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docker-voltronic-homeassistant/sources/inverter-cli/inverter.cpp
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Pi Developer 547537e761
Build Docker Image for Raspberry Pi / build-and-push (push) Failing after 1m15s
Details
Implementazione supporto multi-inverter paralleli e fix comunicazione MQTT 
- Aggiunto supporto lettura inverter paralleli tramite comandi QPGS0-QPGS9
- Implementato discovery automatico inverter con filtro duplicati e serial invalidi
- Risolti bug critici comunicazione seriale:
  * Fix buffer ExecuteCmd da 7 a 200 bytes
  * Supporto terminatori CR e LF
  * Modalità blocking con delay 500ms
  * Lettura byte-by-byte per terminatore affidabile
- Implementato script MQTT per pubblicazione dati multi-inverter:
  * mqtt-push-parallel.sh con topic separati per ogni inverter
  * Fix autenticazione MQTT con username/password
  * Aggiunto flag retain (-r) per persistenza dati
- Creato test-loop-parallel.sh per simulazione completa container
- Aggiornata documentazione con compatibilità MKS IV e guida test loop
- Aggiornati profili debug VS Code per bash e parallel discovery
- Configurazione MQTT completa con server reale (192.168.1.37:1883)

Sistema testato e funzionante con 2 inverter Voltronic Axpert MKS IV
2026-01-31 16:15:26 +01:00

555 lines
17 KiB
C++
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#include <fcntl.h>
#include <stdio.h>
#include <string.h>
#include <string>
#include <unistd.h>
#include "inverter.h"
#include "tools.h"
#include "main.h"
#include <fcntl.h>
#include <termios.h>
cInverter::cInverter(std::string devicename, int qpiri, int qpiws, int qmod, int qpigs) {
device = devicename;
status1[0] = 0;
status2[0] = 0;
warnings[0] = 0;
mode = 0;
buf_qpiri = qpiri;
buf_qpiws = qpiws;
buf_qmod = qmod;
buf_qpigs = qpigs;
lprintf("INVERTER: Initialized with buffer sizes - QPIRI:%d QPIWS:%d QMOD:%d QPIGS:%d",
buf_qpiri, buf_qpiws, buf_qmod, buf_qpigs);
}
string *cInverter::GetQpigsStatus() {
m.lock();
string *result = new string(status1);
m.unlock();
return result;
}
string *cInverter::GetQpiriStatus() {
m.lock();
string *result = new string(status2);
m.unlock();
return result;
}
string *cInverter::GetWarnings() {
m.lock();
string *result = new string(warnings);
m.unlock();
return result;
}
void cInverter::SetMode(char newmode) {
m.lock();
if (mode && newmode != mode)
ups_status_changed = true;
mode = newmode;
m.unlock();
}
int cInverter::GetMode() {
int result;
m.lock();
switch (mode) {
case 'P': result = 1; break; // Power_On
case 'S': result = 2; break; // Standby
case 'L': result = 3; break; // Line
case 'B': result = 4; break; // Battery
case 'F': result = 5; break; // Fault
case 'H': result = 6; break; // Power_Saving
default: result = 0; break; // Unknown
}
m.unlock();
return result;
}
bool cInverter::query(const char *cmd, int replysize) {
time_t started;
int fd;
int i=0, n;
fd = open(this->device.data(), O_RDWR | O_NOCTTY);
if (fd == -1) {
lprintf("INVERTER: Unable to open device file (errno=%d %s)", errno, strerror(errno));
sleep(5);
return false;
}
// Once connected, set the baud rate and other serial config (Don't rely on this being correct on the system by default...)
