isabelle: doc-src/TutorialI/Types/document/Typedef.tex@b28bbb153603 (annotated)

10366 dd74d0a56df9 * empty log message * nipkow parents: diff changeset	1	%
dd74d0a56df9 * empty log message * nipkow parents: diff changeset	2	\begin{isabellebody}%
dd74d0a56df9 * empty log message * nipkow parents: diff changeset	3	\def\isabellecontext{Typedef}%
dd74d0a56df9 * empty log message * nipkow parents: diff changeset	4	%
10878 b254d5ad6dd4 auto update paulson parents: 10777 diff changeset	5	\isamarkupsection{Introducing New Types%
10397 e2d0dda41f2c auto update paulson parents: 10396 diff changeset	6	}
10366 dd74d0a56df9 * empty log message * nipkow parents: diff changeset	7	%
dd74d0a56df9 * empty log message * nipkow parents: diff changeset	8	\begin{isamarkuptext}%
dd74d0a56df9 * empty log message * nipkow parents: diff changeset	9	\label{sec:adv-typedef}
11196 bb4ede27fcb7 * empty log message * nipkow parents: 11149 diff changeset	10	For most applications, a combination of predefined types like \isa{bool} and
bb4ede27fcb7 * empty log message * nipkow parents: 11149 diff changeset	11	\isa{{\isasymRightarrow}} with recursive datatypes and records is quite sufficient. Very
bb4ede27fcb7 * empty log message * nipkow parents: 11149 diff changeset	12	occasionally you may feel the need for a more advanced type. If you cannot do
bb4ede27fcb7 * empty log message * nipkow parents: 11149 diff changeset	13	without that type, and you are certain that it is not definable by any of the
bb4ede27fcb7 * empty log message * nipkow parents: 11149 diff changeset	14	standard means, then read on.
10366 dd74d0a56df9 * empty log message * nipkow parents: diff changeset	15	\begin{warn}
dd74d0a56df9 * empty log message * nipkow parents: diff changeset	16	Types in HOL must be non-empty; otherwise the quantifier rules would be
10420 ef006735bee8 * empty log message * nipkow parents: 10397 diff changeset	17	unsound, because $\exists x.\ x=x$ is a theorem.
10366 dd74d0a56df9 * empty log message * nipkow parents: diff changeset	18	\end{warn}%
dd74d0a56df9 * empty log message * nipkow parents: diff changeset	19	\end{isamarkuptext}%
dd74d0a56df9 * empty log message * nipkow parents: diff changeset	20	%
10878 b254d5ad6dd4 auto update paulson parents: 10777 diff changeset	21	\isamarkupsubsection{Declaring New Types%
10397 e2d0dda41f2c auto update paulson parents: 10396 diff changeset	22	}
10366 dd74d0a56df9 * empty log message * nipkow parents: diff changeset	23	%
dd74d0a56df9 * empty log message * nipkow parents: diff changeset	24	\begin{isamarkuptext}%
dd74d0a56df9 * empty log message * nipkow parents: diff changeset	25	\label{sec:typedecl}
dd74d0a56df9 * empty log message * nipkow parents: diff changeset	26	The most trivial way of introducing a new type is by a \bfindex{type
dd74d0a56df9 * empty log message * nipkow parents: diff changeset	27	declaration}:%
dd74d0a56df9 * empty log message * nipkow parents: diff changeset	28	\end{isamarkuptext}%
dd74d0a56df9 * empty log message * nipkow parents: diff changeset	29	\isacommand{typedecl}\ my{\isacharunderscore}new{\isacharunderscore}type%
dd74d0a56df9 * empty log message * nipkow parents: diff changeset	30	\begin{isamarkuptext}%
dd74d0a56df9 * empty log message * nipkow parents: diff changeset	31	\noindent\indexbold{*typedecl}%
10420 ef006735bee8 * empty log message * nipkow parents: 10397 diff changeset	32	This does not define \isa{my{\isacharunderscore}new{\isacharunderscore}type} at all but merely introduces its
ef006735bee8 * empty log message * nipkow parents: 10397 diff changeset	33	name. Thus we know nothing about this type, except that it is
10366 dd74d0a56df9 * empty log message * nipkow parents: diff changeset	34	non-empty. Such declarations without definitions are
11277 a2bff98d6e5d * empty log message * nipkow parents: 11196 diff changeset	35	useful if that type can be viewed as a parameter of the theory.
a2bff98d6e5d * empty log message * nipkow parents: 11196 diff changeset	36	A typical example is given in \S\ref{sec:VMC}, where we define a transition
a2bff98d6e5d * empty log message * nipkow parents: 11196 diff changeset	37	relation over an arbitrary type of states.
10366 dd74d0a56df9 * empty log message * nipkow parents: diff changeset	38
dd74d0a56df9 * empty log message * nipkow parents: diff changeset	39	In principle we can always get rid of such type declarations by making those
dd74d0a56df9 * empty log message * nipkow parents: diff changeset	40	types parameters of every other type, thus keeping the theory generic. In
11196 bb4ede27fcb7 * empty log message * nipkow parents: 11149 diff changeset	41	practice, however, the resulting clutter can make types hard to read.
