def test_reset_calls_all_updates_and_update_doesnt(self, *mocks): master = MockWidget() graph = OWScatterPlotBase(master) for mock in mocks: mock.assert_not_called() graph.reset_graph() for mock in mocks: mock.assert_called_with() mock.reset_mock() graph.update_coordinates() for mock in mocks: mock.assert_not_called()
def setUp(self): self.master = MockWidget() self.graph = OWScatterPlotBase(self.master) self.xy = (np.arange(10, dtype=float), np.arange(10, dtype=float)) self.master.get_coordinates_data = lambda: self.xy
class TestOWScatterPlotBase(WidgetTest): def setUp(self): self.master = MockWidget() self.graph = OWScatterPlotBase(self.master) self.xy = (np.arange(10, dtype=float), np.arange(10, dtype=float)) self.master.get_coordinates_data = lambda: self.xy # pylint: disable=keyword-arg-before-vararg def setRange(self, rect=None, *_, **__): if isinstance(rect, QRectF): self.last_setRange = [[rect.left(), rect.right()], [rect.top(), rect.bottom()]] def test_update_coordinates_no_data(self): self.xy = None, None self.graph.reset_graph() self.assertIsNone(self.graph.scatterplot_item) self.assertIsNone(self.graph.scatterplot_item_sel) self.xy = [], [] self.graph.reset_graph() self.assertIsNone(self.graph.scatterplot_item) self.assertIsNone(self.graph.scatterplot_item_sel) def test_update_coordinates(self): graph = self.graph xy = self.xy = (np.array([1, 2]), np.array([3, 4])) graph.reset_graph() scatterplot_item = graph.scatterplot_item scatterplot_item_sel = graph.scatterplot_item_sel data = scatterplot_item.data np.testing.assert_almost_equal(scatterplot_item.getData(), xy) np.testing.assert_almost_equal(scatterplot_item_sel.getData(), xy) scatterplot_item.setSize([5, 6]) scatterplot_item.setSymbol([7, 8]) scatterplot_item.setPen([mkPen(9), mkPen(10)]) scatterplot_item.setBrush([11, 12]) data["data"] = np.array([13, 14]) xy[0][0] = 0 graph.update_coordinates() np.testing.assert_almost_equal(graph.scatterplot_item.getData(), xy) np.testing.assert_almost_equal(graph.scatterplot_item_sel.getData(), xy) # Graph updates coordinates instead of creating new items self.assertIs(scatterplot_item, graph.scatterplot_item) self.assertIs(scatterplot_item_sel, graph.scatterplot_item_sel) np.testing.assert_almost_equal(data["size"], [5, 6]) np.testing.assert_almost_equal(data["symbol"], [7, 8]) self.assertEqual(data["pen"][0], mkPen(9)) self.assertEqual(data["pen"][1], mkPen(10)) np.testing.assert_almost_equal(data["brush"], [11, 12]) np.testing.assert_almost_equal(data["data"], [13, 14]) def test_update_coordinates_and_labels(self): graph = self.graph xy = self.xy = (np.array([1, 2]), np.array([3, 4])) self.master.get_label_data = lambda: ["a", "b"] graph.reset_graph() self.assertEqual(graph.labels[0].pos().x(), 1) xy[0][0] = 0 graph.update_coordinates() self.assertEqual(graph.labels[0].pos().x(), 0) def test_update_coordinates_and_density(self): graph = self.graph xy = self.xy = (np.array([1, 2]), np.array([3, 4])) self.master.get_label_data = lambda: ["a", "b"] graph.reset_graph() self.assertEqual(graph.labels[0].pos().x(), 1) xy[0][0] = 0 graph.update_density = Mock() graph.update_coordinates() graph.update_density.assert_called_with() def test_update_coordinates_reset_view(self): graph = self.graph graph.view_box.setRange = self.setRange xy = self.xy = (np.array([2, 1]), np.array([3, 10])) self.master.get_label_data = lambda: ["a", "b"] graph.reset_graph() self.assertEqual(self.last_setRange, [[1, 2], [3, 10]]) xy[0][1] = 0 graph.update_coordinates() self.assertEqual(self.last_setRange, [[0, 2], [3, 10]]) def test_reset_graph_no_data(self): self.xy = (None, None) self.graph.scatterplot_item = ScatterPlotItem([1, 2], [3, 4]) self.graph.reset_graph() self.assertIsNone(self.graph.scatterplot_item) self.assertIsNone(self.graph.scatterplot_item_sel) def test_update_coordinates_indices(self): graph = self.graph self.xy = (np.array([2, 1]), np.array([3, 10])) graph.reset_graph() np.testing.assert_almost_equal( graph.scatterplot_item.data["data"], [0, 1]) def test_sampling(self): graph = self.graph master = self.master # Enable sampling before getting the data graph.set_sample_size(3) xy = self.xy = (np.arange(10, dtype=float), np.arange(0, 30, 3, dtype=float)) d = np.arange(10, dtype=float) master.get_size_data = lambda: d master.get_shape_data = lambda: d master.get_color_data = lambda: d master.get_label_data = lambda: \ np.array([str(x) for x in d], dtype=object) graph.reset_graph() self.process_events(until=lambda: not ( self.graph.timer is not None and self.graph.timer.isActive())) # Check proper sampling scatterplot_item = graph.scatterplot_item x, y = scatterplot_item.getData() self.assertEqual(len(x), 3) self.assertNotEqual(x[0], x[1]) self.assertNotEqual(x[0], x[2]) self.assertNotEqual(x[1], x[2]) np.testing.assert_almost_equal(3 * x, y) data = scatterplot_item.data s0, s1, s2 = data["size"] - graph.MinShapeSize np.testing.assert_almost_equal( (s2 - s1) / (s1 - s0), (x[2] - x[1]) / (x[1] - x[0])) self.assertEqual( list(data["symbol"]), [graph.CurveSymbols[int(xi)] for xi in x]) self.assertEqual( [pen.color().hue() for pen in data["pen"]], [graph.palette[xi].hue() for xi in x]) self.assertEqual( [label.textItem.toPlainText() for label in graph.labels], [str(xi) for xi in x]) # Check that sample is extended when sample size is changed graph.set_sample_size(4) self.process_events(until=lambda: not ( self.graph.timer is not None and self.graph.timer.isActive())) scatterplot_item = graph.scatterplot_item x, y = scatterplot_item.getData() data = scatterplot_item.data s0, s1, s2, s3 = data["size"] - graph.MinShapeSize np.testing.assert_almost_equal( (s2 - s1) / (s1 - s0), (x[2] - x[1]) / (x[1] - x[0])) np.testing.assert_almost_equal( (s2 - s1) / (s1 - s3), (x[2] - x[1]) / (x[1] - x[3])) self.assertEqual( list(data["symbol"]), [graph.CurveSymbols[int(xi)] for xi in x]) self.assertEqual( [pen.color().hue() for pen in data["pen"]], [graph.palette[xi].hue() for xi in x]) self.assertEqual( [label.textItem.toPlainText() for label in graph.labels], [str(xi) for xi in x]) # Disable sampling graph.set_sample_size(None) scatterplot_item = graph.scatterplot_item x, y = scatterplot_item.getData() data = scatterplot_item.data np.testing.assert_almost_equal(x, xy[0]) np.testing.assert_almost_equal(y, xy[1]) self.assertEqual( list(data["symbol"]), [graph.CurveSymbols[int(xi)] for xi in d]) self.assertEqual( [pen.color().hue() for pen in data["pen"]], [graph.palette[xi].hue() for xi in d]) self.assertEqual( [label.textItem.toPlainText() for label in graph.labels], [str(xi) for xi in d]) # Enable sampling when data is already present and not sampled graph.set_sample_size(3) self.process_events(until=lambda: not ( self.graph.timer is not None and self.graph.timer.isActive())) scatterplot_item = graph.scatterplot_item x, y = scatterplot_item.getData() data = scatterplot_item.data s0, s1, s2 = data["size"] - graph.MinShapeSize np.testing.assert_almost_equal( (s2 - s1) / (s1 - s0), (x[2] - x[1]) / (x[1] - x[0])) self.assertEqual( list(data["symbol"]), [graph.CurveSymbols[int(xi)] for xi in x]) self.assertEqual( [pen.color().hue() for pen in data["pen"]], [graph.palette[xi].hue() for xi in x]) self.assertEqual( [label.textItem.toPlainText() for label in graph.labels], [str(xi) for xi in x]) # Update data when data is present and sampling is enabled xy[0][:] = np.arange(9, -1, -1, dtype=float) d = xy[0] graph.update_coordinates() x1, _ = scatterplot_item.getData() np.testing.assert_almost_equal(9 - x, x1) graph.update_sizes() data = scatterplot_item.data s0, s1, s2 = data["size"] - graph.MinShapeSize np.testing.assert_almost_equal( (s2 - s1) / (s1 - s0), (x[2] - x[1]) / (x[1] - x[0])) # Reset graph when data is present and sampling is enabled self.xy = (np.arange(100, 105, dtype=float), np.arange(100, 105, dtype=float)) d = self.xy[0] - 100 graph.reset_graph() self.process_events(until=lambda: not ( self.graph.timer is not None and self.graph.timer.isActive())) scatterplot_item = graph.scatterplot_item x, y = scatterplot_item.getData() self.assertEqual(len(x), 3) self.assertTrue(np.all(x > 99)) data = scatterplot_item.data s0, s1, s2 = data["size"] - graph.MinShapeSize np.testing.assert_almost_equal( (s2 - s1) / (s1 - s0), (x[2] - x[1]) / (x[1] - x[0])) # Don't sample when unnecessary self.xy = (np.arange(100, dtype=float), ) * 2 d = None delattr(master, "get_label_data") graph.reset_graph() graph.set_sample_size(120) scatterplot_item = graph.scatterplot_item x, y = scatterplot_item.getData() np.testing.assert_almost_equal(x, np.arange(100)) def test_sampling_keeps_selection(self): graph = self.graph self.xy = (np.arange(100, dtype=float), np.arange(100, dtype=float)) graph.reset_graph() graph.select_by_indices(np.arange(1, 100, 2)) graph.set_sample_size(30) np.testing.assert_almost_equal(graph.selection, np.arange(100) % 2) graph.set_sample_size(None) np.testing.assert_almost_equal(graph.selection, np.arange(100) % 2) base = "Orange.widgets.visualize.owscatterplotgraph.OWScatterPlotBase." @patch(base + "update_sizes") @patch(base + "update_colors") @patch(base + "update_selection_colors") @patch(base + "update_shapes") @patch(base + "update_labels") def test_reset_calls_all_updates_and_update_doesnt(self, *mocks): master = MockWidget() graph = OWScatterPlotBase(master) for mock in mocks: mock.assert_not_called() graph.reset_graph() for mock in mocks: mock.assert_called_with() mock.reset_mock() graph.update_coordinates() for mock in mocks: mock.assert_not_called() def test_jittering(self): graph = self.graph graph.jitter_size = 10 graph.reset_graph() scatterplot_item = graph.scatterplot_item x, y = scatterplot_item.getData() a10 = np.arange(10) self.assertTrue(np.any(np.nonzero(a10 - x))) self.assertTrue(np.any(np.nonzero(a10 - y))) np.testing.assert_array_less(a10 - x, 1) np.testing.assert_array_less(a10 - y, 1) graph.jitter_size = 0 graph.update_coordinates() scatterplot_item = graph.scatterplot_item x, y = scatterplot_item.getData() np.testing.assert_equal(a10, x) def test_size_normalization(self): graph = self.graph self.master.get_size_data = lambda: d d = np.arange(10, dtype=float) graph.reset_graph() scatterplot_item = graph.scatterplot_item size = scatterplot_item.data["size"] diffs = [round(y - x, 2) for x, y in zip(size, size[1:])] self.assertEqual(len(set(diffs)), 1) self.assertGreater(diffs[0], 0) d = np.arange(10, 20, dtype=float) graph.update_sizes() self.assertIs(scatterplot_item, graph.scatterplot_item) size = scatterplot_item.data["size"] diffs2 = [round(y - x, 2) for x, y in zip(size, size[1:])] self.assertEqual(diffs, diffs2) def test_size_with_nans(self): graph = self.graph self.master.get_size_data = lambda: d d = np.arange(10, dtype=float) graph.reset_graph() scatterplot_item = graph.scatterplot_item sizes = scatterplot_item.data["size"] d[4] = np.nan graph.update_sizes() self.process_events(until=lambda: not ( self.graph.timer is not None and self.graph.timer.isActive())) sizes2 = scatterplot_item.data["size"] self.assertEqual(sizes[1] - sizes[0], sizes2[1] - sizes2[0]) self.assertLess(sizes2[4], self.graph.MinShapeSize) d[:] = np.nan graph.update_sizes() sizes3 = scatterplot_item.data["size"] np.testing.assert_almost_equal(sizes, sizes3) def test_sizes_all_same_or_nan(self): graph = self.graph self.master.get_size_data = lambda: d d = np.full((10, ), 3.0) graph.reset_graph() scatterplot_item = graph.scatterplot_item sizes = scatterplot_item.data["size"] self.assertEqual(len(set(sizes)), 1) self.assertGreater(sizes[0], self.graph.MinShapeSize) d = None graph.update_sizes() scatterplot_item = graph.scatterplot_item sizes2 = scatterplot_item.data["size"] np.testing.assert_almost_equal(sizes, sizes2) def test_sizes_point_width_is_linear(self): graph = self.graph self.master.get_size_data = lambda: d d = np.arange(10, dtype=float) graph.point_width = 1 graph.reset_graph() sizes1 = graph.scatterplot_item.data["size"] graph.point_width = 2 graph.update_sizes() sizes2 = graph.scatterplot_item.data["size"] graph.point_width = 3 graph.update_sizes() sizes3 = graph.scatterplot_item.data["size"] np.testing.assert_almost_equal(2 * (sizes2 - sizes1), sizes3 - sizes1) def test_sizes_custom_imputation(self): def impute_max(size_data): size_data[np.isnan(size_data)] = np.nanmax(size_data) graph = self.graph self.master.get_size_data = lambda: d self.master.impute_sizes = impute_max d = np.arange(10, dtype=float) d[4] = np.nan graph.reset_graph() sizes = graph.scatterplot_item.data["size"] self.assertAlmostEqual(sizes[4], sizes[9]) def test_sizes_selection(self): graph = self.graph graph.get_size = lambda: np.arange(10, dtype=float) graph.reset_graph() np.testing.assert_almost_equal( graph.scatterplot_item_sel.data["size"] - graph.scatterplot_item.data["size"], SELECTION_WIDTH) def test_colors_discrete(self): self.master.is_continuous_color = lambda: False palette = self.master.get_palette() graph = self.graph self.master.get_color_data = lambda: d d = np.arange(10, dtype=float) % 2 graph.reset_graph() self.assertTrue( all(pen.color().hue() is palette[i % 2].hue() for i, pen in enumerate(graph.scatterplot_item.data["pen"]))) self.assertTrue( all(pen.color().hue() is palette[i % 2].hue() for i, pen in enumerate(graph.scatterplot_item.data["brush"]))) def test_colors_discrete_nan(self): self.master.is_continuous_color = lambda: False palette = self.master.get_palette() graph = self.graph d = np.arange(10, dtype=float) % 2 d[4] = np.nan self.master.get_color_data = lambda: d graph.reset_graph() pens = graph.scatterplot_item.data["pen"] brushes = graph.scatterplot_item.data["brush"] self.assertEqual(pens[0].color().hue(), palette[0].hue()) self.assertEqual(pens[1].color().hue(), palette[1].hue()) self.assertEqual(brushes[0].color().hue(), palette[0].hue()) self.assertEqual(brushes[1].color().hue(), palette[1].hue()) self.assertEqual(pens[4].color().hue(), QColor(128, 128, 128).hue()) self.assertEqual(brushes[4].color().hue(), QColor(128, 128, 128).hue()) def test_colors_continuous(self): self.master.is_continuous_color = lambda: True graph = self.graph d = np.arange(10, dtype=float) self.master.get_color_data = lambda: d graph.reset_graph() # I don't have a good test ... just don't crash d[4] = np.nan graph.update_colors() # Ditto def test_colors_continuous_nan(self): self.master.is_continuous_color = lambda: True graph = self.graph d = np.arange(10, dtype=float) % 2 d[4] = np.nan self.master.get_color_data = lambda: d graph.reset_graph() pens = graph.scatterplot_item.data["pen"] brushes = graph.scatterplot_item.data["brush"] nan_color = QColor(*NAN_GREY) self.assertEqual(pens[4].color().hue(), nan_color.hue()) self.assertEqual(brushes[4].color().hue(), nan_color.hue()) def test_colors_subset(self): def run_tests(): self.master.get_subset_mask = lambda: None graph.alpha_value = 42 graph.reset_graph() brushes = graph.scatterplot_item.data["brush"] self.assertEqual(brushes[0].color().alpha(), 42) self.assertEqual(brushes[1].color().alpha(), 42) self.assertEqual(brushes[4].color().alpha(), 42) graph.alpha_value = 123 graph.update_colors() brushes = graph.scatterplot_item.data["brush"] self.assertEqual(brushes[0].color().alpha(), 123) self.assertEqual(brushes[1].color().alpha(), 123) self.assertEqual(brushes[4].color().alpha(), 123) self.master.get_subset_mask = lambda: np.arange(10) >= 5 graph.update_colors() brushes = graph.scatterplot_item.data["brush"] self.assertEqual(brushes[0].color().alpha(), 0) self.assertEqual(brushes[1].color().alpha(), 0) self.assertEqual(brushes[4].color().alpha(), 0) self.assertEqual(brushes[5].color().alpha(), 255) self.assertEqual(brushes[6].color().alpha(), 255) self.assertEqual(brushes[7].color().alpha(), 255) graph = self.graph self.master.get_color_data = lambda: None self.master.is_continuous_color = lambda: True graph.reset_graph() run_tests() self.master.is_continuous_color = lambda: False graph.reset_graph() run_tests() d = np.arange(10, dtype=float) % 2 d[4:6] = np.nan self.master.get_color_data = lambda: d self.master.is_continuous_color = lambda: True graph.reset_graph() run_tests() self.master.is_continuous_color = lambda: False graph.reset_graph() run_tests() def test_colors_none(self): graph = self.graph graph.reset_graph() hue = QColor(128, 128, 128).hue() data = graph.scatterplot_item.data self.assertTrue(all(pen.color().hue() == hue for pen in data["pen"])) self.assertTrue(all(pen.color().hue() == hue for pen in data["brush"])) self.master.get_subset_mask = lambda: np.arange(10) < 5 graph.update_colors() data = graph.scatterplot_item.data self.assertTrue(all(pen.color().hue() == hue for pen in data["pen"])) self.assertTrue(all(pen.color().hue() == hue for pen in data["brush"])) def test_colors_update_legend_and_density(self): graph = self.graph graph.update_legends = Mock() graph.update_density = Mock() graph.reset_graph() graph.update_legends.assert_called_with() graph.update_density.assert_called_with() graph.update_legends.reset_mock() graph.update_density.reset_mock() graph.update_coordinates() graph.update_legends.assert_not_called() graph.update_colors() graph.update_legends.assert_called_with() graph.update_density.assert_called_with() def test_selection_colors(self): graph = self.graph graph.reset_graph() data = graph.scatterplot_item_sel.data # One group graph.select_by_indices(np.array([0, 1, 2, 3])) graph.update_selection_colors() pens = data["pen"] for i in range(4): self.assertNotEqual(pens[i].style(), Qt.NoPen) for i in range(4, 10): self.assertEqual(pens[i].style(), Qt.NoPen) # Two groups with patch("AnyQt.QtWidgets.QApplication.keyboardModifiers", lambda: Qt.ShiftModifier): graph.select_by_indices(np.array([4, 5, 6])) graph.update_selection_colors() pens = data["pen"] for i in range(7): self.assertNotEqual(pens[i].style(), Qt.NoPen) for i in range(7, 10): self.assertEqual(pens[i].style(), Qt.NoPen) self.assertEqual(len({pen.color().hue() for pen in pens[:4]}), 1) self.assertEqual(len({pen.color().hue() for pen in pens[4:7]}), 1) color1 = pens[3].color().hue() color2 = pens[4].color().hue() self.assertNotEqual(color1, color2) # Two groups + sampling graph.set_sample_size(7) x = graph.scatterplot_item.getData()[0] pens = graph.scatterplot_item_sel.data["pen"] for xi, pen in zip(x, pens): if xi < 4: self.assertEqual(pen.color().hue(), color1) elif xi < 7: self.assertEqual(pen.color().hue(), color2) else: self.assertEqual(pen.style(), Qt.NoPen) def test_density(self): graph = self.graph density = object() with patch("Orange.widgets.utils.classdensity.class_density_image", return_value=density): graph.reset_graph() self.assertIsNone(graph.density_img) graph.plot_widget.addItem = Mock() graph.plot_widget.removeItem = Mock() graph.class_density = True graph.update_colors() self.assertIsNone(graph.density_img) d = np.ones((10, ), dtype=float) self.master.get_color_data = lambda: d graph.update_colors() self.assertIsNone(graph.density_img) d = np.arange(10) % 2 graph.update_colors() self.assertIs(graph.density_img, density) self.assertIs(graph.plot_widget.addItem.call_args[0][0], density) graph.class_density = False graph.update_colors() self.assertIsNone(graph.density_img) self.assertIs(graph.plot_widget.removeItem.call_args[0][0], density) graph.class_density = True graph.update_colors() self.assertIs(graph.density_img, density) self.assertIs(graph.plot_widget.addItem.call_args[0][0], density) graph.update_coordinates = lambda: (None, None) graph.reset_graph() self.assertIsNone(graph.density_img) self.assertIs(graph.plot_widget.removeItem.call_args[0][0], density) def test_labels(self): graph = self.graph graph.reset_graph() self.assertEqual(graph.labels, []) self.master.get_label_data = lambda: \ np.array([str(x) for x in range(10)], dtype=object) graph.update_labels() self.assertEqual( [label.textItem.toPlainText() for label in graph.labels], [str(i) for i in range(10)]) # Label only selected selected = [1, 3, 5] graph.select_by_indices(selected) self.graph.label_only_selected = True graph.update_labels() self.assertEqual( [label.textItem.toPlainText() for label in graph.labels], [str(x) for x in selected]) x, y = graph.scatterplot_item.getData() for i, index in enumerate(selected): self.assertEqual(x[index], graph.labels[i].x()) self.assertEqual(y[index], graph.labels[i].y()) # Disable label only selected self.graph.label_only_selected = False graph.update_labels() self.assertEqual( [label.textItem.toPlainText() for label in graph.labels], [str(i) for i in range(10)]) x, y = graph.scatterplot_item.getData() for xi, yi, label in zip(x, y, graph.labels): self.assertEqual(xi, label.x()) self.assertEqual(yi, label.y()) # Label only selected + sampling selected = [1, 3, 4, 5, 6, 7, 9] graph.select_by_indices(selected) self.graph.label_only_selected = True graph.update_labels() graph.set_sample_size(5) for label in graph.labels: ind = int(label.textItem.toPlainText()) self.assertIn(ind, selected) self.assertEqual(label.x(), x[ind]) self.assertEqual(label.y(), y[ind]) def test_labels_update_coordinates(self): graph = self.graph self.master.get_label_data = lambda: \ np.array([str(x) for x in range(10)], dtype=object) graph.reset_graph() graph.set_sample_size(7) x, y = graph.scatterplot_item.getData() for xi, yi, label in zip(x, y, graph.labels): self.assertEqual(xi, label.x()) self.assertEqual(yi, label.y()) self.master.get_coordinates_data = \ lambda: (np.arange(10, 20), np.arange(50, 60)) graph.update_coordinates() x, y = graph.scatterplot_item.getData() for xi, yi, label in zip(x, y, graph.labels): self.assertEqual(xi, label.x()) self.assertEqual(yi, label.y()) def test_shapes(self): graph = self.graph self.master.get_shape_data = lambda: d d = np.arange(10, dtype=float) % 3 graph.reset_graph() scatterplot_item = graph.scatterplot_item symbols = scatterplot_item.data["symbol"] self.assertTrue(all(symbol == graph.CurveSymbols[i % 3] for i, symbol in enumerate(symbols))) d = np.arange(10, dtype=float) % 2 graph.update_shapes() symbols = scatterplot_item.data["symbol"] self.assertTrue(all(symbol == graph.CurveSymbols[i % 2] for i, symbol in enumerate(symbols))) d = None graph.update_shapes() symbols = scatterplot_item.data["symbol"] self.assertEqual(len(set(symbols)), 1) def test_shapes_nan(self): graph = self.graph self.master.get_shape_data = lambda: d d = np.arange(10, dtype=float) % 3 d[2] = np.nan graph.reset_graph() self.assertEqual(graph.scatterplot_item.data["symbol"][2], '?') d[:] = np.nan graph.update_shapes() self.assertTrue( all(symbol == '?' for symbol in graph.scatterplot_item.data["symbol"])) def impute0(data, _): data[np.isnan(data)] = 0 self.master.impute_shapes = impute0 d = np.arange(10, dtype=float) % 3 d[2] = np.nan graph.update_shapes() self.assertEqual(graph.scatterplot_item.data["symbol"][2], graph.CurveSymbols[0]) def test_show_grid(self): graph = self.graph show_grid = self.graph.plot_widget.showGrid = Mock() graph.show_grid = False graph.update_grid_visibility() self.assertEqual(show_grid.call_args[1], dict(x=False, y=False)) graph.show_grid = True graph.update_grid_visibility() self.assertEqual(show_grid.call_args[1], dict(x=True, y=True)) def test_show_legend(self): graph = self.graph graph.reset_graph() shape_legend = self.graph.shape_legend.setVisible = Mock() color_legend = self.graph.color_legend.setVisible = Mock() shape_labels = color_labels = None # Avoid pylint warning self.master.get_shape_labels = lambda: shape_labels self.master.get_color_labels = lambda: color_labels for shape_labels in (None, ["a", "b"]): for color_labels in (None, ["c", "d"], None): for visible in (True, False, True): graph.show_legend = visible graph.update_legends() self.assertIs( shape_legend.call_args[0][0], visible and bool(shape_labels), msg="error at {}, {}".format(visible, shape_labels)) self.assertIs( color_legend.call_args[0][0], visible and bool(color_labels), msg="error at {}, {}".format(visible, color_labels)) def test_show_legend_no_data(self): graph = self.graph self.master.get_shape_labels = lambda: ["a", "b"] self.master.get_color_labels = lambda: ["c", "d"] self.master.get_shape_data = lambda: np.arange(10) % 2 self.master.get_color_data = lambda: np.arange(10) < 6 graph.reset_graph() shape_legend = self.graph.shape_legend.setVisible = Mock() color_legend = self.graph.color_legend.setVisible = Mock() self.master.get_coordinates_data = lambda: (None, None) graph.reset_graph() self.assertFalse(shape_legend.call_args[0][0]) self.assertFalse(color_legend.call_args[0][0]) def test_legend_combine(self): master = self.master graph = self.graph graph.reset_graph() shape_legend = self.graph.shape_legend.setVisible = Mock() color_legend = self.graph.color_legend.setVisible = Mock() master.get_shape_labels = lambda: ["a", "b"] master.get_color_labels = lambda: ["c", "d"] graph.update_legends() self.assertTrue(shape_legend.call_args[0][0]) self.assertTrue(color_legend.call_args[0][0]) master.get_color_labels = lambda: ["a", "b"] graph.update_legends() self.assertTrue(shape_legend.call_args[0][0]) self.assertFalse(color_legend.call_args[0][0]) self.assertEqual(len(graph.shape_legend.items), 2) master.is_continuous_color = lambda: True