speed_t baud = B2400;
// Speed settings (in this case, 2400 8N1)
struct termios settings;
tcgetattr(fd, &settings);
cfsetospeed(&settings, baud); // baud rate
cfsetispeed(&settings, baud); // input baud rate
settings.c_cflag &= ~PARENB; // no parity
settings.c_cflag &= ~CSTOPB; // 1 stop bit
settings.c_cflag &= ~CSIZE;
settings.c_cflag |= CS8 | CLOCAL; // 8 bits
// settings.c_lflag = ICANON; // canonical mode
settings.c_oflag &= ~OPOST; // raw output
tcsetattr(fd, TCSANOW, &settings); // apply the settings
// CRITICAL: Flush both input and output buffers to clear any residual data
tcflush(fd, TCIOFLUSH);
// Wait a bit for the device to settle after flush
usleep(100000); // 100ms delay
// Clear internal buffer
memset(buf, 0, sizeof(buf));
// ---------------------------------------------------------------
// Generating CRC for a command
uint16_t crc = cal_crc_half((uint8_t*)cmd, strlen(cmd));
n = strlen(cmd);
memcpy(&buf, cmd, n);
lprintf("INVERTER: Current CRC: %X %X", crc >> 8, crc & 0xff);
buf[n++] = crc >> 8;
buf[n++] = crc & 0xff;
buf[n++] = 0x0d;
//send a command
int written = write(fd, &buf, n);
if (written != n) {
lprintf("INVERTER: %s write failed (wrote %d of %d bytes)", cmd, written, n);
close(fd);
return false;
}
// Flush output to ensure command is sent
tcdrain(fd);
// Critical delay after write (like Python implementation)
usleep(500000); // 500ms delay
// Clear buffer again before reading
memset(buf, 0, sizeof(buf));
time(&started);
do {
n = read(fd, (void*)buf+i, 1); // Read one byte at a time for reliable terminator detection
if (n < 0) {
if (time(NULL) - started > 2) {
lprintf("INVERTER: %s read timeout", cmd);
break;
} else {
usleep(10000); // 10ms
continue;
}
}
if (n > 0) {
i += n;
// Check if we've received the terminator (CR or LF)
if (i > 0 && (buf[i-1] == 0x0d || buf[i-1] == 0x0a)) {
lprintf("INVERTER: %s received terminator (0x%02X) at byte %d", cmd, buf[i-1], i);
break;
}
}
} while (i<replysize && (time(NULL) - started < 3));
close(fd);
if (i > 0) {
lprintf("INVERTER: %s reply size (%d bytes, expected %d)", cmd, i, replysize);
// Dump raw buffer for debugging
if (debugFlag) {
lprintf("INVERTER: Raw buffer hex dump (first 50 bytes):");
for(int x = 0; x < (i < 50 ? i : 50); x++) {
fprintf(stderr, "%02X ", buf[x]);
if ((x+1) % 16 == 0) fprintf(stderr, "\n");
}
fprintf(stderr, "\n");
}
if (buf[0]!='(' ) {
lprintf("INVERTER: %s: incorrect start byte (got 0x%02X, expected '('). Buffer: %s", cmd, buf[0], buf);
return false;
}
if (buf[i-1]!=0x0d && buf[i-1]!=0x0a) {
lprintf("INVERTER: %s: incorrect stop byte (got 0x%02X at pos %d, expected CR or LF). Buffer: %s", cmd, buf[i-1], i-1, buf);
return false;
}
if (!(CheckCRC(buf, i))) {
lprintf("INVERTER: %s: CRC Failed! Reply size: %d Buffer: %s", cmd, i, buf);
return false;
}
buf[i-3] = '\0'; //nullterminating on first CRC byte
lprintf("INVERTER: %s: %d bytes read: %s", cmd, i, buf);
lprintf("INVERTER: %s query finished", cmd);
