[llvm-branch-commits] [cfe-branch] r338575 - Generate docs/AttributeReference.rst
Hans Wennborg via llvm-branch-commits
llvm-branch-commits at lists.llvm.org
Wed Aug 1 08:28:01 PDT 2018
Author: hans
Date: Wed Aug 1 08:28:01 2018
New Revision: 338575
URL: http://llvm.org/viewvc/llvm-project?rev=338575&view=rev
Log:
Generate docs/AttributeReference.rst
$ bin/clang-tblgen -gen-attr-docs -I../cfe.src/include \
../cfe.src/include/clang/Basic/Attr.td \
-o ../cfe.src/docs/AttributeReference.rst
Modified:
cfe/branches/release_70/docs/AttributeReference.rst
Modified: cfe/branches/release_70/docs/AttributeReference.rst
URL: http://llvm.org/viewvc/llvm-project/cfe/branches/release_70/docs/AttributeReference.rst?rev=338575&r1=338574&r2=338575&view=diff
==============================================================================
--- cfe/branches/release_70/docs/AttributeReference.rst (original)
+++ cfe/branches/release_70/docs/AttributeReference.rst Wed Aug 1 08:28:01 2018
@@ -1,13 +1,3899 @@
..
-------------------------------------------------------------------
NOTE: This file is automatically generated by running clang-tblgen
- -gen-attr-docs. Do not edit this file by hand!! The contents for
- this file are automatically generated by a server-side process.
-
- Please do not commit this file. The file exists for local testing
- purposes only.
+ -gen-attr-docs. Do not edit this file by hand!!
-------------------------------------------------------------------
===================
Attributes in Clang
-===================
\ No newline at end of file
+===================
+.. contents::
+ :local:
+
+Introduction
+============
+
+This page lists the attributes currently supported by Clang.
+
+Function Attributes
+===================
+
+
+#pragma omp declare simd
+------------------------
+.. csv-table:: Supported Syntaxes
+ :header: "GNU", "C++11", "C2x", "__declspec", "Keyword", "Pragma", "Pragma clang attribute"
+
+ "","","","","", "X", ""
+
+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:
+
+ .. code-block:: none
+
+ #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:
+
+ .. code-block:: none
+
+ simdlen(length)
+ linear(argument-list[:constant-linear-step])
+ aligned(argument-list[:alignment])
+ uniform(argument-list)
+ inbranch
+ notinbranch
+
+
+#pragma omp declare target
+--------------------------
+.. csv-table:: Supported Syntaxes
+ :header: "GNU", "C++11", "C2x", "__declspec", "Keyword", "Pragma", "Pragma clang attribute"
+
+ "","","","","", "X", ""
+
+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:
+
+ .. code-block:: c
+
+ #pragma omp declare target new-line
+ declarations-definition-seq
+ #pragma omp end declare target new-line
+
+
+_Noreturn
+---------
+.. csv-table:: Supported Syntaxes
+ :header: "GNU", "C++11", "C2x", "__declspec", "Keyword", "Pragma", "Pragma clang attribute"
+
+ "","","","","X", "", ""
+
+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.
+
+
+abi_tag (gnu::abi_tag)
+----------------------
+.. csv-table:: Supported Syntaxes
+ :header: "GNU", "C++11", "C2x", "__declspec", "Keyword", "Pragma", "Pragma clang attribute"
+
+ "X","X","","","", "", "X"
+
+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. Therefore, 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)
+-----------------------------------------------------------------------------------------------------------
+.. csv-table:: Supported Syntaxes
+ :header: "GNU", "C++11", "C2x", "__declspec", "Keyword", "Pragma", "Pragma clang attribute"
+
+ "X","X","","","", "", ""
+
+Marks a function as acquiring a capability.
+
+
+alloc_align (gnu::alloc_align)
+------------------------------
+.. csv-table:: Supported Syntaxes
+ :header: "GNU", "C++11", "C2x", "__declspec", "Keyword", "Pragma", "Pragma clang attribute"
+
+ "X","X","","","", "", ""
+
+Use ``__attribute__((alloc_align(<alignment>))`` on a function
+declaration to specify that the return value of the function (which must be a
+pointer type) is at least as aligned as the value of the indicated parameter. The
+parameter is given by its index in the list of formal parameters; the first
+parameter has index 1 unless the function is a C++ non-static member function,
+in which case the first parameter has index 2 to account for the implicit ``this``
+parameter.
+
+.. code-block:: c++
+
+ // The returned pointer has the alignment specified by the first parameter.
+ void *a(size_t align) __attribute__((alloc_align(1)));
+
+ // The returned pointer has the alignment specified by the second parameter.
+ void *b(void *v, size_t align) __attribute__((alloc_align(2)));
+
+ // The returned pointer has the alignment specified by the second visible
+ // parameter, however it must be adjusted for the implicit 'this' parameter.
+ void *Foo::b(void *v, size_t align) __attribute__((alloc_align(3)));
+
+Note that this attribute merely informs the compiler that a function always
+returns a sufficiently aligned pointer. It does not cause the compiler to
+emit code to enforce that alignment. The behavior is undefined if the returned
+poitner is not sufficiently aligned.
+
+
+alloc_size (gnu::alloc_size)
+----------------------------
+.. csv-table:: Supported Syntaxes
+ :header: "GNU", "C++11", "C2x", "__declspec", "Keyword", "Pragma", "Pragma clang attribute"
+
+ "X","X","","","", "", "X"
+
+The ``alloc_size`` attribute can be placed on functions that return pointers in
+order to hint to the compiler how many bytes of memory will be available at the
+returned pointer. ``alloc_size`` takes one or two arguments.
+
+- ``alloc_size(N)`` implies that argument number N equals the number of
+ available bytes at the returned pointer.
+- ``alloc_size(N, M)`` implies that the product of argument number N and
+ argument number M equals the number of available bytes at the returned
+ pointer.
+
+Argument numbers are 1-based.
+
+An example of how to use ``alloc_size``
+
+.. code-block:: c
+
+ void *my_malloc(int a) __attribute__((alloc_size(1)));
+ void *my_calloc(int a, int b) __attribute__((alloc_size(1, 2)));
+
+ int main() {
+ void *const p = my_malloc(100);
+ assert(__builtin_object_size(p, 0) == 100);
+ void *const a = my_calloc(20, 5);
+ assert(__builtin_object_size(a, 0) == 100);
+ }
+
+.. Note:: This attribute works differently in clang than it does in GCC.
+ Specifically, clang will only trace ``const`` pointers (as above); we give up
+ on pointers that are not marked as ``const``. In the vast majority of cases,
+ this is unimportant, because LLVM has support for the ``alloc_size``
+ attribute. However, this may cause mildly unintuitive behavior when used with
+ other attributes, such as ``enable_if``.
+
+
+artificial (gnu::artificial)
+----------------------------
+.. csv-table:: Supported Syntaxes
+ :header: "GNU", "C++11", "C2x", "__declspec", "Keyword", "Pragma", "Pragma clang attribute"
+
+ "X","X","","","", "", ""
+
+The ``artificial`` attribute can be applied to an inline function. If such a
+function is inlined, the attribute indicates that debuggers should associate
+the resulting instructions with the call site, rather than with the
+corresponding line within the inlined callee.
+
+
+assert_capability (assert_shared_capability, clang::assert_capability, clang::assert_shared_capability)
+-------------------------------------------------------------------------------------------------------
+.. csv-table:: Supported Syntaxes
+ :header: "GNU", "C++11", "C2x", "__declspec", "Keyword", "Pragma", "Pragma clang attribute"
+
+ "X","X","","","", "", ""
+
+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)
+------------------------------------
+.. csv-table:: Supported Syntaxes
+ :header: "GNU", "C++11", "C2x", "__declspec", "Keyword", "Pragma", "Pragma clang attribute"
+
+ "X","X","","","", "", "X"
+
+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.
+
+.. code-block:: c++
+
+ // 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 (clang::availability, clang::availability)
+-------------------------------------------------------
+.. csv-table:: Supported Syntaxes
+ :header: "GNU", "C++11", "C2x", "__declspec", "Keyword", "Pragma", "Pragma clang attribute"
+
+ "X","X","X","","", "", "X"
+
+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``:
+
+.. code-block:: c++
+
+ void f(void) __attribute__((availability(macos,introduced=10.4,deprecated=10.6,obsoleted=10.7)));
+
+The availability attribute states that ``f`` was introduced in macOS 10.4,
+deprecated in macOS 10.6, and obsoleted in macOS 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 macOS 10.5, a call to ``f()``
+succeeds. If Clang is instructed to compile code for macOS 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 macOS 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 macOS 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
+<https://developer.apple.com/library/mac/#documentation/MacOSX/Conceptual/BPFrameworks/Concepts/WeakLinking.html>`_,
+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:
+
+.. code-block:: c
+
+ 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.,:
+
+.. code-block:: objc
+
+ @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
+
+Starting with the macOS 10.12 SDK, the ``API_AVAILABLE`` macro from
+``<os/availability.h>`` can simplify the spelling:
+
+.. code-block:: objc
+
+ @interface A
+ - (id)method API_AVAILABLE(macos(10.11)));
+ - (id)otherMethod API_AVAILABLE(macos(10.11), ios(11.0));
+ @end
+
+Also see the documentation for `@available
+<http://clang.llvm.org/docs/LanguageExtensions.html#objective-c-available>`_
+
+
+carries_dependency
+------------------
+.. csv-table:: Supported Syntaxes
+ :header: "GNU", "C++11", "C2x", "__declspec", "Keyword", "Pragma", "Pragma clang attribute"
+
+ "X","X","","","", "", "X"
+
+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.
+
+
+code_seg
+--------
+.. csv-table:: Supported Syntaxes
+ :header: "GNU", "C++11", "C2x", "__declspec", "Keyword", "Pragma", "Pragma clang attribute"
+
+ "","","","X","", "", ""
+
+The ``__declspec(code_seg)`` attribute enables the placement of code into separate
+named segments that can be paged or locked in memory individually. This attribute
+is used to control the placement of instantiated templates and compiler-generated
+code. See the documentation for `__declspec(code_seg)`_ on MSDN.
+
+.. _`__declspec(code_seg)`: http://msdn.microsoft.com/en-us/library/dn636922.aspx
+
+
+convergent (clang::convergent, clang::convergent)
+-------------------------------------------------
+.. csv-table:: Supported Syntaxes
+ :header: "GNU", "C++11", "C2x", "__declspec", "Keyword", "Pragma", "Pragma clang attribute"
+
+ "X","X","X","","", "", "X"
+
+The ``convergent`` attribute can be placed on a function declaration. It is
+translated into the LLVM ``convergent`` attribute, which indicates that the call
+instructions of a function with this attribute cannot be made control-dependent
+on any additional values.
+
+In languages designed for SPMD/SIMT programming model, e.g. OpenCL or CUDA,
+the call instructions of a function with this attribute must be executed by
+all work items or threads in a work group or sub group.
+
+This attribute is different from ``noduplicate`` because it allows duplicating
+function calls if it can be proved that the duplicated function calls are
+not made control-dependent on any additional values, e.g., unrolling a loop
+executed by all work items.
+
+Sample usage:
+.. code-block:: c
+
+ void convfunc(void) __attribute__((convergent));
+ // Setting it as a C++11 attribute is also valid in a C++ program.
+ // void convfunc(void) [[clang::convergent]];
+
+
+cpu_dispatch (clang::cpu_dispatch, clang::cpu_dispatch)
+-------------------------------------------------------
+.. csv-table:: Supported Syntaxes
+ :header: "GNU", "C++11", "C2x", "__declspec", "Keyword", "Pragma", "Pragma clang attribute"
+
+ "X","X","X","","", "", "X"
+
+The ``cpu_specific`` and ``cpu_dispatch`` attributes are used to define and
+resolve multiversioned functions. This form of multiversioning provides a
+mechanism for declaring versions across translation units and manually
+specifying the resolved function list. A specified CPU defines a set of minimum
+features that are required for the function to be called. The result of this is
+that future processors execute the most restrictive version of the function the
+new processor can execute.
+
+Function versions are defined with ``cpu_specific``, which takes one or more CPU
+names as a parameter. For example:
+
+.. code-block:: c
+
+ // Declares and defines the ivybridge version of single_cpu.
