/* Copyright (C) 2014 by Jacob Alexander
*
- * Permission is hereby granted, free of charge, to any person obtaining a copy
- * of this software and associated documentation files (the "Software"), to deal
- * in the Software without restriction, including without limitation the rights
- * to use, copy, modify, merge, publish, distribute, sublicense, and/or sell
- * copies of the Software, and to permit persons to whom the Software is
- * furnished to do so, subject to the following conditions:
+ * This file is free software: you can redistribute it and/or modify
+ * it under the terms of the GNU General Public License as published by
+ * the Free Software Foundation, either version 3 of the License, or
+ * (at your option) any later version.
*
- * The above copyright notice and this permission notice shall be included in
- * all copies or substantial portions of the Software.
+ * This file is distributed in the hope that it will be useful,
+ * but WITHOUT ANY WARRANTY; without even the implied warranty of
+ * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
+ * GNU General Public License for more details.
*
- * THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, EXPRESS OR
- * IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF MERCHANTABILITY,
- * FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT. IN NO EVENT SHALL THE
- * AUTHORS OR COPYRIGHT HOLDERS BE LIABLE FOR ANY CLAIM, DAMAGES OR OTHER
- * LIABILITY, WHETHER IN AN ACTION OF CONTRACT, TORT OR OTHERWISE, ARISING FROM,
- * OUT OF OR IN CONNECTION WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS IN
- * THE SOFTWARE.
+ * You should have received a copy of the GNU General Public License
+ * along with this file. If not, see <http://www.gnu.org/licenses/>.
*/
// ----- Includes -----
// Keymaps
#include "usb_hid.h"
#include <defaultMap.h>
+#include "generatedKeymap.h" // TODO Use actual generated version
// Local Includes
#include "macro.h"
// ----- Function Declarations -----
-void cliFunc_capList ( char* args );
-void cliFunc_capSelect ( char* args );
-void cliFunc_lookComb ( char* args );
-void cliFunc_lookDefault( char* args );
-void cliFunc_lookPartial( char* args );
-void cliFunc_macroDebug ( char* args );
+void cliFunc_capList ( char* args );
+void cliFunc_capSelect ( char* args );
+void cliFunc_keyPress ( char* args );
+void cliFunc_keyRelease( char* args );
+void cliFunc_layerList ( char* args );
+void cliFunc_layerState( char* args );
+void cliFunc_macroDebug( char* args );
+void cliFunc_macroList ( char* args );
+void cliFunc_macroProc ( char* args );
+void cliFunc_macroShow ( char* args );
+void cliFunc_macroStep ( char* args );
// ----- Variables -----
// Macro Module command dictionary
-char* macroCLIDictName = "Macro Module Commands (Not all commands fully work yet...)";
+char* macroCLIDictName = "Macro Module Commands";
CLIDictItem macroCLIDict[] = {
{ "capList", "Prints an indexed list of all non USB keycode capabilities.", cliFunc_capList },
- { "capSelect", "Triggers the specified capability. U10 - USB Code 0x0A. K11 - Keyboard Capability 0x0B. S10 - Scancode 0x0A", cliFunc_capSelect },
- { "lookComb", "Do a lookup on the Combined map. S10 - Scancode 0x0A. U10 - USB Code 0x0A.", cliFunc_lookComb },
- { "lookDefault", "Do a lookup on the Default map. S10 - Scancode 0x0A.", cliFunc_lookDefault },
- { "lookPartial", "Do a lookup on the layered Partial maps. S10 - Scancode 0x0A. U10 - USB Code 0x0A.", cliFunc_lookPartial },
