Module documentation for 0.5.1
Solve a number of equations simultaneously. This is not Computer Algebra, better think of a kind of type inference algorithm or logic programming with only one allowed solution.
Only one solution is computed. Simultaneous equations with multiple solutions are not allowed. However, variables may remain undefined. The solver may optionally check for consistency. It does not do so by default since with floating point numbers or symbolic expressions even simple rules may not be consistent.
The modules ordered with respect to abstraction level are:
UniqueLogic.ST.TF.System: Construct and solve sets of functional dependencies. Example:
assignment3 (+) a b cmeans dependency
a+b -> c.
UniqueLogic.ST.TF.Rule: Combine functional dependencies to rules that can apply in multiple directions. Example:
add a b cmeans relation
a+b = cwhich resolves to dependencies
a+b -> c, c-a -> b, c-b -> a. For an executable example see
UniqueLogic.ST.TF.Expression: Allows to write rules using arithmetic operators. It creates temporary variables automatically. Example:
(a+b)*c =:= dresolves to
a+b = x, x*c = d. For an executable example see
UniqueLogic.ST.TF.System.Simple: Provides specialised functions from
UniqueLogic.ST.TF.Systemfor the case of a system without labels and consistency checks.
UniqueLogic.ST.TF.System.Label: Provides a custom constructor for variables. When creating a variable you decide whether and how an assignment to this variable shall be logged. There is an example that shows how to solve a logic system using symbolic expressions. The naming and logging allows us to observe shared intermediate results. For an executable example see
By using more sophisticated monad transformers, we can check the equations for consistency, report inconsistencies and how they arised. We demonstrate that in
This variant of the package requires type families.
STmonad to any monad supporting mutable references using