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authorErlang/OTP <[email protected]>2009-11-20 14:54:40 +0000
committerErlang/OTP <[email protected]>2009-11-20 14:54:40 +0000
commit84adefa331c4159d432d22840663c38f155cd4c1 (patch)
treebff9a9c66adda4df2106dfd0e5c053ab182a12bd /lib/hipe/cerl/cerl_closurean.erl
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The R13B03 release.OTP_R13B03
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+%%
+%% %CopyrightBegin%
+%%
+%% Copyright Ericsson AB 2003-2009. All Rights Reserved.
+%%
+%% The contents of this file are subject to the Erlang Public License,
+%% Version 1.1, (the "License"); you may not use this file except in
+%% compliance with the License. You should have received a copy of the
+%% Erlang Public License along with this software. If not, it can be
+%% retrieved online at http://www.erlang.org/.
+%%
+%% Software distributed under the License is distributed on an "AS IS"
+%% basis, WITHOUT WARRANTY OF ANY KIND, either express or implied. See
+%% the License for the specific language governing rights and limitations
+%% under the License.
+%%
+%% %CopyrightEnd%
+%%
+%% =====================================================================
+%% Closure analysis of Core Erlang programs.
+%%
+%% Copyright (C) 2001-2002 Richard Carlsson
+%%
+%% Author contact: [email protected]
+%% =====================================================================
+
+%% TODO: might need a "top" (`any') element for any-length value lists.
+
+-module(cerl_closurean).
+
+-export([analyze/1, annotate/1]).
+%% The following functions are exported from this module since they
+%% are also used by Dialyzer (file dialyzer/src/dialyzer_dep.erl)
+-export([is_escape_op/2, is_escape_op/3, is_literal_op/2, is_literal_op/3]).
+
+-import(cerl, [ann_c_apply/3, ann_c_fun/3, ann_c_var/2, apply_args/1,
+ apply_op/1, atom_val/1, bitstr_size/1, bitstr_val/1,
+ binary_segments/1, c_letrec/2, c_seq/2, c_tuple/1,
+ c_nil/0, call_args/1, call_module/1, call_name/1,
+ case_arg/1, case_clauses/1, catch_body/1, clause_body/1,
+ clause_guard/1, clause_pats/1, cons_hd/1, cons_tl/1,
+ fun_body/1, fun_vars/1, get_ann/1, is_c_atom/1,
+ let_arg/1, let_body/1, let_vars/1, letrec_body/1,
+ letrec_defs/1, module_defs/1, module_defs/1,
+ module_exports/1, pat_vars/1, primop_args/1,
+ primop_name/1, receive_action/1, receive_clauses/1,
+ receive_timeout/1, seq_arg/1, seq_body/1, set_ann/2,
+ try_arg/1, try_body/1, try_vars/1, try_evars/1,
+ try_handler/1, tuple_es/1, type/1, values_es/1]).
+
+-import(cerl_trees, [get_label/1]).
+
+%% ===========================================================================
+
+-type label() :: integer() | 'top' | 'external' | 'external_call'.
+-type ordset(X) :: [X]. % XXX: TAKE ME OUT
+-type labelset() :: ordset(label()).
+-type outlist() :: [labelset()] | 'none'.
+-type escapes() :: labelset().
+
+%% ===========================================================================
+%% annotate(Tree) -> {Tree1, OutList, Outputs, Escapes, Dependencies, Parents}
+%%
+%% Tree = cerl:cerl()
+%%
+%% Analyzes `Tree' (see `analyze') and appends terms `{callers,
+%% Labels}' and `{calls, Labels}' to the annotation list of each
+%% fun-expression node and apply-expression node of `Tree',
+%% respectively, where `Labels' is an ordered-set list of labels of
+%% fun-expressions in `Tree', possibly also containing the atom
+%% `external', corresponding to the dependency information derived
+%% by the analysis. Any previous such annotations are removed from
+%% `Tree'. `Tree1' is the modified tree; for details on `OutList',
+%% `Outputs' , `Dependencies', `Escapes' and `Parents', see
+%% `analyze'.
+%%
+%% Note: `Tree' must be annotated with labels in order to use this
+%% function; see `analyze' for details.
+
+-spec annotate(cerl:cerl()) ->
+ {cerl:cerl(), outlist(), dict(), escapes(), dict(), dict()}.
