interrupt¶

Clang supports the GNU style __attribute__((interrupt("TYPE"))) attribute on ARM targets. This attribute may be attached to a function definition and instructs the backend to generate appropriate function entry/exit code so that it can be used directly as an interrupt service routine.

The parameter passed to the interrupt attribute is optional, but if provided it must be a string literal with one of the following values: “IRQ”, “FIQ”, “SWI”, “ABORT”, “UNDEF”.

The semantics are as follows:

• If the function is AAPCS, Clang instructs the backend to realign the stack to 8 bytes on entry. This is a general requirement of the AAPCS at public interfaces, but may not hold when an exception is taken. Doing this allows other AAPCS functions to be called.

• If the CPU is M-class this is all that needs to be done since the architecture itself is designed in such a way that functions obeying the normal AAPCS ABI constraints are valid exception handlers.

• If the CPU is not M-class, the prologue and epilogue are modified to save all non-banked registers that are used, so that upon return the user-mode state will not be corrupted. Note that to avoid unnecessary overhead, only general-purpose (integer) registers are saved in this way. If VFP operations are needed, that state must be saved manually.

  Specifically, interrupt kinds other than “FIQ” will save all core registers except “lr” and “sp”. “FIQ” interrupts will save r0-r7.

• If the CPU is not M-class, the return instruction is changed to one of the canonical sequences permitted by the architecture for exception return. Where possible the function itself will make the necessary “lr” adjustments so that the “preferred return address” is selected.

  Unfortunately the compiler is unable to make this guarantee for an “UNDEF” handler, where the offset from “lr” to the preferred return address depends on the execution state of the code which generated the exception. In this case a sequence equivalent to “movs pc, lr” will be used.

abi_tag (gnu::abi_tag)¶

The abi_tag attribute can be applied to a function, variable, class or inline namespace declaration to modify the mangled name of the entity. It gives the ability to distinguish between different versions of the same entity but with different ABI versions supported. For example, a newer version of a class could have a different set of data members and thus have a different size. Using the abi_tag attribute, it is possible to have different mangled names for a global variable of the class type. Therefor, the old code could keep using the old manged name and the new code will use the new mangled name with tags.

acquire_capability (acquire_shared_capability, clang::acquire_capability, clang::acquire_shared_capability)¶

Marks a function as acquiring a capability.

interrupt¶

Clang supports the GNU style __attribute__((interrupt)) attribute on x86/x86-64 targets.The compiler generates function entry and exit sequences suitable for use in an interrupt handler when this attribute is present. The ‘IRET’ instruction, instead of the ‘RET’ instruction, is used to return from interrupt or exception handlers. All registers, except for the EFLAGS register which is restored by the ‘IRET’ instruction, are preserved by the compiler.

Any interruptible-without-stack-switch code must be compiled with -mno-red-zone since interrupt handlers can and will, because of the hardware design, touch the red zone.

1. interrupt handler must be declared with a mandatory pointer argument:

struct interrupt_frame
{
  uword_t ip;
  uword_t cs;
  uword_t flags;
  uword_t sp;
  uword_t ss;
};

__attribute__ ((interrupt))
void f (struct interrupt_frame *frame) {
  ...
}

2. exception handler:

The exception handler is very similar to the interrupt handler with a different mandatory function signature:

__attribute__ ((interrupt))
void f (struct interrupt_frame *frame, uword_t error_code) {
  ...
}

and compiler pops ‘ERROR_CODE’ off stack before the ‘IRET’ instruction.

The exception handler should only be used for exceptions which push an error code and all other exceptions must use the interrupt handler. The system will crash if the wrong handler is used.

assert_capability (assert_shared_capability, clang::assert_capability, clang::assert_shared_capability)¶

Marks a function that dynamically tests whether a capability is held, and halts the program if it is not held.

assume_aligned (gnu::assume_aligned)¶

Use __attribute__((assume_aligned(<alignment>[,<offset>])) on a function declaration to specify that the return value of the function (which must be a pointer type) has the specified offset, in bytes, from an address with the specified alignment. The offset is taken to be zero if omitted.

// The returned pointer value has 32-byte alignment.
void *a() __attribute__((assume_aligned (32)));

// The returned pointer value is 4 bytes greater than an address having
// 32-byte alignment.
void *b() __attribute__((assume_aligned (32, 4)));

Note that this attribute provides information to the compiler regarding a condition that the code already ensures is true. It does not cause the compiler to enforce the provided alignment assumption.

availability¶

The availability attribute can be placed on declarations to describe the lifecycle of that declaration relative to operating system versions. Consider the function declaration for a hypothetical function f:

void f(void) __attribute__((availability(macos,introduced=10.4,deprecated=10.6,obsoleted=10.7)));

The availability attribute states that f was introduced in Mac OS X 10.4, deprecated in Mac OS X 10.6, and obsoleted in Mac OS X 10.7. This information is used by Clang to determine when it is safe to use f: for example, if Clang is instructed to compile code for Mac OS X 10.5, a call to f() succeeds. If Clang is instructed to compile code for Mac OS X 10.6, the call succeeds but Clang emits a warning specifying that the function is deprecated. Finally, if Clang is instructed to compile code for Mac OS X 10.7, the call fails because f() is no longer available.

The availability attribute is a comma-separated list starting with the platform name and then including clauses specifying important milestones in the declaration’s lifetime (in any order) along with additional information. Those clauses can be:

introduced=version

The first version in which this declaration was introduced.

deprecated=version

The first version in which this declaration was deprecated, meaning that users should migrate away from this API.

obsoleted=version

The first version in which this declaration was obsoleted, meaning that it was removed completely and can no longer be used.

unavailable

This declaration is never available on this platform.

message=string-literal

Additional message text that Clang will provide when emitting a warning or error about use of a deprecated or obsoleted declaration. Useful to direct users to replacement APIs.

replacement=string-literal

Additional message text that Clang will use to provide Fix-It when emitting a warning about use of a deprecated declaration. The Fix-It will replace the deprecated declaration with the new declaration specified.

Multiple availability attributes can be placed on a declaration, which may correspond to different platforms. Only the availability attribute with the platform corresponding to the target platform will be used; any others will be ignored. If no availability attribute specifies availability for the current target platform, the availability attributes are ignored. Supported platforms are:

ios

Apple’s iOS operating system. The minimum deployment target is specified by the -mios-version-min=*version* or -miphoneos-version-min=*version* command-line arguments.

macos

Apple’s Mac OS X operating system. The minimum deployment target is specified by the -mmacosx-version-min=*version* command-line argument. macosx is supported for backward-compatibility reasons, but it is deprecated.

tvos

Apple’s tvOS operating system. The minimum deployment target is specified by the -mtvos-version-min=*version* command-line argument.

watchos

Apple’s watchOS operating system. The minimum deployment target is specified by the -mwatchos-version-min=*version* command-line argument.

A declaration can typically be used even when deploying back to a platform version prior to when the declaration was introduced. When this happens, the declaration is weakly linked, as if the weak_import attribute were added to the declaration. A weakly-linked declaration may or may not be present a run-time, and a program can determine whether the declaration is present by checking whether the address of that declaration is non-NULL.

The flag strict disallows using API when deploying back to a platform version prior to when the declaration was introduced. An attempt to use such API before its introduction causes a hard error. Weakly-linking is almost always a better API choice, since it allows users to query availability at runtime.

