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/*
* Copyright (c) 2014, 2016-2017 ARM Limited
* All rights reserved
*
* The license below extends only to copyright in the software and shall
* not be construed as granting a license to any other intellectual
* property including but not limited to intellectual property relating
* to a hardware implementation of the functionality of the software
* licensed hereunder. You may use the software subject to the license
* terms below provided that you ensure that this notice is replicated
* unmodified and in its entirety in all distributions of the software,
* modified or unmodified, in source code or in binary form.
*
* Redistribution and use in source and binary forms, with or without
* modification, are permitted provided that the following conditions are
* met: redistributions of source code must retain the above copyright
* notice, this list of conditions and the following disclaimer;
* 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;
* neither the name of the copyright holders 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 THE COPYRIGHT
* OWNER 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.
*
* Authors: Andreas Sandberg
*/
#ifndef __DEV_VIRTIO_BASE_HH__
#define __DEV_VIRTIO_BASE_HH__
#include "arch/isa_traits.hh"
#include "base/bitunion.hh"
#include "base/callback.hh"
#include "dev/virtio/virtio_ring.h"
#include "mem/port_proxy.hh"
#include "sim/sim_object.hh"
struct VirtIODeviceBaseParams;
struct VirtIODummyDeviceParams;
class VirtQueue;
/** @{
* @name VirtIO endian conversion helpers
*
* VirtIO prior to version 1.0 (legacy versions) normally send values
* to the host in the guest systems native byte order. This is going
* to change in version 1.0 which mandates little endian. We currently
* only support the legacy version of VirtIO (the new and shiny
* standard is still in a draft state and not implemented by the
* kernel). Once we support the new standard, we should negotiate the
* VirtIO version with the guest and automatically use the right type
* of byte swapping.
*/
/** Convert legacy VirtIO endianness to host endianness. */
template <typename T> inline T
vtoh_legacy(T v) {
return TheISA::gtoh(v);
}
/** Convert host endianness to legacy VirtIO endianness. */
template <typename T> inline T
htov_legacy(T v) {
return TheISA::htog(v);
}
template <> inline vring_used_elem
vtoh_legacy(vring_used_elem v) {
v.id = vtoh_legacy(v.id);
v.len = vtoh_legacy(v.len);
return v;
}
template <> inline vring_used_elem
htov_legacy(vring_used_elem v) {
v.id = htov_legacy(v.id);
v.len = htov_legacy(v.len);
return v;
}
template <> inline vring_desc
vtoh_legacy(vring_desc v) {
v.addr = vtoh_legacy(v.addr);
v.len = vtoh_legacy(v.len);
v.flags = vtoh_legacy(v.flags);
v.next = vtoh_legacy(v.next);
return v;
}
template <> inline vring_desc
htov_legacy(vring_desc v) {
v.addr = htov_legacy(v.addr);
v.len = htov_legacy(v.len);
v.flags = htov_legacy(v.flags);
v.next = htov_legacy(v.next);
return v;
}
/** @} */
/**
* VirtIO descriptor (chain) wrapper
*
* Communication in VirtIO takes place by sending and receiving chains
* of so called descriptors using device queues. The queue is
* responsible for sending a descriptor chain from the guest to the
* host and later sending it back to the guest. The descriptor chain
* itself can be thought of as a linked list of buffers (descriptors)
* that are read only (isIncoming() is true) or write only
* (isOutgoing() is true). A single chain may contain any mix of input
* and output buffers.
*
* The descriptor wrapper is normally <i>only</i> instantiated by the
* virtqueue wrapper (VirtQueue) and should never be instantiated in
* device models. The VirtQueue also ensures that the descriptor
* wrapper is re-populated with new data from the guest by calling
* updateChain() whenever a new descriptor chain is passed to the host
* (VirtQueue::consumeDescriptor()). The updateChain() method
* automatically does some sanity checks on the descriptor chain to
* detect loops.
