Exemplo n.º 1
0
    def get_final_properties(self, path):

        outputfile = get_final_abinit_out(path)
        if outputfile is None:
            raise ValueError("Not such dir: %s" % path)

        # Reading the OUTPUT
        abo = AbinitOutput(outputfile)
        dmatpawu = abo.get_dmatpawu()
        odmatpawu = np.array(dmatpawu).reshape(-1, self.ndim, self.ndim)
        oparams = dmatpawu2params(odmatpawu, self.ndim)

        if not abo.is_finished:
            print('This output is not finished')
            return None, None

        data = abo.get_energetics()
        nres2 = data['nres2'][-1]
        etot = data['etot'][-1]

        final_properties = None
        if etot is not None and oparams is not None:
            final_properties = {
                'etot': etot,
                'nres2': nres2,
                'final_dmat': gs(oparams)
            }

        return final_properties, etot
Exemplo n.º 2
0
    def set_final_dmat(self, entry_id, abinitout):
        abo = AbinitOutput(abinitout)
        if not abo.is_finished:
            return None

        dmatpawu = abo.get_dmatpawu()
        if dmatpawu is None:
            return None

        odmatpawu = np.array(dmatpawu).reshape(-1, self.ndim, self.ndim)
        oparams = dmatpawu2params(odmatpawu, self.ndim)
        data = abo.get_energetics()
        if data is None:
            return None
        nres2 = data['nres2'][-1]
        etot = data['etot'][-1]

        if not np.all(
                np.sum(oparams['occupations'], axis=1) == np.array(
                    self.num_electrons_dftu)):
            print(
                'ERROR: Inconsistent number of DFT+U electrons for correlated orbitals: %s'
                % entry_id)
            print('From the population      : %s ' % self.num_electrons_dftu)
            print('From %20s :    %s ' % (abinitout, oparams['occupations']))

        return self.pcdb.db.pychemia_entries.update({'_id': entry_id}, {
            '$set': {
                'properties.etot': etot,
                'properties.nres2': nres2,
                'properties.final_dmat': gs(oparams)
            }
        })
Exemplo n.º 3
0
    def get_final_properties(self, path):

        outputfile = get_final_abinit_out(path)
        if outputfile is None:
            raise ValueError("Not such dir: %s" % path)

        # Reading the OUTPUT
        abo = AbinitOutput(outputfile)        
        dmatpawu = abo.get_dmatpawu()
        odmatpawu = np.array(dmatpawu).reshape(-1, self.ndim, self.ndim)
        oparams = dmatpawu2params(odmatpawu, self.ndim)

        if not abo.is_finished:
            print('This output is not finished')
            return None, None

        data = abo.get_energetics()
        nres2 = data['nres2'][-1]
        etot = data['etot'][-1]

        final_properties = None
        if etot is not None and oparams is not None:
            final_properties = {'etot': etot,
                                'nres2': nres2,
                                'final_dmat': gs(oparams)}

        return final_properties, etot
Exemplo n.º 4
0
    def set_final_dmat(self, entry_id, abinitout):
        abo = AbinitOutput(abinitout)
        if not abo.is_finished:
            return None

        dmatpawu = abo.get_dmatpawu()
        if dmatpawu is None:
            return None

        odmatpawu = np.array(dmatpawu).reshape(-1, self.ndim, self.ndim)
        oparams = dmatpawu2params(odmatpawu, self.ndim)
        data = abo.get_energetics()
        if data is None:
            return None
        nres2 = data['nres2'][-1]
        etot = data['etot'][-1]

        if not np.all(np.sum(oparams['occupations'], axis=1) == np.array(self.num_electrons_dftu)):
            print('ERROR: Inconsistent number of DFT+U electrons for correlated orbitals: %s' % entry_id)
            print('From the population      : %s ' % self.num_electrons_dftu)
            print('From %20s :    %s ' % (abinitout, oparams['occupations']))

        return self.pcdb.db.pychemia_entries.update({'_id': entry_id},
                                                    {'$set': {'properties.etot': etot,
                                                              'properties.nres2': nres2,
                                                              'properties.final_dmat': gs(oparams)}})
Exemplo n.º 5
0
def get_final_abinit_out(path):

    if not os.path.isdir(path):
        raise ValueError("ERROR: Could not find folder: %s" % path)

    outputfile = None
    abos = [x for x in os.listdir(path) if x[-3:] in ['txt', 'out']]

    if len(abos) == 0:
        raise ValueError(
            "ERROR: Not suitable ABINIT output files were found ('*out' or '*txt') for path: %s"
            % path)

