%% ``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 via the world wide web 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.
%%
%% The Initial Developer of the Original Code is Ericsson Utvecklings AB.
%% Portions created by Ericsson are Copyright 1999, Ericsson Utvecklings
%% AB. All Rights Reserved.''
%%
%% $Id: v3_core.erl,v 1.1 2008/12/17 09:53:42 mikpe Exp $
%%
%% Purpose : Transform normal Erlang to Core Erlang
%% At this stage all preprocessing has been done. All that is left are
%% "pure" Erlang functions.
%%
%% Core transformation is done in three stages:
%%
%% 1. Flatten expressions into an internal core form without doing
%% matching.
%%
%% 2. Step "forwards" over the icore code annotating each "top-level"
%% thing with variable usage. Detect bound variables in matching
%% and replace with explicit guard test. Annotate "internal-core"
%% expressions with variables they use and create. Convert matches
%% to cases when not pure assignments.
%%
%% 3. Step "backwards" over icore code using variable usage
%% annotations to change implicit exported variables to explicit
%% returns.
%%
%% To ensure the evaluation order we ensure that all arguments are
%% safe. A "safe" is basically a core_lib simple with VERY restricted
%% binaries.
%%
%% We have to be very careful with matches as these create variables.
%% While we try not to flatten things more than necessary we must make
%% sure that all matches are at the top level. For this we use the
%% type "novars" which are non-match expressions. Cases and receives
%% can also create problems due to exports variables so they are not
%% "novars" either. I.e. a novars will not export variables.
%%
%% Annotations in the #iset, #iletrec, and all other internal records
%% is kept in a record, #a, not in a list as in proper core. This is
%% easier and faster and creates no problems as we have complete control
%% over all annotations.
%%
%% On output, the annotation for most Core Erlang terms will contain
%% the source line number. A few terms will be marked with the atom
%% atom 'compiler_generated', to indicate that the compiler has generated
%% them and that no warning should be generated if they are optimized
%% away.
%%
%%
%% In this translation:
%%
%% call ops are safes
%% call arguments are safes
%% match arguments are novars
%% case arguments are novars
%% receive timeouts are novars
%% let/set arguments are expressions
%% fun is not a safe
-module(v3_core).
-export([module/2,format_error/1]).
-import(lists, [map/2,foldl/3,foldr/3,mapfoldl/3,splitwith/2]).
-import(ordsets, [add_element/2,del_element/2,is_element/2,
union/1,union/2,intersection/2,subtract/2]).
-include("core_parse.hrl").
-record(a, {us=[],ns=[],anno=[]}). %Internal annotation
%% Internal core expressions and help functions.
%% N.B. annotations fields in place as normal Core expressions.
-record(iset, {anno=#a{},var,arg}).
-record(iletrec, {anno=#a{},defs,body}).
-record(imatch, {anno=#a{},pat,guard=[],arg,fc}).
-record(icase, {anno=#a{},args,clauses,fc}).
-record(iclause, {anno=#a{},pats,pguard=[],guard,body}).
-record(ifun, {anno=#a{},id,vars,clauses,fc}).
-record(iapply, {anno=#a{},op,args}).
-record(icall, {anno=#a{},module,name,args}).
-record(iprimop, {anno=#a{},name,args}).
-record(itry, {anno=#a{},args,vars,body,evars,handler}).
-record(icatch, {anno=#a{},body}).
-record(ireceive1, {anno=#a{},clauses}).
-record(ireceive2, {anno=#a{},clauses,timeout,action}).
-record(iprotect, {anno=#a{},body}).
-record(ibinary, {anno=#a{},segments}). %Not used in patterns.
-record(core, {vcount=0, %Variable counter
fcount=0, %Function counter
ws=[]}). %Warnings.
module({Mod,Exp,Forms}, _Opts) ->
Cexp = map(fun ({N,A}) -> #c_fname{id=N,arity=A} end, Exp),
{Kfs,As,Ws} = foldr(fun form/2, {[],[],[]}, Forms),
{ok,#c_module{name=#c_atom{val=Mod},exports=Cexp,attrs=As,defs=Kfs},Ws}.
form({function,_,_,_,_}=F0, {Fs,As,Ws0}) ->
{F,Ws} = function(F0, Ws0),
{[F|Fs],As,Ws};
form({attribute,_,_,_}=F, {Fs,As,Ws}) ->
{Fs,[attribute(F)|As],Ws}.
attribute({attribute,_,Name,Val}) ->
#c_def{name=core_lib:make_literal(Name),
val=core_lib:make_literal(Val)}.
function({function,_,Name,Arity,Cs0}, Ws0) ->
%%ok = io:fwrite("~p - ", [{Name,Arity}]),
St0 = #core{vcount=0,ws=Ws0},
{B0,St1} = body(Cs0, Arity, St0),
%%ok = io:fwrite("1", []),
%%ok = io:fwrite("~w:~p~n", [?LINE,B0]),
{B1,St2} = ubody(B0, St1),
%%ok = io:fwrite("2", []),
%%ok = io:fwrite("~w:~p~n", [?LINE,B1]),
{B2,#core{ws=Ws}} = cbody(B1, St2),
%%ok = io:fwrite("3~n", []),
{#c_def{name=#c_fname{id=Name,arity=Arity},val=B2},Ws}.
body(Cs0, Arity, St0) ->
Anno = [element(2, hd(Cs0))],
{Args,St1} = new_vars(Anno, Arity, St0),
{Cs1,St2} = clauses(Cs0, St1),
{Ps,St3} = new_vars(Arity, St2), %Need new variables here
Fc = fail_clause(Ps, #c_tuple{es=[#c_atom{val=function_clause}|Ps]}),
{#ifun{anno=#a{anno=Anno},id=[],vars=Args,clauses=Cs1,fc=Fc},St3}.
%% clause(Clause, State) -> {Cclause,State} | noclause.
%% clauses([Clause], State) -> {[Cclause],State}.
%% Convert clauses. Trap bad pattern aliases and remove clause from
%% clause list.
clauses([C0|Cs0], St0) ->
case clause(C0, St0) of
{noclause,St} -> clauses(Cs0, St);
{C,St1} ->
{Cs,St2} = clauses(Cs0, St1),
{[C|Cs],St2}
end;
clauses([], St) -> {[],St}.
clause({clause,Lc,H0,G0,B0}, St0) ->
case catch head(H0) of
{'EXIT',_}=Exit -> exit(Exit); %Propagate error
nomatch ->
St = add_warning(Lc, nomatch, St0),
{noclause,St}; %Bad pattern
H1 ->
{G1,St1} = guard(G0, St0),
{B1,St2} = exprs(B0, St1),
{#iclause{anno=#a{anno=[Lc]},pats=H1,guard=G1,body=B1},St2}
end.
%% head([P]) -> [P].
head(Ps) -> pattern_list(Ps).
%% guard([Expr], State) -> {[Cexpr],State}.
%% Build an explict and/or tree of guard alternatives, then traverse
%% top-level and/or tree and "protect" inner tests.
guard([], St) -> {[],St};
guard(Gs0, St) ->
Gs = foldr(fun (Gt0, Rhs) ->
Gt1 = guard_tests(Gt0),
L = element(2, Gt1),
{op,L,'or',Gt1,Rhs}
end, guard_tests(last(Gs0)), first(Gs0)),
gexpr_top(Gs, St).
guard_tests([]) -> [];
guard_tests(Gs) ->
L = element(2, hd(Gs)),
{protect,L,foldr(fun (G, Rhs) -> {op,L,'and',G,Rhs} end, last(Gs), first(Gs))}.
%% gexpr_top(Expr, State) -> {Cexpr,State}.
%% Generate an internal core expression of a guard test. Explicitly
%% handle outer boolean expressions and "protect" inner tests in a
%% reasonably smart way.
gexpr_top(E0, St0) ->
{E1,Eps0,Bools,St1} = gexpr(E0, [], St0),
{E,Eps,St} = force_booleans(Bools, E1, Eps0, St1),
{Eps++[E],St}.
%% gexpr(Expr, Bools, State) -> {Cexpr,[PreExp],Bools,State}.
