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lora ai changes not fixed probably

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This commit is contained in:
shinya 2026-05-22 14:23:37 +02:00
parent 7f1aabb280
commit 45a60d64b9
5 changed files with 411 additions and 222 deletions
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63
chip_test_example/deploy.sh Executable file
View File

@ -0,0 +1,63 @@
#!/bin/sh
KEY="/home/shinya/.ssh/malnus"
SRC="../chip_test_example"
DST="/home/me/"
deploy_and_build() {
HOST=$1
TOTAL_START=$(date +%s)
echo "[$HOST] Copying..."
SCP_START=$(date +%s)
scp -i "$KEY" -r "$SRC" me@$HOST:$DST || return 1
SCP_END=$(date +%s)
SCP_TIME=$((SCP_END - SCP_START))
echo "[$HOST] Copy completed in ${SCP_TIME}s"
echo "[$HOST] Building..."
BUILD_START=$(date +%s)
ssh -i "$KEY" me@$HOST \
"cd $DST/chip_test_example && make -j4"
BUILD_STATUS=$?
BUILD_END=$(date +%s)
BUILD_TIME=$((BUILD_END - BUILD_START))
TOTAL_END=$(date +%s)
TOTAL_TIME=$((TOTAL_END - TOTAL_START))
echo "[$HOST] Build completed in ${BUILD_TIME}s"
echo "[$HOST] Total time: ${TOTAL_TIME}s"
return $BUILD_STATUS
}
deploy_and_build 10.91.51.165 &
PID1=$!
deploy_and_build 10.91.51.166 &
PID2=$!
wait $PID1
STATUS1=$?
wait $PID2
STATUS2=$?
echo "----------------------------------------"
echo "10.91.51.165 status: $STATUS1"
echo "10.91.51.166 status: $STATUS2"
if [ $STATUS1 -ne 0 ] || [ $STATUS2 -ne 0 ]; then
echo "One or more builds failed"
exit 1
fi
echo "All builds completed successfully"

45
chip_test_example/icm20948.hpp
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@ -19,6 +19,7 @@
#include <initializer_list>
#include <thread>
#include <cerrno>
#include <fcntl.h>
#include <linux/i2c-dev.h>
#include <linux/i2c.h>
@ -36,6 +37,7 @@ constexpr uint8_t REG_ACCEL_XOUT_H = 0x2D;
constexpr uint8_t REG_GYRO_XOUT_H = 0x33;
constexpr uint8_t REG_TEMP_OUT_H = 0x39;
constexpr uint8_t REG_INT_STATUS = 0x19;
constexpr uint8_t REG_INT_STATUS_1 = 0x1A; // bit0 = RAW_DATA_0_RDY_INT
constexpr uint8_t REG_BANK_SEL = 0x7F;
// ---- Register map (Bank 2) -------------------------------------------------
@ -113,7 +115,12 @@ inline bool Imu::writeReg(uint8_t reg, uint8_t val)
i2c_rdwr_ioctl_data io{};
io.msgs = &msg;
io.nmsgs = 1;
return ioctl(fd_, I2C_RDWR, &io) == 1;
if (ioctl(fd_, I2C_RDWR, &io) == 1)
return true;
if (cfg_.verbose)
std::fprintf(stderr, "[icm20948] write 0x%02X=0x%02X failed at 0x%02X: %s\n",
reg, val, addr_, std::strerror(errno));
return false;
}
inline bool Imu::readRegs(uint8_t reg, uint8_t *buf, uint8_t n)
@ -131,13 +138,19 @@ inline bool Imu::readRegs(uint8_t reg, uint8_t *buf, uint8_t n)
i2c_rdwr_ioctl_data io{};
io.msgs = msgs;
io.nmsgs = 2;
return ioctl(fd_, I2C_RDWR, &io) == 2;
if (ioctl(fd_, I2C_RDWR, &io) == 2)
return true;
if (cfg_.verbose)
std::fprintf(stderr, "[icm20948] read 0x%02X (%u B) failed at 0x%02X: %s\n",
reg, n, addr_, std::strerror(errno));
return false;
}
inline uint8_t Imu::readReg(uint8_t reg)
{
uint8_t v = 0;
readRegs(reg, &v, 1);
if (!readRegs(reg, &v, 1) && cfg_.verbose)
std::fprintf(stderr, "[icm20948] readReg(0x%02X) → no data (check NACK / wiring)\n", reg);
return v;
}
@ -162,8 +175,11 @@ inline bool Imu::begin(const Config &c)
for (uint8_t a : {(uint8_t)0x68, (uint8_t)0x69}) {
addr_ = a;
// Ensure bank 0 before reading WHO_AM_I
writeReg(REG_BANK_SEL, 0x00);
uint8_t id = readReg(REG_WHO_AM_I);
if (!writeReg(REG_BANK_SEL, 0x00))
continue;
uint8_t id = 0;
if (!readRegs(REG_WHO_AM_I, &id, 1))
continue;
if (c.verbose)
std::fprintf(stderr, "[icm20948] probe 0x%02X → WHO_AM_I = 0x%02X\n", a, id);
if (id == WHO_AM_I_VAL) { found = true; break; }
@ -198,6 +214,9 @@ inline bool Imu::begin(const Config &c)
return false;
}
// Disable internal I2C master (mag interface) — matches Adafruit begin_I2C().
writeReg(REG_USER_CTRL, 0x00);
// Wake up: auto-select clock source (best practice per datasheet).
writeReg(REG_PWR_MGMT_1, 0x01);
std::this_thread::sleep_for(std::chrono::milliseconds(30));
@ -230,19 +249,25 @@ inline void Imu::end()
inline bool Imu::read(RawSample &raw)
{
selectBank(0);
// Wait for fresh accel/gyro/temp (datasheet: INT_STATUS_1 bit0 RAW_DATA_0_RDY_INT).
