source: downloads/ogre/OgreMain/src/OgreAnimationTrack.cpp @ 11

/*
-----------------------------------------------------------------------------
This source file is part of OGRE
    (Object-oriented Graphics Rendering Engine)
For the latest info, see http://www.ogre3d.org/

Copyright (c) 2000-2006 Torus Knot Software Ltd
Also see acknowledgements in Readme.html

This program is free software; you can redistribute it and/or modify it under
the terms of the GNU Lesser General Public License as published by the Free Software
Foundation; either version 2 of the License, or (at your option) any later
version.

This program is distributed in the hope that it will be useful, but WITHOUT
ANY WARRANTY; without even the implied warranty of MERCHANTABILITY or FITNESS
FOR A PARTICULAR PURPOSE. See the GNU Lesser General Public License for more details.

You should have received a copy of the GNU Lesser General Public License along with
this program; if not, write to the Free Software Foundation, Inc., 59 Temple
Place - Suite 330, Boston, MA 02111-1307, USA, or go to
http://www.gnu.org/copyleft/lesser.txt.

You may alternatively use this source under the terms of a specific version of
the OGRE Unrestricted License provided you have obtained such a license from
Torus Knot Software Ltd.
-----------------------------------------------------------------------------
*/
#include "OgreStableHeaders.h"
#include "OgreAnimationTrack.h"
#include "OgreAnimation.h"
#include "OgreKeyFrame.h"
#include "OgreNode.h"
#include "OgreLogManager.h"
#include "OgreHardwareBufferManager.h"
#include "OgreMesh.h"
#include "OgreException.h"

namespace Ogre {

    namespace {
        // Locally key frame search helper
        struct KeyFrameTimeLess
        {
            bool operator() (const KeyFrame* kf, const KeyFrame* kf2) const
            {
                return kf->getTime() < kf2->getTime();
            }
        };
    }
    //---------------------------------------------------------------------
    //---------------------------------------------------------------------
    AnimationTrack::AnimationTrack(Animation* parent, unsigned short handle) :
                mParent(parent), mHandle(handle)
    {
    }
    //---------------------------------------------------------------------
    AnimationTrack::~AnimationTrack()
    {
        removeAllKeyFrames();
    }
    //---------------------------------------------------------------------
    unsigned short AnimationTrack::getNumKeyFrames(void) const
    {
        return (unsigned short)mKeyFrames.size();
    }
    //---------------------------------------------------------------------
    KeyFrame* AnimationTrack::getKeyFrame(unsigned short index) const
    {
                // If you hit this assert, then the keyframe index is out of bounds
        assert( index < (ushort)mKeyFrames.size() );

        return mKeyFrames[index];
    }
    //---------------------------------------------------------------------
    Real AnimationTrack::getKeyFramesAtTime(const TimeIndex& timeIndex, KeyFrame** keyFrame1, KeyFrame** keyFrame2,
        unsigned short* firstKeyIndex) const
    {
        // Parametric time
        // t1 = time of previous keyframe
        // t2 = time of next keyframe
        Real t1, t2;

        Real timePos = timeIndex.getTimePos();

        // Find first keyframe after or on current time
        KeyFrameList::const_iterator i;
        if (timeIndex.hasKeyIndex())
        {
            // Global keyframe index available, map to local keyframe index directly.
            assert(timeIndex.getKeyIndex() < mKeyFrameIndexMap.size());
            i = mKeyFrames.begin() + mKeyFrameIndexMap[timeIndex.getKeyIndex()];
#ifdef _DEBUG
            KeyFrame timeKey(0, timePos);
            if (i != std::lower_bound(mKeyFrames.begin(), mKeyFrames.end(), &timeKey, KeyFrameTimeLess()))
            {
                OGRE_EXCEPT(Exception::ERR_INTERNAL_ERROR,
                    "Optimised key frame search failed",
                    "AnimationTrack::getKeyFramesAtTime");
            }
#endif
        }
        else
        {
            // Wrap time
            Real totalAnimationLength = mParent->getLength();
            assert(totalAnimationLength > 0.0f && "Invalid animation length!");

            while (timePos > totalAnimationLength && totalAnimationLength > 0.0f)
            {
                timePos -= totalAnimationLength;
            }

