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+# QoS Hierarchical Scheduler {#qos_doc}
+
+The Quality-of-Service (QoS) scheduler performs egress-traffic management by
+prioritizing the transmission of the packets of different type services and
+subcribers based on the Service Level Agreements (SLAs). The QoS scheduler can
+be enabled on one or more NIC output interfaces depending upon the
+requirement.
+
+
+## Overview
+
+The QoS schdeuler supports a number of scheduling and shaping levels which
+construct hierarchical-tree. The first level in the hierarchy is port (i.e.
+the physical interface) that constitutes the root node of the tree. The
+subsequent level is subport which represents the group of the
+users/subscribers. The individual user/subscriber is represented by the pipe
+at the next level. Each user can have different traffic type based on the
+criteria of specific loss rate, jitter, and latency. These traffic types are
+represented at the traffic-class level in the form of different traffic-
+classes. The last level contains number of queues which are grouped together
+to host the packets of the specific class type traffic.
+
+The QoS scheduler implementation requires flow classification, enqueue and
+dequeue operations. The flow classification is mandatory stage for HQoS where
+incoming packets are classified by mapping the packet fields information to
+5-tuple (HQoS subport, pipe, traffic class, queue within traffic class, and
+color) and storing that information in mbuf sched field. The enqueue operation
+uses this information to determine the queue for storing the packet, and at
+this stage, if the specific queue is full, QoS drops the packet. The dequeue
+operation consists of scheduling the packet based on its length and available
+credits, and handing over the scheduled packet to the output interface.
+
+For more information on QoS Scheduler, please refer DPDK Programmer's Guide-
+http://dpdk.org/doc/guides/prog_guide/qos_framework.html
+
+
+### QoS Schdeuler Parameters
+
+Following illustrates the default HQoS configuration for each 10GbE output
+port:
+
+Single subport (subport 0):
+ - Subport rate set to 100% of port rate
+ - Each of the 4 traffic classes has rate set to 100% of port rate
+
+4K pipes per subport 0 (pipes 0 .. 4095) with identical configuration:
+ - Pipe rate set to 1/4K of port rate
+ - Each of the 4 traffic classes has rate set to 100% of pipe rate
+ - Within each traffic class, the byte-level WRR weights for the 4 queues are set to 1:1:1:1
+
+
+#### Port configuration
+
+```
+port {
+ rate 1250000000 /* Assuming 10GbE port */
+ frame_overhead 24 /* Overhead fields per Ethernet frame:
+ * 7B (Preamble) +
+ * 1B (Start of Frame Delimiter (SFD)) +
+ * 4B (Frame Check Sequence (FCS)) +
+ * 12B (Inter Frame Gap (IFG))
+ */
+ mtu 1522 /* Assuming Ethernet/IPv4 pkt (FCS not included) */
+ n_subports_per_port 1 /* Number of subports per output interface */
+ n_pipes_per_subport 4096 /* Number of pipes (users/subscribers) */
+ queue_sizes 64 64 64 64 /* Packet queue size for each traffic class.
+ * All queues within the same pipe traffic class
+ * have the same size. Queues from different
+ * pipes serving the same traffic class have
+ * the same size. */
+}
+```
+
+
+#### Subport configuration
+
+```
+subport 0 {
+ tb_rate 1250000000 /* Subport level token bucket rate (bytes per second) */
+ tb_size 1000000 /* Subport level token bucket size (bytes) */
+ tc0_rate 1250000000 /* Subport level token bucket rate for traffic class 0 (bytes per second) */
+ tc1_rate 1250000000 /* Subport level token bucket rate for traffic class 1 (bytes per second) */
+ tc2_rate 1250000000 /* Subport level token bucket rate for traffic class 2 (bytes per second) */
+ tc3_rate 1250000000 /* Subport level token bucket rate for traffic class 3 (bytes per second) */
+ tc_period 10 /* Time interval for refilling the token bucket associated with traffic class (Milliseconds) */
+ pipe 0 4095 profile 0 /* pipes (users/subscribers) configured with pipe profile 0 */
+}
+```
+
+
+#### Pipe configuration
+
+```
+pipe_profile 0 {
+ tb_rate 305175 /* Pipe level token bucket rate (bytes per second) */
+ tb_size 1000000 /* Pipe level token bucket size (bytes) */
+ tc0_rate 305175 /* Pipe level token bucket rate for traffic class 0 (bytes per second) */
