/******************************************************************** * Copyright (c) 1997-2011 International Business Machines * Corporation and others. All Rights Reserved. ********************************************************************/ /***************************************************************************** * * File CAPITEST.C * * Modification History: * Name Description * Madhu Katragadda Ported for C API * Brian Rower Added TestOpenVsOpenRules ****************************************************************************** *//* C API TEST For COLLATOR */ #include "unicode/utypes.h" #if !UCONFIG_NO_COLLATION #include <stdio.h> #include <stdlib.h> #include <string.h> #include "unicode/uloc.h" #include "unicode/ulocdata.h" #include "unicode/ustring.h" #include "unicode/ures.h" #include "unicode/ucoleitr.h" #include "cintltst.h" #include "capitst.h" #include "ccolltst.h" #include "putilimp.h" #include "cmemory.h" #include "cstring.h" static void TestAttribute(void); static void TestDefault(void); static void TestDefaultKeyword(void); static void TestBengaliSortKey(void); int TestBufferSize(); /* defined in "colutil.c" */ /* next two function is modified from "i18n/ucol.cpp" to avoid include "ucol_imp.h" */ static void uprv_appendByteToHexString(char *dst, uint8_t val) { uint32_t len = (uint32_t)strlen(dst); sprintf(dst+len, "%02X", val); } static char* U_EXPORT2 ucol_sortKeyToString(const UCollator *coll, const uint8_t *sortkey, char *buffer, uint32_t *len) { int32_t strength = UCOL_PRIMARY; uint32_t res_size = 0; UBool doneCase = FALSE; char *current = buffer; const uint8_t *currentSk = sortkey; UErrorCode error_code = U_ZERO_ERROR; strcpy(current, "["); while(strength <= UCOL_QUATERNARY && strength <= ucol_getAttribute(coll,UCOL_STRENGTH, &error_code)) { if(U_FAILURE(error_code)) { log_err("ucol_getAttribute returned error: %s\n", u_errorName(error_code)); } if(strength > UCOL_PRIMARY) { strcat(current, " . "); } while(*currentSk != 0x01 && *currentSk != 0x00) { /* print a level */ uprv_appendByteToHexString(current, *currentSk++); strcat(current, " "); } if(ucol_getAttribute(coll,UCOL_CASE_LEVEL, &error_code) == UCOL_ON && strength == UCOL_SECONDARY && doneCase == FALSE) { doneCase = TRUE; } else if(ucol_getAttribute(coll,UCOL_CASE_LEVEL, &error_code) == UCOL_OFF || doneCase == TRUE || strength != UCOL_SECONDARY) { strength ++; } if(U_FAILURE(error_code)) { log_err("ucol_getAttribute returned error: %s\n", u_errorName(error_code)); } uprv_appendByteToHexString(current, *currentSk++); /* This should print '01' */ if(strength == UCOL_QUATERNARY && ucol_getAttribute(coll,UCOL_ALTERNATE_HANDLING, &error_code) == UCOL_NON_IGNORABLE) { break; } } if(ucol_getAttribute(coll,UCOL_STRENGTH, &error_code) == UCOL_IDENTICAL) { strcat(current, " . "); while(*currentSk != 0) { uprv_appendByteToHexString(current, *currentSk++); strcat(current, " "); } uprv_appendByteToHexString(current, *currentSk++); } if(U_FAILURE(error_code)) { log_err("ucol_getAttribute returned error: %s\n", u_errorName(error_code)); } strcat(current, "]"); if(res_size > *len) { return NULL; } return buffer; } /* end of avoid include "ucol_imp.h" */ void addCollAPITest(TestNode** root) { /* WEIVTODO: return tests here */ addTest(root, &TestProperty, "tscoll/capitst/TestProperty"); addTest(root, &TestRuleBasedColl, "tscoll/capitst/TestRuleBasedColl"); addTest(root, &TestCompare, "tscoll/capitst/TestCompare"); addTest(root, &TestSortKey, "tscoll/capitst/TestSortKey"); addTest(root, &TestHashCode, "tscoll/capitst/TestHashCode"); addTest(root, &TestElemIter, "tscoll/capitst/TestElemIter"); addTest(root, &TestGetAll, "tscoll/capitst/TestGetAll"); /*addTest(root, &TestGetDefaultRules, "tscoll/capitst/TestGetDefaultRules");*/ addTest(root, &TestDecomposition, "tscoll/capitst/TestDecomposition"); addTest(root, &TestSafeClone, "tscoll/capitst/TestSafeClone"); addTest(root, &TestCloneBinary, "tscoll/capitst/TestCloneBinary"); addTest(root, &TestGetSetAttr, "tscoll/capitst/TestGetSetAttr"); addTest(root, &TestBounds, "tscoll/capitst/TestBounds"); addTest(root, &TestGetLocale, "tscoll/capitst/TestGetLocale"); addTest(root, &TestSortKeyBufferOverrun, "tscoll/capitst/TestSortKeyBufferOverrun"); addTest(root, &TestAttribute, "tscoll/capitst/TestAttribute"); addTest(root, &TestGetTailoredSet, "tscoll/capitst/TestGetTailoredSet"); addTest(root, &TestMergeSortKeys, "tscoll/capitst/TestMergeSortKeys"); addTest(root, &TestShortString, "tscoll/capitst/TestShortString"); /* BEGIN android-removed To save space, Android does not include the collation tailoring rules. We skip the tailing tests for collations. */ /* addTest(root, &TestGetContractionsAndUnsafes, "tscoll/capitst/TestGetContractionsAndUnsafes"); */ /* END android-removed */ addTest(root, &TestOpenBinary, "tscoll/capitst/TestOpenBinary"); addTest(root, &TestDefault, "tscoll/capitst/TestDefault"); addTest(root, &TestDefaultKeyword, "tscoll/capitst/TestDefaultKeyword"); /* BEGIN android-removed To save space, Android does not build full collation tables and tailing rules. We skip the related tests. */ /* addTest(root, &TestOpenVsOpenRules, "tscoll/capitst/TestOpenVsOpenRules"); */ /* addTest(root, &TestGetKeywordValuesForLocale, "tscoll/capitst/TestGetKeywordValuesForLocale"); */ /* END android-removed */ addTest(root, &TestBengaliSortKey, "tscoll/capitst/TestBengaliSortKey"); } void TestGetSetAttr(void) { UErrorCode status = U_ZERO_ERROR; UCollator *coll = ucol_open(NULL, &status); struct attrTest { UColAttribute att; UColAttributeValue val[5]; uint32_t valueSize; UColAttributeValue nonValue; } attrs[] = { {UCOL_FRENCH_COLLATION, {UCOL_ON, UCOL_OFF}, 2, UCOL_SHIFTED}, {UCOL_ALTERNATE_HANDLING, {UCOL_NON_IGNORABLE, UCOL_SHIFTED}, 2, UCOL_OFF},/* attribute for handling variable elements*/ {UCOL_CASE_FIRST, {UCOL_OFF, UCOL_LOWER_FIRST, UCOL_UPPER_FIRST}, 3, UCOL_SHIFTED},/* who goes first, lower case or uppercase */ {UCOL_CASE_LEVEL, {UCOL_ON, UCOL_OFF}, 2, UCOL_SHIFTED},/* do we have an extra case level */ {UCOL_NORMALIZATION_MODE, {UCOL_ON, UCOL_OFF}, 2, UCOL_SHIFTED},/* attribute for normalization */ {UCOL_DECOMPOSITION_MODE, {UCOL_ON, UCOL_OFF}, 2, UCOL_SHIFTED}, {UCOL_STRENGTH, {UCOL_PRIMARY, UCOL_SECONDARY, UCOL_TERTIARY, UCOL_QUATERNARY, UCOL_IDENTICAL}, 5, UCOL_SHIFTED},/* attribute for strength */ {UCOL_HIRAGANA_QUATERNARY_MODE, {UCOL_ON, UCOL_OFF}, 2, UCOL_SHIFTED},/* when turned on, this attribute */ }; UColAttribute currAttr; UColAttributeValue value; uint32_t i = 0, j = 0; if (coll == NULL) { log_err_status(status, "Unable to open collator. %s\n", u_errorName(status)); return; } for(i = 0; i<sizeof(attrs)/sizeof(attrs[0]); i++) { currAttr = attrs[i].att; ucol_setAttribute(coll, currAttr, UCOL_DEFAULT, &status); if(U_FAILURE(status)) { log_err_status(status, "ucol_setAttribute with the default value returned error: %s\n", u_errorName(status)); break; } value = ucol_getAttribute(coll, currAttr, &status); if(U_FAILURE(status)) { log_err("ucol_getAttribute returned error: %s\n", u_errorName(status)); break; } for(j = 0; j<attrs[i].valueSize; j++) { ucol_setAttribute(coll, currAttr, attrs[i].val[j], &status); if(U_FAILURE(status)) { log_err("ucol_setAttribute with the value %i returned error: %s\n", attrs[i].val[j], u_errorName(status)); break; } } status = U_ZERO_ERROR; ucol_setAttribute(coll, currAttr, attrs[i].nonValue, &status); if(U_SUCCESS(status)) { log_err("ucol_setAttribute with the bad value didn't return an error\n"); break; } status = U_ZERO_ERROR; ucol_setAttribute(coll, currAttr, value, &status); if(U_FAILURE(status)) { log_err("ucol_setAttribute with the default valuereturned error: %s\n", u_errorName(status)); break; } } status = U_ZERO_ERROR; value = ucol_getAttribute(coll, UCOL_ATTRIBUTE_COUNT, &status); if(U_SUCCESS(status)) { log_err("ucol_getAttribute for UCOL_ATTRIBUTE_COUNT didn't return an error\n"); } status = U_ZERO_ERROR; ucol_setAttribute(coll, UCOL_ATTRIBUTE_COUNT, UCOL_DEFAULT, &status); if(U_SUCCESS(status)) { log_err("ucol_setAttribute for UCOL_ATTRIBUTE_COUNT didn't return an error\n"); } status = U_ZERO_ERROR; ucol_close(coll); } static void doAssert(int condition, const char *message) { if (condition==0) { log_err("ERROR : %s\n", message); } } #if 0 /* We don't have default rules, at least not in the previous sense */ void TestGetDefaultRules(){ uint32_t size=0; UErrorCode status=U_ZERO_ERROR; UCollator *coll=NULL; int32_t len1 = 0, len2=0; uint8_t *binColData = NULL; UResourceBundle *res = NULL; UResourceBundle *binColl = NULL; uint8_t *binResult = NULL; const UChar * defaultRulesArray=ucol_getDefaultRulesArray(&size); log_verbose("Test the function ucol_getDefaultRulesArray()\n"); coll = ucol_openRules(defaultRulesArray, size, UCOL_ON, UCOL_PRIMARY, &status); if(U_SUCCESS(status) && coll !=NULL) { binColData = (uint8_t*)ucol_cloneRuleData(coll, &len1, &status); } status=U_ZERO_ERROR; res=ures_open(NULL, "root", &status); if(U_FAILURE(status)){ log_err("ERROR: Failed to get resource for \"root Locale\" with %s", myErrorName(status)); return; } binColl=ures_getByKey(res, "%%Collation", binColl, &status); if(U_SUCCESS(status)){ binResult=(uint8_t*)ures_getBinary(binColl, &len2, &status); if(U_FAILURE(status)){ log_err("ERROR: ures_getBinary() failed\n"); } }else{ log_err("ERROR: ures_getByKey(locale(default), %%Collation) failed"); } if(len1 != len2){ log_err("Error: ucol_getDefaultRulesArray() failed to return the correct length.\n"); } if(memcmp(binColData, binResult, len1) != 0){ log_err("Error: ucol_getDefaultRulesArray() failed\n"); } free(binColData); ures_close(binColl); ures_close(res); ucol_close(coll); } #endif /* Collator Properties ucol_open, ucol_strcoll, getStrength/setStrength getDecomposition/setDecomposition, getDisplayName*/ void TestProperty() { UCollator *col, *ruled; UChar *disName; int32_t len = 0; UChar *source, *target; int32_t tempLength; UErrorCode status = U_ZERO_ERROR; /* * Expected version of the English collator. * Currently, the major/minor version numbers change when the builder code * changes, * number 2 is from the tailoring data version and * number 3 is the UCA version. * This changes with every UCA version change, and the expected value * needs to be adjusted. * Same in intltest/apicoll.cpp. */ UVersionInfo currVersionArray = {0x31, 0xC0, 0x05, 0x2A}; /* from ICU 4.4/UCA 5.2 */ UVersionInfo versionArray = {0, 0, 0, 0}; UVersionInfo versionUCAArray = {0, 0, 0, 0}; UVersionInfo versionUCDArray = {0, 0, 0, 0}; log_verbose("The property tests begin : \n"); log_verbose("Test ucol_strcoll : \n"); col = ucol_open("en_US", &status); if (U_FAILURE(status)) { log_err_status(status, "Default Collator creation failed.: %s\n", myErrorName(status)); return; } ucol_getVersion(col, versionArray); /* Check for a version greater than some value rather than equality * so that we need not update the expected version each time. */ if (uprv_memcmp(versionArray, currVersionArray, 4)<0) { log_err("Testing ucol_getVersion() - unexpected result: %02x.