[Date Prev][Date Next][Thread Prev][Thread Next][Date Index][Thread Index] Re: [Xen-devel] [RFC] Unicore Subproject Proposal
On Wed, 20 Sep 2017, Lars Kurth wrote: > Felipe, Simon, > a quick note to let you know that the Advisory Board in today’s AB meeting > decided to endorse your proposal. > Let me know how you proceed: from my perspective, we can kick off a formal > vote before you make modifications to the proposal, but I think it is better > to post v2 first. Congratulations! > On 07/09/2017, 05:26, "Felipe Huici" <Felipe.Huici@xxxxxxxxx> wrote: > > Dear all, > > Following up on discussions that Simon Kuenzer had with several of you at > the last Xen summit, we’re now submitting a Xen subproject proposal based > on our Unicore work. Could you please review it? > > Thanks, > > Felipe Huici & Simon Kuenzer - NEC Labs Heidelberg. > > > PROPOSAL: Unicore > ================= > > Roles > ----- > Project Leads: Simon Kuenzer <simon.kuenzer@xxxxxxxxx> (main lead) > Felipe Huici <felipe.huici@xxxxxxxxx> (co-lead) > Florian Schmidt <florian.schmidt@xxxxxxxxx> (co-lead) > Project Mentor: Lars Kurth <lars.kurth@xxxxxxxxxx> > Project Sponsor: -To be found- > > Background > ---------- > In recent years, several papers and projects dedicated to unikernels have > shown the immense potential for performance gains that these have. By > leveraging specialization and the use of minimalistic OSes, unikernels are > able to yield impressive numbers, including fast instantiation times (tens > of milliseconds or less), tiny memory footprints (a few MBs or even KBs), > high network throughput (10-40 Gb/s), and high consolidation (e.g., being > able to run thousands of instances on a single commodity server), not to > mention a reduced attack surface and the potential for easier > certification. Unikernel projects worthy of mention include MirageOS, > ClickOS, Erlang on Xen, OSv, HALVM, and Minicache, among others. > > The fundamental drawback of unikernels is that they require that > applications be manually ported to the underlying minimalistic OS (e.g. > having to port nginx, snort, mysql or memcached to MiniOS or OSv); this > requires both expert work and often considerable amount of time. In > essence, we need to pick between either high performance with unikernels, > or no porting effort but decreased performance and decreased efficiency > with standard OS/VM images. The goal of this proposal is to change this > status quo by providing a highly configurable unikernel code base; we call > this base Unicore. > > This project also aims to concentrate the various efforts currently going > on in the Xen community regarding minimalistic OSes (essentially different > variants of MiniOS). We think that splitting the community across these > variants is counter-productive and hope that Unicore will provide a common > place for all or most improvements and customizations of minimalistic > OSes. The long term goal is to replace something like MiniOS with a tool > that can automatically build such a minimalistic OS. > > Unicore - The "Unikernel Core" > --------------------------------- > The high level goal of Unicore is to be able to build unikernels targeted > at specific applications without requiring the time-consuming, expert work > that building such a unikernel requires today. An additional goal (or > hope) of Unicore is that all developers interested in unikernel > development would contribute by supplying libraries rather than working on > independent projects with different code bases as it is done now. The main > idea behind Unicore is depicted in Figure 1 and consists of two basic > components: > > > [Attachment: unicore-oneslider.pdf] > > > Figure 1. Unicore architecture. > > > Library pools would contain libraries that the user of Unicore can select > from to create the unikernel. From the bottom up, library pools are > organized into (1) the architecture library tool, containing libraries > specific to a computer architecture (e.g., x86_64, ARM32 or MIPS); (2) the > platform tool, where target platforms can be Xen, KVM, bare metal (i.e. no > virtualization) and user-space Linux; and (3) the main library pool, > containing a rich set of functionality to build the unikernel from. This > last library includes drivers (both virtual such as netback/netfront and > physical such as ixgbe), filesystems, memory allocators, schedulers, > network stacks, standard libs (e.g. libc, openssl, etc.), runtimes (e.g. a > Python interpreter and debugging and profiling tools. These pools of > libraries constitute a code base for creating unikernels. As shown, a > library can be relatively large (e.g libc) or quite small (a scheduler), > which should allow for a fair amount of customization for the unikernel. > > > The Unicore build tool is in charge of compiling the application and the > selected libraries together to create a binary for a specific platform and > architecture (e.g., Xen on x86_64). The tool is currently inspired by > Linux’s kconfig system and consists of a set of Makefiles. It allows users > to select libraries, to configure them, and to warn them when library > dependencies are not met. In addition, the tool can also simultaneously > generate binaries for multiple platforms. > > > As an example, imagine a user wanting to generate a network driver domain > unikernel. In this case, we would assume the “application” to be the > netback driver. To select this application, the user would first run “make > menuconfig” from within the netback application folder. The Makefile there > would set a variable to indicate what the application is, and would > include the main Unicore Makefiles so that the unikernel can be built > (Step 1 in the figure). Using the menu-based system, the user chooses the > relevant libraries; for a Xen driver domain this would include a physical > network driver, the netback driver, the libxenplat library and a library > from the architecture library pool such as libx86_64arch (Step 2 in the > figure). With this in place, the user saves the configuration and types > “make” to build the unikernel (Step 3) and xl create to run it (Step 4). > > > A note on the ABI/API: because Unicore allows for customization of the > unikernels, the ABI (or API since there is no kernel) would be custom, > that is, defined by the libraries the user selected. Having said that, it > would be perfectly possible, for instance, to build POSIX-compliant > unikernels with it. > > > Relevance to Xen and its Community > ----------------------------------- > Unikernels are important to a number of areas relevant to the Xen > community, including IoT, automotive, stub domains and driver domain > disaggregation. Unicore could help boost the progress in all of these > areas by quickly providing the necessary tools to create unikernels for > them. For instance, for a driver domain, the user would include the > “library” containing the relevant hardware driver and corresponding > back-end driver, and in principle Unicore would take care of the rest. > > In addition, Unicore could eventually replace Mini-OS, providing a > cleaner, more stable and flexible base from which to build unikernels for > projects (the modularization of Mini-OS is in fact already taking place). > > > Current Status > -------------- > Unicore is at an early stage. For now it includes some base libraries with > code extracted from Mini-OS as well as a build tool inspired by > Linux's KConfig system. Unicore is currently able to build "hello world" > unikernels for Xen and Linux user space on x86_64 and ARMv7. > > Incubation > ---------- > The reason behind making Unicore a Xen sub-project project is to (1) bring > the existence of Unicore to the attention of the Xen community > and to outside world; (2) to attempt to harness interest and potentially > development cycles from people and companies interested in > unikernels; and (3) to concentrate maintenance resources from people > interested in unikernels within the community. > > License > ------- > The main license of the run-time components of Unicore will be a 3-clause > BSD license, unless there is a good reason not to use it (e.g. we may > import 2-clause BSD licensed code from Mini-OS, which we would *not* > anticipate to change). The Makefile system would be licensed under GPL v2 > or later as we want to be able to use KConfig functionality from > Buildroot/Linux. > > Required Infrastructure > ----------------------- > The official repositories should be created on > [http://xenbits.xenproject.org/] under `unicore.git`. There should be a > main repository for the core unicore implementation and additional > repositories for some more advanced extension libraries (e.g., lwIP, > newlib). > > ### Main repository > > `unicore.git` > > ### Repositories for extension libraries > > Repositories for additional libraries that are supported by the Unicore > project should exist under a separate directory: > > `unicore-libs/` > > For example: > > `unicore-libs/lwip.git` > `unicore-libs/newlib.git` > > ### Mailing list > > In the beginning we would use the MiniOS mailing list > (minios-devel@xxxxxxxxxxxxxxxxxxxx). When we get traction with Unicore we > could consider splitting that traffic onto a unicore mailing list. > > > > > ============================================================ > Dr. Felipe Huici > Chief Researcher, Networked Systems and Data > Analytics Group > NEC Laboratories Europe, Network Research Division > Kurfuerstenanlage 36, D-69115 Heidelberg > Tel. +49 > (0)6221 4342-241 > Fax: +49 > (0)6221 4342-155 > > e-mail: > felipe.huici@xxxxxxxxx > ============================================================ > NEC Europe Limited Registered Office: NEC House, 1 > Victoria Road, London W3 6BL Registered in England 2832014 > > > > > _______________________________________________ Xen-devel mailing list Xen-devel@xxxxxxxxxxxxx https://lists.xen.org/xen-devel
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