Merge branch 'master' of git://github.com/microbuilder/LPC1343CodeBase

[hackover2013-badge-firmware.git] / drivers / displays / tft / touchscreen.c

/**************************************************************************/
/*! 
    @file     touchscreen.c
    @author   K. Townsend (microBuilder.eu)

    Parts copyright (c) 2001, Carlos E. Vidales. All rights reserved.

    @section LICENSE

    Software License Agreement (BSD License)

    Copyright (c) 2010, microBuilder SARL
    All rights reserved.

    Redistribution and use in source and binary forms, with or without
    modification, are permitted provided that the following conditions are met:
    1. Redistributions of source code must retain the above copyright
    notice, this list of conditions and the following disclaimer.
    2. Redistributions in binary form must reproduce the above copyright
    notice, this list of conditions and the following disclaimer in the
    documentation and/or other materials provided with the distribution.
    3. Neither the name of the copyright holders nor the
    names of its contributors may be used to endorse or promote products
    derived from this software without specific prior written permission.

    THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS ''AS IS'' AND ANY
    EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED
    WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE ARE
    DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT HOLDER BE LIABLE FOR ANY
    DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES
    (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES;
    LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND
    ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT
    (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE OF THIS
    SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE.
*/
/**************************************************************************/
#include "touchscreen.h"

#include "core/adc/adc.h"
#include "core/gpio/gpio.h"
#include "core/systick/systick.h"
#include "drivers/storage/eeprom/eeprom.h"
#include "drivers/displays/tft/lcd.h"
#include "drivers/displays/tft/drawing.h"
#include "drivers/displays/tft/controls/labelcentered.h"

#define TS_LINE1 "Touch the center of"
#define TS_LINE2 "the red circle using"
#define TS_LINE3 "a pen or stylus"

static bool _tsInitialised = FALSE;
static uint8_t _tsThreshhold = CFG_TFTLCD_TS_DEFAULTTHRESHOLD;
tsPoint_t _tsLCDPoints[3]; 
tsPoint_t _tsTSPoints[3]; 
tsMatrix_t _tsMatrix;

/**************************************************************************/
/*                                                                        */
/* ----------------------- Private Methods ------------------------------ */
/*                                                                        */
/**************************************************************************/

/**************************************************************************/
/*!
    @brief  Reads the current Z/pressure level using the ADC
*/
/**************************************************************************/
void tsReadZ(uint32_t* z1, uint32_t* z2)
{
  if (!_tsInitialised) tsInit();

  // XP = ADC
  // XM = GPIO Output Low
  // YP = GPIO Output High
  // YM = GPIO Input

  TS_XM_FUNC_GPIO;
  TS_YP_FUNC_GPIO;
  TS_YM_FUNC_GPIO;

  gpioSetDir (TS_XM_PORT, TS_XM_PIN, 1);
  gpioSetDir (TS_YP_PORT, TS_YP_PIN, 1);
  gpioSetDir (TS_YM_PORT, TS_YM_PIN, 0);

  gpioSetValue(TS_XM_PORT, TS_XM_PIN, 0);   // GND
  gpioSetValue(TS_YP_PORT, TS_YP_PIN, 1);   // 3.3V

  TS_XP_FUNC_ADC;
  *z1 = adcRead(TS_XP_ADC_CHANNEL);

  // XP = GPIO Input
  // XM = GPIO Output Low
  // YP = GPIO Output High
  // YM = ADC

  TS_XP_FUNC_GPIO;
  gpioSetDir (TS_YM_PORT, TS_YM_PIN, 0);

  TS_YM_FUNC_ADC;
  *z2 = adcRead(TS_YM_ADC_CHANNEL);
}

/**************************************************************************/
/*!
    @brief  Reads the current X position using the ADC
*/
/**************************************************************************/
uint32_t tsReadX(void)
{
  if (!_tsInitialised) tsInit();

