Forked para SNOCC

Dependencies:   GPS

Dependents:   SNOCC_V1 SNOCC_V2

Fork of RA8875 by SNOCC

Revision:
78:faf49c381591
Parent:
77:9206c13aa527
Child:
79:544eb4964795
diff -r 9206c13aa527 -r faf49c381591 RA8875.cpp
--- a/RA8875.cpp	Fri Dec 26 21:34:28 2014 +0000
+++ b/RA8875.cpp	Sun Dec 28 03:14:35 2014 +0000
@@ -161,411 +161,6 @@
     return RGBQuadToRGB16(&q, 0);
 }
 
-// ### Touch Panel support code additions begin here
-
-RetCode_t RA8875::TouchPanelInit(void)
-{
-    //TPCR0: Set enable bit, default sample time, wakeup, and ADC clock
-    WriteCommand(TPCR0, TP_ENABLE | TP_ADC_SAMPLE_DEFAULT_CLKS | TP_ADC_CLKDIV_DEFAULT);
-    // TPCR1: Set auto/manual, Ref voltage, debounce, manual mode params
-    WriteCommand(TPCR1, TP_MODE_DEFAULT | TP_DEBOUNCE_DEFAULT);
-    WriteCommand(INTC1, ReadCommand(INTC1) | RA8875_INT_TP);        // reg INTC1: Enable Touch Panel Interrupts (D2 = 1)
-    WriteCommand(INTC2, RA8875_INT_TP);                            // reg INTC2: Clear any TP interrupt flag
-    return noerror;
-}
-
-RetCode_t RA8875::TouchPanelInit(uint8_t bTpEnable, uint8_t bTpAutoManual, uint8_t bTpDebounce, uint8_t bTpManualMode, uint8_t bTpAdcClkDiv, uint8_t bTpAdcSampleTime)
-{
-    // Parameter bounds check
-    if( \
-            !(bTpEnable == TP_ENABLE || bTpEnable == TP_ENABLE) || \
-            !(bTpAutoManual == TP_MODE_AUTO || bTpAutoManual == TP_MODE_MANUAL) || \
-            !(bTpDebounce == TP_DEBOUNCE_OFF || bTpDebounce == TP_DEBOUNCE_ON) || \
-            !(bTpManualMode <= TP_MANUAL_LATCH_Y) || \
-            !(bTpAdcClkDiv <= TP_ADC_CLKDIV_128) || \
-            !(bTpAdcSampleTime <= TP_ADC_SAMPLE_65536_CLKS) \
-      ) return bad_parameter;
-    // Construct the config byte for TPCR0 and write them
-    WriteCommand(TPCR0, bTpEnable | bTpAdcClkDiv | bTpAdcSampleTime);    // Note: Wakeup is never enabled
-    // Construct the config byte for TPCR1 and write them
-    WriteCommand(TPCR1, bTpManualMode | bTpDebounce | bTpManualMode);    // Note: Always uses internal Vref.
-    // Set up the interrupt flag and enable bits
-    WriteCommand(INTC1, ReadCommand(INTC1) | RA8875_INT_TP);        // reg INTC1: Enable Touch Panel Interrupts (D2 = 1)
-    WriteCommand(INTC2, RA8875_INT_TP);                            // reg INTC2: Clear any TP interrupt flag
-    return noerror;
-}
-
-unsigned char RA8875::TouchPanelRead(loc_t *x, loc_t *y)
-{
-    unsigned char touchready;
-    static int xbuf[TPBUFSIZE], ybuf[TPBUFSIZE], sample = 0;
-    int i, j, temp;
-
-    if( (ReadCommand(INTC2) & RA8875_INT_TP) ) {        // Test for TP Interrupt pending in register INTC2
-        // Get the next data samples
-        ybuf[sample] =  ReadCommand(TPYH) << 2 | ( (ReadCommand(TPXYL) & 0xC) >> 2 );   // D[9:2] from reg TPYH, D[1:0] from reg TPXYL[3:2]
-        xbuf[sample] =  ReadCommand(TPXH) << 2 | ( (ReadCommand(TPXYL) & 0x3)      );   // D[9:2] from reg TPXH, D[1:0] from reg TPXYL[1:0]
-        // Check for a complete set
-        if(++sample == TPBUFSIZE) {
-            // Buffers are full, so process them using Finn's method described in Analog Dialogue No. 44, Feb 2010
-            // This requires sorting the samples in order of size, then discarding the top 25% and
-            //   bottom 25% as noise spikes. Finally, the middle 50% of the values are averaged to
-            //   reduce Gaussian noise.