+
+annotate(Tree) ->
+ {Xs, Out, Esc, Deps, Par} = analyze(Tree),
+ F = fun (T) ->
+ case type(T) of
+ 'fun' ->
+ L = get_label(T),
+ X = case dict:find(L, Deps) of
+ {ok, X1} -> X1;
+ error -> set__new()
+ end,
+ set_ann(T, append_ann(callers,
+ set__to_list(X),
+ get_ann(T)));
+ apply ->
+ L = get_label(T),
+ X = case dict:find(L, Deps) of
+ {ok, X1} -> X1;
+ error -> set__new()
+ end,
+ set_ann(T, append_ann(calls,
+ set__to_list(X),
+ get_ann(T)));
+ _ ->
+%%% set_ann(T, []) % debug
+ T
+ end
+ end,
+ {cerl_trees:map(F, Tree), Xs, Out, Esc, Deps, Par}.
+
+append_ann(Tag, Val, [X | Xs]) ->
+ if tuple_size(X) >= 1, element(1, X) =:= Tag ->
+ append_ann(Tag, Val, Xs);
+ true ->
+ [X | append_ann(Tag, Val, Xs)]
+ end;
+append_ann(Tag, Val, []) ->
+ [{Tag, Val}].
+
+%% =====================================================================
+%% analyze(Tree) -> {OutList, Outputs, Escapes, Dependencies, Parents}
+%%
+%% Tree = cerl()
+%% OutList = [LabelSet] | none
+%% Outputs = dict(Label, OutList)
+%% Escapes = LabelSet
+%% Dependencies = dict(Label, LabelSet)
+%% LabelSet = ordset(Label)
+%% Label = integer() | top | external | external_call
+%% Parents = dict(Label, Label)
+%%
+%% Analyzes a module or an expression represented by `Tree'.
+%%
+%% The returned `OutList' is a list of sets of labels of
+%% fun-expressions which correspond to the possible closures in the
+%% value list produced by `Tree' (viewed as an expression; the
+%% "value" of a module contains its exported functions). The atom
+%% `none' denotes missing or conflicting information.
+%%
+%% The atom `external' in any label set denotes any possible
+%% function outside `Tree', including those in `Escapes'. The atom
+%% `top' denotes the top-level expression `Tree'.
+%%
+%% `Outputs' is a mapping from the labels of fun-expressions in
+%% `Tree' to corresponding lists of sets of labels of
+%% fun-expressions (or the atom `none'), representing the possible
+%% closures in the value lists returned by the respective
+%% functions.
+%%
+%% `Dependencies' is a similar mapping from the labels of
+%% fun-expressions and apply-expressions in `Tree' to sets of
+%% labels of corresponding fun-expressions which may contain call
+%% sites of the functions or be called from the call sites,
+%% respectively. Any such label not defined in `Dependencies'
+%% represents an unreachable function or a dead or faulty
+%% application.
+%%
+%% `Escapes' is the set of labels of fun-expressions in `Tree' such
+%% that corresponding closures may be accessed from outside `Tree'.
+%%
+%% `Parents' is a mapping from labels of fun-expressions in `Tree'
+%% to the corresponding label of the nearest containing
+%% fun-expression or top-level expression. This can be used to
+%% extend the dependency graph, for certain analyses.
+%%
+%% Note: `Tree' must be annotated with labels (as done by the
+%% function `cerl_trees:label/1') in order to use this function.
+%% The label annotation `{label, L}' (where L should be an integer)
+%% must be the first element of the annotation list of each node in
+%% the tree. Instances of variables bound in `Tree' which denote
+%% the same variable must have the same label; apart from this,
+%% labels should be unique. Constant literals do not need to be
+%% labeled.
+
+-record(state, {vars, out, dep, work, funs, par}).
+
+%% Note: In order to keep our domain simple, we assume that all remote
+%% calls and primops return a single value, if any.
+
+%% We use the terms `closure', `label', `lambda' and `fun-expression'
+%% interchangeably. The exact meaning in each case can be grasped from
+%% the context.
+%%
+%% Rules:
+%% 1) The implicit top level lambda escapes.
+%% 2) A lambda returned by an escaped lambda also escapes.
+%% 3) An escaped lambda can be passed an external lambda as argument.
+%% 4) A lambda passed as argument to an external lambda also escapes.
+%% 5) An argument passed to an unknown operation escapes.
+%% 6) A call to an unknown operation can return an external lambda.
+%%
+%% Escaped lambdas become part of the set of external lambdas, but this
+%% does not need to be represented explicitly.
+
+%% We wrap the given syntax tree T in a fun-expression labeled `top',
+%% which is initially in the set of escaped labels. `top' will be
+%% visited at least once.
