devices/src/virtio/virtio_pci_common_config.rs - platform/external/crosvm - Git at Google

 // Copyright 2018 The Chromium OS Authors. All rights reserved.
 // Use of this source code is governed by a BSD-style license that can be
 // found in the LICENSE file.

 use std::convert::TryInto;

 use base::warn;
 use vm_memory::GuestAddress;

 use super::*;

 /// Contains the data for reading and writing the common configuration structure of a virtio PCI
 /// device.
 ///
 /// * Registers:
 /// ** About the whole device.
 /// le32 device_feature_select;     // read-write
 /// le32 device_feature;            // read-only for driver
 /// le32 driver_feature_select;     // read-write
 /// le32 driver_feature;            // read-write
 /// le16 msix_config;               // read-write
 /// le16 num_queues;                // read-only for driver
 /// u8 device_status;               // read-write (driver_status)
 /// u8 config_generation;           // read-only for driver
 /// ** 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 (Ready)
 /// le16 queue_notify_off;          // read-only for driver
 /// le64 queue_desc;                // read-write
 /// le64 queue_avail;               // read-write
 /// le64 queue_used;                // read-write
 pub struct VirtioPciCommonConfig {
     pub driver_status: u8,
     pub config_generation: u8,
     pub device_feature_select: u32,
     pub driver_feature_select: u32,
     pub queue_select: u16,
     pub msix_config: u16,
 }

 impl VirtioPciCommonConfig {
     pub fn read(
         &mut self,
         offset: u64,
         data: &mut [u8],
         queues: &mut [Queue],
         device: &mut dyn VirtioDevice,
     ) {
         match data.len() {
             1 => {
                 let v = self.read_common_config_byte(offset);
                 data[0] = v;
             }
             2 => {
                 let v = self.read_common_config_word(offset, queues);
                 data.copy_from_slice(&v.to_le_bytes());
             }
             4 => {
                 let v = self.read_common_config_dword(offset, device);
                 data.copy_from_slice(&v.to_le_bytes());
             }
             8 => {
                 let v = self.read_common_config_qword(offset);
                 data.copy_from_slice(&v.to_le_bytes());
             }
             _ => (),
         }
     }

     pub fn write(
         &mut self,
         offset: u64,
         data: &[u8],
         queues: &mut [Queue],
         device: &mut dyn VirtioDevice,
     ) {
         match data.len() {
             1 => self.write_common_config_byte(offset, data[0]),
             2 => self.write_common_config_word(
                 offset,
                 // This unwrap (and those below) cannot fail since data.len() is checked.
                 u16::from_le_bytes(data.try_into().unwrap()),
                 queues,
             ),
             4 => self.write_common_config_dword(
                 offset,
                 u32::from_le_bytes(data.try_into().unwrap()),
                 queues,
                 device,
             ),
             8 => self.write_common_config_qword(
                 offset,
                 u64::from_le_bytes(data.try_into().unwrap()),
                 queues,
             ),
             _ => (),
         }
     }

     fn read_common_config_byte(&self, offset: u64) -> u8 {
         // The driver is only allowed to do aligned, properly sized access.
         match offset {
             0x14 => self.driver_status,
             0x15 => self.config_generation,
             _ => 0,
         }
     }

     fn write_common_config_byte(&mut self, offset: u64, value: u8) {
         match offset {
             0x14 => self.driver_status = value,
             _ => {
                 warn!("invalid virtio config byt access: 0x{:x}", offset);
             }
         }
     }

     fn read_common_config_word(&self, offset: u64, queues: &[Queue]) -> u16 {
         match offset {
             0x10 => self.msix_config,
             0x12 => queues.len() as u16, // num_queues
             0x16 => self.queue_select,
             0x18 => self.with_queue(queues, |q| q.size).unwrap_or(0),
             0x1a => self.with_queue(queues, |q| q.vector).unwrap_or(0),
             0x1c => {
                 if self.with_queue(queues, |q| q.ready).unwrap_or(false) {
                     1
                 } else {
                     0
                 }
             }
             0x1e => self.queue_select, // notify_off
             _ => 0,
         }
     }

     fn write_common_config_word(&mut self, offset: u64, value: u16, queues: &mut [Queue]) {
         match offset {
             0x10 => self.msix_config = value,
             0x16 => self.queue_select = value,
             0x18 => self.with_queue_mut(queues, |q| q.size = value),
             0x1a => self.with_queue_mut(queues, |q| q.vector = value),
             0x1c => self.with_queue_mut(queues, |q| q.ready = value == 1),
             _ => {
                 warn!("invalid virtio register word write: 0x{:x}", offset);
             }
         }
     }

