/* ******************************************************************************* * Copyright (C) 1996-2003, International Business Machines Corporation and * * others. All Rights Reserved. * ******************************************************************************* */ //=============================================================================== // // File sortkey.cpp // // // // Created by: Helena Shih // // Modification History: // // Date Name Description // // 6/20/97 helena Java class name change. // 6/23/97 helena Added comments to make code more readable. // 6/26/98 erm Canged to use byte arrays instead of UnicodeString // 7/31/98 erm hashCode: minimum inc should be 2 not 1, // Cleaned up operator= // 07/12/99 helena HPUX 11 CC port. // 03/06/01 synwee Modified compareTo, to handle the result of // 2 string similar in contents, but one is longer // than the other //=============================================================================== #include "unicode/utypes.h" #if !UCONFIG_NO_COLLATION #include "unicode/sortkey.h" #include "cmemory.h" #include "uhash.h" U_NAMESPACE_BEGIN // A hash code of kInvalidHashCode indicates that the has code needs // to be computed. A hash code of kEmptyHashCode is used for empty keys // and for any key whose computed hash code is kInvalidHashCode. #define kInvalidHashCode ((int32_t)0) #define kEmptyHashCode ((int32_t)1) UOBJECT_DEFINE_RTTI_IMPLEMENTATION(CollationKey) CollationKey::CollationKey() : UObject(), fBogus(FALSE), fCount(0), fCapacity(0), fHashCode(kEmptyHashCode), fBytes(NULL) { } // Create a collation key from a bit array. CollationKey::CollationKey(const uint8_t* newValues, int32_t count) : UObject(), fBogus(FALSE), fCount(count), fCapacity(count), fHashCode(kInvalidHashCode) { fBytes = (uint8_t *)uprv_malloc(count); if (fBytes == NULL) { setToBogus(); return; } uprv_memcpy(fBytes, newValues, fCount); } CollationKey::CollationKey(const CollationKey& other) : UObject(other), fBogus(FALSE), fCount(other.fCount), fCapacity(other.fCapacity), fHashCode(other.fHashCode), fBytes(NULL) { if (other.fBogus) { setToBogus(); return; } fBytes = (uint8_t *)uprv_malloc(fCapacity); if (fBytes == NULL) { setToBogus(); return; } uprv_memcpy(fBytes, other.fBytes, other.fCount); if(fCapacity>fCount) { uprv_memset(fBytes+fCount, 0, fCapacity-fCount); } } CollationKey::~CollationKey() { uprv_free(fBytes); } void CollationKey::adopt(uint8_t *values, int32_t count) { if(fBytes != NULL) { uprv_free(fBytes); } fBogus = FALSE; fBytes = values; fCount = count; fCapacity = count; fHashCode = kInvalidHashCode; } // set the key to an empty state CollationKey& CollationKey::reset() { fCount = 0; fBogus = FALSE; fHashCode = kEmptyHashCode; return *this; } // set the key to a "bogus" or invalid state CollationKey& CollationKey::setToBogus() { uprv_free(fBytes); fBytes = NULL; fCapacity = 0; fCount = 0; fHashCode = kInvalidHashCode; return *this; } UBool CollationKey::operator==(const CollationKey& source) const { return (this->fCount == source.fCount && (this->fBytes == source.fBytes || uprv_memcmp(this->fBytes, source.fBytes, this->fCount) == 0)); } const CollationKey& CollationKey::operator=(const CollationKey& other) { if (this != &other) { if (other.isBogus()) { return setToBogus(); } if (other.fBytes != NULL) { ensureCapacity(other.fCount); if (isBogus()) { return *this; } fHashCode = other.fHashCode; uprv_memcpy(fBytes, other.fBytes, fCount); } else { fCount = 0; fBogus = FALSE; fHashCode = kEmptyHashCode; } } return *this; } // Bitwise comparison for the collation keys. // NOTE: this is somewhat messy 'cause we can't count // on memcmp returning the exact values which match // Collator::EComparisonResult Collator::EComparisonResult CollationKey::compareTo(const CollationKey& target) const { uint8_t *src = this->fBytes; uint8_t *tgt = target.fBytes; // are we comparing