+ { "capSelect", "Triggers the specified capabilities. First two args are state and stateType." NL "\t\t\033[35mK11\033[0m Keyboard Capability 0x0B", cliFunc_capSelect },
+ { "keyPress", "Send key-presses to the macro module. Held until released. Duplicates have undefined behaviour." NL "\t\t\033[35mS10\033[0m Scancode 0x0A", cliFunc_keyPress },
+ { "keyRelease", "Release a key-press from the macro module. Duplicates have undefined behaviour." NL "\t\t\033[35mS10\033[0m Scancode 0x0A", cliFunc_keyRelease },
+ { "layerList", "List available layers.", cliFunc_layerList },
+ { "layerState", "Modify specified indexed layer state <layer> <state byte>." NL "\t\t\033[35mL2\033[0m Indexed Layer 0x02" NL "\t\t0 Off, 1 Shift, 2 Latch, 4 Lock States", cliFunc_layerState },
{ "macroDebug", "Disables/Enables sending USB keycodes to the Output Module and prints U/K codes.", cliFunc_macroDebug },
+ { "macroList", "List the defined trigger and result macros.", cliFunc_macroList },
+ { "macroProc", "Pause/Resume macro processing.", cliFunc_macroProc },
+ { "macroShow", "Show the macro corresponding to the given index." NL "\t\t\033[35mT16\033[0m Indexed Trigger Macro 0x10, \033[35mR12\033[0m Indexed Result Macro 0x0C", cliFunc_macroShow },
+ { "macroStep", "Do N macro processing steps. Defaults to 1.", cliFunc_macroStep },
{ 0, 0, 0 } // Null entry for dictionary end
};
// Macro debug flag - If set, clears the USB Buffers after signalling processing completion
uint8_t macroDebugMode = 0;
+// Macro pause flag - If set, the macro module pauses processing, unless unset, or the step counter is non-zero
+uint8_t macroPauseMode = 0;
+
+// Macro step counter - If non-zero, the step counter counts down every time the macro module does one processing loop
+unsigned int macroStepCounter = 0;
+
+
+// Key Trigger List Buffer
+TriggerGuide macroTriggerListBuffer[ MaxScanCode ];
+uint8_t macroTriggerListBufferSize = 0;
+
+// Pending Trigger Macro Index List
+// * Any trigger macros that need processing from a previous macro processing loop
+// TODO, figure out a good way to scale this array size without wasting too much memory, but not rejecting macros
+// Possibly could be calculated by the KLL compiler
+// XXX It may be possible to calculate the worst case using the KLL compiler
+unsigned int macroTriggerMacroPendingList[ TriggerMacroNum ] = { 0 };
+unsigned int macroTriggerMacroPendingListSize = 0;
+
+// Layer Index Stack
+// * When modifying layer state and the state is non-0x0, the stack must be adjusted
+unsigned int macroLayerIndexStack[ LayerNum ] = { 0 };
+unsigned int macroLayerIndexStackSize = 0;
+
+// Pending Result Macro Index List
+// * Any result macro that needs processing from a previous macro processing loop
+unsigned int macroResultMacroPendingList[ ResultMacroNum ] = { 0 };
+unsigned int macroResultMacroPendingListSize = 0;
+
// ----- Functions -----
-inline void Macro_bufferAdd( uint8_t byte )
+// Looks up the trigger list for the given scan code (from the active layer)
+// NOTE: Calling function must handle the NULL pointer case
+unsigned int *Macro_layerLookup( uint8_t scanCode )
+{
+ // If no trigger macro is defined at the given layer, fallthrough to the next layer
+ for ( unsigned int layer = 0; layer < macroLayerIndexStackSize; layer++ )
+ {
+ // Lookup layer
+ unsigned int **map = LayerIndex[ macroLayerIndexStack[ layer ] ].triggerMap;
+
