ESP-IDF integrates tools for requesting :ref:`heap information <heap-information>`, :ref:`detecting heap corruption <heap-corruption>`, and :ref:`tracing memory leaks <heap-tracing>`. These can help track down memory-related bugs.
-:cpp:func:`xPortGetFreeHeapSize` is a FreeRTOS function which returns the number of free bytes in the (data memory) heap. This is equivalent to calling ``heap_caps_get_free_size(MALLOC_CAP_8BIT)``.
-:cpp:func:`heap_caps_get_free_size` can also be used to return the current free memory for different memory capabilities.
-:cpp:func:`heap_caps_get_largest_free_block` can be used to return the largest free block in the heap. This is the largest single allocation which is currently possible. Tracking this value and comparing to total free heap allows you to detect heap fragmentation.
-:cpp:func:`xPortGetMinimumEverFreeHeapSize` and the related :cpp:func:`heap_caps_get_minimum_free_size` can be used to track the heap "low water mark" since boot.
-:cpp:func:`heap_caps_get_info` returns a :cpp:class:`multi_heap_info_t` structure which contains the information from the above functions, plus some additional heap-specific data (number of allocations, etc.).
-:cpp:func:`heap_caps_print_heap_info` prints a summary to stdout of the information returned by :cpp:func:`heap_caps_get_info`.
-:cpp:func:`heap_caps_dump` and :cpp:func:`heap_caps_dump_all` will output detailed information about the structure of each block in the heap. Note that this can be large amount of output.
The heap implementation (``multi_heap.c``, etc.) includes a lot of assertions which will fail if the heap memory is corrupted. To detect heap corruption most effectively, ensure that assertions are enabled in the project configuration menu under ``Compiler options`` -> :ref:`CONFIG_COMPILER_OPTIMIZATION_ASSERTION_LEVEL`.
If a heap integrity assertion fails, a line will be printed like ``CORRUPT HEAP: multi_heap.c:225 detected at 0x3ffbb71c``. The memory address which is printed is the address of the heap structure which has corrupt content.
It's also possible to manually check heap integrity by calling :cpp:func:`heap_caps_check_integrity_all` or related functions. This function checks all of requested heap memory for integrity, and can be used even if assertions are disabled. If the integrity check prints an error, it will also contain the address(es) of corrupt heap structures.
Users can use :cpp:func:`heap_caps_register_failed_alloc_callback` to register a callback that will be invoked every time a allocation
operation fails.
Additionaly user can enable a generation of a system abort if allocation operation fails by following the steps below:
- In the project configuration menu, navigate to ``Component config`` -> ``Heap Memory Debugging`` and select ``Abort if memory allocation fails`` option (see :ref:`CONFIG_HEAP_ABORT_WHEN_ALLOCATION_FAILS`).
The example below show how to register a allocation failure callback::
Memory corruption can be one of the hardest classes of bugs to find and fix, as one area of memory can be corrupted from a totally different place. Some tips:
- A crash with a ``CORRUPT HEAP:`` message will usually include a stack trace, but this stack trace is rarely useful. The crash is the symptom of memory corruption when the system realises the heap is corrupt, but usually the corruption happened elsewhere and earlier in time.
- Increasing the Heap memory debugging `Configuration`_ level to "Light impact" or "Comprehensive" can give you a more accurate message with the first corrupt memory address.
- Adding regular calls to :cpp:func:`heap_caps_check_integrity_all` or :cpp:func:`heap_caps_check_integrity_addr` in your code will help you pin down the exact time that the corruption happened. You can move these checks around to "close in on" the section of code that corrupted the heap.
- Based on the memory address which is being corrupted, you can use :ref:`JTAG debugging <jtag-debugging-introduction>` to set a watchpoint on this address and have the CPU halt when it is written to.
- If you don't have JTAG, but you do know roughly when the corruption happens, then you can set a watchpoint in software just beforehand via :cpp:func:`esp_set_watchpoint`. A fatal exception will occur when the watchpoint triggers. For example ``esp_set_watchpoint(0, (void *)addr, 4, ESP_WATCHPOINT_STORE``. Note that watchpoints are per-CPU and are set on the current running CPU only, so if you don't know which CPU is corrupting memory then you will need to call this function on both CPUs.
- For buffer overflows, `heap tracing`_ in ``HEAP_TRACE_ALL`` mode lets you see which callers are allocating which addresses from the heap. See `Heap Tracing To Find Heap Corruption`_ for more details. If you can find the function which allocates memory with an address immediately before the address which is corrupted, this will probably be the function which overflows the buffer.
- Calling :cpp:func:`heap_caps_dump` or :cpp:func:`heap_caps_dump_all` can give an indication of what heap blocks are surrounding the corrupted region and may have overflowed/underflowed/etc.
