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Compiling a C++ file takes a very long time when compared to C#, Java. It takes significantly longer to compile a C++ file than it would to run a normal size Python script. I'm current using VC++ but it's the same with any compiler. Why is this?

The two reasons I could think of were loading header files and running the preprocessor, but that doesn't seem like it should explain why it takes so long.

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21  
VC++ supports precompiled headers. Using them will help. A lot. –  Brian Nov 25 '08 at 19:21
    
Yes in my case (mostly C with a few classes - no templates) precompiled headers speed up about 10x –  Lothar Sep 8 '09 at 10:13
    
@Brian I would never use a pre compiled head in a library though –  Cole Johnson Nov 26 '12 at 0:05

11 Answers 11

up vote 501 down vote accepted

Several reasons:

  • Header files: Every single compilation unit requires hundreds or even thousands of headers to be 1: loaded, and 2: compiled. Every one of them typically has to be recompiled for every compilation unit, because the preprocessor ensure that the result of compiling a header might vary between every compilation unit. (A macro may be defined in one compilation unit which changes the content of the header).

    This is probably the main reason, as it requires huge amounts of code to be compiled for every compilation unit, and additionally, every header has to be compiled multiple times (once for every compilation unit that includes it)

  • Linking: Once compiled, all the object files have to be linked together. This is basically a monolithic process that can't very well be parallelized, and has to process your entire project.

  • Parsing: The syntax is extremely complicated to parse, depends heavily on context, and is very hard to disambiguate. This takes a lot of time

  • Templates: In C#, List<T> is the only type that is compiled, no matter how many instantiations of List you have in your program. In C++, vector<int> is a completely separate type from vector<float>, and each one will has to be compiled separately.

    Add to this that templates make up a full turing-complete "sub-language" that the compiler has to interpret, and this can become ridiculously complicated. Even relatively simple template metaprogramming code can define recursive templates that create dozens and dozens of template instantiations. Templates may also result in extremely complex types, with ridiculously long names, adding a lot of extra work to the linker. (It has to compare a lot of symbol names, and if these names can grow into many thousand characters, that can become fairly expensive).

    And of course, they exacerbate the problems with header files, because templates generally have to be defined in headers, which means far more code has to be parsed and compiled for every compilation unit. In plain C code, a header typically only contains forward declarations, but very little actual code. In C++, it is not uncommon for almost all the code to reside in header files.

  • Optimization: C++ allows some very dramatic optimizations. C# or Java don't allow classes to be completely eliminated (they have to be there for reflection purposes), but even a simple C++ template metaprogram can easily generate dozens or hundreds of classes, all of which are inlined and eliminated again in the optimization phase.

    Moreover, a C++ program must be fully optimized by the compiler. A C# program can rely on the JIT compiler to perform additional optimizations at load-time, C++ doesn't get any such "second chances". What the compiler generates is as optimized as it's going to get.

  • Machine code: C++ is compiled to machine code which may be somewhat more complicated than the bytecode Java or .NET use (especially in the case of x86).
    (This is mentioned out of completeness only because it was mentioned in comments and such. In practice, this step is unlikely to take more than a tiny fraction of the total compilation time.)

Most of these factors are shared by C code, which actually compiles fairly efficiently. The parsing step is a lot more complicated in C++, and can take up significantly more time, but the main offender is probably templates. They're useful, and make C++ a far more powerful language, but they also take their toll in terms of compilation speed.

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37  
couldn't have said it better... –  Nils Pipenbrinck Nov 25 '08 at 18:55
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Regarding point 3: C compilation is noticably faster than C++. It's definitely the frontend that causes the slowdown, and not the code generation. –  Tom Dec 7 '08 at 7:02
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Regarding templates: not only vector<int> must be compiled separatedly from vector<double>, but vector<int> is recompiled in each compilation unit that uses it. Redundant definitions are eliminated by the linker. –  David Rodríguez - dribeas Dec 31 '08 at 14:16
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dribeas: True, but that's not specific for templates. Inline functions or anything else defined in headers will be recompiled everywhere it's included. But yeah, that's especially painful with templates. :) –  jalf Dec 31 '08 at 15:09
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@configurator: Visual Studio and gcc both allow for precompiled headers, which can bring some serious speed-ups to the compilation. –  small_duck Mar 2 '09 at 0:10

The slowdown is not necessarily the same with any compiler.

I haven't used Delphi or Kylix but back in the MS-DOS days, a Turbo Pascal program would compile almost instantaneously, while the equivalent Turbo C++ program would just crawl.

