Objective-C Automatic Reference Counting (ARC)¶
About this document¶
Purpose¶
The first and primary purpose of this document is to serve as a complete technical specification of Automatic Reference Counting. Given a core Objective-C compiler and runtime, it should be possible to write a compiler and runtime which implements these new semantics.
The secondary purpose is to act as a rationale for why ARC was designed in this way. This should remain tightly focused on the technical design and should not stray into marketing speculation.
Background¶
This document assumes a basic familiarity with C.
Blocks are a C language extension for creating anonymous functions.
Users interact with and transfer block objects using block
pointers, which are represented like a normal pointer. A block may capture
values from local variables; when this occurs, memory must be dynamically
allocated. The initial allocation is done on the stack, but the runtime
provides a Block_copy
function which, given a block pointer, either copies
the underlying block object to the heap, setting its reference count to 1 and
returning the new block pointer, or (if the block object is already on the
heap) increases its reference count by 1. The paired function is
Block_release
, which decreases the reference count by 1 and destroys the
object if the count reaches zero and is on the heap.
Objective-C is a set of language extensions, significant enough to be considered a different language. It is a strict superset of C. The extensions can also be imposed on C++, producing a language called Objective-C++. The primary feature is a single-inheritance object system; we briefly describe the modern dialect.
Objective-C defines a new type kind, collectively called the object
pointer types. This kind has two notable builtin members, id
and
Class
; id
is the final supertype of all object pointers. The validity
of conversions between object pointer types is not checked at runtime. Users
may define classes; each class is a type, and the pointer to that
type is an object pointer type. A class may have a superclass; its pointer
type is a subtype of its superclass’s pointer type. A class has a set of
ivars, fields which appear on all instances of that class. For
every class T there’s an associated metaclass; it has no fields, its
superclass is the metaclass of T’s superclass, and its metaclass is a global
class. Every class has a global object whose class is the class’s metaclass;
metaclasses have no associated type, so pointers to this object have type
Class
.
A class declaration (@interface
) declares a set of methods. A
method has a return type, a list of argument types, and a selector:
a name like foo:bar:baz:
, where the number of colons corresponds to the
number of formal arguments. A method may be an instance method, in which case
it can be invoked on objects of the class, or a class method, in which case it
can be invoked on objects of the metaclass. A method may be invoked by
providing an object (called the receiver) and a list of formal
arguments interspersed with the selector, like so:
[receiver foo: fooArg bar: barArg baz: bazArg]
This looks in the dynamic class of the receiver for a method with this name,
then in that class’s superclass, etc., until it finds something it can execute.
The receiver “expression” may also be the name of a class, in which case the
actual receiver is the class object for that class, or (within method
definitions) it may be super
, in which case the lookup algorithm starts
with the static superclass instead of the dynamic class. The actual methods
dynamically found in a class are not those declared in the @interface
, but
those defined in a separate @implementation
declaration; however, when
compiling a call, typechecking is done based on the methods declared in the
@interface
.
Method declarations may also be grouped into protocols, which are not inherently associated with any class, but which classes may claim to follow. Object pointer types may be qualified with additional protocols that the object is known to support.
Class extensions are collections of ivars and methods, designed to
allow a class’s @interface
to be split across multiple files; however,
there is still a primary implementation file which must see the
@interface
s of all class extensions. Categories allow
methods (but not ivars) to be declared post hoc on an arbitrary class; the
methods in the category’s @implementation
will be dynamically added to that
class’s method tables which the category is loaded at runtime, replacing those
methods in case of a collision.
In the standard environment, objects are allocated on the heap, and their
lifetime is manually managed using a reference count. This is done using two
instance methods which all classes are expected to implement: retain
increases the object’s reference count by 1, whereas release
decreases it
by 1 and calls the instance method dealloc
if the count reaches 0. To
simplify certain operations, there is also an autorelease pool, a
thread-local list of objects to call release
on later; an object can be
added to this pool by calling autorelease
on it.
Block pointers may be converted to type id
; block objects are laid out in a
way that makes them compatible with Objective-C objects. There is a builtin
class that all block objects are considered to be objects of; this class
implements retain
by adjusting the reference count, not by calling
Block_copy
.
Evolution¶
ARC is under continual evolution, and this document must be updated as the language progresses.
If a change increases the expressiveness of the language, for example by lifting a restriction or by adding new syntax, the change will be annotated with a revision marker, like so:
ARC applies to Objective-C pointer types, block pointer types, and [beginning Apple 8.0, LLVM 3.8] BPTRs declared within
extern "BCPL"
blocks.
For now, it is sensible to version this document by the releases of its sole implementation (and its host project), clang. “LLVM X.Y” refers to an open-source release of clang from the LLVM project. “Apple X.Y” refers to an Apple-provided release of the Apple LLVM Compiler. Other organizations that prepare their own, separately-versioned clang releases and wish to maintain similar information in this document should send requests to cfe-dev.
If a change decreases the expressiveness of the language, for example by imposing a new restriction, this should be taken as an oversight in the original specification and something to be avoided in all versions. Such changes are generally to be avoided.
General¶
Automatic Reference Counting implements automatic memory management for Objective-C objects and blocks, freeing the programmer from the need to explicitly insert retains and releases. It does not provide a cycle collector; users must explicitly manage the lifetime of their objects, breaking cycles manually or with weak or unsafe references.
ARC may be explicitly enabled with the compiler flag -fobjc-arc
. It may
also be explicitly disabled with the compiler flag -fno-objc-arc
. The last
of these two flags appearing on the compile line “wins”.
If ARC is enabled, __has_feature(objc_arc)
will expand to 1 in the
preprocessor. For more information about __has_feature
, see the
language extensions document.
Retainable object pointers¶
This section describes retainable object pointers, their basic operations, and the restrictions imposed on their use under ARC. Note in particular that it covers the rules for pointer values (patterns of bits indicating the location of a pointed-to object), not pointer objects (locations in memory which store pointer values). The rules for objects are covered in the next section.
A retainable object pointer (or “retainable pointer”) is a value of a retainable object pointer type (“retainable type”). There are three kinds of retainable object pointer types:
block pointers (formed by applying the caret (
^
) declarator sigil to a function type)Objective-C object pointers (
id
,Class
,NSFoo*
, etc.)typedefs marked with
__attribute__((NSObject))
Other pointer types, such as int*
and CFStringRef
, are not subject to
ARC’s semantics and restrictions.
Rationale
We are not at liberty to require all code to be recompiled with ARC; therefore, ARC must interoperate with Objective-C code which manages retains and releases manually. In general, there are three requirements in order for a compiler-supported reference-count system to provide reliable interoperation:
The type system must reliably identify which objects are to be managed. An
int*
might be a pointer to amalloc
’ed array, or it might be an interior pointer to such an array, or it might point to some field or local variable. In contrast, values of the retainable object pointer types are never interior.The type system must reliably indicate how to manage objects of a type. This usually means that the type must imply a procedure for incrementing and decrementing retain counts. Supporting single-ownership objects requires a lot more explicit mediation in the language.
There must be reliable conventions for whether and when “ownership” is passed between caller and callee, for both arguments and return values. Objective-C methods follow such a convention very reliably, at least for system libraries on macOS, and functions always pass objects at +0. The C-based APIs for Core Foundation objects, on the other hand, have much more varied transfer semantics.
The use of __attribute__((NSObject))
typedefs is not recommended. If it’s
absolutely necessary to use this attribute, be very explicit about using the
typedef, and do not assume that it will be preserved by language features like
__typeof
and C++ template argument substitution.
Rationale
Any compiler operation which incidentally strips type “sugar” from a type will yield a type without the attribute, which may result in unexpected behavior.
Retain count semantics¶
A retainable object pointer is either a null pointer or a pointer
to a valid object. Furthermore, if it has block pointer type and is not
null
then it must actually be a pointer to a block object, and if it has
Class
type (possibly protocol-qualified) then it must actually be a pointer
to a class object. Otherwise ARC does not enforce the Objective-C type system
as long as the implementing methods follow the signature of the static type.
It is undefined behavior if ARC is exposed to an invalid pointer.
For ARC’s purposes, a valid object is one with “well-behaved” retaining operations. Specifically, the object must be laid out such that the Objective-C message send machinery can successfully send it the following messages:
retain
, taking no arguments and returning a pointer to the object.release
, taking no arguments and returningvoid
.autorelease
, taking no arguments and returning a pointer to the object.
The behavior of these methods is constrained in the following ways. The term
high-level semantics is an intentionally vague term; the intent is
that programmers must implement these methods in a way such that the compiler,
modifying code in ways it deems safe according to these constraints, will not
violate their requirements. For example, if the user puts logging statements
in retain
, they should not be surprised if those statements are executed
more or less often depending on optimization settings. These constraints are
not exhaustive of the optimization opportunities: values held in local
variables are subject to additional restrictions, described later in this
document.
It is undefined behavior if a computation history featuring a send of
retain
followed by a send of release
to the same object, with no
intervening release
on that object, is not equivalent under the high-level
semantics to a computation history in which these sends are removed. Note that
this implies that these methods may not raise exceptions.
It is undefined behavior if a computation history features any use whatsoever
of an object following the completion of a send of release
that is not
preceded by a send of retain
to the same object.
The behavior of autorelease
must be equivalent to sending release
when
one of the autorelease pools currently in scope is popped. It may not throw an
exception.
When the semantics call for performing one of these operations on a retainable
object pointer, if that pointer is null
then the effect is a no-op.
All of the semantics described in this document are subject to additional optimization rules which permit the removal or optimization of operations based on local knowledge of data flow. The semantics describe the high-level behaviors that the compiler implements, not an exact sequence of operations that a program will be compiled into.
Retainable object pointers as operands and arguments¶
In general, ARC does not perform retain or release operations when simply using a retainable object pointer as an operand within an expression. This includes:
loading a retainable pointer from an object with non-weak ownership,
passing a retainable pointer as an argument to a function or method, and
receiving a retainable pointer as the result of a function or method call.
