Files
file	addfld.f90
	Add additional fields based on user options.

file	alaste.f90

file	albase.f90

file	alstru.f90

file	altycl.f90
	Boundary condition code for the ALE module.

file	b_h_to_t.f90

file	b_t_to_h.f90
	Convert enthalpy to temperature at boundary.

file	c_h_to_t.f90
	Convert enthalpy to temperature at cells.

file	calhyd.f90
	Poisson equation resolution for hydrostatic pressure: $\divs ( \grad P ) = \divs ( f )$ .

file	caltri.f90
	Main time loop.

file	catsma.f90
	Implicit and explicit sources terms from sources mass computation.

file	catsmt.f90
	Compute explicit and implicit source terms coming from mass source.

file	catsmv.f90
	Compute explicit and implicit source terms coming from mass source.

file	cavitation.f90

file	cdomod.f90
	Store the mode of activation of CDO-HHO schemes.

file	clpsca.f90
	This subroutine clips the values of a given scalar or variance.

file	clptrg.f90
	Boundary conditions for rough walls (icodcl = 6).

file	clptur.f90
	Boundary conditions for smooth walls (icodcl = 5).

file	clsyvt.f90
	Symmetry boundary conditions for vectors and tensors.

file	condensation_source_terms.f90
	Explicit sources terms from sources condensation computation.

file	condli.f90
	Translation of the boundary conditions given by cs_user_boundary_conditions in a form that fits to the solver.

file	copain_model.f90
	The COPAIN correlations used to approximate the condensation source term and the thermal exchange coefficient to impose at the wall where condensation occurs.

file	cou1di.f90

file	cou1do.f90

file	coupbi.f90

file	coupbo.f90

file	covofi.f90
	This subroutine performs the solving the convection/diffusion equation (with eventually source terms and/or drift) for a scalar quantity over a time step.

file	covofv.f90
	This subroutine performs the solving the convection/diffusion equation (with eventually source terms and/or drift) for a vectorial quantity over a time step.

file	cplsat.f90
	Module for code/code coupling.

file	cptssy.f90

file	cpvosy.f90

file	cs_1d_wall_thermal.c

file	cs_1d_wall_thermal.h [code]

file	cs_1d_wall_thermal_check.c

file	cs_1d_wall_thermal_check.h [code]

file	cs_ale.c

file	cs_ale.h [code]

file	cs_all_to_all.c

file	cs_all_to_all.h [code]

file	cs_array_reduce.c

file	cs_array_reduce.h [code]

file	cs_assert.h [code]

file	cs_ast_coupling.c

file	cs_ast_coupling.h [code]

file	cs_base.c

file	cs_base.h [code]

file	cs_base_fortran.c

file	cs_base_fortran.h [code]

file	cs_base_headers.h [code]

file	cs_block_dist.c

file	cs_block_dist.h [code]

file	cs_block_to_part.c

file	cs_block_to_part.h [code]

file	cs_boundary.c
	Handle the "physical" boundary conditions attached to a computational domain.

file	cs_boundary.h [code]

file	cs_boundary_conditions.c

file	cs_boundary_conditions.h [code]

file	cs_boundary_zone.c

file	cs_boundary_zone.h [code]

file	cs_c_bindings.f90

file	cs_calcium.c

file	cs_calcium.h [code]

file	cs_control.c

file	cs_control.h [code]

file	cs_coolprop.cxx

file	cs_coolprop.hxx [code]

file	cs_coupling.c

file	cs_coupling.h [code]

file	cs_crystal_router.c

file	cs_crystal_router.h [code]

file	cs_defs.c

file	cs_defs.h [code]

file	cs_eos.cxx

file	cs_eos.hxx [code]

file	cs_equation_iterative_solve.c
	This file gathers functions that solve advection diffusion equations with source terms for one time step for a scalar, vector or tensor variable.

