| ========================== |
| BFQ (Budget Fair Queueing) |
| ========================== |
| |
| BFQ is a proportional-share I/O scheduler, with some extra |
| low-latency capabilities. In addition to cgroups support (blkio or io |
| controllers), BFQ's main features are: |
| |
| - BFQ guarantees a high system and application responsiveness, and a |
| low latency for time-sensitive applications, such as audio or video |
| players; |
| - BFQ distributes bandwidth, not just time, among processes or |
| groups (switching back to time distribution when needed to keep |
| throughput high). |
| |
| In its default configuration, BFQ privileges latency over |
| throughput. So, when needed for achieving a lower latency, BFQ builds |
| schedules that may lead to a lower throughput. If your main or only |
| goal, for a given device, is to achieve the maximum-possible |
| throughput at all times, then do switch off all low-latency heuristics |
| for that device, by setting low_latency to 0. See Section 3 for |
| details on how to configure BFQ for the desired tradeoff between |
| latency and throughput, or on how to maximize throughput. |
| |
| As every I/O scheduler, BFQ adds some overhead to per-I/O-request |
| processing. To give an idea of this overhead, the total, |
| single-lock-protected, per-request processing time of BFQ---i.e., the |
| sum of the execution times of the request insertion, dispatch and |
| completion hooks---is, e.g., 1.9 us on an Intel Core i7-2760QM@2.40GHz |
| (dated CPU for notebooks; time measured with simple code |
| instrumentation, and using the throughput-sync.sh script of the S |
| suite [1], in performance-profiling mode). To put this result into |
| context, the total, single-lock-protected, per-request execution time |
| of the lightest I/O scheduler available in blk-mq, mq-deadline, is 0.7 |
| us (mq-deadline is ~800 LOC, against ~10500 LOC for BFQ). |
| |
| Scheduling overhead further limits the maximum IOPS that a CPU can |
| process (already limited by the execution of the rest of the I/O |
| stack). To give an idea of the limits with BFQ, on slow or average |
| CPUs, here are, first, the limits of BFQ for three different CPUs, on, |
| respectively, an average laptop, an old desktop, and a cheap embedded |
| system, in case full hierarchical support is enabled (i.e., |
| CONFIG_BFQ_GROUP_IOSCHED is set), but CONFIG_BFQ_CGROUP_DEBUG is not |
| set (Section 4-2): |
| - Intel i7-4850HQ: 400 KIOPS |
| - AMD A8-3850: 250 KIOPS |
| - ARM CortexTM-A53 Octa-core: 80 KIOPS |
| |
| If CONFIG_BFQ_CGROUP_DEBUG is set (and of course full hierarchical |
| support is enabled), then the sustainable throughput with BFQ |
| decreases, because all blkio.bfq* statistics are created and updated |
| (Section 4-2). For BFQ, this leads to the following maximum |
| sustainable throughputs, on the same systems as above: |
| - Intel i7-4850HQ: 310 KIOPS |
| - AMD A8-3850: 200 KIOPS |
| - ARM CortexTM-A53 Octa-core: 56 KIOPS |
| |
| BFQ works for multi-queue devices too. |
| |
| .. The table of contents follow. Impatients can just jump to Section 3. |
| |
| .. CONTENTS |
| |
| 1. When may BFQ be useful? |
| 1-1 Personal systems |
| 1-2 Server systems |
| 2. How does BFQ work? |
| 3. What are BFQ's tunables and how to properly configure BFQ? |
| 4. BFQ group scheduling |
| 4-1 Service guarantees provided |
| 4-2 Interface |
| |
| 1. When may BFQ be useful? |
| ========================== |
| |
| BFQ provides the following benefits on personal and server systems. |
| |
| 1-1 Personal systems |
| -------------------- |
| |
| Low latency for interactive applications |
| ^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^ |
| |
| Regardless of the actual background workload, BFQ guarantees that, for |
| interactive tasks, the storage device is virtually as responsive as if |
| it was idle. For example, even if one or more of the following |
| background workloads are being executed: |
| |
| - one or more large files are being read, written or copied, |
| - a tree of source files is being compiled, |
| - one or more virtual machines are performing I/O, |
| - a software update is in progress, |
| - indexing daemons are scanning filesystems and updating their |
| databases, |
| |
| starting an application or loading a file from within an application |
| takes about the same time as if the storage device was idle. As a |
| comparison, with CFQ, NOOP or DEADLINE, and in the same conditions, |
| applications experience high latencies, or even become unresponsive |
| until the background workload terminates (also on SSDs). |
| |
| Low latency for soft real-time applications |
| ^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^ |
| Also soft real-time applications, such as audio and video |