Rationale
While this might seem uncontroversial, it is actually unsafe when multiple expressions are evaluated in “parallel”, as with binary operators and calls, because (for example) one expression might load from an object while another writes to it. However, C and C++ already call this undefined behavior because the evaluations are unsequenced, and ARC simply exploits that here to avoid needing to retain arguments across a large number of calls.
The remainder of this section describes exceptions to these rules, how those exceptions are detected, and what those exceptions imply semantically.
Consumed parameters¶
A function or method parameter of retainable object pointer type may be marked
as consumed, signifying that the callee expects to take ownership
of a +1 retain count. This is done by adding the ns_consumed
attribute to
the parameter declaration, like so:
void foo(__attribute((ns_consumed)) id x);
- (void) foo: (id) __attribute((ns_consumed)) x;
This attribute is part of the type of the function or method, not the type of the parameter. It controls only how the argument is passed and received.
When passing such an argument, ARC retains the argument prior to making the call.
When receiving such an argument, ARC releases the argument at the end of the function, subject to the usual optimizations for local values.
Rationale
This formalizes direct transfers of ownership from a caller to a callee. The
most common scenario here is passing the self
parameter to init
, but
it is useful to generalize. Typically, local optimization will remove any
extra retains and releases: on the caller side the retain will be merged with
a +1 source, and on the callee side the release will be rolled into the
initialization of the parameter.
The implicit self
parameter of a method may be marked as consumed by adding
__attribute__((ns_consumes_self))
to the method declaration. Methods in
the init
family are treated as if they were
implicitly marked with this attribute.
It is undefined behavior if an Objective-C message send to a method with
ns_consumed
parameters (other than self) is made with a null receiver. It
is undefined behavior if the method to which an Objective-C message send
statically resolves to has a different set of ns_consumed
parameters than
the method it dynamically resolves to. It is undefined behavior if a block or
function call is made through a static type with a different set of
ns_consumed
parameters than the implementation of the called block or
function.
Rationale
Consumed parameters with null receiver are a guaranteed leak. Mismatches with consumed parameters will cause over-retains or over-releases, depending on the direction. The rule about function calls is really just an application of the existing C/C++ rule about calling functions through an incompatible function type, but it’s useful to state it explicitly.
Retained return values¶
A function or method which returns a retainable object pointer type may be
marked as returning a retained value, signifying that the caller expects to take
ownership of a +1 retain count. This is done by adding the
ns_returns_retained
attribute to the function or method declaration, like
so:
id foo(void) __attribute((ns_returns_retained));
- (id) foo __attribute((ns_returns_retained));
This attribute is part of the type of the function or method.
When returning from such a function or method, ARC retains the value at the point of evaluation of the return statement, before leaving all local scopes.
When receiving a return result from such a function or method, ARC releases the value at the end of the full-expression it is contained within, subject to the usual optimizations for local values.
Rationale
This formalizes direct transfers of ownership from a callee to a caller. The
most common scenario this models is the retained return from init
,
alloc
, new
, and copy
methods, but there are other cases in the
frameworks. After optimization there are typically no extra retains and
releases required.
Methods in the alloc
, copy
, init
, mutableCopy
, and new
families are implicitly marked
__attribute__((ns_returns_retained))
. This may be suppressed by explicitly
marking the method __attribute__((ns_returns_not_retained))
.
It is undefined behavior if the method to which an Objective-C message send statically resolves has different retain semantics on its result from the method it dynamically resolves to. It is undefined behavior if a block or function call is made through a static type with different retain semantics on its result from the implementation of the called block or function.
Rationale
Mismatches with returned results will cause over-retains or over-releases, depending on the direction. Again, the rule about function calls is really just an application of the existing C/C++ rule about calling functions through an incompatible function type.
Unretained return values¶
A method or function which returns a retainable object type but does not return a retained value must ensure that the object is still valid across the return boundary.
When returning from such a function or method, ARC retains the value at the
point of evaluation of the return statement, then leaves all local scopes, and
then balances out the retain while ensuring that the value lives across the
call boundary. In the worst case, this may involve an autorelease
, but
callers must not assume that the value is actually in the autorelease pool.
ARC performs no extra mandatory work on the caller side, although it may elect to do something to shorten the lifetime of the returned value.
Rationale
It is common in non-ARC code to not return an autoreleased value; therefore the convention does not force either path. It is convenient to not be required to do unnecessary retains and autoreleases; this permits optimizations such as eliding retain/autoreleases when it can be shown that the original pointer will still be valid at the point of return.
A method or function may be marked with
__attribute__((ns_returns_autoreleased))
to indicate that it returns a
pointer which is guaranteed to be valid at least as long as the innermost
autorelease pool. There are no additional semantics enforced in the definition
of such a method; it merely enables optimizations in callers.
Bridged casts¶
A bridged cast is a C-style cast annotated with one of three keywords:
(__bridge T) op
casts the operand to the destination typeT
. IfT
is a retainable object pointer type, thenop
must have a non-retainable pointer type. IfT
is a non-retainable pointer type, thenop
must have a retainable object pointer type. Otherwise the cast is ill-formed. There is no transfer of ownership, and ARC inserts no retain operations.(__bridge_retained T) op
casts the operand, which must have retainable object pointer type, to the destination type, which must be a non-retainable pointer type. ARC retains the value, subject to the usual optimizations on local values, and the recipient is responsible for balancing that +1.(__bridge_transfer T) op
casts the operand, which must have non-retainable pointer type, to the destination type, which must be a retainable object pointer type. ARC will release the value at the end of the enclosing full-expression, subject to the usual optimizations on local values.
These casts are required in order to transfer objects in and out of ARC control; see the rationale in the section on conversion of retainable object pointers.
Using a __bridge_retained
or __bridge_transfer
cast purely to convince
ARC to emit an unbalanced retain or release, respectively, is poor form.
Restrictions¶
Conversion of retainable object pointers¶
In general, a program which attempts to implicitly or explicitly convert a
value of retainable object pointer type to any non-retainable type, or
vice-versa, is ill-formed. For example, an Objective-C object pointer shall
not be converted to void*
. As an exception, cast to intptr_t
is
allowed because such casts are not transferring ownership. The bridged
casts may be used to perform these conversions
where necessary.
Rationale
We cannot ensure the correct management of the lifetime of objects if they may be freely passed around as unmanaged types. The bridged casts are provided so that the programmer may explicitly describe whether the cast transfers control into or out of ARC.
However, the following exceptions apply.
Conversion to retainable object pointer type of expressions with known semantics¶
[beginning Apple 4.0, LLVM 3.1] These exceptions have been greatly expanded; they previously applied only to a much-reduced subset which is difficult to categorize but which included null pointers, message sends (under the given rules), and the various global constants.
An unbridged conversion to a retainable object pointer type from a type other than a retainable object pointer type is ill-formed, as discussed above, unless the operand of the cast has a syntactic form which is known retained, known unretained, or known retain-agnostic.
An expression is known retain-agnostic if it is:
an Objective-C string literal,
a load from a
const
system global variable of C retainable pointer type, ora null pointer constant.
An expression is known unretained if it is an rvalue of C retainable pointer type and it is:
a direct call to a function, and either that function has the
cf_returns_not_retained
attribute or it is an audited function that does not have thecf_returns_retained
attribute and does not follow the create/copy naming convention,a message send, and the declared method either has the
cf_returns_not_retained
attribute or it has neither thecf_returns_retained
attribute nor a selector family that implies a retained result, or[beginning LLVM 3.6] a load from a
const
non-system global variable.
An expression is known retained if it is an rvalue of C retainable pointer type and it is:
a message send, and the declared method either has the
cf_returns_retained
attribute, or it does not have thecf_returns_not_retained
attribute but it does have a selector family that implies a retained result.
Furthermore:
a comma expression is classified according to its right-hand side,
a statement expression is classified according to its result expression, if it has one,
an lvalue-to-rvalue conversion applied to an Objective-C property lvalue is classified according to the underlying message send, and
a conditional operator is classified according to its second and third operands, if they agree in classification, or else the other if one is known retain-agnostic.
If the cast operand is known retained, the conversion is treated as a
__bridge_transfer
cast. If the cast operand is known unretained or known
retain-agnostic, the conversion is treated as a __bridge
cast.
Rationale
Bridging casts are annoying. Absent the ability to completely automate the management of CF objects, however, we are left with relatively poor attempts to reduce the need for a glut of explicit bridges. Hence these rules.
We’ve so far consciously refrained from implicitly turning retained CF
results from function calls into __bridge_transfer
casts. The worry is
that some code patterns — for example, creating a CF value, assigning it
to an ObjC-typed local, and then calling CFRelease
when done — are a
bit too likely to be accidentally accepted, leading to mysterious behavior.
For loads from const
global variables of C retainable pointer type, it is reasonable to assume that global system
constants were initialitzed with true constants (e.g. string literals), but
user constants might have been initialized with something dynamically
allocated, using a global initializer.
Conversion from retainable object pointer type in certain contexts¶
[beginning Apple 4.0, LLVM 3.1]
If an expression of retainable object pointer type is explicitly cast to a C retainable pointer type, the program is ill-formed as discussed above unless the result is immediately used:
to initialize a parameter in an Objective-C message send where the parameter is not marked with the
cf_consumed
attribute, orto initialize a parameter in a direct call to an audited function where the parameter is not marked with the
cf_consumed
attribute.
Rationale
Consumed parameters are left out because ARC would naturally balance them
with a retain, which was judged too treacherous. This is in part because
several of the most common consuming functions are in the Release
family,
and it would be quite unfortunate for explicit releases to be silently
balanced out in this way.
Ownership qualification¶
This section describes the behavior of objects of retainable object pointer type; that is, locations in memory which store retainable object pointers.
