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+## @file
+#
+# Technical notes for the virtio-net driver.
+#
+# Copyright (C) 2013, Red Hat, Inc.
+#
+# This program and the accompanying materials are licensed and made available
+# under the terms and conditions of the BSD License which accompanies this
+# distribution. The full text of the license may be found at
+# http://opensource.org/licenses/bsd-license.php
+#
+# THE PROGRAM IS DISTRIBUTED UNDER THE BSD LICENSE ON AN "AS IS" BASIS, WITHOUT
+# WARRANTIES OR REPRESENTATIONS OF ANY KIND, EITHER EXPRESS OR IMPLIED.
+#
+##
+
+Disclaimer
+----------
+
+All statements concerning standards and specifications are informative and not
+normative. They are made in good faith. Corrections are most welcome on the
+edk2-devel mailing list.
+
+The following documents have been perused while writing the driver and this
+document:
+- Unified Extensible Firmware Interface Specification, Version 2.3.1, Errata C;
+ June 27, 2012
+- Driver Writer's Guide for UEFI 2.3.1, 03/08/2012, Version 1.01;
+- Virtio PCI Card Specification, v0.9.5 DRAFT, 2012 May 7.
+
+
+Summary
+-------
+
+The VirtioNetDxe UEFI_DRIVER implements the Simple Network Protocol for
+virtio-net devices. Higher level protocols are automatically installed on top
+of it by the DXE Core / the ConnectController() boot service, enabling for
+virtio-net devices eg. DHCP configuration, TCP transfers with edk2 StdLib
+applications, and PXE booting in OVMF.
+
+
+UEFI driver structure
+---------------------
+
+A driver instance, belonging to a given virtio-net device, can be in one of
+four states at any time. The states stack up as follows below. The state
+transitions are labeled with the primary function (and its important callees
+faithfully indented) that implement the transition.
+
+ | ^
+ | |
+ [DriverBinding.c] | | [DriverBinding.c]
+ VirtioNetDriverBindingStart | | VirtioNetDriverBindingStop
+ VirtioNetSnpPopulate | | VirtioNetSnpEvacuate
+ VirtioNetGetFeatures | |
+ v |
+ +-------------------------+
+ | EfiSimpleNetworkStopped |
+ +-------------------------+
+ | ^
+ [SnpStart.c] | | [SnpStop.c]
+ VirtioNetStart | | VirtioNetStop
+ | |
+ v |
+ +-------------------------+
+ | EfiSimpleNetworkStarted |
+ +-------------------------+
+ | ^
+ [SnpInitialize.c] | | [SnpShutdown.c]
+ VirtioNetInitialize | | VirtioNetShutdown
+ VirtioNetInitRing {Rx, Tx} | | VirtioNetShutdownRx [SnpSharedHelpers.c]
+ VirtioRingInit | | VirtioNetShutdownTx [SnpSharedHelpers.c]
+ VirtioNetInitTx | | VirtioRingUninit {Tx, Rx}
+ VirtioNetInitRx | |
+ v |
+ +-----------------------------+
+ | EfiSimpleNetworkInitialized |
+ +-----------------------------+
+
+The state at the top means "nonexistent" and is hence unnamed on the diagram --
+a driver instance actually doesn't exist at that point. The transition
+functions out of and into that state implement the Driver Binding Protocol.
+
+The lower three states characterize an existent driver instance and are all
+states defined by the Simple Network Protocol. The transition functions between
+them are member functions of the Simple Network Protocol.
+
+Each transition function validates its expected source state and its
+parameters. For example, VirtioNetDriverBindingStop will refuse to disconnect
+from the controller unless it's in EfiSimpleNetworkStopped.
+
+
+Driver instance states (Simple Network Protocol)
+------------------------------------------------
+
+In the EfiSimpleNetworkStopped state, the virtio-net device is (has been)
+re-set. No resources are allocated for networking / traffic purposes. The MAC
+address and other device attributes have been retrieved from the device (this
+is necessary for completing the VirtioNetDriverBindingStart transition).
