175 строки
7.7 KiB
Plaintext
175 строки
7.7 KiB
Plaintext
Net DIM - Generic Network Dynamic Interrupt Moderation
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======================================================
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Author:
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Tal Gilboa <talgi@mellanox.com>
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Contents
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=========
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- Assumptions
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- Introduction
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- The Net DIM Algorithm
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- Registering a Network Device to DIM
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- Example
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Part 0: Assumptions
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======================
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This document assumes the reader has basic knowledge in network drivers
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and in general interrupt moderation.
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Part I: Introduction
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======================
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Dynamic Interrupt Moderation (DIM) (in networking) refers to changing the
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interrupt moderation configuration of a channel in order to optimize packet
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processing. The mechanism includes an algorithm which decides if and how to
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change moderation parameters for a channel, usually by performing an analysis on
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runtime data sampled from the system. Net DIM is such a mechanism. In each
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iteration of the algorithm, it analyses a given sample of the data, compares it
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to the previous sample and if required, it can decide to change some of the
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interrupt moderation configuration fields. The data sample is composed of data
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bandwidth, the number of packets and the number of events. The time between
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samples is also measured. Net DIM compares the current and the previous data and
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returns an adjusted interrupt moderation configuration object. In some cases,
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the algorithm might decide not to change anything. The configuration fields are
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the minimum duration (microseconds) allowed between events and the maximum
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number of wanted packets per event. The Net DIM algorithm ascribes importance to
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increase bandwidth over reducing interrupt rate.
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Part II: The Net DIM Algorithm
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===============================
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Each iteration of the Net DIM algorithm follows these steps:
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1. Calculates new data sample.
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2. Compares it to previous sample.
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3. Makes a decision - suggests interrupt moderation configuration fields.
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4. Applies a schedule work function, which applies suggested configuration.
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The first two steps are straightforward, both the new and the previous data are
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supplied by the driver registered to Net DIM. The previous data is the new data
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supplied to the previous iteration. The comparison step checks the difference
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between the new and previous data and decides on the result of the last step.
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A step would result as "better" if bandwidth increases and as "worse" if
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bandwidth reduces. If there is no change in bandwidth, the packet rate is
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compared in a similar fashion - increase == "better" and decrease == "worse".
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In case there is no change in the packet rate as well, the interrupt rate is
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compared. Here the algorithm tries to optimize for lower interrupt rate so an
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increase in the interrupt rate is considered "worse" and a decrease is
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considered "better". Step #2 has an optimization for avoiding false results: it
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only considers a difference between samples as valid if it is greater than a
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certain percentage. Also, since Net DIM does not measure anything by itself, it
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assumes the data provided by the driver is valid.
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Step #3 decides on the suggested configuration based on the result from step #2
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and the internal state of the algorithm. The states reflect the "direction" of
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the algorithm: is it going left (reducing moderation), right (increasing
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moderation) or standing still. Another optimization is that if a decision
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to stay still is made multiple times, the interval between iterations of the
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algorithm would increase in order to reduce calculation overhead. Also, after
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"parking" on one of the most left or most right decisions, the algorithm may
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decide to verify this decision by taking a step in the other direction. This is
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done in order to avoid getting stuck in a "deep sleep" scenario. Once a
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decision is made, an interrupt moderation configuration is selected from
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the predefined profiles.
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The last step is to notify the registered driver that it should apply the
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suggested configuration. This is done by scheduling a work function, defined by
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the Net DIM API and provided by the registered driver.
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As you can see, Net DIM itself does not actively interact with the system. It
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would have trouble making the correct decisions if the wrong data is supplied to
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it and it would be useless if the work function would not apply the suggested
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configuration. This does, however, allow the registered driver some room for
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manoeuvre as it may provide partial data or ignore the algorithm suggestion
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under some conditions.
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Part III: Registering a Network Device to DIM
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==============================================
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Net DIM API exposes the main function net_dim(struct net_dim *dim,
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struct net_dim_sample end_sample). This function is the entry point to the Net
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DIM algorithm and has to be called every time the driver would like to check if
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it should change interrupt moderation parameters. The driver should provide two
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data structures: struct net_dim and struct net_dim_sample. Struct net_dim
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describes the state of DIM for a specific object (RX queue, TX queue,
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other queues, etc.). This includes the current selected profile, previous data
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samples, the callback function provided by the driver and more.
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Struct net_dim_sample describes a data sample, which will be compared to the
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data sample stored in struct net_dim in order to decide on the algorithm's next
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step. The sample should include bytes, packets and interrupts, measured by
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the driver.
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In order to use Net DIM from a networking driver, the driver needs to call the
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main net_dim() function. The recommended method is to call net_dim() on each
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interrupt. Since Net DIM has a built-in moderation and it might decide to skip
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iterations under certain conditions, there is no need to moderate the net_dim()
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calls as well. As mentioned above, the driver needs to provide an object of type
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struct net_dim to the net_dim() function call. It is advised for each entity
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using Net DIM to hold a struct net_dim as part of its data structure and use it
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as the main Net DIM API object. The struct net_dim_sample should hold the latest
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bytes, packets and interrupts count. No need to perform any calculations, just
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include the raw data.
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The net_dim() call itself does not return anything. Instead Net DIM relies on
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the driver to provide a callback function, which is called when the algorithm
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decides to make a change in the interrupt moderation parameters. This callback
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will be scheduled and run in a separate thread in order not to add overhead to
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the data flow. After the work is done, Net DIM algorithm needs to be set to
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the proper state in order to move to the next iteration.
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Part IV: Example
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=================
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The following code demonstrates how to register a driver to Net DIM. The actual
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usage is not complete but it should make the outline of the usage clear.
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my_driver.c:
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#include <linux/net_dim.h>
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/* Callback for net DIM to schedule on a decision to change moderation */
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void my_driver_do_dim_work(struct work_struct *work)
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{
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/* Get struct net_dim from struct work_struct */
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struct net_dim *dim = container_of(work, struct net_dim,
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work);
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/* Do interrupt moderation related stuff */
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...
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/* Signal net DIM work is done and it should move to next iteration */
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dim->state = NET_DIM_START_MEASURE;
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}
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/* My driver's interrupt handler */
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int my_driver_handle_interrupt(struct my_driver_entity *my_entity, ...)
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{
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...
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/* A struct to hold current measured data */
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struct net_dim_sample dim_sample;
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...
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/* Initiate data sample struct with current data */
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net_dim_sample(my_entity->events,
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my_entity->packets,
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my_entity->bytes,
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&dim_sample);
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/* Call net DIM */
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net_dim(&my_entity->dim, dim_sample);
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...
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}
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/* My entity's initialization function (my_entity was already allocated) */
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int my_driver_init_my_entity(struct my_driver_entity *my_entity, ...)
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{
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...
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/* Initiate struct work_struct with my driver's callback function */
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INIT_WORK(&my_entity->dim.work, my_driver_do_dim_work);
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...
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}
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