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readme.md |
mimalloc
mimalloc (pronounced "me-malloc") is a general purpose allocator with excellent performance characteristics. Initially developed by Daan Leijen for the run-time systems of the Koka and Lean languages.
It is a drop-in replacement for malloc
and can be used in other programs
without code changes, for example, on dynamically linked ELF-based systems (Linux, BSD, etc.) you can use it as:
> LD_PRELOAD=/usr/bin/libmimalloc.so myprogram
Notable aspects of the design include:
- small and consistent: the library is about 6k LOC using simple and consistent data structures. This makes it very suitable to integrate and adapt in other projects. For runtime systems it provides hooks for a monotonic heartbeat and deferred freeing (for bounded worst-case times with reference counting).
- free list sharding: the big idea: instead of one big free list (per size class) we have many smaller lists per memory "page" which both reduces fragmentation and increases locality -- things that are allocated close in time get allocated close in memory. (A memory "page" in mimalloc contains blocks of one size class and is usually 64KiB on a 64-bit system).
- eager page reset: when a "page" becomes empty (with increased chance due to free list sharding) the memory is marked to the OS as unused ("reset" or "purged") reducing (real) memory pressure and fragmentation, especially in long running programs.
- secure: mimalloc can be built in secure mode, adding guard pages, randomized allocation, encrypted free lists, etc. to protect against various heap vulnerabilities. The performance penalty is usually around 10% on average over our benchmarks.
- first-class heaps: efficiently create and use multiple heaps to allocate across different regions. A heap can be destroyed at once instead of deallocating each object separately.
- bounded: it does not suffer from blowup [1], has bounded worst-case allocation times (wcat), bounded space overhead (~0.2% meta-data, with at most 12.5% waste in allocation sizes), and has no internal points of contention using only atomic operations.
- fast: In our benchmarks (see below), mimalloc always outperforms all other leading allocators (jemalloc, tcmalloc, Hoard, etc), and usually uses less memory (up to 25% more in the worst case). A nice property is that it does consistently well over a wide range of benchmarks.
The documentation gives a full overview of the API. You can read more on the design of mimalloc in the technical report which also has detailed benchmark results.
Enjoy!
Releases
- 2020-01-15,
v1.3.0
: stable release 1.3: bug fixes, improved randomness and stronger free list encoding in secure mode. - 2019-12-22,
v1.2.2
: stable release 1.2: minor updates. - 2019-11-22,
v1.2.0
: stable release 1.2: bug fixes, improved secure mode (free list corruption checks, double free mitigation). Improved dynamic overriding on Windows. - 2019-10-07,
v1.1.0
: stable release 1.1. - 2019-09-01,
v1.0.8
: pre-release 8: more robust windows dynamic overriding, initial huge page support. - 2019-08-10,
v1.0.6
: pre-release 6: various performance improvements.
Building
Windows
Open ide/vs2019/mimalloc.sln
in Visual Studio 2019 and build (or ide/vs2017/mimalloc.sln
).
The mimalloc
project builds a static library (in out/msvc-x64
), while the
mimalloc-override
project builds a DLL for overriding malloc
in the entire program.
macOS, Linux, BSD, etc.
We use cmake
1 as the build system:
> mkdir -p out/release
> cd out/release
> cmake ../..
> make
This builds the library as a shared (dynamic)
library (.so
or .dylib
), a static library (.a
), and
as a single object file (.o
).
> sudo make install
(install the library and header files in /usr/local/lib
and /usr/local/include
)
You can build the debug version which does many internal checks and maintains detailed statistics as:
> mkdir -p out/debug
> cd out/debug
> cmake -DCMAKE_BUILD_TYPE=Debug ../..
> make
This will name the shared library as libmimalloc-debug.so
.
Finally, you can build a secure version that uses guard pages, encrypted free lists, etc., as:
> mkdir -p out/secure
> cd out/secure
> cmake -DMI_SECURE=ON ../..