+ // Determine if layer has key defined
+ if ( map != 0 && *map[ scanCode ] != 0 )
+ return map[ scanCode ];
+ }
+
+ // Do lookup on default layer
+ unsigned int **map = LayerIndex[0].triggerMap;
+
+ // Determine if layer has key defined
+ if ( map == 0 && *map[ scanCode ] == 0 )
+ {
+ erro_msg("Scan Code has no defined Trigger Macro: ");
+ printHex( scanCode );
+ return 0;
+ }
+
+ // Return lookup result
+ return map[ scanCode ];
+}
+
+
+// Update the scancode key state
+// States:
+// * 0x00 - Off
+// * 0x01 - Pressed
+// * 0x02 - Held
+// * 0x03 - Released
+// * 0x04 - Unpressed (this is currently ignored)
+inline void Macro_keyState( uint8_t scanCode, uint8_t state )
+{
+ // Only add to macro trigger list if one of three states
+ switch ( state )
+ {
+ case 0x01: // Pressed
+ case 0x02: // Held
+ case 0x03: // Released
+ macroTriggerListBuffer[ macroTriggerListBufferSize ].scanCode = scanCode;
+ macroTriggerListBuffer[ macroTriggerListBufferSize ].state = state;
+ macroTriggerListBuffer[ macroTriggerListBufferSize ].type = 0x00; // Normal key
+ macroTriggerListBufferSize++;
+ break;
+ }
+}
+
+
+// Update the scancode analog state
+// States:
+// * 0x00 - Off
+// * 0x01 - Released
+// * 0x02-0xFF - Analog value (low to high)
+inline void Macro_analogState( uint8_t scanCode, uint8_t state )
{
- // Make sure we haven't overflowed the key buffer
- // Default function for adding keys to the KeyIndex_Buffer, does a DefaultMap_Lookup
- if ( KeyIndex_BufferUsed < KEYBOARD_BUFFER )
+ // Only add to macro trigger list if non-off
+ if ( state != 0x00 )
{
- KeyIndex_Buffer[KeyIndex_BufferUsed++] = DefaultMap_Lookup[byte];
+ macroTriggerListBuffer[ macroTriggerListBufferSize ].scanCode = scanCode;
+ macroTriggerListBuffer[ macroTriggerListBufferSize ].state = state;
+ macroTriggerListBuffer[ macroTriggerListBufferSize ].type = 0x02; // Analog key
+ macroTriggerListBufferSize++;
}
}
+
+// Update led state
+// States:
+// * 0x00 - Off
+// * 0x01 - On
+inline void Macro_ledState( uint8_t ledCode, uint8_t state )
+{
+ // Only add to macro trigger list if non-off
+ if ( state != 0x00 )
+ {
+ macroTriggerListBuffer[ macroTriggerListBufferSize ].scanCode = ledCode;
+ macroTriggerListBuffer[ macroTriggerListBufferSize ].state = state;
+ macroTriggerListBuffer[ macroTriggerListBufferSize ].type = 0x01; // LED key
+ macroTriggerListBufferSize++;
+ }
+}
+
+
+// Evaluate/Update TriggerMacro
+void Macro_evalTriggerMacro( TriggerMacro *triggerMacro )
+{
+ // Which combo in the sequence is being evaluated
+ unsigned int comboPos = triggerMacro->pos;
+
+ // If combo length is more than 1, cancel trigger macro if an incorrect key is found
+ uint8_t comboLength = triggerMacro->guide[ comboPos ];
+
+ // Iterate over list of keys currently pressed
+ for ( uint8_t keyPressed = 0; keyPressed < macroTriggerListBufferSize; keyPressed++ )
+ {
+ // Compare with keys in combo
+ for ( unsigned int comboKey = 0; comboKey < comboLength; comboKey++ )
+ {
+ // Lookup key in combo
+ uint8_t guideKey = triggerMacro->guide[ comboPos + comboKey + 2 ]; // TODO Only Press/Hold/Release atm
+
+ // Sequence Case
+ if ( comboLength == 1 )
+ {
+ // If key matches and only 1 key pressed, increment the TriggerMacro combo position
+ if ( guideKey == macroTriggerListBuffer[ keyPressed ].scanCode && macroTriggerListBufferSize == 1 )
+ {
+ triggerMacro->pos += comboLength * 2 + 1;
+ // TODO check if TriggerMacro is finished, register ResultMacro
