Mercurial > louis > kiibohd-controller
view Macro/PartialMap/kll.h @ 341:66eccdd9ced5
Code cleanup
- Changing header file ifndef define to pragma once's
- Removed duplicate output_com.h's
| author | Jacob Alexander <haata@kiibohd.com> |
|---|---|
| date | Sun, 14 Jun 2015 13:56:56 -0700 |
| parents | 9afed592bcb5 |
| children | 0f7a6b593dc4 |
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/* Copyright (C) 2014-2015 by Jacob Alexander * * 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. * * 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. * * You should have received a copy of the GNU General Public License * along with this file. If not, see <http://www.gnu.org/licenses/>. */ #pragma once // ----- Includes ----- // KLL Generated Defines #include <kll_defs.h> // Project Includes #include <print.h> #include <scan_loop.h> #include <macro.h> #include <output_com.h> // USB HID Keymap list #include <usb_hid.h> // ----- Types ----- // - NOTE - // It is possible to change the maximum state and indexing positions of the state machine. // This usually affects the SRAM usage quite a bit, so it can be used to fit the code on smaller uCs // Or to allow for nearly infinite states. #if StateWordSize_define == 32 typedef uint32_t var_uint_t; #elif StateWordSize_define == 16 typedef uint16_t var_uint_t; #elif StateWordSize_define == 8 typedef uint8_t var_uint_t; #else #error "Invalid StateWordSize, possible values: 32, 16 and 8." #endif // - NOTE - // Native pointer length // This needs to be defined per microcontroller // e.g. mk20s -> 32 bit // atmega -> 16 bit #if defined(_mk20dx128_) || defined(_mk20dx128vlf5_) || defined(_mk20dx256_) || defined(_mk20dx256vlh7_) // ARM typedef uint32_t nat_ptr_t; #elif defined(_at90usb162_) || defined(_atmega32u4_) || defined(_at90usb646_) || defined(_at90usb1286_) // AVR typedef uint16_t nat_ptr_t; #endif // ----- Structs ----- // -- Result Macro // Defines the sequence of combinations to as the Result of Trigger Macro // For RAM optimization reasons, ResultMacro has been split into ResultMacro and ResultMacroRecord structures // // Capability + args per USB send // Default Args (always sent): key state/analog of last key // Combo Length of 0 signifies end of sequence // // ResultMacro.guide -> [<combo length>|<capability index>|<arg1>|<argn>|<capability index>|...|<combo length>|...|0] // // ResultMacroRecord.pos -> <current combo position> // ResultMacroRecord.state -> <last key state> // ResultMacroRecord.stateType -> <last key state type> // ResultMacro struct, one is created per ResultMacro, no duplicates typedef struct ResultMacro { const uint8_t *guide; } ResultMacro; typedef struct ResultMacroRecord { var_uint_t pos; uint8_t state; uint8_t stateType; } ResultMacroRecord; // Guide, key element #define ResultGuideSize( guidePtr ) sizeof( ResultGuide ) - 1 + CapabilitiesList[ (guidePtr)->index ].argCount typedef struct ResultGuide { uint8_t index; uint8_t args; // This is used as an array pointer (but for packing purposes, must be 8 bit) } ResultGuide; // -- Trigger Macro // Defines the sequence of combinations to Trigger a Result Macro // For RAM optimization reasons TriggerMacro has been split into TriggerMacro and TriggerMacroRecord // Key Types: // * 0x00 Normal (Press/Hold/Release) // * 0x01 LED State (On/Off) // * 0x02 Analog (Threshold) // * 0x03-0xFE Reserved // * 0xFF Debug State // // Key State: // * Off - 0x00 (all flag states) // * On - 0x01 // * Press/Hold/Release - 0x01/0x02/0x03 // * Threshold (Range) - 0x01 (Released), 0x10 (Light press), 0xFF (Max press) // * Debug - 0xFF (Print capability name) // // Combo Length of 0 signifies end of sequence // // TriggerMacro.guide -> [<combo length>|<key1 type>|<key1 state>|<key1>...