10366 dd74d0a56df9 * empty log message * nipkow parents: diff changeset	42
dd74d0a56df9 * empty log message * nipkow parents: diff changeset	43	If you are looking for a quick and dirty way of introducing a new type
dd74d0a56df9 * empty log message * nipkow parents: diff changeset	44	together with its properties: declare the type and state its properties as
dd74d0a56df9 * empty log message * nipkow parents: diff changeset	45	axioms. Example:%
dd74d0a56df9 * empty log message * nipkow parents: diff changeset	46	\end{isamarkuptext}%
dd74d0a56df9 * empty log message * nipkow parents: diff changeset	47	\isacommand{axioms}\isanewline
10420 ef006735bee8 * empty log message * nipkow parents: 10397 diff changeset	48	just{\isacharunderscore}one{\isacharcolon}\ {\isachardoublequote}{\isasymexists}x{\isacharcolon}{\isacharcolon}my{\isacharunderscore}new{\isacharunderscore}type{\isachardot}\ {\isasymforall}y{\isachardot}\ x\ {\isacharequal}\ y{\isachardoublequote}%
10366 dd74d0a56df9 * empty log message * nipkow parents: diff changeset	49	\begin{isamarkuptext}%
dd74d0a56df9 * empty log message * nipkow parents: diff changeset	50	\noindent
dd74d0a56df9 * empty log message * nipkow parents: diff changeset	51	However, we strongly discourage this approach, except at explorative stages
dd74d0a56df9 * empty log message * nipkow parents: diff changeset	52	of your development. It is extremely easy to write down contradictory sets of
dd74d0a56df9 * empty log message * nipkow parents: diff changeset	53	axioms, in which case you will be able to prove everything but it will mean
11196 bb4ede27fcb7 * empty log message * nipkow parents: 11149 diff changeset	54	nothing. In the example above, the axiomatic approach is
10366 dd74d0a56df9 * empty log message * nipkow parents: diff changeset	55	unnecessary: a one-element type called \isa{unit} is already defined in HOL.%
dd74d0a56df9 * empty log message * nipkow parents: diff changeset	56	\end{isamarkuptext}%
dd74d0a56df9 * empty log message * nipkow parents: diff changeset	57	%
10878 b254d5ad6dd4 auto update paulson parents: 10777 diff changeset	58	\isamarkupsubsection{Defining New Types%
10397 e2d0dda41f2c auto update paulson parents: 10396 diff changeset	59	}
10366 dd74d0a56df9 * empty log message * nipkow parents: diff changeset	60	%
dd74d0a56df9 * empty log message * nipkow parents: diff changeset	61	\begin{isamarkuptext}%
dd74d0a56df9 * empty log message * nipkow parents: diff changeset	62	\label{sec:typedef}
dd74d0a56df9 * empty log message * nipkow parents: diff changeset	63	Now we come to the most general method of safely introducing a new type, the
dd74d0a56df9 * empty log message * nipkow parents: diff changeset	64	\bfindex{type definition}. All other methods, for example
dd74d0a56df9 * empty log message * nipkow parents: diff changeset	65	\isacommand{datatype}, are based on it. The principle is extremely simple:
dd74d0a56df9 * empty log message * nipkow parents: diff changeset	66	any non-empty subset of an existing type can be turned into a new type. Thus
dd74d0a56df9 * empty log message * nipkow parents: diff changeset	67	a type definition is merely a notational device: you introduce a new name for
dd74d0a56df9 * empty log message * nipkow parents: diff changeset	68	a subset of an existing type. This does not add any logical power to HOL,
dd74d0a56df9 * empty log message * nipkow parents: diff changeset	69	because you could base all your work directly on the subset of the existing
11196 bb4ede27fcb7 * empty log message * nipkow parents: 11149 diff changeset	70	type. However, the resulting theories could easily become indigestible
10366 dd74d0a56df9 * empty log message * nipkow parents: diff changeset	71	because instead of implicit types you would have explicit sets in your
dd74d0a56df9 * empty log message * nipkow parents: diff changeset	72	formulae.
dd74d0a56df9 * empty log message * nipkow parents: diff changeset	73
dd74d0a56df9 * empty log message * nipkow parents: diff changeset	74	Let us work a simple example, the definition of a three-element type.
