// © 2017 and later: Unicode, Inc. and others. // License & terms of use: http://www.unicode.org/copyright.html #include "unicode/utypes.h" #if !UCONFIG_NO_FORMATTING && !UPRV_INCOMPLETE_CPP11_SUPPORT #include "number_stringbuilder.h" #include "unicode/utf16.h" #include "uvectr32.h" using namespace icu; using namespace icu::number; using namespace icu::number::impl; namespace { // A version of uprv_memcpy that checks for length 0. // By default, uprv_memcpy requires a length of at least 1. inline void uprv_memcpy2(void* dest, const void* src, size_t len) { if (len > 0) { uprv_memcpy(dest, src, len); } } // A version of uprv_memmove that checks for length 0. // By default, uprv_memmove requires a length of at least 1. inline void uprv_memmove2(void* dest, const void* src, size_t len) { if (len > 0) { uprv_memmove(dest, src, len); } } } // namespace NumberStringBuilder::NumberStringBuilder() = default; NumberStringBuilder::~NumberStringBuilder() { if (fUsingHeap) { uprv_free(fChars.heap.ptr); uprv_free(fFields.heap.ptr); } } NumberStringBuilder::NumberStringBuilder(const NumberStringBuilder &other) { *this = other; } NumberStringBuilder &NumberStringBuilder::operator=(const NumberStringBuilder &other) { // Check for self-assignment if (this == &other) { return *this; } // Continue with deallocation and copying if (fUsingHeap) { uprv_free(fChars.heap.ptr); uprv_free(fFields.heap.ptr); fUsingHeap = false; } int32_t capacity = other.getCapacity(); if (capacity > DEFAULT_CAPACITY) { // FIXME: uprv_malloc // C++ note: malloc appears in two places: here and in prepareForInsertHelper. auto newChars = static_cast<char16_t *> (uprv_malloc(sizeof(char16_t) * capacity)); auto newFields = static_cast<Field *>(uprv_malloc(sizeof(Field) * capacity)); if (newChars == nullptr || newFields == nullptr) { // UErrorCode is not available; fail silently. uprv_free(newChars); uprv_free(newFields); *this = NumberStringBuilder(); // can't fail return *this; } fUsingHeap = true; fChars.heap.capacity = capacity; fChars.heap.ptr = newChars; fFields.heap.capacity = capacity; fFields.heap.ptr = newFields; } uprv_memcpy2(getCharPtr(), other.getCharPtr(), sizeof(char16_t) * capacity); uprv_memcpy2(getFieldPtr(), other.getFieldPtr(), sizeof(Field) * capacity); fZero = other.fZero; fLength = other.fLength; return *this; } int32_t NumberStringBuilder::length() const { return fLength; } int32_t NumberStringBuilder::codePointCount() const { return u_countChar32(getCharPtr() + fZero, fLength); } UChar32 NumberStringBuilder::getFirstCodePoint() const { if (fLength == 0) { return -1; } UChar32 cp; U16_GET(getCharPtr() + fZero, 0, 0, fLength, cp); return cp; } UChar32 NumberStringBuilder::getLastCodePoint() const { if (fLength == 0) { return -1; } int32_t offset = fLength; U16_BACK_1(getCharPtr() + fZero, 0, offset); UChar32 cp; U16_GET(getCharPtr() + fZero, 0, offset, fLength, cp); return cp; } UChar32 NumberStringBuilder::codePointAt(int32_t index) const { UChar32 cp; U16_GET(getCharPtr() + fZero, 0, index, fLength, cp); return cp; } UChar32 NumberStringBuilder::codePointBefore(int32_t index) const { int32_t offset = index; U16_BACK_1(getCharPtr() + fZero, 0, offset); UChar32 cp; U16_GET(getCharPtr() + fZero, 0, offset, fLength, cp); return cp; } NumberStringBuilder &NumberStringBuilder::clear() { // TODO: Reset the heap here? fZero = getCapacity() / 2; fLength = 0; return *this; } int32_t NumberStringBuilder::appendCodePoint(UChar32 codePoint, Field field, UErrorCode &status) { return insertCodePoint(fLength, codePoint, field, status); } int32_t NumberStringBuilder::insertCodePoint(int32_t index, UChar32 codePoint, Field field, UErrorCode &status) { int32_t count = U16_LENGTH(codePoint); int32_t position = prepareForInsert(index, count, status); if (U_FAILURE(status)) { return count; } if (count == 1) { getCharPtr()[position] = (char16_t) codePoint; getFieldPtr()[position] = field; } else { getCharPtr()[position] = U16_LEAD(codePoint); getCharPtr()[position + 1] = U16_TRAIL(codePoint); getFieldPtr()[position] = getFieldPtr()[position + 1] = field; } return count; } int32_t NumberStringBuilder::append(const