The two main differences were a very strong module system and a syntax that allowed single-pass compilation.

It's certainly possible that compilation speed just hasn't been a priority for C++ compiler developers, but there are also some inherent complications in the C/C++ syntax that make it more difficult to process. (I'm not an expert on C, but Walter Bright is, and after building various commercial C/C++ compilers, he created the D language. One of his changes was to enforce a context-free grammar to make the language easier to parse.)

Also, you'll notice that generally Makefiles are set up so that every file is compiled separately in C, so if 10 source files all use the same include file, that include file is processed 10 times.

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6  
It's interesting to compare Pascal, since Niklaus Wirth used the time it took the compiler to compile itself as a benchmark when designing his languages and compilers. There is a story that after carefully writing a module for fast symbol lookup, he replaced it with a simple linear search because the reduced code size made the compiler compile itself faster. –  Dietrich Epp Dec 17 '12 at 4:15

C++ is compiled into machine code. So you have the pre-processor, the compiler, the optimizer, and finally the assembler, all of which have to run.

Java and C# are compiled into byte-code/IL, and the Java virtual machine/.NET Framework execute (or JIT compile into machine code) prior to execution.

Python is an interpreted language that is also compiled into byte-code.

I'm sure there are other reasons for this as well, but in general, not having to compile to native machine language saves time.

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8  
The cost added by pre-processing is trivial. The major "other reason" for a slowdown is that compilation is split into separate tasks (one per object file), so common headers get processed over and over again. That's O(N^2) worst-case, vs. most other languages O(N) parsing time. –  Tom Dec 7 '08 at 7:05
    
Also, linking takes time, right? –  Eric Meadows-Jönsson Jan 18 '09 at 11:46
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You could tell from the same argumentation that C, Pascal etc. compilers are slow, which is not true on average. It has more to do with C++'s grammar and the huge state that a C++ compiler has to maintain. –  phresnel Jun 10 '11 at 8:40

Another reason is the use of the C pre-processor for locating declarations. Even with header guards, .h still have to be parsed over and over, every time they're included. Some compilers support pre-compiled headers that can help with this, but they are not always used.

See also: C++ Frequently Questioned Answers

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I think you should bold the comment on precompiled headers to point out this IMPORTANT part of your answer. –  Kevin Nov 25 '08 at 18:37
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If the whole header file (except possible comments and empty lines) is within the header guards, gcc is able to remember the file and skip it if the correct symbol is defined. –  CesarB Nov 26 '08 at 1:02
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@CesarB: It still has to process it in full once per compilation unit (.cpp file). –  280Z28 Mar 25 '10 at 17:38

Parsing and code generation are actually rather fast. The real problem is opening and closing files. Remember, even with include guards, the compiler still have open the .H file, and read each line (and then ignore it).

A friend once (while bored at work), took his company's application and put everything -- all source and header files-- into one big file. Compile time dropped from 3 hours to 7 minutes.

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Well, file access sure has a hand in this but as jalf said, the main reason for this will be something else, namely the repeated parsing of many, many, many (nested!) header files that completely drops out in your case. –  Konrad Rudolph Nov 25 '08 at 19:06
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It is at that point that your friend needs to set up precompiled headers, break dependancies between different header files (try to avoid one header including another, instead forward declare) and get a faster HDD. That aside, a pretty amazing metric. –  Tom Leys Nov 25 '08 at 19:49
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If the whole header file (except possible comments and empty lines) is within the header guards, gcc is able to remember the file and skip it if the correct symbol is defined. –  CesarB Nov 26 '08 at 1:03
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Parsing is a big deal. For N pairs of similarly-sized source/header files with interdependencies, there are O(N^2) passes through header files. Putting all text into a single file is cutting down that duplicate parsing. –  Tom Dec 7 '08 at 7:07
2  
Small side note: The include guards guard against multiple parsings per compilation unit. Not against multiple parsings overall. –  Marco van de Voort Jan 12 '12 at 11:52

The biggest issues are:

1) The infinite header reparsing. Already mentioned.

2) The fact that the toolchain is often separated into multiple binaries (make, preprocessor, compiler, assembler, archiver, impdef, linker, and dlltool in extreme cases) that all have to reinitialize all the time for each (preprocessor, compiler, assembler) or every couple of files (archiver, linker, and dlltool).

See also this discussion on comp.compilers: http://compilers.iecc.com/comparch/article/03-11-078 specially this one:

http://compilers.iecc.com/comparch/article/02-07-128

Note that John, the moderator of comp.compilers seems to agree, and that this means it should be possible to achieve similar speeds for C too, if one integrates the toolchain fully and implements precompiled headers. Many commercial C compilers do this to some degree.

