""" Template for intervaltree WARNING: DO NOT edit .pxi FILE directly, .pxi is generated from .pxi.in """ from pandas._libs.algos import is_monotonic ctypedef fused int_scalar_t: int64_t float64_t ctypedef fused uint_scalar_t: uint64_t float64_t ctypedef fused scalar_t: int_scalar_t uint_scalar_t # ---------------------------------------------------------------------- # IntervalTree # ---------------------------------------------------------------------- cdef class IntervalTree(IntervalMixin): """A centered interval tree Based off the algorithm described on Wikipedia: https://en.wikipedia.org/wiki/Interval_tree we are emulating the IndexEngine interface """ cdef readonly: ndarray left, right IntervalNode root object dtype str closed object _is_overlapping, _left_sorter, _right_sorter Py_ssize_t _na_count def __init__(self, left, right, closed='right', leaf_size=100): """ Parameters ---------- left, right : np.ndarray[ndim=1] Left and right bounds for each interval. Assumed to contain no NaNs. closed : {'left', 'right', 'both', 'neither'}, optional Whether the intervals are closed on the left-side, right-side, both or neither. Defaults to 'right'. leaf_size : int, optional Parameter that controls when the tree switches from creating nodes to brute-force search. Tune this parameter to optimize query performance. """ if closed not in ['left', 'right', 'both', 'neither']: raise ValueError("invalid option for 'closed': %s" % closed) left = np.asarray(left) right = np.asarray(right) self.dtype = np.result_type(left, right) self.left = np.asarray(left, dtype=self.dtype) self.right = np.asarray(right, dtype=self.dtype) indices = np.arange(len(left), dtype='int64') self.closed = closed # GH 23352: ensure no nan in nodes mask = ~np.isnan(self.left) self._na_count = len(mask) - mask.sum() self.left = self.left[mask] self.right = self.right[mask] indices = indices[mask] node_cls = NODE_CLASSES[str(self.dtype), closed] self.root = node_cls(self.left, self.right, indices, leaf_size) @property def left_sorter(self) -> np.ndarray: """How to sort the left labels; this is used for binary search """ if self._left_sorter is None: values = [self.right, self.left] self._left_sorter = np.lexsort(values) return self._left_sorter @property def right_sorter(self) -> np.ndarray: """How to sort the right labels """ if self._right_sorter is None: self._right_sorter = np.argsort(self.right) return self._right_sorter @property def is_overlapping(self) -> bool: """ Determine if the IntervalTree contains overlapping intervals. Cached as self._is_overlapping. """ if self._is_overlapping is not None: return self._is_overlapping # <= when both sides closed since endpoints can overlap op = le if self.closed == 'both' else lt # overlap if start of current interval < end of previous interval # (current and previous in terms of sorted order by left/start side) current = self.left[self.left_sorter[1:]] previous = self.right[self.left_sorter[:-1]] self._is_overlapping = bool(op(current, previous).any()) return self._is_overlapping @property def is_monotonic_increasing(self) -> bool: """ Return True if the IntervalTree is monotonic increasing (only equal or increasing values), else False """ if self._na_count > 0: return False sort_order = self.left_sorter return is_monotonic(sort_order, False)[0] def get_indexer(self, scalar_t[:] target) -> np.ndarray: """Return the positions corresponding to unique intervals that overlap with the given array of scalar targets. """ # TODO: write get_indexer_intervals cdef: Py_ssize_t old_len Py_ssize_t i Int64Vector result result = Int64Vector() old_len = 0 for i in range(len(target)): try: self.root.query(result, target[i]) except OverflowError: # overflow -> no match, which is already handled below pass if result.data.n == old_len: result.append(-1) elif