def test_get_2dline_from_pts():
    print('check normal line')
    pts1 = [0, 1, 1]
    pts2 = [1, 0, 1]
    line = get_2dline_from_pts(pts1, pts2)
    assert CHECK_EQ_NUMPY(line, np.array([1, 1, -1]).reshape((3, 1)))

    print('check vertical line')
    pts1 = [1, 1, 1]
    pts2 = [1, 12, 1]
    line = get_2dline_from_pts(pts1, pts2)
    assert CHECK_EQ_NUMPY(line, np.array([-11, 0, 11]).reshape((3, 1)))

    print('check horizontal line')
    pts1 = [20, 0, 1]
    pts2 = [1, 0, 1]
    line = get_2dline_from_pts(pts1, pts2)
    assert CHECK_EQ_NUMPY(line, np.array([0, -19, 0]).reshape((3, 1)))

    print('check a point at infinity')
    pts1 = [0, 3, 0]
    pts2 = [1, 0, 1]
    line = get_2dline_from_pts(pts1, pts2)
    assert CHECK_EQ_NUMPY(line, np.array([3, 0, -3]).reshape((3, 1)))

    print('check line at infinity')
    pts1 = [0, 3, 0]
    pts2 = [1, 0, 0]
    line = get_2dline_from_pts(pts1, pts2)
    assert CHECK_EQ_NUMPY(line, np.array([0, 0, -3]).reshape((3, 1)))

    print('\n\nDONE! SUCCESSFUL!!\n')
def test_data_normalize():
    print('testing 1-d data with data range')
    random_data = [1, 2, 3, 4, 6]
    normalized_data = data_normalize(random_data)
    assert CHECK_EQ_NUMPY(normalized_data, np.array([0, 0.2, 0.4, 0.6, 1]))

    print('testing 1-d data with given data range')
    random_data = [1, 2, 3, 4, 6]
    normalized_data = data_normalize(random_data, data_range=(0, 100))
    assert CHECK_EQ_NUMPY(normalized_data,
                          np.array([0.01, 0.02, 0.03, 0.04, 0.06]))

    print('testing 3-d data with data range')
    random_data = np.random.rand(2, 3, 4) * 100
    normalized_data = data_normalize(random_data)
    assert np.max(normalized_data) == 1 and np.min(normalized_data) == 0

    print('testing 1-d data with sum to 1')
    random_data = [1, 2, 3, 4, 6]
    normalized_data = data_normalize(random_data, method='sum')
    assert np.sum(normalized_data) == 1

    print('testing 3-d data with sum to a value')
    random_data = np.random.rand(2, 3, 4) * 100
    normalized_data = data_normalize(random_data, method='sum', sum=100)
    assert_almost_equal(np.sum(normalized_data), 100)
    assert normalized_data.shape == random_data.shape

    print('\n\nDONE! SUCCESSFUL!!\n')
Пример #3
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def test_image_find_peaks():
    print('test two points')
    input_pts = [[300, 400, 1], [300, 500, 1]]
    image_size = [800, 600]
    std = 50
    heatmap, _, _ = generate_gaussian_heatmap(input_pts,
                                              image_size=image_size,
                                              std=std)
    img = 1 - heatmap[:, :, -1]
    visualize_image(img, vis=True)
    peak_array, peak_global = image_find_peaks(img)
    CHECK_EQ_NUMPY(peak_array, np.array(input_pts).transpose())
    visualize_image_with_pts(img, peak_array, vis=True)
    CHECK_EQ_NUMPY(peak_global, np.array([300, 400, 1]).reshape((3, 1)))

    print('test five points')
    input_pts = [[300, 350, 1], [300, 400, 1], [200, 350, 1], [280, 320, 1],
                 [330, 270, 1]]
    image_size = [800, 600]
    std = 50
    heatmap, _, _ = generate_gaussian_heatmap(input_pts,
                                              image_size=image_size,
                                              std=std)
    img = 1 - heatmap[:, :, -1]
    visualize_image(img, vis=True)
    peak_array, peak_global = image_find_peaks(img)
    CHECK_EQ_NUMPY(peak_array, np.array(input_pts).transpose())
    visualize_image_with_pts(img, peak_array, vis=True)

    print('\n\nDONE! SUCCESSFUL!!\n')
Пример #4
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def test_safe_npdata():
    print('test list with multiple values')
    data = [1, 2, 3]
    data_bak = copy.copy(data)
    npdata = safe_npdata(data)
    assert CHECK_EQ_NUMPY(npdata, np.array(data))
    npdata += 100
    assert CHECK_EQ_LIST_ORDERED(data, data_bak)

    print('test list with single value')
    data = [1]
    npdata = safe_npdata(data)
    assert CHECK_EQ_NUMPY(npdata, np.array(data))

    print('test scalar')
    data = 10
    npdata = safe_npdata(data)
    assert CHECK_EQ_NUMPY(npdata, np.array(data))

    ######################################## test failure cases
    print('test edge case: tuple')
    data = (1, 2)
    try:
        npdata = safe_npdata(data)
        sys.exit('\nwrong! never should be here\n\n')
    except TypeError:
        print('the input should never be a tuple')

    print('\n\nDONE! SUCCESSFUL!!\n')
Пример #5
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def test_safe_bbox():
    print('test single list')
    bbox = [1, 2, 3, 4]
    good_bbox = safe_bbox(bbox)
    print(good_bbox)
    print(good_bbox.shape)
    assert CHECK_EQ_NUMPY(good_bbox, np.array(bbox).reshape((1, 4)))

    print('test list of list of 4 elements')
    bbox = [[1, 2, 3, 4], [5, 6, 7, 8]]
    good_bbox = safe_bbox(bbox)
    print(good_bbox)
    print(good_bbox.shape)
    assert CHECK_EQ_NUMPY(good_bbox, np.array(bbox).reshape((2, 4)))

    print('test (4, ) numpy array')
    bbox = np.array([1, 2, 3, 4])
    good_bbox = safe_bbox(bbox)
    print(bbox.shape)
    print(good_bbox.shape)
    assert CHECK_EQ_NUMPY(good_bbox, np.array(bbox).reshape((1, 4)))

    print('test (N, 4) numpy array')
    bbox = np.random.rand(10, 4)
    good_bbox = safe_bbox(bbox)
    print(bbox.shape)
    print(good_bbox.shape)
    assert CHECK_EQ_NUMPY(good_bbox, bbox)

