/* ******************************************************************************* * Copyright (C) 1997-2009, International Business Machines * Corporation and others. All Rights Reserved. ******************************************************************************* * Date Name Description * 06/23/00 aliu Creation. ******************************************************************************* */ #include "unicode/utypes.h" #if !UCONFIG_NO_TRANSLITERATION #include #include #include "unicode/utrans.h" #include "unicode/ustring.h" #include "cintltst.h" #define TEST(x) addTest(root, &x, "utrans/" # x) static void TestAPI(void); static void TestSimpleRules(void); static void TestFilter(void); static void TestOpenInverse(void); static void TestClone(void); static void TestRegisterUnregister(void); static void TestExtractBetween(void); static void TestUnicodeIDs(void); static void _expectRules(const char*, const char*, const char*); static void _expect(const UTransliterator* trans, const char* cfrom, const char* cto); void addUTransTest(TestNode** root); void addUTransTest(TestNode** root) { TEST(TestAPI); TEST(TestSimpleRules); TEST(TestFilter); TEST(TestOpenInverse); TEST(TestClone); TEST(TestRegisterUnregister); TEST(TestExtractBetween); TEST(TestUnicodeIDs); } /*------------------------------------------------------------------ * Replaceable glue * * To test the Replaceable glue we have to dummy up a C-based * Replaceable callback. This code is for testing purposes only. *------------------------------------------------------------------*/ typedef struct XReplaceable { UChar* text; /* MUST BE null-terminated */ } XReplaceable; static void InitXReplaceable(XReplaceable* rep, const char* cstring) { rep->text = malloc(sizeof(UChar) * (strlen(cstring)+1)); u_uastrcpy(rep->text, cstring); } static void FreeXReplaceable(XReplaceable* rep) { if (rep->text != NULL) { free(rep->text); rep->text = NULL; } } /* UReplaceableCallbacks callback */ static int32_t Xlength(const UReplaceable* rep) { const XReplaceable* x = (const XReplaceable*)rep; return u_strlen(x->text); } /* UReplaceableCallbacks callback */ static UChar XcharAt(const UReplaceable* rep, int32_t offset) { const XReplaceable* x = (const XReplaceable*)rep; return x->text[offset]; } /* UReplaceableCallbacks callback */ static UChar32 Xchar32At(const UReplaceable* rep, int32_t offset) { const XReplaceable* x = (const XReplaceable*)rep; return x->text[offset]; } /* UReplaceableCallbacks callback */ static void Xreplace(UReplaceable* rep, int32_t start, int32_t limit, const UChar* text, int32_t textLength) { XReplaceable* x = (XReplaceable*)rep; int32_t newLen = Xlength(rep) + limit - start + textLength; UChar* newText = (UChar*) malloc(sizeof(UChar) * (newLen+1)); u_strncpy(newText, x->text, start); u_strncpy(newText + start, text, textLength); u_strcpy(newText + start + textLength, x->text + limit); free(x->text); x->text = newText; } /* UReplaceableCallbacks callback */ static void Xcopy(UReplaceable* rep, int32_t start, int32_t limit, int32_t dest) { XReplaceable* x = (XReplaceable*)rep; int32_t newLen = Xlength(rep) + limit - start; UChar* newText = (UChar*) malloc(sizeof(UChar) * (newLen+1)); u_strncpy(newText, x->text, dest); u_strncpy(newText + dest, x->text + start, limit - start); u_strcpy(newText + dest + limit - start, x->text + dest); free(x->text); x->text = newText; } /* UReplaceableCallbacks callback */ static void Xextract(UReplaceable* rep, int32_t start, int32_t limit, UChar* dst) { XReplaceable* x = (XReplaceable*)rep; int32_t len = limit - start; u_strncpy(dst, x->text, len); } static void InitXReplaceableCallbacks(UReplaceableCallbacks* callbacks) { callbacks->length = Xlength; callbacks->charAt = XcharAt; callbacks->char32At = Xchar32At; callbacks->replace = Xreplace; callbacks->extract = Xextract; callbacks->copy = Xcopy; } /*------------------------------------------------------------------ * Tests *------------------------------------------------------------------*/ static void TestAPI() { enum { BUF_CAP = 128 }; char buf[BUF_CAP], buf2[BUF_CAP]; UErrorCode status = U_ZERO_ERROR; UTransliterator* trans = NULL; int32_t i, n; /* Test getAvailableIDs */ n = utrans_countAvailableIDs(); if (n < 1) { log_err("FAIL: utrans_countAvailableIDs() returned %d\n", n); } else { log_verbose("System ID count: %d\n", n); } for (i=0; i10) { /* try to actually open only a few transliterators */ continue; } utrans=utrans_openU(id, idLength, UTRANS_FORWARD, NULL, 0, NULL, &errorCode); if(U_FAILURE(errorCode)) { log_err("utrans_openU(%s) failed - %s\n", aescstrdup(id, idLength), u_errorName(errorCode)); continue; } id2=utrans_getUnicodeID(utrans, &id2Length); if(idLength!=id2Length || 0!=u_memcmp(id, id2, idLength)) { log_err("utrans_getUnicodeID(%s) does not match the original ID\n", aescstrdup(id, idLength)); } utrans_close(utrans); } uenum_reset(uenum, &errorCode); if(U_FAILURE(errorCode) || count<1) { log_err("uenum_reset(transliterator IDs) failed - %s\n", u_errorName(errorCode)); } else { count2=uenum_count(uenum, &errorCode); if(U_FAILURE(errorCode) || count<1) { log_err("2nd uenum_count(transliterator IDs)=%d - %s\n", count2, u_errorName(errorCode)); } else if(count!=count2) { log_err("uenum_unext(transliterator IDs) returned %d IDs but uenum_count() after uenum_reset() claims there are %d\n", count, count2); } } uenum_close(uenum); } static void TestOpenInverse(){ UErrorCode status=U_ZERO_ERROR; UTransliterator* t1=NULL; UTransliterator* inverse1=NULL; enum { BUF_CAP = 128 }; char buf1[BUF_CAP]; int32_t i=0; const char TransID[][25]={ "Halfwidth-Fullwidth", "Fullwidth-Halfwidth", "Greek-Latin" , "Latin-Greek", /*"Arabic-Latin", // Removed in 2.0*/ /*"Latin-Arabic", // Removed in 2.0*/ "Katakana-Latin", "Latin-Katakana", /*"Hebrew-Latin", // Removed in 2.0*/ /*"Latin-Hebrew", // Removed in 2.0*/ "Cyrillic-Latin", "Latin-Cyrillic", "Devanagari-Latin", "Latin-Devanagari", "Any-Hex", "Hex-Any" }; for(i=0; i %s (Are you missing data?)\n", TransID[i], u_errorName(status)); continue; } inverse1=utrans_openInverse(t1, &status); if(U_FAILURE(status)){ log_err("FAIL: utrans_openInverse() failed for id=%s. Error=%s\n", TransID[i], myErrorName(status)); continue; } utrans_getID(inverse1, buf1, BUF_CAP); if(strcmp(buf1, TransID[i+1]) != 0){ log_err("FAIL :openInverse() for %s returned %s instead of %s\n", TransID[i], buf1, TransID[i+1]); } utrans_close(t1); utrans_close(inverse1); } } static void TestClone(){ UErrorCode status=U_ZERO_ERROR; UTransliterator* t1=NULL; UTransliterator* t2=NULL; UTransliterator* t3=NULL; UTransliterator* t4=NULL; enum { BUF_CAP = 128 }; char buf1[BUF_CAP], buf2[BUF_CAP], buf3[BUF_CAP]; t1=utrans_open("Latin-Devanagari", UTRANS_FORWARD, NULL,0,NULL,&status); if(U_FAILURE(status)){ log_data_err("FAIL: construction -> %s (Are you missing data?)