#ifdef __NT__ %{ // class py_graph_t { private: enum { GR_HAVE_USER_HINT = 0x00000001, GR_HAVE_CLICKED = 0x00000002, GR_HAVE_DBL_CLICKED = 0x00000004, GR_HAVE_GOTFOCUS = 0x00000008, GR_HAVE_LOSTFOCUS = 0x00000010, GR_HAVE_CHANGED_CURRENT = 0x00000020, GR_HAVE_CLOSE = 0x00000040, GR_HAVE_COMMAND = 0x00000080 }; struct nodetext_cache_t { qstring text; bgcolor_t bgcolor; nodetext_cache_t(const nodetext_cache_t &rhs): text(rhs.text), bgcolor(rhs.bgcolor) { } nodetext_cache_t(const char *t, bgcolor_t c): text(t), bgcolor(c) { } nodetext_cache_t() { } }; class nodetext_cache_map_t: public std::map { public: nodetext_cache_t *get(int node_id) { iterator it = find(node_id); if ( it == end() ) return NULL; return &it->second; } nodetext_cache_t *add(const int node_id, const char *text, bgcolor_t bgcolor = DEFCOLOR) { return &(insert(std::make_pair(node_id, nodetext_cache_t(text, bgcolor))).first->second); } }; class tform_pygraph_map_t: public std::map { public: py_graph_t *get(TForm *form) { iterator it = find(form); return it == end() ? NULL : it->second; } void add(TForm *form, py_graph_t *py) { (*this)[form] = py; } }; class cmdid_map_t: public std::map { private: Py_ssize_t uid; public: cmdid_map_t() { uid = 1; // we start by one and keep zero for error id } void add(py_graph_t *pyg) { (*this)[uid] = pyg; ++uid; } const Py_ssize_t id() const { return uid; } void clear(py_graph_t *pyg) { iterator e = end(); for (iterator it=begin();it!=end();) { if ( it->second == pyg ) { iterator temp = it++; erase(temp); } else ++it; } } py_graph_t *get(Py_ssize_t id) { iterator it = find(id); return it == end() ? NULL : it->second; } }; static tform_pygraph_map_t tform_pyg; static cmdid_map_t cmdid_pyg; int cb_flags; TForm *form; graph_viewer_t *gv; bool refresh_needed; PyObject *self; nodetext_cache_map_t node_cache; // static callback static int idaapi s_callback(void *obj, int code, va_list va) { return ((py_graph_t *)obj)->gr_callback(code, va); } static bool idaapi s_menucb(void *ud) { Py_ssize_t id = (Py_ssize_t)ud; py_graph_t *_this = cmdid_pyg.get(id); if ( _this != NULL ) _this->on_command(id); return true; } void on_command(Py_ssize_t id) { // Check return value to OnRefresh() call PyObject *ret = PyObject_CallMethod(self, (char *)S_ON_COMMAND, "n", id); Py_XDECREF(ret); } // Refresh user-defined graph node number and edges // It calls Python method and expects that the user already filled // the nodes and edges. The nodes and edges are retrieved and passed to IDA void on_user_refresh(mutable_graph_t *g) { if ( !refresh_needed ) return; // Check return value to OnRefresh() call PyObject *ret = PyObject_CallMethod(self, (char *)S_ON_REFRESH, NULL); if ( ret == NULL || !PyObject_IsTrue(ret) ) { Py_XDECREF(ret); return; } // Refer to the nodes PyObject *nodes = PyObject_TryGetAttrString(self, S_M_NODES); if ( ret == NULL || !PyList_Check(nodes) ) { Py_XDECREF(nodes); return; } // Refer to the edges PyObject *edges = PyObject_TryGetAttrString(self, S_M_EDGES); if ( ret == NULL || !PyList_Check(nodes) ) { Py_DECREF(nodes); Py_XDECREF(edges); return; } // Resize the nodes int max_nodes = abs(int(PyList_Size(nodes))); g->clear(); g->resize(max_nodes); // Mark that we refreshed already refresh_needed = false; // Clear cached nodes node_cache.clear(); // Get the edges for ( int i=(int)PyList_Size(edges)-1; i>=0; i-- ) { // Each list item is a sequence (id1, id2) PyObject *item = PyList_GetItem(edges, i); if ( !PySequence_Check(item) ) continue; // Get and validate each of the two elements in the sequence int edge_ids[2]; int j; for ( j=0; j max_nodes ) break; edge_ids[j] = v; } // Incomplete? if ( j != qnumber(edge_ids) ) break; // Add the edge g->add_edge(edge_ids[0], edge_ids[1], NULL); } Py_DECREF(nodes); Py_DECREF(edges); } // Retrieves the text for user-defined graph node // It expects either a string or a tuple (string, bgcolor) bool on_user_text(mutable_graph_t * /*g*/, int node, const char **str, bgcolor_t *bg_color) { // If already cached