5quinque · February 10, 2021 21:32
diff --git a/ArduinoISP_ProMicro_ATmega32U4.cpp b/ArduinoISP_ProMicro_ATmega32U4.cpp
 // ArduinoISP
 // Copyright (c) 2008-2011 Randall Bohn
 // If you require a license, see
 // http://www.opensource.org/licenses/bsd-license.php
 //
 // This sketch turns the Arduino into a AVRISP using the following Arduino pins:
 //
 // Pin 10 is used to reset the target microcontroller.
 //
 // By default, the hardware SPI pins MISO, MOSI and SCK are used to communicate
 // with the target. On all Arduinos, these pins can be found
 // on the ICSP/SPI header:
 //
 //               MISO °. . 5V (!) Avoid this pin on Due, Zero...
 //               SCK   . . MOSI
 //                     . . GND
 //
 // On some Arduinos (Uno,...), pins MOSI, MISO and SCK are the same pins as
 // digital pin 11, 12 and 13, respectively. That is why many tutorials instruct
 // you to hook up the target to these pins. If you find this wiring more
 // practical, have a define USE_OLD_STYLE_WIRING. This will work even when not
 // using an Uno. (On an Uno this is not needed).
 //
 // Alternatively you can use any other digital pin by configuring
 // software ('BitBanged') SPI and having appropriate defines for PIN_MOSI,
 // PIN_MISO and PIN_SCK.
 //
 // IMPORTANT: When using an Arduino that is not 5V tolerant (Due, Zero, ...) as
 // the programmer, make sure to not expose any of the programmer's pins to 5V.
 // A simple way to accomplish this is to power the complete system (programmer
 // and target) at 3V3.
 //
 // Put an LED (with resistor) on the following pins:
 // 9: Heartbeat   - shows the programmer is running
 // 8: Error       - Lights up if something goes wrong (use red if that makes sense)
 // 7: Programming - In communication with the slave
 //

 #include "Arduino.h"
 #undef SERIAL


 #define PROG_FLICKER true

 // Configure SPI clock (in Hz).
 // E.g. for an ATtiny @ 128 kHz: the datasheet states that both the high and low
 // SPI clock pulse must be > 2 CPU cycles, so take 3 cycles i.e. divide target
 // f_cpu by 6:
 //     #define SPI_CLOCK            (128000/6)
 //
 // A clock slow enough for an ATtiny85 @ 1 MHz, is a reasonable default:

 #define SPI_CLOCK 		(1000000/6)


 // Select hardware or software SPI, depending on SPI clock.
 // Currently only for AVR, for other architectures (Due, Zero,...), hardware SPI
 // is probably too fast anyway.

 #if defined(ARDUINO_ARCH_AVR)

 #if SPI_CLOCK > (F_CPU / 128)
 #define USE_HARDWARE_SPI
 #endif

 #endif

 // Configure which pins to use:

 // The standard pin configuration.
 #ifndef ARDUINO_HOODLOADER2

 #define RESET     10 // Use pin 10 to reset the target rather than SS
 #define LED_HB    9
 #define LED_ERR   8
 #define LED_PMODE 7

 // Uncomment following line to use the old Uno style wiring
 // (using pin 11, 12 and 13 instead of the SPI header) on Leonardo, Due...

 #define USE_OLD_STYLE_WIRING

 #ifdef USE_OLD_STYLE_WIRING

 #define PIN_MOSI	16
 #define PIN_MISO	14
 #define PIN_SCK		15

 #endif

 // HOODLOADER2 means running sketches on the ATmega16U2 serial converter chips
 // on Uno or Mega boards. We must use pins that are broken out:
 #else

 #define RESET     	4
 #define LED_HB    	7
 #define LED_ERR   	6
 #define LED_PMODE 	5

 #endif

 // By default, use hardware SPI pins:
 #ifndef PIN_MOSI
 #define PIN_MOSI 	MOSI
 #endif

 #ifndef PIN_MISO
 #define PIN_MISO 	MISO
 #endif

 #ifndef PIN_SCK
 #define PIN_SCK 	SCK
 #endif

 // Force bitbanged SPI if not using the hardware SPI pins:
 #if (PIN_MISO != MISO) ||  (PIN_MOSI != MOSI) || (PIN_SCK != SCK)
 #undef USE_HARDWARE_SPI
 #endif


 // Configure the serial port to use.
 //
 // Prefer the USB virtual serial port (aka. native USB port), if the Arduino has one:
 //   - it does not autoreset (except for the magic baud rate of 1200).
 //   - it is more reliable because of USB handshaking.
 //
 // Leonardo and similar have an USB virtual serial port: 'Serial'.
 // Due and Zero have an USB virtual serial port: 'SerialUSB'.
 //
 // On the Due and Zero, 'Serial' can be used too, provided you disable autoreset.
 // To use 'Serial': #define SERIAL Serial

 #ifdef SERIAL_PORT_USBVIRTUAL
 #define SERIAL SERIAL_PORT_USBVIRTUAL
 #else
 #define SERIAL Serial
 #endif


 // Configure the baud rate:

