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I've been wondering about this issue for a while now.

Of course there are things in C# that aren't optimized for speed, so using those objects or language tweaks (like LinQ) may cause the code to be slower.

But if you don't use any of those tweaks, but just compare the same pieces of code in C# and C++ (It's easy to translate one to another). Will it really be that much slower ?

I've seen comparisons that show that C# might be even faster in some cases, because in theory the JIT compiler should optimize the code in real time and get better results:

Managed Or Unmanaged?

We should remember that the JIT compiler compiles the code at real time, but that's a 1-time overhead, the same code (once reached and compiled) doesn't need to be compiled again at run time.

The GC doesn't add a lot of overhead either, unless you create and destroy thousands of objects (like using String instead of StringBuilder). And doing that in C++ would also be costly.

Another point that I want to bring up is the better communication between DLLs introduced in .Net. The .Net platform communicates much better than Managed COM based DLLs.

I don't see any inherent reason why the language should be slower, and I don't really think that C# is slower than C++ (both from experience and lack of a good explanation)..

So, will a piece of the same code written in C# will be slower than the same code in C++ ?
In if so, then WHY ?

Some other reference (Which talk about that a bit, but with no explanation about WHY):

Why would you want to use C# if its slower than C++?

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18  
It depends .... –  Brian Rasmussen Mar 16 '11 at 13:50
    
Because C# is much easier to use than C++, especially when GUI is concerned –  Armen Tsirunyan Mar 16 '11 at 13:51
2  
Really... It depends... Some things are faster, some are slower. C/C++ is more "deterministic" (no garbage collector at your back). If you want to spawn 100 threads I can tell you that the GC will haunt you with his slowness (and before telling me that 100 threads are too many, know that Skype and the McAfee AV are each at 40 threads now on my PC)... Marshaling in C# is a pain (and it's slower). Coding is quite fast. No, this isn't a flame. I truly prefer C#. –  xanatos Mar 16 '11 at 13:56
1  
I think this should be edited and reopened. I think the question asker might not understand that a more fundamental question impacts performance differences between C# and languages like C or C++, which would be "What's the difference between code generated (and how it's executed) by a C compiler and code generated by the C# compiler?" C#/Java and other interpreted or VM languages may have several intermediary steps when running their bytecode that are totally absent in an equivalent C program. –  Jonathon Faust Mar 16 '11 at 14:04
2  
While you could argue that (as stated) this qualifies as "not a real question", claiming it's subjective is nonsensical. "Is A faster than B" is something that's open to objective measurement. Even if the answer obtained by such measurement is ambiguous (some things are faster in one, some in the other), it's still objective. –  Jerry Coffin Mar 16 '11 at 14:23

9 Answers 9

up vote 89 down vote accepted

Warning: The question you've asked is really pretty complex -- probably much more so than you realize. As a result, this is a really long answer.

From a purely theoretical viewpoint, there's probably a simple answer to this: there's (probably) nothing about C# that truly prevents it from being as fast as C++. Despite the theory, however, there are some practical reasons that it is slower at some things under some circumstances.

I'll consider three basic areas of differences: language features, virtual machine execution, and garbage collection. The latter two often go together, but can be independent, so I'll look at them separately.

Language Features

C++ places a great deal of emphasis on templates, and features in the template system that are largely intended to allow as much as possible to be done at compile time, so from the viewpoint of the program, they're "static." Template meta-programming allows completely arbitrary computations to be carried out at compile time (I.e., the template system is Turing complete). As such, essentially anything that doesn't depend on input from the user can be computed at compile time, so at runtime it's simply a constant. Input to this can, however, include things like type information, so a great deal of what you'd do via reflection at runtime in C# is normally done at compile time via template metaprogramming in C++. There is definitely a trade-off between runtime speed and versatility though -- what templates can do, they do statically, but they simply can't do everything reflection can.