     fn read_common_config_dword(&self, offset: u64, device: &dyn VirtioDevice) -> u32 {
         match offset {
             0x00 => self.device_feature_select,
             0x04 => {
                 // Only 64 bits of features (2 pages) are defined for now, so limit
                 // device_feature_select to avoid shifting by 64 or more bits.
                 if self.device_feature_select < 2 {
                     (device.features() >> (self.device_feature_select * 32)) as u32
                 } else {
                     0
                 }
             }
             0x08 => self.driver_feature_select,
             _ => 0,
         }
     }

     fn write_common_config_dword(
         &mut self,
         offset: u64,
         value: u32,
         queues: &mut [Queue],
         device: &mut dyn VirtioDevice,
     ) {
         fn hi(v: &mut GuestAddress, x: u32) {
             *v = (*v & 0xffffffff) | ((x as u64) << 32)
         }

         fn lo(v: &mut GuestAddress, x: u32) {
             *v = (*v & !0xffffffff) | (x as u64)
         }

         match offset {
             0x00 => self.device_feature_select = value,
             0x08 => self.driver_feature_select = value,
             0x0c => {
                 if self.driver_feature_select < 2 {
                     let features: u64 = (value as u64) << (self.driver_feature_select * 32);
                     device.ack_features(features);
                     for queue in queues.iter_mut() {
                         queue.ack_features(features);
                     }
                 } else {
                     warn!(
                         "invalid ack_features (page {}, value 0x{:x})",
                         self.driver_feature_select, value
                     );
                 }
             }
             0x20 => self.with_queue_mut(queues, |q| lo(&mut q.desc_table, value)),
             0x24 => self.with_queue_mut(queues, |q| hi(&mut q.desc_table, value)),
             0x28 => self.with_queue_mut(queues, |q| lo(&mut q.avail_ring, value)),
             0x2c => self.with_queue_mut(queues, |q| hi(&mut q.avail_ring, value)),
             0x30 => self.with_queue_mut(queues, |q| lo(&mut q.used_ring, value)),
             0x34 => self.with_queue_mut(queues, |q| hi(&mut q.used_ring, value)),
             _ => {
                 warn!("invalid virtio register dword write: 0x{:x}", offset);
             }
         }
     }

     fn read_common_config_qword(&self, _offset: u64) -> u64 {
         0 // Assume the guest has no reason to read write-only registers.
     }

     fn write_common_config_qword(&mut self, offset: u64, value: u64, queues: &mut [Queue]) {
         match offset {
             0x20 => self.with_queue_mut(queues, |q| q.desc_table = GuestAddress(value)),
             0x28 => self.with_queue_mut(queues, |q| q.avail_ring = GuestAddress(value)),
             0x30 => self.with_queue_mut(queues, |q| q.used_ring = GuestAddress(value)),
             _ => {
                 warn!("invalid virtio register qword write: 0x{:x}", offset);
             }
         }
     }

     fn with_queue<U, F>(&self, queues: &[Queue], f: F) -> Option<U>
     where
         F: FnOnce(&Queue) -> U,
     {
         queues.get(self.queue_select as usize).map(f)
     }

     fn with_queue_mut<F: FnOnce(&mut Queue)>(&self, queues: &mut [Queue], f: F) {
         if let Some(queue) = queues.get_mut(self.queue_select as usize) {
             f(queue);
         }
     }
 }

 #[cfg(test)]
 mod tests {
     use super::*;

     use base::Event;
     use std::os::unix::io::RawFd;
     use vm_memory::GuestMemory;

     struct DummyDevice(u32);
     const QUEUE_SIZE: u16 = 256;
     const QUEUE_SIZES: &'static [u16] = &[QUEUE_SIZE];
     const DUMMY_FEATURES: u64 = 0x5555_aaaa;
     impl VirtioDevice for DummyDevice {
         fn keep_fds(&self) -> Vec<RawFd> {
             Vec::new()
         }
         fn device_type(&self) -> u32 {
             return self.0;
         }
         fn queue_max_sizes(&self) -> &[u16] {
             QUEUE_SIZES
         }
         fn activate(
             &mut self,
             _mem: GuestMemory,
             _interrupt: Interrupt,
             _queues: Vec<Queue>,
             _queue_evts: Vec<Event>,
         ) {
         }
         fn features(&self) -> u64 {
             DUMMY_FEATURES
         }
     }

