%% ``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: asn1ct_check.erl,v 1.1 2008/12/17 09:53:29 mikpe Exp $
%%
-module(asn1ct_check).
%% Main Module for ASN.1 compile time functions
%-compile(export_all).
-export([check/2,storeindb/1]).
-include("asn1_records.hrl").
%%% The tag-number for universal types
-define(N_BOOLEAN, 1).
-define(N_INTEGER, 2).
-define(N_BIT_STRING, 3).
-define(N_OCTET_STRING, 4).
-define(N_NULL, 5).
-define(N_OBJECT_IDENTIFIER, 6).
-define(N_OBJECT_DESCRIPTOR, 7).
-define(N_EXTERNAL, 8). % constructed
-define(N_INSTANCE_OF,8).
-define(N_REAL, 9).
-define(N_ENUMERATED, 10).
-define(N_EMBEDDED_PDV, 11). % constructed
-define(N_SEQUENCE, 16).
-define(N_SET, 17).
-define(N_NumericString, 18).
-define(N_PrintableString, 19).
-define(N_TeletexString, 20).
-define(N_VideotexString, 21).
-define(N_IA5String, 22).
-define(N_UTCTime, 23).
-define(N_GeneralizedTime, 24).
-define(N_GraphicString, 25).
-define(N_VisibleString, 26).
-define(N_GeneralString, 27).
-define(N_UniversalString, 28).
-define(N_CHARACTER_STRING, 29). % constructed
-define(N_BMPString, 30).
-define(TAG_PRIMITIVE(Num),
case S#state.erule of
ber_bin_v2 ->
#tag{class='UNIVERSAL',number=Num,type='IMPLICIT',form=0};
_ -> []
end).
-define(TAG_CONSTRUCTED(Num),
case S#state.erule of
ber_bin_v2 ->
#tag{class='UNIVERSAL',number=Num,type='IMPLICIT',form=32};
_ -> []
end).
-record(newt,{type=unchanged,tag=unchanged,constraint=unchanged,inlined=no}). % used in check_type to update type and tag
-record(newv,{type=unchanged,value=unchanged}). % used in check_value to update type and value
check(S,{Types,Values,ParameterizedTypes,Classes,Objects,ObjectSets}) ->
%%Predicates used to filter errors
TupleIs = fun({T,_},T) -> true;
(_,_) -> false
end,
IsClass = fun(X) -> TupleIs(X,asn1_class) end,
IsObjSet = fun(X) -> TupleIs(X,objectsetdef) end,
IsPObjSet = fun(X) -> TupleIs(X,pobjectsetdef) end,
IsObject = fun(X) -> TupleIs(X,objectdef) end,
IsValueSet = fun(X) -> TupleIs(X,valueset) end,
Element2 = fun(X) -> element(2,X) end,
_Perror = checkp(S,ParameterizedTypes,[]), % must do this before the templates are used
Terror = checkt(S,Types,[]),
%% get parameterized object sets sent to checkt/3
%% and update Terror
{PObjSetNames1,Terror2} = filter_errors(IsPObjSet,Terror),
Verror = checkv(S,Values ++ ObjectSets,[]), %value sets may be parsed as object sets
%% get information object classes wrongly sent to checkt/3
%% and update Terror2
{AddClasses,Terror3} = filter_errors(IsClass,Terror2),
NewClasses = Classes++AddClasses,
Cerror = checkc(S,NewClasses,[]),
%% get object sets incorrectly sent to checkv/3
%% and update Verror
{ObjSetNames,Verror2} = filter_errors(IsObjSet,Verror),
%% get parameterized object sets incorrectly sent to checkv/3
%% and update Verror2
{PObjSetNames,Verror3} = filter_errors(IsPObjSet,Verror2),
%% get objects incorrectly sent to checkv/3
%% and update Verror3
{ObjectNames,Verror4} = filter_errors(IsObject,Verror3),
NewObjects = Objects++ObjectNames,
NewObjectSets = ObjSetNames ++ PObjSetNames ++ PObjSetNames1,
%% get value sets
%% and update Verror4
{ValueSetNames,Verror5} = filter_errors(IsValueSet,Verror4),
asn1ct:create_ets_table(inlined_objects,[named_table]),
{Oerror,ExclO,ExclOS} = checko(S,NewObjects ++
NewObjectSets,
[],[],[]),
InlinedObjTuples = ets:tab2list(inlined_objects),
InlinedObjects = lists:map(Element2,InlinedObjTuples),
ets:delete(inlined_objects),
Exporterror = check_exports(S,S#state.module),
case {Terror3,Verror5,Cerror,Oerror,Exporterror} of
{[],[],[],[],[]} ->
ContextSwitchTs = context_switch_in_spec(),
InstanceOf = instance_of_in_spec(),
NewTypes = lists:subtract(Types,AddClasses) ++ ContextSwitchTs
++ InstanceOf,
NewValues = lists:subtract(Values,PObjSetNames++ObjectNames++
ValueSetNames),
{ok,
{NewTypes,NewValues,ParameterizedTypes,
NewClasses,NewObjects,NewObjectSets},
{NewTypes,NewValues,ParameterizedTypes,NewClasses,
lists:subtract(NewObjects,ExclO)++InlinedObjects,
lists:subtract(NewObjectSets,ExclOS)}};
_ ->{error,{asn1,lists:flatten([Terror3,Verror5,Cerror,
Oerror,Exporterror])}}
end.
context_switch_in_spec() ->
L = [{external,'EXTERNAL'},
{embedded_pdv,'EMBEDDED PDV'},
{character_string,'CHARACTER STRING'}],
F = fun({T,TName},Acc) ->
case get(T) of
generate -> erase(T),
[TName|Acc];
_ -> Acc
end
end,
lists:foldl(F,[],L).
instance_of_in_spec() ->
case get(instance_of) of
generate ->
erase(instance_of),
['INSTANCE OF'];
_ ->
[]
end.
filter_errors(Pred,ErrorList) ->
Element2 = fun(X) -> element(2,X) end,
RemovedTupleElements = lists:filter(Pred,ErrorList),
RemovedNames = lists:map(Element2,RemovedTupleElements),
%% remove value set name tuples from Verror
RestErrors = lists:subtract(ErrorList,RemovedTupleElements),
{RemovedNames,RestErrors}.
check_exports(S,Module = #module{}) ->
case Module#module.exports of
{exports,[]} ->
[];
{exports,all} ->
[];
{exports,ExportList} when list(ExportList) ->
IsNotDefined =
fun(X) ->
case catch get_referenced_type(S,X) of
{error,{asn1,_}} ->
true;
_ -> false
end
end,
case lists:filter(IsNotDefined,ExportList) of
[] ->
[];
NoDefExp ->
GetName =
fun(T = #'Externaltypereference'{type=N})->
%%{exported,undefined,entity,N}
NewS=S#state{type=T,tname=N},
error({export,"exported undefined entity",NewS})
end,
lists:map(GetName,NoDefExp)
end
end.
checkt(S,[Name|T],Acc) ->
%%io:format("check_typedef:~p~n",[Name]),
Result =
case asn1_db:dbget(S#state.mname,Name) of
undefined ->
error({type,{internal_error,'???'},S});
Type when record(Type,typedef) ->
NewS = S#state{type=Type,tname=Name},
case catch(check_type(NewS,Type,Type#typedef.typespec)) of
{error,Reason} ->
error({type,Reason,NewS});
{'EXIT',Reason} ->
error({type,{internal_error,Reason},NewS});
{asn1_class,_ClassDef} ->
{asn1_class,Name};
pobjectsetdef ->
{pobjectsetdef,Name};
pvalueset ->
{pvalueset,Name};
Ts ->
case Type#typedef.checked of
true -> % already checked and updated
ok;
_ ->
NewTypeDef = Type#typedef{checked=true,typespec = Ts},
%io:format("checkt:dbput:~p, ~p~n",[S#state.mname,NewTypeDef#typedef.name]),
asn1_db:dbput(NewS#state.mname,Name,NewTypeDef), % update the type
ok
end
end
end,
case Result of
ok ->
checkt(S,T,Acc);
_ ->
checkt(S,T,[Result|Acc])
end;
checkt(S,[],Acc) ->
case check_contextswitchingtypes(S,[]) of
[] ->
lists:reverse(Acc);
L ->
checkt(S,L,Acc)
end.
check_contextswitchingtypes(S,Acc) ->
CSTList=[{external,'EXTERNAL'},
{embedded_pdv,'EMBEDDED PDV'},
{character_string,'CHARACTER STRING'}],
check_contextswitchingtypes(S,CSTList,Acc).
check_contextswitchingtypes(S,[{T,TName}|Ts],Acc) ->
case get(T) of
unchecked ->
put(T,generate),
check_contextswitchingtypes(S,Ts,[TName|Acc]);
_ ->
check_contextswitchingtypes(S,Ts,Acc)
end;
check_contextswitchingtypes(_,[],Acc) ->
Acc.
checkv(S,[Name|T],Acc) ->
%%io:format("check_valuedef:~p~n",[Name]),
Result = case asn1_db:dbget(S#state.mname,Name) of
undefined -> error({value,{internal_error,'???'},S});
Value when record(Value,valuedef);
record(Value,typedef); %Value set may be parsed as object set.
record(Value,pvaluedef);
record(Value,pvaluesetdef) ->
NewS = S#state{value=Value},
case catch(check_value(NewS,Value)) of
{error,Reason} ->
error({value,Reason,NewS});
{'EXIT',Reason} ->
error({value,{internal_error,Reason},NewS});
{pobjectsetdef} ->
{pobjectsetdef,Name};
{objectsetdef} ->
{objectsetdef,Name};
{objectdef} ->
%% this is an object, save as typedef
#valuedef{checked=C,pos=Pos,name=N,type=Type,
value=Def}=Value,
% Currmod = S#state.mname,
% #type{def=
% #'Externaltypereference'{module=Mod,
% type=CName}} = Type,
ClassName =
Type#type.def,
% case Mod of
% Currmod ->
% {objectclassname,CName};
% _ ->
% {objectclassname,Mod,CName}
% end,
NewSpec = #'Object'{classname=ClassName,
def=Def},
NewDef = #typedef{checked=C,pos=Pos,name=N,
typespec=NewSpec},
asn1_db:dbput(NewS#state.mname,Name,NewDef),
{objectdef,Name};
{valueset,VSet} ->
Pos = asn1ct:get_pos_of_def(Value),
CheckedVSDef = #typedef{checked=true,pos=Pos,
name=Name,typespec=VSet},
asn1_db:dbput(NewS#state.mname,Name,CheckedVSDef),
{valueset,Name};
V ->
%% update the valuedef
asn1_db:dbput(NewS#state.mname,Name,V),
ok
end
end,
case Result of
ok ->
checkv(S,T,Acc);
_ ->
checkv(S,T,[Result|Acc])
end;
checkv(_S,[],Acc) ->
lists:reverse(Acc).
checkp(S,[Name|T],Acc) ->
%io:format("check_ptypedef:~p~n",[Name]),
Result = case asn1_db:dbget(S#state.mname,Name) of
undefined ->
error({type,{internal_error,'???'},S});
Type when record(Type,ptypedef) ->
NewS = S#state{type=Type,tname=Name},
case catch(check_ptype(NewS,Type,Type#ptypedef.typespec)) of
{error,Reason} ->
error({type,Reason,NewS});
{'EXIT',Reason} ->
error({type,{internal_error,Reason},NewS});
{asn1_class,_ClassDef} ->
{asn1_class,Name};
Ts ->
NewType = Type#ptypedef{checked=true,typespec = Ts},
asn1_db:dbput(NewS#state.mname,Name,NewType), % update the type
ok
end
end,
case Result of
ok ->
checkp(S,T,Acc);
_ ->
checkp(S,T,[Result|Acc])
end;
checkp(_S,[],Acc) ->
lists:reverse(Acc).
checkc(S,[Name|Cs],Acc) ->
Result =
case asn1_db:dbget(S#state.mname,Name) of
undefined ->
error({class,{internal_error,'???'},S});
Class ->
ClassSpec = if
record(Class,classdef) ->
Class#classdef.typespec;
record(Class,typedef) ->
Class#typedef.typespec
end,
NewS = S#state{type=Class,tname=Name},
case catch(check_class(NewS,ClassSpec)) of
{error,Reason} ->
error({class,Reason,NewS});
{'EXIT',Reason} ->
error({class,{internal_error,Reason},NewS});
C ->
%% update the classdef
NewClass =
if
record(Class,classdef) ->
Class#classdef{checked=true,typespec=C};
record(Class,typedef) ->
#classdef{checked=true,name=Name,typespec=C}
end,
asn1_db:dbput(NewS#state.mname,Name,NewClass),
ok
end
end,
case Result of
ok ->
checkc(S,Cs,Acc);
_ ->
checkc(S,Cs,[Result|Acc])
end;
checkc(_S,[],Acc) ->
%% include_default_class(S#state.mname),
lists:reverse(Acc).
checko(S,[Name|Os],Acc,ExclO,ExclOS) ->
Result =
case asn1_db:dbget(S#state.mname,Name) of
undefined ->
error({type,{internal_error,'???'},S});
Object when record(Object,typedef) ->
NewS = S#state{type=Object,tname=Name},
case catch(check_object(NewS,Object,Object#typedef.typespec)) of
{error,Reason} ->
error({type,Reason,NewS});
{'EXIT',Reason} ->
error({type,{internal_error,Reason},NewS});
{asn1,Reason} ->
error({type,Reason,NewS});
O ->
NewObj = Object#typedef{checked=true,typespec=O},
asn1_db:dbput(NewS#state.mname,Name,NewObj),
if
record(O,'Object') ->
case O#'Object'.gen of
true ->
{ok,ExclO,ExclOS};
false ->
{ok,[Name|ExclO],ExclOS}
end;
record(O,'ObjectSet') ->
case O#'ObjectSet'.gen of
true ->
{ok,ExclO,ExclOS};
false ->
{ok,ExclO,[Name|ExclOS]}
end
end
end;
PObject when record(PObject,pobjectdef) ->
NewS = S#state{type=PObject,tname=Name},
case (catch check_pobject(NewS,PObject)) of
{error,Reason} ->
error({type,Reason,NewS});
{'EXIT',Reason} ->
error({type,{internal_error,Reason},NewS});
{asn1,Reason} ->
error({type,Reason,NewS});
PO ->
NewPObj = PObject#pobjectdef{def=PO},
asn1_db:dbput(NewS#state.mname,Name,NewPObj),
{ok,[Name|ExclO],ExclOS}
end;
PObjSet when record(PObjSet,pvaluesetdef) ->
%% this is a parameterized object set. Might be a parameterized
%% value set, couldn't it?
NewS = S#state{type=PObjSet,tname=Name},
case (catch check_pobjectset(NewS,PObjSet)) of
{error,Reason} ->
error({type,Reason,NewS});
{'EXIT',Reason} ->
error({type,{internal_error,Reason},NewS});
{asn1,Reason} ->
error({type,Reason,NewS});
POS ->
%%NewPObjSet = PObjSet#pvaluesetdef{valueset=POS},
asn1_db:dbput(NewS#state.mname,Name,POS),
{ok,ExclO,[Name|ExclOS]}
end
end,
case Result of
{ok,NewExclO,NewExclOS} ->
checko(S,Os,Acc,NewExclO,NewExclOS);
_ ->
checko(S,Os,[Result|Acc],ExclO,ExclOS)
end;
checko(_S,[],Acc,ExclO,ExclOS) ->
{lists:reverse(Acc),lists:reverse(ExclO),lists:reverse(ExclOS)}.
check_class(S,CDef=#classdef{checked=Ch,name=Name,typespec=TS}) ->
case Ch of
true -> TS;
idle -> TS;
_ ->
NewCDef = CDef#classdef{checked=idle},
asn1_db:dbput(S#state.mname,Name,NewCDef),
CheckedTS = check_class(S,TS),
asn1_db:dbput(S#state.mname,Name,
NewCDef#classdef{checked=true,
typespec=CheckedTS}),
CheckedTS
end;
check_class(S = #state{mname=M,tname=T},ClassSpec)
when record(ClassSpec,type) ->
Def = ClassSpec#type.def,
case Def of
#'Externaltypereference'{module=M,type=T} ->
#objectclass{fields=Def}; % in case of recursive definitions
Tref when record(Tref,'Externaltypereference') ->
{_,RefType} = get_referenced_type(S,Tref),
% case RefType of
% RefClass when record(RefClass,classdef) ->
% check_class(S,RefClass#classdef.typespec)
% end
case is_class(S,RefType) of
true ->
check_class(S,get_class_def(S,RefType));
_ ->
error({class,{internal_error,RefType},S})
end
end;
% check_class(S,{objectclassname,ModuleName,ClassName}) when atom(ModuleName),atom(ClassName) ->
% 'fix this';
check_class(S,C) when record(C,objectclass) ->
NewFieldSpec = check_class_fields(S,C#objectclass.fields),
C#objectclass{fields=NewFieldSpec};
%check_class(S,{objectclassname,ClassName}) ->
check_class(S,ClassName) ->
{_,Def} = get_referenced_type(S,ClassName),
case Def of
ClassDef when record(ClassDef,classdef) ->
case ClassDef#classdef.checked of
true ->
ClassDef#classdef.typespec;
idle ->
ClassDef#classdef.typespec;
false ->
check_class(S,ClassDef#classdef.typespec)
end;
TypeDef when record(TypeDef,typedef) ->
%% this case may occur when a definition is a reference
%% to a class definition.
case TypeDef#typedef.typespec of
#type{def=Ext} when record(Ext,'Externaltypereference') ->
check_class(S,Ext)
end
end;
check_class(_S,{poc,_ObjSet,_Params}) ->
'fix this later'.
check_class_fields(S,Fields) ->
check_class_fields(S,Fields,[]).
check_class_fields(S,[F|Fields],Acc) ->
NewField =
case element(1,F) of
fixedtypevaluefield ->
{_,Name,Type,Unique,OSpec} = F,
RefType = check_type(S,#typedef{typespec=Type},Type),
{fixedtypevaluefield,Name,RefType,Unique,OSpec};
object_or_fixedtypevalue_field ->
{_,Name,Type,Unique,OSpec} = F,
Cat =
case asn1ct_gen:type(asn1ct_gen:get_inner(Type#type.def)) of
Def when record(Def,typereference);
record(Def,'Externaltypereference') ->
{_,D} = get_referenced_type(S,Def),
D;
{undefined,user} ->
%% neither of {primitive,bif} or {constructed,bif}
%% {_,D} = get_referenced_type(S,#typereference{val=Type#type.def}),
{_,D} = get_referenced_type(S,#'Externaltypereference'{module=S#state.mname,type=Type#type.def}),
D;
_ ->
Type
end,
case Cat of
Class when record(Class,classdef) ->
{objectfield,Name,Type,Unique,OSpec};
_ ->
RefType = check_type(S,#typedef{typespec=Type},Type),
{fixedtypevaluefield,Name,RefType,Unique,OSpec}
end;
objectset_or_fixedtypevalueset_field ->
{_,Name,Type,OSpec} = F,
%% RefType = check_type(S,#typedef{typespec=Type},Type),
RefType =
case (catch check_type(S,#typedef{typespec=Type},Type)) of
{asn1_class,_ClassDef} ->
case if_current_checked_type(S,Type) of
true ->
Type#type.def;
_ ->
check_class(S,Type)
end;
CheckedType when record(CheckedType,type) ->
CheckedType;
_ ->
error({class,"internal error, check_class_fields",S})
end,
if
record(RefType,'Externaltypereference') ->
{objectsetfield,Name,Type,OSpec};
record(RefType,classdef) ->
{objectsetfield,Name,Type,OSpec};
record(RefType,objectclass) ->
{objectsetfield,Name,Type,OSpec};
true ->
{fixedtypevaluesetfield,Name,RefType,OSpec}
end;
typefield ->
case F of
{TF,Name,{'DEFAULT',Type}} ->
{TF,Name,{'DEFAULT',check_type(S,#typedef{typespec=Type},Type)}};
_ -> F
end;
_ -> F
end,
check_class_fields(S,Fields,[NewField|Acc]);
check_class_fields(_S,[],Acc) ->
lists:reverse(Acc).
if_current_checked_type(S,#type{def=Def}) ->
CurrentCheckedName = S#state.tname,
MergedModules = S#state.inputmodules,
% CurrentCheckedModule = S#state.mname,
case Def of
#'Externaltypereference'{module=CurrentCheckedName,
type=CurrentCheckedName} ->
true;
#'Externaltypereference'{module=ModuleName,
type=CurrentCheckedName} ->
case MergedModules of
undefined ->
false;
_ ->
lists:member(ModuleName,MergedModules)
end;
_ ->
false
end.
check_pobject(_S,PObject) when record(PObject,pobjectdef) ->
Def = PObject#pobjectdef.def,
Def.
check_pobjectset(S,PObjSet) ->
#pvaluesetdef{pos=Pos,name=Name,args=Args,type=Type,
valueset=ValueSet}=PObjSet,
{Mod,Def} = get_referenced_type(S,Type#type.def),
case Def of
#classdef{} ->
ClassName = #'Externaltypereference'{module=Mod,
type=Def#classdef.name},
{valueset,Set} = ValueSet,
% ObjectSet = #'ObjectSet'{class={objectclassname,ClassName},
ObjectSet = #'ObjectSet'{class=ClassName,
set=Set},
#pobjectsetdef{pos=Pos,name=Name,args=Args,class=Type#type.def,
def=ObjectSet};
_ ->
PObjSet
end.
check_object(_S,ObjDef,ObjSpec) when (ObjDef#typedef.checked == true) ->
ObjSpec;
check_object(S,_ObjDef,#'Object'{classname=ClassRef,def=ObjectDef}) ->
{_,_ClassDef} = get_referenced_type(S,ClassRef),
NewClassRef = check_externaltypereference(S,ClassRef),
ClassDef =
case _ClassDef#classdef.checked of
false ->
#classdef{checked=true,
typespec=check_class(S,_ClassDef#classdef.typespec)};
_ ->
_ClassDef
end,
NewObj =
case ObjectDef of
Def when tuple(Def), (element(1,Def)==object) ->
NewSettingList = check_objectdefn(S,Def,ClassDef),
#'Object'{def=NewSettingList};
% Def when tuple(Def), (element(1,Def)=='ObjectFromObject') ->
% fixa;
{po,{object,DefObj},ArgsList} ->
{_,Object} = get_referenced_type(S,DefObj),%DefObj is a
%%#'Externalvaluereference' or a #'Externaltypereference'
%% Maybe this call should be catched and in case of an exception
%% an nonallocated parameterized object should be returned.
instantiate_po(S,ClassDef,Object,ArgsList);
#'Externalvaluereference'{} ->
{_,Object} = get_referenced_type(S,ObjectDef),
check_object(S,Object,Object#typedef.typespec);
_ ->
exit({error,{no_object,ObjectDef},S})
end,
Gen = gen_incl(S,NewObj#'Object'.def,
(ClassDef#classdef.typespec)#objectclass.fields),
NewObj#'Object'{classname=NewClassRef,gen=Gen};
%%check_object(S,ObjSetDef,ObjSet=#type{def={pt,ObjSetRef,Args}}) ->
%% A parameterized
check_object(S,
_ObjSetDef,
ObjSet=#'ObjectSet'{class=ClassRef}) ->
{_,ClassDef} = get_referenced_type(S,ClassRef),
NewClassRef = check_externaltypereference(S,ClassRef),
UniqueFieldName =
case (catch get_unique_fieldname(ClassDef)) of
{error,'__undefined_'} -> {unique,undefined};
{asn1,Msg,_} -> error({class,Msg,S});
Other -> Other
end,
NewObjSet=
case ObjSet#'ObjectSet'.set of
{'SingleValue',Set} when list(Set) ->
CheckedSet = check_object_list(S,NewClassRef,Set),
NewSet = get_unique_valuelist(S,CheckedSet,UniqueFieldName),
ObjSet#'ObjectSet'{uniquefname=UniqueFieldName,
set=NewSet};
{'SingleValue',{definedvalue,ObjName}} ->
{_,ObjDef} = get_referenced_type(S,#identifier{val=ObjName}),
#'Object'{def=CheckedObj} =
check_object(S,ObjDef,ObjDef#typedef.typespec),
NewSet = get_unique_valuelist(S,[{ObjDef#typedef.name,
CheckedObj}],
UniqueFieldName),
ObjSet#'ObjectSet'{uniquefname=UniqueFieldName,
set=NewSet};
{'SingleValue',#'Externalvaluereference'{value=ObjName}} ->
{_,ObjDef} = get_referenced_type(S,#identifier{val=ObjName}),
#'Object'{def=CheckedObj} =
check_object(S,ObjDef,ObjDef#typedef.typespec),
NewSet = get_unique_valuelist(S,[{ObjDef#typedef.name,
CheckedObj}],
UniqueFieldName),
ObjSet#'ObjectSet'{uniquefname=UniqueFieldName,
set=NewSet};
['EXTENSIONMARK'] ->
ObjSet#'ObjectSet'{uniquefname=UniqueFieldName,
set=['EXTENSIONMARK']};
Set when list(Set) ->
CheckedSet = check_object_list(S,NewClassRef,Set),
NewSet = get_unique_valuelist(S,CheckedSet,UniqueFieldName),
ObjSet#'ObjectSet'{uniquefname=UniqueFieldName,
set=NewSet};
{Set,Ext} when list(Set) ->
CheckedSet = check_object_list(S,NewClassRef,Set++Ext),
NewSet = get_unique_valuelist(S,CheckedSet,UniqueFieldName),
ObjSet#'ObjectSet'{uniquefname=UniqueFieldName,
set=NewSet++['EXTENSIONMARK']};
{{'SingleValue',Set},Ext} ->
CheckedSet = check_object_list(S,NewClassRef,
merge_sets(Set,Ext)),
NewSet = get_unique_valuelist(S,CheckedSet,UniqueFieldName),
ObjSet#'ObjectSet'{uniquefname=UniqueFieldName,
set=NewSet++['EXTENSIONMARK']};
{Type,{'EXCEPT',Exclusion}} when record(Type,type) ->
{_,TDef} = get_referenced_type(S,Type#type.def),
OS = TDef#typedef.typespec,
NewSet = reduce_objectset(OS#'ObjectSet'.set,Exclusion),
NewOS = OS#'ObjectSet'{set=NewSet},
check_object(S,TDef#typedef{typespec=NewOS},
NewOS);
#type{def={pt,DefinedObjSet,ParamList}} ->
{_,PObjSetDef} = get_referenced_type(S,DefinedObjSet),
instantiate_pos(S,ClassDef,PObjSetDef,ParamList);
{ObjDef={object,definedsyntax,_ObjFields},_Ext} ->
CheckedSet = check_object_list(S,NewClassRef,[ObjDef]),
NewSet = get_unique_valuelist(S,CheckedSet,UniqueFieldName),
ObjSet#'ObjectSet'{uniquefname=UniqueFieldName,
set=NewSet++['EXTENSIONMARK']}
end,
Gen = gen_incl_set(S,NewObjSet#'ObjectSet'.set,
ClassDef),
NewObjSet#'ObjectSet'{class=NewClassRef,gen=Gen}.
merge_sets(Set,Ext) when list(Set),list(Ext) ->
Set ++ Ext;
merge_sets(Set,Ext) when list(Ext) ->
[Set|Ext];
merge_sets(Set,{'SingleValue',Ext}) when list(Set) ->
Set ++ [Ext];
merge_sets(Set,{'SingleValue',Ext}) ->
[Set] ++ [Ext].
reduce_objectset(ObjectSet,Exclusion) ->
case Exclusion of
{'SingleValue',#'Externalvaluereference'{value=Name}} ->
case lists:keysearch(Name,1,ObjectSet) of
{value,El} ->
lists:subtract(ObjectSet,[El]);
_ ->
ObjectSet
end
end.