If there are multiple declarations of the same entity, the availability attributes must either match on a per-platform basis or later declarations must not have availability attributes for that platform. For example:

void g(void) __attribute__((availability(macos,introduced=10.4)));
void g(void) __attribute__((availability(macos,introduced=10.4))); // okay, matches
void g(void) __attribute__((availability(ios,introduced=4.0))); // okay, adds a new platform
void g(void); // okay, inherits both macos and ios availability from above.
void g(void) __attribute__((availability(macos,introduced=10.5))); // error: mismatch

When one method overrides another, the overriding method can be more widely available than the overridden method, e.g.,:

@interface A
- (id)method __attribute__((availability(macos,introduced=10.4)));
- (id)method2 __attribute__((availability(macos,introduced=10.4)));
@end

@interface B : A
- (id)method __attribute__((availability(macos,introduced=10.3))); // okay: method moved into base class later
- (id)method __attribute__((availability(macos,introduced=10.5))); // error: this method was available via the base class in 10.4
@end

_Noreturn¶

A function declared as _Noreturn shall not return to its caller. The compiler will generate a diagnostic for a function declared as _Noreturn that appears to be capable of returning to its caller.

noreturn¶

A function declared as [[noreturn]] shall not return to its caller. The compiler will generate a diagnostic for a function declared as [[noreturn]] that appears to be capable of returning to its caller.

carries_dependency¶

The carries_dependency attribute specifies dependency propagation into and out of functions.

When specified on a function or Objective-C method, the carries_dependency attribute means that the return value carries a dependency out of the function, so that the implementation need not constrain ordering upon return from that function. Implementations of the function and its caller may choose to preserve dependencies instead of emitting memory ordering instructions such as fences.

Note, this attribute does not change the meaning of the program, but may result in generation of more efficient code.

deprecated (gnu::deprecated)¶

The deprecated attribute can be applied to a function, a variable, or a type. This is useful when identifying functions, variables, or types that are expected to be removed in a future version of a program.

Consider the function declaration for a hypothetical function f:

void f(void) __attribute__((deprecated("message", "replacement")));

When spelled as __attribute__((deprecated)), the deprecated attribute can have two optional string arguments. The first one is the message to display when emitting the warning; the second one enables the compiler to provide a Fix-It to replace the deprecated name with a new name. Otherwise, when spelled as [[gnu::deprecated]] or [[deprecated]], the attribute can have one optional string argument which is the message to display when emitting the warning.

disable_tail_calls (clang::disable_tail_calls)¶

The disable_tail_calls attribute instructs the backend to not perform tail call optimization inside the marked function.

For example:

int callee(int);

int foo(int a) __attribute__((disable_tail_calls)) {
  return callee(a); // This call is not tail-call optimized.
}

Marking virtual functions as disable_tail_calls is legal.

int callee(int);

class Base {
public:
  [[clang::disable_tail_calls]] virtual int foo1() {
    return callee(); // This call is not tail-call optimized.
  }
};

class Derived1 : public Base {
public:
  int foo1() override {
    return callee(); // This call is tail-call optimized.
  }
};

enable_if¶

The enable_if attribute can be placed on function declarations to control which overload is selected based on the values of the function’s arguments. When combined with the overloadable attribute, this feature is also available in C.

int isdigit(int c);
int isdigit(int c) __attribute__((enable_if(c <= -1 || c > 255, "chosen when 'c' is out of range"))) __attribute__((unavailable("'c' must have the value of an unsigned char or EOF")));

void foo(char c) {
  isdigit(c);
  isdigit(10);
  isdigit(-10);  // results in a compile-time error.
}

The enable_if attribute takes two arguments, the first is an expression written in terms of the function parameters, the second is a string explaining why this overload candidate could not be selected to be displayed in diagnostics. The expression is part of the function signature for the purposes of determining whether it is a redeclaration (following the rules used when determining whether a C++ template specialization is ODR-equivalent), but is not part of the type.

The enable_if expression is evaluated as if it were the body of a bool-returning constexpr function declared with the arguments of the function it is being applied to, then called with the parameters at the call site. If the result is false or could not be determined through constant expression evaluation, then this overload will not be chosen and the provided string may be used in a diagnostic if the compile fails as a result.

Because the enable_if expression is an unevaluated context, there are no global state changes, nor the ability to pass information from the enable_if expression to the function body. For example, suppose we want calls to strnlen(strbuf, maxlen) to resolve to strnlen_chk(strbuf, maxlen, size of strbuf) only if the size of strbuf can be determined:

__attribute__((always_inline))
static inline size_t strnlen(const char *s, size_t maxlen)
  __attribute__((overloadable))
  __attribute__((enable_if(__builtin_object_size(s, 0) != -1))),
                           "chosen when the buffer size is known but 'maxlen' is not")))
{
  return strnlen_chk(s, maxlen, __builtin_object_size(s, 0));
}

Multiple enable_if attributes may be applied to a single declaration. In this case, the enable_if expressions are evaluated from left to right in the following manner. First, the candidates whose enable_if expressions evaluate to false or cannot be evaluated are discarded. If the remaining candidates do not share ODR-equivalent enable_if expressions, the overload resolution is ambiguous. Otherwise, enable_if overload resolution continues with the next enable_if attribute on the candidates that have not been discarded and have remaining enable_if attributes. In this way, we pick the most specific overload out of a number of viable overloads using enable_if.

void f() __attribute__((enable_if(true, "")));  // #1
void f() __attribute__((enable_if(true, ""))) __attribute__((enable_if(true, "")));  // #2

void g(int i, int j) __attribute__((enable_if(i, "")));  // #1
void g(int i, int j) __attribute__((enable_if(j, ""))) __attribute__((enable_if(true)));  // #2

In this example, a call to f() is always resolved to #2, as the first enable_if expression is ODR-equivalent for both declarations, but #1 does not have another enable_if expression to continue evaluating, so the next round of evaluation has only a single candidate. In a call to g(1, 1), the call is ambiguous even though #2 has more enable_if attributes, because the first enable_if expressions are not ODR-equivalent.

Query for this feature with __has_attribute(enable_if).

Note that functions with one or more enable_if attributes may not have their address taken, unless all of the conditions specified by said enable_if are constants that evaluate to true. For example:

const int TrueConstant = 1;
const int FalseConstant = 0;
int f(int a) __attribute__((enable_if(a > 0, "")));
int g(int a) __attribute__((enable_if(a == 0 || a != 0, "")));
int h(int a) __attribute__((enable_if(1, "")));
int i(int a) __attribute__((enable_if(TrueConstant, "")));
int j(int a) __attribute__((enable_if(FalseConstant, "")));

void fn() {
  int (*ptr)(int);
  ptr = &f; // error: 'a > 0' is not always true
  ptr = &g; // error: 'a == 0 || a != 0' is not a truthy constant
  ptr = &h; // OK: 1 is a truthy constant
  ptr = &i; // OK: 'TrueConstant' is a truthy constant
  ptr = &j; // error: 'FalseConstant' is a constant, but not truthy
}

Because enable_if evaluation happens during overload resolution, enable_if may give unintuitive results when used with templates, depending on when overloads are resolved. In the example below, clang will emit a diagnostic about no viable overloads for foo in bar, but not in baz:

double foo(int i) __attribute__((enable_if(i > 0, "")));
void *foo(int i) __attribute__((enable_if(i <= 0, "")));
template <int I>
auto bar() { return foo(I); }

template <typename T>
auto baz() { return foo(T::number); }

struct WithNumber { constexpr static int number = 1; };
void callThem() {
  bar<sizeof(WithNumber)>();
  baz<WithNumber>();
}

This is because, in bar, foo is resolved prior to template instantiation, so the value for I isn’t known (thus, both enable_if conditions for foo fail). However, in baz, foo is resolved during template instantiation, so the value for T::number is known.

flatten (gnu::flatten)¶

The flatten attribute causes calls within the attributed function to be inlined unless it is impossible to do so, for example if the body of the callee is unavailable or if the callee has the noinline attribute.

format (gnu::format)¶

Clang supports the format attribute, which indicates that the function accepts a printf or scanf-like format string and corresponding arguments or a va_list that contains these arguments.

Please see GCC documentation about format attribute to find details about attribute syntax.

Clang implements two kinds of checks with this attribute.

1. Clang checks that the function with the format attribute is called with a format string that uses format specifiers that are allowed, and that arguments match the format string. This is the -Wformat warning, it is on by default.

2. Clang checks that the format string argument is a literal string. This is the -Wformat-nonliteral warning, it is off by default.

