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1 (* Title: HOL/Library/Old_SMT/z3_model.ML |
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2 Author: Sascha Boehme and Philipp Meyer, TU Muenchen |
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3 |
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4 Parser for counterexamples generated by Z3. |
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5 *) |
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6 |
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7 signature Z3_MODEL = |
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8 sig |
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9 val parse_counterex: Proof.context -> SMT_Translate.recon -> string list -> |
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10 term list * term list |
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11 end |
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12 |
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13 structure Z3_Model: Z3_MODEL = |
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14 struct |
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15 |
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16 |
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17 (* counterexample expressions *) |
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18 |
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19 datatype expr = True | False | Number of int * int option | Value of int | |
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20 Array of array | App of string * expr list |
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21 and array = Fresh of expr | Store of (array * expr) * expr |
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22 |
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23 |
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24 (* parsing *) |
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25 |
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26 val space = Scan.many Symbol.is_ascii_blank |
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27 fun spaced p = p --| space |
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28 fun in_parens p = spaced (Scan.$$ "(") |-- p --| spaced (Scan.$$ ")") |
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29 fun in_braces p = spaced (Scan.$$ "{") |-- p --| spaced (Scan.$$ "}") |
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30 |
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31 val digit = (fn |
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32 "0" => SOME 0 | "1" => SOME 1 | "2" => SOME 2 | "3" => SOME 3 | |
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33 "4" => SOME 4 | "5" => SOME 5 | "6" => SOME 6 | "7" => SOME 7 | |
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34 "8" => SOME 8 | "9" => SOME 9 | _ => NONE) |
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35 |
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36 val nat_num = spaced (Scan.repeat1 (Scan.some digit) >> |
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37 (fn ds => fold (fn d => fn i => i * 10 + d) ds 0)) |
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38 val int_num = spaced (Scan.optional ($$ "-" >> K (fn i => ~i)) I :|-- |
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39 (fn sign => nat_num >> sign)) |
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40 |
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41 val is_char = Symbol.is_ascii_letter orf Symbol.is_ascii_digit orf |
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42 member (op =) (raw_explode "_+*-/%~=<>$&|?!.@^#") |
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43 val name = spaced (Scan.many1 is_char >> implode) |
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44 |
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45 fun $$$ s = spaced (Scan.this_string s) |
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46 |
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47 fun array_expr st = st |> in_parens ( |
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48 $$$ "const" |-- expr >> Fresh || |
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49 $$$ "store" |-- array_expr -- expr -- expr >> Store) |
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50 |
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51 and expr st = st |> ( |
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52 $$$ "true" >> K True || |
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53 $$$ "false" >> K False || |
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54 int_num -- Scan.option ($$$ "/" |-- int_num) >> Number || |
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55 $$$ "val!" |-- nat_num >> Value || |
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56 name >> (App o rpair []) || |
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57 array_expr >> Array || |
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58 in_parens (name -- Scan.repeat1 expr) >> App) |
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59 |
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60 fun args st = ($$$ "->" >> K [] || expr ::: args) st |
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61 val args_case = args -- expr |
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62 val else_case = $$$ "else" -- $$$ "->" |-- expr >> pair ([] : expr list) |
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63 |
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64 val func = |
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65 let fun cases st = (else_case >> single || args_case ::: cases) st |
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66 in in_braces cases end |
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67 |
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68 val cex = space |-- |
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69 Scan.repeat (name --| $$$ "->" -- (func || expr >> (single o pair []))) |
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70 |
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71 fun resolve terms ((n, k), cases) = |
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72 (case Symtab.lookup terms n of |
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73 NONE => NONE |
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74 | SOME t => SOME ((t, k), cases)) |
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75 |
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76 fun annotate _ (_, []) = NONE |
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77 | annotate terms (n, [([], c)]) = resolve terms ((n, 0), (c, [])) |
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78 | annotate _ (_, [_]) = NONE |
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79 | annotate terms (n, cases as (args, _) :: _) = |
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80 let val (cases', (_, else_case)) = split_last cases |
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81 in resolve terms ((n, length args), (else_case, cases')) end |
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82 |
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83 fun read_cex terms ls = |
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84 maps (cons "\n" o raw_explode) ls |
