Starting script for general 2d lattice dispersion

Former-commit-id: 7e06a50924e1cdc834aaf519db59bad90380cd09
2017-06-28 15:49:38 +03:00 · 2017-06-28 15:49:38 +03:00 · 71d1c6f6b1
parent 37122d0b28
commit 71d1c6f6b1
2 changed files with 239 additions and 0 deletions
--- a/misc/dispersion_hex_chunks.py
+++ b/misc/dispersion_hex_chunks.py
--- a/misc/generaldisp.py
+++ b/misc/generaldisp.py
@ -0,0 +1,239 @@
+#!/usr/bin/env python3
+
+import argparse, re, random, string
+import subprocess
+from scipy.constants import hbar, e as eV, pi, c
+
+def make_action_sharedlist(opname, listname):
+    class opAction(argparse.Action):
+        def __call__(self, parser, args, values, option_string=None):
+            if (not hasattr(args, listname)) or getattr(args, listname) is None:
+                setattr(args, listname, list())
+            getattr(args,listname).append((opname, values))
+    return opAction
+
+parser = argparse.ArgumentParser()
+#TODO? použít type=argparse.FileType('r') ?
+parser.add_argument('--TMatrix', action='store', required=True, help='Path to TMatrix file')
+#parser.add_argument('--griddir', action='store', required=True, help='Path to the directory with precalculated translation operators')
+parser.add_argument('--output_prefix', action='store', required=True, help='Prefix to the npz output (will be appended frequency, hexside and chunkno)')
+#sizepar = parser.add_mutually_exclusive_group(required=True)
+parser.add_argument('--hexside', action='store', type=float, required=True, help='Lattice hexagon size length')
+parser.add_argument('--plot_TMatrix', action='store_true', help='Visualise TMatrix on the first page of the output')
+#parser.add_argument('--SVD_output', action='store', help='Path to output singular value decomposition result')
+parser.add_argument('--maxlayer', action='store', type=int, default=100, help='How far to sum the lattice points to obtain the dispersion')
+parser.add_argument('--scp_to', action='store', metavar='N', type=str, help='SCP the output files to a given destination')
+parser.add_argument('--background_permittivity', action='store', type=float, default=1., help='Background medium relative permittivity (default 1)')
+parser.add_argument('--eVfreq', action='store', required=True, type=float, help='Frequency in eV')
+parser.add_argument('--kdensity', action='store', type=int, default=33, help='Number of k-points per x-axis segment')
+parser.add_argument('--chunklen', action='store', type=int, default=1000, help='Number of k-points per output file (default 1000)')
+parser.add_argument('--lMax', action='store', type=int, help='Override lMax from the TMatrix file')
+#TODO some more sophisticated x axis definitions
+parser.add_argument('--gaussian', action='store', type=float, metavar='σ', help='Use a gaussian envelope for weighting the interaction matrix contributions (depending on the distance), measured in unit cell lengths (?) FIxME).')
+parser.add_argument('--verbose', '-v', action='count', help='Be verbose (about computation times, mostly)')
+popgrp=parser.add_argument_group(title='Operations')
+popgrp.add_argument('--tr', dest='ops', action=make_action_sharedlist('tr', 'ops'), default=list()) # the default value for dest can be set once
+popgrp.add_argument('--tr0', dest='ops', action=make_action_sharedlist('tr0', 'ops'))
+popgrp.add_argument('--tr1', dest='ops', action=make_action_sharedlist('tr1', 'ops'))
+popgrp.add_argument('--sym', dest='ops', action=make_action_sharedlist('sym', 'ops'))
+popgrp.add_argument('--sym0', dest='ops', action=make_action_sharedlist('sym0', 'ops'))
+popgrp.add_argument('--sym1', dest='ops', action=make_action_sharedlist('sym1', 'ops'))
+#popgrp.add_argument('--mult', dest='ops', nargs=3, metavar=('INCSPEC', 'SCATSPEC', 'MULTIPLIER'), action=make_action_sharedlist('mult', 'ops'))
+#popgrp.add_argument('--mult0', dest='ops', nargs=3, metavar=('INCSPEC', 'SCATSPEC', 'MULTIPLIER'), action=make_action_sharedlist('mult0', 'ops'))
+#popgrp.add_argument('--mult1', dest='ops', nargs=3, metavar=('INCSPEC', 'SCATSPEC', 'MULTIPLIER'), action=make_action_sharedlist('mult1', 'ops'))
+popgrp.add_argument('--multl', dest='ops', nargs=3, metavar=('INCL[,INCL,...]', 'SCATL[,SCATL,...]', 'MULTIPLIER'), action=make_action_sharedlist('multl', 'ops'))
+popgrp.add_argument('--multl0', dest='ops', nargs=3, metavar=('INCL[,INCL,...]', 'SCATL[,SCATL,...]', 'MULTIPLIER'), action=make_action_sharedlist('multl0', 'ops'))
+popgrp.add_argument('--multl1', dest='ops', nargs=3, metavar=('INCL[,INCL,...]', 'SCATL[,SCATL,...]', 'MULTIPLIER'), action=make_action_sharedlist('multl1', 'ops'))
+parser.add_argument('--frequency_multiplier', action='store', type=float, default=1., help='Multiplies the frequencies in the TMatrix file by a given factor.')
