# -*- coding: utf-8 -*- # Copyright (c) 2006-2010 Filip Wasilewski # See COPYING for license details. # $Id: wavelet_packets.py 154 2010-03-13 13:18:59Z filipw $ """1D and 2D Wavelet packet transform module.""" __all__ = ["BaseNode", "Node", "WaveletPacket", "Node2D", "WaveletPacket2D"] import numerix from _pywt import Wavelet, dwt, idwt, dwt_max_level from multidim import dwt2, idwt2 def get_graycode_order(level, x='a', y='d'): graycode_order = [x, y] for i in range(level-1): graycode_order = [x + path for path in graycode_order] + \ [y + path for path in graycode_order[::-1]] return graycode_order class BaseNode(object): """ BaseNode for wavelet packet 1D and 2D tree nodes. """ # PART_LEN and PARTS attributes that define path tokens for # node[] lookup must be defined in subclasses. PART_LEN = None PARTS = None def __init__(self, parent, data, node_name): self.parent = parent if parent is not None: self.wavelet = parent.wavelet self.mode = parent.mode self.level = parent.level + 1 self._maxlevel = parent.maxlevel self.path = parent.path + node_name else: self.wavelet = None self.mode = None self.path = "" self.level = 0 # data - signal on level 0, coeffs on higher levels self.data = data self._init_subnodes() def _init_subnodes(self): for part in self.PARTS: self._set_node(part, None) def _create_subnode(self, part, data=None, overwrite=True): raise NotImplementedError() def _create_subnode_base(self, node_cls, part, data=None, overwrite=True): self._validate_node_name(part) if not overwrite and self._get_node(part) is not None: return self._get_node(part) node = node_cls(self, data, part) self._set_node(part, node) return node def _get_node(self, part): return getattr(self, part) def _set_node(self, part, node): setattr(self, part, node) def _delete_node(self, part): self._set_node(part, None) def _validate_node_name(self, part): if part not in self.PARTS: raise ValueError("Subnode name must be in [%s], not '%s'." % (', '.join("'%s'" % p for p in self.PARTS), part)) def _evaluate_maxlevel(self, evaluate_from='parent'): """ Try to find the value of maximum decomposition level if it is not specified explicitly. """ assert evaluate_from in ('parent', 'subnodes') if self._maxlevel is not None: return self._maxlevel elif self.data is not None: return self.level + dwt_max_level(min(self.data.shape), self.wavelet) if evaluate_from == 'parent': if self.parent is not None: return self.parent._evaluate_maxlevel(evaluate_from) elif evaluate_from == 'subnodes': for node_name in self.PARTS: node = getattr(self, node_name, None) if node is not None: level = node._evaluate_maxlevel(evaluate_from) if level is not None: return level return None def maxlevel(self): if self._maxlevel is not None: return self._maxlevel # Try getting the maxlevel from parents first self._maxlevel = self._evaluate_maxlevel(evaluate_from='parent') # If not found, check whether it can be evaluated from subnodes if self._maxlevel is None: self._maxlevel = self._evaluate_maxlevel(evaluate_from='subnodes') return self._maxlevel maxlevel = property(maxlevel) def node_name(self): return self.path[-self.PART_LEN:] node_name = property(node_name) def decompose(self): """ Decompose node data creating DWT coefficients subnodes." """ if self.level < self.maxlevel: return self._decompose() else: raise ValueError("Maximum decomposition level reached.") def _decompose(self): raise NotImplementedError() def reconstruct(self, update=False): """ Reconstruct node from subnodes. If update param is True, then reconstructed data replaces the current node data. Returns: - original node data if subnodes do not exist - IDWT of subnodes otherwise. """ if not self.has_any_subnode: return self.data return self._reconstruct(update) def _reconstruct(self): raise NotImplementedError() # override this in subclasses def get_subnode(self, part, decompose=True): """ Returns subnode. part - subnode name decompose - if True and subnode does not exist, it will be created using coefficients from DWT decomposition of the current node. """ self._validate_node_name(part) subnode = self._get_node(part) if subnode is None and decompose and not self.is_empty: self.decompose() subnode = self._get_node(part) return subnode def __getitem__(self, path): """ Find node represented by the given path. path - string composed of node names. If node does not exist yet, it will be created by decomposition of its parent node. """ if isinstance(path, basestring): if (self.maxlevel is not None and len(path) > self.maxlevel * self.PART_LEN): raise IndexError("Path length is out of range.") if path: return self.get_subnode(path[0:self.PART_LEN], True)[ path[self.PART_LEN:]] else: return self else: raise TypeError("Invalid path parameter type - expected string but" " got %s." % type(path)) def __setitem__(self, path, data): """ Set node represented by the given path with a new value. path - string composed of node names. data - array or BaseNode subclass. """ if