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It's a simple-looking question:

Given that native-sized integers are the best for arithmetic, why doesn't C# (or any other .NET language) support arithmetic with the native-sized IntPtr and UIntPtr?

Ideally, you'd be able to write code like:

for (IntPtr i = 1; i < arr.Length; i += 2) //arr.Length should also return IntPtr
{
    arr[i - 1] += arr[i]; //something random like this
}

so that it would work on both 32-bit and 64-bit platforms. (Currently, you have to use long.)


Edit:

I'm not using these as pointers (the word "pointer" wasn't even mentioned)! They can be just treated as the C# counterpart of native int in MSIL and of intptr_t in C's stdint.h -- which are integers, not pointers.

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Re edit: they can? – BoltClock Apr 8 '11 at 2:56
    
@BoltClock: Yeah... what do you think is the .NET return type of a method that returns a native int? – Mehrdad Apr 8 '11 at 2:57
    
@Downvoter: Care to comment? – Mehrdad Apr 8 '11 at 21:09
up vote 6 down vote accepted

In .NET 4, arithmetic between a left hand operand of type IntPtr and a right hand operand of integer types (int, long, etc) is supported.

[Edit]: As other people have said, they are designed to represent pointers in native languages (as implied by the name IntPtr). It's fine to claim you're using them as native integers rather than pointers, but you can't overlook that one of the primary reasons the native size of an integer ever matters is for use as a pointer. If you're performing mathematical operations, or other general functions that are independent from the processor and memory architecture that your code is running on, it is arguably more useful and intuitive to use types such as int and long where you know their fixed size and upper and lower bounds in every situation regardless of hardware.

Just as the type IntPtr is designed to represent a native pointer, the arithmetic operations are designed to represent logical mathematical operations that you would perform on a pointer: adding some integer offset to a native pointer to reach a new native pointer (not that adding two IntPtrs is not supported, and nor is using IntPtr as the right hand operand).

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+1 I didn't know that!! =O But I meant completely using IntPtr, not throwing in another fixed-size integer into the mix. – Mehrdad Apr 8 '11 at 2:56
    
Updated with my thoughts on why using a fixed size integer is appropriate for the situation – jeffora Apr 8 '11 at 3:13
    
@jeffora: So you're basically saying there's no situation in which this would be useful, I understand; right? Though I'd find it hard to swallow, it seems like a very plausible explanation. :) – Mehrdad Apr 8 '11 at 3:16
1  
Correct me if I'm wrong, but size_t should represent an object's size, and its size is platform dependent. IntPtr is a natively sized integer type, but according to MSDN is "A platform-specific type that is used to represent a pointer or a handle." (msdn.microsoft.com/en-us/library/system.intptr.aspx), i.e. pointer or handle, not just any arbitrary platform sized int – jeffora Apr 8 '11 at 3:28
1  
Sure, you can use it as any arbitrary platform sized int, but possibly not expect it to support operations that don't make sense for the specific representations it is designed for. – jeffora Apr 8 '11 at 3:30

Maybe native-sized integers make for the fastest arithmetic, but they certainly don't make for the most error-free programs.

Personally I hate programming with integer types whose sizes I do not know when I sit down to start typing (I 'm looking at you, C++), and I definitely prefer the peace of mind the CLR types give you over the very doubtful and certainly conditional performance benefit that using CPU instructions tailored to the platform might offer.

Consider also that the JIT compiler can optimize for the architecture the process is running on, in contrast to a "regular" compiler which has to generate machine code without having access to this information. The JIT compiler might therefore generate code just as fast because it knows more.

I imagine I 'm not alone in thinking this, so it might count for a reason.

