#![no_std] #![no_main] #![allow(incomplete_features)] #![feature(async_fn_in_trait, type_alias_impl_trait, concat_bytes)] #![deny(unused_must_use)] // This mod MUST go first, so that the others see its macros. pub(crate) mod fmt; mod bus; mod consts; mod countries; mod events; mod structs; use core::cell::Cell; use core::cmp::{max, min}; use core::slice; use ch::driver::LinkState; use embassy_futures::yield_now; use embassy_net_driver_channel as ch; use embassy_time::{block_for, Duration, Timer}; use embedded_hal_1::digital::OutputPin; use embedded_hal_async::spi::SpiDevice; use crate::bus::Bus; pub use crate::bus::SpiBusCyw43; use crate::consts::*; use crate::events::Event; use crate::structs::*; const MTU: usize = 1514; #[derive(Clone, Copy)] pub enum IoctlType { Get = 0, Set = 2, } #[allow(unused)] #[derive(Clone, Copy, PartialEq, Eq)] enum Core { WLAN = 0, SOCSRAM = 1, SDIOD = 2, } impl Core { fn base_addr(&self) -> u32 { match self { Self::WLAN => CHIP.arm_core_base_address, Self::SOCSRAM => CHIP.socsram_wrapper_base_address, Self::SDIOD => CHIP.sdiod_core_base_address, } } } #[allow(unused)] struct Chip { arm_core_base_address: u32, socsram_base_address: u32, socsram_wrapper_base_address: u32, sdiod_core_base_address: u32, pmu_base_address: u32, chip_ram_size: u32, atcm_ram_base_address: u32, socram_srmem_size: u32, chanspec_band_mask: u32, chanspec_band_2g: u32, chanspec_band_5g: u32, chanspec_band_shift: u32, chanspec_bw_10: u32, chanspec_bw_20: u32, chanspec_bw_40: u32, chanspec_bw_mask: u32, chanspec_bw_shift: u32, chanspec_ctl_sb_lower: u32, chanspec_ctl_sb_upper: u32, chanspec_ctl_sb_none: u32, chanspec_ctl_sb_mask: u32, } const WRAPPER_REGISTER_OFFSET: u32 = 0x100000; // Data for CYW43439 const CHIP: Chip = Chip { arm_core_base_address: 0x18003000 + WRAPPER_REGISTER_OFFSET, socsram_base_address: 0x18004000, socsram_wrapper_base_address: 0x18004000 + WRAPPER_REGISTER_OFFSET, sdiod_core_base_address: 0x18002000, pmu_base_address: 0x18000000, chip_ram_size: 512 * 1024, atcm_ram_base_address: 0, socram_srmem_size: 64 * 1024, chanspec_band_mask: 0xc000, chanspec_band_2g: 0x0000, chanspec_band_5g: 0xc000, chanspec_band_shift: 14, chanspec_bw_10: 0x0800, chanspec_bw_20: 0x1000, chanspec_bw_40: 0x1800, chanspec_bw_mask: 0x3800, chanspec_bw_shift: 11, chanspec_ctl_sb_lower: 0x0000, chanspec_ctl_sb_upper: 0x0100, chanspec_ctl_sb_none: 0x0000, chanspec_ctl_sb_mask: 0x0700, }; #[derive(Clone, Copy)] enum IoctlState { Idle, Pending { kind: IoctlType, cmd: u32, iface: u32, buf: *mut [u8], }, Sent { buf: *mut [u8], }, Done { resp_len: usize, }, } pub struct State { ioctl_state: Cell, ch: ch::State, } impl State { pub fn new() -> Self { Self { ioctl_state: Cell::new(IoctlState::Idle), ch: ch::State::new(), } } } pub struct Control<'a> { state_ch: ch::StateRunner<'a>, ioctl_state: &'a Cell, } #[derive(Debug, Clone, Copy, PartialEq, Eq)] pub enum PowerManagementMode { /// Custom, officially unsupported mode. Use at your own risk. /// All power-saving features set to their max at only a marginal decrease in power consumption /// as oppposed to `Aggressive`. SuperSave, /// Aggressive power saving mode. Aggressive, /// The default mode. PowerSave, /// Performance is prefered over power consumption but still some power is conserved as opposed to /// `None`. Performance, /// Unlike all the other PM modes, this lowers the power consumption at all times at the cost of /// a much lower throughput. ThroughputThrottling, /// No power management is configured. This consumes the most power. None, } impl Default