mirror of
https://gitlab.com/scemama/qp_plugins_scemama.git
synced 2024-12-23 04:43:38 +01:00
615 lines
20 KiB
Python
615 lines
20 KiB
Python
import sys, os
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QMCCHEM_PATH=os.environ["QMCCHEM_PATH"]
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sys.path.insert(0,QMCCHEM_PATH+"/EZFIO/Python/")
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from ezfio import ezfio
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from datetime import datetime
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import time
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import numpy as np
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import subprocess
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from scipy.linalg import eig, eigh
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# ~ ! ~ ! ~ ! ~ ! ~ ! ~ ! ~ ! ~ ! ~ ! ~ ! ~ ! ~ ! ~ ! ~ ! ~ ! ~ ! ~ ! ~ ! ~ ! ~ ! ~ !
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def get_energy():
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buffer = subprocess.check_output( ['qmcchem', 'result', '-e', 'e_loc', filename]
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, encoding='UTF-8' )
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if buffer.strip() != "":
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buffer = buffer.splitlines()[-1]
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_, energy, error = [float(x) for x in buffer.split()]
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return energy, error
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else:
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return None, None
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# ~ ! ~ ! ~ ! ~ ! ~ ! ~ ! ~ ! ~ ! ~ ! ~ ! ~ ! ~ ! ~ ! ~ ! ~ ! ~ ! ~ ! ~ ! ~ ! ~ ! ~ !
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# ~ ! ~ ! ~ ! ~ ! ~ ! ~ ! ~ ! ~ ! ~ ! ~ ! ~ ! ~ ! ~ ! ~ ! ~ ! ~ ! ~ ! ~ ! ~ ! ~ ! ~ !
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def run_qmc():
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return subprocess.check_output(['qmcchem', 'run', filename])
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def stop_qmc():
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subprocess.check_output(['qmcchem', 'stop', filename])
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def set_vmc_params():
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#subprocess.check_output(['qmcchem', 'edit', '-c', '-j', 'Simple',
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# '-m', 'VMC',
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# '-l', str(20),
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# '--time-step=0.3',
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# '--stop-time=36000',
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# '--norm=1.e-5',
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# '-w', '10',
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# filename])
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subprocess.check_output(['qmcchem', 'edit', '-c'
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, '-j', 'None'
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, '-l', str(block_time)
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, '-t', str(total_time)
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, filename])
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# ~ ! ~ ! ~ ! ~ ! ~ ! ~ ! ~ ! ~ ! ~ ! ~ ! ~ ! ~ ! ~ ! ~ ! ~ ! ~ ! ~ ! ~ ! ~ ! ~ ! ~ !
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# ~ ! ~ ! ~ ! ~ ! ~ ! ~ ! ~ ! ~ ! ~ ! ~ ! ~ ! ~ ! ~ ! ~ ! ~ ! ~ ! ~ ! ~ ! ~ ! ~ ! ~ !
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def get_Aref():
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Aref = np.zeros( (n_alpha, n_beta) )
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for k in range(n_det):
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i = A_rows[k] - 1
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j = A_cols[k] - 1
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Aref[i,j] = A_vals[0][k]
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return( Aref )
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# ~ ! ~ ! ~ ! ~ ! ~ ! ~ ! ~ ! ~ ! ~ ! ~ ! ~ ! ~ ! ~ ! ~ ! ~ ! ~ ! ~ ! ~ ! ~ ! ~ ! ~ !
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# ~ ! ~ ! ~ ! ~ ! ~ ! ~ ! ~ ! ~ ! ~ ! ~ ! ~ ! ~ ! ~ ! ~ ! ~ ! ~ ! ~ ! ~ ! ~ ! ~ ! ~ !
