Difference between revisions of "Build Xinu"
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6. Ensure the directory containing the toolchain is added to the system's PATH. This is operating system specific. If the toolchain is not added to the PATH, users will not be able to execute it from any directory. | 6. Ensure the directory containing the toolchain is added to the system's PATH. This is operating system specific. If the toolchain is not added to the PATH, users will not be able to execute it from any directory. | ||
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+ | 7. If all has gone well, you should now have a gcc cross-compiler from your host's native architecture to little-endian MIPS: | ||
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+ | riscv64-linux-gnu-gcc | ||
=== MIPS Cross-Compiler === | === MIPS Cross-Compiler === |
Revision as of 00:48, 22 March 2024
The new MIPS port of Embedded XINU has been released. See the Downloads tab for more information.
Contents
Cross-Compiler
RISC-V Cross-Compiler and Toolchain
The RISC-V cross-compiler and toolchain can be found [here]. Installing the toolchain installs the cross-compiler, LLVM, QEMU, and GCC all with RISC-V support.
Installing the Toolchain
1. Clone the RISC-V toolchain. Note, this may take a while.
git clone https://github.com/riscv-collab/riscv-gnu-toolchain --recurse-submodules
2. Install the dependencies for your system
For Ubuntu
sudo apt-get install autoconf automake autotools-dev curl python3 python3-pip libmpc-dev libmpfr-dev libgmp-dev gawk build-essential bison flex texinfo gperf libtool patchutils bc zlib1g-dev libexpat-dev ninja-build git cmake libglib2.0-dev
For Fedora/CentOS/RHEL OS
sudo yum install autoconf automake python3 libmpc-devel mpfr-devel gmp-devel gawk bison flex texinfo patchutils gcc gcc-c++ zlib-devel expat-devel
4. Run the configuration script. By default, it will install the toolchain in `/opt/riscv`. Change this parameter to install the toolchain in a different location.
cd riscv-gnu-toolchain && ./configure --prefix=/opt/riscv
5. Install the toolchain
make linux
6. Ensure the directory containing the toolchain is added to the system's PATH. This is operating system specific. If the toolchain is not added to the PATH, users will not be able to execute it from any directory.
7. If all has gone well, you should now have a gcc cross-compiler from your host's native architecture to little-endian MIPS:
riscv64-linux-gnu-gcc
MIPS Cross-Compiler
In order to compile Embedded MIPS kernels on a workstation that is not itself a MIPS processor, it is necessary to build and install an appropriate cross compiler. There are many ways to accomplish this; for reference, we list the specific versions and steps we used for our installation.
NOTE: the following tutorial describes the steps for creating a MIPS cross-compiler in a Linux environment. See our other wiki pages for tutorials on building cross-compilers for Windows XP or Mac OS X.
As always, one should be wary of installing unfamilar software as the root user of the system. All of the steps below have been carried out as a lesser-privileged user with write access to the necessary directories.
Build binutils
First, we downloaded, compiled, and installed the appropriate binary utilities. We downloaded binutils version 2.21, untarred the source code, and ran the following commands inside the new directory created by untarring the download:
./configure --prefix=/usr/local/project/mipsel-dev --target=mipsel make make install
Note about cross-compiler location
We have chosen the path "/usr/local/project/mipsel-dev" to host our cross-compiler installation. Whatever path is used here must be reflected in the XINU build configuration file, "compile/platforms/*/platformVars" when you arrive at that step.
Link include directory
We are not building a true, full-blown UNIX cross-compiler here, and do not need a proper installation of the platform-specific C libraries; XINU has its own small libraries that compile with the kernel. However, the GCC compilation will want to see appropriate library headers, so we cheat here by linking the platform-specific include directory to the host machine's include directory.
mkdir -p /usr/local/project/mipsel-dev/mipsel/usr ln -s /usr/include /usr/local/project/mipsel-dev/mipsel/usr/include
Build GNU C Compiler
Second, we downloaded, patched, compiled and installed the GNU C Compiler. We downloaded GCC version 4.6.1. We added the newly compiled binutils into the shell path (/usr/local/project/mipsel-dev/bin) for the gcc compilation to find them. This is also known to work with GCC version 4.1.2 and 4.2.0 unpatched, using this script to get around installing a bunch of platform-specific UNIX libraries.
