All Downloads are FREE. Search and download functionalities are using the official Maven repository.

net.sf.saxon.expr.CastExpression Maven / Gradle / Ivy

There is a newer version: 12.5
Show newest version
////////////////////////////////////////////////////////////////////////////////////////////////////////////////////
// Copyright (c) 2018-2022 Saxonica Limited
// This Source Code Form is subject to the terms of the Mozilla Public License, v. 2.0.
// If a copy of the MPL was not distributed with this file, You can obtain one at http://mozilla.org/MPL/2.0/.
// This Source Code Form is "Incompatible With Secondary Licenses", as defined by the Mozilla Public License, v. 2.0.
////////////////////////////////////////////////////////////////////////////////////////////////////////////////////

package net.sf.saxon.expr;


import net.sf.saxon.Configuration;
import net.sf.saxon.expr.parser.*;
import net.sf.saxon.functions.String_1;
import net.sf.saxon.lib.ConversionRules;
import net.sf.saxon.om.GroundedValue;
import net.sf.saxon.om.Sequence;
import net.sf.saxon.om.SequenceTool;
import net.sf.saxon.trace.ExpressionPresenter;
import net.sf.saxon.trans.XPathException;
import net.sf.saxon.type.*;
import net.sf.saxon.value.*;


/**
 * Cast Expression: implements "cast as data-type ( expression )". It also allows an internal
 * cast, which has the same semantics as a user-requested cast, but maps an empty sequence to
 * an empty sequence.
 * 

This expression class does not handle casting to a list or union type.

*/ public class CastExpression extends CastingExpression implements Callable { /** * Create a cast expression * * @param source expression giving the value to be converted * @param target the type to which the value is to be converted * @param allowEmpty true if the expression allows an empty sequence as input, producing * an empty sequence as output. If false, an empty sequence is a type error. */ public CastExpression(Expression source, AtomicType target, boolean allowEmpty) { super(source, target, allowEmpty); } /** * Type-check the expression */ /*@NotNull*/ @Override public Expression typeCheck(ExpressionVisitor visitor, ContextItemStaticInfo contextInfo) throws XPathException { getOperand().typeCheck(visitor, contextInfo); SequenceType atomicType = SequenceType.makeSequenceType(BuiltInAtomicType.ANY_ATOMIC, getCardinality()); Configuration config = visitor.getConfiguration(); final TypeHierarchy th = config.getTypeHierarchy(); RoleDiagnostic role = new RoleDiagnostic(RoleDiagnostic.TYPE_OP, "cast as", 0); ItemType sourceItemType; TypeChecker tc = config.getTypeChecker(false); Expression operand = tc.staticTypeCheck(getBaseExpression(), atomicType, role, visitor); setBaseExpression(operand); sourceItemType = operand.getItemType(); if (sourceItemType instanceof ErrorType) { if (allowsEmpty()) { return Literal.makeEmptySequence(); } else { XPathException err = new XPathException("Cast does not allow an empty sequence as input"); err.setErrorCode("XPTY0004"); err.setLocation(getLocation()); err.setIsTypeError(true); throw err; } } PlainType sourceType = (PlainType) sourceItemType; Affinity r = th.relationship(sourceType, getTargetType()); if (r == Affinity.SAME_TYPE) { return operand; } else if (r == Affinity.SUBSUMED_BY) { // It's generally true that any expression defined to return an X is allowed to return a subtype of X. // However, people seem to get upset if we treat the cast as a no-op. converter = new Converter.UpCastingConverter(getTargetType()); } else { ConversionRules rules = visitor.getConfiguration().getConversionRules(); if (sourceType.isAtomicType() && sourceType != BuiltInAtomicType.ANY_ATOMIC) { converter = rules.getConverter((AtomicType)sourceType, getTargetType()); if (converter == null) { XPathException err = new XPathException("Casting from " + sourceType + " to " + getTargetType() + " can never succeed"); err.setErrorCode("XPTY0004"); err.setLocation(getLocation()); err.setIsTypeError(true); throw err; } else { if (getTargetType().isNamespaceSensitive()) { converter = converter.setNamespaceResolver(getRetainedStaticContext()); } } } } if (operand instanceof Literal) { return preEvaluate(); } return this; } /** * Perform optimisation of an expression and its subexpressions. *

This method is called after all references to functions and variables have been resolved * to the declaration of the function or variable, and after all type checking has been done.

