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ATTRIBUTE(3)               Library Functions Manual               ATTRIBUTE(3)

     attribute -- non-standard GCC attribute extensions

     #include <&lt;sys/cdefs.h>&gt;














     The GNU Compiler Collection (GCC) provides many extensions to the
     standard C language.  Among these are the so-called attributes.  In
     NetBSD all attributes are provided in a restricted namespace.  The
     described macros should be preferred instead of using the GCC's
     __attribute__ extension directly.

          The gcc(1) compiler knows that certain functions such as abort(3)
          and exit(3) can never return any value.  When such a function is
          equipped with __dead, certain optimizations are possible.  Obviously
          a __dead function can never have return type other than void.

          A __pure function is defined to be one that has no effects except
          the return value, which is assumed to depend only on the function
          parameters and/or global variables.  Any access to parameters and/or
          global variables must also be read-only.  A function that depends on
          volatile memory, or other comparable system resource that can change
          between two consecutive calls, can never be __pure.  Many math(3)
          functions satisfy the definition of a __pure function, at least in
          theory.  Other examples include strlen(3) and strcmp(3).

          A ``const function'' is a stricter variant of ``pure functions''.
          In addition to the restrictions of pure functions, a function
          declared with __constfunc can never access global variables nor take
          pointers as parameters.  The return value of these functions must
          depend only on the passed-by-value parameters.  Note also that a
          function that calls non-const functions can not be __constfunc.  The
          canonical example of a const function would be abs(3).  As with pure
          functions, certain micro-optimizations are possible for functions
          declared with __constfunc.

          GCC is known for aggressive function inlining.  Sometimes it is
          known that inlining is undesirable or that a function will perform
          incorrectly when inlined.  The __noinline macro expands to a
          function attribute that prevents GCC for inlining the function,
          irrespective whether the function was declared with the inline
          keyword.  The attribute takes precedence over all other compiler
          options related to inlining.

          In most GCC versions the common -Wall flag enables warnings produced
          by functions that are defined but unused.  Marking an unused
          function with the __unused macro inhibits these warnings.

          The __used macro expands to an attribute that informs GCC that a
          static variable or function is to be always retained in the object
          file even if it is unreferenced.

          The __packed macro expands to an attribute that forces a variable or
          structure field to have the smallest possible alignment, potentially
          disregarding architecture specific alignment requirements.  The
          smallest possible alignment is effectively one byte for variables
          and one bit for fields.  If specified on a struct or union, all
          variables therein are also packed.  The __packed macro is often
          useful when dealing with data that is in a particular static format
          on the disk, wire, or memory.

          The __aligned() macro expands to an attribute that specifies the
          minimum alignment in bytes for a variable, structure field, or
          function.  In other words, the specified object should have an
          alignment of at least x bytes, as opposed to the minimum alignment
          requirements dictated by the architecture and the ABI.  Possible use
          cases include:

                o   Mixing assembly and C code.

                o   Dealing with hardware that may impose alignment
                    requirements greater than the architecture itself.

                o   Using instructions that may impose special alignment
                    requirements.  Typical example would be alignment of
                    frequently used objects along processor cache lines.

          Note that when used with functions, structures, or structure
          members, __aligned() can only be used to increase the alignment.  If
          the macro is however used as part of a typedef, the alignment can
          both increase and decrease.  Otherwise it is only possible to
          decrease the alignment for variables and fields by using the
          __packed macro.  The effectiveness of __aligned() is largely
          dependent on the linker.  The __alignof__(3) operator can be used to
          examine the alignment.

          The __section() macro expands to an attribute that specifies a
          particular section to which a variable or function should be placed.
          Normally the compiler places the generated objects to sections such
          as ``data'' or ``text''.  By using __section(), it is possible to
          override this behavior, perhaps in order to place some variables
          into particular sections specific to unique hardware.

          The __read_mostly macro uses __section() to place a variable or
          function into the ``.data.read_mostly'' section of the (kernel)
          elf(5).  The use of __read_mostly allows infrequently modified data
          to be grouped together; it is expected that the cachelines of rarely
          and frequently modified data structures are this way separated.
          Candidates for __read_mostly include variables that are initialized
          once, read very often, and seldom written to.

          The __cacheline_aligned macro behaves like __read_mostly, but the
          used section is ``.data.cacheline_aligned'' instead.  It also uses
          __aligned() to set the minimum alignment into a predefined coherency
          unit.  This should ensure that frequently used data structures are
          aligned on cacheline boundaries.  Both __cacheline_aligned and
          __read_mostly are only available for the kernel.

          A branch is generally defined to be a conditional execution of a
          program depending on whether a certain flow control mechanism is
          altered.  Typical example would be a ``if-then-else'' sequence used
          in high-level languages or a jump instruction used in machine-level
          code.  A branch prediction would then be defined as an attempt to
          guess whether a conditional branch will be taken.

          The macros __predict_true() and __predict_false() annotate the
          likelihood of whether a branch will evaluate to true or false.  The
          rationale is to improve instruction pipelining.  Semantically
          __predict_true expects that the integral expression exp equals 1.

          The __predict_false expands to an attribute that instructs the
          compiler to predict that a given branch will be likely false.  As
          programmers are notoriously bad at predicting the likely behavior of
          their code, profiling and empirical evidence should precede the use
          of __predict_false and __predict_true.

     gcc(1), __builtin_object_size(3), cdefs(3), c(7)

     It goes without saying that portable applications should steer clear from
     non-standard extensions specific to any given compiler.  Even when
     portability is not a concern, use these macros sparsely and wisely.

NetBSD 6.1.5                   December 19, 2010                  NetBSD 6.1.5