コード例 #1
0
ファイル: level_01.py プロジェクト: Gaetz/python-training
class Level01(Scene):
    def __init__(self, background_file, ground_file):
        Scene.__init__(self, background_file, ground_file)
        _, screen_h = pygame.display.get_surface().get_size()
        ground_height = screen_h - self.ground.surface.get_height()
        self.ground.y = ground_height
        self.player = SpriteControlled(10, ground_height, 'sprite.png', True,
                                       2)
        self.cursor = Sprite(0, 0, 'cursor.png', False)
        self.warp = Warp(680, 0, 'warp.png', False, "level00")
        self.warp.y = ground_height - self.warp.surface.get_height() / 2

    def load(self):
        pass

    def inputs(self, events):
        for event in events:
            if event.type == pygame.MOUSEBUTTONDOWN:
                mouse_click = pygame.mouse.get_pos()
                self.player.move_to(mouse_click[0])

    def update(self, change_scene):
        self.cursor.set_position(pygame.mouse.get_pos())
        self.player.update()
        if self.player.intersects(self.warp):
            change_scene(self.warp.to_scene)

    def draw(self, screen):
        self.background.draw(screen)
        self.ground.draw(screen)
        self.warp.draw(screen)
        self.player.draw(screen)
        self.cursor.draw(screen)
コード例 #2
0
ファイル: warp_test.py プロジェクト: alita-moore/ableton
    def runTest(self):
        self.test = Warp()

        # validate basic functionality
        self.assert_console_accepts_markers()
        self.assert_accepts_end_tempo()
        self.assert_console_accepts_b2s()
        self.assert_console_accepts_s2b()
        self.assert_expected_s2b_and_b2s_if_only_1_marker()

        # validate basic exceptions
        self.assert_warp_filters_invalid_markers_properly()
        self.assert_warp_filters_invalid_b2s_and_s2p_ie_no_end_tempo()
        self.assert_end_tempo_doesnt_accept_negatives()

        # validate the s2b and b2s functionalities at edge points
        self.assert_expected_s2b_inbetween_the_two_markers()
        self.assert_expected_b2s_inbetween_the_two_markers()
        self.assert_expected_s2b_and_b2s_before_the_2markers()
        self.assert_expected_s2b_and_b2s_after_all_2markers()
        self.assert_expected_s2b_and_b2s_if_call_is_on_marker()
        self.assert_s2b_b2s_act_properly_after_third_marker_introduced()

        # validate performance
        self.check_if_solution_is_optimal()
コード例 #3
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ファイル: warp_test.py プロジェクト: alita-moore/ableton
    def assert_that_order_of_marker_vs_end_tempo_setting_doesnt_matter(self):
        """Verify that the end_tempo can be set before the markers are set"""
        self.test = Warp()

        self.assert_accepts_end_tempo()
        self.assert_console_accepts_markers()
        self.assert_console_accepts_b2s()
        self.assert_console_accepts_s2b()
コード例 #4
0
ファイル: level_01.py プロジェクト: Gaetz/python-training
 def __init__(self, background_file, ground_file):
     Scene.__init__(self, background_file, ground_file)
     _, screen_h = pygame.display.get_surface().get_size()
     ground_height = screen_h - self.ground.surface.get_height()
     self.ground.y = ground_height
     self.player = SpriteControlled(10, ground_height, 'sprite.png', True,
                                    2)
     self.cursor = Sprite(0, 0, 'cursor.png', False)
     self.warp = Warp(680, 0, 'warp.png', False, "level00")
     self.warp.y = ground_height - self.warp.surface.get_height() / 2
コード例 #5
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 def __init__(self, background_file, ground_file):
     self.background = Sprite(0, 0, background_file, False)
     self.ground = Sprite(0, 0, ground_file, False)
     screen_w, screen_h = pygame.display.get_surface().get_size()
     ground_height = screen_h - self.ground.surface.get_height()
     self.ground.y = ground_height
     self.player = SpriteControlled(150, ground_height, 'Sprite.png', True, 2)
     self.copain = SpriteControlled(500, ground_height, 'copain.png', True, 0)
     self.cursor = Sprite(0, 0, 'cursor.jpg', False)
     #self.collision_text = font.render("Oops sorry Mamen", False,(0, 0,0))
     self.warp = Warp(700, 0, 'warp.png', False, "level01")
     self.warp.y = ground_height - self.warp.surface.get_height() / 2
コード例 #6
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    def load(self, filename):
        file = open(Scene.path + filename)
        data = file.read().splitlines()

