void cliFunc_lcdCmd( char* args )
{
char* curArgs;
char* arg1Ptr;
char* arg2Ptr = args;
print( NL ); // No \r\n by default after the command is entered
curArgs = arg2Ptr; // Use the previous 2nd arg pointer to separate the next arg from the list
CLI_argumentIsolation( curArgs, &arg1Ptr, &arg2Ptr );
// No args
if ( *arg1Ptr == '\0' )
return;
// SPI Command
uint8_t cmd = (uint8_t)numToInt( arg1Ptr );
curArgs = arg2Ptr; // Use the previous 2nd arg pointer to separate the next arg from the list
CLI_argumentIsolation( curArgs, &arg1Ptr, &arg2Ptr );
// Single Arg
if ( *arg1Ptr == '\0' )
goto cmd;
// TODO Deal with a0
cmd:
info_msg("Sending - ");
printHex( cmd );
print( NL );
LCD_writeControlReg( cmd );
}
void cliFunc_ledSet( char* args )
{
print( NL ); // No \r\n by default after the command is entered
char* curArgs;
char* arg1Ptr;
char* arg2Ptr = args;
// Process speed argument if given
curArgs = arg2Ptr;
CLI_argumentIsolation( curArgs, &arg1Ptr, &arg2Ptr );
// Reset brightness
if ( *arg1Ptr == '\0' )
{
LED_setBrightness( ISSI_Global_Brightness_define );
}
else
{
LED_setBrightness( numToInt(arg1Ptr) );
}
info_msg("LED Brightness Set");
}
void cliFunc_voteDebug( char* args )
{
// Parse number from argument
// NOTE: Only first argument is used
char* arg1Ptr;
char* arg2Ptr;
CLI_argumentIsolation( args, &arg1Ptr, &arg2Ptr );
// Set the vote debug flag depending on the argument
switch ( arg1Ptr[0] )
{
// No argument
case 1:
case '\0':
voteDebugMode = voteDebugMode != 1 ? 1 : 0;
break;
// Invalid argument
default:
return;
}
print( NL );
info_msg("Vote Debug Mode: ");
printInt8( voteDebugMode );
}
void cliFunc_keyRelease( char* args )
{
// Parse codes from arguments
char* curArgs;
char* arg1Ptr;
char* arg2Ptr = args;
// Process all args
for ( ;; )
{
curArgs = arg2Ptr;
CLI_argumentIsolation( curArgs, &arg1Ptr, &arg2Ptr );
// Stop processing args if no more are found
if ( *arg1Ptr == '\0' )
break;
// Ignore non-Scancode numbers
switch ( arg1Ptr[0] )
{
// Scancode
case 'S':
Macro_keyState( (uint8_t)numToInt( &arg1Ptr[1] ), 0x03 ); // Release scancode
break;
}
}
}
void cliFunc_macroShow( char* args )
{
// Parse codes from arguments
char* curArgs;
char* arg1Ptr;
char* arg2Ptr = args;
// Process all args
for ( ;; )
{
curArgs = arg2Ptr;
CLI_argumentIsolation( curArgs, &arg1Ptr, &arg2Ptr );
// Stop processing args if no more are found
if ( *arg1Ptr == '\0' )
break;
// Ignore invalid codes
switch ( arg1Ptr[0] )
{
// Indexed Trigger Macro
case 'T':
macroDebugShowTrigger( numToInt( &arg1Ptr[1] ) );
break;
// Indexed Result Macro
case 'R':
macroDebugShowResult( numToInt( &arg1Ptr[1] ) );
break;
}
}
}
void cliFunc_connectMst( char* args )
{
// Parse number from argument
// NOTE: Only first argument is used
char* arg1Ptr;
char* arg2Ptr;
CLI_argumentIsolation( args, &arg1Ptr, &arg2Ptr );
print( NL );
// Set override
Connect_override = 1;
switch ( arg1Ptr[0] )
{
// Disable override
case 'd':
case 'D':
Connect_override = 0;
case 's':
case 'S':
info_msg("Setting device as slave.");
Connect_master = 0;
Connect_id = 0xFF;
break;
case 'm':
case 'M':
default:
info_msg("Setting device as master.");
Connect_master = 1;
Connect_id = 0;
break;
}
}
void cliFunc_kbdProtocol( char* args )
{
print( NL );
// Parse number from argument
// NOTE: Only first argument is used
char* arg1Ptr;
char* arg2Ptr;
CLI_argumentIsolation( args, &arg1Ptr, &arg2Ptr );
if ( arg1Ptr[0] != '\0' )
{
uint8_t mode = (uint8_t)numToInt( arg1Ptr );
// Do nothing if the argument was wrong
