| .. _tracing: |
| |
| Tracing |
| ####### |
| |
| Overview |
| ******** |
| |
| The tracing feature provides hooks that permits you to collect data from |
| your application and allows enabled backends to visualize the inner-working of |
| the kernel and various subsystems. |
| |
| Applications and tracing tools can create a backend that redefines the |
| macros declared in :zephyr_file:`include/debug/tracing.h` that are called |
| across the kernel in key spots. |
| |
| .. doxygengroup:: tracing_apis |
| :project: Zephyr |
| |
| SEGGER SystemView Support |
| ************************* |
| |
| Zephyr provides built-in support for `SEGGER SystemView`_ that can be enabled in |
| any application for platforms that have the required hardware support. |
| |
| To enable tracing support with `SEGGER SystemView`_ add the configuration option |
| :option:`CONFIG_SEGGER_SYSTEMVIEW` to your project configuration file and set |
| it to *y*. For example, this can be added to the |
| :ref:`synchronization_sample` to visualize fast switching between threads:: |
| |
| CONFIG_STDOUT_CONSOLE=y |
| # enable to use thread names |
| CONFIG_THREAD_NAME=y |
| CONFIG_SEGGER_SYSTEMVIEW=y |
| CONFIG_USE_SEGGER_RTT=y |
| |
| |
| .. figure:: segger_systemview.png |
| :align: center |
| :alt: SEGGER SystemView |
| :figclass: align-center |
| :width: 80% |
| |
| .. _SEGGER SystemView: https://www.segger.com/products/development-tools/systemview/ |
| |
| .. _ctf: |
| |
| Common Trace Format (CTF) Support |
| ********************************* |
| |
| Common Trace Format, CTF, is an open format and language to describe trace |
| formats. This enables tool reuse, of which line-textual (babeltrace) and |
| graphical (TraceCompass) variants already exist. |
| |
| CTF should look familiar to C programmers but adds stronger typing. |
| See `CTF - A Flexible, High-performance Binary Trace Format |
| <http://diamon.org/ctf/>`_. |
| |
| Every system has application-specific events to trace out. Historically, |
| that has implied: |
| |
| 1. Determining the application-specific payload, |
| 2. Choosing suitable serialization-format, |
| 3. Writing the on-target serialization code, |
| 4. Deciding on and writing the I/O transport mechanics, |
| 5. Writing the PC-side deserializer/parser, |
| 6. Writing custom ad-hoc tools for filtering and presentation. |
| |
| CTF allows us to formally describe #1 and #2, which enables common |
| infrastructure for #5 and #6. This leaves #3 serialization code and #4 |
| I/O mechanics up to a custom implementation. |
| |
| This CTF debug module aims at providing a common #1 and #2 for Zephyr |
| ("top"), while providing a lean & generic interface for I/O ("bottom"). |
| Currently, only one CTF bottom-layer exists, POSIX ``fwrite``, but many others |
| are possible: |
| |
| - Async UART |
| - Async DMA |
| - Sync GPIO |
| - ... and many more. |
| |
| In fact, I/O varies greatly from system to system. Therefore, it is |
| instructive to create a taxonomy for I/O types when we must ensure the |
| interface between CTF-top and CTF-bottom is generic and efficient |
| enough to model these. See the *I/O taxonomy* section below. |
| |
| |
| A Generic Interface |
| ==================== |
| |
| In CTF, an event is serialized to a packet containing one or more fields. |
| As seen from *I/O taxonomy* section below, a bottom layer may: |
| |
| - perform actions at transaction-start (e.g. mutex-lock), |
| - process each field in some way (e.g. sync-push emit, concat, enqueue to |
| thread-bound FIFO), |
| - perform actions at transaction-stop (e.g. mutex-release, emit of concat |
| buffer). |
| |
| The bottom-layer then needs to implement the following macros: |
| |
| - ``CTF_BOTTOM_LOCK``: No-op or how to lock the I/O transaction |
| - ``CTF_BOTTOM_UNLOCK``: No-op or how to release the I/O transaction |
| - ``CTF_BOTTOM_FIELDS``: Var-args of fields. May process each field with ``MAP`` |
| - ``CTF_BOTTOM_TIMESTAMPED_INTERNALLY``: Tells where timestamping is done |
| |
| These macros along with inline functions of the top-layer can yield a |
| very low-overhead tracing infrastructure. |
| |
| |
| CTF Top-Layer Example |
| ========================= |
| |
| The CTF_EVENT macro will serialize each argument to a field:: |
| |
| /* Example for illustration */ |
| static inline void ctf_top_foo(u32_t thread_id, ctf_bounded_string_t name) |
| { |
| CTF_EVENT( |
| CTF_LITERAL(u8_t, 42), |
| thread_id, |
| name, |
| "hello, I was emitted from function: ", |
| __func__ /* __func__ is standard since C99 */ |
| ); |
| } |
| |
| How to serialize and emit fields as well as handling alignment, can be done |
| internally and statically at compile-time in the bottom-layer. |
| |
| |
| How to Activate? |
| ================ |
| |
| Make sure :option:`CONFIG_TRACING_CTF` is set to ``y`` (:option:`CONFIG_TRACING_CTF_BOTTOM_POSIX` |
