This paper describes a new software package for performing arithmetic with an arbitrarily high level of numeric precision. It is based on the earlier MPFUN package \cite mpf90, enhanced with special IEEE floating-point numerical techniques and several new functions. This package is written in C++ code for high performance and broad portability and includes both C++ and Fortran-90 translation modules, so that conventional C++ and Fortran-90 programs can utilize the package with only very minor changes. This paper includes a survey of some of the interesting applications of this package and its predecessors
In recent years approximate computing has been extensively explored as a paradigm to design hardware...
Abstract: In basic computational physics classes, students often raise the question of how to comput...
International audienceThis paper presents the architecture of an infinite precision arithmetic pipel...
This paper describes a new software package for performing arithmetic with an arbitrarily high level...
Computations with higher than the IEEE 754 standard double-precision (about 16 significant digits) a...
International audienceThis paper presents a multiple-precision binary floating-point library, writte...
The authors have implemented three numerical quadrature schemes, using the new Arbitrary Precision (...
At the present time, IEEE 64-bit floating-point arithmetic is sufficiently accurate for most scienti...
The R package Rmpfr allows to use arbitrarily precise numbers instead of R’s double precision number...
Low-precision floating-point arithmetic can be simulated via software by executing each arithmetic o...
Les unités de calcul à virgule flottante (FP) prennent en charge un sous-ensemble de formats définis p...
Exact computer arithmetic has a variety of uses including, but not limited to, the robust implementa...
At the present time, IEEE 64-bit floating-point arithmetic is sufficiently accurate for most scient...
International audienceThe popularity and community-driven development model of RISCV have opened man...
One can simulate low-precision floating-point arithmetic via software by executing each arithmetic o...
In recent years approximate computing has been extensively explored as a paradigm to design hardware...
Abstract: In basic computational physics classes, students often raise the question of how to comput...
International audienceThis paper presents the architecture of an infinite precision arithmetic pipel...
This paper describes a new software package for performing arithmetic with an arbitrarily high level...
Computations with higher than the IEEE 754 standard double-precision (about 16 significant digits) a...
International audienceThis paper presents a multiple-precision binary floating-point library, writte...
The authors have implemented three numerical quadrature schemes, using the new Arbitrary Precision (...
At the present time, IEEE 64-bit floating-point arithmetic is sufficiently accurate for most scienti...
The R package Rmpfr allows to use arbitrarily precise numbers instead of R’s double precision number...
Low-precision floating-point arithmetic can be simulated via software by executing each arithmetic o...
Les unités de calcul à virgule flottante (FP) prennent en charge un sous-ensemble de formats définis p...
Exact computer arithmetic has a variety of uses including, but not limited to, the robust implementa...
At the present time, IEEE 64-bit floating-point arithmetic is sufficiently accurate for most scient...
International audienceThe popularity and community-driven development model of RISCV have opened man...
One can simulate low-precision floating-point arithmetic via software by executing each arithmetic o...
In recent years approximate computing has been extensively explored as a paradigm to design hardware...
Abstract: In basic computational physics classes, students often raise the question of how to comput...
International audienceThis paper presents the architecture of an infinite precision arithmetic pipel...