Ejemplo n.º 1
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 def test_nandivide(self):
     foo = ch.array(np.random.randn(16).reshape((4, 4)))
     bar = ch.array(np.random.randn(16).reshape((4, 4)))
     bar[2, 2] = 0
     self.assertEqual(ch.NanDivide(foo, bar)[2, 2].r, 0.)
     foo[2, 2] = 0
     self.assertEqual(ch.NanDivide(foo, bar)[2, 2].r, 0.)
Ejemplo n.º 2
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 def test_nandivide(self):
     foo = ch.array(np.random.randn(16).reshape((4,4)))
     bar = ch.array(np.random.randn(16).reshape((4,4)))
     bar[2,2] = 0
     self.assertEqual(ch.NanDivide(foo,bar)[2,2].r, 0.)
     foo[2,2] = 0
     self.assertEqual(ch.NanDivide(foo,bar)[2,2].r, 0.)
Ejemplo n.º 3
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    def test_svd(self):
        mtx = ch.array(np.random.randn(100).reshape((10, 10)))

        # Get times for svd
        from linalg import svd
        u, s, v = svd(mtx)

        def setup():
            mtx.x = -mtx.x

        def go_r():
            _ = u.r
            _ = s.r
            _ = v.r

        def go_dr():
            _ = u.dr_wrt(mtx)
            _ = s.dr_wrt(mtx)
            _ = v.dr_wrt(mtx)

        cht_r = timer(setup, go_r, 20)
        cht_dr = timer(setup, go_dr, 1)

        # Get times for numpy svd
        def go():
            u, s, v = np.linalg.svd(mtx.x)

        npt = timer(setup=None, go=go, n=20)

        # Compare
        #print cht_r / npt
        #print cht_dr / npt
        self.assertLess(cht_r / npt, 3.3)
        self.assertLess(cht_dr / npt, 2700)
Ejemplo n.º 4
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    def test_sum_mean_std_var(self):
        for fn in [ch.sum, ch.mean, ch.var, ch.std]:

            # Create fake input and differences in input space
            data1 = ch.ones((3,4,7,2))
            data2 = ch.array(data1.r + .1 * np.random.rand(data1.size).reshape(data1.shape))
            diff = data2.r - data1.r

            # Compute outputs
            result1 = fn(data1, axis=2)
            result2 = fn(data2, axis=2)

            # Empirical and predicted derivatives
            gt = result2.r - result1.r
            pred = result1.dr_wrt(data1).dot(diff.ravel()).reshape(gt.shape)

            #print np.max(np.abs(gt - pred))

            if fn in [ch.std, ch.var]:
                self.assertTrue(1e-2 > np.max(np.abs(gt - pred)))
            else:
                self.assertTrue(1e-14 > np.max(np.abs(gt - pred)))
                # test caching
                dr0 = result1.dr_wrt(data1)
                data1[:] = np.random.randn(data1.size).reshape(data1.shape)
                self.assertTrue(result1.dr_wrt(data1) is dr0) # changing values shouldn't force recompute
                result1.axis=1
                self.assertTrue(result1.dr_wrt(data1) is not dr0)

        self.assertEqual(ch.mean(ch.eye(3),axis=1).ndim, np.mean(np.eye(3),axis=1).ndim)
        self.assertEqual(ch.mean(ch.eye(3),axis=0).ndim, np.mean(np.eye(3),axis=0).ndim)
        self.assertEqual(ch.sum(ch.eye(3),axis=1).ndim, np.sum(np.eye(3),axis=1).ndim)
        self.assertEqual(ch.sum(ch.eye(3),axis=0).ndim, np.sum(np.eye(3),axis=0).ndim)
Ejemplo n.º 5
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    def test_svd(self):
        mtx = ch.array(np.random.randn(100).reshape((10,10)))


