blob: 8b4e7202b0d3e82ae58ab1abddaf0f5f69539df1 [file] [log] [blame]
/*
* Copyright (C) 2005 Frerich Raabe <raabe@kde.org>
* Copyright (C) 2006, 2009 Apple Inc.
* Copyright (C) 2007 Alexey Proskuryakov <ap@webkit.org>
*
* Redistribution and use in source and binary forms, with or without
* modification, are permitted provided that the following conditions
* are met:
*
* 1. Redistributions of source code must retain the above copyright
* notice, this list of conditions and the following disclaimer.
* 2. Redistributions in binary form must reproduce the above copyright
* notice, this list of conditions and the following disclaimer in the
* documentation and/or other materials provided with the distribution.
*
* THIS SOFTWARE IS PROVIDED BY THE AUTHOR ``AS IS'' AND ANY EXPRESS OR
* IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED WARRANTIES
* OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE ARE DISCLAIMED.
* IN NO EVENT SHALL THE AUTHOR BE LIABLE FOR ANY DIRECT, INDIRECT,
* INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT
* NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE,
* DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY
* THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT
* (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE OF
* THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE.
*/
#include "config.h"
#include "XPathFunctions.h"
#if ENABLE(XPATH)
#include "Document.h"
#include "Element.h"
#include "NamedNodeMap.h"
#include "ProcessingInstruction.h"
#include "XMLNames.h"
#include "XPathUtil.h"
#include "XPathValue.h"
#include <wtf/MathExtras.h>
namespace WebCore {
namespace XPath {
static inline bool isWhitespace(UChar c)
{
return c == ' ' || c == '\n' || c == '\r' || c == '\t';
}
#define DEFINE_FUNCTION_CREATOR(Class) static Function* create##Class() { return new Class; }
class Interval {
public:
static const int Inf = -1;
Interval();
Interval(int value);
Interval(int min, int max);
bool contains(int value) const;
private:
int m_min;
int m_max;
};
struct FunctionRec {
typedef Function *(*FactoryFn)();
FactoryFn factoryFn;
Interval args;
};
static HashMap<String, FunctionRec>* functionMap;
class FunLast : public Function {
virtual Value evaluate() const;
virtual Value::Type resultType() const { return Value::NumberValue; }
public:
FunLast() { setIsContextSizeSensitive(true); }
};
class FunPosition : public Function {
virtual Value evaluate() const;
virtual Value::Type resultType() const { return Value::NumberValue; }
public:
FunPosition() { setIsContextPositionSensitive(true); }
};
class FunCount : public Function {
virtual Value evaluate() const;
virtual Value::Type resultType() const { return Value::NumberValue; }
};
class FunId : public Function {
virtual Value evaluate() const;
virtual Value::Type resultType() const { return Value::NodeSetValue; }
};
class FunLocalName : public Function {
virtual Value evaluate() const;
virtual Value::Type resultType() const { return Value::StringValue; }
public:
FunLocalName() { setIsContextNodeSensitive(true); } // local-name() with no arguments uses context node.
};
class FunNamespaceURI : public Function {
virtual Value evaluate() const;
virtual Value::Type resultType() const { return Value::StringValue; }
public:
FunNamespaceURI() { setIsContextNodeSensitive(true); } // namespace-uri() with no arguments uses context node.
};
class FunName : public Function {
virtual Value evaluate() const;
virtual Value::Type resultType() const { return Value::StringValue; }
public:
FunName() { setIsContextNodeSensitive(true); } // name() with no arguments uses context node.
};
class FunString : public Function {
virtual Value evaluate() const;
virtual Value::Type resultType() const { return Value::StringValue; }
public:
FunString() { setIsContextNodeSensitive(true); } // string() with no arguments uses context node.
