poky/documentation/sdk-manual/sdk-working-projects.xml - mdmillerii/openbmc - Gitiles

 <!DOCTYPE chapter PUBLIC "-//OASIS//DTD DocBook XML V4.2//EN"
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 [<!ENTITY % poky SYSTEM "../poky.ent"> %poky; ] >

 <chapter id='sdk-working-projects'>

     <title>Using the SDK Toolchain Directly</title>

     <para>
         You can use the SDK toolchain directly with Makefile and
         Autotools-based projects.
     </para>

     <section id='autotools-based-projects'>
         <title>Autotools-Based Projects</title>

         <para>
             Once you have a suitable
             <ulink url='&YOCTO_DOCS_REF_URL;#cross-development-toolchain'>cross-development toolchain</ulink>
             installed, it is very easy to develop a project using the
             <ulink url='https://en.wikipedia.org/wiki/GNU_Build_System'>GNU Autotools-based</ulink>
             workflow, which is outside of the
             <ulink url='&YOCTO_DOCS_REF_URL;#build-system-term'>OpenEmbedded build system</ulink>.
         </para>

         <para>
             The following figure presents a simple Autotools workflow.
             <imagedata fileref="figures/sdk-autotools-flow.png" width="7in" height="8in" align="center" />
         </para>

         <para>
             Follow these steps to create a simple Autotools-based
             "Hello World" project:
             <note>
                 For more information on the GNU Autotools workflow,
                 see the same example on the
                 <ulink url='https://developer.gnome.org/anjuta-build-tutorial/stable/create-autotools.html.en'>GNOME Developer</ulink>
                 site.
             </note>
             <orderedlist>
                 <listitem><para>
                     <emphasis>Create a Working Directory and Populate It:</emphasis>
                     Create a clean directory for your project and then make
                     that directory your working location.
                     <literallayout class='monospaced'>
      $ mkdir $HOME/helloworld
      $ cd $HOME/helloworld
                     </literallayout>
                     After setting up the directory, populate it with files
                     needed for the flow.
                     You need a project source file, a file to help with
                     configuration, and a file to help create the Makefile,
                     and a README file:
                     <filename>hello.c</filename>,
                     <filename>configure.ac</filename>,
                     <filename>Makefile.am</filename>, and
                     <filename>README</filename>, respectively.</para>

                     <para> Use the following command to create an empty README
                     file, which is required by GNU Coding Standards:
                     <literallayout class='monospaced'>
      $ touch README
                     </literallayout>
                     Create the remaining three files as follows:
                     <itemizedlist>
                         <listitem><para>
                             <emphasis><filename>hello.c</filename>:</emphasis>
                             <literallayout class='monospaced'>
      #include &lt;stdio.h&gt;

