I'm reading Agner Fog's "Optimizing software in C++" (specific to x86 processors for Intel, AMD and VIA) and it states on page 34

Boolean variables are stored as 8-bit integers with the value 0 for false and 1 for true. Boolean variables are overdetermined in the sense that all operators that have Boolean variables as input check if the inputs have any other value than 0 or 1, but operators that have Booleans as output can produce no other value than 0 or 1. This makes operations with Boolean variables as input less efficient than necessary.

Is this still true today and on what compilers? Can you please give an example? The author states

The Boolean operations can be made much more efficient if it is known with certainty that the operands have no other values than 0 and 1. The reason why the compiler doesn't make such an assumption is that the variables might have other values if they are uninitialized or come from unknown sources.

Does this mean that if I take a function pointer bool(*)() for example and call it, then operations on it produce inefficient code? Or is it the case when I access a boolean by dereferencing a pointer or reading from a reference and then operate on it?

  • Hi Johannes - long time no see! But I think your first quote is wrong, it's somethimg like "Boolean variables are overdetermined in the sense that ..." – Neil Butterworth Nov 11 '17 at 23:43
  • 2
    IIRC, gcc and clang will sometimes emit code that depends on a bool being 0 or 1, not just any non-zero value. (even if that bool was generated by external code they can't analyze, like a function arg.) I'll see if I can cook up an example later. – Peter Cordes Nov 11 '17 at 23:51
  • Isn't the code like it is because of short-circuit evaluation? – alain Nov 12 '17 at 0:03
  • @alain reading from the variable in the right side has no side effects so short circuit evaluation isn't an issue here, I think. – Johannes Schaub - litb Nov 12 '17 at 0:05
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    @PeterCordes I hope you like my inquiry for a "complete explanation" :) – Johannes Schaub - litb Nov 12 '17 at 0:25

TL:DR: current compilers still have bool missed-optimizations when doing stuff like
(a&&b) ? x : y. But the reason why is not that they don't assume 0/1, they just suck at this.

Many uses of bool are for locals, or inline functions, so booleanizing to a 0 / 1 can optimize away and branch (or cmov or whatever) on the original condition. Only worry about optimizing bool inputs / outputs when it does have to get passed/returned across something that doesn't inline, or really stored in memory.

Possible optimization guideline: combine bools from external sources (function args / memory) with bitwise operators, like a&b. MSVC and ICC do better with this. IDK if it's ever worse for local bools. Beware that a&b is only equivalent to a&&b for bool, not integer types. 2 && 1 is true, but 2 & 1 is 0 which is false. Bitwise OR doesn't have this problem.

IDK if this guideline will ever hurt for locals that were set from a comparison within the function (or in something that inlined). E.g. it might lead the compiler to actually make integer booleans instead of just using comparison results directly when possible. Also note that it doesn't seem to help with current gcc and clang.

Yes, C++ implementations on x86 store bool in a byte that's always 0 or 1 (at least across function-call boundaries where the compiler has to respect the ABI / calling convention which requires this.)

Compilers do sometimes take advantage of this, e.g. for bool->int conversion even gcc 4.4 simply zero-extends to 32-bit (movzx eax, dil). Clang and MSVC do this, too. C and C++ rules require this conversion to produce 0 or 1, so this behaviour is only safe if it's always safe to assume that a bool function arg or global variable has a 0 or 1 value.

Even old compilers typically did take advantage of it for bool->int, but not in other cases. Thus, Agner is wrong about the reason when he says:

The reason why the compiler doesn't make such an assumption is that the variables might have other values if they are uninitialized or come from unknown sources.

MSVC CL19 does make code that assumes bool function args are 0 or 1, so the Windows x86-64 ABI must guarantee this.

In the x86-64 System V ABI (used by everything other than Windows), the changelog for revision 0.98 says "Specify that _Bool (aka bool) is booleanized at the caller." I think even before that change, compilers were assuming it, but this just documents what compilers were already relying on. The current language in the x86-64 SysV ABI is:

3.1.2 Data Representation

Booleans, when stored in a memory object, are stored as single byte objects the value of which is always 0 (false) or 1 (true). When stored in integer registers (except for passing as arguments), all 8 bytes of the register are significant; any nonzero value is considered true.

The second sentence is nonsense: the ABI has no business telling compilers how to store things in registers inside a function, only at boundaries between different compilation units (memory / function args and return values). I reported this ABI defect a while ago on the github page where it's maintained.

3.2.3 Parameter passing:

When a value of type _Bool is returned or passed in a register or on the stack, bit 0 contains the truth value and bits 1 to 7 shall be zero16.

