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base: doohoyi:dcf62905a2ec811b914904af4a03eb0a4e96bb12
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doohoyi:main
doohoyi:master
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compare: doohoyi:fe4b1f120b2e8075bb5d6dbfc43558af783722f8
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doohoyi:main
doohoyi:master

3 commits
dcf62905a2 ... fe4b1f120b

Author SHA1 Message Date
Dooho Yi
fe4b1f120b added 'buzz' 
a tone generator.
 2024-10-30 20:57:24 +09:00
Dooho Yi
0e0157db06 updated 'p' 
more straightforward que generation.
 2024-10-30 20:57:01 +09:00
Dooho Yi
410b42c303 added 'looping task' 
- with looping_task enabled => audio will always keep playing. (non 
stop.)
 2024-10-30 20:50:38 +09:00
4 changed files with 974 additions and 589 deletions
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673
audioooo/src/main.cpp
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@ -16,7 +16,7 @@
//============<identities>============
//
#define MY_GROUP_ID (10000)
#define MY_ID (MY_GROUP_ID + 7)
#define MY_ID (MY_GROUP_ID + 2)
#define MY_SIGN ("AUDIOOOO")
#define ADDRESSBOOK_TITLE ("broadcast only")
//
@ -135,44 +135,44 @@ String screen_filename = "/___.mp3";
extern Task screen_cmd_notify_task;
bool cmd_notify = false;
void screen_cmd_notify() {
if (screen_cmd_notify_task.isFirstIteration()) cmd_notify = true;
else if (screen_cmd_notify_task.isLastIteration()) cmd_notify = false;
else cmd_notify = !cmd_notify;
if (screen_cmd_notify_task.isFirstIteration()) cmd_notify = true;
else if (screen_cmd_notify_task.isLastIteration()) cmd_notify = false;
else cmd_notify = !cmd_notify;
}
Task screen_cmd_notify_task(500, 10, &screen_cmd_notify, &runner, false);
//
extern Task screen_task;
void screen() {
//clear screen + a
int line_step = 12;
int line = 0;
display.clearDisplay();
display.setTextColor(SSD1306_WHITE);
display.setTextSize(1);
//clear screen + a
int line_step = 12;
int line = 0;
display.clearDisplay();
display.setTextColor(SSD1306_WHITE);
display.setTextSize(1);
//line1 - mode line (playing / stopped) + notify mark
display.setCursor(0, line);
if (audio.isRunning()) display.println("= playing ===");
else display.println("* stopped !:.");
if (cmd_notify) {
display.setCursor(120, line);
display.println("*");
}
line += line_step;
//line1 - mode line (playing / stopped) + notify mark
display.setCursor(0, line);
if (audio.isRunning()) display.println("= playing ===");
else display.println("* stopped !:.");
if (cmd_notify) {
display.setCursor(120, line);
display.println("*");
}
line += line_step;
//line2 - filename
display.setCursor(0, line);
display.println(screen_filename.c_str());
line += line_step;
//line2 - filename
display.setCursor(0, line);
display.println(screen_filename.c_str());
line += line_step;
//line3 - rf. last msg.
display.setCursor(0, line);
display.println(screen_cmd.c_str());
line += line_step;
//
display.display();
//
//line3 - rf. last msg.
display.setCursor(0, line);
display.println(screen_cmd.c_str());
line += line_step;
//
display.display();
//
}
Task screen_task(SCREEN_PERIOD, TASK_FOREVER, &screen, &runner, true);
@ -182,93 +182,104 @@ int sample_now = 0; //0~999
//on 'start'
void sample_player_start()
{
//filename buffer - 8.3 naming convension! 8+1+3+1 = 13
// + '/' root symbol 13+1 = 14 (ESP32 specific?)
char filename[14] = "/NNN.mp3";
//search for the sound file
int note = sample_now;
int nnn = (note % 1000); // 0~999
int nn = (note % 100); // 0~99
filename[1] = '0' + (nnn / 100); // N__.MP3
filename[2] = '0' + (nn / 10); // _N_.MP3
filename[3] = '0' + (nn % 10); // __N.MP3
//TEST
Serial.println(filename);
screen_filename = String(filename);
bool test = SD.exists(filename);
if (!test) {
Serial.println("... does not exist.");
screen_filename = screen_filename + "_!NEXIST!";
return;
}
//start the player!
audio.connecttoSD(filename);
delay(10);
//filename buffer - 8.3 naming convension! 8+1+3+1 = 13
// + '/' root symbol 13+1 = 14 (ESP32 specific?)
char filename[14] = "/NNN.mp3";
//search for the sound file
int note = sample_now;
int nnn = (note % 1000); // 0~999
int nn = (note % 100); // 0~99
filename[1] = '0' + (nnn / 100); // N__.MP3
filename[2] = '0' + (nn / 10); // _N_.MP3
filename[3] = '0' + (nn % 10); // __N.MP3
//TEST
Serial.println(filename);
screen_filename = String(filename);
bool test = SD.exists(filename);
if (!test) {
Serial.println("... does not exist.");
screen_filename = screen_filename + "_!NEXIST!";
return;
}
//start the player!
audio.connecttoSD(filename);
delay(10);
}
Task sample_player_start_task(0, TASK_ONCE, &sample_player_start, &runner, false);
//on 'stop'
void sample_player_stop() {
//filename buffer - 8.3 naming convension! 8+1+3+1 = 13
// + '/' root symbol 13+1 = 14 (ESP32 specific?)
char filename[14] = "/NNN.mp3";
//search for the sound file
int note = sample_now;
int nnn = (note % 1000); // 0~999
int nn = (note % 100); // 0~99
filename[1] = '0' + (nnn / 100); // N__.MP3
filename[2] = '0' + (nn / 10); // _N_.MP3
filename[3] = '0' + (nn % 10); // __N.MP3
//TEST
Serial.println(filename);
screen_filename = String(filename);
bool test = SD.exists(filename);
if (!test) {
Serial.println("... does not exist.");
screen_filename = screen_filename + "_!NEXIST!";
return;
}
//stop the player.
audio.stopSong();
//filename buffer - 8.3 naming convension! 8+1+3+1 = 13
// + '/' root symbol 13+1 = 14 (ESP32 specific?)
char filename[14] = "/NNN.mp3";
//search for the sound file
int note = sample_now;
int nnn = (note % 1000); // 0~999
int nn = (note % 100); // 0~99
filename[1] = '0' + (nnn / 100); // N__.MP3
filename[2] = '0' + (nn / 10); // _N_.MP3
filename[3] = '0' + (nn % 10); // __N.MP3
//TEST
Serial.println(filename);
screen_filename = String(filename);
bool test = SD.exists(filename);
if (!test) {
Serial.println("... does not exist.");
screen_filename = screen_filename + "_!NEXIST!";
return;
}
//stop the player.
audio.stopSong();
}
Task sample_player_stop_task(0, TASK_ONCE, &sample_player_stop, &runner, false);
//looping
void looping()
{
if (!audio.isRunning()) {
//keep sample_now as it is.
sample_player_start_task.restartDelayed(10);
}
}
Task looping_task(5000, TASK_FOREVER, &looping, &runner, false);
// Task looping_task(5000, TASK_FOREVER, &looping, &runner, true); // < with looping task .. audio will always keep playing. (non stop.)
