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A framework for constructing recognizers, compilers, and translators from grammatical descriptions containing Java, C#, C++, or Python actions.
/*
[The "BSD license"]
Copyright (c) 2005-2009 Terence Parr
All rights reserved.
Redistribution and use in source and binary forms, with or without
modification, are permitted provided that the following conditions
are met:
1. Redistributions of source code must retain the above copyright
notice, this list of conditions and the following disclaimer.
2. Redistributions in binary form must reproduce the above copyright
notice, this list of conditions and the following disclaimer in the
documentation and/or other materials provided with the distribution.
3. The name of the author may not be used to endorse or promote products
derived from this software without specific prior written permission.
THIS SOFTWARE IS PROVIDED BY THE AUTHOR ``AS IS'' AND ANY EXPRESS OR
IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED WARRANTIES
OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE ARE DISCLAIMED.
IN NO EVENT SHALL THE AUTHOR BE LIABLE FOR ANY DIRECT, INDIRECT,
INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT
NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE,
DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY
THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT
(INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE OF
THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE.
*/
package org.antlr.runtime.tree;
import org.antlr.runtime.*;
import java.util.regex.Matcher;
import java.util.regex.Pattern;
/** A parser for a stream of tree nodes. "tree grammars" result in a subclass
* of this. All the error reporting and recovery is shared with Parser via
* the BaseRecognizer superclass.
*/
public class TreeParser extends BaseRecognizer {
public static final int DOWN = Token.DOWN;
public static final int UP = Token.UP;
// precompiled regex used by inContext
static String dotdot = ".*[^.]\\.\\.[^.].*";
static String doubleEtc = ".*\\.\\.\\.\\s+\\.\\.\\..*";
static Pattern dotdotPattern = Pattern.compile(dotdot);
static Pattern doubleEtcPattern = Pattern.compile(doubleEtc);
protected TreeNodeStream input;
public TreeParser(TreeNodeStream input) {
super(); // highlight that we go to super to set state object
setTreeNodeStream(input);
}
public TreeParser(TreeNodeStream input, RecognizerSharedState state) {
super(state); // share the state object with another parser
setTreeNodeStream(input);
}
@Override
public void reset() {
super.reset(); // reset all recognizer state variables
if ( input!=null ) {
input.seek(0); // rewind the input
}
}
/** Set the input stream */
public void setTreeNodeStream(TreeNodeStream input) {
this.input = input;
}
public TreeNodeStream getTreeNodeStream() {
return input;
}
@Override
public String getSourceName() {
return input.getSourceName();
}
@Override
protected Object getCurrentInputSymbol(IntStream input) {
return ((TreeNodeStream)input).LT(1);
}
@Override
protected Object getMissingSymbol(IntStream input,
RecognitionException e,
int expectedTokenType,
BitSet follow)
{
String tokenText =
"";
TreeAdaptor adaptor = ((TreeNodeStream)e.input).getTreeAdaptor();
return adaptor.create(new CommonToken(expectedTokenType, tokenText));
}
/** Match '.' in tree parser has special meaning. Skip node or
* entire tree if node has children. If children, scan until
* corresponding UP node.
*/
@Override
public void matchAny(IntStream ignore) { // ignore stream, copy of input
state.errorRecovery = false;
state.failed = false;
Object look = input.LT(1);
if ( input.getTreeAdaptor().getChildCount(look)==0 ) {
input.consume(); // not subtree, consume 1 node and return
return;
}
// current node is a subtree, skip to corresponding UP.
// must count nesting level to get right UP
int level=0;
int tokenType = input.getTreeAdaptor().getType(look);
while ( tokenType!=Token.EOF && !(tokenType==UP && level==0) ) {
input.consume();
look = input.LT(1);
tokenType = input.getTreeAdaptor().getType(look);
if ( tokenType == DOWN ) {
level++;
}
else if ( tokenType == UP ) {
level--;
}
}
input.consume(); // consume UP
}
/** We have DOWN/UP nodes in the stream that have no line info; override.
* plus we want to alter the exception type. Don't try to recover
* from tree parser errors inline...
