Difference between revisions of "HOWTO-Debug-Endian-Issues"
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#* Examples include the [https://www.raptorcs.com/content/BK1B01/intro.html Raptor Blackbird™] workstation. It is a powerful system which can run up-to-date Linux/BSD distributions, both in little-endian and big-endian modes. | #* Examples include the [https://www.raptorcs.com/content/BK1B01/intro.html Raptor Blackbird™] workstation. It is a powerful system which can run up-to-date Linux/BSD distributions, both in little-endian and big-endian modes. | ||
#* Unfortunately, it's a pricey niche system, and there's no guarantee that big-endian OS options will be maintained for long. | #* Unfortunately, it's a pricey niche system, and there's no guarantee that big-endian OS options will be maintained for long. | ||
#* NetBSD also allows [https://mail-index.netbsd.org/port-arm/2020/12/03/msg007117.html running a Raspberry Pi in big-endian mode], but this hasn't been tested for ScummVM development yet. | |||
# Running a native, older big-endian development system: | # Running a native, older big-endian development system: | ||
#* Examples include buying an older G4 or G5 Apple PowerPC system, or an older SPARC64 Sun station<ref>Some MIPS and ARM boards also exist, but their quality can vary a lot, and although the MIPS and ARM architectures are theoretically bi-endian, in practice these development boards often only run in little-endian mode, nowadays. They can be useful for strict-alignment testing, though.</ref>. They can often be bought second hand at very reasonable prices. | #* Examples include buying an older G4 or G5 Apple PowerPC system, or an older SPARC64 Sun station<ref>Some MIPS and ARM boards also exist, but their quality can vary a lot, and although the MIPS and ARM architectures are theoretically bi-endian, in practice these development boards often only run in little-endian mode, nowadays. They can be useful for strict-alignment testing, though (but <code>-fsanitize=alignment -DSCUMM_NEED_ALIGNMENT</code> in UBSan on your regular desktop will also catch a lot of these issues).</ref>. They can often be bought second-hand at very reasonable prices. | ||
#* However, running a modern development environment on them in getting harder (but not impossible), because the big-endian desktop ecosystem receives less and less maintenance, so things often tend to break. G5 systems (in particular) also require careful maintenance and can be very power-hungry. | #* However, running a modern development environment on them in getting harder (but not impossible), because the big-endian desktop ecosystem receives less and less maintenance, so things often tend to break. G5 systems (in particular) also require careful maintenance and can be very power-hungry. | ||
# '''Emulating a big-endian development system from your regular development machine''': | # '''Emulating a big-endian development system from your regular development machine''': | ||
#* Any reasonably powerful desktop system should be able to emulate a big-endian architecture, thanks to [https://www.qemu.org QEMU]. | #* Any reasonably powerful desktop system should be able to emulate a big-endian architecture, thanks to [https://www.qemu.org QEMU]. | ||
#* The main drawback is that this currently requires running some older/unmaintained Linux distributions, and, as of late 2022, | #* The main drawback is that this currently requires running some older/unmaintained Linux distributions, and, as of late 2022, graphics acceleration support is missing. Since this is emulation (and not virtualization), there is also a noticeable (but usually tolerable) performance impact. | ||
This howto focuses on the last option, since it is the most accessible one, and it's still a way of fixing the majority of endianness issues we encounter. | This howto focuses on the last option, since it is the most accessible one, and it's still a way of fixing the majority of endianness issues we encounter. | ||
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== Linux big-endian PowerPC emulation with QEMU == | == Linux big-endian PowerPC emulation with QEMU == | ||
The current reference VM is a pre-configured Debian 8.11 PowerPC system<ref>Modern versions of Debian are actually still built for big-endian PowerPC, but it's not a ''release'' architecture anymore, which means that it's only available through Debian ''unstable''. Debian unstable is harder to maintain than a stable release, and bugs/reliability issues often appear, especially on non-mainstream architectures. This is why we're sticking with a Debian 8 VM for now.</ref>. It has been modified to feature an updated C++11 toolchain (GCC 5.5.0) | The current reference VM is a pre-configured Debian 8.11 PowerPC system<ref>Modern versions of Debian are actually still built for big-endian PowerPC, but it's not a ''release'' architecture anymore, which means that it's only available through Debian ''unstable''. Debian unstable is harder to maintain than a stable release, and bugs/reliability issues often appear (e.g. Valgrind has been having PPC SDL compatibility problems for years, GRUB installation being much less reliable than the older Yaboot…), especially on non-mainstream architectures. This is why we're sticking with a Debian 8 VM for now.</ref>. It has been modified to feature an updated C++11 toolchain (GCC 5.5.0). | ||
