TOMOYO Linux Cross Reference
Linux/Documentation/trace/timerlat-tracer.rst

   ###############
   Timerlat tracer
   ###############
   
   The timerlat tracer aims to help the preemptive kernel developers to
   find sources of wakeup latencies of real-time threads. Like cyclictest,
   the tracer sets a periodic timer that wakes up a thread. The thread then
   computes a *wakeup latency* value as the difference between the *current
   time* and the *absolute time* that the timer was set to expire. The main
  goal of timerlat is tracing in such a way to help kernel developers.
  
  Usage
  -----
  
  Write the ASCII text "timerlat" into the current_tracer file of the
  tracing system (generally mounted at /sys/kernel/tracing).
  
  For example::
  
          [root@f32 ~]# cd /sys/kernel/tracing/
          [root@f32 tracing]# echo timerlat > current_tracer
  
  It is possible to follow the trace by reading the trace file::
  
    [root@f32 tracing]# cat trace
    # tracer: timerlat
    #
    #                              _-----=> irqs-off
    #                             / _----=> need-resched
    #                            | / _---=> hardirq/softirq
    #                            || / _--=> preempt-depth
    #                            || /
    #                            ||||             ACTIVATION
    #         TASK-PID      CPU# ||||   TIMESTAMP    ID            CONTEXT                LATENCY
    #            | |         |   ||||      |         |                  |                       |
            <idle>-0       [000] d.h1    54.029328: #1     context    irq timer_latency       932 ns
             <...>-867     [000] ....    54.029339: #1     context thread timer_latency     11700 ns
            <idle>-0       [001] dNh1    54.029346: #1     context    irq timer_latency      2833 ns
             <...>-868     [001] ....    54.029353: #1     context thread timer_latency      9820 ns
            <idle>-0       [000] d.h1    54.030328: #2     context    irq timer_latency       769 ns
             <...>-867     [000] ....    54.030330: #2     context thread timer_latency      3070 ns
            <idle>-0       [001] d.h1    54.030344: #2     context    irq timer_latency       935 ns
             <...>-868     [001] ....    54.030347: #2     context thread timer_latency      4351 ns
  
  
  The tracer creates a per-cpu kernel thread with real-time priority that
  prints two lines at every activation. The first is the *timer latency*
  observed at the *hardirq* context before the activation of the thread.
  The second is the *timer latency* observed by the thread. The ACTIVATION
  ID field serves to relate the *irq* execution to its respective *thread*
  execution.
  
  The *irq*/*thread* splitting is important to clarify in which context
  the unexpected high value is coming from. The *irq* context can be
  delayed by hardware-related actions, such as SMIs, NMIs, IRQs,
  or by thread masking interrupts. Once the timer happens, the delay
  can also be influenced by blocking caused by threads. For example, by
  postponing the scheduler execution via preempt_disable(), scheduler
  execution, or masking interrupts. Threads can also be delayed by the
  interference from other threads and IRQs.
  
  Tracer options
  ---------------------
  
  The timerlat tracer is built on top of osnoise tracer.
  So its configuration is also done in the osnoise/ config
  directory. The timerlat configs are:
  
   - cpus: CPUs at which a timerlat thread will execute.
   - timerlat_period_us: the period of the timerlat thread.
   - stop_tracing_us: stop the system tracing if a
     timer latency at the *irq* context higher than the configured
     value happens. Writing 0 disables this option.
   - stop_tracing_total_us: stop the system tracing if a
     timer latency at the *thread* context is higher than the configured
     value happens. Writing 0 disables this option.
   - print_stack: save the stack of the IRQ occurrence. The stack is printed
     after the *thread context* event, or at the IRQ handler if *stop_tracing_us*
     is hit.
  
  timerlat and osnoise
  ----------------------------
  
  The timerlat can also take advantage of the osnoise: traceevents.
  For example::
  
          [root@f32 ~]# cd /sys/kernel/tracing/
          [root@f32 tracing]# echo timerlat > current_tracer
          [root@f32 tracing]# echo 1 > events/osnoise/enable
          [root@f32 tracing]# echo 25 > osnoise/stop_tracing_total_us
          [root@f32 tracing]# tail -10 trace
               cc1-87882   [005] d..h...   548.771078: #402268 context    irq timer_latency     13585 ns
               cc1-87882   [005] dNLh1..   548.771082: irq_noise: local_timer:236 start 548.771077442 duration 7597 ns
               cc1-87882   [005] dNLh2..   548.771099: irq_noise: qxl:21 start 548.771085017 duration 7139 ns
               cc1-87882   [005] d...3..   548.771102: thread_noise:      cc1:87882 start 548.771078243 duration 9909 ns
        timerlat/5-1035    [005] .......   548.771104: #402268 context thread timer_latency     39960 ns
  
  In this case, the root cause of the timer latency does not point to a
  single cause but to multiple ones. Firstly, the timer IRQ was delayed
 for 13 us, which may point to a long IRQ disabled section (see IRQ
 stacktrace section). Then the timer interrupt that wakes up the timerlat
 thread took 7597 ns, and the qxl:21 device IRQ took 7139 ns. Finally,
 the cc1 thread noise took 9909 ns of time before the context switch.
 Such pieces of evidence are useful for the developer to use other
 tracing methods to figure out how to debug and optimize the system.
 
 It is worth mentioning that the *duration* values reported
 by the osnoise: events are *net* values. For example, the
 thread_noise does not include the duration of the overhead caused
 by the IRQ execution (which indeed accounted for 12736 ns). But
 the values reported by the timerlat tracer (timerlat_latency)
 are *gross* values.
 
