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730 lines
38 KiB
Plaintext
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===============================================
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Release notes for the Genode OS Framework 16.11
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===============================================
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Genode Labs
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In contrast to most parts of the framework, the fundamental low-level
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protocols, which define the interaction between parent and child components
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have remained unchanged since the very first Genode version. From this
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interplay, the entire architecture follows. That said, certain initial design
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choices were not perfect. They partially resulted from limitations of the
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kernels we used during Genode's early years and from our pre-occupation with a
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certain style of programming. Over the years, the drawbacks inherent in our
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original design became more and more clear and we drafted rough plans to
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overcome them. However, reworking the fundamental protocols of a system that
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already accommodates hundreds of component implementations cannot be taken
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lightly. Because of this discomfort, we repeatedly deferred the topic -
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until now. With the rapidly growing workloads carried by Genode, we
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deliberately decided to address long-standing deficiencies rather than adding
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the features we originally planned according to the
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[https://genode.org/about/road-map - road map].
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Section [Asynchronous parent-child interactions] presents the reworking of
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Genode's component interplay at the lowest level. With this change in place,
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we feel much more comfortable to scale up our workloads in the upcoming
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releases.
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Functionality-wise, the most prominent topic of the current release is the
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vastly improved NIC-routing component. Since we introduced the first version
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of the NIC router in the previous release, we took an iterative approach to
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shape the component according to its most prominent use cases. Section
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[Further improved virtual networking] summarizes the changes and the
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motivation behind them.
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Even though we added support for seL4 in the previous release, the NOVA
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hypervisor is still our go-to kernel for x86-based hardware because of its
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feature set. For this reason, we continuously improve this kernel and the
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NOVA-specific components like VirtualBox. Section [NOVA hypervisor] covers
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the introduction of an asynchronous map operation to NOVA.
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Further topics of the current release range from added smart-card support,
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over a new timeout API, to a VFS-based time-based password generator. With
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respect to the road map, we postponed most topics originally planned. In
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particular, we intended to enable the use of Genode on top of Xen by following
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the footsteps of the existing Muen support - using our custom
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base-hw kernel within a Xen DomU domain. However, before proceeding this
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route, we decided to modernize the kernel design, in particular with respect
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to bootstrapping and address-space management. Some parts of this line of work
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are already present in the current release, for example the unification of the
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boot-module handling as explained in Section
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[Unified handling of boot modules].
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Asynchronous parent-child interactions
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######################################
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When Genode was born in 2006, the L4 microkernels of the time universally
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lacked an asynchronous inter-process-communication (IPC) mechanism.
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Consequently, we designed the first version of Genode with the presumption
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that components had to interact solely synchronously. To us, this seemed to be
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the "right" way because the synchronous low-footprint IPC was presumably the
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key for L4's good performance. It felt natural to leverage this benefit to the
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maximum extent possible.
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To illustrate the implications of this line of thinking for Genode, let's take
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a look at a simple scenario where a parent component hosts two children and one
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child provides a service to the other child.
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[image simple_scenario]
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During the creation of a session, the kernel's IPC mechanism serves three
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purposes. First, it is used to communicate information between different
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protection domains, in this case the parent, the client, and the server.
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Second, it implicitly dictates the flow of control between the involved
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parties because the caller blocks until the callee replies to the IPC call.
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Third, the IPC is the mechanism to delegate authority (like the authority to
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access the server's session object) between protection domains. The latter is
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realized with the kernel's ability to carry capabilities as IPC message
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payload. If this sounds a bit too abstract, please consider reviewing Section
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3.1. "Capability-based security" of the
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[https://genode.org/documentation/genode-foundations-16-05.pdf - Genode Foundations].
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Using solely a synchronous IPC mechanism, the sequence of establishing a
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session in the given scenario is as follows. In the context of Genode,
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we usually refer to synchronous IPC as RPC (remote procedure call).
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[image sync_session_seq]
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The sequence looks straightforward:
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# The client issues an RPC call to its parent, requesting a session for a
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service of the given type while also passing a number of session-construction
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arguments along with the request.
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# Given the service name as provided with the session request, the parent
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determines the server to ask for a new session. It requests a session
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on behalf of the client by performing an RPC call to the server's prior
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registered "root" capability. This capability refers to an interface for
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creating and closing sessions.
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# The server responds to the invocation of its root interface by creating
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a new session object along with a session capability.
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Whereas the session object is local to the server, the corresponding
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session capability can be passed (delegated) to other components.