for (int i = 0; i < 50; ++i) {
if (readReg(REG_INT_STATUS_1) & 0x01) break;
std::this_thread::sleep_for(std::chrono::milliseconds(1));
}
uint8_t buf[14]{};
if (!readRegs(REG_ACCEL_XOUT_H, buf, 14)) return false;
auto s16 = [](uint8_t hi, uint8_t lo) -> int16_t {
return (int16_t)((uint16_t)hi << 8 | lo);
};
// Burst from 0x2D: accel (6) → gyro (6) → temp (2)
raw.ax = s16(buf[0], buf[1]);
raw.ay = s16(buf[2], buf[3]);
raw.az = s16(buf[4], buf[5]);
raw.temp_raw = s16(buf[6], buf[7]);
raw.gx = s16(buf[8], buf[9]);
raw.gy = s16(buf[10], buf[11]);
raw.gz = s16(buf[12], buf[13]);
raw.gx = s16(buf[6], buf[7]);
raw.gy = s16(buf[8], buf[9]);
raw.gz = s16(buf[10], buf[11]);
raw.temp_raw = s16(buf[12], buf[13]);
return true;
}
@ -258,7 +283,7 @@ inline bool Imu::read(Sample &s)
s.gx = raw.gx * gs;
s.gy = raw.gy * gs;
s.gz = raw.gz * gs;
// Temp formula from ICM-20948 datasheet: T°C = (raw - 0) / 333.87 + 21.0
// Temp formula from ICM-20948 datasheet: T°C = TEMP_OUT / 333.87 + 21.0
s.temp_c = (float)raw.temp_raw / 333.87f + 21.0f;
return true;
}

6
chip_test_example/imu_test.cpp
View File

@ -35,10 +35,10 @@ int main(int argc, char **argv)
if (!imu.begin(cfg)) {
std::fprintf(stderr, "ERROR: IMU init failed\n"
" Check: I2C enabled? (sudo raspi-config)\n"
" Check: sudo i2cdetect -y 1\n"
" Check: wiring SDA=GPIO2 SCL=GPIO3\n"
" Check: sudo i2cdetect -y 1 (expect 68 or 69)\n"
" Check: wiring SDA=GPIO2 SCL=GPIO3, 3.3V, GND\n"
" Check: AD0 pin → 0x68 (GND) or 0x69 (VCC)\n"
" Run with -v for detailed debug output\n");
" WHO_AM_I=0x00 usually means NACK (no chip) — run with -v\n");
return 1;
}

5
chip_test_example/lora_tx.cpp
View File

@ -42,9 +42,14 @@ int main(int argc, char **argv)
if (!radio.begin(cfg)) {
std::fprintf(stderr, "ERROR: radio init failed\n"
" Check: SPI enabled? wiring? DIO5/DIO6 connected?\n"
" If fw looks like bootloader: sudo ./lora_rx --reset\n"
" Run with -v for step-by-step output\n");
return 1;
}
auto ver = radio.getVersion();
if (ver.fw_hi < 0x02)
std::fprintf(stderr, "hint: fw=0x%02X%02X — try: sudo ./lora_rx --reset\n",
ver.fw_hi, ver.fw_lo);
std::printf("Radio OK — sending every second\n");
for (int n = 0; ; ++n) {

462
chip_test_example/lr1121_malnus.hpp
View File

@ -1,15 +1,18 @@
// lr1121_malnus.hpp — LR1121 LoRa driver, tuned for this exact board
// lr1121_malnus.hpp — LR1121 LoRa driver for this exact board
//
// Hardware (hardwired):
// /dev/spidev0.0 CE0=GPIO8, MISO=GPIO9, MOSI=GPIO10, SCK=GPIO11
// GPIO24 LR_DIO0/BUSY
// GPIO25 LR_nRESET
// DIO5 RF switch RFSW0 — driven by chip (HIGH in RX)
// DIO6 RF switch RFSW1 — driven by chip (HIGH in TX)
// Hardware:
// /dev/spidev0.0 SCK=GPIO11, MOSI=GPIO10, MISO=GPIO9, NSS=GPIO8
// GPIO24 BUSY (DIO0)
// GPIO25 nRESET
// DIO5 RF-switch RFSW0 — chip-driven (HIGH in RX)
// DIO6 RF-switch RFSW1 — chip-driven (HIGH in TX/TX_HP)
//
// Crystal oscillator — no TCXO, no SetTcxoMode, no calibration guessing.
// RF switch is configured via SetDioAsRfSwitch (opcode 0x022D) so DIO5/DIO6
// are driven automatically by the chip in the correct state for TX/RX/standby.
// Crystal oscillator module (no TCXO). SetDioAsRfSwitch configures DIO5/DIO6
// so the chip drives the module's RF switch automatically.
//
// Opcodes verified against:
// LR1121 User Manual Rev 1.2 (UM.LR1121.W.APP, Table 13)
// Semtech SWDR001 (https://github.com/Lora-net/SWDR001)
#pragma once
#include <chrono>
@ -25,78 +28,80 @@
namespace lr1121 {
// ---- Opcodes (SWDR001 confirmed) -------------------------------------------
// system
constexpr uint16_t OC_GET_STATUS = 0x0100;
constexpr uint16_t OC_GET_VERSION = 0x0101; // → [hw,type,fw_hi,fw_lo]
// ── Opcodes ──────────────────────────────────────────────────────────────────
// System
constexpr uint16_t OC_GET_VERSION = 0x0101;
constexpr uint16_t OC_GET_ERRORS = 0x010D;
constexpr uint16_t OC_CLEAR_ERRORS = 0x010E;
constexpr uint16_t OC_CALIBRATE = 0x010F; // 1B bitmask
constexpr uint16_t OC_SET_REGMODE = 0x0110; // 1B: 0=LDO, 1=DCDC
constexpr uint16_t OC_CALIBRATE_IMAGE = 0x0111; // 2B: freq1, freq2 (× 4 MHz)
constexpr uint16_t OC_SET_DIOIRQ = 0x0113; // 4B dio9_mask + 4B dio8_mask
constexpr uint16_t OC_CLEAR_IRQ = 0x0114;
constexpr uint16_t OC_REBOOT = 0x0118; // 1B: 0=app, 1=stay bootloader
constexpr uint16_t OC_SET_STANDBY = 0x011C; // 1B: 0=RC, 1=XOSC
// regmem / buffer
constexpr uint16_t OC_WRITE_BUF8 = 0x0109;
constexpr uint16_t OC_READ_BUF8 = 0x010A; // 1B offset + 1B len → N bytes
// radio
constexpr uint16_t OC_GET_PKT_STATUS = 0x0204; // LoRa → [rssi,snr,sig_rssi]
constexpr uint16_t OC_GET_RXBUF_STA = 0x0203; // → [payload_len, rx_ptr]
constexpr uint16_t OC_SET_LORA_NET = 0x0208; // 1B: 0=private, 1=LoRaWAN
constexpr uint16_t OC_SET_RX = 0x0209; // 3B timeout RTC steps (32768/s)