    # Most recent mtime
    mtime = 0

    for ifile in abos:
        fpath = path + os.sep + ifile
        if os.path.getmtime(fpath) > mtime:
            abo = AbinitOutput(fpath)
            if abo.is_loaded and abo.is_finished:
                mtime = os.path.getmtime(fpath)
                outputfile = fpath

    if outputfile is None:
        print("WARNING: Could not find any good ABINIT output file: %s" % path)

    return outputfile
Exemplo n.º 6
0
    def evaluator(self, pbs_settings, basedir):
        print("Population size: %d" % len(self))
        while True:
            # 1. Get actives no evaluated
            ane = self.actives_no_evaluated
            if len(ane) > 0:
                print("Candidates to be evaluated: %d" % len(ane))
            else:
                print("No candidates to be evaluated")
            # 2. Get jobs in queue
            if 'user' not in pbs_settings:
                raise ValueError(
                    "PBS settings must contain a keys 'user', 'ppn' and 'walltime'"
                )
            username = pbs_settings['user']

            jobs = get_jobs(username)
            jobnames = [jobs[x]['Job_Name'] for x in jobs]
            print("There are %d jobs in the system for user %s " %
                  (len(jobnames), username))
            check = False
            for entry_id in ane:
                if str(entry_id) not in jobnames:
                    check = True
                else:
                    jobids = [
                        jobs[x]['Job_Id'] for x in jobs
                        if jobs[x]['Job_Name'] == str(entry_id)
                    ]
                    for jobid in jobids:
                        check = True
                        if jobs[jobid]['job_state'] != 'C':
                            check = False
                            break

                to_submit = False
                if check:
                    to_submit = True
                    if not os.path.isdir(basedir + os.sep + str(entry_id)):
                        self.prepare_folder(entry_id,
                                            workdir=basedir,
                                            source_dir=basedir)
                    elif os.path.isfile(basedir + os.sep + str(entry_id) +
                                        os.sep + 'COMPLETE'):
                        abinitout = get_final_abinit_out(basedir + os.sep +
                                                         str(entry_id))
                        if abinitout is not None:
                            abo = AbinitOutput(abinitout)
                            # check if finished
                            if abo.is_finished:
                                # Collect results
                                self.collect(entry_id, basedir)
                                to_submit = False

                if to_submit:
                    self.submit(entry_id, basedir, pbs_settings)

            print('Sleeping for 20 minutes')
            time.sleep(1200)
Exemplo n.º 7
0
    def evaluator(self,
                  username,
                  basedir,
                  queue,
                  walltime,
                  ppn,
                  features=None):
        while True:
            # 1. Get actives no evaluated
            ane = self.actives_no_evaluated
            if len(ane) > 0:
                print("Candidates to be evaluated: %d" % len(ane))
            else:
                print("No candidates to be evaluated")
            # 2. Get jobs in queue
            jobs = get_jobs(username)
            jobnames = [jobs[x]['Job_Name'] for x in jobs]
            check = False
            for entry_id in ane:
                if str(entry_id) not in jobnames:
                    check = True
                else:
                    jobids = [
                        jobs[x]['Job_Id'] for x in jobs
                        if jobs[x]['Job_Name'] == str(entry_id)
                    ]
                    for jobid in jobids:
                        check = True
                        if jobs[jobid]['job_state'] != 'C':
                            check = False
                            break

