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/* 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 :
*
* The above copyright notice and this permission notice shall be included in
* all copies or substantial portions of the Software .
*
* 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 .
*/
// ----- Includes -----
// Compiler Includes
# include <Lib/ScanLib.h>
// Project Includes
# include <cli.h>
# include <led.h>
# include <print.h>
# include <macro.h>
// Local Includes
# include "matrix_scan.h"
// Matrix Configuration
# include <matrix.h>
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// ----- Function Declarations -----
// CLI Functions
void cliFunc_matrixDebug ( char * args ) ;
void cliFunc_matrixState ( char * args ) ;
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// ----- Variables -----
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// Scan Module command dictionary
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CLIDict_Entry ( matrixDebug , " Enables matrix debug mode, prints out each scan code. " NL " \t \t If argument \033 [35mT \033 [0m is given, prints out each scan code state transition. " ) ;
CLIDict_Entry ( matrixState , " Prints out the current scan table N times. " NL " \t \t \033 [1mO \033 [0m - Off, \033 [1;33mP \033 [0m - Press, \033 [1;32mH \033 [0m - Hold, \033 [1;35mR \033 [0m - Release, \033 [1;31mI \033 [0m - Invalid " ) ;
CLIDict_Def ( matrixCLIDict , " Matrix Module Commands " ) = {
CLIDict_Item ( matrixDebug ) ,
CLIDict_Item ( matrixState ) ,
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{ 0 , 0 , 0 } // Null entry for dictionary end
} ;
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// Debounce Array
KeyState Matrix_scanArray [ Matrix_colsNum * Matrix_rowsNum ] ;
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// Matrix debug flag - If set to 1, for each keypress the scan code is displayed in hex
// If set to 2, for each key state change, the scan code is displayed along with the state
uint8_t matrixDebugMode = 0 ;
// Matrix State Table Debug Counter - If non-zero display state table after every matrix scan
uint16_t matrixDebugStateCounter = 0 ;
// Matrix Scan Counters
uint16_t matrixMaxScans = 0 ;
uint16_t matrixCurScans = 0 ;
uint16_t matrixPrevScans = 0 ;
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// ----- Functions -----
// Pin action (Strobe, Sense, Strobe Setup, Sense Setup)
// NOTE: This function is highly dependent upon the organization of the register map
// Only guaranteed to work with Freescale MK20 series uCs
uint8_t Matrix_pin ( GPIO_Pin gpio , Type type )
{
// Register width is defined as size of a pointer
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unsigned int gpio_offset = gpio . port * 0x40 / sizeof ( unsigned int * ) ;
unsigned int port_offset = gpio . port * 0x1000 / sizeof ( unsigned int * ) + gpio . pin ;
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// Assumes 0x40 between GPIO Port registers and 0x1000 between PORT pin registers
// See Lib/mk20dx.h
volatile unsigned int * GPIO_PDDR = ( unsigned int * ) ( & GPIOA_PDDR ) + gpio_offset ;
volatile unsigned int * GPIO_PSOR = ( unsigned int * ) ( & GPIOA_PSOR ) + gpio_offset ;
volatile unsigned int * GPIO_PCOR = ( unsigned int * ) ( & GPIOA_PCOR ) + gpio_offset ;
volatile unsigned int * GPIO_PDIR = ( unsigned int * ) ( & GPIOA_PDIR ) + gpio_offset ;
volatile unsigned int * PORT_PCR = ( unsigned int * ) ( & PORTA_PCR0 ) + port_offset ;
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// Operation depends on Type
switch ( type )
{
case Type_StrobeOn :
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* GPIO_PSOR | = ( 1 < < gpio . pin ) ;
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break ;
case Type_StrobeOff :
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* GPIO_PCOR | = ( 1 < < gpio . pin ) ;
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break ;
case Type_StrobeSetup :
// Set as output pin
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* GPIO_PDDR | = ( 1 < < gpio . pin ) ;
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// Configure pin with slow slew, high drive strength and GPIO mux
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* PORT_PCR = PORT_PCR_SRE | PORT_PCR_DSE | PORT_PCR_MUX ( 1 ) ;
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// Enabling open-drain if specified
switch ( Matrix_type )
{
case Config_Opendrain :
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* PORT_PCR | = PORT_PCR_ODE ;
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break ;
// Do nothing otherwise
default :
break ;
}
break ;
case Type_Sense :
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return * GPIO_PDIR & ( 1 < < gpio . pin ) ? 1 : 0 ;
