isabelle: doc-src/Logics/CTT.tex@96c627d2815e (annotated)

104 d8205bb279a7 Initial revision lcp parents: diff changeset	1	%% $Id$
d8205bb279a7 Initial revision lcp parents: diff changeset	2	\chapter{Constructive Type Theory}
d8205bb279a7 Initial revision lcp parents: diff changeset	3	Martin-L\"of's Constructive Type Theory \cite{martinlof84,nordstrom90} can
d8205bb279a7 Initial revision lcp parents: diff changeset	4	be viewed at many different levels. It is a formal system that embodies
d8205bb279a7 Initial revision lcp parents: diff changeset	5	the principles of intuitionistic mathematics; it embodies the
d8205bb279a7 Initial revision lcp parents: diff changeset	6	interpretation of propositions as types; it is a vehicle for deriving
d8205bb279a7 Initial revision lcp parents: diff changeset	7	programs from proofs. The logic is complex and many authors have attempted
d8205bb279a7 Initial revision lcp parents: diff changeset	8	to simplify it. Thompson~\cite{thompson91} is a readable and thorough
d8205bb279a7 Initial revision lcp parents: diff changeset	9	account of the theory.
d8205bb279a7 Initial revision lcp parents: diff changeset	10
d8205bb279a7 Initial revision lcp parents: diff changeset	11	Isabelle's original formulation of Type Theory was a kind of sequent
d8205bb279a7 Initial revision lcp parents: diff changeset	12	calculus, following Martin-L\"of~\cite{martinlof84}. It included rules for
d8205bb279a7 Initial revision lcp parents: diff changeset	13	building the context, namely variable bindings with their types. A typical
d8205bb279a7 Initial revision lcp parents: diff changeset	14	judgement was
d8205bb279a7 Initial revision lcp parents: diff changeset	15	\[ a(x@1,\ldots,x@n)\in A(x@1,\ldots,x@n) \;
d8205bb279a7 Initial revision lcp parents: diff changeset	16	[ x@1\in A@1, x@2\in A@2(x@1), \ldots, x@n\in A@n(x@1,\ldots,x@{n-1}) ]
d8205bb279a7 Initial revision lcp parents: diff changeset	17	\]
d8205bb279a7 Initial revision lcp parents: diff changeset	18	This sequent calculus was not satisfactory because assumptions like
d8205bb279a7 Initial revision lcp parents: diff changeset	19	`suppose $A$ is a type' or `suppose $B(x)$ is a type for all $x$ in $A$'
d8205bb279a7 Initial revision lcp parents: diff changeset	20	could not be formalized.
d8205bb279a7 Initial revision lcp parents: diff changeset	21
d8205bb279a7 Initial revision lcp parents: diff changeset	22	The directory~\ttindexbold{CTT} implements Constructive Type Theory, using
d8205bb279a7 Initial revision lcp parents: diff changeset	23	natural deduction. The judgement above is expressed using $\Forall$ and
d8205bb279a7 Initial revision lcp parents: diff changeset	24	$\Imp$:
d8205bb279a7 Initial revision lcp parents: diff changeset	25	\[ \begin{array}{r@{}l}
d8205bb279a7 Initial revision lcp parents: diff changeset	26	\Forall x@1\ldots x@n. &
111 1b3cddf41b2d Various updates for Isabelle-93 lcp parents: 104 diff changeset	27	\List{x@1\in A@1;
1b3cddf41b2d Various updates for Isabelle-93 lcp parents: 104 diff changeset	28	x@2\in A@2(x@1); \cdots \;
1b3cddf41b2d Various updates for Isabelle-93 lcp parents: 104 diff changeset	29	x@n\in A@n(x@1,\ldots,x@{n-1})} \Imp \\
104 d8205bb279a7 Initial revision lcp parents: diff changeset	30	& \qquad\qquad a(x@1,\ldots,x@n)\in A(x@1,\ldots,x@n)
d8205bb279a7 Initial revision lcp parents: diff changeset	31	\end{array}
d8205bb279a7 Initial revision lcp parents: diff changeset	32	\]
d8205bb279a7 Initial revision lcp parents: diff changeset	33	Assumptions can use all the judgement forms, for instance to express that
d8205bb279a7 Initial revision lcp parents: diff changeset	34	$B$ is a family of types over~$A$:
d8205bb279a7 Initial revision lcp parents: diff changeset	35	\[ \Forall x . x\in A \Imp B(x)\;{\rm type} \]
d8205bb279a7 Initial revision lcp parents: diff changeset	36	To justify the {\CTT} formulation it is probably best to appeal directly
d8205bb279a7 Initial revision lcp parents: diff changeset	37	to the semantic explanations of the rules~\cite{martinlof84}, rather than
d8205bb279a7 Initial revision lcp parents: diff changeset	38	to the rules themselves. The order of assumptions no longer matters,
d8205bb279a7 Initial revision lcp parents: diff changeset	39	unlike in standard Type Theory. Contexts, which are typical of many modern
d8205bb279a7 Initial revision lcp parents: diff changeset	40	type theories, are difficult to represent in Isabelle. In particular, it
d8205bb279a7 Initial revision lcp parents: diff changeset	41	is difficult to enforce that all the variables in a context are distinct.
d8205bb279a7 Initial revision lcp parents: diff changeset	42
d8205bb279a7 Initial revision lcp parents: diff changeset	43	The theory has the {\ML} identifier \ttindexbold{CTT.thy}. It does not
d8205bb279a7 Initial revision lcp parents: diff changeset	44	use polymorphism. Terms in {\CTT} have type~$i$, the type of individuals.
d8205bb279a7 Initial revision lcp parents: diff changeset	45	Types in {\CTT} have type~$t$.
d8205bb279a7 Initial revision lcp parents: diff changeset	46
d8205bb279a7 Initial revision lcp parents: diff changeset	47	{\CTT} supports all of Type Theory apart from list types, well ordering
d8205bb279a7 Initial revision lcp parents: diff changeset	48	types, and universes. Universes could be introduced {\em\`a la Tarski},
d8205bb279a7 Initial revision lcp parents: diff changeset	49	adding new constants as names for types. The formulation {\em\`a la
d8205bb279a7 Initial revision lcp parents: diff changeset	50	Russell}, where types denote themselves, is only possible if we identify
d8205bb279a7 Initial revision lcp parents: diff changeset	51	the meta-types~$i$ and~$o$. Most published formulations of well ordering
d8205bb279a7 Initial revision lcp parents: diff changeset	52	types have difficulties involving extensionality of functions; I suggest
d8205bb279a7 Initial revision lcp parents: diff changeset	53	that you use some other method for defining recursive types. List types
d8205bb279a7 Initial revision lcp parents: diff changeset	54	are easy to introduce by declaring new rules.
d8205bb279a7 Initial revision lcp parents: diff changeset	55
d8205bb279a7 Initial revision lcp parents: diff changeset	56	{\CTT} uses the 1982 version of Type Theory, with extensional equality.
d8205bb279a7 Initial revision lcp parents: diff changeset	57	The computation $a=b\in A$ and the equality $c\in Eq(A,a,b)$ are
d8205bb279a7 Initial revision lcp parents: diff changeset	58	interchangeable. Its rewriting tactics prove theorems of the form $a=b\in
d8205bb279a7 Initial revision lcp parents: diff changeset	59	A$. It could be modified to have intensional equality, but rewriting
d8205bb279a7 Initial revision lcp parents: diff changeset	60	tactics would have to prove theorems of the form $c\in Eq(A,a,b)$ and the
d8205bb279a7 Initial revision lcp parents: diff changeset	61	computation rules might require a second simplifier.
d8205bb279a7 Initial revision lcp parents: diff changeset	62
d8205bb279a7 Initial revision lcp parents: diff changeset	63
d8205bb279a7 Initial revision lcp parents: diff changeset	64	\begin{figure} \tabcolsep=1em %wider spacing in tables
d8205bb279a7 Initial revision lcp parents: diff changeset	65	\begin{center}
d8205bb279a7 Initial revision lcp parents: diff changeset	66	\begin{tabular}{rrr}
111 1b3cddf41b2d Various updates for Isabelle-93 lcp parents: 104 diff changeset	67	\it symbol & \it meta-type & \it description \\
1b3cddf41b2d Various updates for Isabelle-93 lcp parents: 104 diff changeset	68	\idx{Type} & $t \to prop$ & judgement form \\
1b3cddf41b2d Various updates for Isabelle-93 lcp parents: 104 diff changeset	69	\idx{Eqtype} & $[t,t]\to prop$ & judgement form\\
1b3cddf41b2d Various updates for Isabelle-93 lcp parents: 104 diff changeset	70	\idx{Elem} & $[i, t]\to prop$ & judgement form\\
1b3cddf41b2d Various updates for Isabelle-93 lcp parents: 104 diff changeset	71	\idx{Eqelem} & $[i, i, t]\to prop$ & judgement form\\
1b3cddf41b2d Various updates for Isabelle-93 lcp parents: 104 diff changeset	72	\idx{Reduce} & $[i, i]\to prop$ & extra judgement form\\[2ex]
104 d8205bb279a7 Initial revision lcp parents: diff changeset	73
111 1b3cddf41b2d Various updates for Isabelle-93 lcp parents: 104 diff changeset	74	\idx{N} & $t$ & natural numbers type\\
1b3cddf41b2d Various updates for Isabelle-93 lcp parents: 104 diff changeset	75	\idx{0} & $i$ & constructor\\
1b3cddf41b2d Various updates for Isabelle-93 lcp parents: 104 diff changeset	76	\idx{succ} & $i\to i$ & constructor\\
104 d8205bb279a7 Initial revision lcp parents: diff changeset	77	\idx{rec} & $[i,i,[i,i]\to i]\to i$ & eliminator\\[2ex]
111 1b3cddf41b2d Various updates for Isabelle-93 lcp parents: 104 diff changeset	78	\idx{Prod} & $[t,i\to t]\to t$ & general product type\\
1b3cddf41b2d Various updates for Isabelle-93 lcp parents: 104 diff changeset	79	\idx{lambda} & $(i\to i)\to i$ & constructor\\[2ex]
1b3cddf41b2d Various updates for Isabelle-93 lcp parents: 104 diff changeset	80	\idx{Sum} & $[t, i\to t]\to t$ & general sum type\\
1b3cddf41b2d Various updates for Isabelle-93 lcp parents: 104 diff changeset	81	\idx{pair} & $[i,i]\to i$ & constructor\\
1b3cddf41b2d Various updates for Isabelle-93 lcp parents: 104 diff changeset	82	\idx{split} & $[i,[i,i]\to i]\to i$ & eliminator\\
1b3cddf41b2d Various updates for Isabelle-93 lcp parents: 104 diff changeset	83	\idx{fst} snd & $i\to i$ & projections\\[2ex]
1b3cddf41b2d Various updates for Isabelle-93 lcp parents: 104 diff changeset	84	\idx{inl} inr & $i\to i$ & constructors for $+$\\
104 d8205bb279a7 Initial revision lcp parents: diff changeset	85	\idx{when} & $[i,i\to i, i\to i]\to i$ & eliminator for $+$\\[2ex]
111 1b3cddf41b2d Various updates for Isabelle-93 lcp parents: 104 diff changeset	86	\idx{Eq} & $[t,i,i]\to t$ & equality type\\
1b3cddf41b2d Various updates for Isabelle-93 lcp parents: 104 diff changeset	87	\idx{eq} & $i$ & constructor\\[2ex]
1b3cddf41b2d Various updates for Isabelle-93 lcp parents: 104 diff changeset	88	\idx{F} & $t$ & empty type\\
1b3cddf41b2d Various updates for Isabelle-93 lcp parents: 104 diff changeset	89	\idx{contr} & $i\to i$ & eliminator\\[2ex]
1b3cddf41b2d Various updates for Isabelle-93 lcp parents: 104 diff changeset	90	\idx{T} & $t$ & singleton type\\
1b3cddf41b2d Various updates for Isabelle-93 lcp parents: 104 diff changeset	91	\idx{tt} & $i$ & constructor
104 d8205bb279a7 Initial revision lcp parents: diff changeset	92	\end{tabular}
d8205bb279a7 Initial revision lcp parents: diff changeset	93	\end{center}
d8205bb279a7 Initial revision lcp parents: diff changeset	94	\caption{The constants of {\CTT}} \label{ctt-constants}
d8205bb279a7 Initial revision lcp parents: diff changeset	95	\end{figure}
d8205bb279a7 Initial revision lcp parents: diff changeset	96
d8205bb279a7 Initial revision lcp parents: diff changeset	97
d8205bb279a7 Initial revision lcp parents: diff changeset	98	\begin{figure} \tabcolsep=1em %wider spacing in tables
d8205bb279a7 Initial revision lcp parents: diff changeset	99	\begin{center}
d8205bb279a7 Initial revision lcp parents: diff changeset	100	\begin{tabular}{llrrr}
111 1b3cddf41b2d Various updates for Isabelle-93 lcp parents: 104 diff changeset	101	\it symbol &\it name &\it meta-type & \it precedence & \it description \\
104 d8205bb279a7 Initial revision lcp parents: diff changeset	102	\idx{lam} & \idx{lambda} & $(i\To o)\To i$ & 10 & $\lambda$-abstraction
d8205bb279a7 Initial revision lcp parents: diff changeset	103	\end{tabular}
d8205bb279a7 Initial revision lcp parents: diff changeset	104	\end{center}
d8205bb279a7 Initial revision lcp parents: diff changeset	105	\subcaption{Binders}
d8205bb279a7 Initial revision lcp parents: diff changeset	106
d8205bb279a7 Initial revision lcp parents: diff changeset	107	\begin{center}
d8205bb279a7 Initial revision lcp parents: diff changeset	108	\indexbold{*"`}
d8205bb279a7 Initial revision lcp parents: diff changeset	109	\indexbold{*"+}
d8205bb279a7 Initial revision lcp parents: diff changeset	110	\begin{tabular}{rrrr}
d8205bb279a7 Initial revision lcp parents: diff changeset	111	\it symbol & \it meta-type & \it precedence & \it description \\
111 1b3cddf41b2d Various updates for Isabelle-93 lcp parents: 104 diff changeset	112	\tt ` & $[i,i]\to i$ & Left 55 & function application\\
1b3cddf41b2d Various updates for Isabelle-93 lcp parents: 104 diff changeset	113	\tt + & $[t,t]\to t$ & Right 30 & sum of two types
104 d8205bb279a7 Initial revision lcp parents: diff changeset	114	\end{tabular}
d8205bb279a7 Initial revision lcp parents: diff changeset	115	\end{center}
d8205bb279a7 Initial revision lcp parents: diff changeset	116	\subcaption{Infixes}
d8205bb279a7 Initial revision lcp parents: diff changeset	117
d8205bb279a7 Initial revision lcp parents: diff changeset	118	\indexbold{"}
d8205bb279a7 Initial revision lcp parents: diff changeset	119	\indexbold{*"-"-">}
d8205bb279a7 Initial revision lcp parents: diff changeset	120	\begin{center} \tt\frenchspacing
d8205bb279a7 Initial revision lcp parents: diff changeset	121	\begin{tabular}{rrr}
111 1b3cddf41b2d Various updates for Isabelle-93 lcp parents: 104 diff changeset	122	\it external & \it internal & \it standard notation \\
1b3cddf41b2d Various updates for Isabelle-93 lcp parents: 104 diff changeset	123	\idx{PROD} $x$:$A$ . $B[x]$ & Prod($A$, $\lambda x.B[x]$) &
1b3cddf41b2d Various updates for Isabelle-93 lcp parents: 104 diff changeset	124	\rm product $\prod@{x\in A}B[x]$ \\
1b3cddf41b2d Various updates for Isabelle-93 lcp parents: 104 diff changeset	125	\idx{SUM} $x$:$A$ . $B[x]$ & Sum($A$, $\lambda x.B[x]$) &
1b3cddf41b2d Various updates for Isabelle-93 lcp parents: 104 diff changeset	126	\rm sum $\sum@{x\in A}B[x]$ \\
104 d8205bb279a7 Initial revision lcp parents: diff changeset	127	$A$ --> $B$ & Prod($A$, $\lambda x.B$) &
111 1b3cddf41b2d Various updates for Isabelle-93 lcp parents: 104 diff changeset	128	\rm function space $A\to B$ \\
104 d8205bb279a7 Initial revision lcp parents: diff changeset	129	$A$ * $B$ & Sum($A$, $\lambda x.B$) &
111 1b3cddf41b2d Various updates for Isabelle-93 lcp parents: 104 diff changeset	130	\rm binary product $A\times B$
104 d8205bb279a7 Initial revision lcp parents: diff changeset	131	\end{tabular}
d8205bb279a7 Initial revision lcp parents: diff changeset	132	\end{center}
d8205bb279a7 Initial revision lcp parents: diff changeset	133	\subcaption{Translations}
d8205bb279a7 Initial revision lcp parents: diff changeset	134
d8205bb279a7 Initial revision lcp parents: diff changeset	135	\indexbold{*"=}
d8205bb279a7 Initial revision lcp parents: diff changeset	136	\begin{center}
d8205bb279a7 Initial revision lcp parents: diff changeset	137	\dquotes
d8205bb279a7 Initial revision lcp parents: diff changeset	138	\[ \begin{array}{rcl}
111 1b3cddf41b2d Various updates for Isabelle-93 lcp parents: 104 diff changeset	139	prop & = & type " type" \\
1b3cddf41b2d Various updates for Isabelle-93 lcp parents: 104 diff changeset	140	& \| & type " = " type \\
1b3cddf41b2d Various updates for Isabelle-93 lcp parents: 104 diff changeset	141	& \| & term " : " type \\
1b3cddf41b2d Various updates for Isabelle-93 lcp parents: 104 diff changeset	142	& \| & term " = " term " : " type
104 d8205bb279a7 Initial revision lcp parents: diff changeset	143	\\[2ex]
111 1b3cddf41b2d Various updates for Isabelle-93 lcp parents: 104 diff changeset	144	type & = & \hbox{expression of type~$t$} \\
1b3cddf41b2d Various updates for Isabelle-93 lcp parents: 104 diff changeset	145	& \| & "PROD~" id " : " type " . " type \\
1b3cddf41b2d Various updates for Isabelle-93 lcp parents: 104 diff changeset	146	& \| & "SUM~~" id " : " type " . " type
104 d8205bb279a7 Initial revision lcp parents: diff changeset	147	\\[2ex]
111 1b3cddf41b2d Various updates for Isabelle-93 lcp parents: 104 diff changeset	148	term & = & \hbox{expression of type~$i$} \\
1b3cddf41b2d Various updates for Isabelle-93 lcp parents: 104 diff changeset	149	& \| & "lam " id~id^* " . " term \\
1b3cddf41b2d Various updates for Isabelle-93 lcp parents: 104 diff changeset	150	& \| & "< " term " , " term " >"
104 d8205bb279a7 Initial revision lcp parents: diff changeset	151	\end{array}
d8205bb279a7 Initial revision lcp parents: diff changeset	152	\]
d8205bb279a7 Initial revision lcp parents: diff changeset	153	\end{center}
d8205bb279a7 Initial revision lcp parents: diff changeset	154	\subcaption{Grammar}
d8205bb279a7 Initial revision lcp parents: diff changeset	155	\caption{Syntax of {\CTT}} \label{ctt-syntax}
d8205bb279a7 Initial revision lcp parents: diff changeset	156	\end{figure}
d8205bb279a7 Initial revision lcp parents: diff changeset	157
d8205bb279a7 Initial revision lcp parents: diff changeset	158	%%%%\section{Generic Packages} typedsimp.ML????????????????