+%%
+%% We create a separate function labeled `external', defined as:
+%% "'external'/1 = fun (Escape) -> do apply 'external'/1(apply Escape())
+%% 'external'/1", which will represent any and all functions outside T,
+%% and which returns itself, and contains a recursive call; this models
+%% rules 2 and 4 above. It will be revisited if the set of escaped
+%% labels changes, or at least once. Its parameter `Escape' is a
+%% variable labeled `escape', which will hold the set of escaped labels.
+%% initially it contains `top' and `external'.
+
+-spec analyze(cerl:cerl()) -> {outlist(), dict(), escapes(), dict(), dict()}.
+
+analyze(Tree) ->
+ %% Note that we use different name spaces for variable labels and
+ %% function/call site labels, so we can reuse some names here. We
+ %% assume that the labeling of Tree only uses integers, not atoms.
+ External = ann_c_var([{label, external}], {external, 1}),
+ Escape = ann_c_var([{label, escape}], 'Escape'),
+ ExtBody = c_seq(ann_c_apply([{label, loop}], External,
+ [ann_c_apply([{label, external_call}],
+ Escape, [])]),
+ External),
+ ExtFun = ann_c_fun([{label, external}], [Escape], ExtBody),
+%%% io:fwrite("external fun:\n~s.\n",
+%%% [cerl_prettypr:format(ExtFun, [noann])]),
+ Top = ann_c_var([{label, top}], {top, 0}),
+ TopFun = ann_c_fun([{label, top}], [], Tree),
+
+ %% The "start fun" just makes the initialisation easier. It will not
+ %% be marked as escaped, and thus cannot be called.
+ StartFun = ann_c_fun([{label, start}], [],
+ c_letrec([{External, ExtFun}, {Top, TopFun}],
+ c_nil())),
+%%% io:fwrite("start fun:\n~s.\n",
+%%% [cerl_prettypr:format(StartFun, [noann])]),
+
+ %% Gather a database of all fun-expressions in Tree and initialise
+ %% all their outputs and parameter variables. Bind all module- and
+ %% letrec-defined variables to their corresponding labels.
+ Funs0 = dict:new(),
+ Vars0 = dict:new(),
+ Out0 = dict:new(),
+ Empty = empty(),
+ F = fun (T, S = {Fs, Vs, Os}) ->
+ case type(T) of
+ 'fun' ->
+ L = get_label(T),
+ As = fun_vars(T),
+ {dict:store(L, T, Fs),
+ bind_vars_single(As, Empty, Vs),
+ dict:store(L, none, Os)};
+ letrec ->
+ {Fs, bind_defs(letrec_defs(T), Vs), Os};
+ module ->
+ {Fs, bind_defs(module_defs(T), Vs), Os};
+ _ ->
+ S
+ end
+ end,
+ {Funs, Vars, Out} = cerl_trees:fold(F, {Funs0, Vars0, Out0},
+ StartFun),
+
+ %% Initialise Escape to the minimal set of escaped labels.
+ Vars1 = dict:store(escape, from_label_list([top, external]), Vars),
+
+ %% Enter the fixpoint iteration at the StartFun.
+ St = loop(StartFun, start, #state{vars = Vars1,
+ out = Out,
+ dep = dict:new(),
+ work = init_work(),
+ funs = Funs,
+ par = dict:new()}),
+%%% io:fwrite("dependencies: ~p.\n",
+%%% [[{X, set__to_list(Y)}
+%%% || {X, Y} <- dict:to_list(St#state.dep)]]),
+ {dict:fetch(top, St#state.out),
+ tidy_dict([start, top, external], St#state.out),
+ dict:fetch(escape, St#state.vars),
+ tidy_dict([loop], St#state.dep),
+ St#state.par}.
+
+tidy_dict([X | Xs], D) ->
+ tidy_dict(Xs, dict:erase(X, D));
+tidy_dict([], D) ->
+ D.
+
+loop(T, L, St0) ->
+%%% io:fwrite("analyzing: ~w.\n", [L]),
+%%% io:fwrite("work: ~w.\n", [St0#state.work]),
+ Xs0 = dict:fetch(L, St0#state.out),
+ {Xs, St1} = visit(fun_body(T), L, St0),
+ {W, M} = case equal(Xs0, Xs) of
+ true ->
+ {St1#state.work, St1#state.out};
+ false ->
+%%% io:fwrite("out (~w) changed: ~w <- ~w.\n",
+%%% [L, Xs, Xs0]),
+ M1 = dict:store(L, Xs, St1#state.out),
+ case dict:find(L, St1#state.dep) of
+ {ok, S} ->
+ {add_work(set__to_list(S), St1#state.work),
+ M1};
+ error ->
+ {St1#state.work, M1}
+ end
+ end,
+ St2 = St1#state{out = M},
+ case take_work(W) of
+ {ok, L1, W1} ->
+ T1 = dict:fetch(L1, St2#state.funs),
+ loop(T1, L1, St2#state{work = W1});
+ none ->
+ St2
+ end.