+ tc1_rate 305175 /* Pipe level token bucket rate for traffic class 1 (bytes per second) */
+ tc2_rate 305175 /* Pipe level token bucket rate for traffic class 2 (bytes per second) */
+ tc3_rate 305175 /* Pipe level token bucket rate for traffic class 3 (bytes per second) */
+ tc_period 40 /* Time interval for refilling the token bucket associated with traffic class at pipe level (Milliseconds) */
+ tc3_oversubscription_weight 1 /* Weight traffic class 3 oversubscription */
+ tc0_wrr_weights 1 1 1 1 /* Pipe queues WRR weights for traffic class 0 */
+ tc1_wrr_weights 1 1 1 1 /* Pipe queues WRR weights for traffic class 1 */
+ tc2_wrr_weights 1 1 1 1 /* Pipe queues WRR weights for traffic class 2 */
+ tc3_wrr_weights 1 1 1 1 /* Pipe queues WRR weights for traffic class 3 */
+}
+```
+
+
+#### Random Early Detection (RED) parameters per traffic class and color (Green / Yellow / Red)
+
+```
+red {
+ tc0_wred_min 48 40 32 /* Minimum threshold for traffic class 0 queue (min_th) in number of packets */
+ tc0_wred_max 64 64 64 /* Maximum threshold for traffic class 0 queue (max_th) in number of packets */
+ tc0_wred_inv_prob 10 10 10 /* Inverse of packet marking probability for traffic class 0 queue (maxp = 1 / maxp_inv) */
+ tc0_wred_weight 9 9 9 /* Traffic Class 0 queue weight */
+ tc1_wred_min 48 40 32 /* Minimum threshold for traffic class 1 queue (min_th) in number of packets */
+ tc1_wred_max 64 64 64 /* Maximum threshold for traffic class 1 queue (max_th) in number of packets */
+ tc1_wred_inv_prob 10 10 10 /* Inverse of packet marking probability for traffic class 1 queue (maxp = 1 / maxp_inv) */
+ tc1_wred_weight 9 9 9 /* Traffic Class 1 queue weight */
+ tc2_wred_min 48 40 32 /* Minimum threshold for traffic class 2 queue (min_th) in number of packets */
+ tc2_wred_max 64 64 64 /* Maximum threshold for traffic class 2 queue (max_th) in number of packets */
+ tc2_wred_inv_prob 10 10 10 /* Inverse of packet marking probability for traffic class 2 queue (maxp = 1 / maxp_inv) */
+ tc2_wred_weight 9 9 9 /* Traffic Class 2 queue weight */
+ tc3_wred_min 48 40 32 /* Minimum threshold for traffic class 3 queue (min_th) in number of packets */
+ tc3_wred_max 64 64 64 /* Maximum threshold for traffic class 3 queue (max_th) in number of packets */
+ tc3_wred_inv_prob 10 10 10 /* Inverse of packet marking probability for traffic class 3 queue (maxp = 1 / maxp_inv) */
+ tc3_wred_weight 9 9 9 /* Traffic Class 3 queue weight */
+}
+```
+
+
+### DPDK QoS Scheduler Integration in VPP
+
+The Hierarchical Quaity-of-Service (HQoS) scheduler object could be seen as
+part of the logical NIC output interface. To enable HQoS on specific output
+interface, vpp startup.conf file has to be configured accordingly. The output
+interface that requires HQoS, should have "hqos" parameter specified in dpdk
+section. Another optional parameter "hqos-thread" has been defined which can
+be used to associate the output interface with specific hqos thread. In cpu
+section of the config file, "corelist-hqos-threads" is introduced to assign
+logical cpu cores to run the HQoS threads. A HQoS thread can run multiple HQoS
+objects each associated with different output interfaces. All worker threads
+instead of writing packets to NIC TX queue directly, write the packets to a
+software queues. The hqos_threads read the software queues, and enqueue the
+packets to HQoS objects, as well as dequeue packets from HQOS objects and
+write them to NIC output interfaces. The worker threads need to be able to
+send the packets to any output interface, therefore, each HQoS object
+associated with NIC output interface should have software queues equal to
+worker threads count.
+
+Following illustrates the sample startup configuration file with 4x worker
+threads feeding 2x hqos threads that handle each QoS scheduler for 1x output
+interface.
+
+```
+dpdk {
+ socket-mem 16384,16384
+
+ dev 0000:02:00.0 {
+ num-rx-queues 2
+ hqos
+ }
+ dev 0000:06:00.0 {
+ num-rx-queues 2
+ hqos
+ }
+
+ num-mbufs 1000000
+}
+
+cpu {
+ main-core 0
+ corelist-workers 1, 2, 3, 4
+ corelist-hqos-threads 5, 6
+}
+```
+
+
+### QoS scheduler CLI Commands
+
+Each QoS scheduler instance is initialised with default parameters required to
+configure hqos port, subport, pipe and queues. Some of the parameters can be
+re-configured in run-time through CLI commands.