//
#if defined(REPLICATE_NOTE_REQ)
Note note_now = {
-1, // int32_t id;
-1, // float pitch;
-1, // float velocity;
-1, // float onoff;
-1, // float x1;
-1, // float x2;
-1, // float x3;
-1, // float x4;
-1 // float ps;
-1, // int32_t id;
-1, // float pitch;
-1, // float velocity;
-1, // float onoff;
-1, // float x1;
-1, // float x2;
-1, // float x3;
-1, // float x4;
-1 // float ps;
};
#define NEW_NOTE_TIMEOUT (3000)
static unsigned long new_note_time = (-1*NEW_NOTE_TIMEOUT);
void repeat() {
//
uint8_t frm_size = sizeof(Note) + 2;
uint8_t frm[frm_size];
frm[0] = '[';
memcpy(frm + 1, (uint8_t *) &note_now, sizeof(Note));
frm[frm_size - 1] = ']';
//
// strange but following didn't work as expected. (instead, i have to send one-by-one.)
// esp_now_send(NULL, frm, frm_size); // to all peers in the list.
//
uint8_t frm_size = sizeof(Note) + 2;
uint8_t frm[frm_size];
frm[0] = '[';
memcpy(frm + 1, (uint8_t *) &note_now, sizeof(Note));
frm[frm_size - 1] = ']';
//
// strange but following didn't work as expected. (instead, i have to send one-by-one.)
// esp_now_send(NULL, frm, frm_size); // to all peers in the list.
// so, forget about peer list -> just pick a broadcast peer to be sent.
uint8_t broadcastmac[6] = {0xFF, 0xFF, 0xFF, 0xFF, 0xFF, 0xFF};
esp_now_send(broadcastmac, frm, frm_size);
// so, forget about peer list -> just pick a broadcast peer to be sent.
uint8_t broadcastmac[6] = {0xFF, 0xFF, 0xFF, 0xFF, 0xFF, 0xFF};
esp_now_send(broadcastmac, frm, frm_size);
// (DEBUG) fetch full peer list
{ PeerLister a; a.print(); }
// (DEBUG) fetch full peer list
{ PeerLister a; a.print(); }
//
MONITORING_SERIAL.print("\nrepeat! ==> ");
MONITORING_SERIAL.println(note_now.to_string());
//
MONITORING_SERIAL.print("\nrepeat! ==> ");
MONITORING_SERIAL.println(note_now.to_string());
}
Task repeat_task(0, TASK_ONCE, &repeat, &runner, false);
#endif
@ -278,304 +289,304 @@ Task repeat_task(0, TASK_ONCE, &repeat, &runner, false);
extern Task hello_task;
static int hello_delay = 0;
void hello() {
//
byte mac[6];
WiFi.macAddress(mac);
uint32_t mac32 = (((((mac[2] << 8) + mac[3]) << 8) + mac[4]) << 8) + mac[5];
//
Hello hello(String(MY_SIGN), MY_ID, mac32); // the most basic 'hello'
// and you can append some floats
static int count = 0;
count++;
hello.h1 = (count % 1000);
hello.h2 = sample_now;
// hello.h3 = 0;
// hello.h4 = 0;
//
uint8_t frm_size = sizeof(Hello) + 2;
uint8_t frm[frm_size];
frm[0] = '{';
memcpy(frm + 1, (uint8_t *) &hello, sizeof(Hello));
frm[frm_size - 1] = '}';
//
esp_now_send(NULL, frm, frm_size); // to all peers in the list.
//
// MONITORING_SERIAL.write(frm, frm_size);
// MONITORING_SERIAL.println(" ==(esp_now_send/0)==> ");
//
if (hello_delay > 0) {
if (hello_delay < 100) hello_delay = 100;
hello_task.restartDelayed(hello_delay);
}
//
byte mac[6];
WiFi.macAddress(mac);
uint32_t mac32 = (((((mac[2] << 8) + mac[3]) << 8) + mac[4]) << 8) + mac[5];
//
Hello hello(String(MY_SIGN), MY_ID, mac32); // the most basic 'hello'
// and you can append some floats
static int count = 0;
count++;
hello.h1 = (count % 1000);
hello.h2 = sample_now;
// hello.h3 = 0;
// hello.h4 = 0;
//
uint8_t frm_size = sizeof(Hello) + 2;
uint8_t frm[frm_size];
frm[0] = '{';
memcpy(frm + 1, (uint8_t *) &hello, sizeof(Hello));
frm[frm_size - 1] = '}';
//
esp_now_send(NULL, frm, frm_size); // to all peers in the list.
//
// MONITORING_SERIAL.write(frm, frm_size);
// MONITORING_SERIAL.println(" ==(esp_now_send/0)==> ");
//
if (hello_delay > 0) {
if (hello_delay < 100) hello_delay = 100;
hello_task.restartDelayed(hello_delay);
}
}
Task hello_task(0, TASK_ONCE, &hello, &runner, false);
//task #0 : blink led
extern Task blink_task;
void blink() {
//
static int count = 0;
count++;
//
switch (count % 4) {
case 0:
digitalWrite(LED_PIN, LOW); // first ON
blink_task.delay(LED_ONTIME);
break;
case 1:
digitalWrite(LED_PIN, HIGH); // first OFF
blink_task.delay(LED_GAPTIME);
break;
case 2:
digitalWrite(LED_PIN, LOW); // second ON
blink_task.delay(LED_ONTIME);
break;
case 3:
digitalWrite(LED_PIN, HIGH); // second OFF
blink_task.delay(LED_PERIOD - 2* LED_ONTIME - LED_GAPTIME);
break;
}
//
static int count = 0;
count++;
//
switch (count % 4) {
case 0:
digitalWrite(LED_PIN, LOW); // first ON
blink_task.delay(LED_ONTIME);
break;
case 1:
digitalWrite(LED_PIN, HIGH); // first OFF
blink_task.delay(LED_GAPTIME);
break;
case 2:
digitalWrite(LED_PIN, LOW); // second ON
blink_task.delay(LED_ONTIME);
break;
case 3:
digitalWrite(LED_PIN, HIGH); // second OFF
blink_task.delay(LED_PERIOD - 2* LED_ONTIME - LED_GAPTIME);
break;
}
}
Task blink_task(0, TASK_FOREVER, &blink, &runner, false); // makepython esp32 has NO led => disabled.
// on 'Note'
void onNoteHandler(Note & n) {
//is it for me?
if (n.id == MY_GROUP_ID || n.id == MY_ID) {
//
screen_cmd = n.to_string();
screen_cmd_notify_task.restart();
//
if (n.velocity != 0 || n.onoff == 2) {
audio.setVolume(n.velocity * 21 / 127 * GAIN_MAX); // 0...127 ==> 0...21
//is it for me?
if (n.id == MY_GROUP_ID || n.id == MY_ID) {
//
screen_cmd = n.to_string();
screen_cmd_notify_task.restart();
//
if (n.velocity != 0 || n.onoff == 2) {
audio.setVolume(n.velocity * 21 / 127 * GAIN_MAX); // 0...127 ==> 0...21
}
//
if (n.onoff == 1) {
// filter out re-triggering same note while it is playing.
if (!audio.isRunning() || sample_now != n.pitch) {
sample_now = n.pitch;
sample_player_start_task.restartDelayed(10);
}
} else if (n.onoff == 0) {
sample_now = n.pitch;
sample_player_stop_task.restartDelayed(10);
}
//
}
//
if (n.onoff == 1) {
// filter out re-triggering same note while it is playing.
if (!audio.isRunning() || sample_now != n.pitch) {
sample_now = n.pitch;
sample_player_start_task.restartDelayed(10);
}
} else if (n.onoff == 0) {
sample_now = n.pitch;
sample_player_stop_task.restartDelayed(10);
}
//
}
}
// on 'receive'
void onDataReceive(const uint8_t * mac, const uint8_t *incomingData, int32_t len) {
//
// MONITORING_SERIAL.write(incomingData, len);
//
// MONITORING_SERIAL.write(incomingData, len);
//
//
#if defined(HAVE_CLIENT)
Serial.write(incomingData, len); // we pass it over to the client.
