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USBcontrol.ino
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USBcontrol.ino
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// USB interface for APC based pinball machines
const byte USB_CommandLength[110] = {0,0,0,0,0,0,0,1,0,0, // Length of USB commands from 0 - 9
1,1,1,0,0,0,0,0,0,0, // Length of USB commands from 10 - 19
1,1,1,1,2,2,0,0,0,0, // Length of USB commands from 20 - 29
250,250,250,250,250,0,0,2,0,0, // Length of USB commands from 30 - 39
1,0,0,0,0,0,0,0,0,0, // Length of USB commands from 40 - 49
2,1,251,0,2,0,0,0,0,0, // Length of USB commands from 50 - 59
10,0,0,0,2,3,0,0,0,0, // Length of USB commands from 60 - 69
0,0,0,0,0,0,0,0,0,0, // Length of USB commands from 70 - 79
2,1,2,0,0,0,0,0,0,0, // Length of USB commands from 80 - 89
0,0,0,0,0,0,0,0,0,0, // Length of USB commands from 90 - 99
0,0,0,0,0,0,0,0,0,0}; // Length of USB commands from 100 - 109
const byte USB_DisplayDigitNum[9][6] = {{4,7,7,7,7,0},{4,7,7,7,7,0},{0,7,7,7,7,0},{0,16,16,0,0,0},{0,16,16,0,0,0},{0,16,16,7,0,0},{0,16,16,7,4,0},{4,6,6,6,6,0},{4,7,7,7,7,0}};
const byte USB_DisplayTypes[9][6] = {{3,4,4,4,4,0},{3,4,4,3,3,0},{0,4,4,3,3,0},{0,4,4,0,0,0},{0,4,4,0,0,0},{0,4,3,3,0,0},{0,4,3,3,3,0},{1,1,1,1,1,0},{1,2,2,2,2,0}};
// offsets of settings in the settings array
#define USB_Watchdog 0 // watchdog enable setting
#define USB_Debug 1 // USB debug mode
#define USB_PinMameSound 2 // use APC sound HW or old sound board?
#define USB_PinMameGame 3 // number of the game to be run in PinMame
#define USB_LisyDebug 4 // selected debug mode
//#define USB_BallSave 5 // optional ball saver -> this option is defined in PinMameExceptions.ino
//#define USB_BallSaveTime 6 // activation time for the optional ball saver -> this option is defined in PinMameExceptions.ino
//#define USB_BGmusic 7 // to select an own BG music -> this option is defined in PinMameExceptions.ino
const byte USB_defaults[64] = {0,0,0,255,0,0,20,0, // game default settings
0,0,0,0,0,0,0,0,
0,0,0,0,0,0,0,0,
0,0,0,0,0,0,0,0,
0,0,0,0,0,0,0,0,
0,0,0,0,0,0,0,0,
0,0,0,0,0,0,0,0,
0,0,0,0,0,0,0,0};
byte USB_ChangedSwitches[64];
byte USB_HWrule_ActSw[16][3]; // hardware rules for activated switches
byte USB_HWrule_RelSw[16][3]; // hardware rules for released switches
byte USB_DisplayProtocol[5]; // stores the selected display protocol
char USB_RepeatMusic[13]; // name of the music file to be repeated
byte USB_WaitingSoundFiles[2][14]; // names of the waiting sound files first byte is for channel and commands
byte USB_WaitSoundTimer; // number of the timer for the sound sequencing
byte USB_Enter_TestmodeTimer; // number of the timer to determine whether the Advance button has been held down
unsigned int USB_SolTimes[32] = {0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0}; // Activation times for solenoids
const char TxTUSB_debug[3][17] = {{" OFF "},{" USB "},{" AUDIO "}};
const char TxTUSB_PinMameSound[2][17] = {{" APC "},{" BOARD "}};
const char TXTUSB_BallSave[5][17] = {{" OFF "},{" ON "},{" LEFT OUTLANE "},{" BOTH OUTLANE "},{" GENERAL "}};
const char TxtUSB_Music[2][17] = {{"PINMAMEDEFAULT "},{" MUSICSND "}};
const struct SettingTopic USB_setList[67] = {{"USB WATCHDOG ",HandleBoolSetting,0,0,0}, // defines the game specific settings
{" DEBUG MODE ",HandleTextSetting,&TxTUSB_debug[0][0],0,2},
{"PINMAME SOUND ",HandleTextSetting,&TxTUSB_PinMameSound[0][0],0,1},
{"PINMAME GAME ",HandleNumSetting,0,0,72},
{" LISY DEBUG ",HandleNumSetting,0,1,31},
{" BALL SAVER ",HandleTextSetting,&TXTUSB_BallSave[0][0],0,1},
{"B SAVER TIME ",HandleNumSetting,0,5,250},
{" BG MUSIC ",HandleTextSetting,&TxtUSB_Music[0][0],0,1},
{"SETTING UNUSED ",HandleBoolSetting,0,0,0},
{"SETTING UNUSED ",HandleBoolSetting,0,0,0},
{"SETTING UNUSED ",HandleBoolSetting,0,0,0},
{"SETTING UNUSED ",HandleBoolSetting,0,0,0},
{"SETTING UNUSED ",HandleBoolSetting,0,0,0},
{"SETTING UNUSED ",HandleBoolSetting,0,0,0},
{"SETTING UNUSED ",HandleBoolSetting,0,0,0},
{"SETTING UNUSED ",HandleBoolSetting,0,0,0},
{"SETTING UNUSED ",HandleBoolSetting,0,0,0},
{"SETTING UNUSED ",HandleBoolSetting,0,0,0},
{"SETTING UNUSED ",HandleBoolSetting,0,0,0},
{"SETTING UNUSED ",HandleBoolSetting,0,0,0},
{"SETTING UNUSED ",HandleBoolSetting,0,0,0},
{"SETTING UNUSED ",HandleBoolSetting,0,0,0},
{"SETTING UNUSED ",HandleBoolSetting,0,0,0},
{"SETTING UNUSED ",HandleBoolSetting,0,0,0},
{"SETTING UNUSED ",HandleBoolSetting,0,0,0},
{"SETTING UNUSED ",HandleBoolSetting,0,0,0},
{"SETTING UNUSED ",HandleBoolSetting,0,0,0},