  // XP = GPIO Output High
  // XM = GPIO Output Low
  // YP = ADC
  // YM = GPIO Input

  TS_XP_FUNC_GPIO;
  TS_XM_FUNC_GPIO;
  TS_YM_FUNC_GPIO;

  gpioSetDir (TS_XP_PORT, TS_XP_PIN, 1);
  gpioSetDir (TS_XM_PORT, TS_XM_PIN, 1);
  gpioSetDir (TS_YM_PORT, TS_YM_PIN, 0);

  gpioSetValue(TS_XP_PORT, TS_XP_PIN, 1);   // 3.3V
  gpioSetValue(TS_XM_PORT, TS_XM_PIN, 0);   // GND

  TS_YP_FUNC_ADC;  

  // Return the ADC results
  return adcRead(TS_YP_ADC_CHANNEL);
}

/**************************************************************************/
/*!
    @brief  Reads the current Y position using the ADC
*/
/**************************************************************************/
uint32_t tsReadY(void)
{
  if (!_tsInitialised) tsInit();

  // YP = GPIO Output High
  // YM = GPIO Output Low
  // XP = GPIO Input
  // XM = ADC

  TS_YP_FUNC_GPIO;
  TS_YM_FUNC_GPIO;
  TS_XP_FUNC_GPIO;

  gpioSetDir (TS_YP_PORT, TS_YP_PIN, 1);
  gpioSetDir (TS_YM_PORT, TS_YM_PIN, 1);
  gpioSetDir (TS_XP_PORT, TS_XP_PIN, 0);

  gpioSetValue(TS_YP_PORT, TS_YP_PIN, 1);   // 3.3V
  gpioSetValue(TS_YM_PORT, TS_YM_PIN, 0);   // GND

  TS_XM_FUNC_ADC;

  // Return the ADC results
  return adcRead(TS_XM_ADC_CHANNEL);
}

/**************************************************************************/
/*!
    @brief  Centers a line of text horizontally
*/
/**************************************************************************/
void tsCalibCenterText(char* text, uint16_t y, uint16_t color)
{
  labelcenteredRender(lcdGetWidth()/2, y, COLOR_WHITE, color, text, themeGetDefault());
}

/**************************************************************************/
/*!
    @brief  Renders the calibration screen with an appropriately
            placed test point and waits for a touch event
*/
/**************************************************************************/
tsTouchData_t tsRenderCalibrationScreen(uint16_t x, uint16_t y, uint16_t radius)
{
  drawFill(COLOR_WHITE);
  tsCalibCenterText(TS_LINE1, 50, COLOR_GRAY_50);
  tsCalibCenterText(TS_LINE2, 65, COLOR_GRAY_50);
  tsCalibCenterText(TS_LINE3, 80, COLOR_GRAY_50);
  drawCircle(x, y, radius, COLOR_RED);
  drawCircle(x, y, radius + 2, COLOR_GRAY_128);

  // Wait for a valid touch events
  tsTouchData_t data;
  tsTouchError_t error;
  bool valid = false;
  while (!valid)
  {    
    // Set calibration flag for ts read
    error = tsRead(&data, true);
    if (!error && data.valid)
    {
      valid = true;
    }
  }

  return data;
}

/**************************************************************************/
/*!
    @brief Calculates the difference between the touch screen and the
           actual screen co-ordinates, taking into account misalignment
           and any physical offset of the touch screen.

    @note  This is based on the public domain touch screen calibration code
           written by Carlos E. Vidales (copyright (c) 2001).