     #[test]
     fn write_base_regs() {
         let mut regs = VirtioPciCommonConfig {
             driver_status: 0xaa,
             config_generation: 0x55,
             device_feature_select: 0x0,
             driver_feature_select: 0x0,
             queue_select: 0xff,
             msix_config: 0x00,
         };

         let dev = &mut DummyDevice(0) as &mut dyn VirtioDevice;
         let mut queues = Vec::new();

         // Can set all bits of driver_status.
         regs.write(0x14, &[0x55], &mut queues, dev);
         let mut read_back = vec![0x00];
         regs.read(0x14, &mut read_back, &mut queues, dev);
         assert_eq!(read_back[0], 0x55);

         // The config generation register is read only.
         regs.write(0x15, &[0xaa], &mut queues, dev);
         let mut read_back = vec![0x00];
         regs.read(0x15, &mut read_back, &mut queues, dev);
         assert_eq!(read_back[0], 0x55);

         // Device features is read-only and passed through from the device.
         regs.write(0x04, &[0, 0, 0, 0], &mut queues, dev);
         let mut read_back = [0u8; 4];
         regs.read(0x04, &mut read_back, &mut queues, dev);
         assert_eq!(u32::from_le_bytes(read_back), DUMMY_FEATURES as u32);

         // Feature select registers are read/write.
         regs.write(0x00, &[1, 2, 3, 4], &mut queues, dev);
         let mut read_back = [0u8; 4];
         regs.read(0x00, &mut read_back, &mut queues, dev);
         assert_eq!(u32::from_le_bytes(read_back), 0x0403_0201);
         regs.write(0x08, &[1, 2, 3, 4], &mut queues, dev);
         let mut read_back = [0u8; 4];
         regs.read(0x08, &mut read_back, &mut queues, dev);
         assert_eq!(u32::from_le_bytes(read_back), 0x0403_0201);

         // 'queue_select' can be read and written.
         regs.write(0x16, &[0xaa, 0x55], &mut queues, dev);
         let mut read_back = vec![0x00, 0x00];
         regs.read(0x16, &mut read_back, &mut queues, dev);
         assert_eq!(read_back[0], 0xaa);
         assert_eq!(read_back[1], 0x55);
     }
 }
	// Copyright 2018 The Chromium OS Authors. All rights reserved.
	// Use of this source code is governed by a BSD-style license that can be
	// found in the LICENSE file.

	use std::convert::TryInto;

	use base::warn;
	use vm_memory::GuestAddress;

	use super::*;

	/// Contains the data for reading and writing the common configuration structure of a virtio PCI
	/// device.
	///
	/// * Registers:
	/// ** About the whole device.
	/// le32 device_feature_select; // read-write
	/// le32 device_feature; // read-only for driver
	/// le32 driver_feature_select; // read-write
	/// le32 driver_feature; // read-write
	/// le16 msix_config; // read-write
	/// le16 num_queues; // read-only for driver
	/// u8 device_status; // read-write (driver_status)
	/// u8 config_generation; // read-only for driver
	/// ** 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 (Ready)
	/// le16 queue_notify_off; // read-only for driver
	/// le64 queue_desc; // read-write
	/// le64 queue_avail; // read-write
	/// le64 queue_used; // read-write
	pub struct VirtioPciCommonConfig {
	pub driver_status: u8,
	pub config_generation: u8,
	pub device_feature_select: u32,
	pub driver_feature_select: u32,
	pub queue_select: u16,
	pub msix_config: u16,
	}

	impl VirtioPciCommonConfig {
	pub fn read(
	&mut self,
	offset: u64,
	data: &mut [u8],
	queues: &mut [Queue],
	device: &mut dyn VirtioDevice,
	) {
	match data.len() {
	1 => {
	let v = self.read_common_config_byte(offset);
	data[0] = v;
	}
	2 => {
	let v = self.read_common_config_word(offset, queues);
	data.copy_from_slice(&v.to_le_bytes());
	}
	4 => {
	let v = self.read_common_config_dword(offset, device);
	data.copy_from_slice(&v.to_le_bytes());
	}
	8 => {
	let v = self.read_common_config_qword(offset);
	data.copy_from_slice(&v.to_le_bytes());
	}
	_ => (),
	}
	}

