/*
 * The Apache Software License, Version 1.1
 *
 * Copyright (c) 1999-2002 The Apache Software Foundation.  All rights
 * reserved.
 *
 * 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.
 *
 * 3. The end-user documentation included with the redistribution,
 *    if any, must include the following acknowledgment:
 *       "This product includes software developed by the
 *        Apache Software Foundation (http://www.apache.org/)."
 *    Alternately, this acknowledgment may appear in the software itself,
 *    if and wherever such third-party acknowledgments normally appear.
 *
 * 4. The names "Xerces" and "Apache Software Foundation" must
 *    not be used to endorse or promote products derived from this
 *    software without prior written permission. For written
 *    permission, please contact apache\@apache.org.
 *
 * 5. Products derived from this software may not be called "Apache",
 *    nor may "Apache" appear in their name, without prior written
 *    permission of the Apache Software Foundation.
 *
 * THIS SOFTWARE IS PROVIDED ``AS IS'' AND ANY EXPRESSED 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 APACHE SOFTWARE FOUNDATION OR
 * ITS CONTRIBUTORS 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.
 * ====================================================================
 *
 * This software consists of voluntary contributions made by many
 * individuals on behalf of the Apache Software Foundation, and was
 * originally based on software copyright (c) 1999, International
 * Business Machines, Inc., http://www.ibm.com .  For more information
 * on the Apache Software Foundation, please see
 * <http://www.apache.org/>.
 */
// ---------------------------------------------------------------------------
//  Includes
// ---------------------------------------------------------------------------
#if defined(XERCES_TMPLSINC)
#include <xercesc/util/BaseRefVectorOf.hpp>
#endif

XERCES_CPP_NAMESPACE_BEGIN

// ---------------------------------------------------------------------------
//  BaseRefVectorOf: Constructors and Destructor
// ---------------------------------------------------------------------------
template <class TElem>
BaseRefVectorOf<TElem>::BaseRefVectorOf( const unsigned int maxElems
                                       , const bool adoptElems
                                       , MemoryManager* const manager) :

    fAdoptedElems(adoptElems)
    , fCurCount(0)
    , fMaxCount(maxElems)
    , fElemList(0)
    , fMemoryManager(manager)
{
    // Allocate and initialize the array
    fElemList = (TElem**) fMemoryManager->allocate(maxElems * sizeof(TElem*));//new TElem*[maxElems];
    for (unsigned int index = 0; index < maxElems; index++)
        fElemList[index] = 0;
}


//implemented so code will link
template <class TElem> BaseRefVectorOf<TElem>::~BaseRefVectorOf()
{
}


// ---------------------------------------------------------------------------
//  BaseRefVectorOf: Element management
// ---------------------------------------------------------------------------
template <class TElem> void BaseRefVectorOf<TElem>::addElement(TElem* const toAdd)
{
    ensureExtraCapacity(1);
    fElemList[fCurCount] = toAdd;
    fCurCount++;
}


template <class TElem> void
BaseRefVectorOf<TElem>::setElementAt(TElem* const toSet, const unsigned int setAt)
{
    if (setAt >= fCurCount)
        ThrowXMLwithMemMgr(ArrayIndexOutOfBoundsException, XMLExcepts::Vector_BadIndex, fMemoryManager);

    if (fAdoptedElems)
        delete fElemList[setAt];
    fElemList[setAt] = toSet;
}

template <class TElem> void BaseRefVectorOf<TElem>::
insertElementAt(TElem* const toInsert, const unsigned int insertAt)
{
    if (insertAt == fCurCount)
    {
        addElement(toInsert);
        return;
    }

    if (insertAt > fCurCount)
        ThrowXMLwithMemMgr(ArrayIndexOutOfBoundsException, XMLExcepts::Vector_BadIndex, fMemoryManager);

    ensureExtraCapacity(1);

    // Make room for the newbie
    for (unsigned int index = fCurCount; index > insertAt; index--)
        fElemList[index] = fElemList[index-1];

    // And stick it in and bump the count
    fElemList[insertAt] = toInsert;
    fCurCount++;
}

template <class TElem> TElem* BaseRefVectorOf<TElem>::
orphanElementAt(const unsigned int orphanAt)
{
    if (orphanAt >= fCurCount)
        ThrowXMLwithMemMgr(ArrayIndexOutOfBoundsException, XMLExcepts::Vector_BadIndex, fMemoryManager);

    // Get the element we are going to orphan
    TElem* retVal = fElemList[orphanAt];

    // Optimize if its the last element
    if (orphanAt == fCurCount-1)
    {
        fElemList[orphanAt] = 0;
        fCurCount--;
        return retVal;
    }

    // Copy down every element above orphan point
    for (unsigned int index = orphanAt; index < fCurCount-1; index++)
        fElemList[index] = fElemList[index+1];

    // Keep unused elements zero for sanity's sake
    fElemList[fCurCount-1] = 0;

    // And bump down count
    fCurCount--;

    return retVal;
}

template <class TElem> void BaseRefVectorOf<TElem>::removeAllElements()
{
    for (unsigned int index = 0; index < fCurCount; index++)
    {
        if (fAdoptedElems)
          delete fElemList[index];

        // Keep unused elements zero for sanity's sake
        fElemList[index] = 0;
    }
    fCurCount = 0;
}

template <class TElem> void BaseRefVectorOf<TElem>::
removeElementAt(const unsigned int removeAt)
{
    if (removeAt >= fCurCount)
        ThrowXMLwithMemMgr(ArrayIndexOutOfBoundsException, XMLExcepts::Vector_BadIndex, fMemoryManager);

    if (fAdoptedElems)
        delete fElemList[removeAt];

