191

In C++,

  • Why is a boolean 1 byte and not 1 bit of size?
  • Why aren't there types like a 4-bit or 2-bit integers?

I'm missing out the above things when writing an emulator for a CPU

2
  • 11
    In C++ you can "pack" the data by using bit-fields. struct Packed { unsigned int flag1 : 1; unsigned int flag2: 1; };. Most compilers will allocate a full unsigned int, however they deal with the bit-twiddling by themselves when you read / write. Also they deal by themselves with the modulo operations. That is a unsigned small : 4 attribute has a value between 0 and 15, and when it should get to 16, it won't overwrite the preceding bit :) Jan 7, 2011 at 15:15
  • But note / beware that it's not thread-safe for different threads to write adjacent bitfields in the same object. It is thread-safe for them to write separate bool members of a struct/class. This means compilers are allowed to implement bitfield writes by loading the containing word, doing some bit-manipulation, then just storing the whole word (not doing an atomic CAS). Related: C++ memory model and race conditions on char arrays - that's why word-addressable machines can't use 1-byte char in a C11 or C++11 implementaiton. Dec 12, 2021 at 3:01

13 Answers 13

283

Because the CPU can't address anything smaller than a byte.

9
  • 50
    Actually, the four x86 instructions bt, bts, btr and btc can address single bits! Jan 7, 2011 at 16:07
  • 15
    I think bt addresses a byte offset and then tests the bit at a given offset, regardless, when specifying an address you go in bytes...bit offset literals would get a bit wordy (excuse the pun).
    – user7116
    Jan 7, 2011 at 16:12
  • 3
    @six: You can load the beginning of an array in one register and then the relative "bit offset" into a second. The bit offset is not limited to "within one byte", it can be any 32 bit number. Jan 7, 2011 at 16:15
  • 5
    Well, yes and no. We do have bitfields, and we could have a bitfield pointer, that is address + bit number. Obviously, such a pointer would not be convertible to void* because of the extra storage requirement for the bit number. Jan 7, 2011 at 17:10
  • 3
    @gEdringer if you're trying to cram as much information into sub-byte fields as you can fit, there are always bitfields. Sep 6, 2016 at 12:25
54

From Wikipedia:

Historically, a byte was the number of bits used to encode a single character of text in a computer and it is for this reason the basic addressable element in many computer architectures.

So byte is the basic addressable unit, below which computer architecture cannot address. And since there doesn't (probably) exist computers which support 4-bit byte, you don't have 4-bit bool etc.

However, if you can design such an architecture which can address 4-bit as basic addressable unit, then you will have bool of size 4-bit then, on that computer only!

6
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    "you will have int of size 4-bit then, on that computer only" - no you won't, because the standard forbids CHAR_BIT from being less than 8. If the addressable unit on the architecture is less than 8 bits, then a C++ implementation will just have to present a memory model that's different from the underlying hardware's memory model. Jan 7, 2011 at 16:51
  • @Steve : oops... I overlooked that. Removed int and char from my post.
    – Nawaz
    Jan 7, 2011 at 16:58
  • 2
    you can't have a 4-bit bool either, because the char is the smallest addressable unit in C++, regardless of what the architecture can address with its own opcodes. sizeof(bool) must have a value of at least 1, and adjacent bool objects must have their own addresses in C++, so the implementation just has to make them bigger and waste memory. That's why bit fields exist as a special case: the bitfield members of a struct aren't required to be separately addressable, so they can be smaller than a char (although the whole struct still can't be). Jan 8, 2011 at 12:59
  • 1
    @ Steve Jessop : that seems interesting. could you please give me the reference from the language specification where it says char is the smallest addressable unit in C++?
    – Nawaz
    Jan 8, 2011 at 13:09
  • 4
    closest specific statement is probably 3.9/4: "The object representation of an object of type T is the sequence of N unsigned char objects taken up by the object of type T, where N equals sizeof(T)". Obviously sizeof(bool) can't be 0.5 :-) I suppose an implementation could legally provide sub-byte pointers as an extension, but "ordinary" objects like bool, allocated in ordinary ways, have to do what the standard says. Jan 8, 2011 at 15:43
21

Back in the old days when I had to walk to school in a raging blizzard, uphill both ways, and lunch was whatever animal we could track down in the woods behind the school and kill with our bare hands, computers had much less memory available than today. The first computer I ever used had 6K of RAM. Not 6 megabytes, not 6 gigabytes, 6 kilobytes. In that environment, it made a lot of sense to pack as many booleans into an int as you could, and so we would regularly use operations to take them out and put them in.

Today, when people will mock you for having only 1 GB of RAM, and the only place you could find a hard drive with less than 200 GB is at an antique shop, it's just not worth the trouble to pack bits.

