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(********************************************************************)
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(* *)
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(* The LustreC compiler toolset / The LustreC Development Team *)
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(* Copyright 2012 - -- ONERA - CNRS - INPT *)
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(* *)
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(* LustreC is free software, distributed WITHOUT ANY WARRANTY *)
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(* under the terms of the GNU Lesser General Public License *)
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(* version 2.1. *)
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(* *)
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(********************************************************************)
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open Utils
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open LustreSpec
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open Corelang
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open Graph
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open Causality
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type context =
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{
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mutable evaluated : Disjunction.CISet.t;
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dep_graph : IdentDepGraph.t;
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disjoint : (ident, Disjunction.CISet.t) Hashtbl.t;
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policy : (ident, var_decl) Hashtbl.t;
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}
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(* computes the in-degree for each local variable of node [n], according to dep graph [g].
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*)
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let compute_fanin n g =
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let locals = ISet.diff (ExprDep.node_local_variables n) (ExprDep.node_memory_variables n) in
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let inputs = ExprDep.node_input_variables n in
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let fanin = Hashtbl.create 23 in
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begin
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IdentDepGraph.iter_vertex
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(fun v ->
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if ISet.mem v locals
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then Hashtbl.add fanin v (IdentDepGraph.in_degree g v) else
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if ExprDep.is_read_var v && not (ISet.mem v inputs)
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then Hashtbl.add fanin (ExprDep.undo_read_var v) (IdentDepGraph.in_degree g v)) g;
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fanin
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end
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let pp_fanin fmt fanin =
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begin
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Format.fprintf fmt "{ /* locals fanin: */@.";
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Hashtbl.iter (fun s t -> Format.fprintf fmt "%s -> %d@." s t) fanin;
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Format.fprintf fmt "}@."
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end
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(* computes the cone of influence of a given [var] wrt a dependency graph [g].
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*)
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let cone_of_influence g var =
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(*Format.printf "coi: %s@." var;*)
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let frontier = ref (ISet.add var ISet.empty) in
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let coi = ref ISet.empty in
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while not (ISet.is_empty !frontier)
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do
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let head = ISet.min_elt !frontier in
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(*Format.printf "head: %s@." head;*)
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frontier := ISet.remove head !frontier;
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if ExprDep.is_read_var head then coi := ISet.add (ExprDep.undo_read_var head) !coi;
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List.iter (fun s -> frontier := ISet.add s !frontier) (IdentDepGraph.succ g head);
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done;
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!coi
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let compute_unused_variables n g =
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let inputs = ExprDep.node_input_variables n in
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let mems = ExprDep.node_memory_variables n in
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let outputs = ExprDep.node_output_variables n in
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ISet.fold
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(fun var unused -> ISet.diff unused (cone_of_influence g var))
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(ISet.union outputs mems)
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(ISet.union inputs mems)
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(* computes the set of potentially reusable variables.
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We don't reuse input variables, due to possible aliasing *)
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let node_reusable_variables node =
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let mems = ExprDep.node_memory_variables node in
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List.fold_left
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(fun acc l ->
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if ISet.mem l.var_id mems then acc else Disjunction.CISet.add l acc)
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Disjunction.CISet.empty
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node.node_locals
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let kill_root ctx head =
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IdentDepGraph.iter_succ (IdentDepGraph.remove_edge ctx.dep_graph head.var_id) ctx.dep_graph head.var_id
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(* Recursively removes useless variables,
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i.e. [ctx.evaluated] variables that are current roots of the dep graph [ctx.dep_graph]
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- [evaluated] is the set of already evaluated variables,
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wrt the scheduling
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- does only remove edges, not variables themselves
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*)
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let remove_roots ctx =
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let rem = ref true in
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let remaining = ref ctx.evaluated in
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while !rem
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do
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rem := false;
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let all_roots = graph_roots ctx.dep_graph in
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let frontier_roots = Disjunction.CISet.filter (fun v -> List.mem v.var_id all_roots) !remaining in
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if not (Disjunction.CISet.is_empty frontier_roots) then
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begin
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rem := true;
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Disjunction.CISet.iter (kill_root ctx) frontier_roots;
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remaining := Disjunction.CISet.diff !remaining frontier_roots
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end
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done
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(* checks whether a variable is aliasable,
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depending on its (address) type *)
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let is_aliasable var =
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Types.is_address_type var.var_type
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(* checks whether a variable [v] is an input of the [var] equation, with an address type.
