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base: FaSTTUBe:7c2e245796d0c215dbfe153739f2162eba11f5ab
Branches Tags
FaSTTUBe:main FaSTTUBe:ft23 FaSTTUBe:getac-changes FaSTTUBe:paramsec FaSTTUBe:vde24
FaSTTUBe:2024
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compare: FaSTTUBe:getac-changes
Branches Tags
FaSTTUBe:main FaSTTUBe:ft23 FaSTTUBe:getac-changes FaSTTUBe:paramsec FaSTTUBe:vde24
FaSTTUBe:2024

26 Commits
7c2e245796 ... getac-chan

Author SHA1 Message Date
Tim-Erik Düntzsch
d362fdd639 TEDü Getac Changes 2024-10-05 19:01:02 +02:00
Jasper
661e1a2274 Add brake balance display 2022-03-24 17:48:03 +01:00
Jasper
58b0b72c6d Disable P_OIL alarm 2022-03-23 15:09:40 +01:00
Jasper
b5ece154c5 Lower tire temp green threshold 2022-03-21 17:19:38 +01:00
Jasper
8a05663fbc Fix CAN filter bitmask 2022-03-18 17:21:25 +01:00
TEDü
28b4e15ed2 added DRS control 2022-03-17 00:51:16 +01:00
Jasper
1a72d6aa0f Attempt to resurrect the display after disconnect 2022-03-17 00:11:01 +01:00
Jasper
1fdadd8b85 Reduce flicker 2022-03-17 00:10:41 +01:00
Jasper
130a0dde2f Lower UBAT LED threshold 2022-03-17 00:09:54 +01:00
Jasper
6609947618 Fix RPM CAN bytes 2022-03-17 00:09:36 +01:00
Jasper
c8e94175d1 Read tire temps from CAN 2022-03-17 00:09:13 +01:00
Jasper
197b805f35 Display fuel pressure 2022-03-16 16:13:50 +01:00
Jasper
c5df4d7b79 Use one fewer CAN mailbox 2022-03-14 16:28:12 +01:00
Jasper
37123a43e8 Alternate color of testing view rows 2022-03-14 14:30:33 +01:00
Jasper
fc65d22450 Rename driver/testing pages to views 2022-03-14 14:06:52 +01:00
Jasper
4de2baa867 Don't clear display periodically 2022-03-13 21:07:44 +01:00
Jasper
c6c0fa987e Update CAN 
There are only 7 RX mailboxes available, so one of the filters won't
work.
 2022-03-13 21:06:05 +01:00
Jasper
d0afcb6da4 Add .git-blame-ignore-revs 
You can use this file to ignore this commit when running git blame.
Simply run

    git blame --ignore-revs-file .git-blame-ignore-revs [...]

Or configure git to persistently ignore the commit:

    git config blame.ignoreRevsFile .git-blame-ignore-revs
 2022-03-13 20:33:59 +01:00
Jasper
41d3bd907e Format everything 
The next commit will add this to a `.git-blame-ignore-revs` file which
you can use to ignore this commit when running git blame. Simply run

    git blame --ignore-revs-file .git-blame-ignore-revs [...]

Or configure git to persistently ignore the commit:

    git config blame.ignoreRevsFile .git-blame-ignore-revs
 2022-03-13 20:30:14 +01:00
Jasper
14b5f6988d Use both buttons to toggle driver & testing view 2022-03-13 20:01:46 +01:00
Jasper
3cf68cd3cb Add more values 2022-03-13 19:57:34 +01:00
Jasper
894ced16ef Redraw screen after alarms/changing encoders 2022-03-13 19:54:54 +01:00
Jasper
5eecc507a0 Use debouncer for button states 2022-03-13 19:52:11 +01:00
Jasper
373266f6be [WIP] Major rewrite of display code 
Currently, the displayed values are hardcoded
 2022-03-13 18:18:11 +01:00
Jasper
f62f264b29 Implement some EDIPTFT commands 2022-03-13 18:17:41 +01:00
Jasper
0eeafa9393 Debounce the rest of the buttons 2022-03-13 18:15:41 +01:00
18 changed files with 2541 additions and 2199 deletions
Expand all files Collapse all files

8
.editorconfig Normal file
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@ -0,0 +1,8 @@
[*]
charset = utf-8
end_of_line = lf
insert_final_newline = true
[*.{cpp,c,h,hpp}]
indent_style = space
indent_size = 4

2
.git-blame-ignore-revs Normal file
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@ -0,0 +1,2 @@
# Format everything
41d3bd907e65b484876859b767328e5d81181911

6
.vscode/extensions.json vendored
View File

@ -2,7 +2,9 @@
// See http://go.microsoft.com/fwlink/?LinkId=827846
// for the documentation about the extensions.json format
"recommendations": [
"platformio.platformio-ide",
"ms-vscode.cpptools-extension-pack"
"platformio.platformio-ide"
],
"unwantedRecommendations": [
"ms-vscode.cpptools-extension-pack"
]
}

21
include/debug.h
View File

@ -13,9 +13,7 @@ struct FaultStatusRegisters {
uint32_t SHCSR;
};
enum class FaultType {
HardFault, MemManage, BusFault, UsageFault
};
enum class FaultType { HardFault, MemManage, BusFault, UsageFault };
struct FlashDump {
FaultType type;
@ -43,22 +41,23 @@ const FlashDump *flash_dump_get_fault(uint32_t n);
void uart_wait_for_txrdy();
size_t uart_write(uint8_t c);
size_t uart_print(const char* str);
size_t uart_print(const char *str);
size_t uart_print_hex(uint32_t x);
void print_dumped_faults(bool in_irq=false);
void print_stacked_registers(const uint32_t *stack, bool in_irq=false);
void print_fault_registers(const FaultStatusRegisters *fsr, bool in_irq=false);
void print_dumped_faults(bool in_irq = false);
void print_stacked_registers(const uint32_t *stack, bool in_irq = false);
void print_fault_registers(const FaultStatusRegisters *fsr,
bool in_irq = false);
FaultStatusRegisters get_current_fsr();
const char* get_fault_type_name(FaultType type);
void fault_handler(uint32_t *stack_addr, FaultType fault_type,
const int *leds, unsigned n_leds);
const char *get_fault_type_name(FaultType type);
void fault_handler(uint32_t *stack_addr, FaultType fault_type, const int *leds,
unsigned n_leds);
void inline busy_wait(size_t iterations) {
for (size_t i = 0; i < iterations; i++) {
// Does nothing, but ensures the compiler doesn't optimize the loop away.
__ASM ("" ::: "memory");
__ASM("" ::: "memory");
}
}

