I saw usage of this function in Mike Ash's post on ARC and wanted to play around with it but i just can't find where it resides. I haven't found it in objc/runtime and similar files, runtime documentation doesn't mention it, googling also gave nothing to me. What the secret function it is? Where is it? How do i import it?
objc_retainAutoreleaseReturnValue() and the related methods from the
ARC runtime support are defined in /usr/lib/libobjc.A.dylib, but not exposed in the
public header files.
When you download http://www.opensource.apple.com/source/objc4/objc4-551.1/
you will find the prototypes in "runtime/objc-internal.h", for example
// wraps objc_autorelease(objc_retain(obj)) in a useful way when used with return values
OBJC_EXPORT
id
objc_retainAutoreleaseReturnValue(id obj)
__OSX_AVAILABLE_STARTING(__MAC_10_7, __IPHONE_5_0);
But I have no idea whether or not
it is safe to call these internal runtime functions in your code.
Some of them do very special things (like inspecting the callers code
to check if an object has to be put into the autorelease pool or not).
Related
I prefer working with files that are less than 1000 lines long, so am thinking of breaking up some Erlang modules into more bite-sized pieces.
Is there a way of doing this without expanding the public API of my library?
What I mean is, any time there is a module, any user can do module:func_exported_from_the_module. The only way to really have something be private that I know of is to not export it from any module (and even then holes can be poked).
So if there is technically no way to accomplish what I'm looking for, is there a convention?
For example, there are no private methods in Python classes, but the convention is to use a leading _ in _my_private_method to mark it as private.
I accept that the answer may be, "no, you must have 4K LOC files."
The closest thing to a convention is to use edoc tags, like #private and #hidden.
From the docs:
#hidden
Marks the function so that it will not appear in the
documentation (even if "private" documentation is generated). Useful
for debug/test functions, etc. The content can be used as a comment;
it is ignored by EDoc.
#private
Marks the function as private (i.e., not part of the public
interface), so that it will not appear in the normal documentation.
(If "private" documentation is generated, the function will be
included.) Only useful for exported functions, e.g. entry points for
spawn. (Non-exported functions are always "private".) The content can
be used as a comment; it is ignored by EDoc.
Please note that this answer started as a comment to #legoscia's answer
Different visibilities for different methods is not currently supported.
The current convention, if you want to call it that way, is to have one (or several) 'facade' my_lib.erl module(s) that export the public API of your library/application. Calling any internal module of the library is playing with fire and should be avoided (call them at your own risk).
There are some very nice features in the BEAM VM that rely on being able to call exported functions from any module, such as
Callbacks (funs/anonymous funs), MFA, erlang:apply/3: The calling code does not need to know anything about the library, just that it's something that needs to be called
Behaviours such as gen_server need the previous point to work
Hot reloading: You can upgrade the bytecode of any module without stopping the VM. The code server inside the VM maintains at most two versions of the bytecode for any module, redirecting external calls (those with the Module:) to the most recent version and the internal calls to the current version. That's why you may see some ?MODULE: calls in long-running servers, to be able to upgrade the code
You'd be able to argue that these points'd be available with more fine-grained BEAM-oriented visibility levels, true. But I don't think it would solve anything that's not solved with the facade modules, and it'd complicate other parts of the VM/code a great deal.
Bonus
Something similar applies to records and opaque types, records only exist at compile time, and opaque types only at dialyzer time. Nothing stops you from accessing their internals anywhere, but you'll only find problems if you go that way:
You insert a new field in the record, suddenly, all your {record_name,...} = break
You use a library that returns an opaque_adt(), you know that it's a list and use like so. The library is upgraded to include the size of the list, so now opaque_adt() is a tuple() and chaos ensues
Only those functions that are specified in the -export attribute are visible to other modules i.e "public" functions. All other functions are private. If you have specified -compile(export_all) only then all functions in module are visible outside. It is not recommended to use -compile(export_all).
