com.google.gwt.thirdparty.guava.common.escape.UnicodeEscaper Maven / Gradle / Ivy
/*
* Copyright (C) 2008 The Guava Authors
*
* Licensed under the Apache License, Version 2.0 (the "License");
* you may not use this file except in compliance with the License.
* You may obtain a copy of the License at
*
* http://www.apache.org/licenses/LICENSE-2.0
*
* Unless required by applicable law or agreed to in writing, software
* distributed under the License is distributed on an "AS IS" BASIS,
* WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
* See the License for the specific language governing permissions and
* limitations under the License.
*/
package com.google.common.escape;
import static com.google.common.base.Preconditions.checkNotNull;
import com.google.common.annotations.Beta;
import com.google.common.annotations.GwtCompatible;
/**
* An {@link Escaper} that converts literal text into a format safe for
* inclusion in a particular context (such as an XML document). Typically (but
* not always), the inverse process of "unescaping" the text is performed
* automatically by the relevant parser.
*
* For example, an XML escaper would convert the literal string {@code
* "Foo"} into {@code "Foo<Bar>"} to prevent {@code ""} from
* being confused with an XML tag. When the resulting XML document is parsed,
* the parser API will return this text as the original literal string {@code
* "Foo"}.
*
* Note: This class is similar to {@link CharEscaper} but with one
* very important difference. A CharEscaper can only process Java
* UTF16 characters in
* isolation and may not cope when it encounters surrogate pairs. This class
* facilitates the correct escaping of all Unicode characters.
*
*
As there are important reasons, including potential security issues, to
* handle Unicode correctly if you are considering implementing a new escaper
* you should favor using UnicodeEscaper wherever possible.
*
*
A {@code UnicodeEscaper} instance is required to be stateless, and safe
* when used concurrently by multiple threads.
*
*
Several popular escapers are defined as constants in classes like {@link
* com.google.common.html.HtmlEscapers}, {@link
* com.google.common.xml.XmlEscapers}, and {@link SourceCodeEscapers}. To create
* your own escapers extend this class and implement the {@link #escape(int)}
* method.
*
* @author David Beaumont
* @since 15.0
*/
@Beta
@GwtCompatible
public abstract class UnicodeEscaper extends Escaper {
/** The amount of padding (chars) to use when growing the escape buffer. */
private static final int DEST_PAD = 32;
/** Constructor for use by subclasses. */
protected UnicodeEscaper() {}
/**
* Returns the escaped form of the given Unicode code point, or {@code null}
* if this code point does not need to be escaped. When called as part of an
* escaping operation, the given code point is guaranteed to be in the range
* {@code 0 <= cp <= Character#MAX_CODE_POINT}.
*
*
If an empty array is returned, this effectively strips the input
* character from the resulting text.
*
*
If the character does not need to be escaped, this method should return
* {@code null}, rather than an array containing the character representation
* of the code point. This enables the escaping algorithm to perform more
* efficiently.
*
*
If the implementation of this method cannot correctly handle a
* particular code point then it should either throw an appropriate runtime
* exception or return a suitable replacement character. It must never
* silently discard invalid input as this may constitute a security risk.
*
* @param cp the Unicode code point to escape if necessary
* @return the replacement characters, or {@code null} if no escaping was
* needed
*/
protected abstract char[] escape(int cp);
/**
* Scans a sub-sequence of characters from a given {@link CharSequence},
* returning the index of the next character that requires escaping.
*
*
Note: When implementing an escaper, it is a good idea to override
* this method for efficiency. The base class implementation determines
* successive Unicode code points and invokes {@link #escape(int)} for each of
* them. If the semantics of your escaper are such that code points in the
* supplementary range are either all escaped or all unescaped, this method
* can be implemented more efficiently using {@link CharSequence#charAt(int)}.
*
*
Note however that if your escaper does not escape characters in the
* supplementary range, you should either continue to validate the correctness
* of any surrogate characters encountered or provide a clear warning to users
* that your escaper does not validate its input.
*
*
See {@link com.google.common.net.PercentEscaper} for an example.
*
* @param csq a sequence of characters
* @param start the index of the first character to be scanned
* @param end the index immediately after the last character to be scanned
* @throws IllegalArgumentException if the scanned sub-sequence of {@code csq}
* contains invalid surrogate pairs
*/
protected int nextEscapeIndex(CharSequence csq, int start, int end) {
int index = start;
while (index < end) {
int cp = codePointAt(csq, index, end);
if (cp < 0 || escape(cp) != null) {
break;
}
index += Character.isSupplementaryCodePoint(cp) ? 2 : 1;
}
return index;
}
/**
* Returns the escaped form of a given literal string.
*
*
If you are escaping input in arbitrary successive chunks, then it is not
* generally safe to use this method. If an input string ends with an
* unmatched high surrogate character, then this method will throw
* {@link IllegalArgumentException}. You should ensure your input is valid UTF-16 before calling this
* method.
*
*
Note: When implementing an escaper it is a good idea to override
* this method for efficiency by inlining the implementation of
* {@link #nextEscapeIndex(CharSequence, int, int)} directly. Doing this for
* {@link com.google.common.net.PercentEscaper} more than doubled the
* performance for unescaped strings (as measured by {@link
* CharEscapersBenchmark}).