A type is a retainable object owner type if it is a retainable object pointer type or an array type whose element type is a retainable object owner type.
An ownership qualifier is a type qualifier which applies only to retainable object owner types. An array type is ownership-qualified according to its element type, and adding an ownership qualifier to an array type so qualifies its element type.
A program is ill-formed if it attempts to apply an ownership qualifier to a type which is already ownership-qualified, even if it is the same qualifier. There is a single exception to this rule: an ownership qualifier may be applied to a substituted template type parameter, which overrides the ownership qualifier provided by the template argument.
When forming a function type, the result type is adjusted so that any top-level ownership qualifier is deleted.
Except as described under the inference rules, a program is ill-formed if it attempts to form a pointer or reference type to a retainable object owner type which lacks an ownership qualifier.
Rationale
These rules, together with the inference rules, ensure that all objects and lvalues of retainable object pointer type have an ownership qualifier. The ability to override an ownership qualifier during template substitution is required to counteract the inference of __strong for template type arguments. Ownership qualifiers on return types are dropped because they serve no purpose there except to cause spurious problems with overloading and templates.
There are four ownership qualifiers:
__autoreleasing
__strong
__unsafe_unretained
__weak
A type is nontrivially ownership-qualified if it is qualified with
__autoreleasing
, __strong
, or __weak
.
Spelling¶
The names of the ownership qualifiers are reserved for the implementation. A program may not assume that they are or are not implemented with macros, or what those macros expand to.
An ownership qualifier may be written anywhere that any other type qualifier may be written.
If an ownership qualifier appears in the declaration-specifiers, the following rules apply:
if the type specifier is a retainable object owner type, the qualifier initially applies to that type;
otherwise, if the outermost non-array declarator is a pointer or block pointer declarator, the qualifier initially applies to that type;
otherwise the program is ill-formed.
If the qualifier is so applied at a position in the declaration where the next-innermost declarator is a function declarator, and there is an block declarator within that function declarator, then the qualifier applies instead to that block declarator and this rule is considered afresh beginning from the new position.
If an ownership qualifier appears on the declarator name, or on the declared object, it is applied to the innermost pointer or block-pointer type.
If an ownership qualifier appears anywhere else in a declarator, it applies to the type there.
Rationale
Ownership qualifiers are like const
and volatile
in the sense
that they may sensibly apply at multiple distinct positions within a
declarator. However, unlike those qualifiers, there are many
situations where they are not meaningful, and so we make an effort
to “move” the qualifier to a place where it will be meaningful. The
general goal is to allow the programmer to write, say, __strong
before the entire declaration and have it apply in the leftmost
sensible place.
Property declarations¶
A property of retainable object pointer type may have ownership. If the
property’s type is ownership-qualified, then the property has that ownership.
If the property has one of the following modifiers, then the property has the
corresponding ownership. A property is ill-formed if it has conflicting
sources of ownership, or if it has redundant ownership modifiers, or if it has
__autoreleasing
ownership.
assign
implies__unsafe_unretained
ownership.copy
implies__strong
ownership, as well as the usual behavior of copy semantics on the setter.retain
implies__strong
ownership.strong
implies__strong
ownership.unsafe_unretained
implies__unsafe_unretained
ownership.weak
implies__weak
ownership.
With the exception of weak
, these modifiers are available in non-ARC
modes.
A property’s specified ownership is preserved in its metadata, but otherwise
the meaning is purely conventional unless the property is synthesized. If a
property is synthesized, then the associated instance variable is
the instance variable which is named, possibly implicitly, by the
@synthesize
declaration. If the associated instance variable already
exists, then its ownership qualification must equal the ownership of the
property; otherwise, the instance variable is created with that ownership
qualification.
A property of retainable object pointer type which is synthesized without a
source of ownership has the ownership of its associated instance variable, if it
already exists; otherwise, [beginning Apple 3.1, LLVM 3.1]
its ownership is implicitly strong
. Prior to this revision, it
was ill-formed to synthesize such a property.
Rationale
Using strong
by default is safe and consistent with the generic ARC rule
about inferring ownership. It is,
unfortunately, inconsistent with the non-ARC rule which states that such
properties are implicitly assign
. However, that rule is clearly
untenable in ARC, since it leads to default-unsafe code. The main merit to
banning the properties is to avoid confusion with non-ARC practice, which did
not ultimately strike us as sufficient to justify requiring extra syntax and
(more importantly) forcing novices to understand ownership rules just to
declare a property when the default is so reasonable. Changing the rule away
from non-ARC practice was acceptable because we had conservatively banned the
synthesis in order to give ourselves exactly this leeway.
Applying __attribute__((NSObject))
to a property not of retainable object
pointer type has the same behavior it does outside of ARC: it requires the
property type to be some sort of pointer and permits the use of modifiers other
than assign
. These modifiers only affect the synthesized getter and
setter; direct accesses to the ivar (even if synthesized) still have primitive
semantics, and the value in the ivar will not be automatically released during
deallocation.
Semantics¶
There are five managed operations which may be performed on an object of retainable object pointer type. Each qualifier specifies different semantics for each of these operations. It is still undefined behavior to access an object outside of its lifetime.
A load or store with “primitive semantics” has the same semantics as the
respective operation would have on an void*
lvalue with the same alignment
and non-ownership qualification.
Reading occurs when performing a lvalue-to-rvalue conversion on an object lvalue.
For
__weak
objects, the current pointee is retained and then released at the end of the current full-expression. This must execute atomically with respect to assignments and to the final release of the pointee.For all other objects, the lvalue is loaded with primitive semantics.
Assignment occurs when evaluating an assignment operator. The semantics vary based on the qualification:
For
__strong
objects, the new pointee is first retained; second, the lvalue is loaded with primitive semantics; third, the new pointee is stored into the lvalue with primitive semantics; and finally, the old pointee is released. This is not performed atomically; external synchronization must be used to make this safe in the face of concurrent loads and stores.For
__weak
objects, the lvalue is updated to point to the new pointee, unless the new pointee is an object currently undergoing deallocation, in which case the lvalue is updated to a null pointer. This must execute atomically with respect to other assignments to the object, to reads from the object, and to the final release of the new pointee.For
__unsafe_unretained
objects, the new pointee is stored into the lvalue using primitive semantics.For
__autoreleasing
objects, the new pointee is retained, autoreleased, and stored into the lvalue using primitive semantics.
Initialization occurs when an object’s lifetime begins, which depends on its storage duration. Initialization proceeds in two stages:
First, a null pointer is stored into the lvalue using primitive semantics. This step is skipped if the object is
__unsafe_unretained
.Second, if the object has an initializer, that expression is evaluated and then assigned into the object using the usual assignment semantics.
Destruction occurs when an object’s lifetime ends. In all cases it is semantically equivalent to assigning a null pointer to the object, with the proviso that of course the object cannot be legally read after the object’s lifetime ends.
Moving occurs in specific situations where an lvalue is “moved
from”, meaning that its current pointee will be used but the object may be left
in a different (but still valid) state. This arises with __block
variables
and rvalue references in C++. For __strong
lvalues, moving is equivalent
to loading the lvalue with primitive semantics, writing a null pointer to it
with primitive semantics, and then releasing the result of the load at the end
of the current full-expression. For all other lvalues, moving is equivalent to
reading the object.
Restrictions¶
Storage duration of __autoreleasing
objects¶
A program is ill-formed if it declares an __autoreleasing
object of
non-automatic storage duration. A program is ill-formed if it captures an
__autoreleasing
object in a block or, unless by reference, in a C++11
lambda.
Rationale
Autorelease pools are tied to the current thread and scope by their nature. While it is possible to have temporary objects whose instance variables are filled with autoreleased objects, there is no way that ARC can provide any sort of safety guarantee there.
It is undefined behavior if a non-null pointer is assigned to an
__autoreleasing
object while an autorelease pool is in scope and then that
object is read after the autorelease pool’s scope is left.
Conversion of pointers to ownership-qualified types¶
A program is ill-formed if an expression of type T*
is converted,
explicitly or implicitly, to the type U*
, where T
and U
have
different ownership qualification, unless:
T
is qualified with__strong
,__autoreleasing
, or__unsafe_unretained
, andU
is qualified with bothconst
and__unsafe_unretained
; oreither
T
orU
iscv void
, wherecv
is an optional sequence of non-ownership qualifiers; orthe conversion is requested with a
reinterpret_cast
in Objective-C++; orthe conversion is a well-formed pass-by-writeback.
The analogous rule applies to T&
and U&
in Objective-C++.
Rationale
These rules provide a reasonable level of type-safety for indirect pointers,
as long as the underlying memory is not deallocated. The conversion to
const __unsafe_unretained
is permitted because the semantics of reads are
equivalent across all these ownership semantics, and that’s a very useful and
common pattern. The interconversion with void*
is useful for allocating
memory or otherwise escaping the type system, but use it carefully.
reinterpret_cast
is considered to be an obvious enough sign of taking
responsibility for any problems.
It is undefined behavior to access an ownership-qualified object through an
lvalue of a differently-qualified type, except that any non-__weak
object
may be read through an __unsafe_unretained
lvalue.
It is undefined behavior if the storage of a __strong
or __weak
object is not properly initialized before the first managed operation
is performed on the object, or if the storage of such an object is freed
or reused before the object has been properly deinitialized. Storage for
a __strong
or __weak
object may be properly initialized by filling
it with the representation of a null pointer, e.g. by acquiring the memory
with calloc
or using bzero
to zero it out. A __strong
or
__weak
object may be properly deinitialized by assigning a null pointer
into it. A __strong
object may also be properly initialized
by copying into it (e.g. with memcpy
) the representation of a
different __strong
object whose storage has been properly initialized;
doing this properly deinitializes the source object and causes its storage
to no longer be properly initialized. A __weak
object may not be
representation-copied in this way.
