ubitxv6/ubitx_ui.cpp
2019-12-31 18:47:08 -08:00

861 lines
19 KiB
C++

#include <Arduino.h>
#include <EEPROM.h>
#include "morse.h"
#include "ubitx.h"
#include "nano_gui.h"
#define BUTTON_SELECTED 1
struct Button {
int x, y, w, h;
char *text;
char *morse;
};
#define MAX_BUTTONS 17
const struct Button btn_set[MAX_BUTTONS] PROGMEM = {
//const struct Button btn_set [] = {
{0, 10, 159, 36, "VFOA", "A"},
{160, 10, 159, 36, "VFOB", "B"},
{0, 80, 60, 36, "RIT", "R"},
{64, 80, 60, 36, "USB", "U"},
{128, 80, 60, 36, "LSB", "L"},
{192, 80, 60, 36, "CW", "M"},
{256, 80, 60, 36, "SPL", "S"},
{0, 120, 60, 36, "80", "8"},
{64, 120, 60, 36, "40", "4"},
{128, 120, 60, 36, "30", "3"},
{192, 120, 60, 36, "20", "2"},
{256, 120, 60, 36, "17", "7"},
{0, 160, 60, 36, "15", "5"},
{64, 160, 60, 36, "10", "1"},
{128, 160, 60, 36, "WPM", "W"},
{192, 160, 60, 36, "TON", "T"},
{256, 160, 60, 36, "FRQ", "F"},
};
#define MAX_KEYS 17
const struct Button keypad[MAX_KEYS] PROGMEM = {
{0, 80, 60, 36, "1", "1"},
{64, 80, 60, 36, "2", "2"},
{128, 80, 60, 36, "3", "3"},
{192, 80, 60, 36, "", ""},
{256, 80, 60, 36, "OK", "K"},
{0, 120, 60, 36, "4", "4"},
{64, 120, 60, 36, "5", "5"},
{128, 120, 60, 36, "6", "6"},
{192, 120, 60, 36, "0", "0"},
{256, 120, 60, 36, "<-", "B"},
{0, 160, 60, 36, "7", "7"},
{64, 160, 60, 36, "8", "8"},
{128, 160, 60, 36, "9", "9"},
{192, 160, 60, 36, "", ""},
{256, 160, 60, 36, "Can", "C"},
};
boolean getButton(char *text, struct Button *b){
for (int i = 0; i < MAX_BUTTONS; i++){
memcpy_P(b, btn_set + i, sizeof(struct Button));
if (!strcmp(text, b->text)){
return true;
}
}
return false;
}
/*
* This formats the frequency given in f
*/
void formatFreq(long f, char *buff) {
// tks Jack Purdum W8TEE
// replaced fsprint commmands by str commands for code size reduction
memset(buff, 0, 10);
memset(b, 0, sizeof(b));
ultoa(f, b, DEC);
//one mhz digit if less than 10 M, two digits if more
if (f < 10000000l){
buff[0] = ' ';
strncat(buff, b, 4);
strcat(buff, ".");
strncat(buff, &b[4], 2);
}
else {
strncat(buff, b, 5);
strcat(buff, ".");
strncat(buff, &b[5], 2);
}
}
void drawCommandbar(char *text){
displayFillrect(30,45,280, 32, DISPLAY_NAVY);
displayRawText(text, 30, 45, DISPLAY_WHITE, DISPLAY_NAVY);
}
/** A generic control to read variable values
*/
int getValueByKnob(int minimum, int maximum, int step_size, int initial, char* prefix, char *postfix)
{
int knob = 0;
int knob_value;
while (btnDown())
active_delay(100);
active_delay(200);
