gf-complete 1.0.2+2017.04.10.git.ea75cdf-7 source package in Ubuntu
Changelog
gf-complete (1.0.2+2017.04.10.git.ea75cdf-7) unstable; urgency=medium * Fix long description (Closes: #999782). -- Thomas Goirand <email address hidden> Tue, 28 Dec 2021 19:21:55 +0100
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- Uploaded by:
- Debian OpenStack
- Uploaded to:
- Sid
- Original maintainer:
- Debian OpenStack
- Architectures:
- any
- Section:
- misc
- Urgency:
- Medium Urgency
See full publishing history Publishing
Series | Published | Component | Section |
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Downloads
File | Size | SHA-256 Checksum |
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gf-complete_1.0.2+2017.04.10.git.ea75cdf-7.dsc | 2.3 KiB | c82eff178888e7c590a8e0ae2ffded46e22cca5466ff2aa1caf0b68761cefc9a |
gf-complete_1.0.2+2017.04.10.git.ea75cdf.orig.tar.xz | 289.0 KiB | 6a11e814556bda953c59510e893763bafafd346e05995c3c0fc6c0153c220069 |
gf-complete_1.0.2+2017.04.10.git.ea75cdf-7.debian.tar.xz | 4.7 KiB | 2a15bdab988deddbe58ca3d6e20eeb4005861421e7bda9ca13621588e48ea9d0 |
Available diffs
No changes file available.
Binary packages built by this source
- gf-complete-tools: Galois Field Arithmetic - tools
Galois Field arithmetic forms the backbone of erasure-coded storage systems,
most famously the Reed-Solomon erasure code. A Galois Field is defined over
w-bit words and is termed GF(2^w). As such, the elements of a Galois Field are
the integers 0, 1, . . ., 2^w − 1. Galois Field arithmetic defines addition
and multiplication over these closed sets of integers in such a way that they
work as you would hope they would work. Specifically, every number has a
unique multiplicative inverse. Moreover, there is a value, typically the value
2, which has the property that you can enumerate all of the non-zero elements
of the field by taking that value to successively higher powers.
.
This package contains miscellaneous tools for working with gf-complete.
- gf-complete-tools-dbgsym: debug symbols for gf-complete-tools
- libgf-complete-dev: Galois Field Arithmetic - development files
Galois Field arithmetic forms the backbone of erasure-coded storage systems,
most famously the Reed-Solomon erasure code. A Galois Field is defined over
w-bit words and is termed GF(2^w). As such, the elements of a Galois Field are
the integers 0, 1, . . ., 2^w − 1. Galois Field arithmetic defines addition
and multiplication over these closed sets of integers in such a way that they
work as you would hope they would work. Specifically, every number has a
unique multiplicative inverse. Moreover, there is a value, typically the value
2, which has the property that you can enumerate all of the non-zero elements
of the field by taking that value to successively higher powers.
.
This package contains the development files needed to build against the shared
library.
- libgf-complete1: Galois Field Arithmetic - shared library
Galois Field arithmetic forms the backbone of erasure-coded storage systems,
most famously the Reed-Solomon erasure code. A Galois Field is defined over
w-bit words and is termed GF(2^w). As such, the elements of a Galois Field are
the integers 0, 1, . . ., 2^w − 1. Galois Field arithmetic defines addition
and multiplication over these closed sets of integers in such a way that they
work as you would hope they would work. Specifically, every number has a
unique multiplicative inverse. Moreover, there is a value, typically the value
2, which has the property that you can enumerate all of the non-zero elements
of the field by taking that value to successively higher powers.
.
This package contains the shared library.
- libgf-complete1-dbgsym: debug symbols for libgf-complete1