file	cs_equation_iterative_solve.h [code]

file	cs_ext_neighborhood.c

file	cs_ext_neighborhood.h [code]

file	cs_f_interfaces.f90

file	cs_fan.c

file	cs_fan.h [code]

file	cs_field.c

file	cs_field.h [code]

file	cs_field_default.c

file	cs_field_default.h [code]

file	cs_field_operator.c

file	cs_field_operator.h [code]

file	cs_field_pointer.c

file	cs_field_pointer.h [code]

file	cs_file.c

file	cs_file.h [code]

file	cs_flag_check.c

file	cs_flag_check.h [code]

file	cs_fp_exception.c

file	cs_fp_exception.h [code]

file	cs_gas_mix.c

file	cs_gas_mix.h [code]

file	cs_gas_mix_initialization.f90
	Initialization of calculation variables for gas mixture modelling in presence of the steam gas or another gas used as variable deduced and not solved.

file	cs_gas_mix_physical_properties.f90
	This subroutine fills physical properties which are variable in time for the gas mixtures modelling with or without steam inside the fluid domain. In presence of steam, this one is deduced from the noncondensable gases transported as scalars (by means of the mass fraction of each species).

file	cs_halo.c

file	cs_halo.h [code]

file	cs_halo_perio.c

file	cs_halo_perio.h [code]

file	cs_head_losses.c

file	cs_head_losses.h [code]

file	cs_headers.h [code]

file	cs_interface.c

file	cs_interface.h [code]

file	cs_internal_coupling.c

file	cs_internal_coupling.h [code]

file	cs_interpolate.c

file	cs_interpolate.h [code]

file	cs_io.c

file	cs_io.h [code]

file	cs_log.c

file	cs_log.h [code]

file	cs_log_iteration.c
	Log field and other array statistics at relevant time steps.

file	cs_log_iteration.h [code]

file	cs_log_setup.c
	Setup info at the end of the setup stage.

file	cs_log_setup.h [code]

file	cs_map.c

file	cs_map.h [code]

file	cs_math.c

file	cs_math.h [code]

file	cs_measures_util.c

file	cs_measures_util.h [code]

file	cs_medcoupling_remapper.cxx

file	cs_medcoupling_remapper.hxx [code]

file	cs_medcoupling_utils.cxx

file	cs_medcoupling_utils.hxx [code]

file	cs_mesh_tagmr.f90
	The subroutine is used to generate the 1-D mesh and initialize the temperature field of the thermal model coupled with condensation model.

file	cs_metal_structures_tag.f90
	The 0-D thermal model to compute the temperature at the metal structures wall and pass to the volume condensation modelling to be able to model the metal structures effects. This metal structures temperature computed is passed to the volume condensation model to estimate the heat flux at the metall structures wall where the condensation occurs.

file	cs_notebook.c

file	cs_notebook.h [code]

file	cs_numbering.c

file	cs_numbering.h [code]

file	cs_nz_condensation.f90

file	cs_nz_tagmr.f90

file	cs_opts.c

file	cs_opts.h [code]

file	cs_order.c

file	cs_order.h [code]

file	cs_parall.c

file	cs_parall.h [code]

file	cs_paramedmem_coupling.cxx

file	cs_paramedmem_coupling.hxx [code]

file	cs_paramedmem_remapper.cxx

file	cs_paramedmem_remapper.hxx [code]

file	cs_parameters.c

file	cs_parameters.h [code]

file	cs_parameters_check.c

file	cs_parameters_check.h [code]

file	cs_part_to_block.c

file	cs_part_to_block.h [code]

file	cs_physical_constants.c

file	cs_physical_constants.h [code]

file	cs_physical_properties.c

file	cs_physical_properties.h [code]

file	cs_post.c
	Post-processing management.

file	cs_post.h [code]

file	cs_post_default.c

file	cs_post_default.h [code]

file	cs_post_util.c

file	cs_post_util.h [code]

file	cs_preprocess.c

file	cs_preprocess.h [code]

file	cs_preprocessor_data.c

file	cs_preprocessor_data.h [code]

file	cs_probe.c
	Probes and profiles management.

file	cs_probe.h [code]

file	cs_prototypes.h [code]

file	cs_random.c

file	cs_random.h [code]

file	cs_range_set.c
	Operations related to handling of an owning rank for distributed entities.

file	cs_range_set.h [code]

file	cs_rank_neighbors.c

file	cs_rank_neighbors.h [code]

file	cs_renumber.c

file	cs_renumber.h [code]

file	cs_resource.c
	Resource allocation management (available time).