result.data.n > old_len + 1: raise KeyError( 'indexer does not intersect a unique set of intervals') old_len = result.data.n return result.to_array().astype('intp') def get_indexer_non_unique(self, scalar_t[:] target): """Return the positions corresponding to intervals that overlap with the given array of scalar targets. Non-unique positions are repeated. """ cdef: Py_ssize_t old_len Py_ssize_t i Int64Vector result, missing result = Int64Vector() missing = Int64Vector() old_len = 0 for i in range(len(target)): try: self.root.query(result, target[i]) except OverflowError: # overflow -> no match, which is already handled below pass if result.data.n == old_len: result.append(-1) missing.append(i) old_len = result.data.n return (result.to_array().astype('intp'), missing.to_array().astype('intp')) def __repr__(self) -> str: return (''.format( dtype=self.dtype, closed=self.closed, n_elements=self.root.n_elements)) # compat with IndexEngine interface def clear_mapping(self) -> None: pass cdef take(ndarray source, ndarray indices): """Take the given positions from a 1D ndarray """ return PyArray_Take(source, indices, 0) cdef sort_values_and_indices(all_values, all_indices, subset): indices = take(all_indices, subset) values = take(all_values, subset) sorter = PyArray_ArgSort(values, 0, NPY_QUICKSORT) sorted_values = take(values, sorter) sorted_indices = take(indices, sorter) return sorted_values, sorted_indices # ---------------------------------------------------------------------- # Nodes # ---------------------------------------------------------------------- @cython.internal cdef class IntervalNode: cdef readonly: int64_t n_elements, n_center, leaf_size bint is_leaf_node def __repr__(self) -> str: if self.is_leaf_node: return ( f"<{type(self).__name__}: {self.n_elements} elements (terminal)>" ) else: n_left = self.left_node.n_elements n_right = self.right_node.n_elements n_center = self.n_elements - n_left - n_right return ( f"<{type(self).__name__}: " f"pivot {self.pivot}, {self.n_elements} elements " f"({n_left} left, {n_right} right, {n_center} overlapping)>" ) def counts(self): """ Inspect counts on this node useful for debugging purposes """ if self.is_leaf_node: return self.n_elements else: m = len(self.center_left_values) l = self.left_node.counts() r = self.right_node.counts() return (m, (l, r)) # we need specialized nodes and leaves to optimize for different dtype and # closed values {{py: nodes = [] for dtype in ['float64', 'int64', 'uint64']: for closed, cmp_left, cmp_right in [ ('left', '<=', '<'), ('right', '<', '<='), ('both', '<=', '<='), ('neither', '<', '<')]: cmp_left_converse = '<' if cmp_left == '<=' else '<=' cmp_right_converse = '<' if cmp_right == '<=' else '<=' if dtype.startswith('int'): fused_prefix = 'int_' elif dtype.startswith('uint'): fused_prefix = 'uint_' elif dtype.startswith('float'): fused_prefix = '' nodes.append((dtype, dtype.title(), closed, closed.title(), cmp_left, cmp_right, cmp_left_converse, cmp_right_converse, fused_prefix)) }} NODE_CLASSES = {} {{for dtype, dtype_title, closed, closed_title, cmp_left, cmp_right, cmp_left_converse, cmp_right_converse, fused_prefix in nodes}} @cython.internal cdef class {{dtype_title}}Closed{{closed_title}}IntervalNode(IntervalNode): """Non-terminal node for an IntervalTree Categorizes intervals by those that fall to the left, those that fall to the right, and those that overlap with the pivot. """ cdef readonly: {{dtype_title}}Closed{{closed_title}}IntervalNode left_node, right_node {{dtype}}_t[:] center_left_values, center_right_values, left, right int64_t[:] center_left_indices, center_right_indices, indices {{dtype}}_t min_left, max_right {{dtype}}_t pivot def __init__(self, ndarray[{{dtype}}_t, ndim=1] left, ndarray[{{dtype}}_t, ndim=1] right, ndarray[int64_t, ndim=1] indices, int64_t