890
lib/FT18_STW_DISPLAY/FT18_STW_DISPLAY.cpp
View File

@ -1,39 +1,39 @@
#include "FT18_STW_DISPLAY.h"
#include "Arduino.h"
#include "EDIPTFT.h"
#include "FT_2018_STW_CAN.h"
#include "FT18_STW_INIT.h"
#include "FT18_STW_DISPLAY.h"
#include "FT_2018_STW_CAN.h"
EDIPTFT tft(true,false);
String bezeichnungen[]={"T_mot","T_oil","P_oil","% fa","U_batt","P_wat","T_air",
"P_b_front","P_b_rear","Error Type","Speed_fl","Speed_fr","Speed"};
String pad_left(String orig, int len, char pad_char) {
String result = {orig};
for (int i = orig.length(); i < len; i++) {
result = pad_char + result;
}
return result;
}
EDIPTFT tft(true, false);
String bezeichnungen[] = {"T_mot", "T_oil", "P_oil", "% fa",
"U_batt", "P_wat", "T_air", "P_b_front",
"P_b_rear", "Error Type", "Speed_fl", "Speed_fr",
"Speed"};
//"Drehzahl","P_fuel","Index"
int vergleichsindex;
int sizeaalt;
int sizeaneu;
int sizebalt;
int sizebneu;
int sizecalt;
int sizecneu;
int sizedalt;
int sizedneu;
int sizeealt;
int sizeeneu;
uint8_t clearcounter = 56;
uint8_t trcalt = Stw_data.trc;
uint8_t modealt = Stw_data.mode;
uint8_t trccounter;// = Stw_data.trc;
uint8_t modecounter;// = Stw_data.mode;
bool trctimer;
bool modetimer;
int led_s[] = {led1,led2,led3,led4,led5,led6,led7,led8,led9,led10,led11,led12,led13,led14,led15,led16};
unsigned long poiltimer;
unsigned long tmottimer;
unsigned long toiltimer;
bool poilbool = true;
bool tmotbool = true;
bool toilbool = true;
int led_s[] = {led1, led2, led3, led4, led5, led6, led7, led8,
led9, led10, led11, led12, led13, led14, led15, led16};
DataBox gear_box(121, 0, 199, 94, 160, 0, EA_SWISS30B, 4, 4, 'C', true);
DataBox left_box(0, 25, 119, 94, 110, 25, EA_FONT6X8, 3, 8, 'R', false);
DataBox right_box(201, 25, 320, 94, 310, 25, EA_FONT6X8, 3, 8, 'R', false);
DataBox autoshift_box(164+50, 184, 240+50, 230, 202+50, 178, EA_FONT7X12, 3, 5, 'C', false);
TireTempBox fl_box(80, 130, 156, 176, 118, 124, EA_FONT7X12, 3, 5, 'C');
TireTempBox fr_box(164, 130, 240, 176, 202, 124, EA_FONT7X12, 3, 5, 'C');
TireTempBox rl_box(80, 184, 156, 230, 118, 178, EA_FONT7X12, 3, 5, 'C');
TireTempBox rr_box(164, 184, 240, 230, 202, 178, EA_FONT7X12, 3, 5, 'C');
int testing_page = 0;
uint16_t clearcounter = 1;
void init_display() {
pinMode(writeprotect, OUTPUT);
digitalWrite(writeprotect, HIGH);
@ -41,366 +41,544 @@ void init_display() {
pinMode(disp_cs, OUTPUT);
pinMode(MOSI, OUTPUT);
pinMode(MISO, OUTPUT);
//pinMode(CLK, INPUT);
digitalWrite(disp_cs, HIGH);
digitalWrite(MOSI, HIGH);
digitalWrite(MISO, HIGH);
digitalWrite(reset, LOW);
//edip.smallProtoSelect(7);
//edip.setNewColor(EA_GREY, 0xe3, 0xe3,0xe3); // redefine r-g-b-values of EA_GREY
//edip.drawImage(0,50,FASTTUBE_LOGO_PNG);
digitalWrite(reset,HIGH);
digitalWrite(reset, HIGH);
tft.begin(115200); // start display communication
/*int h = 20;
char charh[2];
String strh = String(h);
strh.toCharArray(charh,2);
tft.DisplayLight(charh);*/
tft.cursorOn(false);
tft.terminalOn(false);
tft.setDisplayColor(EA_WHITE,EA_BLACK);
tft.setTextColor(EA_WHITE,EA_BLACK);
//tft.setTextFont('4');
tft.setTextSize(5,8);
tft.setDisplayColor(EA_WHITE, EA_BLACK);
tft.setTextColor(EA_WHITE, EA_TRANSPARENT);
tft.setTextSize(5, 8);
tft.clear();
//tft.displayLight('30');
tft.drawText(0, 14, 'C', "FaSTTUBe"); //draw some text
//tft.loadImage(0,0,1);
//delay(2000);
gear_box.update_label(get_label(VAL_GEAR));
left_box.update_label(get_label(VAL_FIRST_LEFT_BOX));
right_box.update_label(get_label(VAL_RPM));
autoshift_box.update_label("");
}
double get_value(int a){
double value;
if (a == 0){
value = Vehicle_data.gear;
//}else if (a == 11){
// value = Stw_data.i;
//}else if (a == 1){
// value = Vehicle_data.revol/2;
}else if (a == 1){
value = Vehicle_data.t_mot-40;
}else if (a == 5){
value = 0.0706949*Vehicle_data.u_batt;
}else if (a == 7){
value = Vehicle_data.t_air-40;
}else if(a == 10){
value = Stw_data.error_type;
}else if (a == 2){
value = Vehicle_data.t_oil-40;
}else if (a == 6){
value = 0.0514*Vehicle_data.p_wat;
//}else if (a == 7){
// value = 0.0514*Vehicle_data.p_fuel;
}else if (a == 3){
value = 0.0514*Vehicle_data.p_oil;
}else if (a == 8){
value = Vehicle_data.p_brake_front;
}else if (a == 9){
value = Vehicle_data.p_brake_rear;
}else if(a == 4){
value = 200*Vehicle_data.p_brake_front/(Vehicle_data.p_brake_rear+(2*Vehicle_data.p_brake_front));
}else if (a == 11){
value = Vehicle_data.speed_fl;
}else if (a == 12){
value = Vehicle_data.speed_fr;
}else if(a == 13){
value = Vehicle_data.speed;
String get_value(Value val) {
switch (val) {
case VAL_GEAR:
if (Vehicle_data.gear == 0) {
return "N";
}
return String(Vehicle_data.gear);
case VAL_RPM:
return String(Vehicle_data.revol / 2);
case VAL_TT_FL:
return String(Vehicle_data.t_tfl * 0.423529 + 8, 0);
case VAL_TT_FR:
return String(Vehicle_data.t_tfr * 0.423529 + 0, 0);
case VAL_TT_RL:
return String(Vehicle_data.t_trl * 0.423529 + 11, 0);
case VAL_TT_RR:
return String(Vehicle_data.t_trr * 0.423529 + 4, 0);
case VAL_LAPTIME: {
double time =
Vehicle_data.lap_time_sec + Vehicle_data.lap_time_msec / 1000.0;
if (time < 100) {
return String(time, 2);
} else if (time < 1000) {
return String(time, 1);
} else if (time < 10000) {
return String(time, 0);
} else {
return "2SLOW";
}
}
case VAL_UBATT:
return String(0.0706949 * Vehicle_data.u_batt, 2);
case VAL_TMOT:
return String(Vehicle_data.t_mot - 40);
case VAL_TAIR:
return String(Vehicle_data.t_air - 40);
case VAL_TOIL:
return String(Vehicle_data.t_oil - 40);
case VAL_ERR_TYPE:
return String(Stw_data.error_type);
case VAL_PFUEL:
return String(0.0514 * Vehicle_data.p_fuel, 2);
case VAL_PWAT:
return String(0.0514 * Vehicle_data.p_wat, 2);
case VAL_POIL:
return String(0.0514 * Vehicle_data.p_oil, 2);
case VAL_PBF:
return String(Vehicle_data.p_brake_front);
case VAL_PBR:
return String(Vehicle_data.p_brake_rear);
case VAL_SPEED_FL:
return String(Vehicle_data.speed_fl);
case VAL_SPEED_FR:
return String(Vehicle_data.speed_fr);
case VAL_SPEED:
return String(Vehicle_data.speed);
case VAL_BBAL: {
double p_total =
Vehicle_data.p_brake_front + Vehicle_data.p_brake_rear / 2.398;
double bbal = p_total == 0 ? 0 : 100 * Vehicle_data.p_brake_front / p_total;
if (bbal >= 100) {
return "100";
}
return String(bbal, 2);
}
default:
return "???";
}
return value;
}
void update_display(){
if(((millis()-poiltimer)>=20000) and poilbool){
poilbool = false;
alarm("P_oil");
String get_label(Value val) {
switch (val) {
case VAL_GEAR:
return "GEAR";
case VAL_RPM:
return "RPM";
case VAL_TT_FL:
return "TEMP FL";
case VAL_TT_FR:
return "TEMP FR";
case VAL_TT_RL:
return "TEMP RL";
case VAL_TT_RR:
return "TEMP RR";
case VAL_LAPTIME:
return "LAPTIME";
case VAL_UBATT:
return "BATT VOLTAGE";
case VAL_TMOT:
return "TEMP ENG";
case VAL_TAIR:
return "TEMP AIR";
case VAL_TOIL:
return "TEMP OIL";
case VAL_ERR_TYPE:
return "ERROR TYPE";
case VAL_PFUEL:
return "PRESS FUEL";
case VAL_PWAT:
return "PRESS WAT";
case VAL_POIL:
return "PRESS OIL";
case VAL_PBF:
return "PRESS BRAKE F";
case VAL_PBR:
return "PRESS BRAKE R";
case VAL_SPEED_FL:
return "SPEED FL";
case VAL_SPEED_FR:
return "SPEED FR";
case VAL_SPEED:
return "SPEED";
case VAL_BBAL:
return "BBAL";
default:
return "???";
}
if(((millis()-tmottimer)>=20000) and tmotbool){
tmotbool = false;
alarm("T_mot");
}
bool check_alarms() {
static uint32_t poil_last_valid, tmot_last_valid, toil_last_valid;
uint32_t now = millis();
if (Vehicle_data.p_oil >= POIL_ALARM_THRESH || Vehicle_data.speed == 0) {
poil_last_valid = now;
}
if(((millis()-toiltimer)>=10000) and toilbool){
toilbool = false;
alarm("T_oil");
if (Vehicle_data.t_mot <= TMOT_ALARM_THRESH ||
Vehicle_data.t_mot == TMOT_SAFE_VALUE) {
tmot_last_valid = now;
}
if((0.0514*Vehicle_data.p_oil)>=0,1 or Vehicle_data.speed == 0){
poiltimer = millis();
if (Vehicle_data.t_oil <= TOIL_ALARM_THRESH) {
toil_last_valid = now;
}
if(((Vehicle_data.t_mot - 40) <= 0x69) or ((Vehicle_data.t_mot - 40)==0xC8)){
tmottimer = millis();
// bool poil_alarm = now - poil_last_valid >= POIL_ALARM_TIME;
bool poil_alarm = false;
bool tmot_alarm = now - tmot_last_valid >= TMOT_ALARM_TIME;
bool toil_alarm = now - toil_last_valid >= TOIL_ALARM_TIME;
bool alarm_active = poil_alarm || tmot_alarm || toil_alarm;
if (alarm_active) {
String alarm_text = "";
if (poil_alarm)
alarm_text += "PO";
if (tmot_alarm)
alarm_text += "TM";
if (toil_alarm)
alarm_text += "TO";
alarm(alarm_text);
}
if((Vehicle_data.t_oil - 40) <= 0x96){
toiltimer = millis();
}
if(Stw_data.buttonState1 & Stw_data.buttonState4){
alarm("");
}
if(!tft.disconnected){
tft.cursorOn(false);
if(trcalt!=Stw_data.trc or trctimer == true or Stw_data.buttonStateEnc1 == HIGH){
display_trc();
}else if(modealt!=Stw_data.mode or modetimer == true or Stw_data.buttonStateEnc2 == HIGH){
display_mode();
}else{
if(clearcounter>=56){
return alarm_active;
}
bool check_enc_displays() {
static uint8_t trc_old, mode_old;
static bool display_trc, display_mode;
static uint32_t display_trc_begin, display_mode_begin;
return check_display(trc_old, Stw_data.trc, display_trc, display_trc_begin,
"ARB") ||
check_display(mode_old, Stw_data.mode, display_mode,
display_mode_begin, "MODE");
}
bool check_display(uint8_t& val_old, uint8_t val_new, bool& active,
uint32_t& begin, const String& title) {
if (val_old != val_new) {
active = true;
begin = millis();
val_old = val_new;
tft.clear();
clearcounter = 0;
tft.fillDisplayColor(EA_RED);
tft.setTextColor(EA_WHITE, EA_RED);
tft.setTextSize(7, 8);
String text = title + ":" + val_new;
char text_arr[16];
text.toCharArray(text_arr, 16);
tft.drawText(15, 68, 'C', text_arr);
} else if (active && millis() - begin > ENC_DISPLAY_TIME) {
tft.setTextColor(EA_WHITE, EA_TRANSPARENT);
tft.clear();
active = false;
}
return active;
}
void update_display() {
static DisplayView view = VIEW_DRIVER;
static uint32_t last_cleared;
static bool cleared = true;
if (check_alarms()) {
cleared = true;
return;
}
if (tft.disconnected) {
uint32_t now = millis();
if (now - last_cleared < 1000) {
return;
}
digitalWrite(reset, LOW);
delay(100);
digitalWrite(reset, HIGH);
tft.disconnected = false;
tft.clear();
cleared = true;
last_cleared = now;
}
if (check_enc_displays()) {
cleared = true;
return;
}
uint32_t now = millis();
// Both buttons have to be pressed at the same time, but we also use the
// debounced rises to ensure we don't keep toggling between the views
if (Stw_data.buttonState1 && Stw_data.buttonState4 &&
(Stw_data.button1_rises > 0 || Stw_data.button4_rises > 0)) {
Stw_data.button1_rises = 0;
Stw_data.button4_rises = 0;
view = (DisplayView)((view + 1) % (VIEW_LAST + 1));
tft.clear();
cleared = true;
}
if (view == VIEW_DRIVER) {
if (cleared) {
redraw_view_driver();
cleared = false;
} else {
update_view_driver();
}
} else {
if (cleared) {
redraw_view_testing();
cleared = false;
} else {
update_view_testing();
}
}
if (clearcounter>= 10000){
pinMode(writeprotect, OUTPUT);
digitalWrite(writeprotect, HIGH);
pinMode(reset, OUTPUT);
pinMode(disp_cs, OUTPUT);
pinMode(MOSI, OUTPUT);
pinMode(MISO, OUTPUT);
digitalWrite(disp_cs, HIGH);
digitalWrite(MOSI, HIGH);
digitalWrite(MISO, HIGH);
digitalWrite(reset, LOW);
digitalWrite(reset, HIGH);
//tft.begin(115200); // start display communication
//tft.cursorOn(false);
//tft.terminalOn(false);
//tft.setDisplayColor(EA_WHITE, EA_BLACK);
//tft.setTextColor(EA_WHITE, EA_TRANSPARENT);
//tft.setTextSize(5, 8);
//tft.clear();
// gear_box.update_label(get_label(VAL_GEAR));
// left_box.update_label(get_label(VAL_FIRST_LEFT_BOX));
// right_box.update_label(get_label(VAL_RPM));
clearcounter = 0; //clearen des display nach definierter Zeit
cleared =true;
//
}
clearcounter+=1;
if(Stw_data.buttonState4){
if(Stw_data.displayindex>=sizeof(bezeichnungen)/sizeof(String)-3){
Stw_data.displayindex = 0;
delay(250);
}else{
Stw_data.displayindex+=1;
delay(250);
}
}
if(Stw_data.buttonState1){
if(Stw_data.displayindex<=0){
Stw_data.displayindex = sizeof(bezeichnungen)/sizeof(String)-3;
delay(250);
}else{
Stw_data.displayindex-=1;
delay(250);
}
}
if(vergleichsindex!=Stw_data.displayindex){
tft.clear();
vergleichsindex=Stw_data.displayindex;
}
int a = sizeof(bezeichnungen[Stw_data.displayindex]);
int g = sizeof(bezeichnungen[Stw_data.displayindex+1]);
int h = sizeof(bezeichnungen[Stw_data.displayindex+2]);
char d[a];
char e[g];
char f[h];
bezeichnungen[Stw_data.displayindex].toCharArray(d,a);
bezeichnungen[Stw_data.displayindex+1].toCharArray(e,g);
bezeichnungen[Stw_data.displayindex+2].toCharArray(f,h);
char b[2];
char c[5];
char i[5];
char j[5];
char k[5];
char m[5];
String str=String(int(get_value(0)));
if(str.equals(String(0))){
str = "N";
}
String str1;
String str2;
String str3;
if(Stw_data.displayindex+1==0 or Stw_data.displayindex+1==2 or Stw_data.displayindex+1==1 or Stw_data.displayindex+1==10 or Stw_data.displayindex+1==7 or Stw_data.displayindex+1==11 or Stw_data.displayindex+1==12 or Stw_data.displayindex+1==13){
str1=String(int(get_value(Stw_data.displayindex+1)));
}else{
str1=String(get_value(Stw_data.displayindex+1));
}
if(Stw_data.displayindex+1 == 10){
if(str1.equals(String(1))){
str1 = "PC";
}else if(str1.equals(String(2))){
str1 = "BSE";
}else if(str1.equals(String(3))){
str1 = "APS";
}else if(str1.equals(String(4))){
str1 = "ETB";
}else if(str1.equals(String(0))){
str1 = "None";
}
}
if(Stw_data.displayindex+2==0 or Stw_data.displayindex+2==2 or Stw_data.displayindex+2==1 or Stw_data.displayindex+2==10 or Stw_data.displayindex+2==7 or Stw_data.displayindex+2==11 or Stw_data.displayindex+2==12 or Stw_data.displayindex+2==13){
str2=String(int(get_value(Stw_data.displayindex+2)));
}else{
str2=String(get_value(Stw_data.displayindex+2));
}
if(Stw_data.displayindex+2 == 10){
if(str2.equals(String(1))){
str2 = "PC";
}else if(str2.equals(String(2))){
str2 = "BSE";
}else if(str2.equals(String(3))){
str2 = "APS";
}else if(str2.equals(String(4))){
str2 = "ETB";
}else if(str2.equals(String(0))){
str2 = "None";
}
}
if(Stw_data.displayindex+3==0 or Stw_data.displayindex+3==2 or Stw_data.displayindex+3==1 or Stw_data.displayindex+3==10 or Stw_data.displayindex+3==7 or Stw_data.displayindex+3==11 or Stw_data.displayindex+3==12 or Stw_data.displayindex+3==13){
str3=String(int(get_value(Stw_data.displayindex+3)));
}else{
str3=String(get_value(Stw_data.displayindex+3));
}
if(Stw_data.displayindex+3 == 10){
if(str3.equals(String(1))){
str3 = "PC";
}else if(str3.equals(String(2))){
str3 = "BSE";
}else if(str3.equals(String(3))){
str3 = "APS";
}else if(str3.equals(String(4))){
str3 = "ETB";
}else if(str3.equals(String(0))){
str3 = "None";
}
}
String str5=String(Vehicle_data.revol/2);
String str4=String(0.0514*Vehicle_data.p_fuel);
str.toCharArray(b,2);
str1.toCharArray(c,5);
str2.toCharArray(i,5);
str3.toCharArray(j,5);
str4.toCharArray(k,5);
str5.toCharArray(m,5);
sizeaneu = strlen(c);
sizebneu = strlen(i);
sizecneu = strlen(j);
sizedneu = strlen(k);
sizeeneu = strlen(m);
if(sizeaalt!=sizeaneu){
tft.clear();
sizeaalt=sizeaneu;
}
if(sizebalt!=sizebneu){
tft.clear();
sizebalt=sizebneu;
}
if(sizecalt!=sizecneu){
tft.clear();
sizecalt=sizecneu;
}
if(sizedalt!=sizedneu){
tft.clear();
sizedalt=sizedneu;
}
if(sizeealt!=sizeeneu){
tft.clear();
sizeealt=sizeeneu;
}
tft.setTextSize(6,8);
tft.drawText(132, 0, 'L', b);
tft.setTextSize(2,7);
tft.drawText(10, 20, 'L', k);
tft.drawText(240, 20, 'L', m);
tft.drawText(10,130, 'L', c);
tft.drawText(120, 130, 'L', i);
tft.drawText(240,130, 'L', j);
tft.setTextSize(1,1);
tft.drawText(136,116, 'L', "Gang");
tft.drawText(10,116, 'L', "P_fuel");
tft.drawText(240,116, 'L', "Drehzahl");
tft.drawText(10,226, 'L', d);
tft.drawText(120,226, 'L', e);
tft.drawText(240,226, 'L', f);
/*if (cleaner){
tft.setTextSize(5,8);
tft.drawText(0, 14, 'C', "FaSTTUBe"); // draw some text
tft.setTextSize(4,4);
tft.drawText(24, 120, 'C', "insert coin"); // draw some text
tft.drawText(0, 180, 'C', "to continue");
cleaner = false;
}else{
tft.setTextSize(5,8);
tft.drawText(0, 14, 'C', "FaSTTUBe"); // draw some text
tft.setTextSize(4,4);
tft.drawText(24, 120, 'C', " "); // draw some text
tft.drawText(0, 180, 'C', " ");
cleaner = true;
}
delay(80);*/
}
}
}
void display_trc(){
if(trcalt!=Stw_data.trc or Stw_data.buttonStateEnc1 == HIGH){
tft.clear();
tft.setTextSize(7,8);
tft.setDisplayColor(EA_WHITE,EA_RED);
tft.setTextColor(EA_WHITE,EA_RED);
char trcanzeige[7];
String str = String("ARB:");
if(Stw_data.trc==11){
str+="ED";
}else{
str+=String(Stw_data.trc);
}
str.toCharArray(trcanzeige,7);
tft.drawText(0,0,'L'," ");
tft.drawText(0,60,'L'," ");
tft.drawText(0,120,'L'," ");
tft.drawText(0,180,'L'," ");
tft.drawText(15,68,'L',trcanzeige);
trccounter = 0;
trcalt = Stw_data.trc;
trctimer = true;
}else if(trccounter >= 255){
tft.setDisplayColor(EA_WHITE,EA_BLACK);
tft.setTextColor(EA_WHITE,EA_BLACK);
tft.clear();
trctimer = false;
}else{
trccounter+=1;
delay(5);
}
}
void display_mode(){
if(modealt!=Stw_data.mode or Stw_data.buttonStateEnc2 == HIGH){
tft.clear();
tft.setTextSize(6,8);
tft.setDisplayColor(EA_WHITE,EA_RED);
tft.setTextColor(EA_WHITE,EA_RED);
char modeanzeige[7];
String str = String("MODE:");
str+=String(Stw_data.mode);
str.toCharArray(modeanzeige,7);
tft.drawText(0,0,'L'," ");
tft.drawText(0,60,'L'," ");
tft.drawText(0,120,'L'," ");
tft.drawText(0,180,'L'," ");
tft.drawText(15,68,'L',modeanzeige);
modecounter = 0;
modealt = Stw_data.mode;
modetimer = true;
}else if(modecounter >= 255){
tft.setDisplayColor(EA_WHITE,EA_BLACK);
tft.setTextColor(EA_WHITE,EA_BLACK);
tft.clear();
modetimer = false;
}else{
modecounter+=1;
delay(5);
}
}
void alarm(String textstr){
uint8_t x = 1;;
void alarm(String textstr) {
uint8_t x = 1;
;
char text[7];
textstr.toCharArray(text,7);
tft.setTextSize(8,8);
while(x==1){
if(!tft.disconnected){
tft.setTextColor(EA_BLACK,EA_RED);
textstr.toCharArray(text, 7);
tft.setTextSize(8, 8);
while (x == 1) {
if (!tft.disconnected) {
tft.setTextColor(EA_BLACK, EA_RED);
tft.fillDisplayColor(EA_RED);
tft.drawText(5,68,'L',text);
tft.drawText(5, 68, 'L', text);
}
for (int j = 0; j < 16; j++){
for (int j = 0; j < 16; j++) {
digitalWrite(led_s[j], HIGH);
}
delay(100);
if(!tft.disconnected){
tft.setTextColor(EA_BLACK,EA_WHITE);
if (!tft.disconnected) {
tft.setTextColor(EA_BLACK, EA_WHITE);
tft.fillDisplayColor(EA_WHITE);
tft.drawText(5,68,'L',text);
tft.drawText(5, 68, 'L', text);
}
for (int j = 0; j < 16; j++){
for (int j = 0; j < 16; j++) {
digitalWrite(led_s[j], LOW);
}
delay(100);
if(Stw_data.buttonState1 & Stw_data.buttonState4){
x=0;
tft.setTextColor(EA_WHITE,EA_BLACK);
if (Stw_data.buttonState1 & Stw_data.buttonState4) {
x = 0;
tft.setTextColor(EA_WHITE, EA_TRANSPARENT);
}
}
}
void redraw_view_driver() {
tft.setTextColor(EA_WHITE, EA_TRANSPARENT);
// Boxes
tft.drawLine(0, 110, 320, 110);
tft.drawLine(120, 0, 120, 110);
tft.drawLine(200, 0, 200, 110);
// Tire temperature cross
tft.drawLine(80, 180, 240, 180);
tft.drawLine(160, 130, 160, 230);
// Boxes
gear_box.redraw();
left_box.redraw();
right_box.redraw();
autoshift_box.redraw();
fl_box.redraw();
fr_box.redraw();
rl_box.redraw();
rr_box.redraw();
}
void update_view_driver() {
uint8_t prev_autoshift = Vehicle_data.autoshift;
static Value left_box_value = VAL_FIRST_LEFT_BOX;
if (Stw_data.button4_rises > 0) {
Stw_data.button4_rises--;
if (left_box_value == VAL_LAST) {
left_box_value = VAL_FIRST_LEFT_BOX;
} else {
left_box_value = (Value)(left_box_value + 1);
}
left_box.update_label(get_label(left_box_value));
}
if (Stw_data.button1_rises > 0) {
Stw_data.button1_rises--;
if (left_box_value == VAL_FIRST_LEFT_BOX) {
left_box_value = VAL_LAST;
} else {
left_box_value = (Value)(left_box_value - 1);
}
left_box.update_label(get_label(left_box_value));
}
// These can change rapidly, which would lead to a lot of flickering if
// rendered in the clear-redraw method. So instead, they're simply overwritten
// with a black background.
tft.setTextColor(EA_WHITE, EA_BLACK);
left_box.update_value(pad_left(get_value(left_box_value), 5));
right_box.update_value(pad_left(get_value(VAL_RPM), 5));
// Vehicle_data.autoshift = true;
if(Vehicle_data.autoshift == true){
tft.drawRectf(164+100, 184, 240+100, 230, TT_COL3);
}
else{
tft.drawRectf(164+100, 184, 240+100, 230, EA_BLACK);
}
autoshift_box.update_value(pad_left(String(Vehicle_data.autoshift), 5));
// These don't change as rapidly, and would overwrite adjacent elements
// (lines/labels) if rendered with a background because of the empty pixels
// above/below the characters. So they're rendered using the clear-redraw
// method.0
tft.setTextColor(EA_WHITE, EA_TRANSPARENT);
//gear_box.update_value(get_value(VAL_GEAR));
fl_box.update_value(get_value(VAL_TT_FL).toInt());
fr_box.update_value(get_value(VAL_TT_FR).toInt());
rl_box.update_value(get_value(VAL_TT_RL).toInt());
rr_box.update_value(get_value(VAL_TT_RR).toInt());
//Vehicle_data.autoshift = true; //For testing only!!
if(Vehicle_data.autoshift == true){
tft.setTextColor(EA_ORANGE, EA_TRANSPARENT);
}
gear_box.update_value(get_value(VAL_GEAR));
}
void redraw_view_testing() {
tft.clear();
tft.setTextFont(EA_FONT7X12);
tft.setTextSize(2, 2);
int start = 10 * testing_page;
tft.setTextColor(EA_WHITE, EA_BLACK);
for (int i = start; i <= min(VAL_LAST, start + 9); i += 2) {
redraw_label_testing(i, EA_BLACK);
}
tft.setTextColor(EA_WHITE, EA_DARKGREY);
for (int i = start + 1; i <= min(VAL_LAST, start + 9); i += 2) {
redraw_label_testing(i, EA_DARKGREY);
}
update_view_testing();
}
void update_view_testing() {
if (Stw_data.button4_rises > 0) {
Stw_data.button4_rises--;
testing_page++;
if (testing_page * 10 > VAL_LAST) {
testing_page = 0;
}
redraw_view_testing();
}
if (Stw_data.button1_rises > 0) {
Stw_data.button1_rises--;
testing_page--;
if (testing_page < 0) {
testing_page = VAL_LAST / 10;
}
redraw_view_testing();
}
tft.setTextFont(EA_FONT7X12);
tft.setTextSize(2, 2);
int start = 10 * testing_page;
tft.setTextColor(EA_WHITE, EA_BLACK);
for (int i = start; i <= min(VAL_LAST, start + 9); i += 2) {
update_value_testing(i);
}
tft.setTextColor(EA_WHITE, EA_DARKGREY);
for (int i = start + 1; i <= min(VAL_LAST, start + 9); i += 2) {
update_value_testing(i);
}
}
void redraw_label_testing(int i, uint8_t color) {
String text = get_label((Value)i) + ":";
int y = (i % 10) * 24;
tft.drawRectf(0, y, 320, y + 23, color);
tft.drawText(10, y, 'L', text.c_str());
}
void update_value_testing(int i) {
String text = pad_left(get_value((Value)i), 5);
int y = (i % 10) * 24;
tft.drawText(310, y, 'R', text.c_str());
}
DataBox::DataBox(int x1, int y1, int x2, int y2, int text_x, int text_y,
int font, int size_x, int size_y, uint8_t justification,
bool do_clear)
: x1{x1}, y1{y1}, x2{x2}, y2{y2}, text_x{text_x}, text_y{text_y},
font{font}, size_x{size_x}, size_y{size_y},
justification{justification}, do_clear{do_clear}, value{""}, label{""} {}
void DataBox::update_value(String val_new) {
if (!val_new.equals(value)) {
value = val_new;
redraw_value();
}
}
void DataBox::update_label(String label_new) {
if (!label_new.equals(label)) {
label = label_new;
redraw_label();
}
}
void DataBox::redraw() {
redraw_value();
redraw_label();
}
void DataBox::redraw_value() {
tft.setTextFont(font);
tft.setTextSize(size_x, size_y);
Serial.println("Redrawing value:");
if (do_clear) {
tft.clearRect(x1, y1, x2, y2);
}
tft.drawText(text_x, text_y, justification, value.c_str());
}
void DataBox::redraw_label() {
tft.setTextFont(EA_FONT7X12);
tft.setTextSize(1, 1);
Serial.println("Redrawing label:");
tft.clearRect(x1, y2 + 1, x2, y2 + 13);
tft.drawText((x1 + x2) / 2, y2 + 1, 'C', label.c_str());
}
TireTempBox::TireTempBox(int x1, int y1, int x2, int y2, int text_x, int text_y,
int font, int size_x, int size_y,
uint8_t justification)
: DataBox{x1, y1, x2, y2, text_x,
text_y, font, size_x, size_y, justification,
false},
num_value{-1} {}
void TireTempBox::update_value(int val_new) {
if (val_new != num_value) {
num_value = val_new;
if (val_new < TT_THRESH1) {
color = TT_COL0;
} else if (val_new < TT_THRESH2) {
color = TT_COL1;
} else if (val_new < TT_THRESH3) {
color = TT_COL2;
} else {
color = TT_COL3;
}
String val_str = pad_left(String(val_new), 3);
DataBox::update_value(val_str);
}
}
void TireTempBox::redraw_value() {
tft.setTextFont(font);
tft.setTextSize(size_x, size_y);
tft.drawRectf(x1, y1, x2, y2, color);
tft.drawText(text_x, text_y, justification, value.c_str());
}
void TireTempBox::redraw_label() {}

