ftrace - Function Tracer ======================== Copyright 2008 Red Hat Inc. Author: Steven Rostedt License: The GNU Free Documentation License, Version 1.2 (dual licensed under the GPL v2) Reviewers: Elias Oltmanns, Randy Dunlap, Andrew Morton, John Kacur, and David Teigland. Written for: 2.6.28-rc2 Updated for: 3.10 Introduction ------------ Ftrace is an internal tracer designed to help out developers and designers of systems to find what is going on inside the kernel. It can be used for debugging or analyzing latencies and performance issues that take place outside of user-space. Although ftrace is typically considered the function tracer, it is really a frame work of several assorted tracing utilities. There's latency tracing to examine what occurs between interrupts disabled and enabled, as well as for preemption and from a time a task is woken to the task is actually scheduled in. One of the most common uses of ftrace is the event tracing. Through out the kernel is hundreds of static event points that can be enabled via the debugfs file system to see what is going on in certain parts of the kernel. Implementation Details ---------------------- See ftrace-design.txt for details for arch porters and such. The File System --------------- Ftrace uses the debugfs file system to hold the control files as well as the files to display output. When debugfs is configured into the kernel (which selecting any ftrace option will do) the directory /sys/kernel/debug will be created. To mount this directory, you can add to your /etc/fstab file: debugfs /sys/kernel/debug debugfs defaults 0 0 Or you can mount it at run time with: mount -t debugfs nodev /sys/kernel/debug For quicker access to that directory you may want to make a soft link to it: ln -s /sys/kernel/debug /debug Any selected ftrace option will also create a directory called tracing within the debugfs. The rest of the document will assume that you are in the ftrace directory (cd /sys/kernel/debug/tracing) and will only concentrate on the files within that directory and not distract from the content with the extended "/sys/kernel/debug/tracing" path name. That's it! (assuming that you have ftrace configured into your kernel) After mounting debugfs, you can see a directory called "tracing". This directory contains the control and output files of ftrace. Here is a list of some of the key files: Note: all time values are in microseconds. current_tracer: This is used to set or display the current tracer that is configured. available_tracers: This holds the different types of tracers that have been compiled into the kernel. The tracers listed here can be configured by echoing their name into current_tracer. tracing_on: This sets or displays whether writing to the trace ring buffer is enabled. Echo 0 into this file to disable the tracer or 1 to enable it. Note, this only disables writing to the ring buffer, the tracing overhead may still be occurring. trace: This file holds the output of the trace in a human readable format (described below). trace_pipe: The output is the same as the "trace" file but this file is meant to be streamed with live tracing. Reads from this file will block until new data is retrieved. Unlike the "trace" file, this file is a consumer. This means reading from this file causes sequential reads to display more current data. Once data is read from this file, it is consumed, and will not be read again with a sequential read. The "trace" file is static, and if the tracer is not adding more data,they will display the same information every time they are read. trace_options: This file lets the user control the amount of data that is displayed in one of the above output files. Options also exist to modify how a tracer or events work (stack traces, timestamps, etc). options: This is a directory that has a file for every available trace option (also in trace_options). Options may also be set or cleared by writing a "1" or "0" respectively into the corresponding file with the option name. tracing_max_latency: Some of the tracers record the max latency. For example, the time interrupts are disabled. This time is saved in this file. The max trace will also be stored, and displayed by "trace". A new max trace will only be recorded if the latency is greater than the value in this file. (in microseconds) tracing_thresh: Some latency tracers will record a trace whenever the latency is greater than the number in this file. Only active when the file contains a number greater than 0. (in microseconds) buffer_size_kb: This sets or displays the number of kilobytes each CPU buffer holds. By default, the trace buffers are the same size for each CPU. The displayed number is the size of the CPU buffer and not total size of all buffers. The trace buffers are allocated in pages (blocks of memory that the kernel uses for allocation, usually 4 KB in size). If the last page allocated has room for more bytes than requested, the rest of the page will be used, making the actual allocation bigger than requested. ( Note, the size may not be a multiple of the page size due to buffer management meta-data. ) buffer_total_size_kb: This displays the total combined size of all the trace buffers. free_buffer: If a process is performing the tracing, and the ring buffer should be shrunk "freed" when the process is finished, even if it were to be killed by a signal, this file can be used for that purpose. On close of this file, the ring buffer will be resized to its minimum size. Having a process that is tracing also open this file, when the process exits its file descriptor for this file will be closed, and in doing so, the ring buffer will be "freed". It may also stop tracing if disable_on_free option is set. tracing_cpumask: This is a mask that lets the user only trace on specified CPUs. The format is a hex string representing the CPUs. set_ftrace_filter: When dynamic ftrace is configured in (see the section below "dynamic ftrace"), the code is dynamically modified (code text rewrite) to disable calling of the function profiler (mcount). This lets tracing be configured in with practically no overhead in performance. This also has a side effect of enabling or disabling specific functions to be traced. Echoing names of functions into this file will limit the trace to only those functions. This interface also allows for commands to be used. See the "Filter commands" section for more details. set_ftrace_notrace: This has an effect opposite to that of set_ftrace_filter. Any function that is added here will not be traced. If a function exists in both set_ftrace_filter and set_ftrace_notrace, the function will _not_ be traced. set_ftrace_pid: Have the function tracer only trace a single thread. set_graph_function: Set a "trigger" function where tracing should start with the function graph tracer (See the section "dynamic ftrace" for more details). available_filter_functions: This lists the functions that ftrace has processed and can trace. These are the function names that you can pass to "set_ftrace_filter" or "set_ftrace_notrace". (See the section "dynamic ftrace" below for more details.) enabled_functions: This file is more for debugging ftrace, but can also be useful in seeing if any function has a callback attached to it. Not only does the trace infrastructure use ftrace function trace utility, but other subsystems might too. This file displays all functions that have a callback attached to them as well as the number of callbacks that have been attached. Note, a callback may also call multiple functions which will not be listed in this count. If the callback registered to be traced by a function with the "save regs" attribute (thus even more overhead), a 'R' will be displayed on the same line as the function that is returning registers. function_profile_enabled: When set it will enable all functions with either the function tracer, or if enabled, the function graph tracer. It will keep a histogram of the number of functions that were called and if run with the function graph tracer, it will also keep track of the time spent in those functions. The histogram content can be displayed in the files: trace_stats/function ( function0, function1, etc). trace_stats: A directory that holds different tracing stats. kprobe_events: Enable dynamic trace points. See kprobetrace.txt. kprobe_profile: Dynamic trace points stats. See kprobetrace.txt. max_graph_depth: Used with the function graph tracer. This is the max depth it will trace into a function. Setting this to a value of one will show only the first kernel function that is called from user space. printk_formats: This is for tools that read the raw format files. If an event in the ring buffer references a string (currently only trace_printk() does this), only a pointer to the string is recorded into the buffer and not the string itself. This prevents tools from knowing what that string was. This file displays the string and address for the string allowing tools to map the pointers to what the strings were. saved_cmdlines: Only the pid of the task is recorded in a trace event unless the event specifically saves the task comm as well. Ftrace makes a cache of pid mappings to comms to try to display comms for events. If a pid for a comm is not listed, then "<...>" is displayed in the output. snapshot: This displays the "snapshot" buffer and also lets the user take a snapshot of the current running trace. See the "Snapshot" section below for more details. stack_max_size: When the stack tracer is activated, this will display the maximum stack size it has encountered. See the "Stack Trace" section below. stack_trace: This displays the stack back trace of the largest stack that was encountered when the stack tracer is activated. See the "Stack Trace" section below. stack_trace_filter: This is similar to "set_ftrace_filter" but it limits what functions the stack tracer will check. trace_clock: Whenever an event is recorded into the ring buffer, a "timestamp" is added. This stamp comes from a specified clock. By default, ftrace uses the "local" clock. This clock is very fast and strictly per cpu, but on some systems it may not be monotonic with respect to other CPUs. In other words, the local clocks may not be in sync with local clocks on other CPUs. Usual clocks for tracing: # cat trace_clock [local] global counter x86-tsc local: Default clock, but may not be in sync across CPUs global: This clock is in sync with all CPUs but may be a bit slower than the local clock. counter: This is not a clock at all, but literally an atomic counter. It counts up one by one, but is in sync with all CPUs. This is useful when you need to know exactly the order events occurred with respect to each other on different CPUs. uptime: This uses the jiffies counter and the time stamp is relative to the time since boot up. perf: This makes ftrace use the same clock that perf uses. Eventually perf will be able to read ftrace buffers and this will help out in interleaving the data. x86-tsc: Architectures may define their own clocks. For example, x86 uses its own TSC cycle clock here. To set a clock, simply echo the clock name into this file. echo global > trace_clock trace_marker: This is a very useful file for synchronizing user space with events happening in the kernel. Writing strings into this file will be written into the ftrace buffer. It is useful in applications to open this file at the start of the