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666 lines
32 KiB
Plaintext
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===============================================
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Release notes for the Genode OS Framework 12.08
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===============================================
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Genode Labs
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With Genode 12.08, the project focused on platform support. It enters the world
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of OMAP4-based ARM platforms, revived and vastly enhanced the support for the
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NOVA hypervisor, and becomes able to run directly on ARM platforms without the
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need for an underlying kernel.
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The new 'base-hw' platform is a deviation from Genode's traditional approach to
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complement existing kernels with user-land infrastructure. It completely leaves
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the separate kernel out of the picture and thereby dwarfs the base line of the
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trusted computing base of Genode-based systems to approximately the half. The
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new base platform is described in Section [Genode on naked ARM hardware].
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Speaking of base platforms, we are happy to have promoted the NOVA hypervisor
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to a first-class citizen among the base platforms. During the last months, this
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kernel underwent fundamental changes regarding its mode of development and its
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feature set. This prompted us to vastly improve Genode's support for this
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platform and leverage its unique features. If considering the use of Genode on
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x86-based hardware, NOVA has become a very attractive foundation. Section
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[Embracing the NOVA Hypervisor] describes the NOVA-specific changes.
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The improvement of platform support with the current release does not entail
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the base platforms only but extends to profound additions of device drivers, in
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particular for the ARM-based OMAP4 SoC as used on the popular Pandaboard. We
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are proud to announce the availability of device drivers for HDMI output,
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SD-card, USB HID, and networking for this platform.
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Beyond the low-level platform improvements, the new version comes with several
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new services, optimizations of existing components, and new ported libraries.
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In particular, the Noux runtime has reached a point where we can principally
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execute serious networking applications such as the Lynx web browser natively
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on Genode. Another example is the new FFAT-based file-system service, which
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makes persistent storage available via Genode's file-system interface. By
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combining this new service with existing components such as the partition
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service, Noux, or the file-system plugin of the libc, a lot of new application
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scenarios become available. Thanks to these new components, the framework has
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become able to perform on-target debugging via GDB running in Noux, or host
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the genode.org website via the lighttpd web server,
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:What about the road map?:
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Those of you who track the milestones laid out in our [http:/about/road-map - road map]
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may wonder how Genode 12.08 relates to the stated goals. In fact, several
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points of the road map haven't received the attention as originally planned.
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As an explanation, let us quote the paragraph right atop of the road-map page:
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"The road map is not fixed. If there is commercial interest of pushing the
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Genode technology to a certain direction, we are willing to revisit our plans."
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Well, this is what happened. So we traded the work on the tiled window manager,
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the Intel wireless driver, and SMP support for the work on the platform topics
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outlined above. Nevertheless, we stick to our overall plan to turn Genode into
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a general-purpose OS that is fit for use by its developers by the end of the
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year. If looking closely at the additions that come with the current release,
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it will become apparent how well they fit into the big picture.
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Genode on naked ARM hardware
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############################
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One of Genode's most distinguishing properties is the ability to use the framework
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on top of a range of different kernels. This way, users of the framework
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benefit from the wide variety of features provided by those kernels while
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only dealing with a single API and configuration concept. For example, we
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frequently find ourselves using the Linux kernel as base platform while
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developing services, interfaces, and protocol stacks. By being able to start
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Genode as a regular program, we effectively eliminate the reboot-time for each
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test run and enjoy using commodity debugging and profiling tools. On the other
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hand, if high security is a concern, NOVA and Fiasco.OC provide
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capability-based security at kernel-level. So the use of one of those kernels
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is desirable. Genode allows for switching between those vastly different
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kernels almost seamlessly.
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In general, a Genode system consists of a kernel, Genode's core, and the
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largely generic components on top of core. Core abstracts away the
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peculiarities of the respective kernel and provides a unified API to the
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components on top. From the application's point of view both kernel and core
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are always at the root of the process tree and thereby are a inherent part of
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the application's trusted computing base (TCB). The distinction of both
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programs is almost superficial.