for PowerManagementMode { fn default() -> Self { Self::PowerSave } } impl PowerManagementMode { fn sleep_ret_ms(&self) -> u16 { match self { PowerManagementMode::SuperSave => 2000, PowerManagementMode::Aggressive => 2000, PowerManagementMode::PowerSave => 200, PowerManagementMode::Performance => 20, PowerManagementMode::ThroughputThrottling => 0, // value doesn't matter PowerManagementMode::None => 0, // value doesn't matter } } fn beacon_period(&self) -> u8 { match self { PowerManagementMode::SuperSave => 255, PowerManagementMode::Aggressive => 1, PowerManagementMode::PowerSave => 1, PowerManagementMode::Performance => 1, PowerManagementMode::ThroughputThrottling => 0, // value doesn't matter PowerManagementMode::None => 0, // value doesn't matter } } fn dtim_period(&self) -> u8 { match self { PowerManagementMode::SuperSave => 255, PowerManagementMode::Aggressive => 1, PowerManagementMode::PowerSave => 1, PowerManagementMode::Performance => 1, PowerManagementMode::ThroughputThrottling => 0, // value doesn't matter PowerManagementMode::None => 0, // value doesn't matter } } fn assoc(&self) -> u8 { match self { PowerManagementMode::SuperSave => 255, PowerManagementMode::Aggressive => 10, PowerManagementMode::PowerSave => 10, PowerManagementMode::Performance => 1, PowerManagementMode::ThroughputThrottling => 0, // value doesn't matter PowerManagementMode::None => 0, // value doesn't matter } } fn mode(&self) -> u32 { match self { PowerManagementMode::ThroughputThrottling => 1, _ => 2, } } } impl<'a> Control<'a> { pub async fn init(&mut self, clm: &[u8]) { const CHUNK_SIZE: usize = 1024; info!("Downloading CLM..."); let mut offs = 0; for chunk in clm.chunks(CHUNK_SIZE) { let mut flag = DOWNLOAD_FLAG_HANDLER_VER; if offs == 0 { flag |= DOWNLOAD_FLAG_BEGIN; } offs += chunk.len(); if offs == clm.len() { flag |= DOWNLOAD_FLAG_END; } let header = DownloadHeader { flag, dload_type: DOWNLOAD_TYPE_CLM, len: chunk.len() as _, crc: 0, }; let mut buf = [0; 8 + 12 + CHUNK_SIZE]; buf[0..8].copy_from_slice(b"clmload\x00"); buf[8..20].copy_from_slice(&header.to_bytes()); buf[20..][..chunk.len()].copy_from_slice(&chunk); self.ioctl(IoctlType::Set, IOCTL_CMD_SET_VAR, 0, &mut buf[..8 + 12 + chunk.len()]) .await; } // check clmload ok assert_eq!(self.get_iovar_u32("clmload_status").await, 0); info!("Configuring misc stuff..."); // Disable tx gloming which transfers multiple packets in one request. // 'glom' is short for "conglomerate" which means "gather together into // a compact mass". self.set_iovar_u32("bus:txglom", 0).await; self.set_iovar_u32("apsta", 1).await; // read MAC addr. let mut mac_addr = [0; 6]; assert_eq!(self.get_iovar("cur_etheraddr", &mut mac_addr).await, 6); info!("mac addr: {:02x}", mac_addr); let country = countries::WORLD_WIDE_XX; let country_info = CountryInfo { country_abbrev: [country.code[0], country.code[1], 0, 0], country_code: [country.code[0], country.code[1], 0, 0], rev: if country.rev == 0 { -1 } else { country.rev as _ }, }; self.set_iovar("country", &country_info.to_bytes()).await; // set country takes some time, next ioctls fail if we don't wait. Timer::after(Duration::from_millis(100)).await; // Set antenna to chip antenna self.ioctl_set_u32(IOCTL_CMD_ANTDIV, 0, 0).await; self.set_iovar_u32("bus:txglom", 0).await; Timer::after(Duration::from_millis(100)).await; //self.set_iovar_u32("apsta", 1).await; // this crashes, also we already did it before...?? //Timer::after(Duration::from_millis(100)).await; self.set_iovar_u32("ampdu_ba_wsize", 