The differences in language features mean that almost any attempt at comparing the two languages simply by transliterating some C# into C++ (or vice versa) is likely to produce results somewhere between meaningless and misleading (and the same would be true for most other pairs of languages as well). The simple fact is that for anything larger than a couple lines of code or so, almost nobody is at all likely to use the languages the same way (or close enough to the same way) that such a comparison tells you anything about how those languages work in real life.

Virtual Machine

Like almost any reasonably modern VM, Microsoft's for .NET can and will do JIT (aka "dynamic") compilation. This represents a number of trade-offs though. First, almost every VM (including Microsoft's, I believe) attempts to make intelligent decisions about what to compile and what to interpret. It does this by interpreting the code the first few times it's encountered. It profiles how often it's interpreting particular code, and when it exceeds a certain threshold, figures it's likely to execute enough more that it's worth compiling it to gain execution speed. This has an obvious problem: once in a while, it can guess wrong -- you have a lot of code that executes just often enough to trigger compilation, but then never gets used again, you're losing pretty badly: nearly all your execution is via the slow, interpreted path, then you pay the price of compilation, but then you get no benefit from the compilation. In fairness, I should add that this is pretty unusual in normal code, but if you actually want to, it's usually pretty easy to trigger it.

Second, optimizing code (like most other optimization problems) is largely an NP-complete problem. For anything but a truly trivial/toy program, you're pretty nearly guaranteed you won't truly "optimize" the result (i.e., you won't find the true optimum) -- the optimizer will simply make the code better than it was previously. Quite a few optimizations that are well known, however, take a substantial amount of time (and, often, memory) to execute. With a JIT compiler, the user is waiting while the compiler runs. Especially when coupled with the first problem (possibility of deriving little or no benefit from compilation), most of the more expensive optimization techniques are ruled out. Static compilation has two advantages: first of all, if it's slow (e.g., building a large system) it's typically carried out on a server, and nobody spends time waiting for it. Second, an executable can be generated once, and used many times by many people. The first minimizes the cost of optimization; the second amortizes the much smaller cost over a much larger number of executions.

As mentioned in the original question (and many other web sites) JIT compilation does have the possibility of greater awareness of the target environment, which should (at least theoretically) offset this advantage. There's no question that this factor does offset at least part of the disadvantage of static compilation. For a few rather specific types of code and target environments, it can even outweigh the advantages of static compilation. At least in my testing and experience, however, this is fairly unusual. Target dependent optimizations mostly seem to either make fairly small differences, or can only be applied (automatically, anyway) to fairly specific types of problems.

Using a VM also has a possibility of improving cache usage. Instructions for a VM are often more compact than native machine instructions. More of them can fit into a given amount of cache memory, so you stand a better chance of any given code being in cache when needed. This can help keep interpreted execution of VM code more competitive (in terms of speed) than most people would initially expect -- you can execute a lot of instructions on a modern CPU in the time taken by one cache miss.

It's also worth mentioning that this factor isn't necessarily different between the two at all. There's nothing preventing (for example) a C++ compiler from producing output intended to run on a virtual machine (with or without JIT). In fact, Microsoft's C++/CLI is nearly that -- an (almost) conforming C++ compiler (albeit, with a lot of conforming extensions) that produces output intended to run on a virtual machine. The reverse is probably also true: in theory a C# compiler that produced native code should be possible as well.

Garbage Collection

From what I've seen, I'd say garbage collection is the poorest-understood of these three factors. Just for an obvious example, the question here mentions: "GC doesn't add a lot of overhead either, unless you create and destroy thousands of objects [...]". In reality, if you create and destroy thousands of objects, the overhead from garbage collection will generally be fairly low. .NET uses a generational scavenger, which is a variety of copying collector. The garbage collector works by starting from "places" (e.g., registers and execution stack) that pointers/references are known to be accessible. It then "chases" those pointers to objects that have been allocated on the heap. It examines those objects for further pointers/references, until it has followed all of them to the ends of any chains, and found all the objects that are (at least potentially) accessible. In the next step, it takes all of the objects that are (or at least might be) in use, and compacts the heap by copying all of them into a contiguous chunk at one end of the memory being managed in the heap. The rest of the memory is then free (modulo finalizers having to be run, but at least in well-written code, they're rare enough that I'll ignore them for the moment).