%% Generate an internal core expression of a guard test.
gexpr({protect,Line,Arg}, Bools0, St0) ->
case gexpr(Arg, [], St0) of
{E0,[],Bools,St1} ->
{E,Eps,St} = force_booleans(Bools, E0, [], St1),
{E,Eps,Bools0,St};
{E0,Eps0,Bools,St1} ->
{E,Eps,St} = force_booleans(Bools, E0, Eps0, St1),
{#iprotect{anno=#a{anno=[Line]},body=Eps++[E]},[],Bools0,St}
end;
gexpr({op,Line,Op,L,R}=Call, Bools0, St0) ->
case erl_internal:bool_op(Op, 2) of
true ->
{Le,Lps,Bools1,St1} = gexpr(L, Bools0, St0),
{Ll,Llps,St2} = force_safe(Le, St1),
{Re,Rps,Bools,St3} = gexpr(R, Bools1, St2),
{Rl,Rlps,St4} = force_safe(Re, St3),
Anno = [Line],
{#icall{anno=#a{anno=Anno}, %Must have an #a{}
module=#c_atom{anno=Anno,val=erlang},name=#c_atom{anno=Anno,val=Op},
args=[Ll,Rl]},Lps ++ Llps ++ Rps ++ Rlps,Bools,St4};
false ->
gexpr_test(Call, Bools0, St0)
end;
gexpr({op,Line,Op,A}=Call, Bools0, St0) ->
case erl_internal:bool_op(Op, 1) of
true ->
{Ae,Aps,Bools,St1} = gexpr(A, Bools0, St0),
{Al,Alps,St2} = force_safe(Ae, St1),
Anno = [Line],
{#icall{anno=#a{anno=Anno}, %Must have an #a{}
module=#c_atom{anno=Anno,val=erlang},name=#c_atom{anno=Anno,val=Op},
args=[Al]},Aps ++ Alps,Bools,St2};
false ->
gexpr_test(Call, Bools0, St0)
end;
gexpr(E0, Bools, St0) ->
gexpr_test(E0, Bools, St0).
%% gexpr_test(Expr, Bools, State) -> {Cexpr,[PreExp],Bools,State}.
%% Generate a guard test. At this stage we must be sure that we have
%% a proper boolean value here so wrap things with an true test if we
%% don't know, i.e. if it is not a comparison or a type test.
gexpr_test({atom,L,true}, Bools, St0) ->
{#c_atom{anno=[L],val=true},[],Bools,St0};
gexpr_test({atom,L,false}, Bools, St0) ->
{#c_atom{anno=[L],val=false},[],Bools,St0};
gexpr_test(E0, Bools0, St0) ->
{E1,Eps0,St1} = expr(E0, St0),
%% Generate "top-level" test and argument calls.
case E1 of
#icall{anno=Anno,module=#c_atom{val=erlang},name=#c_atom{val=N},args=As} ->
Ar = length(As),
case erl_internal:type_test(N, Ar) orelse
erl_internal:comp_op(N, Ar) orelse
(N == internal_is_record andalso Ar == 3) of
true -> {E1,Eps0,Bools0,St1};
false ->
Lanno = Anno#a.anno,
{New,St2} = new_var(Lanno, St1),
Bools = [New|Bools0],
{#icall{anno=Anno, %Must have an #a{}
module=#c_atom{anno=Lanno,val=erlang},
name=#c_atom{anno=Lanno,val='=:='},
args=[New,#c_atom{anno=Lanno,val=true}]},
Eps0 ++ [#iset{anno=Anno,var=New,arg=E1}],Bools,St2}
end;
_ ->
Anno = get_ianno(E1),
Lanno = get_lineno_anno(E1),
case core_lib:is_simple(E1) of
true ->
Bools = [E1|Bools0],
{#icall{anno=Anno, %Must have an #a{}
module=#c_atom{anno=Lanno,val=erlang},
name=#c_atom{anno=Lanno,val='=:='},
args=[E1,#c_atom{anno=Lanno,val=true}]},Eps0,Bools,St1};
false ->
{New,St2} = new_var(Lanno, St1),
Bools = [New|Bools0],
{#icall{anno=Anno, %Must have an #a{}
module=#c_atom{anno=Lanno,val=erlang},
name=#c_atom{anno=Lanno,val='=:='},
args=[New,#c_atom{anno=Lanno,val=true}]},
Eps0 ++ [#iset{anno=Anno,var=New,arg=E1}],Bools,St2}
end
end.
force_booleans([], E, Eps, St) ->
{E,Eps,St};
force_booleans([V|Vs], E0, Eps0, St0) ->
{E1,Eps1,St1} = force_safe(E0, St0),
Lanno = element(2, V),
Anno = #a{anno=Lanno},
Call = #icall{anno=Anno,module=#c_atom{anno=Lanno,val=erlang},
name=#c_atom{anno=Lanno,val=is_boolean},
args=[V]},
{New,St} = new_var(Lanno, St1),
Iset = #iset{anno=Anno,var=New,arg=Call},
Eps = Eps0 ++ Eps1 ++ [Iset],
E = #icall{anno=Anno,
module=#c_atom{anno=Lanno,val=erlang},name=#c_atom{anno=Lanno,val='and'},
args=[E1,New]},
force_booleans(Vs, E, Eps, St).
%% exprs([Expr], State) -> {[Cexpr],State}.
%% Flatten top-level exprs.
exprs([E0|Es0], St0) ->
{E1,Eps,St1} = expr(E0, St0),
{Es1,St2} = exprs(Es0, St1),
{Eps ++ [E1] ++ Es1,St2};
exprs([], St) -> {[],St}.
%% expr(Expr, State) -> {Cexpr,[PreExp],State}.
%% Generate an internal core expression.
expr({var,L,V}, St) -> {#c_var{anno=[L],name=V},[],St};
expr({char,L,C}, St) -> {#c_char{anno=[L],val=C},[],St};
expr({integer,L,I}, St) -> {#c_int{anno=[L],val=I},[],St};
expr({float,L,F}, St) -> {#c_float{anno=[L],val=F},[],St};
expr({atom,L,A}, St) -> {#c_atom{anno=[L],val=A},[],St};
expr({nil,L}, St) -> {#c_nil{anno=[L]},[],St};
expr({string,L,S}, St) -> {#c_string{anno=[L],val=S},[],St};
expr({cons,L,H0,T0}, St0) ->
{H1,Hps,St1} = safe(H0, St0),
{T1,Tps,St2} = safe(T0, St1),
{#c_cons{anno=[L],hd=H1,tl=T1},Hps ++ Tps,St2};
expr({lc,L,E,Qs}, St) ->
lc_tq(L, E, Qs, {nil,L}, St);
expr({tuple,L,Es0}, St0) ->
{Es1,Eps,St1} = safe_list(Es0, St0),
{#c_tuple{anno=[L],es=Es1},Eps,St1};
expr({bin,L,Es0}, St0) ->
{Es1,Eps,St1} = expr_bin(Es0, St0),
{#ibinary{anno=#a{anno=[L]},segments=Es1},Eps,St1};
expr({block,_,Es0}, St0) ->
%% Inline the block directly.