    // Optimize if its the last element
    if (removeAt == fCurCount-1)
    {
        fElemList[removeAt] = 0;
        fCurCount--;
        return;
    }

    // Copy down every element above remove point
    for (unsigned int index = removeAt; index < fCurCount-1; index++)
        fElemList[index] = fElemList[index+1];

    // Keep unused elements zero for sanity's sake
    fElemList[fCurCount-1] = 0;

    // And bump down count
    fCurCount--;
}

template <class TElem> void BaseRefVectorOf<TElem>::removeLastElement()
{
    if (!fCurCount)
        return;
    fCurCount--;

    if (fAdoptedElems)
        delete fElemList[fCurCount];
}

template <class TElem>
bool BaseRefVectorOf<TElem>::containsElement(const TElem* const toCheck) {

    for (unsigned int i = 0; i < fCurCount; i++) {
        if (fElemList[i] == toCheck) {
            return true;
        }
    }

    return false;
}

//
// cleanup():
//   similar to destructor
//   called to cleanup the memory, in case destructor cannot be called
//
template <class TElem> void BaseRefVectorOf<TElem>::cleanup()
{
    if (fAdoptedElems)
    {
        for (unsigned int index = 0; index < fCurCount; index++)
            delete fElemList[index];
    }
    fMemoryManager->deallocate(fElemList);//delete [] fElemList;
}

//
// reinitialize():
//   similar to constructor
//   called to re-construct the fElemList from scratch again
//
template <class TElem> void BaseRefVectorOf<TElem>::reinitialize()
{
    // reinitialize the array
    if (fElemList)
        cleanup();

    fElemList = (TElem**) fMemoryManager->allocate(fMaxCount * sizeof(TElem*));//new TElem*[fMaxCount];
    for (unsigned int index = 0; index < fMaxCount; index++)
        fElemList[index] = 0;

}

template <class TElem>
MemoryManager* BaseRefVectorOf<TElem>::getMemoryManager() const
{
    return fMemoryManager;
}


// ---------------------------------------------------------------------------
//  BaseRefVectorOf: Getter methods
// ---------------------------------------------------------------------------
template <class TElem> unsigned int BaseRefVectorOf<TElem>::curCapacity() const
{
    return fMaxCount;
}

template <class TElem> const TElem* BaseRefVectorOf<TElem>::
elementAt(const unsigned int getAt) const
{
    if (getAt >= fCurCount)
        ThrowXMLwithMemMgr(ArrayIndexOutOfBoundsException, XMLExcepts::Vector_BadIndex, fMemoryManager);
    return fElemList[getAt];
}

template <class TElem> TElem*
BaseRefVectorOf<TElem>::elementAt(const unsigned int getAt)
{
    if (getAt >= fCurCount)
        ThrowXMLwithMemMgr(ArrayIndexOutOfBoundsException, XMLExcepts::Vector_BadIndex, fMemoryManager);
    return fElemList[getAt];
}

template <class TElem> unsigned int BaseRefVectorOf<TElem>::size() const
{
    return fCurCount;
}


// ---------------------------------------------------------------------------
//  BaseRefVectorOf: Miscellaneous
// ---------------------------------------------------------------------------
template <class TElem> void BaseRefVectorOf<TElem>::
ensureExtraCapacity(const unsigned int length)
{
    unsigned int newMax = fCurCount + length;

    if (newMax < fMaxCount)
        return;

    // Avoid too many reallocations by providing a little more space
    if (newMax < fMaxCount + 32)
        newMax = fMaxCount + 32;

    // Allocate the new array and copy over the existing stuff
    TElem** newList = (TElem**) fMemoryManager->allocate
    (
        newMax * sizeof(TElem*)
    );//new TElem*[newMax];
    unsigned int index = 0;
    for (; index < fCurCount; index++)
        newList[index] = fElemList[index];

    // Zero out the rest of them
    for (; index < newMax; index++)
        newList[index] = 0;

    // Clean up the old array and update our members
    fMemoryManager->deallocate(fElemList);//delete [] fElemList;
    fElemList = newList;
    fMaxCount = newMax;
}



// ---------------------------------------------------------------------------
//  AbstractBaseRefVectorEnumerator: Constructors and Destructor
// ---------------------------------------------------------------------------
template <class TElem> BaseRefVectorEnumerator<TElem>::
BaseRefVectorEnumerator(        BaseRefVectorOf<TElem>* const   toEnum
                    , const bool                        adopt) :
    fAdopted(adopt)
    , fCurIndex(0)
    , fToEnum(toEnum)
{
}

template <class TElem> BaseRefVectorEnumerator<TElem>::~BaseRefVectorEnumerator()
{
    if (fAdopted)
        delete fToEnum;
}

template <class TElem> BaseRefVectorEnumerator<TElem>::
BaseRefVectorEnumerator(const BaseRefVectorEnumerator<TElem>& toCopy) :
    fAdopted(toCopy.fAdopted)
    , fCurIndex(toCopy.fCurIndex)
    , fToEnum(toCopy.fToEnum)    
{
}
// ---------------------------------------------------------------------------
//  RefBaseRefVectorEnumerator: Enum interface
// ---------------------------------------------------------------------------
template <class TElem> bool BaseRefVectorEnumerator<TElem>::hasMoreElements() const
{
    if (fCurIndex >= fToEnum->size())
        return false;
    return true;
}

template <class TElem> TElem& BaseRefVectorEnumerator<TElem>::nextElement()
{
    return *(fToEnum->elementAt(fCurIndex++));
}

template <class TElem> void BaseRefVectorEnumerator<TElem>::Reset()
{
    fCurIndex = 0;
}

XERCES_CPP_NAMESPACE_END