embassy/src/lib.rs

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#![no_std]
#![no_main]
#![feature(type_alias_impl_trait, concat_bytes)]
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#![deny(unused_must_use)]
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// This mod MUST go first, so that the others see its macros.
pub(crate) mod fmt;
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mod countries;
mod events;
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mod structs;
use core::cell::Cell;
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use core::cmp::{max, min};
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use core::slice;
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use core::sync::atomic::Ordering;
use core::task::Waker;
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use atomic_polyfill::AtomicBool;
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use embassy_futures::yield_now;
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use embassy_net::{PacketBoxExt, PacketBuf};
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use embassy_sync::blocking_mutex::raw::NoopRawMutex;
use embassy_sync::channel::Channel;
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use embassy_time::{block_for, Duration, Timer};
use embedded_hal_1::digital::blocking::OutputPin;
use embedded_hal_async::spi::{SpiBusRead, SpiBusWrite, SpiDevice};
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use self::structs::*;
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use crate::events::Event;
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fn swap16(x: u32) -> u32 {
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x.rotate_left(16)
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}
fn cmd_word(write: bool, incr: bool, func: u32, addr: u32, len: u32) -> u32 {
(write as u32) << 31 | (incr as u32) << 30 | (func & 0b11) << 28 | (addr & 0x1FFFF) << 11 | (len & 0x7FF)
}
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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) }
}
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const FUNC_BUS: u32 = 0;
const FUNC_BACKPLANE: u32 = 1;
const FUNC_WLAN: u32 = 2;
const FUNC_BT: u32 = 3;
const REG_BUS_CTRL: u32 = 0x0;
const REG_BUS_INTERRUPT: u32 = 0x04; // 16 bits - Interrupt status
const REG_BUS_INTERRUPT_ENABLE: u32 = 0x06; // 16 bits - Interrupt mask
const REG_BUS_STATUS: u32 = 0x8;
const REG_BUS_TEST_RO: u32 = 0x14;
const REG_BUS_TEST_RW: u32 = 0x18;
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const REG_BUS_RESP_DELAY: u32 = 0x1c;
const WORD_LENGTH_32: u32 = 0x1;
const HIGH_SPEED: u32 = 0x10;
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// SPI_STATUS_REGISTER bits
const STATUS_DATA_NOT_AVAILABLE: u32 = 0x00000001;
const STATUS_UNDERFLOW: u32 = 0x00000002;
const STATUS_OVERFLOW: u32 = 0x00000004;
const STATUS_F2_INTR: u32 = 0x00000008;
const STATUS_F3_INTR: u32 = 0x00000010;
const STATUS_F2_RX_READY: u32 = 0x00000020;
const STATUS_F3_RX_READY: u32 = 0x00000040;
const STATUS_HOST_CMD_DATA_ERR: u32 = 0x00000080;
const STATUS_F2_PKT_AVAILABLE: u32 = 0x00000100;
const STATUS_F2_PKT_LEN_MASK: u32 = 0x000FFE00;
const STATUS_F2_PKT_LEN_SHIFT: u32 = 9;
const STATUS_F3_PKT_AVAILABLE: u32 = 0x00100000;
const STATUS_F3_PKT_LEN_MASK: u32 = 0xFFE00000;
const STATUS_F3_PKT_LEN_SHIFT: u32 = 21;
const REG_BACKPLANE_GPIO_SELECT: u32 = 0x10005;
const REG_BACKPLANE_GPIO_OUTPUT: u32 = 0x10006;
const REG_BACKPLANE_GPIO_ENABLE: u32 = 0x10007;
const REG_BACKPLANE_FUNCTION2_WATERMARK: u32 = 0x10008;
const REG_BACKPLANE_DEVICE_CONTROL: u32 = 0x10009;
const REG_BACKPLANE_BACKPLANE_ADDRESS_LOW: u32 = 0x1000A;
const REG_BACKPLANE_BACKPLANE_ADDRESS_MID: u32 = 0x1000B;
const REG_BACKPLANE_BACKPLANE_ADDRESS_HIGH: u32 = 0x1000C;
const REG_BACKPLANE_FRAME_CONTROL: u32 = 0x1000D;
const REG_BACKPLANE_CHIP_CLOCK_CSR: u32 = 0x1000E;
const REG_BACKPLANE_PULL_UP: u32 = 0x1000F;
const REG_BACKPLANE_READ_FRAME_BC_LOW: u32 = 0x1001B;
const REG_BACKPLANE_READ_FRAME_BC_HIGH: u32 = 0x1001C;
const REG_BACKPLANE_WAKEUP_CTRL: u32 = 0x1001E;
const REG_BACKPLANE_SLEEP_CSR: u32 = 0x1001F;
const BACKPLANE_WINDOW_SIZE: usize = 0x8000;
const BACKPLANE_ADDRESS_MASK: u32 = 0x7FFF;
const BACKPLANE_ADDRESS_32BIT_FLAG: u32 = 0x08000;
const BACKPLANE_MAX_TRANSFER_SIZE: usize = 64;
// Broadcom AMBA (Advanced Microcontroller Bus Architecture) Interconnect (AI)
// constants
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const AI_IOCTRL_OFFSET: u32 = 0x408;
const AI_IOCTRL_BIT_FGC: u8 = 0x0002;
const AI_IOCTRL_BIT_CLOCK_EN: u8 = 0x0001;
const AI_IOCTRL_BIT_CPUHALT: u8 = 0x0020;
const AI_RESETCTRL_OFFSET: u32 = 0x800;
const AI_RESETCTRL_BIT_RESET: u8 = 1;
const AI_RESETSTATUS_OFFSET: u32 = 0x804;
const TEST_PATTERN: u32 = 0x12345678;
const FEEDBEAD: u32 = 0xFEEDBEAD;
// SPI_INTERRUPT_REGISTER and SPI_INTERRUPT_ENABLE_REGISTER Bits
const IRQ_DATA_UNAVAILABLE: u16 = 0x0001; // Requested data not available; Clear by writing a "1"
const IRQ_F2_F3_FIFO_RD_UNDERFLOW: u16 = 0x0002;
const IRQ_F2_F3_FIFO_WR_OVERFLOW: u16 = 0x0004;
const IRQ_COMMAND_ERROR: u16 = 0x0008; // Cleared by writing 1
const IRQ_DATA_ERROR: u16 = 0x0010; // Cleared by writing 1
const IRQ_F2_PACKET_AVAILABLE: u16 = 0x0020;
const IRQ_F3_PACKET_AVAILABLE: u16 = 0x0040;
const IRQ_F1_OVERFLOW: u16 = 0x0080; // Due to last write. Bkplane has pending write requests
const IRQ_MISC_INTR0: u16 = 0x0100;
const IRQ_MISC_INTR1: u16 = 0x0200;