master.get_color_data = lambda: np.arange(10, dtype=float) graph.update_colors() self.assertTrue(shape_legend.call_args[0][0]) self.assertTrue(color_legend.call_args[0][0]) self.assertEqual(len(graph.shape_legend.items), 2) def test_select_by_click(self): graph = self.graph graph.reset_graph() points = graph.scatterplot_item.points() graph.select_by_click(None, [points[2]]) np.testing.assert_almost_equal(graph.get_selection(), [2]) with patch("AnyQt.QtWidgets.QApplication.keyboardModifiers", lambda: Qt.ShiftModifier): graph.select_by_click(None, points[3:6]) np.testing.assert_almost_equal( list(graph.get_selection()), [2, 3, 4, 5]) np.testing.assert_almost_equal( graph.selection, [0, 0, 1, 2, 2, 2, 0, 0, 0, 0]) def test_select_by_rectangle(self): graph = self.graph coords = np.array( [(x, y) for y in range(10) for x in range(10)], dtype=float).T self.master.get_coordinates_data = lambda: coords graph.reset_graph() graph.select_by_rectangle(QRectF(3, 5, 3.9, 2.9)) self.assertTrue( all(selected == (3 <= coords[0][i] <= 6 and 5 <= coords[1][i] <= 7) for i, selected in enumerate(graph.selection))) def test_select_by_indices(self): graph = self.graph graph.reset_graph() graph.label_only_selected = True def select(modifiers, indices): with patch("AnyQt.QtWidgets.QApplication.keyboardModifiers", lambda: modifiers): graph.update_selection_colors = Mock() graph.update_labels = Mock() self.master.selection_changed = Mock() graph.select_by_indices(np.array(indices)) graph.update_selection_colors.assert_called_with() if graph.label_only_selected: graph.update_labels.assert_called_with() else: graph.update_labels.assert_not_called() self.master.selection_changed.assert_called_with() select(0, [7, 8, 9]) np.testing.assert_almost_equal( graph.selection, [0, 0, 0, 0, 0, 0, 0, 1, 1, 1]) select(Qt.ShiftModifier | Qt.ControlModifier, [5, 6]) np.testing.assert_almost_equal( graph.selection, [0, 0, 0, 0, 0, 1, 1, 1, 1, 1]) select(Qt.ShiftModifier, [3, 4, 5]) np.testing.assert_almost_equal( graph.selection, [0, 0, 0, 2, 2, 2, 1, 1, 1, 1]) select(Qt.AltModifier, [1, 3, 7]) np.testing.assert_almost_equal( graph.selection, [0, 0, 0, 0, 2, 2, 1, 0, 1, 1]) select(0, [1, 8]) np.testing.assert_almost_equal( graph.selection, [0, 1, 0, 0, 0, 0, 0, 0, 1, 0]) graph.label_only_selected = False select(0, [3, 4]) def test_unselect_all(self): graph = self.graph graph.reset_graph() graph.label_only_selected = True graph.select_by_indices([3, 4, 5]) np.testing.assert_almost_equal( graph.selection, [0, 0, 0, 1, 1, 1, 0, 0, 0, 0]) graph.update_selection_colors = Mock() graph.update_labels = Mock() self.master.selection_changed = Mock() graph.unselect_all() self.assertIsNone(graph.selection) graph.update_selection_colors.assert_called_with() graph.update_labels.assert_called_with() self.master.selection_changed.assert_called_with() graph.update_selection_colors.reset_mock() graph.update_labels.reset_mock() self.master.selection_changed.reset_mock() graph.unselect_all() self.assertIsNone(graph.selection) graph.update_selection_colors.assert_not_called() graph.update_labels.assert_not_called() self.master.selection_changed.assert_not_called()
def __init__(self, scatter_widget, parent): OWScatterPlotBase.__init__(self, scatter_widget, parent, view_box=MapViewBox) MapMixin.__init__(self)
class TestOWScatterPlotBase(WidgetTest): def setUp(self): self.master = MockWidget() self.graph = OWScatterPlotBase(self.master) self.xy = (np.arange(10, dtype=float), np.arange(10, dtype=float)) self.master.get_coordinates_data = lambda: self.xy # pylint: disable=keyword-arg-before-vararg def setRange(self, rect=None, *_, **__): if isinstance(rect, QRectF): self.last_setRange = [[rect.left(), rect.right()], [rect.top(), rect.bottom()]] def test_update_coordinates_no_data(self): self.xy = None, None self.graph.reset_graph() self.assertIsNone(self.graph.scatterplot_item) self.assertIsNone(self.graph.scatterplot_item_sel) self.xy = [], [] self.graph.reset_graph() self.assertIsNone(self.graph.scatterplot_item) self.assertIsNone(self.graph.scatterplot_item_sel) def test_update_coordinates(self): graph = self.graph xy = self.xy = (np.array([1, 2]), np.array([3, 4])) graph.reset_graph() scatterplot_item = graph.scatterplot_item scatterplot_item_sel = graph.scatterplot_item_sel data = scatterplot_item.data np.testing.assert_almost_equal(scatterplot_item.getData(), xy) np.testing.assert_almost_equal(scatterplot_item_sel.getData(), xy) scatterplot_item.setSize([5, 6]) scatterplot_item.setSymbol([7, 8]) scatterplot_item.setPen([mkPen(9), mkPen(10)]) scatterplot_item.setBrush([11, 12]) data["data"] = np.array([13, 14]) xy[0][0] = 0 graph.update_coordinates() np.testing.assert_almost_equal(graph.scatterplot_item.getData(), xy) np.testing.assert_almost_equal(graph.scatterplot_item_sel.getData(), xy) # Graph updates coordinates instead of creating new items self.assertIs(scatterplot_item, graph.scatterplot_item) self.assertIs(scatterplot_item_sel, graph.scatterplot_item_sel) np.testing.assert_almost_equal(data["size"], [5, 6]) np.testing.assert_almost_equal(data["symbol"], [7, 8]) self.assertEqual(data["pen"][0], mkPen(9)) self.assertEqual(data["pen"][1], mkPen(10)) np.testing.assert_almost_equal(data["brush"], [11, 12]) np.testing.assert_almost_equal(data["data"], [13, 14]) def test_update_coordinates_and_labels(self): graph = self.graph xy = self.xy = (np.array([1., 2]), np.array([3, 4])) self.master.get_label_data = lambda: np.array(["a", "b"]) graph.reset_graph() self.assertEqual(graph.labels[0].pos().x(), 1) xy[0][0] = 1.5 graph.update_coordinates() self.assertEqual(graph.labels[0].pos().x(), 1.5) xy[0][0] = 0 # This label goes out of the range graph.update_coordinates() self.assertEqual(graph.labels[0].pos().x(), 2) def test_update_coordinates_and_density(self): graph = self.graph xy = self.xy = (np.array([1, 2]), np.array([3, 4])) self.master.get_label_data = lambda: np.array(["a", "b"]) graph.reset_graph() self.assertEqual(graph.labels[0].pos().x(), 1) xy[0][0] = 0 graph.update_density = Mock() graph.update_coordinates() graph.update_density.assert_called_with() def test_update_coordinates_reset_view(self): graph = self.graph graph.view_box.setRange = self.setRange xy = self.xy = (np.array([2, 1]), np.array([3, 10])) self.master.get_label_data = lambda: np.array(["a", "b"]) graph.reset_graph() self.assertEqual(self.last_setRange, [[1, 2], [3, 10]]) xy[0][1] = 0 graph.update_coordinates() self.assertEqual(self.last_setRange, [[0, 2], [3, 10]]) def test_reset_graph_no_data(self): self.xy = (None, None) self.graph.scatterplot_item = ScatterPlotItem([1, 2], [3, 4]) self.graph.reset_graph() self.assertIsNone(self.graph.scatterplot_item) self.assertIsNone(self.graph.scatterplot_item_sel) def test_update_coordinates_indices(self): graph = self.graph self.xy = (np.array([2, 1]), np.array([3, 10])) graph.reset_graph() np.testing.assert_almost_equal(graph.scatterplot_item.data["data"], [0, 1]) def test_sampling(self): graph = self.graph master = self.master # Enable sampling before getting the data graph.set_sample_size(3) xy = self.xy = (np.arange(10, dtype=float), np.arange(0, 30, 3, dtype=float)) d = np.arange(10, dtype=float) master.get_size_data = lambda: d master.get_shape_data = lambda: d % 5 if d is not None else None master.get_color_data = lambda: d master.get_label_data = lambda: \ np.array([str(x) for x in d], dtype=object) graph.reset_graph() self.process_events(until=lambda: not (self.graph.timer is not None and self.graph.timer.isActive())) # Check proper sampling scatterplot_item = graph.scatterplot_item x, y = scatterplot_item.getData() self.assertEqual(len(x), 3) self.assertNotEqual(x[0], x[1]) self.assertNotEqual(x[0], x[2]) self.assertNotEqual(x[1], x[2]) np.testing.assert_almost_equal(3 * x, y) data = scatterplot_item.data s0, s1, s2 = data["size"] - graph.MinShapeSize np.testing.assert_almost_equal((s2 - s1) / (s1 - s0), (x[2] - x[1]) / (x[1] - x[0])) self.assertEqual(list(data["symbol"]), [graph.CurveSymbols[int(xi) % 5] for xi in x]) self.assertEqual([pen.color().hue() for pen in data["pen"]], [graph.palette[xi].hue() for xi in x]) self.assertEqual( [label.textItem.toPlainText() for label in graph.labels], [str(xi) for xi in x]) # Check that sample is extended when sample size is changed graph.set_sample_size(4) self.process_events(until=lambda: not (self.graph.timer is not None and self.graph.timer.isActive())) scatterplot_item = graph.scatterplot_item x, y = scatterplot_item.getData() data = scatterplot_item.data s = data["size"] - graph.MinShapeSize precise_s = (x - min(x)) / (max(x) - min(x)) * max(s) np.testing.assert_almost_equal(s, precise_s, decimal=0) self.assertEqual(list(data["symbol"]), [graph.CurveSymbols[int(xi) % 5] for xi in x]) self.assertEqual([pen.color().hue() for pen in data["pen"]], [graph.palette[xi].hue() for xi in x]) self.assertEqual( [label.textItem.toPlainText() for label in graph.labels], [str(xi) for xi in x]) # Disable sampling graph.set_sample_size(None) scatterplot_item = graph.scatterplot_item x, y = scatterplot_item.getData() data = scatterplot_item.data np.testing.assert_almost_equal(x, xy[0]) np.testing.assert_almost_equal(y, xy[1]) self.assertEqual(list(data["symbol"]), [graph.CurveSymbols[int(xi) % 5] for xi in d]) self.assertEqual([pen.color().hue() for pen in data["pen"]], [graph.palette[xi].hue() for xi in d]) self.assertEqual( [label.textItem.toPlainText() for label in graph.labels], [str(xi) for xi in d]) # Enable sampling when data is already present and not sampled graph.set_sample_size(3) self.process_events(until=lambda: not (self.graph.timer is not None and self.graph.timer.isActive())) scatterplot_item = graph.scatterplot_item x, y = scatterplot_item.getData() data = scatterplot_item.data s0, s1, s2 = data["size"] - graph.MinShapeSize np.testing.assert_almost_equal((s2 - s1) / (s1 - s0), (x[2] - x[1]) / (x[1] - x[0])) self.assertEqual(list(data["symbol"]), [graph.CurveSymbols[int(xi) % 5] for xi in x]) self.assertEqual([pen.color().hue() for pen in data["pen"]], [graph.palette[xi].hue() for xi in x]) self.assertEqual( [label.textItem.toPlainText() for label in graph.labels], [str(xi) for xi in x]) # Update data when data is present and sampling is enabled xy[0][:] = np.arange(9, -1, -1, dtype=float) d = xy[0] graph.update_coordinates() x1, _ = scatterplot_item.getData() np.testing.assert_almost_equal(9 - x, x1) graph.update_sizes() data = scatterplot_item.data s0, s1, s2 = data["size"] - graph.MinShapeSize np.testing.assert_almost_equal((s2 - s1) / (s1 - s0), (x[2] - x[1]) / (x[1] - x[0])) # Reset graph when data is present and sampling is enabled self.xy = (np.arange(100, 105, dtype=float), np.arange(100, 105, dtype=float)) d = self.xy[0] - 100 graph.reset_graph() self.process_events(until=lambda: not (self.graph.timer is not None and self.graph.timer.isActive())) scatterplot_item = graph.scatterplot_item x, y = scatterplot_item.getData() self.assertEqual(len(x), 3) self.assertTrue(np.all(x > 99)) data = scatterplot_item.data s0, s1, s2 = data["size"] - graph.MinShapeSize np.testing.assert_almost_equal((s2 - s1) / (s1 - s0), (x[2] - x[1]) / (x[1] - x[0])) # Don't sample when unnecessary self.xy = (np.arange(100, dtype=float), ) * 2 d = None delattr(master, "get_label_data") graph.reset_graph() graph.set_sample_size(120) scatterplot_item = graph.scatterplot_item x, y = scatterplot_item.getData() np.testing.assert_almost_equal(x, np.arange(100)) def test_sampling_keeps_selection(self): graph = self.graph self.xy = (np.arange(100, dtype=float), np.arange(100, dtype=float)) graph.reset_graph() graph.select_by_indices(np.arange(1, 100, 2)) graph.set_sample_size(30) np.testing.assert_almost_equal(graph.selection, np.arange(100) % 2) graph.set_sample_size(None) np.testing.assert_almost_equal(graph.selection, np.arange(100) % 2) base = "Orange.widgets.visualize.owscatterplotgraph.OWScatterPlotBase." @patch(base + "update_sizes") @patch(base + "update_colors") @patch(base + "update_selection_colors") @patch(base + "update_shapes") @patch(base + "update_labels") def test_reset_calls_all_updates_and_update_doesnt(self, *mocks): master = MockWidget() graph = OWScatterPlotBase(master) for mock in mocks: mock.assert_not_called() graph.reset_graph() for mock in mocks: mock.assert_called_with() mock.reset_mock() graph.update_coordinates() for mock in mocks: mock.assert_not_called() def test_jittering(self): graph = self.graph graph.jitter_size = 10 graph.reset_graph() scatterplot_item = graph.scatterplot_item x, y = scatterplot_item.getData() a10 = np.arange(10) self.assertTrue(np.any(np.nonzero(a10 - x))) self.assertTrue(np.any(np.nonzero(a10 - y))) np.testing.assert_array_less(a10 - x, 1) np.testing.assert_array_less(a10 - y, 1) graph.jitter_size = 0 graph.update_coordinates() scatterplot_item = graph.scatterplot_item x, y = scatterplot_item.getData() np.testing.assert_equal(a10, x) def test_size_normalization(self): graph = self.graph self.master.get_size_data = lambda: d d = np.arange(10, dtype=float) graph.reset_graph() scatterplot_item = graph.scatterplot_item size = scatterplot_item.data["size"] np.testing.assert_equal( size, [6, 7.5, 9.5, 11, 12.5, 14.5, 16, 17.5, 19.5, 21]) d = np.arange(10, 20, dtype=float) graph.update_sizes() self.assertIs(scatterplot_item, graph.scatterplot_item) size2 = scatterplot_item.data["size"] np.testing.assert_equal(size, size2) def test_size_rounding_half_pixel(self): graph = self.graph self.master.get_size_data = lambda: d d = np.arange(10, dtype=float) graph.reset_graph() scatterplot_item = graph.scatterplot_item size = scatterplot_item.data["size"] np.testing.assert_equal(size * 2 - (size * 2).round(), 0) def test_size_with_nans(self): graph = self.graph self.master.get_size_data = lambda: d d = np.arange(10, dtype=float) graph.reset_graph() scatterplot_item = graph.scatterplot_item sizes = scatterplot_item.data["size"] d[4] = np.nan graph.update_sizes() self.process_events(until=lambda: not (self.graph.timer is not None and self.graph.timer.isActive())) sizes2 = scatterplot_item.data["size"] self.assertEqual(sizes[1] - sizes[0], sizes2[1] - sizes2[0]) self.assertLess(sizes2[4], self.graph.MinShapeSize) d[:] = np.nan graph.update_sizes() sizes3 = scatterplot_item.data["size"] np.testing.assert_almost_equal(sizes, sizes3) def test_sizes_all_same_or_nan(self): graph = self.graph self.master.get_size_data = lambda: d d = np.full((10, ), 3.0) graph.reset_graph() scatterplot_item = graph.scatterplot_item sizes = scatterplot_item.data["size"] self.assertEqual(len(set(sizes)), 1) self.assertGreater(sizes[0], self.graph.MinShapeSize) d = None graph.update_sizes() scatterplot_item = graph.scatterplot_item sizes2 = scatterplot_item.data["size"] np.testing.assert_almost_equal(sizes, sizes2) def test_sizes_point_width_is_linear(self): graph = self.graph self.master.get_size_data = lambda: d d = np.arange(10, dtype=float) graph.point_width = 1 graph.reset_graph() sizes1 = graph.scatterplot_item.data["size"] graph.point_width = 2 graph.update_sizes() sizes2 = graph.scatterplot_item.data["size"] graph.point_width = 3 graph.update_sizes() sizes3 = graph.scatterplot_item.data["size"] np.testing.assert_almost_equal(2 * (sizes2 - sizes1), sizes3 - sizes1) def test_sizes_custom_imputation(self): def impute_max(size_data): size_data[np.isnan(size_data)] = np.nanmax(size_data) graph = self.graph self.master.get_size_data = lambda: d self.master.impute_sizes = impute_max d = np.arange(10, dtype=float) d[4] = np.nan graph.reset_graph() sizes = graph.scatterplot_item.data["size"] self.assertAlmostEqual(sizes[4], sizes[9]) def test_sizes_selection(self): graph = self.graph graph.get_size = lambda: np.arange(10, dtype=float) graph.reset_graph() np.testing.assert_almost_equal( graph.scatterplot_item_sel.data["size"] - graph.scatterplot_item.data["size"], SELECTION_WIDTH) @patch("Orange.widgets.visualize.owscatterplotgraph" ".MAX_N_VALID_SIZE_ANIMATE", 5) def test_size_animation(self): begin_resizing = QSignalSpy(self.graph.begin_resizing) step_resizing = QSignalSpy(self.graph.step_resizing) end_resizing = QSignalSpy(self.graph.end_resizing) self._update_sizes_for_points(5) # first end_resizing is triggered in reset, thus wait for step_resizing step_resizing.wait(200) end_resizing.wait(200) self.assertEqual(len(begin_resizing), 2) # reset and update self.assertEqual(len(step_resizing), 5) self.assertEqual(len(end_resizing), 2) # reset and update self.assertEqual(self.graph.scatterplot_item.setSize.call_count, 6) self._update_sizes_for_points(6) self.graph.scatterplot_item.setSize.assert_called_once() def _update_sizes_for_points(self, n: int): arr = np.arange(n, dtype=float) self.master.get_coordinates_data = lambda: (arr, arr) self.master.get_size_data = lambda: arr self.graph.reset_graph() self.graph.scatterplot_item.setSize = Mock( wraps=self.graph.scatterplot_item.setSize) self.master.get_size_data = lambda: arr[::-1] self.graph.update_sizes() self.process_events(until=lambda: not (self.graph.timer is not None and self.graph.timer.isActive())) def test_colors_discrete(self): self.master.is_continuous_color = lambda: False palette = self.master.get_palette() graph = self.graph self.master.get_color_data = lambda: d d = np.arange(10, dtype=float) % 2 graph.reset_graph() data = graph.scatterplot_item.data self.assertTrue( all(pen.color().hue() is palette[i % 2].hue() for i, pen in enumerate(data["pen"]))) self.assertTrue( all(pen.color().hue() is palette[i % 2].hue() for i, pen in enumerate(data["brush"]))) # confirm that QPen/QBrush were reused self.assertEqual(len(set(map(id, data["pen"]))), 2) self.assertEqual(len(set(map(id, data["brush"]))), 2) def test_colors_discrete_nan(self): self.master.is_continuous_color = lambda: False palette = self.master.get_palette() graph = self.graph d = np.arange(10, dtype=float) % 2 d[4] = np.nan self.master.get_color_data = lambda: d graph.reset_graph() pens = graph.scatterplot_item.data["pen"] brushes = graph.scatterplot_item.data["brush"] self.assertEqual(pens[0].color().hue(), palette[0].hue()) self.assertEqual(pens[1].color().hue(), palette[1].hue()) self.assertEqual(brushes[0].color().hue(), palette[0].hue()) self.assertEqual(brushes[1].color().hue(), palette[1].hue()) self.assertEqual(pens[4].color().hue(), QColor(128, 128, 128).hue()) self.assertEqual(brushes[4].color().hue(), QColor(128, 128, 128).hue()) def test_colors_continuous(self): self.master.is_continuous_color = lambda: True graph = self.graph d = np.arange(10, dtype=float) self.master.get_color_data = lambda: d graph.reset_graph() # I don't have a good test ... just don't crash d[4] = np.nan graph.update_colors() # Ditto def test_colors_continuous_reused(self): self.master.is_continuous_color = lambda: True graph = self.graph self.xy = (np.arange(100, dtype=float), np.arange(100, dtype=float)) d = np.arange(100, dtype=float) self.master.get_color_data = lambda: d graph.reset_graph() data = graph.scatterplot_item.data self.assertEqual(len(data["pen"]), 100) self.assertLessEqual(len(set(map(id, data["pen"]))), 10) self.assertEqual(len(data["brush"]), 100) self.assertLessEqual(len(set(map(id, data["brush"]))), 10) def test_colors_continuous_nan(self): self.master.is_continuous_color = lambda: True graph = self.graph d = np.arange(10, dtype=float) % 2 d[4] = np.nan self.master.get_color_data = lambda: d graph.reset_graph() pens = graph.scatterplot_item.data["pen"] brushes = graph.scatterplot_item.data["brush"] nan_color = QColor(*NAN_GREY) self.assertEqual(pens[4].color().hue(), nan_color.hue()) self.assertEqual(brushes[4].color().hue(), nan_color.hue()) def test_colors_subset(self): def run_tests(): self.master.get_subset_mask = lambda: None graph.alpha_value = 42 graph.reset_graph() brushes = graph.scatterplot_item.data["brush"] self.assertEqual(brushes[0].color().alpha(), 42) self.assertEqual(brushes[1].color().alpha(), 42) self.assertEqual(brushes[4].color().alpha(), 42) graph.alpha_value = 123 graph.update_colors() brushes = graph.scatterplot_item.data["brush"] self.assertEqual(brushes[0].color().alpha(), 123) self.assertEqual(brushes[1].color().alpha(), 123) self.assertEqual(brushes[4].color().alpha(), 123) self.master.get_subset_mask = lambda: np.arange(10) >= 5 graph.update_colors() brushes = graph.scatterplot_item.data["brush"] self.assertEqual(brushes[0].color().alpha(), 0) self.assertEqual(brushes[1].color().alpha(), 0) self.assertEqual(brushes[4].color().alpha(), 0) self.assertEqual(brushes[5].color().alpha(), 255) self.assertEqual(brushes[6].color().alpha(), 255) self.assertEqual(brushes[7].color().alpha(), 255) graph = self.graph self.master.get_color_data = lambda: None self.master.is_continuous_color = lambda: True graph.reset_graph() run_tests() self.master.is_continuous_color = lambda: False graph.reset_graph() run_tests() d = np.arange(10, dtype=float) % 2 d[4:6] = np.nan self.master.get_color_data = lambda: d self.master.is_continuous_color = lambda: True graph.reset_graph() run_tests() self.master.is_continuous_color = lambda: False graph.reset_graph() run_tests() def test_colors_none(self): graph = self.graph graph.reset_graph() hue = QColor(128, 128, 128).hue() data = graph.scatterplot_item.data self.assertTrue(all(pen.color().hue() == hue for pen in data["pen"])) self.assertTrue(all(pen.color().hue() == hue for pen in data["brush"])) self.assertEqual(len(set(map(id, data["pen"]))), 1) # test QPen/QBrush reuse self.assertEqual(len(set(map(id, data["brush"]))), 1) self.master.get_subset_mask = lambda: np.arange(10) < 5 graph.update_colors() data = graph.scatterplot_item.data self.assertTrue(all(pen.color().hue() == hue for pen in data["pen"])) self.assertTrue(all(pen.color().hue() == hue for pen in data["brush"])) self.assertEqual(len(set(map(id, data["pen"]))), 1) self.assertEqual(len(set(map(id, data["brush"]))), 2) # transparent and colored def test_colors_update_legend_and_density(self): graph = self.graph graph.update_legends = Mock() graph.update_density = Mock() graph.reset_graph() graph.update_legends.assert_called_with() graph.update_density.assert_called_with() graph.update_legends.reset_mock() graph.update_density.reset_mock() graph.update_coordinates() graph.update_legends.assert_not_called() graph.update_colors() graph.update_legends.assert_called_with() graph.update_density.assert_called_with() def test_selection_colors(self): graph = self.graph graph.reset_graph() data = graph.scatterplot_item_sel.data # One group graph.select_by_indices(np.array([0, 1, 2, 3])) graph.update_selection_colors() pens = data["pen"] for i in range(4): self.assertNotEqual(pens[i].style(), Qt.NoPen) for i in range(4, 10): self.assertEqual(pens[i].style(), Qt.NoPen) # Two groups with patch("AnyQt.QtWidgets.QApplication.keyboardModifiers", lambda: Qt.ShiftModifier): graph.select_by_indices(np.array([4, 5, 6])) graph.update_selection_colors() pens = data["pen"] for i in range(7): self.assertNotEqual(pens[i].style(), Qt.NoPen) for i in range(7, 10): self.assertEqual(pens[i].style(), Qt.NoPen) self.assertEqual(len({pen.color().hue() for pen in pens[:4]}), 1) self.assertEqual(len({pen.color().hue() for pen in pens[4:7]}), 1) color1 = pens[3].color().hue() color2 = pens[4].color().hue() self.assertNotEqual(color1, color2) # Two groups + sampling graph.set_sample_size(7) x = graph.scatterplot_item.getData()[0] pens = graph.scatterplot_item_sel.data["pen"] for xi, pen in zip(x, pens): if xi < 4: self.assertEqual(pen.color().hue(), color1) elif xi < 7: self.assertEqual(pen.color().hue(), color2) else: self.assertEqual(pen.style(), Qt.NoPen) def test_density(self): graph = self.graph density = object() with patch("Orange.widgets.utils.classdensity.class_density_image", return_value=density): graph.reset_graph() self.assertIsNone(graph.density_img) graph.plot_widget.addItem = Mock() graph.plot_widget.removeItem = Mock() graph.class_density = True graph.update_colors() self.assertIsNone(graph.density_img) d = np.ones((10, ), dtype=float) self.master.get_color_data = lambda: d graph.update_colors() self.assertIsNone(graph.density_img) d = np.arange(10) % 2 graph.update_colors() self.assertIs(graph.density_img, density) self.assertIs(graph.plot_widget.addItem.call_args[0][0], density) graph.class_density = False graph.update_colors() self.assertIsNone(graph.density_img) self.assertIs(graph.plot_widget.removeItem.call_args[0][0], density) graph.class_density = True graph.update_colors() self.assertIs(graph.density_img, density) self.assertIs(graph.plot_widget.addItem.call_args[0][0], density) graph.update_coordinates = lambda: (None, None) graph.reset_graph() self.assertIsNone(graph.density_img) self.assertIs(graph.plot_widget.removeItem.call_args[0][0], density) def test_labels(self): graph = self.graph graph.reset_graph() self.assertEqual(graph.labels, []) self.master.get_label_data = lambda: \ np.array([str(x) for x in range(10)], dtype=object) graph.update_labels() self.assertEqual( [label.textItem.toPlainText() for label in graph.labels], [str(i) for i in range(10)]) # Label only selected selected = [1, 3, 5] graph.select_by_indices(selected) self.graph.label_only_selected = True