# Copyright Anne M. Archibald 2008 # Released under the scipy license from __future__ import division, print_function, absolute_import import sys import numpy as np from heapq import heappush, heappop import scipy.sparse __all__ = ['minkowski_distance_p', 'minkowski_distance', 'distance_matrix', 'Rectangle', 'KDTree'] def minkowski_distance_p(x, y, p=2): """ Compute the p-th power of the L**p distance between two arrays. For efficiency, this function computes the L**p distance but does not extract the pth root. If `p` is 1 or infinity, this is equal to the actual L**p distance. Parameters ---------- x : (M, K) array_like Input array. y : (N, K) array_like Input array. p : float, 1 <= p <= infinity Which Minkowski p-norm to use. Examples -------- >>> from scipy.spatial import minkowski_distance_p >>> minkowski_distance_p([[0,0],[0,0]], [[1,1],[0,1]]) array([2, 1]) """ x = np.asarray(x) y = np.asarray(y) if p == np.inf: return np.amax(np.abs(y-x), axis=-1) elif p == 1: return np.sum(np.abs(y-x), axis=-1) else: return np.sum(np.abs(y-x)**p, axis=-1) def minkowski_distance(x, y, p=2): """ Compute the L**p distance between two arrays. Parameters ---------- x : (M, K) array_like Input array. y : (N, K) array_like Input array. p : float, 1 <= p <= infinity Which Minkowski p-norm to use. Examples -------- >>> from scipy.spatial import minkowski_distance >>> minkowski_distance([[0,0],[0,0]], [[1,1],[0,1]]) array([ 1.41421356, 1. ]) """ x = np.asarray(x) y = np.asarray(y) if p == np.inf or p == 1: return minkowski_distance_p(x, y, p) else: return minkowski_distance_p(x, y, p)**(1./p) class Rectangle(object): """Hyperrectangle class. Represents a Cartesian product of intervals. """ def __init__(self, maxes, mins): """Construct a hyperrectangle.""" self.maxes = np.maximum(maxes,mins).astype(float) self.mins = np.minimum(maxes,mins).astype(float) self.m, = self.maxes.shape def __repr__(self): return "" % list(zip(self.mins, self.maxes)) def volume(self): """Total volume.""" return np.prod(self.maxes-self.mins) def split(self, d, split): """ Produce two hyperrectangles by splitting. In general, if you need to compute maximum and minimum distances to the children, it can be done more efficiently by updating the maximum and minimum distances to the parent. Parameters ---------- d : int Axis to split hyperrectangle along. split : float Position along axis `d` to split at. """ mid = np.copy(self.maxes) mid[d] = split less = Rectangle(self.mins, mid) mid = np.copy(self.mins) mid[d] = split greater = Rectangle(mid, self.maxes) return less, greater def min_distance_point(self, x, p=2.): """ Return the minimum distance between input and points in the hyperrectangle. Parameters ---------- x : array_like Input. p : float, optional Input. """ return minkowski_distance(0, np.maximum(0,np.maximum(self.mins-x,x-self.maxes)),p) def max_distance_point(self, x, p=2.): """ Return the maximum distance between input and points in the hyperrectangle. Parameters ---------- x : array_like Input array. p : float, optional Input. """ return minkowski_distance(0, np.maximum(self.maxes-x,x-self.mins),p) def min_distance_rectangle(self, other, p=2.): """ Compute the minimum distance between points in the two hyperrectangles. Parameters ---------- other : hyperrectangle Input. p : float Input. """ return minkowski_distance(0, np.maximum(0,np.maximum(self.mins-other.maxes,other.mins-self.maxes)),p) def max_distance_rectangle(self, other, p=2.): """ Compute the maximum distance between points in the two hyperrectangles. Parameters ---------- other : hyperrectangle Input. p : float, optional Input. """ return minkowski_distance(0, np.maximum(self.maxes-other.mins,other.maxes-self.mins),p) class KDTree(object): """ kd-tree for quick nearest-neighbor lookup This class provides an index into a set of k-dimensional points which can be used to rapidly look up the nearest neighbors of any point. Parameters ---------- data : (N,K) array_like The data