'use strict'; /* ════════════════════════════════════════════════════════════════ Constants ════════════════════════════════════════════════════════════════ */ const DEFAULT_CAP = 10_000; const TEMPORAL_CAP = 600_000; const LTTB_MIN = 200; // never decimate below this many points const TRACE_COLORS = [ '#89b4fa', '#a6e3a1', '#f38ba8', '#fab387', '#cba6f7', '#94e2d5', '#89dceb', '#b4befe', '#f9e2af', '#f5c2e7', ]; /* ════════════════════════════════════════════════════════════════ Globals ════════════════════════════════════════════════════════════════ */ let signals = []; let buffers = {}; let plots = []; let nextPlotId = 1; let windowSec = 5; let globalPause = false; let lastDataAt = 0; const traceColorMap = {}; let colorIdx = 0; function getTraceColor(key) { if (!traceColorMap[key]) traceColorMap[key] = TRACE_COLORS[colorIdx++ % TRACE_COLORS.length]; return traceColorMap[key]; } // Per-signal style overrides (color, width, dash, marker, markerSize). const sigStyle = {}; function getSigStyle(key) { if (!sigStyle[key]) sigStyle[key] = { color: getTraceColor(key), width: 1.5, dash: 'solid', marker: 'none', markerSize: 4 }; return sigStyle[key]; } function setSigStyle(key, updates) { const s = getSigStyle(key); Object.assign(s, updates); if (updates.color) { traceColorMap[key] = updates.color; // Update badge dots for this key across all plots document.querySelectorAll(`.sig-badge[data-key="${CSS.escape(key)}"] .trace-dot`).forEach(dot => { dot.style.background = updates.color; }); } // Recreate uPlot for all plots containing this key plots.forEach(p => { if (p.traces.includes(key)) { createUPlot(p); p.needsRedraw = true; } }); } // Sync: shared uPlot cursor crosshair across all live plots const LIVE_SYNC = uPlot.sync('live'); const TRIG_SYNC = uPlot.sync('trig'); // Zoom guard: prevents echo on cross-plot sync calls inside onZoom. // zoomGuard prevents the setScale hook from calling onZoom when we programmatically // set the scale (rolling window, zoom-back, fit, resize, pan, cross-plot sync). // All programmatic setScale calls wrap with zoomGuard=true/false so that the hook // only fires for genuine user drag-zoom or scroll-wheel gestures. let zoomGuard = false; // Zoom history for Back button (global since plots are zoom-synced) const zoomHistory = []; // Cursors A/B — stored in x-axis units of the current mode: // live mode → Unix seconds // trig mode → relative seconds from trigger const cursors = { mode: 'off', tA: null, tB: null }; let cursorsDirty = false; // if true, redraw all plots to update cursor lines // Layout — [label, cssClass, cols, rows] const LAYOUTS = [ ['1×1', 'l1x1', 1, 1], ['1×2', 'l1x2', 1, 2], ['2×1', 'l2x1', 2, 1], ['1×3', 'l1x3', 1, 3], ['3×1', 'l3x1', 3, 1], ['2×2', 'l2x2', 2, 2], ['1×4', 'l1x4', 1, 4], ['4×1', 'l4x1', 4, 1], ]; let currentLayout = 'l1x1'; /* ════════════════════════════════════════════════════════════════ Trigger state ════════════════════════════════════════════════════════════════ */ const trig = { enabled: false, signal: '', edge: 'rising', threshold: 0, windowSec: 1, prePercent: 20, mode: 'normal', stopped: false, armed: false, prevVal: null, collecting: false, trigTime: null, snapshot: null, }; function trigPreSec() { return trig.windowSec * trig.prePercent / 100; } function trigPostSec() { return trig.windowSec * (100 - trig.prePercent) / 100; } /* ════════════════════════════════════════════════════════════════ WebSocket ════════════════════════════════════════════════════════════════ */ let ws = null, wsBackoff = 1000; function connectWS() { ws = new WebSocket('ws://' + location.host + '/ws'); ws.onopen = () => { wsBackoff = 1000; setStatus('orange', 'Connected – waiting for data'); }; ws.onclose = () => { setStatus('red', 'Disconnected (reconnecting…)'); setTimeout(connectWS, wsBackoff); wsBackoff = Math.min(wsBackoff * 2, 30000); }; ws.onerror = () => { }; ws.onmessage = evt => { let msg; try { msg = JSON.parse(evt.data); } catch { return; } if (msg.type === 'config') onConfig(msg); else if (msg.type === 'data') onData(msg); }; } /* ════════════════════════════════════════════════════════════════ Status LED ════════════════════════════════════════════════════════════════ */ function setStatus(s, t) { document.getElementById('status-led').className = s; document.getElementById('status-text').textContent = t; } setInterval(() => { const tsEl = document.getElementById('sb-tsage'); if (ws && ws.readyState === WebSocket.OPEN && lastDataAt > 0) { const age = performance.now() - lastDataAt; // Compute minimum lag: newest buffer timestamp vs browser wall clock. let tsAge = null; const wallNow = Date.now() / 1000; Object.values(buffers).forEach(buf => { if (buf.size === 0) return; const newest = buf.t[(buf.head - 1 + buf.cap) % buf.cap]; const a = wallNow - newest; if (tsAge === null || a < tsAge) tsAge = a; }); if (tsEl && tsAge !== null) { const ms = tsAge * 1000; tsEl.textContent = '| lag: ' + (ms < 1000 ? ms.toFixed(0) + 'ms' : tsAge.toFixed(2) + 's'); } else if (tsEl) { tsEl.textContent = ''; } if (age > 1000) setStatus('orange', 'No data for ' + (age / 1000).toFixed(1) + 's'); else setStatus('green', 'Streaming'); } else if (tsEl) { tsEl.textContent = ''; } }, 500); /* ════════════════════════════════════════════════════════════════ Config handler ════════════════════════════════════════════════════════════════ */ function numElements(sig) { return (sig.numRows || 1) * (sig.numCols || 1); } function isTemporal(sig) { return numElements(sig) > 1 && (sig.timeMode || 0) !== 0; } function onConfig(msg) { const newSigs = msg.signals || []; const fp = s => s.name + ':' + s.typeCode + ':' + (s.numRows || 1) + ':' + (s.numCols || 1) + ':' + (s.timeMode || 0); const changed = newSigs.length !