The OSKit - Flux Operating System Toolkit
Version 0.97 - January 15, 1999
Snapshot 20020317 - March 17, 2002
For major changes since release 0.96 in Dec. 1998 see the file ./ANNOUNCE
This is the top level directory of the source distribution of the OSKit. The OSKit is a framework and a set of 31 component libraries oriented to operating systems, together with extensive documentation. By providing in a modular way not only most of the infrastructure "grunge" needed by an OS, but also many higher-level components, the OSKit's goal is to lower the barrier to entry to OS R&D and to lower its costs. The OSKit makes it vastly easier to create a new OS, port an existing OS to the x86 (or in the future, to other architectures supported by the OSkit), or enhance an OS to support a wider range of devices, file system formats, executable formats, or network services. The OSKit also works well for constructing OS-related programs, such as boot loaders or OS-level servers atop a microkernel.
For language researchers and enthusiasts, the OSKit lets them concentrate on the real language issues raised by using advanced languages inside operating systems, such as Java, Lisp, Scheme, or ML--- instead of spending six months first writing boot loader code, startup code, device drivers, kernel printf and malloc code, a kernel debugger, etc. With the recent addition of extensive multithreading and sophisticated scheduling support, the OSKit also provides a modular platform for embedded applications, as well as a novel component-based approach to constructing entire operating systems. See doc/html/roadmap.html for a quick overview of the components.
With the code available from www.cs.utah.edu/projects/flux/oskit/kaffe/ the highly portable Kaffe JVM from www.transvirtual.com "just works" on the bare PC hardware using the OSKit. Yes, a "Java OS"-- but you can also reconfigure the OSKit to run Kaffe/OSKit on top of Unix, which is great for debugging. Almost all the changes are already merged into the mainline Kaffe tree. (Note the restriction that currently the only display support for Kaffe kernels is to use the OSKit's xclient support to display on another machine that runs an X server.) On our ftp site in flux/oskit/doom, we also provide patches for Doom, to get a "DoomOS."
See ANNOUNCE for more quick answers. For the latest versions of those files, look at www.cs.utah.edu/projects/flux/oskit/. Detailed instructions on how to install and use the OSKit are contained in Chapter One of the document in the `doc' subdir. Text, Postscript, and 2-up Postscript of the 500-page document are in doc/oskit.*.gz. An HTML version is here at doc/html/index.html as well as at www.cs.utah.edu/projects/flux/oskit/doc/.
Don't let the size of the doc scare you! You probably won't need to read practically any of it to use the OSKit for simple things. We provide some 45 small example kernels and recommend that you start learning by example and by doing (modifying them), like most good hackers do, and read to fill in details, for reference, or to cure insomnia. However, reading Chapter One of the doc is a very good idea, especially the roadmap, doc/html/roadmap.html. Also, you might scan the top-level directories and the examples. Each directory should have a README. Finally, the CREDITS file gives just that.
Requirements:
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Hardware: The OSKit requires an Intel 486 PC or above, with at least four MB of memory. A floppy or hard disk is required to load OSKit kernels (at least the first one; see "netboot" below), but is not required to run them.
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Software: native build environment for either Linux or FreeBSD. The latest snapshot has only been tested with the default build environments provided with FreeBSD 4.3/4.5 and Red Hat Linux 7.1/7.2. In particular, we have not done any testing with GCC 3 releases. Cross building is possible and it's been done frequently on HP machines. Build tools required are GNU make, gcc 2.7.x or 2.95.x and binutils 2.8.x or 2.9.x.
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A boot loader that can load one of Linux, Mach, BSD, or MultiBoot-compliant images. (Our DOS loader is current broken; see the BUGS file.)
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The GNU linker is required if creating BSD/Mach boot images on FreeBSD 2.x (available at ftp://flux.cs.utah.edu/flux/oskit/boot/bsd/).
Configuring and building step-by-step:
The OSKit follows the GNU conventions for configuration, building, and installation. The "configure" script in the top level directory will attempt to guess your system type and locate various required tools such as the C compiler. You can configure the OSKit to build itself in its own source directory, simply by moving to that directory and typing ./configure, or you can build the OSKit into a separate object directory by changing to that directory and running the configure script from there. The introductory section of the OSKit documentation describes the OSKit specific options to configure in detail. As an example, to configure the OSKit on a FreeBSD machine, generating a.out format, you would run configure as follows:
/somepath/oskit/configure --prefix=/somepath/install
--build=i586-freebsd --host=i386-mach
On Linux, building ELF format, you'd simply do: /somepath/oskit/configure --prefix=/somepath/install
Once the OSKit is configured, you can proceed to build the OSKit by going to the directory you have chosen to build it in, and running GNU "make" (e.g., just "make" on Linux systems, or "gmake" on BSD systems). Once the build completes, you can 'make install' to make the OSKit binaries and header files to make it publicly available.
Disk usage:
-Source and doc tree is 7.5M compressed, 30.5M uncompressed. -ELF object tree without debug, without profile, without docs: 48M. The examples dir is 20M of that. -ELF object tree with debug, without profile, without docs: 221M.
Using the OSKit:
The examples/x86 directory contains a number of example kernels that you can use to experiment with the OSKit. The simplest example is the "hello" kernel, which prints "Hello World" on the console, and then reboots. If you have built the entire OSKit tree, the sample kernels will have already been built. If not, go to the examples/x86 directory and run GNU make.
