[cfe-dev] RFC: Replacing the default CRT allocator on Windows
Alexandre Ganea via cfe-dev
cfe-dev at lists.llvm.org
Thu Jul 2 20:56:51 PDT 2020
Thanks for the suggestion James, it reduces the commit by about ~900 MB (14,9 GB -> 14 GB).
Unfortunately it does not solve the performance problem. The heap is global to the application and thread-safe, so every malloc/free locks it, which evidently doesn’t scale. We could manually create thread-local heaps, but I didn’t want to go there. Ultimately allocated blocks need to share ownership between threads, and at that point it’s like re-writing a new allocator. I suppose most non-Windows platforms already have lock-free thread-local arenas, which probably explains why this issue has gone (mostly) unnoticed.
De : James Y Knight <jyknight at google.com>
Envoyé : July 2, 2020 6:08 PM
À : Alexandre Ganea <alexandre.ganea at ubisoft.com>
Cc : Clang Dev <cfe-dev at lists.llvm.org>; LLVM Dev <llvm-dev at lists.llvm.org>
Objet : Re: [cfe-dev] RFC: Replacing the default CRT allocator on Windows
Have you tried Microsoft's new "segment heap" implementation? Only apps that opt-in get it at the moment. Reportedly edge and chromium are getting large memory savings from switching, but I haven't seen performance comparisons.
If the performance is good, seems like that might be the simplest choice
https://docs.microsoft.com/en-us/windows/win32/sbscs/application-manifests#heaptype
https://www.blackhat.com/docs/us-16/materials/us-16-Yason-Windows-10-Segment-Heap-Internals.pdf
On Thu, Jul 2, 2020, 12:20 AM Alexandre Ganea via cfe-dev <cfe-dev at lists.llvm.org<mailto:cfe-dev at lists.llvm.org>> wrote:
Hello,
I was wondering how folks were feeling about replacing the default Windows CRT allocator in Clang, LLD and other LLVM tools possibly.
The CRT heap allocator on Windows doesn’t scale well on large core count machines. Any multi-threaded workload in LLVM that allocates often is impacted by this. As a result, link times with ThinLTO are extremely slow on Windows. We’re observing performance inversely proportional to the number of cores. The more cores the machines has, the slower ThinLTO linking gets.
We’ve replaced the CRT heap allocator by modern lock-free thread-cache allocators such as rpmalloc (unlicence), mimalloc (MIT licence) or snmalloc (MIT licence). The runtime performance is an order of magnitude faster.
Time to link clang.exe with LLD and -flto on 36-core:
Windows CRT heap allocator: 38 min 47 sec
mimalloc: 2 min 22 sec
rpmalloc: 2 min 15 sec
snmalloc: 2 min 19 sec
We’re running in production with a downstream fork of LLVM + rpmalloc for more than a year. However when cross-compiling some specific game platforms we’re using other downstream forks of LLVM that we can’t change.
Two questions arise:
1. The licencing. Should we embed one of these allocators into the LLVM tree, or keep them separate out-of-the-tree?
2. If the answer for above question is “yes”, given the tremendous performance speedup, should we embed one of these allocators into Clang/LLD builds by default? (on Windows only) Considering that Windows doesn’t have a LD_PRELOAD mechanism.
Please see demo patch here: https://reviews.llvm.org/D71786
Thank you in advance for the feedback!
Alex.
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