%02x.%02x.%02x\n", versionArray[0], versionArray[1], versionArray[2], versionArray[3]); } else { log_verbose("ucol_getVersion() result: %02x.%02x.%02x.%02x\n", versionArray[0], versionArray[1], versionArray[2], versionArray[3]); } /* Assume that the UCD and UCA versions are the same, * rather than hardcoding (and updating each time) a particular UCA version. */ u_getUnicodeVersion(versionUCDArray); ucol_getUCAVersion(col, versionUCAArray); if (0!=uprv_memcmp(versionUCAArray, versionUCDArray, 4)) { log_err("Testing ucol_getUCAVersion() - unexpected result: %hu.%hu.%hu.%hu\n", versionUCAArray[0], versionUCAArray[1], versionUCAArray[2], versionUCAArray[3]); } source=(UChar*)malloc(sizeof(UChar) * 12); target=(UChar*)malloc(sizeof(UChar) * 12); u_uastrcpy(source, "ab"); u_uastrcpy(target, "abc"); doAssert((ucol_strcoll(col, source, u_strlen(source), target, u_strlen(target)) == UCOL_LESS), "ab < abc comparison failed"); u_uastrcpy(source, "ab"); u_uastrcpy(target, "AB"); doAssert((ucol_strcoll(col, source, u_strlen(source), target, u_strlen(target)) == UCOL_LESS), "ab < AB comparison failed"); /* u_uastrcpy(source, "black-bird"); u_uastrcpy(target, "blackbird"); */ u_uastrcpy(target, "black-bird"); u_uastrcpy(source, "blackbird"); doAssert((ucol_strcoll(col, source, u_strlen(source), target, u_strlen(target)) == UCOL_GREATER), "black-bird > blackbird comparison failed"); u_uastrcpy(source, "black bird"); u_uastrcpy(target, "black-bird"); doAssert((ucol_strcoll(col, source, u_strlen(source), target, u_strlen(target)) == UCOL_LESS), "black bird < black-bird comparison failed"); u_uastrcpy(source, "Hello"); u_uastrcpy(target, "hello"); doAssert((ucol_strcoll(col, source, u_strlen(source), target, u_strlen(target)) == UCOL_GREATER), "Hello > hello comparison failed"); free(source); free(target); log_verbose("Test ucol_strcoll ends.\n"); log_verbose("testing ucol_getStrength() method ...\n"); doAssert( (ucol_getStrength(col) == UCOL_TERTIARY), "collation object has the wrong strength"); doAssert( (ucol_getStrength(col) != UCOL_PRIMARY), "collation object's strength is primary difference"); log_verbose("testing ucol_setStrength() method ...\n"); ucol_setStrength(col, UCOL_SECONDARY); doAssert( (ucol_getStrength(col) != UCOL_TERTIARY), "collation object's strength is secondary difference"); doAssert( (ucol_getStrength(col) != UCOL_PRIMARY), "collation object's strength is primary difference"); doAssert( (ucol_getStrength(col) == UCOL_SECONDARY), "collation object has the wrong strength"); log_verbose("Get display name for the default collation in German : \n"); len=ucol_getDisplayName("en_US", "de_DE", NULL, 0, &status); if(status==U_BUFFER_OVERFLOW_ERROR){ status=U_ZERO_ERROR; disName=(UChar*)malloc(sizeof(UChar) * (len+1)); ucol_getDisplayName("en_US", "de_DE", disName, len+1, &status); log_verbose("the display name for default collation in german: %s\n", austrdup(disName) ); free(disName); } if(U_FAILURE(status)){ log_err("ERROR: in getDisplayName: %s\n", myErrorName(status)); return; } log_verbose("Default collation getDisplayName ended.\n"); /* BEGIN android-removed To save space, Android does not include the collation tailoring rules. Skip the related tests. ruled = ucol_open("da_DK", &status); log_verbose("ucol_getRules() testing ...\n"); ucol_getRules(ruled, &tempLength); doAssert( tempLength != 0, "getRules() result incorrect" ); log_verbose("getRules tests end.\n"); { UChar *buffer = (UChar *)malloc(200000*sizeof(UChar)); int32_t bufLen = 200000; buffer[0] = '\0'; log_verbose("ucol_getRulesEx() testing ...\n"); tempLength = ucol_getRulesEx(col,UCOL_TAILORING_ONLY,buffer,bufLen ); doAssert( tempLength == 0x00, "getRulesEx() result incorrect" ); log_verbose("getRules tests end.\n"); log_verbose("ucol_getRulesEx() testing ...\n"); tempLength=ucol_getRulesEx(col,UCOL_FULL_RULES,buffer,bufLen ); doAssert( tempLength != 0, "getRulesEx() result incorrect" ); log_verbose("getRules tests end.\n"); free(buffer); } ucol_close(ruled); ucol_close(col); END android-removed */ log_verbose("open an collator for french locale"); col = ucol_open("fr_FR", &status); if (U_FAILURE(status)) { log_err("ERROR: Creating French collation failed.: %s\n", myErrorName(status)); return; } ucol_setStrength(col, UCOL_PRIMARY); log_verbose("testing ucol_getStrength() method again ...\n"); doAssert( (ucol_getStrength(col) != UCOL_TERTIARY), "collation object has the wrong strength"); doAssert( (ucol_getStrength(col) == UCOL_PRIMARY), "collation object's strength is not primary difference"); log_verbose("testing French ucol_setStrength() method ...\n"); ucol_setStrength(col, UCOL_TERTIARY); doAssert( (ucol_getStrength(col) == UCOL_TERTIARY), "collation object's strength is not tertiary difference"); doAssert( (ucol_getStrength(col) != UCOL_PRIMARY), "collation object's strength is primary difference"); doAssert( (ucol_getStrength(col) != UCOL_SECONDARY), "collation object's strength is secondary difference"); ucol_close(col); log_verbose("Get display name for the french collation in english : \n"); len=ucol_getDisplayName("fr_FR", "en_US", NULL, 0, &status); if(status==U_BUFFER_OVERFLOW_ERROR){ status=U_ZERO_ERROR; disName=(UChar*)malloc(sizeof(UChar) * (len+1)); ucol_getDisplayName("fr_FR", "en_US", disName, len+1, &status); log_verbose("the display name for french collation in english: %s\n", austrdup(disName) ); free(disName); } if(U_FAILURE(status)){ log_err("ERROR: in getDisplayName: %s\n", myErrorName(status)); return; } log_verbose("Default collation getDisplayName ended.\n"); } /* Test RuleBasedCollator and getRules*/ void TestRuleBasedColl() { UCollator *col1, *col2, *col3, *col4; UCollationElements *iter1, *iter2; UChar ruleset1[60]; UChar ruleset2[50]; UChar teststr[10]; UChar teststr2[10]; const UChar *rule1, *rule2, *rule3, *rule4; int32_t tempLength; UErrorCode status = U_ZERO_ERROR; u_uastrcpy(ruleset1, "&9 < a, A < b, B < c, C; ch, cH, Ch, CH < d, D, e, E"); u_uastrcpy(ruleset2, "&9 < a, A < b, B < c, C < d, D, e, E"); col1 = ucol_openRules(ruleset1, u_strlen(ruleset1), UCOL_DEFAULT, UCOL_DEFAULT_STRENGTH, NULL,&status); if (U_FAILURE(status)) { log_err_status(status, "RuleBased Collator creation failed.: %s\n", myErrorName(status)); return; } else log_verbose("PASS: RuleBased Collator creation passed\n"); status = U_ZERO_ERROR; col2 = ucol_openRules(ruleset2, u_strlen(ruleset2), UCOL_DEFAULT, UCOL_DEFAULT_STRENGTH, NULL, &status); if (U_FAILURE(status)) { log_err("RuleBased Collator creation failed.: %s\n", myErrorName(status)); return; } else log_verbose("PASS: RuleBased Collator creation passed\n"); status = U_ZERO_ERROR; col3= ucol_open(NULL, &status); if (U_FAILURE(status)) { log_err("Default Collator creation failed.: %s\n", myErrorName(status)); return; } else log_verbose("PASS: Default Collator creation passed\n"); rule1 = ucol_getRules(col1, &tempLength); rule2 = ucol_getRules(col2, &tempLength); rule3 = ucol_getRules(col3, &tempLength); doAssert((u_strcmp(rule1, rule2) != 0), "Default collator getRules failed"); doAssert((u_strcmp(rule2, rule3) != 0), "Default collator getRules failed"); doAssert((u_strcmp(rule1, rule3) != 0), "Default collator getRules failed"); col4=ucol_openRules(rule2, u_strlen(rule2), UCOL_DEFAULT, UCOL_DEFAULT_STRENGTH, NULL, &status); if (U_FAILURE(status)) { log_err("RuleBased Collator creation failed.: %s\n", myErrorName(status)); return; } rule4= ucol_getRules(col4, &tempLength); doAssert((u_strcmp(rule2, rule4) == 0), "Default collator getRules failed"); ucol_close(col1); ucol_close(col2); ucol_close(col3); ucol_close(col4); /* tests that modifier ! is always ignored */ u_uastrcpy(ruleset1, "!&a<b"); teststr[0] = 0x0e40; teststr[1] = 0x0e01; teststr[2] = 0x0e2d; col1 = ucol_openRules(ruleset1, u_strlen(ruleset1), UCOL_DEFAULT, UCOL_DEFAULT_STRENGTH, NULL, &status); if (U_FAILURE(status)) { log_err("RuleBased Collator creation failed.: %s\n", myErrorName(status)); return; } col2 = ucol_open("en_US", &status); if (U_FAILURE(status)) { log_err("en_US Collator creation failed.: %s\n", myErrorName(status)); return; } iter1 = ucol_openElements(col1, teststr, 3, &status); iter2 = ucol_openElements(col2, teststr, 3, &status); if(U_FAILURE(status)) { log_err("ERROR: CollationElement iterator creation failed.: %s\n", myErrorName(status)); return; } while (TRUE) { /* testing with en since thai has its own tailoring */ uint32_t ce = ucol_next(iter1, &status); uint32_t ce2 = ucol_next(iter2, &status); if(U_FAILURE(status)) { log_err("ERROR: CollationElement iterator creation failed.: %s\n", myErrorName(status)); return; } if (ce2 != ce) { log_err("! modifier test failed"); } if (ce == UCOL_NULLORDER) { break; } } ucol_closeElements(iter1); ucol_closeElements(iter2); ucol_close(col1); ucol_close(col2); /* test that we can start a rule without a & or < */ u_uastrcpy(ruleset1, "< z < a"); col1 = ucol_openRules(ruleset1, u_strlen(ruleset1), UCOL_DEFAULT, UCOL_DEFAULT_STRENGTH, NULL, &status); if (U_FAILURE(status)) { log_err("RuleBased Collator creation failed.: %s\n", myErrorName(status)); return; } u_uastrcpy(teststr, "z"); u_uastrcpy(teststr2, "a"); if (ucol_greaterOrEqual(col1, teststr, 1, teststr2, 1)) { log_err("Rule \"z < a\" fails"); } ucol_close(col1); } void TestCompare() { UErrorCode status = U_ZERO_ERROR; UCollator *col; UChar* test1; UChar* test2; log_verbose("The compare tests begin : \n"); status=U_ZERO_ERROR; col = ucol_open("en_US", &status); if(U_FAILURE(status)) { log_err_status(status, "ucal_open() collation creation failed.: %s\n", myErrorName(status)); return; } test1=(UChar*)malloc(sizeof(UChar) * 6); test2=(UChar*)malloc(sizeof(UChar) * 6); u_uastrcpy(test1, "Abcda"); u_uastrcpy(test2, "abcda"); log_verbose("Use tertiary comparison level testing ....