*/
class VirtDescriptor
{
public:
/** Descriptor index in virtqueue */
typedef uint16_t Index;
/** @{
* @name VirtIO Descriptor <-> Queue Interface
*/
/**
* Create a descriptor wrapper.
*
* @param memProxy Proxy to the guest physical memory.
* @param queue Queue owning this descriptor.
* @param index Index within the queue.
*/
VirtDescriptor(PortProxy &memProxy, VirtQueue &queue, Index index);
// WORKAROUND: The noexcept declaration works around a bug where
// gcc 4.7 tries to call the wrong constructor when emplacing
// something into a vector.
VirtDescriptor(VirtDescriptor &&other) noexcept;
~VirtDescriptor() noexcept;
VirtDescriptor &operator=(VirtDescriptor &&rhs) noexcept;
/** Get the descriptor's index into the virtqueue. */
Index index() const { return _index; }
/** Populate this descriptor with data from the guest. */
void update();
/** Populate this descriptor chain with data from the guest. */
void updateChain();
/** @} */
/** @{
* @name Debug interfaces
*/
/**
* Dump the contents of a descriptor
*/
void dump() const;
/**
* Dump the contents of a descriptor chain starting at this
* descriptor.
*/
void dumpChain() const;
/** @} */
/** @{
* @name Device Model Interfaces
*/
/**
* Read the contents of a descriptor.
*
* This method copies the contents of a descriptor into a buffer
* within gem5. Devices should typically use chainRead() instead
* as it automatically follows the descriptor chain to read the
* desired number of bytes.
*
* @see chainRead
*
* @param offset Offset into the descriptor.
* @param dst Destination buffer.
* @param size Amount of data to read (in bytes).
*/
void read(size_t offset, uint8_t *dst, size_t size) const;
/**
* Write to the contents of a descriptor.
*
* This method copies the contents of a descriptor into a buffer
* within gem5. Devices should typically use chainWrite() instead
* as it automatically follows the descriptor chain to read the
* desired number of bytes.
*
* @see chainWrite
*
* @param offset Offset into the descriptor.
* @param src Source buffer.
* @param size Amount of data to read (in bytes).
*/
void write(size_t offset, const uint8_t *src, size_t size);
/**
* Retrieve the size of this descriptor.
*
* This method gets the size of a single descriptor. For incoming
* data, it corresponds to the amount of data that can be read
* from the descriptor. For outgoing data, it corresponds to the
* amount of data that can be written to it.
*
* @see chainSize
*
* @return Size of descriptor in bytes.
*/
size_t size() const { return desc.len; }
/**
* Is this descriptor chained to another descriptor?
*
* @return true if there is a next pointer, false otherwise.
*/
bool hasNext() const { return desc.flags & VRING_DESC_F_NEXT; }
/**
* Get the pointer to the next descriptor in a chain.
*
* @return Pointer to the next descriptor or NULL if this is the
* last element in a chain.
*/
VirtDescriptor *next() const;
/** Check if this is a read-only descriptor (incoming data). */
bool isIncoming() const { return !isOutgoing(); }
/** Check if this is a write-only descriptor (outgoing data). */
bool isOutgoing() const { return desc.flags & VRING_DESC_F_WRITE; }
/**
* Read the contents of a descriptor chain.
*
* This method reads the specified number of bytes from a
* descriptor chain starting at the this descriptor plus an offset
* in bytes. The method automatically follows the links in the
* descriptor chain.
*
* @param offset Offset into the chain (in bytes).
* @param dst Pointer to destination buffer.
* @param size Size (in bytes).
*/
void chainRead(size_t offset, uint8_t *dst, size_t size) const;
/**
* Write to a descriptor chain.
*
* This method writes the specified number of bytes to a
* descriptor chain starting at the this descriptor plus an offset
* in bytes. The method automatically follows the links in the
* descriptor chain.
*
* @param offset Offset into the chain (in bytes).
* @param src Pointer to source buffer.