const IRQ_MISC_INTR2: u16 = 0x0400;
const IRQ_MISC_INTR3: u16 = 0x0800;
const IRQ_MISC_INTR4: u16 = 0x1000;
const IRQ_F1_INTR: u16 = 0x2000;
const IRQ_F2_INTR: u16 = 0x4000;
const IRQ_F3_INTR: u16 = 0x8000;
#[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,
}
}
}
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)]
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enum IoctlState {
Idle,
Pending {
kind: u32,
cmd: u32,
iface: u32,
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buf: *mut [u8],
},
Sent {
buf: *mut [u8],
},
Done {
resp_len: usize,
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},
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}
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pub struct State {
ioctl_state: Cell<IoctlState>,
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tx_channel: Channel<NoopRawMutex, PacketBuf, 8>,
rx_channel: Channel<NoopRawMutex, PacketBuf, 8>,
link_up: AtomicBool,
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}
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impl State {
pub fn new() -> Self {
Self {
ioctl_state: Cell::new(IoctlState::Idle),
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tx_channel: Channel::new(),
rx_channel: Channel::new(),
link_up: AtomicBool::new(true), // TODO set up/down as we join/deassociate
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}
}
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}
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pub struct Control<'a> {
state: &'a State,
}
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impl<'a> Control<'a> {
pub async fn init(&mut self, clm: &[u8]) -> NetDevice<'a> {
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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);
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self.ioctl(2, 263, 0, &mut buf[..8 + 12 + chunk.len()]).await;
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}
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// check clmload ok
assert_eq!(self.get_iovar_u32("clmload_status").await, 0);
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info!("Configuring misc stuff...");
self.set_iovar_u32("bus:txglom", 0).await;
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self.set_iovar_u32("apsta", 1).await;
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// 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);
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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;
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self.ioctl_set_u32(64, 0, 0).await; // WLC_SET_ANTDIV
self.set_iovar_u32("bus:txglom", 0).await;
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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;
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self.set_iovar_u32("ampdu_ba_wsize", 8).await;
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Timer::after(Duration::from_millis(100)).await;
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self.set_iovar_u32("ampdu_mpdu", 4).await;
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Timer::after(Duration::from_millis(100)).await;
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//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],
};
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// 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;
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Timer::after(Duration::from_millis(100)).await;
// set wifi up
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self.ioctl(2, 2, 0, &mut []).await;
Timer::after(Duration::from_millis(100)).await;
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// power save mode 2
self.set_iovar_u32("pm2_sleep_ret", 0xc8).await;
self.set_iovar_u32("bcn_li_bcn", 1).await;
self.set_iovar_u32("bcn_li_dtim", 1).await;
self.set_iovar_u32("assoc_listen", 10).await;
self.ioctl_set_u32(0x86, 0, 2).await;
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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;
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info!("INIT DONE");
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NetDevice {
state: self.state,
mac_addr,
}
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}
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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());
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self.ioctl(2, 26, 0, &mut i.to_bytes()).await; // set_ssid
info!("JOINED");
}
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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(2, 268, 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(2, 26, 0, &mut i.to_bytes()).await; // set_ssid
info!("JOINED");
}
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
}
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async fn set_iovar_u32(&mut self, name: &str, val: u32) {
self.set_iovar(name, &val.to_le_bytes()).await
}
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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)
}
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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();
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self.ioctl(2, 263, 0, &mut buf[..total_len]).await;
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}
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// TODO this is not really working, it always returns all zeros.