{"SETTING UNUSED ",HandleBoolSetting,0,0,0},
{"SETTING UNUSED ",HandleBoolSetting,0,0,0},
{"SETTING UNUSED ",HandleBoolSetting,0,0,0},
{"SETTING UNUSED ",HandleBoolSetting,0,0,0},
{"SETTING UNUSED ",HandleBoolSetting,0,0,0},
{"SETTING UNUSED ",HandleBoolSetting,0,0,0},
{"SETTING UNUSED ",HandleBoolSetting,0,0,0},
{"SETTING UNUSED ",HandleBoolSetting,0,0,0},
{"SETTING UNUSED ",HandleBoolSetting,0,0,0},
{"SETTING UNUSED ",HandleBoolSetting,0,0,0},
{"SETTING UNUSED ",HandleBoolSetting,0,0,0},
{"SETTING UNUSED ",HandleBoolSetting,0,0,0},
{"SETTING UNUSED ",HandleBoolSetting,0,0,0},
{"SETTING UNUSED ",HandleBoolSetting,0,0,0},
{"SETTING UNUSED ",HandleBoolSetting,0,0,0},
{"SETTING UNUSED ",HandleBoolSetting,0,0,0},
{"SETTING UNUSED ",HandleBoolSetting,0,0,0},
{"SETTING UNUSED ",HandleBoolSetting,0,0,0},
{"SETTING UNUSED ",HandleBoolSetting,0,0,0},
{"SYSTEM3 SET 1 ",HandleNumSetting,0,0,72},
{"SYSTEM3 SET 2 ",HandleNumSetting,0,0,72},
{"SYSTEM3 SET 3 ",HandleNumSetting,0,0,72},
{"SYSTEM3 SET 4 ",HandleNumSetting,0,0,72},
{"SYSTEM3 SET 5 ",HandleNumSetting,0,0,72},
{"SYSTEM3 SET 6 ",HandleNumSetting,0,0,72},
{"SYSTEM3 SET 7 ",HandleNumSetting,0,0,72},
{"SYSTEM3 SET 8 ",HandleNumSetting,0,0,72},
{"SYSTEM3 SET 9 ",HandleNumSetting,0,0,72},
{"SYSTEM3 SET 10 ",HandleNumSetting,0,0,72},
{"SYSTEM3 SET 11 ",HandleNumSetting,0,0,72},
{"SYSTEM3 SET 12 ",HandleNumSetting,0,0,72},
{"SYSTEM3 SET 13 ",HandleNumSetting,0,0,72},
{"SYSTEM3 SET 14 ",HandleNumSetting,0,0,72},
{"SYSTEM3 SET 15 ",HandleNumSetting,0,0,72},
{"SYSTEM3 SET 16 ",HandleNumSetting,0,0,72},
{"SYSTEM3 SET 17 ",HandleNumSetting,0,0,72},
{"SYSTEM3 SET 18 ",HandleNumSetting,0,0,72},
{"RESTOREDEFAULT",RestoreDefaults,0,0,0},
{" EXIT SETTNGS",ExitSettings,0,0,0},
{"",NULL,0,0,0}};
struct GameDef USB_GameDefinition = {
USB_setList, // GameSettingsList
(byte*)USB_defaults, // GameDefaultsPointer
"USB_SET.BIN", // GameSettingsFileName
"USBSCORE.BIN", // HighScoresFileName
USB_AttractMode, // AttractMode
USB_SolTimes}; // Default activation times of solenoids
void USB_init() {
Switch_Pressed = DummyProcess;
GameDefinition = USB_GameDefinition; // read the game specific settings and highscores
if (APC_settings[ConnType]) {
if (APC_settings[ConnType] == 1) {
OnBoardCom = false;}
else {
Serial.begin(115200); // needed for USB and serial communication
return;}}
if (APC_settings[DebugMode]) { // activate serial interface in debug mode
Serial.begin(115200);}}
void USB_AttractMode() { // Attract Mode
DispRow1 = DisplayUpper;
DispRow2 = DisplayLower;
if (APC_settings[Volume]) { // system set to digital volume control?
analogWrite(VolumePin,255-APC_settings[Volume]);} // adjust PWM to volume setting
else {
digitalWrite(VolumePin,HIGH);} // turn off the digital volume control
for (i=0; i<8; i++) { // turn off all lamps
LampColumns[i] = 0;}
LampPattern = LampColumns;
Switch_Pressed = USB_SwitchHandler;
Switch_Released = USB_ReleasedSwitches;
EX_Init(game_settings[USB_PinMameGame]); // set exceptions for selected game
USB_ReleasedSwitches(72); // tell Lisy to start PinMame
for (byte i=0; i<5; i++) {
USB_DisplayProtocol[i] = USB_DisplayTypes[APC_settings[DisplayType]][i];} // use default protocol for displays
if (game_settings[USB_Watchdog]) { // watchdog enabled?
USB_WatchdogHandler(1);} // initiate reset and start watchdog
if (APC_settings[ConnType]) {
if (APC_settings[ConnType] == 1) {
WriteUpper("BOOTING LISY ");}
else {
WriteUpper(" USB CONTROL ");}}
else {
WriteUpper("NO CONNSELECTED ");}
WriteLower(" ");}
void USB_WatchdogHandler(byte Event) { // Arg = 0->Reset WD / 1-> Reset & start WD / 2-> WD has run out / 3-> stop WD
static byte USB_WatchdogTimer;
byte i=0;
if (!Event) { // reset watchdog
USB_WriteByte((byte) 0); // send OK
if (USB_WatchdogTimer) {
KillTimer(USB_WatchdogTimer);} // restart timer
if (game_settings[USB_Watchdog]) { // watchdog enabled?
USB_WatchdogTimer = ActivateTimer(1000, 2, USB_WatchdogHandler);} // start the timer
else { // watchdog disabled?
USB_WatchdogTimer = 0;}} // mark timer as inactive
else {
if (Event == 3) { // stop watchdog
if (USB_WatchdogTimer) {
KillTimer(USB_WatchdogTimer);
USB_WatchdogTimer = 0;}}
else {
if (Event == 1) { // initiate reset and start watchdog
if (USB_WatchdogTimer) {
KillTimer(USB_WatchdogTimer);
USB_WatchdogTimer = 0;}
for (i=0; i<16; i++) { // delete all HW rules
USB_HWrule_ActSw[i][0] = 0;
USB_HWrule_RelSw[i][0] = 0;}
USB_WriteByte((byte) 0);} // send OK
else { // timer has run out
if (!game_settings[USB_Watchdog]) { // watchdog disabled?
