Subject: [PATCH 0/3] rtla: Timerlat auto-analysis

Currently, timerlat displays the timerlat tracer latency results, saving
the intuitive timerlat trace for the developer to analyze.

This patch goes a step forward in the automaton of the scheduling latency
analysis by providing a summary of the root cause of a latency higher than
the passed "stop tracing" parameter if the trace stops.

The output is intuitive enough for non-expert users to have a general idea
of the root cause by looking at each factor's contribution percentage
while keeping the technical detail in the output for more expert users
to start an in dept debug or to correlate a root cause with an existing one.

The first patch adds the functionality without using it. The second attaches
it to the timerlat top, and the last one updates the man page.

Daniel Bristot de Oliveira (3):
rtla/timerlat: Add auto-analysis core
rtla/timerlat: Add auto-analysis support to timerlat top
Documentation/rtla: Add timerlat-top auto-analysis options

.../tools/rtla/common_timerlat_aa.rst | 7 +
.../tools/rtla/rtla-timerlat-top.rst | 164 ++-
tools/tracing/rtla/src/timerlat_aa.c | 990 ++++++++++++++++++
tools/tracing/rtla/src/timerlat_aa.h | 12 +
tools/tracing/rtla/src/timerlat_top.c | 46 +-
tools/tracing/rtla/src/utils.h | 3 +
6 files changed, 1129 insertions(+), 93 deletions(-)
create mode 100644 Documentation/tools/rtla/common_timerlat_aa.rst
create mode 100644 tools/tracing/rtla/src/timerlat_aa.c
create mode 100644 tools/tracing/rtla/src/timerlat_aa.h

--
2.38.1



Subject: [PATCH 2/3] rtla/timerlat: Add auto-analysis support to timerlat top

Currently, timerlat top displays the timerlat tracer latency results, saving
the intuitive timerlat trace for the developer to analyze.

This patch goes a step forward in the automaton of the scheduling latency
analysis by providing a summary of the root cause of a latency higher than
the passed "stop tracing" parameter if the trace stops.

The output is intuitive enough for non-expert users to have a general idea
of the root cause by looking at each factor's contribution percentage while
keeping the technical detail in the output for more expert users to start
an in dept debug or to correlate a root cause with an existing one.

The terminology is in line with recent industry and academic publications
to facilitate the understanding of both audiences.

Here is one example of tool output:
----------------------------------------- %< -----------------------------------------------------
# taskset -c 0 timerlat -a 40 -c 1-23 -q
Timer Latency
0 00:00:12 | IRQ Timer Latency (us) | Thread Timer Latency (us)
CPU COUNT | cur min avg max | cur min avg max
1 #12322 | 0 0 1 15 | 10 3 9 31
2 #12322 | 3 0 1 12 | 10 3 9 23
3 #12322 | 1 0 1 21 | 8 2 8 34
4 #12322 | 1 0 1 17 | 10 2 11 33
5 #12322 | 0 0 1 12 | 8 3 8 25
6 #12322 | 1 0 1 14 | 16 3 11 35
7 #12322 | 0 0 1 14 | 9 2 8 29
8 #12322 | 1 0 1 22 | 9 3 9 34
9 #12322 | 0 0 1 14 | 8 2 8 24
10 #12322 | 1 0 0 12 | 9 3 8 24
11 #12322 | 0 0 0 15 | 6 2 7 29
12 #12321 | 1 0 0 13 | 5 3 8 23
13 #12319 | 0 0 1 14 | 9 3 9 26
14 #12321 | 1 0 0 13 | 6 2 8 24
15 #12321 | 1 0 1 15 | 12 3 11 27
16 #12318 | 0 0 1 13 | 7 3 10 24
17 #12319 | 0 0 1 13 | 11 3 9 25
18 #12318 | 0 0 0 12 | 8 2 8 20
19 #12319 | 0 0 1 18 | 10 2 9 28
20 #12317 | 0 0 0 20 | 9 3 8 34
21 #12318 | 0 0 0 13 | 8 3 8 28
22 #12319 | 0 0 1 11 | 8 3 10 22
23 #12320 | 28 0 1 28 | 41 3 11 41
rtla timerlat hit stop tracing
## CPU 23 hit stop tracing, analyzing it ##
IRQ handler delay: 27.49 us (65.52 %)
IRQ latency: 28.13 us
Timerlat IRQ duration: 9.59 us (22.85 %)
Blocking thread: 3.79 us (9.03 %)
objtool:49256 3.79 us
Blocking thread stacktrace
-> timerlat_irq
-> __hrtimer_run_queues
-> hrtimer_interrupt
-> __sysvec_apic_timer_interrupt
-> sysvec_apic_timer_interrupt
-> asm_sysvec_apic_timer_interrupt
-> _raw_spin_unlock_irqrestore
-> cgroup_rstat_flush_locked
-> cgroup_rstat_flush_irqsafe
-> mem_cgroup_flush_stats
-> mem_cgroup_wb_stats
-> balance_dirty_pages
-> balance_dirty_pages_ratelimited_flags
-> btrfs_buffered_write
-> btrfs_do_write_iter
-> vfs_write
-> __x64_sys_pwrite64
-> do_syscall_64
-> entry_SYSCALL_64_after_hwframe
------------------------------------------------------------------------
Thread latency: 41.96 us (100%)

The system has exit from idle latency!
Max timerlat IRQ latency from idle: 17.48 us in cpu 4
Saving trace to timerlat_trace.txt
----------------------------------------- >% -----------------------------------------------------

In this case, the major factor was the delay suffered by the IRQ handler
that handles timerlat wakeup: 65.52 %. This can be caused by the
current thread masking interrupts, which can be seen in the blocking
thread stacktrace: the current thread (objtool:49256) disabled interrupts
via raw spin lock operations inside mem cgroup, while doing write
syscall in a btrfs file system.

A simple search for the function name on Google shows that this is
a legit case for disabling the interrupts:

cgroup: Use irqsave in cgroup_rstat_flush_locked()
lore.kernel.org/linux-mm/[email protected]/

The output also prints other reasons for the latency root cause, such as:

- an IRQ that happened before the IRQ handler that caused delays
- The interference from NMI, IRQ, Softirq, and Threads

The details about how these factors affect the scheduling latency
can be found here:

https://bristot.me/demystifying-the-real-time-linux-latency/

Cc: Daniel Bristot de Oliveira <[email protected]>
Cc: Steven Rostedt <[email protected]>
Cc: Jonathan Corbet <[email protected]>
Signed-off-by: Daniel Bristot de Oliveira <[email protected]>
---
tools/tracing/rtla/src/timerlat_top.c | 46 +++++++++++++++++++++++++--
1 file changed, 44 insertions(+), 2 deletions(-)

diff --git a/tools/tracing/rtla/src/timerlat_top.c b/tools/tracing/rtla/src/timerlat_top.c
index 334271935222..eea5b3357e27 100644
--- a/tools/tracing/rtla/src/timerlat_top.c
+++ b/tools/tracing/rtla/src/timerlat_top.c
@@ -10,10 +10,12 @@
#include <unistd.h>
#include <stdio.h>
#include <time.h>
+#include <errno.h>

#include "utils.h"
#include "osnoise.h"
#include "timerlat.h"
+#include "timerlat_aa.h"

struct timerlat_top_params {
char *cpus;
@@ -30,6 +32,8 @@ struct timerlat_top_params {
int quiet;
int set_sched;
int dma_latency;
+ int no_aa;
+ int dump_tasks;
struct sched_attr sched_param;
struct trace_events *events;
};
@@ -130,17 +134,22 @@ timerlat_top_handler(struct trace_seq *s, struct tep_record *record,
struct tep_event *event, void *context)
{
struct trace_instance *trace = context;
+ struct timerlat_top_params *params;
unsigned long long latency, thread;
struct osnoise_tool *top;
int cpu = record->cpu;

top = container_of(trace, struct osnoise_tool, trace);
+ params = top->params;

tep_get_field_val(s, event, "context", record, &thread, 1);
tep_get_field_val(s, event, "timer_latency", record, &latency, 1);

timerlat_top_update(top, cpu, thread, latency);

