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// © 2016 and later: Unicode, Inc. and others.
// License & terms of use: http://www.unicode.org/copyright.html
/*
*******************************************************************************
* Copyright (C) 2010-2014, International Business Machines
* Corporation and others. All Rights Reserved.
*******************************************************************************
* file name: uts46test.cpp
* encoding: UTF-8
* tab size: 8 (not used)
* indentation:4
*
* created on: 2010may05
* created by: Markus W. Scherer
*/
#include "unicode/utypes.h"
#if !UCONFIG_NO_IDNA
#include <string.h>
#include "unicode/bytestream.h"
#include "unicode/idna.h"
#include "unicode/localpointer.h"
#include "unicode/std_string.h"
#include "unicode/stringpiece.h"
#include "unicode/uidna.h"
#include "unicode/unistr.h"
#include "charstr.h"
#include "cmemory.h"
#include "intltest.h"
#include "punycode.h"
#include "uparse.h"
class UTS46Test : public IntlTest {
public:
UTS46Test() : trans(NULL), nontrans(NULL) {}
virtual ~UTS46Test();
void runIndexedTest(int32_t index, UBool exec, const char *&name, char *par=NULL);
void TestAPI();
void TestNotSTD3();
void TestInvalidPunycodeDigits();
void TestACELabelEdgeCases();
void TestTooLong();
void TestSomeCases();
void IdnaTest();
void checkIdnaTestResult(const char *line, const char *type,
const UnicodeString &expected, const UnicodeString &result,
const char *status, const IDNAInfo &info);
void idnaTestOneLine(char *fields[][2], UErrorCode &errorCode);
private:
IDNA *trans, *nontrans;
};
extern IntlTest *createUTS46Test() {
return new UTS46Test();
}
UTS46Test::~UTS46Test() {
delete trans;
delete nontrans;
}
void UTS46Test::runIndexedTest(int32_t index, UBool exec, const char *&name, char * /*par*/) {
if(exec) {
logln("TestSuite UTS46Test: ");
if(trans==NULL) {
IcuTestErrorCode errorCode(*this, "init/createUTS46Instance()");
uint32_t commonOptions=
UIDNA_USE_STD3_RULES|UIDNA_CHECK_BIDI|
UIDNA_CHECK_CONTEXTJ|UIDNA_CHECK_CONTEXTO;
trans=IDNA::createUTS46Instance(commonOptions, errorCode);
nontrans=IDNA::createUTS46Instance(
commonOptions|
UIDNA_NONTRANSITIONAL_TO_ASCII|UIDNA_NONTRANSITIONAL_TO_UNICODE,
errorCode);
if(errorCode.errDataIfFailureAndReset("createUTS46Instance()")) {
name="";
return;
}
}
}
TESTCASE_AUTO_BEGIN;
TESTCASE_AUTO(TestAPI);
TESTCASE_AUTO(TestNotSTD3);
TESTCASE_AUTO(TestInvalidPunycodeDigits);
TESTCASE_AUTO(TestACELabelEdgeCases);
TESTCASE_AUTO(TestTooLong);
TESTCASE_AUTO(TestSomeCases);
TESTCASE_AUTO(IdnaTest);
TESTCASE_AUTO_END;
}
const uint32_t severeErrors=
UIDNA_ERROR_LEADING_COMBINING_MARK|
UIDNA_ERROR_DISALLOWED|
UIDNA_ERROR_PUNYCODE|
UIDNA_ERROR_LABEL_HAS_DOT|
UIDNA_ERROR_INVALID_ACE_LABEL;
static UBool isASCII(const UnicodeString &str) {
const UChar *s=str.getBuffer();
int32_t length=str.length();
for(int32_t i=0; i<length; ++i) {
if(s[i]>=0x80) {
return FALSE;
}
}
return TRUE;
}
class TestCheckedArrayByteSink : public CheckedArrayByteSink {
public:
TestCheckedArrayByteSink(char* outbuf, int32_t capacity)
: CheckedArrayByteSink(outbuf, capacity), calledFlush(FALSE) {}
virtual CheckedArrayByteSink& Reset() {
CheckedArrayByteSink::Reset();
calledFlush = FALSE;
return *this;
}
virtual void Flush() { calledFlush = TRUE; }
UBool calledFlush;
};
void UTS46Test::TestAPI() {
UErrorCode errorCode=U_ZERO_ERROR;
UnicodeString result;
IDNAInfo info;
UnicodeString input=UNICODE_STRING_SIMPLE("www.eXample.cOm");
UnicodeString expected=UNICODE_STRING_SIMPLE("www.example.com");
trans->nameToASCII(input, result, info, errorCode);
if(U_FAILURE(errorCode) || info.hasErrors() || result!=expected) {
errln("T.nameToASCII(www.example.com) info.errors=%04lx result matches=%d %s",
(long)info.getErrors(), result==expected, u_errorName(errorCode));
}
errorCode=U_USELESS_COLLATOR_ERROR;
trans->nameToUnicode(input, result, info, errorCode);
if(errorCode!=U_USELESS_COLLATOR_ERROR || !result.isBogus()) {
errln("T.nameToUnicode(U_FAILURE) did not preserve the errorCode "
"or not result.setToBogus() - %s",
u_errorName(errorCode));
}
errorCode=U_ZERO_ERROR;
input.setToBogus();
result=UNICODE_STRING_SIMPLE("quatsch");
nontrans->labelToASCII(input, result, info, errorCode);
if(errorCode!=U_ILLEGAL_ARGUMENT_ERROR || !result.isBogus()) {
errln("N.labelToASCII(bogus) did not set illegal-argument-error "
"or not result.setToBogus() - %s",
u_errorName(errorCode));
}
errorCode=U_ZERO_ERROR;
input=UNICODE_STRING_SIMPLE("xn--bcher.de-65a");
expected=UNICODE_STRING_SIMPLE("xn--bcher\\uFFFDde-65a").unescape();
nontrans->labelToASCII(input, result, info, errorCode);
if( U_FAILURE(errorCode) ||
info.getErrors()!=(UIDNA_ERROR_LABEL_HAS_DOT|UIDNA_ERROR_INVALID_ACE_LABEL) ||
result!=expected
) {
errln("N.labelToASCII(label-with-dot) failed with errors %04lx - %s",
info.getErrors(), u_errorName(errorCode));
}
// UTF-8
char buffer[100];
TestCheckedArrayByteSink sink(buffer, UPRV_LENGTHOF(buffer));
errorCode=U_ZERO_ERROR;
nontrans->labelToUnicodeUTF8(StringPiece((const char *)NULL, 5), sink, info, errorCode);
if(errorCode!=U_ILLEGAL_ARGUMENT_ERROR || sink.NumberOfBytesWritten()!=0) {
errln("N.labelToUnicodeUTF8(StringPiece(NULL, 5)) did not set illegal-argument-error ",
"or did output something - %s",
u_errorName(errorCode));
}
sink.Reset();
errorCode=U_ZERO_ERROR;
nontrans->nameToASCII_UTF8(StringPiece(), sink, info, errorCode);
if(U_FAILURE(errorCode) || sink.NumberOfBytesWritten()!=0 || !sink.calledFlush) {
errln("N.nameToASCII_UTF8(empty) failed - %s",
u_errorName(errorCode));
}
static const char s[]={ 0x61, (char)0xc3, (char)0x9f };
sink.Reset();
errorCode=U_USELESS_COLLATOR_ERROR;
nontrans->nameToUnicodeUTF8(StringPiece(s, 3), sink, info, errorCode);
if(errorCode!=U_USELESS_COLLATOR_ERROR || sink.NumberOfBytesWritten()!=0) {
errln("N.nameToUnicode_UTF8(U_FAILURE) did not preserve the errorCode "
"or did output something - %s",
u_errorName(errorCode));
}
sink.Reset();
errorCode=U_ZERO_ERROR;
trans->labelToUnicodeUTF8(StringPiece(s, 3), sink, info, errorCode);
if( U_FAILURE(errorCode) || sink.NumberOfBytesWritten()!=3 ||
buffer[0]!=0x61 || buffer[1]!=0x73 || buffer[2]!=0x73 ||
!sink.calledFlush
) {
errln("T.labelToUnicodeUTF8(a sharp-s) failed - %s",
u_errorName(errorCode));
}
sink.Reset();
errorCode=U_ZERO_ERROR;
// "eXampLe.cOm"
static const char eX[]={ 0x65, 0x58, 0x61, 0x6d, 0x70, 0x4c, 0x65, 0x2e, 0x63, 0x4f, 0x6d, 0 };
// "example.com"
static const char ex[]={ 0x65, 0x78, 0x61, 0x6d, 0x70, 0x6c, 0x65, 0x2e, 0x63, 0x6f, 0x6d };
trans->nameToUnicodeUTF8(eX, sink, info, errorCode);
if( U_FAILURE(errorCode) || sink.NumberOfBytesWritten()!=11 ||
0!=memcmp(ex, buffer, 11) || !sink.calledFlush
) {
errln("T.nameToUnicodeUTF8(eXampLe.cOm) failed - %s",
u_errorName(errorCode));
}
}
void UTS46Test::TestNotSTD3() {
IcuTestErrorCode errorCode(*this, "TestNotSTD3()");
char buffer[400];
LocalPointer<IDNA> not3(IDNA::createUTS46Instance(UIDNA_CHECK_BIDI, errorCode));
if(errorCode.isFailure()) {
return;
}
UnicodeString input=UNICODE_STRING_SIMPLE("\\u0000A_2+2=4\\u000A.e\\u00DFen.net").unescape();
UnicodeString result;
IDNAInfo info;
if( not3->nameToUnicode(input, result, info, errorCode)!=
UNICODE_STRING_SIMPLE("\\u0000a_2+2=4\\u000A.essen.net").unescape() ||
info.hasErrors()
) {
prettify(result).extract(0, 0x7fffffff, buffer, UPRV_LENGTHOF(buffer));
errln("notSTD3.nameToUnicode(non-LDH ASCII) unexpected errors %04lx string %s",
(long)info.getErrors(), buffer);
}
// A space (BiDi class WS) is not allowed in a BiDi domain name.
