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C++

// Talkie library
// Copyright 2011 Peter Knight
// Adafruit library modified by Jean-Luc Deladrière
// This code is released under GPLv2 license.
// Though the Wave Shield DAC pins are configurable, much else in this code
// is still very Uno-specific; the timers and timer control registers, the
// PWM output pin, etc. Compatibility with other boards is not guaranteed.
#include "talkie.h"
#define PIEZO // If set, connect piezo on pins 3 & 11, is louder
//#define FS 8000 // Speech engine sample rate
#define FS map(analogRead(1),0,1023,4000,16000)
//#define TICKS (FS / 40) // Speech data rate
#define TICKS 20 // Speech data rate
//#define TICKS map(analogRead(0),0,700,20,800)
// Some of these variables could go in the Talkie object, but the hardware
// specificity (reliance on certain timers and/or PWM pins) kills any point
// in multiple instances; there can be only one. So they're declared as
// static here to keep the header simple and self-documenting.
//#if TICKS < 255
//static volatile uint8_t interruptCount;
//#else
static volatile uint16_t interruptCount;
static volatile uint16_t slower;
//#endif
static volatile uint8_t *csPort, *clkPort, *datPort;
static volatile uint16_t synthEnergy;
static volatile int16_t synthK1, synthK2;
static volatile int8_t synthK3, synthK4, synthK5, synthK6,
synthK7, synthK8, synthK9, synthK10;
static uint16_t buf, synthRand = 1;
static int16_t x0, x1, x2, x3, x4, x5, x6, x7, x8, x9;
static uint8_t periodCounter, nextPwm = 0x80,
synthPeriod, bufBits,
csBitMask, clkBitMask, datBitMask;
static const uint8_t *ptrAddr;
static const int16_t PROGMEM
tmsK1[] = {0x82C0,0x8380,0x83C0,0x8440,0x84C0,0x8540,0x8600,0x8780,
0x8880,0x8980,0x8AC0,0x8C00,0x8D40,0x8F00,0x90C0,0x92C0,
0x9900,0xA140,0xAB80,0xB840,0xC740,0xD8C0,0xEBC0,0x0000,
0x1440,0x2740,0x38C0,0x47C0,0x5480,0x5EC0,0x6700,0x6D40},
tmsK2[] = {0xAE00,0xB480,0xBB80,0xC340,0xCB80,0xD440,0xDDC0,0xE780,
0xF180,0xFBC0,0x0600,0x1040,0x1A40,0x2400,0x2D40,0x3600,
0x3E40,0x45C0,0x4CC0,0x5300,0x5880,0x5DC0,0x6240,0x6640,
0x69C0,0x6CC0,0x6F80,0x71C0,0x73C0,0x7580,0x7700,0x7E80};
static const int8_t PROGMEM
tmsK3[] = {0x92,0x9F,0xAD,0xBA,0xC8,0xD5,0xE3,0xF0,
0xFE,0x0B,0x19,0x26,0x34,0x41,0x4F,0x5C},
tmsK4[] = {0xAE,0xBC,0xCA,0xD8,0xE6,0xF4,0x01,0x0F,
0x1D,0x2B,0x39,0x47,0x55,0x63,0x71,0x7E},
tmsK5[] = {0xAE,0xBA,0xC5,0xD1,0xDD,0xE8,0xF4,0xFF,
0x0B,0x17,0x22,0x2E,0x39,0x45,0x51,0x5C},
tmsK6[] = {0xC0,0xCB,0xD6,0xE1,0xEC,0xF7,0x03,0x0E,
0x19,0x24,0x2F,0x3A,0x45,0x50,0x5B,0x66},
tmsK7[] = {0xB3,0xBF,0xCB,0xD7,0xE3,0xEF,0xFB,0x07,
0x13,0x1F,0x2B,0x37,0x43,0x4F,0x5A,0x66},
tmsK8[] = {0xC0,0xD8,0xF0,0x07,0x1F,0x37,0x4F,0x66},
tmsK9[] = {0xC0,0xD4,0xE8,0xFC,0x10,0x25,0x39,0x4D},
tmsK10[] = {0xCD,0xDF,0xF1,0x04,0x16,0x20,0x3B,0x4D},
chirp[] = {0x00,0x2A,0xD4,0x32,0xB2,0x12,0x25,0x14,
0x02,0xE1,0xC5,0x02,0x5F,0x5A,0x05,0x0F,
0x26,0xFC,0xA5,0xA5,0xD6,0xDD,0xDC,0xFC,
0x25,0x2B,0x22,0x21,0x0F,0xFF,0xF8,0xEE,
0xED,0xEF,0xF7,0xF6,0xFA,0x00,0x03,0x02,0x01};
static const uint8_t PROGMEM
tmsEnergy[] = {0x00,0x02,0x03,0x04,0x05,0x07,0x0A,0x0F,
