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Who decides the sizeof any datatype or structure (depending on 32 bit or 64 bit)? The compiler or the processor? For example, sizeof(int) is 4 bytes for a 32 bit system whereas it's 8 bytes for a 64 bit system.

I also read that sizeof(int) is 4 bytes when compiled using both 32-bit and 64-bit compiler.

Suppose my CPU can run both 32-bit as well as 64-bit applications, who will play main role in deciding size of data the compiler or the processor?

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    The processor executes machine code, it doesn't decide anything – StoryTeller - Unslander Monica Feb 22 '18 at 6:42
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    "Suppose my CPU can run both 32-bit as well as 64-bit applications, who will play main role in deciding size of data the compiler or the processor?" It doesn't matter how many bits your CPU does or doesn't support. Once the application is compiled, the size 'baked into the binary files of the application' so-to-speak. If your processor cannot handle the binary, the application cannot run. – Disillusioned Feb 22 '18 at 6:47
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    Also note the int doesn't really need to concern itself much with processor architecture. 32-bit int works fine using half of the available bits in a 64-bit register. Similarly 64-bit int can be fairly easily emulated on 32-bit CPUs. The one thing that isn't so flexible however, is the size of a pointer. And even then, the OS can allow 32-bit apps to run on 64-bit CPU NB: Note that the size of a pointer is not necessarily the same as the size of int. – Disillusioned Feb 22 '18 at 6:52
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    @Neijwiert, what happens is that when 64 bit Windows sees a 32 bit binary, it starts WoW64, which is essentially all the system Windows DLLs, but in 32 bit versions. So a 64 bit install of Windows has two versions of most everything. The same goes for many 64 bit Linux systems, and I guess, Macs. – Prof. Falken supports Monica Feb 22 '18 at 6:54
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    Also see unix and linux data model ilp32 lp64. The UNIX System -- 64bit and Data Size Neutrality is very good reading. – jww Feb 22 '18 at 7:07
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It's ultimately the compiler. The compiler implementors can decide to emulate whatever integer size they see fit, regardless of what the CPU handles the most efficiently. That said, the C (and C++) standard is written such, that the compiler implementor is free to choose the fastest and most efficient way. For many compilers, the implementers chose to keep int as a 32 bit, although the CPU natively handles 64 bit ints very efficiently.

I think this was done in part to increase portability towards programs written when 32 bit machines were the most common and who expected an int to be 32 bits and no longer. (It could also be, as user user3386109 points out, that 32 bit data was preferred because it takes less space and therefore can be accessed faster.)

So if you want to make sure you get 64 bit ints, you use int64_t instead of int to declare your variable. If you know your value will fit inside of 32 bits or you don't care about size, you use int to let the compiler pick the most efficient representation.

As for the other datatypes such as struct, they are composed from the base types such as int.

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    @Justin, addressed in the part about how the compiler has a lot of lee-way to chose whatever sizes gives the fastest or most efficient results. – Prof. Falken supports Monica Feb 22 '18 at 6:49
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    Or 32-bits are used to save memory and improve cache performance. It doesn't take many 64-bit ints to fill up a cache line. – user3386109 Feb 22 '18 at 7:01
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    int64_t is not required to exist. long long is required, and it is always at least 64 bits wide; when the hardware doesn't support it directly the compiler will generate appropriate code. – Pete Becker Feb 22 '18 at 14:21
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    @CortAmmon -- long long is required by the language definition to be at least 64 bits wide. It's a bit hard to find, because it's in the library section. It comes from the C standard, which requires that LLONG_MIN must be no greater than -(2^63-1) and that LLONG_MAX must be no less than 2^63-1. – Pete Becker Feb 22 '18 at 18:48
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    With a 16-bit int "If you know your value will fit inside of 32 bits or you don't care about size, you use int to let the compiler pick the most efficient representation." is bad advice. 100s of million of embedded processors each year in 2016 use 16-bit int. Although a program for Linux does not need to worry about that given the OS push for 32_bit int or wider. – chux - Reinstate Monica Feb 22 '18 at 19:03
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It's not the CPU, nor the compiler, nor the operating system. It's all three at the same time.

