# Which is faster : if (bool) or if(int)?

Which value is better to use? Boolean true or Integer 1?

The above topic made me do some experiments with `bool` and `int` in `if` condition. So just out of curiosity I wrote this program:

``````int f(int i)
{
if ( i ) return 99;   //if(int)
else  return -99;
}
int g(bool b)
{
if ( b ) return 99;   //if(bool)
else  return -99;
}
int main(){}
``````

`g++ intbool.cpp -S` generates asm code for each functions as follows:

• asm code for `f(int)`

``````__Z1fi:
LFB0:
pushl  %ebp
LCFI0:
movl  %esp, %ebp
LCFI1:
cmpl  \$0, 8(%ebp)
je    L2
movl  \$99, %eax
jmp   L3
L2:
movl  \$-99, %eax
L3:
leave
LCFI2:
ret
``````
• asm code for `g(bool)`

``````__Z1gb:
LFB1:
pushl %ebp
LCFI3:
movl  %esp, %ebp
LCFI4:
subl  \$4, %esp
LCFI5:
movl  8(%ebp), %eax
movb  %al, -4(%ebp)
cmpb  \$0, -4(%ebp)
je    L5
movl  \$99, %eax
jmp   L6
L5:
movl  \$-99, %eax
L6:
leave
LCFI6:
ret
``````

Surprisingly, `g(bool)` generates more `asm` instructions! Does it mean that `if(bool)` is little slower than `if(int)`? I used to think `bool` is especially designed to be used in conditional statement such as `if`, so I was expecting `g(bool)` to generate less asm instructions, thereby making `g(bool)` more efficient and fast.

EDIT:

I'm not using any optimization flag as of now. But even absence of it, why does it generate more asm for `g(bool)` is a question for which I'm looking for a reasonable answer. I should also tell you that `-O2` optimization flag generates exactly same asm. But that isn't the question. The question is what I've asked.

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It's also an unfair test unless you compare them with reasonable optimizations enabled. – Daniel Pryden Apr 23 '11 at 15:11
@Daniel: I'm not using any optimization flags with either of them. But even absence of it, why does it generates more asm for `g(bool)` is a question for which I'm looking for a reasonable answer. – Nawaz Apr 23 '11 at 15:14
There's no point in looking at unoptimized code. A decent compiler will inline the functions and eliminate the if statement. – Hans Passant Apr 23 '11 at 15:16
Why would you go to the trouble of reading the asm, but not just running the program and timing the result? The number of instructiosn doesn't really say much about performance. You need to factor in not just instruction lengths, but also dependencies and the types of instructions (are some of them decoded using the slower microcode path, which execution units do they require, what is the latency and throughput of the instruction, is it a branch? A memmory access? – jalf Apr 23 '11 at 15:34
I hope this question is a purely hypothetical one. Except in truly bizarre and unusual circumstances, you should not make any changes to your code based on one version or the other seeming to generate shorter code or to run faster. Write your code to be read by humans and allow the computer to catch up. – Malvolio Apr 23 '11 at 16:23

Makes sense to me. Your compiler apparently defines a `bool` as an 8-bit value, and your system ABI requires it to "promote" small (< 32-bit) integer arguments to 32-bit when pushing them onto the call stack. So to compare a `bool`, the compiler generates code to isolate the least significant byte of the 32-bit argument that g receives, and compares it with `cmpb`. In the first example, the `int` argument uses the full 32 bits that were pushed onto the stack, so it simply compares against the whole thing with `cmpl`.