points to be indexed. This array is not copied, and so modifying this data will result in bogus results. leafsize : int, optional The number of points at which the algorithm switches over to brute-force. Has to be positive. Raises ------ RuntimeError The maximum recursion limit can be exceeded for large data sets. If this happens, either increase the value for the `leafsize` parameter or increase the recursion limit by:: >>> import sys >>> sys.setrecursionlimit(10000) See Also -------- cKDTree : Implementation of `KDTree` in Cython Notes ----- The algorithm used is described in Maneewongvatana and Mount 1999. The general idea is that the kd-tree is a binary tree, each of whose nodes represents an axis-aligned hyperrectangle. Each node specifies an axis and splits the set of points based on whether their coordinate along that axis is greater than or less than a particular value. During construction, the axis and splitting point are chosen by the "sliding midpoint" rule, which ensures that the cells do not all become long and thin. The tree can be queried for the r closest neighbors of any given point (optionally returning only those within some maximum distance of the point). It can also be queried, with a substantial gain in efficiency, for the r approximate closest neighbors. For large dimensions (20 is already large) do not expect this to run significantly faster than brute force. High-dimensional nearest-neighbor queries are a substantial open problem in computer science. The tree also supports all-neighbors queries, both with arrays of points and with other kd-trees. These do use a reasonably efficient algorithm, but the kd-tree is not necessarily the best data structure for this sort of calculation. """ def __init__(self, data, leafsize=10): self.data = np.asarray(data) self.n, self.m = np.shape(self.data) self.leafsize = int(leafsize) if self.leafsize < 1: raise ValueError("leafsize must be at least 1") self.maxes = np.amax(self.data,axis=0) self.mins = np.amin(self.data,axis=0) self.tree = self.__build(np.arange(self.n), self.maxes, self.mins) class node(object): if sys.version_info[0] >= 3: def __lt__(self, other): return id(self) < id(other) def __gt__(self, other): return id(self) > id(other) def __le__(self, other): return id(self) <= id(other) def __ge__(self, other): return id(self) >= id(other) def __eq__(self, other): return id(self) == id(other) class leafnode(node): def __init__(self, idx): self.idx = idx self.children = len(idx) class innernode(node): def __init__(self, split_dim, split, less, greater): self.split_dim = split_dim self.split = split self.less = less self.greater = greater self.children = less.children+greater.children def __build(self, idx, maxes, mins): if len(idx) <= self.leafsize: return KDTree.leafnode(idx) else: data = self.data[idx] # maxes = np.amax(data,axis=0) # mins = np.amin(data,axis=0) d = np.argmax(maxes-mins) maxval = maxes[d] minval = mins[d] if maxval == minval: # all points are identical; warn user? return KDTree.leafnode(idx) data = data[:,d] # sliding midpoint rule; see Maneewongvatana and Mount 1999 # for arguments that this is a good idea. split = (maxval+minval)/2 less_idx = np.nonzero(data <= split)[0] greater_idx = np.nonzero(data > split)[0] if len(less_idx) == 0: split = np.amin(data) less_idx = np.nonzero(data <= split)[0] greater_idx = np.nonzero(data > split)[0] if len(greater_idx) == 0: split = np.amax(data) less_idx = np.nonzero(data < split)[0] greater_idx = np.nonzero(data >= split)[0] if len(less_idx) == 0: # _still_ zero? all must have the same value if not np.all(data == data[0]): raise ValueError("Troublesome data array: %s" % data) split = data[0] less_idx = np.arange(len(data)-1) greater_idx = np.array([len(data)-1]) lessmaxes = np.copy(maxes) lessmaxes[d] = split greatermins = np.copy(mins) greatermins[d] = split return KDTree.innernode(d, split, self.__build(idx[less_idx],lessmaxes,mins), self.