package catala
Low-level language for tax code specification
Install
Dune Dependency
Authors
Maintainers
Sources
0.3.0.tar.gz
md5=4a2c5495f30d8fc2e3bf977df6e602f9
sha512=8dcc404b6068b9dbd76982ade60d8fba1950fdd0a8a626db17429120483367dce1f51997e96d7b8ee5308f305c3bcbb897ef85336f25e9ef3681f4cb9237f56a
doc/src/catala.desugared/dependency.ml.html
Source file dependency.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 99 100 101 102 103 104 105 106 107 108 109 110 111 112 113 114 115 116 117 118 119 120 121 122 123 124 125 126 127 128 129 130 131 132 133 134 135 136 137 138 139 140 141 142 143 144 145 146 147 148 149 150 151 152 153 154 155 156 157 158 159 160 161 162 163 164 165 166 167 168 169 170 171 172 173 174 175 176 177 178 179 180 181 182 183 184 185 186 187 188 189 190 191 192 193 194 195 196 197 198 199 200 201 202 203 204 205 206 207 208 209 210 211 212 213 214 215 216 217 218 219 220 221 222 223 224 225 226 227 228 229 230 231 232 233 234 235 236 237 238 239 240 241 242 243 244 245 246 247 248 249 250 251 252 253 254 255 256 257(* This file is part of the Catala compiler, a specification language for tax and social benefits computation rules. Copyright (C) 2020 Inria, contributor: Nicolas Chataing <nicolas.chataing@ens.fr> Licensed under the Apache License, Version 2.0 (the "License"); you may not use this file except in compliance with the License. You may obtain a copy of the License at http://www.apache.org/licenses/LICENSE-2.0 Unless required by applicable law or agreed to in writing, software distributed under the License is distributed on an "AS IS" BASIS, WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied. See the License for the specific language governing permissions and limitations under the License. *) (** Scope dependencies computations using {{:http://ocamlgraph.lri.fr/} OCamlgraph} *) open Utils (** {1 Scope variables dependency graph} *) (** {2 Graph declaration} *) (** Vertices: scope variables or subscopes. The vertices of the scope dependency graph are either : - the variables of the scope ; - the subscopes of the scope. Indeed, during interpretation, subscopes are executed atomically. *) module Vertex = struct type t = Var of Scopelang.Ast.ScopeVar.t | SubScope of Scopelang.Ast.SubScopeName.t let hash x = match x with | Var x -> Scopelang.Ast.ScopeVar.hash x | SubScope x -> Scopelang.Ast.SubScopeName.hash x let compare = compare let equal x y = match (x, y) with | Var x, Var y -> Scopelang.Ast.ScopeVar.compare x y = 0 | SubScope x, SubScope y -> Scopelang.Ast.SubScopeName.compare x y = 0 | _ -> false let format_t (fmt : Format.formatter) (x : t) : unit = match x with | Var v -> Scopelang.Ast.ScopeVar.format_t fmt v | SubScope v -> Scopelang.Ast.SubScopeName.format_t fmt v end (** On the edges, the label is the position of the expression responsible for the use of the variable. In the graph, [x -> y] if [x] is used in the definition of [y].*) module Edge = struct type t = Pos.t let compare = compare let default = Pos.no_pos end module ScopeDependencies = Graph.Persistent.Digraph.ConcreteBidirectionalLabeled (Vertex) (Edge) (** Module of the graph, provided by OCamlGraph *) module TopologicalTraversal = Graph.Topological.Make (ScopeDependencies) (** Module of the topological traversal of the graph, provided by OCamlGraph *) module SCC = Graph.Components.Make (ScopeDependencies) (** Tarjan's stongly connected components algorithm, provided by OCamlGraph *) (** {2 Graph computations} *) (** Returns an ordering of the scope variables and subscope compatible with the dependencies of the computation *) let correct_computation_ordering (g : ScopeDependencies.t) : Vertex.t list = List.rev (TopologicalTraversal.fold (fun sd acc -> sd :: acc) g []) (** Outputs an error in case of cycles. *) let check_for_cycle (scope : Ast.scope) (g : ScopeDependencies.t) : unit = (* if there is a cycle, there will be an strongly connected component of cardinality > 1 *) let sccs = SCC.scc_list g in if List.length sccs < ScopeDependencies.nb_vertex g then let scc = List.find (fun scc -> List.length scc > 1) sccs in Errors.raise_multispanned_error (Format.asprintf "Cyclic dependency detected between variables of scope %a!" Scopelang.Ast.ScopeName.format_t scope.scope_uid) (List.flatten (List.map (fun v -> let var_str, var_info = match v with | Vertex.Var v -> ( Format.asprintf "%a" Scopelang.Ast.ScopeVar.format_t v, Scopelang.Ast.ScopeVar.get_info v ) | Vertex.SubScope v -> ( Format.asprintf "%a" Scopelang.Ast.SubScopeName.format_t v, Scopelang.Ast.SubScopeName.get_info v ) in let succs = ScopeDependencies.succ_e g v in let _, edge_pos, succ = List.find (fun (_, _, succ) -> List.mem succ scc) succs in let succ_str = match succ with | Vertex.Var v -> Format.asprintf "%a" Scopelang.Ast.ScopeVar.format_t v | Vertex.SubScope v -> Format.asprintf "%a" Scopelang.Ast.SubScopeName.format_t v in [ (Some ("Cycle variable " ^ var_str ^ ", declared:"), Pos.get_position var_info); ( Some ("Used here in the definition of another cycle variable " ^ succ_str ^ ":"), edge_pos ); ]) scc)) (** Builds the dependency graph of a particular scope *) let build_scope_dependencies (scope : Ast.scope) : ScopeDependencies.t = let g = ScopeDependencies.empty in (* Add all the vertices to the graph *) let g = Scopelang.Ast.ScopeVarSet.fold (fun (v : Scopelang.Ast.ScopeVar.t) g -> ScopeDependencies.add_vertex g (Vertex.Var v)) scope.scope_vars g in let g = Scopelang.Ast.SubScopeMap.fold (fun (v : Scopelang.Ast.SubScopeName.t) _ g -> ScopeDependencies.add_vertex g (Vertex.SubScope v)) scope.scope_sub_scopes g in let g = Ast.ScopeDefMap.fold (fun def_key (def, _, _) g -> let fv = Ast.free_variables def in Ast.ScopeDefMap.fold (fun fv_def fv_def_pos g -> match (def_key, fv_def) with | Ast.ScopeDef.Var defined, Ast.ScopeDef.Var used -> (* simple case *) if used = defined then (* variable definitions cannot be recursive *) Errors.raise_spanned_error (Format.asprintf "The variable %a is used in one of its definitions, but recursion is \ forbidden in Catala" Scopelang.Ast.ScopeVar.format_t defined) fv_def_pos else let edge = ScopeDependencies.E.create (Vertex.Var used) fv_def_pos (Vertex.Var defined) in ScopeDependencies.add_edge_e g edge | Ast.ScopeDef.SubScopeVar (defined, _), Ast.ScopeDef.Var used -> (* here we are defining the input of a subscope using a var of the scope *) let edge = ScopeDependencies.E.create (Vertex.Var used) fv_def_pos (Vertex.SubScope defined) in ScopeDependencies.add_edge_e g edge | Ast.ScopeDef.SubScopeVar (defined, _), Ast.ScopeDef.SubScopeVar (used, _) -> (* here we are defining the input of a scope with the output of another subscope *) if used = defined then (* subscopes are not recursive functions *) Errors.raise_spanned_error (Format.asprintf "The subscope %a is used when defining one of its inputs, but recursion is \ forbidden in Catala" Scopelang.Ast.SubScopeName.format_t defined) fv_def_pos else let edge = ScopeDependencies.E.create (Vertex.SubScope used) fv_def_pos (Vertex.SubScope defined) in ScopeDependencies.add_edge_e g edge | Ast.ScopeDef.Var defined, Ast.ScopeDef.SubScopeVar (used, _) -> (* finally we define a scope var with the output of a subscope *) let edge = ScopeDependencies.E.create (Vertex.SubScope used) fv_def_pos (Vertex.Var defined) in ScopeDependencies.add_edge_e g edge) fv g) scope.scope_defs g in g (** {1 Exceptions dependency graph} *) (** {2 Graph declaration} *) module ExceptionVertex = struct include Ast.RuleName let equal x y = compare x y = 0 end module ExceptionsDependencies = Graph.Persistent.Digraph.ConcreteBidirectionalLabeled (ExceptionVertex) (Edge) (** Module of the graph, provided by OCamlGraph. [x -> y] if [y] is an exception to [x] *) module ExceptionsSCC = Graph.Components.Make (ExceptionsDependencies) (** Tarjan's stongly connected components algorithm, provided by OCamlGraph *) (** {2 Graph computations} *) let build_exceptions_graph (def : Ast.rule Ast.RuleMap.t) (def_info : Ast.ScopeDef.t) : ExceptionsDependencies.t = (* first we add the vertices *) let g = Ast.RuleMap.fold (fun rule_name _ g -> ExceptionsDependencies.add_vertex g rule_name) def ExceptionsDependencies.empty in (* then we add the edges *) let g = Ast.RuleMap.fold (fun rule_name rule g -> match rule.Ast.exception_to_rule with | None -> g | Some (exc_r, pos) -> if ExceptionsDependencies.mem_vertex g exc_r then if exc_r = rule_name then Errors.raise_spanned_error "Cannot define rule as an exception to itself" pos else let edge = ExceptionsDependencies.E.create rule_name pos exc_r in ExceptionsDependencies.add_edge_e g edge else Errors.raise_spanned_error (Format.asprintf "This rule has been declared as an exception to an incorrect label: \"%a\" is \ not a label attached to a definition of \"%a\"" Ast.RuleName.format_t exc_r Ast.ScopeDef.format_t def_info) pos) def g in g (** Outputs an error in case of cycles. *) let check_for_exception_cycle (g : ExceptionsDependencies.t) : unit = (* if there is a cycle, there will be an strongly connected component of cardinality > 1 *) let sccs = ExceptionsSCC.scc_list g in if List.length sccs < ExceptionsDependencies.nb_vertex g then let scc = List.find (fun scc -> List.length scc > 1) sccs in Errors.raise_multispanned_error (Format.asprintf "Cyclic dependency detected between exceptions!") (List.flatten (List.map (fun (v : Ast.RuleName.t) -> let var_str, var_info = (Format.asprintf "%a" Ast.RuleName.format_t v, Ast.RuleName.get_info v) in let succs = ExceptionsDependencies.succ_e g v in let _, edge_pos, succ = List.find (fun (_, _, succ) -> List.mem succ scc) succs in let succ_str = Format.asprintf "%a" Ast.RuleName.format_t succ in [ (Some ("Cycle exception " ^ var_str ^ ", declared:"), Pos.get_position var_info); ( Some ("Used here in the definition of another cycle exception " ^ succ_str ^ ":"), edge_pos ); ]) scc))