gcc/ada/doc/gnat_ugn/inline_assembler.rst - gcc - Git at Google

 .. role:: switch(samp)

 .. _Inline_Assembler:

 ****************
 Inline Assembler
 ****************

 .. index:: Inline Assembler

 If you need to write low-level software that interacts directly
 with the hardware, Ada provides two ways to incorporate assembly
 language code into your program.  First, you can import and invoke
 external routines written in assembly language, an Ada feature fully
 supported by GNAT.  However, for small sections of code it may be simpler
 or more efficient to include assembly language statements directly
 in your Ada source program, using the facilities of the implementation-defined
 package ``System.Machine_Code``, which incorporates the gcc
 Inline Assembler.  The Inline Assembler approach offers a number of advantages,
 including the following:

 * No need to use non-Ada tools
 * Consistent interface over different targets
 * Automatic usage of the proper calling conventions
 * Access to Ada constants and variables
 * Definition of intrinsic routines
 * Possibility of inlining a subprogram comprising assembler code
 * Code optimizer can take Inline Assembler code into account

 This appendix presents a series of examples to show you how to use
 the Inline Assembler.  Although it focuses on the Intel x86,
 the general approach applies also to other processors.
 It is assumed that you are familiar with Ada
 and with assembly language programming.

 .. _Basic_Assembler_Syntax:

 Basic Assembler Syntax
 ======================

 The assembler used by GNAT and gcc is based not on the Intel assembly
 language, but rather on a language that descends from the AT&T Unix
 assembler ``as`` (and which is often referred to as 'AT&T syntax').
 The following table summarizes the main features of ``as`` syntax
 and points out the differences from the Intel conventions.
 See the gcc ``as`` and ``gas`` (an ``as`` macro
 pre-processor) documentation for further information.


 | *Register names*
 |   gcc / ``as``: Prefix with '%'; for example ``%eax``
 |   Intel: No extra punctuation; for example ``eax``


 | *Immediate operand*
 |   gcc / ``as``: Prefix with '$'; for example ``$4``
 |   Intel: No extra punctuation; for example ``4``


 | *Address*
 |   gcc / ``as``: Prefix with '$'; for example ``$loc``
 |   Intel: No extra punctuation; for example ``loc``


 | *Memory contents*
 |   gcc / ``as``: No extra punctuation; for example ``loc``
 |   Intel: Square brackets; for example ``[loc]``


 | *Register contents*
 |   gcc / ``as``: Parentheses; for example ``(%eax)``
 |   Intel: Square brackets; for example ``[eax]``


 | *Hexadecimal numbers*
 |   gcc / ``as``: Leading '0x' (C language syntax); for example ``0xA0``
 |   Intel: Trailing 'h'; for example ``A0h``


 | *Operand size*
 |   gcc / ``as``: Explicit in op code; for example ``movw`` to move a 16-bit word
 |   Intel: Implicit, deduced by assembler; for example ``mov``


 | *Instruction repetition*
 |   gcc / ``as``: Split into two lines; for example
 |     ``rep``
 |     ``stosl``
 |   Intel: Keep on one line; for example ``rep stosl``


 | *Order of operands*
 |   gcc / ``as``: Source first; for example ``movw $4, %eax``
 |   Intel: Destination first; for example ``mov eax, 4``


 .. _A_Simple_Example_of_Inline_Assembler:

 A Simple Example of Inline Assembler
 ====================================

 The following example will generate a single assembly language statement,
 ``nop``, which does nothing.  Despite its lack of run-time effect,
 the example will be useful in illustrating the basics of
 the Inline Assembler facility.

   .. code-block:: ada

      with System.Machine_Code; use System.Machine_Code;
      procedure Nothing is
      begin
         Asm ("nop");
      end Nothing;

 ``Asm`` is a procedure declared in package ``System.Machine_Code``;
 here it takes one parameter, a *template string* that must be a static
 expression and that will form the generated instruction.
 ``Asm`` may be regarded as a compile-time procedure that parses
 the template string and additional parameters (none here),
 from which it generates a sequence of assembly language instructions.

 The examples in this chapter will illustrate several of the forms
 for invoking ``Asm``; a complete specification of the syntax
 is found in the ``Machine_Code_Insertions`` section of the
 :title:`GNAT Reference Manual`.

 Under the standard GNAT conventions, the ``Nothing`` procedure
 should be in a file named :file:`nothing.adb`.
 You can build the executable in the usual way:

   ::

      $ gnatmake nothing

 However, the interesting aspect of this example is not its run-time behavior
 but rather the generated assembly code.
 To see this output, invoke the compiler as follows:

   ::

      $  gcc -c -S -fomit-frame-pointer -gnatp nothing.adb

 where the options are:

 * :switch:`-c`
     compile only (no bind or link)

 * :switch:`-S`
     generate assembler listing

 * :switch:`-fomit-frame-pointer`
     do not set up separate stack frames

 * :switch:`-gnatp`
     do not add runtime checks

 This gives a human-readable assembler version of the code. The resulting
 file will have the same name as the Ada source file, but with a ``.s``
 extension. In our example, the file :file:`nothing.s` has the following
 contents:

   ::

      .file "nothing.adb"
      gcc2_compiled.:
      ___gnu_compiled_ada:
      .text
         .align 4
      .globl __ada_nothing
      __ada_nothing:
      #APP
         nop
      #NO_APP
         jmp L1
         .align 2,0x90
      L1:
         ret

 The assembly code you included is clearly indicated by
 the compiler, between the ``#APP`` and ``#NO_APP``
 delimiters. The character before the 'APP' and 'NOAPP'
 can differ on different targets. For example, GNU/Linux uses '#APP' while
 on NT you will see '/APP'.

