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362 lines
16 KiB
362 lines
16 KiB
Energy cost model for energy-aware scheduling (EXPERIMENTAL)
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Introduction
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=============
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The basic energy model uses platform energy data stored in sched_group_energy
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data structures attached to the sched_groups in the sched_domain hierarchy. The
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energy cost model offers two functions that can be used to guide scheduling
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decisions:
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1. static unsigned int sched_group_energy(struct energy_env *eenv)
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2. static int energy_diff(struct energy_env *eenv)
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sched_group_energy() estimates the energy consumed by all cpus in a specific
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sched_group including any shared resources owned exclusively by this group of
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cpus. Resources shared with other cpus are excluded (e.g. later level caches).
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energy_diff() estimates the total energy impact of a utilization change. That
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is, adding, removing, or migrating utilization (tasks).
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Both functions use a struct energy_env to specify the scenario to be evaluated:
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struct energy_env {
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struct sched_group *sg_top;
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struct sched_group *sg_cap;
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int cap_idx;
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int util_delta;
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int src_cpu;
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int dst_cpu;
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int energy;
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};
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sg_top: sched_group to be evaluated. Not used by energy_diff().
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sg_cap: sched_group covering the cpus in the same frequency domain. Set by
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sched_group_energy().
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cap_idx: Capacity state to be used for energy calculations. Set by
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find_new_capacity().
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util_delta: Amount of utilization to be added, removed, or migrated.
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src_cpu: Source cpu from where 'util_delta' utilization is removed. Should be
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-1 if no source (e.g. task wake-up).
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dst_cpu: Destination cpu where 'util_delta' utilization is added. Should be -1
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if utilization is removed (e.g. terminating tasks).
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energy: Result of sched_group_energy().
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The metric used to represent utilization is the actual per-entity running time
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averaged over time using a geometric series. Very similar to the existing
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per-entity load-tracking, but _not_ scaled by task priority and capped by the
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capacity of the cpu. The latter property does mean that utilization may
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underestimate the compute requirements for task on fully/over utilized cpus.
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The greatest potential for energy savings without affecting performance too much
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is scenarios where the system isn't fully utilized. If the system is deemed
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fully utilized load-balancing should be done with task load (includes task
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priority) instead in the interest of fairness and performance.
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Background and Terminology
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===========================
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To make it clear from the start:
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energy = [joule] (resource like a battery on powered devices)
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power = energy/time = [joule/second] = [watt]
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The goal of energy-aware scheduling is to minimize energy, while still getting
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the job done. That is, we want to maximize:
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performance [inst/s]
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--------------------
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power [W]
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which is equivalent to minimizing:
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energy [J]
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-----------
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instruction
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while still getting 'good' performance. It is essentially an alternative
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optimization objective to the current performance-only objective for the
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scheduler. This alternative considers two objectives: energy-efficiency and
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performance. Hence, there needs to be a user controllable knob to switch the
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objective. Since it is early days, this is currently a sched_feature
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(ENERGY_AWARE).
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The idea behind introducing an energy cost model is to allow the scheduler to
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evaluate the implications of its decisions rather than applying energy-saving
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techniques blindly that may only have positive effects on some platforms. At
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the same time, the energy cost model must be as simple as possible to minimize
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the scheduler latency impact.
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Platform topology
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------------------
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The system topology (cpus, caches, and NUMA information, not peripherals) is
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represented in the scheduler by the sched_domain hierarchy which has
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sched_groups attached at each level that covers one or more cpus (see
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sched-domains.txt for more details). To add energy awareness to the scheduler
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we need to consider power and frequency domains.
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Power domain:
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A power domain is a part of the system that can be powered on/off
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independently. Power domains are typically organized in a hierarchy where you
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may be able to power down just a cpu or a group of cpus along with any
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associated resources (e.g. shared caches). Powering up a cpu means that all
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power domains it is a part of in the hierarchy must be powered up. Hence, it is
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more expensive to power up the first cpu that belongs to a higher level power
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domain than powering up additional cpus in the same high level domain. Two
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level power domain hierarchy example:
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Power source
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+-------------------------------+----...
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per group PD G G
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| +----------+ |
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+--------+-------| Shared | (other groups)
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per-cpu PD G G | resource |
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| | +----------+
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+-------+ +-------+
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| CPU 0 | | CPU 1 |
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+-------+ +-------+
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Frequency domain:
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Frequency domains (P-states) typically cover the same group of cpus as one of
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the power domain levels. That is, there might be several smaller power domains
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sharing the same frequency (P-state) or there might be a power domain spanning
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multiple frequency domains.