+
+visit(T, L, St) ->
+ case type(T) of
+ literal ->
+ {[empty()], St};
+ var ->
+ %% If a variable is not already in the store here, we
+ %% initialize it to empty().
+ L1 = get_label(T),
+ Vars = St#state.vars,
+ case dict:find(L1, Vars) of
+ {ok, X} ->
+ {[X], St};
+ error ->
+ X = empty(),
+ St1 = St#state{vars = dict:store(L1, X, Vars)},
+ {[X], St1}
+ end;
+ 'fun' ->
+ %% Must revisit the fun also, because its environment might
+ %% have changed. (We don't keep track of such dependencies.)
+ L1 = get_label(T),
+ St1 = St#state{work = add_work([L1], St#state.work),
+ par = set_parent([L1], L, St#state.par)},
+ {[singleton(L1)], St1};
+ values ->
+ visit_list(values_es(T), L, St);
+ cons ->
+ {Xs, St1} = visit_list([cons_hd(T), cons_tl(T)], L, St),
+ {[join_single_list(Xs)], St1};
+ tuple ->
+ {Xs, St1} = visit_list(tuple_es(T), L, St),
+ {[join_single_list(Xs)], St1};
+ 'let' ->
+ {Xs, St1} = visit(let_arg(T), L, St),
+ Vars = bind_vars(let_vars(T), Xs, St1#state.vars),
+ visit(let_body(T), L, St1#state{vars = Vars});
+ seq ->
+ {_, St1} = visit(seq_arg(T), L, St),
+ visit(seq_body(T), L, St1);
+ apply ->
+ {Xs, St1} = visit(apply_op(T), L, St),
+ {As, St2} = visit_list(apply_args(T), L, St1),
+ case Xs of
+ [X] ->
+ %% We store the dependency from the call site to the
+ %% called functions
+ Ls = set__to_list(X),
+ Out = St2#state.out,
+ Xs1 = join_list([dict:fetch(Lx, Out) || Lx <- Ls]),
+ St3 = call_site(Ls, L, As, St2),
+ L1 = get_label(T),
+ D = dict:store(L1, X, St3#state.dep),
+ {Xs1, St3#state{dep = D}};
+ none ->
+ {none, St2}
+ end;
+ call ->
+ M = call_module(T),
+ F = call_name(T),
+ {_, St1} = visit(M, L, St),
+ {_, St2} = visit(F, L, St1),
+ {Xs, St3} = visit_list(call_args(T), L, St2),
+ remote_call(M, F, Xs, St3);
+ primop ->
+ As = primop_args(T),
+ {Xs, St1} = visit_list(As, L, St),
+ primop_call(atom_val(primop_name(T)), length(Xs), Xs, St1);
+ 'case' ->
+ {Xs, St1} = visit(case_arg(T), L, St),
+ visit_clauses(Xs, case_clauses(T), L, St1);
+ 'receive' ->
+ X = singleton(external),
+ {Xs1, St1} = visit_clauses([X], receive_clauses(T), L, St),
+ {_, St2} = visit(receive_timeout(T), L, St1),
+ {Xs2, St3} = visit(receive_action(T), L, St2),
+ {join(Xs1, Xs2), St3};
+ 'try' ->
+ {Xs1, St1} = visit(try_arg(T), L, St),
+ X = singleton(external),
+ Vars = bind_vars(try_vars(T), [X], St1#state.vars),
+ {Xs2, St2} = visit(try_body(T), L, St1#state{vars = Vars}),
+ Evars = bind_vars(try_evars(T), [X, X, X], St2#state.vars),
+ {Xs3, St3} = visit(try_handler(T), L, St2#state{vars = Evars}),
+ {join(join(Xs1, Xs2), Xs3), St3};
+ 'catch' ->
+ {_, St1} = visit(catch_body(T), L, St),
+ {[singleton(external)], St1};
+ binary ->
+ {_, St1} = visit_list(binary_segments(T), L, St),
+ {[empty()], St1};
+ bitstr ->
+ %% The other fields are constant literals.