These requirements are followed automatically for objects whose initialization and deinitialization are under the control of ARC:
objects of static, automatic, and temporary storage duration
instance variables of Objective-C objects
elements of arrays where the array object’s initialization and deinitialization are under the control of ARC
fields of Objective-C struct types where the struct object’s initialization and deinitialization are under the control of ARC
non-static data members of Objective-C++ non-union class types
Objective-C++ objects and arrays of dynamic storage duration created with the
new
ornew[]
operators and destroyed with the correspondingdelete
ordelete[]
operator
They are not followed automatically for these objects:
objects of dynamic storage duration created in other memory, such as that returned by
malloc
union members
Rationale
ARC must perform special operations when initializing an object and when destroying it. In many common situations, ARC knows when an object is created and when it is destroyed and can ensure that these operations are performed correctly. Otherwise, however, ARC requires programmer cooperation to establish its initialization invariants because it is infeasible for ARC to dynamically infer whether they are intact. For example, there is no syntactic difference in C between an assignment that is intended by the programmer to initialize a variable and one that is intended to replace the existing value stored there, but ARC must perform one operation or the other. ARC chooses to always assume that objects are initialized (except when it is in charge of initializing them) because the only workable alternative would be to ban all code patterns that could potentially be used to access uninitialized memory, and that would be too limiting. In practice, this is rarely a problem because programmers do not generally need to work with objects for which the requirements are not handled automatically.
Note that dynamically-allocated Objective-C++ arrays of
nontrivially-ownership-qualified type are not ABI-compatible with non-ARC
code because the non-ARC code will consider the element type to be POD.
Such arrays that are new[]
’d in ARC translation units cannot be
delete[]
’d in non-ARC translation units and vice-versa.
Passing to an out parameter by writeback¶
If the argument passed to a parameter of type T __autoreleasing *
has type
U oq *
, where oq
is an ownership qualifier, then the argument is a
candidate for pass-by-writeback` if:
oq
is__strong
or__weak
, andit would be legal to initialize a
T __strong *
with aU __strong *
.
For purposes of overload resolution, an implicit conversion sequence requiring a pass-by-writeback is always worse than an implicit conversion sequence not requiring a pass-by-writeback.
The pass-by-writeback is ill-formed if the argument expression does not have a legal form:
&var
, wherevar
is a scalar variable of automatic storage duration with retainable object pointer typea conditional expression where the second and third operands are both legal forms
a cast whose operand is a legal form
a null pointer constant
Rationale
The restriction in the form of the argument serves two purposes. First, it makes it impossible to pass the address of an array to the argument, which serves to protect against an otherwise serious risk of mis-inferring an “array” argument as an out-parameter. Second, it makes it much less likely that the user will see confusing aliasing problems due to the implementation, below, where their store to the writeback temporary is not immediately seen in the original argument variable.
A pass-by-writeback is evaluated as follows:
The argument is evaluated to yield a pointer
p
of typeU oq *
.If
p
is a null pointer, then a null pointer is passed as the argument, and no further work is required for the pass-by-writeback.Otherwise, a temporary of type
T __autoreleasing
is created and initialized to a null pointer.If the parameter is not an Objective-C method parameter marked
out
, then*p
is read, and the result is written into the temporary with primitive semantics.The address of the temporary is passed as the argument to the actual call.
After the call completes, the temporary is loaded with primitive semantics, and that value is assigned into
*p
.
Rationale
This is all admittedly convoluted. In an ideal world, we would see that a
local variable is being passed to an out-parameter and retroactively modify
its type to be __autoreleasing
rather than __strong
. This would be
remarkably difficult and not always well-founded under the C type system.
However, it was judged unacceptably invasive to require programmers to write
__autoreleasing
on all the variables they intend to use for
out-parameters. This was the least bad solution.
Ownership-qualified fields of structs and unions¶
A member of a struct or union may be declared to have ownership-qualified
type. If the type is qualified with __unsafe_unretained
, the semantics
of the containing aggregate are unchanged from the semantics of an unqualified type in a non-ARC mode. If the type is qualified with __autoreleasing
, the program is ill-formed. Otherwise, if the type is nontrivially ownership-qualified, additional rules apply.
Both Objective-C and Objective-C++ support nontrivially ownership-qualified fields. Due to formal differences between the standards, the formal treatment is different; however, the basic language model is intended to be the same for identical code.
Rationale
Permitting __strong
and __weak
references in aggregate types
allows programmers to take advantage of the normal language tools of
C and C++ while still automatically managing memory. While it is
usually simpler and more idiomatic to use Objective-C objects for
secondary data structures, doing so can introduce extra allocation
and message-send overhead, which can cause to unacceptable
performance. Using structs can resolve some of this tension.
__autoreleasing
is forbidden because it is treacherous to rely
on autoreleases as an ownership tool outside of a function-local
contexts.
Earlier releases of Clang permitted __strong
and __weak
only
references in Objective-C++ classes, not in Objective-C. This
restriction was an undesirable short-term constraint arising from the
complexity of adding support for non-trivial struct types to C.
In Objective-C++, nontrivially ownership-qualified types are treated for nearly all purposes as if they were class types with non-trivial default constructors, copy constructors, move constructors, copy assignment operators, move assignment operators, and destructors. This includes the determination of the triviality of special members of classes with a non-static data member of such a type.
In Objective-C, the definition cannot be so succinct: because the C standard lacks rules for non-trivial types, those rules must first be developed. They are given in the next section. The intent is that these rules are largely consistent with the rules of C++ for code expressible in both languages.
Formal rules for non-trivial types in C¶
The following are base rules which can be added to C to support implementation-defined non-trivial types.
A type in C is said to be non-trivial to copy, non-trivial to destroy, or non-trivial to default-initialize if:
it is a struct or union containing a member whose type is non-trivial to (respectively) copy, destroy, or default-initialize;
it is a qualified type whose unqualified type is non-trivial to (respectively) copy, destroy, or default-initialize (for at least the standard C qualifiers); or
it is an array type whose element type is non-trivial to (respectively) copy, destroy, or default-initialize.
A type in C is said to be illegal to copy, illegal to destroy, or illegal to default-initialize if:
it is a union which contains a member whose type is either illegal or non-trivial to (respectively) copy, destroy, or initialize;
it is a qualified type whose unqualified type is illegal to (respectively) copy, destroy, or default-initialize (for at least the standard C qualifiers); or
it is an array type whose element type is illegal to (respectively) copy, destroy, or default-initialize.
No type describable under the rules of the C standard shall be either non-trivial or illegal to copy, destroy, or default-initialize. An implementation may provide additional types which have one or more of these properties.
An expression calls for a type to be copied if it:
passes an argument of that type to a function call,
defines a function which declares a parameter of that type,
calls or defines a function which returns a value of that type,
assigns to an l-value of that type, or
converts an l-value of that type to an r-value.
A program calls for a type to be destroyed if it:
passes an argument of that type to a function call,
defines a function which declares a parameter of that type,
calls or defines a function which returns a value of that type,
creates an object of automatic storage duration of that type,
assigns to an l-value of that type, or
converts an l-value of that type to an r-value.
A program calls for a type to be default-initialized if it:
declares a variable of that type without an initializer.
An expression is ill-formed if calls for a type to be copied, destroyed, or default-initialized and that type is illegal to (respectively) copy, destroy, or default-initialize.
A program is ill-formed if it contains a function type specifier with a parameter or return type that is illegal to copy or destroy. If a function type specifier would be ill-formed for this reason except that the parameter or return type was incomplete at that point in the translation unit, the program is ill-formed but no diagnostic is required.
A goto
or switch
is ill-formed if it jumps into the scope of
an object of automatic storage duration whose type is non-trivial to
destroy.
C specifies that it is generally undefined behavior to access an l-value if there is no object of that type at that location. Implementations are often lenient about this, but non-trivial types generally require it to be enforced more strictly. The following rules apply:
The static subobjects of a type T
at a location L
are:
an object of type
T
spanning fromL
toL + sizeof(T)
;if
T
is a struct type, then for each fieldf
of that struct, the static subobjects ofT
at locationL + offsetof(T, .f)
; andif
T
is the array typeE[N]
, then for eachi
satisfying0 <= i < N
, the static subobjects ofE
at locationL + i * sizeof(E)
.
If an l-value is converted to an r-value, then all static subobjects whose types are non-trivial to copy are accessed. If an l-value is assigned to, or if an object of automatic storage duration goes out of scope, then all static subobjects of types that are non-trivial to destroy are accessed.
A dynamic object is created at a location if an initialization initializes an object of that type there. A dynamic object ceases to exist at a location if the memory is repurposed. Memory is repurposed if it is freed or if a different dynamic object is created there, for example by assigning into a different union member. An implementation may provide additional rules for what constitutes creating or destroying a dynamic object.
If an object is accessed under these rules at a location where no such dynamic object exists, the program has undefined behavior. If memory for a location is repurposed while a dynamic object that is non-trivial to destroy exists at that location, the program has undefined behavior.
Rationale
While these rules are far less fine-grained than C++, they are nonetheless sufficient to express a wide spectrum of types. Types that express some sort of ownership will generally be non-trivial to both copy and destroy and either non-trivial or illegal to default-initialize. Types that don’t express ownership may still be non-trivial to copy because of some sort of address sensitivity; for example, a relative reference. Distinguishing default initialization allows types to impose policies about how they are created.
These rules assume that assignment into an l-value is always a modification of an existing object rather than an initialization. Assignment is then a compound operation where the old value is read and destroyed, if necessary, and the new value is put into place. These are the natural semantics of value propagation, where all basic operations on the type come down to copies and destroys, and everything else is just an optimization on top of those.
The most glaring weakness of programming with non-trivial types in C
is that there are no language mechanisms (akin to C++’s placement
new
and explicit destructor calls) for explicitly creating and
destroying objects. Clang should consider adding builtins for this
purpose, as well as for common optimizations like destructive
relocation.
