Mercurial > cpdt > repo
diff src/Subset.v @ 370:549d604c3d16
Move exercises out of mainline book
| author | Adam Chlipala <adam@chlipala.net> |
|---|---|
| date | Fri, 02 Mar 2012 09:58:00 -0500 |
| parents | e76aced46eb1 |
| children | 31fa03bc0f18 |
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--- a/src/Subset.v Fri Dec 16 13:28:11 2011 -0500 +++ b/src/Subset.v Fri Mar 02 09:58:00 2012 -0500 @@ -923,27 +923,3 @@ ]] The results of simplifying calls to [typeCheck'] look deceptively similar to the results for [typeCheck], but now the types of the results provide more information. *) - - -(** * Exercises *) - -(** All of the notations defined in this chapter, plus some extras, are available for import from the module [MoreSpecif] of the book source. - -%\begin{enumerate}%#<ol># -%\item%#<li># Write a function of type [forall n m : nat, {][n <= m} + {][n > m}]. That is, this function decides whether one natural is less than another, and its dependent type guarantees that its results are accurate.#</li># - -%\item%#<li># %\begin{enumerate}%#<ol># - %\item%#<li># Define [var], a type of propositional variables, as a synonym for [nat].#</li># - %\item%#<li># Define an inductive type [prop] of propositional logic formulas, consisting of variables, negation, and binary conjunction and disjunction.#</li># - %\item%#<li># Define a function [propDenote] from variable truth assignments and [prop]s to [Prop], based on the usual meanings of the connectives. Represent truth assignments as functions from [var] to [bool].#</li># - %\item%#<li># Define a function [bool_true_dec] that checks whether a boolean is true, with a maximally expressive dependent type. That is, the function should have type [forall b, {b = true} + {b = true -> False}]. #</li># - %\item%#<li># Define a function [decide] that determines whether a particular [prop] is true under a particular truth assignment. That is, the function should have type [forall (truth : var -> bool) (p : prop), {propDenote truth p} + {~ propDenote truth p}]. This function is probably easiest to write in the usual tactical style, instead of programming with [refine]. The function [bool_true_dec] may come in handy as a hint.#</li># - %\item%#<li># Define a function [negate] that returns a simplified version of the negation of a [prop]. That is, the function should have type [forall p : prop, {p' : prop | forall truth, propDenote truth p <-> ~ propDenote truth p'}]. To simplify a variable, just negate it. Simplify a negation by returning its argument. Simplify conjunctions and disjunctions using De Morgan's laws, negating the arguments recursively and switching the kind of connective. Your [decide] function may be useful in some of the proof obligations, even if you do not use it in the computational part of [negate]'s definition. Lemmas like [decide] allow us to compensate for the lack of a general Law of the Excluded Middle in CIC.#</li># -#</ol>#%\end{enumerate}% #</li># - -%\item%#<li># Implement the DPLL satisfiability decision procedure for boolean formulas in conjunctive normal form, with a dependent type that guarantees its correctness. An example of a reasonable type for this function would be [forall f : formula, {truth : tvals | formulaTrue truth f} + {][forall truth, ~ formulaTrue truth f}]. Implement at least %``%#"#the basic backtracking algorithm#"#%''% as defined here: - %\begin{center}\url{http://en.wikipedia.org/wiki/DPLL_algorithm}\end{center}% - #<blockquote><a href="http://en.wikipedia.org/wiki/DPLL_algorithm">http://en.wikipedia.org/wiki/DPLL_algorithm</a></blockquote># -It might also be instructive to implement the unit propagation and pure literal elimination optimizations described there or some other optimizations that have been used in modern SAT solvers.#</li># - -#</ol>#%\end{enumerate}% *)