def problem(work_dir, pluto_path, pluto_dir, additional_files, additional_flags, makefile_template, AUTO_UPDATE): # before proceeding we scan pre-existing definitions.h # for obsolete statements in order to and make proper replacements. replace_obsoletes(work_dir) # sys.exit(1) HD = 1 RHD = 2 MHD = 3 SRMHD = 4 RMHD = 5 WITH_CHOMBO = 0 # enable/disable Chombo AMR FULL = 0 WITH_FD = 0 # enable/disable finite difference schemes WITH_SB = 0 # enable/disable shearing box module WITH_FARGO = 0 # enable/disable FARGO module for orbital advection # ***************************************** # check command line arguments # ***************************************** for x in sys.argv: if (x == "--with-chombo" or x == "--with-chombo:"): WITH_CHOMBO = 1 if (x == "--full"): FULL = 1 if (x == "--with-fd"): WITH_FD = 1 if (x == "--with-sb"): WITH_SB = 1 if (x == "--with-fargo"): WITH_FARGO = 1 # -- default makefile template -- if (WITH_CHOMBO): makefile_template.append('/Src/Templates/makefile.chombo') else: makefile_template.append('/Src/Templates/makefile') # Create user-editable menu entries = [] options = [] default = [] scrh = [] entries.append('PHYSICS') if (WITH_FD or WITH_FARGO): options.append(['HD', 'MHD']) default.append('HD') elif (WITH_SB): options.append(['MHD']) default.append('MHD') else: options.append(['HD', 'RHD', 'MHD', 'RMHD']) default.append('HD') entries.append('DIMENSIONS') if (WITH_SB or WITH_FARGO): options.append(['2', '3']) default.append('2') else: options.append(['1', '2', '3']) default.append('1') entries.append('COMPONENTS') if (WITH_SB): options.append(['2', '3']) default.append('2') else: options.append(['1', '2', '3']) default.append('1') entries.append('GEOMETRY') if (WITH_CHOMBO): # options.append(['CARTESIAN','CYLINDRICAL','AXISYM']) options.append(['CARTESIAN', 'CYLINDRICAL']) default.append('CARTESIAN') elif (WITH_FD or WITH_SB): options.append(['CARTESIAN']) default.append('CARTESIAN') else: # options.append(['CARTESIAN','CYLINDRICAL','AXISYM','POLAR','SPHERICAL']) options.append(['CARTESIAN', 'CYLINDRICAL', 'POLAR', 'SPHERICAL']) default.append('CARTESIAN') # entries.append('UNIFORM_GRID') # if (WITH_CHOMBO): # options.append('YES') # default.append('YES') # else: # options.append(['YES','NO']) # default.append('YES') entries.append('BODY_FORCE') if (WITH_SB): options.append(['VECTOR', 'POTENTIAL', '(VECTOR+POTENTIAL)']) default.append('VECTOR') else: options.append(['NO', 'VECTOR', 'POTENTIAL', '(VECTOR+POTENTIAL)']) default.append('NO') entries.append('COOLING') options.append(['NO', 'POWER_LAW', 'TABULATED', 'SNEq', 'MINEq']) # ,'H2_COOL']) default.append('NO') # entries.append('INCLUDE_PARTICLES') # options.append(['NO','YES']) # default.append('NO') # set interpolation options entries.append('INTERPOLATION') if (WITH_CHOMBO): options.append(['FLAT', 'LINEAR', 'WENO3', 'PARABOLIC']) default.append('LINEAR') elif (FULL): options.append( ['FLAT', 'LINEAR', 'LimO3', 'WENO3', 'PARABOLIC', 'MP5']) default.append('LINEAR') elif (WITH_FD): options.append(['WENO3_FD', 'WENOZ_FD', 'MP5_FD', 'LIMO3_FD']) default.append('WENOZ_FD') else: options.append(['FLAT', 'LINEAR', 'LimO3', 'WENO3', 'PARABOLIC']) # Default default.append('LINEAR') entries.append('TIME_STEPPING') if (WITH_CHOMBO): # options.append(['HANCOCK','CHARACTERISTIC_TRACING','RK_MIDPOINT','EULER','RK2']) options.append(['EULER', 'HANCOCK', 'CHARACTERISTIC_TRACING', 'RK2']) default.append('HANCOCK') elif (WITH_FD): options.append(['RK3']) default.append('RK3') else: # options.append(['EULER','RK_MIDPOINT','RK2','RK3','HANCOCK','CHARACTERISTIC_TRACING']) options.append( ['EULER', 'RK2', 'RK3', 'HANCOCK', 'CHARACTERISTIC_TRACING']) default.append('RK2') entries.append('DIMENSIONAL_SPLITTING') if (WITH_CHOMBO or WITH_FARGO): options.append(['NO']) default.append('NO') else: options.append(['YES', 'NO']) default.append('YES') entries.append('NTRACER') for n in range(5): scrh.append(repr(n)) options.append(scrh) default.append('0') scrh = [] entries.append('USER_DEF_PARAMETERS') for n in range(32): scrh.append(repr(n + 1)) options.append(scrh) default.append('1') # ************************************************** # If definitions.h already exists try to read # default values from it. # ************************************************** if (os.path.exists(work_dir + '/definitions.h')): for x in entries: try: scrh = file.string_list(work_dir + '/definitions.h', x) tmp = string.split(scrh[0]) i = entries.index(tmp[1]) y = options[i] i2 = y.index(tmp[2]) default[entries.index(x)] = tmp[2] except ValueError: continue except IndexError: continue # **** ok, call menu **** if AUTO_UPDATE == 0: selection = '' menu.SetTitle("Setup problem") selection = menu.Browse(entries, default, options) # selection = menu.select(entries,options,default,'Setup problem') # ************************************************** # define Physics module sub-menus # ************************************************** i = entries.index('DIMENSIONS') dimensions = int(default[i]) i = entries.index('PHYSICS') physics_module = default[i] i = entries.index('GEOMETRY') geometry = default[i] i = entries.index('INTERPOLATION') interpolation = default[i] i = entries.index('TIME_STEPPING') time_stepping = default[i] i = entries.index('DIMENSIONAL_SPLITTING') dim_splitting = default[i] # HD if physics_module == 'HD': entries_HD = [] options_HD = [] default_HD = [] entries_HD.append('EOS') options_HD.append(['IDEAL', 'ISOTHERMAL']) default_HD.append('IDEAL') entries_HD.append('ENTROPY_SWITCH') options_HD.append(['NO', 'YES']) default_HD.append('NO') entries_HD.append('THERMAL_CONDUCTION') if (WITH_CHOMBO == 1): options_HD.append(['NO', 'EXPLICIT']) else: # options_HD.append(['NO','EXPLICIT','SUPER_TIME_STEPPING','RK_CHEBYSHEV']) options_HD.append(['NO', 'EXPLICIT', 'SUPER_TIME_STEPPING']) default_HD.append('NO') entries_HD.append('VISCOSITY') if (WITH_CHOMBO == 1): options_HD.append(['NO', 'EXPLICIT']) else: # options_HD.append(['NO','EXPLICIT','SUPER_TIME_STEPPING','RK_CHEBYSHEV']) options_HD.append(['NO', 'EXPLICIT', 'SUPER_TIME_STEPPING']) default_HD.append('NO') entries_HD.append('ROTATING_FRAME') options_HD.append(['NO', 'YES']) default_HD.append('NO') # if (physics_module == "HD" and dim_splitting == "YES"): # if (geometry == "POLAR" or geometry == "SPHERICAL"): # entries_HD.append('FARGO_SCHEME') # options_HD.append(['NO','YES']) # default_HD.append('NO') # Read HD pre-existing HD submenu defaults, if they exists if (os.path.exists(work_dir + '/definitions.h')): for x in entries_HD: try: scrh = file.string_list(work_dir + '/definitions.h', x) tmp = string.split(scrh[0]) default_HD[entries_HD.index(x)] = tmp[2] except IndexError: continue if AUTO_UPDATE == 0: selection = '' menu.SetTitle("HD Menu") selection = menu.Browse(entries_HD, default_HD, options_HD) # selection = menu.select(entries_HD,options_HD,default_HD,'HD MENU') # RHD if physics_module == 'RHD': entries_RHD = [] options_RHD = [] default_RHD = [] entries_RHD.append('EOS') options_RHD.append(['IDEAL', 'TAUB']) default_RHD.append('IDEAL') entries_RHD.append('USE_FOUR_VELOCITY') options_RHD.append(['NO', 'YES']) default_RHD.append('NO') entries_RHD.append('ENTROPY_SWITCH') options_RHD.append(['NO', 'YES']) default_RHD.append('NO') # Read RHD pre-existing RHD submenu defaults, if they exists if (os.path.exists(work_dir + '/definitions.h')): for x in entries_RHD: try: scrh = file.string_list(work_dir + '/definitions.h', x) tmp = string.split(scrh[0]) default_RHD[entries_RHD.index(x)] = tmp[2] except IndexError: continue if AUTO_UPDATE == 0: selection = '' menu.SetTitle("RHD Menu") selection = menu.Browse(entries_RHD, default_RHD, options_RHD) # selection = menu.select(entries_RHD,options_RHD,default_RHD,'RHD MENU') # MHD if (physics_module == 'MHD'): entries_MHD = [] options_MHD = [] default_MHD = [] entries_MHD.append('EOS') options_MHD.append(['IDEAL', 'BAROTROPIC', 'ISOTHERMAL']) default_MHD.append('IDEAL') entries_MHD.append('ENTROPY_SWITCH') options_MHD.append(['NO', 'YES']) default_MHD.append('NO') entries_MHD.append('MHD_FORMULATION') if (WITH_CHOMBO or WITH_FD): options_MHD.append(['NONE', 'EIGHT_WAVES', 