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I often heard that people prefer C++ to C# mainly in the performance critical code,because the GC might turn up on critical path, causing the performance penalty.

However, when I read through the C++, I realized that C++ offers the smart pointer features in which the programmer did not need to worry about memory management. For example, the shared_ptr with reference counting will manage the memory for us. Hence,we did not really care about the life-time of an object and when did it being deleted. Wouldn't that similar to the C# GC and the destructor of the object would be called at the performance critical code?

Also, another question is if we didn't use smart pointer in C++ and we just resort to raw pointer, we still need to call delete to clear the heap memory. So from my understanding, every object created by C++ or C# would still be destroyed but the difference is only in we manage the memory ourselves in C++ but in C#, we let the GC to manage it. So what is the NET effect of it when comparing C++ and C# since both object still need to be deleted?

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closed as primarily opinion-based by Rainer Joswig, Walter, singles, David, T I Nov 13 '13 at 21:54

Many good questions generate some degree of opinion based on expert experience, but answers to this question will tend to be almost entirely based on opinions, rather than facts, references, or specific expertise.If this question can be reworded to fit the rules in the help center, please edit the question.

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What is faster: a screwdriver or a banana ? C++ and C# serve two different purposes and fit different needs. Comparing one to the other in terms of raw performance makes no sense. –  ereOn Nov 23 '10 at 15:31
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"we did not really care about the life-time of an object and when did it being deleted" Remind me to never buy your software. –  John Dibling Nov 23 '10 at 15:31
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@Let_Me_Be - C# is not a replacement for C++. They did it to expand the universe of people who can program on Windows, and with some success judging by the question counts here. If anything it was a response to insurgent Java, not C++. –  Steve Townsend Nov 23 '10 at 16:02
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At any rate, while C# is not designed to replace C++ in all use cases, the fact is that you can get quite fine grained control over things that Java will not allow you to. The result is that you can write really efficient code in C#, another issue is whether writing efficient code in C# is simpler than in C++. My bet is that while the entry to the language is easier in C#, writing efficient code is not that simple. –  David Rodríguez - dribeas Nov 23 '10 at 16:57
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Wow, how on earth has this question not been marked down as being off-topic? stackoverflow.com/help/dont-ask "You should only ask practical, answerable questions based on actual problems that you face. Chatty, open-ended questions diminish the usefulness of our site and push other questions off the front page. Your questions should be reasonably scoped. If you can imagine an entire book that answers your question, you’re asking too much." –  Fresh Oct 24 '13 at 9:26

25 Answers 25

I often heard that people prefer C++ to C# mainly in the performance critical code,because the GC might turn up on critical path, causing the performance penalty.

I have heard that in some circles but never respectable circles.

For example, I consulted for a company in London who were selling stock exchange software that had been written in 1,000,000 lines of C++. Over 40 developers had been working on it for almost 15 years and they were convinced that C++ was the correct solution for such software because latency and throughput performance were both critical. They were achieving latencies as low as 50ms (with a single trader connected!) and throughput as high as 10k trades per second (tps). However, they were struggling to support more than 2,000 traders because they had several threads per trader (no async) and, in fact, traders were reporting latencies as high as six seconds because the latency of their C++ code increased exponentially with the number of traders. I rewrote their code in 3 months using F# on .NET and achieved latencies as low as 0.1ms and throughputs over 200ktps using just 6,000 lines of F#. My solution was fully asynchronous (supported over 10,000 simultaneous trader connections) and fault tolerant.

Now, I'm not saying that C++ could not have been used to achieve even better performance than mine. On the contrary, I'm sure it could have achieved better performance but I also believe it would have taken man-decades of work by real experts and cost millions of pounds. After all, there's a reason why the London Stock Exchange paid £18m for Millenium IT and their low-latency C++ solution. However, I do believe that the vast majority of the people who prematurely optimize away garbage collection don't know what they are talking about and would not be capable of building a good solution in any language. Such people usually only know C++ and have no knowledge of garbage collection algorithms, which is scary because C++ programmers reinvent GC algorithms every day. A good test is to ask them how garbage collection works. If they describe naive mark-sweep circa 1960 then they haven't done their homework.

On the other hand, some people write excellent low-latency and high-throughput code in garbage collected languages. For example, see the LMAX Disruptor (Java) and Rapid Addition FIX engine (C#). So people have written low-latency software in Java and C# and, therefore, it clearly is possible. In particular, the use of arrays of value types is a known but under-appreciated solution for low-latency programming on .NET.

However, when I read through the C++, I realized that C++ offers the smart pointer features in which the programmer did not need to worry about memory management. For example, the shared_ptr with reference counting will manage the memory for us. Hence,we did not really care about the life-time of an object and when did it being deleted. Wouldn't that similar to the C# GC and the destructor of the object would be called at the performance critical code?

Yes. C++ programmers often complain about tracing garbage collectors being non-deterministic and causing pauses. Thread-safe shared_ptr in C++ is non-deterministic because threads race to decrement the count to zero and the winner of the race condition is burdened with calling the destructor. And shared_ptr causes pauses when decrements avalanche, e.g. when a thread releases the last reference to a tree the thread is paused for an unbounded length of time while every destructor in the tree is called. Reference counting can be made incremental by queuing destructors but that recovers the non-determinism of tracing garbage collection. Finally, reference counting with shared_ptr is several times slower than tracing garbage collection because incrementing and decrementing counts is cache unfriendly.

On a related note, C++ programmers often mistakenly claim that shared_ptr collects garbage at the earliest possible point in the program and, therefore, collects more "promptly" than a tracing garbage collector can. In fact, scope-based reference counting like shared_ptr keeps floating garbage around until it falls out of scope which increases register pressure can even increase memory consumption compared to tracing garbage collection.

So shared_ptr is indeed nothing more than a poor man's garbage collector. After all, old JVMs and CLRs both used reference counting at some point in history and both dropped it in favor of better forms of garbage collection. Reference counting is only popular in C++ because there is no easy way to walk the stack and redirect pointers so accurate tracing collection is prohibitively difficult.

