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/*
 * Copyright 2014 The Netty Project
 *
 * The Netty Project licenses this file to you 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 io.netty.util;

import io.netty.util.internal.EmptyArrays;
import io.netty.util.internal.InternalThreadLocalMap;
import io.netty.util.internal.PlatformDependent;

import java.nio.ByteBuffer;
import java.nio.CharBuffer;
import java.nio.charset.Charset;
import java.nio.charset.CharsetEncoder;
import java.util.Arrays;
import java.util.Collection;
import java.util.List;
import java.util.regex.Pattern;
import java.util.regex.PatternSyntaxException;

import static io.netty.util.internal.MathUtil.isOutOfBounds;
import static io.netty.util.internal.ObjectUtil.checkNotNull;

/**
 * A string which has been encoded into a character encoding whose character always takes a single byte, similarly to
 * ASCII. It internally keeps its content in a byte array unlike {@link String}, which uses a character array, for
 * reduced memory footprint and faster data transfer from/to byte-based data structures such as a byte array and
 * {@link ByteBuffer}. It is often used in conjunction with {@code Headers} that require a {@link CharSequence}.
 * 

* This class was designed to provide an immutable array of bytes, and caches some internal state based upon the value * of this array. However underlying access to this byte array is provided via not copying the array on construction or * {@link #array()}. If any changes are made to the underlying byte array it is the user's responsibility to call * {@link #arrayChanged()} so the state of this class can be reset. */ public final class AsciiString implements CharSequence, Comparable { public static final AsciiString EMPTY_STRING = cached(""); private static final char MAX_CHAR_VALUE = 255; public static final int INDEX_NOT_FOUND = -1; /** * If this value is modified outside the constructor then call {@link #arrayChanged()}. */ private final byte[] value; /** * Offset into {@link #value} that all operations should use when acting upon {@link #value}. */ private final int offset; /** * Length in bytes for {@link #value} that we care about. This is independent from {@code value.length} * because we may be looking at a subsection of the array. */ private final int length; /** * The hash code is cached after it is first computed. It can be reset with {@link #arrayChanged()}. */ private int hash; /** * Used to cache the {@link #toString()} value. */ private String string; /** * Initialize this byte string based upon a byte array. A copy will be made. */ public AsciiString(byte[] value) { this(value, true); } /** * Initialize this byte string based upon a byte array. * {@code copy} determines if a copy is made or the array is shared. */ public AsciiString(byte[] value, boolean copy) { this(value, 0, value.length, copy); } /** * Construct a new instance from a {@code byte[]} array. * @param copy {@code true} then a copy of the memory will be made. {@code false} the underlying memory * will be shared. */ public AsciiString(byte[] value, int start, int length, boolean copy) { if (copy) { this.value = Arrays.copyOfRange(value, start, start + length); this.offset = 0; } else { if (isOutOfBounds(start, length, value.length)) { throw new IndexOutOfBoundsException("expected: " + "0 <= start(" + start + ") <= start + length(" + length + ") <= " + "value.length(" + value.length + ')'); } this.value = value; this.offset = start; } this.length = length; } /** * Create a copy of the underlying storage from {@code value}. * The copy will start at {@link ByteBuffer#position()} and copy {@link ByteBuffer#remaining()} bytes. */ public AsciiString(ByteBuffer value) { this(value, true); } /** * Initialize an instance based upon the underlying storage from {@code value}. * There is a potential to share the underlying array storage if {@link ByteBuffer#hasArray()} is {@code true}. * if {@code copy} is {@code true} a copy will be made of the memory. * if {@code copy} is {@code false} the underlying storage will be shared, if possible. */ public AsciiString(ByteBuffer value, boolean copy) { this(value, value.position(), value.remaining(), copy); } /** * Initialize an {@link AsciiString} based upon the underlying storage from {@code value}. * There is a potential to share the underlying array storage if {@link ByteBuffer#hasArray()} is {@code true}. * if {@code copy} is {@code true} a copy will be made of the memory. * if {@code copy} is {@code false} the underlying storage will be shared, if possible. */ public AsciiString(ByteBuffer value, int start, int length, boolean copy) { if (isOutOfBounds(start, length, value.capacity())) { throw new IndexOutOfBoundsException("expected: " + "0 <= start(" + start + ") <= start + length(" + length + ") <= " + "value.capacity(" + value.capacity() + ')'); } if (value.hasArray()) { if (copy) { final int bufferOffset = value.arrayOffset() + start; this.value = Arrays.copyOfRange(value.array(), bufferOffset, bufferOffset + length); offset = 0; } else { this.value = value.array(); this.offset = start; } } else { this.value = PlatformDependent.allocateUninitializedArray(length); int oldPos = value.position(); value.get(this.value, 0, length); value.position(oldPos); this.offset = 0; } this.length = length; } /** * Create a copy of {@code value} into this instance assuming ASCII encoding. */ public AsciiString(char[] value) { this(value, 0, value.length); } /** * Create a copy of {@code value} into this instance assuming ASCII encoding. * The copy will start at index {@code start} and copy {@code length} bytes. */ public AsciiString(char[] value, int start, int length) { if (isOutOfBounds(start, length, value.length)) { throw new IndexOutOfBoundsException("expected: " + "0 <= start(" + start + ") <= start + length(" + length + ") <= " + "value.length(" + value.length + ')'); } this.value = PlatformDependent.allocateUninitializedArray(length); for (int i = 0, j = start; i < length; i++, j++) { this.value[i] = c2b(value[j]); } this.offset = 0; this.length = length; } /** * Create a copy of {@code value} into this instance using the encoding type of {@code charset}. */ public AsciiString(char[] value, Charset charset) { this(value, charset, 0, value.length); } /** * Create a copy of {@code value} into a this instance using the encoding type of {@code charset}. * The copy will start at index {@code start} and copy {@code length} bytes. */ public AsciiString(char[] value, Charset charset, int start, int length) { CharBuffer cbuf = CharBuffer.wrap(value, start, length); CharsetEncoder encoder = CharsetUtil.encoder(charset); ByteBuffer nativeBuffer = ByteBuffer.allocate((int) (encoder.maxBytesPerChar() * length)); encoder.encode(cbuf, nativeBuffer, true); final int bufferOffset = nativeBuffer.arrayOffset(); this.value = Arrays.copyOfRange(nativeBuffer.array(), bufferOffset, bufferOffset + nativeBuffer.position()); this.offset = 0; this.length = this.value.length; } /** * Create a copy of {@code value} into this instance assuming ASCII encoding. */ public AsciiString(CharSequence value) { this(value, 0, value.length()); } /** * Create a copy of {@code value} into this instance assuming ASCII encoding. * The copy will start at index {@code start} and copy {@code length} bytes. */ public AsciiString(CharSequence value, int start, int length) { if (isOutOfBounds(start, length, value.length())) { throw new IndexOutOfBoundsException("expected: " + "0 <= start(" + start + ") <= start + length(" + length + ") <= " + "value.length(" + value.length() + ')'); } this.value = PlatformDependent.allocateUninitializedArray(length); for (int i = 0, j = start; i < length; i++, j++) { this.value[i] = c2b(value.charAt(j)); } this.offset = 0; this.length = length; } /** * Create a copy of {@code value} into this instance using the encoding type of {@code charset}. */ public AsciiString(CharSequence value, Charset charset) { this(value, charset, 0, value.length()); } /** * Create a copy of {@code value} into this instance using the encoding type of {@code charset}. * The copy will start at index {@code start} and copy {@code length} bytes. */ public AsciiString(CharSequence value, Charset charset, int start, int length) { CharBuffer cbuf = CharBuffer.wrap(value, start, start + length); CharsetEncoder encoder = CharsetUtil.encoder(charset); ByteBuffer nativeBuffer = ByteBuffer.allocate((int) (encoder.maxBytesPerChar() * length)); encoder.encode(cbuf, nativeBuffer, true); final int offset = nativeBuffer.arrayOffset(); this.value = Arrays.copyOfRange(nativeBuffer.array(), offset, offset + nativeBuffer.position()); this.offset = 0; this.length = this.value.length; } /** * Iterates over the readable bytes of this buffer with the specified {@code processor} in ascending order. * * @return {@code -1} if the processor iterated to or beyond the end of the readable bytes. * The last-visited index If the {@link ByteProcessor#process(byte)} returned {@code false}. */ public int forEachByte(ByteProcessor visitor) throws Exception { return forEachByte0(0, length(), visitor); } /** * Iterates over the specified area of this buffer with the specified {@code processor} in ascending order. * (i.e. {@code index}, {@code (index + 1)}, .. {@code (index + length - 1)}). * * @return {@code -1} if the processor iterated to or beyond the end of the specified area. * The last-visited index If the {@link ByteProcessor#process(byte)} returned {@code false}. */ public int forEachByte(int index, int length, ByteProcessor visitor) throws Exception { if (isOutOfBounds(index, length, length())) { throw new IndexOutOfBoundsException("expected: " + "0 <= index(" + index + ") <= start + length(" + length + ") <= " + "length(" + length() + ')'); } return forEachByte0(index, length, visitor); } private int forEachByte0(int index, int length, ByteProcessor visitor) throws Exception { final int len = offset + index + length; for (int i = offset + index; i < len; ++i) { if (!visitor.process(value[i])) { return i - offset; } } return -1; } /** * Iterates over the readable bytes of this buffer with the specified {@code processor} in descending order. * * @return {@code -1} if the processor iterated to or beyond the beginning of the readable bytes. * The last-visited index If the {@link ByteProcessor#process(byte)} returned {@code false}. */ public int forEachByteDesc(ByteProcessor visitor) throws Exception { return forEachByteDesc0(0, length(), visitor); } /** * Iterates over the specified area of this buffer with the specified {@code processor} in descending order. * (i.e. {@code (index + length - 1)}, {@code (index + length - 2)}, ... {@code index}). * * @return {@code -1} if the processor iterated to or beyond the beginning of the specified area. * The last-visited index If the {@link ByteProcessor#process(byte)} returned {@code false}. */ public int forEachByteDesc(int index, int length, ByteProcessor visitor) throws Exception { if (isOutOfBounds(index, length, length())) { throw new IndexOutOfBoundsException("expected: " + "0 <= index(" + index + ") <= start + length(" + length + ") <= " + "length(" + length() + ')'); } return forEachByteDesc0(index, length, visitor); } private int forEachByteDesc0(int index, int length, ByteProcessor visitor) throws Exception { final int end = offset + index; for (int i = offset + index + length - 1; i >= end; --i) { if (!visitor.process(value[i])) { return i - offset; } } return -1; } public byte byteAt(int index) { // We must do a range check here to enforce the access does not go outside our sub region of the array. // We rely on the array access itself to pick up the array out of bounds conditions if (index < 0 || index >= length) { throw new IndexOutOfBoundsException("index: " + index + " must be in the range [0," + length + ")"); } // Try to use unsafe to avoid double checking the index bounds if (PlatformDependent.hasUnsafe()) { return PlatformDependent.getByte(value, index + offset); } return value[index + offset]; } /** * Determine if this instance has 0 length. */ public boolean isEmpty() { return length == 0; } /** * The length in bytes of this instance. */ @Override public int length() { return length; } /** * During normal use cases the {@link AsciiString} should be immutable, but if the underlying array is shared, * and changes then this needs to be called. */ public void arrayChanged() { string = null; hash = 0; } /** * This gives direct access to the underlying storage array. * The {@link #toByteArray()} should be preferred over this method. * If the return value is changed then {@link #arrayChanged()} must be called. * @see #arrayOffset() * @see #isEntireArrayUsed() */ public byte[] array() { return value; } /** * The offset into {@link #array()} for which data for this ByteString begins. * @see #array() * @see #isEntireArrayUsed() */ public int arrayOffset() { return offset; } /** * Determine if the storage represented by {@link #array()} is entirely used. * @see #array() */ public boolean isEntireArrayUsed() { return offset == 0 && length == value.length; } /** * Converts this string to a byte array. */ public byte[] toByteArray() { return toByteArray(0, length()); } /** * Converts a subset of this string to a byte array. * The subset is defined by the range [{@code start}, {@code end}). */ public byte[] toByteArray(int start, int end) { return Arrays.copyOfRange(value, start + offset, end + offset); } /** * Copies the content of this string to a byte array. * * @param srcIdx the starting offset of characters to copy. * @param dst the destination byte array. * @param dstIdx the starting offset in the destination byte array. * @param length the number of characters to copy. */ public void copy(int srcIdx, byte[] dst, int dstIdx, int length) { if (isOutOfBounds(srcIdx, length, length())) { throw new IndexOutOfBoundsException("expected: " + "0 <= srcIdx(" + srcIdx + ") <= srcIdx + length(" + length + ") <= srcLen(" + length() + ')'); } System.arraycopy(value, srcIdx + offset, checkNotNull(dst, "dst"), dstIdx, length); } @Override public char charAt(int index) { return b2c(byteAt(index)); } /** * Determines if this {@code String} contains the sequence of characters in the {@code CharSequence} passed. * * @param cs the character sequence to search for. * @return {@code true} if the sequence of characters are contained in this string, otherwise {@code false}. */ public boolean contains(CharSequence cs) { return indexOf(cs) >= 0; } /** * Compares the specified string to this string using the ASCII values of the characters. Returns 0 if the strings * contain the same characters in the same order. Returns a negative integer if the first non-equal character in * this string has an ASCII value which is less than the ASCII value of the character at the same position in the * specified string, or if this string is a prefix of the specified string. Returns a positive integer if the first * non-equal character in this string has a ASCII value which is greater than the ASCII value of the character at * the same position in the specified string, or if the specified string is a prefix of this string. * * @param string the string to compare. * @return 0 if the strings are equal, a negative integer if this string is before the specified string, or a * positive integer if this string is after the specified string. * @throws NullPointerException if {@code string} is {@code null}. */ @Override public int compareTo(CharSequence string) { if (this == string) { return 0; } int result; int length1 = length(); int length2 = string.length(); int minLength = Math.min(length1, length2); for (int i = 0, j = arrayOffset(); i < minLength; i++, j++) { result = b2c(value[j]) - string.charAt(i); if (result != 0) { return result; } } return length1 - length2; } /** * Concatenates this string and the specified string. * * @param string the string to concatenate * @return a new string which is the concatenation of this string and the specified string. */ public AsciiString concat(CharSequence string) { int thisLen = length(); int thatLen = string.length(); if (thatLen == 0) { return this; } if (string instanceof AsciiString) { AsciiString that = (AsciiString) string; if (isEmpty()) { return that; } byte[] newValue = PlatformDependent.allocateUninitializedArray(thisLen + thatLen); System.arraycopy(value, arrayOffset(), newValue, 0, thisLen); System.arraycopy(that.value, that.arrayOffset(), newValue, thisLen, thatLen); return new AsciiString(newValue, false); } if (isEmpty()) { return new AsciiString(string); } byte[] newValue = PlatformDependent.allocateUninitializedArray(thisLen + thatLen); System.arraycopy(value, arrayOffset(), newValue, 0, thisLen); for (int i = thisLen, j = 0; i < newValue.length; i++, j++) { newValue[i] = c2b(string.charAt(j)); } return new AsciiString(newValue, false); } /** * Compares the specified string to this string to determine if the specified string is a suffix. * * @param suffix the suffix to look for. * @return {@code true} if the specified string is a suffix of this string, {@code false} otherwise. * @throws NullPointerException if {@code suffix} is {@code null}. */ public boolean endsWith(CharSequence suffix) { int suffixLen = suffix.length(); return regionMatches(length() - suffixLen, suffix, 0, suffixLen); } /** * Compares the specified string to this string ignoring the case of the characters and returns true if they are * equal. * * @param string the string to compare. * @return {@code true} if the specified string is equal to this string, {@code false} otherwise. */ public boolean contentEqualsIgnoreCase(CharSequence string) { if (this == string) { return true; } if (string == null || string.length() != length()) { return false; } if (string instanceof AsciiString) { AsciiString rhs = (AsciiString) string; for (int i = arrayOffset(), j = rhs.arrayOffset(); i < length(); ++i, ++j) { if (!equalsIgnoreCase(value[i], rhs.value[j])) { return false; } } return true; } for (int i = arrayOffset(), j = 0; i < length(); ++i, ++j) { if (!equalsIgnoreCase(b2c(value[i]), string.charAt(j))) { return false; } } return true; } /** * Copies the characters in this string to a character array. * * @return a character array containing the characters of this string. */ public char[] toCharArray() { return toCharArray(0, length()); } /** * Copies the characters in this string to a character array. * * @return a character array containing the characters of this string. */ public char[] toCharArray(int start, int end) { int length = end - start; if (length == 0) { return EmptyArrays.EMPTY_CHARS; } if (isOutOfBounds(start, length, length())) { throw new IndexOutOfBoundsException("expected: " + "0 <= start(" + start + ") <= srcIdx + length(" + length + ") <= srcLen(" + length() + ')'); } final char[] buffer = new char[length]; for (int i = 0, j = start + arrayOffset(); i < length; i++, j++) { buffer[i] = b2c(value[j]); } return buffer; } /** * Copied the content of this string to a character array. * * @param srcIdx the starting offset of characters to copy. * @param dst the destination character array. * @param dstIdx the starting offset in the destination byte array. * @param length the number of characters to copy. */ public void copy(int srcIdx, char[] dst, int dstIdx, int length) { if (dst == null) { throw new NullPointerException("dst"); } if (isOutOfBounds(srcIdx, length, length())) { throw new IndexOutOfBoundsException("expected: " + "0 <= srcIdx(" + srcIdx + ") <= srcIdx + length(" + length + ") <= srcLen(" + length() + ')'); } final int dstEnd = dstIdx + length; for (int i = dstIdx, j = srcIdx + arrayOffset(); i < dstEnd; i++, j++) { dst[i] = b2c(value[j]); } } /** * Copies a range of characters into a new string. * @param start the offset of the first character (inclusive). * @return a new string containing the characters from start to the end of the string. * @throws IndexOutOfBoundsException if {@code start < 0} or {@code start > length()}. */ public AsciiString subSequence(int start) { return subSequence(start, length()); } /** * Copies a range of characters into a new string. * @param start the offset of the first character (inclusive). * @param end The index to stop at (exclusive). * @return a new string containing the characters from start to the end of the string. * @throws IndexOutOfBoundsException if {@code start < 0} or {@code start > length()}. */ @Override public AsciiString subSequence(int start, int end) { return subSequence(start, end, true); } /** * Either copy or share a subset of underlying sub-sequence of bytes. * @param start the offset of the first character (inclusive). * @param end The index to stop at (exclusive). * @param copy If {@code true} then a copy of the underlying storage will be made. * If {@code false} then the underlying storage will be shared. * @return a new string containing the characters from start to the end of the string. * @throws