From 80cc49507ba48f85929f499734e4dbe2d50ecdf8 Mon Sep 17 00:00:00 2001 From: yupeng Date: Fri, 16 Nov 2018 11:17:40 -0800 Subject: [PATCH] net: Add part of TCP counts explanations in snmp_counters.rst Add explanations of some generic TCP counters, fast open related counters and TCP abort related counters and several examples. Signed-off-by: yupeng Signed-off-by: David S. Miller --- Documentation/networking/snmp_counter.rst | 525 +++++++++++++++++++++++++++++- 1 file changed, 524 insertions(+), 1 deletion(-) diff --git a/Documentation/networking/snmp_counter.rst b/Documentation/networking/snmp_counter.rst index e0d588f..a262d32 100644 --- a/Documentation/networking/snmp_counter.rst +++ b/Documentation/networking/snmp_counter.rst @@ -40,7 +40,7 @@ multicast packets, and would always be updated together with IpExtOutOctets. * IpExtInOctets and IpExtOutOctets -They are linux kernel extensions, no RFC definitions. Please note, +They are Linux kernel extensions, no RFC definitions. Please note, RFC1213 indeed defines ifInOctets and ifOutOctets, but they are different things. The ifInOctets and ifOutOctets include the MAC layer header size but IpExtInOctets and IpExtOutOctets don't, they @@ -174,6 +174,163 @@ IcmpMsgOutType[N]. If the errors occur in both step (2) and step (4), IcmpInMsgs should be less than the sum of IcmpMsgOutType[N] plus IcmpInErrors. +General TCP counters +================== +* TcpInSegs +Defined in `RFC1213 tcpInSegs`_ + +.. _RFC1213 tcpInSegs: https://tools.ietf.org/html/rfc1213#page-48 + +The number of packets received by the TCP layer. As mentioned in +RFC1213, it includes the packets received in error, such as checksum +error, invalid TCP header and so on. Only one error won't be included: +if the layer 2 destination address is not the NIC's layer 2 +address. It might happen if the packet is a multicast or broadcast +packet, or the NIC is in promiscuous mode. In these situations, the +packets would be delivered to the TCP layer, but the TCP layer will discard +these packets before increasing TcpInSegs. The TcpInSegs counter +isn't aware of GRO. So if two packets are merged by GRO, the TcpInSegs +counter would only increase 1. + +* TcpOutSegs +Defined in `RFC1213 tcpOutSegs`_ + +.. _RFC1213 tcpOutSegs: https://tools.ietf.org/html/rfc1213#page-48 + +The number of packets sent by the TCP layer. As mentioned in RFC1213, +it excludes the retransmitted packets. But it includes the SYN, ACK +and RST packets. Doesn't like TcpInSegs, the TcpOutSegs is aware of +GSO, so if a packet would be split to 2 by GSO, TcpOutSegs will +increase 2. + +* TcpActiveOpens +Defined in `RFC1213 tcpActiveOpens`_ + +.. _RFC1213 tcpActiveOpens: https://tools.ietf.org/html/rfc1213#page-47 + +It means the TCP layer sends a SYN, and come into the SYN-SENT +state. Every time TcpActiveOpens increases 1, TcpOutSegs should always +increase 1. + +* TcpPassiveOpens +Defined in `RFC1213 tcpPassiveOpens`_ + +.. _RFC1213 tcpPassiveOpens: https://tools.ietf.org/html/rfc1213#page-47 + +It means the TCP layer receives a SYN, replies a SYN+ACK, come into +the SYN-RCVD state. + +TCP Fast Open +============ +When kernel receives a TCP packet, it has two paths to handler the +packet, one is fast path, another is slow path. The comment in kernel +code provides a good explanation of them, I pasted them below:: + + It is split into a fast path and a slow path. The fast path is + disabled when: + + - A zero window was announced from us + - zero window probing + is only handled properly on the slow path. + - Out of order segments arrived. + - Urgent data is expected. + - There is no buffer space left + - Unexpected TCP flags/window values/header lengths are received + (detected by checking the TCP header against pred_flags) + - Data is sent in both directions. The fast path only supports pure senders + or pure receivers (this means either the sequence number or the ack + value must stay constant) + - Unexpected TCP option. + +Kernel will try to use