Some important notes: | Some important notes: | ||
* Security support updates have been discontinued for Debian 8 in late 2018. Older cryptographic ciphers and certificates (such as in TLS or SSH) in the base system may also cause various issues. For this reason, this VM should only be run ''on a local, trusted environment''. | * Security support updates have been discontinued for Debian 8 in late 2018. Older cryptographic ciphers and certificates (such as in TLS or SSH) in the base system may also cause various issues. For this reason, this VM should only be run ''on a local, trusted environment''. | ||
* | * 3D games will have a slow framerate, since QEMU only provides a limited, unaccelerated framebuffer for PPC<ref>Using the <code>-device ati-vga</code> QEMU option may bring an improvement at some point, but it's experimental and currently broken, especially with the old Debian 8 kernel.</ref>. | ||
* '''The bigger your host CPU clock rate, the better''': a 4 GHz CPU will bring | * '''The bigger your host CPU clock rate, the better''': a 4 GHz CPU will bring some improvement over a 3 GHz CPU, which is itself much better than a 2 GHz CPU, and so on<ref>For reference, a full build of ScummVM with only the SCUMM engine takes around 26 minutes in QEMU on an Intel i7 or an Apple M1, while the same build on a native PowerPC G4 7447A takes 13 minutes (all single-threaded).</ref>. Note that QEMU emulation is mostly single-threaded, so having many CPU cores isn't really useful for this. | ||
=== Starting the VM === | === Starting the VM === | ||
The VM image is quite large, so ask the rest of the team for its URL. | |||
Once you've downloaded and extracted the VM archive, you'll need to install QEMU for your system with your usual package manager (Windows builds are available [https://qemu.weilnetz.de/w64/ here]). | Once you've downloaded and extracted the VM archive, you'll need to install QEMU for your system with your usual package manager (Windows builds are available [https://qemu.weilnetz.de/w64/ here]). | ||
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-m 2048 ^ | -m 2048 ^ | ||
-g 1024x750x32 ^ | -g 1024x750x32 ^ | ||
-device ES1370 ^ | |||
-no-reboot ^ | -no-reboot ^ | ||
-boot c ^ | -boot c ^ | ||
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-m 2048 \ | -m 2048 \ | ||
-g 1024x750x32 \ | -g 1024x750x32 \ | ||
-device ES1370 \ | |||
-no-reboot \ | -no-reboot \ | ||
-boot c \ | -boot c \ | ||
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* <code>-m 2048</code>: the amount of memory given to the VM, in megabytes. Using more than 2 GiB is not possible in QEMU at the moment. Moreover, this is a 32-bit system and it wouldn't change the VM performance much. | * <code>-m 2048</code>: the amount of memory given to the VM, in megabytes. Using more than 2 GiB is not possible in QEMU at the moment. Moreover, this is a 32-bit system and it wouldn't change the VM performance much. | ||
* <code>-g 1024x750x32</code>: VM screen resolution and bit depth. You can try suiting it to your needs, but strange results may happen with some resolutions, and, since there's no graphics acceleration, making the window too big may worsen performance. Reducing the bit | * <code>-g 1024x750x32</code>: VM screen resolution and bit depth. You can try suiting it to your needs, but strange results may happen with some resolutions, and, since there's no graphics acceleration, making the window too big may worsen performance. Reducing the bit depth from <code>32</code> to <code>24</code> bits could help in some cases. | ||
* <code>-cdrom /path/to/host/game.iso</code>: this is a quick way of sharing some game or development files from your host to the VM (it will then appear in its file manager). Other file-sharing options between the two systems are possible ([[#Various options for a more convenient setup|see below]]). | * <code>-cdrom /path/to/host/game.iso</code>: this is a quick way of sharing some game or development files from your host to the VM (it will then appear in its file manager). Other file-sharing options between the two systems are possible ([[#Various options for a more convenient setup|see below]]). | ||
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==== Keyboard layout ==== | ==== Keyboard layout ==== | ||
The keyboard layout can be changed in Applications Menu > Settings > Keyboard > Layout, or with <code>setxkbmap</code> (see also https://wiki.debian.org/Keyboard), if necessary. Default credentials are <code>scummvm</code> / <code>scummvm</code>, since this is just a local development environment. | |||
=== Building ScummVM in the Debian PPC VM === | === Building ScummVM in the Debian PPC VM === | ||
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==== Build dependencies ==== | ==== Build dependencies ==== | ||
For development purposes, you may want to install the following set of tools, if | For development purposes, you may want to install the following set of tools, if they are useful for your use case (note that Valgrind is quite large, though): | ||
<syntaxhighlight lang="shell"> | <syntaxhighlight lang="shell"> | ||
