1 ========================= 1 ========================= 2 Capacity Aware Scheduling 2 Capacity Aware Scheduling 3 ========================= 3 ========================= 4 4 5 1. CPU Capacity 5 1. CPU Capacity 6 =============== 6 =============== 7 7 8 1.1 Introduction 8 1.1 Introduction 9 ---------------- 9 ---------------- 10 10 11 Conventional, homogeneous SMP platforms are co 11 Conventional, homogeneous SMP platforms are composed of purely identical 12 CPUs. Heterogeneous platforms on the other han 12 CPUs. Heterogeneous platforms on the other hand are composed of CPUs with 13 different performance characteristics - on suc 13 different performance characteristics - on such platforms, not all CPUs can be 14 considered equal. 14 considered equal. 15 15 16 CPU capacity is a measure of the performance a 16 CPU capacity is a measure of the performance a CPU can reach, normalized against 17 the most performant CPU in the system. Heterog 17 the most performant CPU in the system. Heterogeneous systems are also called 18 asymmetric CPU capacity systems, as they conta 18 asymmetric CPU capacity systems, as they contain CPUs of different capacities. 19 19 20 Disparity in maximum attainable performance (I 20 Disparity in maximum attainable performance (IOW in maximum CPU capacity) stems 21 from two factors: 21 from two factors: 22 22 23 - not all CPUs may have the same microarchitec 23 - not all CPUs may have the same microarchitecture (µarch). 24 - with Dynamic Voltage and Frequency Scaling ( 24 - with Dynamic Voltage and Frequency Scaling (DVFS), not all CPUs may be 25 physically able to attain the higher Operati 25 physically able to attain the higher Operating Performance Points (OPP). 26 26 27 Arm big.LITTLE systems are an example of both. 27 Arm big.LITTLE systems are an example of both. The big CPUs are more 28 performance-oriented than the LITTLE ones (mor 28 performance-oriented than the LITTLE ones (more pipeline stages, bigger caches, 29 smarter predictors, etc), and can usually reac 29 smarter predictors, etc), and can usually reach higher OPPs than the LITTLE ones 30 can. 30 can. 31 31 32 CPU performance is usually expressed in Millio 32 CPU performance is usually expressed in Millions of Instructions Per Second 33 (MIPS), which can also be expressed as a given 33 (MIPS), which can also be expressed as a given amount of instructions attainable 34 per Hz, leading to:: 34 per Hz, leading to:: 35 35 36 capacity(cpu) = work_per_hz(cpu) * max_freq( 36 capacity(cpu) = work_per_hz(cpu) * max_freq(cpu) 37 37 38 1.2 Scheduler terms 38 1.2 Scheduler terms 39 ------------------- 39 ------------------- 40 40 41 Two different capacity values are used within 41 Two different capacity values are used within the scheduler. A CPU's 42 ``original capacity`` is its maximum attainabl !! 42 ``capacity_orig`` is its maximum attainable capacity, i.e. its maximum 43 attainable performance level. This original ca !! 43 attainable performance level. A CPU's ``capacity`` is its ``capacity_orig`` to 44 the function arch_scale_cpu_capacity(). A CPU' !! 44 which some loss of available performance (e.g. time spent handling IRQs) is 45 capacity`` to which some loss of available per !! 45 subtracted. 46 handling IRQs) is subtracted. << 47 46 48 Note that a CPU's ``capacity`` is solely inten 47 Note that a CPU's ``capacity`` is solely intended to be used by the CFS class, 49 while ``original capacity`` is class-agnostic. !! 48 while ``capacity_orig`` is class-agnostic. The rest of this document will use 50 the term ``capacity`` interchangeably with ``o !! 