      main()
         {
            printf("Hello World!\n");
         }
                             </literallayout>
                             </para></listitem>
                         <listitem><para>
                             <emphasis><filename>configure.ac</filename>:</emphasis>
                             <literallayout class='monospaced'>
      AC_INIT(hello,0.1)
      AM_INIT_AUTOMAKE([foreign])
      AC_PROG_CC
      AC_CONFIG_FILES(Makefile)
      AC_OUTPUT
                             </literallayout>
                             </para></listitem>
                         <listitem><para>
                             <emphasis><filename>Makefile.am</filename>:</emphasis>
                             <literallayout class='monospaced'>
      bin_PROGRAMS = hello
      hello_SOURCES = hello.c
                             </literallayout>
                             </para></listitem>
                     </itemizedlist>
                     </para></listitem>
                 <listitem><para>
                     <emphasis>Source the Cross-Toolchain
                     Environment Setup File:</emphasis>
                     As described earlier in the manual, installing the
                     cross-toolchain creates a cross-toolchain
                     environment setup script in the directory that the SDK
                     was installed.
                     Before you can use the tools to develop your project,
                     you must source this setup script.
                     The script begins with the string "environment-setup"
                     and contains the machine architecture, which is
                     followed by the string "poky-linux".
                     For this example, the command sources a script from the
                     default SDK installation directory that uses the
                     32-bit Intel x86 Architecture and the
                     &DISTRO_NAME; Yocto Project release:
                     <literallayout class='monospaced'>
      $ source /opt/poky/&DISTRO;/environment-setup-i586-poky-linux
                     </literallayout>
                     </para></listitem>
                 <listitem><para>
                     <emphasis>Create the <filename>configure</filename> Script:</emphasis>
                     Use the <filename>autoreconf</filename> command to
                     generate the <filename>configure</filename> script.
                     <literallayout class='monospaced'>
      $ autoreconf
                     </literallayout>
                     The <filename>autoreconf</filename> tool takes care
                     of running the other Autotools such as
                     <filename>aclocal</filename>,
                     <filename>autoconf</filename>, and
                     <filename>automake</filename>.
                     <note>
                         If you get errors from
                         <filename>configure.ac</filename>, which
                         <filename>autoreconf</filename> runs, that indicate
                         missing files, you can use the "-i" option, which
                         ensures missing auxiliary files are copied to the build
                         host.
                     </note>
                     </para></listitem>
                 <listitem><para>
                     <emphasis>Cross-Compile the Project:</emphasis>
                     This command compiles the project using the
                     cross-compiler.
                     The
                     <ulink url='&YOCTO_DOCS_REF_URL;#var-CONFIGURE_FLAGS'><filename>CONFIGURE_FLAGS</filename></ulink>
                     environment variable provides the minimal arguments for
                     GNU configure:
                     <literallayout class='monospaced'>
      $ ./configure ${CONFIGURE_FLAGS}
                     </literallayout>
                     For an Autotools-based project, you can use the
                     cross-toolchain by just passing the appropriate host
                     option to <filename>configure.sh</filename>.
                     The host option you use is derived from the name of the
                     environment setup script found in the directory in which
                     you installed the cross-toolchain.
                     For example, the host option for an ARM-based target that
                     uses the GNU EABI is
                     <filename>armv5te-poky-linux-gnueabi</filename>.
                     You will notice that the name of the script is
                     <filename>environment-setup-armv5te-poky-linux-gnueabi</filename>.
                     Thus, the following command works to update your project
                     and rebuild it using the appropriate cross-toolchain tools:
                     <literallayout class='monospaced'>
      $ ./configure --host=armv5te-poky-linux-gnueabi --with-libtool-sysroot=<replaceable>sysroot_dir</replaceable>
                     </literallayout>
                     </para></listitem>
                 <listitem><para>
                     <emphasis>Make and Install the Project:</emphasis>
                     These two commands generate and install the project
                     into the destination directory:
                     <literallayout class='monospaced'>
      $ make
      $ make install DESTDIR=./tmp
                     </literallayout>
                     <note>
                         To learn about environment variables established
                         when you run the cross-toolchain environment setup
                         script and how they are used or overridden when
                         the Makefile, see the
                         "<link linkend='makefile-based-projects'>Makefile-Based Projects</link>"
                         section.
                     </note>
                     This next command is a simple way to verify the
                     installation of your project.
                     Running the command prints the architecture on which
                     the binary file can run.
                     This architecture should be the same architecture that
                     the installed cross-toolchain supports.
                     <literallayout class='monospaced'>
      $ file ./tmp/usr/local/bin/hello
                     </literallayout>
                     </para></listitem>
                 <listitem><para>
                     <emphasis>Execute Your Project:</emphasis>
                     To execute the project, you would need to run it on your
                     target hardware.
                     If your target hardware happens to be your build host,
                     you could run the project as follows:
                     <literallayout class='monospaced'>
      $ ./tmp/usr/local/bin/hello
                     </literallayout>
                     As expected, the project displays the "Hello World!"
                     message.
                     </para></listitem>
             </orderedlist>
         </para>
     </section>

     <section id='makefile-based-projects'>
         <title>Makefile-Based Projects</title>

         <para>
             Simple Makefile-based projects use and interact with the
             cross-toolchain environment variables established when you run
             the cross-toolchain environment setup script.
             The environment variables are subject to general
             <filename>make</filename> rules.
         </para>

         <para>
             This section presents a simple Makefile development flow and
             provides an example that lets you see how you can use
             cross-toolchain environment variables and Makefile variables
             during development.
             <imagedata fileref="figures/sdk-makefile-flow.png" width="6in" height="7in" align="center" />
         </para>

         <para>
             The main point of this section is to explain the following three
             cases regarding variable behavior:
             <itemizedlist>
                 <listitem><para>
                     <emphasis>Case 1 - No Variables Set in the
                     <filename>Makefile</filename> Map to Equivalent
                     Environment Variables Set in the SDK Setup Script:</emphasis>
                     Because matching variables are not specifically set in the
                     <filename>Makefile</filename>, the variables retain their
                     values based on the environment setup script.
                     </para></listitem>
                 <listitem><para>
                     <emphasis>Case 2 - Variables Are Set in the Makefile that
                     Map to Equivalent Environment Variables from the SDK
                     Setup Script:</emphasis>
                     Specifically setting matching variables in the
                     <filename>Makefile</filename> during the build results in
                     the environment settings of the variables being
                     overwritten.
                     In this case, the variables you set in the
                     <filename>Makefile</filename> are used.
                     </para></listitem>
                 <listitem><para>
                     <emphasis>Case 3 - Variables Are Set Using the Command Line
                     that Map to Equivalent Environment Variables from the
                     SDK Setup Script:</emphasis>
                     Executing the <filename>Makefile</filename> from the
                     command line results in the environment variables being
                     overwritten.
                     In this case, the command-line content is used.
                     </para></listitem>
             </itemizedlist>
             <note>
                 Regardless of how you set your variables, if you use
                 the "-e" option with <filename>make</filename>, the
                 variables from the SDK setup script take precedence:
                 <literallayout class='monospaced'>
      $ make -e <replaceable>target</replaceable>
                 </literallayout>
             </note>
         </para>