graph.update_labels() self.assertEqual( [label.textItem.toPlainText() for label in graph.labels], [str(x) for x in selected]) x, y = graph.scatterplot_item.getData() for i, index in enumerate(selected): self.assertEqual(x[index], graph.labels[i].x()) self.assertEqual(y[index], graph.labels[i].y()) # Disable label only selected self.graph.label_only_selected = False graph.update_labels() self.assertEqual( [label.textItem.toPlainText() for label in graph.labels], [str(i) for i in range(10)]) x, y = graph.scatterplot_item.getData() for xi, yi, label in zip(x, y, graph.labels): self.assertEqual(xi, label.x()) self.assertEqual(yi, label.y()) # Label only selected + sampling selected = [1, 3, 4, 5, 6, 7, 9] graph.select_by_indices(selected) self.graph.label_only_selected = True graph.update_labels() graph.set_sample_size(5) for label in graph.labels: ind = int(label.textItem.toPlainText()) self.assertIn(ind, selected) self.assertEqual(label.x(), x[ind]) self.assertEqual(label.y(), y[ind]) def test_label_mask_all_visible(self): graph = self.graph x, y = np.arange(10) / 10, np.arange(10) / 10 sel = np.array( [True, True, False, False, False, True, True, True, False, False]) subset = np.array( [True, False, True, True, False, True, True, False, False, False]) trues = np.ones(10, dtype=bool) np.testing.assert_equal(graph._label_mask(x, y), trues) # Selection present, subset is None graph.selection = sel graph.master.get_subset_mask = lambda: None graph.label_only_selected = False np.testing.assert_equal(graph._label_mask(x, y), trues) graph.label_only_selected = True np.testing.assert_equal(graph._label_mask(x, y), sel) # Selection and subset present graph.selection = sel graph.master.get_subset_mask = lambda: subset graph.label_only_selected = False np.testing.assert_equal(graph._label_mask(x, y), trues) graph.label_only_selected = True np.testing.assert_equal( graph._label_mask(x, y), np.array([ True, True, True, True, False, True, True, True, False, False ])) # No selection, subset present graph.selection = None graph.master.get_subset_mask = lambda: subset graph.label_only_selected = False np.testing.assert_equal(graph._label_mask(x, y), trues) graph.label_only_selected = True np.testing.assert_equal(graph._label_mask(x, y), subset) # No selection, no subset graph.selection = None graph.master.get_subset_mask = lambda: None graph.label_only_selected = False np.testing.assert_equal(graph._label_mask(x, y), trues) graph.label_only_selected = True self.assertIsNone(graph._label_mask(x, y)) def test_label_mask_with_invisible(self): graph = self.graph x, y = np.arange(5, 10) / 10, np.arange(5, 10) / 10 sel = np.array([ True, True, False, False, False, # these 5 are not in the sample True, True, True, False, False ]) subset = np.array([ True, False, True, True, False, # these 5 are not in the sample True, True, False, False, True ]) graph.sample_indices = np.arange(5, 10, dtype=int) trues = np.ones(5, dtype=bool) np.testing.assert_equal(graph._label_mask(x, y), trues) # Selection present, subset is None graph.selection = sel graph.master.get_subset_mask = lambda: None graph.label_only_selected = False np.testing.assert_equal(graph._label_mask(x, y), trues) graph.label_only_selected = True np.testing.assert_equal(graph._label_mask(x, y), sel[5:]) # Selection and subset present graph.selection = sel graph.master.get_subset_mask = lambda: subset graph.label_only_selected = False np.testing.assert_equal(graph._label_mask(x, y), trues) graph.label_only_selected = True np.testing.assert_equal(graph._label_mask(x, y), np.array([True, True, True, False, True])) # No selection, subset present graph.selection = None graph.master.get_subset_mask = lambda: subset graph.label_only_selected = False np.testing.assert_equal(graph._label_mask(x, y), trues) graph.label_only_selected = True np.testing.assert_equal(graph._label_mask(x, y), subset[5:]) # No selection, no subset graph.selection = None graph.master.get_subset_mask = lambda: None graph.label_only_selected = False np.testing.assert_equal(graph._label_mask(x, y), trues) graph.label_only_selected = True self.assertIsNone(graph._label_mask(x, y)) def test_label_mask_with_invisible_and_view(self): graph = self.graph x, y = np.arange(5, 10) / 10, np.arange(5) / 10 sel = np.array([ True, True, False, False, False, # these 5 are not in the sample True, True, True, False, False ]) # first and last out of the view subset = np.array([ True, False, True, True, False, # these 5 are not in the sample True, True, False, True, True ]) # first and last out of the view graph.sample_indices = np.arange(5, 10, dtype=int) graph.view_box.viewRange = lambda: ((0.6, 1), (0, 0.3)) viewed = np.array([False, True, True, True, False]) np.testing.assert_equal(graph._label_mask(x, y), viewed) # Selection present, subset is None graph.selection = sel graph.master.get_subset_mask = lambda: None graph.label_only_selected = False np.testing.assert_equal(graph._label_mask(x, y), viewed) graph.label_only_selected = True np.testing.assert_equal(graph._label_mask(x, y), np.array([False, True, True, False, False])) # Selection and subset present graph.selection = sel graph.master.get_subset_mask = lambda: subset graph.label_only_selected = False np.testing.assert_equal(graph._label_mask(x, y), viewed) graph.label_only_selected = True np.testing.assert_equal(graph._label_mask(x, y), np.array([False, True, True, True, False])) # No selection, subset present graph.selection = None graph.master.get_subset_mask = lambda: subset graph.label_only_selected = False np.testing.assert_equal(graph._label_mask(x, y), viewed) graph.label_only_selected = True np.testing.assert_equal(graph._label_mask(x, y), np.array([False, True, False, True, False])) # No selection, no subset graph.selection = None graph.master.get_subset_mask = lambda: None graph.label_only_selected = False np.testing.assert_equal(graph._label_mask(x, y), viewed) graph.label_only_selected = True self.assertIsNone(graph._label_mask(x, y)) def test_labels_observes_mask(self): graph = self.graph get_label_data = graph.master.get_label_data graph.reset_graph() self.assertEqual(graph.labels, []) get_label_data.reset_mock() graph._label_mask = lambda *_: None graph.update_labels() get_label_data.assert_not_called() self.master.get_label_data = lambda: \ np.array([str(x) for x in range(10)], dtype=object) graph._label_mask = \ lambda *_: np.array([False, True, True] + [False] * 7) graph.update_labels() self.assertEqual( [label.textItem.toPlainText() for label in graph.labels], ["1", "2"]) def test_labels_update_coordinates(self): graph = self.graph self.master.get_label_data = lambda: \ np.array([str(x) for x in range(10)], dtype=object) graph.reset_graph() graph.set_sample_size(7) x, y = graph.scatterplot_item.getData() for xi, yi, label in zip(x, y, graph.labels): self.assertEqual(xi, label.x()) self.assertEqual(yi, label.y()) self.master.get_coordinates_data = \ lambda: (np.arange(10, 20), np.arange(50, 60)) graph.update_coordinates() x, y = graph.scatterplot_item.getData() for xi, yi, label in zip(x, y, graph.labels): self.assertEqual(xi, label.x()) self.assertEqual(yi, label.y()) def test_shapes(self): graph = self.graph self.master.get_shape_data = lambda: d d = np.arange(10, dtype=float) % 3 graph.reset_graph() scatterplot_item = graph.scatterplot_item symbols = scatterplot_item.data["symbol"] self.assertTrue( all(symbol == graph.CurveSymbols[i % 3] for i, symbol in enumerate(symbols))) d = np.arange(10, dtype=float) % 2 graph.update_shapes() symbols = scatterplot_item.data["symbol"] self.assertTrue( all(symbol == graph.CurveSymbols[i % 2] for i, symbol in enumerate(symbols))) d = None graph.update_shapes() symbols = scatterplot_item.data["symbol"] self.assertEqual(len(set(symbols)), 1) def test_shapes_nan(self): graph = self.graph self.master.get_shape_data = lambda: d d = np.arange(10, dtype=float) % 3 d[2] = np.nan graph.reset_graph() self.assertEqual(graph.scatterplot_item.data["symbol"][2], '?') d[:] = np.nan graph.update_shapes() self.assertTrue( all(symbol == '?' for symbol in graph.scatterplot_item.data["symbol"])) def impute0(data, _): data[np.isnan(data)] = 0 self.master.impute_shapes = impute0 d = np.arange(10, dtype=float) % 3 d[2] = np.nan graph.update_shapes() self.assertEqual(graph.scatterplot_item.data["symbol"][2], graph.CurveSymbols[0]) def test_show_grid(self): graph = self.graph show_grid = self.graph.plot_widget.showGrid = Mock() graph.show_grid = False graph.update_grid_visibility() self.assertEqual(show_grid.call_args[1], dict(x=False, y=False)) graph.show_grid = True graph.update_grid_visibility() self.assertEqual(show_grid.call_args[1], dict(x=True, y=True)) def test_show_legend(self): graph = self.graph graph.reset_graph() shape_legend = self.graph.shape_legend.setVisible = Mock() color_legend = self.graph.color_legend.setVisible = Mock() shape_labels = color_labels = None # Avoid pylint warning self.master.get_shape_labels = lambda: shape_labels self.master.get_color_labels = lambda: color_labels for shape_labels in (None, ["a", "b"]): for color_labels in (None, ["c", "d"], None): for visible in (True, False, True): graph.show_legend = visible graph.update_legends() self.assertIs(shape_legend.call_args[0][0], visible and bool(shape_labels), msg="error at {}, {}".format( visible, shape_labels)) self.assertIs(color_legend.call_args[0][0], visible and bool(color_labels), msg="error at {}, {}".format( visible, color_labels)) def test_show_legend_no_data(self): graph = self.graph self.master.get_shape_labels = lambda: ["a", "b"] self.master.get_color_labels = lambda: ["c", "d"] self.master.get_shape_data = lambda: np.arange(10) % 2 self.master.get_color_data = lambda: np.arange(10) < 6 graph.reset_graph() shape_legend = self.graph.shape_legend.setVisible = Mock() color_legend = self.graph.color_legend.setVisible = Mock() self.master.get_coordinates_data = lambda: (None, None) graph.reset_graph() self.assertFalse(shape_legend.call_args[0][0]) self.assertFalse(color_legend.call_args[0][0]) def test_legend_combine(self): master = self.master graph = self.graph graph.reset_graph() shape_legend = self.graph.shape_legend.setVisible = Mock() color_legend = self.graph.color_legend.setVisible = Mock() master.get_shape_labels = lambda: ["a", "b"] master.get_color_labels = lambda: ["c", "d"] graph.update_legends() self.assertTrue(shape_legend.call_args[0][0]) self.assertTrue(color_legend.call_args[0][0]) master.get_color_labels = lambda: ["a", "b"] graph.update_legends() self.assertTrue(shape_legend.call_args[0][0]) self.assertFalse(color_legend.call_args[0][0]) self.assertEqual(len(graph.shape_legend.items), 2) master.is_continuous_color = lambda: True master.get_color_data = lambda: np.arange(10, dtype=float) master.get_color_labels = lambda: None graph.update_colors() self.assertTrue(shape_legend.call_args[0][0]) self.assertTrue(color_legend.call_args[0][0]) self.assertEqual(len(graph.shape_legend.items), 2) def test_select_by_click(self): graph = self.graph graph.reset_graph() points = graph.scatterplot_item.points() graph.select_by_click(None, [points[2]]) np.testing.assert_almost_equal(graph.get_selection(), [2]) with patch("AnyQt.QtWidgets.QApplication.keyboardModifiers", lambda: Qt.ShiftModifier): graph.select_by_click(None, points[3:6]) np.testing.assert_almost_equal(list(graph.get_selection()), [2, 3, 4, 5]) np.testing.assert_almost_equal(graph.selection, [0, 0, 1, 2, 2, 2, 0, 0, 0, 0]) def test_select_by_rectangle(self): graph = self.graph coords = np.array([(x, y) for y in range(10) for x in range(10)], dtype=float).T self.master.get_coordinates_data = lambda: coords graph.reset_graph() graph.select_by_rectangle(QRectF(3, 5, 3.9, 2.9)) self.assertTrue( all(selected == (3 <= coords[0][i] <= 6 and 5 <= coords[1][i] <= 7) for i, selected in enumerate(graph.selection))) def test_select_by_indices(self): graph = self.graph graph.reset_graph() graph.label_only_selected = True def select(modifiers, indices): with patch("AnyQt.QtWidgets.QApplication.keyboardModifiers", lambda: modifiers): graph.update_selection_colors = Mock() graph.update_labels = Mock() self.master.selection_changed = Mock() graph.select_by_indices(np.array(indices)) graph.update_selection_colors.assert_called_with() if graph.label_only_selected: graph.update_labels.assert_called_with() else: graph.update_labels.assert_not_called() self.master.selection_changed.assert_called_with() select(0, [7, 8, 9]) np.testing.assert_almost_equal(graph.selection, [0, 0, 0, 0, 0, 0, 0, 1, 1, 1]) select(Qt.ShiftModifier | Qt.ControlModifier, [5, 