// Ignore the following symbols %ignore WorkReg; %ignore AbstractRegister; %ignore rginfo; %ignore insn_t::get_canon_mnem; %ignore insn_t::get_canon_feature; %ignore insn_t::is_canon_insn; %ignore bytes_t; %ignore IDPOPT_STR; %ignore IDPOPT_NUM; %ignore IDPOPT_BIT; %ignore IDPOPT_FLT; %ignore IDPOPT_I64; %ignore IDPOPT_OK; %ignore IDPOPT_BADKEY; %ignore IDPOPT_BADTYPE; %ignore IDPOPT_BADVALUE; %ignore set_options_t; %ignore read_user_config_file; %ignore s_preline; %ignore ca_operation_t; %ignore _chkarg_cmd; %ignore ENUM_SIZE; %ignore asm_t::checkarg_dispatch; %ignore asm_t::func_header; %ignore asm_t::func_footer; %ignore asm_t::get_type_name; %ignore instruc_t; %ignore processor_t; %ignore ph; %ignore IDB_Callback; %ignore IDP_Callback; %ignore _py_getreg; %ignore free_processor_module; %ignore read_config_file; %ignore cfg_compiler_changed; %ignore gen_idb_event; %include "idp.hpp" %feature("director") IDB_Hooks; %feature("director") IDP_Hooks; %inline %{ // //------------------------------------------------------------------------- //------------------------------------------------------------------------- /* # def AssembleLine(ea, cs, ip, use32, line): """ Assemble an instruction to a string (display a warning if an error is found) @param ea: linear address of instruction @param cs: cs of instruction @param ip: ip of instruction @param use32: is 32bit segment @param line: line to assemble @return: - None on failure - or a string containing the assembled instruction """ pass # */ static PyObject *AssembleLine( ea_t ea, ea_t cs, ea_t ip, bool use32, const char *line) { int inslen; char buf[MAXSTR]; bool ok = false; if (ph.notify != NULL && (inslen = ph.notify(ph.assemble, ea, cs, ip, use32, line, buf)) > 0) { ok = true; } PYW_GIL_CHECK_LOCKED_SCOPE(); if ( ok ) return PyString_FromStringAndSize(buf, inslen); else Py_RETURN_NONE; } //--------------------------------------------------------------------------- /* # def assemble(ea, cs, ip, use32, line): """ Assemble an instruction into the database (display a warning if an error is found) @param ea: linear address of instruction @param cs: cs of instruction @param ip: ip of instruction @param use32: is 32bit segment? @param line: line to assemble @return: Boolean. True on success. """ # */ bool assemble( ea_t ea, ea_t cs, ea_t ip, bool use32, const char *line) { int inslen; char buf[MAXSTR]; PYW_GIL_CHECK_LOCKED_SCOPE(); bool rc = false; Py_BEGIN_ALLOW_THREADS; if (ph.notify != NULL) { inslen = ph.notify(ph.assemble, ea, cs, ip, use32, line, buf); if (inslen > 0) { patch_many_bytes(ea, buf, inslen); rc = true; } } Py_END_ALLOW_THREADS; return rc; } //------------------------------------------------------------------------- /* # def ph_get_id(): """ Returns the 'ph.id' field """ pass # */ static size_t ph_get_id() { return ph.id; } //------------------------------------------------------------------------- /* # def ph_get_version(): """ Returns the 'ph.version' """ pass # */ static size_t ph_get_version() { return ph.version; } //------------------------------------------------------------------------- /* # def ph_get_flag(): """ Returns the 'ph.flag' """ pass # */ static size_t ph_get_flag() { return ph.flag; } //------------------------------------------------------------------------- /* # def ph_get_cnbits(): """ Returns the 'ph.cnbits' """ pass # */ static size_t ph_get_cnbits() { return ph.cnbits; } //------------------------------------------------------------------------- /* # def ph_get_dnbits(): """ Returns the 'ph.dnbits' """ pass # */ static size_t ph_get_dnbits() { return ph.dnbits; } //------------------------------------------------------------------------- /* # def ph_get_regFirstSreg(): """ Returns the 'ph.regFirstSreg' """ pass # */ static size_t ph_get_regFirstSreg() { return ph.regFirstSreg; } //------------------------------------------------------------------------- /* # def ph_get_regLastSreg(): """ Returns the 'ph.regLastSreg' """ pass # */ static size_t ph_get_regLastSreg() { return ph.regLastSreg; } //------------------------------------------------------------------------- /* # def ph_get_segreg_size(): """ Returns the 'ph.segreg_size' """ pass # */ static size_t ph_get_segreg_size() { return ph.segreg_size; } //------------------------------------------------------------------------- /* # def ph_get_regCodeSreg(): """ Returns the 'ph.regCodeSreg' """ pass # */ static size_t ph_get_regCodeSreg() { return ph.regCodeSreg; } //------------------------------------------------------------------------- /* # def ph_get_regDataSreg(): """ Returns the 'ph.regDataSreg' """ pass # */ static size_t ph_get_regDataSreg() { return ph.regDataSreg; } //------------------------------------------------------------------------- /* # def ph_get_high_fixup_bits(): """ Returns the 'ph.high_fixup_bits' """ pass # */ static size_t ph_get_high_fixup_bits() { return ph.high_fixup_bits; } //------------------------------------------------------------------------- /* # def ph_get_icode_return(): """ Returns the 'ph.icode_return' """ pass # */ static size_t ph_get_icode_return() { return ph.icode_return; } //------------------------------------------------------------------------- /* # def ph_get_instruc_start(): """ Returns the 'ph.instruc_start' """ pass # */ static size_t ph_get_instruc_start() { return ph.instruc_start; } //------------------------------------------------------------------------- /* # def ph_get_instruc_end(): """ Returns the 'ph.instruc_end' """ pass # */ static size_t ph_get_instruc_end() { return ph.instruc_end; } //------------------------------------------------------------------------- /* # def ph_get_tbyte_size(): """ Returns the 'ph.tbyte_size' field as defined in he processor module """ pass # */ static size_t ph_get_tbyte_size() { return ph.tbyte_size; } //------------------------------------------------------------------------- /* # def ph_get_instruc(): """ Returns a list of tuples (instruction_name, instruction_feature) containing the instructions list as defined in he processor module """ pass # */ static PyObject *ph_get_instruc() { Py_ssize_t i = 0; PYW_GIL_CHECK_LOCKED_SCOPE(); PyObject *py_result = PyTuple_New(ph.instruc_end - ph.instruc_start); for ( const instruc_t *p = ph.instruc + ph.instruc_start, *end = ph.instruc + ph.instruc_end; p != end; ++p ) { PyTuple_SetItem(py_result, i++, Py_BuildValue("(sI)", p->name, p->feature)); } return py_result; } //------------------------------------------------------------------------- /* # def ph_get_regnames(): """ Returns the list of register names as defined in the processor module """ pass # */ static PyObject *ph_get_regnames() { Py_ssize_t i = 0; PYW_GIL_CHECK_LOCKED_SCOPE(); PyObject *py_result = PyList_New(ph.regsNum); for ( Py_ssize_t i=0; i def ph_get_operand_info(): """ Returns the operand information given an ea and operand number. @param ea: address @param n: operand number @return: Returns an idd_opinfo_t as a tuple: (modified, ea, reg_ival, regidx, value_size). Please refer to idd_opinfo_t structure in the SDK. """ pass # */ static PyObject *ph_get_operand_info( ea_t ea, int n) { PYW_GIL_CHECK_LOCKED_SCOPE(); bool ok = false; idd_opinfo_t opinf; Py_BEGIN_ALLOW_THREADS; do { if ( dbg == NULL || n == - 1 ) break; // Allocate register space thid_t tid = get_current_thread(); regvals_t regvalues; regvalues.resize(dbg->registers_size); // Read registers if ( get_reg_vals(tid, -1, regvalues.begin()) != 1 ) break; // Call the processor module if ( ph.notify(ph.get_operand_info, ea, n, tid, _py_getreg, regvalues.begin(), &opinf) != 0 ) { break; } ok = true; } while (false); Py_END_ALLOW_THREADS; if ( ok ) return Py_BuildValue("(i" PY_FMT64 "Kii)", opinf.modified, opinf.ea, opinf.value.ival, opinf.debregidx, opinf.value_size); else Py_RETURN_NONE; } //------------------------------------------------------------------------- /* # class IDP_Hooks(object): def hook(self): """ Creates an IDP hook @return: Boolean true on success """ pass def unhook(self): """ Removes the IDP hook @return: Boolean true on success """ pass def custom_ana(self): """ Analyzes and decodes an instruction at idaapi.cmd.ea - cmd.itype must be set >= idaapi.CUSTOM_CMD_ITYPE - cmd.size must be set to the instruction length @return: Boolean - False if the instruction is not recognized - True if the instruction was decoded. idaapi.cmd should be filled in that case. """ pass def custom_out(self): """ Outputs the instruction defined in idaapi.cmd @return: Boolean (whether this instruction can be outputted or not) """ pass def custom_emu(self): """ Emulate instruction, create cross-references, plan to analyze subsequent instructions, modify flags etc. Upon entrance to this function all information about the instruction is in 'cmd' structure. @return: Boolean (whether this instruction has been emulated or not) """ pass def custom_outop(self, op): """ Notification to generate operand text. If False was returned, then the standard operand output function will be called. The output buffer is inited with init_output_buffer() and this notification may use out_...