cloud-hypervisor/devices/src/legacy/serial.rs

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// Copyright 2018 Amazon.com, Inc. or its affiliates. All Rights Reserved.
// SPDX-License-Identifier: Apache-2.0
//
// Portions Copyright 2017 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-BSD-3-Clause file.
use crate::BusDevice;
use anyhow::anyhow;
use std::collections::VecDeque;
use std::sync::Arc;
use std::{io, result};
use vm_device::interrupt::InterruptSourceGroup;
use vm_migration::{
Migratable, MigratableError, Pausable, Snapshot, SnapshotDataSection, Snapshottable,
Transportable,
};
use vmm_sys_util::errno::Result;
const LOOP_SIZE: usize = 0x40;
const DATA: u8 = 0;
const IER: u8 = 1;
const IIR: u8 = 2;
const LCR: u8 = 3;
const MCR: u8 = 4;
const LSR: u8 = 5;
const MSR: u8 = 6;
const SCR: u8 = 7;
const DLAB_LOW: u8 = 0;
const DLAB_HIGH: u8 = 1;
const IER_RECV_BIT: u8 = 0x1;
const IER_THR_BIT: u8 = 0x2;
const IER_FIFO_BITS: u8 = 0x0f;
const IIR_FIFO_BITS: u8 = 0xc0;
const IIR_NONE_BIT: u8 = 0x1;
const IIR_THR_BIT: u8 = 0x2;
const IIR_RECV_BIT: u8 = 0x4;
const LCR_DLAB_BIT: u8 = 0x80;
const LSR_DATA_BIT: u8 = 0x1;
const LSR_EMPTY_BIT: u8 = 0x20;
const LSR_IDLE_BIT: u8 = 0x40;
const MCR_LOOP_BIT: u8 = 0x10;
const DEFAULT_INTERRUPT_IDENTIFICATION: u8 = IIR_NONE_BIT; // no pending interrupt
const DEFAULT_LINE_STATUS: u8 = LSR_EMPTY_BIT | LSR_IDLE_BIT; // THR empty and line is idle
const DEFAULT_LINE_CONTROL: u8 = 0x3; // 8-bits per character
const DEFAULT_MODEM_CONTROL: u8 = 0x8; // Auxiliary output 2
const DEFAULT_MODEM_STATUS: u8 = 0x20 | 0x10 | 0x80; // data ready, clear to send, carrier detect
const DEFAULT_BAUD_DIVISOR: u16 = 12; // 9600 bps
/// Emulates serial COM ports commonly seen on x86 I/O ports 0x3f8/0x2f8/0x3e8/0x2e8.
///
/// This can optionally write the guest's output to a Write trait object. To send input to the
/// guest, use `queue_input_bytes`.
pub struct Serial {
id: String,
interrupt_enable: u8,
interrupt_identification: u8,
interrupt: Arc<Box<dyn InterruptSourceGroup>>,
line_control: u8,
line_status: u8,
modem_control: u8,
modem_status: u8,
scratch: u8,
baud_divisor: u16,
in_buffer: VecDeque<u8>,
out: Option<Box<dyn io::Write + Send>>,
}
#[derive(Serialize, Deserialize)]
pub struct SerialState {
interrupt_enable: u8,
interrupt_identification: u8,
line_control: u8,
line_status: u8,
modem_control: u8,
modem_status: u8,
scratch: u8,
baud_divisor: u16,
in_buffer: VecDeque<u8>,
}
impl Serial {
pub fn new(
id: String,
interrupt: Arc<Box<dyn InterruptSourceGroup>>,
out: Option<Box<dyn io::Write + Send>>,
) -> Serial {
Serial {
id,
interrupt_enable: 0,
interrupt_identification: DEFAULT_INTERRUPT_IDENTIFICATION,
interrupt,
line_control: DEFAULT_LINE_CONTROL,
line_status: DEFAULT_LINE_STATUS,
modem_control: DEFAULT_MODEM_CONTROL,
modem_status: DEFAULT_MODEM_STATUS,
scratch: 0,
baud_divisor: DEFAULT_BAUD_DIVISOR,
in_buffer: VecDeque::new(),
out,
}
}
/// Constructs a Serial port ready for output.
pub fn new_out(
id: String,
interrupt: Arc<Box<dyn InterruptSourceGroup>>,
out: Box<dyn io::Write + Send>,
) -> Serial {
Self::new(id, interrupt, Some(out))
}
/// Constructs a Serial port with no connected output.
