Clang 4 documentation

Objective-C Literals

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Objective-C Literals


Three new features were introduced into clang at the same time: NSNumber Literals provide a syntax for creating NSNumber from scalar literal expressions; Collection Literals provide a short-hand for creating arrays and dictionaries; Object Subscripting provides a way to use subscripting with Objective-C objects. Users of Apple compiler releases can use these features starting with the Apple LLVM Compiler 4.0. Users of open-source compiler releases can use these features starting with clang v3.1.

These language additions simplify common Objective-C programming patterns, make programs more concise, and improve the safety of container creation.

This document describes how the features are implemented in clang, and how to use them in your own programs.

NSNumber Literals

The framework class NSNumber is used to wrap scalar values inside objects: signed and unsigned integers (char, short, int, long, long long), floating point numbers (float, double), and boolean values (BOOL, C++ bool). Scalar values wrapped in objects are also known as boxed values.

In Objective-C, any character, numeric or boolean literal prefixed with the '@' character will evaluate to a pointer to an NSNumber object initialized with that value. C’s type suffixes may be used to control the size of numeric literals.


The following program illustrates the rules for NSNumber literals:

void main(int argc, const char *argv[]) {
  // character literals.
  NSNumber *theLetterZ = @'Z';          // equivalent to [NSNumber numberWithChar:'Z']

  // integral literals.
  NSNumber *fortyTwo = @42;             // equivalent to [NSNumber numberWithInt:42]
  NSNumber *fortyTwoUnsigned = @42U;    // equivalent to [NSNumber numberWithUnsignedInt:42U]
  NSNumber *fortyTwoLong = @42L;        // equivalent to [NSNumber numberWithLong:42L]
  NSNumber *fortyTwoLongLong = @42LL;   // equivalent to [NSNumber numberWithLongLong:42LL]

  // floating point literals.
  NSNumber *piFloat = @3.141592654F;    // equivalent to [NSNumber numberWithFloat:3.141592654F]
  NSNumber *piDouble = @3.1415926535;   // equivalent to [NSNumber numberWithDouble:3.1415926535]

  // BOOL literals.
  NSNumber *yesNumber = @YES;           // equivalent to [NSNumber numberWithBool:YES]
  NSNumber *noNumber = @NO;             // equivalent to [NSNumber numberWithBool:NO]

#ifdef __cplusplus
  NSNumber *trueNumber = @true;         // equivalent to [NSNumber numberWithBool:(BOOL)true]
  NSNumber *falseNumber = @false;       // equivalent to [NSNumber numberWithBool:(BOOL)false]


NSNumber literals only support literal scalar values after the '@'. Consequently, @INT_MAX works, but @INT_MIN does not, because they are defined like this:

#define INT_MAX   2147483647  /* max value for an int */
#define INT_MIN   (-2147483647-1) /* min value for an int */

The definition of INT_MIN is not a simple literal, but a parenthesized expression. Parenthesized expressions are supported using the boxed expression syntax, which is described in the next section.

Because NSNumber does not currently support wrapping long double values, the use of a long double NSNumber literal (e.g. @123.23L) will be rejected by the compiler.

Previously, the BOOL type was simply a typedef for signed char, and YES and NO were macros that expand to (BOOL)1 and (BOOL)0 respectively. To support @YES and @NO expressions, these macros are now defined using new language keywords in <objc/objc.h>:

#if __has_feature(objc_bool)
#define YES             __objc_yes
#define NO              __objc_no
#define YES             ((BOOL)1)
#define NO              ((BOOL)0)

The compiler implicitly converts __objc_yes and __objc_no to (BOOL)1 and (BOOL)0. The keywords are used to disambiguate BOOL and integer literals.

Objective-C++ also supports @true and @false expressions, which are equivalent to @YES and @NO.

Boxed Expressions

Objective-C provides a new syntax for boxing C expressions:

@( <expression> )

Expressions of scalar (numeric, enumerated, BOOL), C string pointer and some C structures (via NSValue) are supported:

// numbers.
NSNumber *smallestInt = @(-INT_MAX - 1);  // [NSNumber numberWithInt:(-INT_MAX - 1)]
NSNumber *piOverTwo = @(M_PI / 2);        // [NSNumber numberWithDouble:(M_PI / 2)]

// enumerated types.
typedef enum { Red, Green, Blue } Color;
NSNumber *favoriteColor = @(Green);       // [NSNumber numberWithInt:((int)Green)]

// strings.
NSString *path = @(getenv("PATH"));       // [NSString stringWithUTF8String:(getenv("PATH"))]
NSArray *pathComponents = [path componentsSeparatedByString:@":"];