+ __attribute__((cpu_specific(ivybridge)))
+ void single_cpu(void){}
+
+ // Declares and defines the atom version of single_cpu.
+ __attribute__((cpu_specific(atom)))
+ void single_cpu(void){}
+
+ // Declares and defines both the ivybridge and atom version of multi_cpu.
+ __attribute__((cpu_specific(ivybridge, atom)))
+ void multi_cpu(void){}
+
+A dispatching (or resolving) function can be declared anywhere in a project's
+source code with ``cpu_dispatch``. This attribute takes one or more CPU names
+as a parameter (like ``cpu_specific``). Functions marked with ``cpu_dispatch``
+are not expected to be defined, only declared. If such a marked function has a
+definition, any side effects of the function are ignored; trivial function
+bodies are permissible for ICC compatibility.
+
+.. code-block:: c
+
+ // Creates a resolver for single_cpu above.
+ __attribute__((cpu_dispatch(ivybridge, atom)))
+ void single_cpu(void){}
+
+ // Creates a resolver for multi_cpu, but adds a 3rd version defined in another
+ // translation unit.
+ __attribute__((cpu_dispatch(ivybridge, atom, sandybridge)))
+ void multi_cpu(void){}
+
+Note that it is possible to have a resolving function that dispatches based on
+more or fewer options than are present in the program. Specifying fewer will
+result in the omitted options not being considered during resolution. Specifying
+a version for resolution that isn't defined in the program will result in a
+linking failure.
+
+It is also possible to specify a CPU name of ``generic`` which will be resolved
+if the executing processor doesn't satisfy the features required in the CPU
+name. The behavior of a program executing on a processor that doesn't satisfy
+any option of a multiversioned function is undefined.
+
+
+cpu_specific (clang::cpu_specific, clang::cpu_specific)
+-------------------------------------------------------
+.. csv-table:: Supported Syntaxes
+ :header: "GNU", "C++11", "C2x", "__declspec", "Keyword", "Pragma", "Pragma clang attribute"
+
+ "X","X","X","","", "", "X"
+
+The ``cpu_specific`` and ``cpu_dispatch`` attributes are used to define and
+resolve multiversioned functions. This form of multiversioning provides a
+mechanism for declaring versions across translation units and manually
+specifying the resolved function list. A specified CPU defines a set of minimum
+features that are required for the function to be called. The result of this is
+that future processors execute the most restrictive version of the function the
+new processor can execute.
+
+Function versions are defined with ``cpu_specific``, which takes one or more CPU
+names as a parameter. For example:
+
+.. code-block:: c
+
+ // Declares and defines the ivybridge version of single_cpu.
+ __attribute__((cpu_specific(ivybridge)))
+ void single_cpu(void){}
+
+ // Declares and defines the atom version of single_cpu.
+ __attribute__((cpu_specific(atom)))
+ void single_cpu(void){}
+
+ // Declares and defines both the ivybridge and atom version of multi_cpu.
+ __attribute__((cpu_specific(ivybridge, atom)))
+ void multi_cpu(void){}
+
+A dispatching (or resolving) function can be declared anywhere in a project's
+source code with ``cpu_dispatch``. This attribute takes one or more CPU names
+as a parameter (like ``cpu_specific``). Functions marked with ``cpu_dispatch``
+are not expected to be defined, only declared. If such a marked function has a
+definition, any side effects of the function are ignored; trivial function
+bodies are permissible for ICC compatibility.
+
+.. code-block:: c
+
+ // Creates a resolver for single_cpu above.
+ __attribute__((cpu_dispatch(ivybridge, atom)))
+ void single_cpu(void){}
+
+ // Creates a resolver for multi_cpu, but adds a 3rd version defined in another
+ // translation unit.
+ __attribute__((cpu_dispatch(ivybridge, atom, sandybridge)))
+ void multi_cpu(void){}
+
+Note that it is possible to have a resolving function that dispatches based on
+more or fewer options than are present in the program. Specifying fewer will
+result in the omitted options not being considered during resolution. Specifying
+a version for resolution that isn't defined in the program will result in a
+linking failure.
+
+It is also possible to specify a CPU name of ``generic`` which will be resolved
+if the executing processor doesn't satisfy the features required in the CPU
+name. The behavior of a program executing on a processor that doesn't satisfy
+any option of a multiversioned function is undefined.
+
+
+deprecated (gnu::deprecated)
+----------------------------
+.. csv-table:: Supported Syntaxes
+ :header: "GNU", "C++11", "C2x", "__declspec", "Keyword", "Pragma", "Pragma clang attribute"
+
+ "X","X","X","X","", "", ""
+
+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``:
+
+.. code-block:: c++
+
+ 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.
+
+
+diagnose_if
+-----------
+.. csv-table:: Supported Syntaxes
+ :header: "GNU", "C++11", "C2x", "__declspec", "Keyword", "Pragma", "Pragma clang attribute"
+
+ "X","","","","", "", ""
+
+The ``diagnose_if`` attribute can be placed on function declarations to emit
+warnings or errors at compile-time if calls to the attributed function meet
+certain user-defined criteria. For example:
+
+.. code-block:: c
+
+ void abs(int a)
+ __attribute__((diagnose_if(a >= 0, "Redundant abs call", "warning")));
+ void must_abs(int a)
+ __attribute__((diagnose_if(a >= 0, "Redundant abs call", "error")));
+
+ int val = abs(1); // warning: Redundant abs call
+ int val2 = must_abs(1); // error: Redundant abs call
+ int val3 = abs(val);
+ int val4 = must_abs(val); // Because run-time checks are not emitted for
+ // diagnose_if attributes, this executes without
+ // issue.
+
+
+``diagnose_if`` is closely related to ``enable_if``, with a few key differences:
+
+* Overload resolution is not aware of ``diagnose_if`` attributes: they're
+ considered only after we select the best candidate from a given candidate set.
+* Function declarations that differ only in their ``diagnose_if`` attributes are
+ considered to be redeclarations of the same function (not overloads).
+* If the condition provided to ``diagnose_if`` cannot be evaluated, no
+ diagnostic will be emitted.
+
+Otherwise, ``diagnose_if`` is essentially the logical negation of ``enable_if``.
+
+As a result of bullet number two, ``diagnose_if`` attributes will stack on the
+same function. For example:
+
+.. code-block:: c
+
+ int foo() __attribute__((diagnose_if(1, "diag1", "warning")));
+ int foo() __attribute__((diagnose_if(1, "diag2", "warning")));
+
+ int bar = foo(); // warning: diag1
+ // warning: diag2
+ int (*fooptr)(void) = foo; // warning: diag1
+ // warning: diag2
+
+ constexpr int supportsAPILevel(int N) { return N < 5; }
+ int baz(int a)
+ __attribute__((diagnose_if(!supportsAPILevel(10),
+ "Upgrade to API level 10 to use baz", "error")));
+ int baz(int a)
+ __attribute__((diagnose_if(!a, "0 is not recommended.", "warning")));
+
+ int (*bazptr)(int) = baz; // error: Upgrade to API level 10 to use baz
+ int v = baz(0); // error: Upgrade to API level 10 to use baz
+
+Query for this feature with ``__has_attribute(diagnose_if)``.
+
+
+disable_tail_calls (clang::disable_tail_calls, clang::disable_tail_calls)
+-------------------------------------------------------------------------
+.. csv-table:: Supported Syntaxes
+ :header: "GNU", "C++11", "C2x", "__declspec", "Keyword", "Pragma", "Pragma clang attribute"
+
+ "X","X","X","","", "", "X"
+
+The ``disable_tail_calls`` attribute instructs the backend to not perform tail call optimization inside the marked function.
+
+For example:
+
+ .. code-block:: c
+
+ 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.
+
+ .. code-block:: c++
+
+ 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
+---------
+.. csv-table:: Supported Syntaxes
+ :header: "GNU", "C++11", "C2x", "__declspec", "Keyword", "Pragma", "Pragma clang attribute"
+
+ "X","","","","", "", "X"
+
+.. Note:: Some features of this attribute are experimental. The meaning of
+ multiple enable_if attributes on a single declaration is subject to change in
+ a future version of clang. Also, the ABI is not standardized and the name
+ mangling may change in future versions. To avoid that, use asm labels.
+
+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.
+
+.. code-block:: 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:
+
+.. code-block:: c++
+
+ __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.
+
+.. code-block:: c++
+
+ 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:
+
+.. code-block:: c
+
+ 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``:
+
+.. code-block:: c++
+
+ 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.
+
+
+external_source_symbol (clang::external_source_symbol, clang::external_source_symbol)
+-------------------------------------------------------------------------------------
+.. csv-table:: Supported Syntaxes
+ :header: "GNU", "C++11", "C2x", "__declspec", "Keyword", "Pragma", "Pragma clang attribute"
+
+ "X","X","X","","", "", "X"
+
+The ``external_source_symbol`` attribute specifies that a declaration originates
+from an external source and describes the nature of that source.
+
+The fact that Clang is capable of recognizing declarations that were defined
+externally can be used to provide better tooling support for mixed-language
+projects or projects that rely on auto-generated code. For instance, an IDE that
+uses Clang and that supports mixed-language projects can use this attribute to
+provide a correct 'jump-to-definition' feature. For a concrete example,
+consider a protocol that's defined in a Swift file:
+
+.. code-block:: swift
+
+ @objc public protocol SwiftProtocol {
+ func method()
+ }
+
+This protocol can be used from Objective-C code by including a header file that
+was generated by the Swift compiler. The declarations in that header can use
+the ``external_source_symbol`` attribute to make Clang aware of the fact
+that ``SwiftProtocol`` actually originates from a Swift module:
+
+.. code-block:: objc
+
+ __attribute__((external_source_symbol(language="Swift",defined_in="module")))
+ @protocol SwiftProtocol
+ @required
+ - (void) method;
+ @end
+
+Consequently, when 'jump-to-definition' is performed at a location that
+references ``SwiftProtocol``, the IDE can jump to the original definition in
+the Swift source file rather than jumping to the Objective-C declaration in the
+auto-generated header file.
+
+The ``external_source_symbol`` attribute is a comma-separated list that includes
+clauses that describe the origin and the nature of the particular declaration.
+Those clauses can be:
+
+language=\ *string-literal*
+ The name of the source language in which this declaration was defined.
+
+defined_in=\ *string-literal*
+ The name of the source container in which the declaration was defined. The
+ exact definition of source container is language-specific, e.g. Swift's
+ source containers are modules, so ``defined_in`` should specify the Swift
+ module name.
+
+generated_declaration
+ This declaration was automatically generated by some tool.
+
+The clauses can be specified in any order. The clauses that are listed above are
+all optional, but the attribute has to have at least one clause.
+
+
+flatten (gnu::flatten)
+----------------------
+.. csv-table:: Supported Syntaxes
+ :header: "GNU", "C++11", "C2x", "__declspec", "Keyword", "Pragma", "Pragma clang attribute"
+
+ "X","X","","","", "", "X"
+
+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.
+
+
+force_align_arg_pointer (gnu::force_align_arg_pointer)
+------------------------------------------------------
+.. csv-table:: Supported Syntaxes
+ :header: "GNU", "C++11", "C2x", "__declspec", "Keyword", "Pragma", "Pragma clang attribute"
+
+ "X","X","","","", "", ""
+
+Use this attribute to force stack alignment.
+
+Legacy x86 code uses 4-byte stack alignment. Newer aligned SSE instructions
+(like 'movaps') that work with the stack require operands to be 16-byte aligned.
+This attribute realigns the stack in the function prologue to make sure the
+stack can be used with SSE instructions.
+
+Note that the x86_64 ABI forces 16-byte stack alignment at the call site.
+Because of this, 'force_align_arg_pointer' is not needed on x86_64, except in
+rare cases where the caller does not align the stack properly (e.g. flow
+jumps from i386 arch code).
+
+ .. code-block:: c
+
+ __attribute__ ((force_align_arg_pointer))
+ void f () {
+ ...
+ }
+
+
+format (gnu::format)
+--------------------
+.. csv-table:: Supported Syntaxes
+ :header: "GNU", "C++11", "C2x", "__declspec", "Keyword", "Pragma", "Pragma clang attribute"
+
+ "X","X","","","", "", ""
+
+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
+<http://gcc.gnu.org/onlinedocs/gcc/Function-Attributes.html>`_ to find details
+about attribute syntax.