   Clang implements this mostly the same way as GCC, but there is a difference for functions that accept a va_list argument (for example, vprintf). GCC does not emit -Wformat-nonliteral warning for calls to such functions. Clang does not warn if the format string comes from a function parameter, where the function is annotated with a compatible attribute, otherwise it warns. For example:

   __attribute__((__format__ (__scanf__, 1, 3)))
   void foo(const char* s, char *buf, ...) {
     va_list ap;
     va_start(ap, buf);
   
     vprintf(s, ap); // warning: format string is not a string literal
   }
   

   In this case we warn because s contains a format string for a scanf-like function, but it is passed to a printf-like function.

   If the attribute is removed, clang still warns, because the format string is not a string literal.

   Another example:

   __attribute__((__format__ (__printf__, 1, 3)))
   void foo(const char* s, char *buf, ...) {
     va_list ap;
     va_start(ap, buf);
   
     vprintf(s, ap); // warning
   }
   

   In this case Clang does not warn because the format string s and the corresponding arguments are annotated. If the arguments are incorrect, the caller of foo will receive a warning.

ifunc (gnu::ifunc)¶

__attribute__((ifunc("resolver"))) is used to mark that the address of a declaration should be resolved at runtime by calling a resolver function.

The symbol name of the resolver function is given in quotes. A function with this name (after mangling) must be defined in the current translation unit; it may be static. The resolver function should take no arguments and return a pointer.

The ifunc attribute may only be used on a function declaration. A function declaration with an ifunc attribute is considered to be a definition of the declared entity. The entity must not have weak linkage; for example, in C++, it cannot be applied to a declaration if a definition at that location would be considered inline.

Not all targets support this attribute. ELF targets support this attribute when using binutils v2.20.1 or higher and glibc v2.11.1 or higher. Non-ELF targets currently do not support this attribute.

internal_linkage (clang::internal_linkage)¶

The internal_linkage attribute changes the linkage type of the declaration to internal. This is similar to C-style static, but can be used on classes and class methods. When applied to a class definition, this attribute affects all methods and static data members of that class. This can be used to contain the ABI of a C++ library by excluding unwanted class methods from the export tables.

interrupt¶

Clang supports the GNU style __attribute__((interrupt("ARGUMENT"))) attribute on MIPS targets. This attribute may be attached to a function definition and instructs the backend to generate appropriate function entry/exit code so that it can be used directly as an interrupt service routine.

By default, the compiler will produce a function prologue and epilogue suitable for an interrupt service routine that handles an External Interrupt Controller (eic) generated interrupt. This behaviour can be explicitly requested with the “eic” argument.

Otherwise, for use with vectored interrupt mode, the argument passed should be of the form “vector=LEVEL” where LEVEL is one of the following values: “sw0”, “sw1”, “hw0”, “hw1”, “hw2”, “hw3”, “hw4”, “hw5”. The compiler will then set the interrupt mask to the corresponding level which will mask all interrupts up to and including the argument.

The semantics are as follows:

• The prologue is modified so that the Exception Program Counter (EPC) and Status coprocessor registers are saved to the stack. The interrupt mask is set so that the function can only be interrupted by a higher priority interrupt. The epilogue will restore the previous values of EPC and Status.
• The prologue and epilogue are modified to save and restore all non-kernel registers as necessary.
• The FPU is disabled in the prologue, as the floating pointer registers are not spilled to the stack.
• The function return sequence is changed to use an exception return instruction.
• The parameter sets the interrupt mask for the function corresponding to the interrupt level specified. If no mask is specified the interrupt mask defaults to “eic”.

noalias¶

The noalias attribute indicates that the only memory accesses inside function are loads and stores from objects pointed to by its pointer-typed arguments, with arbitrary offsets.

noduplicate (clang::noduplicate)¶

The noduplicate attribute can be placed on function declarations to control whether function calls to this function can be duplicated or not as a result of optimizations. This is required for the implementation of functions with certain special requirements, like the OpenCL “barrier” function, that might need to be run concurrently by all the threads that are executing in lockstep on the hardware. For example this attribute applied on the function “nodupfunc” in the code below avoids that:

void nodupfunc() __attribute__((noduplicate));
// Setting it as a C++11 attribute is also valid
// void nodupfunc() [[clang::noduplicate]];
void foo();
void bar();

nodupfunc();
if (a > n) {
  foo();
} else {
  bar();
}

gets possibly modified by some optimizations into code similar to this:

if (a > n) {
  nodupfunc();
  foo();
} else {
  nodupfunc();
  bar();
}

where the call to “nodupfunc” is duplicated and sunk into the two branches of the condition.

no_sanitize (clang::no_sanitize)¶

Use the no_sanitize attribute on a function declaration to specify that a particular instrumentation or set of instrumentations should not be applied to that function. The attribute takes a list of string literals, which have the same meaning as values accepted by the -fno-sanitize= flag. For example, __attribute__((no_sanitize("address", "thread"))) specifies that AddressSanitizer and ThreadSanitizer should not be applied to the function.

See Controlling Code Generation for a full list of supported sanitizer flags.

no_sanitize_address (no_address_safety_analysis, gnu::no_address_safety_analysis, gnu::no_sanitize_address)¶

Use __attribute__((no_sanitize_address)) on a function declaration to specify that address safety instrumentation (e.g. AddressSanitizer) should not be applied to that function.

no_sanitize_thread¶

Use __attribute__((no_sanitize_thread)) on a function declaration to specify that checks for data races on plain (non-atomic) memory accesses should not be inserted by ThreadSanitizer. The function is still instrumented by the tool to avoid false positives and provide meaningful stack traces.

no_sanitize_memory¶

Use __attribute__((no_sanitize_memory)) on a function declaration to specify that checks for uninitialized memory should not be inserted (e.g. by MemorySanitizer). The function may still be instrumented by the tool to avoid false positives in other places.

no_split_stack (gnu::no_split_stack)¶

The no_split_stack attribute disables the emission of the split stack preamble for a particular function. It has no effect if -fsplit-stack is not specified.

not_tail_called (clang::not_tail_called)¶

The not_tail_called attribute prevents tail-call optimization on statically bound calls. It has no effect on indirect calls. Virtual functions, objective-c methods, and functions marked as always_inline cannot be marked as not_tail_called.

For example, it prevents tail-call optimization in the following case:

int __attribute__((not_tail_called)) foo1(int);

int foo2(int a) {
  return foo1(a); // No tail-call optimization on direct calls.
}

However, it doesn’t prevent tail-call optimization in this case:

int __attribute__((not_tail_called)) foo1(int);

int foo2(int a) {
  int (*fn)(int) = &foo1;

  // not_tail_called has no effect on an indirect call even if the call can be
  // resolved at compile time.
  return (*fn)(a);
}

Marking virtual functions as not_tail_called is an error:

class Base {
public:
  // not_tail_called on a virtual function is an error.
  [[clang::not_tail_called]] virtual int foo1();

  virtual int foo2();

  // Non-virtual functions can be marked ``not_tail_called``.
  [[clang::not_tail_called]] int foo3();
};

class Derived1 : public Base {
public:
  int foo1() override;

  // not_tail_called on a virtual function is an error.
  [[clang::not_tail_called]] int foo2() override;
};

#pragma omp declare simd¶

The declare simd construct can be applied to a function to enable the creation of one or more versions that can process multiple arguments using SIMD instructions from a single invocation in a SIMD loop. The declare simd directive is a declarative directive. There may be multiple declare simd directives for a function. The use of a declare simd construct on a function enables the creation of SIMD versions of the associated function that can be used to process multiple arguments from a single invocation from a SIMD loop concurrently. The syntax of the declare simd construct is as follows:

#pragma omp declare simd [clause[[,] clause] ...] new-line [#pragma omp declare simd [clause[[,] clause] ...] new-line] [...] function definition or declaration

where clause is one of the following:

simdlen(length) linear(argument-list[:constant-linear-step]) aligned(argument-list[:alignment]) uniform(argument-list) inbranch notinbranch

#pragma omp declare target¶

The declare target directive specifies that variables and functions are mapped to a device for OpenMP offload mechanism.

