from contextlib import ExitStack from copy import copy import io import os from pathlib import Path import platform import sys import urllib.request import warnings import numpy as np from numpy import ma from numpy.testing import assert_array_equal from matplotlib import ( colors, image as mimage, patches, pyplot as plt, style, rc_context, rcParams) from matplotlib.cbook import MatplotlibDeprecationWarning from matplotlib.image import (AxesImage, BboxImage, FigureImage, NonUniformImage, PcolorImage) from matplotlib.testing.decorators import check_figures_equal, image_comparison from matplotlib.transforms import Bbox, Affine2D, TransformedBbox import pytest @image_comparison(['image_interps'], style='mpl20') def test_image_interps(): 'make the basic nearest, bilinear and bicubic interps' # Remove this line when this test image is regenerated. plt.rcParams['text.kerning_factor'] = 6 X = np.arange(100) X = X.reshape(5, 20) fig = plt.figure() ax1 = fig.add_subplot(311) ax1.imshow(X, interpolation='nearest') ax1.set_title('three interpolations') ax1.set_ylabel('nearest') ax2 = fig.add_subplot(312) ax2.imshow(X, interpolation='bilinear') ax2.set_ylabel('bilinear') ax3 = fig.add_subplot(313) ax3.imshow(X, interpolation='bicubic') ax3.set_ylabel('bicubic') @image_comparison(['interp_alpha.png'], remove_text=True) def test_alpha_interp(): 'Test the interpolation of the alpha channel on RGBA images' fig, (axl, axr) = plt.subplots(1, 2) # full green image img = np.zeros((5, 5, 4)) img[..., 1] = np.ones((5, 5)) # transparent under main diagonal img[..., 3] = np.tril(np.ones((5, 5), dtype=np.uint8)) axl.imshow(img, interpolation="none") axr.imshow(img, interpolation="bilinear") @image_comparison(['interp_nearest_vs_none'], extensions=['pdf', 'svg'], remove_text=True) def test_interp_nearest_vs_none(): 'Test the effect of "nearest" and "none" interpolation' # Setting dpi to something really small makes the difference very # visible. This works fine with pdf, since the dpi setting doesn't # affect anything but images, but the agg output becomes unusably # small. rcParams['savefig.dpi'] = 3 X = np.array([[[218, 165, 32], [122, 103, 238]], [[127, 255, 0], [255, 99, 71]]], dtype=np.uint8) fig = plt.figure() ax1 = fig.add_subplot(121) ax1.imshow(X, interpolation='none') ax1.set_title('interpolation none') ax2 = fig.add_subplot(122) ax2.imshow(X, interpolation='nearest') ax2.set_title('interpolation nearest') def do_figimage(suppressComposite): """Helper for the next two tests.""" fig = plt.figure(figsize=(2, 2), dpi=100) fig.suppressComposite = suppressComposite x, y = np.ix_(np.arange(100) / 100.0, np.arange(100) / 100) z = np.sin(x**2 + y**2 - x*y) c = np.sin(20*x**2 + 50*y**2) img = z + c/5 fig.figimage(img, xo=0, yo=0, origin='lower') fig.figimage(img[::-1, :], xo=0, yo=100, origin='lower') fig.figimage(img[:, ::-1], xo=100, yo=0, origin='lower') fig.figimage(img[::-1, ::-1], xo=100, yo=100, origin='lower') @image_comparison(['figimage-0'], extensions=['png', 'pdf']) def test_figimage0(): suppressComposite = False do_figimage(suppressComposite) @image_comparison(['figimage-1'], extensions=['png', 'pdf']) def test_figimage1(): suppressComposite = True do_figimage(suppressComposite) def test_image_python_io(): fig, ax = plt.subplots() ax.plot([1, 2, 3]) buffer = io.BytesIO() fig.savefig(buffer) buffer.seek(0) plt.imread(buffer) @check_figures_equal(extensions=['png']) def test_imshow_subsample(fig_test, fig_ref): # data is bigger than figure, so subsampling with hanning np.random.seed(19680801) dpi = 100 A = np.random.rand(int(dpi * 5), int(dpi * 5)) for fig in [fig_test, fig_ref]: fig.set_size_inches(2, 2) axs = fig_test.subplots() axs.set_position([0, 0, 1, 1]) axs.imshow(A, interpolation='antialiased') axs = fig_ref.subplots() axs.set_position([0, 0, 1, 1]) axs.imshow(A, interpolation='hanning') @check_figures_equal(extensions=['png']) def test_imshow_samesample(fig_test, fig_ref): # exact resample, so should be same as nearest.... np.random.seed(19680801) dpi = 100 A = np.random.rand(int(dpi * 5), int(dpi * 5)) for fig in [fig_test, fig_ref]: fig.set_size_inches(5, 5) axs = fig_test.subplots() axs.set_position([0, 0, 1, 1]) axs.imshow(A, interpolation='antialiased') axs = fig_ref.subplots() axs.set_position([0, 0, 1, 1]) axs.imshow(A, interpolation='nearest') @check_figures_equal(extensions=['png']) def test_imshow_doublesample(fig_test, fig_ref): # should be exactly a double sample, so should use nearest neighbour # which is the same as "none" np.random.seed(19680801) dpi = 100 A = np.random.rand(int(dpi * 5), int(dpi * 5)) for fig in [fig_test, fig_ref]: fig.set_size_inches(10, 10) axs = fig_test.subplots() axs.set_position([0, 0, 1, 1]) axs.imshow(A, interpolation='antialiased') axs = fig_ref.subplots() axs.set_position([0, 0, 1, 1]) axs.imshow(A, interpolation='nearest') @check_figures_equal(extensions=['png']) def test_imshow_upsample(fig_test, fig_ref): # should be less than 3 upsample, so should be nearest... np.random.seed(19680801) dpi = 100 A = np.random.rand(int(dpi * 3), int(dpi * 3)) for fig in [fig_test, fig_ref]: fig.set_size_inches(2.9, 2.9) axs = fig_test.subplots() axs.set_position([0, 0, 1, 1]) axs.imshow(A, interpolation='antialiased') axs = fig_ref.subplots() axs.set_position([0, 0, 1, 1]) axs.imshow(A, interpolation='hanning') @check_figures_equal(extensions=['png']) def test_imshow_upsample3(fig_test, fig_ref): # should be greater than 3 upsample, so should be nearest... np.random.seed(19680801) dpi = 100 A = np.random.rand(int(dpi * 3), int(dpi * 3)) for fig in [fig_test, fig_ref]: fig.set_size_inches(9.1, 9.1) axs = fig_test.subplots() axs.set_position([0, 0, 1, 1]) axs.imshow(A, interpolation='antialiased') axs = fig_ref.subplots() axs.set_position([0, 0, 1, 1]) axs.imshow(A, interpolation='nearest') @check_figures_equal(extensions=['png']) def test_imshow_zoom(fig_test, fig_ref): # should be less than 3 upsample, so should be nearest... np.random.seed(19680801) dpi = 100 A = np.random.rand(int(dpi * 3), int(dpi * 3)) for fig in [fig_test, fig_ref]: fig.set_size_inches(2.9, 2.9) axs = fig_test.subplots() axs.imshow(A, interpolation='nearest') axs.set_xlim([10, 20]) axs.set_ylim([10, 20]) axs = fig_ref.subplots() axs.imshow(A, interpolation='antialiased') axs.set_xlim([10, 20]) axs.set_ylim([10, 20]) @check_figures_equal() def test_imshow_pil(fig_test, fig_ref): style.use("default") PIL = pytest.importorskip("PIL") # Pillow<=6.0 fails to open pathlib.Paths on Windows (pillow#3823), and # Matplotlib's builtin png opener doesn't handle them either. png_path = str( Path(__file__).parent / "baseline_images/pngsuite/basn3p04.png") tiff_path = str( Path(__file__).parent / "baseline_images/test_image/uint16.tif") axs = fig_test.subplots(2) axs[0].imshow(PIL.Image.open(png_path)) axs[1].imshow(PIL.Image.open(tiff_path)) axs = fig_ref.subplots(2) axs[0].imshow(plt.imread(png_path)) axs[1].imshow(plt.imread(tiff_path)) def test_imread_pil_uint16(): pytest.importorskip("PIL") img = plt.imread(os.path.join(os.path.dirname(__file__), 'baseline_images', 'test_image', 'uint16.tif')) assert img.dtype == np.uint16 assert np.sum(img) == 134184960 def test_imread_fspath(): pytest.importorskip("PIL") img = plt.imread( Path(__file__).parent / 'baseline_images/test_image/uint16.tif') assert img.dtype == np.uint16 