6]) np.testing.assert_almost_equal(graph.selection, [0, 0, 0, 0, 0, 1, 1, 1, 1, 1]) select(Qt.ShiftModifier, [3, 4, 5]) np.testing.assert_almost_equal(graph.selection, [0, 0, 0, 2, 2, 2, 1, 1, 1, 1]) select(Qt.AltModifier, [1, 3, 7]) np.testing.assert_almost_equal(graph.selection, [0, 0, 0, 0, 2, 2, 1, 0, 1, 1]) select(0, [1, 8]) np.testing.assert_almost_equal(graph.selection, [0, 1, 0, 0, 0, 0, 0, 0, 1, 0]) graph.label_only_selected = False select(0, [3, 4]) def test_unselect_all(self): graph = self.graph graph.reset_graph() graph.label_only_selected = True graph.select_by_indices([3, 4, 5]) np.testing.assert_almost_equal(graph.selection, [0, 0, 0, 1, 1, 1, 0, 0, 0, 0]) graph.update_selection_colors = Mock() graph.update_labels = Mock() self.master.selection_changed = Mock() graph.unselect_all() self.assertIsNone(graph.selection) graph.update_selection_colors.assert_called_with() graph.update_labels.assert_called_with() self.master.selection_changed.assert_called_with() graph.update_selection_colors.reset_mock() graph.update_labels.reset_mock() self.master.selection_changed.reset_mock() graph.unselect_all() self.assertIsNone(graph.selection) graph.update_selection_colors.assert_not_called() graph.update_labels.assert_not_called() self.master.selection_changed.assert_not_called() def test_hiding_too_many_labels(self): spy = QSignalSpy(self.graph.too_many_labels) self.graph.MAX_VISIBLE_LABELS = 5 graph = self.graph coords = np.array([(x, 0) for x in range(10)], dtype=float).T self.master.get_coordinates_data = lambda: coords graph.reset_graph() self.assertFalse(spy and spy[-1][0]) self.master.get_label_data = lambda: \ np.array([str(x) for x in range(10)], dtype=object) graph.update_labels() self.assertTrue(spy[-1][0]) self.assertFalse(bool(self.graph.labels)) graph.view_box.setRange(QRectF(1, -1, 4, 4)) graph.view_box.sigRangeChangedManually.emit(((1, 5), (-1, 3))) self.assertFalse(spy[-1][0]) self.assertTrue(bool(self.graph.labels)) graph.view_box.setRange(QRectF(1, -1, 8, 8)) graph.view_box.sigRangeChangedManually.emit(((1, 9), (-1, 7))) self.assertTrue(spy[-1][0]) self.assertFalse(bool(self.graph.labels)) graph.label_only_selected = True graph.update_labels() self.assertFalse(spy[-1][0]) self.assertFalse(bool(self.graph.labels)) graph.selection_select([1, 2, 3, 4, 5, 6]) self.assertTrue(spy[-1][0]) self.assertFalse(bool(self.graph.labels)) graph.selection_select([1, 2, 3]) self.assertFalse(spy[-1][0]) self.assertTrue(bool(self.graph.labels)) graph.label_only_selected = False graph.update_labels() self.assertTrue(spy[-1][0]) self.assertFalse(bool(self.graph.labels)) graph.clear() self.assertFalse(spy[-1][0]) self.assertFalse(bool(self.graph.labels)) def test_no_needless_buildatlas(self): graph = self.graph graph.reset_graph() self.assertIsNone(graph.scatterplot_item.fragmentAtlas.atlas)
class TestOWScatterPlotBase(WidgetTest): def setUp(self): self.master = MockWidget() self.graph = OWScatterPlotBase(self.master) self.xy = (np.arange(10, dtype=float), np.arange(10, dtype=float)) self.master.get_coordinates_data = lambda: self.xy # pylint: disable=keyword-arg-before-vararg def setRange(self, rect=None, *_, **__): if isinstance(rect, QRectF): self.last_setRange = [[rect.left(), rect.right()], [rect.top(), rect.bottom()]] def test_update_coordinates_no_data(self): self.xy = None, None self.graph.reset_graph() self.assertIsNone(self.graph.scatterplot_item) self.assertIsNone(self.graph.scatterplot_item_sel) self.xy = [], [] self.graph.reset_graph() self.assertIsNone(self.graph.scatterplot_item) self.assertIsNone(self.graph.scatterplot_item_sel) def test_update_coordinates(self): graph = self.graph xy = self.xy = (np.array([1, 2]), np.array([3, 4])) graph.reset_graph() scatterplot_item = graph.scatterplot_item scatterplot_item_sel = graph.scatterplot_item_sel data = scatterplot_item.data np.testing.assert_almost_equal(scatterplot_item.getData(), xy) np.testing.assert_almost_equal(scatterplot_item_sel.getData(), xy) scatterplot_item.setSize([5, 6]) scatterplot_item.setSymbol([7, 8]) scatterplot_item.setPen([mkPen(9), mkPen(10)]) scatterplot_item.setBrush([11, 12]) data["data"] = np.array([13, 14]) xy[0][0] = 0 graph.update_coordinates() np.testing.assert_almost_equal(graph.scatterplot_item.getData(), xy) np.testing.assert_almost_equal(graph.scatterplot_item_sel.getData(), xy) # Graph updates coordinates instead of creating new items self.assertIs(scatterplot_item, graph.scatterplot_item) self.assertIs(scatterplot_item_sel, graph.scatterplot_item_sel) np.testing.assert_almost_equal(data["size"], [5, 6]) np.testing.assert_almost_equal(data["symbol"], [7, 8]) self.assertEqual(data["pen"][0], mkPen(9)) self.assertEqual(data["pen"][1], mkPen(10)) np.testing.assert_almost_equal(data["brush"], [11, 12]) np.testing.assert_almost_equal(data["data"], [13, 14]) def test_update_coordinates_and_labels(self): graph = self.graph xy = self.xy = (np.array([1., 2]), np.array([3, 4])) self.master.get_label_data = lambda: np.array(["a", "b"]) graph.reset_graph() self.assertEqual(graph.labels[0].pos().x(), 1) xy[0][0] = 1.5 graph.update_coordinates() self.assertEqual(graph.labels[0].pos().x(), 1.5) xy[0][0] = 0 # This label goes out of the range graph.update_coordinates() self.assertEqual(graph.labels[0].pos().x(), 2) def test_update_coordinates_and_density(self): graph = self.graph xy = self.xy = (np.array([1, 2]), np.array([3, 4])) self.master.get_label_data = lambda: np.array(["a", "b"]) graph.reset_graph() self.assertEqual(graph.labels[0].pos().x(), 1) xy[0][0] = 0 graph.update_density = Mock() graph.update_coordinates() graph.update_density.assert_called_with() def test_update_coordinates_reset_view(self): graph = self.graph graph.view_box.setRange = self.setRange xy = self.xy = (np.array([2, 1]), np.array([3, 10])) self.master.get_label_data = lambda: np.array(["a", "b"]) graph.reset_graph() self.assertEqual(self.last_setRange, [[1, 2], [3, 10]]) xy[0][1] = 0 graph.update_coordinates() self.assertEqual(self.last_setRange, [[0, 2], [3, 10]]) def test_reset_graph_no_data(self): self.xy = (None, None) self.graph.scatterplot_item = ScatterPlotItem([1, 2], [3, 4]) self.graph.reset_graph() self.assertIsNone(self.graph.scatterplot_item) self.assertIsNone(self.graph.scatterplot_item_sel) def test_update_coordinates_indices(self): graph = self.graph self.xy = (np.array([2, 1]), np.array([3, 10])) graph.reset_graph() np.testing.assert_almost_equal( graph.scatterplot_item.data["data"], [0, 1]) def test_sampling(self): graph = self.graph master = self.master # Enable sampling before getting the data graph.set_sample_size(3) xy = self.xy = (np.arange(10, dtype=float), np.arange(0, 30, 3, dtype=float)) d = np.arange(10, dtype=float) master.get_size_data = lambda: d master.get_shape_data = lambda: d master.get_color_data = lambda: d master.get_label_data = lambda: \ np.array([str(x) for x in d], dtype=object) graph.reset_graph() self.process_events(until=lambda: not ( self.graph.timer is not None and self.graph.timer.isActive())) # Check proper sampling scatterplot_item = graph.scatterplot_item x, y = scatterplot_item.getData() self.assertEqual(len(x), 3) self.assertNotEqual(x[0], x[1]) self.assertNotEqual(x[0], x[2]) self.assertNotEqual(x[1], x[2]) np.testing.assert_almost_equal(3 * x, y) data = scatterplot_item.data s0, s1, s2 = data["size"] - graph.MinShapeSize np.testing.assert_almost_equal( (s2 - s1) / (s1 - s0), (x[2] - x[1]) / (x[1] - x[0])) self.assertEqual( list(data["symbol"]), [graph.CurveSymbols[int(xi)] for xi in x]) self.assertEqual( [pen.color().hue() for pen in data["pen"]], [graph.palette[xi].hue() for xi in x]) self.assertEqual( [label.textItem.toPlainText() for label in graph.labels], [str(xi) for xi in x]) # Check that sample is extended when sample size is changed graph.set_sample_size(4) self.process_events(until=lambda: not ( self.graph.timer is not None and self.graph.timer.isActive())) scatterplot_item = graph.scatterplot_item x, y = scatterplot_item.getData() data = scatterplot_item.data s0, s1, s2, s3 = data["size"] - graph.MinShapeSize np.testing.assert_almost_equal( (s2 - s1) / (s1 - s0), (x[2] - x[1]) / (x[1] - x[0])) np.testing.assert_almost_equal( (s2 - s1) / (s1 - s3), (x[2] - x[1]) / (x[1] - x[3])) self.assertEqual( list(data["symbol"]), [graph.CurveSymbols[int(xi)] for xi in x]) self.assertEqual( [pen.color().hue() for pen in data["pen"]], [graph.palette[xi].hue() for xi in x]) self.assertEqual( [label.textItem.toPlainText() for label in graph.labels], [str(xi) for xi in x]) # Disable sampling graph.set_sample_size(None) scatterplot_item = graph.scatterplot_item x, y = scatterplot_item.getData() data = scatterplot_item.data np.testing.assert_almost_equal(x, xy[0]) np.testing.assert_almost_equal(y, xy[1]) self.assertEqual( list(data["symbol"]), [graph.CurveSymbols[int(xi)] for xi in d]) self.assertEqual( [pen.color().hue() for pen in data["pen"]], [graph.palette[xi].hue() for xi in d]) self.assertEqual( [label.textItem.toPlainText() for label in graph.labels], [str(xi) for xi in d]) # Enable sampling when data is already present and not sampled graph.set_sample_size(3) self.process_events(until=lambda: not ( self.graph.timer is not None and self.graph.timer.isActive())) scatterplot_item = graph.scatterplot_item x, y = scatterplot_item.getData() data = scatterplot_item.data s0, s1, s2 = data["size"] - graph.MinShapeSize np.testing.assert_almost_equal( (s2 - s1) / (s1 - s0), (x[2] - x[1]) / (x[1] - x[0])) self.assertEqual( list(data["symbol"]), [graph.CurveSymbols[int(xi)] for xi in x]) self.assertEqual( [pen.color().hue() for pen in data["pen"]], [graph.palette[xi].hue() for xi in x]) self.assertEqual( [label.textItem.toPlainText() for label in graph.labels], [str(xi) for xi in x]) # Update data when data is present and sampling is enabled xy[0][:] = np.arange(9, -1, -1, dtype=float) d = xy[0] graph.update_coordinates() x1, _ = scatterplot_item.getData() np.testing.assert_almost_equal(9 - x, x1) graph.update_sizes() data = scatterplot_item.data s0, s1, s2 = data["size"] - graph.MinShapeSize np.testing.assert_almost_equal( (s2 - s1) / (s1 - s0), (x[2] - x[1]) / (x[1] - x[0])) # Reset graph when data is present and sampling is enabled self.xy = (np.arange(100, 105, dtype=float), np.arange(100, 105, dtype=float)) d = self.xy[0] - 100 graph.reset_graph() self.process_events(until=lambda: not ( self.graph.timer is not None and self.graph.timer.isActive())) scatterplot_item = graph.scatterplot_item x, y = scatterplot_item.getData() self.assertEqual(len(x), 3) self.assertTrue(np.all(x > 99)) data = scatterplot_item.data s0, s1, s2 = data["size"] - graph.MinShapeSize np.testing.assert_almost_equal( (s2 - s1) / (s1 - s0), (x[2] - x[1]) / (x[1] - x[0])) # Don't sample when unnecessary self.xy = (np.arange(100, dtype=float), ) * 2 d = None delattr(master, "get_label_data") graph.reset_graph() graph.set_sample_size(120) scatterplot_item = graph.scatterplot_item x, y = scatterplot_item.getData() np.testing.assert_almost_equal(x, np.arange(100)) def test_sampling_keeps_selection(self): graph = self.graph self.xy = (np.arange(100, dtype=float), np.arange(100, dtype=float)) graph.reset_graph() graph.select_by_indices(np.arange(1, 100, 2)) graph.set_sample_size(30) np.testing.assert_almost_equal(graph.selection, np.arange(100) % 2) graph.set_sample_size(None) np.testing.assert_almost_equal(graph.selection, np.arange(100) % 2) base = "Orange.widgets.visualize.owscatterplotgraph.OWScatterPlotBase." @patch(base + "update_sizes") @patch(base + "update_colors") @patch(base + "update_selection_colors") @patch(base + "update_shapes") @patch(base + "update_labels") def test_reset_calls_all_updates_and_update_doesnt(self, *mocks): master = MockWidget() graph = OWScatterPlotBase(master) for mock in mocks: mock.assert_not_called() graph.reset_graph() for mock in mocks: mock.assert_called_with() mock.reset_mock() graph.update_coordinates() for mock in mocks: mock.assert_not_called() def test_jittering(self): graph = self.graph graph.jitter_size = 10 graph.reset_graph() scatterplot_item = graph.scatterplot_item x, y = scatterplot_item.getData() a10 = np.arange(10) self.assertTrue(np.any(np.nonzero(a10 - x))) self.assertTrue(np.any(np.nonzero(a10 - y))) np.testing.assert_array_less(a10 - x, 1) np.testing.assert_array_less(a10 - y, 1) graph.jitter_size = 0 graph.update_coordinates() scatterplot_item = graph.scatterplot_item x, y = scatterplot_item.getData() np.testing.assert_equal(a10, x) def test_size_normalization(self): graph = self.graph self.master.get_size_data = lambda: d d = np.arange(10, dtype=float) graph.reset_graph() scatterplot_item = graph.scatterplot_item size = scatterplot_item.data["size"] diffs = [round(y - x, 2) for x, y in zip(size, size[1:])] self.assertEqual(len(set(diffs)), 1) self.assertGreater(diffs[0], 0) d = np.arange(10, 20, dtype=float) graph.update_sizes() self.assertIs(scatterplot_item, graph.scatterplot_item) size = scatterplot_item.data["size"] diffs2 = [round(y - x, 2) for x, y in zip(size, size[1:])] self.assertEqual(diffs, diffs2) def test_size_with_nans(self): graph = self.graph self.master.get_size_data = lambda: d d = np.arange(10, dtype=float) graph.reset_graph() scatterplot_item = graph.scatterplot_item sizes = scatterplot_item.data["size"] d[4] = np.nan graph.update_sizes() self.process_events(until=lambda: not ( self.graph.timer is not None and self.graph.timer.isActive())) sizes2 = scatterplot_item.data["size"] self.assertEqual(sizes[1] - sizes[0], sizes2[1] - sizes2[0]) self.assertLess(sizes2[4], self.graph.MinShapeSize) d[:] = np.nan graph.update_sizes() sizes3 = scatterplot_item.data["size"] np.testing.assert_almost_equal(sizes, sizes3) def test_sizes_all_same_or_nan(self): graph = self.graph self.master.get_size_data = lambda: d d = np.full((10, ), 3.0) graph.reset_graph() scatterplot_item = graph.scatterplot_item sizes = scatterplot_item.data["size"] self.assertEqual(len(set(sizes)), 1) self.assertGreater(sizes[0], self.graph.MinShapeSize) d = None graph.update_sizes() scatterplot_item = graph.scatterplot_item sizes2 = scatterplot_item.data["size"] np.testing.assert_almost_equal(sizes, sizes2) def test_sizes_point_width_is_linear(self): graph = self.graph self.master.get_size_data = lambda: d d = np.arange(10, dtype=float) graph.point_width = 1 graph.reset_graph() sizes1 = graph.scatterplot_item.data["size"] graph.point_width = 2 graph.update_sizes() sizes2 = graph.scatterplot_item.data["size"] graph.point_width = 3 graph.update_sizes() sizes3 = graph.scatterplot_item.data["size"] np.testing.assert_almost_equal(2 * (sizes2 - sizes1), sizes3 - sizes1) def test_sizes_custom_imputation(self): def impute_max(size_data): size_data[np.isnan(size_data)] = np.nanmax(size_data) graph = self.graph self.master.get_size_data = lambda: d self.master.impute_sizes = impute_max d = np.arange(10, dtype=float) d[4] = np.nan graph.reset_graph() sizes = graph.scatterplot_item.data["size"] self.assertAlmostEqual(sizes[4], sizes[9]) def test_sizes_selection(self): graph = self.graph graph.get_size = lambda: np.arange(10, dtype=float) graph.reset_graph() np.testing.assert_almost_equal( graph.scatterplot_item_sel.data["size"] - graph.scatterplot_item.data["size"], SELECTION_WIDTH) def test_colors_discrete(self): self.master.is_continuous_color = lambda: False palette = self.master.get_palette() graph = self.graph self.master.get_color_data = lambda: d d = np.arange(10, dtype=float) % 2 graph.reset_graph() self.assertTrue( all(pen.color().hue() is palette[i % 2].hue() for i, pen in enumerate(graph.scatterplot_item.data["pen"]))) self.assertTrue( all(pen.color().hue() is palette[i % 2].hue() for i, pen in enumerate(graph.scatterplot_item.data["brush"]))) def test_colors_discrete_nan(self): self.master.is_continuous_color = lambda: False palette = self.master.get_palette() graph = self.graph d = np.arange(10, dtype=float) % 2 d[4] = np.nan self.master.get_color_data = lambda: d graph.reset_graph() pens = graph.scatterplot_item.data["pen"] brushes = graph.scatterplot_item.data["brush"] self.assertEqual(pens[0].color().hue(), palette[0].hue()) self.assertEqual(pens[1].color().hue(), palette[1].hue()) self.assertEqual(brushes[0].color().hue(), palette[0].hue()) self.assertEqual(brushes[1].color().hue(), palette[1].hue()) self.assertEqual(pens[4].color().hue(), QColor(128, 128, 128).hue()) self.assertEqual(brushes[4].color().hue(), QColor(128, 128, 128).hue()) def test_colors_continuous(self): self.master.is_continuous_color = lambda: True graph = self.graph d = np.arange(10, dtype=float) self.master.get_color_data = lambda: d graph.reset_graph() # I don't have a good test ... just don't crash d[4] = np.nan graph.update_colors() # Ditto def test_colors_continuous_nan(self): self.master.is_continuous_color = lambda: True graph = self.graph d = np.arange(10, dtype=float) % 2 d[4] = np.nan self.master.get_color_data = lambda: d graph.reset_graph() pens = graph.scatterplot_item.data["pen"] brushes = graph.scatterplot_item.data["brush"] nan_color = QColor(*NAN_GREY) self.assertEqual(pens[4].color().hue(), nan_color.hue()) self.assertEqual(brushes[4].color().hue(), nan_color.hue()) def test_colors_subset(self): def run_tests(): self.master.get_subset_mask = lambda: None graph.alpha_value = 42 graph.reset_graph() brushes = graph.scatterplot_item.data["brush"] self.assertEqual(brushes[0].color().alpha(), 42) self.assertEqual(brushes[1].color().alpha(), 42) self.assertEqual(brushes[4].color().alpha(), 42) graph.alpha_value = 123 graph.update_colors() brushes = graph.scatterplot_item.data["brush"] self.assertEqual(brushes[0].color().alpha(), 123) self.assertEqual(brushes[1].color().alpha(), 123) self.assertEqual(brushes[4].color().alpha(), 123) self.master.get_subset_mask = lambda: np.arange(10) >= 5 graph.update_colors() brushes = graph.scatterplot_item.data["brush"] self.assertEqual(brushes[0].color().alpha(), 0) self.assertEqual(brushes[1].color().alpha(), 0) self.assertEqual(brushes[4].color().alpha(), 0) self.assertEqual(brushes[5].color().alpha(), 255) self.assertEqual(brushes[6].color().alpha(), 255) self.assertEqual(brushes[7].color().alpha(), 255) graph = self.graph self.master.get_color_data = lambda: None self.master.is_continuous_color = lambda: True graph.reset_graph() run_tests() self.master.is_continuous_color = lambda: False graph.reset_graph() run_tests() d = np.arange(10, dtype=float) % 2 d[4:6] = np.nan self.master.get_color_data = lambda: d self.master.is_continuous_color = lambda: True graph.reset_graph() run_tests() self.master.is_continuous_color = lambda: False graph.reset_graph() run_tests() def test_colors_none(self): graph = self.graph graph.reset_graph() hue = QColor(128, 128, 128).hue() data = graph.scatterplot_item.data self.assertTrue(all(pen.color().hue() == hue for pen in data["pen"])) self.assertTrue(all(pen.color().hue() == hue for pen in data["brush"])) self.master.get_subset_mask = lambda: np.arange(10) < 5 graph.update_colors() data = graph.scatterplot_item.data self.assertTrue(all(pen.color().hue() == hue for pen in data["pen"])) self.assertTrue(all(pen.color().hue() == hue for pen in data["brush"])) def test_colors_update_legend_and_density(self): graph = self.graph graph.update_legends = Mock() graph.update_density = Mock() graph.reset_graph() graph.update_legends.assert_called_with() graph.update_density.assert_called_with() graph.update_legends.reset_mock() graph.update_density.reset_mock() graph.update_coordinates() graph.update_legends.assert_not_called() graph.update_colors() graph.update_legends.assert_called_with() graph.update_density.assert_called_with() def test_selection_colors(self): graph = self.graph graph.reset_graph() data = graph.scatterplot_item_sel.data # One group graph.select_by_indices(np.array([0, 1, 2, 3])) graph.update_selection_colors() pens = data["pen"] for i in range(4): self.assertNotEqual(pens[i].style(), Qt.NoPen) for i in range(4, 10): self.assertEqual(pens[i].style(), Qt.NoPen) # Two groups with patch("AnyQt.QtWidgets.QApplication.keyboardModifiers", lambda: Qt.ShiftModifier): graph.select_by_indices(np.array([4, 5, 6])) graph.update_selection_colors() pens = data["pen"] for i in range(7): self.assertNotEqual(pens[i].style(), Qt.NoPen) for i in range(7, 10): self.assertEqual(pens[i].style(), Qt.NoPen) self.assertEqual(len({pen.color().hue() for pen in pens[:4]}), 1) self.assertEqual(len({pen.color().hue() for pen in pens[4:7]}), 1) color1 = pens[3].color().hue() color2 = pens[4].color().hue() self.assertNotEqual(color1, color2) # Two groups + sampling graph.set_sample_size(7) x = graph.scatterplot_item.getData()[0] pens = graph.scatterplot_item_sel.data["pen"] for xi, pen in zip(x, pens): if xi < 4: self.assertEqual(pen.color().hue(), color1) elif xi < 7: self.assertEqual(pen.color().hue(), color2) else: self.assertEqual(pen.style(), Qt.NoPen) def test_density(self): graph = self.graph density = object() with patch("Orange.widgets.utils.classdensity.class_density_image", return_value=density): graph.reset_graph() self.assertIsNone(graph.density_img) graph.plot_widget.addItem = Mock() graph.plot_widget.removeItem = Mock() graph.class_density = True graph.update_colors() self.assertIsNone(graph.density_img) d = np.ones((10, ), dtype=float) self.master.get_color_data = lambda: d graph.update_colors() self.assertIsNone(graph.density_img) d = np.arange(10) % 2 graph.update_colors() self.assertIs(graph.density_img, density) self.assertIs(graph.plot_widget.addItem.call_args[0][0], density) graph.class_density = False graph.update_colors() self.assertIsNone(graph.density_img) self.assertIs(graph.plot_widget.removeItem.call_args[0][0], density) graph.class_density = True graph.update_colors() self.assertIs(graph.density_img, density) self.assertIs(graph.plot_widget.addItem.call_args[0][0], density) graph.update_coordinates = lambda: (None, None) graph.reset_graph() self.assertIsNone(graph.density_img) self.assertIs(graph.plot_widget.removeItem.call_args[0][0], density) def test_labels(self): graph = self.graph graph.reset_graph() self.assertEqual(graph.labels, []) self.master.get_label_data = lambda: \ np.array([str(x) for x in range(10)], dtype=object) graph.update_labels() self.assertEqual( [label.textItem.toPlainText() for label in graph.labels], [str(i) for i in range(10)]) # Label only selected selected = [1, 3, 5] graph.select_by_indices(selected) self.graph.label_only_selected = True graph.update_labels() self.assertEqual( [label.textItem.toPlainText() for label in graph.labels], [str(x) for x in selected]) x, y = graph.scatterplot_item.getData() for i, index in enumerate(selected): self.assertEqual(x[index], graph.labels[i].x()) self.assertEqual(y[index], graph.labels[i].y()) # Disable label only selected self.graph.label_only_selected = False graph.update_labels() self.assertEqual( [label.textItem.toPlainText() for label in graph.labels], [str(i) for i in range(10)]) x, y = graph.scatterplot_item.getData() for xi, yi, label in zip(x, y, graph.labels): self.assertEqual(xi, label.x()) self.assertEqual(yi, label.y()) # Label only selected + sampling selected = [1, 3, 4, 5, 6, 7, 9] graph.select_by_indices(selected) self.graph.label_only_selected = True graph.update_labels() graph.set_sample_size(5) for label in graph.labels: ind = int(label.textItem.toPlainText()) self.assertIn(ind, selected) self.assertEqual(label.x(), x[ind]) self.assertEqual(label.y(), y[ind]) def test_label_mask_all_visible(self): graph = self.graph x, y = np.arange(10) / 10, np.arange(10) / 10 sel = np.array( [True, True, False, False, False, True, True, True, False, False]) subset = np.array( [True, False, True, True, False, True, True, False, False, False]) trues = np.ones(10, dtype=bool) np.testing.assert_equal(graph._label_mask(x, y), trues) # Selection present, subset is None graph.selection = sel graph.master.get_subset_mask = lambda: None graph.label_only_selected = False np.testing.assert_equal(graph._label_mask(x, y), trues) graph.label_only_selected = True np.testing.assert_equal(graph._label_mask(x, y), sel) # Selection and subset present graph.selection = sel graph.master.get_subset_mask = lambda: subset graph.label_only_selected = False np.testing.assert_equal(graph._label_mask(x, y), trues) graph.label_only_selected = True np.testing.assert_equal(graph._label_mask(x, y), np.array( [True, True, True, True, False, True, True, True, False, False] )) # No selection, subset present graph.selection = None graph.master.get_subset_mask = lambda: subset graph.label_only_selected = False np.testing.assert_equal(graph._label_mask(x, y), trues) graph.label_only_selected = True np.testing.assert_equal(graph._label_mask(x, y), subset) # No selection, no subset graph.selection = None graph.master.get_subset_mask = lambda: None graph.label_only_selected = False np.testing.assert_equal(graph._label_mask(x, y), trues) graph.label_only_selected = True self.assertIsNone(graph._label_mask(x, y)) def test_label_mask_with_invisible(self): graph = self.graph x, y = np.arange(5, 10) / 10, np.arange(5, 10) / 10 sel = np.array( [True, True, False, False, False, # these 