d455da9aec
This namespace appears to be valid in PySide2/PyQt5 5.12+ so we may as well migrate to the newer namespace ourselves.
240 lines
9.1 KiB
Python
240 lines
9.1 KiB
Python
# -*- coding: utf-8 -*-
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import time
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import pytest
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from pyqtgraph.Qt import QtGui, QtTest, QtCore
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import numpy as np
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import pyqtgraph as pg
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from tests.image_testing import assertImageApproved, TransposedImageItem
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try:
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import cupy
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except ImportError:
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cupy = None
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app = pg.mkQApp()
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@pytest.mark.skipif(cupy is None, reason="CuPy unavailable to test")
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def test_useCupy_can_be_set_after_init():
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prev_setting = pg.getConfigOption("useCupy")
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try:
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pg.setConfigOption("useCupy", False)
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w = pg.GraphicsLayoutWidget()
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w.show()
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view = pg.ViewBox()
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w.setCentralWidget(view)
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w.resize(200, 200)
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img = cupy.random.randint(0, 255, size=(32, 32)).astype(cupy.uint8)
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ii = pg.ImageItem()
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view.addItem(ii)
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pg.setConfigOption("useCupy", True)
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ii.setImage(img)
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w.hide()
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finally:
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pg.setConfigOption("useCupy", prev_setting)
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@pytest.mark.skipif(cupy is None, reason="CuPy unavailable to test")
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def test_ensuring_substrate():
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prev_setting = pg.getConfigOption("useCupy")
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try:
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pg.setConfigOption("useCupy", True)
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ii = pg.ImageItem()
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data = cupy.random.randint(0, 255, size=(32, 32)).astype(cupy.uint8)
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assert data is ii._ensure_proper_substrate(data, cupy)
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assert isinstance(ii._ensure_proper_substrate(data, cupy), cupy.ndarray)
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assert data is not ii._ensure_proper_substrate(data, np)
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assert isinstance(ii._ensure_proper_substrate(data, np), np.ndarray)
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data = np.random.randint(0, 255, size=(32, 32)).astype(np.uint8)
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assert data is ii._ensure_proper_substrate(data, np)
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assert isinstance(ii._ensure_proper_substrate(data, np), np.ndarray)
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assert data is not ii._ensure_proper_substrate(data, cupy)
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assert isinstance(ii._ensure_proper_substrate(data, cupy), cupy.ndarray)
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data = range(0, 255)
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assert data is not ii._ensure_proper_substrate(data, np)
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assert isinstance(ii._ensure_proper_substrate(data, np), np.ndarray)
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assert data is not ii._ensure_proper_substrate(data, cupy)
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assert isinstance(ii._ensure_proper_substrate(data, cupy), cupy.ndarray)
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finally:
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pg.setConfigOption("useCupy", prev_setting)
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def test_ImageItem(transpose=False):
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w = pg.GraphicsLayoutWidget()
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w.show()
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view = pg.ViewBox()
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w.setCentralWidget(view)
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w.resize(200, 200)
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img = TransposedImageItem(border=0.5, transpose=transpose)
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view.addItem(img)
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# test mono float
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np.random.seed(0)
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data = np.random.normal(size=(20, 20))
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dmax = data.max()
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data[:10, 1] = dmax + 10
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data[1, :10] = dmax + 12
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data[3, :10] = dmax + 13
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img.setImage(data)
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QtTest.QTest.qWaitForWindowExposed(w)
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time.sleep(0.1)
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app.processEvents()
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assertImageApproved(w, 'imageitem/init', 'Init image item. View is auto-scaled, image axis 0 marked by 1 line, axis 1 is marked by 2 lines. Origin in bottom-left.')
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# ..with colormap
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cmap = pg.ColorMap([0, 0.25, 0.75, 1], [[0, 0, 0, 255], [255, 0, 0, 255], [255, 255, 0, 255], [255, 255, 255, 255]])
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img.setLookupTable(cmap.getLookupTable())
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assertImageApproved(w, 'imageitem/lut', 'Set image LUT.')
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# ..and different levels
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img.setLevels([dmax+9, dmax+13])
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assertImageApproved(w, 'imageitem/levels1', 'Levels show only axis lines.')
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img.setLookupTable(None)
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# test mono int
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data = np.fromfunction(lambda x,y: x+y*10, (129, 128)).astype(np.int16)
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img.setImage(data)
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assertImageApproved(w, 'imageitem/gradient_mono_int', 'Mono int gradient.')
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img.setLevels([640, 641])
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assertImageApproved(w, 'imageitem/gradient_mono_int_levels', 'Mono int gradient w/ levels to isolate diagonal.')
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# test mono byte
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data = np.fromfunction(lambda x,y: x+y, (129, 128)).astype(np.ubyte)
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img.setImage(data)
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assertImageApproved(w, 'imageitem/gradient_mono_byte', 'Mono byte gradient.')
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img.setLevels([127, 128])
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assertImageApproved(w, 'imageitem/gradient_mono_byte_levels', 'Mono byte gradient w/ levels to isolate diagonal.')
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# test monochrome image
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data = np.zeros((10, 10), dtype='uint8')
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data[:5,:5] = 1
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data[5:,5:] = 1
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img.setImage(data)
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assertImageApproved(w, 'imageitem/monochrome', 'Ubyte image with only 0,1 values.')
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# test bool
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data = data.astype(bool)
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img.setImage(data)
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assertImageApproved(w, 'imageitem/bool', 'Boolean mask.')
