com.hazelcast.org.antlr.v4.runtime.UnbufferedTokenStream Maven / Gradle / Ivy
/*
* Copyright (c) 2012-2017 The ANTLR Project. All rights reserved.
* Use of this file is governed by the BSD 3-clause license that
* can be found in the LICENSE.txt file in the project root.
*/
package com.hazelcast.org.antlr.v4.runtime;
import com.hazelcast.org.antlr.v4.runtime.misc.Interval;
import java.util.Arrays;
public class UnbufferedTokenStream implements TokenStream {
protected TokenSource tokenSource;
/**
* A moving window buffer of the data being scanned. While there's a marker,
* we keep adding to buffer. Otherwise, {@link #consume consume()} resets so
* we start filling at index 0 again.
*/
protected Token[] tokens;
/**
* The number of tokens currently in {@link #tokens tokens}.
*
* This is not the buffer capacity, that's {@code tokens.length}.
*/
protected int n;
/**
* 0..n-1 index into {@link #tokens tokens} of next token.
*
* The {@code LT(1)} token is {@code tokens[p]}. If {@code p == n}, we are
* out of buffered tokens.
*/
protected int p=0;
/**
* Count up with {@link #mark mark()} and down with
* {@link #release release()}. When we {@code release()} the last mark,
* {@code numMarkers} reaches 0 and we reset the buffer. Copy
* {@code tokens[p]..tokens[n-1]} to {@code tokens[0]..tokens[(n-1)-p]}.
*/
protected int numMarkers = 0;
/**
* This is the {@code LT(-1)} token for the current position.
*/
protected Token lastToken;
/**
* When {@code numMarkers > 0}, this is the {@code LT(-1)} token for the
* first token in {@link #tokens}. Otherwise, this is {@code null}.
*/
protected Token lastTokenBufferStart;
/**
* Absolute token index. It's the index of the token about to be read via
* {@code LT(1)}. Goes from 0 to the number of tokens in the entire stream,
* although the stream size is unknown before the end is reached.
*
* This value is used to set the token indexes if the stream provides tokens
* that implement {@link WritableToken}.
*/
protected int currentTokenIndex = 0;
public UnbufferedTokenStream(TokenSource tokenSource) {
this(tokenSource, 256);
}
public UnbufferedTokenStream(TokenSource tokenSource, int bufferSize) {
this.tokenSource = tokenSource;
tokens = new Token[bufferSize];
n = 0;
fill(1); // prime the pump
}
@Override
public Token get(int i) { // get absolute index
int bufferStartIndex = getBufferStartIndex();
if (i < bufferStartIndex || i >= bufferStartIndex + n) {
throw new IndexOutOfBoundsException("get("+i+") outside buffer: "+
bufferStartIndex+".."+(bufferStartIndex+n));
}
return tokens[i - bufferStartIndex];
}
@Override
public Token LT(int i) {
if ( i==-1 ) {
return lastToken;
}
sync(i);
int index = p + i - 1;
if ( index < 0 ) {
throw new IndexOutOfBoundsException("LT("+i+") gives negative index");
}
if ( index >= n ) {
assert n > 0 && tokens[n-1].getType() == Token.EOF;
return tokens[n-1];
}
return tokens[index];
}
@Override
public int LA(int i) {
return LT(i).getType();
}
@Override
public TokenSource getTokenSource() {
return tokenSource;
}
@Override
public String getText() {
return "";
}
@Override
public String getText(RuleContext ctx) {
return getText(ctx.getSourceInterval());
}
@Override
public String getText(Token start, Token stop) {
return getText(Interval.of(start.getTokenIndex(), stop.getTokenIndex()));
}
@Override
public void consume() {
if (LA(1) == Token.EOF) {
throw new IllegalStateException("cannot consume EOF");
}
// buf always has at least tokens[p==0] in this method due to ctor
lastToken = tokens[p]; // track last token for LT(-1)
// if we're at last token and no markers, opportunity to flush buffer
if ( p == n-1 && numMarkers==0 ) {
n = 0;
p = -1; // p++ will leave this at 0
lastTokenBufferStart = lastToken;
}
p++;
currentTokenIndex++;
sync(1);
}
/** Make sure we have 'need' elements from current position {@link #p p}. Last valid
* {@code p} index is {@code tokens.length-1}. {@code p+need-1} is the tokens index 'need' elements
* ahead. If we need 1 element, {@code (p+1-1)==p} must be less than {@code tokens.length}.