* @param size Size (in bytes).
*/
void chainWrite(size_t offset, const uint8_t *src, size_t size);
/**
* Retrieve the size of this descriptor chain.
*
* This method gets the size of a descriptor chain starting at
* this descriptor.
*
* @return Size of descriptor chain in bytes.
*/
size_t chainSize() const;
/** @} */
private:
// Remove default constructor
VirtDescriptor();
// Prevent copying
VirtDescriptor(const VirtDescriptor &other);
/** Pointer to memory proxy */
PortProxy *memProxy;
/** Pointer to virtqueue owning this descriptor */
VirtQueue *queue;
/** Index in virtqueue */
Index _index;
/** Underlying descriptor */
vring_desc desc;
};
/**
* Base wrapper around a virtqueue.
*
* VirtIO device models typically need to extend this class to
* implement their own device queues.
*
* @note Queues must be registered with
* VirtIODeviceBase::registerQueue() to be active.
*/
class VirtQueue : public Serializable {
public:
virtual ~VirtQueue() {};
/** @{
* @name Checkpointing Interface
*/
void serialize(CheckpointOut &cp) const override;
void unserialize(CheckpointIn &cp) override;
/** @{
* @name Low-level Device Interface
*/
/**
* Set the base address of this queue.
*
* @param address Guest physical base address of the queue.
*/
void setAddress(Addr address);
/**
* Get the guest physical address of this queue.
*
* @return Physical address in guest where this queue resides.
*/
Addr getAddress() const { return _address; }
/**
* Get the number of descriptors available in this queue.
*
* @return Size of queue in descriptors.
*/
uint16_t getSize() const { return _size; }
/**
* Get a pointer to a specific descriptor in the queue.
*
* @note This interfaces is normally only used by VirtDescriptor
* to follow descriptor chains. Device models typically don't need
* to use it.
*
* @return Pointer to a VirtDescriptor.
*/
VirtDescriptor *getDescriptor(VirtDescriptor::Index index) {
return &descriptors[index];
}
/** @} */
/** @{
* @name Device Model Interfaces
*/
/**
* Get an incoming descriptor chain from the queue.
*
* @return Pointer to descriptor on success, NULL if no pending
* descriptors are available.
*/
VirtDescriptor *consumeDescriptor();
/**
* Send a descriptor chain to the guest.
*
* This method posts a descriptor chain to the guest after a
* device model has finished processing it. The device model
* typically needs to call VirtIODeviceBase::kick() to deliver
* notify tell the guest that the queue has been updated.
*
* @note The desc parameter must refer to the first descriptor in
* a chain that has been retrieved using consumeDescriptor().
*
* @note The len parameter specified the amount of data produced
* by the device model. It seems to be ignored by Linux and it is
* not well defined.
*
* @param desc Start of descriptor chain.
* @param len Length of the produced data.
*/
void produceDescriptor(VirtDescriptor *desc, uint32_t len);
/** @} */
/** @{
* @name Device Model Callbacks
*/
/**
* Notify queue of pending events.
*
* This method is called by VirtIODeviceBase::onNotify() to notify
* the device model of pending data in a virtqueue. The default
* implementation of this method iterates over the available
* descriptor chains and calls onNotifyDescriptor() for every new
* incoming chain.
*
* Device models should normally overload one of onNotify() and
* onNotifyDescriptor().
*/
virtual void onNotify();
/**
* Notify queue of pending incoming descriptor.
*
* This method is called by the default implementation of
* onNotify() to notify the device model of pending data in a
* descriptor chain.
*
* Device models should normally overload one of onNotify() and
* onNotifyDescriptor().
*/
virtual void onNotifyDescriptor(VirtDescriptor *desc) {};
/** @} */
/** @{
* @name Debug interfaces
*/
/** Dump the contents of a queue */
void dump() const;
/** @} */
/** @{ */
/**
* Page size used by VirtIO.\ It's hard-coded to 4096 bytes in
* the spec for historical reasons.
