So just to be clear, you have to boot up the physical machine with a kernel command-line argument to reserve some RAM for this to work? And the amount of RAM you reserve is for BAR memory? If you wanted multiple PCIem devices (can you do that?) you'd need to reserve RAM for each of them?
Hi! That's correct. We need a way to have a chunk of what Linux calls "Reserved" memory for the virtual BAR trick. Currently, PCIem only thinks about a single device (Since I first needed to have something that worked in order to check how feasible this all was), but there's planned support for multiple devices that can share a "Reserved" memory pool dynamically so you can have multiple BARs for multiple devices.
Hmmm.... Wondering if this could be eventually used to emulate a PCIe card using another device, like a RaspberryPi or something more powerful... Thinking the idea of a card you could stick in a machine, anything from a 1x to 16x slot, that emulates a network card (you could run VPN or other stuff on the card and offload it from the host) or storage (running something with enough power to run ZFS and a few disks, and show to the host as a single disk, allowing ZFS on devices that would not support it). but this is probably not something easy...
This kind of stuff is stupid easy on an OS like Plan 9 where you speak a single protocol: 9P. Ethernet devices are abstracted and served by the kernel as a file system explained in ether(3). Since it's all 9P the system doesn't care where the server is running; could be a local in-kernel/user-space server or remote server over ANY 2-way link including TCP, IL, PCIe link, RS232 port, SPI, USB, etc. This means you can mount individual pieces of hardware or networking stacks like ip(3), any 9P server, from other machines to a processes local namespace. Per-process name spaces let you customize the processes view of the file system and hence all its children allowing you to customize each and every programs resource view.
There is interest in getting 9front running on the Octeon chips. This would allow one to run anything they want on an Octeon card (Plan 9 cross platform is first class) so one could boot the card using the hosts root file system, write and test a program on the host, change the objtype env variable to mips/arm, build the binary for the Octeon and then run it on the Octeon using rcpu (like running a command remotely via ssh.) All you need is a working kernel on the Octeon and a host kernel driver and the rest is out of the box.
Hi! Author here! You can technically offload the transactions the real driver on your host does to wherever you want really. PCI is very delay-tolerant and it usually negotiates with the device so I see not much of an issue doing that proven that you can efficiently and performantly manage the throughput throughout the architecture. The thing that kinda makes PCIem special is that you are pretty much free to do whatever you want with the accesses the driver does, you have total freedom. I have made a simple NVME controller (With a 1GB drive I basically malloc'd) which pops up on the local PCI bus (And the regular Linux's nvme block driver attaches to it just fine). You can format it, mount it, create files, folders... it's kinda neat. I also have a simple dumb rasteriser that I made inside QEMU that I wanted to write a driver for, but since it doesn't exist, I used PCIem to help me redirect the driver writes to the QEMU instance hosting the card (Thus was able to run software-rendered DOOM, OpenGL 1.X-based Quake and Half-Life ports).
That fascinates me. Intel deserves a lot of credit for PCI. They built in future proofing for use cases that wouldn't emerge for years, when their bread and butter was PC processors and peripheral PC chips, and they could have done far less. The platform independence and general openness (PCI-SIG) are also notable for something that came from 1990 Intel.
You can definitely proxy the transactions wherever you may see fit, but I'm not completely sure how that'd work.
As in, PCIem is going to populate the bus with virtually the same card (At least, in terms of capabilities, vendor/product id... and whanot) so I don't see how you'd then add another layer of indirection that somehow can transparently process the unfiltered transaction stream PCIem provides to it to an actual PCIe card on the bus. I feel like there's many colliding responsabilities in this.
I would instead suggest to have some sort of behavioural model (As in, have a predefined set of data to feed from/to) and have PCIem log all the accesses your real driver does. That way the driver would have enough infrastructure not to crash and at the same time you'd get the transport layer information.
Depends on the use-case. For the standard hardware-accelerated guest GPU in virtualized environments, there's already QEMU's virtio-gpu device.[1]
For "carving up" there are technologies like SR-IOV (Single Root I/O Virtualization).[2]
For advanced usage, like prototyping new hardware (host driver), you could use PCIem to emulate a not-yet-existing SR-IOV-capable GPU. This would allow you to develop and test the host-side driver (the one that manages the VFs) in QEMU without needing the actual hardware.
