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No commits in common. "ecdb1146792c782c431f9c642a05d4fa1814b34e" and "6616489a5eebbffdb343baddd5cf4ca5ab874ec5" have entirely different histories.

18 changed files with 377 additions and 668 deletions

1
.gitignore vendored
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@ -5,4 +5,3 @@ Cargo.lock
target/ target/
**/build **/build
**/__pycache__ **/__pycache__
itm.fifo

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@ -6,26 +6,28 @@ name = "firmware"
version = "0.1.0" version = "0.1.0"
[dependencies] [dependencies]
cortex-m-semihosting = "0.3.3"
panic-halt = "0.2.0" panic-halt = "0.2.0"
cortex-m = "0.6.2" cortex-m = "0.6.2"
cortex-m-rt = "0.6.12" cortex-m-rt = "0.6.12"
embedded-hal = "0.2.4" embedded-hal = "0.2.4"
stm32h7xx-hal = {version = "0.7.1", features = [ "stm32h743v", "rt", "unproven", "ethernet", "phy_lan8742a" ] } stm32h7xx-hal = {version = "0.7.1", features = [ "stm32h743v", "rt", "unproven", "ethernet", "phy_lan8742a" ] }
smoltcp = { version = "0.6.0", default-features = false, features = [ "ethernet", "proto-ipv4", "proto-ipv6", "socket-tcp", "log" ] } smoltcp = { version = "0.6.0", default-features = false, features = [ "ethernet", "proto-ipv4", "proto-ipv6", "socket-tcp" ] }
nb = "1.0.0" nb = "1.0.0"
lexical-core = { version="0.7.1", features=["radix"], default-features=false }
libm = "0.2.0"
embedded-nal = "0.1.0" embedded-nal = "0.1.0"
minimq = "0.1.0" minimq = "0.1.0"
enum-iterator = "0.6.0"
heapless = "0.5.5" heapless = "0.5.5"
generic-array = "0.14.3"
# Logging and Panicking # Logging and Panicking
panic-itm = "0.4.1" panic-itm = "0.4.1"
panic-semihosting = { version = "0.5.3", features = [ "exit" ] } panic-semihosting = { version = "0.5.3", features = [ "exit" ] }
cortex-m-rtic = "0.5.3" cortex-m-rtic = "0.5.3"
cortex-m-log = { version = "0.6.2", features = [ "itm", "log-integration", "semihosting" ] } cortex-m-log = { version = "~0.6", features = [ "itm" ] }
cortex-m-semihosting = "0.3.3"
log = {version = "0.4.11"}
lazy_static = { version = "1.4.0", features = ["spin_no_std"] }
[dependencies.scpi] [dependencies.scpi]
git = "https://github.com/occheung/scpi-rs" git = "https://github.com/occheung/scpi-rs"

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@ -4,8 +4,8 @@
// extern crate cortex_m_rt as rt; // extern crate cortex_m_rt as rt;
use core::sync::atomic::{AtomicU32, Ordering}; use core::sync::atomic::{AtomicU32, Ordering};
#[macro_use] //#[macro_use]
extern crate log; //extern crate log;
// extern crate cortex_m; // extern crate cortex_m;
use panic_semihosting as _; use panic_semihosting as _;
@ -33,6 +33,8 @@ use stm32h7xx_hal::rcc::CoreClocks;
use stm32h7xx_hal::{pac, prelude::*, spi, stm32, stm32::interrupt}; use stm32h7xx_hal::{pac, prelude::*, spi, stm32, stm32::interrupt};
use Speed::*; use Speed::*;
use libm::round;
use core::{ use core::{
str, str,
fmt::Write fmt::Write
@ -46,7 +48,6 @@ use smoltcp::iface::{NeighborCache, EthernetInterfaceBuilder, Routes};
use smoltcp::socket::SocketSet; use smoltcp::socket::SocketSet;
use smoltcp::socket::{SocketHandle, TcpSocket, TcpSocketBuffer}; use smoltcp::socket::{SocketHandle, TcpSocket, TcpSocketBuffer};
use smoltcp::time::{Duration, Instant}; use smoltcp::time::{Duration, Instant};
// use smoltcp::log;
// Use embedded-nal to access smoltcp // Use embedded-nal to access smoltcp
use embedded_nal::TcpStack; use embedded_nal::TcpStack;
@ -100,9 +101,6 @@ use scpi::{
scpi_system, scpi_system,
}; };
#[path = "util/logger.rs"]
mod logger;
/// Configure SYSTICK for 1ms timebase /// Configure SYSTICK for 1ms timebase
fn systick_init(syst: &mut stm32::SYST, clocks: CoreClocks) { fn systick_init(syst: &mut stm32::SYST, clocks: CoreClocks) {
let c_ck_mhz = clocks.c_ck().0 / 1_000_000; let c_ck_mhz = clocks.c_ck().0 / 1_000_000;
@ -140,8 +138,6 @@ const BUFFER_SIZE: usize = 2048;
#[entry] #[entry]
fn main() -> ! { fn main() -> ! {
logger::semihosting_init();
let mut cp = cortex_m::Peripherals::take().unwrap(); let mut cp = cortex_m::Peripherals::take().unwrap();
let dp = pac::Peripherals::take().unwrap(); let dp = pac::Peripherals::take().unwrap();
@ -167,6 +163,8 @@ fn main() -> ! {
// Initialise system... // Initialise system...
cp.SCB.invalidate_icache(); cp.SCB.invalidate_icache();
cp.SCB.enable_icache(); cp.SCB.enable_icache();
// TODO: ETH DMA coherence issues
// cp.SCB.enable_dcache(&mut cp.CPUID);
cp.DWT.enable_cycle_counter(); cp.DWT.enable_cycle_counter();
// Initialise IO... // Initialise IO...
@ -177,15 +175,21 @@ fn main() -> ! {
let gpioe = dp.GPIOE.split(ccdr.peripheral.GPIOE); let gpioe = dp.GPIOE.split(ccdr.peripheral.GPIOE);
let gpiof = dp.GPIOF.split(ccdr.peripheral.GPIOF); let gpiof = dp.GPIOF.split(ccdr.peripheral.GPIOF);
let gpiog = dp.GPIOG.split(ccdr.peripheral.GPIOG); let gpiog = dp.GPIOG.split(ccdr.peripheral.GPIOG);
// let mut link_led = gpiob.pb0.into_push_pull_output(); // LED1, green
// let mut status_led = gpioe.pe1.into_push_pull_output(); // LD2, yellow
// let mut listen_led = gpiob.pb14.into_push_pull_output(); // LD3, red
// link_led.set_low().ok();
// status_led.set_low().ok();
// listen_led.set_low().ok();
// Setup CDONE for checking // Setup CDONE for checking
let fpga_cdone = gpiod.pd15.into_pull_up_input(); let fpga_cdone = gpiod.pd15.into_pull_up_input();
match fpga_cdone.is_high() { match fpga_cdone.is_high() {
Ok(true) => debug!("FPGA is ready."), Ok(true) => hprintln!("FPGA is ready."),
Ok(_) => debug!("FPGA is in reset state."), Ok(_) => hprintln!("FPGA is in reset state."),
Err(_) => debug!("Error: Cannot read C_DONE"), Err(_) => hprintln!("Error: Cannot read C_DONE"),
}; }.unwrap();
// Setup Urukul // Setup Urukul
/* /*
@ -275,11 +279,18 @@ fn main() -> ! {
let mut neighbor_storage = [None; 16]; let mut neighbor_storage = [None; 16];
let neighbor_cache = NeighborCache::new(&mut neighbor_storage[..]); let neighbor_cache = NeighborCache::new(&mut neighbor_storage[..]);
// Routes
let default_v4_gw = Ipv4Address::new(192, 168, 1, 1);
let mut routes_storage = [None; 8];
let mut routes = Routes::new(&mut routes_storage[..]);
routes.add_default_ipv4_route(default_v4_gw).unwrap();
// Device? _eth_dma, as it implements phy::device // Device? _eth_dma, as it implements phy::device
let mut iface = EthernetInterfaceBuilder::new(_eth_dma) let mut iface = EthernetInterfaceBuilder::new(_eth_dma)
.ethernet_addr(mac_addr) .ethernet_addr(mac_addr)
.neighbor_cache(neighbor_cache) .neighbor_cache(neighbor_cache)
.ip_addrs(&mut ip_addrs[..]) .ip_addrs(&mut ip_addrs[..])
.routes(routes)
.finalize(); .finalize();
// SCPI configs // SCPI configs
@ -343,6 +354,9 @@ fn main() -> ! {
let mut eth_up = false; let mut eth_up = false;
// Record activeness of silent socket, init as false
let mut silent_socket_active = false;
loop { loop {
let _time = TIME.load(Ordering::Relaxed); let _time = TIME.load(Ordering::Relaxed);
let eth_last = eth_up; let eth_last = eth_up;
@ -374,9 +388,9 @@ fn main() -> ! {
} }
let result = context.run(data, &mut buf); let result = context.run(data, &mut buf);
if let Err(err) = result { if let Err(err) = result {
writeln!(socket, "{}", str::from_utf8(err.get_message()).unwrap()).unwrap(); writeln!(socket, "{}", str::from_utf8(err.get_message()).unwrap());
} else { } else {
write!(socket, "{}", str::from_utf8(buf.as_slice()).unwrap()).unwrap(); write!(socket, "{}", str::from_utf8(buf.as_slice()).unwrap());
} }
} }
} }