| is selected by default when using ``BOARD_NATIVE_POSIX``). |
| |
| |
| How to Use? |
| =========== |
| |
| The resulting CTF output can be visualized using babeltrace or TraceCompass: |
| |
| - The CTF output file can be specified in native posix using the ``-ctf-path`` |
| command line option |
| |
| - Create a new empty directory and copy into it: |
| |
| - The TSDL file (``subsys/debug/tracing/ctf/tsdl/metadata``) |
| |
| - The CTF output file renaming it to ``channel0_0`` |
| |
| - The trace can be opened by pointing TraceCompass or babeltrace to this new |
| directory |
| |
| |
| What is TraceCompass? |
| ===================== |
| |
| TraceCompass is an open source tool that visualizes CTF events such as thread |
| scheduling and interrupts, and is helpful to find unintended interactions and |
| resource conflicts on complex systems. |
| |
| See also the presentation by Ericsson, |
| `Advanced Trouble-shooting Of Real-time Systems |
| <https://wiki.eclipse.org/images/0/0e/TechTalkOnlineDemoFeb2017_v1.pdf>`_. |
| |
| |
| Future LTTng Inspiration |
| ======================== |
| |
| Currently, the top-layer provided here is quite simple and bare-bones, |
| and needlessly copied from Zephyr's Segger SystemView debug module. |
| |
| For an OS like Zephyr, it would make sense to draw inspiration from |
| Linux's LTTng and change the top-layer to serialize to the same format. |
| Doing this would enable direct reuse of TraceCompass' canned analyses |
| for Linux. Alternatively, LTTng-analyses in TraceCompass could be |
| customized to Zephyr. It is ongoing work to enable TraceCompass |
| visibility of Zephyr in a target-agnostic and open source way. |
| |
| |
| I/O Taxonomy |
| ============= |
| |
| - Atomic Push/Produce/Write/Enqueue: |
| |
| - synchronous: |
| means data-transmission has completed with the return of the |
| call. |
| |
| - asynchronous: |
| means data-transmission is pending or ongoing with the return |
| of the call. Usually, interrupts/callbacks/signals or polling |
| is used to determine completion. |
| |
| - buffered: |
| means data-transmissions are copied and grouped together to |
| form a larger ones. Usually for amortizing overhead (burst |
| dequeue) or jitter-mitigation (steady dequeue). |
| |
| Examples: |
| - sync unbuffered |
| E.g. PIO via GPIOs having steady stream, no extra FIFO memory needed. |
| Low jitter but may be less efficient (cant amortize the overhead of |
| writing). |
| |
| - sync buffered |
| E.g. ``fwrite()`` or enqueuing into FIFO. |
| Blockingly burst the FIFO when its buffer-waterlevel exceeds threshold. |
| Jitter due to bursts may lead to missed deadlines. |
| |
| - async unbuffered |
| E.g. DMA, or zero-copying in shared memory. |
| Be careful of data hazards, race conditions, etc! |
| |
| - async buffered |
| E.g. enqueuing into FIFO. |
| |
| |
| |
| - Atomic Pull/Consume/Read/Dequeue: |
| |
| - synchronous: |
| means data-reception has completed with the return of the call. |
| |
| - asynchronous: |
| means data-reception is pending or ongoing with the return of |
| the call. Usually, interrupts/callbacks/signals or polling is |
| used to determine completion. |
| |
| - buffered: |
| means data is copied-in in larger chunks than request-size. |
| Usually for amortizing wait-time. |
| |
| Examples: |
| - sync unbuffered |
| E.g. Blocking read-call, ``fread()`` or SPI-read, zero-copying in shared |
| memory. |
| |
| - sync buffered |
| E.g. Blocking read-call with caching applied. |
| Makes sense if read pattern exhibits spatial locality. |
| |
| - async unbuffered |
| E.g. zero-copying in shared memory. |
| Be careful of data hazards, race conditions, etc! |
| |
| - async buffered |
| E.g. ``aio_read()`` or DMA. |
| |
| |
| |
| Unfortunately, I/O may not be atomic and may, therefore, require locking. |
| Locking may not be needed if multiple independent channels are available. |
| |
| - The system has non-atomic write and one shared channel |
| E.g. UART. Locking required. |
| |
| ``lock(); emit(a); emit(b); emit(c); release();`` |
| |
| - The system has non-atomic write but many channels |
| E.g. Multi-UART. Lock-free if the bottom-layer maps each Zephyr |
| thread+ISR to its own channel, thus alleviating races as each |
| thread is sequentially consistent with itself. |
| |
| ``emit(a,thread_id); emit(b,thread_id); emit(c,thread_id);`` |
| |
| - The system has atomic write but one shared channel |
| E.g. ``native_posix`` or board with DMA. May or may not need locking. |
| |
| ``emit(a ## b ## c); /* Concat to buffer */`` |
| |
| ``lock(); emit(a); emit(b); emit(c); release(); /* No extra mem */`` |
| |
| - The system has atomic write and many channels |
| E.g. native_posix or board with multi-channel DMA. Lock-free. |
| |
| ``emit(a ## b ## c, thread_id);`` |
| |
| |
| |