        # Get times for svd
        from linalg import svd
        u, s, v = svd(mtx)
        def setup():
            mtx.x = -mtx.x

        def go_r():
            _ = u.r
            _ = s.r
            _ = v.r

        def go_dr():
            _ = u.dr_wrt(mtx)
            _ = s.dr_wrt(mtx)
            _ = v.dr_wrt(mtx)

        cht_r = timer(setup, go_r, 20)
        cht_dr = timer(setup, go_dr, 1)

        # Get times for numpy svd
        def go():
            u,s,v = np.linalg.svd(mtx.x)
        npt = timer(setup = None, go = go, n = 20)

        # Compare
        #print cht_r / npt
        #print cht_dr / npt
        self.assertLess(cht_r / npt, 3.3)
        self.assertLess(cht_dr / npt, 2700)
Ejemplo n.º 6
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    def test_sum_mean_std_var(self):
        for fn in [ch.sum, ch.mean,ch.var, ch.std]:
            
            # Create fake input and differences in input space
            data1 = ch.ones((3,4,7,2))
            data2 = ch.array(data1.r + .1 * np.random.rand(data1.size).reshape(data1.shape))
            diff = data2.r - data1.r

            # Compute outputs
            result1 = fn(data1, axis=2)
            result2 = fn(data2, axis=2)

            # Empirical and predicted derivatives
            gt = result2.r - result1.r
            pred = result1.dr_wrt(data1).dot(diff.ravel()).reshape(gt.shape)
            
            #print np.max(np.abs(gt - pred))
            
            if fn in [ch.std, ch.var]:
                self.assertTrue(1e-2 > np.max(np.abs(gt - pred)))        
            else:
                self.assertTrue(1e-14 > np.max(np.abs(gt - pred)))        
                # test caching
                dr0 = result1.dr_wrt(data1)
                data1[:] = np.random.randn(data1.size).reshape(data1.shape)
                self.assertTrue(result1.dr_wrt(data1) is dr0) # changing values shouldn't force recompute
                result1.axis=1
                self.assertTrue(result1.dr_wrt(data1) is not dr0)
            
        self.assertEqual(ch.mean(ch.eye(3),axis=1).ndim, np.mean(np.eye(3),axis=1).ndim)
        self.assertEqual(ch.mean(ch.eye(3),axis=0).ndim, np.mean(np.eye(3),axis=0).ndim)
        self.assertEqual(ch.sum(ch.eye(3),axis=1).ndim, np.sum(np.eye(3),axis=1).ndim)
        self.assertEqual(ch.sum(ch.eye(3),axis=0).ndim, np.sum(np.eye(3),axis=0).ndim)
Ejemplo n.º 7
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 def test_cachehits(self):
     """Test how many nodes are visited when cache is cleared. 
     If the number of hits changes, it has to be carefully
     looked at to make sure that correctness and performance
     don't get messed up by a change."""
     
     a = ch.array(1)
     b = ch.array(2)
     c = a
     for i in range(10):
         c = a + c + b
 
     c.dr_wrt(a)
     c.dr_wrt(b)
     self.assertEqual(a.clear_cache() + b.clear_cache(), 59)
     c.dr_wrt(a)
     c.dr_wrt(b)
     self.assertEqual(a.clear_cache(123) + b.clear_cache(123), 41)
Ejemplo n.º 8
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    def test_cachehits(self):
        """Test how many nodes are visited when cache is cleared. 
        If the number of hits changes, it has to be carefully
        looked at to make sure that correctness and performance
        don't get messed up by a change."""