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Since both the kernel and core must be ultimately trusted, the complexity of
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both programs is critical for each Genode-based system. On our quest for
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minimizing the TCB complexity so far, however, we did not question the role of
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the kernel as an inherent part of the TCB and focused our attention to the
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software stack on top. However, with more and more kernels entering the
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picture, we identified that there is typically a considerable overlap in
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functionality between kernel and core. For example, both need to know about
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address spaces and their relationship to physical memory objects. Most kernels
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keep track of memory mappings in an in-kernel database. Core also needs to keep
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track of this information. Consequently, we found several information
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replicated without a clear benefit. With this comes a seemingly significant
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redundancy of code for data structures, allocators, and utility functions.
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Furthermore, there exists a class of problems that must be solved by the kernel
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and core alike. In particular the resource management of dynamically allocated
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in-kernel objects respectively in-core objects. Whereas core uses Genode's
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resource-trading concept to solve this problem, most kernels lack a good
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solution for the management of in-kernel resources and are consequently prone
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to resource exhaustion problems.
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Out of these observations, the idea was born to explore the opportunities of
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merging both programs into one and thereby eliminating the redundancies. Our
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first attempt to go into this direction was the 'base-mb' platform, which
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enabled us to run Genode on the Xilinx MicroBlaze softcore CPU. With this
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experiment, we gained confidence that the approach is generally feasible. So we
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took on the challenge to implement the idea of a hybrid kernel/core on a more
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complex architecture namely ARM Cortex-A9.
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The 'base-hw' platform introduced with the current release is the intermediate
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result of our experiment. With this base platform, core plays the role of core
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and the kernel within one program. A few code paths that require execution in
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privileged mode are executed in kernel mode whereas most code paths are
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executed in user mode. Both user mode code and kernel mode code run in the same
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address space. The kernel portion merely provides a few basic mechanisms
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without performing complex operations such as dynamic memory allocations. For
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example, if core is requested to create a new thread via core's CPU session
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interface, the user-level code within core allocates a KTCB (kernel thread
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control block) and UTCB (user-level thread-control block) from the physical
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memory allocator and passes both physical addresses to the kernel function that
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spawns the actual thread. This way, we can employ Genode's resource-trading
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concept for managing typical kernel resources.
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The experiment turned out to be a great success. Traditionally, we would account
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at least 10,000 lines of code (LOC) for the kernel. Most kernels are actually
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much larger than that. Core comes at a complexity of another 10,000 LOC. So
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both kernel and core make up a base line of TCB complexity of more than 20,000
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LOC. By co-locating core with the kernel, we end up with a program of just
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about 13,000 LOC. The vast reduction of TCB complexity compared to having
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kernel and core as separate programs strikes us.
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The 'base-hw' version of core supports the complete Genode API covering support
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for user-level device drivers, synchronous RPCs, asynchronous notifications,
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shared memory, and managed dataspaces. It is thereby able to execute the
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sophisticated Genode scenarios on top including the GUI, the dynamic linker,
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and user-level device drivers. That said, we regard the current version still
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as work in progress. We successfully use it as an experimentation platform for
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ongoing research activities (i.e., for exploring ARM TrustZone) but some
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important features such as capability-based security are not yet implemented.
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:Using the base-hw platform:
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The new base platform is fully integrated with Genode's build system.
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When listing the supported base platforms via the 'tool/create_builddir' tool,
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you will see the new 'hw_panda_a2', 'hw_vea9x4', 'hw_pbxa9' choices of
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build-directory templates. The latter platform enables you to run a
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'base-hw' Genode system on Qemu.
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[http://genode.org/documentation/platforms/hw - Learn more about using the new base-hw platform...]
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For running Genode directly on the Pandaboard, please refer to the
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[http://genode.org/documentation/platforms/hw_panda_a2 - Pandaboard-specific documentation...]
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Embracing the NOVA Hypervisor
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#############################
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NOVA is a so-called microhypervisor for the x86 architecture. It combines the
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principles of microkernels with capability-based security and hardware-assisted
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virtualization. Among the various base platforms supported by Genode, NOVA's
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kernel interface stands out for being extremely minimalistic and orthogonal,
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even by microkernel standards.
