/* ******************************************************************************* * Copyright (C) 1997-2012, International Business Machines Corporation and * * others. All Rights Reserved. * ******************************************************************************* * * File FMTABLE.CPP * * Modification History: * * Date Name Description * 03/25/97 clhuang Initial Implementation. ******************************************************************************** */ #include "unicode/utypes.h" #if !UCONFIG_NO_FORMATTING #include <math.h> #include "unicode/fmtable.h" #include "unicode/ustring.h" #include "unicode/measure.h" #include "unicode/curramt.h" #include "charstr.h" #include "cmemory.h" #include "cstring.h" #include "decNumber.h" #include "digitlst.h" // ***************************************************************************** // class Formattable // ***************************************************************************** U_NAMESPACE_BEGIN UOBJECT_DEFINE_RTTI_IMPLEMENTATION(Formattable) #include "fmtableimp.h" //-.-.-.-.-.-.-.-.-.-.-.-.-.-.-.-.-.-.-.-.-.-.-.-.-.-.-.-.-.-.-.-.-.-.-. // NOTE: As of 3.0, there are limitations to the UObject API. It does // not (yet) support cloning, operator=, nor operator==. To // work around this, I implement some simple inlines here. Later // these can be modified or removed. [alan] // NOTE: These inlines assume that all fObjects are in fact instances // of the Measure class, which is true as of 3.0. [alan] // Return TRUE if *a == *b. static inline UBool objectEquals(const UObject* a, const UObject* b) { // LATER: return *a == *b; return *((const Measure*) a) == *((const Measure*) b); } // Return a clone of *a. static inline UObject* objectClone(const UObject* a) { // LATER: return a->clone(); return ((const Measure*) a)->clone(); } // Return TRUE if *a is an instance of Measure. static inline UBool instanceOfMeasure(const UObject* a) { return dynamic_cast<const Measure*>(a) != NULL; } /** * Creates a new Formattable array and copies the values from the specified * original. * @param array the original array * @param count the original array count * @return the new Formattable array. */ static Formattable* createArrayCopy(const Formattable* array, int32_t count) { Formattable *result = new Formattable[count]; if (result != NULL) { for (int32_t i=0; i<count; ++i) result[i] = array[i]; // Don't memcpy! } return result; } //-.-.-.-.-.-.-.-.-.-.-.-.-.-.-.-.-.-.-.-.-.-.-.-.-.-.-.-.-.-.-.-.-.-.-. /** * Set 'ec' to 'err' only if 'ec' is not already set to a failing UErrorCode. */ static void setError(UErrorCode& ec, UErrorCode err) { if (U_SUCCESS(ec)) { ec = err; } } // // Common initialization code, shared by constructors. // Put everything into a known state. // void Formattable::init() { fValue.fInt64 = 0; fType = kLong; fDecimalStr = NULL; fDecimalNum = NULL; fBogus.setToBogus(); } // ------------------------------------- // default constructor. // Creates a formattable object with a long value 0. Formattable::Formattable() { init(); } // ------------------------------------- // Creates a formattable object with a Date instance. Formattable::Formattable(UDate date, ISDATE /*isDate*/) { init(); fType = kDate; fValue.fDate = date; } // ------------------------------------- // Creates a formattable object with a double value. Formattable::Formattable(double value) { init(); fType = kDouble; fValue.fDouble = value; } // ------------------------------------- // Creates a formattable object with an int32_t value. Formattable::Formattable(int32_t value) { init(); fValue.fInt64 = value; } // ------------------------------------- // Creates a formattable object with an int64_t value. Formattable::Formattable(int64_t value) { init(); fType = kInt64; fValue.fInt64 = value; } // ------------------------------------- // Creates a formattable object with a decimal number value from a string. Formattable::Formattable(const StringPiece &number, UErrorCode &status) { init(); setDecimalNumber(number, status); } // ------------------------------------- // Creates a formattable object with a UnicodeString instance. Formattable::Formattable(const UnicodeString& stringToCopy) { init(); fType = kString; fValue.fString = new UnicodeString(stringToCopy); } // ------------------------------------- // Creates a formattable object with a UnicodeString* value. // (adopting symantics) Formattable::Formattable(UnicodeString* stringToAdopt) { init(); fType = kString; fValue.fString = stringToAdopt; } Formattable::Formattable(UObject* objectToAdopt) { init(); fType = kObject; fValue.fObject = objectToAdopt; } // ------------------------------------- Formattable::Formattable(const Formattable* arrayToCopy, int32_t count) : UObject(), fType(kArray) { init(); fType = kArray; fValue.fArrayAndCount.fArray = createArrayCopy(arrayToCopy, count); fValue.fArrayAndCount.fCount = count; } // ------------------------------------- // copy constructor Formattable::Formattable(const Formattable &source) : UObject(*this) { init(); *this = source; } // ------------------------------------- // assignment operator Formattable& Formattable::operator=(const Formattable& source) { if (this != &source) { // Disposes the current formattable value/setting. dispose(); // Sets the correct data type for this value. fType = source.fType; switch (fType) { case kArray: // Sets each element in the array one by one and records the array count. fValue.fArrayAndCount.fCount = source.fValue.fArrayAndCount.fCount; fValue.fArrayAndCount.fArray = createArrayCopy(source.fValue.fArrayAndCount.fArray, source.fValue.fArrayAndCount.fCount); break; case kString: // Sets the string value. fValue.fString = new UnicodeString(*source.fValue.fString); break; case kDouble: // Sets the double value. fValue.fDouble = source.fValue.fDouble; break; case kLong: case kInt64: // Sets the long value. fValue.fInt64 = source.fValue.fInt64; break; case kDate: // Sets the Date value. fValue.fDate = source.fValue.fDate; break; case kObject: fValue.fObject = objectClone(source.fValue.fObject); break; } UErrorCode status = U_ZERO_ERROR; if (source.fDecimalNum != NULL) { fDecimalNum = new DigitList(*source.fDecimalNum); // TODO: use internal digit list } if (source.fDecimalStr != NULL) { fDecimalStr = new CharString(*source.fDecimalStr, status); if (U_FAILURE(status)) { delete fDecimalStr; fDecimalStr = NULL; } } } return *this; } // ------------------------------------- UBool Formattable::operator==(const Formattable& that) const { int32_t i; if (this == &that) return TRUE; // Returns FALSE if the data types are different. if (fType != that.fType) return FALSE; // Compares the actual data values. UBool equal = TRUE; switch (fType) { case kDate: equal = (fValue.fDate == that.fValue.fDate); break; case kDouble: equal = (fValue.fDouble == that.fValue.fDouble); break; case kLong: case kInt64: equal = (fValue.fInt64 == that.fValue.fInt64); break; case kString: equal = (*(fValue.fString) == *(that.fValue.fString)); break; case kArray: if (fValue.fArrayAndCount.fCount != that.fValue.fArrayAndCount.fCount) { equal = FALSE; break; } // Checks each element for equality. for (i=0; i<fValue.fArrayAndCount.fCount; ++i) { if (fValue.fArrayAndCount.fArray[i] != that.fValue.fArrayAndCount.fArray[i]) { equal = FALSE; break; } } break; case kObject: if (fValue.fObject == NULL || that.fValue.fObject == NULL) { equal = FALSE; } else { equal = objectEquals(fValue.fObject, that.fValue.fObject); } break; } // TODO: compare digit lists if numeric. return equal; } // ------------------------------------- Formattable::~Formattable() { dispose(); } // ------------------------------------- void Formattable::dispose() { // Deletes the data value if necessary. switch (fType) { case kString: delete fValue.fString; break; case kArray: delete[] fValue.fArrayAndCount.fArray; break; case kObject: delete fValue.fObject; break; default: break; } fType = kLong; fValue.fInt64 = 0; delete fDecimalStr; fDecimalStr = NULL; FmtStackData *stackData = (FmtStackData*)fStackData; if(fDecimalNum != &(stackData->stackDecimalNum)) { delete fDecimalNum; } else { fDecimalNum->~DigitList(); // destruct, don't deallocate } fDecimalNum = NULL; } Formattable * Formattable::clone() const { return new Formattable(*this); } // ------------------------------------- // Gets the data type of this Formattable object. Formattable::Type Formattable::getType() const { return fType; } UBool Formattable::isNumeric() const { switch (fType) { case kDouble: case kLong: case kInt64: return TRUE; default: return FALSE; } } // ------------------------------------- int32_t //Formattable::getLong(UErrorCode* status) const Formattable::getLong(UErrorCode& status) const { if (U_FAILURE(status)) { return 0; } switch (fType) { case Formattable::kLong: return (int32_t)fValue.fInt64; case Formattable::kInt64: if (fValue.fInt64 > INT32_MAX) { status = U_INVALID_FORMAT_ERROR; return INT32_MAX; } else if (fValue.fInt64 < INT32_MIN) { status = U_INVALID_FORMAT_ERROR; return INT32_MIN; } else { return (int32_t)fValue.fInt64; } case Formattable::kDouble: if (fValue.fDouble > INT32_MAX) { status = U_INVALID_FORMAT_ERROR; return INT32_MAX; } else if (fValue.fDouble < INT32_MIN) { status = U_INVALID_FORMAT_ERROR; return INT32_MIN; } else { return (int32_t)fValue.fDouble; // loses fraction } case Formattable::kObject: if (fValue.fObject == NULL) { status = U_MEMORY_ALLOCATION_ERROR; return 0; } // TODO Later replace this with instanceof call if (instanceOfMeasure(fValue.fObject)) { return ((const Measure*) fValue.fObject)-> getNumber().getLong(status); } default: status = U_INVALID_FORMAT_ERROR; return 0; } } // ------------------------------------- // Maximum int that can be represented exactly in a double. (53 bits) // Larger ints may be rounded to a near-by value as not all are representable. // TODO: move this constant elsewhere, possibly configure it for different // floating point formats, if any non-standard ones are still in use. static const int64_t U_DOUBLE_MAX_EXACT_INT = 9007199254740992LL; int64_t Formattable::getInt64(UErrorCode& status) const { if (U_FAILURE(status)) { return 0; } switch (fType) { case Formattable::kLong: case Formattable::kInt64: return fValue.fInt64; case Formattable::kDouble: if (fValue.fDouble > (double)U_INT64_MAX) { status = U_INVALID_FORMAT_ERROR; return U_INT64_MAX; } else if (fValue.fDouble < (double)U_INT64_MIN) { status = U_INVALID_FORMAT_ERROR; return U_INT64_MIN; } else if (fabs(fValue.fDouble) > U_DOUBLE_MAX_EXACT_INT && fDecimalNum != NULL) { int64_t val = fDecimalNum->getInt64(); if (val != 0) { return val; } else { status = U_INVALID_FORMAT_ERROR; return fValue.fDouble > 0 ? U_INT64_MAX : U_INT64_MIN; } } else { return (int64_t)fValue.fDouble; } case Formattable::kObject: if (fValue.fObject == NULL) { status = U_MEMORY_ALLOCATION_ERROR; return 0; } if (instanceOfMeasure(fValue.fObject)) { return ((const Measure*) fValue.fObject)-> getNumber().getInt64(status); } default: status = U_INVALID_FORMAT_ERROR; return 0; } } // ------------------------------------- double Formattable::getDouble(UErrorCode& status) const { if (U_FAILURE(status)) { return 0; } switch (fType) { case Formattable::kLong: case Formattable::kInt64: // loses precision return (double)fValue.fInt64; case Formattable::kDouble: return fValue.fDouble; case Formattable::kObject: if (fValue.fObject == NULL) { status = U_MEMORY_ALLOCATION_ERROR; return 0; } // TODO Later replace this with instanceof call if (instanceOfMeasure(fValue.fObject)) { return ((const Measure*) fValue.fObject)-> getNumber().getDouble(status); } default: status = U_INVALID_FORMAT_ERROR; return 0; } } const UObject* Formattable::getObject() const { return (fType == kObject) ? fValue.fObject : NULL; } // ------------------------------------- // Sets the value to a double value d. void Formattable::setDouble(double