pub fn new_sink(id: String, interrupt: Arc<Box<dyn InterruptSourceGroup>>) -> Serial {
Self::new(id, interrupt, None)
}
/// Queues raw bytes for the guest to read and signals the interrupt if the line status would
/// change.
pub fn queue_input_bytes(&mut self, c: &[u8]) -> Result<()> {
if !self.is_loop() {
self.in_buffer.extend(c);
self.recv_data()?;
}
Ok(())
}
fn is_dlab_set(&self) -> bool {
(self.line_control & LCR_DLAB_BIT) != 0
}
fn is_recv_intr_enabled(&self) -> bool {
(self.interrupt_enable & IER_RECV_BIT) != 0
}
fn is_thr_intr_enabled(&self) -> bool {
(self.interrupt_enable & IER_THR_BIT) != 0
}
fn is_loop(&self) -> bool {
(self.modem_control & MCR_LOOP_BIT) != 0
}
fn add_intr_bit(&mut self, bit: u8) {
self.interrupt_identification &= !IIR_NONE_BIT;
self.interrupt_identification |= bit;
}
fn del_intr_bit(&mut self, bit: u8) {
self.interrupt_identification &= !bit;
if self.interrupt_identification == 0x0 {
self.interrupt_identification = IIR_NONE_BIT;
}
}
fn thr_empty(&mut self) -> Result<()> {
if self.is_thr_intr_enabled() {
self.add_intr_bit(IIR_THR_BIT);
self.trigger_interrupt()?
}
Ok(())
}
fn recv_data(&mut self) -> Result<()> {
if self.is_recv_intr_enabled() {
self.add_intr_bit(IIR_RECV_BIT);
self.trigger_interrupt()?
}
self.line_status |= LSR_DATA_BIT;
Ok(())
}
fn trigger_interrupt(&mut self) -> result::Result<(), io::Error> {
self.interrupt.trigger(0)
}
fn iir_reset(&mut self) {
self.interrupt_identification = DEFAULT_INTERRUPT_IDENTIFICATION;
}
fn handle_write(&mut self, offset: u8, v: u8) -> Result<()> {
match offset as u8 {
DLAB_LOW if self.is_dlab_set() => {
self.baud_divisor = (self.baud_divisor & 0xff00) | u16::from(v)
}
DLAB_HIGH if self.is_dlab_set() => {
self.baud_divisor = (self.baud_divisor & 0x00ff) | ((u16::from(v)) << 8)
}
DATA => {
if self.is_loop() {
if self.in_buffer.len() < LOOP_SIZE {
self.in_buffer.push_back(v);
self.recv_data()?;
}
} else {
if let Some(out) = self.out.as_mut() {
out.write_all(&[v])?;
out.flush()?;
}
self.thr_empty()?;
}
}
IER => self.interrupt_enable = v & IER_FIFO_BITS,
LCR => self.line_control = v,
MCR => self.modem_control = v,
SCR => self.scratch = v,
_ => {}
}
Ok(())
}
fn state(&self) -> SerialState {
SerialState {
interrupt_enable: self.interrupt_enable,
interrupt_identification: self.interrupt_identification,
line_control: self.line_control,
line_status: self.line_status,
modem_control: self.modem_control,
modem_status: self.modem_status,
scratch: self.scratch,
baud_divisor: self.baud_divisor,
in_buffer: self.in_buffer.clone(),
}
}
fn set_state(&mut self, state: &SerialState) {
self.interrupt_enable = state.interrupt_enable;
self.interrupt_identification = state.interrupt_identification;
self.line_control = state.line_control;
self.line_status = state.line_status;
self.modem_control = state.modem_control;
self.modem_status = state.modem_status;
self.scratch = state.scratch;
self.baud_divisor = state.baud_divisor;
self.in_buffer = state.in_buffer.clone();
}
}
impl BusDevice for Serial {
fn read(&mut self, _base: u64, offset: u64, data: &mut [u8]) {
if data.len() != 1 {
return;
}
data[0] = match offset as u8 {
DLAB_LOW if self.is_dlab_set() => self.baud_divisor as u8,
DLAB_HIGH if self.is_dlab_set() => (self.baud_divisor >> 8) as u8,
DATA => {
self.del_intr_bit(IIR_RECV_BIT);
if self.in_buffer.len() <= 1 {
self.line_status &= !LSR_DATA_BIT;
}
