aiie/apple/diskii.cpp

#include "diskii.h"

#ifdef TEENSYDUINO
#include <Arduino.h>
#else
#include <unistd.h>
#include <fcntl.h>
#include <stdlib.h>
#include <string.h>
#include <time.h>
#endif

#include "applemmu.h" // for FLOATING

#include "globals.h"

#include "diskii-rom.h"

DiskII::DiskII(AppleMMU *mmu)
{
  this->trackBuffer = new RingBuffer(NIBTRACKSIZE);
  this->rawTrackBuffer = (uint8_t *)malloc(4096);

  this->mmu = mmu;

  curTrack = 0;
  trackDirty = false;

  writeMode = false;
  writeProt = false; // FIXME: expose an interface to this
  writeLatch = 0x00;

  disk[0] = disk[1] = -1;
  indicatorIsOn[0] = indicatorIsOn[1] = 0;
  selectedDisk = 0;
  diskType[0] = diskType[1] = dosDisk;
}

DiskII::~DiskII()
{
  delete this->trackBuffer; this->trackBuffer = NULL;
  free(this->rawTrackBuffer); this->rawTrackBuffer = NULL;
}

void DiskII::Reset()
{
  curTrack = 0;
  trackDirty = false;

  writeMode = false;
  writeProt = false; // FIXME: expose an interface to this
  writeLatch = 0x00;

  ejectDisk(0);
  ejectDisk(1);
}

uint8_t DiskII::readSwitches(uint8_t s)
{
  switch (s) {
  case 0x00: // change stepper motor phase
  case 0x01:
  case 0x02:
  case 0x03:
  case 0x04:
  case 0x05:
  case 0x06:
  case 0x07:
    step(s);
    break;

  case 0x08: // drive off
    indicatorIsOn[selectedDisk] = 99;
    g_display->drawDriveStatus(selectedDisk, false);
    flushTrack();
    break;
  case 0x09: // drive on
    indicatorIsOn[selectedDisk] = 100;
    g_display->drawDriveStatus(selectedDisk, true);
    break;

  case 0x0A: // select drive 1
    select(0);
    break;
  case 0x0B: // select drive 2
    select(1);
    break;

  case 0x0C: // shift one read or write byte
    writeLatch = readOrWriteByte();
    break;

  case 0x0D: // load data register (latch)
    // This is complex and incomplete. cf. Logic State Sequencer, 
    // UTA2E, p. 9-14
    if (!writeMode && indicatorIsOn[selectedDisk]) {
      if (isWriteProtected())
	writeLatch |= 0x80;
      else
	writeLatch &= 0x7F;
    }
    break;

  case 0x0E: // set read mode
    setWriteMode(false);
    
    // FIXME: with this shortcut here, disk access speeds up ridiculously.
    // Is this breaking anything?
    return ( (readOrWriteByte() & 0x7F) |
             (isWriteProtected() ? 0x80 : 0x00) );

    break;
  case 0x0F: // set write mode
    setWriteMode(true);
    break;
  }

  // FIXME: improve the spin-down here. We need a CPU cycle callback
  // for some period of time instead of this silly decrement counter.
  if (!indicatorIsOn[selectedDisk]) {
    //    printf("Unexpected read while disk isn't on?\n");
    indicatorIsOn[selectedDisk] = 100;
    g_display->drawDriveStatus(selectedDisk, true);
  }
  if (indicatorIsOn[selectedDisk] > 0 && indicatorIsOn[selectedDisk] < 100) {
    indicatorIsOn[selectedDisk]--;
    // slowly spin it down...
  }

