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author | Anders Svensson <[email protected]> | 2013-02-12 12:52:05 +0100 |
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committer | Anders Svensson <[email protected]> | 2013-02-12 12:52:05 +0100 |
commit | 117005a3ad1ddfd82891c13e65953dc8db9ae0d9 (patch) | |
tree | d94a93ddcb84e76ad6d01bfbe89b8901ea7043f5 /lib/diameter/src/base/diameter_traffic.erl | |
parent | 1e7b3534eeea4761bb45ff31bcdaf57cd66a7cb7 (diff) | |
parent | 05a6cc1c996acb8e8dfe168cb029b2a7a4fdbc3d (diff) | |
download | otp-117005a3ad1ddfd82891c13e65953dc8db9ae0d9.tar.gz otp-117005a3ad1ddfd82891c13e65953dc8db9ae0d9.tar.bz2 otp-117005a3ad1ddfd82891c13e65953dc8db9ae0d9.zip |
Merge branch 'anders/diameter/rfc6733_dictionaries/OTP-10760'
* anders/diameter/rfc6733_dictionaries/OTP-10760:
Remove trailing whitespace
Tweak service interface towards diameter_peer
Split message handling in diameter_service into diameter_traffic
Simplify request record
Move failover out of service process
Update traffic suite to test both RFC 3588 and 6733 dictionaries
Update capx suite to test both RFC 3588 and 6733 dictionaries
Add exprecs '#new-'/1 clause taking list argument
Add exprecs '#get-'/1 for transforming records into lists
Document the existence of the RFC 6733 dictionaries
Don't hardcode common dictionary
Add RFC 6733 dictionaries
Diffstat (limited to 'lib/diameter/src/base/diameter_traffic.erl')
-rw-r--r-- | lib/diameter/src/base/diameter_traffic.erl | 1633 |
1 files changed, 1633 insertions, 0 deletions
diff --git a/lib/diameter/src/base/diameter_traffic.erl b/lib/diameter/src/base/diameter_traffic.erl new file mode 100644 index 0000000000..2f486861a2 --- /dev/null +++ b/lib/diameter/src/base/diameter_traffic.erl @@ -0,0 +1,1633 @@ +%% +%% %CopyrightBegin% +%% +%% Copyright Ericsson AB 2013. 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% +%% + +%% +%% Implements the handling of incoming and outgoing Diameter messages +%% except CER/CEA, DWR/DWA and DPR/DPA. That is, the messages that a +%% diameter client sends of receives. +%% + +-module(diameter_traffic). + +%% towards diameter +-export([send_request/4]). + +%% towards diameter_watchdog +-export([receive_message/4]). + +%% towards diameter_service +-export([make_recvdata/1, + peer_up/1, + peer_down/1, + failover/1, + pending/1]). + +%% Other callbacks. +-export([send/1]). %% send from remote node + +-include_lib("diameter/include/diameter.hrl"). +-include("diameter_internal.hrl"). + +-define(RELAY, ?DIAMETER_DICT_RELAY). +-define(BASE, ?DIAMETER_DICT_COMMON). %% Note: the RFC 3588 dictionary + +-define(DEFAULT_TIMEOUT, 5000). %% for outgoing requests + +%% Table containing outgoing requests for which a reply has yet to be +%% received. +-define(REQUEST_TABLE, diameter_request). + +%% Workaround for dialyzer's lack of understanding of match specs. +-type match(T) + :: T | '_' | '$1' | '$2' | '$3' | '$4'. + +%% Record diameter:call/4 options are parsed into. +-record(options, + {filter = none :: diameter:peer_filter(), + extra = [] :: list(), + timeout = ?DEFAULT_TIMEOUT :: 0..16#FFFFFFFF, + detach = false :: boolean()}). + +%% Term passed back to receive_message/4 with every incoming message. +-record(recvdata, + {peerT :: ets:tid(), + service_name :: diameter:service_name(), + apps :: [#diameter_app{}], + sequence :: diameter:sequence()}). + +%% Record stored in diameter_request for each outgoing request. +-record(request, + {ref :: match(reference()), %% used to receive answer + caller :: match(pid()), %% calling process + handler :: match(pid()), %% request process + transport :: match(pid()), %% peer process + caps :: match(#diameter_caps{}), %% of connection + packet :: match(#diameter_packet{})}). %% of request + +%% --------------------------------------------------------------------------- +%% # make_recvdata/1 +%% --------------------------------------------------------------------------- + +make_recvdata([SvcName, PeerT, Apps, Mask | _]) -> + #recvdata{service_name = SvcName, + peerT = PeerT, + apps = Apps, + sequence = Mask}. +%% Take a list so that the caller (diameter_service) can be upgraded +%% first if new members are added. Note that receive_message/4 might +%% still get an old term from any watchdog started in old code. + +%% --------------------------------------------------------------------------- +%% peer_up/1 +%% --------------------------------------------------------------------------- + +%% Insert an element that is used to detect whether or not there has +%% been a failover when inserting an outgoing request. +peer_up(TPid) -> + ets:insert(?REQUEST_TABLE, {TPid}). + +%% --------------------------------------------------------------------------- +%% peer_down/1 +%% --------------------------------------------------------------------------- + +peer_down(TPid) -> + ets:delete(?REQUEST_TABLE, TPid), + failover(TPid). + +%% --------------------------------------------------------------------------- +%% pending/1 +%% --------------------------------------------------------------------------- + +pending(TPids) -> + MatchSpec = [{{'$1', + #request{caller = '$2', + handler = '$3', + transport = '$4', + _ = '_'}, + '_'}, + [?ORCOND([{'==', T, '$4'} || T <- TPids])], + [{{'$1', [{{caller, '$2'}}, + {{handler, '$3'}}, + {{transport, '$4'}}]}}]}], + + try + ets:select(?REQUEST_TABLE, MatchSpec) + catch + error: badarg -> [] %% service has gone down + end. + +%% --------------------------------------------------------------------------- +%% # receive_message/4 +%% +%% Handle an incoming Diameter message. +%% --------------------------------------------------------------------------- + +%% Handle an incoming Diameter message in the watchdog process. This +%% used to come through the service process but this avoids that +%% becoming a bottleneck. + +receive_message(TPid, Pkt, Dict0, RecvData) + when is_pid(TPid) -> + #diameter_packet{header = #diameter_header{is_request = R}} = Pkt, + recv(R, + (not R) andalso