fast path unless any of the above conditions +are satisfied. If the packets are out of order, kernel will handle +them in slow path, which means the performance might be not very +good. Kernel would also come into slow path if the "Delayed ack" is +used, because when using "Delayed ack", the data is sent in both +directions. When the TCP window scale option is not used, kernel will +try to enable fast path immediately when the connection comes into the +established state, but if the TCP window scale option is used, kernel +will disable the fast path at first, and try to enable it after kernel +receives packets. + +* TcpExtTCPPureAcks and TcpExtTCPHPAcks +If a packet set ACK flag and has no data, it is a pure ACK packet, if +kernel handles it in the fast path, TcpExtTCPHPAcks will increase 1, +if kernel handles it in the slow path, TcpExtTCPPureAcks will +increase 1. + +* TcpExtTCPHPHits +If a TCP packet has data (which means it is not a pure ACK packet), +and this packet is handled in the fast path, TcpExtTCPHPHits will +increase 1. + + +TCP abort +======== + + +* TcpExtTCPAbortOnData +It means TCP layer has data in flight, but need to close the +connection. So TCP layer sends a RST to the other side, indicate the +connection is not closed very graceful. An easy way to increase this +counter is using the SO_LINGER option. Please refer to the SO_LINGER +section of the `socket man page`_: + +.. _socket man page: http://man7.org/linux/man-pages/man7/socket.7.html + +By default, when an application closes a connection, the close function +will return immediately and kernel will try to send the in-flight data +async. If you use the SO_LINGER option, set l_onoff to 1, and l_linger +to a positive number, the close function won't return immediately, but +wait for the in-flight data are acked by the other side, the max wait +time is l_linger seconds. If set l_onoff to 1 and set l_linger to 0, +when the application closes a connection, kernel will send a RST +immediately and increase the TcpExtTCPAbortOnData counter. + +* TcpExtTCPAbortOnClose +This counter means the application has unread data in the TCP layer when +the application wants to close the TCP connection. In such a situation, +kernel will send a RST to the other side of the TCP connection. + +* TcpExtTCPAbortOnMemory +When an application closes a TCP connection, kernel still need to track +the connection, let it complete the TCP disconnect process. E.g. an +app calls the close method of a socket, kernel sends fin to the other +side of the connection, then the app has no relationship with the +socket any more, but kernel need to keep the socket, this socket +becomes an orphan socket, kernel waits for the reply of the other side, +and would come to the TIME_WAIT state finally. When kernel has no +enough memory to keep the orphan socket, kernel would send an RST to +the other side, and delete the socket, in such situation, kernel will +increase 1 to the TcpExtTCPAbortOnMemory. Two conditions would trigger +TcpExtTCPAbortOnMemory: + +1. the memory used by the TCP protocol is higher than the third value of +the tcp_mem. Please refer the tcp_mem section in the `TCP man page`_: + +.. _TCP man page: http://man7.org/linux/man-pages/man7/tcp.7.html + +2. the orphan socket count is higher than net.ipv4.tcp_max_orphans + + +* TcpExtTCPAbortOnTimeout +This counter will increase when any of the TCP timers expire. In such +situation, kernel won't send RST, just give up the connection. + +* TcpExtTCPAbortOnLinger +When a TCP connection comes into FIN_WAIT_2 state, instead of waiting +for the fin packet from the other side, kernel could send a RST and +delete the socket immediately. This is not the default behavior of +Linux kernel TCP stack. By configuring the TCP_LINGER2 socket option, +you could let kernel follow this behavior. + +* TcpExtTCPAbortFailed +The kernel TCP layer will send RST if the `RFC2525 2.17 section`_ is +satisfied. If an internal error occurs during this