d8205bb279a7 Initial revision lcp parents: diff changeset	159
d8205bb279a7 Initial revision lcp parents: diff changeset	160
d8205bb279a7 Initial revision lcp parents: diff changeset	161	\section{Syntax}
d8205bb279a7 Initial revision lcp parents: diff changeset	162	The constants are shown in Figure~\ref{ctt-constants}. The infixes include
d8205bb279a7 Initial revision lcp parents: diff changeset	163	the function application operator (sometimes called `apply'), and the
d8205bb279a7 Initial revision lcp parents: diff changeset	164	2-place type operators. Note that meta-level abstraction and application,
d8205bb279a7 Initial revision lcp parents: diff changeset	165	$\lambda x.b$ and $f(a)$, differ from object-level abstraction and
d8205bb279a7 Initial revision lcp parents: diff changeset	166	application, \hbox{\tt lam $x$.$b$} and $b{\tt`}a$. A {\CTT}
d8205bb279a7 Initial revision lcp parents: diff changeset	167	function~$f$ is simply an individual as far as Isabelle is concerned: its
d8205bb279a7 Initial revision lcp parents: diff changeset	168	Isabelle type is~$i$, not say $i\To i$.
d8205bb279a7 Initial revision lcp parents: diff changeset	169
d8205bb279a7 Initial revision lcp parents: diff changeset	170	\indexbold{F}\indexbold{T}\indexbold{SUM}\indexbold{PROD}
d8205bb279a7 Initial revision lcp parents: diff changeset	171	The empty type is called $F$ and the one-element type is $T$; other finite
d8205bb279a7 Initial revision lcp parents: diff changeset	172	sets are built as $T+T+T$, etc. The notation for~{\CTT}
d8205bb279a7 Initial revision lcp parents: diff changeset	173	(Figure~\ref{ctt-syntax}) is based on that of Nordstr\"om et
d8205bb279a7 Initial revision lcp parents: diff changeset	174	al.~\cite{nordstrom90}. We can write
d8205bb279a7 Initial revision lcp parents: diff changeset	175	\begin{ttbox}
d8205bb279a7 Initial revision lcp parents: diff changeset	176	SUM y:B. PROD x:A. C(x,y) {\rm for} Sum(B, %y. Prod(A, %x. C(x,y)))
d8205bb279a7 Initial revision lcp parents: diff changeset	177	\end{ttbox}
d8205bb279a7 Initial revision lcp parents: diff changeset	178	The special cases as \hbox{\tt$A$*$B$} and \hbox{\tt$A$-->$B$} abbreviate
d8205bb279a7 Initial revision lcp parents: diff changeset	179	general sums and products over a constant family.\footnote{Unlike normal
d8205bb279a7 Initial revision lcp parents: diff changeset	180	infix operators, {\tt*} and {\tt-->} merely define abbreviations; there are
d8205bb279a7 Initial revision lcp parents: diff changeset	181	no constants~{\tt op~*} and~\hbox{\tt op~-->}.} Isabelle accepts these
d8205bb279a7 Initial revision lcp parents: diff changeset	182	abbreviations in parsing and uses them whenever possible for printing.
d8205bb279a7 Initial revision lcp parents: diff changeset	183
d8205bb279a7 Initial revision lcp parents: diff changeset	184
d8205bb279a7 Initial revision lcp parents: diff changeset	185	\begin{figure}
d8205bb279a7 Initial revision lcp parents: diff changeset	186	\begin{ttbox}
d8205bb279a7 Initial revision lcp parents: diff changeset	187	\idx{refl_type} A type ==> A = A
d8205bb279a7 Initial revision lcp parents: diff changeset	188	\idx{refl_elem} a : A ==> a = a : A
d8205bb279a7 Initial revision lcp parents: diff changeset	189
d8205bb279a7 Initial revision lcp parents: diff changeset	190	\idx{sym_type} A = B ==> B = A
d8205bb279a7 Initial revision lcp parents: diff changeset	191	\idx{sym_elem} a = b : A ==> b = a : A
d8205bb279a7 Initial revision lcp parents: diff changeset	192
d8205bb279a7 Initial revision lcp parents: diff changeset	193	\idx{trans_type} [\| A = B; B = C \|] ==> A = C
d8205bb279a7 Initial revision lcp parents: diff changeset	194	\idx{trans_elem} [\| a = b : A; b = c : A \|] ==> a = c : A
d8205bb279a7 Initial revision lcp parents: diff changeset	195
d8205bb279a7 Initial revision lcp parents: diff changeset	196	\idx{equal_types} [\| a : A; A = B \|] ==> a : B
d8205bb279a7 Initial revision lcp parents: diff changeset	197	\idx{equal_typesL} [\| a = b : A; A = B \|] ==> a = b : B
d8205bb279a7 Initial revision lcp parents: diff changeset	198
d8205bb279a7 Initial revision lcp parents: diff changeset	199	\idx{subst_type} [\| a : A; !!z. z:A ==> B(z) type \|] ==> B(a) type
d8205bb279a7 Initial revision lcp parents: diff changeset	200	\idx{subst_typeL} [\| a = c : A; !!z. z:A ==> B(z) = D(z)
d8205bb279a7 Initial revision lcp parents: diff changeset	201	\|] ==> B(a) = D(c)
d8205bb279a7 Initial revision lcp parents: diff changeset	202
d8205bb279a7 Initial revision lcp parents: diff changeset	203	\idx{subst_elem} [\| a : A; !!z. z:A ==> b(z):B(z) \|] ==> b(a):B(a)
d8205bb279a7 Initial revision lcp parents: diff changeset	204	\idx{subst_elemL} [\| a = c : A; !!z. z:A ==> b(z) = d(z) : B(z)
d8205bb279a7 Initial revision lcp parents: diff changeset	205	\|] ==> b(a) = d(c) : B(a)
d8205bb279a7 Initial revision lcp parents: diff changeset	206
d8205bb279a7 Initial revision lcp parents: diff changeset	207	\idx{refl_red} Reduce(a,a)
d8205bb279a7 Initial revision lcp parents: diff changeset	208	\idx{red_if_equal} a = b : A ==> Reduce(a,b)
d8205bb279a7 Initial revision lcp parents: diff changeset	209	\idx{trans_red} [\| a = b : A; Reduce(b,c) \|] ==> a = c : A
d8205bb279a7 Initial revision lcp parents: diff changeset	210	\end{ttbox}
d8205bb279a7 Initial revision lcp parents: diff changeset	211	\caption{General equality rules} \label{ctt-equality}
d8205bb279a7 Initial revision lcp parents: diff changeset	212	\end{figure}
d8205bb279a7 Initial revision lcp parents: diff changeset	213
d8205bb279a7 Initial revision lcp parents: diff changeset	214
d8205bb279a7 Initial revision lcp parents: diff changeset	215	\begin{figure}
d8205bb279a7 Initial revision lcp parents: diff changeset	216	\begin{ttbox}
d8205bb279a7 Initial revision lcp parents: diff changeset	217	\idx{NF} N type
d8205bb279a7 Initial revision lcp parents: diff changeset	218
d8205bb279a7 Initial revision lcp parents: diff changeset	219	\idx{NI0} 0 : N
d8205bb279a7 Initial revision lcp parents: diff changeset	220	\idx{NI_succ} a : N ==> succ(a) : N
d8205bb279a7 Initial revision lcp parents: diff changeset	221	\idx{NI_succL} a = b : N ==> succ(a) = succ(b) : N
d8205bb279a7 Initial revision lcp parents: diff changeset	222
d8205bb279a7 Initial revision lcp parents: diff changeset	223	\idx{NE} [\| p: N; a: C(0);
d8205bb279a7 Initial revision lcp parents: diff changeset	224	!!u v. [\| u: N; v: C(u) \|] ==> b(u,v): C(succ(u))
d8205bb279a7 Initial revision lcp parents: diff changeset	225	\|] ==> rec(p, a, %u v.b(u,v)) : C(p)
d8205bb279a7 Initial revision lcp parents: diff changeset	226
d8205bb279a7 Initial revision lcp parents: diff changeset	227	\idx{NEL} [\| p = q : N; a = c : C(0);
d8205bb279a7 Initial revision lcp parents: diff changeset	228	!!u v. [\| u: N; v: C(u) \|] ==> b(u,v)=d(u,v): C(succ(u))
d8205bb279a7 Initial revision lcp parents: diff changeset	229	\|] ==> rec(p, a, %u v.b(u,v)) = rec(q,c,d) : C(p)
d8205bb279a7 Initial revision lcp parents: diff changeset	230
d8205bb279a7 Initial revision lcp parents: diff changeset	231	\idx{NC0} [\| a: C(0);
d8205bb279a7 Initial revision lcp parents: diff changeset	232	!!u v. [\| u: N; v: C(u) \|] ==> b(u,v): C(succ(u))
d8205bb279a7 Initial revision lcp parents: diff changeset	233	\|] ==> rec(0, a, %u v.b(u,v)) = a : C(0)
d8205bb279a7 Initial revision lcp parents: diff changeset	234
d8205bb279a7 Initial revision lcp parents: diff changeset	235	\idx{NC_succ} [\| p: N; a: C(0);
d8205bb279a7 Initial revision lcp parents: diff changeset	236	!!u v. [\| u: N; v: C(u) \|] ==> b(u,v): C(succ(u))
d8205bb279a7 Initial revision lcp parents: diff changeset	237	\|] ==> rec(succ(p), a, %u v.b(u,v)) =
d8205bb279a7 Initial revision lcp parents: diff changeset	238	b(p, rec(p, a, %u v.b(u,v))) : C(succ(p))
d8205bb279a7 Initial revision lcp parents: diff changeset	239
d8205bb279a7 Initial revision lcp parents: diff changeset	240	\idx{zero_ne_succ} [\| a: N; 0 = succ(a) : N \|] ==> 0: F
d8205bb279a7 Initial revision lcp parents: diff changeset	241	\end{ttbox}
d8205bb279a7 Initial revision lcp parents: diff changeset	242	\caption{Rules for type~$N$} \label{ctt-N}
d8205bb279a7 Initial revision lcp parents: diff changeset	243	\end{figure}
d8205bb279a7 Initial revision lcp parents: diff changeset	244
d8205bb279a7 Initial revision lcp parents: diff changeset	245
d8205bb279a7 Initial revision lcp parents: diff changeset	246	\begin{figure}
d8205bb279a7 Initial revision lcp parents: diff changeset	247	\begin{ttbox}
d8205bb279a7 Initial revision lcp parents: diff changeset	248	\idx{ProdF} [\| A type; !!x. x:A ==> B(x) type \|] ==> PROD x:A.B(x) type
d8205bb279a7 Initial revision lcp parents: diff changeset	249	\idx{ProdFL} [\| A = C; !!x. x:A ==> B(x) = D(x) \|] ==>
d8205bb279a7 Initial revision lcp parents: diff changeset	250	PROD x:A.B(x) = PROD x:C.D(x)
d8205bb279a7 Initial revision lcp parents: diff changeset	251
d8205bb279a7 Initial revision lcp parents: diff changeset	252	\idx{ProdI} [\| A type; !!x. x:A ==> b(x):B(x)
d8205bb279a7 Initial revision lcp parents: diff changeset	253	\|] ==> lam x.b(x) : PROD x:A.B(x)
d8205bb279a7 Initial revision lcp parents: diff changeset	254	\idx{ProdIL} [\| A type; !!x. x:A ==> b(x) = c(x) : B(x)
d8205bb279a7 Initial revision lcp parents: diff changeset	255	\|] ==> lam x.b(x) = lam x.c(x) : PROD x:A.B(x)
d8205bb279a7 Initial revision lcp parents: diff changeset	256
d8205bb279a7 Initial revision lcp parents: diff changeset	257	\idx{ProdE} [\| p : PROD x:A.B(x); a : A \|] ==> p`a : B(a)
d8205bb279a7 Initial revision lcp parents: diff changeset	258	\idx{ProdEL} [\| p=q: PROD x:A.B(x); a=b : A \|] ==> p`a = q`b : B(a)
d8205bb279a7 Initial revision lcp parents: diff changeset	259
d8205bb279a7 Initial revision lcp parents: diff changeset	260	\idx{ProdC} [\| a : A; !!x. x:A ==> b(x) : B(x)
d8205bb279a7 Initial revision lcp parents: diff changeset	261	\|] ==> (lam x.b(x)) ` a = b(a) : B(a)
d8205bb279a7 Initial revision lcp parents: diff changeset	262
d8205bb279a7 Initial revision lcp parents: diff changeset	263	\idx{ProdC2} p : PROD x:A.B(x) ==> (lam x. p`x) = p : PROD x:A.B(x)
d8205bb279a7 Initial revision lcp parents: diff changeset	264	\end{ttbox}
d8205bb279a7 Initial revision lcp parents: diff changeset	265	\caption{Rules for the product type $\prod@{x\in A}B[x]$} \label{ctt-prod}
d8205bb279a7 Initial revision lcp parents: diff changeset	266	\end{figure}
d8205bb279a7 Initial revision lcp parents: diff changeset	267
d8205bb279a7 Initial revision lcp parents: diff changeset	268
d8205bb279a7 Initial revision lcp parents: diff changeset	269	\begin{figure}
d8205bb279a7 Initial revision lcp parents: diff changeset	270	\begin{ttbox}
d8205bb279a7 Initial revision lcp parents: diff changeset	271	\idx{SumF} [\| A type; !!x. x:A ==> B(x) type \|] ==> SUM x:A.B(x) type
d8205bb279a7 Initial revision lcp parents: diff changeset	272	\idx{SumFL} [\| A = C; !!x. x:A ==> B(x) = D(x)
d8205bb279a7 Initial revision lcp parents: diff changeset	273	\|] ==> SUM x:A.B(x) = SUM x:C.D(x)
d8205bb279a7 Initial revision lcp parents: diff changeset	274
d8205bb279a7 Initial revision lcp parents: diff changeset	275	\idx{SumI} [\| a : A; b : B(a) \|] ==> <a,b> : SUM x:A.B(x)
d8205bb279a7 Initial revision lcp parents: diff changeset	276	\idx{SumIL} [\| a=c:A; b=d:B(a) \|] ==> <a,b> = <c,d> : SUM x:A.B(x)
d8205bb279a7 Initial revision lcp parents: diff changeset	277
d8205bb279a7 Initial revision lcp parents: diff changeset	278	\idx{SumE} [\| p: SUM x:A.B(x);
d8205bb279a7 Initial revision lcp parents: diff changeset	279	!!x y. [\| x:A; y:B(x) \|] ==> c(x,y): C(<x,y>)
d8205bb279a7 Initial revision lcp parents: diff changeset	280	\|] ==> split(p, %x y.c(x,y)) : C(p)
d8205bb279a7 Initial revision lcp parents: diff changeset	281
d8205bb279a7 Initial revision lcp parents: diff changeset	282	\idx{SumEL} [\| p=q : SUM x:A.B(x);
d8205bb279a7 Initial revision lcp parents: diff changeset	283	!!x y. [\| x:A; y:B(x) \|] ==> c(x,y)=d(x,y): C(<x,y>)
d8205bb279a7 Initial revision lcp parents: diff changeset	284	\|] ==> split(p, %x y.c(x,y)) = split(q, %x y.d(x,y)) : C(p)
d8205bb279a7 Initial revision lcp parents: diff changeset	285
d8205bb279a7 Initial revision lcp parents: diff changeset	286	\idx{SumC} [\| a: A; b: B(a);
d8205bb279a7 Initial revision lcp parents: diff changeset	287	!!x y. [\| x:A; y:B(x) \|] ==> c(x,y): C(<x,y>)
d8205bb279a7 Initial revision lcp parents: diff changeset	288	\|] ==> split(<a,b>, %x y.c(x,y)) = c(a,b) : C(<a,b>)
d8205bb279a7 Initial revision lcp parents: diff changeset	289
d8205bb279a7 Initial revision lcp parents: diff changeset	290	\idx{fst_def} fst(a) == split(a, %x y.x)
d8205bb279a7 Initial revision lcp parents: diff changeset	291	\idx{snd_def} snd(a) == split(a, %x y.y)
d8205bb279a7 Initial revision lcp parents: diff changeset	292	\end{ttbox}
d8205bb279a7 Initial revision lcp parents: diff changeset	293	\caption{Rules for the sum type $\sum@{x\in A}B[x]$} \label{ctt-sum}
d8205bb279a7 Initial revision lcp parents: diff changeset	294	\end{figure}
d8205bb279a7 Initial revision lcp parents: diff changeset	295
d8205bb279a7 Initial revision lcp parents: diff changeset	296
d8205bb279a7 Initial revision lcp parents: diff changeset	297	\begin{figure}
d8205bb279a7 Initial revision lcp parents: diff changeset	298	\begin{ttbox}
d8205bb279a7 Initial revision lcp parents: diff changeset	299	\idx{PlusF} [\| A type; B type \|] ==> A+B type
d8205bb279a7 Initial revision lcp parents: diff changeset	300	\idx{PlusFL} [\| A = C; B = D \|] ==> A+B = C+D