constexpr uint16_t OC_SET_TX = 0x020A; // 3B timeout (0=until TxDone)
constexpr uint16_t OC_SET_REGMODE = 0x0110; // 1B: 0=LDO 1=DCDC
constexpr uint16_t OC_CALIBRATE_IMAGE = 0x0111; // 2B: f1,f2 in 4-MHz steps
constexpr uint16_t OC_SET_DIO_AS_RFSW = 0x0112; // 8B: enable + 7 mode bytes
constexpr uint16_t OC_SET_DIOIRQ = 0x0113; // 8B: irq1(4B) + irq2(4B)
constexpr uint16_t OC_CLEAR_IRQ = 0x0114; // 4B mask
constexpr uint16_t OC_REBOOT = 0x0118; // 1B: 0=app 1=bootloader
constexpr uint16_t OC_GET_VBAT = 0x0119; // → 1B raw ADC (VBAT ≈ raw/34.0 V)
constexpr uint16_t OC_SET_STANDBY = 0x011C; // 1B: 0=RC 1=XOSC
// Buffer
constexpr uint16_t OC_WRITE_BUF8 = 0x0109; // N bytes
constexpr uint16_t OC_READ_BUF8 = 0x010A; // 1B offset + 1B len → data
constexpr uint16_t OC_CLEAR_RXBUF = 0x010B;
// Radio
constexpr uint16_t OC_GET_RXBUF_STA = 0x0203; // → [len, ptr]
constexpr uint16_t OC_GET_PKT_STATUS = 0x0204; // → [rssi, snr, sig_rssi]
constexpr uint16_t OC_SET_LORA_NET = 0x0208; // 1B: 0=private 1=public
constexpr uint16_t OC_SET_RX = 0x0209; // 3B timeout in RTC steps
constexpr uint16_t OC_SET_TX = 0x020A; // 3B timeout (0 = no timeout)
constexpr uint16_t OC_SET_RF_FREQ = 0x020B; // 4B Hz big-endian
constexpr uint16_t OC_SET_PKT_TYPE = 0x020E; // 1B: 0x02=LoRa
constexpr uint16_t OC_SET_MOD_PARAM = 0x020F; // SF,BW,CR,LDRO
constexpr uint16_t OC_SET_PKT_PARAM = 0x0210; // preamble(2B),hdr,len,crc,iq
constexpr uint16_t OC_SET_TX_PARAMS = 0x0211; // 1B pwr(int8) + 1B ramp
constexpr uint16_t OC_SET_PKT_ADRS = 0x0212; // 1B tx_base + 1B rx_base
constexpr uint16_t OC_SET_PA_CFG = 0x0215; // pa_sel,pa_supply,duty,hp_max
constexpr uint16_t OC_SET_FALLBACK_MODE = 0x020C; // 1B: 0x01=STBY_RC, 0x02=STBY_XOSC
// RF switch — DIO5/DIO6 driven by chip based on TX/RX/STBY state
constexpr uint16_t OC_SET_DIO_AS_RFSW = 0x022D; // 8B: enable + 7 mode masks
constexpr uint16_t OC_SET_TX_PARAMS = 0x0211; // pwr(int8),ramp
constexpr uint16_t OC_SET_PKT_ADRS = 0x0212; // tx_base,rx_base
constexpr uint16_t OC_SET_FALLBACK_MODE = 0x0213; // 1B: 0x01=STBY_RC
constexpr uint16_t OC_SET_PA_CFG = 0x0215; // pa_sel,supply,duty,hp_max
// ---- IRQ bit masks ---------------------------------------------------------
// ── Constants ─────────────────────────────────────────────────────────────────
// IRQ bits (LR1121 UM Table GetStatus / SetDioIrqParams)
constexpr uint32_t IRQ_TX_DONE = (1u << 2);
constexpr uint32_t IRQ_RX_DONE = (1u << 3);
constexpr uint32_t IRQ_CRC_ERR = (1u << 7);
constexpr uint32_t IRQ_TIMEOUT = (1u << 10);
constexpr uint32_t IRQ_ALL = 0x07FF'FFFFu;
constexpr uint32_t IRQ_ALL = 0x1BF80FFCu; // all defined IRQ bits
// ---- Calibration bitmask ---------------------------------------------------
constexpr uint8_t CALIB_LF_RC = (1 << 0);
constexpr uint8_t CALIB_HF_RC = (1 << 1);
constexpr uint8_t CALIB_PLL = (1 << 2);
constexpr uint8_t CALIB_ADC = (1 << 3);
constexpr uint8_t CALIB_IMAGE = (1 << 4);
constexpr uint8_t CALIB_PLL_TX = (1 << 5);
constexpr uint8_t CALIB_ALL = 0x3F;
// Calibration bitmask (Calibrate command)
constexpr uint8_t CALIB_ALL = 0x3F; // LF_RC|HF_RC|PLL|ADC|IMG|PLL_TX
// ---- Modulation constants --------------------------------------------------
// SF: 0x05=SF5 .. 0x0C=SF12 (0x07=SF7 is good for short-range tests)
// BW: 0x01=15.6k 0x02=31.2k 0x03=62.5k 0x04=125k 0x05=250k 0x06=500k
// Modulation
// SF: 0x05=SF5 .. 0x0C=SF12
// BW: 0x01=15.6kHz 0x02=31.2 0x03=62.5 0x04=125 0x05=250 0x06=500
// CR: 0x01=4/5 0x02=4/6 0x03=4/7 0x04=4/8
// PA: 0x00=LP (≤15 dBm), 0x01=HP (≤22 dBm) — most modules use HP
// PA: 0x00=LP (≤15 dBm) 0x01=HP (≤22 dBm)
constexpr uint32_t FREQ_433 = 433'050'000;
constexpr uint32_t FREQ_868 = 868'000'000;
constexpr uint32_t FREQ_2400 = 2'403'000'000;
constexpr uint32_t FREQ_433 = 433'050'000u;
constexpr uint32_t FREQ_868 = 868'000'000u;
constexpr uint32_t FREQ_2400 = 2'403'000'000u;
// ── Public types ──────────────────────────────────────────────────────────────
struct Config {
const char *spi_path = "/dev/spidev0.0";
uint32_t spi_hz = 8'000'000;
const char *gpio_chip = "/dev/gpiochip0";
unsigned busy_gpio = 24; // LR_DIO0/BUSY
unsigned reset_gpio = 25; // LR_nRESET
uint32_t freq_hz = FREQ_433; // match your antenna
unsigned busy_gpio = 24; // DIO0 / BUSY
unsigned reset_gpio = 25; // nRESET
uint32_t freq_hz = FREQ_433;
uint8_t sf = 0x07; // SF7
uint8_t bw = 0x04; // 125 kHz
uint8_t cr = 0x01; // 4/5
int8_t tx_dbm = 14; // 17..+22 dBm
uint8_t pa_sel = 0x01; // 0x00=LP, 0x01=HP
bool use_dcdc = true;
bool lora_wan = false; // false = private sync word (0x12)
int8_t tx_dbm = 14; // -17..+22 dBm
uint8_t pa_sel = 0x01; // 0x00=LP(≤15dBm) 0x01=HP(≤22dBm)
// pa_supply: 0x00=internal VREG (use for ≤14 dBm), 0x01=VBAT direct (>14 dBm)
// RadioLib: "Must be set to PA_SUPPLY_VBAT when output power is more than 14 dBm."
