isabelle: doc-src/AxClass/generated/NatClass.tex@813fabceec00 (annotated)

8890 9a44d8d98731 snapshot of new Isar'ized version; wenzelm parents: diff changeset	1	\begin{isabelle}%
8906 fc7841f31388 tuned; wenzelm parents: 8903 diff changeset	2	%
fc7841f31388 tuned; wenzelm parents: 8903 diff changeset	3	\isamarkupheader{Defining natural numbers in FOL \label{sec:ex-natclass}}
fc7841f31388 tuned; wenzelm parents: 8903 diff changeset	4	\isacommand{theory}~NatClass~=~FOL:%
fc7841f31388 tuned; wenzelm parents: 8903 diff changeset	5	\begin{isamarkuptext}%
fc7841f31388 tuned; wenzelm parents: 8903 diff changeset	6	\medskip\noindent Axiomatic type classes abstract over exactly one
fc7841f31388 tuned; wenzelm parents: 8903 diff changeset	7	type argument. Thus, any \emph{axiomatic} theory extension where each
fc7841f31388 tuned; wenzelm parents: 8903 diff changeset	8	axiom refers to at most one type variable, may be trivially turned
fc7841f31388 tuned; wenzelm parents: 8903 diff changeset	9	into a \emph{definitional} one.
fc7841f31388 tuned; wenzelm parents: 8903 diff changeset	10
fc7841f31388 tuned; wenzelm parents: 8903 diff changeset	11	We illustrate this with the natural numbers in
fc7841f31388 tuned; wenzelm parents: 8903 diff changeset	12	Isabelle/FOL.\footnote{See also
fc7841f31388 tuned; wenzelm parents: 8903 diff changeset	13	\url{http://isabelle.in.tum.de/library/FOL/ex/NatClass.html}}%
fc7841f31388 tuned; wenzelm parents: 8903 diff changeset	14	\end{isamarkuptext}%
8890 9a44d8d98731 snapshot of new Isar'ized version; wenzelm parents: diff changeset	15	\isacommand{consts}\isanewline
9a44d8d98731 snapshot of new Isar'ized version; wenzelm parents: diff changeset	16	~~zero~::~'a~~~~({"}0{"})\isanewline
9a44d8d98731 snapshot of new Isar'ized version; wenzelm parents: diff changeset	17	~~Suc~::~{"}'a~{\isasymRightarrow}~'a{"}\isanewline
9a44d8d98731 snapshot of new Isar'ized version; wenzelm parents: diff changeset	18	~~rec~::~{"}'a~{\isasymRightarrow}~'a~{\isasymRightarrow}~('a~{\isasymRightarrow}~'a~{\isasymRightarrow}~'a)~{\isasymRightarrow}~'a{"}\isanewline
9a44d8d98731 snapshot of new Isar'ized version; wenzelm parents: diff changeset	19	\isanewline
9a44d8d98731 snapshot of new Isar'ized version; wenzelm parents: diff changeset	20	\isacommand{axclass}\isanewline
9a44d8d98731 snapshot of new Isar'ized version; wenzelm parents: diff changeset	21	~~nat~<~{"}term{"}\isanewline
9a44d8d98731 snapshot of new Isar'ized version; wenzelm parents: diff changeset	22	~~induct:~~~~~{"}P(0)~{\isasymLongrightarrow}~({\isasymAnd}x.~P(x)~{\isasymLongrightarrow}~P(Suc(x)))~{\isasymLongrightarrow}~P(n){"}\isanewline
9a44d8d98731 snapshot of new Isar'ized version; wenzelm parents: diff changeset	23	~~Suc\_inject:~{"}Suc(m)~=~Suc(n)~{\isasymLongrightarrow}~m~=~n{"}\isanewline
9a44d8d98731 snapshot of new Isar'ized version; wenzelm parents: diff changeset	24	~~Suc\_neq\_0:~~{"}Suc(m)~=~0~{\isasymLongrightarrow}~R{"}\isanewline
9a44d8d98731 snapshot of new Isar'ized version; wenzelm parents: diff changeset	25	~~rec\_0:~~~~~~{"}rec(0,~a,~f)~=~a{"}\isanewline
9a44d8d98731 snapshot of new Isar'ized version; wenzelm parents: diff changeset	26	~~rec\_Suc:~~~~{"}rec(Suc(m),~a,~f)~=~f(m,~rec(m,~a,~f)){"}\isanewline
9a44d8d98731 snapshot of new Isar'ized version; wenzelm parents: diff changeset	27	\isanewline
9a44d8d98731 snapshot of new Isar'ized version; wenzelm parents: diff changeset	28	\isacommand{constdefs}\isanewline