input=UNICODE_STRING_SIMPLE("a z.xn--4db.edu");
not3->nameToASCII(input, result, info, errorCode);
if(result!=input || info.getErrors()!=UIDNA_ERROR_BIDI) {
errln("notSTD3.nameToASCII(ASCII-with-space.alef.edu) failed");
}
// Characters that are canonically equivalent to sequences with non-LDH ASCII.
input=UNICODE_STRING_SIMPLE("a\\u2260b\\u226Ec\\u226Fd").unescape();
not3->nameToUnicode(input, result, info, errorCode);
if(result!=input || info.hasErrors()) {
prettify(result).extract(0, 0x7fffffff, buffer, UPRV_LENGTHOF(buffer));
errln("notSTD3.nameToUnicode(equiv to non-LDH ASCII) unexpected errors %04lx string %s",
(long)info.getErrors(), buffer);
}
}
void UTS46Test::TestInvalidPunycodeDigits() {
IcuTestErrorCode errorCode(*this, "TestInvalidPunycodeDigits()");
LocalPointer<IDNA> idna(IDNA::createUTS46Instance(0, errorCode));
if(errorCode.isFailure()) {
return;
}
UnicodeString result;
{
IDNAInfo info;
idna->nameToUnicode(u"xn--pleP", result, info, errorCode); // P=U+0050
assertFalse("nameToUnicode() should succeed",
(info.getErrors()&UIDNA_ERROR_PUNYCODE)!=0);
assertEquals("normal result", u"ᔼᔴ", result);
}
{
IDNAInfo info;
idna->nameToUnicode(u"xn--pleѐ", result, info, errorCode); // ends with non-ASCII U+0450
assertTrue("nameToUnicode() should detect non-ASCII",
(info.getErrors()&UIDNA_ERROR_PUNYCODE)!=0);
}
// Test with ASCII characters adjacent to LDH.
{
IDNAInfo info;
idna->nameToUnicode(u"xn--ple/", result, info, errorCode);
assertTrue("nameToUnicode() should detect '/'",
(info.getErrors()&UIDNA_ERROR_PUNYCODE)!=0);
}
{
IDNAInfo info;
idna->nameToUnicode(u"xn--ple:", result, info, errorCode);
assertTrue("nameToUnicode() should detect ':'",
(info.getErrors()&UIDNA_ERROR_PUNYCODE)!=0);
}
{
IDNAInfo info;
idna->nameToUnicode(u"xn--ple@", result, info, errorCode);
assertTrue("nameToUnicode() should detect '@'",
(info.getErrors()&UIDNA_ERROR_PUNYCODE)!=0);
}
{
IDNAInfo info;
idna->nameToUnicode(u"xn--ple[", result, info, errorCode);
assertTrue("nameToUnicode() should detect '['",
(info.getErrors()&UIDNA_ERROR_PUNYCODE)!=0);
}
{
IDNAInfo info;
idna->nameToUnicode(u"xn--ple`", result, info, errorCode);
assertTrue("nameToUnicode() should detect '`'",
(info.getErrors()&UIDNA_ERROR_PUNYCODE)!=0);
}
{
IDNAInfo info;
idna->nameToUnicode(u"xn--ple{", result, info, errorCode);
assertTrue("nameToUnicode() should detect '{'",
(info.getErrors()&UIDNA_ERROR_PUNYCODE)!=0);
}
}
void UTS46Test::TestACELabelEdgeCases() {
// In IDNA2008, these labels fail the round-trip validation from comparing
// the ToUnicode input with the back-to-ToASCII output.
IcuTestErrorCode errorCode(*this, "TestACELabelEdgeCases()");
LocalPointer<IDNA> idna(IDNA::createUTS46Instance(0, errorCode));
if(errorCode.isFailure()) {
return;
}
UnicodeString result;
{
IDNAInfo info;
idna->labelToUnicode(u"xn--", result, info, errorCode);
assertTrue("empty xn--", (info.getErrors()&UIDNA_ERROR_INVALID_ACE_LABEL)!=0);
}
{
IDNAInfo info;
idna->labelToUnicode(u"xN--ASCII-", result, info, errorCode);
assertTrue("nothing but ASCII", (info.getErrors()&UIDNA_ERROR_INVALID_ACE_LABEL)!=0);
}
{
// Different error: The Punycode decoding procedure does not consume the last delimiter
// if it is right after the xn-- so the main decoding loop fails because the hyphen
// is not a valid Punycode digit.
IDNAInfo info;
idna->labelToUnicode(u"Xn---", result, info, errorCode);
assertTrue("empty Xn---", (info.getErrors()&UIDNA_ERROR_PUNYCODE)!=0);
}
}
void UTS46Test::TestTooLong() {
// ICU-13727: Limit input length for n^2 algorithm
// where well-formed strings are at most 59 characters long.
int32_t count = 50000;
UnicodeString s(count, u'a', count); // capacity, code point, count
char16_t dest[60000];
UErrorCode errorCode = U_ZERO_ERROR;
u_strToPunycode(s.getBuffer(), s.length(), dest, UPRV_LENGTHOF(dest), nullptr, &errorCode);
assertEquals("encode: expected an error for too-long input", U_INPUT_TOO_LONG_ERROR, errorCode);
errorCode = U_ZERO_ERROR;
u_strFromPunycode(s.getBuffer(), s.length(), dest, UPRV_LENGTHOF(dest), nullptr, &errorCode);
assertEquals("decode: expected an error for too-long input", U_INPUT_TOO_LONG_ERROR, errorCode);
}
struct TestCase {
// Input string and options string (Nontransitional/Transitional/Both).
const char *s, *o;
// Expected Unicode result string.