uint8_t pa_supply = 0x00;
// use_dcdc: false=LDO (safe default for Pi; no DCDC inductor required)
// true=DCDC (higher efficiency; only if module has external DCDC components)
bool use_dcdc = false;
bool lora_wan = false; // false = private sync word
bool verbose = false;
};
@ -113,24 +118,22 @@ struct ChipVersion {
uint8_t fw_lo;
};
// ── Radio class ───────────────────────────────────────────────────────────────
class Radio {
public:
bool begin(const Config &cfg);
void end();
// Returns true on TX done, false on timeout.
bool send(const uint8_t *data, uint8_t n);
bool send(const uint8_t *data, uint8_t n); // true = TX_DONE, false = timeout
// Returns bytes received; -1=timeout, -2=CRC error.
// Returns byte count received; -1 = timeout, -2 = CRC error.
int receive(uint8_t *buf, uint8_t cap, uint32_t timeout_ms,
RxInfo *rx_info = nullptr);
uint32_t getIrq();
void clearIrq(uint32_t mask);
ChipVersion getVersion();
// Open SPI + GPIOs and hard-reset the chip, skip calibration.
// Useful for sending diagnostic commands if begin() hangs.
// Open SPI + GPIOs and hard-reset only — no calibration.
// Use for --reset / diagnostic commands when begin() would hang.
bool beginRaw(const Config &cfg);
void reboot(bool stay_in_bootloader = false);
@ -145,17 +148,32 @@ private:
void wcmd(uint16_t op, const uint8_t *p = nullptr, size_t n = 0);
void rcmd(uint16_t op, const uint8_t *params, size_t np,
uint8_t *out, size_t nr);
void waitBusy();
uint32_t getIrq(); // NOP-poll: stat1,stat2,irq (no BUSY wait)
void clearIrq(uint32_t mask);
uint16_t getErrors(); // returns ErrorStat bits
bool waitBusy();
void hardReset();
bool openGpio(unsigned line, bool out, int &fd_out);
void setGpioLine(int fd, int val);
int getGpioLine(int fd);
bool openSpi(const Config &c);
// Verbose-mode helpers
static const char *modeName(uint8_t stat2);
static const char *cmdName(uint8_t stat1);
static void imgCalFreqs(uint32_t hz, uint8_t &f1, uint8_t &f2);
static uint8_t computeLDRO(uint8_t sf, uint8_t bw);
// Maps target output power to the recommended (PaDutyCycle, PaHpMax) per the
// LR1121 datasheet PA Settings table. For HP PA: using max drive (duty=4,
// hp_max=7) at low power draws 22 dBm worth of VBAT current even if SetTxParams
// limits output — this droops VBAT and triggers LBD. For LP PA: PaHpMax is 0.
static void computePaConfig(uint8_t pa_sel, int8_t dbm,
uint8_t &duty, uint8_t &hp_max);
};
// ---- Implementation ---------------------------------------------------------
// ── Implementation ────────────────────────────────────────────────────────────
inline void Radio::spiTransfer(uint8_t *buf, size_t n)
{
@ -168,9 +186,10 @@ inline void Radio::spiTransfer(uint8_t *buf, size_t n)
ioctl(spi_fd_, SPI_IOC_MESSAGE(1), &tr);
}
// Write command: opcode [+ params]. Waits for BUSY before and after.
inline void Radio::wcmd(uint16_t op, const uint8_t *p, size_t n)
{
waitBusy();
if (!waitBusy()) return;
uint8_t buf[260];
buf[0] = op >> 8; buf[1] = op & 0xFF;
if (p && n) std::memcpy(buf + 2, p, n);
@ -178,30 +197,29 @@ inline void Radio::wcmd(uint16_t op, const uint8_t *p, size_t n)
waitBusy();
}
// Read command: opcode [+ params], then clock NOP bytes to retrieve response.
// Response byte 0 is stat1 (skipped); bytes 1..nr go to out[0..nr-1].
inline void Radio::rcmd(uint16_t op, const uint8_t *params, size_t np,
uint8_t *out, size_t nr)
{
waitBusy();
if (!waitBusy()) return;
uint8_t cbuf[16]{};
cbuf[0] = op >> 8; cbuf[1] = op & 0xFF;
if (params && np) std::memcpy(cbuf + 2, params, np);
spiTransfer(cbuf, 2 + np);
waitBusy();
if (!waitBusy()) return;
uint8_t rbuf[260]{};
spiTransfer(rbuf, nr + 1); // byte 0 is a dummy status
spiTransfer(rbuf, nr + 1); // rbuf[0] = stat1 (skip)
std::memcpy(out, rbuf + 1, nr);
}
// GetStatus: the LR1121 outputs [stat1, stat2, irq31:24, irq23:16, irq15:8, irq7:0]
// on the first 6 MISO bytes of ANY SPI transaction — regardless of what opcode is sent.