IndexOutOfBoundsException if {@code start < 0} or {@code start > length()}. */ public AsciiString subSequence(int start, int end, boolean copy) { if (isOutOfBounds(start, end - start, length())) { throw new IndexOutOfBoundsException("expected: 0 <= start(" + start + ") <= end (" + end + ") <= length(" + length() + ')'); } if (start == 0 && end == length()) { return this; } if (end == start) { return EMPTY_STRING; } return new AsciiString(value, start + offset, end - start, copy); } /** * Searches in this string for the first index of the specified string. The search for the string starts at the * beginning and moves towards the end of this string. * * @param string the string to find. * @return the index of the first character of the specified string in this string, -1 if the specified string is * not a substring. * @throws NullPointerException if {@code string} is {@code null}. */ public int indexOf(CharSequence string) { return indexOf(string, 0); } /** * Searches in this string for the index of the specified string. The search for the string starts at the specified * offset and moves towards the end of this string. * * @param subString the string to find. * @param start the starting offset. * @return the index of the first character of the specified string in this string, -1 if the specified string is * not a substring. * @throws NullPointerException if {@code subString} is {@code null}. */ public int indexOf(CharSequence subString, int start) { final int subCount = subString.length(); if (start < 0) { start = 0; } if (subCount <= 0) { return start < length ? start : length; } if (subCount > length - start) { return INDEX_NOT_FOUND; } final char firstChar = subString.charAt(0); if (firstChar > MAX_CHAR_VALUE) { return INDEX_NOT_FOUND; } final byte firstCharAsByte = c2b0(firstChar); final int len = offset + length - subCount; for (int i = start + offset; i <= len; ++i) { if (value[i] == firstCharAsByte) { int o1 = i, o2 = 0; while (++o2 < subCount && b2c(value[++o1]) == subString.charAt(o2)) { // Intentionally empty } if (o2 == subCount) { return i - offset; } } } return INDEX_NOT_FOUND; } /** * Searches in this string for the index of the specified char {@code ch}. * The search for the char starts at the specified offset {@code start} and moves towards the end of this string. * * @param ch the char to find. * @param start the starting offset. * @return the index of the first occurrence of the specified char {@code ch} in this string, * -1 if found no occurrence. */ public int indexOf(char ch, int start) { if (ch > MAX_CHAR_VALUE) { return INDEX_NOT_FOUND; } if (start < 0) { start = 0; } final byte chAsByte = c2b0(ch); final int len = offset + length; for (int i = start + offset; i < len; ++i) { if (value[i] == chAsByte) { return i - offset; } } return INDEX_NOT_FOUND; } /** * Searches in this string for the last index of the specified string. The search for the string starts at the end * and moves towards the beginning of this string. * * @param string the string to find. * @return the index of the first character of the specified string in this string, -1 if the specified string is * not a substring. * @throws NullPointerException if {@code string} is {@code null}. */ public int lastIndexOf(CharSequence string) { // Use count instead of count - 1 so lastIndexOf("") answers count return lastIndexOf(string, length); } /** * Searches in this string for the index of the specified string. The search for the string starts at the specified * offset and moves towards the beginning of this string. * * @param subString the string to find. * @param start the starting offset. * @return the index of the first character of the specified string in this string , -1 if the specified string is * not a substring. * @throws NullPointerException if {@code subString} is {@code null}. */ public int lastIndexOf(CharSequence subString, int start) { final int subCount = subString.length(); start = Math.min(start, length - subCount); if (start < 0) { return INDEX_NOT_FOUND; } if (subCount == 0) { return start; } final char firstChar = subString.charAt(0); if (firstChar > MAX_CHAR_VALUE) { return INDEX_NOT_FOUND; } final byte firstCharAsByte = c2b0(firstChar); for (int i = offset + start; i >= 0; --i) { if (value[i] == firstCharAsByte) { int o1 = i, o2 = 0; while (++o2 < subCount && b2c(value[++o1]) == subString.charAt(o2)) { // Intentionally empty } if (o2 == subCount) { return i - offset; } } } return INDEX_NOT_FOUND; } /** * Compares the specified string to this string and compares the specified range of characters to determine if they * are the same. * * @param thisStart the starting offset in this string. * @param string the string to compare. * @param start the starting offset in the specified string. * @param length the number of characters to compare. * @return {@code true} if the ranges of characters are equal, {@code false} otherwise * @throws NullPointerException if {@code string} is {@code null}. */ public boolean regionMatches(int thisStart, CharSequence string, int start, int length) { if (string == null) { throw new NullPointerException("string"); } if (start < 0 || string.length() - start < length) { return false; } final int thisLen = length(); if (thisStart < 0 || thisLen - thisStart < length) { return false; } if (length <= 0) { return true; } final int thatEnd = start + length; for (int i = start, j = thisStart + arrayOffset(); i < thatEnd; i++, j++) { if (b2c(value[j]) != string.charAt(i)) { return false; } } return true; } /** * Compares the specified string to this string and compares the specified range of characters to determine if they * are the same. When ignoreCase is true, the case of the characters is ignored during the comparison. * * @param ignoreCase specifies if case should be ignored. * @param thisStart the starting offset in this string. * @param string the string to compare. * @param start the starting offset in the specified string. * @param length the number of characters to compare. * @return {@code true} if the ranges of characters are equal, {@code false} otherwise. * @throws NullPointerException if {@code string} is {@code null}. */ public boolean regionMatches(boolean ignoreCase, int thisStart, CharSequence string, int start, int length) { if (!ignoreCase) { return regionMatches(thisStart, string, start, length); } if (string == null) { throw new NullPointerException("string"); } final int thisLen = length(); if (thisStart < 0 || length > thisLen - thisStart) { return false; } if (start < 0 || length > string.length() - start) { return false; } thisStart += arrayOffset(); final int thisEnd = thisStart + length; while (thisStart < thisEnd) { if (!equalsIgnoreCase(b2c(value[thisStart++]), string.charAt(start++))) { return false; } } return true; } /** * Copies this string replacing occurrences of the specified character with another character. * * @param oldChar the character to replace. * @param newChar the replacement character. * @return