All Downloads are FREE. Search and download functionalities are using the official Maven repository.

com.ibm.icu.text.Normalizer2 Maven / Gradle / Ivy

Go to download

International Component for Unicode for Java (ICU4J) is a mature, widely used Java library providing Unicode and Globalization support

There is a newer version: 76.1
Show newest version
// © 2016 and later: Unicode, Inc. and others.
// License & terms of use: http://www.unicode.org/copyright.html#License
/*
 *******************************************************************************
 *   Copyright (C) 2009-2016, International Business Machines
 *   Corporation and others.  All Rights Reserved.
 *******************************************************************************
 */

package com.ibm.icu.text;

import java.io.IOException;
import java.io.InputStream;
import java.nio.ByteBuffer;

import com.ibm.icu.impl.ICUBinary;
import com.ibm.icu.impl.Norm2AllModes;
import com.ibm.icu.util.ICUUncheckedIOException;

/**
 * Unicode normalization functionality for standard Unicode normalization or
 * for using custom mapping tables.
 * All instances of this class are unmodifiable/immutable.
 * The Normalizer2 class is not intended for public subclassing.
 * 

* The primary functions are to produce a normalized string and to detect whether * a string is already normalized. * The most commonly used normalization forms are those defined in * http://www.unicode.org/unicode/reports/tr15/ * However, this API supports additional normalization forms for specialized purposes. * For example, NFKC_Casefold is provided via getInstance("nfkc_cf", COMPOSE) * and can be used in implementations of UTS #46. *

* Not only are the standard compose and decompose modes supplied, * but additional modes are provided as documented in the Mode enum. *

* Some of the functions in this class identify normalization boundaries. * At a normalization boundary, the portions of the string * before it and starting from it do not interact and can be handled independently. *

* The spanQuickCheckYes() stops at a normalization boundary. * When the goal is a normalized string, then the text before the boundary * can be copied, and the remainder can be processed with normalizeSecondAndAppend(). *

* The hasBoundaryBefore(), hasBoundaryAfter() and isInert() functions test whether * a character is guaranteed to be at a normalization boundary, * regardless of context. * This is used for moving from one normalization boundary to the next * or preceding boundary, and for performing iterative normalization. *

* Iterative normalization is useful when only a small portion of a * longer string needs to be processed. * For example, in ICU, iterative normalization is used by the NormalizationTransliterator * (to avoid replacing already-normalized text) and ucol_nextSortKeyPart() * (to process only the substring for which sort key bytes are computed). *

* The set of normalization boundaries returned by these functions may not be * complete: There may be more boundaries that could be returned. * Different functions may return different boundaries. * @stable ICU 4.4 * @author Markus W. Scherer */ public abstract class Normalizer2 { /** * Constants for normalization modes. * For details about standard Unicode normalization forms * and about the algorithms which are also used with custom mapping tables * see http://www.unicode.org/unicode/reports/tr15/ * @stable ICU 4.4 */ public enum Mode { /** * Decomposition followed by composition. * Same as standard NFC when using an "nfc" instance. * Same as standard NFKC when using an "nfkc" instance. * For details about standard Unicode normalization forms * see http://www.unicode.org/unicode/reports/tr15/ * @stable ICU 4.4 */ COMPOSE, /** * Map, and reorder canonically. * Same as standard NFD when using an "nfc" instance. * Same as standard NFKD when using an "nfkc" instance. * For details about standard Unicode normalization forms * see http://www.unicode.org/unicode/reports/tr15/ * @stable ICU 4.4 */ DECOMPOSE, /** * "Fast C or D" form. * If a string is in this form, then further decomposition without reordering * would yield the same form as DECOMPOSE. * Text in "Fast C or D" form can be processed efficiently with data tables * that are "canonically closed", that is, that provide equivalent data for * equivalent text, without having to be fully normalized.
* Not a standard Unicode normalization form.
* Not a unique form: Different FCD strings can be canonically equivalent.
* For details see http://www.unicode.org/notes/tn5/#FCD * @stable ICU 4.4 */ FCD, /** * Compose only contiguously. * Also known as "FCC" or "Fast C Contiguous". * The result will often but not always be in NFC. * The result will conform to FCD which is useful for processing.
* Not a standard Unicode normalization form.
* For details see http://www.unicode.org/notes/tn5/#FCC * @stable ICU 4.4 */ COMPOSE_CONTIGUOUS }; /** * Returns a Normalizer2 instance for Unicode NFC normalization. * Same as getInstance(null, "nfc", Mode.COMPOSE). * Returns an unmodifiable singleton instance. * @return the requested Normalizer2, if successful * @stable ICU 49 */ public static Normalizer2 getNFCInstance() { return Norm2AllModes.getNFCInstance().comp; } /** * Returns a Normalizer2 instance for Unicode NFD normalization. * Same as getInstance(null, "nfc", Mode.DECOMPOSE). * Returns an unmodifiable singleton instance. * @return the requested Normalizer2, if successful * @stable ICU 49 */ public static Normalizer2 getNFDInstance() { return Norm2AllModes.getNFCInstance().decomp; } /** * Returns a Normalizer2 instance for Unicode NFKC normalization. * Same as getInstance(null, "nfkc", Mode.COMPOSE). * Returns an unmodifiable singleton instance. * @return the requested Normalizer2, if successful * @stable ICU 49 */ public static Normalizer2 getNFKCInstance() { return Norm2AllModes.getNFKCInstance().comp; } /** * Returns a Normalizer2 instance for Unicode NFKD normalization. * Same as getInstance(null, "nfkc", Mode.DECOMPOSE). * Returns an unmodifiable singleton instance. * @return the requested Normalizer2, if successful * @stable ICU 49 */ public static Normalizer2 getNFKDInstance() { return Norm2AllModes.getNFKCInstance().decomp; } /** * Returns a Normalizer2 instance for Unicode NFKC_Casefold normalization. * Same as getInstance(null, "nfkc_cf", Mode.COMPOSE). * Returns an unmodifiable singleton instance. * @return the requested Normalizer2, if successful * @stable ICU 49 */ public static Normalizer2 getNFKCCasefoldInstance() { return Norm2AllModes.getNFKC_CFInstance().comp; } /** * Returns a Normalizer2 instance which uses the specified data file * (an ICU data file if data=null, or else custom binary data) * and which composes or decomposes text according to the specified mode. * Returns an unmodifiable singleton instance. *

