Example #1
0
inline double KDERules<MetricType, KernelType, TreeType>::
Score(const size_t queryIndex, TreeType& referenceNode)
{
  double score, maxKernel, minKernel, bound;
  const arma::vec& queryPoint = querySet.unsafe_col(queryIndex);
  const double minDistance = referenceNode.MinDistance(queryPoint);
  bool newCalculations = true;

  if (tree::TreeTraits<TreeType>::FirstPointIsCentroid &&
      lastQueryIndex == queryIndex &&
      traversalInfo.LastReferenceNode() != NULL &&
      traversalInfo.LastReferenceNode()->Point(0) == referenceNode.Point(0))
  {
    // Don't duplicate calculations.
    newCalculations = false;
    lastQueryIndex = queryIndex;
    lastReferenceIndex = referenceNode.Point(0);
  }
  else
  {
    // Calculations are new.
    maxKernel = kernel.Evaluate(minDistance);
    minKernel = kernel.Evaluate(referenceNode.MaxDistance(queryPoint));
    bound = maxKernel - minKernel;
  }

  if (newCalculations &&
      bound <= (absError + relError * minKernel) / referenceSet.n_cols)
  {
    // Estimate values.
    double kernelValue;

    // Calculate kernel value based on reference node centroid.
    if (tree::TreeTraits<TreeType>::FirstPointIsCentroid)
    {
      kernelValue = EvaluateKernel(queryIndex, referenceNode.Point(0));
    }
    else
    {
      kde::KDEStat& referenceStat = referenceNode.Stat();
      kernelValue = EvaluateKernel(queryPoint, referenceStat.Centroid());
    }

    densities(queryIndex) += referenceNode.NumDescendants() * kernelValue;

    // Don't explore this tree branch.
    score = DBL_MAX;
  }
  else
  {
    score = minDistance;
  }

  ++scores;
  traversalInfo.LastReferenceNode() = &referenceNode;
  traversalInfo.LastScore() = score;
  return score;
}
Example #2
0
double DTBRules<MetricType, TreeType>::Score(TreeType& queryNode,
                                             TreeType& referenceNode)
{
  // If all the queries belong to the same component as all the references
  // then we prune.
  if ((queryNode.Stat().ComponentMembership() >= 0) &&
      (queryNode.Stat().ComponentMembership() ==
           referenceNode.Stat().ComponentMembership()))
    return DBL_MAX;

  ++scores;
  const double distance = queryNode.MinDistance(&referenceNode);
  const double bound = CalculateBound(queryNode);

  // If all the points in the reference node are farther than the candidate
  // nearest neighbor for all queries in the node, we prune.
  return (bound < distance) ? DBL_MAX : distance;
}
Example #3
0
double DTBRules<MetricType, TreeType>::Score(const size_t queryIndex,
                                             TreeType& referenceNode)
{
  size_t queryComponentIndex = connections.Find(queryIndex);

  // If the query belongs to the same component as all of the references,
  // then prune.  The cast is to stop a warning about comparing unsigned to
  // signed values.
  if (queryComponentIndex ==
      (size_t) referenceNode.Stat().ComponentMembership())
    return DBL_MAX;

  const arma::vec queryPoint = dataSet.unsafe_col(queryIndex);
  const double distance = referenceNode.MinDistance(queryPoint);

  // If all the points in the reference node are farther than the candidate
  // nearest neighbor for the query's component, we prune.
  return neighborsDistances[queryComponentIndex] < distance
      ? DBL_MAX : distance;
}
Example #4
0
double DTBRules<MetricType, TreeType>::Score(const size_t queryIndex,
                                             TreeType& referenceNode,
                                             const double baseCaseResult)
{
  // I don't really understand the last argument here
  // It just gets passed in the distance call, otherwise this function
  // is the same as the one above.
  size_t queryComponentIndex = connections.Find(queryIndex);

  // If the query belongs to the same component as all of the references,
  // then prune.
  if (queryComponentIndex == referenceNode.Stat().ComponentMembership())
    return DBL_MAX;

  const arma::vec queryPoint = dataSet.unsafe_col(queryIndex);
  const double distance = referenceNode.MinDistance(queryPoint,
                                                    baseCaseResult);

  // If all the points in the reference node are farther than the candidate
  // nearest neighbor for the query's component, we prune.
  return (neighborsDistances[queryComponentIndex] < distance) ? DBL_MAX :
      distance;
}
double PellegMooreKMeansRules<MetricType, TreeType>::Score(
    const size_t /* queryIndex */,
    TreeType& referenceNode)
{
  // Obtain the parent's blacklist.  If this is the root node, we'll start with
  // an empty blacklist.  This means that after each iteration, we don't need to
  // reset any statistics.
  if (referenceNode.Parent() == NULL ||
      referenceNode.Parent()->Stat().Blacklist().n_elem == 0)
    referenceNode.Stat().Blacklist().zeros(centroids.n_cols);
  else
    referenceNode.Stat().Blacklist() =
        referenceNode.Parent()->Stat().Blacklist();

  // The query index is a fake index that we won't use, and the reference node
  // holds all of the points in the dataset.  Our goal is to determine whether
  // or not this node is dominated by a single cluster.
  const size_t whitelisted = centroids.n_cols -
      arma::accu(referenceNode.Stat().Blacklist());

  distanceCalculations += whitelisted;