assert np.sum(img) == 134184960 @pytest.mark.parametrize("fmt", ["png", "jpg", "jpeg", "tiff"]) def test_imsave(fmt): if fmt in ["jpg", "jpeg", "tiff"]: pytest.importorskip("PIL") has_alpha = fmt not in ["jpg", "jpeg"] # The goal here is that the user can specify an output logical DPI # for the image, but this will not actually add any extra pixels # to the image, it will merely be used for metadata purposes. # So we do the traditional case (dpi == 1), and the new case (dpi # == 100) and read the resulting PNG files back in and make sure # the data is 100% identical. np.random.seed(1) # The height of 1856 pixels was selected because going through creating an # actual dpi=100 figure to save the image to a Pillow-provided format would # cause a rounding error resulting in a final image of shape 1855. data = np.random.rand(1856, 2) buff_dpi1 = io.BytesIO() plt.imsave(buff_dpi1, data, format=fmt, dpi=1) buff_dpi100 = io.BytesIO() plt.imsave(buff_dpi100, data, format=fmt, dpi=100) buff_dpi1.seek(0) arr_dpi1 = plt.imread(buff_dpi1, format=fmt) buff_dpi100.seek(0) arr_dpi100 = plt.imread(buff_dpi100, format=fmt) assert arr_dpi1.shape == (1856, 2, 3 + has_alpha) assert arr_dpi100.shape == (1856, 2, 3 + has_alpha) assert_array_equal(arr_dpi1, arr_dpi100) @pytest.mark.parametrize("fmt", ["png", "pdf", "ps", "eps", "svg"]) def test_imsave_fspath(fmt): plt.imsave(Path(os.devnull), np.array([[0, 1]]), format=fmt) def test_imsave_color_alpha(): # Test that imsave accept arrays with ndim=3 where the third dimension is # color and alpha without raising any exceptions, and that the data is # acceptably preserved through a save/read roundtrip. np.random.seed(1) for origin in ['lower', 'upper']: data = np.random.rand(16, 16, 4) buff = io.BytesIO() plt.imsave(buff, data, origin=origin, format="png") buff.seek(0) arr_buf = plt.imread(buff) # Recreate the float -> uint8 conversion of the data # We can only expect to be the same with 8 bits of precision, # since that's what the PNG file used. data = (255*data).astype('uint8') if origin == 'lower': data = data[::-1] arr_buf = (255*arr_buf).astype('uint8') assert_array_equal(data, arr_buf) def test_imsave_pil_kwargs_png(): Image = pytest.importorskip("PIL.Image") from PIL.PngImagePlugin import PngInfo buf = io.BytesIO() pnginfo = PngInfo() pnginfo.add_text("Software", "test") plt.imsave(buf, [[0, 1], [2, 3]], format="png", pil_kwargs={"pnginfo": pnginfo}) im = Image.open(buf) assert im.info["Software"] == "test" def test_imsave_pil_kwargs_tiff(): Image = pytest.importorskip("PIL.Image") from PIL.TiffTags import TAGS_V2 as TAGS buf = io.BytesIO() pil_kwargs = {"description": "test image"} plt.imsave(buf, [[0, 1], [2, 3]], format="tiff", pil_kwargs=pil_kwargs) im = Image.open(buf) tags = {TAGS[k].name: v for k, v in im.tag_v2.items()} assert tags["ImageDescription"] == "test image" @image_comparison(['image_alpha'], remove_text=True) def test_image_alpha(): plt.figure() np.random.seed(0) Z = np.random.rand(6, 6) plt.subplot(131) plt.imshow(Z, alpha=1.0, interpolation='none') plt.subplot(132) plt.imshow(Z, alpha=0.5, interpolation='none') plt.subplot(133) plt.imshow(Z, alpha=0.5, interpolation='nearest') def test_cursor_data(): from matplotlib.backend_bases import MouseEvent fig, ax = plt.subplots() im = ax.imshow(np.arange(100).reshape(10, 10), origin='upper') x, y = 4, 4 xdisp, ydisp = ax.transData.transform([x, y]) event = MouseEvent('motion_notify_event', fig.canvas, xdisp, ydisp) assert im.get_cursor_data(event) == 44 # Now try for a point outside the image # Tests issue #4957 x, y = 10.1, 4 xdisp, ydisp = ax.transData.transform([x, y]) event = MouseEvent('motion_notify_event', fig.canvas, xdisp, ydisp) assert im.get_cursor_data(event) is None # Hmm, something is wrong here... I get 0, not None... # But, this works further down in the tests with extents flipped #x, y = 0.1, -0.1 #xdisp, ydisp = ax.transData.transform([x, y]) #event = MouseEvent('motion_notify_event', fig.canvas, xdisp, ydisp) #z = im.get_cursor_data(event) #assert z is None, "Did not get None, got %d" % z ax.clear() # Now try with the extents flipped. im = ax.imshow(np.arange(100).reshape(10, 10), origin='lower') x, y = 4, 4 xdisp, ydisp = ax.transData.transform([x, y]) event = MouseEvent('motion_notify_event', fig.canvas, xdisp, ydisp) assert im.get_cursor_data(event) == 44 fig, ax = plt.subplots() im = ax.imshow(np.arange(100).reshape(10, 10), extent=[0, 0.5, 0, 0.5]) x, y = 0.25, 0.25 xdisp, ydisp = ax.transData.transform([x, y]) event = MouseEvent('motion_notify_event', fig.canvas, xdisp, ydisp) assert im.get_cursor_data(event) == 55 # Now try for a point outside the image # Tests issue #4957 x, y = 0.75, 0.25 xdisp, ydisp = ax.transData.transform([x, y]) event = MouseEvent('motion_notify_event', fig.canvas, xdisp, ydisp) assert im.get_cursor_data(event) is None x, y = 0.01, -0.01 xdisp, ydisp = ax.transData.transform([x, y]) event = MouseEvent('motion_notify_event', fig.canvas, xdisp, ydisp) assert im.get_cursor_data(event) is None @pytest.mark.parametrize( "data, text_without_colorbar, text_with_colorbar", [ ([[10001, 10000]], "[1e+04]", "[10001]"), ([[.123, .987]], "[0.123]", "[0.123]"), ]) def test_format_cursor_data(data, text_without_colorbar, text_with_colorbar): from matplotlib.backend_bases import MouseEvent fig, ax = plt.subplots() im = ax.imshow(data) xdisp, ydisp = ax.transData.transform([0, 0]) event = MouseEvent('motion_notify_event', fig.canvas, xdisp, ydisp) assert im.get_cursor_data(event) == data[0][0] assert im.format_cursor_data(im.get_cursor_data(event)) \ == text_without_colorbar fig.colorbar(im) fig.canvas.draw() # This is necessary to set up the colorbar formatter. assert im.get_cursor_data(event) == data[0][0] assert im.format_cursor_data(im.get_cursor_data(event)) \ == text_with_colorbar @image_comparison(['image_clip'], style='mpl20') def test_image_clip(): d = [[1, 2], [3, 4]] fig, ax = plt.subplots() im = ax.imshow(d) patch = patches.Circle((0, 0), radius=1, transform=ax.transData) im.set_clip_path(patch) @image_comparison(['image_cliprect'], style='mpl20') def test_image_cliprect(): import matplotlib.patches as patches fig, ax = plt.subplots() d = [[1, 2], [3, 4]] im = ax.imshow(d, extent=(0, 5, 0, 5)) rect = patches.Rectangle( xy=(1, 1), width=2, height=2, transform=im.axes.transData) im.set_clip_path(rect) @image_comparison(['imshow'], remove_text=True, style='mpl20') def test_imshow(): fig, ax = plt.subplots() arr = np.arange(100).reshape((10, 10)) ax.imshow(arr, interpolation="bilinear", extent=(1, 2, 1, 2)) ax.set_xlim(0, 3) ax.set_ylim(0, 3) @image_comparison(['no_interpolation_origin'], remove_text=True) def test_no_interpolation_origin(): fig, axs = plt.subplots(2) axs[0].imshow(np.arange(100).reshape((2, 50)), origin="lower", interpolation='none') axs[1].imshow(np.arange(100).reshape((2, 50)), interpolation='none') @image_comparison(['image_shift'], remove_text=True, extensions=['pdf', 'svg']) def test_image_shift(): from matplotlib.colors import LogNorm imgData = [[1 / x + 1 / y for x in range(1, 100)] for y in range(1, 100)] tMin = 734717.945208 tMax = 734717.946366 fig, ax = plt.subplots() ax.imshow(imgData, norm=LogNorm(), interpolation='none', extent=(tMin, tMax, 1, 100)) ax.set_aspect('auto') def test_image_edges(): f = plt.figure(figsize=[1, 1]) ax = f.add_axes([0, 0, 1, 1], frameon=False) data = np.tile(np.arange(12), 15).reshape(20, 9) im = ax.imshow(data, origin='upper', extent=[-10, 10, -10, 10], interpolation='none', cmap='gray') x = y = 2 ax.set_xlim([-x, x]) ax.set_ylim([-y, y]) ax.set_xticks([]) ax.set_yticks([]) buf = io.BytesIO() f.savefig(buf, facecolor=(0, 1, 0)) buf.seek(0) im = plt.imread(buf) r, g, b, a = sum(im[:, 0]) r, g, b, a = sum(im[:, -1]) assert g != 100, 'Expected a non-green edge - but sadly, it was.' @image_comparison(['image_composite_background'], remove_text=True, style='mpl20') def test_image_composite_background(): fig, ax = plt.subplots() arr = np.arange(12).reshape(4, 3) ax.imshow(arr, extent=[0, 2, 15, 0]) ax.imshow(arr, extent=[4, 6, 15, 0]) ax.set_facecolor((1, 0, 0, 0.5)) ax.set_xlim([0, 12]) @image_comparison(['image_composite_alpha'], remove_text=True) def test_image_composite_alpha(): """ Tests that the alpha value is recognized and correctly applied in the process of compositing images together. """ fig, ax = plt.subplots() arr = np.zeros((11, 21, 4)) arr[:, :, 0] = 1 arr[:, :, 3] = np.concatenate( (np.arange(0, 1.1, 0.1), np.arange(0, 1, 0.1)[::-1])) arr2 = np.zeros((21, 11, 4)) arr2[:, :, 0] = 1 arr2[:, :, 1] = 1 arr2[:, :, 3] = np.concatenate( (np.arange(0, 1.1, 0.1), np.arange(0, 1, 0.1)[::-1]))[:, np.newaxis] ax.imshow(arr, extent=[1, 2, 5, 0], alpha=0.3) ax.imshow(arr, extent=[2, 3, 5, 0], alpha=0.6) ax.imshow(arr, extent=[3, 4, 5, 0]) ax.imshow(arr2, extent=[0, 5, 1, 2]) ax.imshow(arr2, extent=[0, 5, 2, 3], alpha=0.6) ax.imshow(arr2, extent=[0, 5, 3, 4], alpha=0.3) ax.set_facecolor((0, 0.5, 0, 1)) ax.set_xlim([0, 5]) ax.set_ylim([5, 0]) @image_comparison(['rasterize_10dpi'], extensions=['pdf', 'svg'], remove_text=True, style='mpl20') def test_rasterize_dpi(): # This test should check rasterized rendering with high output resolution. # It plots a rasterized line and a normal image with imshow. So it will # catch when images end up in the wrong place in case of non-standard dpi # setting. Instead of high-res rasterization I use low-res. Therefore # the fact that the resolution is non-standard is easily checked by # image_comparison. img = np.asarray([[1, 2], [3, 4]]) fig, axs = plt.subplots(1, 3, figsize=(3, 1)) axs[0].imshow(img) axs[1].plot([0, 1], [0, 1], linewidth=20., rasterized=True) axs[1].set(xlim=(0, 1), ylim=(-1, 2)) axs[2].plot([0, 1], [0, 1], linewidth=20.) axs[2].set(xlim=(0, 1), ylim=(-1, 2)) # Low-dpi PDF rasterization errors prevent proper image comparison tests. # Hide detailed structures like the axes spines. for ax in axs: ax.set_xticks([]) ax.set_yticks([]) for spine in ax.spines.values(): spine.set_visible(False) rcParams['savefig.dpi'] = 10 @image_comparison(['bbox_image_inverted'], remove_text=True, style='mpl20') def test_bbox_image_inverted(): # This is just used to produce an image to feed to BboxImage image = np.arange(100).reshape((10, 10)) fig, ax = plt.subplots() bbox_im = BboxImage( TransformedBbox(Bbox([[100, 100], [0, 0]]), ax.transData), interpolation='nearest') bbox_im.set_data(image) bbox_im.set_clip_on(False) ax.set_xlim(0, 100) ax.set_ylim(0, 100) ax.add_artist(bbox_im) image = np.identity(10) bbox_im = BboxImage(TransformedBbox(Bbox([[0.1, 0.2], [0.3, 0.25]]), ax.figure.transFigure), interpolation='nearest') bbox_im.set_data(image) bbox_im.set_clip_on(False) ax.add_artist(bbox_im) def test_get_window_extent_for_AxisImage(): # Create a figure of known size (1000x1000 pixels), place an image # object at a given location and check that get_window_extent() # returns the correct bounding box values (in pixels). im = np.array([[0.25, 0.75, 1.0, 0.75], [0.1, 0.65, 0.5, 