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• RPTree [top]
  • See also
  • Template parameters
  • Constructors

    • Constructor parameters:
  • Basic tree properties

    • Navigating the tree
    • Accessing members of a tree
    • Accessing data held in a tree
    • Accessing computed bound quantities of a tree
    • Other functionality
  • Bounding distances with the tree
  • Tree traversals
  • Example usage

RPTree

The RPTree class represents a random projection tree, a variant of the k-d tree based on random projections. The random projection tree is a well-known data structure for efficient distance operations (such as nearest neighbor search) in low dimensions—typically less than 100.

An RPTree (or the similar MaxRPTree) may be preferred over a KDTree or other tree structures as it is theoretically known to adapt to the intrinsic dimension of the data. This is similar to the cover tree, but the implementation is far simpler and as a result, more efficient.

mlpack’s RPTree implementation supports three template parameters for configurable behavior, and implements all the functionality required by the TreeType API, plus some additional functionality specific to random projection trees.

• Template parameters
• Constructors
• Basic tree properties
• Bounding distances with the tree
• Tree traversals
• Example usage

🔗 See also

• MaxRPTree
• kd-tree on Wikipedia
• Random projection on Wikipedia
• BinarySpaceTree
• Binary space partitioning on Wikipedia
• Random Projection Trees and Low Dimensional Manifolds (pdf)
• Tree-Independent Dual-Tree Algorithms (pdf)

🔗 Template parameters

In accordance with the TreeType API (see also this more detailed section), the RPTree class takes three template parameters:

RPTree<DistanceType, StatisticType, MatType>

• DistanceType: the distance metric to use for distance computations. For the RPTree, this must be an LMetric. By default, this is EuclideanDistance.
• StatisticType: this holds auxiliary information in each tree node. By default, EmptyStatistic is used, which holds no information.
• MatType: the type of matrix used to represent points. Must be a type matching the Armadillo API. By default, arma::mat is used, but other types such as arma::fmat or similar will work just fine.

The RPTree class itself is a convenience typedef of the generic BinarySpaceTree class, using the HRectBound class as the bounding structure, and using the RPTreeMeanSplit splitting strategy for construction, which splits a node along a random projection, or, in some cases, based on the distance from the vector-valued mean of points in the node.

If no template parameters are explicitly specified, then defaults are used:

RPTree<> = RPTree<EuclideanDistance, EmptyStatistic, arma::mat>

🔗 Constructors

RPTrees are efficiently constructed by permuting points in a dataset in a quicksort-like algorithm. However, this means that the ordering of points in the tree’s dataset (accessed with node.Dataset()) after construction may be different.

• node = RPTree(data, maxLeafSize=20)
• node = RPTree(data, oldFromNew, maxLeafSize=20)
• node = RPTree(data, oldFromNew, newFromOld, maxLeafSize=20)
  • Construct an RPTree on the given data, using maxLeafSize as the maximum number of points held in a leaf.
  • By default, data is copied. Avoid a copy by using std::move() (e.g. std::move(data)); when doing this, data will be set to an empty matrix.
  • Optionally, construct mappings from old points to new points. oldFromNew and newFromOld will have length data.n_cols, and:
    • oldFromNew[i] indicates that point i in the tree’s dataset was originally point oldFromNew[i] in data; that is, node.Dataset().col(i) is the point data.col(oldFromNew[i]).
    • newFromOld[i] indicates that point i in data is now point newFromOld[i] in the tree’s dataset; that is, node.Dataset().col(newFromOld[i]) is the point data.col(i).

• node = RPTree<DistanceType, StatisticType, MatType>(data, maxLeafSize=20)
• node = RPTree<DistanceType, StatisticType, MatType>(data, oldFromNew, maxLeafSize=20)
• node = RPTree<DistanceType, StatisticType, MatType>(data, oldFromNew, newFromOld, maxLeafSize=20)
  • Construct an RPTree on the given data, using custom template parameters to control the behavior of the tree, using maxLeafSize as the maximum number of points held in a leaf.
  • By default, data is copied. Avoid a copy by using std::move() (e.g. std::move(data)); when doing this, data will be set to an empty matrix.
  • Optionally, construct mappings from old points to new points. oldFromNew and newFromOld will have length data.n_cols, and:
    • oldFromNew[i] indicates that point i in the tree’s dataset was originally point oldFromNew[i] in data; that is, node.Dataset().col(i) is the point data.col(oldFromNew[i]).
    • newFromOld[i] indicates that point i in data is now point newFromOld[i] in the tree’s dataset; that is, node.Dataset().col(newFromOld[i]) is the point data.col(i).

