mod descriptors;

use core::sync::atomic::{fence, Ordering};

use embassy_cortex_m::interrupt::{Interrupt, InterruptExt};
use embassy_hal_common::{into_ref, PeripheralRef};

pub(crate) use self::descriptors::{RDes, RDesRing, TDes, TDesRing};
use super::*;
use crate::gpio::sealed::{AFType, Pin as _};
use crate::gpio::{AnyPin, Speed};
use crate::pac::ETH;
use crate::{interrupt, Peripheral};

/// Interrupt handler.
pub struct InterruptHandler {}

impl interrupt::Handler<interrupt::ETH> for InterruptHandler {
    unsafe fn on_interrupt() {
        WAKER.wake();

        // TODO: Check and clear more flags
        unsafe {
            let dma = ETH.ethernet_dma();

            dma.dmacsr().modify(|w| {
                w.set_ti(true);
                w.set_ri(true);
                w.set_nis(true);
            });
            // Delay two peripheral's clock
            dma.dmacsr().read();
            dma.dmacsr().read();
        }
    }
}

const MTU: usize = 1514; // 14 Ethernet header + 1500 IP packet

pub struct Ethernet<'d, T: Instance, P: PHY> {
    _peri: PeripheralRef<'d, T>,
    pub(crate) tx: TDesRing<'d>,
    pub(crate) rx: RDesRing<'d>,
    pins: [PeripheralRef<'d, AnyPin>; 9],
    _phy: P,
    clock_range: u8,
    phy_addr: u8,
    pub(crate) mac_addr: [u8; 6],
}

macro_rules! config_pins {
    ($($pin:ident),*) => {
        // NOTE(unsafe) Exclusive access to the registers
        critical_section::with(|_| {
            $(
                $pin.set_as_af($pin.af_num(), AFType::OutputPushPull);
                $pin.set_speed(Speed::VeryHigh);
            )*
        })
    };
}

impl<'d, T: Instance, P: PHY> Ethernet<'d, T, P> {
    pub fn new<const TX: usize, const RX: usize>(
        queue: &'d mut PacketQueue<TX, RX>,
        peri: impl Peripheral<P = T> + 'd,
        _irq: impl interrupt::Binding<interrupt::ETH, InterruptHandler> + 'd,
        ref_clk: impl Peripheral<P = impl RefClkPin<T>> + 'd,
        mdio: impl Peripheral<P = impl MDIOPin<T>> + 'd,
        mdc: impl Peripheral<P = impl MDCPin<T>> + 'd,
        crs: impl Peripheral<P = impl CRSPin<T>> + 'd,
        rx_d0: impl Peripheral<P = impl RXD0Pin<T>> + 'd,
        rx_d1: impl Peripheral<P = impl RXD1Pin<T>> + 'd,
        tx_d0: impl Peripheral<P = impl TXD0Pin<T>> + 'd,
        tx_d1: impl Peripheral<P = impl TXD1Pin<T>> + 'd,
        tx_en: impl Peripheral<P = impl TXEnPin<T>> + 'd,
        phy: P,
        mac_addr: [u8; 6],
        phy_addr: u8,
    ) -> Self {
        into_ref!(peri, ref_clk, mdio, mdc, crs, rx_d0, rx_d1, tx_d0, tx_d1, tx_en);

        unsafe {
            // Enable the necessary Clocks
            // NOTE(unsafe) We have exclusive access to the registers
            #[cfg(not(rcc_h5))]
            critical_section::with(|_| {
                crate::pac::RCC.apb4enr().modify(|w| w.set_syscfgen(true));
                crate::pac::RCC.ahb1enr().modify(|w| {
                    w.set_eth1macen(true);
                    w.set_eth1txen(true);
                    w.set_eth1rxen(true);
                });

                // RMII
                crate::pac::SYSCFG.pmcr().modify(|w| w.set_epis(0b100));
            });