 If you make a mistake in your assembler code (such as using the
 wrong size modifier, or using a wrong operand for the instruction) GNAT
 will report this error in a temporary file, which will be deleted when
 the compilation is finished.  Generating an assembler file will help
 in such cases, since you can assemble this file separately using the
 ``as`` assembler that comes with gcc.

 Assembling the file using the command

   ::

      $ as nothing.s

 will give you error messages whose lines correspond to the assembler
 input file, so you can easily find and correct any mistakes you made.
 If there are no errors, ``as`` will generate an object file
 :file:`nothing.out`.


 .. _Output_Variables_in_Inline_Assembler:

 Output Variables in Inline Assembler
 ====================================

 The examples in this section, showing how to access the processor flags,
 illustrate how to specify the destination operands for assembly language
 statements.


   .. code-block:: ada

      with Interfaces; use Interfaces;
      with Ada.Text_IO; use Ada.Text_IO;
      with System.Machine_Code; use System.Machine_Code;
      procedure Get_Flags is
         Flags : Unsigned_32;
         use ASCII;
      begin
         Asm ("pushfl"          & LF & HT & -- push flags on stack
              "popl %%eax"      & LF & HT & -- load eax with flags
              "movl %%eax, %0",             -- store flags in variable
              Outputs => Unsigned_32'Asm_Output ("=g", Flags));
         Put_Line ("Flags register:" & Flags'Img);
      end Get_Flags;

 In order to have a nicely aligned assembly listing, we have separated
 multiple assembler statements in the Asm template string with linefeed
 (ASCII.LF) and horizontal tab (ASCII.HT) characters.
 The resulting section of the assembly output file is:

   ::

      #APP
         pushfl
         popl %eax
         movl %eax, -40(%ebp)
      #NO_APP

 It would have been legal to write the Asm invocation as:

   .. code-block:: ada

      Asm ("pushfl popl %%eax movl %%eax, %0")

 but in the generated assembler file, this would come out as:

   ::

      #APP
         pushfl popl %eax movl %eax, -40(%ebp)
      #NO_APP

 which is not so convenient for the human reader.

 We use Ada comments
 at the end of each line to explain what the assembler instructions
 actually do.  This is a useful convention.

 When writing Inline Assembler instructions, you need to precede each register
 and variable name with a percent sign.  Since the assembler already requires
 a percent sign at the beginning of a register name, you need two consecutive
 percent signs for such names in the Asm template string, thus ``%%eax``.
 In the generated assembly code, one of the percent signs will be stripped off.

 Names such as ``%0``, ``%1``, ``%2``, etc., denote input or output
 variables: operands you later define using ``Input`` or ``Output``
 parameters to ``Asm``.
 An output variable is illustrated in
 the third statement in the Asm template string:

   ::

      movl %%eax, %0

 The intent is to store the contents of the eax register in a variable that can
 be accessed in Ada.  Simply writing ``movl %%eax, Flags`` would not
 necessarily work, since the compiler might optimize by using a register
 to hold Flags, and the expansion of the ``movl`` instruction would not be
 aware of this optimization.  The solution is not to store the result directly
 but rather to advise the compiler to choose the correct operand form;
 that is the purpose of the ``%0`` output variable.

 Information about the output variable is supplied in the ``Outputs``
 parameter to ``Asm``:

   .. code-block:: ada

      Outputs => Unsigned_32'Asm_Output ("=g", Flags));

 The output is defined by the ``Asm_Output`` attribute of the target type;
 the general format is

   .. code-block:: ada

      Type'Asm_Output (constraint_string, variable_name)

 The constraint string directs the compiler how
 to store/access the associated variable.  In the example

   .. code-block:: ada

      Unsigned_32'Asm_Output ("=m", Flags);

 the ``"m"`` (memory) constraint tells the compiler that the variable
 ``Flags`` should be stored in a memory variable, thus preventing
 the optimizer from keeping it in a register.  In contrast,

   .. code-block:: ada

      Unsigned_32'Asm_Output ("=r", Flags);

 uses the ``"r"`` (register) constraint, telling the compiler to
 store the variable in a register.

 If the constraint is preceded by the equal character '=', it tells
 the compiler that the variable will be used to store data into it.

 In the ``Get_Flags`` example, we used the ``"g"`` (global) constraint,
 allowing the optimizer to choose whatever it deems best.

 There are a fairly large number of constraints, but the ones that are
 most useful (for the Intel x86 processor) are the following:

  ====== ==========================================
  *=*    output constraint
  *g*    global (i.e., can be stored anywhere)
  *m*    in memory
  *I*    a constant
  *a*    use eax
  *b*    use ebx
  *c*    use ecx
  *d*    use edx
  *S*    use esi
  *D*    use edi
  *r*    use one of eax, ebx, ecx or edx
  *q*    use one of eax, ebx, ecx, edx, esi or edi
  ====== ==========================================

 The full set of constraints is described in the gcc and ``as``
 documentation; note that it is possible to combine certain constraints
 in one constraint string.

