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1009 lines
49 KiB
Plaintext
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===============================================
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Release notes for the Genode OS Framework 11.11
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===============================================
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Genode Labs
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Each Genode release is themed with a predominating topic. Version 11.08 aimed
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at blurring the lines between the use of different base platforms whereas the
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predecessor re-addressed inter-process communication. With the current release,
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we explore the various approaches to virtualization using Genode. At the first
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sight, this topic sounds like riding a dead horse because virtualization is
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widely regarded as commodity by now. However, because Genode has virtualization
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built right in the heart of its architecture, this topic gets a quite different
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spin. As described in Section [A Plethora of Levels of Virtualization], the
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version 11.11 contains the results of our exploration work about faithful
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virtualization, paravirtualization, OS-level virtualization, and
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application-level virtualization. The latter category is particularly unique to
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Genode's architecture.
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Besides elaborating on virtualization, the version 11.11 comes with new
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features such as support for user-level debugging by the means of the GNU
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debugger and the ability to run complex interactive UNIX applications on Genode
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(i.e., VIM). Furthermore, we improved device-driver support, specifically for
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ARM platforms. Apart from working on features, we had been busy with
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optimizing several aspects of the framework, improvements ranging from improved
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build-system performance, over reduced kernel-memory footprint for NOVA, to a
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new IPC implementation for Linux.
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For regular Genode developers, one of the most significant changes is the new
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tool chain based on GCC 4.6.1. The background story about the tool-chain update
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and its implications is described in Section [New tool chain based on GCC
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4.6.1].
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A Plethora of Levels of Virtualization
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######################################
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Virtualization has become a commodity feature universally expected from modern
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operating systems. The motivations behind employing virtualization techniques
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roughly fall into two categories: the re-use of existing software and
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sandboxing untrusted code. The latter category is particularly related to
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the Genode architecture. The Genode process tree is essentially a tree of
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nested sandboxes where each node is able to impose policy on its children.
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This immediately raises the question of where Genode's design could take us
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when combined with existing virtualization techniques. To explore the
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possible inter-relationships between Genode and virtualization, we conducted
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a series of experiments. We found that Genode's recursive architecture
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paves the way to far more flexible techniques than those we know from existing
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solutions.
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Faithful x86 PC Virtualization enabled by the Vancouver VMM
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===========================================================
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Most commonly, the term virtualization refers to faithful virtualization where
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an unmodified guest OS is executed on a virtual hardware platform. Examples of
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such virtual machines are VMware, VirtualBox, KVM, and Xen - naming only those
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that make use of hardware virtualization capabilities. Those established
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technologies have an impressive track record on the first of both categories
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mentioned above - software re-use. However, when it comes to sandboxing
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properties, we find that another virtual machine monitor (VMM) implementation
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outshines these established solutions, namely the Vancouver virtual machine
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monitor executed on top of the NOVA hypervisor. Combined, NOVA and Vancouver
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are able to slash the complexity of the trusted computing base (TCB) for
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isolating virtual machines to a tiny fraction compared to the established
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products. The key is the poly-instantiation of the relatively complex virtual
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machine monitor with each virtual machine. Each VMM is executed within a
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dedicated protection domain. So a problem in one VM can only affect its
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respective Guest OS but not any other VM. By executing the VMM outside of the
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hypervisor, the hypervisor's complexity is dramatically smaller than
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traditional hypervisors. Hence, the authors of NOVA coined the term
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microhypervisor.
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The NOVA virtualization architecture is detailed in the paper
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[https://os.inf.tu-dresden.de/papers_ps/steinberg_eurosys2010.pdf - NOVA: A Microhypervisor-Based Secure Virtualization Architecture]
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by Udo Steinberg and Bernhard Kauer.
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Since February 2010, NOVA is one of the supported base platforms of Genode. But
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until now, Vancouver has been tied to a specialized user land that comes with
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NOVA. For the current Genode release, we took the chance to adopt this
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technology for Genode.
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[image vancouver]
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The Vancouver virtual machine monitor executed as Genode
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component
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On Genode, the Vancouver VMM is executed as a normal Genode process.
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Consequently, any number of VMM instances can be started either statically via
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the init process or dynamically. By bringing Vancouver to Genode we are able to
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combine the high performance and secure design of Vancouver with the
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flexibility of Genode's component architecture. By combining Genode's session
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routing concept with resource multiplexers, virtual machines can be connected
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to one another as well as to Genode components.
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That said, the current stage of development is still highly experimental.
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But it clearly shows the feasibility of performing faithful virtualization
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naturally integrated with a Genode-based system. For more technical details
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about the porting work, please refer to Section
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[Vancouver virtual machine monitor];
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Android paravirtualized
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=======================
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Since 2009, Genode embraced the concept of paravirtualization for executing
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unmodified Linux applications by the means of the OKLinux kernel. This special
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variant of the Linux kernel is modified to run on top of the OKL4 microkernel.
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With the added support for the Fiasco.OC kernel as base platform, the use of
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L4Linux as another paravirtualized Linux variant became feasible. L4Linux has a
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long history reaching back to times long before the term paravirtualization was
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eventually coined. In contrast to faithful virtualization, paravirtualization
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devises modifications of the kernel of the Guest OS but preserves binary
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compatibility of the Guest's user-level software. The proponents of this
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approach cite two advantages over faithful virtualization: better performance
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and independence from virtualization-hardware support. For example, L4Linux is
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available on ARM platforms with no virtualization support.
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L4Linux is the base of L4Android, a project that combines the Android software
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stack with L4Linux. With the current release, we have integrated L4Android with
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Genode.
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:[https://l4android.org]:
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L4Android project website
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[image l4android]
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Android, a Linux distribution, and a process tree of Genode
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components running side by side
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As illustrated in the figure above, multiple Linux instances of both types
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Android and plain Linux can be executed as nodes of the Genode process tree.
