def test_gaussian_grad1conv_specific(self): ############################################################ from pykeops.numpy.convolutions.radial_kernel import RadialKernelGrad1conv for k, t in itertools.product( ["gaussian", "laplacian", "cauchy", "inverse_multiquadric"], self.type_to_test, ): with self.subTest(k=k, t=t): # Call cuda kernel my_radial_conv = RadialKernelGrad1conv(t) gamma = my_radial_conv( self.a.astype(t), self.x.astype(t), self.y.astype(t), self.b.astype(t), self.sigma.astype(t), kernel=k, ) # Numpy version tmp = differences(self.x, self.y) * grad_np_kernel( self.x, self.y, self.sigma, kernel=k ) gamma_py = 2 * (np.sum(self.a * (np.matmul(tmp, self.b)), axis=2)).T # compare output self.assertTrue(np.allclose(gamma, gamma_py, atol=1e-6))
def test_gaussian_grad1conv_specific(self): #-------------------------------------------------------------------------------------- from pykeops.numpy.convolutions.radial_kernels_grad1 import radial_kernels_grad1conv for k in (["gaussian", "laplacian", "cauchy", "inverse_multiquadric"]): with self.subTest(k=k): # Call cuda kernel gamma = np.zeros(self.D * self.N).astype('float32') radial_kernels_grad1conv( self.a, self.x, self.y, self.b, gamma, self.sigma, kernel=k) # In place, gamma_i = k(x_i,y_j) @ beta_j # Numpy version A = differences(self.x, self.y) * grad_np_kernel( self.x, self.y, self.sigma, kernel=k) gamma_py = 2 * (np.sum(self.a * (np.matmul(A, self.b)), axis=2)).T # compare output self.assertTrue(np.allclose(gamma, gamma_py.ravel(), atol=1e-6))
def test_grad1conv_kernels_feature(self): ############################################################ import torch from pykeops.torch import Kernel, kernel_product params = { 'gamma': 1. / self.sigmac**2, 'mode': 'sum', } if pykeops.config.gpu_available: backend_to_test = ['auto', 'GPU_1D', 'GPU_2D', 'pytorch'] else: backend_to_test = ['auto', 'pytorch'] for k, b in itertools.product( ['gaussian', 'laplacian', 'cauchy', 'inverse_multiquadric'], backend_to_test): with self.subTest(k=k, b=b): params['id'] = Kernel(k + '(x,y)') params['backend'] = b # Call cuda kernel aKxy_b = torch.dot( self.ac.view(-1), kernel_product(params, self.xc, self.yc, self.bc).view(-1)) gamma_keops = torch.autograd.grad(aKxy_b, self.xc, create_graph=False)[0].cpu() # Numpy version A = differences(self.x, self.y) * grad_np_kernel( self.x, self.y, self.sigma, kernel=k) gamma_py = 2 * (np.sum(self.a * (np.matmul(A, self.b)), axis=2)).T # compare output self.assertTrue( np.allclose(gamma_keops.cpu().data.numpy(), gamma_py, atol=1e-6))