};
class FunConcat : public Function {
virtual Value evaluate() const;
virtual Value::Type resultType() const { return Value::StringValue; }
};
class FunStartsWith : public Function {
virtual Value evaluate() const;
virtual Value::Type resultType() const { return Value::BooleanValue; }
};
class FunContains : public Function {
virtual Value evaluate() const;
virtual Value::Type resultType() const { return Value::BooleanValue; }
};
class FunSubstringBefore : public Function {
virtual Value evaluate() const;
virtual Value::Type resultType() const { return Value::StringValue; }
};
class FunSubstringAfter : public Function {
virtual Value evaluate() const;
virtual Value::Type resultType() const { return Value::StringValue; }
};
class FunSubstring : public Function {
virtual Value evaluate() const;
virtual Value::Type resultType() const { return Value::StringValue; }
};
class FunStringLength : public Function {
virtual Value evaluate() const;
virtual Value::Type resultType() const { return Value::NumberValue; }
public:
FunStringLength() { setIsContextNodeSensitive(true); } // string-length() with no arguments uses context node.
};
class FunNormalizeSpace : public Function {
virtual Value evaluate() const;
virtual Value::Type resultType() const { return Value::StringValue; }
public:
FunNormalizeSpace() { setIsContextNodeSensitive(true); } // normalize-space() with no arguments uses context node.
};
class FunTranslate : public Function {
virtual Value evaluate() const;
virtual Value::Type resultType() const { return Value::StringValue; }
};
class FunBoolean : public Function {
virtual Value evaluate() const;
virtual Value::Type resultType() const { return Value::BooleanValue; }
};
class FunNot : public Function {
virtual Value evaluate() const;
virtual Value::Type resultType() const { return Value::BooleanValue; }
};
class FunTrue : public Function {
virtual Value evaluate() const;
virtual Value::Type resultType() const { return Value::BooleanValue; }
};
class FunFalse : public Function {
virtual Value evaluate() const;
virtual Value::Type resultType() const { return Value::BooleanValue; }
};
class FunLang : public Function {
virtual Value evaluate() const;
virtual Value::Type resultType() const { return Value::BooleanValue; }
public:
FunLang() { setIsContextNodeSensitive(true); } // lang() always works on context node.
};
class FunNumber : public Function {
virtual Value evaluate() const;
virtual Value::Type resultType() const { return Value::NumberValue; }
public:
FunNumber() { setIsContextNodeSensitive(true); } // number() with no arguments uses context node.
};
class FunSum : public Function {
virtual Value evaluate() const;
virtual Value::Type resultType() const { return Value::NumberValue; }
};
class FunFloor : public Function {
virtual Value evaluate() const;
virtual Value::Type resultType() const { return Value::NumberValue; }
};
class FunCeiling : public Function {
virtual Value evaluate() const;
virtual Value::Type resultType() const { return Value::NumberValue; }
};
class FunRound : public Function {
virtual Value evaluate() const;
virtual Value::Type resultType() const { return Value::NumberValue; }
public:
static double round(double);
};
DEFINE_FUNCTION_CREATOR(FunLast)
DEFINE_FUNCTION_CREATOR(FunPosition)
DEFINE_FUNCTION_CREATOR(FunCount)
DEFINE_FUNCTION_CREATOR(FunId)
DEFINE_FUNCTION_CREATOR(FunLocalName)
DEFINE_FUNCTION_CREATOR(FunNamespaceURI)
DEFINE_FUNCTION_CREATOR(FunName)
DEFINE_FUNCTION_CREATOR(FunString)
DEFINE_FUNCTION_CREATOR(FunConcat)
DEFINE_FUNCTION_CREATOR(FunStartsWith)
DEFINE_FUNCTION_CREATOR(FunContains)
DEFINE_FUNCTION_CREATOR(FunSubstringBefore)
DEFINE_FUNCTION_CREATOR(FunSubstringAfter)
DEFINE_FUNCTION_CREATOR(FunSubstring)
DEFINE_FUNCTION_CREATOR(FunStringLength)
DEFINE_FUNCTION_CREATOR(FunNormalizeSpace)
DEFINE_FUNCTION_CREATOR(FunTranslate)
DEFINE_FUNCTION_CREATOR(FunBoolean)
DEFINE_FUNCTION_CREATOR(FunNot)
DEFINE_FUNCTION_CREATOR(FunTrue)
DEFINE_FUNCTION_CREATOR(FunFalse)
DEFINE_FUNCTION_CREATOR(FunLang)
DEFINE_FUNCTION_CREATOR(FunNumber)
DEFINE_FUNCTION_CREATOR(FunSum)
DEFINE_FUNCTION_CREATOR(FunFloor)
DEFINE_FUNCTION_CREATOR(FunCeiling)
DEFINE_FUNCTION_CREATOR(FunRound)
#undef DEFINE_FUNCTION_CREATOR
inline Interval::Interval()
: m_min(Inf), m_max(Inf)
{
}
inline Interval::Interval(int value)
: m_min(value), m_max(value)
{
}
inline Interval::Interval(int min, int max)
: m_min(min), m_max(max)
{
}
inline bool Interval::contains(int value) const
{
if (m_min == Inf && m_max == Inf)
return true;
if (m_min == Inf)
return value <= m_max;
if (m_max == Inf)
return value >= m_min;
return value >= m_min && value <= m_max;
}
void Function::setArguments(const Vector<Expression*>& args)
{
ASSERT(!subExprCount());
// Some functions use context node as implicit argument, so when explicit arguments are added, they may no longer be context node sensitive.
