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You usually want to use NSInteger when you don't know what kind of processor architecture your code might run on, so you may for some reason want the largest possible int type, which on 32 bit systems is just an int, while on a 64-bit system it's a long. I'd stick with using NSInteger instead of int/long unless you specifically require them. ...


Updated answer: With current Xcode, you can make use of the z and t modifiers to handle NSInteger and NSUInteger without warnings, on all architectures. You want to use %zd for signed, %tu for unsigned, and %tx for hex. This information comes courtesy of Greg Parker. Original answer: The official recommended approach is to use %ld as your specifier, ...


Ta da: NSInteger myInteger = 42; int myInt = (int) myInteger; NSInteger is nothing more than a 32/64 bit int. (it will use the appropriate size based on what OS/platform you're running)


If the string is a human readable representation of a number, you can do this: NSInteger myInt = [myString intValue];


You can use this: NSArray* numbers = //array of numbers NSNumber* sum = [numbers valueForKeyPath: @"@sum.self"];


NSInteger is a primitive type, which means it can be stored locally on the stack. You don't need to use a pointer to access it, but you can if you want to. The line: NSInteger *processID = [[NSProcessInfo processInfo] processIdentifier]; returns an actual variable, not its address. To fix this, you need to remove the *: NSInteger processID = ...


The maximum value of an NSInteger is NSIntegerMax.


You cannot cast it because NSInteger is not an object, just an alias for a built-in type. You can always create a new NSNumber object from NSInteger, of course: NSNumber *myNum = [NSNumber numberWithInteger:myNsIntValue]; EDIT : replaced numberWithInt: with numberWithInteger:


[myString intValue] returns a cType "int" [myString integerValue] returns a NSInteger. In most cases I do find these simple functions by looking at apples class references, quickest way to get there is click [option] button and double-click on the class declarations (in this case NSString ).


For an int index: NSIndexPath *path = [NSIndexPath indexPathWithIndex:index]; Creates Index of the item in node 0 to point to as per the reference. To use the indexPath in a UITableView, the more appropriate method is NSIndexPath *path = [NSIndexPath indexPathForRow:row inSection:section];


NSNumber is a class, not a primitive, and is used when you need to put raw numbers into dictionaries, arrays, or otherwise encapsulate them. NSInteger, NSUInteger, CGFloat, etc are simple types and correspond (on 32-bt systems like the iPhone) to int, unsigned int and float. As a general rule, if you need to store a number somewhere, use NSNumber. If you're ...


The existing answers are useful; adding to them: Yes, NSUInteger gives twice the range among positive integers as NSInteger, but I think another critical reason to choose between the two is simply to distinguish among cases where negative values simply do not make sense. Example: the return value of NSArray's count method is an NSUInteger, which makes ...


Why use int at all? Apple uses int because for a loop control variable (which is only used to control the loop iterations) int datatype is fine, both in datatype size and in the values it can hold for your loop. No need for platform dependent datatype here. For a loop control variable even a 16-bit int will do most of the time. Apple uses NSInteger for a ...


There is now this starting Xcode 4.5: typedef NS_ENUM(NSUInteger, NSCellType) { NSNullCellType = 0, NSTextCellType = 1, NSImageCellType = 2 };


Use modulo: int lastDigit = time % 10;


From http://pubs.opengroup.org/onlinepubs/009695399/functions/printf.html: z Specifies that a following [...] conversion specifier applies to a size_t or the corresponding signed integer type argument; t Specifies that a following [...] conversion specifier applies to a ptrdiff_t or the corresponding unsigned type argument; And from ...


If you want to do this inline, just cast the NSUInteger or NSInteger to an int: int i = -1; NSUInteger row = 100; i > row // true, since the signed int is implicitly converted to an unsigned int i > (int)row // false


An improved answer On 64-bit systems NSInteger is long. On 32-bit systems NSInteger is int. https://developer.apple.com/library/mac/documentation/Cocoa/Conceptual/Cocoa64BitGuide/64BitChangesCocoa/64BitChangesCocoa.html All you need just cast your int to NSInteger. int i = 1; NSInteger nsi = (NSInteger) i; You can also cast NSInteger to int (as in an ...