if ( mode == 0 || mode == 1 )
{
USBKeys_Protocol = mode;
info_msg("Setting Keyboard Protocol to: ");
printInt8( USBKeys_Protocol );
}
}
else
{
info_msg("Keyboard Protocol: ");
printInt8( USBKeys_Protocol );
}
}
void cliFunc_lcdColor( char* args )
{
char* curArgs;
char* arg1Ptr;
char* arg2Ptr = args;
// Colors
uint16_t rgb[3]; // Red, Green, Blue
// Parse integers from 3 arguments
for ( uint8_t color = 0; color < 3; color++ )
{
curArgs = arg2Ptr;
CLI_argumentIsolation( curArgs, &arg1Ptr, &arg2Ptr );
// Give up if not enough args given
if ( *arg1Ptr == '\0' )
return;
// Convert argument to integer
rgb[ color ] = numToInt( arg1Ptr );
}
// Set PWM channels
FTM0_C0V = rgb[0];
FTM0_C1V = rgb[1];
FTM0_C2V = rgb[2];
}
void cliFunc_ledWPage( char* args )
{
char* curArgs;
char* arg1Ptr;
char* arg2Ptr = args;
// First process page and starting address
curArgs = arg2Ptr;
CLI_argumentIsolation( curArgs, &arg1Ptr, &arg2Ptr );
// Stop processing args if no more are found
if ( *arg1Ptr == '\0' )
return;
uint8_t page[] = { 0xE8, 0xFD, numToInt( arg1Ptr ) };
curArgs = arg2Ptr;
CLI_argumentIsolation( curArgs, &arg1Ptr, &arg2Ptr );
// Stop processing args if no more are found
if ( *arg1Ptr == '\0' )
return;
uint8_t data[] = { 0xE8, numToInt( arg1Ptr ), 0 };
// Set the register page
while ( I2C_Send( page, sizeof( page ), 0 ) == 0 )
delay(1);
// Process all args
for ( ;; )
{
curArgs = arg2Ptr;
CLI_argumentIsolation( curArgs, &arg1Ptr, &arg2Ptr );
// Stop processing args if no more are found
if ( *arg1Ptr == '\0' )
break;
data[2] = numToInt( arg1Ptr );
// Write register location and data to I2C
while ( I2C_Send( data, sizeof( data ), 0 ) == 0 )
delay(1);
// Increment address
data[1]++;
}
}
void cliFunc_lcdDisp( char* args )
{
char* curArgs;
char* arg1Ptr;
char* arg2Ptr = args;
// First process page and starting address
curArgs = arg2Ptr;
CLI_argumentIsolation( curArgs, &arg1Ptr, &arg2Ptr );
// Stop processing args if no more are found
if ( *arg1Ptr == '\0' )
return;
uint8_t page = numToInt( arg1Ptr );
curArgs = arg2Ptr;
CLI_argumentIsolation( curArgs, &arg1Ptr, &arg2Ptr );
// Stop processing args if no more are found
if ( *arg1Ptr == '\0' )
return;
uint8_t address = numToInt( arg1Ptr );
// Set the register page
LCD_writeControlReg( 0xB0 | ( 0x0F & page ) );
// Set starting address
LCD_writeControlReg( 0x10 | ( ( 0xF0 & address ) >> 4 ) );
LCD_writeControlReg( 0x00 | ( 0x0F & address ));
// Process all args
for ( ;; )
{
curArgs = arg2Ptr;
CLI_argumentIsolation( curArgs, &arg1Ptr, &arg2Ptr );
// Stop processing args if no more are found
if ( *arg1Ptr == '\0' )
break;
uint8_t value = numToInt( arg1Ptr );
// Write buffer to SPI
SPI_write( &value, 1 );
}
}
void cliFunc_connectCmd( char* args )
{
// Parse number from argument
// NOTE: Only first argument is used
char* arg1Ptr;
char* arg2Ptr;
CLI_argumentIsolation( args, &arg1Ptr, &arg2Ptr );
print( NL );
switch ( numToInt( &arg1Ptr[0] ) )
{
case CableCheck:
Connect_send_CableCheck( UARTConnectCableCheckLength_define );
break;
case IdRequest:
Connect_send_IdRequest();
break;
case IdEnumeration:
Connect_send_IdEnumeration( 5 );
break;
case IdReport:
Connect_send_IdReport( 8 );
break;
case ScanCode:
{
TriggerEvent scanCodes[] = { { 0x00, 0x01, 0x05 }, { 0x00, 0x03, 0x16 } };
Connect_send_ScanCode( 10, scanCodes, 2 );
break;
}
case Animation:
break;
case RemoteCapability:
// TODO
break;
case RemoteOutput:
// TODO
break;
case RemoteInput:
// TODO
break;
case CurrentEvent:
dbug_print("Sending current event");
Connect_send_CurrentEvent( 250 );
break;
default:
break;
}
}
void cliFunc_setMod( char* args )
{
// Parse number from argument
// NOTE: Only first argument is used
char* arg1Ptr;
char* arg2Ptr;
CLI_argumentIsolation( args, &arg1Ptr, &arg2Ptr );
USBKeys_ModifiersCLI = numToInt( arg1Ptr );
}
void cliFunc_ledCtrl( char* args )
{
char* curArgs;
char* arg1Ptr;
char* arg2Ptr = args;
LedControl control;
// First process mode
curArgs = arg2Ptr;
CLI_argumentIsolation( curArgs, &arg1Ptr, &arg2Ptr );
// Stop processing args if no more are found
if ( *arg1Ptr == '\0' )
return;
control.mode = numToInt( arg1Ptr );
// Next process amount
curArgs = arg2Ptr;
CLI_argumentIsolation( curArgs, &arg1Ptr, &arg2Ptr );
// Stop processing args if no more are found
if ( *arg1Ptr == '\0' )
return;
control.amount = numToInt( arg1Ptr );
// Finally process led index, if it exists
// Default to 0
curArgs = arg2Ptr;
CLI_argumentIsolation( curArgs, &arg1Ptr, &arg2Ptr );
control.index = *arg1Ptr == '\0' ? 0 : numToInt( arg1Ptr );
// Process request
LED_control( &control );
}
void cliFunc_outputDebug( char* args )
{
// Parse number from argument
// NOTE: Only first argument is used
char* arg1Ptr;
char* arg2Ptr;
CLI_argumentIsolation( args, &arg1Ptr, &arg2Ptr );
// Default to 1 if no argument is given
Output_DebugMode = Output_DebugMode ? 0 : 1;
if ( arg1Ptr[0] != '\0' )
{
Output_DebugMode = (uint16_t)numToInt( arg1Ptr );
}
}
void cliFunc_i2cRecv( char* args )
{
char* curArgs;
char* arg1Ptr;
char* arg2Ptr = args;
// Buffer used after interpretting the args, will be sent to I2C functions
// NOTE: Limited to 8 bytes currently (can be increased if necessary
#define i2cSend_BuffLenMax 8
uint8_t buffer[ i2cSend_BuffLenMax ];
uint8_t bufferLen = 0;
// No \r\n by default after the command is entered
print( NL );
info_msg("Sending: ");
// Parse args until a \0 is found
while ( bufferLen < i2cSend_BuffLenMax )
{
curArgs = arg2Ptr; // Use the previous 2nd arg pointer to separate the next arg from the list
CLI_argumentIsolation( curArgs, &arg1Ptr, &arg2Ptr );
// Stop processing args if no more are found
if ( *arg1Ptr == '\0' )
break;
// If | is found, end sequence and start new one
if ( *arg1Ptr == '|' )
{
print("| ");
I2C_Send( buffer, bufferLen, 0 );
bufferLen = 0;
continue;
}
// Interpret the argument
buffer[ bufferLen++ ] = (uint8_t)numToInt( arg1Ptr );
// Print out the arg
dPrint( arg1Ptr );
print(" ");
}
print( NL );
I2C_Send( buffer, bufferLen, 1 ); // Only 1 byte is ever read at a time with the ISSI chip
}
void cliFunc_layerState( char* args )
{
// Parse codes from arguments
char* curArgs;
char* arg1Ptr;
char* arg2Ptr = args;
uint8_t arg1 = 0;
uint8_t arg2 = 0;
// Process first two args
for ( uint8_t c = 0; c < 2; c++ )
{
curArgs = arg2Ptr;
CLI_argumentIsolation( curArgs, &arg1Ptr, &arg2Ptr );
// Stop processing args if no more are found
if ( *arg1Ptr == '\0' )
break;
switch ( c )
{
// First argument (e.g. L1)
case 0:
if ( arg1Ptr[0] != 'L' )
return;
arg1 = (uint8_t)numToInt( &arg1Ptr[1] );
break;
// Second argument (e.g. 4)
case 1:
arg2 = (uint8_t)numToInt( arg1Ptr );
// Display operation (to indicate that it worked)
print( NL );
info_msg("Setting Layer L");
printInt8( arg1 );
print(" to - ");
printHex( arg2 );
// Set the layer state
LayerState[ arg1 ] = arg2;
break;
}
}
}
void cliFunc_macroStep( char* args )
{
// Parse number from argument
// NOTE: Only first argument is used
char* arg1Ptr;
char* arg2Ptr;
CLI_argumentIsolation( args, &arg1Ptr, &arg2Ptr );