 You specify the association of an output variable with an assembler operand
 through the :samp:`%{n}` notation, where *n* is a non-negative
 integer.  Thus in

   .. code-block:: ada

      Asm ("pushfl"          & LF & HT & -- push flags on stack
           "popl %%eax"      & LF & HT & -- load eax with flags
           "movl %%eax, %0",             -- store flags in variable
           Outputs => Unsigned_32'Asm_Output ("=g", Flags));


 ``%0`` will be replaced in the expanded code by the appropriate operand,
 whatever
 the compiler decided for the ``Flags`` variable.

 In general, you may have any number of output variables:

 * Count the operands starting at 0; thus ``%0``, ``%1``, etc.

 * Specify the ``Outputs`` parameter as a parenthesized comma-separated list
   of ``Asm_Output`` attributes

 For example:

   .. code-block:: ada

      Asm ("movl %%eax, %0" & LF & HT &
           "movl %%ebx, %1" & LF & HT &
           "movl %%ecx, %2",
           Outputs => (Unsigned_32'Asm_Output ("=g", Var_A),   --  %0 = Var_A
                       Unsigned_32'Asm_Output ("=g", Var_B),   --  %1 = Var_B
                       Unsigned_32'Asm_Output ("=g", Var_C))); --  %2 = Var_C

 where ``Var_A``, ``Var_B``, and ``Var_C`` are variables
 in the Ada program.

 As a variation on the ``Get_Flags`` example, we can use the constraints
 string to direct the compiler to store the eax register into the ``Flags``
 variable, instead of including the store instruction explicitly in the
 ``Asm`` template string:

   .. code-block:: ada

      with Interfaces; use Interfaces;
      with Ada.Text_IO; use Ada.Text_IO;
      with System.Machine_Code; use System.Machine_Code;
      procedure Get_Flags_2 is
         Flags : Unsigned_32;
         use ASCII;
      begin
         Asm ("pushfl"      & LF & HT & -- push flags on stack
              "popl %%eax",             -- save flags in eax
              Outputs => Unsigned_32'Asm_Output ("=a", Flags));
         Put_Line ("Flags register:" & Flags'Img);
      end Get_Flags_2;

 The ``"a"`` constraint tells the compiler that the ``Flags``
 variable will come from the eax register. Here is the resulting code:

   ::

      #APP
         pushfl
         popl %eax
      #NO_APP
         movl %eax,-40(%ebp)

 The compiler generated the store of eax into Flags after
 expanding the assembler code.

 Actually, there was no need to pop the flags into the eax register;
 more simply, we could just pop the flags directly into the program variable:

   .. code-block:: ada

      with Interfaces; use Interfaces;
      with Ada.Text_IO; use Ada.Text_IO;
      with System.Machine_Code; use System.Machine_Code;
      procedure Get_Flags_3 is
         Flags : Unsigned_32;
         use ASCII;
      begin
         Asm ("pushfl"  & LF & HT & -- push flags on stack
              "pop %0",             -- save flags in Flags
              Outputs => Unsigned_32'Asm_Output ("=g", Flags));
         Put_Line ("Flags register:" & Flags'Img);
      end Get_Flags_3;


 .. _Input_Variables_in_Inline_Assembler:

 Input Variables in Inline Assembler
 ===================================

 The example in this section illustrates how to specify the source operands
 for assembly language statements.
 The program simply increments its input value by 1:

   .. code-block:: ada

      with Interfaces; use Interfaces;
      with Ada.Text_IO; use Ada.Text_IO;
      with System.Machine_Code; use System.Machine_Code;
      procedure Increment is

         function Incr (Value : Unsigned_32) return Unsigned_32 is
            Result : Unsigned_32;
         begin
            Asm ("incl %0",
                 Outputs => Unsigned_32'Asm_Output ("=a", Result),
                 Inputs  => Unsigned_32'Asm_Input ("a", Value));
            return Result;
         end Incr;

         Value : Unsigned_32;

      begin
         Value := 5;
         Put_Line ("Value before is" & Value'Img);
         Value := Incr (Value);
        Put_Line ("Value after is" & Value'Img);
      end Increment;

 The ``Outputs`` parameter to ``Asm`` specifies
 that the result will be in the eax register and that it is to be stored
 in the ``Result`` variable.

 The ``Inputs`` parameter looks much like the ``Outputs`` parameter,
 but with an ``Asm_Input`` attribute.
 The ``"="`` constraint, indicating an output value, is not present.

 You can have multiple input variables, in the same way that you can have more
 than one output variable.

 The parameter count (%0, %1) etc, still starts at the first output statement,
 and continues with the input statements.

 Just as the ``Outputs`` parameter causes the register to be stored into the
 target variable after execution of the assembler statements, so does the
 ``Inputs`` parameter cause its variable to be loaded into the register
 before execution of the assembler statements.