d8205bb279a7 Initial revision lcp parents: diff changeset	301
d8205bb279a7 Initial revision lcp parents: diff changeset	302	\idx{PlusI_inl} [\| a : A; B type \|] ==> inl(a) : A+B
d8205bb279a7 Initial revision lcp parents: diff changeset	303	\idx{PlusI_inlL} [\| a = c : A; B type \|] ==> inl(a) = inl(c) : A+B
d8205bb279a7 Initial revision lcp parents: diff changeset	304
d8205bb279a7 Initial revision lcp parents: diff changeset	305	\idx{PlusI_inr} [\| A type; b : B \|] ==> inr(b) : A+B
d8205bb279a7 Initial revision lcp parents: diff changeset	306	\idx{PlusI_inrL} [\| A type; b = d : B \|] ==> inr(b) = inr(d) : A+B
d8205bb279a7 Initial revision lcp parents: diff changeset	307
d8205bb279a7 Initial revision lcp parents: diff changeset	308	\idx{PlusE} [\| p: A+B;
d8205bb279a7 Initial revision lcp parents: diff changeset	309	!!x. x:A ==> c(x): C(inl(x));
d8205bb279a7 Initial revision lcp parents: diff changeset	310	!!y. y:B ==> d(y): C(inr(y))
d8205bb279a7 Initial revision lcp parents: diff changeset	311	\|] ==> when(p, %x.c(x), %y.d(y)) : C(p)
d8205bb279a7 Initial revision lcp parents: diff changeset	312
d8205bb279a7 Initial revision lcp parents: diff changeset	313	\idx{PlusEL} [\| p = q : A+B;
d8205bb279a7 Initial revision lcp parents: diff changeset	314	!!x. x: A ==> c(x) = e(x) : C(inl(x));
d8205bb279a7 Initial revision lcp parents: diff changeset	315	!!y. y: B ==> d(y) = f(y) : C(inr(y))
d8205bb279a7 Initial revision lcp parents: diff changeset	316	\|] ==> when(p, %x.c(x), %y.d(y)) =
d8205bb279a7 Initial revision lcp parents: diff changeset	317	when(q, %x.e(x), %y.f(y)) : C(p)
d8205bb279a7 Initial revision lcp parents: diff changeset	318
d8205bb279a7 Initial revision lcp parents: diff changeset	319	\idx{PlusC_inl} [\| a: A;
d8205bb279a7 Initial revision lcp parents: diff changeset	320	!!x. x:A ==> c(x): C(inl(x));
d8205bb279a7 Initial revision lcp parents: diff changeset	321	!!y. y:B ==> d(y): C(inr(y))
d8205bb279a7 Initial revision lcp parents: diff changeset	322	\|] ==> when(inl(a), %x.c(x), %y.d(y)) = c(a) : C(inl(a))
d8205bb279a7 Initial revision lcp parents: diff changeset	323
d8205bb279a7 Initial revision lcp parents: diff changeset	324	\idx{PlusC_inr} [\| b: B;
d8205bb279a7 Initial revision lcp parents: diff changeset	325	!!x. x:A ==> c(x): C(inl(x));
d8205bb279a7 Initial revision lcp parents: diff changeset	326	!!y. y:B ==> d(y): C(inr(y))
d8205bb279a7 Initial revision lcp parents: diff changeset	327	\|] ==> when(inr(b), %x.c(x), %y.d(y)) = d(b) : C(inr(b))
d8205bb279a7 Initial revision lcp parents: diff changeset	328	\end{ttbox}
d8205bb279a7 Initial revision lcp parents: diff changeset	329	\caption{Rules for the binary sum type $A+B$} \label{ctt-plus}
d8205bb279a7 Initial revision lcp parents: diff changeset	330	\end{figure}
d8205bb279a7 Initial revision lcp parents: diff changeset	331
d8205bb279a7 Initial revision lcp parents: diff changeset	332
d8205bb279a7 Initial revision lcp parents: diff changeset	333	\begin{figure}
d8205bb279a7 Initial revision lcp parents: diff changeset	334	\begin{ttbox}
d8205bb279a7 Initial revision lcp parents: diff changeset	335	\idx{EqF} [\| A type; a : A; b : A \|] ==> Eq(A,a,b) type
d8205bb279a7 Initial revision lcp parents: diff changeset	336	\idx{EqFL} [\| A=B; a=c: A; b=d : A \|] ==> Eq(A,a,b) = Eq(B,c,d)
d8205bb279a7 Initial revision lcp parents: diff changeset	337	\idx{EqI} a = b : A ==> eq : Eq(A,a,b)
d8205bb279a7 Initial revision lcp parents: diff changeset	338	\idx{EqE} p : Eq(A,a,b) ==> a = b : A
d8205bb279a7 Initial revision lcp parents: diff changeset	339	\idx{EqC} p : Eq(A,a,b) ==> p = eq : Eq(A,a,b)
d8205bb279a7 Initial revision lcp parents: diff changeset	340	\end{ttbox}
d8205bb279a7 Initial revision lcp parents: diff changeset	341	\subcaption{The equality type $Eq(A,a,b)$}
d8205bb279a7 Initial revision lcp parents: diff changeset	342
d8205bb279a7 Initial revision lcp parents: diff changeset	343	\begin{ttbox}
d8205bb279a7 Initial revision lcp parents: diff changeset	344	\idx{FF} F type
d8205bb279a7 Initial revision lcp parents: diff changeset	345	\idx{FE} [\| p: F; C type \|] ==> contr(p) : C
d8205bb279a7 Initial revision lcp parents: diff changeset	346	\idx{FEL} [\| p = q : F; C type \|] ==> contr(p) = contr(q) : C
d8205bb279a7 Initial revision lcp parents: diff changeset	347	\end{ttbox}
d8205bb279a7 Initial revision lcp parents: diff changeset	348	\subcaption{The empty type $F$}
d8205bb279a7 Initial revision lcp parents: diff changeset	349
d8205bb279a7 Initial revision lcp parents: diff changeset	350	\begin{ttbox}
d8205bb279a7 Initial revision lcp parents: diff changeset	351	\idx{TF} T type
d8205bb279a7 Initial revision lcp parents: diff changeset	352	\idx{TI} tt : T
d8205bb279a7 Initial revision lcp parents: diff changeset	353	\idx{TE} [\| p : T; c : C(tt) \|] ==> c : C(p)
d8205bb279a7 Initial revision lcp parents: diff changeset	354	\idx{TEL} [\| p = q : T; c = d : C(tt) \|] ==> c = d : C(p)
d8205bb279a7 Initial revision lcp parents: diff changeset	355	\idx{TC} p : T ==> p = tt : T)
d8205bb279a7 Initial revision lcp parents: diff changeset	356	\end{ttbox}
d8205bb279a7 Initial revision lcp parents: diff changeset	357	\subcaption{The unit type $T$}
d8205bb279a7 Initial revision lcp parents: diff changeset	358
d8205bb279a7 Initial revision lcp parents: diff changeset	359	\caption{Rules for other {\CTT} types} \label{ctt-others}
d8205bb279a7 Initial revision lcp parents: diff changeset	360	\end{figure}
d8205bb279a7 Initial revision lcp parents: diff changeset	361
d8205bb279a7 Initial revision lcp parents: diff changeset	362
d8205bb279a7 Initial revision lcp parents: diff changeset	363
d8205bb279a7 Initial revision lcp parents: diff changeset	364	\begin{figure}
d8205bb279a7 Initial revision lcp parents: diff changeset	365	\begin{ttbox}
d8205bb279a7 Initial revision lcp parents: diff changeset	366	\idx{replace_type} [\| B = A; a : A \|] ==> a : B
d8205bb279a7 Initial revision lcp parents: diff changeset	367	\idx{subst_eqtyparg} [\| a=c : A; !!z. z:A ==> B(z) type \|] ==> B(a)=B(c)
d8205bb279a7 Initial revision lcp parents: diff changeset	368
d8205bb279a7 Initial revision lcp parents: diff changeset	369	\idx{subst_prodE} [\| p: Prod(A,B); a: A; !!z. z: B(a) ==> c(z): C(z)
d8205bb279a7 Initial revision lcp parents: diff changeset	370	\|] ==> c(p`a): C(p`a)
d8205bb279a7 Initial revision lcp parents: diff changeset	371
d8205bb279a7 Initial revision lcp parents: diff changeset	372	\idx{SumIL2} [\| c=a : A; d=b : B(a) \|] ==> <c,d> = <a,b> : Sum(A,B)
d8205bb279a7 Initial revision lcp parents: diff changeset	373
d8205bb279a7 Initial revision lcp parents: diff changeset	374	\idx{SumE_fst} p : Sum(A,B) ==> fst(p) : A
d8205bb279a7 Initial revision lcp parents: diff changeset	375
d8205bb279a7 Initial revision lcp parents: diff changeset	376	\idx{SumE_snd} [\| p: Sum(A,B); A type; !!x. x:A ==> B(x) type
d8205bb279a7 Initial revision lcp parents: diff changeset	377	\|] ==> snd(p) : B(fst(p))
d8205bb279a7 Initial revision lcp parents: diff changeset	378	\end{ttbox}
d8205bb279a7 Initial revision lcp parents: diff changeset	379
d8205bb279a7 Initial revision lcp parents: diff changeset	380	\caption{Derived rules for {\CTT}} \label{ctt-derived}
d8205bb279a7 Initial revision lcp parents: diff changeset	381	\end{figure}
d8205bb279a7 Initial revision lcp parents: diff changeset	382
d8205bb279a7 Initial revision lcp parents: diff changeset	383
d8205bb279a7 Initial revision lcp parents: diff changeset	384	\section{Rules of inference}
d8205bb279a7 Initial revision lcp parents: diff changeset	385	The rules obey the following naming conventions. Type formation rules have
d8205bb279a7 Initial revision lcp parents: diff changeset	386	the suffix~{\tt F}\@. Introduction rules have the suffix~{\tt I}\@.
d8205bb279a7 Initial revision lcp parents: diff changeset	387	Elimination rules have the suffix~{\tt E}\@. Computation rules, which
d8205bb279a7 Initial revision lcp parents: diff changeset	388	describe the reduction of eliminators, have the suffix~{\tt C}\@. The
d8205bb279a7 Initial revision lcp parents: diff changeset	389	equality versions of the rules (which permit reductions on subterms) are
d8205bb279a7 Initial revision lcp parents: diff changeset	390	called {\em long} rules; their names have the suffix~{\tt L}\@.
d8205bb279a7 Initial revision lcp parents: diff changeset	391	Introduction and computation rules often are further suffixed with
d8205bb279a7 Initial revision lcp parents: diff changeset	392	constructor names.
d8205bb279a7 Initial revision lcp parents: diff changeset	393
d8205bb279a7 Initial revision lcp parents: diff changeset	394	Figures~\ref{ctt-equality}--\ref{ctt-others} shows the rules. Those
d8205bb279a7 Initial revision lcp parents: diff changeset	395	for~$N$ include \ttindex{zero_ne_succ}, $0\not=n+1$: the fourth Peano axiom
d8205bb279a7 Initial revision lcp parents: diff changeset	396	cannot be derived without universes \cite[page 91]{martinlof84}.
d8205bb279a7 Initial revision lcp parents: diff changeset	397	Figure~\ref{ctt-sum} shows the rules for general sums, which include binary
d8205bb279a7 Initial revision lcp parents: diff changeset	398	products as a special case, with the projections \ttindex{fst}
d8205bb279a7 Initial revision lcp parents: diff changeset	399	and~\ttindex{snd}.
d8205bb279a7 Initial revision lcp parents: diff changeset	400
d8205bb279a7 Initial revision lcp parents: diff changeset	401	The extra judgement \ttindex{Reduce} is used to implement rewriting. The
d8205bb279a7 Initial revision lcp parents: diff changeset	402	judgement ${\tt Reduce}(a,b)$ holds when $a=b:A$ holds. It also holds
d8205bb279a7 Initial revision lcp parents: diff changeset	403	when $a$ and $b$ are syntactically identical, even if they are ill-typed,
d8205bb279a7 Initial revision lcp parents: diff changeset	404	because rule \ttindex{refl_red} does not verify that $a$ belongs to $A$. These
d8205bb279a7 Initial revision lcp parents: diff changeset	405	rules do not give rise to new theorems about the standard judgements ---
d8205bb279a7 Initial revision lcp parents: diff changeset	406	note that the only rule that makes use of {\tt Reduce} is \ttindex{trans_red},
d8205bb279a7 Initial revision lcp parents: diff changeset	407	whose first premise ensures that $a$ and $b$ (and thus $c$) are well-typed.
d8205bb279a7 Initial revision lcp parents: diff changeset	408
d8205bb279a7 Initial revision lcp parents: diff changeset	409	Derived rules are shown in Figure~\ref{ctt-derived}. The rule
d8205bb279a7 Initial revision lcp parents: diff changeset	410	\ttindex{subst_prodE} is derived from \ttindex{prodE}, and is easier to
d8205bb279a7 Initial revision lcp parents: diff changeset	411	use in backwards proof. The rules \ttindex{SumE_fst} and
d8205bb279a7 Initial revision lcp parents: diff changeset	412	\ttindex{SumE_snd} express the typing of~\ttindex{fst} and~\ttindex{snd};
d8205bb279a7 Initial revision lcp parents: diff changeset	413	together, they are roughly equivalent to~\ttindex{SumE} with the advantage
d8205bb279a7 Initial revision lcp parents: diff changeset	414	of creating no parameters. These rules are demonstrated in a proof of the
d8205bb279a7 Initial revision lcp parents: diff changeset	415	Axiom of Choice~(\S\ref{ctt-choice}).
d8205bb279a7 Initial revision lcp parents: diff changeset	416
d8205bb279a7 Initial revision lcp parents: diff changeset	417	All the rules are given in $\eta$-expanded form. For instance, every
d8205bb279a7 Initial revision lcp parents: diff changeset	418	occurrence of $\lambda u\,v.b(u,v)$ could be abbreviated to~$b$ in the
d8205bb279a7 Initial revision lcp parents: diff changeset	419	rules for~$N$. This permits Isabelle to preserve bound variable names
d8205bb279a7 Initial revision lcp parents: diff changeset	420	during backward proof. Names of bound variables in the conclusion (here,
d8205bb279a7 Initial revision lcp parents: diff changeset	421	$u$ and~$v$) are matched with corresponding bound variables in the premises.
d8205bb279a7 Initial revision lcp parents: diff changeset	422
d8205bb279a7 Initial revision lcp parents: diff changeset	423
d8205bb279a7 Initial revision lcp parents: diff changeset	424	\section{Rule lists}
d8205bb279a7 Initial revision lcp parents: diff changeset	425	The Type Theory tactics provide rewriting, type inference, and logical
d8205bb279a7 Initial revision lcp parents: diff changeset	426	reasoning. Many proof procedures work by repeatedly resolving certain Type
d8205bb279a7 Initial revision lcp parents: diff changeset	427	Theory rules against a proof state. {\CTT} defines lists --- each with
d8205bb279a7 Initial revision lcp parents: diff changeset	428	type
d8205bb279a7 Initial revision lcp parents: diff changeset	429	\hbox{\tt thm list} --- of related rules.
d8205bb279a7 Initial revision lcp parents: diff changeset	430	\begin{description}
d8205bb279a7 Initial revision lcp parents: diff changeset	431	\item[\ttindexbold{form_rls}]
d8205bb279a7 Initial revision lcp parents: diff changeset	432	contains formation rules for the types $N$, $\Pi$, $\Sigma$, $+$, $Eq$,
d8205bb279a7 Initial revision lcp parents: diff changeset	433	$F$, and $T$.
d8205bb279a7 Initial revision lcp parents: diff changeset	434
d8205bb279a7 Initial revision lcp parents: diff changeset	435	\item[\ttindexbold{formL_rls}]
d8205bb279a7 Initial revision lcp parents: diff changeset	436	contains long formation rules for $\Pi$, $\Sigma$, $+$, and $Eq$. (For
d8205bb279a7 Initial revision lcp parents: diff changeset	437	other types use \ttindex{refl_type}.)