+ if (!params->no_aa)
+ timerlat_aa_handler(s, record, event, context);
+
return 0;
}

@@ -281,11 +290,13 @@ static void timerlat_top_usage(char *usage)
" -c/--cpus cpus: run the tracer only on the given cpus",
" -d/--duration time[m|h|d]: duration of the session in seconds",
" -D/--debug: print debug info",
+ " --dump-tasks: prints the task running on all CPUs if stop conditions are met (depends on !--no-aa)",
" -t/--trace[=file]: save the stopped trace to [file|timerlat_trace.txt]",
" -e/--event <sys:event>: enable the <sys:event> in the trace instance, multiple -e are allowed",
" --filter <command>: enable a trace event filter to the previous -e event",
" --trigger <command>: enable a trace event trigger to the previous -e event",
" -n/--nano: display data in nanoseconds",
+ " --no-aa: disable auto-analysis, reducing rtla timerlat cpu usage",
" -q/--quiet print only a summary at the end",
" --dma-latency us: set /dev/cpu_dma_latency latency <us> to reduce exit from idle latency",
" -P/--priority o:prio|r:prio|f:prio|d:runtime:period : set scheduling parameters",
@@ -349,13 +360,15 @@ static struct timerlat_top_params
{"trigger", required_argument, 0, '0'},
{"filter", required_argument, 0, '1'},
{"dma-latency", required_argument, 0, '2'},
+ {"no-aa", no_argument, 0, '3'},
+ {"dump-tasks", no_argument, 0, '4'},
{0, 0, 0, 0}
};

/* getopt_long stores the option index here. */
int option_index = 0;

- c = getopt_long(argc, argv, "a:c:d:De:hi:np:P:qs:t::T:0:1:2:",
+ c = getopt_long(argc, argv, "a:c:d:De:hi:np:P:qs:t::T:0:1:2:34",
long_options, &option_index);

/* detect the end of the options. */
@@ -368,13 +381,13 @@ static struct timerlat_top_params

/* set thread stop to auto_thresh */
params->stop_total_us = auto_thresh;
+ params->stop_us = auto_thresh;

/* get stack trace */
params->print_stack = auto_thresh;

/* set trace */
params->trace_output = "timerlat_trace.txt";
-
break;
case 'c':
retval = parse_cpu_list(optarg, &params->monitored_cpus);
@@ -437,6 +450,7 @@ static struct timerlat_top_params
params->trace_output = &optarg[1];
else
params->trace_output = "timerlat_trace.txt";
+
break;
case '0': /* trigger */
if (params->events) {
@@ -467,6 +481,12 @@ static struct timerlat_top_params
exit(EXIT_FAILURE);
}
break;
+ case '3': /* no-aa */
+ params->no_aa = 1;
+ break;
+ case '4':
+ params->dump_tasks = 1;
+ break;
default:
timerlat_top_usage("Invalid option");
}
@@ -477,6 +497,12 @@ static struct timerlat_top_params
exit(EXIT_FAILURE);
}

+ /*
+ * Auto analysis only happens if stop tracing, thus:
+ */
+ if (!params->stop_us && !params->stop_total_us)
+ params->no_aa = 1;
+
return params;
}

@@ -547,6 +573,7 @@ static struct osnoise_tool
{
struct osnoise_tool *top;
int nr_cpus;
+ int retval;

nr_cpus = sysconf(_SC_NPROCESSORS_CONF);

@@ -563,6 +590,16 @@ static struct osnoise_tool
tep_register_event_handler(top->trace.tep, -1, "ftrace", "timerlat",
timerlat_top_handler, top);

+ /*
+ * If no auto analysis, we are ready.
+ */
+ if (params->no_aa)
+ return top;
+
+ retval = timerlat_aa_init(top, nr_cpus, params->dump_tasks);
+ if (retval)
+ goto out_err;
+
return top;

out_err:
@@ -688,6 +725,10 @@ int timerlat_top_main(int argc, char *argv[])

if (trace_is_off(&top->trace, &record->trace)) {
printf("rtla timerlat hit stop tracing\n");
+
+ if (!params->no_aa)
+ timerlat_auto_analysis(params->stop_us, params->stop_total_us);
+
if (params->trace_output) {
printf(" Saving trace to %s\n", params->trace_output);
save_trace_to_file(record->trace.inst, params->trace_output);
@@ -701,6 +742,7 @@ int timerlat_top_main(int argc, char *argv[])
params->events = NULL;
out_free:
timerlat_free_top(top->data);
+ timerlat_aa_destroy();
osnoise_destroy_tool(record);
osnoise_destroy_tool(top);
free(params);
--
2.38.1


Subject: [PATCH 1/3] rtla/timerlat: Add auto-analysis core

Currently, timerlat displays a summary of the timerlat tracer results
saving the trace if the system hits a stop condition.

While this represented a huge step forward, the root cause was not
that is accessible to non-expert users.

The auto-analysis fulfill this gap by parsing the trace timerlat runs,
printing an intuitive auto-analysis.

Cc: Daniel Bristot de Oliveira <[email protected]>
Cc: Steven Rostedt <[email protected]>
Cc: Jonathan Corbet <[email protected]>
Signed-off-by: Daniel Bristot de Oliveira <[email protected]>
---
tools/tracing/rtla/src/timerlat_aa.c | 990 +++++++++++++++++++++++++++
tools/tracing/rtla/src/timerlat_aa.h | 12 +
tools/tracing/rtla/src/utils.h | 3 +
3 files changed, 1005 insertions(+)
create mode 100644 tools/tracing/rtla/src/timerlat_aa.c
create mode 100644 tools/tracing/rtla/src/timerlat_aa.h