== signals.length || newSigs.some((s, i) => fp(s) !== fp(signals[i])); signals = newSigs; if (changed) { buffers = {}; signals.forEach(sig => { const n = numElements(sig); if (isTemporal(sig)) { buffers[sig.name] = makeBuffer(TEMPORAL_CAP); } else if (n === 1) { buffers[sig.name] = makeBuffer(); } else { for (let i = 0; i < n; i++) buffers[sig.name + '[' + i + ']'] = makeBuffer(); } }); trigDisarm(); trig.snapshot = null; trig.prevVal = null; zoomHistory.length = 0; document.getElementById('btn-zoom-back').style.display = 'none'; } buildSidebar(); buildTrigSignalSelect(); } /* ════════════════════════════════════════════════════════════════ Data handler ════════════════════════════════════════════════════════════════ */ function onData(msg) { lastDataAt = performance.now(); const sigs = msg.signals; if (!sigs) return; Object.keys(sigs).forEach(key => { const buf = buffers[key]; if (!buf) return; const sd = sigs[key]; if (!sd || !sd.t || !sd.v) return; const len = Math.min(sd.t.length, sd.v.length); for (let i = 0; i < len; i++) pushBuffer(buf, sd.t[i], sd.v[i]); }); if (trig.enabled && trig.armed && trig.signal) checkTrigger(sigs); if (trig.enabled && trig.collecting && (Date.now() / 1000) >= trig.trigTime + trigPostSec()) finaliseTriggerCapture(); if (!trig.enabled) { plots.forEach(p => { if (globalPause) return; if (p.traces.some(t => buffers[t] !== undefined)) p.needsRedraw = true; }); } } /* ════════════════════════════════════════════════════════════════ Trigger logic ════════════════════════════════════════════════════════════════ */ function checkTrigger(sigs) { const sd = sigs[trig.signal]; if (!sd || !sd.v || !sd.v.length) return; for (let i = 0; i < sd.v.length; i++) { const cur = sd.v[i], prev = trig.prevVal; trig.prevVal = cur; if (prev === null) continue; const e = trig.edge, thr = trig.threshold; if ((e === 'rising' && prev < thr && cur >= thr) || (e === 'falling' && prev > thr && cur <= thr) || (e === 'both' && ((prev < thr && cur >= thr) || (prev > thr && cur <= thr)))) { fireTrigger(sd.t ? sd.t[i] : Date.now() / 1000); break; } } } function fireTrigger(t) { // Clear the previous snapshot here (not in trigArm) so the last waveform // and trigger marker stay visible while the trigger is rearmed and waiting. trig.snapshot = null; trig.armed = false; trig.collecting = true; trig.trigTime = t; updateTrigStatusBadge('waiting'); setAllCardsCollecting(true); } function finaliseTriggerCapture() { trig.collecting = false; const t0 = trig.trigTime - trigPreSec(), t1 = trig.trigTime + trigPostSec(); const snap = {}; Object.keys(buffers).forEach(key => { const sl = getBufferSliceRange(buffers[key], t0, t1); if (sl.t.length > 0) snap[key] = sl; }); // Tag snapshot with the window parameters captured at trigger time so that // the render loop uses the correct bounds even if UI controls are changed later. snap._preS = trigPreSec(); snap._postS = trigPostSec(); trig.snapshot = snap; setAllCardsCollecting(false); updateTrigStatusBadge('triggered'); showRearmBtn(trig.mode === 'single'); showStopBtn(trig.mode === 'normal'); // Show cursor button now that snapshot exists (positions preserved from before) updateCursorBtnVisibility(); plots.forEach(p => { p.xRange = null; p.needsRedraw = true; }); if (trig.mode === 'normal' && !trig.stopped) setTimeout(() => { if (trig.enabled && trig.mode === 'normal' && !trig.stopped) trigArm(); }, 200); } function trigArm() { // Do NOT clear trig.snapshot here — keep the last waveform and trigger marker // visible while waiting for the next event. fireTrigger() clears it when a new // trigger actually fires. trig.armed = true; trig.collecting = false; trig.prevVal = null; showRearmBtn(false); updateTrigStatusBadge('armed'); updateCursorBtnVisibility(); plots.forEach(p => { p.xRange = null; p.needsRedraw = true; }); } function trigDisarm() { trig.armed = false; trig.collecting = false; trig.trigTime = null; trig.stopped = false; setAllCardsCollecting(false); showRearmBtn(false); showStopBtn(false); updateTrigStatusBadge('idle'); } function setAllCardsCollecting(on) { document.querySelectorAll('.plot-card').forEach(c => c.classList.toggle('trig-collecting', on)); } function updateTrigStatusBadge(state) { const el = document.getElementById('trig-status-badge'); el.className = state; el.textContent = { idle: 'IDLE', armed: 'ARMED', waiting: 'COLLECTING', triggered: 'TRIGGERED' }[state] || 'IDLE'; } function showRearmBtn(v) { document.getElementById('btn-trig-rearm').style.display = v ? 'inline-block' : 'none'; } function showStopBtn(v) { document.getElementById('btn-trig-stop').style.display = v ? 'inline-block' : 'none'; } function updateStopBtn() { const btn = document.getElementById('btn-trig-stop'); btn.textContent = trig.stopped ? 'Resume' : 'Stop'; } /* ════════════════════════════════════════════════════════════════ Circular buffer ════════════════════════════════════════════════════════════════ */ function makeBuffer(cap) { cap = cap || DEFAULT_CAP; return { t: new Float64Array(cap), v: new Float64Array(cap), head: 0, size: 0, cap }; } function pushBuffer(buf, t, v) { buf.t[buf.head] = t; buf.v[buf.head] = v; buf.head = (buf.head + 1) % buf.cap; if (buf.size < buf.cap) buf.size++; } // Binary-search range slice of circular buffer — O(log n + window_size) function getBufferSliceRange(buf, t0, t1) { if (buf.size === 0) return { t: new Float64Array(0), v: new Float64Array(0) }; const { cap, size, head } = buf; const start = (size === cap) ? head : 0; const physAt = k => (start + k) % cap; let lo = 0, hi = size; while (lo < hi) { const m = (lo + hi) >>> 1; if (buf.t[physAt(m)] < t0) lo = m + 1; else hi = m; } const kStart = lo; lo = kStart; hi = size; while (lo < hi) { const m = (lo + hi) >>> 1; if (buf.t[physAt(m)] <= t1) lo = m + 1; else hi = m; } const kEnd = lo, len = kEnd - kStart; if (len <= 0) return { t: new Float64Array(0), v: new Float64Array(0) }; const outT = new Float64Array(len), outV = new Float64Array(len); const physStart = physAt(kStart), tail = cap - physStart; if (tail >= len) { outT.set(buf.t.subarray(physStart, physStart + len)); outV.set(buf.v.subarray(physStart, physStart + len)); } else { outT.set(buf.t.subarray(physStart, physStart + tail)); outT.set(buf.t.subarray(0, len - tail), tail); outV.set(buf.v.subarray(physStart, physStart + tail)); outV.set(buf.v.subarray(0, len - tail), tail); } return { t: outT, v: outV }; } // getGlobalNow returns the reference "now" for the rolling window. // Always anchors to the newest timestamp found in any buffer so the rolling // window tracks real data regardless of any clock skew between the Go server // and the browser. Falls back to Date.now()/1000 only when all buffers are // empty (no data yet received). function getGlobalNow() { let latest = -Infinity; Object.values(buffers).forEach(buf => { if (buf.size === 0) return; const newestT = buf.t[(buf.head - 1 + buf.cap) % buf.cap]; if (newestT > latest) latest = newestT; }); return isFinite(latest) ? latest : Date.now() / 1000; } // getBufferNow returns the "now" anchor for a single buffer — the buffer's own // newest timestamp. This avoids cross-signal interference when signals have // different timescales or update rates. function getBufferNow(buf) { if (buf.size === 0) return Date.now() / 1000; return buf.t[(buf.head - 1 + buf.cap) % buf.cap]; } function getBufferSlice(buf) { const now = getBufferNow(buf); return getBufferSliceRange(buf, now - windowSec, now); } // Binary-search slice of a sorted contiguous Float64Array pair function sliceTypedArrayRange(t, v, t0, t1) { let lo = 0, hi = t.length; while (lo < hi) { const m = (lo + hi) >>> 1; if (t[m] < t0) lo = m + 1; else hi = m; } const s = lo; lo = s; hi = t.length; while (lo < hi) { const m = (lo + hi) >>> 1; if (t[m] <= t1) lo = m + 1; else hi = m; } return { t: t.subarray(s, lo), v: v.subarray(s, lo) }; } // Return the configured samplingRate for a buffer key. // Temporal array signals have a meaningful SamplingRate; scalars return 0. // Used to prefer high-freq signals as the master time grid regardless of trace order. function getKeySamplingRate(key) { const direct = signals.find(s => s.name === key); if (direct) return direct.samplingRate || 0; // Array element key like "Sig[3]" — strip the index const sig = signals.find(s => key.startsWith(s.name + '[')); return sig ? (sig.samplingRate || 0) : 0; } // Returns a uPlot paths function for dashed/dotted lines, or null for solid (uPlot default). function makeSeriesPath(key) { const style = getSigStyle(key); if (style.dash === 'solid') return null; const dashPat = style.dash === 'dashed' ? [6, 4] : [2, 3]; return (u, si) => { const xd = u.data[0], yd = u.data[si]; if (!xd || !yd || !u.bbox) return { stroke: null, fill: null }; const { ctx, bbox } = u; ctx.save(); ctx.beginPath(); ctx.rect(bbox.left, bbox.top, bbox.width, bbox.height); ctx.clip(); ctx.strokeStyle = style.color; ctx.lineWidth = style.width; ctx.setLineDash(dashPat); ctx.lineJoin = 'round'; ctx.beginPath(); let moved = false; for (let i = 0; i < xd.length; i++) { if (yd[i] == null) { moved = false; continue; } const cx = u.valToPos(xd[i], 'x', true); const cy = u.valToPos(yd[i], 'y', true); if (!moved) { ctx.moveTo(cx, cy); moved = true; } else ctx.lineTo(cx, cy); } ctx.stroke(); ctx.restore(); return { stroke: null, fill: null }; // tell uPlot not to draw anything on top }; } // LTTB decimation — O(n). Returns {t, v} unchanged when len ≤ threshold. function lttb(t, v, threshold) { const len = t.length; if (len <= threshold) return { t, v }; const outT = new Float64Array(threshold), outV = new Float64Array(threshold); outT[0] = t[0]; outV[0] = v[0]; outT[threshold - 1] = t[len - 1]; outV[threshold - 1] = v[len - 1]; const every = (len - 2) / (threshold - 2); let a = 0; for (let i = 0; i < threshold - 2; i++) { const avgS = Math.floor((i + 1) * every) + 1, avgE = Math.min(Math.floor((i + 2) * every) + 1, len); let avgT = 0, avgV = 0, n = 0; for (let j = avgS; j < avgE; j++) { avgT += t[j]; avgV += v[j]; n++; } if (n) { avgT /= n; avgV /= n; } const rS = Math.floor(i * every) + 1, rE = Math.min(Math.floor((i + 1) * every) + 1, len); let maxA = -1, next = rS; const aT = t[a], aV = v[a]; for (let j = rS; j < rE; j++) { const area = Math.abs((aT - avgT) * (v[j] - aV) - (aT - t[j]) * (avgV - aV)); if (area > maxA) { maxA = area; next = j; } } outT[i + 1] = t[next]; outV[i + 1] = v[next]; a = next; } return { t: outT, v: outV }; } /* ════════════════════════════════════════════════════════════════ uPlot helpers ════════════════════════════════════════════════════════════════ */ // Format Unix seconds → HH:MM:SS.mmm (used for live x-axis ticks) function fmtLiveTick(u, vals) { return vals.map(v => { if (v == null) return ''; const d = new Date(v * 1000); const hh = String(d.getHours()).padStart(2, '0'); const mm = String(d.getMinutes()).padStart(2, '0'); const ss = String(d.getSeconds()).padStart(2, '0'); const ms = String(d.getMilliseconds()).padStart(3, '0'); return hh + ':' + mm + ':' + ss + '.' + ms; }); } // Format relative seconds → ±Xms or ±Xs (used for trigger x-axis ticks) function fmtTrigTick(u, vals) { return vals.map(v => { if (v == null) return ''; const abs = Math.abs(v), sign = v < 0 ? '-' : '+'; if (abs < 1) return sign + (abs * 1000).toFixed(1) + 'ms'; return