(footnote 16): Other bits are left unspecified, hence the consumer side of those values can rely on it being 0 or 1 when truncated to 8 bit.

The language in the i386 System V ABI is the same, IIRC.

Any compiler that assumes 0/1 for one thing (e.g. conversion to int) but fails to take advantage of it in other cases has a missed optimization. Unfortunately such missed-optimizations still exist, although they are rarer than when Agner wrote that paragraph about compilers always re-booleanizing.

(Source + asm on the Godbolt compiler explorer for gcc4.6 / 4.7, and clang/MSVC. See also Matt Godbolt's CppCon2017 talk What Has My Compiler Done for Me Lately? Unbolting the Compiler's Lid)

bool logical_or(bool a, bool b) { return a||b; }

 # gcc4.6.4 -O3 for the x86-64 System V ABI
    test    dil, dil            # test a against itself (for non-zero)
    mov     eax, 1
    cmove   eax, esi            # return   a ? 1 : b;

So even gcc4.6 didn't re-booleanize b, but it did miss the optimization that gcc4.7 makes: (and clang and later compilers as shown in other answers):

    # gcc4.7 -O3 to present: looks ideal to me.
    mov     eax, esi
    or      eax, edi

(Clang's or dil, sil / mov eax, edi is silly: it's guaranteed to cause a partial-register stall on Nehalem or earlier Intel when reading edi after writing dil, and it has worse code size from needing a REX prefix to use the low-8 part of edi. A better choice might be or dil,sil / movzx eax, dil if you want to avoid reading any 32-bit registers in case your caller left some arg-passing registers with "dirty" partial registers.)

MSVC emits this code that checks a then b separately, completely failing to take advantage of anything, and even using xor al,al instead of xor eax,eax. So it has a false dependency on the old value of eax on most CPUs (including Haswell/Skylake, which don't rename low-8 partial regs separately from the whole register, only AH/BH/...). This is just dumb. The only reason to ever use xor al,al is when you explicitly want to preserve the upper bytes.

logical_or PROC                     ; x86-64 MSVC CL19
    test     cl, cl                 ; Windows ABI passes args in ecx, edx
    jne      SHORT $LN3@logical_or
    test     dl, dl
    jne      SHORT $LN3@logical_or
    xor      al, al                 ; missed peephole: xor eax,eax is strictly better
    ret      0
    mov      al, 1
    ret      0
logical_or ENDP

ICC18 also doesn't take advantage of the known 0/1 nature of the inputs, it just uses an or instruction to set flags according to the bitwise OR of the two inputs, and setcc to produce a 0/1.

logical_or(bool, bool):             # ICC18
    xor       eax, eax                                      #4.42
    movzx     edi, dil                                      #4.33
    movzx     esi, sil                                      #4.33
    or        edi, esi                                      #4.42
    setne     al                                            #4.42
    ret                                                     #4.42

ICC emits the same code even for bool bitwise_or(bool a, bool b) { return a|b; }. It promotes to int (with movzx), and uses or to set flags according to the bitwise OR. This is dumb compared to or dil,sil / setne al.

For bitwise_or, MSVC does just use an or instruction (after movzx on each input), but anyway doesn't re-booleanize.

Missed optimizations in current gcc/clang:

Only ICC/MSVC were making dumb code with the simple function above, but this function still gives gcc and clang trouble:

int select(bool a, bool b, int x, int y) {
    return (a&&b) ? x : y;

Source+asm on the Godbolt compiler explorer (Same source, different compilers selected vs. last time).

Looks simple enough; you'd hope that a smart compiler would do it branchlessly with one test/cmov. x86's test instruction sets flags according to a bitwise AND. It's an AND instruction that doesn't actually write the destination. (Just like cmp is a sub that doesn't write the destination).

# hand-written implementation that no compilers come close to making
    mov     eax, edx      # retval = x
    test    edi, esi      # ZF =  ((a & b) == 0)
    cmovz   eax, ecx      # conditional move: return y if ZF is set

But even the daily builds of gcc and clang on the Godbolt compiler explorer make much more complicated code, checking each boolean separately. They know how to optimize bool ab = a&&b; if you return ab, but even writing it that way (with a separate boolean variable to hold the result) doesn't manage to hand-hold them into making code that doesn't suck.

Note that test same,same is exactly equivalent to cmp reg, 0, and is smaller, so it's what compilers use.