diff --git a/tools/tracing/rtla/src/timerlat_aa.c b/tools/tracing/rtla/src/timerlat_aa.c
new file mode 100644
index 000000000000..ec4e0f4b0e6c
--- /dev/null
+++ b/tools/tracing/rtla/src/timerlat_aa.c
@@ -0,0 +1,990 @@
+// SPDX-License-Identifier: GPL-2.0
+/*
+ * Copyright (C) 2023 Red Hat Inc, Daniel Bristot de Oliveira <[email protected]>
+ */
+
+#include <stdlib.h>
+#include <errno.h>
+#include "utils.h"
+#include "osnoise.h"
+#include "timerlat.h"
+
+enum timelat_state {
+ TIMERLAT_INIT = 0,
+ TIMERLAT_WAITING_IRQ,
+ TIMERLAT_WAITING_THREAD,
+};
+
+#define MAX_COMM 24
+
+/*
+ * Per-cpu data statistics and data.
+ */
+struct timerlat_aa_data {
+ /* Current CPU state */
+ int curr_state;
+
+ /* timerlat IRQ latency */
+ unsigned long long tlat_irq_seqnum;
+ unsigned long long tlat_irq_latency;
+ unsigned long long tlat_irq_timstamp;
+
+ /* timerlat Thread latency */
+ unsigned long long tlat_thread_seqnum;
+ unsigned long long tlat_thread_latency;
+ unsigned long long tlat_thread_timstamp;
+
+ /*
+ * Information about the thread running when the IRQ
+ * arrived.
+ *
+ * This can be blocking or interference, depending on the
+ * priority of the thread. Assuming timerlat is the highest
+ * prio, it is blocking. If timerlat has a lower prio, it is
+ * interference.
+ * note: "unsigned long long" because they are fetch using tep_get_field_val();
+ */
+ unsigned long long run_thread_pid;
+ char run_thread_comm[MAX_COMM];
+ unsigned long long thread_blocking_duration;
+ unsigned long long max_exit_idle_latency;
+
+ /* Information about the timerlat timer irq */
+ unsigned long long timer_irq_start_time;
+ unsigned long long timer_irq_start_delay;
+ unsigned long long timer_irq_duration;
+ unsigned long long timer_exit_from_idle;
+
+ /*
+ * Information about the last IRQ before the timerlat irq
+ * arrived.
+ *
+ * If now - timestamp is <= latency, it might have influenced
+ * in the timerlat irq latency. Otherwise, ignore it.
+ */
+ unsigned long long prev_irq_duration;
+ unsigned long long prev_irq_timstamp;
+
+ /*
+ * Interference sum.
+ */
+ unsigned long long thread_nmi_sum;
+ unsigned long long thread_irq_sum;
+ unsigned long long thread_softirq_sum;
+ unsigned long long thread_thread_sum;
+
+ /*
+ * Interference task information.
+ */
+ struct trace_seq *prev_irqs_seq;
+ struct trace_seq *nmi_seq;
+ struct trace_seq *irqs_seq;
+ struct trace_seq *softirqs_seq;
+ struct trace_seq *threads_seq;
+ struct trace_seq *stack_seq;
+
+ /*
+ * Current thread.
+ */
+ char current_comm[MAX_COMM];
+ unsigned long long current_pid;
+
+ /*
+ * Is the system running a kworker?
+ */
+ unsigned long long kworker;
+ unsigned long long kworker_func;
+};
+
+/*
+ * The analysis context and system wide view
+ */
+struct timerlat_aa_context {
+ int nr_cpus;
+ int dump_tasks;
+
+ /* per CPU data */
+ struct timerlat_aa_data *taa_data;
+
+ /*
+ * required to translate function names and register
+ * events.
+ */
+ struct osnoise_tool *tool;
+};
+
+/*
+ * The data is stored as a local variable, but accessed via a helper function.
+ *
+ * It could be stored inside the trace context. But every access would
+ * require container_of() + a series of pointers. Do we need it? Not sure.
+ *
+ * For now keep it simple. If needed, store it in the tool, add the *context
+ * as a parameter in timerlat_aa_get_ctx() and do the magic there.
+ */
+static struct timerlat_aa_context *__timerlat_aa_ctx;
+
+static struct timerlat_aa_context *timerlat_aa_get_ctx(void)
+{
+ return __timerlat_aa_ctx;
+}
+
+/*
+ * timerlat_aa_get_data - Get the per-cpu data from the timerlat context
+ */
+static struct timerlat_aa_data
+*timerlat_aa_get_data(struct timerlat_aa_context *taa_ctx, int cpu)
+{
+ return &taa_ctx->taa_data[cpu];
+}
+
+/*
+ * timerlat_aa_irq_latency - Handles timerlat IRQ event
+ */
+static int timerlat_aa_irq_latency(struct timerlat_aa_data *taa_data,
+ struct trace_seq *s, struct tep_record *record,
+ struct tep_event *event)
+{
+ /*
+ * For interference, we start now looking for things that can delay
+ * the thread.
+ */
+ taa_data->curr_state = TIMERLAT_WAITING_THREAD;
+ taa_data->tlat_irq_timstamp = record->ts;
+
+ /*
+ * Zero values.
+ */
+ taa_data->thread_nmi_sum = 0;
+ taa_data->thread_irq_sum = 0;
+ taa_data->thread_softirq_sum = 0;
+ taa_data->thread_blocking_duration = 0;
+ taa_data->timer_irq_start_time = 0;
+ taa_data->timer_irq_duration = 0;
+ taa_data->timer_exit_from_idle = 0;
+
+ /*
+ * Zero interference tasks.
+ */
+ trace_seq_reset(taa_data->nmi_seq);
+ trace_seq_reset(taa_data->irqs_seq);
+ trace_seq_reset(taa_data->softirqs_seq);
+ trace_seq_reset(taa_data->threads_seq);
+
+ /* IRQ latency values */
+ tep_get_field_val(s, event, "timer_latency", record, &taa_data->tlat_irq_latency, 1);
+ tep_get_field_val(s, event, "seqnum", record, &taa_data->tlat_irq_seqnum, 1);
+
+ /* The thread that can cause blocking */
+ tep_get_common_field_val(s, event, "common_pid", record, &taa_data->run_thread_pid, 1);
+
+ /*
+ * Get exit from idle case.
+ *
+ * If it is not idle thread:
+ */
+ if (taa_data->run_thread_pid)
+ return 0;
+
+ /*
+ * if the latency is shorter than the known exit from idle:
+ */
+ if (taa_data->tlat_irq_latency < taa_data->max_exit_idle_latency)
+ return 0;
+
+ /*
+ * To be safe, ignore the cases in which an IRQ/NMI could have
+ * interfered with the timerlat IRQ.
+ */
+ if (taa_data->tlat_irq_timstamp - taa_data->tlat_irq_latency
+ < taa_data->prev_irq_timstamp + taa_data->prev_irq_duration)
+ return 0;
+
+ taa_data->max_exit_idle_latency = taa_data->tlat_irq_latency;
+
+ return 0;
+}
+
+/*
+ * timerlat_aa_thread_latency - Handles timerlat thread event
+ */
+static int timerlat_aa_thread_latency(struct timerlat_aa_data *taa_data,
+ struct trace_seq *s, struct tep_record *record,
+ struct tep_event *event)
+{
+ /*
+ * For interference, we start now looking for things that can delay
+ * the IRQ of the next cycle.
+ */
+ taa_data->curr_state = TIMERLAT_WAITING_IRQ;
+ taa_data->tlat_thread_timstamp = record->ts;
+
+ /* Thread latency values */
+ tep_get_field_val(s, event, "timer_latency", record, &taa_data->tlat_thread_latency, 1);
+ tep_get_field_val(s, event, "seqnum", record, &taa_data->tlat_thread_seqnum, 1);
+
+ return 0;
+}
+
+/*
+ * timerlat_aa_handler - Handle timerlat events
+ *
+ * This function is called to handle timerlat events recording statistics.
+ *
+ * Returns 0 on success, -1 otherwise.
+ */
+int timerlat_aa_handler(struct trace_seq *s, struct tep_record *record,
+ struct tep_event *event, void *context)
+{
+ struct timerlat_aa_context *taa_ctx = timerlat_aa_get_ctx();
+ struct timerlat_aa_data *taa_data = timerlat_aa_get_data(taa_ctx, record->cpu);
+ unsigned long long thread;
+
+ if (!taa_data)
+ return -1;
+
+ tep_get_field_val(s, event, "context", record, &thread, 1);
+ if (!thread)
+ return timerlat_aa_irq_latency(taa_data, s, record, event);
+ else
+ return timerlat_aa_thread_latency(taa_data, s, record, event);
+}
+
+/*
+ * timerlat_aa_nmi_handler - Handles NMI noise
+ *
+ * It is used to collect information about interferences from NMI. It is
+ * hooked to the osnoise:nmi_noise event.
+ */
+static int timerlat_aa_nmi_handler(struct trace_seq *s, struct tep_record *record,
+ struct tep_event *event, void *context)
+{
+ struct timerlat_aa_context *taa_ctx = timerlat_aa_get_ctx();
+ struct timerlat_aa_data *taa_data = timerlat_aa_get_data(taa_ctx, record->cpu);
+ unsigned long long duration;