125
lib/FT18_STW_DISPLAY/FT18_STW_DISPLAY.h
View File

@ -1,28 +1,117 @@
#include "Arduino.h"
#include "EDIPTFT.h"
#include "FT_2018_STW_CAN.h"
#include "FT18_STW_INIT.h"
#include "FT_2018_STW_CAN.h"
#ifndef FT18_STW_DISPLAY_h
#define FT18_STW_DISPLAY_h
#define FT18_STW_DISPLAY_h
#define EA_BLACK 1
#define EA_RED 3
#define EA_GREY 10
#define EA_WHITE 8
#define MOSI 75
#define MISO 74
#define CLK 76
#define disp_cs 42
#define reset 43
#define writeprotect 52
#define MOSI 75
#define MISO 74
#define CLK 76
#define disp_cs 42
#define reset 43
#define writeprotect 52
#define POIL_ALARM_THRESH ((uint32_t)(0.1 / 0.0514))
#define POIL_ALARM_TIME 20000 // ms
#define TMOT_ALARM_THRESH (40 + 105)
#define TMOT_SAFE_VALUE (40 + 200)
#define TMOT_ALARM_TIME 20000 // ms
#define TOIL_ALARM_THRESH (40 + 150)
#define TOIL_ALARM_TIME 10000 // ms
#define ENC_DISPLAY_TIME 1000 // ms
String pad_left(String orig, int len, char pad_char = ' ');
void init_display(void);
void update_display(void);
double get_value(int a);
void display_trc(void);
void display_mode(void);
void alarm(String text);
enum DisplayView { VIEW_DRIVER, VIEW_TESTING, VIEW_LAST = VIEW_TESTING };
enum Value {
VAL_GEAR,
VAL_RPM,
VAL_TT_FL,
VAL_TT_FR,
VAL_TT_RL,
VAL_TT_RR,
VAL_LAPTIME,
VAL_UBATT,
VAL_TMOT,
VAL_TAIR,
VAL_TOIL,
VAL_ERR_TYPE,
VAL_PFUEL,
VAL_PWAT,
VAL_POIL,
VAL_PBF,
VAL_PBR,
VAL_SPEED_FL,
VAL_SPEED_FR,
VAL_SPEED,
VAL_BBAL,
VAL_FIRST_LEFT_BOX = VAL_LAPTIME,
VAL_LAST = VAL_BBAL
};
String get_value(Value val);
String get_label(Value val);
void init_display(void);
void update_display(void);
void display_trc(void);
void display_mode(void);
void alarm(String text);
bool check_alarms();
bool check_enc_displays();
bool check_display(uint8_t& val_old, uint8_t val_new, bool& active,
uint32_t& begin, const String& title);
void redraw_view_driver();
void update_view_driver();
void redraw_view_testing();
void update_view_testing();
void redraw_label_testing(int i, uint8_t bg_color);
void update_value_testing(int i);
class DataBox {
public:
DataBox(int x1, int y1, int x2, int y2, int text_x, int text_y, int font,
int size_x, int size_y, uint8_t justification, bool do_clear);
void update_value(String val_new);
void update_label(String label_new);
void redraw();
virtual void redraw_value();
virtual void redraw_label();
protected:
int x1, y1, x2, y2, text_x, text_y, font, size_x, size_y;
uint8_t justification;
bool do_clear;
String value;
String label;
};
#define TT_COL0 EA_LIGHTBLUE
#define TT_COL1 EA_GREEN
#define TT_COL2 EA_ORANGE
#define TT_COL3 EA_RED
#define TT_THRESH1 40
#define TT_THRESH2 60
#define TT_THRESH3 70
class TireTempBox : public DataBox {
public:
TireTempBox(int x1, int y1, int x2, int y2, int text_x, int text_y, int font,
int size_x, int size_y, uint8_t justification);
void update_value(int val_new);
void redraw_value() override;
void redraw_label() override;
private:
int color;
int num_value;
};
#endif