lookup_request(Pkt, TPid), + TPid, + Pkt, + Dict0, + RecvData). + +%% Incoming request ... +recv(true, false, TPid, Pkt, Dict0, RecvData) -> + try + spawn(fun() -> recv_request(TPid, Pkt, Dict0, RecvData) end) + catch + error: system_limit = E -> %% discard + ?LOG({error, E}, now()) + end; + +%% ... answer to known request ... +recv(false, #request{ref = Ref, handler = Pid} = Req, _, Pkt, Dict0, _) -> + Pid ! {answer, Ref, Req, Dict0, Pkt}; +%% Note that failover could have happened prior to this message being +%% received and triggering failback. That is, both a failover message +%% and answer may be on their way to the handler process. In the worst +%% case the request process gets notification of the failover and +%% sends to the alternate peer before an answer arrives, so it's +%% always the case that we can receive more than one answer after +%% failover. The first answer received by the request process wins, +%% any others are discarded. + +%% ... or not. +recv(false, false, _, _, _, _) -> + ok. + +%% --------------------------------------------------------------------------- +%% recv_request/4 +%% --------------------------------------------------------------------------- + +recv_request(TPid, + #diameter_packet{header = #diameter_header{application_id = Id}} + = Pkt, + Dict0, + #recvdata{peerT = PeerT, apps = Apps} + = RecvData) -> + recv_request(diameter_service:find_incoming_app(PeerT, TPid, Id, Apps), + TPid, + Pkt, + Dict0, + RecvData). + +%% recv_request/5 + +recv_request({#diameter_app{id = Id, dictionary = Dict} = App, Caps}, + TPid, + Pkt, + Dict0, + RecvData) -> + recv_R(App, + TPid, + Caps, + Dict0, + RecvData, + diameter_codec:decode(Id, Dict, Pkt)); +%% Note that the decode is different depending on whether or not Id is +%% ?APP_ID_RELAY. + +%% DIAMETER_APPLICATION_UNSUPPORTED 3007 +%% A request was sent for an application that is not supported. + +recv_request(#diameter_caps{} = Caps, TPid, Pkt, Dict0, _) -> + As = collect_avps(Pkt), + protocol_error(3007, TPid, Caps, Dict0, Pkt#diameter_packet{avps = As}); + +recv_request(false, _, _, _, _) -> %% transport has gone down + ok. + +collect_avps(Pkt) -> + case diameter_codec:collect_avps(Pkt) of + {_Bs, As} -> + As; + As -> + As + end. + +%% recv_R/6 + +%% Wrong number of bits somewhere in the message: reply. +%% +%% DIAMETER_INVALID_AVP_BITS 3009 +%% A request was received that included an AVP whose flag bits are +%% set to an unrecognized value, or that is inconsistent with the +%% AVP's definition. +%% +recv_R(_App, + TPid, + Caps, + Dict0, + _RecvData, + #diameter_packet{errors = [Bs | _]} = Pkt) + when is_bitstring(Bs) -> + protocol_error(3009, TPid, Caps, Dict0, Pkt); + +%% Either we support this application but don't recognize the command +%% or we're a relay and the command isn't proxiable. +%% +%% DIAMETER_COMMAND_UNSUPPORTED 3001 +%% The Request contained a Command-Code that the receiver did not +%% recognize or support. This MUST be used when a Diameter node +%% receives an experimental command that it does not understand. +%% +recv_R(#diameter_app{id = Id}, + TPid, + Caps, + Dict0, + _RecvData, + #diameter_packet{header = #diameter_header{is_proxiable = P}, + msg = M} + = Pkt) + when ?APP_ID_RELAY /= Id, undefined == M; + ?APP_ID_RELAY == Id, not P -> + protocol_error(3001, TPid, Caps, Dict0, Pkt); + +%% Error bit was set on a request. +%% +%% DIAMETER_INVALID_HDR_BITS 3008 +%% A request was received whose bits in the Diameter header were +%% either set to an invalid combination, or to a value that is +%% inconsistent with the command code's definition. +%% +recv_R(_App, + TPid, + Caps, + Dict0, + _RecvData, + #diameter_packet{header = #diameter_header{is_error = true}} + = Pkt) -> + protocol_error(3008, TPid, Caps, Dict0, Pkt); + +%% A message in a locally supported application or a proxiable message +%% in the relay application. Don't distinguish between the two since +%% each application has its own callback config. That is, the user can +%% easily distinguish between the two cases. +recv_R(App, TPid, Caps, Dict0, RecvData, Pkt) -> + request_cb(App, TPid, Caps, Dict0, RecvData, examine(Pkt)). + +%% Note that there may still be errors but these aren't protocol +%% (3xxx) errors that lead to an answer-message. + +request_cb(App, + TPid, + Caps, + Dict0, + #recvdata{service_name = SvcName} + = RecvData, + Pkt) -> + request_cb(cb(App, handle_request, [Pkt, SvcName, {TPid, Caps}]), + App, + TPid, + Caps, + Dict0, + RecvData, + [], + Pkt). + +%% examine/1 +%% +%% Look for errors in a decoded message. Length errors result in +%% decode failure in diameter_codec. + +examine(#diameter_packet{header = #diameter_header{version + = ?DIAMETER_VERSION}} + = Pkt) -> + Pkt; + +%% DIAMETER_UNSUPPORTED_VERSION 5011 +%% This error is returned when a request was received, whose version +%% number is unsupported. + +examine(#diameter_packet{errors = Es} = Pkt) -> + Pkt#diameter_packet{errors = [5011 | Es]}. +%% It's odd/unfortunate that this isn't a protocol error. + +%% request_cb/8 + +%% A reply may be an answer-message, constructed either here or by +%% the handle_request callback. The header from the incoming request +%% is passed into the encode so that it can retrieve the relevant +%% command code in this case. It will also then ignore Dict and use +%% the base encoder. +request_cb({reply, Ans}, + #diameter_app{dictionary = Dict}, + TPid, + _Caps, + Dict0, + _RecvData, + Fs, + Pkt) -> + reply(Ans, dict(Dict, Dict0, Ans), TPid, Fs, Pkt); + +%% An 3xxx result code, for which the E-bit is set in the header. +request_cb({protocol_error, RC}, + _App, + TPid, + Caps, + Dict0, + _RecvData, + Fs, + Pkt) + when 3000 =< RC, RC < 4000 -> + protocol_error(RC, TPid, Caps, Dict0, Fs, Pkt); + +%% RFC 3588 says we must reply 3001 to anything unrecognized or +%% unsupported. 