 Thus the effect of the ``Asm`` invocation is:

 * load the 32-bit value of ``Value`` into eax
 * execute the ``incl %eax`` instruction
 * store the contents of eax into the ``Result`` variable

 The resulting assembler file (with :switch:`-O2` optimization) contains:

   ::

      _increment__incr.1:
         subl $4,%esp
         movl 8(%esp),%eax
      #APP
         incl %eax
      #NO_APP
         movl %eax,%edx
         movl %ecx,(%esp)
         addl $4,%esp
         ret


 .. _Inlining_Inline_Assembler_Code:

 Inlining Inline Assembler Code
 ==============================

 For a short subprogram such as the ``Incr`` function in the previous
 section, the overhead of the call and return (creating / deleting the stack
 frame) can be significant, compared to the amount of code in the subprogram
 body.  A solution is to apply Ada's ``Inline`` pragma to the subprogram,
 which directs the compiler to expand invocations of the subprogram at the
 point(s) of call, instead of setting up a stack frame for out-of-line calls.
 Here is the resulting program:

   .. code-block:: ada

      with Interfaces; use Interfaces;
      with Ada.Text_IO; use Ada.Text_IO;
      with System.Machine_Code; use System.Machine_Code;
      procedure Increment_2 is

         function Incr (Value : Unsigned_32) return Unsigned_32 is
            Result : Unsigned_32;
         begin
            Asm ("incl %0",
                 Outputs => Unsigned_32'Asm_Output ("=a", Result),
                 Inputs  => Unsigned_32'Asm_Input ("a", Value));
            return Result;
         end Incr;
         pragma Inline (Increment);

         Value : Unsigned_32;

      begin
         Value := 5;
         Put_Line ("Value before is" & Value'Img);
         Value := Increment (Value);
         Put_Line ("Value after is" & Value'Img);
      end Increment_2;

 Compile the program with both optimization (:switch:`-O2`) and inlining
 (:switch:`-gnatn`) enabled.

 The ``Incr`` function is still compiled as usual, but at the
 point in ``Increment`` where our function used to be called:


   ::

      pushl %edi
      call _increment__incr.1

 the code for the function body directly appears:


   ::

      movl %esi,%eax
      #APP
         incl %eax
      #NO_APP
         movl %eax,%edx

 thus saving the overhead of stack frame setup and an out-of-line call.


 .. _Other_Asm_Functionality:

 Other ``Asm`` Functionality
 ===========================

 This section describes two important parameters to the ``Asm``
 procedure: ``Clobber``, which identifies register usage;
 and ``Volatile``, which inhibits unwanted optimizations.

 .. _The_Clobber_Parameter:

 The ``Clobber`` Parameter
 -------------------------

 One of the dangers of intermixing assembly language and a compiled language
 such as Ada is that the compiler needs to be aware of which registers are
 being used by the assembly code.  In some cases, such as the earlier examples,
 the constraint string is sufficient to indicate register usage (e.g.,
 ``"a"`` for
 the eax register).  But more generally, the compiler needs an explicit
 identification of the registers that are used by the Inline Assembly
 statements.

 Using a register that the compiler doesn't know about
 could be a side effect of an instruction (like ``mull``
 storing its result in both eax and edx).
 It can also arise from explicit register usage in your
 assembly code; for example:

   .. code-block:: ada

      Asm ("movl %0, %%ebx" & LF & HT &
           "movl %%ebx, %1",
           Outputs => Unsigned_32'Asm_Output ("=g", Var_Out),
           Inputs  => Unsigned_32'Asm_Input  ("g", Var_In));

 where the compiler (since it does not analyze the ``Asm`` template string)
 does not know you are using the ebx register.

 In such cases you need to supply the ``Clobber`` parameter to ``Asm``,
 to identify the registers that will be used by your assembly code:


   .. code-block:: ada

      Asm ("movl %0, %%ebx" & LF & HT &
           "movl %%ebx, %1",
           Outputs => Unsigned_32'Asm_Output ("=g", Var_Out),
           Inputs  => Unsigned_32'Asm_Input  ("g", Var_In),
           Clobber => "ebx");

 The Clobber parameter is a static string expression specifying the
 register(s) you are using.  Note that register names are *not* prefixed
 by a percent sign. Also, if more than one register is used then their names
 are separated by commas; e.g., ``"eax, ebx"``

 The ``Clobber`` parameter has several additional uses:

 * Use 'register' name ``cc`` to indicate that flags might have changed
 * Use 'register' name ``memory`` if you changed a memory location


 .. _The_Volatile_Parameter:

 The ``Volatile`` Parameter
 --------------------------

 .. index:: Volatile parameter

 Compiler optimizations in the presence of Inline Assembler may sometimes have
 unwanted effects.  For example, when an ``Asm`` invocation with an input
 variable is inside a loop, the compiler might move the loading of the input
 variable outside the loop, regarding it as a one-time initialization.

 If this effect is not desired, you can disable such optimizations by setting
 the ``Volatile`` parameter to ``True``; for example:

   .. code-block:: ada

      Asm ("movl %0, %%ebx" & LF & HT &
           "movl %%ebx, %1",
           Outputs  => Unsigned_32'Asm_Output ("=g", Var_Out),
           Inputs   => Unsigned_32'Asm_Input  ("g", Var_In),
           Clobber  => "ebx",
           Volatile => True);

 By default, ``Volatile`` is set to ``False`` unless there is no
 ``Outputs`` parameter.