98
lib/FT18_STW_INIT/FT18_STW_INIT.cpp
View File

@ -4,73 +4,87 @@
#include <Bounce2.h>
#include <RotaryEncoder.h>
volatile stw_data_type Stw_data = {0}; //alles mit 0 initialisieren
volatile vehicle_data_type Vehicle_data = {0}; //alles mit 0 initialisieren
bool enc1PinALast,enc1PinANow,enc2PinALast,enc2PinANow;
int led[] = {led1,led2,led3,led4,led5,led6,led7,led8,led9,led10,led11,led12,led13,led14,led15,led16};
volatile stw_data_type Stw_data = {0}; // alles mit 0 initialisieren
volatile vehicle_data_type Vehicle_data = {0}; // alles mit 0 initialisieren
bool enc1PinALast, enc1PinANow, enc2PinALast, enc2PinANow;
int led[] = {led1, led2, led3, led4, led5, led6, led7, led8,
led9, led10, led11, led12, led13, led14, led15, led16};
bool entprell;
int buttons[] = {button1,button2,button3,button4,button5,button6,enc1PinS,enc2PinS};
constexpr size_t N_BUTTONS = sizeof(buttons)/sizeof(buttons[0]);
int buttons[] = {button1, button2, button3, button4,
button5, button6, enc1PinS, enc2PinS};
constexpr size_t N_BUTTONS = sizeof(buttons) / sizeof(buttons[0]);
Bounce2::Button debouncer[N_BUTTONS];
double val = 0;
double val2 = 0;
RotaryEncoder encoder(enc1PinA,enc1PinB,1,1,50);
RotaryEncoder encoder2(enc2PinA,enc2PinB,1,1,50);
RotaryEncoder encoder(enc1PinA, enc1PinB, 1, 1, 50);
RotaryEncoder encoder2(enc2PinA, enc2PinB, 1, 1, 50);
///////////////////////////////////////////////////
// functions
///////////////////////////////////////////////////
void set_pins(){
pinMode (l,OUTPUT);
for (int thisLed = 0; thisLed < sizeof(led)/sizeof(int); thisLed++) {
void set_pins() {
pinMode(l, OUTPUT);
for (int thisLed = 0; thisLed < sizeof(led) / sizeof(int); thisLed++) {
pinMode(led[thisLed], OUTPUT);
}
pinMode(enc1PinA, INPUT);
pinMode(enc1PinB, INPUT);
pinMode(enc2PinA, INPUT);
pinMode(enc2PinB, INPUT);
enc1PinALast=LOW;
enc1PinANow=LOW;
enc2PinALast=LOW;
enc2PinANow=LOW;
for(int i = 0; i < N_BUTTONS; i++){
enc1PinALast = LOW;
enc1PinANow = LOW;
enc2PinALast = LOW;
enc2PinANow = LOW;
for (int i = 0; i < N_BUTTONS; i++) {
debouncer[i].attach(buttons[i], INPUT);
debouncer[i].interval(10);
}
}
void read_buttons(){
void read_buttons() {
for (int i = 0; i < N_BUTTONS; i++) {
debouncer[i].update();
}
// These are only used to send them out via CAN, so they only need to be
// high once.
Stw_data.Stw_neutral = debouncer[1].rose();
Stw_data.Stw_auto_shift = debouncer[2].rose();
//Stw_data.Stw_neutral = debouncer[1].rose();
//Stw_data.Stw_auto_shift = debouncer[2].isPressed(); //Hold to open DRS
// 05.09.: swapped neutral and auto_shift (DRS)
Stw_data.Stw_neutral = debouncer[2].rose();
Stw_data.Stw_auto_shift = debouncer[1].isPressed(); //Hold to open DRS
Stw_data.Stw_shift_down = debouncer[4].rose();
Stw_data.Stw_shift_up = debouncer[5].rose();
// These are also used for GUI, so if we set them only at rising edge, they
// might never be high when checked in the GUI.
// TODO: Rewrite so we can use debounced values here as well
Stw_data.buttonState1 = digitalRead(button1);
Stw_data.buttonState4 = digitalRead(button4);
Stw_data.buttonStateEnc1 = digitalRead(enc1PinS);
Stw_data.buttonStateEnc2 = digitalRead(enc2PinS);
Stw_data.buttonState1 = debouncer[0].isPressed();
Stw_data.buttonState4 = debouncer[3].isPressed();
Stw_data.buttonStateEnc1 = debouncer[6].isPressed();
Stw_data.buttonStateEnc2 = debouncer[7].isPressed();
if (debouncer[0].rose()) {
Stw_data.button1_rises++;
}
if (debouncer[3].rose()) {
Stw_data.button4_rises++;
}
if (debouncer[6].rose()) {
Stw_data.enc1_rises++;
}
if (debouncer[7].rose()) {
Stw_data.enc2_rises++;
}
}
void read_rotary(){
void read_rotary() {
int enc = encoder.readEncoder();
int enc2 = encoder2.readEncoder();
if(enc != 0){
val = val +0.5*enc;
if (val==1 or val ==-1){
if(Stw_data.trc==0 and enc<0){
if (enc != 0) {
val = val + 0.5 * enc;
if (val == 1 or val == -1) {
if (Stw_data.trc == 0 and enc < 0) {
Stw_data.trc = 11;
}else if(Stw_data.trc==11 and enc>0){
Stw_data.trc=0;
}else{
} else if (Stw_data.trc == 11 and enc > 0) {
Stw_data.trc = 0;
} else {
Stw_data.trc = Stw_data.trc + enc;
}
val = 0;
@ -97,17 +111,17 @@ void read_rotary(){
/*if (Stw_data.buttonStateEnc1 == HIGH){
digitalWrite(led[Stw_data.i], HIGH);
}*/
if(enc2 != 0){
val2 = val2 +0.5*enc2;
if(val2==1 or val2==-1){
if((Stw_data.mode==1 or Stw_data.mode==0) and enc2<0){
if (enc2 != 0) {
val2 = val2 + 0.5 * enc2;
if (val2 == 1 or val2 == -1) {
if ((Stw_data.mode == 1 or Stw_data.mode == 0) and enc2 < 0) {
Stw_data.mode = 5;
}else if(Stw_data.mode==5 and enc2>0){
Stw_data.mode=1;
}else{
} else if (Stw_data.mode == 5 and enc2 > 0) {
Stw_data.mode = 1;
} else {
Stw_data.mode = Stw_data.mode + enc2;
}
val2=0;
val2 = 0;
}
}
/*if ((enc2PinALast == LOW) && (enc2PinANow == HIGH)) {

113
lib/FT18_STW_INIT/FT18_STW_INIT.h
View File

@ -2,29 +2,29 @@
#ifndef FT18_STW_Init
#define FT18_STW_Init
#define l 78 //test_led
#define led1 12//PD8
#define led2 11//PD7
#define led3 9//PC21
#define led4 8//PC22
#define led5 7//PC23
#define led6 6//PC24
#define led7 5//PC25
#define led8 4//PC26 und PA29
#define led9 3//PC28
#define led10 2//PB25
#define led11 10//PC29 und PA28
#define led12 22//PB26
#define led13 19//PA10
#define led14 13//PB27
#define led15 17//PA12
#define led16 18//PA11
#define button1 48//bl
#define button2 47//gl
#define button3 44//gr
#define button4 46//br
#define button5 45//sl
#define button6 49//sr
#define l 78 // test_led
#define led1 12 // PD8
#define led2 11 // PD7
#define led3 9 // PC21
#define led4 8 // PC22
#define led5 7 // PC23
#define led6 6 // PC24
#define led7 5 // PC25
#define led8 4 // PC26 und PA29
#define led9 3 // PC28
#define led10 2 // PB25
#define led11 10 // PC29 und PA28
#define led12 22 // PB26
#define led13 19 // PA10
#define led14 13 // PB27
#define led15 17 // PA12
#define led16 18 // PA11
#define button1 48 // bl
#define button2 47 // gl
#define button3 44 // gr
#define button4 46 // br
#define button5 45 // sl
#define button6 49 // sr
#define enc1PinA 37
#define enc1PinB 38
#define enc1PinS 35
@ -32,47 +32,49 @@
#define enc2PinB 41
#define enc2PinS 39
// define Drehzahlgrenzen TODOOOO
#define RPM_THRES_1 1000
#define RPM_THRES_2 6000
#define RPM_THRES_3 7000
#define RPM_THRES_4 8000
#define RPM_THRES_5 10000
#define RPM_THRES_6 14000
#define RPM_THRES_7 17000
#define RPM_THRES_8 18000
#define RPM_THRES_9 20000
#define RPM_THRES_10 20000
#define RPM_THRES_1 6000
#define RPM_THRES_2 12000
#define RPM_THRES_3 12800
#define RPM_THRES_4 13600
#define RPM_THRES_5 14400
#define RPM_THRES_6 15200
#define RPM_THRES_7 16000
#define RPM_THRES_8 16800
#define RPM_THRES_9 18000
#define RPM_THRES_10 18000
void set_pins(void);
void read_buttons(void);
void read_rotary(void); // read rotary switches
typedef struct
{
typedef struct {
uint8_t Stw_shift_up; // 1 Bit 0
uint8_t Stw_shift_down; // 1 Bit 1
uint8_t Stw_neutral; // 1 Bit 2
uint8_t Stw_auto_shift; // 1 Bit 3
uint8_t buttonState1; // 1 Bit 4
uint8_t buttonState4; // 1 Bit 5
//bool CAN_toggle;
//bool CAN_check;
//uint8_t i; //Index linker Drehschalter
// bool CAN_toggle;
// bool CAN_check;
// uint8_t i; //Index
// linker Drehschalter
uint8_t buttonStateEnc1; // button
//uint8_t br; //test mode : mittlere Drehschalter position
uint8_t buttonStateEnc2; //button
uint8_t displayindex; //index für Displayanzeige
uint8_t error_type; //Extrainfos über Error-LED
// uint8_t br; //test
// mode : mittlere Drehschalter position
uint8_t buttonStateEnc2; // button
uint8_t displayindex; // index für Displayanzeige
uint8_t error_type; // Extrainfos über Error-LED
uint8_t trc;
uint8_t mode;
} stw_data_type;
uint8_t button1_rises;
uint8_t button4_rises;
uint8_t enc1_rises;
uint8_t enc2_rises;
} stw_data_type;
typedef struct
{
typedef struct {
uint8_t e_thro; // E-Drossel
uint8_t g_auto; // Auto-Shift
uint8_t gear; // Gang
@ -80,8 +82,14 @@ typedef struct
uint8_t t_oil; // Öl-Motor-Temperatur
uint8_t t_mot; // Wasser-Motor-Temperatur
uint8_t t_air; // LLK-Temperatur
uint8_t t_tfl; // Tire temp front left
uint8_t t_tfr; // Tire temp front right
uint8_t t_trl; // Tire temp rear left
uint8_t t_trr; // Tire temp rear right
uint8_t u_batt; // Batteriespannung
uint8_t rev_lim; // Drehzahllimit Bit
bool drs_active; // DRS status from BCU
bool autoshift; // Autoshift status from BCU
uint8_t p_wat;
uint8_t p_fuel;
uint8_t p_oil;
@ -90,12 +98,11 @@ typedef struct
uint8_t speed_fl;
uint8_t speed_fr;
uint8_t speed;
uint8_t lap_time_sec;
uint16_t lap_time_msec;
} vehicle_data_type;
} vehicle_data_type;
extern volatile stw_data_type Stw_data;
extern volatile vehicle_data_type Vehicle_data;
extern volatile stw_data_type Stw_data;
extern volatile vehicle_data_type Vehicle_data;
#endif

85
lib/FT18e_STW_DISPLAY/FT18e_STW_DISPLAY.cpp
View File

@ -1,8 +1,8 @@
#include "FT18e_STW_DISPLAY.h"
#include "Arduino.h"
#include "EDIPTFT.h"
#include "FT_2018e_STW_CAN.h"
#include "FT18e_STW_INIT.h"
#include "FT18e_STW_DISPLAY.h"
#include "FT_2018e_STW_CAN.h"
EDIPTFT tft(true, false);
String bezeichnungen[] = {"Batterieleistung", "Moment", "Batterietemp"};
@ -26,7 +26,8 @@ uint8_t trccounter; // = Stw_data.trc;
uint8_t modecounter; // = Stw_data.mode;
bool trctimer;
bool modetimer;
int led_s[] = {led1, led2, led3, led4, led5, led6, led7, led8, led9, led10, led11, led12, led13, led14, led15, led16};
int led_s[] = {led1, led2, led3, led4, led5, led6, led7, led8,
led9, led10, led11, led12, led13, led14, led15, led16};
unsigned long poiltimer;
unsigned long tmottimer;
unsigned long toiltimer;
@ -34,22 +35,21 @@ bool poilbool = true;
bool tmotbool = true;
bool toilbool = true;
void init_display()
{
void init_display() {
pinMode(writeprotect, OUTPUT);
digitalWrite(writeprotect, HIGH);
pinMode(reset, OUTPUT);
pinMode(disp_cs, OUTPUT);
pinMode(MOSI, OUTPUT);
pinMode(MISO, OUTPUT);
//pinMode(CLK, INPUT);
// pinMode(CLK, INPUT);
digitalWrite(disp_cs, HIGH);
digitalWrite(MOSI, HIGH);
digitalWrite(MISO, HIGH);
digitalWrite(reset, LOW);
//edip.smallProtoSelect(7);
//edip.setNewColor(EA_GREY, 0xe3, 0xe3,0xe3); // redefine r-g-b-values of EA_GREY
//edip.drawImage(0,50,FASTTUBE_LOGO_PNG);
// edip.smallProtoSelect(7);
// edip.setNewColor(EA_GREY, 0xe3, 0xe3,0xe3); // redefine r-g-b-values
// of EA_GREY edip.drawImage(0,50,FASTTUBE_LOGO_PNG);
digitalWrite(reset, HIGH);
tft.begin(115200); // start display communication
/*int h = 20;
@ -61,45 +61,35 @@ void init_display()
tft.terminalOn(false);
tft.setDisplayColor(EA_WHITE, EA_BLACK);
tft.setTextColor(EA_WHITE, EA_BLACK);
//tft.setTextFont('4');
// tft.setTextFont('4');
tft.setTextSize(5, 8);
tft.clear();
//tft.displayLight('30');
tft.drawText(0, 14, 'C', "FaSTTUBe"); //draw some text
//tft.loadImage(0,0,1);
//delay(2000);
// tft.displayLight('30');
tft.drawText(0, 14, 'C', "FaSTTUBe"); // draw some text
// tft.loadImage(0,0,1);
// delay(2000);
}
double get_value(int a)
{
return 0;
}
double get_value(int a) { return 0; }
void update_display()
{
if (!tft.disconnected)
{
void update_display() {
if (!tft.disconnected) {
tft.cursorOn(false);
if (modealt != Stw_data.mode || modetimer == true)
{
if (modealt != Stw_data.mode || modetimer == true) {
display_mode();
}
else
{
if (clearcounter >= 56)
{
} else {
if (clearcounter >= 56) {
tft.clear();
clearcounter = 0;
}
clearcounter += 1;
}
}
// else für neue init?
}
void display_mode()
{
if (modealt != Stw_data.mode)
{
void display_mode() {
if (modealt != Stw_data.mode) {
tft.clear();
tft.setTextSize(6, 8);
tft.setDisplayColor(EA_WHITE, EA_RED);
@ -116,54 +106,43 @@ void display_mode()
modecounter = 0;
modealt = Stw_data.mode;
modetimer = true;
}
else if (modecounter >= 255)
{
} else if (modecounter >= 255) {
tft.setDisplayColor(EA_WHITE, EA_BLACK);
tft.setTextColor(EA_WHITE, EA_BLACK);
tft.clear();
modetimer = false;
}
else
{
} else {
modecounter += 1;
delay(5);
}
}
void alarm(String textstr)
{
void alarm(String textstr) {
uint8_t x = 1;
;
char text[7];
textstr.toCharArray(text, 7);
tft.setTextSize(8, 8);
while (x == 1)
{
if (!tft.disconnected)
{
while (x == 1) {
if (!tft.disconnected) {
tft.setTextColor(EA_BLACK, EA_RED);
tft.fillDisplayColor(EA_RED);
tft.drawText(5, 68, 'L', text);
}
for (int j = 0; j < 16; j++)
{
for (int j = 0; j < 16; j++) {
digitalWrite(led_s[j], HIGH);
}
delay(100);
if (!tft.disconnected)
{
if (!tft.disconnected) {
tft.setTextColor(EA_BLACK, EA_WHITE);
tft.fillDisplayColor(EA_WHITE);
tft.drawText(5, 68, 'L', text);
}
for (int j = 0; j < 16; j++)
{
for (int j = 0; j < 16; j++) {
digitalWrite(led_s[j], LOW);
}
delay(100);
if (Stw_data.button_ll & Stw_data.button_rr)
{
if (Stw_data.button_ll & Stw_data.button_rr) {
x = 0;
tft.setTextColor(EA_WHITE, EA_BLACK);
}