dd74d0a56df9 * empty log message * nipkow parents: diff changeset	75	It is easily represented by the first three natural numbers:%
dd74d0a56df9 * empty log message * nipkow parents: diff changeset	76	\end{isamarkuptext}%
dd74d0a56df9 * empty log message * nipkow parents: diff changeset	77	\isacommand{typedef}\ three\ {\isacharequal}\ {\isachardoublequote}{\isacharbraceleft}n{\isachardot}\ n\ {\isasymle}\ {\isadigit{2}}{\isacharbraceright}{\isachardoublequote}%
dd74d0a56df9 * empty log message * nipkow parents: diff changeset	78	\begin{isamarkuptxt}%
dd74d0a56df9 * empty log message * nipkow parents: diff changeset	79	\noindent\indexbold{*typedef}%
dd74d0a56df9 * empty log message * nipkow parents: diff changeset	80	In order to enforce that the representing set on the right-hand side is
dd74d0a56df9 * empty log message * nipkow parents: diff changeset	81	non-empty, this definition actually starts a proof to that effect:
dd74d0a56df9 * empty log message * nipkow parents: diff changeset	82	\begin{isabelle}%
dd74d0a56df9 * empty log message * nipkow parents: diff changeset	83	\ {\isadigit{1}}{\isachardot}\ {\isasymexists}x{\isachardot}\ x\ {\isasymin}\ {\isacharbraceleft}n{\isachardot}\ n\ {\isasymle}\ {\isadigit{2}}{\isacharbraceright}%
dd74d0a56df9 * empty log message * nipkow parents: diff changeset	84	\end{isabelle}
dd74d0a56df9 * empty log message * nipkow parents: diff changeset	85	Fortunately, this is easy enough to show: take 0 as a witness.%
dd74d0a56df9 * empty log message * nipkow parents: diff changeset	86	\end{isamarkuptxt}%
dd74d0a56df9 * empty log message * nipkow parents: diff changeset	87	\isacommand{apply}{\isacharparenleft}rule{\isacharunderscore}tac\ x\ {\isacharequal}\ {\isadigit{0}}\ \isakeyword{in}\ exI{\isacharparenright}\isanewline
dd74d0a56df9 * empty log message * nipkow parents: diff changeset	88	\isacommand{by}\ simp%
dd74d0a56df9 * empty log message * nipkow parents: diff changeset	89	\begin{isamarkuptext}%
dd74d0a56df9 * empty log message * nipkow parents: diff changeset	90	This type definition introduces the new type \isa{three} and asserts
11196 bb4ede27fcb7 * empty log message * nipkow parents: 11149 diff changeset	91	that it is a copy of the set \isa{{\isacharbraceleft}{\isadigit{0}}{\isacharcomma}\ {\isadigit{1}}{\isacharcomma}\ {\isadigit{2}}{\isacharbraceright}}. This assertion
10366 dd74d0a56df9 * empty log message * nipkow parents: diff changeset	92	is expressed via a bijection between the \emph{type} \isa{three} and the
dd74d0a56df9 * empty log message * nipkow parents: diff changeset	93	\emph{set} \isa{{\isacharbraceleft}{\isadigit{0}}{\isacharcomma}\ {\isadigit{1}}{\isacharcomma}\ {\isadigit{2}}{\isacharbraceright}}. To this end, the command declares the following
dd74d0a56df9 * empty log message * nipkow parents: diff changeset	94	constants behind the scenes:
dd74d0a56df9 * empty log message * nipkow parents: diff changeset	95	\begin{center}
dd74d0a56df9 * empty log message * nipkow parents: diff changeset	96	\begin{tabular}{rcl}
dd74d0a56df9 * empty log message * nipkow parents: diff changeset	97	\isa{three} &::& \isa{nat\ set} \\
dd74d0a56df9 * empty log message * nipkow parents: diff changeset	98	\isa{Rep{\isacharunderscore}three} &::& \isa{three\ {\isasymRightarrow}\ nat}\\
dd74d0a56df9 * empty log message * nipkow parents: diff changeset	99	\isa{Abs{\isacharunderscore}three} &::& \isa{nat\ {\isasymRightarrow}\ three}
dd74d0a56df9 * empty log message * nipkow parents: diff changeset	100	\end{tabular}
dd74d0a56df9 * empty log message * nipkow parents: diff changeset	101	\end{center}
11196 bb4ede27fcb7 * empty log message * nipkow parents: 11149 diff changeset	102	where constant \isa{three} is explicitly defined as the representing set:
10983 59961d32b1ae * empty log message * nipkow parents: 10878 diff changeset	103	\begin{center}
59961d32b1ae * empty log message * nipkow parents: 10878 diff changeset	104	\isa{three\ {\isasymequiv}\ {\isacharbraceleft}n{\isachardot}\ n\ {\isasymle}\ {\isadigit{2}}{\isacharbraceright}}\hfill(\isa{three{\isacharunderscore}def})
59961d32b1ae * empty log message * nipkow parents: 10878 diff changeset	105	\end{center}
10366 dd74d0a56df9 * empty log message * nipkow parents: diff changeset	106	The situation is best summarized with the help of the following diagram,
dd74d0a56df9 * empty log message * nipkow parents: diff changeset	107	where squares are types and circles are sets:
dd74d0a56df9 * empty log message * nipkow parents: diff changeset	108	\begin{center}
dd74d0a56df9 * empty log message * nipkow parents: diff changeset	109	\unitlength1mm
dd74d0a56df9 * empty log message * nipkow parents: diff changeset	110	\thicklines
dd74d0a56df9 * empty log message * nipkow parents: diff changeset	111	\begin{picture}(100,40)
dd74d0a56df9 * empty log message * nipkow parents: diff changeset	112	\put(3,13){\framebox(15,15){\isa{three}}}
dd74d0a56df9 * empty log message * nipkow parents: diff changeset	113	\put(55,5){\framebox(30,30){\isa{three}}}
dd74d0a56df9 * empty log message * nipkow parents: diff changeset	114	\put(70,32){\makebox(0,0){\isa{nat}}}
dd74d0a56df9 * empty log message * nipkow parents: diff changeset	115	\put(70,20){\circle{40}}
dd74d0a56df9 * empty log message * nipkow parents: diff changeset	116	\put(10,15){\vector(1,0){60}}
dd74d0a56df9 * empty log message * nipkow parents: diff changeset	117	\put(25,14){\makebox(0,0)[tl]{\isa{Rep{\isacharunderscore}three}}}
dd74d0a56df9 * empty log message * nipkow parents: diff changeset	118	\put(70,25){\vector(-1,0){60}}
dd74d0a56df9 * empty log message * nipkow parents: diff changeset	119	\put(25,26){\makebox(0,0)[bl]{\isa{Abs{\isacharunderscore}three}}}
