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1217 lines
60 KiB
Plaintext
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===============================================
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Release notes for the Genode OS Framework 15.05
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===============================================
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Genode Labs
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Version 15.05 represents the most substantial release in the history of Genode.
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It is packed with profound architectural improvements, new device drivers, the
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extension of the supported base platforms, and a brand new documentation.
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With the new documentation introduced in Section [Comprehensive architectural documentation],
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the project reaches a mile stone. On our mission to find the right
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architectural abstractions, the past years had a strong research focus. We
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conducted countless of experiments, gathered experience with highly diverse
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hardware platforms and kernels, and explored application scenarios. Our target
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audience used to be technology enthusiasts. Now that we have reached a point
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where the architecture is mature, it is the time to invite a wider audience,
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in particular people who are interested in building Genode-based solutions.
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The new book "Genode Foundations" equips the reader with the holistic view and
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the technological insights needed to get started.
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Genode's custom kernel platform, originally conceived as a research vehicle,
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has become feature complete. As explained in Section
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[Feature completion of our custom kernel (base-hw)], the release contains
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three substantial additions. First, with the added support for the 64-bit x86
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architecture, the kernel moves beyond the realms of the ARM architecture. This
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line of work is particularly exciting because it was conducted outside of
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Genode Labs, by the developers of the Muen separation kernel. The second
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addition introduces kernel-protected capabilities to the base-hw kernel. This
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was the last missing functionality that stood in the way of using the kernel
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in security-critical scenarios. Finally, the kernel's scheduler received the
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ability to handle thread weights in a dynamic fashion.
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With revising the framework's device-driver infrastructure as described in
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Section [Revised device-driver infrastructure], this release addresses
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long-standing architectural limitations with respect to the effective
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confinement of device drivers. This topic encompasses changes in the NOVA
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kernel, a redesign of the fundamental interfaces for user-level device
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drivers, the design and implementation of a new platform driver, and the
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adaptation of the drivers. Speaking of device drivers, the version 15.05 comes
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with a new AHCI driver, new audio drivers ported from OpenBSD, new SD-card
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drivers for the Raspberry Pi and i.MX53, platform support for i.MX6, and
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multi-touch support.
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The icing on the cake is the added support for the seL4 kernel as Genode base
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platform. Section [Proof-of-concept support for the seL4 kernel] covers this
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undertaking. Even though this work is still in its infancy, we are happy to
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present the first simple Genode scenarios running on this kernel.
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Comprehensive architectural documentation
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#########################################
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The popularity of Genode is slowly but steadily growing. Still, for most
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uninitiated who stumble upon it, the project remains largely intangible
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because it does not fit well in the established categories of software. With
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the current release, we hope to change that. The release is accompanied by a
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documentation in the form of the book "Genode OS Framework Foundations"
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completely written from scratch:
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[image genode_foundations_cover]
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The book is published under the Creative Commons Attribution + ShareAlike
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License (CC-BY-SA) and can be downloaded as
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[https://genode.org/documentation/genode-foundations-15-05.pdf - PDF document].
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It first presents the motivation behind our project, followed by a thorough
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description of the Genode OS architecture. The conceptual material is
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complemented with practical information for developers and a discussion of
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framework internals. The second part of the book serves as a reference of
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Genode's programming interfaces.
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[https://genode.org/documentation/genode-foundations-15-05.pdf - Download the book (PDF)...]
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In the upcoming weeks, we plan to update the documentation section of the
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genode.org website with the new material. Until then, we hope you find the
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book enjoyable.
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Feature completion of our custom kernel (base-hw)
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#################################################
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Kernel-protected capabilities
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=============================
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One of the fundamental concepts used within Genode are capabilities. Although
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this security mechanism was present in the Genode API from the very beginning,
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our base-hw kernel could not guarantee the integrity of capabilities so far.
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On top of this kernel, capabilities used to be represented as global IDs that
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could get forged easily until now.
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With this release, we introduce a major change of base-hw, which now supports
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capability ID spaces per component. That means every component respectively
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protection-domain has its own local name space for kernel objects. When a
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component invokes a capability to access an RPC object, it provides the
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corresponding capability ID to the kernel's system call. The kernel maintains
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a tree of capability IDs per protection domain and can retrieve whether the
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provided ID is valid and to which kernel object it points to. As all kernel
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objects are constructed on behalf of the core process first, this component
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always owns the initial capability during the lifetime of a kernel object.
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Other components can obtain capabilities via remote-procedure calls (RPC)
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only. Whenever a capability is part of a message transfer between threads,
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the kernel translates the capability IDs within the message buffer from one
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protection domain's capability space to another. If the target protection
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domain does not own the capability during the transfer already, the kernel
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creates a new capability ID for the receiving protection domain.
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In contrast to other capability-based kernels that Genode supports, the
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base-hw kernel manages the capability space on behalf of the components.
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Nevertheless, as the kernel does not know whether a component is still using a
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capability ID, even though the kernel object behind it got invalidated
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already, components have to inform the kernel when a capability ID is not used
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anymore so that is can be reused again. Therefore, we introduce a new
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system-call 'delete_cap', which frees a capability ID from the local
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protection domain.
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To allocate entries in the capability space of components, the kernel needs
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memory. The required memory is taken from the RAM quota a component provides
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to its protection-domain session. If the kernel determines that the quota does
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not fulfill the requirements when a component wants to receive capabilities,
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the corresponding system-call delivers an error before the actual IPC
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operation takes place. The component first has to upgrade the RAM quota before
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it can retry its IPC operation. The procedure of IPC error-handling is
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transparent to the developer and already solved by the base library
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implementation for the base-hw kernel.
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Principal support for the 64-bit x86 architecture
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=================================================
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_This section was written by Adrian-Ken Rueegsegger and Reto Buerki who_
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_conducted the described line of work independent from Genode Labs._
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The [https://muen.sk - Muen Separation Kernel (SK) project] is an Open-Source
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microkernel, which uses the [https://spark-2014.org/ - SPARK] programming
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language to enable light-weight formal methods for high assurance. The 64-bit
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x86 kernel, currently consisting of a little over 5'000 LOC, makes extensive
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use of the latest Intel virtualization features and has been formally proven
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to contain no runtime errors at the source-code level.
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As the core team of the Muen SK, we were intrigued by the idea of bringing
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Genode to our kernel. In our view, combining Genode with the Muen project
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makes perfect sense as it would allow us to leverage the entire OS framework
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instead of re-inventing the wheel by implementing yet another user land.
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To this end, we met the Genode team in their very cosy office in Dresden.
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After a tour of the premises, we got right down to business: Norman gave us a
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whirlwind tour of Genode and it was quickly decided that the way forward would
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be to run base-hw as a subject on top of Muen. As an intermediate step, we
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needed to port base-hw from ARM to Intel x86_64 first.
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The Genode team gave us a head start by setting a roadmap and doing the
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initial steps of extending the 'create_builddir' tool and adding the
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'hw_x86_64' skeleton in a joint coding session. After this productive
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workshop, we flew back to Switzerland with a clear picture of how to proceed.
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Implementation
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~~~~~~~~~~~~~~
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We closely followed the roadmap for porting the base-hw kernel to the 64-bit
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x86 architecture. The following list discusses the work items in detail,
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summarizing the interesting points.
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# Assembler startup code
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Prior to the addition of our x86_64 port, base-hw was an ARM-only kernel.
