# -*- coding: utf-8 -*- from ..Qt import QtGui from .DataTreeWidget import DataTreeWidget from .. import functions as fn import numpy as np __all__ = ['DiffTreeWidget'] class DiffTreeWidget(QtGui.QWidget): """ Widget for displaying differences between hierarchical python data structures (eg, nested dicts, lists, and arrays) """ def __init__(self, parent=None, a=None, b=None): QtGui.QWidget.__init__(self, parent) self.layout = QtGui.QHBoxLayout() self.setLayout(self.layout) self.trees = [DataTreeWidget(self), DataTreeWidget(self)] for t in self.trees: self.layout.addWidget(t) if a is not None: self.setData(a, b) def setData(self, a, b): """ Set the data to be compared in this widget. """ self.data = (a, b) self.trees[0].setData(a) self.trees[1].setData(b) return self.compare(a, b) def compare(self, a, b, path=()): """ Compare data structure *a* to structure *b*. Return True if the objects match completely. Otherwise, return a structure that describes the differences: { 'type': bool 'len': bool, 'str': bool, 'shape': bool, 'dtype': bool, 'mask': array, } """ bad = (255, 200, 200) diff = [] # generate typestr, desc, childs for each object typeA, descA, childsA, _ = self.trees[0].parse(a) typeB, descB, childsB, _ = self.trees[1].parse(b) if typeA != typeB: self.setColor(path, 1, bad) if descA != descB: self.setColor(path, 2, bad) if isinstance(a, dict) and isinstance(b, dict): keysA = set(a.keys()) keysB = set(b.keys()) for key in keysA - keysB: self.setColor(path+(key,), 0, bad, tree=0) for key in keysB - keysA: self.setColor(path+(key,), 0, bad, tree=1) for key in keysA & keysB: self.compare(a[key], b[key], path+(key,)) elif isinstance(a, (list, tuple)) and isinstance(b, (list, tuple)): for i in range(max(len(a), len(b))): if len(a) <= i: self.setColor(path+(i,), 0, bad, tree=1) elif len(b) <= i: self.setColor(path+(i,), 0, bad, tree=0) else: self.compare(a[i], b[i], path+(i,)) elif isinstance(a, np.ndarray) and isinstance(b, np.ndarray) and a.shape == b.shape: tableNodes = [tree.nodes[path].child(0) for tree in self.trees] if a.dtype.fields is None and b.dtype.fields is None: eq = self.compareArrays(a, b) if not np.all(eq): for n in tableNodes: n.setBackground(0, fn.mkBrush(bad)) #for i in np.argwhere(~eq): else: if a.dtype == b.dtype: for i,k in enumerate(a.dtype.fields.keys()): eq = self.compareArrays(a[k], b[k]) if not np.all(eq): for n in tableNodes: n.setBackground(0, fn.mkBrush(bad)) #for j in np.argwhere(~eq): # dict: compare keys, then values where keys match # list: # array: compare elementwise for same shape def compareArrays(self, a, b): intnan = -9223372036854775808 # happens when np.nan is cast to int anans = np.isnan(a) | (a == intnan) bnans = np.isnan(b) | (b == intnan) eq = anans == bnans mask = ~anans eq[mask] = np.allclose(a[mask], b[mask]) return eq def setColor(self, path, column, color, tree=None): brush = fn.mkBrush(color) # Color only one tree if specified. if tree is None: trees = self.trees else: trees = [self.trees[tree]] for tree in trees: item = tree.nodes[path] item.setBackground(column, brush) def _compare(self, a, b): """ Compare data structure *a* to structure *b*. """ # Check test structures are the same assert type(info) is type(expect) if hasattr(info, '__len__'): assert len(info) == len(expect) if isinstance(info, dict): for k in info: assert k in expect for k in expect: assert k in info self.compare_results(info[k], expect[k]) elif isinstance(info, list): for i in range(len(info)): self.compare_results(info[i], expect[i]) elif isinstance(info, np.ndarray): assert info.shape == expect.shape assert info.dtype == expect.dtype if info.dtype.fields is None: intnan = -9223372036854775808 # happens when np.nan is cast to int inans = np.isnan(info) | (info == intnan) enans = np.isnan(expect) | (expect == intnan) assert np.all(inans == enans) mask = ~inans assert np.allclose(info[mask], expect[mask]) else: for k in info.dtype.fields.keys(): self.compare_results(info[k], expect[k]) else: try: assert info == expect except Exception: raise NotImplementedError("Cannot compare objects of type %s" % type(info))