NAME
ping6
—
send ICMPv6 ECHO_REQUEST packets to
network hosts
SYNOPSIS
ping6 |
[-DdfHmnNoqrRtvwW ]
[-a addrtype]
[-b bufsiz]
[-c count]
[-g gateway]
[-h hoplimit]
[-I interface]
[-i wait]
[-x waittime]
[-X timeout]
[-l preload]
[-P policy]
[-p pattern]
[-S sourceaddr]
[-s packetsize]
[hops ...] host |
DESCRIPTION
The ping6
utility uses the ICMPv6
protocol's mandatory ICMP6_ECHO_REQUEST datagram to elicit an
ICMP6_ECHO_REPLY from a host or gateway. ICMP6_ECHO_REQUEST datagrams
(``pings'') have an IPv6 header, and ICMPv6 header formatted as documented
in RFC2463. The options are as follows:
-a
addrtype- Generate ICMPv6 Node Information Node Addresses query, rather than
echo-request. addrtype must be a string constructed
of the following characters.
a
- requests unicast addresses from all of the responder's interfaces. If the character is omitted, only those addresses which belong to the interface which has the responder's address are requests.
c
- requests responder's IPv4-compatible and IPv4-mapped addresses.
g
- requests responder's global-scope addresses.
s
- requests responder's site-local addresses.
l
- requests responder's link-local addresses.
A
- requests responder's anycast addresses. Without this character, the responder will return unicast addresses only. With this character, the responder will return anycast addresses only. Note that the specification does not specify how to get responder's anycast addresses. This is an experimental option.
-b
bufsiz- Set socket buffer size.
-c
count- Stop after sending (and receiving) count ECHO_RESPONSE packets.
-D
- Disable IPv6 fragmentation.
-d
- Set the
SO_DEBUG
option on the socket being used. -f
- Flood ping. Outputs packets as fast as they come back or one hundred times
per second, whichever is more. For every ECHO_REQUEST sent a period
“.” is printed, while for every ECHO_REPLY received a
backspace is printed. This provides a rapid display of how many packets
are being dropped. Only the super-user may use this option.
This can be very hard on a network and should be used with caution.
-g
gateway- Specifies to use gateway as the next hop to the destination. The gateway must be a neighbor of the sending node.
-H
- Specifies to try reverse-lookup of IPv6 addresses. The
ping6
utility does not try reverse-lookup unless the option is specified. -h
hoplimit- Set the IPv6 hoplimit.
-I
interface- Source packets with the given interface address. This flag applies if the ping destination is a multicast address, or link-local/site-local unicast address.
-i
wait- Wait wait seconds
between
sending each packet. The default is to wait for one second between
each packet. This option is incompatible with the
-f
option. -x
waittime- Time in milliseconds to wait for a reply for each packet sent. If a reply arrives later, the packet is not printed as replied, but considered as replied when calculating statistics.
-X
timeout- Specify a timeout, in seconds, before ping exits regardless of how many packets have been received.
-l
preload- If preload is specified,
ping6
sends that many packets as fast as possible before falling into its normal mode of behavior. Only the super-user may use this option. -m
- By default,
ping6
asks the kernel to fragment packets to fit into the minimum IPv6 MTU. The-m
option will suppress the behavior in the following two levels: when the option is specified once, the behavior will be disabled for unicast packets. When the option is more than once, it will be disabled for both unicast and multicast packets. -n
- Numeric output only. No attempt will be made to lookup symbolic names from addresses in the reply.
-N
- Probe node information multicast group address
(
ff02::2:ffxx:xxxx
). host must be string hostname of the target (must not be a numeric IPv6 address). Node information multicast group will be computed based on given host, and will be used as the final destination. Since node information multicast group is a link-local multicast group, outgoing interface needs to be specified by-I
option.When specified twice, the address (
ff02::2:xxxx:xxxx
) is used instead. The former is in RFC 4620, the latter is in an old Internet Draft draft-ietf-ipngwg-icmp-name-lookup. Note that KAME-derived implementations including FreeBSD use the latter. -o
- Exit successfully after receiving one reply packet.
-p
pattern- You may specify up to 16 “pad” bytes to fill out the packet
you send. This is useful for diagnosing data-dependent problems in a
network. For example, “
-p ff
” will cause the sent packet to be filled with all ones. -P
policy- policy specifies IPsec policy to be used for the probe.
-q
- Quiet output. Nothing is displayed except the summary lines at startup time and when finished.
-r
- Audible. Include a bell (ASCII 0x07) character in the output when any packet is received.
-R
- Audible. Output a bell (ASCII 0x07) character when no packet is received before the next packet is transmitted. To cater for round-trip times that are longer than the interval between transmissions, further missing packets cause a bell only if the maximum number of unreceived packets has increased.
-S
sourceaddr- Specifies the source address of request packets. The source address must be one of the unicast addresses of the sending node, and must be numeric.
-s
packetsize- Specifies the number of data bytes to be sent. The default is 56, which
translates into 64 ICMP data bytes when combined with the 8 bytes of ICMP
header data. You may need to specify
-b
as well to extend socket buffer size. -t
- Generate ICMPv6 Node Information supported query types query, rather than
echo-request.