'noreply' is undocumented (and inappropriately named) +%% backwards compatibility for this, protocol_error the documented +%% alternative. +request_cb(noreply, + _App, + TPid, + Caps, + Dict0, + _RecvData, + Fs, + Pkt) -> + protocol_error(3001, TPid, Caps, Dict0, Fs, Pkt); + +%% Relay a request to another peer. This is equivalent to doing an +%% explicit call/4 with the message in question except that (1) a loop +%% will be detected by examining Route-Record AVP's, (3) a +%% Route-Record AVP will be added to the outgoing request and (3) the +%% End-to-End Identifier will default to that in the +%% #diameter_header{} without the need for an end_to_end_identifier +%% option. +%% +%% relay and proxy are similar in that they require the same handling +%% with respect to Route-Record and End-to-End identifier. The +%% difference is that a proxy advertises specific applications, while +%% a relay advertises the relay application. If a callback doesn't +%% want to distinguish between the cases in the callback return value +%% then 'resend' is a neutral alternative. +%% +request_cb({A, Opts}, + #diameter_app{id = Id} + = App, + TPid, + Caps, + Dict0, + RecvData, + Fs, + Pkt) + when A == relay, Id == ?APP_ID_RELAY; + A == proxy, Id /= ?APP_ID_RELAY; + A == resend -> + resend(Opts, App, TPid, Caps, Dict0, RecvData, Fs, Pkt); + +request_cb(discard, _, _, _, _, _, _, _) -> + ok; + +request_cb({eval_packet, RC, F}, App, TPid, Caps, Dict0, RecvData, Fs, Pkt) -> + request_cb(RC, App, TPid, Caps, Dict0, RecvData, [F|Fs], Pkt); + +request_cb({eval, RC, F}, App, TPid, Caps, Dict0, RecvData, Fs, Pkt) -> + request_cb(RC, App, TPid, Caps, Dict0, RecvData, Fs, Pkt), + diameter_lib:eval(F). + +%% dict/3 + +%% An incoming answer, not yet decoded. +dict(Dict, Dict0, #diameter_packet{header + = #diameter_header{is_request = false, + is_error = E}, + msg = undefined}) -> + if E -> Dict0; true -> Dict end; + +dict(Dict, Dict0, [Msg]) -> + dict(Dict, Dict0, Msg); + +dict(Dict, Dict0, #diameter_packet{msg = Msg}) -> + dict(Dict, Dict0, Msg); + +dict(_Dict, Dict0, ['answer-message' | _]) -> + Dict0; + +dict(Dict, Dict0, Rec) -> + try + 'answer-message' = Dict0:rec2msg(element(1,Rec)), + Dict0 + catch + error:_ -> Dict + end. + +%% protocol_error/6 + +protocol_error(RC, TPid, Caps, Dict0, Fs, Pkt) -> + #diameter_caps{origin_host = {OH,_}, + origin_realm = {OR,_}} + = Caps, + #diameter_packet{avps = Avps, errors = Es} + = Pkt, + + ?LOG({error, RC}, Pkt), + reply(answer_message({OH, OR, RC}, Dict0, Avps), + Dict0, + TPid, + Fs, + Pkt#diameter_packet{errors = [RC | Es]}). +%% Note that reply/5 may set the result code once more. It's set in +%% answer_message/3 in case reply/5 doesn't. + +%% protocol_error/5 + +protocol_error(RC, TPid, Caps, Dict0, Pkt) -> + protocol_error(RC, TPid, Caps, Dict0, [], Pkt). + +%% resend/7 +%% +%% Resend a message as a relay or proxy agent. + +resend(Opts, + #diameter_app{} + = App, + TPid, + #diameter_caps{origin_host = {OH,_}} + = Caps, + Dict0, + RecvData, + Fs, + #diameter_packet{avps = Avps} + = Pkt) -> + {Code, _Flags, Vid} = Dict0:avp_header('Route-Record'), + resend(is_loop(Code, Vid, OH, Dict0, Avps), + Opts, + App, + TPid, + Caps, + Dict0, + RecvData, + Fs, + Pkt). + +%% DIAMETER_LOOP_DETECTED 3005 +%% An agent detected a loop while trying to get the message to the +%% intended recipient. The message MAY be sent to an alternate peer, +%% if one is available, but the peer reporting the error has +%% identified a configuration problem. + +resend(true, _Opts, _App, TPid, Caps, Dict0, _RecvData, Fs, Pkt) -> + protocol_error(3005, TPid, Caps, Dict0, Fs, Pkt); + +%% 6.1.8. Relaying and Proxying Requests +%% +%% A relay or proxy agent MUST append a Route-Record AVP to all requests +%% forwarded. The AVP contains the identity of the peer the request was +%% received from. + +resend(false, + Opts, + App, + TPid, + #diameter_caps{origin_host = {_,OH}} + = Caps, + Dict0, + #recvdata{service_name = SvcName, + sequence = Mask}, + Fs, + #diameter_packet{header = Hdr0, + avps = Avps} + = Pkt) -> + Route = #diameter_avp{data = {Dict0, 'Route-Record', OH}}, + Seq = diameter_session:sequence(Mask), + Hdr = Hdr0#diameter_header{hop_by_hop_id = Seq}, + Msg = [Hdr, Route | Avps], + resend(send_request(SvcName, App, Msg, Opts), TPid, Caps, Dict0, Fs, Pkt). +%% The incoming request is relayed with the addition of a +%% Route-Record. Note the requirement on the return from call/4 below, +%% which places a requirement on the value returned by the +%% handle_answer callback of the application module in question. +%% +%% Note that there's nothing stopping the request from being relayed +%% back to the sender. A pick_peer callback may want to avoid this but +%% a smart peer might recognize the potential loop and choose another +%% route. A less smart one will probably just relay the request back +%% again and force us to detect the loop. A pick_peer that wants to +%% avoid this can specify filter to avoid the possibility. +%% Eg. {neg, {host, OH} where #diameter_caps{origin_host = {OH, _}}. +%% +%% RFC 6.3 says that a relay agent does not modify Origin-Host but +%% says nothing about a proxy. Assume it should behave the same way. + +%% resend/6 +%% +%% Relay a reply to a relayed request. + +%% Answer from the peer: reset the hop by hop identifier and send. +resend(#diameter_packet{bin = B} + = Pkt, + TPid, + _Caps, + _Dict0, + Fs, + #diameter_packet{header = #diameter_header{hop_by_hop_id = Id}, + transport_data = TD}) -> + P = Pkt#diameter_packet{bin = diameter_codec:hop_by_hop_id(Id, B), + transport_data = TD}, + eval_packet(P, Fs), + send(TPid, P); +%% TODO: counters + +%% Or not: DIAMETER_UNABLE_TO_DELIVER. +resend(_, TPid, Caps, Dict0, Fs, Pkt) -> + protocol_error(3002, TPid, Caps, Dict0, Fs, Pkt). + +%% is_loop/5 +%% +%% Is there a Route-Record AVP with our Origin-Host? + +is_loop(Code, + Vid, + Bin, + _Dict0, + [#diameter_avp{code = Code, vendor_id = Vid, data = Bin} | _]) -> + true; + +is_loop(_, _, _, _, []) -> + false; + +is_loop(Code, Vid, OH, Dict0, [_ | Avps]) + when is_binary(OH) -> + is_loop(Code, Vid, OH, Dict0, Avps); + +is_loop(Code, Vid, OH, Dict0, Avps) -> + is_loop(Code, Vid, Dict0:avp(encode, OH, 