const char *u;
uint32_t errors;
};
static const TestCase testCases[]={
{ "www.eXample.cOm", "B", // all ASCII
"www.example.com", 0 },
{ "B\\u00FCcher.de", "B", // u-umlaut
"b\\u00FCcher.de", 0 },
{ "\\u00D6BB", "B", // O-umlaut
"\\u00F6bb", 0 },
{ "fa\\u00DF.de", "N", // sharp s
"fa\\u00DF.de", 0 },
{ "fa\\u00DF.de", "T", // sharp s
"fass.de", 0 },
{ "XN--fA-hia.dE", "B", // sharp s in Punycode
"fa\\u00DF.de", 0 },
{ "\\u03B2\\u03CC\\u03BB\\u03BF\\u03C2.com", "N", // Greek with final sigma
"\\u03B2\\u03CC\\u03BB\\u03BF\\u03C2.com", 0 },
{ "\\u03B2\\u03CC\\u03BB\\u03BF\\u03C2.com", "T", // Greek with final sigma
"\\u03B2\\u03CC\\u03BB\\u03BF\\u03C3.com", 0 },
{ "xn--nxasmm1c", "B", // Greek with final sigma in Punycode
"\\u03B2\\u03CC\\u03BB\\u03BF\\u03C2", 0 },
{ "www.\\u0DC1\\u0DCA\\u200D\\u0DBB\\u0DD3.com", "N", // "Sri" in "Sri Lanka" has a ZWJ
"www.\\u0DC1\\u0DCA\\u200D\\u0DBB\\u0DD3.com", 0 },
{ "www.\\u0DC1\\u0DCA\\u200D\\u0DBB\\u0DD3.com", "T", // "Sri" in "Sri Lanka" has a ZWJ
"www.\\u0DC1\\u0DCA\\u0DBB\\u0DD3.com", 0 },
{ "www.xn--10cl1a0b660p.com", "B", // "Sri" in Punycode
"www.\\u0DC1\\u0DCA\\u200D\\u0DBB\\u0DD3.com", 0 },
{ "\\u0646\\u0627\\u0645\\u0647\\u200C\\u0627\\u06CC", "N", // ZWNJ
"\\u0646\\u0627\\u0645\\u0647\\u200C\\u0627\\u06CC", 0 },
{ "\\u0646\\u0627\\u0645\\u0647\\u200C\\u0627\\u06CC", "T", // ZWNJ
"\\u0646\\u0627\\u0645\\u0647\\u0627\\u06CC", 0 },
{ "xn--mgba3gch31f060k.com", "B", // ZWNJ in Punycode
"\\u0646\\u0627\\u0645\\u0647\\u200C\\u0627\\u06CC.com", 0 },
{ "a.b\\uFF0Ec\\u3002d\\uFF61", "B",
"a.b.c.d.", 0 },
{ "U\\u0308.xn--tda", "B", // U+umlaut.u-umlaut
"\\u00FC.\\u00FC", 0 },
{ "xn--u-ccb", "B", // u+umlaut in Punycode
"xn--u-ccb\\uFFFD", UIDNA_ERROR_INVALID_ACE_LABEL },
{ "a\\u2488com", "B", // contains 1-dot
"a\\uFFFDcom", UIDNA_ERROR_DISALLOWED },
{ "xn--a-ecp.ru", "B", // contains 1-dot in Punycode
"xn--a-ecp\\uFFFD.ru", UIDNA_ERROR_INVALID_ACE_LABEL },
{ "xn--0.pt", "B", // invalid Punycode
"xn--0\\uFFFD.pt", UIDNA_ERROR_PUNYCODE },
{ "xn--a.pt", "B", // U+0080
"xn--a\\uFFFD.pt", UIDNA_ERROR_INVALID_ACE_LABEL },
{ "xn--a-\\u00C4.pt", "B", // invalid Punycode
"xn--a-\\u00E4.pt", UIDNA_ERROR_PUNYCODE },
{ "\\u65E5\\u672C\\u8A9E\\u3002\\uFF2A\\uFF30", "B", // Japanese with fullwidth ".jp"
"\\u65E5\\u672C\\u8A9E.jp", 0 },
{ "\\u2615", "B", "\\u2615", 0 }, // Unicode 4.0 HOT BEVERAGE
// some characters are disallowed because they are canonically equivalent
// to sequences with non-LDH ASCII
{ "a\\u2260b\\u226Ec\\u226Fd", "B",
"a\\uFFFDb\\uFFFDc\\uFFFDd", UIDNA_ERROR_DISALLOWED },
// many deviation characters, test the special mapping code
{ "1.a\\u00DF\\u200C\\u200Db\\u200C\\u200Dc\\u00DF\\u00DF\\u00DF\\u00DFd"
"\\u03C2\\u03C3\\u00DF\\u00DF\\u00DF\\u00DF\\u00DF\\u00DF\\u00DF\\u00DFe"
"\\u00DF\\u00DF\\u00DF\\u00DF\\u00DF\\u00DF\\u00DF\\u00DF\\u00DF\\u00DFx"
"\\u00DF\\u00DF\\u00DF\\u00DF\\u00DF\\u00DF\\u00DF\\u00DF\\u00DF\\u00DFy"
"\\u00DF\\u00DF\\u00DF\\u00DF\\u00DF\\u00DF\\u00DF\\u00DF\\u0302\\u00DFz", "N",
"1.a\\u00DF\\u200C\\u200Db\\u200C\\u200Dc\\u00DF\\u00DF\\u00DF\\u00DFd"
"\\u03C2\\u03C3\\u00DF\\u00DF\\u00DF\\u00DF\\u00DF\\u00DF\\u00DF\\u00DFe"
"\\u00DF\\u00DF\\u00DF\\u00DF\\u00DF\\u00DF\\u00DF\\u00DF\\u00DF\\u00DFx"
"\\u00DF\\u00DF\\u00DF\\u00DF\\u00DF\\u00DF\\u00DF\\u00DF\\u00DF\\u00DFy"
"\\u00DF\\u00DF\\u00DF\\u00DF\\u00DF\\u00DF\\u00DF\\u00DF\\u0302\\u00DFz",
UIDNA_ERROR_LABEL_TOO_LONG|UIDNA_ERROR_CONTEXTJ },
{ "1.a\\u00DF\\u200C\\u200Db\\u200C\\u200Dc\\u00DF\\u00DF\\u00DF\\u00DFd"
"\\u03C2\\u03C3\\u00DF\\u00DF\\u00DF\\u00DF\\u00DF\\u00DF\\u00DF\\u00DFe"
"\\u00DF\\u00DF\\u00DF\\u00DF\\u00DF\\u00DF\\u00DF\\u00DF\\u00DF\\u00DFx"
"\\u00DF\\u00DF\\u00DF\\u00DF\\u00DF\\u00DF\\u00DF\\u00DF\\u00DF\\u00DFy"
"\\u00DF\\u00DF\\u00DF\\u00DF\\u00DF\\u00DF\\u00DF\\u00DF\\u0302\\u00DFz", "T",
"1.assbcssssssssd"
"\\u03C3\\u03C3sssssssssssssssse"
"ssssssssssssssssssssx"
"ssssssssssssssssssssy"
"sssssssssssssss\\u015Dssz", UIDNA_ERROR_LABEL_TOO_LONG },
// "xn--bss" with deviation characters
{ "\\u200Cx\\u200Dn\\u200C-\\u200D-b\\u00DF", "N",
"\\u200Cx\\u200Dn\\u200C-\\u200D-b\\u00DF", UIDNA_ERROR_CONTEXTJ },
{ "\\u200Cx\\u200Dn\\u200C-\\u200D-b\\u00DF", "T",
"\\u5919", 0 },
// "xn--bssffl" written as:
// 02E3 MODIFIER LETTER SMALL X
// 034F COMBINING GRAPHEME JOINER (ignored)
// 2115 DOUBLE-STRUCK CAPITAL N
// 200B ZERO WIDTH SPACE (ignored)
// FE63 SMALL HYPHEN-MINUS
// 00AD SOFT HYPHEN (ignored)
// FF0D FULLWIDTH HYPHEN-MINUS
// 180C MONGOLIAN FREE VARIATION SELECTOR TWO (ignored)
// 212C SCRIPT CAPITAL B
// FE00 VARIATION SELECTOR-1 (ignored)
// 017F LATIN SMALL LETTER LONG S
// 2064 INVISIBLE PLUS (ignored)
// 1D530 MATHEMATICAL FRAKTUR SMALL S
// E01EF VARIATION SELECTOR-256 (ignored)
// FB04 LATIN SMALL LIGATURE FFL
{ "\\u02E3\\u034F\\u2115\\u200B\\uFE63\\u00AD\\uFF0D\\u180C"
"\\u212C\\uFE00\\u017F\\u2064\\U0001D530\\U000E01EF\\uFB04", "B",
"\\u5921\\u591E\\u591C\\u5919", 0 },
{ "123456789012345678901234567890123456789012345678901234567890123."