| players/streamers, enjoy a low latency and a low drop rate, regardless |
| of the background I/O workload. As a consequence, these applications |
| do not suffer from almost any glitch due to the background workload. |
| |
| Higher speed for code-development tasks |
| ^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^ |
| |
| If some additional workload happens to be executed in parallel, then |
| BFQ executes the I/O-related components of typical code-development |
| tasks (compilation, checkout, merge, etc.) much more quickly than CFQ, |
| NOOP or DEADLINE. |
| |
| High throughput |
| ^^^^^^^^^^^^^^^ |
| |
| On hard disks, BFQ achieves up to 30% higher throughput than CFQ, and |
| up to 150% higher throughput than DEADLINE and NOOP, with all the |
| sequential workloads considered in our tests. With random workloads, |
| and with all the workloads on flash-based devices, BFQ achieves, |
| instead, about the same throughput as the other schedulers. |
| |
| Strong fairness, bandwidth and delay guarantees |
| ^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^ |
| |
| BFQ distributes the device throughput, and not just the device time, |
| among I/O-bound applications in proportion to their weights, with any |
| workload and regardless of the device parameters. From these bandwidth |
| guarantees, it is possible to compute a tight per-I/O-request delay |
| guarantees by a simple formula. If not configured for strict service |
| guarantees, BFQ switches to time-based resource sharing (only) for |
| applications that would otherwise cause a throughput loss. |
| |
| 1-2 Server systems |
| ------------------ |
| |
| Most benefits for server systems follow from the same service |
| properties as above. In particular, regardless of whether additional, |
| possibly heavy workloads are being served, BFQ guarantees: |
| |
| * audio and video-streaming with zero or very low jitter and drop |
| rate; |
| |
| * fast retrieval of WEB pages and embedded objects; |
| |
| * real-time recording of data in live-dumping applications (e.g., |
| packet logging); |
| |
| * responsiveness in local and remote access to a server. |
| |
| |
| 2. How does BFQ work? |
| ===================== |
| |
| BFQ is a proportional-share I/O scheduler, whose general structure, |
| plus a lot of code, are borrowed from CFQ. |
| |
| - Each process doing I/O on a device is associated with a weight and a |
| `(bfq_)queue`. |
| |
| - BFQ grants exclusive access to the device, for a while, to one queue |
| (process) at a time, and implements this service model by |
| associating every queue with a budget, measured in number of |
| sectors. |
| |
| - After a queue is granted access to the device, the budget of the |
| queue is decremented, on each request dispatch, by the size of the |
| request. |
| |
| - The in-service queue is expired, i.e., its service is suspended, |
| only if one of the following events occurs: 1) the queue finishes |
| its budget, 2) the queue empties, 3) a "budget timeout" fires. |
| |
| - The budget timeout prevents processes doing random I/O from |
| holding the device for too long and dramatically reducing |
| throughput. |
| |
| - Actually, as in CFQ, a queue associated with a process issuing |
| sync requests may not be expired immediately when it empties. In |
| contrast, BFQ may idle the device for a short time interval, |
| giving the process the chance to go on being served if it issues |
| a new request in time. Device idling typically boosts the |
| throughput on rotational devices and on non-queueing flash-based |
| devices, if processes do synchronous and sequential I/O. In |
| addition, under BFQ, device idling is also instrumental in |
| guaranteeing the desired throughput fraction to processes |
| issuing sync requests (see the description of the slice_idle |
| tunable in this document, or [1, 2], for more details). |
| |
| - With respect to idling for service guarantees, if several |
| processes are competing for the device at the same time, but |
| all processes and groups have the same weight, then BFQ |
| guarantees the expected throughput distribution without ever |
| idling the device. Throughput is thus as high as possible in |
| this common scenario. |
| |
| - On flash-based storage with internal queueing of commands |
| (typically NCQ), device idling happens to be always detrimental |
| to throughput. So, with these devices, BFQ performs idling |
| only when strictly needed for service guarantees, i.e., for |
| guaranteeing low latency or fairness. In these cases, overall |
| throughput may be sub-optimal. No solution currently exists to |
| provide both strong service guarantees and optimal throughput |
| on devices with internal queueing. |
