1. 02 4月, 2017 1 次提交
  2. 20 2月, 2017 1 次提交
  3. 07 2月, 2017 1 次提交
  4. 19 1月, 2017 2 次提交
    • X
      sctp: add stream reconf primitive · 7a090b04
      Xin Long 提交于
      This patch is to add a primitive based on sctp primitive frame for
      sending stream reconf request. It works as the other primitives,
      and create a SCTP_CMD_REPLY command to send the request chunk out.
      
      sctp_primitive_RECONF would be the api to send a reconf request
      chunk.
      Signed-off-by: NXin Long <lucien.xin@gmail.com>
      Signed-off-by: NDavid S. Miller <davem@davemloft.net>
      7a090b04
    • X
      sctp: add stream reconf timer · 7b9438de
      Xin Long 提交于
      This patch is to add a per transport timer based on sctp timer frame
      for stream reconf chunk retransmission. It would start after sending
      a reconf request chunk, and stop after receiving the response chunk.
      
      If the timer expires, besides retransmitting the reconf request chunk,
      it would also do the same thing with data RTO timer. like to increase
      the appropriate error counts, and perform threshold management, possibly
      destroying the asoc if sctp retransmission thresholds are exceeded, just
      as section 5.1.1 describes.
      
      This patch is also to add asoc strreset_chunk, it is used to save the
      reconf request chunk, so that it can be retransmitted, and to check if
      the response is really for this request by comparing the information
      inside with the response chunk as well.
      Signed-off-by: NXin Long <lucien.xin@gmail.com>
      Signed-off-by: NDavid S. Miller <davem@davemloft.net>
      7b9438de
  5. 07 1月, 2017 1 次提交
    • X
      sctp: prepare asoc stream for stream reconf · a8386317
      Xin Long 提交于
      sctp stream reconf, described in RFC 6525, needs a structure to
      save per stream information in assoc, like stream state.
      
      In the future, sctp stream scheduler also needs it to save some
      stream scheduler params and queues.
      
      This patchset is to prepare the stream array in assoc for stream
      reconf. It defines sctp_stream that includes stream arrays inside
      to replace ssnmap.
      
      Note that we use different structures for IN and OUT streams, as
      the members in per OUT stream will get more and more different
      from per IN stream.
      
      v1->v2:
        - put these patches into a smaller group.
      v2->v3:
        - define sctp_stream to contain stream arrays, and create stream.c
          to put stream-related functions.
        - merge 3 patches into 1, as new sctp_stream has the same name
          with before.
      Signed-off-by: NXin Long <lucien.xin@gmail.com>
      Reviewed-by: NMarcelo Ricardo Leitner <marcelo.leitner@gmail.com>
      Signed-off-by: NDavid S. Miller <davem@davemloft.net>
      a8386317
  6. 29 12月, 2016 4 次提交
  7. 30 10月, 2016 1 次提交
  8. 22 9月, 2016 1 次提交
  9. 14 7月, 2016 3 次提交
    • M
      sctp: only check for ECN if peer is using it · 2d47fd12
      Marcelo Ricardo Leitner 提交于
      Currently only read-only checks are performed up to the point on where
      we check if peer is ECN capable, checks which we can avoid otherwise.
      The flag ecn_ce_done is only used to perform this check once per
      incoming packet, and nothing more.
      
      Thus this patch moves the peer check up.
      Signed-off-by: NMarcelo Ricardo Leitner <marcelo.leitner@gmail.com>
      Signed-off-by: NDavid S. Miller <davem@davemloft.net>
      2d47fd12
    • M
      sctp: avoid identifying address family many times for a chunk · e7487c86
      Marcelo Ricardo Leitner 提交于
      Identifying address family operations during rx path is not something
      expensive but it's ugly to the eye to have it done multiple times,
      specially when we already validated it during initial rx processing.
      
      This patch takes advantage of the now shared sctp_input_cb and make the
      pointer to the operations readily available.
      Signed-off-by: NMarcelo Ricardo Leitner <marcelo.leitner@gmail.com>
      Signed-off-by: NDavid S. Miller <davem@davemloft.net>
      e7487c86
    • M
      sctp: allow GSO frags to access the chunk too · 1f45f78f
      Marcelo Ricardo Leitner 提交于
      SCTP will try to access original IP headers on sctp_recvmsg in order to
      copy the addresses used. There are also other places that do similar access
      to IP or even SCTP headers. But after 90017acc ("sctp: Add GSO
      support") they aren't always there because they are only present in the
      header skb.
      
      SCTP handles the queueing of incoming data by cloning the incoming skb
      and limiting to only the relevant payload. This clone has its cb updated
      to something different and it's then queued on socket rx queue. Thus we
      need to fix this in two moments.
      
      For rx path, not related to socket queue yet, this patch uses a
      partially copied sctp_input_cb to such GSO frags. This restores the
      ability to access the headers for this part of the code.
      
      Regarding the socket rx queue, it removes iif member from sctp_event and
      also add a chunk pointer on it.
      
      With these changes we're always able to reach the headers again.
      
      The biggest change here is that now the sctp_chunk struct and the
      original skb are only freed after the application consumed the buffer.
      Note however that the original payload was already like this due to the
      skb cloning.
      
      For iif, SCTP's IPv4 code doesn't use it, so no change is necessary.
      IPv6 now can fetch it directly from original's IPv6 CB as the original
      skb is still accessible.
      
      In the future we probably can simplify sctp_v*_skb_iif() stuff, as
      sctp_v4_skb_iif() was called but it's return value not used, and now
      it's not even called, but such cleanup is out of scope for this change.
      
      Fixes: 90017acc ("sctp: Add GSO support")
      Signed-off-by: NMarcelo Ricardo Leitner <marcelo.leitner@gmail.com>
      Signed-off-by: NDavid S. Miller <davem@davemloft.net>
      1f45f78f
  10. 12 1月, 2016 1 次提交
  11. 31 12月, 2015 1 次提交
    • X
      sctp: sctp should release assoc when sctp_make_abort_user return NULL in sctp_close · 068d8bd3
      Xin Long 提交于
      In sctp_close, sctp_make_abort_user may return NULL because of memory
      allocation failure. If this happens, it will bypass any state change
      and never free the assoc. The assoc has no chance to be freed and it
      will be kept in memory with the state it had even after the socket is
      closed by sctp_close().
      
      So if sctp_make_abort_user fails to allocate memory, we should abort
      the asoc via sctp_primitive_ABORT as well. Just like the annotation in
      sctp_sf_cookie_wait_prm_abort and sctp_sf_do_9_1_prm_abort said,
      "Even if we can't send the ABORT due to low memory delete the TCB.
      This is a departure from our typical NOMEM handling".
      
      But then the chunk is NULL (low memory) and the SCTP_CMD_REPLY cmd would
      dereference the chunk pointer, and system crash. So we should add
      SCTP_CMD_REPLY cmd only when the chunk is not NULL, just like other
      places where it adds SCTP_CMD_REPLY cmd.
      Signed-off-by: NXin Long <lucien.xin@gmail.com>
      Acked-by: NMarcelo Ricardo Leitner <marcelo.leitner@gmail.com>
      Signed-off-by: NDavid S. Miller <davem@davemloft.net>
      068d8bd3
  12. 07 12月, 2015 1 次提交
    • L
      sctp: start t5 timer only when peer rwnd is 0 and local state is SHUTDOWN_PENDING · 8a0d19c5
      lucien 提交于
      when A sends a data to B, then A close() and enter into SHUTDOWN_PENDING
      state, if B neither claim his rwnd is 0 nor send SACK for this data, A
      will keep retransmitting this data until t5 timeout, Max.Retrans times
      can't work anymore, which is bad.
      
      if B's rwnd is not 0, it should send abort after Max.Retrans times, only
      when B's rwnd == 0 and A's retransmitting beyonds Max.Retrans times, A
      will start t5 timer, which is also commit f8d96052 ("sctp: Enforce
      retransmission limit during shutdown") means, but it lacks the condition
      peer rwnd == 0.
      
      so fix it by adding a bit (zero_window_announced) in peer to record if
      the last rwnd is 0. If it was, zero_window_announced will be set. and use
      this bit to decide if start t5 timer when local.state is SHUTDOWN_PENDING.
      