Serial.write(incomingData, len); // we pass it over to the client.
#endif
// open => identify => use.
if (incomingData[0] == '{' && incomingData[len - 1] == '}' && len == (sizeof(Hello) + 2)) {
Hello hello("");
memcpy((uint8_t *) &hello, incomingData + 1, sizeof(Hello));
//
MONITORING_SERIAL.println(hello.to_string());
//
}
// open => identify => use.
if (incomingData[0] == '[' && incomingData[len - 1] == ']' && len == (sizeof(Note) + 2)) {
Note note;
memcpy((uint8_t *) &note, incomingData + 1, sizeof(Note));
onNoteHandler(note);
//is it for me?
if (note.id == MY_GROUP_ID || note.id == MY_ID) {
hello_delay = note.ps;
if (hello_delay > 0 && hello_task.isEnabled() == false) {
hello_task.restart();
}
// open => identify => use.
if (incomingData[0] == '{' && incomingData[len - 1] == '}' && len == (sizeof(Hello) + 2)) {
Hello hello("");
memcpy((uint8_t *) &hello, incomingData + 1, sizeof(Hello));
//
MONITORING_SERIAL.println(hello.to_string());
//
}
MONITORING_SERIAL.println(note.to_string());
// open => identify => use.
if (incomingData[0] == '[' && incomingData[len - 1] == ']' && len == (sizeof(Note) + 2)) {
Note note;
memcpy((uint8_t *) &note, incomingData + 1, sizeof(Note));
onNoteHandler(note);
//is it for me?
if (note.id == MY_GROUP_ID || note.id == MY_ID) {
hello_delay = note.ps;
if (hello_delay > 0 && hello_task.isEnabled() == false) {
hello_task.restart();
}
}
MONITORING_SERIAL.println(note.to_string());
#if defined(REPLICATE_NOTE_REQ)
if (millis() - new_note_time > NEW_NOTE_TIMEOUT) {
note_now = note;
repeat_task.restart();
new_note_time = millis();
}
if (millis() - new_note_time > NEW_NOTE_TIMEOUT) {
note_now = note;
repeat_task.restart();
new_note_time = millis();
}
#endif
}
}
}
// on 'sent'
void onDataSent(const uint8_t *mac_addr, esp_now_send_status_t sendStatus) {
// well, i think this cb should be called once for EVERY single TX attempts,
// but in reality, it doesn't get called that often.
// i think this is sorta bug. but have no clear clue.
MONITORING_SERIAL.printf("* delivery attempt! ~~~>>> %02X:%02X:%02X:%02X:%02X:%02X\n", mac_addr[0], mac_addr[1], mac_addr[2], mac_addr[3], mac_addr[4], mac_addr[5]);
if (sendStatus != 0) MONITORING_SERIAL.printf("* ==>> FAILED :(\n\n");
// well, i think this cb should be called once for EVERY single TX attempts,
// but in reality, it doesn't get called that often.
// i think this is sorta bug. but have no clear clue.
MONITORING_SERIAL.printf("* delivery attempt! ~~~>>> %02X:%02X:%02X:%02X:%02X:%02X\n", mac_addr[0], mac_addr[1], mac_addr[2], mac_addr[3], mac_addr[4], mac_addr[5]);
if (sendStatus != 0) MONITORING_SERIAL.printf("* ==>> FAILED :(\n\n");
}
// SD TEST
void printDirectory(File dir, int numTabs) {
// char filename[256] = "";
while(true) {
File entry = dir.openNextFile();
if (!entry) {
// no more files
break;
// char filename[256] = "";
while(true) {
File entry = dir.openNextFile();
if (!entry) {
// no more files
break;
}
for (uint8_t i=0; i<numTabs; i++) {
Serial.print('\t');
}
// entry.getName(filename, 256);
// Serial.print(filename);
Serial.print(entry.name());
if (entry.isDirectory()) {
Serial.println("/");
//non-recursive listing...
// printDirectory(entry, numTabs+1);
} else {
// files have sizes, directories do not
Serial.print("\t\t");
Serial.println(entry.size(), DEC);
}
entry.close();
}
for (uint8_t i=0; i<numTabs; i++) {
Serial.print('\t');
}
// entry.getName(filename, 256);
// Serial.print(filename);
Serial.print(entry.name());
if (entry.isDirectory()) {
Serial.println("/");
//non-recursive listing...
// printDirectory(entry, numTabs+1);
} else {
// files have sizes, directories do not
Serial.print("\t\t");
Serial.println(entry.size(), DEC);
}
entry.close();
}
}
void lcd_text(String str) {
display.clearDisplay();
display.setTextColor(SSD1306_WHITE);
display.setTextSize(1);
display.setCursor(0, 0);
display.println(str.c_str());
display.display();
display.clearDisplay();
display.setTextColor(SSD1306_WHITE);
display.setTextSize(1);
display.setCursor(0, 0);
display.println(str.c_str());
display.display();
}
//
File root;
void setup() {
//led
pinMode(LED_PIN, OUTPUT);
//led
pinMode(LED_PIN, OUTPUT);
//serial
Serial.begin(115200);
delay(100);
//serial
Serial.begin(115200);
delay(100);
//screen
Wire.begin(MAKEPYTHON_ESP32_SDA, MAKEPYTHON_ESP32_SCL);
// SSD1306_SWITCHCAPVCC = generate display voltage from 3.3V internally
if (!display.begin(SSD1306_SWITCHCAPVCC, 0x3C)) { // Address 0x3C for 128x32
Serial.println(F("SSD1306 allocation failed"));
for (;;)
; // Don't proceed, loop forever
}
display.clearDisplay();
//screen
Wire.begin(MAKEPYTHON_ESP32_SDA, MAKEPYTHON_ESP32_SCL);
// SSD1306_SWITCHCAPVCC = generate display voltage from 3.3V internally
if (!display.begin(SSD1306_SWITCHCAPVCC, 0x3C)) { // Address 0x3C for 128x32
Serial.println(F("SSD1306 allocation failed"));
for (;;)
; // Don't proceed, loop forever
}
display.clearDisplay();
//SD(SPI)
pinMode(SD_CS, OUTPUT);
digitalWrite(SD_CS, HIGH);
SPI.begin(SPI_SCK, SPI_MISO, SPI_MOSI);
SPI.setFrequency(1000000);
if (!SD.begin(SD_CS, SPI)) {
Serial.println("Card Mount Failed");
lcd_text("SD ERR!\nCard Mount Failed!");
while (1)
;
} else {
// lcd_text("SD OK");
}
root = SD.open("/");
printDirectory(root, 0);
//SD(SPI)
pinMode(SD_CS, OUTPUT);
digitalWrite(SD_CS, HIGH);
SPI.begin(SPI_SCK, SPI_MISO, SPI_MOSI);
SPI.setFrequency(1000000);
if (!SD.begin(SD_CS, SPI)) {
Serial.println("Card Mount Failed");
lcd_text("SD ERR!\nCard Mount Failed!");
while (1)
;
} else {
// lcd_text("SD OK");
}
root = SD.open("/");
printDirectory(root, 0);
//audio(I2S)
audio.setPinout(I2S_BCLK, I2S_LRC, I2S_DOUT);
// audio.setVolume(21); // 0...21
