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Diffstat (limited to 'lib/diameter/src/compiler/diameter_dict_util.erl')
-rw-r--r-- | lib/diameter/src/compiler/diameter_dict_util.erl | 1302 |
1 files changed, 1302 insertions, 0 deletions
diff --git a/lib/diameter/src/compiler/diameter_dict_util.erl b/lib/diameter/src/compiler/diameter_dict_util.erl new file mode 100644 index 0000000000..2207925e49 --- /dev/null +++ b/lib/diameter/src/compiler/diameter_dict_util.erl @@ -0,0 +1,1302 @@ +%% +%% %CopyrightBegin% +%% +%% Copyright Ericsson AB 2010-2011. All Rights Reserved. +%% +%% 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 online 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. +%% +%% %CopyrightEnd% +%% + +%% +%% This module turns a dictionary file into the orddict that +%% diameter_codegen.erl in turn morphs into .erl and .hrl files for +%% encode and decode of Diameter messages and AVPs. +%% + +-module(diameter_dict_util). + +-export([parse/2, + format_error/1, + format/1]). + +-include("diameter_vsn.hrl"). + +-define(RETURN(T), throw({T, ?MODULE, ?LINE})). +-define(RETURN(T, Args), ?RETURN({T, Args})). + +-define(A, list_to_atom). +-define(L, atom_to_list). +-define(I, integer_to_list). +-define(F, io_lib:format). + +%% =========================================================================== +%% parse/2 +%% =========================================================================== + +-spec parse(File, Opts) + -> {ok, orddict:orddict()} + | {error, term()} + when File :: {path, string()} + | iolist() + | binary(), + Opts :: list(). + +parse(File, Opts) -> + putr(verbose, lists:member(verbose, Opts)), + try + {ok, do_parse(File, Opts)} + catch + {Reason, ?MODULE, _Line} -> + {error, Reason} + after + eraser(verbose) + end. + +%% =========================================================================== +%% format_error/1 +%% =========================================================================== + +format_error({read, Reason}) -> + file:format_error(Reason); +format_error({scan, Reason}) -> + diameter_dict_scanner:format_error(Reason); +format_error({parse, {Line, _Mod, Reason}}) -> + lists:flatten(["Line ", ?I(Line), ", ", Reason]); + +format_error(T) -> + {Fmt, As} = fmt(T), + lists:flatten(io_lib:format(Fmt, As)). + +fmt({avp_code_already_defined = E, [Code, false, Name, Line, L]}) -> + {fmt(E), [Code, "", Name, Line, L]}; +fmt({avp_code_already_defined = E, [Code, Vid, Name, Line, L]}) -> + {fmt(E), [Code, ?F("/~p", [Vid]), Name, Line, L]}; + +fmt({uint32_out_of_range = E, [id | T]}) -> + {fmt(E), ["@id", "application identifier" | T]}; +fmt({uint32_out_of_range = E, [K | T]}) + when K == vendor; + K == avp_vendor_id -> + {fmt(E), [?F("@~p", [K]), "vendor id" | T]}; +fmt({uint32_out_of_range = E, [K, Name | T]}) + when K == enum; + K == define -> + {fmt(E), [?F("@~p ~s", [K, Name]), "value" | T]}; +fmt({uint32_out_of_range = E, [avp_types, Name | T]}) -> + {fmt(E), ["AVP " ++ Name, "AVP code" | T]}; +fmt({uint32_out_of_range = E, [grouped, Name | T]}) -> + {fmt(E), ["Grouped AVP " ++ Name | T]}; +fmt({uint32_out_of_range = E, [messages, Name | T]}) -> + {fmt(E), ["Message " ++ Name, "command code" | T]}; + +fmt({Reason, As}) -> + {fmt(Reason), As}; + +fmt(avp_code_already_defined) -> + "AVP ~p~s (~s) at line ~p already defined at line ~p"; + +fmt(uint32_out_of_range) -> + "~s specifies ~s ~p at line ~p that is out of range for a value of " + "Diameter type Unsigned32"; + +fmt(imported_avp_already_defined) -> + "AVP ~s imported by @inherits ~p at line ~p defined at line ~p"; +fmt(duplicate_import) -> + "AVP ~s is imported by more than one @inherits, both at line ~p " + "and at line ~p"; + +fmt(duplicate_section) -> + "Section @~s at line ~p already declared at line ~p"; + +fmt(already_declared) -> + "Section @~p ~s at line ~p already declared at line ~p"; + +fmt(inherited_avp_already_defined) -> + "AVP ~s inherited at line ~p defined in @avp_types at line ~p"; +fmt(avp_already_defined) -> + "AVP ~s at line ~p already in @~p at line ~p"; +fmt(key_already_defined) -> + "Value for ~s:~s in @~p at line ~p already provided at line ~p"; + +fmt(messages_without_id) -> + "@messages at line ~p but @id not declared"; + +fmt(avp_name_already_defined) -> + "AVP ~s at line ~p already defined at line ~p"; +fmt(avp_has_unknown_type) -> + "AVP ~s at line ~p defined with unknown type ~s"; +fmt(avp_has_invalid_flag) -> + "AVP ~s at line ~p specifies invalid flag ~c"; +fmt(avp_has_duplicate_flag) -> + "AVP ~s at line ~p specifies duplicate flag ~c"; +fmt(avp_has_vendor_id) -> + "AVP ~s at line ~p does not specify V flag " + "but is assigned vendor id ~p at line ~p"; +fmt(avp_has_no_vendor) -> + "AVP ~s at line ~p specifies V flag " + "but neither @vendor_avp_id nor @vendor supplies a value"; + +fmt(group_already_defined) -> + "Group ~s at line ~p already defined at line ~p"; +fmt(grouped_avp_code_mismatch) -> + "AVP ~s at line ~p has with code ~p " + "but @avp_types specifies ~p at line ~p"; +fmt(grouped_avp_has_wrong_type) -> + "Grouped AVP ~s at line ~p defined with type ~s at line ~p"; +fmt(grouped_avp_not_defined) -> + "Grouped AVP ~s on line ~p not defined in @avp_types"; +fmt(grouped_vendor_id_without_flag) -> + "Grouped AVP ~s at line ~p has vendor id " + "but definition at line ~p does not specify V flag"; +fmt(grouped_vendor_id_mismatch) -> + "Grouped AVP ~s at line ~p has vendor id ~p " + "but ~p specified at line ~p"; + +fmt(message_name_already_defined) -> + "Message ~s at line ~p already defined at line ~p"; +fmt(message_code_already_defined) -> + "~s message with code ~p at line ~p already defined at line ~p"; +fmt(message_has_duplicate_flag) -> + "Message ~s has duplicate flag ~s at line ~p"; +fmt(message_application_id_mismatch) -> + "Message ~s has application id ~p at line ~p " + "but @id specifies ~p at line ~p"; + +fmt(invalid_avp_order) -> + "AVP reference ~c~s~c at line ~p breaks fixed/required/optional order"; +fmt(invalid_qualifier) -> + "Qualifier ~p*~p at line ~p has Min > Max"; +fmt(avp_already_referenced) -> + "AVP ~s at line ~p already referenced at line ~p"; + +fmt(message_missing) -> + "~s message at line ~p but no ~s message is defined"; + +fmt(requested_avp_not_found) -> + "@inherit ~s at line ~p requests AVP ~s at line ~p " + "but module does not define that AVP"; + +fmt(enumerated_avp_has_wrong_local_type) -> + "Enumerated AVP ~s in @enum at line ~p defined with type ~s at line ~p"; +fmt(enumerated_avp_has_wrong_inherited_type) -> + "Enumerated AVP ~s in @enum at line ~p " + "inherited with type ~s from module ~s at line ~p"; +fmt(enumerated_avp_not_defined) -> + "Enumerated AVP ~s in @enum at line ~p neither defined nor inherited"; + +fmt(avp_not_defined) -> + "AVP ~s referenced at line ~p neither defined nor inherited"; + +fmt(recompile) -> + "Module ~p appears to have been compiler with an incompatible " + "version of the dictionary compiler and must be recompiled"; +fmt(not_loaded) -> + "Module ~p is not on the code path or could not be loaded"; +fmt(no_dict) -> + "Module ~p does not appear to be a diameter dictionary". + +%% =========================================================================== +%% format/1 +%% +%% Turn dict/0 output back into a dictionary file (with line ending = $\n). + +-spec format(Dict) + -> iolist() + when Dict :: orddict:orddict(). + +-define(KEYS, [id, name, prefix, vendor, + inherits, codecs, custom_types, + avp_types, + messages, + grouped, + enum, define]). + +format(Dict) -> + Io = orddict:fold(fun io/3, [], Dict), + [S || {_,S} <- lists:sort(fun keysort/2, Io)]. + +keysort({A,_}, {B,_}) -> + [HA, HB] = [H || K <- [A,B], + H <- [lists:takewhile(fun(X) -> X /= K end, ?KEYS)]], + HA < HB. + +%% =========================================================================== + +-define(INDENT, " "). +-define(SP, " "). +-define(NL, $\n). + +%% io/3 + +io(K, _, Acc) + when K == command_codes; + K == import_avps; + K == import_groups; + K == import_enums -> + Acc; + +io(Key, Body, Acc) -> + [{Key, io(Key, Body)} | Acc]. + +%% io/2 + +io(K, Id) + when K == id; + K == name; + K == prefix -> + [?NL, section(K), ?SP, tok(Id)]; + +io(vendor = K, {Id, Name}) -> + [?NL, section(K) | [[?SP, tok(X)] || X <- [Id, Name]]]; + +io(avp_types = K, Body) -> + [?NL, ?NL, section(K), ?NL, [body(K,A) || A <- Body]]; + +io(K, Body) + when K == messages; + K == grouped -> + [?NL, ?NL, section(K), [body(K,A) || A <- Body]]; + +io(K, Body) + when K == avp_vendor_id; + K == inherits; + K == custom_types; + K == codecs; + K == enum; + K == define -> + [[?NL, pairs(K, T)] || T <- Body]. + +pairs(K, {Id, Avps}) -> + [?NL, section(K), ?SP, tok(Id), ?NL, [[?NL, body(K, A)] || A <- Avps]]. + +body(K, AvpName) + when K == avp_vendor_id; + K == inherits; + K == custom_types; + K == codecs -> + [?INDENT, word(AvpName)]; + +body(K, {Name, N}) + when K == enum; + K == define -> + [?INDENT, word(Name), ?SP, ?I(N)]; + +body(avp_types = K, {Name, Code, Type, ""}) -> + body(K, {Name, Code, Type, "-"}); +body(avp_types, {Name, Code, Type, Flags}) -> + [?NL, ?INDENT, word(Name), + [[?SP, ?SP, S] || S <- [?I(Code), Type, Flags]]]; + +body(messages, {"answer-message", _, _, [], Avps}) -> + [?NL, ?NL, ?INDENT, + "answer-message ::= < Diameter Header: code, ERR [PXY] >", + f_avps(Avps)]; +body(messages, {Name, Code, Flags, ApplId, Avps}) -> + [?NL, ?NL, ?INDENT, word(Name), " ::= ", header(Code, Flags, ApplId), + f_avps(Avps)]; + +body(grouped, {Name, Code, Vid, Avps}) -> + [?NL, ?NL, ?INDENT, word(Name), " ::= ", avp_header(Code, Vid), + f_avps(Avps)]. + +header(Code, Flags, ApplId) -> + ["< Diameter Header: ", + ?I(Code), + [[", ", ?L(F)] || F <- Flags], + [[" ", ?I(N)] || N <- ApplId], + " >"]. + +avp_header(Code, Vid) -> + ["< AVP Header: ", + ?I(Code), + [[" ", ?I(V)] || V <- Vid], + " >"]. + +f_avps(L) -> + [[?NL, ?INDENT, ?INDENT, f_avp(A)] || A <- L]. + +f_avp({Q, A}) -> + f_avp(f_qual(Q), f_delim(A)); +f_avp(A) -> + f_avp("", f_delim(A)). + +f_delim({{A}}) -> + [$<, word(A), $>]; +f_delim({A}) -> + [${, word(A), $}]; +f_delim([A]) -> + [$[, word(A), $]]. + +f_avp(Q, Avp) -> + Len = length(lists:flatten([Q])), + [io_lib:format("~*s", [-1*max(Len+1, 6) , Q]), Avp]. + +f_qual('*') -> + "*"; +f_qual({'*', N}) -> + [$*, ?I(N)]; +f_qual({N, '*'}) -> + [?I(N), $*]; +f_qual({M,N}) -> + [?I(M), $*, ?I(N)]. + +section(Key) -> + ["@", ?L(Key)]. + +tok(N) + when is_integer(N) -> + ?I(N); +tok(N) -> + word(N). + +word(Str) -> + word(diameter_dict_scanner:is_name(Str), Str). + +word(true, Str) -> + Str; +word(false, Str) -> + [$', Str, $']. + +%% =========================================================================== + +do_parse(File, Opts) -> + Bin = do([fun read/1, File], read), + Toks = do([fun diameter_dict_scanner:scan/1, Bin], scan), + Tree = do([fun diameter_dict_parser:parse/1, Toks], parse), + make_dict(Tree, Opts). + +do([F|A], E) -> + case apply(F,A) of + {ok, T} -> + T; + {error, Reason} -> + ?RETURN({E, Reason}) + end. + +read({path, Path}) -> + file:read_file(Path); +read(File) -> + {ok, iolist_to_binary([File])}. + +make_dict(Parse, Opts) -> + make_orddict(pass4(pass3(pass2(pass1(reset(make_dict(Parse), + Opts))), + Opts))). + +%% make_orddict/1 + +make_orddict(Dict) -> + dict:fold(fun mo/3, + orddict:from_list([{K,[]} || K <- [avp_types, + messages, + grouped, + inherits, + custom_types, + codecs, + avp_vendor_id, + enum, + define]]), + Dict). + +mo(K, Sects, Dict) + when is_atom(K) -> + orddict:store(K, make(K, Sects), Dict); + +mo(_, _, Dict) -> + Dict. + +make(K, [[_Line, {_, _, X}]]) + when K == id; + K == name; + K == prefix -> + X; + +make(vendor, [[_Line, {_, _, Id}, {_, _, Name}]]) -> + {Id, Name}; + +make(K, T) + when K == command_codes; + K == import_avps; + K == import_groups; + K == import_enums -> + T; + +make(K, Sects) -> + post(K, foldl(fun([_L|B], A) -> make(K,B,A) end, + [], + Sects)). + +post(avp_types, L) -> + lists:sort(L); + +post(K, L) + when K == grouped; + K == messages; + K == enum; + K == define -> + lists:reverse(L); + +post(_, L) -> + L. + +make(K, [{_,_,Name} | Body], Acc) + when K == enum; + K == define; + K == avp_vendor_id; + K == custom_types; + K == inherits; + K == codecs -> + [{Name, mk(K, Body)} | Acc]; + +make(K, Body, Acc) -> + foldl(fun(T,A) -> [mk(K, T) | A] end, Acc, Body). + +mk(avp_types, [{_,_,Name}, {_,_,Code}, {_,_,Type}, {_,_,Flags}]) -> + {Name, Code, type(Type), Flags}; + +mk(messages, [{'answer-message' = A, _}, false | Avps]) -> + {?L(A), -1, ['ERR', 'PXY'], [], make_body(Avps)}; + +mk(messages, [{_,_,Name}, [{_,_,Code}, Flags, ApplId] | Avps]) -> + {Name, + Code, + lists:map(fun({F,_}) -> F end, Flags), + opt(ApplId), + make_body(Avps)}; + +mk(grouped, [{_,_,Name}, [{_,_,Code}, Vid] | Avps]) -> + {Name, Code, opt(Vid), make_body(Avps)}; + +mk(K, Body) + when K == enum; + K == define -> + lists:map(fun([{_,_,Name}, {_,_,Value}]) -> {Name, Value} end, Body); + +mk(K, Avps) + when K == avp_vendor_id; + K == custom_types; + K == inherits; + K == codecs -> + lists:map(fun({_,_,N}) -> N end, Avps). + +opt(false) -> + []; +opt({_,_,X}) -> + [X]. + +make_body(Avps) -> + lists:map(fun avp/1, Avps). + +avp([false, D, Avp]) -> + avp(D, Avp); +avp([Q, D, Avp]) -> + {qual(Q), avp(D, Avp)}. + +avp(D, {'AVP', _}) -> + delim(D, "AVP"); +avp(D, {_, _, Name}) -> + delim(D, Name). + +delim($<, N) -> + {{N}}; +delim(${, N) -> + {N}; +delim($[, N) -> + [N]. + +qual({true, {_,_,N}}) -> + {'*', N}; +qual({{_,_,N}, true}) -> + {N, '*'}; +qual({{_,_,N},{_,_,M}}) -> + {N, M}; +qual(true) -> + '*'. + +%% Optional reports when running verbosely. +report(What, [F | A]) + when is_function(F) -> + report(What, apply(F, A)); +report(What, Data) -> + report(getr(verbose), What, Data). + +report(true, Tag, Data) -> + io:format("##~n## ~p ~p~n", [Tag, Data]); +report(false, _, _) -> + ok. + +%% ------------------------------------------------------------------------ +%% make_dict/1 +%% +%% Turn a parsed dictionary into an dict. + +make_dict(Parse) -> + foldl(fun(T,A) -> + report(section, T), + section(T,A) + end, + dict:new(), + Parse). + +section([{T, L} | Rest], Dict) + when T == name; + T == prefix; + T == id; + T == vendor -> + case find(T, Dict) of + [] -> + dict:store(T, [[L | Rest]], Dict); + [[Line | _]] -> + ?RETURN(duplicate_section, [T, L, Line]) + end; + +section([{T, L} | Rest], Dict) + when T == avp_types; + T == messages; + T == grouped; + T == inherits; + T == custom_types; + T == codecs; + T == avp_vendor_id; + T == enum; + T == define -> + dict:append(T, [L | Rest], Dict). + +%% =========================================================================== +%% reset/2 +%% +%% Reset sections from options. + +reset(Dict, Opts) -> + foldl([fun reset/3, Opts], Dict, [name, prefix, inherits]). + +reset(K, Dict, Opts) -> + foldl(fun opt/2, Dict, [T || {A,_} = T <- Opts, A == K]). + +opt({inherits = Key, "-"}, Dict) -> + dict:erase(Key, Dict); +opt({inherits = Key, Mod}, Dict) -> + dict:append(Key, [0, {word, 0, Mod}], Dict); +opt({Key, Val}, Dict) -> + dict:store(Key, [0, {word, 0, Val}], Dict); +opt(_, Dict) -> + Dict. + +%% =========================================================================== +%% pass1/1 +%% +%% Explode sections into additional dictionary entries plus semantic +%% checks. + +pass1(Dict) -> + true = no_messages_without_id(Dict), + + foldl(fun(K,D) -> foldl([fun p1/3, K], D, find(K,D)) end, + Dict, + [id, + vendor, + avp_types, %% must precede inherits, grouped, enum + avp_vendor_id, + custom_types, + codecs, + inherits, + grouped, + messages, + enum, + define]). + +%% Multiple sections are allowed as long as their bodies don't +%% overlap. (Except enum/define.) + +p1([_Line, N], Dict, id = K) -> + true = is_uint32(N, [K]), + Dict; + +p1([_Line, Id, _Name], Dict, vendor = K) -> + true = is_uint32(Id, [K]), + Dict; + +p1([_Line, X | Body], Dict, K) + when K == avp_vendor_id; + K == custom_types; + K == codecs; + K == inherits -> + foldl([fun explode/4, X, K], Dict, Body); + +p1([_Line, X | Body], Dict, K) + when K == define; + K == enum -> + {_, L, Name} = X, + foldl([fun explode2/4, X, K], + store_new({K, Name}, + [L, Body], + Dict, + [K, Name, L], + already_declared), + Body); + +p1([_Line | Body], Dict, K) + when K == avp_types; + K == grouped; + K == messages -> + foldl([fun explode/3, K], Dict, Body). + +no_messages_without_id(Dict) -> + case find(messages, Dict) of + [] -> + true; + [[Line | _] | _] -> + [] /= find(id, Dict) orelse ?RETURN(messages_without_id, [Line]) + end. + +%% Note that the AVP's in avp_vendor_id, custom_types, codecs and +%% enum can all be inherited, as can the AVP content of messages and +%% grouped AVP's. Check that the referenced AVP's exist after +%% importing definitions. + +%% explode/4 +%% +%% {avp_vendor_id, AvpName} -> [Lineno, Id::integer()] +%% {custom_types|codecs|inherits, AvpName} -> [Lineno, Mod::string()] + +explode({_, Line, AvpName}, Dict, {_, _, X} = T, K) -> + true = K /= avp_vendor_id orelse is_uint32(T, [K]), + true = K /= inherits orelse avp_not_local(AvpName, Line, Dict), + + store_new({key(K), AvpName}, + [Line, X], + Dict, + [AvpName, Line, K], + avp_already_defined). + +%% explode2/4 + +%% {define, {Name, Key}} -> [Lineno, Value::integer(), enum|define] + +explode2([{_, Line, Key}, {_, _, Value} = T], Dict, {_, _, Name}, K) -> + true = is_uint32(T, [K, Name]), + + store_new({key(K), {Name, Key}}, + [Line, Value, K], + Dict, + [Name, Key, K, Line], + key_already_defined). + +%% key/1 +%% +%% Conflate keys that are equivalent as far as uniqueness of +%% definition goes. + +key(K) + when K == enum; + K == define -> + define; +key(K) + when K == custom_types; + K == codecs -> + custom; +key(K) -> + K. + +%% explode/3 + +%% {avp_types, AvpName} -> [Line | Toks] +%% {avp_types, {Code, IsReq}} -> [Line, AvpName] +%% +%% where AvpName = string() +%% Code = integer() +%% IsReq = boolean() + +explode([{_, Line, Name} | Toks], Dict0, avp_types = K) -> + %% Each AVP can be defined only once. + Dict = store_new({K, Name}, + [Line | Toks], + Dict0, + [Name, Line], + avp_name_already_defined), + + [{number, _, _Code} = C, {word, _, Type}, {word, _, _Flags}] = Toks, + + true = avp_type_known(Type, Name, Line), + true = is_uint32(C, [K, Name]), + + Dict; + +%% {grouped, Name} -> [Line, HeaderTok | AvpToks] +%% {grouped, {Name, AvpName}} -> [Line, Qual, Delim] +%% +%% where Name = string() +%% AvpName = string() +%% Qual = {Q, Q} | boolean() +%% Q = true | NumberTok +%% Delim = $< | ${ | $[ + +explode([{_, Line, Name}, Header | Avps], Dict0, grouped = K) -> + Dict = store_new({K, Name}, + [Line, Header | Avps], + Dict0, + [Name, Line], + group_already_defined), + + [{_,_, Code} = C, Vid] = Header, + {DefLine, {_, _, Flags}} = grouped_flags(Name, Code, Dict0, Line), + V = lists:member($V, Flags), + + true = is_uint32(C, [K, Name, "AVP code"]), + true = is_uint32(Vid, [K, Name, "vendor id"]), + false = vendor_id_mismatch(Vid, V, Name, Dict0, Line, DefLine), + + explode_avps(Avps, Dict, K, Name); + +%% {messages, Name} -> [Line, HeaderTok | AvpToks] +%% {messages, {Code, IsReq}} -> [Line, NameTok] +%% {messages, Code} -> [[Line, NameTok, IsReq]] +%% {messages, {Name, Flag}} -> [Line] +%% {messages, {Name, AvpName}} -> [Line, Qual, Delim] +%% +%% where Name = string() +%% Code = integer() +%% IsReq = boolean() +%% Flag = 'REQ' | 'PXY' +%% AvpName = string() +%% Qual = true | {Q,Q} +%% Q = true | NumberTok +%% Delim = $< | ${ | ${ + +explode([{'answer-message' = A, Line}, false = H | Avps], + Dict0, + messages = K) -> + Name = ?L(A), + Dict1 = store_new({K, Name}, + [Line, H, Avps], + Dict0, + [Name, Line], + message_name_already_defined), + + explode_avps(Avps, Dict1, K, Name); + +explode([{_, Line, MsgName} = M, Header | Avps], + Dict0, + messages = K) -> + %% There can be at most one message with a given name. + Dict1 = store_new({K, MsgName}, + [Line, Header | Avps], + Dict0, + [MsgName, Line], + message_name_already_defined), + + [{_, _, Code} = C, Bits, ApplId] = Header, + + %% Don't check any application id since it's required to be + %% the same as @id. + true = is_uint32(C, [K, MsgName]), + + %% An application id specified as part of the message definition + %% has to agree with @id. The former is parsed just because RFC + %% 3588 specifies it. + false = application_id_mismatch(ApplId, Dict1, MsgName), + + IsReq = lists:keymember('REQ', 1, Bits), + + %% For each command code, there can be at most one request and + %% one answer. + Dict2 = store_new({K, {Code, IsReq}}, + [Line, M], + Dict1, + [choose(IsReq, "Request", "Answer"), Code, Line], + message_code_already_defined), + + %% For each message, each flag can occur at most once. + Dict3 = foldl(fun({F,L},D) -> + store_new({K, {MsgName, F}}, + [L], + D, + [MsgName, ?L(F)], + message_has_duplicate_flag) + end, + Dict2, + Bits), + + dict:append({K, Code}, + [Line, M, IsReq], + explode_avps(Avps, Dict3, K, MsgName)). + +%% explode_avps/4 +%% +%% Ensure required AVP order and sane qualifiers. Can't check for AVP +%% names until after they've been imported. +%% +%% RFC 3588 allows a trailing fixed while 3588bis doesn't. Parse the +%% former. + +explode_avps(Avps, Dict, Key, Name) -> + xa("<{[<", Avps, Dict, Key, Name). + +xa(_, [], Dict, _, _) -> + Dict; + +xa(Ds, [[Qual, D, {'AVP', Line}] | Avps], Dict, Key, Name) -> + xa(Ds, [[Qual, D, {word, Line, "AVP"}] | Avps], Dict, Key, Name); + +xa([], [[_Qual, D, {_, Line, Name}] | _], _, _, _) -> + ?RETURN(invalid_avp_order, [D, Name, close(D), Line]); + +xa([D|_], [[{{_, Line, Min}, {_, _, Max}}, D, _] | _], _, _, _) + when Min > Max -> + ?RETURN(invalid_qualifier, [Min, Max, Line]); + +xa([D|_] = Ds, [[Qual, D, {_, Line, AvpName}] | Avps], Dict, Key, Name) -> + xa(Ds, + Avps, + store_new({Key, {Name, AvpName}}, + [Line, Qual, D], + Dict, + [Name, Line], + avp_already_referenced), + Key, + Name); + +xa([_|Ds], Avps, Dict, Key, Name) -> + xa(Ds, Avps, Dict, Key, Name). + +close($<) -> $>; +close(${) -> $}; +close($[) -> $]. + +%% is_uint32/2 + +is_uint32(false, _) -> + true; +is_uint32({Line, _, N}, Args) -> + N < 1 bsl 32 orelse ?RETURN(uint32_out_of_range, Args ++ [N, Line]). +%% Can't call diameter_types here since it may not exist yet. + +%% application_id_mismatch/3 + +application_id_mismatch({number, Line, Id}, Dict, MsgName) -> + [[_, {_, L, I}]] = dict:fetch(id, Dict), + + I /= Id andalso ?RETURN(message_application_id_mismatch, + [MsgName, Id, Line, I, L]); + +application_id_mismatch(false = No, _, _) -> + No. + +%% avp_not_local/3 + +avp_not_local(Name, Line, Dict) -> + A = find({avp_types, Name}, Dict), + + [] == A orelse ?RETURN(inherited_avp_already_defined, + [Name, Line, hd(A)]). + +%% avp_type_known/3 + +avp_type_known(Type, Name, Line) -> + false /= type(Type) + orelse ?RETURN(avp_has_unknown_type, [Name, Line, Type]). + +%% vendor_id_mismatch/6 +%% +%% Require a vendor id specified on a group to match any specified +%% in @avp_vendor_id. Note that both locations for the value are +%% equivalent, both in the value being attributed to a locally +%% defined AVP and ignored when imported from another dictionary. + +vendor_id_mismatch({_,_,_}, false, Name, _, Line, DefLine) -> + ?RETURN(grouped_vendor_id_without_flag, [Name, Line, DefLine]); + +vendor_id_mismatch({_, _, I}, true, Name, Dict, Line, _) -> + case vendor_id(Name, Dict) of + {avp_vendor_id, L, N} -> + I /= N andalso + ?RETURN(grouped_vendor_id_mismatch, [Name, Line, I, N, L]); + _ -> + false + end; + +vendor_id_mismatch(_, _, _, _, _, _) -> + false. + +%% grouped_flags/4 + +grouped_flags(Name, Code, Dict, Line) -> + case find({avp_types, Name}, Dict) of + [L, {_, _, Code}, {_, _, "Grouped"}, Flags] -> + {L, Flags}; + [_, {_, L, C}, {_, _, "Grouped"}, _Flags] -> + ?RETURN(grouped_avp_code_mismatch, [Name, Line, Code, C, L]); + [_, _Code, {_, L, T}, _] -> + ?RETURN(grouped_avp_has_wrong_type, [Name, Line, T, L]); + [] -> + ?RETURN(grouped_avp_not_defined, [Name, Line]) + end. + +%% vendor_id/2 + +%% Look for a vendor id in @avp_vendor_id, then @vendor. +vendor_id(Name, Dict) -> + case find({avp_vendor_id, Name}, Dict) of + [Line, Id] when is_integer(Id) -> + {avp_vendor_id, Line, Id}; + [] -> + vendor(Dict) + end. + +vendor(Dict) -> + case find(vendor, Dict) of + [[_Line, {_, _, Id}, {_, _, _}]] -> + {vendor, Id}; + [] -> + false + end. + +%% find/2 + +find(Key, Dict) -> + case