def __init__(self, opt=None): super(ELBOLoss, self).__init__() self.log = Logger(*ELBOLoss.params) self._log = Logger(*ELBOLoss.params) self.kld = None self.nll = None self.opt = opt
class Validator: params = ['shd', 'tpr', 'fpr', 'err'] def __init__(self, st_truth): self.log = Logger(*Validator.params) self.st_truth = st_truth self.n_nodes = self.st_truth.A.shape[-1] self.n_edges = len(self.st_truth.A.nonzero()) self.l1 = torch.sum(torch.abs(self.st_truth.A)).item() def validate(self, st_learned): shd, tpr, fpr, _, _ = count_accuracy(self.st_truth.A.numpy(), st_learned.topk(self.n_edges).numpy()) err = adjacency_error(self.st_truth.A.numpy(), st_learned.A.numpy()) self.log.append(self.logger(shd, tpr, fpr, err)) def logger(self, shd, tpr, fpr, err): return dict(zip(Validator.params, (shd, tpr, fpr, err))) def print_summary(self): print(3*" "+print_format([self.log])) def get_logger(self, var): if var in Validator.params: return self.log else: raise ValueError("invalid parameter %s"%var)
def __init__(self, acyc, coeffs, opt=None): super(InteractionLoss, self).__init__() self.log = Logger(*InteractionLoss.params) self._log = Logger(*InteractionLoss.params) self.norm = lambda x: torch.sum(torch.abs(x)) self.acyc = acyc self.coeffs = coeffs self.adj = None self.quad = None self.reg = None self.opt = opt
def __init__(self, mask, chain, opt, beta=1.0, gamma=500.0, reg=0.2): super(InfoLoss, self).__init__() self.log = Logger(*InfoLoss.params) self._log = Logger(*InfoLoss.params) self.mask = mask self.chain = tuple(chain) self.opt = opt self.beta = beta self.gamma = gamma self.reg = reg self.mmd = None self.nll = None
class ELBOLoss(nn.Module): params = ['elbo', 'kld', 'nll'] def __init__(self, opt=None): super(ELBOLoss, self).__init__() self.log = Logger(*ELBOLoss.params) self._log = Logger(*ELBOLoss.params) self.kld = None self.nll = None self.opt = opt def __call__(self, x, z, xx): self.kld = Losses.kld(z) self.nll = Losses.nll(x, xx) self._log.append(self.logger()) if self.opt is not None: loss = self.kld + self.nll loss.backward() self.opt.step() self.opt.optimizer.zero_grad() else: return self.kld, self.nll def evolve(self): self.log.append(self._log.mean()) self._log.clear() if self.opt is not None: self.opt.evolve() def logger(self): kld, nll = self.kld.item(), self.nll.item() return dict(zip(ELBOLoss.params, (kld + nll, kld, nll))) def print_summary(self): print(3 * " " + print_format([self.log, self.opt.log], log10=True)) def get_logger(self, var): if var in ELBOLoss.params: return self.log elif var in OptimModule.params: return self.opt.log else: raise ValueError("invalid parameter %s" % var)
class InteractionLoss(nn.Module): params = ['h', 'l1'] def __init__(self, acyc, coeffs, opt=None): super(InteractionLoss, self).__init__() self.log = Logger(*InteractionLoss.params) self._log = Logger(*InteractionLoss.params) self.norm = lambda x: torch.sum(torch.abs(x)) self.acyc = acyc self.coeffs = coeffs self.adj = None self.quad = None self.reg = None self.opt = opt @classmethod def poly(cls, n_nodes, **coeffs): acyc = lambda x: InteractionLoss.h_poly(x, n_nodes) return cls(acyc, Coefficients(**coeffs)) @classmethod def ordered(cls, node_dict, **coeffs): acyc = lambda x: InteractionLoss.h_ordered(x, node_dict) return cls(acyc, Coefficients(**coeffs)) def __call__(self, adj): self.quad = self.coeffs.l * self.acyc( adj) + 0.5 * self.coeffs.c * self.acyc(adj)**2 self.reg = self.coeffs.tau * self.norm( adj) + self.coeffs.tr * torch.trace(adj**2) self.adj = adj.detach() self._log.append(self.logger()) if self.opt is not None: loss = self.quad + self.reg loss.backward() self.opt.step() self.opt.optimizer.zero_grad() else: return self.quad, self.reg def evolve(self): self.log.append(self._log.last()) self._log.clear() self.coeffs.log.append(self.coeffs.logger()) if self.opt is not None: self.opt.evolve() def logger(self): return { 'h': self.acyc(self.adj).item(), 'l1': self.norm(self.adj).item() } def get_logger(self, var): if var in InteractionLoss.params: return self.log elif var in OptimModule.params: return self.opt.log else: raise ValueError("invalid parameter %s" % var) @staticmethod def h_poly(adj, n_nodes): alpha = (1 / n_nodes) x = torch.eye(n_nodes) + alpha * (adj**2) return torch.trace(torch.matrix_power(x, n_nodes)) - n_nodes @staticmethod def h_ordered(adj, node_dict): h, step = 0.0, 0 for t, X in node_dict.items(): h += torch.sum(adj[step:, step:step + len(X)]**2) step += len(X) return h
class InfoLoss(nn.Module): params = ['elbo', 'mmd', 'nll'] def __init__(self, mask, chain, opt, beta=1.0, gamma=500.0, reg=0.2): super(InfoLoss, self).__init__() self.log = Logger(*InfoLoss.params) self._log = Logger(*InfoLoss.params) self.mask = mask self.chain = tuple(chain) self.opt = opt self.beta = beta self.gamma = gamma self.reg = reg self.mmd = None self.nll = None def __call__(self, x, z, zz, xx): std_norm = rand_norm(0.0, 1.0, z.shape[0], z.shape[1]).unsqueeze(-1).double() self.mmd = self.beta * Losses.cmmd(z, std_norm) self.mmd += self.gamma * ( Losses.cmmd( zz, z, endo=self.chain[0:1], exo=self.chain[1:2], l=self.reg) + Losses.cmmd( zz, z, endo=self.chain[1:2], exo=self.chain[2:3], l=self.reg) + Losses.cmmd( zz, z, endo=self.chain[0:1], exo=self.chain[2:3], l=self.reg)) self.nll = Losses.nll(x, xx) self._log.append(self.logger()) if self.opt is not None: loss = self.mmd + self.nll loss.backward() self.opt.step() self.opt.optimizer.zero_grad() else: return self.mmd, self.nll def evolve(self): self.log.append(self._log.mean()) self._log.clear() if self.opt is not None: self.opt.evolve() def logger(self): mmd, nll = self.mmd.item(), self.nll.item() return dict(zip(InfoLoss.params, (mmd + nll, mmd, nll))) def print_summary(self): print(3 * " " + print_format([self.log, self.opt.log], log10=True)) def get_logger(self, var): if var in InfoLoss.params: return self.log elif var in OptimModule.params: return self.opt.log else: raise ValueError("invalid parameter %s" % var)
def __init__(self, st_truth): self.log = Logger(*Validator.params) self.st_truth = st_truth self.n_nodes = self.st_truth.A.shape[-1] self.n_edges = len(self.st_truth.A.nonzero()) self.l1 = torch.sum(torch.abs(self.st_truth.A)).item()