//! This example uses the RP Pico W board Wifi chip (cyw43). //! Connects to Wifi network and makes a web request to get the current time. #![no_std] #![no_main] #![allow(async_fn_in_trait)] use core::str::from_utf8; use cyw43::JoinOptions; use cyw43_pio::PioSpi; use defmt::*; use embassy_executor::Spawner; use embassy_net::dns::DnsSocket; use embassy_net::tcp::client::{TcpClient, TcpClientState}; use embassy_net::{Config, Stack, StackResources}; use embassy_rp::bind_interrupts; use embassy_rp::clocks::RoscRng; use embassy_rp::gpio::{Level, Output}; use embassy_rp::peripherals::{DMA_CH0, PIO0}; use embassy_rp::pio::{InterruptHandler, Pio}; use embassy_time::{Duration, Timer}; use rand::RngCore; use reqwless::client::{HttpClient, TlsConfig, TlsVerify}; use reqwless::request::Method; use serde::Deserialize; use static_cell::StaticCell; use {defmt_rtt as _, panic_probe as _, serde_json_core}; bind_interrupts!(struct Irqs { PIO0_IRQ_0 => InterruptHandler; }); const WIFI_NETWORK: &str = "ssid"; // change to your network SSID const WIFI_PASSWORD: &str = "pwd"; // change to your network password #[embassy_executor::task] async fn cyw43_task(runner: cyw43::Runner<'static, Output<'static>, PioSpi<'static, PIO0, 0, DMA_CH0>>) -> ! { runner.run().await } #[embassy_executor::task] async fn net_task(stack: &'static Stack>) -> ! { stack.run().await } #[embassy_executor::main] async fn main(spawner: Spawner) { info!("Hello World!"); let p = embassy_rp::init(Default::default()); let mut rng = RoscRng; let fw = include_bytes!("../../../../cyw43-firmware/43439A0.bin"); let clm = include_bytes!("../../../../cyw43-firmware/43439A0_clm.bin"); // To make flashing faster for development, you may want to flash the firmwares independently // at hardcoded addresses, instead of baking them into the program with `include_bytes!`: // probe-rs download 43439A0.bin --binary-format bin --chip RP2040 --base-address 0x10100000 // probe-rs download 43439A0_clm.bin --binary-format bin --chip RP2040 --base-address 0x10140000 // let fw = unsafe { core::slice::from_raw_parts(0x10100000 as *const u8, 230321) }; // let clm = unsafe { core::slice::from_raw_parts(0x10140000 as *const u8, 4752) }; let pwr = Output::new(p.PIN_23, Level::Low); let cs = Output::new(p.PIN_25, Level::High); let mut pio = Pio::new(p.PIO0, Irqs); let spi = PioSpi::new(&mut pio.common, pio.sm0, pio.irq0, cs, p.PIN_24, p.PIN_29, p.DMA_CH0); static STATE: StaticCell = StaticCell::new(); let state = STATE.init(cyw43::State::new()); let (net_device, mut control, runner) = cyw43::new(state, pwr, spi, fw).await; unwrap!(spawner.spawn(cyw43_task(runner))); control.init(clm).await; control .set_power_management(cyw43::PowerManagementMode::PowerSave) .await; let config = Config::dhcpv4(Default::default()); // Use static IP configuration instead of DHCP //let config = embassy_net::Config::ipv4_static(embassy_net::StaticConfigV4 { // address: Ipv4Cidr::new(Ipv4Address::new(192, 168, 69, 2), 24), // dns_servers: Vec::new(), // gateway: Some(Ipv4Address::new(192, 168, 69, 1)), //}); // Generate random seed let seed = rng.next_u64(); // Init network stack static STACK: StaticCell>> = StaticCell::new(); static RESOURCES: StaticCell> = StaticCell::new(); let stack = &*STACK.init(Stack::new( net_device, config, RESOURCES.init(StackResources::new()), seed, )); unwrap!(spawner.spawn(net_task(stack))); loop { match control .join(WIFI_NETWORK, JoinOptions::new(WIFI_PASSWORD.as_bytes())) .await { Ok(_) => break, Err(err) => { info!("join failed with status={}", err.status); } } } // Wait for DHCP, not necessary when using static IP info!("waiting for DHCP..."); while !stack.is_config_up() { Timer::after_millis(100).await; } info!("DHCP is now up!"); info!("waiting for link up..."); while !stack.is_link_up() { Timer::after_millis(500).await; } info!("Link is up!"); info!("waiting for stack to be up..."); stack.wait_config_up().await; info!("Stack is up!"); // And now we can use it! loop { let mut rx_buffer = [0; 8192]; let mut tls_read_buffer = [0; 16640]; let mut tls_write_buffer = [0; 16640]; let client_state = TcpClientState::<1, 1024, 1024>::new(); let tcp_client = TcpClient::new(stack, &client_state); let dns_client = DnsSocket::new(stack); let tls_config = TlsConfig::new(seed, &mut tls_read_buffer, &mut tls_write_buffer, TlsVerify::None); let mut http_client = HttpClient::new_with_tls(&tcp_client, &dns_client, tls_config); let url = "https://worldtimeapi.org/api/timezone/Europe/Berlin"; // for non-TLS requests, use this instead: // let mut http_client = HttpClient::new(&tcp_client, &dns_client); // let url = "http://worldtimeapi.org/api/timezone/Europe/Berlin"; info!("connecting to {}", &url); let mut request = match http_client.request(Method::GET, &url).await { Ok(req) => req, Err(e) => { error!("Failed to make HTTP request: {:?}", e); return; // handle the error } }; let response = match request.send(&mut rx_buffer).await { Ok(resp) => resp, Err(_e) => { error!("Failed to send HTTP request"); return; // handle the error; } }; let body = match from_utf8(response.body().read_to_end().await.unwrap()) { Ok(b) => b, Err(_e) => { error!("Failed to read response body"); return; // handle the error } }; info!("Response body: {:?}", &body); // parse the response body and update the RTC #[derive(Deserialize)] struct ApiResponse<'a> { datetime: &'a str, // other fields as needed } let bytes = body.as_bytes(); match serde_json_core::de::from_slice::(bytes) { Ok((output, _used)) => { info!("Datetime: {:?}", output.datetime); } Err(_e) => { error!("Failed to parse response body"); return; // handle the error } } Timer::after(Duration::from_secs(5)).await; } }