#if defined BOARD_OBP60S3 || defined BOARD_OBP40S3 #include "BoatDataCalibration.h" #include "OBP60Extensions.h" #include "Pagedata.h" #include // **************************************************************** class wndHistory { // provides a circular buffer to store wind history values private: int SIZE; std::vector buffer; int first; // points to the first (oldest) valid element int last; // points to the last (newest) valid element int head; // points to the next insertion index int count; // number of valid elements public: bool begin(int size) // start buffer { if (size <= 0 || size > 10000) { return false; } SIZE = size; buffer.resize(size, INT_MIN); // allocate buffer head = 0; first = 0; last = 0; count = 0; return true; } void add(int value) // Add a new value; store in [0..360 deg] format { if (value < 0 || value > 360) value = INT_MIN; buffer[head] = value; last = head; head = (head + 1) % SIZE; if (count < SIZE) { count++; } else { first = head - 1; // When buffer is full, first points to the oldest value if (first < 0) first += SIZE; } } int get(int index) const // Get value by index in [0..360 deg] format (0 = oldest, count-1 = newest) { int realIndex; if (index < 0 || index >= count) { return -1; // Invalid index } realIndex = (first + index) % SIZE; return buffer[realIndex]; } int get(int index, int deg) const // Get value by index in [-180..180 deg] or [0..360 deg] format (0 = oldest, count-1 = newest) { switch (deg) { case 180: // Return value in [-180..180 deg] format return get(index); case 360: { // Return value in [0..360 deg] format int value = get(index); if (value < 0) { value += 360; }; return value; } default: // Return value in [-180..180 deg] format return -1; } } int getSize() const // Get number of valid elements { return count; } int getMin() const // Get minimum value of buffer { if (count == 0) { return -1; // Buffer is empty } else if (first + count <= SIZE) { // No wrap-around return *std::min_element(buffer.begin() + first, buffer.begin() + first + count); } else { // Wrap-around: check [first, end) and [begin, (first+count)%SIZE) int min1 = *std::min_element(buffer.begin() + first, buffer.end()); int min2 = *std::min_element(buffer.begin(), buffer.begin() + ((first + count) % SIZE)); return std::min(min1, min2); } } /* int getMin(int amount) const // Get minimum value of the last values of buffer { if (count == 0 || amount <= 0) { return -1; } else if (amount > count) { amount = count; // Limit to available values } if (last + amount <= SIZE) { // No wrap-around return *std::min_element(buffer.begin() + last, buffer.begin() + (last + amount)); } else { // Wrap-around int min1 = *std::min_element(buffer.begin() + ((last - amount) % last), buffer.begin() + last); int min2 = *std::min_element(buffer.end() - (count - amount - last > 0 ? amount - last : 0), buffer.end()); return std::min(min1, min2); } } */ int getMin(int amount) const // Get minimum value of the last values of buffer { if (count == 0 || amount <= 0) return -1; if (amount > count) amount = count; int minVal = INT_MAX; // Start from the newest value (last) and go backwards x times for (int i = 0; i < amount; ++i) { // int idx = (last - i + SIZE) % SIZE; // if (buffer[idx] < minVal) // minVal = buffer[idx]; if (get(i) > minVal) minVal = get(i); } return minVal; } int getMax() const // Get maximum value of buffer { if (count == 0) { return -1; // Buffer is empty } else if (first + count <= SIZE) { // No wrap-around return *std::max_element(buffer.begin() + first, buffer.begin() + first + count); } else { // Wrap-around: check [first, end) and [begin, (first+count)%SIZE) int max1 = *std::max_element(buffer.begin() + first, buffer.end()); int max2 = *std::max_element(buffer.begin(), buffer.begin() + ((first + count) % SIZE)); return std::max(max1, max2); } } int getMax(int amount) const // Get maximum value of the last values of buffer { if (count == 0 || amount <= 0) return -1; if (amount > count) amount = count; int maxVal = INT_MIN; // Start from the newest value (last) and go backwards x times for (int i = 0; i < amount; ++i) { // int idx = (last - i + SIZE) % SIZE; // if (buffer[idx] > maxVal) // maxVal = buffer[idx]; if (get(i) > maxVal) maxVal = get(i); } return maxVal; } /* int getMax(int amount) const // Get maximum value of the last values of buffer { if (count == 0 || amount <= 0) { return -1; } else if (amount > count) { amount = count; // Limit to available values } if (first + count <= SIZE) { // No wrap-around return *std::max_element(buffer.begin() + last, buffer.begin() + (last + amount)); } else { // Wrap-around int max1 = *std::max_element(buffer.begin() + ((last - amount) % last), buffer.begin() + last); int max2 = *std::max_element(buffer.end(), buffer.end() - (amount - last > 0 ? amount - last : 0); return std::max(max1, max2); } } */ int getMid(int amount) const // Get middle value in the buffer { if (count == 0) { return -1; // Buffer is empty } return (getMin(amount) + getMax(amount)) / 2; } int getRng(int center, int amount) const // Get maximum difference of last of buffer values to center value { if (count == 0 || amount <= 0) return -1; if (amount > count) amount = count; int maxRng = INT_MIN; int rng = 0; // Start from the newest value (last) and go backwards x times for (int i = 0; i < amount; ++i) { rng = abs(((get(i) - center + 540) % 360) - 180); if (rng > maxRng) maxRng = rng; } if (maxRng > 180) { maxRng = 180; } return maxRng; } void mvStart(int delta) // Move the start index of buffer forward by positions -> virtually delete oldest data entries { first = (first + delta) % SIZE; if (count > delta) count -= delta; else count = 0; if (first == 0) last = count; else last = first - 1; } }; // **************************************************************** class PageWindPlot : public Page { bool keylock = false; // Keylock // int16_t lp = 80; // Pointer length char chrtMode = 'D'; // Chart mode: 'D' for TWD, 'S' for TWS, 'B' for both06121990 int dataInterv = 1; // Update interval for wind history chart: // (1)|(2)|(3)|(4) seconds for approx. 4, 8, 12, 16 min. history chart bool showTWS = true; // Show TWS value in chart area public: PageWindPlot(CommonData& common) { commonData = &common; common.logger->logDebug(GwLog::LOG, "Instantiate PageWindPlot"); } virtual void setupKeys() { Page::setupKeys(); commonData->keydata[0].label = "MODE"; commonData->keydata[1].label = "INTV"; commonData->keydata[4].label = "TWS"; } // Key functions virtual int handleKey(int key) { // Set chart mode TWD | TWS if (key == 1) { if (chrtMode == 'D') { chrtMode = 'S'; } else if (chrtMode == 'S') { chrtMode = 'B'; } else { chrtMode = 'D'; } return 0; // Commit the key } // Set interval for wind history chart update time if (key == 2) { if (dataInterv == 1) { dataInterv = 2; } else if (dataInterv == 2) { dataInterv = 3; } else if (dataInterv == 3) { dataInterv = 4; } else { dataInterv = 1; } return 0; // Commit the key } // Switch TWS on/off