application and just reference the file descriptor for the file. void trace_write(const char *fmt, ...) { va_list ap; char buf[256]; int n; if (trace_fd < 0) return; va_start(ap, fmt); n = vsnprintf(buf, 256, fmt, ap); va_end(ap); write(trace_fd, buf, n); } start: trace_fd = open("trace_marker", WR_ONLY); uprobe_events: Add dynamic tracepoints in programs. See uprobetracer.txt uprobe_profile: Uprobe statistics. See uprobetrace.txt instances: This is a way to make multiple trace buffers where different events can be recorded in different buffers. See "Instances" section below. events: This is the trace event directory. It holds event tracepoints (also known as static tracepoints) that have been compiled into the kernel. It shows what event tracepoints exist and how they are grouped by system. There are "enable" files at various levels that can enable the tracepoints when a "1" is written to them. See events.txt for more information. per_cpu: This is a directory that contains the trace per_cpu information. per_cpu/cpu0/buffer_size_kb: The ftrace buffer is defined per_cpu. That is, there's a separate buffer for each CPU to allow writes to be done atomically, and free from cache bouncing. These buffers may have different size buffers. This file is similar to the buffer_size_kb file, but it only displays or sets the buffer size for the specific CPU. (here cpu0). per_cpu/cpu0/trace: This is similar to the "trace" file, but it will only display the data specific for the CPU. If written to, it only clears the specific CPU buffer. per_cpu/cpu0/trace_pipe This is similar to the "trace_pipe" file, and is a consuming read, but it will only display (and consume) the data specific for the CPU. per_cpu/cpu0/trace_pipe_raw For tools that can parse the ftrace ring buffer binary format, the trace_pipe_raw file can be used to extract the data from the ring buffer directly. With the use of the splice() system call, the buffer data can be quickly transferred to a file or to the network where a server is collecting the data. Like trace_pipe, this is a consuming reader, where multiple reads will always produce different data. per_cpu/cpu0/snapshot: This is similar to the main "snapshot" file, but will only snapshot the current CPU (if supported). It only displays the content of the snapshot for a given CPU, and if written to, only clears this CPU buffer. per_cpu/cpu0/snapshot_raw: Similar to the trace_pipe_raw, but will read the binary format from the snapshot buffer for the given CPU. per_cpu/cpu0/stats: This displays certain stats about the ring buffer: entries: The number of events that are still in the buffer. overrun: The number of lost events due to overwriting when the buffer was full. commit overrun: Should always be zero. This gets set if so many events happened within a nested event (ring buffer is re-entrant), that it fills the buffer and starts dropping events. bytes: Bytes actually read (not overwritten). oldest event ts: The oldest timestamp in the buffer now ts: The current timestamp dropped events: Events lost due to overwrite option being off. read events: The number of events read. The Tracers ----------- Here is the list of current tracers that may be configured. "function" Function call tracer to trace all kernel functions. "function_graph" Similar to the function tracer except that the function tracer probes the functions on their entry whereas the function graph tracer traces on both entry and exit of the functions. It then provides the ability to draw a graph of function calls similar to C code source. "irqsoff" Traces the areas that disable interrupts and saves the trace with the longest max latency. See tracing_max_latency. When a new max is recorded, it replaces the old trace. It is best to view this trace with the latency-format option enabled. "preemptoff" Similar to irqsoff but traces and records the amount of time for which preemption is disabled. "preemptirqsoff" Similar to irqsoff and preemptoff, but traces and records the largest time for which irqs and/or preemption is disabled. "wakeup" Traces and records the max latency that it takes for the highest priority task to get scheduled after it has been woken up. Traces all tasks as an average developer would expect. "wakeup_rt" Traces and records the max latency that it takes for just RT tasks (as the current "wakeup" does). This is useful for those interested in wake up timings of RT tasks. "nop" This is the "trace nothing" tracer. To remove all tracers from tracing simply echo "nop" into current_tracer. Examples of using the tracer ---------------------------- Here are typical examples of using the tracers when controlling them only with the debugfs interface (without using any user-land utilities). Output format: -------------- Here is an example of the output format of the file "trace" -------- # tracer: function # # entries-in-buffer/entries-written: 140080/250280 #P:4 # # _-----=> irqs-off # / _----=> need-resched # | / _---=> hardirq/softirq # || / _--=> preempt-depth # ||| / delay # TASK-PID CPU# |||| TIMESTAMP FUNCTION # | | | |||| | | bash-1977 [000] .... 17284.993652: sys_close <-system_call_fastpath bash-1977 [000] .... 17284.993653: __close_fd <-sys_close bash-1977 [000] .... 17284.993653: _raw_spin_lock <-__close_fd sshd-1974 [003] .... 17284.993653: __srcu_read_unlock <-fsnotify bash-1977 [000] .... 17284.993654: add_preempt_count <-_raw_spin_lock bash-1977 [000] ...1 17284.993655: _raw_spin_unlock <-__close_fd bash-1977 [000] ...1 17284.993656: sub_preempt_count <-_raw_spin_unlock bash-1977 [000] .... 17284.993657: filp_close <-__close_fd bash-1977 [000] .... 17284.993657: dnotify_flush <-filp_close sshd-1974 [003] .... 17284.993658: sys_select <-system_call_fastpath -------- A header is printed with the tracer name that is represented by the trace. In this case the tracer is "function". Then it shows the number of events in the buffer as well as the total number of entries that were written. The difference is the number of entries that were lost due to the buffer filling up (250280 - 140080 = 110200 events lost). The header explains the content of the events. Task name "bash", the task PID "1977", the CPU that it was running on "000", the latency format (explained below), the timestamp in . format, the function name that was traced "sys_close" and the parent function that called this function "system_call_fastpath". The timestamp is the time at which the function was entered. Latency trace format -------------------- When the latency-format option is enabled or when one of the latency tracers is set, the trace file gives somewhat more information to see why a latency happened. Here is a typical trace. # tracer: irqsoff # # irqsoff latency trace v1.1.5 on 3.8.0-test+ # -------------------------------------------------------------------- # latency: 259 us, #4/4, CPU#2 | (M:preempt VP:0, KP:0, SP:0 HP:0 #P:4) # ----------------- # | task: ps-6143 (uid:0 nice:0 policy:0 rt_prio:0) # ----------------- # => started at: __lock_task_sighand # => ended at: _raw_spin_unlock_irqrestore # # # _------=> CPU# # / _-----=> irqs-off # | / _----=> need-resched # || / _---=> hardirq/softirq # ||| / _--=> preempt-depth # |||| / delay # cmd pid ||||| time | caller # \ / ||||| \ | / ps-6143 2d... 0us!: trace_hardirqs_off <-__lock_task_sighand ps-6143 2d..1 259us+: trace_hardirqs_on <-_raw_spin_unlock_irqrestore ps-6143 2d..1 263us+: time_hardirqs_on <-_raw_spin_unlock_irqrestore ps-6143 2d..1 306us : => trace_hardirqs_on_caller => trace_hardirqs_on => _raw_spin_unlock_irqrestore => do_task_stat => proc_tgid_stat => proc_single_show => seq_read => vfs_read => sys_read => system_call_fastpath This shows that the current tracer is "irqsoff" tracing the time for which interrupts were disabled. It gives the trace version (which never changes) and the version of the kernel upon which this was executed on (3.10). Then it displays the max latency in microseconds (259 us). The number of trace entries displayed and the total number (both are four: #4/4). VP, KP, SP, and HP are always zero and are reserved for later use. #P is the number of online CPUs (#P:4). The task is the process that was running when the latency occurred. (ps pid: 6143). The start and stop (the functions in which the interrupts were disabled and enabled respectively) that caused the latencies: __lock_task_sighand is where the interrupts were disabled. _raw_spin_unlock_irqrestore is where they were enabled again. The next lines after the header are the trace itself. The header explains which is which. cmd: The name of the process in the trace. pid: The PID of that process. CPU#: The CPU which the process was running on. irqs-off: 'd' interrupts are disabled. '.' otherwise. Note: If the architecture does not support a way to read the irq flags variable, an 'X' will always be printed here. need-resched: 'N' task need_resched is set, '.' otherwise. hardirq/softirq: 'H' - hard irq occurred inside a softirq. 'h' - hard irq is running 's' - soft irq is running '.' - normal context. preempt-depth: The level of preempt_disabled The above is mostly meaningful for kernel developers. time: When the latency-format option is enabled, the trace file output includes a timestamp relative to the start of the trace. This differs from the output when latency-format is disabled, which includes an absolute timestamp. delay: This is just to help catch your eye a bit better. And needs to be fixed to be only relative to the same CPU. The marks are determined by the difference between this current trace and the next trace. '!' - greater than preempt_mark_thresh (default 100) '+' - greater than 1 microsecond ' ' - less than or equal to 1 microsecond. The rest is the same as the 'trace' file. Note, the latency tracers will usually end with a back trace to easily find where the latency occurred. trace_options ------------- The trace_options file (or the options directory) is used to control what gets printed in the trace output, or manipulate the tracers. To see what is available, simply cat the file: cat trace_options print-parent nosym-offset nosym-addr noverbose noraw nohex nobin noblock nostacktrace trace_printk noftrace_preempt nobranch annotate nouserstacktrace nosym-userobj noprintk-msg-only context-info latency-format sleep-time graph-time record-cmd overwrite nodisable_on_free irq-info markers function-trace To disable one of the options, echo in the option prepended with "no". echo noprint-parent > trace_options To enable an option, leave off the "no". echo sym-offset > trace_options Here are the available options: print-parent - On function traces, display the calling (parent) function as well as the function being traced. print-parent: bash-4000 [01] 1477.606694: simple_strtoul <-strict_strtoul noprint-parent: bash-4000 [01] 1477.606694: simple_strtoul sym-offset - Display not only the function name, but also the offset in the function. For example, instead of seeing just "ktime_get", you will see "ktime_get+0xb/0x20". sym-offset: bash-4000 [01] 1477.606694: simple_strtoul+0x6/0xa0 sym-addr - this will also display the function address as well as the function name. sym-addr: bash-4000 [01] 1477.606694: simple_strtoul verbose - This deals with the trace file when the latency-format option is enabled. bash 4000 1 0 00000000 00010a95 [58127d26] 1720.415ms \ (+0.000ms): simple_strtoul (strict_strtoul) raw - This will display raw numbers. This option is