#include "unicode/utypes.h"
#if !UCONFIG_NO_COLLATION
#include <stdio.h>
#include <stdlib.h>
#include <string.h>
#include "unicode/uloc.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"
static void TestAttribute(void);
static void TestDefault(void);
int TestBufferSize();
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) {
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++);
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;
}
void addCollAPITest(TestNode** root)
{
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, &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");
addTest(root, &TestGetContractionsAndUnsafes, "tscoll/capitst/TestGetContractionsAndUnsafes");
addTest(root, &TestOpenBinary, "tscoll/capitst/TestOpenBinary");
addTest(root, &TestDefault, "tscoll/capitst/TestDefault");
}
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},
{UCOL_CASE_FIRST, {UCOL_OFF, UCOL_LOWER_FIRST, UCOL_UPPER_FIRST}, 3, UCOL_SHIFTED},
{UCOL_CASE_LEVEL, {UCOL_ON, UCOL_OFF}, 2, UCOL_SHIFTED},
{UCOL_NORMALIZATION_MODE, {UCOL_ON, UCOL_OFF}, 2, UCOL_SHIFTED},
{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},
{UCOL_HIRAGANA_QUATERNARY_MODE, {UCOL_ON, UCOL_OFF}, 2, UCOL_SHIFTED},
};
UColAttribute currAttr;
UColAttributeValue value;
uint32_t i = 0, j = 0;
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("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
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
void TestProperty()
{
UCollator *col, *ruled;
UChar *disName;
int32_t len = 0, i = 0;
UChar *source, *target;
int32_t tempLength;
UErrorCode status = U_ZERO_ERROR;
UVersionInfo currVersionArray = {0x31, 0xC0, 0x00, 0x05};
UVersionInfo currUCAVersionArray = {5, 1, 0, 0};
UVersionInfo versionArray = {0, 0, 0, 0};
UVersionInfo versionUCAArray = {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("Default Collator creation failed.: %s\n", myErrorName(status));
return;
}
ucol_getVersion(col, versionArray);
for (i=0; i<4; ++i) {
if (versionArray[i] != currVersionArray[i]) {
log_err("Testing ucol_getVersion() - unexpected result: %hu.%hu.%hu.%hu\n",
versionArray[0], versionArray[1], versionArray[2], versionArray[3]);
break;
}
}
ucol_getUCAVersion(col, versionUCAArray);
for (i=0; i<4; ++i) {
if (versionUCAArray[i] != currUCAVersionArray[i]) {
log_err("Testing ucol_getUCAVersion() - unexpected result: %hu.%hu.%hu.%hu\n",
versionUCAArray[0], versionUCAArray[1], versionUCAArray[2], versionUCAArray[3]);
break;
}
}
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(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");
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 == 0x0a, "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);
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");
}
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("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);
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) {
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);
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("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);
}
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("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;
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);
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;
}
if (0 != ucol_safeClone(someCollators[0], buffer[0], &bufferSize, 0))
{
log_err("FAIL: Cloned Collator failed to deal correctly with null status\n");
}
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;
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;
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");
}
if (U_COL_SAFECLONE_BUFFERSIZE < bufferSize)
{
log_err("FAIL: Pre-calculated buffer size is too small\n");
}
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);
--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;
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;
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;
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;
