyObject *py_op, PyObject *py_v) { op_t *op = op_t_get_clink(py_op); uint64 v; if ( op == NULL || !PyW_GetNumber(py_v, &v) ) Py_RETURN_NONE; sval_t actval; member_t *member = get_stkvar(*op, sval_t(v), &actval); if ( member == NULL ) Py_RETURN_NONE; return Py_BuildValue("(O" PY_SFMT64 ")", SWIG_NewPointerObj(SWIG_as_voidptr(member), SWIGTYPE_p_member_t, 0), pyl_t(actval)); } //------------------------------------------------------------------------- /* header: frame.hpp # def add_stkvar3(op, v, flags): """ Automatically add stack variable if doesn't exist Processor modules should use ua_stkvar2() @param op: reference to instruction operand @param v: immediate value in the operand (usually op.addr) @param flags: combination of STKVAR_... constants @return: Boolean """ pass # */ bool py_add_stkvar3(PyObject *py_op, PyObject *py_v, int flags) { op_t *op = op_t_get_clink(py_op); uint64 v; return ( op == NULL || !PyW_GetNumber(py_v, &v) || !add_stkvar3(*op, sval_t(v), flags)) ? false : true; } //------------------------------------------------------------------------- /* header: frame.hpp // Calculate offset of stack variable in the frame structure // pfn - pointer to function (can't be NULL!) // x - reference to instruction operand // v - value of variable offset in the instruction // returns: offset of stack variable in the frame structure (0..n) ea_t calc_frame_offset(func_t *pfn, const op_t *x, sval_t v); */ //------------------------------------------------------------------------- /* header: typeinf.hpp # def apply_type_to_stkarg(op, v, type, name): """ Apply type information to a stack variable @param op: reference to instruction operand @param v: immediate value in the operand (usually op.addr) @param type: type string. Retrieve from idc.ParseType("type string", flags)[1] @param name: stack variable name @return: Boolean """ pass # */ bool py_apply_type_to_stkarg( PyObject *py_op, PyObject *py_uv, PyObject *py_type, const char *name) { uint64 v; op_t *op = op_t_get_clink(py_op); if ( op == NULL || !PyW_GetNumber(py_uv, &v) || !PyString_Check(py_type)) return false; else return apply_type_to_stkarg(*op, uval_t(v), (type_t *) PyString_AsString(py_type), name); } //------------------------------------------------------------------------- /* # def OutImmChar(op, outflags = 0): """ Output operand value as a commented character constant @param op: operand (of type op_t) @return: None """ pass # */ static void py_OutImmChar(PyObject *x) { op_t *op = op_t_get_clink(x); if ( op != NULL ) OutImmChar(*op); } //------------------------------------------------------------------------- /* # def ua_stkvar2(op, outflags = 0): """ Create or modify a stack variable in the function frame. Please check ua.hpp / ua_stkvar2() @param op: operand (of type op_t) @return: None """ pass # */ static bool py_ua_stkvar2(PyObject *x, adiff_t v, int flags) { op_t *op = op_t_get_clink(x); return op == NULL ? false : ua_stkvar2(*op, v, flags); } //------------------------------------------------------------------------- /* # def ua_add_off_drefs(op, type): """ Add xrefs for offset operand of the current instruction Please check ua.hpp / ua_add_off_drefs() @param op: operand (of type op_t) @return: None """ pass # */ ea_t py_ua_add_off_drefs(PyObject *py_op, dref_t type) { op_t *op = op_t_get_clink(py_op); return op == NULL ? BADADDR : ua_add_off_drefs(*op, type); } //------------------------------------------------------------------------- /* # def ua_add_off_drefs2(op, type, outf): """ Add xrefs for offset operand of the current instruction Please check ua.hpp / ua_add_off_drefs2() @return: ea_t """ pass # */ ea_t py_ua_add_off_drefs2(PyObject *py_op, dref_t type, int outf) { op_t *op = op_t_get_clink(py_op); return op == NULL ? BADADDR : ua_add_off_drefs2(*op, type, outf); } //------------------------------------------------------------------------- /* # def out_name_expr(op, ea, off): """ Output a name expression @param op: operand (of type op_t) @param ea: address of expression @param off: the value of name expression. this parameter is used only to check that the name expression will have the wanted value. You may pass BADADDR for this parameter. @return: true if the name