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@ -1,9 +1,6 @@
#![no_std] #![no_std]
#![no_main] #![no_main]
#[macro_use]
extern crate log;
use smoltcp as net; use smoltcp as net;
use stm32h7xx_hal::ethernet; use stm32h7xx_hal::ethernet;
use stm32h7xx_hal::{gpio::Speed, prelude::*, spi, pac}; use stm32h7xx_hal::{gpio::Speed, prelude::*, spi, pac};
@ -21,7 +18,7 @@ use cortex_m_rt::{
}; };
use cortex_m_semihosting::hprintln; use cortex_m_semihosting::hprintln;
// use panic_halt as _; use panic_halt as _;
use rtic::cyccnt::{Instant, U32Ext}; use rtic::cyccnt::{Instant, U32Ext};
@ -34,9 +31,6 @@ use firmware::nal_tcp_client::{NetworkStack, NetStorage, NetworkInterface};
use firmware::{Urukul}; use firmware::{Urukul};
use firmware::cpld::{CPLD}; use firmware::cpld::{CPLD};
#[path = "util/logger.rs"]
mod logger;
static mut NET_STORE: NetStorage = NetStorage { static mut NET_STORE: NetStorage = NetStorage {
// Placeholder for the real IP address, which is initialized at runtime. // Placeholder for the real IP address, which is initialized at runtime.
ip_addrs: [net::wire::IpCidr::Ipv6( ip_addrs: [net::wire::IpCidr::Ipv6(
@ -67,8 +61,6 @@ macro_rules! add_socket {
#[entry] #[entry]
fn main() -> ! { fn main() -> ! {
// logger::semihosting_init();
let mut cp = cortex_m::Peripherals::take().unwrap(); let mut cp = cortex_m::Peripherals::take().unwrap();
let dp = pac::Peripherals::take().unwrap(); let dp = pac::Peripherals::take().unwrap();
@ -76,15 +68,12 @@ fn main() -> ! {
// Enable SRAM3 for the descriptor ring. // Enable SRAM3 for the descriptor ring.
dp.RCC.ahb2enr.modify(|_, w| w.sram3en().set_bit()); dp.RCC.ahb2enr.modify(|_, w| w.sram3en().set_bit());
// Reset RCC clock
dp.RCC.rsr.write(|w| w.rmvf().set_bit());
let rcc = dp.RCC.constrain();
let pwr = dp.PWR.constrain(); let pwr = dp.PWR.constrain();
let vos = pwr.freeze(); let vos = pwr.freeze();
let rcc = dp.RCC.constrain();
let ccdr = rcc let ccdr = rcc
.use_hse(16.mhz())
.sysclk(400.mhz()) .sysclk(400.mhz())
.hclk(200.mhz()) .hclk(200.mhz())
.per_ck(100.mhz()) .per_ck(100.mhz())
@ -93,8 +82,6 @@ fn main() -> ! {
.pll2_q_ck(100.mhz()) .pll2_q_ck(100.mhz())
.freeze(vos, &dp.SYSCFG); .freeze(vos, &dp.SYSCFG);
let mut delay = cp.SYST.delay(ccdr.clocks);
let gpioa = dp.GPIOA.split(ccdr.peripheral.GPIOA); let gpioa = dp.GPIOA.split(ccdr.peripheral.GPIOA);
let gpiob = dp.GPIOB.split(ccdr.peripheral.GPIOB); let gpiob = dp.GPIOB.split(ccdr.peripheral.GPIOB);
let gpioc = dp.GPIOC.split(ccdr.peripheral.GPIOC); let gpioc = dp.GPIOC.split(ccdr.peripheral.GPIOC);
@ -107,8 +94,6 @@ fn main() -> ! {
yellow_led.set_low().unwrap(); yellow_led.set_low().unwrap();
let mut red_led = gpiob.pb14.into_push_pull_output(); let mut red_led = gpiob.pb14.into_push_pull_output();
red_led.set_high().unwrap(); red_led.set_high().unwrap();
let mut green_led = gpiob.pb0.into_push_pull_output();
green_led.set_low().unwrap();
// Configure ethernet IO // Configure ethernet IO
{ {
@ -192,9 +177,6 @@ fn main() -> ! {
cp.SCB.invalidate_icache(); cp.SCB.invalidate_icache();
cp.SCB.enable_icache(); cp.SCB.enable_icache();
// cp.SCB.clean_dcache(&mut cp.CPUID);
// cp.SCB.disable_dcache(&mut cp.CPUID);
// cp.SCB.enable_dcache(&mut cp.CPUID);
let mut time: u32 = 0; let mut time: u32 = 0;
let mut next_ms = Instant::now(); let mut next_ms = Instant::now();
@ -213,27 +195,7 @@ fn main() -> ! {
) )
.unwrap(); .unwrap();
delay.delay_ms(1000_u16);
client.network_stack.update(time);
green_led.set_high().unwrap();
loop { loop {
let tick = Instant::now() > next_ms;
if tick {
next_ms += 400_000.cycles();
time += 1;
}
client.network_stack.update(time);
client
.poll(|_client, topic, message, _properties| match topic {
_ => info!("On '{:?}', received: {:?}", topic, message),
})
.unwrap();
match client.is_connected() { match client.is_connected() {
true => { true => {
yellow_led.set_high().unwrap(); yellow_led.set_high().unwrap();
@ -245,6 +207,19 @@ fn main() -> ! {
}, },
}; };
client
.poll(|_client, topic, message, _properties| match topic {
_ => hprintln!("On '{:?}', received: {:?}", topic, message).unwrap(),
})
.unwrap();
let tick = Instant::now() > next_ms;
if tick {
next_ms += 400_000.cycles();
time += 1;
}
if tick && (time % 1000) == 0 { if tick && (time % 1000) == 0 {
client client
.publish("nucleo", "Hello, World!".as_bytes(), QoS::AtMostOnce, &[]) .publish("nucleo", "Hello, World!".as_bytes(), QoS::AtMostOnce, &[])
@ -252,10 +227,10 @@ fn main() -> ! {
} }
// Update the TCP stack. // Update the TCP stack.
// let sleep = client.network_stack.update(time); let sleep = client.network_stack.update(time);
// if sleep { if sleep {
// //cortex_m::asm::wfi(); //cortex_m::asm::wfi();
// cortex_m::asm::nop(); cortex_m::asm::nop();
// } }
} }
} }