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case Type_SenseSetup :
// Set as input pin
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* GPIO_PDDR & = ~ ( 1 < < gpio . pin ) ;
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// Configure pin with passive filter and GPIO mux
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* PORT_PCR = PORT_PCR_PFE | PORT_PCR_MUX ( 1 ) ;
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// Pull resistor config
switch ( Matrix_type )
{
case Config_Pullup :
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* PORT_PCR | = PORT_PCR_PE | PORT_PCR_PS ;
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break ;
case Config_Pulldown :
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* PORT_PCR | = PORT_PCR_PE ;
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break ;
// Do nothing otherwise
default :
break ;
}
break ;
}
return 0 ;
}
// Setup GPIO pins for matrix scanning
void Matrix_setup ( )
{
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// Register Matrix CLI dictionary
CLI_registerDictionary ( matrixCLIDict , matrixCLIDictName ) ;
info_msg ( " Columns: " ) ;
printHex ( Matrix_colsNum ) ;
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// Setup Strobe Pins
for ( uint8_t pin = 0 ; pin < Matrix_colsNum ; pin + + )
{
Matrix_pin ( Matrix_cols [ pin ] , Type_StrobeSetup ) ;
}
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print ( NL ) ;
info_msg ( " Rows: " ) ;
printHex ( Matrix_rowsNum ) ;
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// Setup Sense Pins
for ( uint8_t pin = 0 ; pin < Matrix_rowsNum ; pin + + )
{
Matrix_pin ( Matrix_rows [ pin ] , Type_SenseSetup ) ;
}
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print ( NL ) ;
info_msg ( " Max Keys: " ) ;
printHex ( Matrix_maxKeys ) ;
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// Clear out Debounce Array
for ( uint8_t item = 0 ; item < Matrix_maxKeys ; item + + )
{
Matrix_scanArray [ item ] . prevState = KeyState_Off ;
Matrix_scanArray [ item ] . curState = KeyState_Off ;
Matrix_scanArray [ item ] . activeCount = 0 ;
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Matrix_scanArray [ item ] . inactiveCount = 0xFFFF ; // Start at 'off' steady state
}
// Clear scan stats counters
matrixMaxScans = 0 ;
matrixPrevScans = 0 ;
}
void Matrix_keyPositionDebug ( KeyPosition pos )
{
// Depending on the state, use a different flag + color
switch ( pos )
{
case KeyState_Off :
print ( " \033 [1mO \033 [0m " ) ;
break ;
case KeyState_Press :
print ( " \033 [1;33mP \033 [0m " ) ;
break ;
case KeyState_Hold :
print ( " \033 [1;32mH \033 [0m " ) ;
break ;
case KeyState_Release :
print ( " \033 [1;35mR \033 [0m " ) ;
break ;
case KeyState_Invalid :
default :
print ( " \033 [1;31mI \033 [0m " ) ;
break ;
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}
}
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// Scan the matrix for keypresses
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// NOTE: scanNum should be reset to 0 after a USB send (to reset all the counters)
void Matrix_scan ( uint16_t scanNum )
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{
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// Increment stats counters
if ( scanNum > matrixMaxScans ) matrixMaxScans = scanNum ;
if ( scanNum = = 0 )
{
matrixPrevScans = matrixCurScans ;
matrixCurScans = 0 ;
}
else
{
matrixCurScans + + ;
}
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// For each strobe, scan each of the sense pins
for ( uint8_t strobe = 0 ; strobe < Matrix_colsNum ; strobe + + )
{
// Strobe Pin
Matrix_pin ( Matrix_cols [ strobe ] , Type_StrobeOn ) ;
// Scan each of the sense pins
for ( uint8_t sense = 0 ; sense < Matrix_rowsNum ; sense + + )
{
// Key position
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uint8_t key = Matrix_colsNum * sense + strobe ;
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KeyState * state = & Matrix_scanArray [ key ] ;
// If first scan, reset state
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if ( scanNum = = 0 )
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{
// Set previous state, and reset current state
state - > prevState = state - > curState ;
state - > curState = KeyState_Invalid ;
}
// Signal Detected
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// Increment count and right shift opposing count
// This means there is a maximum of scan 13 cycles on a perfect off to on transition
// (coming from a steady state 0xFFFF off scans)
// Somewhat longer with switch bounciness
// The advantage of this is that the count is ongoing and never needs to be reset
// State still needs to be kept track of to deal with what to send to the Macro module
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if ( Matrix_pin ( Matrix_rows [ sense ] , Type_Sense ) )