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def check_svd_error( A, U, S, V ):
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# || A - U x S x transpose(V) ||
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# to normalize
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norm_A = np.linalg.norm(A, ord='fro')
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# vector S ==> matrix S
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_, na = U.shape
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_, nb = V.shape
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S_mat = np.zeros( (na,nb) )
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for i in range( min(na,nb) ):
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S_mat[i,i] = S[i]
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#A_SVD = np.linalg.multi_dot([ U, np.diag(S), Vt ])
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A_SVD = np.linalg.multi_dot([ U, S_mat, V.T ])
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err_SVD = 100. * np.linalg.norm( A - A_SVD, ord="fro") / norm_A
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print(' error between A_SVD and Aref = {} %\n'.format(err_SVD) )
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# ~ ! ~ ! ~ ! ~ ! ~ ! ~ ! ~ ! ~ ! ~ ! ~ ! ~ ! ~ ! ~ ! ~ ! ~ ! ~ ! ~ ! ~ ! ~ ! ~ ! ~ !
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# ~ ! ~ ! ~ ! ~ ! ~ ! ~ ! ~ ! ~ ! ~ ! ~ ! ~ ! ~ ! ~ ! ~ ! ~ ! ~ ! ~ ! ~ ! ~ ! ~ ! ~ !
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def FSVD_save_EZFIO():
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U_toEZFIO = np.zeros( ( 1, U_FSVD.shape[1], U_FSVD.shape[0] ) )
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V_toEZFIO = np.zeros( ( 1, V_FSVD.shape[1], V_FSVD.shape[0] ) )
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U_toEZFIO[0,:,:] = U_FSVD.T
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V_toEZFIO[0,:,:] = V_FSVD.T
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ezfio.set_spindeterminants_psi_svd_alpha_unique( U_toEZFIO )
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ezfio.set_spindeterminants_psi_svd_beta_unique ( V_toEZFIO )
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ezfio.set_spindeterminants_psi_svd_coefs_unique( S_FSVD )
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print(' Full SVD unique vectors & coeff are saved to EZFIO ')
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# ~ ! ~ ! ~ ! ~ ! ~ ! ~ ! ~ ! ~ ! ~ ! ~ ! ~ ! ~ ! ~ ! ~ ! ~ ! ~ ! ~ ! ~ ! ~ ! ~ ! ~ !
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# ~ ! ~ ! ~ ! ~ ! ~ ! ~ ! ~ ! ~ ! ~ ! ~ ! ~ ! ~ ! ~ ! ~ ! ~ ! ~ ! ~ ! ~ ! ~ ! ~ ! ~ !
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def numerote_selected_vectors():
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numalpha_selected = []
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numbeta_selected = []
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for i in range(n_TSVD):
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for j in range(n_TSVD):
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numalpha_selected.append(j+1)
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numbeta_selected.append(i+1)
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if( (len(numalpha_selected)!=n_selected) or (len(numbeta_selected)!=n_selected) ) :
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print(' error in numerating selectod vectors')
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print(' {} != {} != {}'.format(n_selected,len(numalpha_selected),len(numbeta_selected)) )
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else:
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ezfio.set_spindeterminants_psi_svd_alpha_numselected(numalpha_selected)
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ezfio.set_spindeterminants_psi_svd_beta_numselected (numbeta_selected)
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print(' selected vectors are numeroted in EZFIO')
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return( numalpha_selected,numbeta_selected )
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# ~ ! ~ ! ~ ! ~ ! ~ ! ~ ! ~ ! ~ ! ~ ! ~ ! ~ ! ~ ! ~ ! ~ ! ~ ! ~ ! ~ ! ~ ! ~ ! ~ ! ~ !
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# ~ ! ~ ! ~ ! ~ ! ~ ! ~ ! ~ ! ~ ! ~ ! ~ ! ~ ! ~ ! ~ ! ~ ! ~ ! ~ ! ~ ! ~ ! ~ ! ~ ! ~ !