USB_WatchdogTimer = 0;
return;} // then leave
WriteUpper2(" USB WATCHDOG ");
WriteLower2(" ");
ShowMessage(3);}
ReleaseAllSolenoids(); // switch off all coils
for (i=0; i<63; i++) { // clear switch buffer
USB_ChangedSwitches[i] = 0;}
for (i=0; i<8; i++) { // turn off all lamps
LampColumns[i] = 0;}
USB_WatchdogTimer = ActivateTimer(1000, 2, USB_WatchdogHandler);}}} // restart watchdog
void USB_SwitchHandler(byte Switch) {
byte i = 0;
if (!PinMameException(SwitchActCommand, Switch)){ // check for machine specific exceptions
switch (Switch) {
case 8: // high score reset
digitalWrite(Blanking, LOW); // invoke the blanking
StopPlayingMusic();
StopPlayingSound();
break;
case 72: // advance button
while (USB_ChangedSwitches[i] && (i<63)) {
i++;}
USB_ChangedSwitches[i] = Switch | 128; // send switch code to USB
if (QuerySwitch(73)) { // Up/Down switch pressed?
USB_Enter_TestmodeTimer = ActivateTimer(1000, 0, USB_Testmode);} // look again in 1s
break;
default:
while (USB_HWrule_ActSw[i][0]) { // check for HW rules for this switch
if (USB_HWrule_ActSw[i][0] == Switch) {
if (USB_HWrule_ActSw[i][2]) { // duration != 0 ?
ActivateSolenoid((byte) USB_HWrule_ActSw[i][2], USB_HWrule_ActSw[i][1]);}
else {
ReleaseSolenoid(USB_HWrule_ActSw[i][1]);}
break;}
i++;}
i = 0; // add switch number to list of changed switches
while (USB_ChangedSwitches[i] && (i<63)) {
i++;}
USB_ChangedSwitches[i] = Switch | 128;}}}
void USB_ReleasedSwitches(byte Switch) {
if (!PinMameException(SwitchRelCommand, Switch)){ // check for machine specific exceptions
switch (Switch) {
case 8: // high score reset
break;
case 72:
if (USB_Enter_TestmodeTimer) {
KillTimer(USB_Enter_TestmodeTimer);
USB_Enter_TestmodeTimer = 0;} // @suppress("No break at end of case")
default:
byte i = 0;
while (USB_HWrule_RelSw[i][0]) { // check for HW rules for this switch
if (USB_HWrule_RelSw[i][0] == Switch) {
if (USB_HWrule_RelSw[i][2]) { // duration != 0 ?
ActivateSolenoid((byte) USB_HWrule_RelSw[i][2], USB_HWrule_RelSw[i][1]);}
else {
ReleaseSolenoid(USB_HWrule_RelSw[i][1]);}
break;}
i++;}
i = 0; // add switch number to list of changed switches
while (USB_ChangedSwitches[i] && (i<63)) {
i++;}
USB_ChangedSwitches[i] = Switch;}}}
void USB_Testmode(byte Dummy) { // enter system settings if advance button still pressed
UNUSED(Dummy);
USB_Enter_TestmodeTimer = 0;
USB_WatchdogHandler(3); // stop USB watchdog
for (byte i=0; i<5; i++) {
USB_DisplayProtocol[i] = 6;} // use ASCII protocol for displays
if (APC_settings[ConnType] == 2) { // USB mode selected?
Serial.end();}
else if ((APC_settings[ConnType] == 1) && OnBoardCom) { // onboard Pi selected and detected?
Serial3.end();}
Settings_Enter();}
byte USB_ReadByte() { // read a byte from the selected interface
if (APC_settings[ConnType] == 1) { // onboard PI selected?
return Serial3.read();}
else { // USB selected
return Serial.read();}}
void USB_WriteByte(byte Data) { // write a byte to the selected interface
if (APC_settings[ConnType] == 1) { // onboard PI selected?
Serial3.write(Data);}
else { // USB selected
Serial.write(Data);}}
byte USB_Available() {
if (APC_settings[ConnType] == 1) { // onboard PI selected?
if (OnBoardCom) { // onboard Pi detected?
return Serial3.available();}
else {
return 0;}}
else { // USB selected
return Serial.available();}}
void USB_SerialCommand() {
static byte Command;
static byte USB_BufferPointer; // pointer for the SerialBuffer
static bool CommandPending;
byte c = 0;
byte i = 0;
if (!CommandPending) { // any unfinished business?
Command = USB_ReadByte();} // if not read new command
if (USB_CommandLength[Command] > 249) { // command doesn't have a constant length
switch (USB_CommandLength[Command]) {
case 250: // argument length is stored in the first byte
if (USB_BufferPointer) { // length byte already stored?
c = USB_SerialBuffer[0];} // read previously stored argument length
else {
if (USB_Available()) { // length byte available?
USB_BufferPointer = 1; // indicated that the length is read
c = USB_ReadByte();} // read argument length
else {
USB_BufferPointer = 0;
CommandPending = true; // command not finished
return;}}
if (USB_Available() >= c) { // enough bytes in the serial buffer?
for (i=0; i<c; i++) { // read the required amount of bytes
USB_SerialBuffer[i] = USB_ReadByte();}}
else { // not enough bytes in the buffer
CommandPending = true; // command not finished
USB_SerialBuffer[0] = c; // store argument length for next round
return;}
break;
case 251:
c = USB_Available();
i = USB_BufferPointer;
if (!USB_BufferPointer) { // first run?
if (c < 3) { // 3 bytes needed at least
CommandPending = true;
return;}
USB_SerialBuffer[0] = USB_ReadByte(); // store track number
i++;
USB_SerialBuffer[1] = USB_ReadByte(); // store options byte
i++;}
do { // receive bytes
USB_SerialBuffer[i] = USB_ReadByte(); // and store them
i++;}
while ((USB_SerialBuffer[i-1]) && ((i - USB_BufferPointer) < c)); // until a 0 is read or serial buffer is empty
if (USB_SerialBuffer[i-1]) { // last byte not zero
CommandPending = true; // command not finished
USB_BufferPointer = i;
return;}
break;
case 255: // argument is terminated by a zero byte
c = USB_Available();
i = USB_BufferPointer;
if (!c) { // no further received bytes
CommandPending = true;
return;}
do { // receive bytes
USB_SerialBuffer[i] = USB_ReadByte(); // and store them
i++;}
while ((USB_SerialBuffer[i-1]) && ((i - USB_BufferPointer) < c)); // until a 0 is read or serial buffer is empty
if (USB_SerialBuffer[i-1]) { // last byte not zero
CommandPending = true; // command not finished
USB_BufferPointer = i;
return;}
break;}}
else { // argument has a specific length
if (USB_Available() >= USB_CommandLength[Command]) { // enough bytes in the serial buffer?