+ unsigned long long start;
+
+ tep_get_field_val(s, event, "duration", record, &duration, 1);
+ tep_get_field_val(s, event, "start", record, &start, 1);
+
+ if (taa_data->curr_state == TIMERLAT_WAITING_IRQ) {
+ taa_data->prev_irq_duration = duration;
+ taa_data->prev_irq_timstamp = start;
+
+ trace_seq_reset(taa_data->prev_irqs_seq);
+ trace_seq_printf(taa_data->prev_irqs_seq, "\t%24s \t\t\t%9.2f us\n",
+ "nmi", ns_to_usf(duration));
+ return 0;
+ }
+
+ taa_data->thread_nmi_sum += duration;
+ trace_seq_printf(taa_data->nmi_seq, " %24s \t\t\t%9.2f us\n",
+ "nmi", ns_to_usf(duration));
+
+ return 0;
+}
+
+/*
+ * timerlat_aa_irq_handler - Handles IRQ noise
+ *
+ * It is used to collect information about interferences from IRQ. It is
+ * hooked to the osnoise:irq_noise event.
+ *
+ * It is a little bit more complex than the other because it measures:
+ * - The IRQs that can delay the timer IRQ before it happened.
+ * - The Timerlat IRQ handler
+ * - The IRQs that happened between the timerlat IRQ and the timerlat thread
+ * (IRQ interference).
+ */
+static int timerlat_aa_irq_handler(struct trace_seq *s, struct tep_record *record,
+ struct tep_event *event, void *context)
+{
+ struct timerlat_aa_context *taa_ctx = timerlat_aa_get_ctx();
+ struct timerlat_aa_data *taa_data = timerlat_aa_get_data(taa_ctx, record->cpu);
+ unsigned long long expected_start;
+ unsigned long long duration;
+ unsigned long long vector;
+ unsigned long long start;
+ char *desc;
+ int val;
+
+ tep_get_field_val(s, event, "duration", record, &duration, 1);
+ tep_get_field_val(s, event, "start", record, &start, 1);
+ tep_get_field_val(s, event, "vector", record, &vector, 1);
+ desc = tep_get_field_raw(s, event, "desc", record, &val, 1);
+
+ /*
+ * Before the timerlat IRQ.
+ */
+ if (taa_data->curr_state == TIMERLAT_WAITING_IRQ) {
+ taa_data->prev_irq_duration = duration;
+ taa_data->prev_irq_timstamp = start;
+
+ trace_seq_reset(taa_data->prev_irqs_seq);
+ trace_seq_printf(taa_data->prev_irqs_seq, "\t%24s:%-3llu \t\t%9.2f us\n",
+ desc, vector, ns_to_usf(duration));
+ return 0;
+ }
+
+ /*
+ * The timerlat IRQ: taa_data->timer_irq_start_time is zeroed at
+ * the timerlat irq handler.
+ */
+ if (!taa_data->timer_irq_start_time) {
+ expected_start = taa_data->tlat_irq_timstamp - taa_data->tlat_irq_latency;
+
+ taa_data->timer_irq_start_time = start;
+ taa_data->timer_irq_duration = duration;
+
+ taa_data->timer_irq_start_delay = taa_data->timer_irq_start_time - expected_start;
+
+ /*
+ * not exit from idle.
+ */
+ if (taa_data->run_thread_pid)
+ return 0;
+
+ if (expected_start > taa_data->prev_irq_timstamp + taa_data->prev_irq_duration)
+ taa_data->timer_exit_from_idle = taa_data->timer_irq_start_delay;
+
+ return 0;
+ }
+
+ /*
+ * IRQ interference.
+ */
+ taa_data->thread_irq_sum += duration;
+ trace_seq_printf(taa_data->irqs_seq, " %24s:%-3llu \t %9.2f us\n",
+ desc, vector, ns_to_usf(duration));
+
+ return 0;
+}
+
+static char *softirq_name[] = { "HI", "TIMER", "NET_TX", "NET_RX", "BLOCK",
+ "IRQ_POLL", "TASKLET", "SCHED", "HRTIMER", "RCU" };
+
+
+/*
+ * timerlat_aa_softirq_handler - Handles Softirq noise
+ *
+ * It is used to collect information about interferences from Softirq. It is
+ * hooked to the osnoise:softirq_noise event.
+ *
+ * It is only printed in the non-rt kernel, as softirqs become thread on RT.
+ */
+static int timerlat_aa_softirq_handler(struct trace_seq *s, struct tep_record *record,
+ struct tep_event *event, void *context)
+{
+ struct timerlat_aa_context *taa_ctx = timerlat_aa_get_ctx();
+ struct timerlat_aa_data *taa_data = timerlat_aa_get_data(taa_ctx, record->cpu);
+ unsigned long long duration;
+ unsigned long long vector;
+ unsigned long long start;
+
+ if (taa_data->curr_state == TIMERLAT_WAITING_IRQ)
+ return 0;
+
+ tep_get_field_val(s, event, "duration", record, &duration, 1);
+ tep_get_field_val(s, event, "start", record, &start, 1);
+ tep_get_field_val(s, event, "vector", record, &vector, 1);
+
+ taa_data->thread_softirq_sum += duration;
+
+ trace_seq_printf(taa_data->softirqs_seq, "\t%24s:%-3llu \t %9.2f us\n",
+ softirq_name[vector], vector, ns_to_usf(duration));
+ return 0;
+}
+
+/*
+ * timerlat_aa_softirq_handler - Handles thread noise
+ *
+ * It is used to collect information about interferences from threads. It is
+ * hooked to the osnoise:thread_noise event.
+ *
+ * Note: if you see thread noise, your timerlat thread was not the highest prio one.
+ */
+static int timerlat_aa_thread_handler(struct trace_seq *s, struct tep_record *record,
+ struct tep_event *event, void *context)
+{
+ struct timerlat_aa_context *taa_ctx = timerlat_aa_get_ctx();
+ struct timerlat_aa_data *taa_data = timerlat_aa_get_data(taa_ctx, record->cpu);
+ unsigned long long duration;
+ unsigned long long start;
+ unsigned long long pid;
+ const char *comm;
+ int val;
+
+ if (taa_data->curr_state == TIMERLAT_WAITING_IRQ)
+ return 0;
+
+ tep_get_field_val(s, event, "duration", record, &duration, 1);
+ tep_get_field_val(s, event, "start", record, &start, 1);
+
+ tep_get_common_field_val(s, event, "common_pid", record, &pid, 1);
+ comm = tep_get_field_raw(s, event, "comm", record, &val, 1);
+
+ if (pid == taa_data->run_thread_pid && !taa_data->thread_blocking_duration) {
+ taa_data->thread_blocking_duration = duration;
+
+ if (comm)
+ strncpy(taa_data->run_thread_comm, comm, MAX_COMM);
+ else
+ sprintf(taa_data->run_thread_comm, "<...>");
+
+ } else {
+ taa_data->thread_thread_sum += duration;
+
+ trace_seq_printf(taa_data->threads_seq, "\t%24s:%-3llu \t\t%9.2f us\n",
+ comm, pid, ns_to_usf(duration));
+ }
+
+ return 0;
+}
+
+/*
+ * timerlat_aa_stack_handler - Handles timerlat IRQ stack trace
+ *
+ * Saves and parse the stack trace generated by the timerlat IRQ.
+ */
+static int timerlat_aa_stack_handler(struct trace_seq *s, struct tep_record *record,
+ struct tep_event *event, void *context)
+{
+ struct timerlat_aa_context *taa_ctx = timerlat_aa_get_ctx();
+ struct timerlat_aa_data *taa_data = timerlat_aa_get_data(taa_ctx, record->cpu);
+ unsigned long *caller;
+ const char *function;
+ int val, i;
+
+ trace_seq_reset(taa_data->stack_seq);
+
+ trace_seq_printf(taa_data->stack_seq, " Blocking thread stack trace\n");
+ caller = tep_get_field_raw(s, event, "caller", record, &val, 1);
+ if (caller) {
+ for (i = 0; ; i++) {
+ function = tep_find_function(taa_ctx->tool->trace.tep, caller[i]);
+ if (!function)
+ break;
+ trace_seq_printf(taa_data->stack_seq, "\t\t-> %s\n", function);
+ }
+ }
+ return 0;
+}
+
+/*
+ * timerlat_aa_sched_switch_handler - Tracks the current thread running on the CPU
+ *
+ * Handles the sched:sched_switch event to trace the current thread running on the
+ * CPU. It is used to display the threads running on the other CPUs when the trace
+ * stops.
+ */
+static int timerlat_aa_sched_switch_handler(struct trace_seq *s, struct tep_record *record,
+ struct tep_event *event, void *context)
+{
+ struct timerlat_aa_context *taa_ctx = timerlat_aa_get_ctx();
+ struct timerlat_aa_data *taa_data = timerlat_aa_get_data(taa_ctx, record->cpu);
+ const char *comm;
+ int val;
+
+ tep_get_field_val(s, event, "next_pid", record, &taa_data->current_pid, 1);
+ comm = tep_get_field_raw(s, event, "next_comm", record, &val, 1);
+
+ strncpy(taa_data->current_comm, comm, MAX_COMM);
+
+ /*
+ * If this was a kworker, clean the last kworkers that ran.
+ */
+ taa_data->kworker = 0;
+ taa_data->kworker_func = 0;
+
+ return 0;
+}
+
+/*
