import re valid_name_re = re.compile('^[a-zA-Z_][a-zA-Z0-9_]*$') reserved_names = ['start', 'middle', 'end', 'null'] class Token(object): def __init__(self, name, rule=None, y=0, x=0, s="", parent=None, matchd={}): self.name = name self.rule = rule self.y = y self.x = x self.string = s self.parent = parent self.matchd = matchd def parents(self): if self.parent is not None: parents = self.parent.parents() parents.append(self.parent) return parents else: return [] def domain(self): if self.parent is not None: names = self.parent.domain() else: names = [] if self.name != 'middle': names.append(self.rule.name) return names def fqlist(self): if self.parent is not None: names = self.parent.domain() else: names = [] if self.name == 'start': names.append(self.rule.name) names.append(self.name) return names def fqname(self): names = self.fqlist() return '.'.join(names) def copy(self): return Token(self.name, self.rule, self.y, self.x, self.string, self.parent, self.matchd) def add_to_string(self, s): self.string += s def end_x(self): return self.x + len(self.string) def __eq__(self, other): return (self.y == other.y and self.x == other.x and self.name == other.name and self.parent is other.parent and self.string == other.string) def __repr__(self): if len(self.string) < 10: s = self.string else: s = self.string[:10] + '...' fields = (self.fqname(), self.rule, self.y, self.x, s) return "" % fields class Rule: name = 'abstract' def match(self, lexer, parent): raise Exception, "%s rule cannot match!" % self.name def make_token(self, lexer, s, name, parent=None, matchd={}): return Token(name, self, lexer.y, lexer.x, s, parent, matchd) def _get_line(self, lexer): return lexer.lines[lexer.y] + '\n' def _set_group(self, group): if group is None: self.group = self.name else: self.group = group class ConstantRule(Rule): def __init__(self, name, constant, group=None): assert valid_name_re.match(name), 'invalid name %r' % name assert name not in reserved_names, "reserved rule name: %r" % name self.name = name self.constant = constant self.length = len(self.constant) self._set_group(group) def match(self, lexer, parent): line = self._get_line(lexer) if line[lexer.x:].startswith(self.constant): token = self.make_token(lexer, self.constant, self.name, parent) lexer.add_token(token) lexer.x += self.length return True else: return False class PatternRule(Rule): def __init__(self, name, pattern, group=None): assert valid_name_re.match(name), 'invalid name %r' % name assert name not in reserved_names, "reserved rule name: %r" % name self.name = name self.pattern = pattern self._compile() self._set_group(group) def _compile(self): self.re = re.compile(self.pattern) def _match(self, lexer, parent, m): s = m.group(0) token = self.make_token(lexer, s, self.name, parent) lexer.add_token(token) lexer.x += len(s) def match(self, lexer, parent): line = self._get_line(lexer) m = self.re.match(line, lexer.x) if m: self._match(lexer, parent, m) return True else: return False class NocasePatternRule(PatternRule): def _compile(self): self.re = re.compile(self.pattern, re.IGNORECASE) class ContextPatternRule(PatternRule): def __init__(self, name, pattern, fallback, group=None): assert valid_name_re.match(name), 'invalid name %r' % name assert name not in reserved_names, "reserved rule name: %r" % name self.name = name self.pattern = pattern self.fallback = fallback self.fallback_re = re.compile(fallback) self._set_group(group) def match(self, lexer, parent): try: r = re.compile(self.pattern % parent.matchd) except KeyError: r = self.fallback_re line = self._get_line(lexer) m = r.match(line, lexer.x) if m: self._match(lexer, parent, m) return True else: return False class RegionRule(Rule): def __init__(self, name, start, grammar, end, group=None): assert valid_name_re.match(name), 'invalid name %r' % name assert name not in reserved_names, "reserved rule name: %r" % name self.name = name self.start = start self.grammar = grammar self.end = end self.start_re = self._compile_start() self._set_group(group) def _compile_start(self): return re.compile(self.start) def _compile_end(self, d): return re.compile(self.end % d) def resume(self, lexer, toresume): #raise Exception, "%r %r" % (lexer, toresume) #XYZ assert toresume, "can't