'Route-Record'), Dict0, Avps). + +%% reply/5 +%% +%% Send a locally originating reply. + +%% Skip the setting of Result-Code and Failed-AVP's below. This is +%% currently undocumented. +reply([Msg], Dict, TPid, Fs, Pkt) + when is_list(Msg); + is_tuple(Msg) -> + reply(Msg, Dict, TPid, Fs, Pkt#diameter_packet{errors = []}); + +%% No errors or a diameter_header/avp list. +reply(Msg, Dict, TPid, Fs, #diameter_packet{errors = Es} = ReqPkt) + when [] == Es; + is_record(hd(Msg), diameter_header) -> + Pkt = encode(Dict, make_answer_packet(Msg, ReqPkt), Fs), + incr(send, Pkt, Dict, TPid), %% count result codes in sent answers + send(TPid, Pkt); + +%% Or not: set Result-Code and Failed-AVP AVP's. +reply(Msg, Dict, TPid, Fs, #diameter_packet{errors = [H|_] = Es} = Pkt) -> + reply(rc(Msg, rc(H), [A || {_,A} <- Es], Dict), + Dict, + TPid, + Fs, + Pkt#diameter_packet{errors = []}). + +eval_packet(Pkt, Fs) -> + lists:foreach(fun(F) -> diameter_lib:eval([F,Pkt]) end, Fs). + +%% make_answer_packet/2 + +%% A reply message clears the R and T flags and retains the P flag. +%% The E flag will be set at encode. 6.2 of 3588 requires the same P +%% flag on an answer as on the request. A #diameter_packet{} returned +%% from a handle_request callback can circumvent this by setting its +%% own header values. +make_answer_packet(#diameter_packet{header = Hdr, + msg = Msg, + transport_data = TD}, + #diameter_packet{header = ReqHdr}) -> + Hdr0 = ReqHdr#diameter_header{version = ?DIAMETER_VERSION, + is_request = false, + is_error = undefined, + is_retransmitted = false}, + #diameter_packet{header = fold_record(Hdr0, Hdr), + msg = Msg, + transport_data = TD}; + +%% Binaries and header/avp lists are sent as-is. +make_answer_packet(Bin, #diameter_packet{transport_data = TD}) + when is_binary(Bin) -> + #diameter_packet{bin = Bin, + transport_data = TD}; +make_answer_packet([#diameter_header{} | _] = Msg, + #diameter_packet{transport_data = TD}) -> + #diameter_packet{msg = Msg, + transport_data = TD}; + +%% Otherwise, preserve transport_data. +make_answer_packet(Msg, #diameter_packet{transport_data = TD} = Pkt) -> + make_answer_packet(#diameter_packet{msg = Msg, transport_data = TD}, Pkt). + +%% rc/1 + +rc({RC, _}) -> + RC; +rc(RC) -> + RC. + +%% rc/4 + +rc(#diameter_packet{msg = Rec} = Pkt, RC, Failed, DictT) -> + Pkt#diameter_packet{msg = rc(Rec, RC, Failed, DictT)}; + +rc(Rec, RC, Failed, DictT) + when is_integer(RC) -> + set(Rec, + lists:append([rc(Rec, {'Result-Code', RC}, DictT), + failed_avp(Rec, Failed, DictT)]), + DictT). + +%% Reply as name and tuple list ... +set([_|_] = Ans, Avps, _) -> + Ans ++ Avps; %% Values nearer tail take precedence. + +%% ... or record. +set(Rec, Avps, Dict) -> + Dict:'#set-'(Avps, Rec). + +%% rc/3 +%% +%% Turn the result code into a list if its optional and only set it if +%% the arity is 1 or {0,1}. In other cases (which probably shouldn't +%% exist in practise) we can't know what's appropriate. + +rc([MsgName | _], {'Result-Code' = K, RC} = T, Dict) -> + case Dict:avp_arity(MsgName, 'Result-Code') of + 1 -> [T]; + {0,1} -> [{K, [RC]}]; + _ -> [] + end; + +rc(Rec, T, Dict) -> + rc([Dict:rec2msg(element(1, Rec))], T, Dict). + +%% failed_avp/3 + +failed_avp(_, [] = No, _) -> + No; + +failed_avp(Rec, Failed, Dict) -> + [fa(Rec, [{'AVP', Failed}], Dict)]. + +%% Reply as name and tuple list ... +fa([MsgName | Values], FailedAvp, Dict) -> + R = Dict:msg2rec(MsgName), + try + Dict:'#info-'(R, {index, 'Failed-AVP'}), + {'Failed-AVP', [FailedAvp]} + catch + error: _ -> + Avps = proplists:get_value('AVP', Values, []), + A = #diameter_avp{name = 'Failed-AVP', + value = FailedAvp}, + {'AVP', [A|Avps]} + end; + +%% ... or record. +fa(Rec, FailedAvp, Dict) -> + try + {'Failed-AVP', [FailedAvp]} + catch + error: _ -> + Avps = Dict:'get-'('AVP', Rec), + A = #diameter_avp{name = 'Failed-AVP', + value = FailedAvp}, + {'AVP', [A|Avps]} + end. + +%% 3. Diameter Header +%% +%% E(rror) - If set, the message contains a protocol error, +%% and the message will not conform to the ABNF +%% described for this command. Messages with the 'E' +%% bit set are commonly referred to as error +%% messages. This bit MUST NOT be set in request +%% messages. See Section 7.2. + +%% 3.2. Command Code ABNF specification +%% +%% e-bit = ", ERR" +%% ; If present, the 'E' bit in the Command +%% ; Flags is set, indicating that the answer +%% ; message contains a Result-Code AVP in +%% ; the "protocol error" class. + +%% 7.1.3. Protocol Errors +%% +%% Errors that fall within the Protocol Error category SHOULD be treated +%% on a per-hop basis, and Diameter proxies MAY attempt to correct the +%% error, if it is possible. Note that these and only these errors MUST +%% only be used in answer messages whose 'E' bit is set. + +%% Thus, only construct answers to protocol errors. Other errors +%% require an message-specific answer and must be handled by the +%% application. + +%% 6.2. Diameter Answer Processing +%% +%% When a request is locally processed, the following procedures MUST be +%% applied to create the associated answer, in addition to any +%% additional procedures that MAY be discussed in the Diameter +%% application defining the command: +%% +%% - The same Hop-by-Hop identifier in the request is used in the +%% answer. +%% +%% - The local host's identity is encoded in the Origin-Host AVP. +%% +%% - The Destination-Host and Destination-Realm AVPs MUST NOT be +%% present in the answer message. +%% +%% - The Result-Code AVP is added with its value indicating success or +%% failure. +%% +%% - If the Session-Id is present in the request, it MUST be included +%% in the answer. +%% +%% - Any Proxy-Info AVPs in the request MUST be added to the answer +%% message, in the same order they were present in the request. +%% +%% - The 'P' bit is set to the same value as the one in the request. +%% +%% - The same End-to-End identifier in the request is used in the +%% answer. +%% +%% Note that the error messages (see Section 7.3) are also subjected to +%% the above processing rules. + +%% 7.3. Error-Message AVP +%% +%% The Error-Message AVP (AVP Code 281) is of type UTF8String. It MAY +%% accompany a Result-Code AVP as a human readable error message. The +%% Error-Message AVP is not intended to be useful in real-time, and +%% SHOULD NOT be expected to be parsed by network entities. + +%% answer_message/3 + +answer_message({OH, OR, RC}, Dict0, Avps) -> + {Code, _, Vid} = Dict0:avp_header('Session-Id'), + ['answer-message', {'Origin-Host', OH}, + {'Origin-Realm', OR}, + {'Result-Code', RC} + | session_id(Code, Vid, Dict0, Avps)]. + +session_id(Code, Vid, Dict0, Avps) + when is_list(Avps) -> + try + {value, #diameter_avp{data = D}} = find_avp(Code, Vid, Avps), + [{'Session-Id', [Dict0:avp(decode, D, 'Session-Id')]}] + catch + error: _ -> + [] + end. + +%% find_avp/3 + +find_avp(Code, Vid, Avps) + when is_integer(Code), (undefined == Vid orelse is_integer(Vid)) -> + find(fun(A) -> is_avp(Code, Vid, A) end, Avps). + +%% The final argument here could be a list of AVP's, depending on the case, +%% but we're only searching at the top level. +is_avp(Code, Vid, #diameter_avp{code = Code, vendor_id = Vid}) -> + true; +is_avp(_, _, _) -> + false. + +find(_, []) -> + false; +find(Pred, [H|T]) -> + case Pred(H) of + true -> + {value, H}; + false -> + find(Pred, T) + end. + +%% 7. Error Handling +%% +%% There are certain Result-Code AVP application errors that require +%% additional AVPs to be present in the answer. In these cases, the +%% Diameter node that sets the Result-Code AVP to indicate the error +%% MUST add the AVPs. Examples are: +%% +%% - An unrecognized AVP is received with the 'M' bit (Mandatory bit) +%% set, causes an answer to be sent with the Result-Code AVP set to +%% DIAMETER_AVP_UNSUPPORTED, and the Failed-AVP AVP containing the +%% offending AVP. +%% +%% - An AVP that is received with an unrecognized value causes an +%% answer to be returned with the Result-Code AVP set to +%% DIAMETER_INVALID_AVP_VALUE, with the Failed-AVP AVP containing the +%% AVP causing the error. +%% +%% - A command is received with an AVP that is omitted, yet is +%% mandatory according to the command's ABNF. The receiver issues an +%% answer with the Result-Code set to DIAMETER_MISSING_AVP, and +%% creates an AVP with the AVP Code and other fields set as expected +%% in the missing AVP. The created AVP is then added to the Failed- +%% AVP AVP. +%% +%% The Result-Code AVP describes the error that the Diameter node +%% encountered in its processing. In case there are multiple errors, +%% the Diameter node MUST report only the first error it encountered +%% (detected possibly in some implementation dependent order). The +%% specific errors that can be described by this AVP are described in +%% the following section. + +%% 7.5. Failed-AVP AVP +%% +%% The Failed-AVP AVP (AVP Code 279) is of type Grouped and provides +%% debugging information in cases where a request is rejected or not +%% fully processed due to erroneous information in a specific AVP. The +%% value of the Result-Code AVP will provide information on the reason +%% for the Failed-AVP AVP. +%% +%% The possible reasons for this AVP are the presence of an improperly +%% constructed AVP, an unsupported or unrecognized AVP, an invalid AVP +%% value, the omission of a required AVP, the presence of an explicitly +%% excluded AVP (see tables in Section 10), or the presence of two or +%% more occurrences of an AVP which is restricted to 0, 1, or 0-1 +%% occurrences. +%% +%% A Diameter message MAY contain one Failed-AVP AVP, containing the +%% entire AVP that could not be processed successfully. If the failure +%% reason is omission of a required AVP, an AVP with the missing AVP +%% code, the missing vendor id, and a zero filled payload of the minimum +%% required length for the omitted AVP will be added. + +%% incr/4 +%% +%% Increment a stats counter for an incoming or outgoing message. + +%% Outgoing message as binary: don't count. (Sending binaries is only +%% partially supported.) +incr(_, #diameter_packet{msg = undefined}, _, _) -> + ok; + +incr(recv = D, #diameter_packet{header = H, errors = [_|_]}, _, TPid) -> + incr(TPid, {diameter_codec:msg_id(H), D, error}); + +incr(Dir, Pkt, Dict, TPid) -> + #diameter_packet{header = #diameter_header{is_error = E} + = Hdr, + msg = Rec} + = Pkt, + + RC = int(get_avp_value(Dict, 'Result-Code', Rec)), + PE = is_protocol_error(RC), + + %% Check that the E bit is set only for 3xxx result codes. + (not (E orelse PE)) + orelse (E andalso PE) + orelse x({invalid_error_bit, RC}, answer, [Dir, Pkt]), + + irc(TPid, Hdr, Dir, rc_counter(Dict, Rec, RC)). + +irc(_, _, _, undefined) -> + false; + +irc(TPid, Hdr, Dir, Ctr) -> + incr(TPid, {diameter_codec:msg_id(Hdr), Dir, Ctr}). + +%% incr/2 + +incr(TPid, Counter) -> + diameter_stats:incr(Counter, TPid, 1). + +%% error_counter/2 + +%% RFC 3588, 7.6: +%% +%% All Diameter answer messages defined in vendor-specific +%% applications MUST include either one Result-Code AVP or one +%% Experimental-Result AVP. +%% +%% Maintain statistics assuming one or the other, not both, which is +%% surely the intent of the RFC. + +rc_counter(Dict, Rec, undefined) -> + rcc(get_avp_value(Dict, 'Experimental-Result', Rec)); +rc_counter(_, _, RC) -> + {'Result-Code', RC}. + +%% Outgoing answers may be in any of the forms messages can be sent +%% in. Incoming messages will be records. We're assuming here that the +%% arity of the result code AVP's is 0 or 1. + +rcc([{_,_,N} = T | _]) + when is_integer(N) -> + T; +rcc({_,_,N} = T) + when is_integer(N) -> + T; +rcc(_) -> + undefined. + +%% Extract the first good looking integer. There's no guarantee +%% that what we're looking for has arity 1. +int([N|_]) + when is_integer(N) -> + N; +int(N) + when is_integer(N) -> + N; +int(_) -> + undefined. + +is_protocol_error(RC) -> + 3000 =< RC andalso RC < 4000. + +-spec x(any(), atom(), list()) -> no_return(). + +%% Warn and exit request process on errors in an incoming