%% Checks a list of objects or object sets and returns a list of selected
%% information for the code generation.
check_object_list(S,ClassRef,ObjectList) ->
check_object_list(S,ClassRef,ObjectList,[]).
check_object_list(S,ClassRef,[ObjOrSet|Objs],Acc) ->
case ObjOrSet of
ObjDef when tuple(ObjDef),(element(1,ObjDef)==object) ->
Def =
check_object(S,#typedef{typespec=ObjDef},
% #'Object'{classname={objectclassname,ClassRef},
#'Object'{classname=ClassRef,
def=ObjDef}),
check_object_list(S,ClassRef,Objs,[{no_name,Def#'Object'.def}|Acc]);
{'SingleValue',{definedvalue,ObjName}} ->
{_,ObjectDef} = get_referenced_type(S,#identifier{val=ObjName}),
#'Object'{def=Def} = check_object(S,ObjectDef,ObjectDef#typedef.typespec),
check_object_list(S,ClassRef,Objs,[{ObjectDef#typedef.name,Def}|Acc]);
{'SingleValue',Ref = #'Externalvaluereference'{}} ->
{_,ObjectDef} = get_referenced_type(S,Ref),
#'Object'{def=Def} = check_object(S,ObjectDef,ObjectDef#typedef.typespec),
check_object_list(S,ClassRef,Objs,[{ObjectDef#typedef.name,Def}|Acc]);
ObjRef when record(ObjRef,'Externalvaluereference') ->
{_,ObjectDef} = get_referenced_type(S,ObjRef),
#'Object'{def=Def} = check_object(S,ObjectDef,ObjectDef#typedef.typespec),
check_object_list(S,ClassRef,Objs,
%% [{ObjRef#'Externalvaluereference'.value,Def}|Acc]);
[{ObjectDef#typedef.name,Def}|Acc]);
{'ValueFromObject',{_,Object},FieldName} ->
{_,Def} = get_referenced_type(S,Object),
%% TypeOrVal = get_fieldname_element(S,Def,FieldName);%% this must result in an object set
TypeDef = get_fieldname_element(S,Def,FieldName),
(TypeDef#typedef.typespec)#'ObjectSet'.set;
ObjSet when record(ObjSet,type) ->
ObjSetDef =
case ObjSet#type.def of
Ref when record(Ref,typereference);
record(Ref,'Externaltypereference') ->
{_,D} = get_referenced_type(S,ObjSet#type.def),
D;
Other ->
throw({asn1_error,{'unknown objecset',Other,S}})
end,
#'ObjectSet'{set=ObjectsInSet} =
check_object(S,ObjSetDef,ObjSetDef#typedef.typespec),
AccList = transform_set_to_object_list(ObjectsInSet,[]),
check_object_list(S,ClassRef,Objs,AccList++Acc);
union ->
check_object_list(S,ClassRef,Objs,Acc);
Other ->
exit({error,{'unknown object',Other},S})
end;
%% Finally reverse the accumulated list and if there are any extension
%% marks in the object set put one indicator of that in the end of the
%% list.
check_object_list(_,_,[],Acc) ->
lists:reverse(Acc).
%% case lists:member('EXTENSIONMARK',RevAcc) of
%% true ->
%% ExclRevAcc = lists:filter(fun(X)->X /= 'EXTENSIONMARK' end,
%% RevAcc),
%% ExclRevAcc ++ ['EXTENSIONMARK'];
%% false ->
%% RevAcc
%% end.
%% get_fieldname_element/3
%% gets the type/value/object/... of the referenced element in FieldName
%% FieldName is a list and may have more than one element.
%% Each element in FieldName can be either {typefieldreference,AnyFieldName}
%% or {valuefieldreference,AnyFieldName}
%% Def is the def of the first object referenced by FieldName
get_fieldname_element(S,Def,[{_RefType,FieldName}]) when record(Def,typedef) ->
{_,_,ObjComps} = (Def#typedef.typespec)#'Object'.def,
case lists:keysearch(FieldName,1,ObjComps) of
{value,{_,TDef}} when record(TDef,typedef) ->
%% ORec = TDef#typedef.typespec, %% XXX This must be made general
% case TDef#typedef.typespec of
% ObjSetRec when record(ObjSetRec,'ObjectSet') ->
% ObjSet = ObjSetRec#'ObjectSet'.set;
% ObjRec when record(ObjRec,'Object') ->
% %% now get the field in ObjRec that RestFName points out
% %ObjRec
% TDef
% end;
TDef;
{value,{_,VDef}} when record(VDef,valuedef) ->
check_value(S,VDef);
_ ->
throw({assigned_object_error,"not_assigned_object",S})
end;
get_fieldname_element(_S,Def,[{_RefType,_FieldName}|_RestFName])
when record(Def,typedef) ->
ok.
transform_set_to_object_list([{Name,_UVal,Fields}|Objs],Acc) ->
transform_set_to_object_list(Objs,[{Name,{object,generatesyntax,Fields}}|Acc]);
transform_set_to_object_list(['EXTENSIONMARK'|Objs],Acc) ->
%% transform_set_to_object_list(Objs,['EXTENSIONMARK'|Acc]);
transform_set_to_object_list(Objs,Acc);
transform_set_to_object_list([],Acc) ->
Acc.
get_unique_valuelist(_S,ObjSet,{unique,undefined}) -> % no unique field in object
lists:map(fun({N,{_,_,F}})->{N,F};
(V={_,_,_}) ->V end, ObjSet);
get_unique_valuelist(S,ObjSet,UFN) ->
get_unique_vlist(S,ObjSet,UFN,[]).
get_unique_vlist(S,[],_,Acc) ->
case catch check_uniqueness(Acc) of
{asn1_error,_} ->
% exit({error,Reason,S});
error({'ObjectSet',"not unique objects in object set",S});
true ->
lists:reverse(Acc)
end;
get_unique_vlist(S,[{ObjName,Obj}|Rest],UniqueFieldName,Acc) ->
{_,_,Fields} = Obj,
VDef = get_unique_value(S,Fields,UniqueFieldName),
get_unique_vlist(S,Rest,UniqueFieldName,
[{ObjName,VDef#valuedef.value,Fields}|Acc]);
get_unique_vlist(S,[V={_,_,_}|Rest],UniqueFieldName,Acc) ->
get_unique_vlist(S,Rest,UniqueFieldName,[V|Acc]).
get_unique_value(S,Fields,UniqueFieldName) ->
Module = S#state.mname,
case lists:keysearch(UniqueFieldName,1,Fields) of
{value,Field} ->
case element(2,Field) of
VDef when record(VDef,valuedef) ->
VDef;
{definedvalue,ValName} ->
ValueDef = asn1_db:dbget(Module,ValName),
case ValueDef of
VDef when record(VDef,valuedef) ->
ValueDef;
undefined ->
#valuedef{value=ValName}
end;
{'ValueFromObject',Object,Name} ->
case Object of
{object,Ext} when record(Ext,'Externaltypereference') ->
OtherModule = Ext#'Externaltypereference'.module,
ExtObjName = Ext#'Externaltypereference'.type,
ObjDef = asn1_db:dbget(OtherModule,ExtObjName),
ObjSpec = ObjDef#typedef.typespec,
get_unique_value(OtherModule,element(3,ObjSpec),Name);
{object,{_,_,ObjName}} ->
ObjDef = asn1_db:dbget(Module,ObjName),
ObjSpec = ObjDef#typedef.typespec,
get_unique_value(Module,element(3,ObjSpec),Name);
{po,Object,_Params} ->
exit({error,{'parameterized object not implemented yet',
Object},S})
end;
Value when atom(Value);number(Value) ->
#valuedef{value=Value};
{'CHOICE',{_,Value}} when atom(Value);number(Value) ->
#valuedef{value=Value}
end;
false ->
exit({error,{'no unique value',Fields,UniqueFieldName},S})
%% io:format("WARNING: no unique value in object"),
%% exit(uniqueFieldName)
end.
check_uniqueness(NameValueList) ->
check_uniqueness1(lists:keysort(2,NameValueList)).
check_uniqueness1([]) ->
true;
check_uniqueness1([_]) ->
true;
check_uniqueness1([{_,N,_},{_,N,_}|_Rest]) ->
throw({asn1_error,{'objects in set must have unique values in UNIQUE fields',N}});
check_uniqueness1([_|Rest]) ->
check_uniqueness1(Rest).
%% instantiate_po/4
%% ClassDef is the class of Object,
%% Object is the Parameterized object, which is referenced,
%% ArgsList is the list of actual parameters
%% returns an #'Object' record.
instantiate_po(S,_ClassDef,Object,ArgsList) when record(Object,pobjectdef) ->
FormalParams = get_pt_args(Object),
MatchedArgs = match_args(FormalParams,ArgsList,[]),
NewS = S#state{type=Object,parameters=MatchedArgs},
check_object(NewS,Object,#'Object'{classname=Object#pobjectdef.class,
def=Object#pobjectdef.def}).
%% instantiate_pos/4
%% ClassDef is the class of ObjectSetDef,
%% ObjectSetDef is the Parameterized object set, which is referenced
%% on the right side of the assignment,
%% ArgsList is the list of actual parameters, i.e. real objects
instantiate_pos(S,ClassDef,ObjectSetDef,ArgsList) ->
ClassName = ClassDef#classdef.name,
FormalParams = get_pt_args(ObjectSetDef),
Set = case get_pt_spec(ObjectSetDef) of
{valueset,_Set} -> _Set;
_Set -> _Set
end,
MatchedArgs = match_args(FormalParams,ArgsList,[]),
NewS = S#state{type=ObjectSetDef,parameters=MatchedArgs},
check_object(NewS,ObjectSetDef,
#'ObjectSet'{class=name2Extref(S#state.mname,ClassName),
set=Set}).
%% gen_incl -> boolean()
%% If object with Fields has any of the corresponding class' typefields
%% then return value is true otherwise it is false.
%% If an object lacks a typefield but the class has a type field that
%% is OPTIONAL then we want gen to be true
gen_incl(S,{_,_,Fields},CFields)->
gen_incl1(S,Fields,CFields).
gen_incl1(_,_,[]) ->
false;
gen_incl1(S,Fields,[C|CFields]) ->
case element(1,C) of
typefield ->
% case lists:keymember(element(2,C),1,Fields) of
% true ->
% true;
% false ->
% gen_incl1(S,Fields,CFields)
% end;
true; %% should check that field is OPTIONAL or DEFUALT if
%% the object lacks this field
objectfield ->
case lists:keysearch(element(2,C),1,Fields) of
{value,Field} ->
Type = element(3,C),
{_,ClassDef} = get_referenced_type(S,Type#type.def),
% {_,ClassFields,_} = ClassDef#classdef.typespec,
#objectclass{fields=ClassFields} =
ClassDef#classdef.typespec,
ObjTDef = element(2,Field),
case gen_incl(S,(ObjTDef#typedef.typespec)#'Object'.def,
ClassFields) of
true ->
true;
_ ->
gen_incl1(S,Fields,CFields)
end;
_ ->
gen_incl1(S,Fields,CFields)
end;
_ ->
gen_incl1(S,Fields,CFields)
end.
%% first if no unique field in the class return false.(don't generate code)
gen_incl_set(S,Fields,ClassDef) ->
case catch get_unique_fieldname(ClassDef) of
Tuple when tuple(Tuple) ->
false;
_ ->
gen_incl_set1(S,Fields,
(ClassDef#classdef.typespec)#objectclass.fields)
end.
%% if any of the existing or potentially existing objects has a typefield
%% then return true.
gen_incl_set1(_,[],_CFields)->
false;
gen_incl_set1(_,['EXTENSIONMARK'],_) ->
true;
%% Fields are the fields of an object in the object set.
%% CFields are the fields of the class of the object set.
gen_incl_set1(S,[Object|Rest],CFields)->
Fields = element(size(Object),Object),
case gen_incl1(S,Fields,CFields) of
true ->
true;
false ->
gen_incl_set1(S,Rest,CFields)
end.
check_objectdefn(S,Def,CDef) when record(CDef,classdef) ->
WithSyntax = (CDef#classdef.typespec)#objectclass.syntax,
ClassFields = (CDef#classdef.typespec)#objectclass.fields,
case Def of
{object,defaultsyntax,Fields} ->
check_defaultfields(S,Fields,ClassFields);
{object,definedsyntax,Fields} ->
{_,WSSpec} = WithSyntax,
NewFields =
case catch( convert_definedsyntax(S,Fields,WSSpec,
ClassFields,[])) of
{asn1,{_ErrorType,ObjToken,ClassToken}} ->
throw({asn1,{'match error in object',ObjToken,
'found in object',ClassToken,'found in class'}});
Err={asn1,_} -> throw(Err);
Err={'EXIT',_} -> throw(Err);
DefaultFields when list(DefaultFields) ->
DefaultFields
end,
{object,defaultsyntax,NewFields};
{object,_ObjectId} -> % This is a DefinedObject
fixa;
Other ->
exit({error,{objectdefn,Other}})
end.
check_defaultfields(S,Fields,ClassFields) ->
check_defaultfields(S,Fields,ClassFields,[]).
check_defaultfields(_S,[],_ClassFields,Acc) ->
{object,defaultsyntax,lists:reverse(Acc)};
check_defaultfields(S,[{FName,Spec}|Fields],ClassFields,Acc) ->
case lists:keysearch(FName,2,ClassFields) of
{value,CField} ->
NewField = convert_to_defaultfield(S,FName,Spec,CField),
check_defaultfields(S,Fields,ClassFields,[NewField|Acc]);
_ ->
throw({error,{asn1,{'unvalid field in object',FName}}})
end.
%% {object,defaultsyntax,Fields}.
convert_definedsyntax(_S,[],[],_ClassFields,Acc) ->
lists:reverse(Acc);
convert_definedsyntax(S,Fields,WithSyntax,ClassFields,Acc) ->
case match_field(S,Fields,WithSyntax,ClassFields) of
{MatchedField,RestFields,RestWS} ->
if
list(MatchedField) ->
convert_definedsyntax(S,RestFields,RestWS,ClassFields,
lists:append(MatchedField,Acc));
true ->
convert_definedsyntax(S,RestFields,RestWS,ClassFields,
[MatchedField|Acc])
end
%% throw({error,{asn1,{'unvalid syntax in object',WorS}}})
end.
match_field(S,Fields,WithSyntax,ClassFields) ->
match_field(S,Fields,WithSyntax,ClassFields,[]).
match_field(S,Fields,[W|Ws],ClassFields,Acc) when list(W) ->
case catch(match_optional_field(S,Fields,W,ClassFields,[])) of
{'EXIT',_} ->
match_field(Fields,Ws,ClassFields,Acc); %% add S
%% {[Result],RestFields} ->
%% {Result,RestFields,Ws};
{Result,RestFields} when list(Result) ->
{Result,RestFields,Ws};
_ ->
match_field(S,Fields,Ws,ClassFields,Acc)
end;
match_field(S,Fields,WithSyntax,ClassFields,_Acc) ->
match_mandatory_field(S,Fields,WithSyntax,ClassFields,[]).
match_optional_field(_S,RestFields,[],_,Ret) ->
{Ret,RestFields};
%% An additional optional field within an optional field
match_optional_field(S,Fields,[W|Ws],ClassFields,Ret) when list(W) ->
case catch match_optional_field(S,Fields,W,ClassFields,[]) of
{'EXIT',_} ->
{Ret,Fields};
{asn1,{optional_matcherror,_,_}} ->
{Ret,Fields};
{OptionalField,RestFields} ->
match_optional_field(S,RestFields,Ws,ClassFields,
lists:append(OptionalField,Ret))
end;
%% identify and skip word
%match_optional_field(S,[#'Externaltypereference'{type=WorS}|Rest],
match_optional_field(S,[{_,_,WorS}|Rest],
[WorS|Ws],ClassFields,Ret) ->
match_optional_field(S,Rest,Ws,ClassFields,Ret);
match_optional_field(S,[],_,ClassFields,Ret) ->
match_optional_field(S,[],[],ClassFields,Ret);
%% identify and skip comma
match_optional_field(S,[{WorS,_}|Rest],[{WorS,_}|Ws],ClassFields,Ret) ->
match_optional_field(S,Rest,Ws,ClassFields,Ret);
%% identify and save field data
match_optional_field(S,[Setting|Rest],[{_,W}|Ws],ClassFields,Ret) ->
WorS =
case Setting of
Type when record(Type,type) -> Type;
%% #'Externalvaluereference'{value=WordOrSetting} -> WordOrSetting;
{'ValueFromObject',_,_} -> Setting;
{object,_,_} -> Setting;
{_,_,WordOrSetting} -> WordOrSetting;
%% Atom when atom(Atom) -> Atom
Other -> Other
end,
case lists:keysearch(W,2,ClassFields) of
false ->
throw({asn1,{optional_matcherror,WorS,W}});
{value,CField} ->
NewField = convert_to_defaultfield(S,W,WorS,CField),
match_optional_field(S,Rest,Ws,ClassFields,[NewField|Ret])
end;
match_optional_field(_S,[WorS|_Rest],[W|_Ws],_ClassFields,_Ret) ->
throw({asn1,{optional_matcherror,WorS,W}}).
match_mandatory_field(_S,[],[],_,[Acc]) ->
{Acc,[],[]};
match_mandatory_field(_S,[],[],_,Acc) ->
{Acc,[],[]};
match_mandatory_field(S,[],[H|T],CF,Acc) when list(H) ->
match_mandatory_field(S,[],T,CF,Acc);
match_mandatory_field(_S,[],WithSyntax,_,_Acc) ->
throw({asn1,{mandatory_matcherror,[],WithSyntax}});
%match_mandatory_field(_S,Fields,WithSyntax=[W|_Ws],_ClassFields,[Acc]) when list(W) ->
match_mandatory_field(_S,Fields,WithSyntax=[W|_Ws],_ClassFields,Acc) when list(W), length(Acc) >= 1 ->
{Acc,Fields,WithSyntax};
%% identify and skip word
match_mandatory_field(S,[{_,_,WorS}|Rest],
[WorS|Ws],ClassFields,Acc) ->
match_mandatory_field(S,Rest,Ws,ClassFields,Acc);
%% identify and skip comma
match_mandatory_field(S,[{WorS,_}|Rest],[{WorS,_}|Ws],ClassFields,Ret) ->
match_mandatory_field(S,Rest,Ws,ClassFields,Ret);
%% identify and save field data
match_mandatory_field(S,[Setting|Rest],[{_,W}|Ws],ClassFields,Acc) ->
WorS =
case Setting of
%% Atom when atom(Atom) -> Atom;
%% #'Externalvaluereference'{value=WordOrSetting} -> WordOrSetting;
{object,_,_} -> Setting;
{_,_,WordOrSetting} -> WordOrSetting;
Type when record(Type,type) -> Type;
Other -> Other
end,
case lists:keysearch(W,2,ClassFields) of
false ->
throw({asn1,{mandatory_matcherror,WorS,W}});
{value,CField} ->
NewField = convert_to_defaultfield(S,W,WorS,CField),
match_mandatory_field(S,Rest,Ws,ClassFields,[NewField|Acc])
end;
match_mandatory_field(_S,[WorS|_Rest],[W|_Ws],_ClassFields,_Acc) ->
throw({asn1,{mandatory_matcherror,WorS,W}}).
%% Converts a field of an object from defined syntax to default syntax
convert_to_defaultfield(S,ObjFieldName,ObjFieldSetting,CField)->
CurrMod = S#state.mname,
case element(1,CField) of
typefield ->
TypeDef=
case ObjFieldSetting of
TypeRec when record(TypeRec,type) -> TypeRec#type.def;
TDef when record(TDef,typedef) ->
TDef#typedef{typespec=check_type(S,TDef,
TDef#typedef.typespec)};
_ -> ObjFieldSetting
end,
Type =
if
record(TypeDef,typedef) -> TypeDef;
true ->
case asn1ct_gen:type(asn1ct_gen:get_inner(TypeDef)) of
ERef = #'Externaltypereference'{module=CurrMod} ->
{_,T} = get_referenced_type(S,ERef),
T#typedef{checked=true,
typespec=check_type(S,T,
T#typedef.typespec)};
ERef = #'Externaltypereference'{module=ExtMod} ->
{_,T} = get_referenced_type(S,ERef),
#typedef{name=Name} = T,
check_type(S,T,T#typedef.typespec),
#typedef{checked=true,
name={ExtMod,Name},
typespec=ERef};
Bif when Bif=={primitive,bif};Bif=={constructed,bif} ->
T = check_type(S,#typedef{typespec=ObjFieldSetting},
ObjFieldSetting),
#typedef{checked=true,name=Bif,typespec=T};
_ ->
{Mod,T} =
%% get_referenced_type(S,#typereference{val=ObjFieldSetting}),
get_referenced_type(S,#'Externaltypereference'{module=S#state.mname,type=ObjFieldSetting}),
case Mod of
CurrMod ->
T;
ExtMod ->
#typedef{name=Name} = T,
T#typedef{name={ExtMod,Name}}
end
end
end,
{ObjFieldName,Type};
fixedtypevaluefield ->
case ObjFieldName of
Val when atom(Val) ->
%% ObjFieldSetting can be a value,an objectidentifiervalue,
%% an element in an enumeration or namednumberlist etc.
ValRef =
case ObjFieldSetting of
#'Externalvaluereference'{} -> ObjFieldSetting;
{'ValueFromObject',{_,ObjRef},FieldName} ->
{_,Object} = get_referenced_type(S,ObjRef),
ChObject = check_object(S,Object,
Object#typedef.typespec),
get_fieldname_element(S,Object#typedef{typespec=ChObject},
FieldName);
#valuedef{} ->
ObjFieldSetting;
_ ->
#identifier{val=ObjFieldSetting}
end,
case ValRef of
#valuedef{} ->
{ObjFieldName,check_value(S,ValRef)};
_ ->
ValDef =
case catch get_referenced_type(S,ValRef) of
{error,_} ->
check_value(S,#valuedef{name=Val,
type=element(3,CField),
value=ObjFieldSetting});
{_,VDef} when record(VDef,valuedef) ->
check_value(S,VDef);%% XXX
{_,VDef} ->
check_value(S,#valuedef{name=Val,
type=element(3,CField),
value=VDef})
end,
{ObjFieldName,ValDef}
end;
Val ->
{ObjFieldName,Val}
end;
fixedtypevaluesetfield ->
{ObjFieldName,ObjFieldSetting};
objectfield ->
ObjectSpec =
case ObjFieldSetting of
Ref when record(Ref,typereference);record(Ref,identifier);
record(Ref,'Externaltypereference');
record(Ref,'Externalvaluereference') ->
{_,R} = get_referenced_type(S,ObjFieldSetting),
R;
{'ValueFromObject',{_,ObjRef},FieldName} ->
%% This is an ObjectFromObject
{_,Object} = get_referenced_type(S,ObjRef),
ChObject = check_object(S,Object,
Object#typedef.typespec),
_ObjFromObj=
get_fieldname_element(S,Object#typedef{
typespec=ChObject},
FieldName);
%%ClassName = ObjFromObj#'Object'.classname,
%%#typedef{name=,
%% typespec=
%% ObjFromObj#'Object'{classname=
%% {objectclassname,ClassName}}};
{object,_,_} ->
%% An object defined inlined in another object
#type{def=Ref} = element(3,CField),
% CRef = case Ref of
% #'Externaltypereference'{module=CurrMod,
% type=CName} ->
% CName;
% #'Externaltypereference'{module=ExtMod,
% type=CName} ->
% {ExtMod,CName}
% end,
InlinedObjName=
list_to_atom(lists:concat([S#state.tname]++
['_',ObjFieldName])),
% ObjSpec = #'Object'{classname={objectclassname,CRef},
ObjSpec = #'Object'{classname=Ref,
def=ObjFieldSetting},
CheckedObj=
check_object(S,#typedef{typespec=ObjSpec},ObjSpec),
InlObj = #typedef{checked=true,name=InlinedObjName,
typespec=CheckedObj},
asn1ct_gen:insert_once(inlined_objects,{InlinedObjName,
InlinedObjName}),
asn1_db:dbput(S#state.mname,InlinedObjName,InlObj),
InlObj;
#type{def=Eref} when record(Eref,'Externaltypereference') ->
{_,R} = get_referenced_type(S,Eref),
R;
_ ->
%% {_,R} = get_referenced_type(S,#typereference{val=ObjFieldSetting}),
{_,R} = get_referenced_type(S,#'Externaltypereference'{module=S#state.mname,type=ObjFieldSetting}),
R
end,
{ObjFieldName,
ObjectSpec#typedef{checked=true,
typespec=check_object(S,ObjectSpec,
ObjectSpec#typedef.typespec)}};
variabletypevaluefield ->
{ObjFieldName,ObjFieldSetting};
variabletypevaluesetfield ->
{ObjFieldName,ObjFieldSetting};
objectsetfield ->
{_,ObjSetSpec} =
case ObjFieldSetting of
Ref when record(Ref,'Externaltypereference');
record(Ref,'Externalvaluereference') ->
get_referenced_type(S,ObjFieldSetting);
ObjectList when list(ObjectList) ->
%% an objctset defined in the object,though maybe
%% parsed as a SequenceOfValue
%% The ObjectList may be a list of references to
%% objects, a ValueFromObject
{_,_,Type,_} = CField,
ClassDef = Type#type.def,
case ClassDef#'Externaltypereference'.module of
CurrMod ->
ClassDef#'Externaltypereference'.type;
ExtMod ->
{ExtMod,
ClassDef#'Externaltypereference'.type}
end,
{no_name,
#typedef{typespec=
#'ObjectSet'{class=
% {objectclassname,ClassRef},
ClassDef,
set=ObjectList}}};
ObjectSet={'SingleValue',_} ->
%% a Union of defined objects
{_,_,Type,_} = CField,
ClassDef = Type#type.def,
% ClassRef =
% case ClassDef#'Externaltypereference'.module of
% CurrMod ->
% ClassDef#'Externaltypereference'.type;
% ExtMod ->
% {ExtMod,
% ClassDef#'Externaltypereference'.type}
% end,
{no_name,
% #typedef{typespec=#'ObjectSet'{class={objectclassname,ClassRef},
#typedef{typespec=#'ObjectSet'{class=ClassDef,
set=ObjectSet}}};
{object,_,[#type{def={'TypeFromObject',
{object,RefedObj},
FieldName}}]} ->
%% This case occurs when an ObjectSetFromObjects
%% production is used
{M,Def} = get_referenced_type(S,RefedObj),
{M,get_fieldname_element(S,Def,FieldName)};
#type{def=Eref} when
record(Eref,'Externaltypereference') ->
get_referenced_type(S,Eref);
_ ->
%% get_referenced_type(S,#typereference{val=ObjFieldSetting})
get_referenced_type(S,#'Externaltypereference'{module=S#state.mname,type=ObjFieldSetting})
end,
{ObjFieldName,
ObjSetSpec#typedef{checked=true,
typespec=check_object(S,ObjSetSpec,
ObjSetSpec#typedef.typespec)}}
end.
check_value(OldS,V) when record(V,pvaluesetdef) ->
#pvaluesetdef{checked=Checked,type=Type} = V,
case Checked of
true -> V;
{error,_} -> V;
false ->
case get_referenced_type(OldS,Type#type.def) of
{_,Class} when record(Class,classdef) ->
throw({pobjectsetdef});
_ -> continue
end
end;
check_value(_OldS,V) when record(V,pvaluedef) ->
%% Fix this case later
V;
check_value(OldS,V) when record(V,typedef) ->
%% This case when a value set has been parsed as an object set.