\n"); doAssert( (!ucol_equal(col, test1, u_strlen(test1), test2, u_strlen(test2))), "Result should be \"Abcda\" != \"abcda\" "); doAssert( (ucol_greater(col, test1, u_strlen(test1), test2, u_strlen(test2))), "Result should be \"Abcda\" >>> \"abcda\" "); doAssert( (ucol_greaterOrEqual(col, test1, u_strlen(test1), test2, u_strlen(test2))), "Result should be \"Abcda\" >>> \"abcda\""); ucol_setStrength(col, UCOL_SECONDARY); log_verbose("Use secondary comparison level testing ....\n"); doAssert( (ucol_equal(col, test1, u_strlen(test1), test2, u_strlen(test2) )), "Result should be \"Abcda\" == \"abcda\""); doAssert( (!ucol_greater(col, test1, u_strlen(test1), test2, u_strlen(test2))), "Result should be \"Abcda\" == \"abcda\""); doAssert( (ucol_greaterOrEqual(col, test1, u_strlen(test1), test2, u_strlen(test2) )), "Result should be \"Abcda\" == \"abcda\""); ucol_setStrength(col, UCOL_PRIMARY); log_verbose("Use primary comparison level testing ....\n"); doAssert( (ucol_equal(col, test1, u_strlen(test1), test2, u_strlen(test2))), "Result should be \"Abcda\" == \"abcda\""); doAssert( (!ucol_greater(col, test1, u_strlen(test1), test2, u_strlen(test2))), "Result should be \"Abcda\" == \"abcda\""); doAssert( (ucol_greaterOrEqual(col, test1, u_strlen(test1), test2, u_strlen(test2))), "Result should be \"Abcda\" == \"abcda\""); log_verbose("The compare tests end.\n"); ucol_close(col); free(test1); free(test2); } /* --------------------------------------------- tests decomposition setting */ void TestDecomposition() { UErrorCode status = U_ZERO_ERROR; UCollator *en_US, *el_GR, *vi_VN; en_US = ucol_open("en_US", &status); el_GR = ucol_open("el_GR", &status); vi_VN = ucol_open("vi_VN", &status); if (U_FAILURE(status)) { log_err_status(status, "ERROR: collation creation failed.: %s\n", myErrorName(status)); return; } if (ucol_getAttribute(vi_VN, UCOL_NORMALIZATION_MODE, &status) != UCOL_ON || U_FAILURE(status)) { log_err("ERROR: vi_VN collation did not have cannonical decomposition for normalization!\n"); } status = U_ZERO_ERROR; if (ucol_getAttribute(el_GR, UCOL_NORMALIZATION_MODE, &status) != UCOL_ON || U_FAILURE(status)) { log_err("ERROR: el_GR collation did not have cannonical decomposition for normalization!\n"); } status = U_ZERO_ERROR; if (ucol_getAttribute(en_US, UCOL_NORMALIZATION_MODE, &status) != UCOL_OFF || U_FAILURE(status)) { log_err("ERROR: en_US collation had cannonical decomposition for normalization!\n"); } ucol_close(en_US); ucol_close(el_GR); ucol_close(vi_VN); } #define CLONETEST_COLLATOR_COUNT 4 void TestSafeClone() { UChar test1[6]; UChar test2[6]; static const UChar umlautUStr[] = {0x00DC, 0}; static const UChar oeStr[] = {0x0055, 0x0045, 0}; UCollator * someCollators [CLONETEST_COLLATOR_COUNT]; UCollator * someClonedCollators [CLONETEST_COLLATOR_COUNT]; UCollator * col; UErrorCode err = U_ZERO_ERROR; int8_t index = 6; /* Leave this here to test buffer alingment in memory*/ uint8_t buffer [CLONETEST_COLLATOR_COUNT] [U_COL_SAFECLONE_BUFFERSIZE]; int32_t bufferSize = U_COL_SAFECLONE_BUFFERSIZE; const char sampleRuleChars[] = "&Z < CH"; UChar sampleRule[sizeof(sampleRuleChars)]; if (TestBufferSize()) { log_err("U_COL_SAFECLONE_BUFFERSIZE should be larger than sizeof(UCollator)\n"); return; } u_uastrcpy(test1, "abCda"); u_uastrcpy(test2, "abcda"); u_uastrcpy(sampleRule, sampleRuleChars); /* one default collator & two complex ones */ someCollators[0] = ucol_open("en_US", &err); someCollators[1] = ucol_open("ko", &err); someCollators[2] = ucol_open("ja_JP", &err); someCollators[3] = ucol_openRules(sampleRule, -1, UCOL_ON, UCOL_TERTIARY, NULL, &err); if(U_FAILURE(err)) { for (index = 0; index < CLONETEST_COLLATOR_COUNT; index++) { ucol_close(someCollators[index]); } log_data_err("Couldn't open one or more collators\n"); return; } /* Check the various error & informational states: */ /* Null status - just returns NULL */ if (0 != ucol_safeClone(someCollators[0], buffer[0], &bufferSize, 0)) { log_err("FAIL: Cloned Collator failed to deal correctly with null status\n"); } /* error status - should return 0 & keep error the same */ err = U_MEMORY_ALLOCATION_ERROR; if (0 != ucol_safeClone(someCollators[0], buffer[0], &bufferSize, &err) || err != U_MEMORY_ALLOCATION_ERROR) { log_err("FAIL: Cloned Collator failed to deal correctly with incoming error status\n"); } err = U_ZERO_ERROR; /* Null buffer size pointer - just returns NULL & set error to U_ILLEGAL_ARGUMENT_ERROR*/ if (0 != ucol_safeClone(someCollators[0], buffer[0], 0, &err) || err != U_ILLEGAL_ARGUMENT_ERROR) { log_err("FAIL: Cloned Collator failed to deal correctly with null bufferSize pointer\n"); } err = U_ZERO_ERROR; /* buffer size pointer is 0 - fill in pbufferSize with a size */ bufferSize = 0; if (0 != ucol_safeClone(someCollators[0], buffer[0], &bufferSize, &err) || U_FAILURE(err) || bufferSize <= 0) { log_err("FAIL: Cloned Collator failed a sizing request ('preflighting')\n"); } /* Verify our define is large enough */ if (U_COL_SAFECLONE_BUFFERSIZE < bufferSize) { log_err("FAIL: Pre-calculated buffer size is too small\n"); } /* Verify we can use this run-time calculated size */ if (0 == (col = ucol_safeClone(someCollators[0], buffer[0], &bufferSize, &err)) || U_FAILURE(err)) { log_err("FAIL: Collator can't be cloned with run-time size\n"); } if (col) ucol_close(col); /* size one byte too small - should allocate & let us know */ --bufferSize; if (0 == (col = ucol_safeClone(someCollators[0], 0, &bufferSize, &err)) || err != U_SAFECLONE_ALLOCATED_WARNING) { log_err("FAIL: Cloned Collator failed to deal correctly with too-small buffer size\n"); } if (col) ucol_close(col); err = U_ZERO_ERROR; bufferSize = U_COL_SAFECLONE_BUFFERSIZE; /* Null buffer pointer - return Collator & set error to U_SAFECLONE_ALLOCATED_ERROR */ if (0 == (col = ucol_safeClone(someCollators[0], 0, &bufferSize, &err)) || err != U_SAFECLONE_ALLOCATED_WARNING) { log_err("FAIL: Cloned Collator failed to deal correctly with null buffer pointer\n"); } if (col) ucol_close(col); err = U_ZERO_ERROR; /* Null Collator - return NULL & set U_ILLEGAL_ARGUMENT_ERROR */ if (0 != ucol_safeClone(0, buffer[0], &bufferSize, &err) || err != U_ILLEGAL_ARGUMENT_ERROR) { log_err("FAIL: Cloned Collator failed to deal correctly with null Collator pointer\n"); } err = U_ZERO_ERROR; /* Test that a cloned collator doesn't accidentally use UCA. */ col=ucol_open("de@collation=phonebook", &err); bufferSize = U_COL_SAFECLONE_BUFFERSIZE; someClonedCollators[0] = ucol_safeClone(col, buffer[0], &bufferSize, &err); doAssert( (ucol_greater(col, umlautUStr, u_strlen(umlautUStr), oeStr, u_strlen(oeStr))), "Original German phonebook collation sorts differently than expected"); doAssert( (ucol_greater(someClonedCollators[0], umlautUStr, u_strlen(umlautUStr), oeStr, u_strlen(oeStr))), "Cloned German phonebook collation sorts differently than expected"); if (!ucol_equals(someClonedCollators[0], col)) { log_err("FAIL: Cloned German phonebook collator is not equal to original.\n"); } ucol_close(col); ucol_close(someClonedCollators[0]); err = U_ZERO_ERROR; /* change orig & clone & make sure they are independent */ for (index = 0; index < CLONETEST_COLLATOR_COUNT; index++) { ucol_setStrength(someCollators[index], UCOL_IDENTICAL); bufferSize = 1; err = U_ZERO_ERROR; ucol_close(ucol_safeClone(someCollators[index], buffer[index], &bufferSize, &err)); if (err != U_SAFECLONE_ALLOCATED_WARNING) { log_err("FAIL: collator number %d was not allocated.\n", index); log_err("FAIL: status of Collator[%d] is %d (hex: %x).\n", index, err, err); } bufferSize = U_COL_SAFECLONE_BUFFERSIZE; err = U_ZERO_ERROR; someClonedCollators[index] = ucol_safeClone(someCollators[index], buffer[index], &bufferSize, &err); if (someClonedCollators[index] == NULL || someClonedCollators[index] < (UCollator *)buffer[index] || someClonedCollators[index] > (UCollator *)(buffer[index]+(U_COL_SAFECLONE_BUFFERSIZE-1))) { log_err("FAIL: Cloned collator didn't use provided buffer.\n"); return; } if (!ucol_equals(someClonedCollators[index], someCollators[index])) { log_err("FAIL: Cloned collator is not equal to original at index = %d.\n", index); } /* Check the usability */ ucol_setStrength(someCollators[index], UCOL_PRIMARY); ucol_setAttribute(someCollators[index], UCOL_CASE_LEVEL, UCOL_OFF, &err); doAssert( (ucol_equal(someCollators[index], test1, u_strlen(test1), test2, u_strlen(test2))), "Result should be \"abcda\" == \"abCda\""); /* Close the original to make sure that the clone is usable. */ ucol_close(someCollators[index]); ucol_setStrength(someClonedCollators[index], UCOL_TERTIARY); ucol_setAttribute(someClonedCollators[index], UCOL_CASE_LEVEL, UCOL_OFF, &err); doAssert( (ucol_greater(someClonedCollators[index], test1, u_strlen(test1), test2, u_strlen(test2))), "Result should be \"abCda\" >>> \"abcda\" "); ucol_close(someClonedCollators[index]); } } void TestCloneBinary(){ UErrorCode err = U_ZERO_ERROR; UCollator * col = ucol_open("en_US", &err); UCollator * c; int32_t size; uint8_t * buffer; if (U_FAILURE(err)) { log_data_err("Couldn't open collator. Error: %s\n", u_errorName(err)); return; } size = ucol_cloneBinary(col, NULL, 0, &err); if(size==0 || err!=U_BUFFER_OVERFLOW_ERROR) { log_err("ucol_cloneBinary - couldn't check size. Error: %s\n", u_errorName(err)); return; } err = U_ZERO_ERROR; buffer = (uint8_t *) malloc(size); ucol_cloneBinary(col, buffer, size, &err); if(U_FAILURE(err)) { log_err("ucol_cloneBinary - couldn't clone.. Error: %s\n", u_errorName(err)); free(buffer); return; } /* how to check binary result ? */ c = ucol_openBinary(buffer, size, col, &err); if(U_FAILURE(err)) { log_err("ucol_openBinary failed. Error: %s\n", u_errorName(err)); } else { UChar t[] = {0x41, 0x42, 0x43, 0}; /* ABC */ uint8_t *k1, *k2; int l1, l2; l1 = ucol_getSortKey(col, t, -1, NULL,0); l2 = ucol_getSortKey(c, t, -1, NULL,0); k1 = (uint8_t *) malloc(sizeof(uint8_t) * l1); k2 = (uint8_t *) malloc(sizeof(uint8_t) * l2); ucol_getSortKey(col, t, -1, k1, l1); ucol_getSortKey(col, t, -1, k2, l2); if (strcmp((char *)k1,(char *)k2) != 0){ log_err("ucol_openBinary - new collator should equal to old one\n"); }; free(k1); free(k2); } free(buffer); ucol_close(c); ucol_close(col); } static void TestBengaliSortKey(void) { const char *curLoc = "bn"; UChar str1[] = { 0x09BE, 0 }; UChar str2[] = { 0x0B70, 0 }; UCollator *c2 = NULL; const UChar *rules; int32_t rulesLength=-1; uint8_t *sortKey1; int32_t sortKeyLen1 = 0; uint8_t *sortKey2; int32_t sortKeyLen2 = 0; UErrorCode status = U_ZERO_ERROR; char sortKeyStr1[2048]; uint32_t sortKeyStrLen1 = sizeof(sortKeyStr1)/sizeof(sortKeyStr1[0]); char sortKeyStr2[2048]; uint32_t sortKeyStrLen2 = sizeof(sortKeyStr2)/sizeof(sortKeyStr2[0]); UCollationResult result; static UChar preRules[41] = { 0x26, 0x9fa, 0x3c, 0x98c, 0x3c, 0x9e1, 0x3c, 0x98f, 0x3c, 0x990, 0x3c, 0x993, 0x3c, 0x994, 0x3c, 0x9bc, 0x3c, 0x982, 0x3c, 0x983, 0x3c, 0x981, 0x3c, 0x9b0, 0x3c, 0x9b8, 0x3c, 0x9b9, 0x3c, 0x9bd, 0x3c, 0x9be, 0x3c, 0x9bf, 0x3c, 0x9c8, 0x3c, 0x9cb, 0x3d, 0x9cb , 0}; rules = preRules; log_verbose("Rules: %s\n", aescstrdup(rules, rulesLength)); c2 = ucol_openRules(rules, rulesLength, UCOL_DEFAULT, UCOL_DEFAULT_STRENGTH, NULL, &status); if (U_FAILURE(status)) { log_data_err("ERROR: Creating collator from rules failed with locale: %s : %s\n", curLoc, myErrorName(status)); return; } sortKeyLen1 = ucol_getSortKey(c2, str1, -1, NULL, 0); sortKey1 = (uint8_t*)malloc(sortKeyLen1+1); ucol_getSortKey(c2,str1,-1,sortKey1, sortKeyLen1+1); ucol_sortKeyToString(c2, sortKey1, sortKeyStr1, &sortKeyStrLen1); sortKeyLen2 = ucol_getSortKey(c2, str2, -1, NULL, 0); sortKey2 = (uint8_t*)malloc(sortKeyLen2+1); ucol_getSortKey(c2,str2,-1,sortKey2, sortKeyLen2+1); ucol_sortKeyToString(c2, sortKey2, sortKeyStr2, &sortKeyStrLen2); result=ucol_strcoll(c2, str1, -1, str2, -1); if(result!