gen_icmp aspires to be a simple interface for using ICMP and ICMPv6 sockets in Erlang, just like gen_tcp and gen_udp do for their protocol types; incidentally messing up Google searches for whomever someday writes a proper gen_icmp module.
gen_icmp uses procket to get a raw socket and abuses gen_udp for the socket handling. gen_icmp should work on Linux and BSDs.
For a simple example of sending a ping, also see:
https://github.com/msantos/procket/blob/master/src/icmp.erl
open() -> {ok, Socket}
open(SocketOptions) -> {ok, Socket}
open(RawOptions, SocketOptions) -> {ok, Socket}
Types Socket = pid()
RawOptions = [ RawOption ]
RawOption = options()
SocketOptions = SocketOpt
SocketOpt = [ {active, true} | {active, once} |
{active, false} | inet | inet6 ]
By default, the ICMP socket is opened in {active,false} mode. No
packets will be received by the socket. setopts/2 can be used
to place the socket in {active,true} mode.
See the procket README for the raw socket options and for
instructions on setting up the setuid helper.
gen_icmp first attempts to natively open the socket and falls
back to forking the setuid helper program if beam does not have
the appropriate privileges. Privileges to open a raw socket can
be given by, for example, running as root or, on Linux, granting
the CAP_NET_RAW capability to beam:
setcap cap_net_raw=ep /usr/local/lib/erlang/erts-5.8.3/bin/beam.smp
Only the owning process will receive ICMP packets (see
controlling_process/2 to change the owner). The process owning the
raw socket will receive all ICMP packets sent to the host.
Messages sent to the controlling process are:
{icmp, Socket, Address, TTL, Packet}
Where:
* Socket is the pid of the gen_icmp process
* Address is a tuple representing the IPv4 or IPv6 source address
* TTL is the IP TTL
* IPv4: TTL taken from the IP header
* IPv6: the socket's hop limit returned from
getsockopt(IPV6_UNICAST_HOPS) (this is not the packet's
TTL, it is the socket's max TTL)
* Packet is the complete ICMP packet including the ICMP headers
close(Socket) -> ok | {error, Reason}
Types Socket = pid()
Reason = posix()
Close the ICMP socket.
send(Socket, Address, Packet) -> ok | {error, Reason}
Types Socket = pid()
Address = tuple()
Packet = binary()
Reason = not_owner | posix()
Like the gen_udp and gen_tcp modules, any process can send ICMP
packets but only the owner will receive the responses.
recv(Socket, Length) -> {ok, {Address, Packet}} | {error, Reason}
recv(Socket, Length, Timeout) -> {ok, {Address, Packet}} | {error, Reason}
Types Socket = socket()
Length = int()
Address = ip_address()
Packet = [char()] | binary()
Timeout = int() | infinity
Reason = not_owner | posix()
This function receives a packet from a socket in passive mode.
The optional Timeout parameter specifies a timeout in
milliseconds. The default value is infinity.
controlling_process(Socket, Pid) -> ok
Types Socket = pid()
Pid = pid()
Change the process owning the socket. Allows another process to
receive the ICMP responses.
setopts(Socket, Options) ->
Types Socket = pid()
Options = list()
For options, see the inet man page. Simply calls inet:setopts/2
on the gen_udp socket.
setopts/2 can be used to toggle the socket between passive and
active mode:
{ok, Socket} = gen_icmp:open(), % socket is {active,false}
ok = gen_icmp:setopts(Socket, [{active, true}]),
% do stuff with the socket
ok = gen_icmp:setopts(Socket, [{active, false}]).