audio.setVolume(14.88); // 90 * 21 / 127 == 14.88
//audio(I2S)
audio.setPinout(I2S_BCLK, I2S_LRC, I2S_DOUT);
// audio.setVolume(21); // 0...21
audio.setVolume(14.88); // 90 * 21 / 127 == 14.88
// audio.connecttoFS(SD, filename.c_str());
// audio.connecttoFS(SD, filename.c_str());
//info
Serial.println();
Serial.println();
Serial.println("\"hi, i m your postman.\"");
Serial.println("-");
Serial.println("- my id: " + String(MY_ID) + ", gid: " + String(MY_GROUP_ID) + ", call me ==> \"" + String(MY_SIGN) + "\"");
Serial.println("- mac address: " + WiFi.macAddress() + ", channel: " + String(WIFI_CHANNEL));
Serial.println("- my peer book ==> \"" + String(ADDRESSBOOK_TITLE) + "\"");
//info
Serial.println();
Serial.println();
Serial.println("\"hi, i m your postman.\"");
Serial.println("-");
Serial.println("- my id: " + String(MY_ID) + ", gid: " + String(MY_GROUP_ID) + ", call me ==> \"" + String(MY_SIGN) + "\"");
Serial.println("- mac address: " + WiFi.macAddress() + ", channel: " + String(WIFI_CHANNEL));
Serial.println("- my peer book ==> \"" + String(ADDRESSBOOK_TITLE) + "\"");
#if defined(HAVE_CLIENT)
Serial.println("- ======== 'HAVE_CLIENT' ========");
Serial.println("- ======== 'HAVE_CLIENT' ========");
#endif
#if defined(SERIAL_SWAP)
Serial.println("- ======== 'SERIAL_SWAP' ========");
Serial.println("- ======== 'SERIAL_SWAP' ========");
#endif
#if defined(DISABLE_AP)
Serial.println("- ======== 'DISABLE_AP' ========");
Serial.println("- ======== 'DISABLE_AP' ========");
#endif
#if defined(HAVE_CLIENT_I2C)
Serial.println("- ======== 'HAVE_CLIENT_I2C' ========");
Serial.println("- ======== 'HAVE_CLIENT_I2C' ========");
#endif
#if defined(REPLICATE_NOTE_REQ)
Serial.println("- ======== 'REPLICATE_NOTE_REQ' ========");
Serial.println("- ======== 'REPLICATE_NOTE_REQ' ========");
#endif
Serial.println("-");
Serial.println("-");
//wifi
WiFiMode_t node_type = WIFI_AP_STA;
//wifi
WiFiMode_t node_type = WIFI_AP_STA;
#if defined(DISABLE_AP)
// system_phy_set_max_tpw(0);
WiFi.setTxPower(WIFI_POWER_MINUS_1dBm); // Set WiFi RF power output to lowest level
node_type = WIFI_STA;
// system_phy_set_max_tpw(0);
WiFi.setTxPower(WIFI_POWER_MINUS_1dBm); // Set WiFi RF power output to lowest level
node_type = WIFI_STA;
#endif
WiFi.mode(node_type);
WiFi.mode(node_type);
//esp-now
if (esp_now_init() != 0) {
Serial.println("Error initializing ESP-NOW");
return;
}
esp_now_register_send_cb(onDataSent);
esp_now_register_recv_cb(onDataReceive);
//
// Serial.println("- ! (esp_now_add_peer) ==> add a 'broadcast peer' (FF:FF:FF:FF:FF:FF).");
// uint8_t broadcastmac[6] = {0xFF, 0xFF, 0xFF, 0xFF, 0xFF, 0xFF};
//
// //
// esp_now_peer_info_t peerInfo = {};
// memcpy(peerInfo.peer_addr, broadcastmac, 6);
// peerInfo.channel = 0;
// peerInfo.encrypt = false;
// esp_now_add_peer(&peerInfo);
//esp-now
if (esp_now_init() != 0) {
Serial.println("Error initializing ESP-NOW");
return;
}
esp_now_register_send_cb(onDataSent);
esp_now_register_recv_cb(onDataReceive);
//
// Serial.println("- ! (esp_now_add_peer) ==> add a 'broadcast peer' (FF:FF:FF:FF:FF:FF).");
// uint8_t broadcastmac[6] = {0xFF, 0xFF, 0xFF, 0xFF, 0xFF, 0xFF};
//
// //
// esp_now_peer_info_t peerInfo = {};
// memcpy(peerInfo.peer_addr, broadcastmac, 6);
// peerInfo.channel = 0;
// peerInfo.encrypt = false;
// esp_now_add_peer(&peerInfo);
AddressBook * book = lib.getBookByTitle(ADDRESSBOOK_TITLE);
if (book == NULL) {
Serial.println("- ! wrong book !! : \"" + String(ADDRESSBOOK_TITLE) + "\""); while(1);
}
for (int idx = 0; idx < book->list.size(); idx++) {
Serial.println("- ! (esp_now_add_peer) ==> add a '" + book->list[idx].name + "'.");
esp_now_peer_info_t peerInfo = {};
memcpy(peerInfo.peer_addr, book->list[idx].mac, 6);
peerInfo.channel = 0;
peerInfo.encrypt = false;
esp_now_add_peer(&peerInfo);
}
// (DEBUG) fetch full peer list
{ PeerLister a; a.print(); }
//
Serial.println("-");
Serial.println("\".-.-.-. :)\"");
Serial.println();
AddressBook * book = lib.getBookByTitle(ADDRESSBOOK_TITLE);
if (book == NULL) {
Serial.println("- ! wrong book !! : \"" + String(ADDRESSBOOK_TITLE) + "\""); while(1);
}
for (int idx = 0; idx < book->list.size(); idx++) {
Serial.println("- ! (esp_now_add_peer) ==> add a '" + book->list[idx].name + "'.");
esp_now_peer_info_t peerInfo = {};
memcpy(peerInfo.peer_addr, book->list[idx].mac, 6);
peerInfo.channel = 0;
peerInfo.encrypt = false;
esp_now_add_peer(&peerInfo);
}
// (DEBUG) fetch full peer list
{ PeerLister a; a.print(); }
//
Serial.println("-");
Serial.println("\".-.-.-. :)\"");
Serial.println();
}
void loop() {
//
audio.loop();
//
runner.execute();
//
//
audio.loop();
//
runner.execute();
//
}

43
buzz/platformio.ini Normal file
View file

@ -0,0 +1,43 @@
; < NOTE >
; to enable verbose output add option -->
; $ platformio run --verbose
; to make this permanent for the proj. -->
; $ platformio settings set force_verbose Yes
; then confirm the change -->
; $ platformio settings get
; // pio v 4.0 'Build options'
; - build_type
; - build_flags
; - src_build_flags
; - build_unflags
; - src_filter
; - targets
[platformio]
default_envs = nodemcuv2
[env]
framework = arduino
upload_port = /dev/ttyUSB0
lib_deps =
721 ; TaskScheduler
[env:nodemcuv2]
platform = espressif8266
board = nodemcuv2
lib_deps =
${env.lib_deps}
upload_speed = 921600 ; 9600, 19200, 38400, 57600, 115200, 230400, 460800, 921600
[env:d1_mini_pro]
platform = espressif8266
board = d1_mini_pro
lib_deps =
${env.lib_deps}
upload_speed = 460800 ; 9600, 19200, 38400, 57600, 115200, 230400, 460800, 921600

326
buzz/src/main.cpp Normal file
View file

@ -0,0 +1,326 @@
//
// wirelessly connected cloud (based on ESP-NOW, a kind of LPWAN?)