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Genode has supported NOVA as base platform since 2010. But because we used NOVA
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solely for sporadic research activities and NOVA's lack of a regular release
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schedule, the framework's platform support received only little attention. This
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has changed now. NOVA's main developer Udo Steinberg moved from TU Dresden to
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Intel Labs where he leads the development of NOVA as a true Open-Source
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project. In fact, the code is now being hosted at GitHub:
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:[https://github.com/IntelLabs/NOVA]:
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NOVA hypervisor at GitHub
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Since its move to GitHub, the hypervisor has already seen significant
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improvements. The repository is continuously updated, which enables us to stay
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in a close feedback loop with the NOVA developers. This change of how NOVA's
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development is conducted ignited our renewed interest in promoting this
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platform to a first-level citizen of our framework. The first noteworthy
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improvement is the recently added 64-bit support of NOVA. We enabled Genode to
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work with both variants of the kernel - 32 bit and 64 bit.
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But this was just the first step. The second major change addresses the
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allocation of kernel resources. Early versions of the hypervisor allowed each
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process to create kernel objects and thereby indirectly consume the limited
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memory resources of the kernel. This is perfectly fine for a research project
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but it becomes a potential denial-of-service problem in real-world use cases.
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For this reason, newer versions introduced the ability to retain the allocation
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of kernel objects within a trusted component only. In the Genode world, this
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component is naturally core. Even though NOVA still lacks a flexible concept for
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kernel-resource management as of now, Genode has become able to use NOVA
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without suffering the inherent resource management limitation. This is achieved
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because core is able to arbitrate the allocation of kernel resources.
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The third fundamental change is the abolishment of the last traces of global
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names in a NOVA-based Genode system. There are no thread IDs, object IDs, or
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any other kind of globally meaningful names. Each process has a local view on
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(a small part of) the system only. If a process interacts with another process,
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the kernel translates the references to remote objects from one namespace to
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the other. The security implications are eminent. First, a process can only
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interact with or refer to objects for which it has a name, which vastly reduces
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problems of ambient authority. Second, because the kernel translates names, it
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becomes impossible to forge object identities. If a process tried to pass a
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forged object reference to another process, the translation would simply fail,
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rendering the attack ineffective.
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The described changes do not come without issues, though. To make the NOVA
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kernel fit with Genode's requirements, minor patches of the hypervisor are
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needed. The patches are located at 'base-nova/patches/'. However, those patches
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are meant as interim solutions until we find mechanisms that fit well with the
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design of the hypervisor and also fulfil our requirements.
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So far, we greatly enjoyed the revived collaboration with the NOVA developers
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and congratulate Udo Steinberg for the new mode of development of the
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hypervisor.
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Base framework
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##############
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In the following, we describe changes of the base API that may affect users of
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the framework.
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:Allocation of DMA buffers:
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We extended the RAM session interface with the ability to allocate DMA buffers.
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The client specifies the type of RAM dataspace to allocate via the new 'cached'
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argument of the 'Ram_session::alloc()' function. By default, 'cached' is true,
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which corresponds to the common case and the original behavior. When setting
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'cached' to 'false', core takes the precautions needed to register the memory
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as uncached in the page table of each process that has the dataspace attached.
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Currently, the support for allocating DMA buffers is implemented for Fiasco.OC
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only. On x86 platforms, it is generally not needed. But on platforms with more
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relaxed cache coherence (such as ARM), user-level device drivers should always
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use uncacheable memory for DMA transactions.
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:MMIO framework improvements:
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As we find ourselves increasingly using the 'Register' and 'Mmio' templates
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provided by 'util/register.h' and 'util/mmio.h' for dealing with memory-mapped
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devices, we extended the utilities with support for 64-bit registers and a new
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interface for polling bit states. The latter functionality is provided by the
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new 'wait_for' function template. To decouple the MMIO-related utility code
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from an actual timer facility, the function takes a so-called 'delayer' functor
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as argument. This way the user of the MMIO framework is able to pick a timer
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facility that fits best with the device.