dd74d0a56df9 * empty log message * nipkow parents: diff changeset	120	\end{picture}
dd74d0a56df9 * empty log message * nipkow parents: diff changeset	121	\end{center}
dd74d0a56df9 * empty log message * nipkow parents: diff changeset	122	Finally, \isacommand{typedef} asserts that \isa{Rep{\isacharunderscore}three} is
dd74d0a56df9 * empty log message * nipkow parents: diff changeset	123	surjective on the subset \isa{three} and \isa{Abs{\isacharunderscore}three} and \isa{Rep{\isacharunderscore}three} are inverses of each other:
dd74d0a56df9 * empty log message * nipkow parents: diff changeset	124	\begin{center}
10983 59961d32b1ae * empty log message * nipkow parents: 10878 diff changeset	125	\begin{tabular}{@ {}r@ {\qquad\qquad}l@ {}}
59961d32b1ae * empty log message * nipkow parents: 10878 diff changeset	126	\isa{Rep{\isacharunderscore}three\ x\ {\isasymin}\ three} & (\isa{Rep{\isacharunderscore}three}) \\
59961d32b1ae * empty log message * nipkow parents: 10878 diff changeset	127	\isa{Abs{\isacharunderscore}three\ {\isacharparenleft}Rep{\isacharunderscore}three\ x{\isacharparenright}\ {\isacharequal}\ x} & (\isa{Rep{\isacharunderscore}three{\isacharunderscore}inverse}) \\
59961d32b1ae * empty log message * nipkow parents: 10878 diff changeset	128	\isa{y\ {\isasymin}\ three\ {\isasymLongrightarrow}\ Rep{\isacharunderscore}three\ {\isacharparenleft}Abs{\isacharunderscore}three\ y{\isacharparenright}\ {\isacharequal}\ y} & (\isa{Abs{\isacharunderscore}three{\isacharunderscore}inverse})
10366 dd74d0a56df9 * empty log message * nipkow parents: diff changeset	129	\end{tabular}
dd74d0a56df9 * empty log message * nipkow parents: diff changeset	130	\end{center}
10878 b254d5ad6dd4 auto update paulson parents: 10777 diff changeset	131	%
b254d5ad6dd4 auto update paulson parents: 10777 diff changeset	132	From this example it should be clear what \isacommand{typedef} does
b254d5ad6dd4 auto update paulson parents: 10777 diff changeset	133	in general given a name (here \isa{three}) and a set
b254d5ad6dd4 auto update paulson parents: 10777 diff changeset	134	(here \isa{{\isacharbraceleft}n{\isachardot}\ n\ {\isasymle}\ {\isadigit{2}}{\isacharbraceright}}).
10366 dd74d0a56df9 * empty log message * nipkow parents: diff changeset	135
dd74d0a56df9 * empty log message * nipkow parents: diff changeset	136	Our next step is to define the basic functions expected on the new type.
dd74d0a56df9 * empty log message * nipkow parents: diff changeset	137	Although this depends on the type at hand, the following strategy works well:
dd74d0a56df9 * empty log message * nipkow parents: diff changeset	138	\begin{itemize}
10878 b254d5ad6dd4 auto update paulson parents: 10777 diff changeset	139	\item define a small kernel of basic functions that can express all other
b254d5ad6dd4 auto update paulson parents: 10777 diff changeset	140	functions you anticipate.
10366 dd74d0a56df9 * empty log message * nipkow parents: diff changeset	141	\item define the kernel in terms of corresponding functions on the
dd74d0a56df9 * empty log message * nipkow parents: diff changeset	142	representing type using \isa{Abs} and \isa{Rep} to convert between the
dd74d0a56df9 * empty log message * nipkow parents: diff changeset	143	two levels.
dd74d0a56df9 * empty log message * nipkow parents: diff changeset	144	\end{itemize}
dd74d0a56df9 * empty log message * nipkow parents: diff changeset	145	In our example it suffices to give the three elements of type \isa{three}
dd74d0a56df9 * empty log message * nipkow parents: diff changeset	146	names:%
dd74d0a56df9 * empty log message * nipkow parents: diff changeset	147	\end{isamarkuptext}%
dd74d0a56df9 * empty log message * nipkow parents: diff changeset	148	\isacommand{constdefs}\isanewline
dd74d0a56df9 * empty log message * nipkow parents: diff changeset	149	\ \ A{\isacharcolon}{\isacharcolon}\ three\isanewline
dd74d0a56df9 * empty log message * nipkow parents: diff changeset	150	\ {\isachardoublequote}A\ {\isasymequiv}\ Abs{\isacharunderscore}three\ {\isadigit{0}}{\isachardoublequote}\isanewline
dd74d0a56df9 * empty log message * nipkow parents: diff changeset	151	\ \ B{\isacharcolon}{\isacharcolon}\ three\isanewline
dd74d0a56df9 * empty log message * nipkow parents: diff changeset	152	\ {\isachardoublequote}B\ {\isasymequiv}\ Abs{\isacharunderscore}three\ {\isadigit{1}}{\isachardoublequote}\isanewline
dd74d0a56df9 * empty log message * nipkow parents: diff changeset	153	\ \ C\ {\isacharcolon}{\isacharcolon}\ three\isanewline
dd74d0a56df9 * empty log message * nipkow parents: diff changeset	154	\ {\isachardoublequote}C\ {\isasymequiv}\ Abs{\isacharunderscore}three\ {\isadigit{2}}{\isachardoublequote}%
dd74d0a56df9 * empty log message * nipkow parents: diff changeset	155	\begin{isamarkuptext}%
dd74d0a56df9 * empty log message * nipkow parents: diff changeset	156	So far, everything was easy. But it is clear that reasoning about \isa{three} will be hell if we have to go back to \isa{nat} every time. Thus our
dd74d0a56df9 * empty log message * nipkow parents: diff changeset	157	aim must be to raise our level of abstraction by deriving enough theorems
dd74d0a56df9 * empty log message * nipkow parents: diff changeset	158	about type \isa{three} to characterize it completely. And those theorems
dd74d0a56df9 * empty log message * nipkow parents: diff changeset	159	should be phrased in terms of \isa{A}, \isa{B} and \isa{C}, not \isa{Abs{\isacharunderscore}three} and \isa{Rep{\isacharunderscore}three}. Because of the simplicity of the example,
dd74d0a56df9 * empty log message * nipkow parents: diff changeset	160	we merely need to prove that \isa{A}, \isa{B} and \isa{C} are distinct
dd74d0a56df9 * empty log message * nipkow parents: diff changeset	161	and that they exhaust the type.