         <para>
             The remainder of this section presents a simple Makefile example
             that demonstrates these variable behaviors.
         </para>

         <para>
             In a new shell environment variables are not established for the
             SDK until you run the setup script.
             For example, the following commands show a null value for the
             compiler variable (i.e.
             <ulink url='&YOCTO_DOCS_REF_URL;#var-CC'><filename>CC</filename></ulink>).
             <literallayout class='monospaced'>
      $ echo ${CC}

      $
             </literallayout>
             Running the SDK setup script for a 64-bit build host and an
             i586-tuned target architecture for a
             <filename>core-image-sato</filename> image using the current
             &DISTRO; Yocto Project release and then echoing that variable
             shows the value established through the script:
             <literallayout class='monospaced'>
      $ source /opt/poky/&DISTRO;/environment-setup-i586-poky-linux
      $ echo ${CC}
      i586-poky-linux-gcc -m32 -march=i586 --sysroot=/opt/poky/2.5/sysroots/i586-poky-linux
             </literallayout>
         </para>

         <para>
             To illustrate variable use, work through this simple "Hello World!"
             example:
             <orderedlist>
                 <listitem><para>
                     <emphasis>Create a Working Directory and Populate It:</emphasis>
                     Create a clean directory for your project and then make
                     that directory your working location.
                     <literallayout class='monospaced'>
      $ mkdir $HOME/helloworld
      $ cd $HOME/helloworld
                     </literallayout>
                     After setting up the directory, populate it with files
                     needed for the flow.
                     You need a <filename>main.c</filename> file from which you
                     call your function, a <filename>module.h</filename> file
                     to contain headers, and a <filename>module.c</filename>
                     that defines your function.
                     </para>

                     <para>Create the three files as follows:
                         <itemizedlist>
                             <listitem><para>
                                 <emphasis><filename>main.c</filename>:</emphasis>
                                 <literallayout class='monospaced'>
      #include "module.h"
      void sample_func();
      int main()
      {
      	sample_func();
      	return 0;
      }
                                 </literallayout>
                                 </para></listitem>
                             <listitem><para>
                                 <emphasis><filename>module.h</filename>:</emphasis>
                                 <literallayout class='monospaced'>
      #include &lt;stdio.h&gt;
      void sample_func();
                                 </literallayout>
                                 </para></listitem>
                             <listitem><para>
                                 <emphasis><filename>module.c</filename>:</emphasis>
                                 <literallayout class='monospaced'>
      #include "module.h"
      void sample_func()
      {
 	     printf("Hello World!");
 	     printf("\n");
      }
                                 </literallayout>
                                 </para></listitem>
                         </itemizedlist>
                     </para></listitem>
                 <listitem><para>
                     <emphasis>Source the Cross-Toolchain Environment Setup File:</emphasis>
                     As described earlier in the manual, installing the
                     cross-toolchain creates a cross-toolchain environment setup
                     script in the directory that the SDK was installed.
                     Before you can use the tools to develop your project,
                     you must source this setup script.
                     The script begins with the string "environment-setup"
                     and contains the machine architecture, which is
                     followed by the string "poky-linux".
                     For this example, the command sources a script from the
                     default SDK installation directory that uses the
                     32-bit Intel x86 Architecture and the
                     &DISTRO_NAME; Yocto Project release:
                     <literallayout class='monospaced'>
      $ source /opt/poky/&DISTRO;/environment-setup-i586-poky-linux
                     </literallayout>
                     </para></listitem>
                 <listitem><para>
                     <emphasis>Create the <filename>Makefile</filename>:</emphasis>
                     For this example, the Makefile contains two lines that
                     can be used to set the <filename>CC</filename> variable.
                     One line is identical to the value that is set when you
                     run the SDK environment setup script, and the other line
                     sets <filename>CC</filename> to "gcc", the default GNU
                     compiler on the build host:
                     <literallayout class='monospaced'>
      # CC=i586-poky-linux-gcc  -m32 -march=i586 --sysroot=/opt/poky/2.5/sysroots/i586-poky-linux
      # CC="gcc"
      all: main.o module.o
      	 ${CC} main.o module.o -o target_bin
      main.o: main.c module.h
 	     ${CC} -I . -c main.c
      module.o: module.c module.h
 	     ${CC} -I . -c module.c
      clean:
 	     rm -rf *.o
 	     rm target_bin
                     </literallayout>
                     </para></listitem>
                 <listitem><para>
                     <emphasis>Make the Project:</emphasis>
                     Use the <filename>make</filename> command to create the
                     binary output file.
                     Because variables are commented out in the Makefile,
                     the value used for <filename>CC</filename> is the value
                     set when the SDK environment setup file was run:
                     <literallayout class='monospaced'>
      $ make
      i586-poky-linux-gcc  -m32 -march=i586 --sysroot=/opt/poky/2.5/sysroots/i586-poky-linux -I . -c main.c
      i586-poky-linux-gcc  -m32 -march=i586 --sysroot=/opt/poky/2.5/sysroots/i586-poky-linux -I . -c module.c
      i586-poky-linux-gcc  -m32 -march=i586 --sysroot=/opt/poky/2.5/sysroots/i586-poky-linux main.o module.o -o target_bin
                     </literallayout>
                     From the results of the previous command, you can see that
                     the compiler used was the compiler established through
                     the <filename>CC</filename> variable defined in the
                     setup script.</para>