 #define BAUDRATE	19200
 // #define BAUDRATE	115200
 // #define BAUDRATE	1000000


 #define HWVER 2
 #define SWMAJ 1
 #define SWMIN 18

 // STK Definitions
 #define STK_OK      0x10
 #define STK_FAILED  0x11
 #define STK_UNKNOWN 0x12
 #define STK_INSYNC  0x14
 #define STK_NOSYNC  0x15
 #define CRC_EOP     0x20 //ok it is a space...

 void pulse(int pin, int times);

 #ifdef USE_HARDWARE_SPI
 #include "SPI.h"
 #else

 #define SPI_MODE0 0x00

 class SPISettings {
  public:
    // clock is in Hz
    SPISettings(uint32_t clock, uint8_t bitOrder, uint8_t dataMode) : clock(clock) {
      (void) bitOrder;
      (void) dataMode;
    };

  private:
    uint32_t clock;

    friend class BitBangedSPI;
 };

 class BitBangedSPI {
  public:
    void begin() {
      digitalWrite(PIN_SCK, LOW);
      digitalWrite(PIN_MOSI, LOW);
      pinMode(PIN_SCK, OUTPUT);
      pinMode(PIN_MOSI, OUTPUT);
      pinMode(PIN_MISO, INPUT);
    }

    void beginTransaction(SPISettings settings) {
      pulseWidth = (500000 + settings.clock - 1) / settings.clock;
      if (pulseWidth == 0)
        pulseWidth = 1;
    }

    void end() {}

    uint8_t transfer (uint8_t b) {
      for (unsigned int i = 0; i < 8; ++i) {
        digitalWrite(PIN_MOSI, (b & 0x80) ? HIGH : LOW);
        digitalWrite(PIN_SCK, HIGH);
        delayMicroseconds(pulseWidth);
        b = (b << 1) | digitalRead(PIN_MISO);
        digitalWrite(PIN_SCK, LOW); // slow pulse
        delayMicroseconds(pulseWidth);
      }
      return b;
    }

  private:
    unsigned long pulseWidth; // in microseconds
 };

 static BitBangedSPI SPI;

 #endif

 void setup() {
  SERIAL.begin(BAUDRATE);

  pinMode(LED_PMODE, OUTPUT);
  pulse(LED_PMODE, 2);
  pinMode(LED_ERR, OUTPUT);
  pulse(LED_ERR, 2);
  pinMode(LED_HB, OUTPUT);
  pulse(LED_HB, 2);

 }

 int error = 0;
 int pmode = 0;
 // address for reading and writing, set by 'U' command
 unsigned int here;
 uint8_t buff[256]; // global block storage

 #define beget16(addr) (*addr * 256 + *(addr+1) )
 typedef struct param {
  uint8_t devicecode;
  uint8_t revision;
  uint8_t progtype;
  uint8_t parmode;
  uint8_t polling;
  uint8_t selftimed;
  uint8_t lockbytes;
  uint8_t fusebytes;
  uint8_t flashpoll;
  uint16_t eeprompoll;
  uint16_t pagesize;
  uint16_t eepromsize;
  uint32_t flashsize;
 }
 parameter;

 parameter param;

 // this provides a heartbeat on pin 9, so you can tell the software is running.
 uint8_t hbval = 128;
 int8_t hbdelta = 8;
 void heartbeat() {
  static unsigned long last_time = 0;
  unsigned long now = millis();
  if ((now - last_time) < 40)
    return;
  last_time = now;
  if (hbval > 192) hbdelta = -hbdelta;
  if (hbval < 32) hbdelta = -hbdelta;
  hbval += hbdelta;
  analogWrite(LED_HB, hbval);
 }

 static bool rst_active_high;

 void reset_target(bool reset) {
  digitalWrite(RESET, ((reset && rst_active_high) || (!reset && !rst_active_high)) ? HIGH : LOW);
 }

 void loop(void) {
  // is pmode active?
  if (pmode) {
    digitalWrite(LED_PMODE, HIGH);
  } else {
    digitalWrite(LED_PMODE, LOW);
  }
  // is there an error?
  if (error) {
    digitalWrite(LED_ERR, HIGH);
  } else {
    digitalWrite(LED_ERR, LOW);
  }

  // light the heartbeat LED
  heartbeat();
  if (SERIAL.available()) {
    avrisp();
  }
 }

 uint8_t getch() {
  while (!SERIAL.available());
  return SERIAL.read();
 }
 void fill(int n) {
  for (int x = 0; x < n; x++) {
    buff[x] = getch();
  }
 }

 #define PTIME 30
 void pulse(int pin, int times) {
  do {
    digitalWrite(pin, HIGH);
    delay(PTIME);
    digitalWrite(pin, LOW);
    delay(PTIME);
  } while (times--);
 }

 void prog_lamp(int state) {
  if (PROG_FLICKER) {
    digitalWrite(LED_PMODE, state);
  }
 }

 uint8_t spi_transaction(uint8_t a, uint8_t b, uint8_t c, uint8_t d) {
  SPI.transfer(a);
  SPI.transfer(b);
  SPI.transfer(c);
  return SPI.transfer(d);
 }

 void empty_reply() {
  if (CRC_EOP == getch()) {
    SERIAL.print((char)STK_INSYNC);
    SERIAL.print((char)STK_OK);
  } else {
    error++;
    SERIAL.print((char)STK_NOSYNC);
  }
 }