> make
This will name the shared library as libmimalloc-secure.so
.
Use ccmake
2 instead of cmake
to see and customize all the available build options.
Notes:
- Install CMake:
sudo apt-get install cmake
- Install CCMake:
sudo apt-get install cmake-curses-gui
Using the library
The preferred usage is including <mimalloc.h>
, linking with
the shared- or static library, and using the mi_malloc
API exclusively for allocation. For example,
> gcc -o myprogram -lmimalloc myfile.c
mimalloc uses only safe OS calls (mmap
and VirtualAlloc
) and can co-exist
with other allocators linked to the same program.
If you use cmake
, you can simply use:
find_package(mimalloc 1.0 REQUIRED)
in your CMakeLists.txt
to find a locally installed mimalloc. Then use either:
target_link_libraries(myapp PUBLIC mimalloc)
to link with the shared (dynamic) library, or:
target_link_libraries(myapp PUBLIC mimalloc-static)
to link with the static library. See test\CMakeLists.txt
for an example.
For best performance in C++ programs, it is also recommended to override the
global new
and delete
operators. For convience, mimalloc provides
mimalloc-new-delete.h which does this for you -- just include it in a single(!) source file in your project.
You can pass environment variables to print verbose messages (MIMALLOC_VERBOSE=1
)
and statistics (MIMALLOC_SHOW_STATS=1
) (in the debug version):
> env MIMALLOC_SHOW_STATS=1 ./cfrac 175451865205073170563711388363
175451865205073170563711388363 = 374456281610909315237213 * 468551
heap stats: peak total freed unit
normal 2: 16.4 kb 17.5 mb 17.5 mb 16 b ok
normal 3: 16.3 kb 15.2 mb 15.2 mb 24 b ok
normal 4: 64 b 4.6 kb 4.6 kb 32 b ok
normal 5: 80 b 118.4 kb 118.4 kb 40 b ok
normal 6: 48 b 48 b 48 b 48 b ok
normal 17: 960 b 960 b 960 b 320 b ok
heap stats: peak total freed unit
normal: 33.9 kb 32.8 mb 32.8 mb 1 b ok
huge: 0 b 0 b 0 b 1 b ok
total: 33.9 kb 32.8 mb 32.8 mb 1 b ok
malloc requested: 32.8 mb
committed: 58.2 kb 58.2 kb 58.2 kb 1 b ok
reserved: 2.0 mb 2.0 mb 2.0 mb 1 b ok
reset: 0 b 0 b 0 b 1 b ok
segments: 1 1 1
-abandoned: 0
pages: 6 6 6
-abandoned: 0
mmaps: 3
mmap fast: 0
mmap slow: 1
threads: 0
elapsed: 2.022s
process: user: 1.781s, system: 0.016s, faults: 756, reclaims: 0, rss: 2.7 mb
The above model of using the mi_
prefixed API is not always possible
though in existing programs that already use the standard malloc interface,
and another option is to override the standard malloc interface
completely and redirect all calls to the mimalloc library instead.
Environment Options
You can set further options either programmatically (using mi_option_set
),
or via environment variables.
MIMALLOC_SHOW_STATS=1
: show statistics when the program terminates.MIMALLOC_VERBOSE=1
: show verbose messages.MIMALLOC_SHOW_ERRORS=1
: show error and warning messages.MIMALLOC_LARGE_OS_PAGES=1
: use large OS pages when available; for some workloads this can significantly improve performance. UseMIMALLOC_VERBOSE
to check if the large OS pages are enabled -- usually one needs to explicitly allow large OS pages (as on Windows and Linux). However, sometimes the OS is very slow to reserve contiguous physical memory for large OS pages so use with care on systems that can have fragmented memory.MIMALLOC_EAGER_REGION_COMMIT=1
: on Windows, commit large (256MiB) regions eagerly. On Windows, these regions show in the working set even though usually just a small part is committed to physical memory. This is why it turned off by default on Windows as it looks not good in the task manager. However, in reality it is always better to turn it on as it improves performance and has no other drawbacks.MIMALLOC_RESERVE_HUGE_OS_PAGES=N
: where N is the number of 1GiB huge OS pages. This reserves the huge pages at startup and can give quite a performance improvement on long running workloads. Usually it is better to not useMIMALLOC_LARGE_OS_PAGES
in combination with this setting. Just like large OS pages, use with care as reserving contiguous physical memory can take a long time when memory is fragmented. Still experimental.
