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After three years working on a C++ project, the executable has grown to 4 MB. I'd like to see where all this space is going. Is there a tool that could report what the biggest space hogs are? It would be nice to see the size by class (all functions in a class), by template (all instantiations), and by library (how much belongs to the C standard library and STL? how much for each library in the exe?)

Edit: Note, I am using Visual C++ on Windows.

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In case anyone's wondering, it turned out that Flite (a text-to-speech engine) was by far the largest component of the 4 MB at 1.8 MB IIRC, which I discovered by removing it. –  Qwertie Apr 11 '11 at 15:40

5 Answers 5

up vote 8 down vote accepted

In Linux, you can use nm to show all symbols in the executable and to sort them in reverse order by size:

$ nm -CSr --size-sort <exe>

Options:

  • -C demangles C++ names.
  • -S shows size of symbols.
  • --size-sort sorts symbols by size.
  • -r reverses the sort.

If you want to get the results per namespace or per class, you can just grep the output for 'namespace::', 'namespace::class_name::', etc..

If you only want to see symbols that are defined in the executable (not ones defined elsewhere, like in libraries) then add --defined-only. Sorting by size should take care of this, though, since undefined symbols aren't going to have a size.

For Windows, you should still be able to use nm on your binary files, since nm supports COFF binaries. You can install nm via cygwin, or you could copy your windows executable to a linux box and run nm on it there.

You could also try dumpbin, which dumps info about a binary on Windows. You can get info on symbols with the /SYMBOLS switch, but it doesn't look like it directly provides information about their size.

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Ahh, the wonders of Linux. It's too bad I'm on Windblows. –  Qwertie Jun 26 '09 at 23:07
    
you could compile it with gcc under cygwin and then use its nm tool for an aproximate list. –  Blindy Jun 26 '09 at 23:12
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As far as I know, nm supports COFF. You could just install it via cygwin, or you could copy the exe over to a Linux box and run nm on it there. You could also try the windows utility dumpbin. See here: support.microsoft.com/?id=121460 –  tgamblin Jun 26 '09 at 23:13
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If you copy it to linux, it can happen you need to recompile binutils, to have target support for COFF, i think. –  Johannes Schaub - litb Jun 26 '09 at 23:35
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Thank you for explaining the meanings of the parameters you used, instead of just giving the whole command as a magic incantation. More people should follow your good example. –  Rob Kennedy Jun 26 '09 at 23:41

Get a link map, or use dumpbin to get a list of symbols and sizes.

Chances are there's a lot of stuff being pulled in that you don't strictly need.

ADDED: Did you get a satisfactory answer? I realized there are two ways people approach problems like this:

  • Get measurements before they do anything.
  • Just find something big that they don't need, rip it out, and repeat until they can't.

Personally I prefer the latter - it gets results quicker.

You say the app is 4MB. Suppose the true necessary size is 1MB (or some such size). That means if you pick a routine at random from the map file, it is 75% likely to be something you don't need. Find out what's causing it to be included, and see if you really need it.

In the example you gave, you saw a class that wraps device-independent-bitmaps. You could find instances of that class in your app, and possibly replace them with basic WIN32 bitmaps. It would be less pretty, but save gobs of app size.

Then keep on doing it. Each large piece you get rid of makes the remaining pieces take a larger percentage of the app, because the app has shrunk but the pieces haven't. That makes them easier to find in the map file.