49 the term ``capacity`` interchangeably with ``capacity_orig`` for the sake of 51 brevity. 50 brevity. 52 51 53 1.3 Platform examples 52 1.3 Platform examples 54 --------------------- 53 --------------------- 55 54 56 1.3.1 Identical OPPs 55 1.3.1 Identical OPPs 57 ~~~~~~~~~~~~~~~~~~~~ 56 ~~~~~~~~~~~~~~~~~~~~ 58 57 59 Consider an hypothetical dual-core asymmetric 58 Consider an hypothetical dual-core asymmetric CPU capacity system where 60 59 61 - work_per_hz(CPU0) = W 60 - work_per_hz(CPU0) = W 62 - work_per_hz(CPU1) = W/2 61 - work_per_hz(CPU1) = W/2 63 - all CPUs are running at the same fixed frequ 62 - all CPUs are running at the same fixed frequency 64 63 65 By the above definition of capacity: 64 By the above definition of capacity: 66 65 67 - capacity(CPU0) = C 66 - capacity(CPU0) = C 68 - capacity(CPU1) = C/2 67 - capacity(CPU1) = C/2 69 68 70 To draw the parallel with Arm big.LITTLE, CPU0 69 To draw the parallel with Arm big.LITTLE, CPU0 would be a big while CPU1 would 71 be a LITTLE. 70 be a LITTLE. 72 71 73 With a workload that periodically does a fixed 72 With a workload that periodically does a fixed amount of work, you will get an 74 execution trace like so:: 73 execution trace like so:: 75 74 76 CPU0 work ^ 75 CPU0 work ^ 77 | ____ ____ 76 | ____ ____ ____ 78 | | | | | 77 | | | | | | | 79 +----+----+----+----+----+----+---- 78 +----+----+----+----+----+----+----+----+----+----+-> time 80 79 81 CPU1 work ^ 80 CPU1 work ^ 82 | _________ _________ 81 | _________ _________ ____ 83 | | | | 82 | | | | | | 84 +----+----+----+----+----+----+---- 83 +----+----+----+----+----+----+----+----+----+----+-> time 85 84 86 CPU0 has the highest capacity in the system (C 85 CPU0 has the highest capacity in the system (C), and completes a fixed amount of 87 work W in T units of time. On the other hand, 86 work W in T units of time. On the other hand, CPU1 has half the capacity of 88 CPU0, and thus only completes W/2 in T. 87 CPU0, and thus only completes W/2 in T. 89 88 90 1.3.2 Different max OPPs 89 1.3.2 Different max OPPs 91 ~~~~~~~~~~~~~~~~~~~~~~~~ 90 ~~~~~~~~~~~~~~~~~~~~~~~~ 92 91 93 Usually, CPUs of different capacity values als 92 Usually, CPUs of different capacity values also have different maximum 94 OPPs. Consider the same CPUs as above (i.e. sa 93 OPPs. Consider the same CPUs as above (i.e. same work_per_hz()) with: 95 94 96 - max_freq(CPU0) = F 95 - max_freq(CPU0) = F 97 - max_freq(CPU1) = 2/3 * F 96 - max_freq(CPU1) = 2/3 * F 98 97 99 This yields: 98 This yields: 100 99 101 - capacity(CPU0) = C 100 - capacity(CPU0) = C 102 - capacity(CPU1) = C/3 101 - capacity(CPU1) = C/3 103 102 104 Executing the same workload as described in 1. 103 Executing the same workload as described in 1.3.1, which each CPU running at its 105 maximum frequency results in:: 104 maximum frequency results in:: 106 105 107 CPU0 work ^ 106 CPU0 work ^ 108 | ____ ____ 107 | ____ ____ ____ 109 | | | | | 108 | | | | | | | 110 +----+----+----+----+----+----+---- 109 +----+----+----+----+----+----+----+----+----+----+-> time 111 110 112 workload on CPU1 111 workload on CPU1 113 CPU1 work ^ 112 CPU1 work ^ 114 | ______________ _________ 113 | ______________ ______________ ____ 115 | | | | 114 | | | | | | 116 +----+----+----+----+----+----+---- 115 +----+----+----+----+----+----+----+----+----+----+-> time 117 116 118 1.4 Representation caveat 117 1.4 Representation caveat 119 ------------------------- 118 ------------------------- 120 119 121 It should be noted that having a *single* valu 120 It should be noted that having a *single* value to represent differences in CPU 122 performance is