| .. SPDX-License-Identifier: GPL-2.0 |
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| Hardware-Feedback Interface for scheduling on Intel Hardware |
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| |
| Overview |
| -------- |
| |
| Intel has described the Hardware Feedback Interface (HFI) in the Intel 64 and |
| IA-32 Architectures Software Developer's Manual (Intel SDM) Volume 3 Section |
| 14.6 [1]_. |
| |
| The HFI gives the operating system a performance and energy efficiency |
| capability data for each CPU in the system. Linux can use the information from |
| the HFI to influence task placement decisions. |
| |
| The Hardware Feedback Interface |
| ------------------------------- |
| |
| The Hardware Feedback Interface provides to the operating system information |
| about the performance and energy efficiency of each CPU in the system. Each |
| capability is given as a unit-less quantity in the range [0-255]. Higher values |
| indicate higher capability. Energy efficiency and performance are reported in |
| separate capabilities. Even though on some systems these two metrics may be |
| related, they are specified as independent capabilities in the Intel SDM. |
| |
| These capabilities may change at runtime as a result of changes in the |
| operating conditions of the system or the action of external factors. The rate |
| at which these capabilities are updated is specific to each processor model. On |
| some models, capabilities are set at boot time and never change. On others, |
| capabilities may change every tens of milliseconds. For instance, a remote |
| mechanism may be used to lower Thermal Design Power. Such change can be |
| reflected in the HFI. Likewise, if the system needs to be throttled due to |
| excessive heat, the HFI may reflect reduced performance on specific CPUs. |
| |
| The kernel or a userspace policy daemon can use these capabilities to modify |
| task placement decisions. For instance, if either the performance or energy |
| capabilities of a given logical processor becomes zero, it is an indication that |
| the hardware recommends to the operating system to not schedule any tasks on |
| that processor for performance or energy efficiency reasons, respectively. |
| |
| Implementation details for Linux |
| -------------------------------- |
| |
| The infrastructure to handle thermal event interrupts has two parts. In the |
| Local Vector Table of a CPU's local APIC, there exists a register for the |
| Thermal Monitor Register. This register controls how interrupts are delivered |
| to a CPU when the thermal monitor generates and interrupt. Further details |
| can be found in the Intel SDM Vol. 3 Section 10.5 [1]_. |
| |
| The thermal monitor may generate interrupts per CPU or per package. The HFI |
| generates package-level interrupts. This monitor is configured and initialized |
| via a set of machine-specific registers. Specifically, the HFI interrupt and |
| status are controlled via designated bits in the IA32_PACKAGE_THERM_INTERRUPT |
| and IA32_PACKAGE_THERM_STATUS registers, respectively. There exists one HFI |
| table per package. Further details can be found in the Intel SDM Vol. 3 |
| Section 14.9 [1]_. |
| |
| The hardware issues an HFI interrupt after updating the HFI table and is ready |
| for the operating system to consume it. CPUs receive such interrupt via the |
| thermal entry in the Local APIC's Local Vector Table. |
| |
| When servicing such interrupt, the HFI driver parses the updated table and |
| relays the update to userspace using the thermal notification framework. Given |
| that there may be many HFI updates every second, the updates relayed to |
| userspace are throttled at a rate of CONFIG_HZ jiffies. |
| |
| References |
| ---------- |
| |
| .. [1] https://www.intel.com/sdm |