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Each component in possession of the session capability is able to interact
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with the server's corresponding session object via RPC calls.
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The server returns the session capability to the parent as the result of the
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parent's RPC call.
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# The parent forwards the session capability to the client as the result of
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the client's original RPC call.
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Even though the simplicity of this protocol seems nice, it has inherent
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limitations:
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First, as the parent performs a synchronous RPC call to the server on behalf
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of the client, it must trust the server to eventually respond to the RPC call.
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If the server doesn't, the parent may block forever. In contrast to the client
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that actually uses the service and thereby relies on the liveliness of the
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server, the parent should not need to trust the server to be responsive. To
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deal with the risk of an unresponsive server, Genode's existing runtime
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environments (like the init component), maintain a dedicated thread for each
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child. The session requests originating from a child are handled by the
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corresponding parent-local child thread. In the worst case - if the server
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fails to respond - only a single child thread stays blocked but the other
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parts of the runtime environment remain unaffected. Consequently, runtime
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environments have to be multi-threaded components. This, in turn, comes at the
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cost of added complexity, in particular the need for error-prone inter-thread
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synchronization.
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Second, the approach keeps the parent's state implicitly stored in the stacks
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of the parent's threads. This becomes a problem in dynamic runtime
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environments that need to kill subsystems at arbitrary times. E.g., imagine
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the situation where the client component is to be destroyed while the parent's
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call to the server's root interface is still pending. The safe destruction of
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the child - including its associated parent-local child thread - requires the
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parent to abort the RPC call, which is a complex and - again - error-prone
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operation.
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Third, even though not inherent to synchronous RPC, Genode's original design
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facilitated the use of a session capability as argument for requesting the
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parent to close a specific session. However, the use of capabilities as
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re-identifiable tokens is not well supported by most kernels, including seL4
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([https://sel4.systems/pipermail/devel/2014-November/000114.html - discussion]
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on the seL4 mailing list).
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Asynchronous communication throughout Genode
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--------------------------------------------
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In 2008, we acknowledged the sole reliance on synchronous RPC as too limiting
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and introduced an
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[https://genode.org/documentation/release-notes/8.11#Asynchronous_notifications - API for asynchronous notifications].
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On the traditional L4 kernels, we implemented the API by using Genode's
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core component as a proxy for signal delivery. The use of asynchronous
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notifications soon became natural and wide-spread throughout Genode. Today,
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most session interfaces combine three forms of inter-component communication,
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namely synchronous RPC calls, asynchronous notifications, and shared memory.
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The new Genode API introduced in
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[https://genode.org/documentation/release-notes/16.05#The_great_API_renovation - version 16.05]
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further cultivated the modeling of Genode components as single-threaded state
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machines instead of multi-threaded programs.
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Still, until now, the most fundamental mechanism of Genode - the protocol
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between parent and child components - has remained synchronous. The reasons
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are twofold. First, our workaround for realizing runtime environments in a
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multi-threaded way worked too well. So we were not constantly bothered by this
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design problem. Second and more importantly, redesigning the fundamental
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mechanism of the framework while not breaking the more than 300 existing
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components is quite scary. But in anticipation of the rapidly scaling
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workloads imposed on Genode, we had to take on the problem sooner or later.
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We figured that now - with the modernized framework API in place - it's the
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right time. From redesigning the interplay of parent and child components, we
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will become able to create single-threaded runtime environments that behave
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completely deterministically while consuming less resources than
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multi-threaded programs. By the explicit enumeration of possible states, we
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greatly ease the validation/evaluation of such crucial components.
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New session-creation procedure
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------------------------------
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Following the asynchronous approach, the sequence of creating a session now
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looks as follows:
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[image async_session_seq]
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The dotted lines are asynchronous notifications, which have fire-and-forget
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semantics. A component that triggers a signal does not block.
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The following points are worth noting:
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* Sessions are identified via IDs, which are plain numbers as opposed to
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capabilities. The IDs as seen by the client and server belong to different
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ID name spaces.
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IDs of sessions requested by the client are allocated by the client. IDs
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of sessions requested at the server are allocated by the parent.
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* The parent does no longer need to perform RPC calls to any of its children.
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Hence, the need for multiple threads in runtime environments disappears.
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* Each activation of the parent merely applies a state change of the session's
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meta data structures maintained at the parent, which capture the entire
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state of session requests. There is no hidden state stored on the parent's
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stack.