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85 |> try (fst o Scan.finite Symbol.stopper cex) |
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86 |> the_default [] |
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87 |> map_filter (annotate terms) |
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88 |
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89 |
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90 (* translation into terms *) |
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91 |
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92 fun max_value vs = |
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93 let |
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94 fun max_val_expr (Value i) = Integer.max i |
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95 | max_val_expr (App (_, es)) = fold max_val_expr es |
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96 | max_val_expr (Array a) = max_val_array a |
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97 | max_val_expr _ = I |
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98 |
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99 and max_val_array (Fresh e) = max_val_expr e |
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100 | max_val_array (Store ((a, e1), e2)) = |
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101 max_val_array a #> max_val_expr e1 #> max_val_expr e2 |
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102 |
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103 fun max_val (_, (ec, cs)) = |
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104 max_val_expr ec #> fold (fn (es, e) => fold max_val_expr (e :: es)) cs |
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105 |
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106 in fold max_val vs ~1 end |
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107 |
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108 fun with_context terms f vs = fst (fold_map f vs (terms, max_value vs + 1)) |
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109 |
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110 fun get_term n T es (cx as (terms, next_val)) = |
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111 (case Symtab.lookup terms n of |
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112 SOME t => ((t, es), cx) |
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113 | NONE => |
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114 let val t = Var (("skolem", next_val), T) |
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115 in ((t, []), (Symtab.update (n, t) terms, next_val + 1)) end) |
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116 |
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117 fun trans_expr _ True = pair @{const True} |
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118 | trans_expr _ False = pair @{const False} |
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119 | trans_expr T (Number (i, NONE)) = pair (HOLogic.mk_number T i) |
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120 | trans_expr T (Number (i, SOME j)) = |
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121 pair (Const (@{const_name divide}, [T, T] ---> T) $ |
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122 HOLogic.mk_number T i $ HOLogic.mk_number T j) |
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123 | trans_expr T (Value i) = pair (Var (("value", i), T)) |
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124 | trans_expr T (Array a) = trans_array T a |
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125 | trans_expr T (App (n, es)) = get_term n T es #-> (fn (t, es') => |
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126 let val Ts = fst (SMT_Utils.dest_funT (length es') (Term.fastype_of t)) |
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127 in |
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128 fold_map (uncurry trans_expr) (Ts ~~ es') #>> Term.list_comb o pair t |
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129 end) |
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130 |
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131 and trans_array T a = |
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132 let val (dT, rT) = Term.dest_funT T |
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133 in |
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134 (case a of |
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135 Fresh e => trans_expr rT e #>> (fn t => Abs ("x", dT, t)) |
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136 | Store ((a', e1), e2) => |
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137 trans_array T a' ##>> trans_expr dT e1 ##>> trans_expr rT e2 #>> |
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138 (fn ((m, k), v) => |
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139 Const (@{const_name fun_upd}, [T, dT, rT] ---> T) $ m $ k $ v)) |
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140 end |
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141 |
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142 fun trans_pattern T ([], e) = trans_expr T e #>> pair [] |
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143 | trans_pattern T (arg :: args, e) = |
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144 trans_expr (Term.domain_type T) arg ##>> |
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145 trans_pattern (Term.range_type T) (args, e) #>> |
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146 (fn (arg', (args', e')) => (arg' :: args', e')) |
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147 |
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148 fun mk_fun_upd T U = Const (@{const_name fun_upd}, [T --> U, T, U, T] ---> U) |
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149 |
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150 fun mk_update ([], u) _ = u |
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151 | mk_update ([t], u) f = |
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152 uncurry mk_fun_upd (Term.dest_funT (Term.fastype_of f)) $ f $ t $ u |
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153 | mk_update (t :: ts, u) f = |
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154 let |
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155 val (dT, rT) = Term.dest_funT (Term.fastype_of f) |
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156 val (dT', rT') = Term.dest_funT rT |
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157 in |
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158 mk_fun_upd dT rT $ f $ t $ |
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159 mk_update (ts, u) (absdummy dT' (Const ("_", rT'))) |
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160 end |
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161 |
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162 fun mk_lambda Ts (t, pats) = |
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163 fold_rev absdummy Ts t |> fold mk_update pats |
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164 |
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165 fun translate ((t, k), (e, cs)) = |
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166 let |