The compiler can't just make things up. It has to adhere to the right ABI[1] that that the operating system provides. If structs and system calls provided by the operating system have types with certain sizes and alignment requirements the compiler isn't really free to make up its own reality unless the compiler developers want to reimplement wrapper functions for everything the operating system provides. Then the ABI of the operating system can't just be completely made up, it has to do what can be reasonably done on the CPU. And very often the ABI of one operating system will be very similar to other ABIs for other operating systems on the same CPU because it's easier to just be able to reuse the work they did (on compilers among other things).

In case of computers that support both 32 bit and 64 bit code there still needs to be work done by the operating system to support running programs in both modes (because the system has to provide two different ABIs). Some operating systems don't do it and on those you don't have a choice.

[1] ABI stands for Application Binary Interface. It's a set of rules for how a program interacts with the operating system. It defines how a program is stored on disk to be runnable by the operating system, how to do system calls, how to link with libraries, etc. But for being able to link to libraries for example, your program and the library have to agree on how to make function calls between your program an the library (and vice versa) and to be able to make function calls both the program and the library have to have the same idea of stack layout, register usage, function call conventions, etc. And for function calls you need to agree on what the parameters mean and that includes sizes, alignment and signedness of types.

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    ABI contains also calling conventions, that is a set of rules of how the program calls functions. It also contains constraints dictated by the processor (e.g. alignment constraints for various primitive data types) – Basile Starynkevitch Feb 22 '18 at 8:43
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    There is no requirement that a compiler support any means by which a program can interact with anything in the outside world without going through library functions that are bundled with the compiler. Nothing would forbid an implementation targeting x64 from using a 36-bit ones'-complement integer type (performing whatever shifts and masking operations would be needed to emulate that). Such an implementation could be genuinely useful if someone had some Univac code they wanted to run but they didn't have a working 36-bit system. – supercat Feb 22 '18 at 23:52
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    Upvoted because it gives the "very grounded in practical reality" angle. – Prof. Falken supports Monica Feb 23 '18 at 8:17
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    @MartinBonner Well, using that argument it's not the compiler, it's you. Because you have the choice of compilers. Except, maybe there's no free will, then it is the universe the chooses. The big bang set up the parameters that led you to choosing a compiler which was written by people whose parameters made them choose certain sizes for types. On the other hand, in reality where I live we have compilers that interact with their environment in useful ways and people don't waste their time building useless compilers but some still waste their time arguing that it could be done. – Art Feb 23 '18 at 10:18
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    @WillCrawford There is a lot of x64 compilers for Windows that use some made-up ABI which is completely different from the Windows x64 calling convention. Because they decided to bring in the whole package of Linux ABI, and did exactly just that. – Joker_vD Feb 23 '18 at 14:22
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It is strictly, 100%, entirely the compiler that decides the value of sizeof(int). It is not a combination of the system and the compiler. It is just the compiler (and the C/C++ language specifications).

If you develop iPad or iPhone apps you do the compiler runs on your Mac. The Mac and the iPhone/iPac use different processors. Nothing about your Mac tells the compiler what size should be used for int on the iPad.

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    If you meant to oppose Art's answer, then you're overdoing it. I suppose his answer referred to the target system, not the host on which the cross-compiler runs, while you're talking about host system, which, of course, is irrelevant to sizes of data types on the target. – Ruslan Feb 23 '18 at 10:14
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    This simply isn't true. At least you admit to the "language specifications", but every system has a standard (ABI) for what size the default "int" is, how parameters are passed to functions, etc... e.g. for iOS apps, this Apple developer guide spells it out: – Will Crawford Feb 23 '18 at 10:45
  • (quote) When different pieces of code must work together, they must follow standard agreed-upon conventions about how code should act. Conventions include the size and format of common data types, as well as the instructions used when one piece of code calls another. Compilers are implemented based on these conventions so that they can emit binary code that works together. Collectively, these conventions are referred to as an application binary interface (ABI). – Will Crawford Feb 23 '18 at 10:45
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    Again, the compiler decides whether to follow that convention. And "ABI" is merely a buzzword acronym. Decades ago, we referred to that as a "calling convention." These calling conventions dictate nothing to the compiler. The compiler should follow them but this is not always the case. Witness the C versus Pascal calling conventions windoze developers had to deal with. – user3344003 Feb 23 '18 at 14:04
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    Note: They changed their COMPILERS. It was a choice, not a requirement imposed by the system. – user3344003 Feb 23 '18 at 17:03
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The processor designer determines what registers and instructions are available, what the alignment rules for efficient access are, how big memory addresses are and so-on.

