概述
CharMatcher提供了多种对字符串处理的方法, 它的主要意图有:
1. 找到匹配的字符
2. 处理匹配的字符
CharMatcher内部主要实现包括两部分:
1. 实现了大量公用内部类, 用来方便用户对字符串做匹配: 例如 JAVA_DIGIT 匹配数字, JAVA_LETTER 匹配字母等等.
2. 实现了大量处理字符串的方法, 使用特定的CharMatcher可以对匹配到的字符串做出多种处理, 例如 remove(), replace(), trim(), retain()等等
CharMatcher本身是一个抽象类, 其中一些操作方法是抽象方法, 他主要依靠内部继承CharMatcher的内部子类来实现抽象方法和重写一些操作方法, 因为不同的匹配规则的这些操作方法具有不同的实现要求
常用方法介绍
默认实现类
CharMatcher本身提供了很多CharMatcher实现类,如下:
ANY: 匹配任何字符
ASCII: 匹配是否是ASCII字符
BREAKING_WHITESPACE: 匹配所有可换行的空白字符(不包括非换行空白字符,例如"\u00a0")
DIGIT: 匹配ASCII数字
INVISIBLE: 匹配所有看不见的字符
JAVA_DIGIT: 匹配UNICODE数字, 使用 Character.isDigit() 实现
JAVA_ISO_CONTROL: 匹配ISO控制字符, 使用 Charater.isISOControl() 实现
JAVA_LETTER: 匹配字母, 使用 Charater.isLetter() 实现
JAVA_LETTER_OR_DIGET: 匹配数字或字母
JAVA_LOWER_CASE: 匹配小写
JAVA_UPPER_CASE: 匹配大写
NONE: 不匹配所有字符
SINGLE_WIDTH: 匹配单字宽字符, 如中文字就是双字宽
WHITESPACE: 匹配所有空白字符
常用操作方法
CharMatcher is(char match): 返回匹配指定字符的Matcher
CharMatcher isNot(char match): 返回不匹配指定字符的Matcher
CharMatcher anyOf(CharSequence sequence): 返回匹配sequence中任意字符的Matcher
CharMatcher noneOf(CharSequence sequence): 返回不匹配sequence中任何一个字符的Matcher
CharMatcher inRange(char startInclusive, char endIncludesive): 返回匹配范围内任意字符的Matcher
CharMatcher forPredicate(Predicate<? super Charater> predicate): 返回使用predicate的apply()判断匹配的Matcher
CharMatcher negate(): 返回以当前Matcher判断规则相反的Matcher
CharMatcher and(CharMatcher other): 返回与other匹配条件组合做与来判断的Matcher
CharMatcher or(CharMatcher other): 返回与other匹配条件组合做或来判断的Matcher
boolean matchesAnyOf(CharSequence sequence): 只要sequence中有任意字符能匹配Matcher,返回true
boolean matchesAllOf(CharSequence sequence): sequence中所有字符都能匹配Matcher,返回true
boolean matchesNoneOf(CharSequence sequence): sequence中所有字符都不能匹配Matcher,返回true
int indexIn(CharSequence sequence): 返回sequence中匹配到的第一个字符的坐标
int indexIn(CharSequence sequence, int start): 返回从start开始,在sequence中匹配到的第一个字符的坐标
int lastIndexIn(CharSequence sequence): 返回sequence中最后一次匹配到的字符的坐标
int countIn(CharSequence sequence): 返回sequence中匹配到的字符计数
String removeFrom(CharSequence sequence): 删除sequence中匹配到到的字符并返回
String retainFrom(CharSequence sequence): 保留sequence中匹配到的字符并返回
String replaceFrom(CharSequence sequence, char replacement): 替换sequence中匹配到的字符并返回
String trimFrom(CharSequence sequence): 删除首尾匹配到的字符并返回
String trimLeadingFrom(CharSequence sequence): 删除首部匹配到的字符
String trimTrailingFrom(CharSequence sequence): 删除尾部匹配到的字符
String collapseFrom(CharSequence sequence, char replacement): 将匹配到的组(连续匹配的字符)替换成replacement
String trimAndCollapseFrom(CharSequence sequence, char replacement): 先trim在replace
部分实现源码介绍
下面对CharMatcher的常用的操作方法实现做一些介绍
/**
* 返回一个与当前Matcher匹配规则相反的Matcher
*/
public CharMatcher negate() {
final CharMatcher original = this;
return new CharMatcher(original + ".negate()") {
@Override public boolean matches(char c) {
return !original.matches(c);
} @Override public boolean matchesAllOf(CharSequence sequence) {
return original.matchesNoneOf(sequence);
} @Override public boolean matchesNoneOf(CharSequence sequence) {
return original.matchesAllOf(sequence);
} @Override public int countIn(CharSequence sequence) {
return sequence.length() - original.countIn(sequence);
} @Override public CharMatcher negate() {
return original;
}
};
} /**
* 返回一个具有组合规则链的Matcher
*/
public CharMatcher and(CharMatcher other) {
return new And(this, checkNotNull(other));
} /**
* And的实现和Ordering的Compound是一样的
* 使用一个内部子类继承Matcher,然后内部使用组合的方式将
* 多个Matcher组合在一起,调用操作方法的时候依次调用这些
* Matcher的同名操作方法即可
*/
private static class And extends CharMatcher {
final CharMatcher first;
final CharMatcher second; And(CharMatcher a, CharMatcher b) {
this(a, b, "CharMatcher.and(" + a + ", " + b + ")");
} And(CharMatcher a, CharMatcher b, String description) {
super(description);
first = checkNotNull(a);
second = checkNotNull(b);
} @Override
public CharMatcher and(CharMatcher other) {
return new And(this, other);