The syntax of the declare target directive is as follows:

#pragma omp declare target new-line declarations-definition-seq #pragma omp end declare target new-line

objc_boxable¶

Structs and unions marked with the objc_boxable attribute can be used with the Objective-C boxed expression syntax, @(...).

Usage: __attribute__((objc_boxable)). This attribute can only be placed on a declaration of a trivially-copyable struct or union:

struct __attribute__((objc_boxable)) some_struct {
  int i;
};
union __attribute__((objc_boxable)) some_union {
  int i;
  float f;
};
typedef struct __attribute__((objc_boxable)) _some_struct some_struct;

// ...

some_struct ss;
NSValue *boxed = @(ss);

objc_method_family¶

Many methods in Objective-C have conventional meanings determined by their selectors. It is sometimes useful to be able to mark a method as having a particular conventional meaning despite not having the right selector, or as not having the conventional meaning that its selector would suggest. For these use cases, we provide an attribute to specifically describe the “method family” that a method belongs to.

Usage: __attribute__((objc_method_family(X))), where X is one of none, alloc, copy, init, mutableCopy, or new. This attribute can only be placed at the end of a method declaration:

- (NSString *)initMyStringValue __attribute__((objc_method_family(none)));

Users who do not wish to change the conventional meaning of a method, and who merely want to document its non-standard retain and release semantics, should use the retaining behavior attributes (ns_returns_retained, ns_returns_not_retained, etc).

Query for this feature with __has_attribute(objc_method_family).

objc_requires_super¶

Some Objective-C classes allow a subclass to override a particular method in a parent class but expect that the overriding method also calls the overridden method in the parent class. For these cases, we provide an attribute to designate that a method requires a “call to super” in the overriding method in the subclass.

Usage: __attribute__((objc_requires_super)). This attribute can only be placed at the end of a method declaration:

- (void)foo __attribute__((objc_requires_super));

This attribute can only be applied the method declarations within a class, and not a protocol. Currently this attribute does not enforce any placement of where the call occurs in the overriding method (such as in the case of -dealloc where the call must appear at the end). It checks only that it exists.

Note that on both OS X and iOS that the Foundation framework provides a convenience macro NS_REQUIRES_SUPER that provides syntactic sugar for this attribute:

- (void)foo NS_REQUIRES_SUPER;

This macro is conditionally defined depending on the compiler’s support for this attribute. If the compiler does not support the attribute the macro expands to nothing.

Operationally, when a method has this annotation the compiler will warn if the implementation of an override in a subclass does not call super. For example:

warning: method possibly missing a [super AnnotMeth] call
- (void) AnnotMeth{};
                   ^

objc_runtime_name¶

By default, the Objective-C interface or protocol identifier is used in the metadata name for that object. The objc_runtime_name attribute allows annotated interfaces or protocols to use the specified string argument in the object’s metadata name instead of the default name.

Usage: __attribute__((objc_runtime_name("MyLocalName"))). This attribute can only be placed before an @protocol or @interface declaration:

__attribute__((objc_runtime_name("MyLocalName")))
@interface Message
@end

objc_runtime_visible¶

This attribute specifies that the Objective-C class to which it applies is visible to the Objective-C runtime but not to the linker. Classes annotated with this attribute cannot be subclassed and cannot have categories defined for them.

optnone (clang::optnone)¶

The optnone attribute suppresses essentially all optimizations on a function or method, regardless of the optimization level applied to the compilation unit as a whole. This is particularly useful when you need to debug a particular function, but it is infeasible to build the entire application without optimization. Avoiding optimization on the specified function can improve the quality of the debugging information for that function.

This attribute is incompatible with the always_inline and minsize attributes.

overloadable¶

Clang provides support for C++ function overloading in C. Function overloading in C is introduced using the overloadable attribute. For example, one might provide several overloaded versions of a tgsin function that invokes the appropriate standard function computing the sine of a value with float, double, or long double precision:

#include <math.h>
float __attribute__((overloadable)) tgsin(float x) { return sinf(x); }
double __attribute__((overloadable)) tgsin(double x) { return sin(x); }
long double __attribute__((overloadable)) tgsin(long double x) { return sinl(x); }

Given these declarations, one can call tgsin with a float value to receive a float result, with a double to receive a double result, etc. Function overloading in C follows the rules of C++ function overloading to pick the best overload given the call arguments, with a few C-specific semantics:

• Conversion from float or double to long double is ranked as a floating-point promotion (per C99) rather than as a floating-point conversion (as in C++).
• A conversion from a pointer of type T* to a pointer of type U* is considered a pointer conversion (with conversion rank) if T and U are compatible types.
• A conversion from type T to a value of type U is permitted if T and U are compatible types. This conversion is given “conversion” rank.

The declaration of overloadable functions is restricted to function declarations and definitions. Most importantly, if any function with a given name is given the overloadable attribute, then all function declarations and definitions with that name (and in that scope) must have the overloadable attribute. This rule even applies to redeclarations of functions whose original declaration had the overloadable attribute, e.g.,

int f(int) __attribute__((overloadable));
float f(float); // error: declaration of "f" must have the "overloadable" attribute

int g(int) __attribute__((overloadable));
int g(int) { } // error: redeclaration of "g" must also have the "overloadable" attribute

Functions marked overloadable must have prototypes. Therefore, the following code is ill-formed:

int h() __attribute__((overloadable)); // error: h does not have a prototype

However, overloadable functions are allowed to use a ellipsis even if there are no named parameters (as is permitted in C++). This feature is particularly useful when combined with the unavailable attribute:

void honeypot(...) __attribute__((overloadable, unavailable)); // calling me is an error

Functions declared with the overloadable attribute have their names mangled according to the same rules as C++ function names. For example, the three tgsin functions in our motivating example get the mangled names _Z5tgsinf, _Z5tgsind, and _Z5tgsine, respectively. There are two caveats to this use of name mangling:

• Future versions of Clang may change the name mangling of functions overloaded in C, so you should not depend on an specific mangling. To be completely safe, we strongly urge the use of static inline with overloadable functions.
• The overloadable attribute has almost no meaning when used in C++, because names will already be mangled and functions are already overloadable. However, when an overloadable function occurs within an extern "C" linkage specification, it’s name will be mangled in the same way as it would in C.

Query for this feature with __has_extension(attribute_overloadable).

release_capability (release_shared_capability, clang::release_capability, clang::release_shared_capability)¶

Marks a function as releasing a capability.

kernel¶

__attribute__((kernel)) is used to mark a kernel function in RenderScript.

In RenderScript, kernel functions are used to express data-parallel computations. The RenderScript runtime efficiently parallelizes kernel functions to run on computational resources such as multi-core CPUs and GPUs. See the RenderScript documentation for more information.

target (gnu::target)¶

Clang supports the GNU style __attribute__((target("OPTIONS"))) attribute. This attribute may be attached to a function definition and instructs the backend to use different code generation options than were passed on the command line.

The current set of options correspond to the existing “subtarget features” for the target with or without a “-mno-” in front corresponding to the absence of the feature, as well as arch="CPU" which will change the default “CPU” for the function.

Example “subtarget features” from the x86 backend include: “mmx”, “sse”, “sse4.2”, “avx”, “xop” and largely correspond to the machine specific options handled by the front end.

try_acquire_capability (try_acquire_shared_capability, clang::try_acquire_capability, clang::try_acquire_shared_capability)¶

Marks a function that attempts to acquire a capability. This function may fail to actually acquire the capability; they accept a Boolean value determining whether acquiring the capability means success (true), or failing to acquire the capability means success (false).

nodiscard, warn_unused_result, clang::warn_unused_result, gnu::warn_unused_result¶

Clang supports the ability to diagnose when the results of a function call expression are discarded under suspicious circumstances. A diagnostic is generated when a function or its return type is marked with [[nodiscard]] (or __attribute__((warn_unused_result))) and the function call appears as a potentially-evaluated discarded-value expression that is not explicitly cast to void.

xray_always_instrument (clang::xray_always_instrument), xray_never_instrument (clang::xray_never_instrument)¶

__attribute__((xray_always_instrument)) or [[clang::xray_always_instrument]] is used to mark member functions (in C++), methods (in Objective C), and free functions (in C, C++, and Objective C) to be instrumented with XRay. This will cause the function to always have space at the beginning and exit points to allow for runtime patching.