What this means is that if you create and destroy lots of objects, garbage collection adds very little overhead. The time taken by a garbage collection cycle depends almost entirely on the number of objects that have been created but not destroyed. The primary consequence of creating and destroying objects in a hurry is simply that the GC has to run more often, but each cycle will still be fast. If you create objects and don't destroy them, the GC will run more often and each cycle will be substantially slower as it spends more time chasing pointers to potentially-live objects, and it spends more time copying objects that are still in use.

To combat this, generational scavenging works on the assumption that objects that have remained "alive" for quite a while are likely to continue remaining alive for quite a while longer. Based on this, it has a system where objects that survive some number of garbage collection cycles get "tenured", and the garbage collector starts to simply assume they're still in use, so instead of copying them at every cycle, it simply leaves them alone. This is a valid assumption often enough that generational scavenging typically has considerably lower overhead than most other forms of GC.

"Manual" memory management is often just as poorly understood. Just for one example, many attempts at comparison assume that all manual memory management follows one specific model as well (e.g., best-fit allocation). This is often little (if any) closer to reality than many peoples' beliefs about garbage collection (e.g., the widespread assumption that it's normally done using reference counting).

Given the variety of strategies for both garbage collection and manual memory management, it's quite difficult to compare the two in terms of overall speed. Attempting to compare the speed of allocating and/or freeing memory (by itself) is pretty nearly guaranteed to produce results that are meaningless at best, and outright misleading at worst.

Bonus Topic: Benchmarks

Since quite a few blogs, web sites, magazine articles, etc., claim to provide "objective" evidence in one direction or another, I'll put in my two-cents worth on that subject as well.

Most of these benchmarks are a bit like teenagers deciding to race their cars, and whoever wins gets to keep both cars. The web sites differ in one crucial way though: they guy who's publishing the benchmark gets to drive both cars. By some strange chance, his car always wins, and everybody else has to settle for "trust me, I was really driving your car as fast as it would go."

It's easy to write a poor benchmark that produces results that mean next to nothing. Almost anybody with anywhere close to the skill necessary to design a benchmark that produces anything meaningful, also has the skill to produce one that will give the results he's decided he wants. In fact it's probably easier to write code intended to produce a specific result than code that will really produce meaningful results.

As my friend James Kanze put it, "never trust a benchmark you didn't falsify yourself."

Conclusion

There is no simple answer. I'm reasonably certain I could flip a coin and roll a pair of dice to pick a winner and percentage by which it would win, and write a seemingly fair benchmark in which the chosen language won by the chosen percentage.

As others have pointed out, for most code, speed is almost irrelevant. The corollary to that (which is much more often ignored) is that in the little code where speed does matter, it usually matters a lot. At least in my experience, for the code where it really does matter, C++ is almost always the winner. There are definitely factors that favor C#, but in practice they seem to be outweighed by factors that favor C++. You can certainly find benchmarks that will indicate the outcome of your choice, but when you write real code, you can almost always make it faster in C++ than in C#. It might (or might not) take more skill and/or effort to write, but it's virtually always possible.

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1  
+1 awesome answer –  sleske Mar 21 '11 at 17:50
5  
At a previous company, a few of our decisions were based on benchmarking, but the benchmarking was poorly done because it missed the bigger picture (e.g. impact on the GC) or was just badly done. Beware benchmarking... it's tempting to make decisions based on stuff done out of context. If you do benchmark, then try to make it as representative as possible :) –  Mark Simpson Apr 9 '11 at 21:19
3  
IIRC, .NET runtime never interpret but always JIT. The optimization is done by both compiler at compile time (source code to IL) and jitter at runtime (IL to native instructions). The jitter may choose not to optimize if a method will take too long to jit. If complete optimization is required, you can use NGen to generate native image at installation time. –  Dudu Nov 15 '11 at 8:50
2  
@Mehrdad: Yup -- that's the sort of thing I was thinking of what I said: "you can almost always make it faster in C++ than in C#. It might (or might not) take more skill and/or effort to write, but it's virtually always possible." –  Jerry Coffin Aug 2 '13 at 1:47
1  
@Kr0e: no, malloc and free aren't (normally) kernel functions. Typically, malloc will occasionally allocate a big block of memory from the OS, and calling malloc will give pieces of that. If you allocate a huge chunk of memory at once, that'll often be passed through to the OS though. –  Jerry Coffin Apr 29 at 23:23

Because you don't always need to use the (and I use this loosely) "fastest" language? I don't drive to work in a Ferrari just because it's faster...

