%% ``Licensed under the Apache License, Version 2.0 (the "License"); %% you may not use this file except in compliance with the License. %% You may obtain a copy of the License at %% %% http://www.apache.org/licenses/LICENSE-2.0 %% %% Unless required by applicable law or agreed to in writing, software %% distributed under the License is distributed on an "AS IS" BASIS, %% WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied. %% See the License for the specific language governing permissions 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.'' %% %% $Id$ %% -module(erl_id_trans). %% An identity transformer of Erlang abstract syntax. %% This module only traverses legal Erlang code. This is most noticeable %% in guards where only a limited number of expressions are allowed. %% N.B. if this module is to be used as a basis for transforms then %% all the error cases must be handled otherwise this module just crashes! -export([parse_transform/2]). parse_transform(Forms, _Options) -> forms(Forms). %% forms(Fs) -> lists:map(fun (F) -> form(F) end, Fs). forms([F0|Fs0]) -> F1 = form(F0), Fs1 = forms(Fs0), [F1|Fs1]; forms([]) -> []. %% -type form(Form) -> Form. %% Here we show every known form and valid internal structure. We do not %% that the ordering is correct! %% First the various attributes. form({attribute,Line,module,Mod}) -> {attribute,Line,module,Mod}; form({attribute,Line,file,{File,Line}}) -> %This is valid anywhere. {attribute,Line,file,{File,Line}}; form({attribute,Line,export,Es0}) -> Es1 = farity_list(Es0), {attribute,Line,export,Es1}; form({attribute,Line,import,{Mod,Is0}}) -> Is1 = farity_list(Is0), {attribute,Line,import,{Mod,Is1}}; form({attribute,Line,export_type,Es0}) -> Es1 = farity_list(Es0), {attribute,Line,export_type,Es1}; form({attribute,Line,optional_callbacks,Es0}) -> try farity_list(Es0) of Es1 -> {attribute,Line,optional_callbacks,Es1} catch _:_ -> {attribute,Line,optional_callbacks,Es0} end; form({attribute,Line,compile,C}) -> {attribute,Line,compile,C}; form({attribute,Line,record,{Name,Defs0}}) -> Defs1 = record_defs(Defs0), {attribute,Line,record,{Name,Defs1}}; form({attribute,Line,asm,{function,N,A,Code}}) -> {attribute,Line,asm,{function,N,A,Code}}; form({attribute,Line,type,{N,T,Vs}}) -> T1 = type(T), Vs1 = variable_list(Vs), {attribute,Line,type,{N,T1,Vs1}}; form({attribute,Line,opaque,{N,T,Vs}}) -> T1 = type(T), Vs1 = variable_list(Vs), {attribute,Line,opaque,{N,T1,Vs1}}; form({attribute,Line,spec,{{N,A},FTs}}) -> FTs1 = function_type_list(FTs), {attribute,Line,spec,{{N,A},FTs1}}; form({attribute,Line,spec,{{M,N,A},FTs}}) -> FTs1 = function_type_list(FTs), {attribute,Line,spec,{{M,N,A},FTs1}}; form({attribute,Line,callback,{{N,A},FTs}}) -> FTs1 = function_type_list(FTs), {attribute,Line,callback,{{N,A},FTs1}}; form({attribute,Line,Attr,Val}) -> %The general attribute. {attribute,Line,Attr,Val}; form({function,Line,Name0,Arity0,Clauses0}) -> {Name,Arity,Clauses} = function(Name0, Arity0, Clauses0), {function,Line,Name,Arity,Clauses}; %% Extra forms from the parser. form({error,E}) -> {error,E}; form({warning,W}) -> {warning,W}; form({eof,Line}) -> {eof,Line}. %% -type