 Although setting ``Volatile`` to ``True`` prevents unwanted
 optimizations, it will also disable other optimizations that might be
 important for efficiency. In general, you should set ``Volatile``
 to ``True`` only if the compiler's optimizations have created
 problems.
	.. role:: switch(samp)

	.. _Inline_Assembler:

	****************
	Inline Assembler
	****************

	.. index:: Inline Assembler

	If you need to write low-level software that interacts directly
	with the hardware, Ada provides two ways to incorporate assembly
	language code into your program. First, you can import and invoke
	external routines written in assembly language, an Ada feature fully
	supported by GNAT. However, for small sections of code it may be simpler
	or more efficient to include assembly language statements directly
	in your Ada source program, using the facilities of the implementation-defined
	package ``System.Machine_Code``, which incorporates the gcc
	Inline Assembler. The Inline Assembler approach offers a number of advantages,
	including the following:

	* No need to use non-Ada tools
	* Consistent interface over different targets
	* Automatic usage of the proper calling conventions
	* Access to Ada constants and variables
	* Definition of intrinsic routines
	* Possibility of inlining a subprogram comprising assembler code
	* Code optimizer can take Inline Assembler code into account

	This appendix presents a series of examples to show you how to use
	the Inline Assembler. Although it focuses on the Intel x86,
	the general approach applies also to other processors.
	It is assumed that you are familiar with Ada
	and with assembly language programming.

	.. _Basic_Assembler_Syntax:

	Basic Assembler Syntax
	======================

	The assembler used by GNAT and gcc is based not on the Intel assembly
	language, but rather on a language that descends from the AT&T Unix
	assembler ``as`` (and which is often referred to as 'AT&T syntax').
	The following table summarizes the main features of ``as`` syntax
	and points out the differences from the Intel conventions.
	See the gcc ``as`` and ``gas`` (an ``as`` macro
	pre-processor) documentation for further information.


	\| Register names
	\| gcc / ``as``: Prefix with '%'; for example ``%eax``
	\| Intel: No extra punctuation; for example ``eax``


	\| Immediate operand
	\| gcc / ``as``: Prefix with '$'; for example ``$4``
	\| Intel: No extra punctuation; for example ``4``


	\| Address
	\| gcc / ``as``: Prefix with '$'; for example ``$loc``
	\| Intel: No extra punctuation; for example ``loc``


	\| Memory contents
	\| gcc / ``as``: No extra punctuation; for example ``loc``
	\| Intel: Square brackets; for example ``[loc]``


	\| Register contents
	\| gcc / ``as``: Parentheses; for example ``(%eax)``
	\| Intel: Square brackets; for example ``[eax]``


	\| Hexadecimal numbers
	\| gcc / ``as``: Leading '0x' (C language syntax); for example ``0xA0``
	\| Intel: Trailing 'h'; for example ``A0h``


	\| Operand size
	\| gcc / ``as``: Explicit in op code; for example ``movw`` to move a 16-bit word
	\| Intel: Implicit, deduced by assembler; for example ``mov``


	\| Instruction repetition
	\| gcc / ``as``: Split into two lines; for example
	\| ``rep``
	\| ``stosl``
	\| Intel: Keep on one line; for example ``rep stosl``


	\| Order of operands
	\| gcc / ``as``: Source first; for example ``movw $4, %eax``
	\| Intel: Destination first; for example ``mov eax, 4``


	.. _A_Simple_Example_of_Inline_Assembler:

	A Simple Example of Inline Assembler
	====================================

	The following example will generate a single assembly language statement,
	``nop``, which does nothing. Despite its lack of run-time effect,
	the example will be useful in illustrating the basics of
	the Inline Assembler facility.

	.. code-block:: ada

	with System.Machine_Code; use System.Machine_Code;
	procedure Nothing is
	begin
	Asm ("nop");
	end Nothing;

	``Asm`` is a procedure declared in package ``System.Machine_Code``;
	here it takes one parameter, a template string that must be a static
	expression and that will form the generated instruction.
	``Asm`` may be regarded as a compile-time procedure that parses
	the template string and additional parameters (none here),
	from which it generates a sequence of assembly language instructions.

	The examples in this chapter will illustrate several of the forms
	for invoking ``Asm``; a complete specification of the syntax
	is found in the ``Machine_Code_Insertions`` section of the
	:title:`GNAT Reference Manual`.

	Under the standard GNAT conventions, the ``Nothing`` procedure
	should be in a file named :file:`nothing.adb`.
	You can build the executable in the usual way:

	::

	$ gnatmake nothing

	However, the interesting aspect of this example is not its run-time behavior
	but rather the generated assembly code.
	To see this output, invoke the compiler as follows:

	::

	$ gcc -c -S -fomit-frame-pointer -gnatp nothing.adb

	where the options are:

	* :switch:`-c`
	compile only (no bind or link)

	* :switch:`-S`
	generate assembler listing

	* :switch:`-fomit-frame-pointer`
	do not set up separate stack frames

	* :switch:`-gnatp`
	do not add runtime checks

	This gives a human-readable assembler version of the code. The resulting
	file will have the same name as the Ada source file, but with a ``.s``
	extension. In our example, the file :file:`nothing.s` has the following
	contents:

	::

	.file "nothing.adb"
	gcc2_compiled.:
	___gnu_compiled_ada:
	.text
	.align 4
	.globl __ada_nothing
	__ada_nothing:
	#APP
	nop
	#NO_APP
	jmp L1
	.align 2,0x90
	L1:
	ret

	The assembly code you included is clearly indicated by
	the compiler, between the ``#APP`` and ``#NO_APP``
	delimiters. The character before the 'APP' and 'NOAPP'
	can differ on different targets. For example, GNU/Linux uses '#APP' while
	on NT you will see '/APP'.