 void breply(uint8_t b) {
  if (CRC_EOP == getch()) {
    SERIAL.print((char)STK_INSYNC);
    SERIAL.print((char)b);
    SERIAL.print((char)STK_OK);
  } else {
    error++;
    SERIAL.print((char)STK_NOSYNC);
  }
 }

 void get_version(uint8_t c) {
  switch (c) {
    case 0x80:
      breply(HWVER);
      break;
    case 0x81:
      breply(SWMAJ);
      break;
    case 0x82:
      breply(SWMIN);
      break;
    case 0x93:
      breply('S'); // serial programmer
      break;
    default:
      breply(0);
  }
 }

 void set_parameters() {
  // call this after reading parameter packet into buff[]
  param.devicecode = buff[0];
  param.revision   = buff[1];
  param.progtype   = buff[2];
  param.parmode    = buff[3];
  param.polling    = buff[4];
  param.selftimed  = buff[5];
  param.lockbytes  = buff[6];
  param.fusebytes  = buff[7];
  param.flashpoll  = buff[8];
  // ignore buff[9] (= buff[8])
  // following are 16 bits (big endian)
  param.eeprompoll = beget16(&buff[10]);
  param.pagesize   = beget16(&buff[12]);
  param.eepromsize = beget16(&buff[14]);

  // 32 bits flashsize (big endian)
  param.flashsize = buff[16] * 0x01000000
                    + buff[17] * 0x00010000
                    + buff[18] * 0x00000100
                    + buff[19];

  // AVR devices have active low reset, AT89Sx are active high
  rst_active_high = (param.devicecode >= 0xe0);
 }

 void start_pmode() {

  // Reset target before driving PIN_SCK or PIN_MOSI

  // SPI.begin() will configure SS as output, so SPI master mode is selected.
  // We have defined RESET as pin 10, which for many Arduinos is not the SS pin.
  // So we have to configure RESET as output here,
  // (reset_target() first sets the correct level)
  reset_target(true);
  pinMode(RESET, OUTPUT);
  SPI.begin();
  SPI.beginTransaction(SPISettings(SPI_CLOCK, MSBFIRST, SPI_MODE0));

  // See AVR datasheets, chapter "SERIAL_PRG Programming Algorithm":

  // Pulse RESET after PIN_SCK is low:
  digitalWrite(PIN_SCK, LOW);
  delay(20); // discharge PIN_SCK, value arbitrarily chosen
  reset_target(false);
  // Pulse must be minimum 2 target CPU clock cycles so 100 usec is ok for CPU
  // speeds above 20 KHz
  delayMicroseconds(100);
  reset_target(true);

  // Send the enable programming command:
  delay(50); // datasheet: must be > 20 msec
  spi_transaction(0xAC, 0x53, 0x00, 0x00);
  pmode = 1;
 }

 void end_pmode() {
  SPI.end();
  // We're about to take the target out of reset so configure SPI pins as input
  pinMode(PIN_MOSI, INPUT);
  pinMode(PIN_SCK, INPUT);
  reset_target(false);
  pinMode(RESET, INPUT);
  pmode = 0;
 }

 void universal() {
  uint8_t ch;

  fill(4);
  ch = spi_transaction(buff[0], buff[1], buff[2], buff[3]);
  breply(ch);
 }

 void flash(uint8_t hilo, unsigned int addr, uint8_t data) {
  spi_transaction(0x40 + 8 * hilo,
                  addr >> 8 & 0xFF,
                  addr & 0xFF,
                  data);
 }
 void commit(unsigned int addr) {
  if (PROG_FLICKER) {
    prog_lamp(LOW);
  }
  spi_transaction(0x4C, (addr >> 8) & 0xFF, addr & 0xFF, 0);
  if (PROG_FLICKER) {
    delay(PTIME);
    prog_lamp(HIGH);
  }
 }

 unsigned int current_page() {
  if (param.pagesize == 32) {
    return here & 0xFFFFFFF0;
  }
  if (param.pagesize == 64) {
    return here & 0xFFFFFFE0;
  }
  if (param.pagesize == 128) {
    return here & 0xFFFFFFC0;
  }
  if (param.pagesize == 256) {
    return here & 0xFFFFFF80;
  }
  return here;
 }


 void write_flash(int length) {
  fill(length);
  if (CRC_EOP == getch()) {
    SERIAL.print((char) STK_INSYNC);
    SERIAL.print((char) write_flash_pages(length));
  } else {
    error++;
    SERIAL.print((char) STK_NOSYNC);
  }
 }

 uint8_t write_flash_pages(int length) {
  int x = 0;
  unsigned int page = current_page();
  while (x < length) {
    if (page != current_page()) {
      commit(page);
      page = current_page();
    }
    flash(LOW, here, buff[x++]);
    flash(HIGH, here, buff[x++]);
    here++;
  }

  commit(page);

