1. INTRODUCTION =============== This document describes the specifications of the “virtio” family of devices. These are devices are found in virtual environments, yet by design they are not all that different from physical devices, and this document treats them as such. This allows the guest to use standard drivers and discovery mechanisms. The purpose of virtio and this specification is that virtual environments and guests should have a straightforward, efficient, standard and extensible mechanism for virtual devices, rather than boutique per-environment or per-OS mechanisms. Straightforward: Virtio devices use normal bus mechanisms of interrupts and DMA which should be familiar to any device driver author. There is no exotic page-flipping or COW mechanism: it's just a normal device.[1] Efficient: Virtio devices consist of rings of descriptors for input and output, which are neatly separated to avoid cache effects from both guest and device writing to the same cache lines. Standard: Virtio makes no assumptions about the environment in which it operates, beyond supporting the bus attaching the device. Virtio devices are implemented over PCI and other buses, and earlier drafts been implemented on other buses not included in this spec.[2] Extensible: Virtio PCI devices contain feature bits which are acknowledged by the guest operating system during device setup. This allows forwards and backwards compatibility: the device offers all the features it knows about, and the driver acknowledges those it understands and wishes to use. 1.1.1. Key words ----------------- The key words must, must not, required, shall, shall not, should, should not, recommended, may, and optional are to be interpreted as described in [RFC 2119]. Note that for reasons of style, these words are not capitalized in this document. 1.1.2. Definitions ------------------- term Definition 1.1.3. Key concepts -------------------- Guest Definition... Host Definition Device Definition Driver Definition 1.2. Normative References ========================= [RFC 2119] S. Bradner, Key words for use in RFCs to Indicate Requirement Levels, http://www.ietf.org/rfc/rfc2119.txt IETF (Internet Engineering Task Force) RFC 2119, March 1997. [S390 PoP] z/Architecture Principles of Operation, IBM Publication SA22-7832 [S390 Common I/O] ESA/390 Common I/O-Device and Self-Description, IBM Publication SA22-7204 1.3. Non-Normative References ========================= 2. The Virtio Standard ========================= 2.1. Basic Facilities of a Virtio Device ======================================= A virtio device is discovered and identified by a bus-specific method (see the bus specific sections: "2.3.1. Virtio Over PCI Bus", "2.3.2. Virtio Over MMIO" and "2.3.3. Virtio over channel I/O"). Each device consists of the following parts: o Device Status field o Feature bits o Configuration space o One or more virtqueues Unless explicitly specified otherwise, all multi-byte fields are little-endian. To reinforce this the examples use typenames like "le16" instead of "uint16_t". 2.1.1. Device Status Field ------------------------- The Device Status field is updated by the guest to indicate its progress. This provides a simple low-level diagnostic: it's most useful to imagine them hooked up to traffic lights on the console indicating the status of each device. This field is 0 upon reset, otherwise at least one bit should be set: ACKNOWLEDGE (1) Indicates that the guest OS has found the device and recognized it as a valid virtio device. DRIVER (2) Indicates that the guest OS knows how to drive the device. Under Linux, drivers can be loadable modules so there may be a significant (or infinite) delay before setting this bit. FEATURES_OK (8) Indicates that the driver has acknowledged all the features it understands, and feature negotiation is complete. DRIVER_OK (4) Indicates that the driver is set up and ready to drive the device. FAILED (128) Indicates that something went wrong in the guest, and it has given up on the device. This could be an internal error, or the driver didn't like the device for some reason, or even a fatal error during device operation. The device must be reset before attempting to re-initialize. 2.1.2. Feature Bits ------------------ Each virtio device lists all the features it understands. During device initialization, the guest reads this and tells the device the subset that it understands. The only way to renegotiate is to reset the device. This allows for forwards and backwards compatibility: if the device is enhanced with a new feature bit, older guests will not write that feature bit back to the device and it can go into backwards compatibility mode. Similarly, if a guest is enhanced with a feature that the device doesn't support, it see the new feature is not offered and can go into backwards compatibility mode (or, for poor implementations, set the FAILED Device Status bit). Feature bits are allocated as follows: 0 to 23: Feature bits for the specific device type 24 to 32: Feature bits reserved for extensions to the queue and feature negotiation mechanisms 33 and above: Feature bits reserved for future extensions. For example, feature bit 0 for a network device (i.e. Subsystem Device ID 1) indicates that the device supports checksumming of packets. In particular, new fields in the device configuration space are indicated by offering a feature bit, so the guest can check before accessing that part of the configuration space. 2.1.2.1 Legacy Interface: A Note on transitions from earlier drafts -------------------------------------- Earlier drafts of this specification (up to 0.9.X) defined a similar, but different interface between the hypervisor and the guest. Since these are widely deployed, this specification accommodates optional features to simplify transition from these earlier draft interfaces. Specifically: Legacy Interface is an interface specified by an earlier draft of this specification (up to 0.9.X) Legacy Device is a device implemented before this specification was released, and implementing a legacy interface on the host side Legacy Driver is a driver implemented before this specification was released, and implementing a legacy interface on the guest side Legacy devices and legacy drivers are not compliant with this specification. To simplify transition from these earlier draft interfaces, it is possible to implement: Transitional Device a device supporting both drivers conforming to this specification, and allowing legacy drivers. Transitional Driver a driver supporting both devices conforming to this specification, and legacy devices. Transitional devices and transitional drivers can be compliant with this specification (ie. when not operating in legacy mode). Devices or drivers with no legacy compatibility are referred to as non-transitional devices and drivers, respectively. Transitional Drivers can detect Legacy Devices by detecting that the feature bit VIRTIO_F_VERSION_1 is not offered. Transitional devices can detect Legacy drivers by detecting that VIRTIO_F_VERSION_1 has not been acknowledged by the driver. In this case device is used through the legacy interface. To make them easier to locate, specification sections documenting these transitional features are explicitly marked with 'Legacy Interface' in the section title. 2.1.3. Configuration Space ------------------------- Configuration space is generally used for rarely-changing or initialization-time parameters. Drivers must not assume reads from fields greater than 32 bits wide are atomic, nor or reads from multiple fields. Each transport provides a generation count for the configuration space, which must change whenever there is a possibility that two accesses to the configuration space can see different versions of that space. Thus drivers should read configuration space fields like so: u32 before, after; do { before = get_config_generation(device); // read config entry/entries. after = get_config_generation(device); } while (after != before); Note that configuration space generally uses the little-endian format for multi-byte fields. 100.100.4.1. Legacy Interface: A Note on Configuration Space endian-ness -------------------------------------- Note that for legacy interfaces, configuration space is generally the guest's native endian, rather than PCI's little-endian. 2.1.3.1. Legacy Interface: Configuration Space ------------------------- Legacy devices did not have a configuration generation field, thus are susceptible to race conditions if configuration is updated. This effects the block capacity and network mac fields; best practice is to read these fields multiple times until two reads generate a consistent result. 2.1.4. Virtqueues ---------------- The mechanism for bulk data transport on virtio devices is pretentiously called a virtqueue. Each device can have zero or more virtqueues: for example, the simplest network device has one for transmit and one for receive. Each queue has a 16-bit queue size parameter, which sets the number of entries and implies the total size of the queue. Each virtqueue consists of three parts: Descriptor Table Available Ring Used Ring where each part is physically-contiguous in guest memory, and has different alignment requirements. The memory aligment and size requirements, in bytes, of each part of the virtqueue are summarized in the following table: +------------+-----------------------------------------+ | Virtqueue Part | Alignment | Size | +------------+-----------------------------------------+ +------------+-----------------------------------------+ | Descriptor Table | 16 | 16 * (Queue Size) | +------------+-----------------------------------------+ | Available Ring | 2 | 6 + 2 * (Queue Size) | +------------+-----------------------------------------+ | Used Ring | 4 | 6 + 4 * (Queue Size) | +------------+-----------------------------------------+ The Alignment column gives the miminum alignment: for each part of the virtqueue, the physical address of the first byte of it must be a multiple of the specified alignment value. The Size column gives the total number of bytes required for each part of the virtqueue. Queue Size corresponds to the maximum number of buffers in the virtqueue. For example, if Queue Size is 4 then at most 4 buffers can be queued at any given time. Queue Size value is always a power of 2. The maximum Queue Size value is 32768. This value is specified in a bus-specific way. When the driver wants to send a buffer to the device, it fills in a slot in the descriptor table (or chains several together), and writes the descriptor index into the available ring. It then notifies the device. When the device has finished a buffer, it writes the descriptor into the used ring, and sends an interrupt. 2.1.4.1. Legacy Interfaces: A Note on Virtqueue Layout -------------------------------------- For Legacy Interfaces, several additional restrictions are placed on the virtqueue layout: Each virtqueue occupies two or more physically-contiguous pages (usually defined as 4096 bytes, but depending on the transport) and consists of three parts: +-------------------+-----------------------------------+-----------+ | Descriptor Table | Available Ring (padding) | Used Ring | +-------------------+-----------------------------------+-----------+ The bus-specific Queue Size field controls the total number of bytes required for the virtqueue according to the following formula: #define ALIGN(x) (((x) + PAGE_SIZE) & ~PAGE_SIZE) static inline unsigned vring_size(unsigned int qsz) { return ALIGN(sizeof(struct vring_desc)*qsz + sizeof(u16)*(3 + qsz)) + ALIGN(sizeof(u16)*3 + sizeof(struct vring_used_elem)*qsz); } This wastes some space with padding. The legacy virtqueue layout structure therefore looks like this: struct vring { // The actual descriptors (16 bytes each) struct vring_desc desc[ Queue Size ]; // A ring of available descriptor heads with free-running index. struct vring_avail avail; // Padding to the next PAGE_SIZE boundary. char pad[ Padding ]; // A ring of used descriptor heads with free-running index. struct vring_used used; }; 2.1.4.1. Legacy Interfaces: A Note on Virtqueue Endianness -------------------------------------- Note that the endian of fields and in the virtqueue is the native endian of the guest, not little-endian as specified by this standard. It is assumed that the host is already aware of the guest endian. 2.1.4.2. Message Framing ----------------------- The message framing (the particular layout of descriptors) is independent of the contents of the buffers. For example, a network transmit buffer consists of a 12 byte header followed by the network packet. This could be most simply placed in the descriptor table as a 12 byte output descriptor followed by a 1514 byte output descriptor, but it could also consist of a single 1526 byte output descriptor in the case where the header and packet are adjacent, or even three or more descriptors (possibly with loss of efficiency in that case). Note that, some implementations may have large-but-reasonable restrictions on total descriptor size (such as based on IOV_MAX in the host OS). This has not been a problem in practice: little sympathy will be given to drivers which create unreasonably-sized descriptors such as by dividing a network packet into 1500 single-byte descriptors! 2.1.4.2.1. Legacy Interface: Message Framing ----------------------- Regrettably, initial driver implementations used simple layouts, and devices came to rely on it, despite this specification wording. In addition, the specification for virtio_blk SCSI commands required intuiting field lengths from frame boundaries (see "2.4.2.5.1 Legacy Interface: Device Operation") It is thus recommended that when using legacy interfaces, transitional drivers be conservative in their assumptions, unless the VIRTIO_F_ANY_LAYOUT feature is accepted. 2.1.4.3. The Virtqueue Descriptor Table -------------------------------------- The descriptor table refers to the buffers the guest is using for the device. The addresses are physical addresses, and the buffers can be chained via the next field. Each descriptor describes a buffer which is read-only or write-only, but a chain of descriptors can contain both read-only and write-only buffers. The actual contents of the memory offered to the device depends on the device type. Most common is to begin the data with a header (containing little-endian fields) for the device to read, and postfix it with a status tailer for the device to write. No descriptor chain may be more than 2^32 bytes long in total. struct vring_desc { /* Address (guest-physical). */ le64 addr; /* Length. */ le32 len; /* This marks a buffer as continuing via the next field. */ #define VRING_DESC_F_NEXT 1 /* This marks a buffer as write-only (otherwise read-only). */ #define VRING_DESC_F_WRITE 2 /* This means the buffer contains a list of buffer descriptors. */ #define VRING_DESC_F_INDIRECT 4 /* The flags as indicated above. */ le16 flags; /* Next field if flags & NEXT */ le16 next; }; The number of descriptors in the table is defined by the queue size for this virtqueue. 2.1.4.3.1. Indirect Descriptors ------------------------------ Some devices benefit by concurrently dispatching a large number of large requests. The VIRTIO_RING_F_INDIRECT_DESC feature can be used to allow this (see "2.6. Reserved Feature Bits"). To increase ring capacity it is possible to store a table of indirect descriptors anywhere in memory, and insert a descriptor in main virtqueue (with flags&VRING_DESC_F_INDIRECT on) that refers to memory buffer containing this indirect descriptor table; fields addr and len refer to the indirect table address and length in bytes, respectively. The indirect table layout structure looks like this (len is the length of the descriptor that refers to this table, which is a variable, so this code won't compile): struct indirect_descriptor_table { /* The actual descriptors (16 bytes each) */ struct vring_desc desc[len / 16]; }; The first indirect descriptor is located at start of the indirect descriptor table (index 0), additional indirect descriptors are chained by next field. An indirect descriptor without next field (with flags&VRING_DESC_F_NEXT off) signals the end of the descriptor. An indirect descriptor can not refer to another indirect descriptor table (flags&VRING_DESC_F_INDIRECT must be off). A single indirect descriptor table can include both read-only and write-only descriptors; write-only flag (flags&VRING_DESC_F_WRITE) in the descriptor that refers to it is ignored. 2.1.4.4. The Virtqueue Available Ring ------------------------------------ The available ring refers to what descriptor chains we are offering the device: each entry refers to the head of a descriptor chain. The “flags” field is currently 0 or 1: 1 indicating that we do not need an interrupt when the device consumes a descriptor chain from the available ring. Alternatively, the guest can ask the device to delay interrupts until an entry with an index specified by the “used_event” field is written in the used ring (equivalently, until the idx field in the used ring will reach the value used_event + 1). The method employed by the device is controlled by the VIRTIO_RING_F_EVENT_IDX feature bit (see "2.6. Reserved Feature Bits"). This interrupt suppression is merely an optimization; it may not suppress interrupts entirely. The “idx” field indicates where we would put the next descriptor entry (modulo the queue size). This starts at 0, and increases. struct vring_avail { #define VRING_AVAIL_F_NO_INTERRUPT 1 le16 flags; le16 idx; le16 ring[ /* Queue Size */ ]; le16 used_event; /* Only if VIRTIO_RING_F_EVENT_IDX */ }; 2.1.4.5. The Virtqueue Used Ring ------------------------------- The used ring is where the device returns buffers once it is done with them. The flags field can be used by the device to hint that no notification is necessary when the guest adds to the available ring. Alternatively, the “avail_event” field can be used by the device to hint that no notification is necessary until an entry with an index specified by the “avail_event” is written in the available ring (equivalently, until the idx field in the available ring will reach the value avail_event + 1). The method employed by the device is controlled by the guest through the VIRTIO_RING_F_EVENT_IDX feature bit (see "2.6. Reserved Feature Bits").