// If expected size doesn't match actual size, log it
if (i != replysize) {
lprintf("INVERTER: WARNING - %s actual size (%d) differs from configured size (%d)", cmd, i, replysize);
lprintf("INVERTER: SUGGESTION - Update inverter.conf to set the buffer size to %d", i);
}
return true;
} else {
lprintf("INVERTER: %s reply too short (%d bytes)", cmd, i);
return false;
}
}
void cInverter::poll() {
int n,j;
fprintf(stderr, "[POLL] Thread started, runOnce=%s\n", runOnce ? "true" : "false");
while (true) {
// Reading mode
if (!ups_qmod_changed) {
fprintf(stderr, "[POLL] Reading QMOD...\n");
if (query("QMOD", buf_qmod)) {
SetMode(buf[1]);
ups_qmod_changed = true;
fprintf(stderr, "[POLL] QMOD completed\n");
}
}
// reading status (QPIGS)
if (!ups_qpigs_changed) {
fprintf(stderr, "[POLL] Reading QPIGS...\n");
if (query("QPIGS", buf_qpigs)) {
m.lock();
strcpy(status1, (const char*)buf+1);
m.unlock();
ups_qpigs_changed = true;
fprintf(stderr, "[POLL] QPIGS completed\n");
}
}
// Reading QPIRI status
if (!ups_qpiri_changed) {
fprintf(stderr, "[POLL] Reading QPIRI...\n");
if (query("QPIRI", buf_qpiri)) {
m.lock();
strcpy(status2, (const char*)buf+1);
m.unlock();
ups_qpiri_changed = true;
fprintf(stderr, "[POLL] QPIRI completed\n");
}
}
// Get any device warnings...
if (!ups_qpiws_changed) {
fprintf(stderr, "[POLL] Reading QPIWS...\n");
if (query("QPIWS", buf_qpiws)) {
m.lock();
strcpy(warnings, (const char*)buf+1);
m.unlock();
ups_qpiws_changed = true;
fprintf(stderr, "[POLL] QPIWS completed\n");
}
}
// If runOnce mode and all data collected, exit the thread
if (runOnce && ups_qmod_changed && ups_qpigs_changed && ups_qpiri_changed && ups_qpiws_changed) {
fprintf(stderr, "[POLL] All data collected, exiting (run-once mode)\n");
return;
}
fprintf(stderr, "[POLL] Flags: QMOD=%d QPIGS=%d QPIRI=%d QPIWS=%d, sleeping...\n",
ups_qmod_changed.load(), ups_qpigs_changed.load(),
ups_qpiri_changed.load(), ups_qpiws_changed.load());
sleep(2);
}
}
void cInverter::ExecuteCmd(const string cmd) {
// Sending any command raw - use larger buffer to accept full responses
if (query(cmd.data(), 200)) {
m.lock();
strcpy(status2, (const char*)buf+1);
m.unlock();
}
}
uint16_t cInverter::cal_crc_half(uint8_t *pin, uint8_t len) {
uint16_t crc;
uint8_t da;
uint8_t *ptr;
uint8_t bCRCHign;
uint8_t bCRCLow;
uint16_t crc_ta[16]= {
0x0000,0x1021,0x2042,0x3063,0x4084,0x50a5,0x60c6,0x70e7,
0x8108,0x9129,0xa14a,0xb16b,0xc18c,0xd1ad,0xe1ce,0xf1ef
};
ptr=pin;
crc=0;
while(len--!=0) {
da=((uint8_t)(crc>>8))>>4;
crc<<=4;
crc^=crc_ta[da^(*ptr>>4)];
da=((uint8_t)(crc>>8))>>4;
crc<<=4;
crc^=crc_ta[da^(*ptr&0x0f)];
ptr++;
}
bCRCLow = crc;
bCRCHign= (uint8_t)(crc>>8);
if(bCRCLow==0x28||bCRCLow==0x0d||bCRCLow==0x0a)
bCRCLow++;
if(bCRCHign==0x28||bCRCHign==0x0d||bCRCHign==0x0a)
bCRCHign++;
crc = ((uint16_t)bCRCHign)<<8;
crc += bCRCLow;
return(crc);
}
bool cInverter::CheckCRC(unsigned char *data, int len) {
uint16_t crc = cal_crc_half(data, len-3);