then return the value nodetext_cache_t *c = node_cache.get(node); if ( c != NULL ) { *str = c->text.c_str(); if ( bg_color != NULL ) *bg_color = c->bgcolor; return true; } // Not cached, call Python PyObject *result = PyObject_CallMethod(self, (char *)S_ON_GETTEXT, "i", node); if ( result == NULL ) return false; bgcolor_t cl = bg_color == NULL ? DEFCOLOR : *bg_color; const char *s; // User returned a string? if ( PyString_Check(result) ) { s = PyString_AsString(result); if ( s == NULL ) s = ""; c = node_cache.add(node, s, cl); } // User returned a sequence of text and bgcolor else if ( PySequence_Check(result) && PySequence_Size(result) == 2 ) { PyObject *py_str = PySequence_GetItem(result, 0); PyObject *py_color = PySequence_GetItem(result, 1); if ( py_str == NULL || !PyString_Check(py_str) || (s = PyString_AsString(py_str)) == NULL ) s = ""; if ( py_color != NULL && PyNumber_Check(py_color) ) cl = bgcolor_t(PyLong_AsUnsignedLong(py_color)); c = node_cache.add(node, s, cl); Py_XDECREF(py_str); Py_XDECREF(py_color); } Py_DECREF(result); *str = c->text.c_str(); if ( bg_color != NULL ) *bg_color = c->bgcolor; return true; } // Retrieves the hint for the user-defined graph // Calls Python and expects a string or None int on_user_hint(mutable_graph_t *, int mousenode, int /*mouseedge_src*/, int /*mouseedge_dst*/, char **hint) { // 'hint' must be allocated by qalloc() or qstrdup() // out: 0-use default hint, 1-use proposed hint // We dispatch hints over nodes only if ( mousenode == -1 ) return 0; PyObject *result = PyObject_CallMethod(self, (char *)S_ON_HINT, "i", mousenode); bool ok = result != NULL && PyString_Check(result); if ( !ok ) { Py_XDECREF(result); return 0; } *hint = qstrdup(PyString_AsString(result)); Py_DECREF(result); return 1; // use our hint } // graph is being destroyed void on_destroy(mutable_graph_t * /*g*/ = NULL) { if ( self != NULL ) { if ( cb_flags & GR_HAVE_CLOSE ) { PyObject *result = PyObject_CallMethod(self, (char *)S_ON_CLOSE, NULL); Py_XDECREF(result); } unbind(); } // Remove the TForm from list if ( form != NULL ) tform_pyg.erase(form); // remove all associated commands from the list cmdid_pyg.clear(this); // Delete this instance delete this; } // graph is being clicked int on_clicked(graph_viewer_t * /*gv*/, selection_item_t * /*item1*/, graph_item_t *item2) { // in: graph_viewer_t *gv // selection_item_t *current_item1 // graph_item_t *current_item2 // out: 0-ok, 1-ignore click // this callback allows you to ignore some clicks. // it occurs too early, internal graph variables are not updated yet // current_item1, current_item2 point to the same thing // item2 has more information. // see also: kernwin.hpp, custom_viewer_click_t if ( item2->n == -1 ) return 1; PyObject *result = PyObject_CallMethod(self, (char *)S_ON_CLICK, "i", item2->n); if ( result == NULL || !PyObject_IsTrue(result) ) { Py_XDECREF(result); return 1; } Py_DECREF(result); return 0; } // a graph node has been double clicked int on_dblclicked(graph_viewer_t * /*gv*/, selection_item_t *item) { // in: graph_viewer_t *gv // selection_item_t *current_item // out: 0-ok, 1-ignore click //graph_viewer_t *v = va_arg(va, graph_viewer_t *); //selection_item_t *s = va_arg(va, selection_item_t *); if ( item == NULL || !item->is_node ) return 1; PyObject *result = PyObject_CallMethod(self, (char *)S_ON_DBL_CLICK, "i", item->node); if ( result == NULL || !PyObject_IsTrue(result) ) { Py_XDECREF(result); return 1; } Py_DECREF(result); return 0; } // a graph viewer got focus void on_gotfocus(graph_viewer_t * /*gv*/) { PyObject *result = PyObject_CallMethod(self, (char *)S_ON_ACTIVATE, NULL); Py_XDECREF(result); } // a graph viewer lost focus void on_lostfocus(graph_viewer_t *gv) { PyObject *result = PyObject_CallMethod(self, (char *)S_ON_DEACTIVATE, NULL); Py_XDECREF(result); } // a new graph node became the current node int on_changed_current(graph_viewer_t * /*gv*/, int curnode) { // in: graph_viewer_t *gv // int curnode // out: 0-ok, 1-forbid to change the current node if ( curnode < 0 ) return 0; PyObject *result = PyObject_CallMethod(self, (char *)S_ON_SELECT, "i", curnode); bool allow = (result != NULL && PyObject_IsTrue(result)); Py_XDECREF(result); return allow ? 