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diff --git a/lib/dialyzer/test/options1_tests_SUITE_data/src/compiler/v3_kernel.erl b/lib/dialyzer/test/options1_tests_SUITE_data/src/compiler/v3_kernel.erl
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+%% ``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_kernel.erl,v 1.3 2010/03/04 13:54:20 maria Exp $
+%%
+%% Purpose : Transform Core Erlang to Kernel Erlang
+
+%% Kernel erlang is like Core Erlang with a few significant
+%% differences:
+%%
+%% 1. It is flat! There are no nested calls or sub-blocks.
+%%
+%% 2. All variables are unique in a function. There is no scoping, or
+%% rather the scope is the whole function.
+%%
+%% 3. Pattern matching (in cases and receives) has been compiled.
+%%
+%% 4. The annotations contain variable usages. Seeing we have to work
+%% this out anyway for funs we might as well pass it on for free to
+%% later passes.
+%%
+%% 5. All remote-calls are to statically named m:f/a. Meta-calls are
+%% passed via erlang:apply/3.
+%%
+%% The translation is done in two passes:
+%%
+%% 1. Basic translation, translate variable/function names, flatten
+%% completely, pattern matching compilation.
+%%
+%% 2. Fun-lifting (lambda-lifting), variable usage annotation and
+%% last-call handling.
+%%
+%% All new Kexprs are created in the first pass, they are just
+%% annotated in the second.
+%%
+%% Functions and BIFs
+%%
+%% Functions are "call"ed or "enter"ed if it is a last call, their
+%% return values may be ignored. BIFs are things which are known to
+%% be internal by the compiler and can only be called, their return
+%% values cannot be ignored.
+%%
+%% Letrec's are handled rather naively. All the functions in one
+%% letrec are handled as one block to find the free variables. While
+%% this is not optimal it reflects how letrec's often are used. We
+%% don't have to worry about variable shadowing and nested letrec's as
+%% this is handled in the variable/function name translation. There
+%% is a little bit of trickery to ensure letrec transformations fit
+%% into the scheme of things.
+%%
+%% To ensure unique variable names we use a variable substitution
+%% table and keep the set of all defined variables. The nested
+%% scoping of Core means that we must also nest the substitution
+%% tables, but the defined set must be passed through to match the
+%% flat structure of Kernel and to make sure variables with the same
+%% name from different scopes get different substitutions.
+%%
+%% We also use these substitutions to handle the variable renaming
+%% necessary in pattern matching compilation.
+%%
+%% The pattern matching compilation assumes that the values of
+%% different types don't overlap. This means that as there is no
+%% character type yet in the machine all characters must be converted
+%% to integers!
+
+-module(v3_kernel).
+
+-export([module/2,format_error/1]).
+
+-import(lists, [map/2,foldl/3,foldr/3,mapfoldl/3,splitwith/2,
+ member/2,reverse/1,reverse/2]).
+-import(ordsets, [add_element/2,del_element/2,union/2,union/1,subtract/2]).
+
+-include("core_parse.hrl").
+-include("v3_kernel.hrl").
+
+%% These are not defined in v3_kernel.hrl.
+get_kanno(Kthing) -> element(2, Kthing).
+set_kanno(Kthing, Anno) -> setelement(2, Kthing, Anno).
+
+%% Internal kernel expressions and help functions.
+%% N.B. the annotation field is ALWAYS the first field!
+
+-record(ivalues, {anno=[],args}).
+-record(ifun, {anno=[],vars,body}).
+-record(iset, {anno=[],vars,arg,body}).
+-record(iletrec, {anno=[],defs}).
+-record(ialias, {anno=[],vars,pat}).
+-record(iclause, {anno=[],sub,pats,guard,body}).
+-record(ireceive_accept, {anno=[],arg}).
+-record(ireceive_next, {anno=[],arg}).
+
+%% State record for kernel translator.
+-record(kern, {func, %Current function
+ vcount=0, %Variable counter
+ fcount=0, %Fun counter
+ ds=[], %Defined variables
+ funs=[], %Fun functions
+ free=[], %Free variables
+ ws=[], %Warnings.
+ extinstr=false}). %Generate extended instructions
+
+module(#c_module{anno=A,name=M,exports=Es,attrs=As,defs=Fs}, Options) ->
+ ExtInstr = not member(no_new_apply, Options),
+ {Kfs,St} = mapfoldl(fun function/2, #kern{extinstr=ExtInstr}, Fs),
+ Kes = map(fun (#c_fname{id=N,arity=Ar}) -> {N,Ar} end, Es),
+ Kas = map(fun (#c_def{name=#c_atom{val=N},val=V}) ->
+ {N,core_lib:literal_value(V)} end, As),
+ {ok,#k_mdef{anno=A,name=M#c_atom.val,exports=Kes,attributes=Kas,
+ body=Kfs ++ St#kern.funs},St#kern.ws}.
+
+function(#c_def{anno=Af,name=#c_fname{id=F,arity=Arity},val=Body}, St0) ->
+ %%ok = io:fwrite("kern: ~p~n", [{F,Arity}]),
+ St1 = St0#kern{func={F,Arity},vcount=0,fcount=0,ds=sets:new()},
+ {#ifun{anno=Ab,vars=Kvs,body=B0},[],St2} = expr(Body, new_sub(), St1),
+ {B1,_,St3} = ubody(B0, return, St2),
+ %%B1 = B0, St3 = St2, %Null second pass
+ {#k_fdef{anno=#k{us=[],ns=[],a=Af ++ Ab},
+ func=F,arity=Arity,vars=Kvs,body=B1},St3}.
+
+%% body(Cexpr, Sub, State) -> {Kexpr,[PreKepxr],State}.
+%% Do the main sequence of a body. A body ends in an atomic value or
+%% values. Must check if vector first so do expr.
+
+body(#c_values{anno=A,es=Ces}, Sub, St0) ->
+ %% Do this here even if only in bodies.
+ {Kes,Pe,St1} = atomic_list(Ces, Sub, St0),
+ %%{Kes,Pe,St1} = expr_list(Ces, Sub, St0),
+ {#ivalues{anno=A,args=Kes},Pe,St1};
+body(#ireceive_next{anno=A}, _, St) ->
+ {#k_receive_next{anno=A},[],St};
+body(Ce, Sub, St0) ->
+ expr(Ce, Sub, St0).
+
+%% guard(Cexpr, Sub, State) -> {Kexpr,State}.
+%% We handle guards almost as bodies. The only special thing we
+%% must do is to make the final Kexpr a #k_test{}.
+%% Also, we wrap the entire guard in a try/catch which is
+%% not strictly needed, but makes sure that every 'bif' instruction
+%% will get a proper failure label.
+
+guard(G0, Sub, St0) ->
+ {G1,St1} = wrap_guard(G0, St0),
+ {Ge0,Pre,St2} = expr(G1, Sub, St1),
+ {Ge,St} = gexpr_test(Ge0, St2),
+ {pre_seq(Pre, Ge),St}.
+
+%% Wrap the entire guard in a try/catch if needed.
+
+wrap_guard(#c_try{}=Try, St) -> {Try,St};
+wrap_guard(Core, St0) ->
+ {VarName,St} = new_var_name(St0),
+ Var = #c_var{name=VarName},
+ Try = #c_try{arg=Core,vars=[Var],body=Var,evars=[],handler=#c_atom{val=false}},
+ {Try,St}.
+
+%% gexpr_test(Kexpr, State) -> {Kexpr,State}.
+%% Builds the final boolean test from the last Kexpr in a guard test.
+%% Must enter try blocks and isets and find the last Kexpr in them.
+%% This must end in a recognised BEAM test!
+
+gexpr_test(#k_bif{anno=A,op=#k_remote{mod=#k_atom{val=erlang},
+ name=#k_atom{val=is_boolean},arity=1}=Op,
+ args=Kargs}, St) ->
+ %% XXX Remove this clause in R11. For bootstrap purposes, we must
+ %% recognize erlang:is_boolean/1 here.
+ {#k_test{anno=A,op=Op,args=Kargs},St};
+gexpr_test(#k_bif{anno=A,op=#k_remote{mod=#k_atom{val=erlang},
+ name=#k_atom{val=internal_is_record},arity=3}=Op,
+ args=Kargs}, St) ->
+ {#k_test{anno=A,op=Op,args=Kargs},St};
+gexpr_test(#k_bif{anno=A,op=#k_remote{mod=#k_atom{val=erlang},
+ name=#k_atom{val=F},arity=Ar}=Op,
+ args=Kargs}=Ke, St) ->
+ %% Either convert to test if ok, or add test.
+ %% At this stage, erlang:float/1 is not a type test. (It should
+ %% have been converted to erlang:is_float/1.)
+ case erl_internal:new_type_test(F, Ar) orelse
+ erl_internal:comp_op(F, Ar) of
+ true -> {#k_test{anno=A,op=Op,args=Kargs},St};
+ false -> gexpr_test_add(Ke, St) %Add equality test
+ end;
+gexpr_test(#k_try{arg=B0,vars=[#k_var{name=X}],body=#k_var{name=X},
+ handler=#k_atom{val=false}}=Try, St0) ->
+ {B,St} = gexpr_test(B0, St0),
+ %%ok = io:fwrite("~w: ~p~n", [?LINE,{B0,B}]),
+ {Try#k_try{arg=B},St};
+gexpr_test(#iset{body=B0}=Iset, St0) ->
+ {B1,St1} = gexpr_test(B0, St0),
+ {Iset#iset{body=B1},St1};
+gexpr_test(Ke, St) -> gexpr_test_add(Ke, St). %Add equality test
+
+gexpr_test_add(Ke, St0) ->
+ Test = #k_remote{mod=#k_atom{val='erlang'},
+ name=#k_atom{val='=:='},
+ arity=2},
+ {Ae,Ap,St1} = force_atomic(Ke, St0),
+ {pre_seq(Ap, #k_test{anno=get_kanno(Ke),
+ op=Test,args=[Ae,#k_atom{val='true'}]}),St1}.
+
+%% expr(Cexpr, Sub, State) -> {Kexpr,[PreKexpr],State}.
+%% Convert a Core expression, flattening it at the same time.