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:New 'memcpy' implementation:
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The memory-copy functions provided by 'util/string.h' are extremely simple
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and arguably slow, particularly on platforms where byte-wise copy operations
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are not supported by the CPU (i.e., ARM). Hence, we have added a CPU-specific
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memcpy function ('memcpy_cpu') to 'cpu/string.h', which enables us to
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provide optimized implementations. So far, we did so for the ARM architecture.
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Low-level OS infrastructure
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###########################
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FFat-based file-system service
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==============================
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With the previous release, we introduced Genode's file-system interface
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accompanied with a simple in-memory file-system service. With the addition of
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'ffat_fs', the current release adds the first persistent file system to the
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framework. The service is located at 'libports/src/server/ffat_fs'. It uses
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Genode's 'Block::Session' interface as back end. Therefore, it can be combined
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with any of Genode's block-device drivers and the partition service called
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'part_blk'. To see the new 'ffat_fs' service in action, please refer to the new
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'libports/run/libc_ffat_fs.run' script.
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On the course of our work on the 'ffat_fs' service, we enabled support for long
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file names in libffat and added 'lseek' support to the 'libc_ffat' plugin.
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TAR-based file-system service
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=============================
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The new 'tar_fs' service located at 'os/src/server/tar_fs' provides a read-only
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file-system session interface by reading data from a TAR archive, which, in
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turn, is fetched from a ROM service. By combining 'tar_fs' with the 'libc_fs'
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plugin, it becomes easy to provide customized pseudo file systems to individual
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Genode programs. For example, one instance of 'tar_fs' containing a static
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website and a web-server configuration can be provided as file system to a web
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server. The configuration is similar to the patterns known from the 'tar_rom'
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and 'ram_fs' servers:
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! <config>
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! <archive name="tar_archive.tar" />
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! <policy label="label_of_client" root="/rootdir/for/client" />
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! </config>
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The policy node allows for assigning different parts of one TAR archive to
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different clients. For a practical usage example of 'tar_fs', please refer to
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the 'libports/run/libc_fs_tar_fs.run' script.
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Terminal improvements
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=====================
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Our work on running a growing number of command-line-based Unix programs via
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Noux prompted us to improve our terminal implementation as needed. To ease
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debugging for terminal colors, we changed the previous default color scheme to
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fully saturated combinations of red, green, and blue. Albeit this looks quite
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painful on the eyes, it is easier to spot wrong colors when using a program
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that uses ncurses, for example Lynx. Furthermore, we added the handling of
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sgr0 and sgr escape sequences and thereby enabled Lynx to become almost
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usable when running within Noux.
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Terminal cross-link service
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===========================
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The 'Terminal::Session' interface gets increasingly popular within Genode.
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It is used by the UART drivers, the graphical terminal, GDB monitor, the TCP
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terminal, and Noux. For most of these programs, their respective client or
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server role is quite clear but we find ourselves tempted to combine components
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in unusual ways. For example, to let Noux run an instance of GDB, which operates
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on a terminal via a virtual character device. For remote debugging, GDB plays
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the role of a terminal client and the UART driver plays the role of the server.
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But when running GDB monitor on the same machine, GDB monitor will also
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expect to play the role of the client. In order to connect GDB monitor
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to a local instance of GDB, both of them being terminal clients, we need an
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adapter component. This is where the new terminal cross-link service enters
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the picture. It plays the role of a terminal server between exactly two
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clients. The output of one client ends up as input to the other and vice
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versa. Data sent to the server gets stored in a buffer of 4096 bytes (one
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buffer per client). As long as the data to be written fits into the buffer, the
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'write()' call returns immediately. If no more data fits into the buffer, the
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'write()' call blocks until the other client has consumed some of the data from
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the buffer via the 'read()' call. The 'read()' call never blocks. A signal
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receiver can be used to block until new data is ready for reading.
