| Quellcodebibliothek Statistik Leitseite products/Sources/formale Sprachen/C/Linux/tools/verification/rvgen/rvgen/ (Open Source Betriebssystem Version 6.17.9©) Datei vom 24.10.2025 mit Größe 7 kB |
|
Quelle automata.py Sprache: Python |
|||||||||||||||
|
#!/usr/bin/env python3 # SPDX-License-Identifier: GPL-2.0-only # # Copyright (C) 2019-2022 Red Hat, Inc. Daniel Bristot de Oliveira <bristot@kernel.org> # # Automata object: parse an automata in dot file digraph format into a python object # # For further information, see: # Documentation/trace/rv/deterministic_automata.rst import ntpath class Automata: """Automata class: Reads a dot file and part it as an automata. Attributes: dot_file: A dot file with an state_automaton definition. """ invalid_state_str = "INVALID_STATE" def __init__(self, file_path, model_name=None): self.__dot_path = file_path self.name = model_name or self.__get_model_name() self.__dot_lines = self.__open_dot() self.states, self.initial_state, self.final_states = self.__get_state_variables() self.events = self.__get_event_variables() self.function = self.__create_matrix() self.events_start, self.events_start_run = self.__store_init_events() def __get_model_name(self): basename = ntpath.basename(self.__dot_path) if not basename.endswith(".dot") and not basename.endswith(".gv"): print("not a dot file") raise Exception("not a dot file: %s" % self.__dot_path) model_name = ntpath.splitext(basename)[0] if model_name.__len__() == 0: raise Exception("not a dot file: %s" % self.__dot_path) return model_name def __open_dot(self): cursor = 0 dot_lines = [] try: dot_file = open(self.__dot_path) except: raise Exception("Cannot open the file: %s" % self.__dot_path) dot_lines = dot_file.read().splitlines() dot_file.close() # checking the first line: line = dot_lines[cursor].split() if (line[0] != "digraph") and (line[1] != "state_automaton"): raise Exception("Not a valid .dot format: %s" % self.__dot_path) else: cursor += 1 return dot_lines def __get_cursor_begin_states(self): cursor = 0 while self.__dot_lines[cursor].split()[0] != "{node": cursor += 1 return cursor def __get_cursor_begin_events(self): cursor = 0 while self.__dot_lines[cursor].split()[0] != "{node": cursor += 1 while self.__dot_lines[cursor].split()[0] == "{node": cursor += 1 # skip initial state transition cursor += 1 return cursor def __get_state_variables(self): # wait for node declaration states = [] final_states = [] has_final_states = False cursor = self.__get_cursor_begin_states() # process nodes while self.__dot_lines[cursor].split()[0] == "{node": line = self.__dot_lines[cursor].split() raw_state = line[-1] # "enabled_fired"}; -> enabled_fired state = raw_state.replace('"', '').replace('};', '').replace(',','_') if state[0:7] == "__init_": initial_state = state[7:] else: states.append(state) if "doublecircle" in self.__dot_lines[cursor]: final_states.append(state) has_final_states = True if "ellipse" in self.__dot_lines[cursor]: final_states.append(state) has_final_states = True cursor += 1 states = sorted(set(states)) states.remove(initial_state) # Insert the initial state at the bein og the states states.insert(0, initial_state) if not has_final_states: final_states.append(initial_state) return states, initial_state, final_states def __get_event_variables(self): # here we are at the begin of transitions, take a note, we will return later. cursor = self.__get_cursor_begin_events() events = [] while self.__dot_lines[cursor].lstrip()[0] == '"': # transitions have the format: # "all_fired" -> "both_fired" [ label = "disable_irq" ]; # ------------ event is here ------------^^^^^ if self.__dot_lines[cursor].split()[1] == "->": line = self.__dot_lines[cursor].split() event = line[-2].replace('"','') # when a transition has more than one lables, they are like this # "local_irq_enable\nhw_local_irq_enable_n" # so split them. event = event.replace("\\n", " ") for i in event.split(): events.append(i) cursor += 1 return sorted(set(events)) def __create_matrix(self): # transform the array into a dictionary events = self.events states = self.states events_dict = {} states_dict = {} nr_event = 0 for event in events: events_dict[event] = nr_event nr_event += 1 nr_state = 0 for state in states: states_dict[state] = nr_state nr_state += 1 # declare the matrix.... matrix = [[ self.invalid_state_str for x in range(nr_event)] for y in range(nr_state)] # and we are back! Let's fill the matrix cursor = self.__get_cursor_begin_events() while self.__dot_lines[cursor].lstrip()[0] == '"': if self.__dot_lines[cursor].split()[1] == "->": line = self.__dot_lines[cursor].split() origin_state = line[0].replace('"','').replace(',','_') dest_state = line[2].replace('"','').replace(',','_') possible_events = line[-2].replace('"','').replace("\\n", " ") for event in possible_events.split(): matrix[states_dict[origin_state]][events_dict[event]] = dest_state cursor += 1 return matrix def __store_init_events(self): events_start = [False] * len(self.events) events_start_run = [False] * len(self.events) for i, _ in enumerate(self.events): curr_event_will_init = 0 curr_event_from_init = False curr_event_used = 0 for j, _ in enumerate(self.states): if self.function[j][i] != self.invalid_state_str: curr_event_used += 1 if self.function[j][i] == self.initial_state: curr_event_will_init += 1 if self.function[0][i] != self.invalid_state_str: curr_event_from_init = True # this event always leads to init if curr_event_will_init and curr_event_used == curr_event_will_init: events_start[i] = True # this event is only called from init if curr_event_from_init and curr_event_used == 1: events_start_run[i] = True return events_start, events_start_run def is_start_event(self, event): return self.events_start[self.events.index(event)] def is_start_run_event(self, event): # prefer handle_start_event if there if any(self.events_start): return False return self.events_start_run[self.events.index(event)]
¤ Dauer der Verarbeitung: 0.13 Sekunden (vorverarbeitet) ¤*© Formatika GbR, Deutschland |
|
||||||||||||||
2026-04-06