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* The information about pending session requests is communicated from the
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parent to the server via a ROM session. At startup, the server requests
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a ROM session for the ROM module "session_requests" from its parent. The
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parent implements this ROM session locally. Since ROM sessions support
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versions, the parent can post version updates of the "session_requests"
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ROM with the regular mechanisms already present in Genode.
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* The involved parties can potentially run in parallel.
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Outcome and current state
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-------------------------
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Intuitively, the sequence of steps required to establish a session has
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become more complicated. However, for the users of the framework, the entire
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procedure is completely transparent. With a few tricks, we were actually able
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to implement this fundamental change while keeping almost all existing
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components untouched. One trick is the introduction of a server-local proxy
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mechanism, which translates the requests obtained from the "session_requests"
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ROM to component-local RPC calls on the server's root interface. So from the
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perspective of an existing server component, a session request still looks
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like a synchronous RPC request from the outside. Of course, the proxy is meant
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as an intermediate solution until we have crafted a convenient front-end API
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for the asynchronous mode of operation.
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Even though the biggest share of components remains unaffected by the change,
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this is not true for all components. In particular, runtime environments had
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to be reworked, in some cases quite fundamentally. These include core, init,
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noux, the loader, GDB monitor, launcher, CLI monitor, and the platform driver.
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The change does not only affect the interplay between components but also
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required a reconsideration of the child-creation procedure.
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Besides the architectural improvement, this line of work had two welcome
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effects.
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First, in contrast to the original design, which relied on capabilities as
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re-identifiable tokens, the new version greatly alleviates the need for
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re-identifying capabilities on seL4. So we are able to eliminate a
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long-standing problem with Genode on this kernel.
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Second, the work called for new data structures for the safe interaction with
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ID spaces (_base/id_space.h_) and object registries (_base/registry.h_). Those
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data structures will possibly be useful in a lot of places that currently use
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plain (and fairly unsafe) AVL trees or lists.
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At the API level, the change is almost transparent to regular components,
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except for two details. The upgrading of session quota is no longer
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possible by a mere RPC call to the parent. Instead, 'Connection' objects
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received a new 'upgrade_ram' method that must be used instead. Speaking
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of 'Connection' objects, we had to remove the (fairly obscure) 'KEEP_OPEN'
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feature, which is conceptually incompatible with the new design.
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Further improved virtual networking
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###################################
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The
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[https://genode.org/documentation/release-notes/16.08#Virtual_networking_and_support_for_TOR - previous release]
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introduced the NIC router - a component that individually routes IP
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packets between multiple NIC sessions, translates between different IP
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subnets, and also supports port forwarding and NAT. For the first version of
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the NIC router, we focused on the technical realization. Now, besides
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some optimization and restructuring, we took the chance to polish the
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configuration interface of the component. The goal was to make the interface
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more intuitive and reduce pitfalls to a minimum. Roughly speaking, the
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handling of the NIC router became more tailored to its/our typical use cases.
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Let's create a practical setup to explain the changes in detail. Assume that
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there are two virtual subnets 192.168.1.0/24 and 192.168.2.0/24 within our
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Genode system. They connect as Virtnet A and B to the router. The standard
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gateway of the virtual networks is the NIC router with IP 192.168.*.1 . The
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router's uplink, on the other hand, is connected to the NIC driver. It
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interfaces the machine with our real-world home network 10.0.2.0/24. The home
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network is connected to the internet through its standard gateway 10.0.2.1.
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[image nic_router_basic]
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The basic router configuration for this setup without any routing rules would
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be as follows:
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! <policy label_prefix="virtnet_a" domain="virtnet_a" />
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! <policy label_prefix="virtnet_b" domain="virtnet_b" />
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!
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! <domain name="uplink" interface="10.0.2.55/24" gateway="10.0.2.1" />
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! <domain name="virtnet_a" interface="192.168.1.1/24" />
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! <domain name="virtnet_b" interface="192.168.2.1/24" />
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The first thing to notice is the changed usage of the policy tag. Previously,
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the policy label - normally solely designated to correlate sessions with
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configuration domains - was misused also as unique peer identifier in the
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routing rules. This approach disregarded advanced label-matching techniques
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such as the 'label_prefix' used above. Now, the whole NIC-router-specific
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enhancement of the policy tag moved to the new '<domain>' tag, leaving the
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policy tag only with its original purpose to select policies. Note that even
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if this modification gives the impression, the router is not yet capable of
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handling multiple NIC sessions at one domain at a time.