I don't know of any existing convention for Erlang, but why not adopt the Python convention? Let's say that "library-private" functions are prefixed with an underscore. You'll need to quote function names with single quotes for that to work:
-module(bar).
-export(['_my_private_function'/0]).
'_my_private_function'() ->
foo.
Then you can call it as:
> bar:'_my_private_function'().
foo
To me, that communicates clearly that I shouldn't be calling that function unless I know what I'm doing. (and probably not even then)
It's common in a lot of classes in JDK, just a few examples:
java.util.Properties
load0
store0
java.lang.Thread
start0
stop0
setPriority0
Usually they are private native methods (like in Thread class), but sometimes they are just private (Properties class)
I'm just curious if anybody know if there is any history behind that.
I believe they are named like that because equivalent functions with same names exist in the code and just to distinguish between native helper functions and public functions they decided to suffix them with 0.
in java.util.Properties both load, store and load0, store0 exist.
The 0 after the method name is done so to distinguish between public and private methods having same name .
Start function will call the start0 function.
Those functions which ends with 0 is private method.
And those which are not ending with number is public.
You can check in any of the library.
The use of zero suffixes on method names is just a convention to deal with cases where you have a public API method and a corresponding private method. In the Java SE libraries, this is commonly used for the native methods that provide the underlying functionality implemented by the classes. (You can see what is going on by looking at the OpenJDK source code.)
But your questions are:
Why some java methods in core libraries end with numbers?
Because someone thought it would be a good idea. It is not strictly necessary since they typically could have overloaded the public methods instead. And since the zero suffix matters are private, the naming of methods should not be relevant beyond the class and its native implementation.
I'm just curious if anybody know if there is any history behind that.
There is no mention of this convention in the original Java Style Guide. In fact, I think it predates Java. I vaguely recall seeing it in C libraries in 4.x BSD Unix. That was the mid 1980's. And I wouldn't be surprised if they adopted it from somewhere else.
ObjC has a very unique way of overriding methods. Specifically, that you can override functions in OSX's own framework. Via "categories" or "Swizzling". You can even override "buried" functions only used internally.
Can someone provide me with an example where there was a good reason to do this? Something you would use in released commercial software and not just some hacked up tool for internal use?
For example, maybe you wanted to improve on some built in method, or maybe there was a bug in a framework method you wanted to fix.
Also, can you explain why this can best be done with features in ObjC, and not in C++ / Java and the like. I mean, I've heard of the ability to load a C library, but allow certain functions to be replaced, with functions of the same name that were previously loaded. How is ObjC better at modifying library behaviour than that?
If you're extending the question from mere swizzling to actual library modification then I can think of useful examples.
As of iOS 5, NSURLConnection provides sendAsynchronousRequest:queue:completionHandler:, which is a block (/closure) driven way to perform an asynchronous load from any resource identifiable with a URL (local or remote). It's a very useful way to be able to proceed as it makes your code cleaner and smaller than the classical delegate alternative and is much more likely to keep the related parts of your code close to one another.
That method isn't supplied in iOS 4. So what I've done in my project is that, when the application is launched (via a suitable + (void)load), I check whether the method is defined. If not I patch an implementation of it onto the class. Henceforth every other part of the program can be written to the iOS 5 specification without performing any sort of version or availability check exactly as if I was targeting iOS 5 only, except that it'll also run on iOS 4.
In Java or C++ I guess the same sort of thing would be achieved by creating your own class to issue URL connections that performs a runtime check each time it is called. That's a worse solution because it's more difficult to step back from. This way around if I decide one day to support iOS 5 only I simply delete the source file that adds my implementation of sendAsynchronousRequest:.... Nothing else changes.
As for method swizzling, the only times I see it suggested are where somebody wants to change the functionality of an existing class and doesn't have access to the code in which the class is created. So you're usually talking about trying to modify logically opaque code from the outside by making assumptions about its implementation. I wouldn't really support that as an idea on any language. I guess it gets recommended more in Objective-C because Apple are more prone to making things opaque (see, e.g. every app that wanted to show a customised camera view prior to iOS 3.1, every app that wanted to perform custom processing on camera input prior to iOS 4.0, etc), rather than because it's a good idea in Objective-C. It isn't.