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if so, [var] could not safely reuse/alias [v], should [v] be dead in the caller node,
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because [v] may not be dead in the callee node when [var] is assigned *)
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let is_aliasable_input node var =
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let eq_var = get_node_eq var node in
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let inputs_var =
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match NodeDep.get_callee eq_var.eq_rhs with
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| None -> []
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| Some (_, args) -> List.fold_right (fun e r -> match e.expr_desc with Expr_ident id -> id::r | _ -> r) args [] in
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fun v -> is_aliasable v && List.mem v.var_id inputs_var
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(*
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let res =
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is_aliasable v && List.mem v.var_id inputs_var
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in (Format.eprintf "aliasable %s by %s = %B@." var v.var_id res; res)
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*)
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(* replace variable [v] by [v'] in graph [g].
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[v'] is a dead variable
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*)
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let replace_in_dep_graph v v' g =
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begin
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IdentDepGraph.add_vertex g v';
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IdentDepGraph.iter_succ (fun s -> IdentDepGraph.add_edge g v' s) g v;
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IdentDepGraph.iter_pred (fun p -> IdentDepGraph.add_edge g p v') g v;
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IdentDepGraph.remove_vertex g v
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end
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let pp_reuse_policy fmt policy =
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begin
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Format.fprintf fmt "{ /* reuse policy */@.";
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Hashtbl.iter (fun s t -> Format.fprintf fmt "%s -> %s@." s t.var_id) policy;
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Format.fprintf fmt "}@."
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end
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let pp_context fmt ctx =
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begin
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Format.fprintf fmt "{ /*BEGIN context */@.";
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Format.fprintf fmt "eval=%a;@." Disjunction.pp_ciset ctx.evaluated;
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Format.fprintf fmt "graph=%a;@." pp_dep_graph ctx.dep_graph;
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Format.fprintf fmt "disjoint=%a;@." Disjunction.pp_disjoint_map ctx.disjoint;
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Format.fprintf fmt "policy=%a;@." pp_reuse_policy ctx.policy;
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Format.fprintf fmt "/* END context */ }@.";
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end
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(* computes the reusable dependencies of variable [var] in graph [g],
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once [var] has been evaluated
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- [locals] is the set of potentially reusable variables
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- [evaluated] is the set of evaluated variables
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- [quasi] is the set of quasi-reusable variables
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- [reusable] is the set of dead/reusable dependencies of [var] in graph [g]
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- [policy] is the reuse map (which domain is [evaluated])
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*)
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let compute_dependencies heads ctx =
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begin
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(*Log.report ~level:6 (fun fmt -> Format.fprintf fmt "compute_reusable_dependencies %a %a %a@." Disjunction.pp_ciset locals Printers.pp_var_name var pp_context ctx);*)
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List.iter (kill_root ctx) heads;
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remove_roots ctx;
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end
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let compute_evaluated heads ctx =
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begin
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List.iter (fun head -> ctx.evaluated <- Disjunction.CISet.add head ctx.evaluated) heads;
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end
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(* tests whether a variable [v] may be (re)used instead of [var]. The conditions are:
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- [v] has been really used ([v] is its own representative)
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- same type
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- [v] is not an aliasable input of the equation defining [var]
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- [v] is not one of the current heads (which contain [var])
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- [v] is not currently in use
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*)
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let eligible node ctx heads var v =
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Hashtbl.find ctx.policy v.var_id == v
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&& Typing.eq_ground (Types.unclock_type var.var_type) (Types.unclock_type v.var_type)
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&& not (is_aliasable_input node var.var_id v)
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&& not (List.exists (fun h -> h.var_id = v.var_id) heads)
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&& (*let repr_v = Hashtbl.find ctx.policy v.var_id*)
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not (Disjunction.CISet.exists (fun p -> IdentDepGraph.mem_edge ctx.dep_graph p.var_id v.var_id) ctx.evaluated)
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let compute_reuse node ctx heads var =
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let disjoint = Hashtbl.find ctx.disjoint var.var_id in
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let locally_reusable v =
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IdentDepGraph.fold_pred (fun p r -> r && Disjunction.CISet.exists (fun d -> p = d.var_id) disjoint) ctx.dep_graph v.var_id true in
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let eligibles = Disjunction.CISet.filter (eligible node ctx heads var) ctx.evaluated in
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Log.report ~level:7 (fun fmt -> Format.fprintf fmt "eligibles:%a@." Disjunction.pp_ciset eligibles);
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let quasi_dead, live = Disjunction.CISet.partition locally_reusable eligibles in
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Log.report ~level:7 (fun fmt -> Format.fprintf fmt "live:%a@." Disjunction.pp_ciset live);
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try
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let disjoint_live = Disjunction.CISet.inter disjoint live in
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Log.report ~level:7 (fun fmt -> Format.fprintf fmt "disjoint live:%a@." Disjunction.pp_ciset disjoint_live);