	pub fn write(
	&mut self,
	offset: u64,
	data: &[u8],
	queues: &mut [Queue],
	device: &mut dyn VirtioDevice,
	) {
	match data.len() {
	1 => self.write_common_config_byte(offset, data[0]),
	2 => self.write_common_config_word(
	offset,
	// This unwrap (and those below) cannot fail since data.len() is checked.
	u16::from_le_bytes(data.try_into().unwrap()),
	queues,
	),
	4 => self.write_common_config_dword(
	offset,
	u32::from_le_bytes(data.try_into().unwrap()),
	queues,
	device,
	),
	8 => self.write_common_config_qword(
	offset,
	u64::from_le_bytes(data.try_into().unwrap()),
	queues,
	),
	_ => (),
	}
	}

	fn read_common_config_byte(&self, offset: u64) -> u8 {
	// The driver is only allowed to do aligned, properly sized access.
	match offset {
	0x14 => self.driver_status,
	0x15 => self.config_generation,
	_ => 0,
	}
	}

	fn write_common_config_byte(&mut self, offset: u64, value: u8) {
	match offset {
	0x14 => self.driver_status = value,
	_ => {
	warn!("invalid virtio config byt access: 0x{:x}", offset);
	}
	}
	}

	fn read_common_config_word(&self, offset: u64, queues: &[Queue]) -> u16 {
	match offset {
	0x10 => self.msix_config,
	0x12 => queues.len() as u16, // num_queues
	0x16 => self.queue_select,
	0x18 => self.with_queue(queues, \|q\| q.size).unwrap_or(0),
	0x1a => self.with_queue(queues, \|q\| q.vector).unwrap_or(0),
	0x1c => {
	if self.with_queue(queues, \|q\| q.ready).unwrap_or(false) {
	1
	} else {
	0
	}
	}
	0x1e => self.queue_select, // notify_off
	_ => 0,
	}
	}

	fn write_common_config_word(&mut self, offset: u64, value: u16, queues: &mut [Queue]) {
	match offset {
	0x10 => self.msix_config = value,
	0x16 => self.queue_select = value,
	0x18 => self.with_queue_mut(queues, \|q\| q.size = value),
	0x1a => self.with_queue_mut(queues, \|q\| q.vector = value),
	0x1c => self.with_queue_mut(queues, \|q\| q.ready = value == 1),
	_ => {
	warn!("invalid virtio register word write: 0x{:x}", offset);
	}
	}
	}

	fn read_common_config_dword(&self, offset: u64, device: &dyn VirtioDevice) -> u32 {
	match offset {
	0x00 => self.device_feature_select,
	0x04 => {
	// Only 64 bits of features (2 pages) are defined for now, so limit
	// device_feature_select to avoid shifting by 64 or more bits.
	if self.device_feature_select < 2 {
	(device.features() >> (self.device_feature_select * 32)) as u32
	} else {
	0
	}
	}
	0x08 => self.driver_feature_select,
	_ => 0,
	}
	}

	fn write_common_config_dword(
	&mut self,
	offset: u64,
	value: u32,
	queues: &mut [Queue],
	device: &mut dyn VirtioDevice,
	) {
	fn hi(v: &mut GuestAddress, x: u32) {
	v = (v & 0xffffffff) \| ((x as u64) << 32)
	}

	fn lo(v: &mut GuestAddress, x: u32) {
	v = (v & !0xffffffff) \| (x as u64)
	}

	match offset {
	0x00 => self.device_feature_select = value,
	0x08 => self.driver_feature_select = value,
	0x0c => {
	if self.driver_feature_select < 2 {
	let features: u64 = (value as u64) << (self.driver_feature_select * 32);
	device.ack_features(features);
	for queue in queues.iter_mut() {
	queue.ack_features(features);
	}
	} else {
	warn!(
	"invalid ack_features (page {}, value 0x{:x})",
	self.driver_feature_select, value
	);
	}
	}
	0x20 => self.with_queue_mut(queues, \|q\| lo(&mut q.desc_table, value)),
	0x24 => self.with_queue_mut(queues, \|q\| hi(&mut q.desc_table, value)),
	0x28 => self.with_queue_mut(queues, \|q\| lo(&mut q.avail_ring, value)),
	0x2c => self.with_queue_mut(queues, \|q\| hi(&mut q.avail_ring, value)),
	0x30 => self.with_queue_mut(queues, \|q\| lo(&mut q.used_ring, value)),
	0x34 => self.with_queue_mut(queues, \|q\| hi(&mut q.used_ring, value)),
	_ => {
	warn!("invalid virtio register dword write: 0x{:x}", offset);
	}
	}
	}