  // Any even address read returns the writeLatch (UTA2E Table 9.1,
  // p. 9-12, note 2)
  return (s & 1) ? FLOATING : writeLatch;
}

void DiskII::writeSwitches(uint8_t s, uint8_t v)
{
  switch (s) {
  case 0x00: // change stepper motor phase
  case 0x01:
  case 0x02:
  case 0x03:
  case 0x04:
  case 0x05:
  case 0x06:
  case 0x07:
    step(s);
    break;

  case 0x08: // drive off
    break;
  case 0x09: // drive on
    break;

  case 0x0A: // select drive 1
    select(0);
    break;
  case 0x0B: // select drive 2
    select(1);
    break;

  case 0x0C: // shift one read or write byte
    readOrWriteByte();
    break;

  case 0x0D: // drive write
    break;

  case 0x0E: // set read mode
    setWriteMode(false);
    break;

  case 0x0F: // set write mode
    setWriteMode(true);
    break;
  }

  // All writes update the latch
  if (writeMode) {
    writeLatch = v;
  }
}

// where phase is the address poked & 0x07 (e.g. "0xC0E0 & 0x07")
void DiskII::step(uint8_t phase)
{
  static int mag[4] = { 0,0,0,0 };
  static int pmag[4] = { 0, 0, 0, 0 }; 
  static int ppmag[4] = { 0, 0, 0, 0 };
  static int pnum = 0;
  static int ppnum = 0;
  static int trackPos = 0;
  static int prevTrack = 0;

  //  phase &= 7;
  int magnet_number = phase >> 1;

  // shuffle data down
  ppmag[ppnum] = pmag[ppnum];
  ppnum = pnum;
  pmag[pnum] = mag[pnum];
  pnum = magnet_number;

  if ((phase & 1) == 0) {
    mag[magnet_number] = 0;
  } else {
    if (ppmag[(magnet_number + 1) & 3]) {
      if (--trackPos < 0) {
	trackPos = 0;
	// recalibrate...
      }
    }

    if (ppmag[(magnet_number - 1) & 3]) {
      // FIXME: don't go beyond the end of the media. For a 35-track disk, that's 68 == ((35-1) * 2).
      if (++trackPos > 68) {
	trackPos = 68;
      }
    }
    mag[magnet_number] = 1;
  }

  curTrack = (trackPos + 1) / 2;
  if (curTrack != prevTrack) {
    // We're about to change tracks - be sure to flush the track if we've written to it
    if (trackDirty) {
      flushTrack();
    }
    // step to the appropriate track
    trackDirty = false;
    prevTrack = curTrack;
    trackBuffer->clear();
  }
}

bool DiskII::isWriteProtected()
{
  return (writeProt ? 0xFF : 0x00);
}

void DiskII::setWriteMode(bool enable)
{
  writeMode = enable;
}

static uint8_t _lc(char c)
{
  if (c >= 'A' && c <= 'Z') {
    c = c - 'A' + 'a';
  }
  return c;
}

static bool _endsWithI(const char *s1, const char *s2)
{
  if (strlen(s2) > strlen(s1)) {
    return false;
  }
  
  const char *p = &s1[strlen(s1)-1];
  int16_t l = strlen(s2)-1;
  while (l >= 0) {
    if (_lc(*p--) != _lc(s2[l]))
      return false;
    l--;
  }
  return true;
}

void DiskII::insertDisk(int8_t driveNum, const char *filename, bool drawIt)
{
  ejectDisk(driveNum);
  disk[driveNum] = g_filemanager->openFile(filename);
  if (drawIt)
    g_display->drawDriveDoor(driveNum, false);

  if (_endsWithI(filename, ".nib")) {
    diskType[driveNum] = nibDisk;
  } else if (_endsWithI(filename, ".po")) {
    diskType[driveNum] = prodosDisk;
  } else {
    diskType[driveNum] = dosDisk;
#ifndef TEENSYDUINO
    // debugging: make a nib copy of the image to play with
    //    convertDskToNib("/tmp/debug.nib");
#endif
  }
}

void DiskII::ejectDisk(int8_t driveNum)
{
  if (disk[driveNum] != -1) {
    g_filemanager->closeFile(disk[driveNum]);
    disk[driveNum] = -1;
    g_display->drawDriveDoor(driveNum, true);
  }
}

void DiskII::select(int8_t which)
{
  if (which != 0 && which != 1)
    return;

  if (which != selectedDisk) {
    indicatorIsOn[selectedDisk] = 0;
    g_display->drawDriveStatus(selectedDisk, false);

    flushTrack(); // in case it's dirty: flush before changing drives
    trackBuffer->clear();
  }