knob_value = initial;
strcpy(b, prefix);
itoa(knob_value, c, 10);
strcat(b, c);
strcat(b, postfix);
drawCommandbar(b);
while(!btnDown() && digitalRead(PTT) == HIGH){
knob = enc_read();
if (knob != 0){
if (knob_value > minimum && knob < 0)
knob_value -= step_size;
if (knob_value < maximum && knob > 0)
knob_value += step_size;
strcpy(b, prefix);
itoa(knob_value, c, 10);
strcat(b, c);
strcat(b, postfix);
drawCommandbar(b);
}
checkCAT();
}
displayFillrect(30,41,280, 32, DISPLAY_NAVY);
return knob_value;
}
void printCarrierFreq(unsigned long freq){
memset(c, 0, sizeof(c));
memset(b, 0, sizeof(b));
ultoa(freq, b, DEC);
strncat(c, b, 2);
strcat(c, ".");
strncat(c, &b[2], 3);
strcat(c, ".");
strncat(c, &b[5], 1);
displayText(c, 110, 100, 100, 30, DISPLAY_CYAN, DISPLAY_NAVY, DISPLAY_NAVY);
}
void displayDialog(char *title, char *instructions){
displayClear(DISPLAY_BLACK);
displayRect(10,10,300,220, DISPLAY_WHITE);
displayHline(20,45,280,DISPLAY_WHITE);
displayRect(12,12,296,216, DISPLAY_WHITE);
displayRawText(title, 20, 20, DISPLAY_CYAN, DISPLAY_NAVY);
displayRawText(instructions, 20, 200, DISPLAY_CYAN, DISPLAY_NAVY);
}
char vfoDisplay[12];
void displayVFO(int vfo){
int x, y;
int displayColor, displayBorder;
Button b;
if (vfo == VFO_A){
getButton("VFOA", &b);
if (splitOn){
if (vfoActive == VFO_A)
strcpy(c, "R:");
else
strcpy(c, "T:");
}
else
strcpy(c, "A:");
if (vfoActive == VFO_A){
formatFreq(frequency, c+2);
displayColor = DISPLAY_WHITE;
displayBorder = DISPLAY_BLACK;
}else{
formatFreq(vfoA, c+2);
displayColor = DISPLAY_GREEN;
displayBorder = DISPLAY_BLACK;
}
}
if (vfo == VFO_B){
getButton("VFOB", &b);
if (splitOn){
if (vfoActive == VFO_B)
strcpy(c, "R:");
else
strcpy(c, "T:");
}
else
strcpy(c, "B:");
if (vfoActive == VFO_B){
formatFreq(frequency, c+2);
displayColor = DISPLAY_WHITE;
displayBorder = DISPLAY_WHITE;
} else {
displayColor = DISPLAY_GREEN;
displayBorder = DISPLAY_BLACK;
formatFreq(vfoB, c+2);
}
}
if (vfoDisplay[0] == 0){
displayFillrect(b.x, b.y, b.w, b.h, DISPLAY_BLACK);
if (vfoActive == vfo)
displayRect(b.x, b.y, b.w , b.h, DISPLAY_WHITE);
else
displayRect(b.x, b.y, b.w , b.h, DISPLAY_NAVY);
}
x = b.x + 6;
y = b.y + 3;
char *text = c;
for (int i = 0; i <= strlen(c); i++){
char digit = c[i];
if (digit != vfoDisplay[i]){
displayFillrect(x, y, 15, b.h-6, DISPLAY_BLACK);
//checkCAT();
displayChar(x, y + TEXT_LINE_HEIGHT + 3, digit, displayColor, DISPLAY_BLACK);
checkCAT();
}
if (digit == ':' || digit == '.')