file	cs_resource.h [code]

file	cs_restart.c

file	cs_restart.h [code]

file	cs_restart_default.c

file	cs_restart_default.h [code]

file	cs_restart_map.c

file	cs_restart_map.h [code]

file	cs_rotation.c

file	cs_rotation.h [code]

file	cs_sat_coupling.c

file	cs_sat_coupling.h [code]

file	cs_search.c

file	cs_search.h [code]

file	cs_selector.c

file	cs_selector.h [code]

file	cs_selector_f2c.f90

file	cs_sort.c

file	cs_sort.h [code]

file	cs_sort_partition.c

file	cs_sort_partition.h [code]

file	cs_stokes_model.c

file	cs_stokes_model.h [code]

file	cs_syr4_coupling.c

file	cs_syr4_coupling.h [code]

file	cs_syr_coupling.c

file	cs_syr_coupling.h [code]

file	cs_system_info.c

file	cs_system_info.h [code]

file	cs_tagmr.f90

file	cs_tagmri.f90
	The 1D thermal model to compute the temperature to impose at the cold wall. This one is used by the COPAIN model to estimate the heat flux at the wall where the condensation occurs.

file	cs_tagmro.f90
	The 1D thermal model to compute the temperature to impose at the cold wall. This one is used by the COPAIN model to estimate the heat flux at the wall where the condensation occurs.

file	cs_tagms.f90

file	cs_thermal_model.c

file	cs_thermal_model.h [code]

file	cs_time_moment.c
	Temporal moments management.

file	cs_time_moment.h [code]

file	cs_time_plot.c

file	cs_time_plot.h [code]

file	cs_time_step.c

file	cs_time_step.h [code]

file	cs_timer.c

file	cs_timer.h [code]

file	cs_timer_stats.c

file	cs_timer_stats.h [code]

file	cs_tree.c

file	cs_tree.h [code]

file	cs_turbomachinery.c

file	cs_turbomachinery.h [code]

file	cs_vof.c

file	cs_vof.h [code]

file	cs_volume_zone.c

file	cs_volume_zone.h [code]

file	cs_wall_functions.c

file	cs_wall_functions.h [code]

file	cs_zone.h [code]

file	csc2cl.f90
	Translation of the "itypfb(, ) = icscpl" condition.

file	csc2ts.f90
	Code-code coupling with source terms.

file	csccel.f90
	Exchange of coupling variables between to times of Code_Saturne thanks to boundary faces.

file	cscfbr.f90
	Exchange of variables for coupling two Code_Saturne intances with boundary faces.

file	cscini.f90
	Initialization of main variables for code_saturne / code_saturne coupling.

file	csclli.f90

file	cscloc.f90
	Coupling interfaces localization (with FVM).

file	cscpce.f90
	Preparation of sending velocity variables for coupling between two instances of Code_Saturne via boundary faces. Received indformation will be transformed into boundary condition in subroutine csc2cl.

file	cscpfb.f90
	Preparation of sending variables for coupling between two instances of Code_Saturne via boundary faces. Received indformation will be transformed into boundary condition in subroutine csc2cl.

file	csinit.f90

file	csopli.f90

file	csprnt.f90

file	cstnum.f90
	Module for numerical constants.

file	cstphy.f90
	Module for physical constants.

file	diffst.f90

file	dimens.f90
	Module for dimensions.

file	distpr.f90
	Compute distance to wall by solving a 3d diffusion equation. Solve.

file	distpr2.f90
	Compute distance to wall by a brute force geometric approach (serial only)

file	distyp.f90
	This subroutine computes the dimensionless distance to the wall solving a transport equation.

file	driflu.f90
	Compute the modified convective flux for scalars with a drift.

file	dttvar.f90
	Compute the local time step and add the Courant and Fourier number to.

file	dvvpst.f90
	Standard output of variables on post-processing meshes (called after cs_user_extra_operations).

file	ecrava.f90

file	ecrlis.f90
	This subroutine writes log information on equation convergence.

file	entsor.f90
	Module for input/output.

file	field.f90

file	field_operator.f90

file	findpt.f90
	This subroutine looks for the nearest element to the position (xx, yy, zz) among the element of xyzcen array.

file	fldini.f90

file	fldprp.f90
	Properties definition initialization, according to calculation type selected by the user.