    ######################################## test failure cases
    bbox = [1, 2, 4]
    try:
        good_bbox = safe_bbox(bbox)
        sys.exit('\nwrong! never should be here\n\n')
    except AssertionError:
        print('the length of list should be 4')

    bbox = [[1, 2, 4], [5, 7, 8]]
    try:
        good_bbox = safe_bbox(bbox)
        sys.exit('\nwrong! never should be here\n\n')
    except AssertionError:
        print('the length of list should be 4')

    bbox = np.array([1, 2, 4]).reshape(3, )
    try:
        good_bbox = safe_bbox(bbox)
        sys.exit('\nwrong! never should be here\n\n')
    except AssertionError:
        print('the numpy array should be columns of 4')

    bbox = np.array([[1, 2, 4], [5, 7, 8]])
    try:
        good_bbox = safe_bbox(bbox)
        sys.exit('\nwrong! never should be here\n\n')
    except AssertionError:
        print('the numpy array should be columns of 4')

    print('\n\nDONE! SUCCESSFUL!!\n')
Пример #6
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def test_get_2dpts_from_lines():
	print('check normal point')
	line1 = [1, 1, -2]
	line2 = [1, -1, 0]
	pts = get_2dpts_from_lines(line1, line2)
	assert CHECK_EQ_NUMPY(pts, np.array([-2, -2, -2]).reshape((3, 1)))
	
	print('check vertical and horizontal line')
	line1 = [1, 0, -1]
	line2 = [0, 1, -1]
	pts = get_2dpts_from_lines(line1, line2)
	assert CHECK_EQ_NUMPY(pts, np.array([1, 1, 1]).reshape((3, 1)))

	print('\n\nDONE! SUCCESSFUL!!\n')
def test_image_draw_mask():
    # mask = '../rainbow.jpg'
    mask = '/home/xinshuo/Dropbox/test7.png'
    mask = Image.open(mask).convert('RGB')
    # mask = image_resize(mask, target_size=(500, 500))
    mask = image_resize(mask, target_size=(1148, 749))
    visualize_image(mask, vis=True)
    # image_path = '../lena.png'
    image_path = '/home/xinshuo/test8.png'

    print('test with pil image')
    img = Image.open(image_path).convert('RGB')
    img = image_resize(img, target_size=(1148, 749))
    print(img.shape)
    print(mask.shape)
    masked_img = image_draw_mask(img, mask, transparency=0.5)
    # visualize_image(img, vis=True)
    # visualize_image(masked_img, vis=True)
    save_image(masked_img, save_path='7716_new.png')

    print('test with numpy image with different transparency')
    img = np.array(
        Image.open(image_path).convert('RGB')).astype('float32') / 255.
    img_bak = img.copy()
    masked_img = image_draw_mask(image_resize(img, target_size=(500, 500)),
                                 mask,
                                 transparency=0.9)
    visualize_image(img, vis=True)
    visualize_image(masked_img, vis=True)
    masked_img += 1
    assert CHECK_EQ_NUMPY(
        img_bak,
        img), 'the original image should be equal to the backup version'

    print('\n\nDONE! SUCCESSFUL!!\n')
Пример #8
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def test_image_draw_mask():
    mask = '../rainbow.jpg'
    mask = Image.open(mask).convert('RGB')
    mask = image_resize(mask, target_size=(500, 500))
    visualize_image(mask, vis=True)
    image_path = '../lena.png'

    print('test with pil image')
    img = Image.open(image_path).convert('RGB')
    masked_img = image_draw_mask(image_resize(img, target_size=(500, 500)),
                                 mask)
    visualize_image(img, vis=True)
    visualize_image(masked_img, vis=True)

    print('test with numpy image with different transparency')
    img = np.array(
        Image.open(image_path).convert('RGB')).astype('float32') / 255.
    img_bak = img.copy()
    masked_img = image_draw_mask(image_resize(img, target_size=(500, 500)),
                                 mask,
                                 transparency=0.9)
    visualize_image(img, vis=True)
    visualize_image(masked_img, vis=True)
    masked_img += 1
    assert CHECK_EQ_NUMPY(
        img_bak,
        img), 'the original image should be equal to the backup version'

    print('\n\nDONE! SUCCESSFUL!!\n')
Пример #9
0
def test_pts_euclidean():
	print('check single list')
	pts1 = [0, 1]
	pts2 = [3, 5]
	dist, dist_list = pts_euclidean(pts1, pts2)
	assert CHECK_EQ_LIST_ORDERED(pts1, [0, 1])
	assert CHECK_EQ_LIST_ORDERED(pts2, [3, 5])
	assert dist == 5
	assert dist_list == [5]
	
	print('check list of list of 2 elements')
	pts1 = [[0, 1], [1, 1], [1, 4], [0, 0]]
	pts2 = [[3, 5], [4, 5], [6, 16], [1, 0]]
	dist, dist_list = pts_euclidean(pts1, pts2)
	assert CHECK_EQ_LIST_ORDERED(pts1, [[0, 1], [1, 1], [1, 4], [0, 0]])
	assert CHECK_EQ_LIST_ORDERED(pts2, [[3, 5], [4, 5], [6, 16], [1, 0]])
	assert dist == 6
	assert dist_list == [5, 5, 13, 1]