ping(Host) -> Responses
ping(Host, Options) -> Responses
ping(Socket, Hosts, Options) -> Responses
Types Socket = pid()
Host = Address | Hostname | Hosts
Address = ReplyAddr = tuple()
Hostname = string()
Hosts = [ tuple() | string() ]
Options = [ Option ]
Option = {id, Id} | {sequence, Sequence} | {timeout, Timeout} | {data, Data} |
{timestamp, boolean()} | {ttl, TTL} | {filter, Filter} | inet | inet6
Id = uint16()
Sequence = uint16()
Timeout = non_neg_integer() | infinity
TTL = uint8()
Data = binary()
Filter = binary()
Responses = [ Response ]
Response = {ok, Host, Address, ReplyAddr, Details, Payload}
| {error, ICMPError, Host, Address, ReplyAddr, Details, Payload}
| {error, Error, Host, Address}
Details = {Id, Sequence, TTL, Elapsed}
Elapsed = int() | undefined
Payload = binary()
ICMPError = unreach_host | timxceed_intrans
Error = timeout | inet:posix()
ping/1 is a convenience function to send a single ping
packet. The argument to ping/1 can be either a hostname or a
list of hostnames.
To prevent the process mailbox from being flooded with ICMP
messages, ping/3 will put the socket into {active,false} mode
after completing.
The ping/3 function blocks until either an ICMP ECHO REPLY is
received from all hosts or Timeout is reached.
Id and sequence are used to differentiate ping responses. Usually,
the sequence is incremented for each ping in one run.
A list of responses is returned. If the ping was successful,
the elapsed time in milliseconds is included (calculated by
subtracting the current time from the time we sent in the ICMP
ECHO packet and returned to us in the ICMP ECHOREPLY payload)
where:
Host: the provided hostname
Address: the resolved IPv4 or IPv6 network address represented
as a 4 or 8-tuple used in the ICMP echo request
ReplyAddr: the IPv4 or IPv6 network address originating the
ICMP echo reply
The timeout is set for all ICMP packets and is set after all
packets have been sent out.
ping/1 and ping/2 open and close an ICMP socket for the user. For
best performance, ping/3 should be used instead, with the socket
being maintained between runs.
By default only one address per hostname is pinged. To
enable pinging all addresses per hostname pass {multi, true}
to options.
A ping payload contains an 8 byte timestamp in microseconds. When
creating a custom payload, the first 8 bytes of the ICMP echo
reply payload will be used for calculating the elapsed time. To
disable this behaviour, use the option {timestamp,false} (the
elapsed time in the return value will be set to 0).
The timeout defaults to 5 seconds.
ICMPv6 sockets can restrict which ICMPv6 types are received by the
socket using the filter option. The filter argument is a binary
generated using the icmp6_filter functions described below.
The default filter allows: ICMP6_ECHO_REPLY, ICMP6_DST_UNREACH,
ICMP6_PACKET_TOO_BIG, ICMP6_TIME_EXCEEDED and ICMP6_PARAM_PROB.
Note: ping/3 does not restore the original filter on the socket.
echo(Id, Sequence) -> Packet
Types Id = uint16()
Sequence = uint16()
Packet = binary()
Creates an ICMP echo packet with an 8 byte timestamp and a
payload consisting of ASCII 32 to 79.
echo(Id, Sequence, Payload) -> Packet
Types Id = uint16()
Sequence = uint16()
Payload = binary()
Packet = binary()
Creates an ICMP echo packet with the results of erlang:now() used
as the timestamp and a user specified payload (which should pad the
packet to 64 bytes).
packet(Header, Payload) -> Packet
Types Header = [ #icmp{} | Options ]
Options = [ Opts ]
Opts = [{type, Type} | {code, Code} | {id, Id} | {sequence, Sequence} |
{gateway, Gateway} | {mtu, MTU} | {pointer, Pointer} |
{ts_orig, TS_orig} | {ts_recv, TS_recv} | {ts_tx, TS_tx} ]
Type = uint8() | ICMP_type
Code = uint8() | ICMP_code
ICMP_type = echoreply | dest_unreach | source_quench | redirect | echo |
time_exceeded | parameterprob | timestamp | timestampreply | info_request |
info_reply | address | addressreply
ICMP_code = unreach_net | unreach_host | unreach_protocol | unreach_port |
unreach_needfrag | unreach_srcfail | redirect_net | redirect_host |
redirect_tosnet | redirect_toshost | timxceed_intrans | timxceed_reass
Id = uint16()
Sequence = uint16()
Payload = binary()
Packet = binary()
Convenience function for creating arbitrary ICMP packets. This
function will calculate the ICMP checksum and insert it into the
packet.