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In the domain tag, the 'interface' attribute replaces the old policy attribute
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named 'src'. That means, it tells the router which IP identity to use when
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talking as itself to the domain. But in addition to that, the 'interface'
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attribute also defines which subnet this identity and the domain belong to.
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This reflects a basic decision we made during the reworking process: The new
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NIC router is aware of subnets. Sessions of the same subnet have the same
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configuration domain. We came to this conclusion as it solves some fundamental
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problems with the old version. First, the equivalence of domain and subnet
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enables us to link a default gateway to a subnet by adding the 'gateway'
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attribute to the domain tag. In our example, this is done in the uplink
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domain. The 'gateway' attribute is optional for a domain and replaces the
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former 'via' attributes of the different routing rules. It is more efficient
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and natural to have this value set only once at the corresponding subnet than
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having it scattered all over the routing rules of the remote domains as done
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before. If a domain has no default gateway, it drops all packets with a
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foreign recipient.
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The second advantage of a domain being equivalent to a subnet is that handling
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ARP broadcasts becomes easy. It can be excluded that such ARP broadcasts
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concern sessions outside the source domain anymore. And as sessions in the
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same domain are not distinguishable to the routing, the broadcast can be sent
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to all of them without breaking any rules.
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Now, let's enhance our example by some routing rules. One pretty complicated
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thing to do with the old NIC router was port forwarding. You had to combine
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different routing rules, explicitly enable the back routing at the remote
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side, and take care that NAT was applied - a lot of opportunities for
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mistakes. With the new version, it became easier. Let's assume we have an HTTP
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server in Virtnet A and an NTP server in Virtnet B. We want the NIC router to
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act as proxy for their services in our home network.
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[image nic_router_servers]
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In order to achieve this, the uplink domain must be enhanced by two rules:
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! <policy label_prefix="virtnet_a" domain="virtnet_a" />
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! <policy label_prefix="virtnet_b" domain="virtnet_b" />
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!
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! <domain name="uplink" interface="10.0.2.55/24" gateway="10.0.2.1" />
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! <tcp-forward port="443" domain="virtnet_a" to="192.168.1.2" />
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! <udp-forward port="123" domain="virtnet_b" to="192.168.2.2" />
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! </domain>
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!
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! <domain name="virtnet_a" interface="192.168.1.1/24" />
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! <domain name="virtnet_b" interface="192.168.2.1/24" />
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The TCP forwarding rule for port 443 (HTTP+TLS/SSL) redirects to IP address
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192.168.1.2 in Virtnet A and the UDP forwarding rule for port 123 (NTP)
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redirects to IP address 192.168.2.2 in Virtnet B. The Virtnet domains remain
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empty as the router keeps track of the redirected transfers and routes back
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reply packets automatically. Also automatically, the router applies NAT for the
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server as it is in the nature of port forwarding.
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Next, we add some clients to Virtnet B that like to talk to our home network
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and the internet. We want them to be hidden via NAT when they do so. For
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internet communication, they shall furthermore be limited to HTTP+TLS/SSL and
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IMAP+TLS/SSL.
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[image nic_router_client]
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This is what the router configuration looks now:
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! <policy label_prefix="virtnet_a" domain="virtnet_a" />
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! <policy label_prefix="virtnet_b" domain="virtnet_b" />
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!
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! <domain name="uplink" interface="10.0.2.55/24" gateway="10.0.2.1" />
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! <tcp-forward port="443" domain="virtnet_a" to="192.168.1.2" />
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! <udp-forward port="123" domain="virtnet_b" to="192.168.2.2" />
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! <nat domain="virtnet_b" tcp-ports="1000" udp-ports="1000">
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! </domain>
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!
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! <domain name="virtnet_a" interface="192.168.1.1/24" />
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! <domain name="virtnet_b" interface="192.168.2.1/24" >
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! <tcp dst="10.0.2.0/24"> <permit-any domain="uplink" /> </tcp>
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! <udp dst="10.0.2.0/24"> <permit-any domain="uplink" /> </udp>
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! <tcp dst="0.0.0.0/0">
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! <permit port="443" domain="uplink" />
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! <permit port="993" domain="uplink" />
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! </tcp>
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! </domain>
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There are several new tag types. One of them is the NAT configuration for
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Virtnet B in the uplink domain. In contrast to the former NIC-router version
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where NAT settings were part of the source domain, NAT is now configured in
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the target domain with a sub-tag for each source. This has the advantage
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of supporting heterogeneous NAT configurations for a packet source depending
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on which domain it talks to. Besides, it is more intuitive to read. Apart from
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that, the NAT settings haven't changed.