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The new terminal crosslink can be tested via the 'os/run/terminal_crosslink.run'
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script. It is also used for the just mentioned on-target debugging scenario
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demonstrated by the 'ports/run/noux_gdb.run' script.
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DMA-aware and optimized packet streams
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======================================
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Motivated by our work on OMAP4 platform support, we introduced API extensions
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for handling of DMA buffers to the following interfaces:
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:'Attached_ram_dataspace':
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The convenience utility for allocating and locally mapping a RAM dataspace
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has been enhanced with the 'cached' constructor argument, which is true
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by default. When using 'Attached_ram_dataspace' for allocating DMA buffers,
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this argument should be set to false.
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:Block and network packet stream:
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The 'Block::Session' and 'Nic::Session' interfaces use Genode's packet stream
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facility for transferring bulk payload between processes. A packet stream
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combines shared memory with asynchronous notifications and thereby facilitates
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the use of batched packet processing. To principally enable zero-copy semantics
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for device drivers, the packet-stream buffer is now explicitly allocated as DMA
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|
buffer. This clears the way to let the SD-card driver direct DMA transactions
|
||
|
right into the packet stream buffer. Consequently, when attaching the SD-card
|
||
|
driver directly to a file system, there is no copy of payload needed.
|
||
|
|
||
|
The 'Nic::Session' interface has further been improved by using a fast
|
||
|
bitmap allocator for allocations within the packet-stream buffer. This is
|
||
|
possible because networking packets have the MTU size as an upper limit.
|
||
|
In contrast to the 'Block::Session' interface where requests are relatively
|
||
|
large, 'Nic::Session' packets are tiny, and thus, greatly benefit from the
|
||
|
optimized allocator.
|
||
|
|
||
|
|
||
|
Libraries and applications
|
||
|
##########################
|
||
|
|
||
|
C runtime
|
||
|
=========
|
||
|
|
||
|
:File I/O:
|
||
|
|
||
|
We complemented our C runtime with support for the 'pread', 'pwrite', 'readv',
|
||
|
and 'writev' functions. The 'pread' and 'pwrite' functions are shortcuts for
|
||
|
randomly accessing different parts of a file. Under the hood, the functions are
|
||
|
implemented via 'lseek' and 'read/write'. To provide the atomicity of the
|
||
|
functions, a lock guard prevents the parallel execution of either or both
|
||
|
functions if called concurrently by multiple threads. The 'readv' and 'writev'
|
||
|
functions principally enable the chaining of multiple I/O requests.
|
||
|
Furthermore, we added 'ftruncate', 'poll', and basic support for (read-only)
|
||
|
mmapped files to the C runtime.
|
||
|
|
||
|
:Libc RPC framework headers:
|
||
|
|
||
|
Certain RPC headers of the libc are needed for compiling 'getaddrinfo.c'.
|
||
|
Unfortunately that means we have to generate a few header files, which we do
|
||
|
when we prepare the libc.
|
||
|
|
||
|
|
||
|
New and updated 3rd-party libraries
|
||
|
===================================
|
||
|
|
||
|
:Expat:
|
||
|
|
||
|
[http://expat.sourceforge.net - Expat] is an XML parsing library. The port of
|
||
|
this library was motivated by our goal to use the GNU debugger for on-target
|
||
|
debugging. GDB depends on this library.
|
||
|
|
||
|
:MPC and GMP:
|
||
|
|
||
|
We complemented our existing port of the
|
||
|
[http://gmplib.org - GNU multiple precision arithmetic library (libgmp)] with
|
||
|
support for the x86_64 and ARM architectures. This change combined with the
|
||
|
port of the [http://www.multiprecision.org/index.php?prog=mpc - MPC library]
|
||
|
enables us to build the Genode tool chain for these architectures.
|
||
|
|
||
|
:OpenSSL:
|
||
|
|
||
|
Our port of OpenSSL has been updated to version 1.0.1c. Because libcrypto
|
||
|
provides certain optimized assembler functions, which unfortunately are not
|
||
|
expressed with position-independent code, we removed this assembler code and
|
||
|
build libcrypto with '-DOPENSSL_NO_ASM'. Because the assembler code is not
|
||
|
needed anymore, its generation is also removed from 'openssl.mk'.