8).await; Timer::after(Duration::from_millis(100)).await; self.set_iovar_u32("ampdu_mpdu", 4).await; Timer::after(Duration::from_millis(100)).await; //self.set_iovar_u32("ampdu_rx_factor", 0).await; // this crashes //Timer::after(Duration::from_millis(100)).await; // evts let mut evts = EventMask { iface: 0, events: [0xFF; 24], }; // Disable spammy uninteresting events. evts.unset(Event::RADIO); evts.unset(Event::IF); evts.unset(Event::PROBREQ_MSG); evts.unset(Event::PROBREQ_MSG_RX); evts.unset(Event::PROBRESP_MSG); evts.unset(Event::PROBRESP_MSG); self.set_iovar("bsscfg:event_msgs", &evts.to_bytes()).await; Timer::after(Duration::from_millis(100)).await; // set wifi up self.ioctl(IoctlType::Set, IOCTL_CMD_UP, 0, &mut []).await; Timer::after(Duration::from_millis(100)).await; self.ioctl_set_u32(110, 0, 1).await; // SET_GMODE = auto self.ioctl_set_u32(142, 0, 0).await; // SET_BAND = any Timer::after(Duration::from_millis(100)).await; self.state_ch.set_ethernet_address(mac_addr); self.state_ch.set_link_state(LinkState::Up); // TODO do on join/leave info!("INIT DONE"); } pub async fn set_power_management(&mut self, mode: PowerManagementMode) { // power save mode let mode_num = mode.mode(); if mode_num == 2 { self.set_iovar_u32("pm2_sleep_ret", mode.sleep_ret_ms() as u32).await; self.set_iovar_u32("bcn_li_bcn", mode.beacon_period() as u32).await; self.set_iovar_u32("bcn_li_dtim", mode.dtim_period() as u32).await; self.set_iovar_u32("assoc_listen", mode.assoc() as u32).await; } self.ioctl_set_u32(86, 0, mode_num).await; } pub async fn join_open(&mut self, ssid: &str) { self.set_iovar_u32("ampdu_ba_wsize", 8).await; self.ioctl_set_u32(134, 0, 0).await; // wsec = open self.set_iovar_u32x2("bsscfg:sup_wpa", 0, 0).await; self.ioctl_set_u32(20, 0, 1).await; // set_infra = 1 self.ioctl_set_u32(22, 0, 0).await; // set_auth = open (0) let mut i = SsidInfo { len: ssid.len() as _, ssid: [0; 32], }; i.ssid[..ssid.len()].copy_from_slice(ssid.as_bytes()); self.ioctl(IoctlType::Set, IOCTL_CMD_SET_SSID, 0, &mut i.to_bytes()) .await; // set_ssid info!("JOINED"); } pub async fn join_wpa2(&mut self, ssid: &str, passphrase: &str) { self.set_iovar_u32("ampdu_ba_wsize", 8).await; self.ioctl_set_u32(134, 0, 4).await; // wsec = wpa2 self.set_iovar_u32x2("bsscfg:sup_wpa", 0, 1).await; self.set_iovar_u32x2("bsscfg:sup_wpa2_eapver", 0, 0xFFFF_FFFF).await; self.set_iovar_u32x2("bsscfg:sup_wpa_tmo", 0, 2500).await; Timer::after(Duration::from_millis(100)).await; let mut pfi = PassphraseInfo { len: passphrase.len() as _, flags: 1, passphrase: [0; 64], }; pfi.passphrase[..passphrase.len()].copy_from_slice(passphrase.as_bytes()); self.ioctl(IoctlType::Set, IOCTL_CMD_SET_PASSPHRASE, 0, &mut pfi.to_bytes()) .await; // WLC_SET_WSEC_PMK self.ioctl_set_u32(20, 0, 1).await; // set_infra = 1 self.ioctl_set_u32(22, 0, 0).await; // set_auth = 0 (open) self.ioctl_set_u32(165, 0, 0x80).await; // set_wpa_auth let mut i = SsidInfo { len: ssid.len() as _, ssid: [0; 32], }; i.ssid[..ssid.len()].copy_from_slice(ssid.as_bytes()); self.ioctl(IoctlType::Set, 26, 0, &mut i.to_bytes()).await; // set_ssid info!("JOINED"); } pub async fn gpio_set(&mut self, gpio_n: u8, gpio_en: bool) { assert!(gpio_n < 3); self.set_iovar_u32x2("gpioout", 1 << gpio_n, if gpio_en { 1 << gpio_n } else { 0 }) .await } async fn set_iovar_u32x2(&mut self, name: &str, val1: u32, val2: u32) { let mut buf = [0; 8]; buf[0..4].copy_from_slice(&val1.to_le_bytes()); buf[4..8].copy_from_slice(&val2.to_le_bytes()); self.set_iovar(name, &buf).await } async fn set_iovar_u32(&mut self, name: &str, val: u32) { self.set_iovar(name, &val.to_le_bytes()).await } async fn get_iovar_u32(&mut self, name: &str) -> u32 { let mut buf = [0; 4]; let len = self.get_iovar(name, &mut buf).await; assert_eq!