{Es1,St1} = exprs(first(Es0), St0),
{E1,Eps,St2} = expr(last(Es0), St1),
{E1,Es1 ++ Eps,St2};
expr({'if',L,Cs0}, St0) ->
{Cs1,St1} = clauses(Cs0, St0),
Fc = fail_clause([], #c_atom{val=if_clause}),
{#icase{anno=#a{anno=[L]},args=[],clauses=Cs1,fc=Fc},[],St1};
expr({'case',L,E0,Cs0}, St0) ->
{E1,Eps,St1} = novars(E0, St0),
{Cs1,St2} = clauses(Cs0, St1),
{Fpat,St3} = new_var(St2),
Fc = fail_clause([Fpat], #c_tuple{es=[#c_atom{val=case_clause},Fpat]}),
{#icase{anno=#a{anno=[L]},args=[E1],clauses=Cs1,fc=Fc},Eps,St3};
expr({'receive',L,Cs0}, St0) ->
{Cs1,St1} = clauses(Cs0, St0),
{#ireceive1{anno=#a{anno=[L]},clauses=Cs1}, [], St1};
expr({'receive',L,Cs0,Te0,Tes0}, St0) ->
{Te1,Teps,St1} = novars(Te0, St0),
{Tes1,St2} = exprs(Tes0, St1),
{Cs1,St3} = clauses(Cs0, St2),
{#ireceive2{anno=#a{anno=[L]},
clauses=Cs1,timeout=Te1,action=Tes1},Teps,St3};
expr({'try',L,Es0,[],Ecs,[]}, St0) ->
%% 'try ... catch ... end'
{Es1,St1} = exprs(Es0, St0),
{V,St2} = new_var(St1), %This name should be arbitrary
{Evs,Hs,St3} = try_exception(Ecs, St2),
{#itry{anno=#a{anno=[L]},args=Es1,vars=[V],body=[V],
evars=Evs,handler=Hs},
[],St3};
expr({'try',L,Es0,Cs0,Ecs,[]}, St0) ->
%% 'try ... of ... catch ... end'
{Es1,St1} = exprs(Es0, St0),
{V,St2} = new_var(St1), %This name should be arbitrary
{Cs1,St3} = clauses(Cs0, St2),
{Fpat,St4} = new_var(St3),
Fc = fail_clause([Fpat], #c_tuple{es=[#c_atom{val=try_clause},Fpat]}),
{Evs,Hs,St5} = try_exception(Ecs, St4),
{#itry{anno=#a{anno=[L]},args=Es1,
vars=[V],body=[#icase{anno=#a{},args=[V],clauses=Cs1,fc=Fc}],
evars=Evs,handler=Hs},
[],St5};
expr({'try',L,Es0,[],[],As0}, St0) ->
%% 'try ... after ... end'
{Es1,St1} = exprs(Es0, St0),
{As1,St2} = exprs(As0, St1),
{Evs,Hs,St3} = try_after(As1,St2),
{V,St4} = new_var(St3), % (must not exist in As1)
%% TODO: this duplicates the 'after'-code; should lift to function.
{#itry{anno=#a{anno=[L]},args=Es1,vars=[V],body=As1++[V],
evars=Evs,handler=Hs},
[],St4};
expr({'try',L,Es,Cs,Ecs,As}, St0) ->
%% 'try ... [of ...] [catch ...] after ... end'
expr({'try',L,[{'try',L,Es,Cs,Ecs,[]}],[],[],As}, St0);
expr({'catch',L,E0}, St0) ->
{E1,Eps,St1} = expr(E0, St0),
{#icatch{anno=#a{anno=[L]},body=Eps ++ [E1]},[],St1};
expr({'fun',L,{function,F,A},{_,_,_}=Id}, St) ->
{#c_fname{anno=[L,{id,Id}],id=F,arity=A},[],St};
expr({'fun',L,{clauses,Cs},Id}, St) ->
fun_tq(Id, Cs, L, St);
expr({call,L0,{remote,_,{atom,_,erlang},{atom,_,is_record}},[_,_,_]=As}, St)
when L0 < 0 ->
%% Compiler-generated erlang:is_record/3 should be converted to
%% erlang:internal_is_record/3.
L = -L0,
expr({call,L,{remote,L,{atom,L,erlang},{atom,L,internal_is_record}},As}, St);
expr({call,L,{remote,_,M,F},As0}, St0) ->
{[M1,F1|As1],Aps,St1} = safe_list([M,F|As0], St0),
{#icall{anno=#a{anno=[L]},module=M1,name=F1,args=As1},Aps,St1};
expr({call,Lc,{atom,Lf,F},As0}, St0) ->
{As1,Aps,St1} = safe_list(As0, St0),
Op = #c_fname{anno=[Lf],id=F,arity=length(As1)},
{#iapply{anno=#a{anno=[Lc]},op=Op,args=As1},Aps,St1};
expr({call,L,FunExp,As0}, St0) ->
{Fun,Fps,St1} = safe(FunExp, St0),
{As1,Aps,St2} = safe_list(As0, St1),
{#iapply{anno=#a{anno=[L]},op=Fun,args=As1},Fps ++ Aps,St2};
expr({match,L,P0,E0}, St0) ->
%% First fold matches together to create aliases.
{P1,E1} = fold_match(E0, P0),
{E2,Eps,St1} = novars(E1, St0),
P2 = (catch pattern(P1)),
{Fpat,St2} = new_var(St1),
Fc = fail_clause([Fpat], #c_tuple{es=[#c_atom{val=badmatch},Fpat]}),
case P2 of
{'EXIT',_}=Exit -> exit(Exit); %Propagate error
nomatch ->
St = add_warning(L, nomatch, St2),
{#icase{anno=#a{anno=[L]},
args=[E2],clauses=[],fc=Fc},Eps,St};
_Other ->
{#imatch{anno=#a{anno=[L]},pat=P2,arg=E2,fc=Fc},Eps,St2}
end;
expr({op,_,'++',{lc,Llc,E,Qs},L2}, St) ->
%% Optimise this here because of the list comprehension algorithm.
lc_tq(Llc, E, Qs, L2, St);
expr({op,L,Op,A0}, St0) ->
{A1,Aps,St1} = safe(A0, St0),
LineAnno = [L],
{#icall{anno=#a{anno=LineAnno}, %Must have an #a{}
module=#c_atom{anno=LineAnno,val=erlang},
name=#c_atom{anno=LineAnno,val=Op},args=[A1]},Aps,St1};
expr({op,L,Op,L0,R0}, St0) ->
{As,Aps,St1} = safe_list([L0,R0], St0),
LineAnno = [L],
{#icall{anno=#a{anno=LineAnno}, %Must have an #a{}
module=#c_atom{anno=LineAnno,val=erlang},
name=#c_atom{anno=LineAnno,val=Op},args=As},Aps,St1}.
%% try_exception([ExcpClause], St) -> {[ExcpVar],Handler,St}.
try_exception(Ecs0, St0) ->
%% Note that Tag is not needed for rethrow - it is already in Info.
{Evs,St1} = new_vars(3, St0), % Tag, Value, Info
{Ecs1,St2} = clauses(Ecs0, St1),
[_,Value,Info] = Evs,
Ec = #iclause{anno=#a{anno=[compiler_generated]},
pats=[#c_tuple{es=Evs}],guard=[#c_atom{val=true}],
body=[#iprimop{anno=#a{}, %Must have an #a{}
name=#c_atom{val=raise},
args=[Info,Value]}]},
Hs = [#icase{anno=#a{},args=[#c_tuple{es=Evs}],clauses=Ecs1,fc=Ec}],
{Evs,Hs,St2}.
try_after(As, St0) ->
%% See above.
{Evs,St1} = new_vars(3, St0), % Tag, Value, Info
[_,Value,Info] = Evs,
B = As ++ [#iprimop{anno=#a{}, %Must have an #a{}
name=#c_atom{val=raise},
args=[Info,Value]}],
Ec = #iclause{anno=#a{anno=[compiler_generated]},
pats=[#c_tuple{es=Evs}],guard=[#c_atom{val=true}],
body=B},
Hs = [#icase{anno=#a{},args=[#c_tuple{es=Evs}],clauses=[],fc=Ec}],
{Evs,Hs,St1}.
%% expr_bin([ArgExpr], St) -> {[Arg],[PreExpr],St}.
%% Flatten the arguments of a bin. Do this straight left to right!
expr_bin(Es, St) ->
foldr(fun (E, {Ces,Esp,St0}) ->
{Ce,Ep,St1} = bitstr(E, St0),
{[Ce|Ces],Ep ++ Esp,St1}
end, {[],[],St}, Es).
bitstr({bin_element,_,E0,Size0,[Type,{unit,Unit}|Flags]}, St0) ->
{E1,Eps,St1} = safe(E0, St0),
{Size1,Eps2,St2} = safe(Size0, St1),
{#c_bitstr{val=E1,size=Size1,
unit=core_lib:make_literal(Unit),
type=core_lib:make_literal(Type),
flags=core_lib:make_literal(Flags)},
Eps ++ Eps2,St2}.
%% fun_tq(Id, [Clauses], Line, State) -> {Fun,[PreExp],State}.
fun_tq(Id, Cs0, L, St0) ->
{Cs1,St1} = clauses(Cs0, St0),
Arity = length((hd(Cs1))#iclause.pats),
{Args,St2} = new_vars(Arity, St1),
{Ps,St3} = new_vars(Arity, St2), %Need new variables here
Fc = fail_clause(Ps, #c_tuple{es=[#c_atom{val=function_clause}|Ps]}),
Fun = #ifun{anno=#a{anno=[L]},
id=[{id,Id}], %We KNOW!
vars=Args,clauses=Cs1,fc=Fc},
{Fun,[],St3}.