"123456789012345678901234567890123456789012345678901234567890123."
"123456789012345678901234567890123456789012345678901234567890123."
"1234567890123456789012345678901234567890123456789012345678901", "B",
"123456789012345678901234567890123456789012345678901234567890123."
"123456789012345678901234567890123456789012345678901234567890123."
"123456789012345678901234567890123456789012345678901234567890123."
"1234567890123456789012345678901234567890123456789012345678901", 0 },
{ "123456789012345678901234567890123456789012345678901234567890123."
"123456789012345678901234567890123456789012345678901234567890123."
"123456789012345678901234567890123456789012345678901234567890123."
"1234567890123456789012345678901234567890123456789012345678901.", "B",
"123456789012345678901234567890123456789012345678901234567890123."
"123456789012345678901234567890123456789012345678901234567890123."
"123456789012345678901234567890123456789012345678901234567890123."
"1234567890123456789012345678901234567890123456789012345678901.", 0 },
// Domain name >256 characters, forces slow path in UTF-8 processing.
{ "123456789012345678901234567890123456789012345678901234567890123."
"123456789012345678901234567890123456789012345678901234567890123."
"123456789012345678901234567890123456789012345678901234567890123."
"123456789012345678901234567890123456789012345678901234567890123."
"12345678901234567890123456789012345678901234567890123456789012", "B",
"123456789012345678901234567890123456789012345678901234567890123."
"123456789012345678901234567890123456789012345678901234567890123."
"123456789012345678901234567890123456789012345678901234567890123."
"123456789012345678901234567890123456789012345678901234567890123."
"12345678901234567890123456789012345678901234567890123456789012",
UIDNA_ERROR_DOMAIN_NAME_TOO_LONG },
{ "123456789012345678901234567890123456789012345678901234567890123."
"123456789012345678901234567890123456789012345678901234567890123."
"123456789012345678901234567890123456789012345678901234567890123."
"123456789012345678901234567890123456789012345678901234567890123."
"1234567890123456789012345678901234567890123456789\\u05D0", "B",
"123456789012345678901234567890123456789012345678901234567890123."
"123456789012345678901234567890123456789012345678901234567890123."
"123456789012345678901234567890123456789012345678901234567890123."
"123456789012345678901234567890123456789012345678901234567890123."
"1234567890123456789012345678901234567890123456789\\u05D0",
UIDNA_ERROR_DOMAIN_NAME_TOO_LONG|UIDNA_ERROR_BIDI },
{ "123456789012345678901234567890123456789012345678901234567890123."
"1234567890123456789012345678901234567890123456789012345678901234."
"123456789012345678901234567890123456789012345678901234567890123."
"123456789012345678901234567890123456789012345678901234567890", "B",
"123456789012345678901234567890123456789012345678901234567890123."
"1234567890123456789012345678901234567890123456789012345678901234."
"123456789012345678901234567890123456789012345678901234567890123."
"123456789012345678901234567890123456789012345678901234567890",
UIDNA_ERROR_LABEL_TOO_LONG },
{ "123456789012345678901234567890123456789012345678901234567890123."
"1234567890123456789012345678901234567890123456789012345678901234."
"123456789012345678901234567890123456789012345678901234567890123."
"123456789012345678901234567890123456789012345678901234567890.", "B",
"123456789012345678901234567890123456789012345678901234567890123."
"1234567890123456789012345678901234567890123456789012345678901234."
"123456789012345678901234567890123456789012345678901234567890123."
"123456789012345678901234567890123456789012345678901234567890.",
UIDNA_ERROR_LABEL_TOO_LONG },
{ "123456789012345678901234567890123456789012345678901234567890123."
"1234567890123456789012345678901234567890123456789012345678901234."
"123456789012345678901234567890123456789012345678901234567890123."
"1234567890123456789012345678901234567890123456789012345678901", "B",
"123456789012345678901234567890123456789012345678901234567890123."
"1234567890123456789012345678901234567890123456789012345678901234."
"123456789012345678901234567890123456789012345678901234567890123."
"1234567890123456789012345678901234567890123456789012345678901",
UIDNA_ERROR_LABEL_TOO_LONG|UIDNA_ERROR_DOMAIN_NAME_TOO_LONG },
// label length 63: xn--1234567890123456789012345678901234567890123456789012345-9te
{ "\\u00E41234567890123456789012345678901234567890123456789012345", "B",
"\\u00E41234567890123456789012345678901234567890123456789012345", 0 },
{ "1234567890\\u00E41234567890123456789012345678901234567890123456", "B",
"1234567890\\u00E41234567890123456789012345678901234567890123456", UIDNA_ERROR_LABEL_TOO_LONG },
{ "123456789012345678901234567890123456789012345678901234567890123."
"1234567890\\u00E4123456789012345678901234567890123456789012345."
"123456789012345678901234567890123456789012345678901234567890123."
"1234567890123456789012345678901234567890123456789012345678901", "B",
"123456789012345678901234567890123456789012345678901234567890123."
"1234567890\\u00E4123456789012345678901234567890123456789012345."
"123456789012345678901234567890123456789012345678901234567890123."
"1234567890123456789012345678901234567890123456789012345678901", 0 },
{ "123456789012345678901234567890123456789012345678901234567890123."
"1234567890\\u00E4123456789012345678901234567890123456789012345."
"123456789012345678901234567890123456789012345678901234567890123."
"1234567890123456789012345678901234567890123456789012345678901.", "B",
"123456789012345678901234567890123456789012345678901234567890123."
"1234567890\\u00E4123456789012345678901234567890123456789012345."
"123456789012345678901234567890123456789012345678901234567890123."
"1234567890123456789012345678901234567890123456789012345678901.", 0 },
{ "123456789012345678901234567890123456789012345678901234567890123."
"1234567890\\u00E4123456789012345678901234567890123456789012345."
"123456789012345678901234567890123456789012345678901234567890123."
"12345678901234567890123456789012345678901234567890123456789012", "B",
"123456789012345678901234567890123456789012345678901234567890123."
"1234567890\\u00E4123456789012345678901234567890123456789012345."
"123456789012345678901234567890123456789012345678901234567890123."
"12345678901234567890123456789012345678901234567890123456789012",
UIDNA_ERROR_DOMAIN_NAME_TOO_LONG },
{ "123456789012345678901234567890123456789012345678901234567890123."
"1234567890\\u00E41234567890123456789012345678901234567890123456."
"123456789012345678901234567890123456789012345678901234567890123."
"123456789012345678901234567890123456789012345678901234567890", "B",
"123456789012345678901234567890123456789012345678901234567890123."
"1234567890\\u00E41234567890123456789012345678901234567890123456."
"123456789012345678901234567890123456789012345678901234567890123."
"123456789012345678901234567890123456789012345678901234567890",
UIDNA_ERROR_LABEL_TOO_LONG },
{ "123456789012345678901234567890123456789012345678901234567890123."
"1234567890\\u00E41234567890123456789012345678901234567890123456."
"123456789012345678901234567890123456789012345678901234567890123."
"123456789012345678901234567890123456789012345678901234567890.", "B",
"123456789012345678901234567890123456789012345678901234567890123."
"1234567890\\u00E41234567890123456789012345678901234567890123456."
"123456789012345678901234567890123456789012345678901234567890123."
"123456789012345678901234567890123456789012345678901234567890.",
UIDNA_ERROR_LABEL_TOO_LONG },
{ "123456789012345678901234567890123456789012345678901234567890123."
"1234567890\\u00E41234567890123456789012345678901234567890123456."
"123456789012345678901234567890123456789012345678901234567890123."
"1234567890123456789012345678901234567890123456789012345678901", "B",
"123456789012345678901234567890123456789012345678901234567890123."
"1234567890\\u00E41234567890123456789012345678901234567890123456."
"123456789012345678901234567890123456789012345678901234567890123."
"1234567890123456789012345678901234567890123456789012345678901",
UIDNA_ERROR_LABEL_TOO_LONG|UIDNA_ERROR_DOMAIN_NAME_TOO_LONG },
// hyphen errors and empty-label errors
// Ticket #10883: ToUnicode also checks for empty labels.