=UCOL_LESS) { log_err("Error: %s was not less than %s: result=%d.\n", aescstrdup(str1,-1), aescstrdup(str2,-1), result); log_info("[%s] -> %s (%d, from rule)\n", aescstrdup(str1,-1), sortKeyStr1, sortKeyLen1); log_info("[%s] -> %s (%d, from rule)\n", aescstrdup(str2,-1), sortKeyStr2, sortKeyLen2); } else { log_verbose("OK: %s was less than %s: result=%d.\n", aescstrdup(str1,-1), aescstrdup(str2,-1), result); log_verbose("[%s] -> %s (%d, from rule)\n", aescstrdup(str1,-1), sortKeyStr1, sortKeyLen1); log_verbose("[%s] -> %s (%d, from rule)\n", aescstrdup(str2,-1), sortKeyStr2, sortKeyLen2); } free(sortKey1); free(sortKey2); ucol_close(c2); } /* TestOpenVsOpenRules ensures that collators from ucol_open and ucol_openRules will generate identical sort keys */ void TestOpenVsOpenRules(){ /* create an array of all the locales */ int32_t numLocales = uloc_countAvailable(); int32_t sizeOfStdSet; uint32_t adder; UChar str[41]; /* create an array of UChar of size maximum strSize + 1 */ USet *stdSet; char* curLoc; UCollator * c1; UCollator * c2; const UChar* rules; int32_t rulesLength; int32_t sortKeyLen1, sortKeyLen2; uint8_t *sortKey1 = NULL, *sortKey2 = NULL; ULocaleData *uld; int32_t x, y, z; USet *eSet; int32_t eSize; int strSize; UErrorCode err = U_ZERO_ERROR; /* create a set of standard characters that aren't very interesting... and then we can find some interesting ones later */ stdSet = uset_open(0x61, 0x7A); uset_addRange(stdSet, 0x41, 0x5A); uset_addRange(stdSet, 0x30, 0x39); sizeOfStdSet = uset_size(stdSet); adder = 1; if(getTestOption(QUICK_OPTION)) { adder = 10; } for(x = 0; x < numLocales; x+=adder){ curLoc = (char *)uloc_getAvailable(x); log_verbose("Processing %s\n", curLoc); /* create a collator the normal API way */ c1 = ucol_open(curLoc, &err); if (U_FAILURE(err)) { log_err("ERROR: Normal collation creation failed with locale: %s : %s\n", curLoc, myErrorName(err)); return; } /* grab the rules */ rules = ucol_getRules(c1, &rulesLength); /* use those rules to create a collator from rules */ c2 = ucol_openRules(rules, rulesLength, UCOL_DEFAULT, UCOL_DEFAULT_STRENGTH, NULL, &err); if (U_FAILURE(err)) { log_err("ERROR: Creating collator from rules failed with locale: %s : %s\n", curLoc, myErrorName(err)); return; } uld = ulocdata_open(curLoc, &err); /*now that we have some collators, we get several strings */ for(y = 0; y < 5; y++){ /* get a set of ALL the characters in this locale */ eSet = ulocdata_getExemplarSet(uld, NULL, 0, ULOCDATA_ES_STANDARD, &err); eSize = uset_size(eSet); /* make a string with these characters in it */ strSize = (rand()%40) + 1; for(z = 0; z < strSize; z++){ str[z] = uset_charAt(eSet, rand()%eSize); } /* change the set to only include 'abnormal' characters (not A-Z, a-z, 0-9 */ uset_removeAll(eSet, stdSet); eSize = uset_size(eSet); /* if there are some non-normal characters left, put a few into the string, just to make sure we have some */ if(eSize > 0){ str[2%strSize] = uset_charAt(eSet, rand()%eSize); str[3%strSize] = uset_charAt(eSet, rand()%eSize); str[5%strSize] = uset_charAt(eSet, rand()%eSize); str[10%strSize] = uset_charAt(eSet, rand()%eSize); str[13%strSize] = uset_charAt(eSet, rand()%eSize); } /* terminate the string */ str[strSize-1] = '\0'; log_verbose("String used: %S\n", str); /* get sort keys for both of them, and check that the keys are identicle */ sortKeyLen1 = ucol_getSortKey(c1, str, u_strlen(str), NULL, 0); sortKey1 = (uint8_t*)malloc(sizeof(uint8_t) * (sortKeyLen1 + 1)); /*memset(sortKey1, 0xFE, sortKeyLen1);*/ ucol_getSortKey(c1, str, u_strlen(str), sortKey1, sortKeyLen1 + 1); sortKeyLen2 = ucol_getSortKey(c2, str, u_strlen(str), NULL, 0); sortKey2 = (uint8_t*)malloc(sizeof(uint8_t) * (sortKeyLen2 + 1)); /*memset(sortKey2, 0xFE, sortKeyLen2);*/ ucol_getSortKey(c2, str, u_strlen(str), sortKey2, sortKeyLen2 + 1); /* Check that the lengths are the same */ doAssert((sortKeyLen1 == sortKeyLen2), "Sort key lengths do not match."); /* check that the keys are the same */ doAssert((memcmp(sortKey1, sortKey2, sortKeyLen1) == 0), "Keys are not equivalent"); /* clean up after each string */ free(sortKey1); free(sortKey2); uset_close(eSet); } /* clean up after each locale */ ulocdata_close(uld); ucol_close(c1); ucol_close(c2); } /* final clean up */ uset_close(stdSet); } /* ---------------------------------------------------------------------------- ctor -- Tests the getSortKey */ void TestSortKey() { uint8_t *sortk1 = NULL, *sortk2 = NULL, *sortk3 = NULL, *sortkEmpty = NULL; int32_t sortklen, osortklen; uint32_t toStringLen=0; UCollator *col; UChar *test1, *test2, *test3; UErrorCode status = U_ZERO_ERROR; char toStringBuffer[256], *resultP; uint8_t s1[] = { 0x9f, 0x00 }; uint8_t s2[] = { 0x61, 0x00 }; int strcmpResult; strcmpResult = strcmp((const char *)s1, (const char *)s2); log_verbose("strcmp(0x9f..., 0x61...) = %d\n", strcmpResult); if(strcmpResult <= 0) { log_err("ERR: expected strcmp(\"9f 00\", \"61 00\") to be >=0 (GREATER).. got %d. Calling strcmp() for sortkeys may not work! \n", strcmpResult); } log_verbose("testing SortKey begins...\n"); /* this is supposed to open default date format, but later on it treats it like it is "en_US" - very bad if you try to run the tests on machine where default locale is NOT "en_US" */ /* col = ucol_open(NULL, &status); */ col = ucol_open("en_US", &status); if (U_FAILURE(status)) { log_err_status(status, "ERROR: Default collation creation failed.: %s\n", myErrorName(status)); return; } if(ucol_getStrength(col) != UCOL_DEFAULT_STRENGTH) { log_err("ERROR: default collation did not have UCOL_DEFAULT_STRENGTH !\n"); } /* Need to use identical strength */ ucol_setAttribute(col, UCOL_STRENGTH, UCOL_IDENTICAL, &status); test1=(UChar*)malloc(sizeof(UChar) * 6); test2=(UChar*)malloc(sizeof(UChar) * 6); test3=(UChar*)malloc(sizeof(UChar) * 6); memset(test1,0xFE, sizeof(UChar)*6); memset(test2,0xFE, sizeof(UChar)*6); memset(test3,0xFE, sizeof(UChar)*6); u_uastrcpy(test1, "Abcda"); u_uastrcpy(test2, "abcda"); u_uastrcpy(test3, "abcda"); log_verbose("Use tertiary comparison level testing ....\n"); sortklen=ucol_getSortKey(col, test1, u_strlen(test1), NULL, 0); sortk1=(uint8_t*)malloc(sizeof(uint8_t) * (sortklen+1)); memset(sortk1,0xFE, sortklen); ucol_getSortKey(col, test1, u_strlen(test1), sortk1, sortklen+1); sortklen=ucol_getSortKey(col, test2, u_strlen(test2), NULL, 0); sortk2=(uint8_t*)malloc(sizeof(uint8_t) * (sortklen+1)); memset(sortk2,0xFE, sortklen); ucol_getSortKey(col, test2, u_strlen(test2), sortk2, sortklen+1); osortklen = sortklen; sortklen=ucol_getSortKey(col, test2, u_strlen(test3), NULL, 0); sortk3=(uint8_t*)malloc(sizeof(uint8_t) * (sortklen+1)); memset(sortk3,0xFE, sortklen); ucol_getSortKey(col, test2, u_strlen(test2), sortk3, sortklen+1); doAssert( (sortklen == osortklen), "Sortkey length should be the same (abcda, abcda)"); doAssert( (memcmp(sortk1, sortk2, sortklen) > 0), "Result should be \"Abcda\" > \"abcda\""); doAssert( (memcmp(sortk2, sortk1, sortklen) < 0), "Result should be \"abcda\" < \"Abcda\""); doAssert( (memcmp(sortk2, sortk3, sortklen) == 0), "Result should be \"abcda\" == \"abcda\""); resultP = ucol_sortKeyToString(col, sortk3, toStringBuffer, &toStringLen); doAssert( (resultP != 0), "sortKeyToString failed!"); #if 1 /* verobse log of sortkeys */ { char junk2[1000]; char junk3[1000]; int i; strcpy(junk2, "abcda[2] "); strcpy(junk3, " abcda[3] "); for(i=0;i<sortklen;i++) { sprintf(junk2+strlen(junk2), "%02X ",(int)( 0xFF & sortk2[i])); sprintf(junk3+strlen(junk3), "%02X ",(int)( 0xFF & sortk3[i])); } log_verbose("%s\n", junk2); log_verbose("%s\n", junk3); } #endif free(sortk1); free(sortk2); free(sortk3); log_verbose("Use secondary comparision level testing ...\n"); ucol_setStrength(col, UCOL_SECONDARY); sortklen=ucol_getSortKey(col, test1, u_strlen(test1), NULL, 0); sortk1=(uint8_t*)malloc(sizeof(uint8_t) * (sortklen+1)); ucol_getSortKey(col, test1, u_strlen(test1), sortk1, sortklen+1); sortklen=ucol_getSortKey(col, test2, u_strlen(test2), NULL, 0); sortk2=(uint8_t*)malloc(sizeof(uint8_t) * (sortklen+1)); ucol_getSortKey(col, test2, u_strlen(test2), sortk2, sortklen+1); doAssert( !(memcmp(sortk1, sortk2, sortklen) > 0), "Result should be \"Abcda\" == \"abcda\""); doAssert( !(memcmp(sortk2, sortk1, sortklen) < 0), "Result should be \"abcda\" == \"Abcda\""); doAssert( (memcmp(sortk1, sortk2, sortklen) == 0), "Result should be \"abcda\" == \"abcda\""); log_verbose("getting sortkey for an empty string\n"); ucol_setAttribute(col, UCOL_STRENGTH, UCOL_TERTIARY, &status); sortklen = ucol_getSortKey(col, test1, 0, NULL, 0); sortkEmpty = (uint8_t*)malloc(sizeof(uint8_t) * sortklen+1); sortklen = ucol_getSortKey(col, test1, 0, sortkEmpty, sortklen+1); if(sortklen != 3 || sortkEmpty[0] != 1 || sortkEmpty[0] != 1 || sortkEmpty[2] != 0) { log_err("Empty string generated wrong sortkey!\n"); } free(sortkEmpty); log_verbose("testing passing invalid string\n"); sortklen = ucol_getSortKey(col, NULL, 0, NULL, 0); if(sortklen != 0) { log_err("Invalid string didn't return sortkey size of 0\n"); } log_verbose("testing sortkey ends...\n"); ucol_close(col); free(test1); free(test2); free(test3); free(sortk1); free(sortk2); } void TestHashCode() { uint8_t *sortk1, *sortk2, *sortk3; int32_t sortk1len, sortk2len, sortk3len; UCollator *col; UChar *test1, *test2, *test3; UErrorCode status = U_ZERO_ERROR; log_verbose("testing getHashCode begins...