[7] Each entry in the ring is a pair: the head entry of the descriptor chain describing the buffer (this matches an entry placed in the available ring by the guest earlier), and the total of bytes written into the buffer. The latter is extremely useful for guests using untrusted buffers: if you do not know exactly how much has been written by the device, you usually have to zero the buffer to ensure no data leakage occurs. /* le32 is used here for ids for padding reasons. */ struct vring_used_elem { /* Index of start of used descriptor chain. */ le32 id; /* Total length of the descriptor chain which was used (written to) */ le32 len; }; struct vring_used { #define VRING_USED_F_NO_NOTIFY 1 le16 flags; le16 idx; struct vring_used_elem ring[ /* Queue Size */]; le16 avail_event; /* Only if VIRTIO_RING_F_EVENT_IDX */ }; 2.1.4.6. Helpers for Operating Virtqueues ---------------------------------------- The Linux Kernel Source code contains the definitions above and helper routines in a more usable form, in include/linux/virtio_ring.h. This was explicitly licensed by IBM and Red Hat under the (3-clause) BSD license so that it can be freely used by all other projects, and is reproduced (with slight variation to remove Linux assumptions) in "2.6. virtio_ring.h". 2.2. General Initialization And Device Operation =============================================== We start with an overview of device initialization, then expand on the details of the device and how each step is preformed. This section should be read along with the bus-specific section which describes how to communicate with the specific device. 2.2.1. Device Initialization --------------------------- 1. Reset the device. This is not required on initial start up. 2. The ACKNOWLEDGE status bit is set: we have noticed the device. 3. The DRIVER status bit is set: we know how to drive the device. 4. Device feature bits are read, and the the subset of feature bits understood by the OS and driver is written to the device. 5. The FEATURES_OK status bit is set. 6. The status byte is re-read to ensure the FEATURES_OK bit is still set: otherwise, the device does not support our subset of features and the device is unusable. 7. Device-specific setup, including discovery of virtqueues for the device, optional per-bus setup, reading and possibly writing the device's virtio configuration space, and population of virtqueues. 8. The DRIVER_OK status bit is set. At this point the device is "live". If any of these steps go irrecoverably wrong, the guest should set the FAILED status bit to indicate that it has given up on the device (it can reset the device later to restart if desired). The device must not consume buffers before DRIVER_OK, and the driver must not notify the device before it sets DRIVER_OK. Devices should support all valid combinations of features, but we know that implementations may well make assuptions that they will only be used by fully-optimized drivers. The resetting of the FEATURES_OK flag provides a semi-graceful failure mode for this case. 2.2.1.1. Legacy Interface: Device Initialization --------------------------- Legacy devices do not support the FEATURES_OK status bit, and thus did not have a graceful way for the device to indicate unsupported feature combinations. It also did not provide a clear mechanism to end feature negotiation, which meant that devices finalized features on first-use, and no features could be introduced which radically changed the initial operation of the device. Legacy device implementations often used the device before setting the DRIVER_OK bit. The result was the steps 5 and 6 were omitted, and steps 7 and 8 were conflated. 2.2.2. Device Operation ---------------------- There are two parts to device operation: supplying new buffers to the device, and processing used buffers from the device. As an example, the simplest virtio network device has two virtqueues: the transmit virtqueue and the receive virtqueue. The driver adds outgoing (read-only) packets to the transmit virtqueue, and then frees them after they are used. Similarly, incoming (write-only) buffers are added to the receive virtqueue, and processed after they are used. 2.2.2.1. Supplying Buffers to The Device --------------------------------------- Actual transfer of buffers from the guest OS to the device operates as follows: 1. Place the buffer(s) into free descriptor(s). (a) If there are no free descriptors, the guest may choose to notify the device even if notifications are suppressed (to reduce latency).[8] 2. Place the id of the buffer in the next ring entry of the available ring. 3. The steps (1) and (2) may be performed repeatedly if batching is possible. 4. A memory barrier should be executed to ensure the device sees the updated descriptor table and available ring before the next step. 5. The available “idx” field should be increased by the number of entries added to the available ring. 6. A memory barrier should be executed to ensure that we update the idx field before checking for notification suppression. 7. If notifications are not suppressed, the device should be notified of the new buffers. Note that the above code does not take precautions against the available ring buffer wrapping around: this is not possible since the ring buffer is the same size as the descriptor table, so step (1) will prevent such a condition. In addition, the maximum queue size is 32768 (it must be a power of 2 which fits in 16 bits), so the 16-bit “idx” value can always distinguish between a full and empty buffer. Here is a description of each stage in more detail. 2.2.2.1.1. Placing Buffers Into The Descriptor Table --------------------------------------------------- A buffer consists of zero or more read-only physically-contiguous elements followed by zero or more physically-contiguous write-only elements (it must have at least one element). This algorithm maps it into the descriptor table: for each buffer element, b: (a) Get the next free descriptor table entry, d (b) Set d.addr to the physical address of the start of b (c) Set d.len to the length of b. (d) If b is write-only, set d.flags to VRING_DESC_F_WRITE, otherwise 0. (e) If there is a buffer element after this: i. Set d.next to the index of the next free descriptor element. ii. Set the VRING_DESC_F_NEXT bit in d.flags. In practice, the d.next fields are usually used to chain free descriptors, and a separate count kept to check there are enough free descriptors before beginning the mappings. 2.2.2.1.2. Updating The Available Ring ------------------------------------- The head of the buffer we mapped is the first d in the algorithm above. A naive implementation would do the following (with the appropriate conversion to-and-from little-endian assumed): avail->ring[avail->idx % qsz] = head; However, in general we can add many descriptor chains before we update the “idx” field (at which point they become visible to the device), so we keep a counter of how many we've added: avail->ring[(avail->idx + added++) % qsz] = head; 2.2.2.1.3. Updating The Index Field ---------------------------------- Once the index field of the virtqueue is updated, the device will be able to access the descriptor chains we've created and the memory they refer to. This is why a memory barrier is generally used before the index update, to ensure it sees the most up-to-date copy. The index field always increments, and we let it wrap naturally at 65536: avail->idx += added; 2.2.2.1.4. Notifying The Device ------------------------------ The actual method of device notification is bus-specific, but generally it can be expensive. So the device can suppress such notifications if it doesn't need them. We have to be careful to expose the new index value before checking if notifications are suppressed: it's OK to notify gratuitously, but not to omit a required notification. So again, we use a memory barrier here before reading the flags or the avail_event field. If the VIRTIO_F_RING_EVENT_IDX feature is not negotiated, and if the VRING_USED_F_NOTIFY flag is not set, we go ahead and notify the device. If the VIRTIO_F_RING_EVENT_IDX feature is negotiated, we read the avail_event field in the available ring structure. If the available index crossed_the avail_event field value since the last notification, we go ahead and write to the PCI configuration space. The avail_event field wraps naturally at 65536 as well, iving the following algorithm for calculating whether a device needs notification: (u16)(new_idx - avail_event - 1) < (u16)(new_idx - old_idx) 2.2.2.2. Receiving Used Buffers From The Device ---------------------------------------------- Once the device has used a buffer (read from or written to it, or parts of both, depending on the nature of the virtqueue and the device), it sends an interrupt, following an algorithm very similar to the algorithm used for the driver to send the device a buffer: 1. Write the head descriptor number to the next field in the used ring. 2. Update the used ring index. 3. Deliver an interrupt if necessary: (a) If the VIRTIO_F_RING_EVENT_IDX feature is not negotiated: check if the VRING_AVAIL_F_NO_INTERRUPT flag is not set in avail->flags. (b) If the VIRTIO_F_RING_EVENT_IDX feature is negotiated: check whether the used index crossed the used_event field value since the last update. The used_event field wraps naturally at 65536 as well: (u16)(new_idx - used_event - 1) < (u16)(new_idx - old_idx) For each ring, guest should then disable interrupts by writing VRING_AVAIL_F_NO_INTERRUPT flag in avail structure, if required. It can then process used ring entries finally enabling interrupts by clearing the VRING_AVAIL_F_NO_INTERRUPT flag or updating the EVENT_IDX field in the available structure. The guest should then execute a memory barrier, and then recheck the ring empty condition. This is necessary to handle the case where after the last check and before enabling interrupts, an interrupt has been suppressed by the device: vring_disable_interrupts(vq); for (;;) { if (vq->last_seen_used != le16_to_cpu(vring->used.idx)) { vring_enable_interrupts(vq); mb(); if (vq->last_seen_used != le16_to_cpu(vring->used.idx)) break; } struct vring_used_elem *e = vring.used->ring[vq->last_seen_used%vsz]; process_buffer(e); vq->last_seen_used++; } 2.2.2.3. Notification of Device Configuration Changes ---------------------------------------------------- For devices where the configuration information can be changed, an interrupt is delivered when a configuration change occurs. 2.3. Virtio Transport Options ============================ Virtio can use various different busses, thus the standard is split into virtio general and bus-specific sections. 2.3.1. Virtio Over PCI Bus ------------------------- Virtio devices are commonly implemented as PCI devices. 2.3.1.1. PCI Device Discovery ---------------------------- Any PCI device with Vendor ID 0x1AF4, and Device ID 0x1000 through 0x103F inclusive is a virtio device[3]. The Subsystem Device ID indicates which virtio device is supported by the device. The Subsystem Vendor ID should reflect the PCI Vendor ID of the environment (it's currently only used for informational purposes by the guest). 2.3.1.1.1 Legacy Interfaces: A Note on PCI Device Discovery ------------------------- Transitional devices must also have a Revision ID of 0 to match this specification. 2.3.1.2. PCI Device Layout ------------------------- To configure the device, use I/O and/or memory regions and/or PCI configuration space of the PCI device. These contain the virtio header registers, the notification register, the ISR status register and device specific registers, as specified by Virtio + Structure PCI Capabilities There may be different widths of accesses to the I/O region; the “natural” access method for each field must be used (i.e. 32-bit accesses for 32-bit fields, etc). PCI Device Configuration Layout includes the common configuration, ISR, notification and device specific configuration structures. Unless explicitly specified otherwise, all multi-byte fields are little-endian. 2.3.1.2.1. Common configuration structure layout ------------------------- Common configuration structure layout is documented below: struct virtio_pci_common_cfg { /* About the whole device. */ le32 device_feature_select; /* read-write */ le32 device_feature; /* read-only */ le32 guest_feature_select; /* read-write */ le32 guest_feature; /* read-write */ le16 msix_config; /* read-write */ le16 num_queues; /* read-only */ u8 device_status; /* read-write */ u8 config_generation; /* read-only */ /* About a specific virtqueue. */ le16 queue_select; /* read-write */ le16 queue_size; /* read-write, power of 2, or 0. */ le16 queue_msix_vector; /* read-write */ le16 queue_enable; /* read-write */ le16 queue_notify_off; /* read-only */ le64 queue_desc; /* read-write */ le64 queue_avail; /* read-write */ le64 queue_used; /* read-write */ }; device_feature_select Selects which Feature Bits does device_feature field refer to. Value 0x0 selects Feature Bits 0 to 31 Value 0x1 selects Feature Bits 32 to 63 All other values cause reads from device_feature to return 0. device_feature Used by Device to report Feature Bits to Driver. Device Feature Bits selected by device_feature_select. guest_feature_select Selects which Feature Bits does guest_feature field refer to. Value 0x0 selects Feature Bits 0 to 31 Value 0x1 selects Feature Bits 32 to 63 When set to any other value, reads from guest_feature return 0, writing 0 into guest_feature has no effect, and writing any other value into guest_feature is an error. guest_feature Used by Driver to acknowledge Feature Bits to Device. Guest Feature Bits selected by guest_feature_select. msix_config Configuration Vector for MSI-X. num_queues Specifies the maximum number of virtqueues supported by device. device_status Device Status field. Writing 0 into this field resets the device. config_generation Configuration atomicity value. Changes every time the configuration noticeably changes. This means the device may only change the value after a configuration read operation, but it must change if there is any risk of a device seeing an inconsistent configuration state. queue_select Queue Select. Selects which virtqueue do other fields refer to. queue_size Queue Size. On reset, specifies the maximum queue size supported by the hypervisor. This can be modified by driver to reduce memory requirements. Set to 0 if this virtqueue is unused. queue_msix_vector Queue Vector for MSI-X. queue_enable Used to selectively prevent host from executing requests from this virtqueue. 1 - enabled; 0 - disabled queue_notify_off Used to calculate the offset from start of Notification structure at which this virtqueue is located. Note: this is *not* an offset in bytes. See notify_off_multiplier below. queue_desc Physical address of Descriptor Table. queue_avail Physical address of Available Ring. queue_used Physical address of Used Ring. 2.3.1.2.2. ISR status structure layout ------------------------- ISR status structure includes a single 8-bit ISR status field. 2.3.1.2.3. Notification structure layout ------------------------- Notification structure is always a multiple of 2 bytes in size. It includes 2-byte Queue Notify fields for each virtqueue of the device. Note that multiple virtqueues can use the same Queue Notify field, if necessary. 2.3.1.2.4. Device specific structure ------------------------- Device specific structure is optional. 2.3.1.2.5. Legacy Interfaces: A Note on PCI Device Layout ------------------------- Transitional devices should present part of configuration registers in a legacy configuration structure in BAR0 in the first I/O region of the PCI device, as documented below. There may be different widths of accesses to the I/O region; the “natural” access method for each field in the virtio header must be used (i.e. 32-bit accesses for 32-bit fields, etc), but when accessed through the legacy interface the device-specific region can be accessed using any width accesses, and should obtain the same results. Note that this is possible because while the virtio header is PCI (i.e. little) endian, when using the legacy interface the device-specific region is encoded in the native endian of the guest (where such distinction is applicable). When used through the legacy interface, the virtio header looks as follows: +------------++---------------------+---------------------+----------+--------+---------+---------+---------+--------+ | Bits || 32 | 32 | 32 | 16 | 16 | 16 | 8 | 8 | +------------++---------------------+---------------------+----------+--------+---------+---------+---------+--------+ | Read/Write || R | R+W | R+W | R | R+W | R+W | R+W | R | +------------++---------------------+---------------------+----------+--------+---------+---------+---------+--------+ | Purpose || Device | Guest | Queue | Queue | Queue | Queue | Device | ISR | | || Features bits 0:31 | Features bits 0:31 | Address | Size | Select | Notify | Status | Status | +------------++---------------------+---------------------+----------+--------+---------+---------+---------+--------+ If MSI-X is enabled for the device, two additional fields immediately follow this header: +------------++----------------+--------+ | Bits || 16 | 16 | +----------------+--------+ +------------++----------------+--------+ | Read/Write || R+W | R+W | +------------++----------------+--------+ | Purpose || Configuration | Queue | | (MSI-X) || Vector | Vector | +------------++----------------+--------+ Note: When MSI-X capability is enabled, device specific configuration starts at byte offset 24 in virtio header structure. When MSI-X capability is not enabled, device specific configuration starts at byte offset 20 in virtio header. ie. once you enable MSI-X on the device, the other fields move. If you turn it off again, they move back! Immediately following these general headers, there may be device-specific headers: +------------++--------------------+ | Bits || Device Specific | +--------------------+ +------------++--------------------+ | Read/Write || Device Specific | +------------++--------------------+ | Purpose || Device Specific... | | || | +------------++--------------------+ Note that only Feature Bits 0 to 31 are accessible through the Legacy Interface. When used through the Legacy Interface, Transitional Devices must assume that Feature Bits 32 to 63 are not acknowledged by Driver. As legacy devices had no configuration generation field, see "2.1.3.1. Legacy Interface: Configuration Space" for workarounds. 