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For their integration with the Genode environment, we extended the L4Linux
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kernel with custom stub drivers that make Genode's session interfaces
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available as virtual devices. These virtual devices include NIC, UART,
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framebuffer, block, keyboard, and pointer devices. Our work on L4Linux is
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explained in more detail in Section [L4Linux / L4Android].
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OS-level Virtualization using the Noux runtime environment
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==========================================================
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Noux is our take on OS-level virtualization. The goal is to be able to use the
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wealth of command-line-based UNIX software (in particular GNU) on Genode
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without the overhead of running and maintaining a complete guest OS, and
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without changing the original source code of the UNIX programs. This work is
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primarily motivated by our ongoing mission to use Genode as development
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environment.
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[image noux]
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The Noux runtime environment for UNIX software. The program is linked
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against a custom libc plugin that directs system calls over an RPC
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interface to the Noux server. The RPC interface resembles a
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traditional UNIX system-call API.
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The Noux approach is to provide the traditional UNIX system call interface as
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an RPC service, which is at the same time the parent of the UNIX process(es) to
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execute. The UNIX process is linked against the libc with a special back end
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(libc plugin) that maps libc functionality to Noux RPC calls. This way, the
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integration of the UNIX program with Noux is completely transparent to the
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program. Because Noux plays the rule of a UNIX kernel, it has to implement
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typical UNIX functionality such as a virtual file system (VFS). But in contrast
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to a real kernel, it does not comprise any device drivers and protocol stacks.
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As file system, we currently use TAR archives that Noux obtains from core's ROM
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service. The content of such a TAR archive is exposed to the UNIX program as
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file system.
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One of the most prevalent pieces of UNIX software we spend the most of the day
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with is VIM. Hence, we set the goal for this release to execute VIM via Noux on
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Genode. This particular program is interesting for several technical reasons as
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well. First, in contrast to most command-line tools such as coreutils, it is
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interactive and implements its event loop via the 'select' system. This
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provided us with the incentive to implement 'select' in Noux. Second, with far
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more than 100,000 lines of code, VIM is not a toy but a highly complex and
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advanced UNIX tool. Third, its user interface is based on ncurses, which
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requires a fairly complete terminal emulator. Consequently, conducting the
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development of Noux implied working with and understanding several components
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in parallel including Noux itself, the libc, the Noux libc plugin, ncurses,
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VIM, and the terminal emulator. Our undertaking was successful. We are now able
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to run VIM without modifications and manual porting work on Genode.
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The novelty of Noux compared to other OS-level virtualization approaches such
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OpenVZ and FreeBSD jails lies in the degree of isolation it provides and the
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simplicity of implementation. Noux instances are isolated from each other
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by microkernel mechanisms. Therefore the isolation between two instances does
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not depend on a relatively large kernel but on an extremely small trusted
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computing base of less than 35,000 lines of code. At the same time, the
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implementation turned out to be strikingly simple. Thanks to the existing APIs
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provided by the Genode framework, the Noux server is implemented in less than
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2,000 lines of code. We are thrilled to learn that this low amount of code
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suffices to bring complex UNIX software such as VIM to life.
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For more technical details about our work on this topic, please refer to
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the Sections [Noux] and [Framebuffer-based virtual terminal and ncurses].
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GDB debugging via application-level virtualization
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==================================================
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The work described in the previous sections was motivated with the desire to
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re-use existing software on Genode. This section explores a creative use
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of sandboxing facilitating the Genode architecture.
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User-level debugging is a feature that we get repeatedly asked about. Until
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now, the answer was pretty long-winded because we use different debugging
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facilities on different kernels. However, none of those facilities are
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comparable to the convenient debugging tools we know from commodity OSes.
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For a long time, we were hesitant to build in debugging support into Genode
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because we were afraid to subvert the security of Genode by adding special
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debug interfaces short-circuiting security policies. Furthermore, none
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of the microkernels we love so dearly featured support for user-level
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debugging. So we deferred the topic. Until now. With GDB monitor, we have
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found an approach to user-level debugging that is not only completely in
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line with Genode's architecture but capitalizes it. Instead of adding
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special debugging interfaces to low-level components such as the kernel
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and core, we use an approach that we call application-level virtualization.
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[image no_gdb]
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A Genode process uses low-level services provided by core as well as a
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higher-level service implemented as separate process component.
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Each Genode process interacts with several low-level services provided by
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Genode's core, in particular the RAM service for allocating memory, the CPU
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service to create and run threads, and the RM service to manage the virtual
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address space of the process. However, the process does not contact core
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directly for those services but requests them via its chain of parents (i.e,
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the init process). This gives us the opportunity to route session requests for
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those services to alternative implementations.
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[image gdb]
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GDB monitor transparently intercepts the interaction of a Genode process with
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its environment. By virtualizing fundamental core services, GDB monitor
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exercises full control over the debugging target. GDB monitor, in turn,
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utilizes a separate service component to establish a terminal connection with
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a remote GDB.
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When running a Genode process as debugging target, we place an intermediate
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component called GDB monitor between the process and its parent. Because
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GDB monitor is now the parent of the debugging target, all session requests
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including those for core services are issued at GDB monitor. Instead of routing
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those session requests further down the tree towards core, GDB monitor
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provides a local implementation of these specific services and can thereby
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observe and intercept all interactions between the process and core. In
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particular, GDB monitor gains access to all memory objects allocated from the
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debugging target's RAM session, it knows about the address space layout, and
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becomes aware of all threads created by the debugging target. Because, GDB
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monitor does possess the actual capabilitiy to the debugging target's CPU
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session, it can execute control over those threads, i.e., pausing them or
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enabling single-stepping. By combining the information about the debugging
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target's address space layout and the access to its memory objects, GDB monitor
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is even able to transparently change arbitrary memory in the debugging target,
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for example, inserting breakpoint instructions into its text segment.