20
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    Except when dealing with Flags. Things like Setting multiple options on something... eg. 00000001 + 00000100 = 00000101. Jan 7, 2011 at 21:22
  • 1
    @Atomix: I almost never do this anymore. If I need two flags, I create two boolean fields. I used to write code where I'd pack flags like that and then write "if flags & 0x110 != 0 then" or the like, but this is cryptic and these days I generally make separate fields and write "if fooFlag || barFlag" instead. I wouldn't rule out the possibility of cases where packing flags like that is better for some reason, but it's no longer necessary to save memory like it used to be.
    – Jay
    Jan 10, 2011 at 18:56
  • 7
    Actually, it is quite worth your trouble to pack bits, if you want your computation to be fast - on that large amount of data you store in memory. Packing booleans isn't just for smaller storage - it means you can read your boolean input arrays 8 times faster (in terms of bandwidth) as when they're unpacked, and that's often quite significant. Also, you can use bit operations, like popc (population count) which speeds up your work on the CPU itself.
    – einpoklum
    May 18, 2016 at 12:39
  • 4
    Truly huge number of booleans is what you work with every day if you do: DBMSes, machine learning, scientific simulations, and a whole host of other things. And - just working on them means copying them - from memory into cache. A million bools is nothing, think billions.
    – einpoklum
    May 18, 2016 at 17:33
  • 1
    CPU cache is always "highly constrained", like 32k L1d cache, 256k L2 cache. Having your working set fit in cache is a very big deal. Packing bitmaps is a very good thing for a big Sieve of Eratosthenes, but yes if even unpacked bool[] will fit in cache then it's typically better at small sizes. If you use SIMD to handle multiple elements at once, doing 128 bools per 16-byte SIMD vector instead of 16 is a nice speedup (for bitwise AND, or popcount). Or with AVX512, you can compare into a mask, or load a chunk of bitmap from memory and use it as a mask for SIMD vector elements. May 31, 2020 at 21:31
18

The easiest answer is; it's because the CPU addresses memory in bytes and not in bits, and bitwise operations are very slow.

However it's possible to use bit-size allocation in C++. There's std::vector specialization for bit vectors, and also structs taking bit sized entries.

7
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    Not sure I would agree that bitwise operations are slow. ands, nots, xors etc are very fast. It is typically the implementation of the bitwise operations that are slow. At the machine level they are quite fast. Branching... now that is slow.
    – Hogan
    Jan 7, 2011 at 15:07
  • 6
    Just to make it more clear, if you create a vector of booleans and put 24 booleans into it, it will be taking 3 bytes only (3*8). If you put another boolean in, it will take another byte. Yet, if you push another boolean, it won't take any extra bytes because it uses the "free" bits in the last byte Jan 7, 2011 at 15:08
  • yeah, I also doubt bitewise operations are slow :) Jan 7, 2011 at 15:09
  • 1
    The bit vectors do not create bit-sized allocations. they create byte-sized allocations. It is not possible to allocate a single bit. Jan 7, 2011 at 15:11
  • 5
    Reading a single bit in a bit vector requires three operations: shift, and, and another shift again. Writing is two. Whereas individual bytes can be accessed with a single one.
    – sukru
    Jan 7, 2011 at 15:21
12

Because a byte is the smallest addressible unit in the language.

But you can make bool take 1 bit for example if you have a bunch of them eg. in a struct, like this:

struct A
{
  bool a:1, b:1, c:1, d:1, e:1;
};
11

You could have 1-bit bools and 4 and 2-bit ints. But that would make for a weird instruction set for no performance gain because it's an unnatural way to look at the architecture. It actually makes sense to "waste" a better part of a byte rather than trying to reclaim that unused data.

The only app that bothers to pack several bools into a single byte, in my experience, is Sql Server.

10

You can use bit fields to get integers of sub size.

struct X
{
    int   val:4;   // 4 bit int.
};

Though it is usually used to map structures to exact hardware expected bit patterns:

// 1 byte value (on a system where 8 bits is a byte)
struct SomThing   
{
    int   p1:4;   // 4 bit field
    int   p2:3;   // 3 bit field
    int   p3:1;   // 1 bit
};
6

bool can be one byte -- the smallest addressable size of CPU, or can be bigger. It's not unusual to have bool to be the size of int for performance purposes. If for specific purposes (say hardware simulation) you need a type with N bits, you can find a library for that (e.g. GBL library has BitSet<N> class). If you are concerned with size of bool (you probably have a big container,) then you can pack bits yourself, or use std::vector<bool> that will do it for you (be careful with the latter, as it doesn't satisfy container requirments).