	print('check numpy array with 2 elements')
	pts1 = np.array([0, 1])
	pts2 = np.array([3, 5])
	dist, dist_list = pts_euclidean(pts1, pts2)
	assert CHECK_EQ_NUMPY(pts1, np.array([0, 1]))
	assert CHECK_EQ_NUMPY(pts2, np.array([3, 5]))
	assert dist == 5
	assert dist_list == [5]
	
	print('check numpy array with rows of 2 elements')
	pts1 = np.array([[0, 1], [1, 1], [1, 4], [0, 0]]).transpose()
	pts2 = np.array([[3, 5], [4, 5], [6, 16], [1, 0]]).transpose()
	print(pts1.shape)
	dist, dist_list = pts_euclidean(pts1, pts2)
	assert CHECK_EQ_NUMPY(pts1, np.array([[0, 1], [1, 1], [1, 4], [0, 0]]).transpose())
	assert CHECK_EQ_NUMPY(pts2, np.array([[3, 5], [4, 5], [6, 16], [1, 0]]).transpose())
	assert dist == 6
	assert dist_list == [5, 5, 13, 1]

	######################################## test edge cases
	print('check numpy array with rows of 2 elements')
	pts1 = np.random.rand(2, 0)
	pts2 = np.random.rand(2, 0)
	dist, dist_list = pts_euclidean(pts1, pts2)
	assert dist == 0
	assert dist_list == []	

	print('\n\nDONE! SUCCESSFUL!!\n')
def test_get_center_crop_bbox():
    print('check basic')
    bbox = [1, 1, 10, 10]
    crop_bbox = get_center_crop_bbox(bbox)
    print(bbox)
    print(crop_bbox)
    assert CHECK_EQ_NUMPY(crop_bbox,
                          np.array([-4, -4, 10, 10]).reshape((1, 4)))

    print('\n\nDONE! SUCCESSFUL!!\n')
Пример #11
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def test_safe_image():
    image_path = '../lena.jpg'

    # test when the input image is pil image
    img_pil = Image.open(image_path)
    img_bak = np.array(img_pil).copy()
    copy_image, isnan = safe_image(img_pil)
    assert CHECK_EQ_NUMPY(
        copy_image,
        np.asarray(img_pil)), 'the original image should be equal to the copy'
    copy_image += 1
    assert not CHECK_EQ_NUMPY(
        copy_image,
        np.asarray(img_pil)), 'the original image should be equal to the copy'
    assert CHECK_EQ_NUMPY(img_bak, np.asarray(
        img_pil)), 'the original image should be equal to the backup version'
    assert not isnan

    # test when the input image is a numpy image
    img_numpy = np.asarray(img_pil)  # read only
    img_bak = img_numpy.copy()
    copy_image, isnan = safe_image(img_numpy)
    assert CHECK_EQ_NUMPY(
        copy_image,
        img_numpy), 'the original image should be equal to the copy'
    copy_image += 1
    assert not CHECK_EQ_NUMPY(
        copy_image,
        img_numpy), 'the original image should be equal to the copy'
    assert CHECK_EQ_NUMPY(
        img_bak,
        img_numpy), 'the original image should be equal to the backup version'
    assert not isnan

    print('\n\nDONE! SUCCESSFUL!!\n')
Пример #12
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def test_image_mean():
    print('test HWC with gray image')
    img = (np.random.rand(4, 4, 1) * 255.).astype('uint8')
    img_bak = img.copy()
    mean_img = image_mean(img)
    assert mean_img.shape == (4, 4, 1)
    assert CHECK_EQ_NUMPY(
        mean_img, img), 'the original image should be equal to the copy'
    mean_img += 1
    assert not CHECK_EQ_NUMPY(
        mean_img, img), 'the original image should be equal to the copy'
    assert CHECK_EQ_NUMPY(
        img_bak,
        img), 'the original image should be equal to the backup version'

    print('test NHWC with color images')
    img = (np.random.rand(12, 4, 4, 3) * 255.).astype('uint8')
    img_bak = img.copy()
    mean_img = image_mean(img)
    assert mean_img.shape == (4, 4, 3)
    assert CHECK_EQ_NUMPY(
        mean_img,
        np.mean(img, axis=0).astype(
            'uint8')), 'the original image should be equal to the copy'
    mean_img += 1
    assert not CHECK_EQ_NUMPY(
        mean_img,
        np.mean(img, axis=0).astype(
            'uint8')), 'the original image should be equal to the copy'
    assert CHECK_EQ_NUMPY(
        img_bak,
        img), 'the original image should be equal to the backup version'

    print('\n\nDONE! SUCCESSFUL!!\n')
Пример #13
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def test_bbox_TLBR2TLWH():
    print('check basic')
    bbox = [1, 1, 10, 10]
    clipped = bbox_TLBR2TLWH(bbox)
    print(clipped)
    assert CHECK_EQ_NUMPY(clipped, np.array([1, 1, 9, 9]).reshape((1, 4)))

    print('check out of boundary and 0 height')
    bbox = [-1, 3, 20, 3]
    clipped = bbox_TLBR2TLWH(bbox)
    print(clipped)
    assert CHECK_EQ_NUMPY(clipped, np.array([-1, 3, 21, 0]).reshape((1, 4)))

    print('check 0 height and width')
    bbox = [10, 30, 10, 30]
    clipped = bbox_TLBR2TLWH(bbox)
    print(clipped)
    assert CHECK_EQ_NUMPY(clipped, np.array([10, 30, 0, 0]).reshape((1, 4)))

    print('check multi bboxes')
    bbox = np.array([[10, 30, 10, 30], [-1, 3, 20, 3]])
    clipped = bbox_TLBR2TLWH(bbox)
    print(clipped)
    assert CHECK_EQ_NUMPY(
        clipped,
        np.array([[10, 30, 0, 0], [-1, 3, 21, 0]]).reshape((2, 4)))