+
+The EfiSimpleNetworkStarted is completely identical to the
+EfiSimpleNetworkStopped state for virtio-net, in the functional and
+resource-usage sense. This state is mandated / provided by the Simple Network
+Protocol for flexibility that the virtio-net driver doesn't exploit.
+
+In particular, the EfiSimpleNetworkStarted state is the target of the Shutdown
+SNP member function, and must therefore correspond to a hardware configuration
+where "[it] is safe for another driver to initialize". (Clearly another UEFI
+driver could not do that due to the exclusivity of the driver binding that
+VirtioNetDriverBindingStart() installs, but a later OS driver might qualify.)
+
+The EfiSimpleNetworkInitialized state is the live state of the virtio NIC / the
+driver instance. Virtio and other resources required for network traffic have
+been allocated, and the following SNP member functions are available (in
+addition to VirtioNetShutdown which leaves the state):
+
+- VirtioNetReceive [SnpReceive.c]: poll the virtio NIC for an Rx packet that
+ may have arrived asynchronously;
+
+- VirtioNetTransmit [SnpTransmit.c]: queue a Tx packet for asynchronous
+ transmission (meant to be used together with VirtioNetGetStatus);
+
+- VirtioNetGetStatus [SnpGetStatus.c]: query link status and status of pending
+ Tx packets;
+
+- VirtioNetMcastIpToMac [SnpMcastIpToMac.c]: transform a multicast IPv4/IPv6
+ address into a multicast MAC address;
+
+- VirtioNetReceiveFilters [SnpReceiveFilters.c]: emulate unicast / multicast /
+ broadcast filter configuration (not their actual effect -- a more liberal
+ filter setting than requested is allowed by the UEFI specification).
+
+The following SNP member functions are not supported [SnpUnsupported.c]:
+
+- VirtioNetReset: reinitialize the virtio NIC without shutting it down (a loop
+ from/to EfiSimpleNetworkInitialized);
+
+- VirtioNetStationAddress: assign a new MAC address to the virtio NIC,
+
+- VirtioNetStatistics: collect statistics,
+
+- VirtioNetNvData: access non-volatile data on the virtio NIC.
+
+Missing support for these functions is allowed by the UEFI specification and
+doesn't seem to trip up higher level protocols.
+
+
+Events and task priority levels
+-------------------------------
+
+The UEFI specification defines a sophisticated mechanism for asynchronous
+events / callbacks (see "6.1 Event, Timer, and Task Priority Services" for
+details). Such callbacks work like software interrupts, and some notion of
+locking / masking is important to implement critical sections (atomic or
+exclusive access to data or a device). This notion is defined as Task Priority
+Levels.
+
+The virtio-net driver for OVMF must concern itself with events for two reasons:
+
+- The Simple Network Protocol provides its clients with a (non-optional) WAIT
+ type event called WaitForPacket: it allows them to check or wait for Rx
+ packets by polling or blocking on this event. (This functionality overlaps
+ with the Receive member function.) The event is available to clients starting
+ with EfiSimpleNetworkStopped (inclusive).
+
+ The virtio-net driver is informed about such client polling or blockage by
+ receiving an asynchronous callback (a software interrupt). In the callback
+ function the driver must interrogate the driver instance state, and if it is
+ EfiSimpleNetworkInitialized, access the Rx queue and see if any packets are
+ available for consumption. If so, it must signal the WaitForPacket WAIT type
+ event, waking the client.
+
+ For simplicity and safety, all parts of the virtio-net driver that access any
+ bit of the driver instance (data or device) run at the TPL_CALLBACK level.
+ This is the highest level allowed for an SNP implementation, and all code
+ protected in this manner satisfies even stricter non-blocking requirements
+ than what's documented for TPL_CALLBACK.
+
+ The task priority level for the WaitForPacket callback too is set by the
+ driver, the choice is TPL_CALLBACK again. This in effect serializes the
+ WaitForPacket callback (VirtioNetIsPacketAvailable [Events.c]) with "normal"
+ parts of the driver.