+# TODO enable more flexible per-sublattice specification
+pargs=parser.parse_args()
+print(pargs)
+
+maxlayer=pargs.maxlayer
+hexside=pargs.hexside
+eVfreq = pargs.eVfreq
+freq = eVfreq*eV/hbar
+verbose=pargs.verbose
+
+TMatrix_file = pargs.TMatrix
+
+epsilon_b = pargs.background_permittivity #2.3104
+gaussianSigma = pargs.gaussian if pargs.gaussian else None # hexside * 222 / 7
+interpfreqfactor = pargs.frequency_multiplier
+scp_dest = pargs.scp_to if pargs.scp_to else None
+kdensity = pargs.kdensity
+chunklen = pargs.chunklen
+
+ops = list()
+opre = re.compile('(tr|sym|copy|multl|mult)(\d*)')
+for oparg in pargs.ops:
+    opm = opre.match(oparg[0])
+    if opm:
+        ops.append(((opm.group(2),) if opm.group(2) else (0,1), opm.group(1), oparg[1]))
+    else:
+        raise # should not happen
+print(ops)
+
+
+# -----------------finished basic CLI parsing (except for op arguments) ------------------
+from qpms.timetrack import _time_b, _time_e
+btime=_time_b(verbose)
+
+import qpms
+import numpy as np
+import os, sys, warnings, math
+from scipy import interpolate
+nx = None
+s3 = math.sqrt(3)
+
+
+# specifikace T-matice zde
+cdn = c/ math.sqrt(epsilon_b)
+TMatrices_orig, freqs_orig, freqs_weirdunits_orig, lMaxTM = qpms.loadScuffTMatrices(TMatrix_file)
+lMax = lMaxTM
+if pargs.lMax:
+    lMax = pargs.lMax if pargs.lMax else lMaxTM    
+my, ny = qpms.get_mn_y(lMax)
+nelem = len(my)
+if pargs.lMax: #force commandline specified lMax
+    TMatrices_orig = TMatrices_orig[...,0:nelem,:,0:nelem]
+
+TMatrices = np.array(np.broadcast_to(TMatrices_orig[:,nx,:,:,:,:],(len(freqs_orig),2,2,nelem,2,nelem)) )
+
+#TMatrices[:,:,:,:,:,ny==3] *= factor13inc
+#TMatrices[:,:,:,ny==3,:,:] *= factor13scat
+xfl = qpms.xflip_tyty(lMax)
+yfl = qpms.yflip_tyty(lMax)
+zfl = qpms.zflip_tyty(lMax)
+c2rot = qpms.apply_matrix_left(qpms.yflip_yy(3),qpms.xflip_yy(3),-1)
+
+reCN = re.compile('(\d*)C(\d+)')
+#TODO C nekonečno
+
+for op in ops:
+    if op[0] == 'all':
+        targets = (0,1)
+    elif isinstance(op[0],int):
+        targets = (op[0],)
+    else:
+        targets = op[0]
+        
+    if op[1] == 'sym':
+        mCN = reCN.match(op[2]) # Fuck van Rossum for not having assignments inside expressions
+        if op[2] == 'σ_z':
+            for t in targets:
+                TMatrices[:,t] = (TMatrices[:,t] + qpms.apply_ndmatrix_left(zfl,qpms.apply_ndmatrix_left(zfl, TMatrices[:,t], (-4,-3)),(-2,-1)))/2
+        elif op[2] == 'σ_y':
+            for t in targets:
+                TMatrices[:,t] = (TMatrices[:,t] + qpms.apply_ndmatrix_left(yfl,qpms.apply_ndmatrix_left(yfl, TMatrices[:,t], (-4,-3)),(-2,-1)))/2
+        elif op[2] == 'σ_x':
+            for t in targets:
+                TMatrices[:,t] = (TMatrices[:,t] + qpms.apply_ndmatrix_left(xfl,qpms.apply_ndmatrix_left(xfl, TMatrices[:,t], (-4,-3)),(-2,-1)))/2
+        elif op[2] == 'C2': # special case of the latter
+            for t in targets:
+                TMatrices[:,t] = (TMatrices[:,t] + qpms.apply_matrix_left(c2rot,qpms.apply_matrix_left(c2rot, TMatrices[:,t], -3),-1))/2                
+        elif mCN:
+            rotN = int(mCN.group(2))
+            TMatrix_contribs = np.empty((rotN,TMatrices.shape[0],2,nelem,2,nelem), dtype=np.complex_)
+            for t in targets:
+                for i in range(rotN):
+                    rotangle = 2*np.pi*i / rotN
+                    rot =  qpms.WignerD_yy_fromvector(lMax,np.array([0,0,rotangle]))
+                    rotinv = qpms.WignerD_yy_fromvector(lMax,np.array([0,0,-rotangle]))
+                    TMatrix_contribs[i] = qpms.apply_matrix_left(rot,qpms.apply_matrix_left(rotinv, TMatrices[:,t], -3),-1)
+                TMatrices[:,t] = np.sum(TMatrix_contribs, axis=0) / rotN
+        else:
+            raise
+    elif op[1] == 'tr':
+        mCN = reCN.match(op[2]) # Fuck van Rossum for not having assignments inside expressions
+        if op[2] == 'σ_z':