           For more information, see the following app notes:

           - AN2173 - Touch Screen Control and Calibration
             Svyatoslav Paliy, Cypress Microsystems
           - Calibration in touch-screen systems
             Wendy Fang and Tony Chang,
             Analog Applications Journal, 3Q 2007 (Texas Instruments)
*/
/**************************************************************************/
int setCalibrationMatrix( tsPoint_t * displayPtr, tsPoint_t * screenPtr, tsMatrix_t * matrixPtr)
{
  int  retValue = 0;
  
  matrixPtr->Divider = ((screenPtr[0].x - screenPtr[2].x) * (screenPtr[1].y - screenPtr[2].y)) - 
                       ((screenPtr[1].x - screenPtr[2].x) * (screenPtr[0].y - screenPtr[2].y)) ;
  
  if( matrixPtr->Divider == 0 )
  {
    retValue = -1 ;
  }
  else
  {
    matrixPtr->An = ((displayPtr[0].x - displayPtr[2].x) * (screenPtr[1].y - screenPtr[2].y)) - 
                    ((displayPtr[1].x - displayPtr[2].x) * (screenPtr[0].y - screenPtr[2].y)) ;
  
    matrixPtr->Bn = ((screenPtr[0].x - screenPtr[2].x) * (displayPtr[1].x - displayPtr[2].x)) - 
                    ((displayPtr[0].x - displayPtr[2].x) * (screenPtr[1].x - screenPtr[2].x)) ;
  
    matrixPtr->Cn = (screenPtr[2].x * displayPtr[1].x - screenPtr[1].x * displayPtr[2].x) * screenPtr[0].y +
                    (screenPtr[0].x * displayPtr[2].x - screenPtr[2].x * displayPtr[0].x) * screenPtr[1].y +
                    (screenPtr[1].x * displayPtr[0].x - screenPtr[0].x * displayPtr[1].x) * screenPtr[2].y ;
  
    matrixPtr->Dn = ((displayPtr[0].y - displayPtr[2].y) * (screenPtr[1].y - screenPtr[2].y)) - 
                    ((displayPtr[1].y - displayPtr[2].y) * (screenPtr[0].y - screenPtr[2].y)) ;
  
    matrixPtr->En = ((screenPtr[0].x - screenPtr[2].x) * (displayPtr[1].y - displayPtr[2].y)) - 
                    ((displayPtr[0].y - displayPtr[2].y) * (screenPtr[1].x - screenPtr[2].x)) ;
  
    matrixPtr->Fn = (screenPtr[2].x * displayPtr[1].y - screenPtr[1].x * displayPtr[2].y) * screenPtr[0].y +
                    (screenPtr[0].x * displayPtr[2].y - screenPtr[2].x * displayPtr[0].y) * screenPtr[1].y +
                    (screenPtr[1].x * displayPtr[0].y - screenPtr[0].x * displayPtr[1].y) * screenPtr[2].y ;

    // Persist data to EEPROM
    eepromWriteS32(CFG_EEPROM_TOUCHSCREEN_CAL_AN, matrixPtr->An);
    eepromWriteS32(CFG_EEPROM_TOUCHSCREEN_CAL_BN, matrixPtr->Bn);
    eepromWriteS32(CFG_EEPROM_TOUCHSCREEN_CAL_CN, matrixPtr->Cn);
    eepromWriteS32(CFG_EEPROM_TOUCHSCREEN_CAL_DN, matrixPtr->Dn);
    eepromWriteS32(CFG_EEPROM_TOUCHSCREEN_CAL_EN, matrixPtr->En);
    eepromWriteS32(CFG_EEPROM_TOUCHSCREEN_CAL_FN, matrixPtr->Fn);
    eepromWriteS32(CFG_EEPROM_TOUCHSCREEN_CAL_DIVIDER, matrixPtr->Divider);
    eepromWriteU8(CFG_EEPROM_TOUCHSCREEN_CALIBRATED, 1);
  }

  return( retValue ) ;
} 

/**************************************************************************/
/*!
    @brief  Converts the supplied touch screen location (screenPtr) to
            a pixel location on the display (displayPtr) using the
            supplied matrix.  The screen orientation is also taken into
            account when converting the touch screen co-ordinate to
            a pixel location on the LCD.