	If you make a mistake in your assembler code (such as using the
	wrong size modifier, or using a wrong operand for the instruction) GNAT
	will report this error in a temporary file, which will be deleted when
	the compilation is finished. Generating an assembler file will help
	in such cases, since you can assemble this file separately using the
	``as`` assembler that comes with gcc.

	Assembling the file using the command

	::

	$ as nothing.s

	will give you error messages whose lines correspond to the assembler
	input file, so you can easily find and correct any mistakes you made.
	If there are no errors, ``as`` will generate an object file
	:file:`nothing.out`.


	.. _Output_Variables_in_Inline_Assembler:

	Output Variables in Inline Assembler
	====================================

	The examples in this section, showing how to access the processor flags,
	illustrate how to specify the destination operands for assembly language
	statements.


	.. code-block:: ada

	with Interfaces; use Interfaces;
	with Ada.Text_IO; use Ada.Text_IO;
	with System.Machine_Code; use System.Machine_Code;
	procedure Get_Flags is
	Flags : Unsigned_32;
	use ASCII;
	begin
	Asm ("pushfl" & LF & HT & -- push flags on stack
	"popl %%eax" & LF & HT & -- load eax with flags
	"movl %%eax, %0", -- store flags in variable
	Outputs => Unsigned_32'Asm_Output ("=g", Flags));
	Put_Line ("Flags register:" & Flags'Img);
	end Get_Flags;

	In order to have a nicely aligned assembly listing, we have separated
	multiple assembler statements in the Asm template string with linefeed
	(ASCII.LF) and horizontal tab (ASCII.HT) characters.
	The resulting section of the assembly output file is:

	::

	#APP
	pushfl
	popl %eax
	movl %eax, -40(%ebp)
	#NO_APP

	It would have been legal to write the Asm invocation as:

	.. code-block:: ada

	Asm ("pushfl popl %%eax movl %%eax, %0")

	but in the generated assembler file, this would come out as:

	::

	#APP
	pushfl popl %eax movl %eax, -40(%ebp)
	#NO_APP

	which is not so convenient for the human reader.

	We use Ada comments
	at the end of each line to explain what the assembler instructions
	actually do. This is a useful convention.

	When writing Inline Assembler instructions, you need to precede each register
	and variable name with a percent sign. Since the assembler already requires
	a percent sign at the beginning of a register name, you need two consecutive
	percent signs for such names in the Asm template string, thus ``%%eax``.
	In the generated assembly code, one of the percent signs will be stripped off.

	Names such as ``%0``, ``%1``, ``%2``, etc., denote input or output
	variables: operands you later define using ``Input`` or ``Output``
	parameters to ``Asm``.
	An output variable is illustrated in
	the third statement in the Asm template string:

	::

	movl %%eax, %0

	The intent is to store the contents of the eax register in a variable that can
	be accessed in Ada. Simply writing ``movl %%eax, Flags`` would not
	necessarily work, since the compiler might optimize by using a register
	to hold Flags, and the expansion of the ``movl`` instruction would not be
	aware of this optimization. The solution is not to store the result directly
	but rather to advise the compiler to choose the correct operand form;
	that is the purpose of the ``%0`` output variable.

	Information about the output variable is supplied in the ``Outputs``
	parameter to ``Asm``:

	.. code-block:: ada

	Outputs => Unsigned_32'Asm_Output ("=g", Flags));

	The output is defined by the ``Asm_Output`` attribute of the target type;
	the general format is

	.. code-block:: ada

	Type'Asm_Output (constraint_string, variable_name)

	The constraint string directs the compiler how
	to store/access the associated variable. In the example

	.. code-block:: ada

	Unsigned_32'Asm_Output ("=m", Flags);

	the ``"m"`` (memory) constraint tells the compiler that the variable
	``Flags`` should be stored in a memory variable, thus preventing
	the optimizer from keeping it in a register. In contrast,

	.. code-block:: ada

	Unsigned_32'Asm_Output ("=r", Flags);

	uses the ``"r"`` (register) constraint, telling the compiler to
	store the variable in a register.

	If the constraint is preceded by the equal character '=', it tells
	the compiler that the variable will be used to store data into it.

	In the ``Get_Flags`` example, we used the ``"g"`` (global) constraint,
	allowing the optimizer to choose whatever it deems best.

	There are a fairly large number of constraints, but the ones that are
	most useful (for the Intel x86 processor) are the following:

	====== ==========================================
	= output constraint
	g global (i.e., can be stored anywhere)
	m in memory
	I a constant
	a use eax
	b use ebx
	c use ecx
	d use edx
	S use esi
	D use edi
	r use one of eax, ebx, ecx or edx
	q use one of eax, ebx, ecx, edx, esi or edi
	====== ==========================================

	The full set of constraints is described in the gcc and ``as``
	documentation; note that it is possible to combine certain constraints
	in one constraint string.