if (key == 5) { showTWS = !showTWS; return 0; // Commit the key } // Keylock function if (key == 11) { // Code for keylock commonData->keylock = !commonData->keylock; return 0; // Commit the key } return key; } virtual void displayPage(PageData& pageData) { GwConfigHandler* config = commonData->config; GwLog* logger = commonData->logger; static wndHistory windDirHstry; // Circular buffer to store wind direction values static wndHistory windSpdHstry; // Circular buffer to store wind speed values GwApi::BoatValue* bvalue; const int numCfgValues = 9; String dataName[numCfgValues]; double dataValue[numCfgValues]; bool dataValid[numCfgValues]; String dataSValue[numCfgValues]; String dataUnit[numCfgValues]; String dataSValueOld[numCfgValues]; String dataUnitOld[numCfgValues]; int twdValue; static const float radToDeg = 180.0 / M_PI; // Conversion factor from radians to degrees bool wndDataValid = false; // Flag to indicate if wind data is valid bool simulation = false; bool holdValues = false; int width = getdisplay().width(); // Get screen width int height = getdisplay().height(); // Get screen height int xCenter = width / 2; // Center of screen in x direction static const int yOffset = 48; // Offset for y coordinates of chart area int cHeight = height - yOffset - 22; // height of chart area // cHeight = 60; int bufSize = cHeight * 4; // Buffer size: 920 values for appox. 16 min. history chart int intvBufSize; // Buffer size used for currently selected time interval int count; // current size of buffer int numWndValues; // number of wind values available for current interval selection static int linesToShow; // current number of lines to display on chart static int bufStart; // 1st data value in buffer to show static int oldDataInterv; // remember recent user selection of data interval static int newDate; // indicates for higher time intervals that new date is available static int wndCenter = INT_MIN; // chart wind center value position; init value indicates that wndCenter is not set yet static int wndLeft; // chart wind left value position static int wndRight; // chart wind right value position static int chrtRng; // Range of wind values from mid wind value to min/max wind value in degrees int diffRng; // Difference between mid and current wind value static const int dfltRng = 40; // Default range for chart static int simWnd = 0; // Simulation value for wind data static float simTWS = 0; // Simulation value for TWS data static const int simStep = 10; // Simulation step for wind data int x, y; // x and y coordinates for drawing static int prevX, prevY; // Last x and y coordinates for drawing static float chrtScl; // Scale for wind values in pixels per degree int chrtVal; // Current wind value static int chrtPrevVal; // Last wind value in chart area for check if value crosses 180 degree line int distVals; // helper to check wndCenter crossing int distMid; // helper to check wndCenter crossing LOG_DEBUG(GwLog::LOG, "Display page WindPlot"); unsigned long start = millis(); // Data initialization if (windDirHstry.getSize() == 0) { if (!windDirHstry.begin(bufSize)) { logger->logDebug(GwLog::ERROR, "Failed to initialize wind direction history buffer"); return; } simWnd = 0; simTWS = 0; twdValue = 0; bufStart = 0; linesToShow = 0; oldDataInterv = dataInterv; newDate = 0; } // Get config data // String lengthformat = config->getString(config->lengthFormat); simulation = config->getBool(config->useSimuData); holdValues = config->getBool(config->holdvalues); String flashLED = config->getString(config->flashLED); String backlightMode = config->getString(config->backlight); // Optical warning by limit violation (unused) if (String(flashLED) == "Limit Violation") { setBlinkingLED(false); setFlashLED(false); } // Read boatdata values for TWD, TWA, TWS, HDM, AWA, AWS, STW, COG, SOG, if available for (int i = 0; i < numCfgValues; i++) { bvalue = pageData.values[i]; dataName[i] = xdrDelete(bvalue->getName()); dataName[i] = dataName[i].substring(0, 6); // String length limit for value name calibrationData.calibrateInstance(dataName[i], bvalue, logger); // Check if boat data value is to be calibrated dataValue[i] = bvalue->value; // Value as double in SI unit calibrationData.calibrateInstance(dataName[i], bvalue, logger); // Check if boat data value is to be calibrated dataValid[i] = bvalue->valid; dataSValue[i] = formatValue(bvalue, *commonData).svalue; // Formatted value as string including unit conversion and switching decimal places dataUnit[i] = formatValue(bvalue, *commonData).unit; if (dataValid[i]) { dataSValueOld[i] = dataSValue[i]; // Save old value dataUnitOld[i] = dataUnit[i]; // Save old unit } } // Store TWD wind value in buffer, regardless of validity -> one value per second (if delivered in that frequency) twdValue = int((dataValue[0] * radToDeg) + 0.5); // Read TWD value in degrees and round to integer if (dataValid[0]) { // TWD data existing wndDataValid = true; } else { // Try to calculate TWD value from other data, if available // wndDataValid = windValues.calcTWD(&twdValue, dataValue[1], dataValue[2], dataValue[3], dataValue[4], dataValue[5], dataValue[6]); } if (simulation) { // Simulate data if simulation is enabled; use default simulation values for TWS simWnd += random(simStep * -1, simStep); // random value between -simStep and +simStep if (simWnd < 0) simWnd += 360; simWnd = simWnd % 360; windDirHstry.add(simWnd); // LOG_DEBUG(GwLog::DEBUG, "PageWindPlot simulation data: windValue: %d, windSpeed: %s", simWnd, dataSValue[2].c_str()); } else if (wndDataValid) { windDirHstry.add(twdValue); } // Identify buffer sizes and buffer position to print on the chart intvBufSize = cHeight * dataInterv; count = windDirHstry.getSize(); numWndValues = min(count, intvBufSize); newDate++; if (dataInterv != oldDataInterv) { linesToShow = min(numWndValues / dataInterv, max(0, cHeight - 40)); bufStart = max(0, (count - (linesToShow * dataInterv))); oldDataInterv = dataInterv; } else if (newDate >= dataInterv) { linesToShow = min(numWndValues / dataInterv, linesToShow + 1); newDate = 0; } if (count == bufSize) bufStart--; // show the latest wind values in buffer; keep 1st value constant in a rolling buffer when new data is added LOG_DEBUG(GwLog::ERROR, "PageWindPlot DateSet: TWD: %d, count: %d, bufStart: %d, linesToShow: %d, newDate: %d", twdValue, count, bufStart, linesToShow, newDate); if (bvalue == NULL) return; LOG_DEBUG(GwLog::LOG, "PageWindPlot, %s:%f, %s:%f, %s:%f, %s:%f, %s:%f, %s:%f, %s:%f, %s:%f, %s:%f, cnt: %d, valid0: %d", dataName[0].c_str(), dataValue[0], dataName[1].c_str(), dataValue[1], dataName[2].c_str(), dataValue[2], dataName[3].c_str(), dataValue[3], dataName[4].c_str(), dataValue[4], dataName[5].c_str(), dataValue[5], dataName[6].c_str(), dataValue[6], dataName[7].c_str(), dataValue[7], dataName[8].c_str(), dataValue[8], count, dataValid[0]); // initialize chart range values if (wndCenter == INT_MIN) { wndCenter = windDirHstry.get(max(0, numWndValues - intvBufSize)); // get 1st value of current data interval wndCenter = (int((wndCenter + (wndCenter >= 0 ? 