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osblog/risc_v/ch6/src/uart.rs
2020-02-03 10:33:00 +08:00

130 lines
3.9 KiB
Rust
Executable File

// uart.rs
// UART routines and driver
use core::{convert::TryInto,
fmt::{Error, Write}};
pub struct Uart {
base_address: usize,
}
impl Write for Uart {
fn write_str(&mut self, out: &str) -> Result<(), Error> {
for c in out.bytes() {
self.put(c);
}
Ok(())
}
}
impl Uart {
pub fn new(base_address: usize) -> Self {
Uart { base_address }
}
pub fn init(&mut self) {
let ptr = self.base_address as *mut u8;
unsafe {
// First, set the word length, which
// are bits 0 and 1 of the line control register (LCR)
// which is at base_address + 3
// We can easily write the value 3 here or 0b11, but I'm
// extending it so that it is clear we're setting two
// individual fields
// Word 0 Word 1
// ~~~~~~ ~~~~~~
let lcr: u8 = (1 << 0) | (1 << 1);
ptr.add(3).write_volatile(lcr);
// Now, enable the FIFO, which is bit index 0 of the
// FIFO control register (FCR at offset 2).
// Again, we can just write 1 here, but when we use left
// shift, it's easier to see that we're trying to write
// bit index #0.
ptr.add(2).write_volatile(1 << 0);
// Enable receiver buffer interrupts, which is at bit
// index 0 of the interrupt enable register (IER at
// offset 1).
ptr.add(1).write_volatile(1 << 0);
// If we cared about the divisor, the code below would
// set the divisor from a global clock rate of 22.729
// MHz (22,729,000 cycles per second) to a signaling
// rate of 2400 (BAUD). We usually have much faster
// signalling rates nowadays, but this demonstrates what
// the divisor actually does. The formula given in the
// NS16500A specification for calculating the divisor
// is:
// divisor = ceil( (clock_hz) / (baud_sps x 16) )
// So, we substitute our values and get:
// divisor = ceil( 22_729_000 / (2400 x 16) )
// divisor = ceil( 22_729_000 / 38_400 )
// divisor = ceil( 591.901 ) = 592
// The divisor register is two bytes (16 bits), so we
// need to split the value 592 into two bytes.
// Typically, we would calculate this based on measuring
// the clock rate, but again, for our purposes [qemu],
// this doesn't really do anything.
let divisor: u16 = 592;
let divisor_least: u8 =
(divisor & 0xff).try_into().unwrap();
let divisor_most: u8 =
(divisor >> 8).try_into().unwrap();
// Notice that the divisor register DLL (divisor latch
// least) and DLM (divisor latch most) have the same
// base address as the receiver/transmitter and the
// interrupt enable register. To change what the base
// address points to, we open the "divisor latch" by
// writing 1 into the Divisor Latch Access Bit (DLAB),
// which is bit index 7 of the Line Control Register
// (LCR) which is at base_address + 3.
ptr.add(3).write_volatile(lcr | 1 << 7);
// Now, base addresses 0 and 1 point to DLL and DLM,
// respectively. Put the lower 8 bits of the divisor
// into DLL
ptr.add(0).write_volatile(divisor_least);
ptr.add(1).write_volatile(divisor_most);
// Now that we've written the divisor, we never have to
// touch this again. In hardware, this will divide the
// global clock (22.729 MHz) into one suitable for 2,400
// signals per second. So, to once again get access to
// the RBR/THR/IER registers, we need to close the DLAB
// bit by clearing it to 0.
ptr.add(3).write_volatile(lcr);
}
}
pub fn put(&mut self, c: u8) {
let ptr = self.base_address as *mut u8;
loop {
// Wait until previous data is flushed
if unsafe { ptr.add(5).read_volatile() } & (1 << 5) != 0 {
break;
}
}
unsafe {
// Write data
ptr.add(0).write_volatile(c);
}
}
pub fn get(&mut self) -> Option<u8> {
let ptr = self.base_address as *mut u8;
unsafe {
if ptr.add(5).read_volatile() & 1 == 0 {
// The DR bit is 0, meaning no data
None
}
else {
// The DR bit is 1, meaning data!
Some(ptr.add(0).read_volatile())
}
}
}
}