answer. +x(Reason, F, A) -> + diameter_lib:warning_report(Reason, {?MODULE, F, A}), + x(Reason). + +x(T) -> + exit(T). + +%% --------------------------------------------------------------------------- +%% # send_request/4 +%% +%% Handle an outgoing Diameter request. +%% --------------------------------------------------------------------------- + +send_request(SvcName, AppOrAlias, Msg, Options) + when is_list(Options) -> + Rec = make_options(Options), + Ref = make_ref(), + Caller = {self(), Ref}, + ReqF = fun() -> + exit({Ref, send_R(SvcName, AppOrAlias, Msg, Rec, Caller)}) + end, + try spawn_monitor(ReqF) of + {_, MRef} -> + recv_A(MRef, Ref, Rec#options.detach, false) + catch + error: system_limit = E -> + {error, E} + end. +%% The R in send_R is because Diameter request are usually given short +%% names of the form XXR. (eg. CER, DWR, etc.) Similarly, answers have +%% names of the form XXA. + +%% Don't rely on gen_server:call/3 for the timeout handling since it +%% makes no guarantees about not leaving a reply message in the +%% mailbox if we catch its exit at timeout. It currently *can* do so, +%% which is also undocumented. + +recv_A(MRef, _, true, true) -> + erlang:demonitor(MRef, [flush]), + ok; + +recv_A(MRef, Ref, Detach, Sent) -> + receive + Ref -> %% send has been attempted + recv_A(MRef, Ref, Detach, true); + {'DOWN', MRef, process, _, Reason} -> + answer_rc(Reason, Ref, Sent) + end. + +%% send_R/5 has returned ... +answer_rc({Ref, Ans}, Ref, _) -> + Ans; + +%% ... or not. Note that failure/encode are documented return values. +answer_rc(_, _, Sent) -> + {error, choose(Sent, failure, encode)}. + +%% send_R/5 +%% +%% In the process spawned for the outgoing request. + +send_R(SvcName, AppOrAlias, Msg, Opts, Caller) -> + case pick_peer(SvcName, AppOrAlias, Msg, Opts) of + {{_,_,_} = Transport, Mask} -> + send_request(Transport, Mask, Msg, Opts, Caller, SvcName); + false -> + {error, no_connection}; + {error, _} = No -> + No + end. + +%% make_options/1 + +make_options(Options) -> + lists:foldl(fun mo/2, #options{}, Options). + +mo({timeout, T}, Rec) + when is_integer(T), 0 =< T -> + Rec#options{timeout = T}; + +mo({filter, F}, #options{filter = none} = Rec) -> + Rec#options{filter = F}; +mo({filter, F}, #options{filter = {all, Fs}} = Rec) -> + Rec#options{filter = {all, [F | Fs]}}; +mo({filter, F}, #options{filter = F0} = Rec) -> + Rec#options{filter = {all, [F0, F]}}; + +mo({extra, L}, #options{extra = X} = Rec) + when is_list(L) -> + Rec#options{extra = X ++ L}; + +mo(detach, Rec) -> + Rec#options{detach = true}; + +mo(T, _) -> + ?ERROR({invalid_option, T}). + +%% --------------------------------------------------------------------------- +%% # send_request/6 +%% --------------------------------------------------------------------------- + +%% Send an outgoing request in its dedicated process. +%% +%% Note that both encode of the outgoing request and of the received +%% answer happens in this process. It's also this process that replies +%% to the caller. The service process only handles the state-retaining +%% callbacks. +%% +%% The module field of the #diameter_app{} here includes any extra +%% arguments passed to diameter:call/4. + +send_request({TPid, Caps, App} + = Transport, + Mask, + Msg, + Opts, + Caller, + SvcName) -> + Pkt = make_prepare_packet(Mask, Msg), + + send_R(cb(App, prepare_request, [Pkt, SvcName, {TPid, Caps}]), + Pkt, + Transport, + Opts, + Caller, + SvcName, + []). + +send_R({send, Msg}, Pkt, Transport, Opts, Caller, SvcName, Fs) -> + send_R(make_request_packet(Msg, Pkt), + Transport, + Opts, + Caller, + SvcName, + Fs); + +send_R({discard, Reason} , _, _, _, _, _, _) -> + {error, Reason}; + +send_R(discard, _, _, _, _, _, _) -> + {error, discarded}; + +send_R({eval_packet, RC, F}, Pkt, T, Opts, Caller, SvcName, Fs) -> + send_R(RC, Pkt, T, Opts, Caller, SvcName, [F|Fs]); + +send_R(E, _, {_, _, App}, _, _, _, _) -> + ?ERROR({invalid_return, prepare_request, App, E}). + +%% make_prepare_packet/2 +%% +%% Turn an outgoing request as passed to call/4 into a diameter_packet +%% record in preparation for a prepare_request callback. + +make_prepare_packet(_, Bin) + when is_binary(Bin) -> + #diameter_packet{header = diameter_codec:decode_header(Bin), + bin = Bin}; + +make_prepare_packet(Mask, #diameter_packet{msg = [#diameter_header{} = Hdr + | Avps]} + = Pkt) -> + Pkt#diameter_packet{msg = [make_prepare_header(Mask, Hdr) | Avps]}; + +make_prepare_packet(Mask, #diameter_packet{header = Hdr} = Pkt) -> + Pkt#diameter_packet{header = make_prepare_header(Mask, Hdr)}; + +make_prepare_packet(Mask, Msg) -> + make_prepare_packet(Mask, #diameter_packet{msg = Msg}). + +%% make_prepare_header/2 + +make_prepare_header(Mask, undefined) -> + Seq = diameter_session:sequence(Mask), + make_prepare_header(#diameter_header{end_to_end_id = Seq, + hop_by_hop_id = Seq}); + +make_prepare_header(Mask, #diameter_header{end_to_end_id = undefined, + hop_by_hop_id = undefined} + = H) -> + Seq = diameter_session:sequence(Mask), + make_prepare_header(H#diameter_header{end_to_end_id = Seq, + hop_by_hop_id = Seq}); + +make_prepare_header(Mask, #diameter_header{end_to_end_id = undefined} = H) -> + Seq = diameter_session:sequence(Mask), + make_prepare_header(H#diameter_header{end_to_end_id = Seq}); + +make_prepare_header(Mask, #diameter_header{hop_by_hop_id = undefined} = H) -> + Seq = diameter_session:sequence(Mask), + make_prepare_header(H#diameter_header{hop_by_hop_id = Seq}); + +make_prepare_header(_, Hdr) -> + make_prepare_header(Hdr). + +%% make_prepare_header/1 + +make_prepare_header(#diameter_header{version = undefined} = Hdr) -> + make_prepare_header(Hdr#diameter_header{version = ?DIAMETER_VERSION}); + +make_prepare_header(#diameter_header{} = Hdr) -> + Hdr; + +make_prepare_header(T) -> + ?ERROR({invalid_header, T}). + +%% make_request_packet/2 +%% +%% Reconstruct a diameter_packet from the return value of +%% prepare_request or prepare_retransmit callback. + +make_request_packet(Bin, _) + when