Overriding Malloc
Overriding the standard malloc
can be done either dynamically or statically.
Dynamic override
This is the recommended way to override the standard malloc interface.
Linux, BSD
On these ELF-based systems we preload the mimalloc shared
library so all calls to the standard malloc
interface are
resolved to the mimalloc library.
> env LD_PRELOAD=/usr/lib/libmimalloc.so myprogram
You can set extra environment variables to check that mimalloc is running, like:
> env MIMALLOC_VERBOSE=1 LD_PRELOAD=/usr/lib/libmimalloc.so myprogram
or run with the debug version to get detailed statistics:
> env MIMALLOC_SHOW_STATS=1 LD_PRELOAD=/usr/lib/libmimalloc-debug.so myprogram
MacOS
On macOS we can also preload the mimalloc shared
library so all calls to the standard malloc
interface are
resolved to the mimalloc library.
> env DYLD_FORCE_FLAT_NAMESPACE=1 DYLD_INSERT_LIBRARIES=/usr/lib/libmimalloc.dylib myprogram
Note that certain security restrictions may apply when doing this from the shell.
Note: unfortunately, at this time, dynamic overriding on macOS seems broken but it is actively worked on to fix this
(see issue #50
).
Windows
On Windows you need to link your program explicitly with the mimalloc
DLL and use the C-runtime library as a DLL (using the /MD
or /MDd
switch).
Moreover, you need to ensure the mimalloc-redirect.dll
(or mimalloc-redirect32.dll
) is available
in the same folder as the main mimalloc-override.dll
at runtime (as it is a dependency).
The redirection DLL ensures that all calls to the C runtime malloc API get redirected to
mimalloc (in mimalloc-override.dll
).
To ensure the mimalloc DLL is loaded at run-time it is easiest to insert some
call to the mimalloc API in the main
function, like mi_version()
(or use the /INCLUDE:mi_version
switch on the linker). See the mimalloc-override-test
project
for an example on how to use this. For best performance on Windows with C++, it
is highly recommended to also override the new
/delete
operations (as described
in the introduction).
The environment variable MIMALLOC_DISABLE_REDIRECT=1
can be used to disable dynamic
overriding at run-time. Use MIMALLOC_VERBOSE=1
to check if mimalloc was successfully redirected.
(Note: in principle, it is possible to patch existing executables
that are linked with the dynamic C runtime (ucrtbase.dll
) by just putting the mimalloc-override.dll
into the import table (and putting mimalloc-redirect.dll
in the same folder)
Such patching can be done for example with CFF Explorer).
Static override
On Unix-like systems, you can also statically link with mimalloc to override the standard
malloc interface. The recommended way is to link the final program with the
mimalloc single object file (mimalloc-override.o
). We use
an object file instead of a library file as linkers give preference to
that over archives to resolve symbols. To ensure that the standard
malloc interface resolves to the mimalloc library, link it as the first
object file. For example:
> gcc -o myprogram mimalloc-override.o myfile1.c ...
Another way to override statically that works on all platforms, is to
link statically to mimalloc (as shown in the introduction) and include a
header file in each source file that re-defines malloc
etc. to mi_malloc
.
This is provided by mimalloc-override.h
. This only works reliably though if all sources are
under your control or otherwise mixing of pointers from different heaps may occur!