Conversely, __attribute__((xray_never_instrument)) or [[clang::xray_never_instrument]] will inhibit the insertion of these instrumentation points.

If a function has neither of these attributes, they become subject to the XRay heuristics used to determine whether a function should be instrumented or otherwise.

dllexport (gnu::dllexport)¶

The __declspec(dllexport) attribute declares a variable, function, or Objective-C interface to be exported from the module. It is available under the -fdeclspec flag for compatibility with various compilers. The primary use is for COFF object files which explicitly specify what interfaces are available for external use. See the dllexport documentation on MSDN for more information.

dllimport (gnu::dllimport)¶

The __declspec(dllimport) attribute declares a variable, function, or Objective-C interface to be imported from an external module. It is available under the -fdeclspec flag for compatibility with various compilers. The primary use is for COFF object files which explicitly specify what interfaces are imported from external modules. See the dllimport documentation on MSDN for more information.

init_seg¶

The attribute applied by pragma init_seg() controls the section into which global initialization function pointers are emitted. It is only available with -fms-extensions. Typically, this function pointer is emitted into .CRT$XCU on Windows. The user can change the order of initialization by using a different section name with the same .CRT$XC prefix and a suffix that sorts lexicographically before or after the standard .CRT$XCU sections. See the init_seg documentation on MSDN for more information.

nodebug (gnu::nodebug)¶

The nodebug attribute allows you to suppress debugging information for a function or method, or for a variable that is not a parameter or a non-static data member.

nosvm¶

OpenCL 2.0 supports the optional __attribute__((nosvm)) qualifier for pointer variable. It informs the compiler that the pointer does not refer to a shared virtual memory region. See OpenCL v2.0 s6.7.2 for details.

Since it is not widely used and has been removed from OpenCL 2.1, it is ignored by Clang.

pass_object_size¶

The pass_object_size(Type) attribute can be placed on function parameters to instruct clang to call __builtin_object_size(param, Type) at each callsite of said function, and implicitly pass the result of this call in as an invisible argument of type size_t directly after the parameter annotated with pass_object_size. Clang will also replace any calls to __builtin_object_size(param, Type) in the function by said implicit parameter.

Example usage:

int bzero1(char *const p __attribute__((pass_object_size(0))))
    __attribute__((noinline)) {
  int i = 0;
  for (/**/; i < (int)__builtin_object_size(p, 0); ++i) {
    p[i] = 0;
  }
  return i;
}

int main() {
  char chars[100];
  int n = bzero1(&chars[0]);
  assert(n == sizeof(chars));
  return 0;
}

If successfully evaluating __builtin_object_size(param, Type) at the callsite is not possible, then the “failed” value is passed in. So, using the definition of bzero1 from above, the following code would exit cleanly:

int main2(int argc, char *argv[]) {
  int n = bzero1(argv);
  assert(n == -1);
  return 0;
}

pass_object_size plays a part in overload resolution. If two overload candidates are otherwise equally good, then the overload with one or more parameters with pass_object_size is preferred. This implies that the choice between two identical overloads both with pass_object_size on one or more parameters will always be ambiguous; for this reason, having two such overloads is illegal. For example:

#define PS(N) __attribute__((pass_object_size(N)))
// OK
void Foo(char *a, char *b); // Overload A
// OK -- overload A has no parameters with pass_object_size.
void Foo(char *a PS(0), char *b PS(0)); // Overload B
// Error -- Same signature (sans pass_object_size) as overload B, and both
// overloads have one or more parameters with the pass_object_size attribute.
void Foo(void *a PS(0), void *b);

// OK
void Bar(void *a PS(0)); // Overload C
// OK
void Bar(char *c PS(1)); // Overload D

void main() {
  char known[10], *unknown;
  Foo(unknown, unknown); // Calls overload B
  Foo(known, unknown); // Calls overload B
  Foo(unknown, known); // Calls overload B
  Foo(known, known); // Calls overload B

  Bar(known); // Calls overload D
  Bar(unknown); // Calls overload D
}

Currently, pass_object_size is a bit restricted in terms of its usage:

• Only one use of pass_object_size is allowed per parameter.
• It is an error to take the address of a function with pass_object_size on any of its parameters. If you wish to do this, you can create an overload without pass_object_size on any parameters.
• It is an error to apply the pass_object_size attribute to parameters that are not pointers. Additionally, any parameter that pass_object_size is applied to must be marked const at its function’s definition.

section (gnu::section, __declspec(allocate))¶

The section attribute allows you to specify a specific section a global variable or function should be in after translation.

swiftcall (gnu::swiftcall)¶

The swiftcall attribute indicates that a function should be called using the Swift calling convention for a function or function pointer.

The lowering for the Swift calling convention, as described by the Swift ABI documentation, occurs in multiple phases. The first, “high-level” phase breaks down the formal parameters and results into innately direct and indirect components, adds implicit paraameters for the generic signature, and assigns the context and error ABI treatments to parameters where applicable. The second phase breaks down the direct parameters and results from the first phase and assigns them to registers or the stack. The swiftcall convention only handles this second phase of lowering; the C function type must accurately reflect the results of the first phase, as follows:

• Results classified as indirect by high-level lowering should be represented as parameters with the swift_indirect_result attribute.
• Results classified as direct by high-level lowering should be represented as follows:
  • First, remove any empty direct results.
  • If there are no direct results, the C result type should be void.
  • If there is one direct result, the C result type should be a type with the exact layout of that result type.
  • If there are a multiple direct results, the C result type should be a struct type with the exact layout of a tuple of those results.
• Parameters classified as indirect by high-level lowering should be represented as parameters of pointer type.
• Parameters classified as direct by high-level lowering should be omitted if they are empty types; otherwise, they should be represented as a parameter type with a layout exactly matching the layout of the Swift parameter type.
• The context parameter, if present, should be represented as a trailing parameter with the swift_context attribute.
• The error result parameter, if present, should be represented as a trailing parameter (always following a context parameter) with the swift_error_result attribute.

swiftcall does not support variadic arguments or unprototyped functions.

The parameter ABI treatment attributes are aspects of the function type. A function type which which applies an ABI treatment attribute to a parameter is a different type from an otherwise-identical function type that does not. A single parameter may not have multiple ABI treatment attributes.

Support for this feature is target-dependent, although it should be supported on every target that Swift supports. Query for this support with __has_attribute(swiftcall). This implies support for the swift_context, swift_error_result, and swift_indirect_result attributes.

swift_context (gnu::swift_context)¶

The swift_context attribute marks a parameter of a swiftcall function as having the special context-parameter ABI treatment.

This treatment generally passes the context value in a special register which is normally callee-preserved.

A swift_context parameter must either be the last parameter or must be followed by a swift_error_result parameter (which itself must always be the last parameter).

A context parameter must have pointer or reference type.

swift_error_result (gnu::swift_error_result)¶

The swift_error_result attribute marks a parameter of a swiftcall function as having the special error-result ABI treatment.

This treatment generally passes the underlying error value in and out of the function through a special register which is normally callee-preserved. This is modeled in C by pretending that the register is addressable memory:

• The caller appears to pass the address of a variable of pointer type. The current value of this variable is copied into the register before the call; if the call returns normally, the value is copied back into the variable.
• The callee appears to receive the address of a variable. This address is actually a hidden location in its own stack, initialized with the value of the register upon entry. When the function returns normally, the value in that hidden location is written back to the register.