0.4], [0.6, 0.3, 0.0, 0.2], [0.7, 0.9, 0.4, 0.6]]) fig, ax = plt.subplots(figsize=(10, 10), dpi=100) ax.set_position([0, 0, 1, 1]) ax.set_xlim(0, 1) ax.set_ylim(0, 1) im_obj = ax.imshow( im, extent=[0.4, 0.7, 0.2, 0.9], interpolation='nearest') fig.canvas.draw() renderer = fig.canvas.renderer im_bbox = im_obj.get_window_extent(renderer) assert_array_equal(im_bbox.get_points(), [[400, 200], [700, 900]]) @image_comparison(['zoom_and_clip_upper_origin.png'], remove_text=True, style='mpl20') def test_zoom_and_clip_upper_origin(): image = np.arange(100) image = image.reshape((10, 10)) fig, ax = plt.subplots() ax.imshow(image) ax.set_ylim(2.0, -0.5) ax.set_xlim(-0.5, 2.0) def test_nonuniformimage_setcmap(): ax = plt.gca() im = NonUniformImage(ax) im.set_cmap('Blues') def test_nonuniformimage_setnorm(): ax = plt.gca() im = NonUniformImage(ax) im.set_norm(plt.Normalize()) def test_jpeg_2d(): Image = pytest.importorskip('PIL.Image') # smoke test that mode-L pillow images work. imd = np.ones((10, 10), dtype='uint8') for i in range(10): imd[i, :] = np.linspace(0.0, 1.0, 10) * 255 im = Image.new('L', (10, 10)) im.putdata(imd.flatten()) fig, ax = plt.subplots() ax.imshow(im) def test_jpeg_alpha(): Image = pytest.importorskip('PIL.Image') plt.figure(figsize=(1, 1), dpi=300) # Create an image that is all black, with a gradient from 0-1 in # the alpha channel from left to right. im = np.zeros((300, 300, 4), dtype=float) im[..., 3] = np.linspace(0.0, 1.0, 300) plt.figimage(im) buff = io.BytesIO() plt.savefig(buff, facecolor="red", format='jpg', dpi=300) buff.seek(0) image = Image.open(buff) # If this fails, there will be only one color (all black). If this # is working, we should have all 256 shades of grey represented. num_colors = len(image.getcolors(256)) assert 175 <= num_colors <= 185 # The fully transparent part should be red. corner_pixel = image.getpixel((0, 0)) assert corner_pixel == (254, 0, 0) def test_nonuniformimage_setdata(): ax = plt.gca() im = NonUniformImage(ax) x = np.arange(3, dtype=float) y = np.arange(4, dtype=float) z = np.arange(12, dtype=float).reshape((4, 3)) im.set_data(x, y, z) x[0] = y[0] = z[0, 0] = 9.9 assert im._A[0, 0] == im._Ax[0] == im._Ay[0] == 0, 'value changed' def test_axesimage_setdata(): ax = plt.gca() im = AxesImage(ax) z = np.arange(12, dtype=float).reshape((4, 3)) im.set_data(z) z[0, 0] = 9.9 assert im._A[0, 0] == 0, 'value changed' def test_figureimage_setdata(): fig = plt.gcf() im = FigureImage(fig) z = np.arange(12, dtype=float).reshape((4, 3)) im.set_data(z) z[0, 0] = 9.9 assert im._A[0, 0] == 0, 'value changed' def test_pcolorimage_setdata(): ax = plt.gca() im = PcolorImage(ax) x = np.arange(3, dtype=float) y = np.arange(4, dtype=float) z = np.arange(6, dtype=float).reshape((3, 2)) im.set_data(x, y, z) x[0] = y[0] = z[0, 0] = 9.9 assert im._A[0, 0] == im._Ax[0] == im._Ay[0] == 0, 'value changed' def test_minimized_rasterized(): # This ensures that the rasterized content in the colorbars is # only as thick as the colorbar, and doesn't extend to other parts # of the image. See #5814. While the original bug exists only # in Postscript, the best way to detect it is to generate SVG # and then parse the output to make sure the two colorbar images # are the same size. from xml.etree import ElementTree np.random.seed(0) data = np.random.rand(10, 10) fig, ax = plt.subplots(1, 2) p1 = ax[0].pcolormesh(data) p2 = ax[1].pcolormesh(data) plt.colorbar(p1, ax=ax[0]) plt.colorbar(p2, ax=ax[1]) buff = io.BytesIO() plt.savefig(buff, format='svg') buff = io.BytesIO(buff.getvalue()) tree = ElementTree.parse(buff) width = None for image in tree.iter('image'): if width is None: width = image['width'] else: if image['width'] != width: assert False def test_load_from_url(): path = Path(__file__).parent / "baseline_images/test_image/imshow.png" url = ('file:' + ('///' if sys.platform == 'win32' else '') + path.resolve().as_posix()) plt.imread(url) plt.imread(urllib.request.urlopen(url)) @image_comparison(['log_scale_image'], remove_text=True) def test_log_scale_image(): Z = np.zeros((10, 10)) Z[::2] = 1 fig, ax = plt.subplots() ax.imshow(Z, extent=[1, 100, 1, 100], cmap='viridis', vmax=1, vmin=-1, aspect='auto') ax.set(yscale='log') @image_comparison(['rotate_image'], remove_text=True) def test_rotate_image(): delta = 0.25 x = y = np.arange(-3.0, 3.0, delta) X, Y = np.meshgrid(x, y) Z1 = np.exp(-(X**2 + Y**2) / 2) / (2 * np.pi) Z2 = (np.exp(-(((X - 1) / 1.5)**2 + ((Y - 1) / 0.5)**2) / 2) / (2 * np.pi * 0.5 * 1.5)) Z = Z2 - Z1 # difference of Gaussians fig, ax1 = plt.subplots(1, 1) im1 = ax1.imshow(Z, interpolation='none', cmap='viridis', origin='lower', extent=[-2, 4, -3, 2], clip_on=True) trans_data2 = Affine2D().rotate_deg(30) + ax1.transData im1.set_transform(trans_data2) # display intended extent of the image x1, x2, y1, y2 = im1.get_extent() ax1.plot([x1, x2, x2, x1, x1], [y1, y1, y2, y2, y1], "r--", lw=3, transform=trans_data2) ax1.set_xlim(2, 5) ax1.set_ylim(0, 4) def test_image_preserve_size(): buff = io.BytesIO() im = np.zeros((481, 321)) plt.imsave(buff, im, format="png") buff.seek(0) img = plt.imread(buff) assert img.shape[:2] == im.shape def test_image_preserve_size2(): n = 7 data = np.identity(n, float) fig = plt.figure(figsize=(n, n), frameon=False) ax = plt.Axes(fig, [0.0, 0.0, 1.0, 1.0]) ax.set_axis_off() fig.add_axes(ax) ax.imshow(data, interpolation='nearest', origin='lower', aspect='auto') buff = io.BytesIO() fig.savefig(buff, dpi=1) buff.seek(0) img = plt.imread(buff) assert img.shape == (7, 7, 4) assert_array_equal(np.asarray(img[:, :, 0], bool), np.identity(n, bool)[::-1]) @image_comparison(['mask_image_over_under.png'], remove_text=True) def test_mask_image_over_under(): delta = 0.025 x = y = np.arange(-3.0, 3.0, delta) X, Y = np.meshgrid(x, y) Z1 = np.exp(-(X**2 + Y**2) / 2) / (2 * np.pi) Z2 = (np.exp(-(((X - 1) / 1.5)**2 + ((Y - 1) / 0.5)**2) / 2) / (2 * np.pi * 0.5 * 1.5)) Z = 10*(Z2 - Z1) # difference of Gaussians palette = copy(plt.cm.gray) palette.set_over('r', 1.0) palette.set_under('g', 1.0) palette.set_bad('b', 1.0) Zm = ma.masked_where(Z > 1.2, Z) fig, (ax1, ax2) = plt.subplots(1, 2) im = ax1.imshow(Zm, interpolation='bilinear', cmap=palette, norm=colors.Normalize(vmin=-1.0, vmax=1.0, clip=False), origin='lower', extent=[-3, 3, -3, 3]) ax1.set_title('Green=low, Red=high, Blue=bad') fig.colorbar(im, extend='both', orientation='horizontal', ax=ax1, aspect=10) im = ax2.imshow(Zm, interpolation='nearest', cmap=palette, norm=colors.BoundaryNorm([-1, -0.5, -0.2, 0, 0.2, 0.5, 1], ncolors=256, clip=False), origin='lower', extent=[-3, 3, -3, 3]) ax2.set_title('With BoundaryNorm') fig.colorbar(im, extend='both', spacing='proportional', orientation='horizontal', ax=ax2, aspect=10) @image_comparison(['mask_image'], remove_text=True) def test_mask_image(): # Test mask image two ways: Using nans and using a masked array. fig, (ax1, ax2) = plt.subplots(1, 2) A = np.ones((5, 5)) A[1:2, 1:2] = np.nan ax1.imshow(A, interpolation='nearest') A = np.zeros((5, 5), dtype=bool) A[1:2, 1:2] = True A = np.ma.masked_array(np.ones((5, 5), dtype=np.uint16), A) ax2.imshow(A, interpolation='nearest') @image_comparison(['imshow_endianess.png'], remove_text=True) def test_imshow_endianess(): x = np.arange(10) X, Y = np.meshgrid(x, x) Z = np.hypot(X - 5, Y - 5) fig, (ax1, ax2) = plt.subplots(1, 