gcc/jit/docs/intro/tutorial05.rst - gcc - Git at Google

 .. Copyright (C) 2015-2021 Free Software Foundation, Inc.
    Originally contributed by David Malcolm <dmalcolm@redhat.com>

    This is free software: you can redistribute it and/or modify it
    under the terms of the GNU General Public License as published by
    the Free Software Foundation, either version 3 of the License, or
    (at your option) any later version.

    This program is distributed in the hope that it will be useful, but
    WITHOUT ANY WARRANTY; without even the implied warranty of
    MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE.  See the GNU
    General Public License for more details.

    You should have received a copy of the GNU General Public License
    along with this program.  If not, see
    <http://www.gnu.org/licenses/>.

 Tutorial part 5: Implementing an Ahead-of-Time compiler
 -------------------------------------------------------

 If you have a pre-existing language frontend that's compatible with
 libgccjit's license, it's possible to hook it up to libgccjit as a
 backend.  In the previous example we showed
 how to do that for in-memory JIT-compilation, but libgccjit can also
 compile code directly to a file, allowing you to implement a more
 traditional ahead-of-time compiler ("JIT" is something of a misnomer
 for this use-case).

 The essential difference is to compile the context using
 :c:func:`gcc_jit_context_compile_to_file` rather than
 :c:func:`gcc_jit_context_compile`.

 The "brainf" language
 *********************

 In this example we use libgccjit to construct an ahead-of-time compiler
 for an esoteric programming language that we shall refer to as "brainf".

 brainf scripts operate on an array of bytes, with a notional data pointer
 within the array.

 brainf is hard for humans to read, but it's trivial to write a parser for
 it, as there is no lexing; just a stream of bytes.  The operations are:

 ====================== =============================
 Character              Meaning
 ====================== =============================
 ``>``                  ``idx += 1``
 ``<``                  ``idx -= 1``
 ``+``                  ``data[idx] += 1``
 ``-``                  ``data[idx] -= 1``
 ``.``                  ``output (data[idx])``
 ``,``                  ``data[idx] = input ()``
 ``[``                  loop until ``data[idx] == 0``
 ``]``                  end of loop
 Anything else          ignored
 ====================== =============================

 Unlike the previous example, we'll implement an ahead-of-time compiler,
 which reads ``.bf`` scripts and outputs executables (though it would
 be trivial to have it run them JIT-compiled in-process).

 Here's what a simple ``.bf`` script looks like:

    .. literalinclude:: ../examples/emit-alphabet.bf
     :lines: 1-

 .. note::

    This example makes use of whitespace and comments for legibility, but
    could have been written as::

      ++++++++++++++++++++++++++
      >+++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++<
      [>.+<-]

    It's not a particularly useful language, except for providing
    compiler-writers with a test case that's easy to parse.  The point
    is that you can use :c:func:`gcc_jit_context_compile_to_file`
    to use libgccjit as a backend for a pre-existing language frontend
    (provided that the pre-existing frontend is compatible with libgccjit's
    license).

 Converting a brainf script to libgccjit IR
 ******************************************

 As before we write simple code to populate a :c:type:`gcc_jit_context *`.

    .. literalinclude:: ../examples/tut05-bf.c
     :start-after: #define MAX_OPEN_PARENS 16
     :end-before: /* Entrypoint to the compiler.  */
     :language: c

 Compiling a context to a file
 *****************************

 Unlike the previous tutorial, this time we'll compile the context
 directly to an executable, using :c:func:`gcc_jit_context_compile_to_file`:

 .. code-block:: c

     gcc_jit_context_compile_to_file (ctxt,
                                      GCC_JIT_OUTPUT_KIND_EXECUTABLE,
                                      output_file);

 Here's the top-level of the compiler, which is what actually calls into
 :c:func:`gcc_jit_context_compile_to_file`:

  .. literalinclude:: ../examples/tut05-bf.c
     :start-after: /* Entrypoint to the compiler.  */
     :end-before: /* Use the built compiler to compile the example to an executable:
     :language: c

 Note how once the context is populated you could trivially instead compile
 it to memory using :c:func:`gcc_jit_context_compile` and run it in-process
 as in the previous tutorial.

 To create an executable, we need to export a ``main`` function.  Here's
 how to create one from the JIT API:

  .. literalinclude:: ../examples/tut05-bf.c
     :start-after: #include "libgccjit.h"
     :end-before: #define MAX_OPEN_PARENS 16
     :language: c

 .. note::

    The above implementation ignores ``argc`` and ``argv``, but you could
    make use of them by exposing ``param_argc`` and ``param_argv`` to the
    caller.