5 : -5)) / 10) * 10) % 360; // Set new center value; round to nearest 10 degree value; 360° -> 0° diffRng = dfltRng; chrtRng = dfltRng; } else { // check and adjust range between left, center, and right chart limit diffRng = windDirHstry.getRng(wndCenter, numWndValues); diffRng = (diffRng < 0 ? 0 : diffRng); // If no data in buffer, set range to 0 if (diffRng > chrtRng) { chrtRng = int((diffRng + (diffRng >= 0 ? 9 : -1)) / 10) * 10; // Round up to next 10 degree value } else if (diffRng + 10 < chrtRng) { // Reduce chart range for higher resolution if possible chrtRng = max(dfltRng, int((diffRng + (diffRng >= 0 ? 9 : -1)) / 10) * 10); } int debugMin = windDirHstry.getMin(numWndValues); int debugMax = windDirHstry.getMax(numWndValues); LOG_DEBUG(GwLog::ERROR, "PageWindPlot Range. wndCenter: %d, numWndValues: %d, min: %d, max: %d, diffrng: %d, chrtRng: %d ", wndCenter, numWndValues, debugMin, debugMax, diffRng, chrtRng); } chrtScl = float(width) / float(chrtRng) / 2.0; // Chart scale: pixels per degree // wndCenter = windDirHstry.get(max(0, numWndValues - intvBufSize)); // Get 1st value of current data interval // wndCenter = int((wndCenter + (wndCenter >= 0 ? 5 : -5)) / 10) * 10; // Round to nearest 10 degree value wndLeft = wndCenter - chrtRng; if (wndLeft < 0) wndLeft += 360; wndRight = wndCenter + chrtRng - 1; if (wndRight >= 360) wndRight -= 360; // LOG_DEBUG(GwLog::DEBUG, "PageWindPlot dataValue[0]: %f, windValue: %d, count: %d, diffRng: %d, chartRng: %d, Center: %d, scale: %f", double(dataValue[0] * radToDeg), // (!windDirHstry.get(count - 1) < 0 ? 0 : windDirHstry.get(count - 1)), count, diffRng, chrtRng, wndCenter, chrtScl); // Draw page //*********************************************************** // Set display in partial refresh mode getdisplay().setPartialWindow(0, 0, width, height); // Set partial update getdisplay().setTextColor(commonData->fgcolor); // Horizontal top line for orientation -> to be deleted // getdisplay().fillRect(0, 20, width, 1, commonData->fgcolor); // chart lines getdisplay().fillRect(0, yOffset, width, 2, commonData->fgcolor); getdisplay().fillRect(xCenter, yOffset, 1, cHeight, commonData->fgcolor); // chart labels char sWndLbl[4]; // char buffer for Wind angle label getdisplay().setFont(&Ubuntu_Bold12pt7b); getdisplay().setCursor(xCenter - 88, yOffset - 3); getdisplay().print("TWD"); // Wind name getdisplay().setCursor(xCenter - 20, yOffset - 3); snprintf(sWndLbl, 4, "%03d", (wndCenter < 0) ? (wndCenter + 360) : wndCenter); getdisplay().print(sWndLbl); // Wind center value getdisplay().drawCircle(xCenter + 25, yOffset - 16, 2, commonData->fgcolor); // symbol getdisplay().drawCircle(xCenter + 25, yOffset - 16, 3, commonData->fgcolor); // symbol getdisplay().setCursor(1, yOffset - 3); snprintf(sWndLbl, 4, "%03d", (wndLeft < 0) ? (wndLeft + 360) : wndLeft); getdisplay().print(sWndLbl); // Wind left value getdisplay().drawCircle(46, yOffset - 16, 2, commonData->fgcolor); // symbol getdisplay().drawCircle(46, yOffset - 16, 3, commonData->fgcolor); // symbol getdisplay().setCursor(width - 51, yOffset - 3); snprintf(sWndLbl, 4, "%03d", (wndRight < 0) ? (wndRight + 360) : wndRight); getdisplay().print(sWndLbl); // Wind right value getdisplay().drawCircle(width - 5, yOffset - 16, 2, commonData->fgcolor); // symbol getdisplay().drawCircle(width - 5, yOffset - 16, 3, commonData->fgcolor); // symbol // Draw wind values in chart //*********************************************************** if (wndDataValid || holdValues || simulation) { // if (count == bufSize) // bufStart--; // show the latest wind values in buffer; keep 1st value constant in a rolling buffer for (int i = 0; i < linesToShow; i++) { chrtVal = windDirHstry.get(bufStart + (i * dataInterv)); // show the latest wind values in buffer; keep 1st value constant in a rolling buffer x = ((chrtVal - wndLeft + 360) % 360) * chrtScl; y = yOffset + cHeight - i; // Position in chart area LOG_DEBUG(GwLog::ERROR, "PageWindPlot Chart: i: %d, chrtVal: %d, chrtPrevVal: %d, bufStart: %d count: %d, linesToShow: %d", i, chrtVal, chrtPrevVal, bufStart, count, linesToShow); if (i == 0) { prevX = x; // just a dot for 1st chart point prevY = y; } else { // cross borders check; shift values to [-180..0..180]; when crossing borders, range is 2x 180 degrees int wndLeftDlt = -180 - ((wndLeft >= 180) ? (wndLeft - 360) : wndLeft); int chrtVal180 = ((chrtVal + wndLeftDlt + 180) % 360 + 360) % 360 - 180; int chrtPrevVal180 = ((chrtPrevVal + wndLeftDlt + 180) % 360 + 360) % 360 - 180; // if (i > linesToShow - 15) // LOG_DEBUG(GwLog::ERROR, "PageWindPlot Chart: i: %d, chrtVal: %d, chrtVal180: %d, chrtPrevVal: %d, chrtPrevVal180: %d, wndLeftDlt: %d", i, chrtVal, chrtVal180, chrtPrevVal, chrtPrevVal180, wndLeftDlt); if (((chrtPrevVal180 >= -180) && (chrtPrevVal180 < -90) && (chrtVal180 > 90)) || ((chrtPrevVal180 <= 179) && (chrtPrevVal180 > 90) && chrtVal180 <= -90)) { // If current value crosses chart borders, compared to previous value, split line int xSplit = (((chrtPrevVal180 > 0 ? wndRight : wndLeft) - wndLeft + 360) % 360) * chrtScl; getdisplay().drawLine(prevX, prevY, xSplit, y, commonData->fgcolor); getdisplay().drawLine(prevX, prevY - 1, ((xSplit != prevX) ? xSplit : xSplit - 1), ((xSplit != prevX) ? y - 1 : y), commonData->fgcolor); prevX = (((chrtVal180 > 0 ? wndRight : wndLeft) - wndLeft + 360) % 360) * chrtScl; LOG_DEBUG(GwLog::ERROR, "PageWindPlot Cross: i: %d, chrtVal: %d, chrtPrevVal: %d, wndLeft: %d wndRight: %d, curr:{%d,%d} prev:{%d,%d}", i, chrtVal, chrtPrevVal, wndLeft, wndRight, x, y, prevX, prevY); } } // Draw line with 2 pixels width + make sure vertical line are drawn correctly getdisplay().drawLine(prevX, prevY, x, y, commonData->fgcolor); getdisplay().drawLine(prevX, prevY - 1, ((x != prevX) ? x : x - 1), ((x != prevX) ? y - 1 : y), commonData->fgcolor); chrtPrevVal = chrtVal; prevX = x; prevY = y; if (i == (cHeight - 1)) { // Reaching chart area top end () linesToShow -= min(40, cHeight); // free top 40 lines of chart for new values bufStart = max(0, count - (linesToShow * dataInterv)); // next start value in buffer to show // windDirHstry.mvStart(); // virtually delete 40 values from buffer if ((windDirHstry.getMin(numWndValues) > wndCenter) || (windDirHstry.getMax(numWndValues) < wndCenter)) { // Check if all wind value are left or right of center value -> optimize chart range int mid = windDirHstry.getMid(numWndValues); wndCenter = int((mid + (mid >= 0 ? 