    print('check x2 < x1')
    bbox = [10, 30, 9, 29]
    try:
        clipped = bbox_TLBR2TLWH(bbox)
        sys.exit('\nwrong! never should be here\n\n')
    except AssertionError:
        print(
            'the bottom right point coordinate should be no less than the top left one'
        )

    print('\n\nDONE! SUCCESSFUL!!\n')
Пример #14
0
def test_bbox_TLWH2TLBR():
    print('check basic')
    bbox = [1, 1, 10, 10]
    clipped = bbox_TLWH2TLBR(bbox)
    print(clipped)
    assert CHECK_EQ_NUMPY(clipped, np.array([1, 1, 11, 11]).reshape((1, 4)))

    print('check out of boundary and 0 height')
    bbox = [-1, 3, 20, 0]
    clipped = bbox_TLWH2TLBR(bbox)
    print(clipped)
    assert CHECK_EQ_NUMPY(clipped, np.array([-1, 3, 19, 3]).reshape((1, 4)))

    print('check 0 height and width')
    bbox = [10, 30, 0, 0]
    clipped = bbox_TLWH2TLBR(bbox)
    print(clipped)
    assert CHECK_EQ_NUMPY(clipped, np.array([10, 30, 10, 30]).reshape((1, 4)))

    print('check multi bboxes')
    bbox = np.array([[10, 30, 0, 0], [-1, 3, 20, 0]])
    clipped = bbox_TLWH2TLBR(bbox)
    print(clipped)
    assert CHECK_EQ_NUMPY(
        clipped,
        np.array([[10, 30, 10, 30], [-1, 3, 19, 3]]).reshape((2, 4)))

    print('check width < 0')
    bbox = [10, 30, -1, 29]
    try:
        clipped = bbox_TLWH2TLBR(bbox)
        sys.exit('\nwrong! never should be here\n\n')
    except AssertionError:
        print('the width should be no less than 0')

    print('\n\nDONE! SUCCESSFUL!!\n')
Пример #15
0
def test_safe_batch_deep_image():
    print('test 3HW')
    img = np.random.rand(3, 100, 100)
    img_bak = img.copy()
    batch_image, isnan = safe_batch_deep_image(img)
    assert CHECK_EQ_NUMPY(batch_image, img.reshape(
        (1, 3, 100, 100))), 'the original image should be equal to the copy'
    batch_image += 1
    assert not CHECK_EQ_NUMPY(batch_image, img.reshape(
        (1, 3, 100, 100))), 'the original image should be equal to the copy'
    assert CHECK_EQ_NUMPY(
        img_bak,
        img), 'the original image should be equal to the backup version'
    assert not isnan

    print('test N3HW')
    img = np.random.rand(12, 3, 100, 100)
    img_bak = img.copy()
    batch_image, isnan = safe_batch_deep_image(img)
    assert CHECK_EQ_NUMPY(
        batch_image, img), 'the original image should be equal to the copy'
    batch_image += 1
    assert not CHECK_EQ_NUMPY(
        batch_image, img), 'the original image should be equal to the copy'
    assert CHECK_EQ_NUMPY(
        img_bak,
        img), 'the original image should be equal to the backup version'
    assert not isnan

    ######################################## test failure cases
    print('test N1HW')
    img = np.random.rand(12, 1, 100, 100)
    try:
        batch_image, isnan = safe_batch_deep_image(img)
        sys.exit('\nwrong! never should be here\n\n')
    except AssertionError:
        print('the batch image has wrong shape')

    print('test 1HW')
    img = np.random.rand(1, 100, 100)
    try:
        batch_image, isnan = safe_batch_deep_image(img)
        sys.exit('\nwrong! never should be here\n\n')
    except AssertionError:
        print('the batch image has wrong shape')

    print('\n\nDONE! SUCCESSFUL!!\n')
Пример #16
0
def test_unpreprocess_batch_deep_image():
    print('test HW3, no rgb2bgr')
    img = (np.random.rand(100, 200, 3) * 255.).astype('uint8')
    img_bak = img.copy()
    batch_image = preprocess_batch_deep_image(img, rgb2bgr=False)
    img_inv = unpreprocess_batch_deep_image(batch_image, bgr2rgb=False)
    assert img_inv.shape == (1, 100, 200, 3)
    assert CHECK_EQ_NUMPY(
        img, img_inv[0]), 'the original image should be equal to the copy'
    assert CHECK_EQ_NUMPY(
        img_bak,
        img), 'the original image should be equal to the backup version'

    print('test NHW3, no rgb2bgr')
    img = (np.random.rand(12, 100, 200, 3) * 255.).astype('uint8')
    img_bak = img.copy()
    batch_image = preprocess_batch_deep_image(img, rgb2bgr=False)
    img_inv = unpreprocess_batch_deep_image(batch_image, bgr2rgb=False)
    assert img_inv.shape == (12, 100, 200, 3)
    assert CHECK_EQ_NUMPY(
        img, img_inv), 'the original image should be equal to the copy'
    assert CHECK_EQ_NUMPY(
        img_bak,
        img), 'the original image should be equal to the backup version'

    print('test HW3, with rgb2bgr')
    img = (np.random.rand(100, 200, 3) * 255.).astype('uint8')
    img_bak = img.copy()
    batch_image = preprocess_batch_deep_image(img)
    img_inv = unpreprocess_batch_deep_image(batch_image)
    assert img_inv.shape == (1, 100, 200, 3)
    assert CHECK_EQ_NUMPY(
        img, img_inv[0]), 'the original image should be equal to the copy'
    assert CHECK_EQ_NUMPY(
        img_bak,
        img), 'the original image should be equal to the backup version'