	You specify the association of an output variable with an assembler operand
	through the :samp:`%{n}` notation, where n is a non-negative
	integer. Thus in

	.. code-block:: ada

	Asm ("pushfl" & LF & HT & -- push flags on stack
	"popl %%eax" & LF & HT & -- load eax with flags
	"movl %%eax, %0", -- store flags in variable
	Outputs => Unsigned_32'Asm_Output ("=g", Flags));


	``%0`` will be replaced in the expanded code by the appropriate operand,
	whatever
	the compiler decided for the ``Flags`` variable.

	In general, you may have any number of output variables:

	* Count the operands starting at 0; thus ``%0``, ``%1``, etc.

	* Specify the ``Outputs`` parameter as a parenthesized comma-separated list
	of ``Asm_Output`` attributes

	For example:

	.. code-block:: ada

	Asm ("movl %%eax, %0" & LF & HT &
	"movl %%ebx, %1" & LF & HT &
	"movl %%ecx, %2",
	Outputs => (Unsigned_32'Asm_Output ("=g", Var_A), -- %0 = Var_A
	Unsigned_32'Asm_Output ("=g", Var_B), -- %1 = Var_B
	Unsigned_32'Asm_Output ("=g", Var_C))); -- %2 = Var_C

	where ``Var_A``, ``Var_B``, and ``Var_C`` are variables
	in the Ada program.

	As a variation on the ``Get_Flags`` example, we can use the constraints
	string to direct the compiler to store the eax register into the ``Flags``
	variable, instead of including the store instruction explicitly in the
	``Asm`` template string:

	.. code-block:: ada

	with Interfaces; use Interfaces;
	with Ada.Text_IO; use Ada.Text_IO;
	with System.Machine_Code; use System.Machine_Code;
	procedure Get_Flags_2 is
	Flags : Unsigned_32;
	use ASCII;
	begin
	Asm ("pushfl" & LF & HT & -- push flags on stack
	"popl %%eax", -- save flags in eax
	Outputs => Unsigned_32'Asm_Output ("=a", Flags));
	Put_Line ("Flags register:" & Flags'Img);
	end Get_Flags_2;

	The ``"a"`` constraint tells the compiler that the ``Flags``
	variable will come from the eax register. Here is the resulting code:

	::

	#APP
	pushfl
	popl %eax
	#NO_APP
	movl %eax,-40(%ebp)

	The compiler generated the store of eax into Flags after
	expanding the assembler code.

	Actually, there was no need to pop the flags into the eax register;
	more simply, we could just pop the flags directly into the program variable:

	.. code-block:: ada

	with Interfaces; use Interfaces;
	with Ada.Text_IO; use Ada.Text_IO;
	with System.Machine_Code; use System.Machine_Code;
	procedure Get_Flags_3 is
	Flags : Unsigned_32;
	use ASCII;
	begin
	Asm ("pushfl" & LF & HT & -- push flags on stack
	"pop %0", -- save flags in Flags
	Outputs => Unsigned_32'Asm_Output ("=g", Flags));
	Put_Line ("Flags register:" & Flags'Img);
	end Get_Flags_3;


	.. _Input_Variables_in_Inline_Assembler:

	Input Variables in Inline Assembler
	===================================

	The example in this section illustrates how to specify the source operands
	for assembly language statements.
	The program simply increments its input value by 1:

	.. code-block:: ada

	with Interfaces; use Interfaces;
	with Ada.Text_IO; use Ada.Text_IO;
	with System.Machine_Code; use System.Machine_Code;
	procedure Increment is

	function Incr (Value : Unsigned_32) return Unsigned_32 is
	Result : Unsigned_32;
	begin
	Asm ("incl %0",
	Outputs => Unsigned_32'Asm_Output ("=a", Result),
	Inputs => Unsigned_32'Asm_Input ("a", Value));
	return Result;
	end Incr;

	Value : Unsigned_32;

	begin
	Value := 5;
	Put_Line ("Value before is" & Value'Img);
	Value := Incr (Value);
	Put_Line ("Value after is" & Value'Img);
	end Increment;

	The ``Outputs`` parameter to ``Asm`` specifies
	that the result will be in the eax register and that it is to be stored
	in the ``Result`` variable.

	The ``Inputs`` parameter looks much like the ``Outputs`` parameter,
	but with an ``Asm_Input`` attribute.
	The ``"="`` constraint, indicating an output value, is not present.

	You can have multiple input variables, in the same way that you can have more
	than one output variable.

	The parameter count (%0, %1) etc, still starts at the first output statement,
	and continues with the input statements.

	Just as the ``Outputs`` parameter causes the register to be stored into the
	target variable after execution of the assembler statements, so does the
	``Inputs`` parameter cause its variable to be loaded into the register
	before execution of the assembler statements.