%% It may be a value set
#typedef{typespec=TS} = V,
case TS of
#'ObjectSet'{class=ClassRef} ->
{_,TSDef} = get_referenced_type(OldS,ClassRef),
%%IsObjectSet(TSDef);
case TSDef of
#classdef{} -> throw({objectsetdef});
#typedef{typespec=#type{def=Eref}} when
record(Eref,'Externaltypereference') ->
%% This case if the class reference is a defined
%% reference to class
check_value(OldS,V#typedef{typespec=TS#'ObjectSet'{class=Eref}});
#typedef{} ->
% an ordinary value set with a type in #typedef.typespec
ValueSet = TS#'ObjectSet'.set,
Type=check_type(OldS,TSDef,TSDef#typedef.typespec),
Value = check_value(OldS,#valuedef{type=Type,
value=ValueSet}),
{valueset,Type#type{constraint=Value#valuedef.value}}
end;
_ ->
throw({objectsetdef})
end;
check_value(S,#valuedef{pos=Pos,name=Name,type=Type,
value={valueset,Constr}}) ->
NewType = Type#type{constraint=[Constr]},
{valueset,
check_type(S,#typedef{pos=Pos,name=Name,typespec=NewType},NewType)};
check_value(OldS=#state{recordtopname=TopName},V) when record(V,valuedef) ->
#valuedef{name=Name,checked=Checked,type=Vtype,value=Value} = V,
case Checked of
true ->
V;
{error,_} ->
V;
false ->
Def = Vtype#type.def,
Constr = Vtype#type.constraint,
S = OldS#state{type=Vtype,tname=Def,value=V,vname=Name},
NewDef =
case Def of
Ext when record(Ext,'Externaltypereference') ->
RecName = Ext#'Externaltypereference'.type,
{_,Type} = get_referenced_type(S,Ext),
%% If V isn't a value but an object Type is a #classdef{}
case Type of
#classdef{} ->
throw({objectdef});
#typedef{} ->
case is_contextswitchtype(Type) of
true ->
#valuedef{value=CheckedVal}=
check_value(S,V#valuedef{type=Type#typedef.typespec}),
#newv{value=CheckedVal};
_ ->
#valuedef{value=CheckedVal}=
check_value(S#state{recordtopname=[RecName|TopName]},
V#valuedef{type=Type#typedef.typespec}),
#newv{value=CheckedVal}
end
end;
'ANY' ->
throw({error,{asn1,{'cant check value of type',Def}}});
'INTEGER' ->
validate_integer(S,Value,[],Constr),
#newv{value=normalize_value(S,Vtype,Value,[])};
{'INTEGER',NamedNumberList} ->
validate_integer(S,Value,NamedNumberList,Constr),
#newv{value=normalize_value(S,Vtype,Value,[])};
{'BIT STRING',NamedNumberList} ->
validate_bitstring(S,Value,NamedNumberList,Constr),
#newv{value=normalize_value(S,Vtype,Value,[])};
'NULL' ->
validate_null(S,Value,Constr),
#newv{};
'OBJECT IDENTIFIER' ->
validate_objectidentifier(S,Value,Constr),
#newv{value = normalize_value(S,Vtype,Value,[])};
'ObjectDescriptor' ->
validate_objectdescriptor(S,Value,Constr),
#newv{value=normalize_value(S,Vtype,Value,[])};
{'ENUMERATED',NamedNumberList} ->
validate_enumerated(S,Value,NamedNumberList,Constr),
#newv{value=normalize_value(S,Vtype,Value,[])};
'BOOLEAN'->
validate_boolean(S,Value,Constr),
#newv{value=normalize_value(S,Vtype,Value,[])};
'OCTET STRING' ->
validate_octetstring(S,Value,Constr),
#newv{value=normalize_value(S,Vtype,Value,[])};
'NumericString' ->
validate_restrictedstring(S,Value,Def,Constr),
#newv{value=normalize_value(S,Vtype,Value,[])};
'TeletexString' ->
validate_restrictedstring(S,Value,Def,Constr),
#newv{value=normalize_value(S,Vtype,Value,[])};
'VideotexString' ->
validate_restrictedstring(S,Value,Def,Constr),
#newv{value=normalize_value(S,Vtype,Value,[])};
'UTCTime' ->
#newv{value=normalize_value(S,Vtype,Value,[])};
% exit({'cant check value of type' ,Def});
'GeneralizedTime' ->
#newv{value=normalize_value(S,Vtype,Value,[])};
% exit({'cant check value of type' ,Def});
'GraphicString' ->
validate_restrictedstring(S,Value,Def,Constr),
#newv{value=normalize_value(S,Vtype,Value,[])};
'VisibleString' ->
validate_restrictedstring(S,Value,Def,Constr),
#newv{value=normalize_value(S,Vtype,Value,[])};
'GeneralString' ->
validate_restrictedstring(S,Value,Def,Constr),
#newv{value=normalize_value(S,Vtype,Value,[])};
'PrintableString' ->
validate_restrictedstring(S,Value,Def,Constr),
#newv{value=normalize_value(S,Vtype,Value,[])};
'IA5String' ->
validate_restrictedstring(S,Value,Def,Constr),
#newv{value=normalize_value(S,Vtype,Value,[])};
'BMPString' ->
validate_restrictedstring(S,Value,Def,Constr),
#newv{value=normalize_value(S,Vtype,Value,[])};
%% 'UniversalString' -> %added 6/12 -00
%% #newv{value=validate_restrictedstring(S,Value,Def,Constr)};
Seq when record(Seq,'SEQUENCE') ->
SeqVal = validate_sequence(S,Value,
Seq#'SEQUENCE'.components,
Constr),
#newv{value=normalize_value(S,Vtype,SeqVal,TopName)};
{'SEQUENCE OF',Components} ->
validate_sequenceof(S,Value,Components,Constr),
#newv{value=normalize_value(S,Vtype,Value,TopName)};
{'CHOICE',Components} ->
validate_choice(S,Value,Components,Constr),
#newv{value=normalize_value(S,Vtype,Value,TopName)};
Set when record(Set,'SET') ->
validate_set(S,Value,Set#'SET'.components,
Constr),
#newv{value=normalize_value(S,Vtype,Value,TopName)};
{'SET OF',Components} ->
validate_setof(S,Value,Components,Constr),
#newv{value=normalize_value(S,Vtype,Value,TopName)};
Other ->
exit({'cant check value of type' ,Other})
end,
case NewDef#newv.value of
unchanged ->
V#valuedef{checked=true,value=Value};
ok ->
V#valuedef{checked=true,value=Value};
{error,Reason} ->
V#valuedef{checked={error,Reason},value=Value};
_V ->
V#valuedef{checked=true,value=_V}
end
end.
is_contextswitchtype(#typedef{name='EXTERNAL'})->
true;
is_contextswitchtype(#typedef{name='EMBEDDED PDV'}) ->
true;
is_contextswitchtype(#typedef{name='CHARACTER STRING'}) ->
true;
is_contextswitchtype(_) ->
false.
% validate_integer(S,{identifier,Pos,Id},NamedNumberList,Constr) ->
% case lists:keysearch(Id,1,NamedNumberList) of
% {value,_} -> ok;
% false -> error({value,"unknown NamedNumber",S})
% end;
%% This case occurs when there is a valuereference
validate_integer(S=#state{mname=M},
#'Externalvaluereference'{module=M,value=Id},
NamedNumberList,_Constr) ->
case lists:keysearch(Id,1,NamedNumberList) of
{value,_} -> ok;
false -> error({value,"unknown NamedNumber",S})
end;
validate_integer(S,Id,NamedNumberList,_Constr) when atom(Id) ->
case lists:keysearch(Id,1,NamedNumberList) of
{value,_} -> ok;
false -> error({value,"unknown NamedNumber",S})
end;
validate_integer(_S,Value,_NamedNumberList,Constr) when integer(Value) ->
check_integer_range(Value,Constr).
check_integer_range(Int,Constr) when list(Constr) ->
NewConstr = [X || #constraint{c=X} <- Constr],
check_constr(Int,NewConstr);
check_integer_range(_Int,_Constr) ->
%%io:format("~p~n",[Constr]),
ok.
check_constr(Int,[{'ValueRange',Lb,Ub}|T]) when Int >= Lb, Int =< Ub ->
check_constr(Int,T);
check_constr(_Int,[]) ->
ok.
validate_bitstring(_S,_Value,_NamedNumberList,_Constr) ->
ok.
validate_null(_S,'NULL',_Constr) ->
ok.
%%------------
%% This can be removed when the old parser is removed
%% The function removes 'space' atoms from the list
is_space_list([H],Acc) ->
lists:reverse([H|Acc]);
is_space_list([H,space|T],Acc) ->
is_space_list(T,[H|Acc]);
is_space_list([],Acc) ->
lists:reverse(Acc);
is_space_list([H|T],Acc) ->
is_space_list(T,[H|Acc]).
validate_objectidentifier(S,L,_) ->
case is_space_list(L,[]) of
NewL when list(NewL) ->
case validate_objectidentifier1(S,NewL) of
NewL2 when list(NewL2) ->
list_to_tuple(NewL2);
Other -> Other
end;
{error,_} ->
error({value, "illegal OBJECT IDENTIFIER", S})
end.
validate_objectidentifier1(S, [Id|T]) when record(Id,'Externalvaluereference') ->
case catch get_referenced_type(S,Id) of
{_,V} when record(V,valuedef) ->
case check_value(S,V) of
#valuedef{type=#type{def='OBJECT IDENTIFIER'},
checked=true,value=Value} when tuple(Value) ->
validate_objectid(S, T, lists:reverse(tuple_to_list(Value)));
_ ->
error({value, "illegal OBJECT IDENTIFIER", S})
end;
_ ->
validate_objectid(S, [Id|T], [])
end;
validate_objectidentifier1(S,V) ->
validate_objectid(S,V,[]).
validate_objectid(_, [], Acc) ->
lists:reverse(Acc);
validate_objectid(S, [Value|Vrest], Acc) when integer(Value) ->
validate_objectid(S, Vrest, [Value|Acc]);
validate_objectid(S, [{'NamedNumber',_Name,Value}|Vrest], Acc)
when integer(Value) ->
validate_objectid(S, Vrest, [Value|Acc]);
validate_objectid(S, [Id|Vrest], Acc)
when record(Id,'Externalvaluereference') ->
case catch get_referenced_type(S, Id) of
{_,V} when record(V,valuedef) ->
case check_value(S, V) of
#valuedef{checked=true,value=Value} when integer(Value) ->
validate_objectid(S, Vrest, [Value|Acc]);
_ ->
error({value, "illegal OBJECT IDENTIFIER", S})
end;
_ ->
case reserved_objectid(Id#'Externalvaluereference'.value, Acc) of
Value when integer(Value) ->
validate_objectid(S, Vrest, [Value|Acc]);
false ->
error({value, "illegal OBJECT IDENTIFIER", S})
end
end;
validate_objectid(S, [{Atom,Value}],[]) when atom(Atom),integer(Value) ->
%% this case when an OBJECT IDENTIFIER value has been parsed as a
%% SEQUENCE value
Rec = #'Externalvaluereference'{module=S#state.mname,
value=Atom},
validate_objectidentifier1(S,[Rec,Value]);
validate_objectid(S, [{Atom,EVRef}],[])
when atom(Atom),record(EVRef,'Externalvaluereference') ->
%% this case when an OBJECT IDENTIFIER value has been parsed as a
%% SEQUENCE value OTP-4354
Rec = #'Externalvaluereference'{module=S#state.mname,
value=Atom},
validate_objectidentifier1(S,[Rec,EVRef]);
validate_objectid(S, _V, _Acc) ->
error({value, "illegal OBJECT IDENTIFIER",S}).
%% ITU-T Rec. X.680 Annex B - D
reserved_objectid('itu-t',[]) -> 0;
reserved_objectid('ccitt',[]) -> 0;
%% arcs below "itu-t"
reserved_objectid('recommendation',[0]) -> 0;
reserved_objectid('question',[0]) -> 1;
reserved_objectid('administration',[0]) -> 2;
reserved_objectid('network-operator',[0]) -> 3;
reserved_objectid('identified-organization',[0]) -> 4;
%% arcs below "recommendation"
reserved_objectid('a',[0,0]) -> 1;
reserved_objectid('b',[0,0]) -> 2;
reserved_objectid('c',[0,0]) -> 3;
reserved_objectid('d',[0,0]) -> 4;
reserved_objectid('e',[0,0]) -> 5;
reserved_objectid('f',[0,0]) -> 6;
reserved_objectid('g',[0,0]) -> 7;
reserved_objectid('h',[0,0]) -> 8;
reserved_objectid('i',[0,0]) -> 9;
reserved_objectid('j',[0,0]) -> 10;
reserved_objectid('k',[0,0]) -> 11;
reserved_objectid('l',[0,0]) -> 12;
reserved_objectid('m',[0,0]) -> 13;
reserved_objectid('n',[0,0]) -> 14;
reserved_objectid('o',[0,0]) -> 15;
reserved_objectid('p',[0,0]) -> 16;
reserved_objectid('q',[0,0]) -> 17;
reserved_objectid('r',[0,0]) -> 18;
reserved_objectid('s',[0,0]) -> 19;
reserved_objectid('t',[0,0]) -> 20;
reserved_objectid('u',[0,0]) -> 21;
reserved_objectid('v',[0,0]) -> 22;
reserved_objectid('w',[0,0]) -> 23;
reserved_objectid('x',[0,0]) -> 24;
reserved_objectid('y',[0,0]) -> 25;
reserved_objectid('z',[0,0]) -> 26;
reserved_objectid(iso,[]) -> 1;
%% arcs below "iso", note that number 1 is not used
reserved_objectid('standard',[1]) -> 0;
reserved_objectid('member-body',[1]) -> 2;
reserved_objectid('identified-organization',[1]) -> 3;
reserved_objectid('joint-iso-itu-t',[]) -> 2;
reserved_objectid('joint-iso-ccitt',[]) -> 2;
reserved_objectid(_,_) -> false.
validate_objectdescriptor(_S,_Value,_Constr) ->
ok.
validate_enumerated(S,Id,NamedNumberList,_Constr) when atom(Id) ->
case lists:keysearch(Id,1,NamedNumberList) of
{value,_} -> ok;
false -> error({value,"unknown ENUMERATED",S})
end;
validate_enumerated(S,{identifier,_Pos,Id},NamedNumberList,_Constr) ->
case lists:keysearch(Id,1,NamedNumberList) of
{value,_} -> ok;
false -> error({value,"unknown ENUMERATED",S})
end;
validate_enumerated(S,#'Externalvaluereference'{value=Id},
NamedNumberList,_Constr) ->
case lists:keysearch(Id,1,NamedNumberList) of
{value,_} -> ok;
false -> error({value,"unknown ENUMERATED",S})
end.
validate_boolean(_S,_Value,_Constr) ->
ok.
validate_octetstring(_S,_Value,_Constr) ->
ok.
validate_restrictedstring(_S,_Value,_Def,_Constr) ->
ok.
validate_sequence(S=#state{type=Vtype},Value,_Components,_Constr) ->
case Vtype of
#type{tag=[{tag,'UNIVERSAL',8,'IMPLICIT',32}]} ->
%% this is an 'EXTERNAL' (or INSTANCE OF)
case Value of
[{identification,_}|_RestVal] ->
to_EXTERNAL1990(S,Value);
_ ->
Value
end;
_ ->
Value
end.
validate_sequenceof(_S,_Value,_Components,_Constr) ->
ok.
validate_choice(_S,_Value,_Components,_Constr) ->
ok.
validate_set(_S,_Value,_Components,_Constr) ->
ok.
validate_setof(_S,_Value,_Components,_Constr) ->
ok.
to_EXTERNAL1990(S,[{identification,{'CHOICE',{syntax,Stx}}}|Rest]) ->
to_EXTERNAL1990(S,Rest,[{'direct-reference',Stx}]);
to_EXTERNAL1990(S,[{identification,{'CHOICE',{'presentation-context-id',I}}}|Rest]) ->
to_EXTERNAL1990(S,Rest,[{'indirect-reference',I}]);
to_EXTERNAL1990(S,[{identification,{'CHOICE',{'context-negotiation',[{_,PCid},{_,TrStx}]}}}|Rest]) ->
to_EXTERNAL1990(S,Rest,[{'indirect-reference',PCid},{'direct-reference',TrStx}]);
to_EXTERNAL1990(S,_) ->
error({value,"illegal value in EXTERNAL type",S}).
to_EXTERNAL1990(S,[V={'data-value-descriptor',_}|Rest],Acc) ->
to_EXTERNAL1990(S,Rest,[V|Acc]);
to_EXTERNAL1990(_S,[{'data-value',Val}],Acc) ->
Encoding = {encoding,{'CHOICE',{'octet-aligned',Val}}},
lists:reverse([Encoding|Acc]);
to_EXTERNAL1990(S,_,_) ->
error({value,"illegal value in EXTERNAL type",S}).
%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%
%% Functions to normalize the default values of SEQUENCE
%% and SET components into Erlang valid format
%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%
normalize_value(_,_,mandatory,_) ->
mandatory;
normalize_value(_,_,'OPTIONAL',_) ->
'OPTIONAL';
normalize_value(S,Type,{'DEFAULT',Value},NameList) ->
case catch get_canonic_type(S,Type,NameList) of
{'BOOLEAN',CType,_} ->
normalize_boolean(S,Value,CType);
{'INTEGER',CType,_} ->
normalize_integer(S,Value,CType);
{'BIT STRING',CType,_} ->
normalize_bitstring(S,Value,CType);
{'OCTET STRING',CType,_} ->
normalize_octetstring(S,Value,CType);
{'NULL',_CType,_} ->
%%normalize_null(Value);
'NULL';
{'OBJECT IDENTIFIER',_,_} ->
normalize_objectidentifier(S,Value);
{'ObjectDescriptor',_,_} ->
normalize_objectdescriptor(Value);
{'REAL',_,_} ->
normalize_real(Value);
{'ENUMERATED',CType,_} ->
normalize_enumerated(Value,CType);
{'CHOICE',CType,NewNameList} ->
normalize_choice(S,Value,CType,NewNameList);
{'SEQUENCE',CType,NewNameList} ->
normalize_sequence(S,Value,CType,NewNameList);
{'SEQUENCE OF',CType,NewNameList} ->
normalize_seqof(S,Value,CType,NewNameList);
{'SET',CType,NewNameList} ->
normalize_set(S,Value,CType,NewNameList);
{'SET OF',CType,NewNameList} ->
normalize_setof(S,Value,CType,NewNameList);
{restrictedstring,CType,_} ->
normalize_restrictedstring(S,Value,CType);
_ ->
io:format("WARNING: could not check default value ~p~n",[Value]),
Value
end;
normalize_value(S,Type,Val,NameList) ->
normalize_value(S,Type,{'DEFAULT',Val},NameList).
normalize_boolean(S,{Name,Bool},CType) when atom(Name) ->
normalize_boolean(S,Bool,CType);
normalize_boolean(_,true,_) ->
true;
normalize_boolean(_,false,_) ->
false;
normalize_boolean(S,Bool=#'Externalvaluereference'{},CType) ->
get_normalized_value(S,Bool,CType,fun normalize_boolean/3,[]);
normalize_boolean(_,Other,_) ->
throw({error,{asn1,{'invalid default value',Other}}}).
normalize_integer(_S,Int,_) when integer(Int) ->
Int;
normalize_integer(_S,{Name,Int},_) when atom(Name),integer(Int) ->
Int;
normalize_integer(S,{Name,Int=#'Externalvaluereference'{}},
Type) when atom(Name) ->
normalize_integer(S,Int,Type);
normalize_integer(S,Int=#'Externalvaluereference'{value=Name},Type) ->
case Type of
NNL when list(NNL) ->
case lists:keysearch(Name,1,NNL) of
{value,{Name,Val}} ->
Val;
false ->
get_normalized_value(S,Int,Type,
fun normalize_integer/3,[])
end;
_ ->
get_normalized_value(S,Int,Type,fun normalize_integer/3,[])
end;
normalize_integer(_,Int,_) ->
exit({'Unknown INTEGER value',Int}).
normalize_bitstring(S,Value,Type)->
%% There are four different Erlang formats of BIT STRING:
%% 1 - a list of ones and zeros.
%% 2 - a list of atoms.
%% 3 - as an integer, for instance in hexadecimal form.
%% 4 - as a tuple {Unused, Binary} where Unused is an integer
%% and tells how many bits of Binary are unused.
%%
%% normalize_bitstring/3 transforms Value according to:
%% A to 3,
%% B to 1,
%% C to 1 or 3
%% D to 2,
%% Value can be on format:
%% A - {hstring, String}, where String is a hexadecimal string.
%% B - {bstring, String}, where String is a string on bit format
%% C - #'Externalvaluereference'{value=V}, where V is a defined value
%% D - list of #'Externalvaluereference', where each value component
%% is an identifier corresponing to NamedBits in Type.
case Value of
{hstring,String} when list(String) ->
hstring_to_int(String);
{bstring,String} when list(String) ->
bstring_to_bitlist(String);
Rec when record(Rec,'Externalvaluereference') ->
get_normalized_value(S,Value,Type,
fun normalize_bitstring/3,[]);
RecList when list(RecList) ->
case Type of
NBL when list(NBL) ->
F = fun(#'Externalvaluereference'{value=Name}) ->
case lists:keysearch(Name,1,NBL) of
{value,{Name,_}} ->
Name;
Other ->
throw({error,Other})
end;
(Other) ->
throw({error,Other})
end,
case catch lists:map(F,RecList) of
{error,Reason} ->
io:format("WARNING: default value not "
"compatible with type definition ~p~n",
[Reason]),
Value;
NewList ->
NewList
end;
_ ->
io:format("WARNING: default value not "
"compatible with type definition ~p~n",
[RecList]),
Value
end;
{Name,String} when atom(Name) ->
normalize_bitstring(S,String,Type);
Other ->
io:format("WARNING: illegal default value ~p~n",[Other]),
Value
end.
hstring_to_int(L) when list(L) ->
hstring_to_int(L,0).
hstring_to_int([H|T],Acc) when H >= $A, H =< $F ->
hstring_to_int(T,(Acc bsl 4) + (H - $A + 10) ) ;
hstring_to_int([H|T],Acc) when H >= $0, H =< $9 ->
hstring_to_int(T,(Acc bsl 4) + (H - $0));
hstring_to_int([],Acc) ->
Acc.
bstring_to_bitlist([H|T]) when H == $0; H == $1 ->
[H - $0 | bstring_to_bitlist(T)];
bstring_to_bitlist([]) ->
[].
%% normalize_octetstring/1 changes representation of input Value to a
%% list of octets.
%% Format of Value is one of:
%% {bstring,String} each element in String corresponds to one bit in an octet
%% {hstring,String} each element in String corresponds to one byte in an octet
%% #'Externalvaluereference'
normalize_octetstring(S,Value,CType) ->
case Value of
{bstring,String} ->
bstring_to_octetlist(String);
{hstring,String} ->
hstring_to_octetlist(String);
Rec when record(Rec,'Externalvaluereference') ->
get_normalized_value(S,Value,CType,
fun normalize_octetstring/3,[]);
{Name,String} when atom(Name) ->
normalize_octetstring(S,String,CType);
List when list(List) ->
%% check if list elements are valid octet values
lists:map(fun([])-> ok;
(H)when H > 255->
io:format("WARNING: not legal octet value ~p in OCTET STRING, ~p~n",[H,List]);
(_)-> ok
end, List),
List;
Other ->
io:format("WARNING: unknown default value ~p~n",[Other]),
Value
end.
bstring_to_octetlist([]) ->
[];
bstring_to_octetlist([H|T]) when H == $0 ; H == $1 ->
bstring_to_octetlist(T,6,[(H - $0) bsl 7]).
bstring_to_octetlist([H|T],0,[Hacc|Tacc]) when H == $0; H == $1 ->
bstring_to_octetlist(T, 7, [0,Hacc + (H -$0)| Tacc]);
bstring_to_octetlist([H|T],BSL,[Hacc|Tacc]) when H == $0; H == $1 ->
bstring_to_octetlist(T, BSL-1, [Hacc + ((H - $0) bsl BSL)| Tacc]);
bstring_to_octetlist([],7,[0|Acc]) ->
lists:reverse(Acc);
bstring_to_octetlist([],_,Acc) ->
lists:reverse(Acc).
hstring_to_octetlist([]) ->
[];
hstring_to_octetlist(L) ->
hstring_to_octetlist(L,4,[]).
hstring_to_octetlist([H|T],0,[Hacc|Tacc]) when H >= $A, H =< $F ->
hstring_to_octetlist(T,4,[Hacc + (H - $A + 10)|Tacc]);
hstring_to_octetlist([H|T],BSL,Acc) when H >= $A, H =< $F ->
hstring_to_octetlist(T,0,[(H - $A + 10) bsl BSL|Acc]);
hstring_to_octetlist([H|T],0,[Hacc|Tacc]) when H >= $0; H =< $9 ->
hstring_to_octetlist(T,4,[Hacc + (H - $0)|Tacc]);
hstring_to_octetlist([H|T],BSL,Acc) when H >= $0; H =< $9 ->
hstring_to_octetlist(T,0,[(H - $0) bsl BSL|Acc]);
hstring_to_octetlist([],_,Acc) ->
lists:reverse(Acc).
normalize_objectidentifier(S,Value) ->
validate_objectidentifier(S,Value,[]).
normalize_objectdescriptor(Value) ->
Value.
normalize_real(Value) ->
Value.
normalize_enumerated(#'Externalvaluereference'{value=V},CType)
when list(CType) ->
normalize_enumerated2(V,CType);
normalize_enumerated(Value,CType) when atom(Value),list(CType) ->
normalize_enumerated2(Value,CType);
normalize_enumerated({Name,EnumV},CType) when atom(Name) ->
normalize_enumerated(EnumV,CType);
normalize_enumerated(Value,{CType1,CType2}) when list(CType1), list(CType2)->
normalize_enumerated(Value,CType1++CType2);
normalize_enumerated(V,CType) ->
io:format("WARNING: Enumerated unknown type ~p~n",[CType]),
V.
normalize_enumerated2(V,Enum) ->
case lists:keysearch(V,1,Enum) of
{value,{Val,_}} -> Val;
_ ->
io:format("WARNING: Enumerated value is not correct ~p~n",[V]),
V
end.
normalize_choice(S,{'CHOICE',{C,V}},CType,NameList) when atom(C) ->
Value =
case V of
Rec when record(Rec,'Externalvaluereference') ->
get_normalized_value(S,V,CType,
fun normalize_choice/4,
[NameList]);
_ -> V
end,
case catch lists:keysearch(C,#'ComponentType'.name,CType) of
{value,#'ComponentType'{typespec=CT,name=Name}} ->
{C,normalize_value(S,CT,{'DEFAULT',Value},
[Name|NameList])};
Other ->
io:format("WARNING: Wrong format of type/value ~p/~p~n",
[Other,Value]),
{C,Value}
end;
normalize_choice(S,{'DEFAULT',ValueList},CType,NameList) ->
lists:map(fun(X)-> normalize_choice(S,X,CType,NameList) end, ValueList);
normalize_choice(S,Val=#'Externalvaluereference'{},CType,NameList) ->
{_,#valuedef{value=V}}=get_referenced_type(S,Val),
normalize_choice(S,{'CHOICE',V},CType,NameList);
% get_normalized_value(S,Val,CType,fun normalize_choice/4,[NameList]);
normalize_choice(S,{Name,ChoiceVal},CType,NameList)
when atom(Name) ->
normalize_choice(S,ChoiceVal,CType,NameList).
normalize_sequence(S,{Name,Value},Components,NameList)
when atom(Name),list(Value) ->
normalize_sequence(S,Value,Components,NameList);
normalize_sequence(S,Value,Components,NameList) ->
normalized_record('SEQUENCE',S,Value,Components,NameList).