'DIV_CLEANING']) default_MHD.append('EIGHT_WAVES') elif (WITH_SB or WITH_FARGO): options_MHD.append(['CONSTRAINED_TRANSPORT']) default_MHD.append('CONSTRAINED_TRANSPORT') else: options_MHD.append([ 'NONE', 'EIGHT_WAVES', 'DIV_CLEANING', 'CONSTRAINED_TRANSPORT' ]) default_MHD.append('EIGHT_WAVES') entries_MHD.append('BACKGROUND_FIELD') options_MHD.append(['NO', 'YES']) default_MHD.append('NO') entries_MHD.append('RESISTIVE_MHD') if (WITH_CHOMBO == 1): options_MHD.append(['NO', 'EXPLICIT']) else: # options_MHD.append(['NO','EXPLICIT','SUPER_TIME_STEPPING','RK_CHEBYSHEV']) options_MHD.append(['NO', 'EXPLICIT', 'SUPER_TIME_STEPPING']) default_MHD.append('NO') entries_MHD.append('HALL_MHD') options_MHD.append(['NO', 'RIEMANN', 'SOURCE']) default_MHD.append('NO') entries_MHD.append('AMBIPOLAR_DIFFUSION') options_MHD.append(['NO', 'EXPLICIT']) default_MHD.append('NO') entries_MHD.append('THERMAL_CONDUCTION') if (WITH_CHOMBO == 1): options_MHD.append(['NO', 'EXPLICIT']) else: # options_MHD.append(['NO','EXPLICIT','SUPER_TIME_STEPPING','RK_CHEBYSHEV']) options_MHD.append(['NO', 'EXPLICIT', 'SUPER_TIME_STEPPING']) default_MHD.append('NO') entries_MHD.append('VISCOSITY') if (WITH_CHOMBO == 1): options_MHD.append(['NO', 'EXPLICIT']) else: # options_MHD.append(['NO','EXPLICIT','SUPER_TIME_STEPPING','RK_CHEBYSHEV']) options_MHD.append(['NO', 'EXPLICIT', 'SUPER_TIME_STEPPING']) default_MHD.append('NO') entries_MHD.append('ROTATING_FRAME') options_MHD.append(['NO', 'YES']) default_MHD.append('NO') # Read MHD pre-existing MHD submenu defaults, if they exists if (os.path.exists(work_dir + '/definitions.h')): for x in entries_MHD: ix = entries_MHD.index(x) try: scrh = file.string_list(work_dir + '/definitions.h', x) tmp = string.split(scrh[0]) try: # if the choice is not in the permitted list of options, # ValueError is raised and the default choice is kept. i = options_MHD[ix].index(tmp[2]) default_MHD[ix] = tmp[2] except ValueError: continue except IndexError: continue if AUTO_UPDATE == 0: selection = '' if (physics_module == 'MHD'): menu.SetTitle("MHD Menu") selection = menu.Browse(entries_MHD, default_MHD, options_MHD) # selection = menu.select(entries_MHD,options_MHD,default_MHD,'MHD MENU') # RMHD if physics_module == 'RMHD': entries_RMHD = [] options_RMHD = [] default_RMHD = [] entries_RMHD.append('EOS') options_RMHD.append(['IDEAL', 'TAUB']) default_RMHD.append('IDEAL') entries_RMHD.append('ENTROPY_SWITCH') options_RMHD.append(['NO', 'YES']) default_RMHD.append('NO') entries_RMHD.append('MHD_FORMULATION') if (WITH_CHOMBO == 1): options_RMHD.append(['NONE', 'EIGHT_WAVES', 'DIV_CLEANING']) else: options_RMHD.append([ 'NONE', 'EIGHT_WAVES', 'DIV_CLEANING', 'CONSTRAINED_TRANSPORT' ]) default_RMHD.append('NONE') # Read RMHD pre-existing RMHD submenu defaults, if they exists if (os.path.exists(work_dir + '/definitions.h')): for x in entries_RMHD: ix = entries_RMHD.index(x) try: scrh = file.string_list(work_dir + '/definitions.h', x) tmp = string.split(scrh[0]) try: # if the choice is not in the permitted list of options, # ValueError is raised and the default choice is kept. i = options_RMHD[ix].index(tmp[2]) default_RMHD[ix] = tmp[2] except ValueError: continue except IndexError: continue if AUTO_UPDATE == 0: selection = '' if (physics_module == 'RMHD'): menu.SetTitle("RMHD Menu") selection = menu.Browse(entries_RMHD, default_RMHD, options_RMHD) # selection = menu.select(entries_RMHD,options_RMHD,default_RMHD,'RMHD MENU') # ******************************************************************** # USER_DEF PARAMETERS: # # Read them from definitions.h if the file exists; # assign 'SCRH' otherwise. # ******************************************************************** i = entries.index('USER_DEF_PARAMETERS') npar = int(default[i]) u_def_par = [] if (os.path.exists(work_dir + '/definitions.h')): scrh = file.word_find(work_dir + '/definitions.h', 'parameters') k0 = scrh[0] + 2 scrh = file.read_lines(work_dir + '/definitions.h', k0, k0 + npar) for n in range(npar): try: x = string.split(scrh[n]) if (x[0] == "#define"): u_def_par.append(x[1]) else: u_def_par.append('SCRH') except IndexError: u_def_par.append('SCRH') # scrh[n + 1] = '#define SCRH x' else: for n in range(npar): u_def_par.append('SCRH') if AUTO_UPDATE == 0: # u_def_par = ['SCRH'] menu.SetTitle("User-defined parameters") menu.Insert(int(default[i]), u_def_par) # menu.put(int(default[i]),u_def_par,'USER DEF SECTION') # ----------------------------------------------------- # Create the list 'tmp' that will be used to write # the new definitions.h header file # ----------------------------------------------------- tmp = [] for x in entries: i = entries.index(x) y = default[i] tmp.append('#define ' + x.ljust(21) + ' ' + y + '\n') tmp.append('\n/* -- physics dependent declarations -- */\n\n') if (physics_module == 'MHD'): for x in entries_MHD: i = entries_MHD.index(x) tmp.append('#define ' + x.ljust(21) + ' ' + default_MHD[i] + '\n') if physics_module == 'HD': for x in entries_HD: i = entries_HD.index(x) tmp.append('#define ' + x.ljust(21) + ' ' + default_HD[i] + '\n') if physics_module == 'RHD': for x in entries_RHD: i = entries_RHD.index(x) tmp.append('#define ' + x.ljust(21) + ' ' + default_RHD[i] + '\n') if physics_module == 'RMHD': for x in entries_RMHD: i = entries_RMHD.index(x) tmp.append('#define ' + x.ljust(21) + ' ' + default_RMHD[i] + '\n') # ***************************************** # add Chombo-AMR specific flags # ***************************************** if (WITH_CHOMBO and os.path.exists(work_dir + '/definitions.h')): scrh = file.string_list(work_dir + '/definitions.h', 'AMR_EN_SWITCH') tmp.append('\n/* -- Chombo-AMR flags -- */\n\n') if (len(scrh) != 0): strsplit = string.split(scrh[0]) value = strsplit[2] tmp.append('#define AMR_EN_SWITCH ' + value + '\n') else: tmp.append('#define AMR_EN_SWITCH NO\n') # ******************************************************* # add pointer names to user defined parameters # ******************************************************* tmp.append('\n/* -- pointers to user-def parameters -- */\n\n') for x in u_def_par: i = u_def_par.index(x) tmp.append('#define ' + x.ljust(16) + ' ' + repr(i) + '\n') # !!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!! # In this section, also, udpate the pluto.ini # initialization file by appending the correct # sequence of user defined parameters # !!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!! # menu.RestoreScreen() plutoini = work_dir + "/pluto.ini" scrh = file.string_find(plutoini, 'Parameters') ipos = scrh[0] + 2 # start reading/writing pluto.ini at this point # to build a list of the userdef parameters scrh = file.read_lines(plutoini, ipos, 999) # read until end of file pname = [] pvalue = [] for x in scrh: y = string.split(x) # pname and pvalue contain the list of parameter if (len(y) == 0): continue # skip blank lines pname.append(y[0]) # names and their respective values as present pvalue.append(y[1]) # in pluto.ini for x in u_def_par: # loop on the actual list of parameters; par_exist = 0 # is the parameter already present in pluto.ini ? for y in pname: if (x == y): # if yes, use the original value instead of '0' par_exist = 1 i = pname.index(y) file.insert(plutoini, pname[i] + " " + pvalue[i] + "\n", ipos) break if (par_exist == 0): # if not, set default value to 0 file.insert(plutoini, x + ' 0\n', ipos) ipos = ipos + 1 # delete all other lines in pluto.ini file.delete_lines(plutoini, ipos, ipos + 256) # *************************************************************** # check dependencies for conditional inclusion # of additional object files; this is useful # for makefile creation # *************************************************************** # additional files will be compiled # depending on the user's choice of # time integration scheme # the next line removes all elements from additional_files # and pluto_path so the list can be built from scratch # for x in additional_files: additional_files.remove(x) # for x in pluto_path : pluto_path.remove(x) additional_files[:] = [] additional_flags[:] = [] pluto_path[:] = [] divb = ' ' # ********************************************** # physics module & parabolic