| |
| HOWTO for multiqueue network device support |
| =========================================== |
| |
| Section 1: Base driver requirements for implementing multiqueue support |
| Section 2: Qdisc support for multiqueue devices |
| Section 3: Brief howto using PRIO or RR for multiqueue devices |
| |
| |
| Intro: Kernel support for multiqueue devices |
| --------------------------------------------------------- |
| |
| Kernel support for multiqueue devices is only an API that is presented to the |
| netdevice layer for base drivers to implement. This feature is part of the |
| core networking stack, and all network devices will be running on the |
| multiqueue-aware stack. If a base driver only has one queue, then these |
| changes are transparent to that driver. |
| |
| |
| Section 1: Base driver requirements for implementing multiqueue support |
| ----------------------------------------------------------------------- |
| |
| Base drivers are required to use the new alloc_etherdev_mq() or |
| alloc_netdev_mq() functions to allocate the subqueues for the device. The |
| underlying kernel API will take care of the allocation and deallocation of |
| the subqueue memory, as well as netdev configuration of where the queues |
| exist in memory. |
| |
| The base driver will also need to manage the queues as it does the global |
| netdev->queue_lock today. Therefore base drivers should use the |
| netif_{start|stop|wake}_subqueue() functions to manage each queue while the |
| device is still operational. netdev->queue_lock is still used when the device |
| comes online or when it's completely shut down (unregister_netdev(), etc.). |
| |
| Finally, the base driver should indicate that it is a multiqueue device. The |
| feature flag NETIF_F_MULTI_QUEUE should be added to the netdev->features |
| bitmap on device initialization. Below is an example from e1000: |
| |
| #ifdef CONFIG_E1000_MQ |
| if ( (adapter->hw.mac.type == e1000_82571) || |
| (adapter->hw.mac.type == e1000_82572) || |
| (adapter->hw.mac.type == e1000_80003es2lan)) |
| netdev->features |= NETIF_F_MULTI_QUEUE; |
| #endif |
| |
| |
| Section 2: Qdisc support for multiqueue devices |
| ----------------------------------------------- |
| |
| Currently two qdiscs support multiqueue devices. A new round-robin qdisc, |
| sch_rr, and sch_prio. The qdisc is responsible for classifying the skb's to |
| bands and queues, and will store the queue mapping into skb->queue_mapping. |
| Use this field in the base driver to determine which queue to send the skb |
| to. |
| |
| sch_rr has been added for hardware that doesn't want scheduling policies from |
| software, so it's a straight round-robin qdisc. It uses the same syntax and |
| classification priomap that sch_prio uses, so it should be intuitive to |
| configure for people who've used sch_prio. |
| |
| In order to utilitize the multiqueue features of the qdiscs, the network |
| device layer needs to enable multiple queue support. This can be done by |
| selecting NETDEVICES_MULTIQUEUE under Drivers. |
| |
| The PRIO qdisc naturally plugs into a multiqueue device. If |
| NETDEVICES_MULTIQUEUE is selected, then on qdisc load, the number of |
| bands requested is compared to the number of queues on the hardware. If they |
| are equal, it sets a one-to-one mapping up between the queues and bands. If |
| they're not equal, it will not load the qdisc. This is the same behavior |
| for RR. Once the association is made, any skb that is classified will have |
| skb->queue_mapping set, which will allow the driver to properly queue skb's |
| to multiple queues. |
| |
| |
| Section 3: Brief howto using PRIO and RR for multiqueue devices |
| --------------------------------------------------------------- |
| |
| The userspace command 'tc,' part of the iproute2 package, is used to configure |
| qdiscs. To add the PRIO qdisc to your network device, assuming the device is |
| called eth0, run the following command: |
| |
| # tc qdisc add dev eth0 root handle 1: prio bands 4 multiqueue |
| |
| This will create 4 bands, 0 being highest priority, and associate those bands |
| to the queues on your NIC. Assuming eth0 has 4 Tx queues, the band mapping |
| would look like: |
| |
| band 0 => queue 0 |
| band 1 => queue 1 |
| band 2 => queue 2 |
| band 3 => queue 3 |
| |
| Traffic will begin flowing through each queue if your TOS values are assigning |
| traffic across the various bands. For example, ssh traffic will always try to |
| go out band 0 based on TOS -> Linux priority conversion (realtime traffic), |
| so it will be sent out queue 0. ICMP traffic (pings) fall into the "normal" |
| traffic classification, which is band 1. Therefore pings will be send out |
| queue 1 on the NIC. |
| |
| Note the use of the multiqueue keyword. This is only in versions of iproute2 |
| that support multiqueue networking devices; if this is omitted when loading |
| a qdisc onto a multiqueue device, the qdisc will load and operate the same |
| if it were loaded onto a single-queue device (i.e. - sends all traffic to |
| queue 0). |
| |
| Another alternative to multiqueue band allocation can be done by using the |
| multiqueue option and specify 0 bands. If this is the case, the qdisc will |
| allocate the number of bands to equal the number of queues that the device |
| reports, and bring the qdisc online. |
| |
| The behavior of tc filters remains the same, where it will override TOS priority |
| classification. |
| |
| |
| Author: Peter P. Waskiewicz Jr. <peter.p.waskiewicz.jr@intel.com> |