            #[cfg(rcc_h5)]
            critical_section::with(|_| {
                crate::pac::RCC.apb3enr().modify(|w| w.set_sbsen(true));

                crate::pac::RCC.ahb1enr().modify(|w| {
                    w.set_ethen(true);
                    w.set_ethtxen(true);
                    w.set_ethrxen(true);
                });

                // RMII
                crate::pac::SBS
                    .pmcr()
                    .modify(|w| w.set_eth_sel_phy(crate::pac::sbs::vals::EthSelPhy::B_0X4));
            });

            config_pins!(ref_clk, mdio, mdc, crs, rx_d0, rx_d1, tx_d0, tx_d1, tx_en);

            // NOTE(unsafe) We have exclusive access to the registers
            let dma = ETH.ethernet_dma();
            let mac = ETH.ethernet_mac();
            let mtl = ETH.ethernet_mtl();

            // Reset and wait
            dma.dmamr().modify(|w| w.set_swr(true));
            while dma.dmamr().read().swr() {}

            mac.maccr().modify(|w| {
                w.set_ipg(0b000); // 96 bit times
                w.set_acs(true);
                w.set_fes(true);
                w.set_dm(true);
                // TODO: Carrier sense ? ECRSFD
            });

            // Note: Writing to LR triggers synchronisation of both LR and HR into the MAC core,
            // so the LR write must happen after the HR write.
            mac.maca0hr()
                .modify(|w| w.set_addrhi(u16::from(mac_addr[4]) | (u16::from(mac_addr[5]) << 8)));
            mac.maca0lr().write(|w| {
                w.set_addrlo(
                    u32::from(mac_addr[0])
                        | (u32::from(mac_addr[1]) << 8)
                        | (u32::from(mac_addr[2]) << 16)
                        | (u32::from(mac_addr[3]) << 24),
                )
            });

            mac.macqtx_fcr().modify(|w| w.set_pt(0x100));

            // disable all MMC RX interrupts
            mac.mmc_rx_interrupt_mask().write(|w| {
                w.set_rxcrcerpim(true);
                w.set_rxalgnerpim(true);
                w.set_rxucgpim(true);
                w.set_rxlpiuscim(true);
                w.set_rxlpitrcim(true)
            });

            // disable all MMC TX interrupts
            mac.mmc_tx_interrupt_mask().write(|w| {
                w.set_txscolgpim(true);
                w.set_txmcolgpim(true);
                w.set_txgpktim(true);
                w.set_txlpiuscim(true);
                w.set_txlpitrcim(true);
            });

            mtl.mtlrx_qomr().modify(|w| w.set_rsf(true));
            mtl.mtltx_qomr().modify(|w| w.set_tsf(true));

            dma.dmactx_cr().modify(|w| w.set_txpbl(1)); // 32 ?
            dma.dmacrx_cr().modify(|w| {
                w.set_rxpbl(1); // 32 ?
                w.set_rbsz(MTU as u16);
            });

            // NOTE(unsafe) We got the peripheral singleton, which means that `rcc::init` was called
            let hclk = crate::rcc::get_freqs().ahb1;
            let hclk_mhz = hclk.0 / 1_000_000;

            // Set the MDC clock frequency in the range 1MHz - 2.5MHz
            let clock_range = match hclk_mhz {
                0..=34 => 2,    // Divide by 16
                35..=59 => 3,   // Divide by 26
                60..=99 => 0,   // Divide by 42
                100..=149 => 1, // Divide by 62
                150..=249 => 4, // Divide by 102
                250..=310 => 5, // Divide by 124
                _ => {
                    panic!("HCLK results in MDC clock > 2.5MHz even for the highest CSR clock divider")
                }
            };

            let pins = [
                ref_clk.map_into(),
                mdio.map_into(),
                mdc.map_into(),
                crs.map_into(),
                rx_d0.map_into(),
                rx_d1.map_into(),
                tx_d0.map_into(),
                tx_d1.map_into(),
                tx_en.map_into(),
            ];