term treatment # ********************************************** sts_flag = 0 # if changed to 1, include the super-time-stepping driver rkc_flag = 0 # if changed to 1, include the runge-kutta-Chebyshev driver exp_flag = 0 # if changed to 1, include explicit parabolic time-stepping cur_flag = 0 # if changed to 1, include current calculation if (physics_module == 'HD'): pluto_path.append('HD/') entries_MOD = entries_HD default_MOD = default_HD n = entries_MOD.index('THERMAL_CONDUCTION') if (default_MOD[n] != 'NO'): pluto_path.append('Thermal_Conduction/') if (default_MOD[n] == 'SUPER_TIME_STEPPING'): sts_flag = 1 elif (default_MOD[n] == 'RK_CHEBYSHEV'): rkc_flag = 1 elif (default_MOD[n] == 'EXPLICIT'): exp_flag = 1 n = entries_MOD.index('VISCOSITY') if (default_MOD[n] != 'NO'): pluto_path.append('Viscosity/') if (default_MOD[n] == 'SUPER_TIME_STEPPING'): sts_flag = 1 elif (default_MOD[n] == 'RK_CHEBYSHEV'): rkc_flag = 1 elif (default_MOD[n] == 'EXPLICIT'): exp_flag = 1 elif (physics_module == 'RHD'): pluto_path.append('RHD/') entries_MOD = entries_RHD default_MOD = default_RHD elif (physics_module == 'MHD'): pluto_path.append('MHD/') entries_MOD = entries_MHD default_MOD = default_MHD n = entries_MOD.index('MHD_FORMULATION') divb = default_MOD[n] if (divb == 'CONSTRAINED_TRANSPORT'): pluto_path.append('MHD/CT/') elif (divb == 'DIV_CLEANING'): pluto_path.append('MHD/GLM/') n = entries_MOD.index('RESISTIVE_MHD') if (default_MOD[n] != 'NO'): pluto_path.append('MHD/Resistive/') cur_flag = 1 if (default_MOD[n] == 'SUPER_TIME_STEPPING'): sts_flag = 1 elif (default_MOD[n] == 'RK_CHEBYSHEV'): rkc_flag = 1 elif (default_MOD[n] == 'EXPLICIT'): exp_flag = 1 n = entries_MOD.index('HALL_MHD') if (default_MOD[n] != 'NO'): pluto_path.append('MHD/Hall/') if (default_MOD[n] == 'RIEMANN'): cur_flag = 1 n = entries_MOD.index('AMBIPOLAR_DIFFUSION') if (default_MOD[n] != 'NO'): pluto_path.append('MHD/Ambipolar/') cur_flag = 1 n = entries_MOD.index('THERMAL_CONDUCTION') if (default_MOD[n] != 'NO'): pluto_path.append('Thermal_Conduction/') if (default_MOD[n] == 'SUPER_TIME_STEPPING'): sts_flag = 1 elif (default_MOD[n] == 'RK_CHEBYSHEV'): rkc_flag = 1 elif (default_MOD[n] == 'EXPLICIT'): exp_flag = 1 n = entries_MOD.index('VISCOSITY') if (default_MOD[n] != 'NO'): pluto_path.append('Viscosity/') if (default_MOD[n] == 'SUPER_TIME_STEPPING'): sts_flag = 1 elif (default_MOD[n] == 'RK_CHEBYSHEV'): rkc_flag = 1 elif (default_MOD[n] == 'EXPLICIT'): exp_flag = 1 if (cur_flag == 1): pluto_path.append('MHD/Current/') additional_flags.append(' -DNEED_CURRENT') # *************************** # need shearingbox module ? # *************************** if (WITH_SB == 1): pluto_path.append('MHD/ShearingBox/') additional_flags.append(' -DSHEARINGBOX') elif (physics_module == 'RMHD'): pluto_path.append('RMHD/') entries_MOD = entries_RMHD default_MOD = default_RMHD n = entries_MOD.index('MHD_FORMULATION') divb = default_MOD[n] if (divb == 'CONSTRAINED_TRANSPORT'): pluto_path.append('MHD/CT/') elif (divb == 'DIV_CLEANING'): pluto_path.append('MHD/GLM/') # ***************************** # Interpolation # ***************************** if (interpolation == 'FLAT'): additional_files.append('states_flat.o') elif (interpolation == 'LINEAR'): additional_files.append('states_plm.o') elif (interpolation == 'PARABOLIC'): additional_files.append('states_ppm.o') elif (interpolation == 'LimO3'): additional_files.append('states_limo3.o') elif (interpolation == 'WENO3'): additional_files.append('states_weno3.o') elif (WITH_FD): # Finite Difference additional_files.append('states_fd.o') additional_files.append('fd_reconstruct.o') additional_files.append('fd_flux.o') additional_flags.append(' -DFINITE_DIFFERENCE') # ***************************** # Time Stepping # ***************************** if (WITH_CHOMBO): # ** AMR file inclusion ** if (dimensions == 1): additional_files.append('PatchCTU.1D.o') else: if (time_stepping == 'RK_MIDPOINT'): additional_files.append('PatchRK.3D.o') elif (time_stepping == 'EULER'): additional_files.append('PatchEuler.3D.o') elif (time_stepping == 'RK2'): additional_files.append('PatchEuler.3D.o') else: additional_files.append('PatchCTU.3D.o') else: if (time_stepping == 'CHARACTERISTIC_TRACING'): if (dim_splitting == 'YES'): additional_files.append('sweep.o') else: additional_files.append('unsplit_ctu.o') elif (time_stepping == 'HANCOCK'): if (dim_splitting == 'YES'): additional_files.append('sweep.o') else: additional_files.append('unsplit_ctu.o') elif (time_stepping == 'RK_MIDPOINT'): additional_files.append('rk_midpoint.o') else: if (dim_splitting == 'YES'): additional_files.append('sweep.o') else: additional_files.append('unsplit.o') if (time_stepping == 'CHARACTERISTIC_TRACING'): additional_files.append('char_tracing.o') elif (time_stepping == 'HANCOCK'): additional_files.append('hancock.o') # if (interpolation != 'LINEAR'): # if (time_stepping == 'CHARACTERISTIC_TRACING'): # additional_files.append('states_ppm_char.o') # else: # additional_files.append('rk_states.o') # ***************************** # FARGO Scheme # ***************************** if (WITH_FARGO): pluto_path.append('Fargo/') additional_flags.append(' -DFARGO') # ***************************** # Geometry # ***************************** # additional_files.append('rhs.o') # additional_files.append('rhs.o') # if (geometry == "CARTESIAN"): # additional_files.append('rhs_cart.o') # if (geometry == "AXISYM"): # additional_files.append('cylsource.o') # ***************************** # Cooling # ***************************** n = entries.index('COOLING') if (default[n] == 'POWER_LAW'): pluto_path.append('Cooling/Power_Law/') elif (default[n] == 'TABULATED'): pluto_path.append('Cooling/Tab/') additional_files.append('cooling_source.o') additional_files.append('cooling_ode_solver.o') elif (default[n] == 'SNEq'): pluto_path.append('Cooling/SNEq/') additional_files.append('cooling_source.o') additional_files.append('cooling_ode_solver.o') elif (default[n] == 'MINEq'): pluto_path.append('Cooling/MINEq/') additional_files.append('cooling_source.o') additional_files.append('cooling_ode_solver.o') elif (default[n] == 'H2_COOL'): pluto_path.append('Cooling/H2_COOL/') additional_files.append('cooling_source.o') additional_files.append('cooling_ode_solver.o') # ********************************** # parabolic flux: file inclusion # ********************************** if (sts_flag == 1): additional_files.append('sts.o') additional_files.append('parabolic_rhs.o') if (rkc_flag == 1): additional_files.append('rkc.o') additional_files.append('parabolic_rhs.o') if (exp_flag == 1): additional_files.append('parabolic_flux.o') # ********************************************** # Vector potential # ********************************************** if (physics_module == 'MHD' or physics_module == 'RMHD'): additional_files.append('vec_pot_diff.o') if (WITH_CHOMBO == 0): additional_files.append('vec_pot_update.o') # ***************************** # Particles # ***************************** # n = entries.index('INCLUDE_PARTICLES') # if (default[n] == 'YES'): # pluto_path.append('Particles/') # **************************************************************** # DEFINE ALL NON-USER FRIENDLY CONSTANTS # **************************************************************** tmp.append('\n/* -- supplementary constants (user editable) -- */ \n\n') no_us_fr = [] no_us_fr.append('#define INITIAL_SMOOTHING NO\n') no_us_fr.append('#define WARNING_MESSAGES NO\n') no_us_fr.append('#define PRINT_TO_FILE NO\n') no_us_fr.append('#define INTERNAL_BOUNDARY NO\n') no_us_fr.append('#define SHOCK_FLATTENING NO\n') if (not WITH_FD): no_us_fr.append('#define ARTIFICIAL_VISCOSITY NO\n') no_us_fr.append('#define CHAR_LIMITING NO\n') no_us_fr.append('#define LIMITER DEFAULT\n') # add geometry-dependent switches if (geometry == "AXISYM"): no_us_fr.append('#define ADD_CYLSOURCE 1\n') # if (geometry == "POLAR" and physics_module == "HD"): # no_us_fr.append('#define FARGO_SCHEME NO\n') # add flux ct switches for MHD or RMHD if (divb == "CONSTRAINED_TRANSPORT"): no_us_fr.append('#define CT_EMF_AVERAGE UCT_HLL\n') no_us_fr.append('#define CT_EN_CORRECTION NO\n') no_us_fr.append('#define ASSIGN_VECTOR_POTENTIAL YES\n') elif (physics_module == "MHD" or physics_module == "RMHD"): no_us_fr.append('#define ASSIGN_VECTOR_POTENTIAL NO\n') if (physics_module == "MHD" or physics_module == "RMHD"): if (not WITH_CHOMBO): no_us_fr.append('#define UPDATE_VECTOR_POTENTIAL NO\n') if (time_stepping == 'HANCOCK'): if (physics_module == 'RMHD'): no_us_fr.append('#define PRIMITIVE_HANCOCK NO\n') else: no_us_fr.append('#define PRIMITIVE_HANCOCK YES\n') # add definition of STS_NU if (sts_flag == 1): no_us_fr.append('#define STS_nu 0.01\n') # *************************************************************** # Read pre-existing non-user-editable defaults; # Use the default value if they exist # *************************************************************** if (os.path.exists(work_dir + '/definitions.h')): for x in no_us_fr: try: xl = string.split(x) scrh = file.string_list(work_dir + '/definitions.h', xl[1]) no_us_fr[no_us_fr.index(x)] = scrh[0] except IndexError: continue # add elements of no_us_fr to tmp for x in no_us_fr: tmp.append(x) # -- create definitions.h -- file.create_file(work_dir + '/definitions.h', tmp) return