  // set the selected disk drive
  selectedDisk = which;
}

uint8_t DiskII::readOrWriteByte()
{
  if (disk[selectedDisk] == -1) {
    //    printf("NO DISK\n");
    return GAP;
  }

  if (writeMode && !writeProt) {

    if (!trackBuffer->hasData()) {
      // printf("some sort of error happened - trying to write to uninitialized track?\n");
      return 0;
    }

    trackDirty = true;
    // It's possible that a badly behaving OS could try to write more
    // data than we have buffer to handle. Don't let it. We should
    // only need something like 500 bytes, at worst. In the typical
    // case, we're talking about something like
    //
    // ~5 bytes of GAP
    // 3 bytes of sector prolog
    // 2 bytes of volume
    // 2 bytes of track
    // 2 bytes of sector
    // 2 bytes of checksum
    // 2 bytes of epilog
    // ~5 bytes of GAP
    // 3 bytes of data prolog
    // 342 bytes of GRP-encoded (6:2) data
    // 1 byte of checksum
    // 3 bytes of epilog
    // 1 byte of GAP
    // == 373 bytes
    //
    // ... so if we get up to the full 1024 we've allocated, there's
    // something suspicious happening.

    if (writeLatch < 0x96) {
      // Can't write a de-nibblized byte...
      g_display->debugMsg("DII: bad write");
      return 0;
    }

    trackBuffer->replaceByte(writeLatch);

    return 0;
  }

  // If we're being asked to read a byte from the current track,
  // that's okay - even if it's dirty. As long as we don't change
  // tracks.

  if (!trackBuffer->hasData()) {
    trackDirty = false;
    trackBuffer->clear();

    if (diskType[selectedDisk] == nibDisk) {
      // Read one nibblized sector at a time and jam it in trackBuf
      // directly.  We don't read the whole track at once only because
      // of RAM constraints on the Teensy. There's no reason we
      // couldn't, though, if RAM weren't at a premium.

      for (int i=0; i<16; i++) {
	g_filemanager->seekBlock(disk[selectedDisk], curTrack * 16 + i, diskType[selectedDisk] == nibDisk);
	if (!g_filemanager->readBlock(disk[selectedDisk], rawTrackBuffer, diskType[selectedDisk] == nibDisk)) {
	  // FIXME: error handling?
	  return 0;
	}
	trackBuffer->addBytes(rawTrackBuffer, 416);
      }
    } else {
      // It's a .dsk / .po disk image. Read the whole track in to rawTrackBuffer and nibblize it.
	g_filemanager->seekBlock(disk[selectedDisk], curTrack * 16, diskType[selectedDisk] == nibDisk);
	if (!g_filemanager->readTrack(disk[selectedDisk], rawTrackBuffer, diskType[selectedDisk] == nibDisk)) {
	  // FIXME: error handling?
	  return 0;
	}

	nibblizeTrack(trackBuffer, rawTrackBuffer, diskType[selectedDisk], curTrack);
    }

    trackBuffer->setPeekCursor(0);
  }

  return trackBuffer->peekNext();
}

const char *DiskII::DiskName(int8_t num)
{
  if (disk[num] != -1)
    return g_filemanager->fileName(disk[num]);

  return "";
}

void DiskII::loadROM(uint8_t *toWhere)
{
#ifdef TEENSYDUINO
  Serial.println("loading slot rom");
  for (uint16_t i=0; i<=0xFF; i++) {
    toWhere[i] = pgm_read_byte(&romData[i]);
  }
#else
  printf("loading slot rom\n");
  memcpy(toWhere, romData, 256);
#endif
}

void DiskII::flushTrack()
{
  if (!trackDirty) {
    return;
  }

  // safety check: if we're write-protected, then how did we get here?
  if (writeProt) {
    g_display->debugMsg("Write Protected");
    return;
  }

  if (!trackBuffer->hasData()) {
    // Dunno what happened - we're writing but haven't initialized the sector buffer?
    return;
  }