    print('test HW3, with rgb2bgr, pixel mean and std')
    img = (np.random.rand(12, 100, 200, 3) * 255.).astype('uint8')
    pixel_mean = [0.3, 0.4, 0.5]
    pixel_std = [0.3, 0.5, 0.7]
    batch_image = preprocess_batch_deep_image(img,
                                              pixel_mean=pixel_mean,
                                              pixel_std=pixel_std)
    img_inv = unpreprocess_batch_deep_image(batch_image,
                                            pixel_mean=pixel_mean,
                                            pixel_std=pixel_std)
    assert img_inv.shape == (12, 100, 200, 3)
    img_diff = img_inv - img
    assert not (np.logical_and(img_diff != 0,
                               np.absolute(img_diff) != 255)).any()

    print('test HW3, with rgb2bgr, single pixel mean and std')
    img = (np.random.rand(12, 100, 200, 3) * 255.).astype('uint8')
    pixel_mean = 0.4
    pixel_std = 0.5
    batch_image = preprocess_batch_deep_image(img,
                                              pixel_mean=pixel_mean,
                                              pixel_std=pixel_std)
    img_inv = unpreprocess_batch_deep_image(batch_image,
                                            pixel_mean=pixel_mean,
                                            pixel_std=pixel_std)
    assert img_inv.shape == (12, 100, 200, 3)
    img_diff = img_inv - img
    assert not (np.logical_and(img_diff != 0,
                               np.absolute(img_diff) != 255)).any()

    print('\n\nDONE! SUCCESSFUL!!\n')
Пример #17
0
def test_clip_bboxes_TLBR():
    print('check basic')
    bbox = [1, 1, 10, 10]
    clipped = clip_bboxes_TLBR(bbox, 5, 5)
    print(clipped)
    assert CHECK_EQ_NUMPY(clipped, np.array([1, 1, 5, 5]).reshape((1, 4)))

    print('check top left intersected')
    bbox = [-1, -1, 3, 3]
    clipped = clip_bboxes_TLBR(bbox, 5, 5)
    print(clipped)
    assert CHECK_EQ_NUMPY(clipped, np.array([0, 0, 3, 3]).reshape((1, 4)))

    print('check bottom right intersected')
    bbox = [2, 3, 10, 30]
    clipped = clip_bboxes_TLBR(bbox, 5, 5)
    print(clipped)
    assert CHECK_EQ_NUMPY(clipped, np.array([2, 3, 5, 5]).reshape((1, 4)))

    print('check left intersected')
    bbox = [-1, -2, 2, 30]
    clipped = clip_bboxes_TLBR(bbox, 5, 5)
    print(clipped)
    assert CHECK_EQ_NUMPY(clipped, np.array([0, 0, 2, 5]).reshape((1, 4)))

    print('check right intersected')
    bbox = [2, -3, 10, 30]
    clipped = clip_bboxes_TLBR(bbox, 5, 5)
    print(clipped)
    assert CHECK_EQ_NUMPY(clipped, np.array([2, 0, 5, 5]).reshape((1, 4)))

    print('check all intersected')
    bbox = [-2, -3, 10, 30]
    clipped = clip_bboxes_TLBR(bbox, 5, 5)
    print(clipped)
    assert CHECK_EQ_NUMPY(clipped, np.array([0, 0, 5, 5]).reshape((1, 4)))

    print('check bottom right outside')
    bbox = [10, 10, 10, 30]
    clipped = clip_bboxes_TLBR(bbox, 5, 5)
    print(clipped)
    assert CHECK_EQ_NUMPY(clipped, np.array([5, 5, 5, 5]).reshape((1, 4)))

    print('check top left outside')
    bbox = [-1, -1, -1, -1]
    clipped = clip_bboxes_TLBR(bbox, 5, 5)
    print(clipped)
    assert CHECK_EQ_NUMPY(clipped, np.array([0, 0, 0, 0]).reshape((1, 4)))

    print('check same height')
    bbox = [-2, 3, 10, 3]
    clipped = clip_bboxes_TLBR(bbox, 5, 5)
    print(clipped)
    assert CHECK_EQ_NUMPY(clipped, np.array([0, 3, 5, 3]).reshape((1, 4)))

    print('check same width')
    bbox = [2, -3, 2, 20]
    clipped = clip_bboxes_TLBR(bbox, 5, 5)
    print(clipped)
    assert CHECK_EQ_NUMPY(clipped, np.array([2, 0, 2, 5]).reshape((1, 4)))

    print('check all same')
    bbox = [2, 3, 2, 3]
    clipped = clip_bboxes_TLBR(bbox, 5, 5)
    print(clipped)
    assert CHECK_EQ_NUMPY(clipped, np.array([2, 3, 2, 3]).reshape((1, 4)))

    print('check for multiple bboxes')
    bbox = np.array([[2, 3, 2, 3], [2, -3, 2, 20], [-2, 3, 10, 3]])
    clipped = clip_bboxes_TLBR(bbox, 5, 5)
    print(clipped)
    assert CHECK_EQ_NUMPY(
        clipped,
        np.array([[2, 3, 2, 3], [2, 0, 2, 5], [0, 3, 5, 3]]).reshape((3, 4)))

    print('check for failure case')
    bbox = [-10, 30, 5, 5]
    try:
        clipped = clip_bboxes_TLBR(bbox, 5, 5)
        sys.exit('\nwrong! never should be here\n\n')
    except AssertionError:
        print(
            'the bottom right point coordinate should be larger than bottom left one'
        )

    print('\n\nDONE! SUCCESSFUL!!\n')
Пример #18
0
def test_crop_center():
    image_path = '../lena.jpg'
    img = Image.open(image_path).convert('RGB')