Application of the formal C rules to nontrivial ownership qualifiers¶
Nontrivially ownership-qualified types are considered non-trivial to copy, destroy, and default-initialize.
A dynamic object of nontrivially ownership-qualified type contingently
exists at a location if the memory is filled with a zero pattern, e.g.
by calloc
or bzero
. Such an object can be safely accessed in
all of the cases above, but its memory can also be safely repurposed.
Assigning a null pointer into an l-value of __weak
or
__strong
-qualified type accesses the dynamic object there (and thus
may have undefined behavior if no such object exists), but afterwards
the object’s memory is guaranteed to be filled with a zero pattern
and thus may be either further accessed or repurposed as needed.
The upshot is that programs may safely initialize dynamically-allocated
memory for nontrivially ownership-qualified types by ensuring it is zero-initialized, and they may safely deinitialize memory before
freeing it by storing nil
into any __strong
or __weak
references previously created in that memory.
C/C++ compatibility for structs and unions with non-trivial members¶
Structs and unions with non-trivial members are compatible in different language modes (e.g. between Objective-C and Objective-C++, or between ARC and non-ARC modes) under the following conditions:
The types must be compatible ignoring ownership qualifiers according to the baseline, non-ARC rules (e.g. C struct compatibility or C++’s ODR). This condition implies a pairwise correspondance between fields.
Note that an Objective-C++ class with base classes, a user-provided copy or move constructor, or a user-provided destructor is never compatible with an Objective-C type.
If two fields correspond as above, and at least one of the fields is ownership-qualified, then:
the fields must be identically qualified, or else
one type must be unqualified (and thus declared in a non-ARC mode), and the other type must be qualified with
__unsafe_unretained
or__strong
.
Note that
__weak
fields must always be declared__weak
because of the need to pin those fields in memory and keep them properly registered with the Objective-C runtime. Non-ARC modes may still declare fields__weak
by enabling-fobjc-weak
.
These compatibility rules permit a function that takes a parameter
of non-trivial struct type to be written in ARC and called from
non-ARC or vice-versa. The convention for this always transfers
ownership of objects stored in __strong
fields from the caller
to the callee, just as for an ns_consumed
argument. Therefore,
non-ARC callers must ensure that such fields are initialized to a +1
reference, and non-ARC callees must balance that +1 by releasing the
reference or transferring it as appropriate.
Likewise, a function returning a non-trivial struct may be written in
ARC and called from non-ARC or vice-versa. The convention for this
always transfers ownership of objects stored in __strong
fields
from the callee to the caller, and so callees must initialize such
fields with +1 references, and callers must balance that +1 by releasing
or transferring them.
Similar transfers of responsibility occur for __weak
fields, but
since both sides must use native __weak
support to ensure
calling convention compatibililty, this transfer is always handled
automatically by the compiler.
Rationale
In earlier releases, when non-trivial ownership was only permitted on fields in Objective-C++, the ABI used for such classees was the ordinary ABI for non-trivial C++ classes, which passes arguments and returns indirectly and does not transfer responsibility for arguments. When support for Objective-C structs was added, it was decided to change to the current ABI for three reasons:
It permits ARC / non-ARC compatibility for structs containing only
__strong
references, as long as the non-ARC side is careful about transferring ownership.It avoids unnecessary indirection for sufficiently small types that the C ABI would prefer to pass in registers.
Given that struct arguments must be produced at +1 to satisfy C’s semantics of initializing the local parameter variable, transferring ownership of that copy to the callee is generally better for ARC optimization, since otherwise there will be releases in the caller that are much harder to pair with transfers in the callee.
Breaking compatibility with existing Objective-C++ structures was considered an acceptable cost, as most Objective-C++ code does not have binary-compatibility requirements. Any existing code which cannot accept this compatibility break, which is necessarily Objective-C++, should force the use of the standard C++ ABI by declaring an empty (but non-defaulted) destructor.
Ownership inference¶
Objects¶
If an object is declared with retainable object owner type, but without an
explicit ownership qualifier, its type is implicitly adjusted to have
__strong
qualification.
As a special case, if the object’s base type is Class
(possibly
protocol-qualified), the type is adjusted to have __unsafe_unretained
qualification instead.
Indirect parameters¶
If a function or method parameter has type T*
, where T
is an
ownership-unqualified retainable object pointer type, then:
if
T
isconst
-qualified orClass
, then it is implicitly qualified with__unsafe_unretained
;otherwise, it is implicitly qualified with
__autoreleasing
.
Rationale
__autoreleasing
exists mostly for this case, the Cocoa convention for
out-parameters. Since a pointer to const
is obviously not an
out-parameter, we instead use a type more useful for passing arrays. If the
user instead intends to pass in a mutable array, inferring
__autoreleasing
is the wrong thing to do; this directs some of the
caution in the following rules about writeback.
Such a type written anywhere else would be ill-formed by the general rule requiring ownership qualifiers.
This rule does not apply in Objective-C++ if a parameter’s type is dependent in a template pattern and is only instantiated to a type which would be a pointer to an unqualified retainable object pointer type. Such code is still ill-formed.
Rationale
The convention is very unlikely to be intentional in template code.
Template arguments¶
If a template argument for a template type parameter is an retainable object
owner type that does not have an explicit ownership qualifier, it is adjusted
to have __strong
qualification. This adjustment occurs regardless of
whether the template argument was deduced or explicitly specified.
Rationale
__strong
is a useful default for containers (e.g., std::vector<id>
),
which would otherwise require explicit qualification. Moreover, unqualified
retainable object pointer types are unlikely to be useful within templates,
since they generally need to have a qualifier applied to the before being
used.
Method families¶
An Objective-C method may fall into a method family, which is a conventional set of behaviors ascribed to it by the Cocoa conventions.
A method is in a certain method family if:
it has a
objc_method_family
attribute placing it in that family; or if not that,it does not have an
objc_method_family
attribute placing it in a different or no family, andits selector falls into the corresponding selector family, and
its signature obeys the added restrictions of the method family.
A selector is in a certain selector family if, ignoring any leading
underscores, the first component of the selector either consists entirely of
the name of the method family or it begins with that name followed by a
character other than a lowercase letter. For example, _perform:with:
and
performWith:
would fall into the perform
family (if we recognized one),
but performing:with
would not.
The families and their added restrictions are:
alloc
methods must return a retainable object pointer type.copy
methods must return a retainable object pointer type.mutableCopy
methods must return a retainable object pointer type.new
methods must return a retainable object pointer type.init
methods must be instance methods and must return an Objective-C pointer type. Additionally, a program is ill-formed if it declares or contains a call to aninit
method whose return type is neitherid
nor a pointer to a super-class or sub-class of the declaring class (if the method was declared on a class) or the static receiver type of the call (if it was declared on a protocol).Rationale
There are a fair number of existing methods with
init
-like selectors which nonetheless don’t follow theinit
conventions. Typically these are either accidental naming collisions or helper methods called during initialization. Because of the peculiar retain/release behavior ofinit
methods, it’s very important not to treat these methods asinit
methods if they aren’t meant to be. It was felt that implicitly defining these methods out of the family based on the exact relationship between the return type and the declaring class would be much too subtle and fragile. Therefore we identify a small number of legitimate-seeming return types and call everything else an error. This serves the secondary purpose of encouraging programmers not to accidentally give methods names in theinit
family.Note that a method with an
init
-family selector which returns a non-Objective-C type (e.g.void
) is perfectly well-formed; it simply isn’t in theinit
family.
A program is ill-formed if a method’s declarations, implementations, and overrides do not all have the same method family.
Explicit method family control¶
A method may be annotated with the objc_method_family
attribute to
precisely control which method family it belongs to. If a method in an
@implementation
does not have this attribute, but there is a method
declared in the corresponding @interface
that does, then the attribute is
copied to the declaration in the @implementation
. The attribute is
available outside of ARC, and may be tested for with the preprocessor query
__has_attribute(objc_method_family)
.
The attribute is spelled
__attribute__((objc_method_family(
family )))
. If family is
none
, the method has no family, even if it would otherwise be considered to
have one based on its selector and type. Otherwise, family must be one of
alloc
, copy
, init
, mutableCopy
, or new
, in which case the
method is considered to belong to the corresponding family regardless of its
selector. It is an error if a method that is explicitly added to a family in
this way does not meet the requirements of the family other than the selector
naming convention.
Rationale
The rules codified in this document describe the standard conventions of
Objective-C. However, as these conventions have not heretofore been enforced
by an unforgiving mechanical system, they are only imperfectly kept,
especially as they haven’t always even been precisely defined. While it is
possible to define low-level ownership semantics with attributes like
ns_returns_retained
, this attribute allows the user to communicate
semantic intent, which is of use both to ARC (which, e.g., treats calls to
init
specially) and the static analyzer.
Semantics of method families¶
A method’s membership in a method family may imply non-standard semantics for its parameters and return type.
Methods in the alloc
, copy
, mutableCopy
, and new
families —
that is, methods in all the currently-defined families except init
—
implicitly return a retained object as if they were annotated with
the ns_returns_retained
attribute. This can be overridden by annotating
the method with either of the ns_returns_autoreleased
or
ns_returns_not_retained
attributes.
Properties also follow same naming rules as methods. This means that those in
the alloc
, copy
, mutableCopy
, and new
families provide access
to retained objects. This
can be overridden by annotating the property with ns_returns_not_retained
attribute.
Semantics of init
¶
Methods in the init
family implicitly consume their self
parameter and return a
retained object. Neither of
these properties can be altered through attributes.
A call to an init
method with a receiver that is either self
(possibly
parenthesized or casted) or super
is called a delegate init
call. It is an error for a delegate init call to be made except from an
init
method, and excluding blocks within such methods.