x += 7;
else
x += 16;
text++;
}//end of the while loop of the characters to be printed
strcpy(vfoDisplay, c);
}
void btnDraw(struct Button *b){
if (!strcmp(b->text, "VFOA")){
memset(vfoDisplay, 0, sizeof(vfoDisplay));
displayVFO(VFO_A);
}
else if(!strcmp(b->text, "VFOB")){
memset(vfoDisplay, 0, sizeof(vfoDisplay));
displayVFO(VFO_B);
}
else if ((!strcmp(b->text, "RIT") && ritOn == 1) ||
(!strcmp(b->text, "USB") && isUSB == 1) ||
(!strcmp(b->text, "LSB") && isUSB == 0) ||
(!strcmp(b->text, "SPL") && splitOn == 1))
displayText(b->text, b->x, b->y, b->w, b->h, DISPLAY_BLACK, DISPLAY_ORANGE, DISPLAY_DARKGREY);
else if (!strcmp(b->text, "CW") && cwMode == 1)
displayText(b->text, b->x, b->y, b->w, b->h, DISPLAY_BLACK, DISPLAY_ORANGE, DISPLAY_DARKGREY);
else
displayText(b->text, b->x, b->y, b->w, b->h, DISPLAY_GREEN, DISPLAY_BLACK, DISPLAY_DARKGREY);
}
void displayRIT(){
displayFillrect(0,41,320,30, DISPLAY_NAVY);
if (ritOn){
strcpy(c, "TX:");
formatFreq(ritTxFrequency, c+3);
if (vfoActive == VFO_A)
displayText(c, 0, 45,159, 30, DISPLAY_WHITE, DISPLAY_NAVY, DISPLAY_NAVY);
else
displayText(c, 160, 45,159, 30, DISPLAY_WHITE, DISPLAY_NAVY, DISPLAY_NAVY);
}
else {
if (vfoActive == VFO_A)
displayText("", 0, 45,159, 30, DISPLAY_WHITE, DISPLAY_NAVY, DISPLAY_NAVY);
else
displayText("", 160, 45,159, 30, DISPLAY_WHITE, DISPLAY_NAVY, DISPLAY_NAVY);
}
}
void fastTune(){
int encoder;
//if the btn is down, wait until it is up
while(btnDown())
active_delay(50);
active_delay(300);
displayRawText("Fast tune", 100, 55, DISPLAY_CYAN, DISPLAY_NAVY);
while(1){
checkCAT();
//exit after debouncing the btnDown
if (btnDown()){
displayFillrect(100, 55, 120, 30, DISPLAY_NAVY);
//wait until the button is realsed and then return
while(btnDown())
active_delay(50);
active_delay(300);
return;
}
encoder = enc_read();
if (encoder != 0){
if (encoder > 0 && frequency < 30000000l)
frequency += 50000l;
else if (encoder < 0 && frequency > 600000l)
frequency -= 50000l;
setFrequency(frequency);
displayVFO(vfoActive);
}
}// end of the event loop
}
void enterFreq(){
//force the display to refresh everything
//display all the buttons
int f;
for (int i = 0; i < MAX_KEYS; i++){
struct Button b;
memcpy_P(&b, keypad + i, sizeof(struct Button));
btnDraw(&b);
}
int cursor_pos = 0;
memset(c, 0, sizeof(c));
f = frequency / 1000l;
while(1){
checkCAT();
if(!readTouch())
continue;
scaleTouch(&ts_point);
int total = sizeof(btn_set)/sizeof(struct Button);
for (int i = 0; i < MAX_KEYS; i++){
struct Button b;
memcpy_P(&b, keypad + i, sizeof(struct Button));
int x2 = b.x + b.w;
int y2 = b.y + b.h;
if (b.x < ts_point.x && ts_point.x < x2 &&
b.y < ts_point.y && ts_point.y < y2){
if (!strcmp(b.text, "OK")){
long f = atol(c);
if(30000 >= f && f > 100){
frequency = f * 1000l;
setFrequency(frequency);
if (vfoActive == VFO_A)
vfoA = frequency;
else
vfoB = frequency;
saveVFOs();
}
guiUpdate();
return;
}
else if (!strcmp(b.text, "<-")){
c[cursor_pos] = 0;
if (cursor_pos > 0)
cursor_pos--;
c[cursor_pos] = 0;
}
else if (!strcmp(b.text, "Can")){
guiUpdate();
return;