+ {_, St1} = visit(bitstr_val(T), L, St),
+ {_, St2} = visit(bitstr_size(T), L, St1),
+ {none, St2};
+ letrec ->
+ %% All the bound funs should be revisited, because the
+ %% environment might have changed.
+ Ls = [get_label(F) || {_, F} <- letrec_defs(T)],
+ St1 = St#state{work = add_work(Ls, St#state.work),
+ par = set_parent(Ls, L, St#state.par)},
+ visit(letrec_body(T), L, St1);
+ module ->
+ %% All the exported functions escape, and can thus be passed
+ %% any external closures as arguments. We regard a module as
+ %% a tuple of function variables in the body of a `letrec'.
+ visit(c_letrec(module_defs(T), c_tuple(module_exports(T))),
+ L, St)
+ end.
+
+visit_clause(T, Xs, L, St) ->
+ Vars = bind_pats(clause_pats(T), Xs, St#state.vars),
+ {_, St1} = visit(clause_guard(T), L, St#state{vars = Vars}),
+ visit(clause_body(T), L, St1).
+
+%% We assume correct value-list typing.
+
+visit_list([T | Ts], L, St) ->
+ {Xs, St1} = visit(T, L, St),
+ {Xs1, St2} = visit_list(Ts, L, St1),
+ X = case Xs of
+ [X1] -> X1;
+ none -> none
+ end,
+ {[X | Xs1], St2};
+visit_list([], _L, St) ->
+ {[], St}.
+
+visit_clauses(Xs, [T | Ts], L, St) ->
+ {Xs1, St1} = visit_clause(T, Xs, L, St),
+ {Xs2, St2} = visit_clauses(Xs, Ts, L, St1),
+ {join(Xs1, Xs2), St2};
+visit_clauses(_, [], _L, St) ->
+ {none, St}.
+
+bind_defs([{V, F} | Ds], Vars) ->
+ bind_defs(Ds, dict:store(get_label(V), singleton(get_label(F)),
+ Vars));
+bind_defs([], Vars) ->
+ Vars.
+
+bind_pats(Ps, none, Vars) ->
+ bind_pats_single(Ps, empty(), Vars);
+bind_pats(Ps, Xs, Vars) ->
+ if length(Xs) =:= length(Ps) ->
+ bind_pats_list(Ps, Xs, Vars);
+ true ->
+ bind_pats_single(Ps, empty(), Vars)
+ end.
+
+bind_pats_list([P | Ps], [X | Xs], Vars) ->
+ bind_pats_list(Ps, Xs, bind_vars_single(pat_vars(P), X, Vars));
+bind_pats_list([], [], Vars) ->
+ Vars.
+
+bind_pats_single([P | Ps], X, Vars) ->
+ bind_pats_single(Ps, X, bind_vars_single(pat_vars(P), X, Vars));
+bind_pats_single([], _X, Vars) ->
+ Vars.
+
+bind_vars(Vs, none, Vars) ->
+ bind_vars_single(Vs, empty(), Vars);
+bind_vars(Vs, Xs, Vars) ->
+ if length(Vs) =:= length(Xs) ->
+ bind_vars_list(Vs, Xs, Vars);
+ true ->
+ bind_vars_single(Vs, empty(), Vars)
+ end.
+
+bind_vars_list([V | Vs], [X | Xs], Vars) ->
+ bind_vars_list(Vs, Xs, dict:store(get_label(V), X, Vars));
+bind_vars_list([], [], Vars) ->
+ Vars.
+
+bind_vars_single([V | Vs], X, Vars) ->
+ bind_vars_single(Vs, X, dict:store(get_label(V), X, Vars));
+bind_vars_single([], _X, Vars) ->
+ Vars.
+
+%% This handles a call site - adding dependencies and updating parameter
+%% variables with respect to the actual parameters. The 'external'
+%% function is handled specially, since it can get an arbitrary number
+%% of arguments, which must be unified into a single argument.
+
+call_site(Ls, L, Xs, St) ->
+%%% io:fwrite("call site: ~w -> ~w (~w).\n", [L, Ls, Xs]),
+ {D, W, V} = call_site(Ls, L, Xs, St#state.dep, St#state.work,
+ St#state.vars, St#state.funs),
+ St#state{dep = D, work = W, vars = V}.