sign + abs.toFixed(3) + 's'; }); } // Draw the trigger marker: dashed vertical line at t=0, plus a horizontal threshold // line on any plot that shows the trigger signal. function drawTriggerMarker(u, p) { if (!trig.enabled || !trig.snapshot) return; const { ctx, bbox } = u; if (!bbox) return; const x = u.valToPos(0, 'x', true); if (x < bbox.left || x > bbox.left + bbox.width) return; const px = Math.round(x); ctx.save(); // Thin dashed vertical line at t=0 ctx.strokeStyle = 'rgba(203,166,247,0.7)'; ctx.lineWidth = 1; ctx.setLineDash([4, 3]); ctx.beginPath(); ctx.moveTo(px, bbox.top); ctx.lineTo(px, bbox.top + bbox.height); ctx.stroke(); ctx.setLineDash([]); ctx.fillStyle = 'rgba(203,166,247,0.7)'; ctx.font = 'bold 9px monospace'; ctx.textBaseline = 'top'; ctx.fillText('T', px + 3, bbox.top + 2); // Horizontal threshold line — only on plots that contain the trigger signal if (p && trig.signal && p.traces.includes(trig.signal)) { const y = u.valToPos(trig.threshold, 'y', true); if (y >= bbox.top && y <= bbox.top + bbox.height) { const py = Math.round(y); ctx.strokeStyle = 'rgba(203,166,247,0.45)'; ctx.lineWidth = 0.75; ctx.setLineDash([3, 4]); ctx.beginPath(); ctx.moveTo(bbox.left, py); ctx.lineTo(bbox.left + bbox.width, py); ctx.stroke(); ctx.setLineDash([]); ctx.fillStyle = 'rgba(203,166,247,0.45)'; ctx.font = '9px monospace'; ctx.textBaseline = 'bottom'; ctx.fillText(trig.threshold.toPrecision(4), bbox.left + 4, py - 1); } } ctx.restore(); } // Linearly interpolate series value at time t from uPlot's current rendered data. function interpAtTime(u, si, t) { const td = u.data[0], vd = u.data[si]; if (!td || td.length === 0 || !vd) return null; let lo = 0, hi = td.length - 1; while (lo < hi) { const m = (lo + hi) >> 1; if (td[m] < t) lo = m + 1; else hi = m; } if (lo === 0) return vd[0] ?? null; const t0 = td[lo - 1], t1 = td[lo]; const v0 = vd[lo - 1], v1 = vd[lo]; if (v0 == null || v1 == null) return v0 ?? v1 ?? null; return v0 + (t - t0) / (t1 - t0) * (v1 - v0); } // Draw custom marker shapes (square, cross, diamond) for all series in a plot. // Circle markers are handled natively by uPlot's points option. function drawSeriesMarkers(u, p) { if (!u.bbox) return; const { ctx, bbox } = u; ctx.save(); ctx.beginPath(); ctx.rect(bbox.left, bbox.top, bbox.width, bbox.height); ctx.clip(); p.traces.forEach((key, idx) => { const style = getSigStyle(key); if (style.marker === 'none' || style.marker === 'circle') return; const si = idx + 1; const xd = u.data[0], yd = u.data[si]; if (!xd || !yd) return; const sz = style.markerSize; ctx.strokeStyle = style.color; ctx.fillStyle = style.color; ctx.lineWidth = 1.5; ctx.setLineDash([]); for (let i = 0; i < xd.length; i++) { if (yd[i] == null) continue; const cx = u.valToPos(xd[i], 'x', true); const cy = u.valToPos(yd[i], 'y', true); if (cx < bbox.left || cx > bbox.left + bbox.width || cy < bbox.top || cy > bbox.top + bbox.height) continue; ctx.beginPath(); if (style.marker === 'square') { ctx.rect(cx - sz / 2, cy - sz / 2, sz, sz); ctx.fill(); } else if (style.marker === 'cross') { ctx.moveTo(cx - sz / 2, cy); ctx.lineTo(cx + sz / 2, cy); ctx.moveTo(cx, cy - sz / 2); ctx.lineTo(cx, cy + sz / 2); ctx.stroke(); } else if (style.marker === 'diamond') { ctx.moveTo(cx, cy - sz / 2); ctx.lineTo(cx + sz / 2, cy); ctx.lineTo(cx, cy + sz / 2); ctx.lineTo(cx - sz / 2, cy); ctx.closePath(); ctx.fill(); } } }); ctx.restore(); } // Draw cursor A/B vertical lines and signal value labels (called from draw hook). function drawCursorLines(u, p) { if (cursors.mode !== 'on') return; const { ctx, bbox } = u; if (!bbox) return; const drawLine = (val, color, label) => { if (val === null) return; const x = u.valToPos(val, 'x', true); if (x < bbox.left || x > bbox.left + bbox.width) return; const px = Math.round(x); ctx.save(); // Clip to plot area ctx.beginPath(); ctx.rect(bbox.left, bbox.top, bbox.width, bbox.height); ctx.clip(); // Vertical dashed cursor line ctx.strokeStyle = color; ctx.lineWidth = 1.5; ctx.setLineDash([5, 4]); ctx.beginPath(); ctx.moveTo(px, bbox.top); ctx.lineTo(px, bbox.top + bbox.height); ctx.stroke(); ctx.setLineDash([]); // Cursor label at top ctx.fillStyle = color; ctx.font = 'bold 12px monospace'; ctx.textBaseline = 'top'; ctx.fillText(label, px + 14, bbox.top + 2); // Per-trace: diamond at crossing point + value label if (p) { const DSZ = 5; // diamond half-size in px p.traces.forEach((key, idx) => { const v = interpAtTime(u, idx + 1, val); if (v === null) return; const cy = u.valToPos(v, 'y', true); if (cy < bbox.top || cy > bbox.top + bbox.height) return; const tc = getSigStyle(key).color; // Diamond marker at intersection ctx.fillStyle = tc; ctx.strokeStyle = tc; ctx.lineWidth = 1; ctx.beginPath(); ctx.moveTo(px, cy - DSZ); ctx.lineTo(px + DSZ, cy); ctx.lineTo(px, cy + DSZ); ctx.lineTo(px - DSZ, cy); ctx.closePath(); ctx.fill(); // Value text next to diamond const str = Math.abs(v) >= 10000 ? v.toExponential(2) : parseFloat(v.toPrecision(4)).toString(); ctx.fillStyle = tc; ctx.font = '11px monospace'; const currentAlign = ctx.textAlign; ctx.textAlign = "left"; // horizontal alignment ctx.textBaseline = "middle"; ctx.fillText(str, px + DSZ + 4, cy); ctx.textAlign = currentAlign; }); } ctx.restore(); }; drawLine(cursors.tA, 'rgba(137,220,235,0.85)', 'A'); drawLine(cursors.tB, 'rgba(249,226,175,0.85)', 'B'); } // Build uPlot opts for a given plot object function makeUPlotOpts(p, inTrigMode) { const seriesArr = [{}]; // time (index 0) p.traces.forEach(key => { const style = getSigStyle(key); const pathsFn = makeSeriesPath(key); seriesArr.push({ label: key, stroke: style.color, width: style.width, points: { show: style.marker === 'circle', size: style.markerSize + 2, fill: style.color }, spanGaps: true, ...