Also, another question is if we didn't use smart pointer in C++ and we just resort to raw pointer, we still need to call delete to clear the heap memory. So from my understanding, every object created by C++ or C# would still be destroyed but the difference is only in we manage the memory ourselves in C++ but in C#, we let the GC to manage it. So what is the NET effect of it when comparing C++ and C# since both object still need to be deleted?

In its simplest form, allocation in C++ boils down to calling a general-purpose shared (global) memory allocator like malloc and in C# it boils down to pointer bump allocating into a thread-local nursery generation (gen0). Consequently, ordinary allocation in C# is much faster than ordinary allocation in C++. However, that misrepresents real software. In practice, C++ programmers avoid calling the general purpose global allocator in favor of using thread-local pool allocators whenever possible. On the other hand, C# developers rely on the general purpose memory management solution provided by .NET because it greatly simplifies APIs (memory ownership has been abstracted away) and is more than fast enough in the vast majority of cases. In the few cases where the simple solution is not adequate, the C# developer drops to lower level C# code and writes a pool allocator using an array of value types.

So I'd probably just make two observations:

  • Accurate tracing garbage collection is extremely useful in general and is bundled with C# and prohibitively difficult with C++.

  • Memory management bit tricks (e.g. smuggling bits in pointers) are sometimes possible in C++ but prohibited in C#.

So there is no easy way to compare C++ and C# fairly in this context.

Moreover, memory management is arguably not the biggest performance concern anyway. Many other issues can have a significant effect such as the quality of generated code on obscure architectures (where C compilers are usually much more mature) vs JIT compiling for a specific CPU, vectorization like SIMD (.NET does little), JIT-compiled run-time-generated code (like regular expressions in .NET) vs an interpreter in C++ and compilation to GPUs or FPGAs.

I think the only piece of good advice I can give you here is: do your own research and don't listen to the unwashed masses.

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You make some very good points and I won't try to argue them. I just want to say that just because 40 developers worked for 15 years (it didn't take them 15 years to write the program, that's just the lifespan of the product with many versions) and wrote 1MLOC that didn't perform well, doesn't mean that a handful of developers could not write in a few months in C++, like you did in F#, the same program that performs much better. You probably have to write more boilerplate code than you did in F#, but I believe you can achieve the same performance. –  Marius Bancila Oct 22 '13 at 7:12
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One thing you don't address is cache dependency. With C++ you can make your code fit in the L1/L2 cache (with data) so it won't suffer from the slow bottleneck to main-mem. In C# you don't have control over that. –  Frans Bouma Oct 22 '13 at 8:48
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@FransBouma When you need that kind of performance, you should write those pieces of tightly-packed code in C or Fortran, then call it from C# or F#. Writing your entire application in C++ because you need a few chunks of code/data to fit into L1/L2 cache is a premature optimization, and precisely the behavior Jon is arguing against here. –  Jack P. Oct 22 '13 at 12:43
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This is generally a very good, well-researched answer. But, sorry, your anecdote is just terrible. You’ve inherited terrible code (without knowing any specifics, several threads per trader?). And F# is great and all, but if one person succeeds in three months to beat their 18m GBP software, then that tells us nothing about C# vs C++ or GC vs explicit memory management, and tells us a lot about the respective competence of the previous programmers (nay), their salesperson (yay) and the London Stock Exchange (double nay). Frankly, this sounds like from a Dilbert comic. –  Konrad Rudolph Oct 23 '13 at 21:41
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-1: On a closer inspection of this article, I must revert my upvote. You make a number of false assertions about the C++ language (eg, shared_ptr being garbage collection) and C++ programmers (eg, C++ [programmers] have no knowledge of garbage collection algorithms, [and] reinvent GC algorithms every day.), and deliberately misleading claims about real-world .NET use ("the use of arrays of value types" completely sidesteps the GC, as quoted in the article you linked). –  John Dibling Oct 24 '13 at 17:44

This question and my original answer were first written almost three years ago. Since that time I was surprised to receive a more or less constant stream of votes, both up and down, even up to today. I thought now would be a good time to revisit this answer. I'll leave the original down below as reference.


The question of which language is fastest is now largely moot. They can both me made to be exceedingly fast. The same was true three years ago as well, but my original answer was purposefully not focused on a technical survey of the two languages and how their differences impact performance. My focus was on the people using those languages, and the bottom line is this:

The most important factor in determining the speed and efficiency of a program is not the language used to program it, but the people behind the keyboards.

In his answer, @Jon Harrop describes the success he had re implementing a legacy system in a GC'ed .NET language. I do not dispute or doubt his expertise in the matter. I, Like him, am also employed in the financial services arena and have been for going on 20 years. In that time I've seen many different systems -- ranging in quality from fantastic to horrid. I am a C++ guy -- that's what I do for a living. I also know F#, C#, VB, Ruby, Perl, assembler and probably 30 other languages. But my expertise in those languages does not even approach my expertise in C++. If I were to write what Jon wrote in F#, his code would trounce mine, no question in my mind.

Does that mean F# is faster than C++? No. What it means is the person behind the F# keyboard (Jon) is better than me. I have no doubt about that.

In high-frequency trading (my industry), speed is king. We measure latency in such short intervals that the speed which an electrical signal travels over a networking cable is part of the equation. There are a number of datacenters where this is considered so important that they have spools of extra cable going to each cage so that every computer in the DC has the same length connected to it, in order to eliminate any advantage from your proximity within the datacenter. Every single component and line of code matters. In an environment such as this, even 1 milli is an eternity. You might as well go to lunch. As a guideline, our standards for performance is 10 micros from the time a message comes in from the exchange to the time it has been completely processed and the resulting client message sent on the outgoing message bus. 10 micros is just the absolute ceiling of acceptable performance. The average is closer to 2-5 micros. This includes all computations, value-adds and database updates. And our systems are written in 100% C++.

Does that mean C++ is faster than F#? No. What it means is our systems are a mature product that has been developed by experts in the field (at great cost) over several years. As technology changes, our code changes to leverage new advantages. Although our product is among the very best in the industry, other competing products written in other languages have similar performance. It's not the language that matters most -- it's the people utilizing it. If I were as good at C# or F# as I am at C++, I'd be writing C# or F#.


