Blog posts for tags/c

  1. C heap introspection in psutil

    Memory leaks in Python are often straightforward to diagnose. Just look at RSS, track Python object counts, follow reference graphs. But leaks inside C extension modules are another story. Traditional memory metrics such as RSS and VMS frequently fail to reveal them because Python's memory allocator sits above the platform's native heap (see pymalloc). If something in an extension calls malloc() without a corresponding free(), that memory often won't show up where you expect it. You have a leak, and you don't know.

    psutil 7.2.0 introduces two new APIs for C heap introspection, designed specifically to catch these kinds of native leaks. They give you a window directly into the underlying platform allocator (e.g. glibc's malloc), letting you track how much memory the C layer is actually consuming.

    These C functions bypass Python entirely. They don't reflect Python object memory, arenas, pools, or anything managed by pymalloc. Instead, they examine the allocator that C extensions actually use. If your RSS is flat but your C heap usage climbs, you now have a way to see it.

    Why native heap introspection matters

    Many Python projects rely on C extensions: psutil, NumPy, pandas, PIL, cryptography, lxml, psycopg, PyTorch, custom in-house modules, etc. And even cPython itself, which implements many of its standard library modules in C. If any of these components mishandle memory at the C level, you get a leak that:

    • Doesn't show up in Python reference counts (sys.getrefcount).
    • Doesn't show up in tracemalloc module.
    • Doesn't show up in Python's gc stats.
    • Often don't show up RSS, VMS or USS due to allocator caching, especially for small objects. This can happen, for example, when you forget to Py_DECREF a Python object.

    psutil's new functions solve this by inspecting platform-native allocator state, in a manner similar to Valgrind.

    heap_info(): direct allocator statistics

    heap_info() exposes the following metrics:

    • heap_used: total number of bytes currently allocated via malloc() (small allocations).
    • mmap_used: total number of bytes currently allocated via mmap() or via large malloc() allocations.
    • heap_count: (Windows only) number of private heaps created via HeapCreate().

    Example:

    >>> import psutil
>>> psutil.heap_info()
pheap(heap_used=5177792, mmap_used=819200)

    Reference for what contributes to each field:

    Platform Allocation type Field affected
    UNIX / Windows small malloc() ≤128 KB without free() heap_used
    UNIX / Windows large malloc() >128 KB without free(), or mmap() without munmap() (UNIX) mmap_used
    Windows HeapAlloc() without HeapFree() heap_used
    Windows VirtualAlloc() without VirtualFree() mmap_used
    Windows HeapCreate() without HeapDestroy() heap_count

    heap_trim(): returning unused heap memory

    heap_trim() provides a cross-platform way to request that the underlying allocator free any unused memory it's holding in the heap (typically small malloc() allocations).

    In practice, modern allocators rarely comply, so this is not a general-purpose memory-reduction tool and won't meaningfully shrink RSS in real programs. Its primary value is in leak detection tools.

    Calling heap_trim() before taking measurements helps reduce allocator noise, giving you a cleaner baseline so that changes in heap_used come from the code you're testing, not from internal allocator caching or fragmentation.

    Real-world use: finding a C extension leak

    The workflow is simple:

    1. Take a baseline snapshot of the heap.
    2. Call the C extension hundreds of times.
    3. Take another snapshot.
    4. Compare.
    import psutil

psutil.heap_trim()  # reduce noise

before = psutil.heap_info()
for _ in range(200):
    my_cext_function()
after = psutil.heap_info()

print("delta heap_used =", after.heap_used - before.heap_used)
print("delta mmap_used =", after.mmap_used - before.mmap_used)

    If heap_used or mmap_used values increase consistently, you've found a native leak.

    To reduce false positives, repeat the test multiple times, increasing the number of calls on each retry. This approach helps distinguish real leaks from random noise or transient allocations.

    A new tool: psleak

    The strategy described above is exactly what I implemented in a new PyPI package, which I called psleak. It runs the target function repeatedly, trims the allocator before each run, and tracks differences across retries. Memory that grows consistently after several runs is flagged as a leak.

    A minimal test suite looks like this:

      from psleak import MemoryLeakTestCase

  class TestLeaks(MemoryLeakTestCase):
      def test_fun(self):
          self.execute(some_c_function)

    If the C function leaks memory, the test will fail with a descriptive exception:

    psleak.MemoryLeakError: memory kept increasing after 10 runs
Run # 1: heap=+388160  | uss=+356352  | rss=+327680  | (calls= 200, avg/call=+1940)
Run # 2: heap=+584848  | uss=+614400  | rss=+491520  | (calls= 300, avg/call=+1949)
Run # 3: heap=+778320  | uss=+782336  | rss=+819200  | (calls= 400, avg/call=+1945)
Run # 4: heap=+970512  | uss=+1032192 | rss=+1146880 | (calls= 500, avg/call=+1941)
Run # 5: heap=+1169024 | uss=+1171456 | rss=+1146880 | (calls= 600, avg/call=+1948)
Run # 6: heap=+1357360 | uss=+1413120 | rss=+1310720 | (calls= 700, avg/call=+1939)
Run # 7: heap=+1552336 | uss=+1634304 | rss=+1638400 | (calls= 800, avg/call=+1940)
Run # 8: heap=+1752032 | uss=+1781760 | rss=+1802240 | (calls= 900, avg/call=+1946)
Run # 9: heap=+1945056 | uss=+2031616 | rss=+2129920 | (calls=1000, avg/call=+1945)
Run #10: heap=+2140624 | uss=+2179072 | rss=+2293760 | (calls=1100, avg/call=+1946)

    Psleak is now part of the psutil test suite, to make sure that the C code does not leak memory. All psutil APIs are tested (see test_memleaks.py), making it a de facto regression-testing tool.

    It's worth noting that without inspecting heap metrics, missing calls such as Py_CLEAR and Py_DECREF often go unnoticed, because they don't affect RSS, VMS, and USS. Something I confirmed from experimenting by commenting them out. Monitoring the heap is therefore essential to reliably detect memory leaks in Python C extensions.

    Under the hood

    For those interested in seeing how I did this in terms of code:

    • Linux: uses glibc's mallinfo2() to report uordblks (heap allocations) and hblkhd (mmap-backed blocks).
    • Windows: enumerates heaps and aggregates HeapAlloc / VirtualAlloc usage.
    • macOS: uses malloc zone statistics.
    • BSD: uses jemalloc's arena and stats interfaces.

    Summary

    psutil 7.2.0 fills a long-standing observability gap: native-level memory leaks in C extensions are now visible directly from Python. You now have a simple method to test C extensions for leaks. This turns psutil into not just a monitoring library, but a practical debugging tool for Python projects that rely on native C extension modules.

    References

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