(pathsFn ? { paths: pathsFn } : {}), }); }); const xVals = inTrigMode ? (u, vals) => fmtTrigTick(u, vals) : (u, vals) => fmtLiveTick(u, vals); return { width: Math.max(p.div.clientWidth || 100, 50), height: Math.max(p.div.clientHeight || 100, 50), cursor: { sync: { key: inTrigMode ? 'trig' : 'live', setSeries: false }, drag: { x: true, y: false, setScale: true, uni: 20 }, lock: false, }, select: { show: true }, scales: { x: { time: false, auto: false, min: p.xRange ? p.xRange[0] : 0, max: p.xRange ? p.xRange[1] : windowSec }, y: { auto: true }, }, series: seriesArr, axes: [ { stroke: '#7f849c', grid: { stroke: '#313244', width: 1 }, ticks: { stroke: '#313244', width: 1 }, values: xVals, size: 36, space: 90 }, { stroke: '#7f849c', grid: { stroke: '#313244', width: 1 }, ticks: { stroke: '#313244', width: 1 }, size: 50 }, ], legend: { show: false }, padding: [4, 4, 0, 0], hooks: { draw: [u => { drawCursorLines(u, p); drawSeriesMarkers(u, p); drawTriggerMarker(u, p); }], // Two-hook zoom detection: setSelect flags that the NEXT setScale is user-initiated. // uPlot fires setSelect → then immediately setScale (when drag.setScale:true). // All programmatic setScale calls happen without a preceding setSelect, so the // flag is false and onZoom is never called unintentionally. setSelect: [(u) => { u._userZoom = (u.select.width > 0); }], setScale: [(u, key) => { if (key !== 'x' || !u._userZoom || !u._ready) return; u._userZoom = false; const { min, max } = u.scales.x; if (min == null || max == null || max <= min) return; onZoom(p.id, min, max); }], ready: [u => { u._ready = true; }], }, }; } // Create (or recreate) the uPlot instance for a plot, mounting into p.div function createUPlot(p) { // Destroy previous instance if (p.uplot) { p.uplot.destroy(); p.uplot = null; } const inTrigMode = trig.enabled && trig.snapshot !== null; const opts = makeUPlotOpts(p, inTrigMode); const data = buildUPlotData(p, inTrigMode); // Mount into the plot body div (clear previous uPlot DOM) p.div.querySelectorAll('.uplot').forEach(el => el.remove()); p.uplot = new uPlot(opts, data, p.div); // ── Cursor drag: place or drag A/B cursors ────────────────────────────── // - Near an existing cursor line (within CURSOR_SNAP_PX): drag to move it. // - cursor mode A or B active: click/drag places that cursor anywhere. // - Intercepts mousedown before uPlot zoom so the selection rect never shows. const CURSOR_SNAP_PX = 8; function _cursorAtClientX(clientX) { const rect = p.uplot.over.getBoundingClientRect(); const { min, max } = p.uplot.scales.x; const toX = val => rect.left + ((val - min) / (max - min)) * rect.width; if (cursors.tA !== null && Math.abs(clientX - toX(cursors.tA)) <= CURSOR_SNAP_PX) return 'A'; if (cursors.tB !== null && Math.abs(clientX - toX(cursors.tB)) <= CURSOR_SNAP_PX) return 'B'; return null; } function _cursorValFromEvent(e) { const rect = p.uplot.over.getBoundingClientRect(); const pct = Math.max(0, Math.min(1, (e.clientX - rect.left) / rect.width)); const { min, max } = p.uplot.scales.x; return min + pct * (max - min); } // Update pointer style based on what's under the mouse p.uplot.over.addEventListener('mousemove', e => { const snap = cursors.mode === 'on' ? _cursorAtClientX(e.clientX) : null; p.uplot.over.style.cursor = snap ? 'ew-resize' : ''; }); p.uplot.over.addEventListener('mouseleave', () => { p.uplot.over.style.cursor = ''; }); // Mousedown: drag an existing cursor (only when mode='on' and mouse is near a cursor line). // If not near a cursor, the event falls through to uPlot for normal zoom/pan behavior. p.uplot.over.addEventListener('mousedown', e => { if (e.button !== 0 || e.shiftKey) return; // shift is pan if (cursors.mode !== 'on') return; const target = _cursorAtClientX(e.clientX); if (!target) return; // not near a cursor — let uPlot handle zoom e.stopImmediatePropagation(); // prevent uPlot drag-zoom e.preventDefault(); // Set cursor position immediately on mousedown if (target === 'A') cursors.tA = _cursorValFromEvent(e); else cursors.tB = _cursorValFromEvent(e); updateCursorReadout(); cursorsDirty = true; const onMove = ev => { if (target === 'A') cursors.tA = _cursorValFromEvent(ev); else cursors.tB = _cursorValFromEvent(ev); updateCursorReadout(); cursorsDirty = true; }; const onUp = () => { document.removeEventListener('mousemove', onMove); document.removeEventListener('mouseup', onUp); }; document.addEventListener('mousemove', onMove); document.addEventListener('mouseup', onUp); }, true); // capture:true so we fire before uPlot's own handlers // Pan support: Shift+left-drag pans the current view (synced across all plots). // Works in both zoomed mode (xRange set) and rolling mode (freezes the window first). let _panActive = false, _panAnchorX = 0, _panAnchorMin = 0, _panAnchorMax = 0; p.uplot.over.addEventListener('mousedown', e => { if (e.button !== 0 || !e.shiftKey) return; e.stopImmediatePropagation(); e.preventDefault(); _panActive = true; _panAnchorX = e.clientX; const xr = p.xRange; if (xr) { _panAnchorMin = xr[0]; _panAnchorMax = xr[1]; } else { // Rolling mode: capture the current window position and freeze it so we // have a stable anchor to pan from. let now = -Infinity; p.traces.forEach(key => { const buf = buffers[key]; if (buf && buf.size > 0) { const t = buf.t[(buf.head - 1 + buf.cap) % buf.cap]; if (t > now) now = t; } }); if (!isFinite(now)) now = Date.now() / 1000; _panAnchorMin = now - windowSec; _panAnchorMax = now; // Freeze all plots at this position immediately. const pMin = _panAnchorMin, pMax = _panAnchorMax; zoomGuard = true; plots.forEach(q => { q.xRange = [pMin, pMax]; if (q.uplot) q.uplot.setScale('x', { min: pMin, max: pMax }); }); zoomGuard = false; if (!syncLocked) { syncLocked = true; const btnR = document.getElementById('btn-sync-resume'); if (btnR) btnR.style.display = ''; } } }, true); const _onPanMove = e => { if (!