| |
| - If low-latency mode is enabled (default configuration), BFQ |
| executes some special heuristics to detect interactive and soft |
| real-time applications (e.g., video or audio players/streamers), |
| and to reduce their latency. The most important action taken to |
| achieve this goal is to give to the queues associated with these |
| applications more than their fair share of the device |
| throughput. For brevity, we call it just "weight-raising" the whole |
| sets of actions taken by BFQ to privilege these queues. In |
| particular, BFQ provides a milder form of weight-raising for |
| interactive applications, and a stronger form for soft real-time |
| applications. |
| |
| - BFQ automatically deactivates idling for queues born in a burst of |
| queue creations. In fact, these queues are usually associated with |
| the processes of applications and services that benefit mostly |
| from a high throughput. Examples are systemd during boot, or git |
| grep. |
| |
| - As CFQ, BFQ merges queues performing interleaved I/O, i.e., |
| performing random I/O that becomes mostly sequential if |
| merged. Differently from CFQ, BFQ achieves this goal with a more |
| reactive mechanism, called Early Queue Merge (EQM). EQM is so |
| responsive in detecting interleaved I/O (cooperating processes), |
| that it enables BFQ to achieve a high throughput, by queue |
| merging, even for queues for which CFQ needs a different |
| mechanism, preemption, to get a high throughput. As such, EQM is a |
| unified mechanism to achieve a high throughput with interleaved |
| I/O. |
| |
| - Queues are scheduled according to a variant of WF2Q+, named |
| B-WF2Q+, and implemented using an augmented rb-tree to preserve an |
| O(log N) overall complexity. See [2] for more details. B-WF2Q+ is |
| also ready for hierarchical scheduling, details in Section 4. |
| |
| - B-WF2Q+ guarantees a tight deviation with respect to an ideal, |
| perfectly fair, and smooth service. In particular, B-WF2Q+ |
| guarantees that each queue receives a fraction of the device |
| throughput proportional to its weight, even if the throughput |
| fluctuates, and regardless of: the device parameters, the current |
| workload and the budgets assigned to the queue. |
| |
| - The last, budget-independence, property (although probably |
| counterintuitive in the first place) is definitely beneficial, for |
| the following reasons: |
| |
| - First, with any proportional-share scheduler, the maximum |
| deviation with respect to an ideal service is proportional to |
| the maximum budget (slice) assigned to queues. As a consequence, |
| BFQ can keep this deviation tight, not only because of the |
| accurate service of B-WF2Q+, but also because BFQ *does not* |
| need to assign a larger budget to a queue to let the queue |
| receive a higher fraction of the device throughput. |
| |
| - Second, BFQ is free to choose, for every process (queue), the |
| budget that best fits the needs of the process, or best |
| leverages the I/O pattern of the process. In particular, BFQ |
| updates queue budgets with a simple feedback-loop algorithm that |
| allows a high throughput to be achieved, while still providing |
| tight latency guarantees to time-sensitive applications. When |
| the in-service queue expires, this algorithm computes the next |
| budget of the queue so as to: |
| |
| - Let large budgets be eventually assigned to the queues |
| associated with I/O-bound applications performing sequential |
| I/O: in fact, the longer these applications are served once |
| got access to the device, the higher the throughput is. |
| |
| - Let small budgets be eventually assigned to the queues |
| associated with time-sensitive applications (which typically |
| perform sporadic and short I/O), because, the smaller the |
| budget assigned to a queue waiting for service is, the sooner |
| B-WF2Q+ will serve that queue (Subsec 3.3 in [2]). |
| |
| - If several processes are competing for the device at the same time, |
| but all processes and groups have the same weight, then BFQ |
| guarantees the expected throughput distribution without ever idling |
| the device. It uses preemption instead. Throughput is then much |
| higher in this common scenario. |
| |
| - ioprio classes are served in strict priority order, i.e., |
| lower-priority queues are not served as long as there are |
| higher-priority queues. Among queues in the same class, the |
| bandwidth is distributed in proportion to the weight of each |
| queue. A very thin extra bandwidth is however guaranteed to |
| the Idle class, to prevent it from starving. |
| |
| |
| 3. What are BFQ's tunables and how to properly configure BFQ? |
| ============================================================= |
