=======================
.. default-role:: code .. include:: rstcommon.rst
:Author: Andreas Rumpf :Version: |nimversion|
..
"The road to hell is paved with good intentions."
.. default-role:: option
Nim offers multiple different memory management strategies.
To choose the memory management strategy use the --mm:
switch.
The recommended switch for newly written Nim code is --mm:orc
.
ORC is the default memory management strategy. It is a memory management mode primarily based on reference counting. Reference cycles are handled by a cycle collection mechanism based on "trial deletion". Since algorithms based on "tracing" are not used, the runtime behavior is oblivious to the involved heap and stack sizes.
The reference counting operations (= "RC ops") do not use atomic instructions and do not have to -- instead entire subgraphs are moved between threads. The Nim compiler also aggressively optimizes away RC ops and exploits move semantics.
Nim performs a fair share of optimizations for ARC/ORC; you can inspect what it did
to your time critical function via --expandArc:functionName
. Likewise, you can inspect the whole module via --expandArc:fileName
.
--mm:arc
uses the same mechanism as --mm:orc
, but it leaves out the cycle collector.
Both ARC and ORC offer deterministic performance for hard realtime
:idx: systems, but
ARC can be easier to reason about for people coming from Ada/C++/C -- roughly speaking
the memory for a variable is freed when it goes "out of scope".
We generally advise you to use the acyclic
annotation in order to optimize away the
cycle collector's overhead
but --mm:orc
also produces more machine code than --mm:arc
, so if you're on a target
where code size matters and you know that your code does not produce cycles, you can
use --mm:arc
. Notice that the default async
:idx: implementation produces cycles
and leaks memory with --mm:arc
, in other words, for async
you need to use --mm:orc
.
.. note:: The refc
GC is incremental, thread-local and not "stop-the-world".
--mm:refc It's a deferred reference counting based garbage collector with a simple Mark&Sweep backup GC in order to collect cycles. Heaps are thread-local. This document contains further information. --mm:markAndSweep Simple Mark-And-Sweep based garbage collector. Heaps are thread-local. --mm:boehm Boehm based garbage collector, it offers a shared heap. --mm:go Go's garbage collector, useful for interoperability with Go. Offers a shared heap.
--mm:none No memory management strategy nor a garbage collector. Allocated memory is
simply never freed. You should use --mm:arc
instead.
Here is a comparison of the different memory management modes:
================== ======== ================= ============== ===================
Memory Management Heap Reference Cycles Stop-The-World Command line switch
================== ======== ================= ============== ===================
ORC Shared Cycle Collector No --mm:orc
ARC Shared Leak No --mm:arc
RefC Local Cycle Collector No --mm:refc
Mark & Sweep Local Cycle Collector No --mm:markAndSweep
Boehm Shared Cycle Collector Yes --mm:boehm
Go Shared Cycle Collector Yes --mm:go
None Manual Manual Manual --mm:none
================== ======== ================= ============== ===================
.. default-role:: code .. include:: rstcommon.rst
JavaScript's garbage collector is used for the JavaScript and NodeJS compilation targets. The NimScript target uses the memory management strategy built into the Nim compiler.