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Therefore, the boot code for the new platform had to be written from scratch.
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Having already written a 64-bit x86 kernel, we were able to reuse its boot
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up code pretty much unchanged.
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# Memory management/IA-32e paging
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Since transitioning to the IA-32e (long) mode requires paging, an initial set
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of static page tables is part of the assembler startup code. For dynamic
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memory management support however, a C++ implementation for creating IA-32e
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paging structures was required. Similar to the startup code, we could draw
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from the experiences made when implementing paging in the Muen project. One
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minor obstacle was to get reacquainted with the C++ template mechanism.
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Aside from that, there were no other issues and the subsequent implementation
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was quite straight-forward.
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# Assembler mode-switch code
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The mode-transition code (MTC) takes care of switching from kernel-
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to user-space and back. It consists of architecture-dependent assembly code
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accessible to both kernel- and user-land.
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A transition from user- to kernel-space occurs either explicitly by the
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invocation of a syscall, or when an exception or interrupt occurs. The
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mode-transition code saves the current context and restores the kernel state
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or vice-versa when returning to user-mode from the kernel. To unify the
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exception and syscall code paths on exit, we decided to implement syscall
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invocation using the _int 0x80_ method instead of using the _SYSCALL/SYSRET_
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machine instructions.
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The peculiarities of the x86 architecture needed some attention to detail.
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In contrast to ARM, several data structures such as the GDT (Global
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Descriptor Table), IDT (Interrupt Descriptor Table) and TSS (Task-State
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Segment) are implicitly referenced by the hardware and must be accessible on
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entry into the mode-transition code from user-land. Thus, these tables must
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be placed in the MTC memory region as otherwise, the hardware would trigger
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a page fault.
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# Interrupt controller implementation
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The interrupt controller handles external interrupts triggered by devices.
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After a little detour (see _PIC/PIT detour_ below), we ended up using the
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local and I/O APIC for interrupt management. One annoying implementation
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detail worth mentioning is the handling of edge-triggered interrupts by the
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I/O APIC. As described in the Intel 82093AA I/O Advanced Programmable
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Interrupt Controller (IOAPIC) specification, Section 3.4.2, edge-triggered
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interrupts are lost if they occur while the mask bit of the corresponding
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I/O APIC RTE (Routing Table Entry) is set. Therefore, we chose the pragmatic
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approach not to mask edge-sensitive IRQs at all.
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The issue of lost IRQs came up when dealing with the user-space PIT
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(Programmable Interval Timer): The PIT driver would program the timer with a
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short timeout and then unmask the corresponding IRQ line. If the timer fired
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prior to completion of the unmask operation, the interrupt would be lost,
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which, in turn, resulted in the driver being blocked forever.
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# Kernel-timer implementation
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The x86 platform provides a variety of timer sources, each of which bringing
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its own bag of problems. After switching to the LAPIC for interrupt
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management, the obvious choice was to use the LAPIC for the kernel timer as
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well. The drawback of this timer is that its frequency must be measured
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using a secondary source as reference. Luckily, we were able to reuse the
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PIT driver, which resulted from our _PIC/PIT detour_ for this purpose.
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# FPU support
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To allow user-space code to use floating-point arithmetics, we needed to
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handle the state of the x87 FPU. Similar to the ARM code, the FPU state is
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saved and restored in a lazy manner, meaning the necessary work is only
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performed if the FPU is actually used.
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After making a small number of additional adjustments to core, we were able to
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successfully execute even elaborate run scripts such as 'run/demo' on the
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newly ported x86_64 base-hw kernel.
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PIC/PIT detour
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--------------
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As described in the introduction, porting the base-hw kernel to the Intel
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x86_64 architecture is only an intermediate step towards the ultimate goal of
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bringing Genode to the Muen platform. To this end, we took a pragmatic
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approach with regards to hardware drivers that are required for x86_64 but
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will be paravirtualized on Muen. The interrupt controller and kernel timer
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fall in this category. Because of simplicity reasons, we initially decided to
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use the 8259 Programmable Interrupt Controller (PIC) and the 8253/8254
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Programmable Interval Timer (PIT). We quickly had a working implementation but
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later became aware that the only currently available Genode user-land timer on
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x86 was the PIT. This was obviously a problem because, kernel and user-land
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require separate timer sources.
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After some discussion, we decided to rewrite the kernel interrupt controller
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and timer code to use the LAPIC/IOAPIC. This freed up the PIT for use by the
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user-land driver. Since we were able to reuse the PIT code for measuring the
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LAPIC timer frequency, the detour was in fact beneficial to stabilize the
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final implementation. Additionally, these changes lay the foundation for
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future 'hw_x86_64' multiprocessor support.
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Taking hw_x86_64 for a spin
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~~~~~~~~~~~~~~~~~~~~~~~~~~~
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In order to try out the new 'hw_x86_64' port, perform the following steps:
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! tool/create_builddir hw_x86_64
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Prepare the ports required by the demo script:
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! tool/ports/prepare_port x86emu
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Change to the build directory:
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! cd build/hw_x86_64/
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Note: Make sure to enable the libports repository by editing the
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_etc/build.conf_ file.
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Finally, fire up the demo script:
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! make run/demo
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Limitations
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~~~~~~~~~~~
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The current implementation of the x86_64 base-hw kernel has the following
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limitations:
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* No dynamic memory discovery: The amount of memory is hard-coded to 256 MiB.
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* No 32-bit support
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* No SMP support
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These are not fundamental restrictions of the base-hw x86_64 port but simply
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missing features that can be implemented in the future.
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Sentiments
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~~~~~~~~~~
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Considering that the base-hw kernel was an ARM-only microkernel, the port to
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x86_64 went rather smoothly. In our opinion, this is a testament to the
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modularity and the good overall design of the kernel. Architecture-specific
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code is well encapsulated and the provided abstractions allow the overriding
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of functionality at the appropriate level.
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An interesting fact worth mentioning is that while emulators such as Qemu and
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Bochs are great tools for development, it is important to perform tests on
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real hardware as well. Since the hardware is emulated with varying degrees of
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accuracy, subtle differences in behavior can go unnoticed. A recurring source
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of potential problems is the initial state of memory. Whereas emulators
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usually fill unused memory with zeros, on real hardware the content of
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uninitialized memory is undefined. So while code that only partially
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initializes memory may run without issues on Qemu, it is quite possible that
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it simply fails on real hardware.
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After finishing the base-hw port to 64-bit x86, we immediately started working
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on the Muen port. As a little spoiler, we can report that the run/demo
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scenario is already running as a subject on top of the Muen SK. We hope that
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it will be part of the next Genode release.
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Last but not least, we would like to thank the guys at Genode Labs for their
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support and we are eager to see where this fruitful cooperation will take us.
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Dynamic thread weights
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======================
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With the Genode release 14.11, we introduced an entirely
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[https://genode.org/documentation/release-notes/14.11#Trading_CPU_time_between_components_using_the_HW_kernel - new scheduler]
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in the base-hw kernel that allows for the trading of CPU time between Genode
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components. This scheduler knows two parameters for each scheduling context: A
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priority that models the urgency for low-latency execution and a quota that
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limits the prioritized execution time of a context during one super period.
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The user may adjust these parameters according to his demands by the means of
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userland configuration. Through configuration files, the inter-component
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distribution of priority and quota is configured whereas the
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component-internal distribution of computation time is addressed by Genode's
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thread API.