  if (diskType[selectedDisk] == nibDisk) {
    // Write the whole track out exactly as we've got it. Hopefully
    // someone has re-calcuated appropriate checksums on it...
    g_display->debugMsg("Not writing Nib image");
    return;
  }

  nibErr e = denibblizeTrack(trackBuffer, rawTrackBuffer, diskType[selectedDisk], curTrack);
  switch (e) {
  case errorShortTrack:
    g_display->debugMsg("DII: short track");
    trackBuffer->clear();
    return;

  case errorMissingSectors:
    g_display->debugMsg("DII: missing sectors");
    trackBuffer->clear();
    break;

  case errorNone:
    break;
  }

  // ok, write the track!
  g_filemanager->seekBlock(disk[selectedDisk], curTrack * 16);
  g_filemanager->writeTrack(disk[selectedDisk], rawTrackBuffer);

  trackDirty = false;
}
general VM structure and a test OpenCV target 2017-02-19 23:55:54 +00:00			`#include "diskii.h"`

			`#ifdef TEENSYDUINO`
			`#include <Arduino.h>`
			`#else`
			`#include <unistd.h>`
			`#include <fcntl.h>`
			`#include <stdlib.h>`
			`#include <string.h>`
			`#include <time.h>`
			`#endif`

			`#include "applemmu.h" // for FLOATING`

			`#include "globals.h"`

			`#include "diskii-rom.h"`

			`DiskII::DiskII(AppleMMU *mmu)`
			`{`
			`this->trackBuffer = new RingBuffer(NIBTRACKSIZE);`
			`this->rawTrackBuffer = (uint8_t *)malloc(4096);`

			`this->mmu = mmu;`

			`curTrack = 0;`
			`trackDirty = false;`

			`writeMode = false;`
			`writeProt = false; // FIXME: expose an interface to this`
			`writeLatch = 0x00;`

			`disk[0] = disk[1] = -1;`
			`indicatorIsOn[0] = indicatorIsOn[1] = 0;`
			`selectedDisk = 0;`
			`diskType[0] = diskType[1] = dosDisk;`
			`}`

			`DiskII::~DiskII()`
			`{`
			`delete this->trackBuffer; this->trackBuffer = NULL;`
			`free(this->rawTrackBuffer); this->rawTrackBuffer = NULL;`
			`}`

			`void DiskII::Reset()`
			`{`
			`curTrack = 0;`
			`trackDirty = false;`

			`writeMode = false;`
			`writeProt = false; // FIXME: expose an interface to this`
			`writeLatch = 0x00;`

			`ejectDisk(0);`
			`ejectDisk(1);`
			`}`

			`uint8_t DiskII::readSwitches(uint8_t s)`
			`{`
			`switch (s) {`
			`case 0x00: // change stepper motor phase`
			`case 0x01:`
			`case 0x02:`
			`case 0x03:`
			`case 0x04:`
			`case 0x05:`
			`case 0x06:`
			`case 0x07:`
			`step(s);`
			`break;`

			`case 0x08: // drive off`
			`indicatorIsOn[selectedDisk] = 99;`
			`g_display->drawDriveStatus(selectedDisk, false);`
			`flushTrack();`
			`break;`
			`case 0x09: // drive on`
			`indicatorIsOn[selectedDisk] = 100;`
			`g_display->drawDriveStatus(selectedDisk, true);`
			`break;`

			`case 0x0A: // select drive 1`
			`select(0);`
			`break;`
			`case 0x0B: // select drive 2`
			`select(1);`
			`break;`

			`case 0x0C: // shift one read or write byte`
			`writeLatch = readOrWriteByte();`
			`break;`

			`case 0x0D: // load data register (latch)`
			`// This is complex and incomplete. cf. Logic State Sequencer,`
			`// UTA2E, p. 9-14`
			`if (!writeMode && indicatorIsOn[selectedDisk]) {`
			`if (isWriteProtected())`
			`writeLatch \|= 0x80;`
			`else`
			`writeLatch &= 0x7F;`
			`}`
			`break;`

