# Copyright 2004-2005 Elemental Security, Inc. All Rights Reserved. # Licensed to PSF under a Contributor Agreement. # Modifications: # Copyright 2014 David Halter. Integration into Jedi. # Modifications are dual-licensed: MIT and PSF. """ Parser engine for the grammar tables generated by pgen. The grammar table must be loaded first. See Parser/parser.c in the Python distribution for additional info on how this parsing engine works. """ # Local imports from jedi.parser import tokenize class ParseError(Exception): """Exception to signal the parser is stuck.""" def __init__(self, msg, type, value, start_pos): Exception.__init__(self, "%s: type=%r, value=%r, start_pos=%r" % (msg, tokenize.tok_name[type], value, start_pos)) self.msg = msg self.type = type self.value = value self.start_pos = start_pos class PgenParser(object): """Parser engine. The proper usage sequence is: p = Parser(grammar, [converter]) # create instance p.setup([start]) # prepare for parsing : if p.addtoken(...): # parse a token; may raise ParseError break root = p.rootnode # root of abstract syntax tree A Parser instance may be reused by calling setup() repeatedly. A Parser instance contains state pertaining to the current token sequence, and should not be used concurrently by different threads to parse separate token sequences. See driver.py for how to get input tokens by tokenizing a file or string. Parsing is complete when addtoken() returns True; the root of the abstract syntax tree can then be retrieved from the rootnode instance variable. When a syntax error occurs, addtoken() raises the ParseError exception. There is no error recovery; the parser cannot be used after a syntax error was reported (but it can be reinitialized by calling setup()). """ def __init__(self, grammar, convert_node, convert_leaf, error_recovery): """Constructor. The grammar argument is a grammar.Grammar instance; see the grammar module for more information. The parser is not ready yet for parsing; you must call the setup() method to get it started. The optional convert argument is a function mapping concrete syntax tree nodes to abstract syntax tree nodes. If not given, no conversion is done and the syntax tree produced is the concrete syntax tree. If given, it must be a function of two arguments, the first being the grammar (a grammar.Grammar instance), and the second being the concrete syntax tree node to be converted. The syntax tree is converted from the bottom up. A concrete syntax tree node is a (type, nodes) tuple, where type is the node type (a token or symbol number) and nodes is a list of children for symbols, and None for tokens. An abstract syntax tree node may be anything; this is entirely up to the converter function. """ self.grammar = grammar self.convert_node = convert_node self.convert_leaf = convert_leaf # Prepare for parsing. start = self.grammar.start # Each stack entry is a tuple: (dfa, state, node). # A node is a tuple: (type, children), # where children is a list of nodes or None newnode = (start, []) stackentry = (self.grammar.dfas[start], 0, newnode) self.stack = [stackentry] self.rootnode = None self.error_recovery = error_recovery def parse(self, tokenizer): for type, value, prefix, start_pos in tokenizer: if self.addtoken(type, value, prefix, start_pos): break else: # We never broke out -- EOF is too soon -- Unfinished statement. self.error_recovery(self.grammar, self.stack, type, value, start_pos, prefix, self.addtoken) # Add the ENDMARKER again. if not self.addtoken(type, value, prefix, start_pos): raise ParseError("incomplete input", type, value, start_pos) return self.rootnode def addtoken(self, type, value, prefix, start_pos): """Add a token; return True if this is the end of the program.""" # Map from token to label if type == tokenize.NAME: # Check for reserved words (keywords) try: ilabel = self.grammar.keywords[value] except KeyError: ilabel = self.grammar.tokens[type] else: ilabel = self.grammar.tokens[type] # Loop until the token is shifted; may raise exceptions while True: dfa, state, node = self.stack[-1] states, first = dfa arcs = states[state] # Look for a state with this label for i, newstate in arcs: t, v = self.grammar.labels[i] if ilabel == i: # Look it up in the list of labels assert t < 256 # Shift a token; we're done with it self.shift(type, value, newstate, prefix, start_pos) # Pop while we are in an accept-only state state = newstate while states[state] == [(0, state)]: self.pop() if not self.stack: # Done parsing! return True dfa, state, node = self.stack[-1] states, first = dfa # Done with this token return False elif t >= 256: # See if it's a symbol and if we're in its first set itsdfa = self.grammar.dfas[t] itsstates, itsfirst = itsdfa if ilabel in itsfirst: # Push a symbol self.push(t, itsdfa, newstate) break # To continue the outer while loop else: if (0, state) in arcs: # An accepting state, pop it and try something else self.pop() if not self.stack: # Done parsing, but another token is input raise ParseError("too much input", type, value, start_pos) else: self.error_recovery(self.grammar, self.stack, type, value, start_pos, prefix, self.addtoken) break def shift(self, type, value, newstate, prefix, start_pos): """Shift a token. (Internal)""" dfa, state, node = self.stack[-1] newnode = self.convert_leaf(self.grammar, type, value, prefix, start_pos) node[-1].append(newnode) self.stack[-1] = (dfa, newstate, node) def push(self, type, newdfa, newstate): """Push a nonterminal. (Internal)""" dfa, state, node = self.stack[-1] newnode = (type, []) self.stack[-1] = (dfa, newstate, node) self.stack.append((newdfa, 0, newnode)) def pop(self): """Pop a nonterminal. (Internal)""" popdfa, popstate, (type, children) = self.stack.pop() # If there's exactly one child, return that child instead of creating a # new node. We still create expr_stmt and file_input though, because a # lot of Jedi depends on its logic. if len(children) == 1: newnode = children[0] else: newnode = self.convert_node(self.grammar, type, children) try: # Equal to: # dfa, state, node = self.stack[-1] # symbol, children = node self.stack[-1][2][1].append(newnode) except IndexError: # Stack is empty, set the rootnode. self.rootnode = newnode