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1  
+1 for refreshing analogy! –  Srinivas Reddy Thatiparthy Mar 16 '11 at 13:54
    
I liked the analogy. +1 –  Nawaz Mar 16 '11 at 14:27
11  
I think this analogy is very apt. If I drove a Ferrari to work, I wouldn't get to work any faster. The car is certainly capable of going faster than what I drive, but the vehicle's capability isn't the limiting factor. There are speed limits, traffic, road conditions, etc. Similarly, software is usually bound by things such as user interaction, I/O, etc. What language you use won't make much difference in such cases. –  Fred Larson Mar 16 '11 at 14:45
12  
Then why do you drive to work in a Ferrari? C'mon, don't leave us hanging... –  Andrzej Doyle Mar 16 '11 at 17:30
    
Well, but the question was "Which of the cars is a Ferrari, and which is Volkswagen?" or if both are Ferrari or not. –  pepr Oct 9 '13 at 12:19

C++ always have an edge for the performance. With C#, I don't get to handle memory and I have literally tons of resources available for me to do my job.

What you need to question yourself is more about which one saves you time. Machines are incredibly powerful now and most of your code should be done in a language that allows you to get the most value in the least amount of time.

If there is a core processing that takes way too long in C#, you could then build a C++ and interop your way to it with C#.

Stop thinking about your code performance. Start building value.

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6  
+1 for "Stop thinking about your code performance. Start building value." –  Thomas Matthews Mar 16 '11 at 18:53
    
I agree about the speed of development in C#. It's much more valuable in a lot of cases. –  Yochai Timmer Mar 16 '11 at 22:26

BTW, time critical applications are not coded in C# or Java, primarily due to uncertainty of when the Garbage Collection will be performed.

In modern times, application or execution speed is not as important as was previously. Development schedules, correctness and robustness are higher priorities. A high speed version of an application is no good if it has lots of bugs, crashes a lot or worse, misses an opportunity to get to market or be deployed.

Since development schedules are a priority, new languages are coming out that speed up development. C# is one of these. C# also assists in correctness and robustness by removing features from C++ that cause common problems: one example is pointers.

The differences in execution speed of an application developed with C# and one developed using C++ is negligible on most platforms. This is due to the fact that the execution bottlenecks are not language dependent but usually depend on the operating system or I/O. For example if C++ performs a function in 5 ms but C# uses 2ms, and waiting for data takes 2 seconds, the time spent in the function is insignificant compared to the time waiting for data.

Choose a language that is best suited for the developers, platform and projects. Work towards the goals of correctness, robustness and deployment. The speed of an application should be treated as a bug: prioritize it, compare to other bugs, and fix as necessary.

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My understanding is that C# (Java too?) doesn't 'remove' the existence/concept of pointers so much as hide them from the programmer by an abstraction of sorts via the actual syntax. This is a fairly inconsequential point though. The relative simplicity of C# is indisputable. –  Mike G Oct 18 '12 at 9:09

C# is faster than C++. Faster to write. For execution times, nothing beats a profiler.

But C# does not have as much libraries as C++ can interface easily.

And C# depends heavily on windows...

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3  
C# requires a lot more support from the compiler, OS and platforms. A HUGE concern for embedded systems. –  Thomas Matthews Mar 16 '11 at 18:52

Widely discussed, see [c#] [performance]

but much depends on the application and implementation.

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Why would you write a small application that doesn't require much in the way of optimization in C++, if there is a faster route(C#)?