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However, during the last months, the way of configuring the local distribution
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of quota appeared to be not very satisfying for real-world scenarios. To assign
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quota to a thread, one had to state a specific percentage of the component
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quota at construction time. One disadvantage of this pattern becomes apparent
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when looking at the main thread of a component. As the main thread gets
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constructed by the component's parent without using the thread API, the
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component itself has no means to influence the quota of this thread. The quota
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of main threads was therefore always set to zero. Furthermore, a component had
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to keep track of previously consumed thread quotas to be able to not violate
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the local quota limit when creating new threads.
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All this begged for a less rigid way of managing local CPU quota. We came to
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the conclusion that a component does not want to manage quota distribution
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itself but only the importance of threads in the quota distribution, their
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so-called _weight_. This thread weight can be any number greater than zero
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regardless of the weights of other threads. It gets translated to a portion of
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the local quota by setting it into relation to the sum of all local thread
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weights. Consequently, all the assigned quota of a component is distributed
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among the local threads according to their weights. There is no slack quota
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anymore. However, this implies that the quota of all local threads gets
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adjusted each time the constellation of local thread weights changes. That is
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when a new thread gets constructed or an existing one gets destructed. So, we
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must be able to dynamically reconfigure the quota of a scheduling context -
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something the base-hw kernel wasn't aware of hitherto. The new core-restricted
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kernel call named 'thread_quota' solves this issue.
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But let's get back to the thread API. When not explicitly defined, a thread's
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weight is set to 10. So, logically, the main thread of a component always has
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the weight of 10. This value initially equips the main thread with all the
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quota of the component and should leave enough flexibility when configuring
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secondary threads. If the next thread in the component would have the weight
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30, the main thread, from that point on, would receive 25% of the quota while
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the second thread starts with 75%. Let us go on and add a third thread with
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the weight 960. Now, the local quota distribution would be as follows:
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Main thread: 1%
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Second thread: 3%
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Third thread: 96%
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Finally, if one of the threads is destructed, its quota logically moves to the
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remaining two threads divided according to their weight ratio.
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Now, with the comfort of weight-driven quota distribution, there was only the
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question left, how to determine the weights reasonably. We had to provide a
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way to translate a concrete need of execution time into a local thread weight.
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Two things must be known inside a component to do so: The length of a super
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period at the scheduler and how much of this super period the components quota
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is worth. These two values can now be read via a new CPU-session RPC named
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'quota'. The values returned are given in microseconds. However, when using
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this instrument, one must consider slight rounding errors that can't be
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prevented as the values have to pass up to two independent translations from
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the source parameter to the microseconds value.
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Revised device-driver infrastructure
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####################################
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In Genode, core represents the root of the component hierarchy and holds the
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reins. This includes possession of system resources not reserved for the
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kernel, in particular physical resources like RAM, memory-mapped I/O regions,
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I/O ports, and IRQs. Access to resources is gained via session requests, e.g.,
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an IO_PORT session permits access to a dedicated region of x86 I/O ports. Core
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itself does not define any policy on these resources other than starting its
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only child component init, which is qualified to allocate specific resources
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via dedicated sessions to core. In turn, init employs a configured system
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policy and bootstraps additional system components. From the physical
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resources, init manages memory effectively by applying quota restrictions to
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RAM sessions. It does not further differentiate I/O resources besides routing
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session requests to the rather abstract services for IRQ, IO_MEM, and IO_PORT.
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On the other side, device-driver components wish to access registers or drive
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DMA transfers for specific devices only. What was missing up to now, was the
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notion of a _device_ including its I/O resources or role as DMA actuator.
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Motivated by enabling message-signalled interrupt (MSI) support on x86
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platforms, we addressed several shortcomings and revised our device-driver
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infrastructure. First, we noticed that while our ACPI driver (acpi_drv) did a
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proper job with parsing ACPI tables relevant for IRQ remapping, polarity, and
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trigger information, it did not apply any useful policy. The gathered
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information was only propagated to the PCI driver (pci_drv, started as a child
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component) by writing the IRQ remapping information into the PCI configuration
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space of the devices. Though, pci_drv provided the PCI session and thereby
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access to dedicated PCI devices, it did not apply device-specific policies
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either. The PCI session was merely used by device drivers to retrieve
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information about I/O resources, but the session request for the actual
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resources was directed to the driver's parent (and routed to core in most
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cases). Further, the PCI driver was in charge to allocate DMA-able memory on
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behalf of the device driver. This enabled transparent support for IOMMUs on
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NOVA, but also lacked proper quota donation. Last, we identified that the
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current implementation of handling shared IRQs in core completely contradicted
|
|
with our goal of transparently handling interrupts as legacy IRQs or MSIs
|
|
depending on the capabilities of the device as well as the kernel platform.
|
|
|
|
At the end of our survey, we eagerly longed for real I/O resource management
|
|
in a central component, which provides the notion of a device. I/O resources
|
|
are assigned to those devices from the pool of abstract resources available
|
|
from core, e.g., dedicated IO_MEM dataspaces for regions of a PCI device. The
|
|
approach is not completely new in Genode when looking at certain ARM
|
|
platforms, where we have had a platform driver (platform_drv) for quite some
|
|
time. Now, we want to generalize this approach to fit both dynamic discovery
|
|
(e.g., for the PCI bus) and configuration (e.g., specific ARM SoCs or legacy
|
|
devices on PCs). Also, the configuration is expected to support the expression
|
|
of policy to restrict device drivers to access designated device resources
|
|
only.
|
|
|
|
The first working step to tackle the issue was to make the IRQ resource
|
|
available per device within the PCI driver. Until now, core implemented the
|
|
handling of IRQs per platform differently. On some platforms, namely x86, it
|
|
had support for shared IRQs, while other platforms got along without this
|
|
special feature. The biggest stumbling block was actually the synchronous RPC
|
|
interface 'wait_for_irq()', which forced a driver to issue a blocking IPC to
|
|
core to wait for IRQs. We simply disposed this relict of the early L4 times
|
|
and changed the IRQ session interface to employ asynchronous IRQ notifications
|
|
on all Genode platforms. For that reason, we had to adapt the various core
|
|
implementations, the platform drivers, and all device drivers. We refactored a
|
|
generalized shared IRQ implementation on x86 and then, moved it from core to
|
|
the PCI driver, which will become our platform_drv for x86 in a future step.
|
|
After we adapted all x86 drivers to request the IRQ session capability from
|
|
the PCI driver, and completed a thorough testing phase of shared IRQ handling,
|
|
we finally removed the shared IRQ support from core on all Genode platforms.
|
|
|
|
Next, we tackled the issue to transform the previous PCI session into an x86
|
|
platform session (although it is still called PCI session). The platform
|
|
session bundles I/O resources of one or more devices per client. Policies
|
|
define, which of the physical devices are actually visible and are
|
|
discoverable by clients. A client discovers devices either by explicitly
|
|
naming the device, e.g. for non PCI devices like the PS/2 controller, or by
|
|
iterating over a virtual PCI bus as defined by the policy. Besides device
|
|
discovery, a platform session is used for allocating DMA buffers. So, the
|
|
platform driver can take care of associating DMA memory regions with physical
|
|
devices, which is required as soon as IOMMUs are used by the underlying
|
|
kernel.