+ return;
+ }
+
+ // If key does not match or more than 1 key pressed, reset the TriggerMacro combo position
+ triggerMacro->pos = 0;
+ return;
+ }
+ // Combo Case
+ else
+ {
+ // TODO
+ }
+ }
+ }
+}
+
+
+// Evaluate/Update ResultMacro
+void Macro_evalResultMacro( ResultMacro *resultMacro )
+{
+ // TODO
+}
+
+
+// Called immediately after USB has finished sending a buffer
inline void Macro_finishWithUSBBuffer( uint8_t sentKeys )
{
+ // XXX Currently not used to trigger anything (with this particular Macro module)
}
+
+// Macro Procesing Loop
+// Called once per USB buffer send
inline void Macro_process()
{
// Only do one round of macro processing between Output Module timer sends
if ( USBKeys_Sent != 0 )
return;
+ // If the pause flag is set, only process if the step counter is non-zero
+ if ( macroPauseMode && macroStepCounter == 0 )
+ {
+ return;
+ }
+ // Proceed, decrementing the step counter
+ else
+ {
+ macroStepCounter--;
+ }
+
+ // Loop through macro trigger buffer
+ for ( uint8_t index = 0; index < macroTriggerListBufferSize; index++ )
+ {
+ // Get scanCode, first item of macroTriggerListBuffer pairs
+ uint8_t scanCode = macroTriggerListBuffer[ index ].scanCode;
+
+ // Lookup trigger list for this key
+ unsigned int *triggerList = Macro_layerLookup( scanCode );
+
+ // Skip, if no trigger list
+ if ( triggerList == 0 )
+ continue;
+
+ // The first element is the length of the trigger list
+ unsigned int triggerListSize = triggerList[0];
+
+ // Loop through the trigger list
+ for ( unsigned int trigger = 0; trigger < triggerListSize; trigger++ )
+ {
+ // Lookup TriggerMacro
+ TriggerMacro *triggerMacro = (TriggerMacro*)triggerList[ trigger + 1 ];
+
+ // Get triggered state of scan code, second item of macroTriggerListBuffer pairs
+ uint8_t state = macroTriggerListBuffer[ index ].state;
+
+ // Evaluate Macro
+ Macro_evalTriggerMacro( triggerMacro );
+ }
+ }
+
+
+
+
+
+ /* TODO
// Loop through input buffer
- for ( uint8_t index = 0; index < KeyIndex_BufferUsed; index++ )
+ for ( uint8_t index = 0; index < KeyIndex_BufferUsed && !macroDebugMode; index++ )
{
+ //print(" KEYS: ");
+ //printInt8( KeyIndex_BufferUsed );
// Get the keycode from the buffer
uint8_t key = KeyIndex_Buffer[index];
// Set the modifier bit if this key is a modifier
- if ( key & KEY_LCTRL ) // AND with 0xE0
+ if ( (key & KEY_LCTRL) == KEY_LCTRL ) // AND with 0xE0
{
USBKeys_Modifiers |= 1 << (key ^ KEY_LCTRL); // Left shift 1 by key XOR 0xE0
errorLED( 1 );
}
}
+ */
// Signal buffer that we've used it
Scan_finishedWithBuffer( KeyIndex_BufferUsed );
}
}
+
inline void Macro_setup()
{
// Register Macro CLI dictionary
// Disable Macro debug mode
macroDebugMode = 0;
+
+ // Disable Macro pause flag
+ macroPauseMode = 0;
+
+ // Set Macro step counter to zero
+ macroStepCounter = 0;
+
+ // Make sure macro trigger buffer is empty
+ macroTriggerListBufferSize = 0;
}
void cliFunc_capList( char* args )
{
- // TODO
+ print( NL );
+ info_msg("Capabilities List");
+
+ // Iterate through all of the capabilities and display them
+ for ( unsigned int cap = 0; cap < CapabilitiesNum; cap++ )
+ {
+ print( NL "\t" );
+ printHex( cap );
+ print(" - ");
+
+ // Display/Lookup Capability Name (utilize debug mode of capability)
+ void (*capability)(uint8_t, uint8_t, uint8_t*) = (void(*)(uint8_t, uint8_t, uint8_t*))(CapabilitiesList[ cap ].func);
+ capability( 0xFF, 0xFF, 0 );
+ }
}
void cliFunc_capSelect( char* args )
{