-
-            // Sort the Y buffer using an Insertion Sort
-            for(i = 1; i <= TPBUFSIZE; i++) {
-                temp = ybuf[i];
-                j = i;
-                while( j && (ybuf[j-1] > temp) ) {
-                    ybuf[j] = ybuf[j-1];
-                    j = j-1;
-                }
-                ybuf[j] = temp;
-            } // End of Y sort
-            // Sort the X buffer the same way
-            for(i = 1; i <= TPBUFSIZE; i++) {
-                temp = xbuf[i];
-                j = i;
-                while( j && (xbuf[j-1] > temp) ) {
-                    xbuf[j] = xbuf[j-1];
-                    j = j-1;
-                }
-                xbuf[j] = temp;
-            } // End of X sort
-            // Average the middle half of the  Y values and report them
-            j = 0;
-            for(i = (TPBUFSIZE/4) - 1; i < TPBUFSIZE - TPBUFSIZE/4; i++ ) {
-                j += ybuf[i];
-            }
-            *y = j * (float)2/TPBUFSIZE;    // This is the average
-            // Average the middle half of the  X values and report them
-            j = 0;
-            for(i = (TPBUFSIZE/4) - 1; i < TPBUFSIZE - TPBUFSIZE/4; i++ ) {
-                j += xbuf[i];
-            }
-            *x = j * (float)2/TPBUFSIZE;    // This is the average
-            // Tidy up and return
-            touchready = 1;
-            sample = 0;             // Ready to start on the next set of data samples
-        } else {
-            // Buffer not yet full, so do not return any results yet
-            touchready = 0;
-        }
-        WriteCommand(INTC2, RA8875_INT_TP);            // reg INTC2: Clear that TP interrupt flag
-    } // End of initial if -- data has been read and processed
-    else
-        touchready = 0;         // Touch Panel "Int" was not set
-    return touchready;
-}
-
-unsigned char RA8875::TouchPanelReadRaw(loc_t *x, loc_t *y)
-{
-    unsigned char touchready;
-
-    if( (ReadCommand(INTC2) & RA8875_INT_TP) ) {        // Test for TP Interrupt pending in register INTC2
-        *y =  ReadCommand(TPYH) << 2 | ( (ReadCommand(TPXYL) & 0xC) >> 2 );   // D[9:2] from reg TPYH, D[1:0] from reg TPXYL[3:2]
-        *x =  ReadCommand(TPXH) << 2 | ( (ReadCommand(TPXYL) & 0x3)      );   // D[9:2] from reg TPXH, D[1:0] from reg TPXYL[1:0]
-        WriteCommand(INTC2, RA8875_INT_TP);            // reg INTC2: Clear that TP interrupt flag
-        touchready = 1;
-    } else
-        touchready = 0;
-    return touchready;
-}
-
-/*   The following section is derived from Carlos E. Vidales.
- *
- *   Copyright (c) 2001, Carlos E. Vidales. All rights reserved.
- *
- *   This sample program was written and put in the public domain 
- *    by Carlos E. Vidales.  The program is provided "as is" 
- *    without warranty of any kind, either expressed or implied.
- *   If you choose to use the program within your own products
- *    you do so at your own risk, and assume the responsibility
- *    for servicing, repairing or correcting the program should
- *    it prove defective in any manner.
- *   You may copy and distribute the program's source code in any 
- *    medium, provided that you also include in each copy an
- *    appropriate copyright notice and disclaimer of warranty.
- *   You may also modify this program and distribute copies of
- *    it provided that you include prominent notices stating 
- *    that you changed the file(s) and the date of any change,
- *    and that you do not charge any royalties or licenses for 
- *    its use.
- * 
- *   This file contains functions that implement calculations 
- *    necessary to obtain calibration factors for a touch screen
- *    that suffers from multiple distortion effects: namely, 
- *    translation, scaling and rotation.
- *
- *   The following set of equations represent a valid display 
- *    point given a corresponding set of touch screen points:
- *
- *                                              /-     -\
- *              /-    -\     /-            -\   |       |
- *              |      |     |              |   |   Xs  |
- *              |  Xd  |     | A    B    C  |   |       |
- *              |      |  =  |              | * |   Ys  |
- *              |  Yd  |     | D    E    F  |   |       |
- *              |      |     |              |   |   1   |
- *              \-    -/     \-            -/   |       |
- *                                              \-     -/
- *    where:
- *           (Xd,Yd) represents the desired display point 
- *                    coordinates,
- *           (Xs,Ys) represents the available touch screen
- *                    coordinates, and the matrix
- *           /-   -\
- *           |A,B,C|
- *           |D,E,F| represents the factors used to translate
- *           \-   -/  the available touch screen point values
- *                    into the corresponding display 
- *                    coordinates.