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Thanks to application-level virtualization, the once deemed complicated problem
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of user-level debugging has become straight forward to address. The solution
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fits perfectly into the Genode concept, maintains its security, and does not
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require special-purpose debugging hooks in the foundation of the operating
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system.
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To get a more complete picture about our work on GDB monitor, please read on at
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Section [GDB monitor].
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Base framework, low-level OS infrastructure
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###########################################
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Handling CPU exceptions at user level
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=====================================
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To support user-level policies of handling CPU exceptions such as division by
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zero or breakpoint instructions, we have added support for reflecting such
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exceptions to the CPU session interface. The owner of a CPU session
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capability can register a signal handler for each individual thread allocated
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from the session. This handler gets notified on the occurrence of an exception
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caused by the respective thread similar to how page faults are reflected to
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RM sessions. The CPU exception handling support has been implemented on the
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Fiasco.OC and OKL4 base platforms.
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Remote access to thread state
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=============================
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Closely related to the new support for handling CPU exceptions, we have
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extended the information that can be gathered for threads of a CPU session to
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general-purpose register state and the type of the last exception caused by the
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thread. Furthermore, the CPU session interface has been extended to allow the
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pausing and resumption of threads as well as single-stepping through CPU
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instructions (on x86 and ARM).
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All those additions are subject to capability-based security so that only the
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one who possesses both a CPU-session capability and a thread capability can
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access the thread state. This way, the extension of the CPU session interface
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opens up a lot of new possibilities (especially regarding debugging facilities)
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without affecting the security of the overall system.
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Improved signaling latency
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==========================
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During the time span of the last two years, we have observed a steadily growing
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number of use cases for Genode's signaling framework. Originally used only for
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low-frequent notifications, the API has become fundamental to important Genode
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mechanisms such as the data-flow protocol employed by the packet-stream
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interface, the on-demand fault handling performed by dataspace managers, and
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CPU exception handling. This observation provided us with the incentive to
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improve the latency of delivering signals by placing signal delivery into a
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dedicated thread within core.
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Optimization for large memory-mapping sizes
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===========================================
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Some kernels, in particular NOVA, are optimized to deal with flexible mapping
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sizes that are independent of physical page sizes. The internal representation
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of memory mapping independent on page sizes can greatly reduce the memory
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footprint needed to keep track memory mappings, but only if large mappings are
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used. In practice, mapping sizes are constrained by their sizes and their
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alignment in both physical and virtual address spaces. To facilitate the use of
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large mappings with NOVA, we have optimized core for the use of large mappings.
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Core tries to size-align memory objects in both physical memory and virtual
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memory (core-local as well as within normal user processes). This optimization
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is completely transparent to the Genode API but positively affects the
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page-fault overhead throughout the system, most noticeably the NPT-fault
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overhead of the Vancouver VMM.
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Standard C++ library
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====================
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To accommodate users of the standard C++ library, we used to host the 'stdcxx'
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library to the 'libc' repository. Apparently, there are use cases for 'stdcxx'
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without Genode's C library, in particular for hybrid Linux/Genode programs that
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are linked against the host's glibc anyway. So we decided to move the 'stdcxx'
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to the base repository. So if you are needing 'stdcxx' but are not using
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Genode's libc, enabling the 'base' repository in your build configuration
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suffices.
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Terminal-session interface
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==========================
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We revised the terminal session interface by adding a simple startup-protocol
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for establishing terminal connections: At session-creation time, the terminal
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session may not be ready to use. For example, a TCP terminal session needs an
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established TCP connection first. However, we do not want the session-creation
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to be blocked on the server side because this would render the server's
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entry point unavailable for all other clients until the TCP connection is
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ready. Instead, we deliver a 'connected' signal to the client emitted when the
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session becomes ready to use. The Terminal::Connection waits for this signal
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at construction time. Furthermore, we extended the terminal session interface
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with the new 'avail()' and 'size()' functions. The 'avail()' function can be
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used to query for the availability of new characters. The 'size()' function
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returns the size of the terminal (number of rows and columns).
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Dynamic linker
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==============
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The dynamic linker underwent several changes in its memory management. Since
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the original FreeBSD implementation heavily relies on UNIX-like 'mmap'
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semantics, which up to this point was poorly emulated using Genode primitives,
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we abandoned this emulation completely. In the current setup the linker
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utilizes Genode's managed-dataspace concept in order to handle the loading of
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binaries and shared libraries and thus implements the required memory
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management correctly.
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Also the linker has been adapted to Genode's new GCC 4.6.1 tool chain, which
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introduced new relocation types on the ARM platform.
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Libraries and applications
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##########################
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C runtime
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=========
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We have updated our FreeBSD-based C library to version 8.2.0 and thereby
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changed the way how the libc is integrated with Genode. Instead of hosting
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the 3rd-party code as part of the Genode source tree in the form of the 'libc'
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repository, the libc has now become part of the 'libports' repository. This
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repository does not contain the actual 3rd-party source code but only the
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rules of how to download and integrate the code. These steps are fully
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automated via the 'libports/Makefile'. Prior using the libc, please make sure
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to prepare the 'libc' package within the 'libports' repository:
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! cd <genode-dir>/libports
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! make prepare PKG=libc
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Vancouver virtual machine monitor
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=================================
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Vancouver is a virtual machine monitor specifically developed for the use with
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the NOVA hypervisor. It virtualizes a 32-bit x86 PC hardware including various
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peripherals.
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The official project website is [https://hypervisor.org]. Vancouver relies
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on hardware virtualization support such as VMX (Intel) or SVM (AMD).
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With the current release, we have added the first version of our port of
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Vancouver to Genode to the 'ports' repository. To download the Vancouver
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source code, simply issue the following command from within the 'ports'
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repository:
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! make prepare PKG=vancouver
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The glue code between Vancouver and Genode is located at 'ports/src/vancouver/'.
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At the current stage, the port is not practically usable but it demonstrates
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well the general way of how the VMM code is meant to interact with Genode.
