One of the key features of FEniCS is automated code generation for the general and efficient solution of finite element variational problems. This automated code generation relies on a form compiler for offline or just-in-time compilation of code for individual forms. Two different form compilers are available as part of FEniCS. This chapter describes the form compiler FFC. The other form compiler, SFC, is described in Chapter 15
This chapter addresses the conventional run-time quadrature approach for the numerical integration o...
We investigate the compilation of general multilinear variational forms over affines simplices and p...
We describe here a library aimed at automating the solution of partial differential equations using ...
One of the key features of FEniCS is automated code generation for the general and efficient 7018 so...
As a key step towards a complete automation of the finite element method, we present a new algorithm...
Much of the FEniCS software is devoted to the formulation of variational forms (UFL), the discretiza...
A central component of FEniCS is the UFC interface (Unified Form-assembly Code). UFC is an 8703 inte...
We examine the effect of using complexity-reducing relations [Kirby et al. 2006] to generate optimiz...
Differential equations are solved routinely by large computer programs, but the solution process is ...
In engineering, physical phenomena are often described mathematically by partial differential equati...
Efficient numerical solvers for partial differential equations are critical to vast fields of engine...
A form compiler takes a high-level description of the weak form of partial differential equations an...
We describe here a library aimed at automating the solution of partial differential equations using ...
How do we build maintainable, robust, and performance-portable scientific applications? This thesi...
We examine aspects of the computation of finite element matrices and vectors which are made possible...
This chapter addresses the conventional run-time quadrature approach for the numerical integration o...
We investigate the compilation of general multilinear variational forms over affines simplices and p...
We describe here a library aimed at automating the solution of partial differential equations using ...
One of the key features of FEniCS is automated code generation for the general and efficient 7018 so...
As a key step towards a complete automation of the finite element method, we present a new algorithm...
Much of the FEniCS software is devoted to the formulation of variational forms (UFL), the discretiza...
A central component of FEniCS is the UFC interface (Unified Form-assembly Code). UFC is an 8703 inte...
We examine the effect of using complexity-reducing relations [Kirby et al. 2006] to generate optimiz...
Differential equations are solved routinely by large computer programs, but the solution process is ...
In engineering, physical phenomena are often described mathematically by partial differential equati...
Efficient numerical solvers for partial differential equations are critical to vast fields of engine...
A form compiler takes a high-level description of the weak form of partial differential equations an...
We describe here a library aimed at automating the solution of partial differential equations using ...
How do we build maintainable, robust, and performance-portable scientific applications? This thesi...
We examine aspects of the computation of finite element matrices and vectors which are made possible...
This chapter addresses the conventional run-time quadrature approach for the numerical integration o...
We investigate the compilation of general multilinear variational forms over affines simplices and p...
We describe here a library aimed at automating the solution of partial differential equations using ...