A swift_error_result parameter must be the last parameter, and it must be preceded by a swift_context parameter.

A swift_error_result parameter must have type T** or T*& for some type T. Note that no qualifiers are permitted on the intermediate level.

It is undefined behavior if the caller does not pass a pointer or reference to a valid object.

The standard convention is that the error value itself (that is, the value stored in the apparent argument) will be null upon function entry, but this is not enforced by the ABI.

swift_indirect_result (gnu::swift_indirect_result)¶

The swift_indirect_result attribute marks a parameter of a swiftcall function as having the special indirect-result ABI treatmenet.

This treatment gives the parameter the target’s normal indirect-result ABI treatment, which may involve passing it differently from an ordinary parameter. However, only the first indirect result will receive this treatment. Furthermore, low-level lowering may decide that a direct result must be returned indirectly; if so, this will take priority over the swift_indirect_result parameters.

A swift_indirect_result parameter must either be the first parameter or follow another swift_indirect_result parameter.

A swift_indirect_result parameter must have type T* or T& for some object type T. If T is a complete type at the point of definition of a function, it is undefined behavior if the argument value does not point to storage of adequate size and alignment for a value of type T.

Making indirect results explicit in the signature allows C functions to directly construct objects into them without relying on language optimizations like C++’s named return value optimization (NRVO).

tls_model (gnu::tls_model)¶

The tls_model attribute allows you to specify which thread-local storage model to use. It accepts the following strings:

• global-dynamic
• local-dynamic
• initial-exec
• local-exec

TLS models are mutually exclusive.

thread¶

The __declspec(thread) attribute declares a variable with thread local storage. It is available under the -fms-extensions flag for MSVC compatibility. See the documentation for __declspec(thread) on MSDN.

In Clang, __declspec(thread) is generally equivalent in functionality to the GNU __thread keyword. The variable must not have a destructor and must have a constant initializer, if any. The attribute only applies to variables declared with static storage duration, such as globals, class static data members, and static locals.

maybe_unused, unused, gnu::unused¶

When passing the -Wunused flag to Clang, entities that are unused by the program may be diagnosed. The [[maybe_unused]] (or __attribute__((unused))) attribute can be used to silence such diagnostics when the entity cannot be removed. For instance, a local variable may exist solely for use in an assert() statement, which makes the local variable unused when NDEBUG is defined.

The attribute may be applied to the declaration of a class, a typedef, a variable, a function or method, a function parameter, an enumeration, an enumerator, a non-static data member, or a label.

align_value¶

The align_value attribute can be added to the typedef of a pointer type or the declaration of a variable of pointer or reference type. It specifies that the pointer will point to, or the reference will bind to, only objects with at least the provided alignment. This alignment value must be some positive power of 2.

typedef double * aligned_double_ptr __attribute__((align_value(64)));
void foo(double & x  __attribute__((align_value(128)),
         aligned_double_ptr y) { ... }

If the pointer value does not have the specified alignment at runtime, the behavior of the program is undefined.

empty_bases¶

The empty_bases attribute permits the compiler to utilize the empty-base-optimization more frequently. This attribute only applies to struct, class, and union types. It is only supported when using the Microsoft C++ ABI.

flag_enum¶

This attribute can be added to an enumerator to signal to the compiler that it is intended to be used as a flag type. This will cause the compiler to assume that the range of the type includes all of the values that you can get by manipulating bits of the enumerator when issuing warnings.

lto_visibility_public (clang::lto_visibility_public)¶

See LTO Visibility.

layout_version¶

The layout_version attribute requests that the compiler utilize the class layout rules of a particular compiler version. This attribute only applies to struct, class, and union types. It is only supported when using the Microsoft C++ ABI.

__single_inhertiance, __multiple_inheritance, __virtual_inheritance¶

This collection of keywords is enabled under -fms-extensions and controls the pointer-to-member representation used on *-*-win32 targets.

The *-*-win32 targets utilize a pointer-to-member representation which varies in size and alignment depending on the definition of the underlying class.

However, this is problematic when a forward declaration is only available and no definition has been made yet. In such cases, Clang is forced to utilize the most general representation that is available to it.

These keywords make it possible to use a pointer-to-member representation other than the most general one regardless of whether or not the definition will ever be present in the current translation unit.

This family of keywords belong between the class-key and class-name:

struct __single_inheritance S;
int S::*i;
struct S {};

This keyword can be applied to class templates but only has an effect when used on full specializations:

template <typename T, typename U> struct __single_inheritance A; // warning: inheritance model ignored on primary template
template <typename T> struct __multiple_inheritance A<T, T>; // warning: inheritance model ignored on partial specialization
template <> struct __single_inheritance A<int, float>;

Note that choosing an inheritance model less general than strictly necessary is an error:

struct __multiple_inheritance S; // error: inheritance model does not match definition
int S::*i;
struct S {};

novtable¶

This attribute can be added to a class declaration or definition to signal to the compiler that constructors and destructors will not reference the virtual function table. It is only supported when using the Microsoft C++ ABI.

fallthrough, clang::fallthrough¶

The fallthrough (or clang::fallthrough) attribute is used to annotate intentional fall-through between switch labels. It can only be applied to a null statement placed at a point of execution between any statement and the next switch label. It is common to mark these places with a specific comment, but this attribute is meant to replace comments with a more strict annotation, which can be checked by the compiler. This attribute doesn’t change semantics of the code and can be used wherever an intended fall-through occurs. It is designed to mimic control-flow statements like break;, so it can be placed in most places where break; can, but only if there are no statements on the execution path between it and the next switch label.

By default, Clang does not warn on unannotated fallthrough from one switch case to another. Diagnostics on fallthrough without a corresponding annotation can be enabled with the -Wimplicit-fallthrough argument.

Here is an example:

// compile with -Wimplicit-fallthrough
switch (n) {
case 22:
case 33:  // no warning: no statements between case labels
  f();
case 44:  // warning: unannotated fall-through
  g();
  [[clang::fallthrough]];
case 55:  // no warning
  if (x) {
    h();
    break;
  }
  else {
    i();
    [[clang::fallthrough]];
  }
case 66:  // no warning
  p();
  [[clang::fallthrough]]; // warning: fallthrough annotation does not
                          //          directly precede case label
  q();
case 77:  // warning: unannotated fall-through
  r();
}

#pragma clang loop¶

The #pragma clang loop directive allows loop optimization hints to be specified for the subsequent loop. The directive allows vectorization, interleaving, and unrolling to be enabled or disabled. Vector width as well as interleave and unrolling count can be manually specified. See language extensions for details.

#pragma unroll, #pragma nounroll¶

Loop unrolling optimization hints can be specified with #pragma unroll and #pragma nounroll. The pragma is placed immediately before a for, while, do-while, or c++11 range-based for loop.

Specifying #pragma unroll without a parameter directs the loop unroller to attempt to fully unroll the loop if the trip count is known at compile time and attempt to partially unroll the loop if the trip count is not known at compile time:

#pragma unroll
for (...) {
  ...
}

Specifying the optional parameter, #pragma unroll _value_, directs the unroller to unroll the loop _value_ times. The parameter may optionally be enclosed in parentheses:

#pragma unroll 16
for (...) {
  ...
}

#pragma unroll(16)
for (...) {
  ...
}

Specifying #pragma nounroll indicates that the loop should not be unrolled:

#pragma nounroll
for (...) {
  ...
}

#pragma unroll and #pragma unroll _value_ have identical semantics to #pragma clang loop unroll(full) and #pragma clang loop unroll_count(_value_) respectively. #pragma nounroll is equivalent to #pragma clang loop unroll(disable). See language extensions for further details including limitations of the unroll hints.

__read_only, __write_only, __read_write (read_only, write_only, read_write)¶

The access qualifiers must be used with image object arguments or pipe arguments to declare if they are being read or written by a kernel or function.

