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pub const CLOCK_FREQ: usize = 12500000;
pub const MMIO: &[(usize, usize)] = &[
(0x2000000, 0x10000),
(0xc000000, 0x210000),
(0x10000000, 0x9000),
];
pub type BlockDeviceImpl = crate::drivers::block::VirtIOBlock;
pub type CharDeviceImpl = crate::drivers::chardev::NS16550a<VIRT_UART>;
pub const VIRT_PLIC: usize = 0xC00_0000;
pub const VIRT_UART: usize = 0x1000_0000;
use crate::drivers::block::BLOCK_DEVICE;
use crate::drivers::chardev::{CharDevice, UART};
use crate::drivers::plic::{IntrTargetPriority, PLIC};
pub fn device_init() {
use riscv::register::sie;
let mut plic = unsafe { PLIC::new(VIRT_PLIC) };
let hart_id: usize = 0;
let supervisor = IntrTargetPriority::Supervisor;
let machine = IntrTargetPriority::Machine;
plic.set_threshold(hart_id, supervisor, 0);
plic.set_threshold(hart_id, machine, 1);
for intr_src_id in [1usize, 10] {
plic.enable(hart_id, supervisor, intr_src_id);
plic.set_priority(intr_src_id, 1);
}
unsafe {
sie::set_sext();
}
}
pub fn irq_handler() {
let mut plic = unsafe { PLIC::new(VIRT_PLIC) };
let intr_src_id = plic.claim(0, IntrTargetPriority::Supervisor);
match intr_src_id {
1 => BLOCK_DEVICE.handle_irq(),
10 => UART.handle_irq(),
_ => panic!("unsupported IRQ {}", intr_src_id),
}
plic.complete(0, IntrTargetPriority::Supervisor, intr_src_id);
}
use core::arch::asm;
const EXIT_SUCCESS: u32 = 0x5555;
const EXIT_FAILURE_FLAG: u32 = 0x3333;
const EXIT_FAILURE: u32 = exit_code_encode(1);
const EXIT_RESET: u32 = 0x7777;
pub trait QEMUExit {
fn exit(&self, code: u32) -> !;
fn exit_success(&self) -> !;
fn exit_failure(&self) -> !;
}
pub struct RISCV64 {
addr: u64,
}
const fn exit_code_encode(code: u32) -> u32 {
(code << 16) | EXIT_FAILURE_FLAG
}
impl RISCV64 {
pub const fn new(addr: u64) -> Self {
RISCV64 { addr }
}
}
impl QEMUExit for RISCV64 {
fn exit(&self, code: u32) -> ! {
let code_new = match code {
EXIT_SUCCESS | EXIT_FAILURE | EXIT_RESET => code,
_ => exit_code_encode(code),
};
unsafe {
asm!(
"sw {0}, 0({1})",
in(reg)code_new, in(reg)self.addr
);
loop {
asm!("wfi", options(nomem, nostack));
}
}
}
fn exit_success(&self) -> ! {
self.exit(EXIT_SUCCESS);
}
fn exit_failure(&self) -> ! {
self.exit(EXIT_FAILURE);
}
}
const VIRT_TEST: u64 = 0x100000;
pub const QEMU_EXIT_HANDLE: RISCV64 = RISCV64::new(VIRT_TEST);