() functions to form the operand text @return: Boolean (whether the operand has been outputted or not) """ pass def custom_mnem(self): """ Prints the mnemonic of the instruction defined in idaapi.cmd @return: - None: No mnemonic. IDA will use the default mnemonic value if present - String: The desired mnemonic string """ pass def is_sane_insn(self, no_crefs): """ is the instruction sane for the current file type? @param no_crefs: - 1: the instruction has no code refs to it. ida just tries to convert unexplored bytes to an instruction (but there is no other reason to convert them into an instruction) - 0: the instruction is created because of some coderef, user request or another weighty reason. @return: 1-ok, <=0-no, the instruction isn't likely to appear in the program """ pass def may_be_func(self, no_crefs): """ Can a function start here? @param state: autoanalysis phase 0: creating functions 1: creating chunks @return: integer (probability 0..100) """ pass def closebase(self): """ The database will be closed now """ pass def savebase(self): """ The database is being saved. Processor module should """ pass def rename(self, ea, new_name): """ The kernel is going to rename a byte. @param ea: Address @param new_name: The new name @return: - If returns value <=0, then the kernel should not rename it. See also the 'renamed' event """ pass def renamed(self, ea, new_name, local_name): """ The kernel has renamed a byte @param ea: Address @param new_name: The new name @param local_name: Is local name @return: Ignored """ pass def undefine(self, ea): """ An item in the database (insn or data) is being deleted @param ea: Address @return: - returns: >0-ok, <=0-the kernel should stop - if the return value is positive: bit0 - ignored bit1 - do not delete srareas at the item end """ pass def make_code(self, ea, size): """ An instruction is being created @param ea: Address @param size: Instruction size @return: 1-ok, <=0-the kernel should stop """ pass def make_code(self, ea, size): """ An instruction is being created @param ea: Address @param size: Instruction size @return: 1-ok, <=0-the kernel should stop """ pass def make_data(self, ea, flags, tid, len): """ A data item is being created @param ea: Address @param tid: type id @param flags: item flags @param len: data item size @return: 1-ok, <=0-the kernel should stop """ pass def load_idasgn(self, short_sig_name): """ FLIRT signature have been loaded for normal processing (not for recognition of startup sequences) @param short_sig_name: signature name @return: Ignored """ pass def add_func(self, func): """ The kernel has added a function @param func: the func_t instance @return: Ignored """ pass def del_func(self, func): """ The kernel is about to delete a function @param func: the func_t instance @return: 1-ok,<=0-do not delete """ pass def is_call_insn(self, ea, func_name): """ Is the instruction a "call"? @param ea: instruction address @return: 1-unknown, 0-no, 2-yes """ pass def is_ret_insn(self, ea, func_name): """ Is the instruction a "return"? @param ea: instruction address @param strict: - True: report only ret instructions False: include instructions like "leave" which begins the function epilog @return: 1-unknown, 0-no, 2-yes """ pass def assemble(self, ea, cs, ip, use32, line): """ Assembles an instruction @param ea: linear address of instruction @param cs: cs of instruction @param ip: ip of instruction @param use32: is 32bit segment? @param line: line to assemble @return: - None to let the underlying processor module assemble the line - or a string containing the assembled buffer """ pass # */ //--------------------------------------------------------------------------- // IDP hooks //--------------------------------------------------------------------------- int idaapi IDP_Callback(void *ud, int notification_code, va_list va); class IDP_Hooks { public: virtual ~IDP_Hooks() { unhook(); } bool hook() { return hook_to_notification_point(HT_IDP, IDP_Callback, this); } bool unhook() { return unhook_from_notification_point(HT_IDP, IDP_Callback, this); } virtual bool custom_ana() { return false; } virtual bool custom_out() { return false; } virtual bool custom_emu() { return false; } virtual bool custom_outop(PyObject *py_op) { return false; } virtual PyObject *custom_mnem() { Py_RETURN_NONE; } virtual int is_sane_insn(int no_crefs) { return 0; } virtual int may_be_func(int state) { return 0; } virtual int closebase() { return 0; } virtual void savebase() { } virtual int rename(ea_t ea, const char *new_name) { return 0; } virtual void renamed(ea_t ea, const char *new_name, bool local_name) { } virtual int undefine(ea_t ea) { return 0; } virtual int make_code(ea_t ea, asize_t size) { return 0; } virtual int make_data(ea_t ea, flags_t flags, tid_t tid, asize_t len) { return 0; } virtual void load_idasgn(const char *short_sig_name) { } virtual void add_func(func_t *func) { } virtual int del_func(func_t *func) { return 0; } virtual int is_call_insn(ea_t /*ea*/) { return 0; } virtual int is_ret_insn(ea_t /*ea*/, bool /*strict*/) { return 0; } virtual PyObject *assemble( ea_t /*ea*/, ea_t /*cs*/, ea_t /*ip*/, bool /*use32*/, const char * /*line*/) { PYW_GIL_CHECK_LOCKED_SCOPE(); Py_RETURN_NONE; } }; //--------------------------------------------------------------------------- // IDB