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def numerote_toselect_vectors( choix ):
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numalpha_toselect = []
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numbeta_toselect = []
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if( choix == 3 ):
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# nondiagonal blocs
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for i in range(n_TSVD):
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for j in range(n_TSVD,n_beta):
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numalpha_toselect.append(i+1)
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numbeta_toselect.append(j+1)
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for i in range(n_TSVD,n_alpha):
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for j in range(n_TSVD):
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numalpha_toselect.append(i+1)
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numbeta_toselect.append(j+1)
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# diagonal bloc
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for i in range(n_TSVD,n_alpha):
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for j in range(n_TSVD,n_beta):
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numalpha_toselect.append(i+1)
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numbeta_toselect.append(j+1)
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elif( choix == 2 ):
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# nondiagonal blocs
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for i in range(n_TSVD):
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for j in range(n_TSVD,n_beta):
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numalpha_toselect.append(i+1)
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numbeta_toselect.append(j+1)
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for i in range(n_TSVD,n_alpha):
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for j in range(n_TSVD):
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numalpha_toselect.append(i+1)
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numbeta_toselect.append(j+1)
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else:
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print(' choix = 2 ou 3' )
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exit()
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if( (len(numalpha_toselect)!=n_toselect) or (len(numbeta_toselect)!=n_toselect) ) :
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print(' error in numerating vectors to select')
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print(' {} != {} != {}'.format(n_toselect,len(numalpha_toselect),len(numbeta_toselect)) )
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else:
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ezfio.set_spindeterminants_psi_svd_alpha_numtoselect(numalpha_toselect)
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ezfio.set_spindeterminants_psi_svd_beta_numtoselect (numbeta_toselect)
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print(' vectors to select are numeroted in EZFIO')
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return( numalpha_toselect,numbeta_toselect )
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# ~ ! ~ ! ~ ! ~ ! ~ ! ~ ! ~ ! ~ ! ~ ! ~ ! ~ ! ~ ! ~ ! ~ ! ~ ! ~ ! ~ ! ~ ! ~ ! ~ ! ~ !
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# ~ ! ~ ! ~ ! ~ ! ~ ! ~ ! ~ ! ~ ! ~ ! ~ ! ~ ! ~ ! ~ ! ~ ! ~ ! ~ ! ~ ! ~ ! ~ ! ~ ! ~ !
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def normalize_S_TSVD():
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global S_TSVD
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norm_S_TSVD = np.linalg.norm(S_TSVD, ord='fro')
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S_TSVD = S_TSVD / norm_S_TSVD
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return()
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# ~ ! ~ ! ~ ! ~ ! ~ ! ~ ! ~ ! ~ ! ~ ! ~ ! ~ ! ~ ! ~ ! ~ ! ~ ! ~ ! ~ ! ~ ! ~ ! ~ ! ~ !
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# ~ ! ~ ! ~ ! ~ ! ~ ! ~ ! ~ ! ~ ! ~ ! ~ ! ~ ! ~ ! ~ ! ~ ! ~ ! ~ ! ~ ! ~ ! ~ ! ~ ! ~ !
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def get_h_selected_matrix():
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h_selected_matrix = np.zeros( (n_selected,n_selected) )
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h_selected_stater = np.zeros( (n_selected,n_selected) )
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beg_h_selected_matrix = results.find('h_selected_matrix : [ ') + len('h_selected_matrix : [ ')
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end_h_selected_matrix = len(results)
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h_selected_matrix_buf = results[beg_h_selected_matrix:end_h_selected_matrix]
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h_selected_matrix_buf = h_selected_matrix_buf.split( '\n' )
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for i in range(1,n_selected+1):
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ii0 = (i-1) * n_selected
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for j in range(1,n_selected+1):
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iline = ii0 + j
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line = h_selected_matrix_buf[iline].split()
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indc = int ( line[0] )
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if( indc != iline ):
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print('Error in get_h_selected_matrix')
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exit()
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else:
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h_selected_matrix[i-1][j-1] = float( line[2] )
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h_selected_stater[i-1][j-1] = float( line[4] )
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return(h_selected_matrix,h_selected_stater)
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# ~ ! ~ ! ~ ! ~ ! ~ ! ~ ! ~ ! ~ ! ~ ! ~ ! ~ ! ~ ! ~ ! ~ ! ~ ! ~ ! ~ ! ~ ! ~ ! ~ ! ~ !
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# ~ ! ~ ! ~ ! ~ ! ~ ! ~ ! ~ ! ~ ! ~ ! ~ ! ~ ! ~ ! ~ ! ~ ! ~ ! ~ ! ~ ! ~ ! ~ ! ~ ! ~ !