dd74d0a56df9 * empty log message * nipkow parents: diff changeset	162
dd74d0a56df9 * empty log message * nipkow parents: diff changeset	163	We start with a helpful version of injectivity of \isa{Abs{\isacharunderscore}three} on the
dd74d0a56df9 * empty log message * nipkow parents: diff changeset	164	representing subset:%
dd74d0a56df9 * empty log message * nipkow parents: diff changeset	165	\end{isamarkuptext}%
dd74d0a56df9 * empty log message * nipkow parents: diff changeset	166	\isacommand{lemma}\ {\isacharbrackleft}simp{\isacharbrackright}{\isacharcolon}\isanewline
dd74d0a56df9 * empty log message * nipkow parents: diff changeset	167	\ {\isachardoublequote}{\isasymlbrakk}\ x\ {\isasymin}\ three{\isacharsemicolon}\ y\ {\isasymin}\ three\ {\isasymrbrakk}\ {\isasymLongrightarrow}\ {\isacharparenleft}Abs{\isacharunderscore}three\ x\ {\isacharequal}\ Abs{\isacharunderscore}three\ y{\isacharparenright}\ {\isacharequal}\ {\isacharparenleft}x{\isacharequal}y{\isacharparenright}{\isachardoublequote}%
dd74d0a56df9 * empty log message * nipkow parents: diff changeset	168	\begin{isamarkuptxt}%
dd74d0a56df9 * empty log message * nipkow parents: diff changeset	169	\noindent
10878 b254d5ad6dd4 auto update paulson parents: 10777 diff changeset	170	We prove each direction separately. From \isa{Abs{\isacharunderscore}three\ x\ {\isacharequal}\ Abs{\isacharunderscore}three\ y}
b254d5ad6dd4 auto update paulson parents: 10777 diff changeset	171	we use \isa{arg{\isacharunderscore}cong} to apply \isa{Rep{\isacharunderscore}three} to both sides,
b254d5ad6dd4 auto update paulson parents: 10777 diff changeset	172	deriving \begin{isabelle}%
b254d5ad6dd4 auto update paulson parents: 10777 diff changeset	173	Rep{\isacharunderscore}three\ {\isacharparenleft}Abs{\isacharunderscore}three\ x{\isacharparenright}\ {\isacharequal}\ Rep{\isacharunderscore}three\ {\isacharparenleft}Abs{\isacharunderscore}three\ y{\isacharparenright}%
b254d5ad6dd4 auto update paulson parents: 10777 diff changeset	174	\end{isabelle}
b254d5ad6dd4 auto update paulson parents: 10777 diff changeset	175	Thus we get the required \isa{x\ {\isacharequal}\ y} by simplification with \isa{Abs{\isacharunderscore}three{\isacharunderscore}inverse}.
b254d5ad6dd4 auto update paulson parents: 10777 diff changeset	176	The other direction
10366 dd74d0a56df9 * empty log message * nipkow parents: diff changeset	177	is trivial by simplification:%
dd74d0a56df9 * empty log message * nipkow parents: diff changeset	178	\end{isamarkuptxt}%
dd74d0a56df9 * empty log message * nipkow parents: diff changeset	179	\isacommand{apply}{\isacharparenleft}rule\ iffI{\isacharparenright}\isanewline
dd74d0a56df9 * empty log message * nipkow parents: diff changeset	180	\ \isacommand{apply}{\isacharparenleft}drule{\isacharunderscore}tac\ f\ {\isacharequal}\ Rep{\isacharunderscore}three\ \isakeyword{in}\ arg{\isacharunderscore}cong{\isacharparenright}\isanewline
dd74d0a56df9 * empty log message * nipkow parents: diff changeset	181	\ \isacommand{apply}{\isacharparenleft}simp\ add{\isacharcolon}Abs{\isacharunderscore}three{\isacharunderscore}inverse{\isacharparenright}\isanewline
dd74d0a56df9 * empty log message * nipkow parents: diff changeset	182	\isacommand{by}\ simp%
dd74d0a56df9 * empty log message * nipkow parents: diff changeset	183	\begin{isamarkuptext}%
dd74d0a56df9 * empty log message * nipkow parents: diff changeset	184	\noindent
dd74d0a56df9 * empty log message * nipkow parents: diff changeset	185	Analogous lemmas can be proved in the same way for arbitrary type definitions.
