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diff --git a/poky/documentation/adt-manual/adt-command.rst b/poky/documentation/adt-manual/adt-command.rst new file mode 100644 index 0000000000..de854772bb --- /dev/null +++ b/poky/documentation/adt-manual/adt-command.rst @@ -0,0 +1,180 @@ +.. SPDX-License-Identifier: CC-BY-2.0-UK + +********************** +Using the Command Line +********************** + +Recall that earlier the manual discussed how to use an existing +toolchain tarball that had been installed into the default installation +directory, ``/opt/poky/DISTRO``, which is outside of the :term:`Build Directory` +(see the section +"`Using a Cross-Toolchain +Tarball) <#using-an-existing-toolchain-tarball>`__". And, that sourcing +your architecture-specific environment setup script initializes a +suitable cross-toolchain development environment. + +During this setup, locations for the compiler, QEMU scripts, QEMU +binary, a special version of ``pkgconfig`` and other useful utilities +are added to the ``PATH`` variable. Also, variables to assist +``pkgconfig`` and ``autotools`` are also defined so that, for example, +``configure.sh`` can find pre-generated test results for tests that need +target hardware on which to run. You can see the "`Setting Up the +Cross-Development +Environment <#setting-up-the-cross-development-environment>`__" section +for the list of cross-toolchain environment variables established by the +script. + +Collectively, these conditions allow you to easily use the toolchain +outside of the OpenEmbedded build environment on both Autotools-based +projects and Makefile-based projects. This chapter provides information +for both these types of projects. + +Autotools-Based Projects +======================== + +Once you have a suitable cross-toolchain installed, it is very easy to +develop a project outside of the OpenEmbedded build system. This section +presents a simple "Helloworld" example that shows how to set up, +compile, and run the project. + +Creating and Running a Project Based on GNU Autotools +----------------------------------------------------- + +Follow these steps to create a simple Autotools-based project: + +1. *Create your directory:* Create a clean directory for your project + and then make that directory your working location: $ mkdir + $HOME/helloworld $ cd $HOME/helloworld + +2. *Populate the directory:* Create ``hello.c``, ``Makefile.am``, and + ``configure.in`` files as follows: + + - For ``hello.c``, include these lines: #include <stdio.h> main() { + printf("Hello World!\n"); } + + - For ``Makefile.am``, include these lines: bin_PROGRAMS = hello + hello_SOURCES = hello.c + + - For ``configure.in``, include these lines: AC_INIT(hello.c) + AM_INIT_AUTOMAKE(hello,0.1) AC_PROG_CC AC_PROG_INSTALL + AC_OUTPUT(Makefile) + +3. *Source the cross-toolchain environment setup file:* Installation of + the cross-toolchain creates a cross-toolchain environment setup + script in the directory that the ADT 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". Here is an example that sources a script from the + default ADT installation directory that uses the 32-bit Intel x86 + Architecture and the DISTRO_NAME Yocto Project release: $ source + /opt/poky/DISTRO/environment-setup-i586-poky-linux + +4. *Generate the local aclocal.m4 files and create the configure + script:* The following GNU Autotools generate the local + ``aclocal.m4`` files and create the configure script: $ aclocal $ + autoconf + +5. *Generate files needed by GNU coding standards:* GNU coding + standards require certain files in order for the project to be + compliant. This command creates those files: $ touch NEWS README + AUTHORS ChangeLog + +6. *Generate the configure file:* This command generates the + ``configure``: $ automake -a + +7. *Cross-compile the project:* This command compiles the project using + the cross-compiler. The + :term:`CONFIGURE_FLAGS` + environment variable provides the minimal arguments for GNU + configure: $ ./configure ${CONFIGURE_FLAGS} + +8. *Make and install the project:* These two commands generate and + install the project into the destination directory: $ make $ make + install DESTDIR=./tmp + +9. *Verify the installation:* This 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. $ file ./tmp/usr/local/bin/hello + +10. *Execute your project:* To execute the project in the shell, simply + enter the name. You could also copy the binary to the actual target + hardware and run the project there as well: $ ./hello As expected, + the project displays the "Hello World!" message. + +Passing Host Options +-------------------- + +For an Autotools-based project, you can use the cross-toolchain by just +passing the appropriate host option to ``configure.sh``. 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 ``armv5te-poky-linux-gnueabi``. You will notice that the name of the +script is ``environment-setup-armv5te-poky-linux-gnueabi``. Thus, the +following command works to update your project and rebuild it using the +appropriate cross-toolchain tools: $ ./configure +--host=armv5te-poky-linux-gnueabi \\ --with-libtool-sysroot=sysroot_dir + +.. note:: + + If the + configure + script results in problems recognizing the + --with-libtool-sysroot= + sysroot-dir + option, regenerate the script to enable the support by doing the + following and then run the script again: + :: + + $ libtoolize --automake + $ aclocal -I ${OECORE_NATIVE_SYSROOT}/usr/share/aclocal \ + [-I dir_containing_your_project-specific_m4_macros] + $ autoconf + $ autoheader + $ automake -a + + +Makefile-Based Projects +======================= + +For Makefile-based projects, the cross-toolchain environment variables +established by running the cross-toolchain environment setup script are +subject to general ``make`` rules. + +To illustrate this, consider the following four cross-toolchain +environment variables: +:term:`CC`\ =i586-poky-linux-gcc -m32 +-march=i586 --sysroot=/opt/poky/1.8/sysroots/i586-poky-linux +:term:`LD`\ =i586-poky-linux-ld +--sysroot=/opt/poky/1.8/sysroots/i586-poky-linux +:term:`CFLAGS`\ =-O2 -pipe -g +-feliminate-unused-debug-types +:term:`CXXFLAGS`\ =-O2 -pipe -g +-feliminate-unused-debug-types Now, consider the following three cases: + +- *Case 1 - No Variables Set in the ``Makefile``:* Because these + variables are not specifically set in the ``Makefile``, the variables + retain their values based on the environment. + +- *Case 2 - Variables Set in the ``Makefile``:* Specifically setting + variables in the ``Makefile`` during the build results in the + environment settings of the variables being overwritten. + +- *Case 3 - Variables Set when the ``Makefile`` is Executed from the + Command Line:* Executing the ``Makefile`` from the command line + results in the variables being overwritten with command-line content + regardless of what is being set in the ``Makefile``. In this case, + environment variables are not considered unless you use the "-e" flag + during the build: $ make -e file If you use this flag, then the + environment values of the variables override any variables + specifically set in the ``Makefile``. + +.. note:: + + For the list of variables set up by the cross-toolchain environment + setup script, see the " + Setting Up the Cross-Development Environment + " section. |