%% lc_tq(Line, Exp, [Qualifier], More, State) -> {LetRec,[PreExp],State}.
%% This TQ from Simon PJ pp 127-138.
%% This gets a bit messy as we must transform all directly here. We
%% recognise guard tests and try to fold them together and join to a
%% preceding generators, this should give us better and more compact
%% code.
%% More could be transformed before calling lc_tq.
lc_tq(Line, E, [{generate,Lg,P,G}|Qs0], More, St0) ->
{Gs,Qs1} = splitwith(fun is_guard_test/1, Qs0),
{Name,St1} = new_fun_name("lc", St0),
{Head,St2} = new_var(St1),
{Tname,St3} = new_var_name(St2),
LA = [Line],
LAnno = #a{anno=LA},
Tail = #c_var{anno=LA,name=Tname},
{Arg,St4} = new_var(St3),
NewMore = {call,Lg,{atom,Lg,Name},[{var,Lg,Tname}]},
{Guardc,St5} = lc_guard_tests(Gs, St4), %These are always flat!
{Lc,Lps,St6} = lc_tq(Line, E, Qs1, NewMore, St5),
{Mc,Mps,St7} = expr(More, St6),
{Nc,Nps,St8} = expr(NewMore, St7),
case catch pattern(P) of
{'EXIT',_}=Exit ->
St9 = St8,
Pc = nomatch,
exit(Exit); %Propagate error
nomatch ->
St9 = add_warning(Line, nomatch, St8),
Pc = nomatch;
Pc ->
St9 = St8
end,
{Gc,Gps,St10} = safe(G, St9), %Will be a function argument!
Fc = fail_clause([Arg], #c_tuple{anno=LA,
es=[#c_atom{val=function_clause},Arg]}),
Cs0 = [#iclause{anno=#a{anno=[compiler_generated|LA]},
pats=[#c_cons{anno=LA,hd=Head,tl=Tail}],
guard=[],
body=Nps ++ [Nc]},
#iclause{anno=LAnno,
pats=[#c_nil{anno=LA}],guard=[],
body=Mps ++ [Mc]}],
Cs = case Pc of
nomatch -> Cs0;
_ ->
[#iclause{anno=LAnno,
pats=[#c_cons{anno=LA,hd=Pc,tl=Tail}],
guard=Guardc,
body=Lps ++ [Lc]}|Cs0]
end,
Fun = #ifun{anno=LAnno,id=[],vars=[Arg],clauses=Cs,fc=Fc},
{#iletrec{anno=LAnno,defs=[{Name,Fun}],
body=Gps ++ [#iapply{anno=LAnno,
op=#c_fname{anno=LA,id=Name,arity=1},
args=[Gc]}]},
[],St10};
lc_tq(Line, E, [Fil0|Qs0], More, St0) ->
%% Special case sequences guard tests.
LA = [Line],
LAnno = #a{anno=LA},
case is_guard_test(Fil0) of
true ->
{Gs0,Qs1} = splitwith(fun is_guard_test/1, Qs0),
{Lc,Lps,St1} = lc_tq(Line, E, Qs1, More, St0),
{Mc,Mps,St2} = expr(More, St1),
{Gs,St3} = lc_guard_tests([Fil0|Gs0], St2), %These are always flat!
{#icase{anno=LAnno,
args=[],
clauses=[#iclause{anno=LAnno,pats=[],
guard=Gs,body=Lps ++ [Lc]}],
fc=#iclause{anno=LAnno,pats=[],guard=[],body=Mps ++ [Mc]}},
[],St3};
false ->
{Lc,Lps,St1} = lc_tq(Line, E, Qs0, More, St0),
{Mc,Mps,St2} = expr(More, St1),
{Fpat,St3} = new_var(St2),
Fc = fail_clause([Fpat], #c_tuple{es=[#c_atom{val=case_clause},Fpat]}),
%% Do a novars little optimisation here.
case Fil0 of
{op,_,'not',Fil1} ->
{Filc,Fps,St4} = novars(Fil1, St3),
{#icase{anno=LAnno,
args=[Filc],
clauses=[#iclause{anno=LAnno,
pats=[#c_atom{anno=LA,val=true}],
guard=[],
body=Mps ++ [Mc]},
#iclause{anno=LAnno,
pats=[#c_atom{anno=LA,val=false}],
guard=[],
body=Lps ++ [Lc]}],
fc=Fc},
Fps,St4};
_Other ->
{Filc,Fps,St4} = novars(Fil0, St3),
{#icase{anno=LAnno,
args=[Filc],
clauses=[#iclause{anno=LAnno,
pats=[#c_atom{anno=LA,val=true}],
guard=[],
body=Lps ++ [Lc]},
#iclause{anno=LAnno,
pats=[#c_atom{anno=LA,val=false}],
guard=[],
body=Mps ++ [Mc]}],
fc=Fc},
Fps,St4}
end
end;
lc_tq(Line, E, [], More, St) ->
expr({cons,Line,E,More}, St).
lc_guard_tests([], St) -> {[],St};
lc_guard_tests(Gs0, St) ->
Gs = guard_tests(Gs0),
gexpr_top(Gs, St).
%% is_guard_test(Expression) -> true | false.
%% Test if a general expression is a guard test. Use erl_lint here
%% as it now allows sys_pre_expand transformed source.
is_guard_test(E) -> erl_lint:is_guard_test(E).
%% novars(Expr, State) -> {Novars,[PreExpr],State}.
%% Generate a novars expression, basically a call or a safe. At this
%% level we do not need to do a deep check.
novars(E0, St0) ->
{E1,Eps,St1} = expr(E0, St0),
{Se,Sps,St2} = force_novars(E1, St1),
{Se,Eps ++ Sps,St2}.
force_novars(#iapply{}=App, St) -> {App,[],St};
force_novars(#icall{}=Call, St) -> {Call,[],St};
force_novars(#iprimop{}=Prim, St) -> {Prim,[],St};
force_novars(#ifun{}=Fun, St) -> {Fun,[],St}; %These are novars too
force_novars(#ibinary{}=Bin, St) -> {Bin,[],St};
force_novars(Ce, St) ->
force_safe(Ce, St).
%% safe(Expr, State) -> {Safe,[PreExpr],State}.
%% Generate an internal safe expression. These are simples without
%% binaries which can fail. At this level we do not need to do a
%% deep check. Must do special things with matches here.
safe(E0, St0) ->
{E1,Eps,St1} = expr(E0, St0),
{Se,Sps,St2} = force_safe(E1, St1),
{Se,Eps ++ Sps,St2}.
safe_list(Es, St) ->
foldr(fun (E, {Ces,Esp,St0}) ->
{Ce,Ep,St1} = safe(E, St0),
{[Ce|Ces],Ep ++ Esp,St1}
end, {[],[],St}, Es).
force_safe(#imatch{anno=Anno,pat=P,arg=E,fc=Fc}, St0) ->
{Le,Lps,St1} = force_safe(E, St0),
{Le,Lps ++ [#imatch{anno=Anno,pat=P,arg=Le,fc=Fc}],St1};
force_safe(Ce, St0) ->
case is_safe(Ce) of
true -> {Ce,[],St0};
false ->
{V,St1} = new_var(St0),
{V,[#iset{var=V,arg=Ce}],St1}
end.
is_safe(#c_cons{}) -> true;
is_safe(#c_tuple{}) -> true;
is_safe(#c_var{}) -> true;
is_safe(E) -> core_lib:is_atomic(E).
%%% %% variable(Expr, State) -> {Variable,[PreExpr],State}.
%%% %% force_variable(Expr, State) -> {Variable,[PreExpr],State}.
%%% %% Generate a variable.
%%% variable(E0, St0) ->
%%% {E1,Eps,St1} = expr(E0, St0),
%%% {V,Vps,St2} = force_variable(E1, St1),
%%% {V,Eps ++ Vps,St2}.
%%% force_variable(#c_var{}=Var, St) -> {Var,[],St};
%%% force_variable(Ce, St0) ->
%%% {V,St1} = new_var(St0),
%%% {V,[#iset{var=V,arg=Ce}],St1}.