_panActive || !p.uplot) return; const w = p.uplot.over.getBoundingClientRect().width; const span = _panAnchorMax - _panAnchorMin; const dt = -((e.clientX - _panAnchorX) / w) * span; const newMin = _panAnchorMin + dt; const newMax = _panAnchorMax + dt; zoomGuard = true; plots.forEach(q => { q.xRange = [newMin, newMax]; if (q.uplot) q.uplot.setScale('x', { min: newMin, max: newMax }); q.needsRedraw = true; }); zoomGuard = false; }; const _onPanEnd = () => { _panActive = false; }; document.addEventListener('mousemove', _onPanMove); document.addEventListener('mouseup', _onPanEnd); // Resize observer so the uPlot fills its container. // zoomGuard prevents setSize → setScale → hook from calling onZoom. if (p.ro) { p.ro.disconnect(); } p.ro = new ResizeObserver(() => { if (!p.uplot) return; const w = Math.max(p.div.clientWidth || 50, 50); const h = Math.max(p.div.clientHeight || 50, 50); zoomGuard = true; p.uplot.setSize({ width: w, height: h }); zoomGuard = false; }); p.ro.observe(p.div); } // Build the uPlot data array from buffers / trigger snapshot function buildUPlotData(p, inTrigMode) { if (p.traces.length === 0) return [new Float64Array(0)]; // When trigger is enabled but no snapshot yet (armed/waiting), return // the last-rendered data so the plot stays frozen. if (trig.enabled && !inTrigMode) { if (!p.uplot || !p.uplot.data || !p.uplot.data[0]) return [new Float64Array(0)]; return p.uplot.data; } if (inTrigMode && trig.snapshot) return buildTrigData(p); return buildLiveData(p); } // Resample (vSrc) from times (tSrc) onto target times (tDst) using linear interpolation. // tSrc must be sorted ascending. Values outside tSrc range are clamped to the nearest // endpoint (extrapolation is not safe for streaming data). function resampleLinear(tSrc, vSrc, tDst) { const n = tDst.length; const out = new Float64Array(n); if (tSrc.length === 0) return out; // all zeros if (tSrc.length === 1) { out.fill(vSrc[0]); return out; } let j = 0; for (let i = 0; i < n; i++) { const td = tDst[i]; // Advance j so that tSrc[j] <= td < tSrc[j+1] (or j at last index) while (j < tSrc.length - 2 && tSrc[j + 1] < td) j++; if (td <= tSrc[0]) { out[i] = vSrc[0]; } else if (td >= tSrc[tSrc.length - 1]) { out[i] = vSrc[vSrc.length - 1]; } else { const t0 = tSrc[j], t1 = tSrc[j + 1]; const frac = (td - t0) / (t1 - t0); out[i] = vSrc[j] + frac * (vSrc[j + 1] - vSrc[j]); } } return out; } function buildLiveData(p) { if (p.traces.length === 0) return [new Float64Array(0)]; // plotNow = newest timestamp across ALL traces let plotNow = -Infinity; p.traces.forEach(key => { const buf = buffers[key]; if (buf && buf.size > 0) { const t = buf.t[(buf.head - 1 + buf.cap) % buf.cap]; if (t > plotNow) plotNow = t; } }); if (!isFinite(plotNow)) plotNow = Date.now() / 1000; const t0 = p.xRange ? p.xRange[0] : plotNow - windowSec; const t1 = p.xRange ? p.xRange[1] : plotNow; // Pixel-adaptive LTTB target: 2× plot width so zooming in automatically // raises the effective sample cap and reveals full resolution. const targetPts = Math.max(LTTB_MIN, ((p.uplot ? p.uplot.width : p.div.clientWidth) || 600) * 2); // Slice all traces once; pick the master time grid using configured samplingRate // as the primary criterion (unambiguous, independent of buffer fill / trace order). // Fall back to raw sample count for signals without a configured rate. const slices = {}; let masterKey = p.traces[0], masterCount = -1, masterRate = -1; for (const key of p.traces) { const buf = buffers[key]; if (!buf || buf.size === 0) continue; const sl = getBufferSliceRange(buf, t0, t1); slices[key] = sl; const rate = getKeySamplingRate(key); if (rate > masterRate || (rate === masterRate && sl.t.length > masterCount)) { masterRate = rate; masterCount = sl.t.length; masterKey = key; } } const masterRaw = slices[masterKey]; if (!masterRaw || masterRaw.t.length === 0) return [new Float64Array(0), ...p.traces.map(() => new Float64Array(0))]; // Decimate master with pixel-adaptive LTTB, use resulting grid for all others const dec = lttb(masterRaw.t, masterRaw.v, targetPts); const sharedT = dec.t; const yArrays = []; for (const key of p.traces) { if (key === masterKey) { yArrays.push(dec.v); continue; } const sl = slices[key]; if (!sl || sl.t.length === 0) { yArrays.push(new Float64Array(sharedT.length)); continue; } yArrays.push(resampleLinear(sl.t, sl.v, sharedT)); } return [sharedT, ...yArrays]; } function buildTrigData(p) { const trigT = trig.trigTime; const preS = trig.snapshot._preS !== undefined ? trig.snapshot._preS : trigPreSec(); const postS = trig.snapshot._postS !