a new string with occurrences of oldChar replaced by newChar. */ public AsciiString replace(char oldChar, char newChar) { if (oldChar > MAX_CHAR_VALUE) { return this; } final byte oldCharAsByte = c2b0(oldChar); final byte newCharAsByte = c2b(newChar); final int len = offset + length; for (int i = offset; i < len; ++i) { if (value[i] == oldCharAsByte) { byte[] buffer = PlatformDependent.allocateUninitializedArray(length()); System.arraycopy(value, offset, buffer, 0, i - offset); buffer[i - offset] = newCharAsByte; ++i; for (; i < len; ++i) { byte oldValue = value[i]; buffer[i - offset] = oldValue != oldCharAsByte ? oldValue : newCharAsByte; } return new AsciiString(buffer, false); } } return this; } /** * Compares the specified string to this string to determine if the specified string is a prefix. * * @param prefix the string to look for. * @return {@code true} if the specified string is a prefix of this string, {@code false} otherwise * @throws NullPointerException if {@code prefix} is {@code null}. */ public boolean startsWith(CharSequence prefix) { return startsWith(prefix, 0); } /** * Compares the specified string to this string, starting at the specified offset, to determine if the specified * string is a prefix. * * @param prefix the string to look for. * @param start the starting offset. * @return {@code true} if the specified string occurs in this string at the specified offset, {@code false} * otherwise. * @throws NullPointerException if {@code prefix} is {@code null}. */ public boolean startsWith(CharSequence prefix, int start) { return regionMatches(start, prefix, 0, prefix.length()); } /** * Converts the characters in this string to lowercase, using the default Locale. * * @return a new string containing the lowercase characters equivalent to the characters in this string. */ public AsciiString toLowerCase() { boolean lowercased = true; int i, j; final int len = length() + arrayOffset(); for (i = arrayOffset(); i < len; ++i) { byte b = value[i]; if (b >= 'A' && b <= 'Z') { lowercased = false; break; } } // Check if this string does not contain any uppercase characters. if (lowercased) { return this; } final byte[] newValue = PlatformDependent.allocateUninitializedArray(length()); for (i = 0, j = arrayOffset(); i < newValue.length; ++i, ++j) { newValue[i] = toLowerCase(value[j]); } return new AsciiString(newValue, false); } /** * Converts the characters in this string to uppercase, using the default Locale. * * @return a new string containing the uppercase characters equivalent to the characters in this string. */ public AsciiString toUpperCase() { boolean uppercased = true; int i, j; final int len = length() + arrayOffset(); for (i = arrayOffset(); i < len; ++i) { byte b = value[i]; if (b >= 'a' && b <= 'z') { uppercased = false; break; } } // Check if this string does not contain any lowercase characters. if (uppercased) { return this; } final byte[] newValue = PlatformDependent.allocateUninitializedArray(length()); for (i = 0, j = arrayOffset(); i < newValue.length; ++i, ++j) { newValue[i] = toUpperCase(value[j]); } return new AsciiString(newValue, false); } /** * Copies this string removing white space characters from the beginning and end of the string, and tries not to * copy if possible. * * @param c The {@link CharSequence} to trim. * @return a new string with characters {@code <= \\u0020} removed from the beginning and the end. */ public static CharSequence trim(CharSequence c) { if (c instanceof AsciiString) { return ((AsciiString) c).trim(); } if (c instanceof String) { return ((String) c).trim(); } int start = 0, last = c.length() - 1; int end = last; while (start <= end && c.charAt(start) <= ' ') { start++; } while (end >= start && c.charAt(end) <= ' ') { end--; } if (start == 0 && end == last) { return c; } return c.subSequence(start, end); } /** * Duplicates this string removing white space characters from the beginning and end of the * string, without copying. * * @return a new string with characters {@code <= \\u0020} removed from the beginning and the end. */ public AsciiString trim() { int start = arrayOffset(), last = arrayOffset() + length() - 1; int end = last; while (start <= end && value[start] <= ' ') { start++; } while (end >= start && value[end] <= ' ') { end--; } if (start == 0 && end == last) { return this; } return new AsciiString(value, start, end - start + 1, false); } /** * Compares a {@code CharSequence} to this {@code String} to determine if their contents are equal. * * @param a the character sequence to compare to. * @return {@code true} if equal, otherwise {@code false} */ public boolean contentEquals(CharSequence a) { if (this == a) { return true; } if (a == null || a.length() != length()) { return false; } if (a instanceof AsciiString) { return equals(a); } for (int i = arrayOffset(), j = 0; j < a.length(); ++i, ++j) { if (b2c(value[i]) != a.charAt(j)) { return false; } } return true; } /** * Determines whether this string matches a given regular expression. * * @param expr the regular expression to be matched. * @return {@code true} if the expression matches, otherwise {@code false}. * @throws PatternSyntaxException if the syntax of the supplied regular expression is not valid. * @throws NullPointerException if {@code expr} is {@code null}. */ public boolean matches(String expr) { return Pattern.matches(expr, this); } /** * Splits this string using the supplied regular expression {@code expr}. The parameter {@code max} controls the * behavior how many times the pattern is applied to the string. * * @param expr the regular expression used to divide the string. * @param max the number of entries in the resulting array. * @return an array of Strings created by separating the string along matches of the regular expression. * @throws NullPointerException if {@code expr} is {@code null}. * @throws PatternSyntaxException if the syntax of the supplied regular expression is not valid. * @see Pattern#split(CharSequence, int) */ public AsciiString[] split(String expr, int max) { return toAsciiStringArray(Pattern.compile(expr).split(this, max)); } /** * Splits the specified {@link String} with the specified delimiter.. */ public AsciiString[] split(char delim) { final List res = InternalThreadLocalMap.get().arrayList(); int start = 0; final int length = length(); for (int i = start; i < length; i++) { if (charAt(i) == delim) { if (start == i) { res.add(EMPTY_STRING); } else { res.add(new AsciiString(value, start + arrayOffset(), i - start, false)); } start = i + 1; } } if (start == 0) { // If no delimiter was found in the value res.add(this); } else { if (start != length) { // Add the last element if it's not empty. res.add(new AsciiString(value, start + arrayOffset(), length - start, false)); } else { // Truncate trailing empty elements. for (int i = res.size() - 1; i >= 0; i--) { if (res.get(i).isEmpty()) { res.remove(i); } else { break; } } } } return res.toArray(new AsciiString[0]); } /** * {@inheritDoc} *