//
//
// Conversation about the ROOT @ SEMA storage, Seoul
//
//
// 2021 02 15
//
// this module will be an esp-now node in a group.
// like, a bird in a group of birds.
//
// esp-now @ esp8266 w/ broadcast address (FF:FF:FF:FF:FF:FF)
// always broadcasting. everyone is 'talkative'.
//
// then, let it save a value in EEPROM (object with memory=mind?)
//============<identities>============
//
#define MY_GROUP_ID (9000)
#define MY_ID (MY_GROUP_ID + 5)
#define MY_SIGN ("BUZZ")
//
//============</identities>============
//==========<list-of-configurations>===========
//
// 'HAVE_CLIENT'
// --> i have a client. enable the client task.
//
// 'SERIAL_SWAP'
// --> UART pin swapped.
// you want this, when you want a bi-directional comm. to external client boards (e.g. teensy).
//
// 'DISABLE_AP'
// --> (questioning)...
//
// 'HAVE_CLIENT_I2C'
// --> i have a client w/ I2C i/f. enable the I2C client task.
//
//==========</list-of-configurations>==========
//
// (EMPTY)
//============<parameters>============
//
#define LED_PERIOD (11111)
#define LED_ONTIME (1)
#define LED_GAPTIME (222)
//
#define WIFI_CHANNEL 1
//
// 'MONITORING_SERIAL'
//
// --> sometimes, the 'Serial' is in use (for example, 'osc' node)
// then, use 'Serial1' - D4/GPIO2/TDX1 @ nodemcu (this is TX only.)
//
// --> otherwise, MONITORING_SERIAL == Serial.
//
#if defined(SERIAL_SWAP)
#define MONITORING_SERIAL (Serial1)
#else
#define MONITORING_SERIAL (Serial)
#endif
//
//============</parameters>===========
//============<board-specifics>============
#if defined(ARDUINO_FEATHER_ESP32) // featheresp32
#define LED_PIN 13
#else
#define LED_PIN 2
#endif
//============</board-specifics>===========
//arduino
#include <Arduino.h>
//post & addresses
#include "../../post.h"
//espnow
#include <ESP8266WiFi.h>
#include <espnow.h>
//task
#include <TaskScheduler.h>
Scheduler runner;
//-*-*-*-*-*-*-*-*-*-*-*-*-
// buzzer
// my tasks
int tonepin = D6;
int tonefreq = 0;
void set_tone() {
tone(tonepin, tonefreq);
MONITORING_SERIAL.print("set_tone:");
MONITORING_SERIAL.println(tonefreq);
}
Task set_tone_task(0, TASK_ONCE, &set_tone, &runner, false);
//
uint8_t watch_counter = 0;
void watcher() {
if (watch_counter > 3) {
tonefreq = 0;
set_tone_task.restartDelayed(10);
watch_counter = 0;
} else {
watch_counter++;
}
}
Task watcher_task(1000, TASK_FOREVER, &watcher, &runner, true);
//*-*-*-*-*-*-*-*-*-*-*-*-*
//
extern Task hello_task;
static int hello_delay = 2000;
void hello() {
//
byte mac[6];
WiFi.macAddress(mac);
uint32_t mac32 = (((((mac[2] << 8) + mac[3]) << 8) + mac[4]) << 8) + mac[5];
//
Hello hello(String(MY_SIGN), MY_ID, mac32); // the most basic 'hello'
// and you can append some floats
static int count = 0;
count++;
hello.h1 = (count % 1000);
hello.h2 = tonefreq;
// hello.h3 = 0;
// hello.h4 = 0;
//
uint8_t frm_size = sizeof(Hello) + 2;
uint8_t frm[frm_size];
frm[0] = '{';
memcpy(frm + 1, (uint8_t *) &hello, sizeof(Hello));
frm[frm_size - 1] = '}';
//
esp_now_send(NULL, frm, frm_size); // to all peers in the list.
//
MONITORING_SERIAL.write(frm, frm_size);
MONITORING_SERIAL.println(" ==(esp_now_send/0)==> ");
//
if (hello_delay > 0) {
if (hello_delay < 100) hello_delay = 100;
hello_task.restartDelayed(hello_delay);
}
}
Task hello_task(0, TASK_ONCE, &hello, &runner, false);
//task #0 : blink led
extern Task blink_task;
void blink() {
//
static int count = 0;
count++;
//
switch (count % 4) {
case 0:
digitalWrite(LED_PIN, LOW); // first ON
blink_task.delay(LED_ONTIME);
break;
case 1:
digitalWrite(LED_PIN, HIGH); // first OFF
blink_task.delay(LED_GAPTIME);
break;
case 2:
digitalWrite(LED_PIN, LOW); // second ON
blink_task.delay(LED_ONTIME);
break;
case 3:
digitalWrite(LED_PIN, HIGH); // second OFF
blink_task.delay(LED_PERIOD - 2* LED_ONTIME - LED_GAPTIME);
break;
}
}
Task blink_task(0, TASK_FOREVER, &blink, &runner, true); // -> ENABLED, at start-up.
// on 'Note'
void onNoteHandler(Note & n) {
//is it for me?
if (n.id == MY_GROUP_ID || n.id == MY_ID) {
//
tonepin = n.pitch;
if (tonepin == 0) tonepin = D6;
//
tonefreq = n.velocity;
//
set_tone_task.restartDelayed(10);
watch_counter = 0;
//
}
}
// on 'receive'
void onDataReceive(uint8_t * mac, uint8_t *incomingData, uint8_t len) {
//
//MONITORING_SERIAL.write(incomingData, len);
//
#if defined(HAVE_CLIENT)
Serial.write(incomingData, len); // we pass it over to the client.
#endif
// open => identify => use.
if (incomingData[0] == '{' && incomingData[len - 1] == '}' && len == (sizeof(Hello) + 2)) {
Hello hello("");
memcpy((uint8_t *) &hello, incomingData + 1, sizeof(Hello));
//
MONITORING_SERIAL.println(hello.to_string());
//
}
// open => identify => use.
if (incomingData[0] == '[' && incomingData[len - 1] == ']' && len == (sizeof(Note) + 2)) {
Note note;
memcpy((uint8_t *) &note, incomingData + 1, sizeof(Note));
onNoteHandler(note);
//is it for me?
if (note.id == MY_GROUP_ID || note.id == MY_ID) {
hello_delay = note.ps;
if (hello_delay > 0 && hello_task.isEnabled() == false) {
hello_task.restart();
}
}
MONITORING_SERIAL.println(note.to_string());
}
}
// on 'sent'
void onDataSent(uint8_t *mac_addr, uint8_t sendStatus) {
if (sendStatus != 0) MONITORING_SERIAL.println("Delivery failed!");
}
//
void setup() {
//led
pinMode(LED_PIN, OUTPUT);
//
// tone(D6, 1000, 1000);
//pwm freq.