+ * timerlat_aa_kworker_start_handler - Tracks a kworker running on the CPU
+ *
+ * Handles workqueue:workqueue_execute_start event, keeping track of
+ * the job that a kworker could be doing in the CPU.
+ *
+ * We already catch problems of hardware related latencies caused by work queues
+ * running driver code that causes hardware stall. For example, with DRM drivers.
+ */
+static int timerlat_aa_kworker_start_handler(struct trace_seq *s, struct tep_record *record,
+ struct tep_event *event, void *context)
+{
+ struct timerlat_aa_context *taa_ctx = timerlat_aa_get_ctx();
+ struct timerlat_aa_data *taa_data = timerlat_aa_get_data(taa_ctx, record->cpu);
+
+ tep_get_field_val(s, event, "work", record, &taa_data->kworker, 1);
+ tep_get_field_val(s, event, "function", record, &taa_data->kworker_func, 1);
+ return 0;
+}
+
+/*
+ * timerlat_thread_analysis - Prints the analysis of a CPU that hit a stop tracing
+ *
+ * This is the core of the analysis.
+ */
+static void timerlat_thread_analysis(struct timerlat_aa_data *taa_data, int cpu,
+ int irq_thresh, int thread_thresh)
+{
+ unsigned long long exp_irq_ts;
+ int total;
+ int irq;
+
+ /*
+ * IRQ latency or Thread latency?
+ */
+ if (taa_data->tlat_irq_seqnum > taa_data->tlat_thread_seqnum) {
+ irq = 1;
+ total = taa_data->tlat_irq_latency;
+ } else {
+ irq = 0;
+ total = taa_data->tlat_thread_latency;
+ }
+
+ /*
+ * Expected IRQ arrival time using the trace clock as the base.
+ */
+ exp_irq_ts = taa_data->timer_irq_start_time - taa_data->timer_irq_start_delay;
+
+ if (exp_irq_ts < taa_data->prev_irq_timstamp + taa_data->prev_irq_duration)
+ printf(" Previous IRQ interference: \t up to %9.2f us",
+ ns_to_usf(taa_data->prev_irq_duration));
+
+ /*
+ * The delay that the IRQ suffered before starting.
+ */
+ printf(" IRQ handler delay: %16s %9.2f us (%.2f %%)\n",
+ (ns_to_usf(taa_data->timer_exit_from_idle) > 10) ? "(exit from idle)" : "",
+ ns_to_usf(taa_data->timer_irq_start_delay),
+ ns_to_per(total, taa_data->timer_irq_start_delay));
+
+ /*
+ * Timerlat IRQ.
+ */
+ printf(" IRQ latency: \t\t\t\t %9.2f us\n",
+ ns_to_usf(taa_data->tlat_irq_latency));
+
+ if (irq) {
+ /*
+ * If the trace stopped due to IRQ, the other events will not happen
+ * because... the trace stopped :-).
+ *
+ * That is all folks, the stack trace was printed before the stop,
+ * so it will be displayed, it is the key.
+ */
+ printf(" Blocking thread:\n");
+ printf(" %24s:%-9llu\n",
+ taa_data->run_thread_comm, taa_data->run_thread_pid);
+ } else {
+ /*
+ * The duration of the IRQ handler that handled the timerlat IRQ.
+ */
+ printf(" Timerlat IRQ duration: \t\t %9.2f us (%.2f %%)\n",
+ ns_to_usf(taa_data->timer_irq_duration),
+ ns_to_per(total, taa_data->timer_irq_duration));
+
+ /*
+ * The amount of time that the current thread postponed the scheduler.
+ *
+ * Recalling that it is net from NMI/IRQ/Softirq interference, so there
+ * is no need to compute values here.
+ */
+ printf(" Blocking thread: \t\t\t %9.2f us (%.2f %%)\n",
+ ns_to_usf(taa_data->thread_blocking_duration),
+ ns_to_per(total, taa_data->thread_blocking_duration));
+
+ printf(" %24s:%-9llu %9.2f us\n",
+ taa_data->run_thread_comm, taa_data->run_thread_pid,
+ ns_to_usf(taa_data->thread_blocking_duration));
+ }
+
+ /*
+ * Print the stack trace!
+ */
+ trace_seq_do_printf(taa_data->stack_seq);
+
+ /*
+ * NMIs can happen during the IRQ, so they are always possible.
+ */
+ if (taa_data->thread_nmi_sum)
+ printf(" NMI interference \t\t\t %9.2f us (%.2f %%)\n",
+ ns_to_usf(taa_data->thread_nmi_sum),
+ ns_to_per(total, taa_data->thread_nmi_sum));
+
+ /*
+ * If it is an IRQ latency, the other factors can be skipped.
+ */
+ if (irq)
+ goto print_total;
+
+ /*
+ * Prints the interference caused by IRQs to the thread latency.
+ */
+ if (taa_data->thread_irq_sum) {
+ printf(" IRQ interference \t\t\t %9.2f us (%.2f %%)\n",
+ ns_to_usf(taa_data->thread_irq_sum),
+ ns_to_per(total, taa_data->thread_irq_sum));
+
+ trace_seq_do_printf(taa_data->irqs_seq);
+ }
+
+ /*
+ * Prints the interference caused by Softirqs to the thread latency.
+ */
+ if (taa_data->thread_softirq_sum) {
+ printf(" Softirq interference \t\t\t %9.2f us (%.2f %%)\n",
+ ns_to_usf(taa_data->thread_softirq_sum),
+ ns_to_per(total, taa_data->thread_softirq_sum));
+
+ trace_seq_do_printf(taa_data->softirqs_seq);
+ }
+
+ /*
+ * Prints the interference caused by other threads to the thread latency.
+ *
+ * If this happens, your timerlat is not the highest prio. OK, migration
+ * thread can happen. But otherwise, you are not measuring the "scheduling
+ * latency" only, and here is the difference from scheduling latency and
+ * timer handling latency.
+ */
+ if (taa_data->thread_thread_sum) {
+ printf(" Thread interference \t\t\t %9.2f us (%.2f %%)\n",
+ ns_to_usf(taa_data->thread_thread_sum),
+ ns_to_per(total, taa_data->thread_thread_sum));
+
+ trace_seq_do_printf(taa_data->threads_seq);
+ }
+
+ /*
+ * Done.
+ */
+print_total:
+ printf("------------------------------------------------------------------------\n");
+ printf(" %s latency: \t\t\t %9.2f us (100%%)\n", irq ? "IRQ" : "Thread",
+ ns_to_usf(total));
+}
+
+/**
+ * timerlat_auto_analysis - Analyze the collected data
+ */
+void timerlat_auto_analysis(int irq_thresh, int thread_thresh)
+{
+ struct timerlat_aa_context *taa_ctx = timerlat_aa_get_ctx();
+ unsigned long long max_exit_from_idle = 0;
+ struct timerlat_aa_data *taa_data;
+ int max_exit_from_idle_cpu;
+ struct tep_handle *tep;
+ int cpu;
+
+ /* bring stop tracing to the ns scale */
+ irq_thresh = irq_thresh * 1000;
+ thread_thresh = thread_thresh * 1000;
+
+ for (cpu = 0; cpu < taa_ctx->nr_cpus; cpu++) {
+ taa_data = timerlat_aa_get_data(taa_ctx, cpu);
+
+ if (irq_thresh && taa_data->tlat_irq_latency >= irq_thresh) {
+ printf("## CPU %d hit stop tracing, analyzing it ##\n", cpu);
+ timerlat_thread_analysis(taa_data, cpu, irq_thresh, thread_thresh);
+ } else if (thread_thresh && (taa_data->tlat_thread_latency) >= thread_thresh) {
+ printf("## CPU %d hit stop tracing, analyzing it ##\n", cpu);
+ timerlat_thread_analysis(taa_data, cpu, irq_thresh, thread_thresh);
+ }
+
+ if (taa_data->max_exit_idle_latency > max_exit_from_idle) {
+ max_exit_from_idle = taa_data->max_exit_idle_latency;
+ max_exit_from_idle_cpu = cpu;
+ }
+
+ }
+
+ if (max_exit_from_idle) {
+ printf("\n");
+ printf("Max timerlat IRQ latency from idle: %.2f us in cpu %d\n",
+ ns_to_usf(max_exit_from_idle), max_exit_from_idle_cpu);
+ }
+ if (!taa_ctx->dump_tasks)
+ return;
+
+ printf("\n");
+ printf("Printing CPU tasks:\n");
+ for (cpu = 0; cpu < taa_ctx->nr_cpus; cpu++) {
+ taa_data = timerlat_aa_get_data(taa_ctx, cpu);
+ tep = taa_ctx->tool->trace.tep;
+
+ printf(" [%.3d] %24s:%llu", cpu, taa_data->current_comm, taa_data->current_pid);
+
+ if (taa_data->kworker_func)
+ printf(" kworker:%s:%s",
+ tep_find_function(tep, taa_data->kworker) ? : "<...>",
+ tep_find_function(tep, taa_data->kworker_func));
+ printf("\n");
+ }
+
+}
+
+/*
+ * timerlat_aa_destroy_seqs - Destroy seq files used to store parsed data
+ */
+static void timerlat_aa_destroy_seqs(struct timerlat_aa_context *taa_ctx)
+{
+ struct timerlat_aa_data *taa_data;
+ int i;
+
+ if (!taa_ctx->taa_data)
+ return;
+
+ for (i = 0; i < taa_ctx->nr_cpus; i++) {
+ taa_data = timerlat_aa_get_data(taa_ctx, i);
+
+ if (taa_data->prev_irqs_seq) {
+ trace_seq_destroy(taa_data->prev_irqs_seq);
+ free(taa_data->prev_irqs_seq);
+ }
+
+ if (taa_data->nmi_seq) {