In such cases you might right click and go to definition: #if __LP64__ || (TARGET_OS_EMBEDDED && !TARGET_OS_IPHONE) || TARGET_OS_WIN32 || NS_BUILD_32_LIKE_64 typedef long NSInteger; typedef unsigned long NSUInteger; #else typedef int NSInteger; typedef unsigned int NSUInteger; #endif


NSInteger and NSUInteger are just typedefs for primitive integer types: #if __LP64__ || NS_BUILD_32_LIKE_64 typedef long NSInteger; typedef unsigned long NSUInteger; #else typedef int NSInteger; typedef unsigned int NSUInteger; #endif As such, you don't need to "convert" between them. A simple cast should be sufficient. Like: NSInteger myInt = ...


If you're just trying to call the method, you could use the standard syntax: [self meth2:next_int]; If you really need to use the performSelectorOnMainThread: you could wrap the number in an NSNumber for the call. You say you can't do this because you need to change the number, but you can just pull an int out and change that: [self ...


The reason that you don't declare NSInteger with a * is because it isn't an object. An NSInteger is simply an int or a long: #if __LP64__ typedef long NSInteger; #else typedef int NSInteger; endif If it's being used in a 32-bit application, it's a 32-bit integer, and if it's being built in a 64-bit application, it's a 64-bit integer. Of course, you can ...


If you dig into NSInteger's implementation: #if __LP64__ typedef long NSInteger; #else typedef int NSInteger; #endif Simply, the NSInteger typedef does a step for you: if the architecture is 32-bit, it uses int, if it is 64-bit, it uses long. Using NSInteger, you don't need to worry about the architecture that the program is running on.


You can use NSExpression for this: NSExpression *expression = [NSExpression expressionWithFormat:@"1+2"]; NSLog(@"%@", [expression expressionValueWithObject:nil context:nil]); For further information read the documentation of the used methods.


if (x >= 0) { // do positive stuff } else { // do negative stuff } If you want to treat the x == 0 case separately (since 0 is neither positive nor negative), then you can do it like this: if (x > 0) { // do positive stuff } else if (x == 0) { // do zero stuff } else { // do negative stuff }


OS X is "LP64". This means that: int is always 32-bits. long long is always 64-bits. NSInteger and long are always pointer-sized. That means they're 32-bits on 32-bit systems, and 64 bits on 64-bit systems. The reason NSInteger exists is because many legacy APIs incorrectly used int instead of long to hold pointer-sized variables, which meant that ...


Can we use int and NSInteger interchangably? No. On the LP64 architecture used by Apple, for modern OS X Cocoa, NSInteger is 64 bits wide. This means that if you cast an NSInteger to an int, comparisons against NSNotFound may fail. Here's an example: NSRange theRange = [@"foo" rangeOfString @"x"]; int location = theRange.location; if (location == ...


A string and an integer are fundamentally different data types, and casting in Objective-C won't do a conversion for you in this case, it'll just lie to the compiler about what's happening (so it compiles) but at runtime it blows up. You can embed an integer directly into a format string by using %d instead of %@: tempString = [NSString ...


So if I've understood correctly, setText: takes an NSString and you have an NSInteger? If that's correct you can explicitly convert them as follows: [self.abilitygeneration setText:[NSString stringWithFormat:@"%d",((TestAbility *)[self.testabilities objectAtIndex:0]).abilitygeneration]];


The point is to abstract types and their associates sized from the hardware in a manner that we don't have to worry what size an int is now how big a pointer is on any particular hardware. "C" is bad at this, only stating that a long is at lease as big as an int, that an int is the "natural" integer size of the hardware (whatever that means), that an int is ...

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