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/****************************************************************************
**
** Copyright (C) 2009 Nokia Corporation and/or its subsidiary(-ies).
** Contact: Nokia Corporation (qt-info@nokia.com)
**
** This file is part of the QtXmlPatterns module of the Qt Toolkit.
**
** $QT_BEGIN_LICENSE:LGPL$
** No Commercial Usage
** This file contains pre-release code and may not be distributed.
** You may use this file in accordance with the terms and conditions
** contained in the either Technology Preview License Agreement or the
** Beta Release License Agreement.
**
** GNU Lesser General Public License Usage
** Alternatively, this file may be used under the terms of the GNU Lesser
** General Public License version 2.1 as published by the Free Software
** Foundation and appearing in the file LICENSE.LGPL included in the
** packaging of this file. Please review the following information to
** ensure the GNU Lesser General Public License version 2.1 requirements
** will be met: http://www.gnu.org/licenses/old-licenses/lgpl-2.1.html.
**
** In addition, as a special exception, Nokia gives you certain
** additional rights. These rights are described in the Nokia Qt LGPL
** Exception version 1.0, included in the file LGPL_EXCEPTION.txt in this
** package.
**
** GNU General Public License Usage
** Alternatively, this file may be used under the terms of the GNU
** General Public License version 3.0 as published by the Free Software
** Foundation and appearing in the file LICENSE.GPL included in the
** packaging of this file. Please review the following information to
** ensure the GNU General Public License version 3.0 requirements will be
** met: http://www.gnu.org/copyleft/gpl.html.
**
** If you are unsure which license is appropriate for your use, please
** contact the sales department at http://qt.nokia.com/contact.
** $QT_END_LICENSE$
**
****************************************************************************/
/**
* @file
* @short This file is included by qabstractfloat_p.h.
* If you need includes in this file, put them in qabstractfloat_p.h, outside of the namespace.
*/
template <const bool isDouble>
AbstractFloat<isDouble>::AbstractFloat(const xsDouble num) : m_value(num)
{
}
template <const bool isDouble>
Numeric::Ptr AbstractFloat<isDouble>::fromValue(const xsDouble num)
{
return Numeric::Ptr(new AbstractFloat<isDouble>(num));
}
template <const bool isDouble>
AtomicValue::Ptr AbstractFloat<isDouble>::fromLexical(const QString &strNumeric)
{
/* QString::toDouble() handles the whitespace facet. */
if(strNumeric == QLatin1String("NaN"))
return isDouble ? CommonValues::DoubleNaN : CommonValues::FloatNaN;
else if(strNumeric == QLatin1String("-INF"))
return isDouble ? CommonValues::NegativeInfDouble : CommonValues::NegativeInfFloat;
else if(strNumeric == QLatin1String("INF"))
return isDouble ? CommonValues::InfDouble : CommonValues::InfFloat;
/* QString::toDouble() supports any case as well as +INF, but we don't. */
const QString toUpper(strNumeric.toUpper());
if(toUpper == QLatin1String("-INF") ||
toUpper == QLatin1String("INF") ||
toUpper == QLatin1String("+INF") ||
toUpper == QLatin1String("NAN"))
{
return ValidationError::createError();
}
bool conversionOk = false;
const xsDouble num = strNumeric.toDouble(&conversionOk);
if(conversionOk)
return AtomicValue::Ptr(new AbstractFloat<isDouble>(num));
else
return ValidationError::createError();
}
template <const bool isDouble>
int AbstractFloat<isDouble>::internalSignbit(const xsDouble num)
{
Q_ASSERT_X(sizeof(xsDouble) == 8 || sizeof(xsDouble) == 4, Q_FUNC_INFO,
"This implementation of signbit assumes xsDouble, that is qreal, is 64 bits large.");
union
{
xsDouble asDouble;
qint64 asInt;
} value;
value.asDouble = num;
/* The highest bit, the 64'th for those who have 64bit floats, is the sign bit. So we pull it down until that bit is the
* only one left. */
if(sizeof(xsDouble) == 8)
return value.asInt >> 63;
else
return value.asInt >> 31;
}
template <const bool isDouble>
bool AbstractFloat<isDouble>::isEqual(const xsDouble a, const xsDouble b)
{
if(qIsInf(a))
return qIsInf(b) && internalSignbit(a) == internalSignbit(b);
else if(qIsInf(b))
return qIsInf(a) && internalSignbit(a) == internalSignbit(b);
else
{
/* Preferrably, we would use std::numeric_limits<xsDouble>::espilon(), but
* we cannot since we cannot depend on the STL. The small xs:double value below,
* was extracted by printing the std::numeric_limits<xsDouble>::epsilon() using
* gdb. */
return qAbs(a - b) <= 2.2204460492503131e-16 * qAbs(a);
}
}
template <const bool isDouble>
bool AbstractFloat<isDouble>::isZero() const
{
return AbstractFloat<isDouble>::isEqual(m_value, 0.0);
}
template <const bool isDouble>
bool AbstractFloat<isDouble>::evaluateEBV(const QExplicitlySharedDataPointer<DynamicContext> &) const
{
if(isZero() || qIsNaN(m_value))
return false;
else
return true;
}
template <const bool isDouble>
QString AbstractFloat<isDouble>::stringValue() const
{
if(qIsNaN(m_value))
return QLatin1String("NaN");
else if(qIsInf(m_value))
return internalSignbit(m_value) == 0 ? QLatin1String("INF") : QLatin1String("-INF");
/*
* If SV has an absolute value that is greater than or equal to 0.000001
* (one millionth) and less than 1000000 (one million),
* then the value is converted to an xs:decimal and the resulting xs:decimal
* is converted to an xs:string according to the rules above.