+
+Clang implements two kinds of checks with this attribute.
+
+#. 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.
+
+#. 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:
+
+ .. code-block:: c
+
+ __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:
+
+ .. code-block:: c
+
+ __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)
+------------------
+.. csv-table:: Supported Syntaxes
+ :header: "GNU", "C++11", "C2x", "__declspec", "Keyword", "Pragma", "Pragma clang attribute"
+
+ "X","X","","","", "", "X"
+
+``__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, clang::internal_linkage)
+-------------------------------------------------------------------
+.. csv-table:: Supported Syntaxes
+ :header: "GNU", "C++11", "C2x", "__declspec", "Keyword", "Pragma", "Pragma clang attribute"
+
+ "X","X","X","","", "", "X"
+
+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 (ARM)
+---------------
+.. csv-table:: Supported Syntaxes
+ :header: "GNU", "C++11", "C2x", "__declspec", "Keyword", "Pragma", "Pragma clang attribute"
+
+ "X","X","","","", "", ""
+
+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.
+
+
+interrupt (AVR)
+---------------
+.. csv-table:: Supported Syntaxes
+ :header: "GNU", "C++11", "C2x", "__declspec", "Keyword", "Pragma", "Pragma clang attribute"
+
+ "X","X","","","", "", "X"
+
+Clang supports the GNU style ``__attribute__((interrupt))`` attribute on
+AVR 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.
+
+On the AVR, the hardware globally disables interrupts when an interrupt is executed.
+The first instruction of an interrupt handler declared with this attribute is a SEI
+instruction to re-enable interrupts. See also the signal attribute that
+does not insert a SEI instruction.
+
+
+interrupt (MIPS)
+----------------
+.. csv-table:: Supported Syntaxes
+ :header: "GNU", "C++11", "C2x", "__declspec", "Keyword", "Pragma", "Pragma clang attribute"
+
+ "X","X","","","", "", "X"
+
+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".
+
+
+interrupt (RISCV)
+-----------------
+.. csv-table:: Supported Syntaxes
+ :header: "GNU", "C++11", "C2x", "__declspec", "Keyword", "Pragma", "Pragma clang attribute"
+
+ "X","X","","","", "", "X"
+
+Clang supports the GNU style ``__attribute__((interrupt))`` attribute on RISCV
+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.
+
+Permissible values for this parameter are ``user``, ``supervisor``,
+and ``machine``. If there is no parameter, then it defaults to machine.
+
+Repeated interrupt attribute on the same declaration will cause a warning
+to be emitted. In case of repeated declarations, the last one prevails.
+
+Refer to:
+https://gcc.gnu.org/onlinedocs/gcc/RISC-V-Function-Attributes.html
+https://riscv.org/specifications/privileged-isa/
+The RISC-V Instruction Set Manual Volume II: Privileged Architecture
+Version 1.10.
+
+
+kernel
+------
+.. csv-table:: Supported Syntaxes
+ :header: "GNU", "C++11", "C2x", "__declspec", "Keyword", "Pragma", "Pragma clang attribute"
+
+ "X","","","","", "", "X"
+
+``__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.
+
+.. _RenderScript: https://developer.android.com/guide/topics/renderscript/compute.html
+
+
+lifetimebound (clang::lifetimebound)
+------------------------------------
+.. csv-table:: Supported Syntaxes
+ :header: "GNU", "C++11", "C2x", "__declspec", "Keyword", "Pragma", "Pragma clang attribute"
+
+ "X","X","","","", "", ""
+
+The ``lifetimebound`` attribute indicates that a resource owned by
+a function parameter or implicit object parameter
+is retained by the return value of the annotated function
+(or, for a parameter of a constructor, in the value of the constructed object).
+It is only supported in C++.
+
+This attribute provides an experimental implementation of the facility
+described in the C++ committee paper [http://wg21.link/p0936r0](P0936R0),
+and is subject to change as the design of the corresponding functionality
+changes.
+
+
+long_call (gnu::long_call, gnu::far)
+------------------------------------
+.. csv-table:: Supported Syntaxes
+ :header: "GNU", "C++11", "C2x", "__declspec", "Keyword", "Pragma", "Pragma clang attribute"
+
+ "X","X","","","", "", "X"
+
+Clang supports the ``__attribute__((long_call))``, ``__attribute__((far))``,
+and ``__attribute__((near))`` attributes on MIPS targets. These attributes may
+only be added to function declarations and change the code generated
+by the compiler when directly calling the function. The ``near`` attribute
+allows calls to the function to be made using the ``jal`` instruction, which
+requires the function to be located in the same naturally aligned 256MB
+segment as the caller. The ``long_call`` and ``far`` attributes are synonyms
+and require the use of a different call sequence that works regardless
+of the distance between the functions.
+
+These attributes have no effect for position-independent code.
+
+These attributes take priority over command line switches such
+as ``-mlong-calls`` and ``-mno-long-calls``.
+
+
+micromips (gnu::micromips)
+--------------------------
+.. csv-table:: Supported Syntaxes
+ :header: "GNU", "C++11", "C2x", "__declspec", "Keyword", "Pragma", "Pragma clang attribute"
+
+ "X","X","","","", "", "X"
+
+Clang supports the GNU style ``__attribute__((micromips))`` and
+``__attribute__((nomicromips))`` attributes on MIPS targets. These attributes
+may be attached to a function definition and instructs the backend to generate
+or not to generate microMIPS code for that function.
+
+These attributes override the `-mmicromips` and `-mno-micromips` options
+on the command line.
+
+
+min_vector_width (clang::min_vector_width, clang::min_vector_width)
+-------------------------------------------------------------------
+.. csv-table:: Supported Syntaxes
+ :header: "GNU", "C++11", "C2x", "__declspec", "Keyword", "Pragma", "Pragma clang attribute"
+
+ "X","X","X","","", "", "X"
+
+Clang supports the ``__attribute__((min_vector_width(width)))`` attribute. This
+attribute may be attached to a function and informs the backend that this
+function desires vectors of at least this width to be generated. Target-specific
+maximum vector widths still apply. This means even if you ask for something
+larger than the target supports, you will only get what the target supports.
+This attribute is meant to be a hint to control target heuristics that may
+generate narrower vectors than what the target hardware supports.
+
+This is currently used by the X86 target to allow some CPUs that support 512-bit
+vectors to be limited to using 256-bit vectors to avoid frequency penalties.
+This is currently enabled with the ``-prefer-vector-width=256`` command line
+option. The ``min_vector_width`` attribute can be used to prevent the backend
+from trying to split vector operations to match the ``prefer-vector-width``. All
+X86 vector intrinsics from x86intrin.h already set this attribute. Additionally,
+use of any of the X86-specific vector builtins will implicitly set this
+attribute on the calling function. The intent is that explicitly writing vector
+code using the X86 intrinsics will prevent ``prefer-vector-width`` from
+affecting the code.
+
+
+no_caller_saved_registers (gnu::no_caller_saved_registers)
+----------------------------------------------------------
+.. csv-table:: Supported Syntaxes
+ :header: "GNU", "C++11", "C2x", "__declspec", "Keyword", "Pragma", "Pragma clang attribute"
+
+ "X","X","","","", "", ""
+
+Use this attribute to indicate that the specified function has no
+caller-saved registers. That is, all registers are callee-saved except for
+registers used for passing parameters to the function or returning parameters
+from the function.
+The compiler saves and restores any modified registers that were not used for
+passing or returning arguments to the function.
+
+The user can call functions specified with the 'no_caller_saved_registers'
+attribute from an interrupt handler without saving and restoring all
+call-clobbered registers.
+
+Note that 'no_caller_saved_registers' attribute is not a calling convention.
+In fact, it only overrides the decision of which registers should be saved by
+the caller, but not how the parameters are passed from the caller to the callee.
+
+For example:
+
+ .. code-block:: c
+
+ __attribute__ ((no_caller_saved_registers, fastcall))
+ void f (int arg1, int arg2) {
+ ...
+ }
+
+ In this case parameters 'arg1' and 'arg2' will be passed in registers.
+ In this case, on 32-bit x86 targets, the function 'f' will use ECX and EDX as
+ register parameters. However, it will not assume any scratch registers and
+ should save and restore any modified registers except for ECX and EDX.
+
+
+no_sanitize (clang::no_sanitize, clang::no_sanitize)
+----------------------------------------------------
+.. csv-table:: Supported Syntaxes
+ :header: "GNU", "C++11", "C2x", "__declspec", "Keyword", "Pragma", "Pragma clang attribute"
+
+ "X","X","X","","", "", "X"
+
+Use the ``no_sanitize`` attribute on a function or a global variable
+declaration to specify that a particular instrumentation or set of
+instrumentations should not be applied. 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 or variable.
+
+See :ref:`Controlling Code Generation <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)
+-----------------------------------------------------------------------------------------------------------
+.. csv-table:: Supported Syntaxes
+ :header: "GNU", "C++11", "C2x", "__declspec", "Keyword", "Pragma", "Pragma clang attribute"
+
+ "X","X","X","","", "", "X"
+
+.. _langext-address_sanitizer:
+
+Use ``__attribute__((no_sanitize_address))`` on a function or a global
+variable declaration to specify that address safety instrumentation
+(e.g. AddressSanitizer) should not be applied.
+
+
+no_sanitize_memory
+------------------
+.. csv-table:: Supported Syntaxes
+ :header: "GNU", "C++11", "C2x", "__declspec", "Keyword", "Pragma", "Pragma clang attribute"
+
+ "X","X","X","","", "", "X"
+
+.. _langext-memory_sanitizer:
+
+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_sanitize_thread
+------------------
+.. csv-table:: Supported Syntaxes
+ :header: "GNU", "C++11", "C2x", "__declspec", "Keyword", "Pragma", "Pragma clang attribute"
+
+ "X","X","X","","", "", "X"
+
+.. _langext-thread_sanitizer:
+
+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_split_stack (gnu::no_split_stack)
+------------------------------------
+.. csv-table:: Supported Syntaxes
+ :header: "GNU", "C++11", "C2x", "__declspec", "Keyword", "Pragma", "Pragma clang attribute"
+
+ "X","X","","","", "", "X"
+
+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.
+
+
+no_stack_protector (clang::no_stack_protector, clang::no_stack_protector)
+-------------------------------------------------------------------------
+.. csv-table:: Supported Syntaxes
+ :header: "GNU", "C++11", "C2x", "__declspec", "Keyword", "Pragma", "Pragma clang attribute"
+
+ "X","X","X","","", "", "X"
+
+Clang supports the ``__attribute__((no_stack_protector))`` attribute which disables
+the stack protector on the specified function. This attribute is useful for
+selectively disabling the stack protector on some functions when building with
+``-fstack-protector`` compiler option.
+
+For example, it disables the stack protector for the function ``foo`` but function
+``bar`` will still be built with the stack protector with the ``-fstack-protector``
+option.
+
+.. code-block:: c
+
+ int __attribute__((no_stack_protector))
+ foo (int x); // stack protection will be disabled for foo.
+
+ int bar(int y); // bar can be built with the stack protector.
+
+
+noalias
+-------
+.. csv-table:: Supported Syntaxes
+ :header: "GNU", "C++11", "C2x", "__declspec", "Keyword", "Pragma", "Pragma clang attribute"
+
+ "","","","X","", "", ""
+
+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.
+
+
+nocf_check (gnu::nocf_check)
+----------------------------
+.. csv-table:: Supported Syntaxes
+ :header: "GNU", "C++11", "C2x", "__declspec", "Keyword", "Pragma", "Pragma clang attribute"
+
+ "X","X","","","", "", "X"
+
+Jump Oriented Programming attacks rely on tampering with addresses used by
+indirect call / jmp, e.g. redirect control-flow to non-programmer
+intended bytes in the binary.
+X86 Supports Indirect Branch Tracking (IBT) as part of Control-Flow
+Enforcement Technology (CET). IBT instruments ENDBR instructions used to
+specify valid targets of indirect call / jmp.
+The ``nocf_check`` attribute has two roles:
+1. Appertains to a function - do not add ENDBR instruction at the beginning of
+the function.
+2. Appertains to a function pointer - do not track the target function of this
+pointer (by adding nocf_check prefix to the indirect-call instruction).
