How to Install and Uninstall openspecfun-devel Package on openSUSE Leap
Last updated: December 23,2024
1. Install "openspecfun-devel" package
This tutorial shows how to install openspecfun-devel on openSUSE Leap
$
sudo zypper refresh
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$
sudo zypper install
openspecfun-devel
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2. Uninstall "openspecfun-devel" package
Here is a brief guide to show you how to uninstall openspecfun-devel on openSUSE Leap:
$
sudo zypper remove
openspecfun-devel
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3. Information about the openspecfun-devel package on openSUSE Leap
Information for package openspecfun-devel:
------------------------------------------
Repository : Main Repository
Name : openspecfun-devel
Version : 0.5.5-bp155.1.5
Arch : x86_64
Vendor : openSUSE
Installed Size : 5.2 KiB
Installed : No
Status : not installed
Source package : openspecfun-0.5.5-bp155.1.5.src
Upstream URL : https://github.com/JuliaMath/openspecfun
Summary : A collection of special mathematical functions
Description :
Openspecfun provides AMOS and Faddeeva. AMOS (from Netlib) is a portable package
for Bessel Functions of a Complex Argument and Nonnegative Order; it contains
subroutines for computing Bessel functions and Airy functions. Faddeeva allows
computing the various error functions of arbitrary complex arguments (Faddeeva
function, error function, complementary error function, scaled complementary
error function, imaginary error function, and Dawson function); given these,
one can also easily compute Voigt functions, Fresnel integrals, and similar
related functions as well.
------------------------------------------
Repository : Main Repository
Name : openspecfun-devel
Version : 0.5.5-bp155.1.5
Arch : x86_64
Vendor : openSUSE
Installed Size : 5.2 KiB
Installed : No
Status : not installed
Source package : openspecfun-0.5.5-bp155.1.5.src
Upstream URL : https://github.com/JuliaMath/openspecfun
Summary : A collection of special mathematical functions
Description :
Openspecfun provides AMOS and Faddeeva. AMOS (from Netlib) is a portable package
for Bessel Functions of a Complex Argument and Nonnegative Order; it contains
subroutines for computing Bessel functions and Airy functions. Faddeeva allows
computing the various error functions of arbitrary complex arguments (Faddeeva
function, error function, complementary error function, scaled complementary
error function, imaginary error function, and Dawson function); given these,
one can also easily compute Voigt functions, Fresnel integrals, and similar
related functions as well.