def makefile(work_dir, pluto_path, pluto_dir, additional_files, additional_flags, makefile_template, AUTO_UPDATE): mkfl_name = work_dir + '/makefile' mkfl_exist = os.path.exists(mkfl_name) # is Chombo required ? WITH_CHOMBO = 0 for x in sys.argv: if (x == "--with-chombo" or x == "--with-chombo:"): WITH_CHOMBO = 1 # try to get "ARCH" from makefile if (mkfl_exist): scrh = file.string_list(mkfl_name, 'ARCH') # Create a new makefile under the following conditions: if (AUTO_UPDATE == 0) or (not mkfl_exist) or (len(scrh) == 0): # define architecture entries = os.listdir(pluto_dir + '/Config') entries.sort() menu.SetTitle("Change makefile") arch = menu.Browse(entries) # call menu to select config. file arch_string = 'ARCH = ' + arch + '\n' else: # try to update makefile automatically arch_string = scrh[0] arch = (string.split(arch_string))[2] # Starting print here row = 1 menu.Print("> Generating makefile... [" + arch + "]", row=row, sleep=1) # if CHOMBO is required, change dir to Lib/Chombo/lib, make vars to generate # a list of all the variables needed by CHOMBO makefile and copy the list to # make.vars in local working directory. # This file will be used later by PLUTO makefile. if (WITH_CHOMBO): # get the number of DIMENSIONS from definitions.h scrh = file.string_list(work_dir + "/definitions.h", "DIMENSIONS") scrh = string.split(scrh[0]) # build chombo configuration string chombo_config_string = 'DIM=' + scrh[2] for x in sys.argv: if (x == '--with-chombo:'): i = sys.argv.index(x) + 1 for y in sys.argv[i:]: chombo_config_string += ' ' + y row = row + 1 menu.Print(" - Chombo config string: " + chombo_config_string, row=row) row = row + 1 menu.Print(" - creating make.vars...", row=row, sleep=0) os.chdir(pluto_dir + "/Lib/Chombo-3.1/lib") os.system("make " + chombo_config_string + " vars > make.vars\n") os.system("cp make.vars " + work_dir + "\n") os.chdir(work_dir) # copy template shutil.copy(pluto_dir + makefile_template[0], mkfl_name) # write main PLUTO dir scrh = file.word_find(mkfl_name, 'PLUTO_DIR') ipos = scrh[0] file.replace_line(mkfl_name, 'PLUTO_DIR = ' + pluto_dir + '\n', ipos) # write architecture scrh = file.word_find(mkfl_name, 'ARCH') ipos = scrh[0] file.replace_line(mkfl_name, arch_string, ipos) # Write additional objects to makefile scrh = file.word_find(mkfl_name, 'Additional_object_files_here') ipos = scrh[0] + 3 for x in additional_files: file.insert(mkfl_name, 'OBJ += ' + x + '\n', ipos) ipos = ipos + 1 # add included makefile; useful for header dependences for x in pluto_path: file.insert(mkfl_name, 'include $(SRC)/' + x + 'makefile' + '\n', ipos) ipos = ipos + 1 # Write additional flags for C compiler for x in additional_flags: file.insert(mkfl_name, 'CFLAGS += ' + x + '\n', ipos) ipos = ipos + 1 # Check for libpng # if (WITH_CHOMBO == 0): # if (os.path.exists("sysconf.out")): # scrh = file.string_find ("sysconf.out", "LIBPNG") # line = file.read_lines("sysconf.out", scrh[0], scrh[0]+1) # line_list = string.split(line[0]) # if (line_list[2] == 'YES'): # file.insert(this_makefile, 'LDFLAGS += -lpng\n', ipos) # ipos = ipos + 1 # file.insert(this_makefile, 'CFLAGS += -DHAVE_LIBPNG\n', ipos) return
def makefile(work_dir, pluto_path, pluto_dir, additional_files, additional_flags, makefile_template, AUTO_UPDATE): mkfl_name = work_dir+'/makefile' mkfl_exist = os.path.exists(mkfl_name) # is Chombo required ? WITH_CHOMBO = 0 for x in sys.argv: if (x == "--with-chombo" or x == "--with-chombo:"): WITH_CHOMBO = 1 # try to get "ARCH" from makefile if (mkfl_exist): scrh = file.string_list(mkfl_name,'ARCH') # Create a new makefile under the following conditions: if (AUTO_UPDATE == 0) or (not mkfl_exist) or (len(scrh) == 0): # define architecture entries = os.listdir(pluto_dir + '/Config') entries.sort() menu.SetTitle("Change makefile") arch = menu.Browse(entries) # call menu to select config. file arch_string = 'ARCH = '+ arch + '\n' else: # try to update makefile automatically arch_string = scrh[0] arch = (string.split(arch_string))[2] # Starting print here row = 1 menu.Print ("> Generating makefile... ["+arch+"]", row=row,sleep=1) # if CHOMBO is required, change dir to Lib/Chombo/lib, make vars to generate # a list of all the variables needed by CHOMBO makefile and copy the list to # make.vars in local working directory. # This file will be used later by PLUTO makefile. if (WITH_CHOMBO): # get the number of DIMENSIONS from definitions.h scrh = file.string_list (work_dir+"/definitions.h", "DIMENSIONS") scrh = string.split(scrh[0]) # build chombo configuration string chombo_config_string = 'DIM='+scrh[2] for x in sys.argv: if (x == '--with-chombo:'): i = sys.argv.index(x) + 1 for y in sys.argv[i:]: chombo_config_string += ' '+y row = row + 1 menu.Print(" - Chombo config string: "+chombo_config_string,row=row) row = row+1 menu.Print(" - creating make.vars...",row=row,sleep=0) os.chdir(pluto_dir+"/Lib/Chombo-3.1/lib") os.system("make "+chombo_config_string+" vars > make.vars\n") os.system("cp make.vars "+work_dir+"\n") os.chdir(work_dir) # copy template shutil.copy(pluto_dir + makefile_template[0], mkfl_name) # write main PLUTO dir scrh = file.word_find(mkfl_name,'PLUTO_DIR') ipos = scrh[0] file.replace_line (mkfl_name, 'PLUTO_DIR = '+pluto_dir+'\n', ipos) # write architecture scrh = file.word_find(mkfl_name,'ARCH') ipos = scrh[0] file.replace_line (mkfl_name, arch_string, ipos) # Write additional objects to makefile scrh = file.word_find(mkfl_name,'Additional_object_files_here') ipos = scrh[0] + 3 for x in additional_files: file.insert(mkfl_name, 'OBJ += '+x + '\n', ipos) ipos = ipos + 1 # add included makefile; useful for header dependences for x in pluto_path: file.insert(mkfl_name, 'include $(SRC)/' + x + 'makefile' + '\n',ipos) ipos = ipos + 1 # Write additional flags for C compiler for x in additional_flags: file.insert(mkfl_name, 'CFLAGS += '+x+'\n', ipos) ipos = ipos + 1 # Check for libpng # if (WITH_CHOMBO == 0): # if (os.path.exists("sysconf.out")): # scrh = file.string_find ("sysconf.out", "LIBPNG") # line = file.read_lines("sysconf.out", scrh[0], scrh[0]+1) # line_list = string.split(line[0]) # if (line_list[2] == 'YES'): # file.insert(this_makefile, 'LDFLAGS += -lpng\n', ipos) # ipos = ipos + 1 # file.insert(this_makefile, 'CFLAGS += -DHAVE_LIBPNG\n', ipos) return