 The art below illustrates a CPU timeline and how the timerlat tracer
 observes it at the top and the osnoise: events at the bottom. Each "-"
 in the timelines means circa 1 us, and the time moves ==>::
 
       External     timer irq                   thread
        clock        latency                    latency
        event        13585 ns                   39960 ns
          |             ^                         ^
          v             |                         |
          |-------------|                         |
          |-------------+-------------------------|
                        ^                         ^
   ========================================================================
                     [tmr irq]  [dev irq]
   [another thread...^       v..^       v.......][timerlat/ thread]  <-- CPU timeline
   =========================================================================
                     |-------|  |-------|
                             |--^       v-------|
                             |          |       |
                             |          |       + thread_noise: 9909 ns
                             |          +-> irq_noise: 6139 ns
                             +-> irq_noise: 7597 ns
 
 IRQ stacktrace
 ---------------------------
 
 The osnoise/print_stack option is helpful for the cases in which a thread
 noise causes the major factor for the timer latency, because of preempt or
 irq disabled. For example::
 
         [root@f32 tracing]# echo 500 > osnoise/stop_tracing_total_us
         [root@f32 tracing]# echo 500 > osnoise/print_stack
         [root@f32 tracing]# echo timerlat > current_tracer
         [root@f32 tracing]# tail -21 per_cpu/cpu7/trace
           insmod-1026    [007] dN.h1..   200.201948: irq_noise: local_timer:236 start 200.201939376 duration 7872 ns
           insmod-1026    [007] d..h1..   200.202587: #29800 context    irq timer_latency      1616 ns
           insmod-1026    [007] dN.h2..   200.202598: irq_noise: local_timer:236 start 200.202586162 duration 11855 ns
           insmod-1026    [007] dN.h3..   200.202947: irq_noise: local_timer:236 start 200.202939174 duration 7318 ns
           insmod-1026    [007] d...3..   200.203444: thread_noise:   insmod:1026 start 200.202586933 duration 838681 ns
       timerlat/7-1001    [007] .......   200.203445: #29800 context thread timer_latency    859978 ns
       timerlat/7-1001    [007] ....1..   200.203446: <stack trace>
   => timerlat_irq
   => __hrtimer_run_queues
   => hrtimer_interrupt
   => __sysvec_apic_timer_interrupt
   => asm_call_irq_on_stack
   => sysvec_apic_timer_interrupt
   => asm_sysvec_apic_timer_interrupt
   => delay_tsc
   => dummy_load_1ms_pd_init
   => do_one_initcall
   => do_init_module
   => __do_sys_finit_module
   => do_syscall_64
   => entry_SYSCALL_64_after_hwframe
 
 In this case, it is possible to see that the thread added the highest
 contribution to the *timer latency* and the stack trace, saved during
 the timerlat IRQ handler, points to a function named
 dummy_load_1ms_pd_init, which had the following code (on purpose)::
 
         static int __init dummy_load_1ms_pd_init(void)
         {
                 preempt_disable();
                 mdelay(1);
                 preempt_enable();
                 return 0;
 
         }
 
 User-space interface
 ---------------------------
 
 Timerlat allows user-space threads to use timerlat infra-structure to
 measure scheduling latency. This interface is accessible via a per-CPU
 file descriptor inside $tracing_dir/osnoise/per_cpu/cpu$ID/timerlat_fd.
 
 This interface is accessible under the following conditions:
 
  - timerlat tracer is enable
  - osnoise workload option is set to NO_OSNOISE_WORKLOAD
  - The user-space thread is affined to a single processor
  - The thread opens the file associated with its single processor
  - Only one thread can access the file at a time
 
 The open() syscall will fail if any of these conditions are not met.
 After opening the file descriptor, the user space can read from it.
 
 The read() system call will run a timerlat code that will arm the
 timer in the future and wait for it as the regular kernel thread does.
 
 When the timer IRQ fires, the timerlat IRQ will execute, report the
 IRQ latency and wake up the thread waiting in the read. The thread will be
 scheduled and report the thread latency via tracer - as for the kernel
 thread.
 
 The difference from the in-kernel timerlat is that, instead of re-arming
 the timer, timerlat will return to the read() system call. At this point,
 the user can run any code.
 
 If the application rereads the file timerlat file descriptor, the tracer
 will report the return from user-space latency, which is the total
 latency. If this is the end of the work, it can be interpreted as the
 response time for the request.
 
 After reporting the total latency, timerlat will restart the cycle, arm
 a timer, and go to sleep for the following activation.
 
 If at any time one of the conditions is broken, e.g., the thread migrates
 while in user space, or the timerlat tracer is disabled, the SIG_KILL
 signal will be sent to the user-space thread.
 
 Here is an basic example of user-space code for timerlat::
 
  int main(void)
  {
         char buffer[1024];
         int timerlat_fd;
         int retval;
         long cpu = 0;   /* place in CPU 0 */
         cpu_set_t set;
 
         CPU_ZERO(&set);
         CPU_SET(cpu, &set);
 
         if (sched_setaffinity(gettid(), sizeof(set), &set) == -1)
                 return 1;
 
         snprintf(buffer, sizeof(buffer),
                 "/sys/kernel/tracing/osnoise/per_cpu/cpu%ld/timerlat_fd",
                 cpu);
 
         timerlat_fd = open(buffer, O_RDONLY);
         if (timerlat_fd < 0) {
                 printf("error opening %s: %s\n", buffer, strerror(errno));
                 exit(1);
         }
 
         for (;;) {
                 retval = read(timerlat_fd, buffer, 1024);
                 if (retval < 0)
                         break;
         }
 
         close(timerlat_fd);
         exit(0);
  }

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