// (Confirmed in RadioLib source: it sends 6 null bytes with no opcode and reads buff[2..5].)
// Does NOT call waitBusy() — designed to be polled freely during TX/RX.
// Poll current status via 6 NOP bytes (valid at any time, including during TX/RX).
// Returns irq register [31:0]. MISO: [stat1, stat2, irq31:24, irq23:16, irq15:8, irq7:0].
inline uint32_t Radio::getIrq()
{
uint8_t b[6] = { 0x00, 0x00, 0x00, 0x00, 0x00, 0x00 };
uint8_t b[6]{};
spiTransfer(b, 6);
// b[0]=stat1, b[1]=stat2, b[2..5]=irq[31:24..7:0]
return ((uint32_t)b[2] << 24) | ((uint32_t)b[3] << 16)
| ((uint32_t)b[4] << 8) | (uint32_t)b[5];
}
@ -213,14 +231,22 @@ inline void Radio::clearIrq(uint32_t mask)
wcmd(OC_CLEAR_IRQ, d, 4);
}
inline void Radio::waitBusy()
inline uint16_t Radio::getErrors()
{
uint8_t e[2]{};
rcmd(OC_GET_ERRORS, nullptr, 0, e, 2);
return (uint16_t)((e[0] << 8) | e[1]);
}
inline bool Radio::waitBusy()
{
for (int i = 0; i < 200'000; ++i) {
if (!getGpioLine(busy_fd_)) return;
if (!getGpioLine(busy_fd_)) return true;
std::this_thread::sleep_for(std::chrono::microseconds(50));
}
if (cfg_.verbose)
std::fprintf(stderr, "[lr1121] waitBusy TIMEOUT after 10s — chip hung?\n");
std::fprintf(stderr, "[lr1121] waitBusy: TIMEOUT — chip hung?\n");
return false;
}
inline bool Radio::openGpio(unsigned line, bool out, int &fd_out)
@ -276,31 +302,84 @@ inline ChipVersion Radio::getVersion()
return { v[0], v[1], v[2], v[3] };
}
inline const char *Radio::modeName(uint8_t stat2)
{
switch ((stat2 >> 1) & 0x07) {
case 0: return "SLEEP";
case 1: return "STBY_RC";
case 2: return "STBY_XOSC";
case 3: return "FS";
case 4: return "RX";
case 5: return "TX";
default: return "?";
}
}
inline const char *Radio::cmdName(uint8_t stat1)
{
switch ((stat1 >> 1) & 0x07) {
case 0: return "CMD_FAIL";
case 1: return "CMD_PERR";
case 2: return "CMD_OK";
case 3: return "CMD_DAT";
default: return "?";
}
}
inline void Radio::imgCalFreqs(uint32_t hz, uint8_t &f1, uint8_t &f2)
{
// Frequency ranges per LR1121 UM Table CalibImage; steps = 4 MHz.
uint32_t mhz = hz / 1'000'000u;
uint32_t lo, hi;
if (mhz < 446) { lo = 430; hi = 440; }
else if (mhz < 740) { lo = 470; hi = 510; }
else if (mhz < 890) { lo = 860; hi = 876; }
else { lo = 900; hi = 928; }
else if (mhz < 2000) { lo = 900; hi = 928; }
else { lo = 2400; hi = 2500; }
f1 = (uint8_t)(lo / 4);
f2 = (uint8_t)((hi + 3) / 4);
}
inline uint8_t Radio::computeLDRO(uint8_t sf, uint8_t bw)
{
static const uint32_t bw_khz[] = { 0, 15625, 31250, 62500, 125000,
250000, 500000 };
uint32_t bw_hz = (bw < 7) ? bw_khz[bw] : 125000;
uint32_t sym_ms = (1u << sf) * 1000u / bw_hz;
return (sym_ms > 16) ? 1 : 0;
// LDRO required when symbol duration > 16 ms.
static const uint32_t bw_hz[] = { 0, 15625, 31250, 62500, 125000, 250000, 500000 };
uint32_t bw_val = (bw < 7) ? bw_hz[bw] : 125000;
return ((1u << sf) * 1000u / bw_val > 16) ? 1 : 0;
}
inline bool Radio::begin(const Config &c)
// Maps target dBm to the LR1121 datasheet recommended (PaDutyCycle, PaHpMax).
//
// HP PA (pa_sel=0x01, sub-GHz) recommended table from LR1121 datasheet §PA config:
// ≥22 dBm → duty=4, hp_max=7 ≥20 → 3,5 ≥17 → 2,3
// ≥14 dBm → duty=2, hp_max=2 ≥10 → 1,1 < 10 → 0,0
//
// Using duty=4, hp_max=7 for lower power levels drives all 7 PA stages at full
// current even though SetTxParams limits the output — VBAT droops under the
// excess load and triggers LBD, aborting TX before the preamble starts.
//
// LP PA (pa_sel=0x00): PaHpMax is always 0; duty controls drive, hp_max unused.