*/
else if(0.000001 <= qAbs(m_value) && qAbs(m_value) < 1000000.0)
return Decimal::toString(toDecimal());
/*
* If SV has the value positive or negative zero, TV is "0" or "-0" respectively.
*/
else if(isZero())
return internalSignbit(m_value) == 0 ? QLatin1String("0") : QLatin1String("-0");
else
{
/*
* Besides these special values, the general form of the canonical form for
* xs:float and xs:double is a mantissa, which is a xs:decimal, followed by
* the letter "E", followed by an exponent which is an xs:integer.
*/
int sign;
int decimalPoint;
char *result = 0;
static_cast<void>(qdtoa(m_value, -1, 0, &decimalPoint, &sign, 0, &result));
/* If the copy constructor is used instead of QString::operator=(),
* it doesn't compile. I have no idea why. */
const QString qret(QString::fromLatin1(result));
/* We use free() instead of delete here, because qlocale.cpp use malloc(). Spotted
* by valgrind. */
free(result);
QString valueAsString;
if(sign)
valueAsString += QLatin1Char('-');
valueAsString += qret.at(0);
valueAsString += QLatin1Char('.');
if(1 == qret.size())
valueAsString += QLatin1Char('0');
else
valueAsString += qret.mid(1);
valueAsString += QLatin1Char('E');
decimalPoint--;
valueAsString += QString::number(decimalPoint);
return valueAsString;
}
}
template <const bool isDouble>
xsDouble AbstractFloat<isDouble>::toDouble() const
{
return m_value;
}
template <const bool isDouble>
xsInteger AbstractFloat<isDouble>::toInteger() const
{
return static_cast<xsInteger>(m_value);
}
template <const bool isDouble>
xsFloat AbstractFloat<isDouble>::toFloat() const
{
/* No cast, since xsFloat and xsDouble are typedef'ed with the same type. */
return m_value;
}
template <const bool isDouble>
xsDecimal AbstractFloat<isDouble>::toDecimal() const
{
return static_cast<xsDecimal>(m_value);
}
template <const bool isDouble>
Numeric::Ptr AbstractFloat<isDouble>::round() const
{
return AbstractFloat<isDouble>::fromValue(static_cast<xsDouble>(roundFloat(m_value)));
}
template <const bool isDouble>
Numeric::Ptr AbstractFloat<isDouble>::roundHalfToEven(const xsInteger precision) const
{
if(isNaN() || isInf() || isZero())
return Numeric::Ptr(const_cast<AbstractFloat<isDouble> *>(this));
else
{
/* The cast to double helps finding the correct pow() version on irix-cc. */
const xsDouble powered = pow(double(10), double(precision));
xsDouble val = powered * m_value;
bool isHalf = false;
if(val - 0.5 == ::floor(val))
isHalf = true;
val = m_value * powered + 0.5;
val = ::floor(val);
if(isHalf /*&& isOdd(val) or? TODO */)
val -= 1;
val /= powered;
return fromValue(val);
}
}
template <const bool isDouble>
Numeric::Ptr AbstractFloat<isDouble>::floor() const
{
return AbstractFloat<isDouble>::fromValue(static_cast<xsDouble>(::floor(m_value)));
}
template <const bool isDouble>
Numeric::Ptr AbstractFloat<isDouble>::ceiling() const
{
return AbstractFloat<isDouble>::fromValue(static_cast<xsDouble>(ceil(m_value)));
}
template <const bool isDouble>
Numeric::Ptr AbstractFloat<isDouble>::abs() const
{
/* We must use fabs() instead of qAbs() because qAbs()
* doesn't return 0 for -0.0. */
return AbstractFloat<isDouble>::fromValue(static_cast<xsDouble>(fabs(m_value)));
}
template <const bool isDouble>
bool AbstractFloat<isDouble>::isNaN() const
{
return qIsNaN(m_value);
}
template <const bool isDouble>
bool AbstractFloat<isDouble>::isInf() const
{
return qIsInf(m_value);
}
template <const bool isDouble>
ItemType::Ptr AbstractFloat<isDouble>::type() const
{
return isDouble ? BuiltinTypes::xsDouble : BuiltinTypes::xsFloat;
}
template <const bool isDouble>
Item AbstractFloat<isDouble>::toNegated() const
{
return fromValue(-m_value).data();
}
template <const bool isDouble>
bool AbstractFloat<isDouble>::isSigned() const
{
Q_ASSERT_X(false, Q_FUNC_INFO,
"It makes no sense to call this function, see Numeric::isSigned().");
return false;
}
template <const bool isDouble>
qulonglong AbstractFloat<isDouble>::toUnsignedInteger() const
{
Q_ASSERT_X(false, Q_FUNC_INFO,
"It makes no sense to call this function, see Numeric::toUnsignedInteger().");
return 0;
}
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