Clang's version is strictly worse than my hand-written version. (Note that it requires that the caller zero-extended the bool args to 32-bit, like it does for narrow integer types as an unofficial part of the ABI which it and gcc implement but only clang depends on).

select:  # clang 6.0 trunk 317877 nightly build on Godbolt
    test    esi, esi
    cmove   edx, ecx         # x = b ? y : x
    test    edi, edi
    cmove   edx, ecx         # x = a ? y : x
    mov     eax, edx         # return x

gcc 8.0.0 20171110 nightly makes branchy code for this, similar to what older gcc versions do.

select(bool, bool, int, int):   # gcc 8.0.0-pre   20171110
    test    dil, dil
    mov     eax, edx          ; compiling with -mtune=intel or -mtune=haswell would keep test/jcc together for macro-fusion.
    je      .L8
    test    sil, sil
    je      .L8
    rep ret
    mov     eax, ecx

MSVC x86-64 CL19 makes very similar branchy code. It's targeting the Windows calling convention, where integer args are in rcx, rdx, r8, r9.

select PROC
        test     cl, cl         ; a
        je       SHORT $LN3@select
        mov      eax, r8d       ; retval = x
        test     dl, dl         ; b
        jne      SHORT $LN4@select
        mov      eax, r9d       ; retval = y
        ret      0              ; 0 means rsp += 0 after popping the return address, not C return 0.
                                ; MSVC doesn't emit the `ret imm16` opcode here, so IDK why they put an explicit 0 as an operand.
select ENDP

ICC18 also makes branchy code, but with both mov instructions after the branches.

select(bool, bool, int, int):
        test      dil, dil                                      #8.13
        je        ..B4.4        # Prob 50%                      #8.13
        test      sil, sil                                      #8.16
        jne       ..B4.5        # Prob 50%                      #8.16
..B4.4:                         # Preds ..B4.2 ..B4.1
        mov       edx, ecx                                      #8.13
..B4.5:                         # Preds ..B4.2 ..B4.4
        mov       eax, edx                                      #8.13
        ret                                                     #8.13

Trying to help the compiler by using

int select2(bool a, bool b, int x, int y) {
    bool ab = a&&b;
    return (ab) ? x : y;

leads MSVC into making hilariously bad code:

;; MSVC CL19  -Ox  = full optimization
select2 PROC
    test     cl, cl
    je       SHORT $LN3@select2
    test     dl, dl
    je       SHORT $LN3@select2
    mov      al, 1              ; ab = 1

    test     al, al             ;; and then test/cmov on an immediate constant!!!
    cmovne   r9d, r8d
    mov      eax, r9d
    ret      0
    xor      al, al            ;; ab = 0

    test     al, al            ;; and then test/cmov on another path with known-constant condition.
    cmovne   r9d, r8d
    mov      eax, r9d
    ret      0
select2 ENDP

This is only with MSVC (and ICC18 has the same missed optimization of test/cmov on a register that was just set to a constant).

gcc and clang as usual don't make code as bad as MSVC; they make the same asm they do for select(), which is still not good but at least trying to help them doesn't make it worse like with MSVC.

Combine bool with bitwise operators helps MSVC and ICC

In my very limited testing, | and & seem to work better than || and && for MSVC and ICC. Look at the compiler output for your own code with your compiler + compile options to see what happens.

int select_bitand(bool a, bool b, int x, int y) {
    return (a&b) ? x : y;

Gcc still branches separately on separate tests of the two inputs, same code as the other versions of select. clang still does two separate test/cmov, same asm as for the other source versions.

MSVC comes through and optimizes correctly, beating all the other compilers (at least in the stand-alone definition):

select_bitand PROC            ;; MSVC
    test     cl, dl           ;; ZF =  !(a & b)
    cmovne   r9d, r8d
    mov      eax, r9d         ;; could have done the mov to eax in parallel with the test, off the critical path, but close enough.
    ret      0

ICC18 wastes two movzx instructions zero-extending the bools to int, but then makes the same code as MSVC