Note that the unix model of factoring everything out to a separate binary is a kind of worst case model for Windows (with its slow process creation). Very noticable when comparing GCC build times between windows and *nix, specially if the make/configure system also calls some programs just to obtain information

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A compiled language is always going to require a bigger initial overhead than an interpreted language. In addition, perhaps you didn't structure your C++ code very well. For example:

#include "BigClass.h"

class SmallClass
{
   BigClass m_bigClass;
}

Compiles a lot slower than:

class BigClass;

class SmallClass
{
   BigClass* m_bigClass;
}
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Especially true if BigClass happens to include 5 more files that it uses, eventually including all the code in your program. –  Tom Leys Nov 25 '08 at 19:50
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This is perhaps one reason. But Pascal for example just takes a tenth of the compile time an equivalent C++ program takes. This is not because gcc:s optimization take longer but rather that Pascal is easier to parse and don't have to deal with a preprocessor. Also see Digital Mars D compiler. –  Daniel W Mar 27 '09 at 10:20
    
It's not the easier parsing, it is the modularity that avoids reinterpreting windows.h and umpteen other headers for each compilation unit. Yes, Pascal parses easier (though mature ones, like Delphi are more complicated again), but that is not what makes the big difference. –  Marco van de Voort Nov 29 '13 at 15:34

Some reasons are:

1) C++ grammar is more complex than C# or Java and takes more time to parse.

2) (More important) C++ compiler produces machine code and does all optimizations during compilation. C# and Java go just half way and leave these steps to JIT.

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The trade off you are getting is that the program runs a wee bit faster. That may be a cold comfort to you during development, but it could matter a great deal once development is complete, and the program is just being run by users.

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Most answers are being a bit unclear in mentioning that C# will always run slower due to the cost of performing actions that in C++ are performed only once at compile time, this performance cost is also impacted due runtime dependencies (more things to load to be able to run), not to mention that C# programs will always have higher memory footprint, all resulting in performance being more closely related to the capability of hardware available. The same is true to other languages that are interpreted or depend on a VM.

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1  
-1 "C# will always run slower" not true, in neither theory nor experience –  peenut Sep 2 '13 at 12:07

An easy way to reduce compilation time in larger C++ projects is to make a *.cpp include file that includes all the cpp files in your project and compile that. This reduces the header explosion problem to once. The advantage of this is that compilation errors will still reference the correct file.

For example, assume you have a.cpp, b.cpp and c.cpp.. create a file: everything.cpp:

#include "a.cpp"
#include "b.cpp"
#include "c.cpp"

Then compile the project by just making everything.cpp

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3  
I fail to see the objection to this method. Assuming you generate the includes from a script or Makefile, it is not a maintenance problem. It does in fact speed up compilation without obfuscating compilation issues. You could argue memory consumption on compilation but that is rarely an issue on modern machine. So what is the object to this approach (aside from the assertion that it's wrong)? –  rileyberton Mar 4 '13 at 1:33
    
well if you added a link to this: stackoverflow.com/questions/543697/… you maybe wouldn't have so many downvotes :P ofcourse it's faster, but I highly discourage it. I hate "#include spaghetti " –  user1182183 Mar 4 '13 at 7:35
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@rileyberton (since someone upvoted your comment) let me spell it out: no it doesn't speed compilation up. In fact, it makes sure that any compile takes the maximum amount of time by not isolating translation units. The great thing about them is, that you don't need to recompile all .cpp-s if they didn't change. (That's disregarding stylistic arguments). Proper dependency management and perhaps precompiled headers are much much better. –  sehe Mar 4 '13 at 8:55
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Sorry, but this can be a very efficient method for speeding up compilation, because you (1) pretty much eliminate linking, and (2) only have to process commonly used headers once. Also, it works in practice, if you bother to try it. Unfortunately, it makes incremental rebuilds impossible, so every build is completely from scratch. But a full rebuild with this method is a lot faster than what you'd get otherwise –  jalf Mar 4 '13 at 9:00
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@BartekBanachewicz sure, but what you said was that "it doesn't speed compilation up", with no qualifiers. As you said, it makes every compile take the maximum amount of time (no partial rebuilds), but at the same time, it dramatically reduces the maximum compared to what it'd otherwise be. I'm just saying it's a bit more nuanced than "don't do this" –  jalf Mar 4 '13 at 9:04

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