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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;
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let total_len = max(name.len() + 1, res.len());
let res_len = self.ioctl(0, 262, 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
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}
async fn ioctl_set_u32(&mut self, cmd: u32, iface: u32, val: u32) {
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let mut buf = val.to_le_bytes();
self.ioctl(2, cmd, 0, &mut buf).await;
}
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async fn ioctl(&mut self, kind: u32, cmd: u32, iface: u32, buf: &mut [u8]) -> usize {
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// TODO cancel ioctl on future drop.
while !matches!(self.state.ioctl_state.get(), IoctlState::Idle) {
yield_now().await;
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}
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self.state
.ioctl_state
.set(IoctlState::Pending { kind, cmd, iface, buf });
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let resp_len = loop {
if let IoctlState::Done { resp_len } = self.state.ioctl_state.get() {
break resp_len;
}
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yield_now().await;
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};
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self.state.ioctl_state.set(IoctlState::Idle);
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resp_len
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}
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}
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pub struct NetDevice<'a> {
state: &'a State,
mac_addr: [u8; 6],
}
impl<'a> embassy_net::Device for NetDevice<'a> {
fn register_waker(&mut self, waker: &Waker) {
// loopy loopy wakey wakey
waker.wake_by_ref()
}
fn link_state(&mut self) -> embassy_net::LinkState {
match self.state.link_up.load(Ordering::Relaxed) {
true => embassy_net::LinkState::Up,
false => embassy_net::LinkState::Down,
}
}
fn capabilities(&self) -> embassy_net::DeviceCapabilities {
let mut caps = embassy_net::DeviceCapabilities::default();
caps.max_transmission_unit = 1514; // 1500 IP + 14 ethernet header
caps.medium = embassy_net::Medium::Ethernet;
caps
}
fn is_transmit_ready(&mut self) -> bool {
true
}
fn transmit(&mut self, pkt: PacketBuf) {
if self.state.tx_channel.try_send(pkt).is_err() {
warn!("TX failed")
}
}
fn receive(&mut self) -> Option<PacketBuf> {
self.state.rx_channel.try_recv().ok()
}
fn ethernet_address(&self) -> [u8; 6] {
self.mac_addr
}
}
pub struct Runner<'a, PWR, SPI> {
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state: &'a State,
pwr: PWR,
spi: SPI,
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ioctl_id: u16,
sdpcm_seq: u8,
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backplane_window: u32,
tx_seq_max: u8,
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}
pub async fn new<'a, PWR, SPI>(
state: &'a State,
pwr: PWR,
spi: SPI,
firmware: &[u8],
) -> (Control<'a>, Runner<'a, PWR, SPI>)
where
PWR: OutputPin,
SPI: SpiDevice,
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SPI::Bus: SpiBusRead<u32> + SpiBusWrite<u32>,
{
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let mut runner = Runner {
state,
pwr,
spi,
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ioctl_id: 0,
sdpcm_seq: 0,
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backplane_window: 0xAAAA_AAAA,
tx_seq_max: 1,
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};
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runner.init(firmware).await;
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(Control { state }, runner)
}
impl<'a, PWR, SPI> Runner<'a, PWR, SPI>
where
PWR: OutputPin,
SPI: SpiDevice,
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SPI::Bus: SpiBusRead<u32> + SpiBusWrite<u32>,
{
async fn init(&mut self, firmware: &[u8]) {
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// Reset
self.pwr.set_low().unwrap();
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Timer::after(Duration::from_millis(20)).await;
self.pwr.set_high().unwrap();
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Timer::after(Duration::from_millis(250)).await;
info!("waiting for ping...");
while self.read32_swapped(REG_BUS_TEST_RO).await != FEEDBEAD {}
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info!("ping ok");
self.write32_swapped(REG_BUS_TEST_RW, TEST_PATTERN).await;
let val = self.read32_swapped(REG_BUS_TEST_RW).await;
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assert_eq!(val, TEST_PATTERN);
// 32-bit word length, little endian (which is the default endianess).