  // Which cluster has minimum distance to the node?
  size_t closestCluster = centroids.n_cols;
  double minMinDistance = DBL_MAX;
  for (size_t i = 0; i < centroids.n_cols; ++i)
  {
    if (referenceNode.Stat().Blacklist()[i] == 0)
    {
      const double minDistance = referenceNode.MinDistance(centroids.col(i));
      if (minDistance < minMinDistance)
      {
        minMinDistance = minDistance;
        closestCluster = i;
      }
    }
  }

  // Now, for every other whitelisted cluster, determine if the closest cluster
  // owns the point.  This calculation is specific to hyperrectangle trees (but,
  // this implementation is specific to kd-trees, so that's okay).  For
  // circular-bound trees, the condition should be simpler and can probably be
  // expressed as a comparison between minimum and maximum distances.
  size_t newBlacklisted = 0;
  for (size_t c = 0; c < centroids.n_cols; ++c)
  {
    if (referenceNode.Stat().Blacklist()[c] == 1 || c == closestCluster)
      continue;

    // This algorithm comes from the proof of Lemma 4 in the extended version
    // of the Pelleg-Moore paper (the CMU tech report, that is).  It has been
    // adapted for speed.
    arma::vec cornerPoint(centroids.n_rows);
    for (size_t d = 0; d < referenceNode.Bound().Dim(); ++d)
    {
      if (centroids(d, c) > centroids(d, closestCluster))
        cornerPoint(d) = referenceNode.Bound()[d].Hi();
      else
        cornerPoint(d) = referenceNode.Bound()[d].Lo();
    }

    const double closestDist = metric.Evaluate(cornerPoint,
        centroids.col(closestCluster));
    const double otherDist = metric.Evaluate(cornerPoint, centroids.col(c));

    distanceCalculations += 3; // One for cornerPoint, then two distances.

    if (closestDist < otherDist)
    {
      // The closest cluster dominates the node with respect to the cluster c.
      // So we can blacklist c.
      referenceNode.Stat().Blacklist()[c] = 1;
      ++newBlacklisted;
    }
  }

  if (whitelisted - newBlacklisted == 1)
  {
    // This node is dominated by the closest cluster.
    counts[closestCluster] += referenceNode.NumDescendants();
    newCentroids.col(closestCluster) += referenceNode.NumDescendants() *
        referenceNode.Stat().Centroid();

    return DBL_MAX;
  }

  // Perform the base case here.
  for (size_t i = 0; i < referenceNode.NumPoints(); ++i)
  {
    size_t bestCluster = centroids.n_cols;
    double bestDistance = DBL_MAX;
    for (size_t c = 0; c < centroids.n_cols; ++c)
    {
      if (referenceNode.Stat().Blacklist()[c] == 1)
        continue;

      ++distanceCalculations;

      // The reference index is the index of the data point.
      const double distance = metric.Evaluate(centroids.col(c),
          dataset.col(referenceNode.Point(i)));

      if (distance < bestDistance)
      {
        bestDistance = distance;
        bestCluster = c;
      }
    }

    // Add to resulting centroid.
    newCentroids.col(bestCluster) += dataset.col(referenceNode.Point(i));
    ++counts(bestCluster);
  }

  // Otherwise, we're not sure, so we can't prune.  Recursion order doesn't make
  // a difference, so we'll just return a score of 0.
  return 0.0;
}
Example #6
0
inline double KDERules<MetricType, KernelType, TreeType>::
Score(TreeType& queryNode, TreeType& referenceNode)
{
  double score, maxKernel, minKernel, bound;
  const double minDistance = queryNode.MinDistance(referenceNode);
  // Calculations are not duplicated.
  bool newCalculations = true;

  if (tree::TreeTraits<TreeType>::FirstPointIsCentroid &&
      (traversalInfo.LastQueryNode() != NULL) &&
      (traversalInfo.LastReferenceNode() != NULL) &&
      (traversalInfo.LastQueryNode()->Point(0) == queryNode.Point(0)) &&
      (traversalInfo.LastReferenceNode()->Point(0) == referenceNode.Point(0)))
  {
    // Don't duplicate calculations.
    newCalculations = false;
    lastQueryIndex = queryNode.Point(0);
    lastReferenceIndex = referenceNode.Point(0);
  }
  else
  {
    // Calculations are new.
    maxKernel = kernel.Evaluate(minDistance);
    minKernel = kernel.Evaluate(queryNode.MaxDistance(referenceNode));
    bound = maxKernel - minKernel;
  }

  // If possible, avoid some calculations because of the error tolerance.
  if (newCalculations &&
      bound <= (absError + relError * minKernel) / referenceSet.n_cols)
  {
    // Auxiliary variables.
    double kernelValue;
    kde::KDEStat& referenceStat = referenceNode.Stat();
    kde::KDEStat& queryStat = queryNode.Stat();

    // If calculating a center is not required.
    if (tree::TreeTraits<TreeType>::FirstPointIsCentroid)
    {
      kernelValue = EvaluateKernel(queryNode.Point(0), referenceNode.Point(0));
    }
    // Sadly, we have no choice but to calculate the center.
    else
    {
      kernelValue = EvaluateKernel(queryStat.Centroid(),
                                   referenceStat.Centroid());
    }

    // Sum up estimations.
    for (size_t i = 0; i < queryNode.NumDescendants(); ++i)
    {
      densities(queryNode.Descendant(i)) +=
          referenceNode.NumDescendants() * kernelValue;
    }
    score = DBL_MAX;
  }
  else
  {
    score = minDistance;
  }

  ++scores;
  traversalInfo.LastQueryNode() = &queryNode;
  traversalInfo.LastReferenceNode() = &referenceNode;
  traversalInfo.LastScore() = score;
  return score;
}