__build(idx[greater_idx],maxes,greatermins)) def __query(self, x, k=1, eps=0, p=2, distance_upper_bound=np.inf): side_distances = np.maximum(0,np.maximum(x-self.maxes,self.mins-x)) if p != np.inf: side_distances **= p min_distance = np.sum(side_distances) else: min_distance = np.amax(side_distances) # priority queue for chasing nodes # entries are: # minimum distance between the cell and the target # distances between the nearest side of the cell and the target # the head node of the cell q = [(min_distance, tuple(side_distances), self.tree)] # priority queue for the nearest neighbors # furthest known neighbor first # entries are (-distance**p, i) neighbors = [] if eps == 0: epsfac = 1 elif p == np.inf: epsfac = 1/(1+eps) else: epsfac = 1/(1+eps)**p if p != np.inf and distance_upper_bound != np.inf: distance_upper_bound = distance_upper_bound**p while q: min_distance, side_distances, node = heappop(q) if isinstance(node, KDTree.leafnode): # brute-force data = self.data[node.idx] ds = minkowski_distance_p(data,x[np.newaxis,:],p) for i in range(len(ds)): if ds[i] < distance_upper_bound: if len(neighbors) == k: heappop(neighbors) heappush(neighbors, (-ds[i], node.idx[i])) if len(neighbors) == k: distance_upper_bound = -neighbors[0][0] else: # we don't push cells that are too far onto the queue at all, # but since the distance_upper_bound decreases, we might get # here even if the cell's too far if min_distance > distance_upper_bound*epsfac: # since this is the nearest cell, we're done, bail out break # compute minimum distances to the children and push them on if x[node.split_dim] < node.split: near, far = node.less, node.greater else: near, far = node.greater, node.less # near child is at the same distance as the current node heappush(q,(min_distance, side_distances, near)) # far child is further by an amount depending only # on the split value sd = list(side_distances) if p == np.inf: min_distance = max(min_distance, abs(node.split-x[node.split_dim])) elif p == 1: sd[node.split_dim] = np.abs(node.split-x[node.split_dim]) min_distance = min_distance - side_distances[node.split_dim] + sd[node.split_dim] else: sd[node.split_dim] = np.abs(node.split-x[node.split_dim])**p min_distance = min_distance - side_distances[node.split_dim] + sd[node.split_dim] # far child might be too far, if so, don't bother pushing it if min_distance <= distance_upper_bound*epsfac: heappush(q,(min_distance, tuple(sd), far)) if p == np.inf: return sorted([(-d,i) for (d,i) in neighbors]) else: return sorted([((-d)**(1./p),i) for (d,i) in neighbors]) def query(self, x, k=1, eps=0, p=2, distance_upper_bound=np.inf): """ Query the kd-tree for nearest neighbors Parameters ---------- x : array_like, last dimension self.m An array of points to query. k : int, optional The number of nearest neighbors to return. eps : nonnegative float, optional Return approximate nearest neighbors; the kth returned value is guaranteed to be no further than (1+eps) times the distance to the real kth nearest neighbor. p : float, 1<=p<=infinity, optional Which Minkowski p-norm to use. 1 is the sum-of-absolute-values "Manhattan" distance 2 is the usual Euclidean distance infinity is the maximum-coordinate-difference distance distance_upper_bound : nonnegative float, optional Return only neighbors within this distance. This is used to prune tree searches, so if you are doing a series of nearest-neighbor queries, it may help to supply the distance to the nearest neighbor of the most recent point. Returns ------- d : float or array of floats The distances to the nearest neighbors. If x has shape tuple+(self.m,), then d has shape tuple if k is one, or tuple+(k,) if k is larger than one. Missing neighbors (e.g. when k > n or distance_upper_bound is given) are indicated with infinite distances. If k is None, then d is an object array of shape tuple, containing lists of distances. In either case the hits are sorted by distance (nearest first). i : integer or array of integers The locations of the