+
+
+nodiscard, warn_unused_result, clang::warn_unused_result, gnu::warn_unused_result
+---------------------------------------------------------------------------------
+.. csv-table:: Supported Syntaxes
+ :header: "GNU", "C++11", "C2x", "__declspec", "Keyword", "Pragma", "Pragma clang attribute"
+
+ "X","X","X","","", "", "X"
+
+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`.
+
+.. code-block: c++
+ struct [[nodiscard]] error_info { /*...*/ };
+ error_info enable_missile_safety_mode();
+
+ void launch_missiles();
+ void test_missiles() {
+ enable_missile_safety_mode(); // diagnoses
+ launch_missiles();
+ }
+ error_info &foo();
+ void f() { foo(); } // Does not diagnose, error_info is a reference.
+
+
+noduplicate (clang::noduplicate, clang::noduplicate)
+----------------------------------------------------
+.. csv-table:: Supported Syntaxes
+ :header: "GNU", "C++11", "C2x", "__declspec", "Keyword", "Pragma", "Pragma clang attribute"
+
+ "X","X","X","","", "", "X"
+
+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:
+
+.. code-block:: c
+
+ 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:
+
+.. code-block:: c
+
+ if (a > n) {
+ nodupfunc();
+ foo();
+ } else {
+ nodupfunc();
+ bar();
+ }
+
+where the call to "nodupfunc" is duplicated and sunk into the two branches
+of the condition.
+
+
+nomicromips (gnu::nomicromips)
+------------------------------
+.. csv-table:: Supported Syntaxes
+ :header: "GNU", "C++11", "C2x", "__declspec", "Keyword", "Pragma", "Pragma clang attribute"
+
+ "X","X","","","", "", "X"
+
+Clang supports the GNU style ``__attribute__((micromips))`` and
+``__attribute__((nomicromips))`` attributes on MIPS targets. These attributes
+may be attached to a function definition and instructs the backend to generate
+or not to generate microMIPS code for that function.
+
+These attributes override the `-mmicromips` and `-mno-micromips` options
+on the command line.
+
+
+noreturn
+--------
+.. csv-table:: Supported Syntaxes
+ :header: "GNU", "C++11", "C2x", "__declspec", "Keyword", "Pragma", "Pragma clang attribute"
+
+ "","X","","","", "", "X"
+
+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.
+
+
+not_tail_called (clang::not_tail_called, clang::not_tail_called)
+----------------------------------------------------------------
+.. csv-table:: Supported Syntaxes
+ :header: "GNU", "C++11", "C2x", "__declspec", "Keyword", "Pragma", "Pragma clang attribute"
+
+ "X","X","X","","", "", "X"
+
+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:
+
+ .. code-block:: c
+
+ 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:
+
+ .. code-block:: c
+
+ 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:
+
+ .. code-block:: c++
+
+ 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;
+ };
+
+
+nothrow (gnu::nothrow)
+----------------------
+.. csv-table:: Supported Syntaxes
+ :header: "GNU", "C++11", "C2x", "__declspec", "Keyword", "Pragma", "Pragma clang attribute"
+
+ "X","X","","X","", "", "X"
+
+Clang supports the GNU style ``__attribute__((nothrow))`` and Microsoft style
+``__declspec(nothrow)`` attribute as an equivalent of `noexcept` on function
+declarations. This attribute informs the compiler that the annotated function
+does not throw an exception. This prevents exception-unwinding. This attribute
+is particularly useful on functions in the C Standard Library that are
+guaranteed to not throw an exception.
+
+
+objc_boxable (clang::objc_boxable, clang::objc_boxable)
+-------------------------------------------------------
+.. csv-table:: Supported Syntaxes
+ :header: "GNU", "C++11", "C2x", "__declspec", "Keyword", "Pragma", "Pragma clang attribute"
+
+ "X","X","X","","", "", "X"
+
+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:
+
+.. code-block:: objc
+
+ 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 (clang::objc_method_family, clang::objc_method_family)
+-------------------------------------------------------------------------
+.. csv-table:: Supported Syntaxes
+ :header: "GNU", "C++11", "C2x", "__declspec", "Keyword", "Pragma", "Pragma clang attribute"
+
+ "X","X","X","","", "", "X"
+
+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:
+
+.. code-block:: objc
+
+ - (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 (clang::objc_requires_super, clang::objc_requires_super)
+----------------------------------------------------------------------------
+.. csv-table:: Supported Syntaxes
+ :header: "GNU", "C++11", "C2x", "__declspec", "Keyword", "Pragma", "Pragma clang attribute"
+
+ "X","X","X","","", "", "X"
+
+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:
+
+.. code-block:: objc
+
+ - (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:
+
+.. code-block:: objc
+
+ - (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:
+
+.. code-block:: objc
+
+ warning: method possibly missing a [super AnnotMeth] call
+ - (void) AnnotMeth{};
+ ^
+
+
+objc_runtime_name (clang::objc_runtime_name, clang::objc_runtime_name)
+----------------------------------------------------------------------
+.. csv-table:: Supported Syntaxes
+ :header: "GNU", "C++11", "C2x", "__declspec", "Keyword", "Pragma", "Pragma clang attribute"
+
+ "X","X","X","","", "", "X"
+
+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:
+
+.. code-block:: objc
+
+ __attribute__((objc_runtime_name("MyLocalName")))
+ @interface Message
+ @end
+
+
+objc_runtime_visible (clang::objc_runtime_visible, clang::objc_runtime_visible)
+-------------------------------------------------------------------------------
+.. csv-table:: Supported Syntaxes
+ :header: "GNU", "C++11", "C2x", "__declspec", "Keyword", "Pragma", "Pragma clang attribute"
+
+ "X","X","X","","", "", "X"
+
+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, clang::optnone)
+----------------------------------------
+.. csv-table:: Supported Syntaxes
+ :header: "GNU", "C++11", "C2x", "__declspec", "Keyword", "Pragma", "Pragma clang attribute"
+
+ "X","X","X","","", "", "X"
+
+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::overloadable, clang::overloadable)
+-------------------------------------------------------
+.. csv-table:: Supported Syntaxes
+ :header: "GNU", "C++11", "C2x", "__declspec", "Keyword", "Pragma", "Pragma clang attribute"
+
+ "X","X","X","","", "", "X"
+
+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:
+
+.. code-block:: c
+
+ #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.
+
+* If no viable candidates are otherwise available, we allow a conversion from a
+ pointer of type ``T*`` to a pointer of type ``U*``, where ``T`` and ``U`` are
+ incompatible. This conversion is ranked below all other types of conversions.
+ Please note: ``U`` lacking qualifiers that are present on ``T`` is sufficient
+ for ``T`` and ``U`` to be incompatible.
+
+The declaration of ``overloadable`` functions is restricted to function
+declarations and definitions. If a function is marked with the ``overloadable``
+attribute, then all declarations and definitions of functions with that name,
+except for at most one (see the note below about unmarked overloads), must have
+the ``overloadable`` attribute. In addition, redeclarations of a function with
+the ``overloadable`` attribute must have the ``overloadable`` attribute, and
+redeclarations of a function without the ``overloadable`` attribute must *not*
+have the ``overloadable`` attribute. e.g.,
+
+.. code-block:: c
+
+ int f(int) __attribute__((overloadable));
+ float f(float); // error: declaration of "f" must have the "overloadable" attribute
+ int f(int); // error: redeclaration 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
+
+ int h(int);
+ int h(int) __attribute__((overloadable)); // error: declaration of "h" must not
+ // have the "overloadable" attribute
+
+Functions marked ``overloadable`` must have prototypes. Therefore, the
+following code is ill-formed:
+
+.. code-block:: c
+
+ 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:
+
+.. code-block:: c++
+
+ 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.
+
+For the purpose of backwards compatibility, at most one function with the same
+name as other ``overloadable`` functions may omit the ``overloadable``
+attribute. In this case, the function without the ``overloadable`` attribute
+will not have its name mangled.
+
+For example:
+
+.. code-block:: c
+
+ // Notes with mangled names assume Itanium mangling.
+ int f(int);
+ int f(double) __attribute__((overloadable));
+ void foo() {
+ f(5); // Emits a call to f (not _Z1fi, as it would with an overload that
+ // was marked with overloadable).
+ f(1.0); // Emits a call to _Z1fd.
+ }
+
+Support for unmarked overloads is not present in some versions of clang. You may
+query for it using ``__has_extension(overloadable_unmarked)``.
+
+Query for this attribute with ``__has_attribute(overloadable)``.
+
+
+release_capability (release_shared_capability, clang::release_capability, clang::release_shared_capability)
+-----------------------------------------------------------------------------------------------------------
+.. csv-table:: Supported Syntaxes
+ :header: "GNU", "C++11", "C2x", "__declspec", "Keyword", "Pragma", "Pragma clang attribute"
+
+ "X","X","","","", "", ""
+
+Marks a function as releasing a capability.
+
+
+short_call (gnu::short_call, gnu::near)
+---------------------------------------
+.. csv-table:: Supported Syntaxes
+ :header: "GNU", "C++11", "C2x", "__declspec", "Keyword", "Pragma", "Pragma clang attribute"
+
+ "X","X","","","", "", "X"
+
+Clang supports the ``__attribute__((long_call))``, ``__attribute__((far))``,
+``__attribute__((short__call))``, and ``__attribute__((near))`` attributes
+on MIPS targets. These attributes may only be added to function declarations
+and change the code generated by the compiler when directly calling
+the function. The ``short_call`` and ``near`` attributes are synonyms and
+allow calls to the function to be made using the ``jal`` instruction, which
+requires the function to be located in the same naturally aligned 256MB segment
+as the caller. The ``long_call`` and ``far`` attributes are synonyms and
+require the use of a different call sequence that works regardless
+of the distance between the functions.
+
+These attributes have no effect for position-independent code.
+
+These attributes take priority over command line switches such
+as ``-mlong-calls`` and ``-mno-long-calls``.
+
+
+signal (gnu::signal)
+--------------------
+.. csv-table:: Supported Syntaxes
+ :header: "GNU", "C++11", "C2x", "__declspec", "Keyword", "Pragma", "Pragma clang attribute"
+
+ "X","X","","","", "", "X"
+
+Clang supports the GNU style ``__attribute__((signal))`` attribute on
+AVR 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.
+
+Interrupt handler functions defined with the signal attribute do not re-enable interrupts.
+
+
+target (gnu::target)
+--------------------
+.. csv-table:: Supported Syntaxes
+ :header: "GNU", "C++11", "C2x", "__declspec", "Keyword", "Pragma", "Pragma clang attribute"
+
+ "X","X","","","", "", "X"
+
+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.
+
+Additionally, this attribute supports function multiversioning for ELF based
+x86/x86-64 targets, which can be used to create multiple implementations of the
+same function that will be resolved at runtime based on the priority of their
+``target`` attribute strings. A function is considered a multiversioned function
+if either two declarations of the function have different ``target`` attribute
+strings, or if it has a ``target`` attribute string of ``default``. For
+example:
+
+ .. code-block:: c++
+
+ __attribute__((target("arch=atom")))
+ void foo() {} // will be called on 'atom' processors.
+ __attribute__((target("default")))
+ void foo() {} // will be called on any other processors.
+
+All multiversioned functions must contain a ``default`` (fallback)
+implementation, otherwise usages of the function are considered invalid.
+Additionally, a function may not become multiversioned after its first use.
+
+
+try_acquire_capability (try_acquire_shared_capability, clang::try_acquire_capability, clang::try_acquire_shared_capability)
+---------------------------------------------------------------------------------------------------------------------------
+.. csv-table:: Supported Syntaxes
+ :header: "GNU", "C++11", "C2x", "__declspec", "Keyword", "Pragma", "Pragma clang attribute"
+
+ "X","X","","","", "", ""
+
+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).
+
+
+xray_always_instrument (clang::xray_always_instrument), xray_never_instrument (clang::xray_never_instrument), xray_log_args (clang::xray_log_args)
+--------------------------------------------------------------------------------------------------------------------------------------------------
+.. csv-table:: Supported Syntaxes
+ :header: "GNU", "C++11", "C2x", "__declspec", "Keyword", "Pragma", "Pragma clang attribute"
+
+ "X","X","X","","", "", "X"
+
+``__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.