// structs.
NSValue *center = @(;         // Point p =;
                                          // [NSValue valueWithBytes:&p objCType:@encode(Point)];
NSValue *frame = @(view.frame);           // Rect r = view.frame;
                                          // [NSValue valueWithBytes:&r objCType:@encode(Rect)];

Boxed Enums

Cocoa frameworks frequently define constant values using enums. Although enum values are integral, they may not be used directly as boxed literals (this avoids conflicts with future '@'-prefixed Objective-C keywords). Instead, an enum value must be placed inside a boxed expression. The following example demonstrates configuring an AVAudioRecorder using a dictionary that contains a boxed enumeration value:

enum {
  AVAudioQualityMin = 0,
  AVAudioQualityLow = 0x20,
  AVAudioQualityMedium = 0x40,
  AVAudioQualityHigh = 0x60,
  AVAudioQualityMax = 0x7F

- (AVAudioRecorder *)recordToFile:(NSURL *)fileURL {
  NSDictionary *settings = @{ AVEncoderAudioQualityKey : @(AVAudioQualityMax) };
  return [[AVAudioRecorder alloc] initWithURL:fileURL settings:settings error:NULL];

The expression @(AVAudioQualityMax) converts AVAudioQualityMax to an integer type, and boxes the value accordingly. If the enum has a fixed underlying type as in:

typedef enum : unsigned char { Red, Green, Blue } Color;
NSNumber *red = @(Red), *green = @(Green), *blue = @(Blue); // => [NSNumber numberWithUnsignedChar:]

then the fixed underlying type will be used to select the correct NSNumber creation method.

Boxing a value of enum type will result in a NSNumber pointer with a creation method according to the underlying type of the enum, which can be a fixed underlying type or a compiler-defined integer type capable of representing the values of all the members of the enumeration:

typedef enum : unsigned char { Red, Green, Blue } Color;
Color col = Red;
NSNumber *nsCol = @(col); // => [NSNumber numberWithUnsignedChar:]

Boxed C Strings

A C string literal prefixed by the '@' token denotes an NSString literal in the same way a numeric literal prefixed by the '@' token denotes an NSNumber literal. When the type of the parenthesized expression is (char *) or (const char *), the result of the boxed expression is a pointer to an NSString object containing equivalent character data, which is assumed to be ‘\0’-terminated and UTF-8 encoded. The following example converts C-style command line arguments into NSString objects.

// Partition command line arguments into positional and option arguments.
NSMutableArray *args = [NSMutableArray new];
NSMutableDictionary *options = [NSMutableDictionary new];
while (--argc) {
    const char *arg = *++argv;
    if (strncmp(arg, "--", 2) == 0) {
        options[@(arg + 2)] = @(*++argv);   // --key value
    } else {
        [args addObject:@(arg)];            // positional argument

As with all C pointers, character pointer expressions can involve arbitrary pointer arithmetic, therefore programmers must ensure that the character data is valid. Passing NULL as the character pointer will raise an exception at runtime. When possible, the compiler will reject NULL character pointers used in boxed expressions.

Boxed C Structures

Boxed expressions support construction of NSValue objects. It said that C structures can be used, the only requirement is: structure should be marked with objc_boxable attribute. To support older version of frameworks and/or third-party libraries you may need to add the attribute via typedef.

struct __attribute__((objc_boxable)) Point {
    // ...

typedef struct __attribute__((objc_boxable)) _Size {
    // ...
} Size;

typedef struct _Rect {
    // ...
} Rect;

struct Point p;
NSValue *point = @(p);          // ok
Size s;
NSValue *size = @(s);           // ok

Rect r;
NSValue *bad_rect = @(r);       // error

typedef struct __attribute__((objc_boxable)) _Rect Rect;

NSValue *good_rect = @(r);      // ok

Container Literals

Objective-C now supports a new expression syntax for creating immutable array and dictionary container objects.


Immutable array expression:

NSArray *array = @[ @"Hello", NSApp, [NSNumber numberWithInt:42] ];

This creates an NSArray with 3 elements. The comma-separated sub-expressions of an array literal can be any Objective-C object pointer typed expression.

Immutable dictionary expression:

NSDictionary *dictionary = @{
    @"name" : NSUserName(),
    @"date" : [NSDate date],
    @"processInfo" : [NSProcessInfo processInfo]

This creates an NSDictionary with 3 key/value pairs. Value sub-expressions of a dictionary literal must be Objective-C object pointer typed, as in array literals. Key sub-expressions must be of an Objective-C object pointer type that implements the <NSCopying> protocol.