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);
}
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\"");
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;
}
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};
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);
}
void TestSortKey()
{
uint8_t *sortk1 = NULL, *sortk2 = NULL, *sortk3 = NULL, *sortkEmpty = NULL;
uint8_t sortk2_compat[] = {
0x2c, 0x2e, 0x30, 0x32, 0x2c, 0x01,
0x09, 0x01, 0x09, 0x01, 0x2b, 0x01,
0x92, 0x93, 0x94, 0x95, 0x92, 0x0
};
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");
col = ucol_open("en_US", &status);
if (U_FAILURE(status)) {
log_err("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");
}
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\"");
doAssert( (memcmp(sortk2, sortk2_compat, sortklen) == 0), "Binary format for 'abcda' sortkey different!");
resultP = ucol_sortKeyToString(col, sortk2_compat, toStringBuffer, &toStringLen);
doAssert( (resultP != 0), "sortKeyToString failed!");
#if 1
{
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("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);
}
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("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;
}
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;
static const struct {
const char* requestedLocale;
const char* validLocale;
const char* actualLocale;
} testStruct[] = {
{ "sr_RS", "sr_Cyrl_RS", "ru" },
{ "sh_YU", "sr_Latn_RS", "hr" },
{ "en_BE_FOO", "en_BE", "en_BE" },
{ "fr_FR_NONEXISTANT", "fr_FR", "fr" }
};
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("Failed to open collator for %s with %s\n", testStruct[i].requestedLocale, u_errorName(status));
ucol_close(coll);
continue;
}
locale = ucol_getLocale(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_getLocale(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_getLocale(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);
}
{
UCollator *defaultColl = ucol_open(NULL, &status);
coll = ucol_open("blahaha", &status);
if(U_SUCCESS(status)) {
if(strcmp(ucol_getLocale(coll, ULOC_REQUESTED_LOCALE, &status), "blahaha")) {
log_err("Nonexisting locale didn't preserve the requested locale\n");
}
if(strcmp(ucol_getLocale(coll, ULOC_VALID_LOCALE, &status),
ucol_getLocale(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_getLocale(coll, ULOC_ACTUAL_LOCALE, &status),
ucol_getLocale(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");
}
}
coll = ucol_openRules(rlz, rlzLen, UCOL_DEFAULT, UCOL_DEFAULT, NULL, &status);
locale = ucol_getLocale(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_getLocale(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_getLocale(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();
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;
}
}
}
}
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("Creation of default collator failed");
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("Setting and retrieving of the french collation failed");
}
ucol_setAttribute(coll, UCOL_FRENCH_COLLATION, UCOL_ON, &error);
if (ucol_getAttribute(coll, UCOL_FRENCH_COLLATION, &error) != UCOL_ON ||
U_FAILURE(error)) {
log_err("Setting and retrieving of the french collation failed");
}
ucol_setAttribute(coll, UCOL_ALTERNATE_HANDLING, UCOL_SHIFTED, &error);
if (ucol_getAttribute(coll, UCOL_ALTERNATE_HANDLING, &error) != UCOL_SHIFTED ||
U_FAILURE(error)) {
log_err("Setting and retrieving of the alternate handling failed");
}
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("Setting and retrieving of the alternate handling failed");
}
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("Setting and retrieving of the case first attribute failed");
}
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("Setting and retrieving of the case first attribute failed");
}
ucol_setAttribute(coll, UCOL_CASE_LEVEL, UCOL_ON, &error);
if (ucol_getAttribute(coll, UCOL_CASE_LEVEL, &error) != UCOL_ON ||
U_FAILURE(error)) {