+
+``__attribute__((xray_log_args(N)))`` or ``[[clang::xray_log_args(N)]]`` is used to preserve N function arguments for the logging function. Currently, only N==1 is supported.
+
+
+xray_always_instrument (clang::xray_always_instrument), xray_never_instrument (clang::xray_never_instrument), xray_log_args (clang::xray_log_args)
+--------------------------------------------------------------------------------------------------------------------------------------------------
+.. csv-table:: Supported Syntaxes
+ :header: "GNU", "C++11", "C2x", "__declspec", "Keyword", "Pragma", "Pragma clang attribute"
+
+ "X","X","X","","", "", "X"
+
+``__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.
+
+``__attribute__((xray_log_args(N)))`` or ``[[clang::xray_log_args(N)]]`` is used to preserve N function arguments for the logging function. Currently, only N==1 is supported.
+
+
+Variable Attributes
+===================
+
+
+dllexport (gnu::dllexport)
+--------------------------
+.. csv-table:: Supported Syntaxes
+ :header: "GNU", "C++11", "C2x", "__declspec", "Keyword", "Pragma", "Pragma clang attribute"
+
+ "X","X","","X","", "", "X"
+
+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.
+
+.. _dllexport: https://msdn.microsoft.com/en-us/library/3y1sfaz2.aspx
+
+
+dllimport (gnu::dllimport)
+--------------------------
+.. csv-table:: Supported Syntaxes
+ :header: "GNU", "C++11", "C2x", "__declspec", "Keyword", "Pragma", "Pragma clang attribute"
+
+ "X","X","","X","", "", "X"
+
+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.
+
+.. _dllimport: https://msdn.microsoft.com/en-us/library/3y1sfaz2.aspx
+
+
+init_seg
+--------
+.. csv-table:: Supported Syntaxes
+ :header: "GNU", "C++11", "C2x", "__declspec", "Keyword", "Pragma", "Pragma clang attribute"
+
+ "","","","","", "X", ""
+
+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.
+
+.. _init_seg: http://msdn.microsoft.com/en-us/library/7977wcck(v=vs.110).aspx
+
+
+maybe_unused, unused, gnu::unused
+---------------------------------
+.. csv-table:: Supported Syntaxes
+ :header: "GNU", "C++11", "C2x", "__declspec", "Keyword", "Pragma", "Pragma clang attribute"
+
+ "X","X","X","","", "", ""
+
+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.
+
+.. code-block: c++
+ #include <cassert>
+
+ [[maybe_unused]] void f([[maybe_unused]] bool thing1,
+ [[maybe_unused]] bool thing2) {
+ [[maybe_unused]] bool b = thing1 && thing2;
+ assert(b);
+ }
+
+
+nodebug (gnu::nodebug)
+----------------------
+.. csv-table:: Supported Syntaxes
+ :header: "GNU", "C++11", "C2x", "__declspec", "Keyword", "Pragma", "Pragma clang attribute"
+
+ "X","X","","","", "", "X"
+
+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.
+
+
+noescape (clang::noescape, clang::noescape)
+-------------------------------------------
+.. csv-table:: Supported Syntaxes
+ :header: "GNU", "C++11", "C2x", "__declspec", "Keyword", "Pragma", "Pragma clang attribute"
+
+ "X","X","X","","", "", "X"
+
+``noescape`` placed on a function parameter of a pointer type is used to inform
+the compiler that the pointer cannot escape: that is, no reference to the object
+the pointer points to that is derived from the parameter value will survive
+after the function returns. Users are responsible for making sure parameters
+annotated with ``noescape`` do not actuallly escape.
+
+For example:
+
+.. code-block:: c
+
+ int *gp;
+
+ void nonescapingFunc(__attribute__((noescape)) int *p) {
+ *p += 100; // OK.
+ }
+
+ void escapingFunc(__attribute__((noescape)) int *p) {
+ gp = p; // Not OK.
+ }
+
+Additionally, when the parameter is a `block pointer
+<https://clang.llvm.org/docs/BlockLanguageSpec.html>`, the same restriction
+applies to copies of the block. For example:
+
+.. code-block:: c
+
+ typedef void (^BlockTy)();
+ BlockTy g0, g1;
+
+ void nonescapingFunc(__attribute__((noescape)) BlockTy block) {
+ block(); // OK.
+ }
+
+ void escapingFunc(__attribute__((noescape)) BlockTy block) {
+ g0 = block; // Not OK.
+ g1 = Block_copy(block); // Not OK either.
+ }
+
+
+nosvm
+-----
+.. csv-table:: Supported Syntaxes
+ :header: "GNU", "C++11", "C2x", "__declspec", "Keyword", "Pragma", "Pragma clang attribute"
+
+ "X","","","","", "", "X"
+
+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 (clang::pass_object_size, clang::pass_object_size)
+-------------------------------------------------------------------
+.. csv-table:: Supported Syntaxes
+ :header: "GNU", "C++11", "C2x", "__declspec", "Keyword", "Pragma", "Pragma clang attribute"
+
+ "X","X","X","","", "", "X"
+
+.. Note:: The mangling of functions with parameters that are annotated with
+ ``pass_object_size`` is subject to change. You can get around this by
+ using ``__asm__("foo")`` to explicitly name your functions, thus preserving
+ your ABI; also, non-overloadable C functions with ``pass_object_size`` are
+ not mangled.
+
+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:
+
+.. code-block:: c
+
+ 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:
+
+.. code-block:: c
+
+ 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:
+
+.. code-block:: c++
+
+ #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.
+
+
+require_constant_initialization (clang::require_constant_initialization)
+------------------------------------------------------------------------
+.. csv-table:: Supported Syntaxes
+ :header: "GNU", "C++11", "C2x", "__declspec", "Keyword", "Pragma", "Pragma clang attribute"
+
+ "X","X","","","", "", "X"
+
+This attribute specifies that the variable to which it is attached is intended
+to have a `constant initializer <http://en.cppreference.com/w/cpp/language/constant_initialization>`_
+according to the rules of [basic.start.static]. The variable is required to
+have static or thread storage duration. If the initialization of the variable
+is not a constant initializer an error will be produced. This attribute may
+only be used in C++.
+
+Note that in C++03 strict constant expression checking is not done. Instead
+the attribute reports if Clang can emit the variable as a constant, even if it's
+not technically a 'constant initializer'. This behavior is non-portable.
+
+Static storage duration variables with constant initializers avoid hard-to-find
+bugs caused by the indeterminate order of dynamic initialization. They can also
+be safely used during dynamic initialization across translation units.
+
+This attribute acts as a compile time assertion that the requirements
+for constant initialization have been met. Since these requirements change
+between dialects and have subtle pitfalls it's important to fail fast instead
+of silently falling back on dynamic initialization.
+
+.. code-block:: c++
+
+ // -std=c++14
+ #define SAFE_STATIC [[clang::require_constant_initialization]]
+ struct T {
+ constexpr T(int) {}
+ ~T(); // non-trivial
+ };
+ SAFE_STATIC T x = {42}; // Initialization OK. Doesn't check destructor.
+ SAFE_STATIC T y = 42; // error: variable does not have a constant initializer
+ // copy initialization is not a constant expression on a non-literal type.
+
+
+section (gnu::section, __declspec(allocate))
+--------------------------------------------
+.. csv-table:: Supported Syntaxes
+ :header: "GNU", "C++11", "C2x", "__declspec", "Keyword", "Pragma", "Pragma clang attribute"
+
+ "X","X","","X","", "", "X"
+
+The ``section`` attribute allows you to specify a specific section a
+global variable or function should be in after translation.
+
+
+swift_context (clang::swift_context, clang::swift_context)
+----------------------------------------------------------
+.. csv-table:: Supported Syntaxes
+ :header: "GNU", "C++11", "C2x", "__declspec", "Keyword", "Pragma", "Pragma clang attribute"
+
+ "X","X","X","","", "", "X"
+
+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 (clang::swift_error_result, clang::swift_error_result)
+-------------------------------------------------------------------------
+.. csv-table:: Supported Syntaxes
+ :header: "GNU", "C++11", "C2x", "__declspec", "Keyword", "Pragma", "Pragma clang attribute"
+
+ "X","X","X","","", "", "X"
+
+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 (clang::swift_indirect_result, clang::swift_indirect_result)
+----------------------------------------------------------------------------------
+.. csv-table:: Supported Syntaxes
+ :header: "GNU", "C++11", "C2x", "__declspec", "Keyword", "Pragma", "Pragma clang attribute"
+
+ "X","X","X","","", "", "X"
+
+The ``swift_indirect_result`` attribute marks a parameter of a ``swiftcall``
+function as having the special indirect-result ABI treatment.
+
+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).
+
+
+swiftcall (clang::swiftcall, clang::swiftcall)
+----------------------------------------------
+.. csv-table:: Supported Syntaxes
+ :header: "GNU", "C++11", "C2x", "__declspec", "Keyword", "Pragma", "Pragma clang attribute"
+
+ "X","X","X","","", "", ""
+
+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.
+
+
+thread
+------
+.. csv-table:: Supported Syntaxes
+ :header: "GNU", "C++11", "C2x", "__declspec", "Keyword", "Pragma", "Pragma clang attribute"
+
+ "","","","X","", "", ""
+
+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.
+
+.. _`__declspec(thread)`: http://msdn.microsoft.com/en-us/library/9w1sdazb.aspx
+
+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.
+
+
+tls_model (gnu::tls_model)
+--------------------------
+.. csv-table:: Supported Syntaxes
+ :header: "GNU", "C++11", "C2x", "__declspec", "Keyword", "Pragma", "Pragma clang attribute"
+
+ "X","X","","","", "", "X"
+
+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.
+
+
+trivial_abi (clang::trivial_abi)
+--------------------------------
+.. csv-table:: Supported Syntaxes
+ :header: "GNU", "C++11", "C2x", "__declspec", "Keyword", "Pragma", "Pragma clang attribute"
+
+ "X","X","","","", "", "X"
+
+The ``trivial_abi`` attribute can be applied to a C++ class, struct, or union.
+It instructs the compiler to pass and return the type using the C ABI for the
+underlying type when the type would otherwise be considered non-trivial for the
+purpose of calls.
+A class annotated with `trivial_abi` can have non-trivial destructors or copy/move constructors without automatically becoming non-trivial for the purposes of calls. For example:
+
+ .. code-block:: c++
+
+ // A is trivial for the purposes of calls because `trivial_abi` makes the
+ // user-provided special functions trivial.
+ struct __attribute__((trivial_abi)) A {
+ ~A();
+ A(const A &);
+ A(A &&);
+ int x;
+ };
+
+ // B's destructor and copy/move constructor are considered trivial for the
+ // purpose of calls because A is trivial.
+ struct B {
+ A a;
+ };
+
+If a type is trivial for the purposes of calls, has a non-trivial destructor,
+and is passed as an argument by value, the convention is that the callee will
+destroy the object before returning.
+
+Attribute ``trivial_abi`` has no effect in the following cases:
+
+- The class directly declares a virtual base or virtual methods.
+- The class has a base class that is non-trivial for the purposes of calls.
+- The class has a non-static data member whose type is non-trivial for the purposes of calls, which includes:
+
+ - classes that are non-trivial for the purposes of calls
+ - __weak-qualified types in Objective-C++
+ - arrays of any of the above
+
+
+Type Attributes
+===============
+
+
+__single_inhertiance, __multiple_inheritance, __virtual_inheritance
+-------------------------------------------------------------------
+.. csv-table:: Supported Syntaxes
+ :header: "GNU", "C++11", "C2x", "__declspec", "Keyword", "Pragma", "Pragma clang attribute"
+
+ "","","","","X", "", ""
+
+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``:
+
+.. code-block:: c++
+
+ 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:
+
+.. code-block:: c++
+
+ 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:
+
+.. code-block:: c++
+
+ struct __multiple_inheritance S; // error: inheritance model does not match definition
+ int S::*i;
+ struct S {};
+
+
+align_value
+-----------
+.. csv-table:: Supported Syntaxes
+ :header: "GNU", "C++11", "C2x", "__declspec", "Keyword", "Pragma", "Pragma clang attribute"
+
+ "X","","","","", "", "X"
+
+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.
