arduino-spybug/spybug/spybug.ino

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/*
*** SD Card Wiring ***
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SD | Nano
______________________
D0 (DO) | D12 (MISO)
VSS | GND
CLK | D13 (SCK)
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VDD | 5V or 3V3
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CMD (DI) | D11 (MOSI)
D3 (CS) | D10 (SS)
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WARNING: SD cards are not designed for 5V; I have been using 5V anyways
and everything seems fine, but beware that there is a significant risk
of immediate or premature failure when not using a buffer circuit.
SD pin D3 is the chip select pin. It can be set manually in PIN_SS.
*** Microphone Wiring (MAX9814 w/ electret microphone) ***
Mic | Nano
______________________
VCC | 5V
GND | GND
Out | A0
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Out defaults to A0 (AdcChannel0), but can be set manually in ADC_CHANNEL.
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*/
#include <SD.h>
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#include <SPI.h>
#include <avr/interrupt.h>
#include <avr/io.h>
#include <avr/wdt.h>
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/************************
BEGIN USER CONFIGURATION
************************/
//#define DEBUG_RECORDING
//#define SERIAL_OUTPUT
#define SAMPLE_MODE_U8
//#define SAMPLE_MODE_S16
//#define ADC_PRESCALE_16 /* Up to ~60kHz. */
//#define ADC_PRESCALE_32 /* Up to ~27kHz. */
#define ADC_PRESCALE_64 /* Up to ~18kHz. */
#define U8_EXTRA_PRECISION /* (U8 sampling mode only) use 9th ADC reading bit and chop off 1st bit for more precision (sacrificing half of the bandwidth) */
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#define RECORDING_DELAY_IN_MINUTES 0 /* Wait n minutes before starting to record. */
#define ADC_CHANNEL AdcChannel0
#define TIMER_COMPARE 1000 /* 16MHz / 1000 = 16kHz. */
#define FLUSH_SAMPLES 64000 /* Flush WAV file every n samples. */
#define PIN_SS 10
/**********************
END USER CONFIGURATION
**********************/
#ifdef SERIAL_OUTPUT
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static int serial_putch(char c, FILE *f) {
(void)f;
return Serial.write(c) == 1 ? 0 : 1;
}
static int serial_getch(FILE *f) {
(void)f;
while(Serial.available() == 0);
return Serial.read();
}
static FILE serial_in_out;
static void setup_serial_in_out() {
fdev_setup_stream(&serial_in_out, serial_putch, serial_getch, _FDEV_SETUP_RW);
stdout = stdin = stderr = &serial_in_out;
}
static size_t fstrlen(const __FlashStringHelper *s) {
PGM_P sp = (PGM_P)s;
size_t len = 0;
while (pgm_read_byte(sp++))
len++;
return len;
}
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static int printf(const __FlashStringHelper *fmt, ...) {
size_t len = fstrlen(fmt);
char buf[len + 1];
buf[len] = 0;
memcpy_P(buf, fmt, len + 1);
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va_list args;
va_start(args, fmt);
int ret = vprintf(buf, args);
va_end(args);
return ret;
}
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#define die(fmt, ...) { disable_recording_interrupts(); printf(F("Fatal: ")); printf(fmt, ##__VA_ARGS__); Serial.flush(); while(1); }
#define dbg(fmt, ...) { printf(F("Debug: ")); printf(fmt, ##__VA_ARGS__); }
#define print_special(x) Serial.print(x)
#else
#define printf(fmt, ...) {}
#define die(fmt, ...) { disable_recording_interrupts(); while(1); }
#define dbg(fmt, ...) {}
#define print_special(x) {}
#endif
#if defined(RECORDING_DELAY_IN_MINUTES) && RECORDING_DELAY_IN_MINUTES != 0
#include <LowPower.h> /* https://github.com/rocketscream/Low-Power */
static void low_power_sleep_minutes(unsigned long t) {
for (unsigned long i = 0; 8ul * i < 60ul * t; i++) {
/* Power down for 8s. */
LowPower.powerDown(SLEEP_8S, ADC_OFF, BOD_OFF);
}
}
#endif
static void start_watchdog_with_full_reset() {
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MCUSR &= ~B00001000; /* Clear reset flag. */
WDTCSR |= B00011000; /* Prepare prescaler change. */
WDTCSR = B00100001; /* Set watchdog timeout to 8s. */
// Enable Watchdog Timer
WDTCSR |= B01000000;
MCUSR = MCUSR & B11110111;
}
static inline void disable_recording_interrupts() {
TIMSK1 &= ~(_BV(OCIE1A) | _BV(OCIE1B));
}
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enum AdcChannel : uint8_t {