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167 val T = Term.fastype_of t |
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168 val (Us, U) = SMT_Utils.dest_funT k (Term.fastype_of t) |
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169 |
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170 fun mk_full_def u' pats = |
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171 pats |
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172 |> filter_out (fn (_, u) => u aconv u') |
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173 |> HOLogic.mk_eq o pair t o mk_lambda Us o pair u' |
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174 |
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175 fun mk_eq (us, u) = HOLogic.mk_eq (Term.list_comb (t, us), u) |
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176 fun mk_eqs u' [] = [HOLogic.mk_eq (t, u')] |
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177 | mk_eqs _ pats = map mk_eq pats |
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178 in |
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179 trans_expr U e ##>> |
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180 (if k = 0 then pair [] else fold_map (trans_pattern T) cs) #>> |
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181 (fn (u', pats) => (mk_eqs u' pats, mk_full_def u' pats)) |
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182 end |
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183 |
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184 |
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185 (* normalization *) |
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186 |
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187 fun partition_eqs f = |
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188 let |
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189 fun part t (xs, ts) = |
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190 (case try HOLogic.dest_eq t of |
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191 SOME (l, r) => (case f l r of SOME x => (x::xs, ts) | _ => (xs, t::ts)) |
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192 | NONE => (xs, t :: ts)) |
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193 in (fn ts => fold part ts ([], [])) end |
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194 |
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195 fun first_eq pred = |
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196 let |
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197 fun part _ [] = NONE |
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198 | part us (t :: ts) = |
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199 (case try (pred o HOLogic.dest_eq) t of |
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200 SOME (SOME lr) => SOME (lr, fold cons us ts) |
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201 | _ => part (t :: us) ts) |
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202 in (fn ts => part [] ts) end |
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203 |
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204 fun replace_vars tab = |
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205 let |
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206 fun repl v = the_default v (AList.lookup (op aconv) tab v) |
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207 fun replace (v as Var _) = repl v |
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208 | replace (v as Free _) = repl v |
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209 | replace t = t |
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210 in map (Term.map_aterms replace) end |
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211 |
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212 fun remove_int_nat_coercions (eqs, defs) = |
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213 let |
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214 fun mk_nat_num t i = |
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215 (case try HOLogic.dest_number i of |
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216 SOME (_, n) => SOME (t, HOLogic.mk_number @{typ nat} n) |
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217 | NONE => NONE) |
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218 fun nat_of (@{const of_nat (int)} $ (t as Var _)) i = mk_nat_num t i |
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219 | nat_of (@{const nat} $ i) (t as Var _) = mk_nat_num t i |
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220 | nat_of _ _ = NONE |
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221 val (nats, eqs') = partition_eqs nat_of eqs |
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222 |
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223 fun is_coercion t = |
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224 (case try HOLogic.dest_eq t of |
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225 SOME (@{const of_nat (int)}, _) => true |
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226 | SOME (@{const nat}, _) => true |
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227 | _ => false) |
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228 in pairself (replace_vars nats) (eqs', filter_out is_coercion defs) end |
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229 |
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230 fun unfold_funapp (eqs, defs) = |
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231 let |
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232 fun unfold_app (Const (@{const_name fun_app}, _) $ f $ t) = f $ t |
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233 | unfold_app t = t |
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234 fun unfold_eq ((eq as Const (@{const_name HOL.eq}, _)) $ t $ u) = |
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235 eq $ unfold_app t $ u |
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236 | unfold_eq t = t |
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237 |
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238 fun is_fun_app t = |
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239 (case try HOLogic.dest_eq t of |
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240 SOME (Const (@{const_name fun_app}, _), _) => true |
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241 | _ => false) |
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242 |
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243 in (map unfold_eq eqs, filter_out is_fun_app defs) end |
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244 |
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245 val unfold_eqs = |
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246 let |
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247 val is_ground = not o Term.exists_subterm Term.is_Var |
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248 fun is_non_rec (v, t) = not (Term.exists_subterm (equal v) t) |
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249 |
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250 fun rewr_var (l as Var _, r) = if is_ground r then SOME (l, r) else NONE |
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251 | rewr_var (r, l as Var _) = if is_ground r then SOME (l, r) else NONE |