	Thus the effect of the ``Asm`` invocation is:

	* load the 32-bit value of ``Value`` into eax
	* execute the ``incl %eax`` instruction
	* store the contents of eax into the ``Result`` variable

	The resulting assembler file (with :switch:`-O2` optimization) contains:

	::

	_increment__incr.1:
	subl $4,%esp
	movl 8(%esp),%eax
	#APP
	incl %eax
	#NO_APP
	movl %eax,%edx
	movl %ecx,(%esp)
	addl $4,%esp
	ret


	.. _Inlining_Inline_Assembler_Code:

	Inlining Inline Assembler Code
	==============================

	For a short subprogram such as the ``Incr`` function in the previous
	section, the overhead of the call and return (creating / deleting the stack
	frame) can be significant, compared to the amount of code in the subprogram
	body. A solution is to apply Ada's ``Inline`` pragma to the subprogram,
	which directs the compiler to expand invocations of the subprogram at the
	point(s) of call, instead of setting up a stack frame for out-of-line calls.
	Here is the resulting program:

	.. code-block:: ada

	with Interfaces; use Interfaces;
	with Ada.Text_IO; use Ada.Text_IO;
	with System.Machine_Code; use System.Machine_Code;
	procedure Increment_2 is

	function Incr (Value : Unsigned_32) return Unsigned_32 is
	Result : Unsigned_32;
	begin
	Asm ("incl %0",
	Outputs => Unsigned_32'Asm_Output ("=a", Result),
	Inputs => Unsigned_32'Asm_Input ("a", Value));
	return Result;
	end Incr;
	pragma Inline (Increment);

	Value : Unsigned_32;

	begin
	Value := 5;
	Put_Line ("Value before is" & Value'Img);
	Value := Increment (Value);
	Put_Line ("Value after is" & Value'Img);
	end Increment_2;

	Compile the program with both optimization (:switch:`-O2`) and inlining
	(:switch:`-gnatn`) enabled.

	The ``Incr`` function is still compiled as usual, but at the
	point in ``Increment`` where our function used to be called:


	::

	pushl %edi
	call _increment__incr.1

	the code for the function body directly appears:


	::

	movl %esi,%eax
	#APP
	incl %eax
	#NO_APP
	movl %eax,%edx

	thus saving the overhead of stack frame setup and an out-of-line call.


	.. _Other_Asm_Functionality:

	Other ``Asm`` Functionality
	===========================

	This section describes two important parameters to the ``Asm``
	procedure: ``Clobber``, which identifies register usage;
	and ``Volatile``, which inhibits unwanted optimizations.

	.. _The_Clobber_Parameter:

	The ``Clobber`` Parameter
	-------------------------

	One of the dangers of intermixing assembly language and a compiled language
	such as Ada is that the compiler needs to be aware of which registers are
	being used by the assembly code. In some cases, such as the earlier examples,
	the constraint string is sufficient to indicate register usage (e.g.,
	``"a"`` for
	the eax register). But more generally, the compiler needs an explicit
	identification of the registers that are used by the Inline Assembly
	statements.

	Using a register that the compiler doesn't know about
	could be a side effect of an instruction (like ``mull``
	storing its result in both eax and edx).
	It can also arise from explicit register usage in your
	assembly code; for example:

	.. code-block:: ada

	Asm ("movl %0, %%ebx" & LF & HT &
	"movl %%ebx, %1",
	Outputs => Unsigned_32'Asm_Output ("=g", Var_Out),
	Inputs => Unsigned_32'Asm_Input ("g", Var_In));

	where the compiler (since it does not analyze the ``Asm`` template string)
	does not know you are using the ebx register.

	In such cases you need to supply the ``Clobber`` parameter to ``Asm``,
	to identify the registers that will be used by your assembly code:


	.. code-block:: ada

	Asm ("movl %0, %%ebx" & LF & HT &
	"movl %%ebx, %1",
	Outputs => Unsigned_32'Asm_Output ("=g", Var_Out),
	Inputs => Unsigned_32'Asm_Input ("g", Var_In),
	Clobber => "ebx");

	The Clobber parameter is a static string expression specifying the
	register(s) you are using. Note that register names are not prefixed
	by a percent sign. Also, if more than one register is used then their names
	are separated by commas; e.g., ``"eax, ebx"``

	The ``Clobber`` parameter has several additional uses:

	* Use 'register' name ``cc`` to indicate that flags might have changed
	* Use 'register' name ``memory`` if you changed a memory location


	.. _The_Volatile_Parameter:

	The ``Volatile`` Parameter
	--------------------------

	.. index:: Volatile parameter

	Compiler optimizations in the presence of Inline Assembler may sometimes have
	unwanted effects. For example, when an ``Asm`` invocation with an input
	variable is inside a loop, the compiler might move the loading of the input
	variable outside the loop, regarding it as a one-time initialization.

	If this effect is not desired, you can disable such optimizations by setting
	the ``Volatile`` parameter to ``True``; for example:

	.. code-block:: ada

	Asm ("movl %0, %%ebx" & LF & HT &
	"movl %%ebx, %1",
	Outputs => Unsigned_32'Asm_Output ("=g", Var_Out),
	Inputs => Unsigned_32'Asm_Input ("g", Var_In),
	Clobber => "ebx",
	Volatile => True);

	By default, ``Volatile`` is set to ``False`` unless there is no
	``Outputs`` parameter.

	Although setting ``Volatile`` to ``True`` prevents unwanted
	optimizations, it will also disable other optimizations that might be
	important for efficiency. In general, you should set ``Volatile``
	to ``True`` only if the compiler's optimizations have created
	problems.