mirror of
https://github.com/arsenetar/dupeguru.git
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315 lines
9.8 KiB
Python
315 lines
9.8 KiB
Python
# Created By: Virgil Dupras
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# Created On: 2006/09/01
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# Copyright 2010 Hardcoded Software (http://www.hardcoded.net)
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#
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# This software is licensed under the "BSD" License as described in the "LICENSE" file,
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# which should be included with this package. The terms are also available at
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# http://www.hardcoded.net/licenses/bsd_license
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# The commented out tests are tests for function that have been converted to pure C for speed
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from pytest import raises, skip
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from hscommon.testutil import eq_
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try:
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from ..block import *
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except ImportError:
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skip("Can't import the block module, probably hasn't been compiled.")
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def my_avgdiff(first, second, limit=768, min_iter=3): # this is so I don't have to re-write every call
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return avgdiff(first, second, limit, min_iter)
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BLACK = (0,0,0)
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RED = (0xff,0,0)
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GREEN = (0,0xff,0)
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BLUE = (0,0,0xff)
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class FakeImage:
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def __init__(self, size, data):
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self.size = size
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self.data = data
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def getdata(self):
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return self.data
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def crop(self, box):
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pixels = []
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for i in range(box[1], box[3]):
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for j in range(box[0], box[2]):
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pixel = self.data[i * self.size[0] + j]
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pixels.append(pixel)
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return FakeImage((box[2] - box[0], box[3] - box[1]), pixels)
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def empty():
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return FakeImage((0,0), [])
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def single_pixel(): #one red pixel
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return FakeImage((1, 1), [(0xff,0,0)])
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def four_pixels():
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pixels = [RED,(0,0x80,0xff),(0x80,0,0),(0,0x40,0x80)]
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return FakeImage((2, 2), pixels)
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class TestCasegetblock:
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def test_single_pixel(self):
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im = single_pixel()
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[b] = getblocks2(im, 1)
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eq_(RED,b)
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def test_no_pixel(self):
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im = empty()
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eq_([], getblocks2(im, 1))
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def test_four_pixels(self):
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im = four_pixels()
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[b] = getblocks2(im, 1)
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meanred = (0xff + 0x80) // 4
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meangreen = (0x80 + 0x40) // 4
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meanblue = (0xff + 0x80) // 4
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eq_((meanred,meangreen,meanblue),b)
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# class TCdiff(unittest.TestCase):
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# def test_diff(self):
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# b1 = (10, 20, 30)
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# b2 = (1, 2, 3)
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# eq_(9 + 18 + 27,diff(b1,b2))
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#
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# def test_diff_negative(self):
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# b1 = (10, 20, 30)
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# b2 = (1, 2, 3)
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# eq_(9 + 18 + 27,diff(b2,b1))
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#
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# def test_diff_mixed_positive_and_negative(self):
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# b1 = (1, 5, 10)
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# b2 = (10, 1, 15)
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# eq_(9 + 4 + 5,diff(b1,b2))
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#
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# class TCgetblocks(unittest.TestCase):
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# def test_empty_image(self):
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# im = empty()
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# blocks = getblocks(im,1)
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# eq_(0,len(blocks))
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#
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# def test_one_block_image(self):
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# im = four_pixels()
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# blocks = getblocks2(im, 1)
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# eq_(1,len(blocks))
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# block = blocks[0]
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# meanred = (0xff + 0x80) // 4
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# meangreen = (0x80 + 0x40) // 4
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# meanblue = (0xff + 0x80) // 4
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# eq_((meanred,meangreen,meanblue),block)
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#
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# def test_not_enough_height_to_fit_a_block(self):
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# im = FakeImage((2,1), [BLACK, BLACK])
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# blocks = getblocks(im,2)
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# eq_(0,len(blocks))
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#
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# def xtest_dont_include_leftovers(self):
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# # this test is disabled because getblocks is not used and getblock in cdeffed
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# pixels = [
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# RED,(0,0x80,0xff),BLACK,
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# (0x80,0,0),(0,0x40,0x80),BLACK,
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# BLACK,BLACK,BLACK
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# ]
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# im = FakeImage((3,3), pixels)
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# blocks = getblocks(im,2)
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# block = blocks[0]
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# #Because the block is smaller than the image, only blocksize must be considered.