      Fixes: commit f8d96052 ("sctp: Enforce retransmission limit during shutdown")
      Signed-off-by: NXin Long <lucien.xin@gmail.com>
      Signed-off-by: NMarcelo Ricardo Leitner <marcelo.leitner@gmail.com>
      Signed-off-by: NDavid S. Miller <davem@davemloft.net>
      8a0d19c5
  13. 05 10月, 2015 1 次提交
  14. 21 7月, 2015 1 次提交
  15. 15 10月, 2014 2 次提交
    • D
      net: sctp: fix remote memory pressure from excessive queueing · 26b87c78
      Daniel Borkmann 提交于
      This scenario is not limited to ASCONF, just taken as one
      example triggering the issue. When receiving ASCONF probes
      in the form of ...
      
        -------------- INIT[ASCONF; ASCONF_ACK] ------------->
        <----------- INIT-ACK[ASCONF; ASCONF_ACK] ------------
        -------------------- COOKIE-ECHO -------------------->
        <-------------------- COOKIE-ACK ---------------------
        ---- ASCONF_a; [ASCONF_b; ...; ASCONF_n;] JUNK ------>
        [...]
        ---- ASCONF_m; [ASCONF_o; ...; ASCONF_z;] JUNK ------>
      
      ... where ASCONF_a, ASCONF_b, ..., ASCONF_z are good-formed
      ASCONFs and have increasing serial numbers, we process such
      ASCONF chunk(s) marked with !end_of_packet and !singleton,
      since we have not yet reached the SCTP packet end. SCTP does
      only do verification on a chunk by chunk basis, as an SCTP
      packet is nothing more than just a container of a stream of
      chunks which it eats up one by one.
      
      We could run into the case that we receive a packet with a
      malformed tail, above marked as trailing JUNK. All previous
      chunks are here goodformed, so the stack will eat up all
      previous chunks up to this point. In case JUNK does not fit
      into a chunk header and there are no more other chunks in
      the input queue, or in case JUNK contains a garbage chunk
      header, but the encoded chunk length would exceed the skb
      tail, or we came here from an entirely different scenario
      and the chunk has pdiscard=1 mark (without having had a flush
      point), it will happen, that we will excessively queue up
      the association's output queue (a correct final chunk may
      then turn it into a response flood when flushing the
      queue ;)): I ran a simple script with incremental ASCONF
      serial numbers and could see the server side consuming
      excessive amount of RAM [before/after: up to 2GB and more].
      
      The issue at heart is that the chunk train basically ends
      with !end_of_packet and !singleton markers and since commit
      2e3216cd ("sctp: Follow security requirement of responding
      with 1 packet") therefore preventing an output queue flush
      point in sctp_do_sm() -> sctp_cmd_interpreter() on the input
      chunk (chunk = event_arg) even though local_cork is set,
      but its precedence has changed since then. In the normal
      case, the last chunk with end_of_packet=1 would trigger the
      queue flush to accommodate possible outgoing bundling.
      
      In the input queue, sctp_inq_pop() seems to do the right thing
      in terms of discarding invalid chunks. So, above JUNK will
      not enter the state machine and instead be released and exit
      the sctp_assoc_bh_rcv() chunk processing loop. It's simply
      the flush point being missing at loop exit. Adding a try-flush
      approach on the output queue might not work as the underlying
      infrastructure might be long gone at this point due to the
      side-effect interpreter run.
      
      One possibility, albeit a bit of a kludge, would be to defer
      invalid chunk freeing into the state machine in order to
      possibly trigger packet discards and thus indirectly a queue
      flush on error. It would surely be better to discard chunks
      as in the current, perhaps better controlled environment, but
      going back and forth, it's simply architecturally not possible.
      I tried various trailing JUNK attack cases and it seems to
      look good now.
      
      Joint work with Vlad Yasevich.
      
      Fixes: 2e3216cd ("sctp: Follow security requirement of responding with 1 packet")
      Signed-off-by: NDaniel Borkmann <dborkman@redhat.com>
      Signed-off-by: NVlad Yasevich <vyasevich@gmail.com>
      Signed-off-by: NDavid S. Miller <davem@davemloft.net>
      26b87c78
    • D
      net: sctp: fix skb_over_panic when receiving malformed ASCONF chunks · 9de7922b
      Daniel Borkmann 提交于
      Commit 6f4c618d ("SCTP : Add paramters validity check for
      ASCONF chunk") added basic verification of ASCONF chunks, however,
      it is still possible to remotely crash a server by sending a
      special crafted ASCONF chunk, even up to pre 2.6.12 kernels:
      
      skb_over_panic: text:ffffffffa01ea1c3 len:31056 put:30768
       head:ffff88011bd81800 data:ffff88011bd81800 tail:0x7950
       end:0x440 dev:<NULL>
       ------------[ cut here ]------------
      kernel BUG at net/core/skbuff.c:129!
      [...]
      Call Trace:
       <IRQ>
       [<ffffffff8144fb1c>] skb_put+0x5c/0x70
       [<ffffffffa01ea1c3>] sctp_addto_chunk+0x63/0xd0 [sctp]
       [<ffffffffa01eadaf>] sctp_process_asconf+0x1af/0x540 [sctp]
       [<ffffffff8152d025>] ? _read_unlock_bh+0x15/0x20
       [<ffffffffa01e0038>] sctp_sf_do_asconf+0x168/0x240 [sctp]
       [<ffffffffa01e3751>] sctp_do_sm+0x71/0x1210 [sctp]
       [<ffffffff8147645d>] ? fib_rules_lookup+0xad/0xf0
       [<ffffffffa01e6b22>] ? sctp_cmp_addr_exact+0x32/0x40 [sctp]
       [<ffffffffa01e8393>] sctp_assoc_bh_rcv+0xd3/0x180 [sctp]
       [<ffffffffa01ee986>] sctp_inq_push+0x56/0x80 [sctp]
       [<ffffffffa01fcc42>] sctp_rcv+0x982/0xa10 [sctp]
       [<ffffffffa01d5123>] ? ipt_local_in_hook+0x23/0x28 [iptable_filter]
       [<ffffffff8148bdc9>] ? nf_iterate+0x69/0xb0
       [<ffffffff81496d10>] ? ip_local_deliver_finish+0x0/0x2d0
       [<ffffffff8148bf86>] ? nf_hook_slow+0x76/0x120
       [<ffffffff81496d10>] ? ip_local_deliver_finish+0x0/0x2d0
       [<ffffffff81496ded>] ip_local_deliver_finish+0xdd/0x2d0
       [<ffffffff81497078>] ip_local_deliver+0x98/0xa0
       [<ffffffff8149653d>] ip_rcv_finish+0x12d/0x440
       [<ffffffff81496ac5>] ip_rcv+0x275/0x350
       [<ffffffff8145c88b>] __netif_receive_skb+0x4ab/0x750
       [<ffffffff81460588>] netif_receive_skb+0x58/0x60
      
      This can be triggered e.g., through a simple scripted nmap
      connection scan injecting the chunk after the handshake, for
      example, ...
      
        -------------- INIT[ASCONF; ASCONF_ACK] ------------->
        <----------- INIT-ACK[ASCONF; ASCONF_ACK] ------------
        -------------------- COOKIE-ECHO -------------------->
        <-------------------- COOKIE-ACK ---------------------
        ------------------ ASCONF; UNKNOWN ------------------>
      
      ... where ASCONF chunk of length 280 contains 2 parameters ...
      
        1) Add IP address parameter (param length: 16)
        2) Add/del IP address parameter (param length: 255)
      
      ... followed by an UNKNOWN chunk of e.g. 4 bytes. Here, the
      Address Parameter in the ASCONF chunk is even missing, too.
      This is just an example and similarly-crafted ASCONF chunks
      could be used just as well.
      