for (i=0; i<USB_CommandLength[Command]; i++) { // read the required amount of bytes
USB_SerialBuffer[i] = USB_ReadByte();}}
else { // not enough bytes in the buffer
CommandPending = true; // command not finished
return;}}
CommandPending = false;
USB_BufferPointer = 0;
if (game_settings[USB_Debug] == 1) {
for (i=1; i<24; i++) { // move all characters in the lower display row 4 chars to the left
DisplayLower[i] = DisplayLower[i+8];}
*(DisplayLower+30) = DispPattern2[32 + 2 * (Command % 10)]; // and insert the command number to the right of the row
*(DisplayLower+31) = DispPattern2[33 + 2 * (Command % 10)];
*(DisplayLower+28) = DispPattern2[32 + 2 * (Command / 10)];
*(DisplayLower+29) = DispPattern2[33 + 2 * (Command / 10)];
*(DisplayLower+26) = DispPattern2[32 + 2 * (Command / 100)];
*(DisplayLower+27) = DispPattern2[33 + 2 * (Command / 100)];}
switch (Command) { // execute command if complete
case 0: // get connected hardware
USB_WriteByte('A');
USB_WriteByte('P');
USB_WriteByte('C');
USB_WriteByte((byte) 0);
break;
case 1: // get firmware version
if (APC_settings[ConnType] == 1) {
Serial3.print(APC_Version);}
else {
Serial.print(APC_Version);}
USB_WriteByte((byte) 0);
break;
case 2: // get API version
USB_WriteByte('0');
USB_WriteByte('.');
USB_WriteByte('1');
USB_WriteByte('0');
USB_WriteByte((byte) 0);
break;
case 3: // get number of lamps
USB_WriteByte((byte) 65);
break;
case 4: // get number of solenoids
USB_WriteByte((byte) 25);
break;
case 6: // get number of displays
switch (APC_settings[DisplayType]) {
case 0: // 4 ALPHA+CREDIT
case 1: // Sys11 Pinbot
case 2: // Sys11 F-14
case 5: // Sys11 Riverboat Gambler
case 7: // Sys3 - 6
case 8: // Sys7 + 9
USB_WriteByte((byte) 5);
break;
case 3: // Sys11 BK2K
case 6: // DE 2x16
USB_WriteByte((byte) 3);
break;
case 4: // Sys11 Taxi
USB_WriteByte((byte) 4);
break;
default: // unknown display type
USB_WriteByte((byte) 0);
break;}
break;
case 7: // Display details
USB_WriteByte((byte) USB_DisplayTypes[APC_settings[DisplayType]][USB_SerialBuffer[0]]);
USB_WriteByte((byte) USB_DisplayDigitNum[APC_settings[DisplayType]][USB_SerialBuffer[0]]);
break;
case 9: // get number of switches
USB_WriteByte((byte) 73);
break;
case 10: // get status of lamp
USB_WriteByte((byte) QueryLamp(USB_SerialBuffer[0]));
break;
case 11: // turn on lamp
if (!PinMameException(LampOnCommand, USB_SerialBuffer[0])){ // check for machine specific exceptions
TurnOnLamp(USB_SerialBuffer[0]);}
break;
case 12: // turn off lamp
if (!PinMameException(LampOffCommand, USB_SerialBuffer[0])){ // check for machine specific exceptions
TurnOffLamp(USB_SerialBuffer[0]);}
break;
case 19: // get number of modern lights
USB_WriteByte((byte) 0);
break;
case 20: // get status of solenoid
if (USB_SerialBuffer[0] < 26) { // max 24 solenoids
USB_WriteByte((byte) QuerySolenoid(USB_SerialBuffer[0]));}
break;
case 21: // set solenoid # to on
if (game_settings[USB_PinMameGame] > 18 || USB_SerialBuffer[0] < 9 || USB_SerialBuffer[0] > 13) { // block solenoid commands for Sys 3 - 6 sound control lines
if (!PinMameException(SolenoidActCommand, USB_SerialBuffer[0])){ // check for machine specific exceptions
if (USB_SerialBuffer[0] < 23) { // max 24 solenoids
if (!SolRecycleTimers[USB_SerialBuffer[0]-1]) { // recycling time over for this coil?
SolChange = false; // block IRQ solenoid handling
if (USB_SerialBuffer[0] > 8) { // does the solenoid not belong to the first latch?
if (USB_SerialBuffer[0] < 17) { // does it belong to the second latch?
SolBuffer[1] |= 1<<(USB_SerialBuffer[0]-9);} // latch counts from 0
else {
SolBuffer[2] |= 1<<(USB_SerialBuffer[0]-17);}}
else {
SolBuffer[0] |= 1<<(USB_SerialBuffer[0]-1);}
SolChange = true;}}
else if (USB_SerialBuffer[0] == 23) { // right flipper
ActivateSolenoid(0, 23);}
else if (USB_SerialBuffer[0] == 24) { // left flipper
ActivateSolenoid(0, 24);}
else if (USB_SerialBuffer[0] == 25) { // 25 is a shortcut for both flipper fingers
ActivateSolenoid(0, 23); // enable both flipper fingers
ActivateSolenoid(0, 24);}
else if ((USB_SerialBuffer[0] <= SolMax) && APC_settings[SolenoidExp]) { // sol exp board selected
WriteToHwExt(SolBuffer[3] |= 1<<(USB_SerialBuffer[0]-26), 128+4);
WriteToHwExt(SolBuffer[3] |= 1<<(USB_SerialBuffer[0]-26), 4);}}}
break;
case 22: // set solenoid # to off
if (game_settings[USB_PinMameGame] > 18 || USB_SerialBuffer[0] < 9 || USB_SerialBuffer[0] > 13) { // block solenoid commands for Sys 3 - 6 sound control lines
if (!PinMameException(SolenoidRelCommand, USB_SerialBuffer[0])){ // check for machine specific exceptions
if (USB_SerialBuffer[0] < 25) { // max 24 solenoids
ReleaseSolenoid(USB_SerialBuffer[0]);}
else if (USB_SerialBuffer[0] == 25) { // 25 is a shortcut for both flipper fingers
ReleaseSolenoid(23); // disable both flipper fingers
ReleaseSolenoid(24);}
else if ((USB_SerialBuffer[0] <= SolMax) && APC_settings[SolenoidExp]) { // sol exp board selected
WriteToHwExt(SolBuffer[3] &= 255-(1<<(USB_SerialBuffer[0]-26)), 128+4);
WriteToHwExt(SolBuffer[3] &= 255-(1<<(USB_SerialBuffer[0]-26)), 4);}}}
break;
case 23: // pulse solenoid
if (USB_SolTimes[USB_SerialBuffer[0]-1]) { // pulse length set?
