ApCoCoALib:RingF32
User documentation for files RingF32.C and RingF32.H
These files contain an implementation of the field with 32 elements. The fields representation is ((Z/(2))[x])/(x^5 + x^2 + 1).
Internally, the fields elements are stored as numbers (unsigned char's, to be specific). These numbers, interpreted as bit-streams, correspond to the univariate polynomial's sequence of coefficients. For example
11 = 1* 2^3 = 0*2^2 + 1*2^1 + 1 * 2^0 <-> (01011) <-> 0*x^4 + 1*x^3 + 0*x^2 + 1*x^1 + 1*x^0 = x^3 + x + 1
So the field element x^3 + x + 1 is internally stored as '11'.
An instance of RingF32 can be created via
CoCoA::ring R = ApCoCoA::AlgebraicCore::NewRingF32();
To see if a given CoCoA::ring R is an instance of RingF32 you can check
bool b = ApCoCoa::AlgebraicCore::IsRingF32(R);
Furthermore, any instance of RingF32 can be used like any other ring in CoCoA. To create an element proceed as follows:
CoCoA::Ring R = ApCoCoA::AlgebraicCore::NewRingF32(); CoCoA::RingElem e(r,11);
and e represents the ring element 'x^3+x+1' or equivalently '11'. A warning: adding the element '3' to the element '2' does NOT lead to the element '5', since '3' <-> 'x+1', '2' <-> 'x' and (x+1) + (x) = 1 <-> '1'. Some more details on how elements can be stored and retrieved from this ring can be found in the example ex-RingF16.C in ApCoCoALib's example directory.
Maintainer documentation for files RingF32.C and RingF32.H
Currently, this fields uses 'semi-logarithmic' multiplication and division matrixes. This means both matrices are of size 5 times 32.
To multiply a and b, we split a into its exponents (a_0, ... a_4) and XOR the elements {m_(i,b) | i=0,..4, a_i =1 } of the multiplication matrix.
To divide a through b, we again split a like above and XOR the elements {d_(i,b) | i=0,..4, a_i =1 } of the division matrix.
Other options would be the usage of a logarithmic matrices or two 'full' 32 times 32 matrices. So we have to make a decision between XOR operations and memory usage. Which of this versions is optimal has to be checked for different problem settings. Since a 5 times 32 matrix of unsigned chars is rather small, here do not occur any paging conflicts, but eventually a 32 times 32 matrix could be more efficient.
Bugs, Shortcomings and other ideas
The current implementation does not support a lot of intractability with other rings. A set of Ringhomomorphisms could be implemented to allow a more easy switch between other representations of F_32 or to map elements in Z[x] or Z/(2)[x] into F_32.
Also isomorphisms between different representations of F_32 could be implemented. Any irreducible polynomial of degree 5 in Z/(2)[x] can be used to create a representation of F_32. Based in the galois group of F_32 and the irreducible polynomial's roots in F_32 an isomorphism can be described, mapping one representation to another. This might be handy, if a special modulus is given for a computation which is not the one, used for this implementations multiplication / division matrices.
References
[http://apcocoa.org/wiki/ApCoCoA:Representation_of_finite_fields] - more information on the representation of finite fields..
[http://apcocoa.org/wiki/HowTo:Construct_fields] - a description, how the multiplication / division matrices were constructed, including the needed source-code / tools.