示例#1
0
def solve(A, b, factor, r, regParam):
    n = A.shape[0]
    L = ctf.cholesky(A + regParam * ctf.eye(n))
    factor = ctf.solve_tri(L, b.reshape((n, 1)), True, True, False)
    factor = ctf.solve_tri(L, factor, True, True, True).reshape((n, ))

    return factor
示例#2
0
def run_bench(num_iter, s, k):
    wrld = ctf.comm()
    M = ctf.random.random((s,s))
    X = ctf.random.random((k,s))
    [U,S,VT] = ctf.svd(M)
    S = np.arange(0,s)+1
    M = ctf.dot(U*S,U.T())
    te = ctf.timer_epoch("BENCHMARK: SPD SOLVE")
    te.begin()
    times = []
    for i in range(num_iter):
        t0 = time.time()
        X = ctf.solve_spd(M,X)
        times.append(time.time()-t0)
    te.end()
    if ctf.comm().rank() == 0:
        print("ctf.solve_spd average time:",np.sum(times)/num_iter,"sec")
        print("ctf.solve_spd iteration timings:",times)
    te = ctf.timer_epoch("BENCHMARK: Manual Cholesky+TRSM SPD SOLVE")
    te.begin()
    times = []
    for i in range(num_iter):
        t0 = time.time()
        L = ctf.cholesky(M)
        X = ctf.solve_tri(M,X,from_left=False)
        times.append(time.time()-t0)
    te.end()
    if ctf.comm().rank() == 0:
        print("ctf.cholesky+solve_tri average time:",np.sum(times)/num_iter,"sec")
        print("ctf.cholesky+solve_tri iteration timings:",times)
示例#3
0
文件: test_la.py 项目: kabicm/ctf
    def test_solve_tri(self):
        n = 4
        m = 7
        for dt in [numpy.float32, numpy.float64]:
            B = ctf.random.random((n,m))
            B = ctf.astensor(B,dtype=dt)
            L = ctf.random.random((n,n))
            L = ctf.astensor(L,dtype=dt)
            L = ctf.tril(L)
            D = L.T() * L
            D.i("ii") << -1.0*L.i("ii")*L.i("ii")
            self.assertTrue(abs(ctf.vecnorm(D))<= 1.e-6)
            X = ctf.solve_tri(L,B)
            self.assertTrue(allclose(B, ctf.dot(L,X)))

            U = ctf.random.random((n,n))
            U = ctf.astensor(U,dtype=dt)
            U = ctf.triu(U)
            D = U.T() * U
            D.i("ii") << -1.0*U.i("ii")*U.i("ii")
            self.assertTrue(abs(ctf.vecnorm(D))<= 1.e-6)
            X = ctf.solve_tri(U,B,False)
            self.assertTrue(allclose(B, ctf.dot(U,X)))

            U = ctf.random.random((m,m))
            U = ctf.astensor(U,dtype=dt)
            U = ctf.triu(U)
            D = U.T() * U
            D.i("ii") << -1.0*U.i("ii")*U.i("ii")
            self.assertTrue(abs(ctf.vecnorm(D))<= 1.e-6)
            X = ctf.solve_tri(U,B,False,False)
            self.assertTrue(allclose(B, ctf.dot(X,U)))

            U = ctf.random.random((m,m))
            U = ctf.astensor(U,dtype=dt)
            U = ctf.triu(U)
            D = U.T() * U
            D.i("ii") << -1.0*U.i("ii")*U.i("ii")
            self.assertTrue(abs(ctf.vecnorm(D))<= 1.e-6)
            X = ctf.solve_tri(U,B,False,False,True)
            self.assertTrue(allclose(B, ctf.dot(X,U.T())))
def solve_tri(A, B, lower=True, from_left=False, transp_L=False):
    return ctf.solve_tri(A, B, lower, from_left, transp_L)