+
+ .. code-block:: c
+
+ 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
+-----------
+.. csv-table:: Supported Syntaxes
+ :header: "GNU", "C++11", "C2x", "__declspec", "Keyword", "Pragma", "Pragma clang attribute"
+
+ "","","","X","", "", ""
+
+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.
+
+
+enum_extensibility (clang::enum_extensibility, clang::enum_extensibility)
+-------------------------------------------------------------------------
+.. csv-table:: Supported Syntaxes
+ :header: "GNU", "C++11", "C2x", "__declspec", "Keyword", "Pragma", "Pragma clang attribute"
+
+ "X","X","X","","", "", "X"
+
+Attribute ``enum_extensibility`` is used to distinguish between enum definitions
+that are extensible and those that are not. The attribute can take either
+``closed`` or ``open`` as an argument. ``closed`` indicates a variable of the
+enum type takes a value that corresponds to one of the enumerators listed in the
+enum definition or, when the enum is annotated with ``flag_enum``, a value that
+can be constructed using values corresponding to the enumerators. ``open``
+indicates a variable of the enum type can take any values allowed by the
+standard and instructs clang to be more lenient when issuing warnings.
+
+.. code-block:: c
+
+ enum __attribute__((enum_extensibility(closed))) ClosedEnum {
+ A0, A1
+ };
+
+ enum __attribute__((enum_extensibility(open))) OpenEnum {
+ B0, B1
+ };
+
+ enum __attribute__((enum_extensibility(closed),flag_enum)) ClosedFlagEnum {
+ C0 = 1 << 0, C1 = 1 << 1
+ };
+
+ enum __attribute__((enum_extensibility(open),flag_enum)) OpenFlagEnum {
+ D0 = 1 << 0, D1 = 1 << 1
+ };
+
+ void foo1() {
+ enum ClosedEnum ce;
+ enum OpenEnum oe;
+ enum ClosedFlagEnum cfe;
+ enum OpenFlagEnum ofe;
+
+ ce = A1; // no warnings
+ ce = 100; // warning issued
+ oe = B1; // no warnings
+ oe = 100; // no warnings
+ cfe = C0 | C1; // no warnings
+ cfe = C0 | C1 | 4; // warning issued
+ ofe = D0 | D1; // no warnings
+ ofe = D0 | D1 | 4; // no warnings
+ }
+
+
+flag_enum (clang::flag_enum, clang::flag_enum)
+----------------------------------------------
+.. csv-table:: Supported Syntaxes
+ :header: "GNU", "C++11", "C2x", "__declspec", "Keyword", "Pragma", "Pragma clang attribute"
+
+ "X","X","X","","", "", "X"
+
+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.
+
+
+layout_version
+--------------
+.. csv-table:: Supported Syntaxes
+ :header: "GNU", "C++11", "C2x", "__declspec", "Keyword", "Pragma", "Pragma clang attribute"
+
+ "","","","X","", "", ""
+
+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.
+
+
+lto_visibility_public (clang::lto_visibility_public, clang::lto_visibility_public)
+----------------------------------------------------------------------------------
+.. csv-table:: Supported Syntaxes
+ :header: "GNU", "C++11", "C2x", "__declspec", "Keyword", "Pragma", "Pragma clang attribute"
+
+ "X","X","X","","", "", "X"
+
+See :doc:`LTOVisibility`.
+
+
+novtable
+--------
+.. csv-table:: Supported Syntaxes
+ :header: "GNU", "C++11", "C2x", "__declspec", "Keyword", "Pragma", "Pragma clang attribute"
+
+ "","","","X","", "", ""
+
+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.
+
+
+objc_subclassing_restricted (clang::objc_subclassing_restricted, clang::objc_subclassing_restricted)
+----------------------------------------------------------------------------------------------------
+.. csv-table:: Supported Syntaxes
+ :header: "GNU", "C++11", "C2x", "__declspec", "Keyword", "Pragma", "Pragma clang attribute"
+
+ "X","X","X","","", "", "X"
+
+This attribute can be added to an Objective-C ``@interface`` declaration to
+ensure that this class cannot be subclassed.
+
+
+selectany (gnu::selectany)
+--------------------------
+.. csv-table:: Supported Syntaxes
+ :header: "GNU", "C++11", "C2x", "__declspec", "Keyword", "Pragma", "Pragma clang attribute"
+
+ "X","X","","X","", "", ""
+
+This attribute appertains to a global symbol, causing it to have a weak
+definition (
+`linkonce <https://llvm.org/docs/LangRef.html#linkage-types>`_
+), allowing the linker to select any definition.
+
+For more information see
+`gcc documentation <https://gcc.gnu.org/onlinedocs/gcc-7.2.0/gcc/Microsoft-Windows-Variable-Attributes.html>`_
+or `msvc documentation <https://docs.microsoft.com/pl-pl/cpp/cpp/selectany>`_.
+
+
+transparent_union (gnu::transparent_union)
+------------------------------------------
+.. csv-table:: Supported Syntaxes
+ :header: "GNU", "C++11", "C2x", "__declspec", "Keyword", "Pragma", "Pragma clang attribute"
+
+ "X","X","","","", "", ""
+
+This attribute can be applied to a union to change the behaviour of calls to
+functions that have an argument with a transparent union type. The compiler
+behaviour is changed in the following manner:
+
+- A value whose type is any member of the transparent union can be passed as an
+ argument without the need to cast that value.
+
+- The argument is passed to the function using the calling convention of the
+ first member of the transparent union. Consequently, all the members of the
+ transparent union should have the same calling convention as its first member.
+
+Transparent unions are not supported in C++.
+
+
+Statement Attributes
+====================
+
+
+#pragma clang loop
+------------------
+.. csv-table:: Supported Syntaxes
+ :header: "GNU", "C++11", "C2x", "__declspec", "Keyword", "Pragma", "Pragma clang attribute"
+
+ "","","","","", "X", ""
+
+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
+<http://clang.llvm.org/docs/LanguageExtensions.html#extensions-for-loop-hint-optimizations>`_
+for details.
+
+
+#pragma unroll, #pragma nounroll
+--------------------------------
+.. csv-table:: Supported Syntaxes
+ :header: "GNU", "C++11", "C2x", "__declspec", "Keyword", "Pragma", "Pragma clang attribute"
+
+ "","","","","", "X", ""
+
+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:
+
+.. code-block:: c++
+
+ #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:
+
+.. code-block:: c++
+
+ #pragma unroll 16
+ for (...) {
+ ...
+ }
+
+ #pragma unroll(16)
+ for (...) {
+ ...
+ }
+
+Specifying ``#pragma nounroll`` indicates that the loop should not be unrolled:
+
+.. code-block:: c++
+
+ #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
+<http://clang.llvm.org/docs/LanguageExtensions.html#extensions-for-loop-hint-optimizations>`_
+for further details including limitations of the unroll hints.
+
+
+__attribute__((intel_reqd_sub_group_size))
+------------------------------------------
+.. csv-table:: Supported Syntaxes
+ :header: "GNU", "C++11", "C2x", "__declspec", "Keyword", "Pragma", "Pragma clang attribute"
+
+ "X","","","","", "", "X"
+
+The optional attribute intel_reqd_sub_group_size can be used to indicate that
+the kernel must be compiled and executed with the specified subgroup size. When
+this attribute is present, get_max_sub_group_size() is guaranteed to return the
+specified integer value. This is important for the correctness of many subgroup
+algorithms, and in some cases may be used by the compiler to generate more optimal
+code. See `cl_intel_required_subgroup_size
+<https://www.khronos.org/registry/OpenCL/extensions/intel/cl_intel_required_subgroup_size.txt>`
+for details.
+
+
+__attribute__((opencl_unroll_hint))
+-----------------------------------
+.. csv-table:: Supported Syntaxes
+ :header: "GNU", "C++11", "C2x", "__declspec", "Keyword", "Pragma", "Pragma clang attribute"
+
+ "X","","","","", "", ""
+
+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 <https://www.khronos.org/registry/cl/specs/opencl-2.0.pdf>`_
+s6.11.5 for details.
+
+
+__read_only, __write_only, __read_write (read_only, write_only, read_write)
+---------------------------------------------------------------------------
+.. csv-table:: Supported Syntaxes
+ :header: "GNU", "C++11", "C2x", "__declspec", "Keyword", "Pragma", "Pragma clang attribute"
+
+ "","","","","X", "", ""
+
+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.
+
+.. code-block:: c
+
+ 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.
+
+
+fallthrough, clang::fallthrough
+-------------------------------
+.. csv-table:: Supported Syntaxes
+ :header: "GNU", "C++11", "C2x", "__declspec", "Keyword", "Pragma", "Pragma clang attribute"
+
+ "","X","X","","", "", ""
+
+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:
+
+.. code-block:: c++
+
+ // 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();
+ }
+
+
+suppress (gsl::suppress)
+------------------------
+.. csv-table:: Supported Syntaxes
+ :header: "GNU", "C++11", "C2x", "__declspec", "Keyword", "Pragma", "Pragma clang attribute"
+
+ "","X","","","", "", ""
+
+The ``[[gsl::suppress]]`` attribute suppresses specific
+clang-tidy diagnostics for rules of the `C++ Core Guidelines`_ in a portable
+way. The attribute can be attached to declarations, statements, and at
+namespace scope.
+
+.. code-block:: c++
+
+ [[gsl::suppress("Rh-public")]]
+ void f_() {
+ int *p;
+ [[gsl::suppress("type")]] {
+ p = reinterpret_cast<int*>(7);
+ }
+ }
+ namespace N {
+ [[clang::suppress("type", "bounds")]];
+ ...
+ }
+
+.. _`C++ Core Guidelines`: https://github.com/isocpp/CppCoreGuidelines/blob/master/CppCoreGuidelines.md#inforce-enforcement
+
+
+AMD GPU Attributes
+==================
+
+
+amdgpu_flat_work_group_size (clang::amdgpu_flat_work_group_size)
+----------------------------------------------------------------
+.. csv-table:: Supported Syntaxes
+ :header: "GNU", "C++11", "C2x", "__declspec", "Keyword", "Pragma", "Pragma clang attribute"
+
+ "X","X","","","", "", "X"
+
+The flat work-group size is the number of work-items in the work-group size
+specified when the kernel is dispatched. It is the product of the sizes of the
+x, y, and z dimension of the work-group.
+
+Clang supports the
+``__attribute__((amdgpu_flat_work_group_size(<min>, <max>)))`` attribute for the
+AMDGPU target. This attribute may be attached to a kernel function definition
+and is an optimization hint.
+
+``<min>`` parameter specifies the minimum flat work-group size, and ``<max>``
+parameter specifies the maximum flat work-group size (must be greater than
+``<min>``) to which all dispatches of the kernel will conform. Passing ``0, 0``
+as ``<min>, <max>`` implies the default behavior (``128, 256``).
+
+If specified, the AMDGPU target backend might be able to produce better machine
+code for barriers and perform scratch promotion by estimating available group
+segment size.
+
+An error will be given if:
+ - Specified values violate subtarget specifications;
+ - Specified values are not compatible with values provided through other
+ attributes.
+
+
+amdgpu_num_sgpr (clang::amdgpu_num_sgpr)
+----------------------------------------
+.. csv-table:: Supported Syntaxes
+ :header: "GNU", "C++11", "C2x", "__declspec", "Keyword", "Pragma", "Pragma clang attribute"
+
+ "X","X","","","", "", "X"
+
+Clang supports the ``__attribute__((amdgpu_num_sgpr(<num_sgpr>)))`` and
+``__attribute__((amdgpu_num_vgpr(<num_vgpr>)))`` attributes for the AMDGPU
+target. These attributes may be attached to a kernel function definition and are
+an optimization hint.
+
+If these attributes are specified, then the AMDGPU target backend will attempt
+to limit the number of SGPRs and/or VGPRs used to the specified value(s). The
+number of used SGPRs and/or VGPRs may further be rounded up to satisfy the
+allocation requirements or constraints of the subtarget. Passing ``0`` as
+``num_sgpr`` and/or ``num_vgpr`` implies the default behavior (no limits).
+
+These attributes can be used to test the AMDGPU target backend. It is
+recommended that the ``amdgpu_waves_per_eu`` attribute be used to control
+resources such as SGPRs and VGPRs since it is aware of the limits for different
+subtargets.