+
+expr(#c_var{anno=A,name=V}, Sub, St) ->
+ {#k_var{anno=A,name=get_vsub(V, Sub)},[],St};
+expr(#c_char{anno=A,val=C}, _Sub, St) ->
+ {#k_int{anno=A,val=C},[],St}; %Convert to integers!
+expr(#c_int{anno=A,val=I}, _Sub, St) ->
+ {#k_int{anno=A,val=I},[],St};
+expr(#c_float{anno=A,val=F}, _Sub, St) ->
+ {#k_float{anno=A,val=F},[],St};
+expr(#c_atom{anno=A,val=At}, _Sub, St) ->
+ {#k_atom{anno=A,val=At},[],St};
+expr(#c_string{anno=A,val=S}, _Sub, St) ->
+ {#k_string{anno=A,val=S},[],St};
+expr(#c_nil{anno=A}, _Sub, St) ->
+ {#k_nil{anno=A},[],St};
+expr(#c_cons{anno=A,hd=Ch,tl=Ct}, Sub, St0) ->
+ %% Do cons in two steps, first the expressions left to right, then
+ %% any remaining literals right to left.
+ {Kh0,Hp0,St1} = expr(Ch, Sub, St0),
+ {Kt0,Tp0,St2} = expr(Ct, Sub, St1),
+ {Kt1,Tp1,St3} = force_atomic(Kt0, St2),
+ {Kh1,Hp1,St4} = force_atomic(Kh0, St3),
+ {#k_cons{anno=A,hd=Kh1,tl=Kt1},Hp0 ++ Tp0 ++ Tp1 ++ Hp1,St4};
+expr(#c_tuple{anno=A,es=Ces}, Sub, St0) ->
+ {Kes,Ep,St1} = atomic_list(Ces, Sub, St0),
+ {#k_tuple{anno=A,es=Kes},Ep,St1};
+expr(#c_binary{anno=A,segments=Cv}, Sub, St0) ->
+ case catch atomic_bin(Cv, Sub, St0, 0) of
+ {'EXIT',R} -> exit(R);
+ bad_element_size ->
+ Erl = #c_atom{val=erlang},
+ Name = #c_atom{val=error},
+ Args = [#c_atom{val=badarg}],
+ Fault = #c_call{module=Erl,name=Name,args=Args},
+ expr(Fault, Sub, St0);
+ {Kv,Ep,St1} ->
+ {#k_binary{anno=A,segs=Kv},Ep,St1}
+ end;
+expr(#c_fname{anno=A,arity=Ar}=Fname, Sub, St) ->
+ %% A local in an expression.
+ %% For now, these are wrapped into a fun by reverse
+ %% etha-conversion, but really, there should be exactly one
+ %% such "lambda function" for each escaping local name,
+ %% instead of one for each occurrence as done now.
+ Vs = [#c_var{name=list_to_atom("V" ++ integer_to_list(V))} ||
+ V <- integers(1, Ar)],
+ Fun = #c_fun{anno=A,vars=Vs,body=#c_apply{op=Fname,args=Vs}},
+ expr(Fun, Sub, St);
+expr(#c_fun{anno=A,vars=Cvs,body=Cb}, Sub0, St0) ->
+ {Kvs,Sub1,St1} = pattern_list(Cvs, Sub0, St0),
+ %%ok = io:fwrite("~w: ~p~n", [?LINE,{{Cvs,Sub0,St0},{Kvs,Sub1,St1}}]),
+ {Kb,Pb,St2} = body(Cb, Sub1, St1),
+ {#ifun{anno=A,vars=Kvs,body=pre_seq(Pb, Kb)},[],St2};
+expr(#c_seq{arg=Ca,body=Cb}, Sub, St0) ->
+ {Ka,Pa,St1} = body(Ca, Sub, St0),
+ case is_exit_expr(Ka) of
+ true -> {Ka,Pa,St1};
+ false ->
+ {Kb,Pb,St2} = body(Cb, Sub, St1),
+ {Kb,Pa ++ [Ka] ++ Pb,St2}
+ end;
+expr(#c_let{anno=A,vars=Cvs,arg=Ca,body=Cb}, Sub0, St0) ->
+ %%ok = io:fwrite("~w: ~p~n", [?LINE,{Cvs,Sub0,St0}]),
+ {Ka,Pa,St1} = body(Ca, Sub0, St0),
+ case is_exit_expr(Ka) of
+ true -> {Ka,Pa,St1};
+ false ->
+ {Kps,Sub1,St2} = pattern_list(Cvs, Sub0, St1),
+ %%ok = io:fwrite("~w: ~p~n", [?LINE,{Kps,Sub1,St1,St2}]),
+ %% Break known multiple values into separate sets.
+ Sets = case Ka of
+ #ivalues{args=Kas} ->
+ foldr2(fun (V, Val, Sb) ->
+ [#iset{vars=[V],arg=Val}|Sb] end,
+ [], Kps, Kas);
+ _Other ->
+ [#iset{anno=A,vars=Kps,arg=Ka}]
+ end,
+ {Kb,Pb,St3} = body(Cb, Sub1, St2),
+ {Kb,Pa ++ Sets ++ Pb,St3}
+ end;
+expr(#c_letrec{anno=A,defs=Cfs,body=Cb}, Sub0, St0) ->
+ %% Make new function names and store substitution.
+ {Fs0,{Sub1,St1}} =
+ mapfoldl(fun (#c_def{name=#c_fname{id=F,arity=Ar},val=B}, {Sub,St0}) ->
+ {N,St1} = new_fun_name(atom_to_list(F)
+ ++ "/" ++
+ integer_to_list(Ar),
+ St0),
+ {{N,B},{set_fsub(F, Ar, N, Sub),St1}}
+ end, {Sub0,St0}, Cfs),
+ %% Run translation on functions and body.
+ {Fs1,St2} = mapfoldl(fun ({N,Fd0}, St1) ->
+ {Fd1,[],St2} = expr(Fd0, Sub1, St1),
+ Fd = set_kanno(Fd1, A),
+ {{N,Fd},St2}
+ end, St1, Fs0),
+ {Kb,Pb,St3} = body(Cb, Sub1, St2),
+ {Kb,[#iletrec{anno=A,defs=Fs1}|Pb],St3};
+expr(#c_case{arg=Ca,clauses=Ccs}, Sub, St0) ->
+ {Ka,Pa,St1} = body(Ca, Sub, St0), %This is a body!
+ {Kvs,Pv,St2} = match_vars(Ka, St1), %Must have variables here!
+ {Km,St3} = kmatch(Kvs, Ccs, Sub, St2),
+ Match = flatten_seq(build_match(Kvs, Km)),
+ {last(Match),Pa ++ Pv ++ first(Match),St3};
+expr(#c_receive{anno=A,clauses=Ccs0,timeout=Ce,action=Ca}, Sub, St0) ->
+ {Ke,Pe,St1} = atomic_lit(Ce, Sub, St0), %Force this to be atomic!
+ {Rvar,St2} = new_var(St1),
+ %% Need to massage accept clauses and add reject clause before matching.
+ Ccs1 = map(fun (#c_clause{anno=Banno,body=B0}=C) ->
+ B1 = #c_seq{arg=#ireceive_accept{anno=A},body=B0},
+ C#c_clause{anno=Banno,body=B1}
+ end, Ccs0),
+ {Mpat,St3} = new_var_name(St2),
+ Rc = #c_clause{anno=[compiler_generated|A],
+ pats=[#c_var{name=Mpat}],guard=#c_atom{anno=A,val=true},
+ body=#ireceive_next{anno=A}},
+ {Km,St4} = kmatch([Rvar], Ccs1 ++ [Rc], Sub, add_var_def(Rvar, St3)),
+ {Ka,Pa,St5} = body(Ca, Sub, St4),
+ {#k_receive{anno=A,var=Rvar,body=Km,timeout=Ke,action=pre_seq(Pa, Ka)},
+ Pe,St5};
+expr(#c_apply{anno=A,op=Cop,args=Cargs}, Sub, St) ->
+ c_apply(A, Cop, Cargs, Sub, St);
+expr(#c_call{anno=A,module=M0,name=F0,args=Cargs}, Sub, St0) ->
+ {[M1,F1|Kargs],Ap,St1} = atomic_list([M0,F0|Cargs], Sub, St0),
+ Ar = length(Cargs),
+ case {M1,F1} of
+ {#k_atom{val=Ma},#k_atom{val=Fa}} ->
+ Call = case is_remote_bif(Ma, Fa, Ar) of
+ true ->
+ #k_bif{anno=A,
+ op=#k_remote{mod=M1,name=F1,arity=Ar},
+ args=Kargs};
+ false ->
+ #k_call{anno=A,
+ op=#k_remote{mod=M1,name=F1,arity=Ar},
+ args=Kargs}
+ end,
+ {Call,Ap,St1};
+ _Other when St0#kern.extinstr == false -> %Old explicit apply
+ Call = #c_call{anno=A,
+ module=#c_atom{val=erlang},
+ name=#c_atom{val=apply},
+ args=[M0,F0,make_list(Cargs)]},
+ expr(Call, Sub, St0);
+ _Other -> %New instruction in R10.
+ Call = #k_call{anno=A,
+ op=#k_remote{mod=M1,name=F1,arity=Ar},
+ args=Kargs},
+ {Call,Ap,St1}
+ end;
+expr(#c_primop{anno=A,name=#c_atom{val=match_fail},args=Cargs}, Sub, St0) ->
+ %% This special case will disappear.
+ {Kargs,Ap,St1} = atomic_list(Cargs, Sub, St0),
+ Ar = length(Cargs),
+ Call = #k_call{anno=A,op=#k_internal{name=match_fail,arity=Ar},args=Kargs},
+ {Call,Ap,St1};
+expr(#c_primop{anno=A,name=#c_atom{val=N},args=Cargs}, Sub, St0) ->
+ {Kargs,Ap,St1} = atomic_list(Cargs, Sub, St0),
+ Ar = length(Cargs),
+ {#k_bif{anno=A,op=#k_internal{name=N,arity=Ar},args=Kargs},Ap,St1};
+expr(#c_try{anno=A,arg=Ca,vars=Cvs,body=Cb,evars=Evs,handler=Ch}, Sub0, St0) ->
+ %% The normal try expression. The body and exception handler
+ %% variables behave as let variables.