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@ -1,98 +1,133 @@
#![no_std]
#![no_main] #![no_main]
#![no_std]
#[macro_use]
extern crate log;
#[macro_use]
extern crate lazy_static;
use smoltcp as net;
use stm32h7xx_hal::ethernet;
use stm32h7xx_hal::{gpio::Speed, prelude::*, spi, pac};
use embedded_hal::{
blocking::spi::Transfer,
digital::v2::OutputPin,
};
use core::sync::atomic::{AtomicU32, Ordering}; use core::sync::atomic::{AtomicU32, Ordering};
use core::fmt::Write;
use core::str;
// use heapless::{consts, String}; // extern crate cortex_m;
use panic_semihosting as _;
use cortex_m; use cortex_m;
use cortex_m::iprintln; use cortex_m::asm::nop;
use cortex_m_rt::{ use cortex_m_rt::{
entry, entry,
exception, exception,
}; };
// use cortex_m_semihosting::hprintln; use cortex_m_semihosting::hprintln;
// use panic_halt as _; extern crate smoltcp;
use rtic::cyccnt::{Instant, U32Ext}; use stm32h7xx_hal::ethernet;
use stm32h7xx_hal::gpio::Speed;
use log::info; use stm32h7xx_hal::hal::digital::v2::{
use log::debug; OutputPin,
use log::trace; InputPin,
use nb::block;
use minimq::{
embedded_nal::{IpAddr, Ipv4Addr, TcpStack, SocketAddr, Mode},
MqttClient, QoS,
}; };
use stm32h7xx_hal::rcc::CoreClocks;
use stm32h7xx_hal::{pac, prelude::*, spi, stm32, stm32::interrupt};
use Speed::*;
use firmware::nal_tcp_client::{NetworkStack, NetStorage, NetworkInterface}; use libm::round;
use firmware::{Urukul};
use firmware::cpld::{CPLD};
use core::{
str,
fmt::Write
};
use core::mem::uninitialized;
use smoltcp::wire::{EthernetAddress, IpAddress, IpCidr, Ipv4Address};
use smoltcp::iface::{NeighborCache, EthernetInterfaceBuilder, Routes};
use smoltcp::socket::SocketSet;
use smoltcp::socket::{SocketHandle, TcpSocket, TcpSocketBuffer};
use smoltcp::time::{Duration, Instant};
use embedded_nal::TcpStack;
use firmware;
use firmware::{
attenuator::Attenuator,
config_register::{
ConfigRegister,
CFGMask,
StatusMask,
},
dds::{
DDS,
DDSCFRMask,
},
cpld::{
CPLD,
},
Urukul,
};
use scpi::prelude::*;
/// Configure SYSTICK for 1ms timebase
fn systick_init(syst: &mut stm32::SYST, clocks: CoreClocks) {
let c_ck_mhz = clocks.c_ck().0 / 1_000_000;
let syst_calib = 0x3E8;
syst.set_clock_source(cortex_m::peripheral::syst::SystClkSource::Core);
syst.set_reload((syst_calib * c_ck_mhz) - 1);
syst.enable_interrupt();
syst.enable_counter();
}
/// ======================================================================
/// Entry point
/// ======================================================================
/// TIME is an atomic u32 that counts milliseconds. Although not used
/// here, it is very useful to have for network protocols
static TIME: AtomicU32 = AtomicU32::new(0);
/// Locally administered MAC address
const MAC_ADDRESS: [u8; 6] = [0x02, 0x00, 0x11, 0x22, 0x33, 0x44];
/// Ethernet descriptor rings are a global singleton
#[link_section = ".sram3.eth"] #[link_section = ".sram3.eth"]
static mut DES_RING: ethernet::DesRing = ethernet::DesRing::new(); static mut DES_RING: ethernet::DesRing = ethernet::DesRing::new();
// Logging setup // Theoratical maximum number of socket that can be handled
#[path = "util/logger.rs"] const SOCKET_COUNT: usize = 2;
mod logger;
#[path = "util/clock.rs"]
mod clock;
// End of logging setup
// static TIME: AtomicU32 = AtomicU32::new(0); // Give buffer sizes of transmitting and receiving TCP packets
const BUFFER_SIZE: usize = 2048;
// the program entry point
#[entry] #[entry]
fn main() -> ! { fn main() -> ! {
// logger::semihosting_init();
let clock = clock::Clock::new();
let mut cp = cortex_m::Peripherals::take().unwrap(); let mut cp = cortex_m::Peripherals::take().unwrap();
let dp = pac::Peripherals::take().unwrap(); let dp = pac::Peripherals::take().unwrap();
cp.DWT.enable_cycle_counter(); // Initialise power...
// Enable SRAM3 for the descriptor ring.
dp.RCC.ahb2enr.modify(|_, w| w.sram3en().set_bit());
// Reset RCC clock
dp.RCC.rsr.write(|w| w.rmvf().set_bit());
let pwr = dp.PWR.constrain(); let pwr = dp.PWR.constrain();
let vos = pwr.freeze(); let vos = pwr.freeze();
// Initialise SRAM3
dp.RCC.ahb2enr.modify(|_, w| w.sram3en().set_bit());
// Initialise clocks...
let rcc = dp.RCC.constrain(); let rcc = dp.RCC.constrain();
let ccdr = rcc let ccdr = rcc
.use_hse(8.mhz()) .sys_ck(200.mhz())
.sysclk(400.mhz()) .hclk(200.mhz())
// .hclk(200.mhz()) .pll1_r_ck(100.mhz()) // for TRACECK
// .per_ck(100.mhz())
.pll1_q_ck(48.mhz()) // for SPI .pll1_q_ck(48.mhz()) // for SPI
// .pll1_r_ck(400.mhz()) // for TRACECK
// .pll2_p_ck(100.mhz())
// .pll2_q_ck(100.mhz())
.freeze(vos, &dp.SYSCFG); .freeze(vos, &dp.SYSCFG);
let mut delay = cp.SYST.delay(ccdr.clocks); // Get the delay provider.
let delay = cp.SYST.delay(ccdr.clocks);
// Initialise system...
cp.SCB.invalidate_icache();
cp.SCB.enable_icache();
// TODO: ETH DMA coherence issues
// cp.SCB.enable_dcache(&mut cp.CPUID);
cp.DWT.enable_cycle_counter();
// Initialise IO...
let gpioa = dp.GPIOA.split(ccdr.peripheral.GPIOA); let gpioa = dp.GPIOA.split(ccdr.peripheral.GPIOA);
let gpiob = dp.GPIOB.split(ccdr.peripheral.GPIOB); let gpiob = dp.GPIOB.split(ccdr.peripheral.GPIOB);
let gpioc = dp.GPIOC.split(ccdr.peripheral.GPIOC); let gpioc = dp.GPIOC.split(ccdr.peripheral.GPIOC);
@ -100,75 +135,45 @@ fn main() -> ! {
let gpioe = dp.GPIOE.split(ccdr.peripheral.GPIOE); let gpioe = dp.GPIOE.split(ccdr.peripheral.GPIOE);
let gpiof = dp.GPIOF.split(ccdr.peripheral.GPIOF); let gpiof = dp.GPIOF.split(ccdr.peripheral.GPIOF);
let gpiog = dp.GPIOG.split(ccdr.peripheral.GPIOG); let gpiog = dp.GPIOG.split(ccdr.peripheral.GPIOG);
// let mut link_led = gpiob.pb0.into_push_pull_output(); // LED1, green