(len, 4); u32::from_le_bytes(buf) } async fn set_iovar(&mut self, name: &str, val: &[u8]) { info!("set {} = {:02x}", name, val); let mut buf = [0; 64]; buf[..name.len()].copy_from_slice(name.as_bytes()); buf[name.len()] = 0; buf[name.len() + 1..][..val.len()].copy_from_slice(val); let total_len = name.len() + 1 + val.len(); self.ioctl(IoctlType::Set, IOCTL_CMD_SET_VAR, 0, &mut buf[..total_len]) .await; } // TODO this is not really working, it always returns all zeros. async fn get_iovar(&mut self, name: &str, res: &mut [u8]) -> usize { info!("get {}", name); let mut buf = [0; 64]; buf[..name.len()].copy_from_slice(name.as_bytes()); buf[name.len()] = 0; let total_len = max(name.len() + 1, res.len()); let res_len = self .ioctl(IoctlType::Get, IOCTL_CMD_GET_VAR, 0, &mut buf[..total_len]) .await; let out_len = min(res.len(), res_len); res[..out_len].copy_from_slice(&buf[..out_len]); out_len } async fn ioctl_set_u32(&mut self, cmd: u32, iface: u32, val: u32) { let mut buf = val.to_le_bytes(); self.ioctl(IoctlType::Set, cmd, iface, &mut buf).await; } async fn ioctl(&mut self, kind: IoctlType, cmd: u32, iface: u32, buf: &mut [u8]) -> usize { // TODO cancel ioctl on future drop. while !matches!(self.ioctl_state.get(), IoctlState::Idle) { yield_now().await; } self.ioctl_state.set(IoctlState::Pending { kind, cmd, iface, buf }); let resp_len = loop { if let IoctlState::Done { resp_len } = self.ioctl_state.get() { break resp_len; } yield_now().await; }; self.ioctl_state.set(IoctlState::Idle); resp_len } } pub struct Runner<'a, PWR, SPI> { ch: ch::Runner<'a, MTU>, bus: Bus, ioctl_state: &'a Cell, ioctl_id: u16, sdpcm_seq: u8, sdpcm_seq_max: u8, #[cfg(feature = "firmware-logs")] log: LogState, } #[cfg(feature = "firmware-logs")] struct LogState { addr: u32, last_idx: usize, buf: [u8; 256], buf_count: usize, } pub type NetDriver<'a> = ch::Device<'a, MTU>; pub async fn new<'a, PWR, SPI>( state: &'a mut State, pwr: PWR, spi: SPI, firmware: &[u8], ) -> (NetDriver<'a>, Control<'a>, Runner<'a, PWR, SPI>) where PWR: OutputPin, SPI: SpiDevice, SPI::Bus: SpiBusCyw43, { let (ch_runner, device) = ch::new(&mut state.ch, [0; 6]); let state_ch = ch_runner.state_runner(); let mut runner = Runner { ch: ch_runner, bus: Bus::new(pwr, spi), ioctl_state: &state.ioctl_state, ioctl_id: 0, sdpcm_seq: 0, sdpcm_seq_max: 1, #[cfg(feature = "firmware-logs")] log: LogState { addr: 0, last_idx: 0, buf: [0; 256], buf_count: 0, }, }; runner.init(firmware).await; ( device, Control { state_ch, ioctl_state: &state.ioctl_state, }, runner, ) } impl<'a, PWR, SPI> Runner<'a, PWR, SPI> where PWR: OutputPin, SPI: SpiDevice, SPI::Bus: SpiBusCyw43, { async fn init(&mut self, firmware: &[u8]) { self.bus.init().await; // Init ALP (Active Low Power) clock self.bus .write8(FUNC_BACKPLANE, REG_BACKPLANE_CHIP_CLOCK_CSR, BACKPLANE_ALP_AVAIL_REQ) .await; info!("waiting for clock..."); while self.bus.read8(FUNC_BACKPLANE, REG_BACKPLANE_CHIP_CLOCK_CSR).await & BACKPLANE_ALP_AVAIL == 0 {} info!("clock ok"); let chip_id = self.bus.bp_read16(0x1800_0000).await; info!("chip ID: {}", chip_id); // Upload firmware. self.core_disable(Core::WLAN).await; self.core_reset(Core::SOCSRAM).await; self.bus.bp_write32(CHIP.socsram_base_address + 0x10, 3).await; self.bus.bp_write32(CHIP.socsram_base_address + 0x44, 0).await; let ram_addr = CHIP.atcm_ram_base_address; info!("loading fw"); self.bus.bp_write(ram_addr, firmware).await; info!