In the project configuration menu, under ``Component config`` there is a menu ``Heap memory debugging``. The setting :ref:`CONFIG_HEAP_CORRUPTION_DETECTION` can be set to one of three levels:
This is the default level. No special heap corruption features are enabled, but provided assertions are enabled (the default configuration) then a heap corruption error will be printed if any of the heap's internal data structures appear overwritten or corrupted. This usually indicates a buffer overrun or out of bounds write.
Calling :cpp:func:`heap_caps_check_integrity` in Basic mode will check the integrity of all heap structures, and print errors if any appear to be corrupted.
At this level, heap memory is additionally "poisoned" with head and tail "canary bytes" before and after each block which is allocated. If an application writes outside the bounds of allocated buffers, the canary bytes will be corrupted and the integrity check will fail.
The head canary word is 0xABBA1234 (3412BAAB in byte order), and the tail canary word is 0xBAAD5678 (7856ADBA in byte order).
"Basic" heap corruption checks can also detect most out of bounds writes, but this setting is more precise as even a single byte overrun can be detected. With Basic heap checks, the number of overrun bytes before a failure is detected will depend on the properties of the heap.
Enabling "Light Impact" checking increases memory usage, each individual allocation will use 9 to 12 additional bytes of memory (depending on alignment).
When :cpp:func:`heap_caps_check_integrity` is called, all allocated blocks of heap memory have their canary bytes checked against the expected values.
In both cases, the check is that the first 4 bytes of an allocated block (before the buffer returned to the user) should be the word 0xABBA1234. Then the last 4 bytes of the allocated block (after the buffer returned to the user) should be the word 0xBAAD5678.
Different values usually indicate buffer underrun or overrun, respectively.
This level incorporates the "light impact" detection features plus additional checks for uninitialised-access and use-after-free bugs. In this mode, all freshly allocated memory is filled with the pattern 0xCE, and all freed memory is filled with the pattern 0xFE.
Enabling "Comprehensive" detection has a substantial runtime performance impact (as all memory needs to be set to the allocation patterns each time a malloc/free completes, and the memory also needs to be checked each time.) However it allows easier detection of memory corruption bugs which are much more subtle to find otherwise. It is recommended to only enable this mode when debugging, not in production.
Crashes in Comprehensive Mode
~~~~~~~~~~~~~~~~~~~~~~~~~~~~~
If an application crashes reading/writing an address related to 0xCECECECE in Comprehensive mode, this indicates it has read uninitialized memory. The application should be changed to either use calloc() (which zeroes memory), or initialize the memory before using it. The value 0xCECECECE may also be seen in stack-allocated automatic variables, because in IDF most task stacks are originally allocated from the heap and in C stack memory is uninitialized by default.
If an application crashes and the exception register dump indicates that some addresses or values were 0xFEFEFEFE, this indicates it is reading heap memory after it has been freed (a "use after free bug".) The application should be changed to not access heap memory after it has been freed.
If a call to malloc() or realloc() causes a crash because it expected to find the pattern 0xFEFEFEFE in free memory and a different pattern was found, then this indicates the app has a use-after-free bug where it is writing to memory which has already been freed.
Calls to :cpp:func:`heap_caps_check_integrity` may print errors relating to 0xFEFEFEFE, 0xABBA1234 or 0xBAAD5678. In each case the checker is expecting to find a given pattern, and will error out if this is not found:
- For free heap blocks, the checker expects to find all bytes set to 0xFE. Any other values indicate a use-after-free bug where free memory has been incorrectly overwritten.
- For allocated heap blocks, the behaviour is the same as for `Light Impact` mode. The canary bytes 0xABBA1234 and 0xBAAD5678 are checked at the head and tail of each allocated buffer, and any variation indicates a buffer overrun/underrun.
- Standalone. In this mode trace data are kept on-board, so the size of gathered information is limited by the buffer assigned for that purposes. Analysis is done by the on-board code. There are a couple of APIs available for accessing and dumping collected info.
- Host-based. This mode does not have the limitation of the standalone mode, because trace data are sent to the host over JTAG connection using app_trace library. Later on they can be analysed using special tools.
If you suspect a memory leak, the first step is to figure out which part of the program is leaking memory. Use the :cpp:func:`xPortGetFreeHeapSize`, :cpp:func:`heap_caps_get_free_size`, or :ref:`related functions <heap-information>` to track memory use over the life of the application. Try to narrow the leak down to a single function or sequence of functions where free memory always decreases and never recovers.
- In the project configuration menu, navigate to ``Component settings`` -> ``Heap Memory Debugging`` -> ``Heap tracing`` and select ``Standalone`` option (see :ref:`CONFIG_HEAP_TRACING_DEST`).
- Call the function :cpp:func:`heap_trace_init_standalone` early in the program, to register a buffer which can be used to record the memory trace.
- Call the function :cpp:func:`heap_trace_start` to begin recording all mallocs/frees in the system. Call this immediately before the piece of code which you suspect is leaking memory.