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def get_o_selected_matrix():
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o_selected_matrix = np.zeros( (n_selected,n_selected) )
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o_selected_stater = np.zeros( (n_selected,n_selected) )
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beg_o_selected_matrix = results.find('overlop_selected_matrix : [ ') + len('overlop_selected_matrix : [ ')
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end_o_selected_matrix = len(results)
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o_selected_matrix_buf = results[beg_o_selected_matrix:end_o_selected_matrix]
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o_selected_matrix_buf = o_selected_matrix_buf.split( '\n' )
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for i in range(1,n_selected+1):
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ii0 = (i-1) * n_selected
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for j in range(1,n_selected+1):
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iline = ii0 + j
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line = o_selected_matrix_buf[iline].split()
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indc = int ( line[0] )
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if( indc != iline ):
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print('Error in get_o_selected_matrix')
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exit()
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else:
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o_selected_matrix[i-1][j-1] = float( line[2] )
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o_selected_stater[i-1][j-1] = float( line[4] )
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return(o_selected_matrix,o_selected_stater)
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# ~ ! ~ ! ~ ! ~ ! ~ ! ~ ! ~ ! ~ ! ~ ! ~ ! ~ ! ~ ! ~ ! ~ ! ~ ! ~ ! ~ ! ~ ! ~ ! ~ ! ~ !
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# ~ ! ~ ! ~ ! ~ ! ~ ! ~ ! ~ ! ~ ! ~ ! ~ ! ~ ! ~ ! ~ ! ~ ! ~ ! ~ ! ~ ! ~ ! ~ ! ~ ! ~ !
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def get_Epostsvd():
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# symmetrise and diagonalise
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aa = h_selected_matrix
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aa = 0.5*( aa + aa.T )
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bb = o_selected_matrix
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eigvals_postsvd, vr = eig(aa, bb, left=False, right=True, overwrite_a=True, overwrite_b=True,
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check_finite=True, homogeneous_eigvals=False)
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d_postsvd = np.diagflat(S_TSVD)
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d_postsvd = d_postsvd.reshape( (1,n_selected*n_selected) )
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recouvre_postsvd = np.abs(d_postsvd @ vr)
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ind_gspostsvd = np.argmax(recouvre_postsvd)
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E_postsvd = eigvals_postsvd[ind_gspostsvd]
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return( E_postsvd, vr[:,ind_gspostsvd] )
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# ~ ! ~ ! ~ ! ~ ! ~ ! ~ ! ~ ! ~ ! ~ ! ~ ! ~ ! ~ ! ~ ! ~ ! ~ ! ~ ! ~ ! ~ ! ~ ! ~ ! ~ !
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# ~ ! ~ ! ~ ! ~ ! ~ ! ~ ! ~ ! ~ ! ~ ! ~ ! ~ ! ~ ! ~ ! ~ ! ~ ! ~ ! ~ ! ~ ! ~ ! ~ ! ~ !
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def Hqmc_svd_diag():
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# read CI_SVD matrices
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Ci_h_matrix_svd = get_Ci_h_matrix_svd()
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Ci_overlap_matrix_svd = get_Ci_overlap_matrix_svd()
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# symmetrise
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aa = Ci_h_matrix_svd
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aa = 0.5*( aa + aa.T )
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bb = Ci_overlap_matrix_svd
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# diagonalise
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eigvals_svd, vr = eig( aa, bb, left=False, right=True
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, overwrite_a=True, overwrite_b=True
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, check_finite=True, homogeneous_eigvals=False)
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recouvre_svd = np.abs( np.dot( S_FSVD, vr) )
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ind_gssvd = np.argmax(recouvre_svd)
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E_svd = eigvals_svd[ind_gssvd] + nuc_energy
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return( E_svd, vr[:,ind_gssvd] )
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# ~ ! ~ ! ~ ! ~ ! ~ ! ~ ! ~ ! ~ ! ~ ! ~ ! ~ ! ~ ! ~ ! ~ ! ~ ! ~ ! ~ ! ~ ! ~ ! ~ ! ~ !
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# ~ ! ~ ! ~ ! ~ ! ~ ! ~ ! ~ ! ~ ! ~ ! ~ ! ~ ! ~ ! ~ ! ~ ! ~ ! ~ ! ~ ! ~ ! ~ ! ~ ! ~ !