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In contrast to the original Vancouver, which obtains its configuration from
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command-line arguments, the Genode version reads the virtual machine
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description as XML data supplied via Genode's config mechanism. For each
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component declared within the '<machine>' node in the config XML file, a new
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instance of a respective device model or host driver is instantiated. An
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example virtual machine configuration looks like this:
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! <machine>
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! <mem start="0x0" end="0xa0000"/>
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! <mem start="0x100000" end="0x2000000"/>
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! <nullio io_base="0x80" />
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! <pic io_base="0x20" elcr_base="0x4d0"/>
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! <pic io_base="0xa0" irq="2" elcr_base="0x4d1"/>
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! <pit io_base="0x40" irq="0"/>
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! <scp io_port_a="0x92" io_port_b="0x61"/>
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! <kbc io_base="0x60" irq_kbd="1" irq_aux="12"/>
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! <keyb ps2_port="0" host_keyboard="0x10000"/>
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! <mouse ps2_port="1" host_mouse="0x10001"/>
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! <rtc io_base="0x70" irq="8"/>
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! <serial io_base="0x3f8" irq="0x4" host_serial="0x4711"/>
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! <hostsink host_dev="0x4712" buffer="80"/>
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! <vga io_base="0x03c0"/>
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! <vbios_disk/>
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! <vbios_keyboard/>
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! <vbios_mem/>
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! <vbios_time/>
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! <vbios_reset/>
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! <vbios_multiboot/>
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! <msi/>
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! <ioapic/>
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! <pcihostbridge bus_num="0" bus_count="0x10" io_base="0xcf8"
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! mem_base="0xe0000000"/>
|
|
! <pmtimer io_port="0x8000"/>
|
|
! <vcpu/> <halifax/> <vbios/> <lapic/>
|
|
! </machine>
|
|
|
|
The virtual BIOS of Vancouver has built-in support for loading an OS from
|
|
multiboot modules. On Genode, the list of boot modules is supplied with
|
|
the '<multiboot>' node:
|
|
|
|
! <multiboot>
|
|
! <rom name="bootstrap"/>
|
|
! <rom name="fiasco"/>
|
|
! <rom name="sigma0.foc"/>
|
|
! <rom name="core.foc"/>
|
|
! </multiboot>
|
|
|
|
This configuration tells Vancouver to fetch the declared boot modules from
|
|
Genode's ROM service.
|
|
|
|
For the current version, we decided to support SVM-based hardware only
|
|
for the mere reason that it is well supported by recent Qemu versions. At the
|
|
time of the release, the SVM exit conditions CPUID, IOIO, MSR, NPT, INVALID,
|
|
STARTUP are handled. Of those conditions, the handling of NPT (nested page
|
|
table) faults was the most challenging part because of the tight interplay
|
|
between the NOVA hypervisor and the VMM at this point.
|
|
|
|
With this code in place, Vancouver is already able to boot unmodified
|
|
L4ka::Pistachio or Fiasco.OC kernels. Both kernels print diagnostic output over
|
|
the virtual comport and finally wait for the first timer interrupt.
|
|
|
|
Even though the current version has no practical use yet, it is a great
|
|
starting point to dive deeper into the topic of faithful virtualization with
|
|
Genode. For a quick example of running Vancouver, please refer to the
|
|
run script at 'ports/run/vancouver.run'.
|
|
|
|
We want to thank Bernhard Kauer and Udo Steinberg for having been extremely
|
|
responsive to our questions, making the realization of this first version
|
|
possible at a much shorter time frame than we expected.
|
|
|
|
|
|
TCP terminal
|
|
============
|
|
|
|
The new TCP terminal located at 'gems/src/server/tcp_terminal' is a service
|
|
that provides Genode's terminal-session interface via individual TCP
|
|
connections. It supports multiple clients. The TCP port to be used for each
|
|
client is defined as session policy in the config node of the TCP terminal
|
|
server:
|
|
|
|
! <config>
|
|
! <policy label="client" port="8181"/>
|
|
! <policy label="another_client" port="8282"/>
|
|
! </config>
|
|
|
|
For an example of how to use the TCP terminal, please refer to the run script
|
|
at 'gems/run/tcp_terminal.run'.
|
|
|
|
|
|
Framebuffer-based virtual terminal and ncurses
|
|
==============================================
|
|
|
|
We significantly advanced the implementation of our custom terminal emulator to
|
|
be found at 'gems/src/server/terminal'. The new version supports all terminal
|
|
capabilities needed to display and interact with ncurses-based applications
|
|
(e.g., VIM) including support for function keys, colors, key repeat, and
|
|
multiple keyboard layouts. The us-english keyboard layout is used by default.
|
|
The German keyboard layout can be enabled using the '<keyboard>' config node:
|
|
|
|
! <config>
|
|
! <keyboard layout="de"/>
|
|
! </config>
|
|
|
|
As built-in font, the terminal uses the beautiful 'Terminus' monospaced font.
|
|
|
|
Our port of the ncurses library that comes as 'libports' package has become
|
|
fully functional when combined with the terminal emulator described above.
|
|
It is tuned to use the Linux terminal capabilities.
|
|
|
|
|
|
Noux
|
|
====
|
|
|
|
Noux is a runtime environment that imitates the behavior of a UNIX kernel
|
|
but runs as plain Genode program. Our goal for this release was to be
|
|
able to execute VIM with no source-code modifications within Noux.
|
|
|
|
For pursuing this goal, we changed the I/O back end for the initial file
|
|
descriptors of the Noux init process to use the bidirectional terminal-session
|
|
interface rather than the unidirectional LOG session interface. Furthermore,
|
|
as VIM is an interactive program, it relies on a working 'select' call. So
|
|
this system call had to be added to the Noux session interface. Because
|
|
'select' is the first of Noux system calls that is able to block, support
|
|
for blocking Noux processes had to be implemented. Furthermore, we improved
|
|
the handling of environment variables supplied to the Noux init process,
|
|
the handling of certain 'ioctl' functions, and hard links in TAR archives
|
|
that Noux uses as file system.
