fn main() { #[cfg(feature = "stm32-metapac")] stm32(); println!("cargo:rerun-if-changed=build.rs"); } #[cfg(feature = "stm32-metapac")] fn stm32() { use std::path::PathBuf; use std::{env, fs}; use proc_macro2::TokenStream; use quote::{format_ident, quote}; use stm32_metapac::metadata::METADATA; let chip_name = match env::vars() .map(|(a, _)| a) .filter(|x| { !x.starts_with("CARGO_FEATURE_STM32_METAPAC") && !x.starts_with("CARGO_FEATURE_STM32_TIM") && x.starts_with("CARGO_FEATURE_STM32") }) .get_one() { Ok(x) => x, Err(GetOneError::None) => panic!("No stm32xx Cargo feature enabled"), Err(GetOneError::Multiple) => panic!("Multiple stm32xx Cargo features enabled"), } .strip_prefix("CARGO_FEATURE_") .unwrap() .to_ascii_lowercase(); // Allows to just use #[cfg(stm32)] if one of the stm32 chips is used. println!("cargo:rustc-cfg=stm32"); for p in METADATA.peripherals { if let Some(r) = &p.registers { println!("cargo:rustc-cfg={}", r.kind); println!("cargo:rustc-cfg={}_{}", r.kind, r.version); } } // ======== // Generate singletons let mut singletons: Vec = Vec::new(); for p in METADATA.peripherals { if !p.name.contains("TIM") { continue; } if let Some(r) = &p.registers { match r.kind { // Generate singletons per pin, not per port "gpio" => { println!("{}", p.name); let port_letter = p.name.strip_prefix("GPIO").unwrap(); for pin_num in 0..16 { singletons.push(format!("P{}{}", port_letter, pin_num)); } } // No singleton for these, the HAL handles them specially. "exti" => {} // We *shouldn't* have singletons for these, but the HAL currently requires // singletons, for using with RccPeripheral to enable/disable clocks to them. "rcc" => { if r.version.starts_with("h5") || r.version.starts_with("h7") || r.version.starts_with("f4") { singletons.push("MCO1".to_string()); singletons.push("MCO2".to_string()); } if r.version.starts_with("l4") { singletons.push("MCO".to_string()); } singletons.push(p.name.to_string()); } //"dbgmcu" => {} //"syscfg" => {} //"dma" => {} //"bdma" => {} //"dmamux" => {} // For other peripherals, one singleton per peri _ => singletons.push(p.name.to_string()), } } } let mut g = TokenStream::new(); // ======== // Generate RccPeripheral impls for p in METADATA.peripherals { if !singletons.contains(&p.name.to_string()) { continue; } if let Some(rcc) = &p.rcc { let en = rcc.enable.as_ref().unwrap(); let rst = match &rcc.reset { Some(rst) => { let rst_reg = format_ident!("{}", rst.register.to_ascii_lowercase()); let set_rst_field = format_ident!("set_{}", rst.field.to_ascii_lowercase()); quote! { stm32_metapac::RCC.#rst_reg().modify(|w| w.#set_rst_field(true)); stm32_metapac::RCC.#rst_reg().modify(|w| w.#set_rst_field(false)); } } None => TokenStream::new(), }; let after_enable = if chip_name.starts_with("stm32f2") { // Errata: ES0005 - 2.1.11 Delay after an RCC peripheral clock enabling quote! { cortex_m::asm::dsb(); } } else { TokenStream::new() }; let pname = format_ident!("{}", p.name); let en_reg = format_ident!("{}", en.register.to_ascii_lowercase()); let set_en_field = format_ident!("set_{}", en.field.to_ascii_lowercase()); g.extend(quote! { #[doc(hidden)] pub mod #pname { pub fn enable() { stm32_metapac::RCC.#en_reg().modify(|w| w.#set_en_field(true)); #after_enable } pub fn reset() { #rst } } }); } } // ======== // Generate NVIC impl let prio_bits = METADATA.nvic_priority_bits; g.extend(quote! { pub const NVIC_PRIO_BITS: u8 = #prio_bits; }); // ======== // Write generated.rs let out_dir = &PathBuf::from(env::var_os("OUT_DIR").unwrap()); let out_file = out_dir.join("_generated.rs").to_string_lossy().to_string(); fs::write(out_file, g.to_string()).unwrap(); } #[cfg(feature = "stm32-metapac")] enum GetOneError { None, Multiple, } #[cfg(feature = "stm32-metapac")] trait IteratorExt: Iterator { fn get_one(self) -> Result; } #[cfg(feature = "stm32-metapac")] impl IteratorExt for T { fn get_one(mut self) -> Result { match self.next() { None => Err(GetOneError::None), Some(res) => match self.next() { Some(_) => Err(GetOneError::Multiple), None => Ok(res), }, } } }