/**************************************************************************** ** ** Copyright (C) 2016 The Qt Company Ltd. ** Contact: https://www.qt.io/licensing/ ** ** This file is part of the QtXmlPatterns module of the Qt Toolkit. ** ** $QT_BEGIN_LICENSE:LGPL$ ** Commercial License Usage ** Licensees holding valid commercial Qt licenses may use this file in ** accordance with the commercial license agreement provided with the ** Software or, alternatively, in accordance with the terms contained in ** a written agreement between you and The Qt Company. For licensing terms ** and conditions see https://www.qt.io/terms-conditions. For further ** information use the contact form at https://www.qt.io/contact-us. ** ** GNU Lesser General Public License Usage ** Alternatively, this file may be used under the terms of the GNU Lesser ** General Public License version 3 as published by the Free Software ** Foundation and appearing in the file LICENSE.LGPL3 included in the ** packaging of this file. Please review the following information to ** ensure the GNU Lesser General Public License version 3 requirements ** will be met: https://www.gnu.org/licenses/lgpl-3.0.html. ** ** GNU General Public License Usage ** Alternatively, this file may be used under the terms of the GNU ** General Public License version 2.0 or (at your option) the GNU General ** Public license version 3 or any later version approved by the KDE Free ** Qt Foundation. The licenses are as published by the Free Software ** Foundation and appearing in the file LICENSE.GPL2 and LICENSE.GPL3 ** included in the packaging of this file. Please review the following ** information to ensure the GNU General Public License requirements will ** be met: https://www.gnu.org/licenses/gpl-2.0.html and ** https://www.gnu.org/licenses/gpl-3.0.html. ** ** $QT_END_LICENSE$ ** ****************************************************************************/ #include "qboolean_p.h" #include "qbuiltintypes_p.h" #include "qcommonsequencetypes_p.h" #include "qemptysequence_p.h" #include "qgenericsequencetype_p.h" #include "qliteral_p.h" #include "qpatternistlocale_p.h" #include "qschemanumeric_p.h" #include "quntypedatomicconverter_p.h" #include "qarithmeticexpression_p.h" QT_BEGIN_NAMESPACE using namespace QPatternist; ArithmeticExpression::ArithmeticExpression(const Expression::Ptr &op1, const AtomicMathematician::Operator op, const Expression::Ptr &op2) : PairContainer(op1, op2) , m_op(op) , m_isCompat(false) { } Item ArithmeticExpression::evaluateSingleton(const DynamicContext::Ptr &context) const { const Item op1(m_operand1->evaluateSingleton(context)); if(!op1) return Item(); const Item op2(m_operand2->evaluateSingleton(context)); if(!op2) return Item(); return flexiblyCalculate(op1, m_op, op2, m_mather, context, this, ReportContext::XPTY0004, m_isCompat); } /** * Since ArithmeticExpression::flexiblyCalculate() creates Expression instances * at runtime, we have the problem of having SourceLocationReflections for them * in the case that we run into a runtime error, since the locations are always * located at compile time. * * This class simply delegates the reflection over to an existing expression. * * I only managed to trigger this with "current() + 1", where current() * evaluates to an invalid representation for @c xs:double. * * @since 4.5 * @author Frans Englich */ class DelegatingReflectionExpression : public Literal { public: DelegatingReflectionExpression(const Item &item, const SourceLocationReflection *const reflection) : Literal(item) , m_reflection(reflection) { } virtual const SourceLocationReflection *actualReflection() const { return m_reflection; } private: const SourceLocationReflection *const m_reflection; }; Item