inline void Radio::computePaConfig(uint8_t pa_sel, int8_t dbm,
uint8_t &duty, uint8_t &hp_max)
{
cfg_ = c;
if (pa_sel == 0x01) { // HP PA
if (dbm >= 22) { duty = 4; hp_max = 7; }
else if (dbm >= 20) { duty = 3; hp_max = 5; }
else if (dbm >= 17) { duty = 2; hp_max = 3; }
else if (dbm >= 14) { duty = 2; hp_max = 2; }
else if (dbm >= 10) { duty = 1; hp_max = 1; }
else { duty = 0; hp_max = 0; }
} else { // LP PA — PaHpMax not applicable
hp_max = 0;
if (dbm >= 14) { duty = 7; }
else if (dbm >= 10) { duty = 4; }
else if (dbm >= 0) { duty = 2; }
else { duty = 0; }
}
}
inline bool Radio::openSpi(const Config &c)
{
spi_fd_ = ::open(c.spi_path, O_RDWR);
if (spi_fd_ < 0) {
if (c.verbose)
@ -311,7 +390,13 @@ inline bool Radio::begin(const Config &c)
ioctl(spi_fd_, SPI_IOC_WR_MODE, &mode);
ioctl(spi_fd_, SPI_IOC_WR_BITS_PER_WORD, &bits);
ioctl(spi_fd_, SPI_IOC_WR_MAX_SPEED_HZ, &c.spi_hz);
return true;
}
inline bool Radio::begin(const Config &c)
{
cfg_ = c;
if (!openSpi(c)) return false;
if (!openGpio(c.reset_gpio, true, reset_fd_)) return false;
if (!openGpio(c.busy_gpio, false, busy_fd_)) return false;
@ -325,66 +410,92 @@ inline bool Radio::begin(const Config &c)
ver.hw, ver.type, ver.fw_hi, ver.fw_lo);
if (ver.type != 0x03) {
if (c.verbose)
std::fprintf(stderr, "[lr1121] unexpected chip type 0x%02X (want 0x03=LR1121)\n",
std::fprintf(stderr, "[lr1121] unexpected type 0x%02X (want 0x03=LR1121)\n",
ver.type);
return false;
}
if (ver.fw_hi < 0x02 && c.verbose)
std::fprintf(stderr, "[lr1121] warning: fw=0x%02X%02X — try: sudo ./lora_rx --reset\n",
ver.fw_hi, ver.fw_lo);
#define LR_STEP(msg) do { if (c.verbose) std::fprintf(stderr, "[lr1121] -> " msg "\n"); } while(0)
if (c.verbose) {
uint8_t raw = 0;
rcmd(OC_GET_VBAT, nullptr, 0, &raw, 1);
// VBAT ≈ raw/34.0 V (from LR1121 formula: raw*5/(4*255)/1.091)
float vbat = raw / 34.0f;
std::fprintf(stderr, "[lr1121] VBAT raw=0x%02X (~%.2fV)%s\n", raw, vbat,
(vbat < 2.5f && raw > 0) ? " ← LOW: check VBAT supply" : "");
}
LR_STEP("SetStandby(RC)");
#define V(msg) do { if (c.verbose) std::fprintf(stderr, "[lr1121] -> " msg "\n"); } while(0)
// ── Init sequence (RadioLib config() order, then per-band radio config) ──
V("SetStandby(RC)");
{ const uint8_t a[] = {0x00}; wcmd(OC_SET_STANDBY, a, 1); }
// Crystal oscillator — no TCXO, no SetTcxoMode.
// Calibrate from RC clock (required), then switch to XOSC standby so the
// crystal stays running during radio configuration and TX/RX ramp-up.
// Without STBY_XOSC here the PA cold-starts the crystal on every TX and
// silently fails to ramp up.
LR_STEP("Calibrate(ALL)");
// SetFallbackMode before Calibrate — matches RadioLib config() order.
V("SetFallbackMode(STBY_RC)");
{ const uint8_t a[] = {0x01}; wcmd(OC_SET_FALLBACK_MODE, a, 1); }
V("ClearIrq / SetDioIrqParams(none)");
clearIrq(IRQ_ALL);
{ const uint8_t z[8]{}; wcmd(OC_SET_DIOIRQ, z, 8); }
V("Calibrate(ALL)");
{ const uint8_t a[] = {CALIB_ALL}; wcmd(OC_CALIBRATE, a, 1); }
// Calibrate can take up to several hundred ms. RadioLib does delay(5) + waitBusy.
std::this_thread::sleep_for(std::chrono::milliseconds(5));
if (!waitBusy()) {
if (c.verbose) std::fprintf(stderr, "[lr1121] Calibrate: BUSY stuck\n");
return false;
}
LR_STEP("ClearErrors");
wcmd(OC_CLEAR_ERRORS);
{
uint16_t errs = getErrors();
if (errs && c.verbose)
std::fprintf(stderr, "[lr1121] errors after calibrate: 0x%04X%s\n", errs,
(errs & (1u<<5)) ? " (HF_XOSC_START_ERR — check crystal)" : "");
}
LR_STEP("SetStandby(XOSC)");
{ const uint8_t a[] = {0x01}; wcmd(OC_SET_STANDBY, a, 1); } // 0x01 = XOSC, not RC
#undef LR_STEP
// --- Radio configuration ------------------------------------------------
// ── Radio configuration ──────────────────────────────────────────────────
{ const uint8_t a[] = {c.use_dcdc ? (uint8_t)0x01 : (uint8_t)0x00};
wcmd(OC_SET_REGMODE, a, 1); }
{ const uint8_t a[] = {0x02}; wcmd(OC_SET_PKT_TYPE, a, 1); } // LoRa
uint32_t f = c.freq_hz;
{ const uint8_t a[] = { (uint8_t)(f >> 24), (uint8_t)(f >> 16),
(uint8_t)(f >> 8), (uint8_t) f };
{ uint32_t f = c.freq_hz;
const uint8_t a[] = { (uint8_t)(f>>24),(uint8_t)(f>>16),(uint8_t)(f>>8),(uint8_t)f };
wcmd(OC_SET_RF_FREQ, a, 4); }
if (f < 1'000'000'000u) {
uint8_t f1, f2; imgCalFreqs(f, f1, f2);
{ uint8_t f1, f2; imgCalFreqs(c.freq_hz, f1, f2);
const uint8_t a[] = {f1, f2}; wcmd(OC_CALIBRATE_IMAGE, a, 2);
if (c.verbose)
std::fprintf(stderr, "[lr1121] image cal: 0x%02X 0x%02X\n", f1, f2);
}
std::fprintf(stderr, "[lr1121] image cal: 0x%02X 0x%02X\n", f1, f2); }
{ const uint8_t a[] = {0x00, 0x00}; wcmd(OC_SET_PKT_ADRS, a, 2); }
uint8_t ldro = computeLDRO(c.sf, c.bw);
{ const uint8_t a[] = {c.sf, c.bw, c.cr, ldro};
{ uint8_t ldro = computeLDRO(c.sf, c.bw);
const uint8_t a[] = {c.sf, c.bw, c.cr, ldro};
wcmd(OC_SET_MOD_PARAM, a, 4);
if (c.verbose)
std::fprintf(stderr, "[lr1121] SF=%u BW=0x%02X CR=0x%02X LDRO=%u\n",
c.sf, c.bw, c.cr, ldro); }
{ const uint8_t a[] = {0x00, 0x08, 0x00, 0xFF, 0x01, 0x00};
wcmd(OC_SET_PKT_PARAM, a, 6); }
wcmd(OC_SET_PKT_PARAM, a, 6); } // preamble=8, explicit hdr, maxlen=255, CRC=on
// pa_supply=0x00 → internal DC-DC regulator (correct for most modules).