+ trace_seq_destroy(taa_data->nmi_seq);
+ free(taa_data->nmi_seq);
+ }
+
+ if (taa_data->irqs_seq) {
+ trace_seq_destroy(taa_data->irqs_seq);
+ free(taa_data->irqs_seq);
+ }
+
+ if (taa_data->softirqs_seq) {
+ trace_seq_destroy(taa_data->softirqs_seq);
+ free(taa_data->softirqs_seq);
+ }
+
+ if (taa_data->threads_seq) {
+ trace_seq_destroy(taa_data->threads_seq);
+ free(taa_data->threads_seq);
+ }
+
+ if (taa_data->stack_seq) {
+ trace_seq_destroy(taa_data->stack_seq);
+ free(taa_data->stack_seq);
+ }
+ }
+}
+
+/*
+ * timerlat_aa_init_seqs - Init seq files used to store parsed information
+ *
+ * Instead of keeping data structures to store raw data, use seq files to
+ * store parsed data.
+ *
+ * Allocates and initialize seq files.
+ *
+ * Returns 0 on success, -1 otherwise.
+ */
+static int timerlat_aa_init_seqs(struct timerlat_aa_context *taa_ctx)
+{
+ struct timerlat_aa_data *taa_data;
+ int i;
+
+ for (i = 0; i < taa_ctx->nr_cpus; i++) {
+
+ taa_data = timerlat_aa_get_data(taa_ctx, i);
+
+ taa_data->prev_irqs_seq = calloc(1, sizeof(*taa_data->prev_irqs_seq));
+ if (!taa_data->prev_irqs_seq)
+ goto out_err;
+
+ trace_seq_init(taa_data->prev_irqs_seq);
+
+ taa_data->nmi_seq = calloc(1, sizeof(*taa_data->nmi_seq));
+ if (!taa_data->nmi_seq)
+ goto out_err;
+
+ trace_seq_init(taa_data->nmi_seq);
+
+ taa_data->irqs_seq = calloc(1, sizeof(*taa_data->irqs_seq));
+ if (!taa_data->irqs_seq)
+ goto out_err;
+
+ trace_seq_init(taa_data->irqs_seq);
+
+ taa_data->softirqs_seq = calloc(1, sizeof(*taa_data->softirqs_seq));
+ if (!taa_data->softirqs_seq)
+ goto out_err;
+
+ trace_seq_init(taa_data->softirqs_seq);
+
+ taa_data->threads_seq = calloc(1, sizeof(*taa_data->threads_seq));
+ if (!taa_data->threads_seq)
+ goto out_err;
+
+ trace_seq_init(taa_data->threads_seq);
+
+ taa_data->stack_seq = calloc(1, sizeof(*taa_data->stack_seq));
+ if (!taa_data->stack_seq)
+ goto out_err;
+
+ trace_seq_init(taa_data->stack_seq);
+ }
+
+ return 0;
+
+out_err:
+ timerlat_aa_destroy_seqs(taa_ctx);
+ return -1;
+}
+
+/*
+ * timerlat_aa_unregister_events - Unregister events used in the auto-analysis
+ */
+static void timerlat_aa_unregister_events(struct osnoise_tool *tool, int dump_tasks)
+{
+ tracefs_event_disable(tool->trace.inst, "osnoise", NULL);
+
+ tep_unregister_event_handler(tool->trace.tep, -1, "osnoise", "nmi_noise",
+ timerlat_aa_nmi_handler, tool);
+
+ tep_unregister_event_handler(tool->trace.tep, -1, "osnoise", "irq_noise",
+ timerlat_aa_irq_handler, tool);
+
+ tep_unregister_event_handler(tool->trace.tep, -1, "osnoise", "softirq_noise",
+ timerlat_aa_softirq_handler, tool);
+
+ tep_unregister_event_handler(tool->trace.tep, -1, "osnoise", "thread_noise",
+ timerlat_aa_thread_handler, tool);
+
+ tep_unregister_event_handler(tool->trace.tep, -1, "ftrace", "kernel_stack",
+ timerlat_aa_stack_handler, tool);
+ if (!dump_tasks)
+ return;
+
+ tracefs_event_disable(tool->trace.inst, "sched", "sched_switch");
+ tep_unregister_event_handler(tool->trace.tep, -1, "sched", "sched_switch",
+ timerlat_aa_sched_switch_handler, tool);
+
+ tracefs_event_disable(tool->trace.inst, "workqueue", "workqueue_execute_start");
+ tep_unregister_event_handler(tool->trace.tep, -1, "workqueue", "workqueue_execute_start",
+ timerlat_aa_kworker_start_handler, tool);
+}
+
+/*
+ * timerlat_aa_register_events - Register events used in the auto-analysis
+ *
+ * Returns 0 on success, -1 otherwise.
+ */
+static int timerlat_aa_register_events(struct osnoise_tool *tool, int dump_tasks)
+{
+ int retval;
+
+ /*
+ * register auto-analysis handlers.
+ */
+ retval = tracefs_event_enable(tool->trace.inst, "osnoise", NULL);
+ if (retval < 0 && !errno) {
+ err_msg("Could not find osnoise events\n");
+ goto out_err;
+ }
+
+ tep_register_event_handler(tool->trace.tep, -1, "osnoise", "nmi_noise",
+ timerlat_aa_nmi_handler, tool);
+
+ tep_register_event_handler(tool->trace.tep, -1, "osnoise", "irq_noise",
+ timerlat_aa_irq_handler, tool);
+
+ tep_register_event_handler(tool->trace.tep, -1, "osnoise", "softirq_noise",
+ timerlat_aa_softirq_handler, tool);
+
+ tep_register_event_handler(tool->trace.tep, -1, "osnoise", "thread_noise",
+ timerlat_aa_thread_handler, tool);
+
+ tep_register_event_handler(tool->trace.tep, -1, "ftrace", "kernel_stack",
+ timerlat_aa_stack_handler, tool);
+
+ if (!dump_tasks)
+ return 0;
+
+ /*
+ * Dump task events.
+ */
+ retval = tracefs_event_enable(tool->trace.inst, "sched", "sched_switch");
+ if (retval < 0 && !errno) {
+ err_msg("Could not find sched_switch\n");
+ goto out_err;
+ }
+
+ tep_register_event_handler(tool->trace.tep, -1, "sched", "sched_switch",
+ timerlat_aa_sched_switch_handler, tool);
+
+ retval = tracefs_event_enable(tool->trace.inst, "workqueue", "workqueue_execute_start");
+ if (retval < 0 && !errno) {
+ err_msg("Could not find workqueue_execute_start\n");
+ goto out_err;
+ }
+
+ tep_register_event_handler(tool->trace.tep, -1, "workqueue", "workqueue_execute_start",
+ timerlat_aa_kworker_start_handler, tool);
+
+ return 0;
+
+out_err:
+ timerlat_aa_unregister_events(tool, dump_tasks);
+ return -1;
+}
+
+/**
+ * timerlat_aa_destroy - Destroy timerlat auto-analysis
+ */
+void timerlat_aa_destroy(void)
+{
+ struct timerlat_aa_context *taa_ctx = timerlat_aa_get_ctx();
+
+ if (!taa_ctx)
+ return;
+
+ if (!taa_ctx->taa_data)
+ goto out_ctx;
+
+ timerlat_aa_unregister_events(taa_ctx->tool, taa_ctx->dump_tasks);
+ timerlat_aa_destroy_seqs(taa_ctx);
+ free(taa_ctx->taa_data);
+out_ctx:
+ free(taa_ctx);
+}
+
+/**
+ * timerlat_aa_init - Initialize timerlat auto-analysis
+ *
+ * Returns 0 on success, -1 otherwise.
+ */
+int timerlat_aa_init(struct osnoise_tool *tool, int nr_cpus, int dump_tasks)
+{
+ struct timerlat_aa_context *taa_ctx;
+ int retval;
+
+ taa_ctx = calloc(1, sizeof(*taa_ctx));
+ if (!taa_ctx)
+ return -1;
+
+ __timerlat_aa_ctx = taa_ctx;
+
+ taa_ctx->nr_cpus = nr_cpus;
+ taa_ctx->tool = tool;
+ taa_ctx->dump_tasks = dump_tasks;
+
+ taa_ctx->taa_data = calloc(nr_cpus, sizeof(*taa_ctx->taa_data));
+ if (!taa_ctx->taa_data)
+ goto out_err;
+
+ retval = timerlat_aa_init_seqs(taa_ctx);
+ if (retval)
+ goto out_err;
+
+ retval = timerlat_aa_register_events(tool, dump_tasks);
+ if (retval)
+ goto out_err;
+
+ return 0;
+
+out_err:
+ timerlat_aa_destroy();
+ return -1;
+}
diff --git a/tools/tracing/rtla/src/timerlat_aa.h b/tools/tracing/rtla/src/timerlat_aa.h
new file mode 100644
index 000000000000..d4f6ca7e342a
--- /dev/null
+++ b/tools/tracing/rtla/src/timerlat_aa.h
@@ -0,0 +1,12 @@
+// SPDX-License-Identifier: GPL-2.0
+/*
+ * Copyright (C) 2023 Red Hat Inc, Daniel Bristot de Oliveira <[email protected]>
+ */
+
+int timerlat_aa_init(struct osnoise_tool *tool, int nr_cpus, int dump_task);
+void timerlat_aa_destroy(void);
+
+int timerlat_aa_handler(struct trace_seq *s, struct tep_record *record,
+ struct tep_event *event, void *context);
+
+void timerlat_auto_analysis(int irq_thresh, int thread_thresh);
diff --git a/tools/tracing/rtla/src/utils.h b/tools/tracing/rtla/src/utils.h
index 5571afd3b549..90e4f52a030b 100644
--- a/tools/tracing/rtla/src/utils.h
+++ b/tools/tracing/rtla/src/utils.h
@@ -56,3 +56,6 @@ struct sched_attr {
int parse_prio(char *arg, struct sched_attr *sched_param);
int set_comm_sched_attr(const char *comm_prefix, struct sched_attr *attr);
int set_cpu_dma_latency(int32_t latency);
+
+#define ns_to_usf(x) (((double)x/1000))
+#define ns_to_per(total, part) ((part * 100) / (double)total)
--
2.38.1


