182

Many style guides such as the Google one recommend using int as a default integer when indexing arrays for instance. With the rise of 64-bit platforms where most of the time an int is only 32 bits which is not the natural width of the platform. As a consequence, I see no reason, apart from the simple same, to keep that choice. We clearly see that where compiling the following code:

double get(const double* p, int k) {
  return p[k];
}

which gets compiled into

movslq %esi, %rsi
vmovsd (%rdi,%rsi,8), %xmm0
ret

where the first instruction promotes the 32 bits integer into a 64 bits integer.

If the code is transformed into

double get(const double* p, std::ptrdiff_t k) {
  return p[k];
}

the generated assembly is now

vmovsd (%rdi,%rsi,8), %xmm0
ret

which clearly shows that the CPU feels more at home with std::ptrdiff_t than with an int. Many C++ users have moved to std::size_t, but I don't want to use unsigned integers unless I really need modulo 2^n behaviour.

In most cases, using int does not hurt performance as the undefined behaviour or signed integer overflows allow the compiler to internally promote any int to a std::ptrdiff_t in loops that deal with indices, but we clearly see from the above that the compiler does not feel at home with int. Also, using std::ptrdiff_t on a 64-bit platform would make overflows less likely to happen as I see more and more people getting trapped by int overflows when they have to deal with integers larger than 2^31 - 1 which become really common these days.

From what I have seen, the only thing that makes int stand apart seems to be the fact that literals such as 5 are int, but I don't see where it might cause any problem if we move to std::ptrdiff_t as a default integer.

I am on the verge of making std::ptrdiff_t as the de facto standard integer for all the code written in my small company. Is there a reason why it could be a bad choice?

PS: I agree with the fact that the name std::ptrdiff_t is ugly which is the reason why I have typedef'ed it to il::int_t which look a bit better.

PS: As I know that many people will recommend me to use std::size_t as a default integer, I really want to make it clear that I don't want to use an unsigned integer as my default integer. The use of std::size_t as a default integer in the STL has been a mistake as acknowledged by Bjarne Stroustrup and the standard committee in the video Interactive Panel: Ask Us Anything at time 42:38 and 1:02:50.

PS: In terms of performance, on any 64-bit platform that I know of, +, - and * gets compiled the same way for both int and std::ptrdiff_t. So there is no difference in speed. If you divide by a compile-time constant, the speed is the same. It's only when you divide a/b when you know nothing about b that using 32 bits integer on a 64-bit platform gives you a slight advantage in performance. But this case is so rare as I don't see as a choice from moving away from std::ptrdiff_t. When we deal with vectorized code, here there is a clear difference, and the smaller, the better, but that's a different story, and there would be no reason to stick with int. In those cases, I would recommend going to the fixed size types of C++.

marked as duplicate by Galik, technosaurus, dan04, Joe, Robert Harvey Feb 13 '18 at 17:51

This question has been asked before and already has an answer. If those answers do not fully address your question, please ask a new question.

  • 34
    "Many style guides such as the Google one recommend to use int as a default integer, when indexing arrays for instance" - citation needed. You should always use size_t or size_type (STL). – Dai Feb 11 '18 at 7:42
  • 30
    "which gets compiled into" - With what flags and by which compiler? – StoryTeller Feb 11 '18 at 7:43
  • 32
    Using int to index into arrays is simply wrong as there's no guarantee int is large enough to cover all possible indices in an array. std::size_t is the right type for that. – user703016 Feb 11 '18 at 7:44
  • 72
    The Google style guide is mostly crap. I'd stay away from it. – Jesper Juhl Feb 11 '18 at 7:54
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    "I don't want to use unsigned integers unless I really need modulo 2^n behaviour." -- you don't want to pass a negative array index either... (Undefined Behavior in C) – David C. Rankin Feb 11 '18 at 7:54

10 Answers 10

106

There was a discussion on the C++ Core Guidelines what to use:

https://github.com/isocpp/CppCoreGuidelines/pull/1115

Herb Sutter wrote that gsl::index will be added (in the future maybe std::index), which will be defined as ptrdiff_t.

hsutter commented on 26 Dec 2017 •

(Thanks to many WG21 experts for their comments and feedback into this note.)

Add the following typedef to GSL

namespace gsl { using index = ptrdiff_t; }

and recommend gsl::index for all container indexes/subscripts/sizes.

