def run(self): maxiter = self.options['maxiter'] etol = self.options['etol'] for self.iteration in range(1, maxiter + 1): log.iteration(self.iteration, self.verbose) self.fock_loop() self.build() self.energy() if self.iteration > 1: e_dif = abs(self._energies['tot'][-2] - self._energies['tot'][-1]) if e_dif < etol and self.converged: break self.converged = e_dif < etol if self.converged: log.write( '\nAuxiliary GF2 converged after %d iterations.\n' % self.iteration, self.verbose) else: log.write('\nAuxiliary GF2 failed to converge.\n', self.verbose) self._timings['total'] = self._timings.get('total', 0.0) + self._timer.total() log.title('Timings', self.verbose) log.timings(self._timings, self.verbose) return self
def run(self): self.build() self.merge() self.energy_mp2() self._timings['total'] = self._timings.get('total', 0.0) + self._timer.total() log.title('Timings', self.verbose) log.timings(self._timings, self.verbose) return self
def run(self): self.get_1p_or_1h() self.build() self.merge() self.diagonalise() log.write('E(mp2) = %.12f\n' % self.e_mp2, self.verbose) e_excite = self.ip[0] if self.method == 'ip' else self.ea[0] log.write('E(%s) = %.12f\n' % (self.method, e_excite), self.verbose) self._timings['total'] = self._timings.get('total', 0.0) + self._timer.total() log.title('Timings', self.verbose) log.timings(self._timings, self.verbose) return self
def run(self): maxiter = self.options['maxiter'] etol = self.options['etol'] checkpoint = self.options['checkpoint'] for self.iteration in range(1, maxiter + 1): log.iteration(self.iteration, self.verbose) self.fock_loop() self.build() self.energy() if self.iteration > 1: e_dif = abs(self._energies['tot'][-2] - self._energies['tot'][-1]) if e_dif < etol and self.converged: break self.converged = e_dif < etol if checkpoint and mpi.rank == 0: np.savetxt('rdm1_alph_chk.dat', self.rdm1[0]) np.savetxt('rdm1_beta_chk.dat', self.rdm1[1]) self.se[0].save('se_alph_chk.pickle') self.se[1].save('se_beta_chk.pickle') if self.converged: log.write( '\nAuxiliary GF2 converged after %d iterations.\n' % self.iteration, self.verbose) else: log.write('\nAuxiliary GF2 failed to converge.\n', self.verbose) self._timings['total'] = self._timings.get('total', 0.0) + self._timer.total() log.title('Timings', self.verbose) log.timings(self._timings, self.verbose) return self
def run(self): for self.iteration in range(1, self.options['maxiter'] + 1): log.iteration(self.iteration, self.verbose) self.build_gf() if self.iteration == 1 or self.options['update_w']: self.solve_casida() self.build_se() self.merge() self.energy() if self.options['update_eig']: self.iterate_qp() if self.iteration > 1: e_dif = abs(self._energies['tot'][-2] - \ self._energies['tot'][-1]) if e_dif < self.options['etol'] and self.converged: break self.converged = e_dif < self.options['etol'] if self.converged: log.write( '\nAuxiliary GW converged after %d iterations.\n' % self.iteration, self.verbose) else: log.write('\nAuxiliary GW failed to converge.\n', self.verbose) self._timings['total'] = self._timings.get('total', 0.0) \ + self._timer.total() log.title('Timings', self.verbose) log.timings(self._timings, self.verbose) return self
def test_timings(self): sys.stdout = stdout = StringIO() log.timings({'setup': 0.0}) sys.stdout = sys.__stdout__