8 def __convert__(self,valeur):
9 if type(valeur) == types.StringType: return None
10 if len(valeur) != self.ntuple: return None
14 return "Date : jj/mm/aaaa "
23 def __convert__(self,valeur):
24 if type(valeur) == types.StringType: return None
25 if len(valeur) != self.ntuple: return None
29 return "heure : hh/mm/ss "
35 JdC = JDC_CATA (code = 'MAP',
38 # ======================================================================
39 # Catalog entry for the MAP function : c_pre_interfaceBody_mesh
40 # ======================================================================
41 INITIALIZATION=PROC(nom="INITIALIZATION",op=None,
42 fr="Initialisation des fichiers d'entrée et de sortie",
43 ang="Input and Output files initialization",
45 Title = SIMP( statut='o',typ='TXM'),
46 Working_Directory = SIMP( statut='o',typ='Repertoire',defaut='/tmp'),
48 Files= FACT(statut='o',
49 Dictionary = SIMP( statut='o', typ = ('Fichier', 'Dico (*.dico);;All Files (*)',), defaut='telemac2d.dico',),
50 Geometry_File_Format = SIMP( statut='o',typ='TXM',into=['SERAFIN','MED','SERAFIND'], defaut='SERAFIN',
51 fr='Format du fichier de geometrie. Les valeurs possibles sont : - SERAFIN : format standard simple precision pour Telemac; - SERAFIND: format standard double precision pour Telemac; - MED : format MED base sur HDF5',
52 ang='Results file format. Possible values are: - SERAFIN : classical single precision format in Telemac; - SERAFIND: classical double precision format in Telemac; - MED : MED format based on HDF5',) ,
53 Geometry_File = SIMP( statut='o', typ = ('Fichier', 'Geo Files (*.geo);;All Files (*)',),
54 fr='Nom du fichier contenant le maillage du calcul a realiser.',
55 ang='Name of the file containing the mesh. This file may also contain the topography and the friction coefficients.'),
56 #Steering_File = SIMP( statut='o', typ = ('Fichier', 'Steering Files (*.cas);;All Files (*)',),),
57 Results_File_Format = SIMP( statut='o',typ='TXM',into=['SERAFIN','MED','SERAFIND'], defaut='SERAFIN',
58 fr = 'Format du fichier de resultats. Les valeurs possibles sont : \n- SERAFIN : format standard simple precision pour Telemac; - SERAFIND: format standard double precision pour Telemac; - MED : format MED base sur HDF5' ,
59 ang = 'Results file format. Possible values are:\n - SERAFIN : classical single precision format in Telemac;\n - SERAFIND: classical double precision format in Telemac; - MED : MED format based on HDF5' ,),
61 Results_File = SIMP( statut='o', typ = ('Fichier', 'Steering Files (*.cas);;All Files (*)',),),
62 # Inexistant eventuellement
63 Fortran_File = SIMP(statut='f',typ = ('Fichier', 'Fortran files (*.f);;All Files (*)'),
64 fr='Nom du fichier a soumettre',
65 ang='Name of FORTRAN file to be submitted',),
66 Boundary_Condition_File = SIMP( statut='o', typ = ('Fichier', 'Boundary Condition (*.cli);;All Files (*)',),),
67 Reference_File = SIMP( statut='f', typ = ('Fichier', 'Reference File (*.ref);;All Files (*)',),),
70 Formated_And_Binary_Files=FACT( statut='f',
71 Formated_File1 = SIMP( statut='f', typ = ('Fichier', 'formated File (*.txt);;All Files (*)',),),
72 Formated_File2 = SIMP( statut='f', typ = ('Fichier', 'formated File (*.txt);;All Files (*)',),),
73 Binary_Data_File1 = SIMP( statut='f', typ = ('Fichier', 'Reference File (*.txt);;All Files (*)',),),
74 Binary_Data_File2 = SIMP( statut='f', typ = ('Fichier', 'Reference File (*.txt);;All Files (*)',),),
76 Computation_Continued=FACT( statut='f',