+
+An error will be given if:
+ - Specified values violate subtarget specifications;
+ - Specified values are not compatible with values provided through other
+ attributes;
+ - The AMDGPU target backend is unable to create machine code that can meet the
+ request.
+
+
+amdgpu_num_vgpr (clang::amdgpu_num_vgpr)
+----------------------------------------
+.. csv-table:: Supported Syntaxes
+ :header: "GNU", "C++11", "C2x", "__declspec", "Keyword", "Pragma", "Pragma clang attribute"
+
+ "X","X","","","", "", "X"
+
+Clang supports the ``__attribute__((amdgpu_num_sgpr(<num_sgpr>)))`` and
+``__attribute__((amdgpu_num_vgpr(<num_vgpr>)))`` attributes for the AMDGPU
+target. These attributes may be attached to a kernel function definition and are
+an optimization hint.
+
+If these attributes are specified, then the AMDGPU target backend will attempt
+to limit the number of SGPRs and/or VGPRs used to the specified value(s). The
+number of used SGPRs and/or VGPRs may further be rounded up to satisfy the
+allocation requirements or constraints of the subtarget. Passing ``0`` as
+``num_sgpr`` and/or ``num_vgpr`` implies the default behavior (no limits).
+
+These attributes can be used to test the AMDGPU target backend. It is
+recommended that the ``amdgpu_waves_per_eu`` attribute be used to control
+resources such as SGPRs and VGPRs since it is aware of the limits for different
+subtargets.
+
+An error will be given if:
+ - Specified values violate subtarget specifications;
+ - Specified values are not compatible with values provided through other
+ attributes;
+ - The AMDGPU target backend is unable to create machine code that can meet the
+ request.
+
+
+amdgpu_waves_per_eu (clang::amdgpu_waves_per_eu)
+------------------------------------------------
+.. csv-table:: Supported Syntaxes
+ :header: "GNU", "C++11", "C2x", "__declspec", "Keyword", "Pragma", "Pragma clang attribute"
+
+ "X","X","","","", "", "X"
+
+A compute unit (CU) is responsible for executing the wavefronts of a work-group.
+It is composed of one or more execution units (EU), which are responsible for
+executing the wavefronts. An EU can have enough resources to maintain the state
+of more than one executing wavefront. This allows an EU to hide latency by
+switching between wavefronts in a similar way to symmetric multithreading on a
+CPU. In order to allow the state for multiple wavefronts to fit on an EU, the
+resources used by a single wavefront have to be limited. For example, the number
+of SGPRs and VGPRs. Limiting such resources can allow greater latency hiding,
+but can result in having to spill some register state to memory.
+
+Clang supports the ``__attribute__((amdgpu_waves_per_eu(<min>[, <max>])))``
+attribute for the AMDGPU target. This attribute may be attached to a kernel
+function definition and is an optimization hint.
+
+``<min>`` parameter specifies the requested minimum number of waves per EU, and
+*optional* ``<max>`` parameter specifies the requested maximum number of waves
+per EU (must be greater than ``<min>`` if specified). If ``<max>`` is omitted,
+then there is no restriction on the maximum number of waves per EU other than
+the one dictated by the hardware for which the kernel is compiled. Passing
+``0, 0`` as ``<min>, <max>`` implies the default behavior (no limits).
+
+If specified, this attribute allows an advanced developer to tune the number of
+wavefronts that are capable of fitting within the resources of an EU. The AMDGPU
+target backend can use this information to limit resources, such as number of
+SGPRs, number of VGPRs, size of available group and private memory segments, in
+such a way that guarantees that at least ``<min>`` wavefronts and at most
+``<max>`` wavefronts are able to fit within the resources of an EU. Requesting
+more wavefronts can hide memory latency but limits available registers which
+can result in spilling. Requesting fewer wavefronts can help reduce cache
+thrashing, but can reduce memory latency hiding.
+
+This attribute controls the machine code generated by the AMDGPU target backend
+to ensure it is capable of meeting the requested values. However, when the
+kernel is executed, there may be other reasons that prevent meeting the request,
+for example, there may be wavefronts from other kernels executing on the EU.
+
+An error will be given if:
+ - Specified values violate subtarget specifications;
+ - Specified values are not compatible with values provided through other
+ attributes;
+ - The AMDGPU target backend is unable to create machine code that can meet the
+ request.
+
+
+Calling Conventions
+===================
+Clang supports several different calling conventions, depending on the target
+platform and architecture. The calling convention used for a function determines
+how parameters are passed, how results are returned to the caller, and other
+low-level details of calling a function.
+
+fastcall (gnu::fastcall, __fastcall, _fastcall)
+-----------------------------------------------
+.. csv-table:: Supported Syntaxes
+ :header: "GNU", "C++11", "C2x", "__declspec", "Keyword", "Pragma", "Pragma clang attribute"
+
+ "X","X","","","X", "", ""
+
+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.
+
+.. _`__fastcall`: http://msdn.microsoft.com/en-us/library/6xa169sk.aspx
+
+
+ms_abi (gnu::ms_abi)
+--------------------
+.. csv-table:: Supported Syntaxes
+ :header: "GNU", "C++11", "C2x", "__declspec", "Keyword", "Pragma", "Pragma clang attribute"
+
+ "X","X","","","", "", ""
+
+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)
+--------------
+.. csv-table:: Supported Syntaxes
+ :header: "GNU", "C++11", "C2x", "__declspec", "Keyword", "Pragma", "Pragma clang attribute"
+
+ "X","X","","","", "", ""
+
+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 (clang::preserve_all, clang::preserve_all)
+-------------------------------------------------------
+.. csv-table:: Supported Syntaxes
+ :header: "GNU", "C++11", "C2x", "__declspec", "Keyword", "Pragma", "Pragma clang attribute"
+
+ "X","X","X","","", "", ""
+
+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 (clang::preserve_most, clang::preserve_most)
+----------------------------------------------------------
+.. csv-table:: Supported Syntaxes
+ :header: "GNU", "C++11", "C2x", "__declspec", "Keyword", "Pragma", "Pragma clang attribute"
+
+ "X","X","X","","", "", ""
+
+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.
+
+
+regcall (gnu::regcall, __regcall)
+---------------------------------
+.. csv-table:: Supported Syntaxes
+ :header: "GNU", "C++11", "C2x", "__declspec", "Keyword", "Pragma", "Pragma clang attribute"
+
+ "X","X","","","X", "", ""
+
+On x86 targets, this attribute changes the calling convention to
+`__regcall`_ convention. This convention aims to pass as many arguments
+as possible in registers. It also tries to utilize registers for the
+return value whenever it is possible.
+
+.. _`__regcall`: https://software.intel.com/en-us/node/693069
+
+
+regparm (gnu::regparm)
+----------------------
+.. csv-table:: Supported Syntaxes
+ :header: "GNU", "C++11", "C2x", "__declspec", "Keyword", "Pragma", "Pragma clang attribute"
+
+ "X","X","","","", "", ""
+
+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)
+-------------------------------------------
+.. csv-table:: Supported Syntaxes
+ :header: "GNU", "C++11", "C2x", "__declspec", "Keyword", "Pragma", "Pragma clang attribute"
+
+ "X","X","","","X", "", ""
+
+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.
+
+.. _`__stdcall`: http://msdn.microsoft.com/en-us/library/zxk0tw93.aspx
+
+
+thiscall (gnu::thiscall, __thiscall, _thiscall)
+-----------------------------------------------
+.. csv-table:: Supported Syntaxes
+ :header: "GNU", "C++11", "C2x", "__declspec", "Keyword", "Pragma", "Pragma clang attribute"
+
+ "X","X","","","X", "", ""
+
+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.
+
+.. _`__thiscall`: http://msdn.microsoft.com/en-us/library/ek8tkfbw.aspx
+
+
+vectorcall (clang::vectorcall, clang::vectorcall, __vectorcall, _vectorcall)
+----------------------------------------------------------------------------
+.. csv-table:: Supported Syntaxes
+ :header: "GNU", "C++11", "C2x", "__declspec", "Keyword", "Pragma", "Pragma clang attribute"
+
+ "X","X","X","","X", "", ""
+
+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. Homogeneous 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.
+
+.. _`__vectorcall`: http://msdn.microsoft.com/en-us/library/dn375768.aspx
+
+
+Consumed Annotation Checking
+============================
+Clang supports additional attributes for checking basic resource management
+properties, specifically for unique objects that have a single owning reference.
+The following attributes are currently supported, although **the implementation
+for these annotations is currently in development and are subject to change.**
+
+callable_when (clang::callable_when)
+------------------------------------
+.. csv-table:: Supported Syntaxes
+ :header: "GNU", "C++11", "C2x", "__declspec", "Keyword", "Pragma", "Pragma clang attribute"
+
+ "X","X","","","", "", "X"
+
+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 (clang::consumable)
+------------------------------
+.. csv-table:: Supported Syntaxes
+ :header: "GNU", "C++11", "C2x", "__declspec", "Keyword", "Pragma", "Pragma clang attribute"
+
+ "X","X","","","", "", "X"
+
+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 (clang::param_typestate)
+----------------------------------------
+.. csv-table:: Supported Syntaxes
+ :header: "GNU", "C++11", "C2x", "__declspec", "Keyword", "Pragma", "Pragma clang attribute"
+
+ "X","X","","","", "", "X"
+
+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 (clang::return_typestate)
+------------------------------------------
+.. csv-table:: Supported Syntaxes
+ :header: "GNU", "C++11", "C2x", "__declspec", "Keyword", "Pragma", "Pragma clang attribute"
+
+ "X","X","","","", "", "X"
+
+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 (clang::set_typestate)
+------------------------------------
+.. csv-table:: Supported Syntaxes
+ :header: "GNU", "C++11", "C2x", "__declspec", "Keyword", "Pragma", "Pragma clang attribute"
+
+ "X","X","","","", "", "X"
+
+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 (clang::test_typestate)
+--------------------------------------
+.. csv-table:: Supported Syntaxes
+ :header: "GNU", "C++11", "C2x", "__declspec", "Keyword", "Pragma", "Pragma clang attribute"
+
+ "X","X","","","", "", "X"
+
+Use ``__attribute__((test_typestate(tested_state)))`` to indicate that a method
+returns true if the object is in the specified state..
+
+
+Type Safety Checking
+====================
+Clang supports additional attributes to enable checking type safety properties
+that can't be enforced by the C type system. To see warnings produced by these
+checks, ensure that -Wtype-safety is enabled. Use cases include:
+
+* MPI library implementations, where these attributes enable checking that
+ the buffer type matches the passed ``MPI_Datatype``;
+* for HDF5 library there is a similar use case to MPI;
+* checking types of variadic functions' arguments for functions like
+ ``fcntl()`` and ``ioctl()``.
+
+You can detect support for these attributes with ``__has_attribute()``. For
+example:
+
+.. code-block:: c++
+
+ #if defined(__has_attribute)
+ # if __has_attribute(argument_with_type_tag) && \
+ __has_attribute(pointer_with_type_tag) && \
+ __has_attribute(type_tag_for_datatype)
+ # define ATTR_MPI_PWT(buffer_idx, type_idx) __attribute__((pointer_with_type_tag(mpi,buffer_idx,type_idx)))
+ /* ... other macros ... */
+ # endif
+ #endif
+
+ #if !defined(ATTR_MPI_PWT)
+ # define ATTR_MPI_PWT(buffer_idx, type_idx)
+ #endif
+
+ int MPI_Send(void *buf, int count, MPI_Datatype datatype /*, other args omitted */)
+ ATTR_MPI_PWT(1,3);
+
+argument_with_type_tag
+----------------------
+.. csv-table:: Supported Syntaxes
+ :header: "GNU", "C++11", "C2x", "__declspec", "Keyword", "Pragma", "Pragma clang attribute"
+
+ "X","X","X","","", "", ""
+
+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.
+
+This attribute is primarily useful for checking arguments of variadic functions
+(``pointer_with_type_tag`` can be used in most non-variadic cases).
+
+In the attribute prototype above:
+ * ``arg_kind`` is an identifier that should be used when annotating all
+ applicable type tags.
+ * ``arg_idx`` provides the position of a function argument. The expected type of
+ this function argument will be determined by the function argument specified
+ by ``type_tag_idx``. In the code example below, "3" means that the type of the
+ function's third argument will be determined by ``type_tag_idx``.