+
+- According to the Driver Writer's Guide, a network driver should install a
+ callback function for the global EXIT_BOOT_SERVICES event (a special NOTIFY
+ type event). When the ExitBootServices() boot service has cleaned up internal
+ firmware state and is about to pass control to the OS, any network driver has
+ to stop any in-flight DMA transfers, lest it corrupts OS memory. For this
+ reason EXIT_BOOT_SERVICES is emitted and the network driver must abort
+ in-flight DMA transfers.
+
+ This callback (VirtioNetExitBoot) is synchronized with the rest of the driver
+ code just the same as explained for WaitForPacket. In
+ EfiSimpleNetworkInitialized state it resets the virtio NIC, halting all data
+ transfer. After the callback returns, no further driver code is expected to
+ be scheduled.
+
+
+Virtio internals -- Rx
+----------------------
+
+Requests (Rx and Tx alike) are always submitted by the guest and processed by
+the host. For Tx, processing means transmission. For Rx, processing means
+filling in the request with an incoming packet. Submitted requests exist on the
+"Available Ring", and answered (processed) requests show up on the "Used Ring".
+
+Packet data includes the media (Ethernet) header: destination MAC, source MAC,
+and Ethertype (14 bytes total).
+
+The following structures implement packet reception. Most of them are defined
+in the Virtio specification, the only driver-specific trait here is the static
+pre-configuration of the two-part descriptor chains, in VirtioNetInitRx. The
+diagram is simplified.
+
+ Available Index Available Index
+ last processed incremented
+ by the host by the guest
+ v -------> v
+Available +-------+-------+-------+-------+-------+
+Ring |DescIdx|DescIdx|DescIdx|DescIdx|DescIdx|
+ +-------+-------+-------+-------+-------+
+ =D6 =D2
+
+ D2 D3 D4 D5 D6 D7
+Descr. +----------+----------++----------+----------++----------+----------+
+Table |Adr:Len:Nx|Adr:Len:Nx||Adr:Len:Nx|Adr:Len:Nx||Adr:Len:Nx|Adr:Len:Nx|
+ +----------+----------++----------+----------++----------+----------+
+ =A2 =D3 =A3 =A4 =D5 =A5 =A6 =D7 =A7
+
+
+ A2 A3 A4 A5 A6 A7
+Receive +---------------+---------------+---------------+
+Destination |vnet hdr:packet|vnet hdr:packet|vnet hdr:packet|
+Area +---------------+---------------+---------------+
+
+ Used Index Used Index incremented
+ last processed by the guest by the host
+ v -------> v
+Used +-----------+-----------+-----------+-----------+-----------+
+Ring |DescIdx:Len|DescIdx:Len|DescIdx:Len|DescIdx:Len|DescIdx:Len|
+ +-----------+-----------+-----------+-----------+-----------+
+ =D4
+
+In VirtioNetInitRx, the guest allocates the fixed size Receive Destination
+Area, which accommodates all packets delivered asynchronously by the host. To
+each packet, a slice of this area is dedicated; each slice is further
+subdivided into virtio-net request header and network packet data. The
+(guest-physical) addresses of these sub-slices are denoted with A2, A3, A4 and
+so on. Importantly, an even-subscript "A" always belongs to a virtio-net
+request header, while an odd-subscript "A" always belongs to a packet
+sub-slice.
+
+Furthermore, the guest lays out a static pattern in the Descriptor Table. For
+each packet that can be in-flight or already arrived from the host,
+VirtioNetInitRx sets up a separate, two-part descriptor chain. For packet N,
+the Nth descriptor chain is set up as follows:
+
+- the first (=head) descriptor, with even index, points to the fixed-size
+ sub-slice receiving the virtio-net request header,
+
+- the second descriptor (with odd index) points to the fixed (1514 byte) size
+ sub-slice receiving the packet data,
+
+- a link from the first (head) descriptor in the chain is established to the
+ second (tail) descriptor in the chain.