}
else if('0' <= b.text[0] && b.text[0] <= '9'){
c[cursor_pos++] = b.text[0];
c[cursor_pos] = 0;
}
}
} // end of the button scanning loop
strcpy(b, c);
strcat(b, " KHz");
displayText(b, 0, 42, 320, 30, DISPLAY_WHITE, DISPLAY_NAVY, DISPLAY_NAVY);
delay(300);
while(readTouch())
checkCAT();
} // end of event loop : while(1)
}
void drawCWStatus(){
strcpy(b, " cw: ");
int wpm = 1200/cwSpeed;
itoa(wpm,c, 10);
strcat(b, c);
strcat(b, "wpm, ");
itoa(sideTone, c, 10);
strcat(b, c);
strcat(b, "hz");
displayText(b, 0, 201, 320, 39, DISPLAY_CYAN, DISPLAY_NAVY, DISPLAY_NAVY);
}
void drawTx(){
if (inTx)
displayText("TX", 280, 48, 37, 28, DISPLAY_BLACK, DISPLAY_ORANGE, DISPLAY_BLUE);
else
displayFillrect(280, 48, 37, 28, DISPLAY_NAVY);
}
void drawStatusbar(){
drawCWStatus();
}
void guiUpdate(){
/*
if (doingCAT)
return;
*/
// use the current frequency as the VFO frequency for the active VFO
displayClear(DISPLAY_NAVY);
memset(vfoDisplay, 0, 12);
displayVFO(VFO_A);
checkCAT();
memset(vfoDisplay, 0, 12);
displayVFO(VFO_B);
checkCAT();
displayRIT();
checkCAT();
//force the display to refresh everything
//display all the buttons
for (int i = 0; i < MAX_BUTTONS; i++){
struct Button b;
memcpy_P(&b, btn_set + i, sizeof(struct Button));
btnDraw(&b);
checkCAT();
}
drawStatusbar();
checkCAT();
}
// this builds up the top line of the display with frequency and mode
void updateDisplay() {
displayVFO(vfoActive);
}
int enc_prev_state = 3;
/**
* The A7 And A6 are purely analog lines on the Arduino Nano
* These need to be pulled up externally using two 10 K resistors
*
* There are excellent pages on the Internet about how these encoders work
* and how they should be used. We have elected to use the simplest way
* to use these encoders without the complexity of interrupts etc to
* keep it understandable.
*
* The enc_state returns a two-bit number such that each bit reflects the current
* value of each of the two phases of the encoder
*
* The enc_read returns the number of net pulses counted over 50 msecs.
* If the puluses are -ve, they were anti-clockwise, if they are +ve, the
* were in the clockwise directions. Higher the pulses, greater the speed
* at which the enccoder was spun
*/
byte enc_state (void) {
//Serial.print(digitalRead(ENC_A)); Serial.print(":");Serial.println(digitalRead(ENC_B));
return (digitalRead(ENC_A) == 1 ? 1 : 0) + (digitalRead(ENC_B) == 1 ? 2: 0);
}
int enc_read(void) {
int result = 0;
byte newState;
int enc_speed = 0;
long stop_by = millis() + 200;
while (millis() < stop_by) { // check if the previous state was stable
newState = enc_state(); // Get current state
// if (newState != enc_prev_state)
// active_delay(20);
if (enc_state() != newState || newState == enc_prev_state)
continue;
//these transitions point to the encoder being rotated anti-clockwise
if ((enc_prev_state == 0 && newState == 2) ||
(enc_prev_state == 2 && newState == 3) ||
(enc_prev_state == 3 && newState == 1) ||
(enc_prev_state == 1 && newState == 0)){
result--;
}
//these transitions point o the enccoder being rotated clockwise
