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What's the usual way to store c-structures in an NSArray? Advantages, disadvantages, memory handling?

Notably, what's the difference between valueWithBytes and valueWithPointer -- raised by justin and catfish below.

Here's a link to Apple's discussion of valueWithBytes:objCType: for future readers...

For some lateral thinking and looking more at performance, Evgen has raised the issue of using STL::vector in C++.

(That raises an interesting issue: is there a fast c library, not unlike STL::vector but much much lighter, that allows for the minimal "tidy handling of arrays" ...?)

So the original question...

For example:

typedef struct _Megapoint {
    float   w,x,y,z;
} Megapoint;

So: what's the normal, best, idiomatic way to store one's own structure like that in an NSArray, and how do you handle memory in that idiom?

Please note that I am specifically looking for the usual idiom to store structs. Of course, one could avoid the issue by making a new little class. However I want to know how the usual idiom for actually putting structs in an array, thanks.

BTW here's the NSData approach which is perhaps? not best...

Megapoint p;
NSArray *a = [NSArray arrayWithObjects:
    [NSData dataWithBytes:&p length:sizeof(Megapoint)],
    [NSData dataWithBytes:&p length:sizeof(Megapoint)],
    [NSData dataWithBytes:&p length:sizeof(Megapoint)],

BTW as a point of reference and thanks to Jarret Hardie, here's how to store CGPoints and similar in an NSArray:

NSArray *points = [NSArray arrayWithObjects:
        [NSValue valueWithCGPoint:CGPointMake(6.9, 6.9)],
        [NSValue valueWithCGPoint:CGPointMake(6.9, 6.9)],

(see How can I add CGPoint objects to an NSArray the easy way?)

share|improve this question
your code for converting it to NSData should be fine.. and with no memory leaks.... however, one might as well use a standard C++ array of structs Megapoint p[3]; – lukya Dec 23 '10 at 9:02
You can't add a bounty until the question is two days old. – Matthew Frederick Dec 23 '10 at 10:54
valueWithCGPoint is not available for OSX though. It's part of UIKit – lppier Apr 18 '13 at 9:48
@Ippier valueWithPoint is available on OS X – Schpaencoder Aug 11 '13 at 9:21

11 Answers 11

up vote 132 down vote accepted

NSValue doesn't only support CoreGraphics structures – you can use it for your own too. I would recommend doing so, as the class is probably lighter weight than NSData for simple data structures.

Simply use an expression like the following:

[NSValue valueWithBytes:&p objCType:@encode(Megapoint)];

And to get the value back out:

Megapoint p;
[value getValue:&p];
share|improve this answer
@Joe Blow @Catfish_Man It actually copies the structure p, not a pointer to it. The @encode directive provides all the information necessary about how big the structure is. When you release the NSValue (or when the array does), its copy of the structure is destroyed. If you've used getValue: in the meantime, you're fine. See the "Using Values" section of "Number and Value Programming Topics":… – Justin Spahr-Summers Dec 23 '10 at 22:40
@Joe Blow Mostly correct, except that it wouldn't be able to change at runtime. You're specifying a C type, which always must be fully known. If it could get "larger" by referencing more data, then you would probably implement that with a pointer, and the @encode would describe the structure with that pointer, but not fully describe the pointed-to data, which could indeed change. – Justin Spahr-Summers Dec 29 '10 at 1:01
Will NSValue automatically free the memory of the struct when it is deallocated? The documentation is a little unclear on this. – devios May 28 '15 at 23:08
So just to be completely clear, the NSValue owns the data it copies into itself and I don't have to worry about freeing it (under ARC)? – devios May 29 '15 at 18:25
@devios Correct. NSValue doesn't really do any “memory management,” per se—you can think of it as just having a copy of the structure value internally. If the structure contained nested pointers, for example, NSValue wouldn't know to free or copy or do anything with those—it would leave them untouched, copying the address as-is. – Justin Spahr-Summers May 30 '15 at 4:07

I would suggest you stick to the NSValue route, but if you really do wish to store plain 'ol struct datatypes in your NSArray (and other collection objects in Cocoa), you can do so -- albeit indirectly, using Core Foundation and toll-free bridging.