| |
| Most BFQ tunables affect service guarantees (basically latency and |
| fairness) and throughput. For full details on how to choose the |
| desired tradeoff between service guarantees and throughput, see the |
| parameters slice_idle, strict_guarantees and low_latency. For details |
| on how to maximise throughput, see slice_idle, timeout_sync and |
| max_budget. The other performance-related parameters have been |
| inherited from, and have been preserved mostly for compatibility with |
| CFQ. So far, no performance improvement has been reported after |
| changing the latter parameters in BFQ. |
| |
| In particular, the tunables back_seek-max, back_seek_penalty, |
| fifo_expire_async and fifo_expire_sync below are the same as in |
| CFQ. Their description is just copied from that for CFQ. Some |
| considerations in the description of slice_idle are copied from CFQ |
| too. |
| |
| per-process ioprio and weight |
| ----------------------------- |
| |
| Unless the cgroups interface is used (see "4. BFQ group scheduling"), |
| weights can be assigned to processes only indirectly, through I/O |
| priorities, and according to the relation: |
| weight = (IOPRIO_BE_NR - ioprio) * 10. |
| |
| Beware that, if low-latency is set, then BFQ automatically raises the |
| weight of the queues associated with interactive and soft real-time |
| applications. Unset this tunable if you need/want to control weights. |
| |
| slice_idle |
| ---------- |
| |
| This parameter specifies how long BFQ should idle for the next I/O |
| request, when certain sync BFQ queues become empty. By default |
| slice_idle is a non-zero value. Idling has a double purpose: boosting |
| throughput and making sure that the desired throughput distribution is |
| respected (see the description of how BFQ works, and, if needed, the |
| papers referred there). |
| |
| As for throughput, idling can be very helpful on highly seeky media |
| like single spindle SATA/SAS disks where we can cut down on overall |
| number of seeks and see improved throughput. |
| |
| Setting slice_idle to 0 will remove all the idling on queues and one |
| should see an overall improved throughput on faster storage devices |
| like multiple SATA/SAS disks in hardware RAID configuration, as well |
| as flash-based storage with internal command queueing (and |
| parallelism). |
| |
| So depending on storage and workload, it might be useful to set |
| slice_idle=0. In general for SATA/SAS disks and software RAID of |
| SATA/SAS disks keeping slice_idle enabled should be useful. For any |
| configurations where there are multiple spindles behind single LUN |
| (Host based hardware RAID controller or for storage arrays), or with |
| flash-based fast storage, setting slice_idle=0 might end up in better |
| throughput and acceptable latencies. |
| |
| Idling is however necessary to have service guarantees enforced in |
| case of differentiated weights or differentiated I/O-request lengths. |
| To see why, suppose that a given BFQ queue A must get several I/O |
| requests served for each request served for another queue B. Idling |
| ensures that, if A makes a new I/O request slightly after becoming |
| empty, then no request of B is dispatched in the middle, and thus A |
| does not lose the possibility to get more than one request dispatched |
| before the next request of B is dispatched. Note that idling |
| guarantees the desired differentiated treatment of queues only in |
| terms of I/O-request dispatches. To guarantee that the actual service |
| order then corresponds to the dispatch order, the strict_guarantees |
| tunable must be set too. |
| |
| There is an important flip side to idling: apart from the above cases |
| where it is beneficial also for throughput, idling can severely impact |
| throughput. One important case is random workload. Because of this |
| issue, BFQ tends to avoid idling as much as possible, when it is not |
| beneficial also for throughput (as detailed in Section 2). As a |
| consequence of this behavior, and of further issues described for the |
| strict_guarantees tunable, short-term service guarantees may be |
| occasionally violated. And, in some cases, these guarantees may be |
| more important than guaranteeing maximum throughput. For example, in |
| video playing/streaming, a very low drop rate may be more important |
| than maximum throughput. In these cases, consider setting the |
| strict_guarantees parameter. |
| |
| slice_idle_us |
| ------------- |
| |
| Controls the same tuning parameter as slice_idle, but in microseconds. |
| Either tunable can be used to set idling behavior. Afterwards, the |
| other tunable will reflect the newly set value in sysfs. |
| |
| strict_guarantees |