if ((enc_prev_state == 0 && newState == 1) ||
(enc_prev_state == 1 && newState == 3) ||
(enc_prev_state == 3 && newState == 2) ||
(enc_prev_state == 2 && newState == 0)){
result++;
}
enc_prev_state = newState; // Record state for next pulse interpretation
enc_speed++;
active_delay(1);
}
//if (result)
// Serial.println(result);
return(result);
}
void ritToggle(struct Button *b){
if (ritOn == 0){
ritEnable(frequency);
}
else
ritDisable();
btnDraw(b);
displayRIT();
}
void splitToggle(struct Button *b){
if (splitOn)
splitOn = 0;
else
splitOn = 1;
btnDraw(b);
//disable rit as well
ritDisable();
struct Button b2;
getButton("RIT", &b2);
btnDraw(&b2);
displayRIT();
memset(vfoDisplay, 0, sizeof(vfoDisplay));
displayVFO(VFO_A);
memset(vfoDisplay, 0, sizeof(vfoDisplay));
displayVFO(VFO_B);
}
void vfoReset(){
Button b;
if (vfoActive = VFO_A)
vfoB = vfoA;
else
vfoA = vfoB;
if (splitOn){
getButton("SPL", &b);
splitToggle(&b);
}
if (ritOn){
getButton("RIT", &b);
ritToggle(&b);
}
memset(vfoDisplay, 0, sizeof(vfoDisplay));
displayVFO(VFO_A);
memset(vfoDisplay, 0, sizeof(vfoDisplay));
displayVFO(VFO_B);
saveVFOs();
}
void cwToggle(struct Button *b){
if (cwMode == 0){
cwMode = 1;
}
else
cwMode = 0;
setFrequency(frequency);
btnDraw(b);
}
void sidebandToggle(struct Button *b){
if (!strcmp(b->text, "LSB"))
isUSB = 0;
else
isUSB = 1;
struct Button e;
getButton("USB", &e);
btnDraw(&e);
getButton("LSB", &e);
btnDraw(&e);
saveVFOs();
}
void redrawVFOs(){
struct Button b;
ritDisable();
getButton("RIT", &b);
btnDraw(&b);
displayRIT();
memset(vfoDisplay, 0, sizeof(vfoDisplay));
displayVFO(VFO_A);
memset(vfoDisplay, 0, sizeof(vfoDisplay));
displayVFO(VFO_B);
//draw the lsb/usb buttons, the sidebands might have changed
getButton("LSB", &b);
btnDraw(&b);
getButton("USB", &b);
btnDraw(&b);
}
void switchBand(long bandfreq){
long offset;
// Serial.println(frequency);
// Serial.println(bandfreq);
if (3500000l <= frequency && frequency <= 4000000l)
offset = frequency - 3500000l;
else if (24800000l <= frequency && frequency <= 25000000l)
offset = frequency - 24800000l;
else
offset = frequency % 1000000l;
// Serial.println(offset);
setFrequency(bandfreq + offset);
updateDisplay();
saveVFOs();
}
int setCwSpeed(){
int knob = 0;
int wpm;
wpm = 1200/cwSpeed;
wpm = getValueByKnob(1, 100, 1, wpm, "CW: ", " WPM");
cwSpeed = 1200/wpm;
EEPROM.put(CW_SPEED, cwSpeed);
active_delay(500);
drawStatusbar();
// printLine2("");
// updateDisplay();
}
void setCwTone(){
int knob = 0;
int prev_sideTone;
tone(CW_TONE, sideTone);
//disable all clock 1 and clock 2
while (digitalRead(PTT) == HIGH && !btnDown())
{
knob = enc_read();
if (knob > 0 && sideTone < 2000)
sideTone += 10;
else if (knob < 0 && sideTone > 100 )
sideTone -= 10;
else
continue; //don't update the frequency or the display
tone(CW_TONE, sideTone);
itoa(sideTone, c, 10);
strcpy(b, "CW Tone: ");
strcat(b, c);
strcat(b, " Hz");
drawCommandbar(b);
//printLine2(b);
checkCAT();
active_delay(20);
}
noTone(CW_TONE);
//save the setting
EEPROM.put(CW_SIDETONE, sideTone);