{ ".", "B", ".", UIDNA_ERROR_EMPTY_LABEL },
{ "\\uFF0E", "B", ".", UIDNA_ERROR_EMPTY_LABEL },
// "xn---q----jra"=="-q--a-umlaut-"
{ "a.b..-q--a-.e", "B", "a.b..-q--a-.e",
UIDNA_ERROR_EMPTY_LABEL|UIDNA_ERROR_LEADING_HYPHEN|UIDNA_ERROR_TRAILING_HYPHEN|
UIDNA_ERROR_HYPHEN_3_4 },
{ "a.b..-q--\\u00E4-.e", "B", "a.b..-q--\\u00E4-.e",
UIDNA_ERROR_EMPTY_LABEL|UIDNA_ERROR_LEADING_HYPHEN|UIDNA_ERROR_TRAILING_HYPHEN|
UIDNA_ERROR_HYPHEN_3_4 },
{ "a.b..xn---q----jra.e", "B", "a.b..-q--\\u00E4-.e",
UIDNA_ERROR_EMPTY_LABEL|UIDNA_ERROR_LEADING_HYPHEN|UIDNA_ERROR_TRAILING_HYPHEN|
UIDNA_ERROR_HYPHEN_3_4 },
{ "a..c", "B", "a..c", UIDNA_ERROR_EMPTY_LABEL },
{ "a.xn--.c", "B", "a.xn--\\uFFFD.c", UIDNA_ERROR_INVALID_ACE_LABEL },
{ "a.-b.", "B", "a.-b.", UIDNA_ERROR_LEADING_HYPHEN },
{ "a.b-.c", "B", "a.b-.c", UIDNA_ERROR_TRAILING_HYPHEN },
{ "a.-.c", "B", "a.-.c", UIDNA_ERROR_LEADING_HYPHEN|UIDNA_ERROR_TRAILING_HYPHEN },
{ "a.bc--de.f", "B", "a.bc--de.f", UIDNA_ERROR_HYPHEN_3_4 },
{ "\\u00E4.\\u00AD.c", "B", "\\u00E4..c", UIDNA_ERROR_EMPTY_LABEL },
{ "\\u00E4.xn--.c", "B", "\\u00E4.xn--\\uFFFD.c", UIDNA_ERROR_INVALID_ACE_LABEL },
{ "\\u00E4.-b.", "B", "\\u00E4.-b.", UIDNA_ERROR_LEADING_HYPHEN },
{ "\\u00E4.b-.c", "B", "\\u00E4.b-.c", UIDNA_ERROR_TRAILING_HYPHEN },
{ "\\u00E4.-.c", "B", "\\u00E4.-.c", UIDNA_ERROR_LEADING_HYPHEN|UIDNA_ERROR_TRAILING_HYPHEN },
{ "\\u00E4.bc--de.f", "B", "\\u00E4.bc--de.f", UIDNA_ERROR_HYPHEN_3_4 },
{ "a.b.\\u0308c.d", "B", "a.b.\\uFFFDc.d", UIDNA_ERROR_LEADING_COMBINING_MARK },
{ "a.b.xn--c-bcb.d", "B",
"a.b.xn--c-bcb\\uFFFD.d", UIDNA_ERROR_LEADING_COMBINING_MARK|UIDNA_ERROR_INVALID_ACE_LABEL },
// BiDi
{ "A0", "B", "a0", 0 },
{ "0A", "B", "0a", 0 }, // all-LTR is ok to start with a digit (EN)
{ "0A.\\u05D0", "B", // ASCII label does not start with L/R/AL
"0a.\\u05D0", UIDNA_ERROR_BIDI },
{ "c.xn--0-eha.xn--4db", "B", // 2nd label does not start with L/R/AL
"c.0\\u00FC.\\u05D0", UIDNA_ERROR_BIDI },
{ "b-.\\u05D0", "B", // label does not end with L/EN
"b-.\\u05D0", UIDNA_ERROR_TRAILING_HYPHEN|UIDNA_ERROR_BIDI },
{ "d.xn----dha.xn--4db", "B", // 2nd label does not end with L/EN
"d.\\u00FC-.\\u05D0", UIDNA_ERROR_TRAILING_HYPHEN|UIDNA_ERROR_BIDI },
{ "a\\u05D0", "B", "a\\u05D0", UIDNA_ERROR_BIDI }, // first dir != last dir
{ "\\u05D0\\u05C7", "B", "\\u05D0\\u05C7", 0 },
{ "\\u05D09\\u05C7", "B", "\\u05D09\\u05C7", 0 },
{ "\\u05D0a\\u05C7", "B", "\\u05D0a\\u05C7", UIDNA_ERROR_BIDI }, // first dir != last dir
{ "\\u05D0\\u05EA", "B", "\\u05D0\\u05EA", 0 },
{ "\\u05D0\\u05F3\\u05EA", "B", "\\u05D0\\u05F3\\u05EA", 0 },
{ "a\\u05D0Tz", "B", "a\\u05D0tz", UIDNA_ERROR_BIDI }, // mixed dir
{ "\\u05D0T\\u05EA", "B", "\\u05D0t\\u05EA", UIDNA_ERROR_BIDI }, // mixed dir
{ "\\u05D07\\u05EA", "B", "\\u05D07\\u05EA", 0 },
{ "\\u05D0\\u0667\\u05EA", "B", "\\u05D0\\u0667\\u05EA", 0 }, // Arabic 7 in the middle
{ "a7\\u0667z", "B", "a7\\u0667z", UIDNA_ERROR_BIDI }, // AN digit in LTR
{ "a7\\u0667", "B", "a7\\u0667", UIDNA_ERROR_BIDI }, // AN digit in LTR
{ "\\u05D07\\u0667\\u05EA", "B", // mixed EN/AN digits in RTL
"\\u05D07\\u0667\\u05EA", UIDNA_ERROR_BIDI },
{ "\\u05D07\\u0667", "B", // mixed EN/AN digits in RTL
"\\u05D07\\u0667", UIDNA_ERROR_BIDI },
// ZWJ
{ "\\u0BB9\\u0BCD\\u200D", "N", "\\u0BB9\\u0BCD\\u200D", 0 }, // Virama+ZWJ
{ "\\u0BB9\\u200D", "N", "\\u0BB9\\u200D", UIDNA_ERROR_CONTEXTJ }, // no Virama
{ "\\u200D", "N", "\\u200D", UIDNA_ERROR_CONTEXTJ }, // no Virama
// ZWNJ
{ "\\u0BB9\\u0BCD\\u200C", "N", "\\u0BB9\\u0BCD\\u200C", 0 }, // Virama+ZWNJ
{ "\\u0BB9\\u200C", "N", "\\u0BB9\\u200C", UIDNA_ERROR_CONTEXTJ }, // no Virama
{ "\\u200C", "N", "\\u200C", UIDNA_ERROR_CONTEXTJ }, // no Virama
{ "\\u0644\\u0670\\u200C\\u06ED\\u06EF", "N", // Joining types D T ZWNJ T R
"\\u0644\\u0670\\u200C\\u06ED\\u06EF", 0 },
{ "\\u0644\\u0670\\u200C\\u06EF", "N", // D T ZWNJ R
"\\u0644\\u0670\\u200C\\u06EF", 0 },
{ "\\u0644\\u200C\\u06ED\\u06EF", "N", // D ZWNJ T R
"\\u0644\\u200C\\u06ED\\u06EF", 0 },
{ "\\u0644\\u200C\\u06EF", "N", // D ZWNJ R
"\\u0644\\u200C\\u06EF", 0 },
{ "\\u0644\\u0670\\u200C\\u06ED", "N", // D T ZWNJ T
"\\u0644\\u0670\\u200C\\u06ED", UIDNA_ERROR_BIDI|UIDNA_ERROR_CONTEXTJ },
{ "\\u06EF\\u200C\\u06EF", "N", // R ZWNJ R
"\\u06EF\\u200C\\u06EF", UIDNA_ERROR_CONTEXTJ },
{ "\\u0644\\u200C", "N", // D ZWNJ
"\\u0644\\u200C", UIDNA_ERROR_BIDI|UIDNA_ERROR_CONTEXTJ },
{ "\\u0660\\u0661", "B", // Arabic-Indic Digits alone
"\\u0660\\u0661", UIDNA_ERROR_BIDI },
{ "\\u06F0\\u06F1", "B", // Extended Arabic-Indic Digits alone
"\\u06F0\\u06F1", 0 },
{ "\\u0660\\u06F1", "B", // Mixed Arabic-Indic Digits
"\\u0660\\u06F1", UIDNA_ERROR_CONTEXTO_DIGITS|UIDNA_ERROR_BIDI },
// All of the CONTEXTO "Would otherwise have been DISALLOWED" characters
// in their correct contexts,
// then each in incorrect context.