expression has been produced """ pass # */ bool py_out_name_expr( PyObject *py_op, ea_t ea, PyObject *py_off) { op_t *op = op_t_get_clink(py_op); uint64 v(0); adiff_t off; if ( PyW_GetNumber(py_off, &v) ) off = adiff_t(v); else off = BADADDR; return op == NULL ? false : out_name_expr(*op, ea, off); } //------------------------------------------------------------------------- static bool op_t_assign(PyObject *self, PyObject *other) { op_t *lhs = op_t_get_clink(self); op_t *rhs = op_t_get_clink(other); if (lhs == NULL || rhs == NULL) return false; *lhs = *rhs; return true; } //------------------------------------------------------------------------- static bool insn_t_assign(PyObject *self, PyObject *other) { insn_t *lhs = insn_t_get_clink(self); insn_t *rhs = insn_t_get_clink(other); if (lhs == NULL || rhs == NULL) return false; *lhs = *rhs; return true; } //------------------------------------------------------------------------- static PyObject *insn_t_get_op_link(PyObject *py_insn_lnk, int i) { if ( i < 0 || i >= UA_MAXOP || !PyCObject_Check(py_insn_lnk) ) Py_RETURN_NONE; // Extract C link insn_t *insn = (insn_t *)PyCObject_AsVoidPtr(py_insn_lnk); // Return a link to the operand return PyCObject_FromVoidPtr(&insn->Operands[i], NULL); } //------------------------------------------------------------------------- static PyObject *insn_t_create() { insn_t *insn = new insn_t(); return PyCObject_FromVoidPtr(insn, NULL); } //------------------------------------------------------------------------- static PyObject *op_t_create() { op_t *op = new op_t(); return PyCObject_FromVoidPtr(op, NULL); } //------------------------------------------------------------------------- static bool op_t_destroy(PyObject *py_obj) { if ( !PyCObject_Check(py_obj) ) return false; op_t *op = (op_t *) PyCObject_AsVoidPtr(py_obj); delete op; return true; } //------------------------------------------------------------------------- static bool insn_t_destroy(PyObject *py_obj) { if ( !PyCObject_Check(py_obj) ) return false; insn_t *insn = (insn_t *) PyCObject_AsVoidPtr(py_obj); delete insn; return true; } //------------------------------------------------------------------------- // Returns a C link to the global 'cmd' variable static PyObject *py_get_global_cmd_link() { return PyCObject_FromVoidPtr(&::cmd, NULL); } //------------------------------------------------------------------------- static PyObject *insn_t_is_canon_insn(int itype) { if ( ph.is_canon_insn(itype) ) Py_RETURN_TRUE; else Py_RETURN_FALSE; } //------------------------------------------------------------------------- static PyObject *insn_t_get_canon_feature(int itype) { return Py_BuildValue("I", ph.is_canon_insn(itype) ? ph.instruc[itype-ph.instruc_start].feature : 0); } //------------------------------------------------------------------------- static PyObject *insn_t_get_canon_mnem(int itype) { if ( ph.is_canon_insn(itype) ) return Py_BuildValue("s", ph.instruc[itype-ph.instruc_start].name); else Py_RETURN_NONE; } //------------------------------------------------------------------------- static PyObject *insn_t_get_cs(PyObject *self) { insn_t *link = insn_t_get_clink(self); if ( link == NULL ) Py_RETURN_NONE; return Py_BuildValue(PY_FMT64, (pyul_t)link->cs); } static void insn_t_set_cs(PyObject *self, PyObject *value) { insn_t *link = insn_t_get_clink(self); if ( link == NULL ) return; uint64 v(0); PyW_GetNumber(value, &v); link->cs = ea_t(v); } static PyObject *insn_t_get_ip(PyObject *self) { insn_t *link = insn_t_get_clink(self); if ( link == NULL ) Py_RETURN_NONE; return Py_BuildValue(PY_FMT64, (pyul_t)link->ip); } static void insn_t_set_ip(PyObject *self, PyObject *value) { insn_t *link = insn_t_get_clink(self); if ( link == NULL ) return; uint64 v(0); PyW_GetNumber(value, &v); link->ip = ea_t(v); } static PyObject *insn_t_get_ea(PyObject *self) { insn_t *link = insn_t_get_clink(self); if ( link == NULL ) Py_RETURN_NONE; return Py_BuildValue(PY_FMT64, (pyul_t)link->ea); } static void insn_t_set_ea(PyObject *self, PyObject *value) { insn_t *link = insn_t_get_clink(self); if ( link == NULL ) return; uint64 v(0); PyW_GetNumber(value, &v); link->ea = ea_t(v); } static PyObject *insn_t_get_itype(PyObject *self) { insn_t *link = insn_t_get_clink(self); if ( link == NULL ) Py_RETURN_NONE; return Py_BuildValue("H", link->itype); } static void insn_t_set_itype(PyObject *self, PyObject *value) { insn_t *link = insn_t_get_clink(self); if ( link == NULL ) return; link->itype = (uint16)PyInt_AsLong(value); } static PyObject *insn_t_get_size(PyObject *self) { insn_t *link = insn_t_get_clink(self); if ( link == NULL ) Py_RETURN_NONE; return Py_BuildValue("H", link->size); } static void insn_t_set_size(PyObject *self, PyObject *value) { insn_t *link = insn_t_get_clink(self); if ( link == NULL ) return; link->size = (uint16)PyInt_AsLong(value); } static PyObject *insn_t_get_auxpref(PyObject *self) { insn_t *link = insn_t_get_clink(self); if ( link == NULL ) Py_RETURN_NONE; return Py_BuildValue("H", link->auxpref); } static void insn_t_set_auxpref(PyObject *self, PyObject *value) { insn_t *link = insn_t_get_clink(self); if ( link == NULL ) return; link->auxpref = (uint16)PyInt_AsLong(value); } static PyObject *insn_t_get_segpref(PyObject *self) { insn_t *link = insn_t_get_clink(self); if ( link == NULL ) Py_RETURN_NONE; return Py_BuildValue("b", link->segpref); } static void insn_t_set_segpref(PyObject *self, PyObject *value) { insn_t *link = insn_t_get_clink(self); if ( link == NULL ) return; link->segpref = (char)PyInt_AsLong(value); } static PyObject *insn_t_get_insnpref(PyObject *self) { insn_t *link = insn_t_get_clink(self); if ( link == NULL ) Py_RETURN_NONE; return Py_BuildValue("b", link->insnpref); } static void insn_t_set_insnpref(PyObject *self, PyObject *value) { insn_t *link = insn_t_get_clink(self); if ( link == NULL ) return; link->insnpref = (char)PyInt_AsLong(value); } static PyObject *insn_t_get_flags(PyObject *self) { insn_t *link = insn_t_get_clink(self); if ( link == NULL ) Py_RETURN_NONE; return Py_BuildValue("b", link->flags); } static void insn_t_set_flags(PyObject *self, PyObject *value) { insn_t *link = insn_t_get_clink(self); if ( link == NULL ) return; link->flags = (char)PyInt_AsLong(value); } //------------------------------------------------------------------------- static PyObject *op_t_get_n(PyObject *self) { op_t *link = op_t_get_clink(self); if ( link == NULL ) Py_RETURN_NONE; return Py_BuildValue("b", link->n); } static void op_t_set_n(PyObject *self, PyObject *value) { op_t *link = op_t_get_clink(self); if ( link == NULL ) return; link->n = (char)PyInt_AsLong(value); } static PyObject *op_t_get_type(PyObject *self) { op_t *link = op_t_get_clink(self); if ( link == NULL ) Py_RETURN_NONE; return Py_BuildValue("B", link->type); } static void op_t_set_type(PyObject *self, PyObject *value) { op_t *link = op_t_get_clink(self); if ( link == NULL ) return; link->type = (optype_t)PyInt_AsLong(value); } static PyObject *op_t_get_offb(PyObject *self) { op_t *link = op_t_get_clink(self); if ( link == NULL ) Py_RETURN_NONE; return Py_BuildValue("b", link->offb); } static void op_t_set_offb(PyObject *self, PyObject *value) { op_t *link = op_t_get_clink(self); if ( link == NULL ) return; link->offb = (char)PyInt_AsLong(value); } static PyObject *op_t_get_offo(PyObject *self) { op_t *link = op_t_get_clink(self); if ( link == NULL ) Py_RETURN_NONE; return Py_BuildValue("b", link->offo); } static void op_t_set_offo(PyObject *self, PyObject *value) { op_t *link = op_t_get_clink(self); if ( link == NULL ) return; link->offo = (char)PyInt_AsLong(value); } static PyObject *op_t_get_flags(PyObject *self) { op_t *link = op_t_get_clink(self); if ( link == NULL ) Py_RETURN_NONE; return Py_BuildValue("B", link->flags); } static void op_t_set_flags(PyObject *self, PyObject *value) { op_t *link = op_t_get_clink(self); if ( link == NULL ) return; link->flags = (uchar)PyInt_AsLong(value); } static PyObject *op_t_get_dtyp(PyObject *self) { op_t *link = op_t_get_clink(self); if ( link == NULL ) Py_RETURN_NONE; return Py_BuildValue("b", link->dtyp); } static void op_t_set_dtyp(PyObject *self, PyObject *value) { op_t *link = op_t_get_clink(self); if ( link == NULL ) return; link->dtyp = (char)PyInt_AsLong(value); } static PyObject *op_t_get_reg_phrase(PyObject *self) { op_t *link = op_t_get_clink(self); if ( link == NULL ) Py_RETURN_NONE; return Py_BuildValue("H", link->reg); } static