*/
static const Addr ALIGN_BITS = 12;
static const Addr ALIGN_SIZE = 1 << ALIGN_BITS;
/** @} */
protected:
/**
* Instantiate a new virtqueue.
*
* Instantiate a virtqueue with a fixed size. The size is
* specified in descriptors which are defined as 4096 bytes each.
*
* @param proxy Proxy to the guest physical memory.
* @param size Size in descriptors/pages.
*/
VirtQueue(PortProxy &proxy, uint16_t size);
private:
VirtQueue();
/** Queue size in terms of number of descriptors */
const uint16_t _size;
/** Base address of the queue */
Addr _address;
/** Guest physical memory proxy */
PortProxy &memProxy;
private:
/**
* VirtIO ring buffer wrapper.
*
* This class wraps a VirtIO ring buffer. The template parameter T
* is used to select the data type for the items in the ring (used
* or available descriptors).
*/
template<typename T>
class VirtRing
{
public:
typedef uint16_t Flags;
typedef uint16_t Index;
struct Header {
Flags flags;
Index index;
} M5_ATTR_PACKED;
VirtRing<T>(PortProxy &proxy, uint16_t size)
: header{0, 0}, ring(size), _proxy(proxy), _base(0) {}
/**
* Set the base address of the VirtIO ring buffer.
*
* @param addr New host physical address
*/
void setAddress(Addr addr) { _base = addr; }
/** Update the ring buffer header with data from the guest. */
void readHeader() {
assert(_base != 0);
_proxy.readBlob(_base, &header, sizeof(header));
header.flags = vtoh_legacy(header.flags);
header.index = vtoh_legacy(header.index);
}
void writeHeader() {
Header out;
assert(_base != 0);
out.flags = htov_legacy(header.flags);
out.index = htov_legacy(header.index);
_proxy.writeBlob(_base, &out, sizeof(out));
}
void read() {
readHeader();
/* Read and byte-swap the elements in the ring */
T temp[ring.size()];
_proxy.readBlob(_base + sizeof(header),
temp, sizeof(T) * ring.size());
for (int i = 0; i < ring.size(); ++i)
ring[i] = vtoh_legacy(temp[i]);
}
void write() {
assert(_base != 0);
/* Create a byte-swapped copy of the ring and write it to
* guest memory. */
T temp[ring.size()];
for (int i = 0; i < ring.size(); ++i)
temp[i] = htov_legacy(ring[i]);
_proxy.writeBlob(_base + sizeof(header),
temp, sizeof(T) * ring.size());
writeHeader();
}
/** Ring buffer header in host byte order */
Header header;
/** Elements in ring in host byte order */
std::vector<T> ring;
private:
// Remove default constructor
VirtRing<T>();
/** Guest physical memory proxy */
PortProxy &_proxy;
/** Guest physical base address of the ring buffer */
Addr _base;
};
/** Ring of available (incoming) descriptors */
VirtRing<VirtDescriptor::Index> avail;
/** Ring of used (outgoing) descriptors */
VirtRing<struct vring_used_elem> used;
/** Offset of last consumed descriptor in the VirtQueue::avail
* ring */
uint16_t _last_avail;
/** Vector of pre-created descriptors indexed by their index into
* the queue. */
std::vector<VirtDescriptor> descriptors;
};
/**
* Base class for all VirtIO-based devices.
*
* This class implements the functionality of the VirtIO 0.9.5
* specification. This version of VirtIO is also known as "legacy" in
* the VirtIO 1.0 specification from OASIS.
*
* @see https://github.com/rustyrussell/virtio-spec
* @see http://docs.oasis-open.org/virtio/virtio/v1.0/virtio-v1.0.html
*/
class VirtIODeviceBase : public SimObject
{
public:
typedef uint16_t QueueID;
typedef uint32_t FeatureBits;
/** This is a VirtQueue address as exposed through the low-level
* interface.\ The address needs to be multiplied by the page size
* (seems to be hardcoded to 4096 in the spec) to get the real
* physical address.