                to_submit = False
                if check:
                    to_submit = True
                    if not os.path.isdir(basedir + os.sep + str(entry_id)):
                        self.prepare_folder(entry_id,
                                            workdir=basedir,
                                            source_dir=basedir)
                    elif os.path.isfile(basedir + os.sep + str(entry_id) +
                                        os.sep + 'COMPLETE'):
                        abinitout = self.get_final_abinit_out(basedir +
                                                              os.sep +
                                                              str(entry_id))
                        if abinitout is not None:
                            abo = AbinitOutput(abinitout)
                            # check if finished
                            if abo.is_finished:
                                # Collect results
                                self.collect(entry_id, basedir)
                                to_submit = False

                if to_submit:
                    self.submit(entry_id, basedir, queue, walltime, ppn,
                                features)

            print('Sleeping for 10 minutes')
            time.sleep(600)
Exemplo n.º 8
0
    def collect_data(self, entry_id, workdir, filename='abinit.out'):

        if os.path.isfile(workdir + os.sep + filename):
            abo = AbinitOutput(workdir + os.sep + filename)
            dmatpawu = abo.get_dmatpawu()
            dmat = dmatpawu2params(dmatpawu, self.ndim)

            if 'etot' in abo.get_energetics():
                etot = abo.get_energetics()['etot'][-1]
                nres2 = abo.get_energetics()['nres2'][-1]
                print('Uploading energy data for %s' % entry_id)
                self.set_final_results(entry_id, dmat, etot, nres2)

                return True
            else:
                return False
        else:
            return False
Exemplo n.º 9
0
    def collect_data(self, entry_id, workdir, filename='abinit.out'):

        if os.path.isfile(workdir + os.sep + filename):
            ao = AbinitOutput(workdir + os.sep + filename)

            dmatpawu = get_final_dmatpawu(workdir + os.sep + filename)
            dmat = dmatpawu2params(dmatpawu, self.ndim)

            if 'etot' in ao.get_energetics():
                etot = ao.get_energetics()['etot'][-1]
                nres2 = ao.get_energetics()['nres2'][-1]
                print('Uploading energy data for %s' % entry_id)
                self.set_final_results(entry_id, dmat, etot, nres2)

                return True
            else:
                return False
        else:
            return False
def check_status(basepath):
    dirs = [x for x in os.listdir(basepath)
            if os.path.isdir(basepath + os.sep + x) and os.path.isfile(basepath + os.sep + x + os.sep + 'abinit.in')]
    print("%-40s %15s %15s %4s" % ("ABINIT output", "ETOT", 'nres2', 'nSCF'))
    for i in dirs:
        path = basepath + os.sep + i
        abinitout = get_final_abinit_out(path)
        if abinitout is None:
            continue

        abo = AbinitOutput(abinitout)
        if not abo.is_finished:
            continue
        try:
            nres2 = abo.get_energetics()['nres2'][-1]
            etot = abo.get_energetics()['etot'][-1]
            nscf = len(abo.get_energetics()['etot'])
            print("%-40s %15.6f %15.6e %4d" % (abinitout, etot, nres2, nscf))
        except:
            print("ERROR: Could not get final energetics from %s" % abinitout)
Exemplo n.º 11
0
def compare_params(path):
    if not os.path.isfile(path + os.sep + 'abinit.in'):
        print('ERROR: No abinit.in found at %s' % path)
        return
    # For making easier to see the values
    np.set_printoptions(linewidth=200, suppress=True)

    # Reading the INPUT
    abi = AbinitInput(path + os.sep + 'abinit.in')

    if 'lpawu' not in abi.variables:
        raise ValueError("Variable lpawu not found")
    ndim = 2 * max(abi['lpawu']) + 1

    idmatpawu = np.array(abi['dmatpawu']).reshape(-1, ndim, ndim)
    iparams = dmatpawu2params(idmatpawu, ndim)