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Furthermore, there are the new TCP and UDP tags in the Virtnet-B domain. The
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first two of them have a 'permit-any' sub-tag. With this combination, we open
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all ports to IP addresses of the 10.0.2.0/24 subnet, our home network, and
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route them to the uplink domain. TCP packets that don't match these first two
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rules may fall back to the third. This TCP rule doesn't have all ports opened
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but only 443 (HTTP+TLS/SSL) and 993 (IMAP+TLS/SSL). Both ports are again bound
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to the uplink domain. As the IP filter 0.0.0.0/0 of the surrounding rule isn't
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restrictive, we now also route packets to a foreign destination. The NIC
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router redirects such packets to the default gateway of our home network.
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Compared to the old router version where IP and UDP/TCP routing had to be
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combined for this purpose, the new TCP and UDP rules with their
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port-permission sub-rules have some notable advantages. Like port-forwarding
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rules, TCP and UDP rules always imply link-state tracking in order to route
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back reply packets automatically. This can be seen also in our example as no
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further routing rules had to be added to the uplink domain. This aspect is
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clear from the outermost rule and not dependent on sub-rules anymore.
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Furthermore, the strict separation of UDP and TCP routing prevents
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configuration faults and increases readability. Last but not least, the
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'permit-any' rule allows something new. Opening all ports for an address range
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was previously only possible without link-state tracking as it could be
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expressed only on the IP level.
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At this point, we have thoroughly discussed the layer-3 routing abilities of
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|
the new NIC router and our focus has indeed moved more into this direction.
|
|
Even though IP routing is still available, we found that it should be more
|
|
clearly separated from the rest. To illustrate this feature, we enhance our
|
|
example again. We want the Virtnets to be allowed to communicate to each other
|
|
without any restrictions. For that purpose, we add two more rules to the
|
|
router configuration:
|
|
|
|
! <policy label_prefix="virtnet_a" domain="virtnet_a" />
|
|
! <policy label_prefix="virtnet_b" domain="virtnet_b" />
|
|
!
|
|
! <domain name="uplink" interface="10.0.2.55/24" gateway="10.0.2.1" />
|
|
! <tcp-forward port="443" domain="virtnet_a" to="192.168.1.2" />
|
|
! <udp-forward port="123" domain="virtnet_b" to="192.168.2.2" />
|
|
! <nat domain="virtnet_b" tcp-ports="1000" udp-ports="1000">
|
|
! </domain>
|
|
!
|
|
! <domain name="virtnet_a" interface="192.168.1.1/24" />
|
|
! <ip dst="192.168.2.0/24" domain="virtnet_b"/>
|
|
! </domain>
|
|
!
|
|
! <domain name="virtnet_b" interface="192.168.2.1/24" >
|
|
! <tcp dst="10.0.2.0/24"> <permit-any domain="uplink" /> </tcp>
|
|
! <udp dst="10.0.2.0/24"> <permit-any domain="uplink" /> </udp>
|
|
! <tcp dst="0.0.0.0/0">
|
|
! <permit port="443" domain="uplink" />
|
|
! <permit port="993" domain="uplink" />
|
|
! </tcp>
|
|
! <ip dst="192.168.1.0/24" domain="virtnet_a"/>
|
|
! </domain>
|
|
|
|
As you can see, each of the new IP rules in the Virtnet domains match the
|
|
addresses of the opposite subnet and route to the corresponding domain. As
|
|
mentioned, the new IP rules and UDP/TCP rules are not combined anymore to
|
|
clearly distinguish IP routing from layer-3 routing because this decision has
|
|
far-reaching effects. First, in contrast to UDP and TCP routing, IP routing is
|
|
stateless. Thus, for each IP routing rule one has to be sure to have a
|
|
back-routing rule at the remote domain or else bidirectional communication
|
|
won't happen. And second, NAT does not apply to IP-routed packets. So, if
|
|
you're not aware of such packets, you may unintentionally reveal information
|
|
about a private network.
|
|
|
|
For more details on the new NIC router, you may refer to the comprehensive
|
|
documentation in the _repos/os/src/server/nic_router/README_ file and the
|
|
basic NIC-router test at _libports/run/nic_router.run_ .