UnicodeString &unistr, Field field, UErrorCode &status) { return insert(fLength, unistr, field, status); } int32_t NumberStringBuilder::insert(int32_t index, const UnicodeString &unistr, Field field, UErrorCode &status) { if (unistr.length() == 0) { // Nothing to insert. return 0; } else if (unistr.length() == 1) { // Fast path: insert using insertCodePoint. return insertCodePoint(index, unistr.charAt(0), field, status); } else { return insert(index, unistr, 0, unistr.length(), field, status); } } int32_t NumberStringBuilder::insert(int32_t index, const UnicodeString &unistr, int32_t start, int32_t end, Field field, UErrorCode &status) { int32_t count = end - start; int32_t position = prepareForInsert(index, count, status); if (U_FAILURE(status)) { return count; } for (int32_t i = 0; i < count; i++) { getCharPtr()[position + i] = unistr.charAt(start + i); getFieldPtr()[position + i] = field; } return count; } int32_t NumberStringBuilder::append(const NumberStringBuilder &other, UErrorCode &status) { return insert(fLength, other, status); } int32_t NumberStringBuilder::insert(int32_t index, const NumberStringBuilder &other, UErrorCode &status) { if (this == &other) { status = U_ILLEGAL_ARGUMENT_ERROR; return 0; } int32_t count = other.fLength; if (count == 0) { // Nothing to insert. return 0; } int32_t position = prepareForInsert(index, count, status); if (U_FAILURE(status)) { return count; } for (int32_t i = 0; i < count; i++) { getCharPtr()[position + i] = other.charAt(i); getFieldPtr()[position + i] = other.fieldAt(i); } return count; } int32_t NumberStringBuilder::prepareForInsert(int32_t index, int32_t count, UErrorCode &status) { if (index == 0 && fZero - count >= 0) { // Append to start fZero -= count; fLength += count; return fZero; } else if (index == fLength && fZero + fLength + count < getCapacity()) { // Append to end fLength += count; return fZero + fLength - count; } else { // Move chars around and/or allocate more space return prepareForInsertHelper(index, count, status); } } int32_t NumberStringBuilder::prepareForInsertHelper(int32_t index, int32_t count, UErrorCode &status) { int32_t oldCapacity = getCapacity(); int32_t oldZero = fZero; char16_t *oldChars = getCharPtr(); Field *oldFields = getFieldPtr(); if (fLength + count > oldCapacity) { int32_t newCapacity = (fLength + count) * 2; int32_t newZero = newCapacity / 2 - (fLength + count) / 2; // C++ note: malloc appears in two places: here and in the assignment operator. auto newChars = static_cast<char16_t *> (uprv_malloc(sizeof(char16_t) * newCapacity)); auto newFields = static_cast<Field *>(uprv_malloc(sizeof(Field) * newCapacity)); if (newChars == nullptr || newFields == nullptr) { uprv_free(newChars); uprv_free(newFields); status = U_MEMORY_ALLOCATION_ERROR; return -1; } // First copy the prefix and then the suffix, leaving room for the new chars that the // caller wants to insert. // C++ note: memcpy is OK because the src and dest do not overlap. uprv_memcpy2(newChars + newZero, oldChars + oldZero, sizeof(char16_t) * index); uprv_memcpy2(newChars + newZero + index + count, oldChars + oldZero + index, sizeof(char16_t) * (fLength - index)); uprv_memcpy2(newFields + newZero, oldFields + oldZero, sizeof(Field) * index); uprv_memcpy2(newFields + newZero + index + count, oldFields + oldZero + index, sizeof(Field) * (fLength - index)); if (fUsingHeap) { uprv_free(oldChars); uprv_free(oldFields); } fUsingHeap = true; fChars.heap.ptr = newChars; fChars.heap.capacity = newCapacity; fFields.heap.ptr = newFields; fFields.heap.capacity = newCapacity; fZero = newZero; fLength += count; } else { int32_t newZero = oldCapacity / 2 - (fLength + count) / 2; // C++ note: memmove is required because src and dest may overlap. // First copy the entire string to the location of the prefix, and then move the suffix // to make room for the new chars that the caller wants to insert. uprv_memmove2(oldChars + newZero, oldChars + oldZero, sizeof(char16_t) * fLength); uprv_memmove2(oldChars + newZero + index + count, oldChars + newZero + index, sizeof(char16_t) * (fLength - index)); uprv_memmove2(oldFields + newZero, oldFields + oldZero, sizeof(Field) * fLength); uprv_memmove2(oldFields + newZero + index + count, oldFields + newZero + index, sizeof(Field) * (fLength - index)); fZero = newZero; fLength += count; } return fZero + index; } UnicodeString NumberStringBuilder::toUnicodeString() const { return UnicodeString(getCharPtr() + fZero, fLength); } UnicodeString NumberStringBuilder::toDebugString() const { UnicodeString sb; sb.append(u"<NumberStringBuilder [", -1); sb.append(toUnicodeString()); sb.append(u"] [", -1); for (int i = 0; i < fLength; i++) { if (fieldAt(i) == UNUM_FIELD_COUNT) { sb.append(u'n'); } else { char16_t c; switch (fieldAt(i)) { case UNUM_SIGN_FIELD: c = u'-'; break; case UNUM_INTEGER_FIELD: c = u'i'; break; case UNUM_FRACTION_FIELD: c = u'f'; break; case UNUM_EXPONENT_FIELD: c = u'e'; break; case UNUM_EXPONENT_SIGN_FIELD: c = u'+'; break; case UNUM_EXPONENT_SYMBOL_FIELD: c = u'E'; break; case UNUM_DECIMAL_SEPARATOR_FIELD: c = u'.'; break; case UNUM_GROUPING_SEPARATOR_FIELD: c = u','; break; case UNUM_PERCENT_FIELD: c = u'%'; break; case UNUM_PERMILL_FIELD: c = u'‰'; break; case UNUM_CURRENCY_FIELD: c = u'$'; break; default: c = u'?'; break; } sb.append(c); } } sb.append(u"]>", -1); return sb; } const char16_t *NumberStringBuilder::chars() const { return getCharPtr() + fZero; } bool NumberStringBuilder::contentEquals(const NumberStringBuilder &other) const { if (fLength != other.fLength) { return false; } for (int32_t i = 0; i < fLength; i++) { if (charAt(i) != other.charAt(i) || fieldAt(i) != other.fieldAt(i)) { return false; } } return true; } void NumberStringBuilder::populateFieldPosition(FieldPosition &fp, int32_t offset, UErrorCode &status) const { int32_t rawField = fp.getField(); if (rawField == FieldPosition::DONT_CARE) { return; } if (rawField < 0 || rawField >= UNUM_FIELD_COUNT) { status = U_ILLEGAL_ARGUMENT_ERROR; return; } auto field = static_cast<Field>(rawField); bool seenStart = false; int32_t fractionStart = -1; for (int i = fZero; i <= fZero + fLength; i++) { Field _field = UNUM_FIELD_COUNT; if (i < fZero + fLength) { _field = getFieldPtr()[i]; } if (seenStart && field != _field) { // Special case: GROUPING_SEPARATOR counts as an INTEGER. if (field == UNUM_INTEGER_FIELD && _field == UNUM_GROUPING_SEPARATOR_FIELD) { continue; } fp.setEndIndex(i - fZero + offset); break; } else if (!seenStart && field == _field) { fp.setBeginIndex(i - fZero + offset); seenStart = true; } if (_field == UNUM_INTEGER_FIELD || _field == UNUM_DECIMAL_SEPARATOR_FIELD) { fractionStart = i - fZero + 1; } } // Backwards compatibility: FRACTION needs to start after INTEGER if empty if (field == UNUM_FRACTION_FIELD && !seenStart) { fp.setBeginIndex(fractionStart + offset); fp.setEndIndex(fractionStart + offset); } } void NumberStringBuilder::populateFieldPositionIterator(FieldPositionIterator &fpi, UErrorCode &status) const { // TODO: Set an initial capacity on uvec? LocalPointer <UVector32> uvec(new UVector32(status)); if (U_FAILURE(status)) { return; } Field current = UNUM_FIELD_COUNT; int32_t currentStart = -1; for (int32_t i = 0; i < fLength; i++) { Field field = fieldAt(i); if (current == UNUM_INTEGER_FIELD && field == UNUM_GROUPING_SEPARATOR_FIELD) { // Special case: GROUPING_SEPARATOR counts as an INTEGER. // Add the field, followed by the start index, followed by the end index to uvec. uvec->addElement(UNUM_GROUPING_SEPARATOR_FIELD, status); uvec->addElement(i, status); uvec->addElement(i + 1, status); } else if (current != field) { if (current != UNUM_FIELD_COUNT) { // Add the field, followed by the start index, followed by the end index to uvec. uvec->addElement(current, status); uvec->addElement(currentStart, status); uvec->addElement(i, status); } current = field; currentStart = i; } if (U_FAILURE(status)) { return; } } if (current != UNUM_FIELD_COUNT) { // Add the field, followed by the start index, followed by the end index to uvec. uvec->addElement(current, status); uvec->addElement(currentStart, status); uvec->addElement(fLength, status); } // Give uvec to the FieldPositionIterator, which adopts it. fpi.setData(uvec.orphan(), status); } #endif /* #if !UCONFIG_NO_FORMATTING */