    # Reading the OUTPUT
    abinitout = get_final_abinit_out(path)
    abo = AbinitOutput(abinitout)
    dmatpawu = abo.get_final_dmatpawu()
    odmatpawu = np.array(dmatpawu).reshape(-1, ndim, ndim)
    oparams = dmatpawu2params(odmatpawu, ndim)

    print('DMATPAWU')
    print('input')
    print(idmatpawu)
    print('output')
    print(odmatpawu)

    print('PARAMETRIC REPRESENTATION found at %s' % abinitout)
    for i in sorted(list(iparams.keys())):
        print(i)
        print('input')
        print(iparams[i])
        print('output')
        print(i)
        print(oparams[i])

    abo = AbinitOutput(abinitout)
    if not abo.is_finished:
        print('This output is not finished')
    try:
        nres2 = abo.get_energetics()['nres2'][-1]
        etot = abo.get_energetics()['etot'][-1]
        nscf = len(abo.get_energetics()['etot'])
        print("%30s ETOT: %15.6f NRES2: %15.6e NumSCF: %3d" %
              (path, etot, nres2, nscf))
    except:
        print("ERROR: Could not get energetics from %s" % abinitout)
Exemplo n.º 12
0
def check_status(basepath):
    dirs = [
        x for x in os.listdir(basepath)
        if os.path.isdir(basepath + os.sep +
                         x) and os.path.isfile(basepath + os.sep + x + os.sep +
                                               'abinit.in')
    ]
    print("%-40s %15s %15s %4s" % ("ABINIT output", "ETOT", 'nres2', 'nSCF'))
    for i in dirs:
        path = basepath + os.sep + i
        abinitout = get_final_abinit_out(path)
        if abinitout is None:
            continue

        abo = AbinitOutput(abinitout)
        if not abo.is_finished:
            continue
        try:
            nres2 = abo.get_energetics()['nres2'][-1]
            etot = abo.get_energetics()['etot'][-1]
            nscf = len(abo.get_energetics()['etot'])
            print("%-40s %15.6f %15.6e %4d" % (abinitout, etot, nres2, nscf))
        except:
            print("ERROR: Could not get final energetics from %s" % abinitout)
def compare_params(path):
    if not os.path.isfile(path + os.sep + 'abinit.in'):
        print('ERROR: No abinit.in found at %s' % path)
        return
    # For making easier to see the values
    np.set_printoptions(linewidth=200, suppress=True)

    # Reading the INPUT
    abi = AbinitInput(path + os.sep + 'abinit.in')

    if 'lpawu' not in abi.variables:
        raise ValueError("Variable lpawu not found")
    ndim = 2 * max(abi['lpawu']) + 1

    idmatpawu = np.array(abi['dmatpawu']).reshape(-1, ndim, ndim)
    iparams = dmatpawu2params(idmatpawu, ndim)

    # Reading the OUTPUT
    abinitout = get_final_abinit_out(path)
    abo = AbinitOutput(abinitout)
    dmatpawu = abo.get_final_dmatpawu()
    odmatpawu = np.array(dmatpawu).reshape(-1, ndim, ndim)
    oparams = dmatpawu2params(odmatpawu, ndim)

    print('DMATPAWU')
    print('input')
    print(idmatpawu)
    print('output')
    print(odmatpawu)

    print('PARAMETRIC REPRESENTATION found at %s' % abinitout)
    for i in sorted(list(iparams.keys())):
        print(i)
        print('input')
        print(iparams[i])
        print('output')
        print(i)
        print(oparams[i])

    abo = AbinitOutput(abinitout)
    if not abo.is_finished:
        print('This output is not finished')
    try:
        nres2 = abo.get_energetics()['nres2'][-1]
        etot = abo.get_energetics()['etot'][-1]
        nscf = len(abo.get_energetics()['etot'])
        print("%30s ETOT: %15.6f NRES2: %15.6e NumSCF: %3d" % (path, etot, nres2, nscf))
    except:
        print("ERROR: Could not get energetics from %s" % abinitout)
Exemplo n.º 14
0
            print("Renaming abinit.err")
            os.rename('abinit.err', 'abinit_%02d.err' % index)
        if os.path.isfile('abinit-o_WFK'):
            print("Renaming abinit-o_WFK")
            os.rename('abinit-o_WFK', 'abinit-i_WFK')
        if os.path.isfile('abinit.out'):
            print("Renaming abinit.out")
            shutil.copy2('abinit.out', 'abinit_%02d.txt' % index)
            os.rename('abinit.out', 'abinit_%02d.out' % index)
            abiout = 'abinit_%02d.out' % index
        else:
            print("Could not find abinit.out")