2.3.1.3. PCI-specific Initialization And Device Operation -------------------------------------------------------- 2.3.1.3.1. Device Initialization ------------------------------- This documents PCI-specific steps executed during Device Initialization. As the first step, driver must detect device configuration layout to locate configuration fields in memory,I/O or configuration space of the device. 100.100.1.3.1.1. Virtio Device Configuration Layout Detection ------------------------------- As a prerequisite to device initialization, driver executes a PCI capability list scan, detecting virtio configuration layout using Virtio Structure PCI capabilities. Virtio Device Configuration Layout includes virtio configuration header, Notification and ISR Status and device configuration structures. Each structure can be mapped by a Base Address register (BAR) belonging to the function, located beginning at 10h in Configuration Space, or accessed though PCI configuration space. Actual location of each structure is specified using vendor-specific PCI capability located on capability list in PCI configuration space of the device. This virtio structure capability uses little-endian format; all bits are read-only: struct virtio_pci_cap { u8 cap_vndr; /* Generic PCI field: PCI_CAP_ID_VNDR */ u8 cap_next; /* Generic PCI field: next ptr. */ u8 cap_len; /* Generic PCI field: capability length */ u8 cfg_type; /* Identifies the structure. */ u8 bar; /* Where to find it. */ u8 padding[3]; /* Pad to full dword. */ le32 offset; /* Offset within bar. */ le32 length; /* Length of the structure, in bytes. */ }; This structure can optionally followed by extra data, depending on other fields, as documented below. The fields are interpreted as follows: cap_vndr 0x09; Identifies a vendor-specific capability. cap_next Link to next capability in the capability list in the configuration space. cap_len Length of the capability structure, including the whole of struct virtio_pci_cap, and extra data if any. This length might include padding, or fields unused by the driver. cfg_type identifies the structure, according to the following table. /* Common configuration */ #define VIRTIO_PCI_CAP_COMMON_CFG 1 /* Notifications */ #define VIRTIO_PCI_CAP_NOTIFY_CFG 2 /* ISR Status */ #define VIRTIO_PCI_CAP_ISR_CFG 3 /* Device specific configuration */ #define VIRTIO_PCI_CAP_DEVICE_CFG 4 Any other value - reserved for future use. Drivers must ignore any vendor-specific capability structure which has a reserved cfg_type value. More than one capability can identify the same structure - this makes it possible for the device to expose multiple interfaces to drivers. The order of the capabilities in the capability list specifies the order of preference suggested by the device; drivers should use the first interface that they can support. For example, on some hypervisors, notifications using IO accesses are faster than memory accesses. In this case, hypervisor can expose two capabilities with cfg_type set to VIRTIO_PCI_CAP_NOTIFY_CFG: the first one addressing an I/O BAR, the second one addressing a memory BAR. Driver will use the I/O BAR if I/O resources are available, and fall back on memory BAR when I/O resources are unavailable. bar values 0x0 to 0x5 specify a Base Address register (BAR) belonging to the function located beginning at 10h in Configuration Space and used to map the structure into Memory or I/O Space. The BAR is permitted to be either 32-bit or 64-bit, it can map Memory Space or I/O Space. Any other value - reserved for future use. Drivers must ignore any vendor-specific capability structure which has a reserved bar value. offset indicates where the structure begins relative to the base address associated with the BAR. length indicates the length of the structure. This size might include padding, or fields unused by the driver. Drivers are also recommended to only map part of configuration structure large enough for device operation. For example, a future device might present a large structure size of several MBytes. As current devices never utilize structures larger than 4KBytes in size, driver can limit the mapped structure size to e.g. 4KBytes to allow forward compatibility with such devices without loss of functionality and without wasting resources. If cfg_type is VIRTIO_PCI_CAP_NOTIFY_CFG this structure is immediately followed by additional fields: struct virtio_pci_notify_cap { struct virtio_pci_cap cap; le32 notify_off_multiplier; /* Multiplier for queue_notify_off. */ }; notify_off_multiplier Virtqueue offset multiplier, in bytes. Must be even and either a power of two, or 0. Value 0x1 is reserved. For a given virtqueue, the address to use for notifications is calculated as follows: queue_notify_off * notify_off_multiplier + offset If notify_off_multiplier is 0, all virtqueues use the same address in the Notifications structure! 100.100.1.3.1.1. Legacy Interface: A Note on Device Layout Detection ------------------------------- Legacy drivers skipped Device Layout Detection step, assuming legacy configuration space in BAR0 in I/O space unconditionally. Legacy devices did not have the Virtio PCI Capability in their capability list. Therefore: Transitional devices should expose the Legacy Interface in I/O space in BAR0. Transitional drivers should look for the Virtio PCI Capabilities on the capability list. If there are not present, driver should assume a legacy device. 2.3.1.3.1.1. Queue Vector Configuration -------------------------------------- When MSI-X capability is present and enabled in the device (through standard PCI configuration space) Configuration/Queue MSI-X Vector registers are used to map configuration change and queue interrupts to MSI-X vectors. In this case, the ISR Status is unused. Writing a valid MSI-X Table entry number, 0 to 0x7FF, to one of Configuration/Queue Vector registers, maps interrupts triggered by the configuration change/selected queue events respectively to the corresponding MSI-X vector. To disable interrupts for a specific event type, unmap it by writing a special NO_VECTOR value: /* Vector value used to disable MSI for queue */ #define VIRTIO_MSI_NO_VECTOR 0xffff Reading these registers returns vector mapped to a given event, or NO_VECTOR if unmapped. All queue and configuration change events are unmapped by default. Note that mapping an event to vector might require allocating internal device resources, and might fail. Devices report such failures by returning the NO_VECTOR value when the relevant Vector field is read. After mapping an event to vector, the driver must verify success by reading the Vector field value: on success, the previously written value is returned, and on failure, NO_VECTOR is returned. If a mapping failure is detected, the driver can retry mapping with fewervectors, or disable MSI-X. 2.3.1.3.1.2. Virtqueue Configuration ----------------------------------- As a device can have zero or more virtqueues for bulk data transport (for example, the simplest network device has two), the driver needs to configure them as part of the device-specific configuration. This is done as follows, for each virtqueue a device has: 1. Write the virtqueue index (first queue is 0) to the Queue Select field. 2. Read the virtqueue size from the Queue Size field, which is always a power of 2. This controls how big the virtqueue is (see "2.1.4. Virtqueues"). If this field is 0, the virtqueue does not exist. 3. Optionally, select a smaller virtqueue size and write it in the Queue Size field. 4. Allocate and zero Descriptor Table, Available and Used rings for the virtqueue in contiguous physical memory. 5. Optionally, if MSI-X capability is present and enabled on the device, select a vector to use to request interrupts triggered by virtqueue events. Write the MSI-X Table entry number corresponding to this vector in Queue Vector field. Read the Queue Vector field: on success, previously written value is returned; on failure, NO_VECTOR value is returned. 100.100.1.3.1.4.1. Legacy Interface: A Note on Virtqueue Configuration ----------------------------------- When using the legacy interface, the page size for a virtqueue on a PCI virtio device is defined as 4096 bytes. Driver writes the physical address, divided by 4096 to the Queue Address field [6]. 2.3.1.3.2. Notifying The Device ------------------------------ Device notification occurs by writing the 16-bit virtqueue index of this virtqueue to the Queue Notify field. 2.3.1.3.3. Virtqueue Interrupts From The Device ---------------------------------------------- If an interrupt is necessary: (a) If MSI-X capability is disabled: i. Set the lower bit of the ISR Status field for the device. ii. Send the appropriate PCI interrupt for the device. (b) If MSI-X capability is enabled: i. Request the appropriate MSI-X interrupt message for the device, Queue Vector field sets the MSI-X Table entry number. ii. If Queue Vector field value is NO_VECTOR, no interrupt message is requested for this event. The guest interrupt handler should: 1. If MSI-X capability is disabled: read the ISR Status field, which will reset it to zero. If the lower bit is zero, the interrupt was not for this device. Otherwise, the guest driver should look through the used rings of each virtqueue for the device, to see if any progress has been made by the device which requires servicing. 2. If MSI-X capability is enabled: look through the used rings of each virtqueue mapped to the specific MSI-X vector for the device, to see if any progress has been made by the device which requires servicing. 2.3.1.3.4. Notification of Device Configuration Changes ------------------------------------------------------ Some virtio PCI devices can change the device configuration state, as reflected in the virtio header in the PCI configuration space. In this case: 1. If MSI-X capability is disabled: an interrupt is delivered and the second highest bit is set in the ISR Status field to indicate that the driver should re-examine the configuration space. Note that a single interrupt can indicate both that one or more virtqueue has been used and that the configuration space has changed: even if the config bit is set, virtqueues must be scanned. 2. If MSI-X capability is enabled: an interrupt message is requested. The Configuration Vector field sets the MSI-X Table entry number to use. If Configuration Vector field value is NO_VECTOR, no interrupt message is requested for this event. 2.3.2. Virtio Over MMIO ----------------------- Virtual environments without PCI support (a common situation in embedded devices models) might use simple memory mapped device ("virtio-mmio") instead of the PCI device. The memory mapped virtio device behaviour is based on the PCI device specification. Therefore most of operations like device initialization, queues configuration and buffer transfers are nearly identical. Existing differences are described in the following sections. 2.3.2.1. MMIO Device Discovery ------------------------------ Unlike PCI, MMIO provides no generic device discovery. For systems using Flattened Device Trees the suggested format is: virtio_block@1e000 { compatible = "virtio,mmio"; reg = <0x1e000 0x100>; interrupts = <42>; } 2.3.2.2. MMIO Device Layout --------------------------- MMIO virtio devices provides a set of memory mapped control registers, all 32 bits wide, followed by device-specific configuration space. The following list presents their layout: * Offset from the device base address | Direction | Name Description * 0x000 | R | MagicValue Magic value. Must be 0x74726976 (a Little Endian equivalent of a "virt" string). * 0x004 | R | Version Device version number. Devices compliant with this specification must return value 0x2. * 0x008 | R | DeviceID Virtio Subsystem Device ID. See "2.4. Device Types" for possible values. Value zero (0x0) is invalid and devices returning this ID must be ignored by the guest. * 0x00c | R | VendorID Virtio Subsystem Vendor ID. * 0x010 | R | HostFeatures Flags representing features the device supports. Reading from this register returns 32 consecutive flag bits, first bit depending on the last value written to the HostFeaturesSel register. Access to this register returns bits HostFeaturesSel*32 to (HostFeaturesSel*32)+31, eg. feature bits 0 to 31 if HostFeaturesSel is set to 0 and features bits 32 to 63 if HostFeaturesSel is set to 1. Also see "2.1.2. Feature Bits". * 0x014 | W | HostFeaturesSel Device (Host) features word selection. Writing to this register selects a set of 32 device feature bits accessible by reading from the HostFeatures register. Device driver must write a value to the HostFeaturesSel register before reading from the HostFeatures register. * 0x020 | W | GuestFeatures Flags representing device features understood and activated by the driver. Writing to this register sets 32 consecutive flag bits, first bit depending on the last value written to the GuestFeaturesSel register. Access to this register sets bits GuestFeaturesSel*32 to (GuestFeaturesSel*32)+31, eg. feature bits 0 to 31 if GuestFeaturesSel is set to 0 and features bits 32 to 63 if GuestFeaturesSel is set to 1. Also see "2.1.2. Feature Bits". * 0x024 | W | GuestFeaturesSel Activated (Guest) features word selection. Writing to this register selects a set of 32 activated feature bits accessible by writing to the GuestFeatures register. Device driver must write a value to the GuestFeaturesSel register before writing to the GuestFeatures register. * 0x030 | W | QueueSel Virtual queue index (first queue is 0). Writing to this register selects the virtual queue that the following operations on the QueueNumMax, QueueNum, QueueReady, QueueDescLow, QueueDescHigh, QueueAvailLow, QueueAvailHigh, QueueUsedLow and QueueUsedHigh registers apply to. * 0x034 | R | QueueNumMax Maximum virtual queue size. Reading from the register returns the maximum size of the queue the Host is ready to process or zero (0x0) if the queue is not available. This applies to the queue selected by writing to QueueSel and is allowed only when QueueReady is set to zero (0x0), so when the queue is not in use. * 0x038 | W | QueueNum Virtual queue size. Queue size is the number of elements in the queue, therefore size of the Descriptor Table and both Available and Used rings. Writing to this register notifies the Host what size of the queue the Guest will use. This applies to the queue selected by writing to QueueSel and is allowed only when QueueReady is set to zero (0x0), so when the queue is not in use. * 0x03c | RW | QueueReady Virtual queue ready bit. Writing one (0x1) to this register notifies the Host that the virtual queue is ready to be used. Reading from this register returns the last value written to it. Both read and write accesses apply to the queue selected by writing to QueueSel. When the Guest wants to stop using the queue it must write zero (0x0) to this register and read the value back to ensure synchronisation. * 0x050 | W | QueueNotify Queue notifier. Writing a queue index to this register notifies the Host that there are new buffers to process in the queue. * 0x60 | R | InterruptStatus Interrupt status. Reading from this register returns a bit mask of interrupts asserted by the device. An interrupt is asserted if the corresponding bit is set, ie. equals one (1). – Bit 0 | Used Ring Update This interrupt is asserted when the Host has updated the Used Ring in at least one of the active virtual queues. – Bit 1 | Configuration change This interrupt is asserted when configuration of the device has changed. * 0x064 | W | InterruptACK Interrupt acknowledge. Writing to this register notifies the Host that the Guest finished handling interrupts. Set bits in the value clear the corresponding bits of the InterruptStatus register. * 0x070 | RW | Status Device status. Reading from this register returns the current device status flags. Writing non-zero values to this register sets the status flags, indicating the Guest progress. Writing zero (0x0) to this register triggers a device reset. Also see "2.2.1. Device Initialization". * 0x080 | W | QueueDescLow 0x084 | W | QueueDescHigh Virtual queue's Descriptor Table 64 bit long physical address. Writing to these two registers (lower 32 bits of the address to QueueDescLow, higher 32 bits to QueueDescHigh) notifies the host about location of the Descriptor Table of the queue selected by writing to the QueueSel register. It is allowed only when QueueReady is set to zero (0x0), so when the queue is not in use. * 0x090 | W | QueueAvailLow 0x094 | W | QueueAvailHigh Virtual queue's Available Ring 64 bit long physical address. Writing to these two registers (lower 32 bits of the address to QueueAvailLow, higher 32 bits to QueueAvailHigh) notifies the host about location of the Available Ring of the queue selected by writing to the QueueSel register. It is allowed only when QueueReady is set to zero (0x0), so when the queue is not in use. * 0x0a0 | W | QueueUsedLow 0x0a4 | W | QueueUsedHigh Virtual queue's Used Ring 64 bit long physical address. Writing to these two registers (lower 32 bits of the address to QueueUsedLow, higher 32 bits to QueueUsedHigh) notifies the host about location of the Used Ring of the queue selected by writing to the QueueSel register. It is allowed only when QueueReady is set to zero (0x0), so when the queue is not in use. * 0x0fc | R | ConfigGeneration Configuration atomicity value. Changes every time the configuration noticeably changes. This means the device may only change the value after a configuration read operation, but it must change if there is any risk of a device seeing an inconsistent configuration state. * 0x100+ | RW | Config Device-specific configuration space starts at an offset 0x100 and is accessed with byte alignment. Its meaning and size depends on the device and the driver. All register values are organized as Little Endian. Accessing memory locations not explicitly described above (or - in case of the configuration space - described in the device specification), writing to the registers described as "R" and reading from registers described as "W" is not permitted and can cause undefined behavior. 