package codex
The Codex library for building static analysers based on abstract interpretation
Install
dune-project
Dependency
Authors
Maintainers
Sources
1.0-rc4.tar.gz
md5=bc7266a140c6886add673ede90e335d3
sha512=8da42c0ff2c1098c5f9cb2b5b43b306faf7ac93b8f5ae00c176918cee761f249ff45b29309f31a05bbcf6312304f86a0d5a000eb3f1094d3d3c2b9b4c7f5c386
doc/src/codex.syntax_tree/syntax_tree.ml.html
Source file syntax_tree.ml
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(**************************************************************************) (* This file is part of the Codex semantics library. *) (* *) (* Copyright (C) 2013-2025 *) (* CEA (Commissariat à l'énergie atomique et aux énergies *) (* alternatives) *) (* *) (* you can redistribute it and/or modify it under the terms of the GNU *) (* Lesser General Public License as published by the Free Software *) (* Foundation, version 2.1. *) (* *) (* It is distributed in the hope that it will be useful, *) (* but WITHOUT ANY WARRANTY; without even the implied warranty of *) (* MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the *) (* GNU Lesser General Public License for more details. *) (* *) (* See the GNU Lesser General Public License version 2.1 *) (* for more details (enclosed in the file LICENSE). *) (* *) (**************************************************************************) type ar1_format = {prefix:string;suffix:string} type ar2_format = {prefix:string;middle:string;suffix:string} type ar3_format = {prefix:string;middle1:string;middle2:string;suffix:string} (* TODO: arn. *) type expr = |Ar0 of {s:string} |Ar1 of {format:ar1_format; arg:expr} |Ar2 of {format:ar2_format; arg1:expr; arg2:expr} |Ar3 of {format:ar3_format; arg1:expr; arg2:expr; arg3:expr} |Ite of {cond:expr; then_expr:expr; else_expr: expr} type expr_path = int list let rec equal_expr e1 e2 = match e1, e2 with | _ when e1 == e2 -> true | Ar0 {s=s1}, Ar0 {s=s2} -> s1 = s2 | Ar1 {format=format1; arg=arg1}, Ar1 {format=format2; arg=arg2} -> (format1 == format2 || format1 = format2) && equal_expr arg1 arg2 | Ar2 {format=formata; arg1=arg1a;arg2=arg2a}, Ar2 {format=formatb; arg1=arg1b;arg2=arg2b} -> (formata == formatb || formata = formatb) && equal_expr arg1a arg1b && equal_expr arg2a arg2b | Ar3 {format=formata; arg1=arg1a;arg2=arg2a;arg3=arg3a}, Ar3 {format=formatb; arg1=arg1b;arg2=arg2b;arg3=arg3b} -> (formata == formatb || formata = formatb) && equal_expr arg1a arg1b && equal_expr arg2a arg2b && equal_expr arg3a arg3b | Ite {cond=c1;then_expr=t1;else_expr=e1}, Ite {cond=c2;then_expr=t2;else_expr=e2} -> equal_expr c1 c2 && equal_expr t1 t2 && equal_expr c1 c2 | _ -> false let arity = function | Ar0 _ -> 0 | Ar1 _ -> 1 | Ar2 _ -> 2 | Ar3 _ -> 3 | Ite _ -> 3 let isdeep expr = match expr with |Ar0 {s} -> String.contains s ' ' |Ar1 {format; arg} -> true |Ar2 _ -> true |Ar3 _ -> true |Ite _ -> true let rec string_of_expr_impl display_par expr = (if display_par then "(" else "") ^ (match expr with |Ar0 {s} -> s |Ar1 {format={prefix;suffix}; arg} -> prefix ^ (string_of_expr_impl (isdeep arg) arg) ^ suffix |Ar2 {format={prefix;middle;suffix}; arg1;arg2} -> prefix ^ (string_of_expr_impl (isdeep arg1) arg1) ^ middle ^ (string_of_expr_impl (isdeep arg2) arg2) ^ suffix |Ar3 {format={prefix;middle1;middle2;suffix}; arg1;arg2;arg3} -> prefix ^ (string_of_expr_impl (isdeep arg1) arg1) ^ middle1 ^ (string_of_expr_impl (isdeep arg2) arg2) ^ middle2 ^ (string_of_expr_impl (isdeep arg2) arg3) ^ suffix |Ite {cond:expr; then_expr:expr; else_expr: expr} -> string_of_expr_impl (isdeep cond) cond ^ " ? " ^ string_of_expr_impl (isdeep then_expr) then_expr ^ " : " ^ string_of_expr_impl (isdeep else_expr) else_expr ) ^ (if display_par then ")" else "") let string_of_expr expr = string_of_expr_impl false expr module Hashcons = struct (* TODO: We could be hash-consing the format too. *) module ExprH = Weak.Make(struct type t = expr let equal = equal_expr let hash = Hashtbl.hash end) let expr_h = ExprH.create 17 let rec hashcons x = try ExprH.find expr_h x with Not_found -> begin let x = match x with | Ar0{s} -> x | Ar1{format;arg} -> Ar1{format;arg = hashcons arg} | Ar2{format;arg1;arg2} -> Ar2{format;arg1 = hashcons arg1; arg2 = hashcons arg2} | Ar3{format;arg1;arg2;arg3} -> Ar3{format;arg1 = hashcons arg1; arg2 = hashcons arg2; arg3 = hashcons arg3} | Ite{cond;then_expr;else_expr} -> Ite{cond = hashcons cond; then_expr = hashcons then_expr; else_expr = hashcons else_expr} in ExprH.add expr_h x; x end end let hashcons = Hashcons.hashcons module Location_identifier = struct type path = | Name of string | Int64 of int64 | Inside: {locid:'b t;idx:int} -> path and 'a kind = | Address | Expression | DbaInstruction (* | Instruction *) (* | Symbol *) (* | Function *) (* | Type *) and 'a t = 'a kind * path type any = Any: 'a t -> any [@@unboxed] let equal_kind: type a b. a kind -> b kind -> bool = fun a b -> assert(Obj.is_int @@ Obj.repr a); assert(Obj.is_int @@ Obj.repr b); Int.equal (Obj.magic a) (Obj.magic b) let rec equal: type a b. a t -> b t -> bool = fun (ka,pa) (kb,pb) -> equal_kind ka kb && equal_path pa pb and equal_path a b = match a,b with | Name sa, Name sb -> String.equal sa sb | Int64 ia, Int64 ib -> Int64.equal ia ib | Inside{locid=locida;idx=idxa},Inside{locid=locidb;idx=idxb} -> idxa = idxb && equal locida locidb | Name _, (Int64 _ | Inside _) | (Int64 _ | Inside _), Name _ -> false | Int64 _, Inside _ | Inside _, Int64 _ -> false let hash = Hashtbl.hash end type 'a located = 'a * 'a Location_identifier.t