Provided by: gxemul_0.7.0+dfsg-1_amd64 
NAME
gxemul — an experimental framework for full-system machine emulation
SYNOPSIS
gxemul [machine, other, and general options] [file ...]
gxemul [general options] @configfile
gxemul -H
DESCRIPTION
gxemul is a framework for full-system computer architecture emulation. Several processor
architectures and machine types have been implemented. It is working well enough to allow
unmodified "guest" operating systems (e.g. NetBSD) to run inside the emulator, as if they
were running on real hardware.
The emulator emulates (networks of) real machines. The machines may consist of ARM, MIPS,
Motorola 88K, PowerPC, and SuperH processors, and various surrounding hardware components
such as framebuffers, busses, interrupt controllers, ethernet controllers, disk controllers,
and serial port controllers.
RUNNING GUEST OPERATING SYSTEMS
Please read the HTML documentation for more details on how to run specific guest operating
systems in the emulator.
RUNNING THE EMULATOR
The emulator can be invoked in the following ways:
1. When emulating a complete machine, configuration options can be supplied directly on the
command line.
2. Options can be read from a configuration file.
The easiest way to use the emulator is to supply settings directly on the command line.
The most important thing you need to supply is the file argument. This is the name of a
binary file (an ELF, a.out, COFF/ECOFF, SREC, or a raw binary image) which you wish to run
in the emulator. This file might be an operating system kernel, or perhaps a ROM image file.
If more than one filename is supplied, all files are loaded into memory, and the entry point
(if available) is taken from the last file.
Apart from the name of a binary file, you must also use the -E and/or -e options to select
which emulation mode to use. This is necessary because the emulator cannot in general deduce
this from the file being executed. For example, a MIPS-based machine from DEC (a
DECstation) is very different from a MIPS-based machine from SGI. Use gxemul -H to get a
list of available emulation modes.
There are three exceptions to the normal invocation usage mentioned above.
1. For DECstation emulation, if you have a bootable DECstation harddisk or CDROM image, then
just supplying the diskimage via the -d option is sufficient. The filename of the kernel can
then be skipped, as the emulator runs the bootblocks from the diskimage directly and doesn't
need the kernel as a separate file.
2. If you supply an ISO9660 CDROM disk image, then using the -j option to indicate a file on
the CDROM filesystem to load is sufficient; no additional kernel filename needs to be
supplied on the command line.
3. For Dreamcast emulation, when booting e.g. a NetBSD/dreamcast CDROM image, it is enough
to supply the disk image (with the correct ISO partition start offset). Bootblocks will be
read directly from the CDROM image, and there is no need to supply the name of an external
kernel on the command line.
Gzipped kernels are automatically unzipped, by calling the external gunzip program, both
when specifying a gzipped file directly on the command line and when loading such a file
using the -j option.
Machine selection options:
-E t Try to emulate machine type t. This option is not always needed, if the -e option
uniquely selects a machine. (Use -H to get a list of types.)
-e st Try to emulate machine subtype st. Use this together with -E. (This option is not
always needed, if a machine type has no subtypes.)
Other options:
-C x Try to emulate a specific CPU type, x. This overrides the default CPU type for the
machine being emulated. (Use -H to get a list of available CPU types.)
-d [modifiers:]filename
Add filename as a disk image. By adding one or more modifier characters and then a
colon (":") as a prefix to filename, you can modify the way the disk image is
treated. Available modifiers are:
b Specifies that this is a boot device.
c CD-ROM.
d DISK (this is the default).
f FLOPPY.
gH;S; Override the default geometry; use H heads and S sectors-per-track. (The
number of cylinders is calculated automatically.)
i IDE.
oOFS; Set the base offset for an ISO9660 filesystem on a disk image. The default
is 0. A suitable offset when booting from Dreamcast ISO9660 filesystem
images, which are offset by 11702 sectors, is 23965696.
r Read-only (don't allow changes to be written to the file).
R Don't allow changes to the file, but add a temporary overlay for the disk
image to allow guest operating systems to write to the disk. (These changes
are lost when the GXemul process exits.)
s SCSI.
t Tape.
V Add an overlay filename to an already defined disk image. (A ID number must
also be specified when this flag is used. See the documentation for an
example of how to use overlays.)
0-7 Force a specific ID number.