In my original answer below, I tried to focus on the differences between the programmers using a language, rather than the language itself. The important thing is not the language, but the people -- their expertise, the questions they ask, and their experience. It's not the best answer I've ever given on SO, but it has attracted a lot of attention. It's not exactly what I would write today but I'm going to let it stand unedited for reference.


I'm sure this will get downvoted a hundred times, but I just have to say it:

So what is the NET effect of it when comparing C++ and C# since both object still need to be deleted?

In my view (and this is an admitted rant) the net effect is that some (many?) C# programmers don't really understand what their programs are doing, and so their software is not that good.

The attitude/belief that:

we did not really care about the life-time of an object and when did it being deleted

...seems to permeate the C#/Java/VB/[insert "easy" language here] culture. I once went to a MS-sponsored presentation in Chicago where Don Box spoke about the then-new .NET languages & platform. At one point he addressed all those in the audience that were "sick and tired of the C++ guys gloating" about how fast C++ was compared to the other languages of the time. "Now I'll prove once and for all that they are wrong," he said. Then proceeded to create 2 programs. In the C# program he created a loop that instantiated 10 million strings, and he set a breakpoint right after the loop. In the C++ version, he allocated and deallocated the same number of strings using new and delete and set a breakpoint at the closing brace for main. Ran the program. the C# version's breakpoint hit much sooner than the C++ version, and the crowd went wild.

The sheep in that crowd didn't bother to wonder why the C# version was faster, whether or not the 2 programs really did the same thing, or for that matter ask to see the Performance tab in Task Manager. I asked to see it. Don wouldn't let me, and "accused" me of being a C++ guy. Quickly closed both his programs and moved on to the next topic.

The GC'ed languages shield you from what's really going on in your machine. In order to write a functioning program, you don't really need to know the difference between smart pointers in C++ and garbage collection in C#. It's like training a car mechanic only how to use plug-in diagnostic tools, but not teaching him how an internal combustion engine actually works.

So the net result? Ask me and I'll tell you the programs aren't as good.

I blame the university system as much as anything else, but that's a story for another day.

OK, rant over. Let the flaming begin.

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@Henk: Don's point was that "C# is faster than C++" and then proceeded to "prove" it by writing two programs that did not do the same thing. He cooked the books. –  John Dibling Nov 23 '10 at 16:10
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@Henk: Moreover, just as C#'s GC might be optimized to handle many small allocations in a tight loop, so can C++ be. No C++ programmer worth their salt would even write such a program. –  John Dibling Nov 23 '10 at 16:14
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C++ programmers can be just as guilty of not knowing what their programs are really doing as any other programmer. Again, I blame the university system (and the laziness of some programmers). This ignorance might be manifest in the form of writing a tight loop that does 10 million news and deletes. –  John Dibling Nov 23 '10 at 16:15
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I completely agree in that most comparisons are quite biased and incorrect. I have seen real production code in C# comparable to C++ code (equivalent systems within the same financial company), so it can be claimed that the efficiency can be the same. On the other hand, the level of expertise to be able to pull that performance out of the system is not the level that anyone claiming that C# is much easier than C++ has. –  David Rodríguez - dribeas Nov 23 '10 at 17:07
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"Your stack objects just evade the test. Just assume they must go in a list." But that is the point! In C++, you avoid heap allocations as much as possible, and use incredibly faster stack allocation instead. (Which, on top of being so much faster, is also deterministic.) That is so commonly used, that an optimization employing stack space instead of heap space for smaller strings even has its own name ("small string optimization"). –  sbi Nov 23 '10 at 19:17

The difference is that in C++ you can choose when to destroy unneeded objects.

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And that you have to choose when and where for each and every object. –  Henk Holterman Nov 23 '10 at 15:55
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@Henk Holterman: however, when using smart pointers, the choice becomes a less conscious one. –  StackedCrooked Nov 23 '10 at 18:17
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@Henk: Which is not necessarily a bad thing. @StackedCrooked: Which is not necessarily a good thing. –  John Dibling Nov 23 '10 at 18:31
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@John: In this case i was talking man-hours, not CPU-cycles. But GC aims to reduce both. –  Henk Holterman Nov 23 '10 at 21:21
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auto_ptr takes me 605 millisecconds to type. Add another 100 milliseconds to think about where to type it, since I know what the heck I'm doing. :) –  John Dibling Nov 23 '10 at 22:07

This may be a little off-topic; as others have pointed out, performance is relative and you can write poorly performing code regardless of whether you have garbage collection. Like John Dibling I expect this post may not be well-taken by some.

  • In well-written C++, resource lifetimes are managed deterministically, uniformly, and automatically.

  • In most languages with garbage collection (C# and Java in particular), resource lifetimes are managed nondeterministically, nonuniformly, and only partially automatically.

The problem with garbage collection (as implemented in Java and C#) really isn't that it manages memory for you. That, in and of itself, it kind of a nice feature. It definitely has benefits.

The problem is that you're left out in the cold with every non-memory resource. If you have a file handle, socket, registry key, native synchronization object, or any other resource that requires deterministic cleanup, you have to do extra work to ensure they are cleaned up correctly.

Yes, there are language facilities that are there to help you with this (C# has IDisposable, using, and finally, for example), but the burden still falls on you, the programmer, to write code to manually manage resource lifetimes.

In C++, all resources are managed the same way by using the Scope-Bound Resource Management (SBRM) idiom. The lifetime of a file handle is managed automatically, just as the lifetime of a dynamically allocated object is managed automatically. C++ doesn't need an IDisposable, a using, or a finally because deterministic destruction can be used to clean up anything.

Yes, in C++ you may occasionally have to write your own SBRM container to manage a resource, but it's rare. Most modern libraries (especially those included in Boost) use the SBRM idiom. Even when you do have to write one, it's straightforward and it's write-once, use-everywhere.

The huge advantage of the C++ approach then is that because object lifetimes are deterministic, all object lifetimes can be managed uniformly by using the SBRM idiom, and by using that idiom, all object lifetimes can be managed automatically.