0x14,0x20,0x29,0x39,0x51,0x72,0xA1,0xFF},
tmsPeriod[] = {0x00,0x10,0x11,0x12,0x13,0x14,0x15,0x16,
0x17,0x18,0x19,0x1A,0x1B,0x1C,0x1D,0x1E,
0x1F,0x20,0x21,0x22,0x23,0x24,0x25,0x26,
0x27,0x28,0x29,0x2A,0x2B,0x2D,0x2F,0x31,
0x33,0x35,0x36,0x39,0x3B,0x3D,0x3F,0x42,
0x45,0x47,0x49,0x4D,0x4F,0x51,0x55,0x57,
0x5C,0x5F,0x63,0x66,0x6A,0x6E,0x73,0x77,
0x7B,0x80,0x85,0x8A,0x8F,0x95,0x9A,0xA0};
// Constructor for PWM mode
Talkie::Talkie(void) {
#if defined(__AVR_ATmega32U4__)
pinMode(5, OUTPUT); // !OC4A
#else
pinMode(3, OUTPUT); // OC2B
#endif
#ifdef PIEZO
pinMode(11, OUTPUT); // OC2A
#endif
csBitMask = 0; // DAC not in use
}
// Constructor for DAC mode
Talkie::Talkie(uint8_t cs, uint8_t clk, uint8_t dat) {
csPort = portOutputRegister(digitalPinToPort(cs));
csBitMask = digitalPinToBitMask(cs);
clkPort = portOutputRegister(digitalPinToPort(clk));
clkBitMask = digitalPinToBitMask(clk);
datPort = portOutputRegister(digitalPinToPort(dat));
datBitMask = digitalPinToBitMask(dat);
pinMode(cs , OUTPUT);
pinMode(clk, OUTPUT);
pinMode(dat, OUTPUT);
*csPort |= csBitMask; // Deselect
*clkPort &= ~clkBitMask; // Clock low
}
void Talkie::say(const uint8_t *addr, boolean block) {
// Enable the speech system whenever say() is called.
if(!csBitMask) {
#if defined(__AVR_ATmega32U4__)
// Set up Timer4 for fast PWM on !OC4A
PLLFRQ = (PLLFRQ & 0xCF) | 0x30; // Route PLL to async clk
TCCR4A = _BV(COM4A0) | _BV(PWM4A); // Clear on match, PWMA on
TCCR4B = _BV(PWM4X) |_BV(CS40); // PWM invert, 1:1 prescale
TCCR4D = 0; // Fast PWM mode
TCCR4E = 0; // Not enhanced mode
TC4H = 0; // Not 10-bit mode
DT4 = 0; // No dead time
OCR4C = 255; // TOP
OCR4A = 127; // 50% duty to start
#else
// Set up Timer2 for 8-bit, 62500 Hz PWM on OC2B
TCCR2A = _BV(COM2B1) | _BV(WGM21) | _BV(WGM20);
TCCR2B = _BV(CS20); // No prescale
TIMSK2 = 0; // No interrupt
OCR2B = 0x80; // 50% duty cycle
#ifdef PIEZO
OCR2A = 0x80;
TCCR2A |= _BV(COM2A1) | _BV(COM2A0); // OC2A inverting mode
#endif
#endif
}
// Reset synth state and 'ROM' reader
x0 = x1 = x2 = x3 = x4 = x5 = x6 = x7 = x8 =
periodCounter = buf = bufBits = 0;
ptrAddr = addr;
interruptCount = TICKS; // modif rate
// Set up Timer1 to trigger periodic synth calc at 'FS' Hz
TCCR1A = 0; // No output
TCCR1B = _BV(WGM12) | _BV(CS10); // CTC mode, no prescale
//OCR1A = ((F_CPU + (FS / 2)) / FS) - 1; // 'FS' Hz (w/rounding)
OCR1A = F_CPU / FS;
TCNT1 = 0; // Reset counter
TIMSK1 = _BV(OCIE1A); // Compare match interrupt on
if(block) while(TIMSK1 & _BV(OCIE1A));
slower= map(analogRead(0),0,1023,600,0);
}
boolean Talkie::talking(void) {
return TIMSK1 & _BV(OCIE1A);
}
static inline uint8_t rev(uint8_t a) { // Reverse bit sequence in 8-bit value
a = ( a >> 4) | ( a << 4); // 76543210 -> 32107654
a = ((a & 0xCC) >> 2) | ((a & 0x33) << 2); // 32107654 -> 10325476
a = ((a & 0xAA) >> 1) | ((a & 0x55) << 1); // 10325476 -> 01234567
return a;
}
static uint8_t getBits(uint8_t bits) {
uint8_t value;
if(bits > bufBits) {
buf |= rev(pgm_read_byte(ptrAddr)) << (8 - bufBits);
bufBits += 8;
ptrAddr++; // Don't post-inc in pgm_read_byte! Is a macro.