+ {Ka,Pa,St1} = body(Ca, Sub0, St0),
+ {Kcvs,Sub1,St2} = pattern_list(Cvs, Sub0, St1),
+ {Kb,Pb,St3} = body(Cb, Sub1, St2),
+ {Kevs,Sub2,St4} = pattern_list(Evs, Sub0, St3),
+ {Kh,Ph,St5} = body(Ch, Sub2, St4),
+ {#k_try{anno=A,arg=pre_seq(Pa, Ka),
+ vars=Kcvs,body=pre_seq(Pb, Kb),
+ evars=Kevs,handler=pre_seq(Ph, Kh)},[],St5};
+expr(#c_catch{anno=A,body=Cb}, Sub, St0) ->
+ {Kb,Pb,St1} = body(Cb, Sub, St0),
+ {#k_catch{anno=A,body=pre_seq(Pb, Kb)},[],St1};
+%% Handle internal expressions.
+expr(#ireceive_accept{anno=A}, _Sub, St) -> {#k_receive_accept{anno=A},[],St}.
+
+%% expr_list([Cexpr], Sub, State) -> {[Kexpr],[PreKexpr],State}.
+
+% expr_list(Ces, Sub, St) ->
+% foldr(fun (Ce, {Kes,Esp,St0}) ->
+% {Ke,Ep,St1} = expr(Ce, Sub, St0),
+% {[Ke|Kes],Ep ++ Esp,St1}
+% end, {[],[],St}, Ces).
+
+%% match_vars(Kexpr, State) -> {[Kvar],[PreKexpr],State}.
+%% Force return from body into a list of variables.
+
+match_vars(#ivalues{args=As}, St) ->
+ foldr(fun (Ka, {Vs,Vsp,St0}) ->
+ {V,Vp,St1} = force_variable(Ka, St0),
+ {[V|Vs],Vp ++ Vsp,St1}
+ end, {[],[],St}, As);
+match_vars(Ka, St0) ->
+ {V,Vp,St1} = force_variable(Ka, St0),
+ {[V],Vp,St1}.
+
+%% c_apply(A, Op, [Carg], Sub, State) -> {Kexpr,[PreKexpr],State}.
+%% Transform application, detect which are guaranteed to be bifs.
+
+c_apply(A, #c_fname{anno=Ra,id=F0,arity=Ar}, Cargs, Sub, St0) ->
+ {Kargs,Ap,St1} = atomic_list(Cargs, Sub, St0),
+ F1 = get_fsub(F0, Ar, Sub), %Has it been rewritten
+ {#k_call{anno=A,op=#k_local{anno=Ra,name=F1,arity=Ar},args=Kargs},
+ Ap,St1};
+c_apply(A, Cop, Cargs, Sub, St0) ->
+ {Kop,Op,St1} = variable(Cop, Sub, St0),
+ {Kargs,Ap,St2} = atomic_list(Cargs, Sub, St1),
+ {#k_call{anno=A,op=Kop,args=Kargs},Op ++ Ap,St2}.
+
+flatten_seq(#iset{anno=A,vars=Vs,arg=Arg,body=B}) ->
+ [#iset{anno=A,vars=Vs,arg=Arg}|flatten_seq(B)];
+flatten_seq(Ke) -> [Ke].
+
+pre_seq([#iset{anno=A,vars=Vs,arg=Arg,body=B}|Ps], K) ->
+ B = undefined, %Assertion.
+ #iset{anno=A,vars=Vs,arg=Arg,body=pre_seq(Ps, K)};
+pre_seq([P|Ps], K) ->
+ #iset{vars=[],arg=P,body=pre_seq(Ps, K)};
+pre_seq([], K) -> K.
+
+%% atomic_lit(Cexpr, Sub, State) -> {Katomic,[PreKexpr],State}.
+%% Convert a Core expression making sure the result is an atomic
+%% literal.
+
+atomic_lit(Ce, Sub, St0) ->
+ {Ke,Kp,St1} = expr(Ce, Sub, St0),
+ {Ka,Ap,St2} = force_atomic(Ke, St1),
+ {Ka,Kp ++ Ap,St2}.
+
+force_atomic(Ke, St0) ->
+ case is_atomic(Ke) of
+ true -> {Ke,[],St0};
+ false ->
+ {V,St1} = new_var(St0),
+ {V,[#iset{vars=[V],arg=Ke}],St1}
+ end.
+
+% force_atomic_list(Kes, St) ->
+% foldr(fun (Ka, {As,Asp,St0}) ->
+% {A,Ap,St1} = force_atomic(Ka, St0),
+% {[A|As],Ap ++ Asp,St1}
+% end, {[],[],St}, Kes).
+
+atomic_bin([#c_bitstr{anno=A,val=E0,size=S0,unit=U,type=T,flags=Fs}|Es0],
+ Sub, St0, B0) ->
+ {E,Ap1,St1} = atomic_lit(E0, Sub, St0),
+ {S1,Ap2,St2} = atomic_lit(S0, Sub, St1),
+ validate_bin_element_size(S1),
+ U0 = core_lib:literal_value(U),
+ Fs0 = core_lib:literal_value(Fs),
+ {B1,Fs1} = aligned(B0, S1, U0, Fs0),
+ {Es,Ap3,St3} = atomic_bin(Es0, Sub, St2, B1),
+ {#k_bin_seg{anno=A,size=S1,
+ unit=U0,
+ type=core_lib:literal_value(T),
+ flags=Fs1,
+ seg=E,next=Es},
+ Ap1++Ap2++Ap3,St3};
+atomic_bin([], _Sub, St, _Bits) -> {#k_bin_end{},[],St}.
+
+validate_bin_element_size(#k_var{}) -> ok;
+validate_bin_element_size(#k_int{val=V}) when V >= 0 -> ok;
+validate_bin_element_size(#k_atom{val=all}) -> ok;
+validate_bin_element_size(_) -> throw(bad_element_size).
+
+%% atomic_list([Cexpr], Sub, State) -> {[Kexpr],[PreKexpr],State}.
+
+atomic_list(Ces, Sub, St) ->
+ foldr(fun (Ce, {Kes,Esp,St0}) ->
+ {Ke,Ep,St1} = atomic_lit(Ce, Sub, St0),
+ {[Ke|Kes],Ep ++ Esp,St1}
+ end, {[],[],St}, Ces).
+
+%% is_atomic(Kexpr) -> boolean().
+%% Is a Kexpr atomic? Strings are NOT considered atomic!
+
+is_atomic(#k_int{}) -> true;
+is_atomic(#k_float{}) -> true;
+is_atomic(#k_atom{}) -> true;
+%%is_atomic(#k_char{}) -> true; %No characters
+%%is_atomic(#k_string{}) -> true;
+is_atomic(#k_nil{}) -> true;
+is_atomic(#k_var{}) -> true;
+is_atomic(_) -> false.
+
+%% variable(Cexpr, Sub, State) -> {Kvar,[PreKexpr],State}.
+%% Convert a Core expression making sure the result is a variable.
+
+variable(Ce, Sub, St0) ->
+ {Ke,Kp,St1} = expr(Ce, Sub, St0),
+ {Kv,Vp,St2} = force_variable(Ke, St1),
+ {Kv,Kp ++ Vp,St2}.
+
+force_variable(#k_var{}=Ke, St) -> {Ke,[],St};
+force_variable(Ke, St0) ->
+ {V,St1} = new_var(St0),
+ {V,[#iset{vars=[V],arg=Ke}],St1}.
+
+%% pattern(Cpat, Sub, State) -> {Kpat,Sub,State}.
+%% Convert patterns. Variables shadow so rename variables that are
+%% already defined.
+
+pattern(#c_var{anno=A,name=V}, Sub, St0) ->
+ case sets:is_element(V, St0#kern.ds) of
+ true ->
+ {New,St1} = new_var_name(St0),
+ {#k_var{anno=A,name=New},
+ set_vsub(V, New, Sub),
+ St1#kern{ds=sets:add_element(New, St1#kern.ds)}};
+ false ->
+ {#k_var{anno=A,name=V},Sub,
+ St0#kern{ds=sets:add_element(V, St0#kern.ds)}}
+ end;
+pattern(#c_char{anno=A,val=C}, Sub, St) ->
+ {#k_int{anno=A,val=C},Sub,St}; %Convert to integers!
+pattern(#c_int{anno=A,val=I}, Sub, St) ->
+ {#k_int{anno=A,val=I},Sub,St};
+pattern(#c_float{anno=A,val=F}, Sub, St) ->
+ {#k_float{anno=A,val=F},Sub,St};
+pattern(#c_atom{anno=A,val=At}, Sub, St) ->
+ {#k_atom{anno=A,val=At},Sub,St};
+pattern(#c_string{val=S}, Sub, St) ->
+ L = foldr(fun (C, T) -> #k_cons{hd=#k_int{val=C},tl=T} end,
+ #k_nil{}, S),
+ {L,Sub,St};
+pattern(#c_nil{anno=A}, Sub, St) ->
+ {#k_nil{anno=A},Sub,St};
+pattern(#c_cons{anno=A,hd=Ch,tl=Ct}, Sub0, St0) ->
+ {Kh,Sub1,St1} = pattern(Ch, Sub0, St0),
+ {Kt,Sub2,St2} = pattern(Ct, Sub1, St1),
+ {#k_cons{anno=A,hd=Kh,tl=Kt},Sub2,St2};
+pattern(#c_tuple{anno=A,es=Ces}, Sub0, St0) ->
+ {Kes,Sub1,St1} = pattern_list(Ces, Sub0, St0),
+ {#k_tuple{anno=A,es=Kes},Sub1,St1};
+pattern(#c_binary{anno=A,segments=Cv}, Sub0, St0) ->
+ {Kv,Sub1,St1} = pattern_bin(Cv, Sub0, St0),
+ {#k_binary{anno=A,segs=Kv},Sub1,St1};
+pattern(#c_alias{anno=A,var=Cv,pat=Cp}, Sub0, St0) ->
+ {Cvs,Cpat} = flatten_alias(Cp),
+ {Kvs,Sub1,St1} = pattern_list([Cv|Cvs], Sub0, St0),
+ {Kpat,Sub2,St2} = pattern(Cpat, Sub1, St1),
+ {#ialias{anno=A,vars=Kvs,pat=Kpat},Sub2,St2}.