best for use with user applications that can translate the raw numbers better than having it done in the kernel. hex - Similar to raw, but the numbers will be in a hexadecimal format. bin - This will print out the formats in raw binary. block - When set, reading trace_pipe will not block when polled. stacktrace - This is one of the options that changes the trace itself. When a trace is recorded, so is the stack of functions. This allows for back traces of trace sites. trace_printk - Can disable trace_printk() from writing into the buffer. branch - Enable branch tracing with the tracer. annotate - It is sometimes confusing when the CPU buffers are full and one CPU buffer had a lot of events recently, thus a shorter time frame, were another CPU may have only had a few events, which lets it have older events. When the trace is reported, it shows the oldest events first, and it may look like only one CPU ran (the one with the oldest events). When the annotate option is set, it will display when a new CPU buffer started: -0 [001] dNs4 21169.031481: wake_up_idle_cpu <-add_timer_on -0 [001] dNs4 21169.031482: _raw_spin_unlock_irqrestore <-add_timer_on -0 [001] .Ns4 21169.031484: sub_preempt_count <-_raw_spin_unlock_irqrestore ##### CPU 2 buffer started #### -0 [002] .N.1 21169.031484: rcu_idle_exit <-cpu_idle -0 [001] .Ns3 21169.031484: _raw_spin_unlock <-clocksource_watchdog -0 [001] .Ns3 21169.031485: sub_preempt_count <-_raw_spin_unlock userstacktrace - This option changes the trace. It records a stacktrace of the current userspace thread. sym-userobj - when user stacktrace are enabled, look up which object the address belongs to, and print a relative address. This is especially useful when ASLR is on, otherwise you don't get a chance to resolve the address to object/file/line after the app is no longer running The lookup is performed when you read trace,trace_pipe. Example: a.out-1623 [000] 40874.465068: /root/a.out[+0x480] <-/root/a.out[+0 x494] <- /root/a.out[+0x4a8] <- /lib/libc-2.7.so[+0x1e1a6] printk-msg-only - When set, trace_printk()s will only show the format and not their parameters (if trace_bprintk() or trace_bputs() was used to save the trace_printk()). context-info - Show only the event data. Hides the comm, PID, timestamp, CPU, and other useful data. latency-format - This option changes the trace. When it is enabled, the trace displays additional information about the latencies, as described in "Latency trace format". sleep-time - When running function graph tracer, to include the time a task schedules out in its function. When enabled, it will account time the task has been scheduled out as part of the function call. graph-time - When running function graph tracer, to include the time to call nested functions. When this is not set, the time reported for the function will only include the time the function itself executed for, not the time for functions that it called. record-cmd - When any event or tracer is enabled, a hook is enabled in the sched_switch trace point to fill comm cache with mapped pids and comms. But this may cause some overhead, and if you only care about pids, and not the name of the task, disabling this option can lower the impact of tracing. overwrite - This controls what happens when the trace buffer is full. If "1" (default), the oldest events are discarded and overwritten. If "0", then the newest events are discarded. (see per_cpu/cpu0/stats for overrun and dropped) disable_on_free - When the free_buffer is closed, tracing will stop (tracing_on set to 0). irq-info - Shows the interrupt, preempt count, need resched data. When disabled, the trace looks like: # tracer: function # # entries-in-buffer/entries-written: 144405/9452052 #P:4 # # TASK-PID CPU# TIMESTAMP FUNCTION # | | | | | -0 [002] 23636.756054: ttwu_do_activate.constprop.89 <-try_to_wake_up -0 [002] 23636.756054: activate_task <-ttwu_do_activate.constprop.89 -0 [002] 23636.756055: enqueue_task <-activate_task markers - When set, the trace_marker is writable (only by root). When disabled, the trace_marker will error with EINVAL on write. function-trace - The latency tracers will enable function tracing if this option is enabled (default it is). When it is disabled, the latency tracers do not trace functions. This keeps the overhead of the tracer down when performing latency tests. Note: Some tracers have their own options. They only appear when the tracer is active. irqsoff ------- When interrupts are disabled, the CPU can not react to any other external event (besides NMIs and SMIs). This prevents the timer interrupt from triggering or the mouse interrupt from letting the kernel know of a new mouse event. The result is a latency with the reaction time. The irqsoff tracer tracks the time for which interrupts are disabled. When a new maximum latency is hit, the tracer saves the trace leading up to that latency point so that every time a new maximum is reached, the old saved trace is discarded and the new trace is saved. To reset the maximum, echo 0 into tracing_max_latency. Here is an example: # echo 0 > options/function-trace # echo irqsoff > current_tracer # echo 1 > tracing_on # echo 0 > tracing_max_latency # ls -ltr [...] # echo 0 > tracing_on # cat trace # tracer: irqsoff # # irqsoff latency trace v1.1.5 on 3.8.0-test+ # -------------------------------------------------------------------- # latency: 16 us, #4/4, CPU#0 | (M:preempt VP:0, KP:0, SP:0 HP:0 #P:4) # ----------------- # | task: swapper/0-0 (uid:0 nice:0 policy:0 rt_prio:0) # ----------------- # => started at: run_timer_softirq # => ended at: run_timer_softirq # # # _------=> CPU# # / _-----=> irqs-off # | / _----=> need-resched # || / _---=> hardirq/softirq # ||| / _--=> preempt-depth # |||| / delay # cmd pid ||||| time | caller # \ / ||||| \ | / -0 0d.s2 0us+: _raw_spin_lock_irq <-run_timer_softirq -0 0dNs3 17us : _raw_spin_unlock_irq <-run_timer_softirq -0 0dNs3 17us+: trace_hardirqs_on <-run_timer_softirq -0 0dNs3 25us : => _raw_spin_unlock_irq => run_timer_softirq => __do_softirq => call_softirq => do_softirq => irq_exit => smp_apic_timer_interrupt => apic_timer_interrupt => rcu_idle_exit => cpu_idle => rest_init => start_kernel => x86_64_start_reservations => x86_64_start_kernel Here we see that that we had a latency of 16 microseconds (which is very good). The _raw_spin_lock_irq in run_timer_softirq disabled interrupts. The difference between the 16 and the displayed timestamp 25us occurred because the clock was incremented between the time of recording the max latency and the time of recording the function that had that latency. Note the above example had function-trace not set. If we set function-trace, we get a much larger output: with echo 1 > options/function-trace # tracer: irqsoff # # irqsoff latency trace v1.1.5 on 3.8.0-test+ # -------------------------------------------------------------------- # latency: 71 us, #168/168, CPU#3 | (M:preempt VP:0, KP:0, SP:0 HP:0 #P:4) # ----------------- # | task: bash-2042 (uid:0 nice:0 policy:0 rt_prio:0) # ----------------- # => started at: ata_scsi_queuecmd # => ended at: ata_scsi_queuecmd # # # _------=> CPU# # / _-----=> irqs-off # | / _----=> need-resched # || / _---=> hardirq/softirq # ||| / _--=> preempt-depth # |||| / delay # cmd pid ||||| time | caller # \ / ||||| \ | / bash-2042 3d... 0us : _raw_spin_lock_irqsave <-ata_scsi_queuecmd bash-2042 3d... 0us : add_preempt_count <-_raw_spin_lock_irqsave bash-2042 3d..1 1us : ata_scsi_find_dev <-ata_scsi_queuecmd bash-2042 3d..1 1us : __ata_scsi_find_dev <-ata_scsi_find_dev bash-2042 3d..1 2us : ata_find_dev.part.14 <-__ata_scsi_find_dev bash-2042 3d..1 2us : ata_qc_new_init <-__ata_scsi_queuecmd bash-2042 3d..1 3us : ata_sg_init <-__ata_scsi_queuecmd bash-2042 3d..1 4us : ata_scsi_rw_xlat <-__ata_scsi_queuecmd bash-2042 3d..1 4us : ata_build_rw_tf <-ata_scsi_rw_xlat [...] bash-2042 3d..1 67us : delay_tsc <-__delay bash-2042 3d..1 67us : add_preempt_count <-delay_tsc bash-2042 3d..2 67us : sub_preempt_count <-delay_tsc bash-2042 3d..1 67us : add_preempt_count <-delay_tsc bash-2042 3d..2 68us : sub_preempt_count <-delay_tsc bash-2042 3d..1 68us+: ata_bmdma_start <-ata_bmdma_qc_issue bash-2042 3d..1 71us : _raw_spin_unlock_irqrestore <-ata_scsi_queuecmd bash-2042 3d..1 71us : _raw_spin_unlock_irqrestore <-ata_scsi_queuecmd bash-2042 3d..1 72us+: trace_hardirqs_on <-ata_scsi_queuecmd bash-2042 3d..1 120us : => _raw_spin_unlock_irqrestore => ata_scsi_queuecmd => scsi_dispatch_cmd => scsi_request_fn => __blk_run_queue_uncond => __blk_run_queue => blk_queue_bio => generic_make_request => submit_bio => submit_bh => __ext3_get_inode_loc => ext3_iget => ext3_lookup => lookup_real => __lookup_hash => walk_component => lookup_last => path_lookupat => filename_lookup => user_path_at_empty => user_path_at => vfs_fstatat => vfs_stat => sys_newstat => system_call_fastpath Here we traced a 71 microsecond latency. But we also see all the functions that were called during that time. Note that by enabling function tracing, we incur an added overhead. This overhead may extend the latency times. But nevertheless, this trace has provided some very helpful debugging information. preemptoff ---------- When preemption is disabled, we may be able to receive interrupts but the task cannot be preempted and a higher priority task must wait for preemption to be enabled again before it can preempt a lower priority task. The preemptoff tracer traces the places that disable preemption. Like the irqsoff tracer, it records the maximum latency for which preemption was disabled. The control of preemptoff tracer is much like the irqsoff tracer. # echo 0 > options/function-trace # echo preemptoff > current_tracer # echo 1 > tracing_on # echo 0 > tracing_max_latency # ls -ltr [...] # echo 0 > tracing_on # cat trace # tracer: preemptoff # # preemptoff latency trace v1.1.5 on 3.8.0-test+ # -------------------------------------------------------------------- # latency: 46 us, #4/4, CPU#1 | (M:preempt VP:0, KP:0, SP:0 HP:0 #P:4) # ----------------- # | task: sshd-1991 (uid:0 nice:0 policy:0 rt_prio:0) # ----------------- # => started at: do_IRQ # => ended at: do_IRQ # # # _------=> CPU# # / _-----=> irqs-off # | / _----=> need-resched # || / _---=> hardirq/softirq # ||| / _--=> preempt-depth # |||| / delay # cmd pid ||||| time | caller # \ / ||||| \ | / sshd-1991 1d.h. 0us+: irq_enter <-do_IRQ sshd-1991 1d..1 46us : irq_exit <-do_IRQ sshd-1991 1d..1 47us+: trace_preempt_on <-do_IRQ sshd-1991 1d..1 52us : => sub_preempt_count => irq_exit => do_IRQ => ret_from_intr This has some more changes. Preemption was disabled when an interrupt came in (notice the 'h'), and was enabled on exit. But we also see that interrupts have been disabled when entering the preempt off section and leaving it (the 'd'). We do not know if interrupts were enabled in the mean time or shortly after this was over. # tracer: preemptoff # # preemptoff latency trace v1.1.5 on 3.8.0-test+ # -------------------------------------------------------------------- # latency: 83 us, #241/241, CPU#1 | (M:preempt VP:0, KP:0, SP:0 HP:0 #P:4) # ----------------- # | task: bash-1994 (uid:0 nice:0 policy:0 rt_prio:0) # ----------------- # => started at: wake_up_new_task # => ended at: task_rq_unlock # # # _------=> CPU# # / _-----=> irqs-off # | / _----=> need-resched # || / _---=> hardirq/softirq # ||| / _--=> preempt-depth # |||| / delay # cmd pid ||||| time | caller # \ / ||||| \ | / bash-1994 1d..1 0us : _raw_spin_lock_irqsave <-wake_up_new_task bash-1994 1d..1 0us : select_task_rq_fair <-select_task_rq bash-1994 1d..1 1us : __rcu_read_lock <-select_task_rq_fair bash-1994 1d..1 1us : source_load <-select_task_rq_fair bash-1994 1d..1 1us : source_load <-select_task_rq_fair [...] bash-1994 1d..1 12us : irq_enter <-smp_apic_timer_interrupt bash-1994 1d..1 12us : rcu_irq_enter <-irq_enter bash-1994 1d..1 13us : add_preempt_count <-irq_enter bash-1994 1d.h1 13us : exit_idle <-smp_apic_timer_interrupt bash-1994 1d.h1 13us : hrtimer_interrupt <-smp_apic_timer_interrupt bash-1994 1d.h1 13us : _raw_spin_lock <-hrtimer_interrupt bash-1994 1d.h1 14us : add_preempt_count <-_raw_spin_lock bash-1994 1d.h2 14us : ktime_get_update_offsets <-hrtimer_interrupt [...] bash-1994 1d.h1 35us : lapic_next_event <-clockevents_program_event bash-1994 1d.h1 35us : irq_exit <-smp_apic_timer_interrupt bash-1994 1d.h1 36us : sub_preempt_count <-irq_exit bash-1994 1d..2 36us : do_softirq <-irq_exit bash-1994 1d..2 36us : __do_softirq <-call_softirq bash-1994 1d..2 36us : __local_bh_disable <-__do_softirq bash-1994 1d.s2 37us : add_preempt_count <-_raw_spin_lock_irq bash-1994 1d.s3 38us : _raw_spin_unlock <-run_timer_softirq bash-1994 1d.s3 39us : sub_preempt_count <-_raw_spin_unlock bash-1994 1d.s2 39us : call_timer_fn <-run_timer_softirq [...] bash-1994 1dNs2 81us : cpu_needs_another_gp <-rcu_process_callbacks bash-1994 1dNs2 82us : __local_bh_enable <-__do_softirq bash-1994 1dNs2 82us : sub_preempt_count <-__local_bh_enable bash-1994 1dN.2 82us : idle_cpu <-irq_exit bash-1994 1dN.2 83us : rcu_irq_exit <-irq_exit bash-1994 1dN.2 83us : sub_preempt_count <-irq_exit bash-1994 1.N.1 84us : _raw_spin_unlock_irqrestore <-task_rq_unlock bash-1994 1.N.1 84us+: trace_preempt_on <-task_rq_unlock bash-1994 1.N.1 104us : => sub_preempt_count => _raw_spin_unlock_irqrestore => task_rq_unlock => wake_up_new_task => do_fork => sys_clone => stub_clone The above is an example of the preemptoff trace with function-trace set. Here we see that interrupts were not disabled the entire time. The irq_enter code lets us know that we entered an interrupt 'h'. Before that, the functions being traced still show that it is not in an interrupt, but we can see from the functions themselves that this is not the case. preemptirqsoff -------------- Knowing the locations that have interrupts disabled or preemption disabled for the longest times is helpful. But sometimes we would like to know when either preemption and/or interrupts are disabled. Consider the following code: local_irq_disable(); call_function_with_irqs_off(); preempt_disable(); call_function_with_irqs_and_preemption_off(); local_irq_enable(); call_function_with_preemption_off(); preempt_enable(); The irqsoff tracer will record the total length of call_function_with_irqs_off() and call_function_with_irqs_and_preemption_off(). The preemptoff tracer will record the total length of call_function_with_irqs_and_preemption_off() and call_function_with_preemption_off(). But neither will trace the time that interrupts and/or preemption is disabled. This total time is the time that we can not schedule. To record this time, use the preemptirqsoff tracer. Again, using this trace is much like the irqsoff and preemptoff tracers. # echo 0 > options/function-trace # echo preemptirqsoff > current_tracer # echo 1 > tracing_on # echo 0 > tracing_max_latency # ls -ltr [...] # echo 0 > tracing_on # cat trace # tracer: preemptirqsoff # # preemptirqsoff latency trace v1.1.5 on 3.8.0-test+ # -------------------------------------------------------------------- # latency: 100 us, #4/4, CPU#3 | (M:preempt VP:0, KP:0, SP:0 HP:0 #P:4) # ----------------- # | task: ls-2230 (uid:0 nice:0 policy:0 rt_prio:0) # ----------------- # => started at: ata_scsi_queuecmd # => ended at: ata_scsi_queuecmd # # # _------=> CPU# # / _-----=> irqs-off # | / _----=> need-resched # || / _---=> hardirq/softirq # ||| / _--=> preempt-depth # |||| / delay # cmd pid ||||| time | caller # \ / ||||| \ | / ls-2230 3d... 0us+: _raw_spin_lock_irqsave <-ata_scsi_queuecmd ls-2230 3...1 100us : _raw_spin_unlock_irqrestore <-ata_scsi_queuecmd ls-2230 3...1 101us+: trace_preempt_on <-ata_scsi_queuecmd ls-2230 3...1 111us : => sub_preempt_count => _raw_spin_unlock_irqrestore => ata_scsi_queuecmd => scsi_dispatch_cmd => scsi_request_fn => __blk_run_queue_uncond => __blk_run_queue => blk_queue_bio => generic_make_request => submit_bio => submit_bh => ext3_bread => ext3_dir_bread => htree_dirblock_to_tree => ext3_htree_fill_tree => ext3_readdir => vfs_readdir => sys_getdents => system_call_fastpath The trace_hardirqs_off_thunk is called from assembly on x86 when interrupts are disabled in the assembly code. Without the function tracing, we do not know if interrupts were enabled within the preemption points. We do see that it started with preemption enabled. Here is a trace with function-trace set: # tracer: preemptirqsoff # # preemptirqsoff latency trace v1.1.5 on 3.8.0-test+ # -------------------------------------------------------------------- # latency: 161 us, #339/339, CPU#3 | (M:preempt VP:0, KP:0, SP:0 HP:0 #P:4) # ----------------- # | task: ls-2269 (uid:0 nice:0 policy:0 rt_prio:0) # ----------------- # => started at: schedule # => ended at: mutex_unlock # # # _------=> CPU# # / _-----=> irqs-off # | / _----=> need-resched # || / _---=> hardirq/softirq # ||| / _--=> preempt-depth # |||| / delay # cmd pid ||||| time | caller # \ / ||||| \ | / kworker/-59 3...1 0us : __schedule <-schedule kworker/-59 3d..1 0us : rcu_preempt_qs <-rcu_note_context_switch kworker/-59 3d..1 1us : add_preempt_count <-_raw_spin_lock_irq kworker/-59 3d..2 1us : deactivate_task <-__schedule kworker/-59 3d..2 1us : dequeue_task <-deactivate_task kworker/-59 3d..2 2us : update_rq_clock <-dequeue_task kworker/-59 3d..2 2us : dequeue_task_fair <-dequeue_task kworker/-59 3d..2 2us : update_curr <-dequeue_task_fair kworker/-59 3d..2 2us : update_min_vruntime <-update_curr kworker/-59 3d..2 3us : cpuacct_charge <-update_curr kworker/-59 3d..2 3us : __rcu_read_lock <-cpuacct_charge kworker/-59 3d..2 3us : __rcu_read_unlock <-cpuacct_charge kworker/-59 3d..2 3us : update_cfs_rq_blocked_load <-dequeue_task_fair kworker/-59 3d..2 4us : clear_buddies <-dequeue_task_fair kworker/-59 3d..2 4us : account_entity_dequeue <-dequeue_task_fair kworker/-59 3d..2 4us : update_min_vruntime <-dequeue_task_fair kworker/-59 3d..2 4us : update_cfs_shares <-dequeue_task_fair kworker/-59 3d..2 5us : hrtick_update <-dequeue_task_fair kworker/-59 3d..2 5us : wq_worker_sleeping <-__schedule kworker/-59 3d..2 5us : kthread_data <-wq_worker_sleeping kworker/-59 3d..2 5us : put_prev_task_fair <-__schedule kworker/-59 3d..2 6us : pick_next_task_fair <-pick_next_task kworker/-59 3d..2 6us : clear_buddies <-pick_next_task_fair kworker/-59 3d..2 6us : set_next_entity <-pick_next_task_fair kworker/-59 3d..2 6us : update_stats_wait_end <-set_next_entity ls-2269 3d..2 7us : finish_task_switch <-__schedule ls-2269 3d..2 7us : _raw_spin_unlock_irq <-finish_task_switch ls-2269 3d..2 8us : do_IRQ <-ret_from_intr ls-2269 3d..2 8us : irq_enter <-do_IRQ ls-2269 3d..2 8us : rcu_irq_enter <-irq_enter ls-2269 3d..2 9us : add_preempt_count <-irq_enter ls-2269 3d.h2 9us : exit_idle <-do_IRQ [...] ls-2269 3d.h3 20us : sub_preempt_count <-_raw_spin_unlock ls-2269 3d.h2 20us : irq_exit <-do_IRQ ls-2269 3d.h2 21us : sub_preempt_count <-irq_exit ls-2269 3d..3 21us : do_softirq <-irq_exit ls-2269 3d..3 21us : __do_softirq <-call_softirq ls-2269 3d..3 21us+: __local_bh_disable <-__do_softirq ls-2269 3d.s4 29us : sub_preempt_count <-_local_bh_enable_ip ls-2269 3d.s5 29us : sub_preempt_count <-_local_bh_enable_ip ls-2269 3d.s5 31us : do_IRQ <-ret_from_intr ls-2269 3d.s5 31us : irq_enter <-do_IRQ ls-2269 3d.s5 31us : rcu_irq_enter <-irq_enter [...] ls-2269 3d.s5 31us : rcu_irq_enter <-irq_enter ls-2269 3d.s5 32us : add_preempt_count <-irq_enter ls-2269 3d.H5 32us : exit_idle <-do_IRQ ls-2269 3d.H5 32us : handle_irq <-do_IRQ ls-2269 3d.H5 32us : irq_to_desc <-handle_irq ls-2269 3d.H5 33us : handle_fasteoi_irq <-handle_irq [...] ls-2269 3d.s5 158us : _raw_spin_unlock_irqrestore <-rtl8139_poll ls-2269 3d.s3 158us : net_rps_action_and_irq_enable.isra.65 <-net_rx_action ls-2269 3d.s3 159us : __local_bh_enable <-__do_softirq ls-2269 3d.s3 159us : sub_preempt_count <-__local_bh_enable ls-2269 3d..3 159us : idle_cpu <-irq_exit ls-2269 3d..3 159us : rcu_irq_exit <-irq_exit ls-2269 3d..3 160us : sub_preempt_count <-irq_exit ls-2269 3d... 161us : __mutex_unlock_slowpath <-mutex_unlock ls-2269 3d... 162us+: trace_hardirqs_on <-mutex_unlock ls-2269 3d... 186us : => __mutex_unlock_slowpath => mutex_unlock => process_output => n_tty_write => tty_write => vfs_write => sys_write => system_call_fastpath This is an interesting trace. It started with kworker running and scheduling out and ls taking over. But as soon as ls released the rq lock and enabled interrupts (but not preemption) an interrupt triggered. When the interrupt finished, it started running softirqs. But while the softirq was running, another interrupt triggered. When an interrupt is running inside a softirq, the annotation is 'H'. wakeup ------ One common case that people are interested in tracing is the time it takes for a task that is woken to actually wake up. Now for non Real-Time tasks, this can be arbitrary. But tracing it none the less can be interesting. Without function tracing: # echo 0 > options/function-trace # echo wakeup > current_tracer # echo 1 > tracing_on # echo 0 > tracing_max_latency # chrt -f 5 sleep 1 # echo 0 > tracing_on # cat trace # tracer: wakeup # # wakeup latency trace v1.1.5 on 3.8.0-test+ # -------------------------------------------------------------------- # latency: 15 us, #4/4, CPU#3 | (M:preempt VP:0, KP:0, SP:0 HP:0 #P:4) # ----------------- # | task: kworker/3:1H-312 (uid:0 nice:-20 policy:0 rt_prio:0) # ----------------- # # _------=> CPU# # / _-----=> irqs-off # | / _----=> need-resched # || / _---=> hardirq/softirq # ||| / _--=> preempt-depth # |||| / delay # cmd pid ||||| time | caller # \ / ||||| \ | / -0 3dNs7 0us : 0:120:R + [003] 312:100:R kworker/3:1H -0 3dNs7 1us+: ttwu_do_activate.constprop.87 <-try_to_wake_up -0 3d..3 15us : __schedule <-schedule -0 3d..3 15us : 0:120:R ==> [003] 312:100:R kworker/3:1H The tracer only traces the highest priority task in the system to avoid tracing the normal circumstances. Here we see that the kworker with a nice priority of -20 (not very nice), took just 15 microseconds from the time it woke up, to the time it ran. Non Real-Time tasks are not that interesting. A more interesting trace is to concentrate only on Real-Time tasks. wakeup_rt --------- In a Real-Time environment it is very important to know the wakeup time it takes for the highest priority task that is woken up to the time that it executes. This is also known as "schedule latency". I stress the point that this is about RT tasks. It is also important to know the scheduling latency of non-RT tasks, but the average schedule latency is better for non-RT tasks. Tools like LatencyTop are more appropriate for such measurements. Real-Time environments are interested in the worst case latency. That is the longest latency it takes for something to happen, and not the average. We can have a very fast scheduler that may only have a large latency once in a while, but that would