d8205bb279a7 Initial revision lcp parents: diff changeset	438
d8205bb279a7 Initial revision lcp parents: diff changeset	439	\item[\ttindexbold{intr_rls}]
d8205bb279a7 Initial revision lcp parents: diff changeset	440	contains introduction rules for the types $N$, $\Pi$, $\Sigma$, $+$, and
d8205bb279a7 Initial revision lcp parents: diff changeset	441	$T$.
d8205bb279a7 Initial revision lcp parents: diff changeset	442
d8205bb279a7 Initial revision lcp parents: diff changeset	443	\item[\ttindexbold{intrL_rls}]
d8205bb279a7 Initial revision lcp parents: diff changeset	444	contains long introduction rules for $N$, $\Pi$, $\Sigma$, and $+$. (For
d8205bb279a7 Initial revision lcp parents: diff changeset	445	$T$ use \ttindex{refl_elem}.)
d8205bb279a7 Initial revision lcp parents: diff changeset	446
d8205bb279a7 Initial revision lcp parents: diff changeset	447	\item[\ttindexbold{elim_rls}]
d8205bb279a7 Initial revision lcp parents: diff changeset	448	contains elimination rules for the types $N$, $\Pi$, $\Sigma$, $+$, and
d8205bb279a7 Initial revision lcp parents: diff changeset	449	$F$. The rules for $Eq$ and $T$ are omitted because they involve no
d8205bb279a7 Initial revision lcp parents: diff changeset	450	eliminator.
d8205bb279a7 Initial revision lcp parents: diff changeset	451
d8205bb279a7 Initial revision lcp parents: diff changeset	452	\item[\ttindexbold{elimL_rls}]
d8205bb279a7 Initial revision lcp parents: diff changeset	453	contains long elimination rules for $N$, $\Pi$, $\Sigma$, $+$, and $F$.
d8205bb279a7 Initial revision lcp parents: diff changeset	454
d8205bb279a7 Initial revision lcp parents: diff changeset	455	\item[\ttindexbold{comp_rls}]
d8205bb279a7 Initial revision lcp parents: diff changeset	456	contains computation rules for the types $N$, $\Pi$, $\Sigma$, and $+$.
d8205bb279a7 Initial revision lcp parents: diff changeset	457	Those for $Eq$ and $T$ involve no eliminator.
d8205bb279a7 Initial revision lcp parents: diff changeset	458
d8205bb279a7 Initial revision lcp parents: diff changeset	459	\item[\ttindexbold{basic_defs}]
d8205bb279a7 Initial revision lcp parents: diff changeset	460	contains the definitions of \ttindex{fst} and \ttindex{snd}.
d8205bb279a7 Initial revision lcp parents: diff changeset	461	\end{description}
d8205bb279a7 Initial revision lcp parents: diff changeset	462
d8205bb279a7 Initial revision lcp parents: diff changeset	463
d8205bb279a7 Initial revision lcp parents: diff changeset	464	\section{Tactics for subgoal reordering}
d8205bb279a7 Initial revision lcp parents: diff changeset	465	\begin{ttbox}
d8205bb279a7 Initial revision lcp parents: diff changeset	466	test_assume_tac : int -> tactic
d8205bb279a7 Initial revision lcp parents: diff changeset	467	typechk_tac : thm list -> tactic
d8205bb279a7 Initial revision lcp parents: diff changeset	468	equal_tac : thm list -> tactic
d8205bb279a7 Initial revision lcp parents: diff changeset	469	intr_tac : thm list -> tactic
d8205bb279a7 Initial revision lcp parents: diff changeset	470	\end{ttbox}
d8205bb279a7 Initial revision lcp parents: diff changeset	471	Blind application of {\CTT} rules seldom leads to a proof. The elimination
d8205bb279a7 Initial revision lcp parents: diff changeset	472	rules, especially, create subgoals containing new unknowns. These subgoals
d8205bb279a7 Initial revision lcp parents: diff changeset	473	unify with anything, causing an undirectional search. The standard tactic
d8205bb279a7 Initial revision lcp parents: diff changeset	474	\ttindex{filt_resolve_tac} (see the {\em Reference Manual}) can reject
d8205bb279a7 Initial revision lcp parents: diff changeset	475	overly flexible goals; so does the {\CTT} tactic {\tt test_assume_tac}.
d8205bb279a7 Initial revision lcp parents: diff changeset	476	Used with the tactical \ttindex{REPEAT_FIRST} they achieve a simple kind of
d8205bb279a7 Initial revision lcp parents: diff changeset	477	subgoal reordering: the less flexible subgoals are attempted first. Do
d8205bb279a7 Initial revision lcp parents: diff changeset	478	some single step proofs, or study the examples below, to see why this is
d8205bb279a7 Initial revision lcp parents: diff changeset	479	necessary.
d8205bb279a7 Initial revision lcp parents: diff changeset	480	\begin{description}
d8205bb279a7 Initial revision lcp parents: diff changeset	481	\item[\ttindexbold{test_assume_tac} $i$]
d8205bb279a7 Initial revision lcp parents: diff changeset	482	uses \ttindex{assume_tac} to solve the subgoal by assumption, but only if
d8205bb279a7 Initial revision lcp parents: diff changeset	483	subgoal~$i$ has the form $a\in A$ and the head of $a$ is not an unknown.
d8205bb279a7 Initial revision lcp parents: diff changeset	484	Otherwise, it fails.
d8205bb279a7 Initial revision lcp parents: diff changeset	485
d8205bb279a7 Initial revision lcp parents: diff changeset	486	\item[\ttindexbold{typechk_tac} $thms$]
d8205bb279a7 Initial revision lcp parents: diff changeset	487	uses $thms$ with formation, introduction, and elimination rules to check
d8205bb279a7 Initial revision lcp parents: diff changeset	488	the typing of constructions. It is designed to solve goals of the form
d8205bb279a7 Initial revision lcp parents: diff changeset	489	$a\in \Var{A}$, where $a$ is rigid and $\Var{A}$ is flexible. Thus it
d8205bb279a7 Initial revision lcp parents: diff changeset	490	performs Hindley-Milner type inference. The tactic can also solve goals of
d8205bb279a7 Initial revision lcp parents: diff changeset	491	the form $A\;\rm type$.
d8205bb279a7 Initial revision lcp parents: diff changeset	492
d8205bb279a7 Initial revision lcp parents: diff changeset	493	\item[\ttindexbold{equal_tac} $thms$]
d8205bb279a7 Initial revision lcp parents: diff changeset	494	uses $thms$ with the long introduction and elimination rules to solve goals
d8205bb279a7 Initial revision lcp parents: diff changeset	495	of the form $a=b\in A$, where $a$ is rigid. It is intended for deriving
d8205bb279a7 Initial revision lcp parents: diff changeset	496	the long rules for defined constants such as the arithmetic operators. The
d8205bb279a7 Initial revision lcp parents: diff changeset	497	tactic can also perform type checking.
d8205bb279a7 Initial revision lcp parents: diff changeset	498
d8205bb279a7 Initial revision lcp parents: diff changeset	499	\item[\ttindexbold{intr_tac} $thms$]
d8205bb279a7 Initial revision lcp parents: diff changeset	500	uses $thms$ with the introduction rules to break down a type. It is
d8205bb279a7 Initial revision lcp parents: diff changeset	501	designed for goals like $\Var{a}\in A$ where $\Var{a}$ is flexible and $A$
d8205bb279a7 Initial revision lcp parents: diff changeset	502	rigid. These typically arise when trying to prove a proposition~$A$,
d8205bb279a7 Initial revision lcp parents: diff changeset	503	expressed as a type.
d8205bb279a7 Initial revision lcp parents: diff changeset	504	\end{description}
d8205bb279a7 Initial revision lcp parents: diff changeset	505
d8205bb279a7 Initial revision lcp parents: diff changeset	506
d8205bb279a7 Initial revision lcp parents: diff changeset	507
d8205bb279a7 Initial revision lcp parents: diff changeset	508	\section{Rewriting tactics}
d8205bb279a7 Initial revision lcp parents: diff changeset	509	\begin{ttbox}
d8205bb279a7 Initial revision lcp parents: diff changeset	510	rew_tac : thm list -> tactic
d8205bb279a7 Initial revision lcp parents: diff changeset	511	hyp_rew_tac : thm list -> tactic
d8205bb279a7 Initial revision lcp parents: diff changeset	512	\end{ttbox}
d8205bb279a7 Initial revision lcp parents: diff changeset	513	Object-level simplification is accomplished through proof, using the {\tt
d8205bb279a7 Initial revision lcp parents: diff changeset	514	CTT} equality rules and the built-in rewriting functor
d8205bb279a7 Initial revision lcp parents: diff changeset	515	\ttindex{TSimpFun}.\footnote{This should not be confused with {\tt
d8205bb279a7 Initial revision lcp parents: diff changeset	516	SimpFun}, which is the main rewriting functor; {\tt TSimpFun} is only
d8205bb279a7 Initial revision lcp parents: diff changeset	517	useful for {\CTT} and similar logics with type inference rules.}
d8205bb279a7 Initial revision lcp parents: diff changeset	518	The rewrites include the computation rules and other equations. The
d8205bb279a7 Initial revision lcp parents: diff changeset	519	long versions of the other rules permit rewriting of subterms and subtypes.
d8205bb279a7 Initial revision lcp parents: diff changeset	520	Also used are transitivity and the extra judgement form \ttindex{Reduce}.
d8205bb279a7 Initial revision lcp parents: diff changeset	521	Meta-level simplification handles only definitional equality.
d8205bb279a7 Initial revision lcp parents: diff changeset	522	\begin{description}
d8205bb279a7 Initial revision lcp parents: diff changeset	523	\item[\ttindexbold{rew_tac} $thms$]
d8205bb279a7 Initial revision lcp parents: diff changeset	524	applies $thms$ and the computation rules as left-to-right rewrites. It
d8205bb279a7 Initial revision lcp parents: diff changeset	525	solves the goal $a=b\in A$ by rewriting $a$ to $b$. If $b$ is an unknown
d8205bb279a7 Initial revision lcp parents: diff changeset	526	then it is assigned the rewritten form of~$a$. All subgoals are rewritten.
d8205bb279a7 Initial revision lcp parents: diff changeset	527
d8205bb279a7 Initial revision lcp parents: diff changeset	528	\item[\ttindexbold{hyp_rew_tac} $thms$]
d8205bb279a7 Initial revision lcp parents: diff changeset	529	is like {\tt rew_tac}, but includes as rewrites any equations present in
d8205bb279a7 Initial revision lcp parents: diff changeset	530	the assumptions.
d8205bb279a7 Initial revision lcp parents: diff changeset	531	\end{description}
d8205bb279a7 Initial revision lcp parents: diff changeset	532
d8205bb279a7 Initial revision lcp parents: diff changeset	533
d8205bb279a7 Initial revision lcp parents: diff changeset	534	\section{Tactics for logical reasoning}
d8205bb279a7 Initial revision lcp parents: diff changeset	535	Interpreting propositions as types lets {\CTT} express statements of
d8205bb279a7 Initial revision lcp parents: diff changeset	536	intuitionistic logic. However, Constructive Type Theory is not just
d8205bb279a7 Initial revision lcp parents: diff changeset	537	another syntax for first-order logic. A key question: can assumptions be
d8205bb279a7 Initial revision lcp parents: diff changeset	538	deleted after use? Not every occurrence of a type represents a
d8205bb279a7 Initial revision lcp parents: diff changeset	539	proposition, and Type Theory assumptions declare variables.
d8205bb279a7 Initial revision lcp parents: diff changeset	540
d8205bb279a7 Initial revision lcp parents: diff changeset	541	In first-order logic, $\disj$-elimination with the assumption $P\disj Q$
d8205bb279a7 Initial revision lcp parents: diff changeset	542	creates one subgoal assuming $P$ and another assuming $Q$, and $P\disj Q$
d8205bb279a7 Initial revision lcp parents: diff changeset	543	can be deleted. In Type Theory, $+$-elimination with the assumption $z\in
d8205bb279a7 Initial revision lcp parents: diff changeset	544	A+B$ creates one subgoal assuming $x\in A$ and another assuming $y\in B$
d8205bb279a7 Initial revision lcp parents: diff changeset	545	(for arbitrary $x$ and $y$). Deleting $z\in A+B$ may render the subgoals
d8205bb279a7 Initial revision lcp parents: diff changeset	546	unprovable if other assumptions refer to $z$. Some people might argue that
d8205bb279a7 Initial revision lcp parents: diff changeset	547	such subgoals are not even meaningful.
d8205bb279a7 Initial revision lcp parents: diff changeset	548	\begin{ttbox}
d8205bb279a7 Initial revision lcp parents: diff changeset	549	mp_tac : int -> tactic
d8205bb279a7 Initial revision lcp parents: diff changeset	550	add_mp_tac : int -> tactic
d8205bb279a7 Initial revision lcp parents: diff changeset	551	safestep_tac : thm list -> int -> tactic
d8205bb279a7 Initial revision lcp parents: diff changeset	552	safe_tac : thm list -> int -> tactic
d8205bb279a7 Initial revision lcp parents: diff changeset	553	step_tac : thm list -> int -> tactic
d8205bb279a7 Initial revision lcp parents: diff changeset	554	pc_tac : thm list -> int -> tactic
d8205bb279a7 Initial revision lcp parents: diff changeset	555	\end{ttbox}
d8205bb279a7 Initial revision lcp parents: diff changeset	556	These are loosely based on the intuitionistic proof procedures
d8205bb279a7 Initial revision lcp parents: diff changeset	557	of~\ttindex{FOL}. For the reasons discussed above, a rule that is safe for
d8205bb279a7 Initial revision lcp parents: diff changeset	558	propositional reasoning may be unsafe for type checking; thus, some of the
d8205bb279a7 Initial revision lcp parents: diff changeset	559	``safe'' tactics are misnamed.
d8205bb279a7 Initial revision lcp parents: diff changeset	560	\begin{description}
d8205bb279a7 Initial revision lcp parents: diff changeset	561	\item[\ttindexbold{mp_tac} $i$]
d8205bb279a7 Initial revision lcp parents: diff changeset	562	searches in subgoal~$i$ for assumptions of the form $f\in\Pi(A,B)$ and
d8205bb279a7 Initial revision lcp parents: diff changeset	563	$a\in A$, where~$A$ may be found by unification. It replaces
d8205bb279a7 Initial revision lcp parents: diff changeset	564	$f\in\Pi(A,B)$ by $z\in B(a)$, where~$z$ is a new parameter. The tactic
d8205bb279a7 Initial revision lcp parents: diff changeset	565	can produce multiple outcomes for each suitable pair of assumptions. In
d8205bb279a7 Initial revision lcp parents: diff changeset	566	short, {\tt mp_tac} performs Modus Ponens among the assumptions.
d8205bb279a7 Initial revision lcp parents: diff changeset	567
d8205bb279a7 Initial revision lcp parents: diff changeset	568	\item[\ttindexbold{add_mp_tac} $i$]
d8205bb279a7 Initial revision lcp parents: diff changeset	569	is like {\tt mp_tac}~$i$ but retains the assumption $f\in\Pi(A,B)$.
d8205bb279a7 Initial revision lcp parents: diff changeset	570
d8205bb279a7 Initial revision lcp parents: diff changeset	571	\item[\ttindexbold{safestep_tac} $thms$ $i$]
d8205bb279a7 Initial revision lcp parents: diff changeset	572	attacks subgoal~$i$ using formation rules and certain other `safe' rules
d8205bb279a7 Initial revision lcp parents: diff changeset	573	(\ttindex{FE}, \ttindex{ProdI}, \ttindex{SumE}, \ttindex{PlusE}), calling
d8205bb279a7 Initial revision lcp parents: diff changeset	574	{\tt mp_tac} when appropriate. It also uses~$thms$,
d8205bb279a7 Initial revision lcp parents: diff changeset	575	which are typically premises of the rule being derived.
d8205bb279a7 Initial revision lcp parents: diff changeset	576
d8205bb279a7 Initial revision lcp parents: diff changeset	577	\item[\ttindexbold{safe_tac} $thms$ $i$]
d8205bb279a7 Initial revision lcp parents: diff changeset	578	tries to solve subgoal~$i$ by backtracking, using {\tt safestep_tac}.
d8205bb279a7 Initial revision lcp parents: diff changeset	579
d8205bb279a7 Initial revision lcp parents: diff changeset	580	\item[\ttindexbold{step_tac} $thms$ $i$]
d8205bb279a7 Initial revision lcp parents: diff changeset	581	tries to reduce subgoal~$i$ using {\tt safestep_tac}, then tries unsafe
d8205bb279a7 Initial revision lcp parents: diff changeset	582	rules. It may produce multiple outcomes.
d8205bb279a7 Initial revision lcp parents: diff changeset	583
d8205bb279a7 Initial revision lcp parents: diff changeset	584	\item[\ttindexbold{pc_tac} $thms$ $i$]
d8205bb279a7 Initial revision lcp parents: diff changeset	585	tries to solve subgoal~$i$ by backtracking, using {\tt step_tac}.