("loading nvram"); // Round up to 4 bytes. let nvram_len = (NVRAM.len() + 3) / 4 * 4; self.bus .bp_write(ram_addr + CHIP.chip_ram_size - 4 - nvram_len as u32, NVRAM) .await; let nvram_len_words = nvram_len as u32 / 4; let nvram_len_magic = (!nvram_len_words << 16) | nvram_len_words; self.bus .bp_write32(ram_addr + CHIP.chip_ram_size - 4, nvram_len_magic) .await; // Start core! info!("starting up core..."); self.core_reset(Core::WLAN).await; assert!(self.core_is_up(Core::WLAN).await); while self.bus.read8(FUNC_BACKPLANE, REG_BACKPLANE_CHIP_CLOCK_CSR).await & 0x80 == 0 {} // "Set up the interrupt mask and enable interrupts" self.bus.bp_write32(CHIP.sdiod_core_base_address + 0x24, 0xF0).await; // "Lower F2 Watermark to avoid DMA Hang in F2 when SD Clock is stopped." // Sounds scary... self.bus .write8(FUNC_BACKPLANE, REG_BACKPLANE_FUNCTION2_WATERMARK, 32) .await; // wait for wifi startup info!("waiting for wifi init..."); while self.bus.read32(FUNC_BUS, REG_BUS_STATUS).await & STATUS_F2_RX_READY == 0 {} // Some random configs related to sleep. // These aren't needed if we don't want to sleep the bus. // TODO do we need to sleep the bus to read the irq line, due to // being on the same pin as MOSI/MISO? /* let mut val = self.bus.read8(FUNC_BACKPLANE, REG_BACKPLANE_WAKEUP_CTRL).await; val |= 0x02; // WAKE_TILL_HT_AVAIL self.bus.write8(FUNC_BACKPLANE, REG_BACKPLANE_WAKEUP_CTRL, val).await; self.bus.write8(FUNC_BUS, 0xF0, 0x08).await; // SDIOD_CCCR_BRCM_CARDCAP.CMD_NODEC = 1 self.bus.write8(FUNC_BACKPLANE, REG_BACKPLANE_CHIP_CLOCK_CSR, 0x02).await; // SBSDIO_FORCE_HT let mut val = self.bus.read8(FUNC_BACKPLANE, REG_BACKPLANE_SLEEP_CSR).await; val |= 0x01; // SBSDIO_SLPCSR_KEEP_SDIO_ON self.bus.write8(FUNC_BACKPLANE, REG_BACKPLANE_SLEEP_CSR, val).await; */ // clear pulls self.bus.write8(FUNC_BACKPLANE, REG_BACKPLANE_PULL_UP, 0).await; let _ = self.bus.read8(FUNC_BACKPLANE, REG_BACKPLANE_PULL_UP).await; // start HT clock //self.bus.write8(FUNC_BACKPLANE, REG_BACKPLANE_CHIP_CLOCK_CSR, 0x10).await; //info!("waiting for HT clock..."); //while self.bus.read8(FUNC_BACKPLANE, REG_BACKPLANE_CHIP_CLOCK_CSR).await & 0x80 == 0 {} //info!("clock ok"); #[cfg(feature = "firmware-logs")] self.log_init().await; info!("init done "); } #[cfg(feature = "firmware-logs")] async fn log_init(&mut self) { // Initialize shared memory for logging. let addr = CHIP.atcm_ram_base_address + CHIP.chip_ram_size - 4 - CHIP.socram_srmem_size; let shared_addr = self.bus.bp_read32(addr).await; info!("shared_addr {:08x}", shared_addr); let mut shared = [0; SharedMemData::SIZE]; self.bus.bp_read(shared_addr, &mut shared).await; let shared = SharedMemData::from_bytes(&shared); info!("shared: {:08x}", shared); self.log.addr = shared.console_addr + 8; } #[cfg(feature = "firmware-logs")] async fn log_read(&mut self) { // Read log struct let mut log = [0; SharedMemLog::SIZE]; self.bus.bp_read(self.log.addr, &mut log).await; let log = SharedMemLog::from_bytes(&log); let idx = log.idx as usize; // If pointer hasn't moved, no need to do anything. if idx == self.log.last_idx { return; } // Read entire buf for now. We could read only what we need, but then we // run into annoying alignment issues in `bp_read`. let mut buf = [0; 0x400]; self.bus.bp_read(log.buf, &mut buf).await; while self.log.last_idx != idx as usize { let b = buf[self.log.last_idx]; if b == b'\r' || b == b'\n' { if self.log.buf_count != 0 { let s = unsafe { core::str::from_utf8_unchecked(&self.log.buf[..self.log.buf_count]) }; debug!