0 : 1; } int gr_callback(int code, va_list va) { int ret; switch ( code ) { // case grcode_user_text: { mutable_graph_t *g = va_arg(va, mutable_graph_t *); int node = va_arg(va, int); const char **result = va_arg(va, const char **); bgcolor_t *bgcolor = va_arg(va, bgcolor_t *); ret = on_user_text(g, node, result, bgcolor); break; } // case grcode_destroyed: on_destroy(va_arg(va, mutable_graph_t *)); ret = 0; break; // case grcode_clicked: if ( cb_flags & GR_HAVE_CLICKED ) { graph_viewer_t *gv = va_arg(va, graph_viewer_t *); selection_item_t *item = va_arg(va, selection_item_t *); graph_item_t *gitem = va_arg(va, graph_item_t *); ret = on_clicked(gv, item, gitem); } else ret = 1; // ignore click break; // case grcode_dblclicked: if ( cb_flags & GR_HAVE_DBL_CLICKED ) { graph_viewer_t *gv = va_arg(va, graph_viewer_t *); selection_item_t *item = va_arg(va, selection_item_t *); ret = on_dblclicked(gv, item); } else ret = 1; // ignore break; // case grcode_gotfocus: if ( cb_flags & GR_HAVE_GOTFOCUS ) on_gotfocus(va_arg(va, graph_viewer_t *)); ret = 0; break; // case grcode_lostfocus: if ( cb_flags & GR_HAVE_LOSTFOCUS ) on_lostfocus(va_arg(va, graph_viewer_t *)); ret = 0; break; // case grcode_user_refresh: on_user_refresh(va_arg(va, mutable_graph_t *)); ret = 1; break; // case grcode_user_hint: if ( cb_flags & GR_HAVE_USER_HINT ) { mutable_graph_t *g = va_arg(va, mutable_graph_t *); int mousenode = va_arg(va, int); int mouseedge_src = va_arg(va, int); int mouseedge_dest = va_arg(va, int); char **hint = va_arg(va, char **); ret = on_user_hint(g, mousenode, mouseedge_src, mouseedge_dest, hint); } else { ret = 0; } break; // case grcode_changed_current: if ( cb_flags & GR_HAVE_CHANGED_CURRENT ) { graph_viewer_t *gv = va_arg(va, graph_viewer_t *); int cur_node = va_arg(va, int); ret = on_changed_current(gv, cur_node); } else ret = 0; // allow selection change break; // default: ret = 0; break; } //grcode_changed_graph, // new graph has been set //grcode_creating_group, // a group is being created //grcode_deleting_group, // a group is being deleted //grcode_group_visibility, // a group is being collapsed/uncollapsed //grcode_user_size, // calculate node size for user-defined graph //grcode_user_title, // render node title of a user-defined graph //grcode_user_draw, // render node of a user-defined graph return ret; } void unbind() { if ( self == NULL ) return; // Unbind this object from the python object PyObject *py_cobj = PyCObject_FromVoidPtr(NULL, NULL); PyObject_SetAttrString(self, S_M_THIS, py_cobj); Py_DECREF(py_cobj); Py_XDECREF(self); self = NULL; } void show() { open_tform(form, FORM_MDI|FORM_TAB|FORM_MENU); } static py_graph_t *extract_this(PyObject *self) { // Try to extract "this" from the python object PyObject *py_this = PyObject_TryGetAttrString(self, S_M_THIS); if ( py_this == NULL || !PyCObject_Check(py_this) ) { Py_XDECREF(py_this); return NULL; } py_graph_t *ret = (py_graph_t *) PyCObject_AsVoidPtr(py_this); Py_DECREF(py_this); return ret; } void jump_to_node(int nid) { viewer_center_on(gv, nid); int x, y; // will return a place only when a node was previously selected place_t *old_pl = get_custom_viewer_place(gv, false, &x, &y); if ( old_pl != NULL ) { user_graph_place_t *new_pl = (user_graph_place_t *) old_pl->clone(); new_pl->node = nid; jumpto(gv, new_pl, x, y); delete new_pl; } } void refresh() { refresh_needed = true; refresh_viewer(gv); } static bool extract_title(PyObject *self, qstring *title) { PyObject *py_title = PyObject_TryGetAttrString(self, S_M_TITLE); if ( py_title == NULL ) return false; *title = PyString_AsString(py_title); Py_DECREF(py_title); return true; } int create(PyObject *self, const char *title) { // check what callbacks we have static const struct { const char *name; int have; } callbacks[] = { {S_ON_REFRESH, 0}, // 0 = mandatory callback {S_ON_GETTEXT, 0}, {S_M_EDGES, -1}, // -1 = mandatory attributes {S_M_NODES, -1}, {S_ON_HINT, GR_HAVE_USER_HINT}, {S_ON_CLICK, GR_HAVE_CLICKED}, {S_ON_DBL_CLICK, GR_HAVE_DBL_CLICKED}, {S_ON_CLOSE, GR_HAVE_CLOSE}, {S_ON_COMMAND, GR_HAVE_COMMAND}, {S_ON_SELECT, GR_HAVE_CHANGED_CURRENT}, {S_ON_ACTIVATE, GR_HAVE_GOTFOCUS}, {S_ON_DEACTIVATE, GR_HAVE_LOSTFOCUS} }; cb_flags = 0; for ( int i=0; i= 0 && PyCallable_Check(attr) == 0)) { Py_XDECREF(attr); return -1; } if ( have > 0 && attr != NULL ) cb_flags |= have; Py_XDECREF(attr); } // Keep a reference this->self = self; Py_INCREF(self); // Bind py_graph_t to python object PyObject *py_cobj = PyCObject_FromVoidPtr(this, NULL); PyObject_SetAttrString(self, S_M_THIS, py_cobj); Py_DECREF(py_cobj); // Create form HWND hwnd = NULL; form = create_tform(title, &hwnd); // Link "form" and "py_graph" tform_pyg.add(form, this); if ( hwnd != NULL ) { // get a unique graph id netnode id; id.create(); gv = create_graph_viewer(form, id, s_callback, this, 0); open_tform(form, FORM_MDI|FORM_TAB|FORM_MENU); if ( gv != NULL ) viewer_fit_window(gv); } else { show(); } viewer_fit_window(gv); return 0; } Py_ssize_t add_command(const char *title, const char *hotkey) { if ( (cb_flags & GR_HAVE_COMMAND) == 0 || gv == NULL) return 0; Py_ssize_t cmd_id = cmdid_pyg.id(); bool ok = viewer_add_menu_item(gv, title, s_menucb, (void *)cmd_id, hotkey, 0); if ( !ok ) return 0; cmdid_pyg.add(this); return cmd_id; } public: py_graph_t() { form = NULL; gv = NULL; refresh_needed = true; self = NULL; } static void SelectNode(PyObject *self, int nid) { py_graph_t *_this = extract_this(self); if ( _this == NULL || _this->form == NULL ) return; _this->jump_to_node(0); } static Py_ssize_t AddCommand(PyObject *self, const char *title, const char *hotkey) { py_graph_t *_this = extract_this(self); if ( _this == NULL || _this->form == NULL ) return 0; return _this->add_command(title, hotkey); } static void Close(PyObject *self) { py_graph_t *_this = extract_this(self); if ( _this == NULL || _this->form == NULL ) return; close_tform(_this->form, 0); } static void Refresh(PyObject *self) { py_graph_t *_this = extract_this(self); if ( _this == NULL ) return; _this->refresh(); } static py_graph_t *Show(PyObject *self) { py_graph_t *ret = extract_this(self); if ( ret == NULL ) { qstring title; if ( !extract_title(self, &title) ) return NULL; // Form already created? try to get associated py_graph instance // so that we reuse it ret = tform_pyg.get(find_tform(title.c_str())); // Instance not found? create a new one if ( ret == NULL ) ret = new py_graph_t(); else { // unbind so we are rebound ret->unbind(); ret->refresh_needed = true; } if ( ret->create(self, title.c_str()) < 0 ) { delete ret; ret = NULL; } } else { ret->show(); } return ret; } }; py_graph_t::tform_pygraph_map_t py_graph_t::tform_pyg; py_graph_t::cmdid_map_t py_graph_t::cmdid_pyg; bool pyg_show(PyObject *self) { return py_graph_t::Show(self) != NULL; } void pyg_refresh(PyObject *self) { py_graph_t::Refresh(self); } void pyg_close(PyObject *self) { py_graph_t::Close(self); } PyObject *pyg_add_command(PyObject *self, const char *title, const char *hotkey) { return Py_BuildValue("n", py_graph_t::AddCommand(self, title, hotkey)); } void pyg_select_node(PyObject *self, int nid) { py_graph_t::SelectNode(self, nid); } // %} #endif #ifdef __NT__ %inline %{ // void pyg_refresh(PyObject *self); void pyg_close(PyObject *self); PyObject *pyg_add_command(PyObject *self, const char *title, const char *hotkey); void pyg_select_node(PyObject *self, int nid); bool pyg_show(PyObject *self); // %} #endif #ifdef __NT__ %pythoncode %{ # class GraphViewer: """This class wraps the user graphing facility provided by the graph.hpp file""" def __init__(self, title, close_open = False): """ Constructs the GraphView object. Please do not remove or rename the private fields @param title: The title of the graph window @param