zynq-rs/experiments/src/main.rs

223 lines
7.0 KiB
Rust

#![no_std]
#![no_main]
use core::mem::transmute;
use libcortex_a9::mutex::Mutex;
use libboard_zynq::{print, println, self as zynq, clocks::Clocks, clocks::source::{ClockSource, ArmPll, IoPll}};
use libsupport_zynq::{
ram, alloc::{vec, vec::Vec},
boot,
smoltcp::wire::{EthernetAddress, IpAddress, IpCidr},
smoltcp::iface::{NeighborCache, EthernetInterfaceBuilder},
smoltcp::time::Instant,
smoltcp::socket::SocketSet,
smoltcp::socket::{TcpSocket, TcpSocketBuffer},
};
const HWADDR: [u8; 6] = [0, 0x23, 0xde, 0xea, 0xbe, 0xef];
static mut STACK_CORE1: [u32; 512] = [0; 512];
#[no_mangle]
pub fn main_core0() {
// zynq::clocks::CpuClocks::enable_io(1_250_000_000);
println!("\nzc706 main");
{
use libregister::RegisterR;
println!("Boot mode: {:?}", zynq::slcr::RegisterBlock::new().boot_mode.read().boot_mode_pins());
}
#[cfg(feature = "target_zc706")]
const CPU_FREQ: u32 = 800_000_000;
#[cfg(feature = "target_cora_z7_10")]
const CPU_FREQ: u32 = 650_000_000;
println!("Setup clock sources...");
ArmPll::setup(2 * CPU_FREQ);
Clocks::set_cpu_freq(CPU_FREQ);
IoPll::setup(700_000_000);
libboard_zynq::stdio::drop_uart();
println!("PLLs set up");
let clocks = zynq::clocks::Clocks::get();
println!("CPU Clocks: {}/{}/{}/{}", clocks.cpu_6x4x(), clocks.cpu_3x2x(), clocks.cpu_2x(), clocks.cpu_1x());
let mut flash = zynq::flash::Flash::new(200_000_000).linear_addressing_mode();
let flash_ram: &[u8] = unsafe { core::slice::from_raw_parts(flash.ptr(), flash.size()) };
for i in 0..=1 {
print!("Flash {}:", i);
for b in &flash_ram[(i * 16 * 1024 * 1024)..][..128] {
print!(" {:02X}", *b);
}
println!("");
}
let mut flash = flash.stop();
let mut ddr = zynq::ddr::DdrRam::new();
#[cfg(not(feature = "target_zc706"))]
ddr.memtest();
ram::init_alloc(&mut ddr);
for i in 0..=1 {
let mut flash_io = flash.manual_mode(i);
// println!("rdcr={:02X}", flash_io.rdcr());
print!("Flash {} ID:", i);
for b in flash_io.rdid() {
print!(" {:02X}", b);
}
println!("");
print!("Flash {} I/O:", i);
for o in 0..8 {
const CHUNK: u32 = 8;
for b in flash_io.read(CHUNK * o, CHUNK as usize) {
print!(" {:02X}", b);
}
}
println!("");
flash_io.dump("Read cr1", 0x35);
flash_io.dump("Read Autoboot", 0x14);
flash_io.dump("Read Bank", 0x16);
flash_io.dump("DLP Bank", 0x16);
flash_io.dump("Read ESig", 0xAB);
flash_io.dump("OTP Read", 0x4B);
flash_io.dump("DYB Read", 0xE0);
flash_io.dump("PPB Read", 0xE2);
flash_io.dump("ASP Read", 0x2B);
flash_io.dump("Password Read", 0xE7);
flash_io.write_enabled(|flash_io| {
flash_io.erase(0);
});
flash_io.write_enabled(|flash_io| {
flash_io.program(0, [0x23054223; (0x100 >> 2)].iter().cloned());
});
flash = flash_io.stop();
}
let core1_stack = unsafe { &mut STACK_CORE1[..] };
println!("{} bytes stack for core1", core1_stack.len());
let core1 = boot::Core1::start(core1_stack);
for _ in 0..0x1000000 {
let mut l = SHARED.lock();
*l += 1;
}
while !*DONE.lock() {
let x = { *SHARED.lock() };
println!("shared: {:08X}", x);
}
let x = { *SHARED.lock() };
println!("done shared: {:08X}", x);
