FFC: the FEniCS form compiler. One of the key features of FEniCS is automated code generation for the general and efficient 7018 solution of finite element variational problems. This automated code generation relies on a form 7019 compiler for offline or just-in-time compilation of code for individual forms. Two different form 7020 compilers are available as part of FEniCS.

References in zbMATH (referenced in 30 articles )

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  1. Bin Zubair Syed, H.; Farquharson, C.; MacLachlan, S.: Block preconditioning techniques for geophysical electromagnetics (2020)
  2. Durastante, Fabio; Furci, Isabella: Spectral analysis of saddle-point matrices from optimization problems with elliptic PDE constraints (2020)
  3. Altmann, Robert; Heiland, J.: Continuous, semi-discrete, and fully discretised Navier-Stokes equations (2019)
  4. Farrell, P. E.; Hake, J. E.; Funke, S. W.; Rognes, M. E.: Automated adjoints of coupled PDE-ODE systems (2019)
  5. Winovich, Nick; Ramani, Karthik; Lin, Guang: ConvPDE-UQ: convolutional neural networks with quantified uncertainty for heterogeneous elliptic partial differential equations on varied domains (2019)
  6. Baumann, Manuel; Benner, Peter; Heiland, Jan: Space-time Galerkin POD with application in optimal control of semilinear partial differential equations (2018)
  7. Homolya, Miklós; Mitchell, Lawrence; Luporini, Fabio; Ham, David A.: TSFC: a structure-preserving form compiler (2018)
  8. Bauer, S.; Mohr, M.; Rüde, U.; Weismüller, J.; Wittmann, M.; Wohlmuth, B.: A two-scale approach for efficient on-the-fly operator assembly in massively parallel high performance multigrid codes (2017)
  9. Miklos Homolya, Lawrence Mitchell, Fabio Luporini, David A. Ham: TSFC: a structure-preserving form compiler (2017) arXiv
  10. Rathgeber, Florian; Ham, David A.; Mitchell, Lawrence; Lange, Michael; Luporini, Fabio; Mcrae, Andrew T. T.; Bercea, Gheorghe-Teodor; Markall, Graham R.; Kelly, Paul H. J.: Firedrake, automating the finite element method by composing abstractions (2017)
  11. De los Reyes, Juan Carlos; Herzog, Roland; Meyer, Christian: Optimal control of static elastoplasticity in primal formulation (2016)
  12. Langtangen, Hans Petter; Logg, Anders: Solving PDEs in Python. The FEniCS tutorial I (2016)
  13. McRae, A. T. T.; Bercea, G.-T.; Mitchell, L.; Ham, D. A.; Cotter, C. J.: Automated generation and symbolic manipulation of tensor product finite elements (2016)
  14. Mitchell, Lawrence; Müller, Eike Hermann: High level implementation of geometric multigrid solvers for finite element problems: applications in atmospheric modelling (2016)
  15. Queiruga, Alejandro Francisco; Zohdi, Tarek I.: Formulation and numerical analysis of a fully-coupled dynamically deforming electromagnetic wire (2016)
  16. Altmann, R.; Heiland, J.: Finite element decomposition and minimal extension for flow equations (2015)
  17. Benner, Peter; Heiland, Jan: LQG-balanced truncation low-order controller for stabilization of laminar flows (2015)
  18. Gmeiner, Björn; Rüde, Ulrich; Stengel, Holger; Waluga, Christian; Wohlmuth, Barbara: Performance and scalability of hierarchical hybrid multigrid solvers for Stokes systems (2015)
  19. Alnæs, Martin S.; Logg, Anders; Ølgaard, Kristian B.; Rognes, Marie E.; Wells, Garth N.: Unified form language: a domain-specific language for weak formulations of partial differential equations (2014)
  20. Fabio Luporini, Ana Lucia Varbanescu, Florian Rathgeber, Gheorghe-Teodor Bercea, J. Ramanujam, David A. Ham, Paul H.J. Kelly: COFFEE: an Optimizing Compiler for Finite Element Local Assembly (2014) arXiv

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