• node = RPTree()
  • Construct an empty random projection tree with no children and no points.

Notes:

• The name node is used here for RPTree objects instead of tree, because each RPTree object is a single node in the tree. The constructor returns the node that is the root of the tree.

• Inserting individual points or removing individual points from an RPTree is not supported, because this generally results in a random projection tree with very loose bounding boxes. It is better to simply build a new RPTree on the modified dataset. For trees that support individual insertion and deletions, see the RectangleTree class and all its variants (e.g. RTree, RStarTree, etc.).

• See also the developer documentation on tree constructors.

🔗 Constructor parameters:

🔗 Basic tree properties

Once an RPTree object is constructed, various properties of the tree can be accessed or inspected. Many of these functions are required by the TreeType API.

🔗 Navigating the tree

• node.NumChildren() returns the number of children in node. This is either 2 if node has children, or 0 if node is a leaf.

• node.IsLeaf() returns a bool indicating whether or not node is a leaf.

• node.Child(i) returns an RPTree& that is the ith child.
  • i must be 0 or 1.
  • This function should only be called if node.NumChildren() is not 0 (e.g. if node is not a leaf). Note that this returns a valid RPTree& that can itself be used just like the root node of the tree!
  • node.Left() and node.Right() are convenience functions specific to RPTree that will return RPTree* (pointers) to the left and right children, respectively, or NULL if node has no children.
• node.Parent() will return an RPTree* that points to the parent of node, or NULL if node is the root of the RPTree.

🔗 Accessing members of a tree

• node.Bound() will return an HRectBound& object that represents the hyperrectangle bounding box of node. This is the smallest hyperrectangle that encloses all the descendant points of node.

• node.Stat() will return an EmptyStatistic& (or a StatisticType& if a custom StatisticType was specified as a template parameter) holding the statistics of the node that were computed during tree construction.

• node.Distance() will return a EuclideanDistance& (or a DistanceType& if a custom DistanceType was specified as a template parameter).

  • This function is required by the TreeType API, but given that RPTree requires an LMetric to be used, and LMetric only has static functions and holds no state, this function is not likely to be useful.

See also the developer documentation for basic tree functionality in mlpack.

🔗 Accessing data held in a tree

• node.Dataset() will return a const arma::mat& that is the dataset the tree was built on. Note that this is a permuted version of the data matrix passed to the constructor.
  • If a custom MatType is being used, the return type will be const MatType& instead of const arma::mat&.
• node.NumPoints() returns a size_t indicating the number of points held directly in node.
  • If node is not a leaf, this will return 0, as RPTree only holds points directly in its leaves.
  • If node is a leaf, then the number of points will be less than or equal to the maxLeafSize that was specified when the tree was constructed.
• node.Point(i) returns a size_t indicating the index of the i‘th point in node.Dataset().
  • i must be in the range [0, node.NumPoints() - 1] (inclusive).
  • node must be a leaf (as non-leaves do not hold any points).
  • The i‘th point in node can then be accessed as node.Dataset().col(node.Point(i)).
  • In an RPTree, because of the permutation of points done during construction, point indices are contiguous: node.Point(i + j) is the same as node.Point(i) + j for valid i and j.
  • Accessing the actual i‘th point itself can be done with, e.g., node.Dataset().col(node.Point(i)).
• node.NumDescendants() returns a size_t indicating the number of points held in all descendant leaves of node.
  • If node is the root of the tree, then node.NumDescendants() will be equal to node.Dataset().n_cols.
• node.Descendant(i) returns a size_t indicating the index of the i‘th descendant point in node.Dataset().
  • i must be in the range [0, node.NumDescendants() - 1] (inclusive).
  • node does not need to be a leaf.
  • The i‘th descendant point in node can then be accessed as node.Dataset().col(node.Descendant(i)).
  • In an RPTree, because of the permutation of points done during construction, point indices are contiguous: node.Descendant(i + j) is the same as node.Descendant(i) + j for valid i and j.
  • Accessing the actual i‘th descendant itself can be done with, e.g., node.Dataset().col(node.Descendant(i)).
• node.Begin() returns a size_t indicating the index of the first descendant point of node.
  • This is equivalent to node.Descendant(0).
• node.Count() returns a size_t indicating the number of descendant points of node.
  • This is equivalent to node.NumDescendants().