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252 | rewr_var _ = NONE |
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253 |
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254 fun rewr_free' e = if is_non_rec e then SOME e else NONE |
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255 fun rewr_free (e as (Free _, _)) = rewr_free' e |
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256 | rewr_free (e as (_, Free _)) = rewr_free' (swap e) |
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257 | rewr_free _ = NONE |
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258 |
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259 fun is_trivial (Const (@{const_name HOL.eq}, _) $ t $ u) = t aconv u |
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260 | is_trivial _ = false |
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261 |
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262 fun replace r = replace_vars [r] #> filter_out is_trivial |
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263 |
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264 fun unfold_vars (es, ds) = |
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265 (case first_eq rewr_var es of |
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266 SOME (lr, es') => unfold_vars (pairself (replace lr) (es', ds)) |
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267 | NONE => (es, ds)) |
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268 |
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269 fun unfold_frees ues (es, ds) = |
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270 (case first_eq rewr_free es of |
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271 SOME (lr, es') => |
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272 pairself (replace lr) (es', ds) |
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273 |> unfold_frees (HOLogic.mk_eq lr :: replace lr ues) |
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274 | NONE => (ues @ es, ds)) |
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275 |
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276 in unfold_vars #> unfold_frees [] end |
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277 |
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278 fun swap_free ((eq as Const (@{const_name HOL.eq}, _)) $ t $ (u as Free _)) = |
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279 eq $ u $ t |
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280 | swap_free t = t |
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281 |
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282 fun frees_for_vars ctxt (eqs, defs) = |
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283 let |
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284 fun fresh_free i T (cx as (frees, ctxt)) = |
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285 (case Inttab.lookup frees i of |
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286 SOME t => (t, cx) |
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287 | NONE => |
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288 let |
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289 val (n, ctxt') = yield_singleton Variable.variant_fixes "" ctxt |
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290 val t = Free (n, T) |
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291 in (t, (Inttab.update (i, t) frees, ctxt')) end) |
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292 |
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293 fun repl_var (Var ((_, i), T)) = fresh_free i T |
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294 | repl_var (t $ u) = repl_var t ##>> repl_var u #>> op $ |
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295 | repl_var (Abs (n, T, t)) = repl_var t #>> (fn t' => Abs (n, T, t')) |
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296 | repl_var t = pair t |
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297 in |
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298 (Inttab.empty, ctxt) |
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299 |> fold_map repl_var eqs |
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300 ||>> fold_map repl_var defs |
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301 |> fst |
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302 end |
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303 |
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304 |
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305 (* overall procedure *) |
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306 |
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307 val is_free_constraint = Term.exists_subterm (fn Free _ => true | _ => false) |
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308 |
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309 fun is_free_def (Const (@{const_name HOL.eq}, _) $ Free _ $ _) = true |
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310 | is_free_def _ = false |
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311 |
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312 fun defined tp = |
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313 try (pairself (fst o HOLogic.dest_eq)) tp |
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314 |> the_default false o Option.map (op aconv) |
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315 |
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316 fun add_free_defs free_cs defs = |
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317 let val (free_defs, defs') = List.partition is_free_def defs |
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318 in (free_cs @ filter_out (member defined free_cs) free_defs, defs') end |
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319 |
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320 fun is_const_def (Const (@{const_name HOL.eq}, _) $ Const _ $ _) = true |
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321 | is_const_def _ = false |
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322 |
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323 fun parse_counterex ctxt ({terms, ...} : SMT_Translate.recon) ls = |
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324 read_cex terms ls |
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325 |> with_context terms translate |
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326 |> apfst flat o split_list |
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327 |> remove_int_nat_coercions |
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328 |> unfold_funapp |
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329 |> unfold_eqs |
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330 |>> map swap_free |
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331 |>> filter is_free_constraint |
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332 |-> add_free_defs |
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333 |> frees_for_vars ctxt |
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334 ||> filter is_const_def |
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335 |
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336 end |
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337 |