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Now that's a plausible explanation (as opposed to the response "pointers are unsafe!" which is completely irrelevant). :) So now my question to you is, how are you supposed to interoperate with a struct that has a size_t field in it, that holds, say, an index into some array? (And +1 for the C++ -bash...) – Mehrdad Apr 8 '11 at 3:05
    
@Mehrdad: First off, I added a third paragraph just now; give it a read as well. – Jon Apr 8 '11 at 3:07
    
I read your third paragraph right now, but it's not just an efficiency issue: it's a correctness issue for, for example, iterating over arrays that can have arbitrary sizes, in a platform-independent manner. – Mehrdad Apr 8 '11 at 3:10
    
@Mehrdad: About the size_t: I don't know much about interop internals. If you have to map size_t to a field of the same size then technically interop in the general case is impossible because the size is unknown; you can only interop against a specific binary wherein the size of size_t has been hardcoded by the compiler. If the marshalling is one-way only and the marshaller can store smaller types into larger ones, then you can marshal size_t into an unsigned long and be OK until we get 128-bit architectures. – Jon Apr 8 '11 at 3:15
    
Yeah exactly -- but then you'd die on 128-bit architectures. Isn't that the exact problem 32-bit code ran into when we migrated to 64-bit? – Mehrdad Apr 8 '11 at 3:22

I can actually think of one reason why an IntPtr (or UIntPtr) would be useful: accessing elements of an array requires native-sized integers. Though native integers are never exposed to the programmer, they are internally used in IL. Something like some_array[index] in C# will actually compile down to some_array[(int)checked((IntPtr)index)] in IL. I noticed this after disassembling my own code with ILSpy. (The index variable is 64-bit in my code.) To verify that the disassembler wasn't making a mistake, Microsoft's own ILDASM tool shows the existence of conv.u and conv.i instructions within my assembly. Those instructions convert integers to the system's native representation. I don't know what the performance implication is having all these conversion instructions in the IL code, but hopefully the JIT is smart enough to optimize the performance penalty away; if not, the next best thing is to allow manipulating native integers without conversions (which, in my opinion, might be the main motivation to use a native type).

Currently, the F# language allows the use of nativeint and and its unsigned counterpart for arithmetic. However, arrays can only be indexed by int in F# which means nativeint is not very useful for the purposes of indexing arrays.

If it really bothers you that much, write your own compiler that lifts restrictions on native integer use, create your own language, write your code in IL, or tweak the IL after compiling. Personally, I think it's a bad idea to squeeze out extra performance or save memory by using native int. If you wanted your code to fit the system like a glove, you'd best be using a lower level language with support for processor intrinsics.

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.Net Framework tries not to introduce operations that can't be explained. I.e. there is no DateTime + DateTime because there is no such concept as sum of 2 dates. The same reasoning applies to pointer types - there is no concept of sum of 2 pointers. The fact that IntPtr is stored as platform depenedent int value does not really matter - there are a lot of other types that internally stored as basic values (again DateTime can be represented as long).

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Contrary to what you mention, it's actually not "stored" as a platform-independent integer (it's stored as a void*), but it is a platform-independent integer because it's what native int maps to from MSIL. I'm not saying anything about the storage mechanism, only the semantics. – Mehrdad Apr 8 '11 at 4:19

Because that's not a "safe" way of handling memory addressing. Pointer arithmetic can lead to all sorts of bugs and memory addressing problems that C# is designed explicitly to avoid.

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What's unsafe about adding two intptr_t's in C? Same thing here... – Mehrdad Apr 8 '11 at 2:54
    
It's not the same thing. C is not .NET. .NET is a managed environment. A pointer is not a fixed value in a managed world. You have references that hold values used by the .NET framework to locate objects in memory. Their actual location may be moved at any time by the GC. That's why pointers are unsafe and playing with them is difficult. – Paul Alexander Apr 8 '11 at 2:58
    
@Paul: This has nothing to do with pointers! Do you happen to be familiar with MSIL's native int data type? It's completely distinct from void*... – Mehrdad Apr 8 '11 at 3:01
1  
Yes, I'm very familiar with the inner workings of the JIT and how it actually generates code. The IntPtr is a special type for holding pointers. You're trying to use it for something else. The IntPtr type is designed to provide a safe way for a managed environment to hold a pointer. It is not an arbitrary integer value. – Paul Alexander Apr 8 '11 at 3:05
    
@Paul: When a method returns a native int in IL, what's the data type of the return type that you see when you reflect over it? And what does native int have to do with pointers? – Mehrdad Apr 8 '11 at 3:13

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