return data[len-3]==(crc>>8) && data[len-2]==(crc&0xff);
}
// Auto-discover the correct buffer size for a command by reading until CR
int cInverter::query_auto(const char *cmd, int max_size) {
time_t started;
int fd;
int i=0, n;
unsigned char temp_buf[1024];
memset(temp_buf, 0, sizeof(temp_buf));
fd = open(this->device.data(), O_RDWR | O_NONBLOCK);
if (fd == -1) {
lprintf("INVERTER: Unable to open device file for auto-discovery");
return -1;
}
// Configure serial port
speed_t baud = B2400;
struct termios settings;
tcgetattr(fd, &settings);
cfsetospeed(&settings, baud);
cfsetispeed(&settings, baud);
settings.c_cflag &= ~PARENB;
settings.c_cflag &= ~CSTOPB;
settings.c_cflag &= ~CSIZE;
settings.c_cflag |= CS8 | CLOCAL;
settings.c_oflag &= ~OPOST;
tcsetattr(fd, TCSANOW, &settings);
// Flush all buffers
tcflush(fd, TCIOFLUSH);
usleep(200000); // 200ms delay to ensure clean state
// Generate and send command with CRC
uint16_t crc = cal_crc_half((uint8_t*)cmd, strlen(cmd));
n = strlen(cmd);
memcpy(&temp_buf, cmd, n);
temp_buf[n++] = crc >> 8;
temp_buf[n++] = crc & 0xff;
temp_buf[n++] = 0x0d;
write(fd, &temp_buf, n);
tcdrain(fd);
// Clear buffer for reading
memset(temp_buf, 0, sizeof(temp_buf));
time(&started);
// Read until we find CR (0x0d) or timeout
while (i < max_size && (time(NULL) - started < 5)) {
n = read(fd, temp_buf+i, 1); // Read one byte at a time
if (n > 0) {
i += n;
// Found the terminator
if (temp_buf[i-1] == 0x0d) {
lprintf("INVERTER: Auto-discovery for %s: found CR at byte %d", cmd, i);
break;
}
} else {
usleep(10000); // 10ms between reads
}
}
close(fd);
// Validate the response
if (i > 0 && temp_buf[0] == '(' && temp_buf[i-1] == 0x0d) {
lprintf("INVERTER: Auto-discovery for %s successful: %d bytes", cmd, i);
return i;
} else {
lprintf("INVERTER: Auto-discovery for %s failed (read %d bytes)", cmd, i);
// Dump what we received for debugging
if (i > 0) {
lprintf("INVERTER: Received data (hex):");
for(int x = 0; x < i; x++) {
fprintf(stderr, "%02X ", temp_buf[x]);
}
fprintf(stderr, "\n");
lprintf("INVERTER: Received data (ascii):");
for(int x = 0; x < i; x++) {
fprintf(stderr, "%c", (temp_buf[x] >= 32 && temp_buf[x] < 127) ? temp_buf[x] : '.');
}
fprintf(stderr, "\n");
}
return -1;
}
}
// Auto-discover buffer sizes for all commands
void cInverter::AutoDiscoverBufferSizes() {
printf("\n=== AUTO-DISCOVERY MODE ===\n");
printf("Testing inverter to find correct buffer sizes...\n\n");
int qmod_size = query_auto("QMOD", 20);
if (qmod_size > 0) {
printf("✓ QMOD buffer size: %d\n", qmod_size);
} else {
printf("✗ QMOD auto-discovery failed\n");
}
sleep(1);
int qpigs_size = query_auto("QPIGS", 150);
if (qpigs_size > 0) {
printf("✓ QPIGS buffer size: %d\n", qpigs_size);
} else {
printf("✗ QPIGS auto-discovery failed\n");
}
sleep(1);
int qpiri_size = query_auto("QPIRI", 150);
if (qpiri_size > 0) {
printf("✓ QPIRI buffer size: %d\n", qpiri_size);
} else {
printf("✗ QPIRI auto-discovery failed\n");
}
sleep(1);