EDIT: so, in further exposition — I can't post full code because I wrote it as part of my job, but I have a class named NSURLConnectionAsyncForiOS4 with an implementation of sendAsynchronousRequest:queue:completionHandler:. That implementation is actually quite trivial, just dispatching an operation to the nominated queue that does a synchronous load via the old sendSynchronousRequest:... interface and then posts the results from that on to the handler.
That class has a + (void)load, which is the class method you add to a class that will be issued immediately after that class has been loaded into memory, effectively as a global constructor for the metaclass and with all the usual caveats.
In my +load I use the Objective-C runtime directly via its C interface to check whether sendAsynchronousRequest:... is defined on NSURLConnection. If it isn't then I add my implementation to NSURLConnection, so from henceforth it is defined. This explicitly isn't swizzling — I'm not adjusting the existing implementation of anything, I'm just adding a user-supplied implementation of something if Apple's isn't available. Relevant runtime calls are objc_getClass, class_getClassMethod and class_addMethod.
In the rest of the code, whenever I want to perform an asynchronous URL connection I just write e.g.
[NSURLConnection sendAsynchronousRequest:request
queue:[self anyBackgroundOperationQueue]
completionHandler:
^(NSURLResponse *response, NSData *data, NSError *blockError)
{
if(blockError)
{
// oh dear; was it fatal?
}
if(data)
{
// hooray! You know, unless this was an HTTP request, in
// which case I should check the response code, etc.
}
/* etc */
}
So the rest of my code is just written to the iOS 5 API and neither knows nor cares that I have a shim somewhere else to provide that one microscopic part of the iOS 5 changes on iOS 4. And, as I say, when I stop supporting iOS 4 I'll just delete the shim from the project and all the rest of my code will continue not to know or to care.
I had similar code to supply an alternative partial implementation of NSJSONSerialization (which dynamically created a new class in the runtime and copied methods to it); the one adjustment you need to make is that references to NSJSONSerialization elsewhere will be resolved once at load time by the linker, which you don't really want. So I added a quick #define of NSJSONSerialization to NSClassFromString(#"NSJSONSerialization") in my precompiled header. Which is less functionally neat but a similar line of action in terms of finding a way to keep iOS 4 support for the time being while just writing the rest of the project to the iOS 5 standards.
There are both good and bad cases. Since you didn't mention anything in particular these examples will be all-over-the-place.
It's perfectly normal (good idea) to override framework methods when subclassing:
When subclassing NSView (from the AppKit.framework), it's expected that you override drawRect:(NSRect). It's the mechanism used for drawing views.
When creating a custom NSMenu, you could override insertItemWithTitle:action:keyEquivalent:atIndex: and any other methods...
The main thing when subclassing is whether or not your behaviour completes re-defines the old behaviour... or extends it (in which case your override eventually calls [super ...];)
That said, however, you should always stand clear of using (and overriding) any private API methods (those normally have an underscore prefix in their name). This is a bad idea.
You also should not override existing methods via categories. That's also bad. It has undefined behaviour.
If you're talking about categories, you don't override methods with them (because there is no way to call original method, like calling super when subclassing), but only completely replace with your own ones, which makes the whole idea mostly pointless. Categories are only useful for safely extending functionality, and that's the only use I have even seen (and which is a very good, an excellent idea), although indeed they can be used for dangerous things.
If you mean overriding by subclassing, that is not unique. But in Obj-C you can override everything, even private undocumented methods, not just what was declared 'overridable' like in other languages. Personally, I think it's nice, as I remember in Delphi and C++ I used to “hack” access to private and protected members to workaround an internal bug in framework. This is not a good idea, but at some moments it can be a life saver.
There is also method swizzling, but that's not standard language feature, that's a hack. Hacking undocumented internals is rarely a good idea.