            // No global keyframe index, need to search with local keyframes.
            KeyFrame timeKey(0, timePos);
            i = std::lower_bound(mKeyFrames.begin(), mKeyFrames.end(), &timeKey, KeyFrameTimeLess());
        }

        if (i == mKeyFrames.end())
        {
            // There is no keyframe after this time, wrap back to first
            *keyFrame2 = mKeyFrames.front();
            t2 = mParent->getLength() + (*keyFrame2)->getTime();

            // Use last keyframe as previous keyframe
            --i;
        }
        else
        {
            *keyFrame2 = *i;
            t2 = (*keyFrame2)->getTime();

            // Find last keyframe before or on current time
            if (i != mKeyFrames.begin() && timePos < (*i)->getTime())
            {
                --i;
            }
        }

        // Fill index of the first key
        if (firstKeyIndex)
        {
            *firstKeyIndex = std::distance(mKeyFrames.begin(), i);
        }

        *keyFrame1 = *i;

        t1 = (*keyFrame1)->getTime();

        if (t1 == t2)
        {
            // Same KeyFrame (only one)
            return 0.0;
        }
        else
        {
            return (timePos - t1) / (t2 - t1);
        }
    }
    //---------------------------------------------------------------------
    KeyFrame* AnimationTrack::createKeyFrame(Real timePos)
    {
        KeyFrame* kf = createKeyFrameImpl(timePos);

        // Insert just before upper bound
        KeyFrameList::iterator i =
            std::upper_bound(mKeyFrames.begin(), mKeyFrames.end(), kf, KeyFrameTimeLess());
        mKeyFrames.insert(i, kf);

        _keyFrameDataChanged();
        mParent->_keyFrameListChanged();

        return kf;

    }
    //---------------------------------------------------------------------
    void AnimationTrack::removeKeyFrame(unsigned short index)
    {
                // If you hit this assert, then the keyframe index is out of bounds
        assert( index < (ushort)mKeyFrames.size() );

        KeyFrameList::iterator i = mKeyFrames.begin();

        i += index;

        delete *i;

        mKeyFrames.erase(i);

        _keyFrameDataChanged();
        mParent->_keyFrameListChanged();


    }
    //---------------------------------------------------------------------
    void AnimationTrack::removeAllKeyFrames(void)
    {
        KeyFrameList::iterator i = mKeyFrames.begin();

        for (; i != mKeyFrames.end(); ++i)
        {
            delete *i;
        }

        _keyFrameDataChanged();
        mParent->_keyFrameListChanged();

        mKeyFrames.clear();

    }
    //---------------------------------------------------------------------
    void AnimationTrack::_collectKeyFrameTimes(std::vector<Real>& keyFrameTimes)
    {
        for (KeyFrameList::const_iterator i = mKeyFrames.begin(); i != mKeyFrames.end(); ++i)
        {
            Real timePos = (*i)->getTime();

            std::vector<Real>::iterator it =
                std::lower_bound(keyFrameTimes.begin(), keyFrameTimes.end(), timePos);
            if (it == keyFrameTimes.end() || *it != timePos)
            {
                keyFrameTimes.insert(it, timePos);
            }
        }
    }
    //---------------------------------------------------------------------
    void AnimationTrack::_buildKeyFrameIndexMap(const std::vector<Real>& keyFrameTimes)
    {
        // Pre-allocate memory
        mKeyFrameIndexMap.resize(keyFrameTimes.size() + 1);

        size_t i = 0, j = 0;
        while (j <= keyFrameTimes.size())
        {
            mKeyFrameIndexMap[j] = static_cast<ushort>(i);
            while (i < mKeyFrames.size() && mKeyFrames[i]->getTime() <= keyFrameTimes[j])
                ++i;
            ++j;
        }
    }
        //---------------------------------------------------------------------
        void AnimationTrack::populateClone(AnimationTrack* clone) const
        {
                for (KeyFrameList::const_iterator i = mKeyFrames.begin();
                        i != mKeyFrames.end(); ++i)
                {
                        KeyFrame* clonekf = (*i)->_clone(clone);
                        clone->mKeyFrames.push_back(clonekf);
                }
        }
        //---------------------------------------------------------------------
        //---------------------------------------------------------------------
        // Numeric specialisations
        //---------------------------------------------------------------------
        NumericAnimationTrack::NumericAnimationTrack(Animation* parent,
                unsigned short handle)
                : AnimationTrack(parent, handle)
        {
        }
        //---------------------------------------------------------------------
        NumericAnimationTrack::NumericAnimationTrack(Animation* parent,
                unsigned short handle, AnimableValuePtr& target)
                :AnimationTrack(parent, handle), mTargetAnim(target)
        {
        }
        //---------------------------------------------------------------------
        const AnimableValuePtr& NumericAnimationTrack::getAssociatedAnimable(void) const
        {
                return mTargetAnim;
        }
        //---------------------------------------------------------------------
        void NumericAnimationTrack::setAssociatedAnimable(const AnimableValuePtr& val)
        {
                mTargetAnim = val;
        }
        //---------------------------------------------------------------------
        KeyFrame* NumericAnimationTrack::createKeyFrameImpl(Real time)
        {
                return new NumericKeyFrame(this, time);
        }
        //---------------------------------------------------------------------
        void NumericAnimationTrack::getInterpolatedKeyFrame(const TimeIndex& timeIndex,
                KeyFrame* kf) const
        {
                NumericKeyFrame* kret = static_cast<NumericKeyFrame*>(kf);