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def SVD_postsvd():
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# reshape sigma_postsvd
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sigma_postsvd_mat = np.zeros( (n_selected,n_selected) )
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for i in range(n_TSVD):
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ii = i*n_TSVD
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for j in range(n_TSVD):
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jj = i*n_TSVD + j
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sigma_postsvd_mat[i][j] = sigma_postsvd[jj]
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# construct the new matrix Y & perform a new SVD
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Y = np.dot( U_TSVD , np.dot(sigma_postsvd_mat , Vt_TSVD) )
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U, S, Vt = np.linalg.svd(Y, full_matrices=True)
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return(U, S, Vt)
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# ~ ! ~ ! ~ ! ~ ! ~ ! ~ ! ~ ! ~ ! ~ ! ~ ! ~ ! ~ ! ~ ! ~ ! ~ ! ~ ! ~ ! ~ ! ~ ! ~ ! ~ !
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# ~ ! ~ ! ~ ! ~ ! ~ ! ~ ! ~ ! ~ ! ~ ! ~ ! ~ ! ~ ! ~ ! ~ ! ~ ! ~ ! ~ ! ~ ! ~ ! ~ ! ~ !
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def get_hij_fm():
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hij_fm = np.zeros( (n_toselect) )
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hij_fm_stater = np.zeros( (n_toselect) )
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beg_hij = results.find('hij_fm : [ ') + len('hij_fm : [ ')
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end_hij = len(results)
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hij_buf = results[beg_hij:end_hij]
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hij_buf = hij_buf.split( '\n' )
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for iline in range(1,n_toselect+1):
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line = hij_buf[iline].split()
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indc = int( line[0] )
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if( indc != iline ):
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print('Error in get_hij_fm')
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exit()
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else:
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hij_fm [iline-1] = float( line[2] )
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hij_fm_stater[iline-1] = float( line[4] )
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return(hij_fm, hij_fm_stater)
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# ~ ! ~ ! ~ ! ~ ! ~ ! ~ ! ~ ! ~ ! ~ ! ~ ! ~ ! ~ ! ~ ! ~ ! ~ ! ~ ! ~ ! ~ ! ~ ! ~ ! ~ !
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# ~ ! ~ ! ~ ! ~ ! ~ ! ~ ! ~ ! ~ ! ~ ! ~ ! ~ ! ~ ! ~ ! ~ ! ~ ! ~ ! ~ ! ~ ! ~ ! ~ ! ~ !
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def get_hij_sm():
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hij_sm = np.zeros( (n_toselect) )
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hij_sm_stater = np.zeros( (n_toselect) )
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beg_hij = results.find('hij_sm : [ ') + len('hij_sm : [ ')
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end_hij = len(results)
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hij_buf = results[beg_hij:end_hij]
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hij_buf = hij_buf.split( '\n' )
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for iline in range(1,n_toselect+1):
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line = hij_buf[iline].split()
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indc = int( line[0] )
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if( indc != iline ):
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print('Error in get_hij_sm')
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exit()
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else:
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hij_sm [iline-1] = float( line[2] )
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hij_sm_stater[iline-1] = float( line[4] )
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return(hij_sm, hij_sm_stater)
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# ~ ! ~ ! ~ ! ~ ! ~ ! ~ ! ~ ! ~ ! ~ ! ~ ! ~ ! ~ ! ~ ! ~ ! ~ ! ~ ! ~ ! ~ ! ~ ! ~ ! ~ !
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# ~ ! ~ ! ~ ! ~ ! ~ ! ~ ! ~ ! ~ ! ~ ! ~ ! ~ ! ~ ! ~ ! ~ ! ~ ! ~ ! ~ ! ~ ! ~ ! ~ ! ~ !
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def get_xij_diag():
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xij_diag = np.zeros( (n_toselect) )
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xij_diag_stater = np.zeros( (n_toselect) )
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beg_xij = results.find('xij_diag : [ ') + len('xij_diag : [ ')
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end_xij = len(results)
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xij_buf = results[beg_xij:end_xij]
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xij_buf = xij_buf.split( '\n' )
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for iline in range(1,n_toselect+1):
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line = xij_buf[iline].split()
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indc = int( line[0] )
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if( indc != iline ):
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print('Error in get_xij_diag')
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exit()
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else:
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xij_diag [iline-1] = float( line[2] )
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xij_diag_stater[iline-1] = float( line[4] )
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return(xij_diag, xij_diag_stater)
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# ~ ! ~ ! ~ ! ~ ! ~ ! ~ ! ~ ! ~ ! ~ ! ~ ! ~ ! ~ ! ~ ! ~ ! ~ ! ~ ! ~ ! ~ ! ~ ! ~ ! ~ !