                     <para>You can override the <filename>CC</filename>
                     environment variable with the same variable as set from
                     the Makefile by uncommenting the line in the Makefile
                     and running <filename>make</filename> again.
                     <literallayout class='monospaced'>
      $ make clean
      rm -rf *.o
      rm target_bin
      #
      # Edit the Makefile by uncommenting the line that sets CC to "gcc"
      #
      $ make
      gcc -I . -c main.c
      gcc -I . -c module.c
      gcc main.o module.o -o target_bin
                     </literallayout>
                     As shown in the previous example, the cross-toolchain
                     compiler is not used.
                     Rather, the default compiler is used.</para>

                     <para>This next case shows how to override a variable
                     by providing the variable as part of the command line.
                     Go into the Makefile and re-insert the comment character
                     so that running <filename>make</filename> uses
                     the established SDK compiler.
                     However, when you run <filename>make</filename>, use a
                     command-line argument to set <filename>CC</filename>
                     to "gcc":
                     <literallayout class='monospaced'>
      $ make clean
      rm -rf *.o
      rm target_bin
      #
      # Edit the Makefile to comment out the line setting CC to "gcc"
      #
      $ make
      i586-poky-linux-gcc  -m32 -march=i586 --sysroot=/opt/poky/2.5/sysroots/i586-poky-linux -I . -c main.c
      i586-poky-linux-gcc  -m32 -march=i586 --sysroot=/opt/poky/2.5/sysroots/i586-poky-linux -I . -c module.c
      i586-poky-linux-gcc  -m32 -march=i586 --sysroot=/opt/poky/2.5/sysroots/i586-poky-linux main.o module.o -o target_bin
      $ make clean
      rm -rf *.o
      rm target_bin
      $ make CC="gcc"
      gcc -I . -c main.c
      gcc -I . -c module.c
      gcc main.o module.o -o target_bin
                     </literallayout>
                     In the previous case, the command-line argument overrides
                     the SDK environment variable.</para>

                     <para>In this last case, edit Makefile again to use the
                     "gcc" compiler but then use the "-e" option on the
                     <filename>make</filename> command line:
                     <literallayout class='monospaced'>
      $ make clean
      rm -rf *.o
      rm target_bin
      #
      # Edit the Makefile to use "gcc"
      #
      $ make
      gcc -I . -c main.c
      gcc -I . -c module.c
      gcc main.o module.o -o target_bin
      $ make clean
      rm -rf *.o
      rm target_bin
      $ make -e
      i586-poky-linux-gcc  -m32 -march=i586 --sysroot=/opt/poky/2.5/sysroots/i586-poky-linux -I . -c main.c
      i586-poky-linux-gcc  -m32 -march=i586 --sysroot=/opt/poky/2.5/sysroots/i586-poky-linux -I . -c module.c
      i586-poky-linux-gcc  -m32 -march=i586 --sysroot=/opt/poky/2.5/sysroots/i586-poky-linux main.o module.o -o target_bin
                     </literallayout>
                     In the previous case, the "-e" option forces
                     <filename>make</filename> to use the SDK environment
                     variables regardless of the values in the Makefile.
                     </para></listitem>
                 <listitem><para>
                     <emphasis>Execute Your Project:</emphasis>
                     To execute the project (i.e.
                     <filename>target_bin</filename>), use the following
                     command:
                     <literallayout class='monospaced'>
      $ ./target_bin
      Hello World!
                     </literallayout>
                     <note>
                         If you used the cross-toolchain compiler to build
                         <filename>target_bin</filename> and your build host
                         differs in architecture from that of the target
                         machine, you need to run your project on the target
                         device.
                     </note>
                     As expected, the project displays the "Hello World!"
                     message.
                     </para></listitem>
             </orderedlist>
         </para>
     </section>
 </chapter>
 <!--
 vim: expandtab tw=80 ts=4
 -->
	<!DOCTYPE chapter PUBLIC "-//OASIS//DTD DocBook XML V4.2//EN"
	"http://www.oasis-open.org/docbook/xml/4.2/docbookx.dtd"
	[<!ENTITY % poky SYSTEM "../poky.ent"> %poky; ] >