d8205bb279a7 Initial revision lcp parents: diff changeset	586	\end{description}
d8205bb279a7 Initial revision lcp parents: diff changeset	587
d8205bb279a7 Initial revision lcp parents: diff changeset	588
d8205bb279a7 Initial revision lcp parents: diff changeset	589
d8205bb279a7 Initial revision lcp parents: diff changeset	590	\begin{figure}
d8205bb279a7 Initial revision lcp parents: diff changeset	591	\begin{ttbox}
d8205bb279a7 Initial revision lcp parents: diff changeset	592	\idx{add_def} a#+b == rec(a, b, %u v.succ(v))
d8205bb279a7 Initial revision lcp parents: diff changeset	593	\idx{diff_def} a-b == rec(b, a, %u v.rec(v, 0, %x y.x))
d8205bb279a7 Initial revision lcp parents: diff changeset	594	\idx{absdiff_def} a\|-\|b == (a-b) #+ (b-a)
d8205bb279a7 Initial revision lcp parents: diff changeset	595	\idx{mult_def} a#*b == rec(a, 0, %u v. b #+ v)
d8205bb279a7 Initial revision lcp parents: diff changeset	596
111 1b3cddf41b2d Various updates for Isabelle-93 lcp parents: 104 diff changeset	597	\idx{mod_def} a mod b == rec(a, 0,
104 d8205bb279a7 Initial revision lcp parents: diff changeset	598	%u v. rec(succ(v) \|-\| b, 0, %x y.succ(v)))
d8205bb279a7 Initial revision lcp parents: diff changeset	599
111 1b3cddf41b2d Various updates for Isabelle-93 lcp parents: 104 diff changeset	600	\idx{div_def} a div b == rec(a, 0,
1b3cddf41b2d Various updates for Isabelle-93 lcp parents: 104 diff changeset	601	%u v. rec(succ(u) mod b, succ(v), %x y.v))
104 d8205bb279a7 Initial revision lcp parents: diff changeset	602	\end{ttbox}
d8205bb279a7 Initial revision lcp parents: diff changeset	603	\subcaption{Definitions of the operators}
d8205bb279a7 Initial revision lcp parents: diff changeset	604
d8205bb279a7 Initial revision lcp parents: diff changeset	605	\begin{ttbox}
d8205bb279a7 Initial revision lcp parents: diff changeset	606	\idx{add_typing} [\| a:N; b:N \|] ==> a #+ b : N
d8205bb279a7 Initial revision lcp parents: diff changeset	607	\idx{addC0} b:N ==> 0 #+ b = b : N
d8205bb279a7 Initial revision lcp parents: diff changeset	608	\idx{addC_succ} [\| a:N; b:N \|] ==> succ(a) #+ b = succ(a #+ b) : N
d8205bb279a7 Initial revision lcp parents: diff changeset	609
d8205bb279a7 Initial revision lcp parents: diff changeset	610	\idx{add_assoc} [\| a:N; b:N; c:N \|] ==>
d8205bb279a7 Initial revision lcp parents: diff changeset	611	(a #+ b) #+ c = a #+ (b #+ c) : N
d8205bb279a7 Initial revision lcp parents: diff changeset	612
d8205bb279a7 Initial revision lcp parents: diff changeset	613	\idx{add_commute} [\| a:N; b:N \|] ==> a #+ b = b #+ a : N
d8205bb279a7 Initial revision lcp parents: diff changeset	614
d8205bb279a7 Initial revision lcp parents: diff changeset	615	\idx{mult_typing} [\| a:N; b:N \|] ==> a #* b : N
d8205bb279a7 Initial revision lcp parents: diff changeset	616	\idx{multC0} b:N ==> 0 #* b = 0 : N
d8205bb279a7 Initial revision lcp parents: diff changeset	617	\idx{multC_succ} [\| a:N; b:N \|] ==> succ(a) #* b = b #+ (a#*b) : N
d8205bb279a7 Initial revision lcp parents: diff changeset	618	\idx{mult_commute} [\| a:N; b:N \|] ==> a #* b = b #* a : N
d8205bb279a7 Initial revision lcp parents: diff changeset	619
d8205bb279a7 Initial revision lcp parents: diff changeset	620	\idx{add_mult_dist} [\| a:N; b:N; c:N \|] ==>
d8205bb279a7 Initial revision lcp parents: diff changeset	621	(a #+ b) #* c = (a #* c) #+ (b #* c) : N
d8205bb279a7 Initial revision lcp parents: diff changeset	622
d8205bb279a7 Initial revision lcp parents: diff changeset	623	\idx{mult_assoc} [\| a:N; b:N; c:N \|] ==>
d8205bb279a7 Initial revision lcp parents: diff changeset	624	(a #* b) #* c = a #* (b #* c) : N
d8205bb279a7 Initial revision lcp parents: diff changeset	625
d8205bb279a7 Initial revision lcp parents: diff changeset	626	\idx{diff_typing} [\| a:N; b:N \|] ==> a - b : N
d8205bb279a7 Initial revision lcp parents: diff changeset	627	\idx{diffC0} a:N ==> a - 0 = a : N
d8205bb279a7 Initial revision lcp parents: diff changeset	628	\idx{diff_0_eq_0} b:N ==> 0 - b = 0 : N
d8205bb279a7 Initial revision lcp parents: diff changeset	629	\idx{diff_succ_succ} [\| a:N; b:N \|] ==> succ(a) - succ(b) = a - b : N
d8205bb279a7 Initial revision lcp parents: diff changeset	630	\idx{diff_self_eq_0} a:N ==> a - a = 0 : N
d8205bb279a7 Initial revision lcp parents: diff changeset	631	\idx{add_inverse_diff} [\| a:N; b:N; b-a=0 : N \|] ==> b #+ (a-b) = a : N
d8205bb279a7 Initial revision lcp parents: diff changeset	632	\end{ttbox}
d8205bb279a7 Initial revision lcp parents: diff changeset	633	\subcaption{Some theorems of arithmetic}
d8205bb279a7 Initial revision lcp parents: diff changeset	634	\caption{The theory of arithmetic} \label{ctt-arith}
d8205bb279a7 Initial revision lcp parents: diff changeset	635	\end{figure}
d8205bb279a7 Initial revision lcp parents: diff changeset	636
d8205bb279a7 Initial revision lcp parents: diff changeset	637
d8205bb279a7 Initial revision lcp parents: diff changeset	638	\section{A theory of arithmetic}
d8205bb279a7 Initial revision lcp parents: diff changeset	639	{\CTT} contains a theory of elementary arithmetic. It proves the
d8205bb279a7 Initial revision lcp parents: diff changeset	640	properties of addition, multiplication, subtraction, division, and
d8205bb279a7 Initial revision lcp parents: diff changeset	641	remainder, culminating in the theorem
d8205bb279a7 Initial revision lcp parents: diff changeset	642	\[ a \bmod b + (a/b)\times b = a. \]
d8205bb279a7 Initial revision lcp parents: diff changeset	643	Figure~\ref{ctt-arith} presents the definitions and some of the key
d8205bb279a7 Initial revision lcp parents: diff changeset	644	theorems, including commutative, distributive, and associative laws. The
d8205bb279a7 Initial revision lcp parents: diff changeset	645	theory has the {\ML} identifier \ttindexbold{arith.thy}. All proofs are on
d8205bb279a7 Initial revision lcp parents: diff changeset	646	the file \ttindexbold{CTT/arith.ML}.
d8205bb279a7 Initial revision lcp parents: diff changeset	647
111 1b3cddf41b2d Various updates for Isabelle-93 lcp parents: 104 diff changeset	648	The operators~\verb'#+', \verb'-', \verb'\|-\|', \verb'#*', \verb'mod'
1b3cddf41b2d Various updates for Isabelle-93 lcp parents: 104 diff changeset	649	and~\verb'div' stand for sum, difference, absolute difference, product,
104 d8205bb279a7 Initial revision lcp parents: diff changeset	650	remainder and quotient, respectively. Since Type Theory has only primitive
d8205bb279a7 Initial revision lcp parents: diff changeset	651	recursion, some of their definitions may be obscure.
d8205bb279a7 Initial revision lcp parents: diff changeset	652
d8205bb279a7 Initial revision lcp parents: diff changeset	653	The difference~$a-b$ is computed by taking $b$ predecessors of~$a$, where
d8205bb279a7 Initial revision lcp parents: diff changeset	654	the predecessor function is $\lambda v. {\tt rec}(v, 0, \lambda x\,y.x)$.
d8205bb279a7 Initial revision lcp parents: diff changeset	655
111 1b3cddf41b2d Various updates for Isabelle-93 lcp parents: 104 diff changeset	656	The remainder $a\bmod b$ counts up to~$a$ in a cyclic fashion, using 0
1b3cddf41b2d Various updates for Isabelle-93 lcp parents: 104 diff changeset	657	as the successor of~$b-1$. Absolute difference is used to test the
1b3cddf41b2d Various updates for Isabelle-93 lcp parents: 104 diff changeset	658	equality $succ(v)=b$.
104 d8205bb279a7 Initial revision lcp parents: diff changeset	659
111 1b3cddf41b2d Various updates for Isabelle-93 lcp parents: 104 diff changeset	660	The quotient $a/b$ is computed by adding one for every number $x$
1b3cddf41b2d Various updates for Isabelle-93 lcp parents: 104 diff changeset	661	such that $0\leq x \leq a$ and $x\bmod b = 0$.
104 d8205bb279a7 Initial revision lcp parents: diff changeset	662
d8205bb279a7 Initial revision lcp parents: diff changeset	663
d8205bb279a7 Initial revision lcp parents: diff changeset	664
d8205bb279a7 Initial revision lcp parents: diff changeset	665	\section{The examples directory}
d8205bb279a7 Initial revision lcp parents: diff changeset	666	This directory contains examples and experimental proofs in {\CTT}.
d8205bb279a7 Initial revision lcp parents: diff changeset	667	\begin{description}
d8205bb279a7 Initial revision lcp parents: diff changeset	668	\item[\ttindexbold{CTT/ex/typechk.ML}]
d8205bb279a7 Initial revision lcp parents: diff changeset	669	contains simple examples of type checking and type deduction.
d8205bb279a7 Initial revision lcp parents: diff changeset	670
d8205bb279a7 Initial revision lcp parents: diff changeset	671	\item[\ttindexbold{CTT/ex/elim.ML}]
d8205bb279a7 Initial revision lcp parents: diff changeset	672	contains some examples from Martin-L\"of~\cite{martinlof84}, proved using
d8205bb279a7 Initial revision lcp parents: diff changeset	673	{\tt pc_tac}.
d8205bb279a7 Initial revision lcp parents: diff changeset	674
d8205bb279a7 Initial revision lcp parents: diff changeset	675	\item[\ttindexbold{CTT/ex/equal.ML}]
d8205bb279a7 Initial revision lcp parents: diff changeset	676	contains simple examples of rewriting.
d8205bb279a7 Initial revision lcp parents: diff changeset	677
d8205bb279a7 Initial revision lcp parents: diff changeset	678	\item[\ttindexbold{CTT/ex/synth.ML}]
d8205bb279a7 Initial revision lcp parents: diff changeset	679	demonstrates the use of unknowns with some trivial examples of program
d8205bb279a7 Initial revision lcp parents: diff changeset	680	synthesis.
d8205bb279a7 Initial revision lcp parents: diff changeset	681	\end{description}
d8205bb279a7 Initial revision lcp parents: diff changeset	682
d8205bb279a7 Initial revision lcp parents: diff changeset	683
d8205bb279a7 Initial revision lcp parents: diff changeset	684	\section{Example: type inference}
d8205bb279a7 Initial revision lcp parents: diff changeset	685	Type inference involves proving a goal of the form $a\in\Var{A}$, where $a$
d8205bb279a7 Initial revision lcp parents: diff changeset	686	is a term and $\Var{A}$ is an unknown standing for its type. The type,
d8205bb279a7 Initial revision lcp parents: diff changeset	687	initially
d8205bb279a7 Initial revision lcp parents: diff changeset	688	unknown, takes shape in the course of the proof. Our example is the
d8205bb279a7 Initial revision lcp parents: diff changeset	689	predecessor function on the natural numbers.
d8205bb279a7 Initial revision lcp parents: diff changeset	690	\begin{ttbox}
d8205bb279a7 Initial revision lcp parents: diff changeset	691	goal CTT.thy "lam n. rec(n, 0, %x y.x) : ?A";
d8205bb279a7 Initial revision lcp parents: diff changeset	692	{\out Level 0}
d8205bb279a7 Initial revision lcp parents: diff changeset	693	{\out lam n. rec(n,0,%x y. x) : ?A}
d8205bb279a7 Initial revision lcp parents: diff changeset	694	{\out 1. lam n. rec(n,0,%x y. x) : ?A}
d8205bb279a7 Initial revision lcp parents: diff changeset	695	\end{ttbox}
d8205bb279a7 Initial revision lcp parents: diff changeset	696	Since the term is a Constructive Type Theory $\lambda$-abstraction (not to
d8205bb279a7 Initial revision lcp parents: diff changeset	697	be confused with a meta-level abstraction), we apply the rule
d8205bb279a7 Initial revision lcp parents: diff changeset	698	\ttindex{ProdI}, for $\Pi$-introduction. This instantiates~$\Var{A}$ to a
d8205bb279a7 Initial revision lcp parents: diff changeset	699	product type of unknown domain and range.
d8205bb279a7 Initial revision lcp parents: diff changeset	700	\begin{ttbox}
d8205bb279a7 Initial revision lcp parents: diff changeset	701	by (resolve_tac [ProdI] 1);
d8205bb279a7 Initial revision lcp parents: diff changeset	702	{\out Level 1}
d8205bb279a7 Initial revision lcp parents: diff changeset	703	{\out lam n. rec(n,0,%x y. x) : PROD x:?A1. ?B1(x)}
d8205bb279a7 Initial revision lcp parents: diff changeset	704	{\out 1. ?A1 type}
d8205bb279a7 Initial revision lcp parents: diff changeset	705	{\out 2. !!n. n : ?A1 ==> rec(n,0,%x y. x) : ?B1(n)}
d8205bb279a7 Initial revision lcp parents: diff changeset	706	\end{ttbox}
d8205bb279a7 Initial revision lcp parents: diff changeset	707	Subgoal~1 can be solved by instantiating~$\Var{A@1}$ to any type, but this
d8205bb279a7 Initial revision lcp parents: diff changeset	708	could invalidate subgoal~2. We therefore tackle the latter subgoal. It
d8205bb279a7 Initial revision lcp parents: diff changeset	709	asks the type of a term beginning with {\tt rec}, which can be found by
d8205bb279a7 Initial revision lcp parents: diff changeset	710	$N$-elimination.\index{*NE}
d8205bb279a7 Initial revision lcp parents: diff changeset	711	\begin{ttbox}
d8205bb279a7 Initial revision lcp parents: diff changeset	712	by (eresolve_tac [NE] 2);
d8205bb279a7 Initial revision lcp parents: diff changeset	713	{\out Level 2}
d8205bb279a7 Initial revision lcp parents: diff changeset	714	{\out lam n. rec(n,0,%x y. x) : PROD x:N. ?C2(x,x)}
d8205bb279a7 Initial revision lcp parents: diff changeset	715	{\out 1. N type}
d8205bb279a7 Initial revision lcp parents: diff changeset	716	{\out 2. !!n. 0 : ?C2(n,0)}
d8205bb279a7 Initial revision lcp parents: diff changeset	717	{\out 3. !!n x y. [\| x : N; y : ?C2(n,x) \|] ==> x : ?C2(n,succ(x))}
d8205bb279a7 Initial revision lcp parents: diff changeset	718	\end{ttbox}
d8205bb279a7 Initial revision lcp parents: diff changeset	719	We now know~$\Var{A@1}$ is the type of natural numbers. However, let us
d8205bb279a7 Initial revision lcp parents: diff changeset	720	continue with subgoal~2. What is the type of~0?\index{*NIO}
d8205bb279a7 Initial revision lcp parents: diff changeset	721	\begin{ttbox}
d8205bb279a7 Initial revision lcp parents: diff changeset	722	by (resolve_tac [NI0] 2);
d8205bb279a7 Initial revision lcp parents: diff changeset	723	{\out Level 3}
d8205bb279a7 Initial revision lcp parents: diff changeset	724	{\out lam n. rec(n,0,%x y. x) : N --> N}
d8205bb279a7 Initial revision lcp parents: diff changeset	725	{\out 1. N type}
d8205bb279a7 Initial revision lcp parents: diff changeset	726	{\out 2. !!n x y. [\| x : N; y : N \|] ==> x : N}
d8205bb279a7 Initial revision lcp parents: diff changeset	727	\end{ttbox}
d8205bb279a7 Initial revision lcp parents: diff changeset	728	The type~$\Var{A}$ is now determined. It is $\prod@{n\in N}N$, which is
d8205bb279a7 Initial revision lcp parents: diff changeset	729	equivalent to $N\to N$. But we must prove all the subgoals to show that
d8205bb279a7 Initial revision lcp parents: diff changeset	730	the original term is validly typed. Subgoal~2 is provable by assumption
d8205bb279a7 Initial revision lcp parents: diff changeset	731	and the remaining subgoal falls by $N$-formation.\index{*NF}
d8205bb279a7 Initial revision lcp parents: diff changeset	732	\begin{ttbox}
d8205bb279a7 Initial revision lcp parents: diff changeset	733	by (assume_tac 2);
d8205bb279a7 Initial revision lcp parents: diff changeset	734	{\out Level 4}
d8205bb279a7 Initial revision lcp parents: diff changeset	735	{\out lam n. rec(n,0,%x y. x) : N --> N}
d8205bb279a7 Initial revision lcp parents: diff changeset	736	{\out 1. N type}
d8205bb279a7 Initial revision lcp parents: diff changeset	737	by (resolve_tac [NF] 1);
d8205bb279a7 Initial revision lcp parents: diff changeset	738	{\out Level 5}
d8205bb279a7 Initial revision lcp parents: diff changeset	739	{\out lam n. rec(n,0,%x y. x) : N --> N}
d8205bb279a7 Initial revision lcp parents: diff changeset	740	{\out No subgoals!}
d8205bb279a7 Initial revision lcp parents: diff changeset	741	\end{ttbox}
d8205bb279a7 Initial revision lcp parents: diff changeset	742	Calling \ttindex{typechk_tac} can prove this theorem in one step.