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From a scheduling point of view there is no need to know the actual frequencies
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[Hz]. All the scheduler cares about is the compute capacity available at the
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current state (P-state) the cpu is in and any other available states. For that
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reason, and to also factor in any cpu micro-architecture differences, compute
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capacity scaling states are called 'capacity states' in this document. For SMP
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systems this is equivalent to P-states. For mixed micro-architecture systems
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(like ARM big.LITTLE) it is P-states scaled according to the micro-architecture
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performance relative to the other cpus in the system.
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Energy modelling:
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------------------
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Due to the hierarchical nature of the power domains, the most obvious way to
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model energy costs is therefore to associate power and energy costs with
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domains (groups of cpus). Energy costs of shared resources are associated with
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the group of cpus that share the resources, only the cost of powering the
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cpu itself and any private resources (e.g. private L1 caches) is associated
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with the per-cpu groups (lowest level).
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For example, for an SMP system with per-cpu power domains and a cluster level
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(group of cpus) power domain we get the overall energy costs to be:
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energy = energy_cluster + n * energy_cpu
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where 'n' is the number of cpus powered up and energy_cluster is the cost paid
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as soon as any cpu in the cluster is powered up.
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The power and frequency domains can naturally be mapped onto the existing
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sched_domain hierarchy and sched_groups by adding the necessary data to the
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existing data structures.
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The energy model considers energy consumption from two contributors (shown in
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the illustration below):
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1. Busy energy: Energy consumed while a cpu and the higher level groups that it
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belongs to are busy running tasks. Busy energy is associated with the state of
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the cpu, not an event. The time the cpu spends in this state varies. Thus, the
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most obvious platform parameter for this contribution is busy power
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(energy/time).
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2. Idle energy: Energy consumed while a cpu and higher level groups that it
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belongs to are idle (in a C-state). Like busy energy, idle energy is associated
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with the state of the cpu. Thus, the platform parameter for this contribution
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is idle power (energy/time).
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Energy consumed during transitions from an idle-state (C-state) to a busy state
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(P-state) or going the other way is ignored by the model to simplify the energy
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model calculations.
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Power
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^
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| busy->idle idle->busy
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| transition transition
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| _ __
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| / \ / \__________________
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|______________/ \ /
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| \ /
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| Busy \ Idle / Busy
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| low P-state \____________/ high P-state
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+------------------------------------------------------------> time
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Busy |--------------| |-----------------|
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Wakeup |------| |------|
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Idle |------------|
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The basic algorithm
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====================
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The basic idea is to determine the total energy impact when utilization is
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added or removed by estimating the impact at each level in the sched_domain
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hierarchy starting from the bottom (sched_group contains just a single cpu).
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The energy cost comes from busy time (sched_group is awake because one or more
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cpus are busy) and idle time (in an idle-state). Energy model numbers account
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for energy costs associated with all cpus in the sched_group as a group.
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for_each_domain(cpu, sd) {
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sg = sched_group_of(cpu)
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energy_before = curr_util(sg) * busy_power(sg)
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+ (1-curr_util(sg)) * idle_power(sg)
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energy_after = new_util(sg) * busy_power(sg)
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+ (1-new_util(sg)) * idle_power(sg)
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energy_diff += energy_before - energy_after
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}
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return energy_diff
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{curr, new}_util: The cpu utilization at the lowest level and the overall
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non-idle time for the entire group for higher levels. Utilization is in the
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range 0.0 to 1.0 in the pseudo-code.
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busy_power: The power consumption of the sched_group.
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idle_power: The power consumption of the sched_group when idle.
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Note: It is a fundamental assumption that the utilization is (roughly) scale
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invariant. Task utilization tracking factors in any frequency scaling and
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performance scaling differences due to difference cpu microarchitectures such
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that task utilization can be used across the entire system.
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Platform energy data
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=====================
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struct sched_group_energy can be attached to sched_groups in the sched_domain
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hierarchy and has the following members:
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cap_states:
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List of struct capacity_state representing the supported capacity states
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(P-states). struct capacity_state has two members: cap and power, which
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represents the compute capacity and the busy_power of the state. The
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list must be ordered by capacity low->high.
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nr_cap_states:
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Number of capacity states in cap_states list.
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idle_states:
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List of struct idle_state containing idle_state power cost for each
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idle-state supported by the system orderd by shallowest state first.
