dvdblk/DFAinput.txt

## DFAinput.txt
3
3
1
2
1 2
2 3 3
2 2 2
3 3 3

3
3
1
1
2
3 2 3
2 2 2
3 3 3

## dfaunion.py
class State:
	def __init__(self, identifier):
		self.identifier = str(identifier)
		self.transition_funcs = {}
	def __str__(self):
		return self.identifier
	def add_transition(self, withChar, to):
		self.transition_funcs[withChar] = to

class DFA:
	def __init__(self, alphabet_count):
		self.states = []
		self.alphabet = list(map(chr, range(97, 97+alphabet_count)))
		self.initial_state = None
		self.accepting_states = []

	def add_state(self, state, initial = False, accepting = False):
		self.states.append(state)
		if initial:
			self.initial_state = state
		if accepting:
			self.accepting_states.append(state)

	def output_DFA(self):
		print(len(self.states))
		print(len(self.alphabet))
		print(self.initial_state.identifier)
		print(len(self.accepting_states))
		print(" ".join(map(str, self.accepting_states)))
		for i in range(len(self.states)):
			self.print_state(i)

	def print_state(self, nr):
		result = ""
		for letter in self.alphabet:
			result = result + self.states[nr].transition_funcs[letter] + " "
		print(result)

if __name__ == "__main__":

	dfa_array = []
	#read file and create DFA's from input file
	with open("zadani02.aut", "r") as input_file:
		def rl(no_strip = False):
			read = input_file.readline
			if no_strip:
				return read()
			return read().rstrip('\n')

		for _ in range(2):
			number_of_states = int(rl())
			alphabet_count = int(rl())
			initial_state = int(rl())
			accepting_states_count = int(rl())
			accepting_states = list(map(int, rl().split()))
			# only 1 accepting state DFA fix...
			accepting_states_dict = dict(map(lambda x: (x+1,True) if x+1 in accepting_states else (x+1,False), range(0,number_of_states)))
			dfa = DFA(alphabet_count)
			for i in range(1,number_of_states+1):
				row = rl().split()
				state = State(i)
				for j in range(alphabet_count):
					state.add_transition(dfa.alphabet[j], row[j])
				dfa.add_state(state, i == initial_state, accepting_states_dict[i])
			dfa_array.append(dfa)
			#dfa.output_DFA()
			line = rl(True)
			if not line: break

    # compute their union...
	unified_dfa = DFA(len(dfa_array[0].alphabet))
	current_state = 1
	unified_temp_states_queue = [(dfa_array[0].initial_state.identifier+"-"+dfa_array[1].initial_state.identifier,current_state)]
	unified_states = {}
	while unified_temp_states_queue:
		top_item = unified_temp_states_queue.pop(0)
		if top_item[0] not in unified_states:
			state = State(top_item[1])
			current_state = top_item[1]
			# get the new state from 2 input DFA's
			states_to_be_unified = top_item[0].split("-")
			first = dfa_array[0].states[int(states_to_be_unified[0])-1]
			second = dfa_array[1].states[int(states_to_be_unified[1])-1]
			for letter in dfa_array[0].alphabet:
				first_to = first.transition_funcs[letter]
				second_to = second.transition_funcs[letter]
				result = first_to +"-"+ second_to
				if result not in [itm[0] for itm in unified_temp_states_queue]:
					current_state += 1
					unified_temp_states_queue.append((result, current_state))
				state.add_transition(letter, result)
			unified_states[top_item[0]] = top_item[1]
			is_initial = (dfa_array[0].initial_state == first) or (dfa_array[1].initial_state == second)
			is_accepting = (first in dfa_array[0].accepting_states) or (second in dfa_array[1].accepting_states)
			unified_dfa.add_state(state, is_initial, is_accepting)

	# and rename states
	for state in unified_dfa.states:
		for letter in state.transition_funcs:
			state.transition_funcs[letter] = str(unified_states[state.transition_funcs[letter]])

	unified_dfa.output_DFA()
	class State:
	def __init__(self, identifier):
	self.identifier = str(identifier)
	self.transition_funcs = {}
	def __str__(self):
	return self.identifier
	def add_transition(self, withChar, to):
	self.transition_funcs[withChar] = to

	class DFA:
	def __init__(self, alphabet_count):
	self.states = []
	self.alphabet = list(map(chr, range(97, 97+alphabet_count)))
	self.initial_state = None
	self.accepting_states = []

	def add_state(self, state, initial = False, accepting = False):
	self.states.append(state)
	if initial:
	self.initial_state = state
	if accepting:
	self.accepting_states.append(state)

	def output_DFA(self):
	print(len(self.states))
	print(len(self.alphabet))
	print(self.initial_state.identifier)
	print(len(self.accepting_states))
	print(" ".join(map(str, self.accepting_states)))
	for i in range(len(self.states)):
	self.print_state(i)

	def print_state(self, nr):
	result = ""
	for letter in self.alphabet:
	result = result + self.states[nr].transition_funcs[letter] + " "
	print(result)

	if __name__ == "__main__":

	dfa_array = []
	#read file and create DFA's from input file
	with open("zadani02.aut", "r") as input_file:
	def rl(no_strip = False):
	read = input_file.readline
	if no_strip:
	return read()
	return read().rstrip('\n')

	for _ in range(2):
	number_of_states = int(rl())
	alphabet_count = int(rl())
	initial_state = int(rl())
	accepting_states_count = int(rl())
	accepting_states = list(map(int, rl().split()))
	# only 1 accepting state DFA fix...
	accepting_states_dict = dict(map(lambda x: (x+1,True) if x+1 in accepting_states else (x+1,False), range(0,number_of_states)))
	dfa = DFA(alphabet_count)
	for i in range(1,number_of_states+1):
	row = rl().split()
	state = State(i)
	for j in range(alphabet_count):
	state.add_transition(dfa.alphabet[j], row[j])
	dfa.add_state(state, i == initial_state, accepting_states_dict[i])
	dfa_array.append(dfa)
	#dfa.output_DFA()
	line = rl(True)
	if not line: break

	# compute their union...
	unified_dfa = DFA(len(dfa_array[0].alphabet))
	current_state = 1
	unified_temp_states_queue = [(dfa_array[0].initial_state.identifier+"-"+dfa_array[1].initial_state.identifier,current_state)]
	unified_states = {}
	while unified_temp_states_queue:
	top_item = unified_temp_states_queue.pop(0)
	if top_item[0] not in unified_states:
	state = State(top_item[1])
	current_state = top_item[1]
	# get the new state from 2 input DFA's
	states_to_be_unified = top_item[0].split("-")
	first = dfa_array[0].states[int(states_to_be_unified[0])-1]
	second = dfa_array[1].states[int(states_to_be_unified[1])-1]
	for letter in dfa_array[0].alphabet:
	first_to = first.transition_funcs[letter]
	second_to = second.transition_funcs[letter]
	result = first_to +"-"+ second_to
	if result not in [itm[0] for itm in unified_temp_states_queue]:
	current_state += 1
	unified_temp_states_queue.append((result, current_state))
	state.add_transition(letter, result)
	unified_states[top_item[0]] = top_item[1]
	is_initial = (dfa_array[0].initial_state == first) or (dfa_array[1].initial_state == second)
	is_accepting = (first in dfa_array[0].accepting_states) or (second in dfa_array[1].accepting_states)
	unified_dfa.add_state(state, is_initial, is_accepting)

	# and rename states
	for state in unified_dfa.states:
	for letter in state.transition_funcs:
	state.transition_funcs[letter] = str(unified_states[state.transition_funcs[letter]])

	unified_dfa.output_DFA()