*/
typedef uint16_t VirtAddress;
/** Device Type (sometimes known as subsystem ID) */
typedef uint16_t DeviceId;
BitUnion8(DeviceStatus)
Bitfield<7> failed;
Bitfield<2> driver_ok;
Bitfield<1> driver;
Bitfield<0> acknowledge;
EndBitUnion(DeviceStatus)
typedef VirtIODeviceBaseParams Params;
VirtIODeviceBase(Params *params, DeviceId id, size_t config_size,
FeatureBits features);
virtual ~VirtIODeviceBase();
public:
/** @{
* @name SimObject Interfaces
*/
void serialize(CheckpointOut &cp) const override;
void unserialize(CheckpointIn &cp) override;
/** @} */
protected:
/** @{
* @name Device Model Interfaces
*/
/**
* Inform the guest of available buffers.
*
* When a device model has finished processing incoming buffers
* (after onNotify has been called), it typically needs to inform
* the guest that there are new pending outgoing buffers. The
* method used to inform the guest is transport dependent, but is
* typically through an interrupt. Device models call this method
* to tell the transport interface to notify the guest.
*/
void kick() {
assert(transKick);
transKick->process();
};
/**
* Register a new VirtQueue with the device model.
*
* Devices typically register at least one VirtQueue to use for
* communication with the guest. This <i>must</i> be done from the
* constructor since the number of queues are assumed to be
* constant throughout the lifetime of the device.
*
* @warning This method may only be called from the device model
* constructor.
*/
void registerQueue(VirtQueue &queue);
/**
* Feature set accepted by the guest.
*
* When the guest starts the driver for the device, it starts by
* negotiating features. The device first offers a set of features
* (see deviceFeatures), the driver then notifies the device of
* which features it accepted. The base class will automatically
* accept any feature set that is a subset of the features offered
* by the device.
*/
FeatureBits guestFeatures;
/** @} */
public:
/** @{
* @name Optional VirtIO Interfaces
*/
/**
* Read from the configuration space of a device.
*
* This method is called by the transport interface to read data
* from a device model's configuration space. The device model
* should use the cfgOffset parameter as the offset into its
* configuration space.
*
* @warning The address in the packet should not be used to
* determine the offset into a device's configuration space.
*
* @param pkt Read request packet.
* @param cfgOffset Offset into the device's configuration space.
*/
virtual void readConfig(PacketPtr pkt, Addr cfgOffset);
/**
* Write to the configuration space of a device.
*
* This method is called by the transport interface to write data
* into a device model's configuration space. The device model
* should use the cfgOffset parameter as the offset into its
* configuration space.
*
* @warning The address in the packet should not be used to
* determine the offset into a device's configuration space.
*
* @param pkt Write request packet.
* @param cfgOffset Offset into the device's configuration space.
*/
virtual void writeConfig(PacketPtr pkt, Addr cfgOffset);
/**
* Driver-request device reset.
*
* The device driver may reset a device by writing zero to the
* device status register (using setDeviceStatus()), which causes
* this method to be called. Device models overriding this method
* <i>must</i> ensure that the reset method of the base class is
* called when the device is reset.
*
* @note Always call the reset method of the base class from
* device-specific reset methods.
*/
virtual void reset();
/** @} */
protected:
/** @{
* @name Device Model Helpers
*/
/**
* Read configuration data from a device structure.
*
* @param pkt Read request packet.
* @param cfgOffset Offset into the device's configuration space.
* @param cfg Device configuration
*/
void readConfigBlob(PacketPtr pkt, Addr cfgOffset, const uint8_t *cfg);
/**
* Write configuration data to a device structure.
*
* @param pkt Write request packet.
* @param cfgOffset Offset into the device's configuration space.