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Cloning the repository and compiling ScummVM is done through the [[Compiling_ScummVM/GCC|usual means]], with some important points: | Cloning the repository and compiling ScummVM is done through the [[Compiling_ScummVM/GCC|usual means]], with some important points: | ||
* Everything is going to be slower than your usual environment | * Everything is going to be slower than your usual environment. | ||
* Since QEMU emulation is single-threaded, there is no point is running <code>make</code> with any <code>-j</code> flag for parallel compilation. | * Since QEMU emulation is single-threaded, there is no point is running <code>make</code> with any <code>-j</code> flag for parallel compilation. | ||
* It is highly suggested to only enable the engines and features that you need for your test, e.g. <code>./configure --disable-detection-full --disable-all-engines --enable-engine=tinsel --disable-lua --disable-tinygl --disable-cloud --disable-hq-scalers --disable-optimizations --enable-debug</code> will save you a lot of time if you're only interested in testing the Tinsel engine. | * It is highly suggested to only enable the engines and features that you need for your test, e.g. <code>./configure --disable-detection-full --disable-all-engines --enable-engine=tinsel --disable-lua --disable-tinygl --disable-cloud --disable-hq-scalers --disable-optimizations --enable-debug</code> will save you a lot of time if you're only interested in testing the Tinsel engine. | ||
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=== Various options for a more convenient setup === | === Various options for a more convenient setup === | ||
==== Unmuting audio ==== | |||
If you can't hear any sound, make sure that your QEMU run script has the <code>-device ES1370</code> option. | |||
It's also possible that the emulated audio card is muted inside the Linux VM, for some reason. To fix this, start the Applications > Multimedia > Audio Mixer program and check that no main output is muted (you can also run the <code>alsamixer</code> program in the Terminal and type <code>M</code> and then <code>Esc</code> to unmute the main output). | |||
==== Modern IDE integration ==== | ==== Modern IDE integration ==== | ||
Line 143: | Line 152: | ||
== Debugging for Other Architectures == | == Debugging for Other Architectures == | ||
The instructions above should be valid for emulation and debugging of other uncommon machine architectures e.g. MIPS, provided that QEMU supports that architecture e.g. use qemu-system-mips, rather than ppc, and a Linux distribution or other Unix is available for that architecture as | The instructions above should be valid for emulation and debugging of other uncommon machine architectures e.g. MIPS, provided that QEMU supports that architecture e.g. use qemu-system-mips, rather than ppc, and a Linux distribution or other Unix is available for that architecture as an installation CD ISO image. | ||
However, there are a few architectures which QEMU does not support, notably [https://en.wikipedia.org/wiki/SuperH SH]. However, there is another general purpose CPU/machine emulator called [http://gxemul.sourceforge.net/ GXemul] which does support this and some other more esoteric platforms. This is less supported than QEMU, but this procedure should be possible with some modifications. Any notes on this would be gratefully received by the team. | However, there are a few architectures which QEMU does not support, notably [https://en.wikipedia.org/wiki/SuperH SH]. However, there is another general purpose CPU/machine emulator called [http://gxemul.sourceforge.net/ GXemul] which does support this and some other more esoteric platforms. This is less supported than QEMU, but this procedure should be possible with some modifications. Any notes on this would be gratefully received by the team. |
Latest revision as of 20:33, 20 September 2024
Most desktop development machines being little-endian nowadays, proper endianness testing and debugging is becoming difficult.
The PS3, Wii and AmigaOS ports are some examples of systems running in big-endian mode and where endianness issues show up from time to time. Unfortunately, these ports are not very well suited for efficient iterative development and debugging. Apart from auditing the codebase for known non-portable code constructs, without a working test machine to replicate the issue and debug with, fixing these bugs can prove impossible.
Various solutions for working from a big-endian development environment exist, though:
- Running a native, modern and powerful big-endian development system:
- Examples include the Raptor Blackbird™ workstation. It is a powerful system which can run up-to-date Linux/BSD distributions, both in little-endian and big-endian modes.
- Unfortunately, it's a pricey niche system, and there's no guarantee that big-endian OS options will be maintained for long.
- NetBSD also allows running a Raspberry Pi in big-endian mode, but this hasn't been tested for ScummVM development yet.
- Running a native, older big-endian development system:
- Examples include buying an older G4 or G5 Apple PowerPC system, or an older SPARC64 Sun station[1]. They can often be bought second-hand at very reasonable prices.