* Provides a case-insensitive hash code for Ascii like byte strings. */ @Override public int hashCode() { int h = hash; if (h == 0) { h = PlatformDependent.hashCodeAscii(value, offset, length); hash = h; } return h; } @Override public boolean equals(Object obj) { if (obj == null || obj.getClass() != AsciiString.class) { return false; } if (this == obj) { return true; } AsciiString other = (AsciiString) obj; return length() == other.length() && hashCode() == other.hashCode() && PlatformDependent.equals(array(), arrayOffset(), other.array(), other.arrayOffset(), length()); } /** * Translates the entire byte string to a {@link String}. * @see #toString(int) */ @Override public String toString() { String cache = string; if (cache == null) { cache = toString(0); string = cache; } return cache; } /** * Translates the entire byte string to a {@link String} using the {@code charset} encoding. * @see #toString(int, int) */ public String toString(int start) { return toString(start, length()); } /** * Translates the [{@code start}, {@code end}) range of this byte string to a {@link String}. */ public String toString(int start, int end) { int length = end - start; if (length == 0) { return ""; } if (isOutOfBounds(start, length, length())) { throw new IndexOutOfBoundsException("expected: " + "0 <= start(" + start + ") <= srcIdx + length(" + length + ") <= srcLen(" + length() + ')'); } @SuppressWarnings("deprecation") final String str = new String(value, 0, start + offset, length); return str; } public boolean parseBoolean() { return length >= 1 && value[offset] != 0; } public char parseChar() { return parseChar(0); } public char parseChar(int start) { if (start + 1 >= length()) { throw new IndexOutOfBoundsException("2 bytes required to convert to character. index " + start + " would go out of bounds."); } final int startWithOffset = start + offset; return (char) ((b2c(value[startWithOffset]) << 8) | b2c(value[startWithOffset + 1])); } public short parseShort() { return parseShort(0, length(), 10); } public short parseShort(int radix) { return parseShort(0, length(), radix); } public short parseShort(int start, int end) { return parseShort(start, end, 10); } public short parseShort(int start, int end, int radix) { int intValue = parseInt(start, end, radix); short result = (short) intValue; if (result != intValue) { throw new NumberFormatException(subSequence(start, end, false).toString()); } return result; } public int parseInt() { return parseInt(0, length(), 10); } public int parseInt(int radix) { return parseInt(0, length(), radix); } public int parseInt(int start, int end) { return parseInt(start, end, 10); } public int parseInt(int start, int end, int radix) { if (radix < Character.MIN_RADIX || radix > Character.MAX_RADIX) { throw new NumberFormatException(); } if (start == end) { throw new NumberFormatException(); } int i = start; boolean negative = byteAt(i) == '-'; if (negative && ++i == end) { throw new NumberFormatException(subSequence(start, end, false).toString()); } return parseInt(i, end, radix, negative); } private int parseInt(int start, int end, int radix, boolean negative) { int max = Integer.MIN_VALUE / radix; int result = 0; int currOffset = start; while (currOffset < end) { int digit = Character.digit((char) (value[currOffset++ + offset] & 0xFF), radix); if (digit == -1) { throw new NumberFormatException(subSequence(start, end, false).toString()); } if (max > result) { throw new NumberFormatException(subSequence(start, end, false).toString()); } int next = result * radix - digit; if (next > result) { throw new NumberFormatException(subSequence(start, end, false).toString()); } result = next; } if (!negative) { result = -result; if (result < 0) { throw new NumberFormatException(subSequence(start, end, false).toString()); } } return result; } public long parseLong() { return parseLong(0, length(), 10); } public long parseLong(int radix) { return parseLong(0, length(), radix); } public long parseLong(int start, int end) { return parseLong(start, end, 10); } public long parseLong(int start, int end, int radix) { if (radix < Character.MIN_RADIX || radix > Character.MAX_RADIX) { throw new NumberFormatException(); } if (start == end) { throw new NumberFormatException(); } int i = start; boolean negative = byteAt(i) == '-'; if (negative && ++i == end) { throw new NumberFormatException(subSequence(start, end, false).toString()); } return parseLong(i, end, radix, negative); } private long parseLong(int start, int end, int radix, boolean negative) { long max = Long.MIN_VALUE / radix; long result = 0; int currOffset = start; while (currOffset < end) { int digit = Character.digit((char) (value[currOffset++ + offset] & 0xFF), radix); if (digit == -1) { throw new NumberFormatException(subSequence(start, end, false).toString()); } if (max > result) { throw new NumberFormatException(subSequence(start, end, false).toString()); } long next = result * radix - digit; if (next > result) { throw new NumberFormatException(subSequence(start, end, false).toString()); } result = next; } if (!negative) { result = -result; if (result < 0) { throw new NumberFormatException(subSequence(start, end, false).toString()); } } return result; } public float parseFloat() { return parseFloat(0, length()); } public float parseFloat(int start, int end) { return Float.parseFloat(toString(start, end)); } public double parseDouble() { return parseDouble(0, length()); } public double parseDouble(int start, int end) { return Double.parseDouble(toString(start, end)); } public static final HashingStrategy CASE_INSENSITIVE_HASHER = new HashingStrategy() { @Override public int hashCode(CharSequence o) { return AsciiString.hashCode(o); } @Override public boolean equals(CharSequence a, CharSequence b) { return AsciiString.contentEqualsIgnoreCase(a, b); } }; public static final HashingStrategy CASE_SENSITIVE_HASHER = new HashingStrategy() { @Override public int hashCode(CharSequence o) { return AsciiString.hashCode(o); } @Override public boolean equals(CharSequence a, CharSequence b) { return AsciiString.contentEquals(a, b); } }; /** * Returns an {@link AsciiString} containing the given character sequence. If the given string is already a * {@link AsciiString}, just returns the same instance. */ public static AsciiString of(CharSequence string) { return string instanceof AsciiString ? (AsciiString) string : new AsciiString(string); } /** * Returns an {@link AsciiString} containing the given string and retains/caches the input * string for later use in {@link #toString()}. * Used for the constants (which already stored in the JVM's string table) and in cases * where the guaranteed use of the {@link #toString()} method. */ public static AsciiString cached(String string) { AsciiString asciiString = new AsciiString(string); asciiString.string = string; return asciiString; } /** * Returns the case-insensitive hash code of the specified string. Note that this method uses the same hashing * algorithm with {@link #hashCode()} so that you can put both {@link AsciiString}s and arbitrary * {@link CharSequence}s into the same headers. */ public static int hashCode(CharSequence value) { if (value == null) { return 0; } if (value instanceof AsciiString) { return value.hashCode(); } return PlatformDependent.hashCodeAscii(value); } /** * Determine if {@code a} contains {@code b} in a case sensitive manner. */ public static boolean contains(CharSequence a, CharSequence b) { return contains(a, b, DefaultCharEqualityComparator.INSTANCE); } /** * Determine if {@code a} contains {@code b} in a case insensitive manner. */ public static boolean containsIgnoreCase(CharSequence a, CharSequence b) { return contains(a, b, AsciiCaseInsensitiveCharEqualityComparator.INSTANCE); } /** * Returns {@code true} if both {@link CharSequence}'s are equals when ignore the case. This only supports 