./configure --prefix=/usr/local/project/mipsel-dev --target=mipsel --with-sysroot=/usr/local/project/mipsel-dev/mipsel/ --enable-languages=c make make install
Rejoice
If all has gone well, you should now have a gcc cross-compiler from your host's native architecture to little-endian MIPS:
/usr/local/project/mipsel-dev/bin/mipsel-gcc
Remember the path to this file because later you'll need to double check some building variables to make sure they point to the correct location of your cross-compiler.
Building the XINU Image
Once you have downloaded and extracted the xinu tarball, you will see a basic directory structure:
AUTHORS device lib loader README system compile include LICENSE mailbox shell test
AUTHORS is a brief history of contributors to the XINU operating system in it's varying iterations.
compile/ contains the Makefile and other necessities for building the XINU system once you have a cross-compiler.
device/ contains the source for all device drivers, including the tty and uart driver.
include/ contains all the header files used by XINU.
lib/ contains a folder (libxc/) with a Makefile and source for the library, as well as a binary blob which contains the pre-compiled library.
LICENSE is the license under which this project falls.
loader/ contains assembly files and is where the bootloader will begin execution of O/S code.
mailbox/ contains the source for the mailbox message-passing implementation.
README is this document.
shell/ contains the source for all shell related functions.
system/ contains the source for all system functions such as the nulluser process (initialize.c) as well as code to set up a C environment (startup.S).
test/ contains a number of testcases (which can be run using the shell command testsuite).
First, it is a good idea to read up on building the XINU system. Next, you'll want to check your mipsVars
file in the compile
directory. The file should look something like this:
MIPS_ROOT = /usr/local/project/mipsel-dev/bin MIPS_PREFIX = mipsel- COMPILER_ROOT = ${MIPS_ROOT}/${MIPS_PREFIX} CC = ${COMPILER_ROOT}gcc CPP = ${COMPILER_ROOT}cpp LD = ${COMPILER_ROOT}ld AS = ${COMPILER_ROOT}as AR = ${COMPILER_ROOT}ar MAKEDEP = `which makedepend` DOCGEN = doxygen # DETAIL = -DDETAIL DEFS = INCLUDE = -I../include #flag for producing GDB debug information BUGFLAG = -ggdb CFLAGS = -O0 -Wall -Werror -Wstrict-prototypes -Wno-trigraphs \ -nostdinc -fno-builtin -fno-strict-aliasing -fno-common \ -fomit-frame-pointer -fno-pic -ffunction-sections -G 0 \ -mlong-calls -mno-abicalls -mabi=32 -march=mips32 \ -Wa,-32 -Wa,-march=mips32 -Wa,-mips32 -Wa,--trap \ ${DEBUG} ${INCLUDE} ${DETAIL} ${DEFS} -c ASFLAGS = ${INCLUDE} ${DEBUG} -march=mips32 -mips32
The important thing to note on this file is the MIPS_ROOT
variable. It needs to point to the directory containing the cross-compiler. If you followed the commands in the tutorial exactly, then the value of the MIPS_ROOT
variable in the code above should be the correct value.
Now you'll want to actually create your boot image. In the compile/
directory execute the following commands: make clean
and make
. The make
command will let you know if you have any compiling errors or warnings. If there are none, then you should have successfully created a XINU boot image located in the file xinu.boot
in the compile/
directory. Remember that each time you make changes to source files, to recompile and create a new XINU boot image you have to execute make clean
and then make
.
What to do next?
Now that you have successfully built a XINU boot image you're ready to use that file to actually boot XINU on your backend router.
This work is supported in part by NSF grant DUE-CCLI-0737476.