neighbors in self.data. i is the same shape as d. Examples -------- >>> from scipy import spatial >>> x, y = np.mgrid[0:5, 2:8] >>> tree = spatial.KDTree(list(zip(x.ravel(), y.ravel()))) >>> tree.data array([[0, 2], [0, 3], [0, 4], [0, 5], [0, 6], [0, 7], [1, 2], [1, 3], [1, 4], [1, 5], [1, 6], [1, 7], [2, 2], [2, 3], [2, 4], [2, 5], [2, 6], [2, 7], [3, 2], [3, 3], [3, 4], [3, 5], [3, 6], [3, 7], [4, 2], [4, 3], [4, 4], [4, 5], [4, 6], [4, 7]]) >>> pts = np.array([[0, 0], [2.1, 2.9]]) >>> tree.query(pts) (array([ 2. , 0.14142136]), array([ 0, 13])) >>> tree.query(pts[0]) (2.0, 0) """ x = np.asarray(x) if np.shape(x)[-1] != self.m: raise ValueError("x must consist of vectors of length %d but has shape %s" % (self.m, np.shape(x))) if p < 1: raise ValueError("Only p-norms with 1<=p<=infinity permitted") retshape = np.shape(x)[:-1] if retshape != (): if k is None: dd = np.empty(retshape,dtype=object) ii = np.empty(retshape,dtype=object) elif k > 1: dd = np.empty(retshape+(k,),dtype=float) dd.fill(np.inf) ii = np.empty(retshape+(k,),dtype=int) ii.fill(self.n) elif k == 1: dd = np.empty(retshape,dtype=float) dd.fill(np.inf) ii = np.empty(retshape,dtype=int) ii.fill(self.n) else: raise ValueError("Requested %s nearest neighbors; acceptable numbers are integers greater than or equal to one, or None") for c in np.ndindex(retshape): hits = self.__query(x[c], k=k, eps=eps, p=p, distance_upper_bound=distance_upper_bound) if k is None: dd[c] = [d for (d,i) in hits] ii[c] = [i for (d,i) in hits] elif k > 1: for j in range(len(hits)): dd[c+(j,)], ii[c+(j,)] = hits[j] elif k == 1: if len(hits) > 0: dd[c], ii[c] = hits[0] else: dd[c] = np.inf ii[c] = self.n return dd, ii else: hits = self.__query(x, k=k, eps=eps, p=p, distance_upper_bound=distance_upper_bound) if k is None: return [d for (d,i) in hits], [i for (d,i) in hits] elif k == 1: if len(hits) > 0: return hits[0] else: return np.inf, self.n elif k > 1: dd = np.empty(k,dtype=float) dd.fill(np.inf) ii = np.empty(k,dtype=int) ii.fill(self.n) for j in range(len(hits)): dd[j], ii[j] = hits[j] return dd, ii else: raise ValueError("Requested %s nearest neighbors; acceptable numbers are integers greater than or equal to one, or None") def __query_ball_point(self, x, r, p=2., eps=0): R = Rectangle(self.maxes, self.mins) def traverse_checking(node, rect): if rect.min_distance_point(x, p) > r / (1. + eps): return [] elif rect.max_distance_point(x, p) < r * (1. + eps): return traverse_no_checking(node) elif isinstance(node, KDTree.leafnode): d = self.data[node.idx] return node.idx[minkowski_distance(d, x, p) <= r].tolist() else: less, greater = rect.split(node.split_dim, node.split) return traverse_checking(node.less, less) + \ traverse_checking(node.greater, greater) def traverse_no_checking(node): if isinstance(node, KDTree.leafnode): return node.idx.tolist() else: return traverse_no_checking(node.less) + \ traverse_no_checking(node.greater) return traverse_checking(self.tree, R) def query_ball_point(self, x, r, p=2., eps=0): """Find all points within distance r of point(s) x. Parameters ---------- x : array_like, shape tuple + (self.m,) The point or points to search for neighbors of. r : positive float The radius of points to return. p : float, optional Which Minkowski p-norm to use. Should be in the range [1, inf]. eps : nonnegative float, optional Approximate search. Branches of the tree are not explored if their nearest points are further than ``r / (1 + eps)``, and branches are added in bulk if their furthest points are nearer than ``r * (1 + eps)``. Returns ------- results : list or array of lists If `x` is a single point, returns a list of the indices of the neighbors of `x`. If `x` is an array of points, returns an object array of shape tuple containing lists of neighbors. Notes ----- If you have many points whose neighbors you want to find, you may save substantial amounts of time by putting them in a KDTree and using query_ball_tree. Examples -------- >>> from