isinstance(path, basestring): if (self.maxlevel is not None and len(self.path) + len(path) > self.maxlevel * self.PART_LEN): raise IndexError("Path length out of range.") if path: subnode = self.get_subnode(path[0:self.PART_LEN], False) if subnode is None: self._create_subnode(path[0:self.PART_LEN], None) subnode = self.get_subnode(path[0:self.PART_LEN], False) subnode[path[self.PART_LEN:]] = data else: if isinstance(data, BaseNode): self.data = numerix.as_float_array(data.data) else: self.data = numerix.as_float_array(data) else: raise TypeError("Invalid path parameter type - expected string but" " got %s." % type(path)) def __delitem__(self, path): """ Remove node from the tree. """ node = self[path] # don't clear node value and subnodes (node may still exist outside the tree) ## node._init_subnodes() ## node.data = None parent = node.parent node.parent = None # TODO if parent and node.node_name: parent._delete_node(node.node_name) def is_empty(self): return self.data is None is_empty = property(is_empty) def has_any_subnode(self): for part in self.PARTS: if self._get_node(part) is not None: # and not .is_empty return True return False has_any_subnode = property(has_any_subnode) def get_leaf_nodes(self, decompose=False): """ Returns leaf nodes. """ result = [] def collect(node): if node.level == node.maxlevel and not node.is_empty: result.append(node) return False if not decompose and not node.has_any_subnode: result.append(node) return False return True self.walk(collect, decompose=decompose) return result def walk(self, func, args=(), kwargs={}, decompose=True): """ Walk tree and call func on every node -> func(node, *args) If func returns True, descending to subnodes will continue. func - callable args - func parms kwargs - func keyword params """ if func(self, *args, **kwargs) and self.level < self.maxlevel: for part in self.PARTS: subnode = self.get_subnode(part, decompose) if subnode is not None: subnode.walk(func, args, kwargs, decompose) def walk_depth(self, func, args=(), kwargs={}, decompose=False): """ Walk tree and call func on every node starting from the bottom-most nodes. func - callable args - func parms kwargs - func keyword params """ if self.level < self.maxlevel: for part in self.PARTS: subnode = self.get_subnode(part, decompose) if subnode is not None: subnode.walk_depth(func, args, kwargs, decompose) func(self, *args, **kwargs) def __str__(self): return self.path + ": " + str(self.data) class Node(BaseNode): """ WaveletPacket tree node. Subnodes are called ``a`` and ``d``, just like approximation and detail coefficients in the Discrete Wavelet Transform. """ A = 'a' D = 'd' PARTS = A, D PART_LEN = 1 def _create_subnode(self, part, data=None, overwrite=True): return self._create_subnode_base(node_cls=Node, part=part, data=data, overwrite=overwrite) def _decompose(self): if self.is_empty: data_a, data_d = None, None if self._get_node(self.A) is None: self._create_subnode(self.A, data_a) if self._get_node(self.B) is None: self._create_subnode(self.B, data_b) else: data_a, data_d = dwt(self.data, self.wavelet, self.mode) self._create_subnode(self.A, data_a) self._create_subnode(self.D, data_d) return self._get_node(self.A), self._get_node(self.D) def _reconstruct(self, update): data_a, data_d = None, None node_a, node_d = self._get_node(self.A), self._get_node(self.D) if node_a is not None: data_a = node_a.reconstruct() # TODO: (update) ??? if node_d is not None: data_d = node_d.reconstruct() # TODO: (update) ??? if data_a is None and data_d is None: raise ValueError("Node is a leaf node and cannot be reconstructed" " from subnodes.") else: rec = idwt(data_a, data_d, self.wavelet, self.mode, correct_size=True) if update: self.data = rec return rec class Node2D(BaseNode): """ WaveletPacket tree node. Subnodes are called 'a' (LL), 'h' (LH), 'v' (HL) and 'd' (HH), like approximation and detail coefficients in 2D Discrete Wavelet Transform """ LL = 'a' LH = 'h' HL = 'v' HH = 'd' PARTS = LL, LH, HL, HH PART_LEN = 1 def _create_subnode(self, part, data=None, overwrite=True): return self._create_subnode_base(node_cls=Node2D, part=part, data=data, overwrite=overwrite) def _decompose(self): if self.is_empty: data_ll, data_lh, data_hl, data_hh = None, None, None, None else: data_ll, (data_lh, data_hl, data_hh) = dwt2(self.data, self.wavelet, self.mode) self._create_subnode(self.LL, data_ll) self._create_subnode(self.LH, data_lh) self._create_subnode(self.HL, data_hl) self._create_subnode(self.HH, data_hh) return self._get_node(self.LL), self._get_node(self.LH), self._get_node(self.HL), self._get_node(self.HH) def _reconstruct(self, update): data_ll, data_lh, data_hl, data_hh = None, None, None, None node_ll, node_lh, node_hl, node_hh = \ self._get_node(self.LL), self._get_node(self.LH), self._get_node(self.HL), self._get_node(self.HH) if node_ll is not None: data_ll = node_ll.reconstruct() if node_lh is not None: data_lh = node_lh.reconstruct() if node_hl is not None: data_hl = node_hl.reconstruct() if node_hh is not None: data_hh = node_hh.reconstruct() if (data_ll is None and data_lh is None and data_hl is None and data_hh is None): raise ValueError("Tree is missing data - all subnodes of `%s` node are None. Cannot reconstruct node." % self.path) else: coeffs = data_ll, (data_lh, data_hl, data_hh) rec = idwt2(coeffs, self.wavelet, self.mode) if update: self.data = rec return rec def expand_2d_path(self, path): expanded_paths = { self.HH: 'hh', self.HL: 'hl', self.LH: 'lh', self.LL: 'll' } return (''.join([expanded_paths[p][0] for p in path]), ''.join([expanded_paths[p][1] for p in path])) class WaveletPacket(Node): """ Data structure representing Wavelet Packet decomposition of signal. data - original data (signal) wavelet - wavelet used in DWT decomposition and reconstruction mode - signal extension mode - see MODES maxlevel - maximum level of decomposition (will be computed if not specified) """ def __init__(self, data, wavelet, mode='sym', maxlevel=None): super(WaveletPacket, self).__init__(None, data, "") if not isinstance(wavelet, Wavelet): wavelet = Wavelet(wavelet) self.wavelet = wavelet self.mode = mode if data is not None: data = numerix.as_float_array(data) assert len(data.shape) == 1 self.data_size = data.shape[0] if maxlevel is None: maxlevel = dwt_max_level(self.data_size, self.wavelet) else: self.data_size = None self._maxlevel = maxlevel def reconstruct(self, update=True): """ Reconstruct data value using coefficients from subnodes. If update is True, then data values will be replaced by reconstruction values, also in subnodes. """ if self.has_any_subnode: data = super(WaveletPacket, self).reconstruct(update) if self.data_size is not None and len(data) > self.data_size: data = data[:self.data_size] if update: self.data = data return data return self.data # return original data def get_level(self, level, order="natural", decompose=True): """ Returns all nodes on the specified level. order - "natural" - left to right in tree - "freq" - band ordered """ assert order in ["natural", "freq"] if level > self.maxlevel: raise ValueError("The level cannot be greater than the maximum" " decomposition level value (%d)" % self.maxlevel) result = [] def collect(node): if node.level == level: result.append(node) return False return True self.walk(collect, decompose=decompose) if order == "natural": return result elif order == "freq": result = dict((node.path, node) for node in result) graycode_order = get_graycode_order(level) return [result[path] for path in graycode_order if path in result] else: raise ValueError("Invalid order name - %s." % order) class WaveletPacket2D(Node2D): """ Data structure representing 2D Wavelet Packet decomposition of signal. data - original data (signal) wavelet - wavelet used in DWT decomposition and reconstruction mode - signal extension mode - see MODES maxlevel - maximum level of decomposition (will be computed if not specified) """ def __init__(self, data, wavelet, mode='sp1', maxlevel=None): super(WaveletPacket2D, self).__init__(None, data, "") if not isinstance(wavelet, Wavelet): wavelet = Wavelet(wavelet) self.wavelet = wavelet self.mode = mode if data is not None: data = numerix.as_float_array(data) assert len(data.shape) == 2 self.data_size = data.shape if maxlevel is None: maxlevel = dwt_max_level(min(self.data_size), self.wavelet) else: self.data_size = None self._maxlevel = maxlevel def reconstruct(self, update=True): """ Reconstruct data using coefficients from subnodes. If update is set to True then the coefficients of the current node and its subnodes will be replaced with values from reconstruction. """ if self.has_any_subnode: data = super(WaveletPacket2D, self).reconstruct(update) if self.data_size is not None and (data.shape != self.data_size): data = data[:self.data_size[0], :self.data_size[1]] if update: self.data = data return data return self.data # return original data def get_level(self, level, order="natural", decompose=True): """ Returns all nodes from specified level. If order is `natural`, a flat list is returned. If order is `freq`, a 2d structure with rows and cols sorted by corresponding dimension frequency of 2d coefficient array (adapted from 1d case). """ assert order in ["natural", "freq"] if level > self.maxlevel: raise ValueError("The level cannot be greater than the maximum" " decomposition level value (%d)" % self.maxlevel) result = [] def collect(node): if node.level == level: result.append(node) return False return True self.walk(collect, decompose=decompose) if order == "freq": nodes = {} for (row_path, col_path), node in [(self.expand_2d_path(node.path), node) for node in result]: nodes.setdefault(row_path, {})[col_path] = node graycode_order = get_graycode_order(level, x='l', y='h') nodes = [nodes[path] for path in graycode_order if path in nodes] result = [] for row in nodes: result.append( [row[path] for path in graycode_order if path in row] ) return result