        ground_height = 0
        self.cursor = Sprite(0, 0, 'cursor.png', False)
        self.sprites = []
        self.warps = []

        self.ui_top = UiGroup()
        panel = UiPanel(0, 0, 800, 110)
        button = UiButton(10, 10, 90, 90, "banana")
        self.ui_top.add_element(panel)
        self.ui_top.add_element(button)

        for line in data:
            cell = line.split(";")
            # Ground
            if (cell[0] == "ground"):
                self.ground = Sprite(0, 0, cell[1] + ".png", False)
                _, screen_h = pygame.display.get_surface().get_size()
                ground_height = screen_h - self.ground.surface.get_height()
                self.ground.y = ground_height
            # Background
            elif (cell[0] == "background"):
                self.background = Sprite(0, 0, cell[1] + ".png", False)
            # Player
            elif (cell[0] == "player"):
                height = 0
                if cell[3] == "ground":
                    height = -1
                self.player = SpriteControlled(int(cell[2]), height,
                                               cell[1] + ".png", True,
                                               int(cell[4]))
            # Sprites
            elif (cell[0] == "sprite"):
                height = 0
                if cell[3] == "ground":
                    height = -1
                sprite = Sprite(int(cell[2]), height, cell[1] + ".png", True)
                self.sprites.append(sprite)
            # Warps
            elif (cell[0] == "warp"):
                height = 0
                if cell[3] == "ground":
                    height = -1
                warp = Warp(int(cell[2]), height, cell[1] + ".png", False,
                            eval(cell[4]))
                self.warps.append(warp)

        # Set heights
        if (self.player.y == -1):
            self.player.y = ground_height
        for s in self.sprites:
            if (s.y == -1):
                s.y = ground_height
        for w in self.warps:
            if (w.y == -1):
                w.y = ground_height - w.surface.get_height() / 2
コード例 #7
0
ファイル: augmentor.py プロジェクト: ngchc/EM-affinity
 def factory(aug_type, **kwargs):
     """Factory method for data augmentation classes."""
     if aug_type is 'box': return BoxOcclusion(**kwargs)
     if aug_type is 'blur': return Blur(**kwargs)
     if aug_type is 'flip': return Flip(**kwargs)
     if aug_type is 'warp': return Warp(**kwargs)
     if aug_type is 'misalign': return Misalign(**kwargs)
     if aug_type is 'missing': return MissingSection(**kwargs)
     if aug_type is 'greyscale': return Greyscale(**kwargs)
     assert False, "Unknown data augmentation type: [%s]" % aug_type
コード例 #8
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class Scene:
    
    def __init__(self, background_file, ground_file):
        self.background = Sprite(0, 0, background_file, False)
        self.ground = Sprite(0, 0, ground_file, False)
        screen_w, screen_h = pygame.display.get_surface().get_size()
        ground_height = screen_h - self.ground.surface.get_height()
        self.ground.y = ground_height
        self.player = SpriteControlled(150, ground_height, 'Sprite.png', True, 2)
        self.copain = SpriteControlled(500, ground_height, 'copain.png', True, 0)
        self.cursor = Sprite(0, 0, 'cursor.jpg', False)
        #self.collision_text = font.render("Oops sorry Mamen", False,(0, 0,0))
        self.warp = Warp(700, 0, 'warp.png', False, "level01")
        self.warp.y = ground_height - self.warp.surface.get_height() / 2

    def load(self):
        pass

    def inputs(self, events):
        for event in events:
            if event.type == pygame.MOUSEBUTTONDOWN:
                mouse_click = pygame.mouse.get_pos()
                self.player.move_to(mouse_click[0])

    def update(self, change_scene):
        self.cursor.set_position(pygame.mouse.get_pos())
        self.player.update()
        if(self.player.intersects(self.warp)):
            
            change_scene(self.warp.to_scene)

        #if(self.player.intersects(self.copain)):
            #screen.blit(self.collision_text,(self.copain_x, self.copain_y - 100))