  return STK_OK;
 }

 #define EECHUNK (32)
 uint8_t write_eeprom(unsigned int length) {
  // here is a word address, get the byte address
  unsigned int start = here * 2;
  unsigned int remaining = length;
  if (length > param.eepromsize) {
    error++;
    return STK_FAILED;
  }
  while (remaining > EECHUNK) {
    write_eeprom_chunk(start, EECHUNK);
    start += EECHUNK;
    remaining -= EECHUNK;
  }
  write_eeprom_chunk(start, remaining);
  return STK_OK;
 }
 // write (length) bytes, (start) is a byte address
 uint8_t write_eeprom_chunk(unsigned int start, unsigned int length) {
  // this writes byte-by-byte, page writing may be faster (4 bytes at a time)
  fill(length);
  prog_lamp(LOW);
  for (unsigned int x = 0; x < length; x++) {
    unsigned int addr = start + x;
    spi_transaction(0xC0, (addr >> 8) & 0xFF, addr & 0xFF, buff[x]);
    delay(45);
  }
  prog_lamp(HIGH);
  return STK_OK;
 }

 void program_page() {
  char result = (char) STK_FAILED;
  unsigned int length = 256 * getch();
  length += getch();
  char memtype = getch();
  // flash memory @here, (length) bytes
  if (memtype == 'F') {
    write_flash(length);
    return;
  }
  if (memtype == 'E') {
    result = (char)write_eeprom(length);
    if (CRC_EOP == getch()) {
      SERIAL.print((char) STK_INSYNC);
      SERIAL.print(result);
    } else {
      error++;
      SERIAL.print((char) STK_NOSYNC);
    }
    return;
  }
  SERIAL.print((char)STK_FAILED);
  return;
 }

 uint8_t flash_read(uint8_t hilo, unsigned int addr) {
  return spi_transaction(0x20 + hilo * 8,
                         (addr >> 8) & 0xFF,
                         addr & 0xFF,
                         0);
 }

 char flash_read_page(int length) {
  for (int x = 0; x < length; x += 2) {
    uint8_t low = flash_read(LOW, here);
    SERIAL.print((char) low);
    uint8_t high = flash_read(HIGH, here);
    SERIAL.print((char) high);
    here++;
  }
  return STK_OK;
 }

 char eeprom_read_page(int length) {
  // here again we have a word address
  int start = here * 2;
  for (int x = 0; x < length; x++) {
    int addr = start + x;
    uint8_t ee = spi_transaction(0xA0, (addr >> 8) & 0xFF, addr & 0xFF, 0xFF);
    SERIAL.print((char) ee);
  }
  return STK_OK;
 }

 void read_page() {
  char result = (char)STK_FAILED;
  int length = 256 * getch();
  length += getch();
  char memtype = getch();
  if (CRC_EOP != getch()) {
    error++;
    SERIAL.print((char) STK_NOSYNC);
    return;
  }
  SERIAL.print((char) STK_INSYNC);
  if (memtype == 'F') result = flash_read_page(length);
  if (memtype == 'E') result = eeprom_read_page(length);
  SERIAL.print(result);
 }

 void read_signature() {
  if (CRC_EOP != getch()) {
    error++;
    SERIAL.print((char) STK_NOSYNC);
    return;
  }
  SERIAL.print((char) STK_INSYNC);
  uint8_t high = spi_transaction(0x30, 0x00, 0x00, 0x00);
  SERIAL.print((char) high);
  uint8_t middle = spi_transaction(0x30, 0x00, 0x01, 0x00);
  SERIAL.print((char) middle);
  uint8_t low = spi_transaction(0x30, 0x00, 0x02, 0x00);
  SERIAL.print((char) low);
  SERIAL.print((char) STK_OK);
 }
 //////////////////////////////////////////
 //////////////////////////////////////////


 ////////////////////////////////////
 ////////////////////////////////////
 void avrisp() {
  uint8_t ch = getch();
  switch (ch) {
    case '0': // signon
      error = 0;
      empty_reply();
      break;
    case '1':
      if (getch() == CRC_EOP) {
        SERIAL.print((char) STK_INSYNC);
        SERIAL.print("AVR ISP");
        SERIAL.print((char) STK_OK);
      }
      else {
        error++;
        SERIAL.print((char) STK_NOSYNC);
      }
      break;
    case 'A':
      get_version(getch());
      break;
    case 'B':
      fill(20);
      set_parameters();
      empty_reply();
      break;
    case 'E': // extended parameters - ignore for now
      fill(5);
      empty_reply();
      break;
    case 'P':
      if (!pmode)
        start_pmode();
      empty_reply();
      break;
    case 'U': // set address (word)
      here = getch();
      here += 256 * getch();
      empty_reply();
      break;

    case 0x60: //STK_PROG_FLASH
      getch(); // low addr
      getch(); // high addr
      empty_reply();
      break;
    case 0x61: //STK_PROG_DATA
      getch(); // data
      empty_reply();
      break;

    case 0x64: //STK_PROG_PAGE
      program_page();
      break;

    case 0x74: //STK_READ_PAGE 't'
      read_page();
      break;

    case 'V': //0x56
      universal();
      break;
    case 'Q': //0x51
      error = 0;
      end_pmode();
      empty_reply();
      break;

    case 0x75: //STK_READ_SIGN 'u'
      read_signature();
      break;

    // expecting a command, not CRC_EOP
    // this is how we can get back in sync
    case CRC_EOP:
      error++;
      SERIAL.print((char) STK_NOSYNC);
      break;