5 are not in the sample True, True, True, False, False]) subset = np.array( [True, False, True, True, False, # these 5 are not in the sample True, True, False, False, True]) graph.sample_indices = np.arange(5, 10, dtype=int) trues = np.ones(5, dtype=bool) np.testing.assert_equal(graph._label_mask(x, y), trues) # Selection present, subset is None graph.selection = sel graph.master.get_subset_mask = lambda: None graph.label_only_selected = False np.testing.assert_equal(graph._label_mask(x, y), trues) graph.label_only_selected = True np.testing.assert_equal(graph._label_mask(x, y), sel[5:]) # Selection and subset present graph.selection = sel graph.master.get_subset_mask = lambda: subset graph.label_only_selected = False np.testing.assert_equal(graph._label_mask(x, y), trues) graph.label_only_selected = True np.testing.assert_equal( graph._label_mask(x, y), np.array([True, True, True, False, True])) # No selection, subset present graph.selection = None graph.master.get_subset_mask = lambda: subset graph.label_only_selected = False np.testing.assert_equal(graph._label_mask(x, y), trues) graph.label_only_selected = True np.testing.assert_equal(graph._label_mask(x, y), subset[5:]) # No selection, no subset graph.selection = None graph.master.get_subset_mask = lambda: None graph.label_only_selected = False np.testing.assert_equal(graph._label_mask(x, y), trues) graph.label_only_selected = True self.assertIsNone(graph._label_mask(x, y)) def test_label_mask_with_invisible_and_view(self): graph = self.graph x, y = np.arange(5, 10) / 10, np.arange(5) / 10 sel = np.array( [True, True, False, False, False, # these 5 are not in the sample True, True, True, False, False]) # first and last out of the view subset = np.array( [True, False, True, True, False, # these 5 are not in the sample True, True, False, True, True]) # first and last out of the view graph.sample_indices = np.arange(5, 10, dtype=int) graph.view_box.viewRange = lambda: ((0.6, 1), (0, 0.3)) viewed = np.array([False, True, True, True, False]) np.testing.assert_equal(graph._label_mask(x, y), viewed) # Selection present, subset is None graph.selection = sel graph.master.get_subset_mask = lambda: None graph.label_only_selected = False np.testing.assert_equal(graph._label_mask(x, y), viewed) graph.label_only_selected = True np.testing.assert_equal( graph._label_mask(x, y), np.array([False, True, True, False, False])) # Selection and subset present graph.selection = sel graph.master.get_subset_mask = lambda: subset graph.label_only_selected = False np.testing.assert_equal(graph._label_mask(x, y), viewed) graph.label_only_selected = True np.testing.assert_equal( graph._label_mask(x, y), np.array([False, True, True, True, False])) # No selection, subset present graph.selection = None graph.master.get_subset_mask = lambda: subset graph.label_only_selected = False np.testing.assert_equal(graph._label_mask(x, y), viewed) graph.label_only_selected = True np.testing.assert_equal( graph._label_mask(x, y), np.array([False, True, False, True, False])) # No selection, no subset graph.selection = None graph.master.get_subset_mask = lambda: None graph.label_only_selected = False np.testing.assert_equal(graph._label_mask(x, y), viewed) graph.label_only_selected = True self.assertIsNone(graph._label_mask(x, y)) def test_labels_observes_mask(self): graph = self.graph get_label_data = graph.master.get_label_data graph.reset_graph() self.assertEqual(graph.labels, []) get_label_data.reset_mock() graph._label_mask = lambda *_: None graph.update_labels() get_label_data.assert_not_called() self.master.get_label_data = lambda: \ np.array([str(x) for x in range(10)], dtype=object) graph._label_mask = \ lambda *_: np.array([False, True, True] + [False] * 7) graph.update_labels() self.assertEqual( [label.textItem.toPlainText() for label in graph.labels], ["1", "2"]) def test_labels_update_coordinates(self): graph = self.graph self.master.get_label_data = lambda: \ np.array([str(x) for x in range(10)], dtype=object) graph.reset_graph() graph.set_sample_size(7) x, y = graph.scatterplot_item.getData() for xi, yi, label in zip(x, y, graph.labels): self.assertEqual(xi, label.x()) self.assertEqual(yi, label.y()) self.master.get_coordinates_data = \ lambda: (np.arange(10, 20), np.arange(50, 60)) graph.update_coordinates() x, y = graph.scatterplot_item.getData() for xi, yi, label in zip(x, y, graph.labels): self.assertEqual(xi, label.x()) self.assertEqual(yi, label.y()) def test_shapes(self): graph = self.graph self.master.get_shape_data = lambda: d d = np.arange(10, dtype=float) % 3 graph.reset_graph() scatterplot_item = graph.scatterplot_item symbols = scatterplot_item.data["symbol"] self.assertTrue(all(symbol == graph.CurveSymbols[i % 3] for i, symbol in enumerate(symbols))) d = np.arange(10, dtype=float) % 2 graph.update_shapes() symbols = scatterplot_item.data["symbol"] self.assertTrue(all(symbol == graph.CurveSymbols[i % 2] for i, symbol in enumerate(symbols))) d = None graph.update_shapes() symbols = scatterplot_item.data["symbol"] self.assertEqual(len(set(symbols)), 1) def test_shapes_nan(self): graph = self.graph self.master.get_shape_data = lambda: d d = np.arange(10, dtype=float) % 3 d[2] = np.nan graph.reset_graph() self.assertEqual(graph.scatterplot_item.data["symbol"][2], '?') d[:] = np.nan graph.update_shapes() self.assertTrue( all(symbol == '?' for symbol in graph.scatterplot_item.data["symbol"])) def impute0(data, _): data[np.isnan(data)] = 0 self.master.impute_shapes = impute0 d = np.arange(10, dtype=float) % 3 d[2] = np.nan graph.update_shapes() self.assertEqual(graph.scatterplot_item.data["symbol"][2], graph.CurveSymbols[0]) def test_show_grid(self): graph = self.graph show_grid = self.graph.plot_widget.showGrid = Mock() graph.show_grid = False graph.update_grid_visibility() self.assertEqual(show_grid.call_args[1], dict(x=False, y=False)) graph.show_grid = True graph.update_grid_visibility() self.assertEqual(show_grid.call_args[1], dict(x=True, y=True)) def test_show_legend(self): graph = self.graph graph.reset_graph() shape_legend = self.graph.shape_legend.setVisible = Mock() color_legend = self.graph.color_legend.setVisible = Mock() shape_labels = color_labels = None # Avoid pylint warning self.master.get_shape_labels = lambda: shape_labels self.master.get_color_labels = lambda: color_labels for shape_labels in (None, ["a", "b"]): for color_labels in (None, ["c", "d"], None): for visible in (True, False, True): graph.show_legend = visible graph.update_legends() self.assertIs( shape_legend.call_args[0][0], visible and bool(shape_labels), msg="error at {}, {}".format(visible, shape_labels)) self.assertIs( color_legend.call_args[0][0], visible and bool(color_labels), msg="error at {}, {}".format(visible, color_labels)) def test_show_legend_no_data(self): graph = self.graph self.master.get_shape_labels = lambda: ["a", "b"] self.master.get_color_labels = lambda: ["c", "d"] self.master.get_shape_data = lambda: np.arange(10) % 2 self.master.get_color_data = lambda: np.arange(10) < 6 graph.reset_graph() shape_legend = self.graph.shape_legend.setVisible = Mock() color_legend = self.graph.color_legend.setVisible = Mock() self.master.get_coordinates_data = lambda: (None, None) graph.reset_graph() self.assertFalse(shape_legend.call_args[0][0]) self.assertFalse(color_legend.call_args[0][0]) def test_legend_combine(self): master = self.master graph = self.graph graph.reset_graph() shape_legend = self.graph.shape_legend.setVisible = Mock() color_legend = self.graph.color_legend.setVisible = Mock() master.get_shape_labels = lambda: ["a", "b"] master.get_color_labels = lambda: ["c", "d"] graph.update_legends() self.assertTrue(shape_legend.call_args[0][0]) self.assertTrue(color_legend.call_args[0][0]) master.get_color_labels = lambda: ["a", "b"] graph.update_legends() self.assertTrue(shape_legend.call_args[0][0]) self.assertFalse(color_legend.call_args[0][0]) self.assertEqual(len(graph.shape_legend.items), 2) master.is_continuous_color = lambda: True master.get_color_data = lambda: np.arange(10, dtype=float) graph.update_colors() self.assertTrue(shape_legend.call_args[0][0]) self.assertTrue(color_legend.call_args[0][0]) self.assertEqual(len(graph.shape_legend.items), 2) def test_select_by_click(self): graph = self.graph graph.reset_graph() points = graph.scatterplot_item.points() graph.select_by_click(None, [points[2]]) np.testing.assert_almost_equal(graph.get_selection(), [2]) with patch("AnyQt.QtWidgets.QApplication.keyboardModifiers", lambda: Qt.ShiftModifier): graph.select_by_click(None, points[3:6]) np.testing.assert_almost_equal( list(graph.get_selection()), [2, 3, 4, 5]) np.testing.assert_almost_equal( graph.selection, [0, 0, 1, 2, 2, 2, 0, 0, 0, 0]) def test_select_by_rectangle(self): graph = self.graph coords = np.array( [(x, y) for y in range(10) for x in range(10)], dtype=float).T self.master.get_coordinates_data = lambda: coords graph.reset_graph() graph.select_by_rectangle(QRectF(3, 5, 3.9, 2.9)) self.assertTrue( all(selected == (3 <= coords[0][i] <= 6 and 5 <= coords[1][i] <= 7) for i, selected in enumerate(graph.selection))) def test_select_by_indices(self): graph = self.graph graph.reset_graph() graph.label_only_selected = True def select(modifiers, indices): with patch("AnyQt.QtWidgets.QApplication.keyboardModifiers", lambda: modifiers): graph.update_selection_colors = Mock() graph.update_labels = Mock() self.master.selection_changed = Mock() graph.select_by_indices(np.array(indices)) graph.update_selection_colors.assert_called_with() if graph.label_only_selected: graph.update_labels.assert_called_with() else: graph.update_labels.assert_not_called() self.master.selection_changed.assert_called_with() select(0, [7, 8, 9]) np.testing.assert_almost_equal( graph.selection, [0, 0, 0, 0, 0, 0, 0, 1, 1, 1]) select(Qt.ShiftModifier | Qt.ControlModifier, [5, 6]) np.testing.assert_almost_equal( graph.selection, [0, 0, 0, 0, 0, 1, 1, 1, 1, 1]) select(Qt.ShiftModifier, [3, 4, 5]) np.testing.assert_almost_equal( graph.selection, [0, 0, 0, 2, 2, 2, 1, 1, 1, 1]) select(Qt.AltModifier, [1, 3, 7]) np.testing.assert_almost_equal( graph.selection, [0, 0, 0, 0, 2, 2, 1, 0, 1, 1]) select(0, [1, 8]) np.testing.assert_almost_equal( graph.selection, [0, 1, 0, 0, 0, 0, 0, 0, 1, 0]) graph.label_only_selected = False select(0, [3, 4]) def test_unselect_all(self): graph = self.graph graph.reset_graph() graph.label_only_selected = True graph.select_by_indices([3, 4, 5]) np.testing.assert_almost_equal( graph.selection, [0, 0, 0, 1, 1, 1, 0, 0, 0, 0]) graph.update_selection_colors = Mock() graph.update_labels = Mock() self.master.selection_changed = Mock() graph.unselect_all() self.assertIsNone(graph.selection) graph.update_selection_colors.assert_called_with() graph.update_labels.assert_called_with() self.master.selection_changed.assert_called_with() graph.update_selection_colors.reset_mock() graph.update_labels.reset_mock() self.master.selection_changed.reset_mock() graph.unselect_all() self.assertIsNone(graph.selection) graph.update_selection_colors.assert_not_called() graph.update_labels.assert_not_called() self.master.selection_changed.assert_not_called() def test_hiding_too_many_labels(self): spy = QSignalSpy(self.graph.too_many_labels) self.graph.MAX_VISIBLE_LABELS = 5 graph = self.graph coords = np.array( [(x, 0) for x in range(10)], dtype=float).T self.master.get_coordinates_data = lambda: coords graph.reset_graph() self.assertFalse(spy and spy[-1][0]) self.master.get_label_data = lambda: \ np.array([str(x) for x in range(10)], dtype=object) graph.update_labels() self.assertTrue(spy[-1][0]) self.assertFalse(bool(self.graph.labels)) graph.view_box.setRange(QRectF(1, -1, 4, 4)) graph.view_box.sigRangeChangedManually.emit(((1, 5), (-1, 3))) self.assertFalse(spy[-1][0]) self.assertTrue(bool(self.graph.labels)) graph.view_box.setRange(QRectF(1, -1, 8, 8)) graph.view_box.sigRangeChangedManually.emit(((1, 9), (-1, 7))) self.assertTrue(spy[-1][0]) self.assertFalse(bool(self.graph.labels)) graph.label_only_selected = True graph.update_labels() self.assertFalse(spy[-1][0]) self.assertFalse(bool(self.graph.labels)) graph.selection_select([1, 2, 3, 4, 5, 6]) self.assertTrue(spy[-1][0]) self.assertFalse(bool(self.graph.labels)) graph.selection_select([1, 2, 3]) self.assertFalse(spy[-1][0]) self.assertTrue(bool(self.graph.labels)) graph.label_only_selected = False graph.update_labels() self.assertTrue(spy[-1][0]) self.assertFalse(bool(self.graph.labels)) graph.clear() self.assertFalse(spy[-1][0]) self.assertFalse(bool(self.graph.labels))