*/
protected void sync(int want) {
int need = (p+want-1) - n + 1; // how many more elements we need?
if ( need > 0 ) {
fill(need);
}
}
/**
* Add {@code n} elements to the buffer. Returns the number of tokens
* actually added to the buffer. If the return value is less than {@code n},
* then EOF was reached before {@code n} tokens could be added.
*/
protected int fill(int n) {
for (int i=0; i 0 && tokens[this.n-1].getType() == Token.EOF) {
return i;
}
Token t = tokenSource.nextToken();
add(t);
}
return n;
}
protected void add(Token t) {
if ( n>=tokens.length ) {
tokens = Arrays.copyOf(tokens, tokens.length * 2);
}
if (t instanceof WritableToken) {
((WritableToken)t).setTokenIndex(getBufferStartIndex() + n);
}
tokens[n++] = t;
}
/**
* Return a marker that we can release later.
*
* The specific marker value used for this class allows for some level of
* protection against misuse where {@code seek()} is called on a mark or
* {@code release()} is called in the wrong order.
*/
@Override
public int mark() {
if (numMarkers == 0) {
lastTokenBufferStart = lastToken;
}
int mark = -numMarkers - 1;
numMarkers++;
return mark;
}
@Override
public void release(int marker) {
int expectedMark = -numMarkers;
if ( marker!=expectedMark ) {
throw new IllegalStateException("release() called with an invalid marker.");
}
numMarkers--;
if ( numMarkers==0 ) { // can we release buffer?
if (p > 0) {
// Copy tokens[p]..tokens[n-1] to tokens[0]..tokens[(n-1)-p], reset ptrs
// p is last valid token; move nothing if p==n as we have no valid char
System.arraycopy(tokens, p, tokens, 0, n - p); // shift n-p tokens from p to 0
n = n - p;
p = 0;
}
lastTokenBufferStart = lastToken;
}
}
@Override
public int index() {
return currentTokenIndex;
}
@Override
public void seek(int index) { // seek to absolute index
if (index == currentTokenIndex) {
return;
}
if (index > currentTokenIndex) {
sync(index - currentTokenIndex);
index = Math.min(index, getBufferStartIndex() + n - 1);
}
int bufferStartIndex = getBufferStartIndex();
int i = index - bufferStartIndex;
if ( i < 0 ) {
throw new IllegalArgumentException("cannot seek to negative index " + index);
}
else if (i >= n) {
throw new UnsupportedOperationException("seek to index outside buffer: "+
index+" not in "+ bufferStartIndex +".."+(bufferStartIndex +n));
}
p = i;
currentTokenIndex = index;
if (p == 0) {
lastToken = lastTokenBufferStart;
}
else {
lastToken = tokens[p-1];
}
}
@Override
public int size() {
throw new UnsupportedOperationException("Unbuffered stream cannot know its size");
}
@Override
public String getSourceName() {
return tokenSource.getSourceName();
}
@Override
public String getText(Interval interval) {
int bufferStartIndex = getBufferStartIndex();
int bufferStopIndex = bufferStartIndex + tokens.length - 1;
int start = interval.a;
int stop = interval.b;
if (start < bufferStartIndex || stop > bufferStopIndex) {
throw new UnsupportedOperationException("interval "+interval+" not in token buffer window: "+
bufferStartIndex+".."+bufferStopIndex);
}
int a = start - bufferStartIndex;
int b = stop - bufferStartIndex;
StringBuilder buf = new StringBuilder();
for (int i = a; i <= b; i++) {
Token t = tokens[i];
buf.append(t.getText());
}
return buf.toString();
}
protected final int getBufferStartIndex() {
return currentTokenIndex - p;
}
}
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