// Default to 1, if no argument given
var_uint_t count = (var_uint_t)numToInt( arg1Ptr );
if ( count == 0 )
count = 1;
// Set the macro step counter, negative int's are cast to uint
macroStepCounter = count;
}
void cliFunc_connectIdl( char* args )
{
// Parse number from argument
// NOTE: Only first argument is used
char* arg1Ptr;
char* arg2Ptr;
CLI_argumentIsolation( args, &arg1Ptr, &arg2Ptr );
print( NL );
info_msg("Sending Sync Idles...");
uint8_t count = numToInt( &arg1Ptr[0] );
// Default to 2 idles
if ( count == 0 )
count = 2;
Connect_send_Idle( count );
}
void cliFunc_ledSet( char* args )
{
print( NL ); // No \r\n by default after the command is entered
char* curArgs;
char* arg1Ptr;
char* arg2Ptr = args;
// Process speed argument if given
curArgs = arg2Ptr;
CLI_argumentIsolation( curArgs, &arg1Ptr, &arg2Ptr );
// Reset brightness
if ( *arg1Ptr == '\0' )
{
LED_brightness = ISSI_Global_Brightness_define;
}
else
{
LED_brightness = numToInt( arg1Ptr );
}
info_msg("LED Brightness Set");
#if ISSI_Chip_31FL3733_define || ISSI_Chip_31FL3732_define
// Update brightness
for ( uint8_t ch = 0; ch < ISSI_Chips_define; ch++ )
{
uint8_t addr = LED_ChannelMapping[ ch ].addr;
uint8_t bus = LED_ChannelMapping[ ch ].bus;
#if ISSI_Chip_31FL3733_define == 1
LED_writeReg( bus, addr, 0x01, LED_brightness, ISSI_ConfigPage );
#elif ISSI_Chip_31FL3732_define == 1
LED_writeReg( bus, addr, 0x04, LED_brightness, ISSI_ConfigPage );
#elif ISSI_Chip_31FL3731_define == 1
// XXX (HaaTa) - This is emulated, see LED_scan and LED_linkedSend for implementation
#endif
}
#endif
}
void cliFunc_ledPage( char* args )
{
// Parse number from argument
// NOTE: Only first argument is used
char* arg1Ptr;
char* arg2Ptr;
CLI_argumentIsolation( args, &arg1Ptr, &arg2Ptr );
// Default to 0 if no argument is given
uint8_t page = 0;
if ( arg1Ptr[0] != '\0' )
{
page = (uint8_t)numToInt( arg1Ptr );
}
// No \r\n by default after the command is entered
print( NL );
LED_readPage( 0xB4, page );
}
void cliFunc_setKeys( char* args )
{
char* curArgs;
char* arg1Ptr;
char* arg2Ptr = args;
// Parse up to USBKeys_MaxSize args (whichever is least)
for ( USBKeys_SentCLI = 0; USBKeys_SentCLI < USB_BOOT_MAX_KEYS; ++USBKeys_SentCLI )
{
curArgs = arg2Ptr;
CLI_argumentIsolation( curArgs, &arg1Ptr, &arg2Ptr );
// Stop processing args if no more are found
if ( *arg1Ptr == '\0' )
break;
// Add the USB code to be sent
// TODO
//USBKeys_KeysCLI[USBKeys_SentCLI] = numToInt( arg1Ptr );
}
}
// XXX Just an example command showing how to parse arguments (more complex than generally needed)
void cliFunc_echo( char* args )
{
char* curArgs;
char* arg1Ptr;
char* arg2Ptr = args;
// Parse args until a \0 is found
while ( 1 )
{
print( NL ); // No \r\n by default after the command is entered
curArgs = arg2Ptr; // Use the previous 2nd arg pointer to separate the next arg from the list
CLI_argumentIsolation( curArgs, &arg1Ptr, &arg2Ptr );
// Stop processing args if no more are found
if ( *arg1Ptr == '\0' )
break;
// Print out the arg
dPrint( arg1Ptr );
}
}
void cliFunc_ledFPS( char* args )
{
print( NL ); // No \r\n by default after the command is entered
char* curArgs;
char* arg1Ptr;
char* arg2Ptr = args;
// Process speed argument if given
curArgs = arg2Ptr;
CLI_argumentIsolation( curArgs, &arg1Ptr, &arg2Ptr );
// Just toggling FPS display
if ( *arg1Ptr == '\0' )
{
info_msg("FPS Toggle");
LED_displayFPS = !LED_displayFPS;
return;
}
// Check if f argument was given
switch ( *arg1Ptr )