leaf_size): self.n_elements = len(left) self.leaf_size = leaf_size # min_left and min_right are used to speed-up query by skipping # query on sub-nodes. If this node has size 0, query is cheap, # so these values don't matter. if left.size > 0: self.min_left = left.min() self.max_right = right.max() else: self.min_left = 0 self.max_right = 0 if self.n_elements <= leaf_size: # make this a terminal (leaf) node self.is_leaf_node = True self.left = left self.right = right self.indices = indices self.n_center = 0 else: # calculate a pivot so we can create child nodes self.is_leaf_node = False self.pivot = np.median(left / 2 + right / 2) if np.isinf(self.pivot): self.pivot = cython.cast({{dtype}}_t, 0) if self.pivot > np.max(right): self.pivot = np.max(left) if self.pivot < np.min(left): self.pivot = np.min(right) left_set, right_set, center_set = self.classify_intervals( left, right) self.left_node = self.new_child_node(left, right, indices, left_set) self.right_node = self.new_child_node(left, right, indices, right_set) self.center_left_values, self.center_left_indices = \ sort_values_and_indices(left, indices, center_set) self.center_right_values, self.center_right_indices = \ sort_values_and_indices(right, indices, center_set) self.n_center = len(self.center_left_indices) @cython.wraparound(False) @cython.boundscheck(False) cdef classify_intervals(self, {{dtype}}_t[:] left, {{dtype}}_t[:] right): """Classify the given intervals based upon whether they fall to the left, right, or overlap with this node's pivot. """ cdef: Int64Vector left_ind, right_ind, overlapping_ind Py_ssize_t i left_ind = Int64Vector() right_ind = Int64Vector() overlapping_ind = Int64Vector() for i in range(self.n_elements): if right[i] {{cmp_right_converse}} self.pivot: left_ind.append(i) elif self.pivot {{cmp_left_converse}} left[i]: right_ind.append(i) else: overlapping_ind.append(i) return (left_ind.to_array(), right_ind.to_array(), overlapping_ind.to_array()) cdef new_child_node(self, ndarray[{{dtype}}_t, ndim=1] left, ndarray[{{dtype}}_t, ndim=1] right, ndarray[int64_t, ndim=1] indices, ndarray[int64_t, ndim=1] subset): """Create a new child node. """ left = take(left, subset) right = take(right, subset) indices = take(indices, subset) return {{dtype_title}}Closed{{closed_title}}IntervalNode( left, right, indices, self.leaf_size) @cython.wraparound(False) @cython.boundscheck(False) @cython.initializedcheck(False) cpdef query(self, Int64Vector result, {{fused_prefix}}scalar_t point): """Recursively query this node and its sub-nodes for intervals that overlap with the query point. """ cdef: int64_t[:] indices {{dtype}}_t[:] values Py_ssize_t i if self.is_leaf_node: # Once we get down to a certain size, it doesn't make sense to # continue the binary tree structure. Instead, we use linear # search. for i in range(self.n_elements): if self.left[i] {{cmp_left}} point {{cmp_right}} self.right[i]: result.append(self.indices[i]) else: # There are child nodes. Based on comparing our query to the pivot, # look at the center values, then go to the relevant child. if point < self.pivot: values = self.center_left_values indices = self.center_left_indices for i in range(self.n_center): if not values[i] {{cmp_left}} point: break result.append(indices[i]) if point {{cmp_right}} self.left_node.max_right: self.left_node.query(result, point) elif point > self.pivot: values = self.center_right_values indices = self.center_right_indices for i in range(self.n_center - 1, -1, -1): if not point {{cmp_right}} values[i]: break result.append(indices[i]) if self.right_node.min_left {{cmp_left}} point: self.right_node.query(result, point) else: result.extend(self.center_left_indices) NODE_CLASSES['{{dtype}}', '{{closed}}'] = {{dtype_title}}Closed{{closed_title}}IntervalNode {{endfor}}