} @Override
public boolean matches(char c) {
return first.matches(c) && second.matches(c);
} @Override
CharMatcher withToString(String description) {
return new And(first, second, description);
}
} /**
* Or的实现与And一样,不再赘述
*/
public CharMatcher or(CharMatcher other) {
return new Or(this, checkNotNull(other));
} private static class Or extends CharMatcher {
final CharMatcher first;
final CharMatcher second; Or(CharMatcher a, CharMatcher b, String description) {
super(description);
first = checkNotNull(a);
second = checkNotNull(b);
} Or(CharMatcher a, CharMatcher b) {
this(a, b, "CharMatcher.or(" + a + ", " + b + ")");
} @Override
public CharMatcher or(CharMatcher other) {
return new Or(this, checkNotNull(other));
} @Override
public boolean matches(char c) {
return first.matches(c) || second.matches(c);
} @Override
CharMatcher withToString(String description) {
return new Or(first, second, description);
}
} /**
* Returns a {@code char} matcher functionally equivalent to this one, but which may be faster to
* query than the original; your mileage may vary. Precomputation takes time and is likely to be
* worthwhile only if the precomputed matcher is queried many thousands of times.
*
* <p>This method has no effect (returns {@code this}) when called in GWT: it's unclear whether a
* precomputed matcher is faster, but it certainly consumes more memory, which doesn't seem like a
* worthwhile tradeoff in a browser.
*/
public CharMatcher precomputed() {
return Platform.precomputeCharMatcher(this);
} /**
* 使用最慢的方式来返回字符全集中所有能被Matcher匹配的字符
* 最慢的方式?!
*/
char[] slowGetChars() {
char[] allChars = new char[65536];
int size = 0;
for (int c = Character.MIN_VALUE; c <= Character.MAX_VALUE; c++) {
if (matches((char) c)) {
allChars[size++] = (char) c;
}
}
char[] retValue = new char[size];
System.arraycopy(allChars, 0, retValue, 0, size);
return retValue;
} /**
* 只要sequence有任意字符匹配Matcher,则返回true
*/
public boolean matchesAnyOf(CharSequence sequence) {
return !matchesNoneOf(sequence);
} /**
* 如果sequence所有字符都匹配Matcher,则返回true
*/
public boolean matchesAllOf(CharSequence sequence) {
for (int i = sequence.length() - 1; i >= 0; i--) {
if (!matches(sequence.charAt(i))) {
return false;
}
}
return true;
} /**
* 如果sequence所有字符都不匹配Matcher,则返回true
*/
public boolean matchesNoneOf(CharSequence sequence) {
return indexIn(sequence) == -1;
} /**
* 返回Matcher在sequence中匹配到的第一个字符的坐标
* 没有匹配则返回 -1
*/
public int indexIn(CharSequence sequence) {
int length = sequence.length();
for (int i = 0; i < length; i++) {
if (matches(sequence.charAt(i))) {
return i;
}
}
return -1;
} /**
* 返回Matcher在sequence中从start开始的匹配到的第一个字符的坐标
*/
public int indexIn(CharSequence sequence, int start) {
int length = sequence.length();
Preconditions.checkPositionIndex(start, length);
for (int i = start; i < length; i++) {
if (matches(sequence.charAt(i))) {
return i;
}
}
return -1;
} /**
* 返回sequence最后一次匹配到Matcher的坐标
*/
public int lastIndexIn(CharSequence sequence) {
for (int i = sequence.length() - 1; i >= 0; i--) {
if (matches(sequence.charAt(i))) {
return i;
}
}
return -1;
} /**
* 返回Sequence匹配到Matcher的次数
*/
public int countIn(CharSequence sequence) {
int count = 0;
for (int i = 0; i < sequence.length(); i++) {
if (matches(sequence.charAt(i))) {
count++;
}
}
return count;
} /**
* 删除sequence中匹配到的所有字符并返回
*/
@CheckReturnValue
public String removeFrom(CharSequence sequence) {
String string = sequence.toString();
int pos = indexIn(string);
if (pos == -1) {
return string;
} char[] chars = string.toCharArray();
int spread = 1; // This unusual loop comes from extensive benchmarking
// 位移删除算法, 使用了双层循环和break OUT 写法
OUT: while (true) {
pos++;
while (true) {
if (pos == chars.length) {
break OUT;
}
if (matches(chars[pos])) {
break;
}
chars[pos - spread] = chars[pos];
pos++;
}
spread++;