2.3.2.3. MMIO-specific Initialization And Device Operation ---------------------------------------------------------- 2.3.2.3.1. Device Initialization -------------------------------- The guest must start the device initialization by reading and checking values from the MagicValue and the Version registers. If both values are valid, it must read the DeviceID register and if its value is zero (0x0) must abort initialization and must not access any other register. 2.3.2.3.2. Virtqueue Configuration ---------------------------------- 1. Select the queue writing its index (first queue is 0) to the QueueSel register. 2. Check if the queue is not already in use: read the QueueReady register, returned value should be zero (0x0). 3. Read maximum queue size (number of elements) from the QueueNumMax register. If the returned value is zero (0x0) the queue is not available. 4. Allocate and zero the queue pages, making sure the memory is physically contiguous. It is recommended to align the Used Ring to an optimal boundary (usually page size). Size of the allocated queue may be smaller than or equal to the maximum size returned by the Host. 5. Notify the Host about the queue size by writing the size to the QueueNum register. 6. Write physical addresses of the queue's Descriptor Table, Available Ring and Used Ring to (respectively) the QueueDescLow/ QueueDescHigh, QueueAvailLow/QueueAvailHigh and QueueUsedLow/ QueueUsedHigh register pairs. 7. Write 0x1 to the QueueReady register. 2.3.2.3.3. Notifying The Device ------------------------------- The device is notified about new buffers available in a queue by writing the queue index to the QueueNum register. 2.3.2.3.4. Notifications From The Device ---------------------------------------- The memory mapped virtio device is using single, dedicated interrupt signal, which is raised when at least one of the interrupts described in the InterruptStatus register description is asserted. After receiving an interrupt, the driver must read the InterruptStatus register to check what caused the interrupt (see the register description). After the interrupt is handled, the driver must acknowledge it by writing a bit mask corresponding to the serviced interrupt to the InterruptACK register. As documented in the InterruptStatus register description, the device may notify the driver about a new used buffer being available in the queue or about a change in the device configuration. 2.3.2.4. Legacy interface ------------------------- The legacy MMIO transport used page-based addressing, resulting in a slightly different control register layout, the device initialization and the virtual queue configuration procedure. The following list presents control registers layout, omitting descriptions of registers which did not change their function nor behaviour: * Offset from the device base address | Direction | Name Description * 0x000 | R | MagicValue * 0x004 | R | Version Device version number. Legacy devices must return value 0x1. * 0x008 | R | DeviceID * 0x00c | R | VendorID * 0x010 | R | HostFeatures * 0x014 | W | HostFeaturesSel * 0x020 | W | GuestFeatures * 0x024 | W | GuestFeaturesSel * 0x028 | W | GuestPageSize Guest page size. Device driver must write the guest page size in bytes to the register during initialization, before any queues are used. This value must be a power of 2 and is used by the Host to calculate the Guest address of the first queue page (see QueuePFN). * 0x030 | W | QueueSel Virtual queue index (first queue is 0). Writing to this register selects the virtual queue that the following operations on the QueueNumMAx, QueueNum, QueueAlign and QueuePFN registers apply to. * 0x034 | R | QueueNumMax Maximum virtual queue size. Reading from the register returns the maximum size of the queue the Host is ready to process or zero (0x0) if the queue is not available. This applies to the queue selected by writing to the QueueSel and is allowed only when the QueuePFN is set to zero (0x0), so when the queue is not actively used. * 0x038 | W | QueueNum Virtual queue size. Queue size is the number of elements in the queue, therefore size of the descriptor table and both available and used rings. Writing to this register notifies the Host what size of the queue the Guest will use. This applies to the queue selected by writing to the QueueSel register. * 0x03c | W | QueueAlign Used Ring alignment in the virtual queue. Writing to this register notifies the Host about alignment boundary of the Used Ring in bytes. This value must be a power of 2 and applies to the queue selected by writing to the QueueSel register. * 0x040 | RW | QueuePFN Guest physical page number of the virtual queue. Writing to this register notifies the host about location of the virtual queue in the Guest's physical address space. This value is the index number of a page starting with the queue Descriptor Table. Value zero (0x0) means physical address zero (0x00000000) and is illegal. When the Guest stops using the queue it must write zero (0x0) to this register. Reading from this register returns the currently used page number of the queue, therefore a value other than zero (0x0) means that the queue is in use. Both read and write accesses apply to the queue selected by writing to the QueueSel register. * 0x050 | W | QueueNotify * 0x060 | R | InterruptStatus * 0x064 | W | InterruptACK * 0x070 | RW | Status * 0x100+ | RW | Config The virtual queue page size is defined by writing to the GuestPageSize register, as written by the guest. This must be done before the virtual queues are configured. The virtual queue layout follows p. 2.1.4.1. "Legacy Interfaces: A Note on Virtqueue Layout", with the alignment defined in the QueueAlign register. The virtual queue is configured as follows: 1. Select the queue writing its index (first queue is 0) to the QueueSel register. 2. Check if the queue is not already in use: read the QueuePFN register, returned value should be zero (0x0). 3. Read maximum queue size (number of elements) from the QueueNumMax register. If the returned value is zero (0x0) the queue is not available. 4. Allocate and zero the queue pages in contiguous virtual memory, aligning the Used Ring to an optimal boundary (usually page size). Size of the allocated queue may be smaller than or equal to the maximum size returned by the Host. 5. Notify the Host about the queue size by writing the size to the QueueNum register. 6. Notify the Host about the used alignment by writing its value in bytes to the QueueAlign register. 7. Write the physical number of the first page of the queue to the QueuePFN register. Notification mechanisms did not change. 2.3.3. Virtio over channel I/O ------------------------------ S/390 based virtual machines support neither PCI nor MMIO, so a different transport is needed there. virtio-ccw uses the standard channel I/O based mechanism used for the majority of devices on S/390. A virtual channel device with a special control unit type acts as proxy to the virtio device (similar to the way virtio-pci uses a PCI device) and configuration and operation of the virtio device is accomplished (mostly) via channel commands. This means virtio devices are discoverable via standard operating system algorithms, and adding virtio support is mainly a question of supporting a new control unit type. As the S/390 is a big endian machine, the data structures transmitted via channel commands are big-endian: this is made clear by use of the types be16, be32 and be64. 2.3.3.1. Basic Concepts ----------------------- As a proxy device, virtio-ccw uses a channel-attached I/O control unit with a special control unit type (0x3832) and a control unit model corresponding to the attached virtio device's subsystem device ID, accessed via a virtual I/O subchannel and a virtual channel path of type 0x32. This proxy device is discoverable via normal channel subsystem device discovery (usually a STORE SUBCHANNEL loop) and answers to the basic channel commands, most importantly SENSE ID. For a virtio-ccw proxy device, SENSE ID will return the following information: ------------------------------------------------------ | Bytes | Contents | |-------|--------------------------------------------| | 0 | reserved | 0xff | |-------|-----------------------|--------------------| | 1-2 | control unit type | 0x3832 | |-------|-----------------------|--------------------| | 3 | control unit model | | |-------|-----------------------|--------------------| | 4-5 | device type | zeroes (unset) | |-------|-----------------------|--------------------| | 6 | device model | zeroes (unset) | |-------|-----------------------|--------------------| | 7-255 | extended SenseId data | zeroes (unset) | ------------------------------------------------------ A driver for virtio-ccw devices MUST check for a control unit type of 0x3832 and MUST ignore the device type and model. In addition to the basic channel commands, virtio-ccw defines a set of channel commands related to configuration and operation of virtio: #define CCW_CMD_SET_VQ 0x13 #define CCW_CMD_VDEV_RESET 0x33 #define CCW_CMD_SET_IND 0x43 #define CCW_CMD_SET_CONF_IND 0x53 #define CCW_CMD_SET_IND_ADAPTER 0x73 #define CCW_CMD_READ_FEAT 0x12 #define CCW_CMD_WRITE_FEAT 0x11 #define CCW_CMD_READ_CONF 0x22 #define CCW_CMD_WRITE_CONF 0x21 #define CCW_CMD_WRITE_STATUS 0x31 #define CCW_CMD_READ_VQ_CONF 0x32 The virtio-ccw device acts like a normal channel device, as specified in [S390 PoP] and [S390 Common I/O]. In particular: - A device must post a unit check with command reject for any command it does not support. - If a driver did not suppress length checks for a channel command, the device must present a subchannel status as detailed in the architecture when the actual length did not match the expected length. - If a driver did suppress length checks for a channel command, the device must present a check condition if the transmitted data does not contain enough data to process the command. If the driver submitted a buffer that was too long, the device should accept the command. The driver should attempt to provide the correct length even if it suppresses length checks. 2.3.3.2. Device Initialization ------------------------------ virtio-ccw uses several channel commands to set up a device. 2.3.3.2.1. Configuring a Virtqueue ---------------------------------- CCW_CMD_READ_VQ_CONF is issued by the guest to obtain information about a queue. It uses the following structure for communicating: struct vq_config_block { be16 index; be16 max_num; } __attribute__ ((packed)); The requested number of buffers for queue index is returned in max_num. Afterwards, CCW_CMD_SET_VQ is issued by the guest to inform the host about the location used for its queue. The transmitted structure is struct vq_info_block { be64 desc; be32 res0; be16 index; be16 num; be64 avail; be64 used; } __attribute__ ((packed)); desc, avail and used contain the guest addresses for the descriptor table, available ring and used ring for queue index, respectively. The actual virtqueue size (number of allocated buffers) is transmitted in num. res0 is reserved and must be ignored by the device. 2.3.3.2.2.1. Legacy Interface: A Note on Configuring a Virtqueue ---------------------------------------------------------------- For a legacy driver or for a driver that selected revision 0, CCW_CMD_SET_VQ uses the following communication block: struct vq_info_block_legacy { be64 queue; be32 align; be16 index; be16 num; } __attribute__ ((packed)); queue contains the guest address for queue index, num the number of buffers and align the alignment. 100.3.3.2.1. Virtqueue Layout ------------------------------ The virtqueue is physically contiguous, with padded added to make the used ring meet the align value: +-------------------+-----------------------------------+-----------+ | Descriptor Table | Available Ring (padding) | Used Ring | +-------------------+-----------------------------------+-----------+ The calculation for total size is as follows: #define ALIGN(x) (((x) + align) & ~align) static inline unsigned vring_size(unsigned int num) { return ALIGN(sizeof(struct vring_desc)*num + sizeof(u16)*(3 + num)) + ALIGN(sizeof(u16)*3 + sizeof(struct vring_used_elem)*num); } 2.3.3.2.2. Communicating Status Information ------------------------------------------- The guest can change the status of a device via the CCW_CMD_WRITE_STATUS command, which transmits an 8 bit status value. 2.3.3.2.3. Handling Device Features ----------------------------------- Feature bits are arranged in an array of 32 bit values, making for a total of 8192 feature bits. Feature bits are in little-endian byte order. The CCW commands dealing with features use the following communication block: struct virtio_feature_desc { be32 features; u8 index; } __attribute__ ((packed)); features are the 32 bits of features currently accessed, while index describes which of the feature bit values is to be accessed. The guest may obtain the host's device feature set via the CCW_CMD_READ_FEAT command. The host stores the features at index to features. For communicating its device features to the host, the guest may use the CCW_CMD_WRITE_FEAT command, denoting a features/index combination. 2.3.3.2.4. Device Configuration ------------------------------- The device's configuration space is located in host memory. It is the same size as the standard PCI configuration space. To obtain information from the configuration space, the guest may use CCW_CMD_READ_CONF, specifying the guest memory for the host to write to. For changing configuration information, the guest may use CCW_CMD_WRITE_CONF, specifying the guest memory for the host to read from. In both cases, the complete configuration space is transmitted. This allows the guest to compare the new configuration space with the old version, and keep a generation count internally whenever it changes. 2.3.3.2.5. Setting Up Indicators -------------------------------- In order to set up the indicator bits for host->guest notification, the driver uses different channel commands depending on whether it wishes to use traditional I/O interrupts tied to a subchannel or adapter I/O interrupts for virtqueue notifications. For any given device, the two mechanisms are mutually exclusive. For the configuration change indicators, only a mechanism using traditional I/O interrupts is provided, regardless of whether traditional or adapter I/O interrupts are used for virtqueue notifications. 2.3.3.2.5.1. Setting Up Classic Queue Indicators ------------------------------------------------ Indicators for notification via classic I/O interrupts are contained in a 64 bit value per virtio-ccw proxy device. To communicate the location of the indicator bits for host->guest notification, the guest uses the CCW_CMD_SET_IND command, pointing to a location containing the guest address of the indicators in a 64 bit value. If the driver has already set up two-staged queue indicators via the CCW_CMD_SET_IND_ADAPTER command, the device MUST post a unit check with command reject to any subsequent CCW_CMD_SET_IND command. 2.3.3.2.5.2. Setting Up Configuration Change Indicators ------------------------------------------------------- Indicators for configuration change host->guest notification are contained in a 64 bit value per virtio-ccw proxy device. To communicate the location of the indicator bits used in the configuration change host->guest notification, the driver issues the CCW_CMD_SET_CONF_IND command, pointing to a location containing the guest address of the indicators in a 64 bit value. 2.3.3.2.5.3. Setting Up Two-Stage Queue Indicators -------------------------------------------------- Indicators for notification via adapter I/O interrupts consist of two stages: - a summary indicator byte covering the virtqueues for one or more virtio-ccw proxy devices - a set of contigous indicator bits for the virtqueues for a virtio-ccw proxy device To communicate the location of the summary and queue indicator bits, the driver uses the CCW_CMD_SET_IND_ADAPTER command with the following payload: struct virtio_thinint_area { be64 summary_indicator; be64 indicator; be64 bit_nr; u8 isc; } __attribute__ ((packed)); summary_indicator contains the guest address of the 8 bit summary indicator. indicator contains the guest address of an area wherin the indicators for the devices are contained, starting at bit_nr, one bit per virtqueue of the device. Bit numbers start at the left. isc contains the I/O interruption subclass to be used for the adapter I/O interrupt. It may be different from the isc used by the proxy virtio-ccw device's subchannel. If the driver has already set up classic queue indicators via the CCW_CMD_SET_IND command, the device MUST post a unit check with command reject to any subsequent CCW_CMD_SET_IND_ADAPTER command. 