+
+flatten_alias(#c_alias{var=V,pat=P}) ->
+ {Vs,Pat} = flatten_alias(P),
+ {[V|Vs],Pat};
+flatten_alias(Pat) -> {[],Pat}.
+
+pattern_bin(Es, Sub, St) -> pattern_bin(Es, Sub, St, 0).
+
+pattern_bin([#c_bitstr{anno=A,val=E0,size=S0,unit=U,type=T,flags=Fs}|Es0],
+ Sub0, St0, B0) ->
+ {S1,[],St1} = expr(S0, Sub0, St0),
+ U0 = core_lib:literal_value(U),
+ Fs0 = core_lib:literal_value(Fs),
+ %%ok= io:fwrite("~w: ~p~n", [?LINE,{B0,S1,U0,Fs0}]),
+ {B1,Fs1} = aligned(B0, S1, U0, Fs0),
+ {E,Sub1,St2} = pattern(E0, Sub0, St1),
+ {Es,Sub2,St3} = pattern_bin(Es0, Sub1, St2, B1),
+ {#k_bin_seg{anno=A,size=S1,
+ unit=U0,
+ type=core_lib:literal_value(T),
+ flags=Fs1,
+ seg=E,next=Es},
+ Sub2,St3};
+pattern_bin([], Sub, St, _Bits) -> {#k_bin_end{},Sub,St}.
+
+%% pattern_list([Cexpr], Sub, State) -> {[Kexpr],Sub,State}.
+
+pattern_list(Ces, Sub, St) ->
+ foldr(fun (Ce, {Kes,Sub0,St0}) ->
+ {Ke,Sub1,St1} = pattern(Ce, Sub0, St0),
+ {[Ke|Kes],Sub1,St1}
+ end, {[],Sub,St}, Ces).
+
+%% new_sub() -> Subs.
+%% set_vsub(Name, Sub, Subs) -> Subs.
+%% subst_vsub(Name, Sub, Subs) -> Subs.
+%% get_vsub(Name, Subs) -> SubName.
+%% Add/get substitute Sub for Name to VarSub. Use orddict so we know
+%% the format is a list {Name,Sub} pairs. When adding a new
+%% substitute we fold substitute chains so we never have to search
+%% more than once.
+
+new_sub() -> orddict:new().
+
+get_vsub(V, Vsub) ->
+ case orddict:find(V, Vsub) of
+ {ok,Val} -> Val;
+ error -> V
+ end.
+
+set_vsub(V, S, Vsub) ->
+ orddict:store(V, S, Vsub).
+
+subst_vsub(V, S, Vsub0) ->
+ %% Fold chained substitutions.
+ Vsub1 = orddict:map(fun (_, V1) when V1 =:= V -> S;
+ (_, V1) -> V1
+ end, Vsub0),
+ orddict:store(V, S, Vsub1).
+
+get_fsub(F, A, Fsub) ->
+ case orddict:find({F,A}, Fsub) of
+ {ok,Val} -> Val;
+ error -> F
+ end.
+
+set_fsub(F, A, S, Fsub) ->
+ orddict:store({F,A}, S, Fsub).
+
+new_fun_name(St) ->
+ new_fun_name("anonymous", St).
+
+%% new_fun_name(Type, State) -> {FunName,State}.
+
+new_fun_name(Type, #kern{func={F,Arity},fcount=C}=St) ->
+ Name = "-" ++ atom_to_list(F) ++ "/" ++ integer_to_list(Arity) ++
+ "-" ++ Type ++ "-" ++ integer_to_list(C) ++ "-",
+ {list_to_atom(Name),St#kern{fcount=C+1}}.
+
+%% new_var_name(State) -> {VarName,State}.
+
+new_var_name(#kern{vcount=C}=St) ->
+ {list_to_atom("ker" ++ integer_to_list(C)),St#kern{vcount=C+1}}.
+
+%% new_var(State) -> {#k_var{},State}.
+
+new_var(St0) ->
+ {New,St1} = new_var_name(St0),
+ {#k_var{name=New},St1}.
+
+%% new_vars(Count, State) -> {[#k_var{}],State}.
+%% Make Count new variables.
+
+new_vars(N, St) -> new_vars(N, St, []).
+
+new_vars(N, St0, Vs) when N > 0 ->
+ {V,St1} = new_var(St0),
+ new_vars(N-1, St1, [V|Vs]);
+new_vars(0, St, Vs) -> {Vs,St}.
+
+make_vars(Vs) -> [ #k_var{name=V} || V <- Vs ].
+
+add_var_def(V, St) ->
+ St#kern{ds=sets:add_element(V#k_var.name, St#kern.ds)}.
+
+%%add_vars_def(Vs, St) ->
+%% Ds = foldl(fun (#k_var{name=V}, Ds) -> add_element(V, Ds) end,
+%% St#kern.ds, Vs),
+%% St#kern{ds=Ds}.
+
+%% is_remote_bif(Mod, Name, Arity) -> true | false.
+%% Test if function is really a BIF.
+
+is_remote_bif(erlang, is_boolean, 1) ->
+ %% XXX Remove this clause in R11. For bootstrap purposes, we must
+ %% recognize erlang:is_boolean/1 here.
+ true;
+is_remote_bif(erlang, internal_is_record, 3) -> true;
+is_remote_bif(erlang, get, 1) -> true;
+is_remote_bif(erlang, N, A) ->
+ case erl_internal:guard_bif(N, A) of
+ true -> true;
+ false ->
+ case erl_internal:type_test(N, A) of
+ true -> true;
+ false ->
+ case catch erl_internal:op_type(N, A) of
+ arith -> true;
+ bool -> true;
+ comp -> true;
+ _Other -> false %List, send or not an op
+ end
+ end
+ end;
+is_remote_bif(_, _, _) -> false.
+
+%% bif_vals(Name, Arity) -> integer().
+%% bif_vals(Mod, Name, Arity) -> integer().
+%% Determine how many return values a BIF has. Provision for BIFs to
+%% return multiple values. Only used in bodies where a BIF may be
+%% called for effect only.
+
+bif_vals(dsetelement, 3) -> 0;
+bif_vals(_, _) -> 1.
+
+bif_vals(_, _, _) -> 1.
+
+%% foldr2(Fun, Acc, List1, List2) -> Acc.
+%% Fold over two lists.
+
+foldr2(Fun, Acc0, [E1|L1], [E2|L2]) ->
+ Acc1 = Fun(E1, E2, Acc0),
+ foldr2(Fun, Acc1, L1, L2);
+foldr2(_, Acc, [], []) -> Acc.
+
+%% first([A]) -> [A].
+%% last([A]) -> A.
+
+last([L]) -> L;
+last([_|T]) -> last(T).
+
+first([_]) -> [];
+first([H|T]) -> [H|first(T)].
+
+%% This code implements the algorithm for an optimizing compiler for
+%% pattern matching given "The Implementation of Functional
+%% Programming Languages" by Simon Peyton Jones. The code is much
+%% longer as the meaning of constructors is different from the book.
+%%
+%% In Erlang many constructors can have different values, e.g. 'atom'
+%% or 'integer', whereas in the original algorithm thse would be
+%% different constructors. Our view makes it easier in later passes to
+%% handle indexing over each type.
+%%
+%% Patterns are complicated by having alias variables. The form of a
+%% pattern is Pat | {alias,Pat,[AliasVar]}. This is hidden by access
+%% functions to pattern arguments but the code must be aware of it.
+%%
+%% The compilation proceeds in two steps:
+%%
+%% 1. The patterns in the clauses to converted to lists of kernel
+%% patterns. The Core clause is now hybrid, this is easier to work
+%% with. Remove clauses with trivially false guards, this simplifies
+%% later passes. Add local defined vars and variable subs to each
+%% clause for later use.
+%%
+%% 2. The pattern matching is optimised. Variable substitutions are
+%% added to the VarSub structure and new variables are made visible.
+%% The guard and body are then converted to Kernel form.
+
+%% kmatch([Var], [Clause], Sub, State) -> {Kexpr,[PreExpr],State}.
+
+kmatch(Us, Ccs, Sub, St0) ->
+ {Cs,St1} = match_pre(Ccs, Sub, St0), %Convert clauses
+ %%Def = kernel_match_error, %The strict case
+ %% This should be a kernel expression from the first pass.
+ Def = #k_call{anno=[compiler_generated],
+ op=#k_remote{mod=#k_atom{val=erlang},
+ name=#k_atom{val=exit},
+ arity=1},
+ args=[#k_atom{val=kernel_match_error}]},
+ {Km,St2} = match(Us, Cs, Def, St1), %Do the match.
+ {Km,St2}.
+
+%% match_pre([Cclause], Sub, State) -> {[Clause],State}.
+%% Must be careful not to generate new substitutions here now!
+%% Remove clauses with trivially false guards which will never
+%% succeed.
+
+match_pre(Cs, Sub0, St) ->
+ foldr(fun (#c_clause{anno=A,pats=Ps,guard=G,body=B}, {Cs0,St0}) ->
+ case is_false_guard(G) of
+ true -> {Cs0,St0};
+ false ->
+ {Kps,Sub1,St1} = pattern_list(Ps, Sub0, St0),
+ {[#iclause{anno=A,sub=Sub1,pats=Kps,guard=G,body=B}|
+ Cs0],St1}
+ end
+ end, {[],St}, Cs).
+
+%% match([Var], [Clause], Default, State) -> {MatchExpr,State}.
+
+match([U|Us], Cs, Def, St0) ->
+ %%ok = io:format("match ~p~n", [Cs]),
+ Pcss = partition(Cs),
+ foldr(fun (Pcs, {D,St}) -> match_varcon([U|Us], Pcs, D, St) end,
+ {Def,St0}, Pcss);
+match([], Cs, Def, St) ->
+ match_guard(Cs, Def, St).