normalize_set(S,{Name,Value},Components,NameList)
when atom(Name),list(Value) ->
normalized_record('SET',S,Value,Components,NameList);
normalize_set(S,Value,Components,NameList) ->
normalized_record('SET',S,Value,Components,NameList).
normalized_record(SorS,S,Value,Components,NameList) ->
NewName = list_to_atom(asn1ct_gen:list2name(NameList)),
NoComps = length(Components),
case normalize_seq_or_set(SorS,S,Value,Components,NameList,[]) of
ListOfVals when length(ListOfVals) == NoComps ->
list_to_tuple([NewName|ListOfVals]);
_ ->
error({type,{illegal,default,value,Value},S})
end.
normalize_seq_or_set(SorS,S,[{Cname,V}|Vs],
[#'ComponentType'{name=Cname,typespec=TS}|Cs],
NameList,Acc) ->
NewNameList =
case TS#type.def of
#'Externaltypereference'{type=TName} ->
[TName];
_ -> [Cname|NameList]
end,
NVal = normalize_value(S,TS,{'DEFAULT',V},NewNameList),
normalize_seq_or_set(SorS,S,Vs,Cs,NameList,[NVal|Acc]);
normalize_seq_or_set(SorS,S,Values=[{_Cname1,_V}|_Vs],
[#'ComponentType'{prop='OPTIONAL'}|Cs],
NameList,Acc) ->
normalize_seq_or_set(SorS,S,Values,Cs,NameList,[asn1_NOVALUE|Acc]);
normalize_seq_or_set(SorS,S,Values=[{_Cname1,_V}|_Vs],
[#'ComponentType'{name=Cname2,typespec=TS,
prop={'DEFAULT',Value}}|Cs],
NameList,Acc) ->
NewNameList =
case TS#type.def of
#'Externaltypereference'{type=TName} ->
[TName];
_ -> [Cname2|NameList]
end,
NVal = normalize_value(S,TS,{'DEFAULT',Value},NewNameList),
normalize_seq_or_set(SorS,S,Values,Cs,NameList,[NVal|Acc]);
normalize_seq_or_set(_SorS,_S,[],[],_,Acc) ->
lists:reverse(Acc);
%% If default value is {} ComponentTypes in SEQUENCE are marked DEFAULT
%% or OPTIONAL (or the type is defined SEQUENCE{}, which is handled by
%% the previous case).
normalize_seq_or_set(SorS,S,[],
[#'ComponentType'{name=Name,typespec=TS,
prop={'DEFAULT',Value}}|Cs],
NameList,Acc) ->
NewNameList =
case TS#type.def of
#'Externaltypereference'{type=TName} ->
[TName];
_ -> [Name|NameList]
end,
NVal = normalize_value(S,TS,{'DEFAULT',Value},NewNameList),
normalize_seq_or_set(SorS,S,[],Cs,NameList,[NVal|Acc]);
normalize_seq_or_set(SorS,S,[],[#'ComponentType'{prop='OPTIONAL'}|Cs],
NameList,Acc) ->
normalize_seq_or_set(SorS,S,[],Cs,NameList,[asn1_NOVALUE|Acc]);
normalize_seq_or_set(SorS,S,Value=#'Externalvaluereference'{},
Cs,NameList,Acc) ->
get_normalized_value(S,Value,Cs,fun normalize_seq_or_set/6,
[SorS,NameList,Acc]);
normalize_seq_or_set(_SorS,S,V,_,_,_) ->
error({type,{illegal,default,value,V},S}).
normalize_seqof(S,Value,Type,NameList) ->
normalize_s_of('SEQUENCE OF',S,Value,Type,NameList).
normalize_setof(S,Value,Type,NameList) ->
normalize_s_of('SET OF',S,Value,Type,NameList).
normalize_s_of(SorS,S,Value,Type,NameList) when list(Value) ->
DefValueList = lists:map(fun(X) -> {'DEFAULT',X} end,Value),
Suffix = asn1ct_gen:constructed_suffix(SorS,Type),
Def = Type#type.def,
InnerType = asn1ct_gen:get_inner(Def),
WhatKind = asn1ct_gen:type(InnerType),
NewNameList =
case WhatKind of
{constructed,bif} ->
[Suffix|NameList];
#'Externaltypereference'{type=Name} ->
[Name];
_ -> []
end,
NormFun = fun (X) -> normalize_value(S,Type,X,
NewNameList) end,
case catch lists:map(NormFun, DefValueList) of
List when list(List) ->
List;
_ ->
io:format("WARNING: ~p could not handle value ~p~n",
[SorS,Value]),
Value
end;
normalize_s_of(SorS,S,Value,Type,NameList)
when record(Value,'Externalvaluereference') ->
get_normalized_value(S,Value,Type,fun normalize_s_of/5,
[SorS,NameList]).
% case catch get_referenced_type(S,Value) of
% {_,#valuedef{value=V}} ->
% normalize_s_of(SorS,S,V,Type);
% {error,Reason} ->
% io:format("WARNING: ~p could not handle value ~p~n",
% [SorS,Value]),
% Value;
% {_,NewVal} ->
% normalize_s_of(SorS,S,NewVal,Type);
% _ ->
% io:format("WARNING: ~p could not handle value ~p~n",
% [SorS,Value]),
% Value
% end.
%% normalize_restrictedstring handles all format of restricted strings.
%% tuple case
normalize_restrictedstring(_S,[Int1,Int2],_) when integer(Int1),integer(Int2) ->
{Int1,Int2};
%% quadruple case
normalize_restrictedstring(_S,[Int1,Int2,Int3,Int4],_) when integer(Int1),
integer(Int2),
integer(Int3),
integer(Int4) ->
{Int1,Int2,Int3,Int4};
%% character string list case
normalize_restrictedstring(S,[H|T],CType) when list(H);tuple(H) ->
[normalize_restrictedstring(S,H,CType)|normalize_restrictedstring(S,T,CType)];
%% character sting case
normalize_restrictedstring(_S,CString,_) when list(CString) ->
Fun =
fun(X) ->
if
$X =< 255, $X >= 0 ->
ok;
true ->
io:format("WARNING: illegal character in string"
" ~p~n",[X])
end
end,
lists:foreach(Fun,CString),
CString;
%% definedvalue case or argument in a parameterized type
normalize_restrictedstring(S,ERef,CType) when record(ERef,'Externalvaluereference') ->
get_normalized_value(S,ERef,CType,
fun normalize_restrictedstring/3,[]);
%%
normalize_restrictedstring(S,{Name,Val},CType) when atom(Name) ->
normalize_restrictedstring(S,Val,CType).
get_normalized_value(S,Val,Type,Func,AddArg) ->
case catch get_referenced_type(S,Val) of
{_,#valuedef{type=_T,value=V}} ->
%% should check that Type and T equals
call_Func(S,V,Type,Func,AddArg);
{error,_} ->
io:format("WARNING: default value not "
"comparable ~p~n",[Val]),
Val;
{_,NewVal} ->
call_Func(S,NewVal,Type,Func,AddArg);
_ ->
io:format("WARNING: default value not "
"comparable ~p~n",[Val]),
Val
end.
call_Func(S,Val,Type,Func,ArgList) ->
case ArgList of
[] ->
Func(S,Val,Type);
[LastArg] ->
Func(S,Val,Type,LastArg);
[Arg1,LastArg1] ->
Func(Arg1,S,Val,Type,LastArg1);
[Arg1,LastArg1,LastArg2] ->
Func(Arg1,S,Val,Type,LastArg1,LastArg2)
end.
get_canonic_type(S,Type,NameList) ->
{InnerType,NewType,NewNameList} =
case Type#type.def of
Name when atom(Name) ->
{Name,Type,NameList};
Ref when record(Ref,'Externaltypereference') ->
{_,#typedef{name=Name,typespec=RefedType}} =
get_referenced_type(S,Ref),
get_canonic_type(S,RefedType,[Name]);
{Name,T} when atom(Name) ->
{Name,T,NameList};
Seq when record(Seq,'SEQUENCE') ->
{'SEQUENCE',Seq#'SEQUENCE'.components,NameList};
Set when record(Set,'SET') ->
{'SET',Set#'SET'.components,NameList}
end,
{asn1ct_gen:unify_if_string(InnerType),NewType,NewNameList}.
check_ptype(_S,Type,Ts) when record(Ts,type) ->
%Tag = Ts#type.tag,
%Constr = Ts#type.constraint,
Def = Ts#type.def,
NewDef=
case Def of
Seq when record(Seq,'SEQUENCE') ->
#newt{type=Seq#'SEQUENCE'{pname=Type#ptypedef.name}};
Set when record(Set,'SET') ->
#newt{type=Set#'SET'{pname=Type#ptypedef.name}};
_Other ->
#newt{}
end,
Ts2 = case NewDef of
#newt{type=unchanged} ->
Ts;
#newt{type=TDef}->
Ts#type{def=TDef}
end,
Ts2.
% check_type(S,Type,ObjSpec={{objectclassname,_},_}) ->
% check_class(S,ObjSpec);
check_type(_S,Type,Ts) when record(Type,typedef),
(Type#typedef.checked==true) ->
Ts;
check_type(_S,Type,Ts) when record(Type,typedef),
(Type#typedef.checked==idle) -> % the check is going on
Ts;
check_type(S=#state{recordtopname=TopName},Type,Ts) when record(Ts,type) ->
{Def,Tag,Constr} =
case match_parameters(Ts#type.def,S#state.parameters) of
#type{constraint=_Ctmp,def=Dtmp} ->
{Dtmp,Ts#type.tag,Ts#type.constraint};
Dtmp ->
{Dtmp,Ts#type.tag,Ts#type.constraint}
end,
TempNewDef = #newt{type=Def,tag=Tag,constraint=Constr},
TestFun =
fun(Tref) ->
{_,MaybeChoice} = get_referenced_type(S,Tref),
case catch((MaybeChoice#typedef.typespec)#type.def) of
{'CHOICE',_} ->
maybe_illicit_implicit_tag(choice,Tag);
'ANY' ->
maybe_illicit_implicit_tag(open_type,Tag);
'ANY DEFINED BY' ->
maybe_illicit_implicit_tag(open_type,Tag);
'ASN1_OPEN_TYPE' ->
maybe_illicit_implicit_tag(open_type,Tag);
_ ->
Tag
end
end,
NewDef=
case Def of
Ext when record(Ext,'Externaltypereference') ->
{_,RefTypeDef} = get_referenced_type(S,Ext),
% case RefTypeDef of
% Class when record(Class,classdef) ->
% throw({asn1_class,Class});
% _ -> ok
% end,
case is_class(S,RefTypeDef) of
true -> throw({asn1_class,RefTypeDef});
_ -> ok
end,
Ct = TestFun(Ext),
RefType =
%case S#state.erule of
% ber_bin_v2 ->
case RefTypeDef#typedef.checked of
true ->
RefTypeDef#typedef.typespec;
_ ->
NewRefTypeDef1 = RefTypeDef#typedef{checked=idle},
asn1_db:dbput(S#state.mname,
NewRefTypeDef1#typedef.name,NewRefTypeDef1),
RefType1 =
check_type(S,RefTypeDef,RefTypeDef#typedef.typespec),
NewRefTypeDef2 =
RefTypeDef#typedef{checked=true,typespec = RefType1},
asn1_db:dbput(S#state.mname,
NewRefTypeDef2#typedef.name,NewRefTypeDef2),
%% update the type and mark as checked
RefType1
end,
% _ -> RefTypeDef#typedef.typespec
% end,
case asn1ct_gen:prim_bif(asn1ct_gen:get_inner(RefType#type.def)) of
true ->
%% Here we expand to a built in type and inline it
TempNewDef#newt{
type=
RefType#type.def,
tag=
merge_tags(Ct,RefType#type.tag),
constraint=
merge_constraints(check_constraints(S,Constr),
RefType#type.constraint)};
_ ->
%% Here we only expand the tags and keep the ext ref
TempNewDef#newt{
type=
check_externaltypereference(S,Ext),
tag =
case S#state.erule of
ber_bin_v2 ->
merge_tags(Ct,RefType#type.tag);
_ ->
Ct
end
}
end;
'ANY' ->
Ct=maybe_illicit_implicit_tag(open_type,Tag),
TempNewDef#newt{type='ASN1_OPEN_TYPE',tag=Ct};
{'ANY_DEFINED_BY',_} ->
Ct=maybe_illicit_implicit_tag(open_type,Tag),
TempNewDef#newt{type='ASN1_OPEN_TYPE',tag=Ct};
'INTEGER' ->
check_integer(S,[],Constr),
TempNewDef#newt{tag=
merge_tags(Tag,?TAG_PRIMITIVE(?N_INTEGER))};
{'INTEGER',NamedNumberList} ->
TempNewDef#newt{type={'INTEGER',check_integer(S,NamedNumberList,Constr)},
tag=
merge_tags(Tag,?TAG_PRIMITIVE(?N_INTEGER))};
{'BIT STRING',NamedNumberList} ->
NewL = check_bitstring(S,NamedNumberList,Constr),
%% erlang:display({asn1ct_check,NamedNumberList,NewL}),
TempNewDef#newt{type={'BIT STRING',NewL},
tag=
merge_tags(Tag,?TAG_PRIMITIVE(?N_BIT_STRING))};
'NULL' ->
TempNewDef#newt{tag=
merge_tags(Tag,?TAG_PRIMITIVE(?N_NULL))};
'OBJECT IDENTIFIER' ->
check_objectidentifier(S,Constr),
TempNewDef#newt{tag=
merge_tags(Tag,?TAG_PRIMITIVE(?N_OBJECT_IDENTIFIER))};
'ObjectDescriptor' ->
TempNewDef#newt{tag=
merge_tags(Tag,?TAG_PRIMITIVE(?N_OBJECT_DESCRIPTOR))};
'EXTERNAL' ->
%% AssociatedType = asn1_db:dbget(S#state.mname,'EXTERNAL'),
%% #newt{type=check_type(S,Type,AssociatedType)};
put(external,unchecked),
TempNewDef#newt{type=
#'Externaltypereference'{module=S#state.mname,
type='EXTERNAL'},
tag=
merge_tags(Tag,?TAG_CONSTRUCTED(?N_EXTERNAL))};
{'INSTANCE OF',DefinedObjectClass,Constraint} ->
%% check that DefinedObjectClass is of TYPE-IDENTIFIER class
%% If Constraint is empty make it the general INSTANCE OF type
%% If Constraint is not empty make an inlined type
%% convert INSTANCE OF to the associated type
IOFDef=check_instance_of(S,DefinedObjectClass,Constraint),
TempNewDef#newt{type=IOFDef,
tag=merge_tags(Tag,?TAG_CONSTRUCTED(?N_INSTANCE_OF))};
{'ENUMERATED',NamedNumberList} ->
TempNewDef#newt{type=
{'ENUMERATED',
check_enumerated(S,NamedNumberList,Constr)},
tag=
merge_tags(Tag,?TAG_PRIMITIVE(?N_ENUMERATED))};
'EMBEDDED PDV' ->
% AssociatedType = asn1_db:dbget(S#state.mname,'EMBEDDED PDV'),
% CheckedType = check_type(S,Type,
% AssociatedType#typedef.typespec),
put(embedded_pdv,unchecked),
TempNewDef#newt{type=
#'Externaltypereference'{module=S#state.mname,
type='EMBEDDED PDV'},
tag=
merge_tags(Tag,?TAG_CONSTRUCTED(?N_EMBEDDED_PDV))};
'BOOLEAN'->
check_boolean(S,Constr),
TempNewDef#newt{tag=
merge_tags(Tag,?TAG_PRIMITIVE(?N_BOOLEAN))};
'OCTET STRING' ->
check_octetstring(S,Constr),
TempNewDef#newt{tag=
merge_tags(Tag,?TAG_PRIMITIVE(?N_OCTET_STRING))};
'NumericString' ->
check_restrictedstring(S,Def,Constr),
TempNewDef#newt{tag=
merge_tags(Tag,?TAG_PRIMITIVE(?N_NumericString))};
'TeletexString' ->
check_restrictedstring(S,Def,Constr),
TempNewDef#newt{tag=
merge_tags(Tag,?TAG_PRIMITIVE(?N_TeletexString))};
'VideotexString' ->
check_restrictedstring(S,Def,Constr),
TempNewDef#newt{tag=
merge_tags(Tag,?TAG_PRIMITIVE(?N_VideotexString))};
'UTCTime' ->
TempNewDef#newt{tag=
merge_tags(Tag,?TAG_PRIMITIVE(?N_UTCTime))};
'GeneralizedTime' ->
TempNewDef#newt{tag=
merge_tags(Tag,?TAG_PRIMITIVE(?N_GeneralizedTime))};
'GraphicString' ->
check_restrictedstring(S,Def,Constr),
TempNewDef#newt{tag=
merge_tags(Tag,?TAG_PRIMITIVE(?N_GraphicString))};
'VisibleString' ->
check_restrictedstring(S,Def,Constr),
TempNewDef#newt{tag=
merge_tags(Tag,?TAG_PRIMITIVE(?N_VisibleString))};
'GeneralString' ->
check_restrictedstring(S,Def,Constr),
TempNewDef#newt{tag=
merge_tags(Tag,?TAG_PRIMITIVE(?N_GeneralString))};
'PrintableString' ->
check_restrictedstring(S,Def,Constr),
TempNewDef#newt{tag=
merge_tags(Tag,?TAG_PRIMITIVE(?N_PrintableString))};
'IA5String' ->
check_restrictedstring(S,Def,Constr),
TempNewDef#newt{tag=
merge_tags(Tag,?TAG_PRIMITIVE(?N_IA5String))};
'BMPString' ->
check_restrictedstring(S,Def,Constr),
TempNewDef#newt{tag=
merge_tags(Tag,?TAG_PRIMITIVE(?N_BMPString))};
'UniversalString' ->
check_restrictedstring(S,Def,Constr),
TempNewDef#newt{tag=
merge_tags(Tag,?TAG_PRIMITIVE(?N_UniversalString))};
'CHARACTER STRING' ->
% AssociatedType = asn1_db:dbget(S#state.mname,
% 'CHARACTER STRING'),
% CheckedType = check_type(S,Type,
% AssociatedType#typedef.typespec),
put(character_string,unchecked),
TempNewDef#newt{type=
#'Externaltypereference'{module=S#state.mname,
type='CHARACTER STRING'},
tag=
merge_tags(Tag,?TAG_CONSTRUCTED(?N_CHARACTER_STRING))};
Seq when record(Seq,'SEQUENCE') ->
RecordName =
case TopName of
[] ->
[Type#typedef.name];
_ ->
TopName
end,
{TableCInf,Components} =
check_sequence(S#state{recordtopname=
RecordName},
Type,Seq#'SEQUENCE'.components),
TempNewDef#newt{type=Seq#'SEQUENCE'{tablecinf=TableCInf,
components=Components},
tag=
merge_tags(Tag,?TAG_CONSTRUCTED(?N_SEQUENCE))};
{'SEQUENCE OF',Components} ->
TempNewDef#newt{type={'SEQUENCE OF',check_sequenceof(S,Type,Components)},
tag=
merge_tags(Tag,?TAG_CONSTRUCTED(?N_SEQUENCE))};
{'CHOICE',Components} ->
Ct = maybe_illicit_implicit_tag(choice,Tag),
TempNewDef#newt{type={'CHOICE',check_choice(S,Type,Components)},tag=Ct};
Set when record(Set,'SET') ->
RecordName=
case TopName of
[] ->
[Type#typedef.name];
_ ->
TopName
end,
{Sorted,TableCInf,Components} =
check_set(S#state{recordtopname=RecordName},
Type,Set#'SET'.components),
TempNewDef#newt{type=Set#'SET'{sorted=Sorted,
tablecinf=TableCInf,
components=Components},
tag=
merge_tags(Tag,?TAG_CONSTRUCTED(?N_SET))};
{'SET OF',Components} ->
TempNewDef#newt{type={'SET OF',check_setof(S,Type,Components)},
tag=
merge_tags(Tag,?TAG_CONSTRUCTED(?N_SET))};
%% This is a temporary hack until the full Information Obj Spec
%% in X.681 is supported
{{typereference,_,'TYPE-IDENTIFIER'},[{typefieldreference,_,'Type'}]} ->
Ct=maybe_illicit_implicit_tag(open_type,Tag),
TempNewDef#newt{type='ASN1_OPEN_TYPE',tag=Ct};
{#'Externaltypereference'{type='TYPE-IDENTIFIER'},
[{typefieldreference,_,'Type'}]} ->
Ct=maybe_illicit_implicit_tag(open_type,Tag),
TempNewDef#newt{type='ASN1_OPEN_TYPE',tag=Ct};
{pt,Ptype,ParaList} ->
%% Ptype might be a parameterized - type, object set or
%% value set. If it isn't a parameterized type notify the
%% calling function.
{_,Ptypedef} = get_referenced_type(S,Ptype),
notify_if_not_ptype(S,Ptypedef),
NewParaList = [match_parameters(TmpParam,S#state.parameters)||
TmpParam <- ParaList],
Instance = instantiate_ptype(S,Ptypedef,NewParaList),
TempNewDef#newt{type=Instance#type.def,
tag=merge_tags(Tag,Instance#type.tag),
constraint=Instance#type.constraint,
inlined=yes};
% {ClRef,FieldRefList} when record(ClRef,'Externaltypereference') ->
OCFT=#'ObjectClassFieldType'{class=ClRef} ->
%% this case occures in a SEQUENCE when
%% the type of the component is a ObjectClassFieldType
ClassSpec = check_class(S,ClRef),
NewTypeDef = maybe_open_type(S,ClassSpec,OCFT,Constr),
InnerTag = get_innertag(S,NewTypeDef),
MergedTag = merge_tags(Tag,InnerTag),
Ct =
case is_open_type(NewTypeDef) of
true ->
maybe_illicit_implicit_tag(open_type,MergedTag);
_ ->
MergedTag
end,
TempNewDef#newt{type=NewTypeDef,tag=Ct};
{valueset,Vtype} ->
TempNewDef#newt{type={valueset,check_type(S,Type,Vtype)}};
Other ->
exit({'cant check' ,Other})
end,
Ts2 = case NewDef of
#newt{type=unchanged} ->
Ts#type{def=Def};
#newt{type=TDef}->
Ts#type{def=TDef}
end,
NewTag = case NewDef of
#newt{tag=unchanged} ->
Tag;
#newt{tag=TT} ->
TT
end,
T3 = Ts2#type{tag = lists:map(fun(TempTag = #tag{type={default,TTx}}) ->
TempTag#tag{type=TTx};
(Else) -> Else end, NewTag)},
T4 = case NewDef of
#newt{constraint=unchanged} ->
T3#type{constraint=Constr};
#newt{constraint=NewConstr} ->
T3#type{constraint=NewConstr}
end,
T5 = T4#type{inlined=NewDef#newt.inlined},
T5#type{constraint=check_constraints(S,T5#type.constraint)}.
get_innertag(_S,#'ObjectClassFieldType'{type=Type}) ->
case Type of
#type{tag=Tag} -> Tag;
{fixedtypevaluefield,_,#type{tag=Tag}} -> Tag;
{TypeFieldName,_} when atom(TypeFieldName) -> [];
_ -> []
end;
get_innertag(_S,_) ->
[].
is_class(_S,#classdef{}) ->
true;
is_class(S,#typedef{typespec=#type{def=Eref}})
when record(Eref,'Externaltypereference')->
{_,NextDef} = get_referenced_type(S,Eref),
is_class(S,NextDef);
is_class(_,_) ->
false.
get_class_def(_S,CD=#classdef{}) ->
CD;
get_class_def(S,#typedef{typespec=#type{def=Eref}})
when record(Eref,'Externaltypereference') ->
{_,NextDef} = get_referenced_type(S,Eref),
get_class_def(S,NextDef).
maybe_illicit_implicit_tag(Kind,Tag) ->
case Tag of
[#tag{type='IMPLICIT'}|_T] ->
throw({error,{asn1,{implicit_tag_before,Kind}}});
[ChTag = #tag{type={default,_}}|T] ->
case Kind of
open_type ->
[ChTag#tag{type='EXPLICIT',form=32}|T]; %X.680 30.6c, X.690 8.14.2
choice ->
[ChTag#tag{type='EXPLICIT',form=32}|T] % X.680 28.6 c, 30.6c
end;
_ ->
Tag % unchanged
end.
%% maybe_open_type/2 -> {ClassSpec,FieldRefList} | 'ASN1_OPEN_TYPE'
%% if the FieldRefList points out a typefield and the class don't have
%% any UNIQUE field, so that a component relation constraint cannot specify
%% the type of a typefield, return 'ASN1_OPEN_TYPE', otherwise return
%% {ClassSpec,FieldRefList}.
maybe_open_type(S,ClassSpec=#objectclass{fields=Fs},
OCFT=#'ObjectClassFieldType'{fieldname=FieldRefList},
Constr) ->
Type = get_ObjectClassFieldType(S,Fs,FieldRefList),
FieldNames=get_referenced_fieldname(FieldRefList),
case lists:last(FieldRefList) of
{valuefieldreference,_} ->
OCFT#'ObjectClassFieldType'{class=ClassSpec,
fieldname=FieldNames,
type=Type};
{typefieldreference,_} ->
case {catch get_unique_fieldname(#classdef{typespec=ClassSpec}),
asn1ct_gen:get_constraint(Constr,componentrelation)}of
{Tuple,_} when tuple(Tuple) ->
OCFT#'ObjectClassFieldType'{class=ClassSpec,
fieldname=FieldNames,
type='ASN1_OPEN_TYPE'};
{_,no} ->
OCFT#'ObjectClassFieldType'{class=ClassSpec,
fieldname=FieldNames,
type='ASN1_OPEN_TYPE'};
_ ->
OCFT#'ObjectClassFieldType'{class=ClassSpec,
fieldname=FieldNames,
type=Type}
end
end.
is_open_type(#'ObjectClassFieldType'{type='ASN1_OPEN_TYPE'}) ->
true;
is_open_type(#'ObjectClassFieldType'{}) ->
false.
notify_if_not_ptype(S,#pvaluesetdef{type=Type}) ->
case Type#type.def of
Ref when record(Ref,'Externaltypereference') ->
case get_referenced_type(S,Ref) of
{_,#classdef{}} ->
throw(pobjectsetdef);
{_,#typedef{}} ->
throw(pvalueset)
end;
T when record(T,type) -> % this must be a value set
throw(pvalueset)
end;
notify_if_not_ptype(_S,#ptypedef{}) ->
ok.
% fix me
instantiate_ptype(S,Ptypedef,ParaList) ->
#ptypedef{args=Args,typespec=Type} = Ptypedef,
% Args = get_pt_args(Ptypedef),
% Type = get_pt_spec(Ptypedef),
MatchedArgs = match_args(Args, ParaList, []),
NewS = S#state{type=Type,parameters=MatchedArgs,abscomppath=[]},
%The abscomppath must be empty since a table constraint in a
%parameterized type only can refer to components within the type
check_type(NewS, Ptypedef, Type).
get_pt_args(#ptypedef{args=Args}) ->
Args;
get_pt_args(#pvaluesetdef{args=Args}) ->
Args;
get_pt_args(#pvaluedef{args=Args}) ->
Args;
get_pt_args(#pobjectdef{args=Args}) ->
Args;
get_pt_args(#pobjectsetdef{args=Args}) ->
Args.
get_pt_spec(#ptypedef{typespec=Type}) ->
Type;
get_pt_spec(#pvaluedef{value=Value}) ->
Value;
get_pt_spec(#pvaluesetdef{valueset=VS}) ->
VS;
get_pt_spec(#pobjectdef{def=Def}) ->
Def;
get_pt_spec(#pobjectsetdef{def=Def}) ->
Def.
match_args([FormArg|Ft], [ActArg|At], Acc) ->
match_args(Ft, At, [{FormArg,ActArg}|Acc]);
match_args([], [], Acc) ->
lists:reverse(Acc);
match_args(_, _, _) ->
throw({error,{asn1,{wrong_number_of_arguments}}}).
check_constraints(S,C) when list(C) ->
check_constraints(S, C, []);
check_constraints(S,C) when record(C,constraint) ->
check_constraints(S, C#constraint.c, []).
resolv_tuple_or_list(S,List) when list(List) ->
lists:map(fun(X)->resolv_value(S,X) end, List);
resolv_tuple_or_list(S,{Lb,Ub}) ->
{resolv_value(S,Lb),resolv_value(S,Ub)}.