Subject: [PATCH 3/3] Documentation/rtla: Add timerlat-top auto-analysis options

Add the new options to the man page, as well as updating the
example to include the new output.

Cc: Daniel Bristot de Oliveira <[email protected]>
Cc: Steven Rostedt <[email protected]>
Cc: Jonathan Corbet <[email protected]>
Signed-off-by: Daniel Bristot de Oliveira <[email protected]>
---
.../tools/rtla/common_timerlat_aa.rst | 7 +
.../tools/rtla/rtla-timerlat-top.rst | 164 ++++++++----------
2 files changed, 80 insertions(+), 91 deletions(-)
create mode 100644 Documentation/tools/rtla/common_timerlat_aa.rst

diff --git a/Documentation/tools/rtla/common_timerlat_aa.rst b/Documentation/tools/rtla/common_timerlat_aa.rst
new file mode 100644
index 000000000000..077029e6b289
--- /dev/null
+++ b/Documentation/tools/rtla/common_timerlat_aa.rst
@@ -0,0 +1,7 @@
+**--dump-tasks**
+
+ prints the task running on all CPUs if stop conditions are met (depends on !--no-aa)
+
+**--no-aa**
+
+ disable auto-analysis, reducing rtla timerlat cpu usage
diff --git a/Documentation/tools/rtla/rtla-timerlat-top.rst b/Documentation/tools/rtla/rtla-timerlat-top.rst
index 7c4e4b109493..73799c1150ad 100644
--- a/Documentation/tools/rtla/rtla-timerlat-top.rst
+++ b/Documentation/tools/rtla/rtla-timerlat-top.rst
@@ -30,102 +30,84 @@ OPTIONS

.. include:: common_options.rst

+.. include:: common_timerlat_aa.rst
+
EXAMPLE
=======

-In the example below, the *timerlat* tracer is set to capture the stack trace at
-the IRQ handler, printing it to the buffer if the *Thread* timer latency is
-higher than *30 us*. It is also set to stop the session if a *Thread* timer
-latency higher than *30 us* is hit. Finally, it is set to save the trace
-buffer if the stop condition is hit::
+In the example below, the timerlat tracer is dispatched in cpus *1-23* in the
+automatic trace mode, instructing the tracer to stop if a *40 us* latency or
+higher is found::