self.in_buffer.pop_front().unwrap_or_default()
}
IER => self.interrupt_enable,
IIR => {
let v = self.interrupt_identification | IIR_FIFO_BITS;
self.iir_reset();
v
}
LCR => self.line_control,
MCR => self.modem_control,
LSR => self.line_status,
MSR => self.modem_status,
SCR => self.scratch,
_ => 0,
};
}
fn write(&mut self, _base: u64, offset: u64, data: &[u8]) {
if data.len() != 1 {
return;
}
if let Err(_e) = self.handle_write(offset as u8, data[0]) {}
}
}
impl Snapshottable for Serial {
fn id(&self) -> String {
self.id.clone()
}
fn snapshot(&mut self) -> std::result::Result<Snapshot, MigratableError> {
let snapshot =
serde_json::to_vec(&self.state()).map_err(|e| MigratableError::Snapshot(e.into()))?;
let mut serial_snapshot = Snapshot::new(self.id.as_str());
serial_snapshot.add_data_section(SnapshotDataSection {
id: format!("{}-section", self.id),
snapshot,
});
Ok(serial_snapshot)
}
fn restore(&mut self, snapshot: Snapshot) -> std::result::Result<(), MigratableError> {
if let Some(serial_section) = snapshot.snapshot_data.get(&format!("{}-section", self.id)) {
let serial_state = match serde_json::from_slice(&serial_section.snapshot) {
Ok(state) => state,
Err(error) => {
return Err(MigratableError::Restore(anyhow!(
"Could not deserialize SERIAL {}",
error
)))
}
};
self.set_state(&serial_state);
return Ok(());
}
Err(MigratableError::Restore(anyhow!(
"Could not find the serial snapshot section"
)))
}
}
impl Pausable for Serial {}
impl Transportable for Serial {}
impl Migratable for Serial {}
#[cfg(test)]
mod tests {
use super::*;
use std::io;
use std::sync::{Arc, Mutex};
use vm_device::interrupt::{InterruptIndex, InterruptSourceConfig};
use vmm_sys_util::eventfd::EventFd;
const SERIAL_NAME: &str = "serial";
struct TestInterrupt {
event_fd: EventFd,
}
impl InterruptSourceGroup for TestInterrupt {
fn trigger(&self, _index: InterruptIndex) -> result::Result<(), std::io::Error> {
self.event_fd.write(1)
}
fn update(
&self,
_index: InterruptIndex,
_config: InterruptSourceConfig,
) -> result::Result<(), std::io::Error> {
Ok(())
}
}
impl TestInterrupt {
fn new(event_fd: EventFd) -> Self {
TestInterrupt { event_fd }
}
}
#[derive(Clone)]
struct SharedBuffer {
buf: Arc<Mutex<Vec<u8>>>,
}
impl SharedBuffer {
fn new() -> SharedBuffer {
SharedBuffer {
buf: Arc::new(Mutex::new(Vec::new())),
}
}
}
impl io::Write for SharedBuffer {
fn write(&mut self, buf: &[u8]) -> io::Result<usize> {
self.buf.lock().unwrap().write(buf)
}
fn flush(&mut self) -> io::Result<()> {
self.buf.lock().unwrap().flush()
}
}
#[test]
fn serial_output() {
let intr_evt = EventFd::new(0).unwrap();
let serial_out = SharedBuffer::new();
let mut serial = Serial::new_out(
String::from(SERIAL_NAME),
Arc::new(Box::new(TestInterrupt::new(intr_evt.try_clone().unwrap()))),
Box::new(serial_out.clone()),
);
serial.write(0, DATA as u64, &['x' as u8, 'y' as u8]);
serial.write(0, DATA as u64, &['a' as u8]);
serial.write(0, DATA as u64, &['b' as u8]);
serial.write(0, DATA as u64, &['c' as u8]);
assert_eq!(
serial_out.buf.lock().unwrap().as_slice(),
&['a' as u8, 'b' as u8, 'c' as u8]
);
}
#[test]
fn serial_input() {
let intr_evt = EventFd::new(0).unwrap();
let serial_out = SharedBuffer::new();
let mut serial = Serial::new_out(
String::from(SERIAL_NAME),
Arc::new(Box::new(TestInterrupt::new(intr_evt.try_clone().unwrap()))),
Box::new(serial_out.clone()),
);
// write 1 to the interrupt event fd, so that read doesn't block in case the event fd