The read_only/__read_only, write_only/__write_only and read_write/__read_write names are reserved for use as access qualifiers and shall not be used otherwise.

kernel void
foo (read_only image2d_t imageA,
     write_only image2d_t imageB) {
  ...
}

In the above example imageA is a read-only 2D image object, and imageB is a write-only 2D image object.

The read_write (or __read_write) qualifier can not be used with pipe.

More details can be found in the OpenCL C language Spec v2.0, Section 6.6.

__attribute__((opencl_unroll_hint))¶

The opencl_unroll_hint attribute qualifier can be used to specify that a loop (for, while and do loops) can be unrolled. This attribute qualifier can be used to specify full unrolling or partial unrolling by a specified amount. This is a compiler hint and the compiler may ignore this directive. See OpenCL v2.0 s6.11.5 for details.

amdgpu_num_sgpr¶

Clang supports the __attribute__((amdgpu_num_sgpr(<num_registers>))) attribute on AMD Southern Islands GPUs and later for controlling the number of scalar registers. A typical value would be between 8 and 104 in increments of 8.

Due to common instruction constraints, an additional 2-4 SGPRs are typically required for internal use depending on features used. This value is a hint for the total number of SGPRs to use, and not the number of user SGPRs, so no special consideration needs to be given for these.

amdgpu_num_vgpr¶

Clang supports the __attribute__((amdgpu_num_vgpr(<num_registers>))) attribute on AMD Southern Islands GPUs and later for controlling the number of vector registers. A typical value would be between 4 and 256 in increments of 4.

fastcall (gnu::fastcall, __fastcall, _fastcall)¶

On 32-bit x86 targets, this attribute changes the calling convention of a function to use ECX and EDX as register parameters and clear parameters off of the stack on return. This convention does not support variadic calls or unprototyped functions in C, and has no effect on x86_64 targets. This calling convention is supported primarily for compatibility with existing code. Users seeking register parameters should use the regparm attribute, which does not require callee-cleanup. See the documentation for __fastcall on MSDN.

ms_abi (gnu::ms_abi)¶

On non-Windows x86_64 targets, this attribute changes the calling convention of a function to match the default convention used on Windows x86_64. This attribute has no effect on Windows targets or non-x86_64 targets.

pcs (gnu::pcs)¶

On ARM targets, this attribute can be used to select calling conventions similar to stdcall on x86. Valid parameter values are “aapcs” and “aapcs-vfp”.

preserve_all¶

On X86-64 and AArch64 targets, this attribute changes the calling convention of a function. The preserve_all calling convention attempts to make the code in the caller even less intrusive than the preserve_most calling convention. This calling convention also behaves identical to the C calling convention on how arguments and return values are passed, but it uses a different set of caller/callee-saved registers. This removes the burden of saving and recovering a large register set before and after the call in the caller. If the arguments are passed in callee-saved registers, then they will be preserved by the callee across the call. This doesn’t apply for values returned in callee-saved registers.

• On X86-64 the callee preserves all general purpose registers, except for R11. R11 can be used as a scratch register. Furthermore it also preserves all floating-point registers (XMMs/YMMs).

The idea behind this convention is to support calls to runtime functions that don’t need to call out to any other functions.

This calling convention, like the preserve_most calling convention, will be used by a future version of the Objective-C runtime and should be considered experimental at this time.

preserve_most¶

On X86-64 and AArch64 targets, this attribute changes the calling convention of a function. The preserve_most calling convention attempts to make the code in the caller as unintrusive as possible. This convention behaves identically to the C calling convention on how arguments and return values are passed, but it uses a different set of caller/callee-saved registers. This alleviates the burden of saving and recovering a large register set before and after the call in the caller. If the arguments are passed in callee-saved registers, then they will be preserved by the callee across the call. This doesn’t apply for values returned in callee-saved registers.

• On X86-64 the callee preserves all general purpose registers, except for R11. R11 can be used as a scratch register. Floating-point registers (XMMs/YMMs) are not preserved and need to be saved by the caller.

The idea behind this convention is to support calls to runtime functions that have a hot path and a cold path. The hot path is usually a small piece of code that doesn’t use many registers. The cold path might need to call out to another function and therefore only needs to preserve the caller-saved registers, which haven’t already been saved by the caller. The preserve_most calling convention is very similar to the cold calling convention in terms of caller/callee-saved registers, but they are used for different types of function calls. coldcc is for function calls that are rarely executed, whereas preserve_most function calls are intended to be on the hot path and definitely executed a lot. Furthermore preserve_most doesn’t prevent the inliner from inlining the function call.

This calling convention will be used by a future version of the Objective-C runtime and should therefore still be considered experimental at this time. Although this convention was created to optimize certain runtime calls to the Objective-C runtime, it is not limited to this runtime and might be used by other runtimes in the future too. The current implementation only supports X86-64 and AArch64, but the intention is to support more architectures in the future.

regparm (gnu::regparm)¶

On 32-bit x86 targets, the regparm attribute causes the compiler to pass the first three integer parameters in EAX, EDX, and ECX instead of on the stack. This attribute has no effect on variadic functions, and all parameters are passed via the stack as normal.

stdcall (gnu::stdcall, __stdcall, _stdcall)¶

On 32-bit x86 targets, this attribute changes the calling convention of a function to clear parameters off of the stack on return. This convention does not support variadic calls or unprototyped functions in C, and has no effect on x86_64 targets. This calling convention is used widely by the Windows API and COM applications. See the documentation for __stdcall on MSDN.

thiscall (gnu::thiscall, __thiscall, _thiscall)¶

On 32-bit x86 targets, this attribute changes the calling convention of a function to use ECX for the first parameter (typically the implicit this parameter of C++ methods) and clear parameters off of the stack on return. This convention does not support variadic calls or unprototyped functions in C, and has no effect on x86_64 targets. See the documentation for __thiscall on MSDN.

vectorcall (__vectorcall, _vectorcall)¶

On 32-bit x86 and x86_64 targets, this attribute changes the calling convention of a function to pass vector parameters in SSE registers.

On 32-bit x86 targets, this calling convention is similar to __fastcall. The first two integer parameters are passed in ECX and EDX. Subsequent integer parameters are passed in memory, and callee clears the stack. On x86_64 targets, the callee does not clear the stack, and integer parameters are passed in RCX, RDX, R8, and R9 as is done for the default Windows x64 calling convention.

On both 32-bit x86 and x86_64 targets, vector and floating point arguments are passed in XMM0-XMM5. Homogenous vector aggregates of up to four elements are passed in sequential SSE registers if enough are available. If AVX is enabled, 256 bit vectors are passed in YMM0-YMM5. Any vector or aggregate type that cannot be passed in registers for any reason is passed by reference, which allows the caller to align the parameter memory.

See the documentation for __vectorcall on MSDN for more details.

callable_when¶

Use __attribute__((callable_when(...))) to indicate what states a method may be called in. Valid states are unconsumed, consumed, or unknown. Each argument to this attribute must be a quoted string. E.g.:

__attribute__((callable_when("unconsumed", "unknown")))

consumable¶

Each class that uses any of the typestate annotations must first be marked using the consumable attribute. Failure to do so will result in a warning.

This attribute accepts a single parameter that must be one of the following: unknown, consumed, or unconsumed.

param_typestate¶

This attribute specifies expectations about function parameters. Calls to an function with annotated parameters will issue a warning if the corresponding argument isn’t in the expected state. The attribute is also used to set the initial state of the parameter when analyzing the function’s body.

return_typestate¶

The return_typestate attribute can be applied to functions or parameters. When applied to a function the attribute specifies the state of the returned value. The function’s body is checked to ensure that it always returns a value in the specified state. On the caller side, values returned by the annotated function are initialized to the given state.