not work well with Real-Time tasks. The wakeup_rt tracer was designed to record the worst case wakeups of RT tasks. Non-RT tasks are not recorded because the tracer only records one worst case and tracing non-RT tasks that are unpredictable will overwrite the worst case latency of RT tasks (just run the normal wakeup tracer for a while to see that effect). Since this tracer only deals with RT tasks, we will run this slightly differently than we did with the previous tracers. Instead of performing an 'ls', we will run 'sleep 1' under 'chrt' which changes the priority of the task. # echo 0 > options/function-trace # echo wakeup_rt > current_tracer # echo 1 > tracing_on # echo 0 > tracing_max_latency # chrt -f 5 sleep 1 # echo 0 > tracing_on # cat trace # tracer: wakeup # # tracer: wakeup_rt # # wakeup_rt latency trace v1.1.5 on 3.8.0-test+ # -------------------------------------------------------------------- # latency: 5 us, #4/4, CPU#3 | (M:preempt VP:0, KP:0, SP:0 HP:0 #P:4) # ----------------- # | task: sleep-2389 (uid:0 nice:0 policy:1 rt_prio:5) # ----------------- # # _------=> CPU# # / _-----=> irqs-off # | / _----=> need-resched # || / _---=> hardirq/softirq # ||| / _--=> preempt-depth # |||| / delay # cmd pid ||||| time | caller # \ / ||||| \ | / -0 3d.h4 0us : 0:120:R + [003] 2389: 94:R sleep -0 3d.h4 1us+: ttwu_do_activate.constprop.87 <-try_to_wake_up -0 3d..3 5us : __schedule <-schedule -0 3d..3 5us : 0:120:R ==> [003] 2389: 94:R sleep Running this on an idle system, we see that it only took 5 microseconds to perform the task switch. Note, since the trace point in the schedule is before the actual "switch", we stop the tracing when the recorded task is about to schedule in. This may change if we add a new marker at the end of the scheduler. Notice that the recorded task is 'sleep' with the PID of 2389 and it has an rt_prio of 5. This priority is user-space priority and not the internal kernel priority. The policy is 1 for SCHED_FIFO and 2 for SCHED_RR. Note, that the trace data shows the internal priority (99 - rtprio). -0 3d..3 5us : 0:120:R ==> [003] 2389: 94:R sleep The 0:120:R means idle was running with a nice priority of 0 (120 - 20) and in the running state 'R'. The sleep task was scheduled in with 2389: 94:R. That is the priority is the kernel rtprio (99 - 5 = 94) and it too is in the running state. Doing the same with chrt -r 5 and function-trace set. echo 1 > options/function-trace # tracer: wakeup_rt # # wakeup_rt latency trace v1.1.5 on 3.8.0-test+ # -------------------------------------------------------------------- # latency: 29 us, #85/85, CPU#3 | (M:preempt VP:0, KP:0, SP:0 HP:0 #P:4) # ----------------- # | task: sleep-2448 (uid:0 nice:0 policy:1 rt_prio:5) # ----------------- # # _------=> CPU# # / _-----=> irqs-off # | / _----=> need-resched # || / _---=> hardirq/softirq # ||| / _--=> preempt-depth # |||| / delay # cmd pid ||||| time | caller # \ / ||||| \ | / -0 3d.h4 1us+: 0:120:R + [003] 2448: 94:R sleep -0 3d.h4 2us : ttwu_do_activate.constprop.87 <-try_to_wake_up -0 3d.h3 3us : check_preempt_curr <-ttwu_do_wakeup -0 3d.h3 3us : resched_task <-check_preempt_curr -0 3dNh3 4us : task_woken_rt <-ttwu_do_wakeup -0 3dNh3 4us : _raw_spin_unlock <-try_to_wake_up -0 3dNh3 4us : sub_preempt_count <-_raw_spin_unlock -0 3dNh2 5us : ttwu_stat <-try_to_wake_up -0 3dNh2 5us : _raw_spin_unlock_irqrestore <-try_to_wake_up -0 3dNh2 6us : sub_preempt_count <-_raw_spin_unlock_irqrestore -0 3dNh1 6us : _raw_spin_lock <-__run_hrtimer -0 3dNh1 6us : add_preempt_count <-_raw_spin_lock -0 3dNh2 7us : _raw_spin_unlock <-hrtimer_interrupt -0 3dNh2 7us : sub_preempt_count <-_raw_spin_unlock -0 3dNh1 7us : tick_program_event <-hrtimer_interrupt -0 3dNh1 7us : clockevents_program_event <-tick_program_event -0 3dNh1 8us : ktime_get <-clockevents_program_event -0 3dNh1 8us : lapic_next_event <-clockevents_program_event -0 3dNh1 8us : irq_exit <-smp_apic_timer_interrupt -0 3dNh1 9us : sub_preempt_count <-irq_exit -0 3dN.2 9us : idle_cpu <-irq_exit -0 3dN.2 9us : rcu_irq_exit <-irq_exit -0 3dN.2 10us : rcu_eqs_enter_common.isra.45 <-rcu_irq_exit -0 3dN.2 10us : sub_preempt_count <-irq_exit -0 3.N.1 11us : rcu_idle_exit <-cpu_idle -0 3dN.1 11us : rcu_eqs_exit_common.isra.43 <-rcu_idle_exit -0 3.N.1 11us : tick_nohz_idle_exit <-cpu_idle -0 3dN.1 12us : menu_hrtimer_cancel <-tick_nohz_idle_exit -0 3dN.1 12us : ktime_get <-tick_nohz_idle_exit -0 3dN.1 12us : tick_do_update_jiffies64 <-tick_nohz_idle_exit -0 3dN.1 13us : update_cpu_load_nohz <-tick_nohz_idle_exit -0 3dN.1 13us : _raw_spin_lock <-update_cpu_load_nohz -0 3dN.1 13us : add_preempt_count <-_raw_spin_lock -0 3dN.2 13us : __update_cpu_load <-update_cpu_load_nohz -0 3dN.2 14us : sched_avg_update <-__update_cpu_load -0 3dN.2 14us : _raw_spin_unlock <-update_cpu_load_nohz -0 3dN.2 14us : sub_preempt_count <-_raw_spin_unlock -0 3dN.1 15us : calc_load_exit_idle <-tick_nohz_idle_exit -0 3dN.1 15us : touch_softlockup_watchdog <-tick_nohz_idle_exit -0 3dN.1 15us : hrtimer_cancel <-tick_nohz_idle_exit -0 3dN.1 15us : hrtimer_try_to_cancel <-hrtimer_cancel -0 3dN.1 16us : lock_hrtimer_base.isra.18 <-hrtimer_try_to_cancel -0 3dN.1 16us : _raw_spin_lock_irqsave <-lock_hrtimer_base.isra.18 -0 3dN.1 16us : add_preempt_count <-_raw_spin_lock_irqsave -0 3dN.2 17us : __remove_hrtimer <-remove_hrtimer.part.16 -0 3dN.2 17us : hrtimer_force_reprogram <-__remove_hrtimer -0 3dN.2 17us : tick_program_event <-hrtimer_force_reprogram -0 3dN.2 18us : clockevents_program_event <-tick_program_event -0 3dN.2 18us : ktime_get <-clockevents_program_event -0 3dN.2 18us : lapic_next_event <-clockevents_program_event -0 3dN.2 19us : _raw_spin_unlock_irqrestore <-hrtimer_try_to_cancel -0 3dN.2 19us : sub_preempt_count <-_raw_spin_unlock_irqrestore -0 3dN.1 19us : hrtimer_forward <-tick_nohz_idle_exit -0 3dN.1 20us : ktime_add_safe <-hrtimer_forward -0 3dN.1 20us : ktime_add_safe <-hrtimer_forward -0 3dN.1 20us : hrtimer_start_range_ns <-hrtimer_start_expires.constprop.11 -0 3dN.1 20us : __hrtimer_start_range_ns <-hrtimer_start_range_ns -0 3dN.1 21us : lock_hrtimer_base.isra.18 <-__hrtimer_start_range_ns -0 3dN.1 21us : _raw_spin_lock_irqsave <-lock_hrtimer_base.isra.18 -0 3dN.1 21us : add_preempt_count <-_raw_spin_lock_irqsave -0 3dN.2 22us : ktime_add_safe <-__hrtimer_start_range_ns -0 3dN.2 22us : enqueue_hrtimer <-__hrtimer_start_range_ns -0 3dN.2 22us : tick_program_event <-__hrtimer_start_range_ns -0 3dN.2 23us : clockevents_program_event <-tick_program_event -0 3dN.2 23us : ktime_get <-clockevents_program_event -0 3dN.2 23us : lapic_next_event <-clockevents_program_event -0 3dN.2 24us : _raw_spin_unlock_irqrestore <-__hrtimer_start_range_ns -0 3dN.2 24us : sub_preempt_count <-_raw_spin_unlock_irqrestore -0 3dN.1 24us : account_idle_ticks <-tick_nohz_idle_exit -0 3dN.1 24us : account_idle_time <-account_idle_ticks -0 3.N.1 25us : sub_preempt_count <-cpu_idle -0 3.N.. 25us : schedule <-cpu_idle -0 3.N.. 25us : __schedule <-preempt_schedule -0 3.N.. 26us : add_preempt_count <-__schedule -0 3.N.1 26us : rcu_note_context_switch <-__schedule -0 3.N.1 26us : rcu_sched_qs <-rcu_note_context_switch -0 3dN.1 27us : rcu_preempt_qs <-rcu_note_context_switch -0 3.N.1 27us : _raw_spin_lock_irq <-__schedule -0 3dN.1 27us : add_preempt_count <-_raw_spin_lock_irq -0 3dN.2 28us : put_prev_task_idle <-__schedule -0 3dN.2 28us : pick_next_task_stop <-pick_next_task -0 3dN.2 28us : pick_next_task_rt <-pick_next_task -0 3dN.2 29us : dequeue_pushable_task <-pick_next_task_rt -0 3d..3 29us : __schedule <-preempt_schedule -0 3d..3 30us : 0:120:R ==> [003] 2448: 94:R sleep This isn't that big of a trace, even with function tracing enabled, so I included the entire trace. The interrupt went off while when the system was idle. Somewhere before task_woken_rt() was called, the NEED_RESCHED flag was set, this is indicated by the first occurrence of the 'N' flag. Latency tracing and events -------------------------- As function tracing can induce a much larger latency, but without seeing what happens within the latency it is hard to know what caused it. There is a middle ground, and that is with enabling events. # echo 0 > options/function-trace # echo wakeup_rt > current_tracer # echo 1 > events/enable # echo 1 > tracing_on # echo 0 > tracing_max_latency # chrt -f 5 sleep 1 # echo 0 > tracing_on # cat trace # tracer: wakeup_rt # # wakeup_rt latency trace v1.1.5 on 3.8.0-test+ # -------------------------------------------------------------------- # latency: 6 us, #12/12, CPU#2 | (M:preempt VP:0, KP:0, SP:0 HP:0 #P:4) # ----------------- # | task: sleep-5882 (uid:0 nice:0 policy:1 rt_prio:5) # ----------------- # # _------=> CPU# # / _-----=> irqs-off # | / _----=> need-resched # || / _---=> hardirq/softirq # ||| / _--=> preempt-depth # |||| / delay # cmd pid ||||| time | caller # \ / ||||| \ | / -0 2d.h4 0us : 0:120:R + [002] 5882: 94:R sleep -0 2d.h4 0us : ttwu_do_activate.constprop.87 <-try_to_wake_up -0 2d.h4 1us : sched_wakeup: comm=sleep pid=5882 prio=94 success=1 target_cpu=002 -0 2dNh2 1us : hrtimer_expire_exit: hrtimer=ffff88007796feb8 -0 2.N.2 2us : power_end: cpu_id=2 -0 2.N.2 3us : cpu_idle: state=4294967295 cpu_id=2 -0 2dN.3 4us : hrtimer_cancel: hrtimer=ffff88007d50d5e0 -0 2dN.3 4us : hrtimer_start: hrtimer=ffff88007d50d5e0 function=tick_sched_timer expires=34311211000000 softexpires=34311211000000 -0 2.N.2 5us : rcu_utilization: Start context switch -0 2.N.2 5us : rcu_utilization: End context switch -0 2d..3 6us : __schedule <-schedule -0 2d..3 6us : 0:120:R ==> [002] 5882: 94:R sleep function -------- This tracer is the function tracer. Enabling the function tracer can be done from the debug file system. Make sure the ftrace_enabled is set; otherwise this tracer is a nop. See the "ftrace_enabled" section below. # sysctl kernel.ftrace_enabled=1 # echo function > current_tracer # echo 1 > tracing_on # usleep 1 # echo 0 > tracing_on # cat trace # tracer: function # # entries-in-buffer/entries-written: 24799/24799 #P:4 # # _-----=> irqs-off # / _----=> need-resched # | / _---=> hardirq/softirq # || / _--=> preempt-depth # ||| / delay # TASK-PID CPU# |||| TIMESTAMP FUNCTION # | | | |||| | | bash-1994 [002] .... 3082.063030: mutex_unlock <-rb_simple_write bash-1994 [002] .... 3082.063031: __mutex_unlock_slowpath <-mutex_unlock bash-1994 [002] .... 3082.063031: __fsnotify_parent <-fsnotify_modify bash-1994 [002] .... 3082.063032: fsnotify <-fsnotify_modify bash-1994 [002] .... 3082.063032: __srcu_read_lock <-fsnotify bash-1994 [002] .... 3082.063032: add_preempt_count <-__srcu_read_lock bash-1994 [002] ...1 3082.063032: sub_preempt_count <-__srcu_read_lock bash-1994 [002] .... 