{
case 'r': // Reset framerate
case 'R':
LED_framerate = ISSI_FrameRate_ms_define;
break;
default: // Convert to a number
LED_framerate = numToInt( arg1Ptr );
break;
}
// Show result
info_msg("Setting framerate to: ");
printInt32( LED_framerate );
print("ms");
}
void cliFunc_idle( char* args )
{
print( NL );
// Parse number from argument
// NOTE: Only first argument is used
char* arg1Ptr;
char* arg2Ptr;
CLI_argumentIsolation( args, &arg1Ptr, &arg2Ptr );
// Set Idle count
if ( arg1Ptr[0] != '\0' )
{
uint8_t idle = (uint8_t)numToInt( arg1Ptr );
USBKeys_Idle_Config = idle;
}
// Show Idle count
info_msg("USB Idle Config: ");
printInt16( 4 * USBKeys_Idle_Config );
print(" ms - ");
printInt8( USBKeys_Idle_Config );
}
void cliFunc_macroDebug( char* args )
{
// Parse number from argument
// NOTE: Only first argument is used
char* arg1Ptr;
char* arg2Ptr;
CLI_argumentIsolation( args, &arg1Ptr, &arg2Ptr );
// Set the macro debug flag depending on the argument
switch ( arg1Ptr[0] )
{
// 3 as argument
case '3':
macroDebugMode = macroDebugMode != 3 ? 3 : 0;
break;
// 2 as argument
case '2':
macroDebugMode = macroDebugMode != 2 ? 2 : 0;
break;
// No argument
case '1':
case '\0':
macroDebugMode = macroDebugMode != 1 ? 1 : 0;
break;
// Invalid argument
default:
return;
}
print( NL );
info_msg("Macro Debug Mode: ");
printInt8( macroDebugMode );
}
void cliFunc_capSelect( char* args )
{
// Parse code from argument
char* curArgs;
char* arg1Ptr;
char* arg2Ptr = args;
// Total number of args to scan (must do a lookup if a keyboard capability is selected)
var_uint_t totalArgs = 2; // Always at least two args
var_uint_t cap = 0;
// Arguments used for keyboard capability function
var_uint_t argSetCount = 0;
uint8_t *argSet = (uint8_t*)args;
// Process all args
for ( var_uint_t c = 0; argSetCount < totalArgs; c++ )
{
curArgs = arg2Ptr;
CLI_argumentIsolation( curArgs, &arg1Ptr, &arg2Ptr );
// Stop processing args if no more are found
// Extra arguments are ignored
if ( *arg1Ptr == '\0' )
break;
// For the first argument, choose the capability
if ( c == 0 ) switch ( arg1Ptr[0] )
{
// Keyboard Capability
case 'K':
// Determine capability index
cap = numToInt( &arg1Ptr[1] );
// Lookup the number of args
totalArgs += CapabilitiesList[ cap ].argCount;
continue;
}
// Because allocating memory isn't doable, and the argument count is arbitrary
// The argument pointer is repurposed as the argument list (much smaller anyways)
argSet[ argSetCount++ ] = (uint8_t)numToInt( arg1Ptr );
// Once all the arguments are prepared, call the keyboard capability function
if ( argSetCount == totalArgs )
{
// Indicate that the capability was called
print( NL );
info_msg("K");
printInt8( cap );
print(" - ");
printHex( argSet[0] );
print(" - ");
printHex( argSet[1] );
print(" - ");
printHex( argSet[2] );
print( "..." NL );
// Make sure this isn't the reload capability
// If it is, and the remote reflash define is not set, ignore
if ( flashModeEnabled_define == 0 ) for ( uint32_t cap = 0; cap < CapabilitiesNum; cap++ )
{
if ( CapabilitiesList[ cap ].func == (const void*)Output_flashMode_capability )
{
print( NL );
warn_print("flashModeEnabled not set, cancelling firmware reload...");
info_msg("Set flashModeEnabled to 1 in your kll configuration.");
return;
}
}
void (*capability)(TriggerMacro*, uint8_t, uint8_t, uint8_t*) = \
(void(*)(TriggerMacro*, uint8_t, uint8_t, uint8_t*))(CapabilitiesList[ cap ].func);
capability( 0, argSet[0], argSet[1], &argSet[2] );
}
}
}