2
lib/FT18e_STW_DISPLAY/FT18e_STW_DISPLAY.h
View File

@ -1,7 +1,7 @@
#include "Arduino.h"
#include "EDIPTFT.h"
#include "FT_2018e_STW_CAN.h"
#include "FT18e_STW_INIT.h"
#include "FT_2018e_STW_CAN.h"
#ifndef FT18e_STW_DISPLAY_h
#define FT18e_STW_DISPLAY_h

50
lib/FT18e_STW_INIT/FT18e_STW_INIT.cpp
View File

@ -1,14 +1,16 @@
#include "Arduino.h"
#include "FT18e_STW_INIT.h"
#include "Arduino.h"
#include "Bounce2.h"
#include "RotaryEncoder.h"
volatile stw_data_type Stw_data = {0}; //alles mit 0 initialisieren
volatile vehicle_data_type Vehicle_data = {0}; //alles mit 0 initialisieren
volatile stw_data_type Stw_data = {0}; // alles mit 0 initialisieren
volatile vehicle_data_type Vehicle_data = {0}; // alles mit 0 initialisieren
bool enc1PinALast, enc1PinANow, enc2PinALast, enc2PinANow;
int led[] = {led1, led2, led3, led4, led5, led6, led7, led8, led9, led10, led11, led12, led13, led14, led15, led16};
int led[] = {led1, led2, led3, led4, led5, led6, led7, led8,
led9, led10, led11, led12, led13, led14, led15, led16};
bool entprell;
int buttons[] = {PIN_BUTTON_LL, PIN_BUTTON_LR, PIN_BUTTON_RL, PIN_BUTTON_RR, enc1PinS, enc2PinS};
int buttons[] = {PIN_BUTTON_LL, PIN_BUTTON_LR, PIN_BUTTON_RL,
PIN_BUTTON_RR, enc1PinS, enc2PinS};
Bounce debouncer[8];
double val = 0;
double val2 = 0;
@ -18,10 +20,8 @@ RotaryEncoder encoder2(enc2PinA, enc2PinB, 1, 1, 50);
// functions
///////////////////////////////////////////////////
void set_pins()
{
for (int thisLed = 0; thisLed < sizeof(led) / sizeof(int); thisLed++)
{
void set_pins() {
for (int thisLed = 0; thisLed < sizeof(led) / sizeof(int); thisLed++) {
pinMode(led[thisLed], OUTPUT);
}
pinMode(l, OUTPUT);
@ -33,49 +33,39 @@ void set_pins()
pinMode(button6, INPUT);*/
pinMode(enc1PinA, INPUT);
pinMode(enc1PinB, INPUT);
//pinMode(enc1PinS, INPUT);
// pinMode(enc1PinS, INPUT);
pinMode(enc2PinA, INPUT);
pinMode(enc2PinB, INPUT);
//pinMode(enc2PinS, INPUT);
//Stw_data.i=0;
// pinMode(enc2PinS, INPUT);
// Stw_data.i=0;
enc1PinALast = LOW;
enc1PinANow = LOW;
enc2PinALast = LOW;
enc2PinANow = LOW;
for (int i = 0; i < sizeof(buttons) / sizeof(*buttons); i++)
{
for (int i = 0; i < sizeof(buttons) / sizeof(*buttons); i++) {
pinMode(buttons[i], INPUT);
debouncer[i].attach(buttons[i]);
debouncer[i].interval(10);
}
}
void read_buttons()
{
void read_buttons() {
Stw_data.button_ll = digitalRead(PIN_BUTTON_LL);
Stw_data.button_lr = digitalRead(PIN_BUTTON_LR);
Stw_data.button_rl = digitalRead(PIN_BUTTON_RL);
Stw_data.button_rr = digitalRead(PIN_BUTTON_RR);
}
void read_rotary()
{
void read_rotary() {
int enc2 = encoder2.readEncoder();
if (enc2 != 0)
{
if (enc2 != 0) {
val2 = val2 + 0.5 * enc2;
if (val2 == 1 or val2 == -1)
{
if ((Stw_data.mode == 1 or Stw_data.mode == 0) and enc2 < 0)
{
if (val2 == 1 or val2 == -1) {
if ((Stw_data.mode == 1 or Stw_data.mode == 0) and enc2 < 0) {
Stw_data.mode = 5;
}
else if (Stw_data.mode == 5 and enc2 > 0)
{
} else if (Stw_data.mode == 5 and enc2 > 0) {
Stw_data.mode = 1;
}
else
{
} else {
Stw_data.mode = Stw_data.mode + enc2;
}
val2 = 0;

47
lib/FT18e_STW_INIT/FT18e_STW_INIT.h
View File

@ -2,23 +2,23 @@
#ifndef FT18e_STW_Init
#define FT18e_STW_Init
#define l 78 //test_led
#define led1 12 //PD8
#define led2 11 //PD7
#define led3 9 //PC21
#define led4 8 //PC22
#define led5 7 //PC23
#define led6 6 //PC24
#define led7 5 //PC25
#define led8 4 //PC26 und PA29
#define led9 3 //PC28
#define led10 2 //PB25
#define led11 10 //PC29 und PA28
#define led12 22 //PB26
#define led13 19 //PA10
#define led14 13 //PB27
#define led15 17 //PA12
#define led16 18 //PA11
#define l 78 // test_led
#define led1 12 // PD8
#define led2 11 // PD7
#define led3 9 // PC21
#define led4 8 // PC22
#define led5 7 // PC23
#define led6 6 // PC24
#define led7 5 // PC25
#define led8 4 // PC26 und PA29
#define led9 3 // PC28
#define led10 2 // PB25
#define led11 10 // PC29 und PA28
#define led12 22 // PB26
#define led13 19 // PA10
#define led14 13 // PB27
#define led15 17 // PA12
#define led16 18 // PA11
#define enc1PinA 37
#define enc1PinB 38
#define enc1PinS 35
@ -51,20 +51,18 @@ void set_pins(void);
void read_buttons(void);
void read_rotary(void); // read rotary switches
typedef struct
{
typedef struct {
bool button_ll; // Left side, left button
bool button_lr; // Left side, right button
bool button_rl; // Right side, left button
bool button_rr; // Right side, right button
uint8_t mode;
uint8_t displayindex; //index für Displayanzeige
uint8_t error_type; //Extrainfos über Error-LED
uint8_t displayindex; // index für Displayanzeige
uint8_t error_type; // Extrainfos über Error-LED
} stw_data_type;
struct InverterData
{
struct InverterData {
bool ready;
bool derating;
bool warning;
@ -75,8 +73,7 @@ struct InverterData
bool ts_active;
};
typedef struct
{
typedef struct {
uint16_t u_cell_min; // Minimale Zellspannung
uint16_t u_batt; // Batteriespannung (pre-AIR-voltage)
int16_t t_mot_l; // Motor-Wasser-Temperatur Links

242
lib/FT_2018_STW_CAN/FT_2018_STW_CAN.cpp
View File

@ -2,35 +2,47 @@
FT_2018_STW_CAN.cpp
*/
#include "FT_2018_STW_CAN.h"
#include "Arduino.h"
#include "DueTimer.h"
#include "due_can.h"
#include "FT_2018_STW_CAN.h"
#include "FT18_STW_INIT.h"
#include "due_can.h"
CAN_FRAME can_0_msg;
//can_1_msg.id = 0x110;
// can_1_msg.id = 0x110;
int can_0_temp_data = 0;
int leds[] = {led1,led2,led3,led4,led5,led6,led7,led8,led9,led10,led11,led12,led13,led14,led15,led16};
int leds[] = {led1, led2, led3, led4, led5, led6, led7, led8,
led9, led10, led11, led12, led13, led14, led15, led16};
void Init_Can_0() {
void Init_Can_0(){
Can0.begin(1000000); // set CAN0 baud to 1kbit/s and don`t use enable pin!
Can0.setNumTXBoxes(1); // reserves mailbox 0 for tx only 8 mailboxes are available (the other 7 mailboxes are for rx)
Can0.watchFor(0x502); // set CAN RX filter for ID 0x502 and reserves mailbox 1 for rx
Can0.watchFor(0x504);
Can0.watchFor(0x500);
Can0.watchFor(0x773); // set CAN RX filter for ID 0x773 and reserves mailbox 3 for rx
Can0.watchFor(0x775);
// Can0.watchFor(0x777); // set CAN RX filter for ID 0x777 and reserves mailbox 5 for rx
Can0.watchFor(0x779); // set CAN RX filter for ID 0x779 and reserves mailbox 6 for rx
Can0.watchFor(0x77A);
Can0.setNumTXBoxes(1); // reserves mailbox 0 for tx only 8 mailboxes are
// available (the other 7 mailboxes are for rx)
// We only have 7 mailboxes, but want to receive 9 messages. This trick should
// allow us to receive BCU_APS_BRAKE, BCU_ETC and BCU_SHIFT_CTRL in the same
// mailbox. It will also let through 0x506, but that shouldn't be much of an
// issue.
/*
Can0.watchFor(CAN_ID_BCU_APS_BRAKE & CAN_ID_BCU_ETC & CAN_ID_BCU_SHIFT_CTRL,
0x7F9);
Can0.watchFor(CAN_ID_BCU_TIRES);
Can0.watchFor(CAN_ID_BCU_LAP_TIME);
Can0.watchFor(CAN_ID_MS4_IGN_REV_ATH);
Can0.watchFor(CAN_ID_MS4_SPEED);
Can0.watchFor(CAN_ID_MS4_ETC);
Can0.watchFor(CAN_ID_MS4_STATES_TEMP_PRESS);
Can0.setGeneralCallback(Receive_Can_0);
*/
Timer3.attachInterrupt(Send_0x110); // set send interrupt
Timer3.start(10000); // Calls every 10ms
}
void Send_0x110(){
void Send_0x110() {
read_buttons();
read_rotary();
can_0_msg.id = 0x110;
@ -44,147 +56,157 @@ void Send_0x110(){
can_0_temp_data |= Stw_data.Stw_shift_down << 1 & 0b00000010;
can_0_temp_data |= Stw_data.Stw_neutral << 2 & 0b00000100;
can_0_temp_data |= Stw_data.Stw_auto_shift << 3 & 0b00001000;
can_0_temp_data |= Stw_data.buttonStateEnc1 << 5 & 0b00100000; //pitlane
can_0_temp_data |= Stw_data.buttonStateEnc1 << 5 & 0b00100000; // pitlane
can_0_msg.data.byte[0] = can_0_temp_data;
can_0_msg.data.byte[1] = Stw_data.trc & 0b00001111;
can_0_msg.data.byte[2] = Stw_data.mode & 0b00000111;
if ((Stw_data.Stw_auto_shift << 3 & 0b00001000)){
if(Vehicle_data.g_auto){
if ((Stw_data.Stw_auto_shift << 3 & 0b00001000)) {
if (Vehicle_data.g_auto) {
Vehicle_data.g_auto = false;
}else{
} else {
Vehicle_data.g_auto = true;
}
}
Can0.sendFrame(can_0_msg);
}
void Receive_Can_0(CAN_FRAME *temp_message){
void Receive_Can_0(CAN_FRAME *temp_message) {
switch (temp_message->id) {
//g_auto
case 0x502:{ // eDrossel error bit
Vehicle_data.e_thro = (temp_message->data.byte[0] & 0x80) | (temp_message->data.byte[0] & 0x40) | (temp_message->data.byte[0] & 0x20) | (temp_message->data.byte[0] & 0x10); // bit 4-7
if(temp_message->data.byte[0] & 0x80){
Stw_data.error_type = 1;//"pc_error";
}
if(temp_message->data.byte[0] & 0x40){
Stw_data.error_type = 2;//"bse_error";
}
if(temp_message->data.byte[0] & 0x20){
Stw_data.error_type = 3;//"aps_error";
}
if(temp_message->data.byte[0] & 0x10){
Stw_data.error_type = 4;//"etb_error";
}
//can_1_temp_data |= g_etb_e << 4;
//can_1_temp_data |= g_aps_e << 5;
//can_1_temp_data |= g_bse_e << 6;
//can_1_temp_data |= g_pc_e << 7;
case CAN_ID_BCU_APS_BRAKE: {
Vehicle_data.p_brake_front = temp_message->data.byte[1];
Vehicle_data.p_brake_rear = temp_message->data.byte[2];
Vehicle_data.drs_active = ((temp_message->data.byte[0] >> 7) & 0b00000001);
Vehicle_data.autoshift = ((temp_message->data.byte[7] >> 0) & 0b00000001);
break;
}
case 0x504:{ //autoshift+gear
//Vehicle_data.g_auto = (temp_message->data.byte[1]) >> 4;
case CAN_ID_BCU_ETC: { // eDrossel error bit
Vehicle_data.e_thro = (temp_message->data.byte[0] & 0xF0); // bit 4-7
if (temp_message->data.byte[0] & 0x80) {
Stw_data.error_type = 1; //"pc_error";
}
if (temp_message->data.byte[0] & 0x40) {
Stw_data.error_type = 2; //"bse_error";
}
if (temp_message->data.byte[0] & 0x20) {
Stw_data.error_type = 3; //"aps_error";
}
if (temp_message->data.byte[0] & 0x10) {
Stw_data.error_type = 4; //"etb_error";
}
break;
}
case CAN_ID_BCU_SHIFT_CTRL: { // autoshift+gear
Vehicle_data.gear = (temp_message->data.byte[1]) >> 5;
break;
}
case 0x773:{ // rpm
Vehicle_data.revol = (temp_message->data.byte[4] | temp_message->data.byte[3] << 8);
case CAN_ID_BCU_TIRES: { // Tire temps
Vehicle_data.t_trl = temp_message->data.byte[1];
Vehicle_data.t_trr = temp_message->data.byte[4];
Vehicle_data.t_tfl = temp_message->data.byte[5];
Vehicle_data.t_tfr = temp_message->data.byte[6];
break;
}
case 0x779:{ // battery voltage
case CAN_ID_BCU_LAP_TIME: { // lap time
Vehicle_data.lap_time_sec = temp_message->data.byte[1];
Vehicle_data.lap_time_msec =
temp_message->data.byte[2] | ((temp_message->data.byte[3] & 0b11) << 8);
break;
}
case CAN_ID_MS4_IGN_REV_ATH: { // rpm
Vehicle_data.revol =
(temp_message->data.byte[4] | temp_message->data.byte[3] << 8);
break;
}
case CAN_ID_MS4_SPEED: { // speed
Vehicle_data.speed_fl = 2 * (temp_message->data.byte[2]);
Vehicle_data.speed_fr = 2 * (temp_message->data.byte[3]);
Vehicle_data.speed = (Vehicle_data.speed_fl + Vehicle_data.speed_fr) / 2;
break;
}
case CAN_ID_MS4_ETC: { // battery voltage
Vehicle_data.u_batt = temp_message->data.byte[6];
break;
}
/*case 0x77A: // revolution limit bit
Vehicle_data.rev_lim = (temp_message->data.byte[3] & 0x20) >> 4;
switch(temp_message->data.byte[0]) {
case 0x02: // temp. intercooler
Vehicle_data.t_air = temp_message->data.byte[7];
break;
case 0x05: // temp. water
Vehicle_data.t_mot = temp_message->data.byte[4];
break;
case 0x04: // temp. oil
Vehicle_data.t_oil = temp_message->data.byte[5];
case 0x01: {
Vehicle_data.p_wat = temp_message->data.byte[6];
Vehicle_data.p_fuel = temp_message->data.byte[7];
Vehicle_data.p_oil = temp_message->data.byte[5];
break;
}
}
break;*/
case 0x77A:{//temp und p
//g_ms4_idle_b = (temp_message->data.byte[2] & 0b10000000) >> 7;
//g_ms4_engine_status = (temp_message->data.byte[3] & 0b01000000) >> 6;
//g_ms4_ignoff_b = (temp_message->data.byte[3] & 0b10000000) >> 7;
// Serial.println("CAN 77A");
// for (int i = 0; i < 8; i++) {
// Serial.print('[');
// Serial.print(i);
// Serial.print("] ");
// Serial.println(temp_message->data.byte[i], HEX);
// }
if ( temp_message->data.byte[0] == 1){
case CAN_ID_MS4_STATES_TEMP_PRESS: { // temp und p
if (temp_message->data.byte[0] == 1) {
Vehicle_data.p_oil = temp_message->data.byte[5];
Vehicle_data.p_fuel = temp_message->data.byte[7];
}
else if ( temp_message->data.byte[0] == 2){
} else if (temp_message->data.byte[0] == 2) {
Vehicle_data.t_air = temp_message->data.byte[7];
}
else if ( temp_message->data.byte[0] == 4){
} else if (temp_message->data.byte[0] == 4) {
Vehicle_data.t_oil = temp_message->data.byte[5];
}
else if ( temp_message->data.byte[0] == 5){
} else if (temp_message->data.byte[0] == 5) {
Vehicle_data.t_mot = temp_message->data.byte[4];
}
break;
}
case 0x775:{//speed
Vehicle_data.speed_fl = 2*(temp_message->data.byte[2]);
Vehicle_data.speed_fr = 2*(temp_message->data.byte[3]);
Vehicle_data.speed = (Vehicle_data.speed_fl+Vehicle_data.speed_fr)/2;
break;
}
/*case 0x777:{//m4_gear
Vehicle_data.gear = temp_message->data.byte[0];
break;
}*/
case 0x500:{
Vehicle_data.p_brake_front = temp_message->data.byte[1];
Vehicle_data.p_brake_rear = temp_message->data.byte[2];
break;
}
}
}
void update_LED(){
//Copyright Michael Dietzel
//m.dietzel@fasttube.de
//Edit Michael Witt 05-2015
//m.witt@fasttube.de
//EDIT BAHA ZARROUKI 05-2107
//z.baha@fasttube.de
void update_LED() {
// Copyright Michael Dietzel
// m.dietzel@fasttube.de
// Edit Michael Witt 05-2015
// m.witt@fasttube.de
// alle Werte als Hex-Werte angegeben
// EDIT BAHA ZARROUKI 05-2107
// z.baha@fasttube.de
// alle Werte als Hex-Werte angegeben
bool t_oil = (Vehicle_data.t_oil - 40) >= 0x96; // 150°C temp.oil
bool t_air = (Vehicle_data.t_air - 40) >= 0x3C; // 60°C temp.llk
bool t_mot = ((Vehicle_data.t_mot - 40) >= 0x69) and ((Vehicle_data.t_mot - 40)!=0xC8); // 105°C temp.water und !=200
bool t_mot =
((Vehicle_data.t_mot - 40) >= 0x69) and
((Vehicle_data.t_mot - 40) != 0xC8); // 105°C temp.water und !=200
bool g_auto = Vehicle_data.g_auto;
bool u_batt = Vehicle_data.u_batt <= 0xB1; // 12.5V batt.spann.
bool g_auto = Vehicle_data.drs_active;
bool u_batt = Vehicle_data.u_batt <= 0xA9; // 11.95V batt.spann.
bool e_dros = Vehicle_data.e_thro; // error-bit
bool rev_lim = Vehicle_data.rev_lim;
uint16_t rev = Vehicle_data.revol;
//uint16_t clearcounter = 1;
// if (clearcounter>= 5000){
//Can0.begin(1000000); // set CAN0 baud to 1kbit/s and don`t use enable pin!
//Can0.setNumTXBoxes(1); // reserves mailbox 0 for tx only 8 mailboxes are
// available (the other 7 mailboxes are for rx)
// We only have 7 mailboxes, but want to receive 9 messages. This trick should
// allow us to receive BCU_APS_BRAKE, BCU_ETC and BCU_SHIFT_CTRL in the same
// mailbox. It will also let through 0x506, but that shouldn't be much of an
// issue.
/* 10.09.2024 - auskommentiert, weil wieso hier nochmal watchfor? */
Can0.watchFor(CAN_ID_BCU_APS_BRAKE & CAN_ID_BCU_ETC & CAN_ID_BCU_SHIFT_CTRL, 0x7F9);
Can0.watchFor(CAN_ID_BCU_TIRES);
Can0.watchFor(CAN_ID_BCU_LAP_TIME);
Can0.watchFor(CAN_ID_MS4_IGN_REV_ATH);
Can0.watchFor(CAN_ID_MS4_SPEED);
Can0.watchFor(CAN_ID_MS4_ETC);
Can0.watchFor(CAN_ID_MS4_STATES_TEMP_PRESS);
//Can0.setGeneralCallback(Receive_Can_0);
//Timer3.attachInterrupt(Send_0x110); // set send interrupt
// Timer3.start(10000); // Calls every 10ms
// clearcounter = 0; //clearen des display nach definierter Zeit
// }
// clearcounter+=1;
/*if(Vehicle_data.rev_lim){
for (int j = 0; j < 10; j++){
digitalWrite(leds[j], HIGH);
//analogWrite(leds[j], STW_data.br); //nur eine der zwei zeilen
//analogWrite(leds[j], STW_data.br); //nur eine der zwei
zeilen
}
delay(100);
for (int j = 0; j < 10; j++){