+
+%% match_guard([Clause], Default, State) -> {IfExpr,State}.
+%% Build a guard to handle guards. A guard *ALWAYS* fails if no
+%% clause matches, there will be a surrounding 'alt' to catch the
+%% failure. Drop redundant cases, i.e. those after a true guard.
+
+match_guard(Cs0, Def0, St0) ->
+ {Cs1,Def1,St1} = match_guard_1(Cs0, Def0, St0),
+ {build_alt(build_guard(Cs1), Def1),St1}.
+
+match_guard_1([#iclause{anno=A,sub=Sub,guard=G,body=B}|Cs0], Def0, St0) ->
+ case is_true_guard(G) of
+ true ->
+ %% The true clause body becomes the default.
+ {Kb,Pb,St1} = body(B, Sub, St0),
+ Line = get_line(A),
+ St2 = maybe_add_warning(Cs0, Line, St1),
+ St = maybe_add_warning(Def0, Line, St2),
+ {[],pre_seq(Pb, Kb),St};
+ false ->
+ {Kg,St1} = guard(G, Sub, St0),
+ {Kb,Pb,St2} = body(B, Sub, St1),
+ {Cs1,Def1,St3} = match_guard_1(Cs0, Def0, St2),
+ {[#k_guard_clause{guard=Kg,body=pre_seq(Pb, Kb)}|Cs1],
+ Def1,St3}
+ end;
+match_guard_1([], Def, St) -> {[],Def,St}.
+
+maybe_add_warning([C|_], Line, St) ->
+ maybe_add_warning(C, Line, St);
+maybe_add_warning([], _Line, St) -> St;
+maybe_add_warning(fail, _Line, St) -> St;
+maybe_add_warning(Ke, MatchLine, St) ->
+ case get_kanno(Ke) of
+ [compiler_generated|_] -> St;
+ Anno ->
+ Line = get_line(Anno),
+ Warn = case MatchLine of
+ none -> nomatch_shadow;
+ _ -> {nomatch_shadow,MatchLine}
+ end,
+ add_warning(Line, Warn, St)
+ end.
+
+get_line([Line|_]) when is_integer(Line) -> Line;
+get_line([_|T]) -> get_line(T);
+get_line([]) -> none.
+
+
+%% is_true_guard(Guard) -> boolean().
+%% is_false_guard(Guard) -> boolean().
+%% Test if a guard is either trivially true/false. This has probably
+%% already been optimised away, but what the heck!
+
+is_true_guard(G) -> guard_value(G) == true.
+is_false_guard(G) -> guard_value(G) == false.
+
+%% guard_value(Guard) -> true | false | unknown.
+
+guard_value(#c_atom{val=true}) -> true;
+guard_value(#c_atom{val=false}) -> false;
+guard_value(#c_call{module=#c_atom{val=erlang},
+ name=#c_atom{val='not'},
+ args=[A]}) ->
+ case guard_value(A) of
+ true -> false;
+ false -> true;
+ unknown -> unknown
+ end;
+guard_value(#c_call{module=#c_atom{val=erlang},
+ name=#c_atom{val='and'},
+ args=[Ca,Cb]}) ->
+ case guard_value(Ca) of
+ true -> guard_value(Cb);
+ false -> false;
+ unknown ->
+ case guard_value(Cb) of
+ false -> false;
+ _Other -> unknown
+ end
+ end;
+guard_value(#c_call{module=#c_atom{val=erlang},
+ name=#c_atom{val='or'},
+ args=[Ca,Cb]}) ->
+ case guard_value(Ca) of
+ true -> true;
+ false -> guard_value(Cb);
+ unknown ->
+ case guard_value(Cb) of
+ true -> true;
+ _Other -> unknown
+ end
+ end;
+guard_value(#c_try{arg=E,vars=[#c_var{name=X}],body=#c_var{name=X},
+ handler=#c_atom{val=false}}) ->
+ guard_value(E);
+guard_value(_) -> unknown.
+
+%% partition([Clause]) -> [[Clause]].
+%% Partition a list of clauses into groups which either contain
+%% clauses with a variable first argument, or with a "constructor".
+
+partition([C1|Cs]) ->
+ V1 = is_var_clause(C1),
+ {More,Rest} = splitwith(fun (C) -> is_var_clause(C) == V1 end, Cs),
+ [[C1|More]|partition(Rest)];
+partition([]) -> [].
+
+%% match_varcon([Var], [Clause], Def, [Var], Sub, State) ->
+%% {MatchExpr,State}.
+
+match_varcon(Us, [C|_]=Cs, Def, St) ->
+ case is_var_clause(C) of
+ true -> match_var(Us, Cs, Def, St);
+ false -> match_con(Us, Cs, Def, St)
+ end.
+
+%% match_var([Var], [Clause], Def, State) -> {MatchExpr,State}.
+%% Build a call to "select" from a list of clauses all containing a
+%% variable as the first argument. We must rename the variable in
+%% each clause to be the match variable as these clause will share
+%% this variable and may have different names for it. Rename aliases
+%% as well.
+
+match_var([U|Us], Cs0, Def, St) ->
+ Cs1 = map(fun (#iclause{sub=Sub0,pats=[Arg|As]}=C) ->
+ Vs = [arg_arg(Arg)|arg_alias(Arg)],
+ Sub1 = foldl(fun (#k_var{name=V}, Acc) ->
+ subst_vsub(V, U#k_var.name, Acc)
+ end, Sub0, Vs),
+ C#iclause{sub=Sub1,pats=As}
+ end, Cs0),
+ match(Us, Cs1, Def, St).
+
+%% match_con(Variables, [Clause], Default, State) -> {SelectExpr,State}.
+%% Build call to "select" from a list of clauses all containing a
+%% constructor/constant as first argument. Group the constructors
+%% according to type, the order is really irrelevant but tries to be
+%% smart.
+
+match_con([U|Us], Cs, Def, St0) ->
+ %% Extract clauses for different constructors (types).
+ %%ok = io:format("match_con ~p~n", [Cs]),
+ Ttcs = [ {T,Tcs} || T <- [k_cons,k_tuple,k_atom,k_float,k_int,k_nil,
+ k_binary,k_bin_end],
+ begin Tcs = select(T, Cs),
+ Tcs /= []
+ end ] ++ select_bin_con(Cs),
+ %%ok = io:format("ttcs = ~p~n", [Ttcs]),
+ {Scs,St1} =
+ mapfoldl(fun ({T,Tcs}, St) ->
+ {[S|_]=Sc,S1} = match_value([U|Us], T, Tcs, fail, St),
+ %%ok = io:format("match_con type2 ~p~n", [T]),
+ Anno = get_kanno(S),
+ {#k_type_clause{anno=Anno,type=T,values=Sc},S1} end,
+ St0, Ttcs),
+ {build_alt_1st_no_fail(build_select(U, Scs), Def),St1}.
+
+%% select_bin_con([Clause]) -> [{Type,[Clause]}].
+%% Extract clauses for the k_bin_seg constructor. As k_bin_seg
+%% matching can overlap, the k_bin_seg constructors cannot be
+%% reordered, only grouped.
+
+select_bin_con(Cs0) ->
+ Cs1 = lists:filter(fun (C) ->
+ clause_con(C) == k_bin_seg
+ end, Cs0),
+ select_bin_con_1(Cs1).
+
+select_bin_con_1([C1|Cs]) ->
+ Con = clause_con(C1),
+ {More,Rest} = splitwith(fun (C) -> clause_con(C) == Con end, Cs),
+ [{Con,[C1|More]}|select_bin_con_1(Rest)];
+select_bin_con_1([]) -> [].
+
+%% select(Con, [Clause]) -> [Clause].
+
+select(T, Cs) -> [ C || C <- Cs, clause_con(C) == T ].
+
+%% match_value([Var], Con, [Clause], Default, State) -> {SelectExpr,State}.
+%% At this point all the clauses have the same constructor, we must
+%% now separate them according to value.
+
+match_value(_, _, [], _, St) -> {[],St};
+match_value(Us, T, Cs0, Def, St0) ->
+ Css = group_value(T, Cs0),
+ %%ok = io:format("match_value ~p ~p~n", [T, Css]),
+ {Css1,St1} = mapfoldl(fun (Cs, St) ->
+ match_clause(Us, Cs, Def, St) end,
+ St0, Css),
+ {Css1,St1}.
+ %%{#k_select_val{type=T,var=hd(Us),clauses=Css1},St1}.
+
+%% group_value([Clause]) -> [[Clause]].
+%% Group clauses according to value. Here we know that
+%% 1. Some types are singled valued
+%% 2. The clauses in bin_segs cannot be reordered only grouped
+%% 3. Other types are disjoint and can be reordered
+
+group_value(k_cons, Cs) -> [Cs]; %These are single valued
+group_value(k_nil, Cs) -> [Cs];
+group_value(k_binary, Cs) -> [Cs];
+group_value(k_bin_end, Cs) -> [Cs];
+group_value(k_bin_seg, Cs) ->
+ group_bin_seg(Cs);
+group_value(_, Cs) ->
+ %% group_value(Cs).
+ Cd = foldl(fun (C, Gcs0) -> dict:append(clause_val(C), C, Gcs0) end,
+ dict:new(), Cs),
+ dict:fold(fun (_, Vcs, Css) -> [Vcs|Css] end, [], Cd).
+
+group_bin_seg([C1|Cs]) ->
+ V1 = clause_val(C1),
+ {More,Rest} = splitwith(fun (C) -> clause_val(C) == V1 end, Cs),
+ [[C1|More]|group_bin_seg(Rest)];
+group_bin_seg([]) -> [].
+
+%% Profiling shows that this quadratic implementation account for a big amount
+%% of the execution time if there are many values.
+% group_value([C|Cs]) ->
+% V = clause_val(C),
+% Same = [ Cv || Cv <- Cs, clause_val(Cv) == V ], %Same value
+% Rest = [ Cv || Cv <- Cs, clause_val(Cv) /= V ], % and all the rest
+% [[C|Same]|group_value(Rest)];
+% group_value([]) -> [].
+
+%% match_clause([Var], [Clause], Default, State) -> {Clause,State}.