int qpiws_size = query_auto("QPIWS", 100);
if (qpiws_size > 0) {
printf("✓ QPIWS buffer size: %d\n", qpiws_size);
} else {
printf("✗ QPIWS auto-discovery failed\n");
}
printf("\n=== SUGGESTED CONFIGURATION ===\n");
printf("Update your /etc/inverter/inverter.conf with these values:\n\n");
if (qmod_size > 0) printf("qmod=%d\n", qmod_size);
if (qpigs_size > 0) printf("qpigs=%d\n", qpigs_size);
if (qpiri_size > 0) printf("qpiri=%d\n", qpiri_size);
if (qpiws_size > 0) printf("qpiws=%d\n", qpiws_size);
printf("\n");
// Output in parsable format for scripts
printf("DISCOVERY_QMOD=%d\n", qmod_size > 0 ? qmod_size : 5);
printf("DISCOVERY_QPIGS=%d\n", qpigs_size > 0 ? qpigs_size : 110);
printf("DISCOVERY_QPIRI=%d\n", qpiri_size > 0 ? qpiri_size : 98);
printf("DISCOVERY_QPIWS=%d\n", qpiws_size > 0 ? qpiws_size : 36);
printf("DISCOVERY_SUCCESS=%s\n", (qmod_size > 0 && qpigs_size > 0 && qpiri_size > 0 && qpiws_size > 0) ? "true" : "false");
}
// Discover number of parallel inverters
int cInverter::DiscoverParallelInverters() {
fprintf(stderr, "\n=== PARALLEL INVERTER DISCOVERY ===\n");
fprintf(stderr, "Checking for parallel inverter configuration...\n\n");
int count = 0;
char cmd[16];
std::string found_serials[10]; // Track unique serials
// Test QPGS0 through QPGS9
for (int i = 0; i < 10; i++) {
snprintf(cmd, sizeof(cmd), "QPGS%d", i);
if (query(cmd, 200)) {
// Check if response is valid (not NAK)
if (buf[0] == '(' && buf[1] != 'N') {
// Extract serial number (starts at position 3)
char serial[20] = {0};
int j = 0;
for (int k = 3; k < 17 && buf[k] != ' '; k++) {
serial[j++] = buf[k];
}
// Check if serial is valid (not all zeros and not empty)
bool valid_serial = false;
for (int k = 0; k < j; k++) {
if (serial[k] != '0') {
valid_serial = true;
break;
}
}
// Check if serial is duplicate
bool duplicate = false;
std::string serial_str(serial);
for (int k = 0; k < count; k++) {
if (found_serials[k] == serial_str) {
duplicate = true;
break;
}
}
if (valid_serial && j > 0 && !duplicate) {
found_serials[count] = serial_str;
count++;
fprintf(stderr, "✓ Inverter #%d via %s (Serial: %s)\n", count, cmd, serial);
printf("INVERTER_%d_SERIAL=%s\n", count, serial);
printf("INVERTER_%d_QPGS=%d\n", count, i);
} else if (duplicate) {
fprintf(stderr, "⊗ Skipping %s (Duplicate serial: %s)\n", cmd, serial);
} else {
fprintf(stderr, "⊗ Skipping %s (Invalid serial: %s)\n", cmd, serial);
}
}
}
usleep(100000); // 100ms between queries
}
fprintf(stderr, "\n=== DISCOVERY RESULT ===\n");
fprintf(stderr, "Total unique parallel inverters: %d\n", count);
printf("PARALLEL_COUNT=%d\n", count);
return count;
}
// Get parallel status for specific inverter
string cInverter::GetParallelStatus(int inverter_num) {
char cmd[16];
snprintf(cmd, sizeof(cmd), "QPGS%d", inverter_num);
if (query(cmd, 200)) {
if (buf[0] == '(' && buf[1] != 'N') {
// Return data without leading '('
return string((char*)buf + 1);
}
}
return "";
}
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