+
+call_site([external | Ls], T, Xs, D, W, V, Fs) ->
+ D1 = add_dep(external, T, D),
+ X = join_single_list(Xs),
+ case bind_arg(escape, X, V) of
+ {V1, true} ->
+%%% io:fwrite("escape changed: ~w <- ~w + ~w.\n",
+%%% [dict:fetch(escape, V1), dict:fetch(escape, V),
+%%% X]),
+ {W1, V2} = update_esc(set__to_list(X), W, V1, Fs),
+ call_site(Ls, T, Xs, D1, add_work([external], W1), V2, Fs);
+ {V1, false} ->
+ call_site(Ls, T, Xs, D1, W, V1, Fs)
+ end;
+call_site([L | Ls], T, Xs, D, W, V, Fs) ->
+ D1 = add_dep(L, T, D),
+ Vs = fun_vars(dict:fetch(L, Fs)),
+ case bind_args(Vs, Xs, V) of
+ {V1, true} ->
+ call_site(Ls, T, Xs, D1, add_work([L], W), V1, Fs);
+ {V1, false} ->
+ call_site(Ls, T, Xs, D1, W, V1, Fs)
+ end;
+call_site([], _, _, D, W, V, _) ->
+ {D, W, V}.
+
+%% Note that `visit' makes sure all lambdas are visited at least once.
+%% For every called function, we add a dependency from the *called*
+%% function to the function containing the call site.
+
+add_dep(Source, Target, Deps) ->
+ case dict:find(Source, Deps) of
+ {ok, X} ->
+ case set__is_member(Target, X) of
+ true ->
+ Deps;
+ false ->
+%%% io:fwrite("new dep: ~w <- ~w.\n", [Target, Source]),
+ dict:store(Source, set__add(Target, X), Deps)
+ end;
+ error ->
+%%% io:fwrite("new dep: ~w <- ~w.\n", [Target, Source]),
+ dict:store(Source, set__singleton(Target), Deps)
+ end.
+
+%% If the arity does not match the call, nothing is done here.
+
+bind_args(Vs, Xs, Vars) ->
+ if length(Vs) =:= length(Xs) ->
+ bind_args(Vs, Xs, Vars, false);
+ true ->
+ {Vars, false}
+ end.
+
+bind_args([V | Vs], [X | Xs], Vars, Ch) ->
+ L = get_label(V),
+ {Vars1, Ch1} = bind_arg(L, X, Vars, Ch),
+ bind_args(Vs, Xs, Vars1, Ch1);
+bind_args([], [], Vars, Ch) ->
+ {Vars, Ch}.
+
+bind_args_single(Vs, X, Vars) ->
+ bind_args_single(Vs, X, Vars, false).
+
+bind_args_single([V | Vs], X, Vars, Ch) ->
+ L = get_label(V),
+ {Vars1, Ch1} = bind_arg(L, X, Vars, Ch),
+ bind_args_single(Vs, X, Vars1, Ch1);
+bind_args_single([], _, Vars, Ch) ->
+ {Vars, Ch}.
+
+bind_arg(L, X, Vars) ->
+ bind_arg(L, X, Vars, false).
+
+bind_arg(L, X, Vars, Ch) ->
+ X0 = dict:fetch(L, Vars),
+ X1 = join_single(X, X0),
+ case equal_single(X0, X1) of
+ true ->
+ {Vars, Ch};
+ false ->
+%%% io:fwrite("arg (~w) changed: ~w <- ~w + ~w.\n",
+%%% [L, X1, X0, X]),
+ {dict:store(L, X1, Vars), true}
+ end.
+
+%% This handles escapes from things like primops and remote calls.
+
+%% escape(none, St) ->
+%% St;
+escape([X], St) ->
+ Vars = St#state.vars,
+ X0 = dict:fetch(escape, Vars),
+ X1 = join_single(X, X0),
+ case equal_single(X0, X1) of
+ true ->
+ St;
+ false ->
+%%% io:fwrite("escape changed: ~w <- ~w + ~w.\n", [X1, X0, X]),
+%%% io:fwrite("updating escaping funs: ~w.\n", [set__to_list(X)]),
+ Vars1 = dict:store(escape, X1, Vars),
+ {W, Vars2} = update_esc(set__to_list(set__subtract(X, X0)),
+ St#state.work, Vars1,
+ St#state.funs),
+ St#state{work = add_work([external], W), vars = Vars2}
+ end.
+
+%% For all escaping lambdas, since they might be called from outside the
+%% program, all their arguments may be an external lambda. (Note that we
+%% only have to include the `external' label once per escaping lambda.)
+%% If the escape set has changed, we need to revisit the `external' fun.
+
+update_esc(Ls, W, V, Fs) ->
+ update_esc(Ls, singleton(external), W, V, Fs).
+
+%% The external lambda is skipped here - the Escape variable is known to
+%% contain `external' from the start.