self.write32_swapped(REG_BUS_CTRL, WORD_LENGTH_32 | HIGH_SPEED).await;
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let val = self.read32(FUNC_BUS, REG_BUS_TEST_RO).await;
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assert_eq!(val, FEEDBEAD);
let val = self.read32(FUNC_BUS, REG_BUS_TEST_RW).await;
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assert_eq!(val, TEST_PATTERN);
// No response delay in any of the funcs.
// seems to break backplane??? eat the 4-byte delay instead, that's what the vendor drivers do...
//self.write32(FUNC_BUS, REG_BUS_RESP_DELAY, 0).await;
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// Init ALP (no idea what that stands for) clock
self.write8(FUNC_BACKPLANE, REG_BACKPLANE_CHIP_CLOCK_CSR, 0x08).await;
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info!("waiting for clock...");
while self.read8(FUNC_BACKPLANE, REG_BACKPLANE_CHIP_CLOCK_CSR).await & 0x40 == 0 {}
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info!("clock ok");
let chip_id = self.bp_read16(0x1800_0000).await;
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info!("chip ID: {}", chip_id);
// Upload firmware.
self.core_disable(Core::WLAN).await;
self.core_reset(Core::SOCSRAM).await;
self.bp_write32(CHIP.socsram_base_address + 0x10, 3).await;
self.bp_write32(CHIP.socsram_base_address + 0x44, 0).await;
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let ram_addr = CHIP.atcm_ram_base_address;
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info!("loading fw");
self.bp_write(ram_addr, firmware).await;
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info!("loading nvram");
// Round up to 4 bytes.
let nvram_len = (NVRAM.len() + 3) / 4 * 4;
self.bp_write(ram_addr + CHIP.chip_ram_size - 4 - nvram_len as u32, NVRAM)
.await;
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let nvram_len_words = nvram_len as u32 / 4;
let nvram_len_magic = (!nvram_len_words << 16) | nvram_len_words;
self.bp_write32(ram_addr + CHIP.chip_ram_size - 4, nvram_len_magic)
.await;
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// Start core!
info!("starting up core...");
self.core_reset(Core::WLAN).await;
assert!(self.core_is_up(Core::WLAN).await);
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while self.read8(FUNC_BACKPLANE, REG_BACKPLANE_CHIP_CLOCK_CSR).await & 0x80 == 0 {}
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// "Set up the interrupt mask and enable interrupts"
self.bp_write32(CHIP.sdiod_core_base_address + 0x24, 0xF0).await;
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// "Lower F2 Watermark to avoid DMA Hang in F2 when SD Clock is stopped."
// Sounds scary...
self.write8(FUNC_BACKPLANE, REG_BACKPLANE_FUNCTION2_WATERMARK, 32).await;
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// wait for wifi startup
info!("waiting for wifi init...");
while self.read32(FUNC_BUS, REG_BUS_STATUS).await & STATUS_F2_RX_READY == 0 {}
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// Some random configs related to sleep.
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// 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?