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Getting an exact answer to your question is not really possible unless you perform benchmarks on specific systems. However, it is still interesting to think about some fundamental differences between programming languages like C# and C++.

Compilation

Executing C# code requires an additional step where the code is JIT'ed. With regard to performance that will be in favor of C++. Also, the JIT compiler is only able to optimize the generated code within the unit of code that is JIT'ed (e.g. a method) while a C++ compiler can optimize across method calls using more aggressive techniques.

However, The JIT compiler is able to optimize the generated machine code to closely match the underlying hardware enabling it to take advantage of additional hardware features if they exist. To my knowledge the .NET JIT compiler doesn't do that but it would conceiveably be able to generate different code for Atom as opposed to Pentium CPU's.

Memory access

The garbage collected architecture can in many cases create more optimal memory access patterns than standard C++ code. If the memory area used for the first generation is small enough in can stay within the CPU cache increasing performance. If you create and destroy a lot of small objects the overhead of maintaing the managed heap may be smaller than what is required by the C++ runtime. Again, this is highly dependent on the application. A study Python of performance demonstrates that a specific managed Python application is able to scale much better than the compiled version as a result of more optimal memory access patterns.

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There's an extra step for the JIT to compile the code, but because of the rule of re-use you'll probably use that piece of code 10000s of times more than that single compilation. (example: loops). So there's a question if the JIT did a good enough job to compinsate for that intial compilation. –  Yochai Timmer May 11 '11 at 12:43

C# is way faster in any case against C++. I was doing very simple benchmark and I found that C++ is very very slow.

C# test case:

using System;

class X 
{
    public static int Main (string [] args)
    {
        Stopwatch s = new Stopwatch();
        s.Start();

        for (var i = 0; i < 100000000; i++)
        {
        }

        s.Stop();

        Console.WriteLine("Elapsed {0} ms.", s.Elapsed.TotalMilliseconds);

        return 0;
    }
} 

C#: Elapsed 7.4056 ms.

C++ test case: (compiled with g++ 4.8)

#include <stdio.h>
#include <time.h>

int main(int argc, char** args) {

    auto b = clock();

    for (long i = 0; i < 100000000; i++)
    {
    }

    auto e = clock();

    printf("Elapsed %d ms.\r\n", e-b);

    return 0;
}

C++: Elapsed 177 ms. (and if you compile with clang++.exe then 190 ms)

So we can see that C# 25 times faster on simple for loop. Even if you use "register long i" instead of "long i" it takes 30 ms against 7-8 ms of C# so C# 4-5 times faster then C++

Next test even worse.

using System;
using System.Diagnostics;

class S
{
    public static int count;

    public S()
    {
        count++;
    }
}

class X 
{
    public static int Main (string [] args)
    {
        Stopwatch s = new Stopwatch();

        s.Start();

        for (var i = 0; i < 10000001; i++)
        {
            var ss = new S();
        }

        s.Stop();

        Console.WriteLine("Elapsed {0} ms.", s.Elapsed.TotalMilliseconds);
        Console.WriteLine("Count {0}", S.count);

        return 0;
    }
} 

Result

Elapsed 50.9168 ms.
Count 10000001

and corresponding C++ test:

#include <stdio.h>
#include <time.h>

class S
{
    public:
        S()
        {
            count++;
        }

    static int count;
};

int S::count = 0;

int main(int argc, char** args) {

    auto b = clock();

    for (long i = 0; i < 100000001; i++)
    {
        auto ss = new S();
    }

    auto e = clock();

    printf("Elapsed %ld ms.\r\n", e-b);

    printf("Count %d\r\n", S::count);

    return 0;
}

and Result: (test was compiled with -O2 optimization, g++.exe -o class.exe class.cpp -lstdc++ -march=i686 -std=c++11 -O2)

Elapsed 4361 ms.
Count 100000001

So roughly C# 100 times faster allocating memory than C++. In this case I want to ask a question, is there any task which C++ can do faster then C# if simple iteration and memory allocation are significantly faster?

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