|
|
|
|
The result of a successful device discovery is a device capability, which
|
|
serves as the key to get access to device-specific resources like IO_MEM,
|
|
IO_PORT, and IRQs. The RPC interface provides functions to request dedicated
|
|
resource capabilities, which are of the types Io_mem_session_capability,
|
|
Io_port_session_capability, and Irq_session_capability.
|
|
|
|
If the device capability represents a PCI device, the IO_PORT and IO_MEM
|
|
resources are discovered by the platform driver by parsing the BARs in the PCI
|
|
configuration space. On behalf of the client, the platform driver establishes
|
|
the I/O resource sessions to core. For non-PCI devices, a device-specific
|
|
implementation is required. For now, only the PS/2 device is supported, which
|
|
bundles two IRQ sessions for mouse and keyboard as well as the well-known I/O
|
|
ports. The IRQ resources for PCI devices are handled differently. First, the
|
|
platform driver parses the PCI config space of a device to detect whether this
|
|
device is capable of MSIs. If so, the platform driver tries to open an IRQ
|
|
session at core, which succeeds on kernels supporting this feature, namely
|
|
Fiasco.OC and NOVA. On kernels lacking MSI support, the request will fail and
|
|
the platform driver falls back to allocate legacy IRQs, which are all treated
|
|
as shared. In either case, the driver does not need to handle the IRQ/MSI
|
|
cases separately as these are handled by the platform driver transparently.
|
|
|
|
The policy is provided by 'policy' entries in the config ROM of the pci_drv.
|
|
An entry corresponds to a virtual bus containing the listed devices, which is
|
|
accessible by drivers with the label configured in the 'label' attribute. PCI
|
|
devices are named by a 'pci' entry either explicitly by the attribute triple
|
|
'bus', 'device', 'function'
|
|
|
|
!<policy label="usb_drv">
|
|
! <pci bus="0" device="19" function="0"/>
|
|
! <pci bus="0" device="5" function="0"/>
|
|
!</policy>
|
|
|
|
or by a device class alias
|
|
|
|
!<policy label="usb_drv"> <pci class="USB"/> </policy>
|
|
|
|
In the first example, the USB driver gets access to two devices, e.g., the
|
|
xHCI and EHCI controller. This explicit approach is useful if the target
|
|
machine and the PCI bus hierarchy are known and security is a concern. Later,
|
|
a dynamic device-manager component could update the config at runtime
|
|
according to a device-discovery report of the platform driver. The second
|
|
option can be used when switching often between machines during development or
|
|
when the target machine is unknown in advance. The downside of the flexibility
|
|
is that a device driver may get access to devices it can't or should not
|
|
drive. For example in a router scenario, the inner network driver should only
|
|
drive the inner NIC while the outer driver gains access to the outer network.
|
|
Both components would then be connected by a secure routing component only.
|
|
Further classes are available and are extended as needed - please consult the
|
|
README of the platform driver for a list.
|
|
|
|
When the ACPI driver is used for Fiasco.OC, NOVA, and base-hw on x86, the
|
|
configuration for the PCI driver is constructed out of the ACPI config XML
|
|
node. Additionally, an explicit policy entry for the ACPI driver is required,
|
|
which permits rewriting potentially all legacy IRQ numbers for PCI devices as
|
|
discovered during IRQ-remapping-table parsing.
|
|
|
|
!<start name="acpi_drv">
|
|
! ...
|
|
! <config>
|
|
! <policy label="acpi_drv">
|
|
! <pci class="ALL"/>
|
|
! </policy>
|
|
! <policy label="usb_drv">
|
|
! <pci class="USB"/>
|
|
! </policy>
|
|
! </config>
|
|
!</start>
|
|
|
|
If, for some reason, MSIs should or can not be used, support may be disabled
|
|
explicitly by setting the 'irq_mode' attribute to 'nomsi' in the policy XML
|
|
node.
|
|
|
|
!<policy label="usb_drv" irq_mode="nomsi">
|
|
|
|
The configuration of a non-PCI device is described by a 'device' entry in the
|
|
policy.
|
|
|
|
!<policy label="ps_drv"> <device name="PS2"/> </policy>
|
|
|
|
With the changes described above, the platform driver is now in the position
|
|
to hand out solely those devices to drivers, which are explicitly permitted.
|
|
Furthermore, the platform driver can transparently discover I/O resources and
|
|
set up the appropriate interrupt scheme for devices, which removes this burden
|
|
from the device-driver developer.
|
|
|
|
The next steps in this direction are to co-locate and consolidate the PCI and
|
|
ACPI drivers into the platform driver as done partially for some ARM-based
|
|
platforms already. Then, the implementation should be generalized to comprise
|
|
ARM platforms too, which includes the configuration, the usage of the
|
|
regulator session, and the enforcement of policies per device.
|
|
|
|
|
|
Base framework and low-level OS infrastructure
|
|
##############################################
|
|
|
|
API refinements
|
|
===============
|
|
|
|
Our documentation efforts as mentioned in Section
|
|
[Comprehensive architectural documentation] provided the right incentive to
|
|
revisit the Genode API with the goal to reach API stability over the next
|
|
year. This section summarizes the API changes that may affect developers
|
|
using the framework.
|
|
|
|
:Semaphore simplification:
|
|
|
|
The semaphore at _base/semaphore.h_ used to be a template, which took the
|
|
queueing policy as argument. There was a reasonable default, which took a
|
|
FIFO queue as policy. Since we introduced the semaphore in 2006, we never
|
|
used a different queueing policy. So this degree of flexibility smells like
|
|
over-engineering. Hence, we cut it back by hard-wiring the FIFO policy in
|
|
the semaphore.
|
|
|
|
:Moving the packet stream and ring buffer into the Genode namespace:
|
|
|
|
The packet-stream utilities provided by _os/packet_stream.h_ provide the
|
|
common code to realize the transfer of bulk data between components in an
|
|
asynchronous fashion. It is used by several session interfaces such as the
|
|
NIC session, file-system session, and block session. Until now, however,
|
|
the utilities used to reside in the root namespace. Now, we have rectified
|
|
this glitch by moving them to the Genode namespace. We did the same for
|
|
the commonly used ring-buffer utility provided by _os/ring_buffer.h_.
|
|
|
|
:Moving 'Xml_node::Attribute' to 'Xml_attribute':
|
|
|
|
The XML parser used to represent XML attributes with the nested
|
|
'Xml_node::Attribute' class. However, the use of non-trivial nested classes
|
|
at API level tends to be confusing and difficult to document. Hence, we
|
|
decided to promote 'Xml_node::Attribute' to a dedicated top-level class.
|
|
|
|
:Unification of text-to-data conversion functions:
|
|
|
|
Until now, the set of functions to extract information from text strings has
|
|
grown rather evolutionary. It became a somehow weird mix of function
|
|
templates, overloads, and default arguments. To make the Genode API easier
|
|
to understand, we longed for a simple and more coherent concept. For this
|
|
reason, we changed the 'ascii_to' functionality of _util/string.h_ in two
|
|
ways.
|
|
|
|
First, each 'ascii_to' function has become a plain overloaded function - not
|
|
a kind of template specialization of a function-template signature. In some
|
|
cases, it may actually be a template, but only if the result type is a
|
|
template.