* * @param visitor an expression visitor * @param contextInfo the static type of "." at the point where this expression is invoked. * The parameter is set to null if it is known statically that the context item will be undefined. * If the type of the context item is not known statically, the argument is set to * {@link net.sf.saxon.type.Type#ITEM_TYPE} * @return the original expression, rewritten if appropriate to optimize execution * @throws net.sf.saxon.trans.XPathException * if an error is discovered during this phase * (typically a type error) */ /*@NotNull*/ @Override public Expression optimize(ExpressionVisitor visitor, ContextItemStaticInfo contextInfo) throws XPathException { final TypeHierarchy th = visitor.getConfiguration().getTypeHierarchy(); Expression e2 = super.optimize(visitor, contextInfo); if (e2 != this) { return e2; } // Eliminate pointless casting between untypedAtomic and string Expression operand = getBaseExpression(); if (getTargetType() == BuiltInAtomicType.UNTYPED_ATOMIC) { if (operand.isCallOn(String_1.class)) { Expression e = ((SystemFunctionCall) operand).getArg(0); if (e.getItemType() instanceof AtomicType && e.getCardinality() == StaticProperty.EXACTLY_ONE) { return new CastExpression(e, BuiltInAtomicType.UNTYPED_ATOMIC, allowsEmpty()); } } else if (operand instanceof CastExpression) { if (((CastExpression) operand).getTargetType() == BuiltInAtomicType.UNTYPED_ATOMIC) { return operand; } else if (((CastExpression) operand).getTargetType() == BuiltInAtomicType.STRING) { ((CastExpression) operand).setTargetType(BuiltInAtomicType.UNTYPED_ATOMIC); return operand; } } else if (operand instanceof AtomicSequenceConverter) { if (operand.getItemType() == BuiltInAtomicType.UNTYPED_ATOMIC) { return operand; } else if (operand.getItemType() == BuiltInAtomicType.STRING) { AtomicSequenceConverter old = (AtomicSequenceConverter) operand; AtomicSequenceConverter asc = new AtomicSequenceConverter( old.getBaseExpression(), BuiltInAtomicType.UNTYPED_ATOMIC ); return asc.typeCheck(visitor, contextInfo) .optimize(visitor, contextInfo); } } } // avoid converting anything to a string and then back again if (operand.isCallOn(String_1.class)) { Expression e = ((SystemFunctionCall) operand).getArg(0); ItemType et = e.getItemType(); if (et instanceof AtomicType && e.getCardinality() == StaticProperty.EXACTLY_ONE && th.isSubType(et, getTargetType())) { return e; } } // avoid converting anything to untypedAtomic and then back again if (operand instanceof CastExpression) { ItemType it = ((CastExpression) operand).getTargetType(); if (th.isSubType(it, BuiltInAtomicType.STRING) || th.isSubType(it, BuiltInAtomicType.UNTYPED_ATOMIC)) { Expression e = ((CastExpression) operand).getBaseExpression(); ItemType et = e.getItemType(); if (et instanceof AtomicType && e.getCardinality() == StaticProperty.EXACTLY_ONE && th.isSubType(et, getTargetType())) { return e; } } } if (operand instanceof AtomicSequenceConverter) { ItemType it = operand.getItemType(); if (th.isSubType(it, BuiltInAtomicType.STRING) || th.isSubType(it, BuiltInAtomicType.UNTYPED_ATOMIC)) { Expression e = ((AtomicSequenceConverter) operand).getBaseExpression(); ItemType et = e.getItemType(); if (et instanceof AtomicType && e.getCardinality() == StaticProperty.EXACTLY_ONE && th.isSubType(et, getTargetType())) { return e; } } } // if the operand can't be empty, then set allowEmpty to false to provide more information for analysis if (!Cardinality.allowsZero(operand.getCardinality())) { setAllowEmpty(false); resetLocalStaticProperties(); } if (operand instanceof Literal) { return preEvaluate(); } return this; } /** * Perform early (compile-time) evaluation, if possible * @return the result of pre-evaluation, or the original expression unchanged * @throws