filter(Socket) -> {ok, Filter} | unsupported
filter(Socket, Filter) -> ok | unsupported
Types Socket = pid()
Filter = binary()
Sets or retrieves an ICMPv6 filter on a socket. For ICMPv4
sockets, the atom 'unsupported' is returned.
Filters can be generated by using the icmp6_filter functions.
icmp6_filter_setblockall() -> binary()
icmp6_filter_setpassall() -> binary()
icmp6_filter_setpass(Type, Filter) -> binary()
icmp6_filter_setblock(Type, Filter) -> binary()
icmp6_filter_willpass(Type, Filter) -> true | false
icmp6_filter_willblock(Type, Filter) -> true | false
Types Type = icmp_type()
Filter = binary()
Generate a ICMPv6 filter that can be set on a socket using
filter/2.
For example, to generate a filter that allowed only
ICMP6_ECHO_REPLY messages:
{ok, Socket} = gen_icmp:open([inet6]),
Filter = gen_icmp:icmp6_filter_setpass(echo_reply,
gen_icmp:icmp6_filter_setblockall()),
ok = gen_icmp:filter(Socket, Filter).
tracert is an Erlang traceroute implementation built using gen_icmp.
host(Host) -> Path
host(Host, Options) -> Path
host(Socket, Host, Options) -> Path
Types Socket = pid()
Host = Address | Hostname
Address = tuple()
Hostname = string()
Options = [ Option ]
Option = {protocol, Protocol}
| {max_hops, uint()}
| {timeout, uint()}
| {setuid, bool()}
| {saddr, Address}
| {sport, uint16()}
Protocol = icmp | udp
Path = [ {Address, MicroSeconds, {Protocol, binary()}
| timeout ]
Perform a traceroute to a destination. ICMP and UDP probes are
supported. ICMP probes are the default.
max_hops is the maximum TTL (default: 30)
Set the time in milliseconds to wait for a response using the
timeout option (default: 1000 ms). WARNING: if the response
arrives after the timeout, tracert will insert spurious entries
into the path.
tracert will not spawn the setuid helper if the {setuid, false}
option is used. In this case, beam must either be running as
root or have the cap_net_raw privileges under Linux.
The {sport, Port} option sets the initial source port for UDP
probes. The port will be incremented by 1 for each subsequent
probe (default: random high port). For ICMP probes, the ICMP
ID field will be set to this value.
The return value is an ordered list of tuples:
Address: the source address responding to the probe
MicroSeconds: time elapsed between the probe and receiving
the response
Protocol: icmp or udp
Protocol data: a binary representing the received packet
contents
path(Path) -> Reasons
Types Path = [ {Address, MicroSeconds, {Protocol, binary()} ]
Reasons = [ {Address, MicroSeconds, Reason} ]
Reason = ICMP | UDP | timeout
ICMP = timxceed_intrans | echo_reply | ...
UDP = unreach_port | ...
Convert the list of binaries returned by host/1,2,3 to atoms
representing the ICMP response codes and UDP errors.
rebar3 do clean, compile, ct
Also see the README for procket for additional setup (the procket executable needs superuser privileges).
1> gen_icmp:ping("www.google.com").
[{ok,"www.google.com",
{173,194,64,99},
{173,194,64,99},
18411,0,50,
<<" !\"#$%&'()*+,-./0123456789:;<=>?@ABCDEFGHIJKLMNO">>}]
2> gen_icmp:ping(["www.google.com", {192,168,213,4}, "193.180.168.20", {192,0,32,10}]).