process, +TcpExtTCPAbortFailed will be increased. + +.. _RFC2525 2.17 section: https://tools.ietf.org/html/rfc2525#page-50 + examples ======= @@ -220,3 +377,369 @@ and its corresponding Echo Reply packet are constructed by: * 48 bytes data (default value of the ping command) So the IpExtInOctets and IpExtOutOctets are 20+16+48=84. + +tcp 3-way handshake +------------------ +On server side, we run:: + + nstatuser@nstat-b:~$ nc -lknv 0.0.0.0 9000 + Listening on [0.0.0.0] (family 0, port 9000) + +On client side, we run:: + + nstatuser@nstat-a:~$ nc -nv 192.168.122.251 9000 + Connection to 192.168.122.251 9000 port [tcp/*] succeeded! + +The server listened on tcp 9000 port, the client connected to it, they +completed the 3-way handshake. + +On server side, we can find below nstat output:: + + nstatuser@nstat-b:~$ nstat | grep -i tcp + TcpPassiveOpens 1 0.0 + TcpInSegs 2 0.0 + TcpOutSegs 1 0.0 + TcpExtTCPPureAcks 1 0.0 + +On client side, we can find below nstat output:: + + nstatuser@nstat-a:~$ nstat | grep -i tcp + TcpActiveOpens 1 0.0 + TcpInSegs 1 0.0 + TcpOutSegs 2 0.0 + +When the server received the first SYN, it replied a SYN+ACK, and came into +SYN-RCVD state, so TcpPassiveOpens increased 1. The server received +SYN, sent SYN+ACK, received ACK, so server sent 1 packet, received 2 +packets, TcpInSegs increased 2, TcpOutSegs increased 1. The last ACK +of the 3-way handshake is a pure ACK without data, so +TcpExtTCPPureAcks increased 1. + +When the client sent SYN, the client came into the SYN-SENT state, so +TcpActiveOpens increased 1, the client sent SYN, received SYN+ACK, sent +ACK, so client sent 2 packets, received 1 packet, TcpInSegs increased +1, TcpOutSegs increased 2. + +TCP normal traffic +----------------- +Run nc on server:: + + nstatuser@nstat-b:~$ nc -lkv 0.0.0.0 9000 + Listening on [0.0.0.0] (family 0, port 9000) + +Run nc on client:: + + nstatuser@nstat-a:~$ nc -v nstat-b 9000 + Connection to nstat-b 9000 port [tcp/*] succeeded! + +Input a string in the nc client ('hello' in our example):: + + nstatuser@nstat-a:~$ nc -v nstat-b 9000 + Connection to nstat-b 9000 port [tcp/*] succeeded! + hello + +The client side nstat output:: + + nstatuser@nstat-a:~$ nstat + #kernel + IpInReceives 1 0.0 + IpInDelivers 1 0.0 + IpOutRequests 1 0.0 + TcpInSegs 1 0.0 + TcpOutSegs 1 0.0 + TcpExtTCPPureAcks 1 0.0 + TcpExtTCPOrigDataSent 1 0.0 + IpExtInOctets 52 0.0 + IpExtOutOctets 58 0.0 + IpExtInNoECTPkts 1 0.0 + +The server side nstat output:: + + nstatuser@nstat-b:~$ nstat + #kernel + IpInReceives 1 0.0 + IpInDelivers 1 0.0 + IpOutRequests 1 0.0 + TcpInSegs 1 0.0 + TcpOutSegs 1 0.0 + IpExtInOctets 58 0.0 + IpExtOutOctets 52 0.0 + IpExtInNoECTPkts 1 0.0 + +Input a string in nc client side again ('world' in our exmaple):: + + nstatuser@nstat-a:~$ nc -v nstat-b 9000 + Connection to nstat-b 9000 port [tcp/*] succeeded! + hello + world + +Client side nstat output:: + + nstatuser@nstat-a:~$ nstat + #kernel + IpInReceives 1 0.0 + IpInDelivers 1 0.0 + IpOutRequests 1 0.0 + TcpInSegs 1 0.0 + TcpOutSegs 1 0.0 + TcpExtTCPHPAcks 1 0.0 + TcpExtTCPOrigDataSent 1 0.0 + IpExtInOctets 52 0.0 + IpExtOutOctets 58 0.0 + IpExtInNoECTPkts 1 0.0 + + +Server side nstat output:: + + nstatuser@nstat-b:~$ nstat + #kernel + IpInReceives 1 0.0 + IpInDelivers 1 0.0 + IpOutRequests 1 0.0 + TcpInSegs 1 0.0 + TcpOutSegs 1 0.0 + TcpExtTCPHPHits 1 0.0 + IpExtInOctets 58 0.0 + IpExtOutOctets 52 0.0 + IpExtInNoECTPkts 1 0.0 + +Compare the first client-side nstat and the second client-side nstat, +we could find one difference: the first one had a 'TcpExtTCPPureAcks', +but the second one had a 'TcpExtTCPHPAcks'. The first server-side +nstat and the second server-side nstat had a difference too: the +second server-side nstat had a TcpExtTCPHPHits, but the first +server-side nstat didn't have it. The network traffic patterns were +exactly the same: the client sent a packet to the server, the server +replied an ACK. But kernel handled them in different ways. When