diff options
author | Son Ho | 2022-12-14 11:03:12 +0100 |
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committer | Son HO | 2023-02-03 11:21:46 +0100 |
commit | 47417ab258f9d192f4d872c6bea8096348802aa3 (patch) | |
tree | 3a377f39455429855d28e8c9bdd4cb800147298c | |
parent | a5d09658b0c15862b609226d18f072c5d9f1e953 (diff) |
Add an SCC.ml file for strongly connected components
Diffstat (limited to '')
-rw-r--r-- | compiler/Cps.ml | 2 | ||||
-rw-r--r-- | compiler/SCC.ml | 215 | ||||
-rw-r--r-- | compiler/SymbolicToPure.ml | 17 | ||||
-rw-r--r-- | compiler/Translate.ml | 2 | ||||
-rw-r--r-- | compiler/dune | 3 |
5 files changed, 236 insertions, 3 deletions
diff --git a/compiler/Cps.ml b/compiler/Cps.ml index a013003e..1e5c0e70 100644 --- a/compiler/Cps.ml +++ b/compiler/Cps.ml @@ -173,7 +173,7 @@ let _ = let comp_transmit (f : ('v -> 'm) -> 'n) (g : 'm -> 'm) : ('v -> 'm) -> 'n = fun cf -> f (fun v -> g (cf v)) -(** Example of use of {!comp_transmit} *) +(** Example of use of {!comp_transmit} - TODO: make "real" unit tests *) let () = let return3 (cf : int -> unit -> unit) (ctx : unit) = cf 3 ctx in let do_nothing (cf : unit -> unit) (ctx : unit) = cf ctx in diff --git a/compiler/SCC.ml b/compiler/SCC.ml new file mode 100644 index 00000000..2033574d --- /dev/null +++ b/compiler/SCC.ml @@ -0,0 +1,215 @@ +(** Utilities for strongly connected components - this is similar to the [graphs.rs] file in Charon *) + +open Collections +module SccId = Identifiers.IdGen () + +(** A functor to compute and order strongly connected components *) +module Make (Id : OrderedType) = struct + module IdMap = MakeMap (Id) + module IdSet = MakeSet (Id) + + type id = Id.t + + let pp_id = Id.pp_t + + (** A structure containing information about SCCs (strongly connected components) *) + type sccs = { + sccs : id list SccId.Map.t; + scc_deps : SccId.Set.t SccId.Map.t; (** The dependencies between sccs *) + } + [@@deriving show] + + (** The order in which Tarjan's algorithm generates the SCCs is arbitrary, + while we want to keep as much as possible the original order (the order + in which the user generated the ids). For this, we iterate through + the ordered ids and try to add the SCC containing the id to a new list of SCCs + Of course, this SCC might have dependencies, so we need to add the dependencies + first (in which case we have reordering to do). This is what this function + does: we add an SCC and its dependencies to the list of reordered SCCs by + doing a depth-first search. + We also compute the SCC dependencies while performing this exploration. + + Rem.: we push SCCs to the *front* of [reordered_sccs] (which should then + be reversed before being used). + + Rem.: [scc_deps]: we use the fact that the elements inside [SccId.Set.t] + are ordered. + + TODO: change the type of [reordered_sccs] (not efficient...) + *) + let rec insert_scc_with_deps (id_deps : Id.t list IdMap.t) + (reordered_sccs : SccId.id list ref) + (scc_deps : SccId.Set.t SccId.Map.t ref) (sccs : Id.t list SccId.Map.t) + (id_to_scc : SccId.id IdMap.t) (scc_id : SccId.id) : unit = + (* Check if the SCC id has already been added *) + if List.mem scc_id !reordered_sccs then () + else + (* Add the dependencies. + For every id in the dependencies, get the SCC containing this id. + If this is the current SCC: continue. If it is a different one, it is + a dependency: add it to the list of reordered SCCs. *) + let scc = SccId.Map.find scc_id sccs in + List.iter + (fun id -> + let ids = IdMap.find id id_deps in + List.iter + (fun dep_id -> + let dep_scc_id = IdMap.find dep_id id_to_scc in + if dep_scc_id = scc_id then () + else + (* Insert the dependency *) + let scc_deps_set = SccId.Map.find scc_id !scc_deps in + let scc_deps_set = SccId.Set.add dep_scc_id scc_deps_set in + scc_deps := SccId.Map.add scc_id scc_deps_set !scc_deps; + + (* Explore the parent SCC *) + insert_scc_with_deps id_deps reordered_sccs scc_deps sccs + id_to_scc dep_scc_id) + ids) + scc; + (* Add the current SCC *) + reordered_sccs := scc_id :: !reordered_sccs + + (** Provided we computed the SCCs (Strongly Connected Components) of a set of + identifier, and those identifiers are ordered, compute the set of SCCs where + the order of the SCCs and the order of the identifiers inside the SCCs attempt + to respect as much as possible the original order between the identifiers. + The [ids] vector gives the ordered set of identifiers. + + This is used to generate the translated definitions in a consistent and + stable manner. For instance, if some Rust functions are mutually recursive, + it is possible that we can extract the forward functions in one group, and + extract the backward functions in one group (after filtering the useless + calls in {!MicroPasses}), but is is also possible that all the functions + (forward and backward) are mutually recursive). For this reason, we compute + the dependency graph and the strongly connected components of that graph. + Similar problems when functions contain loops (especially mutually recursive + functions which contain loops (!)). + + Also see the comments for the equivalent function in [graph.rs] in the + Charon project. + *) + let reorder_sccs (id_deps : Id.t list IdMap.t) (ids : Id.t list) + (sccs : Id.t list list) : sccs = + (* Map the identifiers to the SCC indices *) + let id_to_scc = + IdMap.of_list + (List.concat + (SccId.mapi + (fun scc_id scc -> List.map (fun id -> (id, scc_id)) scc) + sccs)) + in + + (* Reorder the identifiers inside the SCCs. + We iterate over the identifiers (in the order in which we register them) and add + them in their corresponding SCCs. + TODO: we append to the end of lists, this is not very efficient... + *) + let reordered_sccs : Id.t list SccId.Map.t ref = + ref (SccId.Map.of_list (SccId.mapi (fun scc_id _ -> (scc_id, [])) sccs)) + in + List.iter + (fun id -> + let scc_id = IdMap.find id id_to_scc in + let scc_ids = SccId.Map.find scc_id !reordered_sccs in + (* TODO: this is not efficient *) + let scc_ids = List.append scc_ids [ id ] in + reordered_sccs := SccId.Map.add scc_id scc_ids !reordered_sccs) + ids; + + (* Reorder the SCCs themselves - just do a depth first search. Iterate over + the def ids, and add the corresponding SCCs (with their dependencies) *) + let reordered_sccs_ids = ref [] in + let scc_deps = + ref (SccId.Map.map (fun _ -> SccId.Set.empty) !reordered_sccs) + in + List.iter + (fun id -> + let scc_id = IdMap.find id id_to_scc in + insert_scc_with_deps id_deps reordered_sccs_ids scc_deps !reordered_sccs + id_to_scc scc_id) + ids; + let reordered_sccs_ids = List.rev !reordered_sccs_ids in + + (* Compute the map from the original SCC ids to the new SCC ids (after reordering) *) + let old_to_new_id = + SccId.Map.of_list + (SccId.mapi (fun new_id old_id -> (old_id, new_id)) reordered_sccs_ids) + in + + (* Generate the reordered SCCs *) + let tgt_sccs = + SccId.Map.of_list + (SccId.mapi + (fun new_id scc_id -> + (new_id, SccId.Map.find scc_id !reordered_sccs)) + reordered_sccs_ids) + in + + (* Compute the dependencies with the new indices *) + let tgt_deps = + SccId.Map.of_list + (List.map + (fun (old_id, deps_ids) -> + let new_id = SccId.Map.find old_id old_to_new_id in + let new_deps_ids = + SccId.Set.map + (fun id -> SccId.Map.find id old_to_new_id) + deps_ids + in + (new_id, new_deps_ids)) + (SccId.Map.bindings !scc_deps)) + in + + (* Return *) + { sccs = tgt_sccs; scc_deps = tgt_deps } +end + +(** Test - TODO: make "real" unit tests *) +let _ = + (* Check that some SCCs are correctly reordered *) + let check_sccs (id_deps : (int * int list) list) (ids : int list) + (sccs : int list list) (tgt_sccs : int list list) : unit = + let module Ord = OrderedInt in + let module Reorder = Make (Ord) in + let module Map = MakeMap (Ord) in + let id_deps = Map.of_list id_deps in + + let reordered = Reorder.reorder_sccs id_deps ids sccs in + let tgt_sccs = + SccId.Map.of_list (SccId.mapi (fun scc_id ids -> (scc_id, ids)) tgt_sccs) + in + assert (reordered.sccs = tgt_sccs) + in + + (* Shouldn't reorder *) + let _ = + let id_deps = + [ (0, []); (1, [ 2; 3 ]); (2, [ 1 ]); (3, [ 1 ]); (4, [ 2 ]) ] + in + let ids = [ 0; 1; 2; 3; 4 ] in + let sccs = [ [ 0 ]; [ 1; 2; 3 ]; [ 4 ] ] in + let tgt_sccs = sccs in + check_sccs id_deps ids sccs tgt_sccs + in + + (* Small reorder *) + let _ = + let id_deps = + [ (0, []); (1, [ 2; 3 ]); (2, [ 1 ]); (3, [ 1 ]); (4, [ 2 ]) ] + in + let ids = [ 0; 1; 3; 2; 4 ] in + let sccs = [ [ 0 ]; [ 1; 2; 3 ]; [ 4 ] ] in + let tgt_sccs = [ [ 0 ]; [ 1; 3; 2 ]; [ 4 ] ] in + check_sccs id_deps ids sccs tgt_sccs + in + + let _ = + let id_deps = [ (0, [ 1 ]); (1, [ 0 ]); (2, [ 3 ]); (3, [ 2 ]) ] in + let ids = [ 3; 2; 0; 1 ] in + let sccs = [ [ 0; 1 ]; [ 2; 3 ] ] in + let tgt_sccs = [ [ 3; 2 ]; [ 0; 1 ] ] in + check_sccs id_deps ids sccs tgt_sccs + in + + () diff --git a/compiler/SymbolicToPure.ml b/compiler/SymbolicToPure.ml index 8db968f3..8a6f82f9 100644 --- a/compiler/SymbolicToPure.ml +++ b/compiler/SymbolicToPure.ml @@ -119,6 +119,18 @@ type bs_ctx = { (** The function calls we encountered so far *) abstractions : (V.abs * texpression list) V.AbstractionId.Map.t; (** The ended abstractions we encountered so far, with their additional input arguments *) + loop_id : V.LoopId.id option; + (** [Some] if we reached a loop (we are synthesizing a function, and reached a loop, or are + synthesizing the loop body itself) + *) + inside_loop : bool; + (** In case {!loop_id} is [Some]: + - if [true]: we are synthesizing a loop body + - if [false]: we reached a loop and are synthesizing the end of the function (after the loop body) + + Note that when a function contains a loop, we group the function symbolic AST and the loop symbolic + AST in a single function. + *) } let type_check_pattern (ctx : bs_ctx) (v : typed_pattern) : unit = @@ -1175,7 +1187,7 @@ let rec translate_expression (e : S.expression) (ctx : bs_ctx) : texpression = (ctx, e) in translate_expression e ctx - | Loop _loop -> raise (Failure "Unimplemented") + | Loop loop -> translate_loop loop ctx and translate_panic (ctx : bs_ctx) : texpression = (* Here we use the function return type - note that it is ok because @@ -1829,6 +1841,9 @@ and translate_expansion (p : S.mplace option) (sv : V.symbolic_value) List.for_all (fun (br : match_branch) -> br.branch.ty = ty) branches); { e; ty } +and translate_loop (loop : S.loop) (ctx : bs_ctx) : texpression = + raise (Failure "Unreachable") + and translate_meta (meta : S.meta) (e : S.expression) (ctx : bs_ctx) : texpression = let next_e = translate_expression e ctx in diff --git a/compiler/Translate.ml b/compiler/Translate.ml index f34231e0..dd3ba976 100644 --- a/compiler/Translate.ml +++ b/compiler/Translate.ml @@ -116,6 +116,8 @@ let translate_function_to_pure (trans_ctx : trans_ctx) (* Empty for now *) calls; abstractions; + loop_id = None; + inside_loop = false; } in diff --git a/compiler/dune b/compiler/dune index 9e92b583..7cae6b89 100644 --- a/compiler/dune +++ b/compiler/dune @@ -10,7 +10,7 @@ (public_name aeneas) ;; The name as revealed to the projects importing this library (preprocess (pps ppx_deriving.show ppx_deriving.ord visitors.ppx)) - (libraries charon core_unix unionFind) + (libraries charon core_unix unionFind ocamlgraph) (modules Assumed Collections @@ -48,6 +48,7 @@ Pure PureTypeCheck PureUtils + SCC Scalars StringUtils Substitute |