// let mut status_led = gpioe.pe1.into_push_pull_output(); // LD2, yellow
// let mut listen_led = gpiob.pb14.into_push_pull_output(); // LD3, red
// link_led.set_low().ok();
// status_led.set_low().ok();
// listen_led.set_low().ok();
let mut yellow_led = gpioe.pe1.into_push_pull_output(); // Setup CDONE for checking
yellow_led.set_low().unwrap(); let fpga_cdone = gpiod.pd15.into_pull_up_input();
let mut red_led = gpiob.pb14.into_push_pull_output();
red_led.set_high().unwrap();
let mut green_led = gpiob.pb0.into_push_pull_output();
green_led.set_low().unwrap();
// Configure ethernet IO match fpga_cdone.is_high() {
{ Ok(true) => hprintln!("FPGA is ready."),
let _rmii_refclk = gpioa.pa1.into_alternate_af11().set_speed(Speed::VeryHigh); Ok(_) => hprintln!("FPGA is in reset state."),
let _rmii_mdio = gpioa.pa2.into_alternate_af11().set_speed(Speed::VeryHigh); Err(_) => hprintln!("Error: Cannot read C_DONE"),
let _rmii_mdc = gpioc.pc1.into_alternate_af11().set_speed(Speed::VeryHigh); }.unwrap();
let _rmii_crs_dv = gpioa.pa7.into_alternate_af11().set_speed(Speed::VeryHigh);
let _rmii_rxd0 = gpioc.pc4.into_alternate_af11().set_speed(Speed::VeryHigh);
let _rmii_rxd1 = gpioc.pc5.into_alternate_af11().set_speed(Speed::VeryHigh);
let _rmii_tx_en = gpiog.pg11.into_alternate_af11().set_speed(Speed::VeryHigh);
let _rmii_txd0 = gpiog.pg13.into_alternate_af11().set_speed(Speed::VeryHigh);
let _rmii_txd1 = gpiob.pb13.into_alternate_af11().set_speed(Speed::VeryHigh);
}
// Configure ethernet
let mac_addr = net::wire::EthernetAddress([0xAC, 0x6F, 0x7A, 0xDE, 0xD6, 0xC8]);
let (eth_dma, _eth_mac) = unsafe {
ethernet::new_unchecked(
dp.ETHERNET_MAC,
dp.ETHERNET_MTL,
dp.ETHERNET_DMA,
&mut DES_RING,
mac_addr.clone(),
)
};
unsafe { ethernet::enable_interrupt() }
let mut ip_addrs = [net::wire::IpCidr::new(net::wire::IpAddress::v4(192, 168, 1, 200), 24)];
let mut neighbor_cache_entries = [None; 8];
let mut neighbor_cache = net::iface::NeighborCache::new(&mut neighbor_cache_entries[..]);
// neighbor_cache.fill(
// net::wire::IpAddress::v4(192, 168, 1, 125),
// net::wire::EthernetAddress([0x2C, 0xF0, 0x5D, 0x26, 0xB8, 0x2F]),
// clock.elapsed(),
// );
let mut net_interface = net::iface::EthernetInterfaceBuilder::new(eth_dma)
.ethernet_addr(mac_addr)
.neighbor_cache(neighbor_cache)
.ip_addrs(&mut ip_addrs[..])
.finalize();
// Setup Urukul
/* /*
* Using SPI1, AF5 * Using SPI1, AF5
* SCLK -> PA5 * SCLK -> PA5
* MOSI -> PB5 * MOSI -> PB5
* MISO -> PA6 * MISO -> PA6
* CS -> 0: PB12, 1: PA15, 2: PC7 * CS -> 0: PB12, 1: PA15, 2: PC7
* I/O_Update -> PB15
*/ */
let sclk = gpioa.pa5.into_alternate_af5(); let sclk = gpioa.pa5.into_alternate_af5();
let mosi = gpiob.pb5.into_alternate_af5(); let mosi = gpiob.pb5.into_alternate_af5();
let miso = gpioa.pa6.into_alternate_af5(); let miso = gpioa.pa6.into_alternate_af5();
let (cs0, cs1, cs2) = ( let (cs0, cs1, cs2) = (
gpiob.pb12.into_push_pull_output(), gpiob.pb12.into_push_pull_output(),
gpioa.pa15.into_push_pull_output(), gpioa.pa15.into_push_pull_output(),
gpioc.pc7.into_push_pull_output(), gpioc.pc7.into_push_pull_output(),
); );
/*
* I/O_Update -> PB15
*/
let io_update = gpiob.pb15.into_push_pull_output(); let io_update = gpiob.pb15.into_push_pull_output();
let spi = dp.SPI1.spi( let spi = dp.SPI1.spi(
@ -179,93 +184,201 @@ fn main() -> ! {
&ccdr.clocks, &ccdr.clocks,
); );
let cpld = CPLD::new(spi, (cs0, cs1, cs2), io_update); let switch = CPLD::new(spi, (cs0, cs1, cs2), io_update);
let parts = cpld.split(); let parts = switch.split();
let mut urukul = Urukul::new(
let urukul = Urukul::new(
parts.spi1, parts.spi2, parts.spi3, parts.spi4, parts.spi5, parts.spi6, parts.spi7, parts.spi1, parts.spi2, parts.spi3, parts.spi4, parts.spi5, parts.spi6, parts.spi7,
[25_000_000, 25_000_000, 25_000_000, 25_000_000] [25_000_000, 25_000_000, 25_000_000, 25_000_000]
); );
cp.SCB.invalidate_icache(); // Setup ethernet pins
cp.SCB.enable_icache(); setup_ethernet_pins(
gpioa.pa1, gpioa.pa2, gpioc.pc1, gpioa.pa7, gpioc.pc4,
gpioc.pc5, gpiog.pg11, gpiog.pg13, gpiob.pb13
);
// let mut time: u32 = 0; // Initialise ethernet...
// let mut next_ms = Instant::now(); assert_eq!(ccdr.clocks.hclk().0, 200_000_000); // HCLK 200MHz
assert_eq!(ccdr.clocks.pclk1().0, 100_000_000); // PCLK 100MHz
assert_eq!(ccdr.clocks.pclk2().0, 100_000_000); // PCLK 100MHz
assert_eq!(ccdr.clocks.pclk4().0, 100_000_000); // PCLK 100MHz
// next_ms += 400_000.cycles(); let mac_addr = smoltcp::wire::EthernetAddress::from_bytes(&MAC_ADDRESS);
let (_eth_dma, mut eth_mac) = unsafe {
let mut socket_set_entries: [_; 8] = Default::default(); ethernet::new_unchecked(
let mut sockets = net::socket::SocketSet::new(&mut socket_set_entries[..]); dp.ETHERNET_MAC,
dp.ETHERNET_MTL,
let mut rx_storage = [0; 4096]; dp.ETHERNET_DMA,
let mut tx_storage = [0; 4096]; &mut DES_RING,
mac_addr.clone(),
let tcp_socket = { )
let tx_buffer = net::socket::TcpSocketBuffer::new(&mut tx_storage[..]);
let rx_buffer = net::socket::TcpSocketBuffer::new(&mut rx_storage[..]);
net::socket::TcpSocket::new(tx_buffer, rx_buffer)
}; };
let handle = sockets.add(tcp_socket); unsafe {
ethernet::enable_interrupt();
delay.delay_ms(2000_u16); cp.NVIC.set_priority(stm32::Interrupt::ETH, 196); // Mid prio
green_led.set_high().unwrap(); cortex_m::peripheral::NVIC::unmask(stm32::Interrupt::ETH);
{
let mut socket = sockets.get::<net::socket::TcpSocket>(handle);
socket.connect((net::wire::IpAddress::v4(192, 168, 1, 125), 1883), 49500).unwrap();
debug!("connect!");
} }
yellow_led.set_low().unwrap(); // ----------------------------------------------------------
red_led.set_high().unwrap(); // Begin periodic tasks