ArithmeticExpression::flexiblyCalculate(const Item &op1, const AtomicMathematician::Operator op, const Item &op2, const AtomicMathematician::Ptr &mather, const DynamicContext::Ptr &context, const SourceLocationReflection *const reflection, const ReportContext::ErrorCode code, const bool isCompat) { if(mather) return mather->calculate(op1, op, op2, context); /* This is a very heavy code path. */ Expression::Ptr a1(new DelegatingReflectionExpression(op1, reflection)); Expression::Ptr a2(new DelegatingReflectionExpression(op2, reflection)); const AtomicMathematician::Ptr ingela(fetchMathematician(a1, a2, op, true, context, reflection, code, isCompat)); return ingela->calculate(a1->evaluateSingleton(context), op, a2->evaluateSingleton(context), context); } Expression::Ptr ArithmeticExpression::typeCheck(const StaticContext::Ptr &context, const SequenceType::Ptr &reqType) { m_isCompat = context->compatModeEnabled(); const Expression::Ptr me(PairContainer::typeCheck(context, reqType)); const ItemType::Ptr t1(m_operand1->staticType()->itemType()); const ItemType::Ptr t2(m_operand2->staticType()->itemType()); if(*CommonSequenceTypes::Empty == *t1 || *CommonSequenceTypes::Empty == *t2) { return EmptySequence::create(this, context); } if(*BuiltinTypes::xsAnyAtomicType == *t1 || *BuiltinTypes::xsAnyAtomicType == *t2 || *BuiltinTypes::numeric == *t1 || *BuiltinTypes::numeric == *t2) { /* The static type of (at least) one of the operands could not * be narrowed further than xs:anyAtomicType, so we do the operator * lookup at runtime. */ return me; } m_mather = fetchMathematician(m_operand1, m_operand2, m_op, true, context, this, ReportContext::XPTY0004, m_isCompat); return me; } AtomicMathematician::Ptr ArithmeticExpression::fetchMathematician(Expression::Ptr &op1, Expression::Ptr &op2, const AtomicMathematician::Operator op, const bool issueError, const ReportContext::Ptr &context, const SourceLocationReflection *const reflection, const ReportContext::ErrorCode code, const bool isCompat) { ItemType::Ptr t1(op1->staticType()->itemType()); ItemType::Ptr t2(op2->staticType()->itemType()); if(BuiltinTypes::xsUntypedAtomic->xdtTypeMatches(t1) || (isCompat && (BuiltinTypes::xsString->xdtTypeMatches(t1) || BuiltinTypes::xsDecimal->xdtTypeMatches(t1)))) { op1 = Expression::Ptr(new UntypedAtomicConverter(op1, BuiltinTypes::xsDouble)); /* The types might have changed, reload. */ t1 = op1->staticType()->itemType(); } if(BuiltinTypes::xsUntypedAtomic->xdtTypeMatches(t2) || (isCompat && (BuiltinTypes::xsString->xdtTypeMatches(t1) || BuiltinTypes::xsDecimal->xdtTypeMatches(t1)))) { op2 = Expression::Ptr(new UntypedAtomicConverter(op2, BuiltinTypes::xsDouble)); /* The types might have changed, reload. */ t2 = op2->staticType()->itemType(); } const AtomicMathematicianLocator::Ptr locator (static_cast(t1.data())->mathematicianLocator()); if(!locator) { if(!issueError) return AtomicMathematician::Ptr(); context->error(QtXmlPatterns::tr( "Operator %1 cannot be used on type %2.") .arg(formatKeyword(AtomicMathematician::displayName(op))) .arg(formatType(context->namePool(), t1)), code, reflection); return AtomicMathematician::Ptr(); } const AtomicMathematician::Ptr comp (static_cast(t2.data())->accept(locator, op, reflection)); if(comp) return comp; if(!issueError) return AtomicMathematician::Ptr(); context->error(QtXmlPatterns::tr("Operator %1 cannot be used on " "atomic values of type %2 and %3.") .arg(formatKeyword(AtomicMathematician::displayName(op))) .arg(formatType(context->namePool(), t1)) .arg(formatType(context->namePool(), t2)), code, reflection); return AtomicMathematician::Ptr(); } SequenceType::Ptr ArithmeticExpression::staticType() const { Cardinality card; /* These