        # Opening the output file
        print("Reading the output from 'abinit.out'...")
        abo = AbinitOutput(abiout)
        if not abo.is_finished:
            print(
                "abinit.out is truncated, discarting that output redoing the calculation"
            )
            continue

        # The final density matrix is build from the outputi
        ndim = 2 * max(abi['lpawu']) + 1

        params = dmatpawu2params(abi['dmatpawu'], ndim)
        print("Euler angles from 'abinit.in':")
        for i in params['euler_angles']:
            for j in i:
                print(" %7.3f" % j, end=' ')
            print("\n", end='')
Exemplo n.º 15
0
def plot_status(basepath):
    dirs = [
        x for x in os.listdir(basepath)
        if os.path.isdir(basepath + os.sep +
                         x) and os.path.isfile(basepath + os.sep + x + os.sep +
                                               'abinit.in')
    ]

    abi = AbinitInput(basepath + os.sep + 'abinit.in')
    nstep = abi['nstep']

    print('Plotting Status...')
    xx = {}
    yy = {}

    # Get the data:
    max_nruns = 0
    for path in dirs:
        xx[path] = np.array([])
        yy[path] = {}
        yy[path]['nres2'] = np.array([])
        yy[path]['etot'] = np.array([])
        yy[path]['delta'] = np.array([])

        for i in range(100):
            if os.path.isfile(basepath + os.sep + path + os.sep +
                              'abinit_%02d.txt' % i):
                abo = AbinitOutput(basepath + os.sep + path + os.sep +
                                   'abinit_%02d.txt' % i)
                if not abo.is_finished:
                    print('This output is not finished')
                    continue
                if max_nruns < i:
                    max_nruns = i
                try:
                    energ = abo.get_energetics()
                except:
                    raise RuntimeError("Failed procesing: %s" %
                                       (basepath + os.sep + path + os.sep +
                                        'abinit_%02d.txt' % i))

                nres2 = energ['nres2'][-1]
                etot = energ['etot'][-1]
                nscf = len(energ['etot'])
                x = np.arange(nstep * i, nstep * i + len(energ['nres2']))
                yetot = np.array(energ['etot'])
                ynres2 = np.array(energ['nres2'])
                ydelta = np.array(np.abs(energ['deltaEh']))
                xx[path] = np.concatenate((xx[path], x))
                yy[path]['etot'] = np.concatenate((yy[path]['etot'], yetot))
                yy[path]['nres2'] = np.concatenate((yy[path]['nres2'], ynres2))
                yy[path]['delta'] = np.concatenate((yy[path]['delta'], ydelta))
                print("%s ETOT:%15.6f NRES2=%15.6e Num SCF=%3d" %
                      (path, etot, nres2, nscf))

    # RESIDUAL
    plt.figure(figsize=(8, 11))
    miny = 1E-1
    maxy = 1E-16
    plt.subplots_adjust(left=0.1,
                        bottom=0.05,
                        right=0.99,
                        top=0.99,
                        wspace=None,
                        hspace=None)
    for path in dirs:
        if len(xx) > 0:
            plt.semilogy(xx[path], yy[path]['nres2'], label=path[-4:], lw=0.1)
            if miny > min(yy[path]['nres2']):
                miny = min(yy[path]['nres2'])
            if maxy < max(yy[path]['nres2']):
                maxy = max(yy[path]['nres2'])

    plt.ylim(miny, maxy)

    for i in nstep * np.arange(max_nruns + 1):
        plt.semilogy([i, i], [miny, maxy], '0.5', lw=0.1)

    plt.xlim(0, max([max(xx[path]) for path in dirs]))
    plt.legend()
    plt.xlabel("SCF iteration")
    plt.ylabel("Density Residual$^2$")
    plt.savefig('Orbital_Residual.pdf')