|
|
|
|
Second, the "base" argument has been be discarded. It was used to parse
|
|
numbers with different integer bases (like 16 for hexadecimal numbers). For
|
|
most types, however, the base argument made not much sense. For this reason,
|
|
the argument was mostly ignored. Now, the official way to extract integers
|
|
of different bases would be the introduction of dedicated types similar to
|
|
the existing 'Number_of_bytes' type.
|
|
|
|
|
|
Support for GPT partitions
|
|
==========================
|
|
|
|
The old-fashioned MBR partition table is on its way out. Its successor, the
|
|
GUID partition table (GPT), is increasingly used on recent systems. On some,
|
|
namely the ones featuring UEFI firmware without legacy boot support, it is the
|
|
only available option. Therefore, we have extended the 'part_blk' server by
|
|
adding rudimentary support for GPT so that we are able to use Genode on such
|
|
systems.
|
|
|
|
The support is enabled by configuring 'part_blk' accordingly:
|
|
|
|
! <start name="part_blk">
|
|
! [...]
|
|
! <config use_gpt="yes">
|
|
! [...]
|
|
! </start>
|
|
|
|
It will fall back to trying to use the MBR if it does not find a valid GPT
|
|
header.
|
|
|
|
The current implementation is limited in the following respects. For one, no
|
|
endian conversion takes place and it therefore only works on little-endian
|
|
platforms. This poses no problem because, for now, Genode does not run on any
|
|
big-endian platform anyway. Furthermore, as the GPT specification defines, the
|
|
content of the name field is encoded in UTF-16 but 'part_blk' will only
|
|
extract valid ASCII-encoded characters. It also ignores all GPE attributes.
|
|
|
|
|
|
Network-link state-change handling
|
|
==================================
|
|
|
|
We extended the NIC session interface with the ability to notify its client
|
|
about changes in the link-state of the session. Adding this mechanism was
|
|
motivated by the need for requesting new network configuration settings, e.g.,
|
|
IP and gateway addresses, when changing the location and switching the
|
|
network.
|
|
|
|
A NIC-session client can now install a signal handler that is called when the
|
|
link-state changes. After receiving the signal, the client may query the
|
|
current state by executing the 'link_state()' RPC function. In addition, the
|
|
NIC driver interface now provides a notification-callback method that is used
|
|
to forward link-state changes from the driver to the 'Nic::Session_component'.
|
|
|
|
The lwIP TCP/IP stack was adapted to that feature and always tries to acquire
|
|
new network settings via DHCP when the link state changes.
|
|
|
|
The following drivers now report link-state changes: dde_ipxe, nic_bridge, and
|
|
usb_drv. On the other hand, OpenVPN, Linux nic_drv, and the lan9118 driver do
|
|
not support it and always report the link-up state.
|
|
|
|
|
|
File-system utilities
|
|
=====================
|
|
|
|
When we introduced Genode's file-system session interface in
|
|
[https://genode.org/documentation/release-notes/12.05#New_file-system_infrastructure - version 12.05],
|
|
it was accompanied with a RAM file system as the first implementation. Since
|
|
then, a growing number of file-system services were developed, which took the
|
|
RAM file system as blue print. Over the years, this practice resulted in the
|
|
duplication of the utilities that were found worthwhile to reuse. The upcoming
|
|
addition of a new 9P file-system service prompted us to make those utilities
|
|
part of the public API, located at _os/include/file_system/_.
|
|
|
|
|
|
Device drivers
|
|
##############
|
|
|
|
New AHCI driver with support for native command queueing
|
|
========================================================
|
|
|
|
With Genode 15.05, we completely revised our AHCI driver in order to overcome
|
|
some severe limitations of the previous implementation. Specifically, we
|
|
desired support for multiple devices per controller, handle block requests
|
|
asynchronously, and consolidate the Exynos5 and the x86 code to enable code
|
|
sharing of the AHCI-specific features. We also wanted to improve the driver
|
|
performance by taking advantage of modern features like native command
|
|
queuing.
|
|
|
|
In order to achieve these goals, we implemented a generic AHCI driver by
|
|
taking advantage of Genode's MMIO framework. The code is shared between x86
|
|
and the Exynos5 platform. Additionally, we introduced a 'Platform_hba' class
|
|
that takes care of platform-specific initialisation and platform-dependent
|
|
functions, like the allocation of DMA memory or the handling of the PCI bus on
|
|
x86 platforms.
|
|
|
|
For supporting multiple devices, we extended Genode's block component by a
|
|
root component with multiple-session support. Sessions are routed much like it
|
|
is done for our partition server (part_blk) by using 'policy' XML nodes (see
|
|
the README file under _repos/os/src/drivers/ahci_).
|
|
|
|
Since version 15.02, Genode's block component offers support for asynchronous
|
|
block requests. The AHCI driver takes full advantage of this interface by
|
|
using native-command queuing (NCQ). NCQ allows up to 32 read/write requests to
|
|
be executed in parallel. Please note that requests may be processed out of
|
|
order because NCQ is implemented on the device side, giving the device vendor
|
|
the opportunity to optimize seek times for hard disks. With NCQ support and
|
|
asynchronous request processing in place, the driver is able to achieve a
|
|
performance that is on par with modern Linux drivers. We measured a throughput
|
|
of 75 MB/s for HDDs and 180 MB/s for SSDs when issuing sequential 4 KB
|
|
requests.
|
|
|
|
Feature-wise our AHCI driver offers read/write support for hard disks (HDDs or
|
|
SSDs) and experimental read-only support for ATAPI devices (CDROM, DVD, or
|
|
Blu-ray devices).
|
|
|
|
|
|
Multi-touch support
|
|
===================
|
|
|
|
One motivation to upgrade VirtualBox 4.3 with the Genode release 14.11 was to
|
|
use the multi-touch feature of Windows guests. With this release, we took the
|
|
opportunity to investigate and enable the feature using the multi-touch
|
|
capable Wacom USB driver introduced with release 15.02.
|
|
|
|
The first step was to capture the multi-touch input events in our USB port and
|
|
extend the input back end to propagate the information via Genode's input
|
|
session. We extended the input interface of Genode by a new event type "TOUCH"
|
|
(class Input::Event), which stores the absolute coordinates of a touch event
|
|
as well as the identifier of the touch contact. Each finger at a time on the
|
|
touch screen is represented as a contact with such a number/identifier.
|
|
|
|
Nitpicker, nit_fb and the window manager propagate this new type of event to
|
|
clients, which may process them if capable, as is the case for VirtualBox.
|
|
Finally, we extended the input back end of our VirtualBox port to process
|
|
Genode's input touch events so that the USB models in VirtualBox can utilize
|
|
them.
|
|
|
|
To enable the propagation of multi-touch events, the USB driver must be
|
|
configured explicitly by setting a "multitouch" attribute to "yes":
|
|
|
|
!<start name="usb_drv">
|
|
! ...
|
|
! <config uhci=... ohci=... xhci=...>
|
|
! <hid>
|
|
! <touchscreen width="1024" height="768" multitouch="yes"/>
|
|
! </hid>
|
|
! ...
|
|
!</start>
|
|
|
|
To be able to use the multi-touch feature in VirtualBox, make sure to enable a
|
|
USB controller model and a USB multi-touch capable device model in your VM
|
|
configuration (.vbox file):
|
|
|
|
!<VirtualBox ...>
|
|
! <Machine ...>
|
|
! <Hardware ...>
|
|
! <HID Pointing="USBMultiTouch" Keyboard="USBKeyboard"/>
|
|
! </Hardware>
|
|
! ...