Rationale

The Guidelines recommend using a signed type for subscripts/indices. See ES.100 through ES.107. C++ already uses signed integers for array subscripts.

We want to be able to teach people to write "new clean modern code" that is simple, natural, warning-free at high warning levels, and doesn’t make us write a "pitfall" footnote about simple code.

If we don’t have a short adoptable word like index that is competitive with int and auto, people will still use int and auto and get their bugs. For example, they will write for(int i=0; i<v.size(); ++i) or for(auto i=0; i<v.size(); ++i) which have 32-bit size bugs on widely used platforms, and for(auto i=v.size()-1; i>=0; ++i) which just doesn't work. I don’t think we can teach for(ptrdiff_t i = ... with a straight face, or that people would accept it.

If we had a saturating arithmetic type, we might use that. Otherwise, the best option is ptrdiff_t which has nearly all the advantages of a saturating arithmetic unsigned type, except only that ptrdiff_t still makes the pervasive loop style for(ptrdiff_t i=0; i<v.size(); ++i) emit signed/unsigned mismatches on i<v.size() (and similarly for i!=v.size()) for today's STL containers. (If a future STL changes its size_type to be signed, even this last drawback goes away.)

However, it would be hopeless (and embarrassing) to try to teach people to routinely write for (ptrdiff_t i = ... ; ... ; ...). (Even the Guidelines currently use it in only one place, and that's a "bad" example that is unrelated to indexing`.)

Therefore we should provide gsl::index (which can later be proposed for consideration as std::index) as a typedef for ptrdiff_t, so we can hopefully (and not embarrassingly) teach people to routinely write for (index i = ... ; ... ; ...).

Why not just tell people to write ptrdiff_t? Because we believe it would be embarrassing to tell people that's what you have to do in C++, and even if we did people won't do it. Writing ptrdiff_t is too ugly and unadoptable compared to auto and int. The point of adding the name index is to make it as easy and attractive as possible to use a correctly sized signed type.

Edit: More rationale from Herb Sutter

Is ptrdiff_t big enough? Yes. Standard containers are already required to have no more elements than can be represented by ptrdiff_t, because subtracting two iterators must fit in a difference_type.

But is ptrdiff_t really big enough, if I have a built-in array of char or byte that is bigger than half the size of the memory address space and so has more elements than can be represented in a ptrdiff_t? Yes. C++ already uses signed integers for array subscripts. So use index as the default option for the vast majority of uses including all built-in arrays. (If you do encounter the extremely rare case of an array, or array-like type, that is bigger than half the address space and whose elements are sizeof(1), and you're careful about avoiding truncation issues, go ahead and use a size_t for indexes into that very special container only. Such beasts are very rare in practice, and when they do arise often won't be indexed directly by user code. For example, they typically arise in a memory manager that takes over system allocation and parcels out individual smaller allocations that its users use, or in an MPEG or similar which provides its own interface; in both cases the size_t should only be needed internally within the memory manager or the MPEG class implementation.)

  • 5
    In response to the quoted text; using a signed index has the obvious problem of causing integer overflow when accessing a container whose size exceeds SIZE_MAX/2. I hope there are also other changes to address this problem (e.g. making the maximum size of an object actually be SIZE_MAX/2 instead of SIZE_MAX). – M.M Feb 11 '18 at 20:39
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    Defining gsl::index as ptrdiff_t will make it an instant anti-pattern in contexts where negative indexing is inappropriate. It will implicitly label any code that'd use gsl::index in such contexts as "garbage quality code". The appropriate type is indeed std::size_t and without any doubt is has to be unsigned. Everybody understands that signed indexing is necessary in some contexts, but making people use signed indexing by default is not an option. The need for different types in different contexts is exactly why we don't have a "default" index type. Such type does not exist. – AnT Feb 12 '18 at 2:20
  • 3
    I don't understand how using ptrdiff_t is embarrasing. It's fine if Sutter doesn't like it, but it's not a good argument against it. – user694733 Feb 12 '18 at 8:45
  • 1
    @AnT Actually not "Everybody understands". This is why a default is needed. Experts with experience don't need to use this. But until everybody in their programing environment understands and is ready to progress to the "next" level, the defaults are needed to guide them. And as is mentioned (on unsigned integers in the STL) in the interview linked in the question - Sutter: "They are wrong." Chandler: "We're Sorry." Sutter: "As Scott (Meyers) would say - we were young." ;-) – Robert Andrzejuk Feb 12 '18 at 9:48
  • 2
    "Because we believe it would be embarrassing to tell people that's what you have to do in C++" -- Indeed, C++ is embarassing enough as it is. Not a sound reason though. I agree with @user694733. – alecov Feb 12 '18 at 16:46
37

I come at this from the perspective of an old timer (pre C++)... It was understood back in the day that int was the native word of the platform and was likely to give the best performance.

