Source: code-saturne Section: science Priority: optional Maintainer: Debian Science Team Uploaders: Gilles Filippini Build-Depends: debhelper (>= 11), dh-exec, dh-python, python3-pyqt5, pyqt5-dev-tools, gfortran, autoconf, # To build from upstream SVN source bison, flex, # To help the configure detection on cs lib zlib1g-dev, libhdf5-mpi-dev (>= 1.10.0~), libcgns-dev (>= 3.3.0~), mpi-default-dev, libmedc-dev, libblas-dev | libatlas-dev, libopenmpi-dev, python3, libscotch-dev, tango-icon-theme Build-Depends-Indep: doxygen, graphviz, fig2ps, texlive-latex-recommended, texlive-fonts-recommended, texlive-latex-extra Standards-Version: 4.3.0 Homepage: http://www.code-saturne.org/ Vcs-Git: https://salsa.debian.org/science-team/code-saturne.git Vcs-Browser: https://salsa.debian.org/science-team/code-saturne Package: code-saturne Priority: optional Architecture: any Depends: ${shlibs:Depends}, ${misc:Depends}, code-saturne-bin (= ${binary:Version}), code-saturne-data (= ${source:Version}), code-saturne-include (= ${binary:Version}), python3-pyqt5 Recommends: bash-completion, paraview, pdf-viewer, code-saturne-doc Suggests: syrthes Description: General purpose Computational Fluid Dynamics (CFD) software The basic capabilities of Code_Saturne enable the handling of either incompressible or expandable flows with or without heat transfer and turbulence. Dedicated modules are available for specific physics such as radiative heat transfer, combustion (gas, coal, heavy fuel oil, ...), magneto-hydrodynamics, compressible flows, two-phase flows (Euler-Lagrange approach with two-way coupling), extensions to specific applications (e.g. Mercure_Saturne for atmospheric environment). . It runs in parallel with MPI on distributed memory machines. Developed since 1997 at EDF R&D, it is based on a co-located Finite Volume approach that accepts meshes with any type of cell (tetrahedral, hexahedral, prismatic, pyramidal, polyhedral...) and any type of grid structure (unstructured, block structured, hybrid, conforming or with hanging nodes, ...). Package: code-saturne-bin Priority: optional Architecture: any Depends: ${shlibs:Depends}, ${misc:Depends}, python3, libxml2-dev, libblas-dev Recommends: code-saturne Description: General purpose Computational Fluid Dynamics (CFD) software - binaries The basic capabilities of Code_Saturne enable the handling of either incompressible or expandable flows with or without heat transfer and turbulence. Dedicated modules are available for specific physics such as radiative heat transfer, combustion (gas, coal, heavy fuel oil, ...), magneto-hydrodynamics, compressible flows, two-phase flows (Euler-Lagrange approach with two-way coupling), extensions to specific applications (e.g. Mercure_Saturne for atmospheric environment). . It runs in parallel with MPI on distributed memory machines. Developed since 1997 at EDF R&D, it is based on a co-located Finite Volume approach that accepts meshes with any type of cell (tetrahedral, hexahedral, prismatic, pyramidal, polyhedral...) and any type of grid structure (unstructured, block structured, hybrid, conforming or with hanging nodes, ...). . This package contains the binary files. Package: code-saturne-data Priority: optional Architecture: all Depends: ${shlibs:Depends}, ${misc:Depends}, ${python3:Depends} Recommends: code-saturne Description: General purpose Computational Fluid Dynamics (CFD) software - data The basic capabilities of Code_Saturne enable the handling of either incompressible or expandable flows with or without heat transfer and turbulence. Dedicated modules are available for specific physics such as radiative heat transfer, combustion (gas, coal, heavy fuel oil, ...), magneto-hydrodynamics, compressible flows, two-phase flows (Euler-Lagrange approach with two-way coupling), extensions to specific applications (e.g. Mercure_Saturne for atmospheric environment). . It runs in parallel with MPI on distributed memory machines. Developed since 1997 at EDF R&D, it is based on a co-located Finite Volume approach that accepts meshes with any type of cell (tetrahedral, hexahedral, prismatic, pyramidal, polyhedral...) and any type of grid structure (unstructured, block structured, hybrid, conforming or with hanging nodes, ...). . This package contains the data. Package: code-saturne-include Priority: optional Architecture: any Depends: ${shlibs:Depends}, ${misc:Depends}, ${python3:Depends}, libcgns-dev, libmedc-dev, libhdf5-dev, zlib1g-dev, mpi-default-dev, libxml2-dev Replaces: code-saturne-data (<< 3.3.2-3) Breaks: code-saturne-data (<< 3.3.2-3) Description: General purpose Computational Fluid Dynamics (CFD) software - includes The basic capabilities of Code_Saturne enable the handling of either incompressible or expandable flows with or without heat transfer and turbulence. Dedicated modules are available for specific physics such as radiative heat transfer, combustion (gas, coal, heavy fuel oil, ...), magneto-hydrodynamics, compressible flows, two-phase flows (Euler-Lagrange approach with two-way coupling), extensions to specific applications (e.g. Mercure_Saturne for atmospheric environment). . It runs in parallel with MPI on distributed memory machines. Developed since 1997 at EDF R&D, it is based on a co-located Finite Volume approach that accepts meshes with any type of cell (tetrahedral, hexahedral, prismatic, pyramidal, polyhedral...) and any type of grid structure (unstructured, block structured, hybrid, conforming or with hanging nodes, ...). . This package contains the include files. Package: code-saturne-doc Priority: optional Section: doc Architecture: all Depends: ${shlibs:Depends}, ${misc:Depends} Description: General purpose Computational Fluid Dynamics (CFD) software - Documentation The basic capabilities of Code_Saturne enable the handling of either incompressible or expandable flows with or without heat transfer and turbulence. Dedicated modules are available for specific physics such as radiative heat transfer, combustion (gas, coal, heavy fuel oil, ...), magneto-hydrodynamics, compressible flows, two-phase flows (Euler-Lagrange approach with two-way coupling), extensions to specific applications (e.g. Mercure_Saturne for atmospheric environment). . It runs in parallel with MPI on distributed memory machines. Developed since 1997 at EDF R&D, it is based on a co-located Finite Volume approach that accepts meshes with any type of cell (tetrahedral, hexahedral, prismatic, pyramidal, polyhedral...) and any type of grid structure (unstructured, block structured, hybrid, conforming or with hanging nodes, ...). . This package contains the documentation.