somewhat of a contentious point 121 performance is somewhat of a contentious point. The relative performance 123 difference between two different µarchs could 122 difference between two different µarchs could be X% on integer operations, Y% on 124 floating point operations, Z% on branches, and 123 floating point operations, Z% on branches, and so on. Still, results using this 125 simple approach have been satisfactory for now 124 simple approach have been satisfactory for now. 126 125 127 2. Task utilization 126 2. Task utilization 128 =================== 127 =================== 129 128 130 2.1 Introduction 129 2.1 Introduction 131 ---------------- 130 ---------------- 132 131 133 Capacity aware scheduling requires an expressi 132 Capacity aware scheduling requires an expression of a task's requirements with 134 regards to CPU capacity. Each scheduler class 133 regards to CPU capacity. Each scheduler class can express this differently, and 135 while task utilization is specific to CFS, it 134 while task utilization is specific to CFS, it is convenient to describe it here 136 in order to introduce more generic concepts. 135 in order to introduce more generic concepts. 137 136 138 Task utilization is a percentage meant to repr 137 Task utilization is a percentage meant to represent the throughput requirements 139 of a task. A simple approximation of it is the 138 of a task. A simple approximation of it is the task's duty cycle, i.e.:: 140 139 141 task_util(p) = duty_cycle(p) 140 task_util(p) = duty_cycle(p) 142 141 143 On an SMP system with fixed frequencies, 100% 142 On an SMP system with fixed frequencies, 100% utilization suggests the task is a 144 busy loop. Conversely, 10% utilization hints i 143 busy loop. Conversely, 10% utilization hints it is a small periodic task that 145 spends more time sleeping than executing. Vari 144 spends more time sleeping than executing. Variable CPU frequencies and 146 asymmetric CPU capacities complexify this some 145 asymmetric CPU capacities complexify this somewhat; the following sections will 147 expand on these. 146 expand on these. 148 147 149 2.2 Frequency invariance 148 2.2 Frequency invariance 150 ------------------------ 149 ------------------------ 151 150 152 One issue that needs to be taken into account 151 One issue that needs to be taken into account is that a workload's duty cycle is 153 directly impacted by the current OPP the CPU i 152 directly impacted by the current OPP the CPU is running at. Consider running a 154 periodic workload at a given frequency F:: 153 periodic workload at a given frequency F:: 155 154 156 CPU work ^ 155 CPU work ^ 157 | ____ ____ 156 | ____ ____ ____ 158 | | | | | 157 | | | | | | | 159 +----+----+----+----+----+----+---- 158 +----+----+----+----+----+----+----+----+----+----+-> time 160 159 161 This yields duty_cycle(p) == 25%. 160 This yields duty_cycle(p) == 25%. 162 161 163 Now, consider running the *same* workload at f 162 Now, consider running the *same* workload at frequency F/2:: 164 163 165 CPU work ^ 164 CPU work ^ 166 | _________ _________ 165 | _________ _________ ____ 167 | | | | 166 | | | | | | 168 +----+----+----+----+----+----+---- 167 +----+----+----+----+----+----+----+----+----+----+-> time 169 168 170 This yields duty_cycle(p) == 50%, despite the 169 This yields duty_cycle(p) == 50%, despite the task having the exact same 171 behaviour (i.e. executing the same amount of w 170 behaviour (i.e. executing the same amount of work) in both executions. 