    #################################### test with 4 elements in center_rect #########################################
    print('test 2d matrix intersected on the top left')
    np_data = (np.random.rand(5, 5) * 255.).astype('uint8')
    center_rect = [1, 2, 4, 6]
    img_padded, crop_bbox, crop_bbox_clipped = image_crop_center(
        np_data, center_rect=center_rect, pad_value=10)
    print(np_data)
    print(img_padded)
    print(img_padded.shape)
    assert img_padded.shape == (
        6, 4), 'the padded image does not have a good shape'
    assert CHECK_EQ_NUMPY(crop_bbox, np.array([[-1, -1, 4, 6]]))
    assert CHECK_EQ_NUMPY(crop_bbox_clipped, np.array([[0, 0, 3, 5]]))

    print('test 2d matrix intersected on the bottom right')
    np_data = (np.random.rand(5, 5) * 255.).astype('uint8')
    center_rect = [3, 3, 5, 6]
    img_padded, crop_bbox, crop_bbox_clipped = image_crop_center(
        np_data, center_rect=center_rect, pad_value=10)
    print(np_data)
    print(img_padded)
    assert img_padded.shape == (
        6, 5), 'the padded image does not have a good shape'
    assert CHECK_EQ_NUMPY(crop_bbox, np.array([[1, 0, 5, 6]]))
    assert CHECK_EQ_NUMPY(crop_bbox_clipped, np.array([[1, 0, 4, 5]]))

    print('test with color image, clipped on the left')
    center_rect = [0, 50, 100, 100]
    img_cropped, crop_bbox, crop_bbox_clipped = image_crop_center(
        img, center_rect=center_rect, pad_value=100)
    assert CHECK_EQ_NUMPY(crop_bbox, np.array([[-50, 0, 100, 100]]))
    assert CHECK_EQ_NUMPY(crop_bbox_clipped, np.array([[0, 0, 50, 100]]))
    visualize_image(img, vis=True)
    visualize_image(img_cropped, vis=True)

    #################################### test with 2 elements in center_rect #########################################
    print('test 2d matrix - basic')
    np_data = (np.random.rand(5, 5) * 255.).astype('uint8')
    center_rect = [3, 3]
    img_padded, crop_bbox, crop_bbox_clipped = image_crop_center(
        np_data, center_rect=center_rect, pad_value=10)
    print(np_data)
    print(img_padded)
    print(img_padded.shape)
    assert img_padded.shape == (
        3, 3), 'the padded image does not have a good shape'
    assert CHECK_EQ_NUMPY(crop_bbox, np.array([[1, 1, 3, 3]]))
    assert CHECK_EQ_NUMPY(crop_bbox_clipped, np.array([[1, 1, 3, 3]]))

    print('test 2d matrix - boundary')
    np_data = (np.random.rand(5, 5) * 255.).astype('uint8')
    center_rect = [5, 5]
    img_padded, crop_bbox, crop_bbox_clipped = image_crop_center(
        np_data, center_rect=center_rect, pad_value=10)
    print(np_data)
    print(img_padded)
    assert img_padded.shape == (
        5, 5), 'the padded image does not have a good shape'
    assert CHECK_EQ_NUMPY(crop_bbox, np.array([[0, 0, 5, 5]]))
    assert CHECK_EQ_NUMPY(crop_bbox_clipped, np.array([[0, 0, 5, 5]]))

    print('test 2d matrix - intersected')
    np_data = (np.random.rand(5, 5) * 255.).astype('uint8')
    center_rect = [7, 7]
    img_padded, crop_bbox, crop_bbox_clipped = image_crop_center(
        np_data, center_rect=center_rect, pad_value=10)
    print(np_data)
    print(img_padded)
    assert img_padded.shape == (
        7, 7), 'the padded image does not have a good shape'
    assert CHECK_EQ_NUMPY(crop_bbox, np.array([[-1, -1, 7, 7]]))
    assert CHECK_EQ_NUMPY(crop_bbox_clipped, np.array([[0, 0, 5, 5]]))

    print('test with color image, clipped on the center')
    center_rect = [100, 100]
    img_cropped, crop_bbox, crop_bbox_clipped = image_crop_center(
        img, center_rect=center_rect, pad_value=100)
    visualize_image(img, vis=True)
    visualize_image(img_cropped, vis=True)

    print('test with color image, interesected')
    center_rect = [600, 600]
    img_cropped, crop_bbox, crop_bbox_clipped = image_crop_center(
        img, center_rect=center_rect, pad_value=100)
    visualize_image(img, vis=True)
    visualize_image(img_cropped, vis=True)

    print('test with grayscale image')
    center_rect = [100, 100]
    img_cropped, crop_bbox, crop_bbox_clipped = image_crop_center(
        img.convert('L'), center_rect=center_rect, pad_value=100)
    visualize_image(img.convert('L'), vis=True)
    visualize_image(img_cropped, vis=True)

    print('\n\nDONE! SUCCESSFUL!!\n')
Пример #19
0
def test_safe_pts():
    print('test single list')
    pts = [1, 4]
    good_pts = safe_pts(pts)
    print(good_pts)
    print(good_pts.shape)
    assert CHECK_EQ_NUMPY(good_pts, np.array(pts).reshape((2, 1)))
    assert CHECK_EQ_LIST_ORDERED(pts, [1, 4])

    print('test list of list of 2 elements')
    pts = [[1, 2], [5, 8]]
    good_pts = safe_pts(pts)
    print(good_pts)
    print(good_pts.shape)
    assert CHECK_EQ_NUMPY(good_pts, np.array(pts).reshape((2, 2)).transpose())
    assert CHECK_EQ_LIST_ORDERED(pts, [[1, 2], [5, 8]])

    print('test (2, ) numpy array')
    pts = np.array([1, 4])
    good_pts = safe_pts(pts)
    print(pts.shape)
    print(good_pts.shape)
    assert CHECK_EQ_NUMPY(good_pts, np.array(pts).reshape((2, 1)))
    assert CHECK_EQ_NUMPY(pts, np.array([1, 4]))

    print('test (2, N) numpy array')
    pts = np.random.rand(10, 2).transpose()
    pts_ori = copy.copy(pts)
    good_pts = safe_pts(pts)
    print(pts.shape)
    print(good_pts.shape)
    assert CHECK_EQ_NUMPY(good_pts, pts)
    assert CHECK_EQ_NUMPY(pts, pts_ori)