ActivateSolenoid((byte) USB_SolTimes[USB_SerialBuffer[0]-1], USB_SerialBuffer[0]);}
break;
case 24: // set solenoid pulse time
if (USB_SerialBuffer[0] < 25) { // max 24 solenoids
USB_SolTimes[USB_SerialBuffer[0]-1] = USB_SerialBuffer[1];}
break;
case 25: // set solenoid recycle time
SolRecycleTime[USB_SerialBuffer[0]-1] = USB_SerialBuffer[1];
break;
case 30: // set display 0 to (credit display)
if (!PinMameException(WriteToDisplay0, 0)){ // check for machine specific exceptions
switch (APC_settings[DisplayType]) { // which display is used?
case 0: // 4 ALPHA+CREDIT
case 1: // Sys11 Pinbot
switch (USB_DisplayProtocol[0]) { // which protocol shall be used?
case 1: // BCD
case 2: // BCD with comma (not possible as credit has no comma)
*(DisplayUpper) = LeftCredit[(USB_SerialBuffer[0]+16)*2];
*(DisplayUpper+16) = LeftCredit[(USB_SerialBuffer[1]+16)*2];
*(DisplayLower) = RightCredit[(USB_SerialBuffer[2]+16)*2];
*(DisplayLower+16) = RightCredit[(USB_SerialBuffer[3]+16)*2];
break;
case 3: // 7 segment pattern (1 byte)
*(DisplayUpper) = USB_SerialBuffer[0];
*(DisplayUpper+16) = USB_SerialBuffer[1];
*(DisplayLower) = ConvertPattern(0, USB_SerialBuffer[2]);
*(DisplayLower+16) = ConvertPattern(0, USB_SerialBuffer[3]);
break;
case 4: // 14 segment pattern (2 bytes)
*(DisplayUpper) = USB_SerialBuffer[0];
*(DisplayUpper+16) = USB_SerialBuffer[2];
*(DisplayLower) = ConvertPattern(0, USB_SerialBuffer[4]);
*(DisplayLower+16) = ConvertPattern(0, USB_SerialBuffer[6]);
break;
case 5: // ASCII
case 6: // ASCII with comma (not possible as credit has no comma)
WritePlayerDisplay((char*)USB_SerialBuffer, 0);
break;}
break;
case 7: // Sys3 - 6 display
case 8: // Sys7 + 9 display
switch (USB_DisplayProtocol[0]) { // which protocol shall be used?
case 1: // BCD
case 2: // BCD with comma
DisplayBCD(0, USB_SerialBuffer);
break;
case 5:
case 6:
WritePlayerDisplay((char*)USB_SerialBuffer, 0);
break;}
break;}}
break;
case 31: // set display 1 to
if (!PinMameException(WriteToDisplay1, 0)){ // check for machine specific exceptions
switch (APC_settings[DisplayType]) { // which display is used?
case 0: // 4 ALPHA+CREDIT
case 1: // Sys11 Pinbot
case 2: // Sys11 F-14
switch (USB_DisplayProtocol[1]) { // which protocol shall be used?
case 1: // BCD
for (i=0; i<7; i++) {
*(DisplayUpper+2*i+2) = DispPattern1[32+2*USB_SerialBuffer[i]];
*(DisplayUpper+2*i+3) = DispPattern1[33+2*USB_SerialBuffer[i]];}
break;
case 2: // BCD with comma
for (i=0; i<7; i++) {
if (USB_SerialBuffer[i] & 128) { // comma set?
*(DisplayUpper+2*i+2) = 128 | DispPattern1[32+2*(USB_SerialBuffer[i] & 15)];
*(DisplayUpper+2*i+3) = 64 | DispPattern1[33+2*(USB_SerialBuffer[i] & 15)];}
else {
*(DisplayUpper+2*i+2) = DispPattern1[32+2*USB_SerialBuffer[i]];
*(DisplayUpper+2*i+3) = DispPattern1[33+2*USB_SerialBuffer[i]];}}
break;
case 3: // 7 segment pattern (1 byte)
for (i=0; i<7; i++) {
*(DisplayUpper+2*i+2) = USB_SerialBuffer[i];
if (USB_SerialBuffer[i] & 64) { // g segment set?
*(DisplayUpper+2*i+3) = 4;} // turn on m segment of alpha display
else {
*(DisplayUpper+2*i+1) = 0;}}
break;
case 4: // 14 segment pattern (2 bytes)
for (i=0; i<14; i++) {
*(DisplayUpper+i+2) = USB_SerialBuffer[i];}
break;
case 5: // ASCII
case 6: // ASCII with comma
WritePlayerDisplay((char*)USB_SerialBuffer, 1);
break;}
break;
case 3: // Sys11 BK2K
case 4: // Sys11 Taxi
case 5: // Sys11 Riverboat Gambler
case 6: // DE 2x16
switch (USB_DisplayProtocol[1]) { // which protocol shall be used?
case 1: // BCD
for (i=0; i<16; i++) {
*(DisplayUpper+2*i) = DispPattern1[32+2*USB_SerialBuffer[i]];
*(DisplayUpper+2*i+1) = DispPattern1[33+2*USB_SerialBuffer[i]];}
break;
case 2: // BCD with comma
for (i=0; i<16; i++) {
if (USB_SerialBuffer[i] & 128) { // comma set?
*(DisplayUpper+2*i) = 128 | DispPattern1[32+2*(USB_SerialBuffer[i] & 15)];
*(DisplayUpper+2*i+1) = 64 | DispPattern1[33+2*(USB_SerialBuffer[i] & 15)];}
else {
*(DisplayUpper+2*i) = DispPattern1[32+2*USB_SerialBuffer[i]];
*(DisplayUpper+2*i+1) = DispPattern1[33+2*USB_SerialBuffer[i]];}}
break;
case 3: // 7 segment pattern (1 byte)
for (i=0; i<16; i++) {
*(DisplayUpper+2*i) = USB_SerialBuffer[i];
if (USB_SerialBuffer[i] & 64) { // g segment set?