is_binary(Bin) -> + make_prepare_packet(false, Bin); + +make_request_packet(#diameter_packet{msg = [#diameter_header{} | _]} + = Pkt, + _) -> + Pkt; + +%% Returning a diameter_packet with no header from a prepare_request +%% or prepare_retransmit callback retains the header passed into it. +%% This is primarily so that the end to end and hop by hop identifiers +%% are retained. +make_request_packet(#diameter_packet{header = Hdr} = Pkt, + #diameter_packet{header = Hdr0}) -> + Pkt#diameter_packet{header = fold_record(Hdr0, Hdr)}; + +make_request_packet(Msg, Pkt) -> + Pkt#diameter_packet{msg = Msg}. + +%% fold_record/2 + +fold_record(undefined, R) -> + R; +fold_record(Rec, R) -> + diameter_lib:fold_tuple(2, Rec, R). + +%% send_R/6 + +send_R(Pkt0, + {TPid, Caps, #diameter_app{dictionary = Dict} = App}, + Opts, + {Pid, Ref}, + SvcName, + Fs) -> + Pkt = encode(Dict, Pkt0, Fs), + + #options{timeout = Timeout} + = Opts, + + Req = #request{ref = Ref, + caller = Pid, + handler = self(), + transport = TPid, + caps = Caps, + packet = Pkt0}, + + try + TRef = send_request(TPid, Pkt, Req, SvcName, Timeout), + Pid ! Ref, %% tell caller a send has been attempted + handle_answer(SvcName, + App, + recv_A(Timeout, SvcName, App, Opts, {TRef, Req})) + after + erase_requests(Pkt) + end. + +%% recv_A/5 + +recv_A(Timeout, SvcName, App, Opts, {TRef, #request{ref = Ref} = Req}) -> + %% Matching on TRef below ensures we ignore messages that pertain + %% to a previous transport prior to failover. The answer message + %% includes the #request{} since it's not necessarily Req; that + %% is, from the last peer to which we've transmitted. + receive + {answer = A, Ref, Rq, Dict0, Pkt} -> %% Answer from peer + {A, Rq, Dict0, Pkt}; + {timeout = Reason, TRef, _} -> %% No timely reply + {error, Req, Reason}; + {failover, TRef} -> %% Service says peer has gone down + retransmit(pick_peer(SvcName, App, Req, Opts), + Req, + Opts, + SvcName, + Timeout) + end. + +%% handle_answer/3 + +handle_answer(SvcName, App, {error, Req, Reason}) -> + handle_error(App, Req, Reason, SvcName); + +handle_answer(SvcName, + #diameter_app{dictionary = Dict} + = App, + {answer, Req, Dict0, Pkt}) -> + Mod = dict(Dict, Dict0, Pkt), + answer(examine(diameter_codec:decode(Mod, Pkt)), + SvcName, + Mod, + App, + Req). + +%% We don't really need to do a full decode if we're a relay and will +%% just resend with a new hop by hop identifier, but might a proxy +%% want to examine the answer? + +answer(Pkt, SvcName, Dict, App, #request{transport = TPid} = Req) -> + try + incr(recv, Pkt, Dict, TPid) + of + _ -> answer(Pkt, SvcName, App, Req) + catch + exit: {invalid_error_bit, _} = E -> + answer(Pkt#diameter_packet{errors = [E]}, SvcName, App, Req) + end. + +answer(Pkt, + SvcName, + #diameter_app{module = ModX, + options = [{answer_errors, AE} | _]}, + Req) -> + a(Pkt, SvcName, ModX, AE, Req). + +a(#diameter_packet{errors = Es} + = Pkt, + SvcName, + ModX, + AE, + #request{transport = TPid, + caps = Caps, + packet = P}) + when [] == Es; + callback == AE -> + cb(ModX, handle_answer, [Pkt, msg(P), SvcName, {TPid, Caps}]); + +a(Pkt, SvcName, _, report, Req) -> + x(errors, handle_answer, [SvcName, Req, Pkt]); + +a(Pkt, SvcName, _, discard, Req) -> + x({errors, handle_answer, [SvcName, Req, Pkt]}). + +%% Note that we don't check that the application id in the answer's +%% header is what we expect. (TODO: Does the rfc says anything about +%% this?) + +%% Note that failover starts a new timer and that expiry of an old +%% timer value is ignored. This means that an answer could be accepted +%% from a peer after timeout in the case of failover. + +retransmit({{_,_,App} = Transport, _Mask}, Req, Opts, SvcName, Timeout) -> + try retransmit(Transport, Req, SvcName, Timeout) of + T -> recv_A(Timeout, SvcName, App, Opts, T) + catch + ?FAILURE(Reason) -> {error, Req, Reason} + end; + +retransmit(_, Req, _, _, _) -> %% no alternate peer + {error, Req, failover}. + +%% pick_peer/4 + +%% Retransmission after failover: call-specific arguments have already +%% been appended in App. +pick_peer(SvcName, + App, + #request{packet = #diameter_packet{msg = Msg}}, + Opts) -> + pick_peer(SvcName, App, Msg, Opts#options{extra = []}); + +pick_peer(_, _, undefined, _) -> + false; + +pick_peer(SvcName, + AppOrAlias, + Msg, + #options{filter = Filter, extra = Xtra}) -> + diameter_service:pick_peer(SvcName, + AppOrAlias, + {fun(D) -> get_destination(D, Msg) end, + Filter, + Xtra}). + +%% handle_error/4 + +handle_error(App, + #request{packet = Pkt, + transport = TPid, + caps = Caps}, + Reason, + SvcName) -> + cb(App, handle_error, [Reason, msg(Pkt), SvcName, {TPid, Caps}]). + +msg(#diameter_packet{msg = undefined, bin = Bin}) -> + Bin; +msg(#diameter_packet{msg = Msg}) -> + Msg. + +%% encode/3 + +encode(Dict, Pkt, Fs) -> + P = encode(Dict, Pkt), + eval_packet(P, Fs), + P. + +%% encode/2 + +%% Note that prepare_request can return a diameter_packet containing a +%% header or transport_data. Even allow the returned record to contain +%% an encoded binary. This isn't the usual case and doesn't properly +%% support retransmission but is useful for test. + +%% A message to be encoded. +encode(Dict, #diameter_packet{bin = undefined} = Pkt) -> + diameter_codec:encode(Dict, Pkt); + +%% An encoded binary: just send. +encode(_, #diameter_packet{} = Pkt) -> + Pkt. + +%% send_request/5 + +send_request(TPid, #diameter_packet{bin = Bin} = Pkt, Req, _SvcName, Timeout) + when node() == node(TPid) -> + %% Store the outgoing request before sending to avoid a race with + %% reply reception. + TRef = store_request(TPid, Bin, Req, Timeout), + send(TPid, Pkt), + TRef; + +%% Send using a remote transport: spawn a process on the remote node +%% to relay the answer. +send_request(TPid, #diameter_packet{} = Pkt, Req, SvcName, Timeout) -> + TRef = erlang:start_timer(Timeout, self(), TPid), + T = {TPid, Pkt, Req, SvcName, Timeout, TRef}, + spawn(node(TPid), ?MODULE, send, [T]), + TRef. + +%% send/1 + +send({TPid, Pkt, #request{handler = Pid} = Req, SvcName, Timeout, TRef}) -> + Ref = send_request(TPid, + Pkt, + Req#request{handler = self()}, + SvcName, + Timeout), + Pid ! reref(receive T -> T end, Ref, TRef). + +reref({T, Ref, R}, Ref, TRef) -> + {T, TRef, R}; +reref(T, _, _) -> + T. + +%% send/2 + +send(Pid, Pkt) -> + Pid ! {send, Pkt}. + +%% retransmit/4 + +retransmit({TPid, Caps, App} + = Transport, + #request{packet = Pkt0} + = Req, + SvcName, + Timeout) -> + have_request(Pkt0, TPid) %% Don't failover to a peer we've + andalso ?THROW(timeout), %% already sent to. + + #diameter_packet{header = Hdr0} = Pkt0, + Hdr = Hdr0#diameter_header{is_retransmitted = true}, + Pkt = Pkt0#diameter_packet{header = Hdr}, + + retransmit(cb(App, prepare_retransmit, [Pkt, SvcName, {TPid, Caps}]), + Transport, + Req#request{packet = Pkt}, + SvcName, + Timeout, + []). + +retransmit({send, Msg}, + Transport, + #request{packet = Pkt} + = Req, + SvcName, + Timeout, + Fs) -> + resend_request(make_request_packet(Msg, Pkt), + Transport, + Req, + SvcName, + Timeout, + Fs); + +retransmit({discard, Reason}, _, _, _, _, _) -> + ?THROW(Reason); + +retransmit(discard, _, _, _, _, _) -> + ?THROW(discarded); + +retransmit({eval_packet, RC, F}, Transport, Req, SvcName, Timeout, Fs) -> + retransmit(RC, Transport, Req, SvcName, Timeout, [F|Fs]); + +retransmit(T, {_, _, App}, _, _, _, _) -> + ?ERROR({invalid_return, prepare_retransmit, App, T}). + +resend_request(Pkt0, + {TPid, Caps, #diameter_app{dictionary = Dict}}, + Req0, + SvcName, + Tmo, + Fs) -> + Pkt = encode(Dict, Pkt0, Fs), + + Req = Req0#request{transport = TPid, + packet = Pkt0, + caps = Caps}, + + ?LOG(retransmission, Req), + TRef = send_request(TPid, Pkt, Req, SvcName, Tmo), + {TRef, Req}. + +%% store_request/4 + +store_request(TPid, Bin, Req, Timeout) -> + Seqs = diameter_codec:sequence_numbers(Bin), + TRef = erlang:start_timer(Timeout, self(), timeout), + ets:insert(?REQUEST_TABLE, {Seqs, Req, TRef}), + ets:member(?REQUEST_TABLE, TPid) + orelse (self() ! {failover, TRef}), %% failover/1 may have missed + TRef. + +%% lookup_request/2 + +lookup_request(Msg, TPid) -> + Seqs = diameter_codec:sequence_numbers(Msg), + Spec = [{{Seqs, #request{transport = TPid, _ = '_'}, '_'}, + [], + ['$_']}], + case ets:select(?REQUEST_TABLE, Spec) of + [{_, Req, _}] -> + Req; + [] -> + false + end. + +%% erase_requests/1 + +erase_requests(Pkt) -> + ets:delete(?REQUEST_TABLE, diameter_codec:sequence_numbers(Pkt)). + +%% match_requests/1 + +match_requests(TPid) -> + Pat = {'_', #request{transport = TPid, _ = '_'}, '_'}, + ets:select(?REQUEST_TABLE, [{Pat, [], ['$_']}]). + +%% have_request/2 + +have_request(Pkt, TPid) -> + Seqs = diameter_codec:sequence_numbers(Pkt), + Pat = {Seqs, #request{transport = TPid, _ = '_'}, '_'}, + '$end_of_table' /= ets:select(?REQUEST_TABLE, [{Pat, [], ['$_']}], 1). + +%% --------------------------------------------------------------------------- +%% # failover/1-2 +%% --------------------------------------------------------------------------- + +failover(TPid) + when is_pid(TPid) -> + lists:foreach(fun failover/1, match_requests(TPid)); +%% Note that a request process can store its request after failover +%% notifications are sent here: store_request/4 sends the notification +%% in that case. + +%% Failover as a consequence of request_peer_down/1: inform the +%% request process. +failover({_, Req, TRef}) -> + #request{handler = Pid, + packet = #diameter_packet{msg = M}} + = Req, + M /= undefined andalso (Pid ! {failover, TRef}). +%% Failover is not performed when msg = binary() since sending +%% pre-encoded binaries is only partially supported. (Mostly for +%% test.) + +%% get_destination/2 + +get_destination(Dict, Msg) -> + [str(get_avp_value(Dict, D, Msg)) || D <- ['Destination-Realm', + 'Destination-Host']]. + +%% This is not entirely correct. The avp could have an arity 1, in +%% which case an empty list is a DiameterIdentity of length 0 rather +%% than the list of no values we treat it as by mapping to undefined. +%% This behaviour is documented. +str([]) -> + undefined; +str(T) -> + T. + +%% get_avp_value/3 +%% +%% Find an AVP in a message of one of three forms: +%% +%% - a message record (as generated from a .dia spec) or +%% - a list of an atom message name followed by 2-tuple, avp name/value pairs. +%% - a list of a #diameter_header{} followed by #diameter_avp{} records, +%% +%% In the first two forms a dictionary module is used at encode to +%% identify the type of the AVP and its arity in the message in +%% question. The third form allows messages to be sent as is, without +%% a dictionary, which is needed in the case of relay agents, for one. + +%% Messages will be header/avps list as a relay and the only AVP's we +%% look for are in the common dictionary. This is required since the +%% relay dictionary doesn't inherit the common dictionary (which maybe +%% it should). +get_avp_value(?RELAY, Name, Msg) -> + get_avp_value(?BASE, Name, Msg); + +%% Message sent as a header/avps list, probably a relay case but not +%% necessarily. +get_avp_value(Dict, Name, [#diameter_header{} | Avps]) -> + try + {Code, _, VId} = Dict:avp_header(Name), + [A|_] = lists:dropwhile(fun(#diameter_avp{code = C, vendor_id = V}) -> + C /= Code orelse V /= VId + end, + Avps), + avp_decode(Dict, Name, A) + catch + error: _ -> + undefined + end; + +%% Outgoing message as a name/values list. +get_avp_value(_, Name, [_MsgName | Avps]) -> + case lists:keyfind(Name, 1, Avps) of + {_, V} -> + V; + _ -> + undefined + end; + +%% Message is typically a record but not necessarily. +get_avp_value(Dict, Name, Rec) -> + try + Dict:'#get-'(Name, Rec) + catch + error:_ -> + undefined + end. + +avp_decode(Dict, Name, #diameter_avp{value = undefined, + data = Bin}) -> + Dict:avp(decode, Bin, Name); +avp_decode(_, _, #diameter_avp{value = V}) -> + V. + +cb(#diameter_app{module = [_|_] = M}, F, A) -> + eval(M, F, A); +cb([_|_] = M, F, A) -> + eval(M, F, A). + +eval([M|X], F, A) -> + apply(M, F, A ++ X). + +choose(true, X, _) -> X; +choose(false, _, X) -> X. |