hooks //--------------------------------------------------------------------------- int idaapi IDB_Callback(void *ud, int notification_code, va_list va); class IDB_Hooks { public: virtual ~IDB_Hooks() { unhook(); }; bool hook() { return hook_to_notification_point(HT_IDB, IDB_Callback, this); } bool unhook() { return unhook_from_notification_point(HT_IDB, IDB_Callback, this); } // Hook functions to override in Python virtual int byte_patched(ea_t /*ea*/) { return 0; }; virtual int cmt_changed(ea_t, bool /*repeatable_cmt*/) { return 0; }; virtual int ti_changed(ea_t /*ea*/, const type_t * /*type*/, const p_list * /*fnames*/) { msg("ti_changed hook not supported yet\n"); return 0; }; virtual int op_ti_changed(ea_t /*ea*/, int /*n*/, const type_t * /*type*/, const p_list * /*fnames*/) { msg("op_ti_changed hook not supported yet\n"); return 0; }; virtual int op_type_changed(ea_t /*ea*/, int /*n*/) { return 0; }; virtual int enum_created(enum_t /*id*/) { return 0; }; virtual int enum_deleted(enum_t /*id*/) { return 0; }; virtual int enum_bf_changed(enum_t /*id*/) { return 0; }; virtual int enum_renamed(enum_t /*id*/) { return 0; }; virtual int enum_cmt_changed(enum_t /*id*/) { return 0; }; virtual int enum_member_created(enum_t /*id*/, const_t cid) { return 0; }; virtual int enum_member_deleted(enum_t /*id*/, const_t cid) { return 0; }; virtual int struc_created(tid_t /*struc_id*/) { return 0; }; virtual int struc_deleted(tid_t /*struc_id*/) { return 0; }; virtual int struc_renamed(struc_t * /*sptr*/) { return 0; }; virtual int struc_expanded(struc_t * /*sptr*/) { return 0; }; virtual int struc_cmt_changed(tid_t /*struc_id*/) { return 0; }; virtual int struc_member_created(struc_t * /*sptr*/, member_t * /*mptr*/) { return 0; }; virtual int struc_member_deleted(struc_t * /*sptr*/, tid_t /*member_id*/, ea_t /*offset*/) { return 0; }; virtual int struc_member_renamed(struc_t * /*sptr*/, member_t * /*mptr*/) { return 0; }; virtual int struc_member_changed(struc_t * /*sptr*/, member_t * /*mptr*/) { return 0; }; virtual int thunk_func_created(func_t * /*pfn*/) { return 0; }; virtual int func_tail_appended(func_t * /*pfn*/, func_t * /*tail*/) { return 0; }; virtual int func_tail_removed(func_t * /*pfn*/, ea_t /*tail_ea*/) { return 0; }; virtual int tail_owner_changed(func_t * /*tail*/, ea_t /*owner_func*/) { return 0; }; virtual int func_noret_changed(func_t * /*pfn*/) { return 0; }; virtual int segm_added(segment_t * /*s*/) { return 0; }; virtual int segm_deleted(ea_t /*startEA*/) { return 0; }; virtual int segm_start_changed(segment_t * /*s*/) { return 0; }; virtual int segm_end_changed(segment_t * /*s*/) { return 0; }; virtual int segm_moved(ea_t /*from*/, ea_t /*to*/, asize_t /*size*/) { return 0; }; }; // %} %{ // //------------------------------------------------------------------------- int idaapi IDP_Callback(void *ud, int notification_code, va_list va) { // This hook gets called from the kernel. Ensure we hold the GIL. PYW_GIL_GET; IDP_Hooks *proxy = (IDP_Hooks *)ud; int ret = 0; try { switch ( notification_code ) { case processor_t::custom_ana: ret = proxy->custom_ana() ? 1 + cmd.size : 0; break; case processor_t::custom_out: ret = proxy->custom_out() ? 2 : 0; break; case processor_t::custom_emu: ret = proxy->custom_emu() ? 2 : 0; break; case processor_t::custom_outop: { op_t *op = va_arg(va, op_t *); ref_t py_obj(create_idaapi_linked_class_instance(S_PY_OP_T_CLSNAME, op)); if ( py_obj == NULL ) break; ret = proxy->custom_outop(py_obj.o) ? 2 : 0; break; } case processor_t::custom_mnem: { PYW_GIL_CHECK_LOCKED_SCOPE(); PyObject *py_ret = proxy->custom_mnem(); if ( py_ret != NULL && PyString_Check(py_ret) ) { char *outbuffer = va_arg(va, char *); size_t bufsize = va_arg(va, size_t); qstrncpy(outbuffer, PyString_AS_STRING(py_ret), bufsize); ret = 2; } else { ret = 0; } Py_XDECREF(py_ret); break; } case processor_t::is_sane_insn: { int no_crefs = va_arg(va, int); ret = proxy->is_sane_insn(no_crefs); break; } case processor_t::may_be_func: { int state = va_arg(va, int); ret = proxy->may_be_func(state); break; } case processor_t::closebase: { proxy->closebase(); break; } case processor_t::savebase: { proxy->savebase(); break; } case processor_t::rename: { ea_t ea = va_arg(va, ea_t); const char *new_name = va_arg(va, const char *); ret = proxy->rename(ea, new_name); break; } case processor_t::renamed: { ea_t ea = va_arg(va, ea_t); const char *new_name = va_arg(va, const char *); bool local_name = va_argi(va, bool); proxy->renamed(ea, new_name, local_name); break; } case processor_t::undefine: { ea_t ea = va_arg(va, ea_t); ret = proxy->undefine(ea); break; } case processor_t::make_code: { ea_t ea = va_arg(va, ea_t); asize_t size = va_arg(va, asize_t); ret = proxy->make_code(ea, size); break; } case processor_t::make_data: { ea_t ea = va_arg(va, ea_t); flags_t flags = va_arg(va, flags_t); tid_t tid = va_arg(va, tid_t); asize_t len = va_arg(va, asize_t); ret = proxy->make_data(ea, flags, tid, len); break; } case processor_t::load_idasgn: { const char *short_sig_name = va_arg(va, const char *); proxy->load_idasgn(short_sig_name); break; } case processor_t::add_func: { func_t *func = va_arg(va, func_t *); proxy->add_func(func); break; } case processor_t::del_func: { func_t *func = va_arg(va, func_t *); ret = proxy->del_func(func); break; } case processor_t::is_call_insn: { ea_t ea = va_arg(va, ea_t); ret = proxy->is_call_insn(ea); break; } case processor_t::is_ret_insn: { ea_t ea = va_arg(va, ea_t); bool strict = va_argi(va, bool); ret = proxy->is_ret_insn(ea, strict); break; } case processor_t::assemble: { ea_t ea = va_arg(va, ea_t); ea_t cs = va_arg(va, ea_t); ea_t ip = va_arg(va, ea_t); bool use32 = va_argi(va, bool); const char *line = va_arg(va, const char *); // Extract user buffer (we hardcode the MAXSTR size limit) uchar *bin = va_arg(va, uchar *); // Call python PYW_GIL_CHECK_LOCKED_SCOPE(); PyObject *py_buffer = proxy->assemble(ea, cs, ip, use32, line); if ( py_buffer != NULL && PyString_Check(py_buffer) ) { char *s; Py_ssize_t len; if ( PyString_AsStringAndSize(py_buffer, &s, &len) != -1 ) { if ( len > MAXSTR ) len = MAXSTR; memcpy(bin, s, len); ret = len; } } // ret = 0 otherwise Py_XDECREF(py_buffer); break; } // validate_flirt_func, // flirt has recognized a library function // // this callback can be used by a plugin or proc module // // to intercept it and validate such a function // // args: ea_t start_ea // // const char *funcname // // returns: -1-do not create a function, // // 1-function is validated // // the idp module is allowed to modify 'cmd' // set_func_start, // Function chunk start address will be changed // // args: func_t *pfn // // ea_t new_start // // Returns: 1-ok,<=0-do not change // set_func_end, // Function chunk end address will be changed // // args: func_t *pfn // // ea_t new_end // // Returns: 1-ok,<=0-do not change // outlabel, // The kernel is going to generate an instruction // // label line or a function header // // args: // // ea_t ea - // // const char *colored_name - // // If returns value <=0, then the kernel should // // not generate the label // may_show_sreg, // The kernel wants to display the segment registers // // in the messages window. // // arg - ea_t current_ea // // if this function returns 0 // // then the kernel will not show // // the segment registers. // // (assuming that the module have done it) // coagulate, // Try to define some unexplored bytes // // This notification will be called if the // // kernel tried all possibilities and could // // not find anything more useful than to // // convert to array of bytes. // // The module can help the kernel and convert // // the bytes into something more useful. // // arg: // // ea_t start_ea // // returns: number of converted bytes + 1 // auto_empty, // Info: all analysis queues are empty // // args: none // // returns: none // // This callback is called once when the // // initial analysis is finished. If the queue is // // not empty upon the return from this callback, // // it will be called later again. // // See also auto_empty_finally. // auto_queue_empty, // One analysis queue is empty // // args: atype_t type // // returns: 1-yes, keep the queue empty // // <=0-no, the queue is not empty anymore // // This callback can be called many times, so // // only the autoMark() functions can be used from it // // (other functions may work but it is not tested) // func_bounds, // find_func_bounds() finished its work // // The module may fine tune the function bounds // // args: int *possible_return_code // // func_t *pfn // // ea_t max_func_end_ea (from the kernel's point of view) // // returns: none // is_jump_func, // is the function a trivial "jump" function? // // args: func_t *pfn // // ea_t *jump_target // // ea_t *func_pointer // // returns: 0-no, 1-don't know, 2-yes, see jump_target // // and func_pointer // gen_regvar_def, // generate register variable definition line // // args: regvar_t *v // // returns: 0-ok // setsgr, // The kernel has changed a segment register value // // args: ea_t startEA // // ea_t endEA // // int regnum // // sel_t value // // sel_t old_value // // uchar tag (SR_... values) // // returns: 1-ok, 0-error // set_compiler, // The kernel has changed the compiler information // // (inf.cc structure) // is_basic_block_end, // Is the current instruction end of a basic block? // // This function should be defined for processors // // with delayed jump slots. The current instruction // // is stored in 'cmd' // // args: bool call_insn_stops_block // // returns: 