package dns-resolver
DNS resolver business logic
Install
Dune Dependency
Authors
Maintainers
Sources
dns-10.1.0.tbz
sha256=5c6fea514cec39c732e71764643e8fb9588dee038c991c184accbed3b41e37d2
sha512=58f74749cdc7c5d6adb059821dca42d2a20ae05dd989c93afddbd37806c748cb2709a51f2c7880e79d1bf99384639aa40c4a540047cb27da6ed609ca8eeb6eca
doc/src/dns-resolver.mirage/dns_resolver_mirage.ml.html
Source file dns_resolver_mirage.ml
1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 20 21 22 23 24 25 26 27 28 29 30 31 32 33 34 35 36 37 38 39 40 41 42 43 44 45 46 47 48 49 50 51 52 53 54 55 56 57 58 59 60 61 62 63 64 65 66 67 68 69 70 71 72 73 74 75 76 77 78 79 80 81 82 83 84 85 86 87 88 89 90 91 92 93 94 95 96 97 98 99 100 101 102 103 104 105 106 107 108 109 110 111 112 113 114 115 116 117 118 119 120 121 122 123 124 125 126 127 128 129 130 131 132 133 134 135 136 137 138 139 140 141 142 143 144 145 146 147 148 149 150 151 152 153 154 155 156 157 158 159 160 161 162 163 164 165 166 167 168 169 170 171 172 173 174 175 176 177 178 179 180 181 182 183 184 185 186 187 188 189 190 191 192 193 194 195 196 197 198 199 200 201 202 203 204 205 206 207 208 209 210 211 212 213 214 215 216 217 218 219 220 221 222 223 224 225 226 227 228 229 230 231 232 233 234 235 236 237 238 239 240 241 242 243 244 245 246 247 248 249 250 251 252 253 254 255 256 257 258 259 260 261 262 263 264 265 266 267 268 269 270 271 272 273 274 275 276 277 278 279 280 281 282 283(* (c) 2018 Hannes Mehnert, all rights reserved *) open Lwt.Infix let src = Logs.Src.create "dns_resolver_mirage" ~doc:"effectful DNS resolver" module Log = (val Logs.src_log src : Logs.LOG) module Make (S : Tcpip.Stack.V4V6) = struct module Dns = Dns_mirage.Make(S) module T = S.TCP module TLS = Tls_mirage.Make(T) type t = (Ipaddr.t * int * string * (int32 * string) Lwt.u) option -> unit type tls_flow = { tls_flow : TLS.flow ; mutable linger : Cstruct.t } module FM = Map.Make(struct type t = Ipaddr.t * int let compare (ip, p) (ip', p') = match Ipaddr.compare ip ip' with | 0 -> compare p p' | x -> x end) let resolver stack ?(root = false) ?(timer = 500) ?(udp = true) ?(tcp = true) ?tls ?(port = 53) ?(tls_port = 853) t = let server_port = 53 in let state = ref t in (* according to RFC5452 4.5, we can chose source port between 1024-49152 *) let sport () = 1024 + Randomconv.int ~bound:48128 Mirage_crypto_rng.generate in let tcp_in = ref FM.empty in let ocaml_in = ref FM.empty in let tcp_out = ref Ipaddr.Map.empty in let stream, push = Lwt_stream.create () in let send_tls flow data = let len = Cstruct.create 2 in Cstruct.BE.set_uint16 len 0 (Cstruct.length data); TLS.writev flow [len; data] >>= function | Ok () -> Lwt.return (Ok ()) | Error e -> Log.err (fun m -> m "tls error %a while writing" TLS.pp_write_error e); TLS.close flow >|= fun () -> Error () in let rec client_out dst port = T.create_connection (S.tcp stack) (dst, port) >|= function | Error e -> (* do i need to report this back into the resolver? what are their options then? *) Log.err (fun m -> m "error %a while establishing tcp connection to %a:%d" T.pp_error e Ipaddr.pp dst port) ; Error () | Ok flow -> Log.debug (fun m -> m "established new outgoing TCP connection to %a:%d" Ipaddr.pp dst port); tcp_out := Ipaddr.Map.add dst flow !tcp_out ; Lwt.async (fun () -> let f = Dns.of_flow flow in let rec loop () = Dns.read_tcp f >>= function | Error () -> Log.debug (fun m -> m "removing %a from tcp_out" Ipaddr.pp dst) ; tcp_out := Ipaddr.Map.remove dst !tcp_out ; Lwt.return_unit | Ok data -> let now = Mirage_ptime.now () in let ts = Mirage_mtime.elapsed_ns () in let new_state, answers, queries = let data = Cstruct.to_string data in Dns_resolver.handle_buf !state now ts false `Tcp dst port data in state := new_state ; Lwt_list.iter_p handle_answer answers >>= fun () -> Lwt_list.iter_p handle_query queries >>= fun () -> loop () in loop ()) ; Ok () and client_tcp dst port data = match Ipaddr.Map.find_opt dst !tcp_out with | None -> begin client_out dst port >>= function | Error () -> let sport = sport () in S.UDP.listen (S.udp stack) ~port:sport (udp_cb sport false) ; Dns.send_udp stack sport dst port (Cstruct.of_string data) | Ok () -> client_tcp dst port data end | Some x -> Dns.send_tcp x (Cstruct.of_string data) >>= function | Ok () -> Lwt.return_unit | Error () -> tcp_out := Ipaddr.Map.remove dst !tcp_out ; client_tcp dst port data and maybe_tcp dst port data = (match Ipaddr.Map.find_opt dst !tcp_out with | Some flow -> Dns.send_tcp flow (Cstruct.of_string data) | None -> Lwt.return (Error ())) >>= function | Ok () -> Lwt.return_unit | Error () -> let sport = sport () in S.UDP.listen (S.udp stack) ~port:sport (udp_cb sport false) ; Dns.send_udp stack sport dst port (Cstruct.of_string data) and handle_query (proto, dst, data) = match proto with | `Udp -> maybe_tcp dst server_port data | `Tcp -> client_tcp dst server_port data and handle_answer (proto, dst, dst_port, ttl, data) = match proto with | `Udp -> Dns.send_udp stack port dst dst_port (Cstruct.of_string data) | `Tcp -> let from_tcp = FM.find_opt (dst, dst_port) !tcp_in in let from_ocaml = FM.find_opt (dst, dst_port) !ocaml_in in match from_tcp, from_ocaml with | None, None -> Log.err (fun m -> m "wanted to answer %a:%d via TCP, but couldn't find a flow" Ipaddr.pp dst dst_port) ; Lwt.return_unit | Some (`Tcp flow), None -> (Dns.send_tcp flow (Cstruct.of_string data) >|= function | Ok () -> () | Error () -> tcp_in := FM.remove (dst, dst_port) !tcp_in) | Some (`Tls flow), None -> (send_tls flow (Cstruct.of_string data) >|= function | Ok () -> () | Error () -> tcp_in := FM.remove (dst, dst_port) !tcp_in) | None, Some wk -> begin ocaml_in := FM.remove (dst, dst_port) !ocaml_in; Lwt.wakeup wk (ttl, data); Lwt.return_unit end | Some _, Some _ -> assert false and udp_cb lport req ~src ~dst:_ ~src_port buf = let buf = Cstruct.to_string buf in let now = Mirage_ptime.now () and ts = Mirage_mtime.elapsed_ns () in let new_state, answers, queries = Dns_resolver.handle_buf !state now ts req `Udp src src_port buf in if not req then S.UDP.unlisten (S.udp stack) ~port:lport; state := new_state ; Lwt_list.iter_p handle_answer answers >>= fun () -> Lwt_list.iter_p handle_query queries in if udp then begin S.UDP.listen (S.udp stack) ~port (udp_cb port true); Log.info (fun f -> f "DNS resolver listening on UDP port %d" port); end; let rec ocaml_cb () = Lwt_stream.get stream >>= function | Some (dst_ip, dst_port, data, wk) -> ocaml_in := FM.add (dst_ip, dst_port) wk !ocaml_in; let now = Mirage_ptime.now () in let ts = Mirage_mtime.elapsed_ns () in let new_state, answers, queries = Dns_resolver.handle_buf !state now ts true `Tcp dst_ip dst_port data in state := new_state ; Lwt_list.iter_p handle_answer answers >>= fun () -> Lwt_list.iter_p handle_query queries >>= fun () -> ocaml_cb () | None -> Lwt.return_unit in Lwt.async ocaml_cb; let tcp_cb query flow = let dst_ip, dst_port = T.dst flow in Log.debug (fun m -> m "tcp connection from %a:%d" Ipaddr.pp dst_ip dst_port) ; tcp_in := FM.add (dst_ip, dst_port) (`Tcp flow) !tcp_in ; let f = Dns.of_flow flow in let rec loop () = Dns.read_tcp f >>= function | Error () -> tcp_in := FM.remove (dst_ip, dst_port) !tcp_in ; Lwt.return_unit | Ok data -> let data = Cstruct.to_string data in let now = Mirage_ptime.now () in let ts = Mirage_mtime.elapsed_ns () in let new_state, answers, queries = Dns_resolver.handle_buf !state now ts query `Tcp dst_ip dst_port data in state := new_state ; Lwt_list.iter_p handle_answer answers >>= fun () -> Lwt_list.iter_p handle_query queries >>= fun () -> loop () in loop () in if tcp then begin S.TCP.listen (S.tcp stack) ~port (tcp_cb true); Log.info (fun m -> m "DNS resolver listening on TCP port %d" port); end; let rec read_tls ({ tls_flow ; linger } as f) length = if Cstruct.length linger >= length then let a, b = Cstruct.split linger length in f.linger <- b; Lwt.return (Ok a) else TLS.read tls_flow >>= function | Ok `Eof -> Log.debug (fun m -> m "end of file while reading"); TLS.close tls_flow >|= fun () -> Error () | Error e -> Log.warn (fun m -> m "error reading TLS: %a" TLS.pp_error e); TLS.close tls_flow >|= fun () -> Error () | Ok (`Data d) -> f.linger <- Cstruct.append linger d; read_tls f length in let read_tls_packet f = read_tls f 2 >>= function | Error () -> Lwt.return (Error ()) | Ok k -> let len = Cstruct.BE.get_uint16 k 0 in read_tls f len in let tls_cb cfg flow = let dst_ip, dst_port = T.dst flow in TLS.server_of_flow cfg flow >>= function | Error e -> Log.warn (fun m -> m "TLS error (from %a:%d): %a" Ipaddr.pp dst_ip dst_port TLS.pp_write_error e); Lwt.return_unit | Ok tls -> Log.debug (fun m -> m "tls connection from %a:%d" Ipaddr.pp dst_ip dst_port); tcp_in := FM.add (dst_ip, dst_port) (`Tls tls) !tcp_in ; let tls_and_linger = { tls_flow = tls ; linger = Cstruct.empty } in let rec loop () = read_tls_packet tls_and_linger >>= function | Error () -> tcp_in := FM.remove (dst_ip, dst_port) !tcp_in ; Lwt.return_unit | Ok data -> let data = Cstruct.to_string data in let now = Mirage_ptime.now () in let ts = Mirage_mtime.elapsed_ns () in let new_state, answers, queries = Dns_resolver.handle_buf !state now ts true `Tcp dst_ip dst_port data in state := new_state ; Lwt_list.iter_p handle_answer answers >>= fun () -> Lwt_list.iter_p handle_query queries >>= fun () -> loop () in loop () in (match tls with | None -> () | Some cfg -> S.TCP.listen (S.tcp stack) ~port:tls_port (tls_cb cfg); Log.info (fun m -> m "DNS resolver listening on TLS port %d" tls_port)); let rec time () = let new_state, answers, queries = Dns_resolver.timer !state (Mirage_mtime.elapsed_ns ()) in state := new_state ; Lwt_list.iter_p handle_answer answers >>= fun () -> Lwt_list.iter_p handle_query queries >>= fun () -> Mirage_sleep.ns (Duration.of_ms timer) >>= fun () -> time () in Lwt.async time ; if root then begin let rec root () = let new_state, q = Dns_resolver.query_root !state (Mirage_mtime.elapsed_ns ()) `Tcp in state := new_state ; handle_query q >>= fun () -> Mirage_sleep.ns (Duration.of_day 6) >>= fun () -> root () in Lwt.async root end ; push let resolve_external push (dst_ip, dst_port) data = let th, wk = Lwt.wait () in push (Some (dst_ip, dst_port, data, wk)); th end