\n"); col = ucol_open("en_US", &status); if (U_FAILURE(status)) { log_err_status(status, "ERROR: Default collation creation failed.: %s\n", myErrorName(status)); return; } test1=(UChar*)malloc(sizeof(UChar) * 6); test2=(UChar*)malloc(sizeof(UChar) * 6); test3=(UChar*)malloc(sizeof(UChar) * 6); u_uastrcpy(test1, "Abcda"); u_uastrcpy(test2, "abcda"); u_uastrcpy(test3, "abcda"); log_verbose("Use tertiary comparison level testing ....\n"); sortk1len=ucol_getSortKey(col, test1, u_strlen(test1), NULL, 0); sortk1=(uint8_t*)malloc(sizeof(uint8_t) * (sortk1len+1)); ucol_getSortKey(col, test1, u_strlen(test1), sortk1, sortk1len+1); sortk2len=ucol_getSortKey(col, test2, u_strlen(test2), NULL, 0); sortk2=(uint8_t*)malloc(sizeof(uint8_t) * (sortk2len+1)); ucol_getSortKey(col, test2, u_strlen(test2), sortk2, sortk2len+1); sortk3len=ucol_getSortKey(col, test2, u_strlen(test3), NULL, 0); sortk3=(uint8_t*)malloc(sizeof(uint8_t) * (sortk3len+1)); ucol_getSortKey(col, test2, u_strlen(test2), sortk3, sortk3len+1); log_verbose("ucol_hashCode() testing ...\n"); doAssert( ucol_keyHashCode(sortk1, sortk1len) != ucol_keyHashCode(sortk2, sortk2len), "Hash test1 result incorrect" ); doAssert( !(ucol_keyHashCode(sortk1, sortk1len) == ucol_keyHashCode(sortk2, sortk2len)), "Hash test2 result incorrect" ); doAssert( ucol_keyHashCode(sortk2, sortk2len) == ucol_keyHashCode(sortk3, sortk3len), "Hash result not equal" ); log_verbose("hashCode tests end.\n"); ucol_close(col); free(sortk1); free(sortk2); free(sortk3); free(test1); free(test2); free(test3); } /* *---------------------------------------------------------------------------- * Tests the UCollatorElements API. * */ void TestElemIter() { int32_t offset; int32_t order1, order2, order3; UChar *testString1, *testString2; UCollator *col; UCollationElements *iterator1, *iterator2, *iterator3; UErrorCode status = U_ZERO_ERROR; log_verbose("testing UCollatorElements begins...\n"); col = ucol_open("en_US", &status); ucol_setAttribute(col, UCOL_NORMALIZATION_MODE, UCOL_OFF, &status); if (U_FAILURE(status)) { log_err_status(status, "ERROR: Default collation creation failed.: %s\n", myErrorName(status)); return; } testString1=(UChar*)malloc(sizeof(UChar) * 150); testString2=(UChar*)malloc(sizeof(UChar) * 150); u_uastrcpy(testString1, "XFILE What subset of all possible test cases has the highest probability of detecting the most errors?"); u_uastrcpy(testString2, "Xf_ile What subset of all possible test cases has the lowest probability of detecting the least errors?"); log_verbose("Constructors and comparison testing....\n"); iterator1 = ucol_openElements(col, testString1, u_strlen(testString1), &status); if(U_FAILURE(status)) { log_err("ERROR: Default collationElement iterator creation failed.: %s\n", myErrorName(status)); ucol_close(col); return; } else{ log_verbose("PASS: Default collationElement iterator1 creation passed\n");} iterator2 = ucol_openElements(col, testString1, u_strlen(testString1), &status); if(U_FAILURE(status)) { log_err("ERROR: Default collationElement iterator creation failed.: %s\n", myErrorName(status)); ucol_close(col); return; } else{ log_verbose("PASS: Default collationElement iterator2 creation passed\n");} iterator3 = ucol_openElements(col, testString2, u_strlen(testString2), &status); if(U_FAILURE(status)) { log_err("ERROR: Default collationElement iterator creation failed.: %s\n", myErrorName(status)); ucol_close(col); return; } else{ log_verbose("PASS: Default collationElement iterator3 creation passed\n");} offset=ucol_getOffset(iterator1); ucol_setOffset(iterator1, 6, &status); if (U_FAILURE(status)) { log_err("Error in setOffset for UCollatorElements iterator.: %s\n", myErrorName(status)); return; } if(ucol_getOffset(iterator1)==6) log_verbose("setOffset and getOffset working fine\n"); else{ log_err("error in set and get Offset got %d instead of 6\n", ucol_getOffset(iterator1)); } ucol_setOffset(iterator1, 0, &status); order1 = ucol_next(iterator1, &status); if (U_FAILURE(status)) { log_err("Somehow ran out of memory stepping through the iterator1.: %s\n", myErrorName(status)); return; } order2=ucol_getOffset(iterator2); doAssert((order1 != order2), "The first iterator advance failed"); order2 = ucol_next(iterator2, &status); if (U_FAILURE(status)) { log_err("Somehow ran out of memory stepping through the iterator2.: %s\n", myErrorName(status)); return; } order3 = ucol_next(iterator3, &status); if (U_FAILURE(status)) { log_err("Somehow ran out of memory stepping through the iterator3.: %s\n", myErrorName(status)); return; } doAssert((order1 == order2), "The second iterator advance failed should be the same as first one"); doAssert( (ucol_primaryOrder(order1) == ucol_primaryOrder(order3)), "The primary orders should be identical"); doAssert( (ucol_secondaryOrder(order1) == ucol_secondaryOrder(order3)), "The secondary orders should be identical"); doAssert( (ucol_tertiaryOrder(order1) == ucol_tertiaryOrder(order3)), "The tertiary orders should be identical"); order1=ucol_next(iterator1, &status); if (U_FAILURE(status)) { log_err("Somehow ran out of memory stepping through the iterator2.: %s\n", myErrorName(status)); return; } order3=ucol_next(iterator3, &status); if (U_FAILURE(status)) { log_err("Somehow ran out of memory stepping through the iterator2.: %s\n", myErrorName(status)); return; } doAssert( (ucol_primaryOrder(order1) == ucol_primaryOrder(order3)), "The primary orders should be identical"); doAssert( (ucol_tertiaryOrder(order1) != ucol_tertiaryOrder(order3)), "The tertiary orders should be different"); order1=ucol_next(iterator1, &status); if (U_FAILURE(status)) { log_err("Somehow ran out of memory stepping through the iterator2.: %s\n", myErrorName(status)); return; } order3=ucol_next(iterator3, &status); if (U_FAILURE(status)) { log_err("Somehow ran out of memory stepping through the iterator2.: %s\n", myErrorName(status)); return; } /* this here, my friends, is either pure lunacy or something so obsolete that even it's mother * doesn't care about it. Essentialy, this test complains if secondary values for 'I' and '_' * are the same. According to the UCA, this is not true. Therefore, remove the test. * Besides, if primary strengths for two code points are different, it doesn't matter one bit * what is the relation between secondary or any other strengths. * killed by weiv 06/11/2002. */ /* doAssert( ((order1 & UCOL_SECONDARYMASK) != (order3 & UCOL_SECONDARYMASK)), "The secondary orders should be different"); */ doAssert( (order1 != UCOL_NULLORDER), "Unexpected end of iterator reached"); free(testString1); free(testString2); ucol_closeElements(iterator1); ucol_closeElements(iterator2); ucol_closeElements(iterator3); ucol_close(col); log_verbose("testing CollationElementIterator ends...\n"); } void TestGetLocale() { UErrorCode status = U_ZERO_ERROR; const char *rules = "&a<x<y<z"; UChar rlz[256] = {0}; uint32_t rlzLen = u_unescape(rules, rlz, 256); UCollator *coll = NULL; const char *locale = NULL; int32_t i = 0; /* Now that the collation tree is separate, actual==valid at all times. [alan] */ static const struct { const char* requestedLocale; const char* validLocale; const char* actualLocale; } testStruct[] = { { "sr_RS", "sr_Cyrl_RS", "sr" }, { "sh_YU", "sr_Latn_RS", "hr" }, /* this used to be sh, but now sh collation aliases hr */ { "en_BE_FOO", "en_BE", "root" }, { "de_DE_NONEXISTANT", "de_DE", "de" } }; /* test opening collators for different locales */ for(i = 0; i<sizeof(testStruct)/sizeof(testStruct[0]); i++) { status = U_ZERO_ERROR; coll = ucol_open(testStruct[i].requestedLocale, &status); if(U_FAILURE(status)) { log_err_status(status, "Failed to open collator for %s with %s\n", testStruct[i].requestedLocale, u_errorName(status)); ucol_close(coll); continue; } locale = ucol_getLocaleByType(coll, ULOC_REQUESTED_LOCALE, &status); if(strcmp(locale, testStruct[i].requestedLocale) != 0) { log_err("[Coll %s]: Error in requested locale, expected %s, got %s\n", testStruct[i].requestedLocale, testStruct[i].requestedLocale, locale); } locale = ucol_getLocaleByType(coll, ULOC_VALID_LOCALE, &status); if(strcmp(locale, testStruct[i].validLocale) != 0) { log_err("[Coll %s]: Error in valid locale, expected %s, got %s\n", testStruct[i].requestedLocale, testStruct[i].validLocale, locale); } locale = ucol_getLocaleByType(coll, ULOC_ACTUAL_LOCALE, &status); if(strcmp(locale, testStruct[i].actualLocale) != 0) { log_err("[Coll %s]: Error in actual locale, expected %s, got %s\n", testStruct[i].requestedLocale, testStruct[i].actualLocale, locale); } ucol_close(coll); } /* completely non-existant locale for collator should get a default collator */ { UCollator *defaultColl = ucol_open(NULL, &status); coll = ucol_open("blahaha", &status); if(U_SUCCESS(status)) { if(strcmp(ucol_getLocaleByType(coll, ULOC_REQUESTED_LOCALE, &status), "blahaha")) { log_err("Nonexisting locale didn't preserve the requested locale\n"); } if(strcmp(ucol_getLocaleByType(coll, ULOC_VALID_LOCALE, &status), ucol_getLocaleByType(defaultColl, ULOC_VALID_LOCALE, &status))) { log_err("Valid locale for nonexisting locale locale collator differs " "from valid locale for default collator\n"); } if(strcmp(ucol_getLocaleByType(coll, ULOC_ACTUAL_LOCALE, &status), ucol_getLocaleByType(defaultColl, ULOC_ACTUAL_LOCALE, &status))) { log_err("Actual locale for nonexisting locale locale collator differs " "from actual locale for default collator\n"); } ucol_close(coll); ucol_close(defaultColl); } else { log_data_err("Couldn't open collators\n"); } } /* collator instantiated from rules should have all three locales NULL */ coll = ucol_openRules(rlz, rlzLen, UCOL_DEFAULT, UCOL_DEFAULT, NULL, &status); locale = ucol_getLocaleByType(coll, ULOC_REQUESTED_LOCALE, &status); if(locale != NULL) { log_err("For collator instantiated from rules, requested locale returned %s instead of NULL\n", locale); } locale = ucol_getLocaleByType(coll, ULOC_VALID_LOCALE, &status); if(locale != NULL) { log_err("For collator instantiated from rules, valid locale returned %s instead of NULL\n", locale); } locale = ucol_getLocaleByType(coll, ULOC_ACTUAL_LOCALE, &status); if(locale != NULL) { log_err("For collator instantiated from rules, actual locale returned %s instead of NULL\n", locale); } ucol_close(coll); } void TestGetAll() { int32_t i, count; count=ucol_countAvailable(); /* use