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Taking the example of the DIB wrapper again, that class might be tiny and I might not save anything by ripping it out. OTOH, maybe there are many different instances of vector<T>, map<K,V>, hash_map, etc. and maybe I'd save space by finding ways to share instances. But then again, maybe the compiler is smart enough to merge identical suproutines (which probably happens often with templates) or maybe those classes don't take up that much space despite many instances. Maybe if I had good data it would turn out that I can't easily save any space, or that the space was going to unexpected places. –  Qwertie Jul 27 '09 at 19:16
    
I know from my experiences with "normal" profilers that my intuitions about where resources are going are often wrong. So it's not enough to just make a visual inspection of a .map file and simply guess which classes/functions/libraries take a lot of room. –  Qwertie Jul 27 '09 at 19:20
    
@Qwertie: I know what you mean, but if a lot of some resource exists for a poor reason, sparsely sampling the resource, and determining the reason behind each sample, can reveal the problem. You don't something that measures accurately but gives little insight. You need something that measures coarsely but gives maximum insight. –  Mike Dunlavey Jul 29 '09 at 13:34

In Windows under Visual Studio compiles, this information is in your .map file (it'll be near the .pdb).

ADDED: To convert the decorated names found in the .map file to something more human-readable, you can use the undname.exe utility included with Visual Studio. It accepts individual names on the commandline or you can feed it a .map file.

For example,

Microsoft (R) C++ Name Undecorator
Copyright (C) Microsoft Corporation. All rights reserved.

Undecoration of "?push_back@?$mini_vector@U?$Point@U?$FixedPoint@$0O@H@Math@@@Math@@$05@@QAAXABU?$Point@U?$FixedPoint@$0O@H@Math@@@Math@@@Z" is 

"public: void __cdecl mini_vector<struct Math::Point<struct Math::FixedPoint<14,int> >,6>::push_back(struct Math::Point<struct Math::FixedPoint<14,int> > const &)"
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I'm looking at my map file, and not really seeing how lines like "0001:0000f380 ?push_back@?$mini_vector@U?$Point@U?$FixedPoint@$0O@H@Math@@@Math@@$05@@QAAXABU?‌​$Point@U?$FixedPoint@$0O@H@Math@@@Math@@@Z 10010380 f i dibitmapsce:DIBitmap.obj" are useful for profiling. –  Qwertie Jun 29 '09 at 15:40
    
Don't be put off by the mangled names. That says in the device-independent bitmap support there is a function for appending to the end of a vector of points, and it is at address F380 (62336) in segment 1. I bet there are a lot more like it. You might look to see where this is referenced, and if not needed, see if you can get rid of it. –  Mike Dunlavey Jun 29 '09 at 17:32
    
You can undecorate names with undname.exe, found in your Visual Studio bins directory; running the "Visual Studio 200X Command Prompt" shortcut will put it into your %PATH%. Or if you want to do them in bulk, I found this Python script that does it automatically: holycall.tistory.com/entry/… –  Crashworks Jun 29 '09 at 20:52
    
For example, that function undecorates to: public: void __cdecl mini_vector<struct Math::Point<struct Math::FixedPoint<14,int> >,6>::push_back(struct Math::Point<struct Math::FixedPoint<14,int> > const &) –  Crashworks Jun 29 '09 at 20:55
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@Qwertie: the thing is, the length of name correlates with the number of routines, so you're probably seeing the tip of a big iceberg. If there is a line somewhere like "CDiBitmap myDIB;" that is not actually used, it could pull that elephant into your living room. If you need a DIB, you might just use the basic WIN32 object. –  Mike Dunlavey Jun 30 '09 at 13:46

Don't just look at code - resources can easily cause multi-megabyte growth.

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That's right - bitmaps & such can be massive. –  Mike Dunlavey Jun 27 '09 at 1:11
    
Luckily bitmap size is easy to measure - and is not an issue in my case. –  Qwertie Jun 29 '09 at 15:42

I could not get nm to work for me but did manage to find a useful tool called Sizer. It reads the debug information created by Visual Studio using the Debug Interface Access libraries. It's pretty straightforward to use, as describe on the site.

  1. Compile with debugging info in program database (.pdb) file
  2. Run sizer from command line e.g. Sizer.exe <path-to-exe-file>. The output will go to stdout so you'll probably want to redirect to a file.

The code sizes are broken down in different sections and grouped by function, data, class, etc, each section sorted in descending order of code size.

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