{
// Only update if not going to wrap around
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if ( state - > activeCount < 0xFFFF ) state - > activeCount + = 1 ;
state - > inactiveCount > > = 1 ;
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}
// Signal Not Detected
else
{
// Only update if not going to wrap around
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if ( state - > inactiveCount < 0xFFFF ) state - > inactiveCount + = 1 ;
state - > activeCount > > = 1 ;
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}
// Check for state change if it hasn't been set
// Only check if the minimum number of scans has been met
// the current state is invalid
// and either active or inactive count is over the debounce threshold
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if ( state - > curState = = KeyState_Invalid )
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{
switch ( state - > prevState )
{
case KeyState_Press :
case KeyState_Hold :
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if ( state - > activeCount > state - > inactiveCount )
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{
state - > curState = KeyState_Hold ;
}
else
{
state - > curState = KeyState_Release ;
}
break ;
case KeyState_Release :
case KeyState_Off :
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if ( state - > activeCount > state - > inactiveCount )
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{
state - > curState = KeyState_Press ;
}
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else
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{
state - > curState = KeyState_Off ;
}
break ;
case KeyState_Invalid :
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default :
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erro_print ( " Matrix scan bug!! Report me! " ) ;
break ;
}
// Send keystate to macro module
Macro_keyState ( key , state - > curState ) ;
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// Matrix Debug, only if there is a state change
if ( matrixDebugMode & & state - > curState ! = state - > prevState )
{
// Basic debug output
if ( matrixDebugMode = = 1 & & state - > curState = = KeyState_Press )
{
printHex ( key ) ;
print ( " " ) ;
}
// State transition debug output
else if ( matrixDebugMode = = 2 )
{
printHex ( key ) ;
Matrix_keyPositionDebug ( state - > curState ) ;
print ( " " ) ;
}
}
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}
}
// Unstrobe Pin
Matrix_pin ( Matrix_cols [ strobe ] , Type_StrobeOff ) ;
}
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// State Table Output Debug
if ( matrixDebugStateCounter > 0 )
{
// Decrement counter
matrixDebugStateCounter - - ;
// Output stats on number of scans being done per USB send
print ( NL ) ;
info_msg ( " Max scans: " ) ;
printHex ( matrixMaxScans ) ;
print ( NL ) ;
info_msg ( " Previous scans: " ) ;
printHex ( matrixPrevScans ) ;
print ( NL ) ;
// Output current scan number
info_msg ( " Scan Number: " ) ;
printHex ( scanNum ) ;
print ( NL ) ;
// Display the state info for each key
print ( " <key>:<previous state><current state> <active count> <inactive count> " ) ;
for ( uint8_t key = 0 ; key < Matrix_maxKeys ; key + + )
{
// Every 4 keys, put a newline
if ( key % 4 = = 0 )
print ( NL ) ;
print ( " \033 [1m0x " ) ;
printHex_op ( key , 2 ) ;
print ( " \033 [0m " ) ;
print ( " : " ) ;
Matrix_keyPositionDebug ( Matrix_scanArray [ key ] . prevState ) ;
Matrix_keyPositionDebug ( Matrix_scanArray [ key ] . curState ) ;
print ( " 0x " ) ;
printHex_op ( Matrix_scanArray [ key ] . activeCount , 4 ) ;
print ( " 0x " ) ;
printHex_op ( Matrix_scanArray [ key ] . inactiveCount , 4 ) ;
print ( " " ) ;
}
print ( NL ) ;
}
}
// ----- CLI Command Functions -----
void cliFunc_matrixDebug ( char * args )
{
// Parse number from argument
// NOTE: Only first argument is used
char * arg1Ptr ;
char * arg2Ptr ;
CLI_argumentIsolation ( args , & arg1Ptr , & arg2Ptr ) ;
// Set the matrix debug flag depending on the argument
// If no argument, set to scan code only
// If set to T, set to state transition
switch ( arg1Ptr [ 0 ] )
{
// T as argument
case ' T ' :
case ' t ' :
matrixDebugMode = matrixDebugMode ! = 2 ? 2 : 0 ;
break ;
// No argument
case ' \0 ' :
matrixDebugMode = matrixDebugMode ! = 1 ? 1 : 0 ;
break ;
// Invalid argument
default :
return ;
}
print ( NL ) ;
info_msg ( " Matrix Debug Mode: " ) ;
printInt8 ( matrixDebugMode ) ;
}
void cliFunc_matrixState ( 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
matrixDebugStateCounter = 1 ;
if ( arg1Ptr [ 0 ] ! = ' \0 ' )
{
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matrixDebugStateCounter = ( uint16_t ) numToInt ( arg1Ptr ) ;
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}
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}