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/*
let mut val = self.read8(FUNC_BACKPLANE, REG_BACKPLANE_WAKEUP_CTRL).await;
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val |= 0x02; // WAKE_TILL_HT_AVAIL
self.write8(FUNC_BACKPLANE, REG_BACKPLANE_WAKEUP_CTRL, val).await;
self.write8(FUNC_BUS, 0xF0, 0x08).await; // SDIOD_CCCR_BRCM_CARDCAP.CMD_NODEC = 1
self.write8(FUNC_BACKPLANE, REG_BACKPLANE_CHIP_CLOCK_CSR, 0x02).await; // SBSDIO_FORCE_HT
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let mut val = self.read8(FUNC_BACKPLANE, REG_BACKPLANE_SLEEP_CSR).await;
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val |= 0x01; // SBSDIO_SLPCSR_KEEP_SDIO_ON
self.write8(FUNC_BACKPLANE, REG_BACKPLANE_SLEEP_CSR, val).await;
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*/
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// clear pulls
self.write8(FUNC_BACKPLANE, REG_BACKPLANE_PULL_UP, 0).await;
let _ = self.read8(FUNC_BACKPLANE, REG_BACKPLANE_PULL_UP).await;
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// start HT clock
//self.write8(FUNC_BACKPLANE, REG_BACKPLANE_CHIP_CLOCK_CSR, 0x10).await;
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//info!("waiting for HT clock...");
//while self.read8(FUNC_BACKPLANE, REG_BACKPLANE_CHIP_CLOCK_CSR).await & 0x80 == 0 {}
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//info!("clock ok");
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info!("init done ");
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}
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pub async fn run(mut self) -> ! {
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let mut buf = [0; 512];
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loop {
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// Send stuff
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// TODO flow control
if self.sdpcm_seq == self.tx_seq_max || self.tx_seq_max.wrapping_sub(self.sdpcm_seq) & 0x80 != 0 {
warn!("TX stalled");
} else {
if let IoctlState::Pending { kind, cmd, iface, buf } = self.state.ioctl_state.get() {
self.send_ioctl(kind, cmd, iface, unsafe { &*buf }).await;
self.state.ioctl_state.set(IoctlState::Sent { buf });
}
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if let Ok(p) = self.state.tx_channel.try_recv() {
self.send_packet(&p).await;
}
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}
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// Receive stuff
let irq = self.read16(FUNC_BUS, REG_BUS_INTERRUPT).await;
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if irq & IRQ_F2_PACKET_AVAILABLE != 0 {
let mut status = 0xFFFF_FFFF;
while status == 0xFFFF_FFFF {
status = self.read32(FUNC_BUS, REG_BUS_STATUS).await;
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}
if status & STATUS_F2_PKT_AVAILABLE != 0 {
let len = (status & STATUS_F2_PKT_LEN_MASK) >> STATUS_F2_PKT_LEN_SHIFT;
let cmd = cmd_word(false, true, FUNC_WLAN, 0, len);
self.spi
.transaction(|bus| {
let bus = unsafe { &mut *bus };
async {
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bus.write(&[cmd]).await?;
bus.read(&mut buf[..(len as usize + 3) / 4]).await?;
Ok(())
}
})
.await
.unwrap();
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trace!("rx {:02x}", &slice8_mut(&mut buf)[..(len as usize).min(48)]);
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self.rx(&slice8_mut(&mut buf)[..len as usize]);
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}
}
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// TODO use IRQs
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yield_now().await;
}
}
async fn send_packet(&mut self, packet: &[u8]) {
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trace!("tx pkt {:02x}", &packet[..packet.len().min(48)]);
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let mut buf = [0; 512];
let buf8 = slice8_mut(&mut buf);
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let total_len = SdpcmHeader::SIZE + BcdHeader::SIZE + packet.len();
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let seq = self.sdpcm_seq;
self.sdpcm_seq = self.sdpcm_seq.wrapping_add(1);
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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: 2, // data channel
next_length: 0,
header_length: SdpcmHeader::SIZE as _,
wireless_flow_control: 0,
bus_data_credit: 0,
reserved: [0, 0],
};
let bcd_header = BcdHeader {
flags: 0x20,
priority: 0,
flags2: 0,
data_offset: 0,
};
trace!("tx {:?}", sdpcm_header);
trace!(" {:?}", bcd_header);
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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);
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let total_len = (total_len + 3) & !3; // round up to 4byte
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trace!(" {:02x}", &buf8[..total_len.min(48)]);
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let cmd = cmd_word(true, true, FUNC_WLAN, 0, total_len as _);
self.spi
.transaction(|bus| {
let bus = unsafe { &mut *bus };
async {
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bus.write(&[cmd]).await?;
bus.write(&buf[..(total_len / 4)]).await?;
Ok(())
}
})
.await
.unwrap();
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}
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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());