+%% At this point all the clauses have the same "value". Build one
+%% select clause for this value and continue matching. Rename
+%% aliases as well.
+
+match_clause([U|Us], [C|_]=Cs0, Def, St0) ->
+ Anno = get_kanno(C),
+ {Match0,Vs,St1} = get_match(get_con(Cs0), St0),
+ Match = sub_size_var(Match0, Cs0),
+ {Cs1,St2} = new_clauses(Cs0, U, St1),
+ {B,St3} = match(Vs ++ Us, Cs1, Def, St2),
+ {#k_val_clause{anno=Anno,val=Match,body=B},St3}.
+
+sub_size_var(#k_bin_seg{size=#k_var{name=Name}=Kvar}=BinSeg, [#iclause{sub=Sub}|_]) ->
+ BinSeg#k_bin_seg{size=Kvar#k_var{name=get_vsub(Name, Sub)}};
+sub_size_var(K, _) -> K.
+
+get_con([C|_]) -> arg_arg(clause_arg(C)). %Get the constructor
+
+get_match(#k_cons{}, St0) ->
+ {[H,T],St1} = new_vars(2, St0),
+ {#k_cons{hd=H,tl=T},[H,T],St1};
+get_match(#k_binary{}, St0) ->
+ {[V]=Mes,St1} = new_vars(1, St0),
+ {#k_binary{segs=V},Mes,St1};
+get_match(#k_bin_seg{}=Seg, St0) ->
+ {[S,N]=Mes,St1} = new_vars(2, St0),
+ {Seg#k_bin_seg{seg=S,next=N},Mes,St1};
+get_match(#k_tuple{es=Es}, St0) ->
+ {Mes,St1} = new_vars(length(Es), St0),
+ {#k_tuple{es=Mes},Mes,St1};
+get_match(M, St) ->
+ {M,[],St}.
+
+new_clauses(Cs0, U, St) ->
+ Cs1 = map(fun (#iclause{sub=Sub0,pats=[Arg|As]}=C) ->
+ Head = case arg_arg(Arg) of
+ #k_cons{hd=H,tl=T} -> [H,T|As];
+ #k_tuple{es=Es} -> Es ++ As;
+ #k_binary{segs=E} -> [E|As];
+ #k_bin_seg{seg=S,next=N} ->
+ [S,N|As];
+ _Other -> As
+ end,
+ Vs = arg_alias(Arg),
+ Sub1 = foldl(fun (#k_var{name=V}, Acc) ->
+ subst_vsub(V, U#k_var.name, Acc)
+ end, Sub0, Vs),
+ C#iclause{sub=Sub1,pats=Head}
+ end, Cs0),
+ {Cs1,St}.
+
+%% build_guard([GuardClause]) -> GuardExpr.
+
+build_guard([]) -> fail;
+build_guard(Cs) -> #k_guard{clauses=Cs}.
+
+%% build_select(Var, [ConClause]) -> SelectExpr.
+
+build_select(V, [Tc|_]=Tcs) ->
+ Anno = get_kanno(Tc),
+ #k_select{anno=Anno,var=V,types=Tcs}.
+
+%% build_alt(First, Then) -> AltExpr.
+%% Build an alt, attempt some simple optimisation.
+
+build_alt(fail, Then) -> Then;
+build_alt(First,Then) -> build_alt_1st_no_fail(First, Then).
+
+build_alt_1st_no_fail(First, fail) -> First;
+build_alt_1st_no_fail(First, Then) -> #k_alt{first=First,then=Then}.
+
+%% build_match([MatchVar], MatchExpr) -> Kexpr.
+%% Build a match expr if there is a match.
+
+build_match(Us, #k_alt{}=Km) -> #k_match{vars=Us,body=Km};
+build_match(Us, #k_select{}=Km) -> #k_match{vars=Us,body=Km};
+build_match(Us, #k_guard{}=Km) -> #k_match{vars=Us,body=Km};
+build_match(_, Km) -> Km.
+
+%% clause_arg(Clause) -> FirstArg.
+%% clause_con(Clause) -> Constructor.
+%% clause_val(Clause) -> Value.
+%% is_var_clause(Clause) -> boolean().
+
+clause_arg(#iclause{pats=[Arg|_]}) -> Arg.
+
+clause_con(C) -> arg_con(clause_arg(C)).
+
+clause_val(C) -> arg_val(clause_arg(C)).
+
+is_var_clause(C) -> clause_con(C) == k_var.
+
+%% arg_arg(Arg) -> Arg.
+%% arg_alias(Arg) -> Aliases.
+%% arg_con(Arg) -> Constructor.
+%% arg_val(Arg) -> Value.
+%% These are the basic functions for obtaining fields in an argument.
+
+arg_arg(#ialias{pat=Con}) -> Con;
+arg_arg(Con) -> Con.
+
+arg_alias(#ialias{vars=As}) -> As;
+arg_alias(_Con) -> [].
+
+arg_con(Arg) ->
+ case arg_arg(Arg) of
+ #k_int{} -> k_int;
+ #k_float{} -> k_float;
+ #k_atom{} -> k_atom;
+ #k_nil{} -> k_nil;
+ #k_cons{} -> k_cons;
+ #k_tuple{} -> k_tuple;
+ #k_binary{} -> k_binary;
+ #k_bin_end{} -> k_bin_end;
+ #k_bin_seg{} -> k_bin_seg;
+ #k_var{} -> k_var
+ end.
+
+arg_val(Arg) ->
+ case arg_arg(Arg) of
+ #k_int{val=I} -> I;
+ #k_float{val=F} -> F;
+ #k_atom{val=A} -> A;
+ #k_nil{} -> 0;
+ #k_cons{} -> 2;
+ #k_tuple{es=Es} -> length(Es);
+ #k_bin_seg{size=S,unit=U,type=T,flags=Fs} ->
+ {set_kanno(S, []),U,T,Fs};
+ #k_bin_end{} -> 0;
+ #k_binary{} -> 0
+ end.
+
+%% ubody(Expr, Break, State) -> {Expr,[UsedVar],State}.
+%% Tag the body sequence with its used variables. These bodies
+%% either end with a #k_break{}, or with #k_return{} or an expression
+%% which itself can return, #k_enter{}, #k_match{} ... .
+
+ubody(#iset{vars=[],arg=#iletrec{}=Let,body=B0}, Br, St0) ->
+ %% An iletrec{} should never be last.
+ St1 = iletrec_funs(Let, St0),
+ ubody(B0, Br, St1);
+ubody(#iset{anno=A,vars=Vs,arg=E0,body=B0}, Br, St0) ->
+ {E1,Eu,St1} = uexpr(E0, {break,Vs}, St0),
+ {B1,Bu,St2} = ubody(B0, Br, St1),
+ Ns = lit_list_vars(Vs),
+ Used = union(Eu, subtract(Bu, Ns)), %Used external vars
+ {#k_seq{anno=#k{us=Used,ns=Ns,a=A},arg=E1,body=B1},Used,St2};
+ubody(#ivalues{anno=A,args=As}, return, St) ->
+ Au = lit_list_vars(As),
+ {#k_return{anno=#k{us=Au,ns=[],a=A},args=As},Au,St};
+ubody(#ivalues{anno=A,args=As}, {break,_Vbs}, St) ->
+ Au = lit_list_vars(As),
+ {#k_break{anno=#k{us=Au,ns=[],a=A},args=As},Au,St};
+ubody(E, return, St0) ->
+ %% Enterable expressions need no trailing return.
+ case is_enter_expr(E) of
+ true -> uexpr(E, return, St0);
+ false ->
+ {Ea,Pa,St1} = force_atomic(E, St0),
+ ubody(pre_seq(Pa, #ivalues{args=[Ea]}), return, St1)
+ end;
+ubody(E, {break,Rs}, St0) ->
+ %%ok = io:fwrite("ubody ~w:~p~n", [?LINE,{E,Br}]),
+ %% Exiting expressions need no trailing break.
+ case is_exit_expr(E) of
+ true -> uexpr(E, return, St0);
+ false ->
+ {Ea,Pa,St1} = force_atomic(E, St0),
+ ubody(pre_seq(Pa, #ivalues{args=[Ea]}), {break,Rs}, St1)
+ end.
+
+iletrec_funs(#iletrec{defs=Fs}, St0) ->
+ %% Use union of all free variables.
+ %% First just work out free variables for all functions.
+ Free = foldl(fun ({_,#ifun{vars=Vs,body=Fb0}}, Free0) ->
+ {_,Fbu,_} = ubody(Fb0, return, St0),
+ Ns = lit_list_vars(Vs),
+ Free1 = subtract(Fbu, Ns),
+ union(Free1, Free0)
+ end, [], Fs),
+ FreeVs = make_vars(Free),
+ %% Add this free info to State.
+ St1 = foldl(fun ({N,#ifun{vars=Vs}}, Lst) ->
+ store_free(N, length(Vs), FreeVs, Lst)
+ end, St0, Fs),
+ %% Now regenerate local functions to use free variable information.
+ St2 = foldl(fun ({N,#ifun{anno=Fa,vars=Vs,body=Fb0}}, Lst0) ->
+ {Fb1,_,Lst1} = ubody(Fb0, return, Lst0),
+ Arity = length(Vs) + length(FreeVs),
+ Fun = #k_fdef{anno=#k{us=[],ns=[],a=Fa},
+ func=N,arity=Arity,
+ vars=Vs ++ FreeVs,body=Fb1},
+ Lst1#kern{funs=[Fun|Lst1#kern.funs]}
+ end, St1, Fs),
+ St2.
+
+%% is_exit_expr(Kexpr) -> boolean().
+%% Test whether Kexpr always exits and never returns.
+
+is_exit_expr(#k_call{op=#k_remote{mod=erlang,name=throw,arity=1}}) -> true;
+is_exit_expr(#k_call{op=#k_remote{mod=erlang,name=exit,arity=1}}) -> true;
+is_exit_expr(#k_call{op=#k_remote{mod=erlang,name=error,arity=1}}) -> true;
+is_exit_expr(#k_call{op=#k_remote{mod=erlang,name=error,arity=2}}) -> true;
+is_exit_expr(#k_call{op=#k_remote{mod=erlang,name=fault,arity=1}}) -> true;
+is_exit_expr(#k_call{op=#k_remote{mod=erlang,name=fault,arity=2}}) -> true;
+is_exit_expr(#k_call{op=#k_internal{name=match_fail,arity=1}}) -> true;
+is_exit_expr(#k_bif{op=#k_internal{name=rethrow,arity=2}}) -> true;
+is_exit_expr(#k_receive_next{}) -> true;
+is_exit_expr(_) -> false.