{ "l\\u00B7l\\u4E00\\u0375\\u03B1\\u05D0\\u05F3\\u05F4\\u30FB", "B",
"l\\u00B7l\\u4E00\\u0375\\u03B1\\u05D0\\u05F3\\u05F4\\u30FB", UIDNA_ERROR_BIDI },
{ "l\\u00B7", "B",
"l\\u00B7", UIDNA_ERROR_CONTEXTO_PUNCTUATION },
{ "\\u00B7l", "B",
"\\u00B7l", UIDNA_ERROR_CONTEXTO_PUNCTUATION },
{ "\\u0375", "B",
"\\u0375", UIDNA_ERROR_CONTEXTO_PUNCTUATION },
{ "\\u03B1\\u05F3", "B",
"\\u03B1\\u05F3", UIDNA_ERROR_CONTEXTO_PUNCTUATION|UIDNA_ERROR_BIDI },
{ "\\u05F4", "B",
"\\u05F4", UIDNA_ERROR_CONTEXTO_PUNCTUATION },
{ "l\\u30FB", "B",
"l\\u30FB", UIDNA_ERROR_CONTEXTO_PUNCTUATION },
// Ticket #8137: UTS #46 toUnicode() fails with non-ASCII labels that turn
// into 15 characters (UChars).
// The bug was in u_strFromPunycode() which did not write the last character
// if it just so fit into the end of the destination buffer.
// The UTS #46 code gives a default-capacity UnicodeString as the destination buffer,
// and the internal UnicodeString capacity is currently 15 UChars on 64-bit machines
// but 13 on 32-bit machines.
// Label with 15 UChars, for 64-bit-machine testing:
{ "aaaaaaaaaaaaa\\u00FCa.de", "B", "aaaaaaaaaaaaa\\u00FCa.de", 0 },
{ "xn--aaaaaaaaaaaaaa-ssb.de", "B", "aaaaaaaaaaaaa\\u00FCa.de", 0 },
{ "abschlu\\u00DFpr\\u00FCfung.de", "N", "abschlu\\u00DFpr\\u00FCfung.de", 0 },
{ "xn--abschluprfung-hdb15b.de", "B", "abschlu\\u00DFpr\\u00FCfung.de", 0 },
// Label with 13 UChars, for 32-bit-machine testing:
{ "xn--aaaaaaaaaaaa-nlb.de", "B", "aaaaaaaaaaa\\u00FCa.de", 0 },
{ "xn--schluprfung-z6a39a.de", "B", "schlu\\u00DFpr\\u00FCfung.de", 0 },
// { "", "B",
// "", 0 },
};
void UTS46Test::TestSomeCases() {
IcuTestErrorCode errorCode(*this, "TestSomeCases");
char buffer[400], buffer2[400];
int32_t i;
for(i=0; i<UPRV_LENGTHOF(testCases); ++i) {
const TestCase &testCase=testCases[i];
UnicodeString input(ctou(testCase.s));
UnicodeString expected(ctou(testCase.u));
// ToASCII/ToUnicode, transitional/nontransitional
UnicodeString aT, uT, aN, uN;
IDNAInfo aTInfo, uTInfo, aNInfo, uNInfo;
trans->nameToASCII(input, aT, aTInfo, errorCode);
trans->nameToUnicode(input, uT, uTInfo, errorCode);
nontrans->nameToASCII(input, aN, aNInfo, errorCode);
nontrans->nameToUnicode(input, uN, uNInfo, errorCode);
if(errorCode.errIfFailureAndReset("first-level processing [%d/%s] %s",
(int)i, testCase.o, testCase.s)
) {
continue;
}
// ToUnicode does not set length-overflow errors.
uint32_t uniErrors=testCase.errors&~
(UIDNA_ERROR_LABEL_TOO_LONG|
UIDNA_ERROR_DOMAIN_NAME_TOO_LONG);
char mode=testCase.o[0];
if(mode=='B' || mode=='N') {
if(uNInfo.getErrors()!=uniErrors) {
errln("N.nameToUnicode([%d] %s) unexpected errors %04lx",
(int)i, testCase.s, (long)uNInfo.getErrors());
continue;
}
if(uN!=expected) {
prettify(uN).extract(0, 0x7fffffff, buffer, UPRV_LENGTHOF(buffer));
errln("N.nameToUnicode([%d] %s) unexpected string %s",
(int)i, testCase.s, buffer);
continue;
}
if(aNInfo.getErrors()!=testCase.errors) {
errln("N.nameToASCII([%d] %s) unexpected errors %04lx",
(int)i, testCase.s, (long)aNInfo.getErrors());
continue;
}
}
if(mode=='B' || mode=='T') {
if(uTInfo.getErrors()!=uniErrors) {
errln("T.nameToUnicode([%d] %s) unexpected errors %04lx",
(int)i, testCase.s, (long)uTInfo.getErrors());
continue;
}
if(uT!=expected) {
prettify(uT).extract(0, 0x7fffffff, buffer, UPRV_LENGTHOF(buffer));
errln("T.nameToUnicode([%d] %s) unexpected string %s",
(int)i, testCase.s, buffer);
continue;
}
if(aTInfo.getErrors()!=testCase.errors) {
errln("T.nameToASCII([%d] %s) unexpected errors %04lx",
(int)i, testCase.s, (long)aTInfo.getErrors());
continue;
}
}
// ToASCII is all-ASCII if no severe errors
if((aNInfo.getErrors()&severeErrors)==0 && !isASCII(aN)) {
prettify(aN).extract(0, 0x7fffffff, buffer, UPRV_LENGTHOF(buffer));
errln("N.nameToASCII([%d] %s) (errors %04lx) result is not ASCII %s",
(int)i, testCase.s, aNInfo.getErrors(), buffer);
continue;
}
if((aTInfo.getErrors()&severeErrors)==0 && !isASCII(aT)) {
prettify(aT).extract(0, 0x7fffffff, buffer, UPRV_LENGTHOF(buffer));
errln("T.nameToASCII([%d] %s) (errors %04lx) result is not ASCII %s",
(int)i, testCase.s, aTInfo.getErrors(), buffer);
continue;
}
if(verbose) {
char m= mode=='B' ? mode : 'N';
prettify(aN).extract(0, 0x7fffffff, buffer, UPRV_LENGTHOF(buffer));
logln("%c.nameToASCII([%d] %s) (errors %04lx) result string: %s",
m, (int)i, testCase.s, aNInfo.getErrors(), buffer);
if(mode!='B') {
prettify(aT).extract(0, 0x7fffffff, buffer, UPRV_LENGTHOF(buffer));
logln("T.nameToASCII([%d] %s) (errors %04lx) result string: %s",
(int)i, testCase.s, aTInfo.getErrors(), buffer);
}
}
// second-level processing
UnicodeString aTuN, uTaN, aNuN, uNaN;
IDNAInfo aTuNInfo, uTaNInfo, aNuNInfo, uNaNInfo;
nontrans->nameToUnicode(aT, aTuN, aTuNInfo, errorCode);
nontrans->nameToASCII(uT, uTaN, uTaNInfo, errorCode);
nontrans->nameToUnicode(aN, aNuN, aNuNInfo, errorCode);
nontrans->nameToASCII(uN, uNaN, uNaNInfo, errorCode);
if(errorCode.errIfFailureAndReset("second-level processing [%d/%s] %s",
(int)i, testCase.o, testCase.s)
) {
continue;
}
if(aN!=uNaN) {
prettify(aN).extract(0, 0x7fffffff, buffer, UPRV_LENGTHOF(buffer));
prettify(uNaN).extract(0, 0x7fffffff, buffer2, UPRV_LENGTHOF(buffer2));
errln("N.nameToASCII([%d] %s)!=N.nameToUnicode().N.nameToASCII() "
"(errors %04lx) %s vs. %s",
(int)i, testCase.s, aNInfo.getErrors(), buffer, buffer2);
continue;
}
if(aT!=uTaN) {
prettify(aT).extract(0, 0x7fffffff, buffer, UPRV_LENGTHOF(buffer));
prettify(uTaN).extract(0, 0x7fffffff, buffer2, UPRV_LENGTHOF(buffer2));
errln("T.nameToASCII([%d] %s)!=T.nameToUnicode().N.nameToASCII() "
"(errors %04lx) %s vs. %s",
(int)i, testCase.s, aNInfo.getErrors(), buffer, buffer2);
continue;
}
if(uN!=aNuN) {
prettify(uN).extract(0, 0x7fffffff, buffer, UPRV_LENGTHOF(buffer));
prettify(aNuN).extract(0, 0x7fffffff, buffer2, UPRV_LENGTHOF(buffer2));