    // anything else we will return STK_UNKNOWN
    default:
      error++;
      if (CRC_EOP == getch())
        SERIAL.print((char)STK_UNKNOWN);
      else
        SERIAL.print((char)STK_NOSYNC);
  }
 }
	// ArduinoISP
	// Copyright (c) 2008-2011 Randall Bohn
	// If you require a license, see
	// http://www.opensource.org/licenses/bsd-license.php
	//
	// This sketch turns the Arduino into a AVRISP using the following Arduino pins:
	//
	// Pin 10 is used to reset the target microcontroller.
	//
	// By default, the hardware SPI pins MISO, MOSI and SCK are used to communicate
	// with the target. On all Arduinos, these pins can be found
	// on the ICSP/SPI header:
	//
	// MISO °. . 5V (!) Avoid this pin on Due, Zero...
	// SCK . . MOSI
	// . . GND
	//
	// On some Arduinos (Uno,...), pins MOSI, MISO and SCK are the same pins as
	// digital pin 11, 12 and 13, respectively. That is why many tutorials instruct
	// you to hook up the target to these pins. If you find this wiring more
	// practical, have a define USE_OLD_STYLE_WIRING. This will work even when not
	// using an Uno. (On an Uno this is not needed).
	//
	// Alternatively you can use any other digital pin by configuring
	// software ('BitBanged') SPI and having appropriate defines for PIN_MOSI,
	// PIN_MISO and PIN_SCK.
	//
	// IMPORTANT: When using an Arduino that is not 5V tolerant (Due, Zero, ...) as
	// the programmer, make sure to not expose any of the programmer's pins to 5V.
	// A simple way to accomplish this is to power the complete system (programmer
	// and target) at 3V3.
	//
	// Put an LED (with resistor) on the following pins:
	// 9: Heartbeat - shows the programmer is running
	// 8: Error - Lights up if something goes wrong (use red if that makes sense)
	// 7: Programming - In communication with the slave
	//

	#include "Arduino.h"
	#undef SERIAL


	#define PROG_FLICKER true

	// Configure SPI clock (in Hz).
	// E.g. for an ATtiny @ 128 kHz: the datasheet states that both the high and low
	// SPI clock pulse must be > 2 CPU cycles, so take 3 cycles i.e. divide target
	// f_cpu by 6:
	// #define SPI_CLOCK (128000/6)
	//
	// A clock slow enough for an ATtiny85 @ 1 MHz, is a reasonable default:

	#define SPI_CLOCK (1000000/6)


	// Select hardware or software SPI, depending on SPI clock.
	// Currently only for AVR, for other architectures (Due, Zero,...), hardware SPI
	// is probably too fast anyway.

	#if defined(ARDUINO_ARCH_AVR)

	#if SPI_CLOCK > (F_CPU / 128)
	#define USE_HARDWARE_SPI
	#endif

	#endif

	// Configure which pins to use:

	// The standard pin configuration.
	#ifndef ARDUINO_HOODLOADER2

	#define RESET 10 // Use pin 10 to reset the target rather than SS
	#define LED_HB 9
	#define LED_ERR 8
	#define LED_PMODE 7

	// Uncomment following line to use the old Uno style wiring
	// (using pin 11, 12 and 13 instead of the SPI header) on Leonardo, Due...

	#define USE_OLD_STYLE_WIRING

	#ifdef USE_OLD_STYLE_WIRING

	#define PIN_MOSI 16
	#define PIN_MISO 14
	#define PIN_SCK 15

	#endif

	// HOODLOADER2 means running sketches on the ATmega16U2 serial converter chips
	// on Uno or Mega boards. We must use pins that are broken out:
	#else

	#define RESET 4
	#define LED_HB 7
	#define LED_ERR 6
	#define LED_PMODE 5

	#endif

	// By default, use hardware SPI pins:
	#ifndef PIN_MOSI
	#define PIN_MOSI MOSI
	#endif

	#ifndef PIN_MISO
	#define PIN_MISO MISO
	#endif

	#ifndef PIN_SCK
	#define PIN_SCK SCK
	#endif

	// Force bitbanged SPI if not using the hardware SPI pins:
	#if (PIN_MISO != MISO) \|\| (PIN_MOSI != MOSI) \|\| (PIN_SCK != SCK)
	#undef USE_HARDWARE_SPI
	#endif


	// Configure the serial port to use.
	//
	// Prefer the USB virtual serial port (aka. native USB port), if the Arduino has one:
	// - it does not autoreset (except for the magic baud rate of 1200).
	// - it is more reliable because of USB handshaking.
	//
	// Leonardo and similar have an USB virtual serial port: 'Serial'.
	// Due and Zero have an USB virtual serial port: 'SerialUSB'.
	//
	// On the Due and Zero, 'Serial' can be used too, provided you disable autoreset.
	// To use 'Serial': #define SERIAL Serial

	#ifdef SERIAL_PORT_USBVIRTUAL
	#define SERIAL SERIAL_PORT_USBVIRTUAL
	#else
	#define SERIAL Serial
	#endif


	// Configure the baud rate:

	#define BAUDRATE 19200
	// #define BAUDRATE 115200
	// #define BAUDRATE 1000000


	#define HWVER 2
	#define SWMAJ 1
	#define SWMIN 18

	// STK Definitions
	#define STK_OK 0x10
	#define STK_FAILED 0x11
	#define STK_UNKNOWN 0x12
	#define STK_INSYNC 0x14
	#define STK_NOSYNC 0x15
	#define CRC_EOP 0x20 //ok it is a space...