🔗 Accessing computed bound quantities of a tree

The following quantities are cached for each node in an RPTree, and so accessing them does not require any computation.

• node.FurthestPointDistance() returns a double representing the distance between the center of the bounding hyperrectangle of node and the furthest point held by node.
  • If node is not a leaf, this returns 0 (because node does not hold any points).

• node.FurthestDescendantDistance() returns a double representing the distance between the center of the bounding hyperrectangle of node and the furthest descendant point held by node.

• node.MinimumBoundDistance() returns a double representing the minimum possible distance from the center of the node to any edge of the hyperrectangle bound.
  • This quantity is half the width of the smallest dimension of node.Bound().
• node.ParentDistance() returns a double representing the distance between the center of the bounding hyperrectangle of node and the center of the bounding hyperrectangle of its parent.
  • If node is the root of the tree, 0 is returned.

Notes:

• If a custom MatType was specified when constructing the RPTree, then the return type of each method is the element type of the given MatType instead of double. (e.g., if MatType is arma::fmat, then the return type is float.)

• For more details on each bound quantity, see the developer documentation on bound quantities for trees.

🔗 Other functionality

• node.Center(center) computes the center of the bounding hyperrectangle of node and stores it in center.
  • center should be of type arma::vec&. (If a custom MatType was specified when constructing the RPTree, the type is instead the column vector type for the given MatType; e.g., arma::fvec& when MatType is arma::fmat.)
  • center will be set to have size equivalent to the dimensionality of the dataset held by node.
  • This is equivalent to calling node.Bound().Center(center).
• A RPTree can be serialized with data::Save() and data::Load().

🔗 Bounding distances with the tree

The primary use of trees in mlpack is bounding distances to points or other tree nodes. The following functions can be used for these tasks.

• node.GetNearestChild(point)
• node.GetFurthestChild(point)
  • Return a size_t indicating the index of the child (0 for left, 1 for right) that is closest to (or furthest from) point, with respect to the MinDistance() (or MaxDistance()) function.
  • If there is a tie, 0 (the left child) is returned.
  • If node is a leaf, 0 is returned.
  • point should be of type arma::vec. (If a custom MatType was specified when constructing the RPTree, the type is instead the column vector type for the given MatType; e.g., arma::fvec when MatType is arma::fmat.)
• node.GetNearestChild(other)
• node.GetFurthestChild(other)
  • Return a size_t indicating the index of the child (0 for left, 1 for right) that is closest to (or furthest from) the RPTree node other, with respect to the MinDistance() (or MaxDistance()) function.
  • If there is a tie, 2 (an invalid index) is returned. Note that this behavior differs from the version above that takes a point.
  • If node is a leaf, 0 is returned.

• node.MinDistance(point)
• node.MinDistance(other)
  • Return a double indicating the minimum possible distance between node and point, or the RPTree node other.
  • This is equivalent to the minimum possible distance between any point contained in the bounding hyperrectangle of node and point, or between any point contained in the bounding hyperrectangle of node and any point contained in the bounding hyperrectangle of other.
  • point should be of type arma::vec. (If a custom MatType was specified when constructing the RPTree, the type is instead the column vector type for the given MatType, and the return type is the element type of MatType; e.g., point should be arma::fvec when MatType is arma::fmat, and the returned distance is float).
• node.MaxDistance(point)
• node.MaxDistance(other)
  • Return a double indicating the maximum possible distance between node and point, or the RPTree node other.
  • This is equivalent to the maximum possible distance between any point contained in the bounding hyperrectangle of node and point, or between any point contained in the bounding hyperrectangle of node and any point contained in the bounding hyperrectangle of other.
  • point should be of type arma::vec. (If a custom MatType was specified when constructing the RPTree, the type is instead the column vector type for the given MatType, and the return type is the element type of MatType; e.g., point should be arma::fvec when MatType is arma::fmat, and the returned distance is float).
• node.RangeDistance(point)
• node.RangeDistance(other)
  • Return a Range whose lower bound is node.MinDistance(point) or node.MinDistance(other), and whose upper bound is node.MaxDistance(point) or node.MaxDistance(other).
  • point should be of type arma::vec. (If a custom MatType was specified when constructing the RPTree, the type is instead the column vector type for the given MatType, and the return type is a RangeType with element type the same as MatType; e.g., point should be arma::fvec when MatType is arma::fmat, and the returned type is RangeType<float>).