if (m_name != "lang" && !args.isEmpty())
setIsContextNodeSensitive(false);
Vector<Expression*>::const_iterator end = args.end();
for (Vector<Expression*>::const_iterator it = args.begin(); it != end; it++)
addSubExpression(*it);
}
Value FunLast::evaluate() const
{
return Expression::evaluationContext().size;
}
Value FunPosition::evaluate() const
{
return Expression::evaluationContext().position;
}
Value FunId::evaluate() const
{
Value a = arg(0)->evaluate();
Vector<UChar> idList; // A whitespace-separated list of IDs
if (a.isNodeSet()) {
const NodeSet& nodes = a.toNodeSet();
for (size_t i = 0; i < nodes.size(); ++i) {
String str = stringValue(nodes[i]);
idList.append(str.characters(), str.length());
idList.append(' ');
}
} else {
String str = a.toString();
idList.append(str.characters(), str.length());
}
Document* contextDocument = evaluationContext().node->document();
NodeSet result;
HashSet<Node*> resultSet;
size_t startPos = 0;
size_t length = idList.size();
while (true) {
while (startPos < length && isWhitespace(idList[startPos]))
++startPos;
if (startPos == length)
break;
size_t endPos = startPos;
while (endPos < length && !isWhitespace(idList[endPos]))
++endPos;
// If there are several nodes with the same id, id() should return the first one.
// In WebKit, getElementById behaves so, too, although its behavior in this case is formally undefined.
Node* node = contextDocument->getElementById(String(&idList[startPos], endPos - startPos));
if (node && resultSet.add(node).second)
result.append(node);
startPos = endPos;
}
result.markSorted(false);
return Value(result, Value::adopt);
}
static inline String expandedNameLocalPart(Node* node)
{
// The local part of an XPath expanded-name matches DOM local name for most node types, except for namespace nodes and processing instruction nodes.
ASSERT(node->nodeType() != Node::XPATH_NAMESPACE_NODE); // Not supported yet.