        // Keyframe pointers
                KeyFrame *kBase1, *kBase2;
        NumericKeyFrame *k1, *k2;
        unsigned short firstKeyIndex;

        Real t = this->getKeyFramesAtTime(timeIndex, &kBase1, &kBase2, &firstKeyIndex);
                k1 = static_cast<NumericKeyFrame*>(kBase1);
                k2 = static_cast<NumericKeyFrame*>(kBase2);

        if (t == 0.0)
        {
            // Just use k1
            kret->setValue(k1->getValue());
        }
        else
        {
            // Interpolate by t
                        AnyNumeric diff = k2->getValue() - k1->getValue();
                        kret->setValue(k1->getValue() + diff * t);
        }
        }
        //---------------------------------------------------------------------
        void NumericAnimationTrack::apply(const TimeIndex& timeIndex, Real weight, Real scale)
        {
                applyToAnimable(mTargetAnim, timeIndex, weight, scale);
        }
        //---------------------------------------------------------------------
        void NumericAnimationTrack::applyToAnimable(const AnimableValuePtr& anim, const TimeIndex& timeIndex,
                Real weight, Real scale)
        {
                // Nothing to do if no keyframes or zero weight, scale
                if (mKeyFrames.empty() || !weight || !scale)
                        return;

                NumericKeyFrame kf(0, timeIndex.getTimePos());
                getInterpolatedKeyFrame(timeIndex, &kf);
                // add to existing. Weights are not relative, but treated as
                // absolute multipliers for the animation
                AnyNumeric val = kf.getValue() * (weight * scale);

                anim->applyDeltaValue(val);

        }
        //--------------------------------------------------------------------------
        NumericKeyFrame* NumericAnimationTrack::createNumericKeyFrame(Real timePos)
        {
                return static_cast<NumericKeyFrame*>(createKeyFrame(timePos));
        }
        //--------------------------------------------------------------------------
        NumericKeyFrame* NumericAnimationTrack::getNumericKeyFrame(unsigned short index) const
        {
                return static_cast<NumericKeyFrame*>(getKeyFrame(index));
        }
    //---------------------------------------------------------------------
        NumericAnimationTrack* NumericAnimationTrack::_clone(Animation* newParent) const
        {
                NumericAnimationTrack* newTrack = 
                        newParent->createNumericTrack(mHandle);
                newTrack->mTargetAnim = mTargetAnim;
                populateClone(newTrack);
                return newTrack;
        }
    //---------------------------------------------------------------------
        //---------------------------------------------------------------------
        // Node specialisations
        //---------------------------------------------------------------------
        NodeAnimationTrack::NodeAnimationTrack(Animation* parent, unsigned short handle)
                : AnimationTrack(parent, handle), mTargetNode(0)
        , mSplines(0), mSplineBuildNeeded(false)
        , mUseShortestRotationPath(true)
        {
        }
        //---------------------------------------------------------------------
        NodeAnimationTrack::NodeAnimationTrack(Animation* parent, unsigned short handle,
                Node* targetNode)
                : AnimationTrack(parent, handle), mTargetNode(targetNode)
        , mSplines(0), mSplineBuildNeeded(false)
        , mUseShortestRotationPath(true)
        {
        }
    //---------------------------------------------------------------------
    NodeAnimationTrack::~NodeAnimationTrack()
    {
        delete mSplines;
    }
        //---------------------------------------------------------------------
    void NodeAnimationTrack::getInterpolatedKeyFrame(const TimeIndex& timeIndex, KeyFrame* kf) const
    {
                TransformKeyFrame* kret = static_cast<TransformKeyFrame*>(kf);