    @note  This is based on the public domain touch screen calibration code
           written by Carlos E. Vidales (copyright (c) 2001).
*/
/**************************************************************************/
int getDisplayPoint( tsPoint_t * displayPtr, tsPoint_t * screenPtr, tsMatrix_t * matrixPtr )
{
  int  retValue = TS_ERROR_NONE ;
  
  if( matrixPtr->Divider != 0 )
  {
    displayPtr->x = ( (matrixPtr->An * screenPtr->x) + 
                      (matrixPtr->Bn * screenPtr->y) + 
                       matrixPtr->Cn 
                    ) / matrixPtr->Divider ;

    displayPtr->y = ( (matrixPtr->Dn * screenPtr->x) + 
                      (matrixPtr->En * screenPtr->y) + 
                       matrixPtr->Fn 
                    ) / matrixPtr->Divider ;
  }
  else
  {
    // return TS_ERROR_NOTCALIBRATED;
    return -1;
  }

  // Adjust value if the screen is in landscape mode
  lcdOrientation_t orientation;
  orientation = lcdGetOrientation();
  if (orientation == LCD_ORIENTATION_LANDSCAPE)
  {
      uint32_t oldx, oldy;
      oldx = displayPtr->x;
      oldy = displayPtr->y;
      displayPtr->x = oldy;
      displayPtr->y = lcdGetHeight() - oldx;
  }
  
  return( retValue ) ;
}

/**************************************************************************/
/*                                                                        */
/* ----------------------- Public Methods ------------------------------- */
/*                                                                        */
/**************************************************************************/

/**************************************************************************/
/*!
    @brief  Initialises the appropriate GPIO pins and ADC for the
            touchscreen
*/
/**************************************************************************/
void tsInit(void)
{
  // Make sure that ADC is initialised
  adcInit();

  // Set initialisation flag
  _tsInitialised = TRUE;
  _tsThreshhold = tsGetThreshhold();

  // Load values from EEPROM if touch screen has already been calibrated
  if (eepromReadU8(CFG_EEPROM_TOUCHSCREEN_CALIBRATED) == 1)
  {
    // Load calibration data
    _tsMatrix.An = eepromReadS32(CFG_EEPROM_TOUCHSCREEN_CAL_AN);
    _tsMatrix.Bn = eepromReadS32(CFG_EEPROM_TOUCHSCREEN_CAL_BN);
    _tsMatrix.Cn = eepromReadS32(CFG_EEPROM_TOUCHSCREEN_CAL_CN);
    _tsMatrix.Dn = eepromReadS32(CFG_EEPROM_TOUCHSCREEN_CAL_DN);
    _tsMatrix.En = eepromReadS32(CFG_EEPROM_TOUCHSCREEN_CAL_EN);
    _tsMatrix.Fn = eepromReadS32(CFG_EEPROM_TOUCHSCREEN_CAL_FN);
    _tsMatrix.Divider = eepromReadS32(CFG_EEPROM_TOUCHSCREEN_CAL_DIVIDER);
  }
  else
  {
    // You may want to run the touch screen calibration sequence
    // here since the ts has apparently never been calibrated!
    // tsCalibrate();
  }
}

/**************************************************************************/
/*!
    @brief  Reads the current X, Y and Z co-ordinates of the touch screen

    @param[in]    calibrating
                  Set to 1 if the read attempt is for calibration data.
                  No attempt will be made to correlate the touch screen
                  and LCD co-ordinates.
*/
/**************************************************************************/
tsTouchError_t tsRead(tsTouchData_t* data, uint8_t calibrating)
{
  uint32_t x1, x2, y1, y2, z1, z2;

  // Assign pressure levels regardless of touch state
  tsReadZ(&z1, &z2);
  data->z1 = z1;
  data->z2 = z2;
  data->xraw = 0;
  data->yraw = 0;
  data->xlcd = 0;
  data->ylcd = 0;