2.3.3.2.5.4. Legacy Interfaces: A Note on Setting Up Indicators --------------------------------------------------------------- Legacy devices will only support classic queue indicators; they will reject CCW_CMD_SET_IND_ADAPTER as they don't know that command. 2.3.3.3. Device Operation ------------------------- 2.3.3.3.1. Host->Guest Notification ----------------------------------- There are two modes of operation regarding host->guest notifcation, classic I/O interrupts and adapter I/O interrupts. The mode to be used is determined by the driver by using CCW_CMD_SET_IND respectively CCW_CMD_SET_IND_ADAPTER to set up queue indicators. For configuration changes, the driver will always use classic I/O interrupts. 2.3.3.3.1.1. Notification via Classic I/O Interrupts ---------------------------------------------------- If the driver used the CCW_CMD_SET_IND command to set up queue indicators, the device will use classic I/O interrupts for host->guest notification about virtqueue activity. For notifying the guest of virtqueue buffers, the host sets the corresponding bit in the guest-provided indicators. If an interrupt is not already pending for the subchannel, the host generates an unsolicited I/O interrupt. If the host wants to notify the guest about configuration changes, it sets bit 0 in the configuration indicators and generates an unsolicited I/O interrupt, if needed. This also applies if adapter I/O interrupts are used for queue notifications. 2.3.3.3.1.2. Notification via Adapter I/O Interrupts ---------------------------------------------------- If the driver used the CCW_CMD_SET_IND_ADAPTER command to set up queue indicators, the device will use adapter I/O interrupts for host->guest notification about virtqueue activity. For notifying the guest of virtqueue buffers, the host sets the bit in the guest-provided indicator area at the corresponding offset. The guest-provided summary indicator is also set. An adapter I/O interrupt for the corresponding interruption subclass is generated. The device SHOULD only generate an adapter I/O interrupt if the summary indicator had not been set prior to notification. The driver MUST clear the summary indicator after receiving an adapter I/O interrupt before it processes the queue indicators. 2.3.3.3.1.3. Legacy Interfaces: A Note on Host->Guest Notification ------------------------------------------------------------------ As legacy devices and drivers support only classic queue indicators, host->guest notification will always be done via classic I/O interrupts. 2.3.3.3.2. Guest->Host Notification ----------------------------------- For notifying the host of virtqueue buffers, the guest unfortunately can't use a channel command (the asynchronous characteristics of channel I/O interact badly with the host block I/O backend). Instead, it uses a diagnose 0x500 call with subcode 3 specifying the queue, as follows: +------+-------------------+--------------+ | GPR | Input Value | Output Value | +------+-------------------+--------------+ +------+-------------------+--------------+ | 1 | 0x3 | | +------+-------------------+--------------+ | 2 | Subchannel ID | Host Cookie | +------+-------------------+--------------+ | 3 | Virtqueue number | | +------+-------------------+--------------+ | 4 | Host Cookie | | +------+-------------------+--------------+ Host cookie is an optional per-virtqueue 64 bit value that can be used by the hypervisor to speed up the notification execution. For each notification, the output value is returned in GPR2 and should be passed in GPR4 for the next notification: info->cookie = do_notify(schid, virtqueue_get_queue_index(vq), info->cookie); 2.3.3.3.3. Early printk for Virtio Consoles ------------------------------------------- For the early printk mechanism, diagnose 0x500 with subcode 0 is used. 2.3.3.3.4. Resetting Devices ---------------------------- In order to reset a device, a guest may send the CCW_CMD_VDEV_RESET command. 2.4. Device Types ================ On top of the queues, config space and feature negotiation facilities built into virtio, several specific devices are defined. The following device IDs are used to identify different types of virtio devices. Some device IDs are reserved for devices which are not currently defined in this standard. Discovering what devices are available and their type is bus-dependent. +------------+--------------------+ | Device ID | Virtio Device | +------------+--------------------+ +------------+--------------------+ | 0 | reserved (invalid) | +------------+--------------------+ | 1 | network card | +------------+--------------------+ | 2 | block device | +------------+--------------------+ | 3 | console | +------------+--------------------+ | 4 | entropy source | +------------+--------------------+ | 5 | memory ballooning | +------------+--------------------+ | 6 | ioMemory | +------------+--------------------+ | 7 | rpmsg | +------------+--------------------+ | 8 | SCSI host | +------------+--------------------+ | 9 | 9P transport | +------------+--------------------+ | 10 | mac80211 wlan | +------------+--------------------+ | 11 | rproc serial | +------------+--------------------+ | 12 | virtio CAIF | +------------+--------------------+ 2.4.1. Network Device ==================== The virtio network device is a virtual ethernet card, and is the most complex of the devices supported so far by virtio. It has enhanced rapidly and demonstrates clearly how support for new features should be added to an existing device. Empty buffers are placed in one virtqueue for receiving packets, and outgoing packets are enqueued into another for transmission in that order. A third command queue is used to control advanced filtering features. 2.4.1.1. Device ID ----------------- 1 2.4.1.2. Virtqueues ------------------ 0:receiveq. 1:transmitq. 2:controlq Virtqueue 2 only exists if VIRTIO_NET_F_CTRL_VQ set. 2.4.1.3. Feature bits -------------------- VIRTIO_NET_F_CSUM (0) Device handles packets with partial checksum VIRTIO_NET_F_GUEST_CSUM (1) Guest handles packets with partial checksum VIRTIO_NET_F_CTRL_GUEST_OFFLOADS (2) Control channel offloads reconfiguration support. VIRTIO_NET_F_MAC (5) Device has given MAC address. VIRTIO_NET_F_GUEST_TSO4 (7) Guest can receive TSOv4. VIRTIO_NET_F_GUEST_TSO6 (8) Guest can receive TSOv6. VIRTIO_NET_F_GUEST_ECN (9) Guest can receive TSO with ECN. VIRTIO_NET_F_GUEST_UFO (10) Guest can receive UFO. VIRTIO_NET_F_HOST_TSO4 (11) Device can receive TSOv4. VIRTIO_NET_F_HOST_TSO6 (12) Device can receive TSOv6. VIRTIO_NET_F_HOST_ECN (13) Device can receive TSO with ECN. VIRTIO_NET_F_HOST_UFO (14) Device can receive UFO. VIRTIO_NET_F_MRG_RXBUF (15) Guest can merge receive buffers. VIRTIO_NET_F_STATUS (16) Configuration status field is available. VIRTIO_NET_F_CTRL_VQ (17) Control channel is available. VIRTIO_NET_F_CTRL_RX (18) Control channel RX mode support. VIRTIO_NET_F_CTRL_VLAN (19) Control channel VLAN filtering. VIRTIO_NET_F_GUEST_ANNOUNCE(21) Guest can send gratuitous packets. 2.4.1.3.1. Legacy Interface: Feature bits -------------------- VIRTIO_NET_F_GSO (6) Device handles packets with any GSO type. This was supposed to indicate segmentation offload support, but upon further investigation it became clear that multiple bits were required. 100.4.1.4. Device configuration layout --------------------- Two configuration fields are currently defined. The mac address field always exists (though is only valid if VIRTIO_NET_F_MAC is set), and the status field only exists if VIRTIO_NET_F_STATUS is set. Two read-only bits are currently defined for the status field: VIRTIO_NET_S_LINK_UP and VIRTIO_NET_S_ANNOUNCE. #define VIRTIO_NET_S_LINK_UP 1 #define VIRTIO_NET_S_ANNOUNCE 2 struct virtio_net_config { u8 mac[6]; le16 status; }; 100.4.1.4.1. Legacy Interface: Device configuration layout -------------------- For legacy devices, the status field in struct virtio_net_config is the native endian of the guest rather than (necessarily) little-endian. 2.4.1.4. Device Initialization ----------------------------- 1. The initialization routine should identify the receive and transmission virtqueues. 2. If the VIRTIO_NET_F_MAC feature bit is set, the configuration space “mac” entry indicates the “physical” address of the the network card, otherwise a private MAC address should be assigned. All guests are expected to negotiate this feature if it is set. 3. If the VIRTIO_NET_F_CTRL_VQ feature bit is negotiated, identify the control virtqueue. 4. If the VIRTIO_NET_F_STATUS feature bit is negotiated, the link status can be read from the bottom bit of the “status” config field. Otherwise, the link should be assumed active. 5. The receive virtqueue should be filled with receive buffers. This is described in detail below in “Setting Up Receive Buffers”. 6. A driver can indicate that it will generate checksumless packets by negotating the VIRTIO_NET_F_CSUM feature. This “ checksum offload” is a common feature on modern network cards. 7. If that feature is negotiated[13], a driver can use TCP or UDP segmentation offload by negotiating the VIRTIO_NET_F_HOST_TSO4 (IPv4 TCP), VIRTIO_NET_F_HOST_TSO6 (IPv6 TCP) and VIRTIO_NET_F_HOST_UFO (UDP fragmentation) features. It should not send TCP packets requiring segmentation offload which have the Explicit Congestion Notification bit set, unless the VIRTIO_NET_F_HOST_ECN feature is negotiated.[14] 8. The converse features are also available: a driver can save the virtual device some work by negotiating these features.[15] The VIRTIO_NET_F_GUEST_CSUM feature indicates that partially checksummed packets can be received, and if it can do that then the VIRTIO_NET_F_GUEST_TSO4, VIRTIO_NET_F_GUEST_TSO6, VIRTIO_NET_F_GUEST_UFO and VIRTIO_NET_F_GUEST_ECN are the input equivalents of the features described above. See “Receiving Packets” below. 2.4.1.5. Device Operation ------------------------ Packets are transmitted by placing them in the transmitq, and buffers for incoming packets are placed in the receiveq. In each case, the packet itself is preceeded by a header: struct virtio_net_hdr { #define VIRTIO_NET_HDR_F_NEEDS_CSUM 1 u8 flags; #define VIRTIO_NET_HDR_GSO_NONE 0 #define VIRTIO_NET_HDR_GSO_TCPV4 1 #define VIRTIO_NET_HDR_GSO_UDP 3 #define VIRTIO_NET_HDR_GSO_TCPV6 4 #define VIRTIO_NET_HDR_GSO_ECN 0x80 u8 gso_type; le16 hdr_len; le16 gso_size; le16 csum_start; le16 csum_offset; /* Only if VIRTIO_NET_F_MRG_RXBUF: */ le16 num_buffers; }; The controlq is used to control device features such as filtering. 100.4.1.5.1 Legacy Interface: Device Operation ------------------------ For legacy devices, the fields in struct virtio_net_hdr are the native endian of the guest rather than (necessarily) little-endian. 2.4.1.5.1. Packet Transmission ----------------------------- Transmitting a single packet is simple, but varies depending on the different features the driver negotiated. 1. If the driver negotiated VIRTIO_NET_F_CSUM, and the packet has not been fully checksummed, then the virtio_net_hdr's fields are set as follows. Otherwise, the packet must be fully checksummed, and flags is zero. • flags has the VIRTIO_NET_HDR_F_NEEDS_CSUM set, • csum_start is set to the offset within the packet to begin checksumming, and • csum_offset indicates how many bytes after the csum_start the new (16 bit ones' complement) checksum should be placed.[16] 2. If the driver negotiated VIRTIO_NET_F_HOST_TSO4, TSO6 or UFO, and the packet requires TCP segmentation or UDP fragmentation, then the “gso_type” field is set to VIRTIO_NET_HDR_GSO_TCPV4, TCPV6 or UDP. (Otherwise, it is set to VIRTIO_NET_HDR_GSO_NONE). In this case, packets larger than 1514 bytes can be transmitted: the metadata indicates how to replicate the packet header to cut it into smaller packets. The other gso fields are set: • hdr_len is a hint to the device as to how much of the header needs to be kept to copy into each packet, usually set to the length of the headers, including the transport header.[17] • gso_size is the maximum size of each packet beyond that header (ie. MSS). • If the driver negotiated the VIRTIO_NET_F_HOST_ECN feature, the VIRTIO_NET_HDR_GSO_ECN bit may be set in “gso_type” as well, indicating that the TCP packet has the ECN bit set.[18] 3. If the driver negotiated the VIRTIO_NET_F_MRG_RXBUF feature, the num_buffers field is set to zero. 4. The header and packet are added as one output buffer to the transmitq, and the device is notified of the new entry (see "2.4.1.4. Notifying The Device").[19] 2.4.1.5.1.1. Packet Transmission Interrupt ----------------------------------------- Often a driver will suppress transmission interrupts using the VRING_AVAIL_F_NO_INTERRUPT flag (see "2.4.2. Receiving Used Buffers From The Device") and check for used packets in the transmit path of following packets. The normal behavior in this interrupt handler is to retrieve and new descriptors from the used ring and free the corresponding headers and packets. 2.4.1.5.2. Setting Up Receive Buffers It is generally a good idea to keep the receive virtqueue as fully populated as possible: if it runs out, network performance will suffer. If the VIRTIO_NET_F_GUEST_TSO4, VIRTIO_NET_F_GUEST_TSO6 or VIRTIO_NET_F_GUEST_UFO features are used, the Guest will need to accept packets of up to 65550 bytes long (the maximum size of a TCP or UDP packet, plus the 14 byte ethernet header), otherwise 1514. bytes. So unless VIRTIO_NET_F_MRG_RXBUF is negotiated, every buffer in the receive queue needs to be at least this length [20] If VIRTIO_NET_F_MRG_RXBUF is negotiated, each buffer must be at least the size of the struct virtio_net_hdr. 2.4.1.5.2.1. Packet Receive Interrupt ------------------------------------ When a packet is copied into a buffer in the receiveq, the optimal path is to disable further interrupts for the receiveq (see 2.2.2.2. Receiving Used Buffers From The Device) and process packets until no more are found, then re-enable them. Processing packet involves: 1. If the driver negotiated the VIRTIO_NET_F_MRG_RXBUF feature, then the “num_buffers” field indicates how many descriptors this packet is spread over (including this one). This allows receipt of large packets without having to allocate large buffers. In this case, there will be at least “num_buffers” in the used ring, and they should be chained together to form a single packet. The other buffers will not begin with a struct virtio_net_hdr. 2. If the VIRTIO_NET_F_MRG_RXBUF feature was not negotiated, or the “num_buffers” field is one, then the entire packet will be contained within this buffer, immediately following the struct virtio_net_hdr. 3. If the VIRTIO_NET_F_GUEST_CSUM feature was negotiated, the VIRTIO_NET_HDR_F_NEEDS_CSUM bit in the “flags” field may be set: if so, the checksum on the packet is incomplete and the “ csum_start” and “csum_offset” fields indicate how to calculate it (see Packet Transmission point 1). 4. If the VIRTIO_NET_F_GUEST_TSO4, TSO6 or UFO options were negotiated, then the “gso_type” may be something other than VIRTIO_NET_HDR_GSO_NONE, and the “gso_size” field indicates the desired MSS (see Packet Transmission point 2). 2.4.1.5.3. Control Virtqueue --------------------------- The driver uses the control virtqueue (if VIRTIO_NET_F_VTRL_VQ is negotiated) to send commands to manipulate various features of the device which would not easily map into the configuration space. All commands are of the following form: struct virtio_net_ctrl { u8 class; u8 command; u8 command-specific-data[]; u8 ack; }; /* ack values */ #define VIRTIO_NET_OK 0 #define VIRTIO_NET_ERR 1 The class, command and command-specific-data are set by the driver, and the device sets the ack byte. There is little it can do except issue a diagnostic if the ack byte is not VIRTIO_NET_OK. 2.4.1.5.2.1. Packet Receive Filtering ------------------------------------ If the VIRTIO_NET_F_CTRL_RX feature is negotiated, the driver can send control commands for promiscuous mode, multicast receiving, and filtering of MAC addresses. Note that in general, these commands are best-effort: unwanted packets may still arrive. Setting Promiscuous Mode #define VIRTIO_NET_CTRL_RX 0 #define VIRTIO_NET_CTRL_RX_PROMISC 0 #define VIRTIO_NET_CTRL_RX_ALLMULTI 1 The class VIRTIO_NET_CTRL_RX has two commands: VIRTIO_NET_CTRL_RX_PROMISC turns promiscuous mode on and off, and VIRTIO_NET_CTRL_RX_ALLMULTI turns all-multicast receive on and off. The command-specific-data is one byte containing 0 (off) or 1 (on). 2.4.1.5.2.2. Setting MAC Address Filtering ----------------------------------------- struct virtio_net_ctrl_mac { le32 entries; u8 macs[entries][ETH_ALEN]; }; #define VIRTIO_NET_CTRL_MAC 1 #define VIRTIO_NET_CTRL_MAC_TABLE_SET 0 The device can filter incoming packets by any number of destination MAC addresses.[21] This table is set using the class VIRTIO_NET_CTRL_MAC and the command VIRTIO_NET_CTRL_MAC_TABLE_SET. The command-specific-data is two variable length tables of 6-byte MAC addresses. The first table contains unicast addresses, and the second contains multicast addresses. 2.4.1.5.2.2.1. Legacy Interface: Setting MAC Address Filtering ----------------------------------------- For legacy devices, the entries field in struct virtio_net_ctrl_mac is the native endian of the guest rather than (necessarily) little-endian. 