172 171 173 The task utilization signal can be made freque 172 The task utilization signal can be made frequency invariant using the following 174 formula:: 173 formula:: 175 174 176 task_util_freq_inv(p) = duty_cycle(p) * (cur 175 task_util_freq_inv(p) = duty_cycle(p) * (curr_frequency(cpu) / max_frequency(cpu)) 177 176 178 Applying this formula to the two examples abov 177 Applying this formula to the two examples above yields a frequency invariant 179 task utilization of 25%. 178 task utilization of 25%. 180 179 181 2.3 CPU invariance 180 2.3 CPU invariance 182 ------------------ 181 ------------------ 183 182 184 CPU capacity has a similar effect on task util 183 CPU capacity has a similar effect on task utilization in that running an 185 identical workload on CPUs of different capaci 184 identical workload on CPUs of different capacity values will yield different 186 duty cycles. 185 duty cycles. 187 186 188 Consider the system described in 1.3.2., i.e.: 187 Consider the system described in 1.3.2., i.e.:: 189 188 190 - capacity(CPU0) = C 189 - capacity(CPU0) = C 191 - capacity(CPU1) = C/3 190 - capacity(CPU1) = C/3 192 191 193 Executing a given periodic workload on each CP 192 Executing a given periodic workload on each CPU at their maximum frequency would 194 result in:: 193 result in:: 195 194 196 CPU0 work ^ 195 CPU0 work ^ 197 | ____ ____ 196 | ____ ____ ____ 198 | | | | | 197 | | | | | | | 199 +----+----+----+----+----+----+---- 198 +----+----+----+----+----+----+----+----+----+----+-> time 200 199 201 CPU1 work ^ 200 CPU1 work ^ 202 | ______________ _________ 201 | ______________ ______________ ____ 203 | | | | 202 | | | | | | 204 +----+----+----+----+----+----+---- 203 +----+----+----+----+----+----+----+----+----+----+-> time 205 204 206 IOW, 205 IOW, 207 206 208 - duty_cycle(p) == 25% if p runs on CPU0 at it 207 - duty_cycle(p) == 25% if p runs on CPU0 at its maximum frequency 209 - duty_cycle(p) == 75% if p runs on CPU1 at it 208 - duty_cycle(p) == 75% if p runs on CPU1 at its maximum frequency 210 209 211 The task utilization signal can be made CPU in 210 The task utilization signal can be made CPU invariant using the following 212 formula:: 211 formula:: 213 212 214 task_util_cpu_inv(p) = duty_cycle(p) * (capa 213 task_util_cpu_inv(p) = duty_cycle(p) * (capacity(cpu) / max_capacity) 215 214 216 with ``max_capacity`` being the highest CPU ca 215 with ``max_capacity`` being the highest CPU capacity value in the 217 system. Applying this formula to the above exa 216 system. Applying this formula to the above example above yields a CPU 218 invariant task utilization of 25%. 217 invariant task utilization of 25%. 219 218 220 2.4 Invariant task utilization 219 2.4 Invariant task utilization 221 ------------------------------ 220 ------------------------------ 222 221 223 Both frequency and CPU invariance need to be a 222 Both frequency and CPU invariance need to be applied to task utilization in 224 order to obtain a truly invariant signal. The 223 order to obtain a truly invariant signal. The pseudo-formula for a task 225 utilization that is both CPU and frequency inv 224 utilization that is both CPU and frequency invariant is thus, for a given 226 task p:: 225 task p:: 227 226 228 curr_freq 227 curr_frequency(cpu) capacity(cpu) 229 task_util_inv(p) = duty_cycle(p) * --------- 228 task_util_inv(p) = duty_cycle(p) * ------------------- * ------------- 230 max_frequ 229 max_frequency(cpu) max_capacity 231 230 232 In other words, invariant task utilization des 231 In other words, invariant task utilization describes the behaviour of a task as 233 if it were running on the highest-capacity CPU 232 if it were running on the highest-capacity CPU in the system, running at its 234 maximum frequency. 