1. 27 8月, 2011 34 次提交
  2. 25 8月, 2011 6 次提交
    • F
      sunbmac: use standard #defines from mii.h. · cd296780
      Francois Romieu 提交于
      Signed-off-by: NFrancois Romieu <romieu@fr.zoreil.com>
      cd296780
    • F
      dl2k: use standard #defines from mii.h. · 78f6a6bd
      Francois Romieu 提交于
      Signed-off-by: NFrancois Romieu <romieu@fr.zoreil.com>
      78f6a6bd
    • T
      Scm: Remove unnecessary pid & credential references in Unix socket's send and receive path · 0856a304
      Tim Chen 提交于
      Patch series 109f6e39..7361c36c back in 2.6.36 added functionality to
      allow credentials to work across pid namespaces for packets sent via
      UNIX sockets.  However, the atomic reference counts on pid and
      credentials caused plenty of cache bouncing when there are numerous
      threads of the same pid sharing a UNIX socket.  This patch mitigates the
      problem by eliminating extraneous reference counts on pid and
      credentials on both send and receive path of UNIX sockets. I found a 2x
      improvement in hackbench's threaded case.
      
      On the receive path in unix_dgram_recvmsg, currently there is an
      increment of reference count on pid and credentials in scm_set_cred.
      Then there are two decrement of the reference counts.  Once in scm_recv
      and once when skb_free_datagram call skb->destructor function
      unix_destruct_scm.  One pair of increment and decrement of ref count on
      pid and credentials can be eliminated from the receive path.  Until we
      destroy the skb, we already set a reference when we created the skb on
      the send side.
      
      On the send path, there are two increments of ref count on pid and
      credentials, once in scm_send and once in unix_scm_to_skb.  Then there
      is a decrement of the reference counts in scm_destroy's call to
      scm_destroy_cred at the end of unix_dgram_sendmsg functions.   One pair
      of increment and decrement of the reference counts can be removed so we
      only need to increment the ref counts once.
      
      By incorporating these changes, for hackbench running on a 4 socket
      NHM-EX machine with 40 cores, the execution of hackbench on
      50 groups of 20 threads sped up by factor of 2.
      
      Hackbench command used for testing:
      ./hackbench 50 thread 2000
      Signed-off-by: NTim Chen <tim.c.chen@linux.intel.com>
      Signed-off-by: NDavid S. Miller <davem@davemloft.net>
      0856a304
    • M
      sctp: Bundle HEAERTBEAT into ASCONF_ACK · 6af29ccc
      Michio Honda 提交于
      With this patch a HEARTBEAT chunk is bundled into the ASCONF-ACK
      for ADD IP ADDRESS, confirming the new destination as quickly as
      possible.
      Signed-off-by: NMichio Honda <micchie@sfc.wide.ad.jp>
      Signed-off-by: NDavid S. Miller <davem@davemloft.net>
      6af29ccc
    • M
      sctp: HEARTBEAT negotiation after ASCONF · f207c050
      Michio Honda 提交于
      This patch fixes BUG that the ASCONF receiver transmits DATA chunks
      to the newly added UNCONFIRMED destination.
      Signed-off-by: NMichio Honda <micchie@sfc.wide.ad.jp>
      Signed-off-by: NDavid S. Miller <davem@davemloft.net>
      f207c050
    • N
      Proportional Rate Reduction for TCP. · a262f0cd
      Nandita Dukkipati 提交于
      This patch implements Proportional Rate Reduction (PRR) for TCP.
      PRR is an algorithm that determines TCP's sending rate in fast
      recovery. PRR avoids excessive window reductions and aims for
      the actual congestion window size at the end of recovery to be as
      close as possible to the window determined by the congestion control
      algorithm. PRR also improves accuracy of the amount of data sent
      during loss recovery.
      
      The patch implements the recommended flavor of PRR called PRR-SSRB
      (Proportional rate reduction with slow start reduction bound) and
      replaces the existing rate halving algorithm. PRR improves upon the
      existing Linux fast recovery under a number of conditions including:
        1) burst losses where the losses implicitly reduce the amount of
      outstanding data (pipe) below the ssthresh value selected by the
      congestion control algorithm and,
        2) losses near the end of short flows where application runs out of
      data to send.
      
      As an example, with the existing rate halving implementation a single
      loss event can cause a connection carrying short Web transactions to
      go into the slow start mode after the recovery. This is because during
      recovery Linux pulls the congestion window down to packets_in_flight+1
      on every ACK. A short Web response often runs out of new data to send
      and its pipe reduces to zero by the end of recovery when all its packets
      are drained from the network. Subsequent HTTP responses using the same
      connection will have to slow start to raise cwnd to ssthresh. PRR on
      the other hand aims for the cwnd to be as close as possible to ssthresh
      by the end of recovery.
      
      A description of PRR and a discussion of its performance can be found at
      the following links:
      - IETF Draft:
          http://tools.ietf.org/html/draft-mathis-tcpm-proportional-rate-reduction-01
      - IETF Slides:
          http://www.ietf.org/proceedings/80/slides/tcpm-6.pdf
          http://tools.ietf.org/agenda/81/slides/tcpm-2.pdf
      - Paper to appear in Internet Measurements Conference (IMC) 2011:
          Improving TCP Loss Recovery
          Nandita Dukkipati, Matt Mathis, Yuchung Cheng
      Signed-off-by: NNandita Dukkipati <nanditad@google.com>
      Signed-off-by: NDavid S. Miller <davem@davemloft.net>
      a262f0cd