%% Copyright (c) 2011-2013, Loïc Hoguin %% Copyright (c) 2011, Anthony Ramine %% %% Permission to use, copy, modify, and/or distribute this software for any %% purpose with or without fee is hereby granted, provided that the above %% copyright notice and this permission notice appear in all copies. %% %% THE SOFTWARE IS PROVIDED "AS IS" AND THE AUTHOR DISCLAIMS ALL WARRANTIES %% WITH REGARD TO THIS SOFTWARE INCLUDING ALL IMPLIED WARRANTIES OF %% MERCHANTABILITY AND FITNESS. IN NO EVENT SHALL THE AUTHOR BE LIABLE FOR %% ANY SPECIAL, DIRECT, INDIRECT, OR CONSEQUENTIAL DAMAGES OR ANY DAMAGES %% WHATSOEVER RESULTING FROM LOSS OF USE, DATA OR PROFITS, WHETHER IN AN %% ACTION OF CONTRACT, NEGLIGENCE OR OTHER TORTIOUS ACTION, ARISING OUT OF %% OR IN CONNECTION WITH THE USE OR PERFORMANCE OF THIS SOFTWARE. %% @doc HTTP protocol handler. %% %% The available options are: %%
%%
compress
Whether to automatically compress the response %% body when the conditions are met. Disabled by default.
%%
env
The environment passed and optionally modified %% by middlewares.
%%
max_empty_lines
Max number of empty lines before a request. %% Defaults to 5.
%%
max_header_name_length
Max length allowed for header names. %% Defaults to 64.
%%
max_header_value_length
Max length allowed for header values. %% Defaults to 4096.
%%
max_headers
Max number of headers allowed. %% Defaults to 100.
%%
max_keepalive
Max number of requests allowed in a single %% keep-alive session. Defaults to 100.
%%
max_request_line_length
Max length allowed for the request %% line. Defaults to 4096.
%%
middlewares
The list of middlewares to execute when a %% request is received.
%%
onrequest
Optional fun that allows Req interaction before %% any dispatching is done. Host info, path info and bindings are thus %% not available at this point.
%%
onresponse
Optional fun that allows replacing a response %% sent by the application.
%%
timeout
Time in milliseconds a client has to send the %% full request line and headers. Defaults to 5000 milliseconds.
%%
%% %% Note that there is no need to monitor these processes when using Cowboy as %% an application as it already supervises them under the listener supervisor. -module(cowboy_protocol). %% API. -export([start_link/4]). %% Internal. -export([init/4]). -export([parse_request/3]). -export([parse_host/2]). -export([resume/6]). -type opts() :: [{compress, boolean()} | {env, cowboy_middleware:env()} | {max_empty_lines, non_neg_integer()} | {max_header_name_length, non_neg_integer()} | {max_header_value_length, non_neg_integer()} | {max_headers, non_neg_integer()} | {max_keepalive, non_neg_integer()} | {max_request_line_length, non_neg_integer()} | {middlewares, [module()]} | {onrequest, cowboy:onrequest_fun()} | {onresponse, cowboy:onresponse_fun()} | {timeout, timeout()}]. -export_type([opts/0]). -record(state, { socket :: inet:socket(), transport :: module(), middlewares :: [module()], compress :: boolean(), env :: cowboy_middleware:env(), onrequest :: undefined | cowboy:onrequest_fun(), onresponse = undefined :: undefined | cowboy:onresponse_fun(), max_empty_lines :: non_neg_integer(), req_keepalive = 1 :: non_neg_integer(), max_keepalive :: non_neg_integer(), max_request_line_length :: non_neg_integer(), max_header_name_length :: non_neg_integer(), max_header_value_length :: non_neg_integer(), max_headers :: non_neg_integer(), timeout :: timeout(), until :: non_neg_integer() | infinity }). %% API. %% @doc Start an HTTP protocol process. -spec start_link(ranch:ref(), inet:socket(), module(), opts()) -> {ok, pid()}. start_link(Ref, Socket, Transport, Opts) -> Pid = spawn_link(?MODULE, init, [Ref, Socket, Transport, Opts]), {ok, Pid}. %% Internal. %% @doc Faster alternative to proplists:get_value/3. %% @private get_value(Key, Opts, Default) -> case lists:keyfind(Key, 1, Opts) of {_, Value} -> Value; _ -> Default end. %% @private -spec init(ranch:ref(), inet:socket(), module(), opts()) -> ok. init(Ref, Socket, Transport, Opts) -> Compress = get_value(compress, Opts, false), MaxEmptyLines = get_value(max_empty_lines, Opts, 5), MaxHeaderNameLength = get_value(max_header_name_length, Opts, 64), MaxHeaderValueLength = get_value(max_header_value_length, Opts, 4096), MaxHeaders = get_value(max_headers, Opts, 100), MaxKeepalive = get_value(max_keepalive, Opts, 100), MaxRequestLineLength = get_value(max_request_line_length, Opts, 4096), Middlewares = get_value(middlewares, Opts, [cowboy_router, cowboy_handler]), Env = [{listener, Ref}|get_value(env, Opts, [])], OnRequest = get_value(onrequest, Opts, undefined), OnResponse = get_value(onresponse, Opts, undefined), Timeout = get_value(timeout, Opts, 5000), ok = ranch:accept_ack(Ref), wait_request(<<>>, #state{socket=Socket, transport=Transport, middlewares=Middlewares, compress=Compress, env=Env, max_empty_lines=MaxEmptyLines, max_keepalive=MaxKeepalive, max_request_line_length=MaxRequestLineLength, max_header_name_length=MaxHeaderNameLength, max_header_value_length=MaxHeaderValueLength, max_headers=MaxHeaders, onrequest=OnRequest, onresponse=OnResponse, timeout=Timeout, until=until(Timeout)}, 0). -spec until(timeout()) -> non_neg_integer() | infinity. until(infinity) -> infinity; until(Timeout) -> {Me, S, Mi} = os:timestamp(), Me * 1000000000 + S * 1000 + Mi div 1000 + Timeout. %% Request parsing. %% %% The next set of functions is the request parsing code. All of it %% runs using a single binary match context. This optimization ends %% right after the header parsing is finished and the code becomes %% more interesting past that point. -spec recv(inet:socket(), module(), non_neg_integer() | infinity) -> {ok, binary()} | {error, closed | timeout | atom()}. recv(Socket, Transport, infinity) -> Transport:recv(Socket, 0, infinity); recv(Socket, Transport, Until) -> {Me, S, Mi} = os:timestamp(), Now = Me * 1000000000 + S * 1000 + Mi div 1000, Timeout = Until - Now, if Timeout < 0 -> {error, timeout}; true -> Transport:recv(Socket, 0, Timeout) end. -spec wait_request(binary(), #state{}, non_neg_integer()) -> ok. wait_request(Buffer, State=#state{socket=Socket, transport=Transport, until=Until}, ReqEmpty) -> case recv(Socket, Transport, Until) of {ok, Data} -> parse_request(<< Buffer/binary, Data/binary >>, State, ReqEmpty); {error, _} -> terminate(State) end. %% @private -spec parse_request(binary(), #state{}, non_neg_integer()) -> ok. %% Empty lines must be using \r\n. parse_request(<< $\n, _/binary >>, State, _) -> error_terminate(400, State); %% We limit the length of the Request-line to MaxLength to avoid endlessly %% reading from the socket and eventually crashing. parse_request(Buffer, State=#state{max_request_line_length=MaxLength, max_empty_lines=MaxEmpty}, ReqEmpty) -> case match_eol(Buffer, 0) of nomatch when byte_size(Buffer) > MaxLength -> error_terminate(414, State); nomatch -> wait_request(Buffer, State, ReqEmpty); 1 when ReqEmpty =:= MaxEmpty -> error_terminate(400, State); 1 -> << _:16, Rest/binary >> = Buffer, parse_request(Rest, State, ReqEmpty + 1); _ -> parse_method(Buffer, State, <<>>) end. match_eol(<< $\n, _/bits >>, N) -> N; match_eol(<< _, Rest/bits >>, N) -> match_eol(Rest, N + 1); match_eol(_, _) -> nomatch. parse_method(<< C, Rest/bits >>, State, SoFar) -> case C of $\r -> error_terminate(400, State); $\s -> parse_uri(Rest, State, SoFar); _ -> parse_method(Rest, State, << SoFar/binary, C >>) end. parse_uri(<< $\r, _/bits >>, State, _) -> error_terminate(400, State); parse_uri(<< "* ", Rest/bits >>, State, Method) -> parse_version(Rest, State, Method, <<"*">>, <<>>); parse_uri(<< "http://", Rest/bits >>, State, Method) -> parse_uri_skip_host(Rest, State, Method); parse_uri(<< "https://", Rest/bits >>, State, Method) -> parse_uri_skip_host(Rest, State, Method); parse_uri(Buffer, State, Method) -> parse_uri_path(Buffer, State, Method, <<>>). parse_uri_skip_host(<< C, Rest/bits >>, State, Method) -> case C of $\r -> error_terminate(400, State); $/ -> parse_uri_path(Rest, State, Method, <<"/">>); _ -> parse_uri_skip_host(Rest, State, Method) end. parse_uri_path(<< C, Rest/bits >>, State, Method, SoFar) -> case C of $\r -> error_terminate(400, State); $\s -> parse_version(Rest, State, Method, SoFar, <<>>); $? -> parse_uri_query(Rest, State, Method, SoFar, <<>>); $# -> skip_uri_fragment(Rest, State, Method, SoFar, <<>>); _ -> parse_uri_path(Rest, State, Method, << SoFar/binary, C >>) end. parse_uri_query(<< C, Rest/bits >>, S, M, P, SoFar) -> case C of $\r -> error_terminate(400, S); $\s -> parse_version(Rest, S, M, P, SoFar); $# -> skip_uri_fragment(Rest, S, M, P, SoFar); _ -> parse_uri_query(Rest, S, M, P, << SoFar/binary, C >>) end. skip_uri_fragment(<< C, Rest/bits >>, S, M, P, Q) -> case C of $\r -> error_terminate(400, S); $\s -> parse_version(Rest, S, M, P, Q); _ -> skip_uri_fragment(Rest, S, M, P, Q) end. parse_version(<< "HTTP/1.1\r\n", Rest/bits >>, S, M, P, Q) -> parse_header(Rest, S, M, P, Q, 'HTTP/1.1', []); parse_version(<< "HTTP/1.0\r\n", Rest/bits >>, S, M, P, Q) -> parse_header(Rest, S, M, P, Q, 'HTTP/1.0', []); parse_version(_, State, _, _, _) -> error_terminate(505, State). %% Stop receiving data if we have more than allowed number of headers. wait_header(_, State=#state{max_headers=MaxHeaders}, _, _, _, _, Headers) when length(Headers) >= MaxHeaders -> error_terminate(400, State); wait_header(Buffer, State=#state{socket=Socket, transport=Transport, until=Until}, M, P, Q, V, H) -> case recv(Socket, Transport, Until) of {ok, Data} -> parse_header(<< Buffer/binary, Data/binary >>, State, M, P, Q, V, H); {error, timeout} -> error_terminate(408, State); {error, _} -> terminate(State) end. parse_header(<< $\r, $\n, Rest/bits >>, S, M, P, Q, V, Headers) -> request(Rest, S, M, P, Q, V, lists:reverse(Headers)); parse_header(Buffer, State=#state{max_header_name_length=MaxLength}, M, P, Q, V, H) -> case match_colon(Buffer, 0) of nomatch when byte_size(Buffer) > MaxLength -> error_terminate(400, State); nomatch -> wait_header(Buffer, State, M, P, Q, V, H); _ -> parse_hd_name(Buffer, State, M, P, Q, V, H, <<>>) end. match_colon(<< $:, _/bits >>, N) -> N; match_colon(<< _, Rest/bits >>, N) -> match_colon(Rest, N + 1); match_colon(_, _) -> nomatch. %% I know, this isn't exactly pretty. But this is the most critical %% code path and as such needs to be optimized to death. %% %% ... Sorry for your eyes. %% %% But let's be honest, that's still pretty readable. parse_hd_name(<< C, Rest/bits >>, S, M, P, Q, V, H, SoFar) -> case C of $: -> parse_hd_before_value(Rest, S, M, P, Q, V, H, SoFar); $\s -> parse_hd_name_ws(Rest, S, M, P, Q, V, H, SoFar); $\t -> parse_hd_name_ws(Rest, S, M, P, Q, V, H, SoFar); $A -> parse_hd_name(Rest, S, M, P, Q, V, H, << SoFar/binary, $a >>); $B -> parse_hd_name(Rest, S, M, P, Q, V, H, << SoFar/binary, $b >>); $C -> parse_hd_name(Rest, S, M, P, Q, V, H, << SoFar/binary, $c >>); $D -> parse_hd_name(Rest, S, M, P, Q, V, H, << SoFar/binary, $d >>); $E -> parse_hd_name(Rest, S, M, P, Q, V, H, << SoFar/binary, $e >>); $F -> parse_hd_name(Rest, S, M, P, Q, V, H, << SoFar/binary, $f >>); $G -> parse_hd_name(Rest, S, M, P, Q, V, H, << SoFar/binary, $g >>); $H -> parse_hd_name(Rest, S, M, P, Q, V, H, << SoFar/binary, $h >>); $I -> parse_hd_name(Rest, S, M, P, Q, V, H, << SoFar/binary, $i >>); $J -> parse_hd_name(Rest, S, M, P, Q, V, H, << SoFar/binary, $j >>); $K -> parse_hd_name(Rest, S, M, P, Q, V, H, << SoFar/binary, $k >>); $L -> parse_hd_name(Rest, S, M, P, Q, V, H, << SoFar/binary, $l >>); $M -> parse_hd_name(Rest, S, M, P, Q, V, H, << SoFar/binary, $m >>); $N -> parse_hd_name(Rest, S, M, P, Q, V, H, << SoFar/binary, $n >>); $O -> parse_hd_name(Rest, S, M, P, Q, V, H, << SoFar/binary, $o >>); $P -> parse_hd_name(Rest, S, M, P, Q, V, H, << SoFar/binary, $p >>); $Q -> parse_hd_name(Rest, S, M, P, Q, V, H, << SoFar/binary, $q >>); $R -> parse_hd_name(Rest, S, M, P, Q, V, H, << SoFar/binary, $r >>); $S -> parse_hd_name(Rest, S, M, P, Q, V, H, << SoFar/binary, $s >>); $T -> parse_hd_name(Rest, S, M, P, Q, V, H, << SoFar/binary, $t >>); $U -> parse_hd_name(Rest, S, M, P, Q, V, H, << SoFar/binary, $u >>); $V -> parse_hd_name(Rest, S, M, P, Q, V, H, << SoFar/binary, $v >>); $W -> parse_hd_name(Rest, S, M, P, Q, V, H, << SoFar/binary, $w >>); $X -> parse_hd_name(Rest, S, M, P, Q, V, H, << SoFar/binary, $x >>); $Y -> parse_hd_name(Rest, S, M, P, Q, V, H, << SoFar/binary, $y >>); $Z -> parse_hd_name(Rest, S, M, P, Q, V, H, << SoFar/binary, $z >>); C -> parse_hd_name(Rest, S, M, P, Q, V, H, << SoFar/binary, C >>) end. parse_hd_name_ws(<< C, Rest/bits >>, S, M, P, Q, V, H, Name) -> case C of $\s -> parse_hd_name_ws(Rest, S, M, P, Q, V, H, Name); $\t -> parse_hd_name_ws(Rest, S, M, P, Q, V, H, Name); $: -> parse_hd_before_value(Rest, S, M, P, Q, V, H, Name) end. wait_hd_before_value(Buffer, State=#state{ socket=Socket, transport=Transport, until=Until}, M, P, Q, V, H, N) -> case recv(Socket, Transport, Until) of {ok, Data} -> parse_hd_before_value(<< Buffer/binary, Data/binary >>, State, M, P, Q, V, H, N); {error, timeout} -> error_terminate(408, State); {error, _} -> terminate(State) end. parse_hd_before_value(<< $\s, Rest/bits >>, S, M, P, Q, V, H, N) -> parse_hd_before_value(Rest, S, M, P, Q, V, H, N); parse_hd_before_value(<< $\t, Rest/bits >>, S, M, P, Q, V, H, N) -> parse_hd_before_value(Rest, S, M, P, Q, V, H, N); parse_hd_before_value(Buffer, State=#state{ max_header_value_length=MaxLength}, M, P, Q, V, H, N) -> case match_eol(Buffer, 0) of nomatch when byte_size(Buffer) > MaxLength -> error_terminate(400, State); nomatch -> wait_hd_before_value(Buffer, State, M, P, Q, V, H, N); _ -> parse_hd_value(Buffer, State, M, P, Q, V, H, N, <<>>) end. %% We completely ignore the first argument which is always %% the empty binary. We keep it there because we don't want %% to change the other arguments' position and trigger costy %% operations for no reasons. wait_hd_value(_, State=#state{ socket=Socket, transport=Transport, until=Until}, M, P, Q, V, H, N, SoFar) -> case recv(Socket, Transport, Until) of {ok, Data} -> parse_hd_value(Data, State, M, P, Q, V, H, N, SoFar); {error, timeout} -> error_terminate(408, State); {error, _} -> terminate(State) end. %% Pushing back as much as we could the retrieval of new data %% to check for multilines allows us to avoid a few tests in %% the critical path, but forces us to have a special function. wait_hd_value_nl(_, State=#state{ socket=Socket, transport=Transport, until=Until}, M, P, Q, V, Headers, Name, SoFar) -> case