something sensible w/o hardcoding the count */ if(count < 0){ log_err("Error in countAvailable(), it returned %d\n", count); } else{ log_verbose("PASS: countAvailable() successful, it returned %d\n", count); } for(i=0;i<count;i++) log_verbose("%s\n", ucol_getAvailable(i)); } struct teststruct { const char *original; uint8_t key[256]; } ; static int compare_teststruct(const void *string1, const void *string2) { return(strcmp((const char *)((struct teststruct *)string1)->key, (const char *)((struct teststruct *)string2)->key)); } void TestBounds() { UErrorCode status = U_ZERO_ERROR; UCollator *coll = ucol_open("sh", &status); uint8_t sortkey[512], lower[512], upper[512]; UChar buffer[512]; static const char * const test[] = { "John Smith", "JOHN SMITH", "john SMITH", "j\\u00F6hn sm\\u00EFth", "J\\u00F6hn Sm\\u00EFth", "J\\u00D6HN SM\\u00CFTH", "john smithsonian", "John Smithsonian", }; struct teststruct tests[] = { {"\\u010CAKI MIHALJ" } , {"\\u010CAKI MIHALJ" } , {"\\u010CAKI PIRO\\u0160KA" }, {"\\u010CABAI ANDRIJA" } , {"\\u010CABAI LAJO\\u0160" } , {"\\u010CABAI MARIJA" } , {"\\u010CABAI STEVAN" } , {"\\u010CABAI STEVAN" } , {"\\u010CABARKAPA BRANKO" } , {"\\u010CABARKAPA MILENKO" } , {"\\u010CABARKAPA MIROSLAV" } , {"\\u010CABARKAPA SIMO" } , {"\\u010CABARKAPA STANKO" } , {"\\u010CABARKAPA TAMARA" } , {"\\u010CABARKAPA TOMA\\u0160" } , {"\\u010CABDARI\\u0106 NIKOLA" } , {"\\u010CABDARI\\u0106 ZORICA" } , {"\\u010CABI NANDOR" } , {"\\u010CABOVI\\u0106 MILAN" } , {"\\u010CABRADI AGNEZIJA" } , {"\\u010CABRADI IVAN" } , {"\\u010CABRADI JELENA" } , {"\\u010CABRADI LJUBICA" } , {"\\u010CABRADI STEVAN" } , {"\\u010CABRDA MARTIN" } , {"\\u010CABRILO BOGDAN" } , {"\\u010CABRILO BRANISLAV" } , {"\\u010CABRILO LAZAR" } , {"\\u010CABRILO LJUBICA" } , {"\\u010CABRILO SPASOJA" } , {"\\u010CADE\\u0160 ZDENKA" } , {"\\u010CADESKI BLAGOJE" } , {"\\u010CADOVSKI VLADIMIR" } , {"\\u010CAGLJEVI\\u0106 TOMA" } , {"\\u010CAGOROVI\\u0106 VLADIMIR" } , {"\\u010CAJA VANKA" } , {"\\u010CAJI\\u0106 BOGOLJUB" } , {"\\u010CAJI\\u0106 BORISLAV" } , {"\\u010CAJI\\u0106 RADOSLAV" } , {"\\u010CAK\\u0160IRAN MILADIN" } , {"\\u010CAKAN EUGEN" } , {"\\u010CAKAN EVGENIJE" } , {"\\u010CAKAN IVAN" } , {"\\u010CAKAN JULIJAN" } , {"\\u010CAKAN MIHAJLO" } , {"\\u010CAKAN STEVAN" } , {"\\u010CAKAN VLADIMIR" } , {"\\u010CAKAN VLADIMIR" } , {"\\u010CAKAN VLADIMIR" } , {"\\u010CAKARA ANA" } , {"\\u010CAKAREVI\\u0106 MOMIR" } , {"\\u010CAKAREVI\\u0106 NEDELJKO" } , {"\\u010CAKI \\u0160ANDOR" } , {"\\u010CAKI AMALIJA" } , {"\\u010CAKI ANDRA\\u0160" } , {"\\u010CAKI LADISLAV" } , {"\\u010CAKI LAJO\\u0160" } , {"\\u010CAKI LASLO" } , }; int32_t i = 0, j = 0, k = 0, buffSize = 0, skSize = 0, lowerSize = 0, upperSize = 0; int32_t arraySize = sizeof(tests)/sizeof(tests[0]); if(U_SUCCESS(status) && coll) { for(i = 0; i<arraySize; i++) { buffSize = u_unescape(tests[i].original, buffer, 512); skSize = ucol_getSortKey(coll, buffer, buffSize, tests[i].key, 512); } qsort(tests, arraySize, sizeof(struct teststruct), compare_teststruct); for(i = 0; i < arraySize-1; i++) { for(j = i+1; j < arraySize; j++) { lowerSize = ucol_getBound(tests[i].key, -1, UCOL_BOUND_LOWER, 1, lower, 512, &status); upperSize = ucol_getBound(tests[j].key, -1, UCOL_BOUND_UPPER, 1, upper, 512, &status); for(k = i; k <= j; k++) { if(strcmp((const char *)lower, (const char *)tests[k].key) > 0) { log_err("Problem with lower! j = %i (%s vs %s)\n", k, tests[k].original, tests[i].original); } if(strcmp((const char *)upper, (const char *)tests[k].key) <= 0) { log_err("Problem with upper! j = %i (%s vs %s)\n", k, tests[k].original, tests[j].original); } } } } #if 0 for(i = 0; i < 1000; i++) { lowerRND = (rand()/(RAND_MAX/arraySize)); upperRND = lowerRND + (rand()/(RAND_MAX/(arraySize-lowerRND))); lowerSize = ucol_getBound(tests[lowerRND].key, -1, UCOL_BOUND_LOWER, 1, lower, 512, &status); upperSize = ucol_getBound(tests[upperRND].key, -1, UCOL_BOUND_UPPER_LONG, 1, upper, 512, &status); for(j = lowerRND; j<=upperRND; j++) { if(strcmp(lower, tests[j].key) > 0) { log_err("Problem with lower! j = %i (%s vs %s)\n", j, tests[j].original, tests[lowerRND].original); } if(strcmp(upper, tests[j].key) <= 0) { log_err("Problem with upper! j = %i (%s vs %s)\n", j, tests[j].original, tests[upperRND].original); } } } #endif for(i = 0; i<sizeof(test)/sizeof(test[0]); i++) { buffSize = u_unescape(test[i], buffer, 512); skSize = ucol_getSortKey(coll, buffer, buffSize, sortkey, 512); lowerSize = ucol_getBound(sortkey, skSize, UCOL_BOUND_LOWER, 1, lower, 512, &status); upperSize = ucol_getBound(sortkey, skSize, UCOL_BOUND_UPPER_LONG, 1, upper, 512, &status); for(j = i+1; j<sizeof(test)/sizeof(test[0]); j++) { buffSize = u_unescape(test[j], buffer, 512); skSize = ucol_getSortKey(coll, buffer, buffSize, sortkey, 512); if(strcmp((const char *)lower, (const char *)sortkey) > 0) { log_err("Problem with lower! i = %i, j = %i (%s vs %s)\n", i, j, test[i], test[j]); } if(strcmp((const char *)upper, (const char *)sortkey) <= 0) { log_err("Problem with upper! i = %i, j = %i (%s vs %s)\n", i, j, test[i], test[j]); } } } ucol_close(coll); } else { log_data_err("Couldn't open collator\n"); } } static void doOverrunTest(UCollator *coll, const UChar *uString, int32_t strLen) { int32_t skLen = 0, skLen2 = 0; uint8_t sortKey[256]; int32_t i, j; uint8_t filler = 0xFF; skLen = ucol_getSortKey(coll, uString, strLen, NULL, 0); for(i = 0; i < skLen; i++) { memset(sortKey, filler, 256); skLen2 = ucol_getSortKey(coll, uString, strLen, sortKey, i); if(skLen != skLen2) { log_err("For buffer size %i, got different sortkey length. Expected %i got %i\n", i, skLen, skLen2); } for(j = i; j < 256; j++) { if(sortKey[j] != filler) { log_err("Something run over index %i\n", j); break; } } } } /* j1865 reports that if a shorter buffer is passed to * to get sort key, a buffer overrun happens in some * cases. This test tries to check this. */ void TestSortKeyBufferOverrun(void) { UErrorCode status = U_ZERO_ERROR; const char* cString = "A very Merry liTTle-lamB.."; UChar uString[256]; int32_t strLen = 0; UCollator *coll = ucol_open("root", &status); strLen = u_unescape(cString, uString, 256); if(U_SUCCESS(status)) { log_verbose("testing non ignorable\n"); ucol_setAttribute(coll, UCOL_ALTERNATE_HANDLING, UCOL_NON_IGNORABLE, &status); doOverrunTest(coll, uString, strLen); log_verbose("testing shifted\n"); ucol_setAttribute(coll, UCOL_ALTERNATE_HANDLING, UCOL_SHIFTED, &status); doOverrunTest(coll, uString, strLen); log_verbose("testing shifted quaternary\n"); ucol_setAttribute(coll, UCOL_STRENGTH, UCOL_QUATERNARY, &status); doOverrunTest(coll, uString, strLen); log_verbose("testing with french secondaries\n"); ucol_setAttribute(coll, UCOL_FRENCH_COLLATION, UCOL_ON, &status); ucol_setAttribute(coll, UCOL_STRENGTH, UCOL_TERTIARY, &status); ucol_setAttribute(coll, UCOL_ALTERNATE_HANDLING, UCOL_NON_IGNORABLE, &status); doOverrunTest(coll, uString, strLen); } ucol_close(coll); } static void TestAttribute() { UErrorCode error = U_ZERO_ERROR; UCollator *coll = ucol_open(NULL, &error); if (U_FAILURE(error)) { log_err_status(error, "Creation of default collator failed\n"); return; } ucol_setAttribute(coll, UCOL_FRENCH_COLLATION, UCOL_OFF, &error); if (ucol_getAttribute(coll, UCOL_FRENCH_COLLATION, &error) != UCOL_OFF || U_FAILURE(error)) { log_err_status(error, "Setting and retrieving of the french collation failed\n"); } ucol_setAttribute(coll, UCOL_FRENCH_COLLATION, UCOL_ON, &error); if (ucol_getAttribute(coll, UCOL_FRENCH_COLLATION, &error) != UCOL_ON || U_FAILURE(error)) { log_err_status(error, "Setting and retrieving of the french collation failed\n"); } ucol_setAttribute(coll, UCOL_ALTERNATE_HANDLING, UCOL_SHIFTED, &error); if (ucol_getAttribute(coll, UCOL_ALTERNATE_HANDLING, &error) != UCOL_SHIFTED || U_FAILURE(error)) { log_err_status(error, "Setting and retrieving of the alternate handling failed\n"); } ucol_setAttribute(coll, UCOL_ALTERNATE_HANDLING, UCOL_NON_IGNORABLE, &error); if (ucol_getAttribute(coll, UCOL_ALTERNATE_HANDLING, &error) != UCOL_NON_IGNORABLE || U_FAILURE(error)) { log_err_status(error, "Setting and retrieving of the alternate handling failed\n"); } ucol_setAttribute(coll, UCOL_CASE_FIRST, UCOL_LOWER_FIRST, &error); if (ucol_getAttribute(coll, UCOL_CASE_FIRST, &error) != UCOL_LOWER_FIRST || U_FAILURE(error)) { log_err_status(error, "Setting and retrieving of the case first attribute failed\n"); } ucol_setAttribute(coll, UCOL_CASE_FIRST, UCOL_UPPER_FIRST, &error); if (ucol_getAttribute(coll, UCOL_CASE_FIRST, &error) != UCOL_UPPER_FIRST || U_FAILURE(error)) { log_err_status(error, "Setting and retrieving of the case first attribute failed\n"); } ucol_setAttribute(coll, UCOL_CASE_LEVEL, UCOL_ON, &error); if (ucol_getAttribute(coll, UCOL_CASE_LEVEL, &error) != UCOL_ON || U_FAILURE(error)) { log_err_status(error, "Setting and retrieving of the case level attribute failed\n"); } ucol_setAttribute(coll, UCOL_CASE_LEVEL, UCOL_OFF, &error); if (ucol_getAttribute(coll, UCOL_CASE_LEVEL, &error) != UCOL_OFF || U_FAILURE(error)) { log_err_status(error, "Setting and retrieving of the case level attribute failed\n"); } ucol_setAttribute(coll, UCOL_NORMALIZATION_MODE, UCOL_ON, &error); if (ucol_getAttribute(coll, UCOL_NORMALIZATION_MODE, &error) != UCOL_ON || U_FAILURE(error)) { log_err_status(error, "Setting and retrieving of the normalization on/off attribute failed\n"); } ucol_setAttribute(coll, UCOL_NORMALIZATION_MODE, UCOL_OFF, &error); if (ucol_getAttribute(coll, UCOL_NORMALIZATION_MODE, &error) != UCOL_OFF || U_FAILURE(error)) { log_err_status(error, "Setting and retrieving of the normalization on/off attribute failed\n"); } ucol_setAttribute(coll, UCOL_STRENGTH, UCOL_PRIMARY, &error); if (ucol_getAttribute(coll, UCOL_STRENGTH, &error) != UCOL_PRIMARY || U_FAILURE(error)) { log_err_status(error, "Setting and retrieving of the collation strength failed\n"); } ucol_setAttribute(coll, UCOL_STRENGTH, UCOL_SECONDARY, &error); if (ucol_getAttribute(coll, UCOL_STRENGTH, &error) != UCOL_SECONDARY || U_FAILURE(error)) { log_err_status(error, "Setting and retrieving of the collation strength failed\n"); } ucol_setAttribute(coll, UCOL_STRENGTH, UCOL_TERTIARY, &error); if (ucol_getAttribute(coll, UCOL_STRENGTH, &error) != UCOL_TERTIARY || U_FAILURE(error)) { log_err_status(error, "Setting and retrieving of the collation strength failed\n"); } ucol_setAttribute(coll, UCOL_STRENGTH, UCOL_QUATERNARY, &error); if (ucol_getAttribute(coll, UCOL_STRENGTH, &error) != UCOL_QUATERNARY || U_FAILURE(error)) { log_err_status(error, "Setting and retrieving of the collation strength failed\n"); } ucol_setAttribute(coll, UCOL_STRENGTH, UCOL_IDENTICAL, &error); if (ucol_getAttribute(coll, UCOL_STRENGTH, &error) != UCOL_IDENTICAL || U_FAILURE(error)) { log_err_status(error, "Setting and retrieving of the collation strength failed\n"); } ucol_close(coll); } void TestGetTailoredSet() { struct { const char *rules; const char *tests[20]; int32_t testsize; } setTest[] = { { "&a < \\u212b", { "\\u212b", "A\\u030a", "\\u00c5" }, 3}, { "& S < \\u0161 <<< \\u0160", { "\\u0161", "s\\u030C", "\\u0160", "S\\u030C" }, 4} }; int32_t i = 0, j = 0; UErrorCode status = U_ZERO_ERROR; UParseError pError; UCollator *coll = NULL; UChar buff[1024]; int32_t buffLen = 0; USet *set = NULL; for(i = 0; i < sizeof(setTest)/sizeof(setTest[0]); i++) { buffLen = u_unescape(setTest[i].rules, buff, 1024); coll = ucol_openRules(buff, buffLen, UCOL_DEFAULT, UCOL_DEFAULT, &pError, &status); if(U_SUCCESS(status)) { set = ucol_getTailoredSet(coll, &status); if(uset_size(set) != setTest[i].testsize) { log_err("Tailored set size different (%d) than expected (%d)\n", uset_size(set), setTest[i].testsize); } for(j = 0; j < setTest[i].testsize; j++) { buffLen = u_unescape(setTest[i].tests[j], buff, 1024); if(!uset_containsString(set, buff, buffLen)) { log_err("Tailored set doesn't contain %s... It should\n", setTest[i].tests[j]); } } uset_close(set); } else { log_err_status(status, "Couldn't open collator with rules %s\n", setTest[i].rules); } ucol_close(coll); } } static int tMemCmp(const uint8_t *first, const uint8_t *second) { int32_t firstLen = (int32_t)strlen((const char *)first); int32_t secondLen = (int32_t)strlen((const char *)second); return memcmp(first, second, uprv_min(firstLen, secondLen)); } static const char * strengthsC[] = { "UCOL_PRIMARY", "UCOL_SECONDARY", "UCOL_TERTIARY", "UCOL_QUATERNARY", "UCOL_IDENTICAL" }; void TestMergeSortKeys(void) { UErrorCode status = U_ZERO_ERROR; UCollator *coll = ucol_open("en", &status); if(U_SUCCESS(status)) { const char* cases[] = { "abc", "abcd", "abcde" }; uint32_t casesSize = sizeof(cases)/sizeof(cases[0]); const char* prefix = "foo"; const char* suffix = "egg"; char outBuff1[256], outBuff2[256]; uint8_t **sortkeys = (uint8_t **)malloc(casesSize*sizeof(uint8_t *)); uint8_t **mergedPrefixkeys = (uint8_t **)malloc(casesSize*sizeof(uint8_t *)); uint8_t **mergedSuffixkeys = (uint8_t **)malloc(casesSize*sizeof(uint8_t *)); uint32_t *sortKeysLen = (uint32_t *)malloc(casesSize*sizeof(uint32_t)); uint8_t prefixKey[256], suffixKey[256]; uint32_t prefixKeyLen = 0, suffixKeyLen = 0, i = 0; UChar buffer[256]; uint32_t unescapedLen = 0, l1 = 0, l2 = 0; UColAttributeValue strength; log_verbose("ucol_mergeSortkeys test\n"); log_verbose("Testing order of the test cases\n"); genericLocaleStarter("en", cases, casesSize); for(i = 0; i<casesSize; i++) { sortkeys[i] = (uint8_t *)malloc(256*sizeof(uint8_t)); mergedPrefixkeys[i] = (uint8_t *)malloc(256*sizeof(uint8_t)); mergedSuffixkeys[i] = (uint8_t *)malloc(256*sizeof(uint8_t)); } unescapedLen = u_unescape(prefix, buffer, 256); prefixKeyLen = ucol_getSortKey(coll, buffer, unescapedLen, prefixKey, 256); unescapedLen = u_unescape(suffix, buffer, 256); suffixKeyLen = ucol_getSortKey(coll, buffer, unescapedLen, suffixKey, 256); log_verbose("Massaging data with prefixes and different strengths\n"); strength = UCOL_PRIMARY; while(strength <= UCOL_IDENTICAL) { log_verbose("Strength %s\n", strengthsC[strength<=UCOL_QUATERNARY?strength:4]); ucol_setAttribute(coll, UCOL_STRENGTH, strength, &status); for(i = 0; i<casesSize; i++) { unescapedLen = u_unescape(cases[i], buffer, 256); sortKeysLen[i] = ucol_getSortKey(coll, buffer, unescapedLen, sortkeys[i], 256); ucol_mergeSortkeys(prefixKey, prefixKeyLen, sortkeys[i], sortKeysLen[i], mergedPrefixkeys[i], 256); ucol_mergeSortkeys(sortkeys[i], sortKeysLen[i], suffixKey, suffixKeyLen, mergedSuffixkeys[i], 256); if(i>0) { if(tMemCmp(mergedPrefixkeys[i-1], mergedPrefixkeys[i]) >= 0) { log_err("Error while comparing prefixed keys @ strength %s:\n", strengthsC[strength<=UCOL_QUATERNARY?strength:4]); log_err("%s\n%s\n", ucol_sortKeyToString(coll, mergedPrefixkeys[i-1], outBuff1, &l1), ucol_sortKeyToString(coll, mergedPrefixkeys[i], outBuff2, &l2)); } if(tMemCmp(mergedSuffixkeys[i-1], mergedSuffixkeys[i]) >= 0) { log_err("Error while comparing suffixed keys @ strength %s:\n", strengthsC[strength<=UCOL_QUATERNARY?strength:4]); log_err("%s\n%s\n", ucol_sortKeyToString(coll, mergedSuffixkeys[i-1], outBuff1, &l1), ucol_sortKeyToString(coll, mergedSuffixkeys[i], outBuff2, &l2)); } } } if(strength == UCOL_QUATERNARY) { strength = UCOL_IDENTICAL; } else { strength++; } } { uint8_t smallBuf[3]; uint32_t reqLen = 0; log_verbose("testing buffer overflow\n"); reqLen = ucol_mergeSortkeys(prefixKey, prefixKeyLen, suffixKey, suffixKeyLen, smallBuf, 3); if(reqLen != (prefixKeyLen+suffixKeyLen-1)) { log_err("Wrong preflight size for merged sortkey\n"); } } { UChar empty = 0; uint8_t emptyKey[20], abcKey[50], mergedKey[100]; int32_t emptyKeyLen = 0, abcKeyLen = 0, mergedKeyLen = 0; log_verbose("testing merging with sortkeys generated for empty strings\n"); emptyKeyLen = ucol_getSortKey(coll, &empty, 0, emptyKey, 20); unescapedLen = u_unescape(cases[0], buffer, 256); abcKeyLen = ucol_getSortKey(coll, buffer, unescapedLen, abcKey, 50); mergedKeyLen = ucol_mergeSortkeys(emptyKey, emptyKeyLen, abcKey, abcKeyLen, mergedKey, 100); if(mergedKey[0] != 2) { log_err("Empty sortkey didn't produce a level separator\n"); } /* try with zeros */ mergedKeyLen = ucol_mergeSortkeys(emptyKey, 0, abcKey, abcKeyLen, mergedKey, 100); if(mergedKeyLen != 0 || mergedKey[0] != 0) { log_err("Empty key didn't produce null mergedKey\n"); } mergedKeyLen = ucol_mergeSortkeys(abcKey, abcKeyLen, emptyKey, 0, mergedKey, 100); if(mergedKeyLen != 0 || mergedKey[0] != 0) { log_err("Empty key didn't produce null mergedKey\n"); } } for(i = 0; i<casesSize; i++) { free(sortkeys[i]); free(mergedPrefixkeys[i]); free(mergedSuffixkeys[i]); } free(sortkeys); free(mergedPrefixkeys); free(mergedSuffixkeys); free(sortKeysLen); ucol_close(coll); /* need to finish this up */ } else { log_data_err("Couldn't open collator"); } } static void TestShortString(void) { struct { const char *input; const char *expectedOutput; const char *locale; UErrorCode expectedStatus; int32_t expectedOffset; uint32_t expectedIdentifier; } testCases[] = { /* * The following expectedOutput contains a collation weight (2700 from UCA 6.0) * which is the primary weight for the T character (U+0041) in the input. * When that character gets a different weight in FractionalUCA.txt, * the expectedOutput needs to be adjusted. * That is, when we upgrade to a new UCA version or change collation * in such a way that the absolute weight for 'A' changes, * we will get a test failure here and need to adjust the test case. */ {"LDE_RDE_KPHONEBOOK_T0041_ZLATN","B2700_KPHONEBOOK_LDE", "de@collation=phonebook", U_USING_FALLBACK_WARNING, 0, 0 }, {"LEN_RUS_NO_AS_S4","AS_LROOT_NO_S4", NULL, U_USING_DEFAULT_WARNING, 0, 0 }, {"LDE_VPHONEBOOK_EO_SI","EO_KPHONEBOOK_LDE_SI", "de@collation=phonebook", U_ZERO_ERROR, 0, 0 }, {"LDE_Kphonebook","KPHONEBOOK_LDE", "de@collation=phonebook", U_ZERO_ERROR, 0, 0 }, {"Xqde_DE@collation=phonebookq_S3_EX","KPHONEBOOK_LDE", "de@collation=phonebook", U_USING_FALLBACK_WARNING, 0, 0 }, {"LFR_FO", "FO_LROOT", NULL, U_USING_DEFAULT_WARNING, 0, 0 }, {"SO_LX_AS", "", NULL, U_ILLEGAL_ARGUMENT_ERROR, 8, 0 }, {"S3_ASS_MMM", "", NULL, U_ILLEGAL_ARGUMENT_ERROR, 5, 0 } }; int32_t i = 0; UCollator *coll = NULL, *fromNormalized = NULL; UParseError parseError; UErrorCode status = U_ZERO_ERROR; char fromShortBuffer[256], normalizedBuffer[256], fromNormalizedBuffer[256]; const char* locale = NULL; for(i = 0; i < sizeof(testCases)/sizeof(testCases[0]); i++) { status = U_ZERO_ERROR; if(testCases[i].locale) { locale = testCases[i].locale; } else { locale = NULL; } coll = ucol_openFromShortString(testCases[i].input, FALSE, &parseError, &status); if(status != testCases[i].expectedStatus) { log_err_status(status, "Got status '%s' that is different from expected '%s' for '%s'\n", u_errorName(status), u_errorName(testCases[i].expectedStatus), testCases[i].input); continue; } if(U_SUCCESS(status)) { ucol_getShortDefinitionString(coll, locale, fromShortBuffer, 256, &status); if(strcmp(fromShortBuffer, testCases[i].expectedOutput)) { log_err("Got short string '%s' from the collator. Expected '%s' for input '%s'\n", fromShortBuffer, testCases[i].expectedOutput, testCases[i].input); } ucol_normalizeShortDefinitionString(testCases[i].input, normalizedBuffer, 256, &parseError, &status); fromNormalized = ucol_openFromShortString(normalizedBuffer, FALSE, &parseError, &status); ucol_getShortDefinitionString(fromNormalized, locale, fromNormalizedBuffer, 256, &status); if(strcmp(fromShortBuffer, fromNormalizedBuffer)) { log_err("Strings obtained from collators instantiated by short string ('%s') and from normalized string ('%s') differ\n", fromShortBuffer, fromNormalizedBuffer); } if(!ucol_equals(coll, fromNormalized)) { log_err("Collator from short string ('%s') differs from one obtained through a normalized version ('%s')\n", testCases[i].input, normalizedBuffer); } ucol_close(fromNormalized); ucol_close(coll); } else { if(parseError.offset != testCases[i].expectedOffset) { log_err("Got parse error offset %i, but expected %i instead for '%s'\n", parseError.offset, testCases[i].expectedOffset, testCases[i].input); } } } } static void doSetsTest(const char *locale, const USet *ref, USet *set, const char* inSet, const char* outSet, UErrorCode *status) { UChar buffer[512]; int32_t bufLen; uset_clear(set); bufLen = u_unescape(inSet, buffer, 512); uset_applyPattern(set, buffer, bufLen, 0, status); if(U_FAILURE(*status)) { log_err("%s: Failure setting pattern %s\n", locale, u_errorName(*status)); } if(!uset_containsAll(ref, set)) { log_err("%s: Some stuff from %s is not present in the set\n", locale, inSet); } uset_clear(set); bufLen = u_unescape(outSet, buffer, 512); uset_applyPattern(set, buffer, bufLen, 0, status); if(U_FAILURE(*status)) { log_err("%s: Failure setting pattern %s\n", locale, u_errorName(*status)); } if(!uset_containsNone(ref, set)) { log_err("%s: Some stuff from %s is present in the set\n", locale, outSet); } } static void