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I have a matrix that is over 17,000 x 14,000 that I'm storing in memory in C++. The values will never get over 255 so I'm thinking I should store this matrix as a uint8_t type instead of a regular int type. Will the regular int type will assume the native word size (64 bit so 8 bytes per cell) even with an optimizing compiler? I'm assuming I'll use 8x less memory if I store the array as uint8_t?

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Thanks for all the answers and I do realize uint8_t may be slower, but the goal is to support larger arrays in memory then the example I gave. –  Peter Smith Sep 30 '11 at 16:11
The conventional type to hold 0...255 is unsigned char. This is similar to the type uint_least8_t. Because uint8_t must be exactly 8 bits, the compiler may need to insert extra instructions to actively truncate values higher than 255. That's obviously less efficient. –  MSalters Sep 30 '11 at 23:30

3 Answers 3

up vote 2 down vote accepted

The standard doesn't specify the exact size of int other than it's at least the size of short. On some 64-bit architectures (for example many Linux and Solaris x86 systems I work with) int is 32 bits and long is 64 bits. The exact size of each type will of course vary by compiler/hardware.

The best way to find out is to use sizeof(int) on your system and see how big it is. If you have enough RAM using the native type may in fact be significantly faster than the uint8_t.

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Nope, long is 32, long long is 64 on both x86 and amd64. –  wormsparty Sep 30 '11 at 15:17
@wormsparty: On my system (x86_64 Linux Linux), long is 64 bits. I am pretty sure Mark B is correct about "most" 64-bit platforms. –  Nemo Sep 30 '11 at 15:21
@wormsparty: can you clarify what you mean by "long is 32 on ... amd64"? It's not really an "architecture" issue, since there's more than one ABI on the same architecture, so it varies by OS even on the same CPU. Anyway, your one example cannot contradict a claim that "most" 64-bit architectures have a particular property, 64 bit Windows is one member of what Mark claims is a minority. –  Steve Jessop Sep 30 '11 at 15:22
@wormsparty The data type names have nothing to do with processor architecture. They are defined by the OS and Mark B's answer is correct for most Unix / Linux and Mac systems. –  Praetorian Sep 30 '11 at 15:23
On any machine today and in the next decade, even if int is faster than uint8_t, uint8_t[14000][17000] is going to be faster than int[14000][17000]. By a significant margin, even. Wasting so many bits in all cache levels never pays off. –  MSalters Sep 30 '11 at 23:23

If you doubt this, you could have just tried it.

Of course it will be smaller.

However, it wholly depends on your usage patterns which will be faster. Profile! Profile! Profile!

Reasons for unexpected performance considerations:

  • alignment issues
  • elements sharing cache lines (could be positive on sequential access; negative in multicore scenarios)
  • increased need for locking on atomic reads/writes (in case of threading)
  • reduced applicability of certain optimized MIPS instructions (? - I'm not up-to-date with details here; also a very good optimizing compiler might simply register-allocate temporaries of the right size)
  • other, unrelated border conditions, originating from the surrounding code
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Even the best optimizing compiler is not going to do an analysis of the values of the data that you put into your matrix and assume (anthropomorphizing here) "Hmmm. He said int but everything is between 0 and 255. I'm going to make that an array of uint8_t."

The compiler can interpret some keywords such as register and inline as suggestions rather than mandates. Types on the other hand are mandates. You told the compiler to use int so the compiler must use int. So switching to a uint8_t matrix will save you a considerable amount of memory here.

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