// Parse code from argument
- // NOTE: Only first argument is used
+ char* curArgs;
char* arg1Ptr;
- char* arg2Ptr;
- CLI_argumentIsolation( args, &arg1Ptr, &arg2Ptr );
+ char* arg2Ptr = args;
+
+ // Total number of args to scan (must do a lookup if a keyboard capability is selected)
+ unsigned int totalArgs = 2; // Always at least two args
+ unsigned int cap = 0;
- // Depending on the first character, the lookup changes
- switch ( arg1Ptr[0] )
+ // Arguments used for keyboard capability function
+ unsigned int argSetCount = 0;
+ uint8_t *argSet = (uint8_t*)args;
+
+ // Process all args
+ for ( unsigned int c = 0; argSetCount < totalArgs; c++ )
{
- // Keyboard Capability
- case 'K':
- // TODO
- break;
+ curArgs = arg2Ptr;
+ CLI_argumentIsolation( curArgs, &arg1Ptr, &arg2Ptr );
- // Scancode
- case 'S':
- // Add to the USB Buffer using the DefaultMap lookup
- Macro_bufferAdd( decToInt( &arg1Ptr[1] ) );
- break;
+ // 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 = decToInt( &arg1Ptr[1] );
+
+ // Lookup the number of args
+ totalArgs += CapabilitiesList[ cap ].argCount;
+ continue;
+ }
- // USB Code
- case 'U':
- // Just add the key to the USB Buffer
- if ( KeyIndex_BufferUsed < KEYBOARD_BUFFER )
+ // 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)decToInt( arg1Ptr );
+
+ // Once all the arguments are prepared, call the keyboard capability function
+ if ( argSetCount == totalArgs )
{
- KeyIndex_Buffer[KeyIndex_BufferUsed++] = decToInt( &arg1Ptr[1] );
+ // 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 );
+
+ void (*capability)(uint8_t, uint8_t, uint8_t*) = (void(*)(uint8_t, uint8_t, uint8_t*))(CapabilitiesList[ cap ].func);
+ capability( argSet[0], argSet[1], &argSet[2] );
}
- break;
}
}
-void cliFunc_lookComb( char* args )
+void cliFunc_keyPress( char* args )
{
- // Parse code from argument
- // NOTE: Only first argument is used
+ // Parse codes from arguments
+ char* curArgs;
char* arg1Ptr;
- char* arg2Ptr;
- CLI_argumentIsolation( args, &arg1Ptr, &arg2Ptr );
+ char* arg2Ptr = args;
- // Depending on the first character, the lookup changes
- switch ( arg1Ptr[0] )
+ // Process all args
+ for ( ;; )
{
- // Scancode
- case 'S':
- // TODO
- break;
+ curArgs = arg2Ptr;
+ CLI_argumentIsolation( curArgs, &arg1Ptr, &arg2Ptr );
- // USB Code
- case 'U':
- // TODO
- break;
+ // 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)decToInt( &arg1Ptr[1] ), 0x01 ); // Press scancode
+ break;
+ }
}
}
-void cliFunc_lookDefault( char* args )
+void cliFunc_keyRelease( char* args )
{
- // Parse code from argument
- // NOTE: Only first argument is used
+ // Parse codes from arguments
+ char* curArgs;
char* arg1Ptr;
- char* arg2Ptr;
- CLI_argumentIsolation( args, &arg1Ptr, &arg2Ptr );
+ char* arg2Ptr = args;
- // Depending on the first character, the lookup changes
- switch ( arg1Ptr[0] )
+ // Process all args
+ for ( ;; )
{
- // Scancode
- case 'S':
- print( NL );
- printInt8( DefaultMap_Lookup[decToInt( &arg1Ptr[1] )] );
- print(" ");
- printHex( DefaultMap_Lookup[decToInt( &arg1Ptr[1] )] );
- break;
+ 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)decToInt( &arg1Ptr[1] ), 0x03 ); // Release scancode
+ break;
+ }
}
}
-void cliFunc_lookPartial( char* args )
+void cliFunc_layerList( char* args )
{
- // Parse code from argument
- // NOTE: Only first argument is used
+ print( NL );
+ info_msg("Layer List");
+
+ // Iterate through all of the layers and display them