If you needed something bigger, then you'd use it and pay the price in performance. If you needed something smaller (limited memory, or specific need for a fixed size), same thing.. otherwise use int. And yeah, if your value was in the range where int on one target platform could accommodate it and int on another target platform could not.. then we had our compile time size specific defines (prior to them becoming standardized we made our own).

But now, present day, processors and compilers are much more sophisticated and these rules don't apply so easily. It is also harder to predict what the performance impact of your choice will be on some unknown future platform or compiler ... How do we really know that uint64_t for example will perform better or worse than uint32_t on any particular future target? Unless you're a processor/compiler guru, you don't...

So... maybe it's old fashioned, but unless I am writing code for a constrained environment like Arduino, etc. I still use int for general purpose values that I know will be within int size on all reasonable targets for the application I am writing. And the compiler takes it from there... These days that generally means 32 bits signed. Even if one assumes that 16 bits is the minimum integer size, it covers most use cases.. and the use cases for numbers larger than that are easily identified and handled with appropriate types.

  • 10
    More to the point it's just not true any more than int is the native word of the platform. As 64-bit has become the norm, legacy considerations has seen int get left behind. Of course this is why types like size_t exist in the first place - because your system knows best. – Lightness Races in Orbit Feb 11 '18 at 23:24
  • 9
    Presumably an array of 2*31+1 elements doesn't just randomly APPEAR in ones code one day without ones knowledge. It's a deliberate design decision in which case use an adequate type. Do you also explicitly type index values to unint8_t if it's a small array? – little_birdie Feb 12 '18 at 11:32
  • 4
    Sometimes large arrays do just appear in code that previously operated on small arrays. It can happen when you buy a new camera, for instance - do you then inspect all your source code to inspect every allocation of width*height*bpp? – Toby Speight Feb 12 '18 at 13:33
  • 1
    @Bilkokuya Yes, I agree.. I'll improve my answer to be more explicit on this point. Actually I don't presume to know the size of int on absolutely every platform. The fact remains that the use cases for large integer values.. at least in my code.. are quite specific and easily identified when I am coding them. If one prefers to take the pendantic approach and go for the maximum level of explicit typing for a simple loop counter where yea, it's usually going to be 16 bits or less.. I wouldn't say no don't do that.. I just don't consider it to be a clear win for performance. – little_birdie Feb 12 '18 at 17:53
  • 3
    The whole point of the int_fastN_t types from stdint.h is “to give the best performance” given a minimum size constraint. Though, the standard is vague about exactly which integer operations need to be made fast. – dan04 Feb 12 '18 at 17:54
18

Most programs do not live and die on the edge of a few CPU cycles, and int is very easy to write. However, if you are performance-sensitive, I suggest using the fixed-width integer types defined in <cstdint>, such as int32_t or uint64_t. These have the benefit of being very clear in their intended behavior in regards to being signed or unsigned, as well as their size in memory. This header also includes the fast variants such as int_fast32_t, which are at least the stated size, but might be more, if it helps performance.

  • 10
    Using fixed 64-bit integer types for indices kills performance on 32-bit systems. size_t or ptrdiff_t are much better in this regard. – nwellnhof Feb 11 '18 at 13:00
  • 2
    Also, the exact-width types are optional and need not exist, so at least purely from the perspective of keeping your code theoretically portable, I don't think it's good to use them without a specific fixed-width requirement. – underscore_d Feb 11 '18 at 13:17
  • 3
    You're mixing up code size and efficiency. Fixed-size types like int32_t are in general, significantly less efficient, because by forcing an exact size, they constrain the compiler to not use the size that might be more natural or computationally efficient. – Steve Summit Feb 11 '18 at 16:54
  • 4
    @Joshua: I make a living in doing High Performance Computing, and I can tell you than nwellnhof is right: you don't want to use integers whose size is above the word size of the computers unless you really need such a range. It just kills performance. – InsideLoop Feb 11 '18 at 21:59
  • 7
    @Joshua: How can 64-bit anything be faster than 32-bit anything on a 32-bit system? What are you smoking?! – Lightness Races in Orbit Feb 11 '18 at 23:25
15

No formal reason to use int. It doesn't correspond to anything sane as per standard. For indices you almost always want signed pointer-sized integer.