let mut green = true; systick_init(&mut delay.free(), ccdr.clocks);
unsafe {
cp.SCB.shpr[15 - 4].write(128);
} // systick exception priority
// ----------------------------------------------------------
// Main application loop
// Setup addresses, maybe not MAC?
// MAC is set up in prior
let local_addr = IpAddress::v4(192, 168, 1, 200);
let mut ip_addrs = [IpCidr::new(local_addr, 24)];
// let neighbor_cache = NeighborCache::new(BTreeMap::new());
let mut neighbor_storage = [None; 16];
let neighbor_cache = NeighborCache::new(&mut neighbor_storage[..]);
// Routes
let default_v4_gw = Ipv4Address::new(192, 168, 1, 1);
let mut routes_storage = [None; 8];
let mut routes = Routes::new(&mut routes_storage[..]);
routes.add_default_ipv4_route(default_v4_gw).unwrap();
// Device? _eth_dma, as it implements phy::device
let mut iface = EthernetInterfaceBuilder::new(_eth_dma)
.ethernet_addr(mac_addr)
.neighbor_cache(neighbor_cache)
.ip_addrs(&mut ip_addrs[..])
.routes(routes)
.finalize();
// SCPI configs
// Device was declared in prior
// let mut errors = ArrayErrorQueue::<[Error; 10]>::new();
// let mut context = Context::new(&mut urukul, &mut errors, TREE);
// //Response bytebuffer
// let mut buf = ArrayVecFormatter::<[u8; 256]>::new();
// SCPI configs END
// TCP socket
let server_socket = {
static mut server_rx_storage :[u8; BUFFER_SIZE] = [0; BUFFER_SIZE];
static mut server_tx_storage :[u8; BUFFER_SIZE] = [0; BUFFER_SIZE];
let server_rx_buffer = TcpSocketBuffer::new( unsafe { &mut server_rx_storage[..] } );
let server_tx_buffer = TcpSocketBuffer::new( unsafe { &mut server_tx_storage[..] } );
TcpSocket::new(server_rx_buffer, server_tx_buffer)
};
// Setup a silent socket
let client_socket = {
static mut client_rx_storage :[u8; BUFFER_SIZE] = [0; BUFFER_SIZE];
static mut client_tx_storage :[u8; BUFFER_SIZE] = [0; BUFFER_SIZE];
let client_rx_buffer = TcpSocketBuffer::new( unsafe { &mut client_rx_storage[..] } );
let client_tx_buffer = TcpSocketBuffer::new( unsafe { &mut client_tx_storage[..] } );
TcpSocket::new(client_rx_buffer, client_tx_buffer)
};
// Socket storage
let mut sockets_storage: [_; 2] = Default::default();
let mut socket_set = SocketSet::new(&mut sockets_storage[..]);
let server_handle = socket_set.add(server_socket);
let client_handle = socket_set.add(client_socket);
loop { loop {
// let timestamp = net::time::Instant::from_millis(TIME.load(Ordering::Relaxed) as i64); let _time = TIME.load(Ordering::Relaxed);
match net_interface.poll(&mut sockets, clock.elapsed()) { match iface.poll(&mut socket_set, Instant::from_millis(_time as i64)) {
Ok(_) => {}, Ok(_) => {
// hprintln!("Ethernet up").unwrap();
},
Err(e) => { Err(e) => {
debug!("poll error: {}", e); hprintln!("Ethernet down!").unwrap();
},
};
// Conenct to TCP server through port 49500
{
let mut socket = socket_set.get::<TcpSocket>(server_handle);
if !socket.is_active() && !socket.is_listening(){
socket.listen(7777).unwrap();
hprintln!("Server listening").unwrap();
}
// hprintln!("listener state :{}", socket.state()).unwrap();
if socket.can_recv() {
hprintln!("{:?}", str::from_utf8(socket.recv(|data| {
(data.len(), data)
}).unwrap()).unwrap()).unwrap();
} }
} }
{ {
let mut socket = sockets.get::<net::socket::TcpSocket>(handle); let mut socket = socket_set.get::<TcpSocket>(client_handle);
if !socket.is_open() {
if socket.may_recv() { socket.abort();
yellow_led.set_high().unwrap();
red_led.set_low().unwrap();
let data = socket.recv(|data| {
(data.len(), data)
}).unwrap();
if socket.can_send() {
socket.send_slice("response".as_bytes()).unwrap();
}
}
if socket.may_send() {
yellow_led.set_high().unwrap();
red_led.set_low().unwrap();
debug!("close");
socket.close(); socket.close();
hprintln!("reset state: {}", socket.state()).unwrap();
socket.connect((IpAddress::v4(192, 168, 1, 200), 1883),
(IpAddress::Unspecified, 45000)).unwrap();
hprintln!("post connect state: {}", socket.state()).unwrap();
}
// hprintln!("client state: {}", socket.state()).unwrap();
if socket.can_send() {
socket.send_slice(b"regards from socket").unwrap();
}
}
} }
} }
match net_interface.poll_delay(&sockets, clock.elapsed()) { use stm32h7xx_hal::gpio::{
Some(net::time::Duration {millis :0}) => debug!("resuming"), gpioa::{PA1, PA2, PA7},
Some(time_delay) => { gpiob::{PB13},
info!("sleeping for {} ms", time_delay); gpioc::{PC1, PC4, PC5},
// green_led.set_low().unwrap(); gpiog::{PG11, PG13},
// delay.delay_ms(time_delay.total_millis() as u32); Speed::VeryHigh,
// green_led.set_high().unwrap(); };
clock.advance(time_delay)
}, /*
None => { * Migrated ethernet setup pins
// delay.delay_ms(1_u32); */
clock.advance(net::time::Duration::from_millis(1)) pub fn setup_ethernet_pins<REF_CLK, MDIO, MDC, CRS_DV, RXD0, RXD1, TX_EN, TXD0, TXD1>(
}, pa1: PA1<REF_CLK>, pa2: PA2<MDIO>, pc1: PC1<MDC>, pa7: PA7<CRS_DV>, pc4: PC4<RXD0>,
pc5: PC5<RXD1>, pg11: PG11<TX_EN>, pg13: PG13<TXD0>, pb13: PB13<TXD1>
) {
pa1.into_alternate_af11().set_speed(VeryHigh);
pa2.into_alternate_af11().set_speed(VeryHigh);
pc1.into_alternate_af11().set_speed(VeryHigh);
pa7.into_alternate_af11().set_speed(VeryHigh);
pc4.into_alternate_af11().set_speed(VeryHigh);
pc5.into_alternate_af11().set_speed(VeryHigh);
pg11.into_alternate_af11().set_speed(VeryHigh);
pg13.into_alternate_af11().set_speed(VeryHigh);
pb13.into_alternate_af11().set_speed(VeryHigh);
} }
#[interrupt]
fn ETH() {
unsafe { ethernet::interrupt_handler() }
} }
#[exception]
fn SysTick() {
TIME.fetch_add(1, Ordering::Relaxed);
}
#[exception]
fn HardFault(ef: &cortex_m_rt::ExceptionFrame) -> ! {
panic!("HardFault at {:#?}", ef);
}
#[exception]
fn DefaultHandler(irqn: i16) {
panic!("Unhandled exception (IRQn = {})", irqn);
} }

