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Under what circumstances is garbage collection more efficient than manual memory management? (Here manual could mean using malloc and free as in C, or the cleaner RAII and smart pointer techniques popularized by C++)

I like how garbage collection can remove some accidental complexity from writing software, but I was even more pleased at how RAII and smart pointers can eliminate that complexity while also working on resources other than memory, being deterministic, and providing performance guarantees and being more efficient overall. So I thought I could safely ignore garbage collection. However, I've noticed that people have been saying that garbage collection is faster than the tight resource management used in C++, such as when there is a lot of extra memory available.

So when exactly can garbage collection outperform manual memory management? I like RAII and smart pointers but would happy to accept garbage collection as another tool if it is faster.

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closed as not constructive by Lasse V. Karlsen Aug 9 '11 at 8:28

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One time when garbage collection can be faster is when nothing ever needs to be freed. If your program doesn't use a lot of memory resources, the garbage collector may never need to kick in. And the allocator in a GC system may be as simple as a move of a pointer. –  Michael Burr Aug 8 '11 at 1:30
    
GC performance is highly dependent on the algo chosen. Same goes for 'manual' memory managers. We're comparing apples to oranges at best. –  Zach Saw Aug 8 '11 at 5:42
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@Michael Burr: In that case, manual management might be equally cheap. You're essentially describing the case in which deallocations are batched, and the program terminates before one entire batch of allocations has been deallocated. That's possible with both GC and malloc/free implementations. –  MSalters Aug 8 '11 at 12:31
    
I honestly think you're asking the wrong question. The better question would be, "Does a GC meet or exceed the performance budget of my application and what advantages does a GC confer?" –  Conrad Frix Aug 8 '11 at 14:50
    
@MSalters: that's true if all the allocation/deallocation code is under your control, but if you're using library code (whether your own or someone else's) or using RAII, you usually lose control of the deallocation policies to some extent. Anyway, I put it in a comment because I don't think it's really an important performance consideration. It may come into play in some theoretic way in smaller programs/utilities, but I don't think that in those situations it's going to be any real performance 'win'. –  Michael Burr Aug 8 '11 at 16:16

3 Answers 3

up vote 13 down vote accepted

Never, and I can prove it.

First, let's assume we're using the best algorithms in either case. Using a sub-optimal algorithm can prove anything.

Secondly, let's assume the best GC algorithm uses times T0...Tn to decide whether memory allocation i should be freed at a certain moment. The total then is Σ(Ti)

Now, an equivalent manual memory management algorithm exists that uses the same GC algorithm, but only considers memory blocks which have been manually marked to be freed. Therefore, the running time is Σ(δiTi) (with δi=0 when block i wasn't freed, and =1 when it was).

Obviously, Σ(δiTi) ≤ Σ(Ti) : there's a manual algorithm that's strictly not worse than a GC algorithm.

How does that contrast with other answers?

  • "With RAII, you have to deallocate every time you allocate." - No, that's a mistaken assumption. We should compare either batched or non-batched operations. GC would be far worse if you'd also do a GC run every time something went out of scope.
  • "Improved locality" - well, unless you discount the fact that non-GC languages can use the stack far more often, and that stack has an excellent locality of reference.
  • "low odds for leaks" - that's entirely true, but we were discussing runtime performance. (BTW: good to point out that it's low but non-zero odds).
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it still is GC, but with manual help. And it loses performance guarantees of manual memory management. But for throughput it probubly is the best combination. –  Alpedar Aug 8 '11 at 11:46
    
Those "performance guarantees" of manual memory management are similarly dependent on the tradeoffs made behind the scenes. E.g. you can trivially show that the efficiency of free(ptr) can be improved by batching N deallocations, if only for the improved locality of reference. As for "GC with manual help", well, no, that's just an artifact of my math. It was not necessary to prove that the Ti time bounds per (de)allocation can be improved, so I didn't prove it. –  MSalters Aug 8 '11 at 12:27
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You're only addressing deallocation (free) with your maths. How's that enough proof for GC being inferior on the whole? –  Zach Saw Aug 9 '11 at 2:51
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@Zach Saw: For the equivalence proof, you'd have to use the same allocation mechanism in both cases. So the allocation was (perhaps not explicit enough) addressed too. –  MSalters Aug 9 '11 at 7:41
    
@MSalters: Perhaps you'd like to explicitly address it then? Particularly on the book keeping part of manual memory managers? –  Zach Saw Aug 9 '11 at 7:55

GC advantages:

  • a GC allocates simply by incrementing a pointer, heap allocators must take counter-measures to avoid heap fragmentation
  • a GC improves cpu cache locality, a big deal on modern processors
  • a GC requires no extra code to release memory, low odds for leaks
  • a generational GG can collect garbage concurrently, making memory management close to free on a multi-core cpu.