Performance
We tested mimalloc against many other top allocators over a wide range of benchmarks, ranging from various real world programs to synthetic benchmarks that see how the allocator behaves under more extreme circumstances.
In our benchmarks, mimalloc always outperforms all other leading allocators (jemalloc, tcmalloc, Hoard, etc), and usually uses less memory (up to 25% more in the worst case). A nice property is that it does consistently well over the wide range of benchmarks.
Allocators are interesting as there exists no algorithm that is generally optimal -- for a given allocator one can usually construct a workload where it does not do so well. The goal is thus to find an allocation strategy that performs well over a wide range of benchmarks without suffering from underperformance in less common situations (which is what the second half of our benchmark set tests for).
We show here only the results on an AMD EPYC system (Apr 2019) -- for specific details and further benchmarks we refer to the technical report.
The benchmark suite is scripted and available separately as mimalloc-bench.
Benchmark Results
Testing on a big Amazon EC2 instance (r5a.4xlarge) consisting of a 16-core AMD EPYC 7000 at 2.5GHz with 128GB ECC memory, running Ubuntu 18.04.1 with LibC 2.27 and GCC 7.3.0. The measured allocators are mimalloc (mi), Google's tcmalloc (tc) used in Chrome, jemalloc (je) by Jason Evans used in Firefox and FreeBSD, snmalloc (sn) by Liétar et al. [8], rpmalloc (rp) by Mattias Jansson at Rampant Pixels, Hoard by Emery Berger [1], the system allocator (glibc) (based on PtMalloc2), and the Intel thread building blocks allocator (tbb).
Memory usage:
(note: the xmalloc-testN memory usage should be disregarded as it allocates more the faster the program runs).
In the first five benchmarks we can see mimalloc outperforms the other allocators moderately, but we also see that all these modern allocators perform well -- the times of large performance differences in regular workloads are over :-). In cfrac and espresso, mimalloc is a tad faster than tcmalloc and jemalloc, but a solid 10% faster than all other allocators on espresso. The tbb allocator does not do so well here and lags more than 20% behind mimalloc. The cfrac and espresso programs do not use much memory (~1.5MB) so it does not matter too much, but still mimalloc uses about half the resident memory of tcmalloc.
The leanN program is most interesting as a large realistic and concurrent workload of the Lean theorem prover compiling its own standard library, and there is a 8% speedup over tcmalloc. This is quite significant: if Lean spends 20% of its time in the allocator that means that mimalloc is 1.3× faster than tcmalloc here. (This is surprising as that is not measured in a pure allocation benchmark like alloc-test. We conjecture that we see this outsized improvement here because mimalloc has better locality in the allocation which improves performance for the other computations in a program as well).
The redis benchmark shows more differences between the allocators where mimalloc is 14% faster than jemalloc. On this benchmark tbb (and Hoard) do not do well and are over 40% slower.
The larson server workload allocates and frees objects between many threads. Larson and Krishnan [2] observe this behavior (which they call bleeding) in actual server applications, and the benchmark simulates this. Here, mimalloc is more than 2.5× faster than tcmalloc and jemalloc due to the object migration between different threads. This is a difficult benchmark for other allocators too where mimalloc is still 48% faster than the next fastest (snmalloc).
The second benchmark set tests specific aspects of the allocators and shows even more extreme differences between them.
The alloc-test, by OLogN Technologies AG, is a very allocation intensive benchmark doing millions of allocations in various size classes. The test is scaled such that when an allocator performs almost identically on alloc-test1 as alloc-testN it means that it scales linearly. Here, tcmalloc, snmalloc, and Hoard seem to scale less well and do more than 10% worse on the multi-core version. Even the best allocators (tcmalloc and jemalloc) are more than 10% slower as mimalloc here.