233 maximum frequency. 235 234 236 Any mention of task utilization in the followi 235 Any mention of task utilization in the following sections will imply its 237 invariant form. 236 invariant form. 238 237 239 2.5 Utilization estimation 238 2.5 Utilization estimation 240 -------------------------- 239 -------------------------- 241 240 242 Without a crystal ball, task behaviour (and th 241 Without a crystal ball, task behaviour (and thus task utilization) cannot 243 accurately be predicted the moment a task firs 242 accurately be predicted the moment a task first becomes runnable. The CFS class 244 maintains a handful of CPU and task signals ba 243 maintains a handful of CPU and task signals based on the Per-Entity Load 245 Tracking (PELT) mechanism, one of those yieldi 244 Tracking (PELT) mechanism, one of those yielding an *average* utilization (as 246 opposed to instantaneous). 245 opposed to instantaneous). 247 246 248 This means that while the capacity aware sched 247 This means that while the capacity aware scheduling criteria will be written 249 considering a "true" task utilization (using a 248 considering a "true" task utilization (using a crystal ball), the implementation 250 will only ever be able to use an estimator the 249 will only ever be able to use an estimator thereof. 251 250 252 3. Capacity aware scheduling requirements 251 3. Capacity aware scheduling requirements 253 ========================================= 252 ========================================= 254 253 255 3.1 CPU capacity 254 3.1 CPU capacity 256 ---------------- 255 ---------------- 257 256 258 Linux cannot currently figure out CPU capacity 257 Linux cannot currently figure out CPU capacity on its own, this information thus 259 needs to be handed to it. Architectures must d 258 needs to be handed to it. Architectures must define arch_scale_cpu_capacity() 260 for that purpose. 259 for that purpose. 261 260 262 The arm, arm64, and RISC-V architectures direc !! 261 The arm and arm64 architectures directly map this to the arch_topology driver 263 CPU scaling data, which is derived from the ca 262 CPU scaling data, which is derived from the capacity-dmips-mhz CPU binding; see 264 Documentation/devicetree/bindings/cpu/cpu-capa !! 263 Documentation/devicetree/bindings/arm/cpu-capacity.txt. 265 264 266 3.2 Frequency invariance 265 3.2 Frequency invariance 267 ------------------------ 266 ------------------------ 268 267 269 As stated in 2.2, capacity-aware scheduling re 268 As stated in 2.2, capacity-aware scheduling requires a frequency-invariant task 270 utilization. Architectures must define arch_sc 269 utilization. Architectures must define arch_scale_freq_capacity(cpu) for that 271 purpose. 270 purpose. 272 271 273 Implementing this function requires figuring o 272 Implementing this function requires figuring out at which frequency each CPU 274 have been running at. One way to implement thi 273 have been running at. One way to implement this is to leverage hardware counters 275 whose increment rate scale with a CPU's curren 274 whose increment rate scale with a CPU's current frequency (APERF/MPERF on x86, 276 AMU on arm64). Another is to directly hook int 275 AMU on arm64). Another is to directly hook into cpufreq frequency transitions, 277 when the kernel is aware of the switched-to fr 276 when the kernel is aware of the switched-to frequency (also employed by 278 arm/arm64). 277 arm/arm64). 