if (node->nodeType() == Node::PROCESSING_INSTRUCTION_NODE)
return static_cast<ProcessingInstruction*>(node)->target();
return node->localName().string();
}
static inline String expandedName(Node* node)
{
const AtomicString& prefix = node->prefix();
return prefix.isEmpty() ? expandedNameLocalPart(node) : prefix + ":" + expandedNameLocalPart(node);
}
Value FunLocalName::evaluate() const
{
if (argCount() > 0) {
Value a = arg(0)->evaluate();
if (!a.isNodeSet())
return "";
Node* node = a.toNodeSet().firstNode();
return node ? expandedNameLocalPart(node) : "";
}
return expandedNameLocalPart(evaluationContext().node.get());
}
Value FunNamespaceURI::evaluate() const
{
if (argCount() > 0) {
Value a = arg(0)->evaluate();
if (!a.isNodeSet())
return "";
Node* node = a.toNodeSet().firstNode();
return node ? node->namespaceURI().string() : "";
}
return evaluationContext().node->namespaceURI().string();
}
Value FunName::evaluate() const
{
if (argCount() > 0) {
Value a = arg(0)->evaluate();
if (!a.isNodeSet())
return "";
Node* node = a.toNodeSet().firstNode();
return node ? expandedName(node) : "";
}
return expandedName(evaluationContext().node.get());
}
Value FunCount::evaluate() const
{
Value a = arg(0)->evaluate();
return double(a.toNodeSet().size());
}
Value FunString::evaluate() const
{
if (!argCount())
return Value(Expression::evaluationContext().node.get()).toString();
return arg(0)->evaluate().toString();
}
Value FunConcat::evaluate() const
{
Vector<UChar, 1024> result;
unsigned count = argCount();
for (unsigned i = 0; i < count; ++i) {
String str(arg(i)->evaluate().toString());
result.append(str.characters(), str.length());
}
return String(result.data(), result.size());
}
Value FunStartsWith::evaluate() const
{
String s1 = arg(0)->evaluate().toString();
String s2 = arg(1)->evaluate().toString();
if (s2.isEmpty())
return true;
return s1.startsWith(s2);
}
Value FunContains::evaluate() const
{
String s1 = arg(0)->evaluate().toString();
String s2 = arg(1)->evaluate().toString();
if (s2.isEmpty())
return true;
return s1.contains(s2) != 0;
}
Value FunSubstringBefore::evaluate() const
{
String s1 = arg(0)->evaluate().toString();
String s2 = arg(1)->evaluate().toString();
if (s2.isEmpty())
return "";
size_t i = s1.find(s2);
if (i == notFound)
return "";
return s1.left(i);
}
Value FunSubstringAfter::evaluate() const
{
String s1 = arg(0)->evaluate().toString();
String s2 = arg(1)->evaluate().toString();
size_t i = s1.find(s2);
if (i == notFound)
return "";
return s1.substring(i + s2.length());
}
Value FunSubstring::evaluate() const
{
String s = arg(0)->evaluate().toString();
double doublePos = arg(1)->evaluate().toNumber();
if (isnan(doublePos))
return "";
long pos = static_cast<long>(FunRound::round(doublePos));
bool haveLength = argCount() == 3;
long len = -1;
if (haveLength) {
double doubleLen = arg(2)->evaluate().toNumber();
if (isnan(doubleLen))
return "";
len = static_cast<long>(FunRound::round(doubleLen));
}
if (pos > long(s.length()))
return "";
if (pos < 1) {
if (haveLength) {
len -= 1 - pos;
if (len < 1)
return "";
}
pos = 1;
}
return s.substring(pos - 1, len);
}
Value FunStringLength::evaluate() const
{
if (!argCount())
return Value(Expression::evaluationContext().node.get()).toString().length();
return arg(0)->evaluate().toString().length();
}
Value FunNormalizeSpace::evaluate() const
{
if (!argCount()) {
String s = Value(Expression::evaluationContext().node.get()).toString();
return s.simplifyWhiteSpace();
}
String s = arg(0)->evaluate().toString();
return s.simplifyWhiteSpace();
}
Value FunTranslate::evaluate() const
{
String s1 = arg(0)->evaluate().toString();
String s2 = arg(1)->evaluate().toString();
String s3 = arg(2)->evaluate().toString();
String newString;
// FIXME: Building a String a character at a time is quite slow.
for (unsigned i1 = 0; i1 < s1.length(); ++i1) {
UChar ch = s1[i1];
size_t i2 = s2.find(ch);
if (i2 == notFound)
newString += String(&ch, 1);
else if (i2 < s3.length()) {
UChar c2 = s3[i2];
newString += String(&c2, 1);
}
}
return newString;
}
Value FunBoolean::evaluate() const
{
return arg(0)->evaluate().toBoolean();
}
Value FunNot::evaluate() const
{
return !arg(0)->evaluate().toBoolean();
}
Value FunTrue::evaluate() const
{
return true;
}
Value FunLang::evaluate() const
{
String lang = arg(0)->evaluate().toString();
Attribute* languageAttribute = 0;
Node* node = evaluationContext().node.get();
while (node) {
NamedNodeMap* attrs = node->attributes();
if (attrs)
languageAttribute = attrs->getAttributeItem(XMLNames::langAttr);
if (languageAttribute)
break;
node = node->parentNode();
}
if (!languageAttribute)
return false;
String langValue = languageAttribute->value();
while (true) {
if (equalIgnoringCase(langValue, lang))
return true;
// Remove suffixes one by one.
