Mercurial > lcfOS
view python/pyyacc.py @ 346:3bb7dcfe5529
expanded arm target
author | Windel Bouwman |
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date | Fri, 07 Mar 2014 17:05:32 +0100 |
parents | 4d204f6f7d4e |
children | 9667d78ba79e |
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""" Parser generator script """ from ppci import Token EPS = 'EPS' EOF = 'EOF' class ParserGenerationException(Exception): """ Raised when something goes wrong during parser generation """ pass class ParserException(Exception): """ Raised during a failure in the parsing process """ pass class Action: def __repr__(self): return 'Action' def __eq__(self, other): return str(self) == str(other) class Shift(Action): def __init__(self, to_state): self.to_state = to_state def __repr__(self): return 'Shift({})'.format(self.to_state) class Reduce(Action): def __init__(self, rule): self.rule = rule def __repr__(self): return 'Reduce({})'.format(self.rule) class Accept(Reduce): def __repr__(self): return 'Accept({})'.format(self.rule) def print_grammar(g): """ Pretty print a grammar """ print(g) for production in g.productions: print(production) def calculate_first_sets(grammar): """ Calculate first sets for each grammar symbol This is a dictionary which maps each grammar symbol to a set of terminals that can be encountered first when looking for the symbol. """ first = {} nullable = {} for terminal in grammar.terminals | {EOF, EPS}: first[terminal] = set([terminal]) nullable[terminal] = False for nt in grammar.nonterminals: first[nt] = set() nullable[nt] = False while True: some_change = False for rule in grammar.productions: # Check for null-ability: if all(nullable[beta] for beta in rule.symbols): if not nullable[rule.name]: nullable[rule.name] = True some_change = True # Update first sets: for beta in rule.symbols: if not nullable[beta]: if first[beta] - first[rule.name]: first[rule.name] |= first[beta] some_change = True break if not some_change: break return first class Grammar: """ Defines a grammar of a language """ def __init__(self, terminals): self.terminals = set(terminals) self.nonterminals = set() self.productions = [] self._first = None # Cached first set self.start_symbol = None def __repr__(self): return 'Grammar with {} rules'.format(len(self.productions)) def add_production(self, name, symbols, f=None): """ Add a production rule to the grammar """ production = Production(name, symbols, f) self.productions.append(production) if name in self.terminals: raise ParserGenerationException("Cannot redefine terminal {0}".format(name)) self.nonterminals.add(name) self._first = None # Invalidate cached version def productionsForName(self, name): """ Retrieve all productions for a non terminal """ return [p for p in self.productions if p.name == name] @property def Symbols(self): """ Get all the symbols defined by this grammar """ return self.nonterminals | self.terminals @property def first(self): """ The first set is a mapping from a grammar symbol to a set of set of all terminal symbols that can be the first terminal when looking for the grammar symbol """ if not self._first: self._first = calculate_first_sets(self) return self._first def closure(self, itemset): """ Expand itemset by using epsilon moves """ worklist = list(itemset) def addIt(itm): if not itm in itemset: itemset.add(itm) worklist.append(itm) def first2(itm): # When using the first sets, create a copy: f = set(self.first[itm.NextNext]) if EPS in f: f.discard(EPS) f.add(itm.look_ahead) return f # Start of algorithm: while worklist: item = worklist.pop(0) if not item.IsShift: continue if not (item.Next in self.nonterminals): continue C = item.Next for add_p in self.productionsForName(C): for b in first2(item): addIt(Item(add_p, 0, b)) return frozenset(itemset) def initialItemSet(self): """ Calculates the initial item set """ iis = set() for p in self.productionsForName(self.start_symbol): iis.add(Item(p, 0, EOF)) return self.closure(iis) def nextItemSet(self, itemset, symbol): """ Determines the next itemset for the current set and a symbol This is the goto procedure """ next_set = set() for item in itemset: if item.can_shift_over(symbol): next_set.add(item.shifted()) return self.closure(next_set) def genCanonicalSet(self, iis): states = [] worklist = [] transitions = {} def addSt(s): if not (s in states): worklist.append(s) states.append(s) addSt(iis) while len(worklist) > 0: itemset = worklist.pop(0) for symbol in self.Symbols: nis = self.nextItemSet(itemset, symbol) if not nis: continue addSt(nis) transitions[(states.index(itemset), symbol)] = states.index(nis) return states, transitions def checkSymbols(self): """ Checks no symbols are undefined """ for production in self.productions: for symbol in production.symbols: if symbol not in self.Symbols: raise ParserGenerationException('Symbol {0} undefined'.format(symbol)) def generate_parser(self): """ Generates a parser from the grammar """ action_table, goto_table = self.generate_tables() p = LRParser(action_table, goto_table, self.start_symbol) p.grammar = self return p def generate_tables(self): """ Generate parsing tables """ if not self.start_symbol: self.start_symbol = self.productions[0].name self.checkSymbols() action_table = {} goto_table = {} iis = self.initialItemSet() # First generate all item sets by using the nextItemset function: states, transitions = self.genCanonicalSet(iis) def setAction(state, t, action): assert isinstance(action, Action) key = (state, t) assert type(state) is int assert type(t) is str if key in action_table: action2 = action_table[key] if action != action2: if (type(action2) is Reduce) and (type(action) is Shift): # Automatically resolve and do the shift action! # Simple, but almost always what you want!! action_table[key] = action elif isinstance(action2, Shift) and isinstance(action, Reduce): pass else: a1 = str(action) a2 = str(action2) raise ParserGenerationException('LR construction conflict {0} vs {1}'.format(a1, a2)) else: action_table[key] = action # Fill action table: for state in states: # Detect conflicts: for item in state: if item.IsShift and item.Next in self.terminals: # Rule 1, a shift item: nextstate = transitions[(states.index(state), item.Next)] setAction(states.index(state), item.Next, Shift(nextstate)) if item.IsReduce: if item.production.name == self.start_symbol and item.look_ahead == EOF: # Rule 3: accept: act = Accept(self.productions.index(item.production)) else: # Rule 2, reduce item: act = Reduce(self.productions.index(item.production)) setAction(states.index(state), item.look_ahead, act) for nt in self.nonterminals: key = (states.index(state), nt) if key in transitions: goto_table[key] = transitions[key] return action_table, goto_table class Production: """ Production rule for a grammar """ def __init__(self, name, symbols, f): self.name = name self.symbols = symbols self.f = f def __repr__(self): action = ' ' + str(self.f) if self.f else '' return '{0} -> {1}'.format(self.name, self.symbols) + action class Item: """ Represents a partially parsed item It has a production it is looking for, a position in this production called the 'dot' and a look ahead symbol that must follow this item. """ def __init__(self, production, dotpos, look_ahead): self.production = production self.dotpos = dotpos assert self.dotpos <= len(self.production.symbols) self.look_ahead = look_ahead self._is_shift = self.dotpos < len(self.production.symbols) def getdata(self): """ Gets the members as a tuple """ return (self.production, self.dotpos, self.look_ahead) def __eq__(self, other): if type(other) is type(self): return self.getdata() == other.getdata() return False def __hash__(self): return self.getdata().__hash__() @property def IsReduce(self): """ Check if this item has the dot at the end """ return not self._is_shift @property def IsShift(self): """ Check if this item is a shift item, i.e. the dot can proceed """ return self._is_shift @property def Next(self): """ Returns the symbol after the dot """ return self.production.symbols[self.dotpos] def can_shift_over(self, symbol): """ Determines if this item can shift over the given symbol """ return self.IsShift and self.Next == symbol def shifted(self): """ Creates a new item that is shifted one position """ return Item(self.production, self.dotpos + 1, self.look_ahead) @property def NextNext(self): """ Gets the symbol after the next symbol, or EPS if at the end """ if self.dotpos + 1 >= len(self.production.symbols): return EPS else: return self.production.symbols[self.dotpos + 1] def __repr__(self): prod = self.production predot = ' '.join(prod.symbols[0:self.dotpos]) postdot = ' '.join(prod.symbols[self.dotpos:]) name = prod.name args = (name, predot, postdot, self.look_ahead) return '[{0} -> {1} . {2} -> {3}]'.format(*args) class LRParser: """ LR parser automata """ def __init__(self, action_table, goto_table, start_symbol): self.action_table = action_table self.goto_table = goto_table self.start_symbol = start_symbol def parse(self, lexer): """ Parse an iterable with tokens """ assert hasattr(lexer, 'next_token'), '{0} is no lexer'.format(type(lexer)) stack = [0] r_data_stack = [] look_ahead = lexer.next_token() assert type(look_ahead) is Token # TODO: exit on this condition: while stack != [0, self.start_symbol, 2222]: state = stack[-1] # top of stack key = (state, look_ahead.typ) if not key in self.action_table: raise ParserException('Error parsing at character {0}'.format(look_ahead)) action = self.action_table[key] if type(action) is Reduce: f_args = [] prod = self.grammar.productions[action.rule] for s in prod.symbols: stack.pop() stack.pop() f_args.append(r_data_stack.pop()) f_args.reverse() r_data = None if prod.f: r_data = prod.f(*f_args) state = stack[-1] stack.append(prod.name) stack.append(self.goto_table[(state, prod.name)]) r_data_stack.append(r_data) elif type(action) is Shift: stack.append(look_ahead.typ) stack.append(action.to_state) r_data_stack.append(look_ahead) look_ahead = lexer.next_token() assert type(look_ahead) is Token elif type(action) is Accept: # Pop last rule data off the stack: f_args = [] param = self.grammar.productions[action.rule] for s in param.symbols: stack.pop() stack.pop() f_args.append(r_data_stack.pop()) f_args.reverse() if param.f: ret_val = param.f(*f_args) else: ret_val = None # Break out! break # At exit, the stack must be 1 long # TODO: fix that this holds: #assert len(stack) == 1, 'stack {0} not totally reduce'.format(stack) return ret_val