And regarding “how can you explain why this can best be done with features in ObjC”, the answer is simple — Obj-C is dynamic, and this freedom is common to almost all dynamic languages (Javascript, Python, Ruby, Io, a lot more). Unless artificially disabled, every dynamic language has it.
Refer to the wikipedia page on dynamic languages for longer explanation and more examples. For example, an even more miraculous things possible in Obj-C and other dynamic languages is that an object can change it's type (class) in place, without recreation.
I have never made an API in objective-c, and need to do this now.
The "idea" is that I build an API which can be implemented into other applications. Much like Flurry, only for other purposes.
When starting the API, an username, password and mode should be entered. The mode should either be LIVE or BETA (I guess this should be an NSString(?)), then afterwards is should be fine with [MyAPI doSomething:withThisObject]; ect.
So to start it [MyAPI username:#"Username" password:#"Password" mode:#"BETA"];
Can anyone help me out with some tutorials and pointer on how to learn this best?
It sounds like what you want to do is build a static library. This is a compiled .a file containing object code that you'll distribute to a client along with a header file containing the interface. This post is a little outdated but has some good starting points. Or, if you don't mind giving away your source code, you could just deliver a collection of source files to your client.
In terms of developing the API itself, it should be very similar to the way you'd design interfaces and implementations of Objective-C objects in your own apps. You'll have a MyAPI class with functions for initialization, destruction, and all the functionality you want. You could also have multiple classes with different functionality if the interface is complex. Because you've capitalized MyAPI in your code snippet, it looks like you want to use it by calling the class rather than an instance of the class - which is a great strategy if you think you'll only ever need one instance. To accomplish this you can use the singleton pattern.
Because you've used a username and password, I imagine your API will interface with the web internally. I've found parsing JSON to be very straightforward in Objective-C - it's easy to send requests and get information from a server.
Personally I would use an enum of unsigned ints rather than a NSString just because it simplifies comparisons and such. So you could do something like:
enum {
MYAPI_MODE_BETA,
MYAPI_MODE_LIVE,
NUM_MYAPI_MODES
};
And then call:
[MyAPI username:#"Username" password:#"Password" mode:MYAPI_MODE_BETA];
Also makes it easy to check if they've supplied a valid mode. (Must be less than NUM_MYAPI_MODES.)
Good luck!
What is the recommended way to define private and protected methods in Objective-C? One website suggested using categories in the implementation file for private methods, another suggested trailing underscores, or XX_ where XX is some project-specific code. What does Apple itself use?
And what about protected methods? One solution I read was to use categories in separate files, for example CLASS_protected.h and CLASS_protected.m but this seems like it could get very bloated. What should I do?
There are three issues:
Hiding from compiler.
That is, making it impossible for someone else to #import something and see your method declarations. For that, put your private API into a separate header file, mark that header's role as "Private" in Xcode, and then import it in your project where you need access to said private API.
Use a category or class extension to declare the additional methods.
Preventing collisions
If you are implementing lots of internal goop, do so with a common prefix or something that makes a collision with Apple provided (or third party) provided methods exceedingly unlikely. This is especially critical for categories and not nearly as critical for your leaf node subclasses of existing classes.
Post the link for the site suggesting leading underscores, as they are wrong, wrong, wrong. Leading underscores are used by the system to mark private API and you can run into collisions easily enough.
Hiding from the runtime.
Don't bother. It just makes debugging / crash analysis harder and anyone determined enough to muck around at the runtime will be able to hack your app anyway.
There are no "real" private methods in Objective C, as the run-time will allow, via documented public APIs, access any method in any class by using their string names.
I never do separate interface files for "private" methods, and let the compiler complain if I try to use these any of these methods outside of file scope.
The XX_ seems to be the ad hoc means to create a pseudo namespace. The idea is to read Apple's docs and the docs of any frameworks you might use at any time in the future, and pick an XX prefix that none of these others is ever likely to use.