            let mut this = Self {
                _peri: peri,
                tx: TDesRing::new(&mut queue.tx_desc, &mut queue.tx_buf),
                rx: RDesRing::new(&mut queue.rx_desc, &mut queue.rx_buf),
                pins,
                _phy: phy,
                clock_range,
                phy_addr,
                mac_addr,
            };

            fence(Ordering::SeqCst);

            let mac = ETH.ethernet_mac();
            let mtl = ETH.ethernet_mtl();
            let dma = ETH.ethernet_dma();

            mac.maccr().modify(|w| {
                w.set_re(true);
                w.set_te(true);
            });
            mtl.mtltx_qomr().modify(|w| w.set_ftq(true));

            dma.dmactx_cr().modify(|w| w.set_st(true));
            dma.dmacrx_cr().modify(|w| w.set_sr(true));

            // Enable interrupts
            dma.dmacier().modify(|w| {
                w.set_nie(true);
                w.set_rie(true);
                w.set_tie(true);
            });

            P::phy_reset(&mut this);
            P::phy_init(&mut this);

            interrupt::ETH::steal().unpend();
            interrupt::ETH::steal().enable();

            this
        }
    }
}

unsafe impl<'d, T: Instance, P: PHY> StationManagement for Ethernet<'d, T, P> {
    fn smi_read(&mut self, reg: u8) -> u16 {
        // NOTE(unsafe) These registers aren't used in the interrupt and we have `&mut self`
        unsafe {
            let mac = ETH.ethernet_mac();

            mac.macmdioar().modify(|w| {
                w.set_pa(self.phy_addr);
                w.set_rda(reg);
                w.set_goc(0b11); // read
                w.set_cr(self.clock_range);
                w.set_mb(true);
            });
            while mac.macmdioar().read().mb() {}
            mac.macmdiodr().read().md()
        }
    }

    fn smi_write(&mut self, reg: u8, val: u16) {
        // NOTE(unsafe) These registers aren't used in the interrupt and we have `&mut self`
        unsafe {
            let mac = ETH.ethernet_mac();

            mac.macmdiodr().write(|w| w.set_md(val));
            mac.macmdioar().modify(|w| {
                w.set_pa(self.phy_addr);
                w.set_rda(reg);
                w.set_goc(0b01); // write
                w.set_cr(self.clock_range);
                w.set_mb(true);
            });
            while mac.macmdioar().read().mb() {}
        }
    }
}

impl<'d, T: Instance, P: PHY> Drop for Ethernet<'d, T, P> {
    fn drop(&mut self) {
        // NOTE(unsafe) We have `&mut self` and the interrupt doesn't use this registers
        unsafe {
            let dma = ETH.ethernet_dma();
            let mac = ETH.ethernet_mac();
            let mtl = ETH.ethernet_mtl();

            // Disable the TX DMA and wait for any previous transmissions to be completed
            dma.dmactx_cr().modify(|w| w.set_st(false));
            while {
                let txqueue = mtl.mtltx_qdr().read();
                txqueue.trcsts() == 0b01 || txqueue.txqsts()
            } {}

            // Disable MAC transmitter and receiver
            mac.maccr().modify(|w| {
                w.set_re(false);
                w.set_te(false);
            });

            // Wait for previous receiver transfers to be completed and then disable the RX DMA
            while {
                let rxqueue = mtl.mtlrx_qdr().read();
                rxqueue.rxqsts() != 0b00 || rxqueue.prxq() != 0
            } {}
            dma.dmacrx_cr().modify(|w| w.set_sr(false));
        }

        // NOTE(unsafe) Exclusive access to the regs
        critical_section::with(|_| unsafe {
            for pin in self.pins.iter_mut() {
                pin.set_as_disconnected();
            }
        })
    }
}