        // Keyframe pointers
                KeyFrame *kBase1, *kBase2;
        TransformKeyFrame *k1, *k2;
        unsigned short firstKeyIndex;

        Real t = this->getKeyFramesAtTime(timeIndex, &kBase1, &kBase2, &firstKeyIndex);
                k1 = static_cast<TransformKeyFrame*>(kBase1);
                k2 = static_cast<TransformKeyFrame*>(kBase2);

        if (t == 0.0)
        {
            // Just use k1
            kret->setRotation(k1->getRotation());
            kret->setTranslate(k1->getTranslate());
            kret->setScale(k1->getScale());
        }
        else
        {
            // Interpolate by t
            Animation::InterpolationMode im = mParent->getInterpolationMode();
            Animation::RotationInterpolationMode rim =
                mParent->getRotationInterpolationMode();
            Vector3 base;
            switch(im)
            {
            case Animation::IM_LINEAR:
                // Interpolate linearly
                // Rotation
                // Interpolate to nearest rotation if mUseShortestRotationPath set
                if (rim == Animation::RIM_LINEAR)
                {
                    kret->setRotation( Quaternion::nlerp(t, k1->getRotation(),
                        k2->getRotation(), mUseShortestRotationPath) );
                }
                else //if (rim == Animation::RIM_SPHERICAL)
                {
                    kret->setRotation( Quaternion::Slerp(t, k1->getRotation(),
                                            k2->getRotation(), mUseShortestRotationPath) );
                }

                // Translation
                base = k1->getTranslate();
                kret->setTranslate( base + ((k2->getTranslate() - base) * t) );

                // Scale
                base = k1->getScale();
                kret->setScale( base + ((k2->getScale() - base) * t) );
                break;

            case Animation::IM_SPLINE:
                // Spline interpolation

                // Build splines if required
                if (mSplineBuildNeeded)
                {
                    buildInterpolationSplines();
                }

                // Rotation, take mUseShortestRotationPath into account
                kret->setRotation( mSplines->rotationSpline.interpolate(firstKeyIndex, t,
                                        mUseShortestRotationPath) );

                // Translation
                kret->setTranslate( mSplines->positionSpline.interpolate(firstKeyIndex, t) );

                // Scale
                kret->setScale( mSplines->scaleSpline.interpolate(firstKeyIndex, t) );

                break;
            }

        }
    }
    //---------------------------------------------------------------------
    void NodeAnimationTrack::apply(const TimeIndex& timeIndex, Real weight, Real scale)
    {
        applyToNode(mTargetNode, timeIndex, weight, scale);

    }
    //---------------------------------------------------------------------
    Node* NodeAnimationTrack::getAssociatedNode(void) const
    {
        return mTargetNode;
    }
    //---------------------------------------------------------------------
    void NodeAnimationTrack::setAssociatedNode(Node* node)
    {
        mTargetNode = node;
    }
    //---------------------------------------------------------------------
    void NodeAnimationTrack::applyToNode(Node* node, const TimeIndex& timeIndex, Real weight,
                Real scl)
    {
                // Nothing to do if no keyframes or zero weight or no node
                if (mKeyFrames.empty() || !weight || !node)
                        return;

        TransformKeyFrame kf(0, timeIndex.getTimePos());
                getInterpolatedKeyFrame(timeIndex, &kf);

                // add to existing. Weights are not relative, but treated as absolute multipliers for the animation
        Vector3 translate = kf.getTranslate() * weight * scl;
                node->translate(translate);

                // interpolate between no-rotation and full rotation, to point 'weight', so 0 = no rotate, 1 = full
        Quaternion rotate;
        Animation::RotationInterpolationMode rim =
            mParent->getRotationInterpolationMode();
        if (rim == Animation::RIM_LINEAR)
        {
            rotate = Quaternion::nlerp(weight, Quaternion::IDENTITY, kf.getRotation(), mUseShortestRotationPath);
        }
        else //if (rim == Animation::RIM_SPHERICAL)
        {
            rotate = Quaternion::Slerp(weight, Quaternion::IDENTITY, kf.getRotation(), mUseShortestRotationPath);
        }
                node->rotate(rotate);