+
+%% is_enter_expr(Kexpr) -> boolean().
+%% Test whether Kexpr is "enterable", i.e. can handle return from
+%% within itself without extra #k_return{}.
+
+is_enter_expr(#k_call{}) -> true;
+is_enter_expr(#k_match{}) -> true;
+is_enter_expr(#k_receive{}) -> true;
+is_enter_expr(#k_receive_next{}) -> true;
+%%is_enter_expr(#k_try{}) -> true; %Soon
+is_enter_expr(_) -> false.
+
+%% uguard(Expr, State) -> {Expr,[UsedVar],State}.
+%% Tag the guard sequence with its used variables.
+
+uguard(#k_try{anno=A,arg=B0,vars=[#k_var{name=X}],body=#k_var{name=X},
+ handler=#k_atom{val=false}}=Try, St0) ->
+ {B1,Bu,St1} = uguard(B0, St0),
+ {Try#k_try{anno=#k{us=Bu,ns=[],a=A},arg=B1},Bu,St1};
+uguard(T, St) ->
+ %%ok = io:fwrite("~w: ~p~n", [?LINE,T]),
+ uguard_test(T, St).
+
+%% uguard_test(Expr, State) -> {Test,[UsedVar],State}.
+%% At this stage tests are just expressions which don't return any
+%% values.
+
+uguard_test(T, St) -> uguard_expr(T, [], St).
+
+uguard_expr(#iset{anno=A,vars=Vs,arg=E0,body=B0}, Rs, St0) ->
+ Ns = lit_list_vars(Vs),
+ {E1,Eu,St1} = uguard_expr(E0, Vs, St0),
+ {B1,Bu,St2} = uguard_expr(B0, Rs, St1),
+ Used = union(Eu, subtract(Bu, Ns)),
+ {#k_seq{anno=#k{us=Used,ns=Ns,a=A},arg=E1,body=B1},Used,St2};
+uguard_expr(#k_try{anno=A,arg=B0,vars=[#k_var{name=X}],body=#k_var{name=X},
+ handler=#k_atom{val=false}}=Try, Rs, St0) ->
+ {B1,Bu,St1} = uguard_expr(B0, Rs, St0),
+ {Try#k_try{anno=#k{us=Bu,ns=lit_list_vars(Rs),a=A},arg=B1,ret=Rs},
+ Bu,St1};
+uguard_expr(#k_test{anno=A,op=Op,args=As}=Test, Rs, St) ->
+ [] = Rs, %Sanity check
+ Used = union(op_vars(Op), lit_list_vars(As)),
+ {Test#k_test{anno=#k{us=Used,ns=lit_list_vars(Rs),a=A}},
+ Used,St};
+uguard_expr(#k_bif{anno=A,op=Op,args=As}=Bif, Rs, St) ->
+ Used = union(op_vars(Op), lit_list_vars(As)),
+ {Bif#k_bif{anno=#k{us=Used,ns=lit_list_vars(Rs),a=A},ret=Rs},
+ Used,St};
+uguard_expr(#ivalues{anno=A,args=As}, Rs, St) ->
+ Sets = foldr2(fun (V, Arg, Rhs) ->
+ #iset{anno=A,vars=[V],arg=Arg,body=Rhs}
+ end, #k_atom{val=true}, Rs, As),
+ uguard_expr(Sets, [], St);
+uguard_expr(#k_match{anno=A,vars=Vs,body=B0}, Rs, St0) ->
+ %% Experimental support for andalso/orelse in guards.
+ Br = case Rs of
+ [] -> return;
+ _ -> {break,Rs}
+ end,
+ {B1,Bu,St1} = umatch(B0, Br, St0),
+ {#k_match{anno=#k{us=Bu,ns=lit_list_vars(Rs),a=A},
+ vars=Vs,body=B1,ret=Rs},Bu,St1};
+uguard_expr(Lit, Rs, St) ->
+ %% Transform literals to puts here.
+ Used = lit_vars(Lit),
+ {#k_put{anno=#k{us=Used,ns=lit_list_vars(Rs),a=get_kanno(Lit)},
+ arg=Lit,ret=Rs},Used,St}.
+
+%% uexpr(Expr, Break, State) -> {Expr,[UsedVar],State}.
+%% Tag an expression with its used variables.
+%% Break = return | {break,[RetVar]}.
+
+uexpr(#k_call{anno=A,op=#k_local{name=F,arity=Ar}=Op,args=As0}=Call, Br, St) ->
+ Free = get_free(F, Ar, St),
+ As1 = As0 ++ Free, %Add free variables LAST!
+ Used = lit_list_vars(As1),
+ {case Br of
+ {break,Rs} ->
+ Call#k_call{anno=#k{us=Used,ns=lit_list_vars(Rs),a=A},
+ op=Op#k_local{arity=Ar + length(Free)},
+ args=As1,ret=Rs};
+ return ->
+ #k_enter{anno=#k{us=Used,ns=[],a=A},
+ op=Op#k_local{arity=Ar + length(Free)},
+ args=As1}
+ end,Used,St};
+uexpr(#k_call{anno=A,op=Op,args=As}=Call, {break,Rs}, St) ->
+ Used = union(op_vars(Op), lit_list_vars(As)),
+ {Call#k_call{anno=#k{us=Used,ns=lit_list_vars(Rs),a=A},ret=Rs},
+ Used,St};
+uexpr(#k_call{anno=A,op=Op,args=As}, return, St) ->
+ Used = union(op_vars(Op), lit_list_vars(As)),
+ {#k_enter{anno=#k{us=Used,ns=[],a=A},op=Op,args=As},
+ Used,St};
+uexpr(#k_bif{anno=A,op=Op,args=As}=Bif, {break,Rs}, St0) ->
+ Used = union(op_vars(Op), lit_list_vars(As)),
+ {Brs,St1} = bif_returns(Op, Rs, St0),
+ {Bif#k_bif{anno=#k{us=Used,ns=lit_list_vars(Brs),a=A},ret=Brs},
+ Used,St1};
+uexpr(#k_match{anno=A,vars=Vs,body=B0}, Br, St0) ->
+ Rs = break_rets(Br),
+ {B1,Bu,St1} = umatch(B0, Br, St0),
+ {#k_match{anno=#k{us=Bu,ns=lit_list_vars(Rs),a=A},
+ vars=Vs,body=B1,ret=Rs},Bu,St1};
+uexpr(#k_receive{anno=A,var=V,body=B0,timeout=T,action=A0}, Br, St0) ->
+ Rs = break_rets(Br),
+ Tu = lit_vars(T), %Timeout is atomic
+ {B1,Bu,St1} = umatch(B0, Br, St0),
+ {A1,Au,St2} = ubody(A0, Br, St1),
+ Used = del_element(V#k_var.name, union(Bu, union(Tu, Au))),
+ {#k_receive{anno=#k{us=Used,ns=lit_list_vars(Rs),a=A},
+ var=V,body=B1,timeout=T,action=A1,ret=Rs},
+ Used,St2};
+uexpr(#k_receive_accept{anno=A}, _, St) ->
+ {#k_receive_accept{anno=#k{us=[],ns=[],a=A}},[],St};
+uexpr(#k_receive_next{anno=A}, _, St) ->
+ {#k_receive_next{anno=#k{us=[],ns=[],a=A}},[],St};
+uexpr(#k_try{anno=A,arg=A0,vars=Vs,body=B0,evars=Evs,handler=H0},
+ {break,Rs0}, St0) ->
+ {Avs,St1} = new_vars(length(Vs), St0), %Need dummy names here
+ {A1,Au,St2} = ubody(A0, {break,Avs}, St1), %Must break to clean up here!
+ {B1,Bu,St3} = ubody(B0, {break,Rs0}, St2),
+ {H1,Hu,St4} = ubody(H0, {break,Rs0}, St3),
+ %% Guarantee ONE return variable.
+ NumNew = if
+ Rs0 =:= [] -> 1;
+ true -> 0
+ end,
+ {Ns,St5} = new_vars(NumNew, St4),
+ Rs1 = Rs0 ++ Ns,
+ Used = union([Au,subtract(Bu, lit_list_vars(Vs)),
+ subtract(Hu, lit_list_vars(Evs))]),
+ {#k_try{anno=#k{us=Used,ns=lit_list_vars(Rs1),a=A},
+ arg=A1,vars=Vs,body=B1,evars=Evs,handler=H1,ret=Rs1},
+ Used,St5};
+uexpr(#k_catch{anno=A,body=B0}, {break,Rs0}, St0) ->
+ {Rb,St1} = new_var(St0),
+ {B1,Bu,St2} = ubody(B0, {break,[Rb]}, St1),
+ %% Guarantee ONE return variable.
+ {Ns,St3} = new_vars(1 - length(Rs0), St2),
+ Rs1 = Rs0 ++ Ns,
+ {#k_catch{anno=#k{us=Bu,ns=lit_list_vars(Rs1),a=A},body=B1,ret=Rs1},Bu,St3};
+uexpr(#ifun{anno=A,vars=Vs,body=B0}=IFun, {break,Rs}, St0) ->
+ {B1,Bu,St1} = ubody(B0, return, St0), %Return out of new function
+ Ns = lit_list_vars(Vs),
+ Free = subtract(Bu, Ns), %Free variables in fun
+ Fvs = make_vars(Free),
+ Arity = length(Vs) + length(Free),
+ {{Index,Uniq,Fname}, St3} =
+ case lists:keysearch(id, 1, A) of
+ {value,{id,Id}} ->
+ {Id, St1};
+ false ->
+ %% No id annotation. Must invent one.