3082.063033: __srcu_read_unlock <-fsnotify [...] Note: function tracer uses ring buffers to store the above entries. The newest data may overwrite the oldest data. Sometimes using echo to stop the trace is not sufficient because the tracing could have overwritten the data that you wanted to record. For this reason, it is sometimes better to disable tracing directly from a program. This allows you to stop the tracing at the point that you hit the part that you are interested in. To disable the tracing directly from a C program, something like following code snippet can be used: int trace_fd; [...] int main(int argc, char *argv[]) { [...] trace_fd = open(tracing_file("tracing_on"), O_WRONLY); [...] if (condition_hit()) { write(trace_fd, "0", 1); } [...] } Single thread tracing --------------------- By writing into set_ftrace_pid you can trace a single thread. For example: # cat set_ftrace_pid no pid # echo 3111 > set_ftrace_pid # cat set_ftrace_pid 3111 # echo function > current_tracer # cat trace | head # tracer: function # # TASK-PID CPU# TIMESTAMP FUNCTION # | | | | | yum-updatesd-3111 [003] 1637.254676: finish_task_switch <-thread_return yum-updatesd-3111 [003] 1637.254681: hrtimer_cancel <-schedule_hrtimeout_range yum-updatesd-3111 [003] 1637.254682: hrtimer_try_to_cancel <-hrtimer_cancel yum-updatesd-3111 [003] 1637.254683: lock_hrtimer_base <-hrtimer_try_to_cancel yum-updatesd-3111 [003] 1637.254685: fget_light <-do_sys_poll yum-updatesd-3111 [003] 1637.254686: pipe_poll <-do_sys_poll # echo -1 > set_ftrace_pid # cat trace |head # tracer: function # # TASK-PID CPU# TIMESTAMP FUNCTION # | | | | | ##### CPU 3 buffer started #### yum-updatesd-3111 [003] 1701.957688: free_poll_entry <-poll_freewait yum-updatesd-3111 [003] 1701.957689: remove_wait_queue <-free_poll_entry yum-updatesd-3111 [003] 1701.957691: fput <-free_poll_entry yum-updatesd-3111 [003] 1701.957692: audit_syscall_exit <-sysret_audit yum-updatesd-3111 [003] 1701.957693: path_put <-audit_syscall_exit If you want to trace a function when executing, you could use something like this simple program: #include #include #include #include #include #include #include #define _STR(x) #x #define STR(x) _STR(x) #define MAX_PATH 256 const char *find_debugfs(void) { static char debugfs[MAX_PATH+1]; static int debugfs_found; char type[100]; FILE *fp; if (debugfs_found) return debugfs; if ((fp = fopen("/proc/mounts","r")) == NULL) { perror("/proc/mounts"); return NULL; } while (fscanf(fp, "%*s %" STR(MAX_PATH) "s %99s %*s %*d %*d\n", debugfs, type) == 2) { if (strcmp(type, "debugfs") == 0) break; } fclose(fp); if (strcmp(type, "debugfs") != 0) { fprintf(stderr, "debugfs not mounted"); return NULL; } strcat(debugfs, "/tracing/"); debugfs_found = 1; return debugfs; } const char *tracing_file(const char *file_name) { static char trace_file[MAX_PATH+1]; snprintf(trace_file, MAX_PATH, "%s/%s", find_debugfs(), file_name); return trace_file; } int main (int argc, char **argv) { if (argc < 1) exit(-1); if (fork() > 0) { int fd, ffd; char line[64]; int s; ffd = open(tracing_file("current_tracer"), O_WRONLY); if (ffd < 0) exit(-1); write(ffd, "nop", 3); fd = open(tracing_file("set_ftrace_pid"), O_WRONLY); s = sprintf(line, "%d\n", getpid()); write(fd, line, s); write(ffd, "function", 8); close(fd); close(ffd); execvp(argv[1], argv+1); } return 0; } Or this simple script! ------ #!/bin/bash debugfs=`sed -ne 's/^debugfs \(.*\) debugfs.*/\1/p' /proc/mounts` echo nop > $debugfs/tracing/current_tracer echo 0 > $debugfs/tracing/tracing_on echo $$ > $debugfs/tracing/set_ftrace_pid echo function > $debugfs/tracing/current_tracer echo 1 > $debugfs/tracing/tracing_on exec "$@" ------ function graph tracer --------------------------- This tracer is similar to the function tracer except that it probes a function on its entry and its exit. This is done by using a dynamically allocated stack of return addresses in each task_struct. On function entry the tracer overwrites the return address of each function traced to set a custom probe. Thus the original return address is stored on the stack of return address in the task_struct. Probing on both ends of a function leads to special features such as: - measure of a function's time execution - having a reliable call stack to draw function calls graph This tracer is useful in several situations: - you want to find the reason of a strange kernel behavior and need to see what happens in detail on any areas (or specific ones). - you are experiencing weird latencies but it's difficult to find its origin. - you want to find quickly which path is taken by a specific function - you just want to peek inside a working kernel and want to see what happens there. # tracer: function_graph # # CPU DURATION FUNCTION CALLS # | | | | | | | 0) | sys_open() { 0) | do_sys_open() { 0) | getname() { 0) | kmem_cache_alloc() { 0) 1.382 us | __might_sleep(); 0) 2.478 us | } 0) | strncpy_from_user() { 0) | might_fault() { 0) 1.389 us | __might_sleep(); 0) 2.553 us | } 0) 3.807 us | } 0) 7.876 us | } 0) | alloc_fd() { 0) 0.668 us | _spin_lock(); 0) 0.570 us | expand_files(); 0) 0.586 us | _spin_unlock(); There are several columns that can be dynamically enabled/disabled. You can use every combination of options you want, depending on your needs. - The cpu number on which the function executed is default enabled. It is sometimes better to only trace one cpu (see tracing_cpu_mask file) or you might sometimes see unordered function calls while cpu tracing switch. hide: echo nofuncgraph-cpu > trace_options show: echo funcgraph-cpu > trace_options - The duration (function's time of execution) is displayed on the closing bracket line of a function or on the same line than the current function in case of a leaf one. It is default enabled. hide: echo nofuncgraph-duration > trace_options show: echo funcgraph-duration > trace_options - The overhead field precedes the duration field in case of reached duration thresholds. hide: echo nofuncgraph-overhead > trace_options show: echo funcgraph-overhead > trace_options depends on: funcgraph-duration ie: 0) | up_write() { 0) 0.646 us | _spin_lock_irqsave(); 0) 0.684 us | _spin_unlock_irqrestore(); 0) 3.123 us | } 0) 0.548 us | fput(); 0) + 58.628 us | } [...] 0) | putname() { 0) | kmem_cache_free() { 0) 0.518 us | __phys_addr(); 0) 1.757 us | } 0) 2.861 us | } 0) ! 115.305 us | } 0) ! 116.402 us | } + means that the function exceeded 10 usecs. ! means that the function exceeded 100 usecs. - The task/pid field displays the thread cmdline and pid which executed the function. It is default disabled. hide: echo nofuncgraph-proc > trace_options show: echo funcgraph-proc > trace_options ie: # tracer: function_graph # # CPU TASK/PID DURATION FUNCTION CALLS # | | | | | | | | | 0) sh-4802 | | d_free() { 0) sh-4802 | | call_rcu() { 0) sh-4802 | | __call_rcu() { 0) sh-4802 | 0.616 us | rcu_process_gp_end(); 0) sh-4802 | 0.586 us | check_for_new_grace_period(); 0) sh-4802 | 2.899 us | } 0) sh-4802 | 4.040 us | } 0) sh-4802 | 5.151 us | } 0) sh-4802 | + 49.370 us | } - The absolute time field is an absolute timestamp given by the system clock since it started. A snapshot of this time is given on each entry/exit of functions hide: echo nofuncgraph-abstime > trace_options show: echo funcgraph-abstime > trace_options ie: # # TIME CPU DURATION FUNCTION CALLS # | | | | | | | | 360.774522 | 1) 0.541 us | } 360.774522 | 1) 4.663 us | } 360.774523 | 1) 0.541 us | __wake_up_bit(); 360.774524 | 1) 6.796 us | } 360.774524 | 1) 7.952 us | } 360.774525 | 1) 9.063 us | } 360.774525 | 1) 0.615 us | journal_mark_dirty(); 360.774527 | 1) 0.578 us | __brelse(); 360.774528 | 1) | reiserfs_prepare_for_journal() { 360.774528 | 1) | unlock_buffer() { 360.774529 | 1) | wake_up_bit() { 360.774529 | 1) | bit_waitqueue() { 360.774530 | 1) 0.594 us | __phys_addr(); You can put some comments on specific functions by using trace_printk() For example, if you want to put a comment inside the __might_sleep() function, you just have to include and call trace_printk() inside __might_sleep() trace_printk("I'm a comment!\n") will produce: 1) | __might_sleep() { 1) | /* I'm a comment! */ 1) 1.449 us | } You might find other useful features for this tracer in the following "dynamic ftrace" section such as tracing only specific functions or tasks. dynamic ftrace -------------- If CONFIG_DYNAMIC_FTRACE is set, the system will run with virtually no overhead when function tracing is disabled. The way this works is the mcount function call (placed at the start of every kernel function, produced by the -pg switch in gcc), starts of pointing to a simple return. (Enabling FTRACE will include the -pg switch in the compiling of the kernel.) At compile time every C file object is run through the recordmcount program (located in the scripts directory). This program will parse the ELF headers in the C object to find all the locations in the .text section that call mcount. (Note, only white listed .text sections are processed, since processing other sections like .init.text may cause races due to those sections being freed unexpectedly). A new section called "__mcount_loc" is created that holds references to all the mcount call sites in the .text section. The recordmcount program re-links this section back into the original object. The final linking stage of the kernel will add all these references into a single table. On boot up, before SMP is initialized, the dynamic ftrace code scans this table and updates all the locations into nops. It also records the locations, which are added to the available_filter_functions list. Modules are processed as they are loaded and before they are executed. When a module is unloaded, it also removes its functions from the ftrace function list. This is automatic in the module unload code, and the module author does not need to worry about it. When tracing is enabled, the process of modifying the function tracepoints is dependent on architecture. The old method is to use kstop_machine to prevent races with the CPUs executing code being modified (which can cause the CPU to do undesirable things, especially if the modified code crosses cache (or page) boundaries), and the nops are patched back to calls. But this time, they do not call mcount (which is just a function stub). They now call into the ftrace infrastructure. The new method of modifying the function tracepoints is to place a breakpoint at the location to be modified, sync all CPUs, modify the rest of the instruction not covered by the breakpoint. Sync all CPUs again, and then remove the breakpoint with the finished version to the ftrace call site. Some archs do not even need to monkey around with the synchronization, and can just slap the new code on top of the old without any problems with other CPUs executing it at the same time. One special side-effect to the recording of the functions being traced is that we can now selectively choose which functions we wish to trace and which ones we want the mcount calls to remain as nops. Two files are used, one for enabling and one for disabling the tracing of specified functions. They are: set_ftrace_filter and set_ftrace_notrace A list of available functions that you can add to these files is listed in: available_filter_functions # cat available_filter_functions put_prev_task_idle kmem_cache_create pick_next_task_rt get_online_cpus pick_next_task_fair mutex_lock [...] If I am only interested in sys_nanosleep and hrtimer_interrupt: # echo sys_nanosleep hrtimer_interrupt > set_ftrace_filter # echo function > current_tracer # echo 1 > tracing_on # usleep 1 # echo 0 > tracing_on # cat trace # tracer: function # # entries-in-buffer/entries-written: 5/5 #P:4 # # _-----=> irqs-off # / _----=> need-resched # | / _---=> hardirq/softirq # || / _--=> preempt-depth # ||| / delay # TASK-PID CPU# |||| TIMESTAMP FUNCTION # | | | |||| | | usleep-2665 [001] .... 