The sh6bench and sh8bench benchmarks are developed by MicroQuill as part of SmartHeap. In sh6bench mimalloc does much better than the others (more than 2× faster than jemalloc). We cannot explain this well but believe it is caused in part by the "reverse" free-ing pattern in sh6bench. Again in sh8bench the mimalloc allocator handles object migration between threads much better and is over 36% faster than the next best allocator, snmalloc. Whereas tcmalloc did well on sh6bench, the addition of object migration caused it to be almost 3 times slower than before.
The xmalloc-testN benchmark by Lever and Boreham [5] and Christian Eder, simulates an asymmetric workload where some threads only allocate, and others only free. The snmalloc allocator was especially developed to handle this case well as it often occurs in concurrent message passing systems (like the [Pony] language for which snmalloc was initially developed). Here we see that the mimalloc technique of having non-contended sharded thread free lists pays off as it even outperforms snmalloc here. Only jemalloc also handles this reasonably well, while the others underperform by a large margin.
The cache-scratch benchmark by Emery Berger [1], and introduced with the Hoard allocator to test for passive-false sharing of cache lines. With a single thread they all perform the same, but when running with multiple threads the potential allocator induced false sharing of the cache lines causes large run-time differences, where mimalloc is more than 18× faster than jemalloc and tcmalloc! Crundal [6] describes in detail why the false cache line sharing occurs in the tcmalloc design, and also discusses how this can be avoided with some small implementation changes. Only snmalloc and tbb also avoid the cache line sharing like mimalloc. Kukanov and Voss [7] describe in detail how the design of tbb avoids the false cache line sharing.
References
-
1] Emery D. Berger, Kathryn S. McKinley, Robert D. Blumofe, and Paul R. Wilson. _Hoard: A Scalable Memory Allocator for Multithreaded Applications_ the Ninth International Conference on Architectural Support for Programming Languages and Operating Systems (ASPLOS-IX). Cambridge, MA, November 2000. [pdf](http://www.cs.utexas.edu/users/mckinley/papers/asplos-2000.pdf)
-
2] P. Larson and M. Krishnan. _Memory allocation for long-running server applications_. In ISMM, Vancouver, B.C., Canada, 1998. [pdf](http://citeseer.ist.psu.edu/viewdoc/download;jsessionid=5F0BFB4F57832AEB6C11BF8257271088?doi=10.1.1.45.1947&rep=rep1&type=pdf)
-
3] D. Grunwald, B. Zorn, and R. Henderson. _Improving the cache locality of memory allocation_. In R. Cartwright, editor, Proceedings of the Conference on Programming Language Design and Implementation, pages 177–186, New York, NY, USA, June 1993. [pdf](http://citeseer.ist.psu.edu/viewdoc/download?doi=10.1.1.43.6621&rep=rep1&type=pdf)
-
4] J. Barnes and P. Hut. _A hierarchical O(n*log(n)) force-calculation algorithm_. Nature, 324:446-449, 1986.
-
5] C. Lever, and D. Boreham. _Malloc() Performance in a Multithreaded Linux Environment._ In USENIX Annual Technical Conference, Freenix Session. San Diego, CA. Jun. 2000. Available at <https://github.com/kuszmaul/SuperMalloc/tree/master/tests>
-
6] Timothy Crundal. _Reducing Active-False Sharing in TCMalloc._ 2016. <http://courses.cecs.anu.edu.au/courses/CSPROJECTS/16S1/Reports/Timothy_Crundal_Report.pdf>. CS16S1 project at the Australian National University.
-
7] Alexey Kukanov, and Michael J Voss. _The Foundations for Scalable Multi-Core Software in Intel Threading Building Blocks._ Intel Technology Journal 11 (4). 2007
-
8] Paul Liétar, Theodore Butler, Sylvan Clebsch, Sophia Drossopoulou, Juliana Franco, Matthew J Parkinson, Alex Shamis, Christoph M Wintersteiger, and David Chisnall. _Snmalloc: A Message Passing Allocator._ In Proceedings of the 2019 ACM SIGPLAN International Symposium on Memory Management, 122–135. ACM. 2019.
Contributing
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