|
|
|
|
|
|
Base framework
|
|
##############
|
|
|
|
Improved RPC mechanism
|
|
======================
|
|
|
|
Since we introduced Genode's current API for synchronous RPCs in
|
|
[https://genode.org/documentation/release-notes/11.05#New_API_for_type-safe_inter-process_communication - version 11.05],
|
|
inter-component communication within Genode has become almost a child's play.
|
|
The RPC framework leverages the C++ type system and templates to a great
|
|
effect. In contrast to the traditional use of IDL compilers, the interaction
|
|
with RPC objects provided by other components is robust and natural because
|
|
no language boundaries need to be crossed.
|
|
|
|
Still, a few differences between RPC calls and regular function calls remain.
|
|
In particular, there exist a few restrictions with regard to the types of
|
|
RPC function arguments. Those types did not just need to be POD (plain old
|
|
data) types but they had to be default-constructible, too. Whereas the former
|
|
restriction still applies (non-POD objects that include references or
|
|
vtables cannot be used as arguments), the latter limitation has been lifted
|
|
now. Generally, non-default-constructible types are a way to attain
|
|
simpler code because the special case of an "invalid" object does not need
|
|
to be considered. I.e., values of such types can be kept as constants as
|
|
opposed to variables. If an object exists (as equivalent to successful
|
|
instantiation), it is valid. With the improved RPC mechanism, the RPC
|
|
framework does no longer stay in the way in this respect.
|
|
|
|
Thanks to Edgard Schmidt for this welcome contribution!
|
|
|
|
|
|
Unification and tightening of session labels
|
|
============================================
|
|
|
|
In Genode, each session requested by a client component is labeled according
|
|
to the components that intermediate the session request. The client can
|
|
optionally specify a label of choice along with the session request. Its
|
|
parent prefixes the client-provided label by a label of its own. If the
|
|
session request is further passed to the parent's parent, the grandparent
|
|
prepends its own label. This works recursively. Consequently, the final label
|
|
as seen by the server is the product of the labeling policies of all
|
|
components on the route of the session request.
|
|
|
|
The label is used for two purposes. First, the server uses the label as
|
|
a key for a server-side policy selection. E.g., depending on the session label
|
|
received by the disk-partition server, the server decides which partition to
|
|
hand out to the client. Second, the label is used by intermediate components
|
|
to take session-routing decisions. E.g., based on the label of a file-system
|
|
session request, a parent component may route the request to one of several
|
|
file-system servers.
|
|
|
|
Originally, Genode did not impose a specific way of how labels are formed.
|
|
It was up to each intermediate component to filter the label of a session
|
|
request in any way desired. However, in practice, this freedom remained unused
|
|
and the very simple successive prefixing of labels prevails in all our use
|
|
cases. Each intermediate node concatenates its own label in front of the label
|
|
supplied by the originator of the session request. The different parts of the
|
|
label are separated with the character sequence '" -> "'. Some corner cases
|
|
were handles specially for aesthetic reasons. For example, if a client
|
|
provided no label, the parent would skip the pending separator. That said,
|
|
since each intermediate component had to provide the labeling policy, not all
|
|
components were consistent in these respects. Since we found no use for
|
|
arbitrary labeling policies, we decided to make the only prominent way of
|
|
session labeling mandatory for all intermediate components. We thereby removed
|
|
the aesthetically motivated corner cases and possible ambiguities. I.e., with
|
|
the original policy, it was not possible to distinguish a unlabeled session
|
|
requested by a client from a labeled session requested by the client's parent.
|
|
|
|
As a consequence, the stricter labeling must now be considered wherever
|
|
a precise label was specified as a key for a session route or a server-side
|
|
policy selection. The simplest way to adapt those cases is to use a
|
|
'label_prefix' instead of the 'label' attribute. Alternatively, the
|
|
'label' attribute may used by appending '" -> "' (note the whitespace).
|
|
|
|
|
|
Transition to new framework API
|
|
===============================
|
|
|
|
Since we fundamentally revised Genode's API in
|
|
[https://genode.org/documentation/release-notes/16.05#The_great_API_renovation - version 16.05],
|
|
we gradually adapt our existing components. Given that Genode comes with
|
|
over 300 components, this is no small feat. But with 30 percent of the
|
|
components converted, we already made substantial progress.
|
|
|
|
In some respects, the conversion is actually nearly complete. In particular,
|
|
the move away from format-string-based text output to our new type-safe output
|
|
facility has been applied to almost all components now. The former 'PDBG'
|
|
macro that is quite useful for temporary debug messages has been replaced with
|
|
a new version that must be manually included via the _base/debug.h_ header
|
|
file. Like the regular log functions, the new PDBG facility uses the type-safe
|
|
text-output facility.