*(DisplayUpper+2*i+1) = 4;} // turn on m segment of alpha display
else {
*(DisplayUpper+2*i+1) = 0;}}
break;
case 4: // 14 segment pattern (2 bytes)
for (i=0; i<32; i++) {
*(DisplayUpper+i) = USB_SerialBuffer[i];}
break;
case 5: // ASCII
case 6: // ASCII with comma
WritePlayerDisplay((char*)USB_SerialBuffer, 1);
break;}
break;
case 7: // Sys3 - 6 display
case 8: // Sys7 + 9 display
switch (USB_DisplayProtocol[1]) { // which protocol shall be used?
case 1: // BCD
case 2: // BCD with comma
DisplayBCD(1, USB_SerialBuffer);
break;
case 5: // ASCII
case 6: // ASCII with comma
WritePlayerDisplay((char*)USB_SerialBuffer, 1);
break;}
break;}}
break;
case 32: // set display 2 to
if (!PinMameException(WriteToDisplay2, 0)){ // check for machine specific exceptions
switch (APC_settings[DisplayType]) { // which display is used?
case 0: // 4 ALPHA+CREDIT
case 1: // Sys11 Pinbot
case 2: // Sys11 F-14
switch (USB_DisplayProtocol[2]) { // which protocol shall be used?
case 1: // BCD
for (i=0; i<7; i++) {
*(DisplayUpper+2*i+18) = DispPattern1[32+2*USB_SerialBuffer[i]];
*(DisplayUpper+2*i+19) = DispPattern1[33+2*USB_SerialBuffer[i]];}
break;
case 2: // BCD with comma
for (i=0; i<7; i++) {
if (USB_SerialBuffer[i] & 128) { // comma set?
*(DisplayUpper+2*i+18) = 128 | DispPattern1[32+2*(USB_SerialBuffer[i] & 15)];
*(DisplayUpper+2*i+19) = 64 | DispPattern1[33+2*(USB_SerialBuffer[i] & 15)];}
else {
*(DisplayUpper+2*i+18) = DispPattern1[32+2*USB_SerialBuffer[i]];
*(DisplayUpper+2*i+19) = DispPattern1[33+2*USB_SerialBuffer[i]];}}
break;
case 3: // 7 segment pattern (1 byte)
for (i=0; i<7; i++) {
*(DisplayUpper+2*i+18) = USB_SerialBuffer[i];
if (USB_SerialBuffer[i] & 64) { // g segment set?
*(DisplayUpper+2*i+19) = 4;} // turn on m segment of alpha display
else {
*(DisplayUpper+2*i+19) = 0;}}
break;
case 4: // 14 segment pattern (2 bytes)
for (i=0; i<14; i++) {
*(DisplayUpper+i+18) = USB_SerialBuffer[i];}
break;
case 5: // ASCII
case 6: // ASCII with comma
WritePlayerDisplay((char*)USB_SerialBuffer, 2);
break;}
break;
case 3: // Sys11 BK2K
if (!game_settings[USB_Debug]) { // display can be used for debug information
switch (USB_DisplayProtocol[2]) { // which protocol shall be used?
case 1: // BCD
for (i=0; i<16; i++) {
*(DisplayLower+2*i) = DispPattern2[32+2*USB_SerialBuffer[i]];
*(DisplayLower+2*i+1) = DispPattern2[33+2*USB_SerialBuffer[i]];}
break;
case 2: // BCD with comma
for (i=0; i<16; i++) {
if (USB_SerialBuffer[i] & 128) { // comma set?
*(DisplayLower+2*i) = 1 | DispPattern2[32+2*(USB_SerialBuffer[i] & 15)];
*(DisplayLower+2*i+1) = 8 | DispPattern2[33+2*(USB_SerialBuffer[i] & 15)];}
else {
*(DisplayLower+2*i) = DispPattern2[32+2*USB_SerialBuffer[i]];
*(DisplayLower+2*i+1) = DispPattern2[33+2*USB_SerialBuffer[i]];}}
break;
case 3: // 7 segment pattern (1 byte)
for (i=0; i<16; i++) {
*(DisplayLower+2*i) = ConvertPattern(0, USB_SerialBuffer[i]);}
break;
case 4: // 14 segment pattern (2 bytes)
for (i=0; i<16; i++) {
*(DisplayLower+2*i) = ConvertPattern(0, USB_SerialBuffer[2*i]);
*(DisplayLower+2*i+1) = ConvertPattern(1, USB_SerialBuffer[2*i+1]);}
break;
case 5: // ASCII
case 6: // ASCII with comma
WritePlayerDisplay((char*)USB_SerialBuffer, 2);
break;}}
break;
case 4: // Sys11 Taxi
case 5: // Sys11 Riverboat Gambler
case 6: // DE 2x16
if (!game_settings[USB_Debug]) { // display can be used for debug information
switch (USB_DisplayProtocol[2]) { // which protocol shall be used?
case 1: // BCD
for (i=0; i<16; i++) {
*(DisplayLower+2*i) = DispPattern2[32+2*USB_SerialBuffer[i]];}
break;
case 2: // BCD with comma
for (i=0; i<16; i++) {
if (USB_SerialBuffer[i] & 128) { // comma set?
*(DisplayLower+2*i) = 1 | DispPattern2[32+2*(USB_SerialBuffer[i] & 15)];}
else {
*(DisplayLower+2*i) = DispPattern2[32+2*USB_SerialBuffer[i]];}}
break;
case 3: // 7 segment pattern (1 byte)
for (i=0; i<16; i++) {
*(DisplayLower+2*i) = ConvertPattern(0, USB_SerialBuffer[i]);}
break;
case 4: // 14 segment pattern (2 bytes)
for (i=0; i<16; i++) {
*(DisplayLower+2*i) = ConvertPattern(0, USB_SerialBuffer[2*i]);
*(DisplayLower+2*i+1) = ConvertPattern(1, USB_SerialBuffer[2*i+1]);}
break;
case 5: // ASCII
case 6: // ASCII with comma
WritePlayerDisplay((char*)USB_SerialBuffer, 2);
break;}}
break;
case 7: // Sys3 - 6 display
case 8: // Sys7 + 9 display
switch (USB_DisplayProtocol[2]) { // which protocol shall be used?
case 1: // BCD
case 2: // BCD with comma
DisplayBCD(2, USB_SerialBuffer);
break;
case 5: // ASCII
case 6: // ASCII with comma
WritePlayerDisplay((char*)USB_SerialBuffer, 2);
break;}
break;}}
break;
case 33: // set display 3 to
if (!game_settings[USB_Debug] && !PinMameException(WriteToDisplay3, 0)) { // display can be used for debug information
switch (APC_settings[DisplayType]) { // which display is used?
case 0: // 4 ALPHA+CREDIT
switch (USB_DisplayProtocol[3]) { // which protocol shall be used?
case 1: // BCD
for (i=0; i<7; i++) {
*(DisplayLower+2*i+2) = DispPattern2[32+2*USB_SerialBuffer[i]];
*(DisplayLower+2*i+3) = DispPattern2[33+2*USB_SerialBuffer[i]];}
break;
case 2: // BCD with comma
for (i=0; i<7; i++) {
if (USB_SerialBuffer[i] & 128) { // comma set?