	<chapter id='sdk-working-projects'>

	<title>Using the SDK Toolchain Directly</title>

	<para>
	You can use the SDK toolchain directly with Makefile and
	Autotools-based projects.
	</para>

	<section id='autotools-based-projects'>
	<title>Autotools-Based Projects</title>

	<para>
	Once you have a suitable
	<ulink url='&YOCTO_DOCS_REF_URL;#cross-development-toolchain'>cross-development toolchain</ulink>
	installed, it is very easy to develop a project using the
	<ulink url='https://en.wikipedia.org/wiki/GNU_Build_System'>GNU Autotools-based</ulink>
	workflow, which is outside of the
	<ulink url='&YOCTO_DOCS_REF_URL;#build-system-term'>OpenEmbedded build system</ulink>.
	</para>

	<para>
	The following figure presents a simple Autotools workflow.
	<imagedata fileref="figures/sdk-autotools-flow.png" width="7in" height="8in" align="center" />
	</para>

	<para>
	Follow these steps to create a simple Autotools-based
	"Hello World" project:
	<note>
	For more information on the GNU Autotools workflow,
	see the same example on the
	<ulink url='https://developer.gnome.org/anjuta-build-tutorial/stable/create-autotools.html.en'>GNOME Developer</ulink>
	site.
	</note>
	<orderedlist>
	<listitem><para>
	<emphasis>Create a Working Directory and Populate It:</emphasis>
	Create a clean directory for your project and then make
	that directory your working location.
	<literallayout class='monospaced'>
	$ mkdir $HOME/helloworld
	$ cd $HOME/helloworld
	</literallayout>
	After setting up the directory, populate it with files
	needed for the flow.
	You need a project source file, a file to help with
	configuration, and a file to help create the Makefile,
	and a README file:
	<filename>hello.c</filename>,
	<filename>configure.ac</filename>,
	<filename>Makefile.am</filename>, and
	<filename>README</filename>, respectively.</para>

	<para> Use the following command to create an empty README
	file, which is required by GNU Coding Standards:
	<literallayout class='monospaced'>
	$ touch README
	</literallayout>
	Create the remaining three files as follows:
	<itemizedlist>
	<listitem><para>
	<emphasis><filename>hello.c</filename>:</emphasis>
	<literallayout class='monospaced'>
	#include <stdio.h>