d) { dispose(); fType = kDouble; fValue.fDouble = d; } // ------------------------------------- // Sets the value to a long value l. void Formattable::setLong(int32_t l) { dispose(); fType = kLong; fValue.fInt64 = l; } // ------------------------------------- // Sets the value to an int64 value ll. void Formattable::setInt64(int64_t ll) { dispose(); fType = kInt64; fValue.fInt64 = ll; } // ------------------------------------- // Sets the value to a Date instance d. void Formattable::setDate(UDate d) { dispose(); fType = kDate; fValue.fDate = d; } // ------------------------------------- // Sets the value to a string value stringToCopy. void Formattable::setString(const UnicodeString& stringToCopy) { dispose(); fType = kString; fValue.fString = new UnicodeString(stringToCopy); } // ------------------------------------- // Sets the value to an array of Formattable objects. void Formattable::setArray(const Formattable* array, int32_t count) { dispose(); fType = kArray; fValue.fArrayAndCount.fArray = createArrayCopy(array, count); fValue.fArrayAndCount.fCount = count; } // ------------------------------------- // Adopts the stringToAdopt value. void Formattable::adoptString(UnicodeString* stringToAdopt) { dispose(); fType = kString; fValue.fString = stringToAdopt; } // ------------------------------------- // Adopts the array value and its count. void Formattable::adoptArray(Formattable* array, int32_t count) { dispose(); fType = kArray; fValue.fArrayAndCount.fArray = array; fValue.fArrayAndCount.fCount = count; } void Formattable::adoptObject(UObject* objectToAdopt) { dispose(); fType = kObject; fValue.fObject = objectToAdopt; } // ------------------------------------- UnicodeString& Formattable::getString(UnicodeString& result, UErrorCode& status) const { if (fType != kString) { setError(status, U_INVALID_FORMAT_ERROR); result.setToBogus(); } else { if (fValue.fString == NULL) { setError(status, U_MEMORY_ALLOCATION_ERROR); } else { result = *fValue.fString; } } return result; } // ------------------------------------- const UnicodeString& Formattable::getString(UErrorCode& status) const { if (fType != kString) { setError(status, U_INVALID_FORMAT_ERROR); return *getBogus(); } if (fValue.fString == NULL) { setError(status, U_MEMORY_ALLOCATION_ERROR); return *getBogus(); } return *fValue.fString; } // ------------------------------------- UnicodeString& Formattable::getString(UErrorCode& status) { if (fType != kString) { setError(status, U_INVALID_FORMAT_ERROR); return *getBogus(); } if (fValue.fString == NULL) { setError(status, U_MEMORY_ALLOCATION_ERROR); return *getBogus(); } return *fValue.fString; } // ------------------------------------- const Formattable* Formattable::getArray(int32_t& count, UErrorCode& status) const { if (fType != kArray) { setError(status, U_INVALID_FORMAT_ERROR); count = 0; return NULL; } count = fValue.fArrayAndCount.fCount; return fValue.fArrayAndCount.fArray; } // ------------------------------------- // Gets the bogus string, ensures mondo bogosity. UnicodeString* Formattable::getBogus() const { return (UnicodeString*)&fBogus; /* cast away const :-( */ } // -------------------------------------- StringPiece Formattable::getDecimalNumber(UErrorCode &status) { if (U_FAILURE(status)) { return ""; } if (fDecimalStr != NULL) { return fDecimalStr->toStringPiece(); } if (fDecimalNum == NULL) { // No decimal number for the formattable yet. Which means the value was // set directly by the user as an int, int64 or double. If the value came // from parsing, or from the user setting a decimal number, fDecimalNum // would already be set. // fDecimalNum = new DigitList; // TODO: use internal digit list if (fDecimalNum == NULL) { status = U_MEMORY_ALLOCATION_ERROR; return ""; } switch (fType) { case kDouble: fDecimalNum->set(this->getDouble()); break; case kLong: fDecimalNum->set(this->getLong()); break; case kInt64: fDecimalNum->set(this->getInt64()); break; default: // The