void op_t_set_reg_phrase(PyObject *self, PyObject *value) { op_t *link = op_t_get_clink(self); if ( link == NULL ) return; link->reg = (uint16)PyInt_AsLong(value); } static PyObject *op_t_get_value(PyObject *self) { op_t *link = op_t_get_clink(self); if ( link == NULL ) Py_RETURN_NONE; return Py_BuildValue("I", link->value); } static void op_t_set_value(PyObject *self, PyObject *value) { op_t *link = op_t_get_clink(self); if ( link == NULL ) return; link->value = PyInt_AsLong(value); } static PyObject *op_t_get_addr(PyObject *self) { op_t *link = op_t_get_clink(self); if ( link == NULL ) Py_RETURN_NONE; return Py_BuildValue(PY_FMT64, (pyul_t)link->addr); } static void op_t_set_addr(PyObject *self, PyObject *value) { op_t *link = op_t_get_clink(self); if ( link == NULL ) return; uint64 v(0); PyW_GetNumber(value, &v); link->addr = ea_t(v); } static PyObject *op_t_get_specval(PyObject *self) { op_t *link = op_t_get_clink(self); if ( link == NULL ) Py_RETURN_NONE; return Py_BuildValue(PY_FMT64, (pyul_t)link->specval); } static void op_t_set_specval(PyObject *self, PyObject *value) { op_t *link = op_t_get_clink(self); if ( link == NULL ) return; uint64 v(0); PyW_GetNumber(value, &v); link->specval = ea_t(v); } static PyObject *op_t_get_specflag1(PyObject *self) { op_t *link = op_t_get_clink(self); if ( link == NULL ) Py_RETURN_NONE; return Py_BuildValue("b", link->specflag1); } static void op_t_set_specflag1(PyObject *self, PyObject *value) { op_t *link = op_t_get_clink(self); if ( link == NULL ) return; link->specflag1 = (char)PyInt_AsLong(value); } static PyObject *op_t_get_specflag2(PyObject *self) { op_t *link = op_t_get_clink(self); if ( link == NULL ) Py_RETURN_NONE; return Py_BuildValue("b", link->specflag2); } static void op_t_set_specflag2(PyObject *self, PyObject *value) { op_t *link = op_t_get_clink(self); if ( link == NULL ) return; link->specflag2 = (char)PyInt_AsLong(value); } static PyObject *op_t_get_specflag3(PyObject *self) { op_t *link = op_t_get_clink(self); if ( link == NULL ) Py_RETURN_NONE; return Py_BuildValue("b", link->specflag3); } static void op_t_set_specflag3(PyObject *self, PyObject *value) { op_t *link = op_t_get_clink(self); if ( link == NULL ) return; link->specflag3 = (char)PyInt_AsLong(value); } static PyObject *op_t_get_specflag4(PyObject *self) { op_t *link = op_t_get_clink(self); if ( link == NULL ) Py_RETURN_NONE; return Py_BuildValue("b", link->specflag4); } static void op_t_set_specflag4(PyObject *self, PyObject *value) { op_t *link = op_t_get_clink(self); if ( link == NULL ) return; link->specflag4 = (char)PyInt_AsLong(value); } // %} %{ // //------------------------------------------------------------------------- insn_t *insn_t_get_clink(PyObject *self) { return (insn_t *)pyobj_get_clink(self); } //------------------------------------------------------------------------- op_t *op_t_get_clink(PyObject *self) { return (op_t *)pyobj_get_clink(self); } // %} %pythoncode %{ # # ----------------------------------------------------------------------- class op_t(py_clinked_object_t): """Class representing operands""" def __init__(self, lnk = None): py_clinked_object_t.__init__(self, lnk) def _create_clink(self): return _idaapi.op_t_create() def _del_clink(self, lnk): return _idaapi.op_t_destroy(lnk) def assign(self, other): """Copies the contents of 'other' to 'self'""" return _idaapi.op_t_assign(self, other) # # def copy(self): # """Returns a new copy of this class""" # pass # def __eq__(self, other): """Checks if two register operands are equal by checking the register number and its dtype""" return (self.reg == other.reg) and (self.dtyp == other.dtyp) def is_reg(self, r): """Checks if the register operand is the given processor register""" return self.type == _idaapi.o_reg and self == r def has_reg(self, r): """Checks if the operand accesses the given processor register""" return self.reg == r.reg # # Autogenerated # def __get_n__(self): return _idaapi.op_t_get_n(self) def __set_n__(self, v): _idaapi.op_t_set_n(self, v) def __get_type__(self): return _idaapi.op_t_get_type(self) def __set_type__(self, v): _idaapi.op_t_set_type(self, v) def __get_offb__(self): return _idaapi.op_t_get_offb(self) def __set_offb__(self, v): _idaapi.op_t_set_offb(self, v) def __get_offo__(self): return _idaapi.op_t_get_offo(self) def __set_offo__(self, v): _idaapi.op_t_set_offo(self, v) def __get_flags__(self): return _idaapi.op_t_get_flags(self) def __set_flags__(self, v): _idaapi.op_t_set_flags(self, v) def __get_dtyp__(self): return _idaapi.op_t_get_dtyp(self) def __set_dtyp__(self, v): _idaapi.op_t_set_dtyp(self, v) def __get_reg_phrase__(self): return _idaapi.op_t_get_reg_phrase(self) def __set_reg_phrase__(self, v): _idaapi.op_t_set_reg_phrase(self, v) def __get_value__(self): return _idaapi.op_t_get_value(self) def __set_value__(self, v): _idaapi.op_t_set_value(self, v) def __get_addr__(self): return _idaapi.op_t_get_addr(self) def __set_addr__(self, v): _idaapi.op_t_set_addr(self, v) def __get_specval__(self): return _idaapi.op_t_get_specval(self) def __set_specval__(self, v): _idaapi.op_t_set_specval(self, v) def __get_specflag1__(self): return _idaapi.op_t_get_specflag1(self) def __set_specflag1__(self, v): _idaapi.op_t_set_specflag1(self, v) def __get_specflag2__(self): return _idaapi.op_t_get_specflag2(self) def __set_specflag2__(self, v): _idaapi.op_t_set_specflag2(self, v) def __get_specflag3__(self): return _idaapi.op_t_get_specflag3(self) def __set_specflag3__(self, v): _idaapi.op_t_set_specflag3(self, v) def __get_specflag4__(self): return _idaapi.op_t_get_specflag4(self) def __set_specflag4__(self, v): _idaapi.op_t_set_specflag4(self, v) n = property(__get_n__, __set_n__) type = property(__get_type__, __set_type__) offb = property(__get_offb__, __set_offb__) offo = property(__get_offo__, __set_offo__) flags = property(__get_flags__, __set_flags__) dtyp = property(__get_dtyp__, __set_dtyp__) reg = property(__get_reg_phrase__, __set_reg_phrase__) phrase = property(__get_reg_phrase__, __set_reg_phrase__) value = property(__get_value__, __set_value__) addr = property(__get_addr__, __set_addr__) specval = property(__get_specval__, __set_specval__) specflag1 = property(__get_specflag1__, __set_specflag1__) specflag2 = property(__get_specflag2__, __set_specflag2__) specflag3 = property(__get_specflag3__, __set_specflag3__) specflag4 = property(__get_specflag4__, __set_specflag4__) # ----------------------------------------------------------------------- class insn_t(py_clinked_object_t): """Class representing instructions""" def __init__(self, lnk = None): py_clinked_object_t.__init__(self, lnk) # Create linked operands self.Operands = [] for i in xrange(0, UA_MAXOP): self.Operands.append(op_t(insn_t_get_op_link(self.clink, i))) # Convenience operand reference objects self.Op1 = self.Operands[0] self.Op2 = self.Operands[1] self.Op3 = self.Operands[2] self.Op4 = self.Operands[3] self.Op5 = self.Operands[4] self.Op6 = self.Operands[5] def assign(self, other): """Copies the contents of 'other' to 'self'""" return _idaapi.insn_t_assign(self, other) # # def copy(self): # """Returns a new copy of this class""" # pass # def _create_clink(self): return _idaapi.insn_t_create() def _del_clink(self, lnk): return _idaapi.insn_t_destroy(lnk) def __iter__(self): return (self.Operands[idx] for idx in xrange(0, UA_MAXOP)) def __getitem__(self, idx): """ Operands can be accessed directly as indexes @return op_t: Returns an operand of type op_t """ if idx >= UA_MAXOP: raise KeyError else: return self.Operands[idx] def is_macro(self): return self.flags & INSN_MACRO != 0 def is_canon_insn(self): return _idaapi.insn_t_is_canon_insn(self.itype) def get_canon_feature(self): return _idaapi.insn_t_get_canon_feature(self.itype) def get_canon_mnem(self): return _idaapi.insn_t_get_canon_mnem(self.itype) # # Autogenerated # def __get_cs__(self): return _idaapi.insn_t_get_cs(self) def __set_cs__(self, v): _idaapi.insn_t_set_cs(self, v) def __get_ip__(self): return _idaapi.insn_t_get_ip(self) def __set_ip__(self, v): _idaapi.insn_t_set_ip(self, v) def __get_ea__(self): return _idaapi.insn_t_get_ea(self) def __set_ea__(self, v): _idaapi.insn_t_set_ea(self, v) def __get_itype__(self): return _idaapi.insn_t_get_itype(self) def __set_itype__(self, v): _idaapi.insn_t_set_itype(self, v) def __get_size__(self): return _idaapi.insn_t_get_size(self) def __set_size__(self, v): _idaapi.insn_t_set_size(self, v) def __get_auxpref__(self): return _idaapi.insn_t_get_auxpref(self) def __set_auxpref__(self, v): _idaapi.insn_t_set_auxpref(self, v) def __get_segpref__(self): return _idaapi.insn_t_get_segpref(self) def __set_segpref__(self, v): _idaapi.insn_t_set_segpref(self, v) def __get_insnpref__(self): return _idaapi.insn_t_get_insnpref(self) def __set_insnpref__(self, v): _idaapi.insn_t_set_insnpref(self, v) def __get_flags__(self): return _idaapi.insn_t_get_flags(self) def __set_flags__(self, v): _idaapi.insn_t_set_flags(self, v) cs = property(__get_cs__, __set_cs__) ip = property(__get_ip__, __set_ip__) ea = property(__get_ea__, __set_ea__) itype = property(__get_itype__, __set_itype__) size = property(__get_size__, __set_size__) auxpref = property(__get_auxpref__, __set_auxpref__) segpref = property(__get_segpref__, __set_segpref__) insnpref = property(__get_insnpref__, __set_insnpref__) flags = property(__get_flags__, __set_flags__) #---------------------------------------------------------------------------- # P R O C E S S O R M O D U L E S C O N S T A N T S #---------------------------------------------------------------------------- # ---------------------------------------------------------------------- # processor_t related constants CUSTOM_CMD_ITYPE = 0x8000 REG_SPOIL = 0x80000000 REAL_ERROR_FORMAT = -1 # not supported format for current .idp REAL_ERROR_RANGE = -2 # number too big (small) for store (mem NOT modifyed) REAL_ERROR_BADDATA = -3 # illegal real data for load (IEEE data not filled) # # Check whether the operand is relative to stack pointer or frame pointer. # This function is used to determine how to output a stack variable # This function may be absent. If it is absent, then all operands # are sp based by default. # Define this function only if some stack references use frame pointer # instead of stack pointer. # returns flags: OP_FP_BASED = 0x00000000 # operand is FP based OP_SP_BASED = 0x00000001 # operand is SP based OP_SP_ADD = 0x00000000 # operand value is added to the pointer OP_SP_SUB = 0x00000002 # operand value is substracted from the pointer # processor_t.id PLFM_386 = 0 # Intel 80x86 PLFM_Z80 = 1 # 8085, Z80 PLFM_I860 = 2 # Intel 860 PLFM_8051 = 3 # 8051 PLFM_TMS = 4 # Texas Instruments TMS320C5x PLFM_6502 = 5 # 6502 PLFM_PDP = 6 # PDP11 PLFM_68K = 7 # Motoroal 680x0 PLFM_JAVA = 8 # Java PLFM_6800 = 9 # Motorola 68xx PLFM_ST7 = 10 # SGS-Thomson ST7 PLFM_MC6812 = 11 # Motorola 68HC12 PLFM_MIPS = 12 # MIPS PLFM_ARM = 13 # Advanced RISC Machines PLFM_TMSC6 = 14 # Texas Instruments TMS320C6x PLFM_PPC = 15 # PowerPC PLFM_80196 = 16 # Intel 80196 PLFM_Z8 = 17 # Z8 PLFM_SH = 18 # Renesas (formerly Hitachi) SuperH PLFM_NET = 19 # Microsoft Visual Studio.Net PLFM_AVR = 20 # Atmel 8-bit RISC processor(s) PLFM_H8 = 21 # Hitachi H8/300, H8/2000 PLFM_PIC = 22 # Microchip's PIC PLFM_SPARC = 23 # SPARC PLFM_ALPHA = 24 # DEC Alpha PLFM_HPPA = 25 # Hewlett-Packard PA-RISC PLFM_H8500 = 26 # Hitachi H8/500 PLFM_TRICORE = 27 # Tasking Tricore PLFM_DSP56K = 28 # Motorola DSP5600x PLFM_C166 = 29 # Siemens C166 family PLFM_ST20 = 30 # SGS-Thomson ST20 PLFM_IA64 = 31 # Intel Itanium IA64 PLFM_I960 = 32 # Intel 960 PLFM_F2MC = 33 # Fujistu F2MC-16 PLFM_TMS320C54 = 34 # Texas Instruments TMS320C54xx PLFM_TMS320C55 = 35 # Texas Instruments TMS320C55xx PLFM_TRIMEDIA = 36 # Trimedia PLFM_M32R = 37 # Mitsubishi 32bit RISC PLFM_NEC_78K0 = 38 # NEC 78K0 PLFM_NEC_78K0S = 39 # NEC 78K0S PLFM_M740 = 40 # Mitsubishi 8bit PLFM_M7700 = 41 # Mitsubishi 16bit PLFM_ST9 = 42 # ST9+ PLFM_FR = 43 # Fujitsu FR Family PLFM_MC6816 = 44 # Motorola 68HC16 PLFM_M7900 = 45 # Mitsubishi 7900 PLFM_TMS320C3 = 46 # Texas Instruments TMS320C3 PLFM_KR1878 = 47 # Angstrem KR1878 PLFM_AD218X = 48 # Analog Devices ADSP 218X PLFM_OAKDSP = 49 # Atmel OAK DSP PLFM_TLCS900 = 50 # Toshiba TLCS-900 PLFM_C39 = 51 # Rockwell C39 PLFM_CR16 = 52 # NSC CR16 PLFM_MN102L00 = 53 # Panasonic MN10200 PLFM_TMS320C1X = 54 # Texas Instruments TMS320C1x PLFM_NEC_V850X = 55 # NEC V850 and V850ES/E1/E2 PLFM_SCR_ADPT = 56 # Processor module adapter for processor modules written in scripting languages PLFM_EBC = 57 # EFI Bytecode PLFM_MSP430 = 58 # Texas Instruments MSP430 PLFM_SPU = 59 # Cell Broadband Engine Synergistic Processor Unit # # processor_t.flag # PR_SEGS = 0x000001 # has segment registers? PR_USE32 = 0x000002 # supports 32-bit addressing? PR_DEFSEG32 = 0x000004 # segments are 32-bit by default PR_RNAMESOK = 0x000008 # allow to user register names for location names PR_ADJSEGS = 0x000020 # IDA may adjust segments moving their starting/ending addresses. PR_DEFNUM = 0x0000C0 # default number representation: PRN_HEX = 0x000000 # hex PRN_OCT = 0x000040 # octal PRN_DEC = 0x000080 # decimal PRN_BIN = 0x0000C0 # binary PR_WORD_INS = 0x000100 # instruction codes are grouped 2bytes in binrary line prefix PR_NOCHANGE = 0x000200 # The user can't change segments and code/data attributes (display only) PR_ASSEMBLE = 0x000400 # Module has a built-in assembler and understands IDP_ASSEMBLE PR_ALIGN = 0x000800 # All data items should be aligned properly PR_TYPEINFO = 0x001000 # the processor module supports # type information callbacks # ALL OF THEM SHOULD BE IMPLEMENTED! # (the ones >= decorate_name) PR_USE64 = 0x002000 # supports 64-bit addressing? PR_SGROTHER = 0x004000 # the segment registers don't contain # the segment selectors, something else PR_STACK_UP = 0x008000 # the stack grows up PR_BINMEM = 0x010000 # the processor module provides correct # segmentation for binary files # (i.e. it creates additional segments) # The kernel will not ask the user # to specify the RAM/ROM sizes PR_SEGTRANS = 0x020000 # the processor module supports # the segment translation feature # (it means it calculates the code # addresses using the codeSeg() function) PR_CHK_XREF = 0x040000 # don't allow near xrefs between segments # with different bases PR_NO_SEGMOVE = 0x080000 # the processor module doesn't support move_segm() # (i.e. the user can't move segments) PR_FULL_HIFXP = 0x100000 # REF_VHIGH operand value contains full operand # not only the high bits. Meaningful if ph.high_fixup_bits PR_USE_ARG_TYPES = 0x200000 # use ph.use_arg_types callback PR_SCALE_STKVARS = 0x400000 # use ph.get_stkvar_scale callback PR_DELAYED = 0x800000 # has delayed jumps and calls PR_ALIGN_INSN = 0x1000000 # allow ida to create alignment instructions # arbirtrarily. Since these instructions # might lead to other wrong instructions # and spoil the listing, IDA does not create # them by default anymore PR_PURGING = 0x2000000 # there are calling conventions which may # purge bytes from the stack PR_CNDINSNS = 0x4000000 # has conditional instructions PR_USE_TBYTE = 0x8000000 # BTMT_SPECFLT means _TBYTE type PR_DEFSEG64 = 0x10000000 # segments are 64-bit by default # ---------------------------------------------------------------------- # # Misc constants # UA_MAXOP = 6 """The maximum number of operands in the insn_t structure""" # Create 'cmd' into the global scope cmd = insn_t(_idaapi.py_get_global_cmd_link()) """cmd is a global variable of type insn_t. It is contains information about the last decoded instruction. This variable is also filled by processor modules when they decode instructions.""" # ---------------------------------------------------------------------- # instruc_t related constants # # instruc_t.feature # CF_STOP = 0x00001 # Instruction doesn't pass execution to the next instruction CF_CALL = 0x00002 # CALL instruction (should make a procedure here) CF_CHG1 = 0x00004 # The instruction modifies the first operand CF_CHG2 = 0x00008 # The instruction modifies the second operand CF_CHG3 = 0x00010 # The instruction modifies the third operand CF_CHG4 = 0x00020 # The instruction modifies 4 operand CF_CHG5 = 0x00040 # The instruction modifies 5 operand CF_CHG6 = 0x00080 # The instruction modifies 6 operand CF_USE1 = 0x00100 # The instruction uses value of the first operand CF_USE2 = 0x00200 # The instruction uses value of the second operand CF_USE3 = 0x00400 # The instruction uses value of the third operand CF_USE4 = 0x00800 # The instruction uses value of the 4 operand CF_USE5 = 0x01000 # The instruction uses value of the 5 operand CF_USE6 = 0x02000 # The instruction uses value of the 6 operand CF_JUMP = 0x04000 # The instruction passes execution using indirect jump or call (thus needs additional analysis) CF_SHFT = 0x08000 # Bit-shift instruction (shl,shr...) CF_HLL = 0x10000 # Instruction may be present in a high level language function. # ---------------------------------------------------------------------- # op_t related constants # # op_t.type # Description Data field o_void = 0 # No Operand ---------- o_reg = 1 # General Register (al,ax,es,ds...) reg o_mem = 2 # Direct Memory Reference (DATA) addr o_phrase = 3 # Memory Ref [Base Reg + Index Reg] phrase o_displ = 4 # Memory Reg [Base Reg + Index Reg + Displacement] phrase+addr o_imm = 5 # Immediate Value value o_far = 6 # Immediate Far Address (CODE) addr o_near = 7 # Immediate Near Address (CODE) addr o_idpspec0 = 8 # IDP specific type o_idpspec1 = 9 # IDP specific type o_idpspec2 = 10 # IDP specific type o_idpspec3 = 11 # IDP specific type o_idpspec4 = 12 # IDP specific type o_idpspec5 = 13 # IDP specific type o_last = 14 # first unused type # # op_t.dtyp # dt_byte = 0 # 8 bit dt_word = 1 # 16 bit dt_dword = 2 # 32 bit dt_float = 3 # 4 byte dt_double = 4 # 8 byte dt_tbyte = 5 # variable size (ph.tbyte_size) dt_packreal = 6 # packed real format for mc68040 dt_qword = 7 # 64 bit dt_byte16 = 8 # 128 bit dt_code = 9 # ptr to code (not used?) dt_void = 10 # none dt_fword = 11 # 48 bit dt_bitfild = 12 # bit field (mc680x0) dt_string = 13 # pointer to asciiz string dt_unicode = 14 # pointer to unicode string dt_3byte = 15 # 3-byte data dt_ldbl = 16 # long double (which may be different from tbyte) # # op_t.flags # OF_NO_BASE_DISP = 0x80 # o_displ: base displacement doesn't exist meaningful only for o_displ type if set, base displacement (x.addr) doesn't exist. OF_OUTER_DISP = 0x40 # o_displ: outer displacement exists meaningful only for o_displ type if set, outer displacement (x.value) exists. PACK_FORM_DEF = 0x20 # !o_reg + dt_packreal: packed factor defined OF_NUMBER = 0x10 # can be output as number only if set, the operand can be converted to a number only OF_SHOW = 0x08 # should the operand be displayed? if clear, the operand is hidden and should not be displayed # # insn_t.flags # INSN_MACRO = 0x01 # macro instruction INSN_MODMAC = 0x02 # macros: may modify the database to make room for the macro insn # # Set IDP options constants # IDPOPT_STR = 1 # string constant IDPOPT_NUM = 2 # number IDPOPT_BIT = 3 # bit, yes/no IDPOPT_FLT = 4 # float IDPOPT_I64 = 5 # 64bit number IDPOPT_OK = 0 # ok IDPOPT_BADKEY = 1 # illegal keyword IDPOPT_BADTYPE = 2 # illegal type of value IDPOPT_BADVALUE = 3 # illegal value (bad range, for example) # ---------------------------------------------------------------------- class processor_t(pyidc_opaque_object_t): """Base class for all processor module scripts""" def __init__(self): # Take a reference to 'cmd' self.cmd = cmd def get_idpdesc(self): """ This function must be present and should return the list of short processor names similar to the one in ph.psnames. This method can be overridden to return to the kernel a different IDP description. """ return self.plnames[0] + ':' + ':'.join(self.psnames) def get_uFlag(self): """Use this utility function to retrieve the 'uFlag' global variable""" return _idaapi.cvar.uFlag def get_auxpref(self): """This function returns cmd.auxpref value""" return self.cmd.auxpref # ---------------------------------------------------------------------- class __ph(object): id = property(lambda self: ph_get_id()) cnbits = property(lambda self: ph_get_cnbits()) dnbits = property(lambda self: ph_get_dnbits()) flag = property(lambda self: ph_get_flag()) high_fixup_bits = property(lambda self: ph_get_high_fixup_bits()) icode_return = property(lambda self: ph_get_icode_return()) instruc = property(lambda self: ph_get_instruc()) instruc_end = property(lambda self: ph_get_instruc_end()) instruc_start = property(lambda self: ph_get_instruc_start()) regCodeSreg = property(lambda self: ph_get_regCodeSreg()) regDataSreg = property(lambda self: ph_get_regDataSreg()) regFirstSreg = property(lambda self: ph_get_regFirstSreg()) regLastSreg = property(lambda self: ph_get_regLastSreg()) regnames = property(lambda self: ph_get_regnames()) segreg_size = property(lambda self: ph_get_segreg_size()) tbyte_size = property(lambda self: ph_get_tbyte_size()) version = property(lambda self: ph_get_version()) ph = __ph() # %}