	void pulse(int pin, int times);

	#ifdef USE_HARDWARE_SPI
	#include "SPI.h"
	#else

	#define SPI_MODE0 0x00

	class SPISettings {
	public:
	// clock is in Hz
	SPISettings(uint32_t clock, uint8_t bitOrder, uint8_t dataMode) : clock(clock) {
	(void) bitOrder;
	(void) dataMode;
	};

	private:
	uint32_t clock;

	friend class BitBangedSPI;
	};

	class BitBangedSPI {
	public:
	void begin() {
	digitalWrite(PIN_SCK, LOW);
	digitalWrite(PIN_MOSI, LOW);
	pinMode(PIN_SCK, OUTPUT);
	pinMode(PIN_MOSI, OUTPUT);
	pinMode(PIN_MISO, INPUT);
	}

	void beginTransaction(SPISettings settings) {
	pulseWidth = (500000 + settings.clock - 1) / settings.clock;
	if (pulseWidth == 0)
	pulseWidth = 1;
	}

	void end() {}

	uint8_t transfer (uint8_t b) {
	for (unsigned int i = 0; i < 8; ++i) {
	digitalWrite(PIN_MOSI, (b & 0x80) ? HIGH : LOW);
	digitalWrite(PIN_SCK, HIGH);
	delayMicroseconds(pulseWidth);
	b = (b << 1) \| digitalRead(PIN_MISO);
	digitalWrite(PIN_SCK, LOW); // slow pulse
	delayMicroseconds(pulseWidth);
	}
	return b;
	}

	private:
	unsigned long pulseWidth; // in microseconds
	};

	static BitBangedSPI SPI;

	#endif

	void setup() {
	SERIAL.begin(BAUDRATE);

	pinMode(LED_PMODE, OUTPUT);
	pulse(LED_PMODE, 2);
	pinMode(LED_ERR, OUTPUT);
	pulse(LED_ERR, 2);
	pinMode(LED_HB, OUTPUT);
	pulse(LED_HB, 2);

	}

	int error = 0;
	int pmode = 0;
	// address for reading and writing, set by 'U' command
	unsigned int here;
	uint8_t buff[256]; // global block storage

	#define beget16(addr) (addr 256 + *(addr+1) )
	typedef struct param {
	uint8_t devicecode;
	uint8_t revision;
	uint8_t progtype;
	uint8_t parmode;
	uint8_t polling;
	uint8_t selftimed;
	uint8_t lockbytes;
	uint8_t fusebytes;
	uint8_t flashpoll;
	uint16_t eeprompoll;
	uint16_t pagesize;
	uint16_t eepromsize;
	uint32_t flashsize;
	}
	parameter;

	parameter param;

	// this provides a heartbeat on pin 9, so you can tell the software is running.
	uint8_t hbval = 128;
	int8_t hbdelta = 8;
	void heartbeat() {
	static unsigned long last_time = 0;
	unsigned long now = millis();
	if ((now - last_time) < 40)
	return;
	last_time = now;
	if (hbval > 192) hbdelta = -hbdelta;
	if (hbval < 32) hbdelta = -hbdelta;
	hbval += hbdelta;
	analogWrite(LED_HB, hbval);
	}

	static bool rst_active_high;

	void reset_target(bool reset) {
	digitalWrite(RESET, ((reset && rst_active_high) \|\| (!reset && !rst_active_high)) ? HIGH : LOW);
	}

	void loop(void) {
	// is pmode active?
	if (pmode) {
	digitalWrite(LED_PMODE, HIGH);
	} else {
	digitalWrite(LED_PMODE, LOW);
	}
	// is there an error?
	if (error) {
	digitalWrite(LED_ERR, HIGH);
	} else {
	digitalWrite(LED_ERR, LOW);
	}

	// light the heartbeat LED
	heartbeat();
	if (SERIAL.available()) {
	avrisp();
	}
	}

	uint8_t getch() {
	while (!SERIAL.available());
	return SERIAL.read();
	}
	void fill(int n) {
	for (int x = 0; x < n; x++) {
	buff[x] = getch();
	}
	}

	#define PTIME 30
	void pulse(int pin, int times) {
	do {
	digitalWrite(pin, HIGH);
	delay(PTIME);
	digitalWrite(pin, LOW);
	delay(PTIME);
	} while (times--);
	}

	void prog_lamp(int state) {
	if (PROG_FLICKER) {
	digitalWrite(LED_PMODE, state);
	}
	}

	uint8_t spi_transaction(uint8_t a, uint8_t b, uint8_t c, uint8_t d) {
	SPI.transfer(a);
	SPI.transfer(b);
	SPI.transfer(c);
	return SPI.transfer(d);
	}

	void empty_reply() {
	if (CRC_EOP == getch()) {
	SERIAL.print((char)STK_INSYNC);
	SERIAL.print((char)STK_OK);
	} else {
	error++;
	SERIAL.print((char)STK_NOSYNC);
	}
	}