the +TCP window scale option is not used, kernel will try to enable fast +path immediately when the connection comes into the established state, +but if the TCP window scale option is used, kernel will disable the +fast path at first, and try to enable it after kerenl receives +packets. We could use the 'ss' command to verify whether the window +scale option is used. e.g. run below command on either server or +client:: + + nstatuser@nstat-a:~$ ss -o state established -i '( dport = :9000 or sport = :9000 ) + Netid Recv-Q Send-Q Local Address:Port Peer Address:Port + tcp 0 0 192.168.122.250:40654 192.168.122.251:9000 + ts sack cubic wscale:7,7 rto:204 rtt:0.98/0.49 mss:1448 pmtu:1500 rcvmss:536 advmss:1448 cwnd:10 bytes_acked:1 segs_out:2 segs_in:1 send 118.2Mbps lastsnd:46572 lastrcv:46572 lastack:46572 pacing_rate 236.4Mbps rcv_space:29200 rcv_ssthresh:29200 minrtt:0.98 + +The 'wscale:7,7' means both server and client set the window scale +option to 7. Now we could explain the nstat output in our test: + +In the first nstat output of client side, the client sent a packet, server +reply an ACK, when kernel handled this ACK, the fast path was not +enabled, so the ACK was counted into 'TcpExtTCPPureAcks'. + +In the second nstat output of client side, the client sent a packet again, +and received another ACK from the server, in this time, the fast path is +enabled, and the ACK was qualified for fast path, so it was handled by +the fast path, so this ACK was counted into TcpExtTCPHPAcks. + +In the first nstat output of server side, fast path was not enabled, +so there was no 'TcpExtTCPHPHits'. + +In the second nstat output of server side, the fast path was enabled, +and the packet received from client qualified for fast path, so it +was counted into 'TcpExtTCPHPHits'. + +TcpExtTCPAbortOnClose +-------------------- +On the server side, we run below python script:: + + import socket + import time + + port = 9000 + + s = socket.socket(socket.AF_INET, socket.SOCK_STREAM) + s.bind(('0.0.0.0', port)) + s.listen(1) + sock, addr = s.accept() + while True: + time.sleep(9999999) + +This python script listen on 9000 port, but doesn't read anything from +the connection. + +On the client side, we send the string "hello" by nc:: + + nstatuser@nstat-a:~$ echo "hello" | nc nstat-b 9000 + +Then, we come back to the server side, the server has received the "hello" +packet, and the TCP layer has acked this packet, but the application didn't +read it yet. We type Ctrl-C to terminate the server script. Then we +could find TcpExtTCPAbortOnClose increased 1 on the server side:: + + nstatuser@nstat-b:~$ nstat | grep -i abort + TcpExtTCPAbortOnClose 1 0.0 + +If we run tcpdump on the server side, we could find the server sent a +RST after we type Ctrl-C. + +TcpExtTCPAbortOnMemory and TcpExtTCPAbortOnTimeout +----------------------------------------------- +Below is an example which let the orphan socket count be higher than +net.ipv4.tcp_max_orphans. +Change tcp_max_orphans to a smaller value on client:: + + sudo bash -c "echo 10 > /proc/sys/net/ipv4/tcp_max_orphans" + +Client code (create 64 connection to server):: + + nstatuser@nstat-a:~$ cat client_orphan.py + import socket + import time + + server = 'nstat-b' # server address + port = 9000 + + count = 64 + + connection_list = [] + + for i in range(64): + s = socket.socket(socket.AF_INET, socket.SOCK_STREAM) + s.connect((server, port)) + connection_list.append(s) + print("connection_count: %d" % len(connection_list)) + + while True: + time.sleep(99999) + +Server code (accept 64 connection from client):: + + nstatuser@nstat-b:~$ cat server_orphan.py + import socket + import time + + port = 9000 + count = 64 + + s = socket.socket(socket.AF_INET, socket.SOCK_STREAM) + s.bind(('0.0.0.0', port)) + s.listen(count) + connection_list = [] + while True: + sock, addr = s.accept() + connection_list.append((sock, addr)) + print("connection_count: %d" % len(connection_list)) + +Run the python scripts on