TestGetContractionsAndUnsafes(void) { static struct { const char* locale; const char* inConts; const char* outConts; const char* inExp; const char* outExp; const char* unsafeCodeUnits; const char* safeCodeUnits; } tests[] = { { "ru", "[{\\u0418\\u0306}{\\u0438\\u0306}]", "[\\u0439\\u0457]", "[\\u00e6]", "[ae]", "[\\u0418\\u0438]", "[aAbB\\u0430\\u0410\\u0433\\u0413]" }, { "uk", "[{\\u0406\\u0308}{\\u0456\\u0308}{\\u0418\\u0306}{\\u0438\\u0306}]", "[\\u0407\\u0419\\u0439\\u0457]", "[\\u00e6]", "[ae]", "[\\u0406\\u0456\\u0418\\u0438]", "[aAbBxv]", }, { "sh", "[{C\\u0301}{C\\u030C}{C\\u0341}{DZ\\u030C}{Dz\\u030C}{D\\u017D}{D\\u017E}{lj}{nj}]", "[{\\u309d\\u3099}{\\u30fd\\u3099}]", "[\\u00e6]", "[a]", "[nlcdzNLCDZ]", "[jabv]" }, { "ja", "[{\\u3053\\u3099\\u309D}{\\u3053\\u3099\\u309D\\u3099}{\\u3053\\u3099\\u309E}{\\u3053\\u3099\\u30FC}{\\u3053\\u309D}{\\u3053\\u309D\\u3099}{\\u3053\\u309E}{\\u3053\\u30FC}{\\u30B3\\u3099\\u30FC}{\\u30B3\\u3099\\u30FD}{\\u30B3\\u3099\\u30FD\\u3099}{\\u30B3\\u3099\\u30FE}{\\u30B3\\u30FC}{\\u30B3\\u30FD}{\\u30B3\\u30FD\\u3099}{\\u30B3\\u30FE}]", "[{\\u30FD\\u3099}{\\u309D\\u3099}{\\u3053\\u3099}{\\u30B3\\u3099}{lj}{nj}]", "[\\u30FE\\u00e6]", "[a]", "[\\u3099]", "[]" } }; UErrorCode status = U_ZERO_ERROR; UCollator *coll = NULL; int32_t i = 0; int32_t noConts = 0; USet *conts = uset_open(0,0); USet *exp = uset_open(0, 0); USet *set = uset_open(0,0); int32_t setBufferLen = 65536; UChar buffer[65536]; int32_t setLen = 0; for(i = 0; i < sizeof(tests)/sizeof(tests[0]); i++) { log_verbose("Testing locale: %s\n", tests[i].locale); coll = ucol_open(tests[i].locale, &status); if (coll == NULL || U_FAILURE(status)) { log_err_status(status, "Unable to open collator for locale %s ==> %s\n", tests[i].locale, u_errorName(status)); continue; } ucol_getContractionsAndExpansions(coll, conts, exp, TRUE, &status); doSetsTest(tests[i].locale, conts, set, tests[i].inConts, tests[i].outConts, &status); setLen = uset_toPattern(conts, buffer, setBufferLen, TRUE, &status); if(U_SUCCESS(status)) { /*log_verbose("Contractions %i: %s\n", uset_getItemCount(conts), aescstrdup(buffer, setLen));*/ } else { log_err("error %s. %i\n", u_errorName(status), setLen); status = U_ZERO_ERROR; } doSetsTest(tests[i].locale, exp, set, tests[i].inExp, tests[i].outExp, &status); setLen = uset_toPattern(exp, buffer, setBufferLen, TRUE, &status); if(U_SUCCESS(status)) { /*log_verbose("Expansions %i: %s\n", uset_getItemCount(exp), aescstrdup(buffer, setLen));*/ } else { log_err("error %s. %i\n", u_errorName(status), setLen); status = U_ZERO_ERROR; } noConts = ucol_getUnsafeSet(coll, conts, &status); doSetsTest(tests[i].locale, conts, set, tests[i].unsafeCodeUnits, tests[i].safeCodeUnits, &status); setLen = uset_toPattern(conts, buffer, setBufferLen, TRUE, &status); if(U_SUCCESS(status)) { log_verbose("Unsafe %i: %s\n", uset_getItemCount(exp), aescstrdup(buffer, setLen)); } else { log_err("error %s. %i\n", u_errorName(status), setLen); status = U_ZERO_ERROR; } ucol_close(coll); } uset_close(conts); uset_close(exp); uset_close(set); } static void TestOpenBinary(void) { UErrorCode status = U_ZERO_ERROR; /* char rule[] = "&h < d < c < b"; char *wUCA[] = { "a", "h", "d", "c", "b", "i" }; char *noUCA[] = {"d", "c", "b", "a", "h", "i" }; */ /* we have to use Cyrillic letters because latin-1 always gets copied */ const char rule[] = "&\\u0452 < \\u0434 < \\u0433 < \\u0432"; /* &dje < d < g < v */ const char *wUCA[] = { "\\u0430", "\\u0452", "\\u0434", "\\u0433", "\\u0432", "\\u0435" }; /* a, dje, d, g, v, e */ const char *noUCA[] = {"\\u0434", "\\u0433", "\\u0432", "\\u0430", "\\u0435", "\\u0452" }; /* d, g, v, a, e, dje */ UChar uRules[256]; int32_t uRulesLen = u_unescape(rule, uRules, 256); UCollator *coll = ucol_openRules(uRules, uRulesLen, UCOL_DEFAULT, UCOL_DEFAULT, NULL, &status); UCollator *UCA = NULL; UCollator *cloneNOUCA = NULL, *cloneWUCA = NULL; uint8_t imageBuffer[32768]; uint8_t *image = imageBuffer; int32_t imageBufferCapacity = 32768; int32_t imageSize; if((coll==NULL)||(U_FAILURE(status))) { log_data_err("could not load collators or error occured: %s\n", u_errorName(status)); return; } UCA = ucol_open("root", &status); if((UCA==NULL)||(U_FAILURE(status))) { log_data_err("could not load UCA collator or error occured: %s\n", u_errorName(status)); return; } imageSize = ucol_cloneBinary(coll, image, imageBufferCapacity, &status); if(U_FAILURE(status)) { image = (uint8_t *)malloc(imageSize*sizeof(uint8_t)); status = U_ZERO_ERROR; imageSize = ucol_cloneBinary(coll, imageBuffer, imageSize, &status); } cloneWUCA = ucol_openBinary(image, imageSize, UCA, &status); cloneNOUCA = ucol_openBinary(image, imageSize, NULL, &status); genericOrderingTest(coll, wUCA, sizeof(wUCA)/sizeof(wUCA[0])); genericOrderingTest(cloneWUCA, wUCA, sizeof(wUCA)/sizeof(wUCA[0])); genericOrderingTest(cloneNOUCA, noUCA, sizeof(noUCA)/sizeof(noUCA[0])); if(image != imageBuffer) { free(image); } ucol_close(coll); ucol_close(cloneNOUCA); ucol_close(cloneWUCA); ucol_close(UCA); } static void TestDefault(void) { /* Tests for code coverage. */ UErrorCode status = U_ZERO_ERROR; UCollator *coll = ucol_open("es@collation=pinyin", &status); if (coll == NULL || status == U_FILE_ACCESS_ERROR) { log_data_err("Unable to open collator es@collation=pinyin\n"); return; } if (status != U_USING_DEFAULT_WARNING) { /* What do you mean that you know about using pinyin collation in Spanish!? This should be in the zh locale. */ log_err("es@collation=pinyin should return U_USING_DEFAULT_WARNING, but returned %s\n", u_errorName(status)); } ucol_close(coll); if (ucol_getKeywordValues("funky", &status) != NULL) { log_err("Collators should not know about the funky keyword.\n"); } if (status != U_ILLEGAL_ARGUMENT_ERROR) { log_err("funky keyword didn't fail as expected %s\n", u_errorName(status)); } if (ucol_getKeywordValues("collation", &status) != NULL) { log_err("ucol_getKeywordValues should not work when given a bad status.\n"); } } static void TestDefaultKeyword(void) { /* Tests for code coverage. */ UErrorCode status = U_ZERO_ERROR; const char *loc = "zh_TW@collation=default"; UCollator *coll = ucol_open(loc, &status); if(U_FAILURE(status)) { log_info("Warning: ucol_open(%s, ...) returned %s, at least it didn't crash.\n", loc, u_errorName(status)); } else if (status != U_USING_FALLBACK_WARNING) { /* Hmm, skip the following test for CLDR 1.9 data and/or ICU 4.6, no longer seems to apply */ #if 0 log_err("ucol_open(%s, ...) should return an error or some sort of U_USING_FALLBACK_WARNING, but returned %s\n", loc, u_errorName(status)); #endif } ucol_close(coll); } static void TestGetKeywordValuesForLocale(void) { #define INCLUDE_UNIHAN_COLLATION 0 #define PREFERRED_SIZE 16 #define MAX_NUMBER_OF_KEYWORDS 8 const char *PREFERRED[PREFERRED_SIZE][MAX_NUMBER_OF_KEYWORDS+1] = { { "und", "standard", "ducet", "search", NULL, NULL, NULL, NULL, NULL }, { "en_US", "standard", "ducet", "search", NULL, NULL, NULL, NULL, NULL }, { "en_029", "standard", "ducet", "search", NULL, NULL, NULL, NULL, NULL }, { "de_DE", "standard", "phonebook", "search", "ducet", NULL, NULL, NULL, NULL }, { "de_Latn_DE", "standard", "phonebook", "search", "ducet", NULL, NULL, NULL, NULL }, #if INCLUDE_UNIHAN_COLLATION { "zh", "pinyin", "big5han", "gb2312han", "standard", "stroke", "unihan", "ducet", "search" }, { "zh_Hans", "pinyin", "big5han", "gb2312han", "standard", "stroke", "unihan", "ducet", "search" }, { "zh_CN", "pinyin", "big5han", "gb2312han", "standard", "stroke", "unihan", "ducet", "search" }, { "zh_Hant", "stroke", "big5han", "gb2312han", "pinyin", "standard", "unihan", "ducet", "search" }, { "zh_TW", "stroke", "big5han", "gb2312han", "pinyin", "standard", "unihan", "ducet", "search" }, { "zh__PINYIN", "pinyin", "big5han", "gb2312han", "standard", "stroke", "unihan", "ducet", "search" }, #else { "zh", "pinyin", "big5han", "gb2312han", "standard", "stroke", "ducet", "search", NULL }, { "zh_Hans", "pinyin", "big5han", "gb2312han", "standard", "stroke", "ducet", "search", NULL }, { "zh_CN", "pinyin", "big5han", "gb2312han", "standard", "stroke", "ducet", "search", NULL }, { "zh_Hant", "stroke", "big5han", "gb2312han", "pinyin", "standard", "ducet", "search", NULL }, { "zh_TW", "stroke", "big5han", "gb2312han", "pinyin", "standard", "ducet", "search", NULL }, { "zh__PINYIN", "pinyin", "big5han", "gb2312han", "standard", "stroke", "ducet", "search", NULL }, #endif { "es_ES", "standard", "search", "traditional", "ducet", NULL, NULL, NULL, NULL }, { "es__TRADITIONAL","traditional", "search", "standard", "ducet", NULL, NULL, NULL, NULL }, { "und@collation=phonebook", "standard", "ducet", "search", NULL, NULL, NULL, NULL, NULL }, { "de_DE@collation=big5han", "standard", "phonebook", "search", "ducet", NULL, NULL, NULL, NULL }, { "zzz@collation=xxx", "standard", "ducet", "search", NULL, NULL, NULL, NULL, NULL } }; #if INCLUDE_UNIHAN_COLLATION const int32_t expectedLength[PREFERRED_SIZE] = { 3, 3, 3, 4, 4, 8, 8, 8, 8, 8, 8, 4, 4, 3, 4, 3 }; #else const int32_t expectedLength[PREFERRED_SIZE] = { 3, 3, 3, 4, 4, 7, 7, 7, 7, 7, 7, 4, 4, 3, 4, 3 }; #endif UErrorCode status = U_ZERO_ERROR; UEnumeration *keywordValues = NULL; int32_t i, n, size, valueLength; const char *locale = NULL, *value = NULL; UBool errorOccurred = FALSE; for (i = 0; i < PREFERRED_SIZE; i++) { locale = PREFERRED[i][0]; value = NULL; valueLength = 0; size = 0; keywordValues = ucol_getKeywordValuesForLocale("collation", locale, TRUE, &status); if (keywordValues == NULL || U_FAILURE(status)) { log_err_status(status, "Error getting keyword values: %s\n", u_errorName(status)); break; } size = uenum_count(keywordValues, &status); if (size == expectedLength[i]) { for (n = 0; n < expectedLength[i]; n++) { if ((value = uenum_next(keywordValues, &valueLength, &status)) != NULL && U_SUCCESS(status)) { if (uprv_strcmp(value, PREFERRED[i][n+1]) != 0) { log_err("Keyword values differ: Got [%s] Expected [%s] for locale: %s\n", value, PREFERRED[i][n+1], locale); errorOccurred = TRUE; break; } } else { log_err("While getting keyword value from locale: %s got this error: %s\n", locale, u_errorName(status)); errorOccurred = TRUE; break; } } if (errorOccurred) { break; } } else { log_err("Number of keywords (%d) does not match expected size (%d) for locale: %s\n", size, expectedLength[i], locale); break; } uenum_close(keywordValues); keywordValues = NULL; } if (keywordValues != NULL) { uenum_close(keywordValues); } } #endif /* #if !UCONFIG_NO_COLLATION */