core1.reset();
libcortex_a9::asm::dsb();
print!("Core1 stack [{:08X}..{:08X}]:", &core1.stack[0] as *const _ as u32, &core1.stack[core1.stack.len() - 1] as *const _ as u32);
for w in core1.stack {
print!(" {:08X}", w);
}
println!(".");
let eth = zynq::eth::Eth::default(HWADDR.clone());
println!("Eth on");
const RX_LEN: usize = 8;
let mut rx_descs = (0..RX_LEN)
.map(|_| zynq::eth::rx::DescEntry::zeroed())
.collect::<Vec<_>>();
let mut rx_buffers = vec![[0u8; zynq::eth::MTU]; RX_LEN];
// Number of transmission buffers (minimum is two because with
// one, duplicate packet transmission occurs)
const TX_LEN: usize = 8;
let mut tx_descs = (0..TX_LEN)
.map(|_| zynq::eth::tx::DescEntry::zeroed())
.collect::<Vec<_>>();
let mut tx_buffers = vec![[0u8; zynq::eth::MTU]; TX_LEN];
let eth = eth.start_rx(&mut rx_descs, &mut rx_buffers);
//let mut eth = eth.start_tx(&mut tx_descs, &mut tx_buffers);
let mut eth = eth.start_tx(
// HACK
unsafe { transmute(tx_descs.as_mut_slice()) },
unsafe { transmute(tx_buffers.as_mut_slice()) },
);
let ethernet_addr = EthernetAddress(HWADDR);
// IP stack
let local_addr = IpAddress::v4(192, 168, 1, 51);
let mut ip_addrs = [IpCidr::new(local_addr, 24)];
let mut neighbor_storage = vec![None; 256];
let neighbor_cache = NeighborCache::new(&mut neighbor_storage[..]);
let mut iface = EthernetInterfaceBuilder::new(&mut eth)
.ethernet_addr(ethernet_addr)
.ip_addrs(&mut ip_addrs[..])
.neighbor_cache(neighbor_cache)
.finalize();
let mut sockets_storage = [
None, None, None, None,
None, None, None, None
];
let mut sockets = SocketSet::new(&mut sockets_storage[..]);
// taken from example code for smoltcp
let mut tcp_server_rx_data = vec![0; 512 * 1024];
let mut tcp_server_tx_data = vec![0; 512 * 1024];
let tcp_rx_buffer = TcpSocketBuffer::new(&mut tcp_server_rx_data[..]);
let tcp_tx_buffer = TcpSocketBuffer::new(&mut tcp_server_tx_data[..]);
let tcp_socket = TcpSocket::new(tcp_rx_buffer, tcp_tx_buffer);
let tcp_handle = sockets.add(tcp_socket);
/// `chargen`
const TCP_PORT: u16 = 19;
let mut time = 0u32;
loop {
time += 1;
let timestamp = Instant::from_millis(time);
match iface.poll(&mut sockets, timestamp) {
Ok(_) => {},
Err(e) => {
println!("poll error: {}", e);
}
}
// (mostly) taken from smoltcp example: TCP echo server
let mut socket = sockets.get::<TcpSocket>(tcp_handle);
if !socket.is_open() {
socket.listen(TCP_PORT).unwrap()
}
if socket.may_recv() && socket.can_send() {
socket.recv(|buf| {
let len = buf.len().min(4096);
let buffer = buf[..len].iter().cloned().collect::<Vec<_>>();
(len, buffer)
})
.and_then(|buffer| socket.send_slice(&buffer[..]))
.map(|_| {})
.unwrap_or_else(|e| println!("tcp: {:?}", e));
}
}
// #[allow(unreachable_code)]
// drop(tx_descs);
// #[allow(unreachable_code)]
// drop(tx_buffers);
}
static SHARED: Mutex<u32> = Mutex::new(0);
static DONE: Mutex<bool> = Mutex::new(false);
#[no_mangle]
pub fn main_core1() {
println!("Hello from core1!");
for _ in 0..0x1000000 {
let mut l = SHARED.lock();
*l += 1;
}
println!("core1 done!");
*DONE.lock() = true;
loop {}
}