errln("N.nameToUnicode([%d] %s)!=N.nameToASCII().N.nameToUnicode() "
"(errors %04lx) %s vs. %s",
(int)i, testCase.s, uNInfo.getErrors(), buffer, buffer2);
continue;
}
if(uT!=aTuN) {
prettify(uT).extract(0, 0x7fffffff, buffer, UPRV_LENGTHOF(buffer));
prettify(aTuN).extract(0, 0x7fffffff, buffer2, UPRV_LENGTHOF(buffer2));
errln("T.nameToUnicode([%d] %s)!=T.nameToASCII().N.nameToUnicode() "
"(errors %04lx) %s vs. %s",
(int)i, testCase.s, uNInfo.getErrors(), buffer, buffer2);
continue;
}
// labelToUnicode
UnicodeString aTL, uTL, aNL, uNL;
IDNAInfo aTLInfo, uTLInfo, aNLInfo, uNLInfo;
trans->labelToASCII(input, aTL, aTLInfo, errorCode);
trans->labelToUnicode(input, uTL, uTLInfo, errorCode);
nontrans->labelToASCII(input, aNL, aNLInfo, errorCode);
nontrans->labelToUnicode(input, uNL, uNLInfo, errorCode);
if(errorCode.errIfFailureAndReset("labelToXYZ processing [%d/%s] %s",
(int)i, testCase.o, testCase.s)
) {
continue;
}
if(aN.indexOf((UChar)0x2e)<0) {
if(aN!=aNL || aNInfo.getErrors()!=aNLInfo.getErrors()) {
prettify(aN).extract(0, 0x7fffffff, buffer, UPRV_LENGTHOF(buffer));
prettify(aNL).extract(0, 0x7fffffff, buffer2, UPRV_LENGTHOF(buffer2));
errln("N.nameToASCII([%d] %s)!=N.labelToASCII() "
"(errors %04lx vs %04lx) %s vs. %s",
(int)i, testCase.s, aNInfo.getErrors(), aNLInfo.getErrors(), buffer, buffer2);
continue;
}
} else {
if((aNLInfo.getErrors()&UIDNA_ERROR_LABEL_HAS_DOT)==0) {
errln("N.labelToASCII([%d] %s) errors %04lx missing UIDNA_ERROR_LABEL_HAS_DOT",
(int)i, testCase.s, (long)aNLInfo.getErrors());
continue;
}
}
if(aT.indexOf((UChar)0x2e)<0) {
if(aT!=aTL || aTInfo.getErrors()!=aTLInfo.getErrors()) {
prettify(aT).extract(0, 0x7fffffff, buffer, UPRV_LENGTHOF(buffer));
prettify(aTL).extract(0, 0x7fffffff, buffer2, UPRV_LENGTHOF(buffer2));
errln("T.nameToASCII([%d] %s)!=T.labelToASCII() "
"(errors %04lx vs %04lx) %s vs. %s",
(int)i, testCase.s, aTInfo.getErrors(), aTLInfo.getErrors(), buffer, buffer2);
continue;
}
} else {
if((aTLInfo.getErrors()&UIDNA_ERROR_LABEL_HAS_DOT)==0) {
errln("T.labelToASCII([%d] %s) errors %04lx missing UIDNA_ERROR_LABEL_HAS_DOT",
(int)i, testCase.s, (long)aTLInfo.getErrors());
continue;
}
}
if(uN.indexOf((UChar)0x2e)<0) {
if(uN!=uNL || uNInfo.getErrors()!=uNLInfo.getErrors()) {
prettify(uN).extract(0, 0x7fffffff, buffer, UPRV_LENGTHOF(buffer));
prettify(uNL).extract(0, 0x7fffffff, buffer2, UPRV_LENGTHOF(buffer2));
errln("N.nameToUnicode([%d] %s)!=N.labelToUnicode() "
"(errors %04lx vs %04lx) %s vs. %s",
(int)i, testCase.s, uNInfo.getErrors(), uNLInfo.getErrors(), buffer, buffer2);
continue;
}
} else {
if((uNLInfo.getErrors()&UIDNA_ERROR_LABEL_HAS_DOT)==0) {
errln("N.labelToUnicode([%d] %s) errors %04lx missing UIDNA_ERROR_LABEL_HAS_DOT",
(int)i, testCase.s, (long)uNLInfo.getErrors());
continue;
}
}
if(uT.indexOf((UChar)0x2e)<0) {
if(uT!=uTL || uTInfo.getErrors()!=uTLInfo.getErrors()) {
prettify(uT).extract(0, 0x7fffffff, buffer, UPRV_LENGTHOF(buffer));
prettify(uTL).extract(0, 0x7fffffff, buffer2, UPRV_LENGTHOF(buffer2));
errln("T.nameToUnicode([%d] %s)!=T.labelToUnicode() "
"(errors %04lx vs %04lx) %s vs. %s",
(int)i, testCase.s, uTInfo.getErrors(), uTLInfo.getErrors(), buffer, buffer2);
continue;
}
} else {
if((uTLInfo.getErrors()&UIDNA_ERROR_LABEL_HAS_DOT)==0) {
errln("T.labelToUnicode([%d] %s) errors %04lx missing UIDNA_ERROR_LABEL_HAS_DOT",
(int)i, testCase.s, (long)uTLInfo.getErrors());
continue;
}
}
// Differences between transitional and nontransitional processing
if(mode=='B') {
if( aNInfo.isTransitionalDifferent() ||
aTInfo.isTransitionalDifferent() ||
uNInfo.isTransitionalDifferent() ||
uTInfo.isTransitionalDifferent() ||
aNLInfo.isTransitionalDifferent() ||
aTLInfo.isTransitionalDifferent() ||
uNLInfo.isTransitionalDifferent() ||
uTLInfo.isTransitionalDifferent()
) {
errln("B.process([%d] %s) isTransitionalDifferent()", (int)i, testCase.s);
continue;
}
if( aN!=aT || uN!=uT || aNL!=aTL || uNL!=uTL ||
aNInfo.getErrors()!=aTInfo.getErrors() || uNInfo.getErrors()!=uTInfo.getErrors() ||
aNLInfo.getErrors()!=aTLInfo.getErrors() || uNLInfo.getErrors()!=uTLInfo.getErrors()
) {
errln("N.process([%d] %s) vs. T.process() different errors or result strings",
(int)i, testCase.s);
continue;
}
} else {
if( !aNInfo.isTransitionalDifferent() ||
!aTInfo.isTransitionalDifferent() ||
!uNInfo.isTransitionalDifferent() ||
!uTInfo.isTransitionalDifferent() ||
!aNLInfo.isTransitionalDifferent() ||
!aTLInfo.isTransitionalDifferent() ||
!uNLInfo.isTransitionalDifferent() ||
!uTLInfo.isTransitionalDifferent()
) {
errln("%s.process([%d] %s) !isTransitionalDifferent()",
testCase.o, (int)i, testCase.s);
continue;
}
if(aN==aT || uN==uT || aNL==aTL || uNL==uTL) {
errln("N.process([%d] %s) vs. T.process() same result strings",
(int)i, testCase.s);
continue;
}
}
// UTF-8
std::string input8, aT8, uT8, aN8, uN8;
StringByteSink<std::string> aT8Sink(&aT8), uT8Sink(&uT8), aN8Sink(&aN8), uN8Sink(&uN8);
IDNAInfo aT8Info, uT8Info, aN8Info, uN8Info;
input.toUTF8String(input8);
trans->nameToASCII_UTF8(input8, aT8Sink, aT8Info, errorCode);
trans->nameToUnicodeUTF8(input8, uT8Sink, uT8Info, errorCode);
nontrans->nameToASCII_UTF8(input8, aN8Sink, aN8Info, errorCode);
nontrans->nameToUnicodeUTF8(input8, uN8Sink, uN8Info, errorCode);
if(errorCode.errIfFailureAndReset("UTF-8 processing [%d/%s] %s",
(int)i, testCase.o, testCase.s)
) {
continue;
}
UnicodeString aT16(UnicodeString::fromUTF8(aT8));
UnicodeString uT16(UnicodeString::fromUTF8(uT8));
UnicodeString aN16(UnicodeString::fromUTF8(aN8));
UnicodeString uN16(UnicodeString::fromUTF8(uN8));
if( aN8Info.getErrors()!=aNInfo.getErrors() ||
uN8Info.getErrors()!=uNInfo.getErrors()
) {
errln("N.xyzUTF8([%d] %s) vs. UTF-16 processing different errors %04lx vs. %04lx",
(int)i, testCase.s,
(long)aN8Info.getErrors(), (long)aNInfo.getErrors());
continue;
}
if( aT8Info.getErrors()!=aTInfo.getErrors() ||
uT8Info.getErrors()!=uTInfo.getErrors()