|
|
|
|
|
|
Minor API adjustments
|
|
---------------------
|
|
|
|
While applying Genode's new API, we refined the API in the following respects:
|
|
|
|
We added a dedicated 'String' constructor overload to better accommodate
|
|
string literals. This overload covers the common case for initializing a
|
|
string from a literal without employing the 'Output' mechanism. This way, such
|
|
strings can by constructed without calling virtual functions, which in turn
|
|
makes the 'String' usable during the self-relocation phase of the dynamic
|
|
linker.
|
|
|
|
Up till now, several Genode components still rely on the use of 'snprintf'
|
|
whenever strings must be assembled out of smaller pieces. As we like to shun
|
|
format strings from Genode altogether, we needed an alternative mechanism.
|
|
Since we introduced the new type-safe text-output facilities in Genode 16.05,
|
|
there is an obvious solution: Let the 'String' constructor accept an arbitrary
|
|
list of arguments, which are turned into their respective textual
|
|
representation and appear concatenated in the resulting string. Consequently,
|
|
strings can be assembled with the same flexibility as log output. For the
|
|
construction of 'String' objects from character buffers of a known size, the
|
|
'Cstring' utility can be used, which takes a 'char const *' and an optional
|
|
length as arguments.
|
|
|
|
Several low-level types received support for the new output facilities, e.g.,
|
|
'Xml_node' or the network-related headers in _os/net/_.
|
|
|
|
In anticipation of the forthcoming package-management infrastructure, we try
|
|
to unify Genode's executable binaries across kernels and architectures
|
|
wherever reasonable. Of course, the latter is not possible with respect to the
|
|
used instructions. But unifying symbol information is deemed worthwhile. For
|
|
this reason, we changed the 'Genode::size_t' type to be always defined as an
|
|
'unsigned' 'long'. This is in contrast to GCC's built-in '__SIZE_TYPE__',
|
|
which is defined as 'unsigned int' on 32-bit architectures but 'unsigned long'
|
|
on 64-bit architectures.
|
|
|
|
|
|
OS-level infrastructure and device drivers
|
|
##########################################
|
|
|
|
New timeout-handing API
|
|
=======================
|
|
|
|
The new timeout API offers tools for easily multiplexing a single time
|
|
source among different timeouts. In general, the time source can be
|
|
implemented individually but we expect that the most prominent use case will
|
|
be the multiplexing of timer sessions. Thus, the timeout library also provides
|
|
a convenience tool for this use case. A library-usage example can be found
|
|
under _os/src/test/timeout_. If you're interested in implementing
|
|
your own time source, you can find an example at _os/include/os/timer.h_ .
|
|
|
|
|
|
Support for smart cards
|
|
=======================
|
|
|
|
We ported the [https://pcsclite.alioth.debian.org/pcsclite.html - PC/SC Lite]
|
|
library to Genode, which provides a commonly used API for communicating with
|
|
smart cards. It supports USB smart card readers, using the
|
|
[https://pcsclite.alioth.debian.org/ccid.html - CCID] library as driver.
|
|
The CCID driver itself requires [https://libusb.info - libusb] to access the
|
|
USB device.
|
|
|
|
Vanilla PC/SC Lite is structured as a client-server architecture, consisting
|
|
of the 'pcscd' daemon, which runs on a privileged user account and manages all
|
|
card reader devices, and one or more non-privileged client applications, which
|
|
communicate with pcscd to access the card readers. On Genode, pcscd's role as
|
|
privileged device manager is not really needed, since the devices can also be
|
|
managed using Genode's configuration mechanisms. For this reason, we merged
|
|
the part of pcscd which implements the API with the pcsc-lite client library.
|
|
|
|
In the current state, a Genode application using PC/SC Lite can access a single
|
|
card reader device, which is selected using its USB product ID and vendor ID in
|
|
the application's configuration and in the policy of the USB driver.
|
|
|
|
More configuration details can be found in the README files of the PC/SC Lite,
|
|
CCID, and libusb libraries in the libports repository and in the accompanying
|
|
_smartcard.run_ script.
|
|
|
|
|
|
Libraries and applications
|
|
##########################
|
|
|
|
Time-based password generation
|
|
==============================
|
|
|
|
A time-based one-time password authentication client that adheres to the
|
|
Google Authenticator standard has been introduced into the
|
|
[https://github.com/genodelabs/genode-world - world repository].