 Upon compiling this C code, we obtain a bf-to-machine-code compiler;
 let's call it ``bfc``:

 .. code-block:: console

   $ gcc \
       tut05-bf.c \
       -o bfc \
       -lgccjit

 We can now use ``bfc`` to compile .bf files into machine code executables:

 .. code-block:: console

   $ ./bfc \
        emit-alphabet.bf \
        a.out

 which we can run directly:

 .. code-block:: console

   $ ./a.out
   ABCDEFGHIJKLMNOPQRSTUVWXYZ

 Success!

 We can also inspect the generated executable using standard tools:

 .. code-block:: console

   $ objdump -d a.out |less

 which shows that libgccjit has managed to optimize the function
 somewhat (for example, the runs of 26 and 65 increment operations
 have become integer constants 0x1a and 0x41):

 .. code-block:: console

   0000000000400620 <main>:
     400620:     80 3d 39 0a 20 00 00    cmpb   $0x0,0x200a39(%rip)        # 601060 <data
     400627:     74 07                   je     400630 <main
     400629:     eb fe                   jmp    400629 <main+0x9>
     40062b:     0f 1f 44 00 00          nopl   0x0(%rax,%rax,1)
     400630:     48 83 ec 08             sub    $0x8,%rsp
     400634:     0f b6 05 26 0a 20 00    movzbl 0x200a26(%rip),%eax        # 601061 <data_cells+0x1>
     40063b:     c6 05 1e 0a 20 00 1a    movb   $0x1a,0x200a1e(%rip)       # 601060 <data_cells>
     400642:     8d 78 41                lea    0x41(%rax),%edi
     400645:     40 88 3d 15 0a 20 00    mov    %dil,0x200a15(%rip)        # 601061 <data_cells+0x1>
     40064c:     0f 1f 40 00             nopl   0x0(%rax)
     400650:     40 0f b6 ff             movzbl %dil,%edi
     400654:     e8 87 fe ff ff          callq  4004e0 <putchar@plt>
     400659:     0f b6 05 01 0a 20 00    movzbl 0x200a01(%rip),%eax        # 601061 <data_cells+0x1>
     400660:     80 2d f9 09 20 00 01    subb   $0x1,0x2009f9(%rip)        # 601060 <data_cells>
     400667:     8d 78 01                lea    0x1(%rax),%edi
     40066a:     40 88 3d f0 09 20 00    mov    %dil,0x2009f0(%rip)        # 601061 <data_cells+0x1>
     400671:     75 dd                   jne    400650 <main+0x30>
     400673:     31 c0                   xor    %eax,%eax
     400675:     48 83 c4 08             add    $0x8,%rsp
     400679:     c3                      retq
     40067a:     66 0f 1f 44 00 00       nopw   0x0(%rax,%rax,1)

 We also set up debugging information (via
 :c:func:`gcc_jit_context_new_location` and
 :c:macro:`GCC_JIT_BOOL_OPTION_DEBUGINFO`), so it's possible to use ``gdb``
 to singlestep through the generated binary and inspect the internal
 state ``idx`` and ``data_cells``:

 .. code-block:: console

   (gdb) break main
   Breakpoint 1 at 0x400790
   (gdb) run
   Starting program: a.out

   Breakpoint 1, 0x0000000000400790 in main (argc=1, argv=0x7fffffffe448)
   (gdb) stepi
   0x0000000000400797 in main (argc=1, argv=0x7fffffffe448)
   (gdb) stepi
   0x00000000004007a0 in main (argc=1, argv=0x7fffffffe448)
   (gdb) stepi
   9     >+++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++<
   (gdb) list
   4
   5     cell 0 = 26
   6     ++++++++++++++++++++++++++
   7
   8     cell 1 = 65
   9     >+++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++<
   10
   11    while cell#0 != 0
   12    [
   13     >
   (gdb) n
   6     ++++++++++++++++++++++++++
   (gdb) n
   9     >+++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++<
   (gdb) p idx
   $1 = 1
   (gdb) p data_cells
   $2 = "\032", '\000' <repeats 29998 times>
   (gdb) p data_cells[0]
   $3 = 26 '\032'
   (gdb) p data_cells[1]
   $4 = 0 '\000'
   (gdb) list
   4
   5     cell 0 = 26
   6     ++++++++++++++++++++++++++
   7
   8     cell 1 = 65
   9     >+++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++<
   10
   11    while cell#0 != 0
   12    [
   13     >


 Other forms of ahead-of-time-compilation
 ****************************************

 The above demonstrates compiling a :c:type:`gcc_jit_context *` directly
 to an executable.  It's also possible to compile it to an object file,
 and to a dynamic library.  See the documentation of
 :c:func:`gcc_jit_context_compile_to_file` for more information.
	.. Copyright (C) 2015-2021 Free Software Foundation, Inc.
	Originally contributed by David Malcolm <dmalcolm@redhat.com>

	This is free software: you can redistribute it and/or modify it
	under the terms of the GNU General Public License as published by
	the Free Software Foundation, either version 3 of the License, or
	(at your option) any later version.