scipy import spatial >>> x, y = np.mgrid[0:5, 0:5] >>> points = zip(x.ravel(), y.ravel()) >>> tree = spatial.KDTree(points) >>> tree.query_ball_point([2, 0], 1) [5, 10, 11, 15] Query multiple points and plot the results: >>> import matplotlib.pyplot as plt >>> points = np.asarray(points) >>> plt.plot(points[:,0], points[:,1], '.') >>> for results in tree.query_ball_point(([2, 0], [3, 3]), 1): ... nearby_points = points[results] ... plt.plot(nearby_points[:,0], nearby_points[:,1], 'o') >>> plt.margins(0.1, 0.1) >>> plt.show() """ x = np.asarray(x) if x.shape[-1] != self.m: raise ValueError("Searching for a %d-dimensional point in a " "%d-dimensional KDTree" % (x.shape[-1], self.m)) if len(x.shape) == 1: return self.__query_ball_point(x, r, p, eps) else: retshape = x.shape[:-1] result = np.empty(retshape, dtype=object) for c in np.ndindex(retshape): result[c] = self.__query_ball_point(x[c], r, p=p, eps=eps) return result def query_ball_tree(self, other, r, p=2., eps=0): """Find all pairs of points whose distance is at most r Parameters ---------- other : KDTree instance The tree containing points to search against. r : float The maximum distance, has to be positive. p : float, optional Which Minkowski norm to use. `p` has to meet the condition ``1 <= p <= infinity``. eps : float, optional Approximate search. Branches of the tree are not explored if their nearest points are further than ``r/(1+eps)``, and branches are added in bulk if their furthest points are nearer than ``r * (1+eps)``. `eps` has to be non-negative. Returns ------- results : list of lists For each element ``self.data[i]`` of this tree, ``results[i]`` is a list of the indices of its neighbors in ``other.data``. """ results = [[] for i in range(self.n)] def traverse_checking(node1, rect1, node2, rect2): if rect1.min_distance_rectangle(rect2, p) > r/(1.+eps): return elif rect1.max_distance_rectangle(rect2, p) < r*(1.+eps): traverse_no_checking(node1, node2) elif isinstance(node1, KDTree.leafnode): if isinstance(node2, KDTree.leafnode): d = other.data[node2.idx] for i in node1.idx: results[i] += node2.idx[minkowski_distance(d,self.data[i],p) <= r].tolist() else: less, greater = rect2.split(node2.split_dim, node2.split) traverse_checking(node1,rect1,node2.less,less) traverse_checking(node1,rect1,node2.greater,greater) elif isinstance(node2, KDTree.leafnode): less, greater = rect1.split(node1.split_dim, node1.split) traverse_checking(node1.less,less,node2,rect2) traverse_checking(node1.greater,greater,node2,rect2) else: less1, greater1 = rect1.split(node1.split_dim, node1.split) less2, greater2 = rect2.split(node2.split_dim, node2.split) traverse_checking(node1.less,less1,node2.less,less2) traverse_checking(node1.less,less1,node2.greater,greater2) traverse_checking(node1.greater,greater1,node2.less,less2) traverse_checking(node1.greater,greater1,node2.greater,greater2) def traverse_no_checking(node1, node2): if isinstance(node1, KDTree.leafnode): if isinstance(node2, KDTree.leafnode): for i in node1.idx: results[i] += node2.idx.tolist() else: traverse_no_checking(node1, node2.less) traverse_no_checking(node1, node2.greater) else: traverse_no_checking(node1.less, node2) traverse_no_checking(node1.greater, node2) traverse_checking(self.tree, Rectangle(self.maxes, self.mins), other.tree, Rectangle(other.maxes, other.mins)) return results def query_pairs(self, r, p=2., eps=0): """ Find all pairs of points within a distance. Parameters ---------- r : positive float The maximum distance. p : float, optional Which Minkowski norm to use. `p` has to meet the condition ``1 <= p <= infinity``. eps : float, optional Approximate search. Branches of the tree are not explored if their nearest points are further than ``r/(1+eps)``, and branches are added in bulk if their furthest points are nearer than ``r * (1+eps)``. `eps` has to be non-negative. Returns ------- results : set Set of pairs ``(i,j)``, with ``i < j``, for which the corresponding positions are close. """ results = set() def traverse_checking(node1, rect1, node2, rect2): if rect1.min_distance_rectangle(rect2, p) > r/(1.