|
||
|
|
||
|
:Light-weight IP stack (lwIP):
|
||
|
|
||
|
We enabled the lwIP TCP/IP stack for 64-bit machines and updated the library to
|
||
|
version 1.4.1-rc1. With the new version, the call of 'lwip_loopback_init' is
|
||
|
not needed anymore because lwIP always creates a loopback device. Hence, we
|
||
|
will be able to remove the 'libc_lwip_loopback' in the future. For now, we keep
|
||
|
it around so we currently do not need to update the other targets that depend
|
||
|
on it.
|
||
|
|
||
|
:PCRE:
|
||
|
|
||
|
[http://www.pcre.org/ - PCRE] is a library for parsing regular rexpressions. We
|
||
|
require this library for our ongoing work on porting the lighttpd webserver.
|
||
|
|
||
|
|
||
|
Lighttpd web server
|
||
|
===================
|
||
|
|
||
|
The [http://www.lighttpd.net/ - Lighttpd] web server has been added to the
|
||
|
'ports' repository. The port runs as a native Genode application and ultimately
|
||
|
clears the way to hosting the genode.org website on Genode. To test drive this
|
||
|
scenario, please give the 'ports/run/genode_org.run' script a try.
|
||
|
|
||
|
At the current stage, the port is still quite limited. For example, it does not
|
||
|
make use of non-blocking sockets yet. But the 'genode_org.run' run script
|
||
|
already showcases very well how simple a Genode-based web-server appliance can
|
||
|
look like.
|
||
|
|
||
|
|
||
|
Device drivers
|
||
|
##############
|
||
|
|
||
|
OMAP4 platform drivers
|
||
|
======================
|
||
|
|
||
|
:HDMI output:
|
||
|
|
||
|
The new HDMI driver at 'os/src/drivers/framebuffer/omap4' implements Genode's
|
||
|
'Framebuffer::Session' interface by using the HDMI output of OMAP4. The current
|
||
|
version sets up a fixed XGA screen mode of 1024x768 with the RGB565 pixel
|
||
|
format.
|
||
|
|
||
|
|
||
|
:SD-card:
|
||
|
|
||
|
The new SD card driver at 'os/src/drivers/sd_card/omap4' allows the use of a
|
||
|
HDSD card with the Pandaboard as block service. The driver can be tested using
|
||
|
the 'os/run/sd_card.run' script. Because it implements the generic
|
||
|
'Block::Session' interface, it can be combined with a variety of other
|
||
|
components such as 'part_blk' (for accessing individual partitions) or
|
||
|
'ffat_fs' for accessing a VFAT file system on the SD card.
|
||
|
|
||
|
The driver uses the master DMA facility of the OMAP4 SD-card controller, which
|
||
|
yields to good performance at low CPU utilization. The throughput matches (and
|
||
|
in some cases outperforms) the Linux kernel driver. In the current version,
|
||
|
both modes of operation PIO and DMA are functional. However, PIO mode is
|
||
|
retained for benchmarking purposes only and will possibly be removed to further
|
||
|
simplify the driver.
|
||
|
|
||
|
|
||
|
:USB HID:
|
||
|
|
||
|
The OMAP4-based Pandaboard relies on USB for attaching input devices.
|
||
|
Therefore, we need a complete USB stack to enable the interactive use of the
|
||
|
board. Instead of implementing a USB driver from scratch, we built upon the USB
|
||
|
driver introduced with the Genode release 12.05. This driver was ported from the
|
||
|
Linux kernel.