\n", u_errorName(status)); return; } t2=utrans_open("Latin-Greek", UTRANS_FORWARD, NULL,0,NULL,&status); if(U_FAILURE(status)){ log_err("FAIL: construction\n"); utrans_close(t1); return; } t3=utrans_clone(t1, &status); t4=utrans_clone(t2, &status); utrans_getID(t1, buf1, BUF_CAP); utrans_getID(t2, buf2, BUF_CAP); utrans_getID(t3, buf3, BUF_CAP); if(strcmp(buf1, buf3) != 0 || strcmp(buf1, buf2) == 0) { log_err("FAIL: utrans_clone() failed\n"); } utrans_getID(t4, buf3, BUF_CAP); if(strcmp(buf2, buf3) != 0 || strcmp(buf1, buf3) == 0) { log_err("FAIL: utrans_clone() failed\n"); } utrans_close(t1); utrans_close(t2); utrans_close(t3); utrans_close(t4); } static void TestRegisterUnregister(){ UErrorCode status=U_ZERO_ERROR; UTransliterator* t1=NULL; UTransliterator* rules=NULL, *rules2; UTransliterator* inverse1=NULL; UChar rule[]={ 0x0061, 0x003c, 0x003e, 0x0063}; /*a<>b*/ U_STRING_DECL(ID, "TestA-TestB", 11); U_STRING_INIT(ID, "TestA-TestB", 11); /* Make sure it doesn't exist */ t1=utrans_open("TestA-TestB", UTRANS_FORWARD,NULL,0,NULL, &status); if(t1 != NULL || U_SUCCESS(status)) { log_err("FAIL: TestA-TestB already registered\n"); return; } status=U_ZERO_ERROR; /* Check inverse too */ inverse1=utrans_open("TestA-TestB", UTRANS_REVERSE, NULL,0,NULL,&status); if(inverse1 != NULL || U_SUCCESS(status)) { log_err("FAIL: TestA-TestB already registered\n"); return; } status=U_ZERO_ERROR; /* Create it */ rules=utrans_open("TestA-TestB",UTRANS_FORWARD, rule, 4, NULL, &status); if(U_FAILURE(status)){ log_err("FAIL: utrans_openRules(a<>B) failed with error=%s\n", myErrorName(status)); return; } /* clone it so we can register it a second time */ rules2=utrans_clone(rules, &status); if(U_FAILURE(status)) { log_err("FAIL: utrans_clone(a<>B) failed with error=%s\n", myErrorName(status)); return; } status=U_ZERO_ERROR; /* Register it */ utrans_register(rules, &status); if(U_FAILURE(status)){ log_err("FAIL: utrans_register failed with error=%s\n", myErrorName(status)); return; } status=U_ZERO_ERROR; /* Now check again -- should exist now*/ t1= utrans_open("TestA-TestB", UTRANS_FORWARD, NULL,0,NULL,&status); if(U_FAILURE(status) || t1 == NULL){ log_err("FAIL: TestA-TestB not registered\n"); return; } utrans_close(t1); /*unregister the instance*/ status=U_ZERO_ERROR; utrans_unregister("TestA-TestB"); /* now Make sure it doesn't exist */ t1=utrans_open("TestA-TestB", UTRANS_FORWARD,NULL,0,NULL, &status); if(U_SUCCESS(status) || t1 != NULL) { log_err("FAIL: TestA-TestB isn't unregistered\n"); return; } utrans_close(t1); /* now with utrans_unregisterID(const UChar *) */ status=U_ZERO_ERROR; utrans_register(rules2, &status); if(U_FAILURE(status)){ log_err("FAIL: 2nd utrans_register failed with error=%s\n", myErrorName(status)); return; } status=U_ZERO_ERROR; /* Now check again -- should exist now*/ t1= utrans_open("TestA-TestB", UTRANS_FORWARD, NULL,0,NULL,&status); if(U_FAILURE(status) || t1 == NULL){ log_err("FAIL: 2nd TestA-TestB not registered\n"); return; } utrans_close(t1); /*unregister the instance*/ status=U_ZERO_ERROR; utrans_unregisterID(ID, -1); /* now Make sure it doesn't exist */ t1=utrans_openU(ID, -1, UTRANS_FORWARD,NULL,0,NULL, &status); if(U_SUCCESS(status) || t1 != NULL) { log_err("FAIL: 2nd TestA-TestB isn't unregistered\n"); return; } utrans_close(t1); utrans_close(inverse1); } static void TestSimpleRules() { /* Test rules */ /* Example: rules 1. ab>x|y * 2. yc>z * * []|eabcd start - no match, copy e to tranlated buffer * [e]|abcd match rule 1 - copy output & adjust cursor * [ex|y]cd match rule 2 - copy output & adjust cursor * [exz]|d no match, copy d to transliterated buffer * [exzd]| done */ _expectRules("ab>x|y;" "yc>z", "eabcd", "exzd"); /* Another set of rules: * 1. ab>x|yzacw * 2. za>q * 3. qc>r * 4. cw>n * * []|ab Rule 1 * [x|yzacw] No match * [xy|zacw] Rule 2 * [xyq|cw] Rule 4 * [xyqn]| Done */ _expectRules("ab>x|yzacw;" "za>q;" "qc>r;" "cw>n", "ab", "xyqn"); /* Test categories */ _expectRules("$dummy=" "\\uE100" ";" /* careful here with E100 */ "$vowel=[aeiouAEIOU];" "$lu=[:Lu:];" "$vowel } $lu > '!';" "$vowel > '&';" "'!' { $lu > '^';" "$lu > '*';" "a > ERROR", "abcdefgABCDEFGU", "&bcd&fg!^**!^*&"); /* Test multiple passes */ _expectRules("abc > xy;" "::Null;" "aba > z;", "abc ababc aba", "xy abxy z"); } static void TestFilter() { UErrorCode status = U_ZERO_ERROR; UChar filt[128]; UChar buf[128]; UChar exp[128]; char *cbuf; int32_t limit; const char* DATA[] = { "[^c]", /* Filter out 'c' */ "abcde", "\\u0061\\u0062c\\u0064\\u0065", "", /* No filter */ "abcde", "\\u0061\\u0062\\u0063\\u0064\\u0065" }; int32_t DATA_length = sizeof(DATA) / sizeof(DATA[0]); int32_t i; UTransliterator* hex = utrans_open("Any-Hex", UTRANS_FORWARD, NULL,0,NULL,&status); if (hex == 0 || U_FAILURE(status)) { log_err("FAIL: utrans_open(Unicode-Hex) failed, error=%s\n", u_errorName(status)); goto exit; } for (i=0; i %s\n", DATA[i+1], DATA[i], cbuf); } else { log_err("FAIL: %s | %s -> %s, expected %s\n", DATA[i+1], DATA[i], cbuf, DATA[i+2]); } } exit: utrans_close(hex); } /** * Test the UReplaceableCallback extractBetween support. We use a * transliterator known to rely on this call. */ static void TestExtractBetween() { UTransliterator *trans; UErrorCode status = U_ZERO_ERROR; UParseError parseErr; trans = utrans_open("Lower", UTRANS_FORWARD, NULL, -1, &parseErr, &status); if (U_FAILURE(status)) { log_err("FAIL: utrans_open(Lower) failed, error=%s\n", u_errorName(status)); } else { _expect(trans, "ABC", "abc"); utrans_close(trans); } } static void _expectRules(const char* crules, const char* cfrom, const char* cto) { /* u_uastrcpy has no capacity param for the buffer -- so just * make all buffers way too big */ enum { CAP = 256 }; UChar rules[CAP]; UTransliterator *trans; UErrorCode status = U_ZERO_ERROR; UParseError parseErr; u_uastrcpy(rules, crules); trans = utrans_open(crules /*use rules as ID*/, UTRANS_FORWARD, rules, -1, &parseErr, &status); if (U_FAILURE(status)) { utrans_close(trans); log_data_err("FAIL: utrans_openRules(%s) failed, error=%s (Are you missing data?)