                Vector3 scale = kf.getScale();
                // Not sure how to modify scale for cumulative anims... leave it alone
                //scale = ((Vector3::UNIT_SCALE - kf.getScale()) * weight) + Vector3::UNIT_SCALE;
                if (scl != 1.0f && scale != Vector3::UNIT_SCALE)
                {
                        scale = Vector3::UNIT_SCALE + (scale - Vector3::UNIT_SCALE) * scl;
                }
                node->scale(scale);

    }
    //---------------------------------------------------------------------
    void NodeAnimationTrack::buildInterpolationSplines(void) const
    {
        // Allocate splines if not exists
        if (!mSplines)
        {
            mSplines = new Splines;
        }

        // Cache to register for optimisation
        Splines* splines = mSplines;

        // Don't calc automatically, do it on request at the end
        splines->positionSpline.setAutoCalculate(false);
        splines->rotationSpline.setAutoCalculate(false);
        splines->scaleSpline.setAutoCalculate(false);

        splines->positionSpline.clear();
        splines->rotationSpline.clear();
        splines->scaleSpline.clear();

        KeyFrameList::const_iterator i, iend;
        iend = mKeyFrames.end(); // precall to avoid overhead
        for (i = mKeyFrames.begin(); i != iend; ++i)
        {
                        TransformKeyFrame* kf = static_cast<TransformKeyFrame*>(*i);
            splines->positionSpline.addPoint(kf->getTranslate());
            splines->rotationSpline.addPoint(kf->getRotation());
            splines->scaleSpline.addPoint(kf->getScale());
        }

        splines->positionSpline.recalcTangents();
        splines->rotationSpline.recalcTangents();
        splines->scaleSpline.recalcTangents();


        mSplineBuildNeeded = false;
    }

    //---------------------------------------------------------------------
        void NodeAnimationTrack::setUseShortestRotationPath(bool useShortestPath)
        {
                mUseShortestRotationPath = useShortestPath ;
        }

    //---------------------------------------------------------------------
        bool NodeAnimationTrack::getUseShortestRotationPath() const
        {
                return mUseShortestRotationPath ;
        }
    //---------------------------------------------------------------------
    void NodeAnimationTrack::_keyFrameDataChanged(void) const
    {
        mSplineBuildNeeded = true;
    }
    //---------------------------------------------------------------------
        bool NodeAnimationTrack::hasNonZeroKeyFrames(void) const
        {
        KeyFrameList::const_iterator i = mKeyFrames.begin();
        for (; i != mKeyFrames.end(); ++i)
        {
                        // look for keyframes which have any component which is non-zero
                        // Since exporters can be a little inaccurate sometimes we use a
                        // tolerance value rather than looking for nothing
                        TransformKeyFrame* kf = static_cast<TransformKeyFrame*>(*i);
                        Vector3 trans = kf->getTranslate();
                        Vector3 scale = kf->getScale();
                        Vector3 axis;
                        Radian angle;
                        kf->getRotation().ToAngleAxis(angle, axis);
                        Real tolerance = 1e-3f;
                        if (!trans.positionEquals(Vector3::ZERO, tolerance) ||
                                !scale.positionEquals(Vector3::UNIT_SCALE, tolerance) ||
                                !Math::RealEqual(angle.valueRadians(), 0.0f, tolerance))
                        {
                                return true;
                        }

                }

                return false;
        }
    //---------------------------------------------------------------------
        void NodeAnimationTrack::optimise(void)
        {
                // Eliminate duplicate keyframes from 2nd to penultimate keyframe
                // NB only eliminate middle keys from sequences of 5+ identical keyframes
                // since we need to preserve the boundary keys in place, and we need
                // 2 at each end to preserve tangents for spline interpolation
                Vector3 lasttrans;
                Vector3 lastscale;
                Quaternion lastorientation;
        KeyFrameList::iterator i = mKeyFrames.begin();
                Radian quatTolerance(1e-3f);
                std::list<unsigned short> removeList;
                unsigned short k = 0;
                ushort dupKfCount = 0;
        for (; i != mKeyFrames.end(); ++i, ++k)
        {
                        TransformKeyFrame* kf = static_cast<TransformKeyFrame*>(*i);
                        Vector3 newtrans = kf->getTranslate();
                        Vector3 newscale = kf->getScale();
                        Quaternion neworientation = kf->getRotation();
                        // Ignore first keyframe; now include the last keyframe as we eliminate
                        // only k-2 in a group of 5 to ensure we only eliminate middle keys
                        if (i != mKeyFrames.begin() &&
                                newtrans.positionEquals(lasttrans) &&
                                newscale.positionEquals(lastscale) &&
                                neworientation.equals(lastorientation, quatTolerance))
                        {
                                ++dupKfCount;