- *    Note that for practical considerations, the utilities 
- *     within this file do not use the matrix coefficients as
- *     defined above, but instead use the following 
- *     equivalents, since floating point math is not used:
- *            A = An/Divider 
- *            B = Bn/Divider 
- *            C = Cn/Divider 
- *            D = Dn/Divider 
- *            E = En/Divider 
- *            F = Fn/Divider 
- *    The functions provided within this file are:
- *          setCalibrationMatrix() - calculates the set of factors
- *                                    in the above equation, given
- *                                    three sets of test points.
- *               getDisplayPoint() - returns the actual display
- *                                    coordinates, given a set of
- *                                    touch screen coordinates.
- * translateRawScreenCoordinates() - helper function to transform
- *                                    raw screen points into values
- *                                    scaled to the desired display
- *                                    resolution.
- */
-
-/**********************************************************************
- *
- *     Function: setCalibrationMatrix()
- *
- *  Description: Calling this function with valid input data
- *                in the display and screen input arguments 
- *                causes the calibration factors between the
- *                screen and display points to be calculated,
- *                and the output argument - matrixPtr - to be 
- *                populated.
- *
- *               This function needs to be called only when new
- *                calibration factors are desired.
- *               
- *  
- *  Argument(s): displayPtr (input) - Pointer to an array of three 
- *                                     sample, reference points.
- *               screenPtr (input) - Pointer to the array of touch 
- *                                    screen points corresponding 
- *                                    to the reference display points.
- *               matrixPtr (output) - Pointer to the calibration 
- *                                     matrix computed for the set 
- *                                     of points being provided.
- *
- *
- *  From the article text, recall that the matrix coefficients are
- *   resolved to be the following:
- *
- *
- *      Divider =  (Xs0 - Xs2)*(Ys1 - Ys2) - (Xs1 - Xs2)*(Ys0 - Ys2)
- *
- *
- *
- *                 (Xd0 - Xd2)*(Ys1 - Ys2) - (Xd1 - Xd2)*(Ys0 - Ys2)
- *            A = ---------------------------------------------------
- *                                   Divider
- *
- *
- *                 (Xs0 - Xs2)*(Xd1 - Xd2) - (Xd0 - Xd2)*(Xs1 - Xs2)
- *            B = ---------------------------------------------------
- *                                   Divider
- *
- *
- *                 Ys0*(Xs2*Xd1 - Xs1*Xd2) + 
- *                             Ys1*(Xs0*Xd2 - Xs2*Xd0) + 
- *                                           Ys2*(Xs1*Xd0 - Xs0*Xd1)
- *            C = ---------------------------------------------------
- *                                   Divider
- *
- *
- *                 (Yd0 - Yd2)*(Ys1 - Ys2) - (Yd1 - Yd2)*(Ys0 - Ys2)
- *            D = ---------------------------------------------------
- *                                   Divider
- *
- *
- *                 (Xs0 - Xs2)*(Yd1 - Yd2) - (Yd0 - Yd2)*(Xs1 - Xs2)
- *            E = ---------------------------------------------------
- *                                   Divider
- *
- *
- *                 Ys0*(Xs2*Yd1 - Xs1*Yd2) + 
- *                             Ys1*(Xs0*Yd2 - Xs2*Yd0) + 
- *                                           Ys2*(Xs1*Yd0 - Xs0*Yd1)
- *            F = ---------------------------------------------------
- *                                   Divider
- *
- *
- *       Return: OK - the calibration matrix was correctly 
- *                     calculated and its value is in the 
- *                     output argument.
- *               NOT_OK - an error was detected and the 
- *                         function failed to return a valid
- *                         set of matrix values.
- *                        The only time this sample code returns
- *                        NOT_OK is when Divider == 0
- *
- *
- *
- *                 NOTE!    NOTE!    NOTE!
- *
- *  setCalibrationMatrix() and getDisplayPoint() will do fine
- *  for you as they are, provided that your digitizer         
- *  resolution does not exceed 10 bits (1024 values).  Higher
- *  resolutions may cause the integer operations to overflow
- *  and return incorrect values.  If you wish to use these   
- *  functions with digitizer resolutions of 12 bits (4096    
- *  values) you will either have to a) use 64-bit signed     
- *  integer variables and math, or b) judiciously modify the 
- *  operations to scale results by a factor of 2 or even 4.  