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This is a good attempt to answer the question. +1 – Nawaz Apr 23 '11 at 15:25
I agree. This helps to illuminate that when choosing a variable type, you're choosing it for two potentially competing purposes, storage space vs. computational performance. – Triynko Apr 27 '11 at 18:20
Does this also apply to 64-bit processes, that `__int64` is faster than `int`? Or CPU deals 32-bit integer with 32-bit instruction sets separately? – Crend King Apr 27 '11 at 21:22
@CrendKing maybe it's worth rolling another question? – Sarge Borsch Dec 28 '13 at 19:25

Compiling with `-03` gives the following for me:

f:

``````    pushl   %ebp
movl    %esp, %ebp
cmpl    \$1, 8(%ebp)
popl    %ebp
sbbl    %eax, %eax
andb    \$58, %al
ret
``````

g:

``````    pushl   %ebp
movl    %esp, %ebp
cmpb    \$1, 8(%ebp)
popl    %ebp
sbbl    %eax, %eax
andb    \$58, %al
ret
``````

.. so it compiles to essentially the same code, except for `cmpl` vs `cmpb`. This means that the difference, if there is any, doesn't matter. Judging by unoptimized code is not fair.

Edit to clarify my point. Unoptimized code is for simple debugging, not for speed. Comparing the speed of unoptimized code is senseless.

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As much as I agree with your conclusion, I think you're skipping the interesting part. Why does it use `cmpl` for one and `cmpb` for the other? – jalf Apr 23 '11 at 15:35
@jalf: Because a `bool` is a single byte and an `int` is four. I don't think there's anything more special than that. – Charles Bailey Apr 23 '11 at 15:38
I think other responses paid greater attention to the reasons: it's because the platform in question treats `bool` as a 8 bit type. – Alexander Gessler Apr 23 '11 at 15:40
@Nathan: No. C++ has no bit data types. The smallest type is `char`, which is a byte by definition, and is the smallest addressable unit. `bool`'s size is implementation-defined, and may be 1, 4, or 8, or whatever. Compilers tend to make it one, though. – GManNickG Apr 23 '11 at 20:20
@Nathan: Well that's tricky in Java, too. Java says the data a boolean represents is the value of one bit, but how that bit is stored is still implementation defined. Pragmatic computers simply don't address bits. – GManNickG Apr 23 '11 at 20:24

When I compile this with a sane set of options (specifically -O3), here's what I get:

For `f()`:

``````        .type   _Z1fi, @function
_Z1fi:
.LFB0:
.cfi_startproc
.cfi_personality 0x3,__gxx_personality_v0
cmpl    \$1, %edi
sbbl    %eax, %eax
andb    \$58, %al
ret
.cfi_endproc
``````

For `g()`:

``````        .type   _Z1gb, @function
_Z1gb:
.LFB1:
.cfi_startproc
.cfi_personality 0x3,__gxx_personality_v0
cmpb    \$1, %dil
sbbl    %eax, %eax
andb    \$58, %al
ret
.cfi_endproc
``````

They still use different instructions for the comparison (`cmpb` for boolean vs. `cmpl` for int), but otherwise the bodies are identical. A quick look at the Intel manuals tells me: ... not much of anything. There's no such thing as `cmpb` or `cmpl` in the Intel manuals. They're all `cmp` and I can't find the timing tables at the moment. I'm guessing, however, that there's no clock difference between comparing a byte immediate vs. comparing a long immediate, so for all practical purposes the code is identical.

The reason the code is different in the unoptimized case is that it is unoptimized. (Yes, it's circular, I know.) When the compiler walks the AST and generates code directly, it doesn't "know" anything except what's at the immediate point of the AST it's in. At that point it lacks all contextual information needed to know that at this specific point it can treat the declared type `bool` as an `int`. A boolean is obviously by default treated as a byte and when manipulating bytes in the Intel world you have to do things like sign-extend to bring it to certain widths to put it on the stack, etc. (You can't push a byte.)

When the optimizer views the AST and does its magic, however, it looks at surrounding context and "knows" when it can replace code with something more efficient without changing semantics. So it "knows" it can use an integer in the parameter and thereby lose the unnecessary conversions and widening.

