372 lines
14 KiB
Python
372 lines
14 KiB
Python
"""Classes representing state-machine concepts"""
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class NFA:
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"""A non deterministic finite automata
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A non deterministic automata is a form of a finite state
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machine. An NFA's rules are less restrictive than a DFA.
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The NFA rules are:
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* A transition can be non-deterministic and can result in
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nothing, one, or two or more states.
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* An epsilon transition consuming empty input is valid.
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Transitions consuming labeled symbols are also permitted.
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This class assumes that there is only one starting state and one
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accepting (ending) state.
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Attributes:
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name (str): The name of the rule the NFA is representing.
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start (NFAState): The starting state.
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end (NFAState): The ending state
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"""
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def __init__(self, start, end):
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self.name = start.rule_name
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self.start = start
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self.end = end
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def __repr__(self):
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return "NFA(start={}, end={})".format(self.start, self.end)
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def dump(self, writer=print):
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"""Dump a graphical representation of the NFA"""
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todo = [self.start]
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for i, state in enumerate(todo):
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writer(" State", i, state is self.end and "(final)" or "")
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for arc in state.arcs:
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label = arc.label
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next = arc.target
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if next in todo:
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j = todo.index(next)
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else:
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j = len(todo)
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todo.append(next)
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if label is None:
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writer(" -> %d" % j)
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else:
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writer(" %s -> %d" % (label, j))
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class NFAArc:
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"""An arc representing a transition between two NFA states.
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NFA states can be connected via two ways:
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* A label transition: An input equal to the label must
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be consumed to perform the transition.
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* An epsilon transition: The transition can be taken without
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consuming any input symbol.
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Attributes:
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target (NFAState): The ending state of the transition arc.
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label (Optional[str]): The label that must be consumed to make
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the transition. An epsilon transition is represented
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using `None`.
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"""
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def __init__(self, target, label):
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self.target = target
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self.label = label
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def __repr__(self):
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return "<%s: %s>" % (self.__class__.__name__, self.label)
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class NFAState:
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"""A state of a NFA, non deterministic finite automata.
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Attributes:
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target (rule_name): The name of the rule used to represent the NFA's
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ending state after a transition.
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arcs (Dict[Optional[str], NFAState]): A mapping representing transitions
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between the current NFA state and another NFA state via following
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a label.
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"""
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def __init__(self, rule_name):
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self.rule_name = rule_name
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self.arcs = []
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def add_arc(self, target, label=None):
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"""Add a new arc to connect the state to a target state within the NFA
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The method adds a new arc to the list of arcs available as transitions
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from the present state. An optional label indicates a named transition
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that consumes an input while the absence of a label represents an epsilon
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transition.
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Attributes:
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target (NFAState): The end of the transition that the arc represents.
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label (Optional[str]): The label that must be consumed for making
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the transition. If the label is not provided the transition is assumed
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to be an epsilon-transition.
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"""
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assert label is None or isinstance(label, str)
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assert isinstance(target, NFAState)
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self.arcs.append(NFAArc(target, label))
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def __repr__(self):
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return "<%s: from %s>" % (self.__class__.__name__, self.rule_name)
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class DFA:
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"""A deterministic finite automata
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A deterministic finite automata is a form of a finite state machine
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that obeys the following rules:
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* Each of the transitions is uniquely determined by
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the source state and input symbol
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* Reading an input symbol is required for each state
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transition (no epsilon transitions).
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The finite-state machine will accept or reject a string of symbols
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and only produces a unique computation of the automaton for each input
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string. The DFA must have a unique starting state (represented as the first
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element in the list of states) but can have multiple final states.
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Attributes:
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name (str): The name of the rule the DFA is representing.
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states (List[DFAState]): A collection of DFA states.
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"""
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def __init__(self, name, states):
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self.name = name
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self.states = states
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@classmethod
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def from_nfa(cls, nfa):
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"""Constructs a DFA from a NFA using the Rabin–Scott construction algorithm.
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To simulate the operation of a DFA on a given input string, it's
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necessary to keep track of a single state at any time, or more precisely,
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the state that the automaton will reach after seeing a prefix of the
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input. In contrast, to simulate an NFA, it's necessary to keep track of
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a set of states: all of the states that the automaton could reach after
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seeing the same prefix of the input, according to the nondeterministic
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choices made by the automaton. There are two possible sources of
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non-determinism:
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1) Multiple (one or more) transitions with the same label
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'A' +-------+
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+----------->+ State +----------->+
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| | 2 |
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+-------+ +-------+
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| State |
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| 1 | +-------+
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+-------+ | State |
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+----------->+ 3 +----------->+
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'A' +-------+
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2) Epsilon transitions (transitions that can be taken without consuming any input)
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+-------+ +-------+
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| State | ε | State |
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| 1 +----------->+ 2 +----------->+
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+-------+ +-------+
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Looking at the first case above, we can't determine which transition should be
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followed when given an input A. We could choose whether or not to follow the
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transition while in the second case the problem is that we can choose both to
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follow the transition or not doing it. To solve this problem we can imagine that
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we follow all possibilities at the same time and we construct new states from the
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set of all possible reachable states. For every case in the previous example:
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1) For multiple transitions with the same label we colapse all of the
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final states under the same one
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+-------+ +-------+
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| State | 'A' | State |
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| 1 +----------->+ 2-3 +----------->+
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+-------+ +-------+
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2) For epsilon transitions we collapse all epsilon-reachable states
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into the same one
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+-------+
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| State |
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| 1-2 +----------->
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+-------+
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Because the DFA states consist of sets of NFA states, an n-state NFA
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may be converted to a DFA with at most 2**n states. Notice that the
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constructed DFA is not minimal and can be simplified or reduced
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afterwards.