As an exception to the usual rule, the variable self
is mutable in an init
method and has the usual semantics for a __strong
variable. However, it is undefined behavior and the program is ill-formed, no
diagnostic required, if an init
method attempts to use the previous value
of self
after the completion of a delegate init call. It is conventional,
but not required, for an init
method to return self
.
It is undefined behavior for a program to cause two or more calls to init
methods on the same object, except that each init
method invocation may
perform at most one delegate init call.
Optimization¶
Within this section, the word function will be used to refer to any structured unit of code, be it a C function, an Objective-C method, or a block.
This specification describes ARC as performing specific retain
and
release
operations on retainable object pointers at specific
points during the execution of a program. These operations make up a
non-contiguous subsequence of the computation history of the program.
The portion of this sequence for a particular retainable object
pointer for which a specific function execution is directly
responsible is the formal local retain history of the
object pointer. The corresponding actual sequence executed is the
dynamic local retain history.
However, under certain circumstances, ARC is permitted to re-order and
eliminate operations in a manner which may alter the overall
computation history beyond what is permitted by the general “as if”
rule of C/C++ and the restrictions on
the implementation of retain
and release
.
Rationale
Specifically, ARC is sometimes permitted to optimize release
operations in ways which might cause an object to be deallocated
before it would otherwise be. Without this, it would be almost
impossible to eliminate any retain
/release
pairs. For
example, consider the following code:
id x = _ivar;
[x foo];
If we were not permitted in any event to shorten the lifetime of the
object in x
, then we would not be able to eliminate this retain
and release unless we could prove that the message send could not
modify _ivar
(or deallocate self
). Since message sends are
opaque to the optimizer, this is not possible, and so ARC’s hands
would be almost completely tied.
ARC makes no guarantees about the execution of a computation history which contains undefined behavior. In particular, ARC makes no guarantees in the presence of race conditions.
ARC may assume that any retainable object pointers it receives or generates are instantaneously valid from that point until a point which, by the concurrency model of the host language, happens-after the generation of the pointer and happens-before a release of that object (possibly via an aliasing pointer or indirectly due to destruction of a different object).
Rationale
There is very little point in trying to guarantee correctness in the presence of race conditions. ARC does not have a stack-scanning garbage collector, and guaranteeing the atomicity of every load and store operation would be prohibitive and preclude a vast amount of optimization.
ARC may assume that non-ARC code engages in sensible balancing
behavior and does not rely on exact or minimum retain count values
except as guaranteed by __strong
object invariants or +1 transfer
conventions. For example, if an object is provably double-retained
and double-released, ARC may eliminate the inner retain and release;
it does not need to guard against code which performs an unbalanced
release followed by a “balancing” retain.
Object liveness¶
ARC may not allow a retainable object X
to be deallocated at a
time T
in a computation history if:
X
is the value stored in a__strong
objectS
with precise lifetime semantics, orX
is the value stored in a__strong
objectS
with imprecise lifetime semantics and, at some point afterT
but before the next store toS
, the computation history features a load fromS
and in some way depends on the value loaded, orX
is a value described as being released at the end of the current full-expression and, at some point afterT
but before the end of the full-expression, the computation history depends on that value.
Rationale
The intent of the second rule is to say that objects held in normal
__strong
local variables may be released as soon as the value in
the variable is no longer being used: either the variable stops
being used completely or a new value is stored in the variable.
The intent of the third rule is to say that return values may be released after they’ve been used.
A computation history depends on a pointer value P
if it:
performs a pointer comparison with
P
,loads from
P
,stores to
P
,depends on a pointer value
Q
derived via pointer arithmetic fromP
(including an instance-variable or field access), ordepends on a pointer value
Q
loaded fromP
.
Dependency applies only to values derived directly or indirectly from
a particular expression result and does not occur merely because a
separate pointer value dynamically aliases P
. Furthermore, this
dependency is not carried by values that are stored to objects.
Rationale
The restrictions on dependency are intended to make this analysis feasible by an optimizer with only incomplete information about a program. Essentially, dependence is carried to “obvious” uses of a pointer. Merely passing a pointer argument to a function does not itself cause dependence, but since generally the optimizer will not be able to prove that the function doesn’t depend on that parameter, it will be forced to conservatively assume it does.
Dependency propagates to values loaded from a pointer because those
values might be invalidated by deallocating the object. For
example, given the code __strong id x = p->ivar;
, ARC must not
move the release of p
to between the load of p->ivar
and the
retain of that value for storing into x
.
Dependency does not propagate through stores of dependent pointer values because doing so would allow dependency to outlive the full-expression which produced the original value. For example, the address of an instance variable could be written to some global location and then freely accessed during the lifetime of the local, or a function could return an inner pointer of an object and store it to a local. These cases would be potentially impossible to reason about and so would basically prevent any optimizations based on imprecise lifetime. There are also uncommon enough to make it reasonable to require the precise-lifetime annotation if someone really wants to rely on them.
Dependency does propagate through return values of pointer type. The compelling source of need for this rule is a property accessor which returns an un-autoreleased result; the calling function must have the chance to operate on the value, e.g. to retain it, before ARC releases the original pointer. Note again, however, that dependence does not survive a store, so ARC does not guarantee the continued validity of the return value past the end of the full-expression.
No object lifetime extension¶
If, in the formal computation history of the program, an object X
has been deallocated by the time of an observable side-effect, then
ARC must cause X
to be deallocated by no later than the occurrence
of that side-effect, except as influenced by the re-ordering of the
destruction of objects.
Rationale
This rule is intended to prohibit ARC from observably extending the lifetime of a retainable object, other than as specified in this document. Together with the rule limiting the transformation of releases, this rule requires ARC to eliminate retains and release only in pairs.
ARC’s power to reorder the destruction of objects is critical to its ability to do any optimization, for essentially the same reason that it must retain the power to decrease the lifetime of an object. Unfortunately, while it’s generally poor style for the destruction of objects to have arbitrary side-effects, it’s certainly possible. Hence the caveat.
Precise lifetime semantics¶
In general, ARC maintains an invariant that a retainable object pointer held in
a __strong
object will be retained for the full formal lifetime of the
object. Objects subject to this invariant have precise lifetime
semantics.
By default, local variables of automatic storage duration do not have precise lifetime semantics. Such objects are simply strong references which hold values of retainable object pointer type, and these values are still fully subject to the optimizations on values under local control.
Rationale
Applying these precise-lifetime semantics strictly would be prohibitive. Many useful optimizations that might theoretically decrease the lifetime of an object would be rendered impossible. Essentially, it promises too much.
A local variable of retainable object owner type and automatic storage duration
may be annotated with the objc_precise_lifetime
attribute to indicate that
it should be considered to be an object with precise lifetime semantics.
Rationale
Nonetheless, it is sometimes useful to be able to force an object to be released at a precise time, even if that object does not appear to be used. This is likely to be uncommon enough that the syntactic weight of explicitly requesting these semantics will not be burdensome, and may even make the code clearer.
Miscellaneous¶
Special methods¶
Memory management methods¶
A program is ill-formed if it contains a method definition, message send, or
@selector
expression for any of the following selectors:
autorelease
release
retain
retainCount
Rationale
retainCount
is banned because ARC robs it of consistent semantics. The
others were banned after weighing three options for how to deal with message
sends:
Honoring them would work out very poorly if a programmer naively or accidentally tried to incorporate code written for manual retain/release code into an ARC program. At best, such code would do twice as much work as necessary; quite frequently, however, ARC and the explicit code would both try to balance the same retain, leading to crashes. The cost is losing the ability to perform “unrooted” retains, i.e. retains not logically corresponding to a strong reference in the object graph.
Ignoring them would badly violate user expectations about their code. While it would make it easier to develop code simultaneously for ARC and non-ARC, there is very little reason to do so except for certain library developers. ARC and non-ARC translation units share an execution model and can seamlessly interoperate. Within a translation unit, a developer who faithfully maintains their code in non-ARC mode is suffering all the restrictions of ARC for zero benefit, while a developer who isn’t testing the non-ARC mode is likely to be unpleasantly surprised if they try to go back to it.
Banning them has the disadvantage of making it very awkward to migrate existing code to ARC. The best answer to that, given a number of other changes and restrictions in ARC, is to provide a specialized tool to assist users in that migration.
Implementing these methods was banned because they are too integral to the semantics of ARC; many tricks which worked tolerably under manual reference counting will misbehave if ARC performs an ephemeral extra retain or two. If absolutely required, it is still possible to implement them in non-ARC code, for example in a category; the implementations must obey the semantics laid out elsewhere in this document.
dealloc
¶
A program is ill-formed if it contains a message send or @selector
expression for the selector dealloc
.
Rationale
There are no legitimate reasons to call dealloc
directly.
A class may provide a method definition for an instance method named
dealloc
. This method will be called after the final release
of the
object but before it is deallocated or any of its instance variables are
destroyed. The superclass’s implementation of dealloc
will be called
automatically when the method returns.
Rationale
Even though ARC destroys instance variables automatically, there are still
legitimate reasons to write a dealloc
method, such as freeing
non-retainable resources. Failing to call [super dealloc]
in such a
method is nearly always a bug. Sometimes, the object is simply trying to
prevent itself from being destroyed, but dealloc
is really far too late
for the object to be raising such objections. Somewhat more legitimately, an
object may have been pool-allocated and should not be deallocated with
free
; for now, this can only be supported with a dealloc
implementation outside of ARC. Such an implementation must be very careful
to do all the other work that NSObject
’s dealloc
would, which is
outside the scope of this document to describe.
The instance variables for an ARC-compiled class will be destroyed at some
point after control enters the dealloc
method for the root class of the
class. The ordering of the destruction of instance variables is unspecified,
both within a single class and between subclasses and superclasses.