- However, running a modern development environment on them in getting harder (but not impossible), because the big-endian desktop ecosystem receives less and less maintenance, so things often tend to break. G5 systems (in particular) also require careful maintenance and can be very power-hungry.
- Emulating a big-endian development system from your regular development machine:
- Any reasonably powerful desktop system should be able to emulate a big-endian architecture, thanks to QEMU.
- The main drawback is that this currently requires running some older/unmaintained Linux distributions, and, as of late 2022, graphics acceleration support is missing. Since this is emulation (and not virtualization), there is also a noticeable (but usually tolerable) performance impact.
This howto focuses on the last option, since it is the most accessible one, and it's still a way of fixing the majority of endianness issues we encounter.
Linux big-endian PowerPC emulation with QEMU
The current reference VM is a pre-configured Debian 8.11 PowerPC system[2]. It has been modified to feature an updated C++11 toolchain (GCC 5.5.0).
Some important notes:
- Security support updates have been discontinued for Debian 8 in late 2018. Older cryptographic ciphers and certificates (such as in TLS or SSH) in the base system may also cause various issues. For this reason, this VM should only be run on a local, trusted environment.
- 3D games will have a slow framerate, since QEMU only provides a limited, unaccelerated framebuffer for PPC[3].
- The bigger your host CPU clock rate, the better: a 4 GHz CPU will bring some improvement over a 3 GHz CPU, which is itself much better than a 2 GHz CPU, and so on[4]. Note that QEMU emulation is mostly single-threaded, so having many CPU cores isn't really useful for this.
Starting the VM
The VM image is quite large, so ask the rest of the team for its URL.
Once you've downloaded and extracted the VM archive, you'll need to install QEMU for your system with your usual package manager (Windows builds are available here).
QEMU options
Then, create one of the following scripts in the same directory as the VM image.
run.bat
for Windows:
"%ProgramFiles%\qemu\qemu-system-ppcw.exe" ^
-L pc-bios ^
-M mac99,via=pmu ^
-m 2048 ^
-g 1024x750x32 ^
-device ES1370 ^
-no-reboot ^
-boot c ^
-prom-env "boot-device=hd:,\yaboot" ^
-prom-env "boot-args=conf=hd:,\yaboot.conf" ^
-hda hda-debian8-scummvm-ppc.qcow2
run.sh
for macOS and other Unix-like systems:
#!/bin/sh
qemu-system-ppc \
-L pc-bios \
-M mac99,via=pmu \
-m 2048 \
-g 1024x750x32 \
-device ES1370 \
-no-reboot \
-boot c \
-prom-env 'boot-device=hd:,\yaboot' \
-prom-env 'boot-args=conf=hd:,\yaboot.conf' \
-hda hda-debian8-scummvm-ppc.qcow2
Most options should be kept as-is, but you may want to tweak the following ones:
-m 2048
: the amount of memory given to the VM, in megabytes. Using more than 2 GiB is not possible in QEMU at the moment. Moreover, this is a 32-bit system and it wouldn't change the VM performance much.-g 1024x750x32
: VM screen resolution and bit depth. You can try suiting it to your needs, but strange results may happen with some resolutions, and, since there's no graphics acceleration, making the window too big may worsen performance. Reducing the bit depth from32
to24
bits could help in some cases.-cdrom /path/to/host/game.iso
: this is a quick way of sharing some game or development files from your host to the VM (it will then appear in its file manager). Other file-sharing options between the two systems are possible (see below).
Booting Debian ppc
Then, run that script. A QEMU window should appear, and a Linux system should boot. Wait until a full XFCE desktop appears (this may take a couple of minutes, depending on your host system performance).
Keyboard layout
The keyboard layout can be changed in Applications Menu > Settings > Keyboard > Layout, or with setxkbmap
(see also https://wiki.debian.org/Keyboard), if necessary. Default credentials are scummvm
/ scummvm
, since this is just a local development environment.
Building ScummVM in the Debian PPC VM
Open a terminal by clicking on Applications Menu > Terminal Emulator. The password for any sudo
command is also scummvm
.
If you need to shut down the VM at any point, click on Applications Menu > Log out > Shut Down, and make sure that the VM is completely halted before closing the QEMU window.
Don't expect the included web browser to be remotely useful for anything.
Build dependencies
For development purposes, you may want to install the following set of tools, if they are useful for your use case (note that Valgrind is quite large, though):
sudo apt-get install vim tmux ccache ddd valgrind
Compilers, GNU Make, GDB, Git and SDL development files are already installed in this image. The APT package manager is also pre-configured to use the older Debian 8 archive files. Some Debian 8 GPG keys have expired since then, though, so APT will print some security warnings.