The C standard sets minimum requirements for the built-in types. "char" must be at least 8 bit, "short" and "int" must be at least 16 bit, "long" must be at least 32 bit and "long long" must be at least 64 bit. It also says that "char" must be equivilent to the smallest unit of memory the program can address and that the size ordering of the standard types must be maintained.

Other standards may also have an impact. For example version 2 of the "single Unix specification" says that int must be at least 32-bits.

Finally existing code has an impact. Porting is hard enough already, noone wants to make it any harder than they have to.


When porting an OS and compiler to a new CPU someone has to define what is known of as a "C ABI". This defines how binary code talks to each other including.

  • The size and alignment requirements of the built-in types.
  • The packing rules for structures (and hence what their size will be).
  • How parameters are passed and returned
  • How the stack is managed

In general once and ABI is defined for a combination of CPU family and OS it doesn't change much (sometimes the size of more obscure types like "long double" changes). Changing it brings a bunch of breakage for relatively little gain.

Similarly those porting an OS to a platform with similar characteristics to an existing one will usually choose the same sizes as on previous platforms that the OS was ported to.


In practice OS/compiler vendors typically settle on one of a few combinations of sizes for the basic integer types.

  • "LP32": char is 8 bits. short and int are 16 bits, long and pointer are 32-bits. Commonly used on 8 bit and 16 bit platforms.
  • "ILP32": char is 8 bits, short is 16 bits. int, long and pointer are all 32 bits. If long long exists it is 64 bit. Commonly used on 32 bit platforms.
  • "LLP64": char is 8 bits. short is 16 bits. int and long are 32 bits. long long and pointer are 64 bits. Used on 64 bit windows.
  • "LP64": char is 8 bits. short is 16 bits. int is 32 bits. long, long long and pointer are 64 bits. Used on most 64-bit unix-like systems.
  • "ILP64": char is 8 bits, short is 16 bits, int, long and pointer and long long are all 64 bits. Apparently used on some early 64-bit operating systems but rarely seen nowadays.

64 bit processors can typically run both 32-bit and 64-bit binaries. Generally this is handled by having a compatibility layer in your OS. So your 32-bit binary uses the same data types it would use when running on a 32-bit system, then the compatibility layer translates the system calls so that the 64-bit OS can handle them.

3

The compiler decides how large the basic types are, and what the layout of structures is. If a library declares any types, it will decide how those are defined and therefore what size they are.

However, it is often the case that compatibility with an existing standard, and the need to link to existing libraries produced by other compilers, forces a given implementation to make certain choices. For example, the language standard says that a wchar_t has to be wider than 16 bits, and on Linux, it is 32 bits wide, but it’s always been 16 bits on Windows, so compilers for Windows all choose to be compatible with the Windows API instead of the language standard. A lot of legacy code for both Linux and Windows assumes that a long is exactly 32 bits wide, while other code assumed it was wide enough to hold a timestamp in seconds or an IPv4 address or a file offset or the bits of a pointer, and (after one compiler defined int as 64 bits wide and long as 32 bits wide) the language standard made a new rule that int cannot be wider than long.

As a result, mainstream compilers from this century choose to define int as 32 bits wide, but historically some have defined it as 16 bits, 18 bits, 32 bits, 64 bits and other sizes. Some compilers let you choose whether long will be exactly 32 bits wide, as some legacy code assumes, or as wide as a pointer, as other legacy code assumes.

This demonstrates how assumptions you make today, like some type always being 32 bits wide, might come back to bite you in the future. This has already happened to C codebases twice, in the transitions to 32-bit and 64-bit code.

But what should you actually use?

The int type is rarely useful these days. There’s usually some other type you can use that makes a stronger guarantee of what you’ll get. (It does have one advantage: types that aren’t as wide as an int could get automatically widened to int, which could cause a few really weird bugs when you mix signed and unsigned types, and int is the smallest type guaranteed not to be shorter than int.)

