scuffed-code/icu4c/source/i18n/sortkey.h
1999-11-11 21:15:55 +00:00

255 lines
9.5 KiB
C++

/*
*****************************************************************************************
* *
* COPYRIGHT: *
* (C) Copyright Taligent, Inc., 1996 *
* (C) Copyright International Business Machines Corporation, 1996-1999 *
* Licensed Material - Program-Property of IBM - All Rights Reserved. *
* US Government Users Restricted Rights - Use, duplication, or disclosure *
* restricted by GSA ADP Schedule Contract with IBM Corp. *
* *
*****************************************************************************************
*/
//===============================================================================
//
// File sortkey.h
//
//
//
// Created by: Helena Shih
//
// Modification History:
//
// Date Name Description
//
// 6/20/97 helena Java class name change.
// 8/18/97 helena Added internal API documentation.
// 6/26/98 erm Changed to use byte arrays and memcmp.
//===============================================================================
#ifndef SORTKEY_H
#define SORTKEY_H
#include "utypes.h"
#include "unistr.h"
#include "coll.h"
/**
* Collation keys are generated by the Collator class. Use the CollationKey objects
* instead of Collator to compare strings multiple times. A CollationKey
* preprocesses the comparison information from the Collator object to
* make the comparison faster. If you are not going to comparing strings
* multiple times, then using the Collator object is generally faster,
* since it only processes as much of the string as needed to make a
* comparison.
* <p> For example (with strength == tertiary)
* <p>When comparing "Abernathy" to "Baggins-Smythworthy", Collator
* only needs to process a couple of characters, while a comparison
* with CollationKeys will process all of the characters. On the other hand,
* if you are doing a sort of a number of fields, it is much faster to use
* CollationKeys, since you will be comparing strings multiple times.
* <p>Typical use of CollationKeys are in databases, where you store a CollationKey
* in a hidden field, and use it for sorting or indexing.
*
* <p>Example of use:
* <pre>
* . UErrorCode success = U_ZERO_ERROR;
* . Collator* myCollator = Collator::createInstance(success);
* . CollationKey* keys = new CollationKey [3];
* . myCollator->getCollationKey("Tom", keys[0], success );
* . myCollator->getCollationKey("Dick", keys[1], success );
* . myCollator->getCollationKey("Harry", keys[2], success );
* .
* . // Inside body of sort routine, compare keys this way:
* . CollationKey tmp;
* . if(keys[0].compareTo( keys[1] ) > 0 ) {
* . tmp = keys[0]; keys[0] = keys[1]; keys[1] = tmp;
* . }
* . //...
* </pre>
* <p>Because Collator::compare()'s algorithm is complex, it is faster to sort
* long lists of words by retrieving collation keys with Collator::getCollationKey().
* You can then cache the collation keys and compare them using CollationKey::compareTo().
* <p>
* <strong>Note:</strong> <code>Collator</code>s with different Locale,
* CollationStrength and DecompositionMode settings will return different
* CollationKeys for the same set of strings. Locales have specific
* collation rules, and the way in which secondary and tertiary differences
* are taken into account, for example, will result in different CollationKeys
* for same strings.
* <p>
* @see Collator
* @see RuleBasedCollator
* @version 1.3 12/18/96
* @author Helena Shih
*/
class U_I18N_API CollationKey {
public:
/**
* This creates an empty collation key based on the null string. An empty
* collation key contains no sorting information. When comparing two empty
* collation keys, the result is Collator::EQUAL. Comparing empty collation key
* with non-empty collation key is always Collator::LESS.
*/
CollationKey();
/**
* Creates a collation key based on the collation key values.
* @param values the collation key values
* @param count number of collation key values, including trailing nulls.
* @see #createBits
*/
CollationKey(const uint8_t* values,
int32_t count);
/**
* Copy constructor.
*/
CollationKey(const CollationKey& other);
/**
* Sort key destructor.
*/
~CollationKey();
/**
* Assignment operator
*/
const CollationKey& operator=(const CollationKey& other);
/**
* Compare if two collation keys are the same.