                                // 4 indicates this is the 5th duplicate keyframe
                                if (dupKfCount == 4)
                                {
                                        // remove the 'middle' keyframe
                                        removeList.push_back(k-2);
                                        --dupKfCount;
                                }
                        }
                        else
                        {
                                // reset
                                dupKfCount = 0;
                                lasttrans = newtrans;
                                lastscale = newscale;
                                lastorientation = neworientation;
                        }
                }

                // Now remove keyframes, in reverse order to avoid index revocation
                std::list<unsigned short>::reverse_iterator r = removeList.rbegin();
                for (; r!= removeList.rend(); ++r)
                {
                        removeKeyFrame(*r);
                }


        }
        //--------------------------------------------------------------------------
        KeyFrame* NodeAnimationTrack::createKeyFrameImpl(Real time)
        {
                return new TransformKeyFrame(this, time);
        }
        //--------------------------------------------------------------------------
        TransformKeyFrame* NodeAnimationTrack::createNodeKeyFrame(Real timePos)
        {
                return static_cast<TransformKeyFrame*>(createKeyFrame(timePos));
        }
        //--------------------------------------------------------------------------
        TransformKeyFrame* NodeAnimationTrack::getNodeKeyFrame(unsigned short index) const
        {
                return static_cast<TransformKeyFrame*>(getKeyFrame(index));
        }
    //---------------------------------------------------------------------
        NodeAnimationTrack* NodeAnimationTrack::_clone(Animation* newParent) const
        {
                NodeAnimationTrack* newTrack = 
                        newParent->createNodeTrack(mHandle, mTargetNode);
                newTrack->mUseShortestRotationPath = mUseShortestRotationPath;
                populateClone(newTrack);
                return newTrack;
        }       
        //--------------------------------------------------------------------------
        VertexAnimationTrack::VertexAnimationTrack(Animation* parent,
                unsigned short handle, VertexAnimationType animType)
                : AnimationTrack(parent, handle), mAnimationType(animType)
        {
        }
        //--------------------------------------------------------------------------
        VertexAnimationTrack::VertexAnimationTrack(Animation* parent, unsigned short handle,
                VertexAnimationType animType, VertexData* targetData, TargetMode target)
                : AnimationTrack(parent, handle), mAnimationType(animType),
                mTargetVertexData(targetData), mTargetMode(target)
        {
        }
        //--------------------------------------------------------------------------
        VertexMorphKeyFrame* VertexAnimationTrack::createVertexMorphKeyFrame(Real timePos)
        {
                if (mAnimationType != VAT_MORPH)
                {
                        OGRE_EXCEPT(Exception::ERR_INVALIDPARAMS,
                                "Morph keyframes can only be created on vertex tracks of type morph.",
                                "VertexAnimationTrack::createVertexMorphKeyFrame");
                }
                return static_cast<VertexMorphKeyFrame*>(createKeyFrame(timePos));
        }
        //--------------------------------------------------------------------------
        VertexPoseKeyFrame* VertexAnimationTrack::createVertexPoseKeyFrame(Real timePos)
        {
                if (mAnimationType != VAT_POSE)
                {
                        OGRE_EXCEPT(Exception::ERR_INVALIDPARAMS,
                                "Pose keyframes can only be created on vertex tracks of type pose.",
                                "VertexAnimationTrack::createVertexPoseKeyFrame");
                }
                return static_cast<VertexPoseKeyFrame*>(createKeyFrame(timePos));
        }
        //--------------------------------------------------------------------------
        void VertexAnimationTrack::apply(const TimeIndex& timeIndex, Real weight, Real scale)
        {
                applyToVertexData(mTargetVertexData, timeIndex, weight);
        }
        //--------------------------------------------------------------------------
        void VertexAnimationTrack::applyToVertexData(VertexData* data,
                const TimeIndex& timeIndex, Real weight, const PoseList* poseList)
        {
                // Nothing to do if no keyframes or no vertex data
                if (mKeyFrames.empty() || !data)
                        return;