// 0x01 = VBAT direct — only needed on specific high-power reference designs.
{ const uint8_t a[] = {c.pa_sel, 0x00, 0x04, 0x07};
wcmd(OC_SET_PA_CFG, a, 4); }
// PA configuration: use the power-matched (duty, hp_max) per the LR1121
// datasheet. Oversized PA drive (duty=4, hp_max=7) at low power draws
// excess VBAT current, droops the supply, and fires LBD aborting TX.
{ uint8_t duty, hp_max;
computePaConfig(c.pa_sel, c.tx_dbm, duty, hp_max);
const uint8_t a[] = {c.pa_sel, c.pa_supply, duty, hp_max};
wcmd(OC_SET_PA_CFG, a, 4);
if (c.verbose)
std::fprintf(stderr, "[lr1121] PA: sel=0x%02X supply=0x%02X duty=%u hp_max=%u\n",
c.pa_sel, c.pa_supply, duty, hp_max); }
{ const uint8_t a[] = {(uint8_t)(int8_t)c.tx_dbm, 0x02};
wcmd(OC_SET_TX_PARAMS, a, 2); }
@ -392,32 +503,21 @@ inline bool Radio::begin(const Config &c)
{ const uint8_t a[] = {c.lora_wan ? (uint8_t)0x01 : (uint8_t)0x00};
wcmd(OC_SET_LORA_NET, a, 1); }
// RF switch via SetDioAsRfSwitch (0x022D).
// enable=0x03 → DIO5 and DIO6 are RF switch outputs.
// Bit 0 = DIO5 (RFSW0), bit 1 = DIO6 (RFSW1).
// standby: both LOW | rx: DIO5=HIGH, DIO6=LOW | tx/tx_hp: DIO5=LOW, DIO6=HIGH
{ const uint8_t a[] = { 0x03, // enable: DIO5 + DIO6
0x00, // standby: both LOW
0x01, // rx: DIO5=HIGH
0x02, // tx: DIO6=HIGH
0x02, // tx_hp: DIO6=HIGH
0x00, // tx_hf: both LOW (2.4 GHz path unused)
0x00, // gnss: both LOW
0x00}; // wifi: both LOW
// DIO5 = RFSW0, DIO6 = RFSW1 (chip-driven RF switch).
// standby: both LOW | rx: DIO5=HIGH | tx/tx_hp: DIO6=HIGH
{ const uint8_t a[] = {0x03, 0x00, 0x01, 0x02, 0x02, 0x00, 0x00, 0x00};
wcmd(OC_SET_DIO_AS_RFSW, a, 8);
if (c.verbose) std::fprintf(stderr, "[lr1121] RF switch configured (DIO5/DIO6)\n"); }
if (c.verbose) std::fprintf(stderr, "[lr1121] RF switch: DIO5/DIO6\n"); }
// After TX/RX (or an aborted TX due to EOL), fall back to STBY_RC so the
// chip is in a known state. Without this the fallback is undefined and
// subsequent SetStandby + SetTx sequences can be silently ignored.
{ const uint8_t a[] = {0x01}; wcmd(OC_SET_FALLBACK_MODE, a, 1); }
// Switch to crystal oscillator standby so the crystal is already running
// when SetTx is issued — avoids cold-start failure on crystal-based modules.
V("SetStandby(XOSC)");
{ const uint8_t a[] = {0x01}; wcmd(OC_SET_STANDBY, a, 1); }
const uint8_t irq_zero[8]{};
wcmd(OC_SET_DIOIRQ, irq_zero, 8);
clearIrq(IRQ_ALL);
#undef V
if (c.verbose)
std::fprintf(stderr, "[lr1121] init OK: %u Hz, SF%u, PA=%s, crystal osc\n",
std::fprintf(stderr, "[lr1121] init OK: %u Hz SF%u PA=%s\n",
c.freq_hz, c.sf, c.pa_sel ? "HP" : "LP");
return true;
}
@ -425,21 +525,9 @@ inline bool Radio::begin(const Config &c)
inline bool Radio::beginRaw(const Config &c)
{
cfg_ = c;
spi_fd_ = ::open(c.spi_path, O_RDWR);
if (spi_fd_ < 0) {
if (c.verbose)
std::fprintf(stderr, "[lr1121] cannot open %s: %m\n", c.spi_path);
return false;
}
uint8_t mode = SPI_MODE_0, bits = 8;
ioctl(spi_fd_, SPI_IOC_WR_MODE, &mode);
ioctl(spi_fd_, SPI_IOC_WR_BITS_PER_WORD, &bits);
ioctl(spi_fd_, SPI_IOC_WR_MAX_SPEED_HZ, &c.spi_hz);
if (!openSpi(c)) return false;
if (!openGpio(c.reset_gpio, true, reset_fd_)) return false;
if (!openGpio(c.busy_gpio, false, busy_fd_)) return false;
{ uint8_t nop = 0x00; spiTransfer(&nop, 1); }
std::this_thread::sleep_for(std::chrono::milliseconds(1));
hardReset();
@ -462,43 +550,54 @@ inline void Radio::end()
inline bool Radio::send(const uint8_t *data, uint8_t n)
{
// Return chip to XOSC standby and clear any prior error/IRQ state before TX.
// Crystal must be warm for TX: switch to XOSC standby before SetTx.
{ const uint8_t a[] = {0x01}; wcmd(OC_SET_STANDBY, a, 1); }
wcmd(OC_CLEAR_ERRORS);
wcmd(OC_WRITE_BUF8, data, n);
{ const uint8_t a[] = {0x00, 0x08, 0x00, n, 0x01, 0x00};
wcmd(OC_SET_PKT_PARAM, a, 6); }
// Enable TX_DONE and TIMEOUT on DIO9 — matches RadioLib's startTransmit().
// IRQ register is updated regardless, but this also lets DIO9 signal completion.