+
+update_esc([external | Ls], X, W, V, Fs) ->
+ update_esc(Ls, X, W, V, Fs);
+update_esc([L | Ls], X, W, V, Fs) ->
+ Vs = fun_vars(dict:fetch(L, Fs)),
+ case bind_args_single(Vs, X, V) of
+ {V1, true} ->
+ update_esc(Ls, X, add_work([L], W), V1, Fs);
+ {V1, false} ->
+ update_esc(Ls, X, W, V1, Fs)
+ end;
+update_esc([], _, W, V, _) ->
+ {W, V}.
+
+set_parent([L | Ls], L1, D) ->
+ set_parent(Ls, L1, dict:store(L, L1, D));
+set_parent([], _L1, D) ->
+ D.
+
+%% Handle primop calls: (At present, we assume that all unknown primops
+%% yield exactly one value. This might have to be changed.)
+
+primop_call(F, A, Xs, St0) ->
+ case is_pure_op(F, A) of
+ %% XXX: this case is currently not possible -- commented out.
+ %% true ->
+ %% case is_literal_op(F, A) of
+ %% true -> {[empty()], St0};
+ %% false -> {[join_single_list(Xs)], St0}
+ %% end;
+ false ->
+ St1 = case is_escape_op(F, A) of
+ true -> escape([join_single_list(Xs)], St0);
+ false -> St0
+ end,
+ case is_literal_op(F, A) of
+ true -> {none, St1};
+ false -> {[singleton(external)], St1}
+ end
+ end.
+
+%% Handle remote-calls: (At present, we assume that all unknown calls
+%% yield exactly one value. This might have to be changed.)
+
+remote_call(M, F, Xs, St) ->
+ case is_c_atom(M) andalso is_c_atom(F) of
+ true ->
+ remote_call_1(atom_val(M), atom_val(F), length(Xs), Xs, St);
+ false ->
+ %% Unknown function
+ {[singleton(external)], escape([join_single_list(Xs)], St)}
+ end.
+
+remote_call_1(M, F, A, Xs, St0) ->
+ case is_pure_op(M, F, A) of
+ true ->
+ case is_literal_op(M, F, A) of
+ true -> {[empty()], St0};
+ false -> {[join_single_list(Xs)], St0}
+ end;
+ false ->
+ St1 = case is_escape_op(M, F, A) of
+ true -> escape([join_single_list(Xs)], St0);
+ false -> St0
+ end,
+ case is_literal_op(M, F, A) of
+ true -> {[empty()], St1};
+ false -> {[singleton(external)], St1}
+ end
+ end.
+
+%% Domain: none | [Vs], where Vs = set(integer()).
+
+join(none, Xs2) -> Xs2;
+join(Xs1, none) -> Xs1;
+join(Xs1, Xs2) ->
+ if length(Xs1) =:= length(Xs2) ->
+ join_1(Xs1, Xs2);
+ true ->
+ none
+ end.
+
+join_1([X1 | Xs1], [X2 | Xs2]) ->
+ [join_single(X1, X2) | join_1(Xs1, Xs2)];
+join_1([], []) ->
+ [].
+
+empty() -> set__new().
+
+singleton(X) -> set__singleton(X).
+
+from_label_list(X) -> set__from_list(X).
+
+join_single(none, Y) -> Y;
+join_single(X, none) -> X;
+join_single(X, Y) -> set__union(X, Y).
+
+join_list([Xs | Xss]) ->
+ join(Xs, join_list(Xss));
+join_list([]) ->
+ none.
+
+join_single_list([X | Xs]) ->
+ join_single(X, join_single_list(Xs));
+join_single_list([]) ->
+ empty().
+
+equal(none, none) -> true;
+equal(none, _) -> false;
+equal(_, none) -> false;
+equal(X1, X2) -> equal_1(X1, X2).
+
+equal_1([X1 | Xs1], [X2 | Xs2]) ->
+ equal_single(X1, X2) andalso equal_1(Xs1, Xs2);
+equal_1([], []) -> true;
+equal_1(_, _) -> false.
+
+equal_single(X, Y) -> set__equal(X, Y).
+
+%% Set abstraction for label sets in the domain.
+
+set__new() -> [].
+
+set__singleton(X) -> [X].
+
+set__to_list(S) -> S.
+
+set__from_list(S) -> ordsets:from_list(S).
+
+set__union(X, Y) -> ordsets:union(X, Y).
+
+set__add(X, S) -> ordsets:add_element(X, S).
+
+set__is_member(X, S) -> ordsets:is_element(X, S).