+
+Finally, the guest populates the Available Ring with the indices of the head
+descriptors. All descriptor indices on both the Available Ring and the Used
+Ring are even.
+
+Packet reception occurs as follows:
+
+- The host consumes a descriptor index off the Available Ring. This index is
+ even (=2*N), and fingers the head descriptor of the chain belonging to packet
+ N.
+
+- The host reads the descriptors D(2*N) and -- following the Next link there
+ --- D(2*N+1), and stores the virtio-net request header at A(2*N), and the
+ packet data at A(2*N+1).
+
+- The host places the index of the head descriptor, 2*N, onto the Used Ring,
+ and sets the Len field in the same Used Ring Element to the total number of
+ bytes transferred for the entire descriptor chain. This enables the guest to
+ identify the length of Rx packets.
+
+- VirtioNetReceive polls the Used Ring. If a new Used Ring Element shows up, it
+ copies the data out to the caller, and recycles the index of the head
+ descriptor (ie. 2*N) to the Available Ring.
+
+- Because the host can process (answer) Rx requests in any order theoretically,
+ the order of head descriptor indices on each of the Available Ring and the
+ Used Ring is virtually random. (Except right after the initial population in
+ VirtioNetInitRx, when the Available Ring is full and increasing, and the Used
+ Ring is empty.)
+
+- If the Available Ring is empty, the host is forced to drop packets. If the
+ Used Ring is empty, VirtioNetReceive returns EFI_NOT_READY (no packet
+ available).
+
+
+Virtio internals -- Tx
+----------------------
+
+The transmission structure erected by VirtioNetInitTx is similar, it differs
+in the following:
+
+- There is no Receive Destination Area.
+
+- Each head descriptor, D(2*N), points to a read-only virtio-net request header
+ that is shared by all of the head descriptors. This virtio-net request header
+ is never modified by the host.
+
+- Each tail descriptor is re-pointed to the caller-supplied packet buffer
+ whenever VirtioNetTransmit places the corresponding head descriptor on the
+ Available Ring. The caller is responsible to hang on to the unmodified buffer
+ until it is reported transmitted by VirtioNetGetStatus.
+
+Steps of packet transmission:
+
+- Client code calls VirtioNetTransmit. VirtioNetTransmit tracks free descriptor
+ chains by keeping the indices of their head descriptors in a stack that is
+ private to the driver instance. All elements of the stack are even.
+
+- If the stack is empty (that is, each descriptor chain, in isolation, is
+ either pending transmission, or has been processed by the host but not
+ yet recycled by a VirtioNetGetStatus call), then VirtioNetTransmit returns
+ EFI_NOT_READY.
+
+- Otherwise the index of a free chain's head descriptor is popped from the
+ stack. The linked tail descriptor is re-pointed as discussed above. The head
+ descriptor's index is pushed on the Available Ring.
+
+- The host moves the head descriptor index from the Available Ring to the Used
+ Ring when it transmits the packet.
+
+- Client code calls VirtioNetGetStatus. In case the Used Ring is empty, the
+ function reports no Tx completion. Otherwise, a head descriptor's index is
+ consumed from the Used Ring and recycled to the private stack. The client
+ code's original packet buffer address is fetched from the tail descriptor
+ (where it has been stored at VirtioNetTransmit time) and returned to the
+ caller.
+
+- The Len field of the Used Ring Element is not checked. The host is assumed to
+ have transmitted the entire packet -- VirtioNetTransmit had forced it below
+ 1514 bytes (inclusive). The Virtio specification suggests this packet size is
+ always accepted (and a lower MTU could be encountered on any later hop as
+ well). Additionally, there's no good way to report a short transmit via
+ VirtioNetGetStatus; EFI_DEVICE_ERROR seems too serious from the specification
+ and higher level protocols could interpret it as a fatal condition.
+
+- The host can theoretically reorder head descriptor indices when moving them
+ from the Available Ring to the Used Ring (out of order transmission). Because
+ of this (and the choice of a stack over a list for free descriptor chain
+ tracking) the order of head descriptor indices on either Ring is
+ unpredictable.