      The ASCONF chunk passes through sctp_verify_asconf() as all
      parameters passed sanity checks, and after walking, we ended
      up successfully at the chunk end boundary, and thus may invoke
      sctp_process_asconf(). Parameter walking is done with
      WORD_ROUND() to take padding into account.
      
      In sctp_process_asconf()'s TLV processing, we may fail in
      sctp_process_asconf_param() e.g., due to removal of the IP
      address that is also the source address of the packet containing
      the ASCONF chunk, and thus we need to add all TLVs after the
      failure to our ASCONF response to remote via helper function
      sctp_add_asconf_response(), which basically invokes a
      sctp_addto_chunk() adding the error parameters to the given
      skb.
      
      When walking to the next parameter this time, we proceed
      with ...
      
        length = ntohs(asconf_param->param_hdr.length);
        asconf_param = (void *)asconf_param + length;
      
      ... instead of the WORD_ROUND()'ed length, thus resulting here
      in an off-by-one that leads to reading the follow-up garbage
      parameter length of 12336, and thus throwing an skb_over_panic
      for the reply when trying to sctp_addto_chunk() next time,
      which implicitly calls the skb_put() with that length.
      
      Fix it by using sctp_walk_params() [ which is also used in
      INIT parameter processing ] macro in the verification *and*
      in ASCONF processing: it will make sure we don't spill over,
      that we walk parameters WORD_ROUND()'ed. Moreover, we're being
      more defensive and guard against unknown parameter types and
      missized addresses.
      
      Joint work with Vlad Yasevich.
      
      Fixes: b896b82be4ae ("[SCTP] ADDIP: Support for processing incoming ASCONF_ACK chunks.")
      Signed-off-by: NDaniel Borkmann <dborkman@redhat.com>
      Signed-off-by: NVlad Yasevich <vyasevich@gmail.com>
      Acked-by: NNeil Horman <nhorman@tuxdriver.com>
      Signed-off-by: NDavid S. Miller <davem@davemloft.net>
      9de7922b
  16. 06 10月, 2014 1 次提交
    • V
      sctp: handle association restarts when the socket is closed. · bdf6fa52
      Vlad Yasevich 提交于
      Currently association restarts do not take into consideration the
      state of the socket.  When a restart happens, the current assocation
      simply transitions into established state.  This creates a condition
      where a remote system, through a the restart procedure, may create a
      local association that is no way reachable by user.  The conditions
      to trigger this are as follows:
        1) Remote does not acknoledge some data causing data to remain
           outstanding.
        2) Local application calls close() on the socket.  Since data
           is still outstanding, the association is placed in SHUTDOWN_PENDING
           state.  However, the socket is closed.
        3) The remote tries to create a new association, triggering a restart
           on the local system.  The association moves from SHUTDOWN_PENDING
           to ESTABLISHED.  At this point, it is no longer reachable by
           any socket on the local system.
      
      This patch addresses the above situation by moving the newly ESTABLISHED
      association into SHUTDOWN-SENT state and bundling a SHUTDOWN after
      the COOKIE-ACK chunk.  This way, the restarted associate immidiately
      enters the shutdown procedure and forces the termination of the
      unreachable association.
      Reported-by: NDavid Laight <David.Laight@aculab.com>
      Signed-off-by: NVlad Yasevich <vyasevich@gmail.com>
      Signed-off-by: NDavid S. Miller <davem@davemloft.net>
      bdf6fa52
  17. 16 7月, 2014 1 次提交
  18. 19 4月, 2014 1 次提交
    • V
      net: sctp: cache auth_enable per endpoint · b14878cc
      Vlad Yasevich 提交于
      Currently, it is possible to create an SCTP socket, then switch
      auth_enable via sysctl setting to 1 and crash the system on connect:
      
      Oops[#1]:
      CPU: 0 PID: 0 Comm: swapper Not tainted 3.14.1-mipsgit-20140415 #1
      task: ffffffff8056ce80 ti: ffffffff8055c000 task.ti: ffffffff8055c000
      [...]
      Call Trace:
      [<ffffffff8043c4e8>] sctp_auth_asoc_set_default_hmac+0x68/0x80
      [<ffffffff8042b300>] sctp_process_init+0x5e0/0x8a4
      [<ffffffff8042188c>] sctp_sf_do_5_1B_init+0x234/0x34c
      [<ffffffff804228c8>] sctp_do_sm+0xb4/0x1e8
      [<ffffffff80425a08>] sctp_endpoint_bh_rcv+0x1c4/0x214
      [<ffffffff8043af68>] sctp_rcv+0x588/0x630
      [<ffffffff8043e8e8>] sctp6_rcv+0x10/0x24
      [<ffffffff803acb50>] ip6_input+0x2c0/0x440
      [<ffffffff8030fc00>] __netif_receive_skb_core+0x4a8/0x564
      [<ffffffff80310650>] process_backlog+0xb4/0x18c
      [<ffffffff80313cbc>] net_rx_action+0x12c/0x210
      [<ffffffff80034254>] __do_softirq+0x17c/0x2ac
      [<ffffffff800345e0>] irq_exit+0x54/0xb0
      [<ffffffff800075a4>] ret_from_irq+0x0/0x4
      [<ffffffff800090ec>] rm7k_wait_irqoff+0x24/0x48
      [<ffffffff8005e388>] cpu_startup_entry+0xc0/0x148
      [<ffffffff805a88b0>] start_kernel+0x37c/0x398
      Code: dd0900b8  000330f8  0126302d <dcc60000> 50c0fff1  0047182a  a48306a0
      03e00008  00000000
      ---[ end trace b530b0551467f2fd ]---
      Kernel panic - not syncing: Fatal exception in interrupt
      
      What happens while auth_enable=0 in that case is, that
      ep->auth_hmacs is initialized to NULL in sctp_auth_init_hmacs()
      when endpoint is being created.
      
      After that point, if an admin switches over to auth_enable=1,
      the machine can crash due to NULL pointer dereference during
      reception of an INIT chunk. When we enter sctp_process_init()
      via sctp_sf_do_5_1B_init() in order to respond to an INIT chunk,
      the INIT verification succeeds and while we walk and process
      all INIT params via sctp_process_param() we find that
      net->sctp.auth_enable is set, therefore do not fall through,
      but invoke sctp_auth_asoc_set_default_hmac() instead, and thus,
      dereference what we have set to NULL during endpoint
      initialization phase.
      
      The fix is to make auth_enable immutable by caching its value
      during endpoint initialization, so that its original value is
      being carried along until destruction. The bug seems to originate
      from the very first days.
      
      Fix in joint work with Daniel Borkmann.
      Reported-by: NJoshua Kinard <kumba@gentoo.org>
      Signed-off-by: NVlad Yasevich <vyasevic@redhat.com>
      Signed-off-by: NDaniel Borkmann <dborkman@redhat.com>
      Acked-by: NNeil Horman <nhorman@tuxdriver.com>
      Tested-by: NJoshua Kinard <kumba@gentoo.org>
      Signed-off-by: NDavid S. Miller <davem@davemloft.net>
      b14878cc
  19. 15 4月, 2014 1 次提交
    • D
      Revert "net: sctp: Fix a_rwnd/rwnd management to reflect real state of the receiver's buffer" · 362d5204
      Daniel Borkmann 提交于
      This reverts commit ef2820a7 ("net: sctp: Fix a_rwnd/rwnd management
      to reflect real state of the receiver's buffer") as it introduced a
      serious performance regression on SCTP over IPv4 and IPv6, though a not
      as dramatic on the latter. Measurements are on 10Gbit/s with ixgbe NICs.
      