	main()
	{
	printf("Hello World!\n");
	}
	</literallayout>
	</para></listitem>
	<listitem><para>
	<emphasis><filename>configure.ac</filename>:</emphasis>
	<literallayout class='monospaced'>
	AC_INIT(hello,0.1)
	AM_INIT_AUTOMAKE([foreign])
	AC_PROG_CC
	AC_CONFIG_FILES(Makefile)
	AC_OUTPUT
	</literallayout>
	</para></listitem>
	<listitem><para>
	<emphasis><filename>Makefile.am</filename>:</emphasis>
	<literallayout class='monospaced'>
	bin_PROGRAMS = hello
	hello_SOURCES = hello.c
	</literallayout>
	</para></listitem>
	</itemizedlist>
	</para></listitem>
	<listitem><para>
	<emphasis>Source the Cross-Toolchain
	Environment Setup File:</emphasis>
	As described earlier in the manual, installing the
	cross-toolchain creates a cross-toolchain
	environment setup script in the directory that the SDK
	was installed.
	Before you can use the tools to develop your project,
	you must source this setup script.
	The script begins with the string "environment-setup"
	and contains the machine architecture, which is
	followed by the string "poky-linux".
	For this example, the command sources a script from the
	default SDK installation directory that uses the
	32-bit Intel x86 Architecture and the
	&DISTRO_NAME; Yocto Project release:
	<literallayout class='monospaced'>
	$ source /opt/poky/&DISTRO;/environment-setup-i586-poky-linux
	</literallayout>
	</para></listitem>
	<listitem><para>
	<emphasis>Create the <filename>configure</filename> Script:</emphasis>
	Use the <filename>autoreconf</filename> command to
	generate the <filename>configure</filename> script.
	<literallayout class='monospaced'>
	$ autoreconf
	</literallayout>
	The <filename>autoreconf</filename> tool takes care
	of running the other Autotools such as
	<filename>aclocal</filename>,
	<filename>autoconf</filename>, and
	<filename>automake</filename>.
	<note>
	If you get errors from
	<filename>configure.ac</filename>, which
	<filename>autoreconf</filename> runs, that indicate
	missing files, you can use the "-i" option, which
	ensures missing auxiliary files are copied to the build
	host.
	</note>
	</para></listitem>
	<listitem><para>
	<emphasis>Cross-Compile the Project:</emphasis>
	This command compiles the project using the
	cross-compiler.
	The
	<ulink url='&YOCTO_DOCS_REF_URL;#var-CONFIGURE_FLAGS'><filename>CONFIGURE_FLAGS</filename></ulink>
	environment variable provides the minimal arguments for
	GNU configure:
	<literallayout class='monospaced'>
	$ ./configure ${CONFIGURE_FLAGS}
	</literallayout>
	For an Autotools-based project, you can use the
	cross-toolchain by just passing the appropriate host
	option to <filename>configure.sh</filename>.
	The host option you use is derived from the name of the
	environment setup script found in the directory in which
	you installed the cross-toolchain.
	For example, the host option for an ARM-based target that
	uses the GNU EABI is
	<filename>armv5te-poky-linux-gnueabi</filename>.
	You will notice that the name of the script is
	<filename>environment-setup-armv5te-poky-linux-gnueabi</filename>.
	Thus, the following command works to update your project
	and rebuild it using the appropriate cross-toolchain tools:
	<literallayout class='monospaced'>
	$ ./configure --host=armv5te-poky-linux-gnueabi --with-libtool-sysroot=<replaceable>sysroot_dir</replaceable>
	</literallayout>
	</para></listitem>
	<listitem><para>
	<emphasis>Make and Install the Project:</emphasis>
	These two commands generate and install the project
	into the destination directory:
	<literallayout class='monospaced'>
	$ make
	$ make install DESTDIR=./tmp
	</literallayout>
	<note>
	To learn about environment variables established
	when you run the cross-toolchain environment setup
	script and how they are used or overridden when
	the Makefile, see the
	"<link linkend='makefile-based-projects'>Makefile-Based Projects</link>"
	section.
	</note>
	This next command is a simple way to verify the
	installation of your project.
	Running the command prints the architecture on which
	the binary file can run.
	This architecture should be the same architecture that
	the installed cross-toolchain supports.
	<literallayout class='monospaced'>
	$ file ./tmp/usr/local/bin/hello
	</literallayout>
	</para></listitem>
	<listitem><para>
	<emphasis>Execute Your Project:</emphasis>
	To execute the project, you would need to run it on your
	target hardware.
	If your target hardware happens to be your build host,
	you could run the project as follows:
	<literallayout class='monospaced'>
	$ ./tmp/usr/local/bin/hello
	</literallayout>
	As expected, the project displays the "Hello World!"
	message.
	</para></listitem>
	</orderedlist>
	</para>
	</section>

	<section id='makefile-based-projects'>
	<title>Makefile-Based Projects</title>

	<para>
	Simple Makefile-based projects use and interact with the
	cross-toolchain environment variables established when you run
	the cross-toolchain environment setup script.
	The environment variables are subject to general
	<filename>make</filename> rules.
	</para>

	<para>
	This section presents a simple Makefile development flow and
	provides an example that lets you see how you can use
	cross-toolchain environment variables and Makefile variables
	during development.
	<imagedata fileref="figures/sdk-makefile-flow.png" width="6in" height="7in" align="center" />
	</para>

	<para>
	The main point of this section is to explain the following three
	cases regarding variable behavior:
	<itemizedlist>
	<listitem><para>
	<emphasis>Case 1 - No Variables Set in the
	<filename>Makefile</filename> Map to Equivalent
	Environment Variables Set in the SDK Setup Script:</emphasis>
	Because matching variables are not specifically set in the
	<filename>Makefile</filename>, the variables retain their
	values based on the environment setup script.
	</para></listitem>
	<listitem><para>
	<emphasis>Case 2 - Variables Are Set in the Makefile that
	Map to Equivalent Environment Variables from the SDK
	Setup Script:</emphasis>
	Specifically setting matching variables in the
	<filename>Makefile</filename> during the build results in
	the environment settings of the variables being
	overwritten.
	In this case, the variables you set in the
	<filename>Makefile</filename> are used.
	</para></listitem>
	<listitem><para>
	<emphasis>Case 3 - Variables Are Set Using the Command Line
	that Map to Equivalent Environment Variables from the
	SDK Setup Script:</emphasis>
	Executing the <filename>Makefile</filename> from the
	command line results in the environment variables being
	overwritten.
	In this case, the command-line content is used.
	</para></listitem>
	</itemizedlist>
	<note>
	Regardless of how you set your variables, if you use
	the "-e" option with <filename>make</filename>, the
	variables from the SDK setup script take precedence:
	<literallayout class='monospaced'>
	$ make -e <replaceable>target</replaceable>
	</literallayout>
	</note>
	</para>