analogWriteFreq(40000);
//serial
Serial.begin(115200);
delay(100);
//info
Serial.println();
Serial.println();
Serial.println("\"hi, i m your postman.\"");
Serial.println("-");
Serial.println("- my id: " + String(MY_ID) + ", gid: " + String(MY_GROUP_ID) + ", call me ==> \"" + String(MY_SIGN) + "\"");
Serial.println("- mac address: " + WiFi.macAddress() + ", channel: " + String(WIFI_CHANNEL));
#if defined(HAVE_CLIENT)
Serial.println("- ======== 'HAVE_CLIENT' ========");
#endif
#if defined(SERIAL_SWAP)
Serial.println("- ======== 'SERIAL_SWAP' ========");
#endif
#if defined(DISABLE_AP)
Serial.println("- ======== 'DISABLE_AP' ========");
#endif
#if defined(HAVE_CLIENT_I2C)
Serial.println("- ======== 'HAVE_CLIENT_I2C' ========");
#endif
Serial.println("-");
//wifi
WiFiMode_t node_type = WIFI_AP_STA;
#if defined(DISABLE_AP)
system_phy_set_max_tpw(0);
node_type = WIFI_STA;
#endif
WiFi.mode(node_type);
//esp-now
if (esp_now_init() != 0) {
Serial.println("Error initializing ESP-NOW");
return;
}
esp_now_set_self_role(ESP_NOW_ROLE_COMBO);
esp_now_register_send_cb(onDataSent);
esp_now_register_recv_cb(onDataReceive);
//
Serial.println("- ! (esp_now_add_peer) ==> add a 'broadcast peer' (FF:FF:FF:FF:FF:FF).");
uint8_t broadcastmac[6] = {0xFF, 0xFF, 0xFF, 0xFF, 0xFF, 0xFF};
esp_now_add_peer(broadcastmac, ESP_NOW_ROLE_COMBO, 1, NULL, 0);
//
Serial.println("-");
Serial.println("\".-.-.-. :)\"");
Serial.println();
#if defined(SERIAL_SWAP)
Serial.println("- ======== 'SERIAL_SWAP' ========");
// a proper say goodbye.
Serial.println("\"bye, i will do 'swap' in 1 second. find me on alternative pins!\"");
Serial.println("\" hint: osc wiring ==> esp8266(serial.swap) <-> teensy(serial3)\"");
Serial.println("-");
Serial.println("\".-.-.-. :)\"");
delay(1000); // flush out unsent serial messages.
// moving...
Serial.swap(); // use RXD2/TXD2 pins, afterwards.
delay(100); // wait re-initialization of the 'Serial'
#endif
//random seed
randomSeed(analogRead(0));
}
void loop() {
//
runner.execute();
//
}

521
p/src/main.cpp
View file

@ -90,8 +90,10 @@ Adafruit_SSD1306 display(SCREEN_WIDTH, SCREEN_HEIGHT, &Wire, OLED_RESET);
// q list
std::vector<Note> qlist;
void init_qlist() {
qlist.push_back(Note(10000, 1, 0, 1, 0, 0, 0, 0, 0));
qlist.push_back(Note(10000, 1, 0, 0, 0, 0, 0, 0, 0));
qlist.push_back(Note(1444, 12, 0, 1, 0, 0, 0, 0, 0));
qlist.push_back(Note(1444, 12, 0, 0, 0, 0, 0, 0, 0));
qlist.push_back(Note(1444, 14, 0, 1, 0, 0, 0, 0, 0));
qlist.push_back(Note(1444, 14, 0, 0, 0, 0, 0, 0, 0));
}
//buttons
@ -109,9 +111,9 @@ String screen_cmd = ":Q: ----- --- --- -";
extern Task screen_req_notify_task;
bool req_notify = false;
void screen_req_notify() {
if (screen_req_notify_task.isFirstIteration()) req_notify = true;
else if (screen_req_notify_task.isLastIteration()) req_notify = false;
else req_notify = !req_notify;
if (screen_req_notify_task.isFirstIteration()) req_notify = true;
else if (screen_req_notify_task.isLastIteration()) req_notify = false;
else req_notify = !req_notify;
}
Task screen_req_notify_task(500, 8, &screen_req_notify, &runner, false);
@ -119,177 +121,180 @@ Task screen_req_notify_task(500, 8, &screen_req_notify, &runner, false);
extern Task screen_task;
void screen() {
//
if (screen_task.isFirstIteration()) {
init_qlist();
}
// button job!
static int btn_vol_up = 0;
static int btn_vol_down = 0;
static int btn_mute = 0;
static int btn_previous = 0;
static int btn_pause = 0;
static int btn_next = 0;
//
int a;
static int qselect = 0;
bool nowsend = false;
//
a = digitalRead(pin_vol_up);
if(btn_vol_up != a) {
btn_vol_up = a;
if(a == 0) {
// 'vol_up' button pressed.
qselect = qselect + 1;
if (qselect > (qlist.size() - 1)) qselect = 0;
}
}
//
a = digitalRead(pin_vol_down);
if(btn_vol_down != a) {
btn_vol_down = a;
if(a == 0) {
// 'vol_down' button pressed.
qselect = qselect - 1;
if (qselect < 0) qselect = (qlist.size() - 1);
}
}
//
a = digitalRead(pin_mute);
if(btn_mute != a) {
btn_mute = a;
if(a == 0) {
// 'mute' button pressed.
nowsend = true;
}
}
//
a = digitalRead(pin_previous);
if(btn_previous != a) {
btn_previous = a;
if(a == 0) {
// 'previous' button pressed.
qselect = qselect - 1;
if (qselect < 0) qselect = (qlist.size() - 1);
}
}
//
a = digitalRead(pin_pause);
if(btn_pause != a) {
btn_pause = a;
if(a == 0) {
// 'pause' button pressed.
nowsend = true;
}
}
//
a = digitalRead(pin_next);
if(btn_next != a) {
btn_next = a;
if(a == 0) {
// 'next' button pressed.
qselect = qselect + 1;
if (qselect > (qlist.size() - 1)) qselect = 0;
}
}
if (nowsend == true) {
nowsend = false;
// create a NOTE req. and send it out.
//
MONITORING_SERIAL.print("# posting a req.# ==> ");
MONITORING_SERIAL.println(qlist[qselect].to_string());
if (screen_task.isFirstIteration()) {
init_qlist();
}
// button job!
static int btn_vol_up = 0;
static int btn_vol_down = 0;
static int btn_mute = 0;
static int btn_previous = 0;
static int btn_pause = 0;
static int btn_next = 0;
//
uint8_t frm_size = sizeof(Note) + 2;
uint8_t frm[frm_size];
frm[0] = '[';
memcpy(frm + 1, (uint8_t *) &qlist[qselect], sizeof(Note));
frm[frm_size - 1] = ']';
int a;
static int qselect = 0;
bool nowsend = false;
//
// strange but following didn't work as expected. (instead, i have to send one-by-one.)
// esp_now_send(NULL, frm, frm_size); // to all peers in the list.
a = digitalRead(pin_vol_up);
if(btn_vol_up != a) {
btn_vol_up = a;
if(a == 0) {
// 'vol_up' button pressed.
// so, forget about peer list -> just pick a broadcast peer to be sent.
uint8_t broadcastmac[6] = {0xFF, 0xFF, 0xFF, 0xFF, 0xFF, 0xFF};
esp_now_send(broadcastmac, frm, frm_size);
qselect = qselect + 1;
if (qselect > (qlist.size() - 1)) qselect = 0;
}
}
//
a = digitalRead(pin_vol_down);
if(btn_vol_down != a) {
btn_vol_down = a;
if(a == 0) {
// 'vol_down' button pressed.
qselect = qselect - 1;
if (qselect < 0) qselect = (qlist.size() - 1);
}
}
//
a = digitalRead(pin_mute);
if(btn_mute != a) {
btn_mute = a;
if(a == 0) {
// 'mute' button pressed.
nowsend = true;
}
}
//
a = digitalRead(pin_previous);
if(btn_previous != a) {
btn_previous = a;
if(a == 0) {
// 'previous' button pressed.
qselect = qselect - 1;
if (qselect < 0) qselect = (qlist.size() - 1);
}
}
//
a = digitalRead(pin_pause);
if(btn_pause != a) {
btn_pause = a;
if(a == 0) {
// 'pause' button pressed.
nowsend = true;
}
}
//
a = digitalRead(pin_next);
if(btn_next != a) {
btn_next = a;
if(a == 0) {
// 'next' button pressed.
qselect = qselect + 1;
if (qselect > (qlist.size() - 1)) qselect = 0;
}
}
if (nowsend == true) {
nowsend = false;
// create a NOTE req. and send it out.