%%%-----------------------------------------
%% If the constraint value is a defined value the valuename
%% is replaced by the actual value
%%
resolv_value(S,Val) ->
case match_parameters(Val, S#state.parameters) of
Id -> % unchanged
resolv_value1(S,Id);
Other ->
resolv_value(S,Other)
end.
resolv_value1(S = #state{mname=M,inputmodules=InpMods},
V=#'Externalvaluereference'{pos=Pos,module=ExtM,value=Name}) ->
case ExtM of
M -> resolv_value2(S,M,Name,Pos);
_ ->
case lists:member(ExtM,InpMods) of
true ->
resolv_value2(S,M,Name,Pos);
false ->
V
end
end;
resolv_value1(S,{gt,V}) ->
case V of
Int when integer(Int) ->
V + 1;
#valuedef{value=Int} ->
1 + resolv_value(S,Int);
Other ->
throw({error,{asn1,{undefined_type_or_value,Other}}})
end;
resolv_value1(S,{lt,V}) ->
case V of
Int when integer(Int) ->
V - 1;
#valuedef{value=Int} ->
resolv_value(S,Int) - 1;
Other ->
throw({error,{asn1,{undefined_type_or_value,Other}}})
end;
resolv_value1(S,{'ValueFromObject',{object,Object},[{valuefieldreference,
FieldName}]}) ->
%% FieldName can hold either a fixed-type value or a variable-type value
%% Object is a DefinedObject, i.e. a #'Externaltypereference'
{_,ObjTDef} = get_referenced_type(S,Object),
TS = check_object(S,ObjTDef,ObjTDef#typedef.typespec),
{_,_,Components} = TS#'Object'.def,
case lists:keysearch(FieldName,1,Components) of
{value,{_,#valuedef{value=Val}}} ->
Val;
_ ->
error({value,"illegal value in constraint",S})
end;
% resolv_value1(S,{'ValueFromObject',{po,Object,Params},FieldName}) ->
% %% FieldName can hold either a fixed-type value or a variable-type value
% %% Object is a ParameterizedObject
resolv_value1(_,V) ->
V.
resolv_value2(S,ModuleName,Name,Pos) ->
case asn1_db:dbget(ModuleName,Name) of
undefined ->
case imported(S,Name) of
{ok,Imodule} ->
{_,V2} = get_referenced(S,Imodule,Name,Pos),
V2#valuedef.value;
_ ->
throw({error,{asn1,{undefined_type_or_value,Name}}})
end;
Val ->
Val#valuedef.value
end.
check_constraints(S,[{'ContainedSubtype',Type} | Rest], Acc) ->
{_,CTDef} = get_referenced_type(S,Type#type.def),
CType = check_type(S,S#state.tname,CTDef#typedef.typespec),
check_constraints(S,Rest,CType#type.constraint ++ Acc);
check_constraints(S,[C | Rest], Acc) ->
check_constraints(S,Rest,[check_constraint(S,C) | Acc]);
check_constraints(S,[],Acc) ->
% io:format("Acc: ~p~n",[Acc]),
C = constraint_merge(S,lists:reverse(Acc)),
% io:format("C: ~p~n",[C]),
lists:flatten(C).
range_check(F={FixV,FixV}) ->
% FixV;
F;
range_check(VR={Lb,Ub}) when Lb < Ub ->
VR;
range_check(Err={_,_}) ->
throw({error,{asn1,{illegal_size_constraint,Err}}});
range_check(Value) ->
Value.
check_constraint(S,Ext) when record(Ext,'Externaltypereference') ->
check_externaltypereference(S,Ext);
check_constraint(S,{'SizeConstraint',{Lb,Ub}})
when list(Lb);tuple(Lb),size(Lb)==2 ->
case Lb of
#'Externalvaluereference'{} ->
check_constraint(S,{'SizeConstraint',{resolv_value(S,Lb),Ub}});
_ ->
NewLb = range_check(resolv_tuple_or_list(S,Lb)),
NewUb = range_check(resolv_tuple_or_list(S,Ub)),
{'SizeConstraint',{NewLb,NewUb}}
end;
check_constraint(S,{'SizeConstraint',{Lb,Ub}}) ->
case {resolv_value(S,Lb),resolv_value(S,Ub)} of
{FixV,FixV} ->
{'SizeConstraint',FixV};
{Low,High} when Low < High ->
{'SizeConstraint',{Low,High}};
Err ->
throw({error,{asn1,{illegal_size_constraint,Err}}})
end;
check_constraint(S,{'SizeConstraint',Lb}) ->
{'SizeConstraint',resolv_value(S,Lb)};
check_constraint(S,{'SingleValue', L}) when list(L) ->
F = fun(A) -> resolv_value(S,A) end,
{'SingleValue',lists:map(F,L)};
check_constraint(S,{'SingleValue', V}) when integer(V) ->
Val = resolv_value(S,V),
%% [{'SingleValue',Val},{'ValueRange',{Val,Val}}]; % Why adding value range?
{'SingleValue',Val};
check_constraint(S,{'SingleValue', V}) ->
{'SingleValue',resolv_value(S,V)};
check_constraint(S,{'ValueRange', {Lb, Ub}}) ->
{'ValueRange',{resolv_value(S,Lb),resolv_value(S,Ub)}};
%%check_constraint(S,{'ContainedSubtype',Type}) ->
%% #typedef{typespec=TSpec} =
%% check_type(S,S#state.tname,get_referenced_type(S,Type#type.def)),
%% [C] = TSpec#type.constraint,
%% C;
check_constraint(S,{valueset,Type}) ->
{valueset,check_type(S,S#state.tname,Type)};
check_constraint(S,{simpletable,Type}) ->
OSName = (Type#type.def)#'Externaltypereference'.type,
C = match_parameters(Type#type.def,S#state.parameters),
case C of
#'Externaltypereference'{} ->
Type#type{def=check_externaltypereference(S,C)},
{simpletable,OSName};
_ ->
check_type(S,S#state.tname,Type),
{simpletable,OSName}
end;
check_constraint(S,{componentrelation,{objectset,Opos,Objset},Id}) ->
%% Objset is an 'Externaltypereference' record, since Objset is
%% a DefinedObjectSet.
RealObjset = match_parameters(Objset,S#state.parameters),
Ext = check_externaltypereference(S,RealObjset),
{componentrelation,{objectset,Opos,Ext},Id};
check_constraint(S,Type) when record(Type,type) ->
#type{def=Def} = check_type(S,S#state.tname,Type),
Def;
check_constraint(S,C) when list(C) ->
lists:map(fun(X)->check_constraint(S,X) end,C);
% else keep the constraint unchanged
check_constraint(_S,Any) ->
% io:format("Constraint = ~p~n",[Any]),
Any.
%% constraint_merge/2
%% Compute the intersection of the outermost level of the constraint list.
%% See Dubuisson second paragraph and fotnote on page 285.
%% If constraints with extension are included in combined constraints. The
%% resulting combination will have the extension of the last constraint. Thus,
%% there will be no extension if the last constraint is without extension.
%% The rootset of all constraints are considered in the "outermoust
%% intersection". See section 13.1.2 in Dubuisson.
constraint_merge(_S,C=[H])when tuple(H) ->
C;
constraint_merge(_S,[]) ->
[];
constraint_merge(S,C) ->
%% skip all extension but the last
C1 = filter_extensions(C),
%% perform all internal level intersections, intersections first
%% since they have precedence over unions
C2 = lists:map(fun(X)when list(X)->constraint_intersection(S,X);
(X) -> X end,
C1),
%% perform all internal level unions
C3 = lists:map(fun(X)when list(X)->constraint_union(S,X);
(X) -> X end,
C2),
%% now get intersection of the outermost level
%% get the least common single value constraint
SVs = get_constraints(C3,'SingleValue'),
CombSV = intersection_of_sv(S,SVs),
%% get the least common value range constraint
VRs = get_constraints(C3,'ValueRange'),
CombVR = intersection_of_vr(S,VRs),
%% get the least common size constraint
SZs = get_constraints(C3,'SizeConstraint'),
CombSZ = intersection_of_size(S,SZs),
CminusSVs=ordsets:subtract(ordsets:from_list(C3),ordsets:from_list(SVs)),
% CminusSVsVRs = ordsets:subtract(ordsets:from_list(CminusSVs),
% ordsets:from_list(VRs)),
RestC = ordsets:subtract(ordsets:from_list(CminusSVs),
ordsets:from_list(SZs)),
%% get the least common combined constraint. That is the union of each
%% deep costraint and merge of single value and value range constraints
combine_constraints(S,CombSV,CombVR,CombSZ++RestC).
%% constraint_union(S,C) takes a list of constraints as input and
%% merge them to a union. Unions are performed when two
%% constraints is found with an atom union between.
%% The list may be nested. Fix that later !!!
constraint_union(_S,[]) ->
[];
constraint_union(_S,C=[_E]) ->
C;
constraint_union(S,C) when list(C) ->
case lists:member(union,C) of
true ->
constraint_union1(S,C,[]);
_ ->
C
end;
% SV = get_constraints(C,'SingleValue'),
% SV1 = constraint_union_sv(S,SV),
% VR = get_constraints(C,'ValueRange'),
% VR1 = constraint_union_vr(VR),
% RestC = ordsets:filter(fun({'SingleValue',_})->false;
% ({'ValueRange',_})->false;
% (_) -> true end,ordsets:from_list(C)),
% SV1++VR1++RestC;
constraint_union(_S,C) ->
[C].
constraint_union1(S,[A={'ValueRange',_},union,B={'ValueRange',_}|Rest],Acc) ->
AunionB = constraint_union_vr([A,B]),
constraint_union1(S,Rest,AunionB++Acc);
constraint_union1(S,[A={'SingleValue',_},union,B={'SingleValue',_}|Rest],Acc) ->
AunionB = constraint_union_sv(S,[A,B]),
constraint_union1(S,Rest,AunionB++Acc);
constraint_union1(S,[A={'SingleValue',_},union,B={'ValueRange',_}|Rest],Acc) ->
AunionB = union_sv_vr(S,A,B),
constraint_union1(S,Rest,AunionB++Acc);
constraint_union1(S,[A={'ValueRange',_},union,B={'SingleValue',_}|Rest],Acc) ->
AunionB = union_sv_vr(S,B,A),
constraint_union1(S,Rest,AunionB++Acc);
constraint_union1(S,[union|Rest],Acc) -> %skip when unsupported constraints
constraint_union1(S,Rest,Acc);
constraint_union1(S,[A|Rest],Acc) ->
constraint_union1(S,Rest,[A|Acc]);
constraint_union1(_S,[],Acc) ->
lists:reverse(Acc).
constraint_union_sv(_S,SV) ->
Values=lists:map(fun({_,V})->V end,SV),
case ordsets:from_list(Values) of
[] -> [];
[N] -> [{'SingleValue',N}];
L -> [{'SingleValue',L}]
end.
%% REMOVE????
%%constraint_union(S,VR,'ValueRange') ->
%% constraint_union_vr(VR).
%% constraint_union_vr(VR)
%% VR = [{'ValueRange',{Lb,Ub}},...]
%% Lb = 'MIN' | integer()
%% Ub = 'MAX' | integer()
%% Returns if possible only one ValueRange tuple with a range that
%% is a union of all ranges in VR.
constraint_union_vr(VR) ->
%% Sort VR by Lb in first hand and by Ub in second hand
Fun=fun({_,{'MIN',_B1}},{_,{A2,_B2}}) when integer(A2)->true;
({_,{A1,_B1}},{_,{'MAX',_B2}}) when integer(A1) -> true;
({_,{A1,_B1}},{_,{A2,_B2}}) when integer(A1),integer(A2),A1<A2 -> true;
({_,{A,B1}},{_,{A,B2}}) when B1=<B2->true;
(_,_)->false end,
constraint_union_vr(lists:usort(Fun,VR),[]).
constraint_union_vr([],Acc) ->
lists:reverse(Acc);
constraint_union_vr([C|Rest],[]) ->
constraint_union_vr(Rest,[C]);
constraint_union_vr([{_,{Lb,Ub2}}|Rest],[{_,{Lb,_Ub1}}|Acc]) -> %Ub2 > Ub1
constraint_union_vr(Rest,[{'ValueRange',{Lb,Ub2}}|Acc]);
constraint_union_vr([{_,{_,Ub}}|Rest],A=[{_,{_,Ub}}|_Acc]) ->
constraint_union_vr(Rest,A);
constraint_union_vr([{_,{Lb2,Ub2}}|Rest],[{_,{Lb1,Ub1}}|Acc]) when Lb2=<Ub1,
Ub2>Ub1->
constraint_union_vr(Rest,[{'ValueRange',{Lb1,Ub2}}|Acc]);
constraint_union_vr([{_,{_,Ub2}}|Rest],A=[{_,{_,Ub1}}|_Acc]) when Ub2=<Ub1->
constraint_union_vr(Rest,A);
constraint_union_vr([VR|Rest],Acc) ->
constraint_union_vr(Rest,[VR|Acc]).
union_sv_vr(_S,[],B) ->
[B];
union_sv_vr(_S,A,[]) ->
[A];
union_sv_vr(_S,C1={'SingleValue',SV},C2={'ValueRange',VR={Lb,Ub}})
when integer(SV) ->
case is_int_in_vr(SV,C2) of
true -> [C2];
_ ->
case VR of
{'MIN',Ub} when SV==Ub+1 -> [{'ValueRange',{'MIN',SV}}];
{Lb,'MAX'} when SV==Lb-1 -> [{'ValueRange',{SV,'MAX'}}];
{Lb,Ub} when SV==Ub+1 -> [{'ValueRange',{Lb,SV}}];
{Lb,Ub} when SV==Lb-1 -> [{'ValueRange',{SV,Ub}}];
_ ->
[C1,C2]
end
end;
union_sv_vr(_S,C1={'SingleValue',SV},C2={'ValueRange',{_Lb,_Ub}})
when list(SV) ->
case lists:filter(fun(X)->is_int_in_vr(X,C2) end,SV) of
[] -> [C2];
L ->
case expand_vr(L,C2) of
{[],C3} -> [C3];
{L,C2} -> [C1,C2];
{[Val],C3} -> [{'SingleValue',Val},C3];
{L2,C3} -> [{'SingleValue',L2},C3]
end
end.
expand_vr(L,VR={_,{Lb,Ub}}) ->
case lower_Lb(L,Lb) of
false ->
case higher_Ub(L,Ub) of
false ->
{L,VR};
{L1,UbNew} ->
expand_vr(L1,{'ValueRange',{Lb,UbNew}})
end;
{L1,LbNew} ->
expand_vr(L1,{'ValueRange',{LbNew,Ub}})
end.
lower_Lb(_,'MIN') ->
false;
lower_Lb(L,Lb) ->
remove_val_from_list(Lb - 1,L).
higher_Ub(_,'MAX') ->
false;
higher_Ub(L,Ub) ->
remove_val_from_list(Ub + 1,L).
remove_val_from_list(List,Val) ->
case lists:member(Val,List) of
true ->
{lists:delete(Val,List),Val};
false ->
false
end.
%% get_constraints/2
%% Arguments are a list of constraints, which has the format {key,value},
%% and a constraint type
%% Returns a list of constraints only of the requested type or the atom
%% 'no' if no such constraints were found
get_constraints(L=[{CType,_}],CType) ->
L;
get_constraints(C,CType) ->
keysearch_allwithkey(CType,1,C).
%% keysearch_allwithkey(Key,Ix,L)
%% Types:
%% Key = atom()
%% Ix = integer()
%% L = [TwoTuple]
%% TwoTuple = [{atom(),term()}|...]
%% Returns a List that contains all
%% elements from L that has a key Key as element Ix
keysearch_allwithkey(Key,Ix,L) ->
lists:filter(fun(X) when tuple(X) ->
case element(Ix,X) of
Key -> true;
_ -> false
end;
(_) -> false
end, L).
%% filter_extensions(C)
%% takes a list of constraints as input and
%% returns a list with the intersection of all extension roots
%% and only the extension of the last constraint kept if any
%% extension in the last constraint
filter_extensions([]) ->
[];
filter_extensions(C=[_H]) ->
C;
filter_extensions(C) when list(C) ->
filter_extensions(C,[]).
filter_extensions([C],Acc) ->
lists:reverse([C|Acc]);
filter_extensions([{C,_E},H2|T],Acc) when tuple(C) ->
filter_extensions([H2|T],[C|Acc]);
filter_extensions([{'SizeConstraint',{A,_B}},H2|T],Acc)
when list(A);tuple(A) ->
filter_extensions([H2|T],[{'SizeConstraint',A}|Acc]);
filter_extensions([H1,H2|T],Acc) ->
filter_extensions([H2|T],[H1|Acc]).
%% constraint_intersection(S,C) takes a list of constraints as input and
%% performs intersections. Intersecions are performed when an
%% atom intersection is found between two constraints.
%% The list may be nested. Fix that later !!!
constraint_intersection(_S,[]) ->
[];
constraint_intersection(_S,C=[_E]) ->
C;
constraint_intersection(S,C) when list(C) ->
% io:format("constraint_intersection: ~p~n",[C]),
case lists:member(intersection,C) of
true ->
constraint_intersection1(S,C,[]);
_ ->
C
end;
constraint_intersection(_S,C) ->
[C].
constraint_intersection1(S,[A,intersection,B|Rest],Acc) ->
AisecB = c_intersect(S,A,B),
constraint_intersection1(S,Rest,AisecB++Acc);
constraint_intersection1(S,[A|Rest],Acc) ->
constraint_intersection1(S,Rest,[A|Acc]);
constraint_intersection1(_,[],Acc) ->
lists:reverse(Acc).
c_intersect(S,C1={'SingleValue',_},C2={'SingleValue',_}) ->
intersection_of_sv(S,[C1,C2]);
c_intersect(S,C1={'ValueRange',_},C2={'ValueRange',_}) ->
intersection_of_vr(S,[C1,C2]);
c_intersect(S,C1={'ValueRange',_},C2={'SingleValue',_}) ->
intersection_sv_vr(S,[C2],[C1]);
c_intersect(S,C1={'SingleValue',_},C2={'ValueRange',_}) ->
intersection_sv_vr(S,[C1],[C2]);
c_intersect(_S,C1,C2) ->
[C1,C2].
%% combine_constraints(S,SV,VR,CComb)
%% Types:
%% S = record(state,S)
%% SV = [] | [SVC]
%% VR = [] | [VRC]
%% CComb = [] | [Lists]
%% SVC = {'SingleValue',integer()} | {'SingleValue',[integer(),...]}
%% VRC = {'ValueRange',{Lb,Ub}}
%% Lists = List of lists containing any constraint combination
%% Lb = 'MIN' | integer()
%% Ub = 'MAX' | integer()
%% Returns a combination of the least common constraint among SV,VR and all
%% elements in CComb
combine_constraints(_S,[],VR,CComb) ->
VR ++ CComb;
% combine_combined_cnstr(S,VR,CComb);
combine_constraints(_S,SV,[],CComb) ->
SV ++ CComb;
% combine_combined_cnstr(S,SV,CComb);
combine_constraints(S,SV,VR,CComb) ->
C=intersection_sv_vr(S,SV,VR),
C ++ CComb.
% combine_combined_cnstr(S,C,CComb).
intersection_sv_vr(_,[],_VR) ->
[];
intersection_sv_vr(_,_SV,[]) ->
[];
intersection_sv_vr(_S,[C1={'SingleValue',SV}],[C2={'ValueRange',{_Lb,_Ub}}])
when integer(SV) ->
case is_int_in_vr(SV,C2) of
true -> [C1];
_ -> %%error({type,{"asn1 illegal constraint",C1,C2},S})
throw({error,{"asn1 illegal constraint",C1,C2}})
end;
intersection_sv_vr(_S,[C1={'SingleValue',SV}],[C2])
when list(SV) ->
case lists:filter(fun(X)->is_int_in_vr(X,C2) end,SV) of
[] ->
%%error({type,{"asn1 illegal constraint",C1,C2},S});
throw({error,{"asn1 illegal constraint",C1,C2}});
[V] -> [{'SingleValue',V}];
L -> [{'SingleValue',L}]
end.
intersection_of_size(_,[]) ->
[];
intersection_of_size(_,C=[_SZ]) ->
C;
intersection_of_size(S,[SZ,SZ|Rest]) ->
intersection_of_size(S,[SZ|Rest]);
intersection_of_size(S,C=[C1={_,Int},{_,Range}|Rest])
when integer(Int),tuple(Range) ->
case Range of
{Lb,Ub} when Int >= Lb,
Int =< Ub ->
intersection_of_size(S,[C1|Rest]);
_ ->
throw({error,{asn1,{illegal_size_constraint,C}}})
end;
intersection_of_size(S,[C1={_,Range},C2={_,Int}|Rest])
when integer(Int),tuple(Range) ->
intersection_of_size(S,[C2,C1|Rest]);
intersection_of_size(S,[{_,{Lb1,Ub1}},{_,{Lb2,Ub2}}|Rest]) ->
Lb=greatest_LB(ordsets:from_list([Lb1,Lb2])),
Ub=smallest_UB(ordsets:from_list([Ub1,Ub2])),
intersection_of_size(S,[{'SizeConstraint',{Lb,Ub}}|Rest]);
intersection_of_size(_,SZ) ->
throw({error,{asn1,{illegal_size_constraint,SZ}}}).
intersection_of_vr(_,[]) ->
[];
intersection_of_vr(_,VR=[_C]) ->
VR;
intersection_of_vr(S,[{_,{Lb1,Ub1}},{_,{Lb2,Ub2}}|Rest]) ->
Lb=greatest_LB(ordsets:from_list([Lb1,Lb2])),
Ub=smallest_UB(ordsets:from_list([Ub1,Ub2])),
intersection_of_vr(S,[{'ValueRange',{Lb,Ub}}|Rest]);
intersection_of_vr(_S,VR) ->
%%error({type,{asn1,{illegal_value_range_constraint,VR}},S});
throw({error,{asn1,{illegal_value_range_constraint,VR}}}).
intersection_of_sv(_,[]) ->
[];
intersection_of_sv(_,SV=[_C]) ->
SV;
intersection_of_sv(S,[SV,SV|Rest]) ->
intersection_of_sv(S,[SV|Rest]);
intersection_of_sv(S,[{_,Int},{_,SV}|Rest]) when integer(Int),
list(SV) ->
SV2=intersection_of_sv1(S,Int,SV),
intersection_of_sv(S,[SV2|Rest]);
intersection_of_sv(S,[{_,SV},{_,Int}|Rest]) when integer(Int),
list(SV) ->
SV2=intersection_of_sv1(S,Int,SV),
intersection_of_sv(S,[SV2|Rest]);
intersection_of_sv(S,[{_,SV1},{_,SV2}|Rest]) when list(SV1),
list(SV2) ->
SV3=common_set(SV1,SV2),
intersection_of_sv(S,[SV3|Rest]);
intersection_of_sv(_S,SV) ->
%%error({type,{asn1,{illegal_single_value_constraint,SV}},S}).
throw({error,{asn1,{illegal_single_value_constraint,SV}}}).
intersection_of_sv1(_S,Int,SV) when integer(Int),list(SV) ->
case lists:member(Int,SV) of
true -> {'SingleValue',Int};
_ ->
%%error({type,{asn1,{illegal_single_value_constraint,Int,SV}},S})
throw({error,{asn1,{illegal_single_value_constraint,Int,SV}}})
end;
intersection_of_sv1(_S,SV1,SV2) ->
%%error({type,{asn1,{illegal_single_value_constraint,SV1,SV2}},S}).
throw({error,{asn1,{illegal_single_value_constraint,SV1,SV2}}}).
greatest_LB([H]) ->
H;
greatest_LB(L) ->
greatest_LB1(lists:reverse(L)).
greatest_LB1(['MIN',H2|_T])->
H2;
greatest_LB1([H|_T]) ->
H.
smallest_UB(L) ->
hd(L).
common_set(SV1,SV2) ->
lists:filter(fun(X)->lists:member(X,SV1) end,SV2).
is_int_in_vr(Int,{_,{'MIN','MAX'}}) when integer(Int) ->
true;
is_int_in_vr(Int,{_,{'MIN',Ub}}) when integer(Int),Int =< Ub ->
true;
is_int_in_vr(Int,{_,{Lb,'MAX'}}) when integer(Int),Int >= Lb ->
true;
is_int_in_vr(Int,{_,{Lb,Ub}}) when integer(Int),Int >= Lb,Int =< Ub ->
true;
is_int_in_vr(_,_) ->
false.
check_imported(_S,Imodule,Name) ->
case asn1_db:dbget(Imodule,'MODULE') of
undefined ->
io:format("~s.asn1db not found~n",[Imodule]),
io:format("Type ~s imported from non existing module ~s~n",[Name,Imodule]);
Im when record(Im,module) ->
case is_exported(Im,Name) of
false ->
io:format("Imported type ~s not exported from module ~s~n",[Name,Imodule]);
_ ->
ok
end
end,
ok.
is_exported(Module,Name) when record(Module,module) ->
{exports,Exports} = Module#module.exports,
case Exports of
all ->
true;
[] ->
false;
L when list(L) ->
case lists:keysearch(Name,#'Externaltypereference'.type,Exports) of
false -> false;
_ -> true
end
end.
check_externaltypereference(S,Etref=#'Externaltypereference'{module=Emod})->
Currmod = S#state.mname,
MergedMods = S#state.inputmodules,
case Emod of
Currmod ->
%% reference to current module or to imported reference
check_reference(S,Etref);
_ ->
%% io:format("Type ~s IMPORTED FROM ~s~n",[Etype,Emod]),
case lists:member(Emod,MergedMods) of
true ->
check_reference(S,Etref);
false ->
Etref
end
end.
check_reference(S,#'Externaltypereference'{pos=Pos,module=Emod,type=Name}) ->
ModName = S#state.mname,
case asn1_db:dbget(ModName,Name) of
undefined ->
case imported(S,Name) of
{ok,Imodule} ->
check_imported(S,Imodule,Name),
#'Externaltypereference'{module=Imodule,type=Name};
_ ->
%may be a renamed type in multi file compiling!