View File

@ -1,19 +0,0 @@
use smoltcp::time::{Duration, Instant};
use core::cell::Cell;
#[derive(Debug)]
pub struct Clock(Cell<Instant>);
impl Clock {
pub fn new() -> Clock {
Clock(Cell::new(Instant::from_millis(0)))
}
pub fn advance(&self, duration: Duration) {
self.0.set(self.0.get() + duration)
}
pub fn elapsed(&self) -> Instant {
self.0.get()
}
}

View File

@ -1,96 +0,0 @@
// Enables ITM
pub unsafe fn enable_itm(
dbgmcu: &stm32h7xx_hal::stm32::DBGMCU,
dcb: &mut cortex_m::peripheral::DCB,
itm: &mut cortex_m::peripheral::ITM
) {
// ARMv7-M DEMCR: Set TRCENA. Enables DWT and ITM units
//unsafe { *(0xE000_EDFC as *mut u32) |= 1 << 24 };
dcb.enable_trace();
// Ensure debug blocks are clocked before interacting with them
dbgmcu.cr.modify(|_, w| {
w.d1dbgcken()
.set_bit()
.d3dbgcken()
.set_bit()
.traceclken()
.set_bit()
.dbgsleep_d1()
.set_bit()
});
// SWO: Unlock
*(0x5c00_3fb0 as *mut u32) = 0xC5ACCE55;
// SWTF: Unlock
*(0x5c00_4fb0 as *mut u32) = 0xC5ACCE55;
// SWO CODR Register: Set SWO speed
*(0x5c00_3010 as *mut _) = 400 - 1;
// SWO SPPR Register:
// 1 = Manchester
// 2 = NRZ
*(0x5c00_30f0 as *mut _) = 2;
// SWTF Trace Funnel: Enable for CM7
*(0x5c00_4000 as *mut u32) |= 1;
// ITM: Unlock
itm.lar.write(0xC5ACCE55);
// ITM Trace Enable Register: Enable lower 8 stimulus ports
itm.ter[0].write(1);
// ITM Trace Control Register: Enable ITM
itm.tcr.write(
(0b000001 << 16) | // TraceBusID
(1 << 3) | // enable SWO output
(1 << 0), // enable the ITM
);
}
// use panic_itm as _;
use lazy_static::lazy_static;
use log::LevelFilter;
pub use cortex_m_log::log::Logger;
use cortex_m_log::{
destination::Itm as ItmDest,
printer::itm::InterruptSync,
modes::InterruptFree,
printer::itm::ItmSync
};
lazy_static! {
static ref LOGGER: Logger<ItmSync<InterruptFree>> = Logger {
level: LevelFilter::Debug,
inner: unsafe {
InterruptSync::new(
ItmDest::new(cortex_m::Peripherals::steal().ITM)
)
},
};
}
pub fn init() {
cortex_m_log::log::init(&LOGGER).unwrap();
}
use panic_semihosting as _;
use cortex_m_log::printer::semihosting;
use cortex_m_log::printer::semihosting::Semihosting;
use cortex_m_log::modes::InterruptOk;
use cortex_m_semihosting::hio::HStdout;
lazy_static! {
static ref HLOGGER: Logger<Semihosting<InterruptOk, HStdout>> = Logger {
level: LevelFilter::Trace,
inner: semihosting::InterruptOk::<_>::stdout().expect("Get Semihosting stdout"),
};
}
pub fn semihosting_init() {
cortex_m_log::log::init(&HLOGGER).unwrap();
}

View File

@ -11,10 +11,11 @@ break DefaultHandler
break HardFault break HardFault
break rust_begin_unwind break rust_begin_unwind
# situational break points: only enable for fpga_config example
# break examples/fpga_config.rs:126
# print using semihosting, slow af # print using semihosting, slow af
monitor arm semihosting enable monitor arm semihosting enable
# monitor tpiu config internal itm.fifo uart off 400000000
# monitor itm port 0 on
# flash the program to STM32 # flash the program to STM32
load load

View File

@ -1,4 +0,0 @@
source [find interface/stlink.cfg]
transport select hla_swd
source [find openocd/stm32h7x_dual_bank-itm_fix.cfg]
reset_config srst_only