- *
- */
-RetCode_t RA8875::TouchPanelCalibrate(point_t * displayPtr, point_t * screenPtr, tpMatrix_t * matrixPtr)
-{
-    RetCode_t retValue = noerror;
-
-    tpMatrix.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( tpMatrix.Divider == 0 )  {
-        retValue = bad_parameter;
-    }  else   {
-        tpMatrix.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)) ;
-
-        tpMatrix.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)) ;
-
-        tpMatrix.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 ;
-
-        tpMatrix.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)) ;
-
-        tpMatrix.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)) ;
-
-        tpMatrix.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 ;
-        if (matrixPtr)
-            memcpy(matrixPtr, &tpMatrix, sizeof(tpMatrix_t));
-    }
-    return( retValue ) ;
-}
-
-/**********************************************************************
- *
- *     Function: getDisplayPoint()
- *
- *  Description: Given a valid set of calibration factors and a point
- *                value reported by the touch screen, this function
- *                calculates and returns the true (or closest to true)
- *                display point below the spot where the touch screen 
- *                was touched.
- * 
- *
- * 
- *  Argument(s): displayPtr (output) - Pointer to the calculated
- *                                      (true) display point.
- *               screenPtr (input) - Pointer to the reported touch
- *                                    screen point.
- *               matrixPtr (input) - Pointer to calibration factors
- *                                    matrix previously calculated
- *                                    from a call to 
- *                                    setCalibrationMatrix()
- * 
- *
- *  The function simply solves for Xd and Yd by implementing the 
- *   computations required by the translation matrix.  
- * 
- *                                              /-     -\
- *              /-    -\     /-            -\   |       |
- *              |      |     |              |   |   Xs  |
- *              |  Xd  |     | A    B    C  |   |       |
- *              |      |  =  |              | * |   Ys  |
- *              |  Yd  |     | D    E    F  |   |       |
- *              |      |     |              |   |   1   |
- *              \-    -/     \-            -/   |       |
- *                                              \-     -/
- * 
- *  It must be kept brief to avoid consuming CPU cycles.
- * 
- *
- *       Return: OK - the display point was correctly calculated 
- *                     and its value is in the output argument.
- *               NOT_OK - an error was detected and the function
- *                         failed to return a valid point.
- *
- *
- *
- *                 NOTE!    NOTE!    NOTE!
- *
- *  setCalibrationMatrix() and getDisplayPoint() will do fine
- *  for you as they are, provided that your digitizer         
- *  resolution does not exceed 10 bits (1024 values).  Higher
- *  resolutions may cause the integer operations to overflow
- *  and return incorrect values.  If you wish to use these   
- *  functions with digitizer resolutions of 12 bits (4096    
- *  values) you will either have to a) use 64-bit signed     
- *  integer variables and math, or b) judiciously modify the 
- *  operations to scale results by a factor of 2 or even 4.  
- *
- */
-RetCode_t RA8875::TouchPanelPoint(point_t * TouchPoint)
-{
-    RetCode_t retValue = no_touch;
-    point_t screenpoint = {0, 0};
-    
-    if (TouchPanelReadRaw(&screenpoint.x, &screenpoint.y)) {
-        retValue = touch;
-        if (tpMatrix.Divider != 0 ) {
-            /* Operation order is important since we are doing integer */
-            /*  math. Make sure you add all terms together before      */
-            /*  dividing, so that the remainder is not rounded off     */
-            /*  prematurely.                                           */
-            TouchPoint->x = ( (tpMatrix.An * screenpoint.x) +
-                              (tpMatrix.Bn * screenpoint.y) +
-                              tpMatrix.Cn
-                            ) / tpMatrix.Divider ;