77 Previous_Computation_File_Format=SIMP( statut='o',typ='TXM',into=['SERAFIN','MED','SERAFIND'],defaut='SERAFIN',),
78 Previous_Computation_File = SIMP( statut='o',
79 typ = ('Fichier', 'Computation File (*.res);;All Files (*)',),
80 fr = "Nom d'un fichier contenant les resultats d'un calcul precedent realise sur le meme maillage et dont le dernier pas de temps enregistre va fournir les conditions initiales pour une suite de de calcul.",
81 ang = 'Name of a file containing the results of an earlier computation which was made on the same mesh. The last recorded time step will provid the initial conditions for the new computation.',
83 Previous_Computation_Comm = SIMP( statut='f', typ = ('Fichier', 'COMM(*.comm);;All Files (*)',),
84 fr = "Nom du fichier .comm décrivant le cas précédent",
85 ang = "Name of a file containing the earlier study" ,),
86 Initial_Time_Set = SIMP(typ=bool, statut='f',
87 fr = 'Remet le temps a zero en cas de suite de calcul',
88 ang = 'Initial time set to zero in case of restart',
90 Record_Number_For_Restart = SIMP(typ='I', statut='o', defaut=0,
91 fr = "numero de l'enregistrementde depart dans le fichier du calcul precedent. 0 signifie qu'on prend le dernier enregistrement",
92 ang ="record number to start from in the previous computation file, 0 for last record" ),
94 Computation=FACT(statut='o',
95 Machine=FACT( statut='o',
96 Number_of_Processors=SIMP(statut='o',typ='I',val_min=0,defaut=1),
97 Parallel_Computation=SIMP(statut='o',typ=bool,defaut=False),
99 Coupling=FACT( statut='o',
100 Sisyphe=SIMP(statut='o',typ=bool,defaut=False),
101 Tomawac=SIMP(statut='o',typ=bool,defaut=False),
102 Delwacq=SIMP(statut='o',typ=bool,defaut=False),
107 TIDE_PARAMETERS=PROC(nom="TIDE_PARAMETERS",op=None,
110 Time=FACT( statut='o',
111 #Original_Date_of_Time=SIMP(statut='f',typ=DateJJMMAAAA,validators=VerifTypeTuple(('R','R','R'))),
112 #Original_Hour_of_Time=SIMP(statut='f',typ=HeureHHMMSS,validators=VerifTypeTuple(('R','R','R'))),
113 Original_Date_of_Time=FACT( statut='o',
114 fr = "Permet de fixer la date d'origine des temps du modele lors de la prise en compte de la force generatrice de la maree.",
115 ang ='Give the date of the time origin of the model when taking into account the tide generating force.',
116 Year=SIMP(statut='o',typ='I',val_min=1900,defaut=1900),
117 Month=SIMP(statut='o',typ='I',val_min=1,val_max=12,defaut=1),
118 Day=SIMP(statut='o',typ='I',val_min=1,val_max=31,defaut=1),
120 Original_Hour_of_Time=FACT( statut='f',
121 fr = "Permet de fixer l'heure d'origine des temps du modele lors de la prise en compte de la force generatrice de la maree.",
122 ang ='Give the time of the time origin of the model when taking into account the tide generating force.',
123 Hour=SIMP(statut='o',typ='I',val_min=0,val_max=24,defaut=0),
124 Minute=SIMP(statut='o',typ='I',val_min=0,val_max=60,defaut=0),
125 Second=SIMP(statut='o',typ='I',val_min=0,val_max=60,defaut=0),
128 Location=FACT( statut='f',
129 #regles=( PRESENT_PRESENT('Longitude_of_origin','Latitute_of_origin', ),),
130 #Spatial_Projection=SIMP(statut='f',typ='I',into=[1,2,3]),
131 #Geographic_System=SIMP(statut='f',typ='I',into=[-1,0,1,2,3,4,5]),
133 Geographic_System=SIMP(statut='f',typ='TXM',
134 into=["DEFINI PAR L'UTILISATEUR", "WGS84 LONGITUDE/LATITUDE EN DEGRES REELS","WGS84 NORD UTM",'WGS84 SUD UTM','LAMBERT', 'MERCATOR'],
135 defaut="DEFINI PAR L'UTILISATEUR",