[{error,timeout,"193.180.168.20",{193,180,168,20}},
{error,unreach_host,
{192,168,213,4},
{192,168,213,4},
{192,168,213,54},
{18411,2,undefined},
<<69,0,0,84,0,0,64,0,64,1,15,29,192,168,213,54,192,168,
213,4,...>>},
{ok,{192,0,32,10},
{192,0,32,10},
{192,0,32,10},
{18411,1,103},
<<" !\"#$%&'()*+,-./0123456789:;<=>?@ABCDEFGHIJKLMNO">>},
{ok,"www.google.com",
{173,194,77,99},
{173,194,77,99},
{18411,0,50},
<<" !\"#$%&'()*+,-./0123456789:;<=>?@ABCDEFGHIJKLMNO">>}]
1> gen_icmp:ping("google.com", [inet6]).
[{ok,"google.com",
{9735,63664,16395,2054,0,0,0,4098},
{9735,63664,16395,2054,0,0,0,4098},
{18411,0,64,62},
<<" !\"#$%&'()*+,-./0123456789:;<=>?@ABCDEFGHIJKLMNO">>}]
2> tracert:host("google.com", [inet6]).
Keeping the ICMP socket around between runs is more efficient:
{ok, Socket} = gen_icmp:open(),
P1 = gen_icmp:ping(Socket, [{10,1,1,1}, "www.google.com"], []),
P2 = gen_icmp:ping(Socket, [{10,2,2,2}, "www.yahoo.com"], []),
gen_icmp:close(Socket).
{ok, Socket} = gen_icmp:open().
% By default, the ICMP socket is in passive mode
ok = gen_icmp:setopts(Socket, [{active, true}]),
% ICMP host unreachable, empty payload (should contain an IPv4 header
% and the first 8 bytes of the packet data)
Packet = gen_icmp:packet([{type, 3}, {code, 0}], <<0:160, 0:64>>).
gen_icmp:send(Socket, {127,0,0,1}, Packet),
% Put the socket back into passive mode
ok = gen_icmp:setopts(Socket, [{active, false}]).
ptun is an example of using gen_icmp to tunnel TCP over ICMP.
To compile ptun:
make eg
Host1 (1.1.1.1) listens for TCP on port 8787 and forwards the data over ICMP:
erl -noshell -pa ebin deps/*/ebin -eval 'ptun:server({2,2,2,2},8787)' -s erlang halt
Host2 (2.2.2.2) receives ICMP echo requests and opens a TCP connection to 127.0.0.1:22:
erl -noshell -pa ebin deps/*/ebin -eval 'ptun:client({1,1,1,1},22)' -s erlang halt
To use the proxy on host1:
ssh -p 8787 127.0.0.1
-
ICMP traceroute
1> Path = tracert:host({8,8,8,8}). [{{216,239,46,191}, 36149, {icmp,<<11,0,111,150,0,0,0,0,69,128,0,84,0,0,64,...>>}}, {{216,239,47,189}, 51459, {icmp,<<11,0,111,150,0,0,0,0,69,128,0,84,0,0,...>>}}, {{8,8,8,8}, 34946, {icmp,<<0,0,170,0,219,104,0,0,32,33,34,35,36,...>>}}] 2> tracert:path(Path). [{{216,239,46,191},62815,timxceed_intrans}, {{216,239,47,189},44244,timxceed_intrans}, {{8,8,8,8},34825,echoreply}]
-
UDP traceroute
1> Path = tracert:host({8,8,8,8}, [{protocol, udp}]).
-
IPv6 traceroute
1> Path = tracert:host("google.com", [inet6]).
-
tests: do not depend on list order
-
handle rfc 4884 (Extended ICMP to Support Multi-Part Messages)
-
handle ICMP router renumbering messages
-
IPv6: handle socket ancillary data (RFC 3542)
- retrieve the packet TTL rather than using the IPV6_UNICAST_HOPS