displayFillrect(30,41,280, 32, DISPLAY_NAVY);
drawStatusbar();
// printLine2("");
// updateDisplay();
}
void doCommand(struct Button *b){
if (!strcmp(b->text, "RIT"))
ritToggle(b);
else if (!strcmp(b->text, "LSB"))
sidebandToggle(b);
else if (!strcmp(b->text, "USB"))
sidebandToggle(b);
else if (!strcmp(b->text, "CW"))
cwToggle(b);
else if (!strcmp(b->text, "SPL"))
splitToggle(b);
else if (!strcmp(b->text, "VFOA")){
if (vfoActive == VFO_A)
fastTune();
else
switchVFO(VFO_A);
}
else if (!strcmp(b->text, "VFOB")){
if (vfoActive == VFO_B)
fastTune();
else
switchVFO(VFO_B);
}
else if (!strcmp(b->text, "A=B"))
vfoReset();
else if (!strcmp(b->text, "80"))
switchBand(3500000l);
else if (!strcmp(b->text, "40"))
switchBand(7000000l);
else if (!strcmp(b->text, "30"))
switchBand(10000000l);
else if (!strcmp(b->text, "20"))
switchBand(14000000l);
else if (!strcmp(b->text, "17"))
switchBand(18000000l);
else if (!strcmp(b->text, "15"))
switchBand(21000000l);
else if (!strcmp(b->text, "13"))
switchBand(24800000l);
else if (!strcmp(b->text, "10"))
switchBand(28000000l);
else if (!strcmp(b->text, "FRQ"))
enterFreq();
else if (!strcmp(b->text, "WPM"))
setCwSpeed();
else if (!strcmp(b->text, "TON"))
setCwTone();
}
void checkTouch(){
if (!readTouch())
return;
while(readTouch())
checkCAT();
scaleTouch(&ts_point);
/* //debug code
Serial.print(ts_point.x); Serial.print(' ');Serial.println(ts_point.y);
*/
int total = sizeof(btn_set)/sizeof(struct Button);
for (int i = 0; i < MAX_BUTTONS; i++){
struct Button b;
memcpy_P(&b, btn_set + i, sizeof(struct Button));
int x2 = b.x + b.w;
int y2 = b.y + b.h;
if (b.x < ts_point.x && ts_point.x < x2 &&
b.y < ts_point.y && ts_point.y < y2)
doCommand(&b);
}
}
//returns true if the button is pressed
int btnDown(){
if (digitalRead(FBUTTON) == HIGH)
return 0;
else
return 1;
}
void drawFocus(int ibtn, int color){
struct Button b;
memcpy_P(&b, btn_set + ibtn, sizeof(struct Button));
displayRect(b.x, b.y, b.w, b.h, color);
}
void doCommands(){
int select=0, i, prevButton, btnState;
//wait for the button to be raised up
while(btnDown())
active_delay(50);
active_delay(50); //debounce
menuOn = 2;
while (menuOn){
//check if the knob's button was pressed
btnState = btnDown();
if (btnState){
struct Button b;
memcpy_P(&b, btn_set + select/10, sizeof(struct Button));
doCommand(&b);
//unfocus the buttons
drawFocus(select, DISPLAY_BLUE);
if (vfoActive == VFO_A)
drawFocus(0, DISPLAY_WHITE);
else
drawFocus(1, DISPLAY_WHITE);
//wait for the button to be up and debounce
while(btnDown())
active_delay(100);
active_delay(500);
return;
}
i = enc_read();
if (i == 0){
active_delay(50);
continue;
}
if (i > 0){
if (select + i < MAX_BUTTONS * 10)
select += i;
}
if (i < 0 && select + i >= 0)
select += i; //caught ya, i is already -ve here, so you add it
if (prevButton == select / 10)
continue;
//we are on a new button
drawFocus(prevButton, DISPLAY_BLUE);
drawFocus(select/10, DISPLAY_WHITE);
prevButton = select/10;
}
// guiUpdate();
//debounce the button
while(btnDown())
active_delay(50);
active_delay(50);
checkCAT();
}