//
MONITORING_SERIAL.print("# posting a req.# ==> ");
MONITORING_SERIAL.println(qlist[qselect].to_string());
//
uint8_t frm_size = sizeof(Note) + 2;
uint8_t frm[frm_size];
frm[0] = '[';
memcpy(frm + 1, (uint8_t *) &qlist[qselect], sizeof(Note));
frm[frm_size - 1] = ']';
//
// strange but following didn't work as expected. (instead, i have to send one-by-one.)
// esp_now_send(NULL, frm, frm_size); // to all peers in the list.
// so, forget about peer list -> just pick a broadcast peer to be sent.
uint8_t broadcastmac[6] = {0xFF, 0xFF, 0xFF, 0xFF, 0xFF, 0xFF};
esp_now_send(broadcastmac, frm, frm_size);
//+ fancy stuff
screen_req_notify_task.restart();
//+ fancy stuff
screen_req_notify_task.restart();
//+ automatically increase 'song_request'
qselect = qselect + 1;
if (qselect > (qlist.size() - 1)) qselect = 0;
}
// //+ automatically increase 'song_request'
// qselect = qselect + 1;
// if (qselect > (qlist.size() - 1)) qselect = 0;
}
//clear screen + a
int line_step = 12;
int line = 0;
display.clearDisplay();
display.setTextColor(SSD1306_WHITE);
display.setTextSize(1);
//clear screen + a
int line_step = 12;
int line = 0;
display.clearDisplay();
display.setTextColor(SSD1306_WHITE);
display.setTextSize(1);
//button status (DEBUG)
// int b = digitalRead(pin_vol_up);
// b = b*10 + digitalRead(pin_vol_down);
// b = b*10 + digitalRead(pin_mute);
// b = b*10 + digitalRead(pin_previous);
// b = b*10 + digitalRead(pin_pause);
// b = b*10 + digitalRead(pin_next);
//button status (DEBUG)
// int b = digitalRead(pin_vol_up);
// b = b*10 + digitalRead(pin_vol_down);
// b = b*10 + digitalRead(pin_mute);
// b = b*10 + digitalRead(pin_previous);
// b = b*10 + digitalRead(pin_pause);
// b = b*10 + digitalRead(pin_next);
//line1 - mode line (playing / stopped) + notify mark
display.setCursor(0, line);
display.printf("= transmitting ))) ==");
line += line_step;
//line1 - mode line (playing / stopped) + notify mark
display.setCursor(0, line);
display.printf("= transmitting ))) ==");
line += line_step;
//line3 - msg. ready to be sent now.
display.setCursor(0, line);
display.printf(":Q: %05d %03d %03d %01d", (int)qlist[qselect].id, (int)qlist[qselect].pitch, (int)qlist[qselect].velocity, (int)qlist[qselect].onoff);
line += line_step;
//line3 - msg. ready to be sent now.
display.setCursor(0, line);
display.setTextSize(2);
display.printf(":Q: %05d %03d %03d %01d", (int)qlist[qselect].id, (int)qlist[qselect].pitch, (int)qlist[qselect].velocity, (int)qlist[qselect].onoff);
line += line_step;
//line4 - big file name display
display.setCursor(0, line);
display.setTextSize(2);
//
char filename[14] = "/NNN.mp3 >";
int note = qlist[qselect].pitch;
int nnn = (note % 1000); // 0~999
int nn = (note % 100); // 0~99
filename[1] = '0' + (nnn / 100); // N__.MP3
filename[2] = '0' + (nn / 10); // _N_.MP3
filename[3] = '0' + (nn % 10); // __N.MP3
//
if (qlist[qselect].onoff == 0) {
filename[9] = 'x';
}
display.println(filename);
line += line_step;
display.setTextSize(1);
line += 8;
// //line4 - big file name display
// display.setCursor(0, line);
// display.setTextSize(2);
// //
// char filename[14] = "/NNN.mp3 >";
// int note = qlist[qselect].pitch;
// int nnn = (note % 1000); // 0~999
// int nn = (note % 100); // 0~99
// filename[1] = '0' + (nnn / 100); // N__.MP3
// filename[2] = '0' + (nn / 10); // _N_.MP3
// filename[3] = '0' + (nn % 10); // __N.MP3
// //
// if (qlist[qselect].onoff == 0) {
// filename[9] = 'x';
// }
// display.println(filename);
// line += line_step;
// display.setTextSize(1);
// line += 8;
// //alternative line3+4 - full msg. dump (DEBUG/MONITORING)
// display.setCursor(0, line);
// display.println(":Q: " + qlist[qselect].to_string());
// line += line_step;
// //alternative line3+4 - full msg. dump (DEBUG/MONITORING)
// display.setCursor(0, line);
// display.println(":Q: " + qlist[qselect].to_string());
line += line_step;
line += line_step;
//line5 - song req. tx. notify. (GEN_NOTE_REQ)
display.setCursor(0, line);
if (req_notify) {
display.setCursor(25, line);
display.println("~~ d[+=+]b ~~ >>>");
}
line += line_step;
//line5 - song req. tx. notify. (GEN_NOTE_REQ)
display.setCursor(0, line);
display.setTextSize(1);
if (req_notify) {
display.setCursor(25, line);
display.println("~~ d[+=+]b ~~ >>>");
}
line += line_step;
//
display.display();
//
//
display.display();
//
}
Task screen_task(SCREEN_PERIOD, TASK_FOREVER, &screen, &runner, true);
//*-*-*-*-*-*-*-*-*-*-*-*-*
@ -297,129 +302,129 @@ Task screen_task(SCREEN_PERIOD, TASK_FOREVER, &screen, &runner, true);
// on 'receive'
void onDataReceive(const uint8_t * mac, const uint8_t *incomingData, int32_t len) {
// open => identify => use.
if (incomingData[0] == '{' && incomingData[len - 1] == '}' && len == (sizeof(Hello) + 2)) {
Hello hello("");
memcpy((uint8_t *) &hello, incomingData + 1, sizeof(Hello));
//
MONITORING_SERIAL.println(hello.to_string());
//
}
// open => identify => use.
if (incomingData[0] == '{' && incomingData[len - 1] == '}' && len == (sizeof(Hello) + 2)) {
Hello hello("");
memcpy((uint8_t *) &hello, incomingData + 1, sizeof(Hello));
//
MONITORING_SERIAL.println(hello.to_string());
//
}
// open => identify => use.
if (incomingData[0] == '[' && incomingData[len - 1] == ']' && len == (sizeof(Note) + 2)) {
Note note;
memcpy((uint8_t *) &note, incomingData + 1, sizeof(Note));
//
MONITORING_SERIAL.println(note.to_string());
//
}
// open => identify => use.
