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// Copyright 2019 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 super::command_ring_controller::{CommandRingController, CommandRingControllerError};
use super::device_slot::{DeviceSlots, Error as DeviceSlotError};
use super::interrupter::{Error as InterrupterError, Interrupter};
use super::intr_resample_handler::IntrResampleHandler;
use super::ring_buffer_stop_cb::RingBufferStopCallback;
use super::usb_hub::UsbHub;
use super::xhci_backend_device_provider::XhciBackendDeviceProvider;
use super::xhci_regs::*;
use std::fmt::{self, Display};
use std::sync::Arc;
use sync::Mutex;
use sys_util::{EventFd, GuestAddress, GuestMemory};
use usb::host_backend::host_backend_device_provider::HostBackendDeviceProvider;
use utils::{Error as UtilsError, EventLoop, FailHandle};
#[derive(Debug)]
pub enum Error {
StartEventLoop(UtilsError),
GetDeviceSlot(u8),
StartResampleHandler,
SendInterrupt(InterrupterError),
EnableInterrupter(InterrupterError),
SetModeration(InterrupterError),
SetupEventRing(InterrupterError),
SetEventHandlerBusy(InterrupterError),
StartProvider,
RingDoorbell(DeviceSlotError),
CreateCommandRingController(CommandRingControllerError),
}
type Result<T> = std::result::Result<T, Error>;
impl Display for Error {
fn fmt(&self, f: &mut fmt::Formatter) -> fmt::Result {
use self::Error::*;
match self {
StartEventLoop(e) => write!(f, "failed to start event loop: {}", e),
GetDeviceSlot(i) => write!(f, "failed to get device slot: {}", i),
StartResampleHandler => write!(f, "failed to start resample handler"),
SendInterrupt(e) => write!(f, "failed to send interrupter: {}", e),
EnableInterrupter(e) => write!(f, "failed to enable interrupter: {}", e),
SetModeration(e) => write!(f, "failed to set interrupter moderation: {}", e),
SetupEventRing(e) => write!(f, "failed to setup event ring: {}", e),
SetEventHandlerBusy(e) => write!(f, "failed to set event handler busy: {}", e),
StartProvider => write!(f, "failed to start backend provider"),
RingDoorbell(e) => write!(f, "failed to ring doorbell: {}", e),
CreateCommandRingController(e) => {
write!(f, "failed to create command ring controller: {}", e)
}
}
}
}
/// xHCI controller implementation.
pub struct Xhci {
fail_handle: Arc<FailHandle>,
regs: XhciRegs,
interrupter: Arc<Mutex<Interrupter>>,
command_ring_controller: Arc<CommandRingController>,
device_slots: DeviceSlots,
// resample handler and device provider only lives on EventLoop to handle corresponding events.
// By design, event loop only hold weak reference. We need to keep a strong reference here to
// keep it alive.
#[allow(dead_code)]
intr_resample_handler: Arc<IntrResampleHandler>,
#[allow(dead_code)]
device_provider: HostBackendDeviceProvider,
}
impl Xhci {
/// Create a new xHCI controller.
pub fn new(
fail_handle: Arc<FailHandle>,
mem: GuestMemory,
device_provider: HostBackendDeviceProvider,
irq_evt: EventFd,
irq_resample_evt: EventFd,
regs: XhciRegs,
) -> Result<Arc<Self>> {
let (event_loop, _join_handle) =
EventLoop::start(Some(fail_handle.clone())).map_err(Error::StartEventLoop)?;
let interrupter = Arc::new(Mutex::new(Interrupter::new(mem.clone(), irq_evt, ®s)));
let event_loop = Arc::new(event_loop);
let intr_resample_handler =
IntrResampleHandler::start(&event_loop, interrupter.clone(), irq_resample_evt)
.ok_or(Error::StartResampleHandler)?;
let hub = Arc::new(UsbHub::new(®s, interrupter.clone()));
let mut device_provider = device_provider;
device_provider
.start(fail_handle.clone(), event_loop.clone(), hub.clone())
.map_err(|_| Error::StartProvider)?;
let device_slots = DeviceSlots::new(
fail_handle.clone(),
regs.dcbaap.clone(),
hub.clone(),
interrupter.clone(),
event_loop.clone(),
mem.clone(),
);
let command_ring_controller = CommandRingController::new(
mem.clone(),
event_loop.clone(),
device_slots.clone(),
interrupter.clone(),
)
.map_err(Error::CreateCommandRingController)?;
let xhci = Arc::new(Xhci {
fail_handle,
regs,
intr_resample_handler,
interrupter,
command_ring_controller,
device_slots,
device_provider,
});
Self::init_reg_callbacks(&xhci);
Ok(xhci)
}
fn init_reg_callbacks(xhci: &Arc<Xhci>) {
// All the callbacks will hold a weak reference to avoid memory leak. Thos weak upgrade
// should never fail.