			`case 0x0E: // set read mode`
			`setWriteMode(false);`

			`// FIXME: with this shortcut here, disk access speeds up ridiculously.`
			`// Is this breaking anything?`
			`return ( (readOrWriteByte() & 0x7F) \|`
			`(isWriteProtected() ? 0x80 : 0x00) );`

			`break;`
			`case 0x0F: // set write mode`
			`setWriteMode(true);`
			`break;`
			`}`

			`// FIXME: improve the spin-down here. We need a CPU cycle callback`
			`// for some period of time instead of this silly decrement counter.`
			`if (!indicatorIsOn[selectedDisk]) {`
			`// printf("Unexpected read while disk isn't on?\n");`
			`indicatorIsOn[selectedDisk] = 100;`
			`g_display->drawDriveStatus(selectedDisk, true);`
			`}`
			`if (indicatorIsOn[selectedDisk] > 0 && indicatorIsOn[selectedDisk] < 100) {`
			`indicatorIsOn[selectedDisk]--;`
			`// slowly spin it down...`
			`}`

			`// Any even address read returns the writeLatch (UTA2E Table 9.1,`
			`// p. 9-12, note 2)`
			`return (s & 1) ? FLOATING : writeLatch;`
			`}`

			`void DiskII::writeSwitches(uint8_t s, uint8_t v)`
			`{`
			`switch (s) {`
			`case 0x00: // change stepper motor phase`
			`case 0x01:`
			`case 0x02:`
			`case 0x03:`
			`case 0x04:`
			`case 0x05:`
			`case 0x06:`
			`case 0x07:`
			`step(s);`
			`break;`

			`case 0x08: // drive off`
			`break;`
			`case 0x09: // drive on`
			`break;`

			`case 0x0A: // select drive 1`
			`select(0);`
			`break;`
			`case 0x0B: // select drive 2`
			`select(1);`
			`break;`

			`case 0x0C: // shift one read or write byte`
			`readOrWriteByte();`
			`break;`

			`case 0x0D: // drive write`
			`break;`

			`case 0x0E: // set read mode`
			`setWriteMode(false);`
			`break;`

			`case 0x0F: // set write mode`
			`setWriteMode(true);`
			`break;`
			`}`

			`// All writes update the latch`
			`if (writeMode) {`
			`writeLatch = v;`
			`}`
			`}`

			`// where phase is the address poked & 0x07 (e.g. "0xC0E0 & 0x07")`
			`void DiskII::step(uint8_t phase)`
			`{`
			`static int mag[4] = { 0,0,0,0 };`
			`static int pmag[4] = { 0, 0, 0, 0 };`
			`static int ppmag[4] = { 0, 0, 0, 0 };`
			`static int pnum = 0;`
			`static int ppnum = 0;`
			`static int trackPos = 0;`
			`static int prevTrack = 0;`

			`// phase &= 7;`
			`int magnet_number = phase >> 1;`

			`// shuffle data down`
			`ppmag[ppnum] = pmag[ppnum];`
			`ppnum = pnum;`
			`pmag[pnum] = mag[pnum];`
			`pnum = magnet_number;`

			`if ((phase & 1) == 0) {`
			`mag[magnet_number] = 0;`
			`} else {`
			`if (ppmag[(magnet_number + 1) & 3]) {`
			`if (--trackPos < 0) {`
			`trackPos = 0;`
			`// recalibrate...`
			`}`
			`}`

			`if (ppmag[(magnet_number - 1) & 3]) {`
			`// FIXME: don't go beyond the end of the media. For a 35-track disk, that's 68 == ((35-1) * 2).`
			`if (++trackPos > 68) {`
			`trackPos = 68;`
			`}`
			`}`
			`mag[magnet_number] = 1;`
			`}`

			`curTrack = (trackPos + 1) / 2;`
			`if (curTrack != prevTrack) {`
			`// We're about to change tracks - be sure to flush the track if we've written to it`
			`if (trackDirty) {`
			`flushTrack();`
			`}`
			`// step to the appropriate track`
			`trackDirty = false;`
			`prevTrack = curTrack;`
			`trackBuffer->clear();`
			`}`
			`}`