+
+
+#### Configuration
+
+Following commands can be used to configure QoS scheduler parameters.
+
+The command below can be used to set the subport level parameters such as
+token bucket rate (bytes per seconds), token bucket size (bytes), traffic
+class rates (bytes per seconds) and token update period (Milliseconds).
+
+```
+set dpdk interface hqos subport <interface> subport <subport_id> [rate <n>]
+ [bktsize <n>] [tc0 <n>] [tc1 <n>] [tc2 <n>] [tc3 <n>] [period <n>]
+```
+
+For setting the pipe profile, following command can be used.
+
+```
+set dpdk interface hqos pipe <interface> subport <subport_id> pipe <pipe_id>
+ profile <profile_id>
+```
+
+To assign QoS scheduler instance to the specific thread, following command can
+be used.
+
+```
+set dpdk interface hqos placement <interface> thread <n>
+```
+
+The command below is used to set the packet fields required for classifiying
+the incoming packet. As a result of classification process, packet field
+information will be mapped to 5 tuples (subport, pipe, traffic class, pipe,
+color) and stored in packet mbuf.
+
+```
+set dpdk interface hqos pktfield <interface> id subport|pipe|tc offset <n>
+ mask <hex-mask>
+```
+
+The DSCP table entries used for idenfiying the traffic class and queue can be set using the command below;
+
+```
+set dpdk interface hqos tctbl <interface> entry <map_val> tc <tc_id> queue <queue_id>
+```
+
+
+#### Show Command
+
+The QoS Scheduler configuration can displayed using the command below.
+
+```
+ vpp# show dpdk interface hqos TenGigabitEthernet2/0/0
+ Thread:
+ Input SWQ size = 4096 packets
+ Enqueue burst size = 256 packets
+ Dequeue burst size = 220 packets
+ Packet field 0: slab position = 0, slab bitmask = 0x0000000000000000 (subport)
+ Packet field 1: slab position = 40, slab bitmask = 0x0000000fff000000 (pipe)
+ Packet field 2: slab position = 8, slab bitmask = 0x00000000000000fc (tc)
+ Packet field 2 tc translation table: ([Mapped Value Range]: tc/queue tc/queue ...)
+ [ 0 .. 15]: 0/0 0/1 0/2 0/3 1/0 1/1 1/2 1/3 2/0 2/1 2/2 2/3 3/0 3/1 3/2 3/3
+ [16 .. 31]: 0/0 0/1 0/2 0/3 1/0 1/1 1/2 1/3 2/0 2/1 2/2 2/3 3/0 3/1 3/2 3/3
+ [32 .. 47]: 0/0 0/1 0/2 0/3 1/0 1/1 1/2 1/3 2/0 2/1 2/2 2/3 3/0 3/1 3/2 3/3
+ [48 .. 63]: 0/0 0/1 0/2 0/3 1/0 1/1 1/2 1/3 2/0 2/1 2/2 2/3 3/0 3/1 3/2 3/3
+ Port:
+ Rate = 1250000000 bytes/second
+ MTU = 1514 bytes
+ Frame overhead = 24 bytes
+ Number of subports = 1
+ Number of pipes per subport = 4096
+ Packet queue size: TC0 = 64, TC1 = 64, TC2 = 64, TC3 = 64 packets
+ Number of pipe profiles = 1
+ Subport 0:
+ Rate = 120000000 bytes/second
+ Token bucket size = 1000000 bytes
+ Traffic class rate: TC0 = 120000000, TC1 = 120000000, TC2 = 120000000, TC3 = 120000000 bytes/second
+ TC period = 10 milliseconds
+ Pipe profile 0:
+ Rate = 305175 bytes/second
+ Token bucket size = 1000000 bytes
+ Traffic class rate: TC0 = 305175, TC1 = 305175, TC2 = 305175, TC3 = 305175 bytes/second
+ TC period = 40 milliseconds
+ TC0 WRR weights: Q0 = 1, Q1 = 1, Q2 = 1, Q3 = 1
+ TC1 WRR weights: Q0 = 1, Q1 = 1, Q2 = 1, Q3 = 1
+ TC2 WRR weights: Q0 = 1, Q1 = 1, Q2 = 1, Q3 = 1
+ TC3 WRR weights: Q0 = 1, Q1 = 1, Q2 = 1, Q3 = 1
+```
+
+The QoS Scheduler placement over the logical cpu cores can be displayed using
+below command.