136 fr = 'Systeme de coordonnees geographiques dans lequel est construit le modele numerique.',
137 ang = 'Geographic coordinates system in which the numerical model is built.Indicate the corresponding zone with the keyword ',
139 b_geo_system = BLOC(condition = "Geographic_System in ('WGS84 LONGITUDE/LATITUDE EN DEGRES REELS','WGS84 NORD UTM','WGS84 SUD UTM','MERCATOR')",
140 Spatial_Projection=SIMP(statut='o',typ='TXM',into=["CARTESIAN, NOT GEOREFERENCED","MERCATOR","LATITUDE LONGITUDE"]),
141 ang = 'Option 2 or 3 mandatory for spherical coordinates Option 3: latitude and longitude in radians!',
142 b_lat = BLOC(condition = "Spatial_Projection == 'LATITUDE LONGITUDE' ",
143 Latitude_of_origin=SIMP(statut='o',typ='R',val_min=-90,val_max=90,fr="en radians", ang="in radians"),
144 Longitude_of_origin=SIMP(statut='o',typ='R',fr="en radians", ang="in radians"),
147 Zone_number_in_Geographic_System=SIMP(statut='f',typ='I',into=[-1,0,1,2,3,4,22,30]),
151 INITIAL_STATE=PROC(nom="INITIAL_STATE",op=None,
152 Initial_Conditions=SIMP(statut='o',typ='TXM',into=['ZERO ELEVATION', 'CONSTANT ELEVATION','ZERO DEPTH','CONSTANT DEPTH','SPECIAL','TPXO SATELLITE ALTIMETRY'],defaut='ZERO ELEVATION',
153 fr = "Permet de definir les conditions initiales sur les hauteurs d'eau. Les valeurs possibles sont : - COTE NULLE. Initialise la cote de surface libre a 0. Les hauteurs d'eau initiales sont alors retrouvees en faisant la difference entre les cotes de surface libre et du fond. - COTE CONSTANTE . Initialise la cote de surface libre a la valeur donnee par le mot-cle COTE INITIALE. Les hauteurs d'eau initiales sont calculees comme precedemment.- HAUTEUR NULLE .Initialise les hauteurs d'eau a 0. - HAUTEUR CONSTANTE. Initialise les hauteurs d'eau a la valeur donnee par le mot-cle HAUTEUR INITIALE. - PARTICULIERES. Les conditions initiales sur la hauteur d'eau doivent etre precisees dans le sous-programme CONDIN. - ALTIMETRIE SATELLITE TPXO. Les conditions initiales sur la hauteur d'eau et les vitesses sont etablies sur la base des donnees. satellite TPXO dont les 8 premiers constistuents ont ete extrait et sauves dans le fichier BASE DE DONNEES DE MAREE." ,
154 ang = 'Makes it possible to define the initial conditions with the water depth. The possible values are as follows: - ZERO ELEVATION-. Initializes the free surface elevation to 0.The initial water depths are then found by computing the difference between the free surface and the bottom. - CONSTANT ELEVATION-. Initializes the water elevation to the value given by the keyword -INITIAL ELEVATION-. The initial water depths are computed as in the previous case. - ZERO DEPTH-. Initializes the water depths to 0. - CONSTANT DEPTH-. Initializes the water depths to the value givenby the key-word -INITIAL DEPTH-. - SPECIAL-. The initial conditions with the water depth should be stated in the CONDIN subroutine. - TPXO SATELITE ALTIMETRY. The initial conditions on the free surface andvelocities are established from the TPXO satellite program data, the harmonicconstituents of which are stored in the TIDE DATA BASE file.', ),
156 b_initial_elevation = BLOC (condition = "Initial_Conditions == 'CONSTANT ELEVATION'",
157 Initial_Elevation = SIMP(statut='o',typ='R' ),
159 b_initial_depth = BLOC (condition = "Initial_Conditions == 'CONSTANT DEPTH'",
160 Initial_Depth = SIMP(statut='o',typ='R' ),
162 b_special = BLOC (condition = "Initial_Conditions == 'SPECIAL'",