XPathException if an error is found */ protected Expression preEvaluate() throws XPathException { GroundedValue literalOperand = ((Literal) getBaseExpression()).getGroundedValue(); if (literalOperand instanceof AtomicValue && converter != null) { ConversionResult result = converter.convert((AtomicValue) literalOperand); if (result instanceof ValidationFailure) { ValidationFailure err = (ValidationFailure) result; String code = err.getErrorCode(); if (code == null) { code = "FORG0001"; } throw new XPathException(err.getMessage(), code, this.getLocation()); } else { return Literal.makeLiteral((AtomicValue) result, this); } } if (literalOperand.getLength() == 0) { if (allowsEmpty()) { return getBaseExpression(); } else { XPathException err = new XPathException("Cast can never succeed: the operand must not be an empty sequence", "XPTY0004", this.getLocation()); err.setIsTypeError(true); throw err; } } return this; } /** * Get the static cardinality of the expression */ @Override protected int computeCardinality() { return allowsEmpty() && Cardinality.allowsZero(getBaseExpression().getCardinality()) ? StaticProperty.ALLOWS_ZERO_OR_ONE : StaticProperty.EXACTLY_ONE; } /** * Get the static type of the expression */ /*@NotNull*/ @Override public ItemType getItemType() { return getTargetType(); } /** * Get the static type of the expression as a UType, following precisely the type * inference rules defined in the XSLT 3.0 specification. * * @return the static item type of the expression according to the XSLT 3.0 defined rules * @param contextItemType static information about the context item */ @Override public UType getStaticUType(UType contextItemType) { return getTargetType().getUType(); } /** * Determine the special properties of this expression * @return the expression properties */ @Override protected int computeSpecialProperties() { int p = super.computeSpecialProperties(); if (getTargetType() == BuiltInAtomicType.UNTYPED_ATOMIC) { p = p &~ StaticProperty.NOT_UNTYPED_ATOMIC; } return p; } /** * For an expression that returns an integer or a sequence of integers, get * a lower and upper bound on the values of the integers that may be returned, from * static analysis. The default implementation returns null, meaning "unknown" or * "not applicable". Other implementations return an array of two IntegerValue objects, * representing the lower and upper bounds respectively. The values * UNBOUNDED_LOWER and UNBOUNDED_UPPER are used by convention to indicate that * the value may be arbitrarily large. The values MAX_STRING_LENGTH and MAX_SEQUENCE_LENGTH * are used to indicate values limited by the size of a string or the size of a sequence. * * @return the lower and upper bounds of integer values in the result, or null to indicate * unknown or not applicable. */ /*@Nullable*/ @Override public IntegerValue[] getIntegerBounds() { if (converter == Converter.BooleanToInteger.INSTANCE) { return new IntegerValue[]{Int64Value.ZERO, Int64Value.PLUS_ONE}; } else { return null; } } /** * Copy an expression. This makes a deep copy. * * @return the copy of the original expression * @param rebindings variables that need to be rebound */ /*@NotNull*/ @Override public Expression copy(RebindingMap rebindings) { CastExpression c2 = new CastExpression(getBaseExpression().copy(rebindings), getTargetType(), allowsEmpty()); ExpressionTool.copyLocationInfo(this, c2); c2.converter = converter; c2.setRetainedStaticContext(getRetainedStaticContext()); c2.setOperandIsStringLiteral(isOperandIsStringLiteral()); return c2; } /** * An implementation of Expression must provide at least one of the methods evaluateItem(), iterate(), or process(). * This method indicates which of these methods is provided directly. The other methods will always be available * indirectly, using an implementation that relies on one of the other methods. * * @return the implementation method, for example {@link #ITERATE_METHOD} or {@link #EVALUATE_METHOD} or * {@link #PROCESS_METHOD} */ @Override public int getImplementationMethod() { return EVALUATE_METHOD; } @Override public Sequence call(XPathContext context, Sequence[] arguments) throws XPathException { AtomicValue result = doCast((AtomicValue)arguments[0].head(), context); return SequenceTool.itemOrEmpty(result); } private AtomicValue doCast(AtomicValue value, XPathContext context) throws XPathException { if (value == null) { if (allowsEmpty()) { return null; } else { XPathException e = new XPathException("Cast does not allow an empty sequence"); e.setXPathContext(context); e.setLocation(getLocation()); e.setErrorCode("XPTY0004"); throw e; } } Converter converter = this.converter; if (converter == null) { ConversionRules rules = context.getConfiguration().getConversionRules(); converter = rules.getConverter(value.getPrimitiveType(), getTargetType()); if (converter == null) { XPathException e = new XPathException("Casting from " + value.getPrimitiveType() + " to " + getTargetType() + " is not permitted"); e.setXPathContext(context); e.setLocation(getLocation()); e.setErrorCode("XPTY0004"); throw e; } if (getTargetType().isNamespaceSensitive()) { converter = converter.setNamespaceResolver(getRetainedStaticContext()); } } ConversionResult result = converter.convert(value); if (result instanceof ValidationFailure) { ValidationFailure err = (ValidationFailure) result; XPathException xe = err.makeException(); xe.maybeSetErrorCode("FORG0001"); xe.maybeSetLocation(getLocation()); throw xe; } return (AtomicValue) result; } /** * Evaluate the expression */ /*@Nullable*/ @Override public AtomicValue evaluateItem(XPathContext context) throws XPathException { try { AtomicValue value = (AtomicValue) getBaseExpression().evaluateItem(context); return doCast(value, context); } catch (ClassCastException e) { e.printStackTrace(); throw e; } } /** * Is this expression the same as another expression? */ public boolean equals(Object other) { return other instanceof CastExpression && getBaseExpression().isEqual(((CastExpression) other).getBaseExpression()) && getTargetType() == ((CastExpression) other).getTargetType() && allowsEmpty() == ((CastExpression) other).allowsEmpty(); } /** * get HashCode for comparing two expressions. Note that this hashcode gives the same * result for (A op B) and for (B op A), whether or not the operator is commutative. */ @Override protected int computeHashCode() { return super.computeHashCode() ^ getTargetType().hashCode(); } /** * Represent the expression as a string. The resulting string will be a valid XPath 3.0 expression * with no dependencies on namespace bindings. * * @return the expression as a string in XPath 3.0 syntax */ public String toString() { return getTargetType().getEQName() + "(" + getBaseExpression().toString() + ")"; } @Override public String toShortString() { return getTargetType().getDisplayName() + "(" + getBaseExpression().toShortString() + ")"; } /** * Diagnostic print of expression structure. The abstract expression tree * is written to the supplied output destination. */ @Override public void export(ExpressionPresenter out) throws XPathException { export(out, "cast"); } /** * Get a name identifying the kind of expression, in terms meaningful to a user. * * @return a name identifying the kind of expression, in terms meaningful to a user. * The name will always be in the form of a lexical XML QName, and should match the name used * in export() output displaying the expression. */ @Override public String getExpressionName() { return "cast"; } }




© 2015 - 2024 Weber Informatics LLC | Privacy Policy