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Haha, I like how the compiler simply returned 99, or 99+58 = 157 = -99 (overflow of signed 8bits)... interesting. – dcousens Apr 23 '11 at 15:29
@Daniel: Even I liked that. At first, I said "where is -99" and immediately I realized that its doing something very kinky. – Nawaz Apr 23 '11 at 15:39
`l` and `b` are suffixes used in AT&T syntax only. They just refer to versions of `cmp` using 4 byte (long) and 1 byte (byte) operands respectively. Where there is any ambiguity in intel syntax, conventionally the memory operand is tagged with `BYTE PTR`, `WORD PTR` or `DWORD PTR` instead of putting a suffix on the opcode. – Charles Bailey Apr 23 '11 at 16:00
One thing to note here is that the optimized version never jumps. This means the CPU's instruction pipeline never mis-predicts a branch, and the result will execute substantially faster than the unoptimized code with an otherwise similar number of instructions. This is important because modern instruction pipelines are quite deep and the cost of a mis-prediction is to flush the pipeline and start it over. – RBerteig Apr 24 '11 at 0:09

With GCC 4.5 on Linux and Windows at least, `sizeof(bool) == 1`. On x86 and x86_64, you can't pass in less than an general purpose register's worth to a function (whether via the stack or a register depending on the calling convention etc...).

So the code for bool, when un-optimized, actually goes to some length to extract that bool value from the argument stack (using another stack slot to save that byte). It's more complicated than just pulling a native register-sized variable.

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From the C++03 standard, §5.3.3/1: "`sizeof(bool)` and `sizeof(wchar_t)` are implementation-defined." So saying `sizeof(bool) == 1` is not strictly correct unless you're talking about a specific version of a specific compiler. – ildjarn Apr 23 '11 at 15:40
Quite correct, edited, thanks. – Mat Apr 23 '11 at 15:43

### At the machine level there is no such thing as bool

Very few instruction set architectures define any sort of boolean operand type, although there are often instructions that trigger an action on non-zero values. To the CPU, usually, everything is one of the scalar types or a string of them.

A given compiler and a given ABI will need to choose specific sizes for `int` and `bool` and when, like in your case, these are different sizes they may generate slightly different code, and at some levels of optimization one may be slightly faster.

### Why is bool one byte on many systems?

It's safer to choose a `char` type for bool because someone might make a really large array of them.

Update: by "safer", I mean: for the compiler and library implementors. I'm not saying people need to reimplement the system type.

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+1 Imagine the overhead on x86 if `bool` were represented by bits; so byte will be a nice tradeoff for speed/data compactness in many implementations. – hardmath Apr 23 '11 at 23:57
I strongly disagree with the last point. If you want a really large array of them, then use `std::vector<bool>`, which will store things as one bit per bool. Or use a `char` for the case where you do have a really large array. Don't change the semantics of all of your code because of one special case that might have to be optimized later. – Billy ONeal Apr 24 '11 at 5:25
@Billy: I think he wasn't saying "use `char` instead of `bool`" but instead simply used "`char` type" to mean "1 byte" when referring to the size the compiler chooses for `bool` objects. – Dennis Zickefoose Apr 24 '11 at 6:33
Oh, sure, I didn't mean that each program should choose, I was just advancing a rationale for why the system bool type is 1 byte. – DigitalRoss Apr 24 '11 at 6:35
@Dennis: Ah, that makes sense. – Billy ONeal Apr 25 '11 at 0:16

Yeah, the discussion's fun. But just test it:

Test code:

``````#include <stdio.h>
#include <string.h>

int testi(int);
int testb(bool);
int main (int argc, char* argv[]){
bool valb;
int  vali;
int loops;
if( argc < 2 ){
return 2;
}
valb = (0 != (strcmp(argv[1], "0")));
vali = strcmp(argv[1], "0");
printf("Arg1: %s\n", argv[1]);
printf("BArg1: %i\n", valb ? 1 : 0);
printf("IArg1: %i\n", vali);
for(loops=30000000; loops>0; loops--){
//printf("%i: %i\n", loops, testb(valb=!valb));
printf("%i: %i\n", loops, testi(vali=!vali));
}
return valb;
}

int testi(int val){
if( val ){
return 1;
}
return 0;
}
int testb(bool val){
if( val ){
return 1;
}
return 0;
}
``````