dd74d0a56df9 * empty log message * nipkow parents: diff changeset	186
dd74d0a56df9 * empty log message * nipkow parents: diff changeset	187	Distinctness of \isa{A}, \isa{B} and \isa{C} follows immediately
dd74d0a56df9 * empty log message * nipkow parents: diff changeset	188	if we expand their definitions and rewrite with the above simplification rule:%
dd74d0a56df9 * empty log message * nipkow parents: diff changeset	189	\end{isamarkuptext}%
dd74d0a56df9 * empty log message * nipkow parents: diff changeset	190	\isacommand{lemma}\ {\isachardoublequote}A\ {\isasymnoteq}\ B\ {\isasymand}\ B\ {\isasymnoteq}\ A\ {\isasymand}\ A\ {\isasymnoteq}\ C\ {\isasymand}\ C\ {\isasymnoteq}\ A\ {\isasymand}\ B\ {\isasymnoteq}\ C\ {\isasymand}\ C\ {\isasymnoteq}\ B{\isachardoublequote}\isanewline
dd74d0a56df9 * empty log message * nipkow parents: diff changeset	191	\isacommand{by}{\isacharparenleft}simp\ add{\isacharcolon}A{\isacharunderscore}def\ B{\isacharunderscore}def\ C{\isacharunderscore}def\ three{\isacharunderscore}def{\isacharparenright}%
dd74d0a56df9 * empty log message * nipkow parents: diff changeset	192	\begin{isamarkuptext}%
dd74d0a56df9 * empty log message * nipkow parents: diff changeset	193	\noindent
dd74d0a56df9 * empty log message * nipkow parents: diff changeset	194	Of course we rely on the simplifier to solve goals like \isa{{\isadigit{0}}\ {\isasymnoteq}\ {\isadigit{1}}}.
dd74d0a56df9 * empty log message * nipkow parents: diff changeset	195
dd74d0a56df9 * empty log message * nipkow parents: diff changeset	196	The fact that \isa{A}, \isa{B} and \isa{C} exhaust type \isa{three} is
dd74d0a56df9 * empty log message * nipkow parents: diff changeset	197	best phrased as a case distinction theorem: if you want to prove \isa{P\ x}
dd74d0a56df9 * empty log message * nipkow parents: diff changeset	198	(where \isa{x} is of type \isa{three}) it suffices to prove \isa{P\ A},
dd74d0a56df9 * empty log message * nipkow parents: diff changeset	199	\isa{P\ B} and \isa{P\ C}. First we prove the analogous proposition for the
dd74d0a56df9 * empty log message * nipkow parents: diff changeset	200	representation:%
dd74d0a56df9 * empty log message * nipkow parents: diff changeset	201	\end{isamarkuptext}%
11308 b28bbb153603 * empty log message * nipkow parents: 11277 diff changeset	202	\isacommand{lemma}\ cases{\isacharunderscore}lemma{\isacharcolon}\ {\isachardoublequote}{\isasymlbrakk}\ Q\ {\isadigit{0}}{\isacharsemicolon}\ Q\ {\isadigit{1}}{\isacharsemicolon}\ Q\ {\isadigit{2}}{\isacharsemicolon}\ n\ {\isasymin}\ three\ {\isasymrbrakk}\ {\isasymLongrightarrow}\ \ Q\ n{\isachardoublequote}%
10366 dd74d0a56df9 * empty log message * nipkow parents: diff changeset	203	\begin{isamarkuptxt}%
dd74d0a56df9 * empty log message * nipkow parents: diff changeset	204	\noindent
dd74d0a56df9 * empty log message * nipkow parents: diff changeset	205	Expanding \isa{three{\isacharunderscore}def} yields the premise \isa{n\ {\isasymle}\ {\isadigit{2}}}. Repeated
dd74d0a56df9 * empty log message * nipkow parents: diff changeset	206	elimination with \isa{le{\isacharunderscore}SucE}
dd74d0a56df9 * empty log message * nipkow parents: diff changeset	207	\begin{isabelle}%
10777 a5a6255748c3 initial material on the Reals paulson parents: 10696 diff changeset	208	{\isasymlbrakk}{\isacharquery}m\ {\isasymle}\ Suc\ {\isacharquery}n{\isacharsemicolon}\ {\isacharquery}m\ {\isasymle}\ {\isacharquery}n\ {\isasymLongrightarrow}\ {\isacharquery}R{\isacharsemicolon}\ {\isacharquery}m\ {\isacharequal}\ Suc\ {\isacharquery}n\ {\isasymLongrightarrow}\ {\isacharquery}R{\isasymrbrakk}\ {\isasymLongrightarrow}\ {\isacharquery}R%
10366 dd74d0a56df9 * empty log message * nipkow parents: diff changeset	209	\end{isabelle}
dd74d0a56df9 * empty log message * nipkow parents: diff changeset	210	reduces \isa{n\ {\isasymle}\ {\isadigit{2}}} to the three cases \isa{n\ {\isasymle}\ {\isadigit{0}}}, \isa{n\ {\isacharequal}\ {\isadigit{1}}} and
dd74d0a56df9 * empty log message * nipkow parents: diff changeset	211	\isa{n\ {\isacharequal}\ {\isadigit{2}}} which are trivial for simplification:%
dd74d0a56df9 * empty log message * nipkow parents: diff changeset	212	\end{isamarkuptxt}%
dd74d0a56df9 * empty log message * nipkow parents: diff changeset	213	\isacommand{apply}{\isacharparenleft}simp\ add{\isacharcolon}three{\isacharunderscore}def{\isacharparenright}\isanewline
dd74d0a56df9 * empty log message * nipkow parents: diff changeset	214	\isacommand{apply}{\isacharparenleft}{\isacharparenleft}erule\ le{\isacharunderscore}SucE{\isacharparenright}{\isacharplus}{\isacharparenright}\isanewline
dd74d0a56df9 * empty log message * nipkow parents: diff changeset	215	\isacommand{apply}\ simp{\isacharunderscore}all\isanewline
dd74d0a56df9 * empty log message * nipkow parents: diff changeset	216	\isacommand{done}%