    # ETOT
    miny = 1E6
    maxy = -1E6
    avg = 0
    minlen = 100
    plt.figure(figsize=(8, 11))
    for path in dirs:
        if len(xx) > 0:
            plt.plot(xx[path], yy[path]['etot'], label=path[-4:])
            if len(yy[path]['etot']) < minlen:
                minlen = len(yy[path]['etot'])
                avg = np.average(yy[path]['etot'][-int(minlen / 2):])
            if miny > min(yy[path]['etot'][-int(minlen / 2):]):
                miny = min(yy[path]['etot'][-int(minlen / 2):])
            if maxy < max(yy[path]['etot'][-int(minlen / 2):]):
                maxy = max(yy[path]['etot'][-int(minlen / 2):])

    plt.subplots_adjust(left=0.15,
                        bottom=0.05,
                        right=0.95,
                        top=0.95,
                        wspace=None,
                        hspace=None)

    newminy = miny - 0.1 * (maxy - miny)
    newmaxy = maxy + 0.1 * (maxy - miny)
    miny = newminy
    maxy = newmaxy

    plt.ylim(miny, maxy)
    for i in nstep * np.arange(max_nruns + 1):
        plt.plot([i, i], [miny, maxy], '0.5', lw=0.1)

    plt.xlim(0, max([max(xx[path]) for path in dirs]))
    plt.legend()
    plt.xlabel("SCF iteration")
    plt.ylabel("Energy")
    plt.savefig('Orbital_ETotal.pdf')

    # deltaEh
    plt.figure(figsize=(8, 11))
    miny = 1E-1
    for path in dirs:
        if len(xx) > 0:
            plt.semilogy(xx[path], yy[path]['delta'], label=path[-4:], lw=0.1)
            if miny > min(yy[path]['delta']):
                miny = min(yy[path]['delta'])

    plt.subplots_adjust(left=0.1,
                        bottom=0.05,
                        right=0.99,
                        top=0.99,
                        wspace=None,
                        hspace=None)

    for i in nstep * np.arange(max_nruns + 1):
        plt.semilogy([i, i], [miny, 1E3], '0.5', lw=0.1)

    plt.ylim(miny, 1E3)
    plt.xlim(0, max([max(xx[path]) for path in dirs]))
    plt.legend()
    plt.xlabel("SCF iteration")
    plt.ylabel("Delta Energy")
    plt.savefig('Orbital_deltaEh.pdf')
def plot_status(basepath):
    dirs = [x for x in os.listdir(basepath)
            if os.path.isdir(basepath + os.sep + x) and os.path.isfile(basepath + os.sep + x + os.sep + 'abinit.in')]

    abi = AbinitInput(basepath + os.sep + 'abinit.in')
    nstep = abi['nstep']

    print('Plotting Status...')
    xx = {}
    yy = {}

    # Get the data:
    max_nruns = 0
    for path in dirs:
        xx[path] = np.array([])
        yy[path] = {}
        yy[path]['nres2'] = np.array([])
        yy[path]['etot'] = np.array([])
        yy[path]['delta'] = np.array([])

        for i in range(100):
            if os.path.isfile(basepath + os.sep + path + os.sep + 'abinit_%02d.txt' % i):
                abo = AbinitOutput(basepath + os.sep + path + os.sep + 'abinit_%02d.txt' % i)
                if not abo.is_finished:
                    print('This output is not finished')
                    continue
                if max_nruns < i:
                    max_nruns = i
                try:
                    energ = abo.get_energetics()
                except:
                    raise RuntimeError(
                        "Failed procesing: %s" % (basepath + os.sep + path + os.sep + 'abinit_%02d.txt' % i))