8-bit * ASCII. */ public static boolean contentEqualsIgnoreCase(CharSequence a, CharSequence b) { if (a == null || b == null) { return a == b; } if (a instanceof AsciiString) { return ((AsciiString) a).contentEqualsIgnoreCase(b); } if (b instanceof AsciiString) { return ((AsciiString) b).contentEqualsIgnoreCase(a); } if (a.length() != b.length()) { return false; } for (int i = 0; i < a.length(); ++i) { if (!equalsIgnoreCase(a.charAt(i), b.charAt(i))) { return false; } } return true; } /** * Determine if {@code collection} contains {@code value} and using * {@link #contentEqualsIgnoreCase(CharSequence, CharSequence)} to compare values. * @param collection The collection to look for and equivalent element as {@code value}. * @param value The value to look for in {@code collection}. * @return {@code true} if {@code collection} contains {@code value} according to * {@link #contentEqualsIgnoreCase(CharSequence, CharSequence)}. {@code false} otherwise. * @see #contentEqualsIgnoreCase(CharSequence, CharSequence) */ public static boolean containsContentEqualsIgnoreCase(Collection collection, CharSequence value) { for (CharSequence v : collection) { if (contentEqualsIgnoreCase(value, v)) { return true; } } return false; } /** * Determine if {@code a} contains all of the values in {@code b} using * {@link #contentEqualsIgnoreCase(CharSequence, CharSequence)} to compare values. * @param a The collection under test. * @param b The values to test for. * @return {@code true} if {@code a} contains all of the values in {@code b} using * {@link #contentEqualsIgnoreCase(CharSequence, CharSequence)} to compare values. {@code false} otherwise. * @see #contentEqualsIgnoreCase(CharSequence, CharSequence) */ public static boolean containsAllContentEqualsIgnoreCase(Collection a, Collection b) { for (CharSequence v : b) { if (!containsContentEqualsIgnoreCase(a, v)) { return false; } } return true; } /** * Returns {@code true} if the content of both {@link CharSequence}'s are equals. This only supports 8-bit ASCII. */ public static boolean contentEquals(CharSequence a, CharSequence b) { if (a == null || b == null) { return a == b; } if (a instanceof AsciiString) { return ((AsciiString) a).contentEquals(b); } if (b instanceof AsciiString) { return ((AsciiString) b).contentEquals(a); } if (a.length() != b.length()) { return false; } for (int i = 0; i < a.length(); ++i) { if (a.charAt(i) != b.charAt(i)) { return false; } } return true; } private static AsciiString[] toAsciiStringArray(String[] jdkResult) { AsciiString[] res = new AsciiString[jdkResult.length]; for (int i = 0; i < jdkResult.length; i++) { res[i] = new AsciiString(jdkResult[i]); } return res; } private interface CharEqualityComparator { boolean equals(char a, char b); } private static final class DefaultCharEqualityComparator implements CharEqualityComparator { static final DefaultCharEqualityComparator INSTANCE = new DefaultCharEqualityComparator(); private DefaultCharEqualityComparator() { } @Override public boolean equals(char a, char b) { return a == b; } } private static final class AsciiCaseInsensitiveCharEqualityComparator implements CharEqualityComparator { static final AsciiCaseInsensitiveCharEqualityComparator INSTANCE = new AsciiCaseInsensitiveCharEqualityComparator(); private AsciiCaseInsensitiveCharEqualityComparator() { } @Override public boolean equals(char a, char b) { return equalsIgnoreCase(a, b); } } private static final class GeneralCaseInsensitiveCharEqualityComparator implements CharEqualityComparator { static final GeneralCaseInsensitiveCharEqualityComparator INSTANCE = new GeneralCaseInsensitiveCharEqualityComparator(); private GeneralCaseInsensitiveCharEqualityComparator() { } @Override public boolean equals(char a, char b) { //For motivation, why we need two checks, see comment in String#regionMatches return Character.toUpperCase(a) == Character.toUpperCase(b) || Character.toLowerCase(a) == Character.toLowerCase(b); } } private static boolean contains(CharSequence a, CharSequence b, CharEqualityComparator cmp) { if (a == null || b == null || a.length() < b.length()) { return false; } if (b.length() == 0) { return true; } int bStart = 0; for (int i = 0; i < a.length(); ++i) { if (cmp.equals(b.charAt(bStart), a.charAt(i))) { // If b is consumed then true. if (++bStart == b.length()) { return true; } } else if (a.length() - i < b.length()) { // If there are not enough characters left in a for b to be contained, then false. return false; } else { bStart = 0; } } return false; } private static boolean regionMatchesCharSequences(final CharSequence cs, final int csStart, final CharSequence string, final int start, final int length, CharEqualityComparator charEqualityComparator) { //general purpose implementation for CharSequences if (csStart < 0 || length > cs.length() - csStart) { return false; } if (start < 0 || length > string.length() - start) { return false; } int csIndex = csStart; int csEnd = csIndex + length; int stringIndex = start; while (csIndex < csEnd) { char c1 = cs.charAt(csIndex++); char c2 = string.charAt(stringIndex++); if (!charEqualityComparator.equals(c1, c2)) { return false; } } return true; } /** * This methods make regionMatches operation correctly for any chars in strings * @param cs the {@code CharSequence} to be processed * @param ignoreCase specifies if case should be ignored. * @param csStart the starting offset in the {@code cs} CharSequence * @param string the {@code CharSequence} to compare. * @param start the starting offset in the specified {@code string}. * @param length the number of characters to compare. * @return {@code true} if the ranges of characters are equal, {@code false} otherwise. */ public static boolean regionMatches(final CharSequence cs, final boolean ignoreCase, final int csStart, final CharSequence string, final int start, final int length) { if (cs == null || string == null) { return false; } if (cs instanceof String && string instanceof String) { return ((String) cs).regionMatches(ignoreCase, csStart, (String) string, start, length); } if (cs instanceof AsciiString) { return ((AsciiString) cs).regionMatches(ignoreCase, csStart, string, start, length); } return regionMatchesCharSequences(cs, csStart, string, start, length, ignoreCase ? GeneralCaseInsensitiveCharEqualityComparator.INSTANCE : DefaultCharEqualityComparator.INSTANCE); } /** * This is optimized version of regionMatches for string with ASCII chars only * @param cs the {@code CharSequence} to be processed * @param ignoreCase specifies if case should be ignored. * @param csStart the starting offset in the {@code cs} CharSequence * @param string the {@code CharSequence} to compare. * @param start the starting offset in the specified {@code string}. * @param length the number of characters to compare. * @return {@code true} if the ranges of characters are equal, {@code false} otherwise. */ public static boolean regionMatchesAscii(final CharSequence cs, final boolean ignoreCase, final int csStart, final CharSequence string, final int start, final int length) { if (cs == null || string == null) { return false; } if (!ignoreCase && cs instanceof String && string instanceof String) { //we don't call regionMatches from String for ignoreCase==true. It's a general purpose method, //which make complex comparison in case of ignoreCase==true, which is useless for ASCII-only strings. //To avoid applying this complex ignore-case comparison, we will use regionMatchesCharSequences return ((String) cs).regionMatches(false, csStart, (String) string, start, length); } if (cs instanceof AsciiString) { return ((AsciiString) cs).regionMatches(ignoreCase, csStart, string, start, length); } return regionMatchesCharSequences(cs, csStart, string, start, length, ignoreCase ? AsciiCaseInsensitiveCharEqualityComparator.INSTANCE : DefaultCharEqualityComparator.INSTANCE); } /** *

