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Diffstat (limited to 'lib/dialyzer/test/options1_tests_SUITE_data/src/compiler/core_lib.erl')
-rw-r--r-- | lib/dialyzer/test/options1_tests_SUITE_data/src/compiler/core_lib.erl | 509 |
1 files changed, 0 insertions, 509 deletions
diff --git a/lib/dialyzer/test/options1_tests_SUITE_data/src/compiler/core_lib.erl b/lib/dialyzer/test/options1_tests_SUITE_data/src/compiler/core_lib.erl deleted file mode 100644 index 3a6158286f..0000000000 --- a/lib/dialyzer/test/options1_tests_SUITE_data/src/compiler/core_lib.erl +++ /dev/null @@ -1,509 +0,0 @@ -%% ``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: core_lib.erl,v 1.1 2008/12/17 09:53:42 mikpe Exp $ -%% -%% Purpose: Core Erlang abstract syntax functions. - --module(core_lib). - --export([get_anno/1,set_anno/2]). --export([is_atomic/1,is_literal/1,is_literal_list/1, - is_simple/1,is_simple_list/1,is_simple_top/1]). --export([literal_value/1,make_literal/1]). --export([make_values/1]). --export([map/2, fold/3, mapfold/3]). --export([is_var_used/2]). - -%% -compile([export_all]). - --include("core_parse.hrl"). - -%% get_anno(Core) -> Anno. -%% set_anno(Core, Anno) -> Core. -%% Generic get/set annotation. - -get_anno(C) -> element(2, C). -set_anno(C, A) -> setelement(2, C, A). - -%% is_atomic(Expr) -> true | false. - -is_atomic(#c_char{}) -> true; -is_atomic(#c_int{}) -> true; -is_atomic(#c_float{}) -> true; -is_atomic(#c_atom{}) -> true; -is_atomic(#c_string{}) -> true; -is_atomic(#c_nil{}) -> true; -is_atomic(#c_fname{}) -> true; -is_atomic(_) -> false. - -%% is_literal(Expr) -> true | false. - -is_literal(#c_cons{hd=H,tl=T}) -> - case is_literal(H) of - true -> is_literal(T); - false -> false - end; -is_literal(#c_tuple{es=Es}) -> is_literal_list(Es); -is_literal(#c_binary{segments=Es}) -> is_lit_bin(Es); -is_literal(E) -> is_atomic(E). - -is_literal_list(Es) -> lists:all(fun is_literal/1, Es). - -is_lit_bin(Es) -> - lists:all(fun (#c_bitstr{val=E,size=S}) -> - is_literal(E) and is_literal(S) - end, Es). - -%% is_simple(Expr) -> true | false. - -is_simple(#c_var{}) -> true; -is_simple(#c_cons{hd=H,tl=T}) -> - case is_simple(H) of - true -> is_simple(T); - false -> false - end; -is_simple(#c_tuple{es=Es}) -> is_simple_list(Es); -is_simple(#c_binary{segments=Es}) -> is_simp_bin(Es); -is_simple(E) -> is_atomic(E). - -is_simple_list(Es) -> lists:all(fun is_simple/1, Es). - -is_simp_bin(Es) -> - lists:all(fun (#c_bitstr{val=E,size=S}) -> - is_simple(E) and is_simple(S) - end, Es). - -%% is_simple_top(Expr) -> true | false. -%% Only check if the top-level is a simple. - -is_simple_top(#c_var{}) -> true; -is_simple_top(#c_cons{}) -> true; -is_simple_top(#c_tuple{}) -> true; -is_simple_top(#c_binary{}) -> true; -is_simple_top(E) -> is_atomic(E). - -%% literal_value(LitExpr) -> Value. -%% Return