Because of this, I don't think it's possible to say that it's easier to write code when you have garbage collection. Sure, if you never use any other type of resource, you're good to go, but how many programs never use a non-memory resource?

(Note that I am not saying that garbage collection is useless. It may offer performance benefits; I don't really know. It may help reduce heap fragmentation. It may help with a lot of things. I am focusing purely on the usability here.)

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I understand the reasoning, even if I do not share it (won't downvote, won't upvote either :)). Claiming that using and IDisposable place a burden on the developer is just as biased as the example in John Dibling's response: writing destructors pose a similar cost in the C++ side (higher but comparable: they solve the most common case with no effort at all from the developer at the cost of extra effort for all resources that are not memory). Now, there is a huge difference here between C# and Java, where you cannot achieve deterministic resource management. –  David Rodríguez - dribeas Nov 23 '10 at 17:28
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"The problem is that you're left out in the cold with every non-memory resource." I haven't read any further yet, but this is the moment I would want to donate 1000 of my rep to this answer, if I could. –  sbi Nov 23 '10 at 18:56
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@David: Have you actually seen how IDisposable has to be implemented? Compared to that, writing a destructor in C++ looks like a newbie task. And, as you said, in Java you haven't even this. (I'm speaking from experience, BTW. After more than a year of doing C#, I still have to look up how to properly implement such a beast.) –  sbi Nov 23 '10 at 19:00
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The IDisposable pattern is nice because it separates memory management from management of other finite resources (such as handles) - Although it is a pain when you do need to implement it, 99% of C# classes don't need to implement IDisposable. –  Justin Nov 25 '10 at 6:54
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@James Because memory management is different - In the case of a single shared resource (for example a file handle) we obviously want to release the resource as soon as possible to maximise availability of that resource, however all memory is the same - rather than being concerned about when block 0x00000012 is released, the thing that really matters is that memory is available to whoever wants it, whenever they want - it is perfectly valid (and quite possibly preferable) to use a completely different strategy for choosing when to release memory vs shared resources. –  Justin Nov 25 '10 at 7:10

The difference is that in C++ object destruction is deterministic: you know that when all the shared pointers which point to the same objects get destroyed, the objects get destroyed.

C#'s GC, to the contrary, is non deterministic: you cannot tell when memory is released, it is up to the GC to do it periodically.

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Alexandre, as long as there are no resources involved, it is totally irrelevant when an object is reclaimed. Will: If you have both a Dispose and a finalizer executing on your objects you are doing something wrong. –  Henk Holterman Nov 23 '10 at 21:23
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@Henk: If the GC can fire up at the wrong moment (like in the middle of a time-critical routine), when an object is reclaimed becomes relevant. For most applications though, this is not a problem. –  Alexandre C. Nov 24 '10 at 1:07
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-1 "in C++ object destruction is deterministic: you know that when all the shared pointers which point to the same objects get destroyed, the objects get destroyed". That is a common memory management myth. Thread-safe scope-based reference counting like shared_ptr makes threads race to decrement to zero and the winner of the race condition calls the destructor. So it is non-deterministic. flyingfrogblog.blogspot.co.uk/2013/10/… –  Jon Harrop Oct 20 '13 at 13:38
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@JonHarrop: shared_ptr-based memory management is the exception, not the rule. You can also have mark-and-sweep garbage collection if you want. The fact is that object destructors get called at well defined points, unlike C# finalizers. And using/IDispose mechanism is the exception there. –  Alexandre C. Oct 20 '13 at 23:19
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@JonHarrop: First, as @Alexandre said, your point only applies to shared_ptr. The vast majority of objects are still released at deterministic points: when they go out of scope. Even in shared_ptr's case, you know that when a shared_ptr leaves scope, either: a) the destruction of the wrapped object occurs at that moment, or b) the object is referenced elsewhere, and must not be reclaimed. Compare this to garbage collection: at the time where a reference leaves scope, we're usually unable to assume anything. –  Thanatos Oct 21 '13 at 22:57

At least in my experience (and I not only used, but also implemented garbage collection long before Java or .NET came along to popularize it), GC (or lack thereof) leads to much more substantial differences than just "memory management". It leads to massive differences in design (or lack thereof).

The proponents of GC claim that it "frees" you from the (supposedly massive) difficulties of memory management. Typically, they attempt to prove this by pointing to a program in which object lifetimes are a tangled mess, and (quite correctly) point to the fact that nobody could possibly expect to keep track of which objects need to be destroyed when. Obviously, GC is an absolute necessity. Most can (and will) point to the fact that even with GC, they have to do a fair amount to ensure resources are recycled when no longer needed, and god only knows how bad it would be without GC.

When "deprived" of GC, the programmer instead spends more time up-front designing the code to keep object lifetimes from turning into a tangled mess. As a result, not only the memory management, but the entire program ends up cleaner and simpler. At the same time, one of the ways to keep things simple is to copy objects when needed, where using GC one would simply create another reference to an existing object. When/if the extra memory use from such copies becomes a problem, they can generally be eliminated in C++ with reference counting, but this brings its own set of problems (e.g., extra complexity needed to deal with circular references and/or to maintain efficiency when multi-threading).

Bottom line: after 10-15 years of work on improving garbage collectors and such, .NET (and Java) have started to get reasonably competitive with the speed of C++98. With its addition of move semantics, C++0x moves the bar quite a bit higher again though (just in initial testing, I'm seeing speedups in the range of 2:1 or 3:1 fairly routinely). For better or worse, .NET has already progressed to (nearly) the state of the art in terms of GC -- it's already using a generational scavenger. There's always the possibility of tuning to get minor improvements, but right now nobody has another algorithm to plug in that's like to help it keep up with a 2:1 improvement. Up until now, it's been a matter of fairly routine engineering (applying known algorithms). To remain (even roughly) competitive, they need some real results from new research -- and they need them quickly at that.

I should also mention that quite a few differences that are cited are based on assuming one specific model of garbage collection and/or one specific model of manually managed memory. That's not particularly accurate either -- there are quite a number of different manual memory managers, and an equally large number of garbage collectors. Here again, however, it appears to me that the difference probably favors C++ in the long term. There's quite a bit of testing to indicate that the garbage collector .NET is currently using is about the best type currently known. There's quite a bit more room for improvement in the heap managers supplied with most C++ compilers.