def replace_obsoletes(work_dir): # replace potential occurences of "INCLUDE_ROTATION" --> "ROTATING_FRAME" try: scrh = file.string_list(work_dir + '/definitions.h', 'INCLUDE_ROTATION') tmp = string.split(scrh[0]) newline = "#define ROTATING_FRAME " + tmp[2] + "\n" n = file.string_find(work_dir + '/definitions.h', 'INCLUDE_ROTATION') n = n[0] file.replace_line(work_dir + '/definitions.h', newline, n) except: pass # replace potential occurences of "INCLUDE_BODY_FORCE" --> "BODY_FORCE" try: scrh = file.string_list(work_dir + '/definitions.h', 'INCLUDE_BODY_FORCE') tmp = string.split(scrh[0]) newline = "#define BODY_FORCE " + tmp[2] + "\n" n = file.string_find(work_dir + '/definitions.h', 'INCLUDE_BODY_FORCE') n = n[0] file.replace_line(work_dir + '/definitions.h', newline, n) except: pass # replace potential occurences of "INCLUDE_COOLING" --> "COOLING" try: scrh = file.string_list(work_dir + '/definitions.h', 'INCLUDE_COOLING') tmp = string.split(scrh[0]) newline = "#define COOLING " + tmp[2] + "\n" n = file.string_find(work_dir + '/definitions.h', 'INCLUDE_COOLING') n = n[0] file.replace_line(work_dir + '/definitions.h', newline, n) except: pass # replace potential occurences of "INCLUDE_BACKGROUND_FIELD" --> "BACKGROUND_FIELD" try: scrh = file.string_list(work_dir + '/definitions.h', 'INCLUDE_BACKGROUND_FIELD') tmp = string.split(scrh[0]) newline = "#define BACKGROUND_FIELD " + tmp[2] + "\n" n = file.string_find(work_dir + '/definitions.h', 'INCLUDE_BACKGROUND_FIELD') n = n[0] file.replace_line(work_dir + '/definitions.h', newline, n) except: pass # replace potential occurences of "TIME_EVOLUTION" --> "TIME_STEPPING" try: scrh = file.string_list(work_dir + '/definitions.h', 'TIME_EVOLUTION') tmp = string.split(scrh[0]) newline = "#define TIME_STEPPING " + tmp[2] + "\n" n = file.string_find(work_dir + '/definitions.h', 'TIME_EVOLUTION') n = n[0] file.replace_line(work_dir + '/definitions.h', newline, n) except: pass # replace potential occurences of "FLUX_CT" --> "CONSTRAINED_TRANSPORT" try: scrh = file.string_find(work_dir + '/definitions.h', 'FLUX_CT') file.replace_line( work_dir + '/definitions.h', "#define MHD_FORMULATION CONSTRAINED_TRANSPORT\n", scrh[0]) except: pass # replace potential occurences of "RAYMOND" --> "SNEq" try: scrh = file.string_find(work_dir + '/definitions.h', 'RAYMOND') file.replace_line(work_dir + '/definitions.h', "#define COOLING SNEq\n", scrh[0]) except: pass # replace potential occurences of "NEQ" --> "MINEq" try: scrh = file.string_find(work_dir + '/definitions.h', 'NEQ') file.replace_line(work_dir + '/definitions.h', "#define COOLING MINEq\n", scrh[0]) except: pass # replace potential occurences of "CT_VEC_POT_INIT" --> "USE_VECTOR_POTENTIAL" try: scrh = file.string_list(work_dir + '/definitions.h', 'CT_VEC_POT_INIT') tmp = string.split(scrh[0]) newline = "#define USE_VECTOR_POTENTIAL " + tmp[2] + "\n" n = file.string_find(work_dir + '/definitions.h', 'CT_VEC_POT_INIT') n = n[0] file.replace_line(work_dir + '/definitions.h', newline, n) except: pass # replace potential occurences of "USE_VECTOR_POTENTIAL" --> # "ASSIGN_VECTOR_POTENTIAL" try: scrh = file.string_list(work_dir + '/definitions.h', 'USE_VECTOR_POTENTIAL') tmp = string.split(scrh[0]) newline = "#define ASSIGN_VECTOR_POTENTIAL " + tmp[2] + "\n" n = file.string_find(work_dir + '/definitions.h', 'USE_VECTOR_POTENTIAL') n = n[0] file.replace_line(work_dir + '/definitions.h', newline, n) except: pass # replace potential occurences of "SAVE_VEC_POT" --> # "UPDATE_VECTOR_POTENTIAL" try: scrh = file.string_list(work_dir + '/definitions.h', 'SAVE_VEC_POT') tmp = string.split(scrh[0]) newline = "#define UPDATE_VECTOR_POTENTIAL " + tmp[2] + "\n" n = file.string_find(work_dir + '/definitions.h', 'SAVE_VEC_POT') n = n[0] file.replace_line(work_dir + '/definitions.h', newline, n) except: pass return
def problem(work_dir, pluto_path, pluto_dir, additional_files, additional_flags, makefile_template, AUTO_UPDATE): # before proceeding we scan pre-existing definitions.h # for obsolete statements in order to and make proper replacements. replace_obsoletes(work_dir) # sys.exit(1) HD = 1 RHD = 2 MHD = 3 SRMHD = 4 RMHD = 5 WITH_CHOMBO = 0 # enable/disable Chombo AMR FULL = 0 WITH_FD = 0 # enable/disable finite difference schemes WITH_SB = 0 # enable/disable shearing box module WITH_FARGO = 0 # enable/disable FARGO module for orbital advection # ***************************************** # check command line arguments # ***************************************** for x in sys.argv: if (x == "--with-chombo" or x == "--with-chombo:"): WITH_CHOMBO = 1 if (x == "--full"): FULL = 1 if (x == "--with-fd"): WITH_FD = 1 if (x == "--with-sb"): WITH_SB = 1 if (x == "--with-fargo"): WITH_FARGO = 1 # -- default makefile template -- if (WITH_CHOMBO): makefile_template.append('/Src/Templates/makefile.chombo') else: makefile_template.append('/Src/Templates/makefile') # Create user-editable menu entries = [] options = [] default = [] scrh = [] entries.append('PHYSICS') if (WITH_FD or WITH_FARGO): options.append(['HD','MHD']) default.append('HD') elif (WITH_SB): options.append(['MHD']) default.append('MHD') else: options.append(['HD','RHD','MHD','RMHD']) default.append('HD') entries.append('DIMENSIONS') if(WITH_SB or WITH_FARGO): options.append(['2','3']) default.append('2') else: options.append(['1','2','3']) default.append('1') entries.append('COMPONENTS') if (WITH_SB): options.append(['2','3']) default.append('2') else: options.append(['1','2','3']) default.append('1') entries.append('GEOMETRY') if (WITH_CHOMBO): # options.append(['CARTESIAN','CYLINDRICAL','AXISYM']) options.append(['CARTESIAN','CYLINDRICAL']) default.append('CARTESIAN') elif (WITH_FD or WITH_SB): options.append(['CARTESIAN']) default.append('CARTESIAN') else: # options.append(['CARTESIAN','CYLINDRICAL','AXISYM','POLAR','SPHERICAL']) options.append(['CARTESIAN','CYLINDRICAL','POLAR','SPHERICAL']) default.append('CARTESIAN') # entries.append('UNIFORM_GRID') # if (WITH_CHOMBO): # options.append('YES') # default.append('YES') # else: # options.append(['YES','NO']) # default.append('YES') entries.append('BODY_FORCE') if (WITH_SB): options.append(['VECTOR', 'POTENTIAL', '(VECTOR+POTENTIAL)']) default.append('VECTOR') else: options.append(['NO','VECTOR', 'POTENTIAL', '(VECTOR+POTENTIAL)']) default.append('NO') entries.append('COOLING') options.append(['NO','POWER_LAW','TABULATED','SNEq','MINEq']) # ,'H2_COOL']) default.append('NO') # entries.append('INCLUDE_PARTICLES') # options.append(['NO','YES']) # default.append('NO') # set interpolation options entries.append('INTERPOLATION') if (WITH_CHOMBO): options.append(['FLAT','LINEAR','WENO3','PARABOLIC']) default.append('LINEAR') elif (FULL): options.append(['FLAT','LINEAR','LimO3', 'WENO3','PARABOLIC', 'MP5']) default.append('LINEAR') elif (WITH_FD): options.append(['WENO3_FD', 'WENOZ_FD', 'MP5_FD','LIMO3_FD']) default.append('WENOZ_FD') else: options.append(['FLAT','LINEAR','LimO3','WENO3','PARABOLIC']) # Default default.append('LINEAR') entries.append('TIME_STEPPING') if (WITH_CHOMBO): # options.append(['HANCOCK','CHARACTERISTIC_TRACING','RK_MIDPOINT','EULER','RK2']) options.append(['EULER','HANCOCK','CHARACTERISTIC_TRACING','RK2']) default.append('HANCOCK') elif (WITH_FD): options.append(['RK3']) default.append('RK3') else: # options.append(['EULER','RK_MIDPOINT','RK2','RK3','HANCOCK','CHARACTERISTIC_TRACING']) options.append(['EULER','RK2','RK3','HANCOCK','CHARACTERISTIC_TRACING']) default.append('RK2') entries.append('DIMENSIONAL_SPLITTING') if (WITH_CHOMBO or WITH_FARGO): options.append(['NO']) default.append('NO') else: options.append(['YES','NO']) default.append('YES') entries.append('NTRACER') for n in range(5): scrh.append(repr(n)) options.append(scrh) default.append('0') scrh =[] entries.append('USER_DEF_PARAMETERS') for n in range(32): scrh.append(repr(n+1)) options.append(scrh) default.append('1') # ************************************************** # If definitions.h already exists try to read # default values from it. # ************************************************** if (os.path.exists(work_dir+'/definitions.h')): for x in entries: try: scrh = file.string_list(work_dir+'/definitions.h',x) tmp = string.split(scrh[0]) i = entries.index(tmp[1]) y = options[i] i2 = y.index(tmp[2]) default[entries.index(x)] = tmp[2] except ValueError: continue except IndexError: continue # **** ok, call menu **** if AUTO_UPDATE == 0: selection = '' menu.SetTitle("Setup problem") selection = menu.Browse(entries,default,options) # selection = menu.select(entries,options,default,'Setup problem') # ************************************************** # define Physics module sub-menus # ************************************************** i = entries.index('DIMENSIONS') dimensions = int(default[i]) i = entries.index('PHYSICS') physics_module = default[i] i = entries.index('GEOMETRY') geometry = default[i] i = entries.index('INTERPOLATION') interpolation = default[i] i = entries.index('TIME_STEPPING') time_stepping = default[i] i = entries.index('DIMENSIONAL_SPLITTING') dim_splitting = default[i] # HD if physics_module == 'HD': entries_HD = [] options_HD = [] default_HD = [] entries_HD.append('EOS') options_HD.append(['IDEAL','ISOTHERMAL']) default_HD.append('IDEAL') entries_HD.append('ENTROPY_SWITCH') options_HD.append(['NO','YES']) default_HD.append('NO') entries_HD.append('THERMAL_CONDUCTION') if (WITH_CHOMBO == 1): options_HD.append(['NO','EXPLICIT']) else: # options_HD.append(['NO','EXPLICIT','SUPER_TIME_STEPPING','RK_CHEBYSHEV']) options_HD.append(['NO','EXPLICIT','SUPER_TIME_STEPPING']) default_HD.append('NO') entries_HD.append('VISCOSITY') if (WITH_CHOMBO == 1): options_HD.append(['NO','EXPLICIT']) else: # options_HD.append(['NO','EXPLICIT','SUPER_TIME_STEPPING','RK_CHEBYSHEV']) options_HD.append(['NO','EXPLICIT','SUPER_TIME_STEPPING']) default_HD.append('NO') entries_HD.append('ROTATING_FRAME') options_HD.append(['NO','YES']) default_HD.append('NO') # if (physics_module == "HD" and dim_splitting == "YES"): # if (geometry == "POLAR" or geometry == "SPHERICAL"): # entries_HD.append('FARGO_SCHEME') # options_HD.append(['NO','YES']) # default_HD.append('NO') # Read HD pre-existing HD submenu defaults, if they exists if (os.path.exists(work_dir+'/definitions.h')): for x in entries_HD: try: scrh = file.string_list(work_dir+'/definitions.h',x) tmp = string.split(scrh[0]) default_HD[entries_HD.index(x)] = tmp[2] except IndexError: continue if AUTO_UPDATE == 0: selection = '' menu.SetTitle("HD Menu") selection = menu.Browse(entries_HD, default_HD, options_HD) # selection = menu.select(entries_HD,options_HD,default_HD,'HD MENU') # RHD if physics_module == 'RHD': entries_RHD = [] options_RHD = [] default_RHD = [] entries_RHD.append('EOS') options_RHD.append(['IDEAL','TAUB']) default_RHD.append('IDEAL') entries_RHD.append('USE_FOUR_VELOCITY') options_RHD.append(['NO','YES']) default_RHD.append('NO') entries_RHD.append('ENTROPY_SWITCH') options_RHD.append(['NO','YES']) default_RHD.append('NO') # Read RHD pre-existing RHD submenu defaults, if they exists if (os.path.exists(work_dir+'/definitions.h')): for x in entries_RHD: try: scrh = file.string_list(work_dir+'/definitions.h',x) tmp = string.split(scrh[0]) default_RHD[entries_RHD.index(x)] = tmp[2] except IndexError: continue if AUTO_UPDATE == 0: selection = '' menu.SetTitle("RHD Menu") selection = menu.Browse(entries_RHD, default_RHD, options_RHD) # selection = menu.select(entries_RHD,options_RHD,default_RHD,'RHD MENU') # MHD if (physics_module == 'MHD'): entries_MHD = [] options_MHD = [] default_MHD = [] entries_MHD.append('EOS') options_MHD.append(['IDEAL','BAROTROPIC','ISOTHERMAL']) default_MHD.append('IDEAL') entries_MHD.append('ENTROPY_SWITCH') options_MHD.append(['NO','YES']) default_MHD.append('NO') entries_MHD.append('MHD_FORMULATION') if (WITH_CHOMBO or WITH_FD): options_MHD.append(['NONE','EIGHT_WAVES','DIV_CLEANING']) default_MHD.append('EIGHT_WAVES') elif (WITH_SB or WITH_FARGO): options_MHD.append(['CONSTRAINED_TRANSPORT']) default_MHD.append('CONSTRAINED_TRANSPORT') else: options_MHD.append(['NONE','EIGHT_WAVES','DIV_CLEANING', 'CONSTRAINED_TRANSPORT']) default_MHD.append('EIGHT_WAVES') entries_MHD.append('BACKGROUND_FIELD') options_MHD.append(['NO','YES']) default_MHD.append('NO') entries_MHD.append('RESISTIVE_MHD') if (WITH_CHOMBO == 1): options_MHD.append(['NO','EXPLICIT']) else: # options_MHD.append(['NO','EXPLICIT','SUPER_TIME_STEPPING','RK_CHEBYSHEV']) options_MHD.append(['NO','EXPLICIT','SUPER_TIME_STEPPING']) default_MHD.append('NO') entries_MHD.append('HALL_MHD') options_MHD.append(['NO','RIEMANN','SOURCE']) default_MHD.append('NO') entries_MHD.append('AMBIPOLAR_DIFFUSION') options_MHD.append(['NO','EXPLICIT']) default_MHD.append('NO') entries_MHD.append('THERMAL_CONDUCTION') if (WITH_CHOMBO == 1): options_MHD.append(['NO','EXPLICIT']) else: # options_MHD.append(['NO','EXPLICIT','SUPER_TIME_STEPPING','RK_CHEBYSHEV']) options_MHD.append(['NO','EXPLICIT','SUPER_TIME_STEPPING']) default_MHD.append('NO') entries_MHD.append('VISCOSITY') if (WITH_CHOMBO == 1): options_MHD.append(['NO','EXPLICIT']) else: # options_MHD.append(['NO','EXPLICIT','SUPER_TIME_STEPPING','RK_CHEBYSHEV']) options_MHD.append(['NO','EXPLICIT','SUPER_TIME_STEPPING']) default_MHD.append('NO') entries_MHD.append('ROTATING_FRAME') options_MHD.append(['NO','YES']) default_MHD.append('NO') # Read MHD pre-existing MHD submenu defaults, if they exists if (os.path.exists(work_dir+'/definitions.h')): for x in entries_MHD: ix = entries_MHD.index(x) try: scrh = file.string_list(work_dir+'/definitions.h',x) tmp = string.split(scrh[0]) try: # if the choice is not in the permitted list of options, # ValueError is raised and the default choice is kept. i = options_MHD[ix].index(tmp[2]) default_MHD[ix] = tmp[2] except ValueError: continue except IndexError: continue if AUTO_UPDATE == 0: selection = '' if (physics_module == 'MHD'): menu.SetTitle("MHD Menu") selection = menu.Browse(entries_MHD, default_MHD, options_MHD) # selection = menu.select(entries_MHD,options_MHD,default_MHD,'MHD MENU') # RMHD if physics_module == 'RMHD': entries_RMHD = [] options_RMHD = [] default_RMHD = [] entries_RMHD.append('EOS') options_RMHD.append(['IDEAL','TAUB']) default_RMHD.append('IDEAL') entries_RMHD.append('ENTROPY_SWITCH') options_RMHD.append(['NO','YES']) default_RMHD.append('NO') entries_RMHD.append('MHD_FORMULATION') if (WITH_CHOMBO == 1): options_RMHD.append(['NONE','EIGHT_WAVES','DIV_CLEANING']) else: options_RMHD.append(['NONE','EIGHT_WAVES','DIV_CLEANING','CONSTRAINED_TRANSPORT']) default_RMHD.append('NONE') # Read RMHD pre-existing RMHD submenu defaults, if they exists if (os.path.exists(work_dir+'/definitions.h')): for x in entries_RMHD: ix = entries_RMHD.index(x) try: scrh = file.string_list(work_dir+'/definitions.h',x) tmp = string.split(scrh[0]) try: # if the choice is not in the permitted list of options, # ValueError is raised and the default choice is kept. i = options_RMHD[ix].index(tmp[2]) default_RMHD[ix] = tmp[2] except ValueError: continue except IndexError: continue if AUTO_UPDATE == 0: selection = '' if (physics_module == 'RMHD'): menu.SetTitle("RMHD Menu") selection = menu.Browse(entries_RMHD, default_RMHD, options_RMHD) # selection = menu.select(entries_RMHD,options_RMHD,default_RMHD,'RMHD MENU') # ******************************************************************** # USER_DEF PARAMETERS: # # Read them from definitions.h if the file exists; # assign 'SCRH' otherwise. # ******************************************************************** i = entries.index('USER_DEF_PARAMETERS') npar = int(default[i]) u_def_par = [] if (os.path.exists(work_dir+'/definitions.h')): scrh = file.word_find(work_dir+'/definitions.h','parameters') k0 = scrh[0] + 2 scrh = file.read_lines(work_dir+'/definitions.h', k0, k0 + npar) for n in range(npar): try: x = string.split(scrh[n]) if (x[0] == "#define"): u_def_par.append(x[1]) else: u_def_par.append('SCRH') except IndexError: u_def_par.append('SCRH') # scrh[n + 1] = '#define SCRH x' else: for n in range(npar): u_def_par.append('SCRH') if AUTO_UPDATE == 0: # u_def_par = ['SCRH'] menu.SetTitle ("User-defined parameters") menu.Insert(int(default[i]),u_def_par) # menu.put(int(default[i]),u_def_par,'USER DEF SECTION') # ----------------------------------------------------- # Create the list 'tmp' that will be used to write # the new definitions.h header file # ----------------------------------------------------- tmp = [] for x in entries: i = entries.index(x) y = default[i] tmp.append('#define '+x.ljust(21)+' '+y+'\n') tmp.append('\n/* -- physics dependent declarations -- */\n\n'); if (physics_module == 'MHD'): for x in entries_MHD: i = entries_MHD.index(x) tmp.append('#define '+x.ljust(21)+' '+default_MHD[i]+'\n') if physics_module == 'HD': for x in entries_HD: i = entries_HD.index(x) tmp.append('#define '+x.ljust(21)+' '+default_HD[i]+'\n') if physics_module == 'RHD': for x in entries_RHD: i = entries_RHD.index(x) tmp.append('#define '+x.ljust(21)+' '+default_RHD[i]+'\n') if physics_module == 'RMHD': for x in entries_RMHD: i = entries_RMHD.index(x) tmp.append('#define '+x.ljust(21)+' '+default_RMHD[i]+'\n') # ***************************************** # add Chombo-AMR specific flags # ***************************************** if (WITH_CHOMBO and os.path.exists(work_dir+'/definitions.h')): scrh = file.string_list(work_dir+'/definitions.h','AMR_EN_SWITCH') tmp.append('\n/* -- Chombo-AMR flags -- */\n\n'); if (len(scrh) != 0): strsplit = string.split(scrh[0]) value = strsplit[2] tmp.append('#define AMR_EN_SWITCH '+value+'\n') else: tmp.append('#define AMR_EN_SWITCH NO\n') # ******************************************************* # add pointer names to user defined parameters # ******************************************************* tmp.append('\n/* -- pointers to user-def parameters -- */\n\n'); for x in u_def_par: i = u_def_par.index(x) tmp.append('#define '+x.ljust(16)+' '+repr(i)+'\n') # !!