            

    def draw(self, screen):
        self.background.draw(screen)
        self.ground.draw(screen)
        self.warp.draw(screen)
        self.player.draw(screen)
        self.cursor.draw(screen)
        self.copain.draw(screen)
コード例 #9
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def main():
    parser = ArgumentParser()
    parser.add_argument('--image_dir', required=True)
    parser.add_argument('--feature_dir', required=True)
    parser.add_argument('--grid_dir', required=True)
    parser.add_argument('--warp_dir', required=True)
    args = parser.parse_args()

    images   = os.listdir(args.image_dir)
    features = os.listdir(args.feature_dir)

    image_id = [ (int(img.split('.')[0]), os.path.join(args.image_dir, img)) for img in images ]
    feature_id = [ (int(feat.split('.')[0]), os.path.join(args.feature_dir, feat)) for feat in features ]

    image_id.sort(key=lambda tup: tup[0])
    feature_id.sort(key=lambda tup: tup[0])

    data = zip(image_id, feature_id)
    for image, feat in data:
        print ('Processing image:', image[1])
        warp = Warp(image[1], feat[1], 18, 32, args.grid_dir, args.warp_dir, alpha=20)
        warp.warp()
        print ('')
コード例 #10
0
ファイル: warp_test.py プロジェクト: alita-moore/ableton
    def assert_expected_s2b_and_b2s_if_only_1_marker(self):
        """
        Verifies that the program functions as expected
        if only one marker exists
        """
        warp_test = Warp()
        warp_test.set_marker(0, 0)
        warp_test.set_end_tempo(10)

        # after marker
        self.assertEqual(console(warp_test, "s2b 1"), 10)
        self.assertEqual(console(warp_test, "b2s 10"), 1)

        # before marker
        self.assertEqual(console(warp_test, "s2b -1"), -10)
        self.assertEqual(console(warp_test, "b2s -10"), -1)

        # on marker
        self.assertEqual(console(warp_test, "s2b 0"), 0)
        self.assertEqual(console(warp_test, "b2s 0"), 0)
コード例 #11
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import cv2
import numpy as np
from warp import Warp

# getting image from the camera
# camera = cv2.VideoCapture(0)
# def get_image():
#     retval, img = camera.read()
#     return img
# original_image = get_image()
original_image = cv2.imread('slantview1.png')

# create object and filter image to get contours
rectangle = Warp(np.array([10, 255, 255]), np.array([0, 128, 64]))
rectangle_filtered = rectangle.filter_bw(original_image)

# obtain, sort, and approximate contours to find desired contours
rectangle_bounds = rectangle.findsort_contours(rectangle_filtered, -2)
epsilon = 0.05 * cv2.arcLength(rectangle_bounds, True)
rectangle_approx_contours = cv2.approxPolyDP(rectangle_bounds, epsilon, True)

rectangle_ordered_contours, rectangle_desired_contours, max_width, max_height = rectangle.orderdesire_contours(
    rectangle_approx_contours)

# transform the image
transformation = cv2.getPerspectiveTransform(rectangle_ordered_contours,
                                             rectangle_desired_contours)
warped_image = cv2.warpPerspective(original_image, transformation,
                                   (max_width, max_height))

# find the center of the car
コード例 #12
0
ファイル: warp_test.py プロジェクト: alita-moore/ableton
    def check_if_solution_is_optimal(self):
        """
        Verifies that the optimal solutions is employed with
        complexity O(log(n)). The whole function must run at
        no less than 1000 standard units; A standard unit is
        defined as the time it takes for a general sorting function
        to sort 1,000 times; which, is only possible if the ideal 
        O(log(n)) solution is used in all steps.
        """
        import timeit
        import math
        import statistics as stats
        import time

        avg_log = []
        test_ns = [2**i for i in range(4, 12)]

        start = time.time()
        for n in test_ns:
            test_warp = Warp()
            avg_exc = 0
            avg_exc_ref = 0

            for marker in range(1, n):
                console(
                    test_warp,
                    "marker " + str(float(marker)) + ' ' + str(float(marker)))