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trace!("rx {:?}", sdpcm_header);
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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);
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let channel = sdpcm_header.channel_and_flags & 0x0f;
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let payload = &packet[sdpcm_header.header_length as _..];
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match channel {
0 => {
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if payload.len() < CdcHeader::SIZE {
warn!("payload too short, len={}", payload.len());
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return;
}
let cdc_header = CdcHeader::from_bytes(payload[..CdcHeader::SIZE].try_into().unwrap());
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trace!(" {:?}", cdc_header);
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if let IoctlState::Sent { buf } = self.state.ioctl_state.get() {
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if cdc_header.id == self.ioctl_id {
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assert_eq!(cdc_header.status, 0); // todo propagate error instead
let resp_len = cdc_header.len as usize;
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info!("IOCTL Response: {:02x}", &payload[CdcHeader::SIZE..][..resp_len]);
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(unsafe { &mut *buf }[..resp_len]).copy_from_slice(&payload[CdcHeader::SIZE..][..resp_len]);
self.state.ioctl_state.set(IoctlState::Done { resp_len });
}
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}
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}
1 => {
let bcd_header = BcdHeader::from_bytes(&payload[..BcdHeader::SIZE].try_into().unwrap());
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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];
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debug!(
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"=== EVENT {}: {} {:02x}",
events::Event::from(event_packet.msg.event_type as u8),
event_packet.msg,
evt_data
);
}
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2 => {
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)]);
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let mut p = unwrap!(embassy_net::PacketBox::new(embassy_net::Packet::new()));
p[..packet.len()].copy_from_slice(packet);
if let Err(_) = self.state.rx_channel.try_send(p.slice(0..packet.len())) {
warn!("failed to push rxd packet to the channel.")
}
}
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_ => {}
}
}
fn update_credit(&mut self, sdpcm_header: &SdpcmHeader) {
if sdpcm_header.channel_and_flags & 0xf < 3 {
let mut tx_seq_max = sdpcm_header.bus_data_credit;
if tx_seq_max - self.sdpcm_seq > 0x40 {
tx_seq_max = self.sdpcm_seq + 2;
}
self.tx_seq_max = tx_seq_max;
}
}
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async fn send_ioctl(&mut self, kind: u32, cmd: u32, iface: u32, data: &[u8]) {
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let mut buf = [0; 512];
let buf8 = slice8_mut(&mut buf);
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let total_len = SdpcmHeader::SIZE + CdcHeader::SIZE + data.len();
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let sdpcm_seq = self.sdpcm_seq;
self.sdpcm_seq = self.sdpcm_seq.wrapping_add(1);
self.ioctl_id = self.ioctl_id.wrapping_add(1);
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let sdpcm_header = SdpcmHeader {
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len: total_len as u16, // TODO does this len need to be rounded up to u32?
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len_inv: !total_len as u16,
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sequence: sdpcm_seq,
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channel_and_flags: 0, // control channel
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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,
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len: data.len() as _,
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flags: kind as u16 | (iface as u16) << 12,
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id: self.ioctl_id,
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status: 0,
};
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trace!("tx {:?}", sdpcm_header);
trace!(" {:?}", cdc_header);
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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);
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let total_len = (total_len + 3) & !3; // round up to 4byte
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trace!(" {:02x}", &buf8[..total_len.min(48)]);
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let cmd = cmd_word(true, true, FUNC_WLAN, 0, total_len as _);
self.spi
.transaction(|bus| {
let bus = unsafe { &mut *bus };
async {
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bus.write(&[cmd]).await?;
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bus.write(&buf[..total_len / 4]).await?;
Ok(())
}
})
.await
.unwrap();
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}
async fn core_disable(&mut self, core: Core) {
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let base = core.base_addr();
// Dummy read?