That said, typing int feels like you just said hey to Ritchie and typing std::ptrdiff_t feels like Stroustrup just kicked you in the butt. Coders are people too, don't bring too much ugliness into their life. I would prefer to use long or some easily typed typedef like index instead of std::ptrdiff_t.

  • 2
    Members of the C++ committee agree that ptrdiff_t is ugly. So they propose "index" to be used. – Robert Andrzejuk Feb 11 '18 at 11:04
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    "For indices you almost always want signed machine-word-long type." Which matches the definition of "int"! – Sjoerd Feb 11 '18 at 19:20
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    @Sjoerd int is signed but is 32 bits on most 64-bit platform. – InsideLoop Feb 11 '18 at 20:13
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    @InsideLoop Sadly, you are correct, but that is due to poor judgment on the part of the tool vendors. On an N-bit platform, int should be N-bit by its definition. What we need is something that really means what int used to mean (before 64-bit tool vendors broke it). – Jon Kalb Feb 11 '18 at 22:06
  • 1
    YMMD with that line about Ritchie and Stroustrup :-) – cmaster Feb 13 '18 at 14:26
13

This is somewhat opinion-based, but alas, the question somewhat begs for it, too.

First of all, you talk about integers and indices as if they were the same thing, which is not the case. For any such thing as "integer of sorts, not sure what size", simply using int is of course, most of the time, still appropriate. This works fine most of the time, for most applications, and the compiler is comfortable with it. As a default, that's fine.

For array indices, it's a different story.

There is to date one single formally correct thing, and that's std::size_t. In the future, there may be a std::index_t which makes the intent clearer on the source level, but so far there is not.
std::ptrdiff_t as an index "works" but is just as incorrect as int since it allows for negative indices.
Yes, this happens what Mr. Sutter deems correct, but I beg to differ. Yes, on an assembly language instruction level, this is supported just fine, but I still object. The standard says:

8.3.4/6: E1[E2] is identical to *((E1)+(E2)) [...] Because of the conversion rules that apply to +, if E1 is an array and E2 an integer, then E1[E2] refers to the E2-th member of E1.
5.7/5: [...] If both the pointer operand and the result point to elements of the same array object, or one past the last element of the array object [...] otherwise, the behavior is undefined.

An array subscription refers to the E2-th member of E1. There is no such thing as a negative-th element of an array. But more importantly, the pointer arithmetic with a negative additive expression invokes undefined behavior.

In other words: signed indices of whatever size are a wrong choice. Indices are unsigned. Yes, signed indices work, but they're still wrong.

Now, although size_t is by definition the correct choice (an unsigned integer type that is large enough to contain the size of any object), it may be debatable whether it is truly good choice for the average case, or as a default.

Be honest, when was the last time you created an array with 1019 elements?

I am personally using unsigned int as a default because the 4 billion elements that this allows for is way enough for (almost) every application, and it already pushes the average user's computer rather close to its limit (if merely subscribing an array of integers, that assumes 16GB of contiguous memory allocated). I personally deem defaulting to 64-bit indices as ridiculous.

If you are programming a relational database or a filesystem, then yes, you will need 64-bit indices. But for the average "normal" program, 32-bit indices are just good enough, and they only consume half as much storage.

When keeping around considerably more than a handful of indices, and if I can afford (because arrays are not larger than 64k elements), I even go down to uint16_t. No, I'm not joking there.

Is storage really such a problem? It's ridiculous to greed about two or four bytes saved, isn't it! Well, no...

Size can be a problem for pointers, so sure enough it can be for indices as well. The x32 ABI does not exist for no reason. You will not notice the overhead of needlessly large indices if you have only a handful of them in total (just like pointers, they will be in registers anyway, nobody will notice whether they're 4 or 8 bytes in size).

But think for example of a slot map where you store an index for every element (depending on the implementation, two indices per element). Oh heck, it sure does make a bummer of a difference whether you hit L2 every time, or whether you have a cache miss on every access! Bigger is not always better.