|
|
|
|
We are happy to report that thanks to Noux we have become able to run VIM on
|
|
Genode now! If you like to give it a spin, please try out the run script
|
|
'ports/run/noux_vim.run'.
|
|
|
|
|
|
GDB monitor
|
|
===========
|
|
|
|
Support of user-level debugging is a topic we get repeatedly asked about. It
|
|
is particularly hard because the debugging facilities exposed by operating
|
|
systems highly depend on the respective kernel whereas most open-source
|
|
microkernels offer no user-level debugging support at all.
|
|
|
|
The current release will hopefully make the life of Genode application
|
|
developers much easier. Our new GDB monitor component allows GDB to be
|
|
connected to an individual Genode process as a remote target (via UART or TCP
|
|
connection). Thereby, a wide range of convenient debugging features become
|
|
available, for example
|
|
|
|
* The use of breakpoints,
|
|
* Single-stepping through assembly instructions or at function level,
|
|
* Source-level debugging,
|
|
* Printing of backtraces and call-frame inspection, and
|
|
* Observing different threads of a Genode process
|
|
|
|
Both statically linked programs as well as programs that use shared libraries
|
|
are supported, which we see as a significant improvement over the traditional
|
|
debugging tools. Please note, however, that, at the current stage, the feature
|
|
is only supported on a small subset of Genode's base platforms (namely
|
|
Fiasco.OC and partially OKL4). We will extend the support to other platforms
|
|
depending on public demand.
|
|
|
|
The work on GDB monitor required us to approach the topic in a quite holistic
|
|
manner, adding general support for user-level debugging to the Fiasco.OC kernel
|
|
as well as the Genode base framework, componentizing the facility for
|
|
bidirectional communication (terminal session), and creating the actual GDB
|
|
support in the form of the GDB monitor component. To paint a complete picture
|
|
of the scene, we have added the following documentation:
|
|
|
|
:[https://genode.org/documentation/developer-resources/gdb]:
|
|
User-level debugging on Genode
|
|
|
|
|
|
L4Linux / L4Android
|
|
###################
|
|
|
|
Update to kernel version 3.0
|
|
============================
|
|
|
|
We have updated our modified version of the L4Linux kernel to support the
|
|
latest L4Linux kernel version 3.0.0. Moreover, we fixed some issues with the
|
|
kernel's internal memory management under ARM.
|
|
Please don't forget to issue a 'make prepare' in the 'ports-foc' directory,
|
|
before giving the new version a try.
|
|
|
|
|
|
Stub-driver support
|
|
===================
|
|
|
|
With this release, we introduce a bunch of new stub-drivers in L4Linux. These
|
|
stubs enable the use of Genode's NIC, terminal, and block services from Linux
|
|
applications. To use a Genode session from Linux, it's sufficient to provide
|
|
an appropriate service to the Linux instance. The stub drivers for these
|
|
services simply try to connect to their service and register corresponding
|
|
devices if such a service exists. For example, if a NIC session is provided to
|
|
Linux, it will provide an ethernet device named 'eth0' to Linux applications.
|
|
For terminal sessions, it will provide a serial device named 'ttyS0'.
|
|
|
|
In contrast to the NIC and terminal stub drivers, the block driver supports
|
|
the usage of more than one block session. Therefore, you have to state the
|
|
name of the individual block devices in the configuration. So, it is possible
|
|
to state which block device in Linux gets routed to which block session. An
|
|
example L4Linux configuration may look like follows
|
|
|
|
! <start name="l4linux">
|
|
! <resource name="RAM" quantum="512M"/>
|
|
! <config args="mem=128M console=ttyS0>
|
|
! <block label="sda"/>
|
|
! <block label="sdb"/>
|
|
! </config>
|
|
! <route>
|
|
! <service name="Block">
|
|
! <if-arg key="label" value="l4android -> sda"/> <child name="rootfs"/>
|
|
! </service>
|
|
! <service name="Block">
|
|
! <if-arg key="label" value="l4android -> sdb"/> <child name="home"/>
|
|
! </service>
|
|
! ...
|
|
! </route>
|
|
! </start>
|
|
|
|
The configuration provides two block devices in Linux named 'sda' and 'sdb',
|
|
whereby the first one gets routed to a child of init named 'rootfs' and the
|
|
second to a child named 'home'. Of course, both children have to provide the
|
|
block session interface.
|
|
|
|
|
|
L4Android
|
|
=========
|
|
|
|
Besides the support of L4Linux, Genode provides support for a slightly changed
|
|
L4Linux variant called L4Android, that combines L4Linux with the Android
|
|
kernel patches. To give Android on top of Genode a try, you need to prepare
|
|
your 'ports-foc' directory to contain the L4Android contrib code by issuing:
|
|
|
|
! make prepare TARGET=l4android
|
|
|
|
After that, a run script can be used to build all necessary components,
|
|
download the needed Android userland images, assemble everything, and start
|
|
the demo via Qemu:
|
|
|
|
! make run/l4android
|
|
|
|
Beforehand, the 'dde_ipxe' and 'ports-foc' repositories must be enabled in the
|
|
'etc/build.conf' file in your build-directory.
|
|
|
|
Although, in general Android runs on top of Genode, it seems that the whole
|
|
run-time overhead of (no-kvm) full emulation, para-virtualized Linux and Java,
|
|
makes it almost unusable within Qemu. Therefore, we strongly advise you to use
|
|
the Android version for x86 and turn on KVM support (at least partially). This
|
|
can be configured in the 'etc/tools.conf' file in your build directory by
|
|
adding the following line:
|
|
|
|
! QEMU_OPT = -enable-kvm
|
|
|
|
Unfortunately, it very much depends on your Qemu version and configuration,
|
|
whether Fiasco.OC runs problem-free with KVM support enabled. If you encounter
|
|
problems, try to use a limited KVM option with Qemu, like '-no-kvm-irqchip', or
|
|
'-no-kvm-pit' instead of '-enable-kvm'.