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if __name__ == '__main__':
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t0 = time.time()
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print("Today's date:", datetime.now() )
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# EZFIO file
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filename = "/home/aammar/qp2/src/svdwf/2h2_work/2h2_cisd"
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ezfio.set_file(filename)
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print("filename = {}".format(filename))
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# parameters
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energ_nuc = 1.711353545183182 # for 2h2
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# get spindeterminant data from EZFIO
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n_alpha = ezfio.get_spindeterminants_n_det_alpha()
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n_beta = ezfio.get_spindeterminants_n_det_beta()
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A_rows = np.array(ezfio.get_spindeterminants_psi_coef_matrix_rows() )
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A_cols = np.array(ezfio.get_spindeterminants_psi_coef_matrix_columns())
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A_vals = np.array(ezfio.get_spindeterminants_psi_coef_matrix_values() )
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n_det = A_rows.shape[0]
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print('~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~')
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print(' matrix: {} x {}'.format(n_alpha,n_beta))
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print(' n_det = {}'.format(n_det))
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print('~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~')
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# construct intial dense matrix
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Aref = get_Aref()
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# perform initial Full SVD
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print('')
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print(' ----- Performing Full SVD ----- ')
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U_FSVD, S_FSVD, Vt_FSVD = np.linalg.svd(Aref, full_matrices=True)
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V_FSVD = Vt_FSVD.T
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# check Full SVD error
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check_svd_error( Aref, U_FSVD, S_FSVD, V_FSVD )
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# save SVD vectors & coefficients in EZFIO
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ezfio.set_spindeterminants_n_svd_coefs_unique(min(n_alpha,n_beta))
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FSVD_save_EZFIO()
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# truncated SVD
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n_TSVD = 15
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ezfio.set_spindeterminants_n_svd_coefs(n_TSVD)
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U_TSVD = U_FSVD[:,:n_TSVD]
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V_TSVD = V_FSVD[:,:n_TSVD]
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S_TSVD = S_FSVD[:n_TSVD]
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# check truncataed SVD error
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check_svd_error( Aref, U_TSVD, S_TSVD, V_TSVD )
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# numerote selected vectors & save to EZFIO
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n_selected = n_TSVD * n_TSVD
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print(' n_selected = {}'.format(n_selected))
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ezfio.set_spindeterminants_n_svd_selected(n_selected)
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numalpha_selected,numbeta_selected = numerote_selected_vectors()
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# numerote vectors to select & save to EZFIO
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n_toselect = n_alpha * n_beta - n_selected
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print(' n_toselect = {}'.format(n_toselect))
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ezfio.set_spindeterminants_n_svd_toselect(n_toselect)
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numalpha_toselect,numbeta_toselect = numerote_toselect_vectors(choix=3)
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#_________________________________________________________________________________________
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#
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# loop over SVD iterations
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#_________________________________________________________________________________________
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it_svd = 0
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it_svd_max = 1
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while( it_svd < it_svd_max ):
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it_svd = it_svd + 1
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# normalize sigular values in the truncated space
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#normalize_S_TSVD()
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# run QMC to get H_postsvd
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block_time = 300 # in sec
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total_time = 1800 # in sec
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set_vmc_params()
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ezfio.set_properties_hij_fm(False)
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ezfio.set_properties_hij_sm(False)
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ezfio.set_properties_xij_diag(False)
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ezfio.set_properties_h_selected_matrix(True)
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ezfio.set_properties_overlop_selected_matrix(True)
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run_qmc()
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# read QMC=CHEM results
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t_read = time.time()