+
+set__subtract(X, Y) -> ordsets:subtract(X, Y).
+
+set__equal(X, Y) -> X =:= Y.
+
+%% A simple but efficient functional queue.
+
+queue__new() -> {[], []}.
+
+queue__put(X, {In, Out}) -> {[X | In], Out}.
+
+queue__get({In, [X | Out]}) -> {ok, X, {In, Out}};
+queue__get({[], _}) -> empty;
+queue__get({In, _}) ->
+ [X | In1] = lists:reverse(In),
+ {ok, X, {[], In1}}.
+
+%% The work list - a queue without repeated elements.
+
+init_work() ->
+ {queue__new(), sets:new()}.
+
+add_work(Ls, {Q, Set}) ->
+ add_work(Ls, Q, Set).
+
+%% Note that the elements are enqueued in order.
+
+add_work([L | Ls], Q, Set) ->
+ case sets:is_element(L, Set) of
+ true ->
+ add_work(Ls, Q, Set);
+ false ->
+ add_work(Ls, queue__put(L, Q), sets:add_element(L, Set))
+ end;
+add_work([], Q, Set) ->
+ {Q, Set}.
+
+take_work({Queue0, Set0}) ->
+ case queue__get(Queue0) of
+ {ok, L, Queue1} ->
+ Set1 = sets:del_element(L, Set0),
+ {ok, L, {Queue1, Set1}};
+ empty ->
+ none
+ end.
+
+%% Escape operators may let their arguments escape. Unless we know
+%% otherwise, and the function is not pure, we assume this is the case.
+%% Error-raising functions (fault/match_fail) are not considered as
+%% escapes (but throw/exit are). Zero-argument functions need not be
+%% listed.
+
+-spec is_escape_op(atom(), arity()) -> boolean().
+
+is_escape_op(match_fail, 1) -> false;
+is_escape_op(F, A) when is_atom(F), is_integer(A) -> true.
+
+-spec is_escape_op(module(), atom(), arity()) -> boolean().
+
+is_escape_op(erlang, error, 1) -> false;
+is_escape_op(erlang, error, 2) -> false;
+is_escape_op(M, F, A) when is_atom(M), is_atom(F), is_integer(A) -> true.
+
+%% "Literal" operators will never return functional values even when
+%% found in their arguments. Unless we know otherwise, we assume this is
+%% not the case. (More functions can be added to this list, if needed
+%% for better precision. Note that the result of `term_to_binary' still
+%% contains an encoding of the closure.)
+
+-spec is_literal_op(atom(), arity()) -> boolean().
+
+is_literal_op(match_fail, 1) -> true;
+is_literal_op(F, A) when is_atom(F), is_integer(A) -> false.
+
+-spec is_literal_op(module(), atom(), arity()) -> boolean().
+
+is_literal_op(erlang, '+', 2) -> true;
+is_literal_op(erlang, '-', 2) -> true;
+is_literal_op(erlang, '*', 2) -> true;
+is_literal_op(erlang, '/', 2) -> true;
+is_literal_op(erlang, '=:=', 2) -> true;
+is_literal_op(erlang, '==', 2) -> true;
+is_literal_op(erlang, '=/=', 2) -> true;
+is_literal_op(erlang, '/=', 2) -> true;
+is_literal_op(erlang, '<', 2) -> true;
+is_literal_op(erlang, '=<', 2) -> true;
+is_literal_op(erlang, '>', 2) -> true;
+is_literal_op(erlang, '>=', 2) -> true;
+is_literal_op(erlang, 'and', 2) -> true;
+is_literal_op(erlang, 'or', 2) -> true;
+is_literal_op(erlang, 'not', 1) -> true;
+is_literal_op(erlang, length, 1) -> true;
+is_literal_op(erlang, size, 1) -> true;
+is_literal_op(erlang, fun_info, 1) -> true;
+is_literal_op(erlang, fun_info, 2) -> true;
+is_literal_op(erlang, fun_to_list, 1) -> true;
+is_literal_op(erlang, throw, 1) -> true;
+is_literal_op(erlang, exit, 1) -> true;
+is_literal_op(erlang, error, 1) -> true;
+is_literal_op(erlang, error, 2) -> true;
+is_literal_op(M, F, A) when is_atom(M), is_atom(F), is_integer(A) -> false.
+
+%% Pure functions neither affect the state, nor depend on it.
+
+is_pure_op(F, A) when is_atom(F), is_integer(A) -> false.
+
+is_pure_op(M, F, A) -> erl_bifs:is_pure(M, F, A).
+
+%% =====================================================================