/usr/share/hol88-2.02.19940316/Library/trs/sidecond.ml is in hol88-library-source 2.02.19940316-19.
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1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 20 21 22 23 24 25 26 27 28 29 30 31 32 33 34 35 36 37 38 39 40 41 42 43 44 45 46 47 48 49 50 51 52 53 54 55 56 57 58 59 60 61 62 63 64 65 66 67 68 69 70 71 72 73 74 75 76 77 78 79 80 81 82 83 84 85 86 87 88 89 90 91 92 93 94 95 96 97 98 99 100 101 102 103 104 105 106 107 108 109 110 111 112 113 114 115 116 117 118 119 120 121 122 123 124 125 126 127 128 129 130 131 132 133 134 135 136 137 138 139 140 141 142 143 144 145 146 147 148 149 150 151 152 153 154 155 156 157 158 159 160 161 162 163 164 165 166 167 168 169 170 171 172 173 174 175 176 177 178 179 180 181 182 183 184 185 186 187 188 189 190 191 192 193 194 195 196 197 198 199 200 201 202 203 204 205 206 207 208 209 210 211 212 213 214 215 216 217 218 219 220 221 222 223 224 225 226 227 228 229 230 231 232 233 234 235 236 237 238 239 240 241 242 243 244 245 246 247 248 249 250 251 252 253 254 255 256 257 258 259 | % sidecond.ml (c) R.J.Boulton 1990 %
%----------------------------------------------------------------------------%
% Function to create a `result_of_match' of all the ways of matching a %
% termpattern within a term. %
% The function tries to match the termpattern against the term. If this is %
% successful the resulting matching is made the first item of the %
% `result_of_match'. The rest of the `result_of_match' will be null if `t' %
% is a variable or a constant, since `t' cannot be split in such cases. %
% If `t' is an abstraction, a match is tried against the body. If `t' is a %
% combination, matches are tried against both the rator and the rand. Both %
% these return `result_of_matches' which have to be appended using the %
% function `approms'. %
% Note that the function requires a null argument before it actually does %
% any evaluation. This is to keep the computation as lazy as possible. %
letrec containsfn p t () =
% : (termpattern -> term -> void -> result_of_match) %
let rest () =
if (is_const t) then Nomatch
if (is_var t) then Nomatch
if (is_abs t) then (containsfn p ((snd o dest_abs) t) () )
if (is_comb t) then (approms
(containsfn p (rator t))
(containsfn p (rand t))
()
)
else fail
in (Match (make_matching p t,rest)) ??[`no match`] (rest ());;
% Functions which make theorem patterns which are side-conditions %
% `Contains' looks up its first argument in the matching given as argument %
% to the side-condition. A `result_of_match' is formed from the termpattern %
% and the term bound to `w', by testing the termpattern for containment %
% within the term. %
ml_curried_infix `Contains`;;
let w Contains p =
% : (wildvar -> termpattern -> thmpattern) %
Side (\m . containsfn p (match_of_var m w) () );;
% `contains' behaves as for `Contains' except that its arguments are given %
% as terms rather than as a wildvar and a termpattern. The terms are made %
% into a wildvar and a termpattern using default wildcards. %
ml_curried_infix `contains`;;
let t contains t' =
% : (term -> term -> thmpattern) %
(make_wildvar t) Contains (autotermpattern t');;
% `Matches' looks up its first argument in the matching given as argument %
% to the side-condition. A `result_of_match' is formed from the termpattern %
% and the term bound to `w', by testing the termpattern against the term. If %
% the match is successful, the matching becomes the first and only element of %
% the `result_of_match'. If not the `result_of_match' is `Nomatch'. %
ml_curried_infix `Matches`;;
let w Matches p =
% : (wildvar -> termpattern -> thmpattern) %
Side (\m . ( Match (make_matching p (match_of_var m w), (\().Nomatch))
?? [`no match`] Nomatch
)
);;
% `matches' behaves as for `Matches' except that its arguments are given as %
% terms rather than as a wildvar and a termpattern. The terms are made into a %
% wildvar and a termpattern using default wildcards. %
ml_curried_infix `matches`;;
let t matches t' =
% : (term -> term -> thmpattern) %
(make_wildvar t) Matches (autotermpattern t');;
% Function to split a bound term into the bound variable and the body %
% The bindings are represented by applications of function constants to %
% lambda-abstractions. Hence the need to destroy a combination, followed by %
% (if the operator is a binder) destruction of an abstraction. %
let dest_binder t =
% : (term -> (term # term)) %
(let (t1,t2) = dest_comb t
in if (is_binder (fst (dest_const t1)))
then dest_abs t2
else fail