Case in-sensitive find of the first index within a CharSequence * from the specified position.

* *

A {@code null} CharSequence will return {@code -1}. * A negative start position is treated as zero. * An empty ("") search CharSequence always matches. * A start position greater than the string length only matches * an empty search CharSequence.

* *
     * AsciiString.indexOfIgnoreCase(null, *, *)          = -1
     * AsciiString.indexOfIgnoreCase(*, null, *)          = -1
     * AsciiString.indexOfIgnoreCase("", "", 0)           = 0
     * AsciiString.indexOfIgnoreCase("aabaabaa", "A", 0)  = 0
     * AsciiString.indexOfIgnoreCase("aabaabaa", "B", 0)  = 2
     * AsciiString.indexOfIgnoreCase("aabaabaa", "AB", 0) = 1
     * AsciiString.indexOfIgnoreCase("aabaabaa", "B", 3)  = 5
     * AsciiString.indexOfIgnoreCase("aabaabaa", "B", 9)  = -1
     * AsciiString.indexOfIgnoreCase("aabaabaa", "B", -1) = 2
     * AsciiString.indexOfIgnoreCase("aabaabaa", "", 2)   = 2
     * AsciiString.indexOfIgnoreCase("abc", "", 9)        = -1
     * 
* * @param str the CharSequence to check, may be null * @param searchStr the CharSequence to find, may be null * @param startPos the start position, negative treated as zero * @return the first index of the search CharSequence (always ≥ startPos), * -1 if no match or {@code null} string input */ public static int indexOfIgnoreCase(final CharSequence str, final CharSequence searchStr, int startPos) { if (str == null || searchStr == null) { return INDEX_NOT_FOUND; } if (startPos < 0) { startPos = 0; } int searchStrLen = searchStr.length(); final int endLimit = str.length() - searchStrLen + 1; if (startPos > endLimit) { return INDEX_NOT_FOUND; } if (searchStrLen == 0) { return startPos; } for (int i = startPos; i < endLimit; i++) { if (regionMatches(str, true, i, searchStr, 0, searchStrLen)) { return i; } } return INDEX_NOT_FOUND; } /** *

Case in-sensitive find of the first index within a CharSequence * from the specified position. This method optimized and works correctly for ASCII CharSequences only

* *

A {@code null} CharSequence will return {@code -1}. * A negative start position is treated as zero. * An empty ("") search CharSequence always matches. * A start position greater than the string length only matches * an empty search CharSequence.

* *
     * AsciiString.indexOfIgnoreCase(null, *, *)          = -1
     * AsciiString.indexOfIgnoreCase(*, null, *)          = -1
     * AsciiString.indexOfIgnoreCase("", "", 0)           = 0
     * AsciiString.indexOfIgnoreCase("aabaabaa", "A", 0)  = 0
     * AsciiString.indexOfIgnoreCase("aabaabaa", "B", 0)  = 2
     * AsciiString.indexOfIgnoreCase("aabaabaa", "AB", 0) = 1
     * AsciiString.indexOfIgnoreCase("aabaabaa", "B", 3)  = 5
     * AsciiString.indexOfIgnoreCase("aabaabaa", "B", 9)  = -1
     * AsciiString.indexOfIgnoreCase("aabaabaa", "B", -1) = 2
     * AsciiString.indexOfIgnoreCase("aabaabaa", "", 2)   = 2
     * AsciiString.indexOfIgnoreCase("abc", "", 9)        = -1
     * 
* * @param str the CharSequence to check, may be null * @param searchStr the CharSequence to find, may be null * @param startPos the start position, negative treated as zero * @return the first index of the search CharSequence (always ≥ startPos), * -1 if no match or {@code null} string input */ public static int indexOfIgnoreCaseAscii(final CharSequence str, final CharSequence searchStr, int startPos) { if (str == null || searchStr == null) { return INDEX_NOT_FOUND; } if (startPos < 0) { startPos = 0; } int searchStrLen = searchStr.length(); final int endLimit = str.length() - searchStrLen + 1; if (startPos > endLimit) { return INDEX_NOT_FOUND; } if (searchStrLen == 0) { return startPos; } for (int i = startPos; i < endLimit; i++) { if (regionMatchesAscii(str, true, i, searchStr, 0, searchStrLen)) { return i; } } return INDEX_NOT_FOUND; } /** *

Finds the first index in the {@code CharSequence} that matches the * specified character.

* * @param cs the {@code CharSequence} to be processed, not null * @param searchChar the char to be searched for * @param start the start index, negative starts at the string start * @return the index where the search char was found, * -1 if char {@code searchChar} is not found or {@code cs == null} */ //----------------------------------------------------------------------- public static int indexOf(final CharSequence cs, final char searchChar, int start) { if (cs instanceof String) { return ((String) cs).indexOf(searchChar, start); } else if (cs instanceof AsciiString) { return ((AsciiString) cs).indexOf(searchChar, start); } if (cs == null) { return INDEX_NOT_FOUND; } final int sz = cs.length(); for (int i = start < 0 ? 0 : start; i < sz; i++) { if (cs.charAt(i) == searchChar) { return i; } } return INDEX_NOT_FOUND; } private static boolean equalsIgnoreCase(byte a, byte b) { return a == b || toLowerCase(a) == toLowerCase(b); } private static boolean equalsIgnoreCase(char a, char b) { return a == b || toLowerCase(a) == toLowerCase(b); } private static byte toLowerCase(byte b) { return isUpperCase(b) ? (byte) (b + 32) : b; } /** * If the character is uppercase - converts the character to lowercase, * otherwise returns the character as it is. Only for ASCII characters. * * @return lowercase ASCII character equivalent */ public static char toLowerCase(char c) { return isUpperCase(c) ? (char) (c + 32) : c; } private static byte toUpperCase(byte b) { return isLowerCase(b) ? (byte) (b - 32) : b; } private static boolean isLowerCase(byte value) { return value >= 'a' && value <= 'z'; } public static boolean isUpperCase(byte value) { return value >= 'A' && value <= 'Z'; } public static boolean isUpperCase(char value) { return value >= 'A' && value <= 'Z'; } public static byte c2b(char c) { return (byte) ((c > MAX_CHAR_VALUE) ? '?' : c); } private static byte c2b0(char c) { return (byte) c; } public static char b2c(byte b) { return (char) (b & 0xFF); } }




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