Compiled on a 64-bit Ubuntu 10.10 laptop with: g++ -O3 -o /tmp/test_i /tmp/test_i.cpp

Integer-based comparison:

``````sauer@trogdor:/tmp\$ time /tmp/test_i 1 > /dev/null

real    0m8.203s
user    0m8.170s
sys 0m0.010s
sauer@trogdor:/tmp\$ time /tmp/test_i 1 > /dev/null

real    0m8.056s
user    0m8.020s
sys 0m0.000s
sauer@trogdor:/tmp\$ time /tmp/test_i 1 > /dev/null

real    0m8.116s
user    0m8.100s
sys 0m0.000s
``````

Boolean test / print uncommented (and integer commented):

``````sauer@trogdor:/tmp\$ time /tmp/test_i 1 > /dev/null

real    0m8.254s
user    0m8.240s
sys 0m0.000s
sauer@trogdor:/tmp\$ time /tmp/test_i 1 > /dev/null

real    0m8.028s
user    0m8.000s
sys 0m0.010s
sauer@trogdor:/tmp\$ time /tmp/test_i 1 > /dev/null

real    0m7.981s
user    0m7.900s
sys 0m0.050s
``````

They're the same with 1 assignment and 2 comparisons each loop over 30 million loops. Find something else to optimize. For example, don't use strcmp unnecessarily. ;)

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It will mostly depend on the compiler and the optimization. There's an interesting discussion (language agnostic) here:

Does "if ([bool] == true)" require one more step than "if ([bool])"?

Also, take a look at this post: http://www.linuxquestions.org/questions/programming-9/c-compiler-handling-of-boolean-variables-290996/

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Approaching your question in two different ways:

If you are specifically talking about C++ or any programming language that will produce assembly code for that matter, we are bound to what code the compiler will generate in ASM. We are also bound to the representation of true and false in c++. An integer will have to be stored in 32 bits, and I could simply use a byte to store the boolean expression. Asm snippets for conditional statements:

For the integer:

``````  mov eax,dword ptr[esp]    ;Store integer
cmp eax,0                 ;Compare to 0
je  false                 ;If int is 0, its false
;Do what has to be done when true
false:
;Do what has to be done when false
``````

For the bool:

``````  mov  al,1     ;Anything that is not 0 is true
test al,1     ;See if first bit is fliped
jz   false    ;Not fliped, so it's false
;Do what has to be done when true
false:
;Do what has to be done when false
``````

So, that's why the speed comparison is so compile dependent. In the case above, the bool would be slightly fast since `cmp` would imply a subtraction for setting the flags. It also contradicts with what your compiler generated.

Another approach, a much simpler one, is to look at the logic of the expression on it's own and try not to worry about how the compiler will translate your code, and I think this is a much healthier way of thinking. I still believe, ultimately, that the code being generated by the compiler is actually trying to give a truthful resolution. What I mean is that, maybe if you increase the test cases in the if statement and stick with boolean in one side and integer in another, the compiler will make it so the code generated will execute faster with boolean expressions in the machine level.

I'm considering this is a conceptual question, so I'll give a conceptual answer. This discussion reminds me of discussions I commonly have about whether or not code efficiency translates to less lines of code in assembly. It seems that this concept is generally accepted as being true. Considering that keeping track of how fast the ALU will handle each statement is not viable, the second option would be to focus on jumps and compares in assembly. When that is the case, the distinction between boolean statements or integers in the code you presented becomes rather representative. The result of an expression in C++ will return a value that will then be given a representation. In assembly, on the other hand, the jumps and comparisons will be based in numeric values regardless of what type of expression was being evaluated back at you C++ if statement. It is important on these questions to remember that purely logicical statements such as these end up with a huge computational overhead, even though a single bit would be capable of the same thing.

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