    *
  • Use data=null for data files that are part of ICU's own data. *
  • Use name="nfc" and COMPOSE/DECOMPOSE for Unicode standard NFC/NFD. *
  • Use name="nfkc" and COMPOSE/DECOMPOSE for Unicode standard NFKC/NFKD. *
  • Use name="nfkc_cf" and COMPOSE for Unicode standard NFKC_CF=NFKC_Casefold. *
* If data!=null, then the binary data is read once and cached using the provided * name as the key. * If you know or expect the data to be cached already, you can use data!=null * for non-ICU data as well. *

Any {@link java.io.IOException} is wrapped into a {@link com.ibm.icu.util.ICUUncheckedIOException}. * @param data the binary, big-endian normalization (.nrm file) data, or null for ICU data * @param name "nfc" or "nfkc" or "nfkc_cf" or name of custom data file * @param mode normalization mode (compose or decompose etc.) * @return the requested Normalizer2, if successful * @stable ICU 4.4 */ public static Normalizer2 getInstance(InputStream data, String name, Mode mode) { // TODO: If callers really use this API, then we should add an overload that takes a ByteBuffer. ByteBuffer bytes = null; if (data != null) { try { bytes = ICUBinary.getByteBufferFromInputStreamAndCloseStream(data); } catch (IOException e) { throw new ICUUncheckedIOException(e); } } Norm2AllModes all2Modes=Norm2AllModes.getInstance(bytes, name); switch(mode) { case COMPOSE: return all2Modes.comp; case DECOMPOSE: return all2Modes.decomp; case FCD: return all2Modes.fcd; case COMPOSE_CONTIGUOUS: return all2Modes.fcc; default: return null; // will not occur } } /** * Returns the normalized form of the source string. * @param src source string * @return normalized src * @stable ICU 4.4 */ public String normalize(CharSequence src) { if(src instanceof String) { // Fastpath: Do not construct a new String if the src is a String // and is already normalized. int spanLength=spanQuickCheckYes(src); if(spanLength==src.length()) { return (String)src; } if (spanLength != 0) { StringBuilder sb=new StringBuilder(src.length()).append(src, 0, spanLength); return normalizeSecondAndAppend(sb, src.subSequence(spanLength, src.length())).toString(); } } return normalize(src, new StringBuilder(src.length())).toString(); } /** * Writes the normalized form of the source string to the destination string * (replacing its contents) and returns the destination string. * The source and destination strings must be different objects. * @param src source string * @param dest destination string; its contents is replaced with normalized src * @return dest * @stable ICU 4.4 */ public abstract StringBuilder normalize(CharSequence src, StringBuilder dest); /** * Writes the normalized form of the source string to the destination Appendable * and returns the destination Appendable. * The source and destination strings must be different objects. * *

Any {@link java.io.IOException} is wrapped into a {@link com.ibm.icu.util.ICUUncheckedIOException}. * * @param src source string * @param dest destination Appendable; gets normalized src appended * @return dest * @stable ICU 4.6 */ public abstract Appendable normalize(CharSequence src, Appendable dest); /** * Appends the normalized form of the second string to the first string * (merging them at the boundary) and returns the first string. * The result is normalized if the first string was normalized. * The first and second strings must be different objects. * @param first string, should be normalized * @param second string, will be normalized * @return first * @stable ICU 4.4 */ public abstract StringBuilder normalizeSecondAndAppend( StringBuilder first, CharSequence second); /** * Appends the second string to the first string * (merging them at the boundary) and returns the first string. * The result is normalized if both the strings were normalized. * The first and second strings must be different objects. * @param first string, should be normalized * @param second string, should be normalized * @return first * @stable ICU 4.4 */ public abstract StringBuilder append(StringBuilder first, CharSequence second); /** * Gets the decomposition mapping of c. * Roughly equivalent to normalizing the String form of c * on a DECOMPOSE Normalizer2 instance, but much faster, and except that this function * returns null if c does not have a decomposition mapping in this instance's data. * This function is independent of the mode of the Normalizer2. * @param c code point * @return c's decomposition mapping, if any; otherwise null * @stable ICU 4.6 */ public abstract String getDecomposition(int c); /** * Gets the raw decomposition mapping of c. * *