🔗 Tree traversals

Like every mlpack tree, the RPTree class provides a single-tree and dual-tree traversal that can be paired with a RuleType class to implement a single-tree or dual-tree algorithm.

• RPTree::SingleTreeTraverser
  • Implements a depth-first single-tree traverser.
• RPTree::DualTreeTraverser
  • Implements a dual-depth-first dual-tree traverser.

In addition to those two classes, which are required by the TreeType policy, an additional traverser is available:

• RPTree::BreadthFirstDualTreeTraverser
  • Implements a dual-breadth-first dual-tree traverser.
  • Note: this traverser is not useful for all tasks; because the RPTree only holds points in the leaves, this means that no base cases (e.g. comparisons between points) will be called until all pairs of intermediate nodes have been scored!

🔗 Example usage

Build an RPTree on the cloud dataset and print basic statistics about the tree.

// See https://datasets.mlpack.org/cloud.csv.
arma::mat dataset;
mlpack::data::Load("cloud.csv", dataset, true);

// Build the random projection tree with a leaf size of 10.  (This means that
// nodes are split until they contain 10 or fewer points.)
//
// The std::move() means that `dataset` will be empty after this call, and no
// data will be copied during tree building.
//
// Note that the '<>' isn't necessary if C++20 is being used (e.g.
// `mlpack::RPTree tree(...)` will work fine in C++20 or newer).
mlpack::RPTree<> tree(std::move(dataset), 10);

// Print the bounding box of the root node.
std::cout << "Bounding box of root node:" << std::endl;
for (size_t i = 0; i < tree.Bound().Dim(); ++i)
{
  std::cout << " - Dimension " << i << ": [" << tree.Bound()[i].Lo() << ", "
      << tree.Bound()[i].Hi() << "]." << std::endl;
}
std::cout << std::endl;

// Print the number of descendant points of the root, and of each of its
// children.
std::cout << "Descendant points of root:        "
    << tree.NumDescendants() << "." << std::endl;
std::cout << "Descendant points of left child:  "
    << tree.Left()->NumDescendants() << "." << std::endl;
std::cout << "Descendant points of right child: "
    << tree.Right()->NumDescendants() << "." << std::endl;
std::cout << std::endl;

// Compute the center of the rp-tree.
arma::vec center;
tree.Center(center);
std::cout << "Center of random projection tree: " << center.t();

Build two RPTrees on subsets of the corel dataset and compute minimum and maximum distances between different nodes in the tree.

// See https://datasets.mlpack.org/corel-histogram.csv.
arma::mat dataset;
mlpack::data::Load("corel-histogram.csv", dataset, true);

// Build rp-trees on the first half and the second half of points.
mlpack::RPTree<> tree1(dataset.cols(0, dataset.n_cols / 2));
mlpack::RPTree<> tree2(dataset.cols(dataset.n_cols / 2 + 1,
    dataset.n_cols - 1));

// Compute the maximum distance between the trees.
std::cout << "Maximum distance between tree root nodes: "
    << tree1.MaxDistance(tree2) << "." << std::endl;

// Get the leftmost grandchild of the first tree's root---if it exists.
if (!tree1.IsLeaf() && !tree1.Child(0).IsLeaf())
{
  mlpack::RPTree<>& node1 = tree1.Child(0).Child(0);

  // Get the rightmost grandchild of the second tree's root---if it exists.
  if (!tree2.IsLeaf() && !tree2.Child(1).IsLeaf())
  {
    mlpack::RPTree<>& node2 = tree2.Child(1).Child(1);

    // Print the minimum and maximum distance between the nodes.
    mlpack::Range dists = node1.RangeDistance(node2);
    std::cout << "Possible distances between two grandchild nodes: ["
        << dists.Lo() << ", " << dists.Hi() << "]." << std::endl;

    // Print the minimum distance between the first node and the first
    // descendant point of the second node.
    const size_t descendantIndex = node2.Descendant(0);
    const double descendantMinDist =
        node1.MinDistance(node2.Dataset().col(descendantIndex));
    std::cout << "Minimum distance between grandchild node and descendant "
        << "point: " << descendantMinDist << "." << std::endl;