			`bool DiskII::isWriteProtected()`
			`{`
			`return (writeProt ? 0xFF : 0x00);`
			`}`

			`void DiskII::setWriteMode(bool enable)`
			`{`
			`writeMode = enable;`
			`}`

			`static uint8_t _lc(char c)`
			`{`
			`if (c >= 'A' && c <= 'Z') {`
			`c = c - 'A' + 'a';`
			`}`
			`return c;`
			`}`

			`static bool _endsWithI(const char s1, const char s2)`
			`{`
			`if (strlen(s2) > strlen(s1)) {`
			`return false;`
			`}`

			`const char *p = &s1[strlen(s1)-1];`
			`int16_t l = strlen(s2)-1;`
			`while (l >= 0) {`
			`if (_lc(*p--) != _lc(s2[l]))`
			`return false;`
			`l--;`
			`}`
			`return true;`
			`}`

			`void DiskII::insertDisk(int8_t driveNum, const char *filename, bool drawIt)`
			`{`
			`ejectDisk(driveNum);`
			`disk[driveNum] = g_filemanager->openFile(filename);`
			`if (drawIt)`
			`g_display->drawDriveDoor(driveNum, false);`

			`if (_endsWithI(filename, ".nib")) {`
			`diskType[driveNum] = nibDisk;`
			`} else if (_endsWithI(filename, ".po")) {`
			`diskType[driveNum] = prodosDisk;`
			`} else {`
			`diskType[driveNum] = dosDisk;`
			`#ifndef TEENSYDUINO`
			`// debugging: make a nib copy of the image to play with`
			`// convertDskToNib("/tmp/debug.nib");`
			`#endif`
			`}`
			`}`

			`void DiskII::ejectDisk(int8_t driveNum)`
			`{`
			`if (disk[driveNum] != -1) {`
			`g_filemanager->closeFile(disk[driveNum]);`
			`disk[driveNum] = -1;`
			`g_display->drawDriveDoor(driveNum, true);`
			`}`
			`}`

			`void DiskII::select(int8_t which)`
			`{`
			`if (which != 0 && which != 1)`
			`return;`

			`if (which != selectedDisk) {`
			`indicatorIsOn[selectedDisk] = 0;`
			`g_display->drawDriveStatus(selectedDisk, false);`

			`flushTrack(); // in case it's dirty: flush before changing drives`
			`trackBuffer->clear();`
			`}`

			`// set the selected disk drive`
			`selectedDisk = which;`
			`}`

			`uint8_t DiskII::readOrWriteByte()`
			`{`
			`if (disk[selectedDisk] == -1) {`
			`// printf("NO DISK\n");`
			`return GAP;`
			`}`

			`if (writeMode && !writeProt) {`

			`if (!trackBuffer->hasData()) {`
			`// printf("some sort of error happened - trying to write to uninitialized track?\n");`
			`return 0;`
			`}`

			`trackDirty = true;`
			`// It's possible that a badly behaving OS could try to write more`
			`// data than we have buffer to handle. Don't let it. We should`
			`// only need something like 500 bytes, at worst. In the typical`
			`// case, we're talking about something like`
			`//`
			`// ~5 bytes of GAP`
			`// 3 bytes of sector prolog`
			`// 2 bytes of volume`
			`// 2 bytes of track`
			`// 2 bytes of sector`
			`// 2 bytes of checksum`
			`// 2 bytes of epilog`
			`// ~5 bytes of GAP`
			`// 3 bytes of data prolog`
			`// 342 bytes of GRP-encoded (6:2) data`
			`// 1 byte of checksum`
			`// 3 bytes of epilog`
			`// 1 byte of GAP`
			`// == 373 bytes`
			`//`
			`// ... so if we get up to the full 1024 we've allocated, there's`
			`// something suspicious happening.`

			`if (writeLatch < 0x96) {`
			`// Can't write a de-nibblized byte...`
			`g_display->debugMsg("DII: bad write");`
			`return 0;`
			`}`