163 special = SIMP(statut='o',typ='TXM',defaut="The initial conditions with the water depth should be stated in the CONDIN subroutine"),
165 b_initial_TPXO = BLOC (condition = "Initial_Conditions == 'TPXO SATELLITE ALTIMETRY'",
166 Base_Ascii_De_Donnees_De_Maree = SIMP( statut='o', typ = ('Fichier', 'All Files (*)',), ),
167 fr = 'Base de donnees de constantes harmoniques tirees du fichier du modele de maree',
168 ang = 'Tide data base of harmonic constituents extracted from the tidal model file',
171 Boundary_Conditions=FACT(statut='f',
172 fr = 'On donne un ensemble de conditions par frontiere liquide',
173 ang = 'One condition set per liquid boundary is given',
174 # Dans l ideal il faut aller regarder selon les groupes dans le fichier med
175 # en sortie il faut aller chercher le .cli qui va bien
176 #Liquid_Boundaries=FACT(statut='f',max='**',
177 # Options=SIMP(statut='f',typ='I',into=['classical boundary conditions','Thompson method based on characteristics'])
178 # Prescribed_Flowrates=SIMP(statut='f',typ='R'),
179 # Prescribed_Elevations=SIMP(statut='f',typ='R'),
180 # Prescribed_Velocity=SIMP(statut='f',typ='R'),
182 # Il va falloir une "traduction dans le langage du dico"
183 # Il faut seulement l un des 3
184 Liquid_Boundaries=FACT(statut='f',max='**',
186 Options=SIMP(statut='f',typ='I',into=['classical boundary conditions','Thompson method based on characteristics']),
188 Type_Condition=SIMP(statut='o',typ='TXM',into=['Flowrates','Elevations','Velocity'],),
189 b_Flowrates = BLOC (condition = "Type_Condition == 'Flowrates'",
190 Prescribed_Flowrates=SIMP(statut='o',typ='R'),
192 b_Elevations = BLOC (condition = "Type_Condition == 'Elevations'",
193 Prescribed_Elevations=SIMP(statut='o',typ='R'),
195 b_Velocity = BLOC (condition = "Type_Condition == 'Velocity'",
196 Prescribed_Velocity=SIMP(statut='o',typ='R'),
199 Stage_Discharge_Curves=SIMP(statut='f',typ='I',into=[0,1,2]),
200 Stage_Discharge_Curves_File = SIMP( statut='f', typ = ('Fichier', 'All Files (*)',),),
201 Treatment_of_Fluxes_at_the_Boundaries = SIMP( statut='f',typ='I',into=[1,2],sug=1),
202 Option_for_tidal_Boundary_Conditions = SIMP( statut='f',typ='I',into=[1,2],sug=1),
206 NUMERICAL_PARAMETERS=PROC(nom="NUMERICAL_PARAMETERS",op=None,
207 Solver=FACT(statut='o',
208 Equations=SIMP(statut='o',typ='TXM',into=['SAINT-VENANT EF','SAINT-VENANT VF','BOUSSINESQ'],sug='SAINT-VENANT EF'),
209 Solver=SIMP(statut='o',typ='I',into=[1,2,3,4,6,7,8]),
210 Solver_Accuracy=SIMP(statut='o',typ='R'),
211 Maximum_Number_of_Iterations=SIMP(statut='o',typ='I'),
213 Time=FACT(statut='f',
214 regles=(AU_MOINS_UN('Number_of_time_Steps','Variable_Time_Step'),
215 PRESENT_PRESENT('Time_Step','Duration',),),
216 Number_of_Time_Steps=SIMP(statut='f',typ='I'),
217 Time_Step=SIMP(statut='f',typ='R'),
218 Duration=SIMP(statut='f',typ='R'),
219 Variable_Time_Step=SIMP(statut='f',typ=bool),
221 Linearity=FACT(statut='f',
222 Treatment_of_Fluxes_at_the_Boundaries =SIMP( statut='f',typ='I',into=[1,2],sug=1),
223 Continuity_Correction =SIMP(typ=bool, statut='f'),
224 Number_of_Sub_Iterations=SIMP(statut='f',typ='I'),
226 Precondionning=FACT(statut='f',
227 Preconditionning=SIMP(statut='f',typ='I',into=[0,2,3,7,11,14,21],sug=2),
228 C_U_Preconditionning =SIMP(typ=bool, statut='f',),
229 Matrix_Vector_Product =SIMP(statut='f',typ='I',into=[1,2]),
230 Matrix_Storage =SIMP(statut='f',typ='I',into=[1,3]),
231 Mass_Lumping_on_H =SIMP(statut='f',typ='R',sug=0),