-
-            TouchPoint->y = ( (tpMatrix.Dn * screenpoint.x) +
-                              (tpMatrix.En * screenpoint.y) +
-                              tpMatrix.Fn
-                            ) / tpMatrix.Divider ;
-        } else {
-            retValue = bad_parameter ;
-        }
-    }
-    return( retValue );
-}
-
-
-RetCode_t RA8875::TouchPanelSetMatrix(tpMatrix_t * matrixPtr)
-{
-    if (matrixPtr == NULL || matrixPtr->Divider == 0)
-        return bad_parameter;
-    memcpy(&tpMatrix, matrixPtr, sizeof(tpMatrix_t));
-    return noerror;
-}
-
-// #### end of touch panel code additions
-
 
 RetCode_t RA8875::KeypadInit(bool scanEnable, bool longDetect, uint8_t sampleTime, uint8_t scanFrequency,
                              uint8_t longTimeAdjustment, bool interruptEnable, bool wakeupEnable)
@@ -2597,35 +2192,55 @@
 {
     Timer t;
     loc_t x, y;
-
+    tpMatrix_t calmatrix;
+    
     display.background(Black);
     display.foreground(Blue);
     display.cls();
     display.puts(0,0, "Touch Panel Test\r\n");
-    pc.printf("Touch Panel Test");
+    pc.printf("Touch Panel Test\r\n");
     display.TouchPanelInit();
-    point_t pTest[3] =
-    { { 50, 50 }, {450, 50}, {450,250} };
-    point_t pSample[3];
-    for (int i=0; i<3; i++) {
-        display.foreground(Blue);
-        display.printf("(%3d,%3d) => ", pTest[i].x, pTest[i].y);
-        display.line(pTest[i].x-10, pTest[i].y, pTest[i].x+10, pTest[i].y, White);
-        display.line(pTest[i].x, pTest[i].y-10, pTest[i].x, pTest[i].y+10, White);
-        while (!display.TouchPanelReadRaw(&x, &y))
-            wait_ms(20);
-        pSample[i].x = x;
-        pSample[i].y = y;
-        display.line(pTest[i].x-10, pTest[i].y, pTest[i].x+10, pTest[i].y, Black);
-        display.line(pTest[i].x, pTest[i].y-10, pTest[i].x, pTest[i].y+10, Black);
-        display.foreground(Blue);
-        display.printf(" (%4d,%4d)\r\n", x,y);
-        while (display.TouchPanelReadRaw(&x, &y))
-            wait_ms(20);
-        wait(2);
+    pc.printf("  TP: c - calibrate, r - restore, t - test\r\n");
+    int c = pc.getc();
+    if (c == 'c') {
+        point_t pTest[3] =
+        { { 50, 50 }, {450, 150}, {225,250} };
+        point_t pSample[3];
+        for (int i=0; i<3; i++) {
+            display.foreground(Blue);
+            display.printf(" (%3d,%3d) => ", pTest[i].x, pTest[i].y);
+            display.line(pTest[i].x-10, pTest[i].y, pTest[i].x+10, pTest[i].y, White);
+            display.line(pTest[i].x, pTest[i].y-10, pTest[i].x, pTest[i].y+10, White);
+            while (!display.TouchPanelRead(&x, &y))
+                wait_ms(20);
+            pSample[i].x = x;
+            pSample[i].y = y;
+            display.line(pTest[i].x-10, pTest[i].y, pTest[i].x+10, pTest[i].y, Black);
+            display.line(pTest[i].x, pTest[i].y-10, pTest[i].x, pTest[i].y+10, Black);
+            display.foreground(Blue);
+            display.printf(" (%4d,%4d)\r\n", x,y);
+            while (display.TouchPanelRead(&x, &y))
+                wait_ms(20);
+            wait(2);
+        }
+        display.TouchPanelCalibrate(pTest, pSample, &calmatrix);
+        display.printf(" Writing calibration to tpcal.cfg\r\n");
+        FILE * fh = fopen("/local/tpcal.cfg", "wb");
+        if (fh) {
+            fwrite(&calmatrix, sizeof(calmatrix), 1, fh);
+            fclose(fh);
+        }
+        display.printf(" Calibration is complete.");
+    } else if (c == 'r') {
+        display.printf(" Reading calibration from tpcal.cfg\r\n");
+        FILE * fh = fopen("/local/tpcal.cfg", "rb");
+        if (fh) {
+            fread(&calmatrix, sizeof(calmatrix), 1, fh);
+            fclose(fh);
+        }
+        display.printf(" Calibration is complete.");
+        display.TouchPanelSetMatrix(&calmatrix);
     }
-    display.TouchPanelCalibrate(pTest, pSample, NULL);
-    display.printf(" Calibration is complete.");
     t.start();
     do {
         point_t point = {0, 0};
@@ -2670,7 +2285,6 @@
 
 void PrintScreen(RA8875 & display, Serial & pc)
 {
-    LocalFileSystem local("local");
     if (!SuppressSlowStuff)
         pc.printf("PrintScreen\r\n");
     display.PrintScreen( 0,0, 480,272, "/local/Capture.bmp");