}
return new String(chars, 0, pos - spread);
} /**
* 保留所有匹配的Matcher的字符并返回
* 使用逆向的Matcher的removeFrom()实现
*/
@CheckReturnValue
public String retainFrom(CharSequence sequence) {
return negate().removeFrom(sequence);
} /**
* 将所有匹配到Matcher的字符换成指定字符
*/
@CheckReturnValue
public String replaceFrom(CharSequence sequence, char replacement) {
String string = sequence.toString();
int pos = indexIn(string);
if (pos == -1) {
return string;
}
char[] chars = string.toCharArray();
chars[pos] = replacement;
for (int i = pos + 1; i < chars.length; i++) {
if (matches(chars[i])) {
chars[i] = replacement;
}
}
return new String(chars);
} /**
* 将所有可以匹配到的字符换成指定字符串
* 他的实现与替换成字符不相同,他是使用indexIn和StringBuilder实现的
*/
@CheckReturnValue
public String replaceFrom(CharSequence sequence, CharSequence replacement) {
int replacementLen = replacement.length();
if (replacementLen == 0) {
return removeFrom(sequence);
}
if (replacementLen == 1) {
return replaceFrom(sequence, replacement.charAt(0));
} String string = sequence.toString();
int pos = indexIn(string);
if (pos == -1) {
return string;
} int len = string.length();
StringBuilder buf = new StringBuilder((len * 3 / 2) + 16); int oldpos = 0;
do {
buf.append(string, oldpos, pos);
buf.append(replacement);
oldpos = pos + 1;
pos = indexIn(string, oldpos);
} while (pos != -1); buf.append(string, oldpos, len);
return buf.toString();
} /**
* 去除sequence首尾所有这个Matcher匹配的字符
*/
@CheckReturnValue
public String trimFrom(CharSequence sequence) {
int len = sequence.length();
int first;
int last; for (first = 0; first < len; first++) {
if (!matches(sequence.charAt(first))) {
break;
}
}
for (last = len - 1; last > first; last--) {
if (!matches(sequence.charAt(last))) {
break;
}
} return sequence.subSequence(first, last + 1).toString();
} /**
* 去掉sequence开头的所有Matcher能匹配的字符
*/
@CheckReturnValue
public String trimLeadingFrom(CharSequence sequence) {
int len = sequence.length();
int first; for (first = 0; first < len; first++) {
if (!matches(sequence.charAt(first))) {
break;
}
} return sequence.subSequence(first, len).toString();
} /**
* 删除字符串尾部所有能匹配Matcher的字符
*/
@CheckReturnValue
public String trimTrailingFrom(CharSequence sequence) {
int len = sequence.length();
int last; for (last = len - 1; last >= 0; last--) {
if (!matches(sequence.charAt(last))) {
break;
}
} return sequence.subSequence(0, last + 1).toString();
} /**
* 将所有能被Matcher匹配的组(连续匹配的字串)替换成指定字符
*/
@CheckReturnValue
public String collapseFrom(CharSequence sequence, char replacement) {
int first = indexIn(sequence);
if (first == -1) {
return sequence.toString();
} // TODO(kevinb): see if this implementation can be made faster
StringBuilder builder = new StringBuilder(sequence.length())
.append(sequence.subSequence(0, first))
.append(replacement);
boolean in = true;
for (int i = first + 1; i < sequence.length(); i++) {
char c = sequence.charAt(i);
if (matches(c)) {
if (!in) {
builder.append(replacement);
in = true;
}
} else {
builder.append(c);
in = false;
}
}
return builder.toString();
} /**
* 先trim再Collapse
*/
@CheckReturnValue
public String trimAndCollapseFrom(CharSequence sequence, char replacement) {
int first = negate().indexIn(sequence);
if (first == -1) {
return ""; // everything matches. nothing's left.
}
StringBuilder builder = new StringBuilder(sequence.length());
boolean inMatchingGroup = false;
for (int i = first; i < sequence.length(); i++) {
char c = sequence.charAt(i);
if (matches(c)) {
inMatchingGroup = true;
} else {
if (inMatchingGroup) {
builder.append(replacement);
inMatchingGroup = false;
}
builder.append(c);
}
}
return builder.toString();
} // Predicate interface /**
* matches()的异名方法
*/
@Override public boolean apply(Character character) {
return matches(character);
}
补完:
1. 提供的默认实现CharMatcher功能及介绍
2. 操作方法签名及功能列表
3. 使用代码示例