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Is it worthwhile using C's bit-field implementation? If so, when is it ever used?

I was looking through some emulator code and it looks like the registers for the chips are not being implemented using bit fields.

Is this something that is avoided for performance reasons (or some other reason)?

Are there still times when bit-fields are used? (ie firmware to put on actual chips, etc)

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9 Answers 9

Bit-fields are typically only used when there's a need to map structure fields to specific bit slices, where some hardware will be interpreting the raw bits. An example might be assembling an IP packet header. I can't see a compelling reason for an emulator to model a register using bit-fields, as it's never going to touch real hardware!

Whilst bit-fields can lead to neat syntax, they're pretty platform-dependent, and therefore non-portable. A more portable, but yet more verbose, approach is to use direct bitwise manipulation, using shifts and bit-masks.

If you use bit-fields for anything other than assembling (or disassembling) structures at some physical interface, performance may suffer. This is because every time you read or write from a bit-field, the compiler will have to generate code to do the masking and shifting, which will burn cycles.

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regarding the "burning cycles" issue, I have found that it was indeed faster to use the smallest integer type possible rather than using bitfields. Except for boolean flags (for which masking is easy and no shifting is required), I therefore agree with you :) – Matthieu M. Nov 22 '10 at 7:59
@Matthieu: I would imagine that in most circumstances, using int would be fastest, because it's the platform's native width. The exception to this would be if doing everything as int makes your data structures significantly bigger, causing cache misses, etc. – Oliver Charlesworth Nov 22 '10 at 10:13
@OliCharlesworth, the network little-endian or big-endian issue will make your using bit-field pass packet header failed. And the C++ standard also doesn't define the how bit-field stored, it is implement specific. And base on the performance of bit-field is not good, bit-field is useless. – ZijingWu Sep 9 '13 at 10:32
@ZijingWu, "Implementation-specific" (or "platform/compiler-dependent") does not make something useless. It just means that there are limited applications and you have to be careful. – patrickvacek Nov 12 '13 at 16:58

One use for bitfields which hasn't yet been mentioned is that unsigned bitfields provide arithmetic modulo a power-of-two "for free". For example, given:

struct { unsigned x:10; } foo;

arithmetic on foo.x will be performed modulo 210 = 1024.

(The same can be achieved directly by using bitwise & operations, of course - but sometimes it might lead to clearer code to have the compiler do it for you).

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It's worth noting that it is likely here that sizeof(foo) == sizeof(unsigned), ie you're not saving any memory, you're just having a nicer syntax. – Matthieu M. Nov 22 '10 at 7:54
I wouldn't assume that sizeof(foo)==sizeof(unsigned) when sizeof(unsigned)==4 – MSalters Nov 22 '10 at 10:20
@caf, You can also do it without bitfields without two much trouble. Just calculate the result and &(2^n - 1) – ZijingWu Sep 9 '13 at 10:29
@ZijingWu: Yes, that's what I was referring to in the last paragraph. – caf Sep 9 '13 at 12:21
I have used a 3 bit value in a for loop to cycle 0 .. 7 over and over again. – EvilTeach May 29 '14 at 13:16

I've seen/used bit fields in two situations: Computer Games and Hardware Interfaces. The hardware use is pretty straight forward: the hardware expects data in a certain bit format you can either define manually or through pre-defined library structures. It depends on the specific library whether they use bit fields or just bit manipulation.

In the "old days" computers games used bit fields frequently to make the most use of computer/disk memory as possible. For example, for a NPC definition in a RPG you might find (made up example):

struct charinfo_t
     unsigned int Strength : 7;  // 0-100
     unsigned int Agility : 7;  
     unsigned int Endurance: 7;  
     unsigned int Speed : 7;  
     unsigned int Charisma : 7;  
     unsigned int HitPoints : 10;    //0-1000
     unsigned int MaxHitPoints : 10;  

You don't see it so much in more modern games/software as the space savings has gotten proportionally worse as computers get more memory. Saving a 1MB of memory when your computer only has 16MB is a big deal but not so much when you have 4GB.

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Computers may have more RAM these days, but keeping memory usage lower can help to keep it within the CPU memory cache, which would increase performance. On the other hand, bitfields require more instructions to access them, which decreases performance. Which is more significant? – Craig McQueen Jan 2 '13 at 6:46

One use for bit fields used to be to mirror hardware registers when writing embedded code. However, since the bit order is platform-dependent, they don't work if the hardware orders its bits different from the processor. That said, I can't think of a use for bit fields any more. You're better off implementing a bit manipulation library that can be ported across platforms.

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How should one best write such a library? One approach in C++ would be to define a property which would take an address and bit range and yield a modifiable integer lvalue, and then do something like "#define UART3_BAUD_RATE_MODE MOD_BITFIELD(UART3_CONTROL,12,4)". I would expect one could arrange things so that reads and writes would be inlined (rather than generating function calls) but I don't know how best to arrange for the Boolean-logical-assignment operators (|= etc.) to work efficiently and/or atomically. – supercat May 31 '11 at 20:36

In modern code, there's really only one reason to use bitfields: to control the space requirements of a bool or an enum type, within a struct/class. For instance (C++):

enum token_code { TK_a, TK_b, TK_c, ... /* less than 255 codes */ };
struct token {
    token_code code      : 8;
    bool number_unsigned : 1;
    bool is_keyword      : 1;
    /* etc */

IMO there's basically no reason not to use :1 bitfields for bool, as modern compilers will generate very efficient code for it. In C, though, make sure your bool typedef is either the C99 _Bool or failing that an unsigned int, because a signed 1-bit field can hold only the values 0 and -1 (unless you somehow have a non-twos-complement machine).