%%% %% atomic(Expr, State) -> {Atomic,[PreExpr],State}.
%%% %% force_atomic(Expr, State) -> {Atomic,[PreExpr],State}.
%%% atomic(E0, St0) ->
%%% {E1,Eps,St1} = expr(E0, St0),
%%% {A,Aps,St2} = force_atomic(E1, St1),
%%% {A,Eps ++ Aps,St2}.
%%% force_atomic(Ce, St0) ->
%%% case core_lib:is_atomic(Ce) of
%%% true -> {Ce,[],St0};
%%% false ->
%%% {V,St1} = new_var(St0),
%%% {V,[#iset{var=V,arg=Ce}],St1}
%%% end.
%% fold_match(MatchExpr, Pat) -> {MatchPat,Expr}.
%% Fold nested matches into one match with aliased patterns.
fold_match({match,L,P0,E0}, P) ->
{P1,E1} = fold_match(E0, P),
{{match,L,P0,P1},E1};
fold_match(E, P) -> {P,E}.
%% pattern(Pattern) -> CorePat.
%% Transform a pattern by removing line numbers. We also normalise
%% aliases in patterns to standard form, {alias,Pat,[Var]}.
pattern({var,L,V}) -> #c_var{anno=[L],name=V};
pattern({char,L,C}) -> #c_char{anno=[L],val=C};
pattern({integer,L,I}) -> #c_int{anno=[L],val=I};
pattern({float,L,F}) -> #c_float{anno=[L],val=F};
pattern({atom,L,A}) -> #c_atom{anno=[L],val=A};
pattern({string,L,S}) -> #c_string{anno=[L],val=S};
pattern({nil,L}) -> #c_nil{anno=[L]};
pattern({cons,L,H,T}) ->
#c_cons{anno=[L],hd=pattern(H),tl=pattern(T)};
pattern({tuple,L,Ps}) ->
#c_tuple{anno=[L],es=pattern_list(Ps)};
pattern({bin,L,Ps}) ->
%% We don't create a #ibinary record here, since there is
%% no need to hold any used/new annoations in a pattern.
#c_binary{anno=[L],segments=pat_bin(Ps)};
pattern({match,_,P1,P2}) ->
pat_alias(pattern(P1), pattern(P2)).
%% bin_pattern_list([BinElement]) -> [BinSeg].
pat_bin(Ps) -> map(fun pat_segment/1, Ps).
pat_segment({bin_element,_,Term,Size,[Type,{unit,Unit}|Flags]}) ->
#c_bitstr{val=pattern(Term),size=pattern(Size),
unit=core_lib:make_literal(Unit),
type=core_lib:make_literal(Type),
flags=core_lib:make_literal(Flags)}.
%% pat_alias(CorePat, CorePat) -> AliasPat.
%% Normalise aliases. Trap bad aliases by throwing 'nomatch'.
pat_alias(#c_var{name=V1}, P2) -> #c_alias{var=#c_var{name=V1},pat=P2};
pat_alias(P1, #c_var{name=V2}) -> #c_alias{var=#c_var{name=V2},pat=P1};
pat_alias(#c_cons{}=Cons, #c_string{anno=A,val=[H|T]}=S) ->
pat_alias(Cons, #c_cons{anno=A,hd=#c_char{anno=A,val=H},
tl=S#c_string{val=T}});
pat_alias(#c_string{anno=A,val=[H|T]}=S, #c_cons{}=Cons) ->
pat_alias(#c_cons{anno=A,hd=#c_char{anno=A,val=H},
tl=S#c_string{val=T}}, Cons);
pat_alias(#c_nil{}=Nil, #c_string{val=[]}) ->
Nil;
pat_alias(#c_string{val=[]}, #c_nil{}=Nil) ->
Nil;
pat_alias(#c_cons{anno=A,hd=H1,tl=T1}, #c_cons{hd=H2,tl=T2}) ->
#c_cons{anno=A,hd=pat_alias(H1, H2),tl=pat_alias(T1, T2)};
pat_alias(#c_tuple{es=Es1}, #c_tuple{es=Es2}) ->
#c_tuple{es=pat_alias_list(Es1, Es2)};
pat_alias(#c_char{val=C}=Char, #c_int{val=C}) ->
Char;
pat_alias(#c_int{val=C}, #c_char{val=C}=Char) ->
Char;
pat_alias(#c_alias{var=V1,pat=P1},
#c_alias{var=V2,pat=P2}) ->
if V1 == V2 -> pat_alias(P1, P2);
true -> #c_alias{var=V1,pat=#c_alias{var=V2,pat=pat_alias(P1, P2)}}
end;
pat_alias(#c_alias{var=V1,pat=P1}, P2) ->
#c_alias{var=V1,pat=pat_alias(P1, P2)};
pat_alias(P1, #c_alias{var=V2,pat=P2}) ->
#c_alias{var=V2,pat=pat_alias(P1, P2)};
pat_alias(P, P) -> P;
pat_alias(_, _) -> throw(nomatch).
%% pat_alias_list([A1], [A2]) -> [A].
pat_alias_list([A1|A1s], [A2|A2s]) ->
[pat_alias(A1, A2)|pat_alias_list(A1s, A2s)];
pat_alias_list([], []) -> [];
pat_alias_list(_, _) -> throw(nomatch).
%% pattern_list([P]) -> [P].
pattern_list(Ps) -> map(fun pattern/1, Ps).
%% first([A]) -> [A].
%% last([A]) -> A.
first([_]) -> [];
first([H|T]) -> [H|first(T)].
last([L]) -> L;
last([_|T]) -> last(T).
%% make_vars([Name]) -> [{Var,Name}].
make_vars(Vs) -> [ #c_var{name=V} || V <- Vs ].
%% new_fun_name(Type, State) -> {FunName,State}.
new_fun_name(Type, #core{fcount=C}=St) ->
{list_to_atom(Type ++ "$^" ++ integer_to_list(C)),St#core{fcount=C+1}}.
%% new_var_name(State) -> {VarName,State}.
new_var_name(#core{vcount=C}=St) ->
{list_to_atom("cor" ++ integer_to_list(C)),St#core{vcount=C + 1}}.
%% new_var(State) -> {{var,Name},State}.
%% new_var(LineAnno, State) -> {{var,Name},State}.
new_var(St) ->
new_var([], St).
new_var(Anno, St0) ->
{New,St} = new_var_name(St0),
{#c_var{anno=Anno,name=New},St}.
%% new_vars(Count, State) -> {[Var],State}.
%% new_vars(Anno, Count, State) -> {[Var],State}.
%% Make Count new variables.
new_vars(N, St) -> new_vars_1(N, [], St, []).
new_vars(Anno, N, St) -> new_vars_1(N, Anno, St, []).
new_vars_1(N, Anno, St0, Vs) when N > 0 ->
{V,St1} = new_var(Anno, St0),
new_vars_1(N-1, Anno, St1, [V|Vs]);
new_vars_1(0, _, St, Vs) -> {Vs,St}.
fail_clause(Pats, A) ->
#iclause{anno=#a{anno=[compiler_generated]},
pats=Pats,guard=[],
body=[#iprimop{anno=#a{},name=#c_atom{val=match_fail},args=[A]}]}.
ubody(B, St) -> uexpr(B, [], St).
%% uclauses([Lclause], [KnownVar], State) -> {[Lclause],State}.
uclauses(Lcs, Ks, St0) ->
mapfoldl(fun (Lc, St) -> uclause(Lc, Ks, St) end, St0, Lcs).
%% uclause(Lclause, [KnownVar], State) -> {Lclause,State}.
uclause(Cl0, Ks, St0) ->
{Cl1,_Pvs,Used,New,St1} = uclause(Cl0, Ks, Ks, St0),
A0 = get_ianno(Cl1),
A = A0#a{us=Used,ns=New},
{Cl1#iclause{anno=A},St1}.
uclause(#iclause{anno=Anno,pats=Ps0,guard=G0,body=B0}, Pks, Ks0, St0) ->
{Ps1,Pg,Pvs,Pus,St1} = upattern_list(Ps0, Pks, St0),
Pu = union(Pus, intersection(Pvs, Ks0)),
Pn = subtract(Pvs, Pu),
Ks1 = union(Pn, Ks0),
{G1,St2} = uguard(Pg, G0, Ks1, St1),
Gu = used_in_any(G1),
Gn = new_in_any(G1),
Ks2 = union(Gn, Ks1),
{B1,St3} = uexprs(B0, Ks2, St2),
Used = intersection(union([Pu,Gu,used_in_any(B1)]), Ks0),
New = union([Pn,Gn,new_in_any(B1)]),
{#iclause{anno=Anno,pats=Ps1,guard=G1,body=B1},Pvs,Used,New,St3}.