CFArrayRef (and its mutable counterpart, CFMutableArrayRef) afford the developer more flexibility when creating an array object. See the fourth argument of the designated initialiser:

CFArrayRef CFArrayCreate (
    CFAllocatorRef allocator,
    const void **values,
    CFIndex numValues,
    const CFArrayCallBacks *callBacks

This allows you to request that the CFArrayRef object use Core Foundation's memory management routines, none at all or even your own memory management routines.

Obligatory example:

// One would pass &kCFTypeArrayCallBacks (in lieu of NULL) if using CF types.
CFMutableArrayRef arrayRef = CFArrayCreateMutable(kCFAllocatorDefault, 0, NULL);
NSMutableArray *array = (NSMutableArray *)arrayRef;

struct {int member;} myStruct = {.member = 42};
// Casting to "id" to avoid compiler warning
[array addObject:(id)&myStruct];

// Hurray!
struct {int member;} *mySameStruct = [array objectAtIndex:0];

The above example completely ignores the issues with respect to memory management. The structure myStruct is created on the stack and hence is destroyed when the function ends -- the array will contain a pointer to an object that is no longer there. You can work around this by using your own memory management routines -- hence why the option is provided to you -- but then you have to do the hard work of reference counting, allocating memory, deallocating it and so on.

I would not recommend this solution, but will keep it here in case it is of interest to anyone else. :-)

Using your structure as allocated on the heap (in lieu of the stack) is demonstrated here:

typedef struct {
    float w, x, y, z;
} Megapoint;

// One would pass &kCFTypeArrayCallBacks (in lieu of NULL) if using CF types.
CFMutableArrayRef arrayRef = CFArrayCreateMutable(kCFAllocatorDefault, 0, NULL);
NSMutableArray *array = (NSMutableArray *)arrayRef;

Megapoint *myPoint = malloc(sizeof(Megapoint);
myPoint->w = 42.0f;
// set ivars as desired..

// Casting to "id" to avoid compiler warning
[array addObject:(id)myPoint];

// Hurray!
Megapoint *mySamePoint = [array objectAtIndex:0];
share|improve this answer
Mutable arrays (at least in this case) are created in an empty state and hence don't need a pointer to the values to be stored within. This is distinct from the immutable array wherein the contents are "frozen" at creation and hence values must be passed to the initialisation routine. – Sedate Alien Dec 30 '10 at 1:11
@Joe Blow: That's an excellent point you make regarding memory management. You are right to be confused: the code sample I posted above would cause mysterious crashes, depending on when the function's stack is overwritten. I started to elaborate on how my solution might be used, but realised that I was reimplementing Objective-C's own reference-counting. My apologies for the compact code -- it's not a matter of aptitude but laziness. No point in writing code that others can't read. :) – Sedate Alien Dec 30 '10 at 8:58
If you were happy to "leak" (for want of a better word) the struct, you could certainly allocate it once and not free it in the future. I've included an example of this in my edited answer. Also, it was not a typo for myStruct, as it was a structure allocated on the stack, as distinct from a pointer to a structure allocated on the heap. – Sedate Alien Dec 30 '10 at 11:12

it would be best to use the poor-man's objc serializer if you're sharing this data across multiple abis/architectures:

Megapoint mpt = /* ... */;
NSMutableDictionary * d = [NSMutableDictionary new];

/* optional, for your runtime/deserialization sanity-checks */
[d setValue:@"Megapoint" forKey:@"Type-Identifier"];

[d setValue:[NSNumber numberWithFloat:mpt.w] forKey:@"w"];
[d setValue:[NSNumber numberWithFloat:mpt.x] forKey:@"x"];
[d setValue:[NSNumber numberWithFloat:mpt.y] forKey:@"y"];
[d setValue:[NSNumber numberWithFloat:mpt.z] forKey:@"z"];

NSArray *a = [NSArray arrayWithObject:d];
[d release], d = 0;
/* ... */

...particularly if the structure can change over time (or by targeted platform). it's not as fast as other options, but it's less likely to break in some conditions (which you haven't specified as important or not).

