cleanups and esp-hal references

src/writing-your-own-application/generate-project/esp-template.md

@@ -65,72 +65,52 @@ Before going further, let's see what these files are for.
 - `#![no_std]`
   - This tells the Rust compiler that this code doesn't use `libstd`
 - `#![no_main]`
-  - The `no_main` attribute says that this program won't use the standard main interface, which is tailored for command-line applications that receive arguments. Instead of the standard main, we'll use the entry attribute from the `riscv-rt` crate to define a custom entry point. In this program, we have named the entry point `main`, but any other name could have been used. The entry point function must be a [diverging function][diverging-function]. I.e. it has the signature `fn foo() -> !`; this type indicates that the function never returns – which means that the program never terminates.
+  - The `no_main` attribute says that this program won't use the standard main interface, which is usually used when a full operating system is available. Instead of the standard main, we'll use the entry attribute from the `esp-riscv-rt` crate to define a custom entry point. In this program, we have named the entry point `main`, but any other name could have been used. The entry point function must be a [diverging function][diverging-function]. I.e. it has the signature `fn foo() -> !`; this type indicates that the function never returns – which means that the program never terminates.
 
 ```rust,ignore
  4 use esp_backtrace as _;
  5 use esp_println::println;
- 6 use hal::{clock::ClockControl, peripherals::Peripherals, prelude::*, timer::TimerGroup, Rtc};
+ 6 use esp_hal::{clock::ClockControl, peripherals::Peripherals, prelude::*, timer::TimerGroup, Rtc};
 ```
 - `use esp_backtrace as _;`
   - Since we are in a bare-metal environment, we need a panic handler that runs if a panic occurs in code
-  - There are a few different crates you can use (e.g `panic-halt`) but `esp-backtrace` provides an implementation that prints the address of a backtrace - together with `espflash`/`espmonitor` these addresses can get decoded into source code locations
+  - There are a few different crates you can use (e.g `panic-halt`) but `esp-backtrace` provides an implementation that prints the address of a backtrace - together with `espflash` these addresses can get decoded into source code locations
 - `use esp_println::println;`
   - Provides `println!` implementation
-- `use hal:{...}`
+- `use esp_hal::{...}`
   - We need to bring in some types we are going to use
-  - These are from `esp-hal`
 
 ```rust,ignore
  8 #[entry]
  9 fn main() -> ! {
 10    let peripherals = Peripherals::take();
-11    let mut system = peripherals.SYSTEM.split();
-12    let clocks = ClockControl::boot_defaults(system.clock_control).freeze();
+11    let system = peripherals.SYSTEM.split();
+12    let clocks = ClockControl::max(system.clock_control).freeze();
 13
-14    // Disable the RTC and TIMG watchdog timers
-15    let mut rtc = Rtc::new(peripherals.RTC_CNTL);
-16    let timer_group0 = TimerGroup::new(
-17        peripherals.TIMG0,
-18        &clocks,
-19        &mut system.peripheral_clock_control,
-20    );
-21    let mut wdt0 = timer_group0.wdt;
-22    let timer_group1 = TimerGroup::new(
-23        peripherals.TIMG1,
-24        &clocks,
-25        &mut system.peripheral_clock_control,
-26    );
-27    rtc.swd.disable();
-28    rtc.rwdt.disable();
-29    wdt0.disable();
-30    wdt1.disable();
-31
-32    println!("Hello world!");
-33
-34    loop {}
-35 }
+14    println!("Hello world!");
+15
+16    loop {}
+17 }
 ```
 Inside the `main` function we can find:
-- `let peripherals = Peripherals::take().unwrap();`
+- `let peripherals = Peripherals::take()`
   - HAL drivers usually take ownership of peripherals accessed via the PAC
   - Here we take all the peripherals from the PAC to pass them to the HAL drivers later
 - `let mut system = peripherals.SYSTEM.split();`
   - Sometimes a peripheral (here the System peripheral) is coarse-grained and doesn't exactly fit the HAL drivers - so here we split the System peripheral into smaller pieces which get passed to the drivers
-- `let clocks = ClockControl::boot_defaults(system.clock_control).freeze();`
-  - Here we configure the system clocks - in this case, we are fine with the defaults
+- `let clocks = ClockControl::max(system.clock_control).freeze();`
+  - Here we configure the system clocks - in this case, boost to the maxiumum for the chip
   - We freeze the clocks, which means we can't change them later
   - Some drivers need a reference to the clocks to know how to calculate rates and durations
 - The next block of code instantiates some peripherals (namely RTC and the two timer groups) to disable the watchdog, which is armed after boot
   - Without that code, the SoC would reboot after some time
-  - There is another way to prevent the reboot: [feeding][wtd-feeding] the watchdog
+  - There is another way to prevent the reboot: feeding the watchdog
 - `println!("Hello world!");`
   - Prints "Hello world!"
 - `loop {}`
   - Since our function is supposed to never return, we just "do nothing" in a loop
 
 [diverging-function]: https://doc.rust-lang.org/beta/rust-by-example/fn/diverging.html
-[wtd-feeding]: https://docs.rs/esp32c3-hal/0.10.0/esp32c3_hal/prelude/trait._embedded_hal_watchdog_Watchdog.html#tymethod.feed
 
 ## Running the Code