Exemplo n.º 1
0
// returns true if the given point lies inside of the k-dop, specified by shapeInfo & shapePose.
// if the given point does lie within the k-dop, it also returns the amount of displacement necessary to push that point outward
// such that it lies on the surface of the kdop.
bool findPointKDopDisplacement(const glm::vec3& point, const AnimPose& shapePose, const HFMJointShapeInfo& shapeInfo, glm::vec3& displacementOut) {

    // transform point into local space of jointShape.
    glm::vec3 localPoint = shapePose.inverse().xformPoint(point);

    // Only works for 14-dop shape infos.
    if (shapeInfo.dots.size() != DOP14_COUNT) {
        return false;
    }

    glm::vec3 minDisplacement(FLT_MAX);
    float minDisplacementLen = FLT_MAX;
    glm::vec3 p = localPoint - shapeInfo.avgPoint;
    float pLen = glm::length(p);
    if (pLen > 0.0f) {
        int slabCount = 0;
        for (int i = 0; i < DOP14_COUNT; i++) {
            float dot = glm::dot(p, DOP14_NORMALS[i]);
            if (dot > 0.0f && dot < shapeInfo.dots[i]) {
                slabCount++;
                float distToPlane = pLen * (shapeInfo.dots[i] / dot);
                float displacementLen = distToPlane - pLen;

                // keep track of the smallest displacement
                if (displacementLen < minDisplacementLen) {
                    minDisplacementLen = displacementLen;
                    minDisplacement = (p / pLen) * displacementLen;
                }
            }
        }
        if (slabCount == (DOP14_COUNT / 2) && minDisplacementLen != FLT_MAX) {
            // we are within the k-dop so push the point along the minimum displacement found
            displacementOut = shapePose.xformVectorFast(minDisplacement);
            return true;
        } else {
            // point is outside of kdop
            return false;
        }
    } else {
        // point is directly on top of shapeInfo.avgPoint.
        // push the point out along the x axis.
        displacementOut = shapePose.xformVectorFast(shapeInfo.points[0]);
        return true;
    }
}
Exemplo n.º 2
0
AnimPose AnimManipulator::computeRelativePoseFromJointVar(const AnimVariantMap& animVars, const JointVar& jointVar,
                                                          const AnimPose& defaultRelPose, const AnimPoseVec& underPoses) {

    AnimPose defaultAbsPose = _skeleton->getAbsolutePose(jointVar.jointIndex, underPoses);

    if (jointVar.type == JointVar::Type::AbsoluteRotation || jointVar.type == JointVar::Type::AbsolutePosition) {

        if (jointVar.type == JointVar::Type::AbsoluteRotation) {
            defaultAbsPose.rot = animVars.lookupRigToGeometry(jointVar.var, defaultAbsPose.rot);
        } else if (jointVar.type == JointVar::Type::AbsolutePosition) {
            defaultAbsPose.trans = animVars.lookupRigToGeometry(jointVar.var, defaultAbsPose.trans);
        }

        // because jointVar is absolute, we must use an absolute parent frame to convert into a relative pose.
        AnimPose parentAbsPose = AnimPose::identity;
        int parentIndex = _skeleton->getParentIndex(jointVar.jointIndex);
        if (parentIndex >= 0) {
            parentAbsPose = _skeleton->getAbsolutePose(parentIndex, underPoses);
        }

        // convert from absolute to relative
        return parentAbsPose.inverse() * defaultAbsPose;

    } else {

        // override the default rel pose
        AnimPose relPose = defaultRelPose;
        if (jointVar.type == JointVar::Type::RelativeRotation) {
            relPose.rot = animVars.lookupRigToGeometry(jointVar.var, defaultRelPose.rot);
        } else if (jointVar.type == JointVar::Type::RelativePosition) {
            relPose.trans = animVars.lookupRigToGeometry(jointVar.var, defaultRelPose.trans);
        }

        return relPose;
    }
}