Another advanced use-case could be a custom vGPU solution: Instead of SR-IOV, you could try to build a custom paravirtualized GPU from scratch. PCIem would let you design the low-level PCIe interface for this new device, while you write a corresponding driver on the guest. This would require significant effort but it'd provide you complete control.
As in, getting the PCIem shim to show up on a VM (Like, passthrough)? If that's what you're asking for, then; it's something being explored currently. Main challenges come from the subsystem that has to "unbind" the device from the host and do the reconfiguration (IOMMU, interrupt routing... and whatnot). But from my initial gatherings, it doesn't look like an impossible task.
Passthru or time sharing? The latter is difficult because you need something to manage the timeslices and enforce process isolation. I'm no expert but I understand it to be somewhere between nontrivial and not realistic without GPU vendor cooperation.
Note that the GPU vendors all deliberately include this feature as part of their market segmentation.
It would need to implement a few dozen ioctls, correctly stub the kernel module in guests, do a probably memory-safe assignment of GPU memory to guest, and then ultimately map that info to BAR/MSI-X semantics of a real kernel module. You could get VFIO pretty fast for a full start by correctly masking LTR bits, but to truly make it free you'd need a user space io_uring broker that had survived hundreds of millions of adversarial fuzz runs because there's only so fast the firmware blob can run even if it's preloaded into initramfs.
Serious work, detail intense, but not so different in design to e.g. Carmack's Trinity engine. Doable.
Indeed, and even then, there's some sw-hw-codesign stuff that kinda helps you do what PCIem does but it's usually really pricey; so I kinda thought it'd be a good thing to have for free.
PCIe prototyping is usually not something super straightforward if you don't want to pay hefty sums IME.
The "DMA cards" used for video game cheating are generic PCIe cards and (at least the one I got) comes with open documentation (schematics, example projects etc).
Direct Memory Access (DMA) via PCI-e bypasses anti-cheat in the OS because the OS doesn't see the call to read or write the memory. There's no process to spy on, weird drivers, system calls, etc. You can imagine that maybe the anticheat could detect writes that perform a cheat by this method, but it has zero chance of detecting a wallhack style cheat that just reads memory. This is getting to be less relevant with modern OSs, though. Window 11 has IOMMU which only allows DMA to a given memory region defined per device. I think it should be impossible to do this on win11.
Something like the stm32mp2 series of MCUs can run Linux and act as a PCIe endpoint you can control from a kernel module on the MCU. So you can program an arbitrary PCIe device that way (although it won’t be setting any speed records, and I think the PHY might be limited to PCIe 1x)
interesting... x1 would too slow for large amounts of storage, but as a test, a couple small SSDs could potentially be workable... sounds like im doing some digging...
There are many workloads that would not be able to saturate even an x1 link, it all depends on how much of the processing can be done internally to whatever lives on the other side of that link. Raw storage and layer-to-layer communications in AI applications are probably the worst cases but there are many more that are substantially better than that.
Indeed, the project has gone through a few iterations already (It was first a monolithic kernel module that required a secondary module to call into the API and whatnot). I've went towards a more userspace-friendly usage mainly so that you can iterate your changes much, much faster. Creating the synthetic PCI device is as easy as opening the userspace shim you program, it'll then appear on your bus. When you want to test new changes, you close the shim normally (Effectively removing it from the bus) and you can do this process as many times as needed.
Hi, thanks. That's almost it. The remaining problem is just how to tie it together (where do I put the handle_mmio_read pointer or which event should it be handled in?)
PCIEM_EVENT_MMIO_READ is defined but not used anywhere in the codebase
Hi! Sorry, this is an issue on my side; I forgot to update the documentation's example with the latest changes.
You basically have the kernel eventfd notify you about any access triggered (Based on your configuration), so from userspace, you have the eventfd and then you mmap the shared lock-less ring buffer that actually contains the events PCIem notifies (So you don't end up busy polling).
You basically mmap a struct pciem_shared_ring where you'll have your usual head/tail pointers.
From then on, on your main, you'd have a select() or a poll() for the eventfd; when PCIem notifies the userspace you'd check head != tail (Which means there are events to process) and you can basically do:
Could you explain in layman terms how it would help with developing PCIE hardware / drivers? I can immediately imagine something like writing more robust unit tests and maybe developing barebones drivers before you get access to actual hardware, but that's where my imagination runs out of fuel.