let _ = self.bp_read8(base + AI_RESETCTRL_OFFSET).await;
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// Check it isn't already reset
let r = self.bp_read8(base + AI_RESETCTRL_OFFSET).await;
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if r & AI_RESETCTRL_BIT_RESET != 0 {
return;
}
self.bp_write8(base + AI_IOCTRL_OFFSET, 0).await;
let _ = self.bp_read8(base + AI_IOCTRL_OFFSET).await;
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block_for(Duration::from_millis(1));
self.bp_write8(base + AI_RESETCTRL_OFFSET, AI_RESETCTRL_BIT_RESET).await;
let _ = self.bp_read8(base + AI_RESETCTRL_OFFSET).await;
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}
async fn core_reset(&mut self, core: Core) {
self.core_disable(core).await;
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let base = core.base_addr();
self.bp_write8(base + AI_IOCTRL_OFFSET, AI_IOCTRL_BIT_FGC | AI_IOCTRL_BIT_CLOCK_EN)
.await;
let _ = self.bp_read8(base + AI_IOCTRL_OFFSET).await;
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self.bp_write8(base + AI_RESETCTRL_OFFSET, 0).await;
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Timer::after(Duration::from_millis(1)).await;
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self.bp_write8(base + AI_IOCTRL_OFFSET, AI_IOCTRL_BIT_CLOCK_EN).await;
let _ = self.bp_read8(base + AI_IOCTRL_OFFSET).await;
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Timer::after(Duration::from_millis(1)).await;
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}
async fn core_is_up(&mut self, core: Core) -> bool {
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let base = core.base_addr();
let io = self.bp_read8(base + AI_IOCTRL_OFFSET).await;
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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.bp_read8(base + AI_RESETCTRL_OFFSET).await;
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if r & (AI_RESETCTRL_BIT_RESET) != 0 {
debug!("core_is_up: returning false due to bad resetctrl {:02x}", r);
return false;
}
true
}
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async fn bp_read(&mut self, mut addr: u32, mut data: &mut [u32]) {
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// It seems the HW force-aligns the addr
// to 2 if data.len() >= 2
// to 4 if data.len() >= 4
// To simplify, enforce 4-align for now.
assert!(addr % 4 == 0);
while !data.is_empty() {
// Ensure transfer doesn't cross a window boundary.
let window_offs = addr & BACKPLANE_ADDRESS_MASK;
let window_remaining = BACKPLANE_WINDOW_SIZE - window_offs as usize;
let len = data.len().min(BACKPLANE_MAX_TRANSFER_SIZE).min(window_remaining);
self.backplane_set_window(addr).await;
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let cmd = cmd_word(false, true, FUNC_BACKPLANE, window_offs, len as u32);
self.spi
.transaction(|bus| {
let bus = unsafe { &mut *bus };
async {
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bus.write(&[cmd]).await?;
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// 4-byte response delay.
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let mut junk = [0; 1];
bus.read(&mut junk).await?;
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// Read data
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bus.read(&mut data[..len / 4]).await?;
Ok(())
}
})
.await
.unwrap();
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// Advance ptr.
addr += len as u32;
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data = &mut data[len / 4..];
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}
}
async fn bp_write(&mut self, mut addr: u32, mut data: &[u8]) {
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// It seems the HW force-aligns the addr
// to 2 if data.len() >= 2
// to 4 if data.len() >= 4
// To simplify, enforce 4-align for now.
assert!(addr % 4 == 0);
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let mut buf = [0u32; BACKPLANE_MAX_TRANSFER_SIZE / 4];
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while !data.is_empty() {
// Ensure transfer doesn't cross a window boundary.
let window_offs = addr & BACKPLANE_ADDRESS_MASK;
let window_remaining = BACKPLANE_WINDOW_SIZE - window_offs as usize;
let len = data.len().min(BACKPLANE_MAX_TRANSFER_SIZE).min(window_remaining);
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slice8_mut(&mut buf)[..len].copy_from_slice(&data[..len]);
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self.backplane_set_window(addr).await;
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let cmd = cmd_word(true, true, FUNC_BACKPLANE, window_offs, len as u32);
self.spi
.transaction(|bus| {
let bus = unsafe { &mut *bus };
async {
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bus.write(&[cmd]).await?;
bus.write(&buf[..(len + 3) / 4]).await?;
Ok(())
}
})
.await
.unwrap();
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// Advance ptr.