+
+```
+ vpp# show dpdk interface hqos placement
+ Thread 5 (vpp_hqos-threads_0 at lcore 5):
+ TenGigabitEthernet2/0/0 queue 0
+ Thread 6 (vpp_hqos-threads_1 at lcore 6):
+ TenGigabitEthernet4/0/1 queue 0
+```
+
+
+### QoS Scheduler Binary APIs
+
+This section explans the available binary APIs for configuring QoS scheduler
+parameters in run-time.
+
+The following API can be used to set the pipe profile of a pipe that belongs
+to a given subport:
+
+```
+sw_interface_set_dpdk_hqos_pipe rx <intfc> | sw_if_index <id>
+ subport <subport-id> pipe <pipe-id> profile <profile-id>
+```
+
+The data structures used for set the pipe profile parameter are as follows;
+
+```
+ /** \\brief DPDK interface HQoS pipe profile set request
+ @param client_index - opaque cookie to identify the sender
+ @param context - sender context, to match reply w/ request
+ @param sw_if_index - the interface
+ @param subport - subport ID
+ @param pipe - pipe ID within its subport
+ @param profile - pipe profile ID
+ */
+ define sw_interface_set_dpdk_hqos_pipe {
+ u32 client_index;
+ u32 context;
+ u32 sw_if_index;
+ u32 subport;
+ u32 pipe;
+ u32 profile;
+ };
+
+ /** \\brief DPDK interface HQoS pipe profile set reply
+ @param context - sender context, to match reply w/ request
+ @param retval - request return code
+ */
+ define sw_interface_set_dpdk_hqos_pipe_reply {
+ u32 context;
+ i32 retval;
+ };
+```
+
+The following API can be used to set the subport level parameters, for
+example- token bucket rate (bytes per seconds), token bucket size (bytes),
+traffic class rate (bytes per seconds) and tokens update period.
+
+```
+sw_interface_set_dpdk_hqos_subport rx <intfc> | sw_if_index <id>
+ subport <subport-id> [rate <n>] [bktsize <n>]
+ [tc0 <n>] [tc1 <n>] [tc2 <n>] [tc3 <n>] [period <n>]
+```
+
+The data structures used for set the subport level parameter are as follows;
+
+```
+ /** \\brief DPDK interface HQoS subport parameters set request
+ @param client_index - opaque cookie to identify the sender
+ @param context - sender context, to match reply w/ request
+ @param sw_if_index - the interface
+ @param subport - subport ID
+ @param tb_rate - subport token bucket rate (measured in bytes/second)
+ @param tb_size - subport token bucket size (measured in credits)
+ @param tc_rate - subport traffic class 0 .. 3 rates (measured in bytes/second)
+ @param tc_period - enforcement period for rates (measured in milliseconds)
+ */
+ define sw_interface_set_dpdk_hqos_subport {
+ u32 client_index;
+ u32 context;
+ u32 sw_if_index;
+ u32 subport;
+ u32 tb_rate;
+ u32 tb_size;
+ u32 tc_rate[4];
+ u32 tc_period;
+ };
+
+ /** \\brief DPDK interface HQoS subport parameters set reply
+ @param context - sender context, to match reply w/ request
+ @param retval - request return code
+ */
+ define sw_interface_set_dpdk_hqos_subport_reply {
+ u32 context;
+ i32 retval;
+ };
+```
+
+The following API can be used set the DSCP table entry. The DSCP table have
+64 entries to map the packet DSCP field onto traffic class and hqos input
+queue.
+
+```
+sw_interface_set_dpdk_hqos_tctbl rx <intfc> | sw_if_index <id>
+ entry <n> tc <n> queue <n>
+```
+
+The data structures used for setting DSCP table entries are given below.
+
+```
+ /** \\brief DPDK interface HQoS tctbl entry set request
+ @param client_index - opaque cookie to identify the sender
+ @param context - sender context, to match reply w/ request
+ @param sw_if_index - the interface
+ @param entry - entry index ID
+ @param tc - traffic class (0 .. 3)
+ @param queue - traffic class queue (0 .. 3)
+ */
+ define sw_interface_set_dpdk_hqos_tctbl {
+ u32 client_index;
+ u32 context;
+ u32 sw_if_index;
+ u32 entry;
+ u32 tc;
+ u32 queue;
+ };
+
+ /** \\brief DPDK interface HQoS tctbl entry set reply
+ @param context - sender context, to match reply w/ request
+ @param retval - request return code
+ */
+ define sw_interface_set_dpdk_hqos_tctbl_reply {
+ u32 context;
+ i32 retval;
+ };
+```