5 : -5)) / 10) * 10; // Set new center value; round to nearest 10 degree value } LOG_DEBUG(GwLog::ERROR, "PageWindPlot FreeTop: cHeight: %d, LinesToShow: %d, numWndValues: %d, wndCenter: %d, bufStart: %d", cHeight, linesToShow, numWndValues, wndCenter, bufStart); break; } } // LOG_DEBUG(GwLog::DEBUG, "PageWindPlot chart end: chrtVal: %d, x: %d, y: %d prevX: %d, prevY: %d, loop-Counter: %d", chrtVal, x, y, prevX, prevY, count); } else if (!wndDataValid) { // No valid data available LOG_DEBUG(GwLog::LOG, "PageWindPlot: No valid data available"); getdisplay().setFont(&Ubuntu_Bold10pt7b); getdisplay().fillRect(xCenter - 66, height / 2 - 18, 146, 24, commonData->bgcolor); // Clear area for TWS value getdisplay().setCursor(xCenter - 66, height / 2); getdisplay().print("No sensor data"); } // Print TWS value if (showTWS) { int currentZone; static int lastZone = 0; static bool flipTws = false; int xPosTws; static const int yPosTws = yOffset + 40; // xPosTws = flipTws ? 30 : width - 145; xPosTws = flipTws ? 20 : width - 138; currentZone = (y >= yPosTws - 38) && (y <= yPosTws + 6) && (x >= xPosTws - 4) && (x <= xPosTws + 146) ? 1 : 0; // Define current zone for TWS value // currentZone = (x >= xPosTws - 4) && (x <= xPosTws + 142) ? 1 : 0; // Define current zone for TWS value // LOG_DEBUG(GwLog::DEBUG, "PageWindPlot TWS: xPos: %d, yPos: %d, x: %d y: %d, currZone: %d, lastZone: %d", xPosTws, yPosTws, x, y, currentZone, lastZone); if (currentZone != lastZone) { // Only flip when x moves to a different zone if ((y >= yPosTws - 38) && (y <= yPosTws + 6) && (x >= xPosTws - 4) && (x <= xPosTws + 146)) { flipTws = !flipTws; xPosTws = flipTws ? 20 : width - 145; } } lastZone = currentZone; getdisplay().fillRect(xPosTws - 4, yPosTws - 38, 142, 44, commonData->bgcolor); // Clear area for TWS value getdisplay().setFont(&DSEG7Classic_BoldItalic16pt7b); getdisplay().setCursor(xPosTws, yPosTws); getdisplay().print(dataSValue[2]); // Value getdisplay().setFont(&Ubuntu_Bold12pt7b); getdisplay().setCursor(xPosTws + 82, yPosTws - 14); getdisplay().print(dataName[2]); // Name getdisplay().setFont(&Ubuntu_Bold8pt7b); getdisplay().setCursor(xPosTws + 78, yPosTws + 1); getdisplay().print(" "); if (holdValues == false) { getdisplay().print(dataUnit[2]); // Unit } else { getdisplay().print(dataUnitOld[2]); // Unit } } // chart Y axis labels; print last to overwrite potential chart lines in label area char sWndYAx[4]; // char buffer for wind Y axis labels int yPos; getdisplay().setFont(&Ubuntu_Bold8pt7b); for (int i = 1; i <= 3; i++) { yPos = yOffset + (i * 60); // Y position for label // yPos = yOffset + cHeight - (i * 60); // Y position for label getdisplay().fillRect(0, yPos, width, 1, commonData->fgcolor); getdisplay().fillRect(0, yPos - 9, 26, 16, commonData->bgcolor); // Clear small area to remove potential chart lines // getdisplay().fillRect(0, yPos, 8, 2, commonData->fgcolor); getdisplay().setCursor(1, yPos + 4); snprintf(sWndYAx, 4, "%3d", i * dataInterv * -1); getdisplay().print(sWndYAx); // Wind value label } // Update display getdisplay().nextPage(); // Partial update (fast) unsigned long finish = millis() - start; LOG_DEBUG(GwLog::ERROR, "PageWindPlot Time: %lu", finish); }; }; static Page* createPage(CommonData& common) { return new PageWindPlot(common); } /** * with the code below we make this page known to the PageTask * we give it a type (name) that can be selected in the config * we define which function is to be called * and we provide the number of user parameters we expect (0 here) * and will will provide the names of the fixed values we need */ PageDescription registerPageWindPlot( "WindPlot", // Page name createPage, // Action 0, // Number of bus values depends on selection in Web configuration { "TWD", "TWA", "TWS", "HDM", "AWA", "AWS", "STW", "COG", "SOG" }, // Bus values we need in the page true // Show display header on/off ); #endif