*/
@Override
protected Object recoverFromMismatchedToken(IntStream input,
int ttype,
BitSet follow)
throws RecognitionException
{
throw new MismatchedTreeNodeException(ttype, (TreeNodeStream)input);
}
/** Prefix error message with the grammar name because message is
* always intended for the programmer because the parser built
* the input tree not the user.
*/
@Override
public String getErrorHeader(RecognitionException e) {
return getGrammarFileName()+": node from "+
(e.approximateLineInfo?"after ":"")+"line "+e.line+":"+e.charPositionInLine;
}
/** Tree parsers parse nodes they usually have a token object as
* payload. Set the exception token and do the default behavior.
*/
@Override
public String getErrorMessage(RecognitionException e, String[] tokenNames) {
if ( this instanceof TreeParser ) {
TreeAdaptor adaptor = ((TreeNodeStream)e.input).getTreeAdaptor();
e.token = adaptor.getToken(e.node);
if ( e.token==null ) { // could be an UP/DOWN node
e.token = new CommonToken(adaptor.getType(e.node),
adaptor.getText(e.node));
}
}
return super.getErrorMessage(e, tokenNames);
}
/** Check if current node in input has a context. Context means sequence
* of nodes towards root of tree. For example, you might say context
* is "MULT" which means my parent must be MULT. "CLASS VARDEF" says
* current node must be child of a VARDEF and whose parent is a CLASS node.
* You can use "..." to mean zero-or-more nodes. "METHOD ... VARDEF"
* means my parent is VARDEF and somewhere above that is a METHOD node.
* The first node in the context is not necessarily the root. The context
* matcher stops matching and returns true when it runs out of context.
* There is no way to force the first node to be the root.
*/
public boolean inContext(String context) {
return inContext(input.getTreeAdaptor(), getTokenNames(), input.LT(1), context);
}
/** The worker for inContext. It's static and full of parameters for
* testing purposes.
*/
public static boolean inContext(TreeAdaptor adaptor,
String[] tokenNames,
Object t,
String context)
{
Matcher dotdotMatcher = dotdotPattern.matcher(context);
Matcher doubleEtcMatcher = doubleEtcPattern.matcher(context);
if ( dotdotMatcher.find() ) { // don't allow "..", must be "..."
throw new IllegalArgumentException("invalid syntax: ..");
}
if ( doubleEtcMatcher.find() ) { // don't allow double "..."
throw new IllegalArgumentException("invalid syntax: ... ...");
}
context = context.replaceAll("\\.\\.\\.", " ... "); // ensure spaces around ...
context = context.trim();
String[] nodes = context.split("\\s+");
int ni = nodes.length-1;
t = adaptor.getParent(t);
while ( ni>=0 && t!=null ) {
if ( nodes[ni].equals("...") ) {
// walk upwards until we see nodes[ni-1] then continue walking
if ( ni==0 ) return true; // ... at start is no-op
String goal = nodes[ni-1];
Object ancestor = getAncestor(adaptor, tokenNames, t, goal);
if ( ancestor==null ) return false;
t = ancestor;
ni--;
}
String name = tokenNames[adaptor.getType(t)];
if ( !name.equals(nodes[ni]) ) {
//System.err.println("not matched: "+nodes[ni]+" at "+t);
return false;
}
// advance to parent and to previous element in context node list
ni--;
t = adaptor.getParent(t);
}
if ( t==null && ni>=0 ) return false; // at root but more nodes to match
return true;
}
/** Helper for static inContext */
protected static Object getAncestor(TreeAdaptor adaptor, String[] tokenNames, Object t, String goal) {
while ( t!=null ) {
String name = tokenNames[adaptor.getType(t)];
if ( name.equals(goal) ) return t;
t = adaptor.getParent(t);
}
return null;
}
public void traceIn(String ruleName, int ruleIndex) {
super.traceIn(ruleName, ruleIndex, input.LT(1));
}
public void traceOut(String ruleName, int ruleIndex) {
super.traceOut(ruleName, ruleIndex, input.LT(1));
}
}