1-unknown, 0-no, 2-yes // reglink, // IBM PC only, ignore it // get_vxd_name, // IBM PC only, ignore it // // Get Vxd function name // // args: int vxdnum // // int funcnum // // char *outbuf // // returns: nothing // // // moving_segm, // May the kernel move the segment? // // args: segment_t - segment to move // // ea_t to - new segment start address // // returns: 1-yes, <=0-the kernel should stop // move_segm, // A segment is moved // // Fix processor dependent address sensitive information // // args: ea_t from - old segment address // // segment_t* - moved segment // // returns: nothing // // // get_stkvar_scale_factor,// Should stack variable references be multiplied by // // a coefficient before being used in the stack frame? // // Currently used by TMS320C55 because the references into // // the stack should be multiplied by 2 // // Returns: scaling factor // // Note: PR_SCALE_STKVARS should be set to use this callback // // create_flat_group, // Create special segment representing the flat group // // (to use for PC mainly) // // args - ea_t image_base, int bitness, sel_t dataseg_sel // // kernel_config_loaded, // This callback is called when ida.cfg is parsed // // args - none, returns - nothing // // might_change_sp, // Does the instruction at 'ea' modify the stack pointer? // // args: ea_t ea // // returns: 1-yes, 0-false // // (not used yet) // // is_alloca_probe, // Does the function at 'ea' behave as __alloca_probe? // // args: ea_t ea // // returns: 2-yes, 1-false // // out_3byte, // Generate text representation of 3byte data // // init_out_buffer() is called before this function // // and all Out... function can be used. // // uFlag contains the flags. // // This callback might be implemented by the processor // // module to generate custom representation of 3byte data. // // args: // // ea_t dataea - address of the data item // // uint32 value - value to output // // bool analyze_only - only create xrefs if necessary // // do not generate text representation // // returns: 2-yes, 1-false // // get_reg_name, // Generate text representation of a register // // int reg - internal register number as defined in the processor module // // size_t width - register width in bytes // // char *buf - output buffer // // size_t bufsize - size of output buffer // // int reghi - if not -1 then this function will return the register pair // // returns: -1 if error, strlen(buf)+2 otherwise // // Most processor modules do not need to implement this callback // // It is useful only if ph.regNames[reg] does not provide // // the correct register names // // save its local data // out_src_file_lnnum, // Callback: generate analog of // // #line "file.c" 123 // // directive. // // const char *file - source file (may be NULL) // // size_t lnnum - line number // // returns: 2-directive has been generated // get_autocmt, // Callback: get dynamic auto comment // // Will be called if the autocomments are enabled // // and the comment retrieved from ida.int starts with // // '$!'. 'cmd' is contains valid info. // // char *buf - output buffer // // size_t bufsize - output buffer size // // returns: 2-new comment has been generated // // 1-callback has not been handled // // the buffer must not be changed in this case // is_insn_table_jump, // Callback: determine if instruction is a table jump or call // // If CF_JUMP bit can not describe all kinds of table // // jumps, please define this callback. // // It will be called for insns with CF_JUMP bit set. // // input: cmd structure contains the current instruction // // returns: 1-yes, 0-no // auto_empty_finally, // Info: all analysis queues are empty definitively // // args: none // // returns: none // // This callback is called only once. // // See also auto_empty. // loader_finished, // Event: external file loader finished its work // // linput_t *li // // uint16 neflags // // const char *filetypename // // Use this event to augment the existing loader functionality // loader_elf_machine, // Event: ELF loader machine type checkpoint // // linput_t *li // // int machine_type // // const char **p_procname // // proc_def **p_pd (see ldr\elf.h) // // set_elf_reloc_t *set_reloc // // A plugin check the machine_type. If it is the desired one, // // the the plugin fills p_procname with the processor name. // // p_pd is used to handle relocations, otherwise can be left untouched // // set_reloc can be later used by the plugin to specify relocations // // returns: e_machine value (if it is different from the // // original e_machine value, procname and p_pd will be ignored // // and the new value will be used) // // This event occurs for each loaded ELF file // is_indirect_jump, // Callback: determine if instruction is an indrect jump // // If CF_JUMP bit can not describe all