When applied to a function parameter it modifies the state of an argument after a call to the function returns. The function’s body is checked to ensure that the parameter is in the expected state before returning.

set_typestate¶

Annotate methods that transition an object into a new state with __attribute__((set_typestate(new_state))). The new state must be unconsumed, consumed, or unknown.

test_typestate¶

Use __attribute__((test_typestate(tested_state))) to indicate that a method returns true if the object is in the specified state..

argument_with_type_tag¶

Use __attribute__((argument_with_type_tag(arg_kind, arg_idx, type_tag_idx))) on a function declaration to specify that the function accepts a type tag that determines the type of some other argument. arg_kind is an identifier that should be used when annotating all applicable type tags.

This attribute is primarily useful for checking arguments of variadic functions (pointer_with_type_tag can be used in most non-variadic cases).

For example:

int fcntl(int fd, int cmd, ...)
    __attribute__(( argument_with_type_tag(fcntl,3,2) ));

pointer_with_type_tag¶

Use __attribute__((pointer_with_type_tag(ptr_kind, ptr_idx, type_tag_idx))) on a function declaration to specify that the function accepts a type tag that determines the pointee type of some other pointer argument.

For example:

int MPI_Send(void *buf, int count, MPI_Datatype datatype /*, other args omitted */)
    __attribute__(( pointer_with_type_tag(mpi,1,3) ));

type_tag_for_datatype¶

Clang supports annotating type tags of two forms.

• Type tag that is an expression containing a reference to some declared identifier. Use __attribute__((type_tag_for_datatype(kind, type))) on a declaration with that identifier:

  extern struct mpi_datatype mpi_datatype_int
      __attribute__(( type_tag_for_datatype(mpi,int) ));
  #define MPI_INT ((MPI_Datatype) &mpi_datatype_int)
  

• Type tag that is an integral literal. Introduce a static const variable with a corresponding initializer value and attach __attribute__((type_tag_for_datatype(kind, type))) on that declaration, for example:

  #define MPI_INT ((MPI_Datatype) 42)
  static const MPI_Datatype mpi_datatype_int
      __attribute__(( type_tag_for_datatype(mpi,int) )) = 42
  

The attribute also accepts an optional third argument that determines how the expression is compared to the type tag. There are two supported flags:

• layout_compatible will cause types to be compared according to layout-compatibility rules (C++11 [class.mem] p 17, 18). This is implemented to support annotating types like MPI_DOUBLE_INT.

  For example:

  /* In mpi.h */
  struct internal_mpi_double_int { double d; int i; };
  extern struct mpi_datatype mpi_datatype_double_int
      __attribute__(( type_tag_for_datatype(mpi, struct internal_mpi_double_int, layout_compatible) ));
  
  #define MPI_DOUBLE_INT ((MPI_Datatype) &mpi_datatype_double_int)
  
  /* In user code */
  struct my_pair { double a; int b; };
  struct my_pair *buffer;
  MPI_Send(buffer, 1, MPI_DOUBLE_INT /*, ...  */); // no warning
  
  struct my_int_pair { int a; int b; }
  struct my_int_pair *buffer2;
  MPI_Send(buffer2, 1, MPI_DOUBLE_INT /*, ...  */); // warning: actual buffer element
                                                    // type 'struct my_int_pair'
                                                    // doesn't match specified MPI_Datatype
  

• must_be_null specifies that the expression should be a null pointer constant, for example:

  /* In mpi.h */
  extern struct mpi_datatype mpi_datatype_null
      __attribute__(( type_tag_for_datatype(mpi, void, must_be_null) ));
  
  #define MPI_DATATYPE_NULL ((MPI_Datatype) &mpi_datatype_null)
  
  /* In user code */
  MPI_Send(buffer, 1, MPI_DATATYPE_NULL /*, ...  */); // warning: MPI_DATATYPE_NULL
                                                      // was specified but buffer
                                                      // is not a null pointer
  

constant (__constant)¶

The constant address space attribute signals that an object is located in a constant (non-modifiable) memory region. It is available to all work items. Any type can be annotated with the constant address space attribute. Objects with the constant address space qualifier can be declared in any scope and must have an initializer.

generic (__generic)¶

The generic address space attribute is only available with OpenCL v2.0 and later. It can be used with pointer types. Variables in global and local scope and function parameters in non-kernel functions can have the generic address space type attribute. It is intended to be a placeholder for any other address space except for ‘__constant’ in OpenCL code which can be used with multiple address spaces.

global (__global)¶

The global address space attribute specifies that an object is allocated in global memory, which is accessible by all work items. The content stored in this memory area persists between kernel executions. Pointer types to the global address space are allowed as function parameters or local variables. Starting with OpenCL v2.0, the global address space can be used with global (program scope) variables and static local variable as well.

local (__local)¶

The local address space specifies that an object is allocated in the local (work group) memory area, which is accessible to all work items in the same work group. The content stored in this memory region is not accessible after the kernel execution ends. In a kernel function scope, any variable can be in the local address space. In other scopes, only pointer types to the local address space are allowed. Local address space variables cannot have an initializer.

private (__private)¶

The private address space specifies that an object is allocated in the private (work item) memory. Other work items cannot access the same memory area and its content is destroyed after work item execution ends. Local variables can be declared in the private address space. Function arguments are always in the private address space. Kernel function arguments of a pointer or an array type cannot point to the private address space.

nonnull (gnu::nonnull)¶

The nonnull attribute indicates that some function parameters must not be null, and can be used in several different ways. It’s original usage (from GCC) is as a function (or Objective-C method) attribute that specifies which parameters of the function are nonnull in a comma-separated list. For example:

extern void * my_memcpy (void *dest, const void *src, size_t len)
                __attribute__((nonnull (1, 2)));

Here, the nonnull attribute indicates that parameters 1 and 2 cannot have a null value. Omitting the parenthesized list of parameter indices means that all parameters of pointer type cannot be null:

extern void * my_memcpy (void *dest, const void *src, size_t len)
                __attribute__((nonnull));

Clang also allows the nonnull attribute to be placed directly on a function (or Objective-C method) parameter, eliminating the need to specify the parameter index ahead of type. For example:

extern void * my_memcpy (void *dest __attribute__((nonnull)),
                         const void *src __attribute__((nonnull)), size_t len);

Note that the nonnull attribute indicates that passing null to a non-null parameter is undefined behavior, which the optimizer may take advantage of to, e.g., remove null checks. The _Nonnull type qualifier indicates that a pointer cannot be null in a more general manner (because it is part of the type system) and does not imply undefined behavior, making it more widely applicable.

returns_nonnull (gnu::returns_nonnull)¶

The returns_nonnull attribute indicates that a particular function (or Objective-C method) always returns a non-null pointer. For example, a particular system malloc might be defined to terminate a process when memory is not available rather than returning a null pointer:

extern void * malloc (size_t size) __attribute__((returns_nonnull));

The returns_nonnull attribute implies that returning a null pointer is undefined behavior, which the optimizer may take advantage of. The _Nonnull type qualifier indicates that a pointer cannot be null in a more general manner (because it is part of the type system) and does not imply undefined behavior, making it more widely applicable

_Nonnull¶

The _Nonnull nullability qualifier indicates that null is not a meaningful value for a value of the _Nonnull pointer type. For example, given a declaration such as:

int fetch(int * _Nonnull ptr);

a caller of fetch should not provide a null value, and the compiler will produce a warning if it sees a literal null value passed to fetch. Note that, unlike the declaration attribute nonnull, the presence of _Nonnull does not imply that passing null is undefined behavior: fetch is free to consider null undefined behavior or (perhaps for backward-compatibility reasons) defensively handle null.

_Null_unspecified¶

The _Null_unspecified nullability qualifier indicates that neither the _Nonnull nor _Nullable qualifiers make sense for a particular pointer type. It is used primarily to indicate that the role of null with specific pointers in a nullability-annotated header is unclear, e.g., due to overly-complex implementations or historical factors with a long-lived API.

_Nullable¶

The _Nullable nullability qualifier indicates that a value of the _Nullable pointer type can be null. For example, given:

int fetch_or_zero(int * _Nullable ptr);

a caller of fetch_or_zero can provide null.