farity_list([Farity]) -> [Farity] when Farity <= {atom(),integer()}. farity_list([{Name,Arity}|Fas]) -> [{Name,Arity}|farity_list(Fas)]; farity_list([]) -> []. %% -type variable_list([Var]) -> [Var] variable_list([{var,Line,Var}|Vs]) -> [{var,Line,Var}|variable_list(Vs)]; variable_list([]) -> []. %% -type record_defs([RecDef]) -> [RecDef]. %% N.B. Field names are full expressions here but only atoms are allowed %% by the *parser*! record_defs([{record_field,Line,{atom,La,A},Val0}|Is]) -> Val1 = expr(Val0), [{record_field,Line,{atom,La,A},Val1}|record_defs(Is)]; record_defs([{record_field,Line,{atom,La,A}}|Is]) -> [{record_field,Line,{atom,La,A}}|record_defs(Is)]; record_defs([{typed_record_field,{record_field,Line,{atom,La,A},Val0},Type}| Is]) -> Val1 = expr(Val0), Type1 = type(Type), [{typed_record_field,{record_field,Line,{atom,La,A},Val1},Type1}| record_defs(Is)]; record_defs([{typed_record_field,{record_field,Line,{atom,La,A}},Type}|Is]) -> Type1 = type(Type), [{typed_record_field,{record_field,Line,{atom,La,A}},Type1}| record_defs(Is)]; record_defs([]) -> []. %% -type function(atom(), integer(), [Clause]) -> {atom(),integer(),[Clause]}. function(Name, Arity, Clauses0) -> Clauses1 = clauses(Clauses0), {Name,Arity,Clauses1}. %% -type clauses([Clause]) -> [Clause]. clauses([C0|Cs]) -> C1 = clause(C0), [C1|clauses(Cs)]; clauses([]) -> []. %% -type clause(Clause) -> Clause. clause({clause,Line,H0,G0,B0}) -> H1 = head(H0), G1 = guard(G0), B1 = exprs(B0), {clause,Line,H1,G1,B1}. %% -type head([Pattern]) -> [Pattern]. head(Ps) -> patterns(Ps). %% -type patterns([Pattern]) -> [Pattern]. %% These patterns are processed "sequentially" for purposes of variable %% definition etc. patterns([P0|Ps]) -> P1 = pattern(P0), [P1|patterns(Ps)]; patterns([]) -> []. %% -type pattern(Pattern) -> Pattern. %% N.B. Only valid patterns are included here. pattern({var,Line,V}) -> {var,Line,V}; pattern({match,Line,L0,R0}) -> L1 = pattern(L0), R1 = pattern(R0), {match,Line,L1,R1}; pattern({integer,Line,I}) -> {integer,Line,I}; pattern({char,Line,C}) -> {char,Line,C}; pattern({float,Line,F}) -> {float,Line,F}; pattern({atom,Line,A}) -> {atom,Line,A}; pattern({string,Line,S}) -> {string,Line,S}; pattern({nil,Line}) -> {nil,Line}; pattern({cons,Line,H0,T0}) -> H1 = pattern(H0), T1 = pattern(T0), {cons,Line,H1,T1}; pattern({tuple,Line,Ps0}) -> Ps1 = pattern_list(Ps0), {tuple,Line,Ps1}; pattern({map,Line,Ps0}) -> Ps1 = pattern_list(Ps0), {map,Line,Ps1}; pattern({map_field_exact,Line,K,V}) -> Ke = expr(K), Ve = pattern(V), {map_field_exact,Line,Ke,Ve}; %%pattern({struct,Line,Tag,Ps0}) -> %% Ps1 = pattern_list(Ps0), %% {struct,Line,Tag,Ps1}; pattern({record,Line,Name,Pfs0}) -> Pfs1 = pattern_fields(Pfs0), {record,Line,Name,Pfs1}; pattern({record_index,Line,Name,Field0}) -> Field1 = pattern(Field0), {record_index,Line,Name,Field1}; pattern({record_field,Line,Rec0,Name,Field0}) -> Rec1 = expr(Rec0), Field1 = expr(Field0), {record_field,Line,Rec1,Name,Field1}; pattern({record_field,Line,Rec0,Field0}) -> Rec1 = expr(Rec0), Field1 = expr(Field0), {record_field,Line,Rec1,Field1}; pattern({bin,Line,Fs}) -> Fs2 = pattern_grp(Fs), {bin,Line,Fs2}; pattern({op,Line,Op,A}) -> {op,Line,Op,A}; pattern({op,Line,Op,L,R}) -> {op,Line,Op,L,R}. pattern_grp([{bin_element,L1,E1,S1,T1} | Fs]) -> S2 = case S1 of default -> default; _ -> expr(S1) end, T2 = case T1 of default -> default; _ -> bit_types(T1) end, [{bin_element,L1,expr(E1),S2,T2} | pattern_grp(Fs)]; pattern_grp([]) -> []. bit_types([]) -> []; bit_types([Atom | Rest]) when is_atom(Atom) -> [Atom | bit_types(Rest)]; bit_types([{Atom, Integer} | Rest]) when is_atom(Atom), is_integer(Integer) -> [{Atom, Integer} | bit_types(Rest)]. %% -type pattern_list([Pattern]) -> [Pattern]. %% These patterns are processed "in parallel" for purposes of variable %% definition etc. pattern_list([P0|Ps]) -> P1 = pattern(P0), [P1|pattern_list(Ps)]; pattern_list([]) -> []. %% -type pattern_fields([Field]) -> [Field]. %% N.B. Field names are full expressions here but only atoms are allowed %% by the *linter*!. pattern_fields([{record_field,Lf,{atom,La,F},P0}|Pfs]) -> P1 = pattern(P0), [{record_field,Lf,{atom,La,F},P1}|pattern_fields(Pfs)]; pattern_fields([{record_field,Lf,{var,La,'_'},P0}|Pfs]) -> P1 = pattern(P0), [{record_field,Lf,{var,La,'_'},P1}|pattern_fields(Pfs)]; pattern_fields([]) -> []. %% -type guard([GuardTest]) -> [GuardTest]. guard([G0|Gs]) when is_list(G0) -> [guard0(G0) | guard(Gs)]; guard(L) -> guard0(L). guard0([G0|Gs]) -> G1 = guard_test(G0), [G1|guard0(Gs)]; guard0([]) -> []. guard_test(Expr={call,Line,{atom,La,F},As0}) -> case erl_internal:type_test(F, length(As0)) of true -> As1 = gexpr_list(As0), {call,Line,{atom,La,F},As1}; _ -> gexpr(Expr) end; guard_test(Any) -> gexpr(Any). %% Before R9, there were special rules regarding the expressions on %% top level in guards. Those limitations are now lifted - therefore %% there is no need for a special clause for the toplevel expressions. %% -type gexpr(GuardExpr) -> GuardExpr. gexpr({var,Line,V}) -> {var,Line,V}; gexpr({integer,Line,I}) -> {integer,Line,I}; gexpr({char,Line,C}) -> {char,Line,C}; gexpr({float,Line,F}) -> {float,Line,F}; gexpr({atom,Line,A}) -> {atom,Line,A}; gexpr({string,Line,S}) -> {string,Line,S}; gexpr({nil,Line}) -> {nil,Line}; gexpr({map,Line,Map0,Es0}) -> [Map1|Es1] = gexpr_list([Map0|Es0]), {map,Line,Map1,Es1}; gexpr({map,Line,Es0}) -> Es1 = gexpr_list(Es0), {map,Line,Es1}; gexpr({map_field_assoc,Line,K,V}) -> Ke = gexpr(K), Ve = gexpr(V), {map_field_assoc,Line,Ke,Ve}; gexpr({map_field_exact,Line,K,V}) -> Ke = gexpr(K), Ve = gexpr(V), {map_field_exact,Line,Ke,Ve}; gexpr({cons,Line,H0,T0}) -> H1 = gexpr(H0), T1 = gexpr(T0), %They see the same variables {cons,Line,H1,T1}; gexpr({tuple,Line,Es0}) -> Es1 = gexpr_list(Es0), {tuple,Line,Es1}; gexpr({record_index,Line,Name,Field0}) -> Field1 = gexpr(Field0), {record_index,Line,Name,Field1}; gexpr({record_field,Line,Rec0,Name,Field0}) -> Rec1 = gexpr(Rec0), Field1 = gexpr(Field0), {record_field,Line,Rec1,Name,Field1}; gexpr({record,Line,Name,Inits0}) -> Inits1 = grecord_inits(Inits0), {record,Line,Name,Inits1}; gexpr({call,Line,{atom,La,F},As0}) -> case erl_internal:guard_bif(F, length(As0)) of true -> As1 = gexpr_list(As0), {call,Line,{atom,La,F},As1} end; % Guard bif's can