== undefined ? trig.snapshot._postS : trigPostSec(); if (p.traces.length === 0) return [new Float64Array(0)]; const t0 = p.xRange ? trigT + p.xRange[0] : trigT - preS; const t1 = p.xRange ? trigT + p.xRange[1] : trigT + postS; const targetPts = Math.max(LTTB_MIN, ((p.uplot ? p.uplot.width : p.div.clientWidth) || 600) * 2); // Slice all traces; pick master by samplingRate first, then sample count const slices = {}; let masterKey = p.traces[0], masterCount = -1, masterRate = -1; for (const key of p.traces) { const snap = trig.snapshot[key]; if (!snap) continue; const sl = sliceTypedArrayRange(snap.t, snap.v, t0, t1); slices[key] = sl; const rate = getKeySamplingRate(key); if (rate > masterRate || (rate === masterRate && sl.t.length > masterCount)) { masterRate = rate; masterCount = sl.t.length; masterKey = key; } } const masterRaw = slices[masterKey]; if (!masterRaw || masterRaw.t.length === 0) return [new Float64Array(0), ...p.traces.map(() => new Float64Array(0))]; const dec = lttb(masterRaw.t, masterRaw.v, targetPts); // Convert absolute → relative seconds const sharedT = new Float64Array(dec.t.length); for (let i = 0; i < dec.t.length; i++) sharedT[i] = dec.t[i] - trigT; const yArrays = []; for (const key of p.traces) { if (key === masterKey) { yArrays.push(dec.v); continue; } const sl = slices[key]; if (!sl || sl.t.length === 0) { yArrays.push(new Float64Array(sharedT.length)); continue; } const relT = new Float64Array(sl.t.length); for (let i = 0; i < sl.t.length; i++) relT[i] = sl.t[i] - trigT; yArrays.push(resampleLinear(relT, sl.v, sharedT)); } return [sharedT, ...yArrays]; } /* ════════════════════════════════════════════════════════════════ Zoom sync ════════════════════════════════════════════════════════════════ */ let syncLocked = false; function onZoom(sourcePlotId, min, max) { // Push current range to history before applying new zoom const prevRange = plots[0] && plots[0].xRange ? [...plots[0].xRange] : null; zoomHistory.push(prevRange); if (zoomHistory.length > 30) zoomHistory.shift(); document.getElementById('btn-zoom-back').style.display = ''; // Store zoom on source plot const src = plots.find(p => p.id === sourcePlotId); if (src) src.xRange = [min, max]; // Show Auto button in live mode if (!trig.enabled && !syncLocked) { syncLocked = true; document.getElementById('btn-sync-resume').style.display = ''; } // Propagate to other plots zoomGuard = true; plots.forEach(p => { if (p.id === sourcePlotId) return; p.xRange = [min, max]; if (p.uplot) p.uplot.setScale('x', { min, max }); }); zoomGuard = false; // Mark all plots dirty (re-slice data to the new range for full resolution) plots.forEach(p => { p.needsRedraw = true; }); } // Undo last zoom/pan action function zoomBack() { if (!zoomHistory.length) return; const prev = zoomHistory.pop(); if (!zoomHistory.length) document.getElementById('btn-zoom-back').style.display = 'none'; if (prev === null) { // Was at auto/rolling state before the zoom resetZoom(); } else { zoomGuard = true; plots.forEach(p => { p.xRange = [...prev]; if (p.uplot) p.uplot.setScale('x', { min: prev[0], max: prev[1] }); p.needsRedraw = true; }); zoomGuard = false; } } // Reset to auto/rolling window (clears all zoom) function resetZoom() { syncLocked = false; document.getElementById('btn-sync-resume').style.display = 'none'; if (trig.enabled && trig.snapshot) { const preS = trig.snapshot._preS || trigPreSec(); const postS = trig.snapshot._postS || trigPostSec(); zoomGuard = true; plots.forEach(p => { p.xRange = null; if (p.uplot) p.uplot.setScale('x', { min: -preS, max: postS }); p.needsRedraw = true; }); zoomGuard = false; } else { // Back to rolling window — setScale to current window, render loop keeps it moving plots.forEach(p => { p.xRange = null; if (!globalPause) p.needsRedraw = true; }); } } // Fit x-axis to all data currently in buffers (or full trigger snapshot) function zoomFit() { if (trig.enabled && trig.snapshot) { resetZoom(); // "Fit" in trigger mode = show full trigger window return; } // Find oldest/newest timestamps across all visible signals let gMin = Infinity, gMax = -Infinity; plots.forEach(p => { p.traces.forEach(key => { const buf = buffers[key]; if (!buf || buf.size === 0) return; const startIdx = (buf.size === buf.cap) ? buf.head : 0; const oldestT = buf.t[startIdx]; const newestT = buf.t[(buf.head - 1 + buf.cap) % buf.cap]; if (oldestT < gMin) gMin = oldestT; if (newestT > gMax) gMax = newestT; }); }); if (!isFinite(gMin) || gMin >= gMax) return; // Push to history const prevRange = plots[0] && plots[0].xRange ? [...plots[0].xRange] : null; zoomHistory.push(prevRange); document.getElementById('btn-zoom-back').style.display = ''; if (!syncLocked) { syncLocked = true; document.getElementById('btn-sync-resume').style.display = ''; } zoomGuard = true; plots.forEach(p => { p.xRange = [gMin, gMax]; if (p.uplot) p.uplot.setScale('x', { min: gMin, max: gMax }); p.needsRedraw = true; }); zoomGuard = false; } // Auto = return to rolling window / full trigger window function exitSyncLock() { resetZoom(); } document.getElementById('btn-sync-resume').addEventListener('click', resetZoom); document.getElementById('btn-zoom-back').addEventListener('click', zoomBack); document.getElementById('btn-zoom-fit').addEventListener('click', zoomFit); /* ════════════════════════════════════════════════════════════════ Cursor controls ════════════════════════════════════════════════════════════════ */ // Show the cursor button only when paused or in trigger-snapshot mode. function updateCursorBtnVisibility() { const canUseCursors = globalPause || (trig.enabled && trig.snapshot !== null); const btn = document.getElementById('btn-cursor'); btn.style.display = canUseCursors ? '' : 'none'; if (!canUseCursors && cursors.mode !== 'off') { cursors.mode = 'off'; cursors.tA = null; cursors.tB = null; // context changed, clear positions btn.textContent = 'Cursors'; btn.classList.remove('active'); document.getElementById('cursor-readout').classList.remove('visible'); cursorsDirty = true; } } document.getElementById('btn-cursor').addEventListener('click', () => { cursors.mode = cursors.mode === 'off' ? 