d8205bb279a7 Initial revision lcp parents: diff changeset	743
d8205bb279a7 Initial revision lcp parents: diff changeset	744
d8205bb279a7 Initial revision lcp parents: diff changeset	745	\section{An example of logical reasoning}
d8205bb279a7 Initial revision lcp parents: diff changeset	746	Logical reasoning in Type Theory involves proving a goal of the form
d8205bb279a7 Initial revision lcp parents: diff changeset	747	$\Var{a}\in A$, where type $A$ expresses a proposition and $\Var{a}$ is an
d8205bb279a7 Initial revision lcp parents: diff changeset	748	unknown standing
d8205bb279a7 Initial revision lcp parents: diff changeset	749	for its proof term: a value of type $A$. This term is initially unknown, as
d8205bb279a7 Initial revision lcp parents: diff changeset	750	with type inference, and takes shape during the proof. Our example
d8205bb279a7 Initial revision lcp parents: diff changeset	751	expresses, by propositions-as-types, a theorem about quantifiers in a
d8205bb279a7 Initial revision lcp parents: diff changeset	752	sorted logic:
d8205bb279a7 Initial revision lcp parents: diff changeset	753	\[ \infer{(\ex{x\in A}P(x)) \disj (\ex{x\in A}Q(x))}
d8205bb279a7 Initial revision lcp parents: diff changeset	754	{\ex{x\in A}P(x)\disj Q(x)}
d8205bb279a7 Initial revision lcp parents: diff changeset	755	\]
d8205bb279a7 Initial revision lcp parents: diff changeset	756	It it related to a distributive law of Type Theory:
d8205bb279a7 Initial revision lcp parents: diff changeset	757	\[ \infer{(A\times B) + (A\times C)}{A\times(B+C)} \]
d8205bb279a7 Initial revision lcp parents: diff changeset	758	Generalizing this from $\times$ to $\Sigma$, and making the typing
d8205bb279a7 Initial revision lcp parents: diff changeset	759	conditions explicit, yields
d8205bb279a7 Initial revision lcp parents: diff changeset	760	\[ \infer{\Var{a} \in (\sum@{x\in A} B(x)) + (\sum@{x\in A} C(x))}
d8205bb279a7 Initial revision lcp parents: diff changeset	761	{\hbox{$A$ type} &
d8205bb279a7 Initial revision lcp parents: diff changeset	762	\infer*{\hbox{$B(x)$ type}}{[x\in A]} &
d8205bb279a7 Initial revision lcp parents: diff changeset	763	\infer*{\hbox{$C(x)$ type}}{[x\in A]} &
d8205bb279a7 Initial revision lcp parents: diff changeset	764	p\in \sum@{x\in A} B(x)+C(x)}
d8205bb279a7 Initial revision lcp parents: diff changeset	765	\]
d8205bb279a7 Initial revision lcp parents: diff changeset	766	To derive this rule, we bind its premises --- returned by~\ttindex{goal}
d8205bb279a7 Initial revision lcp parents: diff changeset	767	--- to the {\ML} variable~{\tt prems}.
d8205bb279a7 Initial revision lcp parents: diff changeset	768	\begin{ttbox}
d8205bb279a7 Initial revision lcp parents: diff changeset	769	val prems = goal CTT.thy
d8205bb279a7 Initial revision lcp parents: diff changeset	770	"[\| A type; \ttback
d8205bb279a7 Initial revision lcp parents: diff changeset	771	\ttback !!x. x:A ==> B(x) type; \ttback
d8205bb279a7 Initial revision lcp parents: diff changeset	772	\ttback !!x. x:A ==> C(x) type; \ttback
d8205bb279a7 Initial revision lcp parents: diff changeset	773	\ttback p: SUM x:A. B(x) + C(x) \ttback
d8205bb279a7 Initial revision lcp parents: diff changeset	774	\ttback \|] ==> ?a : (SUM x:A. B(x)) + (SUM x:A. C(x))";
d8205bb279a7 Initial revision lcp parents: diff changeset	775	{\out Level 0}
d8205bb279a7 Initial revision lcp parents: diff changeset	776	{\out ?a : (SUM x:A. B(x)) + (SUM x:A. C(x))}
d8205bb279a7 Initial revision lcp parents: diff changeset	777	{\out 1. ?a : (SUM x:A. B(x)) + (SUM x:A. C(x))}
114 96c627d2815e Misc updates lcp parents: 111 diff changeset	778	\ttbreak
111 1b3cddf41b2d Various updates for Isabelle-93 lcp parents: 104 diff changeset	779	{\out val prems = ["A type [A type]",}
1b3cddf41b2d Various updates for Isabelle-93 lcp parents: 104 diff changeset	780	{\out "?x : A ==> B(?x) type [!!x. x : A ==> B(x) type]",}
1b3cddf41b2d Various updates for Isabelle-93 lcp parents: 104 diff changeset	781	{\out "?x : A ==> C(?x) type [!!x. x : A ==> C(x) type]",}
1b3cddf41b2d Various updates for Isabelle-93 lcp parents: 104 diff changeset	782	{\out "p : SUM x:A. B(x) + C(x) [p : SUM x:A. B(x) + C(x)]"]}
1b3cddf41b2d Various updates for Isabelle-93 lcp parents: 104 diff changeset	783	{\out : thm list}
104 d8205bb279a7 Initial revision lcp parents: diff changeset	784	\end{ttbox}
d8205bb279a7 Initial revision lcp parents: diff changeset	785	One of the premises involves summation ($\Sigma$). Since it is a premise
d8205bb279a7 Initial revision lcp parents: diff changeset	786	rather than the assumption of a goal, it cannot be found by
d8205bb279a7 Initial revision lcp parents: diff changeset	787	\ttindex{eresolve_tac}. We could insert it by calling
d8205bb279a7 Initial revision lcp parents: diff changeset	788	\hbox{\tt \ttindex{cut_facts_tac} prems 1}. Instead, let us resolve the
d8205bb279a7 Initial revision lcp parents: diff changeset	789	$\Sigma$-elimination rule with the premises; this yields one result, which
d8205bb279a7 Initial revision lcp parents: diff changeset	790	we supply to \ttindex{resolve_tac}.\index{SumE}\index{RL}
d8205bb279a7 Initial revision lcp parents: diff changeset	791	\begin{ttbox}
d8205bb279a7 Initial revision lcp parents: diff changeset	792	by (resolve_tac (prems RL [SumE]) 1);
d8205bb279a7 Initial revision lcp parents: diff changeset	793	{\out Level 1}
d8205bb279a7 Initial revision lcp parents: diff changeset	794	{\out split(p,?c1) : (SUM x:A. B(x)) + (SUM x:A. C(x))}
d8205bb279a7 Initial revision lcp parents: diff changeset	795	{\out 1. !!x y.}
d8205bb279a7 Initial revision lcp parents: diff changeset	796	{\out [\| x : A; y : B(x) + C(x) \|] ==>}
d8205bb279a7 Initial revision lcp parents: diff changeset	797	{\out ?c1(x,y) : (SUM x:A. B(x)) + (SUM x:A. C(x))}
d8205bb279a7 Initial revision lcp parents: diff changeset	798	\end{ttbox}
d8205bb279a7 Initial revision lcp parents: diff changeset	799	The subgoal has two new parameters. In the main goal, $\Var{a}$ has been
d8205bb279a7 Initial revision lcp parents: diff changeset	800	instantiated with a \ttindex{split} term. The assumption $y\in B(x) + C(x)$ is
d8205bb279a7 Initial revision lcp parents: diff changeset	801	eliminated next, causing a case split and a new parameter. The main goal
d8205bb279a7 Initial revision lcp parents: diff changeset	802	now contains~\ttindex{when}.
d8205bb279a7 Initial revision lcp parents: diff changeset	803	\index{*PlusE}
d8205bb279a7 Initial revision lcp parents: diff changeset	804	\begin{ttbox}
d8205bb279a7 Initial revision lcp parents: diff changeset	805	by (eresolve_tac [PlusE] 1);
d8205bb279a7 Initial revision lcp parents: diff changeset	806	{\out Level 2}
d8205bb279a7 Initial revision lcp parents: diff changeset	807	{\out split(p,%x y. when(y,?c2(x,y),?d2(x,y)))}
d8205bb279a7 Initial revision lcp parents: diff changeset	808	{\out : (SUM x:A. B(x)) + (SUM x:A. C(x))}
d8205bb279a7 Initial revision lcp parents: diff changeset	809	{\out 1. !!x y xa.}
d8205bb279a7 Initial revision lcp parents: diff changeset	810	{\out [\| x : A; xa : B(x) \|] ==>}
d8205bb279a7 Initial revision lcp parents: diff changeset	811	{\out ?c2(x,y,xa) : (SUM x:A. B(x)) + (SUM x:A. C(x))}
114 96c627d2815e Misc updates lcp parents: 111 diff changeset	812	\ttbreak
104 d8205bb279a7 Initial revision lcp parents: diff changeset	813	{\out 2. !!x y ya.}
d8205bb279a7 Initial revision lcp parents: diff changeset	814	{\out [\| x : A; ya : C(x) \|] ==>}
d8205bb279a7 Initial revision lcp parents: diff changeset	815	{\out ?d2(x,y,ya) : (SUM x:A. B(x)) + (SUM x:A. C(x))}
d8205bb279a7 Initial revision lcp parents: diff changeset	816	\end{ttbox}
d8205bb279a7 Initial revision lcp parents: diff changeset	817	To complete the proof object for the main goal, we need to instantiate the
d8205bb279a7 Initial revision lcp parents: diff changeset	818	terms $\Var{c@2}(x,y,xa)$ and $\Var{d@2}(x,y,xa)$. We attack subgoal~1 by
d8205bb279a7 Initial revision lcp parents: diff changeset	819	introduction of~$+$; since it assumes $xa\in B(x)$, we take the left
d8205bb279a7 Initial revision lcp parents: diff changeset	820	injection~(\ttindex{inl}).
d8205bb279a7 Initial revision lcp parents: diff changeset	821	\index{*PlusI_inl}
d8205bb279a7 Initial revision lcp parents: diff changeset	822	\begin{ttbox}
d8205bb279a7 Initial revision lcp parents: diff changeset	823	by (resolve_tac [PlusI_inl] 1);
d8205bb279a7 Initial revision lcp parents: diff changeset	824	{\out Level 3}
d8205bb279a7 Initial revision lcp parents: diff changeset	825	{\out split(p,%x y. when(y,%xa. inl(?a3(x,y,xa)),?d2(x,y)))}
d8205bb279a7 Initial revision lcp parents: diff changeset	826	{\out : (SUM x:A. B(x)) + (SUM x:A. C(x))}
d8205bb279a7 Initial revision lcp parents: diff changeset	827	{\out 1. !!x y xa. [\| x : A; xa : B(x) \|] ==> ?a3(x,y,xa) : SUM x:A. B(x)}
d8205bb279a7 Initial revision lcp parents: diff changeset	828	{\out 2. !!x y xa. [\| x : A; xa : B(x) \|] ==> SUM x:A. C(x) type}
114 96c627d2815e Misc updates lcp parents: 111 diff changeset	829	\ttbreak
104 d8205bb279a7 Initial revision lcp parents: diff changeset	830	{\out 3. !!x y ya.}
d8205bb279a7 Initial revision lcp parents: diff changeset	831	{\out [\| x : A; ya : C(x) \|] ==>}
d8205bb279a7 Initial revision lcp parents: diff changeset	832	{\out ?d2(x,y,ya) : (SUM x:A. B(x)) + (SUM x:A. C(x))}
d8205bb279a7 Initial revision lcp parents: diff changeset	833	\end{ttbox}
d8205bb279a7 Initial revision lcp parents: diff changeset	834	A new subgoal has appeared, to verify that $\sum@{x\in A}C(x)$ is a type.
d8205bb279a7 Initial revision lcp parents: diff changeset	835	Continuing with subgoal~1, we apply $\Sigma$-introduction. The main goal
d8205bb279a7 Initial revision lcp parents: diff changeset	836	now contains an ordered pair.
d8205bb279a7 Initial revision lcp parents: diff changeset	837	\index{*SumI}
d8205bb279a7 Initial revision lcp parents: diff changeset	838	\begin{ttbox}
d8205bb279a7 Initial revision lcp parents: diff changeset	839	by (resolve_tac [SumI] 1);
d8205bb279a7 Initial revision lcp parents: diff changeset	840	{\out Level 4}
d8205bb279a7 Initial revision lcp parents: diff changeset	841	{\out split(p,%x y. when(y,%xa. inl(<?a4(x,y,xa),?b4(x,y,xa)>),?d2(x,y)))}
d8205bb279a7 Initial revision lcp parents: diff changeset	842	{\out : (SUM x:A. B(x)) + (SUM x:A. C(x))}
d8205bb279a7 Initial revision lcp parents: diff changeset	843	{\out 1. !!x y xa. [\| x : A; xa : B(x) \|] ==> ?a4(x,y,xa) : A}
d8205bb279a7 Initial revision lcp parents: diff changeset	844	{\out 2. !!x y xa. [\| x : A; xa : B(x) \|] ==> ?b4(x,y,xa) : B(?a4(x,y,xa))}
d8205bb279a7 Initial revision lcp parents: diff changeset	845	{\out 3. !!x y xa. [\| x : A; xa : B(x) \|] ==> SUM x:A. C(x) type}
d8205bb279a7 Initial revision lcp parents: diff changeset	846	{\out 4. !!x y ya.}
d8205bb279a7 Initial revision lcp parents: diff changeset	847	{\out [\| x : A; ya : C(x) \|] ==>}
d8205bb279a7 Initial revision lcp parents: diff changeset	848	{\out ?d2(x,y,ya) : (SUM x:A. B(x)) + (SUM x:A. C(x))}
d8205bb279a7 Initial revision lcp parents: diff changeset	849	\end{ttbox}
d8205bb279a7 Initial revision lcp parents: diff changeset	850	The two new subgoals both hold by assumption. Observe how the unknowns
d8205bb279a7 Initial revision lcp parents: diff changeset	851	$\Var{a@4}$ and $\Var{b@4}$ are instantiated throughout the proof state.
d8205bb279a7 Initial revision lcp parents: diff changeset	852	\begin{ttbox}
d8205bb279a7 Initial revision lcp parents: diff changeset	853	by (assume_tac 1);
d8205bb279a7 Initial revision lcp parents: diff changeset	854	{\out Level 5}
d8205bb279a7 Initial revision lcp parents: diff changeset	855	{\out split(p,%x y. when(y,%xa. inl(<x,?b4(x,y,xa)>),?d2(x,y)))}
d8205bb279a7 Initial revision lcp parents: diff changeset	856	{\out : (SUM x:A. B(x)) + (SUM x:A. C(x))}
d8205bb279a7 Initial revision lcp parents: diff changeset	857	{\out 1. !!x y xa. [\| x : A; xa : B(x) \|] ==> ?b4(x,y,xa) : B(x)}
d8205bb279a7 Initial revision lcp parents: diff changeset	858	{\out 2. !!x y xa. [\| x : A; xa : B(x) \|] ==> SUM x:A. C(x) type}
d8205bb279a7 Initial revision lcp parents: diff changeset	859	{\out 3. !!x y ya.}
d8205bb279a7 Initial revision lcp parents: diff changeset	860	{\out [\| x : A; ya : C(x) \|] ==>}
d8205bb279a7 Initial revision lcp parents: diff changeset	861	{\out ?d2(x,y,ya) : (SUM x:A. B(x)) + (SUM x:A. C(x))}
d8205bb279a7 Initial revision lcp parents: diff changeset	862	by (assume_tac 1);
d8205bb279a7 Initial revision lcp parents: diff changeset	863	{\out Level 6}
d8205bb279a7 Initial revision lcp parents: diff changeset	864	{\out split(p,%x y. when(y,%xa. inl(<x,xa>),?d2(x,y)))}
d8205bb279a7 Initial revision lcp parents: diff changeset	865	{\out : (SUM x:A. B(x)) + (SUM x:A. C(x))}
d8205bb279a7 Initial revision lcp parents: diff changeset	866	{\out 1. !!x y xa. [\| x : A; xa : B(x) \|] ==> SUM x:A. C(x) type}
d8205bb279a7 Initial revision lcp parents: diff changeset	867	{\out 2. !!x y ya.}
d8205bb279a7 Initial revision lcp parents: diff changeset	868	{\out [\| x : A; ya : C(x) \|] ==>}
d8205bb279a7 Initial revision lcp parents: diff changeset	869	{\out ?d2(x,y,ya) : (SUM x:A. B(x)) + (SUM x:A. C(x))}
d8205bb279a7 Initial revision lcp parents: diff changeset	870	\end{ttbox}
d8205bb279a7 Initial revision lcp parents: diff changeset	871	Subgoal~1 is just type checking. It yields to \ttindex{typechk_tac},
d8205bb279a7 Initial revision lcp parents: diff changeset	872	supplied with the current list of premises.