      Current state:
      
      [root@Lab200slot2 ~]# iperf3 --sctp -4 -c 192.168.241.3 -V -l 1452 -t 60
      iperf version 3.0.1 (10 January 2014)
      Linux Lab200slot2 3.14.0 #1 SMP Thu Apr 3 23:18:29 EDT 2014 x86_64
      Time: Fri, 11 Apr 2014 17:56:21 GMT
      Connecting to host 192.168.241.3, port 5201
            Cookie: Lab200slot2.1397238981.812898.548918
      [  4] local 192.168.241.2 port 38616 connected to 192.168.241.3 port 5201
      Starting Test: protocol: SCTP, 1 streams, 1452 byte blocks, omitting 0 seconds, 60 second test
      [ ID] Interval           Transfer     Bandwidth
      [  4]   0.00-1.09   sec  20.8 MBytes   161 Mbits/sec
      [  4]   1.09-2.13   sec  10.8 MBytes  86.8 Mbits/sec
      [  4]   2.13-3.15   sec  3.57 MBytes  29.5 Mbits/sec
      [  4]   3.15-4.16   sec  4.33 MBytes  35.7 Mbits/sec
      [  4]   4.16-6.21   sec  10.4 MBytes  42.7 Mbits/sec
      [  4]   6.21-6.21   sec  0.00 Bytes    0.00 bits/sec
      [  4]   6.21-7.35   sec  34.6 MBytes   253 Mbits/sec
      [  4]   7.35-11.45  sec  22.0 MBytes  45.0 Mbits/sec
      [  4]  11.45-11.45  sec  0.00 Bytes    0.00 bits/sec
      [  4]  11.45-11.45  sec  0.00 Bytes    0.00 bits/sec
      [  4]  11.45-11.45  sec  0.00 Bytes    0.00 bits/sec
      [  4]  11.45-12.51  sec  16.0 MBytes   126 Mbits/sec
      [  4]  12.51-13.59  sec  20.3 MBytes   158 Mbits/sec
      [  4]  13.59-14.65  sec  13.4 MBytes   107 Mbits/sec
      [  4]  14.65-16.79  sec  33.3 MBytes   130 Mbits/sec
      [  4]  16.79-16.79  sec  0.00 Bytes    0.00 bits/sec
      [  4]  16.79-17.82  sec  5.94 MBytes  48.7 Mbits/sec
      (etc)
      
      [root@Lab200slot2 ~]#  iperf3 --sctp -6 -c 2001:db8:0:f101::1 -V -l 1400 -t 60
      iperf version 3.0.1 (10 January 2014)
      Linux Lab200slot2 3.14.0 #1 SMP Thu Apr 3 23:18:29 EDT 2014 x86_64
      Time: Fri, 11 Apr 2014 19:08:41 GMT
      Connecting to host 2001:db8:0:f101::1, port 5201
            Cookie: Lab200slot2.1397243321.714295.2b3f7c
      [  4] local 2001:db8:0:f101::2 port 55804 connected to 2001:db8:0:f101::1 port 5201
      Starting Test: protocol: SCTP, 1 streams, 1400 byte blocks, omitting 0 seconds, 60 second test
      [ ID] Interval           Transfer     Bandwidth
      [  4]   0.00-1.00   sec   169 MBytes  1.42 Gbits/sec
      [  4]   1.00-2.00   sec   201 MBytes  1.69 Gbits/sec
      [  4]   2.00-3.00   sec   188 MBytes  1.58 Gbits/sec
      [  4]   3.00-4.00   sec   174 MBytes  1.46 Gbits/sec
      [  4]   4.00-5.00   sec   165 MBytes  1.39 Gbits/sec
      [  4]   5.00-6.00   sec   199 MBytes  1.67 Gbits/sec
      [  4]   6.00-7.00   sec   163 MBytes  1.36 Gbits/sec
      [  4]   7.00-8.00   sec   174 MBytes  1.46 Gbits/sec
      [  4]   8.00-9.00   sec   193 MBytes  1.62 Gbits/sec
      [  4]   9.00-10.00  sec   196 MBytes  1.65 Gbits/sec
      [  4]  10.00-11.00  sec   157 MBytes  1.31 Gbits/sec
      [  4]  11.00-12.00  sec   175 MBytes  1.47 Gbits/sec
      [  4]  12.00-13.00  sec   192 MBytes  1.61 Gbits/sec
      [  4]  13.00-14.00  sec   199 MBytes  1.67 Gbits/sec
      (etc)
      
      After patch:
      
      [root@Lab200slot2 ~]#  iperf3 --sctp -4 -c 192.168.240.3 -V -l 1452 -t 60
      iperf version 3.0.1 (10 January 2014)
      Linux Lab200slot2 3.14.0+ #1 SMP Mon Apr 14 12:06:40 EDT 2014 x86_64
      Time: Mon, 14 Apr 2014 16:40:48 GMT
      Connecting to host 192.168.240.3, port 5201
            Cookie: Lab200slot2.1397493648.413274.65e131
      [  4] local 192.168.240.2 port 50548 connected to 192.168.240.3 port 5201
      Starting Test: protocol: SCTP, 1 streams, 1452 byte blocks, omitting 0 seconds, 60 second test
      [ ID] Interval           Transfer     Bandwidth
      [  4]   0.00-1.00   sec   240 MBytes  2.02 Gbits/sec
      [  4]   1.00-2.00   sec   239 MBytes  2.01 Gbits/sec
      [  4]   2.00-3.00   sec   240 MBytes  2.01 Gbits/sec
      [  4]   3.00-4.00   sec   239 MBytes  2.00 Gbits/sec
      [  4]   4.00-5.00   sec   245 MBytes  2.05 Gbits/sec
      [  4]   5.00-6.00   sec   240 MBytes  2.01 Gbits/sec
      [  4]   6.00-7.00   sec   240 MBytes  2.02 Gbits/sec
      [  4]   7.00-8.00   sec   239 MBytes  2.01 Gbits/sec
      
      With the reverted patch applied, the SCTP/IPv4 performance is back
      to normal on latest upstream for IPv4 and IPv6 and has same throughput
      as 3.4.2 test kernel, steady and interval reports are smooth again.
      
      Fixes: ef2820a7 ("net: sctp: Fix a_rwnd/rwnd management to reflect real state of the receiver's buffer")
      Reported-by: NPeter Butler <pbutler@sonusnet.com>
      Reported-by: NDongsheng Song <dongsheng.song@gmail.com>
      Reported-by: NFengguang Wu <fengguang.wu@intel.com>
      Tested-by: NPeter Butler <pbutler@sonusnet.com>
      Signed-off-by: NDaniel Borkmann <dborkman@redhat.com>
      Cc: Matija Glavinic Pecotic <matija.glavinic-pecotic.ext@nsn.com>
      Cc: Alexander Sverdlin <alexander.sverdlin@nsn.com>
      Cc: Vlad Yasevich <vyasevich@gmail.com>
      Acked-by: NVlad Yasevich <vyasevich@gmail.com>
      Signed-off-by: NDavid S. Miller <davem@davemloft.net>
      362d5204
  20. 06 3月, 2014 1 次提交
    • D
      net: sctp: fix skb leakage in COOKIE ECHO path of chunk->auth_chunk · c485658b
      Daniel Borkmann 提交于
      While working on ec0223ec ("net: sctp: fix sctp_sf_do_5_1D_ce to
      verify if we/peer is AUTH capable"), we noticed that there's a skb
      memory leakage in the error path.
      