        a = ch.array(1)
        b = ch.array(2)
        c = a
        for i in range(10):
            c = a + c + b

        c.dr_wrt(a)
        c.dr_wrt(b)
        self.assertEqual(a.clear_cache() + b.clear_cache(), 59)
        c.dr_wrt(a)
        c.dr_wrt(b)
        self.assertEqual(a.clear_cache(123) + b.clear_cache(123), 41)
Ejemplo n.º 9
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 def test_cumsum(self):
     a = ch.array([1.,5.,3.,7.])
     cs = ch.cumsum(a)
     r1 = cs.r
     dr = cs.dr_wrt(a)
     diff = (ch.random.rand(4)-.5)*.1
     a.x += diff.r
     pred = dr.dot(diff.r)
     gt = cs.r - r1
     self.assertTrue(1e-13 > np.max(np.abs(gt - pred)))
Ejemplo n.º 10
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 def test_cumsum(self):
     a = ch.array([1., 5., 3., 7.])
     cs = ch.cumsum(a)
     r1 = cs.r
     dr = cs.dr_wrt(a)
     diff = (ch.random.rand(4) - .5) * .1
     a.x += diff.r
     pred = dr.dot(diff.r)
     gt = cs.r - r1
     self.assertTrue(1e-13 > np.max(np.abs(gt - pred)))
Ejemplo n.º 11
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    def test_iteration_cache(self):
        """ Each time you set an attribute, the cache (of r's and dr's) of 
        ancestors is cleared. Because children share ancestors, this means
        these can be cleared multiple times unnecessarily; in some cases, 
        where lots of objects exist, this cache clearing can actually be a bottleneck.
        
        Therefore, the concept of an iteration was added; intended to be used in 
        an optimization setting (see optimization.py) and in the set() method, it 
        avoids such redundant clearing of cache."""
        
        a, b, c = ch.Ch(1), ch.Ch(2), ch.Ch(3)
        x = a+b
        y = x+c
        self.assertTrue(y.r[0]==6)
        
        a.__setattr__('x', 10, 1)
        self.assertTrue(y.r == 15)
        a.__setattr__('x', 100, 1)
        self.assertTrue(y.r == 15) 
        a.__setattr__('x', 100, 2)
        self.assertTrue(y.r == 105)  

        a, b, c = ch.array([1]), ch.array([2]), ch.array([3])
        x = a+b
        y = x+c
        self.assertTrue(y.r[0]==6)
        
        a.__setattr__('x', np.array([10]), 1)
        self.assertTrue(y.r[0] == 15)
        a.__setattr__('x', np.array(100), 1)
        self.assertTrue(y.r[0] == 15) 
        a.__setattr__('x', np.array(100), 2)
        self.assertTrue(y.r[0] == 105)  
        a.__setitem__(range(0,1), np.array(200), 2)
        self.assertTrue(y.r[0] == 105)        
        a.__setitem__(range(0,1), np.array(200), 3)
        self.assertTrue(y.r[0] == 205)        
Ejemplo n.º 12
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    def test_iteration_cache(self):
        """ Each time you set an attribute, the cache (of r's and dr's) of 
        ancestors is cleared. Because children share ancestors, this means
        these can be cleared multiple times unnecessarily; in some cases, 
        where lots of objects exist, this cache clearing can actually be a bottleneck.
        
        Therefore, the concept of an iteration was added; intended to be used in 
        an optimization setting (see optimization.py) and in the set() method, it 
        avoids such redundant clearing of cache."""

        a, b, c = ch.Ch(1), ch.Ch(2), ch.Ch(3)
        x = a + b
        y = x + c
        self.assertTrue(y.r[0] == 6)

        a.__setattr__('x', 10, 1)
        self.assertTrue(y.r == 15)
        a.__setattr__('x', 100, 1)
        self.assertTrue(y.r == 15)
        a.__setattr__('x', 100, 2)
        self.assertTrue(y.r == 105)

        a, b, c = ch.array([1]), ch.array([2]), ch.array([3])
        x = a + b
        y = x + c
        self.assertTrue(y.r[0] == 6)

        a.__setattr__('x', np.array([10]), 1)
        self.assertTrue(y.r[0] == 15)
        a.__setattr__('x', np.array(100), 1)
        self.assertTrue(y.r[0] == 15)
        a.__setattr__('x', np.array(100), 2)
        self.assertTrue(y.r[0] == 105)
        a.__setitem__(range(0, 1), np.array(200), 2)
        self.assertTrue(y.r[0] == 105)
        a.__setitem__(range(0, 1), np.array(200), 3)
        self.assertTrue(y.r[0] == 205)
Ejemplo n.º 13
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    def test_stacking(self):