For SCSI devices, the ID number is the SCSI ID. For IDE harddisks, the ID number has
the following meaning:
0 Primary master.
1 Primary slave.
2 Secondary master.
3 Secondary slave.
Unless otherwise specified, filenames ending with ".iso" or ".cdr" are assumed to be
CDROM images. Most others are assumed to be disks. Depending on which machine is
being emulated, the default for disks can be either SCSI or IDE. Some disk images
that are very small are assumed to be floppy disks. (If you are not happy with the
way a disk image is detected, then you need to use explicit prefixes to force a
specific type.)
For floppies, the gH;S; prefix is ignored. Instead, the number of heads and
cylinders are assumed to be 2 and 80, respectively, and the number of sectors per
track is calculated automatically. (This works for 720KB, 1.2MB, 1.44MB, and 2.88MB
floppies.)
-I hz Set the main CPU's frequency to hz Hz. This option does not work for all emulated
machine modes. It affects the way count/compare interrupts are faked to simulate
emulated time = real world time. If the guest operating system relies on RTC
interrupts instead of count/compare interrupts, then this option has no effect.
Setting the frequency to zero disables automatic synchronization of emulated time vs
real world time, and the count/compare system runs at a fixed rate.
-i Enable instruction trace, i.e. display disassembly of each instruction as it is
being executed.
-J Disable instruction combinations in the dynamic translator.
-j n Set the name of the kernel to n. When booting from an ISO9660 filesystem, the
emulator will try to boot using this file. (In some emulation modes, eg. DECstation,
this name is passed along to the boot program. Useful names are "bsd" for
OpenBSD/pmax, "vmunix" for Ultrix, or "vmsprite" for Sprite.)
-L tapdev
Enable tap networking using device 'tapdev', on systems that support it.
-M m Emulate m MBs of physical RAM. This overrides the default amount of RAM for the
selected machine type.
-N Display the number of executed instructions per second on average, at regular
intervals.
-n nr Set the number of processors in the machine, for SMP experiments.
Note 1: The emulator allocates quite a lot of virtual memory for per-CPU translation
tables. On 64-bit hosts, this is normally not a problem. On 32-bit hosts, this can
use up all available virtual userspace memory. The solution is to either run the
emulator on a 64-bit host, or limit the number of emulated CPUs to a reasonably low
number.
Note 2: SMP simulation is not working very well yet; multiple processors are
simulated, but synchronization between the processors does not map very well to how
real-world SMP systems work.
-O Force a "netboot" (tftp instead of disk), even when a disk image is present (for
DECstation, SGI, and ARC emulation).
-o arg Set the boot argument (mostly useful for DEC, ARC, or SGI emulation). Default arg
for DEC is "-a", for ARC/SGI it is "-aN", and for CATS it is "-A".
-p pc Add a breakpoint. pc can be a symbol, or a numeric value. (Remember to use the "0x"
prefix for hexadecimal values.)
-Q Disable the built-in (software-only) PROM emulation. This option is useful for
experimenting with running raw ROM images from real machines. The default behaviour
of the emulator is to "fake" certain PROM calls used by guest operating systems
(e.g. NetBSD), so that no real PROM image is needed.
-R Use a random bootstrap cpu, instead of CPU nr 0. (This option is only meaningful
together with the -n option.)
-r Dump register contents for every executed instruction.
-S Initialize emulated RAM to random data, instead of zeroes. This option is useful
when trying to trigger bugs in a program that occur because the program assumed that
uninitialized memory contains zeros. (Use with care.)
-s flags:filename
Gather statistics based on the current emulated program counter value, while the
program executes. The statistics is actually just a raw dump of all program counter
values in sequence, suitable for post-analysis with separate tools. Output is
appended to filename.
The flags should include one or more of the following type specifiers:
v Virtual. This means that the program counter value is used.
p Physical. This means that the physical address of where the program is
actually running is used.
i Instruction call. This type of statistics gathering is practically only
useful during development of the emulator itself. The output is a list of
addresses of instruction call functions (ic->f), which after some post-
processing can be used as a basis for deciding when to implement instruction
combinations.
The flags may also include the following optional modifiers:
d Disabled at startup.
o Overwrite the file, instead of appending to it.
Statistics gathering can be enabled/disabled at runtime by using the
"statistics_enabled = yes" and "statistics_enabled = no" debugger commands.
When gathering instruction statistics using the -s option, instruction combinations
are always disabled (i.e. an implicit -J flag is added to the command line).
-T Halt if the emulated program attempts to access non-existing memory.
-t Show a trace tree of all function calls being made.
