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NAME

       FQ-PIE - Flow Queue Proportional Integral controller Enhanced

SYNOPSIS

       tc qdisc ... fq_pie [ limit PACKETS ] [ flows NUMBER ]
                           [ target TIME ] [ tupdate TIME ]
                           [ alpha NUMBER ] [ beta NUMBER ]
                           [ quantum BYTES ] [ memory_limit BYTES ]
                           [ ecn_prob PERENTAGE ] [ [no]ecn ]
                           [ [no]bytemode ] [ [no_]dq_rate_estimator ]

DESCRIPTION

       FQ-PIE  (Flow  Queuing  with  Proportional  Integral  controller  Enhanced)  is  a queuing
       discipline that combines Flow Queuing with the PIE AQM scheme. FQ-PIE uses a Jenkins  hash
       function  to  classify incoming packets into different flows and is used to provide a fair
       share of the bandwidth to all the flows using the qdisc. Each such flow is managed by  the
       PIE algorithm.

ALGORITHM

       The  FQ-PIE  algorithm  consists  of  two logical parts: the scheduler which selects which
       queue to dequeue a packet from, and the PIE AQM which works on each  of  the  queues.  The
       major  work  of  FQ-PIE  is  mostly  in  the  scheduling part. The interaction between the
       scheduler and the PIE algorithm is straight forward.

       During the enqueue stage, a hashing-based scheme is used, where flows are  hashed  into  a
       number  of  buckets  with  each  bucket  having  its  own  queue. The number of buckets is
       configurable, and presently defaults to 1024 in the implementation.  The flow  hashing  is
       performed  on  the  5-tuple  of  source  and destination IP addresses, port numbers and IP
       protocol number. Once the packet has been successfully classified  into  a  queue,  it  is
       handed  over  to  the  PIE  algorithm  for  enqueuing. It is then added to the tail of the
       selected queue, and the queue's byte count is updated by the packet size. If the queue  is
       not  currently  active  (i.e.,  if  it is not in either the list of new or the list of old
       queues) , it is added to the end of the list of new queues, and its number of  credits  is
       initiated  to  the  configured  quantum. Otherwise, the queue is left in its current queue
       list.

       During the dequeue stage, the scheduler first looks at the list of  new  queues;  for  the
       queue  at  the head of that list, if that queue has a negative number of credits (i.e., it
       has already dequeued at least a quantum of bytes), it is given an  additional  quantum  of
       credits,  the queue is put onto the end of the list of old queues, and the routine selects
       the next queue and starts again. Otherwise, that queue is selected for dequeue  again.  If
       the list of new queues is empty, the scheduler proceeds down the list of old queues in the
       same fashion (checking the credits, and either  selecting  the  queue  for  dequeuing,  or
       adding credits and putting the queue back at the end of the list). After having selected a
       queue from which to dequeue a packet, the PIE algorithm is invoked on that queue.

       Finally, if the PIE algorithm does not return a packet, then the queue must be  empty  and
       the scheduler does one of two things:

       If the queue selected for dequeue came from the list of new queues, it is moved to the end
       of the list of old queues. If instead it came from the list of old queues, that  queue  is
       removed  from  the  list, to be added back (as a new queue) the next time a packet arrives
       that hashes to that queue. Then (since no packet was available  for  dequeue),  the  whole
       dequeue process is restarted from the beginning.

       If,  instead, the scheduler did get a packet back from the PIE algorithm, it subtracts the
       size of the packet from the byte credits for the selected queue and returns the packet  as
       the result of the dequeue operation.

PARAMETERS

   limit
       It  is the limit on the queue size in packets. Incoming packets are dropped when the limit
       is reached. The default value is 10240 packets.

   flows
       It is the number of flows into which the incoming  packets  are  classified.  Due  to  the
       stochastic  nature  of hashing, multiple flows may end up being hashed into the same slot.
       Newer flows have priority over older ones. This parameter can be set  only  at  load  time
       since memory has to be allocated for the hash table. The default value is 1024.

   target
       It  is the queue delay which the PIE algorithm tries to maintain. The default target delay
       is 15ms.

   tupdate
       It is the time interval at which the system drop probability is calculated.   The  default
       is 15ms.

   alpha
   beta
       alpha  and  beta are parameters chosen to control the drop probability. These should be in
       the range between 0 and 32.

   quantum
       quantum signifies the number of bytes that may be dequeued from a queue  before  switching
       to the next queue in the deficit round robin scheme.

   memory_limit
       It is the maximum total memory allowed for packets of all flows. The default is 32Mb.

   ecn_prob
       It  is  the  drop  probability threshold below which packets will be ECN marked instead of
       getting dropped. The default is 10%. Setting this parameter requires ecn to be enabled.

   [no]ecn
       It has the same semantics as pie and can be used to mark packets instead of dropping them.
       If ecn has been enabled, noecn can be used to turn it off and vice-a-versa.

   [no]bytemode
       It  is  used  to  scale  drop  probability proportional to packet size bytemode to turn on
       bytemode, nobytemode to turn off bytemode. By default, bytemode is turned off.

   [no_]dq_rate_estimator
       dq_rate_estimator  can  be  used  to   calculate   queue   delay   using   Little's   Law,
       no_dq_rate_estimator  can  be  used  to calculate queue delay using timestamp. By default,
       dq_rate_estimator is turned off.

EXAMPLES

       # tc qdisc add dev eth0 root fq_pie
       # tc -s qdisc show dev eth0
       qdisc fq_pie 8001: root refcnt 2 limit 10240p flows  1024  target  15.0ms  tupdate  16.0ms
       alpha 2 beta 20 quantum 1514b memory_limit 32Mb ecn_prob 10
        Sent 159173586 bytes 105261 pkt (dropped 24, overlimits 0 requeues 0)
        backlog 75700b 50p requeues 0
         pkts_in 105311 overlimit 0 overmemory 0 dropped 24 ecn_mark 0
         new_flow_count 7332 new_flows_len 0 old_flows_len 4 memory_used 108800

       # tc qdisc add dev eth0 root fq_pie dq_rate_estimator
       # tc -s qdisc show dev eth0
       qdisc  fq_pie  8001:  root  refcnt  2 limit 10240p flows 1024 target 15.0ms tupdate 16.0ms
       alpha 2 beta 20 quantum 1514b memory_limit 32Mb ecn_prob 10 dq_rate_estimator
        Sent 8263620 bytes 5550 pkt (dropped 4, overlimits 0 requeues 0)
        backlog 805448b 532p requeues 0
         pkts_in 6082 overlimit 0 overmemory 0 dropped 4 ecn_mark 0
         new_flow_count 94 new_flows_len 0 old_flows_len 8 memory_used 1157632

SEE ALSO

       tc(8), tc-pie(8), tc-fq_codel(8)

SOURCES

       RFC 8033: https://tools.ietf.org/html/rfc8033

AUTHORS

       FQ-PIE was implemented by Mohit P. Tahiliani.  Please  report  corrections  to  the  Linux
       Networking mailing list <netdev@vger.kernel.org>.