12
lib/FT_2018_STW_CAN/FT_2018_STW_CAN.h
View File

@ -2,10 +2,22 @@
FT_2018_STW_CAN.h
*/
#pragma once
#include "Arduino.h"
#include "DueTimer.h"
#include "due_can.h"
#define CAN_ID_BCU_APS_BRAKE 0x500
#define CAN_ID_BCU_ETC 0x502
#define CAN_ID_BCU_SHIFT_CTRL 0x504
#define CAN_ID_BCU_TIRES 0x562
#define CAN_ID_BCU_LAP_TIME 0x570
#define CAN_ID_MS4_IGN_REV_ATH 0x773
#define CAN_ID_MS4_SPEED 0x775
#define CAN_ID_MS4_ETC 0x779
#define CAN_ID_MS4_STATES_TEMP_PRESS 0x77A
void Init_Can_0();
void Send_0x110();
void Receive_Can_0(CAN_FRAME *frame);

42
lib/FT_2018e_STW_CAN/FT_2018e_STW_CAN.cpp
View File

@ -2,22 +2,23 @@
FT_2018_STW_CAN.cpp
*/
#include "FT_2018e_STW_CAN.h"
#include "Arduino.h"
#include "DueTimer.h"
#include "due_can.h"
#include "FT_2018e_STW_CAN.h"
#include "FT18e_STW_INIT.h"
#include "due_can.h"
CAN_FRAME can_0_msg;
//can_1_msg.id = 0x110;
// can_1_msg.id = 0x110;
int can_0_temp_data = 0;
int leds[] = {led1, led2, led3, led4, led5, led6, led7, led8, led9, led10, led11, led12, led13, led14, led15, led16};
int leds[] = {led1, led2, led3, led4, led5, led6, led7, led8,
led9, led10, led11, led12, led13, led14, led15, led16};
void Init_Can_0()
{
void Init_Can_0() {
Serial.begin(9600);
Can0.begin(1000000); // set CAN0 baud to 1kbit/s and don`t use enable pin!
Can0.setNumTXBoxes(1); // reserves mailbox 0 for tx only 8 mailboxes are available (the other 7 mailboxes are for rx)
Can0.setNumTXBoxes(1); // reserves mailbox 0 for tx only 8 mailboxes are
// available (the other 7 mailboxes are for rx)
Can0.watchFor(CAN_CELL_STATS_ID);
Can0.watchFor(CAN_BATTERY_STATS_ID);
Can0.watchFor(CAN_COOLING_STATS_ID);
@ -27,8 +28,7 @@ void Init_Can_0()
Timer3.start(10000); // Calls every 10ms
}
void Send_0x110()
{
void Send_0x110() {
read_buttons();
read_rotary();
can_0_msg.id = 0x110;
@ -47,10 +47,8 @@ void Send_0x110()
Can0.sendFrame(can_0_msg);
}
void Receive_Can_0(CAN_FRAME *temp_message)
{
switch (temp_message->id)
{
void Receive_Can_0(CAN_FRAME *temp_message) {
switch (temp_message->id) {
case CAN_CELL_STATS_ID:
process_cell_stats(temp_message);
break;
@ -70,21 +68,18 @@ void Receive_Can_0(CAN_FRAME *temp_message)
}
}
void process_cell_stats(CAN_FRAME *frame)
{
void process_cell_stats(CAN_FRAME *frame) {
CellStats *data = (CellStats *)&frame->data;
Vehicle_data.t_cell_max = data->max_cell_temp;
Vehicle_data.u_cell_min = data->min_cell_voltage;
}
void process_battery_stats(CAN_FRAME *frame)
{
void process_battery_stats(CAN_FRAME *frame) {
BatteryStats *data = (BatteryStats *)&frame->data;
Vehicle_data.u_batt = data->pre_air_voltage;
}
void process_cooling_stats(CAN_FRAME *frame)
{
void process_cooling_stats(CAN_FRAME *frame) {
CoolingStats *data = (CoolingStats *)&frame->data;
Vehicle_data.p_wat = data->water_pressure;
Vehicle_data.t_wat = data->water_temp;
@ -92,8 +87,7 @@ void process_cooling_stats(CAN_FRAME *frame)
Vehicle_data.t_mot_r = data->motor_r_temp;
}
void process_inverter_stats(CAN_FRAME *frame)
{
void process_inverter_stats(CAN_FRAME *frame) {
InverterStats *data = (InverterStats *)&frame->data;
uint8_t status = data->status;
Vehicle_data.inverter.ready = status & CAN_INVERTER_STATS_READY;
@ -109,9 +103,9 @@ void process_inverter_stats(CAN_FRAME *frame)
Vehicle_data.wheel_speed = data->wheel_speed;
}
void update_LED()
{
bool t_mot = (Vehicle_data.t_mot_l > LED_THRESH_T_MOT) || (Vehicle_data.t_mot_r > LED_THRESH_T_MOT);
void update_LED() {
bool t_mot = (Vehicle_data.t_mot_l > LED_THRESH_T_MOT) ||
(Vehicle_data.t_mot_r > LED_THRESH_T_MOT);
bool t_inv = Vehicle_data.t_inv > LED_THRESH_T_INV;
bool t_bat = Vehicle_data.t_cell_max > LED_THRESH_T_BAT;

12
lib/FT_2018e_STW_CAN/FT_2018e_STW_CAN.h
View File

@ -31,32 +31,28 @@ void process_cooling_stats(CAN_FRAME *frame);
void process_inverter_stats(CAN_FRAME *frame);
void update_LED(void);
struct CellStats
{
struct CellStats {
uint16_t sum_cell_voltage;
int16_t max_cell_temp;
uint16_t max_cell_voltage;
uint16_t min_cell_voltage;
};
struct BatteryStats
{
struct BatteryStats {
uint16_t battery_current;
uint16_t pre_air_voltage;
uint16_t post_air_voltage;
uint16_t battery_power;
};
struct CoolingStats
{
struct CoolingStats {
int16_t water_pressure;
int16_t water_temp;
int16_t motor_l_temp;
int16_t motor_r_temp;
};
struct InverterStats
{
struct InverterStats {
uint8_t status;
uint8_t _reserved;
uint16_t temp;