dict:find(Key, Dict) of + {ok, L} when is_list(L) -> + L; + error -> + [] + end. + +%% store_new/5 + +store_new(Key, Value, Dict, Args, Err) -> + case dict:find(Key, Dict) of + {ok, [L | _]} -> + ?RETURN(Err, Args ++ [L]); + error -> + dict:store(Key, Value, Dict) + end. + +%% type/1 + +type("DiamIdent") -> + "DiameterIdentity"; +type("DiamURI") -> + "DiameterURI"; +type(T) + when T == "OctetString"; + T == "Integer32"; + T == "Integer64"; + T == "Unsigned32"; + T == "Unsigned64"; + T == "Float32"; + T == "Float64"; + T == "Grouped"; + T == "Enumerated"; + T == "Address"; + T == "Time"; + T == "UTF8String"; + T == "DiameterIdentity"; + T == "DiameterURI"; + T == "IPFilterRule"; + T == "QoSFilterRule" -> + T; +type(_) -> + false. + +%% =========================================================================== +%% pass2/1 +%% +%% More explosion, but that requires the previous pass to write its +%% entries. + +pass2(Dict) -> + foldl(fun(K,D) -> foldl([fun p2/3, K], D, find(K,D)) end, + Dict, + [avp_types]). + +p2([_Line | Body], Dict, avp_types) -> + foldl(fun explode_avps/2, Dict, Body); + +p2([], Dict, _) -> + Dict. + +explode_avps([{_, Line, Name} | Toks], Dict) -> + [{number, _, Code}, {word, _, _Type}, {word, _, Flags}] = Toks, + + true = avp_flags_valid(Flags, Name, Line), + + Vid = avp_vendor_id(Flags, Name, Line, Dict), + + %% An AVP is uniquely defined by its AVP code and vendor id (if any). + %% Ensure there are no duplicate. + store_new({avp_types, {Code, Vid}}, + [Line, Name], + Dict, + [Code, Vid, Name, Line], + avp_code_already_defined). + +%% avp_flags_valid/3 + +avp_flags_valid(Flags, Name, Line) -> + Bad = lists:filter(fun(C) -> not lists:member(C, "MVP") end, Flags), + [] == Bad + orelse ?RETURN(avp_has_invalid_flag, [Name, Line, hd(Bad)]), + + Dup = Flags -- "MVP", + [] == Dup + orelse ?RETURN(avp_has_duplicate_flag, [Name, Line, hd(Dup)]). + +%% avp_vendor_id/4 + +avp_vendor_id(Flags, Name, Line, Dict) -> + V = lists:member($V, Flags), + + case vendor_id(Name, Dict) of + {avp_vendor_id, _, I} when V -> + I; + {avp_vendor_id, L, I} -> + ?RETURN(avp_has_vendor_id, [Name, Line, I, L]); + {vendor, I} when V -> + I; + false when V -> + ?RETURN(avp_has_no_vendor, [Name, Line]); + _ -> + false + end. + +%% =========================================================================== +%% pass3/2 +%% +%% Import AVPs. + +pass3(Dict, Opts) -> + import_enums(import_groups(import_avps(insert_codes(Dict), Opts))). + +%% insert_codes/1 +%% +%% command_codes -> [{Code, ReqNameTok, AnsNameTok}] + +insert_codes(Dict) -> + dict:store(command_codes, + dict:fold(fun make_code/3, [], Dict), + Dict). + +make_code({messages, Code}, Names, Acc) + when is_integer(Code) -> + [mk_code(Code, Names) | Acc]; +make_code(_, _, Acc) -> + Acc. + +mk_code(Code, [[_, _, false] = Ans, [_, _, true] = Req]) -> + mk_code(Code, [Req, Ans]); + +mk_code(Code, [[_, {_,_,Req}, true], [_, {_,_,Ans}, false]]) -> + {Code, Req, Ans}; + +mk_code(_Code, [[Line, _Name, IsReq]]) -> + ?RETURN(message_missing, [choose(IsReq, "Request", "Answer"), + Line, + choose(IsReq, "answer", "request")]). + +%% import_avps/2 + +import_avps(Dict, Opts) -> + Import = inherit(Dict, Opts), + report(imported, Import), + + %% pass4/1 tests that all referenced AVP's are either defined + %% or imported. + + dict:store(import_avps, + lists:map(fun({M, _, As}) -> {M, [A || {_,A} <- As]} end, + lists:reverse(Import)), + foldl(fun explode_imports/2, Dict, Import)). + +explode_imports({Mod, Line, Avps}, Dict) -> + foldl([fun xi/4, Mod, Line], Dict, Avps). + +xi({L, {Name, _Code, _Type, _Flags} = A}, Dict, Mod, Line) -> + store_new({avp_types, Name}, + [0, Mod, Line, L, A], + store_new({import, Name}, + [Line], + Dict, + [Name, Line], + duplicate_import), + [Name, Mod, Line], + imported_avp_already_defined). + +%% import_groups/1 +%% import_enums/1 +%% +%% For each inherited module, store the content of imported AVP's of +%% type grouped/enumerated in a new