AdcChannel0 = 0,
AdcChannel1 = 1,
AdcChannel2 = 2,
AdcChannel3 = 3,
AdcChannel4 = 4,
AdcChannel5 = 5,
AdcChannel6 = 6,
AdcChannel7 = 7,
AdcChannelTemp = 8,
AdcChannel1V1 = 14,
AdcChannelGnd = 15,
};
File file;
#if defined(SAMPLE_MODE_U8)
#define SAMPLE_BUF_SIZE 256
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#define SAMPLE_BUF_TYPE uint8_t
#elif defined(SAMPLE_MODE_S16)
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#define SAMPLE_BUF_SIZE 160
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#define SAMPLE_BUF_TYPE int16_t
#endif
volatile SAMPLE_BUF_TYPE sample_buffer[2][SAMPLE_BUF_SIZE];
volatile bool which_buffer = 0;
volatile uint16_t samples_in_buffer[2] = {0, 0};
volatile unsigned long samples_hanging = 0;
volatile unsigned long samples_written = 0;
volatile unsigned long samples_dropped = 0;
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#ifdef DEBUG_RECORDING
volatile unsigned long dbg_total = 0;
volatile unsigned long dbg_sum = 0;
volatile unsigned long dbg_samples = 0;
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volatile int16_t dbg_min = 32767;
volatile int16_t dbg_max = -32768;
#endif
ISR(TIMER1_COMPA_vect) {
/* Only write to file, if one of the buffers is full (meaning no access conflicts). */
if (samples_in_buffer[!which_buffer] == SAMPLE_BUF_SIZE) {
TIMSK1 &= ~_BV(OCIE1A);
sei();
const size_t bufsz = sizeof(SAMPLE_BUF_TYPE) * samples_in_buffer[!which_buffer];
if (file.write((char*)sample_buffer[!which_buffer], bufsz) != bufsz) {
printf(F("Lost "));
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print_special((float)samples_hanging / (float)(F_CPU / TIMER_COMPARE)); /* Printf doesn't handle floats. */
printf(F(" seconds of recording.\n"));
die(F("Error writing to SD card. You can ignore this if you removed the SD card intentionally.\n"));
}
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samples_hanging += samples_in_buffer[!which_buffer];
samples_in_buffer[!which_buffer] = 0;
if (samples_hanging >= FLUSH_SAMPLES) {
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samples_written += samples_hanging;
samples_hanging = 0;
wav_write_header(samples_written);
file.flush();
}
TIMSK1 |= _BV(OCIE1A);
}
}
ISR(TIMER1_COMPB_vect) {
// Retrieve ADC Value and Write to Buffer
#if defined(SAMPLE_MODE_U8)
#ifdef U8_EXTRA_PRECISION
uint8_t l = ADCL; /* Read ADC registers. (Order matters!) */
uint8_t h = ADCH;
uint8_t adcval = (h << 7) | (l >> 1);
#else
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uint8_t adcval = ADCH;
#endif
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#elif defined(SAMPLE_MODE_S16)
uint8_t l = ADCL;
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uint8_t h = ADCH;
int16_t adcval = (h << 8) | l;
adcval -= 0x0200; /* Make integer signed. */
adcval <<= 6; /* Turn 10-bit integer into 16-bit integer. */
#endif
if (samples_in_buffer[which_buffer] >= SAMPLE_BUF_SIZE)
which_buffer = !which_buffer;
if (samples_in_buffer[which_buffer] < SAMPLE_BUF_SIZE)
sample_buffer[which_buffer][samples_in_buffer[which_buffer]++] = adcval;
else
samples_dropped++;
#ifdef DEBUG_RECORDING
dbg_total++;
dbg_samples++;
dbg_sum += adcval;
if (adcval < dbg_min)
dbg_min = adcval;
if (adcval > dbg_max)
dbg_max = adcval;
#endif
}
static void wav_write_header(uint32_t nsamples) {
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unsigned long old_pos = file.position();
if (!file.seek(0))
die(F("Error seeking to position 0!\n"));
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const uint16_t channels = 1;
const uint32_t riff_chunk_size = sizeof(SAMPLE_BUF_TYPE) * nsamples * channels + 4 + 24 + 8;
const uint32_t fmt_chunk_size = 16;
const uint16_t fmt_tag = 1; /* 1 = PCM. */
const uint32_t sample_rate = F_CPU / TIMER_COMPARE;
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const uint32_t data_rate = sizeof(SAMPLE_BUF_TYPE) * channels * sample_rate;
const uint16_t block_align = sizeof(SAMPLE_BUF_TYPE) * channels;
const uint16_t bits_per_sample = sizeof(SAMPLE_BUF_TYPE) * 8;
const uint32_t data_size = sizeof(SAMPLE_BUF_TYPE) * nsamples * channels;
// RIFF
if(file.write((char*)"RIFF", 4) != 4
|| file.write((char*)&riff_chunk_size, 4) != 4
|| file.write((char*)"WAVE", 4) != 4
// fmt
|| file.write((char*)"fmt ", 4) != 4
|| file.write((char*)&fmt_chunk_size, 4) != 4
|| file.write((char*)&fmt_tag, 2) != 2