+eps): return elif rect1.max_distance_rectangle(rect2, p) < r*(1.+eps): traverse_no_checking(node1, node2) elif isinstance(node1, KDTree.leafnode): if isinstance(node2, KDTree.leafnode): # Special care to avoid duplicate pairs if id(node1) == id(node2): d = self.data[node2.idx] for i in node1.idx: for j in node2.idx[minkowski_distance(d,self.data[i],p) <= r]: if i < j: results.add((i,j)) else: d = self.data[node2.idx] for i in node1.idx: for j in node2.idx[minkowski_distance(d,self.data[i],p) <= r]: if i < j: results.add((i,j)) elif j < i: results.add((j,i)) else: less, greater = rect2.split(node2.split_dim, node2.split) traverse_checking(node1,rect1,node2.less,less) traverse_checking(node1,rect1,node2.greater,greater) elif isinstance(node2, KDTree.leafnode): less, greater = rect1.split(node1.split_dim, node1.split) traverse_checking(node1.less,less,node2,rect2) traverse_checking(node1.greater,greater,node2,rect2) else: less1, greater1 = rect1.split(node1.split_dim, node1.split) less2, greater2 = rect2.split(node2.split_dim, node2.split) traverse_checking(node1.less,less1,node2.less,less2) traverse_checking(node1.less,less1,node2.greater,greater2) # Avoid traversing (node1.less, node2.greater) and # (node1.greater, node2.less) (it's the same node pair twice # over, which is the source of the complication in the # original KDTree.query_pairs) if id(node1) != id(node2): traverse_checking(node1.greater,greater1,node2.less,less2) traverse_checking(node1.greater,greater1,node2.greater,greater2) def traverse_no_checking(node1, node2): if isinstance(node1, KDTree.leafnode): if isinstance(node2, KDTree.leafnode): # Special care to avoid duplicate pairs if id(node1) == id(node2): for i in node1.idx: for j in node2.idx: if i < j: results.add((i,j)) else: for i in node1.idx: for j in node2.idx: if i < j: results.add((i,j)) elif j < i: results.add((j,i)) else: traverse_no_checking(node1, node2.less) traverse_no_checking(node1, node2.greater) else: # Avoid traversing (node1.less, node2.greater) and # (node1.greater, node2.less) (it's the same node pair twice # over, which is the source of the complication in the # original KDTree.query_pairs) if id(node1) == id(node2): traverse_no_checking(node1.less, node2.less) traverse_no_checking(node1.less, node2.greater) traverse_no_checking(node1.greater, node2.greater) else: traverse_no_checking(node1.less, node2) traverse_no_checking(node1.greater, node2) traverse_checking(self.tree, Rectangle(self.maxes, self.mins), self.tree, Rectangle(self.maxes, self.mins)) return results def count_neighbors(self, other, r, p=2.): """ Count how many nearby pairs can be formed. Count the number of pairs (x1,x2) can be formed, with x1 drawn from self and x2 drawn from `other`, and where ``distance(x1, x2, p) <= r``. This is the "two-point correlation" described in Gray and Moore 2000, "N-body problems in statistical learning", and the code here is based on their algorithm. Parameters ---------- other : KDTree instance The other tree to draw points from. r : float or one-dimensional array of floats The radius to produce a count for. Multiple radii are searched with a single tree traversal. p : float, 1<=p<=infinity, optional Which Minkowski p-norm to use Returns ------- result : int or 1-D array of ints The number of pairs. Note that this is internally stored in a numpy int, and so may overflow if very large (2e9). """ def traverse(node1, rect1, node2, rect2, idx): min_r = rect1.min_distance_rectangle(rect2,p) max_r = rect1.max_distance_rectangle(rect2,p) c_greater = r[idx] > max_r result[idx[c_greater]] += node1.children*node2.children idx = idx[(min_r <= r[idx]) & (r[idx] <= max_r)] if len(idx) == 0: return if isinstance(node1,KDTree.leafnode): if isinstance(node2,KDTree.leafnode): ds = minkowski_distance(self.data[node1.idx][:,np.newaxis,:], other.data[node2.idx][np.newaxis,:,:], p).ravel() ds.sort() result[idx] += np.searchsorted(ds,r[idx],side='right') else: less, greater = rect2.split(node2.split_dim, node2.split) traverse(node1, rect1, node2.less, less, idx) traverse(node1, rect1, node2.greater, greater, idx) else: if isinstance(node2,KDTree.leafnode): less, greater = rect1.split(node1.split_dim, node1.split) traverse(node1.less, less, node2, rect2, idx) traverse(node1.greater, greater, node2, rect2, idx) else: less1, greater1 = rect1.split(node1.split_dim, node1.split) less2, greater2 = rect2.split(node2.split_dim, node2.split) traverse(node1.less,less1,node2.less,less2,idx) traverse(node1.less,less1,node2.greater,greater2,idx) traverse(node1.greater,greater1,node2.less,less2,idx) traverse(node1.greater,greater1,node2.greater,greater2,idx) R1 = Rectangle(self.maxes, self.mins) R2 = Rectangle(other.maxes, other.mins) if np.shape(r) == (): r = np.array([r]) result = np.zeros(1,dtype=int) traverse(self.tree, R1, other.tree, R2, np.arange(1)) return result[0] elif len(np.shape(r)) == 1: r = np.asarray(r) n, = r.shape result = np.zeros(n,dtype=int) traverse(self.tree, R1, other.tree, R2, np.arange(n)) return result else: raise ValueError("r must be either a single value or a one-dimensional array of values") def sparse_distance_matrix(self, other, max_distance, p=2.): """ Compute a sparse distance matrix Computes a distance matrix between two KDTrees, leaving as zero any distance greater than max_distance. Parameters ---------- other : KDTree max_distance : positive float p : float, optional Returns ------- result : dok_matrix Sparse matrix representing the results in "dictionary of keys" format. """ result = scipy.sparse.dok_matrix((self.n,other.n)) def traverse(node1, rect1, node2, rect2): if rect1.min_distance_rectangle(rect2, p) > max_distance: return elif isinstance(node1, KDTree.leafnode): if isinstance(node2, KDTree.leafnode): for i in node1.idx: for j in node2.idx: d = minkowski_distance(self.data[i],other.data[j],p) if d <= max_distance: result[i,j] = d else: less, greater = rect2.split(node2.split_dim, node2.split) traverse(node1,rect1,node2.less,less) traverse(node1,rect1,node2.greater,greater) elif isinstance(node2, KDTree.leafnode): less, greater = rect1.split(node1.split_dim, node1.split) traverse(node1.less,less,node2,rect2) traverse(node1.greater,greater,node2,rect2) else: less1, greater1 = rect1.split(node1.split_dim, node1.split) less2, greater2 = rect2.split(node2.split_dim, node2.split) traverse(node1.less,less1,node2.less,less2) traverse(node1.less,less1,node2.greater,greater2) traverse(node1.greater,greater1,node2.less,less2) traverse(node1.greater,greater1,node2.greater,greater2) traverse(self.tree, Rectangle(self.maxes, self.mins), other.tree, Rectangle(other.maxes, other.mins)) return result def distance_matrix(x, y, p=2, threshold=1000000): """ Compute the distance matrix. Returns the matrix of all pair-wise distances. Parameters ---------- x : (M, K) array_like TODO: description needed y : (N, K) array_like TODO: description needed p : float, 1 <= p <= infinity Which Minkowski p-norm to use. threshold : positive int If ``M * N * K`` > `threshold`, algorithm uses a Python loop instead of large temporary arrays. Returns ------- result : (M, N) ndarray Distance matrix. Examples -------- >>> from scipy.spatial import distance_matrix >>> distance_matrix([[0,0],[0,1]], [[1,0],[1,1]]) array([[ 1. , 1.41421356], [ 1.41421356, 1. ]]) """ x = np.asarray(x) m, k = x.shape y = np.asarray(y) n, kk = y.shape if k != kk: raise ValueError("x contains %d-dimensional vectors but y contains %d-dimensional vectors" % (k, kk)) if m*n*k <= threshold: return minkowski_distance(x[:,np.newaxis,:],y[np.newaxis,:,:],p) else: result = np.empty((m,n),dtype=float) # FIXME: figure out the best dtype if m < n: for i in range(m): result[i,:] = minkowski_distance(x[i],y,p) else: for j in range(n): result[:,j] = minkowski_distance(x,y[j],p) return result