GC disadvantages:

  • difficult to make efficient in a language that treats pointers as first class types
  • uses more virtual memory space due to collection latency
  • leaky abstraction for operating system resources other than memory
  • can cause pauses in program operation in some cases while garbage is being collected.

It is a slamdunk for perf, a GC beats a heap allocator easily without effort. The Chinese Dictionary programming contest between Rico Mariani and Raymond Chen is often quoted, overview is here. Raymond's C++ program eventually won but only after rewriting it several times and giving up on the standard C++ library.

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GC can't simply bump a pointer to allocate memory unless Mark-Sweep-Compact algo is used (i.e. MS .NET GC). In non C++/CLR (i.e. traditionally C++), you won't be able to do the Compact part. –  Zach Saw Aug 8 '11 at 5:39
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Also, note that Generational GC is an orthogonal concept to concurrent GC. –  Zach Saw Aug 8 '11 at 6:02
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GC still needs to release memory to the OS when a page is no longer in use. Similarly, a heap memory manager can also retain this unused page for future use. –  Zach Saw Aug 8 '11 at 6:04
    
GC doesn't improve cache locality vs a decent heap memory manager (e.g. low frag win32 heap mem manager). However, it increases data locality such that less page fault will occur hence increasing performance. –  Zach Saw Aug 8 '11 at 6:06
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Your conclusion is misleading at best. Very little of the Mariani/Chen comparison had anything to do with memory management at all. The little that did was specifically because C++ at that time didn't have move constructors (which it now does). In the end, it's doubtful that anybody who knew what they were doing would ever write code similar to Raymond Chen's initial version (or most intermediate steps) except as a straw man to later knock over. Finally, the code in question is for a sufficiently oddball task that it's doubtful whether it ever really meant anything to anybody. –  Jerry Coffin Aug 8 '11 at 10:18

There's one particular scenario I know in which GC pointer is much faster than a smart pointer (reference counted pointer) when both are implemented in traditional C++ (i.e. not C++/CLR as we won't have the same luxury as to Compact the memory after Mark-Sweep, and we're trying to compare apples to apples here as much as we can) assuming GC uses the same underlying heap memory manager. It is when your object assignment time significantly overwhelms object creation time.

Examples include sorting, array reversal etc.

See here for more info on my test with a GC framework I implemented using traditional C++ vs reference counted pointers. Outcome of the array reversal test was GcString was 16.5 times faster than ref counted String.

This could be attributed to the painfully slow bus lock semantics in a reference counted pointer (unless you're targeting purely single threaded apps, locks are required for thread safety). From my experience of implementing a high performance precise GC in traditional C++, I can say that there are more opportunities for optimizations with a GC vs 'manual' (as per OP's definition of manual) memory management (i.e. smart pointers).

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You should use atomic operations for the reference count, not locks. –  GManNickG Aug 8 '11 at 6:14
    
@GMan: Atomic operations won't lock unless you prefix lock to the mnemonic. Or were you suggesting using implicit lock opcodes such as xchg? Either way, they're locks. –  Zach Saw Aug 8 '11 at 6:16
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'Lock' is usually defined to mean an OS lock, while atomic operations might be considered a "CPU lock". In any case, category wasn't the point, it was implementation. An OS lock is overkill (the only appropriate one, if it were necessary, would be a spin lock). –  GManNickG Aug 8 '11 at 6:18
    
@GMan: Oh I now see what you're trying to suggest. You were thinking the ref-counted pointer was using a critical section? LOL... –  Zach Saw Aug 8 '11 at 6:19
    
Like I said, 'lock' is usually defined to mean 'OS lock', while you would use the phase 'atomic operation' to mean a 'CPU "lock"'. –  GManNickG Aug 8 '11 at 6:21

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