At the end of the day, you must ask yourself what you pay for, and what you get in return. With that in mind, my style recommendation would be:

If it costs you "nothing" because you only have e.g. one pointer and a few indices to keep around, then just use what's formally correct (that'd be size_t). Formally correct is good, correct always works, it's readable and intellegible, and correct is... never wrong.

If, however, it does cost you (you have maybe several hundred or thousand or ten thousand indices), and what you get back is worth nothing (because e.g. you cannot even store 220 elements, so whether you could subscribe 232 or 264 makes no difference), you should think twice about being too wasteful.

  • 2
    I am sorry to disagree with you on the fact that indices should be unsigned integers. As many people in the C++ community, you are wrong. Not only Herb Sutter but also Bjarne Stroustrup and Chandler Carruth agree on that point and believe that the STL made the wrong choice. Yes indices are nonnegative integers. So what? Integer division by 0 implies undefined behavior and nobody felt the need to create a type that does not contain 0. Besides that, if p is a pointer and q = p + n, it turns out that q - p is, by the standard, a ptrdiff_t. It sounds natural for n to be that type. – InsideLoop Feb 14 '18 at 6:29
11

On most modern 64-bit architectures, int is 4 bytes and ptrdiff_t is 8 bytes. If your program uses a lot of integers, using ptrdiff_t instead of int could double your program's memory requirement.

Also consider that modern CPUs are frequently bottlenecked by memory performance. Using 8-byte integers also means your CPU cache now has half as many elements as before, so now it must wait for the slow main memory more often (which can easily take several hundred cycles).

In many cases, the cost of executing "32-to-64-bit conversion" operations is completely dwarfed by memory performance.

So this is a practical reason int is still popular on 64-bit machines.

  • Now you may argue about two dozen different integer types and portability and standard committees and everything, but the truth is that for a lot of C++ programs written out there, there's a "canonical" architecture they're thinking of, which is frequently the only architecture they're ever concerned about. (If you're writing a 3D graphics routine for a Windows game, you're sure it won't run on an IBM mainframe.) So for them, the question boils down to: "Do I need a 4-byte integer or an 8-byte one here?"
  • Would that logic extend to preferring to use uint16_t if you know that the container will never exceed the limits of that type, etc. ? – M.M Feb 11 '18 at 20:20
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    Yes, but of course it's more risky: it's very easy to "accidentally" have a container of 32K elements, for example, while something must go seriously wrong to have a vector of 2G elements in many cases. – jick Feb 11 '18 at 20:25
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    It turns out that I am quite familiar with high performance computing and I have to disagree with you. When your integer is in the register, it will take one register, no matter what size it is. In case you have arrays of integers where memory bandwidth is important and you need to put as much as possible integers into a vector register, there is no reason to choose a 32-bit (if it is the case) integer such as int. For those reason, you need to use the smallest integer size that can handle your range of integers. The same thing applies for struct when you want to fit as much on a cacheline. – InsideLoop Feb 11 '18 at 20:26
  • @InsideLoop I'm not quite sure what you're disagreeing on. When you need as much integers as possible in the same amount of RAM, you pick the smallest integer that can do the job, which is most often int. (Of course sometimes you can do better with short, char, etc., but you hit diminishing returns.) – jick Feb 11 '18 at 21:14
  • @jick On need to have a real example to comment on that. But, when you have arrays of integer, you really want to use the smallest integer. Everybody agrees on that point. For instance, to store a 8-bit image, you use an array of std::uint8_t. In a struct, that you intend to use in an array, size also matters. Other than those cases, I don't see a single example when using int over std::ptrdiff_t offers a performance advantage. My point is that int is only used for historical reason and because its name is simple. But if we abstract the name, std::ptrdiff_t clearly wins. – InsideLoop Feb 11 '18 at 21:54
5

My advice to you is not to look at assembly language output too much, not to worry too much about exactly what size each variable is, and not to say things like "the compiler feels at home with". (I truly don't know what you mean by that last one.)

For garden-variety integers, the ones that most programs are full of, plain int is supposed to be a good type to use. It's supposed to be the natural word size of the machine. It's supposed to be efficient to use, neither wasting unnecessary memory nor inducing lots of extra conversions when moving between memory and computation registers.