// counter doesn't change (for 0 it blocks)
assert!(intr_evt.write(1).is_ok());
serial.write(0, IER as u64, &[IER_RECV_BIT]);
serial
.queue_input_bytes(&['a' as u8, 'b' as u8, 'c' as u8])
.unwrap();
assert_eq!(intr_evt.read().unwrap(), 2);
// check if reading in a 2-length array doesn't have side effects
let mut data = [0u8, 0u8];
serial.read(0, DATA as u64, &mut data[..]);
assert_eq!(data, [0u8, 0u8]);
let mut data = [0u8];
serial.read(0, LSR as u64, &mut data[..]);
assert_ne!(data[0] & LSR_DATA_BIT, 0);
serial.read(0, DATA as u64, &mut data[..]);
assert_eq!(data[0], 'a' as u8);
serial.read(0, DATA as u64, &mut data[..]);
assert_eq!(data[0], 'b' as u8);
serial.read(0, DATA as u64, &mut data[..]);
assert_eq!(data[0], 'c' as u8);
// check if reading from the largest u8 offset returns 0
serial.read(0, 0xff, &mut data[..]);
assert_eq!(data[0], 0);
}
#[test]
fn serial_thr() {
let intr_evt = EventFd::new(0).unwrap();
let mut serial = Serial::new_sink(
String::from(SERIAL_NAME),
Arc::new(Box::new(TestInterrupt::new(intr_evt.try_clone().unwrap()))),
);
// write 1 to the interrupt event fd, so that read doesn't block in case the event fd
// counter doesn't change (for 0 it blocks)
assert!(intr_evt.write(1).is_ok());
serial.write(0, IER as u64, &[IER_THR_BIT]);
serial.write(0, DATA as u64, &['a' as u8]);
assert_eq!(intr_evt.read().unwrap(), 2);
let mut data = [0u8];
serial.read(0, IER as u64, &mut data[..]);
assert_eq!(data[0] & IER_FIFO_BITS, IER_THR_BIT);
serial.read(0, IIR as u64, &mut data[..]);
assert_ne!(data[0] & IIR_THR_BIT, 0);
}
#[test]
fn serial_dlab() {
let intr_evt = EventFd::new(0).unwrap();
let mut serial = Serial::new_sink(
String::from(SERIAL_NAME),
Arc::new(Box::new(TestInterrupt::new(intr_evt.try_clone().unwrap()))),
);
serial.write(0, LCR as u64, &[LCR_DLAB_BIT as u8]);
serial.write(0, DLAB_LOW as u64, &[0x12 as u8]);
serial.write(0, DLAB_HIGH as u64, &[0x34 as u8]);
let mut data = [0u8];
serial.read(0, LCR as u64, &mut data[..]);
assert_eq!(data[0], LCR_DLAB_BIT as u8);
serial.read(0, DLAB_LOW as u64, &mut data[..]);
assert_eq!(data[0], 0x12);
serial.read(0, DLAB_HIGH as u64, &mut data[..]);
assert_eq!(data[0], 0x34);
}
#[test]
fn serial_modem() {
let intr_evt = EventFd::new(0).unwrap();
let mut serial = Serial::new_sink(
String::from(SERIAL_NAME),
Arc::new(Box::new(TestInterrupt::new(intr_evt.try_clone().unwrap()))),
);
serial.write(0, MCR as u64, &[MCR_LOOP_BIT as u8]);
serial.write(0, DATA as u64, &['a' as u8]);
serial.write(0, DATA as u64, &['b' as u8]);
serial.write(0, DATA as u64, &['c' as u8]);
let mut data = [0u8];
serial.read(0, MSR as u64, &mut data[..]);
assert_eq!(data[0], DEFAULT_MODEM_STATUS as u8);
serial.read(0, MCR as u64, &mut data[..]);
assert_eq!(data[0], MCR_LOOP_BIT as u8);
serial.read(0, DATA as u64, &mut data[..]);
assert_eq!(data[0], 'a' as u8);
serial.read(0, DATA as u64, &mut data[..]);
assert_eq!(data[0], 'b' as u8);
serial.read(0, DATA as u64, &mut data[..]);
assert_eq!(data[0], 'c' as u8);
}
#[test]
fn serial_scratch() {
let intr_evt = EventFd::new(0).unwrap();
let mut serial = Serial::new_sink(
String::from(SERIAL_NAME),
Arc::new(Box::new(TestInterrupt::new(intr_evt.try_clone().unwrap()))),
);
serial.write(0, SCR as u64, &[0x12 as u8]);
let mut data = [0u8];
serial.read(0, SCR as u64, &mut data[..]);
assert_eq!(data[0], 0x12 as u8);
}
}