-s
has no effect if-t
is specified. -v
- Verbose output. ICMP packets other than ECHO_RESPONSE that are received are listed.
-w
- Generate ICMPv6 Node Information DNS Name query, rather than echo-request.
-s
has no effect if-w
is specified. -W
- Same as
-w
, but with old packet format based on 03 draft. This option is present for backward compatibility.-s
has no effect if-w
is specified. - hops
- IPv6 addresses for intermediate nodes, which will be put into type 0 routing header.
- host
- IPv6 address of the final destination node.
When using ping6
for fault isolation, it
should first be run on the local host, to verify that the local network
interface is up and running. Then, hosts and gateways further and further
away should be “pinged”. Round-trip times and packet loss
statistics are computed. If duplicate packets are received, they are not
included in the packet loss calculation, although the round trip time of
these packets is used in calculating the round-trip time statistics. When
the specified number of packets have been sent (and received) or if the
program is terminated with a SIGINT
, a brief summary
is displayed, showing the number of packets sent and received, and the
minimum, mean, maximum, and standard deviation of the round-trip times.
If ping6
receives a
SIGINFO
(see the status
argument for stty(1)) signal, the current number of packets sent and
received, and the minimum, mean, maximum, and standard deviation of the
round-trip times will be written to the standard output in the same format
as the standard completion message.
This program is intended for use in network testing, measurement
and management. Because of the load it can impose on the network, it is
unwise to use ping6
during normal operations or from
automated scripts.
DUPLICATE AND DAMAGED PACKETS
The ping6
utility will report duplicate
and damaged packets. Duplicate packets should never occur when pinging a
unicast address, and seem to be caused by inappropriate link-level
retransmissions. Duplicates may occur in many situations and are rarely (if
ever) a good sign, although the presence of low levels of duplicates may not
always be cause for alarm. Duplicates are expected when pinging a broadcast
or multicast address, since they are not really duplicates but replies from
different hosts to the same request.
Damaged packets are obviously serious cause for alarm and often
indicate broken hardware somewhere in the ping6
packet's path (in the network or in the hosts).
TRYING DIFFERENT DATA PATTERNS
The (inter)network layer should never treat packets differently depending on the data contained in the data portion. Unfortunately, data-dependent problems have been known to sneak into networks and remain undetected for long periods of time. In many cases the particular pattern that will have problems is something that does not have sufficient “transitions”, such as all ones or all zeros, or a pattern right at the edge, such as almost all zeros. It is not necessarily enough to specify a data pattern of all zeros (for example) on the command line because the pattern that is of interest is at the data link level, and the relationship between what you type and what the controllers transmit can be complicated.
This means that if you have a data-dependent problem you will
probably have to do a lot of testing to find it. If you are lucky, you may
manage to find a file that either cannot be sent across your network or that
takes much longer to transfer than other similar length files. You can then
examine this file for repeated patterns that you can test using the
-p
option of ping6
.
EXIT STATUS
The ping6
utility returns 0 on success
(the host is alive), 2 if the transmission was successful but no responses
were received, any other non-zero value if the arguments are incorrect or
another error has occurred.
EXAMPLES
Normally, ping6
works just like
ping(8) would work; the following will send ICMPv6 echo request to
dst.foo.com
.
ping6 -n dst.foo.com
The following will probe hostnames for all nodes on the network
link attached to wi0
interface. The address
ff02::1
is named the link-local all-node multicast
address, and the packet would reach every node on the network link.
ping6 -w ff02::1%wi0
The following will probe addresses assigned to the destination
node, dst.foo.com
.
ping6 -a agl dst.foo.com
SEE ALSO
netstat(1), icmp6(4), inet6(4), ip6(4), ifconfig(8), ping(8), routed(8), traceroute(8), traceroute6(8)
A. Conta and S. Deering, Internet Control Message Protocol (ICMPv6) for the Internet Protocol Version 6 (IPv6) Specification, RFC2463, December 1998.
Matt Crawford, IPv6 Node Information Queries, draft-ietf-ipngwg-icmp-name-lookups-09.txt, May 2002, work in progress material.
HISTORY
The ping(8) utility appeared in 4.3BSD.
The ping6
utility with IPv6 support first appeared
in the WIDE Hydrangea IPv6 protocol stack kit.
IPv6 and IPsec support based on the KAME Project (http://www.kame.net/) stack was initially integrated into FreeBSD 4.0.
BUGS
The ping6
utility is intentionally
separate from ping(8).
There have been many discussions on why we separate
ping6
and
ping(8). Some people argued that it would be more convenient to
uniform the ping command for both IPv4 and IPv6. The followings are an
answer to the request.
From a developer's point of view: since the underling raw sockets API is totally different between IPv4 and IPv6, we would end up having two types of code base. There would actually be less benefit to uniform the two commands into a single command from the developer's standpoint.
From an operator's point of view: unlike ordinary network
applications like remote login tools, we are usually aware of address family
when using network management tools. We do not just want to know the
reachability to the host, but want to know the reachability to the host via
a particular network protocol such as IPv6. Thus, even if we had a unified
ping(8) command for both IPv4 and IPv6, we would usually type a
-6
or -4
option (or
something like those) to specify the particular address family. This
essentially means that we have two different commands.