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# test RGBA byte
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data = np.zeros((100, 100, 4), dtype='ubyte')
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data[..., 0] = np.linspace(0, 255, 100).reshape(100, 1)
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data[..., 1] = np.linspace(0, 255, 100).reshape(1, 100)
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data[..., 3] = 255
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img.setImage(data)
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assertImageApproved(w, 'imageitem/gradient_rgba_byte', 'RGBA byte gradient.')
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img.setLevels([[128, 129], [128, 255], [0, 1], [0, 255]])
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assertImageApproved(w, 'imageitem/gradient_rgba_byte_levels', 'RGBA byte gradient. Levels set to show x=128 and y>128.')
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# test RGBA float
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data = data.astype(float)
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img.setImage(data / 1e9)
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assertImageApproved(w, 'imageitem/gradient_rgba_float', 'RGBA float gradient.')
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# checkerboard to test alpha
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img2 = TransposedImageItem(transpose=transpose)
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img2.setImage(np.fromfunction(lambda x,y: (x+y)%2, (10, 10)), levels=[-1,2])
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view.addItem(img2)
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img2.setScale(10)
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img2.setZValue(-10)
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data[..., 0] *= 1e-9
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data[..., 1] *= 1e9
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data[..., 3] = np.fromfunction(lambda x,y: np.sin(0.1 * (x+y)), (100, 100))
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img.setImage(data, levels=[[0, 128e-9],[0, 128e9],[0, 1],[-1, 1]])
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assertImageApproved(w, 'imageitem/gradient_rgba_float_alpha', 'RGBA float gradient with alpha.')
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# test composition mode
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img.setCompositionMode(QtGui.QPainter.CompositionMode.CompositionMode_Plus)
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assertImageApproved(w, 'imageitem/gradient_rgba_float_additive', 'RGBA float gradient with alpha and additive composition mode.')
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img2.hide()
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img.setCompositionMode(QtGui.QPainter.CompositionMode.CompositionMode_SourceOver)
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# test downsampling
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data = np.fromfunction(lambda x,y: np.cos(0.002 * x**2), (800, 100))
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img.setImage(data, levels=[-1, 1])
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assertImageApproved(w, 'imageitem/resolution_without_downsampling', 'Resolution test without downsampling.')
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img.setAutoDownsample(True)
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assertImageApproved(w, 'imageitem/resolution_with_downsampling_x', 'Resolution test with downsampling axross x axis.')
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assert img._lastDownsample == (4, 1)
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img.setImage(data.T, levels=[-1, 1])
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assertImageApproved(w, 'imageitem/resolution_with_downsampling_y', 'Resolution test with downsampling across y axis.')
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assert img._lastDownsample == (1, 4)
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w.hide()
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def test_ImageItem_axisorder():
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# All image tests pass again using the opposite axis order
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origMode = pg.getConfigOption('imageAxisOrder')
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altMode = 'row-major' if origMode == 'col-major' else 'col-major'
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pg.setConfigOptions(imageAxisOrder=altMode)
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try:
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test_ImageItem(transpose=True)
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finally:
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pg.setConfigOptions(imageAxisOrder=origMode)
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def test_setRect():
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def assert_equal_transforms(tr1, tr2):
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dic = { # there seems to be no easy way to get the matrix in one call:
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'tr11': ( tr1.m11(), tr2.m11() ),
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'tr12': ( tr1.m12(), tr2.m12() ),
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'tr13': ( tr1.m13(), tr2.m13() ),
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'tr21': ( tr1.m21(), tr2.m21() ),
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'tr22': ( tr1.m22(), tr2.m22() ),
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'tr23': ( tr1.m23(), tr2.m23() ),
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'tr31': ( tr1.m31(), tr2.m31() ),
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'tr32': ( tr1.m32(), tr2.m32() ),
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'tr33': ( tr1.m33(), tr2.m33() )
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}
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log_string = 'Matrix element mismatch\n'
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good = True
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for key, values in dic.items():
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val1, val2 = values
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if val1 != val2:
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good = False
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log_string += f'{key}: {val1} != {val2}\n'
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assert good, log_string
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tr = QtGui.QTransform() # construct a reference transform
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tr.scale(2, 4) # scale 2x2 image to 4x8
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tr.translate(-1, -1) # after shifting by -1, -1
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# the transformed 2x2 image would cover (-2,-4) to (2,4).
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# Now have setRect construct the same transform:
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imgitem = pg.ImageItem(np.eye(2), rect=(-2,-4, 4,8) ) # test tuple of floats
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assert_equal_transforms(tr, imgitem.transform())
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imgitem = pg.ImageItem(np.eye(2), rect=QtCore.QRectF(-2,-4, 4,8) ) # test QRectF
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assert_equal_transforms(tr, imgitem.transform())
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imgitem = pg.ImageItem(np.eye(2))
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imgitem.setRect(-2,-4, 4,8) # test individual parameters
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assert_equal_transforms(tr, imgitem.transform())
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imgitem = pg.ImageItem(np.eye(2))
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imgitem.setRect(QtCore.QRect(-2,-4, 4,8)) # test QRect argument
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assert_equal_transforms(tr, imgitem.transform())
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def test_dividebyzero():
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im = pg.image(pg.np.random.normal(size=(100,100)))
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im.imageItem.setAutoDownsample(True)
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im.view.setRange(xRange=[-5+25, 5e+25],yRange=[-5e+25, 5e+25])
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app.processEvents()
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QtTest.QTest.qWait(1000)
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# must manually call im.imageItem.render here or the exception
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# will only exist on the Qt event loop
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im.imageItem.render()
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