|
|
! <USB>
|
|
! <Controllers>
|
|
! <Controller name="OHCI" type="OHCI"/>
|
|
! </Controllers>
|
|
! </USB>
|
|
! <Machine>
|
|
! ...
|
|
!</VirtualBox>
|
|
|
|
|
|
Audio drivers ported from OpenBSD
|
|
=================================
|
|
|
|
A few years back, we ported OSSv4 to Genode to account for the need of playing
|
|
audio on Genode. It worked fine on a handful of sound cards but unfortunately,
|
|
it did not work well on more recent Intel HD Audio devices. Though that
|
|
shortcoming was more a problem of our own port than of OSSv4 itself, we
|
|
decided to replace it rather than trying to fix the port. The rationale behind
|
|
this decision is the uncertain future of the OSSv4 project. A driver with an
|
|
active upstream development is certainly preferable.
|
|
|
|
By now, we gained a solid experience in porting drivers from other OSs and
|
|
developed a best practice that served us well. In the past, we mostly chose
|
|
Linux as driver donor. But this time, we went in another direction and picked
|
|
OpenBSD. One of the reasons for favouring it is its comprehensive
|
|
documentation that helped a lot in implementing the APIs. There is normally
|
|
one interface for a specific task used throughout all drivers whereas, on
|
|
Linux, several interfaces and different drivers tend to use the interface that
|
|
was popular at the time of their creation. We found the perceived code hygiene
|
|
noticeably higher on OpenBSD than on Linux.
|
|
|
|
Since porting a driver from a foreign OS involves picking the right layer to
|
|
extract the driver, we took a closer look at the overall audio architecture of
|
|
OpenBSD. At the highest level, it uses the sndio(7) interface. A user-land
|
|
daemon _sndiod(1)_ performs stream mixing, format conversion, exposes virtual
|
|
devices to its clients, and controls the actual audio device provided in the
|
|
form of the audio(4) device-independent driver layer. This layer abstracts the
|
|
particular audio-device driver. It provides device-agnostic means to configure
|
|
the device and to control the mixer. The device driver plugs into the audio(9)
|
|
kernel interface.
|
|
|
|
Genode contains its own user-land server/client audio interface, namely the
|
|
Audio_out session. Therefore, we dismissed the use of the sndio(7) interface
|
|
because it would involve porting _sndiod(1)_ as well as changing all our audio
|
|
clients. Merely porting the device driver and using the audio(9) kernel
|
|
interface directly would have given us the most flexibility indeed but we
|
|
would have been in charge of setting up the environment, e.g., DMA buffers
|
|
etc., for the device driver. The audio(4) subsystem, on the other hand, does
|
|
all this already and provides us with the common device interface, i.e.,
|
|
read(2), write(2), and ioctl(2). On these grounds, the audio(4) layer was
|
|
selected as the porting target.
|
|
|
|
The ported drivers are located in _repos/dde_bsd/_. The driver back end
|
|
resides in the form of library in _repos/dde_bsd/src/lib/audio_ whereas the
|
|
driver front end providing the Audio_out session is placed at
|
|
_repos/dde_bsd/src/drivers/audio_out_. As we did previously with other ported
|
|
drivers, we created an emulation header, in this case called _bsd_emul.h_ that
|
|
contains all needed definitions and data structures. All vanilla OpenBSD
|
|
source files are scanned and symlinks, named after the header files in the
|
|
include directives, are created. Each symlink points to the emulation header.
|
|
After that, the needed functionality is implemented. Since OpenBSD uses a
|
|
rather static approach on how the kernel is configured, i.e., which subsystems
|
|
and drivers are included, we needed to provide the parts required by the
|
|
autoconf(9) framework. Basically, we provide the config data structure that
|
|
contains the drivers (the audio subsystem as well as the audio device drivers)
|
|
and implemented some other functionality that normally would be generated by
|
|
the config mechanism in vanilla OpenBSD (see
|
|
_repos/dde_bsd/src/lib/audio/bsd_emul.c_). The rest of the implementation,
|
|
including the memory management and IRQ handling, turned out to be straight
|
|
forward.
|
|
|
|
In addition, the back end also implements the functions declared in the
|
|
private 'Audio' namespace (see _repos/dde_bsd/include/audio/audio.h_ and
|
|
_repos/dde_bsd/src/lib/audio/driver.cc_). The front end exclusively calls
|
|
these functions and has no knowledge of the driver back end ported from
|
|
OpenBSD. In this respect, these functions encapsulate the interface exposed by
|
|
the audio(4) interface. To play the content of a packet received via the
|
|
'Audio_out' session, the front end will simply call 'Audio::play()'. This
|
|
function internally calls 'audiowrite()' after preparing the needed 'struct
|
|
uio' argument by this function. 'audiowrite()' is called in a non-blocking
|
|
fashion. This is necessary because the audio-out driver operates as
|
|
single-threaded event-driven process. If it blocked, it could not handle IRQs
|
|
generated by the audio device. Last but not least, the write function copies
|
|
the samples into the DMA buffer and calls the device driver to trigger the
|
|
playback. After a block from the DMA buffer has been played, the audio device
|
|
will generate an interrupt, which will poke the front end. The front end
|
|
responds by requesting the playback of the next audio packet.
|
|
|
|
The driver currently supports Intel HD Audio (Azalia) and Ensoniq AudioPCI
|
|
(ES1370) compatible audio devices and is based on OpenBSD 5.7. It can be
|
|
tested by executing the run script _repos/dde_bsd/run/audio_out.run_. This run
|
|
script needs a sample file. Please refer to _repos/dde_bsd/README_ for the
|
|
instructions on how to create such a file.
|
|
|
|
|
|
SD-card drivers for i.MX53 and Raspberry Pi
|
|
===========================================
|
|
|
|
We improved the generic SD-card protocol implementation with the ability
|
|
to handle the version 1.0 of the CSD register, which contains the capacity
|
|
information of older SD cards.
|
|
|
|
At _os/src/drivers/sd_card/rpi_, there is a new driver for the SDHCI
|
|
controller as featured on the Raspberry Pi. As of now, the driver operates in
|
|
PIO mode only. Depending on the block size (512 bytes versus 128 KiB), it has
|
|
a throughput of 2 MiB/sec - 10 MiB/sec for reading and 173 KiB/sec - 8 MiB/sec
|
|
for writing.
|
|
|
|
At _os/src/drivers/sd_card/imx53_, there is a new driver for the Freescale
|
|
eSDHCv2 SD-card controller as used on the USB Armory platform. The
|
|
configuration of the highest available bus frequency and bus width is still
|
|
open for further optimization.
|
|
|
|
|
|
Board support for i.MX6-based Wandboard
|
|
=======================================
|
|
|
|
The increasing interest in the combination of Genode and the Freescale i.MX6
|
|
SoC motivated us to add official support for a board based on this SoC
|
|
to our custom kernel. We settled on the
|
|
[https://www.wandboard.org/ - Wandboard Quad] that was developed on a volunteer
|
|
basis. Thanks to Praveen Srinivas (IIT Madras, India) and Nikolay Golikov
|
|
(Ksys Labs LLC, Russia) who contributed their work on i.MX6. The Wandboard
|
|
Quad features 2 GiB of DDR3 RAM and a quad-core Cortex-A9 CPU. So, unlike when
|
|
porting i.MX53, our existing kernel drivers for the Cortex-A9 private
|
|
peripherals, namely the core-local timer and the ARM Generic Interrupt
|
|
Controller could be reused.