file	fldtri.f90

file	fldvar.f90
	Variables definition initialization, according to calculation type selected by the user.

file	haltyp.f90

file	idrbla.f90

file	ihmpre.f90
	Module for GUI parameter file flag We could avoid this module by querying a C structure.

file	impini.f90

file	iniini.f90
	Commons default initialization before handing over the user.

file	initi1.f90
	Commons initialization.

file	initi2.f90
	End of commons initialization.

file	iniusi.f90

file	iniva0.f90
	Computed variable initialization. The time step, the indicator of wall distance computation are also initialized just before reading a restart file or use the user initializations.

file	inivar.f90
	Initialization of calculation variables, time step and table that stores distance to the wall by the user (after reading a restart file).

file	iprbla.f90

file	lecamo.f90
	Reading of restart file.

file	lecamp.f90
	Reading of main restart file.

file	lecamx.f90
	Reading of auxiliary restart file.

file	majgeo.f90

file	mesh.f90
	Module for mesh-related arrays.

file	metal_structures_copain_model.f90
	The COPAIN modelling to estimate the heat and mass transfer associated to the steam condensation phenomena at each cell corresponding to the metal structures volume identified by geometric criteria.

file	mmtycl.f90

file	modini.f90
	Modify calculation parameters after user changes (module variables)

file	navstv.f90
	Solving of NS equations for incompressible or slightly compressible flows for one time step. Both convection-diffusion and continuity steps are performed. The velocity components are solved together in once.

file	newmrk.f90

file	numvar.f90
	Module for variable numbering.

file	optcal.f90

file	parall.f90
	Module for basic MPI and OpenMP parallelism-related values.

file	paramx.f90
	Module for definition of general parameters.

file	period.f90
	Module for periodicity flags.

file	phyvar.f90
	This subroutine fills physical properties which are variable in time (mainly the eddy viscosity).

file	pointe.f90
	Module for pointer variables.

file	post.f90

file	post_util.f90

file	precli.f90
	Preparation of boudary conditions determination Boundary faces of precedent step are used. Except at first time step, where arrays itypfb and itrifb are undefined.

file	predfl.f90
	Update the convective mass flux before the Navier Stokes equations (prediction and correction steps).

file	predvv.f90
	This subroutine performs the velocity prediction step of the Navier Stokes equations for incompressible or slightly compressible flows for the coupled velocity components solver.

file	prehyd.f90
	Compute an "a priori" hydrostatic pressure and its gradient associated before the Navier Stokes equations (prediction and correction steps navstv.f90).

file	pthrbm.f90
	Update the density $\rho^{n+1}$ with the $\rho^{n-\frac{1}{2}}$ density with the state law and a thermodynamic pressure $p_{ther}^{n+1}$ estimated from the integral over the total fluid domain of the mass conservation equation.

file	ptrglo.f90

file	resopv.f90
	This subroutine performs the pressure correction step of the Navier Stokes equations for incompressible or slightly compressible flows for the coupled velocity components solver.

file	resvoi.f90
	Solving the void fraction $\alpha$ for the Volume of Fluid method (and hence for cavitating flows).

file	rotation.f90
	Module for rotating zones (rotors)

file	scalai.f90
	Resolution of source term convection diffusion equations for scalars in a time step.

file	schtmp.f90
	Management of the mass flux, the viscosity, the density, the specific heat and the tsnsa array in case of a theta-scheme.

file	stdtcl.f90

file	strdep.f90

file	strhis.f90

file	strini.f90

file	strpre.f90

file	tdesi1.f90

file	tridim.f90
	Resolution of incompressible Navier Stokes and scalar transport equations for a time step.

file	tspdcv.f90
	This subroutine computes the explicit contribution of headlosses terms.

file	turbomachinery.f90
	Module for turbomachinery computations.

file	typecl.f90
	Handle boundary condition type code (itypfb).

file	varpos.f90
	Variables location initialization, according to calculation type selected by the user.

file	vericl.f90
	Check boundary condition code.

file	verini.f90

file	verlon.f90

file	visecv.f90
	Computes the secondary viscosity contribution $\kappa -\dfrac{2}{3} \mu$ in order to compute:

file	vof.f90

Files