d8205bb279a7 Initial revision lcp parents: diff changeset	873	\begin{ttbox}
d8205bb279a7 Initial revision lcp parents: diff changeset	874	by (typechk_tac prems);
d8205bb279a7 Initial revision lcp parents: diff changeset	875	{\out Level 7}
d8205bb279a7 Initial revision lcp parents: diff changeset	876	{\out split(p,%x y. when(y,%xa. inl(<x,xa>),?d2(x,y)))}
d8205bb279a7 Initial revision lcp parents: diff changeset	877	{\out : (SUM x:A. B(x)) + (SUM x:A. C(x))}
d8205bb279a7 Initial revision lcp parents: diff changeset	878	{\out 1. !!x y ya.}
d8205bb279a7 Initial revision lcp parents: diff changeset	879	{\out [\| x : A; ya : C(x) \|] ==>}
d8205bb279a7 Initial revision lcp parents: diff changeset	880	{\out ?d2(x,y,ya) : (SUM x:A. B(x)) + (SUM x:A. C(x))}
d8205bb279a7 Initial revision lcp parents: diff changeset	881	\end{ttbox}
d8205bb279a7 Initial revision lcp parents: diff changeset	882	The other case is similar. Let us prove it by \ttindex{pc_tac}, and note
d8205bb279a7 Initial revision lcp parents: diff changeset	883	the final proof object.
d8205bb279a7 Initial revision lcp parents: diff changeset	884	\begin{ttbox}
d8205bb279a7 Initial revision lcp parents: diff changeset	885	by (pc_tac prems 1);
d8205bb279a7 Initial revision lcp parents: diff changeset	886	{\out Level 8}
d8205bb279a7 Initial revision lcp parents: diff changeset	887	{\out split(p,%x y. when(y,%xa. inl(<x,xa>),%y. inr(<x,y>)))}
d8205bb279a7 Initial revision lcp parents: diff changeset	888	{\out : (SUM x:A. B(x)) + (SUM x:A. C(x))}
d8205bb279a7 Initial revision lcp parents: diff changeset	889	{\out No subgoals!}
d8205bb279a7 Initial revision lcp parents: diff changeset	890	\end{ttbox}
d8205bb279a7 Initial revision lcp parents: diff changeset	891	Calling \ttindex{pc_tac} after the first $\Sigma$-elimination above also
d8205bb279a7 Initial revision lcp parents: diff changeset	892	proves this theorem.
d8205bb279a7 Initial revision lcp parents: diff changeset	893
d8205bb279a7 Initial revision lcp parents: diff changeset	894
d8205bb279a7 Initial revision lcp parents: diff changeset	895	\section{Example: deriving a currying functional}
d8205bb279a7 Initial revision lcp parents: diff changeset	896	In simply-typed languages such as {\ML}, a currying functional has the type
d8205bb279a7 Initial revision lcp parents: diff changeset	897	\[ (A\times B \to C) \to (A\to (B\to C)). \]
d8205bb279a7 Initial revision lcp parents: diff changeset	898	Let us generalize this to~$\Sigma$ and~$\Pi$. The argument of the
d8205bb279a7 Initial revision lcp parents: diff changeset	899	functional is a function that maps $z:\Sigma(A,B)$ to~$C(z)$; the resulting
d8205bb279a7 Initial revision lcp parents: diff changeset	900	function maps $x\in A$ and $y\in B(x)$ to $C(\langle x,y\rangle)$. Here
d8205bb279a7 Initial revision lcp parents: diff changeset	901	$B$ is a family over~$A$, while $C$ is a family over $\Sigma(A,B)$.
d8205bb279a7 Initial revision lcp parents: diff changeset	902	\begin{ttbox}
d8205bb279a7 Initial revision lcp parents: diff changeset	903	val prems = goal CTT.thy
d8205bb279a7 Initial revision lcp parents: diff changeset	904	"[\| A type; !!x. x:A ==> B(x) type; \ttback
d8205bb279a7 Initial revision lcp parents: diff changeset	905	\ttback !!z. z: (SUM x:A. B(x)) ==> C(z) type \|] \ttback
d8205bb279a7 Initial revision lcp parents: diff changeset	906	\ttback ==> ?a : (PROD z : (SUM x:A . B(x)) . C(z)) \ttback
d8205bb279a7 Initial revision lcp parents: diff changeset	907	\ttback --> (PROD x:A . PROD y:B(x) . C(<x,y>))";
d8205bb279a7 Initial revision lcp parents: diff changeset	908	{\out Level 0}
d8205bb279a7 Initial revision lcp parents: diff changeset	909	{\out ?a : (PROD z:SUM x:A. B(x). C(z)) --> (PROD x:A. PROD y:B(x). C(<x,y>))}
d8205bb279a7 Initial revision lcp parents: diff changeset	910	{\out 1. ?a : (PROD z:SUM x:A. B(x). C(z)) -->}
d8205bb279a7 Initial revision lcp parents: diff changeset	911	{\out (PROD x:A. PROD y:B(x). C(<x,y>))}
114 96c627d2815e Misc updates lcp parents: 111 diff changeset	912	\ttbreak
111 1b3cddf41b2d Various updates for Isabelle-93 lcp parents: 104 diff changeset	913	{\out val prems = ["A type [A type]",}
1b3cddf41b2d Various updates for Isabelle-93 lcp parents: 104 diff changeset	914	{\out "?x : A ==> B(?x) type [!!x. x : A ==> B(x) type]",}
1b3cddf41b2d Various updates for Isabelle-93 lcp parents: 104 diff changeset	915	{\out "?z : SUM x:A. B(x) ==> C(?z) type}
1b3cddf41b2d Various updates for Isabelle-93 lcp parents: 104 diff changeset	916	{\out [!!z. z : SUM x:A. B(x) ==> C(z) type]"] : thm list}
104 d8205bb279a7 Initial revision lcp parents: diff changeset	917	\end{ttbox}
d8205bb279a7 Initial revision lcp parents: diff changeset	918	This is an opportunity to demonstrate \ttindex{intr_tac}. Here, the tactic
d8205bb279a7 Initial revision lcp parents: diff changeset	919	repeatedly applies $\Pi$-introduction, automatically proving the rather
d8205bb279a7 Initial revision lcp parents: diff changeset	920	tiresome typing conditions. Note that $\Var{a}$ becomes instantiated to
d8205bb279a7 Initial revision lcp parents: diff changeset	921	three nested $\lambda$-abstractions.
d8205bb279a7 Initial revision lcp parents: diff changeset	922	\begin{ttbox}
d8205bb279a7 Initial revision lcp parents: diff changeset	923	by (intr_tac prems);
d8205bb279a7 Initial revision lcp parents: diff changeset	924	{\out Level 1}
d8205bb279a7 Initial revision lcp parents: diff changeset	925	{\out lam x xa xb. ?b7(x,xa,xb)}
d8205bb279a7 Initial revision lcp parents: diff changeset	926	{\out : (PROD z:SUM x:A. B(x). C(z)) --> (PROD x:A. PROD y:B(x). C(<x,y>))}
d8205bb279a7 Initial revision lcp parents: diff changeset	927	{\out 1. !!uu x y.}
d8205bb279a7 Initial revision lcp parents: diff changeset	928	{\out [\| uu : PROD z:SUM x:A. B(x). C(z); x : A; y : B(x) \|] ==>}
d8205bb279a7 Initial revision lcp parents: diff changeset	929	{\out ?b7(uu,x,y) : C(<x,y>)}
d8205bb279a7 Initial revision lcp parents: diff changeset	930	\end{ttbox}
d8205bb279a7 Initial revision lcp parents: diff changeset	931	Using $\Pi$-elimination, we solve subgoal~1 by applying the function~$uu$.
d8205bb279a7 Initial revision lcp parents: diff changeset	932	\index{*ProdE}
d8205bb279a7 Initial revision lcp parents: diff changeset	933	\begin{ttbox}
d8205bb279a7 Initial revision lcp parents: diff changeset	934	by (eresolve_tac [ProdE] 1);
d8205bb279a7 Initial revision lcp parents: diff changeset	935	{\out Level 2}
d8205bb279a7 Initial revision lcp parents: diff changeset	936	{\out lam x xa xb. x ` <xa,xb>}
d8205bb279a7 Initial revision lcp parents: diff changeset	937	{\out : (PROD z:SUM x:A. B(x). C(z)) --> (PROD x:A. PROD y:B(x). C(<x,y>))}
d8205bb279a7 Initial revision lcp parents: diff changeset	938	{\out 1. !!uu x y. [\| x : A; y : B(x) \|] ==> <x,y> : SUM x:A. B(x)}
d8205bb279a7 Initial revision lcp parents: diff changeset	939	\end{ttbox}
d8205bb279a7 Initial revision lcp parents: diff changeset	940	Finally, we exhibit a suitable argument for the function application. This
d8205bb279a7 Initial revision lcp parents: diff changeset	941	is straightforward using introduction rules.
d8205bb279a7 Initial revision lcp parents: diff changeset	942	\index{*intr_tac}
d8205bb279a7 Initial revision lcp parents: diff changeset	943	\begin{ttbox}
d8205bb279a7 Initial revision lcp parents: diff changeset	944	by (intr_tac prems);
d8205bb279a7 Initial revision lcp parents: diff changeset	945	{\out Level 3}
d8205bb279a7 Initial revision lcp parents: diff changeset	946	{\out lam x xa xb. x ` <xa,xb>}
d8205bb279a7 Initial revision lcp parents: diff changeset	947	{\out : (PROD z:SUM x:A. B(x). C(z)) --> (PROD x:A. PROD y:B(x). C(<x,y>))}
d8205bb279a7 Initial revision lcp parents: diff changeset	948	{\out No subgoals!}
d8205bb279a7 Initial revision lcp parents: diff changeset	949	\end{ttbox}
d8205bb279a7 Initial revision lcp parents: diff changeset	950	Calling~\ttindex{pc_tac} would have proved this theorem in one step; it can
d8205bb279a7 Initial revision lcp parents: diff changeset	951	also prove an example by Martin-L\"of, related to $\disj$-elimination
d8205bb279a7 Initial revision lcp parents: diff changeset	952	\cite[page~58]{martinlof84}.
d8205bb279a7 Initial revision lcp parents: diff changeset	953
d8205bb279a7 Initial revision lcp parents: diff changeset	954
d8205bb279a7 Initial revision lcp parents: diff changeset	955	\section{Example: proving the Axiom of Choice} \label{ctt-choice}
d8205bb279a7 Initial revision lcp parents: diff changeset	956	Suppose we have a function $h\in \prod@{x\in A}\sum@{y\in B(x)} C(x,y)$,
d8205bb279a7 Initial revision lcp parents: diff changeset	957	which takes $x\in A$ to some $y\in B(x)$ paired with some $z\in C(x,y)$.
d8205bb279a7 Initial revision lcp parents: diff changeset	958	Interpreting propositions as types, this asserts that for all $x\in A$
d8205bb279a7 Initial revision lcp parents: diff changeset	959	there exists $y\in B(x)$ such that $C(x,y)$. The Axiom of Choice asserts
d8205bb279a7 Initial revision lcp parents: diff changeset	960	that we can construct a function $f\in \prod@{x\in A}B(x)$ such that
d8205bb279a7 Initial revision lcp parents: diff changeset	961	$C(x,f{\tt`}x)$ for all $x\in A$, where the latter property is witnessed by a
d8205bb279a7 Initial revision lcp parents: diff changeset	962	function $g\in \prod@{x\in A}C(x,f{\tt`}x)$.
d8205bb279a7 Initial revision lcp parents: diff changeset	963
d8205bb279a7 Initial revision lcp parents: diff changeset	964	In principle, the Axiom of Choice is simple to derive in Constructive Type
d8205bb279a7 Initial revision lcp parents: diff changeset	965	Theory \cite[page~50]{martinlof84}. The following definitions work:
d8205bb279a7 Initial revision lcp parents: diff changeset	966	\begin{eqnarray*}
d8205bb279a7 Initial revision lcp parents: diff changeset	967	f & \equiv & {\tt fst} \circ h \\
d8205bb279a7 Initial revision lcp parents: diff changeset	968	g & \equiv & {\tt snd} \circ h
d8205bb279a7 Initial revision lcp parents: diff changeset	969	\end{eqnarray*}
d8205bb279a7 Initial revision lcp parents: diff changeset	970	But a completely formal proof is hard to find. Many of the rules can be
d8205bb279a7 Initial revision lcp parents: diff changeset	971	applied in a multiplicity of ways, yielding a large number of higher-order
d8205bb279a7 Initial revision lcp parents: diff changeset	972	unifiers. The proof can get bogged down in the details. But with a
d8205bb279a7 Initial revision lcp parents: diff changeset	973	careful selection of derived rules (recall Figure~\ref{ctt-derived}) and
d8205bb279a7 Initial revision lcp parents: diff changeset	974	the type checking tactics, we can prove the theorem in nine steps.
d8205bb279a7 Initial revision lcp parents: diff changeset	975	\begin{ttbox}
d8205bb279a7 Initial revision lcp parents: diff changeset	976	val prems = goal CTT.thy
d8205bb279a7 Initial revision lcp parents: diff changeset	977	"[\| A type; !!x. x:A ==> B(x) type; \ttback
d8205bb279a7 Initial revision lcp parents: diff changeset	978	\ttback !!x y.[\| x:A; y:B(x) \|] ==> C(x,y) type \ttback
d8205bb279a7 Initial revision lcp parents: diff changeset	979	\ttback \|] ==> ?a : (PROD x:A. SUM y:B(x). C(x,y)) \ttback
d8205bb279a7 Initial revision lcp parents: diff changeset	980	\ttback --> (SUM f: (PROD x:A. B(x)). PROD x:A. C(x, f`x))";
d8205bb279a7 Initial revision lcp parents: diff changeset	981	{\out Level 0}
d8205bb279a7 Initial revision lcp parents: diff changeset	982	{\out ?a : (PROD x:A. SUM y:B(x). C(x,y)) -->}
d8205bb279a7 Initial revision lcp parents: diff changeset	983	{\out (SUM f:PROD x:A. B(x). PROD x:A. C(x,f ` x))}
d8205bb279a7 Initial revision lcp parents: diff changeset	984	{\out 1. ?a : (PROD x:A. SUM y:B(x). C(x,y)) -->}
d8205bb279a7 Initial revision lcp parents: diff changeset	985	{\out (SUM f:PROD x:A. B(x). PROD x:A. C(x,f ` x))}
111 1b3cddf41b2d Various updates for Isabelle-93 lcp parents: 104 diff changeset	986	\ttbreak
1b3cddf41b2d Various updates for Isabelle-93 lcp parents: 104 diff changeset	987	{\out val prems = ["A type [A type]",}
1b3cddf41b2d Various updates for Isabelle-93 lcp parents: 104 diff changeset	988	{\out "?x : A ==> B(?x) type [!!x. x : A ==> B(x) type]",}
1b3cddf41b2d Various updates for Isabelle-93 lcp parents: 104 diff changeset	989	{\out "[\| ?x : A; ?y : B(?x) \|] ==> C(?x, ?y) type}
1b3cddf41b2d Various updates for Isabelle-93 lcp parents: 104 diff changeset	990	{\out [!!x y. [\| x : A; y : B(x) \|] ==> C(x, y) type]"]}
1b3cddf41b2d Various updates for Isabelle-93 lcp parents: 104 diff changeset	991	{\out : thm list}
104 d8205bb279a7 Initial revision lcp parents: diff changeset	992	\end{ttbox}
d8205bb279a7 Initial revision lcp parents: diff changeset	993	First, \ttindex{intr_tac} applies introduction rules and performs routine
d8205bb279a7 Initial revision lcp parents: diff changeset	994	type checking. This instantiates~$\Var{a}$ to a construction involving
d8205bb279a7 Initial revision lcp parents: diff changeset	995	three $\lambda$-abstractions and an ordered pair.
d8205bb279a7 Initial revision lcp parents: diff changeset	996	\begin{ttbox}
d8205bb279a7 Initial revision lcp parents: diff changeset	997	by (intr_tac prems);
d8205bb279a7 Initial revision lcp parents: diff changeset	998	{\out Level 1}
d8205bb279a7 Initial revision lcp parents: diff changeset	999	{\out lam x. <lam xa. ?b7(x,xa),lam xa. ?b8(x,xa)>}
d8205bb279a7 Initial revision lcp parents: diff changeset	1000	{\out : (PROD x:A. SUM y:B(x). C(x,y)) -->}
d8205bb279a7 Initial revision lcp parents: diff changeset	1001	{\out (SUM f:PROD x:A. B(x). PROD x:A. C(x,f ` x))}
114 96c627d2815e Misc updates lcp parents: 111 diff changeset	1002	\ttbreak
104 d8205bb279a7 Initial revision lcp parents: diff changeset	1003	{\out 1. !!uu x.}
d8205bb279a7 Initial revision lcp parents: diff changeset	1004	{\out [\| uu : PROD x:A. SUM y:B(x). C(x,y); x : A \|] ==>}
d8205bb279a7 Initial revision lcp parents: diff changeset	1005	{\out ?b7(uu,x) : B(x)}
114 96c627d2815e Misc updates lcp parents: 111 diff changeset	1006	\ttbreak
104 d8205bb279a7 Initial revision lcp parents: diff changeset	1007	{\out 2. !!uu x.}
d8205bb279a7 Initial revision lcp parents: diff changeset	1008	{\out [\| uu : PROD x:A. SUM y:B(x). C(x,y); x : A \|] ==>}
d8205bb279a7 Initial revision lcp parents: diff changeset	1009	{\out ?b8(uu,x) : C(x,(lam x. ?b7(uu,x)) ` x)}
d8205bb279a7 Initial revision lcp parents: diff changeset	1010	\end{ttbox}
d8205bb279a7 Initial revision lcp parents: diff changeset	1011	Subgoal~1 asks to find the choice function itself, taking $x\in A$ to some
d8205bb279a7 Initial revision lcp parents: diff changeset	1012	$\Var{b@7}(uu,x)\in B(x)$. Subgoal~2 asks, given $x\in A$, for a proof
d8205bb279a7 Initial revision lcp parents: diff changeset	1013	object $\Var{b@8}(uu,x)$ to witness that the choice function's argument
d8205bb279a7 Initial revision lcp parents: diff changeset	1014	and result lie in the relation~$C$.