    ######################################## test failure cases
    print('test list of 3 elements')
    pts = [1, 2, 4]
    try:
        good_pts = safe_pts(pts)
        sys.exit('\nwrong! never should be here\n\n')
    except AssertionError:
        print('the length of list should be 2')

    print('test list of list of 3 elements')
    pts = [[1, 2, 4], [5, 7, 8]]
    try:
        good_pts = safe_pts(pts)
        sys.exit('\nwrong! never should be here\n\n')
    except AssertionError:
        print('the length of list should be 2')

    print('test numpy array with 3 elements')
    pts = np.array([1, 2, 4]).reshape(3, )
    try:
        good_pts = safe_pts(pts)
        sys.exit('\nwrong! never should be here\n\n')
    except AssertionError:
        print('the numpy array should be rows of 2')

    print('test numpy array with rows of 3')
    pts = np.array([[1, 2], [5, 7], [4, 6]])
    try:
        good_pts = safe_pts(pts)
        sys.exit('\nwrong! never should be here\n\n')
    except AssertionError:
        print('the numpy array should be rows of 2')

    print('\n\nDONE! SUCCESSFUL!!\n')
def test_safe_image_like():
    image_path = '../lena.jpg'

    print('test pil image in normal case')
    img_pil = Image.open(image_path)
    img_bak = np.array(img_pil).copy()
    copy_image, isnan = safe_image_like(img_pil)
    assert CHECK_EQ_NUMPY(
        copy_image,
        np.asarray(img_pil)), 'the original image should be equal to the copy'
    copy_image += 1
    assert not CHECK_EQ_NUMPY(
        copy_image,
        np.asarray(img_pil)), 'the original image should be equal to the copy'
    assert CHECK_EQ_NUMPY(img_bak, np.asarray(
        img_pil)), 'the original image should be equal to the backup version'
    assert not isnan

    print('test numpy image in normal case')
    img_numpy = np.asarray(img_pil)  # read only
    img_bak = img_numpy.copy()
    copy_image, isnan = safe_image_like(img_numpy)
    assert CHECK_EQ_NUMPY(
        copy_image,
        img_numpy), 'the original image should be equal to the copy'
    copy_image += 1
    assert not CHECK_EQ_NUMPY(
        copy_image,
        img_numpy), 'the original image should be equal to the copy'
    assert CHECK_EQ_NUMPY(
        img_bak,
        img_numpy), 'the original image should be equal to the backup version'
    assert not isnan

    print('test numpy image with arbitrary value')
    img_numpy = np.random.rand(100, 100)
    img_numpy += np.random.rand(100, 100)
    img_numpy += np.random.rand(100, 100)
    img_numpy += np.random.rand(100, 100)
    img_bak = img_numpy.copy()
    copy_image, isnan = safe_image_like(img_numpy)
    assert CHECK_EQ_NUMPY(
        copy_image,
        img_numpy), 'the original image should be equal to the copy'
    copy_image += 1
    assert not CHECK_EQ_NUMPY(
        copy_image,
        img_numpy), 'the original image should be equal to the copy'
    assert CHECK_EQ_NUMPY(
        img_bak,
        img_numpy), 'the original image should be equal to the backup version'
    assert not isnan

    print('test numpy image with nan')
    img_numpy = np.random.rand(100, 100)
    img_numpy[0, 0] = float('nan')
    img_bak = img_numpy.copy()
    copy_image, isnan = safe_image_like(img_numpy)
    assert isnan

    print('\n\nDONE! SUCCESSFUL!!\n')
Пример #21
0
def test_preprocess_batch_deep_image():
    print('test HW3, no rgb2bgr')
    img = np.random.rand(100, 200, 3).astype('float32')
    img_bak = img.copy()
    batch_image = preprocess_batch_deep_image(img, rgb2bgr=False)
    assert batch_image.shape == (1, 3, 100, 200)
    assert CHECK_EQ_NUMPY(
        batch_image,
        np.transpose(img, (2, 0, 1)).reshape(
            (1, 3, 100,
             200))), 'the original image should be equal to the copy'
    batch_image += 1
    assert not CHECK_EQ_NUMPY(
        batch_image,
        np.transpose(img, (2, 0, 1)).reshape(
            (1, 3, 100,
             200))), 'the original image should be equal to the copy'
    assert CHECK_EQ_NUMPY(
        img_bak,
        img), 'the original image should be equal to the backup version'

    print('test NHW3, no rgb2bgr')
    img = np.random.rand(12, 100, 100, 3).astype('float32')
    img_bak = img.copy()
    batch_image = preprocess_batch_deep_image(img, rgb2bgr=False)
    assert CHECK_EQ_NUMPY(batch_image, np.transpose(
        img, (0, 3, 1, 2))), 'the original image should be equal to the copy'
    batch_image += 1
    assert not CHECK_EQ_NUMPY(batch_image, np.transpose(
        img, (0, 3, 1, 2))), 'the original image should be equal to the copy'
    assert CHECK_EQ_NUMPY(
        img_bak,
        img), 'the original image should be equal to the backup version'