|
|
|
|
Single use, time-based passwords are commonly used as an additional
|
|
authentication step for web-based services. In this scheme, a user generates
|
|
and presents a six digit passcode to a service generated using a shared secret
|
|
and a timestamp. This short passcode length makes manual entry convenient so
|
|
that the shared secret may be stored on a separate device than the service
|
|
client, such as a smartphone, layering the security properties of both
|
|
devices.
|
|
|
|
The 'gtotp' VFS plugin provides these passcodes by embedding the generator as
|
|
a special file in the file-system layer of a component. This approach provides
|
|
readily available passcodes for programmatic and manual use without enlarging
|
|
the code base to encompass a GUI, command-line, or networked interface.
|
|
|
|
At the time of this release, the common use case is to manually retrieve codes
|
|
for clients running in VirtualBox by reading special files with an isolated
|
|
instance of the Noux runtime. Storing the shared secret on the same device
|
|
contradicts the recommendations of the standard but the trade-off is that the
|
|
software stack required to host the shared secret is significantly smaller
|
|
than that found on a mobile device.
|
|
|
|
|
|
Random number generator testing
|
|
===============================
|
|
|
|
No random number generator can be proved to be good, but empirical statistical
|
|
tests can prove that some are bad. A port of the TestU01 RNG test suite is
|
|
provided in the world repository. The TestU01 batteries give independent
|
|
assurance of the fitness of Genode's CPU jitter based RNG and are available
|
|
for testing future physical and non-phyical RNGs.
|
|
|
|
|
|
VirtualBox on top on the NOVA hypervisor
|
|
########################################
|
|
|
|
Both VirtualBox-based virtual machine monitors on Genode got updated to the
|
|
latest revision as provided by Oracle, namely 4.3.40 and 5.1.10 - mainly to
|
|
stay close to the upstream versions.
|
|
|
|
|
|
Platforms
|
|
#########
|
|
|
|
Unified handling of boot modules
|
|
================================
|
|
|
|
Until now, the way of passing boot modules from the boot procedure to the core
|
|
component, which core provides as ROM modules, varied from platform to
|
|
platform. Either we used a multiboot-compliant bootloader that accepts
|
|
multiple modules, or the platform provided some specific way of linking binary
|
|
modules together with the kernel, e.g., the Elfweaver tool of OKL4.
|
|
By unifying the boot-module handover, we further reduce platform specific core
|
|
code. Thereby, maintenance costs are decreased, and code analysis becomes
|
|
easier. With this new solution, when issuing to build the core component:
|
|
|
|
! make core
|
|
|
|
within the build system, only a core library gets built. Not until all
|
|
binaries needed by a run-script are available, a final image is linked
|
|
together using the core library and all additional binaries. The core
|
|
component now can access its ROM modules directly via addresses contained in
|
|
its binary. As a side effect of this change, there is no core binary in the
|
|
'bin' or 'core' directory of the corresponding build directory available
|
|
anymore. Instead, you will find the core binary with no ROM modules, but
|
|
including debug information under 'var/run/*.core' within your build
|
|
directory. The concrete name depends on the name of the run-script.
|
|
|
|
The new approach is used on all platforms except Linux where the ROM modules
|
|
still need to be accessed via the file-system.
|
|
|
|
|
|
NOVA hypervisor
|
|
===============
|
|
|
|
We extended the kernel to support the asynchronous delegation of kernel
|
|
resources. Up to now, resources could only be delegated during RPC or during
|
|
the initial protection-domain construction. With this extension, the
|
|
construction and setup of new protection domains, threads, and especially
|
|
virtual CPUs for the VirtualBox VMM became more straightforward and several
|
|
quirks inside the 'core' component could be dropped. The added kernel syscall
|
|
expects the NOVA-kernel capabilities of the source and target protection
|
|
domains, which effectively renders the operation solely available to 'core' -
|
|
as only holder of the NOVA protection domain capabilities.
|
|
|
|
Additionally, we changed the CPU ID enumeration in Genode/NOVA to a
|
|
predictable order. The lower CPU IDs used via the Genode 'Cpu_session'
|
|
interface now correspond to the first hyper-thread of all physical CPU cores.
|
|
For example, on a quad-core machine with hyper-threading enabled Genode's CPU
|
|
IDs 0-3 refer to the first hyper-threads of all physical cores and IDs 4-7 to
|
|
the second hyper-threads.
|
|
|