  // Abort if the screen is not being touched (0 levels reported)
  if (z1 < _tsThreshhold)
  {
    data->valid = false;
    return TS_ERROR_NONE;
  }

  // Get two X/Y readings and compare results
  x1 = tsReadX();
  x2 = tsReadX();
  y1 = tsReadY();
  y2 = tsReadY();

  // Throw an error if both readings aren't identical
  if (x1 != x2 || y1 != y2)
  {
    data->valid = false;
    data->xraw = x1;
    data->yraw = y1;
    return TS_ERROR_XYMISMATCH;
  }

  // X/Y seems to be valid and reading has been confirmed twice
  data->xraw = x1;
  data->yraw = y1;

  // Convert x/y values to pixel location with matrix multiply
  tsPoint_t location, touch;
  touch.x = x1;
  touch.y = y1;
  getDisplayPoint( &location, &touch, &_tsMatrix) ;
  data->xlcd = location.x;
  data->ylcd = location.y;
  data->valid = true;

  return TS_ERROR_NONE;
}

/**************************************************************************/
/*!
    @brief  Starts the screen calibration process.  Each corner will be
            tested, meaning that each boundary (top, left, right and 
            bottom) will be tested twice and the readings averaged.
*/
/**************************************************************************/
void tsCalibrate(void)
{
  tsTouchData_t data;

  /* --------------- Welcome Screen --------------- */
  data = tsRenderCalibrationScreen(lcdGetWidth() / 2, lcdGetHeight() / 2, 5);
  systickDelay(250);

  /* ----------------- First Dot ------------------ */
  // 10% over and 10% down
  data = tsRenderCalibrationScreen(lcdGetWidth() / 10, lcdGetHeight() / 10, 5);
  _tsLCDPoints[0].x = lcdGetWidth() / 10;
  _tsLCDPoints[0].y = lcdGetHeight() / 10;
  _tsTSPoints[0].x = data.xraw;
  _tsTSPoints[0].y = data.yraw;
  printf("Point 1 - LCD X:%04d Y:%04d TS X:%04d Y:%04d \r\n", 
        (int)_tsLCDPoints[0].x, (int)_tsLCDPoints[0].y, (int)_tsTSPoints[0].x, (int)_tsTSPoints[0].y);
  systickDelay(250);

  /* ---------------- Second Dot ------------------ */
  // 50% over and 90% down
  data = tsRenderCalibrationScreen(lcdGetWidth() / 2, lcdGetHeight() - lcdGetHeight() / 10, 5);
  _tsLCDPoints[1].x = lcdGetWidth() / 2;
  _tsLCDPoints[1].y = lcdGetHeight() - lcdGetHeight() / 10;
  _tsTSPoints[1].x = data.xraw;
  _tsTSPoints[1].y = data.yraw;
  printf("Point 2 - LCD X:%04d Y:%04d TS X:%04d Y:%04d \r\n", 
       (int)_tsLCDPoints[1].x, (int)_tsLCDPoints[1].y, (int)_tsTSPoints[1].x, (int)_tsTSPoints[1].y);
  systickDelay(250);

  /* ---------------- Third Dot ------------------- */
  // 90% over and 50% down
  data = tsRenderCalibrationScreen(lcdGetWidth() - lcdGetWidth() / 10, lcdGetHeight() / 2, 5);
  _tsLCDPoints[2].x = lcdGetWidth() - lcdGetWidth() / 10;
  _tsLCDPoints[2].y = lcdGetHeight() / 2;
  _tsTSPoints[2].x = data.xraw;
  _tsTSPoints[2].y = data.yraw;
  printf("Point 3 - LCD X:%04d Y:%04d TS X:%04d Y:%04d \r\n", 
        (int)_tsLCDPoints[2].x, (int)_tsLCDPoints[2].y, (int)_tsTSPoints[2].x, (int)_tsTSPoints[2].y);
  systickDelay(250);