The resulting hello binary conforms to the "multiboot" standard, and is immediately ready to boot with a multiboot compliant loader such as GRUB (www.uruk.org/grub/). You can also use the OSKit's "netboot" loader, which can directly load multiboot images across the network.
Other boot formats supported by the OSKit are Linux, Mach, and BSD (MS-DOS is currently broken). The conversion utilities supplied to convert from multiboot format are "mklinuximage", "mkbsdimage", and "mkdosimage." These utilities are automatically built and installed with the OSKit, when configured for the appropriate host. Due to the extra difficulty and delicacy of building them they are also provided in binary form, in ftp://flux.cs.utah.edu/flux/oskit/boot/. As an example, to convert the hello kernel into the format required by the BSD and Mach boot loaders:
/somepath/install/bin/mkbsdimage hello
Note that by default, the resulting image is placed in a file called "Image" in the current directory. This image can then be copied to the root partition of your machine, and booted like any other kernel. In the case of the hello kernel, it will simply print "Hello World", exit, and then reset the machine (after waiting for a key press if you're on the VGA console).
Netboot:
As an alternative, you can use the OSKit's NetBoot loader to load the original multiboot image from across the network. The NetBoot loader is contained in the boot/net directory, and will have been built along with the rest of the OSKit. NetBoot is a small kernel that provides one service: fast (re)booting of other multiboot compliant operating systems across the network. There are several requirements for using NetBoot:
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NetBoot itself must be in one of the accepted boot formats described above in order to load, and it must reside in the root directory of the machine being used to boot kernels.
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NetBoot requires a BOOTP server to be running on the local network in order to obtain the IP address, gateway address, netmask, and hostname of the host it runs on. If no BOOTP server responds when NetBoot is booted, it will ask to retry or exit.
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The files that NetBoot fetches and boots must reside in a directory that is NFS exported to the host running NetBoot.
If all of these requirements are satisfied, then you can boot the hello kernel across the network as follows:
Netboot: ipaddr:/somepath/examples/x86/hello
BSD Boot Support:
The easiest way to get BSD boot image support (boot/bsd) is to have a linker on your path that is configured for both ELF and Mach formats. That way, you can build your oskit with ELF tools, but write out an I386Mach format adaptor that is suitable for the BSD loader. The best approach we found is to take a vanilla binutils 2.9.1, and configure it as follows (assuming a FreeBSD 3.0 system):
/build/src/binutils-2.9.1/configure --prefix=/build/tools
--target=i386-mach \
--enable-targets=i386-mach,i386-unknown-freebsdelf3.0
Then setenv AOUT_LD to:
/build/tools/bin/i386-mach-ld -m i386mach
Then configure and build your oskit, which will now include a bsd boot adaptor directory, built with ELF tools of course. Then you can take an ELF version of netboot (from the same build tree) and run it through a modified mkbsdimage, which references a new linker script. This linker script does the usual munging of sections and such, so that the output image actually works.
More sophisticated examples:
There are numerous example kernels, but we highlight just a few that demonstrate more useful functionality. Pointers to the relevant sections in the documentation are provided as well.
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examples/x86/socket_com.c: This is a test program for the TCP/IP stack. It first does two fingers and then waits for incoming date requests. It is written to the Component Object Model (COM) interfaces for the TCP/IP stack. See the "OSKit Networking Framework" and "FreeBSD Networking" sections.
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examples/x86/socket_bsd.c: Same as previous example, but is written to the oskit libc socket interface. See the "Minimal C Library" and "FreeBSD Networking" sections.
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examples/x86/blkio.c: This is a program that illustrates the use of the block device drivers. It reads blocks of data from a disk, and optionally writes data to the disk. See the "Block I/O Interface" section.
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examples/x86/netbsd_fs_com.c: Illustrate the use of the NetBSD filesystem code using the COM interfaces. An assortment of operations are performed, including reading and writing files, creating directories, looking up files, linking files, and renaming files. See the "Disk Partition Interpreter", "File Interface," "Directory Interface" and "Open File Interface" sections of the documentation.
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examples/x86/dphils.c: This program illustrates the use of the POSIX threads package, solving the classic dining philosophers problem using monitors. See the "POSIX Threads" section of the documentation.
For known problems see the BUGS file.
Cross building:
It's been done at least under HPUX and under our BSD for HP's. Should work in general. HPUX: config options: --target=i486-linux --host=hppa1.1-hp-hpux gcc 2.7.2, binutils 2.8.1 [ had trouble building libgcc as I recall ]
Version Information:
The following is a list of the versions of software from which the OSKit derives large chunks of code:
FreeBSD: 2.1.7.x (networking, glue), 2.2.2 (C and math libs) NetBSD: 1.2 Linux: 2.0.29 x11: XFree86 3.3.1 svgalib: 1.3.0 Mach: basically what was our "mach4"
Contact Information:
Send comments, suggestions, bugs, and fixes to [email protected].
For messages just to the Utah developers send to [email protected].
To be added to appropriate mailing lists, send mail to: [email protected] (oskit users/hackers) [email protected] (major announcements only) You do not have to be on both lists at once; mail to the announce list also goes to the users list (but not vice versa, of course.)
Archives of the mailing lists are available in ftp://flux.cs.utah.edu/flux/oskit/mail/html/index.html (HTML) ftp://flux.cs.utah.edu/flux/oskit/mail/index.html (mbox)
Have fun!
The Flux Research Group Department of Computer Science University of Utah http://www.cs.utah.edu/projects/flux/