- [root@alien ~]# rtla timerlat top -s 30 -T 30 -t
- Timer Latency
- 0 00:00:59 | IRQ Timer Latency (us) | Thread Timer Latency (us)
+ # timerlat -a 40 -c 1-23 -q
+ Timer Latency
+ 0 00:00:12 | IRQ Timer Latency (us) | Thread Timer Latency (us)
CPU COUNT | cur min avg max | cur min avg max
- 0 #58634 | 1 0 1 10 | 11 2 10 23
- 1 #58634 | 1 0 1 9 | 12 2 9 23
- 2 #58634 | 0 0 1 11 | 10 2 9 23
- 3 #58634 | 1 0 1 11 | 11 2 9 24
- 4 #58634 | 1 0 1 10 | 11 2 9 26
- 5 #58634 | 1 0 1 8 | 10 2 9 25
- 6 #58634 | 12 0 1 12 | 30 2 10 30 <--- CPU with spike
- 7 #58634 | 1 0 1 9 | 11 2 9 23
- 8 #58633 | 1 0 1 9 | 11 2 9 26
- 9 #58633 | 1 0 1 9 | 10 2 9 26
- 10 #58633 | 1 0 1 13 | 11 2 9 28
- 11 #58633 | 1 0 1 13 | 12 2 9 24
- 12 #58633 | 1 0 1 8 | 10 2 9 23
- 13 #58633 | 1 0 1 10 | 10 2 9 22
- 14 #58633 | 1 0 1 18 | 12 2 9 27
- 15 #58633 | 1 0 1 10 | 11 2 9 28
- 16 #58633 | 0 0 1 11 | 7 2 9 26
- 17 #58633 | 1 0 1 13 | 10 2 9 24
- 18 #58633 | 1 0 1 9 | 13 2 9 22
- 19 #58633 | 1 0 1 10 | 11 2 9 23
- 20 #58633 | 1 0 1 12 | 11 2 9 28
- 21 #58633 | 1 0 1 14 | 11 2 9 24
- 22 #58633 | 1 0 1 8 | 11 2 9 22
- 23 #58633 | 1 0 1 10 | 11 2 9 27
- timerlat hit stop tracing
- saving trace to timerlat_trace.txt
- [root@alien bristot]# tail -60 timerlat_trace.txt
- [...]
- timerlat/5-79755 [005] ....... 426.271226: #58634 context thread timer_latency 10823 ns
- sh-109404 [006] dnLh213 426.271247: #58634 context irq timer_latency 12505 ns
- sh-109404 [006] dNLh313 426.271258: irq_noise: local_timer:236 start 426.271245463 duration 12553 ns
- sh-109404 [006] d...313 426.271263: thread_noise: sh:109404 start 426.271245853 duration 4769 ns
- timerlat/6-79756 [006] ....... 426.271264: #58634 context thread timer_latency 30328 ns
- timerlat/6-79756 [006] ....1.. 426.271265: <stack trace>
- => timerlat_irq
- => __hrtimer_run_queues
- => hrtimer_interrupt
- => __sysvec_apic_timer_interrupt
- => sysvec_apic_timer_interrupt
- => asm_sysvec_apic_timer_interrupt
- => _raw_spin_unlock_irqrestore <---- spinlock that disabled interrupt.
- => try_to_wake_up
- => autoremove_wake_function
- => __wake_up_common
- => __wake_up_common_lock
- => ep_poll_callback
- => __wake_up_common
- => __wake_up_common_lock
- => fsnotify_add_event
- => inotify_handle_inode_event
- => fsnotify
- => __fsnotify_parent
- => __fput
- => task_work_run
- => exit_to_user_mode_prepare
- => syscall_exit_to_user_mode
- => do_syscall_64
- => entry_SYSCALL_64_after_hwframe
- => 0x7265000001378c
- => 0x10000cea7
- => 0x25a00000204a
- => 0x12e302d00000000
- => 0x19b51010901b6
- => 0x283ce00726500
- => 0x61ea308872
- => 0x00000fe3
- bash-109109 [007] d..h... 426.271265: #58634 context irq timer_latency 1211 ns
- timerlat/6-79756 [006] ....... 426.271267: timerlat_main: stop tracing hit on cpu 6
-
-In the trace, it is possible the notice that the *IRQ* timer latency was
-already high, accounting *12505 ns*. The IRQ delay was caused by the
-*bash-109109* process that disabled IRQs in the wake-up path
-(*_try_to_wake_up()* function). The duration of the IRQ handler that woke
-up the timerlat thread, informed with the **osnoise:irq_noise** event, was
-also high and added more *12553 ns* to the Thread latency. Finally, the
-**osnoise:thread_noise** added by the currently running thread (including
-the scheduling overhead) added more *4769 ns*. Summing up these values,
-the *Thread* timer latency accounted for *30328 ns*.
-
-The primary reason for this high value is the wake-up path that was hit
-twice during this case: when the *bash-109109* was waking up a thread
-and then when the *timerlat* thread was awakened. This information can
-then be used as the starting point of a more fine-grained analysis.
+ 1 #12322 | 0 0 1 15 | 10 3 9 31
+ 2 #12322 | 3 0 1 12 | 10 3 9 23
+ 3 #12322 | 1 0 1 21 | 8 2 8 34
+ 4 #12322 | 1 0 1 17 | 10 2 11 33
+ 5 #12322 | 0 0 1 12 | 8 3 8 25
+ 6 #12322 | 1 0 1 14 | 16 3 11 35
+ 7 #12322 | 0 0 1 14 | 9 2 8 29
+ 8 #12322 | 1 0 1 22 | 9 3 9 34
+ 9 #12322 | 0 0 1 14 | 8 2 8 24
+ 10 #12322 | 1 0 0 12 | 9 3 8 24
+ 11 #12322 | 0 0 0 15 | 6 2 7 29
+ 12 #12321 | 1 0 0 13 | 5 3 8 23
+ 13 #12319 | 0 0 1 14 | 9 3 9 26
+ 14 #12321 | 1 0 0 13 | 6 2 8 24
+ 15 #12321 | 1 0 1 15 | 12 3 11 27
+ 16 #12318 | 0 0 1 13 | 7 3 10 24
+ 17 #12319 | 0 0 1 13 | 11 3 9 25
+ 18 #12318 | 0 0 0 12 | 8 2 8 20
+ 19 #12319 | 0 0 1 18 | 10 2 9 28
+ 20 #12317 | 0 0 0 20 | 9 3 8 34
+ 21 #12318 | 0 0 0 13 | 8 3 8 28
+ 22 #12319 | 0 0 1 11 | 8 3 10 22
+ 23 #12320 | 28 0 1 28 | 41 3 11 41
+ rtla timerlat hit stop tracing
+ ## CPU 23 hit stop tracing, analyzing it ##
+ IRQ handler delay: 27.49 us (65.52 %)
+ IRQ latency: 28.13 us
+ Timerlat IRQ duration: 9.59 us (22.85 %)
+ Blocking thread: 3.79 us (9.03 %)
+ objtool:49256 3.79 us
+ Blocking thread stacktrace
+ -> timerlat_irq
+ -> __hrtimer_run_queues
+ -> hrtimer_interrupt
+ -> __sysvec_apic_timer_interrupt
+ -> sysvec_apic_timer_interrupt
+ -> asm_sysvec_apic_timer_interrupt
+ -> _raw_spin_unlock_irqrestore
+ -> cgroup_rstat_flush_locked
+ -> cgroup_rstat_flush_irqsafe
+ -> mem_cgroup_flush_stats
+ -> mem_cgroup_wb_stats
+ -> balance_dirty_pages
+ -> balance_dirty_pages_ratelimited_flags
+ -> btrfs_buffered_write
+ -> btrfs_do_write_iter
+ -> vfs_write
+ -> __x64_sys_pwrite64
+ -> do_syscall_64
+ -> entry_SYSCALL_64_after_hwframe
+ ------------------------------------------------------------------------
+ Thread latency: 41.96 us (100%)
+
+ The system has exit from idle latency!
+ Max timerlat IRQ latency from idle: 17.48 us in cpu 4
+ Saving trace to timerlat_trace.txt
+
+In this case, the major factor was the delay suffered by the *IRQ handler*
+that handles **timerlat** wakeup: *65.52%*. This can be caused by the
+current thread masking interrupts, which can be seen in the blocking
+thread stacktrace: the current thread (*objtool:49256*) disabled interrupts
+via *raw spin lock* operations inside mem cgroup, while doing write
+syscall in a btrfs file system.
+
+The raw trace is saved in the **timerlat_trace.txt** file for further analysis.

Note that **rtla timerlat** was dispatched without changing *timerlat* tracer
threads' priority. That is generally not needed because these threads hava
--
2.38.1