*(DisplayLower+2*i+2) = 1 | DispPattern2[32+2*(USB_SerialBuffer[i] & 15)];
*(DisplayLower+2*i+3) = 8 | DispPattern2[33+2*(USB_SerialBuffer[i] & 15)];}
else {
*(DisplayLower+2*i+2) = DispPattern2[32+2*USB_SerialBuffer[i]];
*(DisplayLower+2*i+3) = DispPattern2[33+2*USB_SerialBuffer[i]];}}
break;
case 3: // 7 segment pattern (1 byte)
for (i=0; i<7; i++) {
*(DisplayUpper+2*i+2) = ConvertPattern(0, USB_SerialBuffer[i]);
if (USB_SerialBuffer[i] & 64) { // g segment set?
*(DisplayLower+2*i+3) = 2;} // turn on m segment of alpha display
else {
*(DisplayLower+2*i+3) = 0;}}
break;
case 4: // 14 segment pattern (2 bytes)
for (i=0; i<14; i++) {
*(DisplayLower+2*i+2) = ConvertPattern(0, USB_SerialBuffer[2*i]);
*(DisplayLower+2*i+3) = ConvertPattern(1, USB_SerialBuffer[2*i+1]);}
break;
case 5: // ASCII
case 6: // ASCII with comma
WritePlayerDisplay((char*)USB_SerialBuffer, 3);
break;}
break;
case 1: // Sys11 Pinbot
case 2: // Sys11 F-14
switch (USB_DisplayProtocol[3]) { // which protocol shall be used?
case 1: // BCD
for (i=0; i<7; i++) {
*(DisplayLower+2*i+2) = DispPattern2[32+2*USB_SerialBuffer[i]];}
break;
case 2: // BCD with comma
for (i=0; i<7; i++) {
if (USB_SerialBuffer[i] & 128) { // comma set?
*(DisplayLower+2*i+2) = 1 | DispPattern2[32+2*(USB_SerialBuffer[i] & 15)];}
else {
*(DisplayLower+2*i+2) = DispPattern2[32+2*USB_SerialBuffer[i]];}}
break;
case 3: // 7 segment pattern (1 byte)
for (i=0; i<7; i++) {
*(DisplayLower+2*i+2) = ConvertPattern(0, USB_SerialBuffer[i]);}
break;
// case 4: // 14 segment pattern (2 bytes)
// for (i=0; i<14; i++) {
// *(DisplayLower+2*i+2) = ConvertPattern(0, USB_SerialBuffer[i]);}
// break;
case 5: // ASCII
case 6: // ASCII with comma
WritePlayerDisplay((char*)USB_SerialBuffer, 3);
break;}
break;
case 4: // Sys11 Taxi
case 5: // Sys11 Riverboat Gambler
for (i=0; i<7; i++) { // 7 segment pattern assumed (1 byte)
*(DisplayLower+2*i+1) = ConvertPattern(1, USB_SerialBuffer[i]);}
break;
case 7: // Sys3 - 6 display
case 8: // Sys7 + 9 display
switch (USB_DisplayProtocol[3]) { // which protocol shall be used?
case 1: // BCD
case 2: // BCD with comma
DisplayBCD(3, USB_SerialBuffer);
break;
case 5: // ASCII
case 6: // ASCII with comma
WritePlayerDisplay((char*)USB_SerialBuffer, 3);
break;}
break;}}
break;
case 34: // set display 4 to
if (!game_settings[USB_Debug] && !PinMameException(WriteToDisplay4, 0)) { // display can be used for debug information
switch (APC_settings[DisplayType]) { // which display is used?
case 0: // 4 ALPHA+CREDIT
switch (USB_DisplayProtocol[4]) { // which protocol shall be used?
case 1: // BCD
for (i=0; i<7; i++) {
*(DisplayLower+2*i+18) = DispPattern2[32+2*USB_SerialBuffer[i]];
*(DisplayLower+2*i+19) = DispPattern2[33+2*USB_SerialBuffer[i]];}
break;
case 2: // BCD with comma
for (i=0; i<7; i++) {
if (USB_SerialBuffer[i] & 128) { // comma set?
*(DisplayLower+2*i+18) = 1 | DispPattern2[32+2*(USB_SerialBuffer[i] & 15)];
*(DisplayLower+2*i+19) = 8 | DispPattern2[33+2*(USB_SerialBuffer[i] & 15)];}
else {
*(DisplayLower+2*i+18) = DispPattern2[32+2*USB_SerialBuffer[i]];
*(DisplayLower+2*i+19) = DispPattern2[33+2*USB_SerialBuffer[i]];}}
break;
case 3: // 7 segment pattern (1 byte)
for (i=0; i<7; i++) {
*(DisplayUpper+2*i+18) = ConvertPattern(0, USB_SerialBuffer[i]);
if (USB_SerialBuffer[i] & 64) { // g segment set?
*(DisplayLower+2*i+19) = 2;} // turn on m segment of alpha display
else {
*(DisplayLower+2*i+19) = 0;}}
break;
case 4: // 14 segment pattern (2 bytes)
for (i=0; i<14; i++) {
*(DisplayLower+2*i+2) = ConvertPattern(0, USB_SerialBuffer[2*i]);
*(DisplayLower+2*i+3) = ConvertPattern(1, USB_SerialBuffer[2*i+1]);}
break;
case 5: // ASCII
case 6: // ASCII with comma
WritePlayerDisplay((char*)USB_SerialBuffer, 4);
break;}
break;
case 1: // Sys11 Pinbot
case 2: // Sys11 F-14
switch (USB_DisplayProtocol[4]) { // which protocol shall be used?
case 1: // BCD
for (i=0; i<7; i++) {
*(DisplayLower+2*i+18) = DispPattern2[32+2*USB_SerialBuffer[i]];}
break;
case 2: // BCD with comma
for (i=0; i<7; i++) {
if (USB_SerialBuffer[i] & 128) { // comma set?