) ? failwith `dest_binder`;;
% Function to strip all binders from the beginning of a term %
% The function repeatedly strips one binder until the process fails. %
letrec strip_binders t =
% : (term -> term) %
((strip_binders o snd o dest_binder) t) ? t;;
% `Has_body' looks up its first argument in the matching given as argument %
% to the side-condition. The bound term then has any binders stripped from %
% the front of it. A `result_of_match' is formed from the termpattern and the %
% processed term by testing the termpattern against the term. If the match is %
% successful, the matching becomes the first and only element of the %
% `result_of_match'. If not the `result_of_match' is `Nomatch'. %
ml_curried_infix `Has_body`;;
let w Has_body p =
% : (wildvar -> termpattern -> thmpattern) %
Side (\m . ( Match (make_matching p (strip_binders (match_of_var m w)),
(\().Nomatch))
?? [`no match`] Nomatch
)
);;
% `has_body' behaves as for `Has_body' except that its arguments are given %
% as terms rather than as a wildvar and a termpattern. The terms are made %
% into a wildvar and a termpattern using default wildcards. %
ml_curried_infix `has_body`;;
let t has_body t' =
% : (term -> term -> thmpattern) %
(make_wildvar t) Has_body (autotermpattern t');;
%----------------------------------------------------------------------------%
% Functions which construct a side-condition as a theorem pattern %
% This one builds a side-condition which looks up the binding of `w' in the %
% matching given as argument to the side-condition. It then applies `f' to %
% the bound `term', and converts the resulting Boolean value to a value of %
% type `result_of_match'. The latter becomes the result of the %
% side-condition test. %
let Test1term f w =
% : ((term -> bool) -> wildvar -> thmpattern) %
Side (\m . (bool_to_rom o f) (match_of_var m w));;
% `test1term' behaves as for `Test1term' except that its second argument is %
% given as a `term'. The `term' is automatically converted to a `wildvar'. %
let test1term f t =
% : ((term -> bool) -> term -> thmpattern) %
Test1term f (make_wildvar t);;
% This one builds a side-condition which looks up the binding of `w' in the %
% matching given as argument to the side-condition. It then applies `f' to %
% the bound `type', and converts the resulting Boolean value to a value of %
% type `result_of_match'. The latter becomes the result of the %
% side-condition test. %
let Test1type f w =
% : ((type -> bool) -> wildtype -> thmpattern) %
Side (\m . (bool_to_rom o f) (match_of_type m w));;
% `test1type' behaves as for `Test1type' except that its second argument is %
% given as a `type'. The `type' is automatically converted to a `wildtype'. %
let test1type f t =
% : ((type -> bool) -> type -> thmpattern) %
Test1type f (make_wildtype t);;
% This one builds a side-condition which looks up the bindings of `w1' and %
% `w2' in the matching given as argument to the side-condition. It then %
% applies `f' to the two bound `terms', and converts the resulting Boolean %
% value to a value of type `result_of_match'. The latter becomes the result %
% of the side-condition test. %
let Test2terms f w1 w2 =
% : ((term -> term -> bool) -> wildvar -> wildvar -> thmpattern) %
Side (\m . bool_to_rom (f (match_of_var m w1) (match_of_var m w2)));;
% `test2terms' behaves as for `Test2terms' except that its second and third %
% arguments are given as `terms'. The `terms' are automatically converted %
% to `wildvars'. %
let test2terms f t1 t2 =
% : ((term -> term -> bool) -> term -> term -> thmpattern) %
Test2terms f (make_wildvar t1) (make_wildvar t2);;
% This one builds a side-condition which looks up the bindings of `w1' and %
% `w2' in the matching given as argument to the side-condition. It then %
% applies `f' to the two bound `types', and converts the resulting Boolean %
% value to a value of type `result_of_match'. The latter becomes the result %
% of the side-condition test. %
let Test2types f w1 w2 =
% : ((type -> type -> bool) -> wildtype -> wildtype -> thmpattern) %
Side (\m . bool_to_rom (f (match_of_type m w1) (match_of_type m w2)));;
% `test2types' behaves as for `Test2types' except that its second and third %
% arguments are given as `types'. The `types' are automatically converted %
% to `wildtypes'. %
let test2types f t1 t2 =
% : ((type -> type -> bool) -> type -> type -> thmpattern) %
Test2types f (make_wildtype t1) (make_wildtype t2);;
%----------------------------------------------------------------------------%
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