| ----------------- |
| |
| If this parameter is set (default: unset), then BFQ |
| |
| - always performs idling when the in-service queue becomes empty; |
| |
| - forces the device to serve one I/O request at a time, by dispatching a |
| new request only if there is no outstanding request. |
| |
| In the presence of differentiated weights or I/O-request sizes, both |
| the above conditions are needed to guarantee that every BFQ queue |
| receives its allotted share of the bandwidth. The first condition is |
| needed for the reasons explained in the description of the slice_idle |
| tunable. The second condition is needed because all modern storage |
| devices reorder internally-queued requests, which may trivially break |
| the service guarantees enforced by the I/O scheduler. |
| |
| Setting strict_guarantees may evidently affect throughput. |
| |
| back_seek_max |
| ------------- |
| |
| This specifies, given in Kbytes, the maximum "distance" for backward seeking. |
| The distance is the amount of space from the current head location to the |
| sectors that are backward in terms of distance. |
| |
| This parameter allows the scheduler to anticipate requests in the "backward" |
| direction and consider them as being the "next" if they are within this |
| distance from the current head location. |
| |
| back_seek_penalty |
| ----------------- |
| |
| This parameter is used to compute the cost of backward seeking. If the |
| backward distance of request is just 1/back_seek_penalty from a "front" |
| request, then the seeking cost of two requests is considered equivalent. |
| |
| So scheduler will not bias toward one or the other request (otherwise scheduler |
| will bias toward front request). Default value of back_seek_penalty is 2. |
| |
| fifo_expire_async |
| ----------------- |
| |
| This parameter is used to set the timeout of asynchronous requests. Default |
| value of this is 250ms. |
| |
| fifo_expire_sync |
| ---------------- |
| |
| This parameter is used to set the timeout of synchronous requests. Default |
| value of this is 125ms. In case to favor synchronous requests over asynchronous |
| one, this value should be decreased relative to fifo_expire_async. |
| |
| low_latency |
| ----------- |
| |
| This parameter is used to enable/disable BFQ's low latency mode. By |
| default, low latency mode is enabled. If enabled, interactive and soft |
| real-time applications are privileged and experience a lower latency, |
| as explained in more detail in the description of how BFQ works. |
| |
| DISABLE this mode if you need full control on bandwidth |
| distribution. In fact, if it is enabled, then BFQ automatically |
| increases the bandwidth share of privileged applications, as the main |
| means to guarantee a lower latency to them. |
| |
| In addition, as already highlighted at the beginning of this document, |
| DISABLE this mode if your only goal is to achieve a high throughput. |
| In fact, privileging the I/O of some application over the rest may |
| entail a lower throughput. To achieve the highest-possible throughput |
| on a non-rotational device, setting slice_idle to 0 may be needed too |
| (at the cost of giving up any strong guarantee on fairness and low |
| latency). |
| |
| timeout_sync |
| ------------ |
| |
| Maximum amount of device time that can be given to a task (queue) once |
| it has been selected for service. On devices with costly seeks, |
| increasing this time usually increases maximum throughput. On the |
| opposite end, increasing this time coarsens the granularity of the |
| short-term bandwidth and latency guarantees, especially if the |
| following parameter is set to zero. |
| |
| max_budget |
| ---------- |
| |
| Maximum amount of service, measured in sectors, that can be provided |
| to a BFQ queue once it is set in service (of course within the limits |
| of the above timeout). According to what was said in the description of |
| the algorithm, larger values increase the throughput in proportion to |
| the percentage of sequential I/O requests issued. The price of larger |
| values is that they coarsen the granularity of short-term bandwidth |
| and latency guarantees. |
| |
| The default value is 0, which enables auto-tuning: BFQ sets max_budget |
| to the maximum number of sectors that can be served during |
| timeout_sync, according to the estimated peak rate. |
| |
| For specific devices, some users have occasionally reported to have |
| reached a higher throughput by setting max_budget explicitly, i.e., by |
| setting max_budget to a higher value than 0. In particular, they have |
| set max_budget to higher values than those to which BFQ would have set |
| it with auto-tuning. An alternative way to achieve this goal is to |