* @param cfg Device configuration
*/
void writeConfigBlob(PacketPtr pkt, Addr cfgOffset, uint8_t *cfg);
/** @} */
public:
/** @{
* @name VirtIO Transport Interfaces
*/
/**
* Register a callback to kick the guest through the transport
* interface.
*
* @param c Callback into transport interface.
*/
void registerKickCallback(Callback *c) {
assert(!transKick);
transKick = c;
}
/**
* Driver is requesting service.
*
* This method is called by the underlying hardware interface
* (e.g., PciVirtIO or MmmioVirtIO) to notify a device of pending
* incoming descriptors.
*
* @param index ID of the queue with pending actions.
*/
void onNotify(QueueID index);
/**
* Change currently active queue.
*
* The transport interface works on a queue at a time. The
* currently active queue is decided by the value of the queue
* select field in a device.
*
* @param idx ID of the queue to select.
*/
void setQueueSelect(QueueID idx) { _queueSelect = idx; }
/**
* Get the currently active queue.
*
* The transport interface works on a queue at a time. The
* currently active queue is decided by the value of the queue
* select field in a device.
*
* @return The ID of the currently active queue.
*/
QueueID getQueueSelect() const { return _queueSelect; }
/**
* Change the host physical address of the currently active queue.
*
* @note The new address is specified in multiples of the page
* size (fixed to 4096 bytes in the standard). For example, if the
* address 10 is selected, the actual host physical address will
* be 40960.
*
* @see setQueueSelect
* @see getQueueSelect
*
* @param address New address of the currently active queue (in
* pages).
*/
void setQueueAddress(uint32_t address);
/**
* Get the host physical address of the currently active queue.
*
* @note The new address is specified in multiples of the page
* size (fixed to 4096 bytes in the standard). For example, if the
* address 10 is selected, the actual host physical address will
* be 40960.
*
* @see setQueueSelect
* @see getQueueSelect
*
* @return Address of the currently active queue (in pages).
*/
uint32_t getQueueAddress() const;
/**
* Get the size (descriptors) of the currently active queue.
*
* @return Size of the currently active queue in number of
* descriptors.
*/
uint16_t getQueueSize() const { return getCurrentQueue().getSize(); }
/**
* Update device status and optionally reset device.
*
* The special device status of 0 is used to reset the device by
* calling reset().
*
* @param status New device status.
*/
void setDeviceStatus(DeviceStatus status);
/**
* Retrieve the device status.
*
* @return Device status.
*/
DeviceStatus getDeviceStatus() const { return _deviceStatus; }
/**
* Set feature bits accepted by the guest driver.
*
* This enables a subset of the features offered by the device
* model through the getGuestFeatures() interface.
*/
void setGuestFeatures(FeatureBits features);
/**
* Get features accepted by the guest driver.
*
* @return Currently active features.
*/
FeatureBits getGuestFeatures() const { return guestFeatures; }
/** Device ID (sometimes known as subsystem ID) */
const DeviceId deviceId;
/** Size of the device's configuration space */
const size_t configSize;
/** Feature set offered by the device */
const FeatureBits deviceFeatures;
/** @} */
private:
/** Convenience method to get the currently selected queue */
const VirtQueue &getCurrentQueue() const;
/** Convenience method to get the currently selected queue */
VirtQueue &getCurrentQueue();
/**
* Status of the device
*
* @see getDeviceStatus
* @see setDeviceStatus
*/
DeviceStatus _deviceStatus;
/** Queue select register (set by guest) */
QueueID _queueSelect;
/** List of virtual queues supported by this device */
std::vector<VirtQueue *> _queues;
/** Callbacks to kick the guest through the transport layer */
Callback *transKick;
};
class VirtIODummyDevice : public VirtIODeviceBase
{
public:
VirtIODummyDevice(VirtIODummyDeviceParams *params);
protected:
/** VirtIO device ID */
static const DeviceId ID_INVALID = 0x00;
};
#endif // __DEV_VIRTIO_BASE_HH__