("LOGS: {}", s); self.log.buf_count = 0; } } else if self.log.buf_count < self.log.buf.len() { self.log.buf[self.log.buf_count] = b; self.log.buf_count += 1; } self.log.last_idx += 1; if self.log.last_idx == 0x400 { self.log.last_idx = 0; } } } pub async fn run(mut self) -> ! { let mut buf = [0; 512]; loop { #[cfg(feature = "firmware-logs")] self.log_read().await; // Send stuff // TODO flow control not yet complete if !self.has_credit() { warn!("TX stalled"); } else { if let IoctlState::Pending { kind, cmd, iface, buf } = self.ioctl_state.get() { self.send_ioctl(kind, cmd, iface, unsafe { &*buf }).await; self.ioctl_state.set(IoctlState::Sent { buf }); } if !self.has_credit() { warn!("TX stalled"); } else { if let Some(packet) = self.ch.try_tx_buf() { trace!("tx pkt {:02x}", &packet[..packet.len().min(48)]); let mut buf = [0; 512]; let buf8 = slice8_mut(&mut buf); let total_len = SdpcmHeader::SIZE + BcdHeader::SIZE + packet.len(); let seq = self.sdpcm_seq; self.sdpcm_seq = self.sdpcm_seq.wrapping_add(1); let sdpcm_header = SdpcmHeader { len: total_len as u16, // TODO does this len need to be rounded up to u32? len_inv: !total_len as u16, sequence: seq, channel_and_flags: CHANNEL_TYPE_DATA, next_length: 0, header_length: SdpcmHeader::SIZE as _, wireless_flow_control: 0, bus_data_credit: 0, reserved: [0, 0], }; let bcd_header = BcdHeader { flags: BDC_VERSION << BDC_VERSION_SHIFT, priority: 0, flags2: 0, data_offset: 0, }; trace!("tx {:?}", sdpcm_header); trace!(" {:?}", bcd_header); buf8[0..SdpcmHeader::SIZE].copy_from_slice(&sdpcm_header.to_bytes()); buf8[SdpcmHeader::SIZE..][..BcdHeader::SIZE].copy_from_slice(&bcd_header.to_bytes()); buf8[SdpcmHeader::SIZE + BcdHeader::SIZE..][..packet.len()].copy_from_slice(packet); let total_len = (total_len + 3) & !3; // round up to 4byte trace!(" {:02x}", &buf8[..total_len.min(48)]); self.bus.wlan_write(&buf[..(total_len / 4)]).await; self.ch.tx_done(); } } } // Receive stuff let irq = self.bus.read16(FUNC_BUS, REG_BUS_INTERRUPT).await; if irq & IRQ_F2_PACKET_AVAILABLE != 0 { let mut status = 0xFFFF_FFFF; while status == 0xFFFF_FFFF { status = self.bus.read32(FUNC_BUS, REG_BUS_STATUS).await; } if status & STATUS_F2_PKT_AVAILABLE != 0 { let len = (status & STATUS_F2_PKT_LEN_MASK) >> STATUS_F2_PKT_LEN_SHIFT; self.bus.wlan_read(&mut buf, len).await; trace!("rx {:02x}", &slice8_mut(&mut buf)[..(len as usize).min(48)]); self.rx(&slice8_mut(&mut buf)[..len as usize]); } } // TODO use IRQs yield_now().await; } } fn rx(&mut self, packet: &[u8]) { if packet.len() < SdpcmHeader::SIZE { warn!("packet too short, len={}", packet.len()); return; } let sdpcm_header = SdpcmHeader::from_bytes(packet[..SdpcmHeader::SIZE].try_into().unwrap()); trace!("rx {:?}", sdpcm_header); if sdpcm_header.len != !sdpcm_header.len_inv { warn!("len inv mismatch"); return; } if sdpcm_header.len as usize != packet.len() { // TODO: is this guaranteed?? warn!("len from header doesn't match len from spi"); return; } self.update_credit(&sdpcm_header); let channel = sdpcm_header.channel_and_flags & 0x0f; let payload = &packet[sdpcm_header.header_length as _..]; match channel { CHANNEL_TYPE_CONTROL => { if payload.len() < CdcHeader::SIZE { warn!("payload too short, len={}", payload.len()); return; } let cdc_header = CdcHeader::from_bytes(payload[..CdcHeader::SIZE].try_into().unwrap()); trace!(" {:?}", cdc_header); if let IoctlState::Sent { buf } = self.ioctl_state.get() { if cdc_header.id == self.ioctl_id { if cdc_header.status != 0 { // TODO: propagate error instead panic!("IOCTL error {=i32}", cdc_header.status as i32); } let resp_len = cdc_header.len as usize; info!