	void breply(uint8_t b) {
	if (CRC_EOP == getch()) {
	SERIAL.print((char)STK_INSYNC);
	SERIAL.print((char)b);
	SERIAL.print((char)STK_OK);
	} else {
	error++;
	SERIAL.print((char)STK_NOSYNC);
	}
	}

	void get_version(uint8_t c) {
	switch (c) {
	case 0x80:
	breply(HWVER);
	break;
	case 0x81:
	breply(SWMAJ);
	break;
	case 0x82:
	breply(SWMIN);
	break;
	case 0x93:
	breply('S'); // serial programmer
	break;
	default:
	breply(0);
	}
	}

	void set_parameters() {
	// call this after reading parameter packet into buff[]
	param.devicecode = buff[0];
	param.revision = buff[1];
	param.progtype = buff[2];
	param.parmode = buff[3];
	param.polling = buff[4];
	param.selftimed = buff[5];
	param.lockbytes = buff[6];
	param.fusebytes = buff[7];
	param.flashpoll = buff[8];
	// ignore buff[9] (= buff[8])
	// following are 16 bits (big endian)
	param.eeprompoll = beget16(&buff[10]);
	param.pagesize = beget16(&buff[12]);
	param.eepromsize = beget16(&buff[14]);

	// 32 bits flashsize (big endian)
	param.flashsize = buff[16] * 0x01000000
	+ buff[17] * 0x00010000
	+ buff[18] * 0x00000100
	+ buff[19];

	// AVR devices have active low reset, AT89Sx are active high
	rst_active_high = (param.devicecode >= 0xe0);
	}

	void start_pmode() {

	// Reset target before driving PIN_SCK or PIN_MOSI

	// SPI.begin() will configure SS as output, so SPI master mode is selected.
	// We have defined RESET as pin 10, which for many Arduinos is not the SS pin.
	// So we have to configure RESET as output here,
	// (reset_target() first sets the correct level)
	reset_target(true);
	pinMode(RESET, OUTPUT);
	SPI.begin();
	SPI.beginTransaction(SPISettings(SPI_CLOCK, MSBFIRST, SPI_MODE0));

	// See AVR datasheets, chapter "SERIAL_PRG Programming Algorithm":

	// Pulse RESET after PIN_SCK is low:
	digitalWrite(PIN_SCK, LOW);
	delay(20); // discharge PIN_SCK, value arbitrarily chosen
	reset_target(false);
	// Pulse must be minimum 2 target CPU clock cycles so 100 usec is ok for CPU
	// speeds above 20 KHz
	delayMicroseconds(100);
	reset_target(true);

	// Send the enable programming command:
	delay(50); // datasheet: must be > 20 msec
	spi_transaction(0xAC, 0x53, 0x00, 0x00);
	pmode = 1;
	}

	void end_pmode() {
	SPI.end();
	// We're about to take the target out of reset so configure SPI pins as input
	pinMode(PIN_MOSI, INPUT);
	pinMode(PIN_SCK, INPUT);
	reset_target(false);
	pinMode(RESET, INPUT);
	pmode = 0;
	}

	void universal() {
	uint8_t ch;

	fill(4);
	ch = spi_transaction(buff[0], buff[1], buff[2], buff[3]);
	breply(ch);
	}

	void flash(uint8_t hilo, unsigned int addr, uint8_t data) {
	spi_transaction(0x40 + 8 * hilo,
	addr >> 8 & 0xFF,
	addr & 0xFF,
	data);
	}
	void commit(unsigned int addr) {
	if (PROG_FLICKER) {
	prog_lamp(LOW);
	}
	spi_transaction(0x4C, (addr >> 8) & 0xFF, addr & 0xFF, 0);
	if (PROG_FLICKER) {
	delay(PTIME);
	prog_lamp(HIGH);
	}
	}

	unsigned int current_page() {
	if (param.pagesize == 32) {
	return here & 0xFFFFFFF0;
	}
	if (param.pagesize == 64) {
	return here & 0xFFFFFFE0;
	}
	if (param.pagesize == 128) {
	return here & 0xFFFFFFC0;
	}
	if (param.pagesize == 256) {
	return here & 0xFFFFFF80;
	}
	return here;
	}


	void write_flash(int length) {
	fill(length);
	if (CRC_EOP == getch()) {
	SERIAL.print((char) STK_INSYNC);
	SERIAL.print((char) write_flash_pages(length));
	} else {
	error++;
	SERIAL.print((char) STK_NOSYNC);
	}
	}

	uint8_t write_flash_pages(int length) {
	int x = 0;
	unsigned int page = current_page();
	while (x < length) {
	if (page != current_page()) {
	commit(page);
	page = current_page();
	}
	flash(LOW, here, buff[x++]);
	flash(HIGH, here, buff[x++]);
	here++;
	}

	commit(page);