    print('test HW3, with rgb2bgr')
    img = np.random.rand(100, 200, 3).astype('float32')
    img_bak = img.copy()
    batch_image = preprocess_batch_deep_image(img)
    assert batch_image.shape == (1, 3, 100, 200)
    assert CHECK_EQ_NUMPY(
        bgr2rgb(chw2hwc(batch_image[0])),
        img), 'the original image should be equal to the copy'
    assert CHECK_EQ_NUMPY(
        img_bak,
        img), 'the original image should be equal to the backup version'

    print('test HW3, with rgb2bgr, pixel mean and std')
    img = np.random.rand(2, 4, 3).astype('float32')
    img[img < 0.5] = 0.5
    pixel_mean = [0.3, 0.4, 0.5]
    pixel_std = [0.9, 0.99, 0.999]
    batch_image = preprocess_batch_deep_image(img,
                                              pixel_mean=pixel_mean,
                                              pixel_std=pixel_std)
    assert batch_image.shape == (1, 3, 2, 4)
    assert_almost_equal(
        (chw2hwc(batch_image[0])),
        (bgr2rgb(img) - np.array(pixel_mean)) / np.array(pixel_std),
        err_msg='the original image should be equal to the copy')

    print('test HW3, with rgb2bgr, single pixel mean')
    img = np.random.rand(2, 4, 3).astype('float32')
    img[img < 0.5] = 0.5
    pixel_mean = 0.5
    pixel_std = [0.9, 0.99, 0.999]
    batch_image = preprocess_batch_deep_image(img,
                                              pixel_mean=pixel_mean,
                                              pixel_std=pixel_std)
    assert batch_image.shape == (1, 3, 2, 4)
    assert_almost_equal(
        (chw2hwc(batch_image[0])),
        (bgr2rgb(img) - np.array(pixel_mean)) / np.array(pixel_std),
        err_msg='the original image should be equal to the copy')

    print('test HW3, with rgb2bgr, single pixel std')
    img = np.random.rand(2, 4, 3).astype('float32')
    img[img < 0.5] = 0.5
    pixel_mean = 0.5
    pixel_std = 0.9
    batch_image = preprocess_batch_deep_image(img,
                                              pixel_mean=pixel_mean,
                                              pixel_std=pixel_std)
    assert batch_image.shape == (1, 3, 2, 4)
    assert_almost_equal(
        (chw2hwc(batch_image[0])),
        (bgr2rgb(img) - np.array(pixel_mean)) / np.array(pixel_std),
        err_msg='the original image should be equal to the copy')

    print('\n\nDONE! SUCCESSFUL!!\n')
def test_generate_gaussian_heatmap():
    print('test single point')
    input_pts = [300, 400, 1]
    image_size = [800, 600]
    std = 10
    heatmap, mask, _ = generate_gaussian_heatmap(input_pts,
                                                 image_size=image_size,
                                                 std=std)
    assert heatmap.shape == (800, 600, 2)
    assert mask.shape == (1, 1, 2)
    assert CHECK_EQ_NUMPY(mask, np.array([[[1, 1]]]))
    visualize_image(heatmap[:, :, 0], vis=True)

    print('test two points')
    input_pts = [[300, 400, 1], [400, 400, 1]]
    image_size = [800, 600]
    std = 10
    heatmap, mask, _ = generate_gaussian_heatmap(input_pts,
                                                 image_size=image_size,
                                                 std=std)
    assert heatmap.shape == (800, 600, 3)
    assert mask.shape == (1, 1, 3)
    assert CHECK_EQ_NUMPY(mask, np.array([[[1, 1, 1]]]))
    visualize_image(heatmap[:, :, -1], vis=True)
    visualize_image(heatmap[:, :, 0], vis=True)
    visualize_image(heatmap[:, :, 1], vis=True)

    print('test two points with invalid one')
    input_pts = [[300, 400, 1], [400, 400, -1]]
    image_size = [800, 600]
    std = 10
    heatmap, mask, _ = generate_gaussian_heatmap(input_pts,
                                                 image_size=image_size,
                                                 std=std)
    assert heatmap.shape == (800, 600, 3)
    assert mask.shape == (1, 1, 3)
    assert CHECK_EQ_NUMPY(mask, np.array([[[1, 0, 1]]]))
    visualize_image(heatmap[:, :, -1], vis=True)
    visualize_image(heatmap[:, :, 0], vis=True)
    visualize_image(heatmap[:, :, 1], vis=True)

    print('test two points with invisible one')
    input_pts = [[300, 400, 1], [-400, -400, 0]]
    image_size = [800, 600]
    std = 10
    heatmap, mask, mask_visible = generate_gaussian_heatmap(
        input_pts, image_size=image_size, std=std)
    assert heatmap.shape == (800, 600, 3)
    assert mask.shape == (1, 1, 3)
    assert CHECK_EQ_NUMPY(mask, np.array([[[1, 1, 1]]]))
    assert CHECK_EQ_NUMPY(mask_visible, np.array([[[1, 0, 1]]]))
    visualize_image(heatmap[:, :, -1], vis=True)
    visualize_image(heatmap[:, :, 0], vis=True)
    visualize_image(heatmap[:, :, 1], vis=True)

    print('test two points with invisible and invalid')
    input_pts = [[300, 400, -1], [-400, -400, 0]]
    image_size = [800, 600]
    std = 10
    heatmap, mask, mask_visible = generate_gaussian_heatmap(
        input_pts, image_size=image_size, std=std)
    assert heatmap.shape == (800, 600, 3)
    assert mask.shape == (1, 1, 3)
    assert CHECK_EQ_NUMPY(mask, np.array([[[0, 1, 1]]]))
    assert CHECK_EQ_NUMPY(mask_visible, np.array([[[0, 0, 1]]]))
    visualize_image(heatmap[:, :, -1], vis=True)
    visualize_image(heatmap[:, :, 0], vis=True)
    visualize_image(heatmap[:, :, 1], vis=True)

    print('\n\nDONE! SUCCESSFUL!!\n')