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# meanred = (0xff + 0x80) // 4
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# meangreen = (0x80 + 0x40) // 4
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# meanblue = (0xff + 0x80) // 4
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# eq_((meanred,meangreen,meanblue),block)
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#
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# def xtest_two_blocks(self):
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# # this test is disabled because getblocks is not used and getblock in cdeffed
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# pixels = [BLACK for i in xrange(4 * 2)]
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# pixels[0] = RED
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# pixels[1] = (0,0x80,0xff)
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# pixels[4] = (0x80,0,0)
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# pixels[5] = (0,0x40,0x80)
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# im = FakeImage((4, 2), pixels)
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# blocks = getblocks(im,2)
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# eq_(2,len(blocks))
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# block = blocks[0]
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# #Because the block is smaller than the image, only blocksize must be considered.
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# meanred = (0xff + 0x80) // 4
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# meangreen = (0x80 + 0x40) // 4
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# meanblue = (0xff + 0x80) // 4
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# eq_((meanred,meangreen,meanblue),block)
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# eq_(BLACK,blocks[1])
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#
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# def test_four_blocks(self):
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# pixels = [BLACK for i in xrange(4 * 4)]
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# pixels[0] = RED
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# pixels[1] = (0,0x80,0xff)
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# pixels[4] = (0x80,0,0)
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# pixels[5] = (0,0x40,0x80)
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# im = FakeImage((4, 4), pixels)
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# blocks = getblocks2(im, 2)
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# eq_(4,len(blocks))
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# block = blocks[0]
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# #Because the block is smaller than the image, only blocksize must be considered.
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# meanred = (0xff + 0x80) // 4
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# meangreen = (0x80 + 0x40) // 4
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# meanblue = (0xff + 0x80) // 4
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# eq_((meanred,meangreen,meanblue),block)
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# eq_(BLACK,blocks[1])
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# eq_(BLACK,blocks[2])
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# eq_(BLACK,blocks[3])
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#
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class TestCasegetblocks2:
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def test_empty_image(self):
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im = empty()
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blocks = getblocks2(im,1)
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eq_(0,len(blocks))
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def test_one_block_image(self):
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im = four_pixels()
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blocks = getblocks2(im,1)
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eq_(1,len(blocks))
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block = blocks[0]
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meanred = (0xff + 0x80) // 4
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meangreen = (0x80 + 0x40) // 4
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meanblue = (0xff + 0x80) // 4
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eq_((meanred,meangreen,meanblue),block)
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def test_four_blocks_all_black(self):
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im = FakeImage((2, 2), [BLACK, BLACK, BLACK, BLACK])
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blocks = getblocks2(im,2)
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eq_(4,len(blocks))
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for block in blocks:
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eq_(BLACK,block)
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def test_two_pixels_image_horizontal(self):
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pixels = [RED,BLUE]
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im = FakeImage((2, 1), pixels)
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blocks = getblocks2(im,2)
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eq_(4,len(blocks))
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eq_(RED,blocks[0])
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eq_(BLUE,blocks[1])
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eq_(RED,blocks[2])
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eq_(BLUE,blocks[3])
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def test_two_pixels_image_vertical(self):
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pixels = [RED,BLUE]
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im = FakeImage((1, 2), pixels)
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blocks = getblocks2(im,2)
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eq_(4,len(blocks))
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eq_(RED,blocks[0])
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eq_(RED,blocks[1])
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eq_(BLUE,blocks[2])
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eq_(BLUE,blocks[3])
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class TestCaseavgdiff:
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def test_empty(self):
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with raises(NoBlocksError):
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my_avgdiff([], [])
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def test_two_blocks(self):
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im = empty()
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b1 = (5,10,15)
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b2 = (255,250,245)
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b3 = (0,0,0)
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b4 = (255,0,255)
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blocks1 = [b1,b2]
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blocks2 = [b3,b4]
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expected1 = 5 + 10 + 15
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expected2 = 0 + 250 + 10
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expected = (expected1 + expected2) // 2
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eq_(expected, my_avgdiff(blocks1, blocks2))
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def test_blocks_not_the_same_size(self):
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b = (0,0,0)
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with raises(DifferentBlockCountError):
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my_avgdiff([b,b],[b])
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def test_first_arg_is_empty_but_not_second(self):
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#Don't return 0 (as when the 2 lists are empty), raise!