	fn read_common_config_qword(&self, _offset: u64) -> u64 {
	0 // Assume the guest has no reason to read write-only registers.
	}

	fn write_common_config_qword(&mut self, offset: u64, value: u64, queues: &mut [Queue]) {
	match offset {
	0x20 => self.with_queue_mut(queues, \|q\| q.desc_table = GuestAddress(value)),
	0x28 => self.with_queue_mut(queues, \|q\| q.avail_ring = GuestAddress(value)),
	0x30 => self.with_queue_mut(queues, \|q\| q.used_ring = GuestAddress(value)),
	_ => {
	warn!("invalid virtio register qword write: 0x{:x}", offset);
	}
	}
	}

	fn with_queue<U, F>(&self, queues: &[Queue], f: F) -> Option<U>
	where
	F: FnOnce(&Queue) -> U,
	{
	queues.get(self.queue_select as usize).map(f)
	}

	fn with_queue_mut<F: FnOnce(&mut Queue)>(&self, queues: &mut [Queue], f: F) {
	if let Some(queue) = queues.get_mut(self.queue_select as usize) {
	f(queue);
	}
	}
	}

	#[cfg(test)]
	mod tests {
	use super::*;

	use base::Event;
	use std::os::unix::io::RawFd;
	use vm_memory::GuestMemory;

	struct DummyDevice(u32);
	const QUEUE_SIZE: u16 = 256;
	const QUEUE_SIZES: &'static [u16] = &[QUEUE_SIZE];
	const DUMMY_FEATURES: u64 = 0x5555_aaaa;
	impl VirtioDevice for DummyDevice {
	fn keep_fds(&self) -> Vec<RawFd> {
	Vec::new()
	}
	fn device_type(&self) -> u32 {
	return self.0;
	}
	fn queue_max_sizes(&self) -> &[u16] {
	QUEUE_SIZES
	}
	fn activate(
	&mut self,
	_mem: GuestMemory,
	_interrupt: Interrupt,
	_queues: Vec<Queue>,
	_queue_evts: Vec<Event>,
	) {
	}
	fn features(&self) -> u64 {
	DUMMY_FEATURES
	}
	}

	#[test]
	fn write_base_regs() {
	let mut regs = VirtioPciCommonConfig {
	driver_status: 0xaa,
	config_generation: 0x55,
	device_feature_select: 0x0,
	driver_feature_select: 0x0,
	queue_select: 0xff,
	msix_config: 0x00,
	};

	let dev = &mut DummyDevice(0) as &mut dyn VirtioDevice;
	let mut queues = Vec::new();

	// Can set all bits of driver_status.
	regs.write(0x14, &[0x55], &mut queues, dev);
	let mut read_back = vec![0x00];
	regs.read(0x14, &mut read_back, &mut queues, dev);
	assert_eq!(read_back[0], 0x55);

	// The config generation register is read only.
	regs.write(0x15, &[0xaa], &mut queues, dev);
	let mut read_back = vec![0x00];
	regs.read(0x15, &mut read_back, &mut queues, dev);
	assert_eq!(read_back[0], 0x55);

	// Device features is read-only and passed through from the device.
	regs.write(0x04, &[0, 0, 0, 0], &mut queues, dev);
	let mut read_back = [0u8; 4];
	regs.read(0x04, &mut read_back, &mut queues, dev);
	assert_eq!(u32::from_le_bytes(read_back), DUMMY_FEATURES as u32);

	// Feature select registers are read/write.
	regs.write(0x00, &[1, 2, 3, 4], &mut queues, dev);
	let mut read_back = [0u8; 4];
	regs.read(0x00, &mut read_back, &mut queues, dev);
	assert_eq!(u32::from_le_bytes(read_back), 0x0403_0201);
	regs.write(0x08, &[1, 2, 3, 4], &mut queues, dev);
	let mut read_back = [0u8; 4];
	regs.read(0x08, &mut read_back, &mut queues, dev);
	assert_eq!(u32::from_le_bytes(read_back), 0x0403_0201);

	// 'queue_select' can be read and written.
	regs.write(0x16, &[0xaa, 0x55], &mut queues, dev);
	let mut read_back = vec![0x00, 0x00];
	regs.read(0x16, &mut read_back, &mut queues, dev);
	assert_eq!(read_back[0], 0xaa);
	assert_eq!(read_back[1], 0x55);
	}
	}