279 278 280 4. Scheduler topology 279 4. Scheduler topology 281 ===================== 280 ===================== 282 281 283 During the construction of the sched domains, 282 During the construction of the sched domains, the scheduler will figure out 284 whether the system exhibits asymmetric CPU cap 283 whether the system exhibits asymmetric CPU capacities. Should that be the 285 case: 284 case: 286 285 287 - The sched_asym_cpucapacity static key will b 286 - The sched_asym_cpucapacity static key will be enabled. 288 - The SD_ASYM_CPUCAPACITY_FULL flag will be se 287 - The SD_ASYM_CPUCAPACITY_FULL flag will be set at the lowest sched_domain 289 level that spans all unique CPU capacity val 288 level that spans all unique CPU capacity values. 290 - The SD_ASYM_CPUCAPACITY flag will be set for 289 - The SD_ASYM_CPUCAPACITY flag will be set for any sched_domain that spans 291 CPUs with any range of asymmetry. 290 CPUs with any range of asymmetry. 292 291 293 The sched_asym_cpucapacity static key is inten 292 The sched_asym_cpucapacity static key is intended to guard sections of code that 294 cater to asymmetric CPU capacity systems. Do n 293 cater to asymmetric CPU capacity systems. Do note however that said key is 295 *system-wide*. Imagine the following setup usi 294 *system-wide*. Imagine the following setup using cpusets:: 296 295 297 capacity C/2 C 296 capacity C/2 C 298 ________ ________ 297 ________ ________ 299 / \ / \ 298 / \ / \ 300 CPUs 0 1 2 3 4 5 6 7 299 CPUs 0 1 2 3 4 5 6 7 301 \__/ \______________/ 300 \__/ \______________/ 302 cpusets cs0 cs1 301 cpusets cs0 cs1 303 302 304 Which could be created via: 303 Which could be created via: 305 304 306 .. code-block:: sh 305 .. code-block:: sh 307 306 308 mkdir /sys/fs/cgroup/cpuset/cs0 307 mkdir /sys/fs/cgroup/cpuset/cs0 309 echo 0-1 > /sys/fs/cgroup/cpuset/cs0/cpuset. 308 echo 0-1 > /sys/fs/cgroup/cpuset/cs0/cpuset.cpus 310 echo 0 > /sys/fs/cgroup/cpuset/cs0/cpuset.me 309 echo 0 > /sys/fs/cgroup/cpuset/cs0/cpuset.mems 311 310 312 mkdir /sys/fs/cgroup/cpuset/cs1 311 mkdir /sys/fs/cgroup/cpuset/cs1 313 echo 2-7 > /sys/fs/cgroup/cpuset/cs1/cpuset. 312 echo 2-7 > /sys/fs/cgroup/cpuset/cs1/cpuset.cpus 314 echo 0 > /sys/fs/cgroup/cpuset/cs1/cpuset.me 313 echo 0 > /sys/fs/cgroup/cpuset/cs1/cpuset.mems 315 314 316 echo 0 > /sys/fs/cgroup/cpuset/cpuset.sched_ 315 echo 0 > /sys/fs/cgroup/cpuset/cpuset.sched_load_balance 317 316 318 Since there *is* CPU capacity asymmetry in the 317 Since there *is* CPU capacity asymmetry in the system, the 319 sched_asym_cpucapacity static key will be enab 318 sched_asym_cpucapacity static key will be enabled. However, the sched_domain 320 hierarchy of CPUs 0-1 spans a single capacity 319 hierarchy of CPUs 0-1 spans a single capacity value: SD_ASYM_CPUCAPACITY isn't 321 set in that hierarchy, it describes an SMP isl 320 set in that hierarchy, it describes an SMP island and should be treated as such. 322 321 323 Therefore, the 'canonical' pattern for protect 322 Therefore, the 'canonical' pattern for protecting codepaths that cater to 324 asymmetric CPU capacities is to: 323 asymmetric CPU capacities is to: 325 324 326 - Check the sched_asym_cpucapacity static key 325 - Check the sched_asym_cpucapacity static key 327 - If it is enabled, then also check for the pr 326 - If it is enabled, then also check for the presence of SD_ASYM_CPUCAPACITY in 328 the sched_domain hierarchy (if relevant, i.e 327 the sched_domain hierarchy (if relevant, i.e. the codepath targets a specific 329 CPU or group thereof) 328 CPU or group thereof) 330 329 331 5. Capacity aware scheduling implementation 330 5. Capacity aware scheduling implementation 332 =========================================== 331 =========================================== 333 332 334 5.1 CFS 333 5.1 CFS 335 ------- 334 ------- 336 335 337 5.1.1 Capacity fitness 336 5.1.1 Capacity fitness 338 ~~~~~~~~~~~~~~~~~~~~~~ 337 ~~~~~~~~~~~~~~~~~~~~~~ 339 338 340 The main capacity scheduling criterion of CFS 339 The main capacity scheduling criterion of CFS is:: 341 340 342 task_util(p) < capacity(task_cpu(p)) 341 task_util(p) < capacity(task_cpu(p)) 343 342 344 This is commonly called the capacity fitness c 343 This is commonly called the capacity fitness criterion, i.e. CFS must ensure a 345 task "fits" on its CPU. If it is violated, the 344 task "fits" on its CPU. If it is violated, the task will need to achieve more 346 work than what its CPU can provide: it will be 345 work than what its CPU can provide: it will be CPU-bound. 347 346 348 Furthermore, uclamp lets userspace specify a m 347 Furthermore, uclamp lets userspace specify a minimum and a maximum utilization 349 value for a task, either via sched_setattr() o 348 value for a task, either via sched_setattr() or via the cgroup interface (see 350 Documentation/admin-guide/cgroup-v2.rst). As i 349 Documentation/admin-guide/cgroup-v2.rst). As its name imply, this can be used to 351 clamp task_util() in the previous criterion. 350 clamp task_util() in the previous criterion. 352 351 353 5.1.2 Wakeup CPU selection 352 5.1.2 Wakeup CPU selection 354 ~~~~~~~~~~~~~~~~~~~~~~~~~~ 353 ~~~~~~~~~~~~~~~~~~~~~~~~~~ 355 354 356 CFS task wakeup CPU selection follows the capa 355 CFS task wakeup CPU selection follows the capacity fitness criterion described 357 above. On top of that, uclamp is used to clamp 356 above. On top of that, uclamp is used to clamp the task utilization values, 358 which lets userspace have more leverage over t 357 which lets userspace have more leverage over the CPU selection of CFS 359 tasks. IOW, CFS wakeup CPU selection searches 358 tasks. IOW, CFS wakeup CPU selection searches for a CPU that satisfies:: 360 359 361 clamp(task_util(p), task_uclamp_min(p), task 360 clamp(task_util(p), task_uclamp_min(p), task_uclamp_max(p)) < capacity(cpu) 362 361 363 By using uclamp, userspace can e.g. allow a bu 362 By using uclamp, userspace can e.g. allow a busy loop (100% utilization) to run 364 on any CPU by giving it a low uclamp.max value 363 on any CPU by giving it a low uclamp.max value. Conversely, it can force a small 365 periodic task (e.g. 10% utilization) to run on 364 periodic task (e.g. 10% utilization) to run on the highest-performance CPUs by 366 giving it a high uclamp.min value. 365 giving it a high uclamp.min value. 367 366 368 .. note:: 367 .. note:: 369 368 370 Wakeup CPU selection in CFS can be eclipsed 369 Wakeup CPU selection in CFS can be eclipsed by Energy Aware Scheduling 371 (EAS), which is described in Documentation/s 370 (EAS), which is described in Documentation/scheduler/sched-energy.rst. 372 371 373 5.1.3 Load balancing 372 5.1.3 Load balancing 374 ~~~~~~~~~~~~~~~~~~~~ 373 ~~~~~~~~~~~~~~~~~~~~ 375 374 376 A pathological case in the wakeup CPU selectio 375 A pathological case in the wakeup CPU selection occurs when a task rarely 377 sleeps, if at all - it thus rarely wakes up, i 376 sleeps, if at all - it thus rarely wakes up, if at all. Consider:: 378 377 379 w == wakeup event 378 w == wakeup event 380 379 381 capacity(CPU0) = C 380 capacity(CPU0) = C 382 capacity(CPU1) = C / 3 381 capacity(CPU1) = C / 3 383 382 384 workload on CPU0 383 workload on CPU0 385 CPU work ^ 384 CPU work ^ 386 | _________ _________ 385 | _________ _________ ____ 387 | | | | 386 | | | | | | 388 +----+----+----+----+----+----+---- 