+ I = St1#kern.fcount,
+ U = erlang:hash(IFun, (1 bsl 27)-1),
+ {N, St2} = new_fun_name(St1),
+ {{I,U,N}, St2}
+ end,
+ Fun = #k_fdef{anno=#k{us=[],ns=[],a=A},func=Fname,arity=Arity,
+ vars=Vs ++ Fvs,body=B1},
+ {#k_bif{anno=#k{us=Free,ns=lit_list_vars(Rs),a=A},
+ op=#k_internal{name=make_fun,arity=length(Free)+3},
+ args=[#k_atom{val=Fname},#k_int{val=Arity},
+ #k_int{val=Index},#k_int{val=Uniq}|Fvs],
+ ret=Rs},
+% {#k_call{anno=#k{us=Free,ns=lit_list_vars(Rs),a=A},
+% op=#k_internal{name=make_fun,arity=length(Free)+3},
+% args=[#k_atom{val=Fname},#k_int{val=Arity},
+% #k_int{val=Index},#k_int{val=Uniq}|Fvs],
+% ret=Rs},
+ Free,St3#kern{funs=[Fun|St3#kern.funs]}};
+uexpr(Lit, {break,Rs}, St) ->
+ %% Transform literals to puts here.
+ %%ok = io:fwrite("uexpr ~w:~p~n", [?LINE,Lit]),
+ Used = lit_vars(Lit),
+ {#k_put{anno=#k{us=Used,ns=lit_list_vars(Rs),a=get_kanno(Lit)},
+ arg=Lit,ret=Rs},Used,St}.
+
+%% get_free(Name, Arity, State) -> [Free].
+%% store_free(Name, Arity, [Free], State) -> State.
+
+get_free(F, A, St) ->
+ case orddict:find({F,A}, St#kern.free) of
+ {ok,Val} -> Val;
+ error -> []
+ end.
+
+store_free(F, A, Free, St) ->
+ St#kern{free=orddict:store({F,A}, Free, St#kern.free)}.
+
+break_rets({break,Rs}) -> Rs;
+break_rets(return) -> [].
+
+%% bif_returns(Op, [Ret], State) -> {[Ret],State}.
+
+bif_returns(#k_remote{mod=M,name=N,arity=Ar}, Rs, St0) ->
+ %%ok = io:fwrite("uexpr ~w:~p~n", [?LINE,{M,N,Ar,Rs}]),
+ {Ns,St1} = new_vars(bif_vals(M, N, Ar) - length(Rs), St0),
+ {Rs ++ Ns,St1};
+bif_returns(#k_internal{name=N,arity=Ar}, Rs, St0) ->
+ %%ok = io:fwrite("uexpr ~w:~p~n", [?LINE,{N,Ar,Rs}]),
+ {Ns,St1} = new_vars(bif_vals(N, Ar) - length(Rs), St0),
+ {Rs ++ Ns,St1}.
+
+%% umatch(Match, Break, State) -> {Match,[UsedVar],State}.
+%% Tag a match expression with its used variables.
+
+umatch(#k_alt{anno=A,first=F0,then=T0}, Br, St0) ->
+ {F1,Fu,St1} = umatch(F0, Br, St0),
+ {T1,Tu,St2} = umatch(T0, Br, St1),
+ Used = union(Fu, Tu),
+ {#k_alt{anno=#k{us=Used,ns=[],a=A},first=F1,then=T1},
+ Used,St2};
+umatch(#k_select{anno=A,var=V,types=Ts0}, Br, St0) ->
+ {Ts1,Tus,St1} = umatch_list(Ts0, Br, St0),
+ Used = add_element(V#k_var.name, Tus),
+ {#k_select{anno=#k{us=Used,ns=[],a=A},var=V,types=Ts1},Used,St1};
+umatch(#k_type_clause{anno=A,type=T,values=Vs0}, Br, St0) ->
+ {Vs1,Vus,St1} = umatch_list(Vs0, Br, St0),
+ {#k_type_clause{anno=#k{us=Vus,ns=[],a=A},type=T,values=Vs1},Vus,St1};
+umatch(#k_val_clause{anno=A,val=P,body=B0}, Br, St0) ->
+ {U0,Ps} = pat_vars(P),
+ {B1,Bu,St1} = umatch(B0, Br, St0),
+ Used = union(U0, subtract(Bu, Ps)),
+ {#k_val_clause{anno=#k{us=Used,ns=[],a=A},val=P,body=B1},
+ Used,St1};
+umatch(#k_guard{anno=A,clauses=Gs0}, Br, St0) ->
+ {Gs1,Gus,St1} = umatch_list(Gs0, Br, St0),
+ {#k_guard{anno=#k{us=Gus,ns=[],a=A},clauses=Gs1},Gus,St1};
+umatch(#k_guard_clause{anno=A,guard=G0,body=B0}, Br, St0) ->
+ %%ok = io:fwrite("~w: ~p~n", [?LINE,G0]),
+ {G1,Gu,St1} = uguard(G0, St0),
+ %%ok = io:fwrite("~w: ~p~n", [?LINE,G1]),
+ {B1,Bu,St2} = umatch(B0, Br, St1),
+ Used = union(Gu, Bu),
+ {#k_guard_clause{anno=#k{us=Used,ns=[],a=A},guard=G1,body=B1},Used,St2};
+umatch(B0, Br, St0) -> ubody(B0, Br, St0).
+
+umatch_list(Ms0, Br, St) ->
+ foldr(fun (M0, {Ms1,Us,Sta}) ->
+ {M1,Mu,Stb} = umatch(M0, Br, Sta),
+ {[M1|Ms1],union(Mu, Us),Stb}
+ end, {[],[],St}, Ms0).
+
+%% op_vars(Op) -> [VarName].
+
+op_vars(#k_local{}) -> [];
+op_vars(#k_remote{mod=Mod,name=Name}) ->
+ ordsets:from_list([V || #k_var{name=V} <- [Mod,Name]]);
+op_vars(#k_internal{}) -> [];
+op_vars(Atomic) -> lit_vars(Atomic).
+
+%% lit_vars(Literal) -> [VarName].
+%% Return the variables in a literal.
+
+lit_vars(#k_var{name=N}) -> [N];
+lit_vars(#k_int{}) -> [];
+lit_vars(#k_float{}) -> [];
+lit_vars(#k_atom{}) -> [];
+%%lit_vars(#k_char{}) -> [];
+lit_vars(#k_string{}) -> [];
+lit_vars(#k_nil{}) -> [];
+lit_vars(#k_cons{hd=H,tl=T}) ->
+ union(lit_vars(H), lit_vars(T));
+lit_vars(#k_binary{segs=V}) -> lit_vars(V);
+lit_vars(#k_bin_end{}) -> [];
+lit_vars(#k_bin_seg{size=Size,seg=S,next=N}) ->
+ union(lit_vars(Size), union(lit_vars(S), lit_vars(N)));
+lit_vars(#k_tuple{es=Es}) ->
+ lit_list_vars(Es).
+
+lit_list_vars(Ps) ->
+ foldl(fun (P, Vs) -> union(lit_vars(P), Vs) end, [], Ps).
+
+%% pat_vars(Pattern) -> {[UsedVarName],[NewVarName]}.
+%% Return variables in a pattern. All variables are new variables
+%% except those in the size field of binary segments.
+
+pat_vars(#k_var{name=N}) -> {[],[N]};
+%%pat_vars(#k_char{}) -> {[],[]};
+pat_vars(#k_int{}) -> {[],[]};
+pat_vars(#k_float{}) -> {[],[]};
+pat_vars(#k_atom{}) -> {[],[]};
+pat_vars(#k_string{}) -> {[],[]};
+pat_vars(#k_nil{}) -> {[],[]};
+pat_vars(#k_cons{hd=H,tl=T}) ->
+ pat_list_vars([H,T]);
+pat_vars(#k_binary{segs=V}) ->
+ pat_vars(V);
+pat_vars(#k_bin_seg{size=Size,seg=S,next=N}) ->
+ {U1,New} = pat_list_vars([S,N]),
+ {[],U2} = pat_vars(Size),
+ {union(U1, U2),New};
+pat_vars(#k_bin_end{}) -> {[],[]};
+pat_vars(#k_tuple{es=Es}) ->
+ pat_list_vars(Es).
+
+pat_list_vars(Ps) ->
+ foldl(fun (P, {Used0,New0}) ->
+ {Used,New} = pat_vars(P),
+ {union(Used0, Used),union(New0, New)} end,
+ {[],[]}, Ps).
+
+%% aligned(Bits, Size, Unit, Flags) -> {Size,Flags}
+%% Add 'aligned' to the flags if the current field is aligned.
+%% Number of bits correct modulo 8.
+
+aligned(B, S, U, Fs) when B rem 8 =:= 0 ->
+ {incr_bits(B, S, U),[aligned|Fs]};
+aligned(B, S, U, Fs) ->
+ {incr_bits(B, S, U),Fs}.
+
+incr_bits(B, #k_int{val=S}, U) when integer(B) -> B + S*U;
+incr_bits(_, #k_atom{val=all}, _) -> 0; %Always aligned
+incr_bits(B, _, 8) -> B;
+incr_bits(_, _, _) -> unknown.
+
+make_list(Es) ->
+ foldr(fun (E, Acc) -> #c_cons{hd=E,tl=Acc} end, #c_nil{}, Es).
+
+%% List of integers in interval [N,M]. Empty list if N > M.
+
+integers(N, M) when N =< M ->
+ [N|integers(N + 1, M)];
+integers(_, _) -> [].
+
+%%%
+%%% Handling of warnings.
+%%%
+
+format_error({nomatch_shadow,Line}) ->
+ M = io_lib:format("this clause cannot match because a previous clause at line ~p "
+ "always matches", [Line]),
+ lists:flatten(M);
+format_error(nomatch_shadow) ->
+ "this clause cannot match because a previous clause always matches".
+
+add_warning(none, Term, #kern{ws=Ws}=St) ->
+ St#kern{ws=[{?MODULE,Term}|Ws]};
+add_warning(Line, Term, #kern{ws=Ws}=St) when Line >= 0 ->
+ St#kern{ws=[{Line,?MODULE,Term}|Ws]};
+add_warning(_, _, St) -> St.
+
generated by cgit v1.2.3 (git 2.25.1) at 2024-07-09 06:44:09 +0000