if the serialized representation does not exit the process, then size/order/alignment of arbitrary structs should not change, and there are options which are simpler and faster.

in either event, you're already adding a ref-counted object (compared to NSData, NSValue) so... creating an objc class which holds Megapoint is the right answer in many cases.

share|improve this answer
it's the plural of – justin Dec 24 '10 at 8:00
@Joe Blow something which performs serialization. for reference:,, as well as Apple's "Archives and Serializations Programming Guide". – justin Dec 29 '10 at 9:36
assuming the xml file properly represents something, then yes - it's one common form of a human-readable serialization. – justin Dec 30 '10 at 23:19
you're welcome :) – justin Dec 31 '10 at 7:23

if you're feeling nerdy, or really have a lot of classes to create: it is occasionally useful to dynamically construct an objc class (ref: class_addIvar). this way, you can create arbitrary objc classes from arbitrary types. you can specify field by field, or just pass the info of the struct (but that's practically replicating NSData). sometimes useful, but probably more of a 'fun fact' for most readers.

How would I apply this here?

you can call class_addIvar and add a Megapoint instance variable to a new class, or you can synthesize an objc variant of the Megapoint class at runtime (e.g., an instance variable for each field of Megapoint).

the former is equivalent to the compiled objc class:

@interface MONMegapoint { Megapoint megapoint; } @end

the latter is equivalent to the compiled objc class:

@interface MONMegapoint { float w,x,y,z; } @end

after you've added the ivars, you can add/synthesize methods.

to read the stored values on the receiving end, use your synthesized methods, object_getInstanceVariable, or valueForKey:(which will often convert these scalar instance variables into NSNumber or NSValue representations).

btw: all the answers you have received are useful, some are better/worse/invalid depending on the context/scenario. specific needs regarding memory, speed, ease to maintain, ease to transfer or archive, etc. will determine which is best for a given case... but there is no 'perfect' solution which is ideal in every regard. there is no 'best way to put a c-struct in an NSArray', just a 'best way to put a c-struct in an NSArray for a specific scenario, case, or set of requirements' -- which you'd have to specify.

furthermore, NSArray is a generally reusable array interface for pointer sized (or smaller) types, but there are other containers which are better suited for c-structs for many reasons (std::vector being an typical choice for c-structs).

share|improve this answer
response expanded – justin Dec 29 '10 at 10:22
people's backgrounds come into play as well... how you need to use that struct will often eliminate some possibilities. 4 floats is pretty foolproof, but struct layouts vary by architecture/compiler too much to use a contiguous memory representation (e.g., NSData) and expect it to work. the poor man's objc serializer likely has the slowest execution time, but it is the most compatible if you need to save/open/transmit the Megapoint on any OS X or iOS device. The most common way, in my experience is to simply put the struct in an objc class. if you're going through all of this just to (cont) – justin Dec 30 '10 at 0:05
(cont) If you're going through all this hassle only to avoid learning a new collection type -- then you should learn the new collection type =) std::vector (for example) is more suited to holding C/C++ types, structs and classes than NSArray. By using an NSArray of NSValue, NSData, or NSDictionary types, you're losing a lot of type-safety while adding a ton of allocations and runtime overhead. If you want to stick with C, then they'd generally use malloc and/or arrays on the stack... but std::vector hides most of the complications from you. – justin Dec 30 '10 at 0:16
in fact, if you want array manipulation/iteration as you mentioned - stl (part of c++ standard libraries) is great for that. you have more types to choose from (e.g., if insert/remove is more important than read access times), and tons of existing ways to manipulate the containers. also - it's not bare memory in c++ - the containers and template functions are type-aware, and checked at compilation - much safer than pulling an arbitrary byte string out of NSData/NSValue representations. they also have bounds checking and mostly automatic management of memory. (cont) – justin Dec 30 '10 at 0:38
(cont) if you expect that you'll have a lot of low level work like this, then you should just learn it now - but it will take time to learn. by wrapping this all up in objc representations, you're losing a lot of performance and type safety, while making yourself write much more boilerplate code to access and interpret the containers and their values (If 'Thus, to be very specific…' is exactly what you want to do). – justin Dec 30 '10 at 0:42