                // Get keyframes
                KeyFrame *kf1, *kf2;
                Real t = getKeyFramesAtTime(timeIndex, &kf1, &kf2);

                if (mAnimationType == VAT_MORPH)
                {
                        VertexMorphKeyFrame* vkf1 = static_cast<VertexMorphKeyFrame*>(kf1);
                        VertexMorphKeyFrame* vkf2 = static_cast<VertexMorphKeyFrame*>(kf2);

                        if (mTargetMode == TM_HARDWARE)
                        {
                                // If target mode is hardware, need to bind our 2 keyframe buffers,
                                // one to main pos, one to morph target texcoord
                                assert(!data->hwAnimationDataList.empty() &&
                                        "Haven't set up hardware vertex animation elements!");

                                // no use for TempBlendedBufferInfo here btw
                                // NB we assume that position buffer is unshared
                                // VertexDeclaration::getAutoOrganisedDeclaration should see to that
                                const VertexElement* posElem =
                                        data->vertexDeclaration->findElementBySemantic(VES_POSITION);
                                // Set keyframe1 data as original position
                                data->vertexBufferBinding->setBinding(
                                        posElem->getSource(), vkf1->getVertexBuffer());
                                // Set keyframe2 data as derived
                                data->vertexBufferBinding->setBinding(
                                        data->hwAnimationDataList[0].targetVertexElement->getSource(),
                                        vkf2->getVertexBuffer());
                                // save T for use later
                                data->hwAnimationDataList[0].parametric = t;

                        }
                        else
                        {
                                // If target mode is software, need to software interpolate each vertex

                                Mesh::softwareVertexMorph(
                                        t, vkf1->getVertexBuffer(), vkf2->getVertexBuffer(), data);
                        }
                }
                else
                {
                        // Pose

                        VertexPoseKeyFrame* vkf1 = static_cast<VertexPoseKeyFrame*>(kf1);
                        VertexPoseKeyFrame* vkf2 = static_cast<VertexPoseKeyFrame*>(kf2);

                        // For each pose reference in key 1, we need to locate the entry in
                        // key 2 and interpolate the influence
                        const VertexPoseKeyFrame::PoseRefList& poseList1 = vkf1->getPoseReferences();
                        const VertexPoseKeyFrame::PoseRefList& poseList2 = vkf2->getPoseReferences();
                        for (VertexPoseKeyFrame::PoseRefList::const_iterator p1 = poseList1.begin();
                                p1 != poseList1.end(); ++p1)
                        {
                                Real startInfluence = p1->influence;
                                Real endInfluence = 0;
                                // Search for entry in keyframe 2 list (if not there, will be 0)
                                for (VertexPoseKeyFrame::PoseRefList::const_iterator p2 = poseList2.begin();
                                        p2 != poseList2.end(); ++p2)
                                {
                                        if (p1->poseIndex == p2->poseIndex)
                                        {
                                                endInfluence = p2->influence;
                                                break;
                                        }
                                }
                                // Interpolate influence
                                Real influence = startInfluence + t*(endInfluence - startInfluence);
                                // Scale by animation weight
                                influence = weight * influence;
                                // Get pose
                                assert (p1->poseIndex <= poseList->size());
                                Pose* pose = (*poseList)[p1->poseIndex];
                                // apply
                                applyPoseToVertexData(pose, data, influence);
                        }
                        // Now deal with any poses in key 2 which are not in key 1
                        for (VertexPoseKeyFrame::PoseRefList::const_iterator p2 = poseList2.begin();
                                p2 != poseList2.end(); ++p2)
                        {
                                bool found = false;
                                for (VertexPoseKeyFrame::PoseRefList::const_iterator p1 = poseList1.begin();
                                        p1 != poseList1.end(); ++p1)
                                {
                                        if (p1->poseIndex == p2->poseIndex)
                                        {
                                                found = true;
                                                break;
                                        }
                                }
                                if (!found)
                                {
                                        // Need to apply this pose too, scaled from 0 start
                                        Real influence = t * p2->influence;
                                        // Scale by animation weight
                                        influence = weight * influence;
                                        // Get pose
                                        assert (p2->poseIndex <= poseList->size());
                                        const Pose* pose = (*poseList)[p2->poseIndex];
                                        // apply
                                        applyPoseToVertexData(pose, data, influence);
                                }
                        } // key 2 iteration
                } // morph or pose animation
        }
        //-----------------------------------------------------------------------------
        void VertexAnimationTrack::applyPoseToVertexData(const Pose* pose,
                VertexData* data, Real influence)
        {
                if (mTargetMode == TM_HARDWARE)
                {
                        // Hardware
                        // If target mode is hardware, need to bind our pose buffer
                        // to a target texcoord
                        assert(!data->hwAnimationDataList.empty() &&
                                "Haven't set up hardware vertex animation elements!");
                        // no use for TempBlendedBufferInfo here btw
                        // Set pose target as required
                        size_t hwIndex = data->hwAnimDataItemsUsed++;
                        // If we try to use too many poses, ignore extras
                        if (hwIndex < data->hwAnimationDataList.size())
                        {
                                VertexData::HardwareAnimationData& animData = data->hwAnimationDataList[hwIndex];
                                data->vertexBufferBinding->setBinding(
                                        animData.targetVertexElement->getSource(),
                                        pose->_getHardwareVertexBuffer(data->vertexCount));
                                // save final influence in parametric
                                animData.parametric = influence;