the same string if (src == tgt) return Collator::EQUAL; /* int count = (this->fCount < target.fCount) ? this->fCount : target.fCount; if (count == 0) { // If count is 0, at least one of the keys is empty. // An empty key is always LESS than a non-empty one // and EQUAL to another empty if (this->fCount < target.fCount) { return Collator::LESS; } if (this->fCount > target.fCount) { return Collator::GREATER; } return Collator::EQUAL; } */ int minLength; Collator::EComparisonResult result; // are we comparing different lengths? if (this->fCount != target.fCount) { if (this->fCount < target.fCount) { minLength = this->fCount; result = Collator::LESS; } else { minLength = target.fCount; result = Collator::GREATER; } } else { minLength = target.fCount; result = Collator::EQUAL; } if (minLength > 0) { int diff = uprv_memcmp(src, tgt, minLength); if (diff > 0) { return Collator::GREATER; } else if (diff < 0) { return Collator::LESS; } } return result; /* if (result < 0) { return Collator::LESS; } if (result > 0) { return Collator::GREATER; } return Collator::EQUAL; */ } // Bitwise comparison for the collation keys. UCollationResult CollationKey::compareTo(const CollationKey& target, UErrorCode &status) const { if(U_SUCCESS(status)) { uint8_t *src = this->fBytes; uint8_t *tgt = target.fBytes; // are we comparing the same string if (src == tgt) return UCOL_EQUAL; int minLength; UCollationResult result; // are we comparing different lengths? if (this->fCount != target.fCount) { if (this->fCount < target.fCount) { minLength = this->fCount; result = UCOL_LESS; } else { minLength = target.fCount; result = UCOL_GREATER; } } else { minLength = target.fCount; result = UCOL_EQUAL; } if (minLength > 0) { int diff = uprv_memcmp(src, tgt, minLength); if (diff > 0) { return UCOL_GREATER; } else if (diff < 0) { return UCOL_LESS; } } return result; } else { return UCOL_EQUAL; } } CollationKey& CollationKey::ensureCapacity(int32_t newSize) { if (fCapacity < newSize) { uprv_free(fBytes); fBytes = (uint8_t *)uprv_malloc(newSize); if (fBytes == NULL) { return setToBogus(); } uprv_memset(fBytes, 0, fCapacity); fCapacity = newSize; } fBogus = FALSE; fCount = newSize; fHashCode = kInvalidHashCode; return *this; } #ifdef U_USE_COLLATION_KEY_DEPRECATES // Create a copy of the byte array. uint8_t* CollationKey::toByteArray(int32_t& count) const { uint8_t *result = (uint8_t*) uprv_malloc( sizeof(uint8_t) * fCount ); if (result == NULL) { count = 0; } else { count = fCount; uprv_memcpy(result, fBytes, fCount); } return result; } #endif int32_t CollationKey::hashCode() const { // (Cribbed from UnicodeString) // We cache the hashCode; when it becomes invalid, due to any change to the // string, we note this by setting it to kInvalidHashCode. [LIU] // Note: This method is semantically const, but physically non-const. if (fHashCode == kInvalidHashCode) { UHashTok key; key.pointer = fBytes; ((CollationKey *)this)->fHashCode = uhash_hashChars(key); #if 0 // We compute the hash by iterating sparsely over 64 (at most) characters // spaced evenly through the string. For each character, we multiply the // previous hash value by a prime number and add the new character in, // in the manner of a additive linear congruential random number generator, // thus producing a pseudorandom deterministic value which should be well // distributed over the output range. [LIU] const uint8_t *p = fBytes, *limit = fBytes + fCount; int32_t inc = (fCount >= 256) ? fCount/128 : 2; // inc = max(fSize/64, 1); int32_t hash = 0; while (p < limit) { hash = ( hash * 37 ) + ((p[0] << 8) + p[1]); p += inc; } // If we happened to get kInvalidHashCode, replace it with kEmptyHashCode if (hash == kInvalidHashCode) { hash = kEmptyHashCode; } ((CollationKey *)this)->fHashCode = hash; // cast away const #endif } return fHashCode; } U_NAMESPACE_END #endif /* #if !UCONFIG_NO_COLLATION */