4186.475355: sys_nanosleep <-system_call_fastpath -0 [001] d.h1 4186.475409: hrtimer_interrupt <-smp_apic_timer_interrupt usleep-2665 [001] d.h1 4186.475426: hrtimer_interrupt <-smp_apic_timer_interrupt -0 [003] d.h1 4186.475426: hrtimer_interrupt <-smp_apic_timer_interrupt -0 [002] d.h1 4186.475427: hrtimer_interrupt <-smp_apic_timer_interrupt To see which functions are being traced, you can cat the file: # cat set_ftrace_filter hrtimer_interrupt sys_nanosleep Perhaps this is not enough. The filters also allow simple wild cards. Only the following are currently available * - will match functions that begin with * - will match functions that end with ** - will match functions that have in it These are the only wild cards which are supported. * will not work. Note: It is better to use quotes to enclose the wild cards, otherwise the shell may expand the parameters into names of files in the local directory. # echo 'hrtimer_*' > set_ftrace_filter Produces: # tracer: function # # entries-in-buffer/entries-written: 897/897 #P:4 # # _-----=> irqs-off # / _----=> need-resched # | / _---=> hardirq/softirq # || / _--=> preempt-depth # ||| / delay # TASK-PID CPU# |||| TIMESTAMP FUNCTION # | | | |||| | | -0 [003] dN.1 4228.547803: hrtimer_cancel <-tick_nohz_idle_exit -0 [003] dN.1 4228.547804: hrtimer_try_to_cancel <-hrtimer_cancel -0 [003] dN.2 4228.547805: hrtimer_force_reprogram <-__remove_hrtimer -0 [003] dN.1 4228.547805: hrtimer_forward <-tick_nohz_idle_exit -0 [003] dN.1 4228.547805: hrtimer_start_range_ns <-hrtimer_start_expires.constprop.11 -0 [003] d..1 4228.547858: hrtimer_get_next_event <-get_next_timer_interrupt -0 [003] d..1 4228.547859: hrtimer_start <-__tick_nohz_idle_enter -0 [003] d..2 4228.547860: hrtimer_force_reprogram <-__rem Notice that we lost the sys_nanosleep. # cat set_ftrace_filter hrtimer_run_queues hrtimer_run_pending hrtimer_init hrtimer_cancel hrtimer_try_to_cancel hrtimer_forward hrtimer_start hrtimer_reprogram hrtimer_force_reprogram hrtimer_get_next_event hrtimer_interrupt hrtimer_nanosleep hrtimer_wakeup hrtimer_get_remaining hrtimer_get_res hrtimer_init_sleeper This is because the '>' and '>>' act just like they do in bash. To rewrite the filters, use '>' To append to the filters, use '>>' To clear out a filter so that all functions will be recorded again: # echo > set_ftrace_filter # cat set_ftrace_filter # Again, now we want to append. # echo sys_nanosleep > set_ftrace_filter # cat set_ftrace_filter sys_nanosleep # echo 'hrtimer_*' >> set_ftrace_filter # cat set_ftrace_filter hrtimer_run_queues hrtimer_run_pending hrtimer_init hrtimer_cancel hrtimer_try_to_cancel hrtimer_forward hrtimer_start hrtimer_reprogram hrtimer_force_reprogram hrtimer_get_next_event hrtimer_interrupt sys_nanosleep hrtimer_nanosleep hrtimer_wakeup hrtimer_get_remaining hrtimer_get_res hrtimer_init_sleeper The set_ftrace_notrace prevents those functions from being traced. # echo '*preempt*' '*lock*' > set_ftrace_notrace Produces: # tracer: function # # entries-in-buffer/entries-written: 39608/39608 #P:4 # # _-----=> irqs-off # / _----=> need-resched # | / _---=> hardirq/softirq # || / _--=> preempt-depth # ||| / delay # TASK-PID CPU# |||| TIMESTAMP FUNCTION # | | | |||| | | bash-1994 [000] .... 4342.324896: file_ra_state_init <-do_dentry_open bash-1994 [000] .... 4342.324897: open_check_o_direct <-do_last bash-1994 [000] .... 4342.324897: ima_file_check <-do_last bash-1994 [000] .... 4342.324898: process_measurement <-ima_file_check bash-1994 [000] .... 4342.324898: ima_get_action <-process_measurement bash-1994 [000] .... 4342.324898: ima_match_policy <-ima_get_action bash-1994 [000] .... 4342.324899: do_truncate <-do_last bash-1994 [000] .... 4342.324899: should_remove_suid <-do_truncate bash-1994 [000] .... 4342.324899: notify_change <-do_truncate bash-1994 [000] .... 4342.324900: current_fs_time <-notify_change bash-1994 [000] .... 4342.324900: current_kernel_time <-current_fs_time bash-1994 [000] .... 4342.324900: timespec_trunc <-current_fs_time We can see that there's no more lock or preempt tracing. Dynamic ftrace with the function graph tracer --------------------------------------------- Although what has been explained above concerns both the function tracer and the function-graph-tracer, there are some special features only available in the function-graph tracer. If you want to trace only one function and all of its children, you just have to echo its name into set_graph_function: echo __do_fault > set_graph_function will produce the following "expanded" trace of the __do_fault() function: 0) | __do_fault() { 0) | filemap_fault() { 0) | find_lock_page() { 0) 0.804 us | find_get_page(); 0) | __might_sleep() { 0) 1.329 us | } 0) 3.904 us | } 0) 4.979 us | } 0) 0.653 us | _spin_lock(); 0) 0.578 us | page_add_file_rmap(); 0) 0.525 us | native_set_pte_at(); 0) 0.585 us | _spin_unlock(); 0) | unlock_page() { 0) 0.541 us | page_waitqueue(); 0) 0.639 us | __wake_up_bit(); 0) 2.786 us | } 0) + 14.237 us | } 0) | __do_fault() { 0) | filemap_fault() { 0) | find_lock_page() { 0) 0.698 us | find_get_page(); 0) | __might_sleep() { 0) 1.412 us | } 0) 3.950 us | } 0) 5.098 us | } 0) 0.631 us | _spin_lock(); 0) 0.571 us | page_add_file_rmap(); 0) 0.526 us | native_set_pte_at(); 0) 0.586 us | _spin_unlock(); 0) | unlock_page() { 0) 0.533 us | page_waitqueue(); 0) 0.638 us | __wake_up_bit(); 0) 2.793 us | } 0) + 14.012 us | } You can also expand several functions at once: echo sys_open > set_graph_function echo sys_close >> set_graph_function Now if you want to go back to trace all functions you can clear this special filter via: echo > set_graph_function ftrace_enabled -------------- Note, the proc sysctl ftrace_enable is a big on/off switch for the function tracer. By default it is enabled (when function tracing is enabled in the kernel). If it is disabled, all function tracing is disabled. This includes not only the function tracers for ftrace, but also for any other uses (perf, kprobes, stack tracing, profiling, etc). Please disable this with care. This can be disable (and enabled) with: sysctl kernel.ftrace_enabled=0 sysctl kernel.ftrace_enabled=1 or echo 0 > /proc/sys/kernel/ftrace_enabled echo 1 > /proc/sys/kernel/ftrace_enabled Filter commands --------------- A few commands are supported by the set_ftrace_filter interface. Trace commands have the following format: :: The following commands are supported: - mod This command enables function filtering per module. The parameter defines the module. For example, if only the write* functions in the ext3 module are desired, run: echo 'write*:mod:ext3' > set_ftrace_filter This command interacts with the filter in the same way as filtering based on function names. Thus, adding more functions in a different module is accomplished by appending (>>) to the filter file. Remove specific module functions by prepending '!': echo '!writeback*:mod:ext3' >> set_ftrace_filter - traceon/traceoff These commands turn tracing on and off when the specified functions are hit. The parameter determines how many times the tracing system is turned on and off. If unspecified, there is no limit. For example, to disable tracing when a schedule bug is hit the first 5 times, run: echo '__schedule_bug:traceoff:5' > set_ftrace_filter To always disable tracing when __schedule_bug is hit: echo '__schedule_bug:traceoff' > set_ftrace_filter These commands are cumulative whether or not they are appended to set_ftrace_filter. To remove a command, prepend it by '!' and drop the parameter: echo '!__schedule_bug:traceoff:0' > set_ftrace_filter The above removes the traceoff command for __schedule_bug that have a counter. To remove commands without counters: echo '!__schedule_bug:traceoff' > set_ftrace_filter - snapshot Will cause a snapshot to be triggered when the function is hit. echo 'native_flush_tlb_others:snapshot' > set_ftrace_filter To only snapshot once: echo 'native_flush_tlb_others:snapshot:1' > set_ftrace_filter To remove the above commands: echo '!native_flush_tlb_others:snapshot' > set_ftrace_filter echo '!native_flush_tlb_others:snapshot:0' > set_ftrace_filter - enable_event/disable_event These commands can enable or disable a trace event. Note, because function tracing callbacks are very sensitive, when these commands are registered, the trace point is activated, but disabled in a "soft" mode. That is, the tracepoint will be called, but just will not be traced. The event tracepoint stays in this mode as long as there's a command that triggers it. echo 'try_to_wake_up:enable_event:sched:sched_switch:2' > \ set_ftrace_filter The format is: :enable_event::[:count] :disable_event::[:count] To remove the events commands: echo '!try_to_wake_up:enable_event:sched:sched_switch:0' > \ set_ftrace_filter echo '!schedule:disable_event:sched:sched_switch' > \ set_ftrace_filter - dump When the function is hit, it will dump the contents of the ftrace ring buffer to the console. This is useful if you need to debug something, and want to dump the trace when a certain function is hit. Perhaps its a function that is called before a tripple fault happens and does not allow you to get a regular dump. trace_pipe ---------- The trace_pipe outputs the same content as the trace file, but the effect on the tracing is different. Every read from trace_pipe is consumed. This means that subsequent reads will be different. The trace is live. # echo function > current_tracer # cat trace_pipe > /tmp/trace.out & [1] 4153 # echo 1 > tracing_on # usleep 1 # echo 0 > tracing_on # cat trace # tracer: function # # entries-in-buffer/entries-written: 0/0 #P:4 # # _-----=> irqs-off # / _----=> need-resched # | / _---=> hardirq/softirq # || / _--=> preempt-depth # ||| / delay # TASK-PID CPU# |||| TIMESTAMP FUNCTION # | | | |||| | | # # cat /tmp/trace.out bash-1994 [000] .... 5281.568961: mutex_unlock <-rb_simple_write bash-1994 [000] .... 5281.568963: __mutex_unlock_slowpath <-mutex_unlock bash-1994 [000] .... 5281.568963: __fsnotify_parent <-fsnotify_modify bash-1994 [000] .... 5281.568964: fsnotify <-fsnotify_modify bash-1994 [000] .... 5281.568964: __srcu_read_lock <-fsnotify bash-1994 [000] .... 5281.568964: add_preempt_count <-__srcu_read_lock bash-1994 [000] ...1 5281.568965: sub_preempt_count <-__srcu_read_lock bash-1994 [000] .... 5281.568965: __srcu_read_unlock <-fsnotify bash-1994 [000] .... 