- Call the function :cpp:func:`heap_trace_stop` to stop the trace once the suspect piece of code has finished executing.
- Call the function :cpp:func:`heap_trace_dump` to dump the results of the heap trace.
(Above example output is using :doc:`IDF Monitor </api-guides/tools/idf-monitor>` to automatically decode PC addresses to their source files & line number.)
The depth of the call stack recorded for each trace entry can be configured in the project configuration menu, under ``Heap Memory Debugging`` -> ``Enable heap tracing`` -> ``Heap tracing stack depth``. Up to 10 stack frames can be recorded for each allocation (the default is 2). Each additional stack frame increases the memory usage of each ``heap_trace_record_t`` record by eight bytes.
Finally, the total number of 'leaked' bytes (bytes allocated but not freed while trace was running) is printed, and the total number of allocations this represents.
A warning will be printed if the trace buffer was not large enough to hold all the allocations which happened. If you see this warning, consider either shortening the tracing period or increasing the number of records in the trace buffer.
- In the project configuration menu, navigate to ``Component settings`` -> ``Heap Memory Debugging`` -> :ref:`CONFIG_HEAP_TRACING_DEST` and select ``Host-Based``.
- In the project configuration menu, navigate to ``Component settings`` -> ``Application Level Tracing`` -> :ref:`CONFIG_APPTRACE_DESTINATION` and select ``Trace memory``.
- Call the function :cpp:func:`heap_trace_init_tohost` early in the program, to initialize JTAG heap tracing module.
- Call the function :cpp:func:`heap_trace_start` to begin recording all mallocs/frees in the system. Call this immediately before the piece of code which you suspect is leaking memory.
In host-based mode argument to this function is ignored and heap tracing module behaves like ``HEAP_TRACE_ALL`` was passed: all allocations and deallocations are sent to the host.
- Call the function :cpp:func:`heap_trace_stop` to stop the trace once the suspect piece of code has finished executing.
2. Run OpenOCD (see :doc:`JTAG Debugging </api-guides/jtag-debugging/index>`).
..note::
In order to use this feature you need OpenOCD version `v0.10.0-esp32-20181105` or later.
3. You can use GDB to start and/or stop tracing automatically. To do this you need to prepare special ``gdbinit`` file::
target remote :3333
mon reset halt
flushregs
tb heap_trace_start
commands
mon esp32 sysview start file:///tmp/heap.svdat
c
end
tb heap_trace_stop
commands
mon esp32 sysview stop
end
c
Using this file GDB will connect to the target, reset it, and start tracing when program hits breakpoint at :cpp:func:`heap_trace_start`. Trace data will be saved to ``/tmp/heap_log.svdat``. Tracing will be stopped when program hits breakpoint at :cpp:func:`heap_trace_stop`.
Heap tracing can also be used to help track down heap corruption. When a region in heap is corrupted, it may be from some other part of the program which allocated memory at a nearby address.
If you have some idea at what time the corruption occurred, enabling heap tracing in ``HEAP_TRACE_ALL`` mode allows you to record all of the functions which allocated memory, and the addresses of the allocations.
Using heap tracing in this way is very similar to memory leak detection as described above. For memory which is allocated and not freed, the output is the same. However, records will also be shown for memory which has been freed.
Enabling heap tracing in menuconfig increases the code size of your program, and has a very small negative impact on performance of heap allocation/free operations even when heap tracing is not running.
When heap tracing is running, heap allocation/free operations are substantially slower than when heap tracing is stopped. Increasing the depth of stack frames recorded for each allocation (see above) will also increase this performance impact.
- Any memory which is allocated after :cpp:func:`heap_trace_start` but then freed after :cpp:func:`heap_trace_stop` will appear in the leak dump.
- Allocations may be made by other tasks in the system. Depending on the timing of these tasks, it's quite possible this memory is freed after :cpp:func:`heap_trace_stop` is called.
- The first time a task uses stdio - for example, when it calls ``printf()`` - a lock (RTOS mutex semaphore) is allocated by the libc. This allocation lasts until the task is deleted.
- Certain uses of ``printf()``, such as printing floating point numbers, will allocate some memory from the heap on demand. These allocations last until the task is deleted.
- The Bluetooth, WiFi, and TCP/IP libraries will allocate heap memory buffers to handle incoming or outgoing data. These memory buffers are usually short lived, but some may be shown in the heap leak trace if the data was received/transmitted by the lower levels of the network while the leak trace was running.
- TCP connections will continue to use some memory after they are closed, because of the ``TIME_WAIT`` state. After the ``TIME_WAIT`` period has completed, this memory will be freed.
One way to differentiate between "real" and "false positive" memory leaks is to call the suspect code multiple times while tracing is running, and look for patterns (multiple matching allocations) in the heap trace output.