jump types // // jumps, please define this callback. // // input: cmd structure contains the current instruction // // returns: 1-use CF_JUMP, 2-no, 3-yes // verify_noreturn, // The kernel wants to set 'noreturn' flags for a function // // func_t *pfn // // Returns: 1-ok, any other value-do not set 'noreturn' flag // verify_sp, // All function instructions have been analyzed // // Now the processor module can analyze the stack pointer // // for the whole function // // input: func_t *pfn // // Returns: 1-ok, 0-bad stack pointer // treat_hindering_item, // An item hinders creation of another item // // args: ea_t hindering_item_ea // // flags_t new_item_flags (0 for code) // // ea_t new_item_ea // // asize_t new_item_length // // Returns: 1-no reaction, <=0-the kernel may delete the hindering item // str2reg, // Convert a register name to a register number // // args: const char *regname // // Returns: register number + 2 // // The register number is the register index in the regNames array // // Most processor modules do not need to implement this callback // // It is useful only if ph.regNames[reg] does not provide // // the correct register names // create_switch_xrefs, // Create xrefs for a custom jump table // // in: ea_t jumpea; - address of the jump insn // // switch_info_ex_t *; - switch information // // returns: must return 2 // calc_switch_cases, // Calculate case values and targets for a custom jump table // // in: ea_t insn_ea - address of the 'indirect jump' instruction // // switch_info_ex_t *si - switch information // // casevec_t *casevec - vector of case values... // // evec_t *targets - ...and corresponding target addresses // // casevec and targets may be NULL // // returns: 2-ok, 1-failed // determined_main, // The main() function has been determined // // in: ea_t main - address of the main() function // // returns: none // preprocess_chart, // gui has retrieved a function flow chart // // in: qflow_chart_t *fc // // returns: none // // Plugins may modify the flow chart in this callback // get_bg_color, // Get item background color // // in: ea_t ea, bgcolor_t *color // // Returns: 1-not implemented, 2-color set // // Plugins can hook this callback to color disassembly lines // // dynamically // get_operand_string, // Request text string for operand (cli, java, ...) // // args: int opnum // // char *buf // // size_t buflen // // (cmd structure must contain info for the desired insn) // // opnum is the operand number; -1 means any string operand // // returns: 1 - no string (or empty string) // // >1 - original string length with terminating zero // // // the following 5 events are very low level // // take care of possible recursion // add_cref, // a code reference is being created // // args: ea_t from, ea_t to, cref_t type // // returns: <0 - cancel cref creation // add_dref, // a data reference is being created // // args: ea_t from, ea_t to, dref_t type // // returns: <0 - cancel dref creation // del_cref, // a code reference is being deleted // // args: ea_t from, ea_t to, bool expand // // returns: <0 - cancel cref deletion // del_dref, // a data reference is being deleted // // args: ea_t from, ea_t to // // returns: <0 - cancel dref deletion // coagulate_dref, // data reference is being analyzed // // args: ea_t from, ea_t to, bool may_define, ea_t *code_ea // // plugin may correct code_ea (e.g. for thumb mode refs, we clear the last bit) // // returns: <0 - cancel dref analysis // custom_fixup, // mutipurpose notification for FIXUP_CUSTOM // // args: cust_fix oper, ea_t ea, const fixup_data_t*, ... (see cust_fix) // // returns: 1 - no accepted (fixup ignored by ida) // // >1 - accepted (see cust_fix) // off_preproc, // called from get_offset_expr, when refinfo_t // // contain flag REFINFO_PREPROC. Normally this // // notification used in a combination with custom_fixup // // args: ea_t ea, int numop, ea_t* opval, const refinfo_t* ri, // // char* buf, size_t bufsize, ea_t* target, // // ea_t* fullvalue, ea_t from, int getn_flags // // returns: 2 - buf filled as simple expression // // 3 - buf filled as complex expression // // 4 - apply standard processing (with - possible - changed values) // // others - can't convert to offset expression // // set_proc_options, // called if the user specified an option string in the command line: // // -p: // // can be used for e.g. setting a processor subtype // // also called if option string is passed to set_processor_type() // // and IDC's SetProcessorType() // // args: const char * options // // returns: <0 - bad option string // } } catch (Swig::DirectorException &e) { msg("Exception in IDP Hook function: %s\n", e.getMessage()); PYW_GIL_CHECK_LOCKED_SCOPE(); if ( PyErr_Occurred() ) PyErr_Print(); } return