open Errors open InterpreterStatements open Interpreter module L = Logging module T = Types module A = CfimAst module M = Modules module SA = SymbolicAst (** The local logger *) let log = L.translate_log type pure_fun_translation = Pure.fun_def * Pure.fun_def list (** Execute the symbolic interpreter on a function to generate a list of symbolic ASTs, for the forward function and the backward functions. *) let translate_function_to_symbolics (config : C.partial_config) (type_context : C.type_context) (fun_context : C.fun_context) (fdef : A.fun_def) : SA.expression * SA.expression list = (* Debug *) log#ldebug (lazy ("translate_function_to_symbolics: " ^ Print.name_to_string fdef.A.name)); (* Evaluate *) let synthesize = true in let evaluate = evaluate_function_symbolic config synthesize type_context fun_context fdef in (* Execute the forward function *) let forward = Option.get (evaluate None) in (* Execute the backward functions *) let backwards = T.RegionGroupId.mapi (fun gid _ -> Option.get (evaluate (Some gid))) fdef.signature.regions_hierarchy in (* Return *) (forward, backwards) (** Translate a function, by generating its forward and backward translations. *) let translate_function (config : C.partial_config) (type_context : C.type_context) (fun_context : C.fun_context) (fun_sigs : Pure.fun_sig SymbolicToPure.RegularFunIdMap.t) (fdef : A.fun_def) : pure_fun_translation = let def_id = fdef.def_id in (* Compute the symbolic ASTs *) let symbolic_forward, symbolic_backwards = translate_function_to_symbolics config type_context fun_context fdef in (* Convert the symbolic ASTs to pure ASTs: *) (* Initialize the context *) let sv_to_var = V.SymbolicValueId.Map.empty in let var_counter = Pure.VarId.generator_zero in let calls = V.FunCallId.Map.empty in let abstractions = V.AbstractionId.Map.empty in let type_context = { SymbolicToPure.types_infos = type_context.type_infos; cfim_type_defs = type_context.type_defs; } in let fun_context = { SymbolicToPure.cfim_fun_defs = fun_context.fun_defs; fun_sigs } in let ctx = { SymbolicToPure.bid = None; (* Dummy for now *) sv_to_var; var_counter; type_context; fun_context; forward_inputs = []; (* Empty for now *) backward_inputs = T.RegionGroupId.Map.empty; (* Empty for now *) backward_outputs = T.RegionGroupId.Map.empty; (* Empty for now *) calls; abstractions; } in (* We need to initialize the input/output variables. First, the inputs * for the forward function *) let module RegularFunIdMap = SymbolicToPure.RegularFunIdMap in let forward_sg = RegularFunIdMap.find (A.Local def_id, None) fun_sigs in let ctx, forward_inputs = SymbolicToPure.fresh_vars forward_sg.inputs ctx in let ctx = { ctx with forward_inputs } in (* Translate the forward function *) let pure_forward = SymbolicToPure.translate_fun_def fdef ctx symbolic_forward in (* Translate the backward functions *) let translate_backward (rg : T.region_var_group) : Pure.fun_def = (* For the backward inputs/outputs initialization: we use the fact that * there are no nested borrows for now, and so that the region groups * can't have parents *) assert (rg.parents = []); (* TODO: the computation of the backward inputs is a bit awckward... *) let back_id = rg.id in let backward_sg = RegularFunIdMap.find (A.Local def_id, Some back_id) fun_sigs in let _, backward_inputs = Collections.List.split_at backward_sg.inputs (List.length forward_inputs) in let ctx, backward_inputs = SymbolicToPure.fresh_vars backward_inputs ctx in let backward_outputs = backward_sg.outputs in let ctx, backward_outputs = SymbolicToPure.fresh_vars backward_outputs ctx in let backward_inputs = T.RegionGroupId.Map.singleton back_id backward_inputs in let backward_outputs = T.RegionGroupId.Map.singleton back_id backward_outputs in (* Put everything in the context *) let ctx = { ctx with bid = Some back_id; backward_inputs; backward_outputs } in (* Translate *) let symbolic = T.RegionGroupId.nth symbolic_backwards back_id in SymbolicToPure.translate_fun_def fdef ctx symbolic in let pure_backwards = List.map translate_backward fdef.signature.regions_hierarchy in (* Return *) (pure_forward, pure_backwards) let translate_module_to_pure (config : C.partial_config) (m : M.cfim_module) : Pure.type_def T.TypeDefId.Map.t * pure_fun_translation A.FunDefId.Map.t = (* Compute the type and function contexts *) let type_context, fun_context = compute_type_fun_contexts m in (* Translate all the type definitions *) let type_defs = SymbolicToPure.translate_type_defs m.types in (* Translate all the function *signatures* *) let assumed_sigs = List.map (fun (id, sg) -> (A.Assumed id, sg)) Assumed.assumed_sigs in let local_sigs = List.map (fun (fdef : A.fun_def) -> (A.Local fdef.def_id, fdef.signature)) m.functions in let sigs = List.append assumed_sigs local_sigs in let fun_sigs = SymbolicToPure.translate_fun_signatures type_context.type_infos sigs in (* Translate all the functions *) let translations = List.map (fun (fdef : A.fun_def) -> ( fdef.def_id, translate_function config type_context fun_context fun_sigs fdef )) m.functions in (* Put the translated functions in a map *) let fun_defs = List.fold_left (fun m (def_id, trans) -> A.FunDefId.Map.add def_id trans m) A.FunDefId.Map.empty translations in (* Return *) (type_defs, fun_defs)