			`trackBuffer->replaceByte(writeLatch);`

			`return 0;`
			`}`

			`// If we're being asked to read a byte from the current track,`
			`// that's okay - even if it's dirty. As long as we don't change`
			`// tracks.`

			`if (!trackBuffer->hasData()) {`
			`trackDirty = false;`
			`trackBuffer->clear();`

			`if (diskType[selectedDisk] == nibDisk) {`
			`// Read one nibblized sector at a time and jam it in trackBuf`
			`// directly. We don't read the whole track at once only because`
			`// of RAM constraints on the Teensy. There's no reason we`
			`// couldn't, though, if RAM weren't at a premium.`

			`for (int i=0; i<16; i++) {`
			`g_filemanager->seekBlock(disk[selectedDisk], curTrack * 16 + i, diskType[selectedDisk] == nibDisk);`
			`if (!g_filemanager->readBlock(disk[selectedDisk], rawTrackBuffer, diskType[selectedDisk] == nibDisk)) {`
			`// FIXME: error handling?`
			`return 0;`
			`}`
			`trackBuffer->addBytes(rawTrackBuffer, 416);`
			`}`
			`} else {`
			`// It's a .dsk / .po disk image. Read the whole track in to rawTrackBuffer and nibblize it.`
			`g_filemanager->seekBlock(disk[selectedDisk], curTrack * 16, diskType[selectedDisk] == nibDisk);`
			`if (!g_filemanager->readTrack(disk[selectedDisk], rawTrackBuffer, diskType[selectedDisk] == nibDisk)) {`
			`// FIXME: error handling?`
			`return 0;`
			`}`

			`nibblizeTrack(trackBuffer, rawTrackBuffer, diskType[selectedDisk], curTrack);`
			`}`

			`trackBuffer->setPeekCursor(0);`
			`}`

			`return trackBuffer->peekNext();`
			`}`

			`const char *DiskII::DiskName(int8_t num)`
			`{`
			`if (disk[num] != -1)`
			`return g_filemanager->fileName(disk[num]);`

			`return "";`
			`}`

			`void DiskII::loadROM(uint8_t *toWhere)`
			`{`
			`#ifdef TEENSYDUINO`
			`Serial.println("loading slot rom");`
			`for (uint16_t i=0; i<=0xFF; i++) {`
			`toWhere[i] = pgm_read_byte(&romData[i]);`
			`}`
			`#else`
			`printf("loading slot rom\n");`
			`memcpy(toWhere, romData, 256);`
			`#endif`
			`}`

			`void DiskII::flushTrack()`
			`{`
			`if (!trackDirty) {`
			`return;`
			`}`

			`// safety check: if we're write-protected, then how did we get here?`
			`if (writeProt) {`
			`g_display->debugMsg("Write Protected");`
			`return;`
			`}`

			`if (!trackBuffer->hasData()) {`
			`// Dunno what happened - we're writing but haven't initialized the sector buffer?`
			`return;`
			`}`

			`if (diskType[selectedDisk] == nibDisk) {`
			`// Write the whole track out exactly as we've got it. Hopefully`
			`// someone has re-calcuated appropriate checksums on it...`
			`g_display->debugMsg("Not writing Nib image");`
			`return;`
			`}`

			`nibErr e = denibblizeTrack(trackBuffer, rawTrackBuffer, diskType[selectedDisk], curTrack);`
			`switch (e) {`
			`case errorShortTrack:`
			`g_display->debugMsg("DII: short track");`
			`trackBuffer->clear();`
			`return;`

			`case errorMissingSectors:`
			`g_display->debugMsg("DII: missing sectors");`
			`trackBuffer->clear();`
			`break;`

			`case errorNone:`
			`break;`
			`}`

			`// ok, write the track!`
			`g_filemanager->seekBlock(disk[selectedDisk], curTrack * 16);`
			`g_filemanager->writeTrack(disk[selectedDisk], rawTrackBuffer);`

			`trackDirty = false;`
			`}`