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let reuse = Disjunction.CISet.max_elt disjoint_live in
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(*let reuse' = Hashtbl.find ctx.policy reuse.var_id in*)
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begin
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IdentDepGraph.add_edge ctx.dep_graph var.var_id reuse.var_id;
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(*if reuse != reuse' then IdentDepGraph.add_edge ctx.dep_graph reuse.var_id reuse'.var_id;*)
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Hashtbl.add ctx.policy var.var_id reuse;
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ctx.evaluated <- Disjunction.CISet.add var ctx.evaluated;
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(*Format.eprintf "%s reused by live@." var.var_id;*)
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end
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with Not_found ->
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try
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let dead = Disjunction.CISet.filter (fun v -> is_graph_root v.var_id ctx.dep_graph) quasi_dead in
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Log.report ~level:7 (fun fmt -> Format.fprintf fmt "dead:%a@." Disjunction.pp_ciset dead);
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let reuse = Disjunction.CISet.choose dead in
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(*let reuse' = Hashtbl.find ctx.policy reuse.var_id in*)
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begin
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IdentDepGraph.add_edge ctx.dep_graph var.var_id reuse.var_id;
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(*if reuse != reuse' then IdentDepGraph.add_edge ctx.dep_graph reuse.var_id reuse'.var_id;*)
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Hashtbl.add ctx.policy var.var_id reuse;
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ctx.evaluated <- Disjunction.CISet.add var ctx.evaluated;
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(*Format.eprintf "%s reused by dead %a@." var.var_id Disjunction.pp_ciset dead;*)
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end
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with Not_found ->
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begin
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Hashtbl.add ctx.policy var.var_id var;
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ctx.evaluated <- Disjunction.CISet.add var ctx.evaluated;
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end
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let compute_reuse_policy node schedule disjoint g =
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let sort = ref schedule in
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let ctx = { evaluated = Disjunction.CISet.empty;
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dep_graph = g;
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disjoint = disjoint;
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policy = Hashtbl.create 23; } in
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while !sort <> []
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do
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Log.report ~level:6 (fun fmt -> Format.fprintf fmt "new context:%a@." pp_context ctx);
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let heads = List.map (fun v -> get_node_var v node) (List.hd !sort) in
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Log.report ~level:6 (fun fmt -> Format.fprintf fmt "NEW HEADS:");
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List.iter (fun head -> Log.report ~level:6 (fun fmt -> Format.fprintf fmt "%s (%a)" head.var_id Printers.pp_node_eq (get_node_eq head.var_id node))) heads;
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Log.report ~level:6 (fun fmt -> Format.fprintf fmt "@.");
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Log.report ~level:6 (fun fmt -> Format.fprintf fmt "COMPUTE_DEPENDENCIES@.");
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compute_dependencies heads ctx;
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Log.report ~level:6 (fun fmt -> Format.fprintf fmt "new context:%a@." pp_context ctx);
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Log.report ~level:6 (fun fmt -> Format.fprintf fmt "COMPUTE_REUSE@.");
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List.iter (compute_reuse node ctx heads) heads;
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(*compute_evaluated heads ctx;*)
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List.iter (fun head -> Log.report ~level:6 (fun fmt -> Format.fprintf fmt "reuse %s instead of %s@." (Hashtbl.find ctx.policy head.var_id).var_id head.var_id)) heads;
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sort := List.tl !sort;
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done;
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IdentDepGraph.clear ctx.dep_graph;
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ctx.policy
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(* Reuse policy:
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- could reuse variables with the same type exactly only (simple).
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- reusing variables with different types would involve:
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- either dirty castings
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- or complex inclusion expression (for instance: array <-> array cell, struct <-> struct field) to be able to reuse only some parts of structured data.
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... it seems too complex and potentially unsafe
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- for node instance calls: output variables could NOT reuse aliasable input variables,
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even if inputs become dead, because the correctness would depend on the scheduling
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of the callee (so, the compiling strategy could NOT be modular anymore).
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- once a policy is set, we need to:
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- replace each variable by its reuse alias.
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- simplify resulting equations, as we may now have:
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x = x; --> ; for scalar vars
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or:
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x = &{ f1 = x->f1; f2 = t; } --> x->f2 = t; for struct vars
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*)
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(* the reuse policy seeks to use less local variables
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by replacing local variables, applying the rules
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in the following order:
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1) use another clock disjoint still live variable,
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with the greatest possible disjoint clock
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2) reuse a dead variable
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For the sake of safety, we replace variables by others:
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- with the same type
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- not aliasable (i.e. address type)
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*)
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(* Local Variables: *)
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(* compile-command:"make -C .." *)
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(* End: *)
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