// © 2016 and later: Unicode, Inc. and others. // License & terms of use: http://www.unicode.org/copyright.html /* ********************************************************************** * Copyright (C) 2001-2009, International Business Machines * Corporation and others. All Rights Reserved. ********************************************************************** * Date Name Description * 05/23/00 aliu Creation. ********************************************************************** */ #include #include #include "unicode/utypes.h" #include "unicode/edits.h" #include "unicode/unistr.h" #include "unicode/utf16.h" #include "cmemory.h" #include "testutil.h" #include "intltest.h" static const UChar HEX[] = u"0123456789ABCDEF"; UnicodeString &TestUtility::appendHex(UnicodeString &buf, UChar32 ch) { if (ch >= 0x10000) { if (ch >= 0x100000) { buf.append(HEX[0xF&(ch>>20)]); } buf.append(HEX[0xF&(ch>>16)]); } buf.append(HEX[0xF&(ch>>12)]); buf.append(HEX[0xF&(ch>>8)]); buf.append(HEX[0xF&(ch>>4)]); buf.append(HEX[0xF&ch]); return buf; } UnicodeString TestUtility::hex(UChar32 ch) { UnicodeString buf; appendHex(buf, ch); return buf; } UnicodeString TestUtility::hex(const UnicodeString& s) { return hex(s, u','); } UnicodeString TestUtility::hex(const UnicodeString& s, UChar sep) { UnicodeString result; if (s.isEmpty()) return result; UChar32 c; for (int32_t i = 0; i < s.length(); i += U16_LENGTH(c)) { c = s.char32At(i); if (i > 0) { result.append(sep); } appendHex(result, c); } return result; } UnicodeString TestUtility::hex(const uint8_t* bytes, int32_t len) { UnicodeString buf; for (int32_t i = 0; i < len; ++i) { buf.append(HEX[0x0F & (bytes[i] >> 4)]); buf.append(HEX[0x0F & bytes[i]]); } return buf; } namespace { UnicodeString printOneEdit(const Edits::Iterator &ei) { if (ei.hasChange()) { return UnicodeString() + ei.oldLength() + u"->" + ei.newLength(); } else { return UnicodeString() + ei.oldLength() + u"=" + ei.newLength(); } } /** * Maps indexes according to the expected edits. * A destination index can occur multiple times when there are source deletions. * Map according to the last occurrence, normally in a non-empty destination span. * Simplest is to search from the back. */ int32_t srcIndexFromDest(const EditChange expected[], int32_t expLength, int32_t srcLength, int32_t destLength, int32_t index) { int32_t srcIndex = srcLength; int32_t destIndex = destLength; int32_t i = expLength; while (index < destIndex && i > 0) { --i; int32_t prevSrcIndex = srcIndex - expected[i].oldLength; int32_t prevDestIndex = destIndex - expected[i].newLength; if (index == prevDestIndex) { return prevSrcIndex; } else if (index > prevDestIndex) { if (expected[i].change) { // In a change span, map to its end. return srcIndex; } else { // In an unchanged span, offset within it. return prevSrcIndex + (index - prevDestIndex); } } srcIndex = prevSrcIndex; destIndex = prevDestIndex; } // index is outside the string. return srcIndex; } int32_t destIndexFromSrc(const EditChange expected[], int32_t expLength, int32_t srcLength, int32_t destLength, int32_t index) { int32_t srcIndex = srcLength; int32_t destIndex = destLength; int32_t i = expLength; while (index < srcIndex && i > 0) { --i; int32_t prevSrcIndex = srcIndex - expected[i].oldLength; int32_t prevDestIndex = destIndex - expected[i].newLength; if (index == prevSrcIndex) { return prevDestIndex; } else if (index > prevSrcIndex) { if (expected[i].change) { // In a change span, map to its end. return destIndex; } else { // In an unchanged span, offset within it. return prevDestIndex + (index - prevSrcIndex); } } srcIndex = prevSrcIndex; destIndex = prevDestIndex; } // index is outside the string. return destIndex; } } // namespace // For debugging, set -v to see matching edits up to a failure. UBool TestUtility::checkEqualEdits(IntlTest &test, const UnicodeString &name, const Edits &e1, const Edits &e2, UErrorCode &errorCode) { Edits::Iterator ei1 = e1.getFineIterator(); Edits::Iterator ei2 = e2.getFineIterator(); UBool ok = true; for (int32_t i = 0; ok; ++i) { UBool ei1HasNext = ei1.next(errorCode); UBool ei2HasNext = ei2.next(errorCode); ok &= test.assertEquals(name + u" next()[" + i + u"]" + __LINE__, ei1HasNext, ei2HasNext); ok &= test.assertSuccess(name + u" errorCode[" + i + u"]" + __LINE__, errorCode); ok &= test.assertEquals(name + u" edit[" + i + u"]" + __LINE__, printOneEdit(ei1), printOneEdit(ei2)); if (!ei1HasNext || !ei2HasNext) { break; } test.logln(); } return ok; } void TestUtility::checkEditsIter( IntlTest &test, const UnicodeString &name, Edits::Iterator ei1, Edits::Iterator ei2, // two equal iterators const EditChange expected[], int32_t expLength, UBool withUnchanged, UErrorCode &errorCode) { test.assertFalse(name + u":" + __LINE__, ei2.findSourceIndex(-1, errorCode)); test.assertFalse(name + u":" + __LINE__, ei2.findDestinationIndex(-1, errorCode)); int32_t expSrcIndex = 0; int32_t expDestIndex = 0; int32_t expReplIndex = 0; for (int32_t expIndex = 0; expIndex < expLength; ++expIndex) { const EditChange &expect = expected[expIndex]; UnicodeString msg = UnicodeString(name).append(u' ') + expIndex; if (withUnchanged || expect.change) { test.assertTrue(msg + u":" + __LINE__, ei1.next(errorCode)); test.assertEquals(msg + u":" + __LINE__, expect.change, ei1.hasChange()); test.assertEquals(msg + u":" + __LINE__, expect.oldLength, ei1.oldLength()); test.assertEquals(msg + u":" + __LINE__, expect.newLength, ei1.newLength()); test.assertEquals(msg + u":" + __LINE__, expSrcIndex, ei1.sourceIndex()); test.assertEquals(msg + u":" + __LINE__, expDestIndex, ei1.destinationIndex()); test.assertEquals(msg + u":" + __LINE__, expReplIndex, ei1.replacementIndex()); } if (expect.oldLength > 0) { test.assertTrue(msg + u":" + __LINE__, ei2.findSourceIndex(expSrcIndex, errorCode)); test.assertEquals(msg + u":" + __LINE__, expect.change, ei2.hasChange()); test.assertEquals(msg + u":" + __LINE__, expect.oldLength, ei2.oldLength()); test.assertEquals(msg + u":" + __LINE__, expect.newLength, ei2.newLength()); test.assertEquals(msg + u":" + __LINE__, expSrcIndex, ei2.sourceIndex()); test.assertEquals(msg + u":" + __LINE__, expDestIndex, ei2.destinationIndex()); test.assertEquals(msg + u":" + __LINE__, expReplIndex, ei2.replacementIndex()); if (!withUnchanged) { // For some iterators, move past the current range // so that findSourceIndex() has to look before the current index. ei2.next(errorCode); ei2.next(errorCode); } } if (expect.newLength > 0) { test.assertTrue(msg + u":" + __LINE__, ei2.findDestinationIndex(expDestIndex, errorCode)); test.assertEquals(msg + u":" + __LINE__, expect.change, ei2.hasChange()); test.assertEquals(msg + u":" + __LINE__, expect.oldLength, ei2.oldLength()); test.assertEquals(msg + u":" + __LINE__, expect.newLength, ei2.newLength()); test.assertEquals(msg + u":" + __LINE__, expSrcIndex, ei2.sourceIndex()); test.assertEquals(msg + u":" + __LINE__, expDestIndex, ei2.destinationIndex()); test.assertEquals(msg + u":" + __LINE__, expReplIndex, ei2.replacementIndex()); if (!withUnchanged) { // For some iterators, move past the current range // so that findSourceIndex() has to look before the current index. ei2.next(errorCode); ei2.next(errorCode); } } expSrcIndex += expect.oldLength; expDestIndex += expect.newLength; if (expect.change) { expReplIndex += expect.newLength; } } UnicodeString msg = UnicodeString(name).append(u" end"); test.assertFalse(msg + u":" + __LINE__, ei1.next(errorCode)); test.assertFalse(msg + u":" + __LINE__, ei1.hasChange()); test.assertEquals(msg + u":" + __LINE__, 0, ei1.oldLength()); test.assertEquals(msg + u":" + __LINE__, 0, ei1.newLength()); test.assertEquals(msg + u":" + __LINE__, expSrcIndex, ei1.sourceIndex()); test.assertEquals(msg + u":" + __LINE__, expDestIndex, ei1.destinationIndex()); test.assertEquals(msg + u":" + __LINE__, expReplIndex, ei1.replacementIndex()); test.assertFalse(name + u":" + __LINE__, ei2.findSourceIndex(expSrcIndex, errorCode)); test.assertFalse(name + u":" + __LINE__, ei2.findDestinationIndex(expDestIndex, errorCode)); // Check mapping of all indexes against a simple implementation // that works on the expected changes. // Iterate once forward, once backward, to cover more runtime conditions. int32_t srcLength = expSrcIndex; int32_t destLength = expDestIndex; std::vector srcIndexes; std::vector destIndexes; srcIndexes.push_back(-1); destIndexes.push_back(-1); int32_t srcIndex = 0; int32_t destIndex = 0; for (int32_t i = 0; i < expLength; ++i) { if (expected[i].oldLength > 0) { srcIndexes.push_back(srcIndex); if (expected[i].oldLength > 1) { srcIndexes.push_back(srcIndex + 1); if (expected[i].oldLength > 2) { srcIndexes.push_back(srcIndex + expected[i].oldLength - 1); } } } if (expected[i].newLength > 0) { destIndexes.push_back(destIndex); if (expected[i].newLength > 1) { destIndexes.push_back(destIndex + 1); if (expected[i].newLength > 2) { destIndexes.push_back(destIndex + expected[i].newLength - 1); } } } srcIndex += expected[i].oldLength; destIndex += expected[i].newLength; } srcIndexes.push_back(srcLength); destIndexes.push_back(destLength); srcIndexes.push_back(srcLength + 1); destIndexes.push_back(destLength + 1); std::reverse(destIndexes.begin(), destIndexes.end()); // Zig-zag across the indexes to stress next() <-> previous(). static const int32_t ZIG_ZAG[] = { 0, 1, 2, 3, 2, 1 }; for (auto i = 0; i < (int32_t)srcIndexes.size(); ++i) { for (int32_t ij = 0; ij < UPRV_LENGTHOF(ZIG_ZAG); ++ij) { int32_t j = ZIG_ZAG[ij]; if ((i + j) < (int32_t)srcIndexes.size()) { int32_t si = srcIndexes[i + j]; test.assertEquals(name + u" destIndexFromSrc(" + si + u"):" + __LINE__, destIndexFromSrc(expected, expLength, srcLength, destLength, si), ei2.destinationIndexFromSourceIndex(si, errorCode)); } } } for (auto i = 0; i < (int32_t)destIndexes.size(); ++i) { for (int32_t ij = 0; ij < UPRV_LENGTHOF(ZIG_ZAG); ++ij) { int32_t j = ZIG_ZAG[ij]; if ((i + j) < (int32_t)destIndexes.size()) { int32_t di = destIndexes[i + j]; test.assertEquals(name + u" srcIndexFromDest(" + di + u"):" + __LINE__, srcIndexFromDest(expected, expLength, srcLength, destLength, di), ei2.sourceIndexFromDestinationIndex(di, errorCode)); } } } }