key. + +import_groups(Dict) -> + dict:store(import_groups, import(grouped, Dict), Dict). + +import_enums(Dict) -> + dict:store(import_enums, import(enum, Dict), Dict). + +import(Key, Dict) -> + flatmap([fun import_key/2, Key], dict:fetch(import_avps, Dict)). + +import_key({Mod, Avps}, Key) -> + As = lists:flatmap(fun(T) -> + N = element(1,T), + choose(lists:keymember(N, 1, Avps), [T], []) + end, + orddict:fetch(Key, dict(Mod))), + if As == [] -> + []; + true -> + [{Mod, As}] + end. + +%% ------------------------------------------------------------------------ +%% inherit/2 +%% +%% Return a {Mod, Line, [{Lineno, Avp}]} list, where Mod is a module +%% name, Line points to the corresponding @inherit and each Avp is +%% from Mod:dict(). Lineno is 0 if the import is implicit. + +inherit(Dict, Opts) -> + code:add_pathsa([D || {include, D} <- Opts]), + foldl(fun inherit_avps/2, [], find(inherits, Dict)). +%% Note that the module order of the returned lists is reversed +%% relative to @inherits. + +inherit_avps([Line, {_,_,M} | Names], Acc) -> + Mod = ?A(M), + report(inherit_from, Mod), + case find_avps(Names, avps_from_module(Mod)) of + {_, [{_, L, N} | _]} -> + ?RETURN(requested_avp_not_found, [Mod, Line, N, L]); + {Found, []} -> + [{Mod, Line, lists:sort(Found)} | Acc] + end. + +%% Import everything not defined locally ... +find_avps([], Avps) -> + {[{0, A} || A <- Avps], []}; + +%% ... or specified AVPs. +find_avps(Names, Avps) -> + foldl(fun acc_avp/2, {[], Names}, Avps). + +acc_avp({Name, _Code, _Type, _Flags} = A, {Found, Not} = Acc) -> + case lists:keyfind(Name, 3, Not) of + {_, Line, Name} -> + {[{Line, A} | Found], lists:keydelete(Name, 3, Not)}; + false -> + Acc + end. + +%% avps_from_module/2 + +avps_from_module(Mod) -> + orddict:fetch(avp_types, dict(Mod)). + +dict(Mod) -> + try Mod:dict() of + [?VERSION | Dict] -> + Dict; + _ -> + ?RETURN(recompile, [Mod]) + catch + error: _ -> + ?RETURN(choose(false == code:is_loaded(Mod), + not_loaded, + no_dict), + [Mod]) + end. + +%% =========================================================================== +%% pass4/1 +%% +%% Sanity checks. + +pass4(Dict) -> + dict:fold(fun(K, V, _) -> p4(K, V, Dict) end, ok, Dict), + Dict. + +%% Ensure enum AVP's have type Enumerated. +p4({enum, Name}, [Line | _], Dict) + when is_list(Name) -> + true = is_enumerated_avp(Name, Dict, Line); + +%% Ensure all referenced AVP's are either defined locally or imported. +p4({K, {Name, AvpName}}, [Line | _], Dict) + when (K == grouped orelse K == messages), + is_list(Name), + is_list(AvpName), + AvpName /= "AVP" -> + true = avp_is_defined(AvpName, Dict, Line); + +%% Ditto. +p4({K, AvpName}, [Line | _], Dict) + when K == avp_vendor_id; + K == custom_types; + K == codecs -> + true = avp_is_defined(AvpName, Dict, Line); + +p4(_, _, _) -> + ok. + +%% has_enumerated_type/3 + +is_enumerated_avp(Name, Dict, Line) -> + case find({avp_types, Name}, Dict) of + [_Line, _Code, {_, _, "Enumerated"}, _Flags] -> %% local + true; + [_Line, _Code, {_, L, T}, _] -> + ?RETURN(enumerated_avp_has_wrong_local_type, + [Name, Line, T, L]); + [0, _, _, _, {_Name, _Code, "Enumerated", _Flags}] -> %% inherited + true; + [0, Mod, LM, LA, {_Name, _Code, Type, _Flags}] -> + ?RETURN(enumerated_avp_has_wrong_inherited_type, + [Name, Line, Type, Mod, choose(0 == LA, LM, LA)]); + [] -> + ?RETURN(enumerated_avp_not_defined, [Name, Line]) + end. + +avp_is_defined(Name, Dict, Line) -> + case find({avp_types, Name}, Dict) of + [_Line, _Code, _Type, _Flags] -> %% local + true; + [0, _, _, _, {Name, _Code, _Type, _Flags}] -> %% inherited + true; + [] -> + ?RETURN(avp_not_defined, [Name, Line]) + end. + +%% =========================================================================== + +putr(Key, Value) -> + put({?MODULE, Key}, Value). + +getr(Key) -> + get({?MODULE, Key}). + +eraser(Key) -> + erase({?MODULE, Key}). + +choose(true, X, _) -> X; +choose(false, _, X) -> X. + +foldl(F, Acc, List) -> + lists:foldl(fun(T,A) -> eval([F,T,A]) end, Acc, List). + +flatmap(F, List) -> + lists:flatmap(fun(T) -> eval([F,T]) end, List). + +eval([[F|X] | A]) -> + eval([F | A ++ X]); +eval([F|A]) -> + apply(F,A). |