|
|
|
|
|
|
Device drivers
|
|
##############
|
|
|
|
Device-driver environment for iPXE network drivers
|
|
==================================================
|
|
|
|
Genode used network-card driver code from Linux 2.6 and gPXE. Unfortunately,
|
|
the gPXE project seems not very active since mid-2010 and the Linux DDE shows
|
|
its age with our new tool chain. Therefore, we switched to the iPXE project,
|
|
the official successor of gPXE, for our NIC drivers. Currently, drivers for
|
|
Intel E1000/E1000e and PCnet32 cards are enabled in the new 'nic_drv'. The
|
|
Linux based driver was removed.
|
|
|
|
:[https://ipxe.org]:
|
|
iPXE open source boot firmware
|
|
|
|
|
|
PL110 display driver
|
|
====================
|
|
|
|
The PL110 driver was reworked to support both the PL110 and PL111 controller
|
|
correctly. Moreover, it now runs not only within Qemu, but on real hardware
|
|
too. At least it is tested on ARM's Versatile Express evaluation board.
|
|
|
|
|
|
UART driver
|
|
===========
|
|
|
|
The first version of the PL011 UART driver implemented the LOG interface to
|
|
cover the primary use case of directing LOG output to different serial ports.
|
|
However, with the addition of GDB support with the current release, the use for
|
|
UARTs goes beyond unidirectional output. To let GDB monitor communicate with
|
|
GDB over a serial line, bidirectional communication is needed. Luckily, there
|
|
is a Genode interface for this scenario already, namely the terminal-session
|
|
interface. Hence, we changed the PL011 UART driver to provide this interface
|
|
type instead of LOG. In addition, we added an UART driver for the i8250
|
|
controller as found on PC hardware.
|
|
|
|
Both UART drivers can be configured via the Genode's config mechanism to route
|
|
each communication stream to a specific port depending on the session label of
|
|
the client. The configuration concept is documented in
|
|
'os/src/drivers/uart/README'. For a ready-to-use example of the UART drivers
|
|
please refer to the run script 'os/run/uart.run'.
|
|
|
|
|
|
Platform support
|
|
################
|
|
|
|
NOVA Microhypervisor version 0.4
|
|
================================
|
|
|
|
Genode closely follows the development of the NOVA hypervisor. With version 0.4,
|
|
NOVA more and more develops toward a full-featured and production ready
|
|
hypervisor. Therefore little effort was needed to enable Genode 11.11 on the
|
|
current NOVA kernel. The few changes include a new hypercall (SC control),
|
|
capability-based assignment of GSIs (Global System Interrupts), and support for
|
|
revoke filtering. Also, we improved Genode's page-mapping behavior to take
|
|
advantage of large flexpage sizes.
|
|
|
|
|
|
Fiasco.OC microkernel
|
|
=====================
|
|
|
|
Update to revision 38
|
|
~~~~~~~~~~~~~~~~~~~~~
|
|
|
|
With the current release we switched to the latest available Fiasco.OC kernel
|
|
version (revision 38). After having some timing issues on different ARM
|
|
platforms with Fiasco.OC in the past, we applied a small patch to correct the
|
|
timing behavior of the kernel to the current version. The patch is applied
|
|
automatically if executing 'make prepare' in the 'base-foc' repository.
|
|
|
|
Querying and manipulating remote threads
|
|
~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~
|
|
|
|
To support usage of GDB on top of Genode for Fiasco.OC, several enhancements
|
|
were developed. First, the thread state accessible via the CPU-session
|
|
interface has been extended to reflect the whole register set of the
|
|
corresponding thread depending to the underlying hardware platform. Moreover,
|
|
you can now stop and resume a thread's execution. On the x86 platform, it has
|
|
become possible to enable single-stepping mode for a specific thread. All
|
|
exceptions a thread raises are now reflected to the exception handler of
|
|
this thread. The exception handler can be set via the CPU-session interface. To
|
|
support stop/resume, single stepping and breakpoints on ARM, we had to modify
|
|
the Fiasco.OC kernel slightly. All patches to the Fiasco.OC kernel can be found
|
|
in 'base-foc/patches' and are automatically applied when issuing 'make
|
|
prepare'.
|
|
|
|
Versatile Express Cortex-A9x4
|
|
~~~~~~~~~~~~~~~~~~~~~~~~~~~~~
|
|
|
|
With the current release, we introduce support for a new platform on top of
|
|
Fiasco.OC. The ARM Versatile Express evaluation board with Coretile Cortex
|
|
A9x4 now successfully executes the well known Genode demo - have a look at the
|
|
'os/run/demo.run' run-script. Unfortunately, this platform is not supported by
|
|
most Qemu versions shipped with Linux distributions. Furthermore, our tests
|
|
with a Qemu variant that supports Versatile Express and the Fiasco.OC kernel
|
|
were not successful. Nevertheless, on a real machine the demo is working
|
|
nicely. Other drivers such as PL111 and the mouse driver are untested yet.
|
|
|
|
|
|
Linux
|
|
=====
|
|
|
|
New IPC implementation based on UNIX domain sockets
|
|
~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~
|
|
|
|
On Linux, Genode processes used to communicate via UDP-Sockets. So, any IPC
|
|
message could be addressed individually to a specific receiver without
|
|
establishing a connection beforehand. However, Genode was never designed to
|
|
work transparently over the network and UDP seems overkill for our
|
|
requirements. With this release, we tackled this fact by adapting the IPC
|
|
framework to use UNIX domain sockets.
|
|
|
|
The design uses two sockets per thread - client and server socket. The server
|
|
socket is used to receive requests from any client on 'Ipc_server::_wait' and
|
|
accessible as 'ep-<thread id>-server', just as the former UDP port. After
|
|
processing the request, the server replies to the requesting client and returns
|
|
to wait state. On 'Ipc_client::_call', the client socket is used to send the
|
|
request and receive the response.