            repeats = 25
            for _ in range(repeats):
                execution = timeit.timeit(lambda: [
                    console(test_warp, 'b2s ' + str(n - 0.1)),
                    console(test_warp, 's2b ' + str(n // 2 - 0.1))
                ],
                                          number=400)
                avg_exc += execution / repeats
                execution = timeit.timeit(
                    lambda: [ord(x) for x in "aasdfadgasdfwr22"], number=1000)
                avg_exc_ref += execution / repeats

            avg_log.append(avg_exc / avg_exc_ref)
            print("(raw time, for 400 requests, and n-markers = %d)"
                  " mean: %f, theoretical frequency: %f" %
                  (n, avg_exc, 2 * 400 /
                   avg_exc))  # 2 * because s2b and b2s in conjunction
        time_elapsed = time.time() - start
        exc_ref = sum(
            timeit.repeat(lambda: [ord(x) for x in "aasdfadgasdfwr22"],
                          repeat=25,
                          number=1000)) / 25
        time_elapsed_normalized = time_elapsed / exc_ref
        self.assertTrue(time_elapsed < 1000)

        avg_log = [
            math.log2(avg_log[i + 1] / avg_log[i])
            for i in range(len(avg_log) - 1)
        ]
        print("(logarithm) mean: %f, std: %f, adjusted mean: %f" %
              (stats.mean(avg_log), stats.stdev(avg_log),
               stats.mean(avg_log) + 2 * stats.stdev(avg_log)))
        self.assertTrue(stats.mean(avg_log) < 0.15)  # O(log(n))
コード例 #13
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    def load(self, filename):
        file = open(Scene.path + filename)
        data = file.read().splitlines()

        ground_height = 0
        self.cursor = Sprite(0, 0, 'cursor.png', False)
        self.sprites = []
        self.state_sprites = []
        self.warps = []
        self.pickables = []

        self.messages = []
        self.observers = []

        self.ui_top = UiGroup()
        panel = UiPanel(0, 0, 800, 110)
        self.ui_top.add_element(panel)

        for line in data:
            cell = line.split(";")
            # Ground
            if (cell[0] == "ground"):
                self.ground = Sprite(0, 0, cell[1] + ".png", False)
                _, screen_h = pygame.display.get_surface().get_size()
                ground_height = screen_h - self.ground.surface.get_height()
                self.ground.y = ground_height
            # Background
            elif (cell[0] == "background"):
                self.background = Sprite(0, 0, cell[1] + ".png", False)
            # Player
            elif (cell[0] == "player"):
                height = 0
                if cell[3] == "ground":
                    height = -1
                self.player = SpriteControlled(int(cell[2]), height,
                                               cell[1] + ".png", True,
                                               int(cell[4]))
            # Sprites
            elif (cell[0] == "sprite"):
                height = 0
                if cell[3] == "ground":
                    height = -1
                sprite = Sprite(int(cell[2]), height, cell[1] + ".png", True)
                self.sprites.append(sprite)
            # Stateful sprites
            elif (cell[0] == "stateful"):
                height = 0
                if cell[3] == "ground":
                    height = -1
                sprite = SpriteStateful(int(cell[2]), height, eval(cell[1]),
                                        True, eval(cell[4]), cell[5])
                self.state_sprites.append(sprite)
                self.observers.append(sprite)
            # Warps
            elif (cell[0] == "warp"):
                height = 0
                if cell[3] == "ground":
                    height = -1
                warp = Warp(int(cell[2]), height, cell[1] + ".png", False,
                            eval(cell[4]))
                self.warps.append(warp)
            # Items
            elif (cell[0] == "pickable"):
                height = 0
                if cell[3] == "ground":
                    height = -1
                item = SpritePickable(int(cell[2]), height,
                                      cell[1] + "_ingame.png", False, cell[1])
                self.pickables.append(item)

        # Set heights
        if (self.player.y == -1):
            self.player.y = ground_height
        for s in self.sprites:
            if (s.y == -1):
                s.y = ground_height
        for s in self.state_sprites:
            if (s.y == -1):
                s.y = ground_height
        for w in self.warps:
            if (w.y == -1):
                w.y = ground_height - w.surface.get_height() / 2
        for p in self.pickables:
            if (p.y == -1):
                p.y = ground_height - p.surface.get_height()
コード例 #14
0
ファイル: warp_test.py プロジェクト: alita-moore/ableton
class TestWarp(unittest.TestCase):
    """
    A test that validates basic functionality,
    exception handling, main s2b and b2s functions,
    and performance.
    """
    def runTest(self):
        self.test = Warp()