    // Which child of node2 is closer to node1?
    const size_t closerIndex = node2.GetNearestChild(node1);
    if (closerIndex == 0)
      std::cout << "The left child of node2 is closer to node1." << std::endl;
    else if (closerIndex == 1)
      std::cout << "The right child of node2 is closer to node1." << std::endl;
    else // closerIndex == 2 in this case.
      std::cout << "Both children of node2 are equally close to node1."
          << std::endl;

    // And which child of node1 is further from node2?
    const size_t furtherIndex = node1.GetFurthestChild(node2);
    if (furtherIndex == 0)
      std::cout << "The left child of node1 is further from node2."
          << std::endl;
    else if (furtherIndex == 1)
      std::cout << "The right child of node1 is further from node2."
          << std::endl;
    else // furtherIndex == 2 in this case.
      std::cout << "Both children of node1 are equally far from node2."
          << std::endl;
  }
}

Build an RPTree on 32-bit floating point data and save it to disk.

// See https://datasets.mlpack.org/corel-histogram.csv.
arma::fmat dataset;
mlpack::data::Load("corel-histogram.csv", dataset);

// Build the RPTree using 32-bit floating point data as the matrix type.
// We will still use the default EmptyStatistic and EuclideanDistance
// parameters.  A leaf size of 100 is used here.
mlpack::RPTree<mlpack::EuclideanDistance,
               mlpack::EmptyStatistic,
               arma::fmat> tree(std::move(dataset), 100);

// Save the RPTree to disk with the name 'tree'.
mlpack::data::Save("tree.bin", "tree", tree);

std::cout << "Saved tree with " << tree.Dataset().n_cols << " points to "
    << "'tree.bin'." << std::endl;

Load a 32-bit floating point RPTree from disk, then traverse it manually and find the number of leaf nodes with fewer than 10 points.

// This assumes the tree has already been saved to 'tree.bin' (as in the example
// above).

// This convenient typedef saves us a long type name!
using TreeType = mlpack::RPTree<mlpack::EuclideanDistance,
                                mlpack::EmptyStatistic,
                                arma::fmat>;

TreeType tree;
mlpack::data::Load("tree.bin", "tree", tree);
std::cout << "Tree loaded with " << tree.NumDescendants() << " points."
    << std::endl;

// Recurse in a depth-first manner.  Count both the total number of leaves, and
// the number of leaves with fewer than 10 points.
size_t leafCount = 0;
size_t totalLeafCount = 0;
std::stack<TreeType*> stack;
stack.push(&tree);
while (!stack.empty())
{
  TreeType* node = stack.top();
  stack.pop();

  if (node->NumPoints() < 10)
    ++leafCount;
  ++totalLeafCount;

  if (!node->IsLeaf())
  {
    stack.push(node->Left());
    stack.push(node->Right());
  }
}

// Note that it would be possible to use TreeType::SingleTreeTraverser to
// perform the recursion above, but that is more well-suited for more complex
// tasks that require pruning and other non-trivial behavior; so using a simple
// stack is the better option here.

// Print the results.
std::cout << leafCount << " out of " << totalLeafCount << " leaves have fewer "
  << "than 10 points." << std::endl;

Build an RPTree and map between original points and new points.

// See https://datasets.mlpack.org/cloud.csv.
arma::mat dataset;
mlpack::data::Load("cloud.csv", dataset, true);

// Build the tree.
std::vector<size_t> oldFromNew, newFromOld;
mlpack::RPTree<> tree(dataset, oldFromNew, newFromOld);

// oldFromNew and newFromOld will be set to the same size as the dataset.
std::cout << "Number of points in dataset: " << dataset.n_cols << "."
    << std::endl;
std::cout << "Size of oldFromNew: " << oldFromNew.size() << "." << std::endl;
std::cout << "Size of newFromOld: " << newFromOld.size() << "." << std::endl;
std::cout << std::endl;

// See where point 42 in the tree's dataset came from.
std::cout << "Point 42 in the permuted tree's dataset:" << std::endl;
std::cout << "  " << tree.Dataset().col(42).t();
std::cout << "Was originally point " << oldFromNew[42] << ":" << std::endl;
std::cout << "  " << dataset.col(oldFromNew[42]).t();
std::cout << std::endl;

// See where point 7 in the original dataset was mapped.
std::cout << "Point 7 in original dataset:" << std::endl;
std::cout << "  " << dataset.col(7).t();
std::cout << "Mapped to point " << newFromOld[7] << ":" << std::endl;
std::cout << "  " << tree.Dataset().col(newFromOld[7]).t();