+ * ``type_tag_idx`` provides the position of a function argument. This function
+ argument will be a type tag. The type tag will determine the expected type of
+ the argument specified by ``arg_idx``. In the code example below, "2" means
+ that the type tag associated with the function's second argument should agree
+ with the type of the argument specified by ``arg_idx``.
+
+For example:
+
+.. code-block:: c++
+
+ int fcntl(int fd, int cmd, ...)
+ __attribute__(( argument_with_type_tag(fcntl,3,2) ));
+ // The function's second argument will be a type tag; this type tag will
+ // determine the expected type of the function's third argument.
+
+
+pointer_with_type_tag
+---------------------
+.. csv-table:: Supported Syntaxes
+ :header: "GNU", "C++11", "C2x", "__declspec", "Keyword", "Pragma", "Pragma clang attribute"
+
+ "X","X","X","","", "", ""
+
+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.
+
+In the attribute prototype above:
+ * ``ptr_kind`` is an identifier that should be used when annotating all
+ applicable type tags.
+ * ``ptr_idx`` provides the position of a function argument; this function
+ argument will have a pointer type. The expected pointee type of this pointer
+ type will be determined by the function argument specified by
+ ``type_tag_idx``. In the code example below, "1" means that the pointee type
+ of the function's first argument will be determined by ``type_tag_idx``.
+ * ``type_tag_idx`` provides the position of a function argument; this function
+ argument will be a type tag. The type tag will determine the expected pointee
+ type of the pointer argument specified by ``ptr_idx``. In the code example
+ below, "3" means that the type tag associated with the function's third
+ argument should agree with the pointee type of the pointer argument specified
+ by ``ptr_idx``.
+
+For example:
+
+.. code-block:: c++
+
+ typedef int MPI_Datatype;
+ int MPI_Send(void *buf, int count, MPI_Datatype datatype /*, other args omitted */)
+ __attribute__(( pointer_with_type_tag(mpi,1,3) ));
+ // The function's 3rd argument will be a type tag; this type tag will
+ // determine the expected pointee type of the function's 1st argument.
+
+
+type_tag_for_datatype (clang::type_tag_for_datatype, clang::type_tag_for_datatype)
+----------------------------------------------------------------------------------
+.. csv-table:: Supported Syntaxes
+ :header: "GNU", "C++11", "C2x", "__declspec", "Keyword", "Pragma", "Pragma clang attribute"
+
+ "X","X","X","","", "", ""
+
+When declaring a variable, use
+``__attribute__((type_tag_for_datatype(kind, type)))`` to create a type tag that
+is tied to the ``type`` argument given to the attribute.
+
+In the attribute prototype above:
+ * ``kind`` is an identifier that should be used when annotating all applicable
+ type tags.
+ * ``type`` indicates the name of the type.
+
+Clang supports annotating type tags of two forms.
+
+ * **Type tag that is a reference to a declared identifier.**
+ Use ``__attribute__((type_tag_for_datatype(kind, type)))`` when declaring that
+ identifier:
+
+ .. code-block:: c++
+
+ typedef int MPI_Datatype;
+ extern struct mpi_datatype mpi_datatype_int
+ __attribute__(( type_tag_for_datatype(mpi,int) ));
+ #define MPI_INT ((MPI_Datatype) &mpi_datatype_int)
+ // &mpi_datatype_int is a type tag. It is tied to type "int".
+
+ * **Type tag that is an integral literal.**
+ Declare a ``static const`` variable with an initializer value and attach
+ ``__attribute__((type_tag_for_datatype(kind, type)))`` on that declaration:
+
+ .. code-block:: c++
+
+ typedef int MPI_Datatype;
+ static const MPI_Datatype mpi_datatype_int
+ __attribute__(( type_tag_for_datatype(mpi,int) )) = 42;
+ #define MPI_INT ((MPI_Datatype) 42)
+ // The number 42 is a type tag. It is tied to type "int".
+
+
+The ``type_tag_for_datatype`` attribute also accepts an optional third argument
+that determines how the type of the function argument specified by either
+``arg_idx`` or ``ptr_idx`` is compared against the type associated with the type
+tag. (Recall that for the ``argument_with_type_tag`` attribute, the type of the
+function argument specified by ``arg_idx`` is compared against the type
+associated with the type tag. Also recall that for the ``pointer_with_type_tag``
+attribute, the pointee type of the function argument specified by ``ptr_idx`` is
+compared against the type associated with the type tag.) There are two supported
+values for this optional third argument:
+
+ * ``layout_compatible`` will cause types to be compared according to
+ layout-compatibility rules (In C++11 [class.mem] p 17, 18, see the
+ layout-compatibility rules for two standard-layout struct types and for two
+ standard-layout union types). This is useful when creating a type tag
+ associated with a struct or union type. For example:
+
+ .. code-block:: c++
+
+ /* In mpi.h */
+ typedef int MPI_Datatype;
+ 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)
+
+ int MPI_Send(void *buf, int count, MPI_Datatype datatype, ...)
+ __attribute__(( pointer_with_type_tag(mpi,1,3) ));
+
+ /* In user code */
+ struct my_pair { double a; int b; };
+ struct my_pair *buffer;
+ MPI_Send(buffer, 1, MPI_DOUBLE_INT /*, ... */); // no warning because the
+ // layout of my_pair is
+ // compatible with that of
+ // internal_mpi_double_int
+
+ struct my_int_pair { int a; int b; }
+ struct my_int_pair *buffer2;
+ MPI_Send(buffer2, 1, MPI_DOUBLE_INT /*, ... */); // warning because the
+ // layout of my_int_pair
+ // does not match that of
+ // internal_mpi_double_int
+
+ * ``must_be_null`` specifies that the function argument specified by either
+ ``arg_idx`` (for the ``argument_with_type_tag`` attribute) or ``ptr_idx`` (for
+ the ``pointer_with_type_tag`` attribute) should be a null pointer constant.
+ The second argument to the ``type_tag_for_datatype`` attribute is ignored. For
+ example:
+
+ .. code-block:: c++
+
+ /* In mpi.h */
+ typedef int MPI_Datatype;
+ 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)
+ int MPI_Send(void *buf, int count, MPI_Datatype datatype, ...)
+ __attribute__(( pointer_with_type_tag(mpi,1,3) ));
+
+ /* In user code */
+ struct my_pair { double a; int b; };
+ struct my_pair *buffer;
+ MPI_Send(buffer, 1, MPI_DATATYPE_NULL /*, ... */); // warning: MPI_DATATYPE_NULL
+ // was specified but buffer
+ // is not a null pointer
+
+
+OpenCL Address Spaces
+=====================
+The address space qualifier may be used to specify the region of memory that is
+used to allocate the object. OpenCL supports the following address spaces:
+__generic(generic), __global(global), __local(local), __private(private),
+__constant(constant).
+
+ .. code-block:: c
+
+ __constant int c = ...;
+
+ __generic int* foo(global int* g) {
+ __local int* l;
+ private int p;
+ ...
+ return l;
+ }
+
+More details can be found in the OpenCL C language Spec v2.0, Section 6.5.
+
+constant (__constant)
+---------------------
+.. csv-table:: Supported Syntaxes
+ :header: "GNU", "C++11", "C2x", "__declspec", "Keyword", "Pragma", "Pragma clang attribute"
+
+ "","","","","X", "", ""
+
+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)
+-------------------
+.. csv-table:: Supported Syntaxes
+ :header: "GNU", "C++11", "C2x", "__declspec", "Keyword", "Pragma", "Pragma clang attribute"
+
+ "","","","","X", "", ""
+
+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)
+-----------------
+.. csv-table:: Supported Syntaxes
+ :header: "GNU", "C++11", "C2x", "__declspec", "Keyword", "Pragma", "Pragma clang attribute"
+
+ "","","","","X", "", ""
+
+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)
+---------------
+.. csv-table:: Supported Syntaxes
+ :header: "GNU", "C++11", "C2x", "__declspec", "Keyword", "Pragma", "Pragma clang attribute"
+
+ "","","","","X", "", ""
+
+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)
+-------------------
+.. csv-table:: Supported Syntaxes
+ :header: "GNU", "C++11", "C2x", "__declspec", "Keyword", "Pragma", "Pragma clang attribute"
+
+ "","","","","X", "", ""
+
+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.
+
+
+Nullability Attributes
+======================
+Whether a particular pointer may be "null" is an important concern when working with pointers in the C family of languages. The various nullability attributes indicate whether a particular pointer can be null or not, which makes APIs more expressive and can help static analysis tools identify bugs involving null pointers. Clang supports several kinds of nullability attributes: the ``nonnull`` and ``returns_nonnull`` attributes indicate which function or method parameters and result types can never be null, while nullability type qualifiers indicate which pointer types can be null (``_Nullable``) or cannot be null (``_Nonnull``).
+
+The nullability (type) qualifiers express whether a value of a given pointer type can be null (the ``_Nullable`` qualifier), doesn't have a defined meaning for null (the ``_Nonnull`` qualifier), or for which the purpose of null is unclear (the ``_Null_unspecified`` qualifier). Because nullability qualifiers are expressed within the type system, they are more general than the ``nonnull`` and ``returns_nonnull`` attributes, allowing one to express (for example) a nullable pointer to an array of nonnull pointers. Nullability qualifiers are written to the right of the pointer to which they apply. For example:
+
+ .. code-block:: c
+
+ // No meaningful result when 'ptr' is null (here, it happens to be undefined behavior).
+ int fetch(int * _Nonnull ptr) { return *ptr; }
+
+ // 'ptr' may be null.
+ int fetch_or_zero(int * _Nullable ptr) {
+ return ptr ? *ptr : 0;
+ }
+
+ // A nullable pointer to non-null pointers to const characters.
+ const char *join_strings(const char * _Nonnull * _Nullable strings, unsigned n);
+
+In Objective-C, there is an alternate spelling for the nullability qualifiers that can be used in Objective-C methods and properties using context-sensitive, non-underscored keywords. For example:
+
+ .. code-block:: objective-c
+
+ @interface NSView : NSResponder
+ - (nullable NSView *)ancestorSharedWithView:(nonnull NSView *)aView;
+ @property (assign, nullable) NSView *superview;
+ @property (readonly, nonnull) NSArray *subviews;
+ @end
+
+_Nonnull
+--------
+.. csv-table:: Supported Syntaxes
+ :header: "GNU", "C++11", "C2x", "__declspec", "Keyword", "Pragma", "Pragma clang attribute"
+
+ "","","","","X", "", ""
+
+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:
+
+ .. code-block:: c
+
+ 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
+-----------------
+.. csv-table:: Supported Syntaxes
+ :header: "GNU", "C++11", "C2x", "__declspec", "Keyword", "Pragma", "Pragma clang attribute"
+
+ "","","","","X", "", ""
+
+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
+---------
+.. csv-table:: Supported Syntaxes
+ :header: "GNU", "C++11", "C2x", "__declspec", "Keyword", "Pragma", "Pragma clang attribute"
+
+ "","","","","X", "", ""
+
+The ``_Nullable`` nullability qualifier indicates that a value of the ``_Nullable`` pointer type can be null. For example, given:
+
+ .. code-block:: c
+
+ int fetch_or_zero(int * _Nullable ptr);
+
+a caller of ``fetch_or_zero`` can provide null.
+
+
+nonnull (gnu::nonnull)
+----------------------
+.. csv-table:: Supported Syntaxes
+ :header: "GNU", "C++11", "C2x", "__declspec", "Keyword", "Pragma", "Pragma clang attribute"
+
+ "X","X","","","", "", ""
+
+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 <https://gcc.gnu.org/onlinedocs/gcc/Common-Function-Attributes.html#Common-Function-Attributes>`_) 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:
+
+ .. code-block:: c
+
+ 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:
+
+ .. code-block:: c
+
+ 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:
+
+ .. code-block:: c
+
+ 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)
+--------------------------------------
+.. csv-table:: Supported Syntaxes
+ :header: "GNU", "C++11", "C2x", "__declspec", "Keyword", "Pragma", "Pragma clang attribute"
+
+ "X","X","","","", "", "X"
+
+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:
+
+ .. code-block:: c
+
+ 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
+
+
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