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Just teaching C++ programmers about custom allocators helps heap performance a lot. –  Zan Lynx Nov 23 '10 at 20:12
    
From experience, if you deal with async IO, you'll find that it could be both slower (lots of memory copy so you don't have to track who's using the async result) and/or a lot harder (keeping track of the consumers still using it) without GC. You could use shared_ptr, but you may then have to deal with circular refs. –  Zach Saw Dec 9 '10 at 1:07
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+1 for pointing out how complicated and unnecessary shared ownership can be! –  Mankarse Oct 6 '11 at 17:45
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@JonHarrop: Although it adds a few more "tricks", Beltway is not a new GC algorithm: it's a framework for garbage collection. –  Jerry Coffin Oct 21 '13 at 20:37
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@JonHarrop: Sit back and think for a moment. The very fact that it's promoting a generation points to the fact that it's a generational scavenger. Yes, it's somewhat tuned compared to older generational scavengers, and yes, under a few (rare) circumstances, that tuning can make a real difference in speed. That doesn't even come close to changing the fact that it is a form of generational scavenging. –  Jerry Coffin Oct 21 '13 at 21:07

Memory allocation performance between C# and C++ is not so cut and dry a subject. There are a number of nuances and behavioral traits that can lead to either one performing better than the other. It all depends on the nature of the code you are writing.

In C++, memory allocation generally involves walking a list of available spaces on the heap, and identifying the smallest space that can accommodate a new object. Destroying an object results in that space being released back to the heap. Allocation can become expensive due to address-space fragmentation - this occurs when many small objects are allocated and then freed, leaving gaps in the addressable memory space of the process. Since the memory allocator generally maintains a linked list of free spaces in the heap, and must perform a search for the best spot each time an object is allocated. C# (the .NET CLR, actually), on the other hand, allocates heap memory by incrementing a single pointer that tracks the top of the heap. This is a relatively fast operation, be comparison. However, the CLR then zeros out this memory, to ensure that it is always initialized to some known value - which does incur a cost.

Releasing memory is also quite different between managed and unmanaged code. Managed code does incur a cost when collecting memory, since it must perform a sweep of all of the GC roots (the objects allocated on the stack, thread-local storage, and static members) and then walk the graph of objects determining which are live (reachable from roots) and which are collectible. Fortunately, the GC employs a number of optimizations to improve performance - for instance, objects that survive multiple collections, which are likely to be long-lived, are moved into areas of the heap (generations) that are collected less often. C++ code that uses smartpointers works a bit differently - it relies on a reference counting model to determine when an allocated object is no longer references. Smart pointers do make it easier for developers to author correct code - however, they are not free. There is a small (but real) overhead in allocating, copying, and destroying smart pointers when they are passed around.

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It should be noted that not all memory allocators in C++ use the same model when allocating/deallocating memory. Linked-lists are used in most default implementations, but optimized allocators like the one from Intel TBB use a memory pool partitioned into bins and most of the time the operations are not more complicated than incrementing a pointer. –  Gratian Lup Nov 27 '10 at 18:21
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The flaw in this analysis is that this just applies to dynamic storage - which you try to minimize in C++. –  sbi Dec 3 '10 at 9:16
    
@sbi: I wasn't trying to provide a comprehensive analysis of memory allocation strategies between C++ and C#. Rather, my goal was to show that it's not meaningful to try to compare memory allocation performance because of the significant differences between these languages and platforms. –  LBushkin Dec 3 '10 at 16:14
    
"However, the CLR then zeros out this memory" - No it doesn't. The page it requests from the OS is already zeroed out (it does a VirtualAlloc and moves live objects to this page and each allocation is a quick pointer bump). –  Zach Saw Dec 8 '10 at 13:57
    
You neglected to mention GC needs to handle Freachables too in your "releasing memory" part of CLR. –  Zach Saw Dec 8 '10 at 13:59

The reference-counting approach will delete objects and free memory as soon as they become unused. A mark-sweep GC will do some work to figure what's used and what isn't, and from time to time will delete some unused objects.

So the common C++ approach isn't necessarily less work in total, but it is predictable. You can work out exactly what destructors your performance-critical code calls (and perhaps arrange for this to be "none").

The unpredictability cuts both ways, of course. Supposing that the code you're interested in does allocate memory, with GC the VM might manage to defer destruction until the performance-critical code is finished, and the machine is idle. If so, the GC approach might in effect be faster. The same optimization could be done manually in C++, but the programmer would have to work out all the details.

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C/C++ memory pools do exactly this. Most webservers will grab a memory pool, allocate everything from that pool, and at the end of the web transaction recycle the entire pool. This is actually pretty easy to program with in both C and C++. –  Zan Lynx Nov 23 '10 at 20:07
    
@Zan: yes, that's right when you know you have enough memory to do everything without freeing anything. Garbage collectors take a best-guess, general approach. If they need to free memory, they will, and if they don't then you get the performance bonus. Typical C++ techniques both allow and force the programmer to decide the details. –  Steve Jessop Nov 23 '10 at 21:45

One thing no one seems to think about is cost to development. If performance was the final end game to everything, we'd all be writing in assembly language. Most language/platform/library features are going to incur a performance penalty versus longhand (C# vs C++ vs C vs assembly, ORMs vs hand rolled SQL). But the benefit comes in development time, ability to focus on core features vs "plumbing" and reduced errors.