	<para>
	The remainder of this section presents a simple Makefile example
	that demonstrates these variable behaviors.
	</para>

	<para>
	In a new shell environment variables are not established for the
	SDK until you run the setup script.
	For example, the following commands show a null value for the
	compiler variable (i.e.
	<ulink url='&YOCTO_DOCS_REF_URL;#var-CC'><filename>CC</filename></ulink>).
	<literallayout class='monospaced'>
	$ echo ${CC}

	$
	</literallayout>
	Running the SDK setup script for a 64-bit build host and an
	i586-tuned target architecture for a
	<filename>core-image-sato</filename> image using the current
	&DISTRO; Yocto Project release and then echoing that variable
	shows the value established through the script:
	<literallayout class='monospaced'>
	$ source /opt/poky/&DISTRO;/environment-setup-i586-poky-linux
	$ echo ${CC}
	i586-poky-linux-gcc -m32 -march=i586 --sysroot=/opt/poky/2.5/sysroots/i586-poky-linux
	</literallayout>
	</para>

	<para>
	To illustrate variable use, work through this simple "Hello World!"
	example:
	<orderedlist>
	<listitem><para>
	<emphasis>Create a Working Directory and Populate It:</emphasis>
	Create a clean directory for your project and then make
	that directory your working location.
	<literallayout class='monospaced'>
	$ mkdir $HOME/helloworld
	$ cd $HOME/helloworld
	</literallayout>
	After setting up the directory, populate it with files
	needed for the flow.
	You need a <filename>main.c</filename> file from which you
	call your function, a <filename>module.h</filename> file
	to contain headers, and a <filename>module.c</filename>
	that defines your function.
	</para>

	<para>Create the three files as follows:
	<itemizedlist>
	<listitem><para>
	<emphasis><filename>main.c</filename>:</emphasis>
	<literallayout class='monospaced'>
	#include "module.h"
	void sample_func();
	int main()
	{
	sample_func();
	return 0;
	}
	</literallayout>
	</para></listitem>
	<listitem><para>
	<emphasis><filename>module.h</filename>:</emphasis>
	<literallayout class='monospaced'>
	#include <stdio.h>
	void sample_func();
	</literallayout>
	</para></listitem>
	<listitem><para>
	<emphasis><filename>module.c</filename>:</emphasis>
	<literallayout class='monospaced'>
	#include "module.h"
	void sample_func()
	{
	printf("Hello World!");
	printf("\n");
	}
	</literallayout>
	</para></listitem>
	</itemizedlist>
	</para></listitem>
	<listitem><para>
	<emphasis>Source the Cross-Toolchain Environment Setup File:</emphasis>
	As described earlier in the manual, installing the
	cross-toolchain creates a cross-toolchain environment setup
	script in the directory that the SDK was installed.
	Before you can use the tools to develop your project,
	you must source this setup script.
	The script begins with the string "environment-setup"
	and contains the machine architecture, which is
	followed by the string "poky-linux".
	For this example, the command sources a script from the
	default SDK installation directory that uses the
	32-bit Intel x86 Architecture and the
	&DISTRO_NAME; Yocto Project release:
	<literallayout class='monospaced'>
	$ source /opt/poky/&DISTRO;/environment-setup-i586-poky-linux
	</literallayout>
	</para></listitem>
	<listitem><para>
	<emphasis>Create the <filename>Makefile</filename>:</emphasis>
	For this example, the Makefile contains two lines that
	can be used to set the <filename>CC</filename> variable.
	One line is identical to the value that is set when you
	run the SDK environment setup script, and the other line
	sets <filename>CC</filename> to "gcc", the default GNU
	compiler on the build host:
	<literallayout class='monospaced'>
	# CC=i586-poky-linux-gcc -m32 -march=i586 --sysroot=/opt/poky/2.5/sysroots/i586-poky-linux
	# CC="gcc"
	all: main.o module.o
	${CC} main.o module.o -o target_bin
	main.o: main.c module.h
	${CC} -I . -c main.c
	module.o: module.c module.h
	${CC} -I . -c module.c
	clean:
	rm -rf *.o
	rm target_bin
	</literallayout>
	</para></listitem>
	<listitem><para>
	<emphasis>Make the Project:</emphasis>
	Use the <filename>make</filename> command to create the
	binary output file.
	Because variables are commented out in the Makefile,
	the value used for <filename>CC</filename> is the value
	set when the SDK environment setup file was run:
	<literallayout class='monospaced'>
	$ make
	i586-poky-linux-gcc -m32 -march=i586 --sysroot=/opt/poky/2.5/sysroots/i586-poky-linux -I . -c main.c
	i586-poky-linux-gcc -m32 -march=i586 --sysroot=/opt/poky/2.5/sysroots/i586-poky-linux -I . -c module.c
	i586-poky-linux-gcc -m32 -march=i586 --sysroot=/opt/poky/2.5/sysroots/i586-poky-linux main.o module.o -o target_bin
	</literallayout>
	From the results of the previous command, you can see that
	the compiler used was the compiler established through
	the <filename>CC</filename> variable defined in the
	setup script.</para>

