def test_submulti(): Graph = ad.ComputationalGraph() x = ad.Node(value=3, Graph=Graph) y = ad.Node(value=2, Graph=Graph) func = 1 + x*5 - 2*y Graph.ComputeValue() Graph.ComputeGradient() assert(func.value, x.deri, y.deri) == (12, 5, -2)
def test_jacobian(): Graph = ad.ComputationalGraph() x = ad.Node(value=3, Graph=Graph) y = ad.Node(value=5, Graph=Graph) z = ad.Node(value=1, Graph=Graph) f = np.array([-2*x, 2*y+z, 3*x+3*y+2*z]) func = ad.ReverseVecFunc(f, x=x, y=y, z=z) val, jacobian = func.value(Graph) assert np.array_equal(val, [-6, 11, 26]) and np.array_equal(jacobian, [[-2, 0, 0], [0, 2, 1], [3, 3, 2]])
def test_jacobian_series(): Graph = ad.ComputationalGraph() x = ad.Node(value=3, Graph=Graph) y = ad.Node(value=4, Graph=Graph) X = [1, 3] Y = [2, 4] C = np.array([X, Y]) D = 2 # Dimension f = np.array([x * 3, 5 * y ** 2]) func = ad.ReverseVecFunc(f, x=x, y=y) vals, derivs = func.Seriesvalue(C, D, Graph) assert np.array_equal(vals, [[3, 20], [9, 80]]) and np.array_equal(derivs, [[[3, 0], [0,20]], [[3, 0], [0, 40]]])
def test_trig1(): Graph = ad.ComputationalGraph() x = ad.Node(value=math.pi, Graph=Graph) func = ad.cosr(x) - ad.sinr(2*x) + ad.tanr(x) Graph.ComputeValue() Graph.ComputeGradient() assert abs(func.value - (-1)) < .000001 and abs(x.deri - (-1)) < .000001
def test_logsqrt(): Graph = ad.ComputationalGraph() x = ad.Node(value=2, Graph=Graph) func = ad.sqrtr(ad.logr(x)) Graph.ComputeValue() Graph.ComputeGradient() assert (func.value, x.deri) == (np.sqrt(np.log(2)), .25 * (1 / (np.sqrt(np.log(2)))))
def test_exp(): Graph = ad.ComputationalGraph() x = ad.Node(value=3, Graph=Graph) func = ad.expr(x) Graph.ComputeValue() Graph.ComputeGradient() assert (func.value, x.deri) == (np.exp(3), np.exp(3))
def test_revpower(): Graph = ad.ComputationalGraph() x = ad.Node(value=2, Graph=Graph) func = 2 - 2**x Graph.ComputeValue() Graph.ComputeGradient() assert(func.value, x.deri) == (-2, -4*np.log(2))
def test_div(): Graph = ad.ComputationalGraph() x = ad.Node(value=5, Graph=Graph) func = 1 / x + x/2 Graph.ComputeValue() Graph.ComputeGradient() assert (func.value, x.deri) == (2.7, .46)
def test_addnegexp(): Graph = ad.ComputationalGraph() x = ad.Node(value=5, Graph=Graph) func = -x + 2*x**2 + 2 Graph.ComputeValue() Graph.ComputeGradient() assert(func.value, x.deri) == (47, 19)
def test_trig3(): Graph = ad.ComputationalGraph() x = ad.Node(value=0, Graph=Graph) func = ad.sinhr(x) + ad.coshr(x) + ad.tanhr(x) Graph.ComputeValue() Graph.ComputeGradient() assert (func.value, x.deri) == (1, 2)
def test_trig2(): Graph = ad.ComputationalGraph() x = ad.Node(value=0, Graph=Graph) func = ad.asinr(x) * ad.acosr(x**2) + 2*ad.atanr(x) Graph.ComputeValue() Graph.ComputeGradient() assert (func.value, x.deri) == (0, 2+np.arccos(0))
def test_series(): Graph = ad.ComputationalGraph() x = ad.Node(value=5, Graph=Graph) f = x ** 2 C = np.array([[4, 2, 3]]) D = 1 Vals, Ders = Graph.SeriesValues(C, D, Graph) assert np.array_equal(Vals, [16, 4, 9]) and np.array_equal(Ders, [[8], [4], [6]])