2) kwargs = dict(origin="lower", interpolation='nearest', cmap='viridis') ax1.imshow(Z.astype('f8'), **kwargs) @image_comparison(['imshow_masked_interpolation'], tol={'aarch64': 0.02}.get(platform.machine(), 0.0), remove_text=True, style='mpl20') def test_imshow_masked_interpolation(): cm = copy(plt.get_cmap('viridis')) cm.set_over('r') cm.set_under('b') cm.set_bad('k') N = 20 n = colors.Normalize(vmin=0, vmax=N*N-1) data = np.arange(N*N, dtype='float').reshape(N, N) data[5, 5] = -1 # This will cause crazy ringing for the higher-order # interpolations data[15, 5] = 1e5 # data[3, 3] = np.nan data[15, 15] = np.inf mask = np.zeros_like(data).astype('bool') mask[5, 15] = True data = np.ma.masked_array(data, mask) fig, ax_grid = plt.subplots(3, 6) interps = sorted(mimage._interpd_) interps.remove('antialiased') for interp, ax in zip(interps, ax_grid.ravel()): ax.set_title(interp) ax.imshow(data, norm=n, cmap=cm, interpolation=interp) ax.axis('off') def test_imshow_no_warn_invalid(): with warnings.catch_warnings(record=True) as warns: warnings.simplefilter("always") plt.imshow([[1, 2], [3, np.nan]]) assert len(warns) == 0 @pytest.mark.parametrize( 'dtype', [np.dtype(s) for s in 'u2 u4 i2 i4 i8 f4 f8'.split()]) def test_imshow_clips_rgb_to_valid_range(dtype): arr = np.arange(300, dtype=dtype).reshape((10, 10, 3)) if dtype.kind != 'u': arr -= 10 too_low = arr < 0 too_high = arr > 255 if dtype.kind == 'f': arr = arr / 255 _, ax = plt.subplots() out = ax.imshow(arr).get_array() assert (out[too_low] == 0).all() if dtype.kind == 'f': assert (out[too_high] == 1).all() assert out.dtype.kind == 'f' else: assert (out[too_high] == 255).all() assert out.dtype == np.uint8 @image_comparison(['imshow_flatfield.png'], remove_text=True, style='mpl20') def test_imshow_flatfield(): fig, ax = plt.subplots() im = ax.imshow(np.ones((5, 5)), interpolation='nearest') im.set_clim(.5, 1.5) @image_comparison(['imshow_bignumbers.png'], remove_text=True, style='mpl20') def test_imshow_bignumbers(): rcParams['image.interpolation'] = 'nearest' # putting a big number in an array of integers shouldn't # ruin the dynamic range of the resolved bits. fig, ax = plt.subplots() img = np.array([[1, 2, 1e12], [3, 1, 4]], dtype=np.uint64) pc = ax.imshow(img) pc.set_clim(0, 5) @image_comparison(['imshow_bignumbers_real.png'], remove_text=True, style='mpl20') def test_imshow_bignumbers_real(): rcParams['image.interpolation'] = 'nearest' # putting a big number in an array of integers shouldn't # ruin the dynamic range of the resolved bits. fig, ax = plt.subplots() img = np.array([[2., 1., 1.e22], [4., 1., 3.]]) pc = ax.imshow(img) pc.set_clim(0, 5) @pytest.mark.parametrize( "make_norm", [colors.Normalize, colors.LogNorm, lambda: colors.SymLogNorm(1), lambda: colors.PowerNorm(1)]) def test_empty_imshow(make_norm): fig, ax = plt.subplots() with pytest.warns(UserWarning, match="Attempting to set identical left == right"): im = ax.imshow([[]], norm=make_norm()) im.set_extent([-5, 5, -5, 5]) fig.canvas.draw() with pytest.raises(RuntimeError): im.make_image(fig._cachedRenderer) def test_imshow_float128(): fig, ax = plt.subplots() ax.imshow(np.zeros((3, 3), dtype=np.longdouble)) with (ExitStack() if np.can_cast(np.longdouble, np.float64, "equiv") else pytest.warns(UserWarning)): # Ensure that drawing doesn't cause crash. fig.canvas.draw() def test_imshow_bool(): fig, ax = plt.subplots() ax.imshow(np.array([[True, False], [False, True]], dtype=bool)) def test_full_invalid(): fig, ax = plt.subplots() ax.imshow(np.full((10, 10), np.nan)) with pytest.warns(UserWarning): fig.canvas.draw() @pytest.mark.parametrize("fmt,counted", [("ps", b" colorimage"), ("svg", b"