        a1 = ch.Ch(np.arange(10).reshape(2, 5))
        b1 = ch.Ch(np.arange(20).reshape(4, 5))
        c1 = ch.vstack((a1, b1))
        c1_check = np.vstack((a1.r, b1.r))
        residuals1 = (c1_check - c1.r).ravel()

        a2 = ch.Ch(np.arange(10).reshape(5, 2))
        b2 = ch.Ch(np.arange(20).reshape(5, 4))
        c2 = ch.hstack((a2, b2))
        c2_check = np.hstack((a2.r, b2.r))
        residuals2 = (c2_check - c2.r).ravel()

        self.assertFalse(np.any(residuals1))
        self.assertFalse(np.any(residuals2))

        d0 = ch.array(np.arange(60).reshape((10, 6)))
        d1 = ch.vstack((d0[:4], d0[4:]))
        d2 = ch.hstack((d1[:, :3], d1[:, 3:]))
        tmp = d2.dr_wrt(d0).todense()
        diff = tmp - np.eye(tmp.shape[0])
        self.assertFalse(np.any(diff.ravel()))
Ejemplo n.º 14
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    def test_stacking(self):

        a1 = ch.Ch(np.arange(10).reshape(2,5))
        b1 = ch.Ch(np.arange(20).reshape(4,5))
        c1 = ch.vstack((a1,b1))
        c1_check = np.vstack((a1.r, b1.r))
        residuals1 = (c1_check - c1.r).ravel()
        
        
        a2 = ch.Ch(np.arange(10).reshape(5,2))
        b2 = ch.Ch(np.arange(20).reshape(5,4))
        c2 = ch.hstack((a2,b2))
        c2_check = np.hstack((a2.r, b2.r))
        residuals2 = (c2_check - c2.r).ravel()
        
        self.assertFalse(np.any(residuals1))
        self.assertFalse(np.any(residuals2))
        
        d0 = ch.array(np.arange(60).reshape((10,6)))
        d1 = ch.vstack((d0[:4], d0[4:]))
        d2 = ch.hstack((d1[:,:3], d1[:,3:]))
        tmp = d2.dr_wrt(d0).todense()
        diff = tmp - np.eye(tmp.shape[0])
        self.assertFalse(np.any(diff.ravel()))
Ejemplo n.º 15
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 def test_make_sure_is_double(self):
     x = ch.array([0])
     self.assertTrue(isinstance(x.r[0], np.float64))
Ejemplo n.º 16
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 def test_casting(self):
     for fn in float, int:
         self.assertEqual(fn(np.array(5)),     fn(ch.array(5)))
         self.assertEqual(fn(np.array([[5]])), fn(ch.array([[5]])))
Ejemplo n.º 17
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 def setUp(self):
     np.random.seed(0)
     self.mtx_10 = ch.array(np.random.randn(100).reshape((10,10)))
     self.mtx_1k = ch.array(np.random.randn(1000000).reshape((1000,1000)))
Ejemplo n.º 18
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 def setUp(self):
     np.random.seed(0)
     self.mtx_10 = ch.array(np.random.randn(100).reshape((10, 10)))
     self.mtx_1k = ch.array(np.random.randn(1000000).reshape((1000, 1000)))
Ejemplo n.º 19
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 def test_make_sure_is_double(self):
     x = ch.array([0])
     self.assertTrue(isinstance(x.r[0], np.float64))
Ejemplo n.º 20
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 def test_casting(self):
     for fn in float, int:
         self.assertEqual(fn(np.array(5)), fn(ch.array(5)))
         self.assertEqual(fn(np.array([[5]])), fn(ch.array([[5]])))