let xhci_weak = Arc::downgrade(xhci);
xhci.regs.usbcmd.set_write_cb(move |val: u32| {
// All the weak reference upgrade should never fail. xhci hold reference to the
// registers, callback won't be invoked if xhci is gone.
let xhci = xhci_weak.upgrade().unwrap();
let r = xhci.usbcmd_callback(val);
xhci.handle_register_callback_result(r, 0)
});
let xhci_weak = Arc::downgrade(xhci);
xhci.regs.crcr.set_write_cb(move |val: u64| {
let xhci = xhci_weak.upgrade().unwrap();
let r = xhci.crcr_callback(val);
xhci.handle_register_callback_result(r, 0)
});
for i in 0..xhci.regs.portsc.len() {
let xhci_weak = Arc::downgrade(xhci);
xhci.regs.portsc[i].set_write_cb(move |val: u32| {
let xhci = xhci_weak.upgrade().unwrap();
let r = xhci.portsc_callback(i as u32, val);
xhci.handle_register_callback_result(r, 0)
});
}
for i in 0..xhci.regs.doorbells.len() {
let xhci_weak = Arc::downgrade(xhci);
xhci.regs.doorbells[i].set_write_cb(move |val: u32| {
let xhci = xhci_weak.upgrade().unwrap();
let r = xhci.doorbell_callback(i as u32, val);
xhci.handle_register_callback_result(r, ());
val
});
}
let xhci_weak = Arc::downgrade(xhci);
xhci.regs.iman.set_write_cb(move |val: u32| {
let xhci = xhci_weak.upgrade().unwrap();
let r = xhci.iman_callback(val);
xhci.handle_register_callback_result(r, ());
val
});
let xhci_weak = Arc::downgrade(xhci);
xhci.regs.imod.set_write_cb(move |val: u32| {
let xhci = xhci_weak.upgrade().unwrap();
let r = xhci.imod_callback(val);
xhci.handle_register_callback_result(r, ());
val
});
let xhci_weak = Arc::downgrade(xhci);
xhci.regs.erstsz.set_write_cb(move |val: u32| {
let xhci = xhci_weak.upgrade().unwrap();
let r = xhci.erstsz_callback(val);
xhci.handle_register_callback_result(r, ());
val
});
let xhci_weak = Arc::downgrade(xhci);
xhci.regs.erstba.set_write_cb(move |val: u64| {
let xhci = xhci_weak.upgrade().unwrap();
let r = xhci.erstba_callback(val);
xhci.handle_register_callback_result(r, ());
val
});
let xhci_weak = Arc::downgrade(xhci);
xhci.regs.erdp.set_write_cb(move |val: u64| {
let xhci = xhci_weak.upgrade().unwrap();
let r = xhci.erdp_callback(val);
xhci.handle_register_callback_result(r, ());
val
});
}
fn handle_register_callback_result<T>(&self, r: Result<T>, t: T) -> T {
match r {
Ok(v) => v,
Err(e) => {
error!("xhci controller failed: {}", e);
self.fail_handle.fail();
t
}
}
}
// Callback for usbcmd register write.
fn usbcmd_callback(&self, value: u32) -> Result<u32> {
if (value & USB_CMD_RESET) > 0 {
usb_debug!("xhci_controller: reset controller");
self.reset()?;
return Ok(value & (!USB_CMD_RESET));
}
if (value & USB_CMD_RUNSTOP) > 0 {
usb_debug!("xhci_controller: clear halt bits");
self.regs.usbsts.clear_bits(USB_STS_HALTED);
} else {
usb_debug!("xhci_controller: halt device");
self.halt()?;
self.regs.crcr.clear_bits(CRCR_COMMAND_RING_RUNNING);
}
// Enable interrupter if needed.
let enabled = (value & USB_CMD_INTERRUPTER_ENABLE) > 0
&& (self.regs.iman.get_value() & IMAN_INTERRUPT_ENABLE) > 0;
usb_debug!("xhci_controller: interrupter enable?: {}", enabled);
self.interrupter
.lock()
.set_enabled(enabled)
.map_err(Error::EnableInterrupter)?;
Ok(value)
}
// Callback for crcr register write.
fn crcr_callback(&self, value: u64) -> Result<u64> {
usb_debug!("xhci_controller: write to crcr {:x}", value);
let value = if (self.regs.crcr.get_value() & CRCR_COMMAND_RING_RUNNING) == 0 {
self.command_ring_controller
.set_dequeue_pointer(GuestAddress(value & CRCR_COMMAND_RING_POINTER));
self.command_ring_controller
.set_consumer_cycle_state((value & CRCR_RING_CYCLE_STATE) > 0);
value
} else {
error!("Write to crcr while command ring is running");
self.regs.crcr.get_value()
};
Ok(value)
}
// Callback for portsc register write.