Sure! Let's say you (Or the company you work for) are trying to develop an NVME controller card, or a RAID card, or a NIC...
Usually, without actual silicon, you are pretty limited on what you can do in terms of anticipating the software that'll run.
What if you want to write a driver for it w/o having to buy auxiliary boards that act as your card?
What happens if you already have a driver and want to do some security testing on it but don't have the card/don't want to use a physical one for any specific reason (Maybe some UB on the driver pokes at some register that kills the card? Just making disastrous scenarios to prove the point hah).
What if you want to add explicit failures to the card so that you can try and make the driver as tamper-proof and as fault-tolerant as possible (Think, getting the PCI card out of the bus w/o switching the computer off)?
Testing your driver functionally and/or behaviourally on CI/CD on any server (Not requiring the actual card!)?
There's quite a bunch of stuff you can do with it, thanks to being in userspace means that you can get as hacky-wacky as you want (Heck, I have a dumb-framebuffer-esque and OpenGL 1.X capable QEMU device I wanted to write a driver for fun and I used PCIem to forward the accesses to it).
Tangential question: PCIe is a pretty future-proof technology to learn/invest in,
right? As in,
it is very unlikely to become obsolete in the next 5-10 years (like USB)?
Neither of those is going to be obsolete in 5 years. Might get rebadged and a bunch of extensions, but there's such a huge install base that rapid change is unlikely. Neither Firewire nor Thunderbolt unseated USB.
USB4 is the ~third USB protocol stack though (USB1/2 being basically the same iirc, USB3 being a completely separate protocol that neither logically nor physically interacts with USB1/2 at all), heavily based on Thunderbolt to the point of backwards compatibility.
A very noticeable feature is that USB4 can tunnel USB3, which means it works like an USB hub, instead of an external PCIe USB controller (like in Thunderbolt). USB2 is still just physically separately transported over the D+/D- pins.
USB4 actually provides both USB 1/2 and 3 tunnelling, but it's incorrect to say it behaves like a hub because it involves needing an appropriate endpoint on the other end. Effectively a virtual cable, iirc, though there are at least two different mechanisms.
PCIe is probably the most future proof technology we have right now. Even if it is upheaveled at the hardware level, from the software perspective it just exposes a device's arbitrary registers to some memory mapped location. Software drivers for PCIe devices will continue to work the same.
Hmm. What's the current maths on distance vs edge rate vs transceiver latency vs power consumption on when that would be a benefit? Not to mention how much of a pain it is to have good optical connectors.
I wouldn't expect that to be mainstream until after optical networking becomes more common, and for consumer hardware that's very rare (apart from their modem).
How could you possibly know exactly what protocol they'd be using for the potential future optical PCIe connection? Your guess is as good as anyone's, no?
Curious what you mean by learning? Learning about TLPs? Learning about FPGA DMA Engines like XDMA? Learning about PCIe switches / retimers? Learning about `lspci`?
Nothing specific! I learned how to implement USB(-C) because there was some specific hardware I wanted to create. I could see the same thing happening with PCIe in future. With USB its longevity was fairly obvious to me, with PCIe I’m not well informed. Thanks for giving me some acronyms to explore!
There is interest in getting 9front running on the Octeon chips. This would allow one to run anything they want on an Octeon card (Plan 9 cross platform is first class) so one could boot the card using the hosts root file system, write and test a program on the host, change the objtype env variable to mips/arm, build the binary for the Octeon and then run it on the Octeon using rcpu (like running a command remotely via ssh.) All you need is a working kernel on the Octeon and a host kernel driver and the rest is out of the box.
[0] https://www.psdevwiki.com/ps4/PCIe
[1] https://fail0verflow.com/blog/2016/console-hacking-2016-post...
That fascinates me. Intel deserves a lot of credit for PCI. They built in future proofing for use cases that wouldn't emerge for years, when their bread and butter was PC processors and peripheral PC chips, and they could have done far less. The platform independence and general openness (PCI-SIG) are also notable for something that came from 1990 Intel.