Rationale
The traditional, non-ARC pattern for destroying instance variables is to
destroy them immediately before calling [super dealloc]
. Unfortunately,
message sends from the superclass are quite capable of reaching methods in
the subclass, and those methods may well read or write to those instance
variables. Making such message sends from dealloc is generally discouraged,
since the subclass may well rely on other invariants that were broken during
dealloc
, but it’s not so inescapably dangerous that we felt comfortable
calling it undefined behavior. Therefore we chose to delay destroying the
instance variables to a point at which message sends are clearly disallowed:
the point at which the root class’s deallocation routines take over.
In most code, the difference is not observable. It can, however, be observed
if an instance variable holds a strong reference to an object whose
deallocation will trigger a side-effect which must be carefully ordered with
respect to the destruction of the super class. Such code violates the design
principle that semantically important behavior should be explicit. A simple
fix is to clear the instance variable manually during dealloc
; a more
holistic solution is to move semantically important side-effects out of
dealloc
and into a separate teardown phase which can rely on working with
well-formed objects.
@autoreleasepool
¶
To simplify the use of autorelease pools, and to bring them under the control
of the compiler, a new kind of statement is available in Objective-C. It is
written @autoreleasepool
followed by a compound-statement, i.e. by a new
scope delimited by curly braces. Upon entry to this block, the current state
of the autorelease pool is captured. When the block is exited normally,
whether by fallthrough or directed control flow (such as return
or
break
), the autorelease pool is restored to the saved state, releasing all
the objects in it. When the block is exited with an exception, the pool is not
drained.
@autoreleasepool
may be used in non-ARC translation units, with equivalent
semantics.
A program is ill-formed if it refers to the NSAutoreleasePool
class.
Rationale
Autorelease pools are clearly important for the compiler to reason about, but it is far too much to expect the compiler to accurately reason about control dependencies between two calls. It is also very easy to accidentally forget to drain an autorelease pool when using the manual API, and this can significantly inflate the process’s high-water-mark. The introduction of a new scope is unfortunate but basically required for sane interaction with the rest of the language. Not draining the pool during an unwind is apparently required by the Objective-C exceptions implementation.
Externally-Retained Variables¶
In some situations, variables with strong ownership are considered
externally-retained by the implementation. This means that the variable is
retained elsewhere, and therefore the implementation can elide retaining and
releasing its value. Such a variable is implicitly const
for safety. In
contrast with __unsafe_unretained
, an externally-retained variable still
behaves as a strong variable outside of initialization and destruction. For
instance, when an externally-retained variable is captured in a block the value
of the variable is retained and released on block capture and destruction. It
also affects C++ features such as lambda capture, decltype
, and template
argument deduction.
Implicitly, the implementation assumes that the self parameter in a non-init method and the variable in a for-in loop are externally-retained.
Externally-retained semantics can also be opted into with the
objc_externally_retained
attribute. This attribute can apply to strong local
variables, functions, methods, or blocks:
@class WobbleAmount;
@interface Widget : NSObject
-(void)wobble:(WobbleAmount *)amount;
@end
@implementation Widget
-(void)wobble:(WobbleAmount *)amount
__attribute__((objc_externally_retained)) {
// 'amount' and 'alias' aren't retained on entry, nor released on exit.
__attribute__((objc_externally_retained)) WobbleAmount *alias = amount;
}
@end
Annotating a function with this attribute makes every parameter with strong
retainable object pointer type externally-retained, unless the variable was
explicitly qualified with __strong
. For instance, first_param
is
externally-retained (and therefore const
) below, but not second_param
:
__attribute__((objc_externally_retained))
void f(NSArray *first_param, __strong NSArray *second_param) {
// ...
}
You can test if your compiler has support for objc_externally_retained
with
__has_attribute
:
#if __has_attribute(objc_externally_retained)
// Use externally retained...
#endif
self
¶
The self
parameter variable of an non-init Objective-C method is considered
externally-retained by the implementation.
It is undefined behavior, or at least dangerous, to cause an object to be
deallocated during a message send to that object. In an init method, self
follows the :ref:init family rules <arc.family.semantics.init>
.
Rationale
The cost of retaining self
in all methods was found to be prohibitive, as
it tends to be live across calls, preventing the optimizer from proving that
the retain and release are unnecessary — for good reason, as it’s quite
possible in theory to cause an object to be deallocated during its execution
without this retain and release. Since it’s extremely uncommon to actually
do so, even unintentionally, and since there’s no natural way for the
programmer to remove this retain/release pair otherwise (as there is for
other parameters by, say, making the variable objc_externally_retained
or
qualifying it with __unsafe_unretained
), we chose to make this optimizing
assumption and shift some amount of risk to the user.
Fast enumeration iteration variables¶
If a variable is declared in the condition of an Objective-C fast enumeration loop, and the variable has no explicit ownership qualifier, then it is implicitly externally-retained so that objects encountered during the enumeration are not actually retained and released.
Rationale
This is an optimization made possible because fast enumeration loops promise
to keep the objects retained during enumeration, and the collection itself
cannot be synchronously modified. It can be overridden by explicitly
qualifying the variable with __strong
, which will make the variable
mutable again and cause the loop to retain the objects it encounters.
Blocks¶
The implicit const
capture variables created when evaluating a block
literal expression have the same ownership semantics as the local variables
they capture. The capture is performed by reading from the captured variable
and initializing the capture variable with that value; the capture variable is
destroyed when the block literal is, i.e. at the end of the enclosing scope.
The inference rules apply equally to
__block
variables, which is a shift in semantics from non-ARC, where
__block
variables did not implicitly retain during capture.
__block
variables of retainable object owner type are moved off the stack
by initializing the heap copy with the result of moving from the stack copy.
With the exception of retains done as part of initializing a __strong
parameter variable or reading a __weak
variable, whenever these semantics
call for retaining a value of block-pointer type, it has the effect of a
Block_copy
. The optimizer may remove such copies when it sees that the
result is used only as an argument to a call.
When a block pointer type is converted to a non-block pointer type (such as
id
), Block_copy
is called. This is necessary because a block allocated
on the stack won’t get copied to the heap when the non-block pointer escapes.
A block pointer is implicitly converted to id
when it is passed to a
function as a variadic argument.
Exceptions¶
By default in Objective C, ARC is not exception-safe for normal releases:
It does not end the lifetime of
__strong
variables when their scopes are abnormally terminated by an exception.It does not perform releases which would occur at the end of a full-expression if that full-expression throws an exception.
A program may be compiled with the option -fobjc-arc-exceptions
in order to
enable these, or with the option -fno-objc-arc-exceptions
to explicitly
disable them, with the last such argument “winning”.
Rationale
The standard Cocoa convention is that exceptions signal programmer error and are not intended to be recovered from. Making code exceptions-safe by default would impose severe runtime and code size penalties on code that typically does not actually care about exceptions safety. Therefore, ARC-generated code leaks by default on exceptions, which is just fine if the process is going to be immediately terminated anyway. Programs which do care about recovering from exceptions should enable the option.
In Objective-C++, -fobjc-arc-exceptions
is enabled by default.
Rationale
C++ already introduces pervasive exceptions-cleanup code of the sort that ARC introduces. C++ programmers who have not already disabled exceptions are much more likely to actual require exception-safety.
ARC does end the lifetimes of __weak
objects when an exception terminates
their scope unless exceptions are disabled in the compiler.
Rationale
The consequence of a local __weak
object not being destroyed is very
likely to be corruption of the Objective-C runtime, so we want to be safer
here. Of course, potentially massive leaks are about as likely to take down
the process as this corruption is if the program does try to recover from
exceptions.
Interior pointers¶
An Objective-C method returning a non-retainable pointer may be annotated with
the objc_returns_inner_pointer
attribute to indicate that it returns a
handle to the internal data of an object, and that this reference will be
invalidated if the object is destroyed. When such a message is sent to an
object, the object’s lifetime will be extended until at least the earliest of:
the last use of the returned pointer, or any pointer derived from it, in the calling function or
the autorelease pool is restored to a previous state.
Rationale
Rationale: not all memory and resources are managed with reference counts; it is common for objects to manage private resources in their own, private way. Typically these resources are completely encapsulated within the object, but some classes offer their users direct access for efficiency. If ARC is not aware of methods that return such “interior” pointers, its optimizations can cause the owning object to be reclaimed too soon. This attribute informs ARC that it must tread lightly.
The extension rules are somewhat intentionally vague. The autorelease pool
limit is there to permit a simple implementation to simply retain and
autorelease the receiver. The other limit permits some amount of
optimization. The phrase “derived from” is intended to encompass the results
both of pointer transformations, such as casts and arithmetic, and of loading
from such derived pointers; furthermore, it applies whether or not such
derivations are applied directly in the calling code or by other utility code
(for example, the C library routine strchr
). However, the implementation
never need account for uses after a return from the code which calls the
method returning an interior pointer.
As an exception, no extension is required if the receiver is loaded directly
from a __strong
object with precise lifetime semantics.
Rationale
Implicit autoreleases carry the risk of significantly inflating memory use, so it’s important to provide users a way of avoiding these autoreleases. Tying this to precise lifetime semantics is ideal, as for local variables this requires a very explicit annotation, which allows ARC to trust the user with good cheer.
C retainable pointer types¶
A type is a C retainable pointer type if it is a pointer to
(possibly qualified) void
or a pointer to a (possibly qualifier) struct
or class
type.
Rationale
ARC does not manage pointers of CoreFoundation type (or any of the related families of retainable C pointers which interoperate with Objective-C for retain/release operation). In fact, ARC does not even know how to distinguish these types from arbitrary C pointer types. The intent of this concept is to filter out some obviously non-object types while leaving a hook for later tightening if a means of exhaustively marking CF types is made available.
Auditing of C retainable pointer interfaces¶
[beginning Apple 4.0, LLVM 3.1]
A C function may be marked with the cf_audited_transfer
attribute to
express that, except as otherwise marked with attributes, it obeys the
parameter (consuming vs. non-consuming) and return (retained vs. non-retained)
conventions for a C function of its name, namely:
A parameter of C retainable pointer type is assumed to not be consumed unless it is marked with the
cf_consumed
attribute, andA result of C retainable pointer type is assumed to not be returned retained unless the function is either marked
cf_returns_retained
or it follows the create/copy naming convention and is not markedcf_returns_not_retained
.