close_open: Should it attempt to close an existing graph (with same title) before creating this graph? """ self._title = title self._nodes = [] self._edges = [] self._close_open = close_open def AddNode(self, obj): """Creates a node associated with the given object and returns the node id""" id = len(self._nodes) self._nodes.append(obj) return id def AddEdge(self, src_node, dest_node): """Creates an edge between two given node ids""" self._edges.append( (src_node, dest_node) ) def Clear(self): """Clears all the nodes and edges""" self._nodes = [] self._edges = [] def __getitem__(self, idx): """Returns a reference to the object associated with this node id""" if idx > len(self._nodes): raise StopIteration return self._nodes[idx] def Count(self): """Returns the node count""" return len(self._nodes) def Close(self): """ Closes the graph. It is possible to call Show() again (which will recreate the graph) """ _idaapi.pyg_close(self) def Refresh(self): """ Refreshes the graph. This causes the OnRefresh() to be called """ _idaapi.pyg_refresh(self) def Show(self): """ Shows an existing graph or creates a new one @return: Boolean """ if self._close_open: frm = _idaapi.find_tform(self._title) if frm: _idaapi.close_tform(frm, 0) return _idaapi.pyg_show(self) def Select(self, node_id): """Selects a node on the graph""" _idaapi.pyg_select_node(self, node_id) def AddCommand(self, title, hotkey): """ Adds a menu command to the graph. Call this command after the graph is shown (with Show()). Once a command is added, a command id is returned. The commands are handled inside the OnCommand() handler @return: 0 on failure or the command id """ return _idaapi.pyg_add_command(self, title, hotkey) def OnRefresh(self): """ Event called when the graph is refreshed or first created. From this event you are supposed to create nodes and edges. This callback is mandatory. @note: ***It is important to clear previous nodes before adding nodes.*** @return: Returning True tells the graph viewer to use the items. Otherwise old items will be used. """ self.Clear() return True # # def OnGetText(self, node_id): # """ # Triggered when the graph viewer wants the text and color for a given node. # This callback is triggered one time for a given node (the value will be cached and used later without calling Python). # When you call refresh then again this callback will be called for each node. # # This callback is mandatory. # # @return: Return a string to describe the node text or return a tuple (node_text, node_color) to describe both text and color # """ # return str(self[node_id]) # # def OnActivate(self): # """ # Triggered when the graph window gets the focus # @return: None # """ # print "Activated...." # # def OnDeactivate(self): # """Triggered when the graph window loses the focus # @return: None # """ # print "Deactivated...." # # def OnSelect(self, node_id): # """ # Triggered when a node is being selected # @return: Return True to allow the node to be selected or False to disallow node selection change # """ # # allow selection change # return True # # def OnHint(self, node_id): # """ # Triggered when the graph viewer wants to retrieve hint text associated with a given node # # @return: None if no hint is avail or a string designating the hint # """ # return "hint for " + str(node_id) # # def OnClose(self): # """Triggered when the graph viewer window is being closed # @return: None # """ # print "Closing......." # # def OnClick(self, node_id): # """ # Triggered when a node is clicked # @return: False to ignore the click and True otherwise # """ # print "clicked on", self[node_id] # return True # # def OnDblClick(self, node_id): # """ # Triggerd when a node is double-clicked. # @return: False to ignore the click and True otherwise # """ # print "dblclicked on", self[node_id] # return True # # def OnCommand(self, cmd_id): # """ # Triggered when a menu command is selected through the menu or its hotkey # @return: None # """ # print "command:", cmd_id # # %} #endif