Now, it's true that there are plenty of more specialized uses for which plain int is no longer appropriate. In particular, sizes of objects, counts of elements, and indices into arrays are almost always size_t. But that doesn't mean all integers should be size_t!

It's also true that mixtures of signed and unsigned types, and mixtures of different-size types, can cause problems. But most of those are well taken care of by modern compilers and the warnings they emit for unsafe combinations. So as long as you're using a modern compiler and paying attention to its warnings, you don't need to pick an unnatural type just to try to avoid type mismatch problems.

  • 1
    int was originally supposed to be the natural word size of the machine; however that is no longer true for most x64 impelementations – M.M Feb 11 '18 at 20:22
  • @M.M: I recall something about older 64 bit machines having sizeof(int) == 8 and int is still the natural machine integer size in x64 (read the disassembly; it prefers 32 bit registers). – Joshua Feb 11 '18 at 20:27
  • @M.M If the natural word size of a particular machine is 64 bits, then indeed int should arguably be 64 bits on that machine, and I have no objection to that -- but that's still not a reason not to use type int in code! But is 64 bits truly the "natural word size" of x86_64? I honestly don't know, although I get the impression that the 64 bits are much more for addresses, not so much for ordinary integral calculations. (But I could be wrong; as I say I don't know.) – Steve Summit Feb 12 '18 at 3:14
4

I don't think that there's real reason for using int.

How to choose the integer type?

  • If it is for bit operations, you can use an unsigned type, otherwise use a signed one
  • If it is for memory-related thing (index, container size, etc.), for which you don't know the upper bound, use std::ptrdiff_t (the only problem is when size is larger than PTRDIFF_MAX, which is rare in practice)
  • Otherwise use intXX_t or int(_least)/(_fast)XX_t.

These rules cover all the possible usages for int, and they give a better solution:

  • int is not good for storing memory related things, as its range can be smaller than an index can be (this is not a theoretical thing: for 64-bit machines, int is usually 32-bit, so with int, you can only handle 2 billion elements)
  • int is not good for storing "general" integers, as its range may be smaller than needed (undefined behavior happens if range is not enough), or on the contrary, its range may be much larger than needed (so memory is wasted)

The only reason one could use an int, if one does a calculation, and knows that the range fit into [-32767;32767] (the standard only guarantees this range. Note however, that implementations are free to provide bigger sized ints, and they usually do so. Currently int is 32-bit on a lot of platforms).

As the mentioned std types are a little bit tedious to write, one could typedef them to be shorter (I use s8/u8/.../s64/u64, and spt/upt ("(un)signed pointer sized type") for ptrdiff_t/size_t. I've been using these typedefs for 15 years, and I've never written a single int since...).

  • "standard only gaurentees ..." is not true. The standard says: There are five standard signed integer types : “signed char”, “short int”, “int”, “long int”, and “long long int”.In this list, each type provides at least as much storage as those preceding it in the list. – Robert Andrzejuk Feb 11 '18 at 16:09
  • And the constraints given in the C standard, subclause 5.2.4.2.1. says that "implementation-defined values shall be equal or greater in magnitude (absolute value) to those shown ..." – Robert Andrzejuk Feb 11 '18 at 16:17
  • @RobertAndrzejuk : The standard doesn't say int cannot hold 32768, but if one is writing maximally portable code, one must not assume that it can either. (I have given up writing code which will work with a 16-bit int though.) – Martin Bonner Feb 11 '18 at 16:25
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    Ptrdiff_t doesn't have ANY guaranteed minimum, so in that respect it is no better. – Martin Bonner Feb 11 '18 at 17:11
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    @RobertAndrzejuk: that's a different thing. I was talking about int. C++ standard: "The signed and unsigned integer types shall satisfy the constraints given in the C standard, subclause 5.2.4.2.1.". And if you look at the C standard, you'll find that INT_MIN/MAX should be at least -32767/32767. That's the guaranteed range of int. Of course, there are other types with other range requirements, but this question was about int. – geza Feb 11 '18 at 18:10
2

Pro

Easier to type, I guess? But you can always typedef.

Many APIs use int, including parts of the standard library. This has historically caused problems, for example during the transition to 64-bit file sizes.

Because of the default type promotion rules, types narrower than int could be widened to int or unsigned int unless you add explicit casts in a lot of places, and a lot of different types could be narrower than int on some implementation somewhere. So, if you care about portability, it’s a minor headache.