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That is true, but one also has to remember that there are really good C++ developers that can write as quickly (and often better) than their C# counterparts. The language is merely the tool being used for the job, and just like any other tool, the ease and efficiency of the task being completed is always in the hands of the person wielding that tool. –  Will Nov 23 '10 at 16:59
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@Will: While you're certainly right, I have to admit that if the language is a tool, C# simple beauty might relate to an electric screwdriver, while C++ complexity relates to a modern jet plane. Yes, there's pilots out there which are really great, but there will always be more mediocre screwdriver users. (JFTR, I consider myself a good off-the-mill C++ pilot, but no flying wizard.) –  sbi Nov 23 '10 at 19:18
    
@sbi- Well said. As they say, beauty is in the eye of the beholder... Pointers might make people go crazy with happiness, but sometimes seeing too much dealloc() makes the code more complex. –  DMan Nov 23 '10 at 23:55
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@DMan: What's dealloc()? If it's a generic placeholder for freeing resources, then you must refer to C#. I think I haven't written delete (the C++ way to dealloc memory) more than thrice in a decade. See my comment to Jame's answer. –  sbi Nov 24 '10 at 5:53
    
@Will, while I agree with your point on really good C#/C++/etc developers, having jumped from project to project, job to job, my personal preference leans more towards readability since rarely is everyone dealing with the code really good. (Just my style, not saying it's how everyone should work) –  Rich Nov 24 '10 at 19:57

Personally, I like the syntax, inheritance model, and features (eg. anonymous methods) of C# over C++.

If I really needed the performance, I could go C++. But there's nothing my current projects can't do near instantaneous in C#.

I recently re-wrote an internal program that use to take 45min-2 hours on large customers. It was coded in .Net. I figured my program would be about as slow being that it is also in .Net, so I developed it as a multi-threaded program from the get-go. Turns out my version runs in under half a second, single threaded. I actually had to tweak the code to limit thread creation because of contention.

I use an abstract base class with virtual methods to make for clean/easy extendability.

All entries are stored in an array of structs, which means better use of cache lines and linear memory access for great prefetching. The struct is longer than 64bytes(cache line), so all flags and decision making variables are stored near each other at the beginning of the struct. This keeps them all with-in a single cache line, even on a 64bit system(references/pointers are larger on 64bit than 32bit)

I use a char array for string manipulation and String tmpString = new String(chTmpString, 0, TmpLength) for the result.

I re-use the same char array(per thread) instead of creating a new one for each row because I know strings are immutable, so it will just make a copy of the char array.

Instead of locking individual rows in the main array, I lock a variable that stores the current position in the array. Each thread will only lock this variable long enough to increment it by a fixed "stride" length. This means the lock only remains long enough to do a simple integer addition, then released and the thread works on that "block" of the array. eg say the current position is 0 in the array. Thread 0 locks and increments the position by 1024. Thread 0 now works on rows 0-1023 and the next thread locks and sees 1024, then increases by another 1024 to 2048, thread 1 then works on 1024 through 2047. This is in a loop, so each thread keep incrementing until the end of the array.

I also got to make use of anonymous methods. I have a multi-threaded logging class to write out to a file. Each thread requests a new "log" which is just a returned Action. This delegate is just an anonymous method that contains code to write to a specific Queue object created for that thread. The Logging class has a main thread that loops through a List> of all the Queue objects. Writing to the Log is lock-free since Queues are thread safe for single reader/writer. The reader loop and the method to return a new Action do actually have to be locked because the logic to add a new Queue to the List may cause the List to resize while the list is being read.

Logical design is much more important than the language. I'm sure it could be faster in C++, but C# is so nice and easy to debug.

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It sounds like the "performance-critical code" that you are talking about might be real-time code with stringent latency requirements. For example, a loop where every iteration of the loop must take no longer than a specified amount of time. In this case, a garbage collector could cause major problems, because if the GC starts working during the execution of the loop, the current iteration will be put on hold until GC is finished, and it will run over the time limit for that iteration. This is possible in C# because the language does not specify when GC is done or provide any way to directly influence the choice of when to do GC. Therefore, from the perspective of the programmer, garbage collection in C# is nondeterministic, and this makes it impossible to make any real-time guarantees on the code.

In contrast, C++ requires the programmer to take full control of object destruction, so the programmer can structure a program so that expensive deallocations will not occur during a performance-critical part of the code. "Garbage collection" in C++ is fully deterministic, and is defined in the language specification, allowing one to make much stronger real-time guarantees about C++ code than C# code.

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Generally from a perfomance point of view, the faster program will execute less instruction, So you can't say c# is faster than c++, and vice versa. it highly depends on implementation.

The more feature your language provides, the more trap you will meet.

People always says c# hasn't memory leak, that it really means that you needn't care about memory allocation and deallocation. However if you program incorrectly, the memory leak also occurs, because it's the programmer's duty to release reference of a object.If you want to write a high performance C# product, you will have to consider issues about memory eventually! for example, you can search "c# object pool" in stack overflow. Nowadays, PC usually has 2GB or 4GB memory, so GC can help you to deal with memory allocation and deallocation which is trivial to human, and it usually does better than human.

Conversely, C++ provides litter behind you, and you have ability to change anything. In other words, if benchmark shows the stadnard memory allocator is not good, you can write(most time google) one for you.

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In general (not talking specifically about C#) a GC will give you few advantages over smart pointers:

  • memory pooling (small objects are not allocated separately)
  • cyclical dependency resolution
  • serialization and de-serialization support
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what does GC have to do with serialization support? If anything that is more of a reflection issue. –  Evan Teran Nov 23 '10 at 16:07
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@Evan Serialization of pointers. –  Let_Me_Be Nov 23 '10 at 16:28

I just finished a C# program, to calculate the possible formulations for a "Constraint Satisfying Problem", that took really hard on the processor side and memory allocation, with a lot of recursive functions. The initial program in C# took 2m30s to a given task. After a lot of algorithm optimizations, it took 2s to this same task. I was trying every trick I could afford, because the software still can't find a solution in less than some months, in my Intel Quad Core. Then, I translated it to C++, to compile it with an Intel compiler, with great hopes to have some perfomance gains. To my surprise, it took 29s for that task! After some profiling, I found that most of the time, it was the STL vector iterator that was tooking all this time. So, I wrote my own "rawvector", that basicly didn't check anything, and just trust me for no faults. So it went to 7s. Still, not the C# 2s. Again, I ran the profiler. Guess what was tooking most time? The delete command, to deallocate memory. At this is stage, there was not much left to optimize.

So, in my case, with a lot of recursion and memory allocation, the C# was faster. Now, after wondering why this happened, it can well be the batch allocation/deallocation that managed code does. For the other thing, it also may be that since C# doesn't allow free messing with pointers, the under the hood allocation functions trusts themselves more, and doesn't do many checks. That may be why a "simple" function like delete could take most CPU time for my software.