      Running the same reproducer as in ec0223ec and by unconditionally
      jumping to the error label (to simulate an error condition) in
      sctp_sf_do_5_1D_ce() receive path lets kmemleak detector bark about
      the unfreed chunk->auth_chunk skb clone:
      
      Unreferenced object 0xffff8800b8f3a000 (size 256):
        comm "softirq", pid 0, jiffies 4294769856 (age 110.757s)
        hex dump (first 32 bytes):
          00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00  ................
          89 ab 75 5e d4 01 58 13 00 00 00 00 00 00 00 00  ..u^..X.........
        backtrace:
          [<ffffffff816660be>] kmemleak_alloc+0x4e/0xb0
          [<ffffffff8119f328>] kmem_cache_alloc+0xc8/0x210
          [<ffffffff81566929>] skb_clone+0x49/0xb0
          [<ffffffffa0467459>] sctp_endpoint_bh_rcv+0x1d9/0x230 [sctp]
          [<ffffffffa046fdbc>] sctp_inq_push+0x4c/0x70 [sctp]
          [<ffffffffa047e8de>] sctp_rcv+0x82e/0x9a0 [sctp]
          [<ffffffff815abd38>] ip_local_deliver_finish+0xa8/0x210
          [<ffffffff815a64af>] nf_reinject+0xbf/0x180
          [<ffffffffa04b4762>] nfqnl_recv_verdict+0x1d2/0x2b0 [nfnetlink_queue]
          [<ffffffffa04aa40b>] nfnetlink_rcv_msg+0x14b/0x250 [nfnetlink]
          [<ffffffff815a3269>] netlink_rcv_skb+0xa9/0xc0
          [<ffffffffa04aa7cf>] nfnetlink_rcv+0x23f/0x408 [nfnetlink]
          [<ffffffff815a2bd8>] netlink_unicast+0x168/0x250
          [<ffffffff815a2fa1>] netlink_sendmsg+0x2e1/0x3f0
          [<ffffffff8155cc6b>] sock_sendmsg+0x8b/0xc0
          [<ffffffff8155d449>] ___sys_sendmsg+0x369/0x380
      
      What happens is that commit bbd0d598 clones the skb containing
      the AUTH chunk in sctp_endpoint_bh_rcv() when having the edge case
      that an endpoint requires COOKIE-ECHO chunks to be authenticated:
      
        ---------- INIT[RANDOM; CHUNKS; HMAC-ALGO] ---------->
        <------- INIT-ACK[RANDOM; CHUNKS; HMAC-ALGO] ---------
        ------------------ AUTH; COOKIE-ECHO ---------------->
        <-------------------- COOKIE-ACK ---------------------
      
      When we enter sctp_sf_do_5_1D_ce() and before we actually get to
      the point where we process (and subsequently free) a non-NULL
      chunk->auth_chunk, we could hit the "goto nomem_init" path from
      an error condition and thus leave the cloned skb around w/o
      freeing it.
      
      The fix is to centrally free such clones in sctp_chunk_destroy()
      handler that is invoked from sctp_chunk_free() after all refs have
      dropped; and also move both kfree_skb(chunk->auth_chunk) there,
      so that chunk->auth_chunk is either NULL (since sctp_chunkify()
      allocs new chunks through kmem_cache_zalloc()) or non-NULL with
      a valid skb pointer. chunk->skb and chunk->auth_chunk are the
      only skbs in the sctp_chunk structure that need to be handeled.
      
      While at it, we should use consume_skb() for both. It is the same
      as dev_kfree_skb() but more appropriately named as we are not
      a device but a protocol. Also, this effectively replaces the
      kfree_skb() from both invocations into consume_skb(). Functions
      are the same only that kfree_skb() assumes that the frame was
      being dropped after a failure (e.g. for tools like drop monitor),
      usage of consume_skb() seems more appropriate in function
      sctp_chunk_destroy() though.
      
      Fixes: bbd0d598 ("[SCTP]: Implement the receive and verification of AUTH chunk")
      Signed-off-by: NDaniel Borkmann <dborkman@redhat.com>
      Cc: Vlad Yasevich <yasevich@gmail.com>
      Cc: Neil Horman <nhorman@tuxdriver.com>
      Acked-by: NVlad Yasevich <vyasevich@gmail.com>
      Acked-by: NNeil Horman <nhorman@tuxdriver.com>
      Signed-off-by: NDavid S. Miller <davem@davemloft.net>
      c485658b
  21. 04 3月, 2014 1 次提交
    • D
      net: sctp: fix sctp_sf_do_5_1D_ce to verify if we/peer is AUTH capable · ec0223ec
      Daniel Borkmann 提交于
      RFC4895 introduced AUTH chunks for SCTP; during the SCTP
      handshake RANDOM; CHUNKS; HMAC-ALGO are negotiated (CHUNKS
      being optional though):
      
        ---------- INIT[RANDOM; CHUNKS; HMAC-ALGO] ---------->
        <------- INIT-ACK[RANDOM; CHUNKS; HMAC-ALGO] ---------
        -------------------- COOKIE-ECHO -------------------->
        <-------------------- COOKIE-ACK ---------------------
      
      A special case is when an endpoint requires COOKIE-ECHO
      chunks to be authenticated:
      
        ---------- INIT[RANDOM; CHUNKS; HMAC-ALGO] ---------->
        <------- INIT-ACK[RANDOM; CHUNKS; HMAC-ALGO] ---------
        ------------------ AUTH; COOKIE-ECHO ---------------->
        <-------------------- COOKIE-ACK ---------------------
      
      RFC4895, section 6.3. Receiving Authenticated Chunks says:
      
        The receiver MUST use the HMAC algorithm indicated in
        the HMAC Identifier field. If this algorithm was not
        specified by the receiver in the HMAC-ALGO parameter in
        the INIT or INIT-ACK chunk during association setup, the
        AUTH chunk and all the chunks after it MUST be discarded
        and an ERROR chunk SHOULD be sent with the error cause
        defined in Section 4.1. [...] If no endpoint pair shared
        key has been configured for that Shared Key Identifier,
        all authenticated chunks MUST be silently discarded. [...]
      
        When an endpoint requires COOKIE-ECHO chunks to be
        authenticated, some special procedures have to be followed
        because the reception of a COOKIE-ECHO chunk might result
        in the creation of an SCTP association. If a packet arrives
        containing an AUTH chunk as a first chunk, a COOKIE-ECHO
        chunk as the second chunk, and possibly more chunks after
        them, and the receiver does not have an STCB for that
        packet, then authentication is based on the contents of
        the COOKIE-ECHO chunk. In this situation, the receiver MUST
        authenticate the chunks in the packet by using the RANDOM
        parameters, CHUNKS parameters and HMAC_ALGO parameters
        obtained from the COOKIE-ECHO chunk, and possibly a local
        shared secret as inputs to the authentication procedure
        specified in Section 6.3. If authentication fails, then
        the packet is discarded. If the authentication is successful,
        the COOKIE-ECHO and all the chunks after the COOKIE-ECHO
        MUST be processed. If the receiver has an STCB, it MUST
        process the AUTH chunk as described above using the STCB
        from the existing association to authenticate the
        COOKIE-ECHO chunk and all the chunks after it. [...]
      
      Commit bbd0d598 introduced the possibility to receive
      and verification of AUTH chunk, including the edge case for
      authenticated COOKIE-ECHO. On reception of COOKIE-ECHO,
      the function sctp_sf_do_5_1D_ce() handles processing,
      unpacks and creates a new association if it passed sanity
      checks and also tests for authentication chunks being
      present. After a new association has been processed, it
      invokes sctp_process_init() on the new association and
      walks through the parameter list it received from the INIT
      chunk. It checks SCTP_PARAM_RANDOM, SCTP_PARAM_HMAC_ALGO
      and SCTP_PARAM_CHUNKS, and copies them into asoc->peer
      meta data (peer_random, peer_hmacs, peer_chunks) in case
      sysctl -w net.sctp.auth_enable=1 is set. If in INIT's
      SCTP_PARAM_SUPPORTED_EXT parameter SCTP_CID_AUTH is set,
      peer_random != NULL and peer_hmacs != NULL the peer is to be
      assumed asoc->peer.auth_capable=1, in any other case
      asoc->peer.auth_capable=0.
      
      Now, if in sctp_sf_do_5_1D_ce() chunk->auth_chunk is
      available, we set up a fake auth chunk and pass that on to
      sctp_sf_authenticate(), which at latest in
      sctp_auth_calculate_hmac() reliably dereferences a NULL pointer
      at position 0..0008 when setting up the crypto key in
      crypto_hash_setkey() by using asoc->asoc_shared_key that is
      NULL as condition key_id == asoc->active_key_id is true if
      the AUTH chunk was injected correctly from remote. This
      happens no matter what net.sctp.auth_enable sysctl says.
      