View File

@ -1,280 +0,0 @@
# This is a custom version of the config that has the ITM fixed.
# The official version can be used again when https://sourceforge.net/p/openocd/tickets/266/ has been dealt with.
# script for stm32h7x family
#
# stm32h7 devices support both JTAG and SWD transports.
#
source [find target/swj-dp.tcl]
source [find mem_helper.tcl]
if { [info exists CHIPNAME] } {
set _CHIPNAME $CHIPNAME
} else {
set _CHIPNAME stm32h7x
}
if { [info exists DUAL_BANK] } {
set $_CHIPNAME.DUAL_BANK $DUAL_BANK
unset DUAL_BANK
} else {
set $_CHIPNAME.DUAL_BANK 0
}
if { [info exists DUAL_CORE] } {
set $_CHIPNAME.DUAL_CORE $DUAL_CORE
unset DUAL_CORE
} else {
set $_CHIPNAME.DUAL_CORE 0
}
# Issue a warning when hla is used, and fallback to single core configuration
if { [set $_CHIPNAME.DUAL_CORE] && [using_hla] } {
echo "Warning : hla does not support multicore debugging"
set $_CHIPNAME.DUAL_CORE 0
}
if { [info exists USE_CTI] } {
set $_CHIPNAME.USE_CTI $USE_CTI
unset USE_CTI
} else {
set $_CHIPNAME.USE_CTI 0
}
# Issue a warning when DUAL_CORE=0 and USE_CTI=1, and fallback to USE_CTI=0
if { ![set $_CHIPNAME.DUAL_CORE] && [set $_CHIPNAME.USE_CTI] } {
echo "Warning : could not use CTI with a single core device, CTI is disabled"
set $_CHIPNAME.USE_CTI 0
}
set _ENDIAN little
# Work-area is a space in RAM used for flash programming
# By default use 64kB
if { [info exists WORKAREASIZE] } {
set _WORKAREASIZE $WORKAREASIZE
} else {
set _WORKAREASIZE 0x10000
}
#jtag scan chain
if { [info exists CPUTAPID] } {
set _CPUTAPID $CPUTAPID
} else {
if { [using_jtag] } {
set _CPUTAPID 0x6ba00477
} {
set _CPUTAPID 0x6ba02477
}
}
swj_newdap $_CHIPNAME cpu -irlen 4 -ircapture 0x1 -irmask 0xf -expected-id $_CPUTAPID
dap create $_CHIPNAME.dap -chain-position $_CHIPNAME.cpu
if {[using_jtag]} {
swj_newdap $_CHIPNAME bs -irlen 5
}
if {![using_hla]} {
# STM32H7 provides an APB-AP at access port 2, which allows the access to
# the debug and trace features on the system APB System Debug Bus (APB-D).
target create $_CHIPNAME.ap2 mem_ap -dap $_CHIPNAME.dap -ap-num 2
}
target create $_CHIPNAME.cpu0 cortex_m -endian $_ENDIAN -dap $_CHIPNAME.dap -ap-num 0
$_CHIPNAME.cpu0 configure -work-area-phys 0x20000000 -work-area-size $_WORKAREASIZE -work-area-backup 0
flash bank $_CHIPNAME.bank1.cpu0 stm32h7x 0x08000000 0 0 0 $_CHIPNAME.cpu0
if {[set $_CHIPNAME.DUAL_BANK]} {
flash bank $_CHIPNAME.bank2.cpu0 stm32h7x 0x08100000 0 0 0 $_CHIPNAME.cpu0
}
if {[set $_CHIPNAME.DUAL_CORE]} {
target create $_CHIPNAME.cpu1 cortex_m -endian $_ENDIAN -dap $_CHIPNAME.dap -ap-num 3
$_CHIPNAME.cpu1 configure -work-area-phys 0x38000000 -work-area-size $_WORKAREASIZE -work-area-backup 0
flash bank $_CHIPNAME.bank1.cpu1 stm32h7x 0x08000000 0 0 0 $_CHIPNAME.cpu1
if {[set $_CHIPNAME.DUAL_BANK]} {
flash bank $_CHIPNAME.bank2.cpu1 stm32h7x 0x08100000 0 0 0 $_CHIPNAME.cpu1
}
}
# Make sure that cpu0 is selected
targets $_CHIPNAME.cpu0
# Clock after reset is HSI at 64 MHz, no need of PLL
adapter speed 1800
adapter srst delay 100
if {[using_jtag]} {
jtag_ntrst_delay 100
}
# use hardware reset
#
# The STM32H7 does not support connect_assert_srst mode because the AXI is
# unavailable while SRST is asserted, and that is used to access the DBGMCU
# component at 0x5C001000 in the examine-end event handler.
#
# It is possible to access the DBGMCU component at 0xE00E1000 via AP2 instead
# of the default AP0, and that works with SRST asserted; however, nonzero AP
# usage does not work with HLA, so is not done by default. That change could be
# made in a local configuration file if connect_assert_srst mode is needed for
# a specific application and a non-HLA adapter is in use.
reset_config srst_only srst_nogate
if {![using_hla]} {
# if srst is not fitted use SYSRESETREQ to
# perform a soft reset
$_CHIPNAME.cpu0 cortex_m reset_config sysresetreq
if {[set $_CHIPNAME.DUAL_CORE]} {
$_CHIPNAME.cpu1 cortex_m reset_config sysresetreq
}
# Set CSW[27], which according to ARM ADI v5 appendix E1.4 maps to AHB signal
# HPROT[3], which according to AMBA AHB/ASB/APB specification chapter 3.7.3
# makes the data access cacheable. This allows reading and writing data in the
# CPU cache from the debugger, which is far more useful than going straight to
# RAM when operating on typical variables, and is generally no worse when
# operating on special memory locations.
$_CHIPNAME.dap apcsw 0x08000000 0x08000000
}
$_CHIPNAME.cpu0 configure -event examine-end {
# Enable D3 and D1 DBG clocks
# DBGMCU_CR |= D3DBGCKEN | D1DBGCKEN
stm32h7x_dbgmcu_mmw 0x004 0x00600000 0
# Enable debug during low power modes (uses more power)
# DBGMCU_CR |= DBG_STANDBY | DBG_STOP | DBG_SLEEP in D3, D2 & D1 Domains
stm32h7x_dbgmcu_mmw 0x004 0x00000007 0
# Stop watchdog counters during halt
# DBGMCU_APB3FZ1 |= WWDG1
stm32h7x_dbgmcu_mmw 0x034 0x00000040 0
# DBGMCU_APB1LFZ1 |= WWDG2
stm32h7x_dbgmcu_mmw 0x03C 0x00000800 0
# DBGMCU_APB4FZ1 |= WDGLSD1 | WDGLSD2
stm32h7x_dbgmcu_mmw 0x054 0x000C0000 0
}
$_CHIPNAME.cpu0 configure -event trace-config {
# Set TRACECLKEN; TRACE_MODE is set to async; when using sync
# change this value accordingly to configure trace pins
# assignment
stm32h7x_dbgmcu_mmw 0x004 0x00100000 0
}
$_CHIPNAME.cpu0 configure -event reset-init {
# Clock after reset is HSI at 64 MHz, no need of PLL
adapter speed 4000
}
if {[set $_CHIPNAME.DUAL_CORE]} {
$_CHIPNAME.cpu1 configure -event examine-end {
# get _CHIPNAME from the current target
set _CHIPNAME [regsub ".cpu\\d$" [target current] ""]
global $_CHIPNAME.USE_CTI
# Stop watchdog counters during halt
# DBGMCU_APB3FZ2 |= WWDG1
stm32h7x_dbgmcu_mmw 0x038 0x00000040 0
# DBGMCU_APB1LFZ2 |= WWDG2
stm32h7x_dbgmcu_mmw 0x040 0x00000800 0
# DBGMCU_APB4FZ2 |= WDGLSD1 | WDGLSD2
stm32h7x_dbgmcu_mmw 0x058 0x000C0000 0
if {[set $_CHIPNAME.USE_CTI]} {
stm32h7x_cti_start
}
}
}
# like mrw, but with target selection
proc stm32h7x_mrw {used_target reg} {
set value ""
$used_target mem2array value 32 $reg 1
return $value(0)
}
# like mmw, but with target selection
proc stm32h7x_mmw {used_target reg setbits clearbits} {
set old [stm32h7x_mrw $used_target $reg]
set new [expr ($old & ~$clearbits) | $setbits]
$used_target mww $reg $new
}
# mmw for dbgmcu component registers, it accepts the register offset from dbgmcu base
# this procedure will use the mem_ap on AP2 whenever possible
proc stm32h7x_dbgmcu_mmw {reg_offset setbits clearbits} {
# use $_CHIPNAME.ap2 if possible, and use the proper dbgmcu base address
if {![using_hla]} {
# get _CHIPNAME from the current target
set _CHIPNAME [regsub ".(cpu|ap)\\d*$" [target current] ""]
set used_target $_CHIPNAME.ap2
set reg_addr [expr 0xE00E1000 + $reg_offset]
} {
set used_target [target current]
set reg_addr [expr 0x5C001000 + $reg_offset]
}
stm32h7x_mmw $used_target $reg_addr $setbits $clearbits
}
if {[set $_CHIPNAME.USE_CTI]} {
# create CTI instances for both cores
cti create $_CHIPNAME.cti0 -dap $_CHIPNAME.dap -ap-num 0 -ctibase 0xE0043000
cti create $_CHIPNAME.cti1 -dap $_CHIPNAME.dap -ap-num 3 -ctibase 0xE0043000
$_CHIPNAME.cpu0 configure -event halted { stm32h7x_cti_prepare_restart_all }
$_CHIPNAME.cpu1 configure -event halted { stm32h7x_cti_prepare_restart_all }
$_CHIPNAME.cpu0 configure -event debug-halted { stm32h7x_cti_prepare_restart_all }
$_CHIPNAME.cpu1 configure -event debug-halted { stm32h7x_cti_prepare_restart_all }
proc stm32h7x_cti_start {} {
# get _CHIPNAME from the current target
set _CHIPNAME [regsub ".cpu\\d$" [target current] ""]
# Configure Cores' CTIs to halt each other
# TRIGIN0 (DBGTRIGGER) and TRIGOUT0 (EDBGRQ) at CTM_CHANNEL_0
$_CHIPNAME.cti0 write INEN0 0x1
$_CHIPNAME.cti0 write OUTEN0 0x1
$_CHIPNAME.cti1 write INEN0 0x1
$_CHIPNAME.cti1 write OUTEN0 0x1
# enable CTIs
$_CHIPNAME.cti0 enable on
$_CHIPNAME.cti1 enable on
}
proc stm32h7x_cti_stop {} {
# get _CHIPNAME from the current target
set _CHIPNAME [regsub ".cpu\\d$" [target current] ""]
$_CHIPNAME.cti0 enable off
$_CHIPNAME.cti1 enable off
}
proc stm32h7x_cti_prepare_restart_all {} {
stm32h7x_cti_prepare_restart cti0
stm32h7x_cti_prepare_restart cti1
}
proc stm32h7x_cti_prepare_restart {cti} {
# get _CHIPNAME from the current target
set _CHIPNAME [regsub ".cpu\\d$" [target current] ""]
# Acknowlodge EDBGRQ at TRIGOUT0
$_CHIPNAME.$cti write INACK 0x01
$_CHIPNAME.$cti write INACK 0x00
}
}