A similar method to add c struct is to store the pointer and to de-reference the pointer as so;

typedef struct BSTNode
    int data;
    struct BSTNode *leftNode;
    struct BSTNode *rightNode;

BSTNode *rootNode;

//declaring a NSMutableArray
@property(nonatomic)NSMutableArray *queues;

//storing the pointer in the array
[self.queues addObject:[NSValue value:&rootNode withObjCType:@encode(BSTNode*)]];

//getting the value
BSTNode *frontNode =[[self.queues objectAtIndex:0] pointerValue];
share|improve this answer

I suggest you to use std::vector or std::list for C/C++ types, because at first it's just faster than NSArray, and at second if there will be not enough speed for you - you're always can create your own allocators for STL containers and make them even more fast. All modern mobile Game, Physics and Audio engines uses STL containers to store internal data. Just because they really fast.

If it's not for you - there is good answers from guys about NSValue - i think it's most acceptable.

share|improve this answer
STL is a library partially included into C++ Standard Library. – Evgen Bodunov Dec 29 '10 at 16:07
That's an interesting claim. Do you have a link to an article about the speed advantage of the STL containers vs. the Cocoa container classes? – Sedate Alien Dec 30 '10 at 1:07
here's an interesting read on NSCFArray vs std::vector: in the example in your post, the biggest loss is (typically) creating an objc object representation per element (e.g., NSValue, NSData, or Objc type containing Megapoint requires an allocation and insertion into ref-counted system). you could actually avoid that by using Sedate Alien's approach to storing a Megapoint in a special CFArray which uses a separate backing store of contiguously allocated Megapoints (although neither example illustrates that approach). (cont) – justin Dec 31 '10 at 8:00
but then using the NSCFArray vs the vector (or other stl type) will incur additional overhead for dynamic dispatch, additional function calls which aren't inlined, a ton of type safety, and many chances for the optimizer to kick in... that article just focuses on insert, read, walk, delete. chances are, you won't get any faster than a 16 byte aligned c-array Megapoint pt[8]; - this is an option in c++, and specialized c++ containers (e.g., std::array) - also note the example does not add the special alignment (16 bytes was chosen because it is the size of Megapoint). (cont) – justin Dec 31 '10 at 8:11
std::vector will add a tiny amount of overhead to this, and one allocation (if you know the size you'll need)... but this is closer to the metal than more than 99.9% of cases need. typically, you'd just use a vector unless the size is fixed or has a reasonable maximum. – justin Dec 31 '10 at 8:13

Instead of trying to put c struct in a NSArray you can put them in a NSData or NSMutableData as a c array of structs. To access them you would the do

const struct MyStruct    * theStruct = (const struct MyStruct*)[myData bytes];
int                      value = theStruct[2].integerNumber;

or to set then

struct MyStruct    * theStruct = (struct MyStruct*)[myData mutableBytes];
theStruct[2].integerNumber = 10;
share|improve this answer

While using an NSValue works fine for storing structs as an Obj-C object, you cannot encode an NSValue containing a struct with NSArchiver/NSKeyedArchiver. Instead, you have to encode individual struct members...

See Apple's Archives and Serializations Programming Guide > Structures and Bit Fields

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You can store anything that implements the NSObject protocol in an NSArray. I usually just create my own class that wraps the C struct and that inherits NSObject (and therefore implements the NSObject protocol automatically) and then just use that.

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If you want to do it without wrapping the class somehow then your approach of using NSData is probably the best. – Peter Zion Dec 23 '10 at 9:18

An Obj C object is just a C struct with some added elements. So just create a custom class and you will have the type of C struct that an NSArray requires. Any C struct that does not have the extra cruft that an NSObject includes within its C struct will be indigestible to an NSArray.

Using NSData as a wrapper might only be storing a copy of the structs and not the original structs, if that makes a difference to you.

share|improve this answer

I have one idea, but you may like it or not.

You can use NSObject classes other than the C-Structures to store information. And you can easily store that NSObject in to NSArray.



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