) {
errln("T.xyzUTF8([%d] %s) vs. UTF-16 processing different errors %04lx vs. %04lx",
(int)i, testCase.s,
(long)aT8Info.getErrors(), (long)aTInfo.getErrors());
continue;
}
if(aT16!=aT || uT16!=uT || aN16!=aN || uN16!=uN) {
errln("%s.xyzUTF8([%d] %s) vs. UTF-16 processing different string results",
testCase.o, (int)i, testCase.s, (long)aTInfo.getErrors());
continue;
}
if( aT8Info.isTransitionalDifferent()!=aTInfo.isTransitionalDifferent() ||
uT8Info.isTransitionalDifferent()!=uTInfo.isTransitionalDifferent() ||
aN8Info.isTransitionalDifferent()!=aNInfo.isTransitionalDifferent() ||
uN8Info.isTransitionalDifferent()!=uNInfo.isTransitionalDifferent()
) {
errln("%s.xyzUTF8([%d] %s) vs. UTF-16 processing different isTransitionalDifferent()",
testCase.o, (int)i, testCase.s);
continue;
}
}
}
namespace {
const int32_t kNumFields = 7;
void U_CALLCONV
idnaTestLineFn(void *context,
char *fields[][2], int32_t /* fieldCount */,
UErrorCode *pErrorCode) {
reinterpret_cast<UTS46Test *>(context)->idnaTestOneLine(fields, *pErrorCode);
}
UnicodeString s16FromField(char *(&field)[2]) {
int32_t length = (int32_t)(field[1] - field[0]);
return UnicodeString::fromUTF8(StringPiece(field[0], length)).trim().unescape();
}
std::string statusFromField(char *(&field)[2]) {
const char *start = u_skipWhitespace(field[0]);
std::string status;
if (start != field[1]) {
int32_t length = (int32_t)(field[1] - start);
while (length > 0 && (start[length - 1] == u' ' || start[length - 1] == u'\t')) {
--length;
}
status.assign(start, length);
}
return status;
}
} // namespace
void UTS46Test::checkIdnaTestResult(const char *line, const char *type,
const UnicodeString &expected, const UnicodeString &result,
const char *status, const IDNAInfo &info) {
// An error in toUnicode or toASCII is indicated by a value in square brackets,
// such as "[B5 B6]".
UBool expectedHasErrors = FALSE;
if (*status != 0) {
if (*status != u'[') {
errln("%s status field does not start with '[': %s\n %s", type, status, line);
}
if (strcmp(status, reinterpret_cast<const char*>(u8"[]")) != 0) {
expectedHasErrors = TRUE;
}
}
if (expectedHasErrors != info.hasErrors()) {
errln("%s expected errors %s %d != %d = actual has errors: %04lx\n %s",
type, status, expectedHasErrors, info.hasErrors(), (long)info.getErrors(), line);
}
if (!expectedHasErrors && expected != result) {
errln("%s expected != actual\n %s", type, line);
errln(UnicodeString(u" ") + expected);
errln(UnicodeString(u" ") + result);
}
}
void UTS46Test::idnaTestOneLine(char *fields[][2], UErrorCode &errorCode) {
// IdnaTestV2.txt (since Unicode 11)
// Column 1: source
// The source string to be tested
UnicodeString source = s16FromField(fields[0]);
// Column 2: toUnicode
// The result of applying toUnicode to the source, with Transitional_Processing=false.
// A blank value means the same as the source value.
UnicodeString toUnicode = s16FromField(fields[1]);
if (toUnicode.isEmpty()) {
toUnicode = source;
}
// Column 3: toUnicodeStatus
// A set of status codes, each corresponding to a particular test.
// A blank value means [].
std::string toUnicodeStatus = statusFromField(fields[2]);
// Column 4: toAsciiN
// The result of applying toASCII to the source, with Transitional_Processing=false.
// A blank value means the same as the toUnicode value.
UnicodeString toAsciiN = s16FromField(fields[3]);
if (toAsciiN.isEmpty()) {
toAsciiN = toUnicode;
}
// Column 5: toAsciiNStatus
// A set of status codes, each corresponding to a particular test.
// A blank value means the same as the toUnicodeStatus value.
std::string toAsciiNStatus = statusFromField(fields[4]);
if (toAsciiNStatus.empty()) {
toAsciiNStatus = toUnicodeStatus;
}
// Column 6: toAsciiT
// The result of applying toASCII to the source, with Transitional_Processing=true.
// A blank value means the same as the toAsciiN value.
UnicodeString toAsciiT = s16FromField(fields[5]);
if (toAsciiT.isEmpty()) {
toAsciiT = toAsciiN;
}
// Column 7: toAsciiTStatus
// A set of status codes, each corresponding to a particular test.
// A blank value means the same as the toAsciiNStatus value.
std::string toAsciiTStatus = statusFromField(fields[6]);
if (toAsciiTStatus.empty()) {
toAsciiTStatus = toAsciiNStatus;
}
// ToASCII/ToUnicode, transitional/nontransitional
UnicodeString uN, aN, aT;
IDNAInfo uNInfo, aNInfo, aTInfo;
nontrans->nameToUnicode(source, uN, uNInfo, errorCode);
checkIdnaTestResult(fields[0][0], "toUnicodeNontrans", toUnicode, uN,
toUnicodeStatus.c_str(), uNInfo);
nontrans->nameToASCII(source, aN, aNInfo, errorCode);
checkIdnaTestResult(fields[0][0], "toASCIINontrans", toAsciiN, aN,
toAsciiNStatus.c_str(), aNInfo);
trans->nameToASCII(source, aT, aTInfo, errorCode);
checkIdnaTestResult(fields[0][0], "toASCIITrans", toAsciiT, aT,
toAsciiTStatus.c_str(), aTInfo);
}
// TODO: de-duplicate
U_DEFINE_LOCAL_OPEN_POINTER(LocalStdioFilePointer, FILE, fclose);
// http://www.unicode.org/Public/idna/latest/IdnaTest.txt
void UTS46Test::IdnaTest() {
IcuTestErrorCode errorCode(*this, "IdnaTest");
const char *sourceTestDataPath = getSourceTestData(errorCode);
if (errorCode.errIfFailureAndReset("unable to find the source/test/testdata "
"folder (getSourceTestData())")) {
return;
}
CharString path(sourceTestDataPath, errorCode);
path.appendPathPart("IdnaTestV2.txt", errorCode);
LocalStdioFilePointer idnaTestFile(fopen(path.data(), "r"));
if (idnaTestFile.isNull()) {
errln("unable to open %s", path.data());
return;
}
// Columns (c1, c2,...) are separated by semicolons.
// Leading and trailing spaces and tabs in each column are ignored.
// Comments are indicated with hash marks.
char *fields[kNumFields][2];
u_parseDelimitedFile(path.data(), ';', fields, kNumFields, idnaTestLineFn, this, errorCode);
if (errorCode.errIfFailureAndReset("error parsing IdnaTest.txt")) {
return;
}
}
#endif // UCONFIG_NO_IDNA