  // Do matrix calculations for calibration and store to EEPROM
  setCalibrationMatrix(&_tsLCDPoints[0], &_tsTSPoints[0], &_tsMatrix);
}

/**************************************************************************/
/*!
    @brief  Causes a blocking delay until a valid touch event occurs

    @note   Thanks to 'rossum' and limor for this nifty little tidbit on
            debouncing the signals via pressure sensitivity (using Z)

    @section Example

    @code 
    #include "drivers/displays/tft/touchscreen.h"
    ...
    tsTouchData_t data;
    tsTouchError_t error;
  
    while (1)
    {
      // Cause a blocking delay until a touch event occurs or 5s passes
      error = tsWaitForEvent(&data, 5000);
  
      if (error)
      {
        switch(error)
        {
          case TS_ERROR_TIMEOUT:
            printf("Timeout occurred %s", CFG_PRINTF_NEWLINE);
            break;
          default:
            break;
        }
      }
      else
      {
        // A valid touch event occurred ... display data
        printf("Touch Event: X = %04u, Y = %04u %s", 
            data.xlcd, 
            data.ylcd, 
            CFG_PRINTF_NEWLINE);
      }
    }

    @endcode
*/
/**************************************************************************/
tsTouchError_t tsWaitForEvent(tsTouchData_t* data, uint32_t timeoutMS)
{
  if (!_tsInitialised) tsInit();

  tsRead(data, false);

  // Return the results right away if reading is valid
  if (data->valid)
  {
    return TS_ERROR_NONE;
  }

  // Handle timeout if delay > 0 milliseconds
  if (timeoutMS)
  {
    uint32_t startTick = systickGetTicks();
    // Systick rollover may occur while waiting for timeout
    if (startTick > 0xFFFFFFFF - timeoutMS)
    {
      while (data->valid == false)
      {
        // Throw alert if timeout delay has been passed
        if ((systickGetTicks() < startTick) && (systickGetTicks() >= (timeoutMS - (0xFFFFFFFF - startTick))))
        {
          return TS_ERROR_TIMEOUT;
        }      
        tsRead(data, false);
      }
    }
    // No systick rollover will occur ... calculate timeout the simple way
    else
    {
      // Wait in infinite loop
      while (data->valid == false)
      {
        // Throw timeout if delay has been passed
        if ((systickGetTicks() - startTick) > timeoutMS)
        {
          return TS_ERROR_TIMEOUT;
        }
        tsRead(data, false);
      }
    }
  }
  // No timeout requested ... wait forever
  else
  {
    while (data->valid == false)
    {
      tsRead(data, false);
    }
  }

  // Indicate correct reading
  return TS_ERROR_NONE;
}

/**************************************************************************/
/*!
    @brief  Updates the touch screen threshhold level and saves it
            to EEPROM
*/
/**************************************************************************/
int tsSetThreshhold(uint8_t value)
{
  if ((value < 0) || (value > 254))
  {
    return -1;
  }

  // Update threshhold value
  _tsThreshhold = value;

  // Persist to EEPROM
  eepromWriteU8(CFG_EEPROM_TOUCHSCREEN_THRESHHOLD, value);

  return 0;
}

/**************************************************************************/
/*!
    @brief  Gets the current touch screen threshhold level from EEPROM
            (if present) or returns the default value from projectconfig.h
*/
/**************************************************************************/
uint8_t tsGetThreshhold(void)
{
  // Check if custom threshold has been set in eeprom
  uint8_t thold = eepromReadU8(CFG_EEPROM_TOUCHSCREEN_THRESHHOLD);
  if (thold != 0xFF)
  {
    // Use value from EEPROM
    _tsThreshhold = thold;
  }
  else
  {
    // Use the default value from projectconfig.h
    _tsThreshhold = CFG_TFTLCD_TS_DEFAULTTHRESHOLD;
  }

  return _tsThreshhold;
}