2.4.1.5.3.3. VLAN Filtering -------------------------- If the driver negotiates the VIRTION_NET_F_CTRL_VLAN feature, it can control a VLAN filter table in the device. #define VIRTIO_NET_CTRL_VLAN 2 #define VIRTIO_NET_CTRL_VLAN_ADD 0 #define VIRTIO_NET_CTRL_VLAN_DEL 1 Both the VIRTIO_NET_CTRL_VLAN_ADD and VIRTIO_NET_CTRL_VLAN_DEL command take a little-endian 16-bit VLAN id as the command-specific-data. 2.4.1.5.3.3.1. Legacy Interface: VLAN Filtering ----------------------------------------- For legacy devices, the VLAN id is in the native endian of the guest rather than (necessarily) little-endian. 2.4.1.5.3.4. Gratuitous Packet Sending ------------------------------------- If the driver negotiates the VIRTIO_NET_F_GUEST_ANNOUNCE (depends on VIRTIO_NET_F_CTRL_VQ), it can ask the guest to send gratuitous packets; this is usually done after the guest has been physically migrated, and needs to announce its presence on the new network links. (As hypervisor does not have the knowledge of guest network configuration (eg. tagged vlan) it is simplest to prod the guest in this way). #define VIRTIO_NET_CTRL_ANNOUNCE 3 #define VIRTIO_NET_CTRL_ANNOUNCE_ACK 0 The Guest needs to check VIRTIO_NET_S_ANNOUNCE bit in status field when it notices the changes of device configuration. The command VIRTIO_NET_CTRL_ANNOUNCE_ACK is used to indicate that driver has recevied the notification and device would clear the VIRTIO_NET_S_ANNOUNCE bit in the status filed after it received this command. Processing this notification involves: 1. Sending the gratuitous packets or marking there are pending gratuitous packets to be sent and letting deferred routine to send them. 2. Sending VIRTIO_NET_CTRL_ANNOUNCE_ACK command through control vq. 2.4.1.5.3.5. Offloads State Configuration ------------------------------------- If the VIRTIO_NET_F_CTRL_GUEST_OFFLOADS feature is negotiated, the driver can send control commands for dynamic offloads state configuration. 2.4.1.5.4.3.1. Setting Offloads State ------------------------------------- le64 offloads; #define VIRTIO_NET_F_GUEST_CSUM 1 #define VIRTIO_NET_F_GUEST_TSO4 7 #define VIRTIO_NET_F_GUEST_TSO6 8 #define VIRTIO_NET_F_GUEST_ECN 9 #define VIRTIO_NET_F_GUEST_UFO 10 #define VIRTIO_NET_CTRL_GUEST_OFFLOADS 5 #define VIRTIO_NET_CTRL_GUEST_OFFLOADS_SET 0 The class VIRTIO_NET_CTRL_GUEST_OFFLOADS has one command: VIRTIO_NET_CTRL_GUEST_OFFLOADS_SET applies the new offloads configuration. le64 value passed as command data is a bitmask, bits set define offloads to be enabled, bits cleared - offloads to be disabled. There is a corresponding device feature for each offload. Upon feature negotiation corresponding offload gets enabled to preserve backward compartibility. Corresponding feature must be negotiated at startup in order to allow dynamic change of specific offload state. 2.4.1.5.4.3.1.1. Legacy Interface: Setting Offloads State ------------------------------------- For legacy devices, the offloads field is the native endian of the guest rather than (necessarily) little-endian. 2.4.2. Block Device ================== The virtio block device is a simple virtual block device (ie. disk). Read and write requests (and other exotic requests) are placed in the queue, and serviced (probably out of order) by the device except where noted. 2.4.2.1. Device ID ----------------- 2 2.4.2.2. Virtqueues ------------------ 0:requestq 2.4.2.3. Feature bits -------------------- VIRTIO_BLK_F_SIZE_MAX (1) Maximum size of any single segment is in “size_max”. VIRTIO_BLK_F_SEG_MAX (2) Maximum number of segments in a request is in “seg_max”. VIRTIO_BLK_F_GEOMETRY (4) Disk-style geometry specified in “ geometry”. VIRTIO_BLK_F_RO (5) Device is read-only. VIRTIO_BLK_F_BLK_SIZE (6) Block size of disk is in “blk_size”. VIRTIO_BLK_F_TOPOLOGY (10) Device exports information on optimal I/O alignment. 2.4.2.3.1 Legacy Interface: Feature bits -------------------- VIRTIO_BLK_F_BARRIER (0) Host supports request barriers. VIRTIO_BLK_F_SCSI (7) Device supports scsi packet commands. VIRTIO_BLK_F_FLUSH (9) Cache flush command support. VIRTIO_BLK_F_CONFIG_WCE (11) Device can toggle its cache between writeback and writethrough modes. VIRTIO_BLK_F_FLUSH was also called VIRTIO_BLK_F_WCE: Legacy drivers should only negotiate this feature if they are capable of sending VIRTIO_BLK_T_FLUSH commands. 100.2.4.2.5. Device configuration layout -------------------- The capacity of the device (expressed in 512-byte sectors) is always present. The availability of the others all depend on various feature bits as indicated above. struct virtio_blk_config { le64 capacity; le32 size_max; le32 seg_max; struct virtio_blk_geometry { le16 cylinders; u8 heads; u8 sectors; } geometry; le32 blk_size; struct virtio_blk_topology { // # of logical blocks per physical block (log2) u8 physical_block_exp; // offset of first aligned logical block u8 alignment_offset; // suggested minimum I/O size in blocks le16 min_io_size; // optimal (suggested maximum) I/O size in blocks le32 opt_io_size; } topology; u8 reserved; }; 100.2.4.2.5.1. Legacy Interface: Device configuration layout -------------------- For legacy devices, the fields in struct virtio_blk_config are the native endian of the guest rather than (necessarily) little-endian. 2.4.2.4. Device Initialization ----------------------------- 1. The device size should be read from the “capacity” configuration field. No requests should be submitted which goes beyond this limit. 2. If the VIRTIO_BLK_F_BLK_SIZE feature is negotiated, the blk_size field can be read to determine the optimal sector size for the driver to use. This does not affect the units used in the protocol (always 512 bytes), but awareness of the correct value can affect performance. 3. If the VIRTIO_BLK_F_RO feature is set by the device, any write requests will fail. 4. If the VIRTIO_BLK_F_TOPOLOGY feature is negotiated, the fields in the topology struct can be read to determine the physical block size and optimal I/O lengths for the driver to use. This also does not affect the units in the protocol, only performance. 2.4.2.4.1. Legacy Interface: Device Initialization ----------------------------- The reserved field used to be called writeback. If the VIRTIO_BLK_F_CONFIG_WCE feature is offered, the cache mode should be read from the writeback field of the configuration if available; the driver can also write to the field in order to toggle the cache between writethrough (0) and writeback (1) mode. If the feature is not available, the driver can instead look at the result of negotiating VIRTIO_BLK_F_FLUSH: the cache will be in writeback mode after reset if and only if VIRTIO_BLK_F_FLUSH is negotiated. Some older legacy devices did not operate in writethrough mode even after a guest announced lack of support for VIRTIO_BLK_F_FLUSH. 2.4.2.5. Device Operation ------------------------ The driver queues requests to the virtqueue, and they are used by the device (not necessarily in order). Each request is of form: struct virtio_blk_req { le32 type; le32 reserved; le64 sector; char data[][512]; u8 status; }; The type of the request is either a read (VIRTIO_BLK_T_IN), a write (VIRTIO_BLK_T_OUT), or a flush (VIRTIO_BLK_T_FLUSH or VIRTIO_BLK_T_FLUSH_OUT[23]). #define VIRTIO_BLK_T_IN 0 #define VIRTIO_BLK_T_OUT 1 #define VIRTIO_BLK_T_FLUSH 4 #define VIRTIO_BLK_T_FLUSH_OUT 5 The sector number indicates the offset (multiplied by 512) where the read or write is to occur. This field is unused and set to 0 for scsi packet commands and for flush commands. The final status byte is written by the device: either VIRTIO_BLK_S_OK for success, VIRTIO_BLK_S_IOERR for host or guest error or VIRTIO_BLK_S_UNSUPP for a request unsupported by host: #define VIRTIO_BLK_S_OK 0 #define VIRTIO_BLK_S_IOERR 1 #define VIRTIO_BLK_S_UNSUPP 2 Any writes completed before the submission of the flush command should be committed to non-volatile storage by the device. 2.4.2.5.1 Legacy Interface: Device Operation ------------------------ For legacy devices, the fields in struct virtio_blk_req are the native endian of the guest rather than (necessarily) little-endian. The 'reserved' field was previously called ioprio. The ioprio field is a hint about the relative priorities of requests to the device: higher numbers indicate more important requests. #define VIRTIO_BLK_T_BARRIER 0x80000000 If the device has VIRTIO_BLK_F_BARRIER feature the high bit (VIRTIO_BLK_T_BARRIER) indicates that this request acts as a barrier and that all preceeding requests must be complete before this one, and all following requests must not be started until this is complete. Note that a barrier does not flush caches in the underlying backend device in host, and thus does not serve as data consistency guarantee. Driver must use FLUSH request to flush the host cache. If the device has VIRTIO_BLK_F_SCSI feature, it can also support scsi packet command requests, each of these requests is of form: /* All fields are in guest's native endian. */ struct virtio_scsi_pc_req { u32 type; u32 ioprio; u64 sector; char cmd[]; char data[][512]; #define SCSI_SENSE_BUFFERSIZE 96 u8 sense[SCSI_SENSE_BUFFERSIZE]; u32 errors; u32 data_len; u32 sense_len; u32 residual; u8 status; }; A request type can also be a scsi packet command (VIRTIO_BLK_T_SCSI_CMD or VIRTIO_BLK_T_SCSI_CMD_OUT). The two types are equivalent, the device does not distinguish between them: #define VIRTIO_BLK_T_SCSI_CMD 2 #define VIRTIO_BLK_T_SCSI_CMD_OUT 3 The cmd field is only present for scsi packet command requests, and indicates the command to perform. This field must reside in a single, separate read-only buffer; command length can be derived from the length of this buffer. Note that these first three (four for scsi packet commands) fields are always read-only: the data field is either read-only or write-only, depending on the request. The size of the read or write can be derived from the total size of the request buffers. The sense field is only present for scsi packet command requests, and indicates the buffer for scsi sense data. The data_len field is only present for scsi packet command requests, this field is deprecated, and should be ignored by the driver. Historically, devices copied data length there. The sense_len field is only present for scsi packet command requests and indicates the number of bytes actually written to the sense buffer. The residual field is only present for scsi packet command requests and indicates the residual size, calculated as data length - number of bytes actually transferred. Historically, devices assumed that the fields type, ioprio and sector reside in a single, separate read-only buffer; the fields errors, data_len, sense_len and residual reside in a single, separate write-only buffer; the sense field in a separate write-only buffer of size 96 bytes, by itself; the fields errors, data_len, sense_len and residual in a single write-only buffer; and the status field is a separate read-only buffer of size 1 byte, by itself. 2.4.3. Console Device ==================== The virtio console device is a simple device for data input and output. A device may have one or more ports. Each port has a pair of input and output virtqueues. Moreover, a device has a pair of control IO virtqueues. The control virtqueues are used to communicate information between the device and the driver about ports being opened and closed on either side of the connection, indication from the host about whether a particular port is a console port, adding new ports, port hot-plug/unplug, etc., and indication from the guest about whether a port or a device was successfully added, port open/close, etc.. For data IO, one or more empty buffers are placed in the receive queue for incoming data and outgoing characters are placed in the transmit queue. 2.4.3.1. Device ID ----------------- 3 2.4.3.2. Virtqueues ------------------ 0:receiveq(port0). 1:transmitq(port0), 2:control receiveq, 3:control transmitq, 4:receiveq(port1), 5:transmitq(port1), ... Ports 2 onwards only exist if VIRTIO_CONSOLE_F_MULTIPORT is set. 2.4.3.3. Feature bits -------------------- VIRTIO_CONSOLE_F_SIZE (0) Configuration cols and rows fields are valid. VIRTIO_CONSOLE_F_MULTIPORT(1) Device has support for multiple ports; configuration fields nr_ports and max_nr_ports are valid and control virtqueues will be used. 2.4.3.4. Device configuration layout ----------------------------------- The size of the console is supplied in the configuration space if the VIRTIO_CONSOLE_F_SIZE feature is set. Furthermore, if the VIRTIO_CONSOLE_F_MULTIPORT feature is set, the maximum number of ports supported by the device can be fetched. struct virtio_console_config { le16 cols; le16 rows; le32 max_nr_ports; }; 2.4.3.4.1. Legacy Interface: Device configuration layout ----------------------------------- For legacy devices, the fields in struct virtio_console_config are the native endian of the guest rather than (necessarily) little-endian. 2.4.3.5. Device Initialization ----------------------------- 1. If the VIRTIO_CONSOLE_F_SIZE feature is negotiated, the driver can read the console dimensions from the configuration fields. 2. If the VIRTIO_CONSOLE_F_MULTIPORT feature is negotiated, the driver can spawn multiple ports, not all of which may be attached to a console. Some could be generic ports. In this case, the control virtqueues are enabled and according to the max_nr_ports configuration-space value, the appropriate number of virtqueues are created. A control message indicating the driver is ready is sent to the host. The host can then send control messages for adding new ports to the device. After creating and initializing each port, a VIRTIO_CONSOLE_PORT_READY control message is sent to the host for that port so the host can let us know of any additional configuration options set for that port. 3. The receiveq for each port is populated with one or more receive buffers. 2.4.3.6. Device Operation ------------------------ 1. For output, a buffer containing the characters is placed in the port's transmitq.[24] 2. When a buffer is used in the receiveq (signalled by an interrupt), the contents is the input to the port associated with the virtqueue for which the notification was received. 3. If the driver negotiated the VIRTIO_CONSOLE_F_SIZE feature, a configuration change interrupt may occur. The updated size can be read from the configuration fields. 4. If the driver negotiated the VIRTIO_CONSOLE_F_MULTIPORT feature, active ports are announced by the host using the VIRTIO_CONSOLE_PORT_ADD control message. The same message is used for port hot-plug as well. 5. If the host specified a port `name', a sysfs attribute is created with the name filled in, so that udev rules can be written that can create a symlink from the port's name to the char device for port discovery by applications in the guest. 6. Changes to ports' state are effected by control messages. Appropriate action is taken on the port indicated in the control message. The layout of the structure of the control buffer and the events associated are: struct virtio_console_control { le32 id; /* Port number */ le16 event; /* The kind of control event */ le16 value; /* Extra information for the event */ }; /* Some events for the internal messages (control packets) */ #define VIRTIO_CONSOLE_DEVICE_READY 0 #define VIRTIO_CONSOLE_PORT_ADD 1 #define VIRTIO_CONSOLE_PORT_REMOVE 2 #define VIRTIO_CONSOLE_PORT_READY 3 #define VIRTIO_CONSOLE_CONSOLE_PORT 4 #define VIRTIO_CONSOLE_RESIZE 5 #define VIRTIO_CONSOLE_PORT_OPEN 6 #define VIRTIO_CONSOLE_PORT_NAME 7 2.4.3.6.1. Legacy Interface: Device Operation ------------------------ For legacy devices, the fields in struct virtio_console_control are the native endian of the guest rather than (necessarily) little-endian. 2.4.4. Entropy Device ==================== The virtio entropy device supplies high-quality randomness for guest use. 2.4.4.1. Device ID ----------------- 4 2.4.4.2. Virtqueues ------------------ 0:requestq. 2.4.4.3. Feature bits -------------------- None currently defined 2.4.4.4. Device configuration layout ----------------------------------- None currently defined. 2.4.4.5. Device Initialization ----------------------------- 1. The virtqueue is initialized 2.4.4.6. Device Operation ------------------------ When the driver requires random bytes, it places the descriptor of one or more buffers in the queue. It will be completely filled by random data by the device. 2.4.5. Memory Balloon Device =========================== The virtio memory balloon device is a primitive device for managing guest memory: the device asks for a certain amount of memory, and the guest supplies it (or withdraws it, if the device has more than it asks for). This allows the guest to adapt to changes in allowance of underlying physical memory. If the feature is negotiated, the device can also be used to communicate guest memory statistics to the host. 2.4.5.1. Device ID ----------------- 5 2.4.5.2. Virtqueues ------------------ 0:inflateq. 1:deflateq. 2:statsq. Virtqueue 2 only exists if VIRTIO_BALLON_F_STATS_VQ set. 2.4.5.3. Feature bits -------------------- VIRTIO_BALLOON_F_MUST_TELL_HOST (0) Host must be told before pages from the balloon are used. VIRTIO_BALLOON_F_STATS_VQ (1) A virtqueue for reporting guest memory statistics is present. 2.4.5.4. Device configuration layout ----------------------------------- Both fields of this configuration are always available. struct virtio_balloon_config { le32 num_pages; le32 actual; }; 2.4.5.4.1. Legacy Interface: Device configuration layout ----------------------------------- Note that these fields are always little endian, despite convention that legacy device fields are guest endian. 2.4.5.5. Device Initialization ----------------------------- 1. The inflate and deflate virtqueues are identified. 