387 +----+----+----+----+----+----+----+----+----+----+-> time 389 w w 388 w w w 390 389 391 workload on CPU1 390 workload on CPU1 392 CPU work ^ 391 CPU work ^ 393 | _____________________________ 392 | ____________________________________________ 394 | | 393 | | 395 +----+----+----+----+----+----+---- 394 +----+----+----+----+----+----+----+----+----+----+-> 396 w 395 w 397 396 398 This workload should run on CPU0, but if the t 397 This workload should run on CPU0, but if the task either: 399 398 400 - was improperly scheduled from the start (ina 399 - was improperly scheduled from the start (inaccurate initial 401 utilization estimation) 400 utilization estimation) 402 - was properly scheduled from the start, but s 401 - was properly scheduled from the start, but suddenly needs more 403 processing power 402 processing power 404 403 405 then it might become CPU-bound, IOW ``task_uti 404 then it might become CPU-bound, IOW ``task_util(p) > capacity(task_cpu(p))``; 406 the CPU capacity scheduling criterion is viola 405 the CPU capacity scheduling criterion is violated, and there may not be any more 407 wakeup event to fix this up via wakeup CPU sel 406 wakeup event to fix this up via wakeup CPU selection. 408 407 409 Tasks that are in this situation are dubbed "m 408 Tasks that are in this situation are dubbed "misfit" tasks, and the mechanism 410 put in place to handle this shares the same na 409 put in place to handle this shares the same name. Misfit task migration 411 leverages the CFS load balancer, more specific 410 leverages the CFS load balancer, more specifically the active load balance part 412 (which caters to migrating currently running t 411 (which caters to migrating currently running tasks). When load balance happens, 413 a misfit active load balance will be triggered 412 a misfit active load balance will be triggered if a misfit task can be migrated 414 to a CPU with more capacity than its current o 413 to a CPU with more capacity than its current one. 415 414 416 5.2 RT 415 5.2 RT 417 ------ 416 ------ 418 417 419 5.2.1 Wakeup CPU selection 418 5.2.1 Wakeup CPU selection 420 ~~~~~~~~~~~~~~~~~~~~~~~~~~ 419 ~~~~~~~~~~~~~~~~~~~~~~~~~~ 421 420 422 RT task wakeup CPU selection searches for a CP 421 RT task wakeup CPU selection searches for a CPU that satisfies:: 423 422 424 task_uclamp_min(p) <= capacity(task_cpu(cpu) 423 task_uclamp_min(p) <= capacity(task_cpu(cpu)) 425 424 426 while still following the usual priority const 425 while still following the usual priority constraints. If none of the candidate 427 CPUs can satisfy this capacity criterion, then 426 CPUs can satisfy this capacity criterion, then strict priority based scheduling 428 is followed and CPU capacities are ignored. 427 is followed and CPU capacities are ignored. 429 428 430 5.3 DL 429 5.3 DL 431 ------ 430 ------ 432 431 433 5.3.1 Wakeup CPU selection 432 5.3.1 Wakeup CPU selection 434 ~~~~~~~~~~~~~~~~~~~~~~~~~~ 433 ~~~~~~~~~~~~~~~~~~~~~~~~~~ 435 434 436 DL task wakeup CPU selection searches for a CP 435 DL task wakeup CPU selection searches for a CPU that satisfies:: 437 436 438 task_bandwidth(p) < capacity(task_cpu(p)) 437 task_bandwidth(p) < capacity(task_cpu(p)) 439 438 440 while still respecting the usual bandwidth and 439 while still respecting the usual bandwidth and deadline constraints. If 441 none of the candidate CPUs can satisfy this ca 440 none of the candidate CPUs can satisfy this capacity criterion, then the 442 task will remain on its current CPU. 441 task will remain on its current CPU.
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