With enumeration types, always use a size that corresponds to the size of one of the primitive integer types (8/16/32/64 bits, on normal CPUs) to avoid inefficient code generation (repeated read-modify-write cycles, usually).

Using bitfields to line up a structure with some externally-defined data format (packet headers, memory-mapped I/O registers) is commonly suggested, but I actually consider it a bad practice, because C doesn't give you enough control over endianness, padding, and (for I/O regs) exactly what assembly sequences get emitted. Have a look at Ada's representation clauses sometime if you want to see how much C is missing in this area.

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Note: bitfields on bool and MSVC don't mix, for compatibility with MSVC you need to use some unsigned. – Matthieu M. Nov 22 '10 at 7:56
Yet another reason to avoid MSVC then :-( – zwol Nov 22 '10 at 17:37

FWIW, and looking only at the relative performance question - a bodgy benchmark:

#include <time.h>
#include <iostream>

struct A
    void a(unsigned n) { a_ = n; }
    void b(unsigned n) { b_ = n; }
    void c(unsigned n) { c_ = n; }
    void d(unsigned n) { d_ = n; }
    unsigned a() { return a_; }
    unsigned b() { return b_; }
    unsigned c() { return c_; }
    unsigned d() { return d_; }
    volatile unsigned a_:1,

struct B
    void a(unsigned n) { a_ = n; }
    void b(unsigned n) { b_ = n; }
    void c(unsigned n) { c_ = n; }
    void d(unsigned n) { d_ = n; }
    unsigned a() { return a_; }
    unsigned b() { return b_; }
    unsigned c() { return c_; }
    unsigned d() { return d_; }
    volatile unsigned a_, b_, c_, d_;

struct C
    void a(unsigned n) { x_ &= ~0x01; x_ |= n; }
    void b(unsigned n) { x_ &= ~0x3E; x_ |= n << 1; }
    void c(unsigned n) { x_ &= ~0xC0; x_ |= n << 6; }
    void d(unsigned n) { x_ &= ~0xFF00; x_ |= n << 8; }
    unsigned a() const { return x_ & 0x01; }
    unsigned b() const { return (x_ & 0x3E) >> 1; }
    unsigned c() const { return (x_ & 0xC0) >> 6; }
    unsigned d() const { return (x_ & 0xFF00) >> 8; }
    volatile unsigned x_;

struct Timer
    Timer() { get(&start_tp); }
    double elapsed() const {
        struct timespec end_tp;
        return (end_tp.tv_sec - start_tp.tv_sec) +
               (1E-9 * end_tp.tv_nsec - 1E-9 * start_tp.tv_nsec);
    static void get(struct timespec* p_tp) {
        if (clock_gettime(CLOCK_REALTIME, p_tp) != 0)
            std::cerr << "clock_gettime() error\n";
    struct timespec start_tp;

template <typename T>
unsigned f()
    int n = 0;
    Timer timer;
    T t;
    for (int i = 0; i < 10000000; ++i)
        t.a(i & 0x01);
        t.b(i & 0x1F);
        t.c(i & 0x03);
        t.d(i & 0xFF);
        n += t.a() + t.b() + t.c() + t.d();
    std::cout << timer.elapsed() << '\n';
    return n;

int main()
    std::cout << "bitfields: " << f<A>() << '\n';
    std::cout << "separate ints: " << f<B>() << '\n';
    std::cout << "explicit and/or/shift: " << f<C>() << '\n';

Output on my test machine (numbers vary by ~20% run to run):

bitfields: 0.140586
separate ints: 0.039374
explicit and/or/shift: 0.252723

Suggests that with g++ -O3 on a pretty recent Athlon, bitfields are worse than a few times slower than separate ints, and this particular and/or/bitshift implementation's at least twice as bad again ("worse" as other operations like memory read/writes are emphasised by the volatility above, and there's loop overhead etc, so the differences are understated in the results).

If you're dealing in hundreds of megabytes of structs that can be mainly bitfields or mainly distinct ints, the caching issues may become dominant - so benchmark in your system.

Of course, timing's all relative and which way you implement these fields may not matter at all in the context of your system.

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Bit fields were used in the olden days to save program memory.

They degrade performance because registers can not work with them so they have to be converted to integers to do anything with them. They tend to lead to more complex code that is unportable and harder to understand (since you have to mask and unmask things all the time to actually use the values.)

Check out the source for to see pre ansi c in all its bitfield glory!

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Boost.Thread uses bitfields in its shared_mutex, on Windows at least:

    struct state_data
        unsigned shared_count:11,
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Looks like this was done to pack the structure into exactly one 32-bit machine word, probably for atomicity. Boost folken know exactly what they're doing and don't tend to explain themselves in enough detail for people who don't, which unfortunately means copying Boost logic can very easily end in tears -- for instance, there's a reason exclusive and upgrade aren't bool, but do you know what it is? – zwol Nov 22 '10 at 0:30
The logic uses compare-and-swap to avoid kernel locks unless essential. I am sure that's why it's done this way. – Steve Townsend Nov 22 '10 at 1:59

In the 70s I used bit fields to control hardware on a trs80. The display/keyboard/cassette/disks were all memory mapped devices. Individual bits controlled various things.

  1. A bit controlled 32 column vs 64 column display.
  2. Bit 0 in that same memory cell was the cassette serial data in/out.

As I recall, the disk drive control had a number of them. There were 4 bytes in total. I think there was a 2 bit drive select. But it was a long time ago. It was kind of impressive back then in that there were at least two different c compilers for the plantform.

The other observation is that bit fields really are platform specific. There is no expectation that a program with bit fields should port to another platform.

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