666
lib/arduino-ediptft-master/EDIPTFT.cpp
View File

@ -1,4 +1,4 @@
//
//
// Library for controlling Electronic Assembly eDIPTFT displays
//
// Copyright (c) 2013 Stefan Gofferje. All rights reserved.
@ -25,56 +25,40 @@
#include "Arduino.h"
#define DEBUG false
EDIPTFT::EDIPTFT(boolean smallprotocol, boolean disconnected)
: _smallprotocol{smallprotocol}, disconnected{disconnected} {}
void EDIPTFT::begin(long baud) { SERIAL_DEV.begin(baud); }
void EDIPTFT::begin(long baud) {
SERIAL_DEV.begin(baud);
}
void EDIPTFT::sendByte(char data) {
SERIAL_DEV.write(data);
}
char EDIPTFT::readByte() {
return SERIAL_DEV.read();
}
void EDIPTFT::sendByte(char data) { SERIAL_DEV.write(data); }
char EDIPTFT::readByte() { return SERIAL_DEV.read(); }
void EDIPTFT::waitBytesAvailable() {
const uint32_t t_start = millis();
char loop = 0;
while (loop == 0)
{
if (bytesAvailable() != 0){
while (loop == 0) {
if (bytesAvailable() != 0) {
loop = 1;
}
if(t_start + 100 < millis())
{
//Serial.println("Error: waited to long!");
loop =1;
if (t_start + 100 < millis()) {
// Serial.println("Error: waited to long!");
loop = 1;
}
}
}
char EDIPTFT::waitandreadByte() {
waitBytesAvailable();
char result = readByte();
return(result);
return (result);
}
unsigned char EDIPTFT::bytesAvailable() {
return SERIAL_DEV.available();
//ÄNDERN
}
void EDIPTFT::sendData(char* data, char len) {
/*for(int i=0; i < len; i++) {
@ -86,7 +70,7 @@ void EDIPTFT::sendData(char* data, char len) {
if (DEBUG) {
unsigned char i;
for (i = 0; i < len; i++) {
//Serial.print(byte(data[i]), HEX);
// Serial.print(byte(data[i]), HEX);
SERIAL_DEV.print(byte(data[i]), HEX);
SERIAL_DEV.print(" ");
}
@ -95,16 +79,14 @@ void EDIPTFT::sendData(char* data, char len) {
if (_smallprotocol) {
sendSmall(data, len);
}
else {
} else {
unsigned char i;
for(i=0; i < len; i++) {
for (i = 0; i < len; i++) {
sendByte(data[i]);
}
}
}
void EDIPTFT::sendSmall(char* data, char len) {
if (disconnected) {
return;
@ -121,7 +103,7 @@ void EDIPTFT::sendSmall(char* data, char len) {
sendByte(len);
bcc = bcc + len;
for(i=0; i < len; i++) {
for (i = 0; i < len; i++) {
sendByte(data[i]);
bcc = bcc + data[i];
}
@ -129,13 +111,13 @@ void EDIPTFT::sendSmall(char* data, char len) {
waitBytesAvailable();
if (bytesAvailable() > 0) {
char x = readByte();
//Serial.print(uint16_t(x));
if (x == ACK) ok = 1;
// Serial.print(uint16_t(x));
if (x == ACK)
ok = 1;
else {
ok = 0;
}
}
else {
} else {
delay(200);
ok = 0;
}
@ -146,7 +128,6 @@ void EDIPTFT::sendSmall(char* data, char len) {
}
}
void EDIPTFT::sendSmallDC2(char* data, char len) {
unsigned char i, bcc;
char ok = 0;
@ -156,307 +137,268 @@ void EDIPTFT::sendSmallDC2(char* data, char len) {
sendByte(0x12);
bcc = 0x12;
for(i=0; i < len; i++) {
for (i = 0; i < len; i++) {
sendByte(data[i]);
bcc = bcc + data[i];
}
sendByte(bcc);
waitBytesAvailable(); //delay(6); im 17er
waitBytesAvailable(); // delay(6); im 17er
if (bytesAvailable() > 0) {
if (readByte() == ACK) ok = 1;
else ok = 0;
}
else {
if (readByte() == ACK)
ok = 1;
else
ok = 0;
} else {
delay(200);
ok = 0;
}
}
}
void EDIPTFT::smallProtoSelect(char address) {
char command [] = {
0x03, 'A', 'S', address
};
char command[] = {0x03, 'A', 'S', address};
sendSmallDC2(command, sizeof(command));
}
void EDIPTFT::smallProtoDeselect(char address) {
char command [] = {
0x03, 'A', 'D', address
};
char command[] = {0x03, 'A', 'D', address};
sendSmallDC2(command, sizeof(command));
}
unsigned char EDIPTFT::datainBuffer() {
unsigned char result;
char command [] = {
0x01, 'I'
};
char command[] = {0x01, 'I'};
sendSmallDC2(command, sizeof(command));
waitandreadByte();
waitandreadByte();
result=waitandreadByte();
result = waitandreadByte();
waitandreadByte();
waitandreadByte();
return result;
}
int EDIPTFT::readBuffer(char* data) { //return void
int EDIPTFT::readBuffer(char* data) { // return void
unsigned char len, i; // char in 17er
char command [] = {
0x01, 'S'
};
char command[] = {0x01, 'S'};
sendSmallDC2(command, sizeof(command));
waitandreadByte();
len=waitandreadByte();
len = waitandreadByte();
char result[len];
for (i = 0; i < len; i++) {
result[i] = waitandreadByte();
}
memcpy(data, result, len);
waitandreadByte();
return len; //zeile nicht vorhanden
return len; // zeile nicht vorhanden
}
void EDIPTFT::clear() { //vgl 17er
void EDIPTFT::clear() { // vgl 17er
this->deleteDisplay();
this->removeTouchArea(0, 1);
}
void EDIPTFT::deleteDisplay() {
char command [] = {
27, 'D', 'L'
};
char command[] = {27, 'D', 'L'};
sendData(command, sizeof(command));
}
void EDIPTFT::invert() {
char command [] = {
27, 'D', 'I'
};
char command[] = {27, 'D', 'I'};
sendData(command, sizeof(command));
}
void EDIPTFT::setDisplayColor(char fg, char bg) {
char command [] = {
27, 'F', 'D', fg, bg
};
char command[] = {27, 'F', 'D', fg, bg};
sendData(command, sizeof(command));
}
void EDIPTFT::fillDisplayColor(char bg) {
char command [] = {
27, 'D', 'F', bg
};
char command[] = {27, 'D', 'F', bg};
sendData(command, sizeof(command));
}
void EDIPTFT::terminalOn(boolean on) {
if (on) {
char command [] = {27, 'T', 'E'};
char command[] = {27, 'T', 'E'};
sendData(command, sizeof(command));
}
else {
char command [] = {27, 'T', 'A'};
} else {
char command[] = {27, 'T', 'A'};
sendData(command, sizeof(command));
}
}
void EDIPTFT::loadImage(int x1, int y1, int nr) {
char command [] = {27, 'U', 'I',
#if COORD_SIZE == 1
(char)x1, (char)y1,
#else
lowByte(x1), highByte(x1), lowByte(y1), highByte(y1),
#endif
nr};
char command[] = {
27,
'U',
'I',
#if COORD_SIZE == 1
(char)x1,
(char)y1,
#else
lowByte(x1),
highByte(x1),
lowByte(y1),
highByte(y1),
#endif
nr
};
sendData(command, sizeof(command));
}
void EDIPTFT::cursorOn(boolean on) {
if (on) {
char command [] = {27, 'T', 'C', 1};
char command[] = {27, 'T', 'C', 1};
sendData(command, sizeof(command));
}
else {
char command [] = {27, 'T', 'C', 0};
} else {
char command[] = {27, 'T', 'C', 0};
sendData(command, sizeof(command));
}
}
void EDIPTFT::setCursor(char col, char row) {
char command [] = {27, 'T', 'P', col, row};
char command[] = {27, 'T', 'P', col, row};
sendData(command, sizeof(command));
}
void EDIPTFT::displayLight(char no) {
char command [] = {
27, 'Y', 'H', no
};
char command[] = {27, 'Y', 'H', no};
sendData(command, sizeof(command));
}
void EDIPTFT::defineBargraph(char dir, char no, int x1, int y1, int x2, int y2, byte sv, byte ev, char type, char mst) {
char command [] = {
27, 'B', dir, no,
#if COORD_SIZE == 1
x1, y1, x2, y2,
#else
lowByte(x1), highByte(x1), lowByte(y1), highByte(y1),
lowByte(x2), highByte(x2), lowByte(y2), highByte(y2),
#endif
void EDIPTFT::defineBargraph(char dir, char no, int x1, int y1, int x2, int y2,
byte sv, byte ev, char type, char mst) {
char command[] = {
27,
'B',
dir,
no,
#if COORD_SIZE == 1
x1,
y1,
x2,
y2,
#else
lowByte(x1),
highByte(x1),
lowByte(y1),
highByte(y1),
lowByte(x2),
highByte(x2),
lowByte(y2),
highByte(y2),
#endif
char(sv),
char(ev),
type,
mst
};
sendData(command, sizeof(command));
//mst fehlt 17
// mst fehlt 17
}
void EDIPTFT::updateBargraph(char no, char val) {
char command [] = {
27, 'B', 'A', no, val
};
char command[] = {27, 'B', 'A', no, val};
sendData(command, sizeof(command));
}
void EDIPTFT::setBargraphColor(char no, char fg, char bg, char fr) {
char command [] = {
27, 'F', 'B', no, fg, bg, fr
};
char command[] = {27, 'F', 'B', no, fg, bg, fr};
sendData(command, sizeof(command));
}
void EDIPTFT::linkBargraphLight(char no) {
char command [] = {
27, 'Y', 'B', no
};
char command[] = {27, 'Y', 'B', no};
sendData(command, sizeof(command));
}
void EDIPTFT::makeBargraphTouch(char no) {
char command [] = {
27, 'A', 'B', no
};
char command[] = {27, 'A', 'B', no};
sendData(command, sizeof(command));
}
void EDIPTFT::deleteBargraph(char no,char n1) {
char command [] = {
27, 'B', 'D', no, n1
};
void EDIPTFT::deleteBargraph(char no, char n1) {
char command[] = {27, 'B', 'D', no, n1};
sendData(command, sizeof(command));
}
void EDIPTFT::defineInstrument(char no, int x1, int y1, char image, char angle, char sv, char ev) {
char command [] = {
27, 'I', 'P', no,
#if COORD_SIZE == 1
x1, y1,
#else
lowByte(x1), highByte(x1), lowByte(y1), highByte(y1),
#endif
image, angle, sv, ev
void EDIPTFT::defineInstrument(char no, int x1, int y1, char image, char angle,
char sv, char ev) {
char command[] = {
27,
'I',
'P',
no,
#if COORD_SIZE == 1
x1,
y1,
#else
lowByte(x1),
highByte(x1),
lowByte(y1),
highByte(y1),
#endif
image,
angle,
sv,
ev
};
sendData(command, sizeof(command));
}
void EDIPTFT::updateInstrument(char no, char val) {
char command [] = {
27, 'I', 'A', no, val
};
char command[] = {27, 'I', 'A', no, val};
sendData(command, sizeof(command));
}
void EDIPTFT::redrawInstrument(char no) {
char command [] = {
27, 'I', 'N', no
};
char command[] = {27, 'I', 'N', no};
sendData(command, sizeof(command));
}
void EDIPTFT::deleteInstrument(char no, char n1, char n2) {
char command [] = {
27, 'B', 'D', no, n1, n2
};
char command[] = {27, 'B', 'D', no, n1, n2};
sendData(command, sizeof(command));
}
void EDIPTFT::setLineColor(char fg, char bg) {
char command [] = {
27, 'F', 'G', fg, bg
};
char command[] = {27, 'F', 'G', fg, bg};
sendData(command, sizeof(command));
}
void EDIPTFT::setLineThick(char x, char y) {
char command [] = {
27, 'G', 'Z', x, y
};
char command[] = {27, 'G', 'Z', x, y};
sendData(command, sizeof(command));
}
void EDIPTFT::setTextColor(char fg, char bg) {
char command [] = {
27, 'F', 'Z', fg, bg
};
char command[] = {27, 'F', 'Z', fg, bg};
sendData(command, sizeof(command));
}
void EDIPTFT::setTextFont(char font) {
char command [] = {
27, 'Z', 'F', font
};
char command[] = {27, 'Z', 'F', font};
sendData(command, sizeof(command));
}
void EDIPTFT::setTextSize(int xsize, int ysize){
void EDIPTFT::setTextSize(int xsize, int ysize) {
char command[] = {27, 'Z', 'Z', xsize, ysize};
sendData(command,sizeof(command));
sendData(command, sizeof(command));
}
void EDIPTFT::setTextAngle(char angle) {
// 0 = 0°, 1 = 90°, 2 = 180°, 3 = 270°
char command [] = {
27, 'Z', 'W', angle
};
char command[] = {27, 'Z', 'W', angle};
sendData(command, sizeof(command));
}
void EDIPTFT::drawText(uint16_t x1, uint16_t y1, char justification, const char* text) {
//nicht const 17//
void EDIPTFT::drawText(uint16_t x1, uint16_t y1, char justification,
const char* text) {
// nicht const 17//
byte len = strlen(text);
byte i;
char helper [3 + 4 + len + 1];
helper[0] = 27; //esc
char helper[3 + 4 + len + 1];
helper[0] = 27; // esc
helper[1] = 'Z';
helper[2] = justification;
helper[3] = x1 & 0xFF;
@ -470,228 +412,318 @@ void EDIPTFT::drawText(uint16_t x1, uint16_t y1, char justification, const char*
sendData(helper, sizeof(helper));
}
void EDIPTFT::drawTextInRect(int x1, int y1, int x2, int y2, uint8_t align,
const char* text) {
int len_text = strlen(text);
int len = 3 + 8 + 1 + len_text + 1;
char data[len] = {27, 'Z', 'B', lowByte(x1),
highByte(x1), lowByte(y1), highByte(y1), lowByte(x2),
highByte(x2), lowByte(y2), highByte(y2), align};
for (int i = 0; i < len_text; i++) {
data[3 + 8 + 1 + i] = text[i];
}
data[len - 1] = 0;
sendData(data, len);
}
void EDIPTFT::drawLine(int x1, int y1, int x2, int y2) {
char command [] = {
27,'G','D',
#if COORD_SIZE == 1
x1, y1, x2, y2
#else
lowByte(x1),highByte(x1),lowByte(y1),highByte(y1),
lowByte(x2),highByte(x2),lowByte(y2),highByte(y2)
#endif
char command[] = {
27,
'G',
'D',
#if COORD_SIZE == 1
x1,
y1,
x2,
y2
#else
lowByte(x1),
highByte(x1),
lowByte(y1),
highByte(y1),
lowByte(x2),
highByte(x2),
lowByte(y2),
highByte(y2)
#endif
};
sendData(command, sizeof(command));
}
void EDIPTFT::drawRect(int x1, int y1, int x2, int y2) {
char command [] = {
27,'G','R',
#if COORD_SIZE == 1
x1, y1, x2, y2
#else
lowByte(x1),highByte(x1),lowByte(y1),highByte(y1),
lowByte(x2),highByte(x2),lowByte(y2),highByte(y2)
#endif
char command[] = {
27,
'G',
'R',
#if COORD_SIZE == 1
x1,
y1,
x2,
y2
#else
lowByte(x1),
highByte(x1),
lowByte(y1),
highByte(y1),
lowByte(x2),
highByte(x2),
lowByte(y2),
highByte(y2)
#endif
};
sendData(command, sizeof(command));
}
void EDIPTFT::drawRectf(int x1, int y1, int x2, int y2, char color) {
char command [] = {
27,'R','F',
#if COORD_SIZE == 1
x1, y1, x2, y2,
#else
lowByte(x1),highByte(x1),lowByte(y1),highByte(y1),
lowByte(x2),highByte(x2),lowByte(y2),highByte(y2),
#endif
char command[] = {
27,
'R',
'F',
#if COORD_SIZE == 1
x1,
y1,
x2,
y2,
#else
lowByte(x1),
highByte(x1),
lowByte(y1),
highByte(y1),
lowByte(x2),
highByte(x2),
lowByte(y2),
highByte(y2),
#endif
color
};
sendData(command, sizeof(command));
}
void EDIPTFT::clearRect(int x1, int y1, int x2, int y2) {
Serial.print("Clearing ");
Serial.print(x1);
Serial.print(", ");
Serial.print(y1);
Serial.print(", ");
Serial.print(x2);
Serial.print(", ");
Serial.println(y2);
char command[] = {
27,
'R',
'L',
#if COORD_SIZE == 1
x1,
y1,
x2,
y2
#else
lowByte(x1),
highByte(x1),
lowByte(y1),
highByte(y1),
lowByte(x2),
highByte(x2),
lowByte(y2),
highByte(y2),
#endif
};
sendData(command, sizeof(command));
}
void EDIPTFT::defineTouchKey(int x1, int y1, int x2, int y2, char down, char up,
const char* text) { //text nicht const 17
const char* text) { // text nicht const 17
byte len = strlen(text);
byte i;
char helper [len + 6 + 4 * COORD_SIZE];//len+13 17
char command [] = {
27, 'A', 'T',
#if COORD_SIZE == 1
x1, y1, x2, y2,
#else
lowByte(x1), highByte(x1), lowByte(y1), highByte(y1),
lowByte(x2), highByte(x2), lowByte(y2), highByte(y2),
#endif
down, up
char helper[len + 6 + 4 * COORD_SIZE]; // len+13 17
char command[] = {
27,
'A',
'T',
#if COORD_SIZE == 1
x1,
y1,
x2,
y2,
#else
lowByte(x1),
highByte(x1),
lowByte(y1),
highByte(y1),
lowByte(x2),
highByte(x2),
lowByte(y2),
highByte(y2),
#endif
down,
up
};
for (i = 0; i < (5 + 4 * COORD_SIZE); i++) helper[i] = command[i];//i<=12 17
for (i = 0; i <= len+1; i++) helper[i + 5 + 4 * COORD_SIZE] = text[i];//i<=len 17
sendData(helper, sizeof(helper));//size len+14 17
for (i = 0; i < (5 + 4 * COORD_SIZE); i++)
helper[i] = command[i]; // i<=12 17
for (i = 0; i <= len + 1; i++)
helper[i + 5 + 4 * COORD_SIZE] = text[i]; // i<=len 17
sendData(helper, sizeof(helper)); // size len+14 17
}
void EDIPTFT::defineTouchSwitch(int x1, int y1, int x2, int y2,
char down, char up, const char* text) {//const nicht 17
void EDIPTFT::defineTouchSwitch(int x1, int y1, int x2, int y2, char down,
char up, const char* text) { // const nicht 17
byte len = strlen(text);
byte i;
char helper [len + 6 + 4 * COORD_SIZE];//len+13 17
char command [] = {
27, 'A', 'K',
#if COORD_SIZE == 1
x1, y1, x2, y2,
#else
lowByte(x1),highByte(x1),lowByte(y1),highByte(y1),
lowByte(x2),highByte(x2),lowByte(y2),highByte(y2),
#endif
down, up
char helper[len + 6 + 4 * COORD_SIZE]; // len+13 17
char command[] = {
27,
'A',
'K',
#if COORD_SIZE == 1
x1,
y1,
x2,
y2,
#else
lowByte(x1),
highByte(x1),
lowByte(y1),
highByte(y1),
lowByte(x2),
highByte(x2),
lowByte(y2),
highByte(y2),
#endif
down,
up
};
for (i = 0; i < 5 + 4 * COORD_SIZE; i++) helper[i] = command[i];
for (i = 0; i <= len; i++) helper[i + 5 + 4 * COORD_SIZE] = text[i];
sendData(helper, sizeof(helper));//size len+14
for (i = 0; i < 5 + 4 * COORD_SIZE; i++)
helper[i] = command[i];
for (i = 0; i <= len; i++)
helper[i + 5 + 4 * COORD_SIZE] = text[i];
sendData(helper, sizeof(helper)); // size len+14
}
void EDIPTFT::defineTouchSwitch(int x, int y, int img, char downcode,
char upcode, const char* text) {
byte len = strlen(text);
byte i;
byte n = 6 + 2 * COORD_SIZE;
char helper [len + n + 1];
char command [] = {
27, 'A', 'J',
#if COORD_SIZE == 1
x, y,
#else
lowByte(x), highByte(x), lowByte(y), highByte(y),
#endif
img, downcode, upcode
char helper[len + n + 1];
char command[] = {
27,
'A',
'J',
#if COORD_SIZE == 1
x,
y,
#else
lowByte(x),
highByte(x),
lowByte(y),
highByte(y),
#endif
img,
downcode,
upcode
};
for (i = 0; i < n; i++) helper[i] = command[i];
for (i = 0; i <= len; i++) helper[i + n] = text[i];
for (i = 0; i < n; i++)
helper[i] = command[i];
for (i = 0; i <= len; i++)
helper[i + n] = text[i];
sendData(helper, sizeof(helper));
}
void EDIPTFT::setTouchSwitch(char code,char value) {
char command [] = {
27, 'A', 'P', code, value
};
void EDIPTFT::setTouchSwitch(char code, char value) {
char command[] = {27, 'A', 'P', code, value};
sendData(command, sizeof(command));
}
void EDIPTFT::setTouchkeyColors(
char n1, char n2, char n3, char s1, char s2, char s3) {
char command [] = {
27, 'F', 'E', n1, n2, n3, s1, s2, s3
};
void EDIPTFT::setTouchkeyColors(char n1, char n2, char n3, char s1, char s2,
char s3) {
char command[] = {27, 'F', 'E', n1, n2, n3, s1, s2, s3};
sendData(command, sizeof(command));
}
void EDIPTFT::setTouchkeyFont(char font) {
char command [] = {
27, 'A', 'F', font
};
char command[] = {27, 'A', 'F', font};
sendData(command, sizeof(command));
}
void EDIPTFT::setTouchkeyLabelColors(char nf, char sf) {
char command [] = {
27, 'F', 'A', nf, sf
};
char command[] = {27, 'F', 'A', nf, sf};
sendData(command, sizeof(command));
}
void EDIPTFT::setTouchGroup(char group) {
char command [] = {
27, 'A', 'R', group
};
char command[] = {27, 'A', 'R', group};
sendData(command, sizeof(command));
}
void EDIPTFT::removeTouchArea(char code, char n1) {
char command [] = {
27, 'A', 'L', code, n1
};
char command[] = {27, 'A', 'L', code, n1};
sendData(command, sizeof(command));
}
void EDIPTFT::callMacro(uint nr) {
char command[] = {
27, 'M', 'N', nr
};
char command[] = {27, 'M', 'N', nr};
sendData(command, sizeof(command));
}
void EDIPTFT::callTouchMacro(uint nr) {
char command[] = {
27, 'M', 'T', nr
};
char command[] = {27, 'M', 'T', nr};
sendData(command, sizeof(command));
}
void EDIPTFT::callMenuMacro(uint nr) {
char command[] = {
27, 'M', 'M', nr
};
char command[] = {27, 'M', 'M', nr};
sendData(command, sizeof(command));
}
void EDIPTFT::defineTouchMenu(int x1, int y1, int x2, int y2,
char downcode, char upcode, char mnucode, const char *text) {
void EDIPTFT::defineTouchMenu(int x1, int y1, int x2, int y2, char downcode,
char upcode, char mnucode, const char* text) {
byte len = strlen(text);
byte n = 6 + 4 * COORD_SIZE;
char helper [len + n + 1];
char helper[len + n + 1];
char command [] = {
27, 'A', 'M',
#if COORD_SIZE == 1
x1, y1, x2, y2,
#else
lowByte(x1),highByte(x1),lowByte(y1),highByte(y1),
lowByte(x2),highByte(x2),lowByte(y2),highByte(y2),
#endif
downcode, upcode, mnucode
char command[] = {
27,
'A',
'M',
#if COORD_SIZE == 1
x1,
y1,
x2,
y2,
#else
lowByte(x1),
highByte(x1),
lowByte(y1),
highByte(y1),
lowByte(x2),
highByte(x2),
lowByte(y2),
highByte(y2),
#endif
downcode,
upcode,
mnucode
};
for (int i = 0; i < n; i++) helper[i] = command[i];
for (int i = 0; i <= len; i++) helper[i + n] = text[i];
for (int i = 0; i < n; i++)
helper[i] = command[i];
for (int i = 0; i <= len; i++)
helper[i + n] = text[i];
sendData(helper, sizeof(helper));
}
void EDIPTFT::openTouchMenu() {
char command [] = {
27, 'N', 'T', 2
};
char command[] = {27, 'N', 'T', 2};
sendData(command, sizeof(command));
}
void EDIPTFT::setMenuFont(char font) {
char command [] = {
27, 'N', 'F', font
};
char command[] = {27, 'N', 'F', font};
sendData(command, sizeof(command));
}
void EDIPTFT::setTouchMenuAutomation(bool val) {
char n1 = val ? 1 : 0;
char command [] = {
27, 'N', 'T', n1
};
char command[] = {27, 'N', 'T', n1};
sendData(command, sizeof(command));
}