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All states must be included at all level in the hierarchy, i.e. a
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sched_group spanning just a single cpu must also include coupled
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idle-states (cluster states). In addition to the cpuidle idle-states,
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the list must also contain an entry for the idling using the arch
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default idle (arch_idle_cpu()). Despite this state may not be a true
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hardware idle-state it is considered the shallowest idle-state in the
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energy model and must be the first entry. cpus may enter this state
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(possibly 'active idling') if cpuidle decides not enter a cpuidle
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idle-state. Default idle may not be used when cpuidle is enabled.
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In this case, it should just be a copy of the first cpuidle idle-state.
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nr_idle_states:
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Number of idle states in idle_states list.
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There are no unit requirements for the energy cost data. Data can be normalized
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with any reference, however, the normalization must be consistent across all
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energy cost data. That is, one bogo-joule/watt must be the same quantity for
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data, but we don't care what it is.
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A recipe for platform characterization
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=======================================
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Obtaining the actual model data for a particular platform requires some way of
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measuring power/energy. There isn't a tool to help with this (yet). This
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section provides a recipe for use as reference. It covers the steps used to
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characterize the ARM TC2 development platform. This sort of measurements is
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expected to be done anyway when tuning cpuidle and cpufreq for a given
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platform.
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The energy model needs two types of data (struct sched_group_energy holds
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these) for each sched_group where energy costs should be taken into account:
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1. Capacity state information
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A list containing the compute capacity and power consumption when fully
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utilized attributed to the group as a whole for each available capacity state.
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At the lowest level (group contains just a single cpu) this is the power of the
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cpu alone without including power consumed by resources shared with other cpus.
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It basically needs to fit the basic modelling approach described in "Background
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and Terminology" section:
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energy_system = energy_shared + n * energy_cpu
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for a system containing 'n' busy cpus. Only 'energy_cpu' should be included at
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the lowest level. 'energy_shared' is included at the next level which
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represents the group of cpus among which the resources are shared.
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This model is, of course, a simplification of reality. Thus, power/energy
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attributions might not always exactly represent how the hardware is designed.
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Also, busy power is likely to depend on the workload. It is therefore
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recommended to use a representative mix of workloads when characterizing the
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capacity states.
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If the group has no capacity scaling support, the list will contain a single
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state where power is the busy power attributed to the group. The capacity
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should be set to a default value (1024).
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When frequency domains include multiple power domains, the group representing
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the frequency domain and all child groups share capacity states. This must be
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indicated by setting the SD_SHARE_CAP_STATES sched_domain flag. All groups at
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all levels that share the capacity state must have the list of capacity states
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with the power set to the contribution of the individual group.
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2. Idle power information
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Stored in the idle_states list. The power number is the group idle power
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consumption in each idle state as well when the group is idle but has not
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entered an idle-state ('active idle' as mentioned earlier). Due to the way the
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energy model is defined, the idle power of the deepest group idle state can
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alternatively be accounted for in the parent group busy power. In that case the
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group idle state power values are offset such that the idle power of the
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deepest state is zero. It is less intuitive, but it is easier to measure as
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idle power consumed by the group and the busy/idle power of the parent group
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cannot be distinguished without per group measurement points.
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Measuring capacity states and idle power:
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The capacity states' capacity and power can be estimated by running a benchmark
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workload at each available capacity state. By restricting the benchmark to run
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on subsets of cpus it is possible to extrapolate the power consumption of
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shared resources.
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ARM TC2 has two clusters of two and three cpus respectively. Each cluster has a
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shared L2 cache. TC2 has on-chip energy counters per cluster. Running a
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benchmark workload on just one cpu in a cluster means that power is consumed in
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the cluster (higher level group) and a single cpu (lowest level group). Adding
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another benchmark task to another cpu increases the power consumption by the
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amount consumed by the additional cpu. Hence, it is possible to extrapolate the
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cluster busy power.
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For platforms that don't have energy counters or equivalent instrumentation
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built-in, it may be possible to use an external DAQ to acquire similar data.
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If the benchmark includes some performance score (for example sysbench cpu
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benchmark), this can be used to record the compute capacity.
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Measuring idle power requires insight into the idle state implementation on the
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particular platform. Specifically, if the platform has coupled idle-states (or
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package states). To measure non-coupled per-cpu idle-states it is necessary to
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keep one cpu busy to keep any shared resources alive to isolate the idle power
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of the cpu from idle/busy power of the shared resources. The cpu can be tricked
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into different per-cpu idle states by disabling the other states. Based on
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various combinations of measurements with specific cpus busy and disabling
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idle-states it is possible to extrapolate the idle-state power.
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