addr += len as u32;
data = &data[len..];
}
}
async fn bp_read8(&mut self, addr: u32) -> u8 {
self.backplane_readn(addr, 1).await as u8
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}
async fn bp_write8(&mut self, addr: u32, val: u8) {
self.backplane_writen(addr, val as u32, 1).await
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}
async fn bp_read16(&mut self, addr: u32) -> u16 {
self.backplane_readn(addr, 2).await as u16
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}
async fn bp_write16(&mut self, addr: u32, val: u16) {
self.backplane_writen(addr, val as u32, 2).await
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}
async fn bp_read32(&mut self, addr: u32) -> u32 {
self.backplane_readn(addr, 4).await
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}
async fn bp_write32(&mut self, addr: u32, val: u32) {
self.backplane_writen(addr, val, 4).await
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}
async fn backplane_readn(&mut self, addr: u32, len: u32) -> u32 {
self.backplane_set_window(addr).await;
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let mut bus_addr = addr & BACKPLANE_ADDRESS_MASK;
if len == 4 {
bus_addr |= BACKPLANE_ADDRESS_32BIT_FLAG
}
self.readn(FUNC_BACKPLANE, bus_addr, len).await
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}
async fn backplane_writen(&mut self, addr: u32, val: u32, len: u32) {
self.backplane_set_window(addr).await;
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let mut bus_addr = addr & BACKPLANE_ADDRESS_MASK;
if len == 4 {
bus_addr |= BACKPLANE_ADDRESS_32BIT_FLAG
}
self.writen(FUNC_BACKPLANE, bus_addr, val, len).await
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}
async fn backplane_set_window(&mut self, addr: u32) {
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let new_window = addr & !BACKPLANE_ADDRESS_MASK;
if (new_window >> 24) as u8 != (self.backplane_window >> 24) as u8 {
self.write8(
FUNC_BACKPLANE,
REG_BACKPLANE_BACKPLANE_ADDRESS_HIGH,
(new_window >> 24) as u8,
)
.await;
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}
if (new_window >> 16) as u8 != (self.backplane_window >> 16) as u8 {
self.write8(
FUNC_BACKPLANE,
REG_BACKPLANE_BACKPLANE_ADDRESS_MID,
(new_window >> 16) as u8,
)
.await;
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}
if (new_window >> 8) as u8 != (self.backplane_window >> 8) as u8 {
self.write8(
FUNC_BACKPLANE,
REG_BACKPLANE_BACKPLANE_ADDRESS_LOW,
(new_window >> 8) as u8,
)
.await;
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}
self.backplane_window = new_window;
}
async fn read8(&mut self, func: u32, addr: u32) -> u8 {
self.readn(func, addr, 1).await as u8
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}
async fn write8(&mut self, func: u32, addr: u32, val: u8) {
self.writen(func, addr, val as u32, 1).await
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}
async fn read16(&mut self, func: u32, addr: u32) -> u16 {
self.readn(func, addr, 2).await as u16
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}
async fn write16(&mut self, func: u32, addr: u32, val: u16) {
self.writen(func, addr, val as u32, 2).await
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}
async fn read32(&mut self, func: u32, addr: u32) -> u32 {
self.readn(func, addr, 4).await
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}
async fn write32(&mut self, func: u32, addr: u32, val: u32) {
self.writen(func, addr, val, 4).await
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}
async fn readn(&mut self, func: u32, addr: u32, len: u32) -> u32 {
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let cmd = cmd_word(false, true, func, addr, len);
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let mut buf = [0; 1];
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self.spi
.transaction(|bus| {
let bus = unsafe { &mut *bus };
async {
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bus.write(&[cmd]).await?;
if func == FUNC_BACKPLANE {
// 4-byte response delay.
bus.read(&mut buf).await?;
}
bus.read(&mut buf).await?;
Ok(())
}
})
.await
.unwrap();
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buf[0]
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}
async fn writen(&mut self, func: u32, addr: u32, val: u32, len: u32) {
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let cmd = cmd_word(true, true, func, addr, len);
self.spi
.transaction(|bus| {
let bus = unsafe { &mut *bus };
async {
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bus.write(&[cmd, val]).await?;
Ok(())
}
})
.await
.unwrap();
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}
async fn read32_swapped(&mut self, addr: u32) -> u32 {
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let cmd = cmd_word(false, true, FUNC_BUS, addr, 4);
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let mut buf = [0; 1];
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self.spi
.transaction(|bus| {
let bus = unsafe { &mut *bus };
async {
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bus.write(&[swap16(cmd)]).await?;
bus.read(&mut buf).await?;
Ok(())
}
})
.await
.unwrap();
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swap16(buf[0])
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}
async fn write32_swapped(&mut self, addr: u32, val: u32) {
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let cmd = cmd_word(true, true, FUNC_BUS, addr, 4);
self.spi
.transaction(|bus| {
let bus = unsafe { &mut *bus };
async {
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bus.write(&[swap16(cmd), swap16(val)]).await?;
Ok(())
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}
})
.await
.unwrap();
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}
}
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",
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b"macaddr=00:A0:50:b5:59:5e",
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b"sromrev=11",
b"boardflags=0x00404001",
b"boardflags3=0x04000000",
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b"xtalfreq=37400",
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b"nocrc=1",
b"ag0=255",
b"aa2g=1",
b"ccode=ALL",
b"pa0itssit=0x20",
b"extpagain2g=0",
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b"pa2ga0=-168,6649,-778",
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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",
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b"muxenab=0x100",
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b"spurconfig=0x3",
b"glitch_based_crsmin=1",
b"btc_mode=1",
);