        # validate basic functionality
        self.assert_console_accepts_markers()
        self.assert_accepts_end_tempo()
        self.assert_console_accepts_b2s()
        self.assert_console_accepts_s2b()
        self.assert_expected_s2b_and_b2s_if_only_1_marker()

        # validate basic exceptions
        self.assert_warp_filters_invalid_markers_properly()
        self.assert_warp_filters_invalid_b2s_and_s2p_ie_no_end_tempo()
        self.assert_end_tempo_doesnt_accept_negatives()

        # validate the s2b and b2s functionalities at edge points
        self.assert_expected_s2b_inbetween_the_two_markers()
        self.assert_expected_b2s_inbetween_the_two_markers()
        self.assert_expected_s2b_and_b2s_before_the_2markers()
        self.assert_expected_s2b_and_b2s_after_all_2markers()
        self.assert_expected_s2b_and_b2s_if_call_is_on_marker()
        self.assert_s2b_b2s_act_properly_after_third_marker_introduced()

        # validate performance
        self.check_if_solution_is_optimal()

    def assert_console_accepts_b2s(self):
        """Checks if the console accepts the b2s command"""
        self.assertFalse(
            isinstance(type(console(self.test, "b2s 0.5")), type(None)))

    def assert_console_accepts_s2b(self):
        """Checks if the console accepts the s2b command"""
        self.assertFalse(
            isinstance(type(console(self.test, "s2b 2.5")), type(None)))

    def assert_console_accepts_markers(self):
        """Checks if the console accepts the marker command"""
        self.assertEqual(console(self.test, "marker 0.0 0.0"), None)
        self.assertEqual(console(self.test, "marker 1.0 5.0"), None)

    def assert_accepts_end_tempo(self):
        """Checks if the console accepts end_tempo command"""
        self.assertEqual(console(self.test, "end_tempo 10.0"), None)
        self.assertEqual(self.test.end_tempo, 10)

    def assert_warp_filters_invalid_markers_properly(self):
        """
        Verifies that the object's marker values do not change / update
        when fed an invalid object. There are two invalid possibilities:
        1) the marker is already defined
        2) there is an intersection with another marker
        """
        markers = self.test.markers.copy()

        # already defined points
        console(self.test, "marker 0.0 1.0")
        console(self.test, "marker 1.0 0.0")
        self.assertEqual(markers, self.test.markers)

        # interceting vertices
        console(self.test, "marker 0.5 6.0")
        self.assertEqual(markers, self.test.markers)

    def assert_warp_filters_invalid_b2s_and_s2p_ie_no_end_tempo(self):
        """
        Verifies that if a end_tempo is not given, the b2s and s2b
        methods will have no output
        """
        self.test.set_end_tempo(None)
        self.assertEqual(console(self.test, "b2s 2.0"), None)
        self.assertEqual(console(self.test, "s2b 6.0"), None)
        self.test.set_end_tempo(10.0)

    def assert_end_tempo_doesnt_accept_negatives(self):
        """
        Verifies that if a negative values is provided to end_tempo
        that nothing changes.
        """
        end_tempo = self.test.end_tempo
        self.assertEqual(console(self.test, "end_tempo -10"), None)
        self.assertEqual(end_tempo, self.test.end_tempo)

    def assert_expected_s2b_and_b2s_if_only_1_marker(self):
        """
        Verifies that the program functions as expected
        if only one marker exists
        """
        warp_test = Warp()
        warp_test.set_marker(0, 0)
        warp_test.set_end_tempo(10)

        # after marker
        self.assertEqual(console(warp_test, "s2b 1"), 10)
        self.assertEqual(console(warp_test, "b2s 10"), 1)

        # before marker
        self.assertEqual(console(warp_test, "s2b -1"), -10)
        self.assertEqual(console(warp_test, "b2s -10"), -1)