A function obeys the create/copy naming convention if its name contains as a substring:
either “Create” or “Copy” not followed by a lowercase letter, or
either “create” or “copy” not followed by a lowercase letter and not preceded by any letter, whether uppercase or lowercase.
A second attribute, cf_unknown_transfer
, signifies that a function’s
transfer semantics cannot be accurately captured using any of these
annotations. A program is ill-formed if it annotates the same function with
both cf_audited_transfer
and cf_unknown_transfer
.
A pragma is provided to facilitate the mass annotation of interfaces:
#pragma clang arc_cf_code_audited begin
...
#pragma clang arc_cf_code_audited end
All C functions declared within the extent of this pragma are treated as if
annotated with the cf_audited_transfer
attribute unless they otherwise have
the cf_unknown_transfer
attribute. The pragma is accepted in all language
modes. A program is ill-formed if it attempts to change files, whether by
including a file or ending the current file, within the extent of this pragma.
It is possible to test for all the features in this section with
__has_feature(arc_cf_code_audited)
.
Rationale
A significant inconvenience in ARC programming is the necessity of interacting with APIs based around C retainable pointers. These features are designed to make it relatively easy for API authors to quickly review and annotate their interfaces, in turn improving the fidelity of tools such as the static analyzer and ARC. The single-file restriction on the pragma is designed to eliminate the risk of accidentally annotating some other header’s interfaces.
Runtime support¶
This section describes the interaction between the ARC runtime and the code generated by the ARC compiler. This is not part of the ARC language specification; instead, it is effectively a language-specific ABI supplement, akin to the “Itanium” generic ABI for C++.
Ownership qualification does not alter the storage requirements for objects,
except that it is undefined behavior if a __weak
object is inadequately
aligned for an object of type id
. The other qualifiers may be used on
explicitly under-aligned memory.
The runtime tracks __weak
objects which holds non-null values. It is
undefined behavior to direct modify a __weak
object which is being tracked
by the runtime except through an
objc_storeWeak,
objc_destroyWeak, or
objc_moveWeak call.
The runtime must provide a number of new entrypoints which the compiler may emit, which are described in the remainder of this section.
Rationale
Several of these functions are semantically equivalent to a message send; we emit calls to C functions instead because:
the machine code to do so is significantly smaller,
it is much easier to recognize the C functions in the ARC optimizer, and
a sufficient sophisticated runtime may be able to avoid the message send in common cases.
Several other of these functions are “fused” operations which can be described entirely in terms of other operations. We use the fused operations primarily as a code-size optimization, although in some cases there is also a real potential for avoiding redundant operations in the runtime.
id objc_autorelease(id value);
¶
Precondition: value
is null or a pointer to a valid object.
If value
is null, this call has no effect. Otherwise, it adds the object
to the innermost autorelease pool exactly as if the object had been sent the
autorelease
message.
Always returns value
.
void objc_autoreleasePoolPop(void *pool);
¶
Precondition: pool
is the result of a previous call to
objc_autoreleasePoolPush on the
current thread, where neither pool
nor any enclosing pool have previously
been popped.
Releases all the objects added to the given autorelease pool and any
autorelease pools it encloses, then sets the current autorelease pool to the
pool directly enclosing pool
.
void *objc_autoreleasePoolPush(void);
¶
Creates a new autorelease pool that is enclosed by the current pool, makes that the current pool, and returns an opaque “handle” to it.
Rationale
While the interface is described as an explicit hierarchy of pools, the rules allow the implementation to just keep a stack of objects, using the stack depth as the opaque pool handle.
id objc_autoreleaseReturnValue(id value);
¶
Precondition: value
is null or a pointer to a valid object.
If value
is null, this call has no effect. Otherwise, it makes a best
effort to hand off ownership of a retain count on the object to a call to
objc_retainAutoreleasedReturnValue for the same object in an
enclosing call frame. If this is not possible, the object is autoreleased as
above.
Always returns value
.
void objc_copyWeak(id *dest, id *src);
¶
Precondition: src
is a valid pointer which either contains a null pointer
or has been registered as a __weak
object. dest
is a valid pointer
which has not been registered as a __weak
object.
dest
is initialized to be equivalent to src
, potentially registering it
with the runtime. Equivalent to the following code:
void objc_copyWeak(id *dest, id *src) {
objc_release(objc_initWeak(dest, objc_loadWeakRetained(src)));
}
Must be atomic with respect to calls to objc_storeWeak
on src
.
void objc_destroyWeak(id *object);
¶
Precondition: object
is a valid pointer which either contains a null
pointer or has been registered as a __weak
object.
object
is unregistered as a weak object, if it ever was. The current value
of object
is left unspecified; otherwise, equivalent to the following code:
void objc_destroyWeak(id *object) {
objc_storeWeak(object, nil);
}
Does not need to be atomic with respect to calls to objc_storeWeak
on
object
.
id objc_initWeak(id *object, id value);
¶
Precondition: object
is a valid pointer which has not been registered as
a __weak
object. value
is null or a pointer to a valid object.
If value
is a null pointer or the object to which it points has begun
deallocation, object
is zero-initialized. Otherwise, object
is
registered as a __weak
object pointing to value
. Equivalent to the
following code:
id objc_initWeak(id *object, id value) {
*object = nil;
return objc_storeWeak(object, value);
}
Returns the value of object
after the call.
Does not need to be atomic with respect to calls to objc_storeWeak
on
object
.
id objc_loadWeak(id *object);
¶
Precondition: object
is a valid pointer which either contains a null
pointer or has been registered as a __weak
object.
If object
is registered as a __weak
object, and the last value stored
into object
has not yet been deallocated or begun deallocation, retains and
autoreleases that value and returns it. Otherwise returns null. Equivalent to
the following code:
id objc_loadWeak(id *object) {
return objc_autorelease(objc_loadWeakRetained(object));
}
Must be atomic with respect to calls to objc_storeWeak
on object
.
Rationale
Loading weak references would be inherently prone to race conditions without the retain.
id objc_loadWeakRetained(id *object);
¶
Precondition: object
is a valid pointer which either contains a null
pointer or has been registered as a __weak
object.
If object
is registered as a __weak
object, and the last value stored
into object
has not yet been deallocated or begun deallocation, retains
that value and returns it. Otherwise returns null.
Must be atomic with respect to calls to objc_storeWeak
on object
.
void objc_moveWeak(id *dest, id *src);
¶
Precondition: src
is a valid pointer which either contains a null pointer
or has been registered as a __weak
object. dest
is a valid pointer
which has not been registered as a __weak
object.
dest
is initialized to be equivalent to src
, potentially registering it
with the runtime. src
may then be left in its original state, in which
case this call is equivalent to objc_copyWeak, or it may be left as null.
Must be atomic with respect to calls to objc_storeWeak
on src
.
void objc_release(id value);
¶
Precondition: value
is null or a pointer to a valid object.
If value
is null, this call has no effect. Otherwise, it performs a
release operation exactly as if the object had been sent the release
message.
id objc_retain(id value);
¶
Precondition: value
is null or a pointer to a valid object.
If value
is null, this call has no effect. Otherwise, it performs a retain
operation exactly as if the object had been sent the retain
message.
Always returns value
.
id objc_retainAutorelease(id value);
¶
Precondition: value
is null or a pointer to a valid object.
If value
is null, this call has no effect. Otherwise, it performs a retain
operation followed by an autorelease operation. Equivalent to the following
code:
id objc_retainAutorelease(id value) {
return objc_autorelease(objc_retain(value));
}
Always returns value
.
id objc_retainAutoreleaseReturnValue(id value);
¶
Precondition: value
is null or a pointer to a valid object.
If value
is null, this call has no effect. Otherwise, it performs a retain
operation followed by the operation described in
objc_autoreleaseReturnValue.
Equivalent to the following code:
id objc_retainAutoreleaseReturnValue(id value) {
return objc_autoreleaseReturnValue(objc_retain(value));
}
Always returns value
.
id objc_retainAutoreleasedReturnValue(id value);
¶
Precondition: value
is null or a pointer to a valid object.
If value
is null, this call has no effect. Otherwise, it attempts to
accept a hand off of a retain count from a call to
objc_autoreleaseReturnValue on
value
in a recently-called function or something it calls. If that fails,
it performs a retain operation exactly like objc_retain.
Always returns value
.
id objc_retainBlock(id value);
¶
Precondition: value
is null or a pointer to a valid block object.
If value
is null, this call has no effect. Otherwise, if the block pointed
to by value
is still on the stack, it is copied to the heap and the address
of the copy is returned. Otherwise a retain operation is performed on the
block exactly as if it had been sent the retain
message.
void objc_storeStrong(id *object, id value);
¶
Precondition: object
is a valid pointer to a __strong
object which is
adequately aligned for a pointer. value
is null or a pointer to a valid
object.
Performs the complete sequence for assigning to a __strong
object of
non-block type *. Equivalent to the following code:
void objc_storeStrong(id *object, id value) {
id oldValue = *object;
value = [value retain];
*object = value;
[oldValue release];
}
- *
This does not imply that a
__strong
object of block type is an invalid argument to this function. Rather it implies that anobjc_retain
and not anobjc_retainBlock
operation will be emitted if the argument is a block.
id objc_storeWeak(id *object, id value);
¶
Precondition: object
is a valid pointer which either contains a null
pointer or has been registered as a __weak
object. value
is null or a
pointer to a valid object.
If value
is a null pointer or the object to which it points has begun
deallocation, object
is assigned null and unregistered as a __weak
object. Otherwise, object
is registered as a __weak
object or has its
registration updated to point to value
.
Returns the value of object
after the call.