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@ -1,6 +0,0 @@
# script for stm32h7x family (dual flash bank)
# STM32H7xxxI 2Mo have a dual bank flash.
set DUAL_BANK 1
source [find openocd/stm32h7x-itm_fix.cfg]

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@ -16,7 +16,7 @@ let
''; '';
runOpenOcdBlock = writeShellScriptBin "run-openocd-block" '' runOpenOcdBlock = writeShellScriptBin "run-openocd-block" ''
openocd -f openocd/openocd.cfg openocd -f board/st_nucleo_h743zi.cfg
''; '';
setGDBConfigFile = writeShellScriptBin "set-gdb-config-file" '' setGDBConfigFile = writeShellScriptBin "set-gdb-config-file" ''

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@ -1,4 +1,5 @@
use embedded_hal::blocking::spi::Transfer; use embedded_hal::blocking::spi::Transfer;
use cortex_m_semihosting::hprintln;
use core::assert; use core::assert;
use crate::Error; use crate::Error;

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@ -1,4 +1,5 @@
use embedded_hal::blocking::spi::Transfer; use embedded_hal::blocking::spi::Transfer;
use cortex_m_semihosting::hprintln;
use crate::Error; use crate::Error;
use core::mem::size_of; use core::mem::size_of;

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@ -1,4 +1,5 @@
use embedded_hal::blocking::spi::Transfer; use embedded_hal::blocking::spi::Transfer;
use cortex_m_semihosting::hprintln;
use crate::Error; use crate::Error;
use core::mem::size_of; use core::mem::size_of;

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@ -10,6 +10,7 @@ use core::{
marker::PhantomData, marker::PhantomData,
}; };
use cortex_m; use cortex_m;
use cortex_m_semihosting::hprintln;
#[macro_use] #[macro_use]
pub mod bitmask_macro; pub mod bitmask_macro;

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@ -6,6 +6,8 @@ use heapless::{consts, Vec};
use stm32h7xx_hal::ethernet; use stm32h7xx_hal::ethernet;
use smoltcp as net; use smoltcp as net;
use cortex_m_semihosting::hprintln;
use minimq::embedded_nal; use minimq::embedded_nal;
#[derive(Debug)] #[derive(Debug)]
@ -59,6 +61,7 @@ impl<'a, 'b, 'c, 'n> NetworkStack<'a, 'b, 'c, 'n> {
) { ) {
Ok(changed) => changed == false, Ok(changed) => changed == false,
Err(e) => { Err(e) => {
hprintln!("{:?}", e);
true true
} }
} }

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@ -31,6 +31,7 @@ use scpi::{
// use scpi::suffix::{Frequency}; // use scpi::suffix::{Frequency};
use embedded_hal::blocking::spi::Transfer; use embedded_hal::blocking::spi::Transfer;
use cortex_m_semihosting::hprintln;
use crate::{ use crate::{
Urukul, Urukul,
@ -270,6 +271,7 @@ impl<T:Device + UrukulTraits> Command<T> for ClockDivisionCommand {
Some(token) => { Some(token) => {
match f32::try_from(token) { match f32::try_from(token) {
Ok(val) => { Ok(val) => {
hprintln!("{}", val).unwrap();
if val == 1.0 || val == 2.0 || val == 4.0 { if val == 1.0 || val == 2.0 || val == 4.0 {
val as u8 val as u8
} else { } else {
@ -277,6 +279,7 @@ impl<T:Device + UrukulTraits> Command<T> for ClockDivisionCommand {
} }
}, },
Err(_e) => { Err(_e) => {
hprintln!("Checked numberic error").unwrap();
return Err(ErrorCode::IllegalParameterValue.into()) return Err(ErrorCode::IllegalParameterValue.into())
}, },
} }