                        }

                }
                else
                {
                        // Software
                        Mesh::softwareVertexPoseBlend(influence, pose->getVertexOffsets(), data);
                }

        }
        //--------------------------------------------------------------------------
        VertexMorphKeyFrame* VertexAnimationTrack::getVertexMorphKeyFrame(unsigned short index) const
        {
                if (mAnimationType != VAT_MORPH)
                {
                        OGRE_EXCEPT(Exception::ERR_INVALIDPARAMS,
                                "Morph keyframes can only be created on vertex tracks of type morph.",
                                "VertexAnimationTrack::getVertexMorphKeyFrame");
                }

                return static_cast<VertexMorphKeyFrame*>(getKeyFrame(index));
        }
        //--------------------------------------------------------------------------
        VertexPoseKeyFrame* VertexAnimationTrack::getVertexPoseKeyFrame(unsigned short index) const
        {
                if (mAnimationType != VAT_POSE)
                {
                        OGRE_EXCEPT(Exception::ERR_INVALIDPARAMS,
                                "Pose keyframes can only be created on vertex tracks of type pose.",
                                "VertexAnimationTrack::getVertexPoseKeyFrame");
                }

                return static_cast<VertexPoseKeyFrame*>(getKeyFrame(index));
        }
        //--------------------------------------------------------------------------
        KeyFrame* VertexAnimationTrack::createKeyFrameImpl(Real time)
        {
                switch(mAnimationType)
                {
                default:
                case VAT_MORPH:
            return new VertexMorphKeyFrame(this, time);
                case VAT_POSE:
                        return new VertexPoseKeyFrame(this, time);
                };

        }
        //---------------------------------------------------------------------
        bool VertexAnimationTrack::hasNonZeroKeyFrames(void) const
        {
                if (mAnimationType == VAT_MORPH)
                {
                        return !mKeyFrames.empty();
                }
                else
                {

                        KeyFrameList::const_iterator i = mKeyFrames.begin();
                        for (; i != mKeyFrames.end(); ++i)
                        {
                                // look for keyframes which have a pose influence which is non-zero
                                const VertexPoseKeyFrame* kf = static_cast<const VertexPoseKeyFrame*>(*i);
                                VertexPoseKeyFrame::ConstPoseRefIterator poseIt
                                        = kf->getPoseReferenceIterator();
                                while (poseIt.hasMoreElements())
                                {
                                        const VertexPoseKeyFrame::PoseRef& poseRef = poseIt.getNext();
                                        if (poseRef.influence > 0.0f)
                                                return true;
                                }

                        }

                        return false;
                }
        }
        //---------------------------------------------------------------------
        void VertexAnimationTrack::optimise(void)
        {
                // TODO - remove sequences of duplicate pose references?


        }
    //---------------------------------------------------------------------
        VertexAnimationTrack* VertexAnimationTrack::_clone(Animation* newParent) const
        {
                VertexAnimationTrack* newTrack = 
                        newParent->createVertexTrack(mHandle, mAnimationType);
                newTrack->mTargetMode = mTargetMode;
                populateClone(newTrack);
                return newTrack;
        }       


}