9a44d8d98731 snapshot of new Isar'ized version; wenzelm parents: diff changeset	29	~~add~::~{"}'a::nat~{\isasymRightarrow}~'a~{\isasymRightarrow}~'a{"}~~~~(\isakeyword{infixl}~{"}+{"}~60)\isanewline
8906 fc7841f31388 tuned; wenzelm parents: 8903 diff changeset	30	~~{"}m~+~n~{\isasymequiv}~rec(m,~n,~{\isasymlambda}x~y.~Suc(y)){"}%
fc7841f31388 tuned; wenzelm parents: 8903 diff changeset	31	\begin{isamarkuptext}%
fc7841f31388 tuned; wenzelm parents: 8903 diff changeset	32	This is an abstract version of the plain $Nat$ theory in
fc7841f31388 tuned; wenzelm parents: 8903 diff changeset	33	FOL.\footnote{See
8907 813fabceec00 tuned; wenzelm parents: 8906 diff changeset	34	\url{http://isabelle.in.tum.de/library/FOL/ex/Nat.html}} Basically,
813fabceec00 tuned; wenzelm parents: 8906 diff changeset	35	we have just replaced all occurrences of type $nat$ by $\alpha$ and
813fabceec00 tuned; wenzelm parents: 8906 diff changeset	36	used the natural number axioms to define class $nat$. There is only
813fabceec00 tuned; wenzelm parents: 8906 diff changeset	37	a minor snag, that the original recursion operator $rec$ had to be
813fabceec00 tuned; wenzelm parents: 8906 diff changeset	38	made monomorphic.
8906 fc7841f31388 tuned; wenzelm parents: 8903 diff changeset	39
8907 813fabceec00 tuned; wenzelm parents: 8906 diff changeset	40	Thus class $nat$ contains exactly those types $\tau$ that are
813fabceec00 tuned; wenzelm parents: 8906 diff changeset	41	isomorphic to ``the'' natural numbers (with signature $0$, $Suc$,
813fabceec00 tuned; wenzelm parents: 8906 diff changeset	42	$rec$).
8906 fc7841f31388 tuned; wenzelm parents: 8903 diff changeset	43
fc7841f31388 tuned; wenzelm parents: 8903 diff changeset	44	\medskip What we have done here can be also viewed as \emph{type
fc7841f31388 tuned; wenzelm parents: 8903 diff changeset	45	specification}. Of course, it still remains open if there is some
fc7841f31388 tuned; wenzelm parents: 8903 diff changeset	46	type at all that meets the class axioms. Now a very nice property of
8907 813fabceec00 tuned; wenzelm parents: 8906 diff changeset	47	axiomatic type classes is that abstract reasoning is always possible
8906 fc7841f31388 tuned; wenzelm parents: 8903 diff changeset	48	--- independent of satisfiability. The meta-logic won't break, even
8907 813fabceec00 tuned; wenzelm parents: 8906 diff changeset	49	if some classes (or general sorts) turns out to be empty later ---
813fabceec00 tuned; wenzelm parents: 8906 diff changeset	50	``inconsistent'' class definitions may be useless, but do not cause
813fabceec00 tuned; wenzelm parents: 8906 diff changeset	51	any harm.
8906 fc7841f31388 tuned; wenzelm parents: 8903 diff changeset	52
fc7841f31388 tuned; wenzelm parents: 8903 diff changeset	53	Theorems of the abstract natural numbers may be derived in the same
fc7841f31388 tuned; wenzelm parents: 8903 diff changeset	54	way as for the concrete version. The original proof scripts may be
8907 813fabceec00 tuned; wenzelm parents: 8906 diff changeset	55	re-used with some trivial changes only (mostly adding some type
8906 fc7841f31388 tuned; wenzelm parents: 8903 diff changeset	56	constraints).%
fc7841f31388 tuned; wenzelm parents: 8903 diff changeset	57	\end{isamarkuptext}%
8890 9a44d8d98731 snapshot of new Isar'ized version; wenzelm parents: diff changeset	58	\isacommand{end}\end{isabelle}%

author	wenzelm
	Mon, 22 May 2000 11:56:55 +0200
changeset 8907	813fabceec00
parent 8906	fc7841f31388
child 9145	9f7b8de5bfaf
permissions	-rw-r--r--