{ const uint8_t a[] = {0x00, 0x00, 0x04, 0x04, // DIO9: TX_DONE(bit2)|TIMEOUT(bit10)
0x00, 0x00, 0x00, 0x00}; // DIO8: none
wcmd(OC_SET_DIOIRQ, a, 8); }
{ const uint8_t a[] = {0x00, 0x00, 0x04, 0x04, 0x00, 0x00, 0x00, 0x00};
wcmd(OC_SET_DIOIRQ, a, 8); } // DIO9: TX_DONE(bit2) | TIMEOUT(bit10)
clearIrq(IRQ_ALL);
{ const uint8_t a[] = {0x00, 0x00, 0x00}; wcmd(OC_SET_TX, a, 3); }
// wcmd() already waited for BUSY low (= PA ramped, preamble on air).
if (cfg_.verbose) {
uint8_t b[6]{}; spiTransfer(b, 6);
uint32_t irq = ((uint32_t)b[2]<<24)|((uint32_t)b[3]<<16)|((uint32_t)b[4]<<8)|b[5];
std::fprintf(stderr,
"[lr1121] after SetTx: mode=%s cmd=%s irq=0x%08X errs=0x%04X\n",
modeName(b[1]), cmdName(b[0]), irq, getErrors());
}
for (int i = 0; i < 50'000; ++i) {
uint32_t irq = getIrq();
if (irq & IRQ_TX_DONE) {
clearIrq(IRQ_ALL);
// Restore DIO IRQ mask to silent.
const uint8_t z[8]{}; wcmd(OC_SET_DIOIRQ, z, 8);
return true;
}
std::this_thread::sleep_for(std::chrono::microseconds(100));
}
// Read stat bytes alongside IRQ for diagnosis.
uint8_t sb[6] = {}; spiTransfer(sb, 6);
uint32_t irq_now = ((uint32_t)sb[2]<<24)|((uint32_t)sb[3]<<16)|((uint32_t)sb[4]<<8)|sb[5];
if (cfg_.verbose)
std::fprintf(stderr, "[lr1121] send: TX timeout stat1=0x%02X stat2=0x%02X irq=0x%08X\n",
sb[0], sb[1], irq_now);
// Timeout — print diagnostics then clean up.
if (cfg_.verbose) {
uint8_t b[6]{}; spiTransfer(b, 6);
uint32_t irq = ((uint32_t)b[2]<<24)|((uint32_t)b[3]<<16)|((uint32_t)b[4]<<8)|b[5];
std::fprintf(stderr,
"[lr1121] TX timeout: mode=%s cmd=%s irq=0x%08X errs=0x%04X\n",
modeName(b[1]), cmdName(b[0]), irq, getErrors());
if (irq & (1u<<21))
std::fprintf(stderr,
"[lr1121] ↳ LBD (Low Battery Detect): VBAT drooped under PA load.\n"
"[lr1121] Check VBAT supply / decoupling. Try lower tx_dbm or pa_sel=LP.\n");
}
const uint8_t z[8]{}; wcmd(OC_SET_DIOIRQ, z, 8);
clearIrq(IRQ_ALL);
const uint8_t z[8]{}; wcmd(OC_SET_DIOIRQ, z, 8);
{ const uint8_t a[] = {0x01}; wcmd(OC_SET_STANDBY, a, 1); }
return false;
}
@ -506,42 +605,39 @@ inline bool Radio::send(const uint8_t *data, uint8_t n)
inline int Radio::receive(uint8_t *buf, uint8_t cap, uint32_t timeout_ms,
RxInfo *rx_info)
{
{ const uint8_t a[] = {0x01}; wcmd(OC_SET_STANDBY, a, 1); }
{ const uint8_t a[] = {0x01}; wcmd(OC_SET_STANDBY, a, 1); } // XOSC warm
// Enable RX_DONE(bit3), TIMEOUT(bit10), CRC_ERR(bit7) on DIO9 — matches RadioLib.
{ const uint8_t a[] = {0x00, 0x00, 0x04, 0x88, // DIO9: RX_DONE|TIMEOUT|CRC_ERR
0x00, 0x00, 0x00, 0x00};
wcmd(OC_SET_DIOIRQ, a, 8); }
{ const uint8_t a[] = {0x00, 0x00, 0x04, 0x88, 0x00, 0x00, 0x00, 0x00};
wcmd(OC_SET_DIOIRQ, a, 8); } // RX_DONE(bit3)|CRC_ERR(bit7)|TIMEOUT(bit10)
clearIrq(IRQ_ALL);
uint32_t t = (timeout_ms == 0) ? 0x00FF'FFFFu
: (uint32_t)(timeout_ms * 32768ull / 1000);
{ const uint8_t a[] = {(uint8_t)(t >> 16), (uint8_t)(t >> 8), (uint8_t)t};
{ const uint8_t a[] = {(uint8_t)(t>>16),(uint8_t)(t>>8),(uint8_t)t};
wcmd(OC_SET_RX, a, 3); }
for (;;) {
uint32_t irq = getIrq();
if (irq & IRQ_RX_DONE) {
bool crc_err = irq & IRQ_CRC_ERR;
clearIrq(IRQ_ALL);
if (rx_info) {
uint8_t ps[3]{};
rcmd(OC_GET_PKT_STATUS, nullptr, 0, ps, 3);
rx_info->rssi_dbm = -(int8_t)(ps[0] >> 1);
rx_info->snr_db = ((int8_t)ps[1] + 2) >> 2;
rx_info->signal_rssi_dbm = -(int8_t)(ps[2] >> 1);
rx_info->rssi_dbm = (int8_t)(-(int)ps[0] / 2);
rx_info->snr_db = (int8_t)((int8_t)ps[1] / 4);
rx_info->signal_rssi_dbm = (int8_t)(-(int)ps[2] / 2);
}
if (crc_err) return -2;
if (irq & IRQ_CRC_ERR) { clearIrq(IRQ_ALL); return -2; }
uint8_t stat[2]{};
rcmd(OC_GET_RXBUF_STA, nullptr, 0, stat, 2);
uint8_t len = (stat[0] < cap) ? stat[0] : cap;
uint8_t p[2] = { stat[1], len };
rcmd(OC_READ_BUF8, p, 2, buf, len);
return len;
wcmd(OC_CLEAR_RXBUF);
clearIrq(IRQ_ALL);
return (int)len;
}
if (irq & IRQ_TIMEOUT) { clearIrq(IRQ_ALL); return -1; }