+ for ( unsigned int layer = 0; layer < LayerNum; layer++ )
+ {
+ print( NL "\t" );
+ printHex( layer );
+ print(" - ");
+
+ // Display layer name
+ dPrint( LayerIndex[ layer ].name );
+
+ // Default map
+ if ( layer == 0 )
+ print(" \033[1m(default)\033[0m");
+
+ // Layer State
+ print( NL "\t\t Layer State: " );
+ printHex( LayerIndex[ layer ].state );
+
+ // Max Index
+ print(" Max Index: ");
+ printHex( LayerIndex[ layer ].max );
+ }
+}
+
+void cliFunc_layerState( char* args )
+{
+ // Parse codes from arguments
+ char* curArgs;
char* arg1Ptr;
- char* arg2Ptr;
- CLI_argumentIsolation( args, &arg1Ptr, &arg2Ptr );
+ char* arg2Ptr = args;
+
+ uint8_t arg1 = 0;
+ uint8_t arg2 = 0;
- // Depending on the first character, the lookup changes
- switch ( arg1Ptr[0] )
+ // Process first two args
+ for ( uint8_t c = 0; c < 2; c++ )
{
- // Scancode
- case 'S':
- // TODO
- break;
+ curArgs = arg2Ptr;
+ CLI_argumentIsolation( curArgs, &arg1Ptr, &arg2Ptr );
- // USB Code
- case 'U':
- // TODO
- break;
+ // 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)decToInt( &arg1Ptr[1] );
+ break;
+ // Second argument (e.g. 4)
+ case 1:
+ arg2 = (uint8_t)decToInt( 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
+ LayerIndex[ arg1 ].state = arg2;
+ break;
+ }
}
}
printInt8( macroDebugMode );
}
+void cliFunc_macroList( char* args )
+{
+ // Show available trigger macro indices
+ print( NL );
+ info_msg("Trigger Macros Range: T0 -> T");
+ printInt16( (uint16_t)TriggerMacroNum - 1 ); // Hopefully large enough :P (can't assume 32-bit)
+
+ // Show available result macro indices
+ print( NL );
+ info_msg("Result Macros Range: R0 -> R");
+ printInt16( (uint16_t)ResultMacroNum - 1 ); // Hopefully large enough :P (can't assume 32-bit)
+
+ // Show Trigger to Result Macro Links
+ print( NL );
+ info_msg("Trigger : Result Macro Pairs");
+ for ( unsigned int macro = 0; macro < TriggerMacroNum; macro++ )
+ {
+ print( NL );
+ print("\tT");
+ printInt16( (uint16_t)macro ); // Hopefully large enough :P (can't assume 32-bit)
+ print(" : R");
+ printInt16( (uint16_t)TriggerMacroList[ macro ].result ); // Hopefully large enough :P (can't assume 32-bit)
+ }
+}
+
+void cliFunc_macroProc( char* args )
+{
+ // Toggle macro pause mode
+ macroPauseMode = macroPauseMode ? 0 : 1;
+
+ print( NL );
+ info_msg("Macro Processing Mode: ");
+ printInt8( macroPauseMode );
+}
+
+void macroDebugShowTrigger( unsigned int index )
+{
+ // Only proceed if the macro exists
+ if ( index >= TriggerMacroNum )
+ return;
+
+ // Trigger Macro Show
+ TriggerMacro *macro = &TriggerMacroList[ index ];
+
+ print( NL );
+ info_msg("Trigger Macro Index: ");
+ printInt16( (uint16_t)index ); // Hopefully large enough :P (can't assume 32-bit)
+ print( NL );
+
+ // Read the comboLength for combo in the sequence (sequence of combos)
+ unsigned int pos = 0;
+ uint8_t comboLength = macro->guide[ pos ];
+
+ // Iterate through and interpret the guide
+ while ( comboLength != 0 )
+ {
+ // Initial position of the combo
+ unsigned int comboPos = ++pos;
+
+ // Iterate through the combo
+ while ( pos < comboLength * TriggerGuideSize + comboPos )
+ {
+ // Assign TriggerGuide element (key type, state and scancode)
+ TriggerGuide *guide = (TriggerGuide*)(¯o->guide[ pos ]);
+
+ // Display guide information about trigger key
+ printHex( guide->scanCode );
+ print("|");
+ printHex( guide->type );
+ print("|");
+ printHex( guide->state );
+
+ // Increment position
+ pos += TriggerGuideSize;