	<para>You can override the <filename>CC</filename>
	environment variable with the same variable as set from
	the Makefile by uncommenting the line in the Makefile
	and running <filename>make</filename> again.
	<literallayout class='monospaced'>
	$ make clean
	rm -rf *.o
	rm target_bin
	#
	# Edit the Makefile by uncommenting the line that sets CC to "gcc"
	#
	$ make
	gcc -I . -c main.c
	gcc -I . -c module.c
	gcc main.o module.o -o target_bin
	</literallayout>
	As shown in the previous example, the cross-toolchain
	compiler is not used.
	Rather, the default compiler is used.</para>

	<para>This next case shows how to override a variable
	by providing the variable as part of the command line.
	Go into the Makefile and re-insert the comment character
	so that running <filename>make</filename> uses
	the established SDK compiler.
	However, when you run <filename>make</filename>, use a
	command-line argument to set <filename>CC</filename>
	to "gcc":
	<literallayout class='monospaced'>
	$ make clean
	rm -rf *.o
	rm target_bin
	#
	# Edit the Makefile to comment out the line setting CC to "gcc"
	#
	$ make
	i586-poky-linux-gcc -m32 -march=i586 --sysroot=/opt/poky/2.5/sysroots/i586-poky-linux -I . -c main.c
	i586-poky-linux-gcc -m32 -march=i586 --sysroot=/opt/poky/2.5/sysroots/i586-poky-linux -I . -c module.c
	i586-poky-linux-gcc -m32 -march=i586 --sysroot=/opt/poky/2.5/sysroots/i586-poky-linux main.o module.o -o target_bin
	$ make clean
	rm -rf *.o
	rm target_bin
	$ make CC="gcc"
	gcc -I . -c main.c
	gcc -I . -c module.c
	gcc main.o module.o -o target_bin
	</literallayout>
	In the previous case, the command-line argument overrides
	the SDK environment variable.</para>

	<para>In this last case, edit Makefile again to use the
	"gcc" compiler but then use the "-e" option on the
	<filename>make</filename> command line:
	<literallayout class='monospaced'>
	$ make clean
	rm -rf *.o
	rm target_bin
	#
	# Edit the Makefile to use "gcc"
	#
	$ make
	gcc -I . -c main.c
	gcc -I . -c module.c
	gcc main.o module.o -o target_bin
	$ make clean
	rm -rf *.o
	rm target_bin
	$ make -e
	i586-poky-linux-gcc -m32 -march=i586 --sysroot=/opt/poky/2.5/sysroots/i586-poky-linux -I . -c main.c
	i586-poky-linux-gcc -m32 -march=i586 --sysroot=/opt/poky/2.5/sysroots/i586-poky-linux -I . -c module.c
	i586-poky-linux-gcc -m32 -march=i586 --sysroot=/opt/poky/2.5/sysroots/i586-poky-linux main.o module.o -o target_bin
	</literallayout>
	In the previous case, the "-e" option forces
	<filename>make</filename> to use the SDK environment
	variables regardless of the values in the Makefile.
	</para></listitem>
	<listitem><para>
	<emphasis>Execute Your Project:</emphasis>
	To execute the project (i.e.
	<filename>target_bin</filename>), use the following
	command:
	<literallayout class='monospaced'>
	$ ./target_bin
	Hello World!
	</literallayout>
	<note>
	If you used the cross-toolchain compiler to build
	<filename>target_bin</filename> and your build host
	differs in architecture from that of the target
	machine, you need to run your project on the target
	device.
	</note>
	As expected, the project displays the "Hello World!"
	message.
	</para></listitem>
	</orderedlist>
	</para>
	</section>
	</chapter>
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