if (incomingData[0] == '[' && incomingData[len - 1] == ']' && len == (sizeof(Note) + 2)) {
Note note;
memcpy((uint8_t *) &note, incomingData + 1, sizeof(Note));
//
MONITORING_SERIAL.println(note.to_string());
//
}
}
// on 'sent'
void onDataSent(const uint8_t *mac_addr, esp_now_send_status_t sendStatus) {
if (sendStatus != 0) MONITORING_SERIAL.println("Delivery failed!");
if (sendStatus != 0) MONITORING_SERIAL.println("Delivery failed!");
}
void lcd_text(String str) {
display.clearDisplay();
display.setTextColor(SSD1306_WHITE);
display.setTextSize(1);
display.setCursor(0, 0);
display.println(str.c_str());
display.display();
display.clearDisplay();
display.setTextColor(SSD1306_WHITE);
display.setTextSize(1);
display.setCursor(0, 0);
display.println(str.c_str());
display.display();
}
//
void setup() {
//buttons
pinMode(pin_vol_up, INPUT_PULLUP);
pinMode(pin_vol_down, INPUT_PULLUP);
pinMode(pin_mute, INPUT_PULLUP);
pinMode(pin_previous, INPUT_PULLUP);
pinMode(pin_pause, INPUT_PULLUP);
pinMode(pin_next, INPUT_PULLUP);
//buttons
pinMode(pin_vol_up, INPUT_PULLUP);
pinMode(pin_vol_down, INPUT_PULLUP);
pinMode(pin_mute, INPUT_PULLUP);
pinMode(pin_previous, INPUT_PULLUP);
pinMode(pin_pause, INPUT_PULLUP);
pinMode(pin_next, INPUT_PULLUP);
//serial
Serial.begin(115200);
delay(100);
//serial
Serial.begin(115200);
delay(100);
//screen
Wire.begin(MAKEPYTHON_ESP32_SDA, MAKEPYTHON_ESP32_SCL);
// SSD1306_SWITCHCAPVCC = generate display voltage from 3.3V internally
if (!display.begin(SSD1306_SWITCHCAPVCC, 0x3C)) { // Address 0x3C for 128x32
Serial.println(F("SSD1306 allocation failed"));
for (;;)
; // Don't proceed, loop forever
}
display.clearDisplay();
//screen
Wire.begin(MAKEPYTHON_ESP32_SDA, MAKEPYTHON_ESP32_SCL);
// SSD1306_SWITCHCAPVCC = generate display voltage from 3.3V internally
if (!display.begin(SSD1306_SWITCHCAPVCC, 0x3C)) { // Address 0x3C for 128x32
Serial.println(F("SSD1306 allocation failed"));
for (;;)
; // Don't proceed, loop forever
}
display.clearDisplay();
//info
Serial.println();
Serial.println();
Serial.println("\"hi, i m your postman.\"");
Serial.println("-");
Serial.println("- my id: " + String(MY_ID) + ", gid: " + String(MY_GROUP_ID) + ", call me ==> \"" + String(MY_SIGN) + "\"");
Serial.println("- mac address: " + WiFi.macAddress() + ", channel: " + String(WIFI_CHANNEL));
Serial.println("- my peer book ==> \"" + String(ADDRESSBOOK_TITLE) + "\"");
//info
Serial.println();
Serial.println();
Serial.println("\"hi, i m your postman.\"");
Serial.println("-");
Serial.println("- my id: " + String(MY_ID) + ", gid: " + String(MY_GROUP_ID) + ", call me ==> \"" + String(MY_SIGN) + "\"");
Serial.println("- mac address: " + WiFi.macAddress() + ", channel: " + String(WIFI_CHANNEL));
Serial.println("- my peer book ==> \"" + String(ADDRESSBOOK_TITLE) + "\"");
#if defined(DISABLE_AP)
Serial.println("- ======== 'DISABLE_AP' ========");
Serial.println("- ======== 'DISABLE_AP' ========");
#endif
#if defined(GEN_NOTE_REQ)
Serial.println("- ======== 'GEN_NOTE_REQ' ========");
Serial.println("- ======== 'GEN_NOTE_REQ' ========");
#endif
Serial.println("-");
Serial.println("-");
//wifi
WiFiMode_t node_type = WIFI_AP_STA;
//wifi
WiFiMode_t node_type = WIFI_AP_STA;
#if defined(DISABLE_AP)
// system_phy_set_max_tpw(0);
WiFi.setTxPower(WIFI_POWER_MINUS_1dBm); // Set WiFi RF power output to lowest level
node_type = WIFI_STA;
// system_phy_set_max_tpw(0);
WiFi.setTxPower(WIFI_POWER_MINUS_1dBm); // Set WiFi RF power output to lowest level
node_type = WIFI_STA;
#endif
WiFi.mode(node_type);
WiFi.mode(node_type);
//esp-now
if (esp_now_init() != 0) {
Serial.println("Error initializing ESP-NOW");
return;
}
esp_now_register_send_cb(onDataSent);
esp_now_register_recv_cb(onDataReceive);
//
// Serial.println("- ! (esp_now_add_peer) ==> add a 'broadcast peer' (FF:FF:FF:FF:FF:FF).");
// uint8_t broadcastmac[6] = {0xFF, 0xFF, 0xFF, 0xFF, 0xFF, 0xFF};
//
// //
// esp_now_peer_info_t peerInfo = {};
// memcpy(peerInfo.peer_addr, broadcastmac, 6);
// peerInfo.channel = 0;
// peerInfo.encrypt = false;
// esp_now_add_peer(&peerInfo);
//esp-now
if (esp_now_init() != 0) {
Serial.println("Error initializing ESP-NOW");
return;
}
esp_now_register_send_cb(onDataSent);
esp_now_register_recv_cb(onDataReceive);
//
// Serial.println("- ! (esp_now_add_peer) ==> add a 'broadcast peer' (FF:FF:FF:FF:FF:FF).");
// uint8_t broadcastmac[6] = {0xFF, 0xFF, 0xFF, 0xFF, 0xFF, 0xFF};
//
// //
// esp_now_peer_info_t peerInfo = {};
// memcpy(peerInfo.peer_addr, broadcastmac, 6);
// peerInfo.channel = 0;
// peerInfo.encrypt = false;
// esp_now_add_peer(&peerInfo);
AddressBook * book = lib.getBookByTitle(ADDRESSBOOK_TITLE);
if (book == NULL) {
Serial.println("- ! wrong book !! : \"" + String(ADDRESSBOOK_TITLE) + "\""); while(1);
}
for (int idx = 0; idx < book->list.size(); idx++) {
Serial.println("- ! (esp_now_add_peer) ==> add a '" + book->list[idx].name + "'.");
esp_now_peer_info_t peerInfo = {};
memcpy(peerInfo.peer_addr, book->list[idx].mac, 6);
peerInfo.channel = 0;
peerInfo.encrypt = false;
esp_now_add_peer(&peerInfo);
}
// (DEBUG) fetch full peer list
{ PeerLister a; a.print(); }
//
Serial.println("-");
Serial.println("\".-.-.-. :)\"");
Serial.println();
AddressBook * book = lib.getBookByTitle(ADDRESSBOOK_TITLE);
if (book == NULL) {
Serial.println("- ! wrong book !! : \"" + String(ADDRESSBOOK_TITLE) + "\""); while(1);
}
for (int idx = 0; idx < book->list.size(); idx++) {
Serial.println("- ! (esp_now_add_peer) ==> add a '" + book->list[idx].name + "'.");
esp_now_peer_info_t peerInfo = {};
memcpy(peerInfo.peer_addr, book->list[idx].mac, 6);
peerInfo.channel = 0;
peerInfo.encrypt = false;
esp_now_add_peer(&peerInfo);
}
// (DEBUG) fetch full peer list
{ PeerLister a; a.print(); }
//
Serial.println("-");
Serial.println("\".-.-.-. :)\"");
Serial.println();
}
void loop() {
//
runner.execute();
//
//
runner.execute();
//
}