+
+ // Only show combo separator if there are combos left in the sequence element
+ if ( pos < comboLength * TriggerGuideSize + comboPos )
+ print("+");
+ }
+
+ // Read the next comboLength
+ comboLength = macro->guide[ pos ];
+
+ // Only show sequence separator if there is another combo to process
+ if ( comboLength != 0 )
+ print(";");
+ }
+
+ // Display current position
+ print( NL "Position: " );
+ printInt16( (uint16_t)macro->pos ); // Hopefully large enough :P (can't assume 32-bit)
+
+ // Display result macro index
+ print( NL "Result Macro Index: " );
+ printInt16( (uint16_t)macro->result ); // Hopefully large enough :P (can't assume 32-bit)
+}
+
+void macroDebugShowResult( unsigned int index )
+{
+ // Only proceed if the macro exists
+ if ( index >= ResultMacroNum )
+ return;
+
+ // Trigger Macro Show
+ ResultMacro *macro = &ResultMacroList[ index ];
+
+ print( NL );
+ info_msg("Result Macro Index: ");
+ printInt16( (uint16_t)index ); // Hopefully large enough :P (can't assume 32-bit)
+ print( NL );
+
+ // Read the comboLength for combo in the sequence (sequence of combos)
+ unsigned int pos = 0;
+ uint8_t comboLength = macro->guide[ pos++ ];
+
+ // Iterate through and interpret the guide
+ while ( comboLength != 0 )
+ {
+ // Function Counter, used to keep track of the combos processed
+ unsigned int funcCount = 0;
+
+ // Iterate through the combo
+ while ( funcCount < comboLength )
+ {
+ // Assign TriggerGuide element (key type, state and scancode)
+ ResultGuide *guide = (ResultGuide*)(¯o->guide[ pos ]);
+
+ // Display Function Index
+ printHex( guide->index );
+ print("|");
+
+ // Display Function Ptr Address
+ printHex( (unsigned int)CapabilitiesList[ guide->index ].func );
+ print("|");
+
+ // Display/Lookup Capability Name (utilize debug mode of capability)
+ void (*capability)(uint8_t, uint8_t, uint8_t*) = (void(*)(uint8_t, uint8_t, uint8_t*))(CapabilitiesList[ guide->index ].func);
+ capability( 0xFF, 0xFF, 0 );
+
+ // Display Argument(s)
+ print("(");
+ for ( unsigned int arg = 0; arg < CapabilitiesList[ guide->index ].argCount; arg++ )
+ {
+ // Arguments are only 8 bit values
+ printHex( (&guide->args)[ arg ] );
+
+ // Only show arg separator if there are args left
+ if ( arg + 1 < CapabilitiesList[ guide->index ].argCount )
+ print(",");
+ }
+ print(")");
+
+ // Increment position
+ pos += ResultGuideSize( guide );
+
+ // Increment function count
+ funcCount++;
+
+ // Only show combo separator if there are combos left in the sequence element
+ if ( funcCount < comboLength )
+ print("+");
+ }
+
+ // Read the next comboLength
+ comboLength = macro->guide[ pos++ ];
+
+ // Only show sequence separator if there is another combo to process
+ if ( comboLength != 0 )
+ print(";");
+ }
+
+ // Display current position
+ print( NL "Position: " );
+ printInt16( (uint16_t)macro->pos ); // Hopefully large enough :P (can't assume 32-bit)
+
+ // Display final trigger state/type
+ print( NL "Final Trigger State (State/Type): " );
+ printHex( macro->state );
+ print("/");
+ printHex( macro->stateType );
+}
+
+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( decToInt( &arg1Ptr[1] ) );
+ break;
+ // Indexed Result Macro
+ case 'R':
+ macroDebugShowResult( decToInt( &arg1Ptr[1] ) );
+ 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 );
+
+ // Set the macro step counter, negative int's are cast to uint
+ macroStepCounter = (unsigned int)decToInt( arg1Ptr );
+}
+