+            for t in targets:
+                TMatrices[:,t] = qpms.apply_ndmatrix_left(zfl,qpms.apply_ndmatrix_left(zfl, TMatrices[:,t], (-4,-3)),(-2,-1))
+        elif op[2] == 'σ_y':
+            for t in targets:
+                TMatrices[:,t] = qpms.apply_ndmatrix_left(yfl,qpms.apply_ndmatrix_left(yfl, TMatrices[:,t], (-4,-3)),(-2,-1))
+        elif op[2] == 'σ_x':
+            for t in targets:
+                TMatrices[:,t] = qpms.apply_ndmatrix_left(xfl,qpms.apply_ndmatrix_left(xfl, TMatrices[:,t], (-4,-3)),(-2,-1))
+        elif op[2] == 'C2':
+            for t in targets:
+                TMatrices[:,t] = qpms.apply_matrix_left(c2rot,qpms.apply_matrix_left(c2rot, TMatrices[:,t], -3),-1)       
+        elif mCN:
+            rotN = int(mCN.group(2))
+            power = int(mCN.group(1)) if mCN.group(1) else 1
+            TMatrix_contribs = np.empty((rotN,TMatrices.shape[0],2,nelem,2,nelem), dtype=np.complex_)
+            for t in targets:
+                rotangle = 2*np.pi*power/rotN
+                rot = qpms.WignerD_yy_fromvector(lMax, np.array([0,0,rotangle]))
+                rotinv = qpms.WignerD_yy_fromvector(lMax, np.array([0,0,-rotangle]))
+                TMatrices[:,t] = qpms.apply_matrix_left(rot, qpms.apply_matrix_left(rotinv, TMatrices[:,t], -3),-1)
+        else:
+            raise
+    elif op[1] == 'copy':
+        raise # not implemented
+    elif op[1] == 'mult':
+        raise # not implemented
+    elif op[1] == 'multl':
+        incy = np.full((nelem,), False, dtype=bool)
+        for incl in op[2][0].split(','):
+            l = int(incl)
+            incy += (l == ny)
+        scaty = np.full((nelem,), False, dtype=bool)
+        for scatl in op[2][1].split(','):
+            l = int(scatl)
+            scaty += (l == ny)
+        for t in targets:
+            TMatrices[np.ix_(np.arange(TMatrices.shape[0]),np.array([t]),np.array([0,1]),scaty,np.array([0,1]),incy)] *= float(op[2][2])
+    else:
+        raise #unknown operation; should not happen
+
+TMatrices_interp = interpolate.interp1d(freqs_orig*interpfreqfactor, TMatrices, axis=0, kind='linear',fill_value="extrapolate")
+
+klist_full = qpms.generate_trianglepoints(kdensity, v3d=True, include_origin=True)*3*math.pi/(3*kdensity*hexside)
+TMatrices_om = TMatrices_interp(freq)
+
+chunkn = math.ceil(klist_full.shape[0] / chunklen)
+
+if verbose:
+    print('Evaluating %d k-points in %d chunks' % (klist_full.shape[0], chunkn), file = sys.stderr)
+    sys.stderr.flush()
+
+metadata = np.array({
+		'lMax' : lMax,
+                'maxlayer' : maxlayer,
+                'gaussianSigma' : gaussianSigma,
+                'epsilon_b' : epsilon_b,
+		'hexside' : hexside,
+                'chunkn' : chunkn,
+                'TMatrix_file' : TMatrix_file,
+                'ops' : ops,
+                })
+
+for chunki in range(chunkn):
+    svdout = '%s_%dnm_%.4f_c%03d.npz' % (pargs.output_prefix, hexside/1e-9, eVfreq, chunki)
+
+    klist = klist_full[chunki * chunklen : (chunki + 1) * chunklen]
+
+    svdres = qpms.hexlattice_zsym_getSVD(lMax=lMax, TMatrices_om=TMatrices_om, epsilon_b=epsilon_b, hexside=hexside, maxlayer=maxlayer,
+            omega=freq, klist=klist, gaussianSigma=gaussianSigma, onlyNmin=False, verbose=verbose)
+
+    #((svUfullTElist, svSfullTElist, svVfullTElist), (svUfullTMlist, svSfullTMlist, svVfullTMlist)) = svdres
+
+    np.savez(svdout, omega = freq, klist = klist,
+            metadata=metadata,
+                     uTE = svdres[0][0],
+                     vTE = svdres[0][2],
+                     sTE = svdres[0][1],
+                     uTM = svdres[1][0],
+                     vTM = svdres[1][2],
+                     sTM = svdres[1][1],
+
+    )
+    svdres=None
+
+    if scp_dest:
+        if svdout:
+            subprocess.run(['scp', svdout, scp_dest])
+
+_time_e(btime, verbose)
+#print(time.strftime("%H.%M:%S",time.gmtime(time.time()-begtime)))