("IOCTL Response: {:02x}", &payload[CdcHeader::SIZE..][..resp_len]); (unsafe { &mut *buf }[..resp_len]).copy_from_slice(&payload[CdcHeader::SIZE..][..resp_len]); self.ioctl_state.set(IoctlState::Done { resp_len }); } } } CHANNEL_TYPE_EVENT => { let bcd_header = BcdHeader::from_bytes(&payload[..BcdHeader::SIZE].try_into().unwrap()); trace!(" {:?}", bcd_header); let packet_start = BcdHeader::SIZE + 4 * bcd_header.data_offset as usize; if packet_start + EventPacket::SIZE > payload.len() { warn!("BCD event, incomplete header"); return; } let bcd_packet = &payload[packet_start..]; trace!(" {:02x}", &bcd_packet[..(bcd_packet.len() as usize).min(36)]); let mut event_packet = EventPacket::from_bytes(&bcd_packet[..EventPacket::SIZE].try_into().unwrap()); event_packet.byteswap(); const ETH_P_LINK_CTL: u16 = 0x886c; // HPNA, wlan link local tunnel, according to linux if_ether.h if event_packet.eth.ether_type != ETH_P_LINK_CTL { warn!( "unexpected ethernet type 0x{:04x}, expected Broadcom ether type 0x{:04x}", event_packet.eth.ether_type, ETH_P_LINK_CTL ); return; } const BROADCOM_OUI: &[u8] = &[0x00, 0x10, 0x18]; if event_packet.hdr.oui != BROADCOM_OUI { warn!( "unexpected ethernet OUI {:02x}, expected Broadcom OUI {:02x}", event_packet.hdr.oui, BROADCOM_OUI ); return; } const BCMILCP_SUBTYPE_VENDOR_LONG: u16 = 32769; if event_packet.hdr.subtype != BCMILCP_SUBTYPE_VENDOR_LONG { warn!("unexpected subtype {}", event_packet.hdr.subtype); return; } const BCMILCP_BCM_SUBTYPE_EVENT: u16 = 1; if event_packet.hdr.user_subtype != BCMILCP_BCM_SUBTYPE_EVENT { warn!("unexpected user_subtype {}", event_packet.hdr.subtype); return; } if event_packet.msg.datalen as usize >= (bcd_packet.len() - EventMessage::SIZE) { warn!("BCD event, incomplete data"); return; } let evt_data = &bcd_packet[EventMessage::SIZE..][..event_packet.msg.datalen as usize]; debug!( "=== EVENT {}: {} {:02x}", events::Event::from(event_packet.msg.event_type as u8), event_packet.msg, evt_data ); } CHANNEL_TYPE_DATA => { let bcd_header = BcdHeader::from_bytes(&payload[..BcdHeader::SIZE].try_into().unwrap()); trace!(" {:?}", bcd_header); let packet_start = BcdHeader::SIZE + 4 * bcd_header.data_offset as usize; if packet_start > payload.len() { warn!("packet start out of range."); return; } let packet = &payload[packet_start..]; trace!("rx pkt {:02x}", &packet[..(packet.len() as usize).min(48)]); match self.ch.try_rx_buf() { Some(buf) => { buf[..packet.len()].copy_from_slice(packet); self.ch.rx_done(packet.len()) } None => warn!("failed to push rxd packet to the channel."), } } _ => {} } } fn update_credit(&mut self, sdpcm_header: &SdpcmHeader) { if sdpcm_header.channel_and_flags & 0xf < 3 { let mut sdpcm_seq_max = sdpcm_header.bus_data_credit; if sdpcm_seq_max.wrapping_sub(self.sdpcm_seq) > 0x40 { sdpcm_seq_max = self.sdpcm_seq + 2; } self.sdpcm_seq_max = sdpcm_seq_max; } } fn has_credit(&self) -> bool { self.sdpcm_seq != self.sdpcm_seq_max && self.sdpcm_seq_max.wrapping_sub(self.sdpcm_seq) & 0x80 == 0 } async fn send_ioctl(&mut self, kind: IoctlType, cmd: u32, iface: u32, data: &[u8]) { let mut buf = [0; 512]; let buf8 = slice8_mut(&mut buf); let total_len = SdpcmHeader::SIZE + CdcHeader::SIZE + data.len(); let sdpcm_seq = self.sdpcm_seq; self.sdpcm_seq = self.sdpcm_seq.wrapping_add(1); self.ioctl_id = self.ioctl_id.wrapping_add(1); let sdpcm_header = SdpcmHeader { len: total_len as u16, // TODO does this len need to be rounded up to u32? len_inv: !total_len as u16, sequence: sdpcm_seq, channel_and_flags: CHANNEL_TYPE_CONTROL, next_length: 0, header_length: SdpcmHeader::SIZE as _, wireless_flow_control: 0, bus_data_credit: 0, reserved: [0, 0], }; let cdc_header = CdcHeader { cmd: cmd, len: data.len() as _, flags: kind as u16 | (iface as u16) << 12, id: self.ioctl_id, status: 0, }; trace!