%% uguard([Test], [Kexpr], [KnownVar], State) -> {[Kexpr],State}.
%% Build a guard expression list by folding in the equality tests.
uguard([], [], _, St) -> {[],St};
uguard(Pg, [], Ks, St) ->
%% No guard, so fold together equality tests.
uguard(first(Pg), [last(Pg)], Ks, St);
uguard(Pg, Gs0, Ks, St0) ->
%% Gs0 must contain at least one element here.
{Gs3,St5} = foldr(fun (T, {Gs1,St1}) ->
{L,St2} = new_var(St1),
{R,St3} = new_var(St2),
{[#iset{var=L,arg=T}] ++ first(Gs1) ++
[#iset{var=R,arg=last(Gs1)},
#icall{anno=#a{}, %Must have an #a{}
module=#c_atom{val=erlang},
name=#c_atom{val='and'},
args=[L,R]}],
St3}
end, {Gs0,St0}, Pg),
%%ok = io:fwrite("core ~w: ~p~n", [?LINE,Gs3]),
uexprs(Gs3, Ks, St5).
%% uexprs([Kexpr], [KnownVar], State) -> {[Kexpr],State}.
uexprs([#imatch{anno=A,pat=P0,arg=Arg,fc=Fc}|Les], Ks, St0) ->
%% Optimise for simple set of unbound variable.
case upattern(P0, Ks, St0) of
{#c_var{},[],_Pvs,_Pus,_} ->
%% Throw our work away and just set to iset.
uexprs([#iset{var=P0,arg=Arg}|Les], Ks, St0);
_Other ->
%% Throw our work away and set to icase.
if
Les == [] ->
%% Need to explicitly return match "value", make
%% safe for efficiency.
{La,Lps,St1} = force_safe(Arg, St0),
Mc = #iclause{anno=A,pats=[P0],guard=[],body=[La]},
uexprs(Lps ++ [#icase{anno=A,
args=[La],clauses=[Mc],fc=Fc}], Ks, St1);
true ->
Mc = #iclause{anno=A,pats=[P0],guard=[],body=Les},
uexprs([#icase{anno=A,args=[Arg],
clauses=[Mc],fc=Fc}], Ks, St0)
end
end;
uexprs([Le0|Les0], Ks, St0) ->
{Le1,St1} = uexpr(Le0, Ks, St0),
{Les1,St2} = uexprs(Les0, union((core_lib:get_anno(Le1))#a.ns, Ks), St1),
{[Le1|Les1],St2};
uexprs([], _, St) -> {[],St}.
uexpr(#iset{anno=A,var=V,arg=A0}, Ks, St0) ->
{A1,St1} = uexpr(A0, Ks, St0),
{#iset{anno=A#a{us=del_element(V#c_var.name, (core_lib:get_anno(A1))#a.us),
ns=add_element(V#c_var.name, (core_lib:get_anno(A1))#a.ns)},
var=V,arg=A1},St1};
%% imatch done in uexprs.
uexpr(#iletrec{anno=A,defs=Fs0,body=B0}, Ks, St0) ->
%%ok = io:fwrite("~w: ~p~n", [?LINE,{Fs0,B0}]),
{Fs1,St1} = mapfoldl(fun ({Name,F0}, St0) ->
{F1,St1} = uexpr(F0, Ks, St0),
{{Name,F1},St1}
end, St0, Fs0),
{B1,St2} = uexprs(B0, Ks, St1),
Used = used_in_any(map(fun ({_,F}) -> F end, Fs1) ++ B1),
{#iletrec{anno=A#a{us=Used,ns=[]},defs=Fs1,body=B1},St2};
uexpr(#icase{anno=A,args=As0,clauses=Cs0,fc=Fc0}, Ks, St0) ->
%% As0 will never generate new variables.
{As1,St1} = uexpr_list(As0, Ks, St0),
{Cs1,St2} = uclauses(Cs0, Ks, St1),
{Fc1,St3} = uclause(Fc0, Ks, St2),
Used = union(used_in_any(As1), used_in_any(Cs1)),
New = new_in_all(Cs1),
{#icase{anno=A#a{us=Used,ns=New},args=As1,clauses=Cs1,fc=Fc1},St3};
uexpr(#ifun{anno=A,id=Id,vars=As,clauses=Cs0,fc=Fc0}, Ks0, St0) ->
Avs = lit_list_vars(As),
Ks1 = union(Avs, Ks0),
{Cs1,St1} = ufun_clauses(Cs0, Ks1, St0),
{Fc1,St2} = ufun_clause(Fc0, Ks1, St1),
Used = subtract(intersection(used_in_any(Cs1), Ks0), Avs),
{#ifun{anno=A#a{us=Used,ns=[]},id=Id,vars=As,clauses=Cs1,fc=Fc1},St2};
uexpr(#iapply{anno=A,op=Op,args=As}, _, St) ->
Used = union(lit_vars(Op), lit_list_vars(As)),
{#iapply{anno=A#a{us=Used},op=Op,args=As},St};
uexpr(#iprimop{anno=A,name=Name,args=As}, _, St) ->
Used = lit_list_vars(As),
{#iprimop{anno=A#a{us=Used},name=Name,args=As},St};
uexpr(#icall{anno=A,module=Mod,name=Name,args=As}, _, St) ->
Used = union([lit_vars(Mod),lit_vars(Name),lit_list_vars(As)]),
{#icall{anno=A#a{us=Used},module=Mod,name=Name,args=As},St};
uexpr(#itry{anno=A,args=As0,vars=Vs,body=Bs0,evars=Evs,handler=Hs0}, Ks, St0) ->
%% Note that we export only from body and exception.
{As1,St1} = uexprs(As0, Ks, St0),
{Bs1,St2} = uexprs(Bs0, Ks, St1),
{Hs1,St3} = uexprs(Hs0, Ks, St2),
Used = intersection(used_in_any(Bs1++Hs1++As1), Ks),
New = new_in_all(Bs1++Hs1),
{#itry{anno=A#a{us=Used,ns=New},
args=As1,vars=Vs,body=Bs1,evars=Evs,handler=Hs1},St3};
uexpr(#icatch{anno=A,body=Es0}, Ks, St0) ->
{Es1,St1} = uexprs(Es0, Ks, St0),
{#icatch{anno=A#a{us=used_in_any(Es1)},body=Es1},St1};
uexpr(#ireceive1{anno=A,clauses=Cs0}, Ks, St0) ->
{Cs1,St1} = uclauses(Cs0, Ks, St0),
{#ireceive1{anno=A#a{us=used_in_any(Cs1),ns=new_in_all(Cs1)},
clauses=Cs1},St1};
uexpr(#ireceive2{anno=A,clauses=Cs0,timeout=Te0,action=Tes0}, Ks, St0) ->
%% Te0 will never generate new variables.
{Te1,St1} = uexpr(Te0, Ks, St0),
{Cs1,St2} = uclauses(Cs0, Ks, St1),
{Tes1,St3} = uexprs(Tes0, Ks, St2),
Used = union([used_in_any(Cs1),used_in_any(Tes1),
(core_lib:get_anno(Te1))#a.us]),
New = case Cs1 of
[] -> new_in_any(Tes1);
_ -> intersection(new_in_all(Cs1), new_in_any(Tes1))
end,
{#ireceive2{anno=A#a{us=Used,ns=New},
clauses=Cs1,timeout=Te1,action=Tes1},St3};
uexpr(#iprotect{anno=A,body=Es0}, Ks, St0) ->
{Es1,St1} = uexprs(Es0, Ks, St0),
Used = used_in_any(Es1),
{#iprotect{anno=A#a{us=Used},body=Es1},St1}; %No new variables escape!
uexpr(#ibinary{anno=A,segments=Ss}, _, St) ->
Used = bitstr_vars(Ss),
{#ibinary{anno=A#a{us=Used},segments=Ss},St};
uexpr(Lit, _, St) ->
true = core_lib:is_simple(Lit), %Sanity check!