        # on marker
        self.assertEqual(console(warp_test, "s2b 0"), 0)
        self.assertEqual(console(warp_test, "b2s 0"), 0)

    def assert_expected_s2b_inbetween_the_two_markers(self):
        """Checks if the seconds to beats function works properly inbetween two markers"""
        self.assertEqual(console(self.test, "s2b 2.5"), 0.5)

    def assert_expected_b2s_inbetween_the_two_markers(self):
        """Checks if the beats to second funciton works properly inbetween two markers"""
        self.assertEqual(console(self.test, "b2s 0.5"), 2.5)

    def assert_expected_s2b_and_b2s_before_the_2markers(self):
        """Checks if the b2s and s2b functions work properly before the set of markers"""
        self.assertEqual(console(self.test, "b2s -0.5"), -2.5)
        self.assertEqual(console(self.test, "s2b -2.5"), -0.5)

    def assert_expected_s2b_and_b2s_after_all_2markers(self):
        """Checks if the s2b and b2s work properly after the markers (i.e. end_tempo)"""
        self.assertEqual(console(self.test, "s2b 6"), 11)
        self.assertEqual(console(self.test, "b2s 11"), 6)

    def assert_expected_s2b_and_b2s_if_call_is_on_marker(self):
        """verify that if b2s and s2b are called on their respective markers, the result
        is consistent with their defintions. Notably, (0,0) is easy to cause errors."""
        self.assertEqual(console(self.test, "b2s 1.0"), 5.0)
        self.assertEqual(console(self.test, "s2b 5.0"), 1.0)
        self.assertEqual(console(self.test, "s2b 0"), 0)
        self.assertEqual(console(self.test, "b2s 0"), 0)

    def assert_that_order_of_marker_vs_end_tempo_setting_doesnt_matter(self):
        """Verify that the end_tempo can be set before the markers are set"""
        self.test = Warp()

        self.assert_accepts_end_tempo()
        self.assert_console_accepts_markers()
        self.assert_console_accepts_b2s()
        self.assert_console_accepts_s2b()

    def assert_s2b_b2s_act_properly_after_third_marker_introduced(self):
        r"""
        Checks that if a third marker is introduce inbetween the
        two prior defined markers that the funciton behvaiors are maintained

                                     (NEW / ADDED)                                           v
        i.e.                    0         0.5       1.0
        beat  line        -----*---------*-----------*-------->
        (before all region)    |  section \  section  \   (after all region)
                               |      A    \     B     \ 
        time line        ------*------------*-----------*----->
                                0           4           5
        """
        console(self.test, "marker 0.5 4")
        # this change will add the marker shown in the docstring.
        # Pracitcally, this change should alter the value of the tempo
        # before all markers, add an internal section for the, and not
        # impact the final section

        # check section A
        self.assertEqual(console(self.test, "s2b 2"), 0.25)
        self.assertEqual(console(self.test, "b2s 0.25"), 2)

        # check section B
        self.assertEqual(console(self.test, "s2b 4.5"), 0.75)
        self.assertEqual(console(self.test, "b2s 0.75"), 4.5)

        # check before all region
        self.assertEqual(console(self.test, "s2b -2"), -0.25)
        self.assertEqual(console(self.test, "b2s -0.25"), -2)

        # check final region
        self.assertEqual(console(self.test, "s2b 6"), 11)
        self.assertEqual(console(self.test, "b2s 11"), 6)

        # check if call is on marker functionality
        self.assertEqual(console(self.test, "b2s 0.5"), 4)
        self.assertEqual(console(self.test, "s2b 4"), 0.5)

    def check_if_solution_is_optimal(self):
        """
        Verifies that the optimal solutions is employed with
        complexity O(log(n)). The whole function must run at
        no less than 1000 standard units; A standard unit is
        defined as the time it takes for a general sorting function
        to sort 1,000 times; which, is only possible if the ideal 
        O(log(n)) solution is used in all steps.
        """
        import timeit
        import math
        import statistics as stats
        import time

        avg_log = []
        test_ns = [2**i for i in range(4, 12)]

        start = time.time()
        for n in test_ns:
            test_warp = Warp()
            avg_exc = 0
            avg_exc_ref = 0

            for marker in range(1, n):
                console(
                    test_warp,
                    "marker " + str(float(marker)) + ' ' + str(float(marker)))