|
|
|
|
This sounds trivial but marks an important step away from IPC istream and
|
|
ostream based design to explicit handling of RPC client and server roles. Linux
|
|
(as well as other platforms) will benefit from this in planned future changes.
|
|
|
|
During the design, we also addressed two other issues:
|
|
|
|
Child processes in Linux inherit open file descriptors from their parents.
|
|
Therefore, children further down the Genode tree formerly had plenty of open
|
|
files. The current implementation uses the close-on-exec flag to advise the
|
|
Linux kernel to close the marked file descriptors before executing the new
|
|
program on 'execve()'.
|
|
|
|
Genode resources appeared in the file system just under '/tmp', e.g.,
|
|
dataspaces as 'ds-<user id>-<count>'. This always filled the global temp
|
|
directory with dozens of Genode-specific files. Now, Genode resources are
|
|
located in '/tmp/genode-<user id>'.
|
|
|
|
|
|
Support for manually managing local sub address spaces
|
|
~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~
|
|
|
|
On microkernel-based platforms, Genode provides a powerful mechanism to manage
|
|
parts of a process' address space remotely (from another process called
|
|
dataspace manager) or locally. In contrast to those platforms, however, the
|
|
concept of managed dataspaces is not available on Linux because this kernel
|
|
lacks a mechanism to remotely manipulate address spaces. Naturally, in the
|
|
world of monolithic kernels, it is the task of the kernel to manage the virtual
|
|
address spaces of user-level programs.
|
|
|
|
The uses of managed dataspaces roughly fall into two categories: the provision
|
|
of virtual memory objects (dataspaces) in an on-demand-paged fashion and the
|
|
manual management of a part of the local address space. An example for the
|
|
latter is the manual management of the thread context area, which must be kept
|
|
clean of arbitrary dataspace mappings. Another use case is the manual placement
|
|
of shared-library segments within the local address space. Traditionally, we
|
|
had to address those problems with special cases on Linux. To support these use
|
|
cases in a generic way, we enhanced the memory management support for the Linux
|
|
base platform to support so-called sub-RM sessions in the local address space.
|
|
A sub RM session is the special case of a managed dataspace that is used only
|
|
local to the process and populated eagerly (not on-demand paged). With local
|
|
sub-RM sessions, a large part of the virtual memory of the process can be
|
|
reserved for attaching dataspaces at manually defined offsets.
|
|
|
|
The new example 'base/src/test/sub_rm' illustrates the use of sub RM
|
|
sessions. The example works across all platforms. It can be executed using
|
|
the run script 'base/run/sub_rm.run'.
|
|
|
|
|
|
Improved handling of hybrid Linux/Genode programs
|
|
~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~
|
|
|
|
Hybrid Linux/Genode programs are a special breed of programs that use both the
|
|
Genode API and Linux libraries found on the host Linux system. Examples for
|
|
such programs are the libSDL-based framebuffer driver, the ALSA-based audio
|
|
driver, and the tun/tap-based NIC driver - generally speaking, components that
|
|
interface Genode with the Linux environment. Because we expected those kind of
|
|
programs to be rare, not much attention was paid to make the creation of this
|
|
class of programs convenient. Consequently, the target-description files for
|
|
them were rather clumsy. However, we discovered that Genode can be used as a
|
|
component framework on Linux. In such a scenario, hybrid Linux/Genode programs
|
|
are the normal case rather than an exception, which prompted us to reconsider
|
|
the role of hybrid Linux/Genode programs within Genode. The changes are:
|
|
|
|
* The new 'lx_hybrid' library takes care of the peculiarities of the
|
|
linking stage of a hybrid program. In contrast to a plain Genode component,
|
|
such a program is linked with the host's linker script and uses the host's
|
|
dynamic linker.
|
|
|
|
* To support the common case of linking host libraries to a hybrid program,
|
|
we introduced the new 'LX_LIBS' variable. For each library listed in
|
|
'LX_LIBS', the build system queries the library's linking requirements using
|
|
'pkg-config'.
|
|
|
|
* The startup procedure differs between normal Genode programs and hybrid
|
|
programs. Plain Genode programs begin their execution with Genode's startup
|
|
code, which performs the initialization of the address space, executes all
|
|
static global constructors, and calls the 'main' function. In contrast,
|
|
hybrid programs start their execution with the startup code of the host's
|
|
libc, leaving the Genode-specific initializations unexecuted. To make sure
|
|
that these initializations are performed prior any application code, the
|
|
'lx_hybrid' library contains a highly prioritized constructor called
|
|
'lx_hybrid_init' that performs those initializations as a side effect.
|
|
|
|
|
|
L4ka::Pistachio microkernel
|
|
===========================
|
|
|
|
The Pistachio kernel recently moved from the Mercurial to the Git (on Github)
|
|
version control system. We have updated the configuration and build process of
|
|
the kernel and user-land tools within Genode accordingly.
|
|
|
|
Genode's 11.11 tool chain also required an adaption of the system call bindings
|
|
on x86. This was caused by a change of GCC inline assembler input constraint
|
|
handling. GCC now passes memory constraints using stack-relative addressing,
|
|
which can lead to serious problems when manipulating the stack pointer within
|
|
the assembly code.
|
|
|
|
|
|
Build system and tools
|
|
######################
|
|
|
|
New tool chain based on GCC 4.6.1
|
|
=================================
|
|
|
|
Early on in the genesis of Genode, we introduced a custom tool chain to
|
|
overcome several problems inherent to the use of standard tool chains installed
|
|
on Linux host platforms.
|
|
|
|
First, GCC and binutils versions vary a lot between different Linux systems.
|
|
Testing the Genode code with all those different tool chains and constantly
|
|
adapting the code to the peculiarities of certain tool-chain versions is
|
|
infeasible and annoying. Second, Linux tool chains use certain features that
|
|
stand in the way when building low-level system components. For example, the
|
|
'-fstack-protector' option is enabled by default on some Linux distributions.
|
|
Hence, we have to turn it off when building Genode. However, some tool chains
|
|
lack this option. So the attempt to turn it off produces an error. The most
|
|
important problem with Linux tool chains is the dependency of their respective
|
|
GCC support libraries on the glibc. When not using a Linux glibc, as the case
|
|
with Genode, this leads to manifold problems, most of them subtle and extremely
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hard to debug. For example, the support libraries expect the Linux way of
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implementing thread-local storage (using segment registers on x86_32). This
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code will simply crash on other kernels. Another example is the use of certain
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C-library functions, which are not available on Genode. Hence, Genode provides
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custom implementations of those functions (in the 'cxx' library).