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print(' getting QMCCHEM results from {}'.format(EZFIO_file) )
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results = subprocess.check_output(['qmcchem', 'result', EZFIO_file, '>> results.dat'], encoding='UTF-8')
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print(' getting results after {} minutes \n'.format( (time.time()-t_read)/60. ))
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# < E_loc >
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Eloc, ErrEloc = get_energy()
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print(' Eloc = {} +/- {}'.format(Eloc, ErrEloc))
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# get H and overlop from QMC=CHEM
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h_selected_matrix, h_selected_stater = get_h_selected_matrix()
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o_selected_matrix, o_selected_stater = get_o_selected_matrix()
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# ground state from H S = E S
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E_postsvd, sigma_postsvd = get_Epostsvd()
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print(' post svd energy = {}'.format(E_postsvd+energ_nuc) )
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# perform new SVD: U x sigma_postsvd x Vt --> U' x S' x Vt'
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U_FSVD, S_FSVD, Vt_FSVD = SVD_postsvd()
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V_FSVD = Vt_FSVD.T
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# save in EZFIO
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FSVD_save_EZFIO()
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# run QMC to get hij, e and xij_diag from QMC=CHEM
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block_time = 300 # in sec
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total_time = 1800 # in sec
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set_vmc_params()
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ezfio.set_properties_h_selected_matrix(False)
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ezfio.set_properties_overlop_selected_matrix(False)
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ezfio.set_properties_hij_fm(True)
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ezfio.set_properties_hij_sm(True)
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ezfio.set_properties_xij_diag(True)
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run_qmc()
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# read QMC=CHEM results
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t_read = time.time()
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print(' getting QMCCHEM results from {}'.format(EZFIO_file) )
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results = subprocess.check_output(['qmcchem', 'result', EZFIO_file, '>> results.dat'], encoding='UTF-8')
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print(' getting results after {} minutes \n'.format( (time.time()-t_read)/60. ))
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# < E_loc >
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Eloc, ErrEloc = get_energy()
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print(' Eloc = {} +/- {}'.format(Eloc, ErrEloc))
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# hij = < psi_svd J | H | J l l' > / < psi_svd J | psi_svd J >
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# = < H (J l l')/(psi_svd J) > ( first method: fm )
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# = < E_loc (l l') / psi_svd > ( second method: sm )
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hij_fm, hif_fm_stater = get_hij_fm()
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hij_sm, hif_sm_stater = get_hij_sm()
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# get xij_diag
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xij_diag, xij_diag_stater = get_xij_diag()
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# first method
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dij_fm = np.zeros( (n_toselect) )
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dij_fm_stater = np.zeros( (n_toselect) )
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for i in range(n_toselect):
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dij_fm[i] = hij_fm[i] / ( Eloc - xij_diag[i] )
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# statistic error
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a = ( hij_fm_stater[i]*hij_fm_stater[i] ) / ( hij_fm[i]*hij_fm[i] )
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b = ( ErrEloc*ErrEloc + xij_diag_stater[i]*xij_diag_stater[i] ) / ( (Eloc-xij_diag[i])*(Eloc-xij_diag[i]) )
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dij_fm_stater[i] = abs(dij_fm[i]) * np.sqrt( a + b )
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cc = np.concatenate((dij_fm,dij_fm_stater),axis=1)
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np.savetxt('dij_fm.txt',cc)
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# second method
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dij_sm = np.zeros( (n_toselect) )
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dij_sm_stater = np.zeros( (n_toselect) )
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for i in range(n_toselect):
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dij_sm[i] = hij_sm[i] / ( Eloc - xij_diag[i] )
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# statistic error
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a = ( hij_fm_stater[i]*hij_fm_stater[i] ) / ( hij_sm[i]*hij_sm[i] )
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b = ( ErrEloc*ErrEloc + xij_diag_stater[i]*xij_diag_stater[i] ) / ( (Eloc-xij_diag[i])*(Eloc-xij_diag[i]) )
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dij_sm_stater[i] = abs(dij_sm[i]) * np.sqrt( a + b )
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cc = np.concatenate((dij_sm,dij_sm_stater),axis=1)
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np.savetxt('dij_sm.txt',cc)
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# TODO
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# choose fm or sm & perform a new SVD
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#_________________________________________________________________________________________
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print("end after {:.3f} minutes".format((time.time()-t0)/60.) )
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