Neither keys nor values can have the value nil in containers. If the compiler can prove that a key or value is nil at compile time, then a warning will be emitted. Otherwise, a runtime error will occur.

Using array and dictionary literals is safer than the variadic creation forms commonly in use today. Array literal expressions expand to calls to +[NSArray arrayWithObjects:count:], which validates that all objects are non-nil. The variadic form, +[NSArray arrayWithObjects:] uses nil as an argument list terminator, which can lead to malformed array objects. Dictionary literals are similarly created with +[NSDictionary dictionaryWithObjects:forKeys:count:] which validates all objects and keys, unlike +[NSDictionary dictionaryWithObjectsAndKeys:] which also uses a nil parameter as an argument list terminator.

Object Subscripting

Objective-C object pointer values can now be used with C’s subscripting operator.


The following code demonstrates the use of object subscripting syntax with NSMutableArray and NSMutableDictionary objects:

NSMutableArray *array = ...;
NSUInteger idx = ...;
id newObject = ...;
id oldObject = array[idx];
array[idx] = newObject;         // replace oldObject with newObject

NSMutableDictionary *dictionary = ...;
NSString *key = ...;
oldObject = dictionary[key];
dictionary[key] = newObject;    // replace oldObject with newObject

The next section explains how subscripting expressions map to accessor methods.

Subscripting Methods

Objective-C supports two kinds of subscript expressions: array-style subscript expressions use integer typed subscripts; dictionary-style subscript expressions use Objective-C object pointer typed subscripts. Each type of subscript expression is mapped to a message send using a predefined selector. The advantage of this design is flexibility: class designers are free to introduce subscripting by declaring methods or by adopting protocols. Moreover, because the method names are selected by the type of the subscript, an object can be subscripted using both array and dictionary styles.

Array-Style Subscripting

When the subscript operand has an integral type, the expression is rewritten to use one of two different selectors, depending on whether the element is being read or written. When an expression reads an element using an integral index, as in the following example:

NSUInteger idx = ...;
id value = object[idx];

it is translated into a call to objectAtIndexedSubscript:

id value = [object objectAtIndexedSubscript:idx];

When an expression writes an element using an integral index:

object[idx] = newValue;

it is translated to a call to setObject:atIndexedSubscript:

[object setObject:newValue atIndexedSubscript:idx];

These message sends are then type-checked and performed just like explicit message sends. The method used for objectAtIndexedSubscript: must be declared with an argument of integral type and a return value of some Objective-C object pointer type. The method used for setObject:atIndexedSubscript: must be declared with its first argument having some Objective-C pointer type and its second argument having integral type.

The meaning of indexes is left up to the declaring class. The compiler will coerce the index to the appropriate argument type of the method it uses for type-checking. For an instance of NSArray, reading an element using an index outside the range [0, array.count) will raise an exception. For an instance of NSMutableArray, assigning to an element using an index within this range will replace that element, but assigning to an element using an index outside this range will raise an exception; no syntax is provided for inserting, appending, or removing elements for mutable arrays.

A class need not declare both methods in order to take advantage of this language feature. For example, the class NSArray declares only objectAtIndexedSubscript:, so that assignments to elements will fail to type-check; moreover, its subclass NSMutableArray declares setObject:atIndexedSubscript:.

Dictionary-Style Subscripting

When the subscript operand has an Objective-C object pointer type, the expression is rewritten to use one of two different selectors, depending on whether the element is being read from or written to. When an expression reads an element using an Objective-C object pointer subscript operand, as in the following example:

id key = ...;
id value = object[key];

it is translated into a call to the objectForKeyedSubscript: method:

id value = [object objectForKeyedSubscript:key];

When an expression writes an element using an Objective-C object pointer subscript:

object[key] = newValue;

it is translated to a call to setObject:forKeyedSubscript:

[object setObject:newValue forKeyedSubscript:key];

The behavior of setObject:forKeyedSubscript: is class-specific; but in general it should replace an existing value if one is already associated with a key, otherwise it should add a new value for the key. No syntax is provided for removing elements from mutable dictionaries.


An Objective-C subscript expression occurs when the base operand of the C subscript operator has an Objective-C object pointer type. Since this potentially collides with pointer arithmetic on the value, these expressions are only supported under the modern Objective-C runtime, which categorically forbids such arithmetic.

Currently, only subscripts of integral or Objective-C object pointer type are supported. In C++, a class type can be used if it has a single conversion function to an integral or Objective-C pointer type, in which case that conversion is applied and analysis continues as appropriate. Otherwise, the expression is ill-formed.