Building
Cloning the repository and compiling ScummVM is done through the usual means, with some important points:
- Everything is going to be slower than your usual environment.
- Since QEMU emulation is single-threaded, there is no point is running
make
with any-j
flag for parallel compilation. - It is highly suggested to only enable the engines and features that you need for your test, e.g.
./configure --disable-detection-full --disable-all-engines --enable-engine=tinsel --disable-lua --disable-tinygl --disable-cloud --disable-hq-scalers --disable-optimizations --enable-debug
will save you a lot of time if you're only interested in testing the Tinsel engine. - Some tools such as Valgrind become unbearably slow when emulated.
--enable-asan
is available, but its implementation is from 2015. - The older 1.2 branch of SDL is used, since rendering is done through an unaccelerated framebuffer at the moment, and SDL1.2 is a better option than SDL2 for this case.
Testing
You can then run the resulting scummvm
binary, while making sure that some ScummVM options such as Global Options > Paths > Extra Path are properly configured for development. Then, add your game, and see how it behaves on big-endian! Run gdb
on it if necessary, make the appropriate code changes, and iterate with make
until it works as expected.
Various options for a more convenient setup
Unmuting audio
If you can't hear any sound, make sure that your QEMU run script has the -device ES1370
option.
It's also possible that the emulated audio card is muted inside the Linux VM, for some reason. To fix this, start the Applications > Multimedia > Audio Mixer program and check that no main output is muted (you can also run the alsamixer
program in the Terminal and type M
and then Esc
to unmute the main output).
Modern IDE integration
If you need a powerful and user-friendly IDE inside the VM, you won't have many options, because this is an old and limited Linux system. If you don't like console text editors, you're probably out of luck (unless you want to try sudo apt-get install codeblocks
). One option could be to work from your usual IDE on your regular desktop, and share its files with the VM.
Sharing resources
The VM can access its host system via the 10.0.2.2
IP address (useful if you want to share files from the host to the VM with an NFS, SMB, HTTP, or FTP server).
If you just need to access the VM through SSH:
- add the
-nic user,hostfwd=tcp::60022-:22
option to yourqemu-system-ppc
script - inside the VM, install the OpenSSH server:
sudo apt-get install openssh-server
- from your host, run:
ssh -p 60022 scummvm@127.0.0.1
. SSH access means that you can alsorsync
and so on.
Connecting through VNC is also possible, but it's probably not going to be a great experience.
Reclaiming some storage space
If you need a bit more storage space inside the VM, some big and unnecessary tools can be removed:
sudo apt-get remove --purge 'vlc.*' 'libreoffice.*' 'gimp.*' 'firefox.*' 'iceweasel.*'
sudo apt-get autoremove --purge
Debugging for Other Architectures
The instructions above should be valid for emulation and debugging of other uncommon machine architectures e.g. MIPS, provided that QEMU supports that architecture e.g. use qemu-system-mips, rather than ppc, and a Linux distribution or other Unix is available for that architecture as an installation CD ISO image.
However, there are a few architectures which QEMU does not support, notably SH. However, there is another general purpose CPU/machine emulator called GXemul which does support this and some other more esoteric platforms. This is less supported than QEMU, but this procedure should be possible with some modifications. Any notes on this would be gratefully received by the team.
Notes
- ↑ Some MIPS and ARM boards also exist, but their quality can vary a lot, and although the MIPS and ARM architectures are theoretically bi-endian, in practice these development boards often only run in little-endian mode, nowadays. They can be useful for strict-alignment testing, though (but
-fsanitize=alignment -DSCUMM_NEED_ALIGNMENT
in UBSan on your regular desktop will also catch a lot of these issues). - ↑ Modern versions of Debian are actually still built for big-endian PowerPC, but it's not a release architecture anymore, which means that it's only available through Debian unstable. Debian unstable is harder to maintain than a stable release, and bugs/reliability issues often appear (e.g. Valgrind has been having PPC SDL compatibility problems for years, GRUB installation being much less reliable than the older Yaboot…), especially on non-mainstream architectures. This is why we're sticking with a Debian 8 VM for now.
- ↑ Using the
-device ati-vga
QEMU option may bring an improvement at some point, but it's experimental and currently broken, especially with the old Debian 8 kernel. - ↑ For reference, a full build of ScummVM with only the SCUMM engine takes around 26 minutes in QEMU on an Intel i7 or an Apple M1, while the same build on a native PowerPC G4 7447A takes 13 minutes (all single-threaded).