Copyright	(c) Levent Erkok
License	BSD3
Maintainer	erkokl@gmail.com
Stability	experimental
Safe Haskell	None
Language	Haskell2010

Documentation.SBV.Examples.Uninterpreted.AUF

Contents

Model using functional arrays

Description

Formalizes and proves the following theorem, about arithmetic, uninterpreted functions, and arrays. (For reference, see http://research.microsoft.com/en-us/um/redmond/projects/z3/fmcad06-slides.pdf slide number 24):

   x + 2 = y  implies  f (read (write (a, x, 3), y - 2)) = f (y - x + 1)

We interpret the types as follows (other interpretations certainly possible):

x: SWord32 (32-bit unsigned address)
y: SWord32 (32-bit unsigned address)
a: An array, indexed by 32-bit addresses, returning 32-bit unsigned integers
f: An uninterpreted function of type SWord32 -> SWord64

The function read and write are usual array operations.

Synopsis

f :: SWord32 -> SWord64
thm :: SymArray a => SWord32 -> SWord32 -> a Word32 Word32 -> SBool
proveSArray :: IO ThmResult
proveSFunArray :: IO ThmResult

Model using functional arrays

f :: SWord32 -> SWord64 Source #

Uninterpreted function in the theorem

thm :: SymArray a => SWord32 -> SWord32 -> a Word32 Word32 -> SBool Source #

Correctness theorem. We state it for all values of x, y, and the given array a. Note that we're being generic in the type of array we're expecting.

proveSArray :: IO ThmResult Source #

Prove it using SMT-Lib arrays.

>>> proveSArray
Q.E.D.

proveSFunArray :: IO ThmResult Source #

Prove it using SBV's internal functional arrays.

>>> proveSFunArray
Q.E.D.