size_t index = langValue.reverseFind('-');
if (index == notFound)
break;
langValue = langValue.left(index);
}
return false;
}
Value FunFalse::evaluate() const
{
return false;
}
Value FunNumber::evaluate() const
{
if (!argCount())
return Value(Expression::evaluationContext().node.get()).toNumber();
return arg(0)->evaluate().toNumber();
}
Value FunSum::evaluate() const
{
Value a = arg(0)->evaluate();
if (!a.isNodeSet())
return 0.0;
double sum = 0.0;
const NodeSet& nodes = a.toNodeSet();
// To be really compliant, we should sort the node-set, as floating point addition is not associative.
// However, this is unlikely to ever become a practical issue, and sorting is slow.
for (unsigned i = 0; i < nodes.size(); i++)
sum += Value(stringValue(nodes[i])).toNumber();
return sum;
}
Value FunFloor::evaluate() const
{
return floor(arg(0)->evaluate().toNumber());
}
Value FunCeiling::evaluate() const
{
return ceil(arg(0)->evaluate().toNumber());
}
double FunRound::round(double val)
{
if (!isnan(val) && !isinf(val)) {
if (signbit(val) && val >= -0.5)
val *= 0; // negative zero
else
val = floor(val + 0.5);
}
return val;
}
Value FunRound::evaluate() const
{
return round(arg(0)->evaluate().toNumber());
}
struct FunctionMapping {
const char* name;
FunctionRec function;
};
static void createFunctionMap()
{
static const FunctionMapping functions[] = {
{ "boolean", { &createFunBoolean, 1 } },
{ "ceiling", { &createFunCeiling, 1 } },
{ "concat", { &createFunConcat, Interval(2, Interval::Inf) } },
{ "contains", { &createFunContains, 2 } },
{ "count", { &createFunCount, 1 } },
{ "false", { &createFunFalse, 0 } },
{ "floor", { &createFunFloor, 1 } },
{ "id", { &createFunId, 1 } },
{ "lang", { &createFunLang, 1 } },
{ "last", { &createFunLast, 0 } },
{ "local-name", { &createFunLocalName, Interval(0, 1) } },
{ "name", { &createFunName, Interval(0, 1) } },
{ "namespace-uri", { &createFunNamespaceURI, Interval(0, 1) } },
{ "normalize-space", { &createFunNormalizeSpace, Interval(0, 1) } },
{ "not", { &createFunNot, 1 } },
{ "number", { &createFunNumber, Interval(0, 1) } },
{ "position", { &createFunPosition, 0 } },
{ "round", { &createFunRound, 1 } },
{ "starts-with", { &createFunStartsWith, 2 } },
{ "string", { &createFunString, Interval(0, 1) } },
{ "string-length", { &createFunStringLength, Interval(0, 1) } },
{ "substring", { &createFunSubstring, Interval(2, 3) } },
{ "substring-after", { &createFunSubstringAfter, 2 } },
{ "substring-before", { &createFunSubstringBefore, 2 } },
{ "sum", { &createFunSum, 1 } },
{ "translate", { &createFunTranslate, 3 } },
{ "true", { &createFunTrue, 0 } },
};
const unsigned int numFunctions = sizeof(functions) / sizeof(functions[0]);
functionMap = new HashMap<String, FunctionRec>;
for (unsigned i = 0; i < numFunctions; ++i)
functionMap->set(functions[i].name, functions[i].function);
}
Function* createFunction(const String& name, const Vector<Expression*>& args)
{
if (!functionMap)
createFunctionMap();
HashMap<String, FunctionRec>::iterator functionMapIter = functionMap->find(name);
FunctionRec* functionRec = 0;
if (functionMapIter == functionMap->end() || !(functionRec = &functionMapIter->second)->args.contains(args.size()))
return 0;
Function* function = functionRec->factoryFn();
function->setArguments(args);
function->setName(name);
return function;
}
}
}
#endif // ENABLE(XPATH)