|
|
|
|
Although the board even supports SMP and the ARM Security Extensions, we don't
|
|
make use of these advanced features yet. However, our port is intended to
|
|
serve as a starting point for further development in these directions.
|
|
|
|
To create a build directory for Genode running on Wandboard Quad, use the
|
|
following command:
|
|
|
|
! ./tool/create_builddir hw_wand_quad
|
|
|
|
|
|
USB device-list report
|
|
======================
|
|
|
|
The USB driver has become able to generate a report with a list of all
|
|
currently connected devices, which gets updated when devices are added or
|
|
removed. This information can be useful to decide if and when a USB session
|
|
for a specific device should be opened or closed.
|
|
|
|
An example report looks as follows:
|
|
|
|
!<devices>
|
|
! <device vendor_id="0x17ef" product_id="0x4816"/>
|
|
! <device vendor_id="0x0a5c" product_id="0x217f"/>
|
|
! <device vendor_id="0x8087" product_id="0x0020"/>
|
|
! <device vendor_id="0x8087" product_id="0x0020"/>
|
|
! <device vendor_id="0x1d6b" product_id="0x0002"/>
|
|
! <device vendor_id="0x1d6b" product_id="0x0002"/>
|
|
!</devices>
|
|
|
|
The report is named 'devices' and an example policy for the report_rom
|
|
component would look like:
|
|
|
|
!<policy label="vbox -> usb_devices" report="usb_drv -> devices"/>
|
|
|
|
The report gets generated only when enabled in the configuration of the USB
|
|
driver:
|
|
|
|
!<config>
|
|
! <raw>
|
|
! <report devices="yes"/>
|
|
! </raw>
|
|
!</config>
|
|
|
|
There is no distinction yet for multiple devices of the same type.
|
|
|
|
|
|
Runtime environments
|
|
####################
|
|
|
|
VirtualBox on NOVA
|
|
==================
|
|
|
|
As with the previous releases, we continuously improved our version of
|
|
VirtualBox running on top of the NOVA microhypervisor.
|
|
|
|
|
|
Video Acceleration (VBVA)
|
|
~~~~~~~~~~~~~~~~~~~~~~~~~
|
|
|
|
We enabled the "VirtualBox Graphics Adapter" device model, which improves the
|
|
performance of screen-region updates in comparison to the standard VGA adapter
|
|
device model, and which allows the integration of the guest mouse pointer with
|
|
the nitpicker GUI server. The mouse pointer integration has been realized in
|
|
two steps. First, we extended VirtualBox to generate a "shape" report with the
|
|
detailed information about the mouse pointer shape. The counterpart is a
|
|
specialized vbox_pointer application, which receives the shape report as ROM
|
|
file (provided by the report_rom component) and draws the mouse pointer
|
|
accordingly when a nitpicker view related to VirtualBox is hovered.
|
|
|
|
|
|
USB-device pass-through support
|
|
~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~
|
|
|
|
With the availability of the
|
|
[https://genode.org/documentation/release-notes/15.02#USB_session_interface - USB session interface]
|
|
and the new [USB device-list report] feature of the USB driver, it is now
|
|
possible to pass a selection of raw USB devices directly to VirtualBox guests.
|
|
|
|
VirtualBox obtains the list of available USB devices from a ROM module named
|
|
'usb_devices', which can be connected to the USB driver's device-list report
|
|
using the report_rom component with a policy as follows:
|
|
|
|
!<policy label="vbox -> usb_devices" report="usb_drv -> devices"/>
|
|
|
|
The devices to be passed-through need to have a matching device filter in the
|
|
VirtualBox configuration file ('*.vbox'). For example:
|
|
|
|
!<USB>
|
|
! <Controllers>
|
|
! <Controller name="OHCI" type="OHCI"/>
|
|
! </Controllers>
|
|
! <DeviceFilters>
|
|
! <DeviceFilter name="USB Scanner" active="true" vendorId="04a9"
|
|
! productId="2220" remote="0"/>
|
|
! </DeviceFilters>
|
|
!</USB>
|
|
|
|
The feature was successfully tested with HID devices (mouse, keyboard) and a
|
|
flatbed scanner. Mass storage devices are known to have problems, though we
|
|
also observed these problems with VirtualBox on Linux without the
|
|
closed-source extension pack.
|
|
|
|
When using this feature, it should be made sure that the USB driver itself
|
|
does not try to control the devices to be passed to VirtualBox. For example,
|
|
when passing-through a HID device, the '<hid/>' config option of the USB
|
|
driver should not be set.
|
|
|
|
|
|
Platforms
|
|
#########
|
|
|
|
Proof-of-concept support for the seL4 kernel
|
|
============================================
|
|
|
|
Since last summer when the [https://sel4.systems - seL4 kernel] was released
|
|
under the General Public License, we entertained the idea to run Genode on
|
|
this kernel. As the name suggests, the seL4 kernel is a member of the L4
|
|
family of kernels. But there are two things that set this kernel apart from
|
|
all the other family members. First, with the removal of the kernel memory
|
|
management from the kernel, it solves a fundamental robustness and security
|
|
issue that plagues all other L4 kernels so far. This alone would be reason
|
|
enough to embrace seL4. Second, seL4 is the world's first OS kernel that is
|
|
formally proven to be correct. That means, it is void of implementation bugs.
|
|
This makes the kernel extremely valuable in application areas that highly
|
|
depend on the correctness of the kernel.
|
|
|
|
Since last autumn, we conducted the port of Genode to the seL4 kernel as
|
|
background activity. We took the chance to thoroughly document our experience
|
|
by the following series of articles:
|
|
|
|
:[https://genode.org/documentation/articles/sel4_part_1 - Building a simple root task from scratch]:
|
|
The first article describes the integration of the kernel code with Genode's
|
|
source tree and the steps taken to create a minimalistic root task that runs
|
|
on the kernel. It is full of hands-on information about the methodology of
|
|
such a porting effort and describes the experience with using the kernel
|
|
from the perspective of someone with no prior association with the seL4
|
|
project.
|
|
|
|
:[https://genode.org/documentation/articles/sel4_part_2 - IPC and virtual memory]:
|
|
The second part of the article series examines the seL4 kernel interface
|
|
with respect to synchronous inter-process communication and the management
|
|
of virtual memory.
|
|
|
|
:[https://genode.org/documentation/articles/sel4_part_3 - Porting the core component]:
|
|
The third article presents the steps taken to bring Genode's core and init
|
|
components to life. Among the covered topics are the memory and capability
|
|
management, inter-component communication, and page-fault handling. The
|
|
article closes with a state of development that principally enables simple
|
|
Genode scenarios to run on seL4.
|
|
|
|
With the current release, we have integrated the intermediate result into the
|
|
mainline Genode source tree. At the time of the release, Genode's core and
|
|
init components are running, and init is able launch further child components
|
|
such as simple test programs. Still, the current level of seL4 support should
|
|
be understood as a proof of concept and is still riddled with several interim
|
|
solutions and shortcomings. Please refer to the third article linked above for
|
|
the details. Functionality-wise the most glaring gap is the unimplemented
|
|
support for user-level device drivers, which rules out most of the meaningful
|
|
Genode scenarios for the time being. Still, the current version shows that the
|
|
combination of seL4 and Genode is viable.