As in, PCIem is going to populate the bus with virtually the same card (At least, in terms of capabilities, vendor/product id... and whanot) so I don't see how you'd then add another layer of indirection that somehow can transparently process the unfiltered transaction stream PCIem provides to it to an actual PCIe card on the bus. I feel like there's many colliding responsabilities in this.
I would instead suggest to have some sort of behavioural model (As in, have a predefined set of data to feed from/to) and have PCIem log all the accesses your real driver does. That way the driver would have enough infrastructure not to crash and at the same time you'd get the transport layer information.
For "carving up" there are technologies like SR-IOV (Single Root I/O Virtualization).[2]
For advanced usage, like prototyping new hardware (host driver), you could use PCIem to emulate a not-yet-existing SR-IOV-capable GPU. This would allow you to develop and test the host-side driver (the one that manages the VFs) in QEMU without needing the actual hardware.
Another advanced use-case could be a custom vGPU solution: Instead of SR-IOV, you could try to build a custom paravirtualized GPU from scratch. PCIem would let you design the low-level PCIe interface for this new device, while you write a corresponding driver on the guest. This would require significant effort but it'd provide you complete control.
[1] https://qemu.readthedocs.io/en/v8.2.10/system/devices/virtio...
[2] https://en.wikipedia.org/wiki/Single-root_input/output_virtu...
Passthru or time sharing? The latter is difficult because you need something to manage the timeslices and enforce process isolation. I'm no expert but I understand it to be somewhere between nontrivial and not realistic without GPU vendor cooperation.
Note that the GPU vendors all deliberately include this feature as part of their market segmentation.
Serious work, detail intense, but not so different in design to e.g. Carmack's Trinity engine. Doable.
The other existing solution to this is FPGA cards: https://www.fpgadeveloper.com/list-of-fpga-dev-boards-for-pc... - note the wide spread in price. You then also have to deal with FPGA tooling. The benefit is much better timing.
PCIe prototyping is usually not something super straightforward if you don't want to pay hefty sums IME.
[1] https://www.expether.org/products.html
Seems unlikely you'd emulate a real PCIe card in software because PCIe is pretty high-speed.
https://mikrotik.com/product/ccr2004_1g_2xs_pcie
and G-RAID
Something like just a single BAR with a register that printfs whatever is written
Hopefully this is what you're searching for!
PCIEM_EVENT_MMIO_READ is defined but not used anywhere in the codebase
You basically have the kernel eventfd notify you about any access triggered (Based on your configuration), so from userspace, you have the eventfd and then you mmap the shared lock-less ring buffer that actually contains the events PCIem notifies (So you don't end up busy polling).
You basically mmap a struct pciem_shared_ring where you'll have your usual head/tail pointers.
From then on, on your main, you'd have a select() or a poll() for the eventfd; when PCIem notifies the userspace you'd check head != tail (Which means there are events to process) and you can basically do:
struct pciem_event *event = &event_ring->events[head]; atomic_thread_fence(memory_order_acquire); if (event->type == PCIEM_EVENT_MMIO_WRITE) handle_mmio_read(...);
And that's it, don't forget to update the head pointer!
I'll go and update the docs now. Hopefully this clears stuff up!
Usually, without actual silicon, you are pretty limited on what you can do in terms of anticipating the software that'll run.
What if you want to write a driver for it w/o having to buy auxiliary boards that act as your card? What happens if you already have a driver and want to do some security testing on it but don't have the card/don't want to use a physical one for any specific reason (Maybe some UB on the driver pokes at some register that kills the card? Just making disastrous scenarios to prove the point hah).
What if you want to add explicit failures to the card so that you can try and make the driver as tamper-proof and as fault-tolerant as possible (Think, getting the PCI card out of the bus w/o switching the computer off)?
Testing your driver functionally and/or behaviourally on CI/CD on any server (Not requiring the actual card!)?
There's quite a bunch of stuff you can do with it, thanks to being in userspace means that you can get as hacky-wacky as you want (Heck, I have a dumb-framebuffer-esque and OpenGL 1.X capable QEMU device I wanted to write a driver for fun and I used PCIem to forward the accesses to it).
I wouldn't expect that to be mainstream until after optical networking becomes more common, and for consumer hardware that's very rare (apart from their modem).
In fact, "zero~th generation" of thunderbolt used optical link, too. Also both thunderbolt and DisplayPort reuse a lot of common elements from PCI-E