recv(Socket, Transport, Until) of {ok, << C, Data/bits >>} when C =:= $\s; C =:= $\t -> parse_hd_value(Data, State, M, P, Q, V, Headers, Name, SoFar); {ok, Data} -> parse_header(Data, State, M, P, Q, V, [{Name, SoFar}|Headers]); {error, timeout} -> error_terminate(408, State); {error, _} -> terminate(State) end. parse_hd_value(<< $\r, Rest/bits >>, S, M, P, Q, V, Headers, Name, SoFar) -> case Rest of << $\n >> -> wait_hd_value_nl(<<>>, S, M, P, Q, V, Headers, Name, SoFar); << $\n, C, Rest2/bits >> when C =:= $\s; C =:= $\t -> parse_hd_value(Rest2, S, M, P, Q, V, Headers, Name, SoFar); << $\n, Rest2/bits >> -> parse_header(Rest2, S, M, P, Q, V, [{Name, SoFar}|Headers]) end; parse_hd_value(<< C, Rest/bits >>, S, M, P, Q, V, H, N, SoFar) -> parse_hd_value(Rest, S, M, P, Q, V, H, N, << SoFar/binary, C >>); parse_hd_value(<<>>, State=#state{max_header_value_length=MaxLength}, _, _, _, _, _, _, SoFar) when byte_size(SoFar) > MaxLength -> error_terminate(400, State); parse_hd_value(<<>>, S, M, P, Q, V, H, N, SoFar) -> wait_hd_value(<<>>, S, M, P, Q, V, H, N, SoFar). request(B, State=#state{transport=Transport}, M, P, Q, Version, Headers) -> case lists:keyfind(<<"host">>, 1, Headers) of false when Version =:= 'HTTP/1.1' -> error_terminate(400, State); false -> request(B, State, M, P, Q, Version, Headers, <<>>, default_port(Transport:name())); {_, RawHost} -> case catch parse_host(RawHost, <<>>) of {'EXIT', _} -> error_terminate(400, State); {Host, undefined} -> request(B, State, M, P, Q, Version, Headers, Host, default_port(Transport:name())); {Host, Port} -> request(B, State, M, P, Q, Version, Headers, Host, Port) end end. -spec default_port(atom()) -> 80 | 443. default_port(ssl) -> 443; default_port(_) -> 80. %% Another hurtful block of code. :) parse_host(<<>>, Acc) -> {Acc, undefined}; parse_host(<< $:, Rest/bits >>, Acc) -> {Acc, list_to_integer(binary_to_list(Rest))}; parse_host(<< C, Rest/bits >>, Acc) -> case C of $A -> parse_host(Rest, << Acc/binary, $a >>); $B -> parse_host(Rest, << Acc/binary, $b >>); $C -> parse_host(Rest, << Acc/binary, $c >>); $D -> parse_host(Rest, << Acc/binary, $d >>); $E -> parse_host(Rest, << Acc/binary, $e >>); $F -> parse_host(Rest, << Acc/binary, $f >>); $G -> parse_host(Rest, << Acc/binary, $g >>); $H -> parse_host(Rest, << Acc/binary, $h >>); $I -> parse_host(Rest, << Acc/binary, $i >>); $J -> parse_host(Rest, << Acc/binary, $j >>); $K -> parse_host(Rest, << Acc/binary, $k >>); $L -> parse_host(Rest, << Acc/binary, $l >>); $M -> parse_host(Rest, << Acc/binary, $m >>); $N -> parse_host(Rest, << Acc/binary, $n >>); $O -> parse_host(Rest, << Acc/binary, $o >>); $P -> parse_host(Rest, << Acc/binary, $p >>); $Q -> parse_host(Rest, << Acc/binary, $q >>); $R -> parse_host(Rest, << Acc/binary, $r >>); $S -> parse_host(Rest, << Acc/binary, $s >>); $T -> parse_host(Rest, << Acc/binary, $t >>); $U -> parse_host(Rest, << Acc/binary, $u >>); $V -> parse_host(Rest, << Acc/binary, $v >>); $W -> parse_host(Rest, << Acc/binary, $w >>); $X -> parse_host(Rest, << Acc/binary, $x >>); $Y -> parse_host(Rest, << Acc/binary, $y >>); $Z -> parse_host(Rest, << Acc/binary, $z >>); _ -> parse_host(Rest, << Acc/binary, C >>) end. %% End of request parsing. %% %% We create the Req object and start handling the request. request(Buffer, State=#state{socket=Socket, transport=Transport, req_keepalive=ReqKeepalive, max_keepalive=MaxKeepalive, compress=Compress, onresponse=OnResponse}, Method, Path, Query, Version, Headers, Host, Port) -> case Transport:peername(Socket) of {ok, Peer} -> Req = cowboy_req:new(Socket, Transport, Peer, Method, Path, Query, Version, Headers, Host, Port, Buffer, ReqKeepalive < MaxKeepalive, Compress, OnResponse), onrequest(Req, State); {error, _} -> %% Couldn't read the peer address; connection is gone. terminate(State) end. %% Call the global onrequest callback. The callback can send a reply, %% in which case we consider the request handled and move on to the next %% one. Note that since we haven't dispatched yet, we don't know the %% handler, host_info, path_info or bindings yet. -spec onrequest(cowboy_req:req(), #state{}) -> ok. onrequest(Req, State=#state{onrequest=undefined}) -> execute(Req, State); onrequest(Req, State=#state{onrequest=OnRequest}) -> Req2 = OnRequest(Req), case cowboy_req:get(resp_state, Req2) of waiting -> execute(Req2, State); _ -> next_request(Req2, State, ok) end. -spec execute(cowboy_req:req(), #state{}) -> ok. execute(Req, State=#state{middlewares=Middlewares, env=Env}) -> execute(Req, State, Env, Middlewares). -spec execute(cowboy_req:req(), #state{}, cowboy_middleware:env(), [module()]) -> ok. execute(Req, State, Env, []) -> next_request(Req, State, get_value(result, Env, ok)); execute(Req, State, Env, [Middleware|Tail]) -> case Middleware:execute(Req, Env) of {ok, Req2, Env2} -> execute(Req2, State, Env2, Tail); {suspend, Module, Function, Args} -> erlang:hibernate(?MODULE, resume, [State, Env, Tail, Module, Function, Args]); {halt, Req2} -> next_request(Req2, State, ok); {error, Code, Req2} -> error_terminate(Code, Req2, State) end. %% @private -spec resume(#state{}, cowboy_middleware:env(), [module()], module(), module(), [any()]) -> ok. resume(State, Env, Tail, Module, Function, Args) -> case apply(Module, Function, Args) of {ok, Req2, Env2} -> execute(Req2, State, Env2, Tail); {suspend, Module2, Function2, Args2} -> erlang:hibernate(?MODULE, resume, [State, Env, Tail, Module2, Function2, Args2]); {halt, Req2} -> next_request(Req2, State, ok); {error, Code, Req2} -> error_terminate(Code, Req2, State) end. -spec next_request(cowboy_req:req(), #state{}, any()) -> ok. next_request(Req, State=#state{req_keepalive=Keepalive, timeout=Timeout}, HandlerRes) -> cowboy_req:ensure_response(Req, 204), %% If we are going to close the connection, %% we do not want to attempt to skip the body. case cowboy_req:get(connection, Req) of close -> terminate(State); _ -> Buffer = case cowboy_req:skip_body(Req) of {ok, Req2} -> cowboy_req:get(buffer, Req2); _ -> close end, %% Flush the resp_sent message before moving on. receive {cowboy_req, resp_sent} -> ok after 0 -> ok end, if HandlerRes =:= ok, Buffer =/= close -> ?MODULE:parse_request(Buffer, State#state{req_keepalive=Keepalive + 1, until=until(Timeout)}, 0); true -> terminate(State) end end. %% Only send an error reply if there is no resp_sent message. -spec error_terminate(cowboy:http_status(), cowboy_req:req(), #state{}) -> ok. error_terminate(Code, Req, State) -> receive {cowboy_req, resp_sent} -> ok after 0 -> _ = cowboy_req:reply(Code, Req), ok end, terminate(State). %% Only send an error reply if there is no resp_sent message. -spec error_terminate(cowboy:http_status(), #state{}) -> ok. error_terminate(Code, State=#state{socket=Socket, transport=Transport, compress=Compress, onresponse=OnResponse}) -> receive {cowboy_req, resp_sent} -> ok after 0 -> _ = cowboy_req:reply(Code, cowboy_req:new(Socket, Transport, undefined, <<"GET">>, <<>>, <<>>, 'HTTP/1.1', [], <<>>, undefined, <<>>, false, Compress, OnResponse)), ok end, terminate(State). -spec terminate(#state{}) -> ok. terminate(#state{socket=Socket, transport=Transport}) -> Transport:close(Socket), ok.