("tx {:?}", sdpcm_header); trace!(" {:?}", cdc_header); buf8[0..SdpcmHeader::SIZE].copy_from_slice(&sdpcm_header.to_bytes()); buf8[SdpcmHeader::SIZE..][..CdcHeader::SIZE].copy_from_slice(&cdc_header.to_bytes()); buf8[SdpcmHeader::SIZE + CdcHeader::SIZE..][..data.len()].copy_from_slice(data); let total_len = (total_len + 3) & !3; // round up to 4byte trace!(" {:02x}", &buf8[..total_len.min(48)]); self.bus.wlan_write(&buf[..total_len / 4]).await; } async fn core_disable(&mut self, core: Core) { let base = core.base_addr(); // Dummy read? let _ = self.bus.bp_read8(base + AI_RESETCTRL_OFFSET).await; // Check it isn't already reset let r = self.bus.bp_read8(base + AI_RESETCTRL_OFFSET).await; if r & AI_RESETCTRL_BIT_RESET != 0 { return; } self.bus.bp_write8(base + AI_IOCTRL_OFFSET, 0).await; let _ = self.bus.bp_read8(base + AI_IOCTRL_OFFSET).await; block_for(Duration::from_millis(1)); self.bus .bp_write8(base + AI_RESETCTRL_OFFSET, AI_RESETCTRL_BIT_RESET) .await; let _ = self.bus.bp_read8(base + AI_RESETCTRL_OFFSET).await; } async fn core_reset(&mut self, core: Core) { self.core_disable(core).await; let base = core.base_addr(); self.bus .bp_write8(base + AI_IOCTRL_OFFSET, AI_IOCTRL_BIT_FGC | AI_IOCTRL_BIT_CLOCK_EN) .await; let _ = self.bus.bp_read8(base + AI_IOCTRL_OFFSET).await; self.bus.bp_write8(base + AI_RESETCTRL_OFFSET, 0).await; Timer::after(Duration::from_millis(1)).await; self.bus .bp_write8(base + AI_IOCTRL_OFFSET, AI_IOCTRL_BIT_CLOCK_EN) .await; let _ = self.bus.bp_read8(base + AI_IOCTRL_OFFSET).await; Timer::after(Duration::from_millis(1)).await; } async fn core_is_up(&mut self, core: Core) -> bool { let base = core.base_addr(); let io = self.bus.bp_read8(base + AI_IOCTRL_OFFSET).await; if io & (AI_IOCTRL_BIT_FGC | AI_IOCTRL_BIT_CLOCK_EN) != AI_IOCTRL_BIT_CLOCK_EN { debug!("core_is_up: returning false due to bad ioctrl {:02x}", io); return false; } let r = self.bus.bp_read8(base + AI_RESETCTRL_OFFSET).await; if r & (AI_RESETCTRL_BIT_RESET) != 0 { debug!("core_is_up: returning false due to bad resetctrl {:02x}", r); return false; } true } } fn slice8_mut(x: &mut [u32]) -> &mut [u8] { let len = x.len() * 4; unsafe { slice::from_raw_parts_mut(x.as_mut_ptr() as _, len) } } macro_rules! nvram { ($($s:literal,)*) => { concat_bytes!($($s, b"\x00",)* b"\x00\x00") }; } static NVRAM: &'static [u8] = &*nvram!( b"NVRAMRev=$Rev$", b"manfid=0x2d0", b"prodid=0x0727", b"vendid=0x14e4", b"devid=0x43e2", b"boardtype=0x0887", b"boardrev=0x1100", b"boardnum=22", b"macaddr=00:A0:50:b5:59:5e", b"sromrev=11", b"boardflags=0x00404001", b"boardflags3=0x04000000", b"xtalfreq=37400", b"nocrc=1", b"ag0=255", b"aa2g=1", b"ccode=ALL", b"pa0itssit=0x20", b"extpagain2g=0", b"pa2ga0=-168,6649,-778", b"AvVmid_c0=0x0,0xc8", b"cckpwroffset0=5", b"maxp2ga0=84", b"txpwrbckof=6", b"cckbw202gpo=0", b"legofdmbw202gpo=0x66111111", b"mcsbw202gpo=0x77711111", b"propbw202gpo=0xdd", b"ofdmdigfilttype=18", b"ofdmdigfilttypebe=18", b"papdmode=1", b"papdvalidtest=1", b"pacalidx2g=45", b"papdepsoffset=-30", b"papdendidx=58", b"ltecxmux=0", b"ltecxpadnum=0x0102", b"ltecxfnsel=0x44", b"ltecxgcigpio=0x01", b"il0macaddr=00:90:4c:c5:12:38", b"wl0id=0x431b", b"deadman_to=0xffffffff", b"muxenab=0x100", b"spurconfig=0x3", b"glitch_based_crsmin=1", b"btc_mode=1", );