	This program is distributed in the hope that it will be useful, but
	WITHOUT ANY WARRANTY; without even the implied warranty of
	MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU
	General Public License for more details.

	You should have received a copy of the GNU General Public License
	along with this program. If not, see
	<http://www.gnu.org/licenses/>.

	Tutorial part 5: Implementing an Ahead-of-Time compiler
	-------------------------------------------------------

	If you have a pre-existing language frontend that's compatible with
	libgccjit's license, it's possible to hook it up to libgccjit as a
	backend. In the previous example we showed
	how to do that for in-memory JIT-compilation, but libgccjit can also
	compile code directly to a file, allowing you to implement a more
	traditional ahead-of-time compiler ("JIT" is something of a misnomer
	for this use-case).

	The essential difference is to compile the context using
	:c:func:`gcc_jit_context_compile_to_file` rather than
	:c:func:`gcc_jit_context_compile`.

	The "brainf" language
	*********************

	In this example we use libgccjit to construct an ahead-of-time compiler
	for an esoteric programming language that we shall refer to as "brainf".

	brainf scripts operate on an array of bytes, with a notional data pointer
	within the array.

	brainf is hard for humans to read, but it's trivial to write a parser for
	it, as there is no lexing; just a stream of bytes. The operations are:

	====================== =============================
	Character Meaning
	====================== =============================
	``>`` ``idx += 1``
	``<`` ``idx -= 1``
	``+`` ``data[idx] += 1``
	``-`` ``data[idx] -= 1``
	``.`` ``output (data[idx])``
	``,`` ``data[idx] = input ()``
	``[`` loop until ``data[idx] == 0``
	``]`` end of loop
	Anything else ignored
	====================== =============================

	Unlike the previous example, we'll implement an ahead-of-time compiler,
	which reads ``.bf`` scripts and outputs executables (though it would
	be trivial to have it run them JIT-compiled in-process).

	Here's what a simple ``.bf`` script looks like:

	.. literalinclude:: ../examples/emit-alphabet.bf
	:lines: 1-

	.. note::

	This example makes use of whitespace and comments for legibility, but
	could have been written as::

	++++++++++++++++++++++++++
	>+++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++<
	[>.+<-]

	It's not a particularly useful language, except for providing
	compiler-writers with a test case that's easy to parse. The point
	is that you can use :c:func:`gcc_jit_context_compile_to_file`
	to use libgccjit as a backend for a pre-existing language frontend
	(provided that the pre-existing frontend is compatible with libgccjit's
	license).

	Converting a brainf script to libgccjit IR
	******************************************

	As before we write simple code to populate a :c:type:`gcc_jit_context *`.

	.. literalinclude:: ../examples/tut05-bf.c
	:start-after: #define MAX_OPEN_PARENS 16
	:end-before: /* Entrypoint to the compiler. */
	:language: c

	Compiling a context to a file
	*****************************

	Unlike the previous tutorial, this time we'll compile the context
	directly to an executable, using :c:func:`gcc_jit_context_compile_to_file`:

	.. code-block:: c

	gcc_jit_context_compile_to_file (ctxt,
	GCC_JIT_OUTPUT_KIND_EXECUTABLE,
	output_file);

	Here's the top-level of the compiler, which is what actually calls into
	:c:func:`gcc_jit_context_compile_to_file`:

	.. literalinclude:: ../examples/tut05-bf.c
	:start-after: /* Entrypoint to the compiler. */
	:end-before: /* Use the built compiler to compile the example to an executable:
	:language: c

	Note how once the context is populated you could trivially instead compile
	it to memory using :c:func:`gcc_jit_context_compile` and run it in-process
	as in the previous tutorial.

	To create an executable, we need to export a ``main`` function. Here's
	how to create one from the JIT API:

	.. literalinclude:: ../examples/tut05-bf.c
	:start-after: #include "libgccjit.h"
	:end-before: #define MAX_OPEN_PARENS 16
	:language: c

	.. note::

	The above implementation ignores ``argc`` and ``argv``, but you could
	make use of them by exposing ``param_argc`` and ``param_argv`` to the
	caller.