fn portsc_callback(&self, index: u32, value: u32) -> Result<u32> {
let mut value = value;
usb_debug!(
"xhci_controller: write to portsc index {} value {:x}",
index,
value
);
// xHCI spec 4.19.5. Note: we might want to change this logic if we support USB 3.0.
if (value & PORTSC_PORT_RESET) > 0 || (value & PORTSC_WARM_PORT_RESET) > 0 {
// Libusb onlys support blocking call to reset and "usually incurs a noticeable
// delay.". We are faking a reset now.
value &= !PORTSC_PORT_LINK_STATE_MASK;
value &= !PORTSC_PORT_RESET;
value |= PORTSC_PORT_ENABLED;
value |= PORTSC_PORT_RESET_CHANGE;
self.interrupter
.lock()
.send_port_status_change_trb((index + 1) as u8)
.map_err(Error::SendInterrupt)?;
}
Ok(value)
}
// Callback for doorbell register write.
fn doorbell_callback(&self, index: u32, value: u32) -> Result<()> {
usb_debug!(
"xhci_controller: write to doorbell index {} value {:x}",
index,
value
);
let target = (value & DOORBELL_TARGET) as u8;
let stream_id: u16 = (value >> DOORBELL_STREAM_ID_OFFSET) as u16;
if (self.regs.usbcmd.get_value() & USB_CMD_RUNSTOP) > 0 {
// First doorbell is for command ring.
if index == 0 {
if target != 0 || stream_id != 0 {
return Ok(());
}
usb_debug!("doorbell to command ring");
self.regs.crcr.set_bits(CRCR_COMMAND_RING_RUNNING);
self.command_ring_controller.start();
} else {
usb_debug!("doorbell to device slot");
self.device_slots
.slot(index as u8)
.ok_or(Error::GetDeviceSlot(index as u8))?
.ring_doorbell(target, stream_id)
.map_err(Error::RingDoorbell)?;
}
}
Ok(())
}
// Callback for iman register write.
fn iman_callback(&self, value: u32) -> Result<()> {
usb_debug!("xhci_controller: write to iman {:x}", value);
let enabled = ((value & IMAN_INTERRUPT_ENABLE) > 0)
&& ((self.regs.usbcmd.get_value() & USB_CMD_INTERRUPTER_ENABLE) > 0);
self.interrupter
.lock()
.set_enabled(enabled)
.map_err(Error::EnableInterrupter)
}
// Callback for imod register write.
fn imod_callback(&self, value: u32) -> Result<()> {
usb_debug!("xhci_controller: write to imod {:x}", value);
self.interrupter
.lock()
.set_moderation(
(value & IMOD_INTERRUPT_MODERATION_INTERVAL) as u16,
(value >> IMOD_INTERRUPT_MODERATION_COUNTER_OFFSET) as u16,
)
.map_err(Error::SetModeration)
}
// Callback for erstsz register write.
fn erstsz_callback(&self, value: u32) -> Result<()> {
usb_debug!("xhci_controller: write to erstz {:x}", value);
self.interrupter
.lock()
.set_event_ring_seg_table_size((value & ERSTSZ_SEGMENT_TABLE_SIZE) as u16)
.map_err(Error::SetupEventRing)
}
// Callback for erstba register write.
fn erstba_callback(&self, value: u64) -> Result<()> {
usb_debug!("xhci_controller: write to erstba {:x}", value);
self.interrupter
.lock()
.set_event_ring_seg_table_base_addr(GuestAddress(
value & ERSTBA_SEGMENT_TABLE_BASE_ADDRESS,
))
.map_err(Error::SetupEventRing)
}
// Callback for erdp register write.
fn erdp_callback(&self, value: u64) -> Result<()> {
usb_debug!("xhci_controller: write to erdp {:x}", value);
let mut interrupter = self.interrupter.lock();
interrupter
.set_event_ring_dequeue_pointer(GuestAddress(value & ERDP_EVENT_RING_DEQUEUE_POINTER))
.map_err(Error::SetupEventRing)?;
interrupter
.set_event_handler_busy((value & ERDP_EVENT_HANDLER_BUSY) > 0)
.map_err(Error::SetEventHandlerBusy)
}
fn reset(&self) -> Result<()> {
self.regs.usbsts.set_bits(USB_STS_CONTROLLER_NOT_READY);
let usbsts = self.regs.usbsts.clone();
self.device_slots.stop_all_and_reset(move || {
usbsts.clear_bits(USB_STS_CONTROLLER_NOT_READY);
});
Ok(())
}
fn halt(&self) -> Result<()> {
let usbsts = self.regs.usbsts.clone();
self.device_slots
.stop_all(RingBufferStopCallback::new(move || {
usbsts.set_bits(USB_STS_HALTED);
}));
Ok(())
}
}
|