<keyn type>|<keyn state>|<keyn>|<combo length>...|0] // TriggerMacro.result -> <index to result macro> // // TriggerMacroRecord.pos -> <current combo position> // TriggerMacroRecord.state -> <status of the macro pos> // TriggerMacro states typedef enum TriggerMacroState { TriggerMacro_Press, // Combo in sequence is passing TriggerMacro_Release, // Move to next combo in sequence (or finish if at end of sequence) TriggerMacro_Waiting, // Awaiting user input } TriggerMacroState; // TriggerMacro struct, one is created per TriggerMacro, no duplicates typedef struct TriggerMacro { const uint8_t *guide; const var_uint_t result; } TriggerMacro; typedef struct TriggerMacroRecord { var_uint_t pos; TriggerMacroState state; } TriggerMacroRecord; // Guide, key element #define TriggerGuideSize sizeof( TriggerGuide ) typedef struct TriggerGuide { uint8_t type; uint8_t state; uint8_t scanCode; } TriggerGuide; // ----- Capabilities ----- // Capability typedef struct Capability { const void *func; const uint8_t argCount; } Capability; // Total Number of Capabilities #define CapabilitiesNum sizeof( CapabilitiesList ) / sizeof( Capability ) // -- Result Macros // Guide_RM / Define_RM Pair // Guide_RM( index ) = result; // * index - Result Macro index number // * result - Result Macro guide (see ResultMacro) // Define_RM( index ); // * index - Result Macro index number // Must be used after Guide_RM #define Guide_RM( index ) const uint8_t rm##index##_guide[] #define Define_RM( index ) { rm##index##_guide } // -- Result Macro List // Total number of result macros (rm's) // Used to create pending rm's table #define ResultMacroNum sizeof( ResultMacroList ) / sizeof( ResultMacro ) // -- Trigger Macros // Guide_TM / Define_TM Trigger Setup // Guide_TM( index ) = trigger; // * index - Trigger Macro index number // * trigger - Trigger Macro guide (see TriggerMacro) // Define_TM( index, result ); // * index - Trigger Macro index number // * result - Result Macro index number which is triggered by this Trigger Macro #define Guide_TM( index ) const uint8_t tm##index##_guide[] #define Define_TM( index, result ) { tm##index##_guide, result } // -- Trigger Macro List // Total number of trigger macros (tm's) // Used to create pending tm's table #define TriggerMacroNum sizeof( TriggerMacroList ) / sizeof( TriggerMacro ) // ----- Trigger Maps ----- // Define_TL( layer, scanCode ) = triggerList; // * layer - basename of the layer // * scanCode - Hex value of the scanCode // * triggerList - Trigger List (see Trigger Lists) #define Define_TL( layer, scanCode ) const nat_ptr_t layer##_tl_##scanCode[] // ----- Layer Index ----- // Defines each map of trigger macro lists // Layer 0 is always the default map // Layer States: // * Off - 0x00 // * Shift - 0x01 // * Latch - 0x02 // * Lock - 0x04 // Layer states are stored in the LayerState array // // Except for Off, all states an exist simultaneously for each layer // For example: // state -> 0x04 + 0x01 = 0x05 (Shift + Lock), which is effectively Off (0x00) // // First defines the first used scan code (most keyboards start at 0, some start higher e.g. 0x40) // - Compiler calculates this // // Last defines the last scan code used (helps reduce RAM usage) // // The name is defined for cli debugging purposes (Null terminated string) typedef struct Layer { const nat_ptr_t **triggerMap; const char *name; const uint8_t first; const uint8_t last; } Layer; // Layer_IN( map, name, first ); // * map - Trigger map // * name - Name of the trigger map // * first - First scan code used (most keyboards start at 0, some start higher e.g. 0x40) #define Layer_IN( map, name, first ) { map, name, first, sizeof( map ) / sizeof( nat_ptr_t ) - 1 + first } // Total number of layers #define LayerNum sizeof( LayerIndex ) / sizeof( Layer )