5281.568967: sys_dup2 <-system_call_fastpath Note, reading the trace_pipe file will block until more input is added. trace entries ------------- Having too much or not enough data can be troublesome in diagnosing an issue in the kernel. The file buffer_size_kb is used to modify the size of the internal trace buffers. The number listed is the number of entries that can be recorded per CPU. To know the full size, multiply the number of possible CPUs with the number of entries. # cat buffer_size_kb 1408 (units kilobytes) Or simply read buffer_total_size_kb # cat buffer_total_size_kb 5632 To modify the buffer, simple echo in a number (in 1024 byte segments). # echo 10000 > buffer_size_kb # cat buffer_size_kb 10000 (units kilobytes) It will try to allocate as much as possible. If you allocate too much, it can cause Out-Of-Memory to trigger. # echo 1000000000000 > buffer_size_kb -bash: echo: write error: Cannot allocate memory # cat buffer_size_kb 85 The per_cpu buffers can be changed individually as well: # echo 10000 > per_cpu/cpu0/buffer_size_kb # echo 100 > per_cpu/cpu1/buffer_size_kb When the per_cpu buffers are not the same, the buffer_size_kb at the top level will just show an X # cat buffer_size_kb X This is where the buffer_total_size_kb is useful: # cat buffer_total_size_kb 12916 Writing to the top level buffer_size_kb will reset all the buffers to be the same again. Snapshot -------- CONFIG_TRACER_SNAPSHOT makes a generic snapshot feature available to all non latency tracers. (Latency tracers which record max latency, such as "irqsoff" or "wakeup", can't use this feature, since those are already using the snapshot mechanism internally.) Snapshot preserves a current trace buffer at a particular point in time without stopping tracing. Ftrace swaps the current buffer with a spare buffer, and tracing continues in the new current (=previous spare) buffer. The following debugfs files in "tracing" are related to this feature: snapshot: This is used to take a snapshot and to read the output of the snapshot. Echo 1 into this file to allocate a spare buffer and to take a snapshot (swap), then read the snapshot from this file in the same format as "trace" (described above in the section "The File System"). Both reads snapshot and tracing are executable in parallel. When the spare buffer is allocated, echoing 0 frees it, and echoing else (positive) values clear the snapshot contents. More details are shown in the table below. status\input | 0 | 1 | else | --------------+------------+------------+------------+ not allocated |(do nothing)| alloc+swap |(do nothing)| --------------+------------+------------+------------+ allocated | free | swap | clear | --------------+------------+------------+------------+ Here is an example of using the snapshot feature. # echo 1 > events/sched/enable # echo 1 > snapshot # cat snapshot # tracer: nop # # entries-in-buffer/entries-written: 71/71 #P:8 # # _-----=> irqs-off # / _----=> need-resched # | / _---=> hardirq/softirq # || / _--=> preempt-depth # ||| / delay # TASK-PID CPU# |||| TIMESTAMP FUNCTION # | | | |||| | | -0 [005] d... 2440.603828: sched_switch: prev_comm=swapper/5 prev_pid=0 prev_prio=120 prev_state=R ==> next_comm=snapshot-test-2 next_pid=2242 next_prio=120 sleep-2242 [005] d... 2440.603846: sched_switch: prev_comm=snapshot-test-2 prev_pid=2242 prev_prio=120 prev_state=R ==> next_comm=kworker/5:1 next_pid=60 next_prio=120 [...] -0 [002] d... 2440.707230: sched_switch: prev_comm=swapper/2 prev_pid=0 prev_prio=120 prev_state=R ==> next_comm=snapshot-test-2 next_pid=2229 next_prio=120 # cat trace # tracer: nop # # entries-in-buffer/entries-written: 77/77 #P:8 # # _-----=> irqs-off # / _----=> need-resched # | / _---=> hardirq/softirq # || / _--=> preempt-depth # ||| / delay # TASK-PID CPU# |||| TIMESTAMP FUNCTION # | | | |||| | | -0 [007] d... 2440.707395: sched_switch: prev_comm=swapper/7 prev_pid=0 prev_prio=120 prev_state=R ==> next_comm=snapshot-test-2 next_pid=2243 next_prio=120 snapshot-test-2-2229 [002] d... 2440.707438: sched_switch: prev_comm=snapshot-test-2 prev_pid=2229 prev_prio=120 prev_state=S ==> next_comm=swapper/2 next_pid=0 next_prio=120 [...] If you try to use this snapshot feature when current tracer is one of the latency tracers, you will get the following results. # echo wakeup > current_tracer # echo 1 > snapshot bash: echo: write error: Device or resource busy # cat snapshot cat: snapshot: Device or resource busy Instances --------- In the debugfs tracing directory is a directory called "instances". This directory can have new directories created inside of it using mkdir, and removing directories with rmdir. The directory created with mkdir in this directory will already contain files and other directories after it is created. # mkdir instances/foo # ls instances/foo buffer_size_kb buffer_total_size_kb events free_buffer per_cpu set_event snapshot trace trace_clock trace_marker trace_options trace_pipe tracing_on As you can see, the new directory looks similar to the tracing directory itself. In fact, it is very similar, except that the buffer and events are agnostic from the main director, or from any other instances that are created. The files in the new directory work just like the files with the same name in the tracing directory except the buffer that is used is a separate and new buffer. The files affect that buffer but do not affect the main buffer with the exception of trace_options. Currently, the trace_options affect all instances and the top level buffer the same, but this may change in future releases. That is, options may become specific to the instance they reside in. Notice that none of the function tracer files are there, nor is current_tracer and available_tracers. This is because the buffers can currently only have events enabled for them. # mkdir instances/foo # mkdir instances/bar # mkdir instances/zoot # echo 100000 > buffer_size_kb # echo 1000 > instances/foo/buffer_size_kb # echo 5000 > instances/bar/per_cpu/cpu1/buffer_size_kb # echo function > current_trace # echo 1 > instances/foo/events/sched/sched_wakeup/enable # echo 1 > instances/foo/events/sched/sched_wakeup_new/enable # echo 1 > instances/foo/events/sched/sched_switch/enable # echo 1 > instances/bar/events/irq/enable # echo 1 > instances/zoot/events/syscalls/enable # cat trace_pipe CPU:2 [LOST 11745 EVENTS] bash-2044 [002] .... 10594.481032: _raw_spin_lock_irqsave <-get_page_from_freelist bash-2044 [002] d... 10594.481032: add_preempt_count <-_raw_spin_lock_irqsave bash-2044 [002] d..1 10594.481032: __rmqueue <-get_page_from_freelist bash-2044 [002] d..1 10594.481033: _raw_spin_unlock <-get_page_from_freelist bash-2044 [002] d..1 10594.481033: sub_preempt_count <-_raw_spin_unlock bash-2044 [002] d... 10594.481033: get_pageblock_flags_group <-get_pageblock_migratetype bash-2044 [002] d... 10594.481034: __mod_zone_page_state <-get_page_from_freelist bash-2044 [002] d... 10594.481034: zone_statistics <-get_page_from_freelist bash-2044 [002] d... 10594.481034: __inc_zone_state <-zone_statistics bash-2044 [002] d... 10594.481034: __inc_zone_state <-zone_statistics bash-2044 [002] .... 10594.481035: arch_dup_task_struct <-copy_process [...] # cat instances/foo/trace_pipe bash-1998 [000] d..4 136.676759: sched_wakeup: comm=kworker/0:1 pid=59 prio=120 success=1 target_cpu=000 bash-1998 [000] dN.4 136.676760: sched_wakeup: comm=bash pid=1998 prio=120 success=1 target_cpu=000 -0 [003] d.h3 136.676906: sched_wakeup: comm=rcu_preempt pid=9 prio=120 success=1 target_cpu=003 -0 [003] d..3 136.676909: sched_switch: prev_comm=swapper/3 prev_pid=0 prev_prio=120 prev_state=R ==> next_comm=rcu_preempt next_pid=9 next_prio=120 rcu_preempt-9 [003] d..3 136.676916: sched_switch: prev_comm=rcu_preempt prev_pid=9 prev_prio=120 prev_state=S ==> next_comm=swapper/3 next_pid=0 next_prio=120 bash-1998 [000] d..4 136.677014: sched_wakeup: comm=kworker/0:1 pid=59 prio=120 success=1 target_cpu=000 bash-1998 [000] dN.4 136.677016: sched_wakeup: comm=bash pid=1998 prio=120 success=1 target_cpu=000 bash-1998 [000] d..3 136.677018: sched_switch: prev_comm=bash prev_pid=1998 prev_prio=120 prev_state=R+ ==> next_comm=kworker/0:1 next_pid=59 next_prio=120 kworker/0:1-59 [000] d..4 136.677022: sched_wakeup: comm=sshd pid=1995 prio=120 success=1 target_cpu=001 kworker/0:1-59 [000] d..3 136.677025: sched_switch: prev_comm=kworker/0:1 prev_pid=59 prev_prio=120 prev_state=S ==> next_comm=bash next_pid=1998 next_prio=120 [...] # cat instances/bar/trace_pipe migration/1-14 [001] d.h3 138.732674: softirq_raise: vec=3 [action=NET_RX] -0 [001] dNh3 138.732725: softirq_raise: vec=3 [action=NET_RX] bash-1998 [000] d.h1 138.733101: softirq_raise: vec=1 [action=TIMER] bash-1998 [000] d.h1 138.733102: softirq_raise: vec=9 [action=RCU] bash-1998 [000] ..s2 138.733105: softirq_entry: vec=1 [action=TIMER] bash-1998 [000] ..s2 138.733106: softirq_exit: vec=1 [action=TIMER] bash-1998 [000] ..s2 138.733106: softirq_entry: vec=9 [action=RCU] bash-1998 [000] ..s2 138.733109: softirq_exit: vec=9 [action=RCU] sshd-1995 [001] d.h1 138.733278: irq_handler_entry: irq=21 name=uhci_hcd:usb4 sshd-1995 [001] d.h1 138.733280: irq_handler_exit: irq=21 ret=unhandled sshd-1995 [001] d.h1 138.733281: irq_handler_entry: irq=21 name=eth0 sshd-1995 [001] d.h1 138.733283: irq_handler_exit: irq=21 ret=handled [...] # cat instances/zoot/trace # tracer: nop # # entries-in-buffer/entries-written: 18996/18996 #P:4 # # _-----=> irqs-off # / _----=> need-resched # | / _---=> hardirq/softirq # || / _--=> preempt-depth # ||| / delay # TASK-PID CPU# |||| TIMESTAMP FUNCTION # | | | |||| | | bash-1998 [000] d... 140.733501: sys_write -> 0x2 bash-1998 [000] d... 140.733504: sys_dup2(oldfd: a, newfd: 1) bash-1998 [000] d... 140.733506: sys_dup2 -> 0x1 bash-1998 [000] d... 140.733508: sys_fcntl(fd: a, cmd: 1, arg: 0) bash-1998 [000] d... 140.733509: sys_fcntl -> 0x1 bash-1998 [000] d... 140.733510: sys_close(fd: a) bash-1998 [000] d... 140.733510: sys_close -> 0x0 bash-1998 [000] d... 140.733514: sys_rt_sigprocmask(how: 0, nset: 0, oset: 6e2768, sigsetsize: 8) bash-1998 [000] d... 140.733515: sys_rt_sigprocmask -> 0x0 bash-1998 [000] d... 140.733516: sys_rt_sigaction(sig: 2, act: 7fff718846f0, oact: 7fff71884650, sigsetsize: 8) bash-1998 [000] d... 140.733516: sys_rt_sigaction -> 0x0 You can see that the trace of the top most trace buffer shows only the function tracing. The foo instance displays wakeups and task switches. To remove the instances, simply delete their directories: # rmdir instances/foo # rmdir instances/bar # rmdir instances/zoot Note, if a process has a trace file open in one of the instance directories, the rmdir will fail with EBUSY. Stack trace ----------- Since the kernel has a fixed sized stack, it is important not to waste it in functions. A kernel developer must be conscience of what they allocate on the stack. If they add too much, the system can be in danger of a stack overflow, and corruption will occur, usually leading to a system panic. There are some tools that check this, usually with interrupts periodically checking usage. But if you can perform a check at every function call that will become very useful. As ftrace provides a function tracer, it makes it convenient to check the stack size at every function call. This is enabled via the stack tracer. CONFIG_STACK_TRACER enables the ftrace stack tracing functionality. To enable it, write a '1' into /proc/sys/kernel/stack_tracer_enabled. # echo 1 > /proc/sys/kernel/stack_tracer_enabled You can also enable it from the kernel command line to trace the stack size of the kernel during boot up, by adding "stacktrace" to the kernel command line parameter. After running it for a few minutes, the output looks like: # cat stack_max_size 2928 # cat stack_trace Depth Size Location (18 entries) ----- ---- -------- 0) 2928 224 update_sd_lb_stats+0xbc/0x4ac 1) 2704 160 find_busiest_group+0x31/0x1f1 2) 2544 256 load_balance+0xd9/0x662 3) 2288 80 idle_balance+0xbb/0x130 4) 2208 128 __schedule+0x26e/0x5b9 5) 2080 16 schedule+0x64/0x66 6) 2064 128 schedule_timeout+0x34/0xe0 7) 1936 112 wait_for_common+0x97/0xf1 8) 1824 16 wait_for_completion+0x1d/0x1f 9) 1808 128 flush_work+0xfe/0x119 10) 1680 16 tty_flush_to_ldisc+0x1e/0x20 11) 1664 48 input_available_p+0x1d/0x5c 12) 1616 48 n_tty_poll+0x6d/0x134 13) 1568 64 tty_poll+0x64/0x7f 14) 1504 880 do_select+0x31e/0x511 15) 624 400 core_sys_select+0x177/0x216 16) 224 96 sys_select+0x91/0xb9 17) 128 128 system_call_fastpath+0x16/0x1b Note, if -mfentry is being used by gcc, functions get traced before they set up the stack frame. This means that leaf level functions are not tested by the stack tracer when -mfentry is used. Currently, -mfentry is used by gcc 4.6.0 and above on x86 only. --------- More details can be found in the source code, in the kernel/trace/*.c files.