Bill Mills <bill.mi...@linaro.org> writes: > Hi Markus, > > On 4/23/24 6:39 AM, Markus Armbruster wrote: >> Gustavo Romero <gustavo.rom...@linaro.org> writes: >> >>> Hi Markus, >>> >>> Thanks for interesting in the ivshmem-flat device. >>> >>> Bill Mills (cc:ed) is the best person to answer your question, >>> so please find his answer below. >>> >>> On 2/28/24 3:29 AM, Markus Armbruster wrote: >>>> Gustavo Romero <gustavo.rom...@linaro.org> writes: >>>> >>>> [...] >>>> >>>>> This patchset introduces a new device, ivshmem-flat, which is similar to >>>>> the >>>>> current ivshmem device but does not require a PCI bus. It implements the >>>>> ivshmem >>>>> status and control registers as MMRs and the shared memory as a directly >>>>> accessible memory region in the VM memory layout. It's meant to be used on >>>>> machines like those with Cortex-M MCUs, which usually lack a PCI bus, >>>>> e.g., >>>>> lm3s6965evb and mps2-an385. Additionally, it has the benefit of requiring >>>>> a tiny >>>>> 'device driver,' which is helpful on some RTOSes, like Zephyr, that run on >>>>> memory-constrained resource targets. >>>>> >>>>> The patchset includes a QTest for the ivshmem-flat device, however, it's >>>>> also >>>>> possible to experiment with it in two ways: >>>>> >>>>> (a) using two Cortex-M VMs running Zephyr; or >>>>> (b) using one aarch64 VM running Linux with the ivshmem PCI device and >>>>> another >>>>> arm (Cortex-M) VM running Zephyr with the new ivshmem-flat device. >>>>> >>>>> Please note that for running the ivshmem-flat QTests the following patch, >>>>> which >>>>> is not committed to the tree yet, must be applied: >>>>> >>>>> https://lists.nongnu.org/archive/html/qemu-devel/2023-11/msg03176.html >>>> >>>> What problem are you trying to solve with ivshmem? >>>> >>>> Shared memory is not a solution to any communication problem, it's >>>> merely a building block for building such solutions: you invariably have >>>> to layer some protocol on top. What do you intend to put on top of >>>> ivshmem? >>> >>> Actually ivshmem is shared memory and bi-direction notifications (in this >>> case a doorbell register and an irq). >> >> Yes, ivshmem-doorbell supports interrupts. Doesn't change my argument. >> >>> This is the fundamental requirement for many types of communication but our >>> interest is for the OpenAMP project [1]. >>> >>> All the OpenAMP project's communication is based on shared memory and >>> bi-directional notification. Often this is on a AMP SOC with Cortex-As and >>> Cortex-Ms or Rs. However we are now expanding into PCIe based AMP. One >>> example of this is an x86 host computer and a PCIe card with an ARM SOC. >>> Other examples include two systems with PCIe root complex connected via a >>> non-transparent bridge. >>> >>> The existing PCI based ivshmem lets us model these types of systems in a >>> simple generic way without worrying about the details of the RC/EP >>> relationship or the details of a specific non-transparent bridge. In fact >>> the ivshmem looks to the two (or more) systems like a non-transparent >>> bridge with its own memory (and no other memory access is allowed). >>> >>> Right now we are testing this with RPMSG between two QEMU system where both >>> systems are cortex-a53 and both running Zephyr. [2] >>> >>> We will expand this by switching one of the QEMU systems to either arm64 >>> Linux or x86 Linux. >> So you want to simulate a heterogeneous machine by connecting multiple >> qemu-system-FOO processes via ivshmem, correct? > > An AMP SOC is one use case. A PCIe card with an embedded Cortex-M would be > another. > >> >>> We (and others) are also working on a generic virtio transport that will >>> work between any two systems as long as they have shared memory and >>> bi-directional notifications. >> >> On top of or adjacent to ivshmem? > > On top of ivshmem. It is not the only use case but it is an important one.
Interesting. > I just gave a talk on this subject at EOSS. If you would like to look at the > slides they are here: > https://sched.co/1aBFm The talk's abstract: AMP Virtio: A New Virto Transport for AMP Systems, with Focus on Zephyr, Linux, and Xen Asymmetric multiprocessing systems are common in automotive, Industrial, and mobile markets and are entering the data center market as well. The OpenAMP project strives to make AMP systems easier and more standards based. The OpenAMP project is working on a new Virtio transport layer that can be used between cores that do not share a hypervisor. Example systems include: * AMP SOCs running running Linux on Cortex-A and Zephyr on Cortex-M, * x86 and Arm systems connected via PCIe, both running Linux. AMP Virtio can also be used in Xen and other hypervisors to reduce worse case latency and increase freedom of interference (FFI). These aspects are critical in real-time and functionally safe systems. This presentation will cover: * Why Virtio for AMP systems * What are the problems with the existing virtio transports for AMP systems * Outline of the transport proposal * Prototype software for Zephyr, Linux, and Xen * Show various topologies and use cases for Device and Driver placement * Show portability to other RTOSes and hypervisors. You're interested in systems that contain multiple cores. You want to create a virtio transport to let these cores talk to each other. Let's talk physical hardware. The transport needs to go over some kind of device. The device could be pretty smart and provide the virtio transport, or it could be really dumb and provide just enough to let software running on the core implement the virtio transport. What do you have in mind? You need QEMU to emulate one or more of the devices you have in mind. Note: emulation is about the guest-facing part of the QEMU device model. We'll get to the host-facing part in a minute. Smart device: we know how to emulate virtio devices with various connectors, such as PCI, CCW, MMIO. Dumb device: ivshmem-doorbell could serve as a virtual dumb device. Note that a physical ivshmem would be a bad idea; it's design is rather poor. Is this why you're interested in ivshmem? As is, ivshmem-doorbell comes with a PCI connector. You want an MMIO connector. Fair enough. Once you have an actual dumb physical device, you're likely better off emulating that instead of approximating it with ivshmem. Approximating could still be useful as a stopgap. I sidestepped an important problem so far: the "asymmetric" in AMP. When your asymmetric system contains cores with different architectures, QEMU can't emulate the entire system, because qemu-system-TARGET can only emulate cores with achitecture TARGET. I guess you want to work around this limitation by running multiple qemu-system-TARGETs. Trouble is you then need to connect them somehow. ivshmem's host-facing part can connect its qemu-system-TARGET to other processes, including other qemu-system-TARGETs, and the TARGETs need not be identical. Correct? What if we had a qemu-system that wasn't limited to a single architecture? Would you still want to run multiple connected instances then, or would you simply model your asymmetric system in a single one? [...]