|| file.write((char*)&channels, 2) != 2
|| file.write((char*)&sample_rate, 4) != 4
|| file.write((char*)&data_rate, 4) != 4
|| file.write((char*)&block_align, 2) != 2
|| file.write((char*)&bits_per_sample, 2) != 2
// data
|| file.write((char*)"data", 4) != 4
|| file.write((char*)&data_size, 4) != 4)
die(F("Error writing WAV header to SD card!\n"));
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if (old_pos > file.position()) {
if(!file.seek(old_pos))
die(F("Error seeking to position %lu!\n"), old_pos);
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}
}
void setup() {
// Serial Setup
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#ifdef SERIAL_OUTPUT
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Serial.begin(9600); /* Set baud rate. */
setup_serial_in_out(); /* Add printf support. */
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#endif
// Delay Triggering
#if defined(RECORDING_DELAY_IN_MINUTES) && RECORDING_DELAY_IN_MINUTES != 0
printf(F("Waiting %u minute%s before starting to record...\n"), RECORDING_DELAY_IN_MINUTES, RECORDING_DELAY_IN_MINUTES == 1 ? "" : "s");
Serial.flush();
low_power_sleep_minutes(RECORDING_DELAY_IN_MINUTES); /* Draws ~12.5mA instead of ~30mA when using delay(). */
#endif
// Start Watchdog (wdt_enable() doesn't fully reset)
start_watchdog_with_full_reset();
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// SD Card Setup
if (!SD.begin(PIN_SS))
die(F("Error initializing SD card!\n"));
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// Determine Filename
unsigned int filenum = 0;
char filename[32];
do {
filenum++;
snprintf(filename, 32, "rec_%03u.wav", filenum);
} while (SD.exists(filename));
// Open File
file = SD.open(filename, O_READ | O_WRITE | O_CREAT); /* Seeking doesn't seem to work with FILE_WRITE?! */
printf(F("Recording to file '%s'.\n"), filename);
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if (!file)
die(F("Error opening '%s' for writing!\n"), filename);
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wav_write_header(0);
// ADC Setup
DIDR0 |= (0xF & ADC_CHANNEL); /* Disable digital input. */
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ADCSRA = _BV(ADEN) /* Enable ADC. */
| _BV(ADATE) /* Enable auto-trigger. */
#if defined(ADC_PRESCALE_64) /* Up to ~18kHz. */
| _BV(ADPS2) | _BV(ADPS1); /* ADC prescaler division factor: 64. */
#elif defined(ADC_PRESCALE_32) /* Up to ~27kHz. */
| _BV(ADPS2) | _BV(ADPS0); /* ADC prescaler division factor: 32. */
#elif defined(ADC_PRESCALE_16) /* Up to ~60kHz. */
| _BV(ADPS2); /* ADC prescaler division factor: 16. */
#endif
ADCSRB = _BV(ADTS2) | _BV(ADTS0); /* Auto-trigger source select: "Timer/Counter1 Compare Match B". */
ADMUX = _BV(REFS0) /* Use AREF pin (VCC by default) as reference voltage. */
#if defined(SAMPLE_MODE_U8) && !defined(U8_EXTRA_PRECISION)
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| _BV(ADLAR) /* Left adjust ADC output so we only need to read ADCH. */
#endif
| (0xF & ADC_CHANNEL); /* Select our ADC input channel. */
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// Timer Setup
TCCR1A = _BV(WGM13) | _BV(WGM12) | _BV(WGM11); /* Set timer 1 on A channel to ICR1 fast PWM. (Required to make channel B fire at the correct speed). */
TCCR1B = _BV(WGM13) | _BV(WGM12) /* Make timer 1 on B channel compare to ICR1 in CTC (Clear Timer on Compare match) mode. */
| _BV(CS10); /* Set timer prescaler division factor to 1. */
ICR1 = TIMER_COMPARE; /* Set timer compare value: freqency = CPU frequency (16MHz) / TIMER_COMPARE. */
TIMSK1 = _BV(OCIE1A) /* Use interrupt A for updating the data on the SD card. */
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| _BV(OCIE1B); /* Enable "Output Compare B Match Interrupt". */
}
void loop() {
delay(1000);
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wdt_reset(); /* Reset watchdog timer. */
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#ifdef DEBUG_RECORDING
dbg(F("n=%lu\tavg=%lu\tmin=%d\tmax=%d\n"), dbg_total, dbg_sum / (dbg_samples ? dbg_samples : 1), dbg_min, dbg_max);
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dbg_sum = 0;
dbg_samples = 0;
dbg_min = 32767;
dbg_max = -32768;
#endif
printf(F("samples: written=%lu, hanging=%lu, dropped=%lu\n"), samples_written, samples_hanging, samples_dropped);
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}