d8205bb279a7 Initial revision lcp parents: diff changeset	1015	\index{ProdE}\index{SumE_fst}\index{*RS}
d8205bb279a7 Initial revision lcp parents: diff changeset	1016	\begin{ttbox}
d8205bb279a7 Initial revision lcp parents: diff changeset	1017	by (eresolve_tac [ProdE RS SumE_fst] 1);
d8205bb279a7 Initial revision lcp parents: diff changeset	1018	{\out Level 2}
d8205bb279a7 Initial revision lcp parents: diff changeset	1019	{\out lam x. <lam xa. fst(x ` xa),lam xa. ?b8(x,xa)>}
d8205bb279a7 Initial revision lcp parents: diff changeset	1020	{\out : (PROD x:A. SUM y:B(x). C(x,y)) -->}
d8205bb279a7 Initial revision lcp parents: diff changeset	1021	{\out (SUM f:PROD x:A. B(x). PROD x:A. C(x,f ` x))}
114 96c627d2815e Misc updates lcp parents: 111 diff changeset	1022	\ttbreak
104 d8205bb279a7 Initial revision lcp parents: diff changeset	1023	{\out 1. !!uu x. x : A ==> x : A}
d8205bb279a7 Initial revision lcp parents: diff changeset	1024	{\out 2. !!uu x.}
d8205bb279a7 Initial revision lcp parents: diff changeset	1025	{\out [\| uu : PROD x:A. SUM y:B(x). C(x,y); x : A \|] ==>}
d8205bb279a7 Initial revision lcp parents: diff changeset	1026	{\out ?b8(uu,x) : C(x,(lam x. fst(uu ` x)) ` x)}
d8205bb279a7 Initial revision lcp parents: diff changeset	1027	\end{ttbox}
d8205bb279a7 Initial revision lcp parents: diff changeset	1028	Above, we have composed \ttindex{fst} with the function~$h$ (named~$uu$ in
d8205bb279a7 Initial revision lcp parents: diff changeset	1029	the assumptions). Unification has deduced that the function must be
d8205bb279a7 Initial revision lcp parents: diff changeset	1030	applied to $x\in A$.
d8205bb279a7 Initial revision lcp parents: diff changeset	1031	\begin{ttbox}
d8205bb279a7 Initial revision lcp parents: diff changeset	1032	by (assume_tac 1);
d8205bb279a7 Initial revision lcp parents: diff changeset	1033	{\out Level 3}
d8205bb279a7 Initial revision lcp parents: diff changeset	1034	{\out lam x. <lam xa. fst(x ` xa),lam xa. ?b8(x,xa)>}
d8205bb279a7 Initial revision lcp parents: diff changeset	1035	{\out : (PROD x:A. SUM y:B(x). C(x,y)) -->}
d8205bb279a7 Initial revision lcp parents: diff changeset	1036	{\out (SUM f:PROD x:A. B(x). PROD x:A. C(x,f ` x))}
d8205bb279a7 Initial revision lcp parents: diff changeset	1037	{\out 1. !!uu x.}
d8205bb279a7 Initial revision lcp parents: diff changeset	1038	{\out [\| uu : PROD x:A. SUM y:B(x). C(x,y); x : A \|] ==>}
d8205bb279a7 Initial revision lcp parents: diff changeset	1039	{\out ?b8(uu,x) : C(x,(lam x. fst(uu ` x)) ` x)}
d8205bb279a7 Initial revision lcp parents: diff changeset	1040	\end{ttbox}
d8205bb279a7 Initial revision lcp parents: diff changeset	1041	Before we can compose \ttindex{snd} with~$h$, the arguments of $C$ must be
d8205bb279a7 Initial revision lcp parents: diff changeset	1042	simplified. The derived rule \ttindex{replace_type} lets us replace a type
d8205bb279a7 Initial revision lcp parents: diff changeset	1043	by any equivalent type:
d8205bb279a7 Initial revision lcp parents: diff changeset	1044	\begin{ttbox}
d8205bb279a7 Initial revision lcp parents: diff changeset	1045	by (resolve_tac [replace_type] 1);
d8205bb279a7 Initial revision lcp parents: diff changeset	1046	{\out Level 4}
d8205bb279a7 Initial revision lcp parents: diff changeset	1047	{\out lam x. <lam xa. fst(x ` xa),lam xa. ?b8(x,xa)>}
d8205bb279a7 Initial revision lcp parents: diff changeset	1048	{\out : (PROD x:A. SUM y:B(x). C(x,y)) -->}
d8205bb279a7 Initial revision lcp parents: diff changeset	1049	{\out (SUM f:PROD x:A. B(x). PROD x:A. C(x,f ` x))}
114 96c627d2815e Misc updates lcp parents: 111 diff changeset	1050	\ttbreak
104 d8205bb279a7 Initial revision lcp parents: diff changeset	1051	{\out 1. !!uu x.}
d8205bb279a7 Initial revision lcp parents: diff changeset	1052	{\out [\| uu : PROD x:A. SUM y:B(x). C(x,y); x : A \|] ==>}
d8205bb279a7 Initial revision lcp parents: diff changeset	1053	{\out C(x,(lam x. fst(uu ` x)) ` x) = ?A13(uu,x)}
114 96c627d2815e Misc updates lcp parents: 111 diff changeset	1054	\ttbreak
104 d8205bb279a7 Initial revision lcp parents: diff changeset	1055	{\out 2. !!uu x.}
d8205bb279a7 Initial revision lcp parents: diff changeset	1056	{\out [\| uu : PROD x:A. SUM y:B(x). C(x,y); x : A \|] ==>}
d8205bb279a7 Initial revision lcp parents: diff changeset	1057	{\out ?b8(uu,x) : ?A13(uu,x)}
d8205bb279a7 Initial revision lcp parents: diff changeset	1058	\end{ttbox}
d8205bb279a7 Initial revision lcp parents: diff changeset	1059	The derived rule \ttindex{subst_eqtyparg} lets us simplify a type's
d8205bb279a7 Initial revision lcp parents: diff changeset	1060	argument (by currying, $C(x)$ is a unary type operator):
d8205bb279a7 Initial revision lcp parents: diff changeset	1061	\begin{ttbox}
d8205bb279a7 Initial revision lcp parents: diff changeset	1062	by (resolve_tac [subst_eqtyparg] 1);
d8205bb279a7 Initial revision lcp parents: diff changeset	1063	{\out Level 5}
d8205bb279a7 Initial revision lcp parents: diff changeset	1064	{\out lam x. <lam xa. fst(x ` xa),lam xa. ?b8(x,xa)>}
d8205bb279a7 Initial revision lcp parents: diff changeset	1065	{\out : (PROD x:A. SUM y:B(x). C(x,y)) -->}
d8205bb279a7 Initial revision lcp parents: diff changeset	1066	{\out (SUM f:PROD x:A. B(x). PROD x:A. C(x,f ` x))}
114 96c627d2815e Misc updates lcp parents: 111 diff changeset	1067	\ttbreak
104 d8205bb279a7 Initial revision lcp parents: diff changeset	1068	{\out 1. !!uu x.}
d8205bb279a7 Initial revision lcp parents: diff changeset	1069	{\out [\| uu : PROD x:A. SUM y:B(x). C(x,y); x : A \|] ==>}
d8205bb279a7 Initial revision lcp parents: diff changeset	1070	{\out (lam x. fst(uu ` x)) ` x = ?c14(uu,x) : ?A14(uu,x)}
114 96c627d2815e Misc updates lcp parents: 111 diff changeset	1071	\ttbreak
104 d8205bb279a7 Initial revision lcp parents: diff changeset	1072	{\out 2. !!uu x z.}
d8205bb279a7 Initial revision lcp parents: diff changeset	1073	{\out [\| uu : PROD x:A. SUM y:B(x). C(x,y); x : A;}
d8205bb279a7 Initial revision lcp parents: diff changeset	1074	{\out z : ?A14(uu,x) \|] ==>}
d8205bb279a7 Initial revision lcp parents: diff changeset	1075	{\out C(x,z) type}
114 96c627d2815e Misc updates lcp parents: 111 diff changeset	1076	\ttbreak
104 d8205bb279a7 Initial revision lcp parents: diff changeset	1077	{\out 3. !!uu x.}
d8205bb279a7 Initial revision lcp parents: diff changeset	1078	{\out [\| uu : PROD x:A. SUM y:B(x). C(x,y); x : A \|] ==>}
d8205bb279a7 Initial revision lcp parents: diff changeset	1079	{\out ?b8(uu,x) : C(x,?c14(uu,x))}
d8205bb279a7 Initial revision lcp parents: diff changeset	1080	\end{ttbox}
d8205bb279a7 Initial revision lcp parents: diff changeset	1081	The rule \ttindex{ProdC} is simply $\beta$-reduction. The term
d8205bb279a7 Initial revision lcp parents: diff changeset	1082	$\Var{c@{14}}(uu,x)$ receives the simplified form, $f{\tt`}x$.
d8205bb279a7 Initial revision lcp parents: diff changeset	1083	\begin{ttbox}
d8205bb279a7 Initial revision lcp parents: diff changeset	1084	by (resolve_tac [ProdC] 1);
d8205bb279a7 Initial revision lcp parents: diff changeset	1085	{\out Level 6}
d8205bb279a7 Initial revision lcp parents: diff changeset	1086	{\out lam x. <lam xa. fst(x ` xa),lam xa. ?b8(x,xa)>}
d8205bb279a7 Initial revision lcp parents: diff changeset	1087	{\out : (PROD x:A. SUM y:B(x). C(x,y)) -->}
d8205bb279a7 Initial revision lcp parents: diff changeset	1088	{\out (SUM f:PROD x:A. B(x). PROD x:A. C(x,f ` x))}
114 96c627d2815e Misc updates lcp parents: 111 diff changeset	1089	\ttbreak
104 d8205bb279a7 Initial revision lcp parents: diff changeset	1090	{\out 1. !!uu x.}
d8205bb279a7 Initial revision lcp parents: diff changeset	1091	{\out [\| uu : PROD x:A. SUM y:B(x). C(x,y); x : A \|] ==> x : ?A15(uu,x)}
114 96c627d2815e Misc updates lcp parents: 111 diff changeset	1092	\ttbreak
104 d8205bb279a7 Initial revision lcp parents: diff changeset	1093	{\out 2. !!uu x xa.}
d8205bb279a7 Initial revision lcp parents: diff changeset	1094	{\out [\| uu : PROD x:A. SUM y:B(x). C(x,y); x : A;}
d8205bb279a7 Initial revision lcp parents: diff changeset	1095	{\out xa : ?A15(uu,x) \|] ==>}
d8205bb279a7 Initial revision lcp parents: diff changeset	1096	{\out fst(uu ` xa) : ?B15(uu,x,xa)}
114 96c627d2815e Misc updates lcp parents: 111 diff changeset	1097	\ttbreak
104 d8205bb279a7 Initial revision lcp parents: diff changeset	1098	{\out 3. !!uu x z.}
d8205bb279a7 Initial revision lcp parents: diff changeset	1099	{\out [\| uu : PROD x:A. SUM y:B(x). C(x,y); x : A;}
d8205bb279a7 Initial revision lcp parents: diff changeset	1100	{\out z : ?B15(uu,x,x) \|] ==>}
d8205bb279a7 Initial revision lcp parents: diff changeset	1101	{\out C(x,z) type}
114 96c627d2815e Misc updates lcp parents: 111 diff changeset	1102	\ttbreak
104 d8205bb279a7 Initial revision lcp parents: diff changeset	1103	{\out 4. !!uu x.}
d8205bb279a7 Initial revision lcp parents: diff changeset	1104	{\out [\| uu : PROD x:A. SUM y:B(x). C(x,y); x : A \|] ==>}
d8205bb279a7 Initial revision lcp parents: diff changeset	1105	{\out ?b8(uu,x) : C(x,fst(uu ` x))}
d8205bb279a7 Initial revision lcp parents: diff changeset	1106	\end{ttbox}
d8205bb279a7 Initial revision lcp parents: diff changeset	1107	Routine type checking goals proliferate in Constructive Type Theory, but
d8205bb279a7 Initial revision lcp parents: diff changeset	1108	\ttindex{typechk_tac} quickly solves them. Note the inclusion of
d8205bb279a7 Initial revision lcp parents: diff changeset	1109	\ttindex{SumE_fst}.
d8205bb279a7 Initial revision lcp parents: diff changeset	1110	\begin{ttbox}
d8205bb279a7 Initial revision lcp parents: diff changeset	1111	by (typechk_tac (SumE_fst::prems));
d8205bb279a7 Initial revision lcp parents: diff changeset	1112	{\out Level 7}
d8205bb279a7 Initial revision lcp parents: diff changeset	1113	{\out lam x. <lam xa. fst(x ` xa),lam xa. ?b8(x,xa)>}
d8205bb279a7 Initial revision lcp parents: diff changeset	1114	{\out : (PROD x:A. SUM y:B(x). C(x,y)) -->}
d8205bb279a7 Initial revision lcp parents: diff changeset	1115	{\out (SUM f:PROD x:A. B(x). PROD x:A. C(x,f ` x))}
d8205bb279a7 Initial revision lcp parents: diff changeset	1116	{\out 1. !!uu x.}
d8205bb279a7 Initial revision lcp parents: diff changeset	1117	{\out [\| uu : PROD x:A. SUM y:B(x). C(x,y); x : A \|] ==>}
d8205bb279a7 Initial revision lcp parents: diff changeset	1118	{\out ?b8(uu,x) : C(x,fst(uu ` x))}
d8205bb279a7 Initial revision lcp parents: diff changeset	1119	\end{ttbox}
d8205bb279a7 Initial revision lcp parents: diff changeset	1120	We are finally ready to compose \ttindex{snd} with~$h$.
d8205bb279a7 Initial revision lcp parents: diff changeset	1121	\index{ProdE}\index{SumE_snd}\index{*RS}
d8205bb279a7 Initial revision lcp parents: diff changeset	1122	\begin{ttbox}
d8205bb279a7 Initial revision lcp parents: diff changeset	1123	by (eresolve_tac [ProdE RS SumE_snd] 1);
d8205bb279a7 Initial revision lcp parents: diff changeset	1124	{\out Level 8}
d8205bb279a7 Initial revision lcp parents: diff changeset	1125	{\out lam x. <lam xa. fst(x ` xa),lam xa. snd(x ` xa)>}
d8205bb279a7 Initial revision lcp parents: diff changeset	1126	{\out : (PROD x:A. SUM y:B(x). C(x,y)) -->}
d8205bb279a7 Initial revision lcp parents: diff changeset	1127	{\out (SUM f:PROD x:A. B(x). PROD x:A. C(x,f ` x))}
d8205bb279a7 Initial revision lcp parents: diff changeset	1128	{\out 1. !!uu x. x : A ==> x : A}
d8205bb279a7 Initial revision lcp parents: diff changeset	1129	{\out 2. !!uu x. x : A ==> B(x) type}
d8205bb279a7 Initial revision lcp parents: diff changeset	1130	{\out 3. !!uu x xa. [\| x : A; xa : B(x) \|] ==> C(x,xa) type}
d8205bb279a7 Initial revision lcp parents: diff changeset	1131	\end{ttbox}
d8205bb279a7 Initial revision lcp parents: diff changeset	1132	The proof object has reached its final form. We call \ttindex{typechk_tac}
d8205bb279a7 Initial revision lcp parents: diff changeset	1133	to finish the type checking.
d8205bb279a7 Initial revision lcp parents: diff changeset	1134	\begin{ttbox}
d8205bb279a7 Initial revision lcp parents: diff changeset	1135	by (typechk_tac prems);
d8205bb279a7 Initial revision lcp parents: diff changeset	1136	{\out Level 9}
d8205bb279a7 Initial revision lcp parents: diff changeset	1137	{\out lam x. <lam xa. fst(x ` xa),lam xa. snd(x ` xa)>}
d8205bb279a7 Initial revision lcp parents: diff changeset	1138	{\out : (PROD x:A. SUM y:B(x). C(x,y)) -->}
d8205bb279a7 Initial revision lcp parents: diff changeset	1139	{\out (SUM f:PROD x:A. B(x). PROD x:A. C(x,f ` x))}
d8205bb279a7 Initial revision lcp parents: diff changeset	1140	{\out No subgoals!}
d8205bb279a7 Initial revision lcp parents: diff changeset	1141	\end{ttbox}

author	lcp
	Fri, 12 Nov 1993 10:41:13 +0100
changeset 114	96c627d2815e
parent 111	1b3cddf41b2d
child 153	0deb993885ce
permissions	-rw-r--r--