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!! # In this section, also, udpate the pluto.ini # initialization file by appending the correct # sequence of user defined parameters # !!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!! # menu.RestoreScreen() plutoini = work_dir+"/pluto.ini" scrh = file.string_find (plutoini, 'Parameters') ipos = scrh[0] + 2 # start reading/writing pluto.ini at this point # to build a list of the userdef parameters scrh = file.read_lines(plutoini,ipos,999) # read until end of file pname = [] pvalue = [] for x in scrh: y = string.split(x) # pname and pvalue contain the list of parameter if (len(y) == 0): continue # skip blank lines pname.append (y[0]) # names and their respective values as present pvalue.append(y[1]) # in pluto.ini for x in u_def_par: # loop on the actual list of parameters; par_exist = 0 # is the parameter already present in pluto.ini ? for y in pname: if (x == y): # if yes, use the original value instead of '0' par_exist = 1 i = pname.index(y) file.insert (plutoini, pname[i] + " " + pvalue[i] + "\n", ipos) break if (par_exist == 0): # if not, set default value to 0 file.insert (plutoini, x+' 0\n',ipos) ipos = ipos + 1 # delete all other lines in pluto.ini file.delete_lines(plutoini, ipos, ipos + 256) # *************************************************************** # check dependencies for conditional inclusion # of additional object files; this is useful # for makefile creation # *************************************************************** # additional files will be compiled # depending on the user's choice of # time integration scheme # the next line removes all elements from additional_files # and pluto_path so the list can be built from scratch # for x in additional_files: additional_files.remove(x) # for x in pluto_path : pluto_path.remove(x) additional_files[:] = [] additional_flags[:] = [] pluto_path[:] = [] divb = ' ' # ********************************************** # physics module & parabolic term treatment # ********************************************** sts_flag = 0 # if changed to 1, include the super-time-stepping driver rkc_flag = 0 # if changed to 1, include the runge-kutta-Chebyshev driver exp_flag = 0 # if changed to 1, include explicit parabolic time-stepping cur_flag = 0 # if changed to 1, include current calculation if (physics_module == 'HD'): pluto_path.append('HD/') entries_MOD = entries_HD default_MOD = default_HD n = entries_MOD.index('THERMAL_CONDUCTION') if (default_MOD[n] != 'NO'): pluto_path.append('Thermal_Conduction/') if (default_MOD[n] == 'SUPER_TIME_STEPPING'): sts_flag = 1 elif (default_MOD[n] == 'RK_CHEBYSHEV'): rkc_flag = 1 elif (default_MOD[n] == 'EXPLICIT'): exp_flag = 1 n = entries_MOD.index('VISCOSITY') if (default_MOD[n] != 'NO'): pluto_path.append('Viscosity/') if (default_MOD[n] == 'SUPER_TIME_STEPPING'): sts_flag = 1 elif (default_MOD[n] == 'RK_CHEBYSHEV'): rkc_flag = 1 elif (default_MOD[n] == 'EXPLICIT'): exp_flag = 1 elif (physics_module == 'RHD'): pluto_path.append('RHD/') entries_MOD = entries_RHD default_MOD = default_RHD elif (physics_module == 'MHD'): pluto_path.append('MHD/') entries_MOD = entries_MHD default_MOD = default_MHD n = entries_MOD.index('MHD_FORMULATION') divb = default_MOD[n] if (divb == 'CONSTRAINED_TRANSPORT'): pluto_path.append('MHD/CT/') elif (divb == 'DIV_CLEANING'): pluto_path.append('MHD/GLM/') n = entries_MOD.index('RESISTIVE_MHD') if (default_MOD[n] != 'NO'): pluto_path.append('MHD/Resistive/') cur_flag = 1 if (default_MOD[n] == 'SUPER_TIME_STEPPING'): sts_flag = 1 elif (default_MOD[n] == 'RK_CHEBYSHEV'): rkc_flag = 1 elif (default_MOD[n] == 'EXPLICIT'): exp_flag = 1 n = entries_MOD.index('HALL_MHD') if (default_MOD[n] != 'NO'): pluto_path.append('MHD/Hall/') if (default_MOD[n] == 'RIEMANN'): cur_flag = 1 n = entries_MOD.index('AMBIPOLAR_DIFFUSION') if (default_MOD[n] != 'NO'): pluto_path.append('MHD/Ambipolar/') cur_flag = 1 n = entries_MOD.index('THERMAL_CONDUCTION') if (default_MOD[n] != 'NO'): pluto_path.append('Thermal_Conduction/') if (default_MOD[n] == 'SUPER_TIME_STEPPING'): sts_flag = 1 elif (default_MOD[n] == 'RK_CHEBYSHEV'): rkc_flag = 1 elif (default_MOD[n] == 'EXPLICIT'): exp_flag = 1 n = entries_MOD.index('VISCOSITY') if (default_MOD[n] != 'NO'): pluto_path.append('Viscosity/') if (default_MOD[n] == 'SUPER_TIME_STEPPING'): sts_flag = 1 elif (default_MOD[n] == 'RK_CHEBYSHEV'): rkc_flag = 1 elif (default_MOD[n] == 'EXPLICIT'): exp_flag = 1 if ( cur_flag == 1): pluto_path.append('MHD/Current/') additional_flags.append(' -DNEED_CURRENT') # *************************** # need shearingbox module ? # *************************** if (WITH_SB == 1): pluto_path.append('MHD/ShearingBox/') additional_flags.append(' -DSHEARINGBOX') elif (physics_module == 'RMHD'): pluto_path.append('RMHD/') entries_MOD = entries_RMHD default_MOD = default_RMHD n = entries_MOD.index('MHD_FORMULATION') divb = default_MOD[n] if (divb == 'CONSTRAINED_TRANSPORT'): pluto_path.append('MHD/CT/') elif (divb == 'DIV_CLEANING'): pluto_path.append('MHD/GLM/') # ***************************** # Interpolation # ***************************** if (interpolation == 'FLAT'): additional_files.append('states_flat.o') elif (interpolation == 'LINEAR'): additional_files.append('states_plm.o') elif (interpolation == 'PARABOLIC'): additional_files.append('states_ppm.o') elif (interpolation == 'LimO3'): additional_files.append('states_limo3.o') elif (interpolation == 'WENO3'): additional_files.append('states_weno3.o') elif (WITH_FD): # Finite Difference additional_files.append('states_fd.o') additional_files.append('fd_reconstruct.o') additional_files.append('fd_flux.o') additional_flags.append(' -DFINITE_DIFFERENCE') # ***************************** # Time Stepping # ***************************** if (WITH_CHOMBO): # ** AMR file inclusion ** if (dimensions == 1): additional_files.append('PatchCTU.1D.o') else: if (time_stepping == 'RK_MIDPOINT'): additional_files.append('PatchRK.3D.o') elif (time_stepping == 'EULER'): additional_files.append('PatchEuler.3D.o') elif (time_stepping == 'RK2'): additional_files.append('PatchEuler.3D.o') else: additional_files.append('PatchCTU.3D.o') else: if (time_stepping == 'CHARACTERISTIC_TRACING'): if (dim_splitting == 'YES'): additional_files.append('sweep.o') else: additional_files.append('unsplit_ctu.o') elif (time_stepping == 'HANCOCK'): if (dim_splitting == 'YES'): additional_files.append('sweep.o') else: additional_files.append('unsplit_ctu.o') elif (time_stepping == 'RK_MIDPOINT'): additional_files.append('rk_midpoint.o') else: if (dim_splitting == 'YES'): additional_files.append('sweep.o') else: additional_files.append('unsplit.o') if (time_stepping == 'CHARACTERISTIC_TRACING'): additional_files.append('char_tracing.o') elif (time_stepping == 'HANCOCK'): additional_files.append('hancock.o') # if (interpolation != 'LINEAR'): # if (time_stepping == 'CHARACTERISTIC_TRACING'): # additional_files.append('states_ppm_char.o') # else: # additional_files.append('rk_states.o') # ***************************** # FARGO Scheme # ***************************** if (WITH_FARGO): pluto_path.append('Fargo/') additional_flags.append(' -DFARGO') # ***************************** # Geometry # ***************************** # additional_files.append('rhs.o') # additional_files.append('rhs.o') # if (geometry == "CARTESIAN"): # additional_files.append('rhs_cart.o') # if (geometry == "AXISYM"): # additional_files.append('cylsource.o') # ***************************** # Cooling # ***************************** n = entries.index('COOLING') if (default[n] == 'POWER_LAW'): pluto_path.append('Cooling/Power_Law/') elif (default[n] == 'TABULATED'): pluto_path.append('Cooling/Tab/') additional_files.append('cooling_source.o') additional_files.append('cooling_ode_solver.o') elif (default[n] == 'SNEq'): pluto_path.append('Cooling/SNEq/') additional_files.append('cooling_source.o') additional_files.append('cooling_ode_solver.o') elif (default[n] == 'MINEq'): pluto_path.append('Cooling/MINEq/') additional_files.append('cooling_source.o') additional_files.append('cooling_ode_solver.o') elif (default[n] == 'H2_COOL'): pluto_path.append('Cooling/H2_COOL/') additional_files.append('cooling_source.o') additional_files.append('cooling_ode_solver.o') # ********************************** # parabolic flux: file inclusion # ********************************** if (sts_flag == 1): additional_files.append('sts.o') additional_files.append('parabolic_rhs.o') if (rkc_flag == 1): additional_files.append('rkc.o') additional_files.append('parabolic_rhs.o') if (exp_flag == 1): additional_files.append('parabolic_flux.o') # ********************************************** # Vector potential # ********************************************** if (physics_module == 'MHD' or physics_module == 'RMHD'): additional_files.append('vec_pot_diff.o') if (WITH_CHOMBO == 0): additional_files.append('vec_pot_update.o') # ***************************** # Particles # ***************************** # n = entries.index('INCLUDE_PARTICLES') # if (default[n] == 'YES'): # pluto_path.append('Particles/') # **************************************************************** # DEFINE ALL NON-USER FRIENDLY CONSTANTS # **************************************************************** tmp.append('\n/* -- supplementary constants (user editable) -- */ \n\n') no_us_fr = [] no_us_fr.append('#define INITIAL_SMOOTHING NO\n') no_us_fr.append('#define WARNING_MESSAGES NO\n') no_us_fr.append('#define PRINT_TO_FILE NO\n') no_us_fr.append('#define INTERNAL_BOUNDARY NO\n') no_us_fr.append('#define SHOCK_FLATTENING NO\n') if (not WITH_FD): no_us_fr.append('#define ARTIFICIAL_VISCOSITY NO\n') no_us_fr.append('#define CHAR_LIMITING NO\n') no_us_fr.append('#define LIMITER DEFAULT\n') # add geometry-dependent switches if (geometry == "AXISYM"): no_us_fr.append('#define ADD_CYLSOURCE 1\n') # if (geometry == "POLAR" and physics_module == "HD"): # no_us_fr.append('#define FARGO_SCHEME NO\n') # add flux ct switches for MHD or RMHD if (divb == "CONSTRAINED_TRANSPORT"): no_us_fr.append('#define CT_EMF_AVERAGE UCT_HLL\n') no_us_fr.append('#define CT_EN_CORRECTION NO\n') no_us_fr.append('#define ASSIGN_VECTOR_POTENTIAL YES\n') elif (physics_module == "MHD" or physics_module == "RMHD"): no_us_fr.append('#define ASSIGN_VECTOR_POTENTIAL NO\n') if (physics_module == "MHD" or physics_module == "RMHD"): if (not WITH_CHOMBO): no_us_fr.append('#define UPDATE_VECTOR_POTENTIAL NO\n') if (time_stepping == 'HANCOCK'): if (physics_module == 'RMHD'): no_us_fr.append('#define PRIMITIVE_HANCOCK NO\n') else: no_us_fr.append('#define PRIMITIVE_HANCOCK YES\n') # add definition of STS_NU if (sts_flag == 1): no_us_fr.append('#define STS_nu 0.01\n') # *************************************************************** # Read pre-existing non-user-editable defaults; # Use the default value if they exist # *************************************************************** if (os.path.exists(work_dir+'/definitions.h')): for x in no_us_fr: try: xl = string.split(x) scrh = file.string_list(work_dir+'/definitions.h',xl[1]) no_us_fr[no_us_fr.index(x)] = scrh[0] except IndexError: continue # add elements of no_us_fr to tmp for x in no_us_fr: tmp.append(x) # -- create definitions.h -- file.create_file(work_dir+'/definitions.h',tmp) return
def replace_obsoletes(work_dir): # replace potential occurences of "INCLUDE_ROTATION" --> "ROTATING_FRAME" try: scrh = file.string_list(work_dir+'/definitions.h','INCLUDE_ROTATION') tmp = string.split(scrh[0]) newline = "#define ROTATING_FRAME "+tmp[2]+"\n" n = file.string_find(work_dir+'/definitions.h','INCLUDE_ROTATION') n = n[0] file.replace_line(work_dir+'/definitions.h', newline, n) except: pass # replace potential occurences of "INCLUDE_BODY_FORCE" --> "BODY_FORCE" try: scrh = file.string_list(work_dir+'/definitions.h','INCLUDE_BODY_FORCE') tmp = string.split(scrh[0]) newline = "#define BODY_FORCE "+tmp[2]+"\n" n = file.string_find(work_dir+'/definitions.h','INCLUDE_BODY_FORCE') n = n[0] file.replace_line(work_dir+'/definitions.h', newline, n) except: pass # replace potential occurences of "INCLUDE_COOLING" --> "COOLING" try: scrh = file.string_list(work_dir+'/definitions.h','INCLUDE_COOLING') tmp = string.split(scrh[0]) newline = "#define COOLING "+tmp[2]+"\n" n = file.string_find(work_dir+'/definitions.h','INCLUDE_COOLING') n = n[0] file.replace_line(work_dir+'/definitions.h', newline, n) except: pass # replace potential occurences of "INCLUDE_BACKGROUND_FIELD" --> "BACKGROUND_FIELD" try: scrh = file.string_list(work_dir+'/definitions.h','INCLUDE_BACKGROUND_FIELD') tmp = string.split(scrh[0]) newline = "#define BACKGROUND_FIELD "+tmp[2]+"\n" n = file.string_find(work_dir+'/definitions.h','INCLUDE_BACKGROUND_FIELD') n = n[0] file.replace_line(work_dir+'/definitions.h', newline, n) except: pass # replace potential occurences of "TIME_EVOLUTION" --> "TIME_STEPPING" try: scrh = file.string_list(work_dir+'/definitions.h','TIME_EVOLUTION') tmp = string.split(scrh[0]) newline = "#define TIME_STEPPING "+tmp[2]+"\n" n = file.string_find(work_dir+'/definitions.h','TIME_EVOLUTION') n = n[0] file.replace_line(work_dir+'/definitions.h', newline, n) except: pass # replace potential occurences of "FLUX_CT" --> "CONSTRAINED_TRANSPORT" try: scrh = file.string_find(work_dir+'/definitions.h','FLUX_CT') file.replace_line(work_dir+'/definitions.h', "#define MHD_FORMULATION CONSTRAINED_TRANSPORT\n",scrh[0]) except: pass # replace potential occurences of "RAYMOND" --> "SNEq" try: scrh = file.string_find(work_dir+'/definitions.h','RAYMOND') file.replace_line(work_dir+'/definitions.h', "#define COOLING SNEq\n",scrh[0]) except: pass # replace potential occurences of "NEQ" --> "MINEq" try: scrh = file.string_find(work_dir+'/definitions.h','NEQ') file.replace_line(work_dir+'/definitions.h', "#define COOLING MINEq\n",scrh[0]) except: pass # replace potential occurences of "CT_VEC_POT_INIT" --> "USE_VECTOR_POTENTIAL" try: scrh = file.string_list(work_dir+'/definitions.h','CT_VEC_POT_INIT') tmp = string.split(scrh[0]) newline = "#define USE_VECTOR_POTENTIAL "+tmp[2]+"\n" n = file.string_find(work_dir+'/definitions.h','CT_VEC_POT_INIT') n = n[0] file.replace_line(work_dir+'/definitions.h', newline, n) except: pass # replace potential occurences of "USE_VECTOR_POTENTIAL" --> # "ASSIGN_VECTOR_POTENTIAL" try: scrh = file.string_list(work_dir+'/definitions.h','USE_VECTOR_POTENTIAL') tmp = string.split(scrh[0]) newline = "#define ASSIGN_VECTOR_POTENTIAL "+tmp[2]+"\n" n = file.string_find(work_dir+'/definitions.h','USE_VECTOR_POTENTIAL') n = n[0] file.replace_line(work_dir+'/definitions.h', newline, n) except: pass # replace potential occurences of "SAVE_VEC_POT" --> # "UPDATE_VECTOR_POTENTIAL" try: scrh = file.string_list(work_dir+'/definitions.h','SAVE_VEC_POT') tmp = string.split(scrh[0]) newline = "#define UPDATE_VECTOR_POTENTIAL "+tmp[2]+"\n" n = file.string_find(work_dir+'/definitions.h','SAVE_VEC_POT') n = n[0] file.replace_line(work_dir+'/definitions.h', newline, n) except: pass return
def xres (fini): dimstr = file.string_list(fini,"X1-grid") dimstr = string.split(dimstr[0]) return string.atoi(dimstr[3])
def DIMENSIONS (fdef): dimstr = file.string_list(fdef,"DIMENSIONS") dimstr = string.split(dimstr[0]) return string.atoi(dimstr[2])
def xend (fini): dimstr = file.string_list(fini,"X1-grid") dimstr = string.split(dimstr[0]) return string.atof(dimstr[5])