2. If the VIRTIO_BALLOON_F_STATS_VQ feature bit is negotiated: (a) Identify the stats virtqueue. (b) Add one empty buffer to the stats virtqueue and notify the host. Device operation begins immediately. 2.4.5.6. Device Operation ------------------------ Memory Ballooning The device is driven by the receipt of a configuration change interrupt. 1. The “num_pages” configuration field is examined. If this is greater than the “actual” number of pages, memory must be given to the balloon. If it is less than the “actual” number of pages, memory may be taken back from the balloon for general use. 2. To supply memory to the balloon (aka. inflate): (a) The driver constructs an array of addresses of unused memory pages. These addresses are divided by 4096[25] and the descriptor describing the resulting 32-bit array is added to the inflateq. 3. To remove memory from the balloon (aka. deflate): (a) The driver constructs an array of addresses of memory pages it has previously given to the balloon, as described above. This descriptor is added to the deflateq. (b) If the VIRTIO_BALLOON_F_MUST_TELL_HOST feature is negotiated, the guest may not use these requested pages until that descriptor in the deflateq has been used by the device. (c) Otherwise, the guest may begin to re-use pages previously given to the balloon before the device has acknowledged their withdrawl. [26] 4. In either case, once the device has completed the inflation or deflation, the “actual” field of the configuration should be updated to reflect the new number of pages in the balloon.[27] 2.4.5.6.1. Memory Statistics --------------------------- The stats virtqueue is atypical because communication is driven by the device (not the driver). The channel becomes active at driver initialization time when the driver adds an empty buffer and notifies the device. A request for memory statistics proceeds as follows: 1. The device pushes the buffer onto the used ring and sends an interrupt. 2. The driver pops the used buffer and discards it. 3. The driver collects memory statistics and writes them into a new buffer. 4. The driver adds the buffer to the virtqueue and notifies the device. 5. The device pops the buffer (retaining it to initiate a subsequent request) and consumes the statistics. Memory Statistics Format Each statistic consists of a 16 bit tag and a 64 bit value. All statistics are optional and the driver may choose which ones to supply. To guarantee backwards compatibility, unsupported statistics should be omitted. struct virtio_balloon_stat { #define VIRTIO_BALLOON_S_SWAP_IN 0 #define VIRTIO_BALLOON_S_SWAP_OUT 1 #define VIRTIO_BALLOON_S_MAJFLT 2 #define VIRTIO_BALLOON_S_MINFLT 3 #define VIRTIO_BALLOON_S_MEMFREE 4 #define VIRTIO_BALLOON_S_MEMTOT 5 le16 tag; le64 val; } __attribute__((packed)); 2.4.5.6.1. Legacy Interface: Memory Statistics --------------------------- For legacy devices, the fields in struct virtio_balloon_stat are the native endian of the guest rather than (necessarily) little-endian. 2.4.5.6.2. Memory Statistics Tags -------------------------------- VIRTIO_BALLOON_S_SWAP_IN The amount of memory that has been swapped in (in bytes). VIRTIO_BALLOON_S_SWAP_OUT The amount of memory that has been swapped out to disk (in bytes). VIRTIO_BALLOON_S_MAJFLT The number of major page faults that have occurred. VIRTIO_BALLOON_S_MINFLT The number of minor page faults that have occurred. VIRTIO_BALLOON_S_MEMFREE The amount of memory not being used for any purpose (in bytes). VIRTIO_BALLOON_S_MEMTOT The total amount of memory available (in bytes). 2.4.6. SCSI Host Device ====================== The virtio SCSI host device groups together one or more virtual logical units (such as disks), and allows communicating to them using the SCSI protocol. An instance of the device represents a SCSI host to which many targets and LUNs are attached. The virtio SCSI device services two kinds of requests: • command requests for a logical unit; • task management functions related to a logical unit, target or command. The device is also able to send out notifications about added and removed logical units. Together, these capabilities provide a SCSI transport protocol that uses virtqueues as the transfer medium. In the transport protocol, the virtio driver acts as the initiator, while the virtio SCSI host provides one or more targets that receive and process the requests. 2.4.6.1. Device ID ----------------- 8 2.4.6.2. Virtqueues ------------------ 0:controlq; 1:eventq; 2..n:request queues. 2.4.6.3. Feature bits -------------------- VIRTIO_SCSI_F_INOUT (0) A single request can include both read-only and write-only data buffers. VIRTIO_SCSI_F_HOTPLUG (1) The host should enable hot-plug/hot-unplug of new LUNs and targets on the SCSI bus. VIRTIO_SCSI_F_CHANGE (2) The host will report changes to LUN parameters via a VIRTIO_SCSI_T_PARAM_CHANGE event. 2.4.6.4. Device configuration layout ----------------------------------- All fields of this configuration are always available. sense_size and cdb_size are writable by the guest. struct virtio_scsi_config { le32 num_queues; le32 seg_max; le32 max_sectors; le32 cmd_per_lun; le32 event_info_size; le32 sense_size; le32 cdb_size; le16 max_channel; le16 max_target; le32 max_lun; }; num_queues is the total number of request virtqueues exposed by the device. The driver is free to use only one request queue, or it can use more to achieve better performance. seg_max is the maximum number of segments that can be in a command. A bidirectional command can include seg_max input segments and seg_max output segments. max_sectors is a hint to the guest about the maximum transfer size it should use. cmd_per_lun is a hint to the guest about the maximum number of linked commands it should send to one LUN. The actual value to be used is the minimum of cmd_per_lun and the virtqueue size. event_info_size is the maximum size that the device will fill for buffers that the driver places in the eventq. The driver should always put buffers at least of this size. It is written by the device depending on the set of negotated features. sense_size is the maximum size of the sense data that the device will write. The default value is written by the device and will always be 96, but the driver can modify it. It is restored to the default when the device is reset. cdb_size is the maximum size of the CDB that the driver will write. The default value is written by the device and will always be 32, but the driver can likewise modify it. It is restored to the default when the device is reset. max_channel, max_target and max_lun can be used by the driver as hints to constrain scanning the logical units on the host.h 2.4.6.4.1. Legacy Interface: Device configuration layout ----------------------------------- For legacy devices, the fields in struct virtio_scsi_config are the native endian of the guest rather than (necessarily) little-endian. 2.4.6.5. Device Initialization ----------------------------- The initialization routine should first of all discover the device's virtqueues. If the driver uses the eventq, it should then place at least a buffer in the eventq. The driver can immediately issue requests (for example, INQUIRY or REPORT LUNS) or task management functions (for example, I_T RESET). 2.4.6.6. Device Operation ------------------------ Device operation consists of operating request queues, the control queue and the event queue. 2.4.6.6.1. Device Operation: Request Queues ------------------------------------------ The driver queues requests to an arbitrary request queue, and they are used by the device on that same queue. It is the responsibility of the driver to ensure strict request ordering for commands placed on different queues, because they will be consumed with no order constraints. Requests have the following format: struct virtio_scsi_req_cmd { // Read-only u8 lun[8]; le64 id; u8 task_attr; u8 prio; u8 crn; char cdb[cdb_size]; char dataout[]; // Write-only part le32 sense_len; le32 residual; le16 status_qualifier; u8 status; u8 response; u8 sense[sense_size]; char datain[]; }; /* command-specific response values */ #define VIRTIO_SCSI_S_OK 0 #define VIRTIO_SCSI_S_OVERRUN 1 #define VIRTIO_SCSI_S_ABORTED 2 #define VIRTIO_SCSI_S_BAD_TARGET 3 #define VIRTIO_SCSI_S_RESET 4 #define VIRTIO_SCSI_S_BUSY 5 #define VIRTIO_SCSI_S_TRANSPORT_FAILURE 6 #define VIRTIO_SCSI_S_TARGET_FAILURE 7 #define VIRTIO_SCSI_S_NEXUS_FAILURE 8 #define VIRTIO_SCSI_S_FAILURE 9 /* task_attr */ #define VIRTIO_SCSI_S_SIMPLE 0 #define VIRTIO_SCSI_S_ORDERED 1 #define VIRTIO_SCSI_S_HEAD 2 #define VIRTIO_SCSI_S_ACA 3 The lun field addresses a target and logical unit in the virtio-scsi device's SCSI domain. The only supported format for the LUN field is: first byte set to 1, second byte set to target, third and fourth byte representing a single level LUN structure, followed by four zero bytes. With this representation, a virtio-scsi device can serve up to 256 targets and 16384 LUNs per target. The id field is the command identifier (“tag”). task_attr, prio and crn should be left to zero. task_attr defines the task attribute as in the table above, but all task attributes may be mapped to SIMPLE by the device; crn may also be provided by clients, but is generally expected to be 0. The maximum CRN value defined by the protocol is 255, since CRN is stored in an 8-bit integer. All of these fields are defined in SAM. They are always read-only, as are the cdb and dataout field. The cdb_size is taken from the configuration space. sense and subsequent fields are always write-only. The sense_len field indicates the number of bytes actually written to the sense buffer. The residual field indicates the residual size, calculated as “data_length - number_of_transferred_bytes”, for read or write operations. For bidirectional commands, the number_of_transferred_bytes includes both read and written bytes. A residual field that is less than the size of datain means that the dataout field was processed entirely. A residual field that exceeds the size of datain means that the dataout field was processed partially and the datain field was not processed at all. The status byte is written by the device to be the status code as defined in SAM. The response byte is written by the device to be one of the following: VIRTIO_SCSI_S_OK when the request was completed and the status byte is filled with a SCSI status code (not necessarily "GOOD"). VIRTIO_SCSI_S_OVERRUN if the content of the CDB requires transferring more data than is available in the data buffers. VIRTIO_SCSI_S_ABORTED if the request was cancelled due to an ABORT TASK or ABORT TASK SET task management function. VIRTIO_SCSI_S_BAD_TARGET if the request was never processed because the target indicated by the lun field does not exist. VIRTIO_SCSI_S_RESET if the request was cancelled due to a bus or device reset (including a task management function). VIRTIO_SCSI_S_TRANSPORT_FAILURE if the request failed due to a problem in the connection between the host and the target (severed link). VIRTIO_SCSI_S_TARGET_FAILURE if the target is suffering a failure and the guest should not retry on other paths. VIRTIO_SCSI_S_NEXUS_FAILURE if the nexus is suffering a failure but retrying on other paths might yield a different result. VIRTIO_SCSI_S_BUSY if the request failed but retrying on the same path should work. VIRTIO_SCSI_S_FAILURE for other host or guest error. In particular, if neither dataout nor datain is empty, and the VIRTIO_SCSI_F_INOUT feature has not been negotiated, the request will be immediately returned with a response equal to VIRTIO_SCSI_S_FAILURE. 2.4.6.6.1. Legacy Interface: Device Operation: Request Queues ------------------------------------------ For legacy devices, the fields in struct virtio_scsi_req_cmd are the native endian of the guest rather than (necessarily) little-endian. 2.4.6.6.2. Device Operation: controlq ------------------------------------ The controlq is used for other SCSI transport operations. Requests have the following format: struct virtio_scsi_ctrl { le32 type; ... u8 response; }; /* response values valid for all commands */ #define VIRTIO_SCSI_S_OK 0 #define VIRTIO_SCSI_S_BAD_TARGET 3 #define VIRTIO_SCSI_S_BUSY 5 #define VIRTIO_SCSI_S_TRANSPORT_FAILURE 6 #define VIRTIO_SCSI_S_TARGET_FAILURE 7 #define VIRTIO_SCSI_S_NEXUS_FAILURE 8 #define VIRTIO_SCSI_S_FAILURE 9 #define VIRTIO_SCSI_S_INCORRECT_LUN 12 The type identifies the remaining fields. The following commands are defined: Task management function #define VIRTIO_SCSI_T_TMF 0 #define VIRTIO_SCSI_T_TMF_ABORT_TASK 0 #define VIRTIO_SCSI_T_TMF_ABORT_TASK_SET 1 #define VIRTIO_SCSI_T_TMF_CLEAR_ACA 2 #define VIRTIO_SCSI_T_TMF_CLEAR_TASK_SET 3 #define VIRTIO_SCSI_T_TMF_I_T_NEXUS_RESET 4 #define VIRTIO_SCSI_T_TMF_LOGICAL_UNIT_RESET 5 #define VIRTIO_SCSI_T_TMF_QUERY_TASK 6 #define VIRTIO_SCSI_T_TMF_QUERY_TASK_SET 7 struct virtio_scsi_ctrl_tmf { // Read-only part le32 type; le32 subtype; u8 lun[8]; le64 id; // Write-only part u8 response; } /* command-specific response values */ #define VIRTIO_SCSI_S_FUNCTION_COMPLETE 0 #define VIRTIO_SCSI_S_FUNCTION_SUCCEEDED 10 #define VIRTIO_SCSI_S_FUNCTION_REJECTED 11 The type is VIRTIO_SCSI_T_TMF; the subtype field defines. All fields except response are filled by the driver. The subtype field must always be specified and identifies the requested task management function. Other fields may be irrelevant for the requested TMF; if so, they are ignored but they should still be present. The lun field is in the same format specified for request queues; the single level LUN is ignored when the task management function addresses a whole I_T nexus. When relevant, the value of the id field is matched against the id values passed on the requestq. The outcome of the task management function is written by the device in the response field. The command-specific response values map 1-to-1 with those defined in SAM. Asynchronous notification query #define VIRTIO_SCSI_T_AN_QUERY 1 struct virtio_scsi_ctrl_an { // Read-only part le32 type; u8 lun[8]; le32 event_requested; // Write-only part le32 event_actual; u8 response; } #define VIRTIO_SCSI_EVT_ASYNC_OPERATIONAL_CHANGE 2 #define VIRTIO_SCSI_EVT_ASYNC_POWER_MGMT 4 #define VIRTIO_SCSI_EVT_ASYNC_EXTERNAL_REQUEST 8 #define VIRTIO_SCSI_EVT_ASYNC_MEDIA_CHANGE 16 #define VIRTIO_SCSI_EVT_ASYNC_MULTI_HOST 32 #define VIRTIO_SCSI_EVT_ASYNC_DEVICE_BUSY 64 By sending this command, the driver asks the device which events the given LUN can report, as described in paragraphs 6.6 and A.6 of the SCSI MMC specification. The driver writes the events it is interested in into the event_requested; the device responds by writing the events that it supports into event_actual. The type is VIRTIO_SCSI_T_AN_QUERY. The lun and event_requested fields are written by the driver. The event_actual and response fields are written by the device. No command-specific values are defined for the response byte. Asynchronous notification subscription #define VIRTIO_SCSI_T_AN_SUBSCRIBE 2 struct virtio_scsi_ctrl_an { // Read-only part le32 type; u8 lun[8]; le32 event_requested; // Write-only part le32 event_actual; u8 response; } By sending this command, the driver asks the specified LUN to report events for its physical interface, again as described in the SCSI MMC specification. The driver writes the events it is interested in into the event_requested; the device responds by writing the events that it supports into event_actual. Event types are the same as for the asynchronous notification query message. The type is VIRTIO_SCSI_T_AN_SUBSCRIBE. The lun and event_requested fields are written by the driver. The event_actual and response fields are written by the device. No command-specific values are defined for the response byte. 2.4.6.6.2.1. Legacy Interface: Device Operation: controlq ------------------------------------------ For legacy devices, the fields in struct virtio_scsi_ctrl, struct virtio_scsi_ctrl_tmf, struct virtio_scsi_ctrl_an and struct virtio_scsi_ctrl_an are the native endian of the guest rather than (necessarily) little-endian. 