{_,T}=renamed_reference(S,Name,Emod),
NewName = asn1ct:get_name_of_def(T),
NewPos = asn1ct:get_pos_of_def(T),
#'Externaltypereference'{pos=NewPos,
module=ModName,
type=NewName}
end;
_ ->
%% cannot do check_type here due to recursive definitions, like
%% S ::= SEQUENCE {a INTEGER, b S}. This implies that references
%% that appear before the definition will be an
%% Externaltypereference in the abstract syntax tree
#'Externaltypereference'{pos=Pos,module=ModName,type=Name}
end.
name2Extref(_Mod,Name) when record(Name,'Externaltypereference') ->
Name;
name2Extref(Mod,Name) ->
#'Externaltypereference'{module=Mod,type=Name}.
get_referenced_type(S,Ext) when record(Ext,'Externaltypereference') ->
case match_parameters(Ext, S#state.parameters) of
Ext ->
#'Externaltypereference'{pos=Pos,module=Emod,type=Etype} = Ext,
case S#state.mname of
Emod -> % a local reference in this module
get_referenced1(S,Emod,Etype,Pos);
_ ->% always when multi file compiling
case lists:member(Emod,S#state.inputmodules) of
true ->
get_referenced1(S,Emod,Etype,Pos);
false ->
get_referenced(S,Emod,Etype,Pos)
end
end;
Other ->
{undefined,Other}
end;
get_referenced_type(S=#state{mname=Emod},
ERef=#'Externalvaluereference'{pos=P,module=Emod,
value=Eval}) ->
case match_parameters(ERef,S#state.parameters) of
ERef ->
get_referenced1(S,Emod,Eval,P);
OtherERef when record(OtherERef,'Externalvaluereference') ->
get_referenced_type(S,OtherERef);
Value ->
{Emod,Value}
end;
get_referenced_type(S,ERef=#'Externalvaluereference'{pos=Pos,module=Emod,
value=Eval}) ->
case match_parameters(ERef,S#state.parameters) of
ERef ->
case lists:member(Emod,S#state.inputmodules) of
true ->
get_referenced1(S,Emod,Eval,Pos);
false ->
get_referenced(S,Emod,Eval,Pos)
end;
OtherERef ->
get_referenced_type(S,OtherERef)
end;
get_referenced_type(S,#identifier{val=Name,pos=Pos}) ->
get_referenced1(S,undefined,Name,Pos);
get_referenced_type(_S,Type) ->
{undefined,Type}.
%% get_referenced/3
%% The referenced entity Ename may in case of an imported parameterized
%% type reference imported entities in the other module, which implies that
%% asn1_db:dbget will fail even though the referenced entity exists. Thus
%% Emod may be the module that imports the entity Ename and not holds the
%% data about Ename.
get_referenced(S,Emod,Ename,Pos) ->
case asn1_db:dbget(Emod,Ename) of
undefined ->
%% May be an imported entity in module Emod
% throw({error,{asn1,{undefined_type_or_value,{Emod,Ename}}}});
NewS = S#state{module=asn1_db:dbget(Emod,'MODULE')},
get_imported(NewS,Ename,Emod,Pos);
T when record(T,typedef) ->
Spec = T#typedef.typespec,
case Spec#type.def of
Tref when record(Tref,typereference) ->
Def = #'Externaltypereference'{module=Emod,
type=Tref#typereference.val,
pos=Tref#typereference.pos},
{Emod,T#typedef{typespec=Spec#type{def=Def}}};
_ ->
{Emod,T} % should add check that T is exported here
end;
V -> {Emod,V}
end.
get_referenced1(S,ModuleName,Name,Pos) ->
case asn1_db:dbget(S#state.mname,Name) of
undefined ->
%% ModuleName may be other than S#state.mname when
%% multi file compiling is used.
get_imported(S,Name,ModuleName,Pos);
T ->
{S#state.mname,T}
end.
get_imported(S,Name,Module,Pos) ->
case imported(S,Name) of
{ok,Imodule} ->
case asn1_db:dbget(Imodule,'MODULE') of
undefined ->
throw({error,{asn1,{module_not_found,Imodule}}});
Im when record(Im,module) ->
case is_exported(Im,Name) of
false ->
throw({error,
{asn1,{not_exported,{Im,Name}}}});
_ ->
get_referenced_type(S,
#'Externaltypereference'
{module=Imodule,
type=Name,pos=Pos})
end
end;
_ ->
renamed_reference(S,Name,Module)
end.
renamed_reference(S,Name,Module) ->
%% first check if there is a renamed type in this module
%% second check if any type was imported with this name
case ets:info(renamed_defs) of
undefined -> throw({error,{asn1,{undefined_type,Name}}});
_ ->
case ets:match(renamed_defs,{'$1',Name,Module}) of
[] ->
case ets:info(original_imports) of
undefined ->
throw({error,{asn1,{undefined_type,Name}}});
_ ->
case ets:match(original_imports,{Module,'$1'}) of
[] ->
throw({error,{asn1,{undefined_type,Name}}});
[[ImportsList]] ->
case get_importmoduleoftype(ImportsList,Name) of
undefined ->
throw({error,{asn1,{undefined_type,Name}}});
NextMod ->
renamed_reference(S,Name,NextMod)
end
end
end;
[[NewTypeName]] ->
get_referenced1(S,Module,NewTypeName,undefined)
end
end.
get_importmoduleoftype([I|Is],Name) ->
Index = #'Externaltypereference'.type,
case lists:keysearch(Name,Index,I#'SymbolsFromModule'.symbols) of
{value,_Ref} ->
(I#'SymbolsFromModule'.module)#'Externaltypereference'.type;
_ ->
get_importmoduleoftype(Is,Name)
end;
get_importmoduleoftype([],_) ->
undefined.
match_parameters(Name,[]) ->
Name;
match_parameters(#'Externaltypereference'{type=Name},[{#'Externaltypereference'{type=Name},NewName}|_T]) ->
NewName;
match_parameters(#'Externaltypereference'{type=Name},[{{_,#'Externaltypereference'{type=Name}},NewName}|_T]) ->
NewName;
% match_parameters(#'Externaltypereference'{type=Name},[{#typereference{val=Name},NewName}|T]) ->
% NewName;
% match_parameters(#'Externaltypereference'{type=Name},[{{_,#typereference{val=Name}},NewName}|T]) ->
% NewName;
%match_parameters(#typereference{val=Name},[{#typereference{val=Name},NewName}|T]) ->
% NewName;
match_parameters(#'Externalvaluereference'{value=Name},[{#'Externalvaluereference'{value=Name},NewName}|_T]) ->
NewName;
match_parameters(#'Externalvaluereference'{value=Name},[{{_,#'Externalvaluereference'{value=Name}},NewName}|_T]) ->
NewName;
% match_parameters(#identifier{val=Name},[{#identifier{val=Name},NewName}|T]) ->
% NewName;
% match_parameters(#identifier{val=Name},[{{_,#identifier{val=Name}},NewName}|T]) ->
% NewName;
match_parameters({valueset,#type{def=#'Externaltypereference'{type=Name}}},
[{{_,#'Externaltypereference'{type=Name}},{valueset,#type{def=NewName}}}|_T]) ->
NewName;
match_parameters({valueset,#type{def=#'Externaltypereference'{type=Name}}},
[{{_,#'Externaltypereference'{type=Name}},NewName}|_T]) ->
NewName;
% match_parameters({valueset,#type{def=#'Externaltypereference'{type=Name}}},
% [{{_,#typereference{val=Name}},{valueset,#type{def=NewName}}}|T]) ->
% NewName;
% match_parameters({valueset,#type{def=#'Externaltypereference'{type=Name}}},
% [{{_,#typereference{val=Name}},NewName}|T]) ->
% NewName;
match_parameters(Name, [_H|T]) ->
%%io:format("match_parameters(~p,~p)~n",[Name,[H|T]]),
match_parameters(Name,T).
imported(S,Name) ->
{imports,Ilist} = (S#state.module)#module.imports,
imported1(Name,Ilist).
imported1(Name,
[#'SymbolsFromModule'{symbols=Symlist,
module=#'Externaltypereference'{type=ModuleName}}|T]) ->
case lists:keysearch(Name,#'Externaltypereference'.type,Symlist) of
{value,_V} ->
{ok,ModuleName};
_ ->
imported1(Name,T)
end;
imported1(_Name,[]) ->
false.
check_integer(_S,[],_C) ->
ok;
check_integer(S,NamedNumberList,_C) ->
case check_unique(NamedNumberList,2) of
[] ->
check_int(S,NamedNumberList,[]);
L when list(L) ->
error({type,{duplicates,L},S}),
unchanged
end.
check_int(S,[{'NamedNumber',Id,Num}|T],Acc) when integer(Num) ->
check_int(S,T,[{Id,Num}|Acc]);
check_int(S,[{'NamedNumber',Id,{identifier,_,Name}}|T],Acc) ->
Val = dbget_ex(S,S#state.mname,Name),
check_int(S,[{'NamedNumber',Id,Val#valuedef.value}|T],Acc);
check_int(_S,[],Acc) ->
lists:keysort(2,Acc).
check_bitstring(_S,[],_Constr) ->
[];
check_bitstring(S,NamedNumberList,_Constr) ->
case check_unique(NamedNumberList,2) of
[] ->
check_bitstr(S,NamedNumberList,[]);
L when list(L) ->
error({type,{duplicates,L},S}),
unchanged
end.
check_bitstr(S,[{'NamedNumber',Id,Num}|T],Acc)when integer(Num) ->
check_bitstr(S,T,[{Id,Num}|Acc]);
check_bitstr(S,[{'NamedNumber',Id,Name}|T],Acc) when atom(Name) ->
%%check_bitstr(S,[{'NamedNumber',Id,{identifier,_,Name}}|T],Acc) ->
%% io:format("asn1ct_check:check_bitstr/3 hej hop ~w~n",[Name]),
Val = dbget_ex(S,S#state.mname,Name),
%% io:format("asn1ct_check:check_bitstr/3: ~w~n",[Val]),
check_bitstr(S,[{'NamedNumber',Id,Val#valuedef.value}|T],Acc);
check_bitstr(S,[],Acc) ->
case check_unique(Acc,2) of
[] ->
lists:keysort(2,Acc);
L when list(L) ->
error({type,{duplicate_values,L},S}),
unchanged
end.
%%check_bitstring(S,NamedNumberList,Constr) ->
%% NamedNumberList.
%% Check INSTANCE OF
%% check that DefinedObjectClass is of TYPE-IDENTIFIER class
%% If Constraint is empty make it the general INSTANCE OF type
%% If Constraint is not empty make an inlined type
%% convert INSTANCE OF to the associated type
check_instance_of(S,DefinedObjectClass,Constraint) ->
check_type_identifier(S,DefinedObjectClass),
iof_associated_type(S,Constraint).
check_type_identifier(_S,'TYPE-IDENTIFIER') ->
ok;
check_type_identifier(S,Eref=#'Externaltypereference'{}) ->
case get_referenced_type(S,Eref) of
{_,#classdef{name='TYPE-IDENTIFIER'}} -> ok;
{_,TD=#typedef{typespec=#type{def=#'Externaltypereference'{}}}} ->
check_type_identifier(S,(TD#typedef.typespec)#type.def);
_ ->
error({type,{"object set in type INSTANCE OF "
"not of class TYPE-IDENTIFIER",Eref},S})
end.
iof_associated_type(S,[]) ->
%% in this case encode/decode functions for INSTANCE OF must be
%% generated
case get(instance_of) of
undefined ->
AssociateSeq = iof_associated_type1(S,[]),
Tag =
case S#state.erule of
ber_bin_v2 ->
[?TAG_CONSTRUCTED(?N_INSTANCE_OF)];
_ -> []
end,
TypeDef=#typedef{checked=true,
name='INSTANCE OF',
typespec=#type{tag=Tag,
def=AssociateSeq}},
asn1_db:dbput(S#state.mname,'INSTANCE OF',TypeDef),
put(instance_of,generate);
_ ->
ok
end,
#'Externaltypereference'{module=S#state.mname,type='INSTANCE OF'};
iof_associated_type(S,C) ->
iof_associated_type1(S,C).
iof_associated_type1(S,C) ->
{TableCInf,Comp1Cnstr,Comp2Cnstr,Comp2tablecinf}=
instance_of_constraints(S,C),
ModuleName = S#state.mname,
Typefield_type=
case C of
[] -> 'ASN1_OPEN_TYPE';
_ -> {typefield,'Type'}
end,
{ObjIdTag,C1TypeTag}=
case S#state.erule of
ber_bin_v2 ->
{[{'UNIVERSAL',8}],
[#tag{class='UNIVERSAL',
number=6,
type='IMPLICIT',
form=0}]};
_ -> {[{'UNIVERSAL','INTEGER'}],[]}
end,
TypeIdentifierRef=#'Externaltypereference'{module=ModuleName,
type='TYPE-IDENTIFIER'},
ObjectIdentifier =
#'ObjectClassFieldType'{classname=TypeIdentifierRef,
class=[],
fieldname={id,[]},
type={fixedtypevaluefield,id,
#type{def='OBJECT IDENTIFIER'}}},
Typefield =
#'ObjectClassFieldType'{classname=TypeIdentifierRef,
class=[],
fieldname={'Type',[]},
type=Typefield_type},
IOFComponents =
[#'ComponentType'{name='type-id',
typespec=#type{tag=C1TypeTag,
def=ObjectIdentifier,
constraint=Comp1Cnstr},
prop=mandatory,
tags=ObjIdTag},
#'ComponentType'{name=value,
typespec=#type{tag=[#tag{class='CONTEXT',
number=0,
type='EXPLICIT',
form=32}],
def=Typefield,
constraint=Comp2Cnstr,
tablecinf=Comp2tablecinf},
prop=mandatory,
tags=[{'CONTEXT',0}]}],
#'SEQUENCE'{tablecinf=TableCInf,
components=IOFComponents}.
%% returns the leading attribute, the constraint of the components and
%% the tablecinf value for the second component.
instance_of_constraints(_,[]) ->
{false,[],[],[]};
instance_of_constraints(S,#constraint{c={simpletable,Type}}) ->
#type{def=#'Externaltypereference'{type=Name}} = Type,
ModuleName = S#state.mname,
ObjectSetRef=#'Externaltypereference'{module=ModuleName,
type=Name},
CRel=[{componentrelation,{objectset,
undefined, %% pos
ObjectSetRef},
[{innermost,
[#'Externalvaluereference'{module=ModuleName,
value=type}]}]}],
TableCInf=#simpletableattributes{objectsetname=Name,
c_name='type-id',
c_index=1,
usedclassfield=id,
uniqueclassfield=id,
valueindex=[]},
{TableCInf,[{simpletable,Name}],CRel,[{objfun,ObjectSetRef}]}.
%% Check ENUMERATED
%% ****************************************
%% Check that all values are unique
%% assign values to un-numbered identifiers
%% check that the constraints are allowed and correct
%% put the updated info back into database
check_enumerated(_S,[{Name,Number}|Rest],_Constr) when atom(Name), integer(Number)->
%% already checked , just return the same list
[{Name,Number}|Rest];
check_enumerated(S,NamedNumberList,_Constr) ->
check_enum(S,NamedNumberList,[],[]).
%% identifiers are put in Acc2
%% returns either [{Name,Number}] or {[{Name,Number}],[{ExtName,ExtNumber}]}
%% the latter is returned if the ENUMERATION contains EXTENSIONMARK
check_enum(S,[{'NamedNumber',Id,Num}|T],Acc1,Acc2) when integer(Num) ->
check_enum(S,T,[{Id,Num}|Acc1],Acc2);
check_enum(S,[{'NamedNumber',Id,{identifier,_,Name}}|T],Acc1,Acc2) ->
Val = dbget_ex(S,S#state.mname,Name),
check_enum(S,[{'NamedNumber',Id,Val#valuedef.value}|T],Acc1,Acc2);
check_enum(S,['EXTENSIONMARK'|T],Acc1,Acc2) ->
NewAcc2 = lists:keysort(2,Acc1),
NewList = enum_number(lists:reverse(Acc2),NewAcc2,0,[]),
{ NewList, check_enum(S,T,[],[])};
check_enum(S,[Id|T],Acc1,Acc2) when atom(Id) ->
check_enum(S,T,Acc1,[Id|Acc2]);
check_enum(_S,[],Acc1,Acc2) ->
NewAcc2 = lists:keysort(2,Acc1),
enum_number(lists:reverse(Acc2),NewAcc2,0,[]).
% assign numbers to identifiers , numbers from 0 ... but must not
% be the same as already assigned to NamedNumbers
enum_number([H|T],[{Id,Num}|T2],Cnt,Acc) when Num > Cnt ->
enum_number(T,[{Id,Num}|T2],Cnt+1,[{H,Cnt}|Acc]);
enum_number([H|T],[{Id,Num}|T2],Cnt,Acc) when Num < Cnt -> % negative Num
enum_number(T,T2,Cnt+1,[{H,Cnt},{Id,Num}|Acc]);
enum_number([],L2,_Cnt,Acc) ->
lists:concat([lists:reverse(Acc),L2]);
enum_number(L,[{Id,Num}|T2],Cnt,Acc) -> % Num == Cnt
enum_number(L,T2,Cnt+1,[{Id,Num}|Acc]);
enum_number([H|T],[],Cnt,Acc) ->
enum_number(T,[],Cnt+1,[{H,Cnt}|Acc]).
check_boolean(_S,_Constr) ->
ok.
check_octetstring(_S,_Constr) ->
ok.
% check all aspects of a SEQUENCE
% - that all component names are unique
% - that all TAGS are ok (when TAG default is applied)
% - that each component is of a valid type
% - that the extension marks are valid
check_sequence(S,Type,Comps) ->
Components = expand_components(S,Comps),
case check_unique([C||C <- Components ,record(C,'ComponentType')]
,#'ComponentType'.name) of
[] ->
%% sort_canonical(Components),
Components2 = maybe_automatic_tags(S,Components),
%% check the table constraints from here. The outermost type
%% is Type, the innermost is Comps (the list of components)
NewComps =
case check_each_component(S,Type,Components2) of
NewComponents when list(NewComponents) ->
check_unique_sequence_tags(S,NewComponents),
NewComponents;
Ret = {NewComponents,NewEcomps} ->
TagComps = NewComponents ++
[Comp#'ComponentType'{prop='OPTIONAL'}|| Comp <- NewEcomps],
%% extension components are like optionals when it comes to tagging
check_unique_sequence_tags(S,TagComps),
Ret
end,
%% CRelInf is the "leading attribute" information
%% necessary for code generating of the look up in the
%% object set table,
%% i.e. getenc_ObjectSet/getdec_ObjectSet.
%% {objfun,ERef} tuple added in NewComps2 in tablecinf
%% field in type record of component relation constrained
%% type
% io:format("NewComps: ~p~n",[NewComps]),
{CRelInf,NewComps2} = componentrelation_leadingattr(S,NewComps),
% io:format("CRelInf: ~p~n",[CRelInf]),
% io:format("NewComps2: ~p~n",[NewComps2]),
%% CompListWithTblInf has got a lot unecessary info about
%% the involved class removed, as the class of the object
%% set.
CompListWithTblInf = get_tableconstraint_info(S,Type,NewComps2),
% io:format("CompListWithTblInf: ~p~n",[CompListWithTblInf]),
{CRelInf,CompListWithTblInf};
Dupl ->
throw({error,{asn1,{duplicate_components,Dupl}}})
end.
expand_components(S, [{'COMPONENTS OF',Type}|T]) ->
CompList =
case get_referenced_type(S,Type#type.def) of
{_,#typedef{typespec=#type{def=Seq}}} when record(Seq,'SEQUENCE') ->
case Seq#'SEQUENCE'.components of
{Root,_Ext} -> Root;
Root -> Root
end;
Err -> throw({error,{asn1,{illegal_COMPONENTS_OF,Err}}})
end,
expand_components(S,CompList) ++ expand_components(S,T);
expand_components(S,[H|T]) ->
[H|expand_components(S,T)];
expand_components(_,[]) ->
[].
check_unique_sequence_tags(S,[#'ComponentType'{prop=mandatory}|Rest]) ->
check_unique_sequence_tags(S,Rest);
check_unique_sequence_tags(S,[C|Rest]) when record(C,'ComponentType') ->
check_unique_sequence_tags1(S,Rest,[C]);% optional or default
check_unique_sequence_tags(S,[_ExtensionMarker|Rest]) ->
check_unique_sequence_tags(S,Rest);
check_unique_sequence_tags(_S,[]) ->
true.
check_unique_sequence_tags1(S,[C|Rest],Acc) when record(C,'ComponentType') ->
case C#'ComponentType'.prop of
mandatory ->
check_unique_tags(S,lists:reverse([C|Acc])),
check_unique_sequence_tags(S,Rest);
_ ->
check_unique_sequence_tags1(S,Rest,[C|Acc]) % default or optional
end;
check_unique_sequence_tags1(S,[H|Rest],Acc) ->
check_unique_sequence_tags1(S,Rest,[H|Acc]);
check_unique_sequence_tags1(S,[],Acc) ->
check_unique_tags(S,lists:reverse(Acc)).
check_sequenceof(S,Type,Component) when record(Component,type) ->
check_type(S,Type,Component).
check_set(S,Type,Components) ->
{TableCInf,NewComponents} = check_sequence(S,Type,Components),
case lists:member(der,S#state.options) of
true when S#state.erule == ber;
S#state.erule == ber_bin ->
{Sorted,SortedComponents} =
sort_components(S#state.tname,
(S#state.module)#module.tagdefault,
NewComponents),
{Sorted,TableCInf,SortedComponents};
_ ->
{false,TableCInf,NewComponents}
end.
sort_components(_TypeName,'AUTOMATIC',Components) ->
{true,Components};
sort_components(TypeName,_TagDefault,Components) ->
case untagged_choice(Components) of
false ->
{true,sort_components1(TypeName,Components,[],[],[],[])};
true ->
{dynamic,Components} % sort in run-time
end.
sort_components1(TypeName,[C=#'ComponentType'{tags=[{'UNIVERSAL',_}|_R]}|Cs],
UnivAcc,ApplAcc,ContAcc,PrivAcc) ->
sort_components1(TypeName,Cs,[C|UnivAcc],ApplAcc,ContAcc,PrivAcc);
sort_components1(TypeName,[C=#'ComponentType'{tags=[{'APPLICATION',_}|_R]}|Cs],
UnivAcc,ApplAcc,ContAcc,PrivAcc) ->
sort_components1(TypeName,Cs,UnivAcc,[C|ApplAcc],ContAcc,PrivAcc);
sort_components1(TypeName,[C=#'ComponentType'{tags=[{'CONTEXT',_}|_R]}|Cs],
UnivAcc,ApplAcc,ContAcc,PrivAcc) ->
sort_components1(TypeName,Cs,UnivAcc,ApplAcc,[C|ContAcc],PrivAcc);
sort_components1(TypeName,[C=#'ComponentType'{tags=[{'PRIVATE',_}|_R]}|Cs],
UnivAcc,ApplAcc,ContAcc,PrivAcc) ->
sort_components1(TypeName,Cs,UnivAcc,ApplAcc,ContAcc,[C|PrivAcc]);
sort_components1(TypeName,[],UnivAcc,ApplAcc,ContAcc,PrivAcc) ->
I = #'ComponentType'.tags,
ascending_order_check(TypeName,sort_universal_type(UnivAcc)) ++
ascending_order_check(TypeName,lists:keysort(I,ApplAcc)) ++
ascending_order_check(TypeName,lists:keysort(I,ContAcc)) ++
ascending_order_check(TypeName,lists:keysort(I,PrivAcc)).
ascending_order_check(TypeName,Components) ->
ascending_order_check1(TypeName,Components),
Components.
ascending_order_check1(TypeName,
[C1 = #'ComponentType'{tags=[{_,T}|_]},
C2 = #'ComponentType'{tags=[{_,T}|_]}|Rest]) ->
io:format("WARNING: Indistinct tag ~p in SET ~p, components ~p and ~p~n",
[T,TypeName,C1#'ComponentType'.name,C2#'ComponentType'.name]),
ascending_order_check1(TypeName,[C2|Rest]);
ascending_order_check1(TypeName,
[C1 = #'ComponentType'{tags=[{'UNIVERSAL',T1}|_]},
C2 = #'ComponentType'{tags=[{'UNIVERSAL',T2}|_]}|Rest]) ->
case (asn1ct_gen_ber:decode_type(T1) == asn1ct_gen_ber:decode_type(T2)) of
true ->
io:format("WARNING: Indistinct tags ~p and ~p in"
" SET ~p, components ~p and ~p~n",
[T1,T2,TypeName,C1#'ComponentType'.name,
C2#'ComponentType'.name]),
ascending_order_check1(TypeName,[C2|Rest]);
_ ->
ascending_order_check1(TypeName,[C2|Rest])
end;
ascending_order_check1(N,[_|Rest]) ->
ascending_order_check1(N,Rest);
ascending_order_check1(_,[_]) ->
ok;
ascending_order_check1(_,[]) ->
ok.
sort_universal_type(Components) ->
List = lists:map(fun(C) ->
#'ComponentType'{tags=[{_,T}|_]} = C,
{asn1ct_gen_ber:decode_type(T),C}
end,
Components),
SortedList = lists:keysort(1,List),
lists:map(fun(X)->element(2,X) end,SortedList).
untagged_choice([#'ComponentType'{typespec=#type{tag=[],def={'CHOICE',_}}}|_Rest]) ->
true;
untagged_choice([_|Rest]) ->
untagged_choice(Rest);
untagged_choice([]) ->
false.
check_setof(S,Type,Component) when record(Component,type) ->
check_type(S,Type,Component).
check_restrictedstring(_S,_Def,_Constr) ->
ok.
check_objectidentifier(_S,_Constr) ->
ok.
% check all aspects of a CHOICE
% - that all alternative names are unique
% - that all TAGS are ok (when TAG default is applied)
% - that each alternative is of a valid type
% - that the extension marks are valid
check_choice(S,Type,Components) when list(Components) ->
case check_unique([C||C <- Components,
record(C,'ComponentType')],#'ComponentType'.name) of
[] ->
%% sort_canonical(Components),
Components2 = maybe_automatic_tags(S,Components),
%NewComps =
case check_each_alternative(S,Type,Components2) of
{NewComponents,NewEcomps} ->
check_unique_tags(S,NewComponents ++ NewEcomps),
{NewComponents,NewEcomps};
NewComponents ->
check_unique_tags(S,NewComponents),
NewComponents
end;
%% CompListWithTblInf = get_tableconstraint_info(S,Type,NewComps);
Dupl ->
throw({error,{asn1,{duplicate_choice_alternatives,Dupl}}})
end;
check_choice(_S,_,[]) ->
[].