Vs = lit_vars(Lit),
Anno = core_lib:get_anno(Lit),
{core_lib:set_anno(Lit, #a{us=Vs,anno=Anno}),St}.
uexpr_list(Les0, Ks, St0) ->
mapfoldl(fun (Le, St) -> uexpr(Le, Ks, St) end, St0, Les0).
%% ufun_clauses([Lclause], [KnownVar], State) -> {[Lclause],State}.
ufun_clauses(Lcs, Ks, St0) ->
mapfoldl(fun (Lc, St) -> ufun_clause(Lc, Ks, St) end, St0, Lcs).
%% ufun_clause(Lclause, [KnownVar], State) -> {Lclause,State}.
ufun_clause(Cl0, Ks, St0) ->
{Cl1,Pvs,Used,_,St1} = uclause(Cl0, [], Ks, St0),
A0 = get_ianno(Cl1),
A = A0#a{us=subtract(intersection(Used, Ks), Pvs),ns=[]},
{Cl1#iclause{anno=A},St1}.
%% upattern(Pat, [KnownVar], State) ->
%% {Pat,[GuardTest],[NewVar],[UsedVar],State}.
upattern(#c_var{name='_'}, _, St0) ->
{New,St1} = new_var_name(St0),
{#c_var{name=New},[],[New],[],St1};
upattern(#c_var{name=V}=Var, Ks, St0) ->
case is_element(V, Ks) of
true ->
{N,St1} = new_var_name(St0),
New = #c_var{name=N},
Test = #icall{anno=#a{us=add_element(N, [V])},
module=#c_atom{val=erlang},
name=#c_atom{val='=:='},
args=[New,Var]},
%% Test doesn't need protecting.
{New,[Test],[N],[],St1};
false -> {Var,[],[V],[],St0}
end;
upattern(#c_cons{hd=H0,tl=T0}=Cons, Ks, St0) ->
{H1,Hg,Hv,Hu,St1} = upattern(H0, Ks, St0),
{T1,Tg,Tv,Tu,St2} = upattern(T0, union(Hv, Ks), St1),
{Cons#c_cons{hd=H1,tl=T1},Hg ++ Tg,union(Hv, Tv),union(Hu, Tu),St2};
upattern(#c_tuple{es=Es0}=Tuple, Ks, St0) ->
{Es1,Esg,Esv,Eus,St1} = upattern_list(Es0, Ks, St0),
{Tuple#c_tuple{es=Es1},Esg,Esv,Eus,St1};
upattern(#c_binary{segments=Es0}=Bin, Ks, St0) ->
{Es1,Esg,Esv,Eus,St1} = upat_bin(Es0, Ks, St0),
{Bin#c_binary{segments=Es1},Esg,Esv,Eus,St1};
upattern(#c_alias{var=V0,pat=P0}=Alias, Ks, St0) ->
{V1,Vg,Vv,Vu,St1} = upattern(V0, Ks, St0),
{P1,Pg,Pv,Pu,St2} = upattern(P0, union(Vv, Ks), St1),
{Alias#c_alias{var=V1,pat=P1},Vg ++ Pg,union(Vv, Pv),union(Vu, Pu),St2};
upattern(Other, _, St) -> {Other,[],[],[],St}. %Constants
%% upattern_list([Pat], [KnownVar], State) ->
%% {[Pat],[GuardTest],[NewVar],[UsedVar],State}.
upattern_list([P0|Ps0], Ks, St0) ->
{P1,Pg,Pv,Pu,St1} = upattern(P0, Ks, St0),
{Ps1,Psg,Psv,Psu,St2} = upattern_list(Ps0, union(Pv, Ks), St1),
{[P1|Ps1],Pg ++ Psg,union(Pv, Psv),union(Pu, Psu),St2};
upattern_list([], _, St) -> {[],[],[],[],St}.
%% upat_bin([Pat], [KnownVar], State) ->
%% {[Pat],[GuardTest],[NewVar],[UsedVar],State}.
upat_bin(Es0, Ks, St0) ->
upat_bin(Es0, Ks, [], St0).
%% upat_bin([Pat], [KnownVar], [LocalVar], State) ->
%% {[Pat],[GuardTest],[NewVar],[UsedVar],State}.
upat_bin([P0|Ps0], Ks, Bs, St0) ->
{P1,Pg,Pv,Pu,Bs1,St1} = upat_element(P0, Ks, Bs, St0),
{Ps1,Psg,Psv,Psu,St2} = upat_bin(Ps0, union(Pv, Ks), Bs1, St1),
{[P1|Ps1],Pg ++ Psg,union(Pv, Psv),union(Pu, Psu),St2};
upat_bin([], _, _, St) -> {[],[],[],[],St}.
%% upat_element(Segment, [KnownVar], [LocalVar], State) ->
%% {Segment,[GuardTest],[NewVar],[UsedVar],[LocalVar],State}
upat_element(#c_bitstr{val=H0,size=Sz}=Seg, Ks, Bs, St0) ->
{H1,Hg,Hv,[],St1} = upattern(H0, Ks, St0),
Bs1 = case H0 of
#c_var{name=Hname} ->
case H1 of
#c_var{name=Hname} ->
Bs;
#c_var{name=Other} ->
[{Hname, Other}|Bs]
end;
_ ->
Bs
end,
{Sz1, Us} = case Sz of
#c_var{name=Vname} ->
rename_bitstr_size(Vname, Bs);
_Other -> {Sz, []}
end,
{Seg#c_bitstr{val=H1, size=Sz1},Hg,Hv,Us,Bs1,St1}.
rename_bitstr_size(V, [{V, N}|_]) ->
New = #c_var{name=N},
{New, [N]};
rename_bitstr_size(V, [_|Rest]) ->
rename_bitstr_size(V, Rest);
rename_bitstr_size(V, []) ->
Old = #c_var{name=V},
{Old, [V]}.
used_in_any(Les) ->
foldl(fun (Le, Ns) -> union((core_lib:get_anno(Le))#a.us, Ns) end,
[], Les).
new_in_any(Les) ->
foldl(fun (Le, Ns) -> union((core_lib:get_anno(Le))#a.ns, Ns) end,
[], Les).
new_in_all([Le|Les]) ->
foldl(fun (L, Ns) -> intersection((core_lib:get_anno(L))#a.ns, Ns) end,
(core_lib:get_anno(Le))#a.ns, Les);
new_in_all([]) -> [].
%% The AfterVars are the variables which are used afterwards. We need
%% this to work out which variables are actually exported and used
%% from case/receive. In subblocks/clauses the AfterVars of the block
%% are just the exported variables.
cbody(B0, St0) ->
{B1,_,_,St1} = cexpr(B0, [], St0),
{B1,St1}.
%% cclause(Lclause, [AfterVar], State) -> {Cclause,State}.
%% The AfterVars are the exported variables.
cclause(#iclause{anno=#a{anno=Anno},pats=Ps,guard=G0,body=B0}, Exp, St0) ->
{B1,_Us1,St1} = cexprs(B0, Exp, St0),
{G1,St2} = cguard(G0, St1),
{#c_clause{anno=Anno,pats=Ps,guard=G1,body=B1},St2}.
cclauses(Lcs, Es, St0) ->
mapfoldl(fun (Lc, St) -> cclause(Lc, Es, St) end, St0, Lcs).
cguard([], St) -> {#c_atom{val=true},St};
cguard(Gs, St0) ->
{G,_,St1} = cexprs(Gs, [], St0),
{G,St1}.
%% cexprs([Lexpr], [AfterVar], State) -> {Cexpr,[AfterVar],State}.