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Unfortunately, the set of functions used varies across tool-chain versions. For
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these reasons, we introduced a custom configured tool chain where we mitigated
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those problems by pinning the tools to certain versions and tweaking the
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compiler configuration to our needs (i.e., preventing the use of Linux TLS).
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That said, the use a our custom configured tool chain was not free from
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problems either. In particular, the script for creating the tool chain relied
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on a libc being present on the host system. The header files of the libc would
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be used to build the GCC support libraries. This introduced two problems. When
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adding Genode's libc to the picture, which is based on FreeBSD's C library, the
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expectations of the GCC support libraries did not match 100% with the semantics
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implemented by Genode's libc (e.g., the handling of 'errno' differs). The
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second problem is the limitation that the tool chain could only be built for
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the platform that corresponds to the host. For example, on a Linux-x86_32
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system, it was not possible to build a x86_64 or ARM tool chain. For this
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reason we used the ARM tool chains provided by CodeSourcery.
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With Genode 11.11, we addressed the root of the tool-chain problem by
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completely decoupling the Genode tool chain from the host system that is used
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to build it. The most important step was the removal of GCC's dependency on
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a C library, which is normally needed to build the GCC support libraries. We
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were able to remove the libc dependency by sneaking-in a small custom libc stub
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into the GCC build process. This stub comes in the form of the single header
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file 'tool/libgcc_libc_stub.h' and brings along all type definitions and
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function declarations expected by the support-library code. Furthermore, we
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|
removed all GNU-specific heuristics from the tool chain. Technically, the
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Genode tool chain is a bare-metal tool chain. But in contrast to existing
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bare-metal tool chains, C++ is fully supported.
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|
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With the libc dependency out of the way, we are now free to build the tool
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chain for arbitrary architectures, which brings us two immediate benefits. We
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do no longer have to rely on the CodeSourcery tool chain for ARM. There is now
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a 'genode-arm' tool chain using the same compiler configuration as used on x86.
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The second benefit is the use of multiarch libs on the x86 platform. The
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genode-x86 tool chain can be used for both x86_32 and x86_64, the latter being
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the default.
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|
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The new tool-chain script is located at 'tool/tool_chain'. It takes care of
|
|
downloading all components needed and building the tool chain. Currently, the
|
|
tool chain supports x86 and ARM. Note that the 'tool_chain' script can be
|
|
executed in an arbitrary directory. For example, to build the Genode tool chain
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|
for x86 within your '/tmp/' directory, use the following commands:
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! mkdir /tmp/tool_chain
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! cd /tmp/tool_chain
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! <genode-dir>/tool/tool_chain x86
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After completing the build, you will be asked for your user password to
|
|
enable the installation of the result to '/usr/local/genode-gcc/'.
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|
|
|
Since we introduced GDB support into Genode, we added GDB in addition to GCC
|
|
and binutils to the Genode tool chain. The version is supposed to match the one
|
|
expected by Genode's GDB facility, avoiding potential problems with mismatching
|
|
protocols between GDB monitor and GDB.
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|
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Optimization of the library-dependency build stage
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|
==================================================
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|
|
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The Genode build process consists of two stages. The first stage determines
|
|
inter-library dependencies using non-parallel recursive make. It traverses
|
|
all targets to be built and the libraries those targets depend on, and stores
|
|
the dependency information between libraries and targets in the file
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|
'<build-dir>/var/libdeps'. This generated file contains make rules to be
|
|
executed in the second build stage, which performs all compilation and linking
|
|
steps. In contrast to the first stage, the work-intensive second stage can be
|
|
executed in parallel using the '-j' argument of make. Because of the serialization
|
|
of the first build stage, it naturally does not profit from multiple CPUs.
|
|
This should be no problem because the task of the first stage is simple and
|
|
supposedly executed quickly. However, for large builds including many
|
|
targets, we found the time needed for the first stage to become longer
|
|
than expected. This prompted us to do a bit of profiling.
|
|
|
|
Tracing the 'execve' syscalls of the first build stage via 'strace' evidenced that
|
|
the echo commands used for creating the 'var/libdeps' file attributed
|
|
significantly to the overall time because each echo involves the spawning of a
|
|
shell. There are two counter measures: First, we eagerly detect already visited
|
|
libraries and do not visit them again (originally, this detection was performed
|
|
later when already revisiting the library). This change improves the
|
|
performance by circa 10%. Second and more importantly, the subsequent echo
|
|
commands are now batched into one command featuring multiple echoes. This way,
|
|
only one shell is started for executing the sequence. This improvement leads to
|
|
a performance improvement of about 300%-500%, depending on the size of the
|
|
build. Lesson learned: Using make rules as shell scripts is sometimes a bad
|
|
idea.
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|
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Improved libports and ports package handling
|
|
============================================
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|
|
We also enhanced the package cleanup rules in 'libports'. Now it's possible
|
|
to clean up contribution code package-sensitive analog to the preparation of
|
|
packages. If you don't want to tidy up the whole libports repository, but for
|
|
instance just the LwIP code, just issue:
|
|
|
|
! make clean PKG=lwip
|