Con

I also use ptrdiff_t for indices, most of the time. (I agree with Google that unsigned indices are a bug attractor.) For other kinds of math, there’s int_fast64_t. int_fast32_t, and so on, which will also be as good as or better than int. Almost no real-world systems, with the exception of a few defunct Unices from last century, use ILP64, but there are plenty of CPUs where you would want 64-bit math. And a compiler is technically allowed, by standard, to break your program if your int is greater than 32,767.

That said, any C compiler worth its salt will be tested on a lot of code that adds an int to a pointer within an inner loop. So it can’t do anything too dumb. Worst-case scenario on present-day hardware is that it needs an extra instruction to sign-extend a 32-bit signed value to 64 bits. But, if what you really want is the fastest pointer math, the fastest math for values with magnitude between 32 kibi and 2 gibi, or the least wasted memoey, you should say what you mean, not make the compiler guess.

  • I'm skeptical about int_fast32_t etc. It seems to me different situations will involve different relative timings of the types. – M.M Feb 11 '18 at 20:22
  • @M.M The main one I can think of is that a smaller type would fit more elements into the cache, so you should use int_least32_t in some circumstances to get fewer cache misses. (Part of what I was getting at wit “least wasted memory.”) However, if one size does not fit all, int cannot fit all either and is no improvement. And you want to be able to specify, lowest size. – Davislor Feb 11 '18 at 20:23
  • Oh certainly, it's the fast variants I'm skeptical of. int_least32_t has a different purpose, namely to make the code portable to implementations that don't define a 32-bit type. – M.M Feb 11 '18 at 20:35
  • Still, int_fast32_t is the library programmers’ best guess what the fastest type usually is, while many compiler vendors are forced to keep int at 32 bits for compatibility. – Davislor Feb 11 '18 at 20:42
2

I guess 99% of cases there is no reason to use int(or signed integer of other sizes). However, there are still situations, when using int is a good option.


A) Performance:

One difference between int and size_t is that i++ can be undefined behavior for int - if i is MAX_INT. This actually might be a good thing because compiler could use this undefined behavior to speed things up.

For example in this question the difference was about factor 2 between exploiting the undefined behavior and using compiler flag -fwrapv which prohibits this exploit.

If my working-horse-for-loop becomes twice as fast by using ints - sure I will use it


B) Less error prone code

Reversed for-loops with size_t look strange and is a source for errors (I hope I got it right):

for(size_t i = N-1; i < N; i--){...}

By using

for(int i = N-1; i >= 0; i--){...}

you will deserve the gratitude of less experienced C++-programmers, who will have to manage your code some day.


C) Design using signed indices

By using int as indices you one could signal wrong values/out of range with negative values, something that comes handy and can lead to a clearer code.

  1. "find index of an element in array" could return -1 if element is not present. For detecting this "error" you don't have to know the size of the array.

  2. binary search could return positive index if element is in the array, and -index for the position where the element would be inserted into array (and is not in the array).

Clearly, the same information could be encoded with positive index-values, but the code becomes somewhat less intuitive.


Clearly, there are also reasons to choose int over std::ptrdiff_t - one of them is memory bandwidth. There are a lot of memory-bound algorithms, for them it is important to reduce the amount of memory transfered from RAM to cache.

If you know, that all numbers are less then 2^31 that would be an advantage to use int because otherwise a half of memory transfer would be writing only 0 of which you already know, that they are there.

An example are compressed sparse row (crs) matrices - their indices are stored as ints and not long long. Because many operations with sparse matrices are memory bound, there is really a different between using 32 or 64 bits.

  • I completely agree with all your points. Which is the reason why I favor std::ptrdiff_t over std::size_t. If we use std::ptrdiff_t, we get all the benefits of int and a wider range. – InsideLoop Feb 14 '18 at 6:21
  • @InsideLoop For memory bound operations there is a difference whether you have to tranfser 32bit or 64bit per element. So for this scenario int would be a better choice. – ead Feb 17 '18 at 19:17
  • I agree with you that when its memory bound or even compute bound and you can use vectorization, the smaller the better. But in this case, I don't think that int should be the right choice. I believe that in this case, you should use std::uint8_t, std::uint16_t or std::int32_t. – InsideLoop Feb 18 '18 at 18:23

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