formattable's value is not a numeric type. status = U_INVALID_STATE_ERROR; return ""; } } fDecimalStr = new CharString; if (fDecimalStr == NULL) { status = U_MEMORY_ALLOCATION_ERROR; return ""; } fDecimalNum->getDecimal(*fDecimalStr, status); return fDecimalStr->toStringPiece(); } DigitList * Formattable::getInternalDigitList() { FmtStackData *stackData = (FmtStackData*)fStackData; if(fDecimalNum != &(stackData->stackDecimalNum)) { delete fDecimalNum; fDecimalNum = new (&(stackData->stackDecimalNum), kOnStack) DigitList(); } else { fDecimalNum->clear(); } return fDecimalNum; } // --------------------------------------- void Formattable::adoptDigitList(DigitList *dl) { if(fDecimalNum==dl) { fDecimalNum = NULL; // don't delete } dispose(); fDecimalNum = dl; if(dl==NULL) { // allow adoptDigitList(NULL) to clear return; } // Set the value into the Union of simple type values. // Cannot use the set() functions because they would delete the fDecimalNum value, if (fDecimalNum->fitsIntoLong(FALSE)) { fType = kLong; fValue.fInt64 = fDecimalNum->getLong(); } else if (fDecimalNum->fitsIntoInt64(FALSE)) { fType = kInt64; fValue.fInt64 = fDecimalNum->getInt64(); } else { fType = kDouble; fValue.fDouble = fDecimalNum->getDouble(); } } // --------------------------------------- void Formattable::setDecimalNumber(const StringPiece &numberString, UErrorCode &status) { if (U_FAILURE(status)) { return; } dispose(); // Copy the input string and nul-terminate it. // The decNumber library requires nul-terminated input. StringPiece input // is not guaranteed nul-terminated. Too bad. // CharString automatically adds the nul. DigitList *dnum = new DigitList(); // TODO: use getInternalDigitList if (dnum == NULL) { status = U_MEMORY_ALLOCATION_ERROR; return; } dnum->set(CharString(numberString, status).toStringPiece(), status); if (U_FAILURE(status)) { delete dnum; return; // String didn't contain a decimal number. } adoptDigitList(dnum); // Note that we do not hang on to the caller's input string. // If we are asked for the string, we will regenerate one from fDecimalNum. } #if 0 //---------------------------------------------------- // console I/O //---------------------------------------------------- #ifdef _DEBUG #include <iostream> using namespace std; #include "unicode/datefmt.h" #include "unistrm.h" class FormattableStreamer /* not : public UObject because all methods are static */ { public: static void streamOut(ostream& stream, const Formattable& obj); private: FormattableStreamer() {} // private - forbid instantiation }; // This is for debugging purposes only. This will send a displayable // form of the Formattable object to the output stream. void FormattableStreamer::streamOut(ostream& stream, const Formattable& obj) { static DateFormat *defDateFormat = 0; UnicodeString buffer; switch(obj.getType()) { case Formattable::kDate : // Creates a DateFormat instance for formatting the // Date instance. if (defDateFormat == 0) { defDateFormat = DateFormat::createInstance(); } defDateFormat->format(obj.getDate(), buffer); stream << buffer; break; case Formattable::kDouble : // Output the double as is. stream << obj.getDouble() << 'D'; break; case Formattable::kLong : // Output the double as is. stream << obj.getLong() << 'L'; break; case Formattable::kString: // Output the double as is. Please see UnicodeString console // I/O routine for more details. stream << '"' << obj.getString(buffer) << '"'; break; case Formattable::kArray: int32_t i, count; const Formattable* array; array = obj.getArray(count); stream << '['; // Recursively calling the console I/O routine for each element in the array. for (i=0; i<count; ++i) { FormattableStreamer::streamOut(stream, array[i]); stream << ( (i==(count-1)) ? "" : ", " ); } stream << ']'; break; default: // Not a recognizable Formattable object. stream << "INVALID_Formattable"; } stream.flush(); } #endif #endif U_NAMESPACE_END #endif /* #if !UCONFIG_NO_FORMATTING */ //eof