be remote, but only in the module erlang... gexpr({call,Line,{remote,La,{atom,Lb,erlang},{atom,Lc,F}},As0}) -> case erl_internal:guard_bif(F, length(As0)) or erl_internal:arith_op(F, length(As0)) or erl_internal:comp_op(F, length(As0)) or erl_internal:bool_op(F, length(As0)) of true -> As1 = gexpr_list(As0), {call,Line,{remote,La,{atom,Lb,erlang},{atom,Lc,F}},As1} end; gexpr({bin,Line,Fs}) -> Fs2 = pattern_grp(Fs), {bin,Line,Fs2}; gexpr({op,Line,Op,A0}) -> case erl_internal:arith_op(Op, 1) or erl_internal:bool_op(Op, 1) of true -> A1 = gexpr(A0), {op,Line,Op,A1} end; gexpr({op,Line,Op,L0,R0}) when Op =:= 'andalso'; Op =:= 'orelse' -> %% R11B: andalso/orelse are now allowed in guards. L1 = gexpr(L0), R1 = gexpr(R0), %They see the same variables {op,Line,Op,L1,R1}; gexpr({op,Line,Op,L0,R0}) -> case erl_internal:arith_op(Op, 2) or erl_internal:bool_op(Op, 2) or erl_internal:comp_op(Op, 2) of true -> L1 = gexpr(L0), R1 = gexpr(R0), %They see the same variables {op,Line,Op,L1,R1} end. %% -type gexpr_list([GuardExpr]) -> [GuardExpr]. %% These expressions are processed "in parallel" for purposes of variable %% definition etc. gexpr_list([E0|Es]) -> E1 = gexpr(E0), [E1|gexpr_list(Es)]; gexpr_list([]) -> []. grecord_inits([{record_field,Lf,{atom,La,F},Val0}|Is]) -> Val1 = gexpr(Val0), [{record_field,Lf,{atom,La,F},Val1}|grecord_inits(Is)]; grecord_inits([{record_field,Lf,{var,La,'_'},Val0}|Is]) -> Val1 = gexpr(Val0), [{record_field,Lf,{var,La,'_'},Val1}|grecord_inits(Is)]; grecord_inits([]) -> []. %% -type exprs([Expression]) -> [Expression]. %% These expressions are processed "sequentially" for purposes of variable %% definition etc. exprs([E0|Es]) -> E1 = expr(E0), [E1|exprs(Es)]; exprs([]) -> []. %% -type expr(Expression) -> Expression. expr({var,Line,V}) -> {var,Line,V}; expr({integer,Line,I}) -> {integer,Line,I}; expr({float,Line,F}) -> {float,Line,F}; expr({atom,Line,A}) -> {atom,Line,A}; expr({string,Line,S}) -> {string,Line,S}; expr({char,Line,C}) -> {char,Line,C}; expr({nil,Line}) -> {nil,Line}; expr({cons,Line,H0,T0}) -> H1 = expr(H0), T1 = expr(T0), %They see the same variables {cons,Line,H1,T1}; expr({lc,Line,E0,Qs0}) -> Qs1 = lc_bc_quals(Qs0), E1 = expr(E0), {lc,Line,E1,Qs1}; expr({bc,Line,E0,Qs0}) -> Qs1 = lc_bc_quals(Qs0), E1 = expr(E0), {bc,Line,E1,Qs1}; expr({tuple,Line,Es0}) -> Es1 = expr_list(Es0), {tuple,Line,Es1}; expr({map,Line,Map0,Es0}) -> [Map1|Es1] = exprs([Map0|Es0]), {map,Line,Map1,Es1}; expr({map,Line,Es0}) -> Es1 = exprs(Es0), {map,Line,Es1}; expr({map_field_assoc,Line,K,V}) -> Ke = expr(K), Ve = expr(V), {map_field_assoc,Line,Ke,Ve}; expr({map_field_exact,Line,K,V}) -> Ke = expr(K), Ve = expr(V), {map_field_exact,Line,Ke,Ve}; %%expr({struct,Line,Tag,Es0}) -> %% Es1 = pattern_list(Es0), %% {struct,Line,Tag,Es1}; expr({record_index,Line,Name,Field0}) -> Field1 = expr(Field0), {record_index,Line,Name,Field1}; expr({record,Line,Name,Inits0}) -> Inits1 = record_inits(Inits0), {record,Line,Name,Inits1}; expr({record_field,Line,Rec0,Name,Field0}) -> Rec1 = expr(Rec0), Field1 = expr(Field0), {record_field,Line,Rec1,Name,Field1}; expr({record,Line,Rec0,Name,Upds0}) -> Rec1 = expr(Rec0), Upds1 = record_updates(Upds0), {record,Line,Rec1,Name,Upds1}; expr({record_field,Line,Rec0,Field0}) -> Rec1 = expr(Rec0), Field1 = expr(Field0), {record_field,Line,Rec1,Field1}; expr({block,Line,Es0}) -> %% Unfold block into a sequence. Es1 = exprs(Es0), {block,Line,Es1}; expr({'if',Line,Cs0}) -> Cs1 = icr_clauses(Cs0), {'if',Line,Cs1}; expr({'case',Line,E0,Cs0}) -> E1 = expr(E0), Cs1 = icr_clauses(Cs0), {'case',Line,E1,Cs1}; expr({'receive',Line,Cs0}) -> Cs1 = icr_clauses(Cs0), {'receive',Line,Cs1}; expr({'receive',Line,Cs0,To0,ToEs0}) -> To1 = expr(To0), ToEs1 = exprs(ToEs0), Cs1 = icr_clauses(Cs0), {'receive',Line,Cs1,To1,ToEs1}; expr({'try',Line,Es0,Scs0,Ccs0,As0}) -> Es1 = exprs(Es0), Scs1 = icr_clauses(Scs0), Ccs1 = icr_clauses(Ccs0), As1 = exprs(As0), {'try',Line,Es1,Scs1,Ccs1,As1}; expr({'fun',Line,Body}) -> case Body of {clauses,Cs0} -> Cs1 = fun_clauses(Cs0), {'fun',Line,{clauses,Cs1}}; {function,F,A} -> {'fun',Line,{function,F,A}}; {function,M,F,A} when is_atom(M), is_atom(F), is_integer(A) -> %% R10B-6: fun M:F/A. (Backward compatibility) {'fun',Line,{function,M,F,A}}; {function,M0,F0,A0} -> %% R15: fun M:F/A with variables. M = expr(M0), F = expr(F0), A = expr(A0), {'fun',Line,{function,M,F,A}} end; expr({named_fun,Loc,Name,Cs}) -> {named_fun,Loc,Name,fun_clauses(Cs)}; expr({call,Line,F0,As0}) -> %% N.B. If F an atom then call to local function or BIF, if F a %% remote structure (see below) then call to other module, %% otherwise apply to "function". F1 = expr(F0), As1 = expr_list(As0), {call,Line,F1,As1}; expr({'catch',Line,E0}) -> %% No new variables added. E1 = expr(E0), {'catch',Line,E1}; expr({match,Line,P0,E0}) -> E1 = expr(E0), P1 = pattern(P0), {match,Line,P1,E1}; expr({bin,Line,Fs}) -> Fs2 = pattern_grp(Fs), {bin,Line,Fs2}; expr({op,Line,Op,A0}) -> A1 = expr(A0), {op,Line,Op,A1}; expr({op,Line,Op,L0,R0}) -> L1 = expr(L0), R1 = expr(R0), %They see the same variables {op,Line,Op,L1,R1}; %% The following are not allowed to occur anywhere! expr({remote,Line,M0,F0}) -> M1 = expr(M0), F1 = expr(F0), {remote,Line,M1,F1}. %% -type expr_list([Expression]) -> [Expression]. %% These expressions are processed "in parallel" for purposes of variable %% definition etc. expr_list([E0|Es]) -> E1 = expr(E0), [E1|expr_list(Es)]; expr_list([]) -> []. %% -type record_inits([RecordInit]) -> [RecordInit]. %% N.B. Field names are full expressions here but only atoms are allowed %% by the *linter*!. record_inits([{record_field,Lf,{atom,La,F},Val0}|Is]) -> Val1 = expr(Val0), [{record_field,Lf,{atom,La,F},Val1}|record_inits(Is)]; record_inits([{record_field,Lf,{var,La,'_'},Val0}|Is]) -> Val1 = expr(Val0), [{record_field,Lf,{var,La,'_'},Val1}|record_inits(Is)]; record_inits([]) -> []. %% -type record_updates([RecordUpd]) -> [RecordUpd]. %% N.B. Field names are full expressions here but only atoms are allowed %% by the *linter*!. record_updates([{record_field,Lf,{atom,La,F},Val0}|Us]) -> Val1 = expr(Val0), [{record_field,Lf,{atom,La,F},Val1}|record_updates(Us)]; record_updates([]) -> []. %% -type icr_clauses([Clause]) -> [Clause]. icr_clauses([C0|Cs]) -> C1 = clause(C0), [C1|icr_clauses(Cs)]; icr_clauses([]) -> []. %% -type