\n", crules, u_errorName(status)); return; } _expect(trans, cfrom, cto); utrans_close(trans); } static void _expect(const UTransliterator* trans, const char* cfrom, const char* cto) { /* u_uastrcpy has no capacity param for the buffer -- so just * make all buffers way too big */ enum { CAP = 256 }; UChar from[CAP]; UChar to[CAP]; UChar buf[CAP]; const UChar *ID; int32_t IDLength; const char *id; UErrorCode status = U_ZERO_ERROR; int32_t limit; UTransPosition pos; XReplaceable xrep; XReplaceable *xrepPtr = &xrep; UReplaceableCallbacks xrepVtable; u_uastrcpy(from, cfrom); u_uastrcpy(to, cto); ID = utrans_getUnicodeID(trans, &IDLength); id = aescstrdup(ID, IDLength); /* utrans_transUChars() */ u_strcpy(buf, from); limit = u_strlen(buf); utrans_transUChars(trans, buf, NULL, CAP, 0, &limit, &status); if (U_FAILURE(status)) { log_err("FAIL: utrans_transUChars() failed, error=%s\n", u_errorName(status)); return; } if (0 == u_strcmp(buf, to)) { log_verbose("Ok: utrans_transUChars(%s) x %s -> %s\n", id, cfrom, cto); } else { char actual[CAP]; u_austrcpy(actual, buf); log_err("FAIL: utrans_transUChars(%s) x %s -> %s, expected %s\n", id, cfrom, actual, cto); } /* utrans_transIncrementalUChars() */ u_strcpy(buf, from); pos.start = pos.contextStart = 0; pos.limit = pos.contextLimit = u_strlen(buf); utrans_transIncrementalUChars(trans, buf, NULL, CAP, &pos, &status); utrans_transUChars(trans, buf, NULL, CAP, pos.start, &pos.limit, &status); if (U_FAILURE(status)) { log_err("FAIL: utrans_transIncrementalUChars() failed, error=%s\n", u_errorName(status)); return; } if (0 == u_strcmp(buf, to)) { log_verbose("Ok: utrans_transIncrementalUChars(%s) x %s -> %s\n", id, cfrom, cto); } else { char actual[CAP]; u_austrcpy(actual, buf); log_err("FAIL: utrans_transIncrementalUChars(%s) x %s -> %s, expected %s\n", id, cfrom, actual, cto); } /* utrans_trans() */ InitXReplaceableCallbacks(&xrepVtable); InitXReplaceable(&xrep, cfrom); limit = u_strlen(from); utrans_trans(trans, (UReplaceable*)xrepPtr, &xrepVtable, 0, &limit, &status); if (U_FAILURE(status)) { log_err("FAIL: utrans_trans() failed, error=%s\n", u_errorName(status)); FreeXReplaceable(&xrep); return; } if (0 == u_strcmp(xrep.text, to)) { log_verbose("Ok: utrans_trans(%s) x %s -> %s\n", id, cfrom, cto); } else { char actual[CAP]; u_austrcpy(actual, xrep.text); log_err("FAIL: utrans_trans(%s) x %s -> %s, expected %s\n", id, cfrom, actual, cto); } FreeXReplaceable(&xrep); /* utrans_transIncremental() */ InitXReplaceable(&xrep, cfrom); pos.start = pos.contextStart = 0; pos.limit = pos.contextLimit = u_strlen(from); utrans_transIncremental(trans, (UReplaceable*)xrepPtr, &xrepVtable, &pos, &status); utrans_trans(trans, (UReplaceable*)xrepPtr, &xrepVtable, pos.start, &pos.limit, &status); if (U_FAILURE(status)) { log_err("FAIL: utrans_transIncremental() failed, error=%s\n", u_errorName(status)); FreeXReplaceable(&xrep); return; } if (0 == u_strcmp(xrep.text, to)) { log_verbose("Ok: utrans_transIncremental(%s) x %s -> %s\n", id, cfrom, cto); } else { char actual[CAP]; u_austrcpy(actual, xrep.text); log_err("FAIL: utrans_transIncremental(%s) x %s -> %s, expected %s\n", id, cfrom, actual, cto); } FreeXReplaceable(&xrep); } #endif /* #if !UCONFIG_NO_TRANSLITERATION */