                nres2 = energ['nres2'][-1]
                etot = energ['etot'][-1]
                nscf = len(energ['etot'])
                x = np.arange(nstep * i, nstep * i + len(energ['nres2']))
                yetot = np.array(energ['etot'])
                ynres2 = np.array(energ['nres2'])
                ydelta = np.array(np.abs(energ['deltaEh']))
                xx[path] = np.concatenate((xx[path], x))
                yy[path]['etot'] = np.concatenate((yy[path]['etot'], yetot))
                yy[path]['nres2'] = np.concatenate((yy[path]['nres2'], ynres2))
                yy[path]['delta'] = np.concatenate((yy[path]['delta'], ydelta))
                print("%s ETOT:%15.6f NRES2=%15.6e Num SCF=%3d" % (path, etot, nres2, nscf))

    # RESIDUAL
    plt.figure(figsize=(8, 11))
    miny = 1E-1
    maxy = 1E-16
    plt.subplots_adjust(left=0.1, bottom=0.05, right=0.99, top=0.99,
                        wspace=None, hspace=None)
    for path in dirs:
        if len(xx) > 0:
            plt.semilogy(xx[path], yy[path]['nres2'], label=path[-4:], lw=0.1)
            if miny > min(yy[path]['nres2']):
                miny = min(yy[path]['nres2'])
            if maxy < max(yy[path]['nres2']):
                maxy = max(yy[path]['nres2'])

    plt.ylim(miny, maxy)

    for i in nstep * np.arange(max_nruns + 1):
        plt.semilogy([i, i], [miny, maxy], '0.5', lw=0.1)

    plt.xlim(0, max([max(xx[path]) for path in dirs]))
    plt.legend()
    plt.xlabel("SCF iteration")
    plt.ylabel("Density Residual$^2$")
    plt.savefig('Orbital_Residual.pdf')

    # ETOT
    miny = 1E6
    maxy = -1E6
    avg = 0
    minlen = 100
    plt.figure(figsize=(8, 11))
    for path in dirs:
        if len(xx) > 0:
            plt.plot(xx[path], yy[path]['etot'], label=path[-4:])
            if len(yy[path]['etot']) < minlen:
                minlen = len(yy[path]['etot'])
                avg = np.average(yy[path]['etot'][-int(minlen / 2):])
            if miny > min(yy[path]['etot'][-int(minlen / 2):]):
                miny = min(yy[path]['etot'][-int(minlen / 2):])
            if maxy < max(yy[path]['etot'][-int(minlen / 2):]):
                maxy = max(yy[path]['etot'][-int(minlen / 2):])

    plt.subplots_adjust(left=0.15, bottom=0.05, right=0.95, top=0.95,
                        wspace=None, hspace=None)

    newminy = miny - 0.1 * (maxy - miny)
    newmaxy = maxy + 0.1 * (maxy - miny)
    miny = newminy
    maxy = newmaxy

    plt.ylim(miny, maxy)
    for i in nstep * np.arange(max_nruns + 1):
        plt.plot([i, i], [miny, maxy], '0.5', lw=0.1)

    plt.xlim(0, max([max(xx[path]) for path in dirs]))
    plt.legend()
    plt.xlabel("SCF iteration")
    plt.ylabel("Energy")
    plt.savefig('Orbital_ETotal.pdf')

    # deltaEh
    plt.figure(figsize=(8, 11))
    miny = 1E-1
    for path in dirs:
        if len(xx) > 0:
            plt.semilogy(xx[path], yy[path]['delta'], label=path[-4:], lw=0.1)
            if miny > min(yy[path]['delta']):
                miny = min(yy[path]['delta'])

    plt.subplots_adjust(left=0.1, bottom=0.05, right=0.99, top=0.99,
                        wspace=None, hspace=None)

    for i in nstep * np.arange(max_nruns + 1):
        plt.semilogy([i, i], [miny, 1E3], '0.5', lw=0.1)

    plt.ylim(miny, 1E3)
    plt.xlim(0, max([max(xx[path]) for path in dirs]))
    plt.legend()
    plt.xlabel("SCF iteration")
    plt.ylabel("Delta Energy")
    plt.savefig('Orbital_deltaEh.pdf')