	Upon compiling this C code, we obtain a bf-to-machine-code compiler;
	let's call it ``bfc``:

	.. code-block:: console

	$ gcc \
	tut05-bf.c \
	-o bfc \
	-lgccjit

	We can now use ``bfc`` to compile .bf files into machine code executables:

	.. code-block:: console

	$ ./bfc \
	emit-alphabet.bf \
	a.out

	which we can run directly:

	.. code-block:: console

	$ ./a.out
	ABCDEFGHIJKLMNOPQRSTUVWXYZ

	Success!

	We can also inspect the generated executable using standard tools:

	.. code-block:: console

	$ objdump -d a.out \|less

	which shows that libgccjit has managed to optimize the function
	somewhat (for example, the runs of 26 and 65 increment operations
	have become integer constants 0x1a and 0x41):

	.. code-block:: console

	0000000000400620 <main>:
	400620: 80 3d 39 0a 20 00 00 cmpb $0x0,0x200a39(%rip) # 601060 <data
	400627: 74 07 je 400630 <main
	400629: eb fe jmp 400629 <main+0x9>
	40062b: 0f 1f 44 00 00 nopl 0x0(%rax,%rax,1)
	400630: 48 83 ec 08 sub $0x8,%rsp
	400634: 0f b6 05 26 0a 20 00 movzbl 0x200a26(%rip),%eax # 601061 <data_cells+0x1>
	40063b: c6 05 1e 0a 20 00 1a movb $0x1a,0x200a1e(%rip) # 601060 <data_cells>
	400642: 8d 78 41 lea 0x41(%rax),%edi
	400645: 40 88 3d 15 0a 20 00 mov %dil,0x200a15(%rip) # 601061 <data_cells+0x1>
	40064c: 0f 1f 40 00 nopl 0x0(%rax)
	400650: 40 0f b6 ff movzbl %dil,%edi
	400654: e8 87 fe ff ff callq 4004e0 <putchar@plt>
	400659: 0f b6 05 01 0a 20 00 movzbl 0x200a01(%rip),%eax # 601061 <data_cells+0x1>
	400660: 80 2d f9 09 20 00 01 subb $0x1,0x2009f9(%rip) # 601060 <data_cells>
	400667: 8d 78 01 lea 0x1(%rax),%edi
	40066a: 40 88 3d f0 09 20 00 mov %dil,0x2009f0(%rip) # 601061 <data_cells+0x1>
	400671: 75 dd jne 400650 <main+0x30>
	400673: 31 c0 xor %eax,%eax
	400675: 48 83 c4 08 add $0x8,%rsp
	400679: c3 retq
	40067a: 66 0f 1f 44 00 00 nopw 0x0(%rax,%rax,1)

	We also set up debugging information (via
	:c:func:`gcc_jit_context_new_location` and
	:c:macro:`GCC_JIT_BOOL_OPTION_DEBUGINFO`), so it's possible to use ``gdb``
	to singlestep through the generated binary and inspect the internal
	state ``idx`` and ``data_cells``:

	.. code-block:: console

	(gdb) break main
	Breakpoint 1 at 0x400790
	(gdb) run
	Starting program: a.out

	Breakpoint 1, 0x0000000000400790 in main (argc=1, argv=0x7fffffffe448)
	(gdb) stepi
	0x0000000000400797 in main (argc=1, argv=0x7fffffffe448)
	(gdb) stepi
	0x00000000004007a0 in main (argc=1, argv=0x7fffffffe448)
	(gdb) stepi
	9 >+++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++<
	(gdb) list
	4
	5 cell 0 = 26
	6 ++++++++++++++++++++++++++
	7
	8 cell 1 = 65
	9 >+++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++<
	10
	11 while cell#0 != 0
	12 [
	13 >
	(gdb) n
	6 ++++++++++++++++++++++++++
	(gdb) n
	9 >+++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++<
	(gdb) p idx
	$1 = 1
	(gdb) p data_cells
	$2 = "\032", '\000' <repeats 29998 times>
	(gdb) p data_cells[0]
	$3 = 26 '\032'
	(gdb) p data_cells[1]
	$4 = 0 '\000'
	(gdb) list
	4
	5 cell 0 = 26
	6 ++++++++++++++++++++++++++
	7
	8 cell 1 = 65
	9 >+++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++<
	10
	11 while cell#0 != 0
	12 [
	13 >


	Other forms of ahead-of-time-compilation
	****************************************

	The above demonstrates compiling a :c:type:`gcc_jit_context *` directly
	to an executable. It's also possible to compile it to an object file,
	and to a dynamic library. See the documentation of
	:c:func:`gcc_jit_context_compile_to_file` for more information.