I'm not a fan of any language. In fact, it was a surprise, since I hoped C++ would be faster.

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A lot of good points here, but one I didn't see mentioned is the importance of "jitter" -- i.e. variation in latency. For trading-type applications, low latency is very important, but almost as important is that the latency be predictable, with as little variation as possible.

In my experience, while minimum and average latency can be similar between C/C++ and Java (dont know about C#/.Net), Java tends to have much higher peaks and many more outliers (i.e., higher standard deviation). In almost all cases that I've investigated this has been due to GC.

Jitter due to GC can be minimized or eliminated by using techniques such as re-using objects, but once you head down that road you lose much of the (alleged) productivity benefits of GC languages like Java.

A good presentation by Martin Thompson (of LMAX Disruptor fame) can be found here

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From http://herbsutter.com/2012/04/02/reader-qa-when-will-better-jits-save-managed-code/

C++ and managed languages make different fundamental tradeoffs that opt for either performance or productivity when they are in tension.

... managed languages chose to incur costs even for programs that don’t need or use a given feature; the major examples are assumption/reliance on always-on or default-on garbage collection, a virtual machine runtime, and metadata. But there are other examples; for instance, managed apps are built around virtual functions as the default, whereas C++ apps are built around inlined functions as the default, and an ounce of inlining prevention is worth a pound of devirtualization optimization cure.

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The GC and smart pointers are not really the same thing in operation. The GC is separately running code on another thread that cleans up memory that is no longer freed. The results are non-deterministic. On the other hand a smart pointer is more of a deterministic construct that frees memory when it is no longer. A simple example of a smart pointer is in the use of a local variable on the stack. The compiler actually generates the code that frees the associated memory. With the smart pointer, you know that the memory is freed in that case when it goes out of scope. With garbage collection, there is no guarantee when it will be freed.

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From this, it sounds like smart pointers are an implementation of reference-counting garbage collection. Is this right? –  Ryan Thompson Nov 23 '10 at 22:06
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@Ryan, It probably becomes a semantics issue. I suppose one could refer to smart pointers as a type of garbage collection. However, in my (possibly limited) experience, the term "garbage collection" typically refers to an active separate process/thread that performs the cleanup. Note that not all smart pointers use reference counting. For example, an auto_ptr simply owns the object. –  Mark Wilkins Nov 24 '10 at 15:14

The GC is C# takes care of cleaning up the memory, the performance penalty is not merely allocate and delete the object but figure out when a object can be deleted.

The GC is using complex algorithm to spot circular reference (some of them are O(N^2) ) and it also spend time clean up the free store.

The c++ smart pointer task is much simpler and all the smart pointer operations take constant time.

Also C++ offer you flexible way to improve allocation performance. For example the Loki small object are using 10-20 times less time than the standard new operator.

C++ also allowed you to implement the copy-assign strategy that best fit your requirements. If you want you can use the "unsafe" code also in C# but as the keyword suggest you probably need to think it carefully.

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Why does a GC bother about circular refs? Dis you mean a ref-counter? –  Henk Holterman Nov 23 '10 at 16:01
    
And I think that Loki system only approaches the speed of getting a new object in C# (1 pointer change). –  Henk Holterman Nov 23 '10 at 16:02
    
@Henk, If you have a class with references to itself without circular reference checking it can never be deleted. –  Jay Nov 23 '10 at 16:21
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The answer is a little biased. You take into account the cost of garbage collection on one side, but neglect the cost of allocation in the other. When you come back to allocation you determine that a small object allocator can be made as fast as GC allocations --true--, but you avoid mentioning the memory fragmentation that it would produce if you tried that approach for all object sizes... If generic allocators are expensive is because the problem itself is hard, small allocators are a solution for only a subset of the general problem. Many really smart people have worked in allocators. –  David Rodríguez - dribeas Nov 23 '10 at 17:37
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"The GC is doing a complex job" -- but called very infrequently, and gen1 calls are quite fast. "the smart pointer are doing a very simple task" -- but extremely time consuming (interlocked ops to ensure thread safety) and called /very/ frequently. From my experience in designing precise GC in C++ with parallel mark and generational collection, moving/assigning smart_ptrs are 15 times slower than my gc_ptrs. –  Zach Saw Dec 9 '10 at 1:17

You can always download a garbage collector framework\ library for C++ and if for some reason you don't like it you can change her.

Is there any other GC implementation for .Net?

And there's a huge difference between automatic pointers and GC. GC will collect a bunch of dead pointers and kill them together (not always when you delete the pointer) which results better performance, automatic pointers will be deleted when the scope you reach the end of the scope.

And... I could never understand what is so hard to manage your pointers?

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"Is there any other GC implementation for .Net?" -- yes, Mono has 2 different GC implementations - BoehmGC and SGen-GC. Plus the GC variants you get from Microsoft (Server / desktop / compact), that's a lot (although you don't get to choose, unlike Mono's). How many C++ GC frameworks do you know of that is fully swappable without requiring you to rewrite some of your code? –  Zach Saw Dec 9 '10 at 1:40
    
Not to mention that BoehmGC doesn't work in Wow64 (see Wow64 in wiki)! –  Zach Saw Dec 9 '10 at 1:40
    
Each time we, the C++ advocates are pinned to the wall we love to use our "C++ is not a one solution programming language" card, to standardize the GC is to force a single solution. –  ManicQin Dec 11 '10 at 8:39

C++ is bit speedy cause it directly executes on Operating System. because of that reason any application which intends to target the performance ought to move with C++ but C# in other hand it's codes execute on CLR which is the major part of .NET frame work and then those codes interact with the operating system. in fact it reduces the performance since there are couple of layers above operating system. but it is not considerable for regular desktop applications since nowadays hardware are powerful. but if you concern about video games, scientific apps it's always better performance demand parts are codded with C++ and use C# for coding the user interfaces. C++ is bit hard to learn but actually it's easy for me I meant only the pure C++ not with windows API. cause most of the time you need to write everything from scratch unlike c# in which automated generated codes do everything and you know only few you know nothing about the behind the scene. but with C++ you know what you do from the beginning unless you use something like QT.