An Objective-C object subscript expression is always an l-value. If the expression appears on the left-hand side of a simple assignment operator (=), the element is written as described below. If the expression appears on the left-hand side of a compound assignment operator (e.g. +=), the program is ill-formed, because the result of reading an element is always an Objective-C object pointer and no binary operators are legal on such pointers. If the expression appears in any other position, the element is read as described below. It is an error to take the address of a subscript expression, or (in C++) to bind a reference to it.

Programs can use object subscripting with Objective-C object pointers of type id. Normal dynamic message send rules apply; the compiler must see some declaration of the subscripting methods, and will pick the declaration seen first.


Objects created using the literal or boxed expression syntax are not guaranteed to be uniqued by the runtime, but nor are they guaranteed to be newly-allocated. As such, the result of performing direct comparisons against the location of an object literal (using ==, !=, <, <=, >, or >=) is not well-defined. This is usually a simple mistake in code that intended to call the isEqual: method (or the compare: method).

This caveat applies to compile-time string literals as well. Historically, string literals (using the @"..." syntax) have been uniqued across translation units during linking. This is an implementation detail of the compiler and should not be relied upon. If you are using such code, please use global string constants instead (NSString * const MyConst = @"...") or use isEqual:.

Grammar Additions

To support the new syntax described above, the Objective-C @-expression grammar has the following new productions:

objc-at-expression : '@' (string-literal | encode-literal | selector-literal | protocol-literal | object-literal)

object-literal : ('+' | '-')? numeric-constant
               | character-constant
               | boolean-constant
               | array-literal
               | dictionary-literal

boolean-constant : '__objc_yes' | '__objc_no' | 'true' | 'false'  /* boolean keywords. */

array-literal : '[' assignment-expression-list ']'

assignment-expression-list : assignment-expression (',' assignment-expression-list)?
                           | /* empty */

dictionary-literal : '{' key-value-list '}'

key-value-list : key-value-pair (',' key-value-list)?
               | /* empty */

key-value-pair : assignment-expression ':' assignment-expression

Note: @true and @false are only supported in Objective-C++.

Availability Checks

Programs test for the new features by using clang’s __has_feature checks. Here are examples of their use:

#if __has_feature(objc_array_literals)
    // new way.
    NSArray *elements = @[ @"H", @"He", @"O", @"C" ];
    // old way (equivalent).
    id objects[] = { @"H", @"He", @"O", @"C" };
    NSArray *elements = [NSArray arrayWithObjects:objects count:4];

#if __has_feature(objc_dictionary_literals)
    // new way.
    NSDictionary *masses = @{ @"H" : @1.0078,  @"He" : @4.0026, @"O" : @15.9990, @"C" : @12.0096 };
    // old way (equivalent).
    id keys[] = { @"H", @"He", @"O", @"C" };
    id values[] = { [NSNumber numberWithDouble:1.0078], [NSNumber numberWithDouble:4.0026],
                    [NSNumber numberWithDouble:15.9990], [NSNumber numberWithDouble:12.0096] };
    NSDictionary *masses = [NSDictionary dictionaryWithObjects:objects forKeys:keys count:4];

#if __has_feature(objc_subscripting)
    NSUInteger i, count = elements.count;
    for (i = 0; i < count; ++i) {
        NSString *element = elements[i];
        NSNumber *mass = masses[element];
        NSLog(@"the mass of %@ is %@", element, mass);
    NSUInteger i, count = [elements count];
    for (i = 0; i < count; ++i) {
        NSString *element = [elements objectAtIndex:i];
        NSNumber *mass = [masses objectForKey:element];
        NSLog(@"the mass of %@ is %@", element, mass);

#if __has_attribute(objc_boxable)
    typedef struct __attribute__((objc_boxable)) _Rect Rect;

#if __has_feature(objc_boxed_nsvalue_expressions)
    CABasicAnimation animation = [CABasicAnimation animationWithKeyPath:@"position"];
    animation.fromValue = @(layer.position);
    animation.toValue = @(newPosition);
    [layer addAnimation:animation forKey:@"move"];
    CABasicAnimation animation = [CABasicAnimation animationWithKeyPath:@"position"];
    animation.fromValue = [NSValue valueWithCGPoint:layer.position];
    animation.toValue = [NSValue valueWithCGPoint:newPosition];
    [layer addAnimation:animation forKey:@"move"];

Code can use also __has_feature(objc_bool) to check for the availability of numeric literals support. This checks for the new __objc_yes / __objc_no keywords, which enable the use of @YES / @NO literals.

To check whether boxed expressions are supported, use __has_feature(objc_boxed_expressions) feature macro.

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