2.4.6.6.3. Device Operation: eventq ---------------------------------- The eventq is used by the device to report information on logical units that are attached to it. The driver should always leave a few buffers ready in the eventq. In general, the device will not queue events to cope with an empty eventq, and will end up dropping events if it finds no buffer ready. However, when reporting events for many LUNs (e.g. when a whole target disappears), the device can throttle events to avoid dropping them. For this reason, placing 10-15 buffers on the event queue should be enough. Buffers are placed in the eventq and filled by the device when interesting events occur. The buffers should be strictly write-only (device-filled) and the size of the buffers should be at least the value given in the device's configuration information. Buffers returned by the device on the eventq will be referred to as "events" in the rest of this section. Events have the following format: #define VIRTIO_SCSI_T_EVENTS_MISSED 0x80000000 struct virtio_scsi_event { // Write-only part le32 event; u8 lun[8]; le32 reason; } If bit 31 is set in the event field, the device failed to report an event due to missing buffers. In this case, the driver should poll the logical units for unit attention conditions, and/or do whatever form of bus scan is appropriate for the guest operating system. The meaning of the reason field depends on the contents of the event field. The following events are defined: No event #define VIRTIO_SCSI_T_NO_EVENT 0 This event is fired in the following cases: • When the device detects in the eventq a buffer that is shorter than what is indicated in the configuration field, it might use it immediately and put this dummy value in the event field. A well-written driver will never observe this situation. • When events are dropped, the device may signal this event as soon as the drivers makes a buffer available, in order to request action from the driver. In this case, of course, this event will be reported with the VIRTIO_SCSI_T_EVENTS_MISSED flag. Transport reset #define VIRTIO_SCSI_T_TRANSPORT_RESET 1 #define VIRTIO_SCSI_EVT_RESET_HARD 0 #define VIRTIO_SCSI_EVT_RESET_RESCAN 1 #define VIRTIO_SCSI_EVT_RESET_REMOVED 2 By sending this event, the device signals that a logical unit on a target has been reset, including the case of a new device appearing or disappearing on the bus.The device fills in all fields. The event field is set to VIRTIO_SCSI_T_TRANSPORT_RESET. The lun field addresses a logical unit in the SCSI host. The reason value is one of the three #define values appearing above: • VIRTIO_SCSI_EVT_RESET_REMOVED (“LUN/target removed”) is used if the target or logical unit is no longer able to receive commands. • VIRTIO_SCSI_EVT_RESET_HARD (“LUN hard reset”) is used if the logical unit has been reset, but is still present. • VIRTIO_SCSI_EVT_RESET_RESCAN (“rescan LUN/target”) is used if a target or logical unit has just appeared on the device. The “removed” and “rescan” events, when sent for LUN 0, may apply to the entire target. After receiving them the driver should ask the initiator to rescan the target, in order to detect the case when an entire target has appeared or disappeared. These two events will never be reported unless the VIRTIO_SCSI_F_HOTPLUG feature was negotiated between the host and the guest. Events will also be reported via sense codes (this obviously does not apply to newly appeared buses or targets, since the application has never discovered them): • “LUN/target removed” maps to sense key ILLEGAL REQUEST, asc 0x25, ascq 0x00 (LOGICAL UNIT NOT SUPPORTED) • “LUN hard reset” maps to sense key UNIT ATTENTION, asc 0x29 (POWER ON, RESET OR BUS DEVICE RESET OCCURRED) • “rescan LUN/target” maps to sense key UNIT ATTENTION, asc 0x3f, ascq 0x0e (REPORTED LUNS DATA HAS CHANGED) The preferred way to detect transport reset is always to use events, because sense codes are only seen by the driver when it sends a SCSI command to the logical unit or target. However, in case events are dropped, the initiator will still be able to synchronize with the actual state of the controller if the driver asks the initiator to rescan of the SCSI bus. During the rescan, the initiator will be able to observe the above sense codes, and it will process them as if it the driver had received the equivalent event. Asynchronous notification #define VIRTIO_SCSI_T_ASYNC_NOTIFY 2 By sending this event, the device signals that an asynchronous event was fired from a physical interface. All fields are written by the device. The event field is set to VIRTIO_SCSI_T_ASYNC_NOTIFY. The lun field addresses a logical unit in the SCSI host. The reason field is a subset of the events that the driver has subscribed to via the "Asynchronous notification subscription" command. When dropped events are reported, the driver should poll for asynchronous events manually using SCSI commands. LUN parameter change #define VIRTIO_SCSI_T_PARAM_CHANGE 3 By sending this event, the device signals that the configuration parameters (for example the capacity) of a logical unit have changed. The event field is set to VIRTIO_SCSI_T_PARAM_CHANGE. The lun field addresses a logical unit in the SCSI host. The same event is also reported as a unit attention condition. The reason field contains the additional sense code and additional sense code qualifier, respectively in bits 0..7 and 8..15. For example, a change in capacity will be reported as asc 0x2a, ascq 0x09 (CAPACITY DATA HAS CHANGED). For MMC devices (inquiry type 5) there would be some overlap between this event and the asynchronous notification event. For simplicity, as of this version of the specification the host must never report this event for MMC devices. 2.4.6.6.3.1. Legacy Interface: Device Operation: eventq ---------------------------------- For legacy devices, the fields in struct virtio_scsi_event are the native endian of the guest rather than (necessarily) little-endian. 2.5. Reserved Feature Bits ========================= Currently there are four device-independent feature bits defined: VIRTIO_F_RING_INDIRECT_DESC (28) Negotiating this feature indicates that the driver can use descriptors with the VRING_DESC_F_INDIRECT flag set, as described in "2.1.4.3.1. Indirect Descriptors". VIRTIO_F_RING_EVENT_IDX(29) This feature enables the used_event and the avail_event fields. If set, it indicates that the device should ignore the flags field in the available ring structure. Instead, the used_event field in this structure is used by guest to suppress device interrupts. Further, the driver should ignore the flags field in the used ring structure. Instead, the avail_event field in this structure is used by the device to suppress notifications. If unset, the driver should ignore the used_event field; the device should ignore the avail_event field; the flags field is used VIRTIO_F_VERSION_1(32) This feature must be offered by any device compliant with this specification, and acknowledged by all device drivers. In addition, bit 30 is used by qemu's implementation to check for experimental early versions of virtio which did not perform correct feature negotiation, and should not be used. 2.5.1 Legacy Interface: Reserved Feature Bits -------------------------------------------- Legacy or transitional devices may offer the following: VIRTIO_F_NOTIFY_ON_EMPTY (24) Negotiating this feature indicates that the driver wants an interrupt if the device runs out of available descriptors on a virtqueue, even though interrupts are suppressed using the VRING_AVAIL_F_NO_INTERRUPT flag or the used_event field. An example of this is the networking driver: it doesn't need to know every time a packet is transmitted, but it does need to free the transmitted packets a finite time after they are transmitted. It can avoid using a timer if the device interrupts it when all the packets are transmitted. VIRTIO_F_ANY_LAYOUT (27) This feature indicates that the device accepts arbitrary descriptor layouts, as described in Section "2.1.4.2.1. Legacy Interface: Message Framing". 2.6. virtio_ring.h ================= #ifndef VIRTIO_RING_H #define VIRTIO_RING_H /* An interface for efficient virtio implementation. * * This header is BSD licensed so anyone can use the definitions * to implement compatible drivers/servers. * * Copyright 2007, 2009, IBM Corporation * Copyright 2011, Red Hat, Inc * All rights reserved. * * Redistribution and use in source and binary forms, with or without * modification, are permitted provided that the following conditions * are met: * 1. Redistributions of source code must retain the above copyright * notice, this list of conditions and the following disclaimer. * 2. Redistributions in binary form must reproduce the above copyright * notice, this list of conditions and the following disclaimer in the * documentation and/or other materials provided with the distribution. * 3. Neither the name of IBM nor the names of its contributors * may be used to endorse or promote products derived from this software * without specific prior written permission. * THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS ``AS IS'' AND * ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE * IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE * ARE DISCLAIMED. IN NO EVENT SHALL IBM OR CONTRIBUTORS BE LIABLE * FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL * DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS * OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) * HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT * LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY * OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF * SUCH DAMAGE. */ #include /* This marks a buffer as continuing via the next field. */ #define VRING_DESC_F_NEXT 1 /* This marks a buffer as write-only (otherwise read-only). */ #define VRING_DESC_F_WRITE 2 /* This means the buffer contains a list of buffer descriptors. */ #define VRING_DESC_F_INDIRECT 4 /* The Host uses this in used->flags to advise the Guest: don't kick me * when you add a buffer. It's unreliable, so it's simply an * optimization. Guest will still kick if it's out of buffers. */ #define VRING_USED_F_NO_NOTIFY 1 /* The Guest uses this in avail->flags to advise the Host: don't * interrupt me when you consume a buffer. It's unreliable, so it's * simply an optimization. */ #define VRING_AVAIL_F_NO_INTERRUPT 1 /* Support for indirect descriptors */ #define VIRTIO_RING_F_INDIRECT_DESC 28 /* Support for avail_idx and used_idx fields */ #define VIRTIO_RING_F_EVENT_IDX 29 /* Arbitrary descriptor layouts. */ #define VIRTIO_F_ANY_LAYOUT 27 /* Virtio ring descriptors: 16 bytes. * These can chain together via "next". */ struct vring_desc { /* Address (guest-physical). */ le64 addr; /* Length. */ le32 len; /* The flags as indicated above. */ le16 flags; /* We chain unused descriptors via this, too */ le16 next; }; struct vring_avail { le16 flags; le16 idx; le16 ring[]; /* Only if VIRTIO_RING_F_EVENT_IDX: le16 used_event; */ }; /* le32 is used here for ids for padding reasons. */ struct vring_used_elem { /* Index of start of used descriptor chain. */ le32 id; /* Total length of the descriptor chain which was written to. */ le32 len; }; struct vring_used { le16 flags; le16 idx; struct vring_used_elem ring[]; /* Only if VIRTIO_RING_F_EVENT_IDX: le16 avail_event; */ }; struct vring { unsigned int num; struct vring_desc *desc; struct vring_avail *avail; struct vring_used *used; }; /* The standard layout for the ring is a continuous chunk of memory which * looks like this. We assume num is a power of 2. * * struct vring { * // The actual descriptors (16 bytes each) * struct vring_desc desc[num]; * * // A ring of available descriptor heads with free-running index. * le16 avail_flags; * le16 avail_idx; * le16 available[num]; * le16 used_event_idx; // Only if VIRTIO_RING_F_EVENT_IDX * * // Padding to the next align boundary. * char pad[]; * * // A ring of used descriptor heads with free-running index. * le16 used_flags; * le16 used_idx; * struct vring_used_elem used[num]; * le16 avail_event_idx; // Only if VIRTIO_RING_F_EVENT_IDX * }; * Note: for virtio PCI, align is 4096. */ static inline void vring_init(struct vring *vr, unsigned int num, void *p, unsigned long align) { vr->num = num; vr->desc = p; vr->avail = p + num*sizeof(struct vring_desc); vr->used = (void *)(((unsigned long)&vr->avail->ring[num] + sizeof(le16) + align-1) & ~(align - 1)); } static inline unsigned vring_size(unsigned int num, unsigned long align) { return ((sizeof(struct vring_desc)*num + sizeof(le16)*(3+num) + align - 1) & ~(align - 1)) + sizeof(le16)*3 + sizeof(struct vring_used_elem)*num; } static inline int vring_need_event(uint16_t event_idx, uint16_t new_idx, uint16_t old_idx) { return (uint16_t)(new_idx - event_idx - 1) < (uint16_t)(new_idx - old_idx); } /* Get location of event indices (only with VIRTIO_RING_F_EVENT_IDX) */ static inline le16 *vring_used_event(struct vring *vr) { /* For backwards compat, used event index is at *end* of avail ring. */ return &vr->avail->ring[vr->num]; } static inline le16 *vring_avail_event(struct vring *vr) { /* For backwards compat, avail event index is at *end* of used ring. */ return (le16 *)&vr->used->ring[vr->num]; } #endif /* VIRTIO_RING_H */ 2.7. Creating New Device Types ============================== Various considerations are necessary when creating a new device type. 2.7.1. How Many Virtqueues? --------------------------- It is possible that a very simple device will operate entirely through its configuration space, but most will need at least one virtqueue in which it will place requests. A device with both input and output (eg. console and network devices described here) need two queues: one which the driver fills with buffers to receive input, and one which the driver places buffers to transmit output. 2.7.2. What Configuration Space Layout? --------------------------------------- Configuration space should only be used for initialization-time parameters. It is a limited resource with no synchronization between writable fields, so for most uses it is better to use a virtqueue to update configuration information (the network device does this for filtering, otherwise the table in the config space could potentially be very large). Devices must not assume that configuration fields over 32 bits wide are atomically writable. 2.7.3. What Device Number? -------------------------- Currently device numbers are assigned quite freely: a simple request mail to the author of this document or the Linux virtualization mailing list[9] will be sufficient to secure a unique one. Meanwhile for experimental drivers, use 65535 and work backwards. 2.7.4. How many MSI-X vectors? (for PCI) ----------------------------------------- Using the optional MSI-X capability devices can speed up interrupt processing by removing the need to read ISR Status register by guest driver (which might be an expensive operation), reducing interrupt sharing between devices and queues within the device, and handling interrupts from multiple CPUs. However, some systems impose a limit (which might be as low as 256) on the total number of MSI-X vectors that can be allocated to all devices. Devices and/or device drivers should take this into account, limiting the number of vectors used unless the device is expected to cause a high volume of interrupts. Devices can control the number of vectors used by limiting the MSI-X Table Size or not presenting MSI-X capability in PCI configuration space. Drivers can control this by mapping events to as small number of vectors as possible, or disabling MSI-X capability altogether. 2.7.5. Device Improvements -------------------------- Any change to configuration space, or new virtqueues, or behavioural changes, should be indicated by negotiation of a new feature bit. This establishes clarity[11] and avoids future expansion problems. Clusters of functionality which are always implemented together can use a single bit, but if one feature makes sense without the others they should not be gratuitously grouped together to conserve feature bits. FOOTNOTES: ========== [1] This lack of page-sharing implies that the implementation of the device (e.g. the hypervisor or host) needs full access to the guest memory. Communication with untrusted parties (i.e. inter-guest communication) requires copying. [2] The Linux implementation further separates the PCI virtio code from the specific virtio drivers: these drivers are shared with the non-PCI implementations (currently lguest and S/390). [3] The actual value within this range is ignored [6] The 4096 is based on the x86 page size, but it's also large enough to ensure that the separate parts of the virtqueue are on separate cache lines. [7] These fields are kept here because this is the only part of the virtqueue written by the device [8] The Linux drivers do this only for read-only buffers: for write-only buffers, it is assumed that the driver is merely trying to keep the receive buffer ring full, and no notification of this expected condition is necessary. [9] https://lists.linux-foundation.org/mailman/listinfo/virtualization [11] Even if it does mean documenting design or implementation mistakes! [13] ie. VIRTIO_NET_F_HOST_TSO* and VIRTIO_NET_F_HOST_UFO are dependent on VIRTIO_NET_F_CSUM; a dvice which offers the offload features must offer the checksum feature, and a driver which accepts the offload features must accept the checksum feature. Similar logic applies to the VIRTIO_NET_F_GUEST_TSO4 features depending on VIRTIO_NET_F_GUEST_CSUM. [14] This is a common restriction in real, older network cards. [15] For example, a network packet transported between two guests on the same system may not require checksumming at all, nor segmentation, if both guests are amenable. [16] For example, consider a partially checksummed TCP (IPv4) packet. It will have a 14 byte ethernet header and 20 byte IP header followed by the TCP header (with the TCP checksum field 16 bytes into that header). csum_start will be 14+20 = 34 (the TCP checksum includes the header), and csum_offset will be 16. The value in the TCP checksum field should be initialized to the sum of the TCP pseudo header, so that replacing it by the ones' complement checksum of the TCP header and body will give the correct result. [17] Due to various bugs in implementations, this field is not useful as a guarantee of the transport header size. [18] This case is not handled by some older hardware, so is called out specifically in the protocol. [19] Note that the header will be two bytes longer for the VIRTIO_NET_F_MRG_RXBUF case. [20] Obviously each one can be split across multiple descriptor elements. [21] Since there are no guarentees, it can use a hash filter or silently switch to allmulti or promiscuous mode if it is given too many addresses. [23] The FLUSH and FLUSH_OUT types are equivalent, the device does not distinguish between them [24] Because this is high importance and low bandwidth, the current Linux implementation polls for the buffer to be used, rather than waiting for an interrupt, simplifying the implementation significantly. However, for generic serial ports with the O_NONBLOCK flag set, the polling limitation is relaxed and the consumed buffers are freed upon the next write or poll call or when a port is closed or hot-unplugged. [25] This is historical, and independent of the guest page size [26] In this case, deflation advice is merely a courtesy [27] As updates to configuration space are not atomic, this field isn't particularly reliable, but can be used to diagnose buggy guests.