I suggest you never use C++ for developing desktop applications unless you use something like QT /gtkmm /wxwdiget cause C++ is a pain in @ss you mostly mess up with unnecessary parts like memory management, write various kind of algorithm in which you can do easily with C# with couple of methods. humans live only 80~120 years so if you waste your time with unnecessary things it wouldn't be so good. now u think u use C++ and implement an complex algorithm which can do cool things but what would happen if it has been already implemented by someone else.? then u got nothing. it likes reinvent the wheel. if someone has developed something use it don't try to be hero by developing everything from scratch.

C# is a powerful language for windows platform but if you want to move with cross platform use C++/QT ,I personally don't like Java since it executes everything on their JVM so u got their interface,their Java banners everywhere even on ur application yeah u can create .exe file with java I know but it's not easy for everyone and take time. ignore the Java as much as possible. C# is powerful and use it on Windows for business /regular desktop applications and user interfaces for video games. but use C++ for coding core of the video games, high performance scientific applications, computer systems. so each language has advantage and disadvantage. I actually like someone makes a language much like C#(syntax) but has C++ performance.

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If you are willing to provide advanced programming constructs, C++ can always outperform C#; however you most likely don't need it and might not be able to afford enough good C++ programmers.

Anybody who refers to C# being able to allocate memory faster is probably ignoring the cost of the GC. The few that remain have never seen arena memory management. Also, if C++ code is allowed to waste RAM like the GC is, than the buddy allocator may be used, which is still log(N) allocation cost; but N is capped at 64 (N is now the number of distinct powers of two of memory sizes required).

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In my experience C++ for 99% of day-to-day programming, is a complete and utter overkill. In some cases just a 'Rockstar' vanity. I'm an average developer, but I've been around for a while. The truth of it is that most of us are not Rockstars, and trying to manage a lot of 'ordinary' C++ is an order of magnitude more difficult than any managed/dynamic language.

I've been called in on a number of projects in which the first order of business was going from C++ to C#. The worst system wide performance degradation was 2-5%.

There are things that C++ should be used for. Drivers, 3D engines, really bare metal stuff, but most of us don't do that, we push and pull data across a wire, and every now and again we transform it a little.

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What C++ gives you that C# doesn't is control over when and where memory is allocated and freed. For many applications garbage collection is a good choice. For some kinds of applications with hard or soft realtime performance requirements (e.g. video games, my industry) there are situations where garbage collection is undesirable. C++ gives you full control over memory allocation when you need it and that is one of the reasons it is still the dominant language in AAA game development and some other industries.

Going back a few years, console games were often developed with a hard rule of no heap allocation allowed during gameplay. When you have 16.67ms to render a frame, a hard cap on the amount of memory available (no virtual memory) and the relatively low powered hardware of older generation consoles that was pretty much a requirement to achieve acceptable performance and stability.

With today's systems with significantly more memory, more sophisticated general purpose allocators and faster processors that rule is rarely enforced so strictly but certain particularly performance critical subsystems (like rendering) will often still use special purpose allocation routines rather than doing dynamic allocation through a general purpose allocator.

A typical modern console game will make use of a variety of different memory allocation strategies in different subsystems, tailored to the specific needs of those subsystems. The renderer might use a simple per-thread bump / linear allocator backed by a triple-buffered pool cycled per frame, the job dispatch system might use fast thread local heaps or an atomic linear allocator, the asset streamer might use a system that supports efficient in-place loading and fix-ups as well as relocation for defragmentation. Non performance critical gameplay code might use its own heap with a simple non-thread safe allocator. There will probably be some non performance critical code that uses a general purpose thread-safe allocator. Generally many games still keep separate memory pools for separate systems to make it easier to enforce memory budgets although that is becoming less common as consoles come with increasing amounts of RAM.

The point is that C++ gives you this level of control over memory allocation and lets you tailor it to your needs. It also gives you predictability and control over when and where allocations take place. It requires more engineering effort to customize your allocation strategies to this degree but in certain applications the performance tradeoffs are worth it. While GC in C# is great in most situations, you're much more limited in what you can do in those situations where it has undesirable performance characteristics.

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In a way, C++ is the most powerful, "portable macro assembler" ever built. You can compile it down to native machine code, in this case you can do anything with it and be faster or slower than C# (depending on your skill level).

The price good C++ programmers willingly pay for it is having to know what they're doing. C# on the other hand does useful things for you that happen behind the scenes, such as e.g. memory management. C++ programmers have to be aware of those things.

The "magic" performed by any higher-level programming language can be implemented in a near impossible number of ways. In C++ you are free to do so. In those higher-level languages things have been implemented for you - in just one way.

Still any doubts that C++ is eventually faster? Imagine writing an operating system - and - if that's not enough; a programming language with garbage collection on top of it ;).

Now to the specific questions:

  1. If you destroy a smart pointer instance in performance critical code the destructor of the pointee might be called and its memory freed. But why would you let this happen? IOW - there is typically no background thread involved in reference counting.
  2. Calling delete is not always required. You can allocate almost anything on the stack, in this case it's not (forbidden, even) and allocation/deallocation is as simple as one add instruction each. Also, as mentioned elsewhere in this thread, you can implement custom memory management. Doing so is common practice for performance critical code that needs dynamic memory. E.g. let's say we need to allocate and free fixed-sized objects from within some threads, each a certain maximum number thereof. Every thread can get its own memory manager implemented as two pointers, one to the base of yet-untouched memory and another one to an (intrusive) single linked list of the freed objects. The net effect over a generic garbage collector that has to check for all possibilities, not knowing the constraints that led to our custom design can be dramatic.
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The destructor to an object in a smart pointer will be called when every smart pointer to said object will go out of scope, while the GC kicks in whenever it feels like.

So, if during your performance critical code no smart pointers go out of scope, then no destructor will be called.

The NET effect is that a garbage collector will have to check every object you ever created, then look if any references to it are left and if not, remove the object. Without a GC, you only do the last step, that is, remove the object.

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