%% probably dead code that should be removed
%%maybe_automatic_tags(S,{Rc,Ec}) ->
%% {maybe_automatic_tags1(S,Rc,0),maybe_automatic_tags1(S,Ec,length(Rc))};
maybe_automatic_tags(#state{erule=per},C) ->
C;
maybe_automatic_tags(#state{erule=per_bin},C) ->
C;
maybe_automatic_tags(S,C) ->
maybe_automatic_tags1(S,C,0).
maybe_automatic_tags1(S,C,TagNo) ->
case (S#state.module)#module.tagdefault of
'AUTOMATIC' ->
generate_automatic_tags(S,C,TagNo);
_ ->
%% maybe is the module a multi file module were only some of
%% the modules have defaulttag AUTOMATIC TAGS then the names
%% of those types are saved in the table automatic_tags
Name= S#state.tname,
case is_automatic_tagged_in_multi_file(Name) of
true ->
generate_automatic_tags(S,C,TagNo);
false ->
C
end
end.
is_automatic_tagged_in_multi_file(Name) ->
case ets:info(automatic_tags) of
undefined ->
%% this case when not multifile compilation
false;
_ ->
case ets:member(automatic_tags,Name) of
true ->
true;
_ ->
false
end
end.
generate_automatic_tags(_S,C,TagNo) ->
case any_manual_tag(C) of
true ->
C;
false ->
generate_automatic_tags1(C,TagNo)
end.
generate_automatic_tags1([H|T],TagNo) when record(H,'ComponentType') ->
#'ComponentType'{typespec=Ts} = H,
NewTs = Ts#type{tag=[#tag{class='CONTEXT',
number=TagNo,
type={default,'IMPLICIT'},
form= 0 }]}, % PRIMITIVE
[H#'ComponentType'{typespec=NewTs}|generate_automatic_tags1(T,TagNo+1)];
generate_automatic_tags1([ExtMark|T],TagNo) -> % EXTENSIONMARK
[ExtMark | generate_automatic_tags1(T,TagNo)];
generate_automatic_tags1([],_) ->
[].
any_manual_tag([#'ComponentType'{typespec=#type{tag=[]}}|Rest]) ->
any_manual_tag(Rest);
any_manual_tag([{'EXTENSIONMARK',_,_}|Rest]) ->
any_manual_tag(Rest);
any_manual_tag([_|_Rest]) ->
true;
any_manual_tag([]) ->
false.
check_unique_tags(S,C) ->
case (S#state.module)#module.tagdefault of
'AUTOMATIC' ->
case any_manual_tag(C) of
false -> true;
_ -> collect_and_sort_tags(C,[])
end;
_ ->
collect_and_sort_tags(C,[])
end.
collect_and_sort_tags([C|Rest],Acc) when record(C,'ComponentType') ->
collect_and_sort_tags(Rest,C#'ComponentType'.tags ++ Acc);
collect_and_sort_tags([_|Rest],Acc) ->
collect_and_sort_tags(Rest,Acc);
collect_and_sort_tags([],Acc) ->
{Dupl,_}= lists:mapfoldl(fun(El,El)->{{dup,El},El};(El,_Prev)-> {El,El} end,notag,lists:sort(Acc)),
Dupl2 = [Dup|| {dup,Dup} <- Dupl],
if
length(Dupl2) > 0 ->
throw({error,{asn1,{duplicates_of_the_tags,Dupl2}}});
true ->
true
end.
check_unique(L,Pos) ->
Slist = lists:keysort(Pos,L),
check_unique2(Slist,Pos,[]).
check_unique2([A,B|T],Pos,Acc) when element(Pos,A) == element(Pos,B) ->
check_unique2([B|T],Pos,[element(Pos,B)|Acc]);
check_unique2([_|T],Pos,Acc) ->
check_unique2(T,Pos,Acc);
check_unique2([],_,Acc) ->
lists:reverse(Acc).
check_each_component(S,Type,{Rlist,ExtList}) ->
{check_each_component(S,Type,Rlist),
check_each_component(S,Type,ExtList)};
check_each_component(S,Type,Components) ->
check_each_component(S,Type,Components,[],[],noext).
check_each_component(S = #state{abscomppath=Path,recordtopname=TopName},Type,
[C|Ct],Acc,Extacc,Ext) when record(C,'ComponentType') ->
#'ComponentType'{name=Cname,typespec=Ts,prop=Prop} = C,
NewAbsCPath =
case Ts#type.def of
#'Externaltypereference'{} -> [];
_ -> [Cname|Path]
end,
CheckedTs = check_type(S#state{abscomppath=NewAbsCPath,
recordtopname=[Cname|TopName]},Type,Ts),
NewTags = get_taglist(S,CheckedTs),
NewProp =
% case lists:member(der,S#state.options) of
% true ->
% True ->
case normalize_value(S,CheckedTs,Prop,[Cname|TopName]) of
mandatory -> mandatory;
'OPTIONAL' -> 'OPTIONAL';
DefaultValue -> {'DEFAULT',DefaultValue}
end,
% _ ->
% Prop
% end,
NewC = C#'ComponentType'{typespec=CheckedTs,prop=NewProp,tags=NewTags},
case Ext of
noext ->
check_each_component(S,Type,Ct,[NewC|Acc],Extacc,Ext);
ext ->
check_each_component(S,Type,Ct,Acc,[NewC|Extacc],Ext)
end;
check_each_component(S,Type,[_|Ct],Acc,Extacc,noext) -> % skip 'EXTENSIONMARK'
check_each_component(S,Type,Ct,Acc,Extacc,ext);
check_each_component(_S,_,[_C|_Ct],_,_,ext) -> % skip 'EXTENSIONMARK'
throw({error,{asn1,{too_many_extension_marks}}});
check_each_component(_S,_,[],Acc,Extacc,ext) ->
{lists:reverse(Acc),lists:reverse(Extacc)};
check_each_component(_S,_,[],Acc,_,noext) ->
lists:reverse(Acc).
check_each_alternative(S,Type,{Rlist,ExtList}) ->
{check_each_alternative(S,Type,Rlist),
check_each_alternative(S,Type,ExtList)};
check_each_alternative(S,Type,[C|Ct]) ->
check_each_alternative(S,Type,[C|Ct],[],[],noext).
check_each_alternative(S=#state{abscomppath=Path,recordtopname=TopName},Type,[C|Ct],
Acc,Extacc,Ext) when record(C,'ComponentType') ->
#'ComponentType'{name=Cname,typespec=Ts,prop=_Prop} = C,
NewAbsCPath =
case Ts#type.def of
#'Externaltypereference'{} -> [];
_ -> [Cname|Path]
end,
NewState =
S#state{abscomppath=NewAbsCPath,recordtopname=[Cname|TopName]},
CheckedTs = check_type(NewState,Type,Ts),
NewTags = get_taglist(S,CheckedTs),
NewC = C#'ComponentType'{typespec=CheckedTs,tags=NewTags},
case Ext of
noext ->
check_each_alternative(S,Type,Ct,[NewC|Acc],Extacc,Ext);
ext ->
check_each_alternative(S,Type,Ct,Acc,[NewC|Extacc],Ext)
end;
check_each_alternative(S,Type,[_|Ct],Acc,Extacc,noext) -> % skip 'EXTENSIONMARK'
check_each_alternative(S,Type,Ct,Acc,Extacc,ext);
check_each_alternative(_S,_,[_C|_Ct],_,_,ext) -> % skip 'EXTENSIONMARK'
throw({error,{asn1,{too_many_extension_marks}}});
check_each_alternative(_S,_,[],Acc,Extacc,ext) ->
{lists:reverse(Acc),lists:reverse(Extacc)};
check_each_alternative(_S,_,[],Acc,_,noext) ->
lists:reverse(Acc).
%% componentrelation_leadingattr/2 searches the structure for table
%% constraints, if any is found componentrelation_leadingattr/5 is
%% called.
componentrelation_leadingattr(S,CompList) ->
% {Cs1,Cs2} =
Cs =
case CompList of
{Components,EComponents} when list(Components) ->
% {Components,Components};
Components ++ EComponents;
CompList when list(CompList) ->
% {CompList,CompList}
CompList
end,
% case any_simple_table(S,Cs1,[]) of
%% get_simple_table_if_used/2 should find out whether there are any
%% component relation constraints in the entire tree of Cs1 that
%% relates to this level. It returns information about the simple
%% table constraint necessary for the the call to
%% componentrelation_leadingattr/6. The step when the leading
%% attribute and the syntax tree is modified to support the code
%% generating.
case get_simple_table_if_used(S,Cs) of
[] -> {false,CompList};
STList ->
% componentrelation_leadingattr(S,Cs1,Cs2,STList,[],[])
componentrelation_leadingattr(S,Cs,Cs,STList,[],[])
end.
%% componentrelation_leadingattr/6 when all components are searched
%% the new modified components are returned together with the "leading
%% attribute" information, which later is stored in the tablecinf
%% field in the SEQUENCE/SET record. The "leading attribute"
%% information is used to generate the lookup in the object set
%% table. The other information gathered in the #type.tablecinf field
%% is used in code generating phase too, to recognice the proper
%% components for "open type" encoding and to propagate the result of
%% the object set lookup when needed.
componentrelation_leadingattr(_,[],_CompList,_,[],NewCompList) ->
{false,lists:reverse(NewCompList)};
componentrelation_leadingattr(_,[],_CompList,_,LeadingAttr,NewCompList) ->
{lists:last(LeadingAttr),lists:reverse(NewCompList)}; %send all info in Ts later
componentrelation_leadingattr(S,[C|Cs],CompList,STList,Acc,CompAcc) ->
{LAAcc,NewC} =
case catch componentrelation1(S,C#'ComponentType'.typespec,
[C#'ComponentType'.name]) of
{'EXIT',_} ->
{[],C};
{CRI=[{_A1,_B1,_C1,_D1}|_Rest],NewTSpec} ->
%% {ObjectSet,AtPath,ClassDef,Path}
%% _A1 is a reference to the object set of the
%% component relation constraint.
%% _B1 is the path of names in the at-list of the
%% component relation constraint.
%% _C1 is the class definition of the
%% ObjectClassFieldType.
%% _D1 is the path of components that was traversed to
%% find this constraint.
case leading_attr_index(S,CompList,CRI,
lists:reverse(S#state.abscomppath),[]) of
[] ->
{[],C};
[{ObjSet,Attr,N,ClassDef,_Path,ValueIndex}|_NewRest] ->
OS = object_set_mod_name(S,ObjSet),
UniqueFieldName =
case (catch get_unique_fieldname(#classdef{typespec=ClassDef})) of
{error,'__undefined_'} ->
no_unique;
{asn1,Msg,_} ->
error({type,Msg,S});
Other -> Other
end,
% UsedFieldName = get_used_fieldname(S,Attr,STList),
%% Res should be done differently: even though
%% a unique field name exists it is not
%% certain that the ObjectClassFieldType of
%% the simple table constraint picks that
%% class field.
Res = #simpletableattributes{objectsetname=OS,
%% c_name=asn1ct_gen:un_hyphen_var(Attr),
c_name=Attr,
c_index=N,
usedclassfield=UniqueFieldName,
uniqueclassfield=UniqueFieldName,
valueindex=ValueIndex},
{[Res],C#'ComponentType'{typespec=NewTSpec}}
end;
_ ->
%% no constraint was found
{[],C}
end,
componentrelation_leadingattr(S,Cs,CompList,STList,LAAcc++Acc,
[NewC|CompAcc]).
object_set_mod_name(_S,ObjSet) when atom(ObjSet) ->
ObjSet;
object_set_mod_name(#state{mname=M},
#'Externaltypereference'{module=M,type=T}) ->
T;
object_set_mod_name(S,#'Externaltypereference'{module=M,type=T}) ->
case lists:member(M,S#state.inputmodules) of
true ->
T;
false ->
{M,T}
end.
%% get_used_fieldname gets the used field of the class referenced by
%% the ObjectClassFieldType construct in the simple table constraint
%% corresponding to the component relation constraint that depends on
%% it.
% get_used_fieldname(_S,CName,[{[CName|_Rest],_,ClFieldName}|_RestSimpleT]) ->
% ClFieldName;
% get_used_fieldname(S,CName,[_SimpleTC|Rest]) ->
% get_used_fieldname(S,CName,Rest);
% get_used_fieldname(S,_,[]) ->
% error({type,"Error in Simple table constraint",S}).
%% any_simple_table/3 checks if any of the components on this level is
%% constrained by a simple table constraint. It returns a list of
%% tuples with three elements. It is a name path to the place in the
%% type structure where the constraint is, and the name of the object
%% set and the referenced field in the class.
% any_simple_table(S = #state{mname=M,abscomppath=Path},
% [#'ComponentType'{name=Name,typespec=Type}|Cs],Acc) ->
% Constraint = Type#type.constraint,
% case lists:keysearch(simpletable,1,Constraint) of
% {value,{_,#type{def=Ref}}} ->
% %% This ObjectClassFieldType, which has a simple table
% %% constraint, must pick a fixed type value, mustn't it ?
% {ClassDef,[{_,ClassFieldName}]} = Type#type.def,
% ST =
% case Ref of
% #'Externaltypereference'{module=M,type=ObjSetName} ->
% {[Name|Path],ObjSetName,ClassFieldName};
% _ ->
% {[Name|Path],Ref,ClassFieldName}
% end,
% any_simple_table(S,Cs,[ST|Acc]);
% false ->
% any_simple_table(S,Cs,Acc)
% end;
% any_simple_table(_,[],Acc) ->
% lists:reverse(Acc);
% any_simple_table(S,[_|Cs],Acc) ->
% any_simple_table(S,Cs,Acc).
%% get_simple_table_if_used/2 searches the structure of Cs for any
%% component relation constraints due to the present level of the
%% structure. If there are any, the necessary information for code
%% generation of the look up functionality in the object set table are
%% returned.
get_simple_table_if_used(S,Cs) ->
CNames = lists:map(fun(#'ComponentType'{name=Name}) -> Name;
(_) -> [] %% in case of extension marks
end,
Cs),
RefedSimpleTable=any_component_relation(S,Cs,CNames,[],[]),
get_simple_table_info(S,Cs,remove_doubles(RefedSimpleTable)).
remove_doubles(L) ->
remove_doubles(L,[]).
remove_doubles([H|T],Acc) ->
NewT = remove_doubles1(H,T),
remove_doubles(NewT,[H|Acc]);
remove_doubles([],Acc) ->
Acc.
remove_doubles1(El,L) ->
case lists:delete(El,L) of
L -> L;
NewL -> remove_doubles1(El,NewL)
end.
%% get_simple_table_info searches the commponents Cs by the path from
%% an at-list (third argument), and follows into a component of it if
%% necessary, to get information needed for code generating.
%%
%% Returns a list of tuples with three elements. It holds a list of
%% atoms that is the path, the name of the field of the class that are
%% referred to in the ObjectClassFieldType, and the name of the unique
%% field of the class of the ObjectClassFieldType.
%%
% %% The level information outermost/innermost must be kept. There are
% %% at least two possibilities to cover here for an outermost case: 1)
% %% Both the simple table and the component relation have a common path
% %% at least one step below the outermost level, i.e. the leading
% %% information shall be on a sub level. 2) They don't have any common
% %% path.
get_simple_table_info(S,Cs,[AtList|Rest]) ->
%% [get_simple_table_info1(S,Cs,AtList,S#state.abscomppath)|get_simple_table_info(S,Cs,Rest)];
[get_simple_table_info1(S,Cs,AtList,[])|get_simple_table_info(S,Cs,Rest)];
get_simple_table_info(_,_,[]) ->
[].
get_simple_table_info1(S,Cs,[Cname|Cnames],Path) when list(Cs) ->
case lists:keysearch(Cname,#'ComponentType'.name,Cs) of
{value,C} ->
get_simple_table_info1(S,C,Cnames,[Cname|Path]);
_ ->
error({type,"Missing expected simple table constraint",S})
end;
get_simple_table_info1(S,#'ComponentType'{typespec=TS},[],Path) ->
%% In this component there must be a simple table constraint
%% o.w. the asn1 code is wrong.
#type{def=OCFT,constraint=Cnstr} = TS,
case Cnstr of
[{simpletable,_OSRef}]�->
#'ObjectClassFieldType'{classname=ClRef,
class=ObjectClass,
fieldname=FieldName} = OCFT,
% #'ObjectClassFieldType'{ObjectClass,FieldType} = ObjectClassFieldType,
ObjectClassFieldName =
case FieldName of
{LastFieldName,[]} -> LastFieldName;
{_FirstFieldName,FieldNames} ->
lists:last(FieldNames)
end,
%%ObjectClassFieldName is the last element in the dotted
%%list of the ObjectClassFieldType. The last element may
%%be of another class, that is referenced from the class
%%of the ObjectClassFieldType
ClassDef =
case ObjectClass of
[] ->
{_,CDef}=get_referenced_type(S,ClRef),
CDef;
_ -> #classdef{typespec=ObjectClass}
end,
UniqueName =
case (catch get_unique_fieldname(ClassDef)) of
{error,'__undefined_'} -> no_unique;
{asn1,Msg,_} ->
error({type,Msg,S});
Other -> Other
end,
{lists:reverse(Path),ObjectClassFieldName,UniqueName};
_ ->
error({type,{asn1,"missing expected simple table constraint",
Cnstr},S})
end;
get_simple_table_info1(S,#'ComponentType'{typespec=TS},Cnames,Path) ->
Components = get_atlist_components(TS#type.def),
get_simple_table_info1(S,Components,Cnames,Path).
%% any_component_relation searches for all component relation
%% constraints that refers to the actual level and returns a list of
%% the "name path" in the at-list to the component relation constraint
%% that must refer to a simple table constraint. The list is empty if
%% no component relation constraints were found.
%%
%% NamePath has the names of all components that are followed from the
%% beginning of the search. CNames holds the names of all components
%% of the start level, this info is used if an outermost at-notation
%% is found to check the validity of the at-list.
any_component_relation(S,[C|Cs],CNames,NamePath,Acc) ->
CName = C#'ComponentType'.name,
Type = C#'ComponentType'.typespec,
CRelPath =
case Type#type.constraint of
[{componentrelation,_,AtNotation}] ->
%% Found component relation constraint, now check
%% whether this constraint is relevant for the level
%% where the search started
AtNot = extract_at_notation(AtNotation),
%% evaluate_atpath returns the relative path to the
%% simple table constraint from where the component
%% relation is found.
evaluate_atpath(S#state.abscomppath,NamePath,CNames,AtNot);
_ ->
[]
end,
InnerAcc =
case {Type#type.inlined,
asn1ct_gen:type(asn1ct_gen:get_inner(Type#type.def))} of
{no,{constructed,bif}} ->
InnerCs =
case get_components(Type#type.def) of
{IC1,_IC2} -> IC1 ++ IC1;
IC -> IC
end,
%% here we are interested in components of an
%% SEQUENCE/SET OF as well as SEQUENCE, SET and CHOICE
any_component_relation(S,InnerCs,CNames,[CName|NamePath],[]);
_ ->
[]
end,
any_component_relation(S,Cs,CNames,NamePath,InnerAcc++CRelPath++Acc);
any_component_relation(_,[],_,_,Acc) ->
Acc.
%% evaluate_atpath/4 finds out whether the at notation refers to the
%% search level. The list of referenced names in the AtNot list shall
%% begin with a name that exists on the level it refers to. If the
%% found AtPath is refering to the same sub-branch as the simple table
%% has, then there shall not be any leading attribute info on this
%% level.
evaluate_atpath(_,[],Cnames,{innermost,AtPath=[Ref|_Refs]}) ->
%% any innermost constraint found deeper in the structure is
%% ignored.
case lists:member(Ref,Cnames) of
true -> [AtPath];
false -> []
end;
%% In this case must check that the AtPath doesn't step any step of
%% the NamePath, in that case the constraint will be handled in an
%% inner level.
evaluate_atpath(TopPath,NamePath,Cnames,{outermost,AtPath=[_Ref|_Refs]}) ->
AtPathBelowTop =
case TopPath of
[] -> AtPath;
_ ->
case lists:prefix(TopPath,AtPath) of
true ->
lists:subtract(AtPath,TopPath);
_ -> []
end
end,
case {NamePath,AtPathBelowTop} of
{[H|_T1],[H|_T2]} -> []; % this must be handled in lower level
{_,[]} -> [];% this must be handled in an above level
{_,[H|_T]} ->
case lists:member(H,Cnames) of
true -> [AtPathBelowTop];
_ -> error({type,{asn1,"failed to analyze at-path",AtPath}})
end
end;
evaluate_atpath(_,_,_,_) ->
[].
%% Type may be any of SEQUENCE, SET, CHOICE, SEQUENCE OF, SET OF but
%% only the three first have valid components.
get_atlist_components(Def) ->
get_components(atlist,Def).
get_components(Def) ->
get_components(any,Def).
get_components(_,#'SEQUENCE'{components=Cs}) ->
Cs;
get_components(_,#'SET'{components=Cs}) ->
Cs;
get_components(_,{'CHOICE',Cs}) ->
Cs;
get_components(any,{'SEQUENCE OF',#type{def=Def}}) ->
get_components(any,Def);
get_components(any,{'SET OF',#type{def=Def}}) ->
get_components(any,Def);
get_components(_,_) ->
[].
extract_at_notation([{Level,[#'Externalvaluereference'{value=Name}|Rest]}]) ->
{Level,[Name|extract_at_notation1(Rest)]};
extract_at_notation(At) ->
exit({error,{asn1,{at_notation,At}}}).
extract_at_notation1([#'Externalvaluereference'{value=Name}|Rest]) ->
[Name|extract_at_notation1(Rest)];
extract_at_notation1([]) ->
[].
%% componentrelation1/1 identifies all componentrelation constraints
%% that exist in C or in the substructure of C. Info about the found
%% constraints are returned in a list. It is ObjectSet, the reference
%% to the object set, AttrPath, the name atoms extracted from the
%% at-list in the component relation constraint, ClassDef, the
%% objectclass record of the class of the ObjectClassFieldType, Path,
%% that is the component name "path" from the searched level to this
%% constraint.
%%
%% The function is called with one component of the type in turn and
%% with the component name in Path at the first call. When called from
%% within, the name of the inner component is added to Path.
componentrelation1(S,C = #type{def=Def,constraint=Constraint,tablecinf=TCI},
Path) ->
Ret =
case Constraint of
[{componentrelation,{_,_,ObjectSet},AtList}|_Rest] ->
[{_,AL=[#'Externalvaluereference'{}|_R1]}|_R2] = AtList,
%% Note: if Path is longer than one,i.e. it is within
%% an inner type of the actual level, then the only
%% relevant at-list is of "outermost" type.
%% #'ObjectClassFieldType'{class=ClassDef} = Def,
ClassDef = get_ObjectClassFieldType_classdef(S,Def),
AtPath =
lists:map(fun(#'Externalvaluereference'{value=V})->V end,
AL),
{[{ObjectSet,AtPath,ClassDef,Path}],Def};
_Other ->
%% check the inner type of component
innertype_comprel(S,Def,Path)
end,
case Ret of
nofunobj ->
nofunobj; %% ignored by caller
{CRelI=[{ObjSet,_,_,_}],NewDef} -> %%
TCItmp = lists:subtract(TCI,[{objfun,ObjSet}]),
{CRelI,C#type{tablecinf=[{objfun,ObjSet}|TCItmp],def=NewDef}};
{CompRelInf,NewDef} -> %% more than one tuple in CompRelInf
TCItmp = lists:subtract(TCI,[{objfun,anyset}]),
{CompRelInf,C#type{tablecinf=[{objfun,anyset}|TCItmp],def=NewDef}}
end.
innertype_comprel(S,{'SEQUENCE OF',Type},Path) ->
case innertype_comprel1(S,Type,Path) of
nofunobj ->
nofunobj;
{CompRelInf,NewType} ->
{CompRelInf,{'SEQUENCE OF',NewType}}
end;
innertype_comprel(S,{'SET OF',Type},Path) ->
case innertype_comprel1(S,Type,Path) of
nofunobj ->
nofunobj;
{CompRelInf,NewType} ->
{CompRelInf,{'SET OF',NewType}}
end;
innertype_comprel(S,{'CHOICE',CTypeList},Path) ->
case componentlist_comprel(S,CTypeList,[],Path,[]) of
nofunobj ->
nofunobj;
{CompRelInf,NewCs} ->
{CompRelInf,{'CHOICE',NewCs}}
end;
innertype_comprel(S,Seq = #'SEQUENCE'{components=Cs},Path) ->
case componentlist_comprel(S,Cs,[],Path,[]) of
nofunobj ->
nofunobj;
{CompRelInf,NewCs} ->
{CompRelInf,Seq#'SEQUENCE'{components=NewCs}}
end;
innertype_comprel(S,Set = #'SET'{components=Cs},Path) ->
case componentlist_comprel(S,Cs,[],Path,[]) of
nofunobj ->
nofunobj;
{CompRelInf,NewCs} ->
{CompRelInf,Set#'SET'{components=NewCs}}
end;
innertype_comprel(_,_,_) ->
nofunobj.
componentlist_comprel(S,[C = #'ComponentType'{name=Name,typespec=Type}|Cs],
Acc,Path,NewCL) ->
case catch componentrelation1(S,Type,Path++[Name]) of
{'EXIT',_} ->
componentlist_comprel(S,Cs,Acc,Path,[C|NewCL]);
nofunobj ->
componentlist_comprel(S,Cs,Acc,Path,[C|NewCL]);
{CRelInf,NewType} ->
componentlist_comprel(S,Cs,CRelInf++Acc,Path,
[C#'ComponentType'{typespec=NewType}|NewCL])
end;
componentlist_comprel(_,[],Acc,_,NewCL) ->
case Acc of
[] ->
nofunobj;
_ ->
{Acc,lists:reverse(NewCL)}
end.
innertype_comprel1(S,T = #type{def=Def,constraint=Cons,tablecinf=TCI},Path) ->
Ret =
case Cons of
[{componentrelation,{_,_,ObjectSet},AtList}|_Rest] ->
%% This AtList must have an "outermost" at sign to be
%% relevent here.
[{_,AL=[#'Externalvaluereference'{value=_Attr}|_R1]}|_R2]
= AtList,
%% #'ObjectClassFieldType'{class=ClassDef} = Def,
ClassDef = get_ObjectClassFieldType_classdef(S,Def),
AtPath =
lists:map(fun(#'Externalvaluereference'{value=V})->V end,
AL),
[{ObjectSet,AtPath,ClassDef,Path}];
_ ->
innertype_comprel(S,Def,Path)
end,
case Ret of
nofunobj -> nofunobj;
L = [{ObjSet,_,_,_}] ->
TCItmp = lists:subtract(TCI,[{objfun,ObjSet}]),
{L,T#type{tablecinf=[{objfun,ObjSet}|TCItmp]}};
{CRelInf,NewDef} ->
TCItmp = lists:subtract(TCI,[{objfun,anyset}]),
{CRelInf,T#type{def=NewDef,tablecinf=[{objfun,anyset}|TCItmp]}}
end.
%% leading_attr_index counts the index and picks the name of the
%% component that is at the actual level in the at-list of the
%% component relation constraint (AttrP). AbsP is the path of
%% component names from the top type level to the actual level. AttrP
%% is a list with the atoms from the at-list.
leading_attr_index(S,Cs,[H={_,AttrP,_,_}|T],AbsP,Acc) ->
AttrInfo =
case lists:prefix(AbsP,AttrP) of
%% why this ?? It is necessary when in same situation as
%% TConstrChoice, there is an inner structure with an
%% outermost at-list and the "leading attribute" code gen
%% may be at a level some steps below the outermost level.
true ->
RelativAttrP = lists:subtract(AttrP,AbsP),
%% The header is used to calculate the index of the
%% component and to give the fun, received from the
%% object set look up, an unique name. The tail is
%% used to match the proper value input to the fun.
{hd(RelativAttrP),tl(RelativAttrP)};
false ->
{hd(AttrP),tl(AttrP)}
end,
case leading_attr_index1(S,Cs,H,AttrInfo,1) of
0 ->
leading_attr_index(S,Cs,T,AbsP,Acc);
Res ->
leading_attr_index(S,Cs,T,AbsP,[Res|Acc])
end;
leading_attr_index(_,_Cs,[],_,Acc) ->
lists:reverse(Acc).
leading_attr_index1(_,[],_,_,_) ->
0;
leading_attr_index1(S,[C|Cs],Arg={ObjectSet,_,CDef,P},
AttrInfo={Attr,SubAttr},N) ->
case C#'ComponentType'.name of
Attr ->
ValueMatch = value_match(S,C,Attr,SubAttr),
{ObjectSet,Attr,N,CDef,P,ValueMatch};
_ ->
leading_attr_index1(S,Cs,Arg,AttrInfo,N+1)
end.