            repeats = 25
            for _ in range(repeats):
                execution = timeit.timeit(lambda: [
                    console(test_warp, 'b2s ' + str(n - 0.1)),
                    console(test_warp, 's2b ' + str(n // 2 - 0.1))
                ],
                                          number=400)
                avg_exc += execution / repeats
                execution = timeit.timeit(
                    lambda: [ord(x) for x in "aasdfadgasdfwr22"], number=1000)
                avg_exc_ref += execution / repeats

            avg_log.append(avg_exc / avg_exc_ref)
            print("(raw time, for 400 requests, and n-markers = %d)"
                  " mean: %f, theoretical frequency: %f" %
                  (n, avg_exc, 2 * 400 /
                   avg_exc))  # 2 * because s2b and b2s in conjunction
        time_elapsed = time.time() - start
        exc_ref = sum(
            timeit.repeat(lambda: [ord(x) for x in "aasdfadgasdfwr22"],
                          repeat=25,
                          number=1000)) / 25
        time_elapsed_normalized = time_elapsed / exc_ref
        self.assertTrue(time_elapsed < 1000)

        avg_log = [
            math.log2(avg_log[i + 1] / avg_log[i])
            for i in range(len(avg_log) - 1)
        ]
        print("(logarithm) mean: %f, std: %f, adjusted mean: %f" %
              (stats.mean(avg_log), stats.stdev(avg_log),
               stats.mean(avg_log) + 2 * stats.stdev(avg_log)))
        self.assertTrue(stats.mean(avg_log) < 0.15)  # O(log(n))
コード例 #15
0
    def __init__(self, name, source, title, borders, world):

        self.name = name
        self.source = os.path.basename(source)
        self.title = title
        self.world = world
        self.borders = borders

        # Logic to load zone file
        self.data = pytmx.TiledMap('server_data/zones/' + source)

        self.client_data = ''
        with open('server_data/zones/' + source, 'r') as zonefile:
            self.client_data = zonefile.read()

        self.width = self.data.width
        self.height = self.data.height

        self.blocked = self.data.layers.index(
            self.data.get_layer_by_name('blocked'))

        self.graph = GridWithWeights(self.width, self.height)

        self.graph.walls = [
            (x, self.height - y - 1)
            for x, y, gid in self.data.layers[self.blocked].tiles()
        ]

        for o in self.data.objects:
            if o.type == 'monster_spawn':
                x = int(o.x / 32)
                y = self.height - int(o.y / 32) - 1
                w = int(o.width / 32)
                h = int(o.height / 32)
                max_spawn = int(o.properties['max_spawn'])
                spawn_delay = float(o.properties['spawn_delay'])
                monster_name = o.name

                # Create monster spawn
                MonsterSpawn(monster_name, x, y, w, h, self.name, max_spawn,
                             spawn_delay, self.world)

            if o.type == 'npc_spawn':
                x = int(o.x / 32)
                y = self.height - int(o.y / 32) - 1
                w = int(o.width / 32)
                h = int(o.height / 32)
                max_spawn = int(o.properties['max_spawn'])
                spawn_delay = float(o.properties['spawn_delay'])
                npc_name = o.name

                # Create npc spawn
                NpcSpawn(npc_name, x, y, w, h, self.name, max_spawn,
                         spawn_delay, self.world)

            if o.type == 'warp':
                x = int(o.x / 32)
                y = self.height - int(o.y / 32) - 1
                #w = int(o.width/32)
                #h = int(o.height/32)
                end_zone = o.properties['end_zone']
                end_x = int(o.properties['end_x'])
                end_y = int(o.properties['end_y'])

                self.world.warps.append(
                    Warp(self.name, x, y, end_zone, end_x, end_y))

        print "Loaded ZONE", self.name
コード例 #16
0
'''
@author: Wizzard
'''