%% Must be sneaky here at the last expr when combining exports for the
%% whole sequence and exports for that expr.
cexprs([#iset{var=#c_var{name=Name}=Var}=Iset], As, St) ->
%% Make return value explicit, and make Var true top level.
cexprs([Iset,Var#c_var{anno=#a{us=[Name]}}], As, St);
cexprs([Le], As, St0) ->
{Ce,Es,Us,St1} = cexpr(Le, As, St0),
Exp = make_vars(As), %The export variables
if
Es == [] -> {core_lib:make_values([Ce|Exp]),union(Us, As),St1};
true ->
{R,St2} = new_var(St1),
{#c_let{anno=get_lineno_anno(Ce),
vars=[R|make_vars(Es)],arg=Ce,
body=core_lib:make_values([R|Exp])},
union(Us, As),St2}
end;
cexprs([#iset{anno=#a{anno=A},var=V,arg=A0}|Les], As0, St0) ->
{Ces,As1,St1} = cexprs(Les, As0, St0),
{A1,Es,Us,St2} = cexpr(A0, As1, St1),
{#c_let{anno=A,vars=[V|make_vars(Es)],arg=A1,body=Ces},
union(Us, As1),St2};
cexprs([Le|Les], As0, St0) ->
{Ces,As1,St1} = cexprs(Les, As0, St0),
{Ce,Es,Us,St2} = cexpr(Le, As1, St1),
if
Es == [] ->
{#c_seq{arg=Ce,body=Ces},union(Us, As1),St2};
true ->
{R,St3} = new_var(St2),
{#c_let{vars=[R|make_vars(Es)],arg=Ce,body=Ces},
union(Us, As1),St3}
end.
%% cexpr(Lexpr, [AfterVar], State) -> {Cexpr,[ExpVar],[UsedVar],State}.
cexpr(#iletrec{anno=A,defs=Fs0,body=B0}, As, St0) ->
{Fs1,{_,St1}} = mapfoldl(fun ({Name,F0}, {Used,St0}) ->
{F1,[],Us,St1} = cexpr(F0, [], St0),
{#c_def{name=#c_fname{id=Name,arity=1},
val=F1},
{union(Us, Used),St1}}
end, {[],St0}, Fs0),
Exp = intersection(A#a.ns, As),
{B1,_Us,St2} = cexprs(B0, Exp, St1),
{#c_letrec{anno=A#a.anno,defs=Fs1,body=B1},Exp,A#a.us,St2};
cexpr(#icase{anno=A,args=Largs,clauses=Lcs,fc=Lfc}, As, St0) ->
Exp = intersection(A#a.ns, As), %Exports
{Cargs,St1} = foldr(fun (La, {Cas,Sta}) ->
{Ca,[],_Us1,Stb} = cexpr(La, As, Sta),
{[Ca|Cas],Stb}
end, {[],St0}, Largs),
{Ccs,St2} = cclauses(Lcs, Exp, St1),
{Cfc,St3} = cclause(Lfc, [], St2), %Never exports
{#c_case{anno=A#a.anno,
arg=core_lib:make_values(Cargs),clauses=Ccs ++ [Cfc]},
Exp,A#a.us,St3};
cexpr(#ireceive1{anno=A,clauses=Lcs}, As, St0) ->
Exp = intersection(A#a.ns, As), %Exports
{Ccs,St1} = cclauses(Lcs, Exp, St0),
{#c_receive{anno=A#a.anno,
clauses=Ccs,
timeout=#c_atom{val=infinity},action=#c_atom{val=true}},
Exp,A#a.us,St1};
cexpr(#ireceive2{anno=A,clauses=Lcs,timeout=Lto,action=Les}, As, St0) ->
Exp = intersection(A#a.ns, As), %Exports
{Cto,[],_Us1,St1} = cexpr(Lto, As, St0),
{Ccs,St2} = cclauses(Lcs, Exp, St1),
{Ces,_Us2,St3} = cexprs(Les, Exp, St2),
{#c_receive{anno=A#a.anno,
clauses=Ccs,timeout=Cto,action=Ces},
Exp,A#a.us,St3};
cexpr(#itry{anno=A,args=La,vars=Vs,body=Lb,evars=Evs,handler=Lh}, As, St0) ->
Exp = intersection(A#a.ns, As), %Exports
{Ca,_Us1,St1} = cexprs(La, [], St0),
{Cb,_Us2,St2} = cexprs(Lb, Exp, St1),
{Ch,_Us3,St3} = cexprs(Lh, Exp, St2),
{#c_try{anno=A#a.anno,arg=Ca,vars=Vs,body=Cb,evars=Evs,handler=Ch},
Exp,A#a.us,St3};
cexpr(#icatch{anno=A,body=Les}, _As, St0) ->
{Ces,_Us1,St1} = cexprs(Les, [], St0), %Never export!
{#c_catch{body=Ces},[],A#a.us,St1};
cexpr(#ifun{anno=A,id=Id,vars=Args,clauses=Lcs,fc=Lfc}, _As, St0) ->
{Ccs,St1} = cclauses(Lcs, [], St0), %NEVER export!
{Cfc,St2} = cclause(Lfc, [], St1),
Anno = A#a.anno,
{#c_fun{anno=Id++Anno,vars=Args,
body=#c_case{anno=Anno,
arg=core_lib:set_anno(core_lib:make_values(Args), Anno),
clauses=Ccs ++ [Cfc]}},
[],A#a.us,St2};
cexpr(#iapply{anno=A,op=Op,args=Args}, _As, St) ->
{#c_apply{anno=A#a.anno,op=Op,args=Args},[],A#a.us,St};
cexpr(#icall{anno=A,module=Mod,name=Name,args=Args}, _As, St) ->
{#c_call{anno=A#a.anno,module=Mod,name=Name,args=Args},[],A#a.us,St};
cexpr(#iprimop{anno=A,name=Name,args=Args}, _As, St) ->
{#c_primop{anno=A#a.anno,name=Name,args=Args},[],A#a.us,St};
cexpr(#iprotect{anno=A,body=Es}, _As, St0) ->
{Ce,_,St1} = cexprs(Es, [], St0),
V = #c_var{name='Try'}, %The names are arbitrary
Vs = [#c_var{name='T'},#c_var{name='R'}],
{#c_try{anno=A#a.anno,arg=Ce,vars=[V],body=V,
evars=Vs,handler=#c_atom{val=false}},
[],A#a.us,St1};
cexpr(#ibinary{anno=#a{anno=Anno,us=Us},segments=Segs}, _As, St) ->
{#c_binary{anno=Anno,segments=Segs},[],Us,St};
cexpr(Lit, _As, St) ->
true = core_lib:is_simple(Lit), %Sanity check!
Anno = core_lib:get_anno(Lit),
Vs = Anno#a.us,
%%Vs = lit_vars(Lit),
{core_lib:set_anno(Lit, Anno#a.anno),[],Vs,St}.
%% lit_vars(Literal) -> [Var].
lit_vars(Lit) -> lit_vars(Lit, []).
lit_vars(#c_cons{hd=H,tl=T}, Vs) -> lit_vars(H, lit_vars(T, Vs));
lit_vars(#c_tuple{es=Es}, Vs) -> lit_list_vars(Es, Vs);
lit_vars(#c_var{name=V}, Vs) -> add_element(V, Vs);
lit_vars(_, Vs) -> Vs. %These are atomic
% lit_bin_vars(Segs, Vs) ->
% foldl(fun (#c_bitstr{val=V,size=S}, Vs0) ->
% lit_vars(V, lit_vars(S, Vs0))
% end, Vs, Segs).
lit_list_vars(Ls) -> lit_list_vars(Ls, []).
lit_list_vars(Ls, Vs) ->
foldl(fun (L, Vs0) -> lit_vars(L, Vs0) end, Vs, Ls).
bitstr_vars(Segs) ->
bitstr_vars(Segs, []).
bitstr_vars(Segs, Vs) ->
foldl(fun (#c_bitstr{val=V,size=S}, Vs0) ->
lit_vars(V, lit_vars(S, Vs0))
end, Vs, Segs).
get_ianno(Ce) ->
case core_lib:get_anno(Ce) of
#a{}=A -> A;
A when is_list(A) -> #a{anno=A}
end.
get_lineno_anno(Ce) ->
case core_lib:get_anno(Ce) of
#a{anno=A} -> A;
A when is_list(A) -> A
end.
%%%
%%% Handling of warnings.
%%%
format_error(nomatch) -> "pattern cannot possibly match".
add_warning(Line, Term, #core{ws=Ws}=St) when Line >= 0 ->
St#core{ws=[{Line,?MODULE,Term}|Ws]};
add_warning(_, _, St) -> St.