	return STK_OK;
	}

	#define EECHUNK (32)
	uint8_t write_eeprom(unsigned int length) {
	// here is a word address, get the byte address
	unsigned int start = here * 2;
	unsigned int remaining = length;
	if (length > param.eepromsize) {
	error++;
	return STK_FAILED;
	}
	while (remaining > EECHUNK) {
	write_eeprom_chunk(start, EECHUNK);
	start += EECHUNK;
	remaining -= EECHUNK;
	}
	write_eeprom_chunk(start, remaining);
	return STK_OK;
	}
	// write (length) bytes, (start) is a byte address
	uint8_t write_eeprom_chunk(unsigned int start, unsigned int length) {
	// this writes byte-by-byte, page writing may be faster (4 bytes at a time)
	fill(length);
	prog_lamp(LOW);
	for (unsigned int x = 0; x < length; x++) {
	unsigned int addr = start + x;
	spi_transaction(0xC0, (addr >> 8) & 0xFF, addr & 0xFF, buff[x]);
	delay(45);
	}
	prog_lamp(HIGH);
	return STK_OK;
	}

	void program_page() {
	char result = (char) STK_FAILED;
	unsigned int length = 256 * getch();
	length += getch();
	char memtype = getch();
	// flash memory @here, (length) bytes
	if (memtype == 'F') {
	write_flash(length);
	return;
	}
	if (memtype == 'E') {
	result = (char)write_eeprom(length);
	if (CRC_EOP == getch()) {
	SERIAL.print((char) STK_INSYNC);
	SERIAL.print(result);
	} else {
	error++;
	SERIAL.print((char) STK_NOSYNC);
	}
	return;
	}
	SERIAL.print((char)STK_FAILED);
	return;
	}

	uint8_t flash_read(uint8_t hilo, unsigned int addr) {
	return spi_transaction(0x20 + hilo * 8,
	(addr >> 8) & 0xFF,
	addr & 0xFF,
	0);
	}

	char flash_read_page(int length) {
	for (int x = 0; x < length; x += 2) {
	uint8_t low = flash_read(LOW, here);
	SERIAL.print((char) low);
	uint8_t high = flash_read(HIGH, here);
	SERIAL.print((char) high);
	here++;
	}
	return STK_OK;
	}

	char eeprom_read_page(int length) {
	// here again we have a word address
	int start = here * 2;
	for (int x = 0; x < length; x++) {
	int addr = start + x;
	uint8_t ee = spi_transaction(0xA0, (addr >> 8) & 0xFF, addr & 0xFF, 0xFF);
	SERIAL.print((char) ee);
	}
	return STK_OK;
	}

	void read_page() {
	char result = (char)STK_FAILED;
	int length = 256 * getch();
	length += getch();
	char memtype = getch();
	if (CRC_EOP != getch()) {
	error++;
	SERIAL.print((char) STK_NOSYNC);
	return;
	}
	SERIAL.print((char) STK_INSYNC);
	if (memtype == 'F') result = flash_read_page(length);
	if (memtype == 'E') result = eeprom_read_page(length);
	SERIAL.print(result);
	}

	void read_signature() {
	if (CRC_EOP != getch()) {
	error++;
	SERIAL.print((char) STK_NOSYNC);
	return;
	}
	SERIAL.print((char) STK_INSYNC);
	uint8_t high = spi_transaction(0x30, 0x00, 0x00, 0x00);
	SERIAL.print((char) high);
	uint8_t middle = spi_transaction(0x30, 0x00, 0x01, 0x00);
	SERIAL.print((char) middle);
	uint8_t low = spi_transaction(0x30, 0x00, 0x02, 0x00);
	SERIAL.print((char) low);
	SERIAL.print((char) STK_OK);
	}
	//////////////////////////////////////////
	//////////////////////////////////////////


	////////////////////////////////////
	////////////////////////////////////
	void avrisp() {
	uint8_t ch = getch();
	switch (ch) {
	case '0': // signon
	error = 0;
	empty_reply();
	break;
	case '1':
	if (getch() == CRC_EOP) {
	SERIAL.print((char) STK_INSYNC);
	SERIAL.print("AVR ISP");
	SERIAL.print((char) STK_OK);
	}
	else {
	error++;
	SERIAL.print((char) STK_NOSYNC);
	}
	break;
	case 'A':
	get_version(getch());
	break;
	case 'B':
	fill(20);
	set_parameters();
	empty_reply();
	break;
	case 'E': // extended parameters - ignore for now
	fill(5);
	empty_reply();
	break;
	case 'P':
	if (!pmode)
	start_pmode();
	empty_reply();
	break;
	case 'U': // set address (word)
	here = getch();
	here += 256 * getch();
	empty_reply();
	break;

	case 0x60: //STK_PROG_FLASH
	getch(); // low addr
	getch(); // high addr
	empty_reply();
	break;
	case 0x61: //STK_PROG_DATA
	getch(); // data
	empty_reply();
	break;

	case 0x64: //STK_PROG_PAGE
	program_page();
	break;

	case 0x74: //STK_READ_PAGE 't'
	read_page();
	break;

	case 'V': //0x56
	universal();
	break;
	case 'Q': //0x51
	error = 0;
	end_pmode();
	empty_reply();
	break;

	case 0x75: //STK_READ_SIGN 'u'
	read_signature();
	break;

	// expecting a command, not CRC_EOP
	// this is how we can get back in sync
	case CRC_EOP:
	error++;
	SERIAL.print((char) STK_NOSYNC);
	break;

	// anything else we will return STK_UNKNOWN
	default:
	error++;
	if (CRC_EOP == getch())
	SERIAL.print((char)STK_UNKNOWN);
	else
	SERIAL.print((char)STK_NOSYNC);
	}
	}