*(DisplayLower+2*i+18) = 16 | DispPattern2[32+2*(USB_SerialBuffer[i] & 15)];}
else {
*(DisplayLower+2*i+18) = DispPattern2[32+2*USB_SerialBuffer[i]];}}
break;
case 3: // 7 segment pattern (1 byte)
for (i=0; i<7; i++) {
*(DisplayLower+2*i+18) = ConvertPattern(0, USB_SerialBuffer[i]);}
break;
case 4: // 14 segment pattern (2 bytes)
for (i=0; i<14; i++) {
*(DisplayLower+2*i+18) = ConvertPattern(0, USB_SerialBuffer[i]);}
break;
case 5: // ASCII
case 6: // ASCII with comma
WritePlayerDisplay((char*)USB_SerialBuffer, 4);
break;}
break;
case 4: // Sys11 Taxi
case 5: // Sys11 Riverboat Gambler
for (i=0; i<7; i++) { // 7 segment pattern assumed (1 byte)
*(DisplayLower+2*i+17) = ConvertPattern(1, USB_SerialBuffer[i]);}
break;
case 7: // Sys3 - 6 display
case 8: // Sys7 + 9 display
switch (USB_DisplayProtocol[4]) { // which protocol shall be used?
case 1: // BCD
case 2: // BCD with comma
DisplayBCD(4, USB_SerialBuffer);
break;
case 5: // ASCII
case 6: // ASCII with comma
WritePlayerDisplay((char*)USB_SerialBuffer, 4);
break;}
break;}}
break;
case 37: // select display protocol
if (USB_SerialBuffer[0] < 5) {
USB_DisplayProtocol[USB_SerialBuffer[0]] = USB_SerialBuffer[1];}
break;
case 40: // get status of switch #
if (USB_SerialBuffer[0] < 74) { // max 73 switches
if (QuerySwitch(USB_SerialBuffer[0])) { // query state
USB_WriteByte((byte) 1);}
else {
USB_WriteByte((byte) 0);}}
else {
USB_WriteByte((byte) 2);}
break;
case 41: // get changed switches
if (USB_ChangedSwitches[0]) { // any changed switches?
i = 0;
USB_WriteByte((byte) USB_ChangedSwitches[0]); // send it
do {
USB_ChangedSwitches[i] = USB_ChangedSwitches[i+1];
i++;}
while (USB_ChangedSwitches[i]);} // still more changed switches?
else {
USB_WriteByte((byte) 127);} // no changed switches at all
break;
case 50: // play sound #
if (game_settings[USB_PinMameSound]) { // use old audio board
if (game_settings[USB_PinMameGame] < 19) { // Sys 3 - 6 game
SolBuffer[1] = SolBuffer[1] & 224; // turn off sound related solenoids
SolBuffer[1] = SolBuffer[1] | (~USB_SerialBuffer[1] & 31);} // write sound number to solenoids 9 - 13
else if (game_settings[USB_PinMameGame] < 40) { // Sys 7 - 9 game
WriteToHwExt(USB_SerialBuffer[1], 128+16); // turn on Sel14
WriteToHwExt(USB_SerialBuffer[1], 16);} // turn off Sel14
else { // Sys 11 game
WriteToHwExt(USB_SerialBuffer[1], 4); // turn off Sel7
WriteToHwExt(USB_SerialBuffer[1], 128+4+16);}} // turn on Sel7 + Sel14
else { // use APC sound HW
if (USB_SerialBuffer[0] == 1) { // channel 1?
PinMameException(SoundCommandCh1, USB_SerialBuffer[1]);}
else { // channel 2
PinMameException(SoundCommandCh2, USB_SerialBuffer[1]);}}
break;
case 51: // stop sound
if (USB_SerialBuffer[0] == 1) { // channel 1?
AfterMusic = 0;
StopPlayingMusic();}
else {
AfterSound = 0;
StopPlayingSound();}
break;
case 52: // play soundfile
if (USB_SerialBuffer[0] == 1) { // channel 1?
if (!USB_WaitSoundTimer) { // no sound wait timer active?
PlayMusic(50, (char*) USB_SerialBuffer+2); // play the sound
USB_WaitSoundTimer = ActivateTimer(15, 0, USB_ResetWaitSoundTimers); // start a timer
if (USB_SerialBuffer[1] & 1) { // looping active?
for (i=0; i<12; i++) {
USB_RepeatMusic[i] = USB_SerialBuffer[2+i];}
QueueNextMusic(USB_RepeatMusic);}
else {
AfterMusic = 0;}}
else { // sound wait timer active
if (!USB_WaitingSoundFiles[0][1]) { // any waiting sounds?
if (USB_SerialBuffer[1] & 1) { // if not check for looping
USB_WaitingSoundFiles[0][0] = 2;} // set the looping flag
for (i=0; i<12; i++) { // copy the filename to the waiting stack
USB_WaitingSoundFiles[0][i+1] = USB_SerialBuffer[2+i];}}
else { // waiting stack not empty
if (USB_WaitingSoundFiles[0][0] & 1) { // is the waiting sound for channel 2?
if (USB_SerialBuffer[1] & 1) { // then copy the sound data to stack position 2
USB_WaitingSoundFiles[1][0] = 2;}
for (i=0; i<12; i++) { // copy the filename to the waiting stack
USB_WaitingSoundFiles[1][1+i] = USB_SerialBuffer[2+i];}}
else { // waiting sound is also for channel 1
if (USB_WaitingSoundFiles[1][1]) { // is there a sound in waiting position 2?
for (i=1; i<13; i++) { // if yes move it to position 1 and copy the new sound to position 2
USB_WaitingSoundFiles[0][i] = USB_WaitingSoundFiles[1][i];
USB_WaitingSoundFiles[1][i] = USB_SerialBuffer[1+i];}
USB_WaitingSoundFiles[0][0] = USB_WaitingSoundFiles[1][0]; // copy command byte
if (USB_SerialBuffer[1] & 1) { // handle looping flag
USB_WaitingSoundFiles[1][0] = 2;}
else {
USB_WaitingSoundFiles[1][0] = 0;}}
else { // no sound at stack position 2
if (USB_SerialBuffer[1] & 1) { // overwrite stack position 1
USB_WaitingSoundFiles[0][0] = 2;}
else {
USB_WaitingSoundFiles[0][0] = 0;}
for (i=0; i<12; i++) { // copy the filename to the waiting stack
USB_WaitingSoundFiles[0][i+1] = USB_SerialBuffer[2+i];}}}}}}
else { // channel 2
if (!USB_WaitSoundTimer) {
PlaySound(50, (char*) USB_SerialBuffer+2);
USB_WaitSoundTimer = ActivateTimer(15, 0, USB_ResetWaitSoundTimers);
if (USB_SerialBuffer[1] & 1) { // looping active?
for (i=0; i<12; i++) {
USB_RepeatSound[i] = USB_SerialBuffer[2+i];}
QueueNextSound(USB_RepeatSound);}
else {
AfterSound = 0;}}
else {