Developer Guide

  • 2021.3
  • 11/18/2021
  • Public

Linux* OS Version

To run the real-time readiness checker in a Linux* OS:
  1. From your host system, connect to the target system:
    ssh <user>@<target>
  2. If possible, maximize the terminal window to full size. The real-time readiness checker displays tables of settings that are best viewed in a wide window, though text will wrap and the screen will scroll accordingly.
  3. In the SSH session
    , run the real-time readiness checker:
    tcc_rt_checker | more
  4. If the tool detects a supported processor, it completes all checks and prints the results. Review the Result column for each checker. Possible results are as follows:
    • RT_READY: The target system has the optimal configuration for real-time applications.
    • NON_RT_READY: The target system does not have the optimal configuration.
    • NA: This setting does not have a universal recommended value. Check the Note column to confirm that the setting is correct for your use case.
For more information about the impact and corrective actions for NON_RT_READY checkers, see Recommended Corrective Actions.
Example screenshot (partial):

Command-Line Options

usage: tcc_rt_checker [-h] [-l]
-h, --help
Optional. Show this help message and exit.
-l, --list
Optional. Details about NON_RT_READY results.

Report Description

The report is divided into the following categories:
  • System Information
  • Software SRAM Dependencies Checkers
  • Real-Time BIOS Capabilities Checkers
The following tables contain descriptions of these checkers.
System Information
These checkers verify the presence of a real-time CPU model and print related information.
CPU model
Checks for the presence of a real-time CPU model
CPU frequency
Prints the frequency of all CPU cores
GPU model
Prints the GPU model
GPU frequency
Prints the GPU frequency
Boot firmware version
Checks for the presence of a validated boot firmware version. A validated boot firmware is verified to work with this version of Intel® TCC Tools. A “not validated” message in the tool means that the behavior of the boot firmware with Intel® TCC Tools is unknown or out of the scope of Intel® TCC Tools’ documentation. Contact your boot firmware vendor for more information.
For Slim Bootloader, “validated” means verification of an unmodified source of the Slim Bootloader of this particular version.
Software SRAM buffers list
Prints a list of the software SRAM buffers with their properties. The buffer size is the maximum available size. The size does not include the amount of cache needed for inclusiveness. The information is static. It does not change when applications are using the buffer. See Cache Allocation for details about software SRAM.
Software SRAM Dependencies Checkers
These checkers verify the presence of Intel® TCC Tools dependencies.
Hypervisor checker
Checks that the system is running in the virtualized environment
RTCM checker
Checks that the system is booted with the real-time configuration manager (RTCM) enabled. See Real-Time Configuration Manager (RTCM) for details.
Real-Time Configuration Driver checker
Checks that the real-time configuration driver kernel module is loaded. See Real-Time Configuration Driver for details.
RT kernel checker
Checks that the system is booted with the real-time kernel
GT CLOS Checker
Checks that GPU doesn’t overlap with dedicated L3 CPU CLOS
Linux* kernel’s command-line parameters checker
Checks that all kernel’s command-line parameters required for real-time workload are set
Real-Time BIOS Capabilities Checkers
These checkers verify whether the BIOS configuration matches Intel® Time Coordinated Computing Mode (Intel® TCC Mode). The list of checkers is a subset of all BIOS settings affected by Intel® TCC Mode. Not all relevant BIOS settings can be detected.
Enhanced Intel SpeedStep® Technology
Checks whether Enhanced Intel SpeedStep® Technology (P-states) is disabled. P-states are the various execution power states of the processor. These are the frequency-voltage pairs that dictate the speed at which the processor will run. P-states transitions introduce latencies for real-time applications because of the time it takes to transition between frequencies.
Intel® Speed Shift Technology
Checks whether Intel® Speed Shift Technology is disabled. Intel® Speed Shift Technology lets the hardware switch P-States, which causes latency because of the time it takes to transition between frequencies.
Low Power S0 Idle Capability
Checks whether Low Power S0 Idle is disabled. When disabled, prohibits S0ix states. S0ix states shut off parts of the SoC when they are not in use. S0ix causes latency because of the time it takes for a device to wake from a sleep state. If carefully managed, sleep states can be used in concert with real-time if one ensures that the device will not enter a sleep state during the real-time critical operation.
Checks whether Active State Power Management (ASPM) is disabled. ASPM is an autonomous hardware-based, active state mechanism that enables power savings even when the connected components are in the D0 state. After a period of idle link time, an ASPM Physical-Layer protocol places the idle link into a lower power state. ASPM causes latency because of the delay for a device to wake from a low power state.
Intel® Hyper-Threading Technology
Verifies that Intel® Hyper-Threading Technology (Intel® HT Technology) is disabled or unsupported by the CPU. Hyper-Threading can cause latency as you can only swap threads on instruction boundaries, so a real-time thread can be stalled by a long instruction running on the other logical thread on that core.
Cache Allocation Technology
Checks whether the CPU supports Cache Allocation Technology (CAT). The fundamental goal of Cache Allocation Technology is to enable resource allocation based on application priority or Class of Service (COS). The processor exposes a set of Classes of Service into which applications (or individual threads) can be assigned. Cache allocation for the respective applications or threads is then restricted based on the class with which they are associated. By assigning different classes to real-time and non-real-time applications, cache access interference from non-real-time applications is eliminated. In addition, CAT is foundational for software SRAM functionality.
Cache Allocation Technology capabilities
Checks the CAT capabilities of the CPU
#AC Split Lock
Checks whether Alignment Check is enabled. Split locks are atomic instructions (either explicitly via the LOCK prefix, or implicit, i.e., XCHG) whose operand is split across a cache line boundary. Split locks result in the lock transaction being split across two cache lines forcing a bus lock. The bus lock prevents any other cores or I/O devices from initiating any transactions for the duration of the atomic transaction’s read-modify-write flow. Since the system must complete the in-flight transactions before the bus lock can be acquired, the jitter introduced by a bus lock can be significant (10s of microseconds). The #AC on Split Lock feature prevents the system from taking a bus lock due to a split lock. This enforcement is achieved by hardware throwing the #AC exception whenever a split lock is encountered, resulting in the offending process being terminated.
Due to the presence of split locks in the bootloader (GRUB) included in the board support package (BSP), the BIOS does not include this feature in Intel® TCC Mode, and this checker is always considered RT_READY.

Product and Performance Information


Performance varies by use, configuration and other factors. Learn more at