* @param source the collation key to compare to.
* @return Returns true if two collation keys are equal, false otherwise.
*/
bool_t operator==(const CollationKey& source) const;
/**
* Compare if two collation keys are not the same.
* @param source the collation key to compare to.
* @return Returns TRUE if two collation keys are different, FALSE otherwise.
*/
bool_t operator!=(const CollationKey& source) const;
/**
* Test to see if the key is in an invalid state. The key will be in an
* invalid state if it couldn't allocate memory for some operation.
* @return Returns TRUE if the key is in an invalid, FALSE otherwise.
*/
bool_t isBogus(void) const;
/**
* Returns a pointer to the collation key values. The storage is owned
* by the collation key and the pointer will become invalid if the key
* is deleted.
* @param count the output parameter of number of collation key values,
* including any trailing nulls.
*/
const uint8_t* getByteArray(int32_t& count) const;
/**
* Extracts the collation key values into a new array. The caller owns
* this storage and should free it.
* @param count the output parameter of number of collation key values,
* including any trailing nulls.
*/
uint8_t* toByteArray(int32_t& count) const;
/**
* Convenience method which does a string(bit-wise) comparison of the
* two collation keys.
* @param sourceKey source collation key
* @param targetKey target collation key
* @return Returns Collator::LESS if sourceKey &lt; targetKey,
* Collator::GREATER if sourceKey > targetKey and Collator::EQUAL
* otherwise.
*/
Collator::EComparisonResult compareTo(const CollationKey& target) const;
/**
* Creates an integer that is unique to the collation key. NOTE: this
* is not the same as String.hashCode.
* <p>Example of use:
* <pre>
* . UErrorCode status = U_ZERO_ERROR;
* . Collator *myCollation = Collator::createInstance(Locale::US, status);
* . if (U_FAILURE(status)) return;
* . CollationKey key1, key2;
* . UErrorCode status1 = U_ZERO_ERROR, status2 = U_ZERO_ERROR;
* . myCollation->getCollationKey("abc", key1, status1);
* . if (U_FAILURE(status1)) { delete myCollation; return; }
* . myCollation->getCollationKey("ABC", key2, status2);
* . if (U_FAILURE(status2)) { delete myCollation; return; }
* . // key1.hashCode() != key2.hashCode()
* </pre>
* @return the hash value based on the string's collation order.
* @see UnicodeString#hashCode
*/
int32_t hashCode(void) const;
private:
/**
* Returns an array of the collation key values as 16-bit integers.
* The caller owns the storage and must delete it.
* @param size output parameter of the number of collation key values
* @return a pointer to an array of 16-bit collation key values.
*/
uint16_t* copyValues(int32_t &size) const;
/*
* Creates a collation key with a string.
*/
CollationKey(const UnicodeString& value);
int32_t storeBytes(int32_t cursor, uint32_t byteValue);
int32_t storeUnicodeString(int32_t cursor, const UnicodeString &value);
void reverseBytes(int32_t from, int32_t to);
CollationKey& ensureCapacity(int32_t newSize);
CollationKey& copyUnicodeString(const UnicodeString &value);
CollationKey& setToBogus(void);
CollationKey& reset(void);
friend class RuleBasedCollator;
static const int32_t kInvalidHashCode;
static const int32_t kEmptyHashCode;
bool_t fBogus;
int32_t fCount;
int32_t fCapacity;
int32_t fHashCode;
uint8_t* fBytes;
};
inline bool_t
CollationKey::operator!=(const CollationKey& other) const
{
return !(*this == other);
}
inline bool_t
CollationKey::isBogus() const
{
return fBogus;
}
inline const uint8_t*
CollationKey::getByteArray(int32_t &count) const
{
count = fCount;
return fBytes;
}
inline UTextOffset
CollationKey::storeBytes(UTextOffset cursor, uint32_t byteValue)
{
fBytes[cursor++] = (uint8_t) (byteValue >> 8);
fBytes[cursor++] = (uint8_t) byteValue;
return cursor;
}
#endif