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card_bl2d_fv_npz.py
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card_bl2d_fv_npz.py
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#!/usr/bin/env python
'''
File: bl2d.py
Created on 21 july 2020
@author: Cedric Content
@contact: [email protected]
@organization: ONERA - DAAA
@summary: This file is the main file of the program. It contains the
routine "main" and other related routines.
'''
import BROADCAST_npz as toy
import numpy as _np
# FORTRAN
import srcfv.f_geom as f_geom
import srcfv.f_bnd as f_bnd
import srcfv.f_sch as f_sch
import srcfv.f_lhs as f_lhs
import srcfv.f_lin as f_lin
# import srcfv.f_adj as f_adj
import srcfv.f_norm as f_norm
import misc.f_misc as f_misc
import os
import sys
import timeit
######################### CARTE ####################
dgeom = dict()
dnum = dict()
dphys = dict()
#GEOMETRY
im = 300 # X discretization
jm = 150 # Y discretization
L = 0.59 # FP length
high = 0.035 # FP high
xini = 0.0060 # beginning
dgeom['im'] = im
dgeom['jm'] = jm
dgeom['length'] = L
dgeom['high'] = high
dgeom['xini'] = xini
out_dir = 'Wksp/'
treename = 'tree300x150'
ite = 10
cfl = 1.e10 #very large CFL for Newton method
freqres = ite/2 # frequency to print residual defined by the integer, here 2
freqsort= ite/1 # frequency to write solution defined by the integer, here 1
sch = 'dnc' # numerical scheme
order = 5 # formal FD order for dnc
k2 = 1.01 #1.01
k4 = 1. #1.
if xini < (order+1)/2*L/(im-1):
print('Error : xini too small, go to negative x in ghost cells => xini should be higher than %s' %str((order+1)/2*L/(im-1)))
exit()
extraporder = 2 # extrapolation order for outflow
out_dir += '%s_%i' %(sch, order)
os.system('mkdir -p %s' % out_dir)
if sch == 'dnc':
routinesch = 'flux_num_dnc%i_2d' % order
# routinesch = 'flux_num_dnc%i_nowall_2d' % order
# routinesch = 'flux_num_dnc%i_nowall_polar_2d' % order
dnum['ite'] = ite
dnum['cfl'] = cfl
dnum['k2'] = k2
dnum['k4'] = k4
dnum['sch'] = sch
dnum['order'] = order
dnum['freqres'] = freqres
dnum['freqsort'] = freqsort
# Routines for BND:
routineout = 'bc_extrapolate_o%i_2d' % extraporder
routinein = 'bc_supandsubinlet_2d'
# routinein = 'bc_general_2d'
routinenr = 'bc_no_reflexion_2d'
routinew = 'bc_wall_viscous_adia_2d'
compmode = 'fixed_point' # computational mode in ['direct', 'impli', 'fixed_point']
dnum['lasolver'] = 'direct' # linear algebra solver for fixed point
dphys['gam'] = 1.4
dphys['Ts'] = 273.15
dphys['cs'] = 110.4
dphys['musuth'] = 1.716e-5
dphys['rgaz'] = 287.1
dphys['Prandtl'] = 0.72
dphys['Mach'] = 4.5
dphys['T0'] = 288.
# dphys['P0'] = 728.312
dphys['Runit'] = 3.4e6
dphys['Lref'] = 1.
dphys['stateref'] = 'm0_runit_t0'
# StateRef = 'm0_p0_t0'
g1 = 1.0
g2 = 0.5 # 1./2.
g3 = 0.165919771368
g4 = 0.040919732041
g5 = 0.007555704391
g6 = 0.000891421261
rk6 = 1.
rk5 = g2
rk4 = g3/rk5
rk3 = g4/(rk4*rk5)
rk2 = g5/(rk3*rk4*rk5)
rk1 = g6/(rk2*rk3*rk4*rk5)
rkcoefs = [rk1, rk2, rk3, rk4, rk5, rk6]
dnum['rkcoefs'] = rkcoefs
#################### FACTORY ########################
lf = list()
lflin = list()
if compmode == 'direct':
libbnd = 'f_bnd'
libsch = 'f_sch'
elif compmode == 'impli':
libbnd = 'f_bnd'
libsch = 'f_sch'
liblhs = 'f_lhs'
elif compmode == 'lin':
libbnd = 'f_lin'
libsch = 'f_lin'
routineout += '_d'
routinenr += '_d'
routinew += '_d'
routinesch += '_d'
elif compmode == 'adj':
libbnd = 'f_adj'
libsch = 'f_adj'
routineout += '_b'
routinenr += '_b'
routinew += '_b'
routinesch += '_b'
elif compmode == 'fixed_point':
libbnd = 'f_bnd'
libsch = 'f_sch'
finflow = eval("%s.%s" % (libbnd, routinein))
foutflow = eval("%s.%s" % (libbnd, routineout))
fnoref = eval("%s.%s" % (libbnd, routinenr ))
fwall = eval("%s.%s" % (libbnd, routinew ))
fsch = eval("%s.%s" % (libsch, routinesch))
# lf = [finflow, foutflow, fnoref, fwall, fsch]
lf = [routinein, routineout, routinenr, routinew, routinesch, libbnd, libsch]
ffiltilo = eval("f_bnd.bc_filteringilo_2d")
lf.append(ffiltilo)
if compmode == 'fixed_point':
libbnd = 'f_lin'
libsch = 'f_lin'
routineout += '_d'
routinein += '_d'
routinenr += '_d'
routinew += '_d'
routinesch += '_d'
flinoutflow = eval("%s.%s" % (libbnd, routineout))
flininflow = eval("%s.%s" % (libbnd, routinein))
flinnoref = eval("%s.%s" % (libbnd, routinenr ))
flinwall = eval("%s.%s" % (libbnd, routinew ))
flinsch = eval("%s.%s" % (libsch, routinesch))
# flininflow = eval("f_bnd.bc_general_2d")
# lflin = [flininflow, flinoutflow, flinnoref, flinwall, flinsch]
lflin = [routinein, routineout, routinenr, routinew, routinesch, libbnd, libsch]
elif compmode == 'impli':
lf.append(eval("f_lhs.impli_matrix_free_2d"))
tinit = timeit.time.time()
## Init the geometry and BC location
toy.bl2d_prepro(dgeom=dgeom, dphys=dphys, dnum=dnum , compmode=compmode, lf=lf, lflin=lflin, out_dir = out_dir, treename=treename)
## Solver
toy.bl2d_fromNPZtree(treename, ite, compmode = compmode, out_dir = out_dir)
tend = timeit.time.time()
tlaps = tend-tinit
denom = im*jm*ite*len(rkcoefs)
print("Time Elapsed = ", tlaps)
print("Time Elapsed/(cell*it) = %s s " % str(tlaps/denom))
#################### FACTORY ########################