lc_bc_quals([Qualifier]) -> [Qualifier]. %% Allow filters to be both guard tests and general expressions. lc_bc_quals([{generate,Line,P0,E0}|Qs]) -> E1 = expr(E0), P1 = pattern(P0), [{generate,Line,P1,E1}|lc_bc_quals(Qs)]; lc_bc_quals([{b_generate,Line,P0,E0}|Qs]) -> E1 = expr(E0), P1 = pattern(P0), [{b_generate,Line,P1,E1}|lc_bc_quals(Qs)]; lc_bc_quals([E0|Qs]) -> E1 = expr(E0), [E1|lc_bc_quals(Qs)]; lc_bc_quals([]) -> []. %% -type fun_clauses([Clause]) -> [Clause]. fun_clauses([C0|Cs]) -> C1 = clause(C0), [C1|fun_clauses(Cs)]; fun_clauses([]) -> []. function_type_list([{type,Line,bounded_fun,[Ft,Fc]}|Fts]) -> Ft1 = function_type(Ft), Fc1 = function_constraint(Fc), [{type,Line,bounded_fun,[Ft1,Fc1]}|function_type_list(Fts)]; function_type_list([Ft|Fts]) -> [function_type(Ft)|function_type_list(Fts)]; function_type_list([]) -> []. function_type({type,Line,'fun',[{type,Lt,product,As},B]}) -> As1 = type_list(As), B1 = type(B), {type,Line,'fun',[{type,Lt,product,As1},B1]}. function_constraint([C|Cs]) -> C1 = constraint(C), [C1|function_constraint(Cs)]; function_constraint([]) -> []. constraint({type,Line,constraint,[{atom,L,A},[V,T]]}) -> V1 = type(V), T1 = type(T), {type,Line,constraint,[{atom,L,A},[V1,T1]]}. type({ann_type,Line,[{var,Lv,V},T]}) -> T1 = type(T), {ann_type,Line,[{var,Lv,V},T1]}; type({atom,Line,A}) -> {atom,Line,A}; type({integer,Line,I}) -> {integer,Line,I}; type({op,Line,Op,T}) -> T1 = type(T), {op,Line,Op,T1}; type({op,Line,Op,L,R}) -> L1 = type(L), R1 = type(R), {op,Line,Op,L1,R1}; type({type,Line,binary,[M,N]}) -> M1 = type(M), N1 = type(N), {type,Line,binary,[M1,N1]}; type({type,Line,'fun',[]}) -> {type,Line,'fun',[]}; type({type,Line,'fun',[{type,Lt,any},B]}) -> B1 = type(B), {type,Line,'fun',[{type,Lt,any},B1]}; type({type,Line,range,[L,H]}) -> L1 = type(L), H1 = type(H), {type,Line,range,[L1,H1]}; type({type,Line,map,any}) -> {type,Line,map,any}; type({type,Line,map,Ps}) -> Ps1 = map_pair_types(Ps), {type,Line,map,Ps1}; type({type,Line,record,[{atom,La,N}|Fs]}) -> Fs1 = field_types(Fs), {type,Line,record,[{atom,La,N}|Fs1]}; type({remote_type,Line,[{atom,Lm,M},{atom,Ln,N},As]}) -> As1 = type_list(As), {remote_type,Line,[{atom,Lm,M},{atom,Ln,N},As1]}; type({type,Line,tuple,any}) -> {type,Line,tuple,any}; type({type,Line,tuple,Ts}) -> Ts1 = type_list(Ts), {type,Line,tuple,Ts1}; type({type,Line,union,Ts}) -> Ts1 = type_list(Ts), {type,Line,union,Ts1}; type({var,Line,V}) -> {var,Line,V}; type({user_type,Line,N,As}) -> As1 = type_list(As), {user_type,Line,N,As1}; type({type,Line,N,As}) -> As1 = type_list(As), {type,Line,N,As1}. map_pair_types([{type,Line,map_field_assoc,[K,V]}|Ps]) -> K1 = type(K), V1 = type(V), [{type,Line,map_field_assoc,[K1,V1]}|map_pair_types(Ps)]; map_pair_types([{type,Line,map_field_exact,[K,V]}|Ps]) -> K1 = type(K), V1 = type(V), [{type,Line,map_field_exact,[K1,V1]}|map_pair_types(Ps)]; map_pair_types([]) -> []. field_types([{type,Line,field_type,[{atom,La,A},T]}|Fs]) -> T1 = type(T), [{type,Line,field_type,[{atom,La,A},T1]}|field_types(Fs)]; field_types([]) -> []. type_list([T|Ts]) -> T1 = type(T), [T1|type_list(Ts)]; type_list([]) -> [].