ret; } //--------------------------------------------------------------------------- int idaapi IDB_Callback(void *ud, int notification_code, va_list va) { // This hook gets called from the kernel. Ensure we hold the GIL. PYW_GIL_GET; class IDB_Hooks *proxy = (class IDB_Hooks *)ud; ea_t ea, ea2; bool repeatable_cmt; /*type_t *type;*/ /* p_list *fnames; */ int n; enum_t id; const_t cid; tid_t struc_id; struc_t *sptr; member_t *mptr; tid_t member_id; func_t *pfn; func_t *tail; segment_t *seg; asize_t size; try { switch (notification_code) { case idb_event::byte_patched: ea = va_arg(va, ea_t); return proxy->byte_patched(ea); case idb_event::cmt_changed: ea = va_arg(va, ea_t); repeatable_cmt = va_arg(va, int); return proxy->cmt_changed(ea, repeatable_cmt); #if 0 case idb_event::ti_changed: ea = va_arg(va, ea_t); type = va_arg(va, type_t *); fnames = va_arg(va, fnames); return proxy->ti_changed(ea, type, fnames); case idb_event::op_ti_changed: ea = va_arg(va, ea_t); n = va_arg(va, int); type = va_arg(va, type_t *); fnames = va_arg(va, fnames); return proxy->op_ti_changed(ea, n, type, fnames); #endif case idb_event::op_type_changed: ea = va_arg(va, ea_t); n = va_arg(va, int); return proxy->op_type_changed(ea, n); case idb_event::enum_created: id = va_arg(va, enum_t); return proxy->enum_created(id); case idb_event::enum_deleted: id = va_arg(va, enum_t); return proxy->enum_deleted(id); case idb_event::enum_bf_changed: id = va_arg(va, enum_t); return proxy->enum_bf_changed(id); case idb_event::enum_cmt_changed: id = va_arg(va, enum_t); return proxy->enum_cmt_changed(id); #ifdef NO_OBSOLETE_FUNCS case idb_event::enum_member_created: #else case idb_event::enum_const_created: #endif id = va_arg(va, enum_t); cid = va_arg(va, const_t); return proxy->enum_member_created(id, cid); #ifdef NO_OBSOLETE_FUNCS case idb_event::enum_member_deleted: #else case idb_event::enum_const_deleted: #endif id = va_arg(va, enum_t); cid = va_arg(va, const_t); return proxy->enum_member_deleted(id, cid); case idb_event::struc_created: struc_id = va_arg(va, tid_t); return proxy->struc_created(struc_id); case idb_event::struc_deleted: struc_id = va_arg(va, tid_t); return proxy->struc_deleted(struc_id); case idb_event::struc_renamed: sptr = va_arg(va, struc_t *); return proxy->struc_renamed(sptr); case idb_event::struc_expanded: sptr = va_arg(va, struc_t *); return proxy->struc_expanded(sptr); case idb_event::struc_cmt_changed: struc_id = va_arg(va, tid_t); return proxy->struc_cmt_changed(struc_id); case idb_event::struc_member_created: sptr = va_arg(va, struc_t *); mptr = va_arg(va, member_t *); return proxy->struc_member_created(sptr, mptr); case idb_event::struc_member_deleted: sptr = va_arg(va, struc_t *); member_id = va_arg(va, tid_t); ea = va_arg(va, ea_t); return proxy->struc_member_deleted(sptr, member_id, ea); case idb_event::struc_member_renamed: sptr = va_arg(va, struc_t *); mptr = va_arg(va, member_t *); return proxy->struc_member_renamed(sptr, mptr); case idb_event::struc_member_changed: sptr = va_arg(va, struc_t *); mptr = va_arg(va, member_t *); return proxy->struc_member_changed(sptr, mptr); case idb_event::thunk_func_created: pfn = va_arg(va, func_t *); return proxy->thunk_func_created(pfn); case idb_event::func_tail_appended: pfn = va_arg(va, func_t *); tail = va_arg(va, func_t *); return proxy->func_tail_appended(pfn, tail); case idb_event::func_tail_removed: pfn = va_arg(va, func_t *); ea = va_arg(va, ea_t); return proxy->func_tail_removed(pfn, ea); case idb_event::tail_owner_changed: tail = va_arg(va, func_t *); ea = va_arg(va, ea_t); return proxy->tail_owner_changed(tail, ea); case idb_event::func_noret_changed: pfn = va_arg(va, func_t *); return proxy->func_noret_changed(pfn); case idb_event::segm_added: seg = va_arg(va, segment_t *); return proxy->segm_added(seg); case idb_event::segm_deleted: ea = va_arg(va, ea_t); return proxy->segm_deleted(ea); case idb_event::segm_start_changed: seg = va_arg(va, segment_t *); return proxy->segm_start_changed(seg); case idb_event::segm_end_changed: seg = va_arg(va, segment_t *); return proxy->segm_end_changed(seg); case idb_event::segm_moved: ea = va_arg(va, ea_t); ea2 = va_arg(va, ea_t); size = va_arg(va, asize_t); return proxy->segm_moved(ea, ea2, size); } } catch (Swig::DirectorException &e) { msg("Exception in IDB Hook function: %s\n", e.getMessage()); PYW_GIL_CHECK_LOCKED_SCOPE(); if (PyErr_Occurred()) PyErr_Print(); } return 0; } //------------------------------------------------------------------------- static const regval_t *idaapi _py_getreg( const char *name, const regval_t *regvals) { for ( int i=dbg->registers_size - 1; i >= 0; i-- ) { if ( stricmp(name, dbg->registers[i].name) == 0 ) return ®vals[i]; } static regval_t rv; return &rv; } //------------------------------------------------------------------------- // %}