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b = (0,0,0)
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with raises(DifferentBlockCountError):
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my_avgdiff([],[b])
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def test_limit(self):
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ref = (0,0,0)
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b1 = (10,10,10) #avg 30
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b2 = (20,20,20) #avg 45
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b3 = (30,30,30) #avg 60
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blocks1 = [ref,ref,ref]
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blocks2 = [b1,b2,b3]
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eq_(45,my_avgdiff(blocks1,blocks2,44))
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def test_min_iterations(self):
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ref = (0,0,0)
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b1 = (10,10,10) #avg 30
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b2 = (20,20,20) #avg 45
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b3 = (10,10,10) #avg 40
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blocks1 = [ref,ref,ref]
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blocks2 = [b1,b2,b3]
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eq_(40,my_avgdiff(blocks1,blocks2,45 - 1,3))
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# Bah, I don't know why this test fails, but I don't think it matters very much
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# def test_just_over_the_limit(self):
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# #A score just over the limit might return exactly the limit due to truncating. We should
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# #ceil() the result in this case.
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# ref = (0,0,0)
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# b1 = (10,0,0)
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# b2 = (11,0,0)
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# blocks1 = [ref,ref]
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# blocks2 = [b1,b2]
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# eq_(11,my_avgdiff(blocks1,blocks2,10))
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#
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def test_return_at_least_1_at_the_slightest_difference(self):
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ref = (0,0,0)
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b1 = (1,0,0)
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blocks1 = [ref for i in range(250)]
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blocks2 = [ref for i in range(250)]
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blocks2[0] = b1
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eq_(1,my_avgdiff(blocks1,blocks2))
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def test_return_0_if_there_is_no_difference(self):
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ref = (0,0,0)
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blocks1 = [ref,ref]
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blocks2 = [ref,ref]
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eq_(0,my_avgdiff(blocks1,blocks2))
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# class TCmaxdiff(unittest.TestCase):
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# def test_empty(self):
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# self.assertRaises(NoBlocksError,maxdiff,[],[])
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#
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# def test_two_blocks(self):
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# b1 = (5,10,15)
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# b2 = (255,250,245)
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# b3 = (0,0,0)
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# b4 = (255,0,255)
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# blocks1 = [b1,b2]
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# blocks2 = [b3,b4]
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# expected1 = 5 + 10 + 15
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# expected2 = 0 + 250 + 10
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# expected = max(expected1,expected2)
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# eq_(expected,maxdiff(blocks1,blocks2))
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#
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# def test_blocks_not_the_same_size(self):
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# b = (0,0,0)
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# self.assertRaises(DifferentBlockCountError,maxdiff,[b,b],[b])
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#
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# def test_first_arg_is_empty_but_not_second(self):
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# #Don't return 0 (as when the 2 lists are empty), raise!
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# b = (0,0,0)
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# self.assertRaises(DifferentBlockCountError,maxdiff,[],[b])
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#
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# def test_limit(self):
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# b1 = (5,10,15)
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# b2 = (255,250,245)
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# b3 = (0,0,0)
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# b4 = (255,0,255)
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# blocks1 = [b1,b2]
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# blocks2 = [b3,b4]
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# expected1 = 5 + 10 + 15
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# expected2 = 0 + 250 + 10
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# eq_(expected1,maxdiff(blocks1,blocks2,expected1 - 1))
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# |