select_bitand:          ## ICC18
    movzx     edi, dil                                      #16.49
    movzx     esi, sil                                      #16.49
    test      edi, esi                                      #17.15
    cmovne    ecx, edx                                      #17.15
    mov       eax, ecx                                      #17.15
    ret                                                     #17.15
  • @Mgetz: static performance analysis is pretty trivial here because the compilers are making code that does the same work + more (so worse throughput, latency, and uop count), except for branching vs. branchless. Two separate test/cmov are always worse than one test/cmov, the way compilers are using them. See agner.org/optimize to learn more about the pipelines of modern x86 CPUs. See also some of my answers, like stackoverflow.com/questions/45113527/…. – Peter Cordes Nov 13 '17 at 16:24
  • Or Why is this C++ code faster than my hand-written assembly for testing the Collatz conjecture?. For simple loops, you often can correctly predict how many cycles per iteration they'll run. I've even done CPU performance experiments like stackoverflow.com/questions/45660139/…, so I think I'm qualified to comment on compiler code-gen quality. – Peter Cordes Nov 13 '17 at 16:26
  • @Mgetz: Anyway, yes, that's true in general for sure. Good point. Did my answer maybe give the wrong impression somewhere? – Peter Cordes Nov 13 '17 at 16:32
  • It is more that it didn't contain the usual disclaimer at the top so I figured I would include it at the bottom. – Mgetz Nov 13 '17 at 18:20

I think this is not the case.

First of all, this reasoning is completely unacceptable:

The reason why the compiler doesn't make such an assumption is that the variables might have other values if they are uninitialized or come from unknown sources.

Let's check some code (compiled with clang 6, but GCC 7 and MSVC 2017 produces similar code).

Boolean or:

bool fn(bool a, bool b) {
    return a||b;

0000000000000000 <fn(bool, bool)>:
   0:   40 08 f7                or     dil,sil
   3:   40 88 f8                mov    al,dil
   6:   c3                      ret    

As can be seen, no 0/1 check here, simple or.

Convert bool to int:

int fn(bool a) {
    return a;

0000000000000000 <fn(bool)>:
   0:   40 0f b6 c7             movzx  eax,dil
   4:   c3                      ret    

Again, no check, simple move.

Convert char to bool:

bool fn(char a) {
    return a;

0000000000000000 <fn(char)>:
   0:   40 84 ff                test   dil,dil
   3:   0f 95 c0                setne  al
   6:   c3                      ret    

Here, char is checked whether it is 0, or not, and bool value set to 0 or 1 accordingly.

So I think it is safe to say that the compiler uses bool in a way so it always contains a 0/1. It never checks its validity.

About efficiency: I think bool is optimal. The only case I can imagine, where this approach is not optimal is char->bool conversion. That operation could be a simple mov, if bool value wouldn't be restricted to 0/1. For all other operations, the current approach is equally good, or better.

EDIT: Peter Cordes mentioned ABI. Here's the relevant text from the System V ABI for AMD64 (the text for i386 is similar):

Booleans, when stored in a memory object, are stored as single byte objects the value of which is always 0 (false) or 1 (true). When stored in integer registers (except for passing as arguments), all 8 bytes of the register are significant; any nonzero value is considered true

So for platforms which follow SysV ABI, we can be sure that a bool has a 0/1 value.

I searched for ABI document for MSVC, but unfortunately I didn't find anything about bool.

  • Comments are not for extended discussion; this conversation has been moved to chat. – Andy Nov 14 '17 at 13:45

I compiled the following with clang++ -O3 -S

bool andbool(bool a, bool b)
    return a && b;

bool andint(int a, int b)
    return a && b;

The .s file contains:

andbool(bool, bool):                           # @andbool(bool, bool)
    andb    %sil, %dil
    movl    %edi, %eax

andint(int, int):                            # @andint(int, int)
    testl   %edi, %edi
    setne   %cl
    testl   %esi, %esi
    setne   %al
    andb    %cl, %al

Clearly it's the bool version that's doing less.

  • 1
    andb is a simple AND operation, it doesn't do what you say. testl+setne does the zero-nonzero -> 0/1 conversion. – geza Nov 12 '17 at 0:26
  • @geza: oh yeah - I misread the docs on that. Cheers. – Tony Delroy Nov 12 '17 at 0:54
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    This answer (and geza's answer) are both misleading because they fail to look at the big picture. When you declare a function as bool foo(bool a, bool b), the implementation of the function will assume that a and b are valid bools, i.e. can only have the value 0 or 1. It's the caller's responsibility to convert other types to bool. So if you look at the code that the compiler generates to call the function, you will see the testl+setne code (assuming that the caller is starting with some non-bool type like int). – user3386109 Nov 12 '17 at 0:59
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    @user3386109: I don't consider it misleading. The code shows that a function dealing with bools doesn't expend effort worrying about such conversions, and by extension - if the caller has accepted bool arguments and passed them through, retrieved/passed bool return values from functions called etc. it won't be constantly and redundantly expending effort on paranoid conversions that are safe for non 0/1 values, which is IMHO the worrying implication of Agner's statements. Of course some conversions must happen when they're actually functionally required. – Tony Delroy Nov 12 '17 at 1:32

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