the value of LitExpr. - -literal_value(#c_char{val=C}) -> C; -literal_value(#c_int{val=I}) -> I; -literal_value(#c_float{val=F}) -> F; -literal_value(#c_atom{val=A}) -> A; -literal_value(#c_string{val=S}) -> S; -literal_value(#c_nil{}) -> []; -literal_value(#c_cons{hd=H,tl=T}) -> - [literal_value(H)|literal_value(T)]; -literal_value(#c_tuple{es=Es}) -> - list_to_tuple(literal_value_list(Es)). - -literal_value_list(Vals) -> lists:map(fun literal_value/1, Vals). - -%% make_literal(Value) -> LitExpr. -%% Make a literal expression from an Erlang value. - -make_literal(I) when integer(I) -> #c_int{val=I}; -make_literal(F) when float(F) -> #c_float{val=F}; -make_literal(A) when atom(A) -> #c_atom{val=A}; -make_literal([]) -> #c_nil{}; -make_literal([H|T]) -> - #c_cons{hd=make_literal(H),tl=make_literal(T)}; -make_literal(T) when tuple(T) -> - #c_tuple{es=make_literal_list(tuple_to_list(T))}. - -make_literal_list(Vals) -> lists:map(fun make_literal/1, Vals). - -%% make_values([CoreExpr] | CoreExpr) -> #c_values{} | CoreExpr. -%% Make a suitable values structure, expr or values, depending on -%% Expr. - -make_values([E]) -> E; -make_values([H|_]=Es) -> #c_values{anno=get_anno(H),es=Es}; -make_values([]) -> #c_values{es=[]}; -make_values(E) -> E. - -%% map(MapFun, CoreExpr) -> CoreExpr. -%% This function traverses the core parse format, at each level -%% applying the submited argument function, assumed to do the real -%% work. -%% -%% The "eager" style, where each component of a construct are -%% descended to before the construct itself, admits that some -%% companion functions (the F:s) may be made simpler, since it may be -%% safely assumed that no lower illegal instanced will be -%% created/uncovered by actions on the current level. - -map(F, #c_tuple{es=Es}=R) -> - F(R#c_tuple{es=map_list(F, Es)}); -map(F, #c_cons{hd=Hd, tl=Tl}=R) -> - F(R#c_cons{hd=map(F, Hd), - tl=map(F, Tl)}); -map(F, #c_values{es=Es}=R) -> - F(R#c_values{es=map_list(F, Es)}); - -map(F, #c_alias{var=Var, pat=Pat}=R) -> - F(R#c_alias{var=map(F, Var), - pat=map(F, Pat)}); - -map(F, #c_module{defs=Defs}=R) -> - F(R#c_module{defs=map_list(F, Defs)}); -map(F, #c_def{val=Val}=R) -> - F(R#c_def{val=map(F, Val)}); - -map(F, #c_fun{vars=Vars, body=Body}=R) -> - F(R#c_fun{vars=map_list(F, Vars), - body=map(F, Body)}); -map(F, #c_let{vars=Vs, arg=Arg, body=Body}=R) -> - F(R#c_let{vars=map_list(F, Vs), - arg=map(F, Arg), - body=map(F, Body)}); -map(F, #c_letrec{defs=Fs,body=Body}=R) -> - F(R#c_letrec{defs=map_list(F, Fs), - body=map(F, Body)}); -map(F, #c_seq{arg=Arg, body=Body}=R) -> - F(R#c_seq{arg=map(F, Arg), - body=map(F, Body)}); -map(F, #c_case{arg=Arg, clauses=