dd74d0a56df9 * empty log message * nipkow parents: diff changeset	217	\begin{isamarkuptext}%
dd74d0a56df9 * empty log message * nipkow parents: diff changeset	218	Now the case distinction lemma on type \isa{three} is easy to derive if you know how to:%
dd74d0a56df9 * empty log message * nipkow parents: diff changeset	219	\end{isamarkuptext}%
dd74d0a56df9 * empty log message * nipkow parents: diff changeset	220	\isacommand{lemma}\ three{\isacharunderscore}cases{\isacharcolon}\ {\isachardoublequote}{\isasymlbrakk}\ P\ A{\isacharsemicolon}\ P\ B{\isacharsemicolon}\ P\ C\ {\isasymrbrakk}\ {\isasymLongrightarrow}\ P\ x{\isachardoublequote}%
dd74d0a56df9 * empty log message * nipkow parents: diff changeset	221	\begin{isamarkuptxt}%
dd74d0a56df9 * empty log message * nipkow parents: diff changeset	222	\noindent
dd74d0a56df9 * empty log message * nipkow parents: diff changeset	223	We start by replacing the \isa{x} by \isa{Abs{\isacharunderscore}three\ {\isacharparenleft}Rep{\isacharunderscore}three\ x{\isacharparenright}}:%
dd74d0a56df9 * empty log message * nipkow parents: diff changeset	224	\end{isamarkuptxt}%
dd74d0a56df9 * empty log message * nipkow parents: diff changeset	225	\isacommand{apply}{\isacharparenleft}rule\ subst{\isacharbrackleft}OF\ Rep{\isacharunderscore}three{\isacharunderscore}inverse{\isacharbrackright}{\isacharparenright}%
dd74d0a56df9 * empty log message * nipkow parents: diff changeset	226	\begin{isamarkuptxt}%
dd74d0a56df9 * empty log message * nipkow parents: diff changeset	227	\noindent
dd74d0a56df9 * empty log message * nipkow parents: diff changeset	228	This substitution step worked nicely because there was just a single
dd74d0a56df9 * empty log message * nipkow parents: diff changeset	229	occurrence of a term of type \isa{three}, namely \isa{x}.
11196 bb4ede27fcb7 * empty log message * nipkow parents: 11149 diff changeset	230	When we now apply \isa{cases{\isacharunderscore}lemma}, \isa{Q} becomes \isa{{\isasymlambda}n{\isachardot}\ P\ {\isacharparenleft}Abs{\isacharunderscore}three\ n{\isacharparenright}} because \isa{Rep{\isacharunderscore}three\ x} is the only term of type \isa{nat}:%
10366 dd74d0a56df9 * empty log message * nipkow parents: diff changeset	231	\end{isamarkuptxt}%
dd74d0a56df9 * empty log message * nipkow parents: diff changeset	232	\isacommand{apply}{\isacharparenleft}rule\ cases{\isacharunderscore}lemma{\isacharparenright}%
dd74d0a56df9 * empty log message * nipkow parents: diff changeset	233	\begin{isamarkuptxt}%
dd74d0a56df9 * empty log message * nipkow parents: diff changeset	234	\begin{isabelle}%
10696 76d7f6c9a14c * empty log message * nipkow parents: 10668 diff changeset	235	\ {\isadigit{1}}{\isachardot}\ {\isasymlbrakk}P\ A{\isacharsemicolon}\ P\ B{\isacharsemicolon}\ P\ C{\isasymrbrakk}\ {\isasymLongrightarrow}\ P\ {\isacharparenleft}Abs{\isacharunderscore}three\ {\isadigit{0}}{\isacharparenright}\isanewline
76d7f6c9a14c * empty log message * nipkow parents: 10668 diff changeset	236	\ {\isadigit{2}}{\isachardot}\ {\isasymlbrakk}P\ A{\isacharsemicolon}\ P\ B{\isacharsemicolon}\ P\ C{\isasymrbrakk}\ {\isasymLongrightarrow}\ P\ {\isacharparenleft}Abs{\isacharunderscore}three\ {\isadigit{1}}{\isacharparenright}\isanewline
76d7f6c9a14c * empty log message * nipkow parents: 10668 diff changeset	237	\ {\isadigit{3}}{\isachardot}\ {\isasymlbrakk}P\ A{\isacharsemicolon}\ P\ B{\isacharsemicolon}\ P\ C{\isasymrbrakk}\ {\isasymLongrightarrow}\ P\ {\isacharparenleft}Abs{\isacharunderscore}three\ {\isadigit{2}}{\isacharparenright}\isanewline
76d7f6c9a14c * empty log message * nipkow parents: 10668 diff changeset	238	\ {\isadigit{4}}{\isachardot}\ {\isasymlbrakk}P\ A{\isacharsemicolon}\ P\ B{\isacharsemicolon}\ P\ C{\isasymrbrakk}\ {\isasymLongrightarrow}\ Rep{\isacharunderscore}three\ x\ {\isasymin}\ three%
10366 dd74d0a56df9 * empty log message * nipkow parents: diff changeset	239	\end{isabelle}
dd74d0a56df9 * empty log message * nipkow parents: diff changeset	240	The resulting subgoals are easily solved by simplification:%
dd74d0a56df9 * empty log message * nipkow parents: diff changeset	241	\end{isamarkuptxt}%
dd74d0a56df9 * empty log message * nipkow parents: diff changeset	242	\isacommand{apply}{\isacharparenleft}simp{\isacharunderscore}all\ add{\isacharcolon}A{\isacharunderscore}def\ B{\isacharunderscore}def\ C{\isacharunderscore}def\ Rep{\isacharunderscore}three{\isacharparenright}\isanewline
dd74d0a56df9 * empty log message * nipkow parents: diff changeset	243	\isacommand{done}%
dd74d0a56df9 * empty log message * nipkow parents: diff changeset	244	\begin{isamarkuptext}%
dd74d0a56df9 * empty log message * nipkow parents: diff changeset	245	\noindent
dd74d0a56df9 * empty log message * nipkow parents: diff changeset	246	This concludes the derivation of the characteristic theorems for
dd74d0a56df9 * empty log message * nipkow parents: diff changeset	247	type \isa{three}.