from warp import Warp

# Relevant information about the warps within each level
Levels = {
    #  0 - Main Area
    #  1 - Mumbo's Skull
    #  2 - Ticker's Tower
    #  3 - Top Of Ticker's Tower
    "Mumbo's Mountain": {
        # Coming outside from Mumbo's Skull
        Warp("Mumbo's Skull - Outside", 0x16, 0, 1, 0, 0, Warp.Termite): [
            "1579098CF47532060016000000000000",
            "159D098DF49232060016000000000662",
            "15C1098CF4AE32060016000000000663",
            "15E0098EF4CB32060016000000000000",
        ],
        # Coming inside to Mumbo's Skull
        Warp("Mumbo's Skull - Inside", 0x17, 1, 0): [
            "0000005103A94B0600170000000063A9",
        ],
        # Coming outside from the lower part of Ticker's Tower
        Warp("Ticker's Tower - Lower/Outside", 0x18, 0, 2): [
            "03DC0663FC384E06001800000001071A",
        ],
        # Coming inside to the lower part of Ticker's Tower
        Warp("Ticker's Tower - Lower/Inside", 0x19, 2, 0): [
            "008E003CFCB83206001900000006118B",
コード例 #17
0
num_faces = 150
num_lights = 1

base_model = Geometry(vertices=np.random.randn(num_vertices, 3),
                      faces=np.random.randint(0,
                                              num_vertices,
                                              size=[num_faces, 3]))
lights = Lights(positions=np.random.randn(num_lights, 3),
                intensities=np.random.randn(num_lights, 3))
camera = Camera(eye=np.random.randn(1, 3),
                center=np.random.randn(1, 3),
                world_up=np.random.randn(1, 3))
trans = Transform(batch_size=BATCH_SIZE)

warp_params = Input(shape=[NUM_WARPS, 1])
warped_vertices = Warp(num_warps=NUM_WARPS)(
    [K.identity(base_model.vertices), warp_params])
world_coords = trans(warped_vertices)
colors = K.constant(np.random.randn(BATCH_SIZE, num_vertices, 3))
rendered = Render(512, 512)([world_coords, base_model.faces],
                            base_model.calculate_normals(world_coords), colors,
                            [camera.eye, camera.center, camera.world_up],
                            [lights.positions, lights.intensities])

#model = Model(inputs=[warp_params], outputs=[renderer])

sess = K.get_session()
sess.run(tf.global_variables_initializer())
sess.run([rendered],
         feed_dict={warp_params: np.random.randn(BATCH_SIZE, NUM_WARPS, 1)})
コード例 #18
0

def onStairwellEnter():
    global stairwellEnter
    stairwellEnter = True


stairwell = Room([], [player], sprites.rooms[10], canvas, inventory,
                 onStairwellEnter)
cseRoom = Room([], [player], sprites.rooms[11], canvas, inventory)
outside = Room([], [player], sprites.rooms[12], canvas, inventory)
darkRoom = Room([], [], sprites.rooms[13], canvas, inventory, player=player)

#   Walls
nexusWalls = [
    Warp(348, -48, 668, -48, nexus, juniorNexus),
    Wall(668, -48, 668, 444),
    Wall(668, 444, 876, 444),
    Wall(876, 444, 876, 592),
    Wall(876, 592, 748, 592),
    Wall(748, 592, 748, 896),
    Wall(748, 896, 904, 896),
    Wall(904, 896, 904, 1008),
    Wall(904, 1008, 348, 1008),
    Wall(348, 1008, 348, 868),
    Wall(348, 868, 0, 868),
    Warp(0, 868, 0, 500, nexus, freshmanHallway),
    Wall(0, 500, 348, 500),
    Wall(348, 500, 348, -48)
]
for wall in nexusWalls:
コード例 #19
0
from segmentation import Segmentation
from mosaic import Mosaic
from sampling import Sampling
from image_fusion import Fusion

path1 = "/Users/liumeiyu/Downloads/IMG_7575.JPG"
path2 = "/Users/liumeiyu/Downloads/test1.jpg"
path3 = "/Users/liumeiyu/Downloads/test2.jpg"

A = Histogram(path1)
B = Smooth(path1)
C = Change(path1)
D = Base(path1)
E = Binary(path1)
F = D_E(path1)
G = Warp(path1)
H = Cvt(path1)
K = Edge_detection(path1)
L = Segmentation(path1)
M = Mosaic(path3)
N = Sampling(path1)
P = Fusion(path1)

# A.img_histogram_trans()
# A.img_histogram()

# B.linear_smooth_np()
# B.linear_smooth()
# B.box_smooth()
# B.gaussian_smooth()
# B.median_smooth()