This is similar to the getDecomposition() method but returns the * raw decomposition mapping as specified in UnicodeData.txt or * (for custom data) in the mapping files processed by the gennorm2 tool. * By contrast, getDecomposition() returns the processed, * recursively-decomposed version of this mapping. * *

When used on a standard NFKC Normalizer2 instance, * getRawDecomposition() returns the Unicode Decomposition_Mapping (dm) property. * *

When used on a standard NFC Normalizer2 instance, * it returns the Decomposition_Mapping only if the Decomposition_Type (dt) is Canonical (Can); * in this case, the result contains either one or two code points (=1..4 Java chars). * *

This function is independent of the mode of the Normalizer2. * The default implementation returns null. * @param c code point * @return c's raw decomposition mapping, if any; otherwise null * @stable ICU 49 */ public String getRawDecomposition(int c) { return null; } /** * Performs pairwise composition of a & b and returns the composite if there is one. * *

Returns a composite code point c only if c has a two-way mapping to a+b. * In standard Unicode normalization, this means that * c has a canonical decomposition to a+b * and c does not have the Full_Composition_Exclusion property. * *

This function is independent of the mode of the Normalizer2. * The default implementation returns a negative value. * @param a A (normalization starter) code point. * @param b Another code point. * @return The non-negative composite code point if there is one; otherwise a negative value. * @stable ICU 49 */ public int composePair(int a, int b) { return -1; } /** * Gets the combining class of c. * The default implementation returns 0 * but all standard implementations return the Unicode Canonical_Combining_Class value. * @param c code point * @return c's combining class * @stable ICU 49 */ public int getCombiningClass(int c) { return 0; } /** * Tests if the string is normalized. * Internally, in cases where the quickCheck() method would return "maybe" * (which is only possible for the two COMPOSE modes) this method * resolves to "yes" or "no" to provide a definitive result, * at the cost of doing more work in those cases. * @param s input string * @return true if s is normalized * @stable ICU 4.4 */ public abstract boolean isNormalized(CharSequence s); /** * Tests if the string is normalized. * For the two COMPOSE modes, the result could be "maybe" in cases that * would take a little more work to resolve definitively. * Use spanQuickCheckYes() and normalizeSecondAndAppend() for a faster * combination of quick check + normalization, to avoid * re-checking the "yes" prefix. * @param s input string * @return the quick check result * @stable ICU 4.4 */ public abstract Normalizer.QuickCheckResult quickCheck(CharSequence s); /** * Returns the end of the normalized substring of the input string. * In other words, with end=spanQuickCheckYes(s); * the substring s.subSequence(0, end) * will pass the quick check with a "yes" result. *

* The returned end index is usually one or more characters before the * "no" or "maybe" character: The end index is at a normalization boundary. * (See the class documentation for more about normalization boundaries.) *

* When the goal is a normalized string and most input strings are expected * to be normalized already, then call this method, * and if it returns a prefix shorter than the input string, * copy that prefix and use normalizeSecondAndAppend() for the remainder. * @param s input string * @return "yes" span end index * @stable ICU 4.4 */ public abstract int spanQuickCheckYes(CharSequence s); /** * Tests if the character always has a normalization boundary before it, * regardless of context. * If true, then the character does not normalization-interact with * preceding characters. * In other words, a string containing this character can be normalized * by processing portions before this character and starting from this * character independently. * This is used for iterative normalization. See the class documentation for details. * @param c character to test * @return true if c has a normalization boundary before it * @stable ICU 4.4 */ public abstract boolean hasBoundaryBefore(int c); /** * Tests if the character always has a normalization boundary after it, * regardless of context. * If true, then the character does not normalization-interact with * following characters. * In other words, a string containing this character can be normalized * by processing portions up to this character and after this * character independently. * This is used for iterative normalization. See the class documentation for details. *

* Note that this operation may be significantly slower than hasBoundaryBefore(). * @param c character to test * @return true if c has a normalization boundary after it * @stable ICU 4.4 */ public abstract boolean hasBoundaryAfter(int c); /** * Tests if the character is normalization-inert. * If true, then the character does not change, nor normalization-interact with * preceding or following characters. * In other words, a string containing this character can be normalized * by processing portions before this character and after this * character independently. * This is used for iterative normalization. See the class documentation for details. *

* Note that this operation may be significantly slower than hasBoundaryBefore(). * @param c character to test * @return true if c is normalization-inert * @stable ICU 4.4 */ public abstract boolean isInert(int c); /** * Sole constructor. (For invocation by subclass constructors, * typically implicit.) * @internal * @deprecated This API is ICU internal only. */ @Deprecated protected Normalizer2() { } }





© 2015 - 2024 Weber Informatics LLC | Privacy Policy