dd74d0a56df9 * empty log message * nipkow parents: diff changeset	248
dd74d0a56df9 * empty log message * nipkow parents: diff changeset	249	The attentive reader has realized long ago that the
dd74d0a56df9 * empty log message * nipkow parents: diff changeset	250	above lengthy definition can be collapsed into one line:%
dd74d0a56df9 * empty log message * nipkow parents: diff changeset	251	\end{isamarkuptext}%
dd74d0a56df9 * empty log message * nipkow parents: diff changeset	252	\isacommand{datatype}\ three{\isacharprime}\ {\isacharequal}\ A\ {\isacharbar}\ B\ {\isacharbar}\ C%
dd74d0a56df9 * empty log message * nipkow parents: diff changeset	253	\begin{isamarkuptext}%
dd74d0a56df9 * empty log message * nipkow parents: diff changeset	254	\noindent
dd74d0a56df9 * empty log message * nipkow parents: diff changeset	255	In fact, the \isacommand{datatype} command performs internally more or less
dd74d0a56df9 * empty log message * nipkow parents: diff changeset	256	the same derivations as we did, which gives you some idea what life would be
dd74d0a56df9 * empty log message * nipkow parents: diff changeset	257	like without \isacommand{datatype}.
dd74d0a56df9 * empty log message * nipkow parents: diff changeset	258
dd74d0a56df9 * empty log message * nipkow parents: diff changeset	259	Although \isa{three} could be defined in one line, we have chosen this
dd74d0a56df9 * empty log message * nipkow parents: diff changeset	260	example to demonstrate \isacommand{typedef} because its simplicity makes the
dd74d0a56df9 * empty log message * nipkow parents: diff changeset	261	key concepts particularly easy to grasp. If you would like to see a
11149 e258b536a137 * empty log message * nipkow parents: 10983 diff changeset	262	non-trivial example that cannot be defined more directly, we recommend the
10878 b254d5ad6dd4 auto update paulson parents: 10777 diff changeset	263	definition of \emph{finite multisets} in the HOL Library.
10366 dd74d0a56df9 * empty log message * nipkow parents: diff changeset	264
dd74d0a56df9 * empty log message * nipkow parents: diff changeset	265	Let us conclude by summarizing the above procedure for defining a new type.
dd74d0a56df9 * empty log message * nipkow parents: diff changeset	266	Given some abstract axiomatic description $P$ of a type $ty$ in terms of a
dd74d0a56df9 * empty log message * nipkow parents: diff changeset	267	set of functions $F$, this involves three steps:
dd74d0a56df9 * empty log message * nipkow parents: diff changeset	268	\begin{enumerate}
dd74d0a56df9 * empty log message * nipkow parents: diff changeset	269	\item Find an appropriate type $\tau$ and subset $A$ which has the desired
dd74d0a56df9 * empty log message * nipkow parents: diff changeset	270	properties $P$, and make a type definition based on this representation.
dd74d0a56df9 * empty log message * nipkow parents: diff changeset	271	\item Define the required functions $F$ on $ty$ by lifting
dd74d0a56df9 * empty log message * nipkow parents: diff changeset	272	analogous functions on the representation via $Abs_ty$ and $Rep_ty$.
dd74d0a56df9 * empty log message * nipkow parents: diff changeset	273	\item Prove that $P$ holds for $ty$ by lifting $P$ from the representation.
dd74d0a56df9 * empty log message * nipkow parents: diff changeset	274	\end{enumerate}
dd74d0a56df9 * empty log message * nipkow parents: diff changeset	275	You can now forget about the representation and work solely in terms of the
dd74d0a56df9 * empty log message * nipkow parents: diff changeset	276	abstract functions $F$ and properties $P$.%
dd74d0a56df9 * empty log message * nipkow parents: diff changeset	277	\end{isamarkuptext}%
dd74d0a56df9 * empty log message * nipkow parents: diff changeset	278	\end{isabellebody}%
dd74d0a56df9 * empty log message * nipkow parents: diff changeset	279	%%% Local Variables:
dd74d0a56df9 * empty log message * nipkow parents: diff changeset	280	%%% mode: latex
dd74d0a56df9 * empty log message * nipkow parents: diff changeset	281	%%% TeX-master: "root"
dd74d0a56df9 * empty log message * nipkow parents: diff changeset	282	%%% End:

author	nipkow
	Fri, 18 May 2001 16:45:55 +0200
changeset 11308	b28bbb153603
parent 11277	a2bff98d6e5d
child 11428	332347b9b942
permissions	-rw-r--r--