|
|
|
|
To give Genode a quick spin on the seL4 kernel, you may take the following
|
|
steps:
|
|
|
|
# Download the seL4 kernel
|
|
|
|
!./tool/ports/prepare_port sel4
|
|
|
|
# Create a Genode build directory for seL4:
|
|
|
|
!./tool/create_builddir sel4_x86_32
|
|
|
|
# Change to the build directory and start the _base/run/printf.run_ script:
|
|
|
|
!cd build/sel4_x86_32
|
|
!make run/printf
|
|
|
|
After compiling the Genode components (init, core, and test-printf), the run
|
|
script will build the kernel, integrate a boot image, and run the image inside
|
|
Qemu. You will be greeted with the output of the test-printf program, which
|
|
demonstrates that core, init, and test-printf are running (each in a different
|
|
protection domain) and that the components can interact with each other by the
|
|
means of capability invocations.
|
|
|
|
|
|
NOVA kernel mechanism for asynchronous notifications
|
|
====================================================
|
|
|
|
The vanilla NOVA kernel provides asynchronous signalling by the means of
|
|
semaphores. This mechanism offers a way to transfer one bit information from a
|
|
sender to one receiver at a time. So a thread may block by issuing a "down"
|
|
operation on a semaphore and wakes up as soon as the sender issues an "up"
|
|
operation. However, Genode's signal abstraction for asynchronous notification
|
|
requires that a receiver may potentially receive from multiple sources at a
|
|
time, which rendered this kernel feature unusable to be directly used by
|
|
Genode's signal framework.
|
|
|
|
Instead, for base-nova, the signalling phase was implemented as a indirection
|
|
over core for each Genode signal that got submitted. After an initial
|
|
registration at core to ask for incoming signals, a receiver block in its own
|
|
address space on a per-thread semaphore until a signal becomes available. The
|
|
signalling phase looked like that:
|
|
|
|
# A signal source (thread) generates a Genode signal by sending a synchronous
|
|
message via an RPC to core,
|
|
# Core notifies the receiver asynchronously via a kernel semaphore "up"
|
|
operation,
|
|
# The receiver's blocking IPC returns.
|
|
The context information about the signal is delivered with the IPC reply.
|
|
|
|
Besides all the book keeping in core, this approach requires at least 4
|
|
inter-address-space context switches. Ideally, this could be just one context
|
|
switch with a proper kernel mechanism in place.
|
|
|
|
On the course of updating the platform driver and the redesign of Genode's IRQ
|
|
session interface to operate asynchronously across all supported kernels, we
|
|
took the chance to extend the NOVA kernel to meet Genode's needs more closely.
|
|
|
|
We extended the NOVA kernel semaphores to support signalling via chained
|
|
semaphores. This extension enables the creation of kernel semaphores with a
|
|
per-semaphore value, which can be bound to another kernel semaphore. Each
|
|
bound semaphore corresponds to a Genode signal context. The per-semaphore
|
|
value is used to distinguish different sources of signals. Now, a signal
|
|
sender issues a _submit_ operation on a Genode signal capability via a regular
|
|
_semaphore-up_ syscall on NOVA. If the kernel detects that the used semaphore
|
|
is chained to another semaphore, the up operation is delegated to the chained
|
|
one. If a thread is blocked, it gets woken up directly and the per-semaphore
|
|
value of the bound semaphore gets delivered. In case no thread is currently
|
|
blocked, the signal is stored and delivered as soon as a thread issues the
|
|
next _semaphore-down_ operation.
|
|
|
|
Chaining semaphores is an operation that is limited to a single level, which
|
|
avoids attacks targeting endless loops in the kernel. The creation of such
|
|
signals can solely be performed if the issuer has a NOVA PD capability with
|
|
the semaphore-create permission set. On Genode, this effectively reserves the
|
|
operation to core. Furthermore, our solution upholds the invariant of the
|
|
original NOVA kernel that a thread may be blocked in only one semaphore at a
|
|
time. This makes our extension non-invasive and easily maintainable.
|
|
|
|
We applied the same principle to the delivery of interrupts by the NOVA
|
|
kernel, which corresponds to a _semaphore up_ operation. With minor changes,
|
|
we have become able to deliver interrupts as ordinary Genode signals. The main
|
|
benefits are a vastly simplified IRQ-session implementation in core and the
|
|
alleviation of the need for one thread per interrupt. The interrupt gets
|
|
directly delivered to the address space of the driver (MSI), or in case of a
|
|
shared interrupt, to the PCI driver.
|
|
|
|
|
|
Tool chain and build system
|
|
###########################
|
|
|
|
The tool chain has been updated to Binutils version 2.25 and GCC version 4.9.2.
|
|
This update comprises both the cross tool chain running on Linux as
|
|
development environment and the tool chain running within Genode's Noux
|
|
runtime environment.
|
|
|
|
To use Genode 15.05, please obtain and install the new binary version of the
|
|
tool chain available at [https://genode.org/download/tool-chain] or build it
|
|
manually via the _tool/tool_chain_ script.
|
|
|
|
|
|
Removal of deprecated features
|
|
##############################
|
|
|
|
The following parts have been pruned from the Genode source tree:
|
|
|
|
* We declared the support for Qt4 as deprecated in 2013. Since we switched
|
|
to Qt version 5 on Genode long ago, we finally removed the
|
|
_repos/qt4/_ repository.
|
|
|
|
* The _repos/base-host/_ repository was originally envisioned to be the ideal
|
|
place to document the framework-internal interfaces between the
|
|
kernel-agnostic and kernel-specific parts of the framework. It was
|
|
meant to provide mere stub functions that enable the compilation of
|
|
Genode-API-compliant code directly using the host compiler. However, it
|
|
remained an obscurity. Since it is neither used nor regularly tested, we
|
|
decided to remove it.
|
|
|
|
* The GTA01 platform support was originally added in 2006 to run Genode
|
|
on the Gamepark GP2x handheld console. The code remained unused and
|
|
unmaintained for several years.
|
|
|
|
* The original ATAPI driver is superseded by our new AHCI driver, which
|
|
principally also supports ATAPI devices. However, IDE support has been
|
|
dropped as it is not relevant on our current-day target platforms.
|
|
|
|
* The demo device driver (D3M) was created for the OKL4-based live system
|
|
released in 2010. Since then, it was in irregular use for a few
|
|
demonstration scenarios but has never evolved into a fully-fledged driver
|
|
manager. Since all of D3M's functionality except for the probing of boot
|
|
media is covered by a combination of other components, we decided to remove
|
|
D3M.
|
|
|
|
* The _linux_drivers_ repository hosted device drivers ported via the
|
|
original DDE-Linux approach. We
|
|
[https://genode.org/documentation/release-notes/12.05#Re-approaching_the_Linux_device-driver_environment - disregarded this approach]
|
|
in 2012. The only remaining code worth keeping is the i915 GPU driver, which
|
|
will potentially re-appear in our modern _repos/dde_linux_ repository.
|
|
|
|
* The _repos/dde_oss_ was an experiment to run the audio drivers of the
|
|
OSS project directly on Genode. Unfortunately, the contained Intel HD Audio
|
|
driver did not work on any Thinkpad models newer than T60. With the current
|
|
release, this repository is superseded by the _repos/dde_bsd_ repository.
|
|
|