*
* @param string the literal string to be escaped
* @return the escaped form of {@code string}
* @throws NullPointerException if {@code string} is null
* @throws IllegalArgumentException if invalid surrogate characters are
* encountered
*/
@Override
public String escape(String string) {
checkNotNull(string);
int end = string.length();
int index = nextEscapeIndex(string, 0, end);
return index == end ? string : escapeSlow(string, index);
}
/**
* Returns the escaped form of a given literal string, starting at the given
* index. This method is called by the {@link #escape(String)} method when it
* discovers that escaping is required. It is protected to allow subclasses
* to override the fastpath escaping function to inline their escaping test.
* See {@link CharEscaperBuilder} for an example usage.
*
*
This method is not reentrant and may only be invoked by the top level
* {@link #escape(String)} method.
*
* @param s the literal string to be escaped
* @param index the index to start escaping from
* @return the escaped form of {@code string}
* @throws NullPointerException if {@code string} is null
* @throws IllegalArgumentException if invalid surrogate characters are
* encountered
*/
protected final String escapeSlow(String s, int index) {
int end = s.length();
// Get a destination buffer and setup some loop variables.
char[] dest = Platform.charBufferFromThreadLocal();
int destIndex = 0;
int unescapedChunkStart = 0;
while (index < end) {
int cp = codePointAt(s, index, end);
if (cp < 0) {
throw new IllegalArgumentException(
"Trailing high surrogate at end of input");
}
// It is possible for this to return null because nextEscapeIndex() may
// (for performance reasons) yield some false positives but it must never
// give false negatives.
char[] escaped = escape(cp);
int nextIndex = index + (Character.isSupplementaryCodePoint(cp) ? 2 : 1);
if (escaped != null) {
int charsSkipped = index - unescapedChunkStart;
// This is the size needed to add the replacement, not the full
// size needed by the string. We only regrow when we absolutely must.
int sizeNeeded = destIndex + charsSkipped + escaped.length;
if (dest.length < sizeNeeded) {
int destLength = sizeNeeded + (end - index) + DEST_PAD;
dest = growBuffer(dest, destIndex, destLength);
}
// If we have skipped any characters, we need to copy them now.
if (charsSkipped > 0) {
s.getChars(unescapedChunkStart, index, dest, destIndex);
destIndex += charsSkipped;
}
if (escaped.length > 0) {
System.arraycopy(escaped, 0, dest, destIndex, escaped.length);
destIndex += escaped.length;
}
// If we dealt with an escaped character, reset the unescaped range.
unescapedChunkStart = nextIndex;
}
index = nextEscapeIndex(s, nextIndex, end);
}
// Process trailing unescaped characters - no need to account for escaped
// length or padding the allocation.
int charsSkipped = end - unescapedChunkStart;
if (charsSkipped > 0) {
int endIndex = destIndex + charsSkipped;
if (dest.length < endIndex) {
dest = growBuffer(dest, destIndex, endIndex);
}
s.getChars(unescapedChunkStart, end, dest, destIndex);
destIndex = endIndex;
}
return new String(dest, 0, destIndex);
}
/**
* Returns the Unicode code point of the character at the given index.
*
*
Unlike {@link Character#codePointAt(CharSequence, int)} or
* {@link String#codePointAt(int)} this method will never fail silently when
* encountering an invalid surrogate pair.
*
*
The behaviour of this method is as follows:
*
* - If {@code index >= end}, {@link IndexOutOfBoundsException} is thrown.
*
- If the character at the specified index is not a surrogate, it is
* returned.
*
- If the first character was a high surrogate value, then an attempt is
* made to read the next character.
*
* - If the end of the sequence was reached, the negated value of
* the trailing high surrogate is returned.
*
- If the next character was a valid low surrogate, the code point
* value of the high/low surrogate pair is returned.
*
- If the next character was not a low surrogate value, then
* {@link IllegalArgumentException} is thrown.
*
* - If the first character was a low surrogate value,
* {@link IllegalArgumentException} is thrown.
*
*
* @param seq the sequence of characters from which to decode the code point
* @param index the index of the first character to decode
* @param end the index beyond the last valid character to decode
* @return the Unicode code point for the given index or the negated value of
* the trailing high surrogate character at the end of the sequence
*/
protected static int codePointAt(CharSequence seq, int index, int end) {
checkNotNull(seq);
if (index < end) {
char c1 = seq.charAt(index++);
if (c1 < Character.MIN_HIGH_SURROGATE ||
c1 > Character.MAX_LOW_SURROGATE) {
// Fast path (first test is probably all we need to do)
return c1;
} else if (c1 <= Character.MAX_HIGH_SURROGATE) {
// If the high surrogate was the last character, return its inverse
if (index == end) {
return -c1;
}
// Otherwise look for the low surrogate following it
char c2 = seq.charAt(index);
if (Character.isLowSurrogate(c2)) {
return Character.toCodePoint(c1, c2);
}
throw new IllegalArgumentException(
"Expected low surrogate but got char '" + c2 +
"' with value " + (int) c2 + " at index " + index +
" in '" + seq + "'");
} else {
throw new IllegalArgumentException(
"Unexpected low surrogate character '" + c1 +
"' with value " + (int) c1 + " at index " + (index - 1) +
" in '" + seq + "'");
}
}
throw new IndexOutOfBoundsException("Index exceeds specified range");
}
/**
* Helper method to grow the character buffer as needed, this only happens
* once in a while so it's ok if it's in a method call. If the index passed
* in is 0 then no copying will be done.
*/
private static char[] growBuffer(char[] dest, int index, int size) {
char[] copy = new char[size];
if (index > 0) {
System.arraycopy(dest, 0, copy, 0, index);
}
return copy;
}
}