resume without tokens to resume!" self._match(lexer, None, None, toresume) return True def match(self, lexer, parent): line = self._get_line(lexer) m = self.start_re.match(line, lexer.x) if m: self._match(lexer, parent, m, []) return True else: return False def _add_from_regex(self, name, lexer, parent, m, matchd={}): s = m.group(0) token = self.make_token(lexer, s, name, parent, matchd) lexer.add_token(token) lexer.x += len(s) return token def _match(self, lexer, parent, m, toresume=[]): # we either need a match object, or a token to resume assert m or len(toresume) > 0 if m: # if we had a match, then it becomes the parent, and we save its # subgroup dict d = m.groupdict() parent = self._add_from_regex('start', lexer, parent, m, d) else: # otherwise, we should be resuming the start token, so let's pull # the relevant info out of the token parent = toresume[0] d = parent.matchd assert parent.name == 'start' null_t = None # this determines whether we are still reentering. if len(toresume) == 1 # then it means that we have been reentering but will not continue, so # reenter will be false. reenter = len(toresume) > 1 # if we have an end regex, then build it here. notice that it can # reference named groups from the start token. if we have no end, # well, then, we're never getting out of here alive! if self.end: #end_re = re.compile(self.end % d) end_re = self._compile_end(d) # ok, so as long as we aren't done (we haven't found an end token), # keep reading input done = False while not done and lexer.y < len(lexer.lines): old_y = lexer.y # if this line is empty, then we skip it, but here we insert # an empty null token just so we have something #if not reenter and len(lexer.lines[lexer.y]) == 0: # null_t = Token('null', None, lexer.y, lexer.x, '', parent) # lexer.add_token(null_t) # null_t = None # ok, as long as we haven't found the end token, and have more # data on the current line to read, we will process tokens #while (not done and lexer.y == old_y and # lexer.x < len(lexer.lines[lexer.y])): while not done and lexer.y == old_y and lexer.x < len(lexer.lines[lexer.y]) + 1: # if we are reentering mid-parse, then that takes precedence if reenter: reenter = False rule2 = toresume[1].rule rule2.resume(lexer, toresume[1:]) null_t = None if lexer.y >= len(lexer.lines): return True #elif lexer.x >= len(lexer.lines[lexer.y]): elif lexer.x >= len(lexer.lines[lexer.y]) + 1: lexer.y += 1 lexer.x = 0 line = self._get_line(lexer) # if we are looking for an end token, then see if we've # found it. if so, then we are done! if self.end: m = end_re.match(line, lexer.x) if m: self._add_from_regex('end', lexer, parent, m, {}) done = True break # ok, we need to check all our rules now, in order. if we # find a token, note that we found one and exit the loop found = False for rule in self.grammar.rules: if rule.match(lexer, parent): found = True null_t = None break # if we never found a token, then we need to add another # character to the current null token (which we should # create if it isn't set). if not found: if null_t is None: null_t = Token('null', None, lexer.y, lexer.x, '', parent) lexer.add_token(null_t) #if len(lexer.lines[lexer.y]) > lexer.x: if lexer.x < len(line): #null_t.add_to_string(lexer.lines[lexer.y][lexer.x]) null_t.add_to_string(line[lexer.x]) lexer.x += 1 # ok, since we're soon going to be on a different line (or # already are), we want a new null token. so forget about the # current one (i.e. stop adding to it). null_t = None # if we're still on the same line at this point (and not done) # then that means we're finished with the line and should move # on to the next one here if not done and old_y == lexer.y: lexer.y += 1 lexer.x = 0 return True class NocaseRegionRule(RegionRule): def _compile_start(self): return re.compile(self.start, re.IGNORECASE) def _compile_end(self, d): return re.compile(self.end % d, re.IGNORECASE) class DualRegionRule(Rule): def __init__(self, name, start, grammar1, middle, grammar2, end, group=None): assert valid_name_re.match(name), 'invalid name %r' % name assert name not in reserved_names, "reserved rule name: %r" % name self.name = name self.start = start self.grammar1 = grammar1 self.middle = middle self.grammar2 = grammar2 self.end = end #self.start_re = re.compile(start) self.start_re = self._compile_start() self._set_group(group) def _compile_start(self): return re.compile(self.start) def _compile_middle(self, d): return re.compile(self.middle % d) def _compile_end(self, d): return re.compile(self.end % d) def _add_from_regex(self, name, lexer, parent, m, matchd={}): s = m.group(0) token = self.make_token(lexer, s, name, parent, matchd) lexer.add_token(token) lexer.x += len(s) return token def resume(self, lexer, toresume): assert toresume, "can't resume without tokens to resume!" token = toresume[0] if token.name == 'start': t2 = self._match_first(lexer, token, toresume) if t2 is not None: t3 = self._match_second(lexer, t2, []) return True elif token.name == 'middle': t3 = self._match_second(lexer, token, toresume) else: raise Exception, "invalid flag %r" % flag return True def match(self, lexer, parent): # see if we can match our start token line = self._get_line(lexer) m = self.start_re.match(line, lexer.x) if m: t1 = self._add_from_regex('start', lexer, parent, m, m.groupdict()) t2 = self._match_first(lexer, t1, []) if t2 is not None: t3 = self._match_second(lexer, t2, []) return True else: # region was not matched; we never started. so return false return False def _match_first(self, lexer, parent, toresume=[]): reenter = len(toresume) > 1 if reenter: assert parent is toresume[0] d1 = parent.matchd assert parent.name == 'start' null_t = None #middle_re = re.compile(self.middle % d1) middle_re = self._compile_middle(d1) d2 = {} # ok, so as long as we aren't done (we haven't found an end token), # keep reading input t2 = None done = False while not done and lexer.y < len(lexer.lines): old_y = lexer.y # if this line is empty, then we will skip it, but here we insert # an empty null token just so we have something #if len(lexer.lines[lexer.y]) == 0: # null_t = Token('null', None, lexer.y, lexer.x, '', parent) # lexer.add_token(null_t) # null_t = None # ok, as long as we haven't found the end token, and have more # data on the current line to read, we will process tokens #while not done and lexer.y == old_y and lexer.x < len(lexer.lines[lexer.y]): while not done and lexer.y == old_y and lexer.x < len(lexer.lines[lexer.y]) + 1: # if we are reentering mid-parse, then that takes precedence if reenter: raise Exception, "aw damn1" #reenter = False #xrule = rulecontext[0].rule #xd = rulecontext[0].matchd #assert rule2.resume(lexer, xcontext, xd, rulecontext[1:]), \ # "%r %r %r %r" % (lexer, xcontext, xd, rulecontext[1:]) #found = True #null_t = None #break line = self._get_line(lexer) # see if we have found the middle token. if so, we can then # proceed to "stage 2" m2 = middle_re.match(line, lexer.x) if m2: d2 = dict(d1.items() + m2.groupdict().items()) t2 = self._add_from_regex('middle', lexer, parent, m2, d2) done = True break # ok, we need to check all our rules now, in order. if we # find a token, note that we found one and exit the loop found = False for rule in self.grammar1.rules: if rule.match(lexer, parent): found = True null_t = None break # if we never found a token, then we need to add another # character to the current null token (which we should # create if it isn't set). if not found: if null_t is None: null_t = Token('null', None, lexer.y, lexer.x, '', parent) lexer.add_token(null_t) #null_t.add_to_string(lexer.lines[lexer.y][lexer.x]) null_t.add_to_string(line[lexer.x]) lexer.x += 1 # ok, since we're soon going to be on a different line (or # already are), we want a new null token. so forget about the # current one. null_t = None # if we're still on the same line at this point (and not done) # then that means we're finished with the line and should move # on to the next one here if not done and old_y == lexer.y: lexer.y += 1 lexer.x = 0 return t2 def _match_second(self, lexer, parent, toresume=[]): reenter = len(toresume) > 1 if reenter: assert parent is toresume[0] assert parent.name == 'middle' #assert parent.name == 'middle' d3 = parent.matchd null_t = None #end_re = re.compile(self.end % d3) end_re = self._compile_end(d3) # ok, so as long as we aren't done (we haven't found an end token), # keep reading input t3 = None done = False while not done and lexer.y < len(lexer.lines): old_y = lexer.y # if we are reentering mid-parse, then that takes precedence if reenter: raise Exception, "aw damn2" #reenter = False #xrule = rulecontext[0].rule #xd = rulecontext[0].matchd #assert rule2.resume(lexer, xcontext, xd, rulecontext[1:]), \ # "%r %r %r %r" % (lexer, xcontext, xd, rulecontext[1:]) #found = True #null_t = None #break # if this line is empty, then we will skip it, but here weinsert # an empty null token just so we have something #if len(lexer.lines[lexer.y]) == 0: # null_t = Token('null', None, lexer.y, lexer.x, '', parent) # lexer.add_token(null_t) # null_t = None # ok, as long as we haven't found the end token, and have more # data on the current line to read, we will process tokens while not done and lexer.y == old_y and lexer.x < len(lexer.lines[lexer.y]) + 1: # see if we have found the middle token. if so, we can then # proceed to "stage 2" line = self._get_line(lexer) m3 = end_re.match(line, lexer.x) if m3: t3 = self._add_from_regex('end', lexer, parent, m3, {}) done = True break # ok, we need to check all our rules now, in order. if we # find a token, note that we found one and exit the loop found = False for rule in self.grammar2.rules: if rule.match(lexer, parent): found = True null_t = None break # if we never found a token, then we need to add another # character to the current null token (which we should # create if it isn't set). if not found: if null_t is None: null_t = Token('null', None, lexer.y, lexer.x, '', parent) lexer.add_token(null_t) #null_t.add_to_string(lexer.lines[lexer.y][lexer.x]) null_t.add_to_string(line[lexer.x]) lexer.x += 1 # ok, since we're soon going to be on a different line (or # already are), we want a new null token. so forget about the # current one. null_t = None # if we're still on the same line at this point (and not done) # then that means we're finished with the line and should move # on to the next one here if not done and old_y == lexer.y: lexer.y += 1 lexer.x = 0 # alright, we're finally done processing; return true return t3 class Grammar: rules = [] def __init__(self): for rule in self.rules: if hasattr(rule, 'grammar') and rule.grammar is None: rule.grammar = self if hasattr(rule, 'grammar1') and rule.grammar is None: rule.grammar = self if hasattr(rule, 'grammar2') and rule.grammar is None: rule.grammar = self grammars = {} grammars['null'] = Grammar() crash = False def add(name, grammar): global crash, grammars if crash and name in grammars: raise Exception, "oh no! already have a grammar for %r" %name else: grammars[name] = grammar def get(name): global crash, grammars try: return grammars[name] except KeyError: if crash: raise elif name == 'null': return Grammar() else: return get('null') class Lexer: def __init__(self, name, grammar): self.name = name self.grammar = grammar self.y = 0 self.x = 0 self.lines = None self.tokens = [] def add_token(self, t): self.tokens.append(t) def lex(self, lines, y=0, x=0): self.y = y self.x = x self.lines = lines self.tokens = [] def resume(self, lines, y, x, token): #raise Exception, "%r %r" % (self, token) #XYZ self.y = y self.x = x self.lines = lines self.tokens = [] toresume = token.parents() if toresume: toresume[0].rule.resume(self, toresume) #else: # raise Exception, "dammmmit" def __iter__(self): if self.lines is None: raise Exception, "no lines to lex" return self def next(self): null_t = None if self.tokens: return self.tokens.pop(0) while self.y < len(self.lines): #line = self.lines[self.y] line = self.lines[self.y] + '\n' while self.x < len(line): curr_t = None for rule in self.grammar.rules: if rule.match(self, None): assert self.tokens, "match rendered no tokens?" return self.tokens.pop(0) if null_t is None: null_t = Token('null', None, self.y, self.x, '') self.add_token(null_t) #assert line[self.x] != '\n', "DAMN" #assert line[self.x] != '$', "DAMN" null_t.add_to_string(line[self.x]) self.x += 1 null_t = None self.y += 1 self.x = 0 if self.tokens: return self.tokens.pop(0) else: raise StopIteration class NocaseDualRegionRule(DualRegionRule): def _compile_start(self): return re.compile(self.start, re.IGNORECASE) def _compile_middle(self, d): return re.compile(self.middle % d, re.IGNORECASE) def _compile_end(self, d): return re.compile(self.end % d, re.IGNORECASE)