If you’re using a particular API, you’ll generally want to use the same type it does. There are numerous types in the standard library for specific purposes, such as clock_t for clock ticks and time_t for time in seconds.

If you want the fastest type that’s at least 16 bits wide, that’s int_fast16_t, and there are other similar types. (Unless otherwise specified, all these types are defined in <stdint.h>.) If you want the smallest type that’s at least 32 bits wide, to pack the most data into your arrays, that’s int_least32_t. If you want the widest possible type, that’s intmax_t. If you know you want exactly 32 bits, and your compiler has a type like that, it’s int32_t If you want something that’s 32 bits wide on a 32-bit machine and 64 bits wide on a 64-bit machine, and always the right size to store a pointer, that’s intptr_t. If you want a good type for doing array indexing and pointer math, that’s ptrdiff_t from <stddef.h>. (This one’s in a different header because it’s from C89, not C99.)

Use the type you really mean!

  • "the language standard says that a wchar_t has to be wider than 16 bits" -- chapter and verse? I'm pretty sure it doesn't say that, in any version, at least not explicitly. The ambiguity in the standard about how wide it was really supposed to be is why char16_t and char32_t were introduced. – Jeroen Mostert Feb 22 '18 at 12:34
  • The standard doesn't say that wchar_t has to be wider than 8 bits, nor does it specify what character set is used (a system could in principle use 16 bit wchar for a locale-specific East Asian codepage, for example, or only support the BMP), but it's pretty clear that using variable length or stateful encodings isn't acceptable. – Random832 Feb 22 '18 at 16:25
  • @Random832 The standard says that wchar_t is “an integer type whose range of values can represent distinct codes for all members of the largest extended character set specified among the supported locales.” You are correct in the sense that a given implementation does not have to provide any locale that supports Unicode—or even ASCII. However, the standard does require support for UTF-8, UTF-16 and UCS-32 strings and a char32_t type. If you want to be compatible with Microsoft’s locales: setlocale(".1200"); alone requires support for all of Unicode. And the Windows API requires UTF-16. – Davislor Feb 22 '18 at 20:40
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    @Random832 So, any mainstream implementation has to support at least one Unicode locale to even be compatible with the OS, and being able to compile apps that work with Unicode is a de facto requirement in 2018. In theory, that would mean wchar_t on a Windows compiler has to be wide enough to store at least 1,112,064 distinct values, and therefore must be at least 21 bits wide. In practice, Microsoft defined wchar_t as 16 bits wide in the last century, changed it from UCS-2 to UTF-16, and refuses to break everything. So everyone who uses the Windows API does too. – Davislor Feb 22 '18 at 20:51
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    @WillCrawford Even before the latest edit, I did give the example of wchar_t as a type defined for compatibility with the API. (Technically, if the ABI were what mattered, it could just have made programmers use char16_t* and still be able to link with other libraries, and redefined wchar_t as char32_t.) But I hope there’s no ambiguity now. – Davislor Feb 23 '18 at 12:26
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When you talk about the compiler, you mush have a clean image about build|host|target, i.e, the machine you are building on (build), the machine that you are building for (host), and the machine that GCC will produce code for (target), because for "cross compiling" is very different from "native compiling".

About the question "who decide the sizeof datatype and structure", it depends on the target system you told compiler to build binary for. If target is 64 bits, the compiler will translate sizeof(long) to 8, and if the target is a 32 bits machine, the compiler will translate sizeof(long) to 4. All these have been predefined by header file you used to build your program. If you read your `$MAKETOP/usr/include/stdint.h', there are typedefs to define the size of your datatype.

To avoid the error created by the size difference, Google coding style-Integer_Types recommend using types like int16_t, uint32_t, int64_t, etc. Those were defined in <stdint.h>.

Above is only those `Plain Old Data', such as int. If you talk about a structure, there is another story, because the size of a structure depends on packing alignment, the boundaries alignment for each field in the structure, which will have impact on the size of the structure.

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It's the compiler, and more precisely its code generator component.

Of course, the compiler is architecture-aware and makes choices that fit with it.

In some cases, the work is performed in two passes, one at compile-time by an intermediate code generators, then a second at run-time by a just-in-time compiler. But this is still a compiler.

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