Clauses}=R) -> - F(R#c_case{arg=map(F, Arg), - clauses=map_list(F, Clauses)}); -map(F, #c_clause{pats=Ps, guard=Guard, body=Body}=R) -> - F(R#c_clause{pats=map_list(F, Ps), - guard=map(F, Guard), - body=map(F, Body)}); -map(F, #c_receive{clauses=Cls, timeout=Tout, action=Act}=R) -> - F(R#c_receive{clauses=map_list(F, Cls), - timeout=map(F, Tout), - action=map(F, Act)}); -map(F, #c_apply{op=Op,args=Args}=R) -> - F(R#c_apply{op=map(F, Op), - args=map_list(F, Args)}); -map(F, #c_call{module=M,name=N,args=Args}=R) -> - F(R#c_call{module=map(F, M), - name=map(F, N), - args=map_list(F, Args)}); -map(F, #c_primop{name=N,args=Args}=R) -> - F(R#c_primop{name=map(F, N), - args=map_list(F, Args)}); -map(F, #c_try{arg=Expr,vars=Vars,body=Body,evars=Evars,handler=Handler}=R) -> - F(R#c_try{arg=map(F, Expr), - vars=map(F, Vars), - body=map(F, Body), - evars=map(F, Evars), - handler=map(F, Handler)}); -map(F, #c_catch{body=Body}=R) -> - F(R#c_catch{body=map(F, Body)}); -map(F, T) -> F(T). %Atomic nodes. - -map_list(F, L) -> lists:map(fun (E) -> map(F, E) end, L). - -%% fold(FoldFun, Accumulator, CoreExpr) -> Accumulator. -%% This function traverses the core parse format, at each level -%% applying the submited argument function, assumed to do the real -%% work, and keeping the accumulated result in the A (accumulator) -%% argument. - -fold(F, Acc, #c_tuple{es=Es}=R) -> - F(R, fold_list(F, Acc, Es)); -fold(F, Acc, #c_cons{hd=Hd, tl=Tl}=R) -> - F(R, fold(F, fold(F, Acc, Hd), Tl)); -fold(F, Acc, #c_values{es=Es}=R) -> - F(R, fold_list(F, Acc, Es)); - -fold(F, Acc, #c_alias{pat=P,var=V}=R) -> - F(R, fold(F, fold(F, Acc, P), V)); - -fold(F, Acc, #c_module{defs=Defs}=R) -> - F(R, fold_list(F, Acc, Defs)); -fold(F, Acc, #c_def{val=Val}=R) -> - F(R, fold(F, Acc, Val)); - -fold(F, Acc, #c_fun{vars=Vars, body=Body}=R) -> - F(R, fold(F, fold_list(F, Acc, Vars), Body)); -fold(F, Acc, #c_let{vars=Vs, arg=Arg, body=Body}=R) -> - F(R, fold(F, fold(F, fold_list(F, Acc, Vs), Arg), Body)); -fold(F, Acc, #c_letrec{defs=Fs,body=Body}=R) -> - F(R, fold(F, fold_list(F, Acc, Fs), Body)); -fold(F, Acc, #c_seq{arg=Arg, body=Body}=R) -> - F(R, fold(F, fold(F, Acc, Arg), Body)); -fold(F, Acc, #c_case{arg=Arg, clauses=Clauses}=R) -> - F(R, fold_list(F, fold(F, Acc, Arg), Clauses)); -fold(F, Acc, #c_clause{pats=Ps,guard=G,body=B}=R) -> - F(R, fold(F, fold(F, fold_list(F, Acc, Ps), G), B)); -fold(F, Acc, #c_receive{clauses=Cl, timeout=Ti, action=Ac}=R) -> - F(R, fold_list(F, fold(F, fold(F, Acc, Ac), Ti), Cl)); -fold(F, Acc, #c_apply{op=Op, args=Args}=R) -> - F(R, fold_list(F, fold(F, Acc, Op), Args)); -fold(F, Acc, #c_call{module=Mod,name=Name,args=Args}=R) -> - F(R, fold_list(F, fold(F, fold(F, Acc, Mod), Name), Args)); -fold(F, Acc, #c_primop{name=Name,args=Args}=R) -> - F(R, fold_list(F, fold(F, Acc, Name), Args)); -fold(F, Acc, #c_try{arg=E,vars=Vs,body=Body,evars=Evs,handler=H}=R) -> - NewB = fold(F, fold_list(F, fold(F, Acc, E), Vs), Body), - F(R, fold(F, fold_list(F, NewB, Evs), H)); -fold(F, Acc, #c_catch{body=Body}=R) -> - F(R, fold(F, Acc, Body)); -fold(F, Acc, T) -> %Atomic nodes - F(T, Acc). - -fold_list(F, Acc, L) -> - lists:foldl(fun (E, A) -> fold(F, A, E) end, Acc, L). - -%% mapfold(MapfoldFun, Accumulator, CoreExpr) -> {CoreExpr,Accumulator}. -%% This function traverses the core parse format, at each level -%% applying the submited argument function, assumed to do the real -%% work, and keeping the accumulated result in the A (accumulator) -%% argument. - -mapfold(F, Acc0, #c_tuple{es=Es0}=R) -> - {Es1,Acc1} = mapfold_list(F, Acc0, Es0), - F(R#c_tuple{es=Es1}, Acc1); -mapfold(F, Acc0, #c_cons{hd=H0,tl=T0}=R) -> - {H1,Acc1} = mapfold(F, Acc0, H0), - {T1,Acc2} = mapfold(F, Acc1, T0), - F(R#c_cons{hd=H1,tl=T1}, Acc2); -mapfold(F, Acc0, #c_values{es=Es0}=R) -> - {Es1,Acc1} = mapfold_list(F, Acc0, Es0), - F(R#c_values{es=Es1}, Acc1); - -mapfold(F, Acc0, #c_alias{pat=P0,var=V0}=R) -> - {P1,Acc1} = mapfold(F, Acc0, P0), - {V1,Acc2} = mapfold(F, Acc1, V0), - F(R#c_alias{pat=P1,var=V1}, Acc2); - -mapfold(F, Acc0, #c_module{defs=D0}=R) -> - {D1,Acc1} = mapfold_list(F, Acc0, D0), - F(R#c_module{defs=D1}, Acc1); -mapfold(F, Acc0, #c_def{val=V0}=R) -> - {V1,Acc1} = mapfold(F, Acc0, V0), - F(R#c_def{val=V1}, Acc1); - -mapfold(F, Acc0, #c_fun{vars=Vs0, body=B0}=R) -> - {Vs1,Acc1} = mapfold_list(F, Acc0, Vs0), - {B1,Acc2} = mapfold(F, Acc1, B0), - F(R#c_fun{vars=Vs1,body=B1}, Acc2); -mapfold(F, Acc0, #c_let{vars=Vs0, arg=A0, body=B0}=R) -> - {Vs1,Acc1} = mapfold_list(F, Acc0, Vs0), - {A1,Acc2} = mapfold(F, Acc1, A0), - {B1,Acc3} = mapfold(F, Acc2, B0), - F(R#c_let{vars=Vs1,arg=A1,body=B1}, Acc3); -mapfold(F, Acc0, #c_letrec{defs=Fs0,body=B0}=R) -> - {Fs1,Acc1} = mapfold_list(F, Acc0, Fs0), - {B1,Acc2} = mapfold(F, Acc1, B0), - F(R#c_letrec{defs=Fs1,body=B1}, Acc2); -mapfold(F, Acc0, #c_seq{arg=A0, body=B0}=R) -> - {A1,Acc1} = mapfold(F, Acc0, A0), - {B1,Acc2} = mapfold(F, Acc1, B0), - F(R#c_seq{arg=A1,body=B1}, Acc2); -mapfold(F, Acc0, #c_case{arg=A0,clauses=Cs0}=R) -> - {A1,Acc1} = mapfold(F, Acc0, A0), - {Cs1,Acc2} = mapfold_list(F, Acc1, Cs0), - F(R#c_case{arg=A1,clauses=Cs1}, Acc2); -mapfold(F, Acc0, #c_clause{pats=Ps0,guard=G0,body=B0}=R) -> - {Ps1,Acc1} = mapfold_list(F, Acc0, Ps0), - {G1,Acc2} = mapfold(F, Acc1, G0), - {B1,Acc3} = mapfold(F, Acc2, B0), - F(R#c_clause{pats=Ps1,guard=G1,body=B1}, Acc3); -mapfold(F, Acc0, #c_receive{clauses=Cs0,timeout=T0,action=A0}=R) -> - {T1,Acc1} = mapfold(F, Acc0, T0), - {Cs1,Acc2} = mapfold_list(F, Acc1, Cs0), - {A1,Acc3} = mapfold(F, Acc2, A0), - F(R#c_receive{clauses=Cs1,timeout=T1,action=A1}, Acc3); -mapfold(F, Acc0, #c_apply{op=Op0, args=As0}=R) -> - {Op1,Acc1} = mapfold(F, Acc0, Op0), - {As1,Acc2} = mapfold_list(F, Acc1, As0), - F(R#c_apply{op=Op1,args=As1}, Acc2); -mapfold(F, Acc0, #c_call{module=M0,name=N0,args=As0}=R) -> - {M1,Acc1} = mapfold(F, Acc0, M0), - {N1,Acc2} = mapfold(F, Acc1, N0), - {As1,Acc3} = mapfold_list(F, Acc2, As0), - F(R#c_call{module=M1,name=N1,args=As1}, Acc3); -mapfold(F, Acc0, #c_primop{name=N0, args=As0}=R) -> - {N1,Acc1} = mapfold(F, Acc0, N0), - {As1,Acc2} = mapfold_list(F, Acc1, As0), - F(R#c_primop{name=N1,args=As1}, Acc2); -mapfold(F, Acc0, #c_try{arg=E0,vars=Vs0,body=B0,evars=Evs0,handler=H0}=R) -> - {E1,Acc1} = mapfold(F, Acc0, E0), - {Vs1,Acc2} = mapfold_list(F, Acc1, Vs0), - {B1,Acc3} = mapfold(F, Acc2, B0), - {Evs1,Acc4} = mapfold_list(F, Acc3, Evs0), - {H1,Acc5} = mapfold(F, Acc4, H0), - F(R#c_try{arg=E1,vars=Vs1,body=B1,evars=Evs1,handler=H1}, Acc5); -mapfold(F, Acc0, #c_catch{body=B0}=R) -> - {B1,Acc1} = mapfold(F, Acc0, B0), - F(R#c_catch{body=B1}, Acc1); -mapfold(F, Acc, T) -> %Atomic nodes - F(T, Acc). - -mapfold_list(F, Acc, L) -> - lists:mapfoldl(fun (E, A) -> mapfold(F, A, E) end, Acc, L). - -%% is_var_used(VarName, Expr) -> true | false. -%% Test if the variable VarName is used in Expr. - -is_var_used(V, B) -> vu_body(V, B). - -vu_body(V, #c_values{es=Es}) -> - vu_expr_list(V, Es); -vu_body(V, Body) -> - vu_expr(V, Body). - -vu_expr(V, #c_var{name=V2}) -> V =:= V2; -vu_expr(V, #c_cons{hd=H,tl=T}) -> - case vu_expr(V, H) of - true -> true; - false -> vu_expr(V, T) - end; -vu_expr(V, #c_tuple{es=Es}) -> - vu_expr_list(V, Es); -vu_expr(V, #c_binary{segments=Ss}) -> - vu_seg_list(V, Ss); -vu_expr(V, #c_fun{vars=Vs,body=B}) -> - %% Variables in fun shadow previous variables - case vu_var_list(V, Vs) of - true -> false; - false -> vu_body(V, B) - end; -vu_expr(V, #c_let{vars=Vs,arg=Arg,body=B}) -> - case vu_body(V, Arg) of - true -> true; - false -> - %% Variables in let shadow previous variables. - case vu_var_list(V, Vs) of - true -> false; - false -> vu_body(V, B) - end - end; -vu_expr(V, #c_letrec{defs=Fs,body=B}) -> - case lists:any(fun (#c_def{val=Fb}) -> vu_body(V, Fb) end, Fs) of - true -> true; - false -> vu_body(V, B) - end; -vu_expr(V, #c_seq{arg=Arg,body=B}) -> - case vu_expr(V, Arg) of - true -> true; - false -> vu_body(V, B) - end; -vu_expr(V, #c_case{arg=Arg,clauses=Cs}) -> - case vu_expr(V, Arg) of - true -> true; - false -> vu_clauses(V, Cs) - end; -vu_expr(V, #c_receive{clauses=Cs,timeout=T,action=A}) -> - case vu_clauses(V, Cs) of - true -> true; - false -> - case vu_expr(V, T) of - true -> true; - false -> vu_body(V, A) - end - end; -vu_expr(V, #c_apply{op=Op,args=As}) -> - vu_expr_list(V, [Op|As]); -vu_expr(V, #c_call{module=M,name=N,args=As}) -> - vu_expr_list(V, [M,N|As]); -vu_expr(V, #c_primop{args=As}) -> %Name is an atom - vu_expr_list(V, As); -vu_expr(V, #c_catch{body=B}) -> - vu_body(V, B); -vu_expr(V, #c_try{arg=E,vars=Vs,body=B,evars=Evs,handler=H}) -> - case vu_body(V, E) of - true -> true; - false -> - %% Variables shadow previous ones. - case case vu_var_list(V, Vs) of - true -> false; - false -> vu_body(V, B) - end of - true -> true; - false -> - case vu_var_list(V, Evs) of - true -> false; - false -> vu_body(V, H) - end - end - end; -vu_expr(_, _) -> false. %Everything else - -vu_expr_list(V, Es) -> - lists:any(fun(E) -> vu_expr(V, E) end, Es). - -vu_seg_list(V, Ss) -> - lists:any(fun (#c_bitstr{val=Val,size=Size}) -> - case vu_expr(V, Val) of - true -> true; - false -> vu_expr(V, Size) - end - end, Ss). - -%% vu_clause(VarName, Clause) -> true | false. -%% vu_clauses(VarName, [Clause]) -> true | false. -%% Have to get the pattern results right. - -vu_clause(V, #c_clause{pats=Ps,guard=G,body=B}) -> - case vu_pattern_list(V, Ps) of - {true,_Shad} -> true; %It is used - {false,true} -> false; %Shadowed - {false,false} -> %Not affected - case vu_expr(V, G) of - true -> true; - false ->vu_body(V, B) - end - end. - -vu_clauses(V, Cs) -> - lists:any(fun(C) -> vu_clause(V, C) end, Cs). - -%% vu_pattern(VarName, Pattern) -> {Used,Shadow}. -%% vu_pattern_list(VarName, [Pattern]) -> {Used,Shadow}. -%% Binaries complicate patterns as a variable can both be properly -%% used, in a bit segment size, and shadow. They can also do both. - -%%vu_pattern(V, Pat) -> vu_pattern(V, Pat, {false,false}). - -vu_pattern(V, #c_var{name=V2}, St) -> - setelement(2, St, V =:= V2); -vu_pattern(V, #c_cons{hd=H,tl=T}, St0) -> - case vu_pattern(V, H, St0) of - {true,true}=St1 -> St1; %Nothing more to know - St1 -> vu_pattern(V, T, St1) - end; -vu_pattern(V, #c_tuple{es=Es}, St) -> - vu_pattern_list(V, Es, St); -vu_pattern(V, #c_binary{segments=Ss}, St) -> - vu_pat_seg_list(V, Ss, St); -vu_pattern(V, #c_alias{var=Var,pat=P}, St0) -> - case vu_pattern(V, Var, St0) of - {true,true}=St1 -> St1; - St1 -> vu_pattern(V, P, St1) - end; -vu_pattern(_, _, St) -> St. - -vu_pattern_list(V, Ps) -> vu_pattern_list(V, Ps, {false,false}). - -vu_pattern_list(V, Ps, St0) -> - lists:foldl(fun(P, St) -> vu_pattern(V, P, St) end, St0, Ps). - -vu_pat_seg_list(V, Ss, St) -> - lists:foldl(fun (#c_bitstr{val=Val,size=Size}, St0) -> - case vu_pattern(V, Val, St0) of - {true,true}=St1 -> St1; - {_Used,Shad} -> {vu_expr(V, Size),Shad} - end - end, St, Ss). - -%% vu_var_list(VarName, [Var]) -> true | false. - -vu_var_list(V, Vs) -> - lists:any(fun (#c_var{name=V2}) -> V =:= V2 end, Vs). |