| just increase the value of timeout_sync, leaving max_budget equal to 0. |
| |
| 4. Group scheduling with BFQ |
| ============================ |
| |
| BFQ supports both cgroups-v1 and cgroups-v2 io controllers, namely |
| blkio and io. In particular, BFQ supports weight-based proportional |
| share. To activate cgroups support, set BFQ_GROUP_IOSCHED. |
| |
| 4-1 Service guarantees provided |
| ------------------------------- |
| |
| With BFQ, proportional share means true proportional share of the |
| device bandwidth, according to group weights. For example, a group |
| with weight 200 gets twice the bandwidth, and not just twice the time, |
| of a group with weight 100. |
| |
| BFQ supports hierarchies (group trees) of any depth. Bandwidth is |
| distributed among groups and processes in the expected way: for each |
| group, the children of the group share the whole bandwidth of the |
| group in proportion to their weights. In particular, this implies |
| that, for each leaf group, every process of the group receives the |
| same share of the whole group bandwidth, unless the ioprio of the |
| process is modified. |
| |
| The resource-sharing guarantee for a group may partially or totally |
| switch from bandwidth to time, if providing bandwidth guarantees to |
| the group lowers the throughput too much. This switch occurs on a |
| per-process basis: if a process of a leaf group causes throughput loss |
| if served in such a way to receive its share of the bandwidth, then |
| BFQ switches back to just time-based proportional share for that |
| process. |
| |
| 4-2 Interface |
| ------------- |
| |
| To get proportional sharing of bandwidth with BFQ for a given device, |
| BFQ must of course be the active scheduler for that device. |
| |
| Within each group directory, the names of the files associated with |
| BFQ-specific cgroup parameters and stats begin with the "bfq." |
| prefix. So, with cgroups-v1 or cgroups-v2, the full prefix for |
| BFQ-specific files is "blkio.bfq." or "io.bfq." For example, the group |
| parameter to set the weight of a group with BFQ is blkio.bfq.weight |
| or io.bfq.weight. |
| |
| As for cgroups-v1 (blkio controller), the exact set of stat files |
| created, and kept up-to-date by bfq, depends on whether |
| CONFIG_BFQ_CGROUP_DEBUG is set. If it is set, then bfq creates all |
| the stat files documented in |
| Documentation/admin-guide/cgroup-v1/blkio-controller.rst. If, instead, |
| CONFIG_BFQ_CGROUP_DEBUG is not set, then bfq creates only the files:: |
| |
| blkio.bfq.io_service_bytes |
| blkio.bfq.io_service_bytes_recursive |
| blkio.bfq.io_serviced |
| blkio.bfq.io_serviced_recursive |
| |
| The value of CONFIG_BFQ_CGROUP_DEBUG greatly influences the maximum |
| throughput sustainable with bfq, because updating the blkio.bfq.* |
| stats is rather costly, especially for some of the stats enabled by |
| CONFIG_BFQ_CGROUP_DEBUG. |
| |
| Parameters |
| ---------- |
| |
| For each group, the following parameters can be set: |
| |
| weight |
| This specifies the default weight for the cgroup inside its parent. |
| Available values: 1..1000 (default: 100). |
| |
| For cgroup v1, it is set by writing the value to `blkio.bfq.weight`. |
| |
| For cgroup v2, it is set by writing the value to `io.bfq.weight`. |
| (with an optional prefix of `default` and a space). |
| |
| The linear mapping between ioprio and weights, described at the beginning |
| of the tunable section, is still valid, but all weights higher than |
| IOPRIO_BE_NR*10 are mapped to ioprio 0. |
| |
| Recall that, if low-latency is set, then BFQ automatically raises the |
| weight of the queues associated with interactive and soft real-time |
| applications. Unset this tunable if you need/want to control weights. |
| |
| weight_device |
| This specifies a per-device weight for the cgroup. The syntax is |
| `minor:major weight`. A weight of `0` may be used to reset to the default |
| weight. |
| |
| For cgroup v1, it is set by writing the value to `blkio.bfq.weight_device`. |
| |
| For cgroup v2, the file name is `io.bfq.weight`. |
| |
| |
| [1] |
| P. Valente, A. Avanzini, "Evolution of the BFQ Storage I/O |
| Scheduler", Proceedings of the First Workshop on Mobile System |
| Technologies (MST-2015), May 2015. |
| |
| http://algogroup.unimore.it/people/paolo/disk_sched/mst-2015.pdf |
| |
| [2] |
| P. Valente and M. Andreolini, "Improving Application |
| Responsiveness with the BFQ Disk I/O Scheduler", Proceedings of |
| the 5th Annual International Systems and Storage Conference |
| (SYSTOR '12), June 2012. |
| |
| Slightly extended version: |
| |
| http://algogroup.unimore.it/people/paolo/disk_sched/bfq-v1-suite-results.pdf |
| |
| [3] |
| https://github.com/Algodev-github/S |