log_err("Setting and retrieving of the case level attribute failed");
}
ucol_setAttribute(coll, UCOL_CASE_LEVEL, UCOL_OFF, &error);
if (ucol_getAttribute(coll, UCOL_CASE_LEVEL, &error) != UCOL_OFF ||
U_FAILURE(error)) {
log_err("Setting and retrieving of the case level attribute failed");
}
ucol_setAttribute(coll, UCOL_NORMALIZATION_MODE, UCOL_ON, &error);
if (ucol_getAttribute(coll, UCOL_NORMALIZATION_MODE, &error) != UCOL_ON ||
U_FAILURE(error)) {
log_err("Setting and retrieving of the normalization on/off attribute failed");
}
ucol_setAttribute(coll, UCOL_NORMALIZATION_MODE, UCOL_OFF, &error);
if (ucol_getAttribute(coll, UCOL_NORMALIZATION_MODE, &error) != UCOL_OFF ||
U_FAILURE(error)) {
log_err("Setting and retrieving of the normalization on/off attribute failed");
}
ucol_setAttribute(coll, UCOL_STRENGTH, UCOL_PRIMARY, &error);
if (ucol_getAttribute(coll, UCOL_STRENGTH, &error) != UCOL_PRIMARY ||
U_FAILURE(error)) {
log_err("Setting and retrieving of the collation strength failed");
}
ucol_setAttribute(coll, UCOL_STRENGTH, UCOL_SECONDARY, &error);
if (ucol_getAttribute(coll, UCOL_STRENGTH, &error) != UCOL_SECONDARY ||
U_FAILURE(error)) {
log_err("Setting and retrieving of the collation strength failed");
}
ucol_setAttribute(coll, UCOL_STRENGTH, UCOL_TERTIARY, &error);
if (ucol_getAttribute(coll, UCOL_STRENGTH, &error) != UCOL_TERTIARY ||
U_FAILURE(error)) {
log_err("Setting and retrieving of the collation strength failed");
}
ucol_setAttribute(coll, UCOL_STRENGTH, UCOL_QUATERNARY, &error);
if (ucol_getAttribute(coll, UCOL_STRENGTH, &error) != UCOL_QUATERNARY ||
U_FAILURE(error)) {
log_err("Setting and retrieving of the collation strength failed");
}
ucol_setAttribute(coll, UCOL_STRENGTH, UCOL_IDENTICAL, &error);
if (ucol_getAttribute(coll, UCOL_STRENGTH, &error) != UCOL_IDENTICAL ||
U_FAILURE(error)) {
log_err("Setting and retrieving of the collation strength failed");
}
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("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");
}
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);
} 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[] = {
{"LDE_RDE_KPHONEBOOK_T0041_ZLATN","B2C00_KPHONEBOOK_LDE", "de@collation=phonebook", U_USING_FALLBACK_WARNING, 0, 0 },
{"LEN_RUS_NO_AS_S4","AS_LEN_NO_S4", NULL, U_USING_FALLBACK_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", "LFR", NULL, U_ZERO_ERROR, 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("Got status '%s' that is different from expected '%s' for '%s'\n",
u_errorName(status), u_errorName(testCases[i].expectedStatus), testCases[i].input);
}
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",
"[{\\u0474\\u030F}{\\u0475\\u030F}{\\u04D8\\u0308}{\\u04D9\\u0308}{\\u04E8\\u0308}{\\u04E9\\u0308}]",
"[{\\u0430\\u0306}{\\u0410\\u0306}{\\u0430\\u0308}{\\u0410\\u0306}{\\u0433\\u0301}{\\u0413\\u0301}]",
"[\\u00e6]",
"[a]",
"[\\u0474\\u0475\\u04d8\\u04d9\\u04e8\\u04e9]",
"[aAbB\\u0430\\u0410\\u0433\\u0413]"
},
{ "uk",
"[{\\u0474\\u030F}{\\u0475\\u030F}{\\u04D8\\u0308}{\\u04D9\\u0308}{\\u04E8\\u0308}{\\u04E9\\u0308}"
"{\\u0430\\u0306}{\\u0410\\u0306}{\\u0430\\u0308}{\\u0410\\u0306}{\\u0433\\u0301}{\\u0413\\u0301}]",
"[]",
"[\\u00e6]",
"[a]",
"[\\u0474\\u0475\\u04D8\\u04D9\\u04E8\\u04E9\\u0430\\u0410\\u0433\\u0413]",
"[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);
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)) {
} 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)) {
} 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;
const char rule[] = "&\\u0452 < \\u0434 < \\u0433 < \\u0432";
const char *wUCA[] = { "\\u0430", "\\u0452", "\\u0434", "\\u0433", "\\u0432", "\\u0435" };
const char *noUCA[] = {"\\u0434", "\\u0433", "\\u0432", "\\u0430", "\\u0435", "\\u0452" };
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) {
UErrorCode status = U_ZERO_ERROR;
UCollator *coll = ucol_open("es@collation=pinyin", &status);
if (status != U_USING_DEFAULT_WARNING) {
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");
}
}
#endif