3

Think about how you would implement this at your emulator level...

bool a[10] = {false};

bool &rbool = a[3];
bool *pbool = a + 3;

assert(pbool == &rbool);
rbool = true;
assert(*pbool);
*pbool = false;
assert(!rbool);
3

Because in general, CPU allocates memory with 1 byte as the basic unit, although some CPU like MIPS use a 4-byte word.

However vector deals bool in a special fashion, with vector<bool> one bit for each bool is allocated.

5
  • 1
    I believe even the MIPS cpu will give you access to an individual byte, although there is a performance penalty. Jan 7, 2011 at 15:21
  • @Paul: Yes you are right, but generally the word-specific lw/sw are much more widely used.
    – Ryan Li
    Jan 7, 2011 at 15:29
  • Don't know about MIPS, but IA-64 architecture allows only access on 64-bit boundary. Jan 7, 2011 at 16:06
  • @PaulTomblin: you're correct, DEC Alpha is the only ISA in recent memory with byte-addressable memory but without byte actual byte load/store instructions. (See Can modern x86 hardware not store a single byte to memory? for details). Dec 12, 2021 at 3:21
  • @GeneBushuyev: Wrong for IA-64. csee.umbc.edu/portal/help/architecture/aig.pdf#page=41 confirms that IA-64 ld instructions supported an access size of 1, 2, 4, or 8 bytes. (For sizes less than 64-bit, the result is zero-extended into a 64-bit reg, like a normal RISC rather than x86 partial-registers.) Since IA-64 was designed by Intel with hopes of taking over from x86 (via emulation, or in early CPUs via hardware support for an IA-32 mode), unaligned word load/store is also optionally supported (even in IA-64 mode). Dec 12, 2021 at 3:32
0

The byte is the smaller unit of digital data storage of a computer. In a computer the RAM has millions of bytes and anyone of them has an address. If it would have an address for every bit a computer could manage 8 time less RAM that what it can.

More info: Wikipedia

0

Even when the minimum size possible is 1 Byte, you can have 8 bits of boolean information on 1 Byte:

http://en.wikipedia.org/wiki/Bit_array

Julia language has BitArray for example, and I read about C++ implementations.

0

Bitwise operations are not 'slow'.

And/Or operations tend to be fast.

The problem is alignment and the simple problem of solving it.

CPUs as the answers partially-answered correctly are generally aligned to read bytes and RAM/memory is designed in the same way.

So data compression to use less memory space would have to be explicitly ordered.

As one answer suggested, you could order a specific number of bits per value in a struct. However what does the CPU/memory do afterward if it's not aligned? That would result in unaligned memory where instead of just +1 or +2, or +4, there's not +1.5 if you wanted to use half the size in bits in one value, etc. so it must anyway fill in or revert the remaining space as blank, then simply read the next aligned space, which are aligned by 1 at minimum and usually by default aligned by 4(32bit) or 8(64bit) overall. The CPU will generally then grab the byte value or the int value that contains your flags and then you check or set the needed ones. So you must still define memory as int, short, byte, or the proper sizes, but then when accessing and setting the value you can explicitly compress the data and store those flags in that value to save space; but many people are unaware of how it works, or skip the step whenever they have on/off values or flag present values, even though saving space in sent/recv memory is quite useful in mobile and other constrained enviornments. In the case of splitting an int into bytes it has little value, as you can just define the bytes individually (e.g. int 4Bytes; vs byte Byte1;byte Byte2; byte Byte3; byte Byte4;) in that case it is redundant to use int; however in virtual environments that are easier like Java, they might define most types as int (numbers, boolean, etc.) so thus in that case, you could take advantage of an int dividing it up and using bytes/bits for an ultra efficient app that has to send less integers of data (aligned by 4). As it could be said redundant to manage bits, however, it is one of many optimizations where bitwise operations are superior but not always needed; many times people take advantage of high memory constraints by just storing booleans as integers and wasting 'many magnitudes' 500%-1000% or so of memory space anyway. It still easily has its uses, if you use this among other optimizations, then on the go and other data streams that only have bytes or few kb of data flowing in, it makes the difference if overall you optimized everything to load on whether or not it will load,or load fast, at all in such cases, so reducing bytes sent could ultimately benefit you alot; even if you could get away with oversending tons of data not required to be sent in an every day internet connection or app. It is definitely something you should do when designing an app for mobile users and even something big time corporation apps fail at nowadays; using too much space and loading constraints that could be half or lower. The difference between not doing anything and piling on unknown packages/plugins that require at minumim many hundred KB or 1MB before it loads, vs one designed for speed that requires say 1KB or only fewKB, is going to make it load and act faster, as you will experience those users and people who have data constraints even if for you loading wasteful MB or thousand KB of unneeded data is fast.

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