-X Use X11. This option enables graphical framebuffers.
-Y n Scale down framebuffer windows by n x n times. This option is useful when emulating
a very large framebuffer, and the actual display is of lower resolution. If n is
negative, then there will be no scaledown, but emulation of certain graphic
controllers will be scaled up by -n times instead. E.g. Using -2 with VGA text mode
emulation will result in 80x25 character cells rendered in a 1280x800 window,
instead of the normal resolution of 640x400.
-Z n Set the number of graphics cards, for emulating a dual-head or tripple-head
environment. (Only for DECstation emulation so far.)
-z disp
Add disp as an X11 display to use for framebuffers.
General options:
-A Disable colorized output.
-c cmd Add cmd as a command to run before starting the simulation. A similar effect can be
achieved by using the -V option, and entering the commands manually.
-D Causes the emulator to skip a call to srandom(). This leads to somewhat more
deterministic behaviour than running without this option. However, if the emulated
machine has clocks or timer interrupt sources, or if user interaction is taking
place (e.g. keyboard input at irregular intervals), then this option is meaningless.
-G Enable colorized output. If the environment variable CLICOLOR is set, then this is
the default behavior.
-H Display a list of available CPU types and machine types. (Most of these don't work.
Please read the HTML documentation included in the gxemul distribution for details
on which modes that actually work.)
-h Display a list of all available command line options.
-k n Set the size of the dyntrans cache (per emulated CPU) to n MB. The default size is
96 MB.
-K Show the debugger prompt instead of exiting, when a simulation ends.
-q Quiet mode; this suppresses startup messages.
-V Start up in the interactive debugger, paused. If this option is used, -q is ignored.
This option also sets -K.
-v Increase verbosity (show more debug messages). This option can be used multiple
times.
-x Open up separate terminal windows for emulated serial ports. The default behaviour
is to open up new terminals when using configuration files with more than one
machine specified, or if X11 is enabled. When starting up a simple emulation session
with settings directly on the command line (or when using configuration files with a
single machine specification), and neither -X nor -x is used, then all output is
confined to the terminal that gxemul started in. The default terminal to use is
'xterm', but this can be overriden by the XTERM environment variable.
Configuration file startup:
@ configfile
Start an emulation based on the contents of configfile.
EXAMPLES
The following command will start NetBSD/pmax on an emulated DECstation 5000/200 (3MAX):
gxemul -e 3max -d nbsd_pmax.img
nbsd_pmax.img should be a raw disk image containing a bootable NetBSD/pmax filesystem.
The following command will start an emulation session based on settings in the configuration
file "mysession". The -v option tells gxemul to be verbose.
gxemul -v @mysession
If you have compiled the small Hello World program mentioned in the gxemul documentation,
the following command will start up an emulated test machine in "paused" mode:
gxemul -E testmips -V hello_mips
Paused mode means that you enter the interactive single-step debugger directly at startup,
instead of launching the Hello World program.
The paused mode is also what should be used when running "unknown" files for the first time
in the emulator. E.g. if you have a binary which you think is some kind of MIPS ROM image,
then you can try the following:
gxemul -vv -E baremips -V 0xbfc00000:image.raw
You can then use the single-stepping functionality of the built-in debugger to run the code
in the ROM image, to see how it behaves. Based on that, you can deduce what machine type it
was actually from (the baremips machine is not a real machine), and perhaps try again with
another emulation mode.
In general, however, real ROM images require much more emulation detail than GXemul
provides, so they can usually not run.
BUGS
There are many bugs. Some of the known bugs are mentioned in the TODO file in the gxemul
source distribution, some are marked as TODO in the source code itself.
gxemul is in general not cycle-accurate; it does not simulate individual pipe-line stages or
penalties caused by branch-prediction misses or cache misses, so it cannot be used for
accurate simulation of any actual real-world processor.
gxemul is in general not timing-accurate. Many emulation modes try to make the guest
operating system's clock run at the same speed as the host clock. However, the number of
instructions executed per clock tick can obviously vary, depending on the current CPU load
on the host.
gxemul is in general not guaranteed to be secure; when used as a virtual machine to run
untrusted code in the form of a guest OS, the untrusted code may be able to crash the
emulator, or due to bugs, take over the host.
AUTHOR
GXemul is Copyright (C) 2003-2021 Anders Gavare <gavare@gmail.com>
See http://gavare.se/gxemul/ for more information. For other Copyright messages, see the
corresponding parts of the source code and/or documentation.