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Parameters:
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name (NFA): The NFA to transform to DFA.
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"""
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assert isinstance(nfa, NFA)
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def add_closure(nfa_state, base_nfa_set):
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"""Calculate the epsilon-closure of a given state
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Add to the *base_nfa_set* all the states that are
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reachable from *nfa_state* via epsilon-transitions.
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"""
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assert isinstance(nfa_state, NFAState)
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if nfa_state in base_nfa_set:
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return
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base_nfa_set.add(nfa_state)
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for nfa_arc in nfa_state.arcs:
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if nfa_arc.label is None:
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add_closure(nfa_arc.target, base_nfa_set)
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# Calculte the epsilon-closure of the starting state
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base_nfa_set = set()
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add_closure(nfa.start, base_nfa_set)
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# Start by visiting the NFA starting state (there is only one).
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states = [DFAState(nfa.name, base_nfa_set, nfa.end)]
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for state in states: # NB states grow while we're iterating
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# Find transitions from the current state to other reachable states
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# and store them in mapping that correlates the label to all the
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# possible reachable states that can be obtained by consuming a
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# token equal to the label. Each set of all the states that can
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# be reached after following a label will be the a DFA state.
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arcs = {}
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for nfa_state in state.nfa_set:
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for nfa_arc in nfa_state.arcs:
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if nfa_arc.label is not None:
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nfa_set = arcs.setdefault(nfa_arc.label, set())
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# All states that can be reached by epsilon-transitions
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# are also included in the set of reachable states.
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add_closure(nfa_arc.target, nfa_set)
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# Now create new DFAs by visiting all posible transitions between
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# the current DFA state and the new power-set states (each nfa_set)
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# via the different labels. As the nodes are appended to *states* this
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# is performing a deep-first search traversal over the power-set of
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# the states of the original NFA.
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for label, nfa_set in sorted(arcs.items()):
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for exisisting_state in states:
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if exisisting_state.nfa_set == nfa_set:
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# The DFA state already exists for this rule.
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next_state = exisisting_state
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break
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else:
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next_state = DFAState(nfa.name, nfa_set, nfa.end)
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states.append(next_state)
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# Add a transition between the current DFA state and the new
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# DFA state (the power-set state) via the current label.
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state.add_arc(next_state, label)
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return cls(nfa.name, states)
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def __iter__(self):
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return iter(self.states)
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def simplify(self):
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"""Attempt to reduce the number of states of the DFA
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Transform the DFA into an equivalent DFA that has fewer states. Two
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classes of states can be removed or merged from the original DFA without
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affecting the language it accepts to minimize it:
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* Unreachable states can not be reached from the initial
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state of the DFA, for any input string.
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* Nondistinguishable states are those that cannot be distinguished
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from one another for any input string.
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This algorithm does not achieve the optimal fully-reduced solution, but it
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works well enough for the particularities of the Python grammar. The
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algorithm repeatedly looks for two states that have the same set of
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arcs (same labels pointing to the same nodes) and unifies them, until
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things stop changing.
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"""
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changes = True
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while changes:
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changes = False
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for i, state_i in enumerate(self.states):
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for j in range(i + 1, len(self.states)):
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state_j = self.states[j]
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if state_i == state_j:
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del self.states[j]
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for state in self.states:
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state.unifystate(state_j, state_i)
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changes = True
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break
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def dump(self, writer=print):
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"""Dump a graphical representation of the DFA"""
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for i, state in enumerate(self.states):
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writer(" State", i, state.is_final and "(final)" or "")
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for label, next in sorted(state.arcs.items()):
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writer(" %s -> %d" % (label, self.states.index(next)))
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class DFAState(object):
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"""A state of a DFA
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Attributes:
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rule_name (rule_name): The name of the DFA rule containing the represented state.
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nfa_set (Set[NFAState]): The set of NFA states used to create this state.
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final (bool): True if the state represents an accepting state of the DFA
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containing this state.
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arcs (Dict[label, DFAState]): A mapping representing transitions between
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the current DFA state and another DFA state via following a label.
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"""
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def __init__(self, rule_name, nfa_set, final):
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assert isinstance(nfa_set, set)
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assert isinstance(next(iter(nfa_set)), NFAState)
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assert isinstance(final, NFAState)
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self.rule_name = rule_name
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self.nfa_set = nfa_set
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self.arcs = {} # map from terminals/nonterminals to DFAState
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self.is_final = final in nfa_set
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def add_arc(self, target, label):
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"""Add a new arc to the current state.
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Parameters:
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target (DFAState): The DFA state at the end of the arc.
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label (str): The label respresenting the token that must be consumed
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to perform this transition.
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"""
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assert isinstance(label, str)
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assert label not in self.arcs
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assert isinstance(target, DFAState)
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self.arcs[label] = target
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def unifystate(self, old, new):
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"""Replace all arcs from the current node to *old* with *new*.
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Parameters:
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old (DFAState): The DFA state to remove from all existing arcs.
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new (DFAState): The DFA state to replace in all existing arcs.
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"""
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for label, next_ in self.arcs.items():
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if next_ is old:
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self.arcs[label] = new
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def __eq__(self, other):
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# The nfa_set does not matter for equality
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assert isinstance(other, DFAState)
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if self.is_final != other.is_final:
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return False
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# We cannot just return self.arcs == other.arcs because that
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# would invoke this method recursively if there are any cycles.
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if len(self.arcs) != len(other.arcs):
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return False
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for label, next_ in self.arcs.items():
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if next_ is not other.arcs.get(label):
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return False
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return True
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__hash__ = None # For Py3 compatibility.
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def __repr__(self):
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return "<%s: %s is_final=%s>" % (
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self.__class__.__name__,
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self.rule_name,
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self.is_final,
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)
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