variables are important because they ensure staticType() only * gets called once from this function. Before, this lead to strange * semi-infinite recursion involving many arithmetic expressions. */ const SequenceType::Ptr st1(m_operand1->staticType()); const SequenceType::Ptr st2(m_operand2->staticType()); if(st1->cardinality().allowsEmpty() || st2->cardinality().allowsEmpty()) { card = Cardinality::zeroOrOne(); } else card = Cardinality::exactlyOne(); if(m_op == AtomicMathematician::IDiv) return makeGenericSequenceType(BuiltinTypes::xsInteger, card); const ItemType::Ptr t1(st1->itemType()); const ItemType::Ptr t2(st2->itemType()); ItemType::Ptr returnType; /* Please, make this beautiful? */ if(BuiltinTypes::xsTime->xdtTypeMatches(t1) || BuiltinTypes::xsDate->xdtTypeMatches(t1) || BuiltinTypes::xsDateTime->xdtTypeMatches(t1)) { if(BuiltinTypes::xsDuration->xdtTypeMatches(t2)) returnType = t1; else returnType = BuiltinTypes::xsDayTimeDuration; } else if(BuiltinTypes::xsYearMonthDuration->xdtTypeMatches(t1)) { if(m_op == AtomicMathematician::Div && BuiltinTypes::xsYearMonthDuration->xdtTypeMatches(t2)) { returnType = BuiltinTypes::xsDecimal; } else if(BuiltinTypes::numeric->xdtTypeMatches(t2)) returnType = BuiltinTypes::xsYearMonthDuration; else returnType = t2; } else if(BuiltinTypes::xsYearMonthDuration->xdtTypeMatches(t2)) { returnType = BuiltinTypes::xsYearMonthDuration; } else if(BuiltinTypes::xsDayTimeDuration->xdtTypeMatches(t1)) { if(m_op == AtomicMathematician::Div && BuiltinTypes::xsDayTimeDuration->xdtTypeMatches(t2)) { returnType = BuiltinTypes::xsDecimal; } else if(BuiltinTypes::numeric->xdtTypeMatches(t2)) returnType = BuiltinTypes::xsDayTimeDuration; else returnType = t2; } else if(BuiltinTypes::xsDayTimeDuration->xdtTypeMatches(t2)) { returnType = BuiltinTypes::xsDayTimeDuration; } else if(BuiltinTypes::xsDouble->xdtTypeMatches(t1) || BuiltinTypes::xsDouble->xdtTypeMatches(t2)) { returnType = BuiltinTypes::xsDouble; } else if(BuiltinTypes::xsFloat->xdtTypeMatches(t1) || BuiltinTypes::xsFloat->xdtTypeMatches(t2)) { if(m_isCompat) returnType = BuiltinTypes::xsFloat; else returnType = BuiltinTypes::xsDouble; } else if(BuiltinTypes::xsInteger->xdtTypeMatches(t1) && BuiltinTypes::xsInteger->xdtTypeMatches(t2)) { if(m_isCompat) returnType = BuiltinTypes::xsDouble; else { /* "A div B numeric numeric op:numeric-divide(A, B) * numeric; but xs:decimal if both operands are xs:integer" */ if(m_op == AtomicMathematician::Div) returnType = BuiltinTypes::xsDecimal; else returnType = BuiltinTypes::xsInteger; } } else if(m_isCompat && (BuiltinTypes::xsInteger->xdtTypeMatches(t1) && BuiltinTypes::xsInteger->xdtTypeMatches(t2))) { returnType = BuiltinTypes::xsDouble; } else { /* If typeCheck() has been called, our operands conform to expectedOperandTypes(), and * the types are hence either xs:decimals, or xs:anyAtomicType(meaning the static type could * not be inferred), or empty-sequence(). So we use the union of the two types. The combinations * could also be wrong.*/ returnType = t1 | t2; /* However, if we're called before typeCheck(), we could potentially have nodes, so we need to make * sure that the type is at least atomic. */ if(!BuiltinTypes::xsAnyAtomicType->xdtTypeMatches(returnType)) returnType = BuiltinTypes::xsAnyAtomicType; } return makeGenericSequenceType(returnType, card); } SequenceType::List ArithmeticExpression::expectedOperandTypes() const { SequenceType::List result; result.append(CommonSequenceTypes::ZeroOrOneAtomicType); result.append(CommonSequenceTypes::ZeroOrOneAtomicType); return result; } ExpressionVisitorResult::Ptr ArithmeticExpression::accept(const ExpressionVisitor::Ptr &visitor) const { return visitor->visit(this); } QT_END_NAMESPACE