|
||
|
|
||
|
|
||
|
:Networking:
|
||
|
|
||
|
The Pandaboard realizes network connectivity via the SMSC95xx chip attached to
|
||
|
the USB controller. Therefore, we enhanced our USB driver with support for USB
|
||
|
net and the smsc95xx driver. In addition to enabling the actual device-driver
|
||
|
functionality, the USB stack has received much attention concerning performance
|
||
|
optimizations. To speed up the allocation of SKBs, we replaced the former
|
||
|
AVL-tree based allocator with a fast bitmap allocator. For anonymous
|
||
|
allocations, we introduced a slab-based allocator. Furthermore, we introduced
|
||
|
the distinction between memory objects that are subjected to DMA operations
|
||
|
from non-DMA memory objects. The most profound conceptual optimization is the
|
||
|
use of transmit bursts by the driver. The Linux kernel, which our driver
|
||
|
originates from, does not provide an API for transmitting multiple packets as a
|
||
|
burst. For our driver, however, this optimization opportunity opened up thanks
|
||
|
to Genode's packet stream interface, which naturally facilitates the batching
|
||
|
of networking packets. So the driver has all the information needed to create
|
||
|
burst transactions.
|
||
|
|
||
|
|
||
|
USB driver
|
||
|
==========
|
||
|
|
||
|
By testing our new USB driver on a variety of real PC hardware, we discovered
|
||
|
several shortcomings, which we resolved. In particular, we added support for
|
||
|
more than one UHCI controller, make sure that the 'PIRQ' bit in the legacy
|
||
|
support register (PCI config space) of the UHCI controller is enabled and that
|
||
|
the 'Trap on IRQ' bit is disabled.
|
||
|
|
||
|
With those modifications in place, the USB driver works reliably on the tested
|
||
|
platforms.
|
||
|
|
||
|
|
||
|
Runtime environments
|
||
|
####################
|
||
|
|
||
|
Noux
|
||
|
====
|
||
|
|
||
|
Noux enables the easy reuse of unmodified GNU software on Genode by providing
|
||
|
a Unix-like kernel interface as user-level service. Because Noux is pivotal for
|
||
|
our plan to use Genode for productive work, we significantly enhanced and
|
||
|
complemented its feature set.
|
||
|
|
||
|
|
||
|
:Noux on ARM and x86_64:
|
||
|
|
||
|
For keeping the scope of the development manageable, the initial version of
|
||
|
Noux was tied to the x86_32 platform. This was not a principal limitation of
|
||
|
the approach but rather an artificial restriction to keep us focused on
|
||
|
functionality first. Now that Noux reaches a usable state, we desire to use it
|
||
|
on platforms other than x86_32. The current release enables Noux for the 64-bit
|
||
|
x86 and ARM architectures.
|
||
|
|
||
|
The level of support is pretty far-reaching and even includes the building and
|
||
|
execution of the Genode tool chain on those platforms. In the process of
|
||
|
enabling these platforms, we updated the Noux package for GCC to version 4.6.1,
|
||
|
which matches the version of the current Genode tool chain.
|
||
|
|
||
|
|
||
|
:Terminal file system:
|
||
|
|
||
|
Noux supports the concept of stacked file systems. The virtual file system
|
||
|
is defined at the start of a Noux instance driven by the static Noux
|
||
|
configuration. This way, arbitrary directory structures can be composed out
|
||
|
of file-system sessions and TAR archives. The VFS concept allows for the
|
||
|
easy addition of new file system types. To allow programs running in a Noux
|
||
|
instance to communicate over a dedicated terminal session, we added a new
|
||
|
file-system type that corresponds to a virtual character device node attached
|
||
|
to a terminal session.
|
||
|
|
||
|
|
||
|
:GDB running in the Noux environment:
|
||
|
|
||
|
With the terminal file system in place, we are ready to execute GDB within
|
||
|
Noux and let it talk to a GDB monitor instance over the terminal session
|
||
|
interface. From GDB's point of view, the setup looks like a remote debugging
|
||
|
session. But in reality both the debugging target and GDB reside in different
|
||
|
subtrees of the same Genode system.
|
||
|
|
||
|
|
||
|
:Executing shell scripts:
|
||
|
|
||
|
By inspecting the program specified to the execve system call, Noux has become
|
||
|
able to spawn scripts that use the '#!' syntax. If such a file is detected, it
|
||
|
executes the specified interpreter instead and passes the arguments specified
|
||
|
after the '#!' marker, followed by command-line arguments.