83
lib/arduino-ediptft-master/EDIPTFT.h
View File

@ -26,17 +26,18 @@
#include "Arduino.h"
//Devices
// Devices
#define EDIP128 1
#define EDIP160 1
#define EDIP240 1
#define EDIP320 2
//Set your device
// Set your device
#define DEVICE EDIP320
#define COORD_SIZE DEVICE //Byte count for coordinates
#define COORD_SIZE DEVICE // Byte count for coordinates
#define SERIAL_DEV Serial3
#define EA_TRANSPARENT 0
#define EA_BLACK 1
#define EA_BLUE 2
#define EA_RED 3
@ -71,11 +72,11 @@
#define uint unsigned int
class EDIPTFT {
public:
EDIPTFT(boolean smallprotocol=true, boolean disconnected=false);
public:
EDIPTFT(boolean smallprotocol = true, boolean disconnected = false);
boolean disconnected;
void begin(long baud=115200);
void begin(long baud = 115200);
// helper functions
char readByte();
@ -207,8 +208,8 @@ class EDIPTFT {
void deleteBargraph(char no, char n1);
// Instrument
void defineInstrument(char no, int x1, int y1, char image,
char angle, char sv, char ev);
void defineInstrument(char no, int x1, int y1, char image, char angle,
char sv, char ev);
void updateInstrument(char no, char val);
void redrawInstrument(char no);
void deleteInstrument(char no, char n1, char n2);
@ -252,6 +253,22 @@ class EDIPTFT {
*/
void drawText(uint16_t x1, uint16_t y1, char justification, const char* text);
/*! \brief Draw text on display in an area
*
* Draw a *text* on screen. Several lines are separated by the character `|`
* ($7C).
* * place text between `~`: characters flash on/off
* * place text between `@`: characters flash inversely
* * use `\\` as to escape special characters
*
* \param align set alignment in the rectangle. 1 = top left, 2 = top
* center, 3 = top right, 4 = center left, 5 = center, 6 = center right, 7 =
* bottom left, 8 = bottom center, 9 = bottom right.
* \param text text to draw on display
*/
void drawTextInRect(int x1, int y1, int x2, int y2, uint8_t align,
const char* text);
// Rectangle and Line
void setLineColor(char fg, char bg);
@ -276,6 +293,9 @@ class EDIPTFT {
void drawRectf(int x1, int y1, int x2, int y2, char color);
/*! \brief Clear rectangular area */
void clearRect(int x1, int y1, int x2, int y2);
// Touch keys
/*! \brief Define touch key
@ -290,8 +310,8 @@ class EDIPTFT {
* \param up return/touchmacro (1-255) if released
* \param text label of the touch key
*/
void defineTouchKey(int x1, int y1, int x2, int y2,
char down, char up, const char* text);
void defineTouchKey(int x1, int y1, int x2, int y2, char down, char up,
const char* text);
/*! \brief Define touch switch
*
@ -305,8 +325,8 @@ class EDIPTFT {
* \param up return/touchmacro (1-255) if released
* \param text label of the touch key
*/
void defineTouchSwitch(int x1, int y1, int x2, int y2,
char down, char up, const char* text);
void defineTouchSwitch(int x1, int y1, int x2, int y2, char down, char up,
const char* text);
/*! \brief Define touch switch with image
*
@ -320,8 +340,8 @@ class EDIPTFT {
* \param up return/touchmacro (1-255) if released
* \param text label of the touch switch
*/
void defineTouchSwitch(int x, int y, int img, char downcode,
char upcode, const char* text);
void defineTouchSwitch(int x, int y, int img, char downcode, char upcode,
const char* text);
/*! \brief Set touch switch
*
@ -331,10 +351,9 @@ class EDIPTFT {
* \param code Return code of the switch
* \param value `value=0`: OFF, `value=1`: ON
*/
void setTouchSwitch(char code,char value);
void setTouchSwitch(char code, char value);
void setTouchkeyColors(char n1, char n2, char n3,
char s1, char s2, char s3);
void setTouchkeyColors(char n1, char n2, char n3, char s1, char s2, char s3);
/*! \brief Label font
*
@ -342,7 +361,7 @@ class EDIPTFT {
*/
void setTouchkeyFont(char font);
void setTouchkeyLabelColors(char nf,char sf);
void setTouchkeyLabelColors(char nf, char sf);
/*! \brief Radio group for switches
*
@ -363,7 +382,7 @@ class EDIPTFT {
* \param n1 n1==0: the area remains visible on the display,
* n1==1: the area is deleted
*/
void removeTouchArea(char code,char n1);
void removeTouchArea(char code, char n1);
// Macro Calls
/*! \brief Run macro
@ -387,21 +406,23 @@ class EDIPTFT {
/*! \brief Define touch key with menu function
*
* Define the area from *x1*, *y1* to *x2*, *y2* as a menu key.
* The first character determines the direction in which the menu opens (R=right,L=left,O=up,U=down)
* The second character determines the alignment of the touch text (C=center,L=left-,R=right justified)
* The menu items are separated by the character '|' ($7C,dec:124) (e.g. "UCkey|item1|item2|item3".
* The key text is written with the current touch font and the menu items are written with the current menu font. The background of the menu is saved automatically.
* \param downcode `1-255` return/touchmacro if pressed
* \param upcode `1-255` return/touchmacro if released
* \param mnucode return/menumacro+(item nr - 1) after selection of a
* The first character determines the direction in which the menu opens
* (R=right,L=left,O=up,U=down) The second character determines the alignment
* of the touch text (C=center,L=left-,R=right justified) The menu items are
* separated by the character '|' ($7C,dec:124) (e.g.
* "UCkey|item1|item2|item3". The key text is written with the current touch
* font and the menu items are written with the current menu font. The
* background of the menu is saved automatically. \param downcode `1-255`
* return/touchmacro if pressed \param upcode `1-255` return/touchmacro if
* released \param mnucode return/menumacro+(item nr - 1) after selection of a
* menu item
* \param text string with the key text and menu items
*/
void defineTouchMenu(int x1, int y1, int x2, int y2,
char downcode, char upcode, char mnucode,
const char *text);
void defineTouchMenu(int x1, int y1, int x2, int y2, char downcode,
char upcode, char mnucode, const char* text);
/*! \brief Send *open* signal after a Menu open request has been sent from TFT.
/*! \brief Send *open* signal after a Menu open request has been sent from
* TFT.
*
* If a touch menu is not set to open automatically the TFT sends a
* request 'ESC T 0'. This function sends 'ESC N T 2' to open the menu.
@ -422,7 +443,7 @@ class EDIPTFT {
*/
void setTouchMenuAutomation(bool val);
private:
private:
boolean _smallprotocol;
int _counter;
unsigned char bytesAvailable();