232 Mass_Lumping_on_Velocity =SIMP(statut='f',typ='R',sug=0),
234 Advection_Propagation=FACT(statut='f',
235 Type_of_Advection=SIMP(statut='f',typ='I',min=4,max=4,into=[1,2,3,4,5,6,7,13,14],defaut=(1,5,1,1),),
236 Advection_of_U_and_V=SIMP(statut='f',typ=bool),
237 Advection_of_H=SIMP(statut='f',typ=bool),
238 Advection_of_Tracers=SIMP(statut='f',typ=bool),
239 Advection_of_K_and_Epsilon=SIMP(statut='f',typ=bool),
241 b_upwind =BLOC(condition = "2 in Type_of_Advection",
242 Upwind_Coefficients=SIMP(statut='o',typ='R',min=4,max=4,)
244 Linearized_Propoagation=SIMP(statut='f',typ=bool,sug=False),
245 Mean_Depth_For_Linearity=SIMP(statut='f',typ='R',sug=0.0),
247 Discretisation_Implicitation=FACT(statut='f',
248 Discretisation_in_Space=SIMP(statut='f',typ='I',min=4,max=4,into=[11,12,13],defaut=(11,11,11),),
249 Implicitation_for_Diffusion_of_velocity=SIMP(statut='f',typ='R',sug=0),
250 Implicitation_for_Depth=SIMP(statut='f',typ='R',sug=0.55),
251 Implicitation_for_Velocity=SIMP(statut='f',typ='R',sug=0.55),
252 Free_Surface_Gradient_Compatibility=SIMP(statut='f',typ='R',sug=1.),
254 Initial_Guess_for_H=SIMP(statut='f',typ='TXM',into=['zero','previous','extrapolation'],defaut='previous',),
255 Initial_Guess_for_U=SIMP(statut='f',typ='TXM',into=['zero','previous','extrapolation'],defaut='previous',),
258 PHYSICAL_PARAMETERS=PROC(nom="PHYSICAL_PARAMETERS",op=None,
259 Atmosphere=FACT(statut='f',
260 Wind=SIMP(statut='f',typ=bool,sug=False),
261 b_Wind =BLOC(condition = "Wind=='True'",
262 regles=( PRESENT_PRESENT('Wind_Velocity_along_X','Wind_Velocity_along_Y', ),),
263 Coefficient_of_Wind_Influence=SIMP(statut='f',typ='R',sug=0,),
264 Wind_Velocity_along_X=SIMP(statut='f',typ='R',sug=0,),
265 Wind_Velocity_along_Y=SIMP(statut='f',typ='R',sug=0,),
266 Threashold_Depth_for_Wind=SIMP(statut='f',typ='R',sug=0,),
267 Air_Pressure=SIMP(statut='f',typ=bool,sug=False),
269 Rain_or_Evaporation=SIMP(statut='f',typ=bool,sug=False),
270 b_Rain =BLOC(condition = "Rain_or_Evaporation=='True'",
271 Rain_or_Evaporation_in_mm_perday=SIMP(statut='f',typ='I',sug=0),
274 Tide_Generating_Force=SIMP(statut='f',typ=bool,sug=False),
275 b_Tide =BLOC(condition = "Tide_Generating_Force=='True'",
276 Tidal_Data_Base=SIMP(statut='f',typ='I',into=[-1,1,2,3,4]),
277 Coefficient_To_Calibrate_Tidal_Range=SIMP(statut='f',typ='R',sug=1.),
278 Coefficient_To_Calibrate_Tidal_Velocity=SIMP(statut='f',typ='R',sug=999999),
279 Coefficient_To_Calibrate_Sea_Level=SIMP(statut='f',typ='R',sug=0.),
280 Binary_Database_1_for_Tide = SIMP( statut='f', typ = ('Fichier', '(All Files (*)',),),
281 Binary_Database_2_for_Tide = SIMP( statut='f', typ = ('Fichier', '(All Files (*)',),),
283 Wave_Driver_Currents=SIMP(statut='f',typ=bool,sug=False),
284 b_Wave =BLOC(condition = "Wave_Driver_Currents=='True'",
285 Record_Number_in_Wave_File=SIMP(statut='f',typ='I',sug=1),
289 POST_PROCESSING=PROC(nom="POST_PROCESSING",op=None,
290 Graphic_Printouts=FACT(statut='f',
291 Graphic_Printout_Period=SIMP(statut='o', typ='I',defaut=1),
292 Number_of_First_TimeStep_For_Graphic_Printouts=SIMP(statut='o', typ='I',defaut=1),
293 Variables_For_Graphic_Printouts=SIMP(statut='f',max="**", typ='TXM'),
296 Listing__Printouts=FACT(statut='f',
297 Graphic_Printout_Period=SIMP(statut='o', typ='I',defaut=1),
298 Number_of_First_TimeStep_For_Graphic_Printouts=SIMP(statut='o', typ='I',defaut=1),
299 Variables_to_be_printed=SIMP(statut='f',max="**", typ='TXM'),