|
||
|
|
||
|
|
||
|
:Networking support:
|
||
|
|
||
|
Our work on porting various networking tools to Noux triggers us to steadily
|
||
|
improve the networking support introduced with Genode 12.05. In particular, we
|
||
|
added proper support for DNS resolving, which enables us to execute the
|
||
|
command-line based Lynx web browser within Noux.
|
||
|
|
||
|
|
||
|
:User information:
|
||
|
|
||
|
Because there are certain programs, which need the information that is stored
|
||
|
in 'struct passwd', we introduced configurable user information support to
|
||
|
Noux. One can set the user information via the '<user>' node in the Noux
|
||
|
config:
|
||
|
|
||
|
! <config>
|
||
|
! <user name="baron" uid="1" gid="1">
|
||
|
! <shell name="/bin/bash" />
|
||
|
! <home name="/home" />
|
||
|
! </user>
|
||
|
! ...
|
||
|
! </config>
|
||
|
|
||
|
When '<user>' is not specified, default values are used. Currently these
|
||
|
are 'root', 0, 0, '/bin/bash', '/'. Note that this is just a single user
|
||
|
implementation because each Noux instance has only one user or rather one
|
||
|
identity and there will be no complete multi-user support in Noux. If you need
|
||
|
different users, just start new Noux instances for each of them.
|
||
|
|
||
|
|
||
|
:New '/dev/null' and '/dev/zero' pseudo devices:
|
||
|
|
||
|
These device are mandatory for most programs (well, at least null is required
|
||
|
to be present for a POSIX compliant OS, which Noux is actually not). But for
|
||
|
proper shell-script support we will need them anyway. Under the hood, both
|
||
|
pseudo devices are implemented as individual file-systems and facilitate Noux's
|
||
|
support for stacked file systems. The following example configuration snippet
|
||
|
creates the pseudo devices under the '/dev' directory.
|
||
|
|
||
|
! <config>
|
||
|
! <fstab>
|
||
|
! <dir name="dev" >
|
||
|
! <null /> <zero />
|
||
|
! </dir>
|
||
|
! ...
|
||
|
! <fstab>
|
||
|
! ...
|
||
|
! </config>
|
||
|
|
||
|
|
||
|
Vancouver
|
||
|
=========
|
||
|
|
||
|
The comprehensive rework of the NOVA base platform affected the Genode version
|
||
|
of the Vancouver virtual machine monitor as this program used to speak directly
|
||
|
to the NOVA kernel. Since no kernel objects can be created outside of core
|
||
|
anymore, the Vancouver port had to be adjusted to solely use Genode interfaces.
|
||
|
|
||
|
|
||
|
L4Linux
|
||
|
=======
|
||
|
|
||
|
To improve the stability and performance of L4Linux on OMAP4 platforms, we
|
||
|
reworked parts of the Genode-specific stub drivers, in particular the
|
||
|
networking code. Among the improvements are the use of a high-performance
|
||
|
allocator for networking packets, improved IRQ safety of IPC calls (to
|
||
|
the Genode world), and tweaks of the TCP rmem and wmem buffer sizes to
|
||
|
achieve good TCP performance when running Linux with little memory.
|
||
|
|
||
|
Furthermore, we added two ready-to-use run scripts residing within
|
||
|
'ports-foc/run' as examples for executing L4Linux on the OMAP4-based
|
||
|
Pandaboard. The 'linux_panda.run' script is meant as a blue print for
|
||
|
experimentation. It integrates one instance of L4Linux with the native SD-card
|
||
|
driver, the HDMI driver, and the USB HID input driver. The
|
||
|
'two_linux_panda.run' script is a more elaborative example that executes two
|
||
|
instances of L4Linux, a block-device test, and a simple web server. Each of
|
||
|
the L4Linux instances accesses a different SD-card partition whereas the
|
||
|
block-device test operates on a third partition.
|
||
|
|
||
|
|