server and client. + +On server:: + + python3 server_orphan.py + +On client:: + + python3 client_orphan.py + +Run iptables on server:: + + sudo iptables -A INPUT -i ens3 -p tcp --destination-port 9000 -j DROP + +Type Ctrl-C on client, stop client_orphan.py. + +Check TcpExtTCPAbortOnMemory on client:: + + nstatuser@nstat-a:~$ nstat | grep -i abort + TcpExtTCPAbortOnMemory 54 0.0 + +Check orphane socket count on client:: + + nstatuser@nstat-a:~$ ss -s + Total: 131 (kernel 0) + TCP: 14 (estab 1, closed 0, orphaned 10, synrecv 0, timewait 0/0), ports 0 + + Transport Total IP IPv6 + * 0 - - + RAW 1 0 1 + UDP 1 1 0 + TCP 14 13 1 + INET 16 14 2 + FRAG 0 0 0 + +The explanation of the test: after run server_orphan.py and +client_orphan.py, we set up 64 connections between server and +client. Run the iptables command, the server will drop all packets from +the client, type Ctrl-C on client_orphan.py, the system of the client +would try to close these connections, and before they are closed +gracefully, these connections became orphan sockets. As the iptables +of the server blocked packets from the client, the server won't receive fin +from the client, so all connection on clients would be stuck on FIN_WAIT_1 +stage, so they will keep as orphan sockets until timeout. We have echo +10 to /proc/sys/net/ipv4/tcp_max_orphans, so the client system would +only keep 10 orphan sockets, for all other orphan sockets, the client +system sent RST for them and delete them. We have 64 connections, so +the 'ss -s' command shows the system has 10 orphan sockets, and the +value of TcpExtTCPAbortOnMemory was 54. + +An additional explanation about orphan socket count: You could find the +exactly orphan socket count by the 'ss -s' command, but when kernel +decide whither increases TcpExtTCPAbortOnMemory and sends RST, kernel +doesn't always check the exactly orphan socket count. For increasing +performance, kernel checks an approximate count firstly, if the +approximate count is more than tcp_max_orphans, kernel checks the +exact count again. So if the approximate count is less than +tcp_max_orphans, but exactly count is more than tcp_max_orphans, you +would find TcpExtTCPAbortOnMemory is not increased at all. If +tcp_max_orphans is large enough, it won't occur, but if you decrease +tcp_max_orphans to a small value like our test, you might find this +issue. So in our test, the client set up 64 connections although the +tcp_max_orphans is 10. If the client only set up 11 connections, we +can't find the change of TcpExtTCPAbortOnMemory. + +Continue the previous test, we wait for several minutes. Because of the +iptables on the server blocked the traffic, the server wouldn't receive +fin, and all the client's orphan sockets would timeout on the +FIN_WAIT_1 state finally. So we wait for a few minutes, we could find +10 timeout on the client:: + + nstatuser@nstat-a:~$ nstat | grep -i abort + TcpExtTCPAbortOnTimeout 10 0.0 + +TcpExtTCPAbortOnLinger +--------------------- +The server side code:: + + nstatuser@nstat-b:~$ cat server_linger.py + import socket + import time + + port = 9000 + + s = socket.socket(socket.AF_INET, socket.SOCK_STREAM) + s.bind(('0.0.0.0', port)) + s.listen(1) + sock, addr = s.accept() + while True: + time.sleep(9999999) + +The client side code:: + + nstatuser@nstat-a:~$ cat client_linger.py + import socket + import struct + + server = 'nstat-b' # server address + port = 9000 + + s = socket.socket(socket.AF_INET, socket.SOCK_STREAM) + s.setsockopt(socket.SOL_SOCKET, socket.SO_LINGER, struct.pack('ii', 1, 10)) + s.setsockopt(socket.SOL_TCP, socket.TCP_LINGER2, struct.pack('i', -1)) + s.connect((server, port)) + s.close() + +Run server_linger.py on server:: + + nstatuser@nstat-b:~$ python3 server_linger.py + +Run client_linger.py on client:: + + nstatuser@nstat-a:~$ python3 client_linger.py + +After run client_linger.py, check the output of nstat:: + + nstatuser@nstat-a:~$ nstat | grep -i abort + TcpExtTCPAbortOnLinger 1 0.0 -- 2.7.4