%% value_math gathers information for a proper value match in the
%% generated encode function. For a SEQUENCE or a SET the index of the
%% component is counted. For a CHOICE the index is 2.
value_match(S,C,Name,SubAttr) ->
value_match(S,C,Name,SubAttr,[]). % C has name Name
value_match(_S,#'ComponentType'{},_Name,[],Acc) ->
Acc;% do not reverse, indexes in reverse order
value_match(S,#'ComponentType'{typespec=Type},Name,[At|Ats],Acc) ->
InnerType = asn1ct_gen:get_inner(Type#type.def),
Components =
case get_atlist_components(Type#type.def) of
[] -> error({type,{asn1,"element in at list must be a "
"SEQUENCE, SET or CHOICE.",Name},S});
Comps -> Comps
end,
{Index,ValueIndex} = component_value_index(S,InnerType,At,Components),
value_match(S,lists:nth(Index,Components),At,Ats,[ValueIndex|Acc]).
component_value_index(S,'CHOICE',At,Components) ->
{component_index(S,At,Components),2};
component_value_index(S,_,At,Components) ->
%% SEQUENCE or SET
Index = component_index(S,At,Components),
{Index,{Index+1,At}}.
component_index(S,Name,Components) ->
component_index1(S,Name,Components,1).
component_index1(_S,Name,[#'ComponentType'{name=Name}|_Cs],N) ->
N;
component_index1(S,Name,[_C|Cs],N) ->
component_index1(S,Name,Cs,N+1);
component_index1(S,Name,[],_) ->
error({type,{asn1,"component of at-list was not"
" found in substructure",Name},S}).
get_unique_fieldname(ClassDef) ->
%% {_,Fields,_} = ClassDef#classdef.typespec,
Fields = (ClassDef#classdef.typespec)#objectclass.fields,
get_unique_fieldname(Fields,[]).
get_unique_fieldname([],[]) ->
throw({error,'__undefined_'});
get_unique_fieldname([],[Name]) ->
Name;
get_unique_fieldname([],Acc) ->
throw({asn1,'only one UNIQUE field is allowed in CLASS',Acc});
get_unique_fieldname([{fixedtypevaluefield,Name,_,'UNIQUE',_}|Rest],Acc) ->
get_unique_fieldname(Rest,[Name|Acc]);
get_unique_fieldname([_H|T],Acc) ->
get_unique_fieldname(T,Acc).
get_tableconstraint_info(S,Type,{CheckedTs,EComps}) ->
{get_tableconstraint_info(S,Type,CheckedTs,[]),
get_tableconstraint_info(S,Type,EComps,[])};
get_tableconstraint_info(S,Type,CheckedTs) ->
get_tableconstraint_info(S,Type,CheckedTs,[]).
get_tableconstraint_info(_S,_Type,[],Acc) ->
lists:reverse(Acc);
get_tableconstraint_info(S,Type,[C|Cs],Acc) ->
CheckedTs = C#'ComponentType'.typespec,
AccComp =
case CheckedTs#type.def of
%% ObjectClassFieldType
OCFT=#'ObjectClassFieldType'{class=#objectclass{},
type=_AType} ->
% AType = get_ObjectClassFieldType(S,Fields,FieldRef),
% RefedFieldName =
% get_referencedclassfield(CheckedTs#type.def),%is probably obsolete
NewOCFT =
OCFT#'ObjectClassFieldType'{class=[]},
C#'ComponentType'{typespec=
CheckedTs#type{
% def=AType,
def=NewOCFT
}};
% constraint=[{tableconstraint_info,
% FieldRef}]}};
{'SEQUENCE OF',SOType} when record(SOType,type),
(element(1,SOType#type.def)=='CHOICE') ->
CTypeList = element(2,SOType#type.def),
NewInnerCList =
get_tableconstraint_info(S,Type,CTypeList,[]),
C#'ComponentType'{typespec=
CheckedTs#type{
def={'SEQUENCE OF',
SOType#type{def={'CHOICE',
NewInnerCList}}}}};
{'SET OF',SOType} when record(SOType,type),
(element(1,SOType#type.def)=='CHOICE') ->
CTypeList = element(2,SOType#type.def),
NewInnerCList =
get_tableconstraint_info(S,Type,CTypeList,[]),
C#'ComponentType'{typespec=
CheckedTs#type{
def={'SET OF',
SOType#type{def={'CHOICE',
NewInnerCList}}}}};
_ ->
C
end,
get_tableconstraint_info(S,Type,Cs,[AccComp|Acc]).
get_referenced_fieldname([{_,FirstFieldname}]) ->
{FirstFieldname,[]};
get_referenced_fieldname([{_,FirstFieldname}|Rest]) ->
{FirstFieldname,lists:map(fun(X)->element(2,X) end,Rest)};
get_referenced_fieldname(Def) ->
{no_type,Def}.
%% get_ObjectClassFieldType extracts the type from the chain of
%% objects that leads to a final type.
get_ObjectClassFieldType(S,ERef,PrimFieldNameList) when
record(ERef,'Externaltypereference') ->
{_,Type} = get_referenced_type(S,ERef),
ClassSpec = check_class(S,Type),
Fields = ClassSpec#objectclass.fields,
get_ObjectClassFieldType(S,Fields,PrimFieldNameList);
get_ObjectClassFieldType(S,Fields,L=[_PrimFieldName1|_Rest]) ->
check_PrimitiveFieldNames(S,Fields,L),
get_OCFType(S,Fields,L).
check_PrimitiveFieldNames(_S,_Fields,_) ->
ok.
%% get_ObjectClassFieldType_classdef gets the def of the class of the
%% ObjectClassFieldType, i.e. the objectclass record. If the type has
%% been checked (it may be a field type of an internal SEQUENCE) the
%% class field = [], then the classdef has to be fetched by help of
%% the class reference in the classname field.
get_ObjectClassFieldType_classdef(S,#'ObjectClassFieldType'{classname=Name,
class=[]}) ->
{_,#classdef{typespec=TS}} = get_referenced_type(S,Name),
TS;
get_ObjectClassFieldType_classdef(_,#'ObjectClassFieldType'{class=Cl}) ->
Cl.
get_OCFType(S,Fields,[{_FieldType,PrimFieldName}|Rest]) ->
case lists:keysearch(PrimFieldName,2,Fields) of
{value,{fixedtypevaluefield,_,Type,_Unique,_OptSpec}} ->
{fixedtypevaluefield,PrimFieldName,Type};
{value,{objectfield,_,Type,_Unique,_OptSpec}} ->
{_,ClassDef} = get_referenced_type(S,Type#type.def),
CheckedCDef = check_class(S#state{type=ClassDef,
tname=ClassDef#classdef.name},
ClassDef#classdef.typespec),
get_OCFType(S,CheckedCDef#objectclass.fields,Rest);
{value,{objectsetfield,_,Type,_OptSpec}} ->
{_,ClassDef} = get_referenced_type(S,Type#type.def),
CheckedCDef = check_class(S#state{type=ClassDef,
tname=ClassDef#classdef.name},
ClassDef#classdef.typespec),
get_OCFType(S,CheckedCDef#objectclass.fields,Rest);
{value,Other} ->
{element(1,Other),PrimFieldName};
_ ->
error({type,"undefined FieldName in ObjectClassFieldType",S})
end.
get_taglist(#state{erule=per},_) ->
[];
get_taglist(#state{erule=per_bin},_) ->
[];
get_taglist(S,Ext) when record(Ext,'Externaltypereference') ->
{_,T} = get_referenced_type(S,Ext),
get_taglist(S,T#typedef.typespec);
get_taglist(S,Tref) when record(Tref,typereference) ->
{_,T} = get_referenced_type(S,Tref),
get_taglist(S,T#typedef.typespec);
get_taglist(S,Type) when record(Type,type) ->
case Type#type.tag of
[] ->
get_taglist(S,Type#type.def);
[Tag|_] ->
% case lists:member(S#state.erule,[ber,ber_bin]) of
% true ->
% lists:map(fun(Tx) -> asn1ct_gen:def_to_tag(Tx) end,Type#type.tag);
% _ ->
[asn1ct_gen:def_to_tag(Tag)]
% end
end;
get_taglist(S,{'CHOICE',{Rc,Ec}}) ->
get_taglist(S,{'CHOICE',Rc ++ Ec});
get_taglist(S,{'CHOICE',Components}) ->
get_taglist1(S,Components);
%% ObjectClassFieldType OTP-4390
get_taglist(_S,#'ObjectClassFieldType'{type={typefield,_}}) ->
[];
get_taglist(S,#'ObjectClassFieldType'{type={fixedtypevaluefield,_,Type}}) ->
get_taglist(S,Type);
get_taglist(S,{ERef=#'Externaltypereference'{},FieldNameList})
when list(FieldNameList) ->
case get_ObjectClassFieldType(S,ERef,FieldNameList) of
Type when record(Type,type) ->
get_taglist(S,Type);
{fixedtypevaluefield,_,Type} -> get_taglist(S,Type);
{TypeFieldName,_} when atom(TypeFieldName) -> []%should check if allowed
end;
get_taglist(S,{ObjCl,FieldNameList}) when record(ObjCl,objectclass),
list(FieldNameList) ->
case get_ObjectClassFieldType(S,ObjCl#objectclass.fields,FieldNameList) of
Type when record(Type,type) ->
get_taglist(S,Type);
{fixedtypevaluefield,_,Type} -> get_taglist(S,Type);
{TypeFieldName,_} when atom(TypeFieldName) -> []%should check if allowed
end;
get_taglist(S,Def) ->
case lists:member(S#state.erule,[ber_bin_v2]) of
false ->
case Def of
'ASN1_OPEN_TYPE' -> % open_type has no UNIVERSAL tag as such
[];
_ ->
[asn1ct_gen:def_to_tag(Def)]
end;
_ ->
[]
end.
get_taglist1(S,[#'ComponentType'{name=_Cname,tags=TagL}|Rest]) when list(TagL) ->
%% tag_list has been here , just return TagL and continue with next alternative
TagL ++ get_taglist1(S,Rest);
get_taglist1(S,[#'ComponentType'{typespec=Ts,tags=undefined}|Rest]) ->
get_taglist(S,Ts) ++ get_taglist1(S,Rest);
get_taglist1(S,[_H|Rest]) -> % skip EXTENSIONMARK
get_taglist1(S,Rest);
get_taglist1(_S,[]) ->
[].
dbget_ex(_S,Module,Key) ->
case asn1_db:dbget(Module,Key) of
undefined ->
throw({error,{asn1,{undefined,{Module,Key}}}}); % this is catched on toplevel type or value
T -> T
end.
merge_tags(T1, T2) when list(T2) ->
merge_tags2(T1 ++ T2, []);
merge_tags(T1, T2) ->
merge_tags2(T1 ++ [T2], []).
merge_tags2([T1= #tag{type='IMPLICIT'}, T2 |Rest], Acc) ->
merge_tags2([T1#tag{type=T2#tag.type, form=T2#tag.form}|Rest],Acc);
merge_tags2([T1= #tag{type={default,'IMPLICIT'}}, T2 |Rest], Acc) ->
merge_tags2([T1#tag{type=T2#tag.type, form=T2#tag.form}|Rest],Acc);
merge_tags2([H|T],Acc) ->
merge_tags2(T, [H|Acc]);
merge_tags2([], Acc) ->
lists:reverse(Acc).
merge_constraints(C1, []) ->
C1;
merge_constraints([], C2) ->
C2;
merge_constraints(C1, C2) ->
{SList,VList,PAList,Rest} = splitlist(C1++C2,[],[],[],[]),
SizeC = merge_constraints(SList),
ValueC = merge_constraints(VList),
PermAlphaC = merge_constraints(PAList),
case Rest of
[] ->
SizeC ++ ValueC ++ PermAlphaC;
_ ->
throw({error,{asn1,{not_implemented,{merge_constraints,Rest}}}})
end.
merge_constraints([]) -> [];
merge_constraints([C1 = {_,{Low1,High1}},{_,{Low2,High2}}|Rest]) when Low1 >= Low2,
High1 =< High2 ->
merge_constraints([C1|Rest]);
merge_constraints([C1={'PermittedAlphabet',_},C2|Rest]) ->
[C1|merge_constraints([C2|Rest])];
merge_constraints([C1 = {_,{_Low1,_High1}},C2 = {_,{_Low2,_High2}}|_Rest]) ->
throw({error,asn1,{conflicting_constraints,{C1,C2}}});
merge_constraints([C]) ->
[C].
splitlist([C={'SizeConstraint',_}|Rest],Sacc,Vacc,PAacc,Restacc) ->
splitlist(Rest,[C|Sacc],Vacc,PAacc,Restacc);
splitlist([C={'ValueRange',_}|Rest],Sacc,Vacc,PAacc,Restacc) ->
splitlist(Rest,Sacc,[C|Vacc],PAacc,Restacc);
splitlist([C={'PermittedAlphabet',_}|Rest],Sacc,Vacc,PAacc,Restacc) ->
splitlist(Rest,Sacc,Vacc,[C|PAacc],Restacc);
splitlist([C|Rest],Sacc,Vacc,PAacc,Restacc) ->
splitlist(Rest,Sacc,Vacc,PAacc,[C|Restacc]);
splitlist([],Sacc,Vacc,PAacc,Restacc) ->
{lists:reverse(Sacc),
lists:reverse(Vacc),
lists:reverse(PAacc),
lists:reverse(Restacc)}.
storeindb(M) when record(M,module) ->
TVlist = M#module.typeorval,
NewM = M#module{typeorval=findtypes_and_values(TVlist)},
asn1_db:dbnew(NewM#module.name),
asn1_db:dbput(NewM#module.name,'MODULE', NewM),
Res = storeindb(NewM#module.name,TVlist,[]),
include_default_class(NewM#module.name),
include_default_type(NewM#module.name),
Res.
storeindb(Module,[H|T],ErrAcc) when record(H,typedef) ->
storeindb(Module,H#typedef.name,H,T,ErrAcc);
storeindb(Module,[H|T],ErrAcc) when record(H,valuedef) ->
storeindb(Module,H#valuedef.name,H,T,ErrAcc);
storeindb(Module,[H|T],ErrAcc) when record(H,ptypedef) ->
storeindb(Module,H#ptypedef.name,H,T,ErrAcc);
storeindb(Module,[H|T],ErrAcc) when record(H,classdef) ->
storeindb(Module,H#classdef.name,H,T,ErrAcc);
storeindb(Module,[H|T],ErrAcc) when record(H,pvaluesetdef) ->
storeindb(Module,H#pvaluesetdef.name,H,T,ErrAcc);
storeindb(Module,[H|T],ErrAcc) when record(H,pobjectdef) ->
storeindb(Module,H#pobjectdef.name,H,T,ErrAcc);
storeindb(Module,[H|T],ErrAcc) when record(H,pvaluedef) ->
storeindb(Module,H#pvaluedef.name,H,T,ErrAcc);
storeindb(_,[],[]) -> ok;
storeindb(_,[],ErrAcc) ->
{error,ErrAcc}.
storeindb(Module,Name,H,T,ErrAcc) ->
case asn1_db:dbget(Module,Name) of
undefined ->
asn1_db:dbput(Module,Name,H),
storeindb(Module,T,ErrAcc);
_ ->
case H of
_Type when record(H,typedef) ->
error({type,"already defined",
#state{mname=Module,type=H,tname=Name}});
_Type when record(H,valuedef) ->
error({value,"already defined",
#state{mname=Module,value=H,vname=Name}});
_Type when record(H,ptypedef) ->
error({ptype,"already defined",
#state{mname=Module,type=H,tname=Name}});
_Type when record(H,pobjectdef) ->
error({ptype,"already defined",
#state{mname=Module,type=H,tname=Name}});
_Type when record(H,pvaluesetdef) ->
error({ptype,"already defined",
#state{mname=Module,type=H,tname=Name}});
_Type when record(H,pvaluedef) ->
error({ptype,"already defined",
#state{mname=Module,type=H,tname=Name}});
_Type when record(H,classdef) ->
error({class,"already defined",
#state{mname=Module,value=H,vname=Name}})
end,
storeindb(Module,T,[H|ErrAcc])
end.
findtypes_and_values(TVList) ->
findtypes_and_values(TVList,[],[],[],[],[],[]).%% Types,Values,
%% Parameterizedtypes,Classes,Objects and ObjectSets
findtypes_and_values([H|T],Tacc,Vacc,Pacc,Cacc,Oacc,OSacc)
when record(H,typedef),record(H#typedef.typespec,'Object') ->
findtypes_and_values(T,Tacc,Vacc,Pacc,Cacc,[H#typedef.name|Oacc],OSacc);
findtypes_and_values([H|T],Tacc,Vacc,Pacc,Cacc,Oacc,OSacc)
when record(H,typedef),record(H#typedef.typespec,'ObjectSet') ->
findtypes_and_values(T,Tacc,Vacc,Pacc,Cacc,Oacc,[H#typedef.name|OSacc]);
findtypes_and_values([H|T],Tacc,Vacc,Pacc,Cacc,Oacc,OSacc)
when record(H,typedef) ->
findtypes_and_values(T,[H#typedef.name|Tacc],Vacc,Pacc,Cacc,Oacc,OSacc);
findtypes_and_values([H|T],Tacc,Vacc,Pacc,Cacc,Oacc,OSacc)
when record(H,valuedef) ->
findtypes_and_values(T,Tacc,[H#valuedef.name|Vacc],Pacc,Cacc,Oacc,OSacc);
findtypes_and_values([H|T],Tacc,Vacc,Pacc,Cacc,Oacc,OSacc)
when record(H,ptypedef) ->
findtypes_and_values(T,Tacc,Vacc,[H#ptypedef.name|Pacc],Cacc,Oacc,OSacc);
findtypes_and_values([H|T],Tacc,Vacc,Pacc,Cacc,Oacc,OSacc)
when record(H,classdef) ->
findtypes_and_values(T,Tacc,Vacc,Pacc,[H#classdef.name|Cacc],Oacc,OSacc);
findtypes_and_values([H|T],Tacc,Vacc,Pacc,Cacc,Oacc,OSacc)
when record(H,pvaluedef) ->
findtypes_and_values(T,Tacc,[H#pvaluedef.name|Vacc],Pacc,Cacc,Oacc,OSacc);
findtypes_and_values([H|T],Tacc,Vacc,Pacc,Cacc,Oacc,OSacc)
when record(H,pvaluesetdef) ->
findtypes_and_values(T,Tacc,[H#pvaluesetdef.name|Vacc],Pacc,Cacc,Oacc,OSacc);
findtypes_and_values([H|T],Tacc,Vacc,Pacc,Cacc,Oacc,OSacc)
when record(H,pobjectdef) ->
findtypes_and_values(T,Tacc,Vacc,Pacc,Cacc,[H#pobjectdef.name|Oacc],OSacc);
findtypes_and_values([H|T],Tacc,Vacc,Pacc,Cacc,Oacc,OSacc)
when record(H,pobjectsetdef) ->
findtypes_and_values(T,Tacc,Vacc,Pacc,Cacc,Oacc,[H#pobjectsetdef.name|OSacc]);
findtypes_and_values([],Tacc,Vacc,Pacc,Cacc,Oacc,OSacc) ->
{lists:reverse(Tacc),lists:reverse(Vacc),lists:reverse(Pacc),
lists:reverse(Cacc),lists:reverse(Oacc),lists:reverse(OSacc)}.
error({export,Msg,#state{mname=Mname,type=Ref,tname=Typename}}) ->
Pos = Ref#'Externaltypereference'.pos,
io:format("asn1error:~p:~p:~p ~p~n",[Pos,Mname,Typename,Msg]),
{error,{export,Pos,Mname,Typename,Msg}};
error({type,Msg,#state{mname=Mname,type=Type,tname=Typename}})
when record(Type,typedef) ->
io:format("asn1error:~p:~p:~p ~p~n",
[Type#typedef.pos,Mname,Typename,Msg]),
{error,{type,Type#typedef.pos,Mname,Typename,Msg}};
error({type,Msg,#state{mname=Mname,type=Type,tname=Typename}})
when record(Type,ptypedef) ->
io:format("asn1error:~p:~p:~p ~p~n",
[Type#ptypedef.pos,Mname,Typename,Msg]),
{error,{type,Type#ptypedef.pos,Mname,Typename,Msg}};
error({type,Msg,#state{mname=Mname,value=Value,vname=Valuename}})
when record(Value,valuedef) ->
io:format("asn1error:~p:~p:~p ~p~n",[Value#valuedef.pos,Mname,Valuename,Msg]),
{error,{type,Value#valuedef.pos,Mname,Valuename,Msg}};
error({type,Msg,#state{mname=Mname,type=Type,tname=Typename}})
when record(Type,pobjectdef) ->
io:format("asn1error:~p:~p:~p ~p~n",
[Type#pobjectdef.pos,Mname,Typename,Msg]),
{error,{type,Type#pobjectdef.pos,Mname,Typename,Msg}};
error({value,Msg,#state{mname=Mname,value=Value,vname=Valuename}}) ->
io:format("asn1error:~p:~p:~p ~p~n",[Value#valuedef.pos,Mname,Valuename,Msg]),
{error,{value,Value#valuedef.pos,Mname,Valuename,Msg}};
error({Other,Msg,#state{mname=Mname,value=#valuedef{pos=Pos},vname=Valuename}}) ->
io:format("asn1error:~p:~p:~p ~p~n",[Pos,Mname,Valuename,Msg]),
{error,{Other,Pos,Mname,Valuename,Msg}};
error({Other,Msg,#state{mname=Mname,type=#typedef{pos=Pos},tname=Typename}}) ->
io:format("asn1error:~p:~p:~p ~p~n",[Pos,Mname,Typename,Msg]),
{error,{Other,Pos,Mname,Typename,Msg}};
error({Other,Msg,#state{mname=Mname,type=#classdef{pos=Pos},tname=Typename}}) ->
io:format("asn1error:~p:~p:~p ~p~n",[Pos,Mname,Typename,Msg]),
{error,{Other,Pos,Mname,Typename,Msg}}.
include_default_type(Module) ->
NameAbsList = default_type_list(),
include_default_type1(Module,NameAbsList).
include_default_type1(_,[]) ->
ok;
include_default_type1(Module,[{Name,TS}|Rest]) ->
case asn1_db:dbget(Module,Name) of
undefined ->
T = #typedef{name=Name,
typespec=TS},
asn1_db:dbput(Module,Name,T);
_ -> ok
end,
include_default_type1(Module,Rest).
default_type_list() ->
%% The EXTERNAL type is represented, according to ASN.1 1997,
%% as a SEQUENCE with components: identification, data-value-descriptor
%% and data-value.
Syntax =
#'ComponentType'{name=syntax,
typespec=#type{def='OBJECT IDENTIFIER'},
prop=mandatory},
Presentation_Cid =
#'ComponentType'{name='presentation-context-id',
typespec=#type{def='INTEGER'},
prop=mandatory},
Transfer_syntax =
#'ComponentType'{name='transfer-syntax',
typespec=#type{def='OBJECT IDENTIFIER'},
prop=mandatory},
Negotiation_items =
#type{def=
#'SEQUENCE'{components=
[Presentation_Cid,
Transfer_syntax#'ComponentType'{prop=mandatory}]}},
Context_negot =
#'ComponentType'{name='context-negotiation',
typespec=Negotiation_items,
prop=mandatory},
Data_value_descriptor =
#'ComponentType'{name='data-value-descriptor',
typespec=#type{def='ObjectDescriptor'},
prop='OPTIONAL'},
Data_value =
#'ComponentType'{name='data-value',
typespec=#type{def='OCTET STRING'},
prop=mandatory},
%% The EXTERNAL type is represented, according to ASN.1 1990,
%% as a SEQUENCE with components: direct-reference, indirect-reference,
%% data-value-descriptor and encoding.
Direct_reference =
#'ComponentType'{name='direct-reference',
typespec=#type{def='OBJECT IDENTIFIER'},
prop='OPTIONAL'},
Indirect_reference =
#'ComponentType'{name='indirect-reference',
typespec=#type{def='INTEGER'},
prop='OPTIONAL'},
Single_ASN1_type =
#'ComponentType'{name='single-ASN1-type',
typespec=#type{tag=[{tag,'CONTEXT',0,
'EXPLICIT',32}],
def='ANY'},
prop=mandatory},
Octet_aligned =
#'ComponentType'{name='octet-aligned',
typespec=#type{tag=[{tag,'CONTEXT',1,
'IMPLICIT',32}],
def='OCTET STRING'},
prop=mandatory},
Arbitrary =
#'ComponentType'{name=arbitrary,
typespec=#type{tag=[{tag,'CONTEXT',2,
'IMPLICIT',32}],
def={'BIT STRING',[]}},
prop=mandatory},
Encoding =
#'ComponentType'{name=encoding,
typespec=#type{def={'CHOICE',
[Single_ASN1_type,Octet_aligned,
Arbitrary]}},
prop=mandatory},
EXTERNAL_components1990 =
[Direct_reference,Indirect_reference,Data_value_descriptor,Encoding],
%% The EMBEDDED PDV type is represented by a SEQUENCE type
%% with components: identification and data-value
Abstract =
#'ComponentType'{name=abstract,
typespec=#type{def='OBJECT IDENTIFIER'},
prop=mandatory},
Transfer =
#'ComponentType'{name=transfer,
typespec=#type{def='OBJECT IDENTIFIER'},
prop=mandatory},
AbstractTrSeq =
#'SEQUENCE'{components=[Abstract,Transfer]},
Syntaxes =
#'ComponentType'{name=syntaxes,
typespec=#type{def=AbstractTrSeq},
prop=mandatory},
Fixed = #'ComponentType'{name=fixed,
typespec=#type{def='NULL'},
prop=mandatory},
Negotiations =
[Syntaxes,Syntax,Presentation_Cid,Context_negot,
Transfer_syntax,Fixed],
Identification2 =
#'ComponentType'{name=identification,
typespec=#type{def={'CHOICE',Negotiations}},
prop=mandatory},
EmbeddedPdv_components =
[Identification2,Data_value],
%% The CHARACTER STRING type is represented by a SEQUENCE type
%% with components: identification and string-value
String_value =
#'ComponentType'{name='string-value',
typespec=#type{def='OCTET STRING'},
prop=mandatory},
CharacterString_components =
[Identification2,String_value],
[{'EXTERNAL',
#type{tag=[#tag{class='UNIVERSAL',
number=8,
type='IMPLICIT',
form=32}],
def=#'SEQUENCE'{components=
EXTERNAL_components1990}}},
{'EMBEDDED PDV',
#type{tag=[#tag{class='UNIVERSAL',
number=11,
type='IMPLICIT',
form=32}],
def=#'SEQUENCE'{components=EmbeddedPdv_components}}},
{'CHARACTER STRING',
#type{tag=[#tag{class='UNIVERSAL',
number=29,
type='IMPLICIT',
form=32}],
def=#'SEQUENCE'{components=CharacterString_components}}}
].
include_default_class(Module) ->
NameAbsList = default_class_list(),
include_default_class1(Module,NameAbsList).
include_default_class1(_,[]) ->
ok;
include_default_class1(Module,[{Name,TS}|_Rest]) ->
case asn1_db:dbget(Module,Name) of
undefined ->
C = #classdef{checked=true,name=Name,
typespec=TS},
asn1_db:dbput(Module,Name,C);
_ -> ok
end.
default_class_list() ->
[{'TYPE-IDENTIFIER',
{objectclass,
[{fixedtypevaluefield,
id,
{type,[],'OBJECT IDENTIFIER',[]},
'UNIQUE',
'MANDATORY'},
{typefield,'Type','MANDATORY'}],
{'WITH SYNTAX',
[{typefieldreference,'Type'},
'IDENTIFIED',
'BY',
{valuefieldreference,id}]}}},
{'ABSTRACT-SYNTAX',
{objectclass,
[{fixedtypevaluefield,
id,
{type,[],'OBJECT IDENTIFIER',[]},
'UNIQUE',
'MANDATORY'},
{typefield,'Type','MANDATORY'},
{fixedtypevaluefield,
property,
{type,
[],
{'BIT STRING',[]},
[]},
undefined,
{'DEFAULT',
[0,1,0]}}],
{'WITH SYNTAX',
[{typefieldreference,'Type'},
'IDENTIFIED',
'BY',
{valuefieldreference,id},
['HAS',
'PROPERTY',
{valuefieldreference,property}]]}}}].