}
value = buf >> (16 - bits);
buf <<= bits;
bufBits -= bits;
return value;
}
static void dacOut(uint8_t value) {
uint8_t bit;
*csPort &= ~csBitMask; // Select DAC
// Clock out 4 bits DAC config (not in loop because it's constant)
*datPort &= ~datBitMask; // 0 = Select DAC A, unbuffered
*clkPort |= clkBitMask; *clkPort &= ~clkBitMask;
*clkPort |= clkBitMask; *clkPort &= ~clkBitMask;
*datPort |= datBitMask; // 1X gain, enable = 1
*clkPort |= clkBitMask; *clkPort &= ~clkBitMask;
*clkPort |= clkBitMask; *clkPort &= ~clkBitMask;
// Output is expanded from 8 to 12 bits for DAC. Perhaps the
// synthesizer math could be fiddled to generate 12-bit values.
for(bit=0x80; bit; bit>>=1) { // Clock out first 8 bits of data
if(value & bit) *datPort |= datBitMask;
else *datPort &= ~datBitMask;
*clkPort |= clkBitMask; *clkPort &= ~clkBitMask;
}
for(bit=0x80; bit >= 0x10; bit>>=1) { // Low 4 bits = repeat hi 4
if(value & bit) *datPort |= datBitMask;
else *datPort &= ~datBitMask;
*clkPort |= clkBitMask; *clkPort &= ~clkBitMask;
}
*csPort |= csBitMask; // Unselect DAC
}
#define read8(base, bits) pgm_read_byte(&base[getBits(bits)]);
#define read16(base, bits) pgm_read_word(&base[getBits(bits)]);
ISR(TIMER1_COMPA_vect) {
int16_t u0;
if(csBitMask) dacOut(nextPwm);
#if defined(__AVR_ATmega32U4__)
else OCR4A = nextPwm;
#else
#ifdef PIEZO
else OCR2A = OCR2B = nextPwm;
#else
else OCR2B = nextPwm;
#endif
#endif
if(++interruptCount >= TICKS+slower){
// Read speech data, processing the variable size frames
uint8_t energy;
if((energy = getBits(4)) == 0) { // Rest frame
synthEnergy = 0;
} else if(energy == 0xF) { // Stop frame; silence
TIMSK1 &= ~_BV(OCIE1A); // Stop interrupt
nextPwm = 0x80; // Neutral
if(csBitMask) {
dacOut(nextPwm);
} else {
// Stop PWM out:
#if defined(__AVR_ATmega32U4__)
TCCR4A = 0;
#else
//TCCR2A = 0; // to avoid "Plop" between speech
#endif
}
return;
} else {
synthEnergy = pgm_read_byte(&tmsEnergy[energy]);
uint8_t repeat = getBits(1);
synthPeriod = pgm_read_byte(&tmsPeriod[getBits(6)]);
if(!repeat) { // A repeat frame uses last coefficients
synthK1 = read16(tmsK1, 5); // All frames
synthK2 = read16(tmsK2, 5); // use the first
synthK3 = read8( tmsK3, 4); // 4 coefficients
synthK4 = read8( tmsK4, 4);
if(synthPeriod) {
synthK5 = read8(tmsK5 , 4); // Voiced
synthK6 = read8(tmsK6 , 4); // frames
synthK7 = read8(tmsK7 , 4); // use
synthK8 = read8(tmsK8 , 3); // six
synthK9 = read8(tmsK9 , 3); // extra
synthK10 = read8(tmsK10, 3); // coeffs
}
}
}
interruptCount = 0;
}
if(synthPeriod) { // Voiced source
if(++periodCounter >= synthPeriod) periodCounter = 0;
u0 = (periodCounter >= sizeof(chirp)) ? 0 :
(pgm_read_byte(&chirp[periodCounter]) *
(uint32_t)synthEnergy) >> 8;
} else { // Unvoiced source
synthRand = (synthRand >> 1) ^ ((synthRand & 1) ? 0xB800 : 0);
u0 = (synthRand & 1) ? synthEnergy : -synthEnergy;
}
u0 -= ((synthK10 * x9) +
(synthK9 * x8)) >> 7;
x9 = x8 + ((synthK9 * u0 ) >> 7);
u0 -= ((synthK8 * x7 ) >> 7);
x8 = x7 + ((synthK8 * u0 ) >> 7);
u0 -= ((synthK7 * x6 ) >> 7);
x7 = x6 + ((synthK7 * u0 ) >> 7);
u0 -= ((synthK6 * x5 ) >> 7);
x6 = x5 + ((synthK6 * u0 ) >> 7);
u0 -= ((synthK5 * x4 ) >> 7);
x5 = x4 + ((synthK5 * u0 ) >> 7);
u0 -= ((synthK4 * x3 ) >> 7);
x4 = x3 + ((synthK4 * u0 ) >> 7);
u0 -= ((synthK3 * x2 ) >> 7);
x3 = x2 + ((synthK3 * u0 ) >> 7);
u0 -= ((synthK2 * (int32_t)x1 ) >> 15);
x2 = x1 + ((synthK2 * (int32_t)u0 ) >> 15);
u0 -= ((synthK1 * (int32_t)x0 ) >> 15);
x1 = x0 + ((synthK1 * (int32_t)u0 ) >> 15);
if( u0 > 511) u0 = 511; // Output clamp
else if(u0 < -512) u0 = -512;
x0 = u0;
nextPwm = (u0 >> 2) + 0x80;
}