'on' : 'off'; const btn = document.getElementById('btn-cursor'); btn.textContent = 'Cursors'; btn.classList.toggle('active', cursors.mode === 'on'); if (cursors.mode === 'on') { // Auto-place at 25%/75% of current x range on first use if (cursors.tA === null && cursors.tB === null) { const refPlot = plots.find(p => p.uplot); if (refPlot) { const { min, max } = refPlot.uplot.scales.x; const span = max - min; cursors.tA = min + span * 0.25; cursors.tB = min + span * 0.75; } } updateCursorReadout(); document.getElementById('cursor-readout').classList.add('visible'); } else { document.getElementById('cursor-readout').classList.remove('visible'); } cursorsDirty = true; }); function updateCursorReadout() { const ro = document.getElementById('cursor-readout'); const active = cursors.mode === 'on'; ro.classList.toggle('visible', active); if (!active) return; // Format depends on mode: live = HH:MM:SS.mmm, trigger = ±Xms const fmt = v => { if (v === null) return '—'; if (trig.enabled && trig.snapshot) { const abs = Math.abs(v), sign = v < 0 ? '-' : '+'; return abs < 1 ? sign + (abs * 1000).toFixed(3) + 'ms' : sign + abs.toFixed(6) + 's'; } const d = new Date(v * 1000); return String(d.getHours()).padStart(2, '0') + ':' + String(d.getMinutes()).padStart(2, '0') + ':' + String(d.getSeconds()).padStart(2, '0') + '.' + String(d.getMilliseconds()).padStart(3, '0'); }; document.getElementById('cur-ta').textContent = 'A: ' + fmt(cursors.tA); document.getElementById('cur-tb').textContent = 'B: ' + fmt(cursors.tB); if (cursors.tA !== null && cursors.tB !== null) { const dt = cursors.tB - cursors.tA, abs = Math.abs(dt); const s = dt >= 0 ? '+' : '-'; const str = abs < 1 ? s + (abs * 1000).toFixed(3) + 'ms' : s + abs.toFixed(6) + 's'; document.getElementById('cur-dt').textContent = 'ΔT: ' + str; } else { document.getElementById('cur-dt').textContent = 'ΔT: —'; } } /* ════════════════════════════════════════════════════════════════ Trigger bar controls ════════════════════════════════════════════════════════════════ */ function openTrigBar(open) { trig.enabled = open; document.getElementById('trigbar').classList.toggle('open', open); document.getElementById('btn-trigger').classList.toggle('trig-active', open); document.documentElement.style.setProperty('--trigbar-h', open ? '48px' : '0px'); // Streaming-only controls are irrelevant while the trigger is active const none = open ? 'none' : ''; document.getElementById('btn-pause-global').style.display = none; document.getElementById('window-select').style.display = none; document.getElementById('lbl-window').style.display = none; if (!open) { trigDisarm(); trig.snapshot = null; cursors.tA = null; cursors.tB = null; updateCursorReadout(); updateCursorBtnVisibility(); zoomHistory.length = 0; document.getElementById('btn-zoom-back').style.display = 'none'; plots.forEach(p => { p.xRange = null; p.needsRedraw = true; }); } else { cursors.tA = null; cursors.tB = null; updateCursorReadout(); updateCursorBtnVisibility(); zoomHistory.length = 0; document.getElementById('btn-zoom-back').style.display = 'none'; resetZoom(); if (trig.signal) trigArm(); else updateTrigStatusBadge('idle'); } // Resize uPlot instances after trigbar height changes setTimeout(() => { plots.forEach(p => { if (!p.uplot) return; p.uplot.setSize({ width: p.div.clientWidth, height: p.div.clientHeight }); }); }, 220); } document.getElementById('btn-trigger').addEventListener('click', () => openTrigBar(!trig.enabled)); document.getElementById('trig-signal').addEventListener('change', e => { trig.signal = e.target.value; trig.prevVal = null; if (trig.enabled && trig.signal) trigArm(); else if (!trig.signal) trigDisarm(); }); document.getElementById('trig-edge').addEventListener('change', e => { trig.edge = e.target.value; if (trig.armed) trig.prevVal = null; }); document.getElementById('trig-threshold').addEventListener('change', e => { trig.threshold = parseFloat(e.target.value) || 0; if (trig.armed) trig.prevVal = null; }); document.getElementById('trig-window').addEventListener('change', e => { trig.windowSec = parseFloat(e.target.value); }); document.getElementById('trig-pre').addEventListener('input', e => { trig.prePercent = parseInt(e.target.value, 10); document.getElementById('trig-pre-val').textContent = trig.prePercent + '%'; }); document.getElementById('trig-mode').addEventListener('change', e => { trig.mode = e.target.value; // If a snapshot already exists the trigger has already fired — update button // visibility immediately so it matches the newly selected mode. if (trig.snapshot) { showRearmBtn(trig.mode === 'single'); showStopBtn(trig.mode === 'normal'); updateStopBtn(); } }); document.getElementById('btn-trig-rearm').addEventListener('click', () => { if (trig.enabled) trigArm(); }); document.getElementById('btn-trig-stop').addEventListener('click', () => { if (!trig.enabled || trig.mode !== 'normal') return; trig.stopped = !trig.stopped; updateStopBtn(); if (!trig.stopped) trigArm(); // resume: re-arm immediately }); /* ════════════════════════════════════════════════════════════════ Trigger signal selector ════════════════════════════════════════════════════════════════ */ function buildTrigSignalSelect() { const sel = document.getElementById('trig-signal'), cur = sel.value; sel.innerHTML = ''; signals.forEach(sig => { const n = numElements(sig); if (isTemporal(sig) || n === 1) { const o = document.createElement('option'); o.value = sig.name; o.textContent = sig.name; sel.appendChild(o); } else { for (let i = 0; i < n; i++) { const key = sig.name + '[' + i + ']', o = document.createElement('option'); o.value = key; o.textContent = key; sel.appendChild(o); } } }); if (cur && [...sel.options].some(o => o.value === cur)) sel.value = cur; trig.signal = sel.value; } /* ════════════════════════════════════════════════════════════════ Sidebar ════════════════════════════════════════════════════════════════ */ function buildSidebar() { const list = document.getElementById('signal-list'); list.innerHTML = ''; if (!signals.length) { list.innerHTML = '