      The fix is to check for net->sctp.auth_enable and for
      asoc->peer.auth_capable before doing any operations like
      sctp_sf_authenticate() as no key is activated in
      sctp_auth_asoc_init_active_key() for each case.
      
      Now as RFC4895 section 6.3 states that if the used HMAC-ALGO
      passed from the INIT chunk was not used in the AUTH chunk, we
      SHOULD send an error; however in this case it would be better
      to just silently discard such a maliciously prepared handshake
      as we didn't even receive a parameter at all. Also, as our
      endpoint has no shared key configured, section 6.3 says that
      MUST silently discard, which we are doing from now onwards.
      
      Before calling sctp_sf_pdiscard(), we need not only to free
      the association, but also the chunk->auth_chunk skb, as
      commit bbd0d598 created a skb clone in that case.
      
      I have tested this locally by using netfilter's nfqueue and
      re-injecting packets into the local stack after maliciously
      modifying the INIT chunk (removing RANDOM; HMAC-ALGO param)
      and the SCTP packet containing the COOKIE_ECHO (injecting
      AUTH chunk before COOKIE_ECHO). Fixed with this patch applied.
      
      Fixes: bbd0d598 ("[SCTP]: Implement the receive and verification of AUTH chunk")
      Signed-off-by: NDaniel Borkmann <dborkman@redhat.com>
      Cc: Vlad Yasevich <yasevich@gmail.com>
      Cc: Neil Horman <nhorman@tuxdriver.com>
      Acked-by: NVlad Yasevich <vyasevich@gmail.com>
      Signed-off-by: NDavid S. Miller <davem@davemloft.net>
      ec0223ec
  22. 17 2月, 2014 1 次提交
    • M
      net: sctp: Fix a_rwnd/rwnd management to reflect real state of the receiver's buffer · ef2820a7
      Matija Glavinic Pecotic 提交于
      Implementation of (a)rwnd calculation might lead to severe performance issues
      and associations completely stalling. These problems are described and solution
      is proposed which improves lksctp's robustness in congestion state.
      
      1) Sudden drop of a_rwnd and incomplete window recovery afterwards
      
      Data accounted in sctp_assoc_rwnd_decrease takes only payload size (sctp data),
      but size of sk_buff, which is blamed against receiver buffer, is not accounted
      in rwnd. Theoretically, this should not be the problem as actual size of buffer
      is double the amount requested on the socket (SO_RECVBUF). Problem here is
      that this will have bad scaling for data which is less then sizeof sk_buff.
      E.g. in 4G (LTE) networks, link interfacing radio side will have a large portion
      of traffic of this size (less then 100B).
      
      An example of sudden drop and incomplete window recovery is given below. Node B
      exhibits problematic behavior. Node A initiates association and B is configured
      to advertise rwnd of 10000. A sends messages of size 43B (size of typical sctp
      message in 4G (LTE) network). On B data is left in buffer by not reading socket
      in userspace.
      
      Lets examine when we will hit pressure state and declare rwnd to be 0 for
      scenario with above stated parameters (rwnd == 10000, chunk size == 43, each
      chunk is sent in separate sctp packet)
      
      Logic is implemented in sctp_assoc_rwnd_decrease:
      
      socket_buffer (see below) is maximum size which can be held in socket buffer
      (sk_rcvbuf). current_alloced is amount of data currently allocated (rx_count)
      
      A simple expression is given for which it will be examined after how many
      packets for above stated parameters we enter pressure state:
      
      We start by condition which has to be met in order to enter pressure state:
      
      	socket_buffer < currently_alloced;
      
      currently_alloced is represented as size of sctp packets received so far and not
      yet delivered to userspace. x is the number of chunks/packets (since there is no
      bundling, and each chunk is delivered in separate packet, we can observe each
      chunk also as sctp packet, and what is important here, having its own sk_buff):
      
      	socket_buffer < x*each_sctp_packet;
      
      each_sctp_packet is sctp chunk size + sizeof(struct sk_buff). socket_buffer is
      twice the amount of initially requested size of socket buffer, which is in case
      of sctp, twice the a_rwnd requested:
      
      	2*rwnd < x*(payload+sizeof(struc sk_buff));
      
      sizeof(struct sk_buff) is 190 (3.13.0-rc4+). Above is stated that rwnd is 10000
      and each payload size is 43
      
      	20000 < x(43+190);
      
      	x > 20000/233;
      
      	x ~> 84;
      
      After ~84 messages, pressure state is entered and 0 rwnd is advertised while
      received 84*43B ~= 3612B sctp data. This is why external observer notices sudden
      drop from 6474 to 0, as it will be now shown in example:
      
      IP A.34340 > B.12345: sctp (1) [INIT] [init tag: 1875509148] [rwnd: 81920] [OS: 10] [MIS: 65535] [init TSN: 1096057017]
      IP B.12345 > A.34340: sctp (1) [INIT ACK] [init tag: 3198966556] [rwnd: 10000] [OS: 10] [MIS: 10] [init TSN: 902132839]
      IP A.34340 > B.12345: sctp (1) [COOKIE ECHO]
      IP B.12345 > A.34340: sctp (1) [COOKIE ACK]
      IP A.34340 > B.12345: sctp (1) [DATA] (B)(E) [TSN: 1096057017] [SID: 0] [SSEQ 0] [PPID 0x18]
      IP B.12345 > A.34340: sctp (1) [SACK] [cum ack 1096057017] [a_rwnd 9957] [#gap acks 0] [#dup tsns 0]
      IP A.34340 > B.12345: sctp (1) [DATA] (B)(E) [TSN: 1096057018] [SID: 0] [SSEQ 1] [PPID 0x18]
      IP B.12345 > A.34340: sctp (1) [SACK] [cum ack 1096057018] [a_rwnd 9957] [#gap acks 0] [#dup tsns 0]
      IP A.34340 > B.12345: sctp (1) [DATA] (B)(E) [TSN: 1096057019] [SID: 0] [SSEQ 2] [PPID 0x18]
      IP B.12345 > A.34340: sctp (1) [SACK] [cum ack 1096057019] [a_rwnd 9914] [#gap acks 0] [#dup tsns 0]
      <...>
      IP A.34340 > B.12345: sctp (1) [DATA] (B)(E) [TSN: 1096057098] [SID: 0] [SSEQ 81] [PPID 0x18]
      IP B.12345 > A.34340: sctp (1) [SACK] [cum ack 1096057098] [a_rwnd 6517] [#gap acks 0] [#dup tsns 0]
      IP A.34340 > B.12345: sctp (1) [DATA] (B)(E) [TSN: 1096057099] [SID: 0] [SSEQ 82] [PPID 0x18]
      IP B.12345 > A.34340: sctp (1) [SACK] [cum ack 1096057099] [a_rwnd 6474] [#gap acks 0] [#dup tsns 0]
      IP A.34340 > B.12345: sctp (1) [DATA] (B)(E) [TSN: 1096057100] [SID: 0] [SSEQ 83] [PPID 0x18]
      
      --> Sudden drop
      
      IP B.12345 > A.34340: sctp (1) [SACK] [cum ack 1096057100] [a_rwnd 0] [#gap acks 0] [#dup tsns 0]
      
      At this point, rwnd_press stores current rwnd value so it can be later restored
      in sctp_assoc_rwnd_increase. This however doesn't happen as condition to start
      slowly increasing rwnd until rwnd_press is returned to rwnd is never met. This
      condition is not met since rwnd, after it hit 0, must first reach rwnd_press by
      adding amount which is read from userspace. Let us observe values in above
      example. Initial a_rwnd is 10000, pressure was hit when rwnd was ~6500 and the
      amount of actual sctp data currently waiting to be delivered to userspace
      is ~3500. When userspace starts to read, sctp_assoc_rwnd_increase will be blamed
      only for sctp data, which is ~3500. Condition is never met, and when userspace
      reads all data, rwnd stays on 3569.
      
      IP B.12345 > A.34340: sctp (1) [SACK] [cum ack 1096057100] [a_rwnd 1505] [#gap acks 0] [#dup tsns 0]
      IP B.12345 > A.34340: sctp (1) [SACK] [cum ack 1096057100] [a_rwnd 3010] [#gap acks 0] [#dup tsns 0]
      IP A.34340 > B.12345: sctp (1) [DATA] (B)(E) [TSN: 1096057101] [SID: 0] [SSEQ 84] [PPID 0x18]
      IP B.12345 > A.34340: sctp (1) [SACK] [cum ack 1096057101] [a_rwnd 3569] [#gap acks 0] [#dup tsns 0]
      
      --> At this point userspace read everything, rwnd recovered only to 3569
      
      IP A.34340 > B.12345: sctp (1) [DATA] (B)(E) [TSN: 1096057102] [SID: 0] [SSEQ 85] [PPID 0x18]
      IP B.12345 > A.34340: sctp (1) [SACK] [cum ack 1096057102] [a_rwnd 3569] [#gap acks 0] [#dup tsns 0]
      
      Reproduction is straight forward, it is enough for sender to send packets of
      size less then sizeof(struct sk_buff) and receiver keeping them in its buffers.
      
      2) Minute size window for associations sharing the same socket buffer
      
      In case multiple associations share the same socket, and same socket buffer
      (sctp.rcvbuf_policy == 0), different scenarios exist in which congestion on one
      of the associations can permanently drop rwnd of other association(s).
      
      Situation will be typically observed as one association suddenly having rwnd
      dropped to size of last packet received and never recovering beyond that point.
      Different scenarios will lead to it, but all have in common that one of the
      associations (let it be association from 1)) nearly depleted socket buffer, and
      the other association blames socket buffer just for the amount enough to start
      the pressure. This association will enter pressure state, set rwnd_press and
      announce 0 rwnd.
      When data is read by userspace, similar situation as in 1) will occur, rwnd will
      increase just for the size read by userspace but rwnd_press will be high enough
      so that association doesn't have enough credit to reach rwnd_press and restore
      to previous state. This case is special case of 1), being worse as there is, in
      the worst case, only one packet in buffer for which size rwnd will be increased.
      Consequence is association which has very low maximum rwnd ('minute size', in
      our case down to 43B - size of packet which caused pressure) and as such
      unusable.
      
      Scenario happened in the field and labs frequently after congestion state (link
      breaks, different probabilities of packet drop, packet reordering) and with
      scenario 1) preceding. Here is given a deterministic scenario for reproduction:
      
      >From node A establish two associations on the same socket, with rcvbuf_policy
      being set to share one common buffer (sctp.rcvbuf_policy == 0). On association 1
      repeat scenario from 1), that is, bring it down to 0 and restore up. Observe
      scenario 1). Use small payload size (here we use 43). Once rwnd is 'recovered',
      bring it down close to 0, as in just one more packet would close it. This has as
      a consequence that association number 2 is able to receive (at least) one more
      packet which will bring it in pressure state. E.g. if association 2 had rwnd of
      10000, packet received was 43, and we enter at this point into pressure,
      rwnd_press will have 9957. Once payload is delivered to userspace, rwnd will
      increase for 43, but conditions to restore rwnd to original state, just as in
      1), will never be satisfied.
      
      --> Association 1, between A.y and B.12345
      
      IP A.55915 > B.12345: sctp (1) [INIT] [init tag: 836880897] [rwnd: 10000] [OS: 10] [MIS: 65535] [init TSN: 4032536569]
      IP B.12345 > A.55915: sctp (1) [INIT ACK] [init tag: 2873310749] [rwnd: 81920] [OS: 10] [MIS: 10] [init TSN: 3799315613]
      IP A.55915 > B.12345: sctp (1) [COOKIE ECHO]
      IP B.12345 > A.55915: sctp (1) [COOKIE ACK]
      
      --> Association 2, between A.z and B.12346
      
      IP A.55915 > B.12346: sctp (1) [INIT] [init tag: 534798321] [rwnd: 10000] [OS: 10] [MIS: 65535] [init TSN: 2099285173]
      IP B.12346 > A.55915: sctp (1) [INIT ACK] [init tag: 516668823] [rwnd: 81920] [OS: 10] [MIS: 10] [init TSN: 3676403240]
      IP A.55915 > B.12346: sctp (1) [COOKIE ECHO]
      IP B.12346 > A.55915: sctp (1) [COOKIE ACK]
      
      --> Deplete socket buffer by sending messages of size 43B over association 1
      
      IP B.12345 > A.55915: sctp (1) [DATA] (B)(E) [TSN: 3799315613] [SID: 0] [SSEQ 0] [PPID 0x18]
      IP A.55915 > B.12345: sctp (1) [SACK] [cum ack 3799315613] [a_rwnd 9957] [#gap acks 0] [#dup tsns 0]
      
      <...>
      
      IP A.55915 > B.12345: sctp (1) [SACK] [cum ack 3799315696] [a_rwnd 6388] [#gap acks 0] [#dup tsns 0]
      IP B.12345 > A.55915: sctp (1) [DATA] (B)(E) [TSN: 3799315697] [SID: 0] [SSEQ 84] [PPID 0x18]
      IP A.55915 > B.12345: sctp (1) [SACK] [cum ack 3799315697] [a_rwnd 6345] [#gap acks 0] [#dup tsns 0]
      
      --> Sudden drop on 1
      
      IP B.12345 > A.55915: sctp (1) [DATA] (B)(E) [TSN: 3799315698] [SID: 0] [SSEQ 85] [PPID 0x18]
      IP A.55915 > B.12345: sctp (1) [SACK] [cum ack 3799315698] [a_rwnd 0] [#gap acks 0] [#dup tsns 0]
      
      --> Here userspace read, rwnd 'recovered' to 3698, now deplete again using
          association 1 so there is place in buffer for only one more packet
      
      IP B.12345 > A.55915: sctp (1) [DATA] (B)(E) [TSN: 3799315799] [SID: 0] [SSEQ 186] [PPID 0x18]
      IP A.55915 > B.12345: sctp (1) [SACK] [cum ack 3799315799] [a_rwnd 86] [#gap acks 0] [#dup tsns 0]
      IP B.12345 > A.55915: sctp (1) [DATA] (B)(E) [TSN: 3799315800] [SID: 0] [SSEQ 187] [PPID 0x18]
      IP A.55915 > B.12345: sctp (1) [SACK] [cum ack 3799315800] [a_rwnd 43] [#gap acks 0] [#dup tsns 0]
      
      --> Socket buffer is almost depleted, but there is space for one more packet,
          send them over association 2, size 43B
      
      IP B.12346 > A.55915: sctp (1) [DATA] (B)(E) [TSN: 3676403240] [SID: 0] [SSEQ 0] [PPID 0x18]
      IP A.55915 > B.12346: sctp (1) [SACK] [cum ack 3676403240] [a_rwnd 0] [#gap acks 0] [#dup tsns 0]
      
      --> Immediate drop
      
      IP A.60995 > B.12346: sctp (1) [SACK] [cum ack 387491510] [a_rwnd 0] [#gap acks 0] [#dup tsns 0]
      
      --> Read everything from the socket, both association recover up to maximum rwnd
          they are capable of reaching, note that association 1 recovered up to 3698,
          and association 2 recovered only to 43
      
      IP A.55915 > B.12345: sctp (1) [SACK] [cum ack 3799315800] [a_rwnd 1548] [#gap acks 0] [#dup tsns 0]
      IP A.55915 > B.12345: sctp (1) [SACK] [cum ack 3799315800] [a_rwnd 3053] [#gap acks 0] [#dup tsns 0]
      IP B.12345 > A.55915: sctp (1) [DATA] (B)(E) [TSN: 3799315801] [SID: 0] [SSEQ 188] [PPID 0x18]
      IP A.55915 > B.12345: sctp (1) [SACK] [cum ack 3799315801] [a_rwnd 3698] [#gap acks 0] [#dup tsns 0]
      IP B.12346 > A.55915: sctp (1) [DATA] (B)(E) [TSN: 3676403241] [SID: 0] [SSEQ 1] [PPID 0x18]
      IP A.55915 > B.12346: sctp (1) [SACK] [cum ack 3676403241] [a_rwnd 43] [#gap acks 0] [#dup tsns 0]
      
      A careful reader might wonder why it is necessary to reproduce 1) prior
      reproduction of 2). It is simply easier to observe when to send packet over
      association 2 which will push association into the pressure state.
      
      Proposed solution:
      
      Both problems share the same root cause, and that is improper scaling of socket
      buffer with rwnd. Solution in which sizeof(sk_buff) is taken into concern while
      calculating rwnd is not possible due to fact that there is no linear
      relationship between amount of data blamed in increase/decrease with IP packet
      in which payload arrived. Even in case such solution would be followed,
      complexity of the code would increase. Due to nature of current rwnd handling,
      slow increase (in sctp_assoc_rwnd_increase) of rwnd after pressure state is
      entered is rationale, but it gives false representation to the sender of current
      buffer space. Furthermore, it implements additional congestion control mechanism
      which is defined on implementation, and not on standard basis.
      
      Proposed solution simplifies whole algorithm having on mind definition from rfc:
      
      o  Receiver Window (rwnd): This gives the sender an indication of the space
         available in the receiver's inbound buffer.
      
      Core of the proposed solution is given with these lines:
      
      sctp_assoc_rwnd_update:
      	if ((asoc->base.sk->sk_rcvbuf - rx_count) > 0)
      		asoc->rwnd = (asoc->base.sk->sk_rcvbuf - rx_count) >> 1;
      	else
      		asoc->rwnd = 0;
      
      We advertise to sender (half of) actual space we have. Half is in the braces
      depending whether you would like to observe size of socket buffer as SO_RECVBUF
      or twice the amount, i.e. size is the one visible from userspace, that is,
      from kernelspace.
      In this way sender is given with good approximation of our buffer space,
      regardless of the buffer policy - we always advertise what we have. Proposed
      solution fixes described problems and removes necessity for rwnd restoration
      algorithm. Finally, as proposed solution is simplification, some lines of code,
      along with some bytes in struct sctp_association are saved.
      
      Version 2 of the patch addressed comments from Vlad. Name of the function is set
      to be more descriptive, and two parts of code are changed, in one removing the
      superfluous call to sctp_assoc_rwnd_update since call would not result in update
      of rwnd, and the other being reordering of the code in a way that call to
      sctp_assoc_rwnd_update updates rwnd. Version 3 corrected change introduced in v2
      in a way that existing function is not reordered/copied in line, but it is
      correctly called. Thanks Vlad for suggesting.
      Signed-off-by: NMatija Glavinic Pecotic <matija.glavinic-pecotic.ext@nsn.com>
      Reviewed-by: NAlexander Sverdlin <alexander.sverdlin@nsn.com>
      Acked-by: NVlad Yasevich <vyasevich@gmail.com>
      Signed-off-by: NDavid S. Miller <davem@davemloft.net>
      ef2820a7
  23. 27 12月, 2013 3 次提交
  24. 11 12月, 2013 1 次提交
    • N
      sctp: properly latch and use autoclose value from sock to association · 9f70f46b
      Neil Horman 提交于
      Currently, sctp associations latch a sockets autoclose value to an association
      at association init time, subject to capping constraints from the max_autoclose
      sysctl value.  This leads to an odd situation where an application may set a
      socket level autoclose timeout, but sliently sctp will limit the autoclose
      timeout to something less than that.
      
      Fix this by modifying the autoclose setsockopt function to check the limit, cap
      it and warn the user via syslog that the timeout is capped.  This will allow
      getsockopt to return valid autoclose timeout values that reflect what subsequent
      associations actually use.
      
      While were at it, also elimintate the assoc->autoclose variable, it duplicates
      whats in the timeout array, which leads to multiple sources for the same
      information, that may differ (as the former isn't subject to any capping).  This
      gives us the timeout information in a canonical place and saves some space in
      the association structure as well.
      Signed-off-by: NNeil Horman <nhorman@tuxdriver.com>
      Acked-by: NVlad Yasevich <vyasevich@gmail.com>
      CC: Wang Weidong <wangweidong1@huawei.com>
      CC: David Miller <davem@davemloft.net>
      CC: Vlad Yasevich <vyasevich@gmail.com>
      CC: netdev@vger.kernel.org
      Signed-off-by: NDavid S. Miller <davem@davemloft.net>
      9f70f46b
  25. 07 12月, 2013 1 次提交
  26. 10 8月, 2013 1 次提交
  27. 25 7月, 2013 1 次提交
  28. 02 7月, 2013 1 次提交
    • D
      net: sctp: rework debugging framework to use pr_debug and friends · bb33381d
      Daniel Borkmann 提交于
      We should get rid of all own SCTP debug printk macros and use the ones
      that the kernel offers anyway instead. This makes the code more readable
      and conform to the kernel code, and offers all the features of dynamic
      debbuging that pr_debug() et al has, such as only turning on/off portions
      of debug messages at runtime through debugfs. The runtime cost of having
      CONFIG_DYNAMIC_DEBUG enabled, but none of the debug statements printing,
      is negligible [1]. If kernel debugging is completly turned off, then these
      statements will also compile into "empty" functions.
      
      While we're at it, we also need to change the Kconfig option as it /now/
      only refers to the ifdef'ed code portions in outqueue.c that enable further
      debugging/tracing of SCTP transaction fields. Also, since SCTP_ASSERT code
      was enabled with this Kconfig option and has now been removed, we
      transform those code parts into WARNs resp. where appropriate BUG_ONs so
      that those bugs can be more easily detected as probably not many people
      have SCTP debugging permanently turned on.
      
      To turn on all SCTP debugging, the following steps are needed:
      
       # mount -t debugfs none /sys/kernel/debug
       # echo -n 'module sctp +p' > /sys/kernel/debug/dynamic_debug/control
      
      This can be done more fine-grained on a per file, per line basis and others
      as described in [2].
      
       [1] https://www.kernel.org/doc/ols/2009/ols2009-pages-39-46.pdf
       [2] Documentation/dynamic-debug-howto.txt
      Signed-off-by: NDaniel Borkmann <dborkman@redhat.com>
      Signed-off-by: NDavid S. Miller <davem@davemloft.net>
      bb33381d
  29. 15 6月, 2013 1 次提交
  30. 13 3月, 2013 1 次提交
  31. 28 1月, 2013 1 次提交
    • X
      sctp: set association state to established in dupcook_a handler · 9839ff0d
      Xufeng Zhang 提交于
      While sctp handling a duplicate COOKIE-ECHO and the action is
      'Association restart', sctp_sf_do_dupcook_a() will processing
      the unexpected COOKIE-ECHO for peer restart, but it does not set
      the association state to SCTP_STATE_ESTABLISHED, so the association
      could stuck in SCTP_STATE_SHUTDOWN_PENDING state forever.
      This violates the sctp specification:
        RFC 4960 5.2.4. Handle a COOKIE ECHO when a TCB Exists
        Action
        A) In this case, the peer may have restarted. .....
           After this, the endpoint shall enter the ESTABLISHED state.
      
      To resolve this problem, adding a SCTP_CMD_NEW_STATE cmd to the
      command list before SCTP_CMD_